AWfaw/ai-hdlcoder-dataset-clean · Datasets at Hugging Face

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marco-c/leon-nexys2	grlib-gpl-1.3.4-b4140/designs/leon3-digilent-xc3s1600e/config.vhd	1	6,040	----------------------------------------------------------------------------- -- LEON3 Demonstration design test bench configuration -- Copyright (C) 2009 Aeroflex Gaisler ------------------------------------------------------------------------------ library techmap; use techmap.gencomp.all; package config is -- Technology and synthesis options constant CFG_FABTECH : integer := spartan3e; constant CFG_MEMTECH : integer := spartan3e; constant CFG_PADTECH : integer := spartan3e; constant CFG_NOASYNC : integer := 0; constant CFG_SCAN : integer := 0; -- Clock generator constant CFG_CLKTECH : integer := spartan3e; constant CFG_CLKMUL : integer := (4); constant CFG_CLKDIV : integer := (5); constant CFG_OCLKDIV : integer := 1; constant CFG_OCLKBDIV : integer := 0; constant CFG_OCLKCDIV : integer := 0; constant CFG_PCIDLL : integer := 0; constant CFG_PCISYSCLK: integer := 0; constant CFG_CLK_NOFB : integer := 0; -- LEON3 processor core constant CFG_LEON3 : integer := 1; constant CFG_NCPU : integer := (1); constant CFG_NWIN : integer := (8); constant CFG_V8 : integer := 2 + 40; constant CFG_MAC : integer := 0; constant CFG_BP : integer := 1; constant CFG_SVT : integer := 1; constant CFG_RSTADDR : integer := 16#00000#; constant CFG_LDDEL : integer := (1); constant CFG_NOTAG : integer := 1; constant CFG_NWP : integer := (2); constant CFG_PWD : integer := 12; constant CFG_FPU : integer := 0 + 160 + 320; constant CFG_GRFPUSH : integer := 0; constant CFG_ICEN : integer := 1; constant CFG_ISETS : integer := 2; constant CFG_ISETSZ : integer := 4; constant CFG_ILINE : integer := 8; constant CFG_IREPL : integer := 2; constant CFG_ILOCK : integer := 0; constant CFG_ILRAMEN : integer := 0; constant CFG_ILRAMADDR: integer := 16#8E#; constant CFG_ILRAMSZ : integer := 1; constant CFG_DCEN : integer := 1; constant CFG_DSETS : integer := 2; constant CFG_DSETSZ : integer := 4; constant CFG_DLINE : integer := 4; constant CFG_DREPL : integer := 2; constant CFG_DLOCK : integer := 0; constant CFG_DSNOOP : integer := 1 + 0 + 40; constant CFG_DFIXED : integer := 16#0#; constant CFG_DLRAMEN : integer := 0; constant CFG_DLRAMADDR: integer := 16#8F#; constant CFG_DLRAMSZ : integer := 1; constant CFG_MMUEN : integer := 1; constant CFG_ITLBNUM : integer := 8; constant CFG_DTLBNUM : integer := 8; constant CFG_TLB_TYPE : integer := 0 + 12; constant CFG_TLB_REP : integer := 0; constant CFG_MMU_PAGE : integer := 0; constant CFG_DSU : integer := 1; constant CFG_ITBSZ : integer := 4; constant CFG_ATBSZ : integer := 4; constant CFG_LEON3FT_EN : integer := 0; constant CFG_IUFT_EN : integer := 0; constant CFG_FPUFT_EN : integer := 0; constant CFG_RF_ERRINJ : integer := 0; constant CFG_CACHE_FT_EN : integer := 0; constant CFG_CACHE_ERRINJ : integer := 0; constant CFG_LEON3_NETLIST: integer := 0; constant CFG_DISAS : integer := 0 + 0; constant CFG_PCLOW : integer := 2; -- AMBA settings constant CFG_DEFMST : integer := (0); constant CFG_RROBIN : integer := 1; constant CFG_SPLIT : integer := 0; constant CFG_FPNPEN : integer := 0; constant CFG_AHBIO : integer := 16#FFF#; constant CFG_APBADDR : integer := 16#800#; constant CFG_AHB_MON : integer := 0; constant CFG_AHB_MONERR : integer := 0; constant CFG_AHB_MONWAR : integer := 0; constant CFG_AHB_DTRACE : integer := 0; -- DSU UART constant CFG_AHB_UART : integer := 1; -- JTAG based DSU interface constant CFG_AHB_JTAG : integer := 1; -- Ethernet DSU constant CFG_DSU_ETH : integer := 1 + 0 + 0; constant CFG_ETH_BUF : integer := 2; constant CFG_ETH_IPM : integer := 16#C0A8#; constant CFG_ETH_IPL : integer := 16#0033#; constant CFG_ETH_ENM : integer := 16#020000#; constant CFG_ETH_ENL : integer := 16#000018#; -- LEON2 memory controller constant CFG_MCTRL_LEON2 : integer := 1; constant CFG_MCTRL_RAM8BIT : integer := 0; constant CFG_MCTRL_RAM16BIT : integer := 1; constant CFG_MCTRL_5CS : integer := 0; constant CFG_MCTRL_SDEN : integer := 0; constant CFG_MCTRL_SEPBUS : integer := 0; constant CFG_MCTRL_INVCLK : integer := 0; constant CFG_MCTRL_SD64 : integer := 0; constant CFG_MCTRL_PAGE : integer := 0 + 0; -- DDR controller constant CFG_DDRSP : integer := 1; constant CFG_DDRSP_INIT : integer := 1; constant CFG_DDRSP_FREQ : integer := (90); constant CFG_DDRSP_COL : integer := (10); constant CFG_DDRSP_SIZE : integer := (64); constant CFG_DDRSP_RSKEW : integer := (40); -- AHB ROM constant CFG_AHBROMEN : integer := 0; constant CFG_AHBROPIP : integer := 0; constant CFG_AHBRODDR : integer := 16#000#; constant CFG_ROMADDR : integer := 16#000#; constant CFG_ROMMASK : integer := 16#E00# + 16#000#; -- AHB RAM constant CFG_AHBRAMEN : integer := 0; constant CFG_AHBRSZ : integer := 1; constant CFG_AHBRADDR : integer := 16#A00#; constant CFG_AHBRPIPE : integer := 0; -- Gaisler Ethernet core constant CFG_GRETH : integer := 1; constant CFG_GRETH1G : integer := 0; constant CFG_ETH_FIFO : integer := 32; -- UART 1 constant CFG_UART1_ENABLE : integer := 1; constant CFG_UART1_FIFO : integer := 8; -- LEON3 interrupt controller constant CFG_IRQ3_ENABLE : integer := 1; constant CFG_IRQ3_NSEC : integer := 0; -- Modular timer constant CFG_GPT_ENABLE : integer := 1; constant CFG_GPT_NTIM : integer := (2); constant CFG_GPT_SW : integer := (8); constant CFG_GPT_TW : integer := (32); constant CFG_GPT_IRQ : integer := (8); constant CFG_GPT_SEPIRQ : integer := 1; constant CFG_GPT_WDOGEN : integer := 0; constant CFG_GPT_WDOG : integer := 16#0#; -- GPIO port constant CFG_GRGPIO_ENABLE : integer := 1; constant CFG_GRGPIO_IMASK : integer := 16#0000#; constant CFG_GRGPIO_WIDTH : integer := (8); -- VGA and PS2/ interface constant CFG_KBD_ENABLE : integer := 1; constant CFG_VGA_ENABLE : integer := 0; constant CFG_SVGA_ENABLE : integer := 1; -- GRLIB debugging constant CFG_DUART : integer := 0; end;	gpl-2.0	a5a7209b77fbbdef297ec7e87d04493c	0.643709	3.616766	false	false	false	false
marco-c/leon-nexys2	grlib-gpl-1.3.4-b4140/lib/gaisler/leon3v3/tbufmem.vhd	1	2,221	------------------------------------------------------------------------------ -- This file is a part of the GRLIB VHDL IP LIBRARY -- Copyright (C) 2003 - 2008, Gaisler Research -- Copyright (C) 2008 - 2013, Aeroflex Gaisler -- -- This program is free software; you can redistribute it and/or modify -- it under the terms of the GNU General Public License as published by -- the Free Software Foundation; either version 2 of the License, or -- (at your option) any later version. -- -- This program is distributed in the hope that it will be useful, -- but WITHOUT ANY WARRANTY; without even the implied warranty of -- MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the -- GNU General Public License for more details. -- -- You should have received a copy of the GNU General Public License -- along with this program; if not, write to the Free Software -- Foundation, Inc., 59 Temple Place, Suite 330, Boston, MA 02111-1307 USA ----------------------------------------------------------------------------- -- Entity: tbufmem -- File: tbufmem.vhd -- Author: Jiri Gaisler - Gaisler Research -- Description: 128-bit trace buffer memory (CPU/AHB) ------------------------------------------------------------------------------ library ieee; use ieee.std_logic_1164.all; library gaisler; use gaisler.leon3.all; library techmap; use techmap.gencomp.all; library grlib; use grlib.stdlib.all; entity tbufmem is generic ( tech : integer := 0; tbuf : integer := 0; -- trace buf size in kB (0 - no trace buffer) testen : integer := 0 ); port ( clk : in std_ulogic; di : in tracebuf_in_type; do : out tracebuf_out_type); end; architecture rtl of tbufmem is constant ADDRBITS : integer := 10 + log2(tbuf) - 4; signal enable : std_logic_vector(1 downto 0); begin enable <= di.enable & di.enable; mem0 : for i in 0 to 1 generate ram0 : syncram64 generic map (tech => tech, abits => addrbits, testen => testen) port map ( clk, di.addr(addrbits-1 downto 0), di.data(((i64)+63) downto (i64)), do.data(((i64)+63) downto (i64)), enable ,di.write(i2+1 downto i2), di.diag); end generate; end;	gpl-2.0	0df27dfc6a8b3c71ca624c6125a25f65	0.60018	3.973166	false	false	false	false
marco-c/leon-nexys2	grlib-gpl-1.3.4-b4140/designs/leon3-altera-c5ekit/memifsim.vhd	1	12,367	------------------------------------------------------------------------------ -- This file is a part of the GRLIB VHDL IP LIBRARY -- Copyright (C) 2003 - 2008, Gaisler Research -- Copyright (C) 2008 - 2013, Aeroflex Gaisler -- -- This program is free software; you can redistribute it and/or modify -- it under the terms of the GNU General Public License as published by -- the Free Software Foundation; either version 2 of the License, or -- (at your option) any later version. -- -- This program is distributed in the hope that it will be useful, -- but WITHOUT ANY WARRANTY; without even the implied warranty of -- MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the -- GNU General Public License for more details. -- -- You should have received a copy of the GNU General Public License -- along with this program; if not, write to the Free Software -- Foundation, Inc., 59 Temple Place, Suite 330, Boston, MA 02111-1307 USA use std.textio.all; library ieee; use ieee.std_logic_1164.all; library grlib; use grlib.stdlib.all; use grlib.stdio.all; entity ddr3ctrl1 is port ( pll_ref_clk : in std_logic; global_reset_n : in std_logic; soft_reset_n : in std_logic; afi_clk : out std_logic; afi_half_clk : out std_logic; afi_reset_n : out std_logic; afi_reset_export_n : out std_logic; mem_a : out std_logic_vector(13 downto 0); mem_ba : out std_logic_vector(2 downto 0); mem_ck : out std_logic_vector(0 downto 0); mem_ck_n : out std_logic_vector(0 downto 0); mem_cke : out std_logic_vector(0 downto 0); mem_cs_n : out std_logic_vector(0 downto 0); mem_dm : out std_logic_vector(3 downto 0); mem_ras_n : out std_logic_vector(0 downto 0); mem_cas_n : out std_logic_vector(0 downto 0); mem_we_n : out std_logic_vector(0 downto 0); mem_reset_n : out std_logic; mem_dq : inout std_logic_vector(31 downto 0); mem_dqs : inout std_logic_vector(3 downto 0); mem_dqs_n : inout std_logic_vector(3 downto 0); mem_odt : out std_logic_vector(0 downto 0); avl_ready : out std_logic; avl_burstbegin : in std_logic; avl_addr : in std_logic_vector(24 downto 0); avl_rdata_valid : out std_logic; avl_rdata : out std_logic_vector(127 downto 0); avl_wdata : in std_logic_vector(127 downto 0); avl_be : in std_logic_vector(15 downto 0); avl_read_req : in std_logic; avl_write_req : in std_logic; avl_size : in std_logic_vector(2 downto 0); local_init_done : out std_logic; local_cal_success : out std_logic; local_cal_fail : out std_logic; oct_rzqin : in std_logic; pll_mem_clk : out std_logic; pll_write_clk : out std_logic; pll_write_clk_pre_phy_clk : out std_logic; pll_addr_cmd_clk : out std_logic; pll_locked : out std_logic; pll_avl_clk : out std_logic; pll_config_clk : out std_logic; pll_mem_phy_clk : out std_logic; afi_phy_clk : out std_logic; pll_avl_phy_clk : out std_logic ); end; architecture sim of ddr3ctrl1 is signal lafi_clk, lafi_rst_n: std_ulogic; signal lafi_half_clk: std_ulogic; begin afi_clk <= lafi_clk; afi_half_clk <= lafi_half_clk; afi_reset_n <= lafi_rst_n; mem_a <= (others => '0'); mem_ba <= (others => '0'); mem_ck <= (others => '0'); mem_ck_n <= (others => '1'); mem_cke <= (others => '0'); mem_cs_n <= (others => '1'); mem_dm <= (others => '0'); mem_ras_n <= (others => '1'); mem_cas_n <= (others => '1'); mem_we_n <= (others => '1'); mem_reset_n <= '0'; mem_dq <= (others => 'Z'); mem_dqs <= (others => 'Z'); mem_dqs_n <= (others => 'Z'); mem_odt <= (others => '0'); avl_ready <= '1'; local_init_done <= '1'; local_cal_success <= '1'; local_cal_fail <= '0'; pll_mem_clk <= '0'; pll_write_clk <= '0'; pll_write_clk_pre_phy_clk <= '0'; pll_addr_cmd_clk <= '0'; pll_locked <= '1'; pll_avl_clk <= '0'; pll_config_clk <= '0'; pll_mem_phy_clk <= '0'; afi_phy_clk <= '0'; pll_avl_phy_clk <= '0'; clkproc: process begin lafi_clk <= '0'; lafi_half_clk <= '0'; loop wait for 3.3 ns; lafi_clk <= not lafi_clk; if lafi_clk='0' then lafi_half_clk <= not lafi_half_clk; end if; end loop; end process; rstproc: process begin lafi_rst_n <= '0'; wait for 10 ns; loop if global_reset_n='0' then lafi_rst_n <= '0'; wait until global_reset_n/='0'; wait until rising_edge(lafi_clk); end if; lafi_rst_n <= '1'; wait until global_reset_n='0'; end loop; end process; avlproc: process subtype BYTE is std_logic_vector(7 downto 0); type MEM is array(0 to ((2*20)-1)) of BYTE; variable MEMA: MEM; procedure load_srec is file TCF : text open read_mode is "ram.srec"; variable L1: line; variable CH: character; variable ai: integer; variable rectype: std_logic_vector(3 downto 0); variable recaddr: std_logic_vector(31 downto 0); variable reclen: std_logic_vector(7 downto 0); variable recdata: std_logic_vector(0 to 168-1); variable len: integer; begin L1:= new string'(""); --' while not endfile(TCF) loop readline(TCF,L1); if (L1'length /= 0) then --' while (not (L1'length=0)) and (L1(L1'left) = ' ') loop std.textio.read(L1,CH); end loop; if L1'length > 0 then --' read(L1, ch); if (ch = 'S') or (ch = 's') then hread(L1, rectype); hread(L1, reclen); len := conv_integer(reclen)-1; recaddr := (others => '0'); case rectype is when "0001" => hread(L1, recaddr(15 downto 0)); len := len-2; when "0010" => hread(L1, recaddr(23 downto 0)); len := len-3; when "0011" => hread(L1, recaddr); len := len-4; when others => next; end case; hread(L1, recdata(0 to 8len-1)); recaddr(31 downto 20) := (others => '0'); ai := conv_integer(recaddr); -- print("Setting " & tost(len) & "bytes at " & tost(recaddr)); for i in 0 to len-1 loop MEMA(ai+i) := recdata((i8) to (i8+7)); end loop; end if; end if; end if; end loop; end load_srec; constant avldbits: integer := 128; variable outqueue: std_logic_vector(0 to 4avldbits-1) := (others => 'X'); variable outqueue_valid: std_logic_vector(0 to 3) := (others => '0'); variable ai,p: integer; variable wbleft: integer := 0; begin load_srec; loop wait until rising_edge(lafi_clk); avl_rdata_valid <= outqueue_valid(0); avl_rdata <= outqueue(0 to avldbits-1); outqueue(0 to 3avldbits-1) := outqueue(avldbits to 4avldbits-1); outqueue(3avldbits to 4avldbits-1) := (others => 'X'); outqueue_valid := outqueue_valid(1 to 3) & '0'; if avl_burstbegin='1' then wbleft:=0; end if; if lafi_rst_n='0' then outqueue_valid := (others => '0'); elsif avl_read_req='1' then ai := conv_integer(avl_addr(16 downto 0)); p := 0; while outqueue_valid(p)='1' loop p:=p+1; end loop; for x in 0 to conv_integer(avl_size)-1 loop for y in 0 to avldbits/8-1 loop outqueue((p+x)avldbits+y8 to (p+x)avldbits+y8+7) := MEMA((ai+x)avldbits/8+y); end loop; outqueue_valid(p+x) := '1'; end loop; elsif avl_write_req='1' then if wbleft=0 then wbleft := conv_integer(avl_size); ai := conv_integer(avl_addr(16 downto 0)); end if; for y in 0 to avldbits/8-1 loop if avl_be(avldbits/8-1-y)='1' then MEMA(aiavldbits/8+y) := avl_wdata(avldbits-8y-1 downto avldbits-8y-8); end if; end loop; wbleft := wbleft-1; ai := ai+1; end if; end loop; end process; end; library ieee; use ieee.std_logic_1164.all; entity lpddr2ctrl1 is port ( pll_ref_clk : in std_logic; global_reset_n : in std_logic; soft_reset_n : in std_logic; afi_clk : out std_logic; afi_half_clk : out std_logic; afi_reset_n : out std_logic; afi_reset_export_n : out std_logic; mem_ca : out std_logic_vector(9 downto 0); mem_ck : out std_logic_vector(0 downto 0); mem_ck_n : out std_logic_vector(0 downto 0); mem_cke : out std_logic_vector(0 downto 0); mem_cs_n : out std_logic_vector(0 downto 0); mem_dm : out std_logic_vector(1 downto 0); mem_dq : inout std_logic_vector(15 downto 0); mem_dqs : inout std_logic_vector(1 downto 0); mem_dqs_n : inout std_logic_vector(1 downto 0); avl_ready : out std_logic; avl_burstbegin : in std_logic; avl_addr : in std_logic_vector(24 downto 0); avl_rdata_valid : out std_logic; avl_rdata : out std_logic_vector(63 downto 0); avl_wdata : in std_logic_vector(63 downto 0); avl_be : in std_logic_vector(7 downto 0); avl_read_req : in std_logic; avl_write_req : in std_logic; avl_size : in std_logic_vector(2 downto 0); local_init_done : out std_logic; local_cal_success : out std_logic; local_cal_fail : out std_logic; oct_rzqin : in std_logic; pll_mem_clk : out std_logic; pll_write_clk : out std_logic; pll_write_clk_pre_phy_clk : out std_logic; pll_addr_cmd_clk : out std_logic; pll_locked : out std_logic; pll_avl_clk : out std_logic; pll_config_clk : out std_logic; pll_mem_phy_clk : out std_logic; afi_phy_clk : out std_logic; pll_avl_phy_clk : out std_logic ); end; architecture sim of lpddr2ctrl1 is signal lafi_clk: std_ulogic; begin afi_clk <= lafi_clk; afi_reset_n <= '0'; afi_reset_export_n <= '0'; mem_ca <= (others => '0'); mem_ck <= (others => '0'); mem_ck_n <= (others => '1'); mem_cke <= (others => '0'); mem_cs_n <= (others => '1'); mem_dm <= (others => '0'); mem_dq <= (others => 'Z'); mem_dqs <= (others => 'Z'); mem_dqs_n <= (others => 'Z'); avl_ready <= '1'; avl_rdata_valid <= '1'; avl_rdata <= (others => '0'); local_init_done <= '1'; local_cal_success <= '1'; local_cal_fail <= '0'; pll_mem_clk <= '0'; pll_write_clk <= '0'; pll_write_clk_pre_phy_clk <= '0'; pll_addr_cmd_clk <= '0'; pll_locked <= '1'; pll_avl_clk <= '0'; pll_config_clk <= '0'; pll_mem_phy_clk <= '0'; afi_phy_clk <= '0'; pll_avl_phy_clk <= '0'; clkproc: process variable vclk,vhclk: std_logic := '0'; begin lafi_clk <= vclk; afi_half_clk <= vhclk; wait for 4 ns; vclk := not vclk; if vclk='0' then vhclk:=not vhclk; end if; end process; rstproc: process begin afi_reset_n <= '0'; for x in 1 to 10 loop wait until rising_edge(lafi_clk); end loop; afi_reset_n <= '1'; wait; end process; end;	gpl-2.0	29bcd84323267e4f7a26e062a0a960fa	0.508612	3.33073	false	false	false	false
marco-c/leon-nexys2	grlib-gpl-1.3.4-b4140/lib/hynix/ddr2/HY5PS121621F_PACK.vhd	3	17,071	------------------------------------------------------ -- Hynix 4BANKS X 8M X 16bits DDR2 SDRAM -- -- -- -- Packages for HY5PS121621F.vhd -- -- -- -- HHHH HHHH -- -- HHHH HHHH -- -- ,O0O. ,O0 .HH ,O0 .HH -- -- (O000O)(000 )H(000 )H Hynix -- -- `O0O' `O0 'HH `O0 'HH -- -- HHHH HHHH Semiconductor -- -- HHHH HHHH -- ------------------------------------------------------ --------------------------------------------------------------------------------------------------------- LIBRARY IEEE; USE IEEE.STD_LOGIC_1164.all; library grlib; use grlib.stdlib.all; --USE IEEE.STD_LOGIC_ARITH.all; --USE IEEE.STD_LOGIC_UNSIGNED.all; --------------------------------------------------------------------------------------------------- package HY5PS121621F_PACK is --------------------------------------------------------------------------------------------------- constant NUM_OF_MROPCODE : integer := 13; constant NUM_OF_ROW_ADD : integer := 13; constant NUM_OF_COL_ADD : integer := 10; constant NUM_OF_BANK_ADD : integer := 2; constant WORD_SIZE : integer := 16; constant NUM_OF_ROWS : integer := 2NUM_OF_ROW_ADD; constant NUM_OF_COLS : integer := 2NUM_OF_COL_ADD; constant NUM_OF_BANKS : integer := 2**NUM_OF_BANK_ADD; constant NUM_OF_BUFFERS : integer := 3; type PART_NUM_TYPE is (B400, B533, B667, B800); type PART_NUM is array (B400 to B800) of time; constant tCKmin : PART_NUM := (B400 => 5 ns, B533 => 3.75 ns, B667 => 3 ns, B800 => 2.5 ns); constant tCKmax : PART_NUM := (B400 => 8 ns, B533 => 8 ns, B667 => 8 ns, B800 => 8 ns); constant tWR : PART_NUM := (B400 => 15 ns, B533 => 15 ns, B667 => 15 ns, B800 => 15 ns); constant tDS : PART_NUM := (B400 => 0.4 ns, B533 => 0.35 ns, B667 => 0.3 ns, B800 => 0.3 ns); constant tDH : PART_NUM := (B400 => 0.4 ns, B533 => 0.35 ns, B667 => 0.3 ns, B800 => 0.3 ns); constant tIS : PART_NUM := (B400 => 0.6 ns, B533 => 0.5 ns, B667 => 0.5 ns, B800 => 0.4 ns); constant tIH : PART_NUM := (B400 => 0.6 ns, B533 => 0.5 ns, B667 => 0.5 ns, B800 => 0.4 ns); constant tWTR : PART_NUM := (B400 => 10 ns, B533 => 7.5 ns, B667 => 7.5 ns, B800 => 7.5 ns); constant tRASmax : PART_NUM := (B400 => 70000 ns, B533 => 70000 ns, B667 => 70000 ns, B800 => 70000 ns); constant tRRD : time := 10 ns; constant tREF : time := 64 ms; constant tRFC : time := 75 ns; constant tRTP : time := 7.5 ns; constant tXSNR : time := tRFC + 10 ns; constant tXP : integer := 2; constant tCKE : integer := 3; constant tXARD : integer := 2; constant tXARDS : integer := 2; constant tXSRD : integer := 200; constant tPUS : time := 200 us; type STATE_TYPE is ( PWRDN, PWRUP, SLFREF, IDLE, RACT, READ, WRITE); type COMMAND_TYPE is ( DSEL, NOP, MRS, EMRS1, EMRS2, EMRS3, ACT, RD, RDAP, WR, WRAP, PCG, PCGA, AREF, SREF, SREX, PDEN, PDEX, ERROR, ILLEGAL); type BURST_MODE_TYPE is ( SEQUENTIAL, INTERLEAVE); type OCD_DRIVE_MODE_TYPE is ( CAL_EXIT, DRIVE1, DRIVE0, ADJUST, CAL_DEFAULT); subtype CL_TYPE is integer range 0 to 6; subtype BL_TYPE is integer range 4 to 8; subtype TWR_TYPE is integer range 2 to 6; type DLL_RST is ( RST, NORST); type MODE_REGISTER is record CAS_LATENCY : CL_TYPE; BURST_MODE : BURST_MODE_TYPE; BURST_LENGTH : BL_TYPE; DLL_STATE : DLL_RST; SAPD : std_logic; TWR : TWR_TYPE; end record; type EMR_TYPE is record DLL_EN : std_logic; AL : CL_TYPE; QOFF : std_logic; DQSB_ENB : std_logic; RDQS_EN : std_logic; OCD_PGM : OCD_DRIVE_MODE_TYPE; end record; type EMR2_TYPE is record SREF_HOT : std_logic; end record; type REF_CHECK is array (0 to (NUM_OF_BANKS - 1), 0 to (NUM_OF_ROWS - 1)) of time; type COL_ADDR_TYPE is array (0 to 3) of std_logic_vector((NUM_OF_COL_ADD - 1) downto 0); type DATA_BUFFER_TYPE is array (0 to 6) of std_logic_vector(8 downto 0); subtype COL_DATA_TYPE is integer range 0 to 65535; type SA_TYPE is array (0 to (NUM_OF_COLS - 1)) of COL_DATA_TYPE; type ROW_DATA_TYPE is array (0 to (NUM_OF_COLS - 1)) of COL_DATA_TYPE; type RAM_PNTR is ACCESS ROW_DATA_TYPE; type SA_ARRAY_TYPE is array (0 to (NUM_OF_BANKS - 1)) of SA_TYPE; type MEM_CELL_TYPE is array (0 to (NUM_OF_ROWS - 1)) of RAM_PNTR; subtype DATA_TYPE is std_logic_vector ((WORD_SIZE - 1) downto 0); type BUFFER_TYPE is array (0 to NUM_OF_BUFFERS - 1, 0 to 3) of DATA_TYPE; type ADD_PIPE_TYPE is array (0 to 12) of std_logic_vector((NUM_OF_COL_ADD + NUM_OF_BANK_ADD - 1) downto 0); type CKE_TYPE is array (integer range -1 to 0) of std_logic; subtype MROPCODE_TYPE is std_logic_vector ((NUM_OF_MROPCODE - 1) downto 0); procedure COMMAND_DECODE ( variable CSB, RASB, CASB, WEB, A10 : in std_logic; variable Bank_Add : in std_logic_vector((NUM_OF_BANK_ADD - 1) downto 0); variable CKE : in CKE_TYPE; variable COMMAND : out COMMAND_TYPE; variable BankState : in std_logic_vector((NUM_OF_BANKS - 1) downto 0); variable State : in STATE_TYPE); procedure MODE_REGISTER_SET ( MROPCODE : in MROPCODE_TYPE; MR : out MODE_REGISTER); procedure EXT_MODE_REGISTER_SET ( MROPCODE : in MROPCODE_TYPE; EMR : out EMR_TYPE); procedure EXT_MODE_REGISTER_SET2 ( MROPCODE : in MROPCODE_TYPE; EMR : out EMR2_TYPE); function REMAINDER ( val0 : in integer; val1 : in integer) return integer; function XOR_FUNC ( val0 : in std_logic_vector; val1 : in std_logic_vector) return std_logic_vector; function CHAR_TO_STD_LOGIC ( c : in character) return std_logic; function STD_LOGIC_TO_BIT (V: STD_LOGIC) return BIT; end HY5PS121621F_PACK; ------------------------------------------------------HY5DU121622T Package --------------------------------------------------------------------------------------------------- package body HY5PS121621F_PACK is --------------------------------------------------------------------------------------------------- procedure COMMAND_DECODE ( variable CSB, RASB, CASB, WEB, A10 : in std_logic; variable Bank_Add : in std_logic_vector((NUM_OF_BANK_ADD - 1) downto 0); variable CKE : in CKE_TYPE; variable COMMAND : out COMMAND_TYPE; variable BankState : in std_logic_vector((NUM_OF_BANKS - 1) downto 0); variable State : in STATE_TYPE) Is begin case CKE (-1) is when '1' => case CKE (0) is when '0' => if (BankState = "0000") then if (CSB = '0' and RASB = '0' and CASB = '0' and WEB = '1') then COMMAND := SREF; elsif ((CSB = '1') or (CSB = '0' and RASB = '1' and CASB = '1' and WEB = '1')) then COMMAND := PDEN; else COMMAND := ILLEGAL; end if; elsif ((CSB = '1') or (CSB = '0' and RASB = '1' and CASB = '1' and WEB = '1')) then COMMAND := PDEN; else COMMAND := ILLEGAL; end if; when '1' => if (CSB = '1') then COMMAND := DSEL; elsif (CSB = '0' and RASB = '1' and CASB = '1' and WEB ='1') then COMMAND := NOP; elsif (CSB = '0' and RASB = '1' and CASB = '0' and WEB ='1') then if (A10 = '0') then COMMAND := RD; else COMMAND := RDAP; end if; elsif (CSB = '0' and RASB = '1' and CASB = '0' and WEB ='0') then if (A10 = '0') then COMMAND := WR; else COMMAND := WRAP; end if; elsif (CSB = '0' and RASB = '0' and CASB = '1' and WEB ='1') then COMMAND := ACT; elsif (CSB = '0' and RASB = '0' and CASB = '1' and WEB ='0') then if (A10 = '0') then COMMAND := PCG; else COMMAND := PCGA; end if; elsif (CSB = '0' and RASB = '0' and CASB = '0' and WEB ='1') then COMMAND := AREF; elsif (CSB = '0' and RASB = '0' and CASB = '0' and WEB ='0') then if (BankState = "0000") then if (Bank_Add = "00") then COMMAND := MRS; elsif (Bank_Add = "01") then COMMAND := EMRS1; elsif (Bank_Add = "10") then COMMAND := EMRS2; elsif (Bank_Add = "11") then COMMAND := EMRS3; end if; else COMMAND := ILLEGAL; end if; end if; when others => COMMAND := ERROR; end case; when '0' => case CKE (0) is when '0' => COMMAND := NOP; when '1' => if (State = PWRUP) then COMMAND := NOP; elsif (CSB = '1') then if (State = SLFREF) then COMMAND := SREX; elsif (State = PWRDN) then COMMAND := PDEX; end if; elsif (CSB = '0' and RASB = '1' and CASB = '1' and WEB ='1') then if (State = SLFREF) then COMMAND := SREX; elsif (State = PWRDN) then COMMAND := PDEX; end if; else COMMAND := ERROR; end if; when others => COMMAND := ERROR; end case; when others => COMMAND := ERROR; end case; end COMMAND_DECODE; ------------------------------------------------------------------------------------------------ procedure MODE_REGISTER_SET ( MROPCODE : in MROPCODE_TYPE; MR : out MODE_REGISTER) is begin if (MROPCODE(6) = '0' and MROPCODE(5) = '1' and MROPCODE(4) = '0')then MR.CAS_LATENCY := 2; elsif (MROPCODE(6) = '0' and MROPCODE(5) = '1' and MROPCODE(4) = '1')then MR.CAS_LATENCY := 3; elsif (MROPCODE(6) = '1' and MROPCODE(5) = '0' and MROPCODE(4) = '0')then MR.CAS_LATENCY := 4; elsif (MROPCODE(6) = '1' and MROPCODE(5) = '0' and MROPCODE(4) = '1')then MR.CAS_LATENCY := 5; elsif (MROPCODE(6) = '1' and MROPCODE(5) = '1' and MROPCODE(4) = '0')then MR.CAS_LATENCY := 6; else assert false report "ERROR : (MODE_REGISTER_SET_PROCEDURE) : Invalid Cas_Latency Encountered!" severity WARNING; end if; if MROPCODE(3) = '0' then MR.BURST_MODE := SEQUENTIAL; elsif MROPCODE(3) = '1' then MR.BURST_MODE := INTERLEAVE; end if; if MROPCODE(8) = '0' then MR.DLL_STATE := NORST; elsif MROPCODE(8) = '1' then MR.DLL_STATE := RST; end if; if MROPCODE(2) = '0' and MROPCODE(1) = '1' and MROPCODE(0) = '0' then MR.BURST_LENGTH := 4; elsif MROPCODE(2) = '0' and MROPCODE(1) = '1' and MROPCODE(0) = '1' then MR.BURST_LENGTH := 8; else assert false report "ERROR : (MODE_REGISTER_SET_PROCEDURE) : Invalid Burst_Length Encountered!" severity ERROR; end if; if MROPCODE(12) = '0' then MR.SAPD := '0'; elsif MROPCODE(12) = '1' then MR.SAPD := '1'; end if; if MROPCODE(11) = '0' and MROPCODE(10) = '0' and MROPCODE(9) = '1' then MR.TWR := 2; elsif MROPCODE(11) = '0' and MROPCODE(10) = '1' and MROPCODE(9) = '0' then MR.TWR := 3; elsif MROPCODE(11) = '0' and MROPCODE(10) = '1' and MROPCODE(9) = '1' then MR.TWR := 4; elsif MROPCODE(11) = '1' and MROPCODE(10) = '0' and MROPCODE(9) = '0' then MR.TWR := 5; elsif MROPCODE(11) = '1' and MROPCODE(10) = '0' and MROPCODE(9) = '1' then MR.TWR := 6; else assert false report "ERROR : (MODE_REGISTER_SET_PROCEDURE) : Invalid Write Recovery Value Encountered!" severity ERROR; end if; end MODE_REGISTER_SET; ------------------------------------------------------------------------------------------------ procedure EXT_MODE_REGISTER_SET ( MROPCODE : in MROPCODE_TYPE; EMR : out EMR_TYPE) is begin if (MROPCODE(0) = '0') then EMR.DLL_EN := '1'; elsif (MROPCODE(0) = '1') then EMR.DLL_EN := '0'; end if; if (MROPCODE(5) = '0' and MROPCODE(4) = '0' and MROPCODE(3) = '0')then EMR.AL := 0; elsif (MROPCODE(5) = '0' and MROPCODE(4) = '0' and MROPCODE(3) = '1')then EMR.AL := 1; elsif (MROPCODE(5) = '0' and MROPCODE(4) = '1' and MROPCODE(3) = '0')then EMR.AL := 2; elsif (MROPCODE(5) = '0' and MROPCODE(4) = '1' and MROPCODE(3) = '1')then EMR.AL := 3; elsif (MROPCODE(5) = '1' and MROPCODE(4) = '0' and MROPCODE(3) = '0')then EMR.AL := 4; elsif (MROPCODE(5) = '1' and MROPCODE(4) = '0' and MROPCODE(3) = '1')then EMR.AL := 5; else assert false report "ERROR : (EXT_MODE_REGISTER_SET_PROCEDURE) : Invalid Additive_Latency Encountered!" severity WARNING; end if; if MROPCODE(12) = '0' then EMR.QOFF := '0'; elsif MROPCODE(12) = '1' then EMR.QOFF := '1'; end if; if MROPCODE(10) = '0' then EMR.DQSB_ENB := '0'; elsif MROPCODE(10) = '1' then EMR.DQSB_ENB := '1'; end if; if MROPCODE(11) = '0' then EMR.RDQS_EN := '0'; elsif MROPCODE(11) = '1' then EMR.RDQS_EN := '1'; end if; if MROPCODE(9) = '0' and MROPCODE(8) = '0' and MROPCODE(7) = '0' then EMR.OCD_PGM := CAL_EXIT; elsif MROPCODE(9) = '0' and MROPCODE(8) = '0' and MROPCODE(7) = '1' then EMR.OCD_PGM := DRIVE1; elsif MROPCODE(9) = '0' and MROPCODE(8) = '1' and MROPCODE(7) = '0' then EMR.OCD_PGM := DRIVE0; elsif MROPCODE(9) = '1' and MROPCODE(8) = '0' and MROPCODE(7) = '0' then EMR.OCD_PGM := ADJUST; elsif MROPCODE(9) = '1' and MROPCODE(8) = '1' and MROPCODE(7) = '1' then EMR.OCD_PGM := CAL_DEFAULT; else assert false report "ERROR : (EXT_MODE_REGISTER_SET_PROCEDURE) : Invalid OCD Calibration Program Encountered!" severity ERROR; end if; end EXT_MODE_REGISTER_SET; ------------------------------------------------------------------------------------------------ procedure EXT_MODE_REGISTER_SET2 ( MROPCODE : in MROPCODE_TYPE; EMR : out EMR2_TYPE) is begin if (MROPCODE(7) = '0') then EMR.SREF_HOT := '0'; elsif (MROPCODE(7) = '1') then EMR.SREF_HOT := '1'; end if; end EXT_MODE_REGISTER_SET2; ------------------------------------------------------------------------------------------------ function REMAINDER (val0 : in integer; val1 : in integer) return integer is variable Result : integer; begin Result := val0; loop exit when Result < val1; Result := Result - val1; end loop; return Result; end REMAINDER; ------------------------------------------------------------------------------------------------ function XOR_FUNC (val0 : in std_logic_vector; val1 : in std_logic_vector) return std_logic_vector is variable Result : std_logic_vector(2 downto 0); variable j : integer := 0; begin for i in val0'RANGE LOOP if (val0(i) /= val1(i)) then Result(i) := '1'; else Result(i) := '0'; end if; j := j + 1; end loop; return Result((j - 1) downto 0); end XOR_FUNC; ------------------------------------------------------------------------------------------------ function CHAR_TO_STD_LOGIC ( c : in character) return std_logic is variable r : std_logic; begin case c is when '0' => r := '0'; when 'L' => r := 'L'; when '1' => r := '1'; when 'H' => r := 'H'; when 'W' => r := 'W'; when 'Z' => r := 'Z'; when 'U' => r := 'U'; when '-' => r := '-'; when others => r := 'X'; end case; return r; end CHAR_TO_STD_LOGIC; ------------------------------------------------------------------------------------------------ function STD_LOGIC_TO_BIT (V: STD_LOGIC) return BIT is variable Result: BIT; begin case V is when '0' \| 'L' => Result := '0'; when '1' \| 'H' => Result := '1'; when 'X' \| 'W' \| 'Z' \| 'U' \| '-' => Result := '0'; end case; return Result; end STD_LOGIC_TO_BIT; ------------------------------------------------------------------------------------------------ end HY5PS121621F_PACK;	gpl-2.0	138eca33ee86695e85a1e489d7a18d85	0.47402	3.39789	false	false	false	false
marco-c/leon-nexys2	grlib-gpl-1.3.4-b4140/lib/gaisler/misc/ahbtrace.vhd	1	2,278	------------------------------------------------------------------------------ -- This file is a part of the GRLIB VHDL IP LIBRARY -- Copyright (C) 2003 - 2008, Gaisler Research -- Copyright (C) 2008 - 2013, Aeroflex Gaisler -- -- This program is free software; you can redistribute it and/or modify -- it under the terms of the GNU General Public License as published by -- the Free Software Foundation; either version 2 of the License, or -- (at your option) any later version. -- -- This program is distributed in the hope that it will be useful, -- but WITHOUT ANY WARRANTY; without even the implied warranty of -- MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the -- GNU General Public License for more details. -- -- You should have received a copy of the GNU General Public License -- along with this program; if not, write to the Free Software -- Foundation, Inc., 59 Temple Place, Suite 330, Boston, MA 02111-1307 USA ----------------------------------------------------------------------------- -- Entity: ahbtrace -- File: ahbtrace.vhd -- Author: Jiri Gaisler - Gaisler Research -- Description: AHB trace unit ------------------------------------------------------------------------------ library ieee; use ieee.std_logic_1164.all; library grlib; use grlib.amba.all; use grlib.stdlib.all; use grlib.devices.all; library techmap; use techmap.gencomp.all; library gaisler; use gaisler.misc.all; entity ahbtrace is generic ( hindex : integer := 0; ioaddr : integer := 16#000#; iomask : integer := 16#E00#; tech : integer := DEFMEMTECH; irq : integer := 0; kbytes : integer := 1; ahbfilt : integer := 0); port ( rst : in std_ulogic; clk : in std_ulogic; ahbmi : in ahb_mst_in_type; ahbsi : in ahb_slv_in_type; ahbso : out ahb_slv_out_type ); end; architecture rtl of ahbtrace is begin ahbt0 : ahbtrace_mb generic map ( hindex => hindex, ioaddr => ioaddr, iomask => iomask, tech => tech, irq => irq, kbytes => kbytes, ahbfilt => ahbfilt) port map( rst => rst, clk => clk, ahbsi => ahbsi, ahbso => ahbso, tahbmi => ahbmi, tahbsi => ahbsi); end;	gpl-2.0	6e61c17c4f52932fb8e0ccd989e77b2f	0.575505	4.017637	false	false	false	false
marco-c/leon-nexys2	grlib-gpl-1.3.4-b4140/lib/techmap/unisim/buffer_unisim.vhd	1	2,757	------------------------------------------------------------------------------ -- This file is a part of the GRLIB VHDL IP LIBRARY -- Copyright (C) 2003 - 2008, Gaisler Research -- Copyright (C) 2008 - 2013, Aeroflex Gaisler -- -- This program is free software; you can redistribute it and/or modify -- it under the terms of the GNU General Public License as published by -- the Free Software Foundation; either version 2 of the License, or -- (at your option) any later version. -- -- This program is distributed in the hope that it will be useful, -- but WITHOUT ANY WARRANTY; without even the implied warranty of -- MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the -- GNU General Public License for more details. -- -- You should have received a copy of the GNU General Public License -- along with this program; if not, write to the Free Software -- Foundation, Inc., 59 Temple Place, Suite 330, Boston, MA 02111-1307 USA ----------------------------------------------------------------------------- -- Entity: clkbuf_xilinx -- File: clkbuf_xilinx.vhd -- Author: Marko Isomaki, Jiri GAisler - Gaisler Research -- Description: Clock buffer generator for Xilinx devices ------------------------------------------------------------------------------ library ieee; use ieee.std_logic_1164.all; -- pragma translate_off library unisim; use unisim.BUFGMUX; use unisim.BUFG; -- pragma translate_on entity clkbuf_xilinx is generic( buftype : integer range 0 to 3 := 0); port( i : in std_ulogic; o : out std_ulogic ); end entity; architecture rtl of clkbuf_xilinx is component BUFGMUX port (O : out std_logic; I0, I1, S : in std_logic); end component; component BUFG port (O : out std_logic; I : in std_logic); end component; signal gnd : std_ulogic; signal x : std_ulogic; attribute syn_noclockbuf : boolean; attribute syn_noclockbuf of x : signal is true; begin gnd <= '0'; buf0 : if (buftype = 0) or (buftype > 2) generate x <= i; o <= x; end generate; buf1 : if buftype = 1 generate buf : bufgmux port map(S => gnd, I0 => i, I1 => gnd, O => o); end generate; buf2 : if (buftype = 2) generate buf : bufg port map(I => i, O => o); end generate; end architecture; library ieee; use ieee.std_logic_1164.all; -- pragma translate_off library unisim; use unisim.BUFGMUX; -- pragma translate_on entity clkmux_xilinx is port( i0, i1 : in std_ulogic; sel : in std_ulogic; o : out std_ulogic ); end entity; architecture rtl of clkmux_xilinx is component BUFGMUX port (O : out std_logic; I0, I1, S : in std_logic); end component; begin buf : bufgmux port map(S => sel, I0 => i0, I1 => i1, O => o); end architecture;	gpl-2.0	d2d54c9febd1b3ec4ac322915e6c5d79	0.620239	3.75102	false	false	false	false
marco-c/leon-nexys2	grlib-gpl-1.3.4-b4140/lib/gaisler/gr1553b/simtrans1553.vhd	1	3,690	------------------------------------------------------------------------------ -- This file is a part of the GRLIB VHDL IP LIBRARY -- Copyright (C) 2003 - 2008, Gaisler Research -- Copyright (C) 2008 - 2013, Aeroflex Gaisler -- -- This program is free software; you can redistribute it and/or modify -- it under the terms of the GNU General Public License as published by -- the Free Software Foundation; either version 2 of the License, or -- (at your option) any later version. -- -- This program is distributed in the hope that it will be useful, -- but WITHOUT ANY WARRANTY; without even the implied warranty of -- MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the -- GNU General Public License for more details. -- -- You should have received a copy of the GNU General Public License -- along with this program; if not, write to the Free Software -- Foundation, Inc., 59 Temple Place, Suite 330, Boston, MA 02111-1307 USA ----------------------------------------------------------------------------- -- Entity: simtrans1553 -- File: simtrans1553.vhd -- Author: Magnus Hjorth - Aeroflex Gaisler -- Description: 1553 Transceiver simulation model ------------------------------------------------------------------------------ library ieee; use ieee.std_logic_1164.all; library gaisler; use gaisler.gr1553b_pkg.all; entity simtrans1553_single is generic ( txdelay: time := 200 ns; rxdelay: time := 450 ns ); port ( buswire: inout wire1553; rxen: in std_logic; txin: in std_logic; txP: in std_logic; txN: in std_logic; rxP: out std_logic; rxN: out std_logic ); end; architecture b of simtrans1553_single is signal bw_rxd, bw_txd: wire1553; begin bw_rxd <= transport buswire after rxdelay; buswire <= bw_txd after txdelay; rxpr: process(bw_rxd,rxen) variable p,n: std_ulogic; begin p:='U'; n:='U'; case rxen is when '0' => p:='0'; n:='0'; when '1' => case bw_rxd is when 'U' => null; when 'X' => p := 'X'; n := 'X'; when '0' => p := '0'; n := '0'; when '+' => p := '1'; n := '0'; when '-' => p := '0'; n := '1'; end case; when 'X' => p:='X'; n:='X'; when others => null; end case; rxP <= p; rxN <= n; end process; txpr: process(txin, txP, txN) variable w: wire1553; begin w := 'U'; if txin='1' or (txP='0' and txN='0') or (txP='1' and txN='1') then w := '0'; elsif txin='0' and txP='1' and txN='0' then w := '+'; elsif txin='0' and txP='0' and txN='1' then w := '-'; elsif txin='X' or txP='X' or txN='X' then w := 'X'; elsif txin='U' or (txP='U' and txN='U') then w := 'U'; else w := 'X'; end if; bw_txd <= w; end process; end; library ieee; use ieee.std_logic_1164.all; library gaisler; use gaisler.gr1553b_pkg.all; entity simtrans1553 is generic ( txdelay: time := 200 ns; rxdelay: time := 450 ns ); port ( busA: inout wire1553; busB: inout wire1553; rxenA: in std_logic; txinA: in std_logic; txAP: in std_logic; txAN: in std_logic; rxAP: out std_logic; rxAN: out std_logic; rxenB: in std_logic; txinB: in std_logic; txBP: in std_logic; txBN: in std_logic; rxBP: out std_logic; rxBN: out std_logic ); end; architecture s of simtrans1553 is begin at: simtrans1553_single generic map (txdelay,rxdelay) port map (busA,rxenA,txinA,txAP,txAN,rxAP,rxAN); bt: simtrans1553_single generic map (txdelay,rxdelay) port map (busB,rxenB,txinB,txBP,txBN,rxBP,rxBN); end;	gpl-2.0	5592a9d1493f2217edde1d134690819c	0.561789	3.419833	false	false	false	false
marco-c/leon-nexys2	grlib-gpl-1.3.4-b4140/lib/techmap/unisim/clkgen_unisim.vhd	1	18,422	------------------------------------------------------------------------------ -- This file is a part of the GRLIB VHDL IP LIBRARY -- Copyright (C) 2003 - 2008, Gaisler Research -- Copyright (C) 2008 - 2013, Aeroflex Gaisler -- -- This program is free software; you can redistribute it and/or modify -- it under the terms of the GNU General Public License as published by -- the Free Software Foundation; either version 2 of the License, or -- (at your option) any later version. -- -- This program is distributed in the hope that it will be useful, -- but WITHOUT ANY WARRANTY; without even the implied warranty of -- MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the -- GNU General Public License for more details. -- -- You should have received a copy of the GNU General Public License -- along with this program; if not, write to the Free Software -- Foundation, Inc., 59 Temple Place, Suite 330, Boston, MA 02111-1307 USA ----------------------------------------------------------------------------- -- Entity: various -- File: clkgen_xilinx.vhd -- Author: Jiri Gaisler, Gaisler Research -- Author: Richard Pender, Pender Electronic Design -- Description: Clock generators for Virtex and Virtex-2 fpgas ------------------------------------------------------------------------------ ------------------------------------------------------------------ -- Virtex5 clock generator --------------------------------------- ------------------------------------------------------------------ library ieee; use ieee.std_logic_1164.all; -- pragma translate_off library grlib; use grlib.stdlib.all; library unisim; use unisim.BUFG; use unisim.DCM; --use unisim.BUFGDLL; use unisim.BUFGMUX; -- pragma translate_on library techmap; use techmap.gencomp.all; entity clkgen_virtex5 is generic ( clk_mul : integer := 1; clk_div : integer := 1; sdramen : integer := 0; noclkfb : integer := 0; pcien : integer := 0; pcidll : integer := 0; pcisysclk: integer := 0; freq : integer := 25000; -- clock frequency in KHz clk2xen : integer := 0; clksel : integer := 0); -- enable clock select port ( clkin : in std_ulogic; pciclkin: in std_ulogic; clk : out std_ulogic; -- main clock clkn : out std_ulogic; -- inverted main clock clk2x : out std_ulogic; -- double clock sdclk : out std_ulogic; -- SDRAM clock pciclk : out std_ulogic; -- PCI clock cgi : in clkgen_in_type; cgo : out clkgen_out_type; clk1xu : out std_ulogic; -- unscaled clock clk2xu : out std_ulogic -- unscaled 2X clock ); end; architecture struct of clkgen_virtex5 is component BUFG port (O : out std_logic; I : in std_logic); end component; component BUFGMUX port ( O : out std_ulogic; I0 : in std_ulogic; I1 : in std_ulogic; S : in std_ulogic); end component; component DCM generic ( CLKDV_DIVIDE : real := 2.0; CLKFX_DIVIDE : integer := 1; CLKFX_MULTIPLY : integer := 4; CLKIN_DIVIDE_BY_2 : boolean := false; CLKIN_PERIOD : real := 10.0; CLKOUT_PHASE_SHIFT : string := "NONE"; CLK_FEEDBACK : string := "1X"; DESKEW_ADJUST : string := "SYSTEM_SYNCHRONOUS"; DFS_FREQUENCY_MODE : string := "LOW"; DLL_FREQUENCY_MODE : string := "LOW"; DSS_MODE : string := "NONE"; DUTY_CYCLE_CORRECTION : boolean := true; FACTORY_JF : bit_vector := X"C080"; PHASE_SHIFT : integer := 0; STARTUP_WAIT : boolean := false ); port ( CLKFB : in std_logic; CLKIN : in std_logic; DSSEN : in std_logic; PSCLK : in std_logic; PSEN : in std_logic; PSINCDEC : in std_logic; RST : in std_logic; CLK0 : out std_logic; CLK90 : out std_logic; CLK180 : out std_logic; CLK270 : out std_logic; CLK2X : out std_logic; CLK2X180 : out std_logic; CLKDV : out std_logic; CLKFX : out std_logic; CLKFX180 : out std_logic; LOCKED : out std_logic; PSDONE : out std_logic; STATUS : out std_logic_vector (7 downto 0)); end component; -- component BUFGDLL port (O : out std_logic; I : in std_logic); end component; constant VERSION : integer := 1; --constant CLKIN_PERIOD_ST : string := "20.0"; constant FREQ_MHZ : integer := freq/1000; --attribute CLKIN_PERIOD : string; --attribute CLKIN_PERIOD of dll0: label is CLKIN_PERIOD_ST; signal gnd, clk_i, clk_j, clk_k, clk_l, clk_m, lsdclk : std_logic; signal clk_x, clk_n, clk_o, clk_p, clk_i2, clk_sd, clk_r: std_logic; signal dll0rst, dll0lock, dll1lock, dll2xlock : std_logic; signal dll1rst, dll2xrst : std_logic_vector(0 to 3); signal clk0B, clkint, pciclkint : std_logic; begin gnd <= '0'; clk <= clk_i when (CLK2XEN = 0) else clk_p; clkn <= clk_m; clk2x <= clk_i2; c0 : if (PCISYSCLK = 0) or (PCIEN = 0) generate clkint <= clkin; end generate; c2 : if PCIEN /= 0 generate pciclkint <= pciclkin; p3 : if PCISYSCLK = 1 generate clkint <= pciclkint; end generate; p0 : if PCIDLL = 1 generate -- x1 : BUFGDLL port map (I => pciclkint, O => pciclk); --pragma translate_off assert false report "PCIDLL = 1 currently not supported for virtex5_clkgen" severity failure; --pragma translate_on end generate; p1 : if PCIDLL = 0 generate x1 : BUFG port map (I => pciclkint, O => pciclk); end generate; end generate; c3 : if PCIEN = 0 generate pciclk <= '0'; end generate; clk1xu <= clk_k; clk2xu <= clk_x; bufg0 : BUFG port map (I => clk0B, O => clk_i); bufg1 : BUFG port map (I => clk_j, O => clk_k); bufg2 : BUFG port map (I => clk_l, O => clk_m); buf34gen : if (CLK2XEN /= 0) generate cs0 : if (clksel = 0) generate bufg3 : BUFG port map (I => clk_n, O => clk_i2); end generate; cs1 : if (clksel /= 0) generate bufg3 : BUFGMUX port map (S => cgi.clksel(0), I0 => clk_o, I1 => clk_n, O => clk_i2); end generate; bufg4 : BUFG port map (I => clk_o, O => clk_p); end generate; dll0rst <= not cgi.pllrst; -- HMODE_dll0 : if (((FREQ_MHZclk_mul)/clk_div >= 140) or (FREQ_MHZ >= 120)) generate -- dll0 : DCM -- generic map (CLKFX_MULTIPLY => clk_mul, CLKFX_DIVIDE => clk_div, -- DFS_FREQUENCY_MODE => "HIGH", DLL_FREQUENCY_MODE => "HIGH") -- port map ( CLKIN => clkint, CLKFB => clk_k, DSSEN => gnd, PSCLK => gnd, -- PSEN => gnd, PSINCDEC => gnd, RST => dll0rst, CLK0 => clk_j, -- CLKFX => clk0B, CLK2X => clk_x, CLKFX180 => clk_l, LOCKED => dll0lock); -- end generate; -- LMODE_dll0 : if not (((FREQ_MHZclk_mul)/clk_div >= 140) or (FREQ_MHZ >= 120)) generate dll0 : DCM generic map (CLKFX_MULTIPLY => clk_mul, CLKFX_DIVIDE => clk_div, DFS_FREQUENCY_MODE => "LOW", DLL_FREQUENCY_MODE => "LOW") port map ( CLKIN => clkint, CLKFB => clk_k, DSSEN => gnd, PSCLK => gnd, PSEN => gnd, PSINCDEC => gnd, RST => dll0rst, CLK0 => clk_j, CLKFX => clk0B, CLK2X => clk_x, CLKFX180 => clk_l, LOCKED => dll0lock); -- end generate; clk2xgen : if (CLK2XEN /= 0) generate -- HMODE_dll2x : if ((FREQ_MHZclk_mul)/clk_div >= 120) generate -- dll2x : DCM generic map (CLKFX_MULTIPLY => 2, CLKFX_DIVIDE => 2, -- DFS_FREQUENCY_MODE => "HIGH", DLL_FREQUENCY_MODE => "HIGH") -- port map ( CLKIN => clk_i, CLKFB => clk_p, DSSEN => gnd, PSCLK => gnd, -- PSEN => gnd, PSINCDEC => gnd, RST => dll2xrst(0), CLK0 => clk_o, -- CLK2X => clk_n, LOCKED => dll2xlock); -- end generate; -- LMODE_dll2x : if not ((FREQ_MHZclk_mul)/clk_div >= 120) generate dll2x : DCM generic map (CLKFX_MULTIPLY => 2, CLKFX_DIVIDE => 2, DFS_FREQUENCY_MODE => "LOW", DLL_FREQUENCY_MODE => "LOW") port map ( CLKIN => clk_i, CLKFB => clk_p, DSSEN => gnd, PSCLK => gnd, PSEN => gnd, PSINCDEC => gnd, RST => dll2xrst(0), CLK0 => clk_o, CLK2X => clk_n, LOCKED => dll2xlock); -- end generate; rstdel2x : process (clk_i, dll0lock) begin if dll0lock = '0' then dll2xrst <= (others => '1'); elsif rising_edge(clk_i) then dll2xrst <= dll2xrst(1 to 3) & '0'; end if; end process; end generate; clk_sd1 : if (CLK2XEN = 0) generate clk_i2 <= clk_x; dll2xlock <= dll0lock; clk_sd <= clk_i; end generate; clk_sd2 : if (CLK2XEN = 1) generate clk_sd <= clk_p; end generate; clk_sd3 : if (CLK2XEN = 2) generate clk_sd <= clk_i2; end generate; sd0 : if (SDRAMEN /= 0) and (NOCLKFB=0) generate cgo.clklock <= dll1lock; -- HMODE_dll1 : if ((FREQ_MHZclk_mul)/clk_div >= (120-60(CLK2XEN/2))) generate -- dll1 : DCM generic map (CLKFX_MULTIPLY => 2, CLKFX_DIVIDE => 2, -- DFS_FREQUENCY_MODE => "HIGH", DLL_FREQUENCY_MODE => "HIGH", -- DESKEW_ADJUST => "SOURCE_SYNCHRONOUS") -- port map ( CLKIN => clk_sd, CLKFB => cgi.pllref, DSSEN => gnd, PSCLK => gnd, -- PSEN => gnd, PSINCDEC => gnd, RST => dll1rst(0), CLK0 => lsdclk, --CLK2X => clk2x, -- LOCKED => dll1lock); -- end generate; -- LMODE_dll1 : if not ((FREQ_MHZclk_mul)/clk_div >= (120-60(CLK2XEN/2))) generate dll1 : DCM generic map (CLKFX_MULTIPLY => 2, CLKFX_DIVIDE => 2, DFS_FREQUENCY_MODE => "LOW", DLL_FREQUENCY_MODE => "LOW", DESKEW_ADJUST => "SOURCE_SYNCHRONOUS") port map ( CLKIN => clk_sd, CLKFB => cgi.pllref, DSSEN => gnd, PSCLK => gnd, PSEN => gnd, PSINCDEC => gnd, RST => dll1rst(0), CLK0 => lsdclk, --CLK2X => clk2x, LOCKED => dll1lock); -- end generate; bufgx : BUFG port map (I => lsdclk, O => sdclk); rstdel : process (clk_sd, dll2xlock) begin if dll2xlock = '0' then dll1rst <= (others => '1'); elsif rising_edge(clk_sd) then dll1rst <= dll1rst(1 to 3) & '0'; end if; end process; end generate; sd1 : if ((SDRAMEN = 0) or (NOCLKFB = 1)) and (CLK2XEN /= 2) generate sdclk <= clk_i; cgo.clklock <= dll0lock when (CLK2XEN = 0) else dll2xlock; end generate; sd1_2x : if ((SDRAMEN = 0) or (NOCLKFB = 1)) and (CLK2XEN = 2) generate sdclk <= clk_i2; cgo.clklock <= dll2xlock; end generate; cgo.pcilock <= '1'; -- pragma translate_off bootmsg : report_version generic map ( "clkgen_virtex5" & ": virtex-5 sdram/pci clock generator, version " & tost(VERSION), "clkgen_virtex5" & ": Frequency " & tost(freq) & " KHz, DCM divisor " & tost(clk_mul) & "/" & tost(clk_div)); -- pragma translate_on end; ------------------------------------------------------------------ -- Virtex7 clock generator --------------------------------------- ------------------------------------------------------------------ library ieee; use ieee.std_logic_1164.all; -- pragma translate_off library grlib; use grlib.stdlib.all; library unisim; use UNISIM.vcomponents.all; -- pragma translate_on library techmap; use techmap.gencomp.all; entity clkgen_virtex7 is generic ( clk_mul : integer := 1; clk_div : integer := 1; freq : integer := 200000 -- clock frequency in KHz ); port ( clkin : in std_ulogic; clk : out std_ulogic; -- main clock clk90 : out std_ulogic; -- main clock 90deg clkio : out std_ulogic; -- IO ref clock cgi : in clkgen_in_type; cgo : out clkgen_out_type ); end; architecture struct of clkgen_virtex7 is component BUFG port (O : out std_logic; I : in std_logic); end component; ----- component PLLE2_ADV ----- component PLLE2_ADV generic ( BANDWIDTH : string := "OPTIMIZED"; CLKFBOUT_MULT : integer := 5; CLKFBOUT_PHASE : real := 0.0; CLKIN1_PERIOD : real := 0.0; CLKIN2_PERIOD : real := 0.0; CLKOUT0_DIVIDE : integer := 1; CLKOUT0_DUTY_CYCLE : real := 0.5; CLKOUT0_PHASE : real := 0.0; CLKOUT1_DIVIDE : integer := 1; CLKOUT1_DUTY_CYCLE : real := 0.5; CLKOUT1_PHASE : real := 0.0; CLKOUT2_DIVIDE : integer := 1; CLKOUT2_DUTY_CYCLE : real := 0.5; CLKOUT2_PHASE : real := 0.0; CLKOUT3_DIVIDE : integer := 1; CLKOUT3_DUTY_CYCLE : real := 0.5; CLKOUT3_PHASE : real := 0.0; CLKOUT4_DIVIDE : integer := 1; CLKOUT4_DUTY_CYCLE : real := 0.5; CLKOUT4_PHASE : real := 0.0; CLKOUT5_DIVIDE : integer := 1; CLKOUT5_DUTY_CYCLE : real := 0.5; CLKOUT5_PHASE : real := 0.0; COMPENSATION : string := "ZHOLD"; DIVCLK_DIVIDE : integer := 1; REF_JITTER1 : real := 0.0; REF_JITTER2 : real := 0.0; STARTUP_WAIT : string := "FALSE" ); port ( CLKFBOUT : out std_ulogic := '0'; CLKOUT0 : out std_ulogic := '0'; CLKOUT1 : out std_ulogic := '0'; CLKOUT2 : out std_ulogic := '0'; CLKOUT3 : out std_ulogic := '0'; CLKOUT4 : out std_ulogic := '0'; CLKOUT5 : out std_ulogic := '0'; DO : out std_logic_vector (15 downto 0); DRDY : out std_ulogic := '0'; LOCKED : out std_ulogic := '0'; CLKFBIN : in std_ulogic; CLKIN1 : in std_ulogic; CLKIN2 : in std_ulogic; CLKINSEL : in std_ulogic; DADDR : in std_logic_vector(6 downto 0); DCLK : in std_ulogic; DEN : in std_ulogic; DI : in std_logic_vector(15 downto 0); DWE : in std_ulogic; PWRDWN : in std_ulogic; RST : in std_ulogic ); end component; constant VERSION : integer := 1; constant period : real := 1000000.0/real(freq); constant clkio_div : integer := freq*clk_mul/200000; signal CLKFBOUT : std_logic; signal CLKFBIN : std_logic; signal int_rst : std_logic; signal clk_nobuf : std_logic; signal clk90_nobuf : std_logic; signal clkio_nobuf : std_logic; begin CLKFBIN <= CLKFBOUT; int_rst <= not cgi.pllrst; PLLE2_ADV_inst : PLLE2_ADV generic map ( BANDWIDTH => "OPTIMIZED", -- OPTIMIZED, HIGH, LOW CLKFBOUT_MULT => clk_mul, -- Multiply value for all CLKOUT, (2-64) CLKFBOUT_PHASE => 0.0, -- Phase offset in degrees of CLKFB, (-360.000-360.000). -- CLKIN_PERIOD: Input clock period in nS to ps resolution (i.e. 33.333 is 30 MHz). CLKIN1_PERIOD => period, CLKIN2_PERIOD => 0.0, -- CLKOUT0_DIVIDE - CLKOUT5_DIVIDE: Divide amount for CLKOUT (1-128) CLKOUT0_DIVIDE => clk_div, CLKOUT1_DIVIDE => clk_div, CLKOUT2_DIVIDE => clkio_div, CLKOUT3_DIVIDE => 1, CLKOUT4_DIVIDE => 1, CLKOUT5_DIVIDE => 1, -- CLKOUT0_DUTY_CYCLE - CLKOUT5_DUTY_CYCLE: Duty cycle for CLKOUT outputs (0.001-0.999). CLKOUT0_DUTY_CYCLE => 0.5, CLKOUT1_DUTY_CYCLE => 0.5, CLKOUT2_DUTY_CYCLE => 0.5, CLKOUT3_DUTY_CYCLE => 0.5, CLKOUT4_DUTY_CYCLE => 0.5, CLKOUT5_DUTY_CYCLE => 0.5, -- CLKOUT0_PHASE - CLKOUT5_PHASE: Phase offset for CLKOUT outputs (-360.000-360.000). CLKOUT0_PHASE => 0.0, CLKOUT1_PHASE => 90.0, CLKOUT2_PHASE => 0.0, CLKOUT3_PHASE => 0.0, CLKOUT4_PHASE => 0.0, CLKOUT5_PHASE => 0.0, COMPENSATION => "ZHOLD", -- ZHOLD, BUF_IN, EXTERNAL, INTERNAL DIVCLK_DIVIDE => 1, -- Master division value (1-56) -- REF_JITTER: Reference input jitter in UI (0.000-0.999). REF_JITTER1 => 0.0, REF_JITTER2 => 0.0, STARTUP_WAIT => "TRUE" -- Delay DONE until PLL Locks, ("TRUE"/"FALSE") ) port map ( -- Clock Outputs: 1-bit (each) output: User configurable clock outputs CLKOUT0 => clk_nobuf, CLKOUT1 => clk90_nobuf, CLKOUT2 => clkio_nobuf, CLKOUT3 => OPEN, CLKOUT4 => OPEN, CLKOUT5 => OPEN, -- DRP Ports: 16-bit (each) output: Dynamic reconfigration ports DO => OPEN, DRDY => OPEN, -- Feedback Clocks: 1-bit (each) output: Clock feedback ports CLKFBOUT => CLKFBOUT, -- Status Ports: 1-bit (each) output: PLL status ports LOCKED => cgo.clklock, -- Clock Inputs: 1-bit (each) input: Clock inputs CLKIN1 => clkin, CLKIN2 => '0', -- Con trol Ports: 1-bit (each) input: PLL control ports CLKINSEL => '1', PWRDWN => '0', RST => int_rst, -- DRP Ports: 7-bit (each) input: Dynamic reconfigration ports DADDR => "0000000", DCLK => '0', DEN => '0', DI => "0000000000000000", DWE => '0', -- Feedback Clocks: 1-bit (each) input: Clock feedback ports CLKFBIN => CLKFBIN ); cgo.pcilock <= '0'; bufgclk0 : BUFG port map (I => clk_nobuf, O => clk); bufgclk90 : BUFG port map (I => clk90_nobuf, O => clk90); bufgclkio : BUFG port map (I => clkio_nobuf, O => clkio); -- pragma translate_off bootmsg : report_version generic map ( "clkgen_virtex7" & ": virtex-7 sdram/pci clock generator, version " & tost(VERSION), "clkgen_virtex7" & ": Frequency " & tost(freq) & " KHz, DCM divisor " & tost(clk_mul) & "/" & tost(clk_div)); -- pragma translate_on end; library ieee; use ieee.std_logic_1164.all; -- pragma translate_off library unisim; use unisim.BUFGMUX; -- pragma translate_on entity clkand_unisim is port( i : in std_ulogic; en : in std_ulogic; o : out std_ulogic ); end entity; architecture rtl of clkand_unisim is component BUFGCE port( O : out STD_ULOGIC; CE: in STD_ULOGIC; I : in STD_ULOGIC ); end component; begin buf : bufgce port map(I => i, CE => en, O => o); end architecture; library ieee; use ieee.std_logic_1164.all; -- pragma translate_off library unisim; use unisim.BUFGMUX; -- pragma translate_on entity clkmux_unisim is port( i0, i1 : in std_ulogic; sel : in std_ulogic; o : out std_ulogic ); end entity; architecture rtl of clkmux_unisim is component bufgmux is port( i0, i1 : in std_ulogic; s : in std_ulogic; o : out std_ulogic); end component; signal sel0, sel1, cg0, cg1 : std_ulogic; begin buf : bufgmux port map(S => sel, I0 => i0, I1 => i1, O => o); end architecture;	gpl-2.0	84aad10c54f1dfb16576f3f05baba44a	0.56438	3.417177	false	false	false	false
mistryalok/Zedboard	learning/training/MSD/s09/axi_dma_sg/vivado/project_1/project_1.srcs/sources_1/ipshared/xilinx.com/axi_sg_v4_1/0535f152/hdl/src/vhdl/axi_sg_updt_noqueue.vhd	3	30,514	-- *********************************************************************** -- -- (c) Copyright 2010-2011 Xilinx, Inc. All rights reserved. -- -- This file contains confidential and proprietary information -- of Xilinx, Inc. and is protected under U.S. and -- international copyright and other intellectual property -- laws. -- -- DISCLAIMER -- This disclaimer is not a license and does not grant any -- rights to the materials distributed herewith. Except as -- otherwise provided in a valid license issued to you by -- Xilinx, and to the maximum extent permitted by applicable -- law: (1) THESE MATERIALS ARE MADE AVAILABLE "AS IS" AND -- WITH ALL FAULTS, AND XILINX HEREBY DISCLAIMS ALL WARRANTIES -- AND CONDITIONS, EXPRESS, IMPLIED, OR STATUTORY, INCLUDING -- BUT NOT LIMITED TO WARRANTIES OF MERCHANTABILITY, NON- -- INFRINGEMENT, OR FITNESS FOR ANY PARTICULAR PURPOSE; and -- (2) Xilinx shall not be liable (whether in contract or tort, -- including negligence, or under any other theory of -- liability) for any loss or damage of any kind or nature -- related to, arising under or in connection with these -- materials, including for any direct, or any indirect, -- special, incidental, or consequential loss or damage -- (including loss of data, profits, goodwill, or any type of -- loss or damage suffered as a result of any action brought -- by a third party) even if such damage or loss was -- reasonably foreseeable or Xilinx had been advised of the -- possibility of the same. -- -- CRITICAL APPLICATIONS -- Xilinx products are not designed or intended to be fail- -- safe, or for use in any application requiring fail-safe -- performance, such as life-support or safety devices or -- systems, Class III medical devices, nuclear facilities, -- applications related to the deployment of airbags, or any -- other applications that could lead to death, personal -- injury, or severe property or environmental damage -- (individually and collectively, "Critical -- Applications"). Customer assumes the sole risk and -- liability of any use of Xilinx products in Critical -- Applications, subject only to applicable laws and -- regulations governing limitations on product liability. -- -- THIS COPYRIGHT NOTICE AND DISCLAIMER MUST BE RETAINED AS -- PART OF THIS FILE AT ALL TIMES. -- -- ********************************************************************* -- ------------------------------------------------------------------------------- -- Filename: axi_sg_updt_noqueue.vhd -- Description: This entity provides the descriptor update for the No Queue mode -- -- VHDL-Standard: VHDL'93 ------------------------------------------------------------------------------- library ieee; use ieee.std_logic_1164.all; use ieee.numeric_std.all; use ieee.std_logic_misc.all; library axi_sg_v4_1; use axi_sg_v4_1.axi_sg_pkg.all; library lib_pkg_v1_0; use lib_pkg_v1_0.lib_pkg.all; ------------------------------------------------------------------------------- entity axi_sg_updt_noqueue is generic ( C_M_AXI_SG_ADDR_WIDTH : integer range 32 to 64 := 32; -- Master AXI Memory Map Address Width for Scatter Gather R/W Port C_M_AXIS_UPDT_DATA_WIDTH : integer range 32 to 32 := 32; -- Master AXI Memory Map Data Width for Scatter Gather R/W Port C_S_AXIS_UPDPTR_TDATA_WIDTH : integer range 32 to 32 := 32; -- 32 Update Status Bits C_S_AXIS_UPDSTS_TDATA_WIDTH : integer range 33 to 33 := 33 -- 1 IOC bit + 32 Update Status Bits ); port ( ----------------------------------------------------------------------- -- AXI Scatter Gather Interface ----------------------------------------------------------------------- m_axi_sg_aclk : in std_logic ; -- m_axi_sg_aresetn : in std_logic ; -- -- -- Channel 1 Control -- updt_curdesc_wren : out std_logic ; -- updt_curdesc : out std_logic_vector -- (C_M_AXI_SG_ADDR_WIDTH-1 downto 0) ; -- updt_active : in std_logic ; -- updt_queue_empty : out std_logic ; -- updt_ioc : out std_logic ; -- updt_ioc_irq_set : in std_logic ; -- -- dma_interr : out std_logic ; -- dma_slverr : out std_logic ; -- dma_decerr : out std_logic ; -- dma_interr_set : in std_logic ; -- dma_slverr_set : in std_logic ; -- dma_decerr_set : in std_logic ; -- updt2_active : in std_logic ; -- updt2_queue_empty : out std_logic ; -- updt2_ioc : out std_logic ; -- updt2_ioc_irq_set : in std_logic ; -- -- dma2_interr : out std_logic ; -- dma2_slverr : out std_logic ; -- dma2_decerr : out std_logic ; -- dma2_interr_set : in std_logic ; -- dma2_slverr_set : in std_logic ; -- dma2_decerr_set : in std_logic ; -- -- --*****************************-- -- -- Channel Update Interface In -- -- --*****************************-- -- -- Update Pointer Stream -- s_axis_updtptr_tdata : in std_logic_vector -- (C_S_AXIS_UPDPTR_TDATA_WIDTH-1 downto 0) ; -- s_axis_updtptr_tvalid : in std_logic ; -- s_axis_updtptr_tready : out std_logic ; -- s_axis_updtptr_tlast : in std_logic ; -- -- -- Update Status Stream -- s_axis_updtsts_tdata : in std_logic_vector -- (C_S_AXIS_UPDSTS_TDATA_WIDTH-1 downto 0); -- s_axis_updtsts_tvalid : in std_logic ; -- s_axis_updtsts_tready : out std_logic ; -- s_axis_updtsts_tlast : in std_logic ; -- -- Update Pointer Stream -- s_axis2_updtptr_tdata : in std_logic_vector -- (C_S_AXIS_UPDPTR_TDATA_WIDTH-1 downto 0) ; -- s_axis2_updtptr_tvalid : in std_logic ; -- s_axis2_updtptr_tready : out std_logic ; -- s_axis2_updtptr_tlast : in std_logic ; -- -- -- Update Status Stream -- s_axis2_updtsts_tdata : in std_logic_vector -- (C_S_AXIS_UPDSTS_TDATA_WIDTH-1 downto 0); -- s_axis2_updtsts_tvalid : in std_logic ; -- s_axis2_updtsts_tready : out std_logic ; -- s_axis2_updtsts_tlast : in std_logic ; -- -- --*****************************-- -- -- Channel Update Interface Out-- -- --*****************************-- -- -- S2MM Stream Out To DataMover -- m_axis_updt_tdata : out std_logic_vector -- (C_M_AXIS_UPDT_DATA_WIDTH-1 downto 0); -- m_axis_updt_tlast : out std_logic ; -- m_axis_updt_tvalid : out std_logic ; -- m_axis_updt_tready : in std_logic -- ); end axi_sg_updt_noqueue; ------------------------------------------------------------------------------- -- Architecture ------------------------------------------------------------------------------- architecture implementation of axi_sg_updt_noqueue is attribute DowngradeIPIdentifiedWarnings: string; attribute DowngradeIPIdentifiedWarnings of implementation : architecture is "yes"; ------------------------------------------------------------------------------- -- Functions ------------------------------------------------------------------------------- -- No Functions Declared ------------------------------------------------------------------------------- -- Constants Declarations ------------------------------------------------------------------------------- -- No Contstants Declared ------------------------------------------------------------------------------- -- Signal / Type Declarations ------------------------------------------------------------------------------- -- Channel signals signal writing_curdesc : std_logic := '0'; signal write_curdesc_lsb : std_logic := '0'; signal write_curdesc_msb : std_logic := '0'; signal updt_active_d1 : std_logic := '0'; signal updt_active_re : std_logic := '0'; type PNTR_STATE_TYPE is (IDLE, READ_CURDESC_LSB, READ_CURDESC_MSB, WRITE_STATUS ); signal pntr_cs : PNTR_STATE_TYPE; signal pntr_ns : PNTR_STATE_TYPE; signal writing_status : std_logic := '0'; signal curdesc_tready : std_logic := '0'; signal writing_status_d1 : std_logic := '0'; signal writing_status_re : std_logic := '0'; signal writing_status_re_ch1 : std_logic := '0'; signal writing_status_re_ch2 : std_logic := '0'; signal updt_active_int : std_logic := '0'; signal s_axis_updtptr_tvalid_int : std_logic := '0'; signal s_axis_updtsts_tvalid_int : std_logic := '0'; signal s_axis_updtsts_tlast_int : std_logic := '0'; signal s_axis_updtptr_tdata_int : std_logic_vector (C_S_AXIS_UPDPTR_TDATA_WIDTH-1 downto 0) := (others => '0'); signal s_axis_qual : std_logic := '0'; signal s_axis2_qual : std_logic := '0'; signal m_axis_updt_tdata_mm2s : std_logic_vector (31 downto 0); -- signal m_axis_updt_tlast_mm2s : std_logic ; -- signal m_axis_updt_tvalid_mm2s : std_logic ; signal m_axis_updt_tdata_s2mm : std_logic_vector (31 downto 0); -- signal m_axis_updt_tlast_s2mm : std_logic ; -- signal m_axis_updt_tvalid_s2mm : std_logic ; ------------------------------------------------------------------------------- -- Begin architecture logic ------------------------------------------------------------------------------- begin m_axis_updt_tdata <= m_axis_updt_tdata_mm2s when updt_active = '1' else m_axis_updt_tdata_s2mm; m_axis_updt_tvalid <= m_axis_updt_tvalid_mm2s when updt_active = '1' else m_axis_updt_tvalid_s2mm; m_axis_updt_tlast <= m_axis_updt_tlast_mm2s when updt_active = '1' else m_axis_updt_tlast_s2mm; updt_active_int <= updt_active or updt2_active; s_axis_updtptr_tvalid_int <= s_axis_updtptr_tvalid or s_axis2_updtptr_tvalid; s_axis_updtsts_tvalid_int <= s_axis_updtsts_tvalid or s_axis2_updtsts_tvalid; s_axis_updtsts_tlast_int <= s_axis_updtsts_tlast or s_axis2_updtsts_tlast; s_axis_qual <= s_axis_updtsts_tvalid and s_axis_updtsts_tlast and updt_active; s_axis2_qual <= s_axis2_updtsts_tvalid and s_axis2_updtsts_tlast and updt2_active; -- Asset active strobe on rising edge of update active -- asertion. This kicks off the update process for -- the channel REG_ACTIVE : process(m_axi_sg_aclk) begin if(m_axi_sg_aclk'EVENT and m_axi_sg_aclk = '1')then if(m_axi_sg_aresetn = '0')then updt_active_d1 <= '0'; else updt_active_d1 <= updt_active or updt2_active; end if; end if; end process REG_ACTIVE; updt_active_re <= (updt_active or updt2_active) and not updt_active_d1; -- Current Descriptor Pointer Fetch. This state machine controls -- reading out the current pointer from the Queue or channel port -- and writing it to the update manager for use in command -- generation to the DataMover for Descriptor update. CURDESC_PNTR_STATE : process(pntr_cs, updt_active_int, s_axis_updtptr_tvalid_int, updt_active, updt2_active, s_axis_qual, s_axis2_qual, s_axis_updtptr_tvalid, s_axis2_updtptr_tvalid, s_axis_updtsts_tvalid_int, m_axis_updt_tready) begin write_curdesc_lsb <= '0'; write_curdesc_msb <= '0'; writing_status <= '0'; writing_curdesc <= '0'; curdesc_tready <= '0'; pntr_ns <= pntr_cs; case pntr_cs is when IDLE => if((s_axis_updtptr_tvalid = '1' and updt_active = '1') or (s_axis2_updtptr_tvalid = '1' and updt2_active = '1')) then writing_curdesc <= '1'; pntr_ns <= READ_CURDESC_LSB; else pntr_ns <= IDLE; end if; --------------------------------------------------------------- -- Get lower current descriptor when READ_CURDESC_LSB => curdesc_tready <= '1'; writing_curdesc <= '1'; -- on tvalid from Queue or channel port then register -- lsb curdesc and setup to register msb curdesc if(s_axis_updtptr_tvalid_int = '1' and updt_active_int = '1')then write_curdesc_lsb <= '1'; -- pntr_ns <= READ_CURDESC_MSB; pntr_ns <= WRITE_STATUS; else -- coverage off pntr_ns <= READ_CURDESC_LSB; -- coverage on end if; -- coverage off --------------------------------------------------------------- -- Get upper current descriptor when READ_CURDESC_MSB => curdesc_tready <= '1'; writing_curdesc <= '1'; -- On tvalid from Queue or channel port then register -- msb. This will also write curdesc out to update -- manager. if(s_axis_updtptr_tvalid_int = '1')then write_curdesc_msb <= '1'; pntr_ns <= WRITE_STATUS; else pntr_ns <= READ_CURDESC_MSB; end if; -- coverage on --------------------------------------------------------------- -- Hold in this state until remainder of descriptor is -- written out. when WRITE_STATUS => writing_status <= '1'; --s_axis_updtsts_tvalid_int; if((s_axis_qual = '1' and m_axis_updt_tready = '1') or (s_axis2_qual = '1' and m_axis_updt_tready = '1')) then pntr_ns <= IDLE; else pntr_ns <= WRITE_STATUS; end if; -- coverage off when others => pntr_ns <= IDLE; -- coverage on end case; end process CURDESC_PNTR_STATE; --------------------------------------------------------------------------- -- Register for CURDESC Pointer state machine --------------------------------------------------------------------------- REG_PNTR_STATES : process(m_axi_sg_aclk) begin if(m_axi_sg_aclk'EVENT and m_axi_sg_aclk = '1')then if(m_axi_sg_aresetn = '0')then pntr_cs <= IDLE; else pntr_cs <= pntr_ns; end if; end if; end process REG_PNTR_STATES; -- Status stream signals m_axis_updt_tdata_mm2s <= s_axis_updtsts_tdata(C_S_AXIS_UPDSTS_TDATA_WIDTH-2 downto 0); m_axis_updt_tvalid_mm2s <= s_axis_updtsts_tvalid and writing_status; m_axis_updt_tlast_mm2s <= s_axis_updtsts_tlast and writing_status; s_axis_updtsts_tready <= m_axis_updt_tready and writing_status and updt_active; -- Pointer stream signals s_axis_updtptr_tready <= curdesc_tready and updt_active; -- Indicate need for channel service for update state machine updt_queue_empty <= not (s_axis_updtsts_tvalid); -- and writing_status); m_axis_updt_tdata_s2mm <= s_axis2_updtsts_tdata(C_S_AXIS_UPDSTS_TDATA_WIDTH-2 downto 0); m_axis_updt_tvalid_s2mm <= s_axis2_updtsts_tvalid and writing_status; m_axis_updt_tlast_s2mm <= s_axis2_updtsts_tlast and writing_status; s_axis2_updtsts_tready <= m_axis_updt_tready and writing_status and updt2_active; -- Pointer stream signals s_axis2_updtptr_tready <= curdesc_tready and updt2_active; -- Indicate need for channel service for update state machine updt2_queue_empty <= not (s_axis2_updtsts_tvalid); -- and writing_status); --***************************************************************** -- POINTER CAPTURE LOGIC --******************************************************************* s_axis_updtptr_tdata_int <= s_axis_updtptr_tdata when (updt_active = '1') else s_axis2_updtptr_tdata; --------------------------------------------------------------------------- -- Write lower order Next Descriptor Pointer out to pntr_mngr --------------------------------------------------------------------------- REG_LSB_CURPNTR : process(m_axi_sg_aclk) begin if(m_axi_sg_aclk'EVENT and m_axi_sg_aclk = '1')then if(m_axi_sg_aresetn = '0' )then updt_curdesc(31 downto 0) <= (others => '0'); -- Capture lower pointer from FIFO or channel port elsif(write_curdesc_lsb = '1')then updt_curdesc(31 downto 0) <= s_axis_updtptr_tdata_int(C_S_AXIS_UPDPTR_TDATA_WIDTH - 1 downto 0); end if; end if; end process REG_LSB_CURPNTR; --------------------------------------------------------------------------- -- 64 Bit Scatter Gather addresses enabled --------------------------------------------------------------------------- GEN_UPPER_MSB_CURDESC : if C_M_AXI_SG_ADDR_WIDTH = 64 generate begin --------------------------------------------------------------------------- -- Write upper order Next Descriptor Pointer out to pntr_mngr --------------------------------------------------------------------------- REG_MSB_CURPNTR : process(m_axi_sg_aclk) begin if(m_axi_sg_aclk'EVENT and m_axi_sg_aclk = '1')then if(m_axi_sg_aresetn = '0' )then updt_curdesc(63 downto 32) <= (others => '0'); updt_curdesc_wren <= '0'; -- Capture upper pointer from FIFO or channel port -- and also write curdesc out elsif(write_curdesc_msb = '1')then updt_curdesc(63 downto 32) <= s_axis_updtptr_tdata(C_S_AXIS_UPDPTR_TDATA_WIDTH - 1 downto 0); updt_curdesc_wren <= '1'; -- Assert tready/wren for only 1 clock else updt_curdesc_wren <= '0'; end if; end if; end process REG_MSB_CURPNTR; end generate GEN_UPPER_MSB_CURDESC; --------------------------------------------------------------------------- -- 32 Bit Scatter Gather addresses enabled --------------------------------------------------------------------------- GEN_NO_UPR_MSB_CURDESC : if C_M_AXI_SG_ADDR_WIDTH = 32 generate begin ----------------------------------------------------------------------- -- No upper order therefore dump fetched word and write pntr lower next -- pointer to pntr mngr ----------------------------------------------------------------------- REG_MSB_CURPNTR : process(m_axi_sg_aclk) begin if(m_axi_sg_aclk'EVENT and m_axi_sg_aclk = '1')then if(m_axi_sg_aresetn = '0' )then updt_curdesc_wren <= '0'; -- Throw away second word, only write curdesc out with msb -- set to zero elsif(write_curdesc_lsb = '1')then -- elsif(write_curdesc_msb = '1')then updt_curdesc_wren <= '1'; -- Assert for only 1 clock else updt_curdesc_wren <= '0'; end if; end if; end process REG_MSB_CURPNTR; end generate GEN_NO_UPR_MSB_CURDESC; --***************************************************************** -- ERROR CAPTURE LOGIC --********************************************************************* ----------------------------------------------------------------------- -- Generate rising edge pulse on writing status signal. This will -- assert at the beginning of the status write. Coupled with status -- fifo set to first word fall through status will be on dout -- regardless of target ready. ----------------------------------------------------------------------- REG_WRITE_STATUS : process(m_axi_sg_aclk) begin if(m_axi_sg_aclk'EVENT and m_axi_sg_aclk = '1')then if(m_axi_sg_aresetn = '0')then writing_status_d1 <= '0'; else writing_status_d1 <= writing_status; end if; end if; end process REG_WRITE_STATUS; writing_status_re <= writing_status and not writing_status_d1; writing_status_re_ch1 <= writing_status_re and updt_active; writing_status_re_ch2 <= writing_status_re and updt2_active; --------------------------------------------------------------------------- -- Caputure IOC begin set --------------------------------------------------------------------------- REG_IOC_PROCESS : process(m_axi_sg_aclk) begin if(m_axi_sg_aclk'EVENT and m_axi_sg_aclk = '1')then if(m_axi_sg_aresetn = '0' or updt_ioc_irq_set = '1')then updt_ioc <= '0'; elsif(writing_status_re_ch1 = '1')then updt_ioc <= s_axis_updtsts_tdata(DESC_IOC_TAG_BIT); end if; end if; end process REG_IOC_PROCESS; ----------------------------------------------------------------------- -- Capture DMA Internal Errors ----------------------------------------------------------------------- CAPTURE_DMAINT_ERROR: process(m_axi_sg_aclk) begin if(m_axi_sg_aclk'EVENT and m_axi_sg_aclk = '1')then if(m_axi_sg_aresetn = '0' or dma_interr_set = '1')then dma_interr <= '0'; elsif(writing_status_re_ch1 = '1')then dma_interr <= s_axis_updtsts_tdata(DESC_STS_INTERR_BIT); end if; end if; end process CAPTURE_DMAINT_ERROR; ----------------------------------------------------------------------- -- Capture DMA Slave Errors ----------------------------------------------------------------------- CAPTURE_DMASLV_ERROR: process(m_axi_sg_aclk) begin if(m_axi_sg_aclk'EVENT and m_axi_sg_aclk = '1')then if(m_axi_sg_aresetn = '0' or dma_slverr_set = '1')then dma_slverr <= '0'; elsif(writing_status_re_ch1 = '1')then dma_slverr <= s_axis_updtsts_tdata(DESC_STS_SLVERR_BIT); end if; end if; end process CAPTURE_DMASLV_ERROR; ----------------------------------------------------------------------- -- Capture DMA Decode Errors ----------------------------------------------------------------------- CAPTURE_DMADEC_ERROR: process(m_axi_sg_aclk) begin if(m_axi_sg_aclk'EVENT and m_axi_sg_aclk = '1')then if(m_axi_sg_aresetn = '0' or dma_decerr_set = '1')then dma_decerr <= '0'; elsif(writing_status_re_ch1 = '1')then dma_decerr <= s_axis_updtsts_tdata(DESC_STS_DECERR_BIT); end if; end if; end process CAPTURE_DMADEC_ERROR; --------------------------------------------------------------------------- -- Caputure IOC begin set --------------------------------------------------------------------------- REG2_IOC_PROCESS : process(m_axi_sg_aclk) begin if(m_axi_sg_aclk'EVENT and m_axi_sg_aclk = '1')then if(m_axi_sg_aresetn = '0' or updt2_ioc_irq_set = '1')then updt2_ioc <= '0'; elsif(writing_status_re_ch2 = '1')then updt2_ioc <= s_axis2_updtsts_tdata(DESC_IOC_TAG_BIT); end if; end if; end process REG2_IOC_PROCESS; ----------------------------------------------------------------------- -- Capture DMA Internal Errors ----------------------------------------------------------------------- CAPTURE2_DMAINT_ERROR: process(m_axi_sg_aclk) begin if(m_axi_sg_aclk'EVENT and m_axi_sg_aclk = '1')then if(m_axi_sg_aresetn = '0' or dma2_interr_set = '1')then dma2_interr <= '0'; elsif(writing_status_re_ch2 = '1')then dma2_interr <= s_axis2_updtsts_tdata(DESC_STS_INTERR_BIT); end if; end if; end process CAPTURE2_DMAINT_ERROR; ----------------------------------------------------------------------- -- Capture DMA Slave Errors ----------------------------------------------------------------------- CAPTURE2_DMASLV_ERROR: process(m_axi_sg_aclk) begin if(m_axi_sg_aclk'EVENT and m_axi_sg_aclk = '1')then if(m_axi_sg_aresetn = '0' or dma2_slverr_set = '1')then dma2_slverr <= '0'; elsif(writing_status_re_ch2 = '1')then dma2_slverr <= s_axis2_updtsts_tdata(DESC_STS_SLVERR_BIT); end if; end if; end process CAPTURE2_DMASLV_ERROR; ----------------------------------------------------------------------- -- Capture DMA Decode Errors ----------------------------------------------------------------------- CAPTURE2_DMADEC_ERROR: process(m_axi_sg_aclk) begin if(m_axi_sg_aclk'EVENT and m_axi_sg_aclk = '1')then if(m_axi_sg_aresetn = '0' or dma2_decerr_set = '1')then dma2_decerr <= '0'; elsif(writing_status_re_ch2 = '1')then dma2_decerr <= s_axis2_updtsts_tdata(DESC_STS_DECERR_BIT); end if; end if; end process CAPTURE2_DMADEC_ERROR; end implementation;	gpl-3.0	9f9ea00202212e89b3e97678d602f678	0.403356	4.911315	false	false	false	false
mistryalok/Zedboard	learning/training/MSD/s09/axi_dma_sg/vivado/project_1/project_1.srcs/sources_1/ipshared/xilinx.com/axi_dma_v7_1/2a047f91/hdl/src/vhdl/axi_dma_afifo_autord.vhd	3	17,911	-- (c) Copyright 2012 Xilinx, Inc. All rights reserved. -- -- This file contains confidential and proprietary information -- of Xilinx, Inc. and is protected under U.S. and -- international copyright and other intellectual property -- laws. -- -- DISCLAIMER -- This disclaimer is not a license and does not grant any -- rights to the materials distributed herewith. Except as -- otherwise provided in a valid license issued to you by -- Xilinx, and to the maximum extent permitted by applicable -- law: (1) THESE MATERIALS ARE MADE AVAILABLE "AS IS" AND -- WITH ALL FAULTS, AND XILINX HEREBY DISCLAIMS ALL WARRANTIES -- AND CONDITIONS, EXPRESS, IMPLIED, OR STATUTORY, INCLUDING -- BUT NOT LIMITED TO WARRANTIES OF MERCHANTABILITY, NON- -- INFRINGEMENT, OR FITNESS FOR ANY PARTICULAR PURPOSE; and -- (2) Xilinx shall not be liable (whether in contract or tort, -- including negligence, or under any other theory of -- liability) for any loss or damage of any kind or nature -- related to, arising under or in connection with these -- materials, including for any direct, or any indirect, -- special, incidental, or consequential loss or damage -- (including loss of data, profits, goodwill, or any type of -- loss or damage suffered as a result of any action brought -- by a third party) even if such damage or loss was -- reasonably foreseeable or Xilinx had been advised of the -- possibility of the same. -- -- CRITICAL APPLICATIONS -- Xilinx products are not designed or intended to be fail- -- safe, or for use in any application requiring fail-safe -- performance, such as life-support or safety devices or -- systems, Class III medical devices, nuclear facilities, -- applications related to the deployment of airbags, or any -- other applications that could lead to death, personal -- injury, or severe property or environmental damage -- (individually and collectively, "Critical -- Applications"). Customer assumes the sole risk and -- liability of any use of Xilinx products in Critical -- Applications, subject only to applicable laws and -- regulations governing limitations on product liability. -- -- THIS COPYRIGHT NOTICE AND DISCLAIMER MUST BE RETAINED AS -- PART OF THIS FILE AT ALL TIMES. ------------------------------------------------------------ -- ************************************************************************* -- ------------------------------------------------------------------------------- -- Filename: axi_dma_afifo_autord.vhd -- Version: initial -- Description: -- This file contains the logic to generate a CoreGen call to create a -- asynchronous FIFO as part of the synthesis process of XST. This eliminates -- the need for multiple fixed netlists for various sizes and widths of FIFOs. -- -- -- VHDL-Standard: VHDL'93 ------------------------------------------------------------------------------- library IEEE; use IEEE.std_logic_1164.all; use IEEE.std_logic_arith.all; use IEEE.std_logic_unsigned.all; library lib_cdc_v1_0; library lib_fifo_v1_0; use lib_fifo_v1_0.async_fifo_fg; library axi_dma_v7_1; use axi_dma_v7_1.axi_dma_pkg.all; ----------------------------------------------------------------------------- -- Entity section ----------------------------------------------------------------------------- entity axi_dma_afifo_autord is generic ( C_DWIDTH : integer := 32; C_DEPTH : integer := 16; C_CNT_WIDTH : Integer := 5; C_USE_BLKMEM : Integer := 0 ; C_USE_AUTORD : Integer := 1; C_PRMRY_IS_ACLK_ASYNC : integer := 1; C_FAMILY : String := "virtex7" ); port ( -- Inputs AFIFO_Ainit : In std_logic; -- AFIFO_Wr_clk : In std_logic; -- AFIFO_Wr_en : In std_logic; -- AFIFO_Din : In std_logic_vector(C_DWIDTH-1 downto 0); -- AFIFO_Rd_clk : In std_logic; -- AFIFO_Rd_en : In std_logic; -- AFIFO_Clr_Rd_Data_Valid : In std_logic; -- -- -- Outputs -- AFIFO_DValid : Out std_logic; -- AFIFO_Dout : Out std_logic_vector(C_DWIDTH-1 downto 0); -- AFIFO_Full : Out std_logic; -- AFIFO_Empty : Out std_logic; -- AFIFO_Almost_full : Out std_logic; -- AFIFO_Almost_empty : Out std_logic; -- AFIFO_Wr_count : Out std_logic_vector(C_CNT_WIDTH-1 downto 0); -- AFIFO_Rd_count : Out std_logic_vector(C_CNT_WIDTH-1 downto 0); -- AFIFO_Corr_Rd_count : Out std_logic_vector(C_CNT_WIDTH downto 0); -- AFIFO_Corr_Rd_count_minus1 : Out std_logic_vector(C_CNT_WIDTH downto 0); -- AFIFO_Rd_ack : Out std_logic -- ); end entity axi_dma_afifo_autord; ----------------------------------------------------------------------------- -- Architecture section ----------------------------------------------------------------------------- architecture imp of axi_dma_afifo_autord is attribute DowngradeIPIdentifiedWarnings: string; attribute DowngradeIPIdentifiedWarnings of imp : architecture is "yes"; -- Constant declarations ATTRIBUTE async_reg : STRING; -- Signal declarations signal write_data_lil_end : std_logic_vector(C_DWIDTH-1 downto 0) := (others => '0'); signal read_data_lil_end : std_logic_vector(C_DWIDTH-1 downto 0) := (others => '0'); signal wr_count_lil_end : std_logic_vector(C_CNT_WIDTH-1 downto 0) := (others => '0'); signal rd_count_lil_end : std_logic_vector(C_CNT_WIDTH-1 downto 0) := (others => '0'); signal rd_count_int : integer range 0 to C_DEPTH+1 := 0; signal rd_count_int_corr : integer range 0 to C_DEPTH+1 := 0; signal rd_count_int_corr_minus1 : integer range 0 to C_DEPTH+1 := 0; Signal corrected_empty : std_logic := '0'; Signal corrected_almost_empty : std_logic := '0'; Signal sig_afifo_empty : std_logic := '0'; Signal sig_afifo_almost_empty : std_logic := '0'; -- backend fifo read ack sample and hold Signal sig_rddata_valid : std_logic := '0'; Signal hold_ff_q : std_logic := '0'; Signal ored_ack_ff_reset : std_logic := '0'; Signal autoread : std_logic := '0'; Signal sig_wrfifo_rdack : std_logic := '0'; Signal fifo_read_enable : std_logic := '0'; Signal first_write : std_logic := '0'; Signal first_read_cdc_tig : std_logic := '0'; Signal first_read1 : std_logic := '0'; Signal first_read2 : std_logic := '0'; signal AFIFO_Ainit_d1_cdc_tig : std_logic; signal AFIFO_Ainit_d2 : std_logic; --ATTRIBUTE async_reg OF AFIFO_Ainit_d1_cdc_tig : SIGNAL IS "true"; --ATTRIBUTE async_reg OF AFIFO_Ainit_d2 : SIGNAL IS "true"; --ATTRIBUTE async_reg OF first_read_cdc_tig : SIGNAL IS "true"; --ATTRIBUTE async_reg OF first_read1 : SIGNAL IS "true"; -- Component declarations ----------------------------------------------------------------------------- -- Begin architecture ----------------------------------------------------------------------------- begin -- Bit ordering translations write_data_lil_end <= AFIFO_Din; -- translate from Big Endian to little -- endian. AFIFO_Rd_ack <= sig_wrfifo_rdack; AFIFO_Dout <= read_data_lil_end; -- translate from Little Endian to -- Big endian. AFIFO_Almost_empty <= corrected_almost_empty; GEN_EMPTY : if (C_USE_AUTORD = 1) generate begin AFIFO_Empty <= corrected_empty; end generate GEN_EMPTY; GEN_EMPTY1 : if (C_USE_AUTORD = 0) generate begin AFIFO_Empty <= sig_afifo_empty; end generate GEN_EMPTY1; AFIFO_Wr_count <= wr_count_lil_end; AFIFO_Rd_count <= rd_count_lil_end; AFIFO_Corr_Rd_count <= CONV_STD_LOGIC_VECTOR(rd_count_int_corr, C_CNT_WIDTH+1); AFIFO_Corr_Rd_count_minus1 <= CONV_STD_LOGIC_VECTOR(rd_count_int_corr_minus1, C_CNT_WIDTH+1); AFIFO_DValid <= sig_rddata_valid; -- Output data valid indicator fifo_read_enable <= AFIFO_Rd_en or autoread; ------------------------------------------------------------------------------- -- Instantiate the CoreGen FIFO -- -- NOTE: -- This instance refers to a wrapper file that interm will use the -- CoreGen FIFO Generator Async FIFO utility. -- ------------------------------------------------------------------------------- I_ASYNC_FIFOGEN_FIFO : entity lib_fifo_v1_0.async_fifo_fg generic map ( -- C_ALLOW_2N_DEPTH => 1, C_ALLOW_2N_DEPTH => 0, C_FAMILY => C_FAMILY, C_DATA_WIDTH => C_DWIDTH, C_ENABLE_RLOCS => 0, C_FIFO_DEPTH => C_DEPTH, C_HAS_ALMOST_EMPTY => 1, C_HAS_ALMOST_FULL => 1, C_HAS_RD_ACK => 1, C_HAS_RD_COUNT => 1, C_HAS_RD_ERR => 0, C_HAS_WR_ACK => 0, C_HAS_WR_COUNT => 1, C_HAS_WR_ERR => 0, C_RD_ACK_LOW => 0, C_RD_COUNT_WIDTH => C_CNT_WIDTH, C_RD_ERR_LOW => 0, C_USE_BLOCKMEM => C_USE_BLKMEM, C_WR_ACK_LOW => 0, C_WR_COUNT_WIDTH => C_CNT_WIDTH, C_WR_ERR_LOW => 0, C_SYNCHRONIZER_STAGE => C_FIFO_MTBF -- C_USE_EMBEDDED_REG => 1, -- 0 ; -- C_PRELOAD_REGS => 0, -- 0 ; -- C_PRELOAD_LATENCY => 1 -- 1 ; ) port Map ( Din => write_data_lil_end, Wr_en => AFIFO_Wr_en, Wr_clk => AFIFO_Wr_clk, Rd_en => fifo_read_enable, Rd_clk => AFIFO_Rd_clk, Ainit => AFIFO_Ainit, Dout => read_data_lil_end, Full => AFIFO_Full, Empty => sig_afifo_empty, Almost_full => AFIFO_Almost_full, Almost_empty => sig_afifo_almost_empty, Wr_count => wr_count_lil_end, Rd_count => rd_count_lil_end, Rd_ack => sig_wrfifo_rdack, Rd_err => open, -- Not used by axi_dma Wr_ack => open, -- Not used by axi_dma Wr_err => open -- Not used by axi_dma ); ---------------------------------------------------------------------------- -- Read Ack assert & hold logic (needed because: -- 1) The Async FIFO has to be read once to get valid -- data to the read data port (data is discarded). -- 2) The Read ack from the fifo is only asserted for 1 clock. -- 3) A signal is needed that indicates valid data is at the read -- port of the FIFO and has not yet been read. This signal needs -- to be held until the next read operation occurs or a clear -- signal is received. ored_ack_ff_reset <= fifo_read_enable or AFIFO_Ainit_d2 or AFIFO_Clr_Rd_Data_Valid; sig_rddata_valid <= hold_ff_q or sig_wrfifo_rdack; ------------------------------------------------------------- -- Synchronous Process with Sync Reset -- -- Label: IMP_ACK_HOLD_FLOP -- -- Process Description: -- Flop for registering the hold flag -- ------------------------------------------------------------- ASYNC_CDC_SYNC : if C_PRMRY_IS_ACLK_ASYNC = 1 generate IMP_SYNC_FLOP : entity lib_cdc_v1_0.cdc_sync generic map ( C_CDC_TYPE => 1, C_RESET_STATE => 0, C_SINGLE_BIT => 1, C_VECTOR_WIDTH => 32, C_MTBF_STAGES => MTBF_STAGES ) port map ( prmry_aclk => '0', prmry_resetn => '0', prmry_in => AFIFO_Ainit, prmry_vect_in => (others => '0'), scndry_aclk => AFIFO_Rd_clk, scndry_resetn => '0', scndry_out => AFIFO_Ainit_d2, scndry_vect_out => open ); end generate ASYNC_CDC_SYNC; SYNC_CDC_SYNC : if C_PRMRY_IS_ACLK_ASYNC = 0 generate AFIFO_Ainit_d2 <= AFIFO_Ainit; end generate SYNC_CDC_SYNC; -- IMP_SYNC_FLOP : process (AFIFO_Rd_clk) -- begin -- if (AFIFO_Rd_clk'event and AFIFO_Rd_clk = '1') then -- AFIFO_Ainit_d1_cdc_tig <= AFIFO_Ainit; -- AFIFO_Ainit_d2 <= AFIFO_Ainit_d1_cdc_tig; -- end if; -- end process IMP_SYNC_FLOP; IMP_ACK_HOLD_FLOP : process (AFIFO_Rd_clk) begin if (AFIFO_Rd_clk'event and AFIFO_Rd_clk = '1') then if (ored_ack_ff_reset = '1') then hold_ff_q <= '0'; else hold_ff_q <= sig_rddata_valid; end if; end if; end process IMP_ACK_HOLD_FLOP; -- I_ACK_HOLD_FF : FDRE -- port map( -- Q => hold_ff_q, -- C => AFIFO_Rd_clk, -- CE => '1', -- D => sig_rddata_valid, -- R => ored_ack_ff_reset -- ); -- generate auto-read enable. This keeps fresh data at the output -- of the FIFO whenever it is available. GEN_AUTORD1 : if C_USE_AUTORD = 1 generate autoread <= '1' -- create a read strobe when the when (sig_rddata_valid = '0' and -- output data is NOT valid sig_afifo_empty = '0') -- and the FIFO is not empty Else '0'; end generate GEN_AUTORD1; GEN_AUTORD2 : if C_USE_AUTORD = 0 generate process (AFIFO_Wr_clk) begin if (AFIFO_Wr_clk'event and AFIFO_Wr_clk = '1') then if (AFIFO_Ainit = '0') then first_write <= '0'; elsif (AFIFO_Wr_en = '1') then first_write <= '1'; end if; end if; end process; IMP_SYNC_FLOP1 : entity lib_cdc_v1_0.cdc_sync generic map ( C_CDC_TYPE => 1, C_RESET_STATE => 0, C_SINGLE_BIT => 1, C_VECTOR_WIDTH => 32, C_MTBF_STAGES => MTBF_STAGES ) port map ( prmry_aclk => '0', prmry_resetn => '0', prmry_in => first_write, prmry_vect_in => (others => '0'), scndry_aclk => AFIFO_Rd_clk, scndry_resetn => '0', scndry_out => first_read1, scndry_vect_out => open ); process (AFIFO_Rd_clk) begin if (AFIFO_Rd_clk'event and AFIFO_Rd_clk = '1') then if (AFIFO_Ainit_d2 = '0') then first_read2 <= '0'; elsif (sig_afifo_empty = '0') then first_read2 <= first_read1; end if; end if; end process; autoread <= first_read1 xor first_read2; end generate GEN_AUTORD2; rd_count_int <= CONV_INTEGER(rd_count_lil_end); ------------------------------------------------------------- -- Combinational Process -- -- Label: CORRECT_RD_CNT -- -- Process Description: -- This process corrects the FIFO Read Count output for the -- auto read function. -- ------------------------------------------------------------- CORRECT_RD_CNT : process (sig_rddata_valid, sig_afifo_empty, sig_afifo_almost_empty, rd_count_int) begin if (sig_rddata_valid = '0') then rd_count_int_corr <= 0; rd_count_int_corr_minus1 <= 0; corrected_empty <= '1'; corrected_almost_empty <= '0'; elsif (sig_afifo_empty = '1') then -- rddata valid and fifo empty rd_count_int_corr <= 1; rd_count_int_corr_minus1 <= 0; corrected_empty <= '0'; corrected_almost_empty <= '1'; Elsif (sig_afifo_almost_empty = '1') Then -- rddata valid and fifo almost empty rd_count_int_corr <= 2; rd_count_int_corr_minus1 <= 1; corrected_empty <= '0'; corrected_almost_empty <= '0'; else -- rddata valid and modify rd count from FIFO rd_count_int_corr <= rd_count_int+1; rd_count_int_corr_minus1 <= rd_count_int; corrected_empty <= '0'; corrected_almost_empty <= '0'; end if; end process CORRECT_RD_CNT; end imp;	gpl-3.0	22208a35fc5ccb8783b5d129aa75dbc2	0.475853	4.081814	false	false	false	false
Yuriu5/MiniBlaze	src/hw1/Sequencer.vhd	1	29,275	-- ******************************************************************************** -- Project : MiniBlaze -- Author : Benjamin Lemoine -- Module : Sequencer -- Date : 07/25/2016 -- -- Description : Sequencer of the core. Fetch, decode, execute and store. -- This implementation (v1) does not aim to be fast. There is -- no pipeline, memory access are slow. The goal is to have -- a functionnal core that can be played with. -- -- -------------------------------------------------------------------------------- -- Modifications -- -------------------------------------------------------------------------------- -- Date : Ver. : Author : Modification comments -- -------------------------------------------------------------------------------- -- : : : -- 07/25/2016 : 1.0 : B.Lemoine : First draft -- : : : -- ****************************************************************************** -- MIT License -- -- Copyright (c) 07/25/2016, Benjamin Lemoine -- -- Permission is hereby granted, free of charge, to any person obtaining a copy -- of this software and associated documentation files (the "Software"), to deal -- in the Software without restriction, including without limitation the rights -- to use, copy, modify, merge, publish, distribute, sublicense, and/or sell -- copies of the Software, and to permit persons to whom the Software is -- furnished to do so, subject to the following conditions: -- -- The above copyright notice and this permission notice shall be included in all -- copies or substantial portions of the Software. -- -- THE SOFTWARE IS PROVIDED "AS IS", WITHOUT WARRANTY OF ANY KIND, EXPRESS OR -- IMPLIED, INCLUDING BUT NOT LIMITED TO THE WARRANTIES OF MERCHANTABILITY, -- FITNESS FOR A PARTICULAR PURPOSE AND NONINFRINGEMENT. IN NO EVENT SHALL THE -- AUTHORS OR COPYRIGHT HOLDERS BE LIABLE FOR ANY CLAIM, DAMAGES OR OTHER -- LIABILITY, WHETHER IN AN ACTION OF CONTRACT, TORT OR OTHERWISE, ARISING FROM, -- OUT OF OR IN CONNECTION WITH THE SOFTWARE OR THE USE OR OTHER DEALINGS IN THE -- SOFTWARE. -- ******************************************************************************** library ieee; use ieee.std_logic_1164.all; use ieee.numeric_std.all; library work; use work.ALU_pkg.all; use work.spec_reg_pkg.all; entity sequencer is generic( D_WIDTH : natural := 32 ); port( -- Clock and reset clk : in std_logic; reset_n : in std_logic; -- Interface memory in data_mem_in_i : in std_logic_vector(D_WIDTH-1 downto 0); data_mem_in_en_i : in std_logic; addr_mem_in_o : out std_logic_vector(D_WIDTH-1 downto 0); rd_en_mem_in_o : out std_logic; -- Interface memory out addr_mem_out_o : out std_logic_vector(D_WIDTH-1 downto 0); data_mem_out_o : out std_logic_vector(D_WIDTH-1 downto 0); wr_en_mem_out_o : out std_logic_vector(3 downto 0) ); end sequencer; architecture rtl of sequencer is -- Components declaration component ALU is generic( DATA_WIDTH : natural := D_WIDTH ); port( param_i : in t_param_alu; carry_i : in std_logic; operandA_i : in std_logic_vector(DATA_WIDTH - 1 downto 0); operandB_i : in std_logic_vector(DATA_WIDTH - 1 downto 0); operandD_o : out std_logic_vector(DATA_WIDTH - 1 downto 0); status_o : out t_status_alu_out ); end component; -- Signals declaration type fsm_seq is (st_fetch, st_decode, st_execute); signal r_fsm_seq : fsm_seq := st_fetch; signal r_last_state : fsm_seq; -- Special purpose registers signal r_ProgramCounter : unsigned(D_WIDTH-1 downto 0) := (others => '0'); signal r_LastProgramCounter : unsigned(D_WIDTH-1 downto 0) := (others => '0'); signal r_MSR : std_logic_vector(D_WIDTH-1 downto 0) := (others => '0'); signal r_imm : std_logic_vector(D_WIDTH/2-1 downto 0) := (others => '0'); -- General purpose registers type vect_32x32b is array (0 to 31) of std_logic_vector(D_WIDTH-1 downto 0); signal v_GeneralReg : vect_32x32b := (others => (others => '0')); -- Mem in signal r_addr_mem_in : unsigned(D_WIDTH-1 downto 0) := (others => '0'); signal r_rd_en_mem_in : std_logic := '0'; signal s_instruction : std_logic_vector(D_WIDTH-1 downto 0) := (others => '0'); signal r_instruction : std_logic_vector(D_WIDTH-1 downto 0) := (others => '0'); -- Mem out signal r_wr_en_mem_out : std_logic_vector(3 downto 0) := (others => '0'); signal r_addr_mem_out : std_logic_vector(D_WIDTH-1 downto 0) := (others => '0'); signal r_data_mem_out : std_logic_vector(D_WIDTH-1 downto 0) := (others => '0'); -- ALU signal r_input_alu_A : std_logic_vector(D_WIDTH-1 downto 0) := (others => '0'); signal r_input_alu_B : std_logic_vector(D_WIDTH-1 downto 0) := (others => '0'); signal s_input_alu_B : std_logic_vector(D_WIDTH-1 downto 0) := (others => '0'); signal r_param_alu : t_param_alu := c_param_alu_null; signal s_carry_alu_in : std_logic := '0'; signal s_output_alu : std_logic_vector(D_WIDTH-1 downto 0) := (others => '0'); signal s_status_alu : t_status_alu_out := c_status_alu_out_null; -- Sequencer signal r_wr_carry_output : std_logic := '0'; signal r_allow_next_instruction : std_logic := '0'; signal r_isInstructionBranchDelay : std_logic := '0'; signal r_last_op_was_imm : std_logic := '0'; signal r_is_imm_instruction : std_logic := '0'; signal r_is_branch_cond : std_logic := '0'; signal r_is_branch_uncond : std_logic := '0'; signal r_is_load_instruction : std_logic := '0'; signal r_is_store_instruction : std_logic := '0'; signal r_load_store_exclusive : std_logic := '0'; signal r_rD_address : std_logic_vector(4 downto 0) := (others => '0'); signal r_return_from_subroutine : std_logic := '0'; signal r_branch_op : std_logic_vector(3 downto 0) := (others => '0'); signal r_op_load_store : std_logic_vector(1 downto 0) := (others => '0'); signal r_step_load : unsigned(1 downto 0) := (others => '0'); signal r_step_fetch : std_logic := '0'; type fsm_fetch is (st_set_address, st_wait_data); signal r_fsm_fetch : fsm_fetch := st_set_address; signal r_fsm_load : fsm_fetch := st_set_address; begin s_instruction <= data_mem_in_i; p_seq : process(clk) variable v_instruction_6_5 : std_logic_vector(1 downto 0); variable v_addr_mem_in_1_0 : unsigned(1 downto 0); variable v_output_alu_1_0 : std_logic_vector(1 downto 0); begin if rising_edge(clk) then if reset_n = '0' then r_fsm_seq <= st_fetch; r_last_state <= st_fetch; r_ProgramCounter <= (others => '0'); r_LastProgramCounter <= (others => '0'); r_fsm_fetch <= st_set_address; r_fsm_load <= st_set_address; else -- Default values r_rd_en_mem_in <= '0'; r_wr_en_mem_out <= (others => '0'); r_last_state <= r_fsm_seq; case r_fsm_seq is when st_fetch => -- Fetch instruction case r_fsm_fetch is when st_set_address => if r_isInstructionBranchDelay = '1' then r_addr_mem_in <= r_LastProgramCounter + 4; else r_addr_mem_in <= r_ProgramCounter; end if; r_rd_en_mem_in <= '1'; r_fsm_fetch <= st_wait_data; when st_wait_data => if data_mem_in_en_i = '1' then r_fsm_seq <= st_decode; r_instruction <= s_instruction; r_fsm_fetch <= st_set_address; end if; when others => r_fsm_fetch <= st_set_address; end case; when st_decode => report " ---- "; report integer'image(to_integer(r_ProgramCounter)); --default value r_input_alu_A <= v_GeneralReg(to_integer(unsigned(r_instruction(20 downto 16)))); r_param_alu.ctrl_op.whichCarry <= CARRY_INPUT; r_param_alu.ctrl_op.ctrlShift <= LEFT_SHIFT; r_param_alu.ctrl_op.negOperandA <= '0'; r_param_alu.ctrl_op.negOperandB <= '0'; r_param_alu.ctrl_op.multType <= LSW; r_wr_carry_output <= '0'; r_allow_next_instruction <= '0'; r_is_branch_cond <= '0'; r_is_branch_uncond <= '0'; r_is_load_instruction <= '0'; r_is_store_instruction <= '0'; r_load_store_exclusive <= '0'; r_return_from_subroutine <= '0'; r_is_imm_instruction <= '0'; r_fsm_load <= st_set_address; -- Next stage r_fsm_seq <= st_execute; -- Type A / Type B instruction if r_instruction(29) = '0' then -- rB r_input_alu_B <= v_GeneralReg(to_integer(unsigned(r_instruction(15 downto 11)))); else -- imm r_input_alu_B <= std_logic_vector(resize(unsigned(r_instruction(15 downto 0)), D_WIDTH)); end if; -- Store rD address r_rD_address <= r_instruction(25 downto 21); -- add, addc, addk, addkc, addi, addic, addik, addikc -- rsub, rsubi if (r_instruction(31 downto 30) = "00") then r_param_alu.operation <= OP_ADD; if r_instruction(27) = '1' then -- C Bit r_param_alu.ctrl_op.whichCarry <= CARRY_INPUT; else if r_instruction(26) = '1' then -- sub r_param_alu.ctrl_op.whichCarry <= CARRY_ONE; else -- add r_param_alu.ctrl_op.whichCarry <= CARRY_ZERO; end if; end if; if r_instruction(26) = '1' then -- Substrate bit r_param_alu.ctrl_op.negOperandA <= '1'; end if; r_wr_carry_output <= not r_instruction(28); -- and, andi elsif r_instruction(31 downto 30) = "10" and r_instruction(28 downto 26) = "001" then r_param_alu.operation <= OP_AND; -- andn, andni elsif r_instruction(31 downto 30) = "10" and r_instruction(28 downto 26) = "011" then r_param_alu.operation <= OP_AND; r_param_alu.ctrl_op.negOperandB <= r_instruction(27); -- or, ori elsif r_instruction(31 downto 30) = "10" and r_instruction(28 downto 26) = "000" then r_param_alu.operation <= OP_OR; -- xor, xori elsif r_instruction(31 downto 30) = "10" and r_instruction(28 downto 26) = "010" then r_param_alu.operation <= OP_XOR; -- conditional branch instructions elsif (r_instruction(31 downto 30) = "10") and (r_instruction(28 downto 26) = "111") then -- D bit, allow following instruction to complete exection r_allow_next_instruction <= r_instruction(25); r_is_branch_cond <= '1'; r_branch_op <= r_instruction(24 downto 21); r_param_alu.operation <= OP_PTA; -- unconditional branch instructions elsif (r_instruction(31 downto 30) = "10") and (r_instruction(28 downto 26) = "110") then r_allow_next_instruction <= r_instruction(20); r_is_branch_uncond <= '1'; r_branch_op <= r_instruction(19 downto 16); r_param_alu.operation <= OP_PTB; -- Barrel Shift : bsrl, bsra, bsll elsif (r_instruction(31 downto 30) = "01") and (r_instruction(28 downto 26) = "001") then r_param_alu.operation <= OP_BS; if r_instruction(10) = '1' then -- bit S (Side bit) r_param_alu.ctrl_op.ctrlShift <= LEFT_SHIFT; else if r_instruction(9) = '1' then -- bit T (Type bit) r_param_alu.ctrl_op.ctrlShift <= RIGHT_SHIFT_ARITH; else r_param_alu.ctrl_op.ctrlShift <= RIGHT_SHIFT_LOGIC; end if; end if; -- Integer Compare : cmp, cmpu elsif r_instruction(31 downto 26) = "000101" then r_param_alu.operation <= OP_ADD; r_param_alu.ctrl_op.whichCarry <= CARRY_ONE; r_param_alu.ctrl_op.negOperandA <= '1'; -- Immediate : imm elsif r_instruction(31 downto 26) = "101100" then r_is_imm_instruction <= '1'; r_param_alu.operation <= OP_PTB; -- Load/Store instruction elsif r_instruction(31 downto 30) = "11" then r_is_load_instruction <= not r_instruction(28); r_is_store_instruction <= r_instruction(28); r_op_load_store <= r_instruction(27 downto 26); r_param_alu.operation <= OP_ADD; r_param_alu.ctrl_op.whichCarry <= CARRY_ZERO; if r_instruction(10) = '1' and r_instruction(29) = '0' then r_load_store_exclusive <= '1'; end if; -- Multipy instruction : only mul, muli (C_USE_HW_MUL = '1') elsif r_instruction(31 downto 30) = "01" and r_instruction(28 downto 26) = "000" then r_param_alu.operation <= OP_MULT; -- Return from Subroutine elsif (r_instruction(31 downto 25) = "1011011") then r_allow_next_instruction <= '1'; r_param_alu.operation <= OP_ADD; r_param_alu.ctrl_op.whichCarry <= CARRY_ZERO; r_return_from_subroutine <= '1'; -- Sign Extend Halfword / Byte and Shift elsif (r_instruction(31 downto 26) = "100100") then if r_instruction(0) = '1' then v_instruction_6_5 := r_instruction(6 downto 5); case v_instruction_6_5 is -- SRA when "00" => r_param_alu.operation <= OP_SHIFT; r_param_alu.ctrl_op.whichCarry <= CARRY_ARITH; -- SRC when "01" => r_param_alu.operation <= OP_SHIFT; r_param_alu.ctrl_op.whichCarry <= CARRY_INPUT; r_wr_carry_output <= '1'; -- SRL when "10" => r_param_alu.operation <= OP_SHIFT; r_param_alu.ctrl_op.whichCarry <= CARRY_ZERO; r_wr_carry_output <= '1'; -- SEXT16 when others => r_param_alu.operation <= OP_SEXT16; r_param_alu.ctrl_op.whichCarry <= CARRY_ZERO; end case; else r_param_alu.operation <= OP_SEXT8; end if; end if; when st_execute => -- Go to fecth step unless we wait for a memory access r_fsm_seq <= st_fetch; r_isInstructionBranchDelay <= '0'; r_last_op_was_imm <= '0'; -- Increment r_ProgramCounter of 4 to fetch the next instruction -- Overwrite the value after if a branch is requested if(r_last_state /= st_execute and r_isInstructionBranchDelay = '0') then r_ProgramCounter <= r_ProgramCounter + 4; end if; -- Store ALU output v_GeneralReg(to_integer(unsigned(r_rD_address))) <= s_output_alu; -- Change MSR carry bit if needed if r_wr_carry_output = '1' then r_MSR(MSR_C) <= s_status_alu.carry; end if; -- Branch execution cond if r_is_branch_cond = '1' then v_GeneralReg(to_integer(unsigned(r_rD_address))) <= v_GeneralReg(to_integer(unsigned(r_rD_address))); if r_branch_op = "0000" and s_status_alu.zero = '1' then -- Branch if Equal r_ProgramCounter <= r_ProgramCounter + unsigned(v_GeneralReg(to_integer(unsigned(r_instruction(15 downto 11))))); elsif r_branch_op = "0101" and ((s_status_alu.negative = '0') or (s_status_alu.zero = '1')) then -- Branch if Greater or Equal r_ProgramCounter <= r_ProgramCounter + unsigned(v_GeneralReg(to_integer(unsigned(r_instruction(15 downto 11))))); elsif r_branch_op = "0100" and s_status_alu.negative = '0' then -- Branch if Greater Than r_ProgramCounter <= r_ProgramCounter + unsigned(v_GeneralReg(to_integer(unsigned(r_instruction(15 downto 11))))); elsif r_branch_op = "0011" and ((s_status_alu.negative = '1') or (s_status_alu.zero = '1')) then -- Branch if Less or Equal r_ProgramCounter <= r_ProgramCounter + unsigned(v_GeneralReg(to_integer(unsigned(r_instruction(15 downto 11))))); elsif r_branch_op = "0010" and s_status_alu.negative = '1' then -- Branch if Less Than r_ProgramCounter <= r_ProgramCounter + unsigned(v_GeneralReg(to_integer(unsigned(r_instruction(15 downto 11))))); elsif r_branch_op = "0001" and s_status_alu.zero = '0' then -- Branch if Not Equal r_ProgramCounter <= r_ProgramCounter + unsigned(v_GeneralReg(to_integer(unsigned(r_instruction(15 downto 11))))); end if; if r_allow_next_instruction = '1' then r_isInstructionBranchDelay <= '1'; r_LastProgramCounter <= r_ProgramCounter; end if; -- Return from subroutine elsif r_return_from_subroutine = '1' then r_ProgramCounter <= unsigned(s_output_alu); -- Branch execution uncond elsif r_is_branch_uncond = '1' then v_GeneralReg(to_integer(unsigned(r_rD_address))) <= v_GeneralReg(to_integer(unsigned(r_rD_address))); if r_branch_op(2) = '1' then -- L bit v_GeneralReg(to_integer(unsigned(r_rD_address))) <= std_logic_vector(r_ProgramCounter); end if; if r_branch_op(3) = '1' then -- A bit r_ProgramCounter <= unsigned(s_output_alu); else r_ProgramCounter <= r_ProgramCounter + unsigned(s_output_alu); end if; if r_allow_next_instruction = '1' then r_isInstructionBranchDelay <= '1'; r_LastProgramCounter <= r_ProgramCounter; end if; -- Note : Load & Write this way only works for one cycle access memory -- Load execution elsif r_is_load_instruction = '1' then v_GeneralReg(to_integer(unsigned(r_rD_address))) <= v_GeneralReg(to_integer(unsigned(r_rD_address))); r_fsm_seq <= st_execute; case r_fsm_load is when st_set_address => r_addr_mem_in <= unsigned(s_output_alu); r_rd_en_mem_in <= '1'; r_fsm_load <= st_wait_data; when st_wait_data => if data_mem_in_en_i = '1' then r_fsm_seq <= st_fetch; if r_op_load_store = "00" then v_addr_mem_in_1_0 := r_addr_mem_in(1 downto 0); case v_addr_mem_in_1_0 is when "00" => v_GeneralReg(to_integer(unsigned(r_rD_address))) <= x"000000" & data_mem_in_i(7 downto 0); when "01" => v_GeneralReg(to_integer(unsigned(r_rD_address))) <= x"000000" & data_mem_in_i(15 downto 8); when "10" => v_GeneralReg(to_integer(unsigned(r_rD_address))) <= x"000000" & data_mem_in_i(23 downto 16); when others => v_GeneralReg(to_integer(unsigned(r_rD_address))) <= x"000000" & data_mem_in_i(31 downto 24); end case; elsif r_op_load_store = "01" then v_addr_mem_in_1_0 := r_addr_mem_in(1 downto 0); case v_addr_mem_in_1_0 is when "00" => v_GeneralReg(to_integer(unsigned(r_rD_address))) <= x"0000" & data_mem_in_i(15 downto 0); when "10" => v_GeneralReg(to_integer(unsigned(r_rD_address))) <= x"0000" & data_mem_in_i(31 downto 16); when others => assert false report "Address non-aligned on 16b access" severity error; end case; elsif r_op_load_store = "10" then if r_addr_mem_in(1 downto 0) = "00" then v_GeneralReg(to_integer(unsigned(r_rD_address)))(31 downto 0) <= data_mem_in_i(31 downto 0); else assert false report "Address non-aligned on 32b access" severity error; end if; if r_load_store_exclusive = '1' then r_MSR(MSR_C) <= '0'; end if; end if; end if; when others => r_fsm_load <= st_set_address; end case; -- Store execution elsif r_is_store_instruction = '1' then v_GeneralReg(to_integer(unsigned(r_rD_address))) <= v_GeneralReg(to_integer(unsigned(r_rD_address))); r_addr_mem_out <= s_output_alu; if r_op_load_store = "00" then r_wr_en_mem_out(to_integer(unsigned(s_output_alu(1 downto 0)))) <= '1'; -- others are at '0' v_output_alu_1_0 := s_output_alu(1 downto 0); case v_output_alu_1_0 is when "00" => r_data_mem_out(7 downto 0) <= v_GeneralReg(to_integer(unsigned(r_rD_address)))(7 downto 0); when "01" => r_data_mem_out(15 downto 8) <= v_GeneralReg(to_integer(unsigned(r_rD_address)))(7 downto 0); when "10" => r_data_mem_out(23 downto 16) <= v_GeneralReg(to_integer(unsigned(r_rD_address)))(7 downto 0); when others => r_data_mem_out(31 downto 24) <= v_GeneralReg(to_integer(unsigned(r_rD_address)))(7 downto 0); end case; elsif r_op_load_store = "01" then if s_output_alu(1) = '0' then r_wr_en_mem_out <= "0011"; else r_wr_en_mem_out <= "1100"; end if; v_output_alu_1_0 := s_output_alu(1 downto 0); case v_output_alu_1_0 is when "00" => r_data_mem_out(15 downto 0) <= v_GeneralReg(to_integer(unsigned(r_rD_address)))(15 downto 0); when others => r_data_mem_out(31 downto 16) <= v_GeneralReg(to_integer(unsigned(r_rD_address)))(15 downto 0); end case; elsif r_op_load_store = "10" then r_wr_en_mem_out <= "1111"; r_data_mem_out <= v_GeneralReg(to_integer(unsigned(r_rD_address))); if r_load_store_exclusive = '1' then r_MSR(MSR_C) <= '0'; end if; end if; elsif r_is_imm_instruction = '1' then v_GeneralReg(to_integer(unsigned(r_rD_address))) <= v_GeneralReg(to_integer(unsigned(r_rD_address))); r_imm <= s_output_alu(15 downto 0); r_last_op_was_imm <= '1'; end if; end case; end if; end if; end process; -- Type B instruction, ALU input B depends of the precedent instruction s_input_alu_B <= r_input_alu_B when r_last_op_was_imm = '0' else (r_imm & r_input_alu_B(15 downto 0)); -- Carry input of the ALU depends of the bit C of the MSR s_carry_alu_in <= r_MSR(MSR_C); -- ALU i_ALU : ALU generic map( DATA_WIDTH => D_WIDTH ) port map( param_i => r_param_alu, carry_i => s_carry_alu_in, operandA_i => r_input_alu_A, operandB_i => s_input_alu_B, operandD_o => s_output_alu, status_o => s_status_alu ); -- =============================== -- Mapping output -- =============================== addr_mem_in_o <= std_logic_vector(r_addr_mem_in); rd_en_mem_in_o <= r_rd_en_mem_in; addr_mem_out_o <= r_addr_mem_out; data_mem_out_o <= r_data_mem_out; wr_en_mem_out_o <= r_wr_en_mem_out; end rtl;	mit	ce0cac8770c3f29c474c5a8523ed4fcf	0.439522	4.172011	false	false	false	false
mistryalok/Zedboard	learning/opencv_hls/xapp1167_vivado/sw/median/prj/solution1/syn/vhdl/FIFO_image_filter_img_0_cols_V_channel.vhd	4	4,628	-- ============================================================== -- File generated by Vivado(TM) HLS - High-Level Synthesis from C, C++ and SystemC -- Version: 2014.4 -- Copyright (C) 2014 Xilinx Inc. All rights reserved. -- -- ============================================================== library IEEE; use IEEE.std_logic_1164.all; use IEEE.std_logic_unsigned.all; entity FIFO_image_filter_img_0_cols_V_channel_shiftReg is generic ( DATA_WIDTH : integer := 12; ADDR_WIDTH : integer := 2; DEPTH : integer := 3); port ( clk : in std_logic; data : in std_logic_vector(DATA_WIDTH-1 downto 0); ce : in std_logic; a : in std_logic_vector(ADDR_WIDTH-1 downto 0); q : out std_logic_vector(DATA_WIDTH-1 downto 0)); end FIFO_image_filter_img_0_cols_V_channel_shiftReg; architecture rtl of FIFO_image_filter_img_0_cols_V_channel_shiftReg is --constant DEPTH_WIDTH: integer := 16; type SRL_ARRAY is array (0 to DEPTH-1) of std_logic_vector(DATA_WIDTH-1 downto 0); signal SRL_SIG : SRL_ARRAY; begin p_shift: process (clk) begin if (clk'event and clk = '1') then if (ce = '1') then SRL_SIG <= data & SRL_SIG(0 to DEPTH-2); end if; end if; end process; q <= SRL_SIG(conv_integer(a)); end rtl; library ieee; use ieee.std_logic_1164.all; use ieee.std_logic_unsigned.all; entity FIFO_image_filter_img_0_cols_V_channel is generic ( MEM_STYLE : string := "shiftreg"; DATA_WIDTH : integer := 12; ADDR_WIDTH : integer := 2; DEPTH : integer := 3); port ( clk : IN STD_LOGIC; reset : IN STD_LOGIC; if_empty_n : OUT STD_LOGIC; if_read_ce : IN STD_LOGIC; if_read : IN STD_LOGIC; if_dout : OUT STD_LOGIC_VECTOR(DATA_WIDTH - 1 downto 0); if_full_n : OUT STD_LOGIC; if_write_ce : IN STD_LOGIC; if_write : IN STD_LOGIC; if_din : IN STD_LOGIC_VECTOR(DATA_WIDTH - 1 downto 0)); end entity; architecture rtl of FIFO_image_filter_img_0_cols_V_channel is component FIFO_image_filter_img_0_cols_V_channel_shiftReg is generic ( DATA_WIDTH : integer := 12; ADDR_WIDTH : integer := 2; DEPTH : integer := 3); port ( clk : in std_logic; data : in std_logic_vector(DATA_WIDTH-1 downto 0); ce : in std_logic; a : in std_logic_vector(ADDR_WIDTH-1 downto 0); q : out std_logic_vector(DATA_WIDTH-1 downto 0)); end component; signal shiftReg_addr : STD_LOGIC_VECTOR(ADDR_WIDTH - 1 downto 0); signal shiftReg_data, shiftReg_q : STD_LOGIC_VECTOR(DATA_WIDTH - 1 downto 0); signal shiftReg_ce : STD_LOGIC; signal mOutPtr : STD_LOGIC_VECTOR(ADDR_WIDTH downto 0) := (others => '1'); signal internal_empty_n : STD_LOGIC := '0'; signal internal_full_n : STD_LOGIC := '1'; begin if_empty_n <= internal_empty_n; if_full_n <= internal_full_n; shiftReg_data <= if_din; if_dout <= shiftReg_q; process (clk) begin if clk'event and clk = '1' then if reset = '1' then mOutPtr <= (others => '1'); internal_empty_n <= '0'; internal_full_n <= '1'; else if ((if_read and if_read_ce) = '1' and internal_empty_n = '1') and ((if_write and if_write_ce) = '0' or internal_full_n = '0') then mOutPtr <= mOutPtr -1; if (mOutPtr = 0) then internal_empty_n <= '0'; end if; internal_full_n <= '1'; elsif ((if_read and if_read_ce) = '0' or internal_empty_n = '0') and ((if_write and if_write_ce) = '1' and internal_full_n = '1') then mOutPtr <= mOutPtr +1; internal_empty_n <= '1'; if (mOutPtr = DEPTH -2) then internal_full_n <= '0'; end if; end if; end if; end if; end process; shiftReg_addr <= (others => '0') when mOutPtr(ADDR_WIDTH) = '1' else mOutPtr(ADDR_WIDTH-1 downto 0); shiftReg_ce <= (if_write and if_write_ce) and internal_full_n; U_FIFO_image_filter_img_0_cols_V_channel_shiftReg : FIFO_image_filter_img_0_cols_V_channel_shiftReg generic map ( DATA_WIDTH => DATA_WIDTH, ADDR_WIDTH => ADDR_WIDTH, DEPTH => DEPTH) port map ( clk => clk, data => shiftReg_data, ce => shiftReg_ce, a => shiftReg_addr, q => shiftReg_q); end rtl;	gpl-3.0	0cff247708909cf76ad3ff91aad77838	0.539326	3.490196	false	false	false	false
mistryalok/Zedboard	learning/training/MSD/s09/axi_dma_sg/vivado/project_1/project_1.srcs/sources_1/ipshared/xilinx.com/axi_dma_v7_1/2a047f91/hdl/src/vhdl/axi_dma_lite_if.vhd	3	61,552	------------------------------------------------------------------------------- -- axi_dma_lite_if ------------------------------------------------------------------------------- -- -- *********************************************************************** -- -- (c) Copyright 2010, 2011 Xilinx, Inc. All rights reserved. -- -- This file contains confidential and proprietary information -- of Xilinx, Inc. and is protected under U.S. and -- international copyright and other intellectual property -- laws. -- -- DISCLAIMER -- This disclaimer is not a license and does not grant any -- rights to the materials distributed herewith. Except as -- otherwise provided in a valid license issued to you by -- Xilinx, and to the maximum extent permitted by applicable -- law: (1) THESE MATERIALS ARE MADE AVAILABLE "AS IS" AND -- WITH ALL FAULTS, AND XILINX HEREBY DISCLAIMS ALL WARRANTIES -- AND CONDITIONS, EXPRESS, IMPLIED, OR STATUTORY, INCLUDING -- BUT NOT LIMITED TO WARRANTIES OF MERCHANTABILITY, NON- -- INFRINGEMENT, OR FITNESS FOR ANY PARTICULAR PURPOSE; and -- (2) Xilinx shall not be liable (whether in contract or tort, -- including negligence, or under any other theory of -- liability) for any loss or damage of any kind or nature -- related to, arising under or in connection with these -- materials, including for any direct, or any indirect, -- special, incidental, or consequential loss or damage -- (including loss of data, profits, goodwill, or any type of -- loss or damage suffered as a result of any action brought -- by a third party) even if such damage or loss was -- reasonably foreseeable or Xilinx had been advised of the -- possibility of the same. -- -- CRITICAL APPLICATIONS -- Xilinx products are not designed or intended to be fail- -- safe, or for use in any application requiring fail-safe -- performance, such as life-support or safety devices or -- systems, Class III medical devices, nuclear facilities, -- applications related to the deployment of airbags, or any -- other applications that could lead to death, personal -- injury, or severe property or environmental damage -- (individually and collectively, "Critical -- Applications"). Customer assumes the sole risk and -- liability of any use of Xilinx products in Critical -- Applications, subject only to applicable laws and -- regulations governing limitations on product liability. -- -- THIS COPYRIGHT NOTICE AND DISCLAIMER MUST BE RETAINED AS -- PART OF THIS FILE AT ALL TIMES. -- -- ********************************************************************* -- ------------------------------------------------------------------------------- -- Filename: axi_dma_lite_if.vhd -- Description: This entity is AXI Lite Interface Module for the AXI DMA -- -- VHDL-Standard: VHDL'93 ------------------------------------------------------------------------------- ------------------------------------------------------------------------------- library ieee; use ieee.std_logic_1164.all; use ieee.numeric_std.all; use ieee.std_logic_misc.all; library unisim; use unisim.vcomponents.all; library axi_dma_v7_1; use axi_dma_v7_1.axi_dma_pkg.all; library lib_pkg_v1_0; library lib_cdc_v1_0; use lib_pkg_v1_0.lib_pkg.clog2; ------------------------------------------------------------------------------- entity axi_dma_lite_if is generic( C_NUM_CE : integer := 8 ; C_AXI_LITE_IS_ASYNC : integer range 0 to 1 := 0 ; C_S_AXI_LITE_ADDR_WIDTH : integer range 2 to 32 := 32 ; C_S_AXI_LITE_DATA_WIDTH : integer range 32 to 32 := 32 ); port ( -- Async clock input ip2axi_aclk : in std_logic ; -- ip2axi_aresetn : in std_logic ; -- ----------------------------------------------------------------------- -- AXI Lite Control Interface ----------------------------------------------------------------------- s_axi_lite_aclk : in std_logic ; -- s_axi_lite_aresetn : in std_logic ; -- -- -- AXI Lite Write Address Channel -- s_axi_lite_awvalid : in std_logic ; -- s_axi_lite_awready : out std_logic ; -- s_axi_lite_awaddr : in std_logic_vector -- (C_S_AXI_LITE_ADDR_WIDTH-1 downto 0); -- -- -- AXI Lite Write Data Channel -- s_axi_lite_wvalid : in std_logic ; -- s_axi_lite_wready : out std_logic ; -- s_axi_lite_wdata : in std_logic_vector -- (C_S_AXI_LITE_DATA_WIDTH-1 downto 0); -- -- -- AXI Lite Write Response Channel -- s_axi_lite_bresp : out std_logic_vector(1 downto 0) ; -- s_axi_lite_bvalid : out std_logic ; -- s_axi_lite_bready : in std_logic ; -- -- -- AXI Lite Read Address Channel -- s_axi_lite_arvalid : in std_logic ; -- s_axi_lite_arready : out std_logic ; -- s_axi_lite_araddr : in std_logic_vector -- (C_S_AXI_LITE_ADDR_WIDTH-1 downto 0); -- s_axi_lite_rvalid : out std_logic ; -- s_axi_lite_rready : in std_logic ; -- s_axi_lite_rdata : out std_logic_vector -- (C_S_AXI_LITE_DATA_WIDTH-1 downto 0); -- s_axi_lite_rresp : out std_logic_vector(1 downto 0) ; -- -- -- User IP Interface -- axi2ip_wrce : out std_logic_vector -- (C_NUM_CE-1 downto 0) ; -- axi2ip_wrdata : out std_logic_vector -- (C_S_AXI_LITE_DATA_WIDTH-1 downto 0); -- -- axi2ip_rdce : out std_logic_vector -- (C_NUM_CE-1 downto 0) ; -- axi2ip_rdaddr : out std_logic_vector -- (C_S_AXI_LITE_ADDR_WIDTH-1 downto 0); -- ip2axi_rddata : in std_logic_vector -- (C_S_AXI_LITE_DATA_WIDTH-1 downto 0) -- ); end axi_dma_lite_if; ------------------------------------------------------------------------------- -- Architecture ------------------------------------------------------------------------------- architecture implementation of axi_dma_lite_if is attribute DowngradeIPIdentifiedWarnings: string; attribute DowngradeIPIdentifiedWarnings of implementation : architecture is "yes"; ------------------------------------------------------------------------------- -- Functions ------------------------------------------------------------------------------- -- No Functions Declared ------------------------------------------------------------------------------- -- Constants Declarations ------------------------------------------------------------------------------- -- Register I/F Address offset constant ADDR_OFFSET : integer := clog2(C_S_AXI_LITE_DATA_WIDTH/8); -- Register I/F CE number constant CE_ADDR_SIZE : integer := clog2(C_NUM_CE); ------------------------------------------------------------------------------- -- Signal / Type Declarations ------------------------------------------------------------------------------- -- AXI Lite slave interface signals signal awvalid : std_logic := '0'; signal awaddr : std_logic_vector (C_S_AXI_LITE_ADDR_WIDTH-1 downto 0) := (others => '0'); signal wvalid : std_logic := '0'; signal wdata : std_logic_vector (C_S_AXI_LITE_DATA_WIDTH-1 downto 0) := (others => '0'); signal arvalid : std_logic := '0'; signal araddr : std_logic_vector (C_S_AXI_LITE_ADDR_WIDTH-1 downto 0) := (others => '0'); signal awvalid_d1 : std_logic := '0'; signal awvalid_re : std_logic := '0'; signal awready_i : std_logic := '0'; signal wvalid_d1 : std_logic := '0'; signal wvalid_re : std_logic := '0'; signal wready_i : std_logic := '0'; signal bvalid_i : std_logic := '0'; signal wr_addr_cap : std_logic := '0'; signal wr_data_cap : std_logic := '0'; -- AXI to IP interface signals signal axi2ip_wraddr_i : std_logic_vector (C_S_AXI_LITE_ADDR_WIDTH-1 downto 0) := (others => '0'); signal axi2ip_wrdata_i : std_logic_vector (C_S_AXI_LITE_DATA_WIDTH-1 downto 0) := (others => '0'); signal axi2ip_wren : std_logic := '0'; signal wrce : std_logic_vector(C_NUM_CE-1 downto 0); signal rdce : std_logic_vector(C_NUM_CE-1 downto 0) := (others => '0'); signal arvalid_d1 : std_logic := '0'; signal arvalid_re : std_logic := '0'; signal arvalid_re_d1 : std_logic := '0'; signal arvalid_i : std_logic := '0'; signal arready_i : std_logic := '0'; signal rvalid : std_logic := '0'; signal axi2ip_rdaddr_i : std_logic_vector (C_S_AXI_LITE_ADDR_WIDTH-1 downto 0) := (others => '0'); signal s_axi_lite_rvalid_i : std_logic := '0'; signal read_in_progress : std_logic := '0'; -- CR607165 signal rst_rvalid_re : std_logic := '0'; -- CR576999 signal rst_wvalid_re : std_logic := '0'; -- CR576999 signal rdy : std_logic := '0'; signal rdy1 : std_logic := '0'; signal wr_in_progress : std_logic := '0'; ------------------------------------------------------------------------------- -- Begin architecture logic ------------------------------------------------------------------------------- begin --************************************************************************* -- AXI LITE READ --*************************************************************************** s_axi_lite_wready <= wready_i; s_axi_lite_awready <= awready_i; s_axi_lite_arready <= arready_i; s_axi_lite_bvalid <= bvalid_i; ------------------------------------------------------------------------------- -- Register AXI Inputs ------------------------------------------------------------------------------- REG_INPUTS : process(s_axi_lite_aclk) begin if(s_axi_lite_aclk'EVENT and s_axi_lite_aclk = '1')then if(s_axi_lite_aresetn = '0')then awvalid <= '0' ; awaddr <= (others => '0') ; wvalid <= '0' ; wdata <= (others => '0') ; arvalid <= '0' ; araddr <= (others => '0') ; else awvalid <= s_axi_lite_awvalid ; awaddr <= s_axi_lite_awaddr ; wvalid <= s_axi_lite_wvalid ; wdata <= s_axi_lite_wdata ; arvalid <= s_axi_lite_arvalid ; araddr <= s_axi_lite_araddr ; end if; end if; end process REG_INPUTS; -- s_axi_lite_aclk is synchronous to ip clock GEN_SYNC_WRITE : if C_AXI_LITE_IS_ASYNC = 0 generate begin ------------------------------------------------------------------------------- -- Assert Write Adddress Ready Handshake -- Capture rising edge of valid and register out as ready. This creates -- a 3 clock cycle address phase but also registers all inputs and outputs. -- Note : Single clock cycle address phase can be accomplished using -- combinatorial logic. ------------------------------------------------------------------------------- REG_AWVALID : process(s_axi_lite_aclk) begin if(s_axi_lite_aclk'EVENT and s_axi_lite_aclk = '1')then if(s_axi_lite_aresetn = '0' or rst_wvalid_re = '1')then awvalid_d1 <= '0'; -- awvalid_re <= '0'; -- CR605883 else awvalid_d1 <= awvalid; -- awvalid_re <= awvalid and not awvalid_d1; -- CR605883 end if; end if; end process REG_AWVALID; awvalid_re <= awvalid and not awvalid_d1 and (not (wr_in_progress)); -- CR605883 ------------------------------------------------------------------------------- -- Capture assertion of awvalid to indicate that we have captured -- a valid address ------------------------------------------------------------------------------- ------------------------------------------------------------------------------- -- Assert Write Data Ready Handshake -- Capture rising edge of valid and register out as ready. This creates -- a 3 clock cycle address phase but also registers all inputs and outputs. -- Note : Single clock cycle address phase can be accomplished using -- combinatorial logic. ------------------------------------------------------------------------------- REG_WVALID : process(s_axi_lite_aclk) begin if(s_axi_lite_aclk'EVENT and s_axi_lite_aclk = '1')then if(s_axi_lite_aresetn = '0' or rst_wvalid_re = '1')then wvalid_d1 <= '0'; -- wvalid_re <= '0'; else wvalid_d1 <= wvalid; -- wvalid_re <= wvalid and not wvalid_d1; -- CR605883 end if; end if; end process REG_WVALID; wvalid_re <= wvalid and not wvalid_d1; -- CR605883 WRITE_IN_PROGRESS : process(s_axi_lite_aclk) begin if(s_axi_lite_aclk'EVENT and s_axi_lite_aclk = '1')then if(s_axi_lite_aresetn = '0' or rst_wvalid_re = '1')then wr_in_progress <= '0'; elsif(awvalid_re = '1')then wr_in_progress <= '1'; end if; end if; end process WRITE_IN_PROGRESS; -- CR605883 (CDC) provide pure register output to synchronizers --wvalid_re <= wvalid and not wvalid_d1 and not rst_wvalid_re; ------------------------------------------------------------------------------- -- Capture assertion of wvalid to indicate that we have captured -- valid data ------------------------------------------------------------------------------- WRDATA_CAP_FLAG : process(s_axi_lite_aclk) begin if(s_axi_lite_aclk'EVENT and s_axi_lite_aclk = '1')then if(s_axi_lite_aresetn = '0' or rdy = '1')then wr_data_cap <= '0'; elsif(wvalid_re = '1')then wr_data_cap <= '1'; end if; end if; end process WRDATA_CAP_FLAG; REG_WREADY : process(s_axi_lite_aclk) begin if(s_axi_lite_aclk'EVENT and s_axi_lite_aclk = '1')then if(s_axi_lite_aresetn = '0' or rdy = '1') then rdy <= '0'; elsif (wr_data_cap = '1' and wr_addr_cap = '1') then rdy <= '1'; end if; wready_i <= rdy; awready_i <= rdy; rdy1 <= rdy; end if; end process REG_WREADY; WRADDR_CAP_FLAG : process(s_axi_lite_aclk) begin if(s_axi_lite_aclk'EVENT and s_axi_lite_aclk = '1')then if(s_axi_lite_aresetn = '0' or rdy = '1')then wr_addr_cap <= '0'; elsif(awvalid_re = '1')then wr_addr_cap <= '1'; end if; end if; end process WRADDR_CAP_FLAG; ------------------------------------------------------------------------------- -- Capture Write Address ------------------------------------------------------------------------------- REG_WRITE_ADDRESS : process(s_axi_lite_aclk) begin if(s_axi_lite_aclk'EVENT and s_axi_lite_aclk = '1')then if(s_axi_lite_aresetn = '0')then -- axi2ip_wraddr_i <= (others => '0'); -- Register address on valid elsif(awvalid_re = '1')then -- axi2ip_wraddr_i <= awaddr; end if; end if; end process REG_WRITE_ADDRESS; ------------------------------------------------------------------------------- -- Capture Write Data ------------------------------------------------------------------------------- REG_WRITE_DATA : process(s_axi_lite_aclk) begin if(s_axi_lite_aclk'EVENT and s_axi_lite_aclk = '1')then if(s_axi_lite_aresetn = '0')then axi2ip_wrdata_i <= (others => '0'); -- Register address and assert ready elsif(wvalid_re = '1')then axi2ip_wrdata_i <= wdata; end if; end if; end process REG_WRITE_DATA; ------------------------------------------------------------------------------- -- Must have both a valid address and valid data before updating -- a register. Note in AXI write address can come before or -- after AXI write data. -- axi2ip_wren <= '1' when wr_data_cap = '1' and wr_addr_cap = '1' -- else '0'; axi2ip_wren <= rdy; -- or rdy1; ------------------------------------------------------------------------------- -- Decode and assert proper chip enable per captured axi lite write address ------------------------------------------------------------------------------- WRCE_GEN: for j in 0 to C_NUM_CE - 1 generate constant BAR : std_logic_vector(CE_ADDR_SIZE-1 downto 0) := std_logic_vector(to_unsigned(j,CE_ADDR_SIZE)); begin wrce(j) <= axi2ip_wren when s_axi_lite_awaddr ((CE_ADDR_SIZE + ADDR_OFFSET) - 1 downto ADDR_OFFSET) = BAR(CE_ADDR_SIZE-1 downto 0) else '0'; end generate WRCE_GEN; ------------------------------------------------------------------------------- -- register write ce's and data out to axi dma register module ------------------------------------------------------------------------------- REG_WR_OUT : process(s_axi_lite_aclk) begin if(s_axi_lite_aclk'EVENT and s_axi_lite_aclk = '1')then if(s_axi_lite_aresetn = '0')then axi2ip_wrce <= (others => '0'); -- axi2ip_wrdata <= (others => '0'); else axi2ip_wrce <= wrce; -- axi2ip_wrdata <= axi2ip_wrdata_i; end if; end if; end process REG_WR_OUT; axi2ip_wrdata <= s_axi_lite_wdata; ------------------------------------------------------------------------------- -- Write Response ------------------------------------------------------------------------------- s_axi_lite_bresp <= OKAY_RESP; WRESP_PROCESS : process(s_axi_lite_aclk) begin if(s_axi_lite_aclk'EVENT and s_axi_lite_aclk = '1')then if(s_axi_lite_aresetn = '0')then bvalid_i <= '0'; rst_wvalid_re <= '0'; -- CR576999 -- If response issued and target indicates ready then -- clear response elsif(bvalid_i = '1' and s_axi_lite_bready = '1')then bvalid_i <= '0'; rst_wvalid_re <= '0'; -- CR576999 -- Issue a resonse on write elsif(rdy1 = '1')then bvalid_i <= '1'; rst_wvalid_re <= '1'; -- CR576999 end if; end if; end process WRESP_PROCESS; end generate GEN_SYNC_WRITE; -- s_axi_lite_aclk is asynchronous to ip clock GEN_ASYNC_WRITE : if C_AXI_LITE_IS_ASYNC = 1 generate -- Data support ----------------------------------------------------------------------------- -- ATTRIBUTE Declarations ----------------------------------------------------------------------------- -- Prevent x-propagation on clock-domain crossing register ATTRIBUTE async_reg : STRING; Attribute KEEP : string; -- declaration Attribute EQUIVALENT_REGISTER_REMOVAL : string; -- declaration signal ip_wvalid_d1_cdc_to : std_logic := '0'; signal ip_wvalid_d2 : std_logic := '0'; signal ip_wvalid_re : std_logic := '0'; signal wr_wvalid_re_cdc_from : std_logic := '0'; signal wr_data_cdc_from : std_logic_vector -- CR605883 (C_S_AXI_LITE_DATA_WIDTH-1 downto 0) := (others => '0'); -- CR605883 signal wdata_d1_cdc_to : std_logic_vector (C_S_AXI_LITE_DATA_WIDTH-1 downto 0) := (others => '0'); signal wdata_d2 : std_logic_vector (C_S_AXI_LITE_DATA_WIDTH-1 downto 0) := (others => '0'); signal axi2ip_wrdata_cdc_tig : std_logic_vector (C_S_AXI_LITE_DATA_WIDTH-1 downto 0) := (others => '0'); signal ip_data_cap : std_logic := '0'; -- Address support signal ip_awvalid_d1_cdc_to : std_logic := '0'; signal ip_awvalid_d2 : std_logic := '0'; signal ip_awvalid_re : std_logic := '0'; signal wr_awvalid_re_cdc_from : std_logic := '0'; signal wr_addr_cdc_from : std_logic_vector -- CR605883 (C_S_AXI_LITE_ADDR_WIDTH-1 downto 0) := (others => '0'); -- CR605883 signal awaddr_d1_cdc_tig : std_logic_vector (C_S_AXI_LITE_ADDR_WIDTH-1 downto 0) := (others => '0'); signal awaddr_d2 : std_logic_vector (C_S_AXI_LITE_ADDR_WIDTH-1 downto 0) := (others => '0'); signal ip_addr_cap : std_logic := '0'; -- Bvalid support signal lite_data_cap_d1 : std_logic := '0'; signal lite_data_cap_d2 : std_logic := '0'; signal lite_addr_cap_d1 : std_logic := '0'; signal lite_addr_cap_d2 : std_logic := '0'; signal lite_axi2ip_wren : std_logic := '0'; signal awvalid_cdc_from : std_logic := '0'; signal awvalid_cdc_to : std_logic := '0'; signal awvalid_to : std_logic := '0'; signal awvalid_to2 : std_logic := '0'; --ATTRIBUTE async_reg OF awvalid_cdc_to : SIGNAL IS "true"; --ATTRIBUTE async_reg OF awvalid_to : SIGNAL IS "true"; signal wvalid_cdc_from : std_logic := '0'; signal wvalid_cdc_to : std_logic := '0'; signal wvalid_to : std_logic := '0'; signal wvalid_to2 : std_logic := '0'; --ATTRIBUTE async_reg OF wvalid_cdc_to : SIGNAL IS "true"; --ATTRIBUTE async_reg OF wvalid_to : SIGNAL IS "true"; signal rdy_cdc_to : std_logic := '0'; signal rdy_cdc_from : std_logic := '0'; signal rdy_to : std_logic := '0'; signal rdy_to2 : std_logic := '0'; signal rdy_to2_cdc_from : std_logic := '0'; signal rdy_out : std_logic := '0'; --ATTRIBUTE async_reg OF rdy_cdc_to : SIGNAL IS "true"; --ATTRIBUTE async_reg OF rdy_to : SIGNAL IS "true"; Attribute KEEP of rdy_to2_cdc_from : signal is "TRUE"; Attribute EQUIVALENT_REGISTER_REMOVAL of rdy_to2_cdc_from : signal is "no"; signal rdy_back_cdc_to : std_logic := '0'; signal rdy_back_to : std_logic :='0'; --ATTRIBUTE async_reg OF rdy_back_cdc_to : SIGNAL IS "true"; --ATTRIBUTE async_reg OF rdy_back_to : SIGNAL IS "true"; signal rdy_back : std_logic := '0'; signal rdy_shut : std_logic := '0'; begin REG_AWVALID : process(s_axi_lite_aclk) begin if(s_axi_lite_aclk'EVENT and s_axi_lite_aclk = '1')then if(s_axi_lite_aresetn = '0' or rst_wvalid_re = '1')then awvalid_d1 <= '0'; else awvalid_d1 <= awvalid; end if; end if; end process REG_AWVALID; awvalid_re <= awvalid and not awvalid_d1 and (not (wr_in_progress)); -- CR605883 ------------------------------------------------------------------------------- -- Capture assertion of awvalid to indicate that we have captured -- a valid address ------------------------------------------------------------------------------- ------------------------------------------------------------------------------- -- Assert Write Data Ready Handshake -- Capture rising edge of valid and register out as ready. This creates -- a 3 clock cycle address phase but also registers all inputs and outputs. -- Note : Single clock cycle address phase can be accomplished using -- combinatorial logic. ------------------------------------------------------------------------------- REG_WVALID : process(s_axi_lite_aclk) begin if(s_axi_lite_aclk'EVENT and s_axi_lite_aclk = '1')then if(s_axi_lite_aresetn = '0' or rst_wvalid_re = '1')then wvalid_d1 <= '0'; else wvalid_d1 <= wvalid; end if; end if; end process REG_WVALID; wvalid_re <= wvalid and not wvalid_d1; -- CR605883 --********************************************************************* -- Write Address Support --*********************************************************************** AWVLD_CDC_FROM : process(s_axi_lite_aclk) begin if(s_axi_lite_aclk'EVENT and s_axi_lite_aclk = '1')then if(s_axi_lite_aresetn = '0' or rst_wvalid_re = '1')then awvalid_cdc_from <= '0'; elsif(awvalid_re = '1')then awvalid_cdc_from <= '1'; end if; end if; end process AWVLD_CDC_FROM; AWVLD_CDC_TO : entity lib_cdc_v1_0.cdc_sync generic map ( C_CDC_TYPE => 1, C_RESET_STATE => 0, C_SINGLE_BIT => 1, C_VECTOR_WIDTH => 32, C_MTBF_STAGES => MTBF_STAGES ) port map ( prmry_aclk => s_axi_lite_aclk, prmry_resetn => '0', prmry_in => awvalid_cdc_from, prmry_vect_in => (others => '0'), scndry_aclk => ip2axi_aclk, scndry_resetn => '0', scndry_out => awvalid_to, scndry_vect_out => open ); -- AWVLD_CDC_TO : process(ip2axi_aclk) -- begin -- if(ip2axi_aclk'EVENT and ip2axi_aclk = '1')then -- awvalid_cdc_to <= awvalid_cdc_from; -- awvalid_to <= awvalid_cdc_to; -- end if; -- end process AWVLD_CDC_TO; AWVLD_CDC_TO2 : process(ip2axi_aclk) begin if(ip2axi_aclk'EVENT and ip2axi_aclk = '1')then if(ip2axi_aresetn = '0')then awvalid_to2 <= '0'; else awvalid_to2 <= awvalid_to; end if; end if; end process AWVLD_CDC_TO2; ip_awvalid_re <= awvalid_to and (not awvalid_to2); WVLD_CDC_FROM : process(s_axi_lite_aclk) begin if(s_axi_lite_aclk'EVENT and s_axi_lite_aclk = '1')then if(s_axi_lite_aresetn = '0' or rst_wvalid_re = '1')then wvalid_cdc_from <= '0'; elsif(wvalid_re = '1')then wvalid_cdc_from <= '1'; end if; end if; end process WVLD_CDC_FROM; WVLD_CDC_TO : entity lib_cdc_v1_0.cdc_sync generic map ( C_CDC_TYPE => 1, C_RESET_STATE => 0, C_SINGLE_BIT => 1, C_VECTOR_WIDTH => 32, C_MTBF_STAGES => MTBF_STAGES ) port map ( prmry_aclk => s_axi_lite_aclk, prmry_resetn => '0', prmry_in => wvalid_cdc_from, prmry_vect_in => (others => '0'), scndry_aclk => ip2axi_aclk, scndry_resetn => '0', scndry_out => wvalid_to, scndry_vect_out => open ); -- WVLD_CDC_TO : process(ip2axi_aclk) -- begin -- if(ip2axi_aclk'EVENT and ip2axi_aclk = '1')then -- wvalid_cdc_to <= wvalid_cdc_from; -- wvalid_to <= wvalid_cdc_to; -- end if; -- end process WVLD_CDC_TO; WVLD_CDC_TO2 : process(ip2axi_aclk) begin if(ip2axi_aclk'EVENT and ip2axi_aclk = '1')then if(ip2axi_aresetn = '0')then wvalid_to2 <= '0'; else wvalid_to2 <= wvalid_to; end if; end if; end process WVLD_CDC_TO2; ip_wvalid_re <= wvalid_to and (not wvalid_to2); REG_WADDR_TO_IPCLK : entity lib_cdc_v1_0.cdc_sync generic map ( C_CDC_TYPE => 1, C_RESET_STATE => 0, C_SINGLE_BIT => 0, C_VECTOR_WIDTH => C_S_AXI_LITE_ADDR_WIDTH, C_MTBF_STAGES => 1 ) port map ( prmry_aclk => s_axi_lite_aclk, prmry_resetn => '0', prmry_in => '0', prmry_vect_in => s_axi_lite_awaddr, scndry_aclk => ip2axi_aclk, scndry_resetn => '0', scndry_out => open, scndry_vect_out => awaddr_d1_cdc_tig ); REG_WADDR_TO_IPCLK1 : entity lib_cdc_v1_0.cdc_sync generic map ( C_CDC_TYPE => 1, C_RESET_STATE => 0, C_SINGLE_BIT => 0, C_VECTOR_WIDTH => C_S_AXI_LITE_DATA_WIDTH, C_MTBF_STAGES => 1 ) port map ( prmry_aclk => s_axi_lite_aclk, prmry_resetn => '0', prmry_in => '0', prmry_vect_in => s_axi_lite_wdata, scndry_aclk => ip2axi_aclk, scndry_resetn => '0', scndry_out => open, scndry_vect_out => axi2ip_wrdata_cdc_tig ); -- Double register address in -- REG_WADDR_TO_IPCLK : process(ip2axi_aclk) -- begin -- if(ip2axi_aclk'EVENT and ip2axi_aclk = '1')then -- if(ip2axi_aresetn = '0')then -- awaddr_d1_cdc_tig <= (others => '0'); -- -- axi2ip_wraddr_i <= (others => '0'); -- axi2ip_wrdata_cdc_tig <= (others => '0'); -- else -- awaddr_d1_cdc_tig <= s_axi_lite_awaddr; -- axi2ip_wrdata_cdc_tig <= s_axi_lite_wdata; -- -- axi2ip_wraddr_i <= awaddr_d1_cdc_tig; -- CR605883 -- end if; -- end if; -- end process REG_WADDR_TO_IPCLK; -- Flag that address has been captured REG_IP_ADDR_CAP : process(ip2axi_aclk) begin if(ip2axi_aclk'EVENT and ip2axi_aclk = '1')then if(ip2axi_aresetn = '0' or rdy_shut = '1')then ip_addr_cap <= '0'; elsif(ip_awvalid_re = '1')then ip_addr_cap <= '1'; end if; end if; end process REG_IP_ADDR_CAP; REG_WREADY : process(ip2axi_aclk) begin if(ip2axi_aclk'EVENT and ip2axi_aclk = '1')then if(ip2axi_aresetn = '0' or rdy_shut = '1') then -- or rdy = '1') then rdy <= '0'; elsif (ip_data_cap = '1' and ip_addr_cap = '1') then rdy <= '1'; end if; end if; end process REG_WREADY; REG3_WREADY : entity lib_cdc_v1_0.cdc_sync generic map ( C_CDC_TYPE => 1, C_RESET_STATE => 0, C_SINGLE_BIT => 1, C_VECTOR_WIDTH => 32, C_MTBF_STAGES => MTBF_STAGES ) port map ( prmry_aclk => s_axi_lite_aclk, prmry_resetn => '0', prmry_in => rdy_to2_cdc_from, prmry_vect_in => (others => '0'), scndry_aclk => ip2axi_aclk, scndry_resetn => '0', scndry_out => rdy_back_to, scndry_vect_out => open ); -- REG3_WREADY : process(ip2axi_aclk) -- begin -- if(ip2axi_aclk'EVENT and ip2axi_aclk = '1')then -- rdy_back_cdc_to <= rdy_to2_cdc_from; -- rdy_back_to <= rdy_back_cdc_to; -- end if; -- end process REG3_WREADY; REG3_WREADY2 : process(ip2axi_aclk) begin if(ip2axi_aclk'EVENT and ip2axi_aclk = '1')then if(ip2axi_aresetn = '0') then rdy_back <= '0'; else rdy_back <= rdy_back_to; end if; end if; end process REG3_WREADY2; rdy_shut <= rdy_back_to and (not rdy_back); REG1_WREADY : process(ip2axi_aclk) begin if(ip2axi_aclk'EVENT and ip2axi_aclk = '1')then if(ip2axi_aresetn = '0' or rdy_shut = '1') then rdy_cdc_from <= '0'; elsif (rdy = '1') then rdy_cdc_from <= '1'; end if; end if; end process REG1_WREADY; REG2_WREADY : entity lib_cdc_v1_0.cdc_sync generic map ( C_CDC_TYPE => 1, C_RESET_STATE => 0, C_SINGLE_BIT => 1, C_VECTOR_WIDTH => 32, C_MTBF_STAGES => MTBF_STAGES ) port map ( prmry_aclk => ip2axi_aclk, prmry_resetn => '0', prmry_in => rdy_cdc_from, prmry_vect_in => (others => '0'), scndry_aclk => s_axi_lite_aclk, scndry_resetn => '0', scndry_out => rdy_to, scndry_vect_out => open ); -- REG2_WREADY : process(s_axi_lite_aclk) -- begin -- if(s_axi_lite_aclk'EVENT and s_axi_lite_aclk = '1')then -- rdy_cdc_to <= rdy_cdc_from; -- rdy_to <= rdy_cdc_to; -- end if; -- end process REG2_WREADY; REG2_WREADY2 : process(s_axi_lite_aclk) begin if(s_axi_lite_aclk'EVENT and s_axi_lite_aclk = '1')then if(s_axi_lite_aresetn = '0') then rdy_to2 <= '0'; rdy_to2_cdc_from <= '0'; else rdy_to2 <= rdy_to; rdy_to2_cdc_from <= rdy_to; end if; end if; end process REG2_WREADY2; rdy_out <= not (rdy_to) and rdy_to2; wready_i <= rdy_out; awready_i <= rdy_out; --********************************************************************* -- Write Data Support --*********************************************************************** ------------------------------------------------------------------------------- -- Capture write data ------------------------------------------------------------------------------- -- WRDATA_S_H : process(s_axi_lite_aclk) -- begin -- if(s_axi_lite_aclk'EVENT and s_axi_lite_aclk = '1')then -- if(s_axi_lite_aresetn = '0')then -- wr_data_cdc_from <= (others => '0'); -- elsif(wvalid_re = '1')then -- wr_data_cdc_from <= wdata; -- end if; -- end if; -- end process WRDATA_S_H; -- Flag that data has been captured REG_IP_DATA_CAP : process(ip2axi_aclk) begin if(ip2axi_aclk'EVENT and ip2axi_aclk = '1')then if(ip2axi_aresetn = '0' or rdy_shut = '1')then ip_data_cap <= '0'; elsif(ip_wvalid_re = '1')then ip_data_cap <= '1'; end if; end if; end process REG_IP_DATA_CAP; -- Must have both a valid address and valid data before updating -- a register. Note in AXI write address can come before or -- after AXI write data. axi2ip_wren <= rdy; -- axi2ip_wren <= '1' when ip_data_cap = '1' and ip_addr_cap = '1' -- else '0'; ------------------------------------------------------------------------------- -- Decode and assert proper chip enable per captured axi lite write address ------------------------------------------------------------------------------- WRCE_GEN: for j in 0 to C_NUM_CE - 1 generate constant BAR : std_logic_vector(CE_ADDR_SIZE-1 downto 0) := std_logic_vector(to_unsigned(j,CE_ADDR_SIZE)); begin wrce(j) <= axi2ip_wren when awaddr_d1_cdc_tig ((CE_ADDR_SIZE + ADDR_OFFSET) - 1 downto ADDR_OFFSET) = BAR(CE_ADDR_SIZE-1 downto 0) else '0'; end generate WRCE_GEN; ------------------------------------------------------------------------------- -- register write ce's and data out to axi dma register module ------------------------------------------------------------------------------- REG_WR_OUT : process(ip2axi_aclk) begin if(ip2axi_aclk'EVENT and ip2axi_aclk = '1')then if(ip2axi_aresetn = '0')then axi2ip_wrce <= (others => '0'); else axi2ip_wrce <= wrce; end if; end if; end process REG_WR_OUT; axi2ip_wrdata <= axi2ip_wrdata_cdc_tig; --s_axi_lite_wdata; --********************************************************************* -- Write Response Support --*********************************************************************** -- Minimum of 2 IP clocks for addr and data capture, therefore delaying -- Lite clock addr and data capture by 2 Lite clocks will guarenttee bvalid -- responce occurs after write data acutally written. -- REG_ALIGN_CAP : process(s_axi_lite_aclk) -- begin -- if(s_axi_lite_aclk'EVENT and s_axi_lite_aclk = '1')then -- if(s_axi_lite_aresetn = '0')then -- lite_data_cap_d1 <= '0'; -- lite_data_cap_d2 <= '0'; -- lite_addr_cap_d1 <= '0'; -- lite_addr_cap_d2 <= '0'; -- else -- lite_data_cap_d1 <= rdy; --wr_data_cap; -- lite_data_cap_d2 <= lite_data_cap_d1; -- lite_addr_cap_d1 <= rdy; --wr_addr_cap; -- lite_addr_cap_d2 <= lite_addr_cap_d1; -- end if; -- end if; -- end process REG_ALIGN_CAP; -- Pseudo write enable used simply to assert bvalid -- lite_axi2ip_wren <= rdy; --'1' when wr_data_cap = '1' and wr_addr_cap = '1' -- else '0'; WRESP_PROCESS : process(s_axi_lite_aclk) begin if(s_axi_lite_aclk'EVENT and s_axi_lite_aclk = '1')then if(s_axi_lite_aresetn = '0')then bvalid_i <= '0'; rst_wvalid_re <= '0'; -- CR576999 -- If response issued and target indicates ready then -- clear response elsif(bvalid_i = '1' and s_axi_lite_bready = '1')then bvalid_i <= '0'; rst_wvalid_re <= '0'; -- CR576999 -- Issue a resonse on write elsif(rdy_out = '1')then -- elsif(lite_axi2ip_wren = '1')then bvalid_i <= '1'; rst_wvalid_re <= '1'; -- CR576999 end if; end if; end process WRESP_PROCESS; s_axi_lite_bresp <= OKAY_RESP; end generate GEN_ASYNC_WRITE; --************************************************************************* -- AXI LITE READ --***************************************************************************** ------------------------------------------------------------------------------- -- Assert Read Adddress Ready Handshake -- Capture rising edge of valid and register out as ready. This creates -- a 3 clock cycle address phase but also registers all inputs and outputs. -- Note : Single clock cycle address phase can be accomplished using -- combinatorial logic. ------------------------------------------------------------------------------- REG_ARVALID : process(s_axi_lite_aclk) begin if(s_axi_lite_aclk'EVENT and s_axi_lite_aclk = '1')then if(s_axi_lite_aresetn = '0' or rst_rvalid_re = '1')then arvalid_d1 <= '0'; else arvalid_d1 <= arvalid; end if; end if; end process REG_ARVALID; arvalid_re <= arvalid and not arvalid_d1 and not rst_rvalid_re and not read_in_progress; -- CR607165 -- register for proper alignment REG_ARREADY : process(s_axi_lite_aclk) begin if(s_axi_lite_aclk'EVENT and s_axi_lite_aclk = '1')then if(s_axi_lite_aresetn = '0')then arready_i <= '0'; else arready_i <= arvalid_re; end if; end if; end process REG_ARREADY; -- Always respond 'okay' axi lite read s_axi_lite_rresp <= OKAY_RESP; s_axi_lite_rvalid <= s_axi_lite_rvalid_i; -- s_axi_lite_aclk is synchronous to ip clock GEN_SYNC_READ : if C_AXI_LITE_IS_ASYNC = 0 generate begin read_in_progress <= '0'; --Not used for sync mode (CR607165) ------------------------------------------------------------------------------- -- Capture Read Address ------------------------------------------------------------------------------- REG_READ_ADDRESS : process(s_axi_lite_aclk) begin if(s_axi_lite_aclk'EVENT and s_axi_lite_aclk = '1')then if(s_axi_lite_aresetn = '0')then axi2ip_rdaddr_i <= (others => '0'); -- Register address on valid elsif(arvalid_re = '1')then axi2ip_rdaddr_i <= araddr; end if; end if; end process REG_READ_ADDRESS; ------------------------------------------------------------------------------- -- Generate RdCE based on address match to address bar ------------------------------------------------------------------------------- RDCE_GEN: for j in 0 to C_NUM_CE - 1 generate constant BAR : std_logic_vector(CE_ADDR_SIZE-1 downto 0) := std_logic_vector(to_unsigned(j,CE_ADDR_SIZE)); begin rdce(j) <= arvalid_re_d1 when axi2ip_rdaddr_i((CE_ADDR_SIZE + ADDR_OFFSET) - 1 downto ADDR_OFFSET) = BAR(CE_ADDR_SIZE-1 downto 0) else '0'; end generate RDCE_GEN; ------------------------------------------------------------------------------- -- Register out to IP ------------------------------------------------------------------------------- REG_RDCNTRL_OUT : process(s_axi_lite_aclk) begin if(s_axi_lite_aclk'EVENT and s_axi_lite_aclk = '1')then if(s_axi_lite_aresetn = '0')then --axi2ip_rdce <= (others => '0'); axi2ip_rdaddr <= (others => '0'); else --axi2ip_rdce <= rdce; axi2ip_rdaddr <= axi2ip_rdaddr_i; end if; end if; end process REG_RDCNTRL_OUT; -- Sample and hold rdce value until rvalid assertion REG_RDCE_OUT : process(s_axi_lite_aclk) begin if(s_axi_lite_aclk'EVENT and s_axi_lite_aclk = '1')then if(s_axi_lite_aresetn = '0' or rst_rvalid_re = '1')then axi2ip_rdce <= (others => '0'); elsif(arvalid_re_d1 = '1')then axi2ip_rdce <= rdce; end if; end if; end process REG_RDCE_OUT; -- Register for proper alignment REG_RVALID : process(s_axi_lite_aclk) begin if(s_axi_lite_aclk'EVENT and s_axi_lite_aclk = '1')then if(s_axi_lite_aresetn = '0')then arvalid_re_d1 <= '0'; rvalid <= '0'; else arvalid_re_d1 <= arvalid_re; rvalid <= arvalid_re_d1; end if; end if; end process REG_RVALID; ------------------------------------------------------------------------------- -- Drive read data and read data valid out on capture of valid address. ------------------------------------------------------------------------------- REG_RD_OUT : process(s_axi_lite_aclk) begin if(s_axi_lite_aclk'EVENT and s_axi_lite_aclk = '1')then if(s_axi_lite_aresetn = '0')then s_axi_lite_rdata <= (others => '0'); s_axi_lite_rvalid_i <= '0'; rst_rvalid_re <= '0'; -- CR576999 -- If rvalid driving out to target and target indicates ready -- then de-assert rvalid. (structure guarentees min 1 clock of rvalid) elsif(s_axi_lite_rvalid_i = '1' and s_axi_lite_rready = '1')then s_axi_lite_rdata <= (others => '0'); s_axi_lite_rvalid_i <= '0'; rst_rvalid_re <= '0'; -- CR576999 -- If read cycle then assert rvalid and rdata out to target elsif(rvalid = '1')then s_axi_lite_rdata <= ip2axi_rddata; s_axi_lite_rvalid_i <= '1'; rst_rvalid_re <= '1'; -- CR576999 end if; end if; end process REG_RD_OUT; end generate GEN_SYNC_READ; -- s_axi_lite_aclk is asynchronous to ip clock GEN_ASYNC_READ : if C_AXI_LITE_IS_ASYNC = 1 generate ATTRIBUTE async_reg : STRING; signal ip_arvalid_d1_cdc_tig : std_logic := '0'; signal ip_arvalid_d2 : std_logic := '0'; signal ip_arvalid_d3 : std_logic := '0'; signal ip_arvalid_re : std_logic := '0'; signal araddr_d1_cdc_tig : std_logic_vector(C_S_AXI_LITE_ADDR_WIDTH-1 downto 0) :=(others => '0'); signal araddr_d2 : std_logic_vector(C_S_AXI_LITE_ADDR_WIDTH-1 downto 0) :=(others => '0'); signal araddr_d3 : std_logic_vector(C_S_AXI_LITE_ADDR_WIDTH-1 downto 0) :=(others => '0'); signal lite_rdata_cdc_from : std_logic_vector(C_S_AXI_LITE_DATA_WIDTH-1 downto 0) :=(others => '0'); signal lite_rdata_d1_cdc_to : std_logic_vector(C_S_AXI_LITE_DATA_WIDTH-1 downto 0) :=(others => '0'); signal lite_rdata_d2 : std_logic_vector(C_S_AXI_LITE_DATA_WIDTH-1 downto 0) :=(others => '0'); --ATTRIBUTE async_reg OF ip_arvalid_d1_cdc_tig : SIGNAL IS "true"; --ATTRIBUTE async_reg OF ip_arvalid_d2 : SIGNAL IS "true"; --ATTRIBUTE async_reg OF araddr_d1_cdc_tig : SIGNAL IS "true"; --ATTRIBUTE async_reg OF araddr_d2 : SIGNAL IS "true"; --ATTRIBUTE async_reg OF lite_rdata_d1_cdc_to : SIGNAL IS "true"; --ATTRIBUTE async_reg OF lite_rdata_d2 : SIGNAL IS "true"; signal p_pulse_s_h : std_logic := '0'; signal p_pulse_s_h_clr : std_logic := '0'; signal s_pulse_d1 : std_logic := '0'; signal s_pulse_d2 : std_logic := '0'; signal s_pulse_d3 : std_logic := '0'; signal s_pulse_re : std_logic := '0'; signal p_pulse_re_d1 : std_logic := '0'; signal p_pulse_re_d2 : std_logic := '0'; signal p_pulse_re_d3 : std_logic := '0'; signal arready_d1 : std_logic := '0'; -- CR605883 signal arready_d2 : std_logic := '0'; -- CR605883 signal arready_d3 : std_logic := '0'; -- CR605883 signal arready_d4 : std_logic := '0'; -- CR605883 signal arready_d5 : std_logic := '0'; -- CR605883 signal arready_d6 : std_logic := '0'; -- CR605883 signal arready_d7 : std_logic := '0'; -- CR605883 signal arready_d8 : std_logic := '0'; -- CR605883 signal arready_d9 : std_logic := '0'; -- CR605883 signal arready_d10 : std_logic := '0'; -- CR605883 signal arready_d11 : std_logic := '0'; -- CR605883 signal arready_d12 : std_logic := '0'; -- CR605883 begin -- CR607165 -- Flag to prevent overlapping reads RD_PROGRESS : process(s_axi_lite_aclk) begin if(s_axi_lite_aclk'EVENT and s_axi_lite_aclk = '1')then if(s_axi_lite_aresetn = '0' or rst_rvalid_re = '1')then read_in_progress <= '0'; elsif(arvalid_re = '1')then read_in_progress <= '1'; end if; end if; end process RD_PROGRESS; -- Double register address in REG_RADDR_TO_IPCLK : entity lib_cdc_v1_0.cdc_sync generic map ( C_CDC_TYPE => 1, C_RESET_STATE => 0, C_SINGLE_BIT => 0, C_VECTOR_WIDTH => C_S_AXI_LITE_ADDR_WIDTH, C_MTBF_STAGES => MTBF_STAGES ) port map ( prmry_aclk => s_axi_lite_aclk, prmry_resetn => '0', prmry_in => '0', prmry_vect_in => s_axi_lite_araddr, scndry_aclk => ip2axi_aclk, scndry_resetn => '0', scndry_out => open, scndry_vect_out => araddr_d3 ); -- REG_RADDR_TO_IPCLK : process(ip2axi_aclk) -- begin -- if(ip2axi_aclk'EVENT and ip2axi_aclk = '1')then -- if(ip2axi_aresetn = '0')then -- araddr_d1_cdc_tig <= (others => '0'); -- araddr_d2 <= (others => '0'); -- araddr_d3 <= (others => '0'); -- else -- araddr_d1_cdc_tig <= s_axi_lite_araddr; -- araddr_d2 <= araddr_d1_cdc_tig; -- araddr_d3 <= araddr_d2; -- end if; -- end if; -- end process REG_RADDR_TO_IPCLK; -- Latch and hold read address REG_ARADDR_PROCESS : process(ip2axi_aclk) begin if(ip2axi_aclk'EVENT and ip2axi_aclk = '1')then if(ip2axi_aresetn = '0')then axi2ip_rdaddr_i <= (others => '0'); elsif(ip_arvalid_re = '1')then axi2ip_rdaddr_i <= araddr_d3; end if; end if; end process REG_ARADDR_PROCESS; axi2ip_rdaddr <= axi2ip_rdaddr_i; -- Register awready into IP clock domain. awready -- is a 1 axi_lite clock delay of the rising edge of -- arvalid. This provides a signal that asserts when -- araddr is known to be stable. REG_ARVALID_TO_IPCLK : entity lib_cdc_v1_0.cdc_sync generic map ( C_CDC_TYPE => 1, C_RESET_STATE => 0, C_SINGLE_BIT => 1, C_VECTOR_WIDTH => C_S_AXI_LITE_ADDR_WIDTH, C_MTBF_STAGES => MTBF_STAGES ) port map ( prmry_aclk => s_axi_lite_aclk, prmry_resetn => '0', prmry_in => arready_i, prmry_vect_in => (others => '0'), scndry_aclk => ip2axi_aclk, scndry_resetn => '0', scndry_out => ip_arvalid_d2, scndry_vect_out => open ); REG_ARVALID_TO_IPCLK1 : process(ip2axi_aclk) begin if(ip2axi_aclk'EVENT and ip2axi_aclk = '1')then if(ip2axi_aresetn = '0')then -- ip_arvalid_d1_cdc_tig <= '0'; -- ip_arvalid_d2 <= '0'; ip_arvalid_d3 <= '0'; else -- ip_arvalid_d1_cdc_tig <= arready_i; -- ip_arvalid_d2 <= ip_arvalid_d1_cdc_tig; ip_arvalid_d3 <= ip_arvalid_d2; end if; end if; end process REG_ARVALID_TO_IPCLK1; ip_arvalid_re <= ip_arvalid_d2 and not ip_arvalid_d3; ------------------------------------------------------------------------------- -- Generate Read CE's ------------------------------------------------------------------------------- RDCE_GEN: for j in 0 to C_NUM_CE - 1 generate constant BAR : std_logic_vector(CE_ADDR_SIZE-1 downto 0) := std_logic_vector(to_unsigned(j,CE_ADDR_SIZE)); begin rdce(j) <= ip_arvalid_re when araddr_d3((CE_ADDR_SIZE + ADDR_OFFSET) - 1 downto ADDR_OFFSET) = BAR(CE_ADDR_SIZE-1 downto 0) else '0'; end generate RDCE_GEN; ------------------------------------------------------------------------------- -- Register RDCE and RD Data out to IP ------------------------------------------------------------------------------- REG_RDCNTRL_OUT : process(ip2axi_aclk) begin if(ip2axi_aclk'EVENT and ip2axi_aclk = '1')then if(ip2axi_aresetn = '0')then axi2ip_rdce <= (others => '0'); elsif(ip_arvalid_re = '1')then axi2ip_rdce <= rdce; else axi2ip_rdce <= (others => '0'); end if; end if; end process REG_RDCNTRL_OUT; -- Generate sample and hold pulse to capture read data from IP REG_RVALID : process(ip2axi_aclk) begin if(ip2axi_aclk'EVENT and ip2axi_aclk = '1')then if(ip2axi_aresetn = '0')then rvalid <= '0'; else rvalid <= ip_arvalid_re; end if; end if; end process REG_RVALID; ------------------------------------------------------------------------------- -- Sample and hold read data from IP ------------------------------------------------------------------------------- S_H_READ_DATA : process(ip2axi_aclk) begin if(ip2axi_aclk'EVENT and ip2axi_aclk = '1')then if(ip2axi_aresetn = '0')then lite_rdata_cdc_from <= (others => '0'); -- If read cycle then assert rvalid and rdata out to target elsif(rvalid = '1')then lite_rdata_cdc_from <= ip2axi_rddata; end if; end if; end process S_H_READ_DATA; -- Cross read data to axi_lite clock domain REG_DATA2LITE_CLOCK : entity lib_cdc_v1_0.cdc_sync generic map ( C_CDC_TYPE => 1, C_RESET_STATE => 0, C_SINGLE_BIT => 0, C_VECTOR_WIDTH => 32, C_MTBF_STAGES => MTBF_STAGES ) port map ( prmry_aclk => ip2axi_aclk, prmry_resetn => '0', prmry_in => '0', --lite_rdata_cdc_from, prmry_vect_in => lite_rdata_cdc_from, scndry_aclk => s_axi_lite_aclk, scndry_resetn => '0', scndry_out => open, --lite_rdata_d2, scndry_vect_out => lite_rdata_d2 ); -- REG_DATA2LITE_CLOCK : process(s_axi_lite_aclk) -- begin -- if(s_axi_lite_aclk'EVENT and s_axi_lite_aclk = '1')then -- if(s_axi_lite_aresetn = '0')then -- lite_rdata_d1_cdc_to <= (others => '0'); -- lite_rdata_d2 <= (others => '0'); -- else -- lite_rdata_d1_cdc_to <= lite_rdata_cdc_from; -- lite_rdata_d2 <= lite_rdata_d1_cdc_to; -- end if; -- end if; -- end process REG_DATA2LITE_CLOCK; -- CR605883 (CDC) modified to remove -- Because axi_lite_aclk must be less than or equal to ip2axi_aclk -- then read data will appear a maximum 6 clocks from assertion -- of arready. REG_ALIGN_RDATA_LATCH : process(s_axi_lite_aclk) begin if(s_axi_lite_aclk'EVENT and s_axi_lite_aclk = '1')then if(s_axi_lite_aresetn = '0')then arready_d1 <= '0'; arready_d2 <= '0'; arready_d3 <= '0'; arready_d4 <= '0'; arready_d5 <= '0'; arready_d6 <= '0'; arready_d7 <= '0'; arready_d8 <= '0'; arready_d9 <= '0'; arready_d10 <= '0'; arready_d11 <= '0'; arready_d12 <= '0'; else arready_d1 <= arready_i; arready_d2 <= arready_d1; arready_d3 <= arready_d2; arready_d4 <= arready_d3; arready_d5 <= arready_d4; arready_d6 <= arready_d5; arready_d7 <= arready_d6; arready_d8 <= arready_d7; arready_d9 <= arready_d8; arready_d10 <= arready_d9; arready_d11 <= arready_d10; arready_d12 <= arready_d11; end if; end if; end process REG_ALIGN_RDATA_LATCH; ------------------------------------------------------------------------------- -- Drive read data and read data valid out on capture of valid address. ------------------------------------------------------------------------------- REG_RD_OUT : process(s_axi_lite_aclk) begin if(s_axi_lite_aclk'EVENT and s_axi_lite_aclk = '1')then if(s_axi_lite_aresetn = '0')then s_axi_lite_rdata <= (others => '0'); s_axi_lite_rvalid_i <= '0'; rst_rvalid_re <= '0'; -- CR576999 -- If rvalid driving out to target and target indicates ready -- then de-assert rvalid. (structure guarentees min 1 clock of rvalid) elsif(s_axi_lite_rvalid_i = '1' and s_axi_lite_rready = '1')then s_axi_lite_rdata <= (others => '0'); s_axi_lite_rvalid_i <= '0'; rst_rvalid_re <= '0'; -- CR576999 -- If read cycle then assert rvalid and rdata out to target -- CR605883 --elsif(s_pulse_re = '1')then elsif(arready_d12 = '1')then s_axi_lite_rdata <= lite_rdata_d2; s_axi_lite_rvalid_i <= '1'; rst_rvalid_re <= '1'; -- CR576999 end if; end if; end process REG_RD_OUT; end generate GEN_ASYNC_READ; end implementation;	gpl-3.0	a49b7840501260aa0af25dbe2a11f8f6	0.426306	4.126575	false	false	false	false
marco-c/leon-nexys2	grlib-gpl-1.3.4-b4140/designs/leon3-xilinx-sp605/leon3mp.vhd	1	35,477	----------------------------------------------------------------------------- -- LEON3 Xilinx SP605 Demonstration design -- Copyright (C) 2011 Jiri Gaisler, Aeroflex Gaisler ------------------------------------------------------------------------------ -- This file is a part of the GRLIB VHDL IP LIBRARY -- Copyright (C) 2003 - 2008, Gaisler Research -- Copyright (C) 2008 - 2013, Aeroflex Gaisler -- -- This program is free software; you can redistribute it and/or modify -- it under the terms of the GNU General Public License as published by -- the Free Software Foundation; either version 2 of the License, or -- (at your option) any later version. -- -- This program is distributed in the hope that it will be useful, -- but WITHOUT ANY WARRANTY; without even the implied warranty of -- MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the -- GNU General Public License for more details. -- -- You should have received a copy of the GNU General Public License -- along with this program; if not, write to the Free Software -- Foundation, Inc., 59 Temple Place, Suite 330, Boston, MA 02111-1307 USA ------------------------------------------------------------------------------ library ieee; use ieee.std_logic_1164.all; library grlib, techmap; use grlib.amba.all; use grlib.amba.all; use grlib.stdlib.all; use techmap.gencomp.all; use techmap.allclkgen.all; library gaisler; use gaisler.memctrl.all; use gaisler.leon3.all; use gaisler.uart.all; use gaisler.misc.all; use gaisler.spi.all; use gaisler.i2c.all; use gaisler.can.all; use gaisler.net.all; use gaisler.jtag.all; use gaisler.spacewire.all; -- pragma translate_off use gaisler.sim.all; library unisim; use unisim.ODDR2; -- pragma translate_on library esa; use esa.memoryctrl.all; use work.config.all; use work.pcie.all; entity leon3mp is generic ( fabtech : integer := CFG_FABTECH; memtech : integer := CFG_MEMTECH; padtech : integer := CFG_PADTECH; clktech : integer := CFG_CLKTECH; disas : integer := CFG_DISAS; -- Enable disassembly to console dbguart : integer := CFG_DUART; -- Print UART on console pclow : integer := CFG_PCLOW ); port ( reset : in std_ulogic; clk27 : in std_ulogic; -- 27 MHz clock clk200p : in std_ulogic; -- 200 MHz clock clk200n : in std_ulogic; -- 200 MHz clock clk33 : in std_ulogic; -- 32 MHz clock from sysace address : out std_logic_vector(23 downto 0); data : inout std_logic_vector(15 downto 0); oen : out std_ulogic; writen : out std_ulogic; romsn : out std_logic; ddr_clk : out std_logic; ddr_clkb : out std_logic; ddr_cke : out std_logic; ddr_odt : out std_logic; ddr_reset_n : out std_logic; ddr_we : out std_ulogic; -- ddr write enable ddr_ras : out std_ulogic; -- ddr ras ddr_cas : out std_ulogic; -- ddr cas ddr_dm : out std_logic_vector (1 downto 0); -- ddr dm ddr_dqs : inout std_logic_vector (1 downto 0); -- ddr dqs ddr_dqs_n : inout std_logic_vector (1 downto 0); -- ddr dqs_n ddr_ad : out std_logic_vector (12 downto 0); -- ddr address ddr_ba : out std_logic_vector (2 downto 0); -- ddr bank address ddr_dq : inout std_logic_vector (15 downto 0); -- ddr data ddr_rzq : inout std_ulogic; ddr_zio : inout std_ulogic; txd1 : out std_ulogic; -- UART1 tx data rxd1 : in std_ulogic; -- UART1 rx data ctsn1 : in std_ulogic; -- UART1 ctsn rtsn1 : out std_ulogic; -- UART1 trsn button : inout std_logic_vector(3 downto 0); -- I/O port switch : inout std_logic_vector(3 downto 0); -- I/O port led : out std_logic_vector(3 downto 0); -- I/O port phy_gtx_clk : out std_logic; phy_mii_data : inout std_logic; -- ethernet PHY interface phy_tx_clk : in std_ulogic; phy_rx_clk : in std_ulogic; phy_rx_data : in std_logic_vector(7 downto 0); phy_dv : in std_ulogic; phy_rx_er : in std_ulogic; phy_col : in std_ulogic; phy_crs : in std_ulogic; phy_tx_data : out std_logic_vector(7 downto 0); phy_tx_en : out std_ulogic; phy_tx_er : out std_ulogic; phy_mii_clk : out std_ulogic; phy_rst_n : out std_ulogic; phy_mii_int_n : in std_ulogic; iic_scl : inout std_ulogic; iic_sda : inout std_ulogic; ddc_scl : inout std_ulogic; ddc_sda : inout std_ulogic; dvi_iic_scl : inout std_logic; dvi_iic_sda : inout std_logic; tft_lcd_data : out std_logic_vector(11 downto 0); tft_lcd_clk_p : out std_ulogic; tft_lcd_clk_n : out std_ulogic; tft_lcd_hsync : out std_ulogic; tft_lcd_vsync : out std_ulogic; tft_lcd_de : out std_ulogic; tft_lcd_reset_b : out std_ulogic; -- SPI flash spi_sel_n : inout std_ulogic; spi_clk : out std_ulogic; spi_mosi : out std_ulogic; --pcie pci_exp_txp : out std_logic; pci_exp_txn : out std_logic; pci_exp_rxp : in std_logic; pci_exp_rxn : in std_logic; sys_clk_p : in std_logic; sys_clk_n : in std_logic; sys_reset_n : in std_logic; sysace_mpa : out std_logic_vector(6 downto 0); sysace_mpce : out std_ulogic; sysace_mpirq : in std_ulogic; sysace_mpoe : out std_ulogic; sysace_mpwe : out std_ulogic; sysace_d : inout std_logic_vector(7 downto 0) ); end; architecture rtl of leon3mp is --attribute syn_netlist_hierarchy : boolean; --attribute syn_netlist_hierarchy of rtl : architecture is false; component ODDR2 generic ( DDR_ALIGNMENT : string := "NONE"; INIT : bit := '0'; SRTYPE : string := "SYNC" ); port ( Q : out std_ulogic; C0 : in std_ulogic; C1 : in std_ulogic; CE : in std_ulogic := 'H'; D0 : in std_ulogic; D1 : in std_ulogic; R : in std_ulogic := 'L'; S : in std_ulogic := 'L' ); end component; constant blength : integer := 12; constant fifodepth : integer := 8; constant maxahbm : integer := CFG_NCPU+CFG_GRETH+CFG_AHB_JTAG+CFG_PCIEXP; signal vcc, gnd : std_logic; signal memi : memory_in_type; signal memo : memory_out_type; signal wpo : wprot_out_type; signal sdi : sdctrl_in_type; signal sdo : sdram_out_type; signal apbi : apb_slv_in_type; signal apbo : apb_slv_out_vector := (others => apb_none); signal ahbsi : ahb_slv_in_type; signal ahbso : ahb_slv_out_vector := (others => ahbs_none); signal ahbmi : ahb_mst_in_type; signal vahbmi : ahb_mst_in_type; signal ahbmo : ahb_mst_out_vector := (others => ahbm_none); signal vahbmo : ahb_mst_out_type; signal clkm, rstn, rstraw, sdclkl : std_ulogic; signal clk_200 : std_ulogic; signal clk25, clk40, clk65 : std_ulogic; signal cgi, cgi2 : clkgen_in_type; signal cgo, cgo2 : clkgen_out_type; signal u1i, u2i, dui : uart_in_type; signal u1o, u2o, duo : uart_out_type; signal irqi : irq_in_vector(0 to CFG_NCPU-1); signal irqo : irq_out_vector(0 to CFG_NCPU-1); signal dbgi : l3_debug_in_vector(0 to CFG_NCPU-1); signal dbgo : l3_debug_out_vector(0 to CFG_NCPU-1); signal dsui : dsu_in_type; signal dsuo : dsu_out_type; signal ethi : eth_in_type; signal etho : eth_out_type; signal egtx_clk :std_ulogic; signal negtx_clk :std_ulogic; signal gpti : gptimer_in_type; signal gpto : gptimer_out_type; signal gpioi : gpio_in_type; signal gpioo : gpio_out_type; signal clklock, elock, ulock : std_ulogic; signal lock, calib_done, clkml, lclk, rst, ndsuact : std_ulogic; signal tck, tckn, tms, tdi, tdo : std_ulogic; signal ethclk : std_ulogic; signal vgao : apbvga_out_type; signal lcd_datal : std_logic_vector(11 downto 0); signal lcd_hsyncl, lcd_vsyncl, lcd_del, lcd_reset_bl : std_ulogic; signal i2ci, dvi_i2ci : i2c_in_type; signal i2co, dvi_i2co : i2c_out_type; signal spmi : spimctrl_in_type; signal spmo : spimctrl_out_type; signal spmi2 : spimctrl_in_type; signal spmo2 : spimctrl_out_type; constant BOARD_FREQ : integer := 33000; -- input frequency in KHz constant CPU_FREQ : integer := BOARD_FREQ * CFG_CLKMUL / CFG_CLKDIV; -- cpu frequency in KHz constant IOAEN : integer := CFG_GRACECTRL; constant DDR2_FREQ : integer := 200000; -- DDR2 input frequency in KHz signal stati : ahbstat_in_type; signal fpi : grfpu_in_vector_type; signal fpo : grfpu_out_vector_type; -- Used for connecting input/output signals to the DDR2 controller signal core_ddr_clk : std_logic_vector(2 downto 0); signal core_ddr_clkb : std_logic_vector(2 downto 0); signal core_ddr_cke : std_logic_vector(1 downto 0); signal core_ddr_csb : std_logic_vector(1 downto 0); signal core_ddr_ad : std_logic_vector(13 downto 0); signal core_ddr_odt : std_logic_vector(1 downto 0); signal video_clk : std_ulogic; -- signals to vga_clkgen. signal clk_sel : std_logic_vector(1 downto 0); signal clkvga, clkvga_p, clkvga_n : std_ulogic; signal acei : gracectrl_in_type; signal aceo : gracectrl_out_type; attribute keep : boolean; attribute syn_keep : boolean; attribute syn_preserve : boolean; attribute syn_keep of video_clk : signal is true; attribute syn_preserve of video_clk : signal is true; attribute keep of video_clk : signal is true; attribute syn_preserve of clkm : signal is true; attribute keep of clkm : signal is true; begin ---------------------------------------------------------------------- --- Reset and Clock generation ------------------------------------- ---------------------------------------------------------------------- vcc <= '1'; gnd <= '0'; cgi.pllctrl <= "00"; cgi.pllrst <= rstraw; ethclk <= lclk; clk_pad : clkpad generic map (tech => padtech) port map (clk33, lclk); clkgen0 : clkgen -- clock generator generic map (clktech, CFG_CLKMUL, CFG_CLKDIV, CFG_MCTRL_SDEN, CFG_CLK_NOFB, 0, 0, 0, BOARD_FREQ) port map (lclk, lclk, clkm, open, open, sdclkl, open, cgi, cgo, open, open, open); reset_pad : inpad generic map (tech => padtech) port map (reset, rst); rst0 : rstgen -- reset generator generic map (acthigh => 1) port map (rst, clkm, lock, rstn, rstraw); lock <= cgo.clklock and calib_done when CFG_MIG_DDR2 = 1 else cgo.clklock; ---------------------------------------------------------------------- --- AHB CONTROLLER -------------------------------------------------- ---------------------------------------------------------------------- ahb0 : ahbctrl -- AHB arbiter/multiplexer generic map (defmast => CFG_DEFMST, split => CFG_SPLIT, rrobin => CFG_RROBIN, ioaddr => CFG_AHBIO, fpnpen => CFG_FPNPEN, ioen => IOAEN, nahbm => maxahbm, nahbs => 16) port map (rstn, clkm, ahbmi, ahbmo, ahbsi, ahbso); ---------------------------------------------------------------------- --- LEON3 processor and DSU ----------------------------------------- ---------------------------------------------------------------------- nosh : if CFG_GRFPUSH = 0 generate cpu : for i in 0 to CFG_NCPU-1 generate l3ft : if CFG_LEON3FT_EN /= 0 generate leon3ft0 : leon3ft -- LEON3 processor generic map (i, fabtech, memtech, CFG_NWIN, CFG_DSU, CFG_FPU(1-CFG_GRFPUSH), CFG_V8, 0, CFG_MAC, pclow, CFG_NOTAG, CFG_NWP, CFG_ICEN, CFG_IREPL, CFG_ISETS, CFG_ILINE, CFG_ISETSZ, CFG_ILOCK, CFG_DCEN, CFG_DREPL, CFG_DSETS, CFG_DLINE, CFG_DSETSZ, CFG_DLOCK, CFG_DSNOOP, CFG_ILRAMEN, CFG_ILRAMSZ, CFG_ILRAMADDR, CFG_DLRAMEN, CFG_DLRAMSZ, CFG_DLRAMADDR, CFG_MMUEN, CFG_ITLBNUM, CFG_DTLBNUM, CFG_TLB_TYPE, CFG_TLB_REP, CFG_LDDEL, disas, CFG_ITBSZ, CFG_PWD, CFG_SVT, CFG_RSTADDR, CFG_NCPU-1, CFG_IUFT_EN, CFG_FPUFT_EN, CFG_CACHE_FT_EN, CFG_RF_ERRINJ, CFG_CACHE_ERRINJ, CFG_DFIXED, CFG_LEON3_NETLIST, CFG_SCAN, CFG_MMU_PAGE) port map (clkm, rstn, ahbmi, ahbmo(i), ahbsi, ahbso, irqi(i), irqo(i), dbgi(i), dbgo(i), clkm); end generate; l3s : if CFG_LEON3FT_EN = 0 generate u0 : leon3s -- LEON3 processor generic map (i, fabtech, memtech, CFG_NWIN, CFG_DSU, CFG_FPU(1-CFG_GRFPUSH), CFG_V8, 0, CFG_MAC, pclow, CFG_NOTAG, CFG_NWP, CFG_ICEN, CFG_IREPL, CFG_ISETS, CFG_ILINE, CFG_ISETSZ, CFG_ILOCK, CFG_DCEN, CFG_DREPL, CFG_DSETS, CFG_DLINE, CFG_DSETSZ, CFG_DLOCK, CFG_DSNOOP, CFG_ILRAMEN, CFG_ILRAMSZ, CFG_ILRAMADDR, CFG_DLRAMEN, CFG_DLRAMSZ, CFG_DLRAMADDR, CFG_MMUEN, CFG_ITLBNUM, CFG_DTLBNUM, CFG_TLB_TYPE, CFG_TLB_REP, CFG_LDDEL, disas, CFG_ITBSZ, CFG_PWD, CFG_SVT, CFG_RSTADDR, CFG_NCPU-1, CFG_DFIXED, CFG_SCAN, CFG_MMU_PAGE, CFG_BP) port map (clkm, rstn, ahbmi, ahbmo(i), ahbsi, ahbso, irqi(i), irqo(i), dbgi(i), dbgo(i)); end generate; end generate; end generate; sh : if CFG_GRFPUSH = 1 generate cpu : for i in 0 to CFG_NCPU-1 generate l3ft : if CFG_LEON3FT_EN /= 0 generate leon3ft0 : leon3ftsh -- LEON3 processor generic map (i, fabtech, memtech, CFG_NWIN, CFG_DSU, CFG_FPU, CFG_V8, 0, CFG_MAC, pclow, CFG_NOTAG, CFG_NWP, CFG_ICEN, CFG_IREPL, CFG_ISETS, CFG_ILINE, CFG_ISETSZ, CFG_ILOCK, CFG_DCEN, CFG_DREPL, CFG_DSETS, CFG_DLINE, CFG_DSETSZ, CFG_DLOCK, CFG_DSNOOP, CFG_ILRAMEN, CFG_ILRAMSZ, CFG_ILRAMADDR, CFG_DLRAMEN, CFG_DLRAMSZ, CFG_DLRAMADDR, CFG_MMUEN, CFG_ITLBNUM, CFG_DTLBNUM, CFG_TLB_TYPE, CFG_TLB_REP, CFG_LDDEL, disas, CFG_ITBSZ, CFG_PWD, CFG_SVT, CFG_RSTADDR, CFG_NCPU-1, CFG_IUFT_EN, CFG_FPUFT_EN, CFG_CACHE_FT_EN, CFG_RF_ERRINJ, CFG_CACHE_ERRINJ, CFG_DFIXED, CFG_LEON3_NETLIST, CFG_SCAN, CFG_MMU_PAGE) port map (clkm, rstn, ahbmi, ahbmo(i), ahbsi, ahbso, irqi(i), irqo(i), dbgi(i), dbgo(i), clkm, fpi(i), fpo(i)); end generate; l3s : if CFG_LEON3FT_EN = 0 generate u0 : leon3sh -- LEON3 processor generic map (i, fabtech, memtech, CFG_NWIN, CFG_DSU, CFG_FPU, CFG_V8, 0, CFG_MAC, pclow, CFG_NOTAG, CFG_NWP, CFG_ICEN, CFG_IREPL, CFG_ISETS, CFG_ILINE, CFG_ISETSZ, CFG_ILOCK, CFG_DCEN, CFG_DREPL, CFG_DSETS, CFG_DLINE, CFG_DSETSZ, CFG_DLOCK, CFG_DSNOOP, CFG_ILRAMEN, CFG_ILRAMSZ, CFG_ILRAMADDR, CFG_DLRAMEN, CFG_DLRAMSZ, CFG_DLRAMADDR, CFG_MMUEN, CFG_ITLBNUM, CFG_DTLBNUM, CFG_TLB_TYPE, CFG_TLB_REP, CFG_LDDEL, disas, CFG_ITBSZ, CFG_PWD, CFG_SVT, CFG_RSTADDR, CFG_NCPU-1, CFG_DFIXED, CFG_SCAN, CFG_MMU_PAGE) port map (clkm, rstn, ahbmi, ahbmo(i), ahbsi, ahbso, irqi(i), irqo(i), dbgi(i), dbgo(i), fpi(i), fpo(i)); end generate; end generate; grfpush0 : grfpushwx generic map ((CFG_FPU-1), CFG_NCPU, fabtech) port map (clkm, rstn, fpi, fpo); end generate; led1_pad : odpad generic map (tech => padtech) port map (led(1), dbgo(0).error); dsugen : if CFG_DSU = 1 generate dsu0 : dsu3 -- LEON3 Debug Support Unit generic map (hindex => 2, haddr => 16#900#, hmask => 16#F00#, ncpu => CFG_NCPU, tbits => 30, tech => memtech, irq => 0, kbytes => CFG_ATBSZ) port map (rstn, clkm, ahbmi, ahbsi, ahbso(2), dbgo, dbgi, dsui, dsuo); dsui.enable <= '1'; dsui.break <= button(3); dsuact_pad : outpad generic map (tech => padtech) port map (led(0), ndsuact); ndsuact <= not dsuo.active; end generate; nodsu : if CFG_DSU = 0 generate dsuo.tstop <= '0'; dsuo.active <= '0'; ahbso(2) <= ahbs_none; end generate; ahbjtaggen0 :if CFG_AHB_JTAG = 1 generate ahbjtag0 : ahbjtag generic map(tech => fabtech, hindex => CFG_NCPU) port map(rstn, clkm, tck, tms, tdi, tdo, ahbmi, ahbmo(CFG_NCPU), open, open, open, open, open, open, open, gnd); end generate; ---------------------------------------------------------------------- --- Memory controllers ---------------------------------------------- ---------------------------------------------------------------------- memi.writen <= '1'; memi.wrn <= "1111"; memi.bwidth <= "01"; memi.brdyn <= '0'; memi.bexcn <= '1'; mctrl_gen : if CFG_MCTRL_LEON2 /= 0 generate mctrl0 : mctrl generic map (hindex => 0, pindex => 0, paddr => 0, srbanks => 2, ram8 => CFG_MCTRL_RAM8BIT, ram16 => CFG_MCTRL_RAM16BIT, sden => CFG_MCTRL_SDEN, invclk => CFG_CLK_NOFB, sepbus => CFG_MCTRL_SEPBUS, pageburst => CFG_MCTRL_PAGE, rammask => 0, iomask => 0) port map (rstn, clkm, memi, memo, ahbsi, ahbso(0), apbi, apbo(0), wpo, sdo); addr_pad : outpadv generic map (width => 24, tech => padtech) port map (address, memo.address(24 downto 1)); roms_pad : outpad generic map (tech => padtech) port map (romsn, memo.romsn(0)); oen_pad : outpad generic map (tech => padtech) port map (oen, memo.oen); wri_pad : outpad generic map (tech => padtech) port map (writen, memo.writen); data_pad : iopadvv generic map (tech => padtech, width => 16) port map (data(15 downto 0), memo.data(31 downto 16), memo.vbdrive(31 downto 16), memi.data(31 downto 16)); end generate; nomctrl : if CFG_MCTRL_LEON2 = 0 generate roms_pad : outpad generic map (tech => padtech) port map (romsn, vcc); --ahbso(0) <= ahbso_none; end generate; ----------------------------------------------------------------------- --- Test report module ---------------------------------------------- ----------------------------------------------------------------------- -- pragma translate_off test0 : ahbrep generic map (hindex => 6, haddr => 16#200#) port map (rstn, clkm, ahbsi, ahbso(6)); -- pragma translate_on ---------------------------------------------------------------------- --- DDR2 memory controller ------------------------------------------ ---------------------------------------------------------------------- mig_gen : if (CFG_MIG_DDR2 = 1) generate ddrc : entity work.ahb2mig_sp605 generic map( hindex => 4, haddr => 16#400#, hmask => 16#F80#, pindex => 4, paddr => 4, vgamst => CFG_SVGA_ENABLE, vgaburst => 64) port map( mcb3_dram_dq => ddr_dq, mcb3_dram_a => ddr_ad, mcb3_dram_ba => ddr_ba, mcb3_dram_ras_n => ddr_ras, mcb3_dram_cas_n => ddr_cas, mcb3_dram_we_n => ddr_we, mcb3_dram_odt => ddr_odt, mcb3_dram_reset_n=> ddr_reset_n, mcb3_dram_cke => ddr_cke, mcb3_dram_dm => ddr_dm(0), mcb3_dram_udqs => ddr_dqs(1), mcb3_dram_udqs_n=> ddr_dqs_n(1), mcb3_rzq => ddr_rzq, mcb3_zio => ddr_zio, mcb3_dram_udm => ddr_dm(1), mcb3_dram_dqs => ddr_dqs(0), mcb3_dram_dqs_n => ddr_dqs_n(0), mcb3_dram_ck => ddr_clk, mcb3_dram_ck_n => ddr_clkb, ahbsi => ahbsi, ahbso => ahbso(4), ahbmi => vahbmi, ahbmo => vahbmo, apbi => apbi, apbo => apbo(4), calib_done => calib_done, rst_n_syn => rstn, rst_n_async => rstraw, clk_amba => clkm, clk_mem_p => clk200p, clk_mem_n => clk200n, clk_125 => egtx_clk, clk_50 => video_clk ); end generate; led(2) <= calib_done; led(3) <= lock; noddr : if CFG_MIG_DDR2 = 0 generate lock <= '1'; end generate; -----------------PCI-EXPRESS-Master-Target------------------------------------------ pcie_mt : if CFG_PCIE_TYPE = 1 generate -- master/target without fifo EP:pcie_master_target_sp605 generic map ( master => CFG_PCIE_SIM_MAS, hmstndx => CFG_NCPU+CFG_GRETH+CFG_AHB_JTAG, hslvndx => 7, abits => 21, device_id => CFG_PCIEXPDID, -- PCIE device ID vendor_id => CFG_PCIEXPVID, -- PCIE vendor ID nsync => 2, -- 1 or 2 sync regs between clocks pcie_bar_mask => 16#FFE#, haddr => 16#a00#, hmask => 16#fff#, pindex => 5, paddr => 5, pmask => 16#fff# ) port map( rst => rstn, clk => clkm, -- System Interface sys_clk_p => sys_clk_p, sys_clk_n => sys_clk_n, sys_reset_n => sys_reset_n, -- PCI Express Fabric Interface pci_exp_txp => pci_exp_txp, pci_exp_txn => pci_exp_txn, pci_exp_rxp => pci_exp_rxp, pci_exp_rxn => pci_exp_rxn, ahbso => ahbso(7), ahbsi => ahbsi, apbi => apbi, apbo => apbo(5), ahbmi => ahbmi, ahbmo => ahbmo(CFG_NCPU+CFG_GRETH+CFG_AHB_JTAG) ); end generate; ---------------------------------------------------------------------- -----------------PCI-EXPRESS-Master-FIFO------------------------------------------ pcie_mf_dma : if CFG_PCIE_TYPE = 3 generate -- master with fifo and DMA dma:pciedma generic map (memtech => memtech, dmstndx => CFG_NCPU+CFG_GRETH+CFG_AHB_JTAG, dapbndx => 7, dapbaddr => 7,dapbmask => 16#FFF#, dapbirq => 4, blength => 12, device_id => CFG_PCIEXPDID, vendor_id => CFG_PCIEXPVID, slvndx => 7, apbndx => 5, apbaddr => 5, apbmask =>16#FFF#, haddr => 16#A00#, hmask => 16#FFF#, nsync => 2, pcie_bar_mask => 16#FFE# ) port map( rst => rstn, clk => clkm, -- System Interface sys_clk_p => sys_clk_p, sys_clk_n => sys_clk_n, sys_reset_n => sys_reset_n, -- PCI Express Fabric Interface pci_exp_txp => pci_exp_txp, pci_exp_txn => pci_exp_txn, pci_exp_rxp => pci_exp_rxp, pci_exp_rxn => pci_exp_rxn, dapbo => apbo(7), dahbmo =>ahbmo(CFG_NCPU+CFG_GRETH+CFG_AHB_JTAG), apbi =>apbi, apbo =>apbo(5), ahbmi =>ahbmi, ahbsi =>ahbsi, ahbso =>ahbso(7) ); end generate; pcie_mf: if CFG_PCIE_TYPE = 2 generate -- master with fifo EP:pcie_master_fifo_sp605 generic map ( memtech => memtech, hslvndx => 7, device_id => CFG_PCIEXPDID, -- PCIE device ID vendor_id => CFG_PCIEXPVID, -- PCIE vendor ID nsync => 2, -- 1 or 2 sync regs between clocks pcie_bar_mask => 16#FFE#, haddr => 16#A00#, hmask => 16#fff#, pindex => 5, paddr => 5, pmask => 16#fff#) port map( rst => rstn, clk => clkm, -- System In sys_clk_p => sys_clk_p, sys_clk_n => sys_clk_n, sys_reset_n => sys_reset_n, -- PCI Expre pci_exp_txp => pci_exp_txp, pci_exp_txn => pci_exp_txn, pci_exp_rxp => pci_exp_rxp, pci_exp_rxn => pci_exp_rxn, ahbso => ahbso(7), ahbsi => ahbsi, apbi => apbi, apbo => apbo(5) ); end generate; ---------------------------------------------------------------------- ---------------------------------------------------------------------- ---------------------------------------------------------------------- --- SPI Memory Controller-------------------------------------------- ---------------------------------------------------------------------- spimc: if CFG_SPICTRL_ENABLE = 0 and CFG_SPIMCTRL = 1 generate spimctrl0 : spimctrl -- SPI Memory Controller generic map (hindex => 3, hirq => 5, faddr => 16#e00#, fmask => 16#ff8#, ioaddr => 16#002#, iomask => 16#fff#, spliten => CFG_SPLIT, oepol => 0, sdcard => CFG_SPIMCTRL_SDCARD, readcmd => CFG_SPIMCTRL_READCMD, dummybyte => CFG_SPIMCTRL_DUMMYBYTE, dualoutput => CFG_SPIMCTRL_DUALOUTPUT, scaler => CFG_SPIMCTRL_SCALER, altscaler => CFG_SPIMCTRL_ASCALER, pwrupcnt => CFG_SPIMCTRL_PWRUPCNT) port map (rstn, clkm, ahbsi, ahbso(3), spmi, spmo); -- MISO is shared with Flash data 0 spmi.miso <= memi.data(16); mosi_pad : outpad generic map (tech => padtech) port map (spi_mosi, spmo.mosi); sck_pad : outpad generic map (tech => padtech) port map (spi_clk, spmo.sck); slvsel0_pad : odpad generic map (tech => padtech) port map (spi_sel_n, spmo.csn); end generate; nospimc: if ((CFG_SPICTRL_ENABLE = 0 and CFG_SPIMCTRL = 0) or (CFG_SPICTRL_ENABLE = 1 and CFG_SPIMCTRL = 1) or (CFG_SPICTRL_ENABLE = 1 and CFG_SPIMCTRL = 0))generate mosi_pad : outpad generic map (tech => padtech) port map (spi_mosi, '0'); sck_pad : outpad generic map (tech => padtech) port map (spi_clk, '0'); end generate; ---------------------------------------------------------------------- --- System ACE I/F Controller --------------------------------------- ---------------------------------------------------------------------- grace: if CFG_GRACECTRL = 1 generate grace0 : gracectrl generic map (hindex => 8, hirq => 10, haddr => 16#002#, hmask => 16#fff#, split => CFG_SPLIT, mode => 2) port map (rstn, clkm, lclk, ahbsi, ahbso(8), acei, aceo); end generate; nograce: if CFG_GRACECTRL /= 1 generate aceo <= gracectrl_none; end generate; sysace_mpa_pads : outpadv generic map (width => 7, tech => padtech) port map (sysace_mpa, aceo.addr); sysace_mpce_pad : outpad generic map (tech => padtech) port map (sysace_mpce, aceo.cen); sysace_d_pads : iopadv generic map (tech => padtech, width => 8) port map (sysace_d, aceo.do(7 downto 0), aceo.doen, acei.di(7 downto 0)); acei.di(15 downto 8) <= (others => '0'); sysace_mpoe_pad : outpad generic map (tech => padtech) port map (sysace_mpoe, aceo.oen); sysace_mpwe_pad : outpad generic map (tech => padtech) port map (sysace_mpwe, aceo.wen); sysace_mpirq_pad : inpad generic map (tech => padtech) port map (sysace_mpirq, acei.irq); ---------------------------------------------------------------------- --- APB Bridge and various periherals ------------------------------- ---------------------------------------------------------------------- apb0 : apbctrl -- AHB/APB bridge generic map (hindex => 1, haddr => CFG_APBADDR, nslaves => 16) port map (rstn, clkm, ahbsi, ahbso(1), apbi, apbo ); ua1 : if CFG_UART1_ENABLE /= 0 generate uart1 : apbuart -- UART 1 generic map (pindex => 1, paddr => 1, pirq => 2, console => dbguart, fifosize => CFG_UART1_FIFO) port map (rstn, clkm, apbi, apbo(1), u1i, u1o); u1i.extclk <= '0'; rxd1_pad : inpad generic map (tech => padtech) port map (rxd1, u1i.rxd); txd1_pad : outpad generic map (tech => padtech) port map (txd1, u1o.txd); cts1_pad : inpad generic map (tech => padtech) port map (ctsn1, u1i.ctsn); rts1_pad : outpad generic map (tech => padtech) port map (rtsn1, u1o.rtsn); end generate; noua0 : if CFG_UART1_ENABLE = 0 generate apbo(1) <= apb_none; end generate; irqctrl : if CFG_IRQ3_ENABLE /= 0 generate irqctrl0 : irqmp -- interrupt controller generic map (pindex => 2, paddr => 2, ncpu => CFG_NCPU) port map (rstn, clkm, apbi, apbo(2), irqo, irqi); end generate; irq3 : if CFG_IRQ3_ENABLE = 0 generate x : for i in 0 to CFG_NCPU-1 generate irqi(i).irl <= "0000"; end generate; apbo(2) <= apb_none; end generate; gpt : if CFG_GPT_ENABLE /= 0 generate timer0 : gptimer -- timer unit generic map (pindex => 3, paddr => 3, pirq => CFG_GPT_IRQ, sepirq => CFG_GPT_SEPIRQ, sbits => CFG_GPT_SW, ntimers => CFG_GPT_NTIM, nbits => CFG_GPT_TW, wdog => 0) port map (rstn, clkm, apbi, apbo(3), gpti, gpto); gpti.dhalt <= dsuo.tstop; gpti.extclk <= '0'; end generate; nogpt : if CFG_GPT_ENABLE = 0 generate apbo(3) <= apb_none; end generate; vga : if CFG_VGA_ENABLE /= 0 generate vga0 : apbvga generic map(memtech => memtech, pindex => 6, paddr => 6) port map(rstn, clkm, ethclk, apbi, apbo(6), vgao); -- video_clk <= not ethclk; end generate; svga : if CFG_SVGA_ENABLE /= 0 generate svga0 : svgactrl generic map(memtech => memtech, pindex => 6, paddr => 6, hindex => CFG_NCPU+CFG_AHB_JTAG, clk0 => 20000, clk1 => 0, --1000000000/((BOARD_FREQ * CFG_CLKMUL)/CFG_CLKDIV), clk2 => 0, clk3 => 0, burstlen => 6) port map(rstn, clkm, video_clk, apbi, apbo(6), vgao, vahbmi, vahbmo, clk_sel); end generate; vgadvi : if (CFG_VGA_ENABLE + CFG_SVGA_ENABLE) /= 0 generate -- b0 : techbuf generic map (2, fabtech) port map (clk50, video_clk); dvi0 : entity work.svga2ch7301c generic map (tech => fabtech, dynamic => 1) port map (clkm, vgao, video_clk, clkvga_p, clkvga_n, lcd_datal, lcd_hsyncl, lcd_vsyncl, lcd_del); i2cdvi : i2cmst generic map (pindex => 9, paddr => 9, pmask => 16#FFF#, pirq => 11) port map (rstn, clkm, apbi, apbo(9), dvi_i2ci, dvi_i2co); end generate; novga : if (CFG_VGA_ENABLE = 0 and CFG_SVGA_ENABLE = 0) generate apbo(6) <= apb_none; vgao <= vgao_none; end generate; tft_lcd_data_pad : outpadv generic map (width => 12, tech => padtech) port map (tft_lcd_data, lcd_datal); tft_lcd_clkp_pad : outpad generic map (tech => padtech) port map (tft_lcd_clk_p, clkvga_p); tft_lcd_clkn_pad : outpad generic map (tech => padtech) port map (tft_lcd_clk_n, clkvga_n); tft_lcd_hsync_pad : outpad generic map (tech => padtech) port map (tft_lcd_hsync, lcd_hsyncl); tft_lcd_vsync_pad : outpad generic map (tech => padtech) port map (tft_lcd_vsync, lcd_vsyncl); tft_lcd_de_pad : outpad generic map (tech => padtech) port map (tft_lcd_de, lcd_del); tft_lcd_reset_pad : outpad generic map (tech => padtech) port map (tft_lcd_reset_b, rstn); dvi_i2c_scl_pad : iopad generic map (tech => padtech) port map (dvi_iic_scl, dvi_i2co.scl, dvi_i2co.scloen, dvi_i2ci.scl); dvi_i2c_sda_pad : iopad generic map (tech => padtech) port map (dvi_iic_sda, dvi_i2co.sda, dvi_i2co.sdaoen, dvi_i2ci.sda); gpio0 : if CFG_GRGPIO_ENABLE /= 0 generate -- GPIO unit grgpio0: grgpio generic map(pindex => 10, paddr => 10, imask => CFG_GRGPIO_IMASK, nbits => 7) port map(rst => rstn, clk => clkm, apbi => apbi, apbo => apbo(10), gpioi => gpioi, gpioo => gpioo); pio_pads : for i in 0 to 3 generate pio_pad : iopad generic map (tech => padtech) port map (switch(i), gpioo.dout(i), gpioo.oen(i), gpioi.din(i)); end generate; pio_pads2 : for i in 4 to 6 generate pio_pad : iopad generic map (tech => padtech) port map (button(i-4), gpioo.dout(i), gpioo.oen(i), gpioi.din(i)); end generate; end generate; ahbs : if CFG_AHBSTAT = 1 generate -- AHB status register ahbstat0 : ahbstat generic map (pindex => 15, paddr => 15, pirq => 7, nftslv => CFG_AHBSTATN) port map (rstn, clkm, ahbmi, ahbsi, stati, apbi, apbo(15)); end generate; ----------------------------------------------------------------------- --- ETHERNET --------------------------------------------------------- ----------------------------------------------------------------------- eth0 : if CFG_GRETH = 1 generate -- Gaisler ethernet MAC negtx_clk <= not egtx_clk; x0 : ODDR2 port map ( Q => phy_gtx_clk, C0 => egtx_clk, C1 => negtx_clk, CE => vcc, D0 => vcc, D1 => gnd, R => gnd, S => gnd); e1 : grethm generic map( hindex => CFG_NCPU+CFG_AHB_JTAG, pindex => 14, paddr => 14, pirq => 12, memtech => memtech, mdcscaler => CPU_FREQ/1000, rmii => 0, enable_mdio => 1, fifosize => CFG_ETH_FIFO, nsync => 1, edcl => CFG_DSU_ETH, edclbufsz => CFG_ETH_BUF, phyrstadr => 7, macaddrh => CFG_ETH_ENM, macaddrl => CFG_ETH_ENL, enable_mdint => 1, ipaddrh => CFG_ETH_IPM, ipaddrl => CFG_ETH_IPL, giga => CFG_GRETH1G) port map( rst => rstn, clk => clkm, ahbmi => ahbmi, ahbmo => ahbmo(CFG_NCPU+CFG_AHB_JTAG), apbi => apbi, apbo => apbo(14), ethi => ethi, etho => etho); emdio_pad : iopad generic map (tech => padtech) port map (phy_mii_data, etho.mdio_o, etho.mdio_oe, ethi.mdio_i); etxc_pad : clkpad generic map (tech => padtech, arch => 2) port map (phy_tx_clk, ethi.tx_clk); erxc_pad : clkpad generic map (tech => padtech, arch => 2) port map (phy_rx_clk, ethi.rx_clk); erxd_pad : inpadv generic map (tech => padtech, width => 8) port map (phy_rx_data, ethi.rxd(7 downto 0)); erxdv_pad : inpad generic map (tech => padtech) port map (phy_dv, ethi.rx_dv); erxer_pad : inpad generic map (tech => padtech) port map (phy_rx_er, ethi.rx_er); erxco_pad : inpad generic map (tech => padtech) port map (phy_col, ethi.rx_col); erxcr_pad : inpad generic map (tech => padtech) port map (phy_crs, ethi.rx_crs); etxd_pad : outpadv generic map (tech => padtech, width => 8) port map (phy_tx_data, etho.txd(7 downto 0)); etxen_pad : outpad generic map (tech => padtech) port map ( phy_tx_en, etho.tx_en); etxer_pad : outpad generic map (tech => padtech) port map (phy_tx_er, etho.tx_er); emdc_pad : outpad generic map (tech => padtech) port map (phy_mii_clk, etho.mdc); erst_pad : outpad generic map (tech => padtech) port map (phy_rst_n, rstn); emdintn_pad : inpad generic map (tech => padtech) port map (phy_mii_int_n, ethi.mdint); ethi.gtx_clk <= egtx_clk; end generate; ----------------------------------------------------------------------- --- AHB ROM ---------------------------------------------------------- ----------------------------------------------------------------------- bpromgen : if CFG_AHBROMEN /= 0 generate brom : entity work.ahbrom generic map (hindex => 5, haddr => CFG_AHBRODDR, pipe => CFG_AHBROPIP) port map ( rstn, clkm, ahbsi, ahbso(5)); end generate; ----------------------------------------------------------------------- --- AHB RAM ---------------------------------------------------------- ----------------------------------------------------------------------- ocram : if CFG_AHBRAMEN = 1 generate ahbram0 : ahbram generic map (hindex => 7, haddr => CFG_AHBRADDR, tech => CFG_MEMTECH, kbytes => CFG_AHBRSZ, pipe => CFG_AHBRPIPE) port map ( rstn, clkm, ahbsi, ahbso(7)); end generate; ----------------------------------------------------------------------- --- Drive unused bus elements --------------------------------------- ----------------------------------------------------------------------- -- nam1 : for i in (CFG_NCPU+CFG_GRETH+CFG_AHB_JTAG+CFG_PCIEXP) to NAHBMST-1 generate -- ahbmo(i) <= ahbm_none; -- end generate; -- nap0 : for i in 11 to NAPBSLV-1 generate apbo(i) <= apb_none; end generate; -- nah0 : for i in 8 to NAHBSLV-1 generate ahbso(i) <= ahbs_none; end generate; ----------------------------------------------------------------------- --- Boot message ---------------------------------------------------- ----------------------------------------------------------------------- -- pragma translate_off x : report_design generic map ( msg1 => "LEON3 Xilinx SP605 Demonstration design", fabtech => tech_table(fabtech), memtech => tech_table(memtech), mdel => 1 ); -- pragma translate_on end;	gpl-2.0	b2967103dc4375399875203242fe750e	0.548496	3.498373	false	false	false	false
mistryalok/Zedboard	learning/opencv_hls/xapp1167_vivado/sw/fast-corner/prj/solution1/syn/vhdl/FIFO_image_filter_p_dst_data_stream_2_V.vhd	2	4,629	-- ============================================================== -- File generated by Vivado(TM) HLS - High-Level Synthesis from C, C++ and SystemC -- Version: 2014.4 -- Copyright (C) 2014 Xilinx Inc. All rights reserved. -- -- ============================================================== library IEEE; use IEEE.std_logic_1164.all; use IEEE.std_logic_unsigned.all; entity FIFO_image_filter_p_dst_data_stream_2_V_shiftReg is generic ( DATA_WIDTH : integer := 8; ADDR_WIDTH : integer := 1; DEPTH : integer := 2); port ( clk : in std_logic; data : in std_logic_vector(DATA_WIDTH-1 downto 0); ce : in std_logic; a : in std_logic_vector(ADDR_WIDTH-1 downto 0); q : out std_logic_vector(DATA_WIDTH-1 downto 0)); end FIFO_image_filter_p_dst_data_stream_2_V_shiftReg; architecture rtl of FIFO_image_filter_p_dst_data_stream_2_V_shiftReg is --constant DEPTH_WIDTH: integer := 16; type SRL_ARRAY is array (0 to DEPTH-1) of std_logic_vector(DATA_WIDTH-1 downto 0); signal SRL_SIG : SRL_ARRAY; begin p_shift: process (clk) begin if (clk'event and clk = '1') then if (ce = '1') then SRL_SIG <= data & SRL_SIG(0 to DEPTH-2); end if; end if; end process; q <= SRL_SIG(conv_integer(a)); end rtl; library ieee; use ieee.std_logic_1164.all; use ieee.std_logic_unsigned.all; entity FIFO_image_filter_p_dst_data_stream_2_V is generic ( MEM_STYLE : string := "auto"; DATA_WIDTH : integer := 8; ADDR_WIDTH : integer := 1; DEPTH : integer := 2); port ( clk : IN STD_LOGIC; reset : IN STD_LOGIC; if_empty_n : OUT STD_LOGIC; if_read_ce : IN STD_LOGIC; if_read : IN STD_LOGIC; if_dout : OUT STD_LOGIC_VECTOR(DATA_WIDTH - 1 downto 0); if_full_n : OUT STD_LOGIC; if_write_ce : IN STD_LOGIC; if_write : IN STD_LOGIC; if_din : IN STD_LOGIC_VECTOR(DATA_WIDTH - 1 downto 0)); end entity; architecture rtl of FIFO_image_filter_p_dst_data_stream_2_V is component FIFO_image_filter_p_dst_data_stream_2_V_shiftReg is generic ( DATA_WIDTH : integer := 8; ADDR_WIDTH : integer := 1; DEPTH : integer := 2); port ( clk : in std_logic; data : in std_logic_vector(DATA_WIDTH-1 downto 0); ce : in std_logic; a : in std_logic_vector(ADDR_WIDTH-1 downto 0); q : out std_logic_vector(DATA_WIDTH-1 downto 0)); end component; signal shiftReg_addr : STD_LOGIC_VECTOR(ADDR_WIDTH - 1 downto 0); signal shiftReg_data, shiftReg_q : STD_LOGIC_VECTOR(DATA_WIDTH - 1 downto 0); signal shiftReg_ce : STD_LOGIC; signal mOutPtr : STD_LOGIC_VECTOR(ADDR_WIDTH downto 0) := (others => '1'); signal internal_empty_n : STD_LOGIC := '0'; signal internal_full_n : STD_LOGIC := '1'; begin if_empty_n <= internal_empty_n; if_full_n <= internal_full_n; shiftReg_data <= if_din; if_dout <= shiftReg_q; process (clk) begin if clk'event and clk = '1' then if reset = '1' then mOutPtr <= (others => '1'); internal_empty_n <= '0'; internal_full_n <= '1'; else if ((if_read and if_read_ce) = '1' and internal_empty_n = '1') and ((if_write and if_write_ce) = '0' or internal_full_n = '0') then mOutPtr <= mOutPtr -1; if (mOutPtr = 0) then internal_empty_n <= '0'; end if; internal_full_n <= '1'; elsif ((if_read and if_read_ce) = '0' or internal_empty_n = '0') and ((if_write and if_write_ce) = '1' and internal_full_n = '1') then mOutPtr <= mOutPtr +1; internal_empty_n <= '1'; if (mOutPtr = DEPTH -2) then internal_full_n <= '0'; end if; end if; end if; end if; end process; shiftReg_addr <= (others => '0') when mOutPtr(ADDR_WIDTH) = '1' else mOutPtr(ADDR_WIDTH-1 downto 0); shiftReg_ce <= (if_write and if_write_ce) and internal_full_n; U_FIFO_image_filter_p_dst_data_stream_2_V_shiftReg : FIFO_image_filter_p_dst_data_stream_2_V_shiftReg generic map ( DATA_WIDTH => DATA_WIDTH, ADDR_WIDTH => ADDR_WIDTH, DEPTH => DEPTH) port map ( clk => clk, data => shiftReg_data, ce => shiftReg_ce, a => shiftReg_addr, q => shiftReg_q); end rtl;	gpl-3.0	ca92a440104dd9b08a2d0a544f2277b9	0.537697	3.449329	false	false	false	false
mistryalok/Zedboard	learning/training/Microsystem/axi_interface_part2/project_1/project_1.srcs/sources_1/ipshared/xilinx.com/axi_bram_ctrl_v4_0/b6365b74/hdl/vhdl/srl_fifo.vhd	6	11,823	------------------------------------------------------------------------------- -- SRL_FIFO entity and architecture ------------------------------------------------------------------------------- -- -- *********************************************************************** -- -- DISCLAIMER OF LIABILITY -- -- This text/file contains proprietary, confidential -- information of Xilinx, Inc., is distributed under -- license from Xilinx, Inc., and may be used, copied -- and/or disclosed only pursuant to the terms of a valid -- license agreement with Xilinx, Inc. Xilinx hereby -- grants you a license to use this text/file solely for -- design, simulation, implementation and creation of -- design files limited to Xilinx devices or technologies. -- Use with non-Xilinx devices or technologies is expressly -- prohibited and immediately terminates your license unless -- covered by a separate agreement. -- -- Xilinx is providing this design, code, or information -- "as-is" solely for use in developing programs and -- solutions for Xilinx devices, with no obligation on the -- part of Xilinx to provide support. By providing this design, -- code, or information as one possible implementation of -- this feature, application or standard, Xilinx is making no -- representation that this implementation is free from any -- claims of infringement. You are responsible for obtaining -- any rights you may require for your implementation. -- Xilinx expressly disclaims any warranty whatsoever with -- respect to the adequacy of the implementation, including -- but not limited to any warranties or representations that this -- implementation is free from claims of infringement, implied -- warranties of merchantability or fitness for a particular -- purpose. -- -- Xilinx products are not intended for use in life support -- appliances, devices, or systems. Use in such applications is -- expressly prohibited. -- -- Any modifications that are made to the Source Code are -- done at the users sole risk and will be unsupported. -- The Xilinx Support Hotline does not have access to source -- code and therefore cannot answer specific questions related -- to source HDL. The Xilinx Hotline support of original source -- code IP shall only address issues and questions related -- to the standard Netlist version of the core (and thus -- indirectly, the original core source). -- -- Copyright (c) 2001-2013 Xilinx, Inc. All rights reserved. -- -- This copyright and support notice must be retained as part -- of this text at all times. -- -- *********************************************************************** -- ------------------------------------------------------------------------------- -- Filename: srl_fifo.vhd -- -- Description: -- -- VHDL-Standard: VHDL'93 ------------------------------------------------------------------------------- -- Structure: -- srl_fifo.vhd -- ------------------------------------------------------------------------------- -- Author: goran -- Revision: $Revision: 1.1.4.1 $ -- Date: $Date: 2010/09/14 22:35:47 $ -- -- History: -- goran 2001-05-11 First Version -- KC 2001-06-20 Added Addr as an output port, for use as an occupancy -- value -- -- DCW 2002-03-12 Structural implementation of synchronous reset for -- Data_Exists DFF (using FDR) -- jam 2002-04-12 added C_XON generic for mixed vhdl/verilog sims -- -- als 2002-04-18 added default for XON generic in SRL16E, FDRE, and FDR -- component declarations -- -- DET 1/17/2008 v4_00_a -- ~~~~~~ -- - Incorporated new disclaimer header -- ^^^^^^ -- ------------------------------------------------------------------------------- -- Naming Conventions: -- active low signals: "_n" -- clock signals: "clk", "clk_div#", "clk_#x" -- reset signals: "rst", "rst_n" -- generics: "C_" -- user defined types: "_TYPE" -- state machine next state: "_ns" -- state machine current state: "_cs" -- combinatorial signals: "_com" -- pipelined or register delay signals: "_d#" -- counter signals: "cnt" -- clock enable signals: "_ce" -- internal version of output port "_i" -- device pins: "_pin" -- ports: - Names begin with Uppercase -- processes: "*_PROCESS" -- component instantiations: "<ENTITY_>I_<#\|FUNC> ------------------------------------------------------------------------------- library IEEE; use IEEE.std_logic_1164.all; library unisim; use unisim.all; entity SRL_FIFO is generic ( C_DATA_BITS : natural := 8; C_DEPTH : natural := 16; C_XON : boolean := false ); port ( Clk : in std_logic; Reset : in std_logic; FIFO_Write : in std_logic; Data_In : in std_logic_vector(0 to C_DATA_BITS-1); FIFO_Read : in std_logic; Data_Out : out std_logic_vector(0 to C_DATA_BITS-1); FIFO_Full : out std_logic; Data_Exists : out std_logic; Addr : out std_logic_vector(0 to 3) -- Added Addr as a port ); end entity SRL_FIFO; architecture IMP of SRL_FIFO is attribute DowngradeIPIdentifiedWarnings: string; attribute DowngradeIPIdentifiedWarnings of IMP : architecture is "yes"; component SRL16E is -- pragma translate_off generic ( INIT : bit_vector := X"0000" ); -- pragma translate_on port ( CE : in std_logic; D : in std_logic; Clk : in std_logic; A0 : in std_logic; A1 : in std_logic; A2 : in std_logic; A3 : in std_logic; Q : out std_logic); end component SRL16E; component LUT4 generic( INIT : bit_vector := X"0000" ); port ( O : out std_logic; I0 : in std_logic; I1 : in std_logic; I2 : in std_logic; I3 : in std_logic); end component; component MULT_AND port ( I0 : in std_logic; I1 : in std_logic; LO : out std_logic); end component; component MUXCY_L port ( DI : in std_logic; CI : in std_logic; S : in std_logic; LO : out std_logic); end component; component XORCY port ( LI : in std_logic; CI : in std_logic; O : out std_logic); end component; component FDRE is port ( Q : out std_logic; C : in std_logic; CE : in std_logic; D : in std_logic; R : in std_logic); end component FDRE; component FDR is port ( Q : out std_logic; C : in std_logic; D : in std_logic; R : in std_logic); end component FDR; signal addr_i : std_logic_vector(0 to 3); signal buffer_Full : std_logic; signal buffer_Empty : std_logic; signal next_Data_Exists : std_logic; signal data_Exists_I : std_logic; signal valid_Write : std_logic; signal hsum_A : std_logic_vector(0 to 3); signal sum_A : std_logic_vector(0 to 3); signal addr_cy : std_logic_vector(0 to 4); begin -- architecture IMP buffer_Full <= '1' when (addr_i = "1111") else '0'; FIFO_Full <= buffer_Full; buffer_Empty <= '1' when (addr_i = "0000") else '0'; next_Data_Exists <= (data_Exists_I and not buffer_Empty) or (buffer_Empty and FIFO_Write) or (data_Exists_I and not FIFO_Read); Data_Exists_DFF : FDR port map ( Q => data_Exists_I, -- [out std_logic] C => Clk, -- [in std_logic] D => next_Data_Exists, -- [in std_logic] R => Reset); -- [in std_logic] Data_Exists <= data_Exists_I; valid_Write <= FIFO_Write and (FIFO_Read or not buffer_Full); addr_cy(0) <= valid_Write; Addr_Counters : for I in 0 to 3 generate hsum_A(I) <= (FIFO_Read xor addr_i(I)) and (FIFO_Write or not buffer_Empty); MUXCY_L_I : MUXCY_L port map ( DI => addr_i(I), -- [in std_logic] CI => addr_cy(I), -- [in std_logic] S => hsum_A(I), -- [in std_logic] LO => addr_cy(I+1)); -- [out std_logic] XORCY_I : XORCY port map ( LI => hsum_A(I), -- [in std_logic] CI => addr_cy(I), -- [in std_logic] O => sum_A(I)); -- [out std_logic] FDRE_I : FDRE port map ( Q => addr_i(I), -- [out std_logic] C => Clk, -- [in std_logic] CE => data_Exists_I, -- [in std_logic] D => sum_A(I), -- [in std_logic] R => Reset); -- [in std_logic] end generate Addr_Counters; FIFO_RAM : for I in 0 to C_DATA_BITS-1 generate SRL16E_I : SRL16E -- pragma translate_off generic map ( INIT => x"0000") -- pragma translate_on port map ( CE => valid_Write, -- [in std_logic] D => Data_In(I), -- [in std_logic] Clk => Clk, -- [in std_logic] A0 => addr_i(0), -- [in std_logic] A1 => addr_i(1), -- [in std_logic] A2 => addr_i(2), -- [in std_logic] A3 => addr_i(3), -- [in std_logic] Q => Data_Out(I)); -- [out std_logic] end generate FIFO_RAM; ------------------------------------------------------------------------------- -- INT_ADDR_PROCESS ------------------------------------------------------------------------------- -- This process assigns the internal address to the output port ------------------------------------------------------------------------------- INT_ADDR_PROCESS:process (addr_i) begin -- process Addr <= addr_i; end process; end architecture IMP;	gpl-3.0	ba29c0ebc30e926b5a221414e80d0cf0	0.438806	4.375648	false	false	false	false
mistryalok/Zedboard	learning/training/MSD/s09/axi_dma_sg/vivado/project_1/project_1.srcs/sources_1/ipshared/xilinx.com/axi_sg_v4_1/0535f152/hdl/src/vhdl/axi_sg_ftch_sm.vhd	4	47,863	-- *********************************************************************** -- -- (c) Copyright 2010-2011 Xilinx, Inc. All rights reserved. -- -- This file contains confidential and proprietary information -- of Xilinx, Inc. and is protected under U.S. and -- international copyright and other intellectual property -- laws. -- -- DISCLAIMER -- This disclaimer is not a license and does not grant any -- rights to the materials distributed herewith. Except as -- otherwise provided in a valid license issued to you by -- Xilinx, and to the maximum extent permitted by applicable -- law: (1) THESE MATERIALS ARE MADE AVAILABLE "AS IS" AND -- WITH ALL FAULTS, AND XILINX HEREBY DISCLAIMS ALL WARRANTIES -- AND CONDITIONS, EXPRESS, IMPLIED, OR STATUTORY, INCLUDING -- BUT NOT LIMITED TO WARRANTIES OF MERCHANTABILITY, NON- -- INFRINGEMENT, OR FITNESS FOR ANY PARTICULAR PURPOSE; and -- (2) Xilinx shall not be liable (whether in contract or tort, -- including negligence, or under any other theory of -- liability) for any loss or damage of any kind or nature -- related to, arising under or in connection with these -- materials, including for any direct, or any indirect, -- special, incidental, or consequential loss or damage -- (including loss of data, profits, goodwill, or any type of -- loss or damage suffered as a result of any action brought -- by a third party) even if such damage or loss was -- reasonably foreseeable or Xilinx had been advised of the -- possibility of the same. -- -- CRITICAL APPLICATIONS -- Xilinx products are not designed or intended to be fail- -- safe, or for use in any application requiring fail-safe -- performance, such as life-support or safety devices or -- systems, Class III medical devices, nuclear facilities, -- applications related to the deployment of airbags, or any -- other applications that could lead to death, personal -- injury, or severe property or environmental damage -- (individually and collectively, "Critical -- Applications"). Customer assumes the sole risk and -- liability of any use of Xilinx products in Critical -- Applications, subject only to applicable laws and -- regulations governing limitations on product liability. -- -- THIS COPYRIGHT NOTICE AND DISCLAIMER MUST BE RETAINED AS -- PART OF THIS FILE AT ALL TIMES. -- -- *********************************************************************** -- ------------------------------------------------------------------------------- -- Filename: axi_sg_ftch_sm.vhd -- Description: This entity manages fetching of descriptors. -- -- VHDL-Standard: VHDL'93 ------------------------------------------------------------------------------- library ieee; use ieee.std_logic_1164.all; use ieee.numeric_std.all; use ieee.std_logic_misc.all; library unisim; use unisim.vcomponents.all; library axi_sg_v4_1; use axi_sg_v4_1.axi_sg_pkg.all; library lib_pkg_v1_0; use lib_pkg_v1_0.lib_pkg.clog2; ------------------------------------------------------------------------------- entity axi_sg_ftch_sm is generic ( C_M_AXI_SG_ADDR_WIDTH : integer range 32 to 64 := 32; -- Master AXI Memory Map Address Width for Scatter Gather R/W Port C_ENABLE_MULTI_CHANNEL : integer range 0 to 1 := 0; C_INCLUDE_CH1 : integer range 0 to 1 := 1; -- Include or Exclude channel 1 scatter gather engine -- 0 = Exclude Channel 1 SG Engine -- 1 = Include Channel 1 SG Engine C_INCLUDE_CH2 : integer range 0 to 1 := 1; -- Include or Exclude channel 2 scatter gather engine -- 0 = Exclude Channel 2 SG Engine -- 1 = Include Channel 2 SG Engine C_SG_CH1_WORDS_TO_FETCH : integer range 4 to 16 := 8; -- Number of words to fetch C_SG_CH2_WORDS_TO_FETCH : integer range 4 to 16 := 8; -- Number of words to fetch C_SG_FTCH_DESC2QUEUE : integer range 0 to 8 := 0; -- Number of descriptors to fetch and queue for each channel. -- A value of zero excludes the fetch queues. C_SG_CH1_ENBL_STALE_ERROR : integer range 0 to 1 := 1; -- Enable or disable stale descriptor check -- 0 = Disable stale descriptor error check -- 1 = Enable stale descriptor error check C_SG_CH2_ENBL_STALE_ERROR : integer range 0 to 1 := 1 -- Enable or disable stale descriptor check -- 0 = Disable stale descriptor error check -- 1 = Enable stale descriptor error check ); port ( ----------------------------------------------------------------------- -- AXI Scatter Gather Interface ----------------------------------------------------------------------- m_axi_sg_aclk : in std_logic ; -- m_axi_sg_aresetn : in std_logic ; -- -- updt_error : in std_logic ; -- -- -- Channel 1 Control and Status -- ch1_run_stop : in std_logic ; -- ch1_desc_flush : in std_logic ; -- ch1_updt_done : in std_logic ; -- ch1_sg_idle : in std_logic ; -- ch1_tailpntr_enabled : in std_logic ; -- ch1_ftch_queue_full : in std_logic ; -- ch1_ftch_queue_empty : in std_logic ; -- ch1_ftch_pause : in std_logic ; -- ch1_fetch_address : in std_logic_vector -- (C_M_AXI_SG_ADDR_WIDTH-1 downto 0) ; -- ch1_ftch_active : out std_logic ; -- ch1_ftch_idle : out std_logic ; -- ch1_ftch_interr_set : out std_logic ; -- ch1_ftch_slverr_set : out std_logic ; -- ch1_ftch_decerr_set : out std_logic ; -- ch1_ftch_err_early : out std_logic ; -- ch1_ftch_stale_desc : out std_logic ; -- -- -- Channel 2 Control and Status -- ch2_run_stop : in std_logic ; -- ch2_desc_flush : in std_logic ; -- ch2_updt_done : in std_logic ; -- ch2_sg_idle : in std_logic ; -- ch2_tailpntr_enabled : in std_logic ; -- ch2_ftch_queue_full : in std_logic ; -- ch2_ftch_queue_empty : in std_logic ; -- ch2_ftch_pause : in std_logic ; -- ch2_fetch_address : in std_logic_vector -- (C_M_AXI_SG_ADDR_WIDTH-1 downto 0) ; -- ch2_ftch_active : out std_logic ; -- ch2_ftch_idle : out std_logic ; -- ch2_ftch_interr_set : out std_logic ; -- ch2_ftch_slverr_set : out std_logic ; -- ch2_ftch_decerr_set : out std_logic ; -- ch2_ftch_err_early : out std_logic ; -- ch2_ftch_stale_desc : out std_logic ; -- -- -- DataMover Command -- ftch_cmnd_wr : out std_logic ; -- ftch_cmnd_data : out std_logic_vector -- ((C_M_AXI_SG_ADDR_WIDTH+CMD_BASE_WIDTH)-1 downto 0); -- -- DataMover Status -- ftch_done : in std_logic ; -- ftch_error : in std_logic ; -- ftch_interr : in std_logic ; -- ftch_slverr : in std_logic ; -- ftch_decerr : in std_logic ; -- ftch_stale_desc : in std_logic ; -- ftch_error_early : in std_logic ; -- ftch_error_addr : out std_logic_vector -- (C_M_AXI_SG_ADDR_WIDTH-1 downto 0) -- ); end axi_sg_ftch_sm; ------------------------------------------------------------------------------- -- Architecture ------------------------------------------------------------------------------- architecture implementation of axi_sg_ftch_sm is attribute DowngradeIPIdentifiedWarnings: string; attribute DowngradeIPIdentifiedWarnings of implementation : architecture is "yes"; attribute mark_debug : string; ------------------------------------------------------------------------------- -- Functions ------------------------------------------------------------------------------- -- No Functions Declared ------------------------------------------------------------------------------- -- Constants Declarations ------------------------------------------------------------------------------- -- DataMover Command Type constant FETCH_CMD_TYPE : std_logic := '1'; -- DataMover Cmnd Reserved Bits constant FETCH_MSB_IGNORED : std_logic_vector(7 downto 0) := (others => '0'); -- DataMover Cmnd Reserved Bits constant FETCH_LSB_IGNORED : std_logic_vector(15 downto 0) := (others => '0'); -- DataMover Cmnd Bytes to Xfer for Channel 1 constant FETCH_CH1_CMD_BTT : std_logic_vector(SG_BTT_WIDTH-1 downto 0) := std_logic_vector(to_unsigned( (C_SG_CH1_WORDS_TO_FETCH4),SG_BTT_WIDTH)); -- DataMover Cmnd Bytes to Xfer for Channel 2 constant FETCH_CH2_CMD_BTT : std_logic_vector(SG_BTT_WIDTH-1 downto 0) := std_logic_vector(to_unsigned( (C_SG_CH2_WORDS_TO_FETCH4),SG_BTT_WIDTH)); -- DataMover Cmnd Reserved Bits constant FETCH_CMD_RSVD : std_logic_vector( DATAMOVER_CMD_RSVMSB_BOFST + C_M_AXI_SG_ADDR_WIDTH downto DATAMOVER_CMD_RSVLSB_BOFST + C_M_AXI_SG_ADDR_WIDTH) := (others => '0'); -- CR585958 Constant declaration in axi_sg_ftch_sm needs to move under associated generate -- Required width in bits for C_SG_FTCH_DESC2QUEUE --constant SG_FTCH_DESC2QUEUE_WIDTH : integer := clog2(C_SG_FTCH_DESC2QUEUE+1); -- ---- Vector version of C_SG_FTCH_DESC2QUEUE --constant SG_FTCH_DESC2QUEUE_VEC : std_logic_vector(SG_FTCH_DESC2QUEUE_WIDTH-1 downto 0) -- := std_logic_vector(to_unsigned -- (C_SG_FTCH_DESC2QUEUE,SG_FTCH_DESC2QUEUE_WIDTH)); ------------------------------------------------------------------------------- -- Signal / Type Declarations ------------------------------------------------------------------------------- -- DataMover Commmand TAG signal fetch_tag : std_logic_vector(3 downto 0) := (others => '0'); type SG_FTCH_STATE_TYPE is ( IDLE, FETCH_DESCRIPTOR, FETCH_STATUS, FETCH_ERROR ); signal ftch_cs : SG_FTCH_STATE_TYPE; signal ftch_ns : SG_FTCH_STATE_TYPE; -- State Machine Signals signal ch1_active_set : std_logic := '0'; signal ch2_active_set : std_logic := '0'; signal write_cmnd_cmb : std_logic := '0'; signal ch1_ftch_sm_idle : std_logic := '0'; signal ch2_ftch_sm_idle : std_logic := '0'; signal ch1_pause_fetch : std_logic := '0'; signal ch2_pause_fetch : std_logic := '0'; signal ch2_pause_fetch1 : std_logic := '0'; signal ch2_pause_fetch2 : std_logic := '0'; signal ch2_pause_fetch3 : std_logic := '0'; signal ch2_updt_done1 : std_logic := '0'; signal ch2_updt_done2 : std_logic := '0'; -- Misc Signals signal fetch_cmd_addr : std_logic_vector (C_M_AXI_SG_ADDR_WIDTH-1 downto 0) := (others => '0'); signal ch1_active_i : std_logic := '0'; signal service_ch1 : std_logic := '0'; signal ch2_active_i : std_logic := '0'; signal service_ch2 : std_logic := '0'; attribute mark_debug of ch1_active_i : signal is "true"; attribute mark_debug of ch2_active_i : signal is "true"; signal fetch_cmd_btt : std_logic_vector (SG_BTT_WIDTH-1 downto 0) := (others => '0'); signal ch1_stale_descriptor : std_logic := '0'; signal ch2_stale_descriptor : std_logic := '0'; attribute mark_debug of ch1_stale_descriptor : signal is "true"; attribute mark_debug of ch2_stale_descriptor : signal is "true"; signal ch1_ftch_interr_set_i : std_logic := '0'; signal ch2_ftch_interr_set_i : std_logic := '0'; -- CR585958 Constant declaration in axi_sg_ftch_sm needs to move under associated generate -- counts for keeping track of queue descriptors to prevent -- fifo fill --signal ch1_desc_ftched_count : std_logic_vector -- (SG_FTCH_DESC2QUEUE_WIDTH-1 downto 0) := (others => '0'); --signal ch2_desc_ftched_count : std_logic_vector -- (SG_FTCH_DESC2QUEUE_WIDTH-1 downto 0) := (others => '0'); ------------------------------------------------------------------------------- -- Begin architecture logic ------------------------------------------------------------------------------- begin ch1_ftch_active <= ch1_active_i; ch2_ftch_active <= ch2_active_i; ------------------------------------------------------------------------------- -- Scatter Gather Fetch State Machine ------------------------------------------------------------------------------- SG_FTCH_MACHINE : process(ftch_cs, ch1_active_i, ch2_active_i, service_ch1, service_ch2, ftch_error, ftch_done) begin -- Default signal assignment ch1_active_set <= '0'; ch2_active_set <= '0'; write_cmnd_cmb <= '0'; ch1_ftch_sm_idle <= '0'; ch2_ftch_sm_idle <= '0'; ftch_ns <= ftch_cs; case ftch_cs is ------------------------------------------------------------------- when IDLE => ch1_ftch_sm_idle <= not service_ch1; ch2_ftch_sm_idle <= not service_ch2; -- sg error during fetch - shut down if(ftch_error = '1')then ftch_ns <= FETCH_ERROR; -- If channel 1 is running and not idle and queue is not full -- then fetch descriptor for channel 1 elsif(service_ch1 = '1')then ch1_active_set <= '1'; ftch_ns <= FETCH_DESCRIPTOR; -- If channel 2 is running and not idle and queue is not full -- then fetch descriptor for channel 2 elsif(service_ch2 = '1')then ch2_active_set <= '1'; ftch_ns <= FETCH_DESCRIPTOR; else ftch_ns <= IDLE; end if; ------------------------------------------------------------------- when FETCH_DESCRIPTOR => -- sg error during fetch - shut down if(ftch_error = '1')then ftch_ns <= FETCH_ERROR; else ch1_ftch_sm_idle <= not ch1_active_i and not service_ch1; ch2_ftch_sm_idle <= not ch2_active_i and not service_ch2; write_cmnd_cmb <= '1'; ftch_ns <= FETCH_STATUS; end if; ------------------------------------------------------------------- when FETCH_STATUS => ch1_ftch_sm_idle <= not ch1_active_i and not service_ch1; ch2_ftch_sm_idle <= not ch2_active_i and not service_ch2; -- sg error during fetch - shut down if(ftch_error = '1')then ftch_ns <= FETCH_ERROR; elsif(ftch_done = '1')then -- If just finished fethcing for channel 2 then... if(ch2_active_i = '1')then -- If ready, fetch descriptor for channel 1 if(service_ch1 = '1')then ch1_active_set <= '1'; ftch_ns <= FETCH_DESCRIPTOR; -- Else if channel 2 still ready then fetch -- another descriptor for channel 2 elsif(service_ch2 = '1')then ch1_ftch_sm_idle <= '1'; ftch_ns <= FETCH_DESCRIPTOR; -- Otherwise return to IDLE else ftch_ns <= IDLE; end if; -- If just finished fethcing for channel 1 then... elsif(ch1_active_i = '1')then -- If ready, fetch descriptor for channel 2 if(service_ch2 = '1')then ch2_active_set <= '1'; ftch_ns <= FETCH_DESCRIPTOR; -- Else if channel 1 still ready then fetch -- another descriptor for channel 1 elsif(service_ch1 = '1')then ch2_ftch_sm_idle <= '1'; ftch_ns <= FETCH_DESCRIPTOR; -- Otherwise return to IDLE else ftch_ns <= IDLE; end if; else ftch_ns <= IDLE; end if; else ftch_ns <= FETCH_STATUS; end if; ------------------------------------------------------------------- when FETCH_ERROR => ch1_ftch_sm_idle <= '1'; ch2_ftch_sm_idle <= '1'; ftch_ns <= FETCH_ERROR; ------------------------------------------------------------------- -- coverage off when others => ftch_ns <= IDLE; -- coverage on end case; end process SG_FTCH_MACHINE; ------------------------------------------------------------------------------- ------------------------------------------------------------------------------- REGISTER_STATE : process(m_axi_sg_aclk) begin if(m_axi_sg_aclk'EVENT and m_axi_sg_aclk = '1')then if(m_axi_sg_aresetn = '0')then ftch_cs <= IDLE; else ftch_cs <= ftch_ns; end if; end if; end process REGISTER_STATE; ------------------------------------------------------------------------------- -- Channel included therefore generate fetch logic ------------------------------------------------------------------------------- GEN_CH1_FETCH : if C_INCLUDE_CH1 = 1 generate begin ------------------------------------------------------------------------------- -- Active channel flag. Indicates which channel is active. -- 0 = channel active -- 1 = channel active ------------------------------------------------------------------------------- CH1_ACTIVE_PROCESS : process(m_axi_sg_aclk) begin if(m_axi_sg_aclk'EVENT and m_axi_sg_aclk = '1')then if(m_axi_sg_aresetn = '0' or ch2_active_set = '1')then ch1_active_i <= '0'; elsif(ch1_active_set = '1')then ch1_active_i <= '1'; end if; end if; end process CH1_ACTIVE_PROCESS; ------------------------------------------------------------------------------- -- Channel 1 IDLE process. Indicates channel 1 fetch process is IDLE -- This is 1 part of determining IDLE for a channel ------------------------------------------------------------------------------- CH1_IDLE_PROCESS : process(m_axi_sg_aclk) begin if(m_axi_sg_aclk'EVENT and m_axi_sg_aclk = '1')then -- If reset or stopped then clear idle bit if(m_axi_sg_aresetn = '0')then ch1_ftch_idle <= '1'; -- SG Error therefore force IDLE -- CR564855 - fetch idle asserted too soon when update error occured. -- fetch idle does not need to be concerned with updt_error. This is -- because on going fetch is guarentteed to complete regardless of dma -- controller or sg update engine. --elsif(updt_error = '1' or ftch_error = '1' elsif(ftch_error = '1' or ch1_ftch_interr_set_i = '1')then ch1_ftch_idle <= '1'; -- When SG Fetch no longer idle then clear fetch idle elsif(ch1_sg_idle = '0')then ch1_ftch_idle <= '0'; -- If tail = cur and fetch queue is empty then elsif(ch1_sg_idle = '1' and ch1_ftch_queue_empty = '1' and ch1_ftch_sm_idle = '1')then ch1_ftch_idle <= '1'; end if; end if; end process CH1_IDLE_PROCESS; ------------------------------------------------------------------------------- -- For No Fetch Queue, generate pause logic to prevent partial descriptor from -- being fetched and then endless throttle on AXI read bus ------------------------------------------------------------------------------- GEN_CH1_FETCH_PAUSE : if C_SG_FTCH_DESC2QUEUE = 0 generate begin REG_PAUSE_FETCH : process(m_axi_sg_aclk) begin if(m_axi_sg_aclk'EVENT and m_axi_sg_aclk = '1')then -- On descriptor update done clear pause if(m_axi_sg_aresetn = '0' or ch1_updt_done = '1')then ch1_pause_fetch <= '0'; -- If channel active and command written then pause elsif(ch1_active_i='1' and write_cmnd_cmb = '1')then ch1_pause_fetch <= '1'; end if; end if; end process REG_PAUSE_FETCH; end generate GEN_CH1_FETCH_PAUSE; -- Fetch queues so do not need to pause GEN_CH1_NO_FETCH_PAUSE : if C_SG_FTCH_DESC2QUEUE /= 0 generate -- -- CR585958 -- -- Required width in bits for C_SG_FTCH_DESC2QUEUE -- constant SG_FTCH_DESC2QUEUE_WIDTH : integer := clog2(C_SG_FTCH_DESC2QUEUE+1); -- -- Vector version of C_SG_FTCH_DESC2QUEUE -- constant SG_FTCH_DESC2QUEUE_VEC : std_logic_vector(SG_FTCH_DESC2QUEUE_WIDTH-1 downto 0) -- := std_logic_vector(to_unsigned -- (C_SG_FTCH_DESC2QUEUE,SG_FTCH_DESC2QUEUE_WIDTH)); -- signal desc_queued_incr : std_logic := '0'; -- signal desc_queued_decr : std_logic := '0'; -- -- -- CR585958 -- signal ch1_desc_ftched_count: std_logic_vector -- (SG_FTCH_DESC2QUEUE_WIDTH-1 downto 0) := (others => '0'); -- begin -- -- desc_queued_incr <= '1' when ch1_active_i = '1' -- and write_cmnd_cmb = '1' -- and ch1_ftch_descpulled = '0' -- else '0'; -- -- desc_queued_decr <= '1' when ch1_ftch_descpulled = '1' -- and not (ch1_active_i = '1' and write_cmnd_cmb = '1') -- else '0'; -- -- -- Keep track of descriptors queued version descriptors updated -- DESC_FETCHED_CNTR : process(m_axi_sg_aclk) -- begin -- if(m_axi_sg_aclk'EVENT and m_axi_sg_aclk = '1')then -- if(m_axi_sg_aresetn = '0')then -- ch1_desc_ftched_count <= (others => '0'); -- elsif(desc_queued_incr = '1')then -- ch1_desc_ftched_count <= std_logic_vector(unsigned(ch1_desc_ftched_count) + 1); -- elsif(desc_queued_decr = '1')then -- ch1_desc_ftched_count <= std_logic_vector(unsigned(ch1_desc_ftched_count) - 1); -- end if; -- end if; -- end process DESC_FETCHED_CNTR; -- -- REG_PAUSE_FETCH : process(m_axi_sg_aclk) -- begin -- if(m_axi_sg_aclk'EVENT and m_axi_sg_aclk = '1')then -- if(m_axi_sg_aresetn = '0')then -- ch1_pause_fetch <= '0'; -- elsif(ch1_desc_ftched_count >= SG_FTCH_DESC2QUEUE_VEC)then -- ch1_pause_fetch <= '1'; -- else -- ch1_pause_fetch <= '0'; -- end if; -- end if; -- end process REG_PAUSE_FETCH; -- -- -- ch1_pause_fetch <= ch1_ftch_pause; end generate GEN_CH1_NO_FETCH_PAUSE; ------------------------------------------------------------------------------- -- Channel 1 ready to be serviced? ------------------------------------------------------------------------------- service_ch1 <= '1' when ch1_run_stop = '1' -- Channel running and ch1_sg_idle = '0' -- SG Engine running and ch1_ftch_queue_full = '0' -- Queue not full and updt_error = '0' -- No SG Update error and ch1_stale_descriptor = '0' -- No Stale Descriptors and ch1_desc_flush = '0' -- Not flushing desc and ch1_pause_fetch = '0' -- Not pausing else '0'; ------------------------------------------------------------------------------- -- Log Fetch Errors ------------------------------------------------------------------------------- INT_ERROR_PROCESS : process(m_axi_sg_aclk) begin if(m_axi_sg_aclk'EVENT and m_axi_sg_aclk = '1')then -- If reset or stopped then clear idle bit if(m_axi_sg_aresetn = '0')then ch1_ftch_interr_set_i <= '0'; -- Channel active and datamover int error or fetch done and descriptor stale elsif((ch1_active_i = '1' and ftch_interr = '1') or ((ftch_done = '1' or ftch_error = '1') and ch1_stale_descriptor = '1'))then ch1_ftch_interr_set_i <= '1'; end if; end if; end process INT_ERROR_PROCESS; ch1_ftch_interr_set <= ch1_ftch_interr_set_i; SLV_ERROR_PROCESS : process(m_axi_sg_aclk) begin if(m_axi_sg_aclk'EVENT and m_axi_sg_aclk = '1')then -- If reset or stopped then clear idle bit if(m_axi_sg_aresetn = '0')then ch1_ftch_slverr_set <= '0'; elsif(ch1_active_i = '1' and ftch_slverr = '1')then ch1_ftch_slverr_set <= '1'; end if; end if; end process SLV_ERROR_PROCESS; DEC_ERROR_PROCESS : process(m_axi_sg_aclk) begin if(m_axi_sg_aclk'EVENT and m_axi_sg_aclk = '1')then -- If reset or stopped then clear idle bit if(m_axi_sg_aresetn = '0')then ch1_ftch_decerr_set <= '0'; elsif(ch1_active_i = '1' and ftch_decerr = '1')then ch1_ftch_decerr_set <= '1'; end if; end if; end process DEC_ERROR_PROCESS; -- Early detection of SlvErr or DecErr, used to prevent error'ed descriptor -- from being used by dma controller ch1_ftch_err_early <= '1' when ftch_error_early = '1' and ch1_active_i = '1' else '0'; -- Enable stale descriptor check GEN_CH1_STALE_CHECK : if C_SG_CH1_ENBL_STALE_ERROR = 1 generate begin ----------------------------------------------------------------------- -- Stale Descriptor Error ----------------------------------------------------------------------- CH1_STALE_DESC : process(m_axi_sg_aclk) begin if(m_axi_sg_aclk'EVENT and m_axi_sg_aclk = '1')then -- If reset then clear flag if(m_axi_sg_aresetn = '0')then ch1_stale_descriptor <= '0'; elsif(ftch_stale_desc = '1' and ch1_active_i = '1' )then ch1_stale_descriptor <= '1'; end if; end if; end process CH1_STALE_DESC; end generate GEN_CH1_STALE_CHECK; -- Disable stale descriptor check GEN_CH1_NO_STALE_CHECK : if C_SG_CH1_ENBL_STALE_ERROR = 0 generate begin ch1_stale_descriptor <= '0'; end generate GEN_CH1_NO_STALE_CHECK; -- Early detection of Stale Descriptor (valid only in tailpntr mode) used -- to prevent error'ed descriptor from being used. ch1_ftch_stale_desc <= ch1_stale_descriptor; end generate GEN_CH1_FETCH; ------------------------------------------------------------------------------- -- Channel excluded therefore do not generate fetch logic ------------------------------------------------------------------------------- GEN_NO_CH1_FETCH : if C_INCLUDE_CH1 = 0 generate begin service_ch1 <= '0'; ch1_active_i <= '0'; ch1_ftch_idle <= '0'; ch1_ftch_interr_set <= '0'; ch1_ftch_slverr_set <= '0'; ch1_ftch_decerr_set <= '0'; ch1_ftch_err_early <= '0'; ch1_ftch_stale_desc <= '0'; end generate GEN_NO_CH1_FETCH; ------------------------------------------------------------------------------- -- Channel included therefore generate fetch logic ------------------------------------------------------------------------------- GEN_CH2_FETCH : if C_INCLUDE_CH2 = 1 generate begin ------------------------------------------------------------------------------- -- Active channel flag. Indicates which channel is active. -- 0 = channel active -- 1 = channel active ------------------------------------------------------------------------------- CH2_ACTIVE_PROCESS : process(m_axi_sg_aclk) begin if(m_axi_sg_aclk'EVENT and m_axi_sg_aclk = '1')then if(m_axi_sg_aresetn = '0' or ch1_active_set = '1')then ch2_active_i <= '0'; elsif(ch2_active_set = '1')then ch2_active_i <= '1'; end if; end if; end process CH2_ACTIVE_PROCESS; ------------------------------------------------------------------------------- -- Channel 2 IDLE process. Indicates channel 2 fetch process is IDLE -- This is 1 part of determining IDLE for a channel ------------------------------------------------------------------------------- CH2_IDLE_PROCESS : process(m_axi_sg_aclk) begin if(m_axi_sg_aclk'EVENT and m_axi_sg_aclk = '1')then -- If reset or stopped then clear idle bit if(m_axi_sg_aresetn = '0')then ch2_ftch_idle <= '1'; -- SG Error therefore force IDLE -- CR564855 - fetch idle asserted too soon when update error occured. -- fetch idle does not need to be concerned with updt_error. This is -- because on going fetch is guarentteed to complete regardless of dma -- controller or sg update engine. -- elsif(updt_error = '1' or ftch_error = '1' elsif(ftch_error = '1' or ch2_ftch_interr_set_i = '1')then ch2_ftch_idle <= '1'; -- When SG Fetch no longer idle then clear fetch idle elsif(ch2_sg_idle = '0')then ch2_ftch_idle <= '0'; -- If tail = cur and fetch queue is empty then elsif(ch2_sg_idle = '1' and ch2_ftch_queue_empty = '1' and ch2_ftch_sm_idle = '1')then ch2_ftch_idle <= '1'; end if; end if; end process CH2_IDLE_PROCESS; ------------------------------------------------------------------------------- -- For No Fetch Queue, generate pause logic to prevent partial descriptor from -- being fetched and then endless throttle on AXI read bus ------------------------------------------------------------------------------- GEN_CH2_FETCH_PAUSE : if C_SG_FTCH_DESC2QUEUE = 0 generate begin REG_PAUSE_FETCH : process(m_axi_sg_aclk) begin if(m_axi_sg_aclk'EVENT and m_axi_sg_aclk = '1')then -- On descriptor update done clear pause if(m_axi_sg_aresetn = '0' or ch2_updt_done = '1')then ch2_pause_fetch <= '0'; -- If channel active and command written then pause elsif(ch2_active_i='1' and write_cmnd_cmb = '1')then ch2_pause_fetch <= '1'; end if; ch2_pause_fetch1 <= ch2_pause_fetch; ch2_pause_fetch2 <= ch2_pause_fetch1; ch2_pause_fetch3 <= ch2_pause_fetch2; end if; end process REG_PAUSE_FETCH; end generate GEN_CH2_FETCH_PAUSE; -- Fetch queues so do not need to pause GEN_CH2_NO_FETCH_PAUSE : if C_SG_FTCH_DESC2QUEUE /= 0 generate -- -- CR585958 -- -- Required width in bits for C_SG_FTCH_DESC2QUEUE -- constant SG_FTCH_DESC2QUEUE_WIDTH : integer := clog2(C_SG_FTCH_DESC2QUEUE+1); -- -- Vector version of C_SG_FTCH_DESC2QUEUE -- constant SG_FTCH_DESC2QUEUE_VEC : std_logic_vector(SG_FTCH_DESC2QUEUE_WIDTH-1 downto 0) -- := std_logic_vector(to_unsigned -- (C_SG_FTCH_DESC2QUEUE,SG_FTCH_DESC2QUEUE_WIDTH)); -- signal desc_queued_incr : std_logic := '0'; -- signal desc_queued_decr : std_logic := '0'; -- -- -- CR585958 -- signal ch2_desc_ftched_count: std_logic_vector -- (SG_FTCH_DESC2QUEUE_WIDTH-1 downto 0) := (others => '0'); -- -- begin -- -- desc_queued_incr <= '1' when ch2_active_i = '1' -- and write_cmnd_cmb = '1' -- and ch2_ftch_descpulled = '0' -- else '0'; -- -- desc_queued_decr <= '1' when ch2_ftch_descpulled = '1' -- and not (ch2_active_i = '1' and write_cmnd_cmb = '1') -- else '0'; -- -- -- Keep track of descriptors queued version descriptors updated -- DESC_FETCHED_CNTR : process(m_axi_sg_aclk) -- begin -- if(m_axi_sg_aclk'EVENT and m_axi_sg_aclk = '1')then -- if(m_axi_sg_aresetn = '0')then -- ch2_desc_ftched_count <= (others => '0'); -- elsif(desc_queued_incr = '1')then -- ch2_desc_ftched_count <= std_logic_vector(unsigned(ch2_desc_ftched_count) + 1); -- elsif(desc_queued_decr = '1')then -- ch2_desc_ftched_count <= std_logic_vector(unsigned(ch2_desc_ftched_count) - 1); -- end if; -- end if; -- end process DESC_FETCHED_CNTR; -- -- REG_PAUSE_FETCH : process(m_axi_sg_aclk) -- begin -- if(m_axi_sg_aclk'EVENT and m_axi_sg_aclk = '1')then -- if(m_axi_sg_aresetn = '0')then -- ch2_pause_fetch <= '0'; -- elsif(ch2_desc_ftched_count >= SG_FTCH_DESC2QUEUE_VEC)then -- ch2_pause_fetch <= '1'; -- else -- ch2_pause_fetch <= '0'; -- end if; -- end if; -- end process REG_PAUSE_FETCH; -- ch2_pause_fetch <= ch2_ftch_pause; end generate GEN_CH2_NO_FETCH_PAUSE; ------------------------------------------------------------------------------- -- Channel 2 ready to be serviced? ------------------------------------------------------------------------------- MCDMA : if (C_ENABLE_MULTI_CHANNEL = 1) generate NOQUEUE : if (C_SG_FTCH_DESC2QUEUE = 0) generate service_ch2 <= '1' when ch2_run_stop = '1' -- Channel running and ch2_sg_idle = '0' -- SG Engine running and ch2_ftch_queue_full = '0' -- Queue not full and updt_error = '0' -- No SG Update error and ch2_stale_descriptor = '0' -- No Stale Descriptors and ch2_desc_flush = '0' -- Not flushing desc and ch2_pause_fetch3 = '0' -- No fetch pause else '0'; end generate NOQUEUE; QUEUE : if (C_SG_FTCH_DESC2QUEUE /= 0) generate service_ch2 <= '1' when ch2_run_stop = '1' -- Channel running and ch2_sg_idle = '0' -- SG Engine running and ch2_ftch_queue_full = '0' -- Queue not full and updt_error = '0' -- No SG Update error and ch2_stale_descriptor = '0' -- No Stale Descriptors and ch2_desc_flush = '0' -- Not flushing desc and ch2_pause_fetch = '0' -- No fetch pause else '0'; end generate QUEUE; end generate MCDMA; NO_MCDMA : if (C_ENABLE_MULTI_CHANNEL = 0) generate service_ch2 <= '1' when ch2_run_stop = '1' -- Channel running and ch2_sg_idle = '0' -- SG Engine running and ch2_ftch_queue_full = '0' -- Queue not full and updt_error = '0' -- No SG Update error and ch2_stale_descriptor = '0' -- No Stale Descriptors and ch2_desc_flush = '0' -- Not flushing desc and ch2_pause_fetch = '0' -- No fetch pause else '0'; end generate NO_MCDMA; ------------------------------------------------------------------------------- -- Log Fetch Errors ------------------------------------------------------------------------------- INT_ERROR_PROCESS : process(m_axi_sg_aclk) begin if(m_axi_sg_aclk'EVENT and m_axi_sg_aclk = '1')then -- If reset or stopped then clear idle bit if(m_axi_sg_aresetn = '0')then ch2_ftch_interr_set_i <= '0'; -- Channel active and datamover int error or fetch done and descriptor stale elsif((ch2_active_i = '1' and ftch_interr = '1') or ((ftch_done = '1' or ftch_error = '1') and ch2_stale_descriptor = '1'))then ch2_ftch_interr_set_i <= '1'; end if; end if; end process INT_ERROR_PROCESS; ch2_ftch_interr_set <= ch2_ftch_interr_set_i; SLV_ERROR_PROCESS : process(m_axi_sg_aclk) begin if(m_axi_sg_aclk'EVENT and m_axi_sg_aclk = '1')then -- If reset or stopped then clear idle bit if(m_axi_sg_aresetn = '0')then ch2_ftch_slverr_set <= '0'; elsif(ch2_active_i = '1' and ftch_slverr = '1')then ch2_ftch_slverr_set <= '1'; end if; end if; end process SLV_ERROR_PROCESS; DEC_ERROR_PROCESS : process(m_axi_sg_aclk) begin if(m_axi_sg_aclk'EVENT and m_axi_sg_aclk = '1')then -- If reset or stopped then clear idle bit if(m_axi_sg_aresetn = '0')then ch2_ftch_decerr_set <= '0'; elsif(ch2_active_i = '1' and ftch_decerr = '1')then ch2_ftch_decerr_set <= '1'; end if; end if; end process DEC_ERROR_PROCESS; -- Early detection of SlvErr or DecErr, used to prevent error'ed descriptor -- from being used by dma controller ch2_ftch_err_early <= '1' when ftch_error_early = '1' and ch2_active_i = '1' else '0'; -- Enable stale descriptor check GEN_CH2_STALE_CHECK : if C_SG_CH2_ENBL_STALE_ERROR = 1 generate begin ----------------------------------------------------------------------- -- Stale Descriptor Error ----------------------------------------------------------------------- CH2_STALE_DESC : process(m_axi_sg_aclk) begin if(m_axi_sg_aclk'EVENT and m_axi_sg_aclk = '1')then -- If reset then clear flag if(m_axi_sg_aresetn = '0')then ch2_stale_descriptor <= '0'; elsif(ftch_stale_desc = '1' and ch2_active_i = '1' )then ch2_stale_descriptor <= '1'; end if; end if; end process CH2_STALE_DESC; end generate GEN_CH2_STALE_CHECK; -- Disable stale descriptor check GEN_CH2_NO_STALE_CHECK : if C_SG_CH2_ENBL_STALE_ERROR = 0 generate begin ch2_stale_descriptor <= '0'; end generate GEN_CH2_NO_STALE_CHECK; -- Early detection of Stale Descriptor (valid only in tailpntr mode) used -- to prevent error'ed descriptor from being used. ch2_ftch_stale_desc <= ch2_stale_descriptor; end generate GEN_CH2_FETCH; ------------------------------------------------------------------------------- -- Channel excluded therefore do not generate fetch logic ------------------------------------------------------------------------------- GEN_NO_CH2_FETCH : if C_INCLUDE_CH2 = 0 generate begin service_ch2 <= '0'; ch2_active_i <= '0'; ch2_ftch_idle <= '0'; ch2_ftch_interr_set <= '0'; ch2_ftch_slverr_set <= '0'; ch2_ftch_decerr_set <= '0'; ch2_ftch_err_early <= '0'; ch2_ftch_stale_desc <= '0'; end generate GEN_NO_CH2_FETCH; ------------------------------------------------------------------------------- -- Build DataMover command ------------------------------------------------------------------------------- -- Assign fetch address fetch_cmd_addr <= ch1_fetch_address when ch1_active_i = '1' else ch2_fetch_address; -- Assign bytes to transfer (BTT) fetch_cmd_btt <= FETCH_CH1_CMD_BTT when ch1_active_i = '1' else FETCH_CH2_CMD_BTT; fetch_tag <= "0001" when ch1_active_i = '1' else "0000"; -- When command by sm, drive command to ftch_cmdsts_if --GEN_DATAMOVER_CMND : process(m_axi_sg_aclk) -- begin -- if(m_axi_sg_aclk'EVENT and m_axi_sg_aclk = '1')then -- if(m_axi_sg_aresetn = '0')then -- ftch_cmnd_wr <= '0'; -- ftch_cmnd_data <= (others => '0'); -- -- Fetch SM issued a command write -- elsif(write_cmnd_cmb = '1')then -- ftch_cmnd_wr <= '1'; -- ftch_cmnd_data <= FETCH_CMD_RSVD -- & fetch_tag -- & fetch_cmd_addr -- & FETCH_MSB_IGNORED -- & FETCH_CMD_TYPE -- & FETCH_LSB_IGNORED -- & fetch_cmd_btt; -- else -- ftch_cmnd_wr <= '0'; -- end if; -- end if; -- end process GEN_DATAMOVER_CMND; ftch_cmnd_wr <= write_cmnd_cmb; ftch_cmnd_data <= FETCH_CMD_RSVD & fetch_tag & fetch_cmd_addr & FETCH_MSB_IGNORED & FETCH_CMD_TYPE & FETCH_LSB_IGNORED & fetch_cmd_btt; ------------------------------------------------------------------------------- -- Capture and hold fetch address in case an error occurs ------------------------------------------------------------------------------- LOG_ERROR_ADDR : process(m_axi_sg_aclk) begin if(m_axi_sg_aclk'EVENT and m_axi_sg_aclk = '1')then if(m_axi_sg_aresetn = '0')then ftch_error_addr (C_M_AXI_SG_ADDR_WIDTH-1 downto SG_ADDR_LSB) <= (others => '0'); elsif(write_cmnd_cmb = '1')then ftch_error_addr (C_M_AXI_SG_ADDR_WIDTH-1 downto SG_ADDR_LSB) <= fetch_cmd_addr (C_M_AXI_SG_ADDR_WIDTH-1 downto SG_ADDR_LSB); end if; end if; end process LOG_ERROR_ADDR; ftch_error_addr (5 downto 0) <= "000000"; end implementation;	gpl-3.0	b55ba81ac6a6813173f6ca17fd630a17	0.425652	4.418259	false	false	false	false
marco-c/leon-nexys2	grlib-gpl-1.3.4-b4140/designs/leon3-gr-xc6s/config.vhd	1	9,158	----------------------------------------------------------------------------- -- LEON3 Demonstration design test bench configuration -- Copyright (C) 2009 Aeroflex Gaisler ------------------------------------------------------------------------------ library techmap; use techmap.gencomp.all; package config is -- Technology and synthesis options constant CFG_FABTECH : integer := spartan6; constant CFG_MEMTECH : integer := spartan6; constant CFG_PADTECH : integer := spartan6; constant CFG_NOASYNC : integer := 0; constant CFG_SCAN : integer := 0; -- Clock generator constant CFG_CLKTECH : integer := spartan6; constant CFG_CLKMUL : integer := (2); constant CFG_CLKDIV : integer := (2); constant CFG_OCLKDIV : integer := 1; constant CFG_OCLKBDIV : integer := 0; constant CFG_OCLKCDIV : integer := 0; constant CFG_PCIDLL : integer := 0; constant CFG_PCISYSCLK: integer := 0; constant CFG_CLK_NOFB : integer := 0; -- LEON3 processor core constant CFG_LEON3 : integer := 1; constant CFG_NCPU : integer := (1); constant CFG_NWIN : integer := (8); constant CFG_V8 : integer := 16#32# + 40; constant CFG_MAC : integer := 0; constant CFG_BP : integer := 1; constant CFG_SVT : integer := 1; constant CFG_RSTADDR : integer := 16#00000#; constant CFG_LDDEL : integer := (1); constant CFG_NOTAG : integer := 1; constant CFG_NWP : integer := (2); constant CFG_PWD : integer := 12; constant CFG_FPU : integer := 0 + 160 + 320; constant CFG_GRFPUSH : integer := 0; constant CFG_ICEN : integer := 1; constant CFG_ISETS : integer := 2; constant CFG_ISETSZ : integer := 8; constant CFG_ILINE : integer := 8; constant CFG_IREPL : integer := 2; constant CFG_ILOCK : integer := 0; constant CFG_ILRAMEN : integer := 0; constant CFG_ILRAMADDR: integer := 16#8E#; constant CFG_ILRAMSZ : integer := 1; constant CFG_DCEN : integer := 1; constant CFG_DSETS : integer := 2; constant CFG_DSETSZ : integer := 4; constant CFG_DLINE : integer := 4; constant CFG_DREPL : integer := 2; constant CFG_DLOCK : integer := 0; constant CFG_DSNOOP : integer := 1 + 1 + 41; constant CFG_DFIXED : integer := 16#0#; constant CFG_DLRAMEN : integer := 0; constant CFG_DLRAMADDR: integer := 16#8F#; constant CFG_DLRAMSZ : integer := 1; constant CFG_MMUEN : integer := 1; constant CFG_ITLBNUM : integer := 8; constant CFG_DTLBNUM : integer := 8; constant CFG_TLB_TYPE : integer := 0 + 12; constant CFG_TLB_REP : integer := 0; constant CFG_MMU_PAGE : integer := 0; constant CFG_DSU : integer := 1; constant CFG_ITBSZ : integer := 4; constant CFG_ATBSZ : integer := 4; constant CFG_LEON3FT_EN : integer := 0; constant CFG_IUFT_EN : integer := 0; constant CFG_FPUFT_EN : integer := 0; constant CFG_RF_ERRINJ : integer := 0; constant CFG_CACHE_FT_EN : integer := 0; constant CFG_CACHE_ERRINJ : integer := 0; constant CFG_LEON3_NETLIST: integer := 0; constant CFG_DISAS : integer := 0 + 0; constant CFG_PCLOW : integer := 2; -- AMBA settings constant CFG_DEFMST : integer := (0); constant CFG_RROBIN : integer := 1; constant CFG_SPLIT : integer := 0; constant CFG_FPNPEN : integer := 0; constant CFG_AHBIO : integer := 16#FFF#; constant CFG_APBADDR : integer := 16#800#; constant CFG_AHB_MON : integer := 0; constant CFG_AHB_MONERR : integer := 0; constant CFG_AHB_MONWAR : integer := 0; constant CFG_AHB_DTRACE : integer := 0; -- DSU UART constant CFG_AHB_UART : integer := 1; -- JTAG based DSU interface constant CFG_AHB_JTAG : integer := 1; -- Ethernet DSU constant CFG_DSU_ETH : integer := 1 + 0 + 0; constant CFG_ETH_BUF : integer := 16; constant CFG_ETH_IPM : integer := 16#C0A8#; constant CFG_ETH_IPL : integer := 16#0033#; constant CFG_ETH_ENM : integer := 16#020000#; constant CFG_ETH_ENL : integer := 16#000000#; -- LEON2 memory controller constant CFG_MCTRL_LEON2 : integer := 1; constant CFG_MCTRL_RAM8BIT : integer := 1; constant CFG_MCTRL_RAM16BIT : integer := 0; constant CFG_MCTRL_5CS : integer := 0; constant CFG_MCTRL_SDEN : integer := 0; constant CFG_MCTRL_SEPBUS : integer := 0; constant CFG_MCTRL_INVCLK : integer := 0; constant CFG_MCTRL_SD64 : integer := 0; constant CFG_MCTRL_PAGE : integer := 0 + 0; -- DDR controller constant CFG_DDR2SP : integer := 0; constant CFG_DDR2SP_INIT : integer := 0; constant CFG_DDR2SP_FREQ : integer := 100; constant CFG_DDR2SP_TRFC : integer := 130; constant CFG_DDR2SP_DATAWIDTH : integer := 64; constant CFG_DDR2SP_FTEN : integer := 0; constant CFG_DDR2SP_FTWIDTH : integer := 0; constant CFG_DDR2SP_COL : integer := 9; constant CFG_DDR2SP_SIZE : integer := 8; constant CFG_DDR2SP_DELAY0 : integer := 0; constant CFG_DDR2SP_DELAY1 : integer := 0; constant CFG_DDR2SP_DELAY2 : integer := 0; constant CFG_DDR2SP_DELAY3 : integer := 0; constant CFG_DDR2SP_DELAY4 : integer := 0; constant CFG_DDR2SP_DELAY5 : integer := 0; constant CFG_DDR2SP_DELAY6 : integer := 0; constant CFG_DDR2SP_DELAY7 : integer := 0; constant CFG_DDR2SP_NOSYNC : integer := 0; -- Xilinx MIG constant CFG_MIG_DDR2 : integer := 1; constant CFG_MIG_RANKS : integer := (1); constant CFG_MIG_COLBITS : integer := (10); constant CFG_MIG_ROWBITS : integer := (13); constant CFG_MIG_BANKBITS: integer := (2); constant CFG_MIG_HMASK : integer := 16#F00#; -- AHB status register constant CFG_AHBSTAT : integer := 1; constant CFG_AHBSTATN : integer := (1); -- AHB ROM constant CFG_AHBROMEN : integer := 0; constant CFG_AHBROPIP : integer := 0; constant CFG_AHBRODDR : integer := 16#000#; constant CFG_ROMADDR : integer := 16#000#; constant CFG_ROMMASK : integer := 16#E00# + 16#000#; -- AHB RAM constant CFG_AHBRAMEN : integer := 0; constant CFG_AHBRSZ : integer := 1; constant CFG_AHBRADDR : integer := 16#A00#; constant CFG_AHBRPIPE : integer := 0; -- Gaisler Ethernet core constant CFG_GRETH : integer := 1; constant CFG_GRETH1G : integer := 1; constant CFG_ETH_FIFO : integer := 8; constant CFG_GRETH_FT : integer := 0; constant CFG_GRETH_EDCLFT : integer := 0; -- CAN 2.0 interface constant CFG_CAN : integer := 0; constant CFG_CAN_NUM : integer := 1; constant CFG_CANIO : integer := 16#0#; constant CFG_CANIRQ : integer := 0; constant CFG_CANSEPIRQ: integer := 0; constant CFG_CAN_SYNCRST : integer := 0; constant CFG_CANFT : integer := 0; -- UART 1 constant CFG_UART1_ENABLE : integer := 1; constant CFG_UART1_FIFO : integer := 4; -- UART 2 constant CFG_UART2_ENABLE : integer := 0; constant CFG_UART2_FIFO : integer := 1; -- LEON3 interrupt controller constant CFG_IRQ3_ENABLE : integer := 1; constant CFG_IRQ3_NSEC : integer := 0; -- Modular timer constant CFG_GPT_ENABLE : integer := 1; constant CFG_GPT_NTIM : integer := (2); constant CFG_GPT_SW : integer := (8); constant CFG_GPT_TW : integer := (32); constant CFG_GPT_IRQ : integer := (8); constant CFG_GPT_SEPIRQ : integer := 1; constant CFG_GPT_WDOGEN : integer := 0; constant CFG_GPT_WDOG : integer := 16#0#; -- GPIO port constant CFG_GRGPIO_ENABLE : integer := 1; constant CFG_GRGPIO_IMASK : integer := 16#0000#; constant CFG_GRGPIO_WIDTH : integer := (8); -- Spacewire interface constant CFG_SPW_EN : integer := 0; constant CFG_SPW_NUM : integer := 1; constant CFG_SPW_AHBFIFO : integer := 4; constant CFG_SPW_RXFIFO : integer := 16; constant CFG_SPW_RMAP : integer := 0; constant CFG_SPW_RMAPBUF : integer := 4; constant CFG_SPW_RMAPCRC : integer := 0; constant CFG_SPW_NETLIST : integer := 0; constant CFG_SPW_FT : integer := 0; constant CFG_SPW_GRSPW : integer := 2; constant CFG_SPW_RXUNAL : integer := 0; constant CFG_SPW_DMACHAN : integer := 1; constant CFG_SPW_PORTS : integer := 1; constant CFG_SPW_INPUT : integer := 2; constant CFG_SPW_OUTPUT : integer := 0; constant CFG_SPW_RTSAME : integer := 0; -- VGA and PS2/ interface constant CFG_KBD_ENABLE : integer := 1; constant CFG_VGA_ENABLE : integer := 0; constant CFG_SVGA_ENABLE : integer := 1; -- SPI memory controller constant CFG_SPIMCTRL : integer := 1; constant CFG_SPIMCTRL_SDCARD : integer := 0; constant CFG_SPIMCTRL_READCMD : integer := 16#0B#; constant CFG_SPIMCTRL_DUMMYBYTE : integer := 0; constant CFG_SPIMCTRL_DUALOUTPUT : integer := 0; constant CFG_SPIMCTRL_SCALER : integer := (1); constant CFG_SPIMCTRL_ASCALER : integer := (8); constant CFG_SPIMCTRL_PWRUPCNT : integer := (0); constant CFG_SPIMCTRL_OFFSET : integer := 16#0#; -- SPI controller constant CFG_SPICTRL_ENABLE : integer := 1; constant CFG_SPICTRL_NUM : integer := (1); constant CFG_SPICTRL_SLVS : integer := (1); constant CFG_SPICTRL_FIFO : integer := (1); constant CFG_SPICTRL_SLVREG : integer := 1; constant CFG_SPICTRL_ODMODE : integer := 0; constant CFG_SPICTRL_AM : integer := 0; constant CFG_SPICTRL_ASEL : integer := 0; constant CFG_SPICTRL_TWEN : integer := 0; constant CFG_SPICTRL_MAXWLEN : integer := (0); constant CFG_SPICTRL_SYNCRAM : integer := 0; constant CFG_SPICTRL_FT : integer := 0; -- GRLIB debugging constant CFG_DUART : integer := 0; end;	gpl-2.0	8bc0f6dcefa0c908858f33a164a816c7	0.65451	3.560653	false	false	false	false
Fairyland0902/BlockyRoads	src/BlockyRoads/ipcore_dir/road/example_design/road_prod.vhd	1	9,891	-------------------------------------------------------------------------------- -- -- BLK MEM GEN v7.1 Core - Top-level wrapper -- -------------------------------------------------------------------------------- -- -- (c) Copyright 2006-2011 Xilinx, Inc. All rights reserved. -- -- This file contains confidential and proprietary information -- of Xilinx, Inc. and is protected under U.S. and -- international copyright and other intellectual property -- laws. -- -- DISCLAIMER -- This disclaimer is not a license and does not grant any -- rights to the materials distributed herewith. Except as -- otherwise provided in a valid license issued to you by -- Xilinx, and to the maximum extent permitted by applicable -- law: (1) THESE MATERIALS ARE MADE AVAILABLE "AS IS" AND -- WITH ALL FAULTS, AND XILINX HEREBY DISCLAIMS ALL WARRANTIES -- AND CONDITIONS, EXPRESS, IMPLIED, OR STATUTORY, INCLUDING -- BUT NOT LIMITED TO WARRANTIES OF MERCHANTABILITY, NON- -- INFRINGEMENT, OR FITNESS FOR ANY PARTICULAR PURPOSE; and -- (2) Xilinx shall not be liable (whether in contract or tort, -- including negligence, or under any other theory of -- liability) for any loss or damage of any kind or nature -- related to, arising under or in connection with these -- materials, including for any direct, or any indirect, -- special, incidental, or consequential loss or damage -- (including loss of data, profits, goodwill, or any type of -- loss or damage suffered as a result of any action brought -- by a third party) even if such damage or loss was -- reasonably foreseeable or Xilinx had been advised of the -- possibility of the same. -- -- CRITICAL APPLICATIONS -- Xilinx products are not designed or intended to be fail- -- safe, or for use in any application requiring fail-safe -- performance, such as life-support or safety devices or -- systems, Class III medical devices, nuclear facilities, -- applications related to the deployment of airbags, or any -- other applications that could lead to death, personal -- injury, or severe property or environmental damage -- (individually and collectively, "Critical -- Applications"). Customer assumes the sole risk and -- liability of any use of Xilinx products in Critical -- Applications, subject only to applicable laws and -- regulations governing limitations on product liability. -- -- THIS COPYRIGHT NOTICE AND DISCLAIMER MUST BE RETAINED AS -- PART OF THIS FILE AT ALL TIMES. -- -------------------------------------------------------------------------------- -- -- Filename: road_prod.vhd -- -- Description: -- This is the top-level BMG wrapper (over BMG core). -- -------------------------------------------------------------------------------- -- Author: IP Solutions Division -- -- History: August 31, 2005 - First Release -------------------------------------------------------------------------------- -- -- Configured Core Parameter Values: -- (Refer to the SIM Parameters table in the datasheet for more information on -- the these parameters.) -- C_FAMILY : artix7 -- C_XDEVICEFAMILY : artix7 -- C_INTERFACE_TYPE : 0 -- C_ENABLE_32BIT_ADDRESS : 0 -- C_AXI_TYPE : 1 -- C_AXI_SLAVE_TYPE : 0 -- C_AXI_ID_WIDTH : 4 -- C_MEM_TYPE : 3 -- C_BYTE_SIZE : 9 -- C_ALGORITHM : 1 -- C_PRIM_TYPE : 1 -- C_LOAD_INIT_FILE : 1 -- C_INIT_FILE_NAME : road.mif -- C_USE_DEFAULT_DATA : 0 -- C_DEFAULT_DATA : 0 -- C_RST_TYPE : SYNC -- C_HAS_RSTA : 0 -- C_RST_PRIORITY_A : CE -- C_RSTRAM_A : 0 -- C_INITA_VAL : 0 -- C_HAS_ENA : 0 -- C_HAS_REGCEA : 0 -- C_USE_BYTE_WEA : 0 -- C_WEA_WIDTH : 1 -- C_WRITE_MODE_A : WRITE_FIRST -- C_WRITE_WIDTH_A : 12 -- C_READ_WIDTH_A : 12 -- C_WRITE_DEPTH_A : 99200 -- C_READ_DEPTH_A : 99200 -- C_ADDRA_WIDTH : 17 -- C_HAS_RSTB : 0 -- C_RST_PRIORITY_B : CE -- C_RSTRAM_B : 0 -- C_INITB_VAL : 0 -- C_HAS_ENB : 0 -- C_HAS_REGCEB : 0 -- C_USE_BYTE_WEB : 0 -- C_WEB_WIDTH : 1 -- C_WRITE_MODE_B : WRITE_FIRST -- C_WRITE_WIDTH_B : 12 -- C_READ_WIDTH_B : 12 -- C_WRITE_DEPTH_B : 99200 -- C_READ_DEPTH_B : 99200 -- C_ADDRB_WIDTH : 17 -- C_HAS_MEM_OUTPUT_REGS_A : 0 -- C_HAS_MEM_OUTPUT_REGS_B : 0 -- C_HAS_MUX_OUTPUT_REGS_A : 0 -- C_HAS_MUX_OUTPUT_REGS_B : 0 -- C_HAS_SOFTECC_INPUT_REGS_A : 0 -- C_HAS_SOFTECC_OUTPUT_REGS_B : 0 -- C_MUX_PIPELINE_STAGES : 0 -- C_USE_ECC : 0 -- C_USE_SOFTECC : 0 -- C_HAS_INJECTERR : 0 -- C_SIM_COLLISION_CHECK : ALL -- C_COMMON_CLK : 0 -- C_DISABLE_WARN_BHV_COLL : 0 -- C_DISABLE_WARN_BHV_RANGE : 0 -------------------------------------------------------------------------------- -- Library Declarations -------------------------------------------------------------------------------- LIBRARY IEEE; USE IEEE.STD_LOGIC_1164.ALL; USE IEEE.STD_LOGIC_ARITH.ALL; USE IEEE.STD_LOGIC_UNSIGNED.ALL; LIBRARY UNISIM; USE UNISIM.VCOMPONENTS.ALL; -------------------------------------------------------------------------------- -- Entity Declaration -------------------------------------------------------------------------------- ENTITY road_prod IS PORT ( --Port A CLKA : IN STD_LOGIC; RSTA : IN STD_LOGIC; --opt port ENA : IN STD_LOGIC; --optional port REGCEA : IN STD_LOGIC; --optional port WEA : IN STD_LOGIC_VECTOR(0 DOWNTO 0); ADDRA : IN STD_LOGIC_VECTOR(16 DOWNTO 0); DINA : IN STD_LOGIC_VECTOR(11 DOWNTO 0); DOUTA : OUT STD_LOGIC_VECTOR(11 DOWNTO 0); --Port B CLKB : IN STD_LOGIC; RSTB : IN STD_LOGIC; --opt port ENB : IN STD_LOGIC; --optional port REGCEB : IN STD_LOGIC; --optional port WEB : IN STD_LOGIC_VECTOR(0 DOWNTO 0); ADDRB : IN STD_LOGIC_VECTOR(16 DOWNTO 0); DINB : IN STD_LOGIC_VECTOR(11 DOWNTO 0); DOUTB : OUT STD_LOGIC_VECTOR(11 DOWNTO 0); --ECC INJECTSBITERR : IN STD_LOGIC; --optional port INJECTDBITERR : IN STD_LOGIC; --optional port SBITERR : OUT STD_LOGIC; --optional port DBITERR : OUT STD_LOGIC; --optional port RDADDRECC : OUT STD_LOGIC_VECTOR(16 DOWNTO 0); --optional port -- AXI BMG Input and Output Port Declarations -- AXI Global Signals S_ACLK : IN STD_LOGIC; S_AXI_AWID : IN STD_LOGIC_VECTOR(3 DOWNTO 0); S_AXI_AWADDR : IN STD_LOGIC_VECTOR(31 DOWNTO 0); S_AXI_AWLEN : IN STD_LOGIC_VECTOR(7 DOWNTO 0); S_AXI_AWSIZE : IN STD_LOGIC_VECTOR(2 DOWNTO 0); S_AXI_AWBURST : IN STD_LOGIC_VECTOR(1 DOWNTO 0); S_AXI_AWVALID : IN STD_LOGIC; S_AXI_AWREADY : OUT STD_LOGIC; S_AXI_WDATA : IN STD_LOGIC_VECTOR(11 DOWNTO 0); S_AXI_WSTRB : IN STD_LOGIC_VECTOR(0 DOWNTO 0); S_AXI_WLAST : IN STD_LOGIC; S_AXI_WVALID : IN STD_LOGIC; S_AXI_WREADY : OUT STD_LOGIC; S_AXI_BID : OUT STD_LOGIC_VECTOR(3 DOWNTO 0):= (OTHERS => '0'); S_AXI_BRESP : OUT STD_LOGIC_VECTOR(1 DOWNTO 0); S_AXI_BVALID : OUT STD_LOGIC; S_AXI_BREADY : IN STD_LOGIC; -- AXI Full/Lite Slave Read (Write side) S_AXI_ARID : IN STD_LOGIC_VECTOR(3 DOWNTO 0); S_AXI_ARADDR : IN STD_LOGIC_VECTOR(31 DOWNTO 0); S_AXI_ARLEN : IN STD_LOGIC_VECTOR(7 DOWNTO 0); S_AXI_ARSIZE : IN STD_LOGIC_VECTOR(2 DOWNTO 0); S_AXI_ARBURST : IN STD_LOGIC_VECTOR(1 DOWNTO 0); S_AXI_ARVALID : IN STD_LOGIC; S_AXI_ARREADY : OUT STD_LOGIC; S_AXI_RID : OUT STD_LOGIC_VECTOR(3 DOWNTO 0):= (OTHERS => '0'); S_AXI_RDATA : OUT STD_LOGIC_VECTOR(11 DOWNTO 0); S_AXI_RRESP : OUT STD_LOGIC_VECTOR(1 DOWNTO 0); S_AXI_RLAST : OUT STD_LOGIC; S_AXI_RVALID : OUT STD_LOGIC; S_AXI_RREADY : IN STD_LOGIC; -- AXI Full/Lite Sideband Signals S_AXI_INJECTSBITERR : IN STD_LOGIC; S_AXI_INJECTDBITERR : IN STD_LOGIC; S_AXI_SBITERR : OUT STD_LOGIC; S_AXI_DBITERR : OUT STD_LOGIC; S_AXI_RDADDRECC : OUT STD_LOGIC_VECTOR(16 DOWNTO 0); S_ARESETN : IN STD_LOGIC ); END road_prod; ARCHITECTURE xilinx OF road_prod IS COMPONENT road_exdes IS PORT ( --Port A ADDRA : IN STD_LOGIC_VECTOR(16 DOWNTO 0); DOUTA : OUT STD_LOGIC_VECTOR(11 DOWNTO 0); CLKA : IN STD_LOGIC ); END COMPONENT; BEGIN bmg0 : road_exdes PORT MAP ( --Port A ADDRA => ADDRA, DOUTA => DOUTA, CLKA => CLKA ); END xilinx;	mit	13a290a1984d223526d26f30b16742b5	0.493984	3.818919	false	false	false	false
marco-c/leon-nexys2	grlib-gpl-1.3.4-b4140/lib/grlib/amba/amba.vhd	1	44,534	------------------------------------------------------------------------------ -- This file is a part of the GRLIB VHDL IP LIBRARY -- Copyright (C) 2003 - 2008, Gaisler Research -- Copyright (C) 2008 - 2013, Aeroflex Gaisler -- -- This program is free software; you can redistribute it and/or modify -- it under the terms of the GNU General Public License as published by -- the Free Software Foundation; either version 2 of the License, or -- (at your option) any later version. -- -- This program is distributed in the hope that it will be useful, -- but WITHOUT ANY WARRANTY; without even the implied warranty of -- MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the -- GNU General Public License for more details. -- -- You should have received a copy of the GNU General Public License -- along with this program; if not, write to the Free Software -- Foundation, Inc., 59 Temple Place, Suite 330, Boston, MA 02111-1307 USA ----------------------------------------------------------------------------- -- Package: amba -- File: amba.vhd -- Author: Jiri Gaisler, Gaisler Research -- Modified by: Jan Andersson, Aeroflex Gaisler -- Description: AMBA 2.0 bus signal definitions + support for plug&play ------------------------------------------------------------------------------ library ieee; use ieee.std_logic_1164.all; use ieee.numeric_std.all; -- pragma translate_off use std.textio.all; -- pragma translate_on library grlib; use grlib.config_types.all; use grlib.config.all; use grlib.stdlib.all; package amba is ------------------------------------------------------------------------------- -- AMBA configuration ------------------------------------------------------------------------------- -- AHBDW - AHB data with -- -- Valid values are 32, 64, 128 and 256 -- -- The value here sets the width of the AMBA AHB data vectors for all -- cores in the library. -- constant AHBDW : integer := CFG_AHBDW; -- CORE_ACDM - Enable AMBA Compliant Data Muxing in cores -- -- Valid values are 0 and 1 -- -- 0: All GRLIB cores that use the ahbread* programs defined in this package -- will read their data from the low part of the AHB data vector. -- -- 1: All GRLIB cores that use the ahbread* programs defined in this package -- will select valid data, as defined in the AMBA AHB standard, from the -- AHB data vectors based on the address input. If a core uses a function -- that does not have the address input, a failure will be asserted. -- constant CORE_ACDM : integer := CFG_AHB_ACDM; constant NAHBMST : integer := 16; -- maximum AHB masters constant NAHBSLV : integer := 16; -- maximum AHB slaves constant NAPBSLV : integer := 16; -- maximum APB slaves constant NAHBIRQ : integer := 32; -- maximum interrupts constant NAHBAMR : integer := 4; -- maximum address mapping registers constant NAHBIR : integer := 4; -- maximum AHB identification registers constant NAHBCFG : integer := NAHBIR + NAHBAMR; -- words in AHB config block constant NAPBIR : integer := 1; -- maximum APB configuration words constant NAPBAMR : integer := 1; -- maximum APB configuration words constant NAPBCFG : integer := NAPBIR + NAPBAMR; -- words in APB config block constant NBUS : integer := 4; -- Number of test vector bits constant NTESTINBITS : integer := 4+GRLIB_CONFIG_ARRAY(grlib_techmap_testin_extra); ------------------------------------------------------------------------------- -- AMBA interface type declarations and constant ------------------------------------------------------------------------------- subtype amba_config_word is std_logic_vector(31 downto 0); type ahb_config_type is array (0 to NAHBCFG-1) of amba_config_word; type apb_config_type is array (0 to NAPBCFG-1) of amba_config_word; -- AHB master inputs type ahb_mst_in_type is record hgrant : std_logic_vector(0 to NAHBMST-1); -- bus grant hready : std_ulogic; -- transfer done hresp : std_logic_vector(1 downto 0); -- response type hrdata : std_logic_vector(AHBDW-1 downto 0); -- read data bus hirq : std_logic_vector(NAHBIRQ-1 downto 0); -- interrupt result bus testen : std_ulogic; -- scan test enable testrst : std_ulogic; -- scan test reset scanen : std_ulogic; -- scan enable testoen : std_ulogic; -- test output enable testin : std_logic_vector(NTESTINBITS-1 downto 0); -- test vector for syncrams end record; -- AHB master outputs type ahb_mst_out_type is record hbusreq : std_ulogic; -- bus request hlock : std_ulogic; -- lock request htrans : std_logic_vector(1 downto 0); -- transfer type haddr : std_logic_vector(31 downto 0); -- address bus (byte) hwrite : std_ulogic; -- read/write hsize : std_logic_vector(2 downto 0); -- transfer size hburst : std_logic_vector(2 downto 0); -- burst type hprot : std_logic_vector(3 downto 0); -- protection control hwdata : std_logic_vector(AHBDW-1 downto 0); -- write data bus hirq : std_logic_vector(NAHBIRQ-1 downto 0); -- interrupt bus hconfig : ahb_config_type; -- memory access reg. hindex : integer range 0 to NAHBMST-1; -- diagnostic use only end record; -- AHB slave inputs type ahb_slv_in_type is record hsel : std_logic_vector(0 to NAHBSLV-1); -- slave select haddr : std_logic_vector(31 downto 0); -- address bus (byte) hwrite : std_ulogic; -- read/write htrans : std_logic_vector(1 downto 0); -- transfer type hsize : std_logic_vector(2 downto 0); -- transfer size hburst : std_logic_vector(2 downto 0); -- burst type hwdata : std_logic_vector(AHBDW-1 downto 0); -- write data bus hprot : std_logic_vector(3 downto 0); -- protection control hready : std_ulogic; -- transfer done hmaster : std_logic_vector(3 downto 0); -- current master hmastlock : std_ulogic; -- locked access hmbsel : std_logic_vector(0 to NAHBAMR-1); -- memory bank select hirq : std_logic_vector(NAHBIRQ-1 downto 0); -- interrupt result bus testen : std_ulogic; -- scan test enable testrst : std_ulogic; -- scan test reset scanen : std_ulogic; -- scan enable testoen : std_ulogic; -- test output enable testin : std_logic_vector(NTESTINBITS-1 downto 0); -- test vector for syncrams end record; -- AHB slave outputs type ahb_slv_out_type is record hready : std_ulogic; -- transfer done hresp : std_logic_vector(1 downto 0); -- response type hrdata : std_logic_vector(AHBDW-1 downto 0); -- read data bus hsplit : std_logic_vector(NAHBMST-1 downto 0); -- split completion hirq : std_logic_vector(NAHBIRQ-1 downto 0); -- interrupt bus hconfig : ahb_config_type; -- memory access reg. hindex : integer range 0 to NAHBSLV-1; -- diagnostic use only end record; -- array types type ahb_mst_out_vector_type is array (natural range <>) of ahb_mst_out_type; type ahb_mst_in_vector_type is array (natural range <>) of ahb_mst_in_type; type ahb_slv_out_vector_type is array (natural range <>) of ahb_slv_out_type; type ahb_slv_in_vector_type is array (natural range <>) of ahb_slv_in_type; subtype ahb_mst_out_vector is ahb_mst_out_vector_type(NAHBMST-1 downto 0); subtype ahb_slv_out_vector is ahb_slv_out_vector_type(NAHBSLV-1 downto 0); type ahb_mst_out_bus_vector is array (0 to NBUS-1) of ahb_mst_out_vector; type ahb_slv_out_bus_vector is array (0 to NBUS-1) of ahb_slv_out_vector; -- constants constant HTRANS_IDLE: std_logic_vector(1 downto 0) := "00"; constant HTRANS_BUSY: std_logic_vector(1 downto 0) := "01"; constant HTRANS_NONSEQ: std_logic_vector(1 downto 0) := "10"; constant HTRANS_SEQ: std_logic_vector(1 downto 0) := "11"; constant HBURST_SINGLE: std_logic_vector(2 downto 0) := "000"; constant HBURST_INCR: std_logic_vector(2 downto 0) := "001"; constant HBURST_WRAP4: std_logic_vector(2 downto 0) := "010"; constant HBURST_INCR4: std_logic_vector(2 downto 0) := "011"; constant HBURST_WRAP8: std_logic_vector(2 downto 0) := "100"; constant HBURST_INCR8: std_logic_vector(2 downto 0) := "101"; constant HBURST_WRAP16: std_logic_vector(2 downto 0) := "110"; constant HBURST_INCR16: std_logic_vector(2 downto 0) := "111"; constant HSIZE_BYTE: std_logic_vector(2 downto 0) := "000"; constant HSIZE_HWORD: std_logic_vector(2 downto 0) := "001"; constant HSIZE_WORD: std_logic_vector(2 downto 0) := "010"; constant HSIZE_DWORD: std_logic_vector(2 downto 0) := "011"; constant HSIZE_4WORD: std_logic_vector(2 downto 0) := "100"; constant HSIZE_8WORD: std_logic_vector(2 downto 0) := "101"; constant HSIZE_16WORD: std_logic_vector(2 downto 0) := "110"; constant HSIZE_32WORD: std_logic_vector(2 downto 0) := "111"; constant HRESP_OKAY: std_logic_vector(1 downto 0) := "00"; constant HRESP_ERROR: std_logic_vector(1 downto 0) := "01"; constant HRESP_RETRY: std_logic_vector(1 downto 0) := "10"; constant HRESP_SPLIT: std_logic_vector(1 downto 0) := "11"; -- APB slave inputs type apb_slv_in_type is record psel : std_logic_vector(0 to NAPBSLV-1); -- slave select penable : std_ulogic; -- strobe paddr : std_logic_vector(31 downto 0); -- address bus (byte) pwrite : std_ulogic; -- write pwdata : std_logic_vector(31 downto 0); -- write data bus pirq : std_logic_vector(NAHBIRQ-1 downto 0); -- interrupt result bus testen : std_ulogic; -- scan test enable testrst : std_ulogic; -- scan test reset scanen : std_ulogic; -- scan enable testoen : std_ulogic; -- test output enable testin : std_logic_vector(NTESTINBITS-1 downto 0); -- test vector for syncrams end record; -- APB slave outputs type apb_slv_out_type is record prdata : std_logic_vector(31 downto 0); -- read data bus pirq : std_logic_vector(NAHBIRQ-1 downto 0); -- interrupt bus pconfig : apb_config_type; -- memory access reg. pindex : integer range 0 to NAPBSLV -1; -- diag use only end record; -- array types type apb_slv_out_vector is array (0 to NAPBSLV-1) of apb_slv_out_type; -- support for plug&play configuration constant AMBA_CONFIG_VER0 : std_logic_vector(1 downto 0) := "00"; subtype amba_vendor_type is integer range 0 to 16#ff#; subtype amba_device_type is integer range 0 to 16#3ff#; subtype amba_version_type is integer range 0 to 16#3f#; subtype amba_cfgver_type is integer range 0 to 3; subtype amba_irq_type is integer range 0 to NAHBIRQ-1; subtype ahb_addr_type is integer range 0 to 16#fff#; constant zx : std_logic_vector(31 downto 0) := (others => '0'); constant zahbdw : std_logic_vector(AHBDW-1 downto 0) := (others => '0'); constant zxirq : std_logic_vector(NAHBIRQ-1 downto 0) := (others => '0'); constant zy : std_logic_vector(0 to 31) := (others => '0'); constant ztestin : std_logic_vector(NTESTINBITS-1 downto 0) := (others => '0'); constant apb_none : apb_slv_out_type := (zx, zxirq(NAHBIRQ-1 downto 0), (others => zx), 0); constant ahbm_none : ahb_mst_out_type := ( '0', '0', "00", zx, '0', "000", "000", "0000", zahbdw, zxirq(NAHBIRQ-1 downto 0), (others => zx), 0); constant ahbm_in_none : ahb_mst_in_type := ((others => '0'), '0', (others => '0'), zahbdw, zxirq(NAHBIRQ-1 downto 0), '0', '0', '0', '0', ztestin); constant ahbs_none : ahb_slv_out_type := ( '1', "00", zahbdw, zx(NAHBMST-1 downto 0), zxirq(NAHBIRQ-1 downto 0), (others => zx), 0); constant ahbs_in_none : ahb_slv_in_type := ( zy(0 to NAHBSLV-1), zx, '0', "00", "000", "000", zahbdw, "0000", '1', "0000", '0', zy(0 to NAHBAMR-1), zxirq(NAHBIRQ-1 downto 0), '0', '0', '0', '0', ztestin); constant ahbsv_none : ahb_slv_out_vector := (others => ahbs_none); constant apb_slv_in_none : apb_slv_in_type := ((others => '0'), '0', (others => '0'), '0', (others => '0'), (others => '0'), '0', '0', '0', '0', ztestin); ------------------------------------------------------------------------------- -- Subprograms ------------------------------------------------------------------------------- function ahb_device_reg(vendor : amba_vendor_type; device : amba_device_type; cfgver : amba_cfgver_type; version : amba_version_type; interrupt : amba_irq_type) return std_logic_vector; function ahb_membar(memaddr : ahb_addr_type; prefetch, cache : std_ulogic; addrmask : ahb_addr_type) return std_logic_vector; function ahb_membar_opt(memaddr : ahb_addr_type; prefetch, cache : std_ulogic; addrmask : ahb_addr_type; enable : integer) return std_logic_vector; function ahb_iobar(memaddr : ahb_addr_type; addrmask : ahb_addr_type) return std_logic_vector; function apb_iobar(memaddr : ahb_addr_type; addrmask : ahb_addr_type) return std_logic_vector; function ahb_slv_dec_cache(haddr : std_logic_vector(31 downto 0); ahbso : ahb_slv_out_vector; cached : integer) return std_ulogic; function ahb_slv_dec_pfetch(haddr : std_logic_vector(31 downto 0); ahbso : ahb_slv_out_vector) return std_ulogic; function ahb_membar_size (addrmask : ahb_addr_type) return integer; function ahb_iobar_size (addrmask : ahb_addr_type) return integer; function ahbdrivedata (hdata : std_logic_vector) return std_logic_vector; function ahbselectdata (hdata : std_logic_vector(AHBDW-1 downto 0); haddr : std_logic_vector(4 downto 2); hsize : std_logic_vector(2 downto 0)) return std_logic_vector; function ahbreadword ( hdata : std_logic_vector(AHBDW-1 downto 0); haddr : std_logic_vector(4 downto 2)) return std_logic_vector; procedure ahbreadword ( hdata : in std_logic_vector(AHBDW-1 downto 0); haddr : in std_logic_vector(4 downto 2); data : out std_logic_vector(31 downto 0)); function ahbreadword ( hdata : std_logic_vector(AHBDW-1 downto 0)) return std_logic_vector; procedure ahbreadword ( hdata : in std_logic_vector(AHBDW-1 downto 0); data : out std_logic_vector(31 downto 0)); function ahbreaddword ( hdata : std_logic_vector(AHBDW-1 downto 0); haddr : std_logic_vector(4 downto 2)) return std_logic_vector; procedure ahbreaddword ( hdata : in std_logic_vector(AHBDW-1 downto 0); haddr : in std_logic_vector(4 downto 2); data : out std_logic_vector(63 downto 0)); function ahbreaddword ( hdata : std_logic_vector(AHBDW-1 downto 0)) return std_logic_vector; procedure ahbreaddword ( hdata : in std_logic_vector(AHBDW-1 downto 0); data : out std_logic_vector(63 downto 0)); function ahbread4word ( hdata : std_logic_vector(AHBDW-1 downto 0); haddr : std_logic_vector(4 downto 2)) return std_logic_vector; procedure ahbread4word ( hdata : in std_logic_vector(AHBDW-1 downto 0); haddr : in std_logic_vector(4 downto 2); data : out std_logic_vector(127 downto 0)); function ahbread4word ( hdata : std_logic_vector(AHBDW-1 downto 0)) return std_logic_vector; procedure ahbread4word ( hdata : in std_logic_vector(AHBDW-1 downto 0); data : out std_logic_vector(127 downto 0)); function ahbread8word ( hdata : std_logic_vector(AHBDW-1 downto 0); haddr : std_logic_vector(4 downto 2)) return std_logic_vector; procedure ahbread8word ( hdata : in std_logic_vector(AHBDW-1 downto 0); haddr : in std_logic_vector(4 downto 2); data : out std_logic_vector(255 downto 0)); function ahbread8word ( hdata : std_logic_vector(AHBDW-1 downto 0)) return std_logic_vector; procedure ahbread8word ( hdata : in std_logic_vector(AHBDW-1 downto 0); data : out std_logic_vector(255 downto 0)); function ahbreaddata ( hdata : std_logic_vector(AHBDW-1 downto 0); haddr : std_logic_vector(4 downto 2); hsize : std_logic_vector(2 downto 0)) return std_logic_vector; function ahbreaddata ( hdata : std_logic_vector(AHBDW-1 downto 0); hsize : std_logic_vector(2 downto 0)) return std_logic_vector; procedure ahbmomux ( signal ai : in ahb_mst_out_type; signal ao : out ahb_mst_out_type; signal en : in std_ulogic); procedure ahbsomux ( signal ai : in ahb_slv_out_type; signal ao : out ahb_slv_out_type; signal en : in std_ulogic); procedure apbsomux ( signal ai : in apb_slv_out_type; signal ao : out apb_slv_out_type; signal en : in std_ulogic); ------------------------------------------------------------------------------- -- Components ------------------------------------------------------------------------------- component ahbctrl generic ( defmast : integer := 0; -- default master split : integer := 0; -- split support rrobin : integer := 0; -- round-robin arbitration timeout : integer range 0 to 255 := 0; -- HREADY timeout ioaddr : ahb_addr_type := 16#fff#; -- I/O area MSB address iomask : ahb_addr_type := 16#fff#; -- I/O area address mask cfgaddr : ahb_addr_type := 16#ff0#; -- config area MSB address cfgmask : ahb_addr_type := 16#ff0#; -- config area address mask nahbm : integer range 1 to NAHBMST := NAHBMST; -- number of masters nahbs : integer range 1 to NAHBSLV := NAHBSLV; -- number of slaves ioen : integer range 0 to 15 := 1; -- enable I/O area disirq : integer range 0 to 1 := 0; -- disable interrupt routing fixbrst : integer range 0 to 1 := 0; -- support fix-length bursts debug : integer range 0 to 2 := 2; -- print config to console fpnpen : integer range 0 to 1 := 0; -- full PnP configuration decoding icheck : integer range 0 to 1 := 1; devid : integer := 0; -- unique device ID enbusmon : integer range 0 to 1 := 0; --enable bus monitor assertwarn : integer range 0 to 1 := 0; --enable assertions for warnings asserterr : integer range 0 to 1 := 0; --enable assertions for errors hmstdisable : integer := 0; --disable master checks hslvdisable : integer := 0; --disable slave checks arbdisable : integer := 0; --disable arbiter checks mprio : integer := 0; --master with highest priority mcheck : integer range 0 to 2 := 1; --check memory map for intersects ccheck : integer range 0 to 1 := 1; --perform sanity checks on pnp config acdm : integer := 0; --AMBA compliant data muxing (for hsize > word) index : integer := 0; --index for trace print-out ahbtrace : integer := 0; --AHB trace enable hwdebug : integer := 0; fourgslv : integer := 0 ); port ( rst : in std_ulogic; clk : in std_ulogic; msti : out ahb_mst_in_type; msto : in ahb_mst_out_vector; slvi : out ahb_slv_in_type; slvo : in ahb_slv_out_vector; testen : in std_ulogic := '0'; testrst : in std_ulogic := '1'; scanen : in std_ulogic := '0'; testoen : in std_ulogic := '1'; testsig : in std_logic_vector(1+GRLIB_CONFIG_ARRAY(grlib_techmap_testin_extra) downto 0) := (others => '0') ); end component; component apbctrl generic ( hindex : integer := 0; haddr : integer := 0; hmask : integer := 16#fff#; nslaves : integer range 1 to NAPBSLV := NAPBSLV; debug : integer range 0 to 2 := 2; -- print config to console icheck : integer range 0 to 1 := 1; enbusmon : integer range 0 to 1 := 0; asserterr : integer range 0 to 1 := 0; assertwarn : integer range 0 to 1 := 0; pslvdisable : integer := 0; mcheck : integer range 0 to 1 := 1; ccheck : integer range 0 to 1 := 1 ); port ( rst : in std_ulogic; clk : in std_ulogic; ahbi : in ahb_slv_in_type; ahbo : out ahb_slv_out_type; apbi : out apb_slv_in_type; apbo : in apb_slv_out_vector ); end component; component ahbctrl_mb generic ( defmast : integer := 0; -- default master split : integer := 0; -- split support rrobin : integer := 0; -- round-robin arbitration timeout : integer range 0 to 255 := 0; -- HREADY timeout ioaddr : ahb_addr_type := 16#fff#; -- I/O area MSB address iomask : ahb_addr_type := 16#fff#; -- I/O area address mask cfgaddr : ahb_addr_type := 16#ff0#; -- config area MSB address cfgmask : ahb_addr_type := 16#ff0#; -- config area address mask nahbm : integer range 1 to NAHBMST := NAHBMST; -- number of masters nahbs : integer range 1 to NAHBSLV := NAHBSLV; -- number of slaves ioen : integer range 0 to 15 := 1; -- enable I/O area disirq : integer range 0 to 1 := 0; -- disable interrupt routing fixbrst : integer range 0 to 1 := 0; -- support fix-length bursts debug : integer range 0 to 2 := 2; -- report cores to console fpnpen : integer range 0 to 1 := 0; -- full PnP configuration decoding busndx : integer range 0 to 3 := 0; icheck : integer range 0 to 1 := 1; devid : integer := 0; -- unique device ID enbusmon : integer range 0 to 1 := 0; --enable bus monitor assertwarn : integer range 0 to 1 := 0; --enable assertions for warnings asserterr : integer range 0 to 1 := 0; --enable assertions for errors hmstdisable : integer := 0; --disable master checks hslvdisable : integer := 0; --disable slave checks arbdisable : integer := 0; --disable arbiter checks mprio : integer := 0; --master with highest priority mcheck : integer range 0 to 2 := 1; --check memory map for intersect ccheck : integer range 0 to 1 := 1; --perform sanity checks on pnp config acdm : integer := 0 --AMBA compliant data muxing (for hsize > word) ); port ( rst : in std_ulogic; clk : in std_ulogic; msti : out ahb_mst_in_type; msto : in ahb_mst_out_bus_vector; slvi : out ahb_slv_in_type; slvo : in ahb_slv_out_bus_vector; testen : in std_ulogic := '0'; testrst : in std_ulogic := '1'; scanen : in std_ulogic := '0'; testoen : in std_ulogic := '1' ); end component; component ahbdefmst generic ( hindex : integer range 0 to NAHBMST-1 := 0); port ( ahbmo : out ahb_mst_out_type); end component; type ahb_dma_in_type is record address : std_logic_vector(31 downto 0); wdata : std_logic_vector(AHBDW-1 downto 0); start : std_ulogic; burst : std_ulogic; write : std_ulogic; busy : std_ulogic; irq : std_ulogic; size : std_logic_vector(2 downto 0); end record; type ahb_dma_out_type is record start : std_ulogic; active : std_ulogic; ready : std_ulogic; retry : std_ulogic; mexc : std_ulogic; haddr : std_logic_vector(9 downto 0); rdata : std_logic_vector(AHBDW-1 downto 0); end record; component ahbmst generic ( hindex : integer := 0; hirq : integer := 0; venid : integer := 1; devid : integer := 0; version : integer := 0; chprot : integer := 3; incaddr : integer := 0); port ( rst : in std_ulogic; clk : in std_ulogic; dmai : in ahb_dma_in_type; dmao : out ahb_dma_out_type; ahbi : in ahb_mst_in_type; ahbo : out ahb_mst_out_type ); end component; -- pragma translate_off component ahbmon is generic( asserterr : integer range 0 to 1 := 1; assertwarn : integer range 0 to 1 := 1; hmstdisable : integer := 0; hslvdisable : integer := 0; arbdisable : integer := 0; nahbm : integer range 0 to NAHBMST := NAHBMST; nahbs : integer range 0 to NAHBSLV := NAHBSLV; ebterm : integer range 0 to 1 := 0 ); port( rst : in std_ulogic; clk : in std_ulogic; ahbmi : in ahb_mst_in_type; ahbmo : in ahb_mst_out_vector; ahbsi : in ahb_slv_in_type; ahbso : in ahb_slv_out_vector; err : out std_ulogic); end component; component apbmon is generic( asserterr : integer range 0 to 1 := 1; assertwarn : integer range 0 to 1 := 1; pslvdisable : integer := 0; napb : integer range 0 to NAPBSLV := NAPBSLV ); port( rst : in std_ulogic; clk : in std_ulogic; apbi : in apb_slv_in_type; apbo : in apb_slv_out_vector; err : out std_ulogic); end component; component ambamon is generic( asserterr : integer range 0 to 1 := 1; assertwarn : integer range 0 to 1 := 1; hmstdisable : integer := 0; hslvdisable : integer := 0; pslvdisable : integer := 0; arbdisable : integer := 0; nahbm : integer range 0 to NAHBMST := NAHBMST; nahbs : integer range 0 to NAHBSLV := NAHBSLV; napb : integer range 0 to NAPBSLV := NAPBSLV; ebterm : integer range 0 to 1 := 0 ); port( rst : in std_ulogic; clk : in std_ulogic; ahbmi : in ahb_mst_in_type; ahbmo : in ahb_mst_out_vector; ahbsi : in ahb_slv_in_type; ahbso : in ahb_slv_out_vector; apbi : in apb_slv_in_type; apbo : in apb_slv_out_vector; err : out std_ulogic); end component; subtype vendor_description is string(1 to 24); subtype device_description is string(1 to 31); type device_table_type is array (0 to 1023) of device_description; type vendor_library_type is record vendorid : amba_vendor_type; vendordesc : vendor_description; device_table : device_table_type; end record; type device_array is array (0 to 255) of vendor_library_type; -- pragma translate_on end; package body amba is function ahb_device_reg(vendor : amba_vendor_type; device : amba_device_type; cfgver : amba_cfgver_type; version : amba_version_type; interrupt : amba_irq_type) return std_logic_vector is variable cfg : std_logic_vector(31 downto 0); begin case cfgver is when 0 => cfg(31 downto 24) := std_logic_vector(to_unsigned(vendor, 8)); cfg(23 downto 12) := std_logic_vector(to_unsigned(device, 12)); cfg(11 downto 10) := std_logic_vector(to_unsigned(cfgver, 2)); cfg( 9 downto 5) := std_logic_vector(to_unsigned(version, 5)); cfg( 4 downto 0) := std_logic_vector(to_unsigned(interrupt, 5)); when others => cfg := (others => '0'); end case; return(cfg); end; function ahb_membar(memaddr : ahb_addr_type; prefetch, cache : std_ulogic; addrmask : ahb_addr_type) return std_logic_vector is variable cfg : std_logic_vector(31 downto 0); begin cfg(31 downto 20) := std_logic_vector(to_unsigned(memaddr, 12)); cfg(19 downto 16) := "00" & prefetch & cache; cfg(15 downto 4) := std_logic_vector(to_unsigned(addrmask, 12)); cfg( 3 downto 0) := "0010"; return(cfg); end; function ahb_membar_opt(memaddr : ahb_addr_type; prefetch, cache : std_ulogic; addrmask : ahb_addr_type; enable : integer) return std_logic_vector is variable cfg : std_logic_vector(31 downto 0); begin cfg := (others => '0'); if enable /= 0 then return (ahb_membar(memaddr, prefetch, cache, addrmask)); else return(cfg); end if; end; function ahb_iobar(memaddr : ahb_addr_type; addrmask : ahb_addr_type) return std_logic_vector is variable cfg : std_logic_vector(31 downto 0); begin cfg(31 downto 20) := std_logic_vector(to_unsigned(memaddr, 12)); cfg(19 downto 16) := "0000"; cfg(15 downto 4) := std_logic_vector(to_unsigned(addrmask, 12)); cfg( 3 downto 0) := "0011"; return(cfg); end; function apb_iobar(memaddr : ahb_addr_type; addrmask : ahb_addr_type) return std_logic_vector is variable cfg : std_logic_vector(31 downto 0); begin cfg(31 downto 20) := std_logic_vector(to_unsigned(memaddr, 12)); cfg(19 downto 16) := "0000"; cfg(15 downto 4) := std_logic_vector(to_unsigned(addrmask, 12)); cfg( 3 downto 0) := "0001"; return(cfg); end; function ahb_slv_dec_cache(haddr : std_logic_vector(31 downto 0); ahbso : ahb_slv_out_vector; cached : integer) return std_ulogic is variable hcache : std_ulogic; variable ctbl : std_logic_vector(15 downto 0); begin hcache := '0'; ctbl := (others => '0'); if cached = 0 then for i in 0 to NAHBSLV-1 loop for j in NAHBAMR to NAHBCFG-1 loop if (ahbso(i).hconfig(j)(16) = '1') and (ahbso(i).hconfig(j)(15 downto 4) /= "000000000000") then if (haddr(31 downto 20) and ahbso(i).hconfig(j)(15 downto 4)) = (ahbso(i).hconfig(j)(31 downto 20) and ahbso(i).hconfig(j)(15 downto 4)) then hcache := '1'; end if; end if; end loop; end loop; else ctbl := conv_std_logic_vector(cached, 16); hcache := ctbl(conv_integer(haddr(31 downto 28))); end if; return(hcache); end; function ahb_slv_dec_pfetch(haddr : std_logic_vector(31 downto 0); ahbso : ahb_slv_out_vector) return std_ulogic is variable pfetch : std_ulogic; begin pfetch := '0'; for i in 0 to NAHBSLV-1 loop for j in NAHBAMR to NAHBCFG-1 loop if ((ahbso(i).hconfig(j)(17) = '1') and (ahbso(i).hconfig(j)(15 downto 4) /= "000000000000")) then if (haddr(31 downto 20) and ahbso(i).hconfig(j)(15 downto 4)) = (ahbso(i).hconfig(j)(31 downto 20) and ahbso(i).hconfig(j)(15 downto 4)) then pfetch := '1'; end if; end if; end loop; end loop; return(pfetch); end; function ahb_membar_size (addrmask : ahb_addr_type) return integer is begin if addrmask = 0 then return 0; end if; return (4096 - addrmask) * 1024 * 1024; end; function ahb_iobar_size (addrmask : ahb_addr_type) return integer is begin return (4096 - addrmask) * 256; end; -- purpose: Duplicates 'hdata' to suite AHB data width. If the input vector's -- length exceeds AHBDW the low part is returned. function ahbdrivedata ( hdata : std_logic_vector) return std_logic_vector is variable data : std_logic_vector(AHBDW-1 downto 0); begin -- ahbdrivedata if AHBDW < hdata'length then data := hdata(AHBDW+hdata'low-1 downto hdata'low); else for i in 0 to AHBDW/hdata'length-1 loop data(hdata'length-1+hdata'lengthi downto hdata'lengthi) := hdata; end loop; end if; return data; end ahbdrivedata; -- Takes in AHB data vector 'hdata' and returns valid data on the full -- data vector output based on 'haddr' and 'hsize' inputs together with -- GRLIB AHB bus width. The function works down to word granularity. function ahbselectdata ( hdata : std_logic_vector(AHBDW-1 downto 0); haddr : std_logic_vector(4 downto 2); hsize : std_logic_vector(2 downto 0)) return std_logic_vector is variable ret : std_logic_vector(AHBDW-1 downto 0); begin -- ahbselectdata ret := hdata; case hsize is when HSIZE_8WORD => if AHBDW = 256 then ret := hdata; end if; when HSIZE_4WORD => if AHBDW = 256 then if haddr(4) = '0' then ret := ahbdrivedata(hdata(AHBDW-1 downto AHBDW/2)); else ret := ahbdrivedata(hdata(AHBDW/2-1 downto 0)); end if; end if; when HSIZE_DWORD => if AHBDW = 256 then case haddr(4 downto 3) is when "00" => ret := ahbdrivedata(hdata(4(AHBDW/4)-1 downto 3(AHBDW/4))); when "01" => ret := ahbdrivedata(hdata(3(AHBDW/4)-1 downto 2(AHBDW/4))); when "10" => ret := ahbdrivedata(hdata(2(AHBDW/4)-1 downto 1(AHBDW/4))); when others => ret := ahbdrivedata(hdata(1(AHBDW/4)-1 downto 0(AHBDW/4))); end case; elsif AHBDW = 128 then if haddr(3) = '0' then ret := ahbdrivedata(hdata(AHBDW-1 downto AHBDW/2)); else ret := ahbdrivedata(hdata(AHBDW/2-1 downto 0)); end if; end if; when others => if AHBDW = 256 then case haddr(4 downto 2) is when "000" => ret := ahbdrivedata(hdata(8(AHBDW/8)-1 downto 7(AHBDW/8))); when "001" => ret := ahbdrivedata(hdata(7(AHBDW/8)-1 downto 6(AHBDW/8))); when "010" => ret := ahbdrivedata(hdata(6(AHBDW/8)-1 downto 5(AHBDW/8))); when "011" => ret := ahbdrivedata(hdata(5(AHBDW/8)-1 downto 4(AHBDW/8))); when "100" => ret := ahbdrivedata(hdata(4(AHBDW/8)-1 downto 3(AHBDW/8))); when "101" => ret := ahbdrivedata(hdata(3(AHBDW/8)-1 downto 2(AHBDW/8))); when "110" => ret := ahbdrivedata(hdata(2(AHBDW/8)-1 downto 1(AHBDW/8))); when others => ret := ahbdrivedata(hdata(1(AHBDW/8)-1 downto 0(AHBDW/8))); end case; elsif AHBDW = 128 then case haddr(3 downto 2) is when "00" => ret := ahbdrivedata(hdata(4(AHBDW/4)-1 downto 3(AHBDW/4))); when "01" => ret := ahbdrivedata(hdata(3(AHBDW/4)-1 downto 2(AHBDW/4))); when "10" => ret := ahbdrivedata(hdata(2(AHBDW/4)-1 downto 1(AHBDW/4))); when others => ret := ahbdrivedata(hdata(1(AHBDW/4)-1 downto 0(AHBDW/4))); end case; elsif AHBDW = 64 then if haddr(2) = '0' then ret := ahbdrivedata(hdata(AHBDW-1 downto AHBDW/2)); else ret := ahbdrivedata(hdata(AHBDW/2-1 downto 0)); end if; end if; end case; return ret; end ahbselectdata; -- Description of ahbread* functions and procedures. -- -- The ahbread* subprograms with an 'haddr' input selects the valid slice of -- data from the AHB data vector, 'hdata', based on the 'haddr' input if -- CORE_ACDM is set to 1 (see top of this package). Otherwise the low part of -- the AHB data vector will be returned. -- -- The ahbread* subprograms that do not have a 'haddr' input will always -- return the low slice of the 'hdata' input. These subprograms will assert a -- failure if CORE_ACDM is set to 1. -- function ahbreadword ( hdata : std_logic_vector(AHBDW-1 downto 0); haddr : std_logic_vector(4 downto 2)) return std_logic_vector is variable data : std_logic_vector(31 downto 0); begin if CORE_ACDM = 1 then data := ahbselectdata(hdata, haddr, HSIZE_WORD)(31 downto 0); else data := hdata(31 downto 0); end if; return data; end ahbreadword; procedure ahbreadword ( hdata : in std_logic_vector(AHBDW-1 downto 0); haddr : in std_logic_vector(4 downto 2); data : out std_logic_vector(31 downto 0)) is begin data := ahbreadword(hdata, haddr); end ahbreadword; function ahbreadword ( hdata : std_logic_vector(AHBDW-1 downto 0)) return std_logic_vector is variable data : std_logic_vector(31 downto 0); begin -- pragma translate_off assert CORE_ACDM = 0 report "ahbreadword without address input used when CORE_ACDM /= 0" severity failure; -- pragma translate_on data := hdata(31 downto 0); return data; end ahbreadword; procedure ahbreadword ( hdata : in std_logic_vector(AHBDW-1 downto 0); data : out std_logic_vector(31 downto 0)) is begin data := ahbreadword(hdata); end ahbreadword; function ahbreaddword ( hdata : std_logic_vector(AHBDW-1 downto 0); haddr : std_logic_vector(4 downto 2)) return std_logic_vector is variable data : std_logic_vector(255 downto 0); begin -- pragma translate_off assert AHBDW > 32 report "ahbreaddword can not be used in system with AHB data width < 64" severity failure; -- pragma translate_on if AHBDW = 256 then if CORE_ACDM = 1 then data(AHBDW/4-1 downto 0) := ahbselectdata(hdata, haddr, HSIZE_DWORD)(AHBDW/4-1 downto 0); else data(AHBDW/4-1 downto 0) := hdata(AHBDW/4-1 downto 0); end if; elsif AHBDW = 128 then if CORE_ACDM = 1 then data(AHBDW/2-1 downto 0) := ahbselectdata(hdata, haddr, HSIZE_DWORD)(AHBDW/2-1 downto 0); else data(AHBDW/2-1 downto 0) := hdata(AHBDW/2-1 downto 0); end if; elsif AHBDW = 64 then if CORE_ACDM = 1 then data(AHBDW-1 downto 0) := ahbselectdata(hdata, haddr, HSIZE_DWORD)(AHBDW-1 downto 0); else data(AHBDW-1 downto 0) := hdata(AHBDW-1 downto 0); end if; end if; return data(63 downto 0); end ahbreaddword; procedure ahbreaddword ( hdata : in std_logic_vector(AHBDW-1 downto 0); haddr : in std_logic_vector(4 downto 2); data : out std_logic_vector(63 downto 0)) is begin data := ahbreaddword(hdata, haddr); end ahbreaddword; function ahbreaddword ( hdata : std_logic_vector(AHBDW-1 downto 0)) return std_logic_vector is variable data : std_logic_vector(255 downto 0); begin -- pragma translate_off assert AHBDW > 32 report "ahbreaddword can not be used in system with AHB data width < 64" severity failure; assert CORE_ACDM = 0 report "ahbreaddword without address input used when CORE_ACDM /= 0" severity failure; -- pragma translate_on if AHBDW = 256 then data(AHBDW/4-1 downto 0) := hdata(AHBDW/4-1 downto 0); elsif AHBDW = 128 then data(AHBDW/2-1 downto 0) := hdata(AHBDW/2-1 downto 0); elsif AHBDW = 64 then data(AHBDW-1 downto 0) := hdata(AHBDW-1 downto 0); end if; return data(63 downto 0); end ahbreaddword; procedure ahbreaddword ( hdata : in std_logic_vector(AHBDW-1 downto 0); data : out std_logic_vector(63 downto 0)) is begin data := ahbreaddword(hdata); end ahbreaddword; function ahbread4word ( hdata : std_logic_vector(AHBDW-1 downto 0); haddr : std_logic_vector(4 downto 2)) return std_logic_vector is variable data : std_logic_vector(255 downto 0); begin -- pragma translate_off assert AHBDW > 64 report "ahbread4word can not be used in system with AHB data width < 128 bits" severity failure; -- pragma translate_on if AHBDW = 256 then if CORE_ACDM = 1 then data(AHBDW/2-1 downto 0) := ahbselectdata(hdata, haddr, HSIZE_4WORD)(AHBDW/2-1 downto 0); else data(AHBDW/2-1 downto 0) := hdata(AHBDW/2-1 downto 0); end if; elsif AHBDW = 128 then if CORE_ACDM = 1 then data(AHBDW-1 downto 0) := ahbselectdata(hdata, haddr, HSIZE_4WORD)(AHBDW-1 downto 0); else data(AHBDW-1 downto 0) := hdata(AHBDW-1 downto 0); end if; end if; return data(127 downto 0); end ahbread4word; procedure ahbread4word ( hdata : in std_logic_vector(AHBDW-1 downto 0); haddr : in std_logic_vector(4 downto 2); data : out std_logic_vector(127 downto 0)) is begin data := ahbread4word(hdata, haddr); end ahbread4word; function ahbread4word ( hdata : std_logic_vector(AHBDW-1 downto 0)) return std_logic_vector is variable data : std_logic_vector(255 downto 0); begin -- pragma translate_off assert AHBDW > 64 report "ahbread4word can not be used in system with AHB data width < 128 bits" severity failure; assert CORE_ACDM = 0 report "ahbread4word without address input used when CORE_ACDM /= 0" severity failure; -- pragma translate_on if AHBDW = 256 then data(AHBDW/2-1 downto 0) := hdata(AHBDW/2-1 downto 0); elsif AHBDW = 128 then data(AHBDW-1 downto 0) := hdata(AHBDW-1 downto 0); end if; return data(127 downto 0); end ahbread4word; procedure ahbread4word ( hdata : in std_logic_vector(AHBDW-1 downto 0); data : out std_logic_vector(127 downto 0)) is begin data := ahbread4word(hdata); end ahbread4word; function ahbread8word ( hdata : std_logic_vector(AHBDW-1 downto 0); haddr : std_logic_vector(4 downto 2)) return std_logic_vector is variable data : std_logic_vector(AHBDW-1 downto 0); begin -- pragma translate_off assert AHBDW > 128 report "ahbread8word can not be used in system with AHB data width < 256 bits" severity failure; -- pragma translate_on if CORE_ACDM = 1 then data(AHBDW-1 downto 0) := ahbselectdata(hdata, haddr, HSIZE_8WORD)(AHBDW-1 downto 0); else data(AHBDW-1 downto 0) := hdata(AHBDW-1 downto 0); end if; return data; end ahbread8word; procedure ahbread8word ( hdata : in std_logic_vector(AHBDW-1 downto 0); haddr : in std_logic_vector(4 downto 2); data : out std_logic_vector(255 downto 0)) is begin data := ahbread8word(hdata, haddr); end ahbread8word; function ahbread8word ( hdata : std_logic_vector(AHBDW-1 downto 0)) return std_logic_vector is variable data : std_logic_vector(AHBDW-1 downto 0); begin -- pragma translate_off assert AHBDW > 128 report "ahbread8word can not be used in system with AHB data width < 256 bits" severity failure; assert CORE_ACDM = 0 report "ahbread8word without address input used when CORE_ACDM /= 0" severity failure; -- pragma translate_on data(AHBDW-1 downto 0) := hdata(AHBDW-1 downto 0); return data; end ahbread8word; procedure ahbread8word ( hdata : in std_logic_vector(AHBDW-1 downto 0); data : out std_logic_vector(255 downto 0)) is begin data := ahbread8word(hdata); end ahbread8word; function ahbreaddata ( hdata : std_logic_vector(AHBDW-1 downto 0); haddr : std_logic_vector(4 downto 2); hsize : std_logic_vector(2 downto 0)) return std_logic_vector is begin case hsize is when HSIZE_8WORD => return ahbread8word(hdata, haddr); when HSIZE_4WORD => return ahbread4word(hdata, haddr); when HSIZE_DWORD => return ahbreaddword(hdata, haddr); when others => null; end case; return ahbreadword(hdata, haddr); end ahbreaddata; function ahbreaddata ( hdata : std_logic_vector(AHBDW-1 downto 0); hsize : std_logic_vector(2 downto 0)) return std_logic_vector is begin case hsize is when HSIZE_8WORD => return ahbread8word(hdata); when HSIZE_4WORD => return ahbread4word(hdata); when HSIZE_DWORD => return ahbreaddword(hdata); when others => null; end case; return ahbreadword(hdata); end ahbreaddata; -- a*mux below drives their amba output records with the amba input record if -- the en input is '1'. Otherwise the amba output record is driven to an idle -- state. Plug'n'play information is kept constant. procedure ahbmomux ( signal ai : in ahb_mst_out_type; signal ao : out ahb_mst_out_type; signal en : in std_ulogic) is begin if en = '1' then ao <= ai; else ao <= ahbm_none; end if; ao.haddr <= ai.haddr; ao.hwrite <= ai.hwrite; ao.hsize <= ai.hsize; ao.hprot <= ai.hprot; ao.hwdata <= ai.hwdata; ao.hconfig <= ai.hconfig; ao.hindex <= ai.hindex; end ahbmomux; procedure ahbsomux ( signal ai : in ahb_slv_out_type; signal ao : out ahb_slv_out_type; signal en : in std_ulogic) is begin if en = '1' then ao <= ai; else ao <= ahbs_none; end if; ao.hrdata <= ai.hrdata; ao.hconfig <= ai.hconfig; ao.hindex <= ai.hindex; end ahbsomux; procedure apbsomux ( signal ai : in apb_slv_out_type; signal ao : out apb_slv_out_type; signal en : in std_ulogic) is begin if en = '1' then ao <= ai; else ao <= apb_none; end if; ao.prdata <= ai.prdata; ao.pconfig <= ai.pconfig; ao.pindex <= ai.pindex; end apbsomux; end;	gpl-2.0	9d5c050131f8e8a5152e5affb134c3e3	0.609422	3.623596	false	false	false	false
marco-c/leon-nexys2	grlib-gpl-1.3.4-b4140/lib/gaisler/can/can_oc.vhd	1	5,690	------------------------------------------------------------------------------ -- This file is a part of the GRLIB VHDL IP LIBRARY -- Copyright (C) 2003 - 2008, Gaisler Research -- Copyright (C) 2008 - 2013, Aeroflex Gaisler -- -- This program is free software; you can redistribute it and/or modify -- it under the terms of the GNU General Public License as published by -- the Free Software Foundation; either version 2 of the License, or -- (at your option) any later version. -- -- This program is distributed in the hope that it will be useful, -- but WITHOUT ANY WARRANTY; without even the implied warranty of -- MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the -- GNU General Public License for more details. -- -- You should have received a copy of the GNU General Public License -- along with this program; if not, write to the Free Software -- Foundation, Inc., 59 Temple Place, Suite 330, Boston, MA 02111-1307 USA ----------------------------------------------------------------------------- -- Entity: can_oc -- File: can_oc.vhd -- Author: Jiri Gaisler - Gaisler Research -- Description: AHB interface for the OpenCores CAN MAC ------------------------------------------------------------------------------ library ieee; use ieee.std_logic_1164.all; library grlib; use grlib.amba.all; use grlib.stdlib.all; use grlib.devices.all; library techmap; use techmap.gencomp.all; library gaisler; use gaisler.can.all; entity can_oc is generic ( slvndx : integer := 0; ioaddr : integer := 16#000#; iomask : integer := 16#FF0#; irq : integer := 0; memtech : integer := DEFMEMTECH; syncrst : integer := 0; ft : integer := 0); port ( resetn : in std_logic; clk : in std_logic; ahbsi : in ahb_slv_in_type; ahbso : out ahb_slv_out_type; can_rxi : in std_logic; can_txo : out std_logic ); end; architecture rtl of can_oc is constant ncores : integer := 1; constant sepirq : integer := 0; constant REVISION : amba_version_type := ncores-1; constant hconfig : ahb_config_type := ( 0 => ahb_device_reg ( VENDOR_GAISLER, GAISLER_CANAHB, 0, REVISION, irq), 4 => ahb_iobar(ioaddr, iomask), others => zero32); type ahbregs is record hsel : std_ulogic; hwrite : std_ulogic; hwrite2 : std_ulogic; htrans : std_logic_vector(1 downto 0); haddr : std_logic_vector(10 downto 0); hwdata : std_logic_vector(7 downto 0); herr : std_ulogic; hready : std_ulogic; ws : std_logic_vector(1 downto 0); irqi : std_logic_vector(ncores-1 downto 0); irqo : std_logic_vector(ncores-1 downto 0); end record; subtype cdata is std_logic_vector(7 downto 0); type cdataarr is array (0 to 7) of cdata; signal data_out : cdataarr; signal reset : std_logic; signal irqo : std_logic_vector(ncores-1 downto 0); signal vcc, gnd : std_ulogic; signal r, rin : ahbregs; attribute sync_set_reset : string; attribute sync_set_reset of reset : signal is "true"; begin gnd <= '0'; vcc <= '1'; reset <= not resetn; comb : process(ahbsi, r, resetn, data_out, irqo) variable v : ahbregs; variable hresp : std_logic_vector(1 downto 0); variable dataout : std_logic_vector(7 downto 0); variable irqvec : std_logic_vector(NAHBIRQ-1 downto 0); variable hwdata : std_logic_vector(31 downto 0); begin v := r; hwdata := ahbreadword(ahbsi.hwdata, r.haddr(4 downto 2)); if (r.hsel = '1' ) and (r.ws /= "11") then v.ws := r.ws + 1; end if; if ahbsi.hready = '1' then v.hsel := ahbsi.hsel(slvndx); v.haddr := ahbsi.haddr(10 downto 0); v.htrans := ahbsi.htrans; v.hwrite := ahbsi.hwrite; v.herr := orv(ahbsi.hsize) and ahbsi.hwrite; v.ws := "00"; end if; v.hready := (r.hsel and r.ws(1) and not r.ws(0)) or not resetn or (ahbsi.hready and not ahbsi.htrans(1)) or not v.hsel; v.hwrite2 := r.hwrite and r.hsel and r.htrans(1) and r.ws(1) and not r.ws(0) and not r.herr; if (r.herr and r.ws(1)) = '1' then hresp := HRESP_ERROR; else hresp := HRESP_OKAY; end if; case r.haddr(1 downto 0) is when "00" => v.hwdata := hwdata(31 downto 24); when "01" => v.hwdata := hwdata(23 downto 16); when "10" => v.hwdata := hwdata(15 downto 8); when others => v.hwdata := hwdata(7 downto 0); end case; dataout := data_out(0); -- Interrupt goes to low when appeard and is normal high -- but the irq controller from leon is active high and the interrupt should appear only -- for 1 Clk cycle, v.irqi := irqo; v.irqo:= (r.irqi and not irqo); irqvec := (others => '0'); if sepirq = 1 then irqvec(ncores-1+irq downto irq) := r.irqo; else irqvec(irq) := orv(r.irqo); end if; ahbso.hirq <= irqvec; ahbso.hrdata <= ahbdrivedata(dataout); ahbso.hresp <= hresp; rin <= v; end process; reg : process(clk) begin if clk'event and clk = '1' then r <= rin; end if; end process; cmod : can_mod generic map (memtech, syncrst, ft) port map (reset, clk, r.hsel, r.hwrite2, r.haddr(7 downto 0), r.hwdata, data_out(0), irqo(0), can_rxi, can_txo, ahbsi.testen); ahbso.hconfig <= hconfig; ahbso.hindex <= slvndx; ahbso.hsplit <= (others => '0'); ahbso.hready <= r.hready; -- pragma translate_off bootmsg : report_version generic map ( "can_oc" & tost(slvndx) & ": SJA1000 Compatible CAN MAC, revision " & tost(REVISION) & ", irq " & tost(irq)); -- pragma translate_on end;	gpl-2.0	22ce04b3418fb65c9d819c4e90870528	0.595079	3.540759	false	false	false	false
marco-c/leon-nexys2	grlib-gpl-1.3.4-b4140/lib/techmap/maps/clkmux.vhd	1	3,820	------------------------------------------------------------------------------ -- This file is a part of the GRLIB VHDL IP LIBRARY -- Copyright (C) 2003 - 2008, Gaisler Research -- Copyright (C) 2008 - 2013, Aeroflex Gaisler -- -- This program is free software; you can redistribute it and/or modify -- it under the terms of the GNU General Public License as published by -- the Free Software Foundation; either version 2 of the License, or -- (at your option) any later version. -- -- This program is distributed in the hope that it will be useful, -- but WITHOUT ANY WARRANTY; without even the implied warranty of -- MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the -- GNU General Public License for more details. -- -- You should have received a copy of the GNU General Public License -- along with this program; if not, write to the Free Software -- Foundation, Inc., 59 Temple Place, Suite 330, Boston, MA 02111-1307 USA ----------------------------------------------------------------------------- -- Entity: clkmux -- File: clkmux.vhd -- Author: Edvin Catovic - Gaisler Research -- Description: Glitch-free clock multiplexer ------------------------------------------------------------------------------ library ieee; use ieee.std_logic_1164.all; use work.gencomp.all; use work.allclkgen.all; entity clkmux is generic(tech : integer := 0; rsel : integer range 0 to 1 := 0); -- registered sel port( i0, i1 : in std_ulogic; sel : in std_ulogic; o : out std_ulogic; rst : in std_ulogic := '1' ); end entity; architecture rtl of clkmux is signal seli, sel0, sel1, cg0, cg1 : std_ulogic; begin rs : if rsel = 1 generate rsproc : process(i0) begin if rising_edge(i0) then seli <= sel; end if; end process; end generate; cs : if rsel = 0 generate seli <= sel; end generate; tec : if has_clkmux(tech) = 1 generate xil : if is_unisim(tech) = 1 generate buf : clkmux_unisim port map(sel => seli, I0 => i0, I1 => i1, O => o); end generate; rhl : if tech = rhlib18t generate buf : clkmux_rhlib18t port map(sel => seli, I0 => i0, I1 => i1, O => o); end generate; ut13 : if tech = ut130 generate x0 : clkmux_ut130hbd port map (i0 => i0, i1 => i1, sel => sel, o => o); end generate; n2x : if tech = easic45 generate mux : clkmux_n2x port map (i0 => i0, i1 => i1, sel => sel, o => o); end generate; ut90n : if tech = ut90 generate x0 : clkmux_ut90nhbd port map (i0 => i0, i1 => i1, sel => seli, o => o); end generate; saed : if tech = saed32 generate x0 : clkmux_saed32 port map (i0 => i0, i1 => i1, sel => seli, o => o); end generate; dar : if tech = dare generate x0 : clkmux_dare port map (i0 => i0, i1 => i1, sel => seli, o => o); end generate; rhu : if tech = rhumc generate x0 : clkmux_rhumc port map (i0 => i0, i1 => i1, sel => seli, o => o); end generate; noxil : if not((is_unisim(tech) = 1) or (tech = rhlib18t) or (tech = ut130) or (tech = easic45) or (tech = ut90) or (tech = saed32) or (tech = dare) or (tech = rhumc)) generate o <= i0 when seli = '0' else i1; end generate; end generate; gen : if has_clkmux(tech) = 0 generate p0 : process(i0, rst) begin if rst = '0' then sel0 <= '1'; elsif falling_edge(i0) then sel0 <= (not seli) and (not sel1); end if; end process; p1 : process(i1, rst) begin if rst = '0' then sel1 <= '0'; elsif falling_edge(i1) then sel1 <= seli and (not sel0); end if; end process; cg0 <= i0 and sel0; cg1 <= i1 and sel1; o <= cg0 or cg1; end generate; end architecture;	gpl-2.0	1639a995be2e00c463b01be3ed9b8272	0.564398	3.475887	false	false	false	false
marco-c/leon-nexys2	grlib-gpl-1.3.4-b4140/designs/leon3-avnet-eval-xc4vlx60/leon3mp.vhd	1	27,300	------------------------------------------------------------------------------ -- LEON3 Demonstration design -- Copyright (C) 2006 Jiri Gaisler, Gaisler Research ------------------------------------------------------------------------------ -- This file is a part of the GRLIB VHDL IP LIBRARY -- Copyright (C) 2003 - 2008, Gaisler Research -- Copyright (C) 2008 - 2013, Aeroflex Gaisler -- -- This program is free software; you can redistribute it and/or modify -- it under the terms of the GNU General Public License as published by -- the Free Software Foundation; either version 2 of the License, or -- (at your option) any later version. -- -- This program is distributed in the hope that it will be useful, -- but WITHOUT ANY WARRANTY; without even the implied warranty of -- MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the -- GNU General Public License for more details. -- -- You should have received a copy of the GNU General Public License -- along with this program; if not, write to the Free Software -- Foundation, Inc., 59 Temple Place, Suite 330, Boston, MA 02111-1307 USA ------------------------------------------------------------------------------ library ieee; use ieee.std_logic_1164.all; library grlib; use grlib.amba.all; use grlib.stdlib.all; use grlib.devices.all; library techmap; use techmap.gencomp.all; use techmap.allclkgen.all; library gaisler; use gaisler.memctrl.all; use gaisler.ddrpkg.all; use gaisler.leon3.all; use gaisler.uart.all; use gaisler.misc.all; use gaisler.net.all; use gaisler.jtag.all; library esa; use esa.memoryctrl.all; use work.config.all; use work.avnet_eval.all; entity leon3mp is generic ( fabtech : integer := CFG_FABTECH; memtech : integer := CFG_MEMTECH; padtech : integer := CFG_PADTECH; clktech : integer := CFG_CLKTECH; disas : integer := CFG_DISAS; -- Enable disassembly to console dbguart : integer := CFG_DUART; -- Print UART on console pclow : integer := CFG_PCLOW; ddrfreq : integer := 100000 -- frequency of ddr clock in kHz ); port ( resetn : in std_ulogic; resoutn : out std_logic; clk_100mhz : in std_ulogic; clk_50mhz : in std_ulogic; clk_200p : in std_ulogic; clk_200n : in std_ulogic; errorn : out std_ulogic; -- prom interface address : out std_logic_vector(21 downto 0); data : inout std_logic_vector(15 downto 0); romsn : out std_ulogic; oen : out std_ulogic; writen : out std_ulogic; romrstn : out std_ulogic; -- pragma translate_off iosn : out std_ulogic; testdata : inout std_logic_vector(15 downto 0); -- pragma translate_on -- ddr memory ddr_clk0 : out std_logic; ddr_clk0b : out std_logic; ddr_clk_fb_out : out std_logic; ddr_clk_fb : in std_logic; ddr_cke0 : out std_logic; ddr_cs0b : out std_logic; ddr_web : out std_ulogic; -- ddr write enable ddr_rasb : out std_ulogic; -- ddr ras ddr_casb : out std_ulogic; -- ddr cas ddr_dm : out std_logic_vector (1 downto 0); -- ddr dm ddr_dqs : inout std_logic_vector (1 downto 0); -- ddr dqs ddr_ad : out std_logic_vector (12 downto 0); -- ddr address ddr_ba : out std_logic_vector (1 downto 0); -- ddr bank address ddr_dq : inout std_logic_vector (15 downto 0); -- ddr data -- debug support unit dsuen : in std_ulogic; dsubre : in std_ulogic; dsuact : out std_ulogic; -- UART for serial DCL/console I/O serrx : in std_ulogic; sertx : out std_ulogic; rtsn : out std_ulogic; ctsn : in std_ulogic; led_rx : out std_ulogic; led_tx : out std_ulogic; -- ethernet signals emdio : inout std_logic; -- ethernet PHY interface etx_clk : in std_ulogic; erx_clk : in std_ulogic; erxd : in std_logic_vector(3 downto 0); erx_dv : in std_ulogic; erx_er : in std_ulogic; erx_col : in std_ulogic; erx_crs : in std_ulogic; etxd : out std_logic_vector(3 downto 0); etx_en : out std_ulogic; etx_er : out std_ulogic; emdc : out std_ulogic; erstn : out std_ulogic; -- OLED display signals disp_dcn : out std_ulogic; disp_csn : out std_ulogic; disp_rdn : out std_ulogic; disp_wrn : out std_ulogic; disp_d : inout std_logic_vector(7 downto 0); phy_done : out std_ulogic; rst_done : out std_ulogic ); end; architecture rtl of leon3mp is component mig_36_1 port( cntrl0_ddr_dq : inout std_logic_vector(15 downto 0); cntrl0_ddr_a : out std_logic_vector(12 downto 0); cntrl0_ddr_ba : out std_logic_vector(1 downto 0); cntrl0_ddr_cke : out std_logic; cntrl0_ddr_cs_n : out std_logic; cntrl0_ddr_ras_n : out std_logic; cntrl0_ddr_cas_n : out std_logic; cntrl0_ddr_we_n : out std_logic; cntrl0_ddr_dm : out std_logic_vector(1 downto 0); sys_clk_p : in std_logic; sys_clk_n : in std_logic; clk200_p : in std_logic; clk200_n : in std_logic; init_done : out std_logic; sys_reset_in_n : in std_logic; cntrl0_clk_tb : out std_logic; cntrl0_reset_tb : out std_logic; cntrl0_wdf_almost_full : out std_logic; cntrl0_af_almost_full : out std_logic; cntrl0_read_data_valid : out std_logic; cntrl0_app_wdf_wren : in std_logic; cntrl0_app_af_wren : in std_logic; cntrl0_burst_length_div2 : out std_logic_vector(2 downto 0); cntrl0_app_af_addr : in std_logic_vector(35 downto 0); cntrl0_app_wdf_data : in std_logic_vector(31 downto 0); cntrl0_read_data_fifo_out : out std_logic_vector(31 downto 0); cntrl0_app_mask_data : in std_logic_vector(3 downto 0); cntrl0_ddr_dqs : inout std_logic_vector(1 downto 0); cntrl0_ddr_ck : out std_logic_vector(0 downto 0); cntrl0_ddr_ck_n : out std_logic_vector(0 downto 0) ); end component; constant blength : integer := 12; constant fifodepth : integer := 8; signal vcc, gnd : std_logic_vector(4 downto 0); signal memi : memory_in_type; signal memo : memory_out_type; signal wpo : wprot_out_type; signal sdi : sdctrl_in_type; signal sdo : sdctrl_out_type; signal gpioi : gpio_in_type; signal gpioo : gpio_out_type; signal apbi : apb_slv_in_type; signal apbo : apb_slv_out_vector := (others => apb_none); signal ahbsi : ahb_slv_in_type; signal ahbso : ahb_slv_out_vector := (others => ahbs_none); signal ahbmi : ahb_mst_in_type; signal ahbmo : ahb_mst_out_vector := (others => ahbm_none); signal lclk : std_ulogic; signal ddrclk, ddrrst, ddrclkfb : std_ulogic; signal clkm, rstn, clkml, clk2x : std_ulogic; signal cgi : clkgen_in_type; signal cgo : clkgen_out_type; signal u1i, dui : uart_in_type; signal u1o, duo : uart_out_type; signal irqi : irq_in_vector(0 to CFG_NCPU-1); signal irqo : irq_out_vector(0 to CFG_NCPU-1); signal dbgi : l3_debug_in_vector(0 to CFG_NCPU-1); signal dbgo : l3_debug_out_vector(0 to CFG_NCPU-1); signal dsui : dsu_in_type; signal dsuo : dsu_out_type; signal ethi, ethi1, ethi2 : eth_in_type; signal etho, etho1, etho2 : eth_out_type; signal gpti : gptimer_in_type; signal tck, tms, tdi, tdo : std_ulogic; signal fpi : grfpu_in_vector_type; signal fpo : grfpu_out_vector_type; -- signal dsubre : std_logic; signal duart, ldsuen : std_logic; signal rsertx, rserrx, rdsuen : std_logic; signal rstraw : std_logic; signal rstneg : std_logic; signal rxd1 : std_logic; signal txd1 : std_logic; signal lock : std_logic; signal lclk50 : std_logic; signal rst0_tb, rst0_tbn, clk0_tb : std_logic; signal migi : mig_app_in_type; signal migo : mig_app_out_type; signal init_done : std_ulogic; signal migrst : std_ulogic; signal ddr_clk : std_logic_vector(2 downto 0); signal ddr_clkb : std_logic_vector(2 downto 0); signal ddr_cke : std_logic_vector(1 downto 0); signal ddr_csb : std_logic_vector(1 downto 0); signal ddr_adl : std_logic_vector(13 downto 0); -- ddr address attribute keep : boolean; attribute syn_keep : boolean; attribute syn_preserve : boolean; attribute syn_keep of lock : signal is true; attribute syn_keep of clkml : signal is true; attribute syn_preserve of clkml : signal is true; attribute keep of lock : signal is true; attribute keep of clkml : signal is true; attribute keep of clkm : signal is true; constant BOARD_FREQ : integer := 50000; -- input frequency in KHz constant CPU_FREQ : integer := BOARD_FREQ * CFG_CLKMUL / CFG_CLKDIV; -- cpu frequency in KHz begin romrstn <= rstn; ---------------------------------------------------------------------- --- Reset and Clock generation ------------------------------------- ---------------------------------------------------------------------- vcc <= (others => '1'); gnd <= (others => '0'); cgi.pllctrl <= "00"; cgi.pllrst <= rstneg; rstneg <= not resetn; rst0 : rstgen port map (rstneg, clkm, lock, rstn, rstraw); clk50_pad : clkpad generic map (tech => padtech) port map (clk_50mhz, lclk50); clkgen0 : clkgen -- clock generator generic map (clktech, CFG_CLKMUL, CFG_CLKDIV, 0, 1, 0, 0, 0, BOARD_FREQ, 0) port map (lclk50, gnd(0), clkm, open, open, open, open, cgi, cgo); ---------------------------------------------------------------------- --- AHB CONTROLLER -------------------------------------------------- ---------------------------------------------------------------------- ahb0 : ahbctrl -- AHB arbiter/multiplexer generic map (defmast => CFG_DEFMST, split => CFG_SPLIT, rrobin => CFG_RROBIN, ioaddr => CFG_AHBIO, ioen => 1, nahbm => CFG_NCPU+CFG_AHB_UART+CFG_AHB_JTAG+CFG_GRETH+1, nahbs => 8) port map (rstn, clkm, ahbmi, ahbmo, ahbsi, ahbso); ---------------------------------------------------------------------- --- LEON3 processor and DSU ----------------------------------------- ---------------------------------------------------------------------- leon3gen : if CFG_LEON3 = 1 generate cpu : for i in 0 to CFG_NCPU-1 generate nosh : if CFG_GRFPUSH = 0 generate u0 : leon3s -- LEON3 processor generic map (i, fabtech, memtech, CFG_NWIN, CFG_DSU, CFG_FPU(1-CFG_GRFPUSH), CFG_V8, 0, CFG_MAC, pclow, CFG_NOTAG, CFG_NWP, CFG_ICEN, CFG_IREPL, CFG_ISETS, CFG_ILINE, CFG_ISETSZ, CFG_ILOCK, CFG_DCEN, CFG_DREPL, CFG_DSETS, CFG_DLINE, CFG_DSETSZ, CFG_DLOCK, CFG_DSNOOP, CFG_ILRAMEN, CFG_ILRAMSZ, CFG_ILRAMADDR, CFG_DLRAMEN, CFG_DLRAMSZ, CFG_DLRAMADDR, CFG_MMUEN, CFG_ITLBNUM, CFG_DTLBNUM, CFG_TLB_TYPE, CFG_TLB_REP, CFG_LDDEL, disas, CFG_ITBSZ, CFG_PWD, CFG_SVT, CFG_RSTADDR, CFG_NCPU-1, CFG_DFIXED, 0, CFG_MMU_PAGE, CFG_BP) port map (clkm, rstn, ahbmi, ahbmo(i), ahbsi, ahbso, irqi(i), irqo(i), dbgi(i), dbgo(i)); end generate; sh : if CFG_GRFPUSH = 1 generate u0 : leon3sh -- LEON3 processor generic map (i, fabtech, memtech, CFG_NWIN, CFG_DSU, CFG_FPU(1-CFG_GRFPUSH), CFG_V8, 0, CFG_MAC, pclow, CFG_NOTAG, CFG_NWP, CFG_ICEN, CFG_IREPL, CFG_ISETS, CFG_ILINE, CFG_ISETSZ, CFG_ILOCK, CFG_DCEN, CFG_DREPL, CFG_DSETS, CFG_DLINE, CFG_DSETSZ, CFG_DLOCK, CFG_DSNOOP, CFG_ILRAMEN, CFG_ILRAMSZ, CFG_ILRAMADDR, CFG_DLRAMEN, CFG_DLRAMSZ, CFG_DLRAMADDR, CFG_MMUEN, CFG_ITLBNUM, CFG_DTLBNUM, CFG_TLB_TYPE, CFG_TLB_REP, CFG_LDDEL, disas, CFG_ITBSZ, CFG_PWD, CFG_SVT, CFG_RSTADDR, CFG_NCPU-1, CFG_DFIXED, 0, CFG_MMU_PAGE, CFG_BP) port map (clkm, rstn, ahbmi, ahbmo(i), ahbsi, ahbso, irqi(i), irqo(i), dbgi(i), dbgo(i), fpi(i), fpo(i)); end generate; end generate; sh : if CFG_GRFPUSH = 1 generate grfpush0 : grfpushwx generic map ((CFG_FPU-1), CFG_NCPU, fabtech) port map (clkm, rstn, fpi, fpo); end generate; error_pad : odpad generic map (tech => padtech) port map (errorn, dbgo(0).error); dsugen : if CFG_DSU = 1 generate dsu0 : dsu3 -- LEON3 Debug Support Unit generic map (hindex => 2, haddr => 16#900#, hmask => 16#F00#, ncpu => CFG_NCPU, tbits => 30, tech => memtech, irq => 0, kbytes => CFG_ATBSZ) port map (rstn, clkm, ahbmi, ahbsi, ahbso(2), dbgo, dbgi, dsui, dsuo); -- dsuen_pad : inpad generic map (tech => padtech) port map (dsuen, dsui.enable); dsui.enable <= '1'; dsubre_pad : inpad generic map (tech => padtech) port map (dsubre, dsui.break); dsuact_pad : outpad generic map (tech => padtech) port map (dsuact, dsuo.active); end generate; end generate; nodsu : if CFG_DSU = 0 generate ahbso(2) <= ahbs_none; dsuo.tstop <= '0'; dsuo.active <= '0'; end generate; dcomgen : if CFG_AHB_UART = 1 generate dcom0 : ahbuart -- Debug UART generic map (hindex => CFG_NCPU, pindex => 4, paddr => 7) port map (rstn, clkm, dui, duo, apbi, apbo(4), ahbmi, ahbmo(CFG_NCPU)); end generate; nouah : if CFG_AHB_UART = 0 generate apbo(4) <= apb_none; end generate; ahbjtaggen0 :if CFG_AHB_JTAG = 1 generate ahbjtag0 : ahbjtag generic map(tech => fabtech, hindex => CFG_NCPU+CFG_AHB_UART) port map(rstn, clkm, tck, tms, tdi, tdo, ahbmi, ahbmo(CFG_NCPU+CFG_AHB_UART), open, open, open, open, open, open, open, gnd(0)); end generate; ---------------------------------------------------------------------- --- Memory controllers ---------------------------------------------- ---------------------------------------------------------------------- mg2 : if CFG_MCTRL_LEON2 = 1 generate -- LEON2 memory controller sr1 : mctrl generic map (hindex => 5, pindex => 0, paddr => 0, srbanks => 1, ramaddr => 16#600#, rammask => 16#F00#, ram16 => 1 ) port map (rstn, clkm, memi, memo, ahbsi, ahbso(5), apbi, apbo(0), wpo, open); end generate; memi.brdyn <= '1'; memi.bexcn <= '1'; memi.writen <= '1'; memi.wrn <= "1111"; memi.bwidth <= "01"; mg0 : if (CFG_MCTRL_LEON2 = 0) generate apbo(0) <= apb_none; ahbso(5) <= ahbs_none; roms_pad : outpad generic map (tech => padtech) port map (romsn, vcc(0)); end generate; mgpads : if (CFG_MCTRL_LEON2 /= 0) generate addr_pad : outpadv generic map (width => 22, tech => padtech) port map (address, memo.address(22 downto 1)); roms_pad : outpad generic map (tech => padtech) port map (romsn, memo.romsn(0)); oen_pad : outpad generic map (tech => padtech) port map (oen, memo.oen); wri_pad : outpad generic map (tech => padtech) port map (writen, memo.writen); -- pragma translate_off iosn_pad : outpad generic map (tech => padtech) port map (iosn, memo.iosn); tbdr : for i in 0 to 1 generate data_pad : iopadv generic map (tech => padtech, width => 8) port map (testdata(15-i8 downto 8-i8), memo.data(15-i8 downto 8-i8), memo.bdrive(i+2), memi.data(15-i8 downto 8-i8)); end generate; -- pragma translate_on bdr : for i in 0 to 1 generate data_pad : iopadv generic map (tech => padtech, width => 8) port map (data(15-i8 downto 8-i8), memo.data(31-i8 downto 24-i8), memo.bdrive(i), memi.data(31-i8 downto 24-i8)); end generate; end generate; ---------------------------------------------------------------------- --- DDR memory controller ------------------------------------------- ---------------------------------------------------------------------- ddrsp0 : if (CFG_DDRSP /= 0) generate clk_pad : clkpad generic map (tech => padtech) port map (clk_100mhz, lclk); ddrc : ddrspa generic map ( fabtech => virtex4, memtech => memtech, hindex => 4, haddr => 16#400#, hmask => 16#F00#, ioaddr => 1, pwron => CFG_DDRSP_INIT, MHz => 100, rskew => -95 -- pragma translate_off * 0 -- disable clock skew during simulation -- pragma translate_on , clkmul => CFG_DDRSP_FREQ/5, clkdiv => 20, col => CFG_DDRSP_COL, Mbyte => CFG_DDRSP_SIZE, ahbfreq => CPU_FREQ/1000, ddrbits => 16) port map ( rstneg, rstn, lclk, clkm, lock, clkml, clkml, ahbsi, ahbso(4), ddr_clk, ddr_clkb, ddr_clk_fb_out, ddr_clk_fb, ddr_cke, ddr_csb, ddr_web, ddr_rasb, ddr_casb, ddr_dm, ddr_dqs, ddr_adl, ddr_ba, ddr_dq); ddr_clk0 <= ddr_clk(0); ddr_clk0b <= ddr_clkb(0); ddr_cke0 <= ddr_cke(0); ddr_cs0b <= ddr_csb(0); ddr_ad <= ddr_adl(12 downto 0); end generate; migsp0 : if (CFG_MIG_DDR2 = 1) generate ahb2mig0 : entity work.ahb2mig_avnet_eval generic map ( hindex => 0, haddr => 16#400#, hmask => 16#FE0#, MHz => 100, Mbyte => 32) port map ( rst_ahb => rstn, rst_ddr => rst0_tbn, rst_50 => rstneg, clk_ahb => clkm, clk_ddr => clk0_tb, clk_50 => lclk50, init_done => init_done, ahbsi => ahbsi, ahbso => ahbso(0), migi => migi, migo => migo); migv5 : mig_36_1 port map( cntrl0_ddr_dq => ddr_dq, cntrl0_ddr_a => ddr_ad(12 downto 0), cntrl0_ddr_ba => ddr_ba, cntrl0_ddr_cke => ddr_cke0, cntrl0_ddr_cs_n => ddr_cs0b, cntrl0_ddr_ras_n => ddr_rasb, cntrl0_ddr_cas_n => ddr_casb, cntrl0_ddr_we_n => ddr_web, cntrl0_ddr_dm => ddr_dm, sys_clk_p => clk_100mhz, clk200_p => clk_200p, sys_clk_n => clk_100mhz, clk200_n => clk_200n, init_done => init_done, sys_reset_in_n => migi.mig_rst, cntrl0_reset_tb => rst0_tb, cntrl0_clk_tb => clk0_tb, cntrl0_wdf_almost_full => migo.app_wdf_afull, cntrl0_af_almost_full => migo.app_af_afull, cntrl0_read_data_valid => migo.app_rd_data_valid, cntrl0_app_wdf_wren => migi.app_wdf_wren, cntrl0_app_af_wren => migi.app_en, cntrl0_app_af_addr => migi.app_addr, cntrl0_app_wdf_data => migi.app_wdf_data, cntrl0_read_data_fifo_out => migo.app_rd_data, cntrl0_app_mask_data => migi.app_wdf_mask, cntrl0_ddr_dqs => ddr_dqs, cntrl0_ddr_ck => ddr_clk(0 downto 0), cntrl0_ddr_ck_n => ddr_clkb(0 downto 0) ); ddr_clk0 <= ddr_clk(0); ddr_clk0b <= ddr_clkb(0); rst0_tbn <= not rst0_tb; -- lock <= cgo.clklock; lock <= init_done and rst0_tbn; -- led(7) <= init_done; end generate; phy_done <= init_done; rst_done <= migi.mig_rst; noddr : if (CFG_DDRSP + CFG_MIG_DDR2) = 0 generate lock <= '1'; end generate; ---------------------------------------------------------------------- --- APB Bridge and various periherals ------------------------------- ---------------------------------------------------------------------- apb0 : apbctrl -- AHB/APB bridge generic map (hindex => 1, haddr => CFG_APBADDR) port map (rstn, clkm, ahbsi, ahbso(1), apbi, apbo); ua1 : if CFG_UART1_ENABLE /= 0 generate uart1 : apbuart -- UART 1 generic map (pindex => 1, paddr => 1, pirq => 2, console => dbguart, fifosize => CFG_UART1_FIFO) port map (rstn, clkm, apbi, apbo(1), u1i, u1o); u1i.rxd <= rxd1; u1i.ctsn <= '0'; u1i.extclk <= '0'; txd1 <= u1o.txd; end generate; noua0 : if CFG_UART1_ENABLE = 0 generate apbo(1) <= apb_none; end generate; irqctrl : if CFG_IRQ3_ENABLE /= 0 generate irqctrl0 : irqmp -- interrupt controller generic map (pindex => 2, paddr => 2, ncpu => CFG_NCPU) port map (rstn, clkm, apbi, apbo(2), irqo, irqi); end generate; irq3 : if CFG_IRQ3_ENABLE = 0 generate x : for i in 0 to CFG_NCPU-1 generate irqi(i).irl <= "0000"; end generate; apbo(2) <= apb_none; end generate; gpt : if CFG_GPT_ENABLE /= 0 generate timer0 : gptimer -- timer unit generic map (pindex => 3, paddr => 3, pirq => CFG_GPT_IRQ, sepirq => CFG_GPT_SEPIRQ, sbits => CFG_GPT_SW, ntimers => CFG_GPT_NTIM, nbits => CFG_GPT_TW) port map (rstn, clkm, apbi, apbo(3), gpti, open); gpti.dhalt <= dsuo.tstop; gpti.extclk <= '0'; end generate; notim : if CFG_GPT_ENABLE = 0 generate apbo(3) <= apb_none; end generate; gpio0 : if CFG_GRGPIO_ENABLE /= 0 generate -- GR GPIO unit grgpio0: grgpio generic map( pindex => 11, paddr => 11, imask => CFG_GRGPIO_IMASK, nbits => 12 --CFG_GRGPIO_WIDTH ) port map( rstn, clkm, apbi, apbo(11), gpioi, gpioo); disp_csn_pad : outpad generic map (tech => padtech) port map (disp_csn, gpioo.dout(8)); disp_dcn_pad : outpad generic map (tech => padtech) port map (disp_dcn, gpioo.dout(9)); disp_rdn_pad : outpad generic map (tech => padtech) port map (disp_rdn, gpioo.dout(10)); disp_wrn_pad : outpad generic map (tech => padtech) port map (disp_wrn, gpioo.dout(11)); disp_d_pads : for i in 0 to 7 generate pio_pad : iopad generic map (tech => padtech) port map (disp_d(i), gpioo.dout(i), gpioo.oen(i), gpioi.din(i)); end generate; end generate; ----------------------------------------------------------------------- --- ETHERNET --------------------------------------------------------- ----------------------------------------------------------------------- eth0 : if CFG_GRETH = 1 generate -- Gaisler ethernet MAC e1 : grethm generic map(hindex => CFG_NCPU+CFG_AHB_UART+CFG_AHB_JTAG, pindex => 15, paddr => 15, pirq => 12, memtech => memtech, mdcscaler => CPU_FREQ/1000, enable_mdio => 1, fifosize => CFG_ETH_FIFO, nsync => 1, edcl => CFG_DSU_ETH, edclbufsz => CFG_ETH_BUF, macaddrh => CFG_ETH_ENM, macaddrl => CFG_ETH_ENL, ipaddrh => CFG_ETH_IPM, ipaddrl => CFG_ETH_IPL, phyrstadr => 3, giga => CFG_GRETH1G) port map( rst => rstn, clk => clkm, ahbmi => ahbmi, ahbmo => ahbmo(CFG_NCPU+CFG_AHB_UART+CFG_AHB_JTAG), apbi => apbi, apbo => apbo(15), ethi => ethi, etho => etho); emdio_pad : iopad generic map (tech => padtech) port map (emdio, etho.mdio_o, etho.mdio_oe, ethi.mdio_i); etxc_pad : clkpad generic map (tech => padtech) port map (etx_clk, ethi.tx_clk); erxc_pad : clkpad generic map (tech => padtech) port map (erx_clk, ethi.rx_clk); erxd_pad : inpadv generic map (tech => padtech, width => 4) port map (erxd, ethi.rxd(3 downto 0)); erxdv_pad : inpad generic map (tech => padtech) port map (erx_dv, ethi.rx_dv); erxer_pad : inpad generic map (tech => padtech) port map (erx_er, ethi.rx_er); erxco_pad : inpad generic map (tech => padtech) port map (erx_col, ethi.rx_col); erxcr_pad : inpad generic map (tech => padtech) port map (erx_crs, ethi.rx_crs); etxd_pad : outpadv generic map (tech => padtech, width => 4) port map (etxd, etho.txd(3 downto 0)); etxen_pad : outpad generic map (tech => padtech) port map (etx_en, etho.tx_en); etxer_pad : outpad generic map (tech => padtech) port map (etx_er, etho.tx_er); emdc_pad : outpad generic map (tech => padtech) port map (emdc, etho.mdc); erstn_pad : outpad generic map (tech => padtech) port map (erstn, rstn); end generate; ----------------------------------------------------------------------- --- AHB DMA ---------------------------------------------------------- ----------------------------------------------------------------------- -- dma0 : ahbdma -- generic map (hindex => CFG_NCPU+CFG_AHB_UART+CFG_GRETH, -- pindex => 12, paddr => 12, dbuf => 32) -- port map (rstn, clkm, apbi, apbo(12), ahbmi, -- ahbmo(CFG_NCPU+CFG_AHB_UART+CFG_GRETH)); -- -- at0 : ahbtrace -- generic map ( hindex => 7, ioaddr => 16#200#, iomask => 16#E00#, -- tech => memtech, irq => 0, kbytes => 8) -- port map ( rstn, clkm, ahbmi, ahbsi, ahbso(7)); ----------------------------------------------------------------------- --- AHB ROM ---------------------------------------------------------- ----------------------------------------------------------------------- bpromgen : if CFG_AHBROMEN /= 0 generate brom : entity work.ahbrom generic map (hindex => 6, haddr => CFG_AHBRODDR, pipe => CFG_AHBROPIP) port map ( rstn, clkm, ahbsi, ahbso(6)); end generate; nobpromgen : if CFG_AHBROMEN = 0 generate ahbso(6) <= ahbs_none; end generate; ----------------------------------------------------------------------- --- AHB RAM ---------------------------------------------------------- ----------------------------------------------------------------------- ahbramgen : if CFG_AHBRAMEN = 1 generate ahbram0 : ahbram generic map (hindex => 3, haddr => CFG_AHBRADDR, tech => CFG_MEMTECH, kbytes => CFG_AHBRSZ, pipe => CFG_AHBRPIPE) port map (rstn, clkm, ahbsi, ahbso(3)); end generate; nram : if CFG_AHBRAMEN = 0 generate ahbso(3) <= ahbs_none; end generate; ----------------------------------------------------------------------- --- Drive unused bus elements --------------------------------------- ----------------------------------------------------------------------- nam1 : for i in (CFG_NCPU+CFG_AHB_UART+CFG_AHB_JTAG+CFG_GRETH+1) to NAHBMST-1 generate ahbmo(i) <= ahbm_none; end generate; -- nap0 : for i in 9 to NAPBSLV-1-CFG_GRETH generate apbo(i) <= apb_none; end generate; -- nah0 : for i in 8 to NAHBSLV-1 generate ahbso(i) <= ahbs_none; end generate; resoutn <= rstn; ----------------------------------------------------------------------- --- Boot message ---------------------------------------------------- ----------------------------------------------------------------------- -- pragma translate_off x : report_design generic map ( msg1 => "LEON3 MP Demonstration design for Avnet Virtex4 Eval board", fabtech => tech_table(fabtech), memtech => tech_table(memtech), mdel => 1 ); -- pragma translate_on -- use switch 1 to multiplex DSU UART and UART1 dsuen_pad : inpad generic map (tech => padtech) port map (dsuen, ldsuen); duart <= rdsuen when CFG_AHB_UART /= 0 else '0'; rxd1 <= txd1 when duart = '1' else rserrx; rsertx <= duo.txd when duart = '1' else txd1; dui.rxd <= rserrx when duart = '1' else '1'; led_rx <= not rserrx; p1 : process(clkm) begin if rising_edge(clkm) then sertx <= rsertx; rserrx <= serrx; rdsuen <= ldsuen; rtsn <= '0'; led_tx <= not rsertx; end if; end process; end rtl;	gpl-2.0	13680519433fc03e4e1d02e8ac4e7e28	0.540769	3.570961	false	false	false	false
marco-c/leon-nexys2	grlib-gpl-1.3.4-b4140/lib/techmap/maps/ddr_oreg.vhd	1	2,899	------------------------------------------------------------------------------ -- This file is a part of the GRLIB VHDL IP LIBRARY -- Copyright (C) 2003 - 2008, Gaisler Research -- Copyright (C) 2008 - 2013, Aeroflex Gaisler -- -- This program is free software; you can redistribute it and/or modify -- it under the terms of the GNU General Public License as published by -- the Free Software Foundation; either version 2 of the License, or -- (at your option) any later version. -- -- This program is distributed in the hope that it will be useful, -- but WITHOUT ANY WARRANTY; without even the implied warranty of -- MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the -- GNU General Public License for more details. -- -- You should have received a copy of the GNU General Public License -- along with this program; if not, write to the Free Software -- Foundation, Inc., 59 Temple Place, Suite 330, Boston, MA 02111-1307 USA ----------------------------------------------------------------------------- -- Entity: ddr_oreg -- File: ddr_oreg.vhd -- Author: Jiri Gaisler - Gaisler Research -- Description: DDR output reg with tech selection ------------------------------------------------------------------------------ library ieee; use ieee.std_logic_1164.all; library techmap; use techmap.gencomp.all; use techmap.allddr.all; entity ddr_oreg is generic (tech : integer; arch : integer := 0); port ( Q : out std_ulogic; C1 : in std_ulogic; C2 : in std_ulogic; CE : in std_ulogic; D1 : in std_ulogic; D2 : in std_ulogic; R : in std_ulogic; S : in std_ulogic); end; architecture rtl of ddr_oreg is begin inf : if not ((tech = lattice) or (is_unisim(tech) = 1) or (tech = axcel) or (tech = axdsp) or (tech = apa3) or (tech = apa3e) or (tech = apa3l)) generate inf0 : gen_oddr_reg port map (Q, C1, C2, CE, D1, D2, R, S); end generate; ax : if (tech = axcel) or (tech = axdsp) generate ax0 : axcel_oddr_reg port map (Q, C1, C2, CE, D1, D2, R, S); end generate; pa3 : if (tech = apa3) generate pa0 : apa3_oddr_reg port map (Q, C1, C2, CE, D1, D2, R, S); end generate; pa3e : if (tech = apa3e) generate pa0 : apa3e_oddr_reg port map (Q, C1, C2, CE, D1, D2, R, S); end generate; pa3l : if (tech = apa3l) generate pa0 : apa3l_oddr_reg port map (Q, C1, C2, CE, D1, D2, R, S); end generate; lat : if tech = lattice generate lat0 : ec_oddr_reg port map (Q, C1, C2, CE, D1, D2, R, S); end generate; xil : if is_unisim(tech) = 1 generate xil0 : unisim_oddr_reg generic map (tech, arch) port map (Q, C1, C2, CE, D1, D2, R, S); end generate; --pragma translate_off assert (tech /= easic45) and (tech /= easic90) report "ddr_oreg: Not supported on eASIC. Use DDR pad instead." severity failure; --pragma translate_on end;	gpl-2.0	952085e6fb4099146053c2fddacba297	0.595723	3.378788	false	false	false	false
Fairyland0902/BlockyRoads	src/BlockyRoads/ipcore_dir/explosion/simulation/explosion_tb.vhd	1	4,361	-------------------------------------------------------------------------------- -- -- BLK MEM GEN v7_3 Core - Top File for the Example Testbench -- -------------------------------------------------------------------------------- -- -- (c) Copyright 2006_3010 Xilinx, Inc. All rights reserved. -- -- This file contains confidential and proprietary information -- of Xilinx, Inc. and is protected under U.S. and -- international copyright and other intellectual property -- laws. -- -- DISCLAIMER -- This disclaimer is not a license and does not grant any -- rights to the materials distributed herewith. Except as -- otherwise provided in a valid license issued to you by -- Xilinx, and to the maximum extent permitted by applicable -- law: (1) THESE MATERIALS ARE MADE AVAILABLE "AS IS" AND -- WITH ALL FAULTS, AND XILINX HEREBY DISCLAIMS ALL WARRANTIES -- AND CONDITIONS, EXPRESS, IMPLIED, OR STATUTORY, INCLUDING -- BUT NOT LIMITED TO WARRANTIES OF MERCHANTABILITY, NON- -- INFRINGEMENT, OR FITNESS FOR ANY PARTICULAR PURPOSE; and -- (2) Xilinx shall not be liable (whether in contract or tort, -- including negligence, or under any other theory of -- liability) for any loss or damage of any kind or nature -- related to, arising under or in connection with these -- materials, including for any direct, or any indirect, -- special, incidental, or consequential loss or damage -- (including loss of data, profits, goodwill, or any type of -- loss or damage suffered as a result of any action brought -- by a third party) even if such damage or loss was -- reasonably foreseeable or Xilinx had been advised of the -- possibility of the same. -- -- CRITICAL APPLICATIONS -- Xilinx products are not designed or intended to be fail- -- safe, or for use in any application requiring fail-safe -- performance, such as life-support or safety devices or -- systems, Class III medical devices, nuclear facilities, -- applications related to the deployment of airbags, or any -- other applications that could lead to death, personal -- injury, or severe property or environmental damage -- (individually and collectively, "Critical -- Applications"). Customer assumes the sole risk and -- liability of any use of Xilinx products in Critical -- Applications, subject only to applicable laws and -- regulations governing limitations on product liability. -- -- THIS COPYRIGHT NOTICE AND DISCLAIMER MUST BE RETAINED AS -- PART OF THIS FILE AT ALL TIMES. -------------------------------------------------------------------------------- -- Filename: explosion_tb.vhd -- Description: -- Testbench Top -------------------------------------------------------------------------------- -- Author: IP Solutions Division -- -- History: Sep 12, 2011 - First Release -------------------------------------------------------------------------------- -- -------------------------------------------------------------------------------- -- Library Declarations -------------------------------------------------------------------------------- LIBRARY IEEE; USE IEEE.STD_LOGIC_1164.ALL; USE IEEE.STD_LOGIC_ARITH.ALL; USE IEEE.STD_LOGIC_UNSIGNED.ALL; LIBRARY work; USE work.ALL; ENTITY explosion_tb IS END ENTITY; ARCHITECTURE explosion_tb_ARCH OF explosion_tb IS SIGNAL STATUS : STD_LOGIC_VECTOR(8 DOWNTO 0); SIGNAL CLK : STD_LOGIC := '1'; SIGNAL RESET : STD_LOGIC; BEGIN CLK_GEN: PROCESS BEGIN CLK <= NOT CLK; WAIT FOR 100 NS; CLK <= NOT CLK; WAIT FOR 100 NS; END PROCESS; RST_GEN: PROCESS BEGIN RESET <= '1'; WAIT FOR 1000 NS; RESET <= '0'; WAIT; END PROCESS; --STOP_SIM: PROCESS BEGIN -- WAIT FOR 200 US; -- STOP SIMULATION AFTER 1 MS -- ASSERT FALSE -- REPORT "END SIMULATION TIME REACHED" -- SEVERITY FAILURE; --END PROCESS; -- PROCESS BEGIN WAIT UNTIL STATUS(8)='1'; IF( STATUS(7 downto 0)/="0") THEN ASSERT false REPORT "Test Completed Successfully" SEVERITY NOTE; REPORT "Simulation Failed" SEVERITY FAILURE; ELSE ASSERT false REPORT "TEST PASS" SEVERITY NOTE; REPORT "Test Completed Successfully" SEVERITY FAILURE; END IF; END PROCESS; explosion_synth_inst:ENTITY work.explosion_synth GENERIC MAP (C_ROM_SYNTH => 0) PORT MAP( CLK_IN => CLK, RESET_IN => RESET, STATUS => STATUS ); END ARCHITECTURE;	mit	373bafdd3956c4a7a5150380a33cf84a	0.620958	4.684211	false	false	false	false
marco-c/leon-nexys2	grlib-gpl-1.3.4-b4140/designs/leon3-altera-ep3sl150/config.vhd	1	6,555	----------------------------------------------------------------------------- -- LEON3 Demonstration design test bench configuration -- Copyright (C) 2009 Aeroflex Gaisler ------------------------------------------------------------------------------ library techmap; use techmap.gencomp.all; package config is -- Technology and synthesis options constant CFG_FABTECH : integer := stratix3; constant CFG_MEMTECH : integer := stratix3; constant CFG_PADTECH : integer := stratix3; constant CFG_NOASYNC : integer := 0; constant CFG_SCAN : integer := 0; -- Clock generator constant CFG_CLKTECH : integer := stratix3; constant CFG_CLKMUL : integer := (30); constant CFG_CLKDIV : integer := (10); constant CFG_OCLKDIV : integer := 1; constant CFG_OCLKBDIV : integer := 0; constant CFG_OCLKCDIV : integer := 0; constant CFG_PCIDLL : integer := 0; constant CFG_PCISYSCLK: integer := 0; constant CFG_CLK_NOFB : integer := 0; -- LEON3 processor core constant CFG_LEON3 : integer := 1; constant CFG_NCPU : integer := (1); constant CFG_NWIN : integer := (8); constant CFG_V8 : integer := 16#32# + 40; constant CFG_MAC : integer := 0; constant CFG_BP : integer := 0; constant CFG_SVT : integer := 0; constant CFG_RSTADDR : integer := 16#00000#; constant CFG_LDDEL : integer := (1); constant CFG_NOTAG : integer := 0; constant CFG_NWP : integer := (2); constant CFG_PWD : integer := 02; constant CFG_FPU : integer := 0 + 160 + 320; constant CFG_GRFPUSH : integer := 0; constant CFG_ICEN : integer := 1; constant CFG_ISETS : integer := 2; constant CFG_ISETSZ : integer := 8; constant CFG_ILINE : integer := 8; constant CFG_IREPL : integer := 0; constant CFG_ILOCK : integer := 0; constant CFG_ILRAMEN : integer := 0; constant CFG_ILRAMADDR: integer := 16#8E#; constant CFG_ILRAMSZ : integer := 1; constant CFG_DCEN : integer := 1; constant CFG_DSETS : integer := 2; constant CFG_DSETSZ : integer := 4; constant CFG_DLINE : integer := 8; constant CFG_DREPL : integer := 0; constant CFG_DLOCK : integer := 0; constant CFG_DSNOOP : integer := 1 + 0 + 40; constant CFG_DFIXED : integer := 16#0#; constant CFG_DLRAMEN : integer := 0; constant CFG_DLRAMADDR: integer := 16#8F#; constant CFG_DLRAMSZ : integer := 1; constant CFG_MMUEN : integer := 0; constant CFG_ITLBNUM : integer := 2; constant CFG_DTLBNUM : integer := 2; constant CFG_TLB_TYPE : integer := 1 + 02; constant CFG_TLB_REP : integer := 1; constant CFG_MMU_PAGE : integer := 0; constant CFG_DSU : integer := 1; constant CFG_ITBSZ : integer := 2; constant CFG_ATBSZ : integer := 2; constant CFG_LEON3FT_EN : integer := 0; constant CFG_IUFT_EN : integer := 0; constant CFG_FPUFT_EN : integer := 0; constant CFG_RF_ERRINJ : integer := 0; constant CFG_CACHE_FT_EN : integer := 0; constant CFG_CACHE_ERRINJ : integer := 0; constant CFG_LEON3_NETLIST: integer := 0; constant CFG_DISAS : integer := 0 + 0; constant CFG_PCLOW : integer := 2; -- AMBA settings constant CFG_DEFMST : integer := (0); constant CFG_RROBIN : integer := 1; constant CFG_SPLIT : integer := 0; constant CFG_FPNPEN : integer := 0; constant CFG_AHBIO : integer := 16#FFF#; constant CFG_APBADDR : integer := 16#800#; constant CFG_AHB_MON : integer := 0; constant CFG_AHB_MONERR : integer := 0; constant CFG_AHB_MONWAR : integer := 0; constant CFG_AHB_DTRACE : integer := 0; -- DSU UART constant CFG_AHB_UART : integer := 0; -- JTAG based DSU interface constant CFG_AHB_JTAG : integer := 1; -- Ethernet DSU constant CFG_DSU_ETH : integer := 1 + 0 + 0; constant CFG_ETH_BUF : integer := 2; constant CFG_ETH_IPM : integer := 16#C0A8#; constant CFG_ETH_IPL : integer := 16#0058#; constant CFG_ETH_ENM : integer := 16#020000#; constant CFG_ETH_ENL : integer := 16#000012#; -- LEON2 memory controller constant CFG_MCTRL_LEON2 : integer := 1; constant CFG_MCTRL_RAM8BIT : integer := 0; constant CFG_MCTRL_RAM16BIT : integer := 1; constant CFG_MCTRL_5CS : integer := 0; constant CFG_MCTRL_SDEN : integer := 0; constant CFG_MCTRL_SEPBUS : integer := 0; constant CFG_MCTRL_INVCLK : integer := 0; constant CFG_MCTRL_SD64 : integer := 0; constant CFG_MCTRL_PAGE : integer := 0 + 0; -- SSRAM controller constant CFG_SSCTRL : integer := 0; constant CFG_SSCTRLP16 : integer := 0; -- DDR controller constant CFG_DDR2SP : integer := 1; constant CFG_DDR2SP_INIT : integer := 1; constant CFG_DDR2SP_FREQ : integer := (200); constant CFG_DDR2SP_TRFC : integer := (130); constant CFG_DDR2SP_DATAWIDTH : integer := (64); constant CFG_DDR2SP_FTEN : integer := 0; constant CFG_DDR2SP_FTWIDTH : integer := 0; constant CFG_DDR2SP_COL : integer := (10); constant CFG_DDR2SP_SIZE : integer := (256); constant CFG_DDR2SP_DELAY0 : integer := (0); constant CFG_DDR2SP_DELAY1 : integer := (0); constant CFG_DDR2SP_DELAY2 : integer := (0); constant CFG_DDR2SP_DELAY3 : integer := (0); constant CFG_DDR2SP_DELAY4 : integer := (0); constant CFG_DDR2SP_DELAY5 : integer := (0); constant CFG_DDR2SP_DELAY6 : integer := (0); constant CFG_DDR2SP_DELAY7 : integer := (0); constant CFG_DDR2SP_NOSYNC : integer := 0; -- AHB ROM constant CFG_AHBROMEN : integer := 0; constant CFG_AHBROPIP : integer := 0; constant CFG_AHBRODDR : integer := 16#000#; constant CFG_ROMADDR : integer := 16#000#; constant CFG_ROMMASK : integer := 16#E00# + 16#000#; -- AHB RAM constant CFG_AHBRAMEN : integer := 0; constant CFG_AHBRSZ : integer := 1; constant CFG_AHBRADDR : integer := 16#A00#; constant CFG_AHBRPIPE : integer := 0; -- Gaisler Ethernet core constant CFG_GRETH : integer := 1; constant CFG_GRETH1G : integer := 0; constant CFG_ETH_FIFO : integer := 16; -- UART 1 constant CFG_UART1_ENABLE : integer := 1; constant CFG_UART1_FIFO : integer := 8; -- LEON3 interrupt controller constant CFG_IRQ3_ENABLE : integer := 1; constant CFG_IRQ3_NSEC : integer := 0; -- Modular timer constant CFG_GPT_ENABLE : integer := 1; constant CFG_GPT_NTIM : integer := (2); constant CFG_GPT_SW : integer := (8); constant CFG_GPT_TW : integer := (32); constant CFG_GPT_IRQ : integer := (8); constant CFG_GPT_SEPIRQ : integer := 1; constant CFG_GPT_WDOGEN : integer := 0; constant CFG_GPT_WDOG : integer := 16#0#; -- GPIO port constant CFG_GRGPIO_ENABLE : integer := 1; constant CFG_GRGPIO_IMASK : integer := 16#6#; constant CFG_GRGPIO_WIDTH : integer := (3); -- GRLIB debugging constant CFG_DUART : integer := 0; end;	gpl-2.0	82a354c034b7a1272106bb76758cda6f	0.645919	3.550921	false	false	false	false
freecores/usb_fpga_1_11	examples/usb-fpga-2.16/2.16b/ucecho/fpga-vivado/ucecho.vhd	4	738	library ieee; use IEEE.std_logic_1164.all; use IEEE.numeric_std.all; Library UNISIM; use UNISIM.vcomponents.all; entity ucecho is port( pd : in unsigned(7 downto 0); pb : out unsigned(7 downto 0); fxclk_in : in std_logic ); end ucecho; architecture RTL of ucecho is --signal declaration signal pb_buf : unsigned(7 downto 0); signal clk : std_logic; begin clk_buf : IBUFG port map ( I => fxclk_in, O => clk ); dpUCECHO: process(CLK) begin if CLK' event and CLK = '1' then if ( pd >= 97 ) and ( pd <= 122) then pb_buf <= pd - 32; else pb_buf <= pd; end if; pb <= pb_buf; end if; end process dpUCECHO; end RTL;	gpl-3.0	9bbe0a9a7f3b9c80a6a6ab1b5e6491ec	0.566396	3.167382	false	false	false	false
marco-c/leon-nexys2	grlib-gpl-1.3.4-b4140/lib/techmap/maps/leon4_net.vhd	1	22,827	------------------------------------------------------------------------------ -- This file is a part of the GRLIB VHDL IP LIBRARY -- Copyright (C) 2003 - 2008, Gaisler Research -- Copyright (C) 2008 - 2013, Aeroflex Gaisler -- -- This program is free software; you can redistribute it and/or modify -- it under the terms of the GNU General Public License as published by -- the Free Software Foundation; either version 2 of the License, or -- (at your option) any later version. -- -- This program is distributed in the hope that it will be useful, -- but WITHOUT ANY WARRANTY; without even the implied warranty of -- MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the -- GNU General Public License for more details. -- -- You should have received a copy of the GNU General Public License -- along with this program; if not, write to the Free Software -- Foundation, Inc., 59 Temple Place, Suite 330, Boston, MA 02111-1307 USA ------------------------------------------------------------------------------ library ieee; use ieee.std_logic_1164.all; library grlib; use grlib.amba.all; use grlib.stdlib.all; use grlib.devices.all; use work.gencomp.all; entity leon4_net is generic ( hindex : integer := 0; fabtech : integer range 0 to NTECH := DEFFABTECH; memtech : integer range 0 to NTECH := DEFMEMTECH; nwindows : integer range 2 to 32 := 8; dsu : integer range 0 to 1 := 0; fpu : integer range 0 to 31 := 0; v8 : integer range 0 to 63 := 0; cp : integer range 0 to 1 := 0; mac : integer range 0 to 1 := 0; pclow : integer range 0 to 2 := 2; notag : integer range 0 to 1 := 0; nwp : integer range 0 to 4 := 0; icen : integer range 0 to 1 := 0; irepl : integer range 0 to 2 := 2; isets : integer range 1 to 4 := 1; ilinesize : integer range 4 to 8 := 4; isetsize : integer range 1 to 256 := 1; isetlock : integer range 0 to 1 := 0; dcen : integer range 0 to 1 := 0; drepl : integer range 0 to 2 := 2; dsets : integer range 1 to 4 := 1; dlinesize : integer range 4 to 8 := 4; dsetsize : integer range 1 to 256 := 1; dsetlock : integer range 0 to 1 := 0; dsnoop : integer range 0 to 6 := 0; ilram : integer range 0 to 1 := 0; ilramsize : integer range 1 to 512 := 1; ilramstart : integer range 0 to 255 := 16#8e#; dlram : integer range 0 to 1 := 0; dlramsize : integer range 1 to 512 := 1; dlramstart : integer range 0 to 255 := 16#8f#; mmuen : integer range 0 to 1 := 0; itlbnum : integer range 2 to 64 := 8; dtlbnum : integer range 2 to 64 := 8; tlb_type : integer range 0 to 3 := 1; tlb_rep : integer range 0 to 1 := 0; lddel : integer range 1 to 2 := 2; disas : integer range 0 to 2 := 0; tbuf : integer range 0 to 64 := 0; pwd : integer range 0 to 2 := 2; -- power-down svt : integer range 0 to 1 := 1; -- single vector trapping rstaddr : integer := 0; smp : integer range 0 to 31 := 0; -- support SMP systems iuft : integer range 0 to 4 := 0; fpft : integer range 0 to 4 := 0; cmft : integer range 0 to 1 := 0; cached : integer := 0; scantest : integer := 0 ); port ( clk : in std_ulogic; gclk : in std_ulogic; hclken : in std_ulogic; rstn : in std_ulogic; ahbix : in ahb_mst_in_type; ahbox : out ahb_mst_out_type; ahbsix : in ahb_slv_in_type; ahbso : in ahb_slv_out_vector; irqi_irl: in std_logic_vector(3 downto 0); irqi_rst: in std_ulogic; irqi_run: in std_ulogic; irqi_rstvec: in std_logic_vector(31 downto 12); irqi_iact: in std_ulogic; irqi_index: in std_logic_vector(3 downto 0); irqo_intack: out std_ulogic; irqo_irl: out std_logic_vector(3 downto 0); irqo_pwd: out std_ulogic; irqo_fpen: out std_ulogic; irqo_idle: out std_ulogic; dbgi_dsuen: in std_ulogic; -- DSU enable dbgi_denable: in std_ulogic; -- diagnostic register access enable dbgi_dbreak: in std_ulogic; -- debug break-in dbgi_step: in std_ulogic; -- single step dbgi_halt: in std_ulogic; -- halt processor dbgi_reset: in std_ulogic; -- reset processor dbgi_dwrite: in std_ulogic; -- read/write dbgi_daddr: in std_logic_vector(23 downto 2); -- diagnostic address dbgi_ddata: in std_logic_vector(31 downto 0); -- diagnostic data dbgi_btrapa: in std_ulogic; -- break on IU trap dbgi_btrape: in std_ulogic; -- break on IU trap dbgi_berror: in std_ulogic; -- break on IU error mode dbgi_bwatch: in std_ulogic; -- break on IU watchpoint dbgi_bsoft: in std_ulogic; -- break on software breakpoint (TA 1) dbgi_tenable: in std_ulogic; dbgi_timer: in std_logic_vector(30 downto 0); dbgo_data: out std_logic_vector(31 downto 0); dbgo_crdy: out std_ulogic; dbgo_dsu: out std_ulogic; dbgo_dsumode: out std_ulogic; dbgo_error: out std_ulogic; dbgo_halt: out std_ulogic; dbgo_pwd: out std_ulogic; dbgo_idle: out std_ulogic; dbgo_ipend: out std_ulogic; dbgo_icnt: out std_ulogic; dbgo_fcnt : out std_ulogic; dbgo_optype : out std_logic_vector(5 downto 0); -- instruction type dbgo_bpmiss : out std_ulogic; -- branch predict miss dbgo_istat_cmiss: out std_ulogic; dbgo_istat_tmiss: out std_ulogic; dbgo_istat_chold: out std_ulogic; dbgo_istat_mhold: out std_ulogic; dbgo_dstat_cmiss: out std_ulogic; dbgo_dstat_tmiss: out std_ulogic; dbgo_dstat_chold: out std_ulogic; dbgo_dstat_mhold: out std_ulogic; dbgo_wbhold : out std_ulogic; -- write buffer hold dbgo_su : out std_ulogic); end ; architecture rtl of leon4_net is signal disasen : std_ulogic; component leon4_ut90nhbd generic ( hindex : integer := 0; fabtech : integer range 0 to NTECH := DEFFABTECH; memtech : integer range 0 to NTECH := DEFMEMTECH; nwindows : integer range 2 to 32 := 8; dsu : integer range 0 to 1 := 0; fpu : integer range 0 to 31 := 0; v8 : integer range 0 to 63 := 0; cp : integer range 0 to 1 := 0; mac : integer range 0 to 1 := 0; pclow : integer range 0 to 2 := 2; notag : integer range 0 to 1 := 0; nwp : integer range 0 to 4 := 0; icen : integer range 0 to 1 := 0; irepl : integer range 0 to 2 := 2; isets : integer range 1 to 4 := 1; ilinesize : integer range 4 to 8 := 4; isetsize : integer range 1 to 256 := 1; isetlock : integer range 0 to 1 := 0; dcen : integer range 0 to 1 := 0; drepl : integer range 0 to 2 := 2; dsets : integer range 1 to 4 := 1; dlinesize : integer range 4 to 8 := 4; dsetsize : integer range 1 to 256 := 1; dsetlock : integer range 0 to 1 := 0; dsnoop : integer range 0 to 6 := 0; ilram : integer range 0 to 1 := 0; ilramsize : integer range 1 to 512 := 1; ilramstart : integer range 0 to 255 := 16#8e#; dlram : integer range 0 to 1 := 0; dlramsize : integer range 1 to 512 := 1; dlramstart : integer range 0 to 255 := 16#8f#; mmuen : integer range 0 to 1 := 0; itlbnum : integer range 2 to 64 := 8; dtlbnum : integer range 2 to 64 := 8; tlb_type : integer range 0 to 1 := 1; tlb_rep : integer range 0 to 1 := 0; lddel : integer range 1 to 2 := 2; disas : integer range 0 to 1 := 0; tbuf : integer range 0 to 64 := 0; pwd : integer range 0 to 2 := 2; -- power-down svt : integer range 0 to 1 := 1; -- single vector trapping rstaddr : integer := 0; smp : integer range 0 to 31 := 0; -- support SMP systems iuft : integer range 0 to 4 := 0; fpft : integer range 0 to 4 := 0; cmft : integer range 0 to 1 := 0; cached : integer := 0; scantest : integer := 0 ); port ( clk: in std_ulogic; gclk: in std_ulogic; hclken: in std_ulogic; rstn: in std_ulogic; ahbi_hgrant: in std_logic_vector(0 to NAHBMST-1); -- bus grant ahbi_hready: in std_ulogic; -- transfer done ahbi_hresp: in std_logic_vector(1 downto 0); -- response type ahbi_hrdata: in std_logic_vector(127 downto 0); -- read data bus ahbi_hirq: in std_logic_vector(NAHBIRQ-1 downto 0); -- interrupt result bus ahbi_testen: in std_ulogic; ahbi_testrst: in std_ulogic; ahbi_scanen: in std_ulogic; ahbi_testoen: in std_ulogic; ahbo_hbusreq: out std_ulogic; -- bus request ahbo_hlock: out std_ulogic; -- lock request ahbo_htrans: out std_logic_vector(1 downto 0); -- transfer type ahbo_haddr: out std_logic_vector(31 downto 0); -- address bus (byte) ahbo_hwrite: out std_ulogic; -- read/write ahbo_hsize: out std_logic_vector(2 downto 0); -- transfer size ahbo_hburst: out std_logic_vector(2 downto 0); -- burst type ahbo_hprot: out std_logic_vector(3 downto 0); -- protection control ahbo_hwdata: out std_logic_vector(127 downto 0); -- write data bus ahbo_hirq: out std_logic_vector(NAHBIRQ-1 downto 0); -- interrupt bus ahbsi_hsel: in std_logic_vector(0 to NAHBSLV-1); -- slave select ahbsi_haddr: in std_logic_vector(31 downto 0); -- address bus (byte) ahbsi_hwrite: in std_ulogic; -- read/write ahbsi_htrans: in std_logic_vector(1 downto 0); -- transfer type ahbsi_hsize: in std_logic_vector(2 downto 0); -- transfer size ahbsi_hburst: in std_logic_vector(2 downto 0); -- burst type ahbsi_hwdata: in std_logic_vector(127 downto 0); -- write data bus ahbsi_hprot: in std_logic_vector(3 downto 0); -- protection control ahbsi_hready: in std_ulogic; -- transfer done ahbsi_hmaster: in std_logic_vector(3 downto 0); -- current master ahbsi_hmastlock: in std_ulogic; -- locked access ahbsi_hmbsel: in std_logic_vector(0 to NAHBAMR-1); -- memory bank select ahbsi_hirq: in std_logic_vector(NAHBIRQ-1 downto 0); -- interrupt result bus irqi_irl: in std_logic_vector(3 downto 0); irqi_rst: in std_ulogic; irqi_run: in std_ulogic; irqi_rstvec: in std_logic_vector(31 downto 12); irqi_iact: in std_ulogic; irqi_index: in std_logic_vector(3 downto 0); irqo_intack: out std_ulogic; irqo_irl: out std_logic_vector(3 downto 0); irqo_pwd: out std_ulogic; irqo_fpen: out std_ulogic; irqo_idle: out std_ulogic; dbgi_dsuen: in std_ulogic; -- DSU enable dbgi_denable: in std_ulogic; -- diagnostic register access enable dbgi_dbreak: in std_ulogic; -- debug break-in dbgi_step: in std_ulogic; -- single step dbgi_halt: in std_ulogic; -- halt processor dbgi_reset: in std_ulogic; -- reset processor dbgi_dwrite: in std_ulogic; -- read/write dbgi_daddr: in std_logic_vector(23 downto 2); -- diagnostic address dbgi_ddata: in std_logic_vector(31 downto 0); -- diagnostic data dbgi_btrapa: in std_ulogic; -- break on IU trap dbgi_btrape: in std_ulogic; -- break on IU trap dbgi_berror: in std_ulogic; -- break on IU error mode dbgi_bwatch: in std_ulogic; -- break on IU watchpoint dbgi_bsoft: in std_ulogic; -- break on software breakpoint (TA 1) dbgi_tenable: in std_ulogic; dbgi_timer: in std_logic_vector(30 downto 0); dbgo_data: out std_logic_vector(31 downto 0); dbgo_crdy: out std_ulogic; dbgo_dsu: out std_ulogic; dbgo_dsumode: out std_ulogic; dbgo_error: out std_ulogic; dbgo_halt: out std_ulogic; dbgo_pwd: out std_ulogic; dbgo_idle: out std_ulogic; dbgo_ipend: out std_ulogic; dbgo_icnt: out std_ulogic; dbgo_fcnt : out std_ulogic; dbgo_optype : out std_logic_vector(5 downto 0); -- instruction type dbgo_bpmiss : out std_ulogic; -- branch predict miss dbgo_istat_cmiss: out std_ulogic; dbgo_istat_tmiss: out std_ulogic; dbgo_istat_chold: out std_ulogic; dbgo_istat_mhold: out std_ulogic; dbgo_dstat_cmiss: out std_ulogic; dbgo_dstat_tmiss: out std_ulogic; dbgo_dstat_chold: out std_ulogic; dbgo_dstat_mhold: out std_ulogic; dbgo_wbhold : out std_ulogic; -- write buffer hold dbgo_su : out std_ulogic; disasen : in std_ulogic); end component; signal ahbi_hgrant: std_logic_vector(0 to NAHBMST-1); signal ahbi_hready: std_ulogic; signal ahbi_hresp: std_logic_vector(1 downto 0); signal ahbi_hrdata: std_logic_vector(127 downto 0); signal ahbi_hirq: std_logic_vector(NAHBIRQ-1 downto 0); signal ahbi_testen: std_ulogic; signal ahbi_testrst: std_ulogic; signal ahbi_scanen: std_ulogic; signal ahbi_testoen: std_ulogic; signal ahbo_hbusreq: std_ulogic; signal ahbo_hlock: std_ulogic; signal ahbo_htrans: std_logic_vector(1 downto 0); signal ahbo_haddr: std_logic_vector(31 downto 0); signal ahbo_hwrite: std_ulogic; signal ahbo_hsize: std_logic_vector(2 downto 0); signal ahbo_hburst: std_logic_vector(2 downto 0); signal ahbo_hprot: std_logic_vector(3 downto 0); signal ahbo_hwdata: std_logic_vector(127 downto 0); signal ahbo_hirq: std_logic_vector(NAHBIRQ-1 downto 0); signal ahbsi_hsel: std_logic_vector(0 to NAHBSLV-1); signal ahbsi_haddr: std_logic_vector(31 downto 0); signal ahbsi_hwrite: std_ulogic; signal ahbsi_htrans: std_logic_vector(1 downto 0); signal ahbsi_hsize: std_logic_vector(2 downto 0); signal ahbsi_hburst: std_logic_vector(2 downto 0); signal ahbsi_hwdata: std_logic_vector(127 downto 0); signal ahbsi_hprot: std_logic_vector(3 downto 0); signal ahbsi_hready: std_ulogic; signal ahbsi_hmaster: std_logic_vector(3 downto 0); signal ahbsi_hmastlock: std_ulogic; signal ahbsi_hmbsel: std_logic_vector(0 to NAHBAMR-1); signal ahbsi_hirq: std_logic_vector(NAHBIRQ-1 downto 0); constant hconfig: ahb_config_type := ( 0 => ahb_device_reg ( VENDOR_GAISLER, GAISLER_LEON4, 0, 0, 0), others => zero32); begin disasen <= '1' when disas /= 0 else '0'; -- Plug&Play information ahbox.hconfig <= hconfig; ahbox.hindex <= hindex; ut09 : if fabtech = ut90 generate wrp: leon4_ut90nhbd generic map (fpu => fpu, v8 => v8, mmuen => mmuen, isets => isets, isetsize => isetsize, smp => smp) port map( clk => clk, gclk => gclk, hclken => hclken, rstn => rstn, ahbi_hgrant => ahbi_hgrant, ahbi_hready => ahbi_hready, ahbi_hresp => ahbi_hresp, ahbi_hrdata => ahbi_hrdata, ahbi_hirq => ahbi_hirq, ahbi_testen => ahbi_testen, ahbi_testrst => ahbi_testrst, ahbi_scanen => ahbi_scanen, ahbi_testoen => ahbi_testoen, ahbo_hbusreq => ahbo_hbusreq, ahbo_hlock => ahbo_hlock, ahbo_htrans => ahbo_htrans, ahbo_haddr => ahbo_haddr, ahbo_hwrite => ahbo_hwrite, ahbo_hsize => ahbo_hsize, ahbo_hburst => ahbo_hburst, ahbo_hprot => ahbo_hprot, ahbo_hwdata => ahbo_hwdata, ahbo_hirq => ahbo_hirq, ahbsi_hsel => ahbsi_hsel, ahbsi_haddr => ahbsi_haddr, ahbsi_hwrite => ahbsi_hwrite, ahbsi_htrans => ahbsi_htrans, ahbsi_hsize => ahbsi_hsize, ahbsi_hburst => ahbsi_hburst, ahbsi_hwdata => ahbsi_hwdata, ahbsi_hprot => ahbsi_hprot, ahbsi_hready => ahbsi_hready, ahbsi_hmaster => ahbsi_hmaster, ahbsi_hmastlock => ahbsi_hmastlock, ahbsi_hmbsel => ahbsi_hmbsel, ahbsi_hirq => ahbsi_hirq, irqi_irl => irqi_irl, irqi_rst => irqi_rst, irqi_run => irqi_run, irqi_rstvec => irqi_rstvec, irqi_iact => irqi_iact, irqi_index => irqi_index, irqo_intack => irqo_intack, irqo_irl => irqo_irl, irqo_pwd => irqo_pwd, irqo_fpen => irqo_fpen, irqo_idle => irqo_idle, dbgi_dsuen => dbgi_dsuen, dbgi_denable => dbgi_denable, dbgi_dbreak => dbgi_dbreak, dbgi_step => dbgi_step, dbgi_halt => dbgi_halt, dbgi_reset => dbgi_reset, dbgi_dwrite => dbgi_dwrite, dbgi_daddr => dbgi_daddr, dbgi_ddata => dbgi_ddata, dbgi_btrapa => dbgi_btrapa, dbgi_btrape => dbgi_btrape, dbgi_berror => dbgi_berror, dbgi_bwatch => dbgi_bwatch, dbgi_bsoft => dbgi_bsoft, dbgi_tenable => dbgi_tenable, dbgi_timer => dbgi_timer, dbgo_data => dbgo_data, dbgo_crdy => dbgo_crdy, dbgo_dsu => dbgo_dsu, dbgo_dsumode => dbgo_dsumode, dbgo_error => dbgo_error, dbgo_halt => dbgo_halt, dbgo_pwd => dbgo_pwd, dbgo_idle => dbgo_idle, dbgo_ipend => dbgo_ipend, dbgo_icnt => dbgo_icnt, dbgo_fcnt => dbgo_fcnt, dbgo_optype => dbgo_optype, dbgo_bpmiss => dbgo_bpmiss, dbgo_istat_cmiss => dbgo_istat_cmiss, dbgo_istat_tmiss => dbgo_istat_tmiss, dbgo_istat_chold => dbgo_istat_chold, dbgo_istat_mhold => dbgo_istat_mhold, dbgo_dstat_cmiss => dbgo_dstat_cmiss, dbgo_dstat_tmiss => dbgo_dstat_tmiss, dbgo_dstat_chold => dbgo_dstat_chold, dbgo_dstat_mhold => dbgo_dstat_mhold, dbgo_wbhold => dbgo_wbhold, dbgo_su => dbgo_su, disasen => disasen); end generate; ahbi_hgrant(0) <= ahbix.hgrant(hindex); ahbi_hgrant(1 to NAHBMST-1) <= (others => '0'); ahbi_hready <= ahbix.hready; ahbi_hresp <= ahbix.hresp; ahbi_hrdata(127 mod AHBDW downto 0) <= ahbix.hrdata(127 mod AHBDW downto 0); ahbi_hirq <= ahbix.hirq; ahbi_testen <= ahbix.testen; ahbi_testrst <= ahbix.testrst; ahbi_scanen <= ahbix.scanen; ahbi_testoen <= ahbix.testoen; ahbox.hbusreq <= ahbo_hbusreq; ahbox.hlock <= ahbo_hlock; ahbox.htrans <= ahbo_htrans; ahbox.haddr <= ahbo_haddr; ahbox.hwrite <= ahbo_hwrite; ahbox.hsize <= ahbo_hsize(2 downto 0); ahbox.hburst <= "00" & ahbo_hburst(0); ahbox.hprot <= ahbo_hprot; ahbox.hwdata(127 mod AHBDW downto 0) <= ahbo_hwdata(127 mod AHBDW downto 0); ahbox.hirq <= (others => '0'); --ahbo_hirq; ahbsi_hsel <= ahbsix.hsel; ahbsi_haddr <= ahbsix.haddr; ahbsi_hwrite <= ahbsix.hwrite; ahbsi_htrans <= ahbsix.htrans; ahbsi_hsize <= ahbsix.hsize; ahbsi_hburst <= ahbsix.hburst; ahbsi_hwdata(127 mod AHBDW downto 0) <= ahbsix.hwdata(127 mod AHBDW downto 0); ahbsi_hprot <= ahbsix.hprot; ahbsi_hready <= ahbsix.hready; ahbsi_hmaster <= ahbsix.hmaster; ahbsi_hmastlock <= ahbsix.hmastlock; ahbsi_hmbsel <= ahbsix.hmbsel; ahbsi_hirq <= ahbsix.hirq; -- pragma translate_off assert NAHBSLV=16 report "LEON3FT netlist: Only NAHBSLV=16 supported by wrapper" severity Failure; -- pragma translate_on end architecture;	gpl-2.0	2c0572cc3831a9777e4ece175637f1c8	0.51093	3.878845	false	false	false	false
marco-c/leon-nexys2	grlib-gpl-1.3.4-b4140/lib/gaisler/memctrl/memctrl.vhd	1	19,714	------------------------------------------------------------------------------ -- This file is a part of the GRLIB VHDL IP LIBRARY -- Copyright (C) 2003 - 2008, Gaisler Research -- Copyright (C) 2008 - 2013, Aeroflex Gaisler -- -- This program is free software; you can redistribute it and/or modify -- it under the terms of the GNU General Public License as published by -- the Free Software Foundation; either version 2 of the License, or -- (at your option) any later version. -- -- This program is distributed in the hope that it will be useful, -- but WITHOUT ANY WARRANTY; without even the implied warranty of -- MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the -- GNU General Public License for more details. -- -- You should have received a copy of the GNU General Public License -- along with this program; if not, write to the Free Software -- Foundation, Inc., 59 Temple Place, Suite 330, Boston, MA 02111-1307 USA ----------------------------------------------------------------------------- -- Entity: memctrl -- File: memctrl.vhd -- Author: Jiri Gaisler - Gaisler Research -- Description: Memory controller package ------------------------------------------------------------------------------ library ieee; use ieee.std_logic_1164.all; library grlib; use grlib.amba.all; use grlib.stdlib.log2; library techmap; use techmap.gencomp.all; package memctrl is type memory_in_type is record data : std_logic_vector(31 downto 0); -- Data bus address brdyn : std_logic; bexcn : std_logic; writen : std_logic; wrn : std_logic_vector(3 downto 0); bwidth : std_logic_vector(1 downto 0); sd : std_logic_vector(63 downto 0); cb : std_logic_vector(15 downto 0); scb : std_logic_vector(15 downto 0); edac : std_logic; end record; constant memory_in_none : memory_in_type := ((others => '0'), '0', '0', '0', (others => '0'), (others => '0'), (others => '0'), (others => '0'), (others => '0'), '0'); type memory_out_type is record address : std_logic_vector(31 downto 0); data : std_logic_vector(31 downto 0); sddata : std_logic_vector(63 downto 0); ramsn : std_logic_vector(7 downto 0); ramoen : std_logic_vector(7 downto 0); ramn : std_ulogic; romn : std_ulogic; mben : std_logic_vector(3 downto 0); iosn : std_logic; romsn : std_logic_vector(7 downto 0); oen : std_logic; writen : std_logic; wrn : std_logic_vector(3 downto 0); bdrive : std_logic_vector(3 downto 0); vbdrive : std_logic_vector(31 downto 0); --vector bus drive svbdrive : std_logic_vector(63 downto 0); --vector bus drive sdram read : std_logic; sa : std_logic_vector(14 downto 0); cb : std_logic_vector(15 downto 0); scb : std_logic_vector(15 downto 0); vcdrive : std_logic_vector(15 downto 0); --vector bus drive cb svcdrive : std_logic_vector(15 downto 0); --vector bus drive cb sdram ce : std_ulogic; sdram_en : std_ulogic; -- SDRAM enabled rs_edac_en : std_ulogic; -- Reed-Solomon enabled end record; constant memory_out_none : memory_out_type := ((others => '0'), (others => '0'), (others => '0'), (others => '1'), (others => '1'), '1', '1', (others => '1'), '1', (others => '1'), '1', '1', (others => '1'), (others => '1'), (others => '1'), (others => '1'), '0', (others => '0'), (others => '1'), (others => '1'), (others => '1'), (others => '1'), '0', '0', '0'); type sdctrl_in_type is record wprot : std_ulogic; data : std_logic_vector (127 downto 0); -- data in cb : std_logic_vector(63 downto 0); regrdata : std_logic_vector(63 downto 0); -- PHY-specific reg in datavalid : std_logic; -- Data-valid signal end record; constant sdctrl_in_none : sdctrl_in_type := ('0', (others => '0'), (others => '0'), (others => '0'), '0'); type sdctrl_out_type is record sdcke : std_logic_vector ( 1 downto 0); -- clk en sdcsn : std_logic_vector ( 1 downto 0); -- chip sel xsdcsn : std_logic_vector ( 7 downto 0); -- ext. chip sel sdwen : std_ulogic; -- write en rasn : std_ulogic; -- row addr stb casn : std_ulogic; -- col addr stb dqm : std_logic_vector ( 15 downto 0); -- data i/o mask bdrive : std_ulogic; -- bus drive qdrive : std_ulogic; -- bus drive nbdrive : std_ulogic; -- bdrive 1 cycle early vbdrive : std_logic_vector(63 downto 0); -- vector bus drive address : std_logic_vector (16 downto 2); -- address out data : std_logic_vector (127 downto 0); -- data out cb : std_logic_vector(63 downto 0); ce : std_ulogic; ba : std_logic_vector (2 downto 0); -- bank address sdck : std_logic_vector(2 downto 0); moben : std_logic; -- Mobile support cal_en : std_logic_vector(7 downto 0); -- enable delay calibration cal_inc : std_logic_vector(7 downto 0); -- inc/dec delay cal_pll : std_logic_vector(1 downto 0); -- (enable,inc/dec) pll phase cal_rst : std_logic; -- calibration reset odt : std_logic_vector(1 downto 0); -- In Die Termination conf : std_logic_vector(63 downto 0); oct : std_logic; -- On Chip Termination vcbdrive : std_logic_vector(31 downto 0); -- cb vector bus drive dqs_gate : std_logic; cbdqm : std_logic_vector(7 downto 0); cbcal_en : std_logic_vector(3 downto 0); cbcal_inc : std_logic_vector(3 downto 0); read_pend : std_logic_vector(7 downto 0); -- Read pending within 7...0 -- cycles (not including phy delays) -- PHY-specific register interface regwdata : std_logic_vector(63 downto 0); regwrite : std_logic_vector(1 downto 0); end record; constant sdctrl_out_none : sdctrl_out_type := ((others => '0'), (others => '0'), (others => '0'), '0', '0', '0', (others => '0'), '0', '0', '0', (others => '0'), (others => '0'), (others => '0'), (others => '0'), '0', (others => '0'), (others => '0'), '0', (others => '0'), (others => '0'), (others => '0'), '0', (others => '0'), (others => '0'), '0', (others => '0'), '0', (others => '0'), (others => '0'), (others => '0'), "00000000", (others => '0'), "00"); type sdram_out_type is record sdcke : std_logic_vector ( 1 downto 0); -- clk en sdcsn : std_logic_vector ( 1 downto 0); -- chip sel sdwen : std_ulogic; -- write en rasn : std_ulogic; -- row addr stb casn : std_ulogic; -- col addr stb dqm : std_logic_vector ( 7 downto 0); -- data i/o mask end record; type zbtssram_out_type is record cen : std_ulogic; oen : std_ulogic; wen : std_ulogic; advld : std_ulogic; addr : std_logic_vector(22 downto 0); bwn : std_logic_vector(15 downto 0); data : std_logic_vector(127 downto 0); dqoen : std_logic_vector(127 downto 0); zz : std_ulogic; shutdown : std_ulogic; end record; constant zbtssram_out_none : zbtssram_out_type := ( '1','1','1','1',(others => '0'),(others => '1'),(others => '0'),(others => '1'),'0','0'); type zbtssram_in_type is record data : std_logic_vector(127 downto 0); mbe : std_logic_vector(7 downto 0); end record; constant zbtssram_in_none : zbtssram_in_type := ( data => (others => '0'), mbe => (others => '0') ); component sdctrl generic ( hindex : integer := 0; haddr : integer := 0; hmask : integer := 16#f00#; ioaddr : integer := 16#000#; iomask : integer := 16#fff#; wprot : integer := 0; invclk : integer := 0; fast : integer := 0; pwron : integer := 0; sdbits : integer := 32; oepol : integer := 0; pageburst : integer := 0; mobile : integer := 0 ); port ( rst : in std_ulogic; clk : in std_ulogic; ahbsi : in ahb_slv_in_type; ahbso : out ahb_slv_out_type; sdi : in sdctrl_in_type; sdo : out sdctrl_out_type ); end component; component sdctrl64 generic ( hindex : integer := 0; haddr : integer := 0; hmask : integer := 16#f00#; ioaddr : integer := 16#000#; iomask : integer := 16#fff#; wprot : integer := 0; invclk : integer := 0; fast : integer := 0; pwron : integer := 0; oepol : integer := 0; pageburst : integer := 0; mobile : integer := 0 ); port ( rst : in std_ulogic; clk : in std_ulogic; ahbsi : in ahb_slv_in_type; ahbso : out ahb_slv_out_type; sdi : in sdctrl_in_type; sdo : out sdctrl_out_type ); end component; component ftsdctrl is generic ( hindex : integer := 0; haddr : integer := 0; hmask : integer := 16#f00#; ioaddr : integer := 16#000#; iomask : integer := 16#fff#; wprot : integer := 0; invclk : integer := 0; fast : integer := 0; pwron : integer := 0; sdbits : integer := 32; edacen : integer := 1; errcnt : integer := 0; cntbits : integer range 1 to 8 := 1; oepol : integer := 0; pageburst : integer := 0 ); port ( rst : in std_ulogic; clk : in std_ulogic; ahbsi : in ahb_slv_in_type; ahbso : out ahb_slv_out_type; sdi : in sdctrl_in_type; sdo : out sdctrl_out_type ); end component; component ftsdctrl64 generic ( hindex : integer := 0; haddr : integer := 0; hmask : integer := 16#f00#; ioaddr : integer := 16#000#; iomask : integer := 16#fff#; wprot : integer := 0; invclk : integer := 0; fast : integer := 0; pwron : integer := 0; oepol : integer := 0; pageburst : integer := 0; mobile : integer := 0; edac : integer := 0 ); port ( rst : in std_ulogic; clk : in std_ulogic; ahbsi : in ahb_slv_in_type; ahbso : out ahb_slv_out_type; sdi : in sdctrl_in_type; sdo : out sdctrl_out_type ); end component; component srctrl generic ( hindex : integer := 0; romaddr : integer := 0; rommask : integer := 16#ff0#; ramaddr : integer := 16#400#; rammask : integer := 16#ff0#; ioaddr : integer := 16#200#; iomask : integer := 16#ff0#; ramws : integer := 0; romws : integer := 2; iows : integer := 2; rmw : integer := 0; prom8en : integer := 0; oepol : integer := 0; srbanks : integer range 1 to 5 := 1; banksz : integer range 0 to 13 := 13; romasel : integer range 0 to 28 := 19 ); port ( rst : in std_ulogic; clk : in std_ulogic; ahbsi : in ahb_slv_in_type; ahbso : out ahb_slv_out_type; sri : in memory_in_type; sro : out memory_out_type; sdo : out sdctrl_out_type ); end component; component ftsrctrl is generic ( hindex : integer := 0; romaddr : integer := 0; rommask : integer := 16#ff0#; ramaddr : integer := 16#400#; rammask : integer := 16#ff0#; ioaddr : integer := 16#200#; iomask : integer := 16#ff0#; ramws : integer := 0; romws : integer := 2; iows : integer := 2; rmw : integer := 0; srbanks : integer range 1 to 8 := 1; banksz : integer range 0 to 15 := 15; rombanks : integer range 1 to 8 := 1; rombanksz : integer range 0 to 15 := 15; rombankszdef : integer range 0 to 15 := 15; pindex : integer := 0; paddr : integer := 0; pmask : integer := 16#fff#; edacen : integer range 0 to 1 := 1; errcnt : integer range 0 to 1 := 0; cntbits : integer range 1 to 8 := 1; wsreg : integer := 0; oepol : integer := 0; prom8en : integer := 0; netlist : integer := 0; tech : integer := 0 ); port ( rst : in std_ulogic; clk : in std_ulogic; ahbsi : in ahb_slv_in_type; ahbso : out ahb_slv_out_type; apbi : in apb_slv_in_type; apbo : out apb_slv_out_type; sri : in memory_in_type; sro : out memory_out_type; sdo : out sdctrl_out_type ); end component; type sdram_in_type is record haddr : std_logic_vector(31 downto 0); -- memory address rhaddr : std_logic_vector(31 downto 0); -- latched memory address hready : std_ulogic; hsize : std_logic_vector(1 downto 0); hsel : std_ulogic; hwrite : std_ulogic; htrans : std_logic_vector(1 downto 0); rhtrans : std_logic_vector(1 downto 0); nhtrans : std_logic_vector(1 downto 0); idle : std_ulogic; enable : std_ulogic; error : std_ulogic; merror : std_ulogic; brmw : std_ulogic; edac : std_ulogic; srdis : std_logic; end record; type sdram_mctrl_out_type is record address : std_logic_vector(16 downto 2); busy : std_ulogic; aload : std_ulogic; bdrive : std_ulogic; hready : std_ulogic; hsel : std_ulogic; bsel : std_ulogic; hresp : std_logic_vector (1 downto 0); vhready : std_ulogic; prdata : std_logic_vector (31 downto 0); end record; type wprot_out_type is record wprothit : std_ulogic; end record; component sdmctrl generic ( pindex : integer := 0; invclk : integer := 0; fast : integer := 0; wprot : integer := 0; sdbits : integer := 32; pageburst : integer := 0; mobile : integer := 0 ); port ( rst : in std_ulogic; clk : in std_ulogic; sdi : in sdram_in_type; sdo : out sdram_out_type; apbi : in apb_slv_in_type; wpo : in wprot_out_type; sdmo : out sdram_mctrl_out_type ); end component; component ftsdmctrl generic ( pindex : integer := 0; invclk : integer := 0; fast : integer := 0; wprot : integer := 0; sdbits : integer := 32; syncrst : integer := 0; pageburst : integer := 0 ); port ( rst : in std_ulogic; clk : in std_ulogic; sdi : in sdram_in_type; sdo : out sdram_out_type; apbi : in apb_slv_in_type; wpo : in wprot_out_type; sdmo : out sdram_mctrl_out_type ); end component; component ftmctrl generic ( hindex : integer := 0; pindex : integer := 0; romaddr : integer := 16#000#; rommask : integer := 16#E00#; ioaddr : integer := 16#200#; iomask : integer := 16#E00#; ramaddr : integer := 16#400#; rammask : integer := 16#C00#; paddr : integer := 0; pmask : integer := 16#fff#; wprot : integer := 0; invclk : integer := 0; fast : integer := 0; romasel : integer := 28; sdrasel : integer := 29; srbanks : integer := 4; ram8 : integer := 0; ram16 : integer := 0; sden : integer := 0; sepbus : integer := 0; sdbits : integer := 32; sdlsb : integer := 2; -- set to 12 for the GE-HPE board oepol : integer := 0; edac : integer := 0; syncrst : integer := 0; pageburst : integer := 0; scantest : integer := 0; writefb : integer := 0; netlist : integer := 0; tech : integer := 0; rahold : integer := 0; wsshift : integer := 0 ); port ( rst : in std_ulogic; clk : in std_ulogic; memi : in memory_in_type; memo : out memory_out_type; ahbsi : in ahb_slv_in_type; ahbso : out ahb_slv_out_type; apbi : in apb_slv_in_type; apbo : out apb_slv_out_type; wpo : in wprot_out_type; sdo : out sdram_out_type ); end component; component ssrctrl generic ( hindex : integer := 0; pindex : integer := 0; romaddr : integer := 0; rommask : integer := 16#ff0#; ramaddr : integer := 16#400#; rammask : integer := 16#ff0#; ioaddr : integer := 16#200#; iomask : integer := 16#ff0#; paddr : integer := 0; pmask : integer := 16#fff#; oepol : integer := 0; bus16 : integer := 0 ); port ( rst : in std_ulogic; clk : in std_ulogic; ahbsi : in ahb_slv_in_type; ahbso : out ahb_slv_out_type; apbi : in apb_slv_in_type; apbo : out apb_slv_out_type; sri : in memory_in_type; sro : out memory_out_type ); end component; component ftsrctrl_v1 generic ( hindex: Integer := 1; romaddr: Integer := 16#000#; rommask: Integer := 16#ff0#; ramaddr: Integer := 16#400#; rammask: Integer := 16#ff0#; ioaddr: Integer := 16#200#; iomask: Integer := 16#ff0#; ramws: Integer := 0; romws: Integer := 0; iows: Integer := 0; rmw: Integer := 1; srbanks: Integer range 1 to 8 := 8; banksz: Integer range 0 to 13 := 0; rombanks: Integer range 1 to 8 := 8; rombanksz: Integer range 0 to 13 := 0; rombankszdef: Integer range 0 to 13 := 6; romasel: Integer range 0 to 28 := 0; pindex: Integer := 0; paddr: Integer := 16#000#; pmask: Integer := 16#fff#; edacen: Integer range 0 to 1 := 1; errcnt: Integer range 0 to 1 := 0; cntbits: Integer range 1 to 8 := 1; wsreg: Integer := 1; oepol: Integer := 0); port ( rst : in std_ulogic; clk : in std_ulogic; ahbsi : in ahb_slv_in_type; ahbso : out ahb_slv_out_type; apbi : in apb_slv_in_type; apbo : out apb_slv_out_type; sri : in memory_in_type; sro : out memory_out_type; sdo : out sdctrl_out_type ); end component; component ftsrctrl8 is generic ( hindex : integer := 0; ramaddr : integer := 16#400#; rammask : integer := 16#ff0#; ioaddr : integer := 16#200#; iomask : integer := 16#ff0#; ramws : integer := 0; iows : integer := 2; srbanks : integer range 1 to 8 := 1; banksz : integer range 0 to 15 := 15; pindex : integer := 0; paddr : integer := 0; pmask : integer := 16#fff#; edacen : integer range 0 to 1 := 1; errcnt : integer range 0 to 1 := 1; cntbits : integer range 1 to 8 := 1; wsreg : integer := 0; oepol : integer := 0 ); port ( rst : in std_ulogic; clk : in std_ulogic; ahbsi : in ahb_slv_in_type; ahbso : out ahb_slv_out_type; apbi : in apb_slv_in_type; apbo : out apb_slv_out_type; sri : in memory_in_type; sro : out memory_out_type ); end component; end;	gpl-2.0	8afada040e4673d6eacc2b645b4c65bf	0.516232	3.476896	false	false	false	false
marco-c/leon-nexys2	grlib-gpl-1.3.4-b4140/designs/leon3-altera-de2-ep2c35/clkgen_de2.vhd	1	3,543	------------------------------------------------------------------------------ -- This file is a part of the GRLIB VHDL IP LIBRARY -- Copyright (C) 2003 - 2008, Gaisler Research -- Copyright (C) 2008 - 2013, Aeroflex Gaisler -- -- This program is free software; you can redistribute it and/or modify -- it under the terms of the GNU General Public License as published by -- the Free Software Foundation; either version 2 of the License, or -- (at your option) any later version. -- -- This program is distributed in the hope that it will be useful, -- but WITHOUT ANY WARRANTY; without even the implied warranty of -- MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the -- GNU General Public License for more details. -- -- You should have received a copy of the GNU General Public License -- along with this program; if not, write to the Free Software -- Foundation, Inc., 59 Temple Place, Suite 330, Boston, MA 02111-1307 USA ------------------------------------------------------------------------------- library ieee; use ieee.std_logic_1164.all; library techmap; use techmap.gencomp.all; library altera_mf; -- pragma translate_off use altera_mf.altpll; -- pragma translate_on entity clkgen_de2 is generic ( clk_mul : integer := 1; clk_div : integer := 1; clk_freq : integer := 25000; clk2xen : integer := 0; sdramen : integer := 0 ); port ( inclk0 : in std_ulogic; c0 : out std_ulogic; c0_2x : out std_ulogic; e0 : out std_ulogic; locked : out std_ulogic ); end; architecture rtl of clkgen_de2 is component altpll generic ( intended_device_family : string := "Stratix" ; operation_mode : string := "NORMAL" ; compensate_clock : string := "CLK0" ; inclk0_input_frequency : positive; width_clock : positive := 6; clk0_multiply_by : positive := 1; clk0_divide_by : positive := 1; clk1_multiply_by : positive := 1; clk1_divide_by : positive := 1; clk2_multiply_by : positive := 1; clk2_divide_by : positive := 1 ); port ( inclk : in std_logic_vector(1 downto 0); clk : out std_logic_vector(width_clock-1 downto 0); locked : out std_logic ); end component; signal clkout : std_logic_vector (5 downto 0); signal inclk : std_logic_vector (1 downto 0); constant clk_period : integer := 1000000000/clk_freq; constant CLK_MUL2X : integer := clk_mul * 2; begin inclk <= '0' & inclk0; c0 <= clkout(0); c0_2x <= clkout(1); sden : if sdramen = 1 generate altpll0 : altpll generic map ( intended_device_family => "Cyclone II", operation_mode => "ZERO_DELAY_BUFFER", compensate_clock => "CLK2", inclk0_input_frequency => clk_period, clk0_multiply_by => clk_mul, clk0_divide_by => clk_div, clk1_multiply_by => 5, clk1_divide_by => 10, clk2_multiply_by => clk_mul, clk2_divide_by => clk_div) port map (inclk => inclk, clk => clkout, locked => locked); e0 <= clkout(2); end generate; nosd : if sdramen = 0 generate altpll0 : altpll generic map ( intended_device_family => "Cyclone II", operation_mode => "NORMAL", inclk0_input_frequency => clk_period, clk0_multiply_by => clk_mul, clk0_divide_by => clk_div, clk1_multiply_by => 5, clk1_divide_by => 10) port map (inclk => inclk, clk => clkout, locked => locked); e0 <= '0'; end generate; end;	gpl-2.0	a4552d87309f27ee42d3a7ae1fbd753c	0.594694	3.675311	false	false	false	false
mistryalok/Zedboard	learning/training/MSD/s05/project_1/project_1.srcs/sources_1/ipshared/xilinx.com/axi_cdma_v4_1/25515467/hdl/src/vhdl/axi_cdma_pkg.vhd	1	12,302	------------------------------------------------------------------------------- -- axi_cdma_pkg ------------------------------------------------------------------------------- -- -- *********************************************************************** -- -- (c) Copyright 2010-2011 Xilinx, Inc. All rights reserved. -- -- This file contains confidential and proprietary information -- of Xilinx, Inc. and is protected under U.S. and -- international copyright and other intellectual property -- laws. -- -- DISCLAIMER -- This disclaimer is not a license and does not grant any -- rights to the materials distributed herewith. Except as -- otherwise provided in a valid license issued to you by -- Xilinx, and to the maximum extent permitted by applicable -- law: (1) THESE MATERIALS ARE MADE AVAILABLE "AS IS" AND -- WITH ALL FAULTS, AND XILINX HEREBY DISCLAIMS ALL WARRANTIES -- AND CONDITIONS, EXPRESS, IMPLIED, OR STATUTORY, INCLUDING -- BUT NOT LIMITED TO WARRANTIES OF MERCHANTABILITY, NON- -- INFRINGEMENT, OR FITNESS FOR ANY PARTICULAR PURPOSE; and -- (2) Xilinx shall not be liable (whether in contract or tort, -- including negligence, or under any other theory of -- liability) for any loss or damage of any kind or nature -- related to, arising under or in connection with these -- materials, including for any direct, or any indirect, -- special, incidental, or consequential loss or damage -- (including loss of data, profits, goodwill, or any type of -- loss or damage suffered as a result of any action brought -- by a third party) even if such damage or loss was -- reasonably foreseeable or Xilinx had been advised of the -- possibility of the same. -- -- CRITICAL APPLICATIONS -- Xilinx products are not designed or intended to be fail- -- safe, or for use in any application requiring fail-safe -- performance, such as life-support or safety devices or -- systems, Class III medical devices, nuclear facilities, -- applications related to the deployment of airbags, or any -- other applications that could lead to death, personal -- injury, or severe property or environmental damage -- (individually and collectively, "Critical -- Applications"). Customer assumes the sole risk and -- liability of any use of Xilinx products in Critical -- Applications, subject only to applicable laws and -- regulations governing limitations on product liability. -- -- THIS COPYRIGHT NOTICE AND DISCLAIMER MUST BE RETAINED AS -- PART OF THIS FILE AT ALL TIMES. -- -- *********************************************************************** -- ------------------------------------------------------------------------------- -- Filename: axi_cdma_pkg.vhd -- Description: This package contains various constants and functions for -- AXI DMA operations. -- -- VHDL-Standard: VHDL'93 ------------------------------------------------------------------------------- ------------------------------------------------------------------------------- library ieee; use ieee.std_logic_1164.all; use ieee.numeric_std.all; library lib_pkg_v1_0; use lib_pkg_v1_0.lib_pkg.clog2; package axi_cdma_pkg is ------------------------------------------------------------------------------- -- Function declarations ------------------------------------------------------------------------------- -- Find minimum required btt width function required_btt_width1 (dwidth, burst_size, btt_width : integer) return integer; ------------------------------------------------------------------------------- -- Constant Declarations ------------------------------------------------------------------------------- ------------------------------------------------------------------------------- -- AXI Responce Values ------------------------------------------------------------------------------- constant OKAY_RESP : std_logic_vector(1 downto 0) := "00"; constant EXOKAY_RESP : std_logic_vector(1 downto 0) := "01"; constant SLVERR_RESP : std_logic_vector(1 downto 0) := "10"; constant DECERR_RESP : std_logic_vector(1 downto 0) := "11"; ------------------------------------------------------------------------------- -- Misc Constants ------------------------------------------------------------------------------- constant NUM_REG_TOTAL : integer := 18; constant NUM_REG_PER_CHANNEL : integer := 6; constant REG_MSB_ADDR_BIT : integer := clog2(NUM_REG_TOTAL)-1; --constant CMD_BASE_WIDTH : integer := 40; constant CMD_BASE_WIDTH : integer := 104; constant BUFFER_LENGTH_WIDTH : integer := 23; -- Constants Used in Desc Updates constant DESC_STS_TYPE : std_logic := '1'; constant DESC_DATA_TYPE : std_logic := '0'; constant DESC_LAST : std_logic := '1'; constant DESC_NOT_LAST : std_logic := '0'; -- Interrupt Coalescing constant ZERO_THRESHOLD : std_logic_vector(7 downto 0) := (others => '0'); constant ONE_THRESHOLD : std_logic_vector(7 downto 0) := "00000001"; constant ZERO_DELAY : std_logic_vector(7 downto 0) := (others => '0'); constant MTBF_STAGES : integer := 4; ------------------------------------------------------------------------------- -- Register Bit Constants ------------------------------------------------------------------------------- -- DMACR constant DMACR_RESERVED0_BIT : integer := 0; constant DMACR_TAILPEN_BIT : integer := 1; constant DMACR_RESET_BIT : integer := 2; constant DMACR_SGMODE_BIT : integer := 3; constant DMACR_KHREAD_BIT : integer := 4; constant DMACR_KHWRITE_BIT : integer := 5; --constant DMACR_RESERVED4_BIT : integer := 4; --constant DMACR_RESERVED5_BIT : integer := 5; constant DMACR_CYCLIC_BIT : integer := 6; constant DMACR_RESERVED7_BIT : integer := 7; constant DMACR_RESERVED8_BIT : integer := 8; constant DMACR_RESERVED9_BIT : integer := 9; constant DMACR_RESERVED10_BIT : integer := 10; constant DMACR_RESERVED11_BIT : integer := 11; constant DMACR_IOC_IRQEN_BIT : integer := 12; constant DMACR_DLY_IRQEN_BIT : integer := 13; constant DMACR_ERR_IRQEN_BIT : integer := 14; constant DMACR_RESERVED15_BIT : integer := 15; constant DMACR_IRQTHRESH_LSB_BIT : integer := 16; constant DMACR_IRQTHRESH_MSB_BIT : integer := 23; constant DMACR_IRQDELAY_LSB_BIT : integer := 24; constant DMACR_IRQDELAY_MSB_BIT : integer := 31; -- DMASR constant DMASR_HALTED_BIT : integer := 0; constant DMASR_IDLE_BIT : integer := 1; constant DMASR_CMPLT_BIT : integer := 2; constant DMASR_ERROR_BIT : integer := 3; constant DMASR_DMAINTERR_BIT : integer := 4; constant DMASR_DMASLVERR_BIT : integer := 5; constant DMASR_DMADECERR_BIT : integer := 6; constant DMASR_RESERVED7_BIT : integer := 7; constant DMASR_SGINTERR_BIT : integer := 8; constant DMASR_SGSLVERR_BIT : integer := 9; constant DMASR_SGDECERR_BIT : integer := 10; constant DMASR_RESERVED11_BIT : integer := 11; constant DMASR_IOCIRQ_BIT : integer := 12; constant DMASR_DLYIRQ_BIT : integer := 13; constant DMASR_ERRIRQ_BIT : integer := 14; constant DMASR_RESERVED15_BIT : integer := 15; constant DMASR_IRQTHRESH_LSB_BIT : integer := 16; constant DMASR_IRQTHRESH_MSB_BIT : integer := 23; constant DMASR_IRQDELAY_LSB_BIT : integer := 24; constant DMASR_IRQDELAY_MSB_BIT : integer := 31; -- CURDESC constant CURDESC_LOWER_MSB_BIT : integer := 31; constant CURDESC_LOWER_LSB_BIT : integer := 6; constant CURDESC_RESERVED_BIT5 : integer := 5; constant CURDESC_RESERVED_BIT4 : integer := 4; constant CURDESC_RESERVED_BIT3 : integer := 3; constant CURDESC_RESERVED_BIT2 : integer := 2; constant CURDESC_RESERVED_BIT1 : integer := 1; constant CURDESC_RESERVED_BIT0 : integer := 0; -- TAILDESC constant TAILDESC_LOWER_MSB_BIT : integer := 31; constant TAILDESC_LOWER_LSB_BIT : integer := 6; constant TAILDESC_RESERVED_BIT5 : integer := 5; constant TAILDESC_RESERVED_BIT4 : integer := 4; constant TAILDESC_RESERVED_BIT3 : integer := 3; constant TAILDESC_RESERVED_BIT2 : integer := 2; constant TAILDESC_RESERVED_BIT1 : integer := 1; constant TAILDESC_RESERVED_BIT0 : integer := 0; -- BTT constant BTT_MSB_BIT : integer := 22; -- DataMover Command / Status Constants constant DATAMOVER_CMDDONE_BIT : integer := 7; constant DATAMOVER_SLVERR_BIT : integer := 6; constant DATAMOVER_DECERR_BIT : integer := 5; constant DATAMOVER_INTERR_BIT : integer := 4; constant DATAMOVER_TAGMSB_BIT : integer := 3; constant DATAMOVER_TAGLSB_BIT : integer := 0; -- Descriptor Control Bits constant DESC_BLENGTH_LSB_BIT : integer := 0; constant DESC_BLENGTH_MSB_BIT : integer := 22; constant DESC_RSVD23_BIT : integer := 23; constant DESC_RSVD24_BIT : integer := 24; constant DESC_RSVD25_BIT : integer := 25; constant DESC_EOF_BIT : integer := 26; constant DESC_SOF_BIT : integer := 27; constant DESC_RSVD28_BIT : integer := 28; constant DESC_RSVD29_BIT : integer := 29; constant DESC_RSVD30_BIT : integer := 30; constant DESC_IOC_BIT : integer := 31; -- Descriptor Status Bits constant DESC_STS_CMPLTD_BIT : integer := 31; constant DESC_STS_DECERR_BIT : integer := 30; constant DESC_STS_SLVERR_BIT : integer := 29; constant DESC_STS_INTERR_BIT : integer := 28; constant DESC_STS_RXSOF_BIT : integer := 27; constant DESC_STS_RXEOF_BIT : integer := 26; constant DESC_STS_RSVD25_BIT : integer := 25; constant DESC_STS_RSVD24_BIT : integer := 24; constant DESC_STS_RSVD23_BIT : integer := 23; constant DESC_STS_XFRDBYTS_MSB_BIT : integer := 22; constant DESC_STS_XFRDBYTS_LSB_BIT : integer := 0; -- DataMover Command / Status Constants constant DATAMOVER_STS_CMDDONE_BIT : integer := 7; constant DATAMOVER_STS_SLVERR_BIT : integer := 6; constant DATAMOVER_STS_DECERR_BIT : integer := 5; constant DATAMOVER_STS_INTERR_BIT : integer := 4; constant DATAMOVER_STS_TAGMSB_BIT : integer := 3; constant DATAMOVER_STS_TAGLSB_BIT : integer := 0; constant DATAMOVER_STS_TAGEOF_BIT : integer := 1; constant DATAMOVER_STS_TLAST_BIT : integer := 31; constant DATAMOVER_CMD_BTTLSB_BIT : integer := 0; constant DATAMOVER_CMD_BTTMSB_BIT : integer := 22; constant DATAMOVER_CMD_TYPE_BIT : integer := 23; constant DATAMOVER_CMD_DSALSB_BIT : integer := 24; constant DATAMOVER_CMD_DSAMSB_BIT : integer := 29; constant DATAMOVER_CMD_EOF_BIT : integer := 30; constant DATAMOVER_CMD_DRR_BIT : integer := 31; constant DATAMOVER_CMD_ADDRLSB_BIT : integer := 32; -- Note: Bit offset require adding ADDR WIDTH to get to actual bit index constant DATAMOVER_CMD_ADDRMSB_BOFST: integer := 31; constant DATAMOVER_CMD_TAGLSB_BOFST : integer := 32; constant DATAMOVER_CMD_TAGMSB_BOFST : integer := 35; constant DATAMOVER_CMD_RSVLSB_BOFST : integer := 36; constant DATAMOVER_CMD_RSVMSB_BOFST : integer := 39; end axi_cdma_pkg; ------------------------------------------------------------------------------- -- PACKAGE BODY ------------------------------------------------------------------------------- package body axi_cdma_pkg is ------------------------------------------------------------------------------- -- Function to determine minimum bits required for BTT_SIZE field ------------------------------------------------------------------------------- function required_btt_width1 ( dwidth, burst_size, btt_width : integer) return integer is variable min_width : integer; begin min_width := clog2((dwidth/8)*burst_size)+1; if(min_width > btt_width)then return min_width; else return btt_width; end if; end function required_btt_width1; end package body axi_cdma_pkg;	gpl-3.0	908a75919102bf41140864f6033b3401	0.569257	4.379494	false	false	false	false
marco-c/leon-nexys2	grlib-gpl-1.3.4-b4140/designs/leon3-digilent-xc3s1000/leon3mp.vhd	1	16,901	----------------------------------------------------------------------------- -- LEON3 Demonstration design -- Copyright (C) 2004 Jiri Gaisler, Gaisler Research ------------------------------------------------------------------------------ -- This file is a part of the GRLIB VHDL IP LIBRARY -- Copyright (C) 2003 - 2008, Gaisler Research -- Copyright (C) 2008 - 2013, Aeroflex Gaisler -- -- This program is free software; you can redistribute it and/or modify -- it under the terms of the GNU General Public License as published by -- the Free Software Foundation; either version 2 of the License, or -- (at your option) any later version. -- -- This program is distributed in the hope that it will be useful, -- but WITHOUT ANY WARRANTY; without even the implied warranty of -- MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the -- GNU General Public License for more details. -- -- You should have received a copy of the GNU General Public License -- along with this program; if not, write to the Free Software -- Foundation, Inc., 59 Temple Place, Suite 330, Boston, MA 02111-1307 USA ------------------------------------------------------------------------------ library ieee; use ieee.std_logic_1164.all; library grlib, techmap; use grlib.amba.all; use grlib.stdlib.all; use techmap.gencomp.all; library gaisler; use gaisler.memctrl.all; use gaisler.leon3.all; use gaisler.uart.all; use gaisler.misc.all; use gaisler.jtag.all; -- pragma translate_off use gaisler.sim.all; -- pragma translate_on library esa; use esa.memoryctrl.all; use work.config.all; entity leon3mp is generic ( fabtech : integer := CFG_FABTECH; memtech : integer := CFG_MEMTECH; padtech : integer := CFG_PADTECH; clktech : integer := CFG_CLKTECH; disas : integer := CFG_DISAS; -- Enable disassembly to console dbguart : integer := CFG_DUART; -- Print UART on console pclow : integer := CFG_PCLOW ); port ( reset : in std_ulogic; clk : in std_ulogic; -- 50 MHz main clock error : out std_ulogic; address : out std_logic_vector(19 downto 2); data : inout std_logic_vector(31 downto 0); ramsn : out std_logic_vector (1 downto 0); mben : out std_logic_vector (3 downto 0); oen : out std_ulogic; writen : out std_ulogic; dsubre : in std_ulogic; dsuact : out std_ulogic; txd1 : out std_ulogic; -- UART1 tx data rxd1 : in std_ulogic; -- UART1 rx data pio : inout std_logic_vector(17 downto 0); -- I/O port -- switch : in std_logic_vector(7 downto 0); -- switches -- button : in std_logic_vector(2 downto 0); -- buttons ps2clk : inout std_logic; ps2data : inout std_logic; vid_hsync : out std_ulogic; vid_vsync : out std_ulogic; vid_r : out std_logic; vid_g : out std_logic; vid_b : out std_logic ); end; architecture rtl of leon3mp is constant blength : integer := 12; constant fifodepth : integer := 8; constant maxahbm : integer := CFG_NCPU+ CFG_AHB_JTAG+CFG_SVGA_ENABLE; signal vcc, gnd : std_logic_vector(4 downto 0); signal memi : memory_in_type; signal memo : memory_out_type; signal wpo : wprot_out_type; signal sdi : sdctrl_in_type; signal sdo : sdram_out_type; signal apbi : apb_slv_in_type; signal apbo : apb_slv_out_vector := (others => apb_none); signal ahbsi : ahb_slv_in_type; signal ahbso : ahb_slv_out_vector := (others => ahbs_none); signal ahbmi : ahb_mst_in_type; signal ahbmo : ahb_mst_out_vector := (others => ahbm_none); signal clkm, rstn, rstraw, nerror : std_ulogic; signal cgi : clkgen_in_type; signal cgo : clkgen_out_type; signal u1i, u2i, dui : uart_in_type; signal u1o, u2o, duo : uart_out_type; signal irqi : irq_in_vector(0 to CFG_NCPU-1); signal irqo : irq_out_vector(0 to CFG_NCPU-1); signal dbgi : l3_debug_in_vector(0 to CFG_NCPU-1); signal dbgo : l3_debug_out_vector(0 to CFG_NCPU-1); signal dsui : dsu_in_type; signal dsuo : dsu_out_type; signal gpti : gptimer_in_type; signal gpioi : gpio_in_type; signal gpioo : gpio_out_type; signal lclk, rst : std_ulogic; signal tck, tckn, tms, tdi, tdo : std_ulogic; signal kbdi : ps2_in_type; signal kbdo : ps2_out_type; signal vgao : apbvga_out_type; signal clkval : std_logic_vector(1 downto 0); constant BOARD_FREQ : integer := 50000; -- input frequency in KHz constant CPU_FREQ : integer := BOARD_FREQ * CFG_CLKMUL / CFG_CLKDIV; -- cpu frequency in KHz constant IOAEN : integer := 0; signal stati : ahbstat_in_type; signal dac_clk, clk1x, vid_clock, video_clk, clkvga : std_logic; -- signals to vga_clkgen. signal clk_sel : std_logic_vector(1 downto 0); attribute keep : boolean; attribute syn_keep : boolean; attribute syn_preserve : boolean; attribute syn_keep of video_clk : signal is true; attribute syn_preserve of video_clk : signal is true; attribute keep of video_clk : signal is true; begin ---------------------------------------------------------------------- --- Reset and Clock generation ------------------------------------- ---------------------------------------------------------------------- vcc <= (others => '1'); gnd <= (others => '0'); cgi.pllctrl <= "00"; cgi.pllrst <= rstraw; clk_pad : clkpad generic map (tech => padtech) port map (clk, lclk); clkgen0 : clkgen -- clock generator generic map (clktech, CFG_CLKMUL, CFG_CLKDIV, CFG_MCTRL_SDEN, CFG_CLK_NOFB, 0, 0, 0, BOARD_FREQ) port map (lclk, lclk, clkm, open, open, open, open, cgi, cgo, open, clk1x); resetn_pad : inpad generic map (tech => padtech) port map (reset, rst); rst0 : rstgen -- reset generator generic map (acthigh => 1) port map (rst, clkm, cgo.clklock, rstn, rstraw); ---------------------------------------------------------------------- --- AHB CONTROLLER -------------------------------------------------- ---------------------------------------------------------------------- ahb0 : ahbctrl -- AHB arbiter/multiplexer generic map (defmast => CFG_DEFMST, split => CFG_SPLIT, rrobin => CFG_RROBIN, ioaddr => CFG_AHBIO, ioen => IOAEN, nahbm => maxahbm, nahbs => 8) port map (rstn, clkm, ahbmi, ahbmo, ahbsi, ahbso); ---------------------------------------------------------------------- --- LEON3 processor and DSU ----------------------------------------- ---------------------------------------------------------------------- l3 : if CFG_LEON3 = 1 generate cpu : for i in 0 to CFG_NCPU-1 generate u0 : leon3s -- LEON3 processor generic map (i, fabtech, memtech, CFG_NWIN, CFG_DSU, CFG_FPU, CFG_V8, 0, CFG_MAC, pclow, CFG_NOTAG, CFG_NWP, CFG_ICEN, CFG_IREPL, CFG_ISETS, CFG_ILINE, CFG_ISETSZ, CFG_ILOCK, CFG_DCEN, CFG_DREPL, CFG_DSETS, CFG_DLINE, CFG_DSETSZ, CFG_DLOCK, CFG_DSNOOP, CFG_ILRAMEN, CFG_ILRAMSZ, CFG_ILRAMADDR, CFG_DLRAMEN, CFG_DLRAMSZ, CFG_DLRAMADDR, CFG_MMUEN, CFG_ITLBNUM, CFG_DTLBNUM, CFG_TLB_TYPE, CFG_TLB_REP, CFG_LDDEL, disas, CFG_ITBSZ, CFG_PWD, CFG_SVT, CFG_RSTADDR, CFG_NCPU-1) port map (clkm, rstn, ahbmi, ahbmo(i), ahbsi, ahbso, irqi(i), irqo(i), dbgi(i), dbgo(i)); end generate; nerror <= not dbgo(0).error; error_pad : outpad generic map (tech => padtech) port map (error, nerror); dsugen : if CFG_DSU = 1 generate dsu0 : dsu3 -- LEON3 Debug Support Unit generic map (hindex => 2, haddr => 16#900#, hmask => 16#F00#, ncpu => CFG_NCPU, tbits => 30, tech => memtech, irq => 0, kbytes => CFG_ATBSZ) port map (rstn, clkm, ahbmi, ahbsi, ahbso(2), dbgo, dbgi, dsui, dsuo); dsui.enable <= '1'; dsubre_pad : inpad generic map (tech => padtech) port map (dsubre, dsui.break); dsuact_pad : outpad generic map (tech => padtech) port map (dsuact, dsuo.active); end generate; end generate; nodsu : if CFG_DSU = 0 generate dsuo.tstop <= '0'; dsuo.active <= '0'; end generate; -- dcomgen : if CFG_AHB_UART = 1 generate -- dcom0: ahbuart -- Debug UART -- generic map (hindex => CFG_NCPU, pindex => 7, paddr => 7) -- port map (rstn, clkm, dui, duo, apbi, apbo(7), ahbmi, ahbmo(CFG_NCPU)); -- dsurx_pad : inpad generic map (tech => padtech) port map (rxd2, dui.rxd); -- dsutx_pad : outpad generic map (tech => padtech) port map (txd2, duo.txd); -- end generate; -- nouah : if CFG_AHB_UART = 0 generate apbo(7) <= apb_none; end generate; ahbjtaggen0 :if CFG_AHB_JTAG = 1 generate ahbjtag0 : ahbjtag generic map(tech => fabtech, hindex => CFG_NCPU) port map(rstn, clkm, tck, tms, tdi, tdo, ahbmi, ahbmo(CFG_NCPU), open, open, open, open, open, open, open, gnd(0)); end generate; ---------------------------------------------------------------------- --- Memory controllers ---------------------------------------------- ---------------------------------------------------------------------- memi.writen <= '1'; memi.wrn <= "1111"; memi.bwidth <= "00"; mctrl0 : mctrl generic map (hindex => 0, pindex => 0, rommask => 16#000#, iomask => 16#000#, paddr => 0, srbanks => 1, ram8 => CFG_MCTRL_RAM8BIT, ram16 => CFG_MCTRL_RAM16BIT, sden => CFG_MCTRL_SDEN, invclk => CFG_CLK_NOFB, sepbus => CFG_MCTRL_SEPBUS) port map (rstn, clkm, memi, memo, ahbsi, ahbso(0), apbi, apbo(0), wpo, sdo); addr_pad : outpadv generic map (width => 18, tech => padtech) port map (address, memo.address(19 downto 2)); ramsa_pad : outpad generic map (tech => padtech) port map (ramsn(0), memo.ramsn(0)); ramsb_pad : outpad generic map (tech => padtech) port map (ramsn(1), memo.ramsn(0)); oen_pad : outpad generic map (tech => padtech) port map (oen, memo.oen); wri_pad : outpad generic map (tech => padtech) port map (writen, memo.writen); mben_pads : outpadv generic map (tech => padtech, width => 4) port map (mben, memo.mben); data_pads : iopadvv generic map (tech => padtech, width => 32) port map (data, memo.data(31 downto 0), memo.vbdrive(31 downto 0), memi.data(31 downto 0)); ---------------------------------------------------------------------- --- APB Bridge and various periherals ------------------------------- ---------------------------------------------------------------------- bpromgen : if CFG_AHBROMEN /= 0 generate brom : entity work.ahbrom generic map (hindex => 6, haddr => CFG_AHBRODDR, pipe => CFG_AHBROPIP) port map ( rstn, clkm, ahbsi, ahbso(6)); end generate; ---------------------------------------------------------------------- --- APB Bridge and various periherals ------------------------------- ---------------------------------------------------------------------- apb0 : apbctrl -- AHB/APB bridge generic map (hindex => 1, haddr => CFG_APBADDR, nslaves => 16) port map (rstn, clkm, ahbsi, ahbso(1), apbi, apbo ); ua1 : if CFG_UART1_ENABLE /= 0 generate uart1 : apbuart -- UART 1 generic map (pindex => 1, paddr => 1, pirq => 2, console => dbguart, fifosize => CFG_UART1_FIFO) port map (rstn, clkm, apbi, apbo(1), u1i, u1o); u1i.extclk <= '0'; rxd1_pad : inpad generic map (tech => padtech) port map (rxd1, u1i.rxd); txd1_pad : outpad generic map (tech => padtech) port map (txd1, u1o.txd); end generate; noua0 : if CFG_UART1_ENABLE = 0 generate apbo(1) <= apb_none; end generate; irqctrl : if CFG_IRQ3_ENABLE /= 0 generate irqctrl0 : irqmp -- interrupt controller generic map (pindex => 2, paddr => 2, ncpu => CFG_NCPU) port map (rstn, clkm, apbi, apbo(2), irqo, irqi); end generate; irq3 : if CFG_IRQ3_ENABLE = 0 generate x : for i in 0 to CFG_NCPU-1 generate irqi(i).irl <= "0000"; end generate; apbo(2) <= apb_none; end generate; gpt : if CFG_GPT_ENABLE /= 0 generate timer0 : gptimer -- timer unit generic map (pindex => 3, paddr => 3, pirq => CFG_GPT_IRQ, sepirq => CFG_GPT_SEPIRQ, sbits => CFG_GPT_SW, ntimers => CFG_GPT_NTIM, nbits => CFG_GPT_TW) port map (rstn, clkm, apbi, apbo(3), gpti, open); gpti.dhalt <= dsuo.tstop; gpti.extclk <= '0'; end generate; nogpt : if CFG_GPT_ENABLE = 0 generate apbo(3) <= apb_none; end generate; kbd : if CFG_KBD_ENABLE /= 0 generate ps20 : apbps2 generic map(pindex => 5, paddr => 5, pirq => 5) port map(rstn, clkm, apbi, apbo(5), kbdi, kbdo); end generate; nokbd : if CFG_KBD_ENABLE = 0 generate apbo(5) <= apb_none; kbdo <= ps2o_none; end generate; kbdclk_pad : iopad generic map (tech => padtech) port map (ps2clk,kbdo.ps2_clk_o, kbdo.ps2_clk_oe, kbdi.ps2_clk_i); kbdata_pad : iopad generic map (tech => padtech) port map (ps2data, kbdo.ps2_data_o, kbdo.ps2_data_oe, kbdi.ps2_data_i); clkdiv : process(clk1x, rstn) begin if rstn = '0' then clkval <= "00"; elsif rising_edge(clk1x) then clkval <= clkval + 1; end if; end process; vga : if CFG_VGA_ENABLE /= 0 generate vga0 : apbvga generic map(memtech => memtech, pindex => 6, paddr => 6) port map(rstn, clkm, video_clk, apbi, apbo(6), vgao); video_clock_pad : outpad generic map ( tech => padtech) port map (vid_clock, dac_clk); dac_clk <= not video_clk; b1 : techbuf generic map (2, virtex2) port map (clkval(0), video_clk); end generate; svga : if CFG_SVGA_ENABLE /= 0 generate clkvga <= clkval(1) when clk_sel = "00" else clkval(0) when clk_sel = "01" else clkm; b1 : techbuf generic map (2, virtex2) port map (clkvga, video_clk); svga0 : svgactrl generic map(memtech => memtech, pindex => 6, paddr => 6, hindex => CFG_NCPU+CFG_AHB_JTAG, clk0 => 40000, clk1 => 20000, clk2 => 25000) port map(rstn, clkm, video_clk, apbi, apbo(6), vgao, ahbmi, ahbmo(CFG_NCPU+CFG_AHB_JTAG), clk_sel); dac_clk <= not video_clk; video_clock_pad : outpad generic map ( tech => padtech) port map (vid_clock, dac_clk); end generate; novga : if (CFG_VGA_ENABLE = 0 and CFG_SVGA_ENABLE = 0) generate apbo(6) <= apb_none; vgao <= vgao_none; end generate; vert_sync_pad : outpad generic map (tech => padtech) port map (vid_vsync, vgao.vsync); horiz_sync_pad : outpad generic map (tech => padtech) port map (vid_hsync, vgao.hsync); video_out_r_pad : outpad generic map (tech => padtech) port map (vid_r, vgao.video_out_r(7)); video_out_g_pad : outpad generic map (tech => padtech) port map (vid_g, vgao.video_out_g(7)); video_out_b_pad : outpad generic map (tech => padtech) port map (vid_b, vgao.video_out_b(7)); gpio0 : if CFG_GRGPIO_ENABLE /= 0 generate -- GPIO unit grgpio0: grgpio generic map(pindex => 8, paddr => 8, imask => CFG_GRGPIO_IMASK, nbits => 18) port map(rst => rstn, clk => clkm, apbi => apbi, apbo => apbo(8), gpioi => gpioi, gpioo => gpioo); pio_pads : iopadvv generic map (width => 18, tech => padtech) port map (pio, gpioo.dout(17 downto 0), gpioo.oen(17 downto 0), gpioi.din(17 downto 0)); end generate; ----------------------------------------------------------------------- --- AHB RAM ---------------------------------------------------------- ----------------------------------------------------------------------- ocram : if CFG_AHBRAMEN = 1 generate ahbram0 : ahbram generic map (hindex => 7, haddr => CFG_AHBRADDR, tech => CFG_MEMTECH, kbytes => CFG_AHBRSZ, pipe => CFG_AHBRPIPE) port map ( rstn, clkm, ahbsi, ahbso(7)); end generate; ----------------------------------------------------------------------- --- Drive unused bus elements --------------------------------------- ----------------------------------------------------------------------- -- nam1 : for i in (CFG_NCPU+FG_AHB_UART+CFG_GRETH+CFG_AHB_JTAG) to NAHBMST-1 generate -- ahbmo(i) <= ahbm_none; -- end generate; -- nap0 : for i in 11 to NAPBSLV-1 generate apbo(i) <= apb_none; end generate; -- nah0 : for i in 8 to NAHBSLV-1 generate ahbso(i) <= ahbs_none; end generate; ----------------------------------------------------------------------- --- Test report module ---------------------------------------------- ----------------------------------------------------------------------- -- pragma translate_off test0 : ahbrep generic map (hindex => 4, haddr => 16#200#) port map (rstn, clkm, ahbsi, ahbso(4)); -- pragma translate_on ----------------------------------------------------------------------- --- Boot message ---------------------------------------------------- ----------------------------------------------------------------------- -- pragma translate_off x : report_design generic map ( msg1 => "LEON3 Digilent XC3S1000 Demonstration design", fabtech => tech_table(fabtech), memtech => tech_table(memtech), mdel => 1 ); -- pragma translate_on end;	gpl-2.0	5836097d76ace44c6de57a8e42d6c0ef	0.558251	3.663776	false	false	false	false
marco-c/leon-nexys2	grlib-gpl-1.3.4-b4140/designs/leon3-xilinx-ml50x/grlib_config.vhd	1	2,564	------------------------------------------------------------------------------ -- This file is a part of the GRLIB VHDL IP LIBRARY -- Copyright (C) 2003 - 2008, Gaisler Research -- Copyright (C) 2008 - 2013, Aeroflex Gaisler -- -- This program is free software; you can redistribute it and/or modify -- it under the terms of the GNU General Public License as published by -- the Free Software Foundation; either version 2 of the License, or -- (at your option) any later version. -- -- This program is distributed in the hope that it will be useful, -- but WITHOUT ANY WARRANTY; without even the implied warranty of -- MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the -- GNU General Public License for more details. -- -- You should have received a copy of the GNU General Public License -- along with this program; if not, write to the Free Software -- Foundation, Inc., 59 Temple Place, Suite 330, Boston, MA 02111-1307 USA ----------------------------------------------------------------------------- -- Package: config -- File: config.vhd -- Author: Jiri Gaisler, Gaisler Research -- Description: GRLIB Global configuration package. Can be overriden -- by local config packages in template designs. ------------------------------------------------------------------------------ library ieee; use ieee.std_logic_1164.all; library grlib; use grlib.config_types.all; package config is -- AHBDW - AHB data with -- -- Valid values are 32, 64, 128 and 256 -- -- The value here sets the width of the AMBA AHB data vectors for all -- cores in the library. -- constant CFG_AHBDW : integer := 64; -- CORE_ACDM - Enable AMBA Compliant Data Muxing in cores -- -- Valid values are 0 and 1 -- -- 0: All GRLIB cores that use the ahbread* programs defined in the AMBA package -- will read their data from the low part of the AHB data vector. -- -- 1: All GRLIB cores that use the ahbread* programs defined in the AMBA package -- will select valid data, as defined in the AMBA AHB standard, from the -- AHB data vectors based on the address input. If a core uses a function -- that does not have the address input, a failure will be asserted. -- constant CFG_AHB_ACDM : integer := 0; -- GRLIB_CONFIG_ARRAY - Array of configuration values -- -- The length of this array and the meaning of different positions is defined -- in the grlib.config_types package. constant GRLIB_CONFIG_ARRAY : grlib_config_array_type := ( grlib_debug_level => 0, grlib_debug_mask => 0, grlib_techmap_strict_ram => 0, others => 0); end;	gpl-2.0	e8136af418a0f6882007fc933bf21ebd	0.654446	4.175896	false	true	false	false
marco-c/leon-nexys2	grlib-gpl-1.3.4-b4140/lib/gaisler/leon3/leon3.vhd	1	35,770	------------------------------------------------------------------------------ -- This file is a part of the GRLIB VHDL IP LIBRARY -- Copyright (C) 2003 - 2008, Gaisler Research -- Copyright (C) 2008 - 2013, Aeroflex Gaisler -- -- This program is free software; you can redistribute it and/or modify -- it under the terms of the GNU General Public License as published by -- the Free Software Foundation; either version 2 of the License, or -- (at your option) any later version. -- -- This program is distributed in the hope that it will be useful, -- but WITHOUT ANY WARRANTY; without even the implied warranty of -- MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the -- GNU General Public License for more details. -- -- You should have received a copy of the GNU General Public License -- along with this program; if not, write to the Free Software -- Foundation, Inc., 59 Temple Place, Suite 330, Boston, MA 02111-1307 USA ----------------------------------------------------------------------------- -- Package: leon3 -- File: leon3.vhd -- Author: Jiri Gaisler, Gaisler Research -- Description: LEON3 types and components ------------------------------------------------------------------------------ library ieee; use ieee.std_logic_1164.all; library grlib; use grlib.amba.all; library techmap; use techmap.gencomp.all; package leon3 is constant LEON3_VERSION : integer := 3; type l3_irq_in_type is record irl : std_logic_vector(3 downto 0); rst : std_ulogic; run : std_ulogic; rstvec : std_logic_vector(31 downto 12); iact : std_ulogic; index : std_logic_vector(3 downto 0); hrdrst : std_ulogic; end record; type l3_irq_out_type is record intack : std_ulogic; irl : std_logic_vector(3 downto 0); pwd : std_ulogic; fpen : std_ulogic; idle : std_ulogic; end record; type l3_debug_in_type is record dsuen : std_ulogic; -- DSU enable denable : std_ulogic; -- diagnostic register access enable dbreak : std_ulogic; -- debug break-in step : std_ulogic; -- single step halt : std_ulogic; -- halt processor reset : std_ulogic; -- reset processor dwrite : std_ulogic; -- read/write daddr : std_logic_vector(23 downto 2); -- diagnostic address ddata : std_logic_vector(31 downto 0); -- diagnostic data btrapa : std_ulogic; -- break on IU trap btrape : std_ulogic; -- break on IU trap berror : std_ulogic; -- break on IU error mode bwatch : std_ulogic; -- break on IU watchpoint bsoft : std_ulogic; -- break on software breakpoint (TA 1) tenable : std_ulogic; timer : std_logic_vector(30 downto 0); -- end record; constant dbgi_none : l3_debug_in_type := ('0', '0', '0', '0', '0', '0', '0', (others => '0'), (others => '0'), '0', '0', '0', '0', '0', '0', (others => '0')); constant l3_dbgi_none : l3_debug_in_type := dbgi_none; type l3_cstat_type is record cmiss : std_ulogic; -- cache miss tmiss : std_ulogic; -- TLB miss chold : std_ulogic; -- cache hold mhold : std_ulogic; -- cache mmu hold end record; constant cstat_none : l3_cstat_type := ('0', '0', '0', '0'); type l3_debug_out_type is record data : std_logic_vector(31 downto 0); crdy : std_ulogic; dsu : std_ulogic; dsumode : std_ulogic; error : std_ulogic; halt : std_ulogic; pwd : std_ulogic; idle : std_ulogic; ipend : std_ulogic; icnt : std_ulogic; fcnt : std_ulogic; optype : std_logic_vector(5 downto 0); -- instruction type bpmiss : std_ulogic; -- branch predict miss istat : l3_cstat_type; dstat : l3_cstat_type; wbhold : std_ulogic; -- write buffer hold su : std_ulogic; -- supervisor state end record; type l3_debug_in_vector is array (natural range <>) of l3_debug_in_type; type l3_debug_out_vector is array (natural range <>) of l3_debug_out_type; constant dbgo_none : l3_debug_out_type := (X"00000000", '0', '0', '0', '0', '0', '0', '0', '0', '0', '0', "000000", '0', cstat_none, cstat_none, '0', '0'); constant l3_dbgo_none : l3_debug_out_type := dbgo_none; type tracebuf_in_type is record addr : std_logic_vector(11 downto 0); data : std_logic_vector(127 downto 0); enable : std_logic; write : std_logic_vector(3 downto 0); diag : std_logic_vector(3 downto 0); end record; type tracebuf_out_type is record data : std_logic_vector(127 downto 0); end record; component tbufmem generic ( tech : integer := 0; tbuf : integer := 0; testen: integer := 0); port ( clk : in std_ulogic; di : in tracebuf_in_type; do : out tracebuf_out_type); end component; component leon3s generic ( hindex : integer := 0; fabtech : integer range 0 to NTECH := DEFFABTECH; memtech : integer range 0 to NTECH := DEFMEMTECH; nwindows : integer range 2 to 32 := 8; dsu : integer range 0 to 1 := 0; fpu : integer range 0 to 31 := 0; v8 : integer range 0 to 63 := 0; cp : integer range 0 to 1 := 0; mac : integer range 0 to 1 := 0; pclow : integer range 0 to 2 := 2; notag : integer range 0 to 1 := 0; nwp : integer range 0 to 4 := 0; icen : integer range 0 to 1 := 0; irepl : integer range 0 to 3 := 2; isets : integer range 1 to 4 := 1; ilinesize : integer range 4 to 8 := 4; isetsize : integer range 1 to 256 := 1; isetlock : integer range 0 to 1 := 0; dcen : integer range 0 to 1 := 0; drepl : integer range 0 to 3 := 2; dsets : integer range 1 to 4 := 1; dlinesize : integer range 4 to 8 := 4; dsetsize : integer range 1 to 256 := 1; dsetlock : integer range 0 to 1 := 0; dsnoop : integer range 0 to 6 := 0; ilram : integer range 0 to 1 := 0; ilramsize : integer range 1 to 512 := 1; ilramstart: integer range 0 to 255 := 16#8e#; dlram : integer range 0 to 1 := 0; dlramsize : integer range 1 to 512 := 1; dlramstart: integer range 0 to 255 := 16#8f#; mmuen : integer range 0 to 1 := 0; itlbnum : integer range 2 to 64 := 8; dtlbnum : integer range 2 to 64 := 8; tlb_type : integer range 0 to 3 := 1; tlb_rep : integer range 0 to 1 := 0; lddel : integer range 1 to 2 := 2; disas : integer range 0 to 2 := 0; tbuf : integer range 0 to 64 := 0; pwd : integer range 0 to 2 := 2; svt : integer range 0 to 1 := 1; rstaddr : integer := 16#00000#; smp : integer range 0 to 15 := 0; cached : integer := 0; scantest : integer := 0; mmupgsz : integer range 0 to 5 := 0; bp : integer := 1 ); port ( clk : in std_ulogic; rstn : in std_ulogic; ahbi : in ahb_mst_in_type; ahbo : out ahb_mst_out_type; ahbsi : in ahb_slv_in_type; ahbso : in ahb_slv_out_vector; irqi : in l3_irq_in_type; irqo : out l3_irq_out_type; dbgi : in l3_debug_in_type; dbgo : out l3_debug_out_type ); end component; component leon3cg generic ( hindex : integer := 0; fabtech : integer range 0 to NTECH := DEFFABTECH; memtech : integer range 0 to NTECH := DEFMEMTECH; nwindows : integer range 2 to 32 := 8; dsu : integer range 0 to 1 := 0; fpu : integer range 0 to 31 := 0; v8 : integer range 0 to 63 := 0; cp : integer range 0 to 1 := 0; mac : integer range 0 to 1 := 0; pclow : integer range 0 to 2 := 2; notag : integer range 0 to 1 := 0; nwp : integer range 0 to 4 := 0; icen : integer range 0 to 1 := 0; irepl : integer range 0 to 3 := 2; isets : integer range 1 to 4 := 1; ilinesize : integer range 4 to 8 := 4; isetsize : integer range 1 to 256 := 1; isetlock : integer range 0 to 1 := 0; dcen : integer range 0 to 1 := 0; drepl : integer range 0 to 3 := 2; dsets : integer range 1 to 4 := 1; dlinesize : integer range 4 to 8 := 4; dsetsize : integer range 1 to 256 := 1; dsetlock : integer range 0 to 1 := 0; dsnoop : integer range 0 to 6 := 0; ilram : integer range 0 to 1 := 0; ilramsize : integer range 1 to 512 := 1; ilramstart: integer range 0 to 255 := 16#8e#; dlram : integer range 0 to 1 := 0; dlramsize : integer range 1 to 512 := 1; dlramstart: integer range 0 to 255 := 16#8f#; mmuen : integer range 0 to 1 := 0; itlbnum : integer range 2 to 64 := 8; dtlbnum : integer range 2 to 64 := 8; tlb_type : integer range 0 to 3 := 1; tlb_rep : integer range 0 to 1 := 0; lddel : integer range 1 to 2 := 2; disas : integer range 0 to 2 := 0; tbuf : integer range 0 to 64 := 0; pwd : integer range 0 to 2 := 2; svt : integer range 0 to 1 := 1; rstaddr : integer := 16#00000#; smp : integer range 0 to 15 := 0; cached : integer := 0; scantest : integer := 0; mmupgsz : integer range 0 to 5 := 0; bp : integer := 1 ); port ( clk : in std_ulogic; rstn : in std_ulogic; ahbi : in ahb_mst_in_type; ahbo : out ahb_mst_out_type; ahbsi : in ahb_slv_in_type; ahbso : in ahb_slv_out_vector; irqi : in l3_irq_in_type; irqo : out l3_irq_out_type; dbgi : in l3_debug_in_type; dbgo : out l3_debug_out_type; gclk : in std_ulogic ); end component; component leon3ft generic ( hindex : integer := 0; fabtech : integer range 0 to NTECH := DEFFABTECH; memtech : integer range 0 to NTECH := DEFMEMTECH; nwindows : integer range 2 to 32 := 8; dsu : integer range 0 to 1 := 0; fpu : integer range 0 to 31 := 0; v8 : integer range 0 to 63 := 0; cp : integer range 0 to 1 := 0; mac : integer range 0 to 1 := 0; pclow : integer range 0 to 2 := 2; notag : integer range 0 to 1 := 0; nwp : integer range 0 to 4 := 0; icen : integer range 0 to 1 := 0; irepl : integer range 0 to 3 := 2; isets : integer range 1 to 4 := 1; ilinesize : integer range 4 to 8 := 4; isetsize : integer range 1 to 256 := 1; isetlock : integer range 0 to 1 := 0; dcen : integer range 0 to 1 := 0; drepl : integer range 0 to 3 := 2; dsets : integer range 1 to 4 := 1; dlinesize : integer range 4 to 8 := 4; dsetsize : integer range 1 to 256 := 1; dsetlock : integer range 0 to 1 := 0; dsnoop : integer range 0 to 6 := 0; ilram : integer range 0 to 1 := 0; ilramsize : integer range 1 to 512 := 1; ilramstart: integer range 0 to 255 := 16#8e#; dlram : integer range 0 to 1 := 0; dlramsize : integer range 1 to 512 := 1; dlramstart: integer range 0 to 255 := 16#8f#; mmuen : integer range 0 to 1 := 0; itlbnum : integer range 2 to 64 := 8; dtlbnum : integer range 2 to 64 := 8; tlb_type : integer range 0 to 3 := 1; tlb_rep : integer range 0 to 1 := 0; lddel : integer range 1 to 2 := 2; disas : integer range 0 to 2 := 0; tbuf : integer range 0 to 64 := 0; pwd : integer range 0 to 2 := 2; svt : integer range 0 to 1 := 1; rstaddr : integer := 16#00000#; smp : integer range 0 to 15 := 0; -- support SMP systems iuft : integer range 0 to 4 := 0; fpft : integer range 0 to 4 := 0; cmft : integer range 0 to 1 := 0; iuinj : integer := 0; ceinj : integer range 0 to 3 := 0; cached : integer := 0; -- cacheability table netlist : integer := 0; -- use netlist scantest : integer := 0; -- enable scan test support mmupgsz : integer range 0 to 5 := 0; bp : integer := 1 ); port ( clk : in std_ulogic; rstn : in std_ulogic; ahbi : in ahb_mst_in_type; ahbo : out ahb_mst_out_type; ahbsi : in ahb_slv_in_type; ahbso : in ahb_slv_out_vector; irqi : in l3_irq_in_type; irqo : out l3_irq_out_type; dbgi : in l3_debug_in_type; dbgo : out l3_debug_out_type; gclk : in std_ulogic ); end component; type grfpu_in_type is record start : std_logic; nonstd : std_logic; flop : std_logic_vector(8 downto 0); op1 : std_logic_vector(63 downto 0); op2 : std_logic_vector(63 downto 0); opid : std_logic_vector(7 downto 0); flush : std_logic; flushid : std_logic_vector(5 downto 0); rndmode : std_logic_vector(1 downto 0); req : std_logic_vector(2 downto 0); end record; constant grfpu_in_none : grfpu_in_type := ('0', '0', (others => '0'), (others => '0'), (others => '0'), (others => '0'), '0', (others => '0'), (others => '0'), (others => '0')); type grfpu_out_type is record res : std_logic_vector(63 downto 0); exc : std_logic_vector(5 downto 0); allow : std_logic_vector(2 downto 0); rdy : std_logic; cc : std_logic_vector(1 downto 0); idout : std_logic_vector(7 downto 0); end record; constant grfpu_out_none : grfpu_out_type := ((others => '0'), (others => '0'), (others => '0'), '0', (others => '0'), (others => '0')); type grfpu_out_vector_type is array (integer range 0 to 7) of grfpu_out_type; type grfpu_in_vector_type is array (integer range 0 to 7) of grfpu_in_type; component grfpushwx generic (mul : integer := 0; nshare : integer range 0 to 8 := 0; tech : integer; arb : integer range 0 to 2 := 1); port( clk : in std_logic; reset : in std_logic; fpvi : in grfpu_in_vector_type; fpvo : out grfpu_out_vector_type ); end component; component leon3sh generic ( hindex : integer := 0; fabtech : integer range 0 to NTECH := DEFFABTECH; memtech : integer range 0 to NTECH := DEFMEMTECH; nwindows : integer range 2 to 32 := 8; dsu : integer range 0 to 1 := 0; fpu : integer range 0 to 63 := 0; v8 : integer range 0 to 63 := 0; cp : integer range 0 to 1 := 0; mac : integer range 0 to 1 := 0; pclow : integer range 0 to 2 := 2; notag : integer range 0 to 1 := 0; nwp : integer range 0 to 4 := 0; icen : integer range 0 to 1 := 0; irepl : integer range 0 to 3 := 2; isets : integer range 1 to 4 := 1; ilinesize : integer range 4 to 8 := 4; isetsize : integer range 1 to 256 := 1; isetlock : integer range 0 to 1 := 0; dcen : integer range 0 to 1 := 0; drepl : integer range 0 to 3 := 2; dsets : integer range 1 to 4 := 1; dlinesize : integer range 4 to 8 := 4; dsetsize : integer range 1 to 256 := 1; dsetlock : integer range 0 to 1 := 0; dsnoop : integer range 0 to 6 := 0; ilram : integer range 0 to 1 := 0; ilramsize : integer range 1 to 512 := 1; ilramstart : integer range 0 to 255 := 16#8e#; dlram : integer range 0 to 1 := 0; dlramsize : integer range 1 to 512 := 1; dlramstart : integer range 0 to 255 := 16#8f#; mmuen : integer range 0 to 1 := 0; itlbnum : integer range 2 to 64 := 8; dtlbnum : integer range 2 to 64 := 8; tlb_type : integer range 0 to 3 := 1; tlb_rep : integer range 0 to 1 := 0; lddel : integer range 1 to 2 := 2; disas : integer range 0 to 2 := 0; tbuf : integer range 0 to 64 := 0; pwd : integer range 0 to 2 := 2; -- power-down svt : integer range 0 to 1 := 1; -- single vector trapping rstaddr : integer := 0; smp : integer range 0 to 15 := 0; -- support SMP systems cached : integer := 0; -- cacheability table scantest : integer := 0; mmupgsz : integer range 0 to 5 := 0; bp : integer := 1 ); port ( clk : in std_ulogic; rstn : in std_ulogic; ahbi : in ahb_mst_in_type; ahbo : out ahb_mst_out_type; ahbsi : in ahb_slv_in_type; ahbso : in ahb_slv_out_vector; irqi : in l3_irq_in_type; irqo : out l3_irq_out_type; dbgi : in l3_debug_in_type; dbgo : out l3_debug_out_type; fpui : out grfpu_in_type; fpuo : in grfpu_out_type ); end component; component leon3s2x generic ( hindex : integer := 0; fabtech : integer range 0 to NTECH := DEFFABTECH; memtech : integer range 0 to NTECH := DEFMEMTECH; nwindows : integer range 2 to 32 := 8; dsu : integer range 0 to 1 := 0; fpu : integer range 0 to 31 := 0; v8 : integer range 0 to 63 := 0; cp : integer range 0 to 1 := 0; mac : integer range 0 to 1 := 0; pclow : integer range 0 to 2 := 2; notag : integer range 0 to 1 := 0; nwp : integer range 0 to 4 := 0; icen : integer range 0 to 1 := 0; irepl : integer range 0 to 3 := 2; isets : integer range 1 to 4 := 1; ilinesize : integer range 4 to 8 := 4; isetsize : integer range 1 to 256 := 1; isetlock : integer range 0 to 1 := 0; dcen : integer range 0 to 1 := 0; drepl : integer range 0 to 3 := 2; dsets : integer range 1 to 4 := 1; dlinesize : integer range 4 to 8 := 4; dsetsize : integer range 1 to 256 := 1; dsetlock : integer range 0 to 1 := 0; dsnoop : integer range 0 to 6 := 0; ilram : integer range 0 to 1 := 0; ilramsize : integer range 1 to 512 := 1; ilramstart : integer range 0 to 255 := 16#8e#; dlram : integer range 0 to 1 := 0; dlramsize : integer range 1 to 512 := 1; dlramstart : integer range 0 to 255 := 16#8f#; mmuen : integer range 0 to 1 := 0; itlbnum : integer range 2 to 64 := 8; dtlbnum : integer range 2 to 64 := 8; tlb_type : integer range 0 to 3 := 1; tlb_rep : integer range 0 to 1 := 0; lddel : integer range 1 to 2 := 2; disas : integer range 0 to 2 := 0; tbuf : integer range 0 to 64 := 0; pwd : integer range 0 to 2 := 2; -- power-down svt : integer range 0 to 1 := 1; -- single vector trapping rstaddr : integer := 0; smp : integer range 0 to 15 := 0; -- support SMP systems cached : integer := 0; -- cacheability table clk2x : integer := 1; scantest : integer := 0; mmupgsz : integer range 0 to 5 := 0; bp : integer := 1 ); port ( clk : in std_ulogic; gclk2 : in std_ulogic; clk2 : in std_ulogic; -- snoop clock rstn : in std_ulogic; ahbi : in ahb_mst_in_type; ahbo : out ahb_mst_out_type; ahbsi : in ahb_slv_in_type; ahbso : in ahb_slv_out_vector; irqi : in l3_irq_in_type; irqo : out l3_irq_out_type; dbgi : in l3_debug_in_type; dbgo : out l3_debug_out_type; clken : in std_ulogic ); end component; component leon3ft2x generic ( hindex : integer := 0; fabtech : integer range 0 to NTECH := DEFFABTECH; memtech : integer range 0 to NTECH := DEFMEMTECH; nwindows : integer range 2 to 32 := 8; dsu : integer range 0 to 1 := 0; fpu : integer range 0 to 63 := 0; v8 : integer range 0 to 63 := 0; cp : integer range 0 to 1 := 0; mac : integer range 0 to 1 := 0; pclow : integer range 0 to 2 := 2; notag : integer range 0 to 1 := 0; nwp : integer range 0 to 4 := 0; icen : integer range 0 to 1 := 0; irepl : integer range 0 to 3 := 2; isets : integer range 1 to 4 := 1; ilinesize : integer range 4 to 8 := 4; isetsize : integer range 1 to 256 := 1; isetlock : integer range 0 to 1 := 0; dcen : integer range 0 to 1 := 0; drepl : integer range 0 to 3 := 2; dsets : integer range 1 to 4 := 1; dlinesize : integer range 4 to 8 := 4; dsetsize : integer range 1 to 256 := 1; dsetlock : integer range 0 to 1 := 0; dsnoop : integer range 0 to 6 := 0; ilram : integer range 0 to 1 := 0; ilramsize : integer range 1 to 512 := 1; ilramstart : integer range 0 to 255 := 16#8e#; dlram : integer range 0 to 1 := 0; dlramsize : integer range 1 to 512 := 1; dlramstart : integer range 0 to 255 := 16#8f#; mmuen : integer range 0 to 1 := 0; itlbnum : integer range 2 to 64 := 8; dtlbnum : integer range 2 to 64 := 8; tlb_type : integer range 0 to 3 := 1; tlb_rep : integer range 0 to 1 := 0; lddel : integer range 1 to 2 := 2; disas : integer range 0 to 2 := 0; tbuf : integer range 0 to 64 := 0; pwd : integer range 0 to 2 := 2; -- power-down svt : integer range 0 to 1 := 1; -- single vector trapping rstaddr : integer := 0; smp : integer range 0 to 15 := 0; -- support SMP systems iuft : integer range 0 to 4 := 0; fpft : integer range 0 to 4 := 0; cmft : integer range 0 to 1 := 0; iuinj : integer := 0; ceinj : integer range 0 to 3 := 0; cached : integer := 0; clk2x : integer := 1; netlist : integer := 0; scantest : integer := 0; mmupgsz : integer range 0 to 5 := 0; bp : integer := 1 ); port ( clk : in std_ulogic; -- free-running clock gclk2 : in std_ulogic; -- gated 2x clock gfclk2 : in std_ulogic; -- gated 2x FPU clock clk2 : in std_ulogic; -- free-running 2x clock rstn : in std_ulogic; ahbi : in ahb_mst_in_type; ahbo : out ahb_mst_out_type; ahbsi : in ahb_slv_in_type; ahbso : in ahb_slv_out_vector; irqi : in l3_irq_in_type; irqo : out l3_irq_out_type; dbgi : in l3_debug_in_type; dbgo : out l3_debug_out_type; fpui : out grfpu_in_type; fpuo : in grfpu_out_type; clken : in std_ulogic ); end component; type dsu_in_type is record enable : std_ulogic; break : std_ulogic; end record; type dsu_out_type is record active : std_ulogic; tstop : std_ulogic; pwd : std_logic_vector(15 downto 0); end record; component dsu3 generic ( hindex : integer := 0; haddr : integer := 16#900#; hmask : integer := 16#f00#; ncpu : integer := 1; tbits : integer := 30; -- timer bits (instruction trace time tag) tech : integer := DEFMEMTECH; irq : integer := 0; kbytes : integer := 0; testen : integer := 0 ); port ( rst : in std_ulogic; clk : in std_ulogic; ahbmi : in ahb_mst_in_type; ahbsi : in ahb_slv_in_type; ahbso : out ahb_slv_out_type; dbgi : in l3_debug_out_vector(0 to NCPU-1); dbgo : out l3_debug_in_vector(0 to NCPU-1); dsui : in dsu_in_type; dsuo : out dsu_out_type ); end component; component dsu3_2x generic ( hindex : integer := 0; haddr : integer := 16#900#; hmask : integer := 16#f00#; ncpu : integer := 1; tbits : integer := 30; -- timer bits (instruction trace time tag) tech : integer := DEFMEMTECH; irq : integer := 0; kbytes : integer := 0; testen : integer := 0 ); port ( rst : in std_ulogic; hclk : in std_ulogic; cpuclk : in std_ulogic; ahbmi : in ahb_mst_in_type; ahbsi : in ahb_slv_in_type; ahbso : out ahb_slv_out_type; dbgi : in l3_debug_out_vector(0 to NCPU-1); dbgo : out l3_debug_in_vector(0 to NCPU-1); dsui : in dsu_in_type; dsuo : out dsu_out_type; hclken : in std_ulogic ); end component; component dsu3x generic ( hindex : integer := 0; haddr : integer := 16#900#; hmask : integer := 16#f00#; ncpu : integer := 1; tbits : integer := 30; -- timer bits (instruction trace time tag) tech : integer := DEFMEMTECH; irq : integer := 0; kbytes : integer := 0; clk2x : integer range 0 to 1 := 0; testen : integer := 0 ); port ( rst : in std_ulogic; hclk : in std_ulogic; cpuclk : in std_ulogic; ahbmi : in ahb_mst_in_type; ahbsi : in ahb_slv_in_type; ahbso : out ahb_slv_out_type; dbgi : in l3_debug_out_vector(0 to NCPU-1); dbgo : out l3_debug_in_vector(0 to NCPU-1); dsui : in dsu_in_type; dsuo : out dsu_out_type; hclken : in std_ulogic ); end component; type irq_in_vector is array (Natural range <> ) of l3_irq_in_type; type irq_out_vector is array (Natural range <> ) of l3_irq_out_type; component irqmp generic ( pindex : integer := 0; paddr : integer := 0; pmask : integer := 16#fff#; ncpu : integer := 1; eirq : integer := 0 ); port ( rst : in std_ulogic; clk : in std_ulogic; apbi : in apb_slv_in_type; apbo : out apb_slv_out_type; irqi : in irq_out_vector(0 to ncpu-1); irqo : out irq_in_vector(0 to ncpu-1) ); end component; component irqmp2x generic ( pindex : integer := 0; paddr : integer := 0; pmask : integer := 16#fff#; ncpu : integer := 1; eirq : integer := 0; clkfact : integer := 2 ); port ( rst : in std_ulogic; hclk : in std_ulogic; cpuclk : in std_ulogic; apbi : in apb_slv_in_type; apbo : out apb_slv_out_type; irqi : in irq_out_vector(0 to ncpu-1); irqo : out irq_in_vector(0 to ncpu-1); hclken : in std_ulogic ); end component; component irqamp generic ( pindex : integer := 0; paddr : integer := 0; pmask : integer := 16#fff#; ncpu : integer := 1; eirq : integer := 0; nctrl : integer range 1 to 16 := 1; tstamp : integer range 0 to 16 := 0; wdogen : integer range 0 to 1 := 0; nwdog : integer range 1 to 16 := 1; dynrstaddr : integer range 0 to 1 := 0; rstaddr : integer range 0 to 16#fffff# := 0; extrun : integer range 0 to 1 := 0 ); port ( rst : in std_ulogic; clk : in std_ulogic; apbi : in apb_slv_in_type; apbo : out apb_slv_out_type; irqi : in irq_out_vector(0 to ncpu-1); irqo : out irq_in_vector(0 to ncpu-1); wdog : in std_logic_vector(nwdog-1 downto 0) := (others => '0'); cpurun : in std_logic_vector(ncpu-1 downto 0) := (others => '0') ); end component; component irqamp2x generic ( pindex : integer := 0; paddr : integer := 0; pmask : integer := 16#fff#; ncpu : integer := 1; eirq : integer := 0; nctrl : integer range 1 to 16 := 1; tstamp : integer range 0 to 16 := 0; wdogen : integer range 0 to 1 := 0; nwdog : integer range 1 to 16 := 1; dynrstaddr : integer range 0 to 1 := 0; rstaddr : integer range 0 to 16#fffff# := 0; extrun : integer range 0 to 1 := 0; clkfact : integer := 2 ); port ( rst : in std_ulogic; hclk : in std_ulogic; cpuclk : in std_ulogic; apbi : in apb_slv_in_type; apbo : out apb_slv_out_type; irqi : in irq_out_vector(0 to ncpu-1); irqo : out irq_in_vector(0 to ncpu-1); wdog : in std_logic_vector(nwdog-1 downto 0) := (others => '0'); cpurun : in std_logic_vector(ncpu-1 downto 0) := (others => '0'); hclken : in std_ulogic ); end component; component leon3ftsh generic ( hindex : integer := 0; fabtech : integer range 0 to NTECH := DEFFABTECH; memtech : integer range 0 to NTECH := DEFMEMTECH; nwindows : integer range 2 to 32 := 8; dsu : integer range 0 to 1 := 0; fpu : integer range 0 to 63 := 0; v8 : integer range 0 to 63 := 0; cp : integer range 0 to 1 := 0; mac : integer range 0 to 1 := 0; pclow : integer range 0 to 2 := 2; notag : integer range 0 to 1 := 0; nwp : integer range 0 to 4 := 0; icen : integer range 0 to 1 := 0; irepl : integer range 0 to 3 := 2; isets : integer range 1 to 4 := 1; ilinesize : integer range 4 to 8 := 4; isetsize : integer range 1 to 256 := 1; isetlock : integer range 0 to 1 := 0; dcen : integer range 0 to 1 := 0; drepl : integer range 0 to 3 := 2; dsets : integer range 1 to 4 := 1; dlinesize : integer range 4 to 8 := 4; dsetsize : integer range 1 to 256 := 1; dsetlock : integer range 0 to 1 := 0; dsnoop : integer range 0 to 6 := 0; ilram : integer range 0 to 1 := 0; ilramsize : integer range 1 to 512 := 1; ilramstart : integer range 0 to 255 := 16#8e#; dlram : integer range 0 to 1 := 0; dlramsize : integer range 1 to 512 := 1; dlramstart : integer range 0 to 255 := 16#8f#; mmuen : integer range 0 to 1 := 0; itlbnum : integer range 2 to 64 := 8; dtlbnum : integer range 2 to 64 := 8; tlb_type : integer range 0 to 3 := 1; tlb_rep : integer range 0 to 1 := 0; lddel : integer range 1 to 2 := 2; disas : integer range 0 to 2 := 0; tbuf : integer range 0 to 64 := 0; pwd : integer range 0 to 2 := 2; -- power-down svt : integer range 0 to 1 := 1; -- single vector trapping rstaddr : integer := 0; smp : integer range 0 to 15 := 0; -- support SMP systems iuft : integer range 0 to 4 := 0; fpft : integer range 0 to 4 := 0; cmft : integer range 0 to 1 := 0; iuinj : integer := 0; ceinj : integer range 0 to 3 := 0; cached : integer := 0; netlist : integer := 0; scantest : integer := 0; mmupgsz : integer range 0 to 5 := 0; bp : integer := 1 ); port ( clk : in std_ulogic; -- free-running clock rstn : in std_ulogic; ahbi : in ahb_mst_in_type; ahbo : out ahb_mst_out_type; ahbsi : in ahb_slv_in_type; ahbso : in ahb_slv_out_vector; irqi : in l3_irq_in_type; irqo : out l3_irq_out_type; dbgi : in l3_debug_in_type; dbgo : out l3_debug_out_type; gclk : in std_ulogic; -- gated clock fpui : out grfpu_in_type; fpuo : in grfpu_out_type ); end component; component leon3x generic ( hindex : integer := 0; fabtech : integer range 0 to NTECH := DEFFABTECH; memtech : integer range 0 to NTECH := DEFMEMTECH; nwindows : integer range 2 to 32 := 8; dsu : integer range 0 to 1 := 0; fpu : integer range 0 to 63 := 0; v8 : integer range 0 to 63 := 0; cp : integer range 0 to 1 := 0; mac : integer range 0 to 1 := 0; pclow : integer range 0 to 2 := 2; notag : integer range 0 to 1 := 0; nwp : integer range 0 to 4 := 0; icen : integer range 0 to 1 := 0; irepl : integer range 0 to 3 := 2; isets : integer range 1 to 4 := 1; ilinesize : integer range 4 to 8 := 4; isetsize : integer range 1 to 256 := 1; isetlock : integer range 0 to 1 := 0; dcen : integer range 0 to 1 := 0; drepl : integer range 0 to 3 := 2; dsets : integer range 1 to 4 := 1; dlinesize : integer range 4 to 8 := 4; dsetsize : integer range 1 to 256 := 1; dsetlock : integer range 0 to 1 := 0; dsnoop : integer range 0 to 6 := 0; ilram : integer range 0 to 1 := 0; ilramsize : integer range 1 to 512 := 1; ilramstart : integer range 0 to 255 := 16#8e#; dlram : integer range 0 to 1 := 0; dlramsize : integer range 1 to 512 := 1; dlramstart : integer range 0 to 255 := 16#8f#; mmuen : integer range 0 to 1 := 0; itlbnum : integer range 2 to 64 := 8; dtlbnum : integer range 2 to 64 := 8; tlb_type : integer range 0 to 3 := 1; tlb_rep : integer range 0 to 1 := 0; lddel : integer range 1 to 2 := 2; disas : integer range 0 to 2 := 0; tbuf : integer range 0 to 64 := 0; pwd : integer range 0 to 2 := 2; -- power-down svt : integer range 0 to 1 := 1; -- single vector trapping rstaddr : integer := 0; smp : integer range 0 to 15 := 0; -- support SMP systems iuft : integer range 0 to 4 := 0; fpft : integer range 0 to 4 := 0; cmft : integer range 0 to 1 := 0; iuinj : integer := 0; ceinj : integer range 0 to 3 := 0; cached : integer := 0; clk2x : integer := 1; netlist : integer := 0; scantest : integer := 0; mmupgsz : integer range 0 to 5 := 0; bp : integer := 1 ); port ( clk : in std_ulogic; -- free-running clock gclk2 : in std_ulogic; -- gated 2x clock gfclk2 : in std_ulogic; -- gated 2x FPU clock clk2 : in std_ulogic; -- free-running 2x clock rstn : in std_ulogic; ahbi : in ahb_mst_in_type; ahbo : out ahb_mst_out_type; ahbsi : in ahb_slv_in_type; ahbso : in ahb_slv_out_vector; irqi : in l3_irq_in_type; irqo : out l3_irq_out_type; dbgi : in l3_debug_in_type; dbgo : out l3_debug_out_type; fpui : out grfpu_in_type; fpuo : in grfpu_out_type; clken : in std_ulogic ); end component; -- disassembly dummy module component cpu_disasx port ( clk : in std_ulogic; rstn : in std_ulogic; dummy : out std_ulogic; inst : in std_logic_vector(31 downto 0); pc : in std_logic_vector(31 downto 2); result : in std_logic_vector(31 downto 0); index : in std_logic_vector(3 downto 0); wreg : in std_ulogic; annul : in std_ulogic; holdn : in std_ulogic; pv : in std_ulogic; trap : in std_ulogic; disas : in std_ulogic); end component; end;	gpl-2.0	252274f86c21776ab5c1dcc41fc45efb	0.52544	3.440746	false	false	false	false
mistryalok/Zedboard	learning/opencv_hls/xapp1167_vivado/sw/fast-corner/prj/solution1/syn/vhdl/FIFO_image_filter_p_src_cols_V_2_loc_channel1.vhd	2	4,684	-- ============================================================== -- File generated by Vivado(TM) HLS - High-Level Synthesis from C, C++ and SystemC -- Version: 2014.4 -- Copyright (C) 2014 Xilinx Inc. All rights reserved. -- -- ============================================================== library IEEE; use IEEE.std_logic_1164.all; use IEEE.std_logic_unsigned.all; entity FIFO_image_filter_p_src_cols_V_2_loc_channel1_shiftReg is generic ( DATA_WIDTH : integer := 12; ADDR_WIDTH : integer := 2; DEPTH : integer := 3); port ( clk : in std_logic; data : in std_logic_vector(DATA_WIDTH-1 downto 0); ce : in std_logic; a : in std_logic_vector(ADDR_WIDTH-1 downto 0); q : out std_logic_vector(DATA_WIDTH-1 downto 0)); end FIFO_image_filter_p_src_cols_V_2_loc_channel1_shiftReg; architecture rtl of FIFO_image_filter_p_src_cols_V_2_loc_channel1_shiftReg is --constant DEPTH_WIDTH: integer := 16; type SRL_ARRAY is array (0 to DEPTH-1) of std_logic_vector(DATA_WIDTH-1 downto 0); signal SRL_SIG : SRL_ARRAY; begin p_shift: process (clk) begin if (clk'event and clk = '1') then if (ce = '1') then SRL_SIG <= data & SRL_SIG(0 to DEPTH-2); end if; end if; end process; q <= SRL_SIG(conv_integer(a)); end rtl; library ieee; use ieee.std_logic_1164.all; use ieee.std_logic_unsigned.all; entity FIFO_image_filter_p_src_cols_V_2_loc_channel1 is generic ( MEM_STYLE : string := "shiftreg"; DATA_WIDTH : integer := 12; ADDR_WIDTH : integer := 2; DEPTH : integer := 3); port ( clk : IN STD_LOGIC; reset : IN STD_LOGIC; if_empty_n : OUT STD_LOGIC; if_read_ce : IN STD_LOGIC; if_read : IN STD_LOGIC; if_dout : OUT STD_LOGIC_VECTOR(DATA_WIDTH - 1 downto 0); if_full_n : OUT STD_LOGIC; if_write_ce : IN STD_LOGIC; if_write : IN STD_LOGIC; if_din : IN STD_LOGIC_VECTOR(DATA_WIDTH - 1 downto 0)); end entity; architecture rtl of FIFO_image_filter_p_src_cols_V_2_loc_channel1 is component FIFO_image_filter_p_src_cols_V_2_loc_channel1_shiftReg is generic ( DATA_WIDTH : integer := 12; ADDR_WIDTH : integer := 2; DEPTH : integer := 3); port ( clk : in std_logic; data : in std_logic_vector(DATA_WIDTH-1 downto 0); ce : in std_logic; a : in std_logic_vector(ADDR_WIDTH-1 downto 0); q : out std_logic_vector(DATA_WIDTH-1 downto 0)); end component; signal shiftReg_addr : STD_LOGIC_VECTOR(ADDR_WIDTH - 1 downto 0); signal shiftReg_data, shiftReg_q : STD_LOGIC_VECTOR(DATA_WIDTH - 1 downto 0); signal shiftReg_ce : STD_LOGIC; signal mOutPtr : STD_LOGIC_VECTOR(ADDR_WIDTH downto 0) := (others => '1'); signal internal_empty_n : STD_LOGIC := '0'; signal internal_full_n : STD_LOGIC := '1'; begin if_empty_n <= internal_empty_n; if_full_n <= internal_full_n; shiftReg_data <= if_din; if_dout <= shiftReg_q; process (clk) begin if clk'event and clk = '1' then if reset = '1' then mOutPtr <= (others => '1'); internal_empty_n <= '0'; internal_full_n <= '1'; else if ((if_read and if_read_ce) = '1' and internal_empty_n = '1') and ((if_write and if_write_ce) = '0' or internal_full_n = '0') then mOutPtr <= mOutPtr -1; if (mOutPtr = 0) then internal_empty_n <= '0'; end if; internal_full_n <= '1'; elsif ((if_read and if_read_ce) = '0' or internal_empty_n = '0') and ((if_write and if_write_ce) = '1' and internal_full_n = '1') then mOutPtr <= mOutPtr +1; internal_empty_n <= '1'; if (mOutPtr = DEPTH -2) then internal_full_n <= '0'; end if; end if; end if; end if; end process; shiftReg_addr <= (others => '0') when mOutPtr(ADDR_WIDTH) = '1' else mOutPtr(ADDR_WIDTH-1 downto 0); shiftReg_ce <= (if_write and if_write_ce) and internal_full_n; U_FIFO_image_filter_p_src_cols_V_2_loc_channel1_shiftReg : FIFO_image_filter_p_src_cols_V_2_loc_channel1_shiftReg generic map ( DATA_WIDTH => DATA_WIDTH, ADDR_WIDTH => ADDR_WIDTH, DEPTH => DEPTH) port map ( clk => clk, data => shiftReg_data, ce => shiftReg_ce, a => shiftReg_addr, q => shiftReg_q); end rtl;	gpl-3.0	ed81fefe4a44812fb1a09e70427df479	0.541418	3.42899	false	false	false	false
mistryalok/Zedboard	learning/training/MSD/s05/project_1/project_1.srcs/sources_1/ipshared/xilinx.com/axi_cdma_v4_1/25515467/hdl/src/vhdl/axi_cdma_sf.vhd	1	40,689	------------------------------------------------------------------------------- -- axi_cdma_sf.vhd ------------------------------------------------------------------------------- -- -- *********************************************************************** -- -- (c) Copyright 2010-2011 Xilinx, Inc. All rights reserved. -- -- This file contains confidential and proprietary information -- of Xilinx, Inc. and is protected under U.S. and -- international copyright and other intellectual property -- laws. -- -- DISCLAIMER -- This disclaimer is not a license and does not grant any -- rights to the materials distributed herewith. Except as -- otherwise provided in a valid license issued to you by -- Xilinx, and to the maximum extent permitted by applicable -- law: (1) THESE MATERIALS ARE MADE AVAILABLE "AS IS" AND -- WITH ALL FAULTS, AND XILINX HEREBY DISCLAIMS ALL WARRANTIES -- AND CONDITIONS, EXPRESS, IMPLIED, OR STATUTORY, INCLUDING -- BUT NOT LIMITED TO WARRANTIES OF MERCHANTABILITY, NON- -- INFRINGEMENT, OR FITNESS FOR ANY PARTICULAR PURPOSE; and -- (2) Xilinx shall not be liable (whether in contract or tort, -- including negligence, or under any other theory of -- liability) for any loss or damage of any kind or nature -- related to, arising under or in connection with these -- materials, including for any direct, or any indirect, -- special, incidental, or consequential loss or damage -- (including loss of data, profits, goodwill, or any type of -- loss or damage suffered as a result of any action brought -- by a third party) even if such damage or loss was -- reasonably foreseeable or Xilinx had been advised of the -- possibility of the same. -- -- CRITICAL APPLICATIONS -- Xilinx products are not designed or intended to be fail- -- safe, or for use in any application requiring fail-safe -- performance, such as life-support or safety devices or -- systems, Class III medical devices, nuclear facilities, -- applications related to the deployment of airbags, or any -- other applications that could lead to death, personal -- injury, or severe property or environmental damage -- (individually and collectively, "Critical -- Applications"). Customer assumes the sole risk and -- liability of any use of Xilinx products in Critical -- Applications, subject only to applicable laws and -- regulations governing limitations on product liability. -- -- THIS COPYRIGHT NOTICE AND DISCLAIMER MUST BE RETAINED AS -- PART OF THIS FILE AT ALL TIMES. -- -- *********************************************************************** -- ------------------------------------------------------------------------------- -- Filename: axi_cdma_sf.vhd -- -- Description: -- This file implements the AXI CDMA store and Forward module. -- The design utilizes the AXI DataMover's new address pipelining -- control interfaces. The design is such that predictive address -- pipelining can be supported on the AXI Read Bus without over-commiting -- the internal Data FIFO and potentially throttling the Read Data Channel -- if the Data FIFO goes full. On the AXI Write side, the Write Master is -- only allowed to post AXI WRite Requests if the associated write data needed -- to complete the Write Data transfer is present in the Data FIFO. In -- addition, the Write side logic is such that Write transfer requests can -- be pipelined to the AXI bus based on the Data FIFO contents but ahead of -- the actual Write Data transfers. -- -- -- VHDL-Standard: VHDL'93 ------------------------------------------------------------------------------- ------------------------------------------------------------------------------- library IEEE; use IEEE.std_logic_1164.all; use IEEE.numeric_std.all; library lib_pkg_v1_0; use lib_pkg_v1_0.lib_pkg.all; use lib_pkg_v1_0.lib_pkg.clog2; library lib_srl_fifo_v1_0; use lib_srl_fifo_v1_0.srl_fifo_f; library axi_cdma_v4_1; use axi_cdma_v4_1.axi_cdma_sfifo_autord; ------------------------------------------------------------------------------- entity axi_cdma_sf is generic ( C_WR_ADDR_PIPE_DEPTH : Integer range 1 to 30 := 4; -- This parameter indicates the depth of the DataMover -- write address pipelining queues for the Main data transport -- channels. The effective address pipelining on the AXI4 -- Write Address Channel will be the value assigned plus 2. C_SF_FIFO_DEPTH : Integer range 128 to 8192 := 512; -- Sets the desired depth of the internal Data FIFO. C_MAX_BURST_LEN : Integer range 2 to 256 := 16; -- Indicates the max burst length being used by the external -- AXI4 Master for each AXI4 transfer request. C_DRE_IS_USED : Integer range 0 to 1 := 0; -- Indicates if the external Master is utilizing a DRE on -- the stream input to this module. C_STREAM_DWIDTH : Integer range 8 to 1024 := 32; -- Sets the Stream Data Width for the Input and Output -- Data streams. C_FAMILY : String := "virtex7" -- Indicates the target FPGA Family. ); port ( -- Clock input aclk : in std_logic; -- Primary synchronization clock for the Master side -- interface and internal logic. It is also used -- for the User interface synchronization when -- C_STSCMD_IS_ASYNC = 0. -- Reset input reset : in std_logic; -- Reset used for the internal syncronization logic -- DataMover Read Side Address Pipelining Control Interface --------------- ok_to_post_rd_addr : Out Std_logic; -- Indicates that the transfer token pool has at least -- one token available to borrow rd_addr_posted : In std_logic; -- Indication that a read address has been posted to AXI4 rd_xfer_cmplt : In std_logic; -- Indicates that the Datamover has completed a Read Data -- transfer on the AXI4 -- Read Side Stream In from DataMover MM2S ----------------------------------- sf2sin_tready : Out Std_logic; -- DRE Stream READY input sin2sf_tvalid : In std_logic; -- DRE Stream VALID Output sin2sf_tdata : In std_logic_vector(C_STREAM_DWIDTH-1 downto 0); -- DRE Stream DATA input sin2sf_tkeep : In std_logic_vector((C_STREAM_DWIDTH/8)-1 downto 0); -- DRE Stream STRB input sin2sf_tlast : In std_logic; -- DRE Xfer LAST input -- DataMover Write Side Address Pipelining Control Interface -------------- ok_to_post_wr_addr : Out Std_logic; -- Indicates that the internal FIFO has enough data -- physically present to supply one more max length -- burst transfer or a completion burst -- (tlast asserted) wr_addr_posted : In std_logic; -- Indication that a write address has been posted to AXI4 wr_xfer_cmplt : In Std_logic; -- Indicates that the Datamover has completed a Write Data -- transfer on the AXI4 wr_ld_nxt_len : in std_logic; -- Active high pulse indicating a new transfer LEN qualifier -- has been queued to the DataMover Write Data Controller wr_len : in std_logic_vector(7 downto 0); -- The actual LEN qualifier value that has been queued to the -- DataMover Write Data Controller -- Write Side Stream Out to DataMover S2MM ------------------------------- sout2sf_tready : In std_logic; -- Write READY input from the Stream Master sf2sout_tvalid : Out std_logic; -- Write VALID output to the Stream Master sf2sout_tdata : Out std_logic_vector(C_STREAM_DWIDTH-1 downto 0); -- Write DATA output to the Stream Master sf2sout_tkeep : Out std_logic_vector((C_STREAM_DWIDTH/8)-1 downto 0); -- Write DATA output to the Stream Master sf2sout_tlast : Out std_logic -- Write LAST output to the Stream Master ); end entity axi_cdma_sf; architecture implementation of axi_cdma_sf is attribute DowngradeIPIdentifiedWarnings: string; attribute DowngradeIPIdentifiedWarnings of implementation : architecture is "yes"; -- Functions --------------------------------------------------------------------------- ------------------------------------------------------------------- -- Function -- -- Function Name: funct_get_dbcntr_width -- -- Function Description: -- simple function to set the width of the burst counter -- based on the parameterized max burst length. -- ------------------------------------------------------------------- function funct_get_dbcntr_width (max_burst_length : integer) return integer is Variable temp_width : integer := 0; begin case max_burst_length is when 2 => temp_width := 1; when 4 => temp_width := 2; when 8 => temp_width := 3; when 16 => temp_width := 4; when 32 => temp_width := 5; when 64 => temp_width := 6; when 128 => temp_width := 7; when others => -- 256 beats temp_width := 8; end case; Return (temp_width); end function funct_get_dbcntr_width; ------------------------------------------------------------------- -- Function -- -- Function Name: funct_get_pwr2_depth -- -- Function Description: -- Rounds up to the next power of 2 depth value in an input -- range of 1 to 8192 -- ------------------------------------------------------------------- function funct_get_pwr2_depth (min_depth : integer) return integer is Variable var_temp_depth : Integer := 16; begin if (min_depth = 1) then var_temp_depth := 1; elsif (min_depth = 2) then var_temp_depth := 2; elsif (min_depth <= 4) then var_temp_depth := 4; elsif (min_depth <= 8) then var_temp_depth := 8; elsif (min_depth <= 16) then var_temp_depth := 16; elsif (min_depth <= 32) then var_temp_depth := 32; elsif (min_depth <= 64) then var_temp_depth := 64; elsif (min_depth <= 128) then var_temp_depth := 128; elsif (min_depth <= 256) then var_temp_depth := 256; elsif (min_depth <= 512) then var_temp_depth := 512; elsif (min_depth <= 1024) then var_temp_depth := 1024; elsif (min_depth <= 2048) then var_temp_depth := 2048; elsif (min_depth <= 4096) then var_temp_depth := 4096; else -- assume 8192 depth var_temp_depth := 8192; end if; Return (var_temp_depth); end function funct_get_pwr2_depth; ------------------------------------------------------------------- -- Function -- -- Function Name: funct_get_fifo_cnt_width -- -- Function Description: -- simple function to set the width of the data fifo read -- and write count outputs. ------------------------------------------------------------------- function funct_get_fifo_cnt_width (fifo_depth : integer) return integer is Variable temp_width : integer := 8; begin if (fifo_depth = 1) then temp_width := 1; elsif (fifo_depth = 2) then temp_width := 2; elsif (fifo_depth <= 4) then temp_width := 3; elsif (fifo_depth <= 8) then temp_width := 4; elsif (fifo_depth <= 16) then temp_width := 5; elsif (fifo_depth <= 32) then temp_width := 6; elsif (fifo_depth <= 64) then temp_width := 7; elsif (fifo_depth <= 128) then temp_width := 8; elsif (fifo_depth <= 256) then temp_width := 9; elsif (fifo_depth <= 512) then temp_width := 10; elsif (fifo_depth <= 1024) then temp_width := 11; elsif (fifo_depth <= 2048) then temp_width := 12; elsif (fifo_depth <= 4096) then temp_width := 13; else -- assume 8192 depth temp_width := 14; end if; Return (temp_width); end function funct_get_fifo_cnt_width; ------------------------------------------------------------------- -- Function -- -- Function Name: funct_get_wrcnt_lsrip -- -- Function Description: -- Calculates the ls index of the upper slice of the data fifo -- write count needed to repesent one max burst worth of data -- present in the fifo. -- ------------------------------------------------------------------- function funct_get_wrcnt_lsrip (max_burst_dbeats : integer) return integer is Variable temp_ls_index : Integer := 0; begin if (max_burst_dbeats <= 2) then temp_ls_index := 1; elsif (max_burst_dbeats <= 4) then temp_ls_index := 2; elsif (max_burst_dbeats <= 8) then temp_ls_index := 3; elsif (max_burst_dbeats <= 16) then temp_ls_index := 4; elsif (max_burst_dbeats <= 32) then temp_ls_index := 5; elsif (max_burst_dbeats <= 64) then temp_ls_index := 6; elsif (max_burst_dbeats <= 128) then temp_ls_index := 7; else temp_ls_index := 8; end if; Return (temp_ls_index); end function funct_get_wrcnt_lsrip; ------------------------------------------------------------------- -- Function -- -- Function Name: funct_get_stall_thresh -- -- Function Description: -- Calculates the Stall threshold for the input side of the Data -- FIFO. If DRE is being used by the DataMover, then the threshold -- must be reduced to account for the potential of an extra write -- databeat per request (DRE alignment dependent). -- ------------------------------------------------------------------- function funct_get_stall_thresh (dre_is_used : integer; max_xfer_length : integer; data_fifo_depth : integer; pipeline_delay_clks : integer; fifo_settling_clks : integer) return integer is Constant DRE_PIPE_DELAY : integer := 2; -- clks Variable var_num_max_xfers_allowed : Integer := 0; Variable var_dre_dbeat_overhead : Integer := 0; Variable var_delay_fudge_factor : Integer := 0; Variable var_thresh_headroom : Integer := 0; Variable var_stall_thresh : Integer := 0; begin var_num_max_xfers_allowed := data_fifo_depth/max_xfer_length; var_dre_dbeat_overhead := var_num_max_xfers_allowed * dre_is_used; var_delay_fudge_factor := (dre_is_used * DRE_PIPE_DELAY) + pipeline_delay_clks + fifo_settling_clks; var_thresh_headroom := max_xfer_length + var_dre_dbeat_overhead + var_delay_fudge_factor; -- Scale the result to be in max transfer length increments var_stall_thresh := (data_fifo_depth - var_thresh_headroom)/max_xfer_length; Return (var_stall_thresh); end function funct_get_stall_thresh; -- Constants --------------------------------------------------------------------------- Constant LOGIC_LOW : std_logic := '0'; Constant LOGIC_HIGH : std_logic := '1'; Constant BLK_MEM_FIFO : integer := 1; Constant SRL_FIFO : integer := 0; Constant NOT_NEEDED : integer := 0; Constant WSTB_WIDTH : integer := C_STREAM_DWIDTH/8; -- bits Constant TLAST_WIDTH : integer := 1; -- bits Constant DATA_FIFO_DEPTH : integer := C_SF_FIFO_DEPTH; Constant DATA_FIFO_CNT_WIDTH : integer := funct_get_fifo_cnt_width(DATA_FIFO_DEPTH); Constant DF_WRCNT_RIP_LS_INDEX : integer := funct_get_wrcnt_lsrip(C_MAX_BURST_LEN); Constant DATA_FIFO_WIDTH : integer := C_STREAM_DWIDTH+ WSTB_WIDTH + TLAST_WIDTH; Constant DATA_OUT_MSB_INDEX : integer := C_STREAM_DWIDTH-1; Constant DATA_OUT_LSB_INDEX : integer := 0; Constant TSTRB_OUT_LSB_INDEX : integer := DATA_OUT_MSB_INDEX+1; Constant TSTRB_OUT_MSB_INDEX : integer := (TSTRB_OUT_LSB_INDEX+WSTB_WIDTH)-1; Constant TLAST_OUT_INDEX : integer := TSTRB_OUT_MSB_INDEX+1; Constant DBEAT_CNTR_WIDTH : integer := funct_get_dbcntr_width(C_MAX_BURST_LEN); Constant MAX_BURST_DBEATS : Unsigned(DBEAT_CNTR_WIDTH-1 downto 0) := TO_UNSIGNED(C_MAX_BURST_LEN-1, DBEAT_CNTR_WIDTH); Constant DBC_ONE : Unsigned(DBEAT_CNTR_WIDTH-1 downto 0) := TO_UNSIGNED(1, DBEAT_CNTR_WIDTH); Constant TOKEN_POOL_SIZE : integer := C_SF_FIFO_DEPTH / C_MAX_BURST_LEN; Constant TOKEN_CNTR_WIDTH : integer := clog2(TOKEN_POOL_SIZE)+1; Constant TOKEN_CNT_ZERO : Unsigned(TOKEN_CNTR_WIDTH-1 downto 0) := TO_UNSIGNED(0, TOKEN_CNTR_WIDTH); Constant TOKEN_CNT_ONE : Unsigned(TOKEN_CNTR_WIDTH-1 downto 0) := TO_UNSIGNED(1, TOKEN_CNTR_WIDTH); Constant TOKEN_CNT_MAX : Unsigned(TOKEN_CNTR_WIDTH-1 downto 0) := TO_UNSIGNED(TOKEN_POOL_SIZE, TOKEN_CNTR_WIDTH); Constant THRESH_COMPARE_WIDTH : integer := TOKEN_CNTR_WIDTH+2; Constant RD_PATH_PIPE_DEPTH : integer := 2; -- clocks excluding DRE Constant WRCNT_SETTLING_TIME : integer := 2; -- data fifo push or pop settling clocks Constant RD_ADDR_POST_STALL_THRESH : integer := funct_get_stall_thresh(C_DRE_IS_USED , C_MAX_BURST_LEN , C_SF_FIFO_DEPTH , RD_PATH_PIPE_DEPTH , WRCNT_SETTLING_TIME); Constant RD_ADDR_POST_STALL_THRESH_US : Unsigned(THRESH_COMPARE_WIDTH-1 downto 0) := TO_UNSIGNED(RD_ADDR_POST_STALL_THRESH , THRESH_COMPARE_WIDTH); Constant WR_LEN_FIFO_DWIDTH : integer := 8; Constant WR_LEN_FIFO_DEPTH : integer := funct_get_pwr2_depth(C_WR_ADDR_PIPE_DEPTH + 2); Constant LEN_CNTR_WIDTH : integer := 8; Constant LEN_CNT_ZERO : Unsigned(LEN_CNTR_WIDTH-1 downto 0) := TO_UNSIGNED(0, LEN_CNTR_WIDTH); Constant LEN_CNT_ONE : Unsigned(LEN_CNTR_WIDTH-1 downto 0) := TO_UNSIGNED(1, LEN_CNTR_WIDTH); Constant WR_XFER_CNTR_WIDTH : integer := 8; Constant WR_XFER_CNT_ZERO : Unsigned(WR_XFER_CNTR_WIDTH-1 downto 0) := TO_UNSIGNED(0, WR_XFER_CNTR_WIDTH); Constant WR_XFER_CNT_ONE : Unsigned(WR_XFER_CNTR_WIDTH-1 downto 0) := TO_UNSIGNED(1, WR_XFER_CNTR_WIDTH); Constant UNCOM_WRCNT_1 : Unsigned(DATA_FIFO_CNT_WIDTH-1 downto 0) := TO_UNSIGNED(1, DATA_FIFO_CNT_WIDTH); Constant UNCOM_WRCNT_0 : Unsigned(DATA_FIFO_CNT_WIDTH-1 downto 0) := TO_UNSIGNED(0, DATA_FIFO_CNT_WIDTH); -- Signals --------------------------------------------------------------------------- signal sig_good_sin_strm_dbeat : std_logic := '0'; signal sig_strm_sin_ready : std_logic := '0'; signal sig_sout2sf_tready : std_logic := '0'; signal sig_sf2sout_tvalid : std_logic := '0'; signal sig_sf2sout_tdata : std_logic_vector(C_STREAM_DWIDTH-1 downto 0) := (others => '0'); signal sig_sf2sout_tkeep : std_logic_vector(WSTB_WIDTH-1 downto 0) := (others => '0'); signal sig_sf2sout_tlast : std_logic := '0'; signal sig_push_data_fifo : std_logic := '0'; signal sig_pop_data_fifo : std_logic := '0'; signal sig_data_fifo_full : std_logic := '0'; signal sig_data_fifo_data_in : std_logic_vector(DATA_FIFO_WIDTH-1 downto 0) := (others => '0'); signal sig_data_fifo_dvalid : std_logic := '0'; signal sig_data_fifo_data_out : std_logic_vector(DATA_FIFO_WIDTH-1 downto 0) := (others => '0'); signal sig_data_fifo_wr_cnt : std_logic_vector(DATA_FIFO_CNT_WIDTH-1 downto 0) := (others => '0'); signal sig_fifo_wr_cnt_unsgnd : unsigned(DATA_FIFO_CNT_WIDTH-1 downto 0) := (others => '0'); signal sig_wrcnt_mblen_slice : unsigned(DATA_FIFO_CNT_WIDTH-1 downto DF_WRCNT_RIP_LS_INDEX) := (others => '0'); signal sig_ok_to_post_rd_addr : std_logic := '0'; signal sig_rd_addr_posted : std_logic := '0'; signal sig_rd_xfer_cmplt : std_logic := '0'; signal sig_taking_last_token : std_logic := '0'; signal sig_stall_rd_addr_posts : std_logic := '0'; signal sig_incr_token_cntr : std_logic := '0'; signal sig_decr_token_cntr : std_logic := '0'; signal sig_token_eq_max : std_logic := '0'; signal sig_token_eq_zero : std_logic := '0'; signal sig_token_eq_one : std_logic := '0'; signal sig_token_cntr : Unsigned(TOKEN_CNTR_WIDTH-1 downto 0) := (others => '0'); signal sig_tokens_commited : Unsigned(TOKEN_CNTR_WIDTH-1 downto 0) := (others => '0'); signal sig_commit_plus_actual : unsigned(THRESH_COMPARE_WIDTH-1 downto 0) := (others => '0'); signal sig_ok_to_post_wr_addr : std_logic := '0'; signal sig_wr_addr_posted : std_logic := '0'; signal sig_wr_xfer_cmplt : std_logic := '0'; signal sig_wr_ld_nxt_len : std_logic := '0'; signal sig_push_len_fifo : std_logic := '0'; signal sig_pop_len_fifo : std_logic := '0'; signal sig_len_fifo_full : std_logic := '0'; signal sig_len_fifo_empty : std_logic := '0'; signal sig_len_fifo_data_in : std_logic_vector(WR_LEN_FIFO_DWIDTH-1 downto 0) := (others => '0'); signal sig_len_fifo_data_out : std_logic_vector(WR_LEN_FIFO_DWIDTH-1 downto 0) := (others => '0'); signal sig_len_fifo_len_out_un : unsigned(WR_LEN_FIFO_DWIDTH-1 downto 0) := (others => '0'); signal sig_uncom_wrcnt : unsigned(DATA_FIFO_CNT_WIDTH-1 downto 0) := (others => '0'); signal sig_sub_len_uncom_wrcnt : std_logic := '0'; signal sig_incr_uncom_wrcnt : std_logic := '0'; signal sig_resized_fifo_len : unsigned(DATA_FIFO_CNT_WIDTH-1 downto 0) := (others => '0'); signal sig_num_wr_dbeats_needed : unsigned(DATA_FIFO_CNT_WIDTH-1 downto 0) := (others => '0'); signal sig_enough_dbeats_rcvd : std_logic := '0'; begin --(architecture implementation) -- Read Side (MM2S) Control Flags port connections ok_to_post_rd_addr <= sig_ok_to_post_rd_addr ; sig_rd_addr_posted <= rd_addr_posted ; sig_rd_xfer_cmplt <= rd_xfer_cmplt ; -- Write Side (S2MM) Control Flags port connections ok_to_post_wr_addr <= sig_ok_to_post_wr_addr ; sig_wr_addr_posted <= wr_addr_posted ; sig_wr_xfer_cmplt <= wr_xfer_cmplt ; sig_wr_ld_nxt_len <= wr_ld_nxt_len ; sig_len_fifo_data_in <= wr_len ; -- Output Stream Port connections sig_sout2sf_tready <= sout2sf_tready ; sf2sout_tvalid <= sig_sf2sout_tvalid ; sf2sout_tdata <= sig_sf2sout_tdata ; sf2sout_tkeep <= sig_sf2sout_tkeep ; sf2sout_tlast <= sig_sf2sout_tlast and sig_sf2sout_tvalid ; -- Input Stream port connections sf2sin_tready <= sig_strm_sin_ready; sig_strm_sin_ready <= not(sig_data_fifo_full); -- Throttle if Read Side Data fifo goes full. -- This should never happen if read address -- posting control is working properly. sig_good_sin_strm_dbeat <= sin2sf_tvalid and sig_strm_sin_ready; ---------------------------------------------------------------- -- Token Counter Logic -- Predicting fifo space availability at some point in the -- future is based on managing a virtual pool of transfer tokens. -- A token represents 1 max length burst worth of space in the -- Data FIFO. ---------------------------------------------------------------- -- calculate how many tokens are commited to pending transfers sig_tokens_commited <= TOKEN_CNT_MAX - sig_token_cntr; -- Decrement the token counter when a token is -- borrowed sig_decr_token_cntr <= '1' when (sig_rd_addr_posted = '1' and sig_token_eq_zero = '0') else '0'; -- Increment the token counter when a -- token is returned. sig_incr_token_cntr <= '1' when (sig_rd_xfer_cmplt = '1' and sig_token_eq_max = '0') else '0'; -- Detect when the xfer token count is at max value sig_token_eq_max <= '1' when (sig_token_cntr = TOKEN_CNT_MAX) Else '0'; -- Detect when the xfer token count is at one sig_token_eq_one <= '1' when (sig_token_cntr = TOKEN_CNT_ONE) Else '0'; -- Detect when the xfer token count is at zero sig_token_eq_zero <= '1' when (sig_token_cntr = TOKEN_CNT_ZERO) Else '0'; -- Look ahead to see if the xfer token pool is going empty sig_taking_last_token <= '1' When (sig_token_eq_one = '1' and sig_rd_addr_posted = '1') Else '0'; ------------------------------------------------------------- -- Synchronous Process with Sync Reset -- -- Label: IMP_TOKEN_CMTR -- -- Process Description: -- Implements the Token counter -- ------------------------------------------------------------- IMP_TOKEN_CMTR : process (aclk) begin if (aclk'event and aclk = '1') then if (reset = '1' ) then sig_token_cntr <= TOKEN_CNT_MAX; elsif (sig_incr_token_cntr = '1' and sig_decr_token_cntr = '0') then sig_token_cntr <= sig_token_cntr + TOKEN_CNT_ONE; elsif (sig_incr_token_cntr = '0' and sig_decr_token_cntr = '1') then sig_token_cntr <= sig_token_cntr - TOKEN_CNT_ONE; else null; -- hold current value end if; end if; end process IMP_TOKEN_CMTR; ------------------------------------------------------------- -- Synchronous Process with Sync Reset -- -- Label: IMP_TOKEN_AVAIL_FLAG -- -- Process Description: -- Implements the flag indicating that the AXI Read Master -- can post a read address request on the AXI4 bus. -- -- Read address posting can occur if: -- -- - The write side LEN fifo is not empty. -- - The commited plus actual Data FIFO space is less than -- the stall threshold (a max length read burst can fit -- in the data FIFO without overflow). -- - The max allowed commited read count has not been reached. -- -- The flag is cleared after each address has been posted to -- ensure a second unauthotized post occurs. ------------------------------------------------------------- IMP_TOKEN_AVAIL_FLAG : process (aclk) begin if (aclk'event and aclk = '1') then if (reset = '1' or sig_rd_addr_posted = '1') then sig_ok_to_post_rd_addr <= '0'; else sig_ok_to_post_rd_addr <= not(sig_stall_rd_addr_posts) and -- the commited Data FIFO space is approaching full not(sig_token_eq_zero) and -- max allowed pending reads has not been reached not(sig_taking_last_token); -- the max allowed pending reads is about to be reached end if; end if; end process IMP_TOKEN_AVAIL_FLAG; ---------------------------------------------------------------- -- Data FIFO Logic ------------------------------------------ ---------------------------------------------------------------- -- FIFO Output to output stream attachments sig_sf2sout_tvalid <= sig_data_fifo_dvalid ; sig_sf2sout_tdata <= sig_data_fifo_data_out(DATA_OUT_MSB_INDEX downto DATA_OUT_LSB_INDEX); sig_sf2sout_tkeep <= sig_data_fifo_data_out(TSTRB_OUT_MSB_INDEX downto TSTRB_OUT_LSB_INDEX); sig_sf2sout_tlast <= sig_data_fifo_data_out(TLAST_OUT_INDEX) ; -- Stall Threshold calculations sig_fifo_wr_cnt_unsgnd <= UNSIGNED(sig_data_fifo_wr_cnt); sig_wrcnt_mblen_slice <= sig_fifo_wr_cnt_unsgnd(DATA_FIFO_CNT_WIDTH-1 downto DF_WRCNT_RIP_LS_INDEX); sig_commit_plus_actual <= RESIZE(sig_tokens_commited, THRESH_COMPARE_WIDTH) + RESIZE(sig_wrcnt_mblen_slice, THRESH_COMPARE_WIDTH); -- Compare the commited read space plus the actual used space against the -- stall threshold. Assert the read address posting stall flag if the -- threshold is met or exceeded. sig_stall_rd_addr_posts <= '1' when (sig_commit_plus_actual > RD_ADDR_POST_STALL_THRESH_US) Else '0'; -- FIFO Rd/WR Controls sig_push_data_fifo <= sig_good_sin_strm_dbeat; sig_pop_data_fifo <= sig_sout2sf_tready and sig_data_fifo_dvalid; -- Concatonate the Stream inputs into the single FIFO data in value sig_data_fifo_data_in <= sin2sf_tlast & sin2sf_tkeep & sin2sf_tdata; ------------------------------------------------------------ -- Instance: I_DATA_FIFO -- -- Description: -- Implements the Store and Forward data FIFO (synchronous) -- ------------------------------------------------------------ I_DATA_FIFO : entity axi_cdma_v4_1.axi_cdma_sfifo_autord generic map ( C_DWIDTH => DATA_FIFO_WIDTH , C_DEPTH => DATA_FIFO_DEPTH , C_DATA_CNT_WIDTH => DATA_FIFO_CNT_WIDTH , C_NEED_ALMOST_EMPTY => NOT_NEEDED , C_NEED_ALMOST_FULL => NOT_NEEDED , C_USE_BLKMEM => BLK_MEM_FIFO , C_FAMILY => C_FAMILY ) port map ( -- Inputs SFIFO_Sinit => reset , SFIFO_Clk => aclk , SFIFO_Wr_en => sig_push_data_fifo , SFIFO_Din => sig_data_fifo_data_in , SFIFO_Rd_en => sig_pop_data_fifo , SFIFO_Clr_Rd_Data_Valid => LOGIC_LOW , -- Outputs SFIFO_DValid => sig_data_fifo_dvalid , SFIFO_Dout => sig_data_fifo_data_out , SFIFO_Full => sig_data_fifo_full , SFIFO_Empty => open , SFIFO_Almost_full => open , SFIFO_Almost_empty => open , SFIFO_Rd_count => open , SFIFO_Rd_count_minus1 => open , SFIFO_Wr_count => sig_data_fifo_wr_cnt , SFIFO_Rd_ack => open ); -------------------------------------------------------------------- -- Write Side Control Logic -------------------------------------------------------------------- -- Convert the LEN fifo data output to unsigned sig_len_fifo_len_out_un <= unsigned(sig_len_fifo_data_out); -- Resize the unsigned LEN output to the Data FIFO writecount width sig_resized_fifo_len <= RESIZE(sig_len_fifo_len_out_un , DATA_FIFO_CNT_WIDTH); -- The actual number of databeats needed for the queued write transfer -- is the current LEN fifo output plus 1. sig_num_wr_dbeats_needed <= sig_resized_fifo_len + UNCOM_WRCNT_1; -- Compare the uncommited receved data beat count to that needed -- for the next queued write request. sig_enough_dbeats_rcvd <= '1' When (sig_num_wr_dbeats_needed <= sig_uncom_wrcnt) else '0'; -- Increment the uncommited databeat counter on a good input -- stream databeat (Read Side of SF) sig_incr_uncom_wrcnt <= sig_good_sin_strm_dbeat; -- Subtract the current number of databeats needed from the -- uncommited databeat counter when the associated transfer -- address/qualifiers have been posted to the AXI Write -- Address Channel sig_sub_len_uncom_wrcnt <= sig_wr_addr_posted; ------------------------------------------------------------- -- Synchronous Process with Sync Reset -- -- Label: IMP_UNCOM_DBEAT_CNTR -- -- Process Description: -- Implements the counter that keeps track of the received read -- data beat count that has not been commited to a transfer on -- the write side with a Write Address posting. -- ------------------------------------------------------------- IMP_UNCOM_DBEAT_CNTR : process (aclk) begin if (aclk'event and aclk = '1') then if (reset = '1') then sig_uncom_wrcnt <= UNCOM_WRCNT_0; elsif (sig_incr_uncom_wrcnt = '1' and sig_sub_len_uncom_wrcnt = '1') then sig_uncom_wrcnt <= sig_uncom_wrcnt - sig_resized_fifo_len; elsif (sig_incr_uncom_wrcnt = '1' and sig_sub_len_uncom_wrcnt = '0') then sig_uncom_wrcnt <= sig_uncom_wrcnt + UNCOM_WRCNT_1; elsif (sig_incr_uncom_wrcnt = '0' and sig_sub_len_uncom_wrcnt = '1') then sig_uncom_wrcnt <= sig_uncom_wrcnt - sig_num_wr_dbeats_needed; else null; -- hold current value end if; end if; end process IMP_UNCOM_DBEAT_CNTR; ------------------------------------------------------------- -- Synchronous Process with Sync Reset -- -- Label: IMP_WR_ADDR_POST_FLAG -- -- Process Description: -- Implements the flag indicating that the pending write -- transfer's data beat count has been received on the input -- side of the Data FIFO. This means the Write side can post -- the associated write address to the AXI4 bus and the -- associated write data transfer can complete without CDMA -- throttling the Write Data Channel. -- -- The flag is cleared immediately after an address is posted -- to prohibit a second unauthorized posting while the control -- logic stabilizes to the next LEN FIFO value --. ------------------------------------------------------------- IMP_WR_ADDR_POST_FLAG : process (aclk) begin if (aclk'event and aclk = '1') then if (reset = '1' or sig_wr_addr_posted = '1') then sig_ok_to_post_wr_addr <= '0'; else sig_ok_to_post_wr_addr <= not(sig_len_fifo_empty) and sig_enough_dbeats_rcvd; end if; end if; end process IMP_WR_ADDR_POST_FLAG; ------------------------------------------------------------- -- LEN FIFO logic sig_push_len_fifo <= sig_wr_ld_nxt_len and not(sig_len_fifo_full); sig_pop_len_fifo <= wr_addr_posted and not(sig_len_fifo_empty); ------------------------------------------------------------ -- Instance: I_WR_LEN_FIFO -- -- Description: -- Implement the LEN FIFO using SRL FIFO elements -- ------------------------------------------------------------ I_WR_LEN_FIFO : entity lib_srl_fifo_v1_0.srl_fifo_f generic map ( C_DWIDTH => WR_LEN_FIFO_DWIDTH , C_DEPTH => WR_LEN_FIFO_DEPTH , C_FAMILY => C_FAMILY ) port map ( Clk => aclk , Reset => reset , FIFO_Write => sig_push_len_fifo , Data_In => sig_len_fifo_data_in , FIFO_Read => sig_pop_len_fifo , Data_Out => sig_len_fifo_data_out , FIFO_Empty => sig_len_fifo_empty , FIFO_Full => sig_len_fifo_full , Addr => open ); end implementation;	gpl-3.0	ec7a13ef49b119d66341a495658075c9	0.482047	4.521	false	false	false	false
mistryalok/Zedboard	learning/opencv_hls/xapp1167_vivado/sw/fast-corner/prj/solution1/syn/vhdl/image_filter_reg_int_s.vhd	2	1,002	-- ============================================================== -- RTL generated by Vivado(TM) HLS - High-Level Synthesis from C, C++ and SystemC -- Version: 2014.4 -- Copyright (C) 2014 Xilinx Inc. All rights reserved. -- -- =========================================================== library IEEE; use IEEE.std_logic_1164.all; use IEEE.numeric_std.all; entity image_filter_reg_int_s is port ( ap_clk : IN STD_LOGIC; ap_rst : IN STD_LOGIC; in_r : IN STD_LOGIC_VECTOR (31 downto 0); ap_return : OUT STD_LOGIC_VECTOR (31 downto 0); ap_ce : IN STD_LOGIC ); end; architecture behav of image_filter_reg_int_s is constant ap_const_logic_1 : STD_LOGIC := '1'; constant ap_const_logic_0 : STD_LOGIC := '0'; begin -- assign process. -- process (ap_clk) begin if (ap_clk'event and ap_clk = '1') then if ((ap_const_logic_1 = ap_ce)) then ap_return <= in_r; end if; end if; end process; end behav;	gpl-3.0	c8cc7babbf2badb0221072fe0044b77d	0.522954	3.515789	false	false	false	false
marco-c/leon-nexys2	grlib-gpl-1.3.4-b4140/designs/leon3-avnet-eval-xc4vlx60/config.vhd	1	6,156	----------------------------------------------------------------------------- -- LEON3 Demonstration design test bench configuration -- Copyright (C) 2009 Aeroflex Gaisler ------------------------------------------------------------------------------ library techmap; use techmap.gencomp.all; package config is -- Technology and synthesis options constant CFG_FABTECH : integer := virtex4; constant CFG_MEMTECH : integer := virtex4; constant CFG_PADTECH : integer := virtex4; constant CFG_NOASYNC : integer := 0; constant CFG_SCAN : integer := 0; -- Clock generator constant CFG_CLKTECH : integer := virtex4; constant CFG_CLKMUL : integer := (7); constant CFG_CLKDIV : integer := (5); constant CFG_OCLKDIV : integer := 1; constant CFG_OCLKBDIV : integer := 0; constant CFG_OCLKCDIV : integer := 0; constant CFG_PCIDLL : integer := 0; constant CFG_PCISYSCLK: integer := 0; constant CFG_CLK_NOFB : integer := 0; -- LEON3 processor core constant CFG_LEON3 : integer := 1; constant CFG_NCPU : integer := (1); constant CFG_NWIN : integer := (8); constant CFG_V8 : integer := 16#32# + 40; constant CFG_MAC : integer := 0; constant CFG_BP : integer := 1; constant CFG_SVT : integer := 1; constant CFG_RSTADDR : integer := 16#00000#; constant CFG_LDDEL : integer := (1); constant CFG_NOTAG : integer := 0; constant CFG_NWP : integer := (2); constant CFG_PWD : integer := 12; constant CFG_FPU : integer := 0 + 160 + 320; constant CFG_GRFPUSH : integer := 0; constant CFG_ICEN : integer := 1; constant CFG_ISETS : integer := 2; constant CFG_ISETSZ : integer := 8; constant CFG_ILINE : integer := 8; constant CFG_IREPL : integer := 0; constant CFG_ILOCK : integer := 0; constant CFG_ILRAMEN : integer := 0; constant CFG_ILRAMADDR: integer := 16#8E#; constant CFG_ILRAMSZ : integer := 1; constant CFG_DCEN : integer := 1; constant CFG_DSETS : integer := 2; constant CFG_DSETSZ : integer := 4; constant CFG_DLINE : integer := 4; constant CFG_DREPL : integer := 0; constant CFG_DLOCK : integer := 0; constant CFG_DSNOOP : integer := 0 + 0 + 40; constant CFG_DFIXED : integer := 16#0#; constant CFG_DLRAMEN : integer := 0; constant CFG_DLRAMADDR: integer := 16#8F#; constant CFG_DLRAMSZ : integer := 1; constant CFG_MMUEN : integer := 1; constant CFG_ITLBNUM : integer := 8; constant CFG_DTLBNUM : integer := 8; constant CFG_TLB_TYPE : integer := 0 + 12; constant CFG_TLB_REP : integer := 0; constant CFG_MMU_PAGE : integer := 0; constant CFG_DSU : integer := 1; constant CFG_ITBSZ : integer := 2; constant CFG_ATBSZ : integer := 2; constant CFG_LEON3FT_EN : integer := 0; constant CFG_IUFT_EN : integer := 0; constant CFG_FPUFT_EN : integer := 0; constant CFG_RF_ERRINJ : integer := 0; constant CFG_CACHE_FT_EN : integer := 0; constant CFG_CACHE_ERRINJ : integer := 0; constant CFG_LEON3_NETLIST: integer := 0; constant CFG_DISAS : integer := 0 + 0; constant CFG_PCLOW : integer := 2; -- AMBA settings constant CFG_DEFMST : integer := (0); constant CFG_RROBIN : integer := 1; constant CFG_SPLIT : integer := 0; constant CFG_FPNPEN : integer := 0; constant CFG_AHBIO : integer := 16#FFF#; constant CFG_APBADDR : integer := 16#800#; constant CFG_AHB_MON : integer := 0; constant CFG_AHB_MONERR : integer := 0; constant CFG_AHB_MONWAR : integer := 0; constant CFG_AHB_DTRACE : integer := 0; -- DSU UART constant CFG_AHB_UART : integer := 0; -- JTAG based DSU interface constant CFG_AHB_JTAG : integer := 1; -- Ethernet DSU constant CFG_DSU_ETH : integer := 1 + 0 + 0; constant CFG_ETH_BUF : integer := 4; constant CFG_ETH_IPM : integer := 16#C0A8#; constant CFG_ETH_IPL : integer := 16#010a#; constant CFG_ETH_ENM : integer := 16#020060#; constant CFG_ETH_ENL : integer := 16#000015#; -- LEON2 memory controller constant CFG_MCTRL_LEON2 : integer := 1; constant CFG_MCTRL_RAM8BIT : integer := 0; constant CFG_MCTRL_RAM16BIT : integer := 1; constant CFG_MCTRL_5CS : integer := 0; constant CFG_MCTRL_SDEN : integer := 0; constant CFG_MCTRL_SEPBUS : integer := 0; constant CFG_MCTRL_INVCLK : integer := 0; constant CFG_MCTRL_SD64 : integer := 0; constant CFG_MCTRL_PAGE : integer := 0 + 0; -- DDR controller constant CFG_DDRSP : integer := 0; constant CFG_DDRSP_INIT : integer := 0; constant CFG_DDRSP_FREQ : integer := 100; constant CFG_DDRSP_COL : integer := 9; constant CFG_DDRSP_SIZE : integer := 8; constant CFG_DDRSP_RSKEW : integer := 0; -- Xilinx MIG constant CFG_MIG_DDR2 : integer := 1; constant CFG_MIG_RANKS : integer := (1); constant CFG_MIG_COLBITS : integer := (10); constant CFG_MIG_ROWBITS : integer := (13); constant CFG_MIG_BANKBITS: integer := (2); constant CFG_MIG_HMASK : integer := 16#FE0#; -- AHB ROM constant CFG_AHBROMEN : integer := 0; constant CFG_AHBROPIP : integer := 0; constant CFG_AHBRODDR : integer := 16#000#; constant CFG_ROMADDR : integer := 16#000#; constant CFG_ROMMASK : integer := 16#E00# + 16#000#; -- AHB RAM constant CFG_AHBRAMEN : integer := 0; constant CFG_AHBRSZ : integer := 1; constant CFG_AHBRADDR : integer := 16#A00#; constant CFG_AHBRPIPE : integer := 0; -- Gaisler Ethernet core constant CFG_GRETH : integer := 1; constant CFG_GRETH1G : integer := 0; constant CFG_ETH_FIFO : integer := 32; -- UART 1 constant CFG_UART1_ENABLE : integer := 1; constant CFG_UART1_FIFO : integer := 8; -- LEON3 interrupt controller constant CFG_IRQ3_ENABLE : integer := 1; constant CFG_IRQ3_NSEC : integer := 0; -- Modular timer constant CFG_GPT_ENABLE : integer := 1; constant CFG_GPT_NTIM : integer := (2); constant CFG_GPT_SW : integer := (8); constant CFG_GPT_TW : integer := (32); constant CFG_GPT_IRQ : integer := (8); constant CFG_GPT_SEPIRQ : integer := 1; constant CFG_GPT_WDOGEN : integer := 0; constant CFG_GPT_WDOG : integer := 16#0#; -- GPIO port constant CFG_GRGPIO_ENABLE : integer := 1; constant CFG_GRGPIO_IMASK : integer := 16#0000#; constant CFG_GRGPIO_WIDTH : integer := (8); -- GRLIB debugging constant CFG_DUART : integer := 0; end;	gpl-2.0	23c4bee071778e2625c35685fe26dc45	0.643437	3.608441	false	false	false	false
marco-c/leon-nexys2	grlib-gpl-1.3.4-b4140/designs/leon3-xilinx-sp601/ahb2mig_sp601.vhd	1	17,376	------------------------------------------------------------------------------ -- This file is a part of the GRLIB VHDL IP LIBRARY -- Copyright (C) 2003 - 2008, Gaisler Research -- Copyright (C) 2008 - 2013, Aeroflex Gaisler -- -- This program is free software; you can redistribute it and/or modify -- it under the terms of the GNU General Public License as published by -- the Free Software Foundation; either version 2 of the License, or -- (at your option) any later version. -- -- This program is distributed in the hope that it will be useful, -- but WITHOUT ANY WARRANTY; without even the implied warranty of -- MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the -- GNU General Public License for more details. -- -- You should have received a copy of the GNU General Public License -- along with this program; if not, write to the Free Software -- Foundation, Inc., 59 Temple Place, Suite 330, Boston, MA 02111-1307 USA ------------------------------------------------------------------------------- -- Entity: ahb2mig_sp601 -- File: ahb2mig_sp601.vhd -- Author: Jiri Gaisler - Aeroflex Gaisler AB -- -- This is a AHB-2.0 interface for the Xilinx Spartan-6 MIG. -- One bidir 32-bit port is used for the main AHB bus. ------------------------------------------------------------------------------- library ieee; use ieee.std_logic_1164.all; library grlib; use grlib.amba.all; use grlib.stdlib.all; use grlib.devices.all; entity ahb2mig_sp601 is generic( hindex : integer := 0; haddr : integer := 0; hmask : integer := 16#f00#; pindex : integer := 0; paddr : integer := 0; pmask : integer := 16#fff# ); port( mcb3_dram_dq : inout std_logic_vector(15 downto 0); mcb3_dram_a : out std_logic_vector(12 downto 0); mcb3_dram_ba : out std_logic_vector(2 downto 0); mcb3_dram_ras_n : out std_logic; mcb3_dram_cas_n : out std_logic; mcb3_dram_we_n : out std_logic; mcb3_dram_odt : out std_logic; mcb3_dram_cke : out std_logic; mcb3_dram_dm : out std_logic; mcb3_dram_udqs : inout std_logic; mcb3_rzq : inout std_logic; mcb3_zio : inout std_logic; mcb3_dram_udm : out std_logic; mcb3_dram_dqs : inout std_logic; mcb3_dram_ck : out std_logic; mcb3_dram_ck_n : out std_logic; ahbso : out ahb_slv_out_type; ahbsi : in ahb_slv_in_type; apbi : in apb_slv_in_type; apbo : out apb_slv_out_type; calib_done : out std_logic; test_error : out std_logic; rst_n_syn : in std_logic; rst_n_async : in std_logic; clk_amba : in std_logic; clk_mem_n : in std_logic; clk_mem_p : in std_logic ); end ; architecture rtl of ahb2mig_sp601 is component mig_37 generic ( C3_P0_MASK_SIZE : integer := 4; C3_P0_DATA_PORT_SIZE : integer := 32; C3_P1_MASK_SIZE : integer := 4; C3_P1_DATA_PORT_SIZE : integer := 32; C3_MEMCLK_PERIOD : integer := 5000; -- Memory data transfer clock period. C3_RST_ACT_LOW : integer := 0; -- # = 1 for active low reset, -- # = 0 for active high reset. C3_INPUT_CLK_TYPE : string := "DIFFERENTIAL"; -- input clock type DIFFERENTIAL or SINGLE_ENDED. C3_CALIB_SOFT_IP : string := "TRUE"; -- # = TRUE, Enables the soft calibration logic, -- # = FALSE, Disables the soft calibration logic. C3_SIMULATION : string := "FALSE"; -- # = TRUE, Simulating the design. Useful to reduce the simulation time, -- # = FALSE, Implementing the design. DEBUG_EN : integer := 0; -- # = 1, Enable debug signals/controls, -- = 0, Disable debug signals/controls. C3_MEM_ADDR_ORDER : string := "ROW_BANK_COLUMN"; -- The order in which user address is provided to the memory controller, -- ROW_BANK_COLUMN or BANK_ROW_COLUMN. C3_NUM_DQ_PINS : integer := 16; -- External memory data width. C3_MEM_ADDR_WIDTH : integer := 13; -- External memory address width. C3_MEM_BANKADDR_WIDTH : integer := 3 -- External memory bank address width. ); port ( mcb3_dram_dq : inout std_logic_vector(C3_NUM_DQ_PINS-1 downto 0); mcb3_dram_a : out std_logic_vector(C3_MEM_ADDR_WIDTH-1 downto 0); mcb3_dram_ba : out std_logic_vector(C3_MEM_BANKADDR_WIDTH-1 downto 0); mcb3_dram_ras_n : out std_logic; mcb3_dram_cas_n : out std_logic; mcb3_dram_we_n : out std_logic; mcb3_dram_odt : out std_logic; mcb3_dram_cke : out std_logic; mcb3_dram_dm : out std_logic; mcb3_dram_udqs : inout std_logic; mcb3_dram_udqs_n : inout std_logic; mcb3_rzq : inout std_logic; mcb3_zio : inout std_logic; mcb3_dram_udm : out std_logic; c3_sys_clk_p : in std_logic; c3_sys_clk_n : in std_logic; c3_sys_rst_n : in std_logic; c3_calib_done : out std_logic; c3_clk0 : out std_logic; c3_rst0 : out std_logic; mcb3_dram_dqs : inout std_logic; mcb3_dram_dqs_n : inout std_logic; mcb3_dram_ck : out std_logic; mcb3_dram_ck_n : out std_logic; c3_p0_cmd_clk : in std_logic; c3_p0_cmd_en : in std_logic; c3_p0_cmd_instr : in std_logic_vector(2 downto 0); c3_p0_cmd_bl : in std_logic_vector(5 downto 0); c3_p0_cmd_byte_addr : in std_logic_vector(29 downto 0); c3_p0_cmd_empty : out std_logic; c3_p0_cmd_full : out std_logic; c3_p0_wr_clk : in std_logic; c3_p0_wr_en : in std_logic; c3_p0_wr_mask : in std_logic_vector(C3_P0_MASK_SIZE - 1 downto 0); c3_p0_wr_data : in std_logic_vector(C3_P0_DATA_PORT_SIZE - 1 downto 0); c3_p0_wr_full : out std_logic; c3_p0_wr_empty : out std_logic; c3_p0_wr_count : out std_logic_vector(6 downto 0); c3_p0_wr_underrun : out std_logic; c3_p0_wr_error : out std_logic; c3_p0_rd_clk : in std_logic; c3_p0_rd_en : in std_logic; c3_p0_rd_data : out std_logic_vector(C3_P0_DATA_PORT_SIZE - 1 downto 0); c3_p0_rd_full : out std_logic; c3_p0_rd_empty : out std_logic; c3_p0_rd_count : out std_logic_vector(6 downto 0); c3_p0_rd_overflow : out std_logic; c3_p0_rd_error : out std_logic ); end component; type bstate_type is (idle, start, read1); constant hconfig : ahb_config_type := ( 0 => ahb_device_reg ( VENDOR_GAISLER, GAISLER_MIGDDR2, 0, 0, 0), 4 => ahb_membar(haddr, '1', '1', hmask), -- 5 => ahb_iobar(ioaddr, iomask), others => zero32); constant pconfig : apb_config_type := ( 0 => ahb_device_reg ( VENDOR_GAISLER, GAISLER_MIGDDR2, 0, 0, 0), 1 => apb_iobar(paddr, pmask)); type reg_type is record bstate : bstate_type; cmd_bl : std_logic_vector(5 downto 0); wr_count : std_logic_vector(6 downto 0); rd_cnt : std_logic_vector(5 downto 0); hready : std_logic; hsel : std_logic; hwrite : std_logic; htrans : std_logic_vector(1 downto 0); hburst : std_logic_vector(2 downto 0); hsize : std_logic_vector(2 downto 0); hrdata : std_logic_vector(31 downto 0); haddr : std_logic_vector(31 downto 0); hmaster : std_logic_vector(3 downto 0); end record; type mcb_type is record cmd_en : std_logic; cmd_instr : std_logic_vector(2 downto 0); cmd_empty : std_logic; cmd_full : std_logic; cmd_bl : std_logic_vector(5 downto 0); cmd_byte_addr : std_logic_vector(29 downto 0); wr_full : std_logic; wr_empty : std_logic; wr_underrun : std_logic; wr_error : std_logic; wr_mask : std_logic_vector(3 downto 0); wr_en : std_logic; wr_data : std_logic_vector(31 downto 0); wr_count : std_logic_vector(6 downto 0); rd_data : std_logic_vector(31 downto 0); rd_full : std_logic; rd_empty : std_logic; rd_count : std_logic_vector(6 downto 0); rd_overflow : std_logic; rd_error : std_logic; rd_en : std_logic; end record; signal r, rin : reg_type; signal i : mcb_type; begin comb: process( rst_n_syn, r, ahbsi, i ) variable v : reg_type; variable wmask : std_logic_vector(3 downto 0); variable wr_en : std_logic; variable cmd_en : std_logic; variable cmd_instr : std_logic_vector(2 downto 0); variable rd_en : std_logic; variable cmd_bl : std_logic_vector(5 downto 0); variable hwdata : std_logic_vector(31 downto 0); variable readdata : std_logic_vector(31 downto 0); begin v := r; wr_en := '0'; cmd_en := '0'; cmd_instr := "000"; rd_en := '0'; if (ahbsi.hready = '1') then if (ahbsi.hsel(hindex) and ahbsi.htrans(1)) = '1' then v.hsel := '1'; v.hburst := ahbsi.hburst; v.hwrite := ahbsi.hwrite; v.hsize := ahbsi.hsize; v.hmaster := ahbsi.hmaster; v.hready := '0'; if ahbsi.htrans(0) = '0' then v.haddr := ahbsi.haddr; end if; else v.hsel := '0'; v.hready := '1'; end if; v.htrans := ahbsi.htrans; end if; hwdata := ahbsi.hwdata(15 downto 0) & ahbsi.hwdata(31 downto 16); case r.hsize(1 downto 0) is when "00" => wmask := not decode(r.haddr(1 downto 0)); case r.haddr(1 downto 0) is when "00" => wmask := "1101"; when "01" => wmask := "1110"; when "10" => wmask := "0111"; when others => wmask := "1011"; end case; when "01" => wmask := not decode(r.haddr(1 downto 0)); wmask(3) := wmask(2); wmask(1) := wmask(0); when others => wmask := "0000"; end case; i.wr_mask <= wmask; cmd_bl := r.cmd_bl; case r.bstate is when idle => if v.hsel = '1' then v.bstate := start; v.hready := ahbsi.hwrite and not i.cmd_full and not i.wr_full; v.haddr := ahbsi.haddr; end if; v.cmd_bl := (others => '0'); when start => if r.hwrite = '1' then v.haddr := r.haddr; if r.hready = '1' then v.cmd_bl := r.cmd_bl + 1; v.hready := '1'; wr_en := '1'; if (ahbsi.htrans /= "11") then if v.hsel = '1' then if (ahbsi.hwrite = '0') or (i.wr_count >= "0000100") then v.hready := '0'; else v.hready := '1'; end if; else v.bstate := idle; end if; v.cmd_bl := (others => '0'); v.haddr := ahbsi.haddr; cmd_en := '1'; elsif (i.cmd_full = '1') then v.hready := '0'; elsif (i.wr_count >= "0101111") then v.hready := '0'; cmd_en := '1'; v.cmd_bl := (others => '0'); v.haddr := ahbsi.haddr; end if; else if (i.cmd_full = '0') and (i.wr_count <= "0001111") then v.hready := '1'; end if; end if; else if i.cmd_full = '0' then cmd_en := '1'; cmd_instr(0) := '1'; v.cmd_bl := "000" & not r.haddr(4 downto 2); cmd_bl := v.cmd_bl; v.bstate := read1; end if; end if; when read1 => v.hready := '0'; if (r.rd_cnt = "000000") then -- flush data from previous line if (i.rd_empty = '0') or ((r.hready = '1') and (ahbsi.htrans /= "11")) then v.hrdata(31 downto 0) := i.rd_data(15 downto 0) & i.rd_data(31 downto 16); v.hready := '1'; if (i.rd_empty = '0') then v.cmd_bl := r.cmd_bl - 1; rd_en := '1'; end if; if (r.cmd_bl = "000000") or (ahbsi.htrans /= "11") then if (ahbsi.hsel(hindex) = '1') and (ahbsi.htrans = "10") and (r.hready = '1') then v.bstate := start; v.hready := ahbsi.hwrite and not i.cmd_full and not i.wr_full; v.cmd_bl := (others => '0'); else v.bstate := idle; end if; if (i.rd_empty = '1') then v.rd_cnt := r.cmd_bl + 1; else v.rd_cnt := r.cmd_bl; end if; end if; end if; end if; when others => end case; readdata := (others => '0'); -- case apbi.paddr(5 downto 2) is -- when "0000" => readdata(nbits-1 downto 0) := r.din2; -- when "0001" => readdata(nbits-1 downto 0) := r.dout; -- when others => -- end case; readdata(20 downto 0) := i.rd_error & i.rd_overflow & i.wr_error & i.wr_underrun & i.cmd_full & i.rd_full & i.rd_empty & i.wr_full & i.wr_empty & r.rd_cnt & r.cmd_bl; if (r.rd_cnt /= "000000") and (i.rd_empty = '0') then rd_en := '1'; v.rd_cnt := r.rd_cnt - 1; end if; if rst_n_syn = '0' then v.rd_cnt := "000000"; v.bstate := idle; v.hready := '1'; end if; rin <= v; apbo.prdata <= readdata; i.rd_en <= rd_en; i.wr_en <= wr_en; i.cmd_bl <= cmd_bl; i.cmd_en <= cmd_en; i.cmd_instr <= cmd_instr; i.wr_data <= hwdata; end process; i.cmd_byte_addr <= r.haddr(29 downto 2) & "00"; ahbso.hready <= r.hready; ahbso.hresp <= "00"; --r.hresp; ahbso.hrdata <= r.hrdata; ahbso.hconfig <= hconfig; ahbso.hirq <= (others => '0'); ahbso.hindex <= hindex; ahbso.hsplit <= (others => '0'); apbo.pindex <= pindex; apbo.pconfig <= pconfig; regs : process(clk_amba) begin if rising_edge(clk_amba) then r <= rin; end if; end process; MCB_inst : entity work.mig_37 generic map( C3_P0_MASK_SIZE => 4, C3_P0_DATA_PORT_SIZE => 32, C3_P1_MASK_SIZE => 4, C3_P1_DATA_PORT_SIZE => 32, C3_MEMCLK_PERIOD => 5000, C3_RST_ACT_LOW => 1, -- C3_INPUT_CLK_TYPE => "DIFFERENTIAL", C3_CALIB_SOFT_IP => "TRUE", -- pragma translate_off C3_SIMULATION => "TRUE", -- pragma translate_on C3_MEM_ADDR_ORDER => "BANK_ROW_COLUMN", C3_NUM_DQ_PINS => 16, C3_MEM_ADDR_WIDTH => 13, C3_MEM_BANKADDR_WIDTH => 3 -- C3_MC_CALIB_BYPASS => "YES" ) port map ( mcb3_dram_dq => mcb3_dram_dq, mcb3_dram_a => mcb3_dram_a, mcb3_dram_ba => mcb3_dram_ba, mcb3_dram_ras_n => mcb3_dram_ras_n, mcb3_dram_cas_n => mcb3_dram_cas_n, mcb3_dram_we_n => mcb3_dram_we_n, mcb3_dram_odt => mcb3_dram_odt, mcb3_dram_cke => mcb3_dram_cke, mcb3_dram_dm => mcb3_dram_dm, mcb3_dram_udqs => mcb3_dram_udqs, mcb3_rzq => mcb3_rzq, mcb3_zio => mcb3_zio, mcb3_dram_udm => mcb3_dram_udm, c3_sys_clk_p => clk_mem_p, c3_sys_clk_n => clk_mem_n, c3_sys_rst_n => rst_n_async, c3_calib_done => calib_done, c3_clk0 => open, c3_rst0 => open, mcb3_dram_dqs => mcb3_dram_dqs, mcb3_dram_ck => mcb3_dram_ck, mcb3_dram_ck_n => mcb3_dram_ck_n, c3_p0_cmd_clk => clk_amba, c3_p0_cmd_en => i.cmd_en, c3_p0_cmd_instr => i.cmd_instr, c3_p0_cmd_bl => i.cmd_bl, c3_p0_cmd_byte_addr => i.cmd_byte_addr, c3_p0_cmd_empty => i.cmd_empty, c3_p0_cmd_full => i.cmd_full, c3_p0_wr_clk => clk_amba, c3_p0_wr_en => i.wr_en, c3_p0_wr_mask => i.wr_mask, c3_p0_wr_data => i.wr_data, c3_p0_wr_full => i.wr_full, c3_p0_wr_empty => i.wr_empty, c3_p0_wr_count => i.wr_count, c3_p0_wr_underrun => i.wr_underrun, c3_p0_wr_error => i.wr_error, c3_p0_rd_clk => clk_amba, c3_p0_rd_en => i.rd_en, c3_p0_rd_data => i.rd_data, c3_p0_rd_full => i.rd_full, c3_p0_rd_empty => i.rd_empty, c3_p0_rd_count => i.rd_count, c3_p0_rd_overflow => i.rd_overflow, c3_p0_rd_error => i.rd_error ); end;	gpl-2.0	70231b66c9d79aa795f970bf84697229	0.493669	3.176019	false	false	false	false
marco-c/leon-nexys2	grlib-gpl-1.3.4-b4140/lib/techmap/unisim/tap_unisim.vhd	1	24,308	------------------------------------------------------------------------------ -- This file is a part of the GRLIB VHDL IP LIBRARY -- Copyright (C) 2003 - 2008, Gaisler Research -- Copyright (C) 2008 - 2013, Aeroflex Gaisler -- -- This program is free software; you can redistribute it and/or modify -- it under the terms of the GNU General Public License as published by -- the Free Software Foundation; either version 2 of the License, or -- (at your option) any later version. -- -- This program is distributed in the hope that it will be useful, -- but WITHOUT ANY WARRANTY; without even the implied warranty of -- MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the -- GNU General Public License for more details. -- -- You should have received a copy of the GNU General Public License -- along with this program; if not, write to the Free Software -- Foundation, Inc., 59 Temple Place, Suite 330, Boston, MA 02111-1307 USA ----------------------------------------------------------------------------- -- Entity: tap_xilinx -- File: tap_xilinx.vhd -- Author: Edvin Catovic, Jiri Gaisler - Gaisler Research -- Description: Xilinx TAP controllers wrappers ------------------------------------------------------------------------------ library ieee; use ieee.std_logic_1164.all; -- pragma translate_off library unisim; use unisim.all; -- pragma translate_on entity virtex_tap is port ( tapi_tdo1 : in std_ulogic; tapi_tdo2 : in std_ulogic; tapo_tck : out std_ulogic; tapo_tdi : out std_ulogic; tapo_rst : out std_ulogic; tapo_capt : out std_ulogic; tapo_shft : out std_ulogic; tapo_upd : out std_ulogic; tapo_xsel1 : out std_ulogic; tapo_xsel2 : out std_ulogic ); end; architecture rtl of virtex_tap is component BSCAN_VIRTEX port (CAPTURE : out STD_ULOGIC; DRCK1 : out STD_ULOGIC; DRCK2 : out STD_ULOGIC; RESET : out STD_ULOGIC; SEL1 : out STD_ULOGIC; SEL2 : out STD_ULOGIC; SHIFT : out STD_ULOGIC; TDI : out STD_ULOGIC; UPDATE : out STD_ULOGIC; TDO1 : in STD_ULOGIC; TDO2 : in STD_ULOGIC); end component; signal drck1, drck2, sel1, sel2 : std_ulogic; attribute dont_touch : boolean; attribute dont_touch of u0 : label is true; begin u0 : BSCAN_VIRTEX port map ( DRCK1 => drck1, DRCK2 => drck2, RESET => tapo_rst, SEL1 => sel1, SEL2 => sel2, SHIFT => tapo_shft, TDI => tapo_tdi, UPDATE => tapo_upd, TDO1 => tapi_tdo1, TDO2 => tapi_tdo2); tapo_tck <= drck1 when sel1 = '1' else drck2; tapo_xsel1 <= sel1; tapo_xsel2 <= sel2; tapo_capt <= '0'; end; library ieee; use ieee.std_logic_1164.all; -- pragma translate_off library unisim; use unisim.all; -- pragma translate_on entity virtex2_tap is port ( tapi_tdo1 : in std_ulogic; tapi_tdo2 : in std_ulogic; tapo_tck : out std_ulogic; tapo_tdi : out std_ulogic; tapo_rst : out std_ulogic; tapo_capt : out std_ulogic; tapo_shft : out std_ulogic; tapo_upd : out std_ulogic; tapo_xsel1 : out std_ulogic; tapo_xsel2 : out std_ulogic ); end; architecture rtl of virtex2_tap is component BSCAN_VIRTEX2 port (CAPTURE : out STD_ULOGIC; DRCK1 : out STD_ULOGIC; DRCK2 : out STD_ULOGIC; RESET : out STD_ULOGIC; SEL1 : out STD_ULOGIC; SEL2 : out STD_ULOGIC; SHIFT : out STD_ULOGIC; TDI : out STD_ULOGIC; UPDATE : out STD_ULOGIC; TDO1 : in STD_ULOGIC; TDO2 : in STD_ULOGIC); end component; signal drck1, drck2, sel1, sel2 : std_ulogic; attribute dont_touch : boolean; attribute dont_touch of u0 : label is true; begin u0 : BSCAN_VIRTEX2 port map (CAPTURE => tapo_capt, DRCK1 => drck1, DRCK2 => drck2, RESET => tapo_rst, SEL1 => sel1, SEL2 => sel2, SHIFT => tapo_shft, TDI => tapo_tdi, UPDATE => tapo_upd, TDO1 => tapi_tdo1, TDO2 => tapi_tdo2); tapo_tck <= drck1 when sel1 = '1' else drck2; tapo_xsel1 <= sel1; tapo_xsel2 <= sel2; end; library ieee; use ieee.std_logic_1164.all; -- pragma translate_off library unisim; use unisim.BSCAN_SPARTAN3; -- pragma translate_on entity spartan3_tap is port ( tapi_tdo1 : in std_ulogic; tapi_tdo2 : in std_ulogic; tapo_tck : out std_ulogic; tapo_tdi : out std_ulogic; tapo_rst : out std_ulogic; tapo_capt : out std_ulogic; tapo_shft : out std_ulogic; tapo_upd : out std_ulogic; tapo_xsel1 : out std_ulogic; tapo_xsel2 : out std_ulogic ); end; architecture rtl of spartan3_tap is component BSCAN_SPARTAN3 port (CAPTURE : out STD_ULOGIC; DRCK1 : out STD_ULOGIC; DRCK2 : out STD_ULOGIC; RESET : out STD_ULOGIC; SEL1 : out STD_ULOGIC; SEL2 : out STD_ULOGIC; SHIFT : out STD_ULOGIC; TDI : out STD_ULOGIC; UPDATE : out STD_ULOGIC; TDO1 : in STD_ULOGIC; TDO2 : in STD_ULOGIC); end component; signal drck1, drck2, sel1, sel2 : std_ulogic; attribute dont_touch : boolean; attribute dont_touch of u0 : label is true; begin u0 : BSCAN_SPARTAN3 port map (CAPTURE => tapo_capt, DRCK1 => drck1, DRCK2 => drck2, RESET => tapo_rst, SEL1 => sel1, SEL2 => sel2, SHIFT => tapo_shft, TDI => tapo_tdi, UPDATE => tapo_upd, TDO1 => tapi_tdo1, TDO2 => tapi_tdo2); tapo_tck <= drck1 when sel1 = '1' else drck2; tapo_xsel1 <= sel1; tapo_xsel2 <= sel2; end; library ieee; use ieee.std_logic_1164.all; -- pragma translate_off library unisim; use unisim.BSCAN_VIRTEX4; -- pragma translate_on entity virtex4_tap is port ( tapi_tdo1 : in std_ulogic; tapi_tdo2 : in std_ulogic; tapo_tck : out std_ulogic; tapo_tdi : out std_ulogic; tapo_rst : out std_ulogic; tapo_capt : out std_ulogic; tapo_shft : out std_ulogic; tapo_upd : out std_ulogic; tapo_xsel1 : out std_ulogic; tapo_xsel2 : out std_ulogic ); end; architecture rtl of virtex4_tap is component BSCAN_VIRTEX4 generic ( JTAG_CHAIN : integer := 1); port ( CAPTURE : out std_ulogic; DRCK : out std_ulogic; RESET : out std_ulogic; SEL : out std_ulogic; SHIFT : out std_ulogic; TDI : out std_ulogic; UPDATE : out std_ulogic; TDO : in std_ulogic); end component; signal drck1, drck2, sel1, sel2 : std_ulogic; signal capt1, capt2, rst1, rst2 : std_ulogic; signal shift1, shift2, tdi1, tdi2 : std_ulogic; signal update1, update2 : std_ulogic; attribute dont_touch : boolean; attribute dont_touch of u0 : label is true; attribute dont_touch of u1 : label is true; begin u0 : BSCAN_VIRTEX4 generic map (JTAG_CHAIN => 1) port map ( CAPTURE => capt1, DRCK => drck1, RESET => rst1, SEL => sel1, SHIFT => shift1, TDI => tdi1, UPDATE => update1, TDO => tapi_tdo1 ); u1 : BSCAN_VIRTEX4 generic map (JTAG_CHAIN => 2) port map ( CAPTURE => capt2, DRCK => drck2, RESET => rst2, SEL => sel2, SHIFT => shift2, TDI => tdi2, UPDATE => update2, TDO => tapi_tdo2 ); tapo_capt <= capt1 when sel1 = '1' else capt2; tapo_tck <= drck1 when sel1 = '1' else drck2; tapo_rst <= rst1 when sel1 = '1' else rst2; tapo_shft <= shift1 when sel1 = '1' else shift2; tapo_tdi <= tdi1 when sel1 = '1' else tdi2; tapo_upd <= update1 when sel1 ='1' else update2; tapo_xsel1 <= sel1; tapo_xsel2 <= sel2; end; library ieee; use ieee.std_logic_1164.all; -- pragma translate_off library unisim; use unisim.BSCAN_VIRTEX5; -- pragma translate_on entity virtex5_tap is port ( tapi_tdo1 : in std_ulogic; tapi_tdo2 : in std_ulogic; tapo_tck : out std_ulogic; tapo_tdi : out std_ulogic; tapo_rst : out std_ulogic; tapo_capt : out std_ulogic; tapo_shft : out std_ulogic; tapo_upd : out std_ulogic; tapo_xsel1 : out std_ulogic; tapo_xsel2 : out std_ulogic ); end; architecture rtl of virtex5_tap is component BSCAN_VIRTEX5 generic ( JTAG_CHAIN : integer := 1); port ( CAPTURE : out std_ulogic; DRCK : out std_ulogic; RESET : out std_ulogic; SEL : out std_ulogic; SHIFT : out std_ulogic; TDI : out std_ulogic; UPDATE : out std_ulogic; TDO : in std_ulogic); end component; signal drck1, drck2, sel1, sel2 : std_ulogic; signal capt1, capt2, rst1, rst2 : std_ulogic; signal shift1, shift2, tdi1, tdi2 : std_ulogic; signal update1, update2 : std_ulogic; attribute dont_touch : boolean; attribute dont_touch of u0 : label is true; attribute dont_touch of u1 : label is true; begin u0 : BSCAN_VIRTEX5 generic map (JTAG_CHAIN => 1) port map ( CAPTURE => capt1, DRCK => drck1, RESET => rst1, SEL => sel1, SHIFT => shift1, TDI => tdi1, UPDATE => update1, TDO => tapi_tdo1 ); u1 : BSCAN_VIRTEX5 generic map (JTAG_CHAIN => 2) port map ( CAPTURE => capt2, DRCK => drck2, RESET => rst2, SEL => sel2, SHIFT => shift2, TDI => tdi2, UPDATE => update2, TDO => tapi_tdo2 ); tapo_capt <= capt1 when sel1 = '1' else capt2; tapo_tck <= drck1 when sel1 = '1' else drck2; tapo_rst <= rst1 when sel1 = '1' else rst2; tapo_shft <= shift1 when sel1 = '1' else shift2; tapo_tdi <= tdi1 when sel1 = '1' else tdi2; tapo_upd <= update1 when sel1 ='1' else update2; tapo_xsel1 <= sel1; tapo_xsel2 <= sel2; end; library ieee; use ieee.std_logic_1164.all; -- pragma translate_off library unisim; use unisim.all; -- pragma translate_on entity virtex6_tap is port ( tapi_tdo1 : in std_ulogic; tapi_tdo2 : in std_ulogic; tapo_tck : out std_ulogic; tapo_tdi : out std_ulogic; tapo_rst : out std_ulogic; tapo_capt : out std_ulogic; tapo_shft : out std_ulogic; tapo_upd : out std_ulogic; tapo_xsel1 : out std_ulogic; tapo_xsel2 : out std_ulogic ); end; architecture rtl of virtex6_tap is component BSCAN_VIRTEX6 generic ( DISABLE_JTAG : boolean := FALSE; JTAG_CHAIN : integer := 1 ); port ( CAPTURE : out std_ulogic := 'H'; DRCK : out std_ulogic := 'H'; RESET : out std_ulogic := 'H'; RUNTEST : out std_ulogic := 'L'; SEL : out std_ulogic := 'L'; SHIFT : out std_ulogic := 'L'; TCK : out std_ulogic := 'L'; TDI : out std_ulogic := 'L'; TMS : out std_ulogic := 'L'; UPDATE : out std_ulogic := 'L'; TDO : in std_ulogic := 'X' ); end component; signal drck1, drck2, sel1, sel2 : std_ulogic; signal capt1, capt2, rst1, rst2 : std_ulogic; signal shift1, shift2, tdi1, tdi2 : std_ulogic; signal update1, update2 : std_ulogic; attribute dont_touch : boolean; attribute dont_touch of u0 : label is true; attribute dont_touch of u1 : label is true; begin u0 : BSCAN_VIRTEX6 generic map (JTAG_CHAIN => 1) port map ( CAPTURE => capt1, DRCK => drck1, RESET => rst1, SEL => sel1, SHIFT => shift1, TDI => tdi1, UPDATE => update1, TDO => tapi_tdo1, TCK => tapo_tck ); u1 : BSCAN_VIRTEX6 generic map (JTAG_CHAIN => 2) port map ( CAPTURE => capt2, DRCK => drck2, RESET => rst2, SEL => sel2, SHIFT => shift2, TDI => tdi2, UPDATE => update2, TDO => tapi_tdo2 ); tapo_capt <= capt1 when sel1 = '1' else capt2; tapo_rst <= rst1 when sel1 = '1' else rst2; tapo_shft <= shift1 when sel1 = '1' else shift2; tapo_tdi <= tdi1 when sel1 = '1' else tdi2; tapo_upd <= update1 when sel1 ='1' else update2; tapo_xsel1 <= sel1; tapo_xsel2 <= sel2; end; library ieee; use ieee.std_logic_1164.all; -- pragma translate_off library unisim; use unisim.all; -- pragma translate_on entity spartan6_tap is port ( tapi_tdo1 : in std_ulogic; tapi_tdo2 : in std_ulogic; tapo_tck : out std_ulogic; tapo_tdi : out std_ulogic; tapo_rst : out std_ulogic; tapo_capt : out std_ulogic; tapo_shft : out std_ulogic; tapo_upd : out std_ulogic; tapo_xsel1 : out std_ulogic; tapo_xsel2 : out std_ulogic ); end; architecture rtl of spartan6_tap is component BSCAN_SPARTAN6 generic ( JTAG_CHAIN : integer := 1 ); port ( CAPTURE : out std_ulogic := 'H'; DRCK : out std_ulogic := 'H'; RESET : out std_ulogic := 'H'; RUNTEST : out std_ulogic := 'L'; SEL : out std_ulogic := 'L'; SHIFT : out std_ulogic := 'L'; TCK : out std_ulogic := 'L'; TDI : out std_ulogic := 'L'; TMS : out std_ulogic := 'L'; UPDATE : out std_ulogic := 'L'; TDO : in std_ulogic := 'X' ); end component; signal drck1, drck2, sel1, sel2 : std_ulogic; signal capt1, capt2, rst1, rst2 : std_ulogic; signal shift1, shift2, tdi1, tdi2 : std_ulogic; signal update1, update2 : std_ulogic; attribute dont_touch : boolean; attribute dont_touch of u0 : label is true; attribute dont_touch of u1 : label is true; begin u0 : BSCAN_SPARTAN6 generic map (JTAG_CHAIN => 1) port map ( CAPTURE => capt1, DRCK => drck1, RESET => rst1, SEL => sel1, SHIFT => shift1, TDI => tdi1, UPDATE => update1, TDO => tapi_tdo1, TCK => tapo_tck ); u1 : BSCAN_SPARTAN6 generic map (JTAG_CHAIN => 2) port map ( CAPTURE => capt2, DRCK => drck2, RESET => rst2, SEL => sel2, SHIFT => shift2, TDI => tdi2, UPDATE => update2, TDO => tapi_tdo2 ); tapo_capt <= capt1 when sel1 = '1' else capt2; tapo_rst <= rst1 when sel1 = '1' else rst2; tapo_shft <= shift1 when sel1 = '1' else shift2; tapo_tdi <= tdi1 when sel1 = '1' else tdi2; tapo_upd <= update1 when sel1 ='1' else update2; tapo_xsel1 <= sel1; tapo_xsel2 <= sel2; end; library ieee; use ieee.std_logic_1164.all; -- pragma translate_off library unisim; use unisim.all; -- pragma translate_on entity virtex7_tap is port ( tapi_tdo1 : in std_ulogic; tapi_tdo2 : in std_ulogic; tapo_tck : out std_ulogic; tapo_tdi : out std_ulogic; tapo_rst : out std_ulogic; tapo_capt : out std_ulogic; tapo_shft : out std_ulogic; tapo_upd : out std_ulogic; tapo_xsel1 : out std_ulogic; tapo_xsel2 : out std_ulogic ); end; architecture rtl of virtex7_tap is component BSCANE2 generic ( DISABLE_JTAG : string := "FALSE"; JTAG_CHAIN : integer := 1 ); port ( CAPTURE : out std_ulogic := 'H'; DRCK : out std_ulogic := 'H'; RESET : out std_ulogic := 'H'; RUNTEST : out std_ulogic := 'L'; SEL : out std_ulogic := 'L'; SHIFT : out std_ulogic := 'L'; TCK : out std_ulogic := 'L'; TDI : out std_ulogic := 'L'; TMS : out std_ulogic := 'L'; UPDATE : out std_ulogic := 'L'; TDO : in std_ulogic := 'X' ); end component; signal drck1, drck2, sel1, sel2 : std_ulogic; signal capt1, capt2, rst1, rst2 : std_ulogic; signal shift1, shift2, tdi1, tdi2 : std_ulogic; signal update1, update2 : std_ulogic; attribute dont_touch : boolean; attribute dont_touch of u0 : label is true; attribute dont_touch of u1 : label is true; begin u0 : BSCANE2 generic map (JTAG_CHAIN => 1) port map ( CAPTURE => capt1, DRCK => drck1, RESET => rst1, SEL => sel1, SHIFT => shift1, TDI => tdi1, UPDATE => update1, TDO => tapi_tdo1, TCK => tapo_tck ); u1 : BSCANE2 generic map (JTAG_CHAIN => 2) port map ( CAPTURE => capt2, DRCK => drck2, RESET => rst2, SEL => sel2, SHIFT => shift2, TDI => tdi2, UPDATE => update2, TDO => tapi_tdo2 ); tapo_capt <= capt1 when sel1 = '1' else capt2; tapo_rst <= rst1 when sel1 = '1' else rst2; tapo_shft <= shift1 when sel1 = '1' else shift2; tapo_tdi <= tdi1 when sel1 = '1' else tdi2; tapo_upd <= update1 when sel1 ='1' else update2; tapo_xsel1 <= sel1; tapo_xsel2 <= sel2; end; library ieee; use ieee.std_logic_1164.all; -- pragma translate_off library unisim; use unisim.all; -- pragma translate_on entity kintex7_tap is port ( tapi_tdo1 : in std_ulogic; tapi_tdo2 : in std_ulogic; tapo_tck : out std_ulogic; tapo_tdi : out std_ulogic; tapo_rst : out std_ulogic; tapo_capt : out std_ulogic; tapo_shft : out std_ulogic; tapo_upd : out std_ulogic; tapo_xsel1 : out std_ulogic; tapo_xsel2 : out std_ulogic ); end; architecture rtl of kintex7_tap is component BSCANE2 generic ( DISABLE_JTAG : string := "FALSE"; JTAG_CHAIN : integer := 1 ); port ( CAPTURE : out std_ulogic := 'H'; DRCK : out std_ulogic := 'H'; RESET : out std_ulogic := 'H'; RUNTEST : out std_ulogic := 'L'; SEL : out std_ulogic := 'L'; SHIFT : out std_ulogic := 'L'; TCK : out std_ulogic := 'L'; TDI : out std_ulogic := 'L'; TMS : out std_ulogic := 'L'; UPDATE : out std_ulogic := 'L'; TDO : in std_ulogic := 'X' ); end component; signal drck1, drck2, sel1, sel2 : std_ulogic; signal capt1, capt2, rst1, rst2 : std_ulogic; signal shift1, shift2, tdi1, tdi2 : std_ulogic; signal update1, update2 : std_ulogic; attribute dont_touch : boolean; attribute dont_touch of u0 : label is true; attribute dont_touch of u1 : label is true; begin u0 : BSCANE2 generic map (JTAG_CHAIN => 1) port map ( CAPTURE => capt1, DRCK => drck1, RESET => rst1, SEL => sel1, SHIFT => shift1, TDI => tdi1, UPDATE => update1, TDO => tapi_tdo1, TCK => tapo_tck ); u1 : BSCANE2 generic map (JTAG_CHAIN => 2) port map ( CAPTURE => capt2, DRCK => drck2, RESET => rst2, SEL => sel2, SHIFT => shift2, TDI => tdi2, UPDATE => update2, TDO => tapi_tdo2 ); tapo_capt <= capt1 when sel1 = '1' else capt2; tapo_rst <= rst1 when sel1 = '1' else rst2; tapo_shft <= shift1 when sel1 = '1' else shift2; tapo_tdi <= tdi1 when sel1 = '1' else tdi2; tapo_upd <= update1 when sel1 ='1' else update2; tapo_xsel1 <= sel1; tapo_xsel2 <= sel2; end; library ieee; use ieee.std_logic_1164.all; -- pragma translate_off library unisim; use unisim.all; -- pragma translate_on entity artix7_tap is port ( tapi_tdo1 : in std_ulogic; tapi_tdo2 : in std_ulogic; tapo_tck : out std_ulogic; tapo_tdi : out std_ulogic; tapo_rst : out std_ulogic; tapo_capt : out std_ulogic; tapo_shft : out std_ulogic; tapo_upd : out std_ulogic; tapo_xsel1 : out std_ulogic; tapo_xsel2 : out std_ulogic ); end; architecture rtl of artix7_tap is component BSCANE2 generic ( DISABLE_JTAG : string := "FALSE"; JTAG_CHAIN : integer := 1 ); port ( CAPTURE : out std_ulogic := 'H'; DRCK : out std_ulogic := 'H'; RESET : out std_ulogic := 'H'; RUNTEST : out std_ulogic := 'L'; SEL : out std_ulogic := 'L'; SHIFT : out std_ulogic := 'L'; TCK : out std_ulogic := 'L'; TDI : out std_ulogic := 'L'; TMS : out std_ulogic := 'L'; UPDATE : out std_ulogic := 'L'; TDO : in std_ulogic := 'X' ); end component; signal drck1, drck2, sel1, sel2 : std_ulogic; signal capt1, capt2, rst1, rst2 : std_ulogic; signal shift1, shift2, tdi1, tdi2 : std_ulogic; signal update1, update2 : std_ulogic; attribute dont_touch : boolean; attribute dont_touch of u0 : label is true; attribute dont_touch of u1 : label is true; begin u0 : BSCANE2 generic map (JTAG_CHAIN => 1) port map ( CAPTURE => capt1, DRCK => drck1, RESET => rst1, SEL => sel1, SHIFT => shift1, TDI => tdi1, UPDATE => update1, TDO => tapi_tdo1, TCK => tapo_tck ); u1 : BSCANE2 generic map (JTAG_CHAIN => 2) port map ( CAPTURE => capt2, DRCK => drck2, RESET => rst2, SEL => sel2, SHIFT => shift2, TDI => tdi2, UPDATE => update2, TDO => tapi_tdo2 ); tapo_capt <= capt1 when sel1 = '1' else capt2; tapo_rst <= rst1 when sel1 = '1' else rst2; tapo_shft <= shift1 when sel1 = '1' else shift2; tapo_tdi <= tdi1 when sel1 = '1' else tdi2; tapo_upd <= update1 when sel1 ='1' else update2; tapo_xsel1 <= sel1; tapo_xsel2 <= sel2; end;	gpl-2.0	1640683f72e97b87baadca2d0fb807dc	0.498025	3.750656	false	false	false	false
marco-c/leon-nexys2	grlib-gpl-1.3.4-b4140/lib/eth/wrapper/greth_gbit_gen.vhd	1	13,434	------------------------------------------------------------------------------ -- This file is a part of the GRLIB VHDL IP LIBRARY -- Copyright (C) 2003 - 2008, Gaisler Research -- Copyright (C) 2008 - 2013, Aeroflex Gaisler -- -- This program is free software; you can redistribute it and/or modify -- it under the terms of the GNU General Public License as published by -- the Free Software Foundation; either version 2 of the License, or -- (at your option) any later version. -- -- This program is distributed in the hope that it will be useful, -- but WITHOUT ANY WARRANTY; without even the implied warranty of -- MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the -- GNU General Public License for more details. -- -- You should have received a copy of the GNU General Public License -- along with this program; if not, write to the Free Software -- Foundation, Inc., 59 Temple Place, Suite 330, Boston, MA 02111-1307 USA ----------------------------------------------------------------------------- -- Entity: greth_gbit_gen -- File: greth_gbit_gen.vhd -- Author: Marko Isomaki -- Description: Generic Gigabit Ethernet MAC ------------------------------------------------------------------------------ library ieee; library grlib; use ieee.std_logic_1164.all; use grlib.stdlib.all; library techmap; use techmap.gencomp.all; library eth; use eth.ethcomp.all; entity greth_gbit_gen is generic( memtech : integer := 0; ifg_gap : integer := 24; attempt_limit : integer := 16; backoff_limit : integer := 10; slot_time : integer := 128; mdcscaler : integer range 0 to 255 := 25; nsync : integer range 1 to 2 := 2; edcl : integer range 0 to 3 := 1; edclbufsz : integer range 1 to 64 := 1; burstlength : integer range 4 to 128 := 32; macaddrh : integer := 16#00005E#; macaddrl : integer := 16#000000#; ipaddrh : integer := 16#c0a8#; ipaddrl : integer := 16#0035#; phyrstadr : integer range 0 to 32 := 0; sim : integer range 0 to 1 := 0; oepol : integer range 0 to 1 := 0; scanen : integer range 0 to 1 := 0; ft : integer range 0 to 2 := 0; edclft : integer range 0 to 2 := 0; mdint_pol : integer range 0 to 1 := 0; enable_mdint : integer range 0 to 1 := 0; multicast : integer range 0 to 1 := 0; edclsepahbg : integer range 0 to 1 := 0; ramdebug : integer range 0 to 2 := 0); port( rst : in std_ulogic; clk : in std_ulogic; --ahb mst in hgrant : in std_ulogic; hready : in std_ulogic; hresp : in std_logic_vector(1 downto 0); hrdata : in std_logic_vector(31 downto 0); --ahb mst out hbusreq : out std_ulogic; hlock : out std_ulogic; htrans : out std_logic_vector(1 downto 0); haddr : out std_logic_vector(31 downto 0); hwrite : out std_ulogic; hsize : out std_logic_vector(2 downto 0); hburst : out std_logic_vector(2 downto 0); hprot : out std_logic_vector(3 downto 0); hwdata : out std_logic_vector(31 downto 0); --edcl ahb mst in ehgrant : in std_ulogic; ehready : in std_ulogic; ehresp : in std_logic_vector(1 downto 0); ehrdata : in std_logic_vector(31 downto 0); --edcl ahb mst out ehbusreq : out std_ulogic; ehlock : out std_ulogic; ehtrans : out std_logic_vector(1 downto 0); ehaddr : out std_logic_vector(31 downto 0); ehwrite : out std_ulogic; ehsize : out std_logic_vector(2 downto 0); ehburst : out std_logic_vector(2 downto 0); ehprot : out std_logic_vector(3 downto 0); ehwdata : out std_logic_vector(31 downto 0); --apb slv in psel : in std_ulogic; penable : in std_ulogic; paddr : in std_logic_vector(31 downto 0); pwrite : in std_ulogic; pwdata : in std_logic_vector(31 downto 0); --apb slv out prdata : out std_logic_vector(31 downto 0); --irq irq : out std_logic; --ethernet input signals gtx_clk : in std_ulogic; tx_clk : in std_ulogic; rx_clk : in std_ulogic; rxd : in std_logic_vector(7 downto 0); rx_dv : in std_ulogic; rx_er : in std_ulogic; rx_col : in std_ulogic; rx_crs : in std_ulogic; mdio_i : in std_ulogic; phyrstaddr : in std_logic_vector(4 downto 0); mdint : in std_ulogic; --ethernet output signals reset : out std_ulogic; txd : out std_logic_vector(7 downto 0); tx_en : out std_ulogic; tx_er : out std_ulogic; mdc : out std_ulogic; mdio_o : out std_ulogic; mdio_oe : out std_ulogic; --scantest testrst : in std_ulogic; testen : in std_ulogic; testoen : in std_ulogic; edcladdr : in std_logic_vector(3 downto 0); edclsepahb : in std_ulogic; edcldisable : in std_ulogic; speed : out std_ulogic; gbit : out std_ulogic ); end entity; architecture rtl of greth_gbit_gen is --host constants constant fifosize : integer := 512; constant fabits : integer := log2(fifosize); constant fsize : std_logic_vector(fabits downto 0) := conv_std_logic_vector(fifosize, fabits+1); --edcl constants type szvct is array (0 to 6) of integer; constant ebuf : szvct := (64, 128, 128, 256, 256, 256, 256); constant eabits: integer := log2(edclbufsz) + 8; constant ebufsize : integer := ebuf(log2(edclbufsz)); --rx ahb fifo signal rxrenable : std_ulogic; signal rxraddress : std_logic_vector(8 downto 0); signal rxwrite : std_ulogic; signal rxwdata : std_logic_vector(31 downto 0); signal rxwaddress : std_logic_vector(8 downto 0); signal rxrdata : std_logic_vector(31 downto 0); --tx ahb fifo signal txrenable : std_ulogic; signal txraddress : std_logic_vector(8 downto 0); signal txwrite : std_ulogic; signal txwdata : std_logic_vector(31 downto 0); signal txwaddress : std_logic_vector(8 downto 0); signal txrdata : std_logic_vector(31 downto 0); --edcl buf signal erenable : std_ulogic; signal eraddress : std_logic_vector(15 downto 0); signal ewritem : std_ulogic; signal ewritel : std_ulogic; signal ewaddressm : std_logic_vector(15 downto 0); signal ewaddressl : std_logic_vector(15 downto 0); signal ewdata : std_logic_vector(31 downto 0); signal erdata : std_logic_vector(31 downto 0); begin gtxc0: greth_gbitc generic map( ifg_gap => ifg_gap, attempt_limit => attempt_limit, backoff_limit => backoff_limit, slot_time => slot_time, mdcscaler => mdcscaler, nsync => nsync, edcl => edcl, edclbufsz => edclbufsz, burstlength => burstlength, macaddrh => macaddrh, macaddrl => macaddrl, ipaddrh => ipaddrh, ipaddrl => ipaddrl, phyrstadr => phyrstadr, sim => sim, oepol => oepol, scanen => scanen, mdint_pol => mdint_pol, enable_mdint => enable_mdint, multicast => multicast, edclsepahbg => edclsepahbg, ramdebug => ramdebug) port map( rst => rst, clk => clk, --ahb mst in hgrant => hgrant, hready => hready, hresp => hresp, hrdata => hrdata, --ahb mst out hbusreq => hbusreq, hlock => hlock, htrans => htrans, haddr => haddr, hwrite => hwrite, hsize => hsize, hburst => hburst, hprot => hprot, hwdata => hwdata, --edcl ahb mst in ehgrant => ehgrant, ehready => ehready, ehresp => ehresp, ehrdata => ehrdata, --edcl ahb mst out ehbusreq => ehbusreq, ehlock => ehlock, ehtrans => ehtrans, ehaddr => ehaddr, ehwrite => ehwrite, ehsize => ehsize, ehburst => ehburst, ehprot => ehprot, ehwdata => ehwdata, --apb slv in psel => psel, penable => penable, paddr => paddr, pwrite => pwrite, pwdata => pwdata, --apb slv out prdata => prdata, --irq irq => irq, --rx ahb fifo rxrenable => rxrenable, rxraddress => rxraddress, rxwrite => rxwrite, rxwdata => rxwdata, rxwaddress => rxwaddress, rxrdata => rxrdata, --tx ahb fifo txrenable => txrenable, txraddress => txraddress, txwrite => txwrite, txwdata => txwdata, txwaddress => txwaddress, txrdata => txrdata, --edcl buf erenable => erenable, eraddress => eraddress, ewritem => ewritem, ewritel => ewritel, ewaddressm => ewaddressm, ewaddressl => ewaddressl, ewdata => ewdata, erdata => erdata, --ethernet input signals gtx_clk => gtx_clk, tx_clk => tx_clk, rx_clk => rx_clk, rxd => rxd, rx_dv => rx_dv, rx_er => rx_er, rx_col => rx_col, rx_crs => rx_crs, mdio_i => mdio_i, phyrstaddr => phyrstaddr, mdint => mdint, --ethernet output signals reset => reset, txd => txd, tx_en => tx_en, tx_er => tx_er, mdc => mdc, mdio_o => mdio_o, mdio_oe => mdio_oe, --scantest testrst => testrst, testen => testen, testoen => testoen, edcladdr => edcladdr, edclsepahb => edclsepahb, edcldisable => edcldisable, speed => speed, gbit => gbit); ------------------------------------------------------------------------------- -- FIFOS ---------------------------------------------------------------------- ------------------------------------------------------------------------------- nft : if ft = 0 generate tx_fifo0 : syncram_2p generic map(tech => memtech, abits => fabits, dbits => 32, sepclk => 0) port map(clk, txrenable, txraddress(fabits-1 downto 0), txrdata, clk, txwrite, txwaddress(fabits-1 downto 0), txwdata); rx_fifo0 : syncram_2p generic map(tech => memtech, abits => fabits, dbits => 32, sepclk => 0) port map(clk, rxrenable, rxraddress(fabits-1 downto 0), rxrdata, clk, rxwrite, rxwaddress(fabits-1 downto 0), rxwdata); end generate; ft1 : if ft /= 0 generate tx_fifo0 : syncram_2pft generic map(tech => memtech, abits => fabits, dbits => 32, sepclk => 0, ft => ft) port map(clk, txrenable, txraddress(fabits-1 downto 0), txrdata, clk, txwrite, txwaddress(fabits-1 downto 0), txwdata); rx_fifo0 : syncram_2pft generic map(tech => memtech, abits => fabits, dbits => 32, sepclk => 0, ft => ft) port map(clk, rxrenable, rxraddress(fabits-1 downto 0), rxrdata, clk, rxwrite, rxwaddress(fabits-1 downto 0), rxwdata); end generate; ------------------------------------------------------------------------------- -- EDCL buffer ram ------------------------------------------------------------ ------------------------------------------------------------------------------- edclramnft : if (edcl /= 0) and (edclft = 0) generate r0 : syncram_2p generic map (memtech, eabits, 16) port map ( clk, erenable, eraddress(eabits-1 downto 0), erdata(31 downto 16), clk, ewritem, ewaddressm(eabits-1 downto 0), ewdata(31 downto 16)); r1 : syncram_2p generic map (memtech, eabits, 16) port map ( clk, erenable, eraddress(eabits-1 downto 0), erdata(15 downto 0), clk, ewritel, ewaddressl(eabits-1 downto 0), ewdata(15 downto 0)); end generate; edclramft1 : if (edcl /= 0) and (edclft /= 0) generate r0 : syncram_2pft generic map (memtech, eabits, 16, 0, 0, edclft) port map ( clk, erenable, eraddress(eabits-1 downto 0), erdata(31 downto 16), clk, ewritem, ewaddressm(eabits-1 downto 0), ewdata(31 downto 16)); r1 : syncram_2pft generic map (memtech, eabits, 16, 0, 0, edclft) port map ( clk, erenable, eraddress(eabits-1 downto 0), erdata(15 downto 0), clk, ewritel, ewaddressl(eabits-1 downto 0), ewdata(15 downto 0)); end generate; end architecture;	gpl-2.0	3d9798233e8e5d196a98a32334ec7c8a	0.511389	4.173346	false	false	false	false
marco-c/leon-nexys2	grlib-gpl-1.3.4-b4140/lib/techmap/maps/syncram128bw.vhd	1	6,251	------------------------------------------------------------------------------ -- This file is a part of the GRLIB VHDL IP LIBRARY -- Copyright (C) 2003 - 2008, Gaisler Research -- Copyright (C) 2008 - 2013, Aeroflex Gaisler -- -- This program is free software; you can redistribute it and/or modify -- it under the terms of the GNU General Public License as published by -- the Free Software Foundation; either version 2 of the License, or -- (at your option) any later version. -- -- This program is distributed in the hope that it will be useful, -- but WITHOUT ANY WARRANTY; without even the implied warranty of -- MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the -- GNU General Public License for more details. -- -- You should have received a copy of the GNU General Public License -- along with this program; if not, write to the Free Software -- Foundation, Inc., 59 Temple Place, Suite 330, Boston, MA 02111-1307 USA ----------------------------------------------------------------------------- -- Entity: syncram128bw -- File: syncram128bw.vhd -- Author: Jiri Gaisler - Gaisler Research -- Description: 128-bit syncronous 1-port ram with 8-bit write strobes -- and tech selection ------------------------------------------------------------------------------ library ieee; library techmap; use ieee.std_logic_1164.all; use techmap.gencomp.all; library grlib; use grlib.config.all; use grlib.config_types.all; use grlib.stdlib.all; entity syncram128bw is generic (tech : integer := 0; abits : integer := 6; testen : integer := 0; custombits: integer := 1); port ( clk : in std_ulogic; address : in std_logic_vector (abits -1 downto 0); datain : in std_logic_vector (127 downto 0); dataout : out std_logic_vector (127 downto 0); enable : in std_logic_vector (15 downto 0); write : in std_logic_vector (15 downto 0); testin : in std_logic_vector (TESTIN_WIDTH-1 downto 0) := testin_none; customclk: in std_ulogic := '0'; customin : in std_logic_vector(16custombits-1 downto 0) := (others => '0'); customout:out std_logic_vector(16custombits-1 downto 0)); end; architecture rtl of syncram128bw is component unisim_syncram128bw generic ( abits : integer := 9); port ( clk : in std_ulogic; address : in std_logic_vector (abits -1 downto 0); datain : in std_logic_vector (127 downto 0); dataout : out std_logic_vector (127 downto 0); enable : in std_logic_vector (15 downto 0); write : in std_logic_vector (15 downto 0) ); end component; component altera_syncram128bw generic ( abits : integer := 9); port ( clk : in std_ulogic; address : in std_logic_vector (abits -1 downto 0); datain : in std_logic_vector (127 downto 0); dataout : out std_logic_vector (127 downto 0); enable : in std_logic_vector (15 downto 0); write : in std_logic_vector (15 downto 0) ); end component; component tm65gplus_syncram128bw generic ( abits : integer := 9); port ( clk : in std_ulogic; address : in std_logic_vector (abits -1 downto 0); datain : in std_logic_vector (127 downto 0); dataout : out std_logic_vector (127 downto 0); enable : in std_logic_vector (15 downto 0); write : in std_logic_vector (15 downto 0); testin : in std_logic_vector (3 downto 0) := "0000" ); end component; component ut90nhbd_syncram128bw generic ( abits : integer := 9); port ( clk : in std_ulogic; address : in std_logic_vector (abits -1 downto 0); datain : in std_logic_vector (127 downto 0); dataout : out std_logic_vector (127 downto 0); enable : in std_logic_vector (15 downto 0); write : in std_logic_vector (15 downto 0); tdbn : in std_ulogic ); end component; signal xenable, xwrite : std_logic_vector(15 downto 0); signal custominx,customoutx: std_logic_vector(syncram_customif_maxwidth downto 0); begin xenable <= enable when testen=0 or testin(TESTIN_WIDTH-2)='0' else (others => '0'); xwrite <= write when testen=0 or testin(TESTIN_WIDTH-2)='0' else (others => '0'); custominx(custominx'high downto custombits) <= (others => '0'); custominx(custombits-1 downto 0) <= customin(custombits-1 downto 0); nocust: if syncram_has_customif(tech)=0 or has_sram128bw(tech)=0 generate customoutx <= (others => '0'); end generate; s64 : if has_sram128bw(tech) = 1 generate xc2v : if (is_unisim(tech) = 1) generate x0 : unisim_syncram128bw generic map (abits) port map (clk, address, datain, dataout, xenable, xwrite); end generate; alt : if (tech = stratix2) or (tech = stratix3) or (tech = stratix4) or (tech = cyclone3) or (tech = altera) generate x0 : altera_syncram128bw generic map (abits) port map (clk, address, datain, dataout, xenable, xwrite); end generate; tm65: if tech = tm65gplus generate x0 : tm65gplus_syncram128bw generic map (abits) port map (clk, address, datain, dataout, xenable, xwrite, testin); end generate; ut09: if tech = ut90 generate x0 : ut90nhbd_syncram128bw generic map (abits) port map (clk, address, datain, dataout, xenable, xwrite, testin(TESTIN_WIDTH-3)); end generate; customout(16custombits-1 downto custombits) <= (others => '0'); customout(custombits-1 downto 0) <= customoutx(custombits-1 downto 0); -- pragma translate_off dmsg : if GRLIB_CONFIG_ARRAY(grlib_debug_level) >= 2 generate x : process begin assert false report "syncram128bw: " & tost(2abits) & "x128" & " (" & tech_table(tech) & ")" severity note; wait; end process; end generate; -- pragma translate_on end generate; nos64 : if has_sram128bw(tech) = 0 generate rx : for i in 0 to 15 generate x0 : syncram generic map (tech, abits, 8, testen, custombits) port map (clk, address, datain(i8+7 downto i8), dataout(i8+7 downto i8), enable(i), write(i), testin, customclk, customin((i+1)custombits-1 downto icustombits), customout((i+1)custombits-1 downto i*custombits)); end generate; end generate; end;	gpl-2.0	9ef54fad13e42c996b112a7b005de961	0.633019	3.647025	false	true	false	false
marco-c/leon-nexys2	grlib-gpl-1.3.4-b4140/lib/techmap/maps/clkinv.vhd	1	1,888	------------------------------------------------------------------------------ -- This file is a part of the GRLIB VHDL IP LIBRARY -- Copyright (C) 2003 - 2008, Gaisler Research -- Copyright (C) 2008 - 2013, Aeroflex Gaisler -- -- This program is free software; you can redistribute it and/or modify -- it under the terms of the GNU General Public License as published by -- the Free Software Foundation; either version 2 of the License, or -- (at your option) any later version. -- -- This program is distributed in the hope that it will be useful, -- but WITHOUT ANY WARRANTY; without even the implied warranty of -- MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the -- GNU General Public License for more details. -- -- You should have received a copy of the GNU General Public License -- along with this program; if not, write to the Free Software -- Foundation, Inc., 59 Temple Place, Suite 330, Boston, MA 02111-1307 USA ----------------------------------------------------------------------------- -- Entity: clkinv -- File: clkinv.vhd -- Author: Fredrik Ringhage - Aeroflex Gaisler Research -- Description: SET protected inverters for clock tree ------------------------------------------------------------------------------ library ieee; use ieee.std_logic_1164.all; use work.gencomp.all; use work.allclkgen.all; entity clkinv is generic(tech : integer := 0); port( i : in std_ulogic; o : out std_ulogic ); end entity; architecture rtl of clkinv is begin tec : if has_clkinv(tech) = 1 generate saed : if (tech = saed32) generate x0 : clkinv_saed32 port map (i => i, o => o); end generate; dar : if (tech = dare) generate x0 : clkinv_dare port map (i => i, o => o); end generate; end generate; gen : if has_clkinv(tech) = 0 generate o <= not i; end generate; end architecture;	gpl-2.0	331f74a4d9d6a2042672d8262450854c	0.601695	4.15859	false	false	false	false
Fairyland0902/BlockyRoads	src/BlockyRoads/ipcore_dir/game_over/simulation/bmg_stim_gen.vhd	1	12,587	-------------------------------------------------------------------------------- -- -- BLK MEM GEN v7_3 Core - Stimulus Generator For Single Port ROM -- -------------------------------------------------------------------------------- -- -- (c) Copyright 2006_3010 Xilinx, Inc. All rights reserved. -- -- This file contains confidential and proprietary information -- of Xilinx, Inc. and is protected under U.S. and -- international copyright and other intellectual property -- laws. -- -- DISCLAIMER -- This disclaimer is not a license and does not grant any -- rights to the materials distributed herewith. Except as -- otherwise provided in a valid license issued to you by -- Xilinx, and to the maximum extent permitted by applicable -- law: (1) THESE MATERIALS ARE MADE AVAILABLE "AS IS" AND -- WITH ALL FAULTS, AND XILINX HEREBY DISCLAIMS ALL WARRANTIES -- AND CONDITIONS, EXPRESS, IMPLIED, OR STATUTORY, INCLUDING -- BUT NOT LIMITED TO WARRANTIES OF MERCHANTABILITY, NON- -- INFRINGEMENT, OR FITNESS FOR ANY PARTICULAR PURPOSE; and -- (2) Xilinx shall not be liable (whether in contract or tort, -- including negligence, or under any other theory of -- liability) for any loss or damage of any kind or nature -- related to, arising under or in connection with these -- materials, including for any direct, or any indirect, -- special, incidental, or consequential loss or damage -- (including loss of data, profits, goodwill, or any type of -- loss or damage suffered as a result of any action brought -- by a third party) even if such damage or loss was -- reasonably foreseeable or Xilinx had been advised of the -- possibility of the same. -- -- CRITICAL APPLICATIONS -- Xilinx products are not designed or intended to be fail- -- safe, or for use in any application requiring fail-safe -- performance, such as life-support or safety devices or -- systems, Class III medical devices, nuclear facilities, -- applications related to the deployment of airbags, or any -- other applications that could lead to death, personal -- injury, or severe property or environmental damage -- (individually and collectively, "Critical -- Applications"). Customer assumes the sole risk and -- liability of any use of Xilinx products in Critical -- Applications, subject only to applicable laws and -- regulations governing limitations on product liability. -- -- THIS COPYRIGHT NOTICE AND DISCLAIMER MUST BE RETAINED AS -- PART OF THIS FILE AT ALL TIMES. -------------------------------------------------------------------------------- -- -- Filename: bmg_stim_gen.vhd -- -- Description: -- Stimulus Generation For SROM -- -------------------------------------------------------------------------------- -- Author: IP Solutions Division -- -- History: Sep 12, 2011 - First Release -------------------------------------------------------------------------------- -- -------------------------------------------------------------------------------- -- Library Declarations -------------------------------------------------------------------------------- LIBRARY IEEE; USE IEEE.STD_LOGIC_1164.ALL; USE IEEE.STD_LOGIC_ARITH.ALL; USE IEEE.STD_LOGIC_UNSIGNED.ALL; USE IEEE.STD_LOGIC_MISC.ALL; LIBRARY work; USE work.ALL; USE work.BMG_TB_PKG.ALL; ENTITY REGISTER_LOGIC_SROM IS PORT( Q : OUT STD_LOGIC; CLK : IN STD_LOGIC; RST : IN STD_LOGIC; D : IN STD_LOGIC ); END REGISTER_LOGIC_SROM; ARCHITECTURE REGISTER_ARCH OF REGISTER_LOGIC_SROM IS SIGNAL Q_O : STD_LOGIC :='0'; BEGIN Q <= Q_O; FF_BEH: PROCESS(CLK) BEGIN IF(RISING_EDGE(CLK)) THEN IF(RST /= '0' ) THEN Q_O <= '0'; ELSE Q_O <= D; END IF; END IF; END PROCESS; END REGISTER_ARCH; LIBRARY STD; USE STD.TEXTIO.ALL; LIBRARY IEEE; USE IEEE.STD_LOGIC_1164.ALL; USE IEEE.STD_LOGIC_ARITH.ALL; --USE IEEE.NUMERIC_STD.ALL; USE IEEE.STD_LOGIC_UNSIGNED.ALL; USE IEEE.STD_LOGIC_MISC.ALL; LIBRARY work; USE work.ALL; USE work.BMG_TB_PKG.ALL; ENTITY BMG_STIM_GEN IS GENERIC ( C_ROM_SYNTH : INTEGER := 0 ); PORT ( CLK : IN STD_LOGIC; RST : IN STD_LOGIC; ADDRA: OUT STD_LOGIC_VECTOR(14 DOWNTO 0) := (OTHERS => '0'); DATA_IN : IN STD_LOGIC_VECTOR (11 DOWNTO 0); --OUTPUT VECTOR STATUS : OUT STD_LOGIC:= '0' ); END BMG_STIM_GEN; ARCHITECTURE BEHAVIORAL OF BMG_STIM_GEN IS FUNCTION hex_to_std_logic_vector( hex_str : STRING; return_width : INTEGER) RETURN STD_LOGIC_VECTOR IS VARIABLE tmp : STD_LOGIC_VECTOR((hex_str'LENGTH4)+return_width-1 DOWNTO 0); BEGIN tmp := (OTHERS => '0'); FOR i IN 1 TO hex_str'LENGTH LOOP CASE hex_str((hex_str'LENGTH+1)-i) IS WHEN '0' => tmp(i4-1 DOWNTO (i-1)4) := "0000"; WHEN '1' => tmp(i4-1 DOWNTO (i-1)4) := "0001"; WHEN '2' => tmp(i4-1 DOWNTO (i-1)4) := "0010"; WHEN '3' => tmp(i4-1 DOWNTO (i-1)4) := "0011"; WHEN '4' => tmp(i4-1 DOWNTO (i-1)4) := "0100"; WHEN '5' => tmp(i4-1 DOWNTO (i-1)4) := "0101"; WHEN '6' => tmp(i4-1 DOWNTO (i-1)4) := "0110"; WHEN '7' => tmp(i4-1 DOWNTO (i-1)4) := "0111"; WHEN '8' => tmp(i4-1 DOWNTO (i-1)4) := "1000"; WHEN '9' => tmp(i4-1 DOWNTO (i-1)4) := "1001"; WHEN 'a' \| 'A' => tmp(i4-1 DOWNTO (i-1)4) := "1010"; WHEN 'b' \| 'B' => tmp(i4-1 DOWNTO (i-1)4) := "1011"; WHEN 'c' \| 'C' => tmp(i4-1 DOWNTO (i-1)4) := "1100"; WHEN 'd' \| 'D' => tmp(i4-1 DOWNTO (i-1)4) := "1101"; WHEN 'e' \| 'E' => tmp(i4-1 DOWNTO (i-1)4) := "1110"; WHEN 'f' \| 'F' => tmp(i4-1 DOWNTO (i-1)4) := "1111"; WHEN OTHERS => tmp(i4-1 DOWNTO (i-1)4) := "1111"; END CASE; END LOOP; RETURN tmp(return_width-1 DOWNTO 0); END hex_to_std_logic_vector; CONSTANT ZERO : STD_LOGIC_VECTOR(31 DOWNTO 0) := (OTHERS => '0'); SIGNAL READ_ADDR_INT : STD_LOGIC_VECTOR(14 DOWNTO 0) := (OTHERS => '0'); SIGNAL READ_ADDR : STD_LOGIC_VECTOR(31 DOWNTO 0) := (OTHERS => '0'); SIGNAL CHECK_READ_ADDR : STD_LOGIC_VECTOR(31 DOWNTO 0) := (OTHERS => '0'); SIGNAL EXPECTED_DATA : STD_LOGIC_VECTOR(11 DOWNTO 0) := (OTHERS => '0'); SIGNAL DO_READ : STD_LOGIC := '0'; SIGNAL CHECK_DATA : STD_LOGIC := '0'; SIGNAL CHECK_DATA_R : STD_LOGIC := '0'; SIGNAL CHECK_DATA_2R : STD_LOGIC := '0'; SIGNAL DO_READ_REG: STD_LOGIC_VECTOR(4 DOWNTO 0) :=(OTHERS => '0'); CONSTANT DEFAULT_DATA : STD_LOGIC_VECTOR(11 DOWNTO 0):= hex_to_std_logic_vector("0",12); BEGIN SYNTH_COE: IF(C_ROM_SYNTH =0 ) GENERATE type mem_type is array (19199 downto 0) of std_logic_vector(11 downto 0); FUNCTION bit_to_sl(input: BIT) RETURN STD_LOGIC IS VARIABLE temp_return : STD_LOGIC; BEGIN IF (input = '0') THEN temp_return := '0'; ELSE temp_return := '1'; END IF; RETURN temp_return; END bit_to_sl; function char_to_std_logic ( char : in character) return std_logic is variable data : std_logic; begin if char = '0' then data := '0'; elsif char = '1' then data := '1'; elsif char = 'X' then data := 'X'; else assert false report "character which is not '0', '1' or 'X'." severity warning; data := 'U'; end if; return data; end char_to_std_logic; impure FUNCTION init_memory( C_USE_DEFAULT_DATA : INTEGER; C_LOAD_INIT_FILE : INTEGER ; C_INIT_FILE_NAME : STRING ; DEFAULT_DATA : STD_LOGIC_VECTOR(11 DOWNTO 0); width : INTEGER; depth : INTEGER) RETURN mem_type IS VARIABLE init_return : mem_type := (OTHERS => (OTHERS => '0')); FILE init_file : TEXT; VARIABLE mem_vector : BIT_VECTOR(width-1 DOWNTO 0); VARIABLE bitline : LINE; variable bitsgood : boolean := true; variable bitchar : character; VARIABLE i : INTEGER; VARIABLE j : INTEGER; BEGIN --Display output message indicating that the behavioral model is being --initialized ASSERT (NOT (C_USE_DEFAULT_DATA=1 OR C_LOAD_INIT_FILE=1)) REPORT " Block Memory Generator CORE Generator module loading initial data..." SEVERITY NOTE; -- Setup the default data -- Default data is with respect to write_port_A and may be wider -- or narrower than init_return width. The following loops map -- default data into the memory IF (C_USE_DEFAULT_DATA=1) THEN FOR i IN 0 TO depth-1 LOOP init_return(i) := DEFAULT_DATA; END LOOP; END IF; -- Read in the .mif file -- The init data is formatted with respect to write port A dimensions. -- The init_return vector is formatted with respect to minimum width and -- maximum depth; the following loops map the .mif file into the memory IF (C_LOAD_INIT_FILE=1) THEN file_open(init_file, C_INIT_FILE_NAME, read_mode); i := 0; WHILE (i < depth AND NOT endfile(init_file)) LOOP mem_vector := (OTHERS => '0'); readline(init_file, bitline); -- read(file_buffer, mem_vector(file_buffer'LENGTH-1 DOWNTO 0)); FOR j IN 0 TO width-1 LOOP read(bitline,bitchar,bitsgood); init_return(i)(width-1-j) := char_to_std_logic(bitchar); END LOOP; i := i + 1; END LOOP; file_close(init_file); END IF; RETURN init_return; END FUNCTION; --************************************************************ -- convert bit to STD_LOGIC --************************************************************* constant c_init : mem_type := init_memory(0, 1, "game_over.mif", DEFAULT_DATA, 12, 19200); constant rom : mem_type := c_init; BEGIN EXPECTED_DATA <= rom(conv_integer(unsigned(check_read_addr))); CHECKER_RD_ADDR_GEN_INST:ENTITY work.ADDR_GEN GENERIC MAP( C_MAX_DEPTH =>19200 ) PORT MAP( CLK => CLK, RST => RST, EN => CHECK_DATA_2R, LOAD => '0', LOAD_VALUE => ZERO, ADDR_OUT => CHECK_READ_ADDR ); PROCESS(CLK) BEGIN IF(RISING_EDGE(CLK)) THEN IF(CHECK_DATA_2R ='1') THEN IF(EXPECTED_DATA = DATA_IN) THEN STATUS<='0'; ELSE STATUS <= '1'; END IF; END IF; END IF; END PROCESS; END GENERATE; -- Simulatable ROM --Synthesizable ROM SYNTH_CHECKER: IF(C_ROM_SYNTH = 1) GENERATE PROCESS(CLK) BEGIN IF(RISING_EDGE(CLK)) THEN IF(CHECK_DATA_2R='1') THEN IF(DATA_IN=DEFAULT_DATA) THEN STATUS <= '0'; ELSE STATUS <= '1'; END IF; END IF; END IF; END PROCESS; END GENERATE; READ_ADDR_INT(14 DOWNTO 0) <= READ_ADDR(14 DOWNTO 0); ADDRA <= READ_ADDR_INT ; CHECK_DATA <= DO_READ; RD_ADDR_GEN_INST:ENTITY work.ADDR_GEN GENERIC MAP( C_MAX_DEPTH => 19200 ) PORT MAP( CLK => CLK, RST => RST, EN => DO_READ, LOAD => '0', LOAD_VALUE => ZERO, ADDR_OUT => READ_ADDR ); RD_PROCESS: PROCESS (CLK) BEGIN IF (RISING_EDGE(CLK)) THEN IF(RST='1') THEN DO_READ <= '0'; ELSE DO_READ <= '1'; END IF; END IF; END PROCESS; BEGIN_SHIFT_REG: FOR I IN 0 TO 4 GENERATE BEGIN DFF_RIGHT: IF I=0 GENERATE BEGIN SHIFT_INST_0: ENTITY work.REGISTER_LOGIC_SROM PORT MAP( Q => DO_READ_REG(0), CLK =>CLK, RST=>RST, D =>DO_READ ); END GENERATE DFF_RIGHT; DFF_OTHERS: IF ((I>0) AND (I<=4)) GENERATE BEGIN SHIFT_INST: ENTITY work.REGISTER_LOGIC_SROM PORT MAP( Q => DO_READ_REG(I), CLK =>CLK, RST=>RST, D =>DO_READ_REG(I-1) ); END GENERATE DFF_OTHERS; END GENERATE BEGIN_SHIFT_REG; CHECK_DATA_REG_1: ENTITY work.REGISTER_LOGIC_SROM PORT MAP( Q => CHECK_DATA_2R, CLK =>CLK, RST=>RST, D =>CHECK_DATA_R ); CHECK_DATA_REG: ENTITY work.REGISTER_LOGIC_SROM PORT MAP( Q => CHECK_DATA_R, CLK =>CLK, RST=>RST, D =>CHECK_DATA ); END ARCHITECTURE;	mit	72965741547e82cdc9b11f7b91e6c288	0.547946	3.686878	false	false	false	false
borti4938/sd2snes	verilog/sd2snes_sdd1/Golomb_N_Decoder.vhd	2	3,249	---------------------------------------------------------------------------------- -- Company: Traducciones Magno -- Engineer: Magno -- -- Create Date: 20.03.2018 18:42:09 -- Design Name: -- Module Name: Golomb_Decoder - Behavioral -- Project Name: -- Target Devices: -- Tool Versions: -- Description: -- -- Dependencies: -- -- Revision: -- Revision 0.01 - File Created -- Additional Comments: -- ---------------------------------------------------------------------------------- library IEEE; use IEEE.STD_LOGIC_1164.ALL; use IEEE.STD_LOGIC_ARITH.ALL; use IEEE.STD_LOGIC_UNSIGNED.ALL; -- Uncomment the following library declaration if using -- arithmetic functions with Signed or Unsigned values --use IEEE.NUMERIC_STD.ALL; -- Uncomment the following library declaration if instantiating -- any Xilinx leaf cells in this code. --library UNISIM; --use UNISIM.VComponents.all; entity Golomb_N_Decoder is Generic( N : integer); Port( clk : IN STD_LOGIC; rst : IN STD_LOGIC; din_tready : OUT STD_LOGIC; din_tdata : IN STD_LOGIC_VECTOR(N DOWNTO 0); din_tuser : OUT STD_LOGIC_VECTOR(2 downto 0); dout_tready : IN STD_LOGIC; dout_tdata : OUT STD_LOGIC; dout_tlast : OUT STD_LOGIC); end Golomb_N_Decoder; architecture Behavioral of Golomb_N_Decoder is signal zero_count : integer range 0 to 2N-1 := 0; signal max_count : integer range 0 to 2N-1 := 0; signal LPS_Flag : STD_LOGIC := '0'; signal end_bit : STD_LOGIC := '0'; begin -- number of zero bits and tail bit max_count <= 2N - conv_integer(din_tdata(N downto 1)) - 1 when din_tdata(0) = '1' else 2N - 1; LPS_Flag <= '0' when din_tdata(0) = '0' else '1'; Process( clk ) Begin if rising_edge( clk ) then if( rst = '1' ) then zero_count <= 0; end_bit <= '0'; else -- each new output bit run, counter is loaded with number of consecutive zeros -- and input code is registered if( dout_tready = '1' ) then if( zero_count = 0 ) then end_bit <= LPS_Flag; zero_count <= max_count; else zero_count <= zero_count-1; end if; end if; end if; end if; End Process; -- select how many input bits to shift Process( zero_count, dout_tready, LPS_Flag ) Begin if( zero_count = 0 ) then din_tready <= dout_tready; -- if input bit is '0', shift 1 bit, else shift N bits if( LPS_Flag = '0' ) then din_tuser <= "000"; else din_tuser <= conv_std_logic_vector(N, 3); end if; else din_tready <= '0'; din_tuser <= "000"; end if; End Process; -- select output data depending on run counter Process( zero_count, max_count, end_bit ) Begin -- new input code must be read to generate run if( zero_count = 0 ) then if( max_count = 0 ) then dout_tdata <= '1'; dout_tlast <= '1'; else dout_tdata <= '0'; dout_tlast <= '0'; end if; elsif( zero_count = 1 ) then dout_tdata <= end_bit; dout_tlast <= '1'; else dout_tdata <= '0'; dout_tlast <= '0'; end if; End Process; end Behavioral;	gpl-2.0	e213b287267fc78c14198eeec1c825a5	0.556479	3.056444	false	false	false	false
mistryalok/Zedboard	learning/training/MSD/s06v2/hls/solution1/syn/vhdl/axi_stream_gpio.vhd	3	4,500	-- ============================================================== -- RTL generated by Vivado(TM) HLS - High-Level Synthesis from C, C++ and SystemC -- Version: 2014.4 -- Copyright (C) 2014 Xilinx Inc. All rights reserved. -- -- =========================================================== library IEEE; use IEEE.std_logic_1164.all; use IEEE.numeric_std.all; entity axi_stream_gpio is port ( ap_clk : IN STD_LOGIC; ap_rst_n : IN STD_LOGIC; ap_start : IN STD_LOGIC; ap_done : OUT STD_LOGIC; ap_idle : OUT STD_LOGIC; ap_ready : OUT STD_LOGIC; inputData_V : IN STD_LOGIC_VECTOR (0 downto 0); inputData_V_ap_vld : IN STD_LOGIC; outputData_TDATA : IN STD_LOGIC_VECTOR (31 downto 0); outputData_TVALID : IN STD_LOGIC; outputData_TREADY : OUT STD_LOGIC; ap_return : OUT STD_LOGIC_VECTOR (31 downto 0) ); end; architecture behav of axi_stream_gpio is attribute CORE_GENERATION_INFO : STRING; attribute CORE_GENERATION_INFO of behav : architecture is "axi_stream_gpio,hls_ip_2014_4,{HLS_INPUT_TYPE=cxx,HLS_INPUT_FLOAT=0,HLS_INPUT_FIXED=1,HLS_INPUT_PART=xc7z020clg484-1,HLS_INPUT_CLOCK=10.000000,HLS_INPUT_ARCH=others,HLS_SYN_CLOCK=0.000000,HLS_SYN_LAT=0,HLS_SYN_TPT=none,HLS_SYN_MEM=0,HLS_SYN_DSP=0,HLS_SYN_FF=1,HLS_SYN_LUT=0}"; constant ap_const_logic_1 : STD_LOGIC := '1'; constant ap_const_logic_0 : STD_LOGIC := '0'; constant ap_ST_st1_fsm_0 : STD_LOGIC_VECTOR (0 downto 0) := "1"; constant ap_const_lv32_0 : STD_LOGIC_VECTOR (31 downto 0) := "00000000000000000000000000000000"; constant ap_const_lv1_1 : STD_LOGIC_VECTOR (0 downto 0) := "1"; signal ap_rst_n_inv : STD_LOGIC; signal ap_CS_fsm : STD_LOGIC_VECTOR (0 downto 0) := "1"; attribute fsm_encoding : string; attribute fsm_encoding of ap_CS_fsm : signal is "none"; signal ap_sig_cseq_ST_st1_fsm_0 : STD_LOGIC; signal ap_sig_bdd_19 : BOOLEAN; signal ap_NS_fsm : STD_LOGIC_VECTOR (0 downto 0); begin -- the current state (ap_CS_fsm) of the state machine. -- ap_CS_fsm_assign_proc : process(ap_clk) begin if (ap_clk'event and ap_clk = '1') then if (ap_rst_n_inv = '1') then ap_CS_fsm <= ap_ST_st1_fsm_0; else ap_CS_fsm <= ap_NS_fsm; end if; end if; end process; -- the next state (ap_NS_fsm) of the state machine. -- ap_NS_fsm_assign_proc : process (ap_start, ap_CS_fsm) begin case ap_CS_fsm is when ap_ST_st1_fsm_0 => ap_NS_fsm <= ap_ST_st1_fsm_0; when others => ap_NS_fsm <= "X"; end case; end process; -- ap_done assign process. -- ap_done_assign_proc : process(ap_start, ap_sig_cseq_ST_st1_fsm_0) begin if (((ap_const_logic_1 = ap_sig_cseq_ST_st1_fsm_0) and not((ap_start = ap_const_logic_0)))) then ap_done <= ap_const_logic_1; else ap_done <= ap_const_logic_0; end if; end process; -- ap_idle assign process. -- ap_idle_assign_proc : process(ap_start, ap_sig_cseq_ST_st1_fsm_0) begin if ((not((ap_const_logic_1 = ap_start)) and (ap_const_logic_1 = ap_sig_cseq_ST_st1_fsm_0))) then ap_idle <= ap_const_logic_1; else ap_idle <= ap_const_logic_0; end if; end process; -- ap_ready assign process. -- ap_ready_assign_proc : process(ap_start, ap_sig_cseq_ST_st1_fsm_0) begin if (((ap_const_logic_1 = ap_sig_cseq_ST_st1_fsm_0) and not((ap_start = ap_const_logic_0)))) then ap_ready <= ap_const_logic_1; else ap_ready <= ap_const_logic_0; end if; end process; ap_return <= ap_const_lv32_0; -- ap_rst_n_inv assign process. -- ap_rst_n_inv_assign_proc : process(ap_rst_n) begin ap_rst_n_inv <= not(ap_rst_n); end process; -- ap_sig_bdd_19 assign process. -- ap_sig_bdd_19_assign_proc : process(ap_CS_fsm) begin ap_sig_bdd_19 <= (ap_CS_fsm(0 downto 0) = ap_const_lv1_1); end process; -- ap_sig_cseq_ST_st1_fsm_0 assign process. -- ap_sig_cseq_ST_st1_fsm_0_assign_proc : process(ap_sig_bdd_19) begin if (ap_sig_bdd_19) then ap_sig_cseq_ST_st1_fsm_0 <= ap_const_logic_1; else ap_sig_cseq_ST_st1_fsm_0 <= ap_const_logic_0; end if; end process; outputData_TREADY <= ap_const_logic_0; end behav;	gpl-3.0	922eca5f1f107d07adddc208e1ac1319	0.574222	3.028264	false	false	false	false
mistryalok/Zedboard	learning/opencv_hls/xapp1167_vivado/sw/median/prj/solution1/syn/vhdl/image_filter_Loop_1_proc.vhd	2	51,389	-- ============================================================== -- RTL generated by Vivado(TM) HLS - High-Level Synthesis from C, C++ and SystemC -- Version: 2014.4 -- Copyright (C) 2014 Xilinx Inc. All rights reserved. -- -- =========================================================== library IEEE; use IEEE.std_logic_1164.all; use IEEE.numeric_std.all; entity image_filter_Loop_1_proc is port ( ap_clk : IN STD_LOGIC; ap_rst : IN STD_LOGIC; ap_start : IN STD_LOGIC; ap_done : OUT STD_LOGIC; ap_continue : IN STD_LOGIC; ap_idle : OUT STD_LOGIC; ap_ready : OUT STD_LOGIC; rows : IN STD_LOGIC_VECTOR (31 downto 0); cols : IN STD_LOGIC_VECTOR (31 downto 0); img_1_data_stream_0_V_din : OUT STD_LOGIC_VECTOR (7 downto 0); img_1_data_stream_0_V_full_n : IN STD_LOGIC; img_1_data_stream_0_V_write : OUT STD_LOGIC; img_1_data_stream_1_V_din : OUT STD_LOGIC_VECTOR (7 downto 0); img_1_data_stream_1_V_full_n : IN STD_LOGIC; img_1_data_stream_1_V_write : OUT STD_LOGIC; img_1_data_stream_2_V_din : OUT STD_LOGIC_VECTOR (7 downto 0); img_1_data_stream_2_V_full_n : IN STD_LOGIC; img_1_data_stream_2_V_write : OUT STD_LOGIC; img_0_data_stream_0_V_dout : IN STD_LOGIC_VECTOR (7 downto 0); img_0_data_stream_0_V_empty_n : IN STD_LOGIC; img_0_data_stream_0_V_read : OUT STD_LOGIC; img_0_data_stream_1_V_dout : IN STD_LOGIC_VECTOR (7 downto 0); img_0_data_stream_1_V_empty_n : IN STD_LOGIC; img_0_data_stream_1_V_read : OUT STD_LOGIC; img_0_data_stream_2_V_dout : IN STD_LOGIC_VECTOR (7 downto 0); img_0_data_stream_2_V_empty_n : IN STD_LOGIC; img_0_data_stream_2_V_read : OUT STD_LOGIC; buffer_val_0_address0 : OUT STD_LOGIC_VECTOR (1 downto 0); buffer_val_0_ce0 : OUT STD_LOGIC; buffer_val_0_we0 : OUT STD_LOGIC; buffer_val_0_d0 : OUT STD_LOGIC_VECTOR (7 downto 0); buffer_val_0_q0 : IN STD_LOGIC_VECTOR (7 downto 0); buffer_val_0_address1 : OUT STD_LOGIC_VECTOR (1 downto 0); buffer_val_0_ce1 : OUT STD_LOGIC; buffer_val_0_we1 : OUT STD_LOGIC; buffer_val_0_d1 : OUT STD_LOGIC_VECTOR (7 downto 0); buffer_val_0_q1 : IN STD_LOGIC_VECTOR (7 downto 0); buffer_val_1_address0 : OUT STD_LOGIC_VECTOR (1 downto 0); buffer_val_1_ce0 : OUT STD_LOGIC; buffer_val_1_we0 : OUT STD_LOGIC; buffer_val_1_d0 : OUT STD_LOGIC_VECTOR (7 downto 0); buffer_val_1_q0 : IN STD_LOGIC_VECTOR (7 downto 0); buffer_val_1_address1 : OUT STD_LOGIC_VECTOR (1 downto 0); buffer_val_1_ce1 : OUT STD_LOGIC; buffer_val_1_we1 : OUT STD_LOGIC; buffer_val_1_d1 : OUT STD_LOGIC_VECTOR (7 downto 0); buffer_val_1_q1 : IN STD_LOGIC_VECTOR (7 downto 0); buffer_val_2_address0 : OUT STD_LOGIC_VECTOR (1 downto 0); buffer_val_2_ce0 : OUT STD_LOGIC; buffer_val_2_we0 : OUT STD_LOGIC; buffer_val_2_d0 : OUT STD_LOGIC_VECTOR (7 downto 0); buffer_val_2_q0 : IN STD_LOGIC_VECTOR (7 downto 0); buffer_val_2_address1 : OUT STD_LOGIC_VECTOR (1 downto 0); buffer_val_2_ce1 : OUT STD_LOGIC; buffer_val_2_we1 : OUT STD_LOGIC; buffer_val_2_d1 : OUT STD_LOGIC_VECTOR (7 downto 0); buffer_val_2_q1 : IN STD_LOGIC_VECTOR (7 downto 0) ); end; architecture behav of image_filter_Loop_1_proc is constant ap_const_logic_1 : STD_LOGIC := '1'; constant ap_const_logic_0 : STD_LOGIC := '0'; constant ap_ST_st1_fsm_0 : STD_LOGIC_VECTOR (5 downto 0) := "000001"; constant ap_ST_st2_fsm_1 : STD_LOGIC_VECTOR (5 downto 0) := "000010"; constant ap_ST_pp0_stg0_fsm_2 : STD_LOGIC_VECTOR (5 downto 0) := "000100"; constant ap_ST_pp0_stg1_fsm_3 : STD_LOGIC_VECTOR (5 downto 0) := "001000"; constant ap_ST_pp0_stg2_fsm_4 : STD_LOGIC_VECTOR (5 downto 0) := "010000"; constant ap_ST_st7_fsm_5 : STD_LOGIC_VECTOR (5 downto 0) := "100000"; constant ap_const_lv32_0 : STD_LOGIC_VECTOR (31 downto 0) := "00000000000000000000000000000000"; constant ap_const_lv1_1 : STD_LOGIC_VECTOR (0 downto 0) := "1"; constant ap_const_lv32_1 : STD_LOGIC_VECTOR (31 downto 0) := "00000000000000000000000000000001"; constant ap_const_lv32_2 : STD_LOGIC_VECTOR (31 downto 0) := "00000000000000000000000000000010"; constant ap_const_lv1_0 : STD_LOGIC_VECTOR (0 downto 0) := "0"; constant ap_const_lv32_3 : STD_LOGIC_VECTOR (31 downto 0) := "00000000000000000000000000000011"; constant ap_const_lv32_4 : STD_LOGIC_VECTOR (31 downto 0) := "00000000000000000000000000000100"; constant ap_const_lv32_5 : STD_LOGIC_VECTOR (31 downto 0) := "00000000000000000000000000000101"; constant ap_const_lv11_0 : STD_LOGIC_VECTOR (10 downto 0) := "00000000000"; constant ap_const_lv64_1 : STD_LOGIC_VECTOR (63 downto 0) := "0000000000000000000000000000000000000000000000000000000000000001"; constant ap_const_lv64_2 : STD_LOGIC_VECTOR (63 downto 0) := "0000000000000000000000000000000000000000000000000000000000000010"; constant ap_const_lv64_0 : STD_LOGIC_VECTOR (63 downto 0) := "0000000000000000000000000000000000000000000000000000000000000000"; constant ap_const_lv11_1 : STD_LOGIC_VECTOR (10 downto 0) := "00000000001"; constant ap_const_lv32_A : STD_LOGIC_VECTOR (31 downto 0) := "00000000000000000000000000001010"; constant ap_const_lv10_0 : STD_LOGIC_VECTOR (9 downto 0) := "0000000000"; signal ap_done_reg : STD_LOGIC := '0'; signal ap_CS_fsm : STD_LOGIC_VECTOR (5 downto 0) := "000001"; attribute fsm_encoding : string; attribute fsm_encoding of ap_CS_fsm : signal is "none"; signal ap_sig_cseq_ST_st1_fsm_0 : STD_LOGIC; signal ap_sig_bdd_25 : BOOLEAN; signal col_reg_269 : STD_LOGIC_VECTOR (10 downto 0); signal tmp_fu_281_p1 : STD_LOGIC_VECTOR (11 downto 0); signal ap_sig_bdd_104 : BOOLEAN; signal tmp_2_fu_285_p1 : STD_LOGIC_VECTOR (11 downto 0); signal buffer_val_0_addr_gep_fu_159_p3 : STD_LOGIC_VECTOR (1 downto 0); signal buffer_val_0_addr_reg_551 : STD_LOGIC_VECTOR (1 downto 0); signal buffer_val_0_addr_1_gep_fu_167_p3 : STD_LOGIC_VECTOR (1 downto 0); signal buffer_val_0_addr_1_reg_556 : STD_LOGIC_VECTOR (1 downto 0); signal buffer_val_1_addr_gep_fu_175_p3 : STD_LOGIC_VECTOR (1 downto 0); signal buffer_val_1_addr_reg_561 : STD_LOGIC_VECTOR (1 downto 0); signal buffer_val_1_addr_1_gep_fu_183_p3 : STD_LOGIC_VECTOR (1 downto 0); signal buffer_val_1_addr_1_reg_566 : STD_LOGIC_VECTOR (1 downto 0); signal buffer_val_2_addr_gep_fu_191_p3 : STD_LOGIC_VECTOR (1 downto 0); signal buffer_val_2_addr_reg_571 : STD_LOGIC_VECTOR (1 downto 0); signal buffer_val_2_addr_1_gep_fu_199_p3 : STD_LOGIC_VECTOR (1 downto 0); signal buffer_val_2_addr_1_reg_577 : STD_LOGIC_VECTOR (1 downto 0); signal buffer_val_0_addr_2_gep_fu_207_p3 : STD_LOGIC_VECTOR (1 downto 0); signal buffer_val_0_addr_2_reg_582 : STD_LOGIC_VECTOR (1 downto 0); signal buffer_val_1_addr_2_gep_fu_215_p3 : STD_LOGIC_VECTOR (1 downto 0); signal buffer_val_1_addr_2_reg_587 : STD_LOGIC_VECTOR (1 downto 0); signal buffer_val_2_addr_2_gep_fu_223_p3 : STD_LOGIC_VECTOR (1 downto 0); signal buffer_val_2_addr_2_reg_592 : STD_LOGIC_VECTOR (1 downto 0); signal exitcond2_fu_293_p2 : STD_LOGIC_VECTOR (0 downto 0); signal ap_sig_cseq_ST_st2_fsm_1 : STD_LOGIC; signal ap_sig_bdd_134 : BOOLEAN; signal row_1_fu_298_p2 : STD_LOGIC_VECTOR (10 downto 0); signal row_1_reg_602 : STD_LOGIC_VECTOR (10 downto 0); signal exitcond1_fu_308_p2 : STD_LOGIC_VECTOR (0 downto 0); signal exitcond1_reg_607 : STD_LOGIC_VECTOR (0 downto 0); signal ap_sig_cseq_ST_pp0_stg0_fsm_2 : STD_LOGIC; signal ap_sig_bdd_145 : BOOLEAN; signal ap_reg_ppiten_pp0_it0 : STD_LOGIC := '0'; signal ap_sig_bdd_159 : BOOLEAN; signal ap_reg_ppiten_pp0_it1 : STD_LOGIC := '0'; signal col_1_fu_313_p2 : STD_LOGIC_VECTOR (10 downto 0); signal col_1_reg_611 : STD_LOGIC_VECTOR (10 downto 0); signal icmp_fu_329_p2 : STD_LOGIC_VECTOR (0 downto 0); signal icmp_reg_616 : STD_LOGIC_VECTOR (0 downto 0); signal scl_val_0_reg_624 : STD_LOGIC_VECTOR (7 downto 0); signal ap_sig_cseq_ST_pp0_stg1_fsm_3 : STD_LOGIC; signal ap_sig_bdd_180 : BOOLEAN; signal ap_sig_bdd_190 : BOOLEAN; signal scl_val_1_reg_630 : STD_LOGIC_VECTOR (7 downto 0); signal p_val_2_reg_636 : STD_LOGIC_VECTOR (7 downto 0); signal buffer_val_0_load_reg_643 : STD_LOGIC_VECTOR (7 downto 0); signal buffer_val_1_load_reg_649 : STD_LOGIC_VECTOR (7 downto 0); signal buffer_val_2_load_reg_655 : STD_LOGIC_VECTOR (7 downto 0); signal buffer_val_0_load_1_reg_660 : STD_LOGIC_VECTOR (7 downto 0); signal buffer_val_1_load_1_reg_665 : STD_LOGIC_VECTOR (7 downto 0); signal buffer_val_2_load_1_reg_670 : STD_LOGIC_VECTOR (7 downto 0); signal c_fu_335_p2 : STD_LOGIC_VECTOR (0 downto 0); signal c_reg_675 : STD_LOGIC_VECTOR (0 downto 0); signal ult_fu_341_p2 : STD_LOGIC_VECTOR (0 downto 0); signal ult_reg_681 : STD_LOGIC_VECTOR (0 downto 0); signal rev1_fu_353_p2 : STD_LOGIC_VECTOR (0 downto 0); signal rev1_reg_686 : STD_LOGIC_VECTOR (0 downto 0); signal c_1_fu_359_p2 : STD_LOGIC_VECTOR (0 downto 0); signal c_1_reg_691 : STD_LOGIC_VECTOR (0 downto 0); signal ult2_fu_365_p2 : STD_LOGIC_VECTOR (0 downto 0); signal ult2_reg_697 : STD_LOGIC_VECTOR (0 downto 0); signal rev3_fu_377_p2 : STD_LOGIC_VECTOR (0 downto 0); signal rev3_reg_702 : STD_LOGIC_VECTOR (0 downto 0); signal c_2_fu_383_p2 : STD_LOGIC_VECTOR (0 downto 0); signal c_2_reg_707 : STD_LOGIC_VECTOR (0 downto 0); signal ult4_fu_389_p2 : STD_LOGIC_VECTOR (0 downto 0); signal ult4_reg_713 : STD_LOGIC_VECTOR (0 downto 0); signal ult5_fu_395_p2 : STD_LOGIC_VECTOR (0 downto 0); signal ult5_reg_718 : STD_LOGIC_VECTOR (0 downto 0); signal p_val_0_1_fu_427_p3 : STD_LOGIC_VECTOR (7 downto 0); signal p_val_0_1_reg_723 : STD_LOGIC_VECTOR (7 downto 0); signal ap_sig_cseq_ST_pp0_stg2_fsm_4 : STD_LOGIC; signal ap_sig_bdd_230 : BOOLEAN; signal p_val_1_1_fu_460_p3 : STD_LOGIC_VECTOR (7 downto 0); signal p_val_1_1_reg_728 : STD_LOGIC_VECTOR (7 downto 0); signal p_val_0_2_fu_499_p3 : STD_LOGIC_VECTOR (7 downto 0); signal p_val_0_2_reg_733 : STD_LOGIC_VECTOR (7 downto 0); signal sel_tmp2_fu_505_p2 : STD_LOGIC_VECTOR (0 downto 0); signal sel_tmp2_reg_738 : STD_LOGIC_VECTOR (0 downto 0); signal p_val_1_2_fu_510_p3 : STD_LOGIC_VECTOR (7 downto 0); signal p_val_1_2_reg_744 : STD_LOGIC_VECTOR (7 downto 0); signal tmp_6_fu_521_p3 : STD_LOGIC_VECTOR (7 downto 0); signal tmp_6_reg_749 : STD_LOGIC_VECTOR (7 downto 0); signal row_reg_258 : STD_LOGIC_VECTOR (10 downto 0); signal ap_sig_cseq_ST_st7_fsm_5 : STD_LOGIC; signal ap_sig_bdd_257 : BOOLEAN; signal col_phi_fu_273_p4 : STD_LOGIC_VECTOR (10 downto 0); signal row_cast_fu_289_p1 : STD_LOGIC_VECTOR (11 downto 0); signal col_cast_fu_304_p1 : STD_LOGIC_VECTOR (11 downto 0); signal tmp_3_fu_319_p4 : STD_LOGIC_VECTOR (9 downto 0); signal ult1_fu_347_p2 : STD_LOGIC_VECTOR (0 downto 0); signal ult3_fu_371_p2 : STD_LOGIC_VECTOR (0 downto 0); signal rev_fu_401_p2 : STD_LOGIC_VECTOR (0 downto 0); signal c_0_not_fu_406_p2 : STD_LOGIC_VECTOR (0 downto 0); signal brmerge1_fu_417_p2 : STD_LOGIC_VECTOR (0 downto 0); signal brmerge_fu_411_p2 : STD_LOGIC_VECTOR (0 downto 0); signal buffer_val_0_load_scl_val_0_fu_421_p3 : STD_LOGIC_VECTOR (7 downto 0); signal rev2_fu_434_p2 : STD_LOGIC_VECTOR (0 downto 0); signal c_0_not_1_fu_439_p2 : STD_LOGIC_VECTOR (0 downto 0); signal brmerge1_1_fu_450_p2 : STD_LOGIC_VECTOR (0 downto 0); signal brmerge_1_fu_444_p2 : STD_LOGIC_VECTOR (0 downto 0); signal buffer_val_1_load_scl_val_1_fu_454_p3 : STD_LOGIC_VECTOR (7 downto 0); signal rev4_fu_467_p2 : STD_LOGIC_VECTOR (0 downto 0); signal c_0_not_2_fu_472_p2 : STD_LOGIC_VECTOR (0 downto 0); signal rev5_fu_483_p2 : STD_LOGIC_VECTOR (0 downto 0); signal brmerge1_2_fu_488_p2 : STD_LOGIC_VECTOR (0 downto 0); signal brmerge_2_fu_477_p2 : STD_LOGIC_VECTOR (0 downto 0); signal buffer_val_2_load_p_val_2_fu_493_p3 : STD_LOGIC_VECTOR (7 downto 0); signal sel_tmp9_fu_516_p3 : STD_LOGIC_VECTOR (7 downto 0); signal ap_NS_fsm : STD_LOGIC_VECTOR (5 downto 0); begin -- the current state (ap_CS_fsm) of the state machine. -- ap_CS_fsm_assign_proc : process(ap_clk) begin if (ap_clk'event and ap_clk = '1') then if (ap_rst = '1') then ap_CS_fsm <= ap_ST_st1_fsm_0; else ap_CS_fsm <= ap_NS_fsm; end if; end if; end process; -- ap_done_reg assign process. -- ap_done_reg_assign_proc : process(ap_clk) begin if (ap_clk'event and ap_clk = '1') then if (ap_rst = '1') then ap_done_reg <= ap_const_logic_0; else if ((ap_const_logic_1 = ap_continue)) then ap_done_reg <= ap_const_logic_0; elsif (((ap_const_logic_1 = ap_sig_cseq_ST_st2_fsm_1) and not((exitcond2_fu_293_p2 = ap_const_lv1_0)))) then ap_done_reg <= ap_const_logic_1; end if; end if; end if; end process; -- ap_reg_ppiten_pp0_it0 assign process. -- ap_reg_ppiten_pp0_it0_assign_proc : process(ap_clk) begin if (ap_clk'event and ap_clk = '1') then if (ap_rst = '1') then ap_reg_ppiten_pp0_it0 <= ap_const_logic_0; else if (((ap_const_logic_1 = ap_sig_cseq_ST_pp0_stg0_fsm_2) and not((ap_sig_bdd_159 and (ap_const_logic_1 = ap_reg_ppiten_pp0_it1))) and not((exitcond1_fu_308_p2 = ap_const_lv1_0)))) then ap_reg_ppiten_pp0_it0 <= ap_const_logic_0; elsif (((ap_const_logic_1 = ap_sig_cseq_ST_st2_fsm_1) and (exitcond2_fu_293_p2 = ap_const_lv1_0))) then ap_reg_ppiten_pp0_it0 <= ap_const_logic_1; end if; end if; end if; end process; -- ap_reg_ppiten_pp0_it1 assign process. -- ap_reg_ppiten_pp0_it1_assign_proc : process(ap_clk) begin if (ap_clk'event and ap_clk = '1') then if (ap_rst = '1') then ap_reg_ppiten_pp0_it1 <= ap_const_logic_0; else if (((exitcond1_reg_607 = ap_const_lv1_0) and (ap_const_logic_1 = ap_sig_cseq_ST_pp0_stg2_fsm_4))) then ap_reg_ppiten_pp0_it1 <= ap_const_logic_1; elsif ((((ap_const_logic_1 = ap_sig_cseq_ST_st2_fsm_1) and (exitcond2_fu_293_p2 = ap_const_lv1_0)) or ((ap_const_logic_1 = ap_sig_cseq_ST_pp0_stg2_fsm_4) and not((exitcond1_reg_607 = ap_const_lv1_0))))) then ap_reg_ppiten_pp0_it1 <= ap_const_logic_0; end if; end if; end if; end process; -- col_reg_269 assign process. -- col_reg_269_assign_proc : process (ap_clk) begin if (ap_clk'event and ap_clk = '1') then if (((ap_const_logic_1 = ap_sig_cseq_ST_pp0_stg0_fsm_2) and (exitcond1_reg_607 = ap_const_lv1_0) and (ap_const_logic_1 = ap_reg_ppiten_pp0_it1) and not((ap_sig_bdd_159 and (ap_const_logic_1 = ap_reg_ppiten_pp0_it1))))) then col_reg_269 <= col_1_reg_611; elsif (((ap_const_logic_1 = ap_sig_cseq_ST_st2_fsm_1) and (exitcond2_fu_293_p2 = ap_const_lv1_0))) then col_reg_269 <= ap_const_lv11_0; end if; end if; end process; -- row_reg_258 assign process. -- row_reg_258_assign_proc : process (ap_clk) begin if (ap_clk'event and ap_clk = '1') then if (((ap_const_logic_1 = ap_sig_cseq_ST_st1_fsm_0) and not(ap_sig_bdd_104))) then row_reg_258 <= ap_const_lv11_0; elsif ((ap_const_logic_1 = ap_sig_cseq_ST_st7_fsm_5)) then row_reg_258 <= row_1_reg_602; end if; end if; end process; -- assign process. -- process (ap_clk) begin if (ap_clk'event and ap_clk = '1') then if (((exitcond1_reg_607 = ap_const_lv1_0) and (ap_const_logic_1 = ap_sig_cseq_ST_pp0_stg1_fsm_3) and not(((ap_const_logic_1 = ap_reg_ppiten_pp0_it0) and ap_sig_bdd_190)))) then buffer_val_0_load_1_reg_660 <= buffer_val_0_q1; buffer_val_0_load_reg_643 <= buffer_val_0_q0; buffer_val_1_load_1_reg_665 <= buffer_val_1_q1; buffer_val_1_load_reg_649 <= buffer_val_1_q0; buffer_val_2_load_1_reg_670 <= buffer_val_2_q1; buffer_val_2_load_reg_655 <= buffer_val_2_q0; c_1_reg_691 <= c_1_fu_359_p2; c_2_reg_707 <= c_2_fu_383_p2; c_reg_675 <= c_fu_335_p2; p_val_2_reg_636 <= img_0_data_stream_2_V_dout; rev1_reg_686 <= rev1_fu_353_p2; rev3_reg_702 <= rev3_fu_377_p2; scl_val_0_reg_624 <= img_0_data_stream_0_V_dout; scl_val_1_reg_630 <= img_0_data_stream_1_V_dout; ult2_reg_697 <= ult2_fu_365_p2; ult4_reg_713 <= ult4_fu_389_p2; ult5_reg_718 <= ult5_fu_395_p2; ult_reg_681 <= ult_fu_341_p2; end if; end if; end process; -- assign process. -- process (ap_clk) begin if (ap_clk'event and ap_clk = '1') then if (((ap_const_logic_1 = ap_sig_cseq_ST_pp0_stg0_fsm_2) and (ap_const_logic_1 = ap_reg_ppiten_pp0_it0) and not((ap_sig_bdd_159 and (ap_const_logic_1 = ap_reg_ppiten_pp0_it1))))) then col_1_reg_611 <= col_1_fu_313_p2; end if; end if; end process; -- assign process. -- process (ap_clk) begin if (ap_clk'event and ap_clk = '1') then if (((ap_const_logic_1 = ap_sig_cseq_ST_pp0_stg0_fsm_2) and not((ap_sig_bdd_159 and (ap_const_logic_1 = ap_reg_ppiten_pp0_it1))))) then exitcond1_reg_607 <= exitcond1_fu_308_p2; end if; end if; end process; -- assign process. -- process (ap_clk) begin if (ap_clk'event and ap_clk = '1') then if (((ap_const_logic_1 = ap_sig_cseq_ST_pp0_stg0_fsm_2) and not((ap_sig_bdd_159 and (ap_const_logic_1 = ap_reg_ppiten_pp0_it1))) and (exitcond1_fu_308_p2 = ap_const_lv1_0))) then icmp_reg_616 <= icmp_fu_329_p2; end if; end if; end process; -- assign process. -- process (ap_clk) begin if (ap_clk'event and ap_clk = '1') then if (((exitcond1_reg_607 = ap_const_lv1_0) and (ap_const_logic_1 = ap_sig_cseq_ST_pp0_stg2_fsm_4))) then p_val_0_1_reg_723 <= p_val_0_1_fu_427_p3; p_val_0_2_reg_733 <= p_val_0_2_fu_499_p3; p_val_1_1_reg_728 <= p_val_1_1_fu_460_p3; p_val_1_2_reg_744 <= p_val_1_2_fu_510_p3; sel_tmp2_reg_738 <= sel_tmp2_fu_505_p2; tmp_6_reg_749 <= tmp_6_fu_521_p3; end if; end if; end process; -- assign process. -- process (ap_clk) begin if (ap_clk'event and ap_clk = '1') then if ((ap_const_logic_1 = ap_sig_cseq_ST_st2_fsm_1)) then row_1_reg_602 <= row_1_fu_298_p2; end if; end if; end process; buffer_val_0_addr_reg_551(1 downto 0) <= "01"; buffer_val_0_addr_1_reg_556(1 downto 0) <= "10"; buffer_val_1_addr_reg_561(1 downto 0) <= "01"; buffer_val_1_addr_1_reg_566(1 downto 0) <= "10"; buffer_val_2_addr_reg_571(1 downto 0) <= "01"; buffer_val_2_addr_1_reg_577(1 downto 0) <= "10"; buffer_val_0_addr_2_reg_582(1 downto 0) <= "00"; buffer_val_1_addr_2_reg_587(1 downto 0) <= "00"; buffer_val_2_addr_2_reg_592(1 downto 0) <= "00"; -- the next state (ap_NS_fsm) of the state machine. -- ap_NS_fsm_assign_proc : process (ap_CS_fsm, ap_sig_bdd_104, exitcond2_fu_293_p2, exitcond1_fu_308_p2, ap_reg_ppiten_pp0_it0, ap_sig_bdd_159, ap_reg_ppiten_pp0_it1, ap_sig_bdd_190) begin case ap_CS_fsm is when ap_ST_st1_fsm_0 => if (not(ap_sig_bdd_104)) then ap_NS_fsm <= ap_ST_st2_fsm_1; else ap_NS_fsm <= ap_ST_st1_fsm_0; end if; when ap_ST_st2_fsm_1 => if (not((exitcond2_fu_293_p2 = ap_const_lv1_0))) then ap_NS_fsm <= ap_ST_st1_fsm_0; else ap_NS_fsm <= ap_ST_pp0_stg0_fsm_2; end if; when ap_ST_pp0_stg0_fsm_2 => if ((not((ap_sig_bdd_159 and (ap_const_logic_1 = ap_reg_ppiten_pp0_it1))) and not(((ap_const_logic_1 = ap_reg_ppiten_pp0_it0) and not((ap_sig_bdd_159 and (ap_const_logic_1 = ap_reg_ppiten_pp0_it1))) and not((exitcond1_fu_308_p2 = ap_const_lv1_0)))))) then ap_NS_fsm <= ap_ST_pp0_stg1_fsm_3; elsif (((ap_const_logic_1 = ap_reg_ppiten_pp0_it0) and not((ap_sig_bdd_159 and (ap_const_logic_1 = ap_reg_ppiten_pp0_it1))) and not((exitcond1_fu_308_p2 = ap_const_lv1_0)))) then ap_NS_fsm <= ap_ST_st7_fsm_5; else ap_NS_fsm <= ap_ST_pp0_stg0_fsm_2; end if; when ap_ST_pp0_stg1_fsm_3 => if (not(((ap_const_logic_1 = ap_reg_ppiten_pp0_it0) and ap_sig_bdd_190))) then ap_NS_fsm <= ap_ST_pp0_stg2_fsm_4; else ap_NS_fsm <= ap_ST_pp0_stg1_fsm_3; end if; when ap_ST_pp0_stg2_fsm_4 => ap_NS_fsm <= ap_ST_pp0_stg0_fsm_2; when ap_ST_st7_fsm_5 => ap_NS_fsm <= ap_ST_st2_fsm_1; when others => ap_NS_fsm <= "XXXXXX"; end case; end process; -- ap_done assign process. -- ap_done_assign_proc : process(ap_done_reg, exitcond2_fu_293_p2, ap_sig_cseq_ST_st2_fsm_1) begin if (((ap_const_logic_1 = ap_done_reg) or ((ap_const_logic_1 = ap_sig_cseq_ST_st2_fsm_1) and not((exitcond2_fu_293_p2 = ap_const_lv1_0))))) then ap_done <= ap_const_logic_1; else ap_done <= ap_const_logic_0; end if; end process; -- ap_idle assign process. -- ap_idle_assign_proc : process(ap_start, ap_sig_cseq_ST_st1_fsm_0) begin if ((not((ap_const_logic_1 = ap_start)) and (ap_const_logic_1 = ap_sig_cseq_ST_st1_fsm_0))) then ap_idle <= ap_const_logic_1; else ap_idle <= ap_const_logic_0; end if; end process; -- ap_ready assign process. -- ap_ready_assign_proc : process(exitcond2_fu_293_p2, ap_sig_cseq_ST_st2_fsm_1) begin if (((ap_const_logic_1 = ap_sig_cseq_ST_st2_fsm_1) and not((exitcond2_fu_293_p2 = ap_const_lv1_0)))) then ap_ready <= ap_const_logic_1; else ap_ready <= ap_const_logic_0; end if; end process; -- ap_sig_bdd_104 assign process. -- ap_sig_bdd_104_assign_proc : process(ap_start, ap_done_reg) begin ap_sig_bdd_104 <= ((ap_start = ap_const_logic_0) or (ap_done_reg = ap_const_logic_1)); end process; -- ap_sig_bdd_134 assign process. -- ap_sig_bdd_134_assign_proc : process(ap_CS_fsm) begin ap_sig_bdd_134 <= (ap_const_lv1_1 = ap_CS_fsm(1 downto 1)); end process; -- ap_sig_bdd_145 assign process. -- ap_sig_bdd_145_assign_proc : process(ap_CS_fsm) begin ap_sig_bdd_145 <= (ap_const_lv1_1 = ap_CS_fsm(2 downto 2)); end process; -- ap_sig_bdd_159 assign process. -- ap_sig_bdd_159_assign_proc : process(img_1_data_stream_0_V_full_n, img_1_data_stream_1_V_full_n, img_1_data_stream_2_V_full_n, exitcond1_reg_607) begin ap_sig_bdd_159 <= (((img_1_data_stream_0_V_full_n = ap_const_logic_0) and (exitcond1_reg_607 = ap_const_lv1_0)) or ((exitcond1_reg_607 = ap_const_lv1_0) and (img_1_data_stream_1_V_full_n = ap_const_logic_0)) or ((exitcond1_reg_607 = ap_const_lv1_0) and (img_1_data_stream_2_V_full_n = ap_const_logic_0))); end process; -- ap_sig_bdd_180 assign process. -- ap_sig_bdd_180_assign_proc : process(ap_CS_fsm) begin ap_sig_bdd_180 <= (ap_const_lv1_1 = ap_CS_fsm(3 downto 3)); end process; -- ap_sig_bdd_190 assign process. -- ap_sig_bdd_190_assign_proc : process(img_0_data_stream_0_V_empty_n, img_0_data_stream_1_V_empty_n, img_0_data_stream_2_V_empty_n, exitcond1_reg_607) begin ap_sig_bdd_190 <= (((exitcond1_reg_607 = ap_const_lv1_0) and (img_0_data_stream_0_V_empty_n = ap_const_logic_0)) or ((exitcond1_reg_607 = ap_const_lv1_0) and (img_0_data_stream_1_V_empty_n = ap_const_logic_0)) or ((exitcond1_reg_607 = ap_const_lv1_0) and (img_0_data_stream_2_V_empty_n = ap_const_logic_0))); end process; -- ap_sig_bdd_230 assign process. -- ap_sig_bdd_230_assign_proc : process(ap_CS_fsm) begin ap_sig_bdd_230 <= (ap_const_lv1_1 = ap_CS_fsm(4 downto 4)); end process; -- ap_sig_bdd_25 assign process. -- ap_sig_bdd_25_assign_proc : process(ap_CS_fsm) begin ap_sig_bdd_25 <= (ap_CS_fsm(0 downto 0) = ap_const_lv1_1); end process; -- ap_sig_bdd_257 assign process. -- ap_sig_bdd_257_assign_proc : process(ap_CS_fsm) begin ap_sig_bdd_257 <= (ap_const_lv1_1 = ap_CS_fsm(5 downto 5)); end process; -- ap_sig_cseq_ST_pp0_stg0_fsm_2 assign process. -- ap_sig_cseq_ST_pp0_stg0_fsm_2_assign_proc : process(ap_sig_bdd_145) begin if (ap_sig_bdd_145) then ap_sig_cseq_ST_pp0_stg0_fsm_2 <= ap_const_logic_1; else ap_sig_cseq_ST_pp0_stg0_fsm_2 <= ap_const_logic_0; end if; end process; -- ap_sig_cseq_ST_pp0_stg1_fsm_3 assign process. -- ap_sig_cseq_ST_pp0_stg1_fsm_3_assign_proc : process(ap_sig_bdd_180) begin if (ap_sig_bdd_180) then ap_sig_cseq_ST_pp0_stg1_fsm_3 <= ap_const_logic_1; else ap_sig_cseq_ST_pp0_stg1_fsm_3 <= ap_const_logic_0; end if; end process; -- ap_sig_cseq_ST_pp0_stg2_fsm_4 assign process. -- ap_sig_cseq_ST_pp0_stg2_fsm_4_assign_proc : process(ap_sig_bdd_230) begin if (ap_sig_bdd_230) then ap_sig_cseq_ST_pp0_stg2_fsm_4 <= ap_const_logic_1; else ap_sig_cseq_ST_pp0_stg2_fsm_4 <= ap_const_logic_0; end if; end process; -- ap_sig_cseq_ST_st1_fsm_0 assign process. -- ap_sig_cseq_ST_st1_fsm_0_assign_proc : process(ap_sig_bdd_25) begin if (ap_sig_bdd_25) then ap_sig_cseq_ST_st1_fsm_0 <= ap_const_logic_1; else ap_sig_cseq_ST_st1_fsm_0 <= ap_const_logic_0; end if; end process; -- ap_sig_cseq_ST_st2_fsm_1 assign process. -- ap_sig_cseq_ST_st2_fsm_1_assign_proc : process(ap_sig_bdd_134) begin if (ap_sig_bdd_134) then ap_sig_cseq_ST_st2_fsm_1 <= ap_const_logic_1; else ap_sig_cseq_ST_st2_fsm_1 <= ap_const_logic_0; end if; end process; -- ap_sig_cseq_ST_st7_fsm_5 assign process. -- ap_sig_cseq_ST_st7_fsm_5_assign_proc : process(ap_sig_bdd_257) begin if (ap_sig_bdd_257) then ap_sig_cseq_ST_st7_fsm_5 <= ap_const_logic_1; else ap_sig_cseq_ST_st7_fsm_5 <= ap_const_logic_0; end if; end process; brmerge1_1_fu_450_p2 <= (rev3_reg_702 or c_1_reg_691); brmerge1_2_fu_488_p2 <= (rev5_fu_483_p2 or c_2_reg_707); brmerge1_fu_417_p2 <= (rev1_reg_686 or c_reg_675); brmerge_1_fu_444_p2 <= (rev2_fu_434_p2 or c_0_not_1_fu_439_p2); brmerge_2_fu_477_p2 <= (rev4_fu_467_p2 or c_0_not_2_fu_472_p2); brmerge_fu_411_p2 <= (rev_fu_401_p2 or c_0_not_fu_406_p2); buffer_val_0_addr_1_gep_fu_167_p3 <= ap_const_lv64_2(2 - 1 downto 0); buffer_val_0_addr_2_gep_fu_207_p3 <= ap_const_lv64_0(2 - 1 downto 0); buffer_val_0_addr_gep_fu_159_p3 <= ap_const_lv64_1(2 - 1 downto 0); -- buffer_val_0_address0 assign process. -- buffer_val_0_address0_assign_proc : process(buffer_val_0_addr_reg_551, buffer_val_0_addr_1_reg_556, ap_sig_cseq_ST_pp0_stg0_fsm_2, ap_reg_ppiten_pp0_it0, ap_sig_cseq_ST_pp0_stg1_fsm_3, ap_sig_cseq_ST_pp0_stg2_fsm_4) begin if (((ap_const_logic_1 = ap_reg_ppiten_pp0_it0) and (ap_const_logic_1 = ap_sig_cseq_ST_pp0_stg2_fsm_4))) then buffer_val_0_address0 <= buffer_val_0_addr_1_reg_556; elsif ((((ap_const_logic_1 = ap_sig_cseq_ST_pp0_stg0_fsm_2) and (ap_const_logic_1 = ap_reg_ppiten_pp0_it0)) or ((ap_const_logic_1 = ap_reg_ppiten_pp0_it0) and (ap_const_logic_1 = ap_sig_cseq_ST_pp0_stg1_fsm_3)))) then buffer_val_0_address0 <= buffer_val_0_addr_reg_551; else buffer_val_0_address0 <= "XX"; end if; end process; buffer_val_0_address1 <= buffer_val_0_addr_2_reg_582; -- buffer_val_0_ce0 assign process. -- buffer_val_0_ce0_assign_proc : process(ap_sig_cseq_ST_pp0_stg0_fsm_2, ap_reg_ppiten_pp0_it0, ap_sig_bdd_159, ap_reg_ppiten_pp0_it1, ap_sig_cseq_ST_pp0_stg1_fsm_3, ap_sig_bdd_190, ap_sig_cseq_ST_pp0_stg2_fsm_4) begin if ((((ap_const_logic_1 = ap_sig_cseq_ST_pp0_stg0_fsm_2) and (ap_const_logic_1 = ap_reg_ppiten_pp0_it0) and not((ap_sig_bdd_159 and (ap_const_logic_1 = ap_reg_ppiten_pp0_it1)))) or ((ap_const_logic_1 = ap_reg_ppiten_pp0_it0) and (ap_const_logic_1 = ap_sig_cseq_ST_pp0_stg1_fsm_3) and not(((ap_const_logic_1 = ap_reg_ppiten_pp0_it0) and ap_sig_bdd_190))) or ((ap_const_logic_1 = ap_reg_ppiten_pp0_it0) and (ap_const_logic_1 = ap_sig_cseq_ST_pp0_stg2_fsm_4)))) then buffer_val_0_ce0 <= ap_const_logic_1; else buffer_val_0_ce0 <= ap_const_logic_0; end if; end process; -- buffer_val_0_ce1 assign process. -- buffer_val_0_ce1_assign_proc : process(ap_sig_cseq_ST_pp0_stg0_fsm_2, ap_reg_ppiten_pp0_it0, ap_sig_bdd_159, ap_reg_ppiten_pp0_it1, ap_sig_cseq_ST_pp0_stg1_fsm_3, ap_sig_bdd_190) begin if ((((ap_const_logic_1 = ap_sig_cseq_ST_pp0_stg0_fsm_2) and (ap_const_logic_1 = ap_reg_ppiten_pp0_it0) and not((ap_sig_bdd_159 and (ap_const_logic_1 = ap_reg_ppiten_pp0_it1)))) or ((ap_const_logic_1 = ap_reg_ppiten_pp0_it0) and (ap_const_logic_1 = ap_sig_cseq_ST_pp0_stg1_fsm_3) and not(((ap_const_logic_1 = ap_reg_ppiten_pp0_it0) and ap_sig_bdd_190))))) then buffer_val_0_ce1 <= ap_const_logic_1; else buffer_val_0_ce1 <= ap_const_logic_0; end if; end process; -- buffer_val_0_d0 assign process. -- buffer_val_0_d0_assign_proc : process(buffer_val_0_q1, ap_reg_ppiten_pp0_it0, ap_sig_cseq_ST_pp0_stg1_fsm_3, buffer_val_0_load_reg_643, ap_sig_cseq_ST_pp0_stg2_fsm_4) begin if ((ap_const_logic_1 = ap_reg_ppiten_pp0_it0)) then if ((ap_const_logic_1 = ap_sig_cseq_ST_pp0_stg2_fsm_4)) then buffer_val_0_d0 <= buffer_val_0_load_reg_643; elsif ((ap_const_logic_1 = ap_sig_cseq_ST_pp0_stg1_fsm_3)) then buffer_val_0_d0 <= buffer_val_0_q1; else buffer_val_0_d0 <= "XXXXXXXX"; end if; else buffer_val_0_d0 <= "XXXXXXXX"; end if; end process; buffer_val_0_d1 <= img_0_data_stream_0_V_dout; buffer_val_0_load_scl_val_0_fu_421_p3 <= buffer_val_0_load_reg_643 when (brmerge1_fu_417_p2(0) = '1') else scl_val_0_reg_624; -- buffer_val_0_we0 assign process. -- buffer_val_0_we0_assign_proc : process(exitcond1_reg_607, ap_reg_ppiten_pp0_it0, ap_sig_cseq_ST_pp0_stg1_fsm_3, ap_sig_bdd_190, ap_sig_cseq_ST_pp0_stg2_fsm_4) begin if ((((ap_const_logic_1 = ap_reg_ppiten_pp0_it0) and (exitcond1_reg_607 = ap_const_lv1_0) and (ap_const_logic_1 = ap_sig_cseq_ST_pp0_stg1_fsm_3) and not(((ap_const_logic_1 = ap_reg_ppiten_pp0_it0) and ap_sig_bdd_190))) or ((ap_const_logic_1 = ap_reg_ppiten_pp0_it0) and (exitcond1_reg_607 = ap_const_lv1_0) and (ap_const_logic_1 = ap_sig_cseq_ST_pp0_stg2_fsm_4)))) then buffer_val_0_we0 <= ap_const_logic_1; else buffer_val_0_we0 <= ap_const_logic_0; end if; end process; -- buffer_val_0_we1 assign process. -- buffer_val_0_we1_assign_proc : process(exitcond1_reg_607, ap_reg_ppiten_pp0_it0, ap_sig_cseq_ST_pp0_stg1_fsm_3, ap_sig_bdd_190) begin if ((((ap_const_logic_1 = ap_reg_ppiten_pp0_it0) and (exitcond1_reg_607 = ap_const_lv1_0) and (ap_const_logic_1 = ap_sig_cseq_ST_pp0_stg1_fsm_3) and not(((ap_const_logic_1 = ap_reg_ppiten_pp0_it0) and ap_sig_bdd_190))))) then buffer_val_0_we1 <= ap_const_logic_1; else buffer_val_0_we1 <= ap_const_logic_0; end if; end process; buffer_val_1_addr_1_gep_fu_183_p3 <= ap_const_lv64_2(2 - 1 downto 0); buffer_val_1_addr_2_gep_fu_215_p3 <= ap_const_lv64_0(2 - 1 downto 0); buffer_val_1_addr_gep_fu_175_p3 <= ap_const_lv64_1(2 - 1 downto 0); -- buffer_val_1_address0 assign process. -- buffer_val_1_address0_assign_proc : process(buffer_val_1_addr_reg_561, buffer_val_1_addr_1_reg_566, ap_sig_cseq_ST_pp0_stg0_fsm_2, ap_reg_ppiten_pp0_it0, ap_sig_cseq_ST_pp0_stg1_fsm_3, ap_sig_cseq_ST_pp0_stg2_fsm_4) begin if (((ap_const_logic_1 = ap_reg_ppiten_pp0_it0) and (ap_const_logic_1 = ap_sig_cseq_ST_pp0_stg2_fsm_4))) then buffer_val_1_address0 <= buffer_val_1_addr_1_reg_566; elsif ((((ap_const_logic_1 = ap_sig_cseq_ST_pp0_stg0_fsm_2) and (ap_const_logic_1 = ap_reg_ppiten_pp0_it0)) or ((ap_const_logic_1 = ap_reg_ppiten_pp0_it0) and (ap_const_logic_1 = ap_sig_cseq_ST_pp0_stg1_fsm_3)))) then buffer_val_1_address0 <= buffer_val_1_addr_reg_561; else buffer_val_1_address0 <= "XX"; end if; end process; buffer_val_1_address1 <= buffer_val_1_addr_2_reg_587; -- buffer_val_1_ce0 assign process. -- buffer_val_1_ce0_assign_proc : process(ap_sig_cseq_ST_pp0_stg0_fsm_2, ap_reg_ppiten_pp0_it0, ap_sig_bdd_159, ap_reg_ppiten_pp0_it1, ap_sig_cseq_ST_pp0_stg1_fsm_3, ap_sig_bdd_190, ap_sig_cseq_ST_pp0_stg2_fsm_4) begin if ((((ap_const_logic_1 = ap_sig_cseq_ST_pp0_stg0_fsm_2) and (ap_const_logic_1 = ap_reg_ppiten_pp0_it0) and not((ap_sig_bdd_159 and (ap_const_logic_1 = ap_reg_ppiten_pp0_it1)))) or ((ap_const_logic_1 = ap_reg_ppiten_pp0_it0) and (ap_const_logic_1 = ap_sig_cseq_ST_pp0_stg1_fsm_3) and not(((ap_const_logic_1 = ap_reg_ppiten_pp0_it0) and ap_sig_bdd_190))) or ((ap_const_logic_1 = ap_reg_ppiten_pp0_it0) and (ap_const_logic_1 = ap_sig_cseq_ST_pp0_stg2_fsm_4)))) then buffer_val_1_ce0 <= ap_const_logic_1; else buffer_val_1_ce0 <= ap_const_logic_0; end if; end process; -- buffer_val_1_ce1 assign process. -- buffer_val_1_ce1_assign_proc : process(ap_sig_cseq_ST_pp0_stg0_fsm_2, ap_reg_ppiten_pp0_it0, ap_sig_bdd_159, ap_reg_ppiten_pp0_it1, ap_sig_cseq_ST_pp0_stg1_fsm_3, ap_sig_bdd_190) begin if ((((ap_const_logic_1 = ap_sig_cseq_ST_pp0_stg0_fsm_2) and (ap_const_logic_1 = ap_reg_ppiten_pp0_it0) and not((ap_sig_bdd_159 and (ap_const_logic_1 = ap_reg_ppiten_pp0_it1)))) or ((ap_const_logic_1 = ap_reg_ppiten_pp0_it0) and (ap_const_logic_1 = ap_sig_cseq_ST_pp0_stg1_fsm_3) and not(((ap_const_logic_1 = ap_reg_ppiten_pp0_it0) and ap_sig_bdd_190))))) then buffer_val_1_ce1 <= ap_const_logic_1; else buffer_val_1_ce1 <= ap_const_logic_0; end if; end process; -- buffer_val_1_d0 assign process. -- buffer_val_1_d0_assign_proc : process(buffer_val_1_q1, ap_reg_ppiten_pp0_it0, ap_sig_cseq_ST_pp0_stg1_fsm_3, buffer_val_1_load_reg_649, ap_sig_cseq_ST_pp0_stg2_fsm_4) begin if ((ap_const_logic_1 = ap_reg_ppiten_pp0_it0)) then if ((ap_const_logic_1 = ap_sig_cseq_ST_pp0_stg2_fsm_4)) then buffer_val_1_d0 <= buffer_val_1_load_reg_649; elsif ((ap_const_logic_1 = ap_sig_cseq_ST_pp0_stg1_fsm_3)) then buffer_val_1_d0 <= buffer_val_1_q1; else buffer_val_1_d0 <= "XXXXXXXX"; end if; else buffer_val_1_d0 <= "XXXXXXXX"; end if; end process; buffer_val_1_d1 <= img_0_data_stream_1_V_dout; buffer_val_1_load_scl_val_1_fu_454_p3 <= buffer_val_1_load_reg_649 when (brmerge1_1_fu_450_p2(0) = '1') else scl_val_1_reg_630; -- buffer_val_1_we0 assign process. -- buffer_val_1_we0_assign_proc : process(exitcond1_reg_607, ap_reg_ppiten_pp0_it0, ap_sig_cseq_ST_pp0_stg1_fsm_3, ap_sig_bdd_190, ap_sig_cseq_ST_pp0_stg2_fsm_4) begin if ((((ap_const_logic_1 = ap_reg_ppiten_pp0_it0) and (exitcond1_reg_607 = ap_const_lv1_0) and (ap_const_logic_1 = ap_sig_cseq_ST_pp0_stg1_fsm_3) and not(((ap_const_logic_1 = ap_reg_ppiten_pp0_it0) and ap_sig_bdd_190))) or ((ap_const_logic_1 = ap_reg_ppiten_pp0_it0) and (exitcond1_reg_607 = ap_const_lv1_0) and (ap_const_logic_1 = ap_sig_cseq_ST_pp0_stg2_fsm_4)))) then buffer_val_1_we0 <= ap_const_logic_1; else buffer_val_1_we0 <= ap_const_logic_0; end if; end process; -- buffer_val_1_we1 assign process. -- buffer_val_1_we1_assign_proc : process(exitcond1_reg_607, ap_reg_ppiten_pp0_it0, ap_sig_cseq_ST_pp0_stg1_fsm_3, ap_sig_bdd_190) begin if ((((ap_const_logic_1 = ap_reg_ppiten_pp0_it0) and (exitcond1_reg_607 = ap_const_lv1_0) and (ap_const_logic_1 = ap_sig_cseq_ST_pp0_stg1_fsm_3) and not(((ap_const_logic_1 = ap_reg_ppiten_pp0_it0) and ap_sig_bdd_190))))) then buffer_val_1_we1 <= ap_const_logic_1; else buffer_val_1_we1 <= ap_const_logic_0; end if; end process; buffer_val_2_addr_1_gep_fu_199_p3 <= ap_const_lv64_2(2 - 1 downto 0); buffer_val_2_addr_2_gep_fu_223_p3 <= ap_const_lv64_0(2 - 1 downto 0); buffer_val_2_addr_gep_fu_191_p3 <= ap_const_lv64_1(2 - 1 downto 0); -- buffer_val_2_address0 assign process. -- buffer_val_2_address0_assign_proc : process(buffer_val_2_addr_reg_571, buffer_val_2_addr_1_reg_577, buffer_val_2_addr_2_reg_592, ap_sig_cseq_ST_pp0_stg0_fsm_2, ap_reg_ppiten_pp0_it0, ap_sig_cseq_ST_pp0_stg1_fsm_3, ap_sig_cseq_ST_pp0_stg2_fsm_4) begin if ((ap_const_logic_1 = ap_reg_ppiten_pp0_it0)) then if ((ap_const_logic_1 = ap_sig_cseq_ST_pp0_stg2_fsm_4)) then buffer_val_2_address0 <= buffer_val_2_addr_2_reg_592; elsif ((ap_const_logic_1 = ap_sig_cseq_ST_pp0_stg1_fsm_3)) then buffer_val_2_address0 <= buffer_val_2_addr_1_reg_577; elsif ((ap_const_logic_1 = ap_sig_cseq_ST_pp0_stg0_fsm_2)) then buffer_val_2_address0 <= buffer_val_2_addr_reg_571; else buffer_val_2_address0 <= "XX"; end if; else buffer_val_2_address0 <= "XX"; end if; end process; -- buffer_val_2_address1 assign process. -- buffer_val_2_address1_assign_proc : process(buffer_val_2_addr_reg_571, buffer_val_2_addr_2_reg_592, ap_sig_cseq_ST_pp0_stg0_fsm_2, ap_reg_ppiten_pp0_it0, ap_sig_cseq_ST_pp0_stg1_fsm_3) begin if ((ap_const_logic_1 = ap_reg_ppiten_pp0_it0)) then if ((ap_const_logic_1 = ap_sig_cseq_ST_pp0_stg1_fsm_3)) then buffer_val_2_address1 <= buffer_val_2_addr_reg_571; elsif ((ap_const_logic_1 = ap_sig_cseq_ST_pp0_stg0_fsm_2)) then buffer_val_2_address1 <= buffer_val_2_addr_2_reg_592; else buffer_val_2_address1 <= "XX"; end if; else buffer_val_2_address1 <= "XX"; end if; end process; -- buffer_val_2_ce0 assign process. -- buffer_val_2_ce0_assign_proc : process(ap_sig_cseq_ST_pp0_stg0_fsm_2, ap_reg_ppiten_pp0_it0, ap_sig_bdd_159, ap_reg_ppiten_pp0_it1, ap_sig_cseq_ST_pp0_stg1_fsm_3, ap_sig_bdd_190, ap_sig_cseq_ST_pp0_stg2_fsm_4) begin if ((((ap_const_logic_1 = ap_sig_cseq_ST_pp0_stg0_fsm_2) and (ap_const_logic_1 = ap_reg_ppiten_pp0_it0) and not((ap_sig_bdd_159 and (ap_const_logic_1 = ap_reg_ppiten_pp0_it1)))) or ((ap_const_logic_1 = ap_reg_ppiten_pp0_it0) and (ap_const_logic_1 = ap_sig_cseq_ST_pp0_stg1_fsm_3) and not(((ap_const_logic_1 = ap_reg_ppiten_pp0_it0) and ap_sig_bdd_190))) or ((ap_const_logic_1 = ap_reg_ppiten_pp0_it0) and (ap_const_logic_1 = ap_sig_cseq_ST_pp0_stg2_fsm_4)))) then buffer_val_2_ce0 <= ap_const_logic_1; else buffer_val_2_ce0 <= ap_const_logic_0; end if; end process; -- buffer_val_2_ce1 assign process. -- buffer_val_2_ce1_assign_proc : process(ap_sig_cseq_ST_pp0_stg0_fsm_2, ap_reg_ppiten_pp0_it0, ap_sig_bdd_159, ap_reg_ppiten_pp0_it1, ap_sig_cseq_ST_pp0_stg1_fsm_3, ap_sig_bdd_190) begin if ((((ap_const_logic_1 = ap_sig_cseq_ST_pp0_stg0_fsm_2) and (ap_const_logic_1 = ap_reg_ppiten_pp0_it0) and not((ap_sig_bdd_159 and (ap_const_logic_1 = ap_reg_ppiten_pp0_it1)))) or ((ap_const_logic_1 = ap_reg_ppiten_pp0_it0) and (ap_const_logic_1 = ap_sig_cseq_ST_pp0_stg1_fsm_3) and not(((ap_const_logic_1 = ap_reg_ppiten_pp0_it0) and ap_sig_bdd_190))))) then buffer_val_2_ce1 <= ap_const_logic_1; else buffer_val_2_ce1 <= ap_const_logic_0; end if; end process; -- buffer_val_2_d0 assign process. -- buffer_val_2_d0_assign_proc : process(buffer_val_2_q0, ap_reg_ppiten_pp0_it0, ap_sig_cseq_ST_pp0_stg1_fsm_3, p_val_2_reg_636, ap_sig_cseq_ST_pp0_stg2_fsm_4) begin if ((ap_const_logic_1 = ap_reg_ppiten_pp0_it0)) then if ((ap_const_logic_1 = ap_sig_cseq_ST_pp0_stg2_fsm_4)) then buffer_val_2_d0 <= p_val_2_reg_636; elsif ((ap_const_logic_1 = ap_sig_cseq_ST_pp0_stg1_fsm_3)) then buffer_val_2_d0 <= buffer_val_2_q0; else buffer_val_2_d0 <= "XXXXXXXX"; end if; else buffer_val_2_d0 <= "XXXXXXXX"; end if; end process; buffer_val_2_d1 <= buffer_val_2_q1; buffer_val_2_load_p_val_2_fu_493_p3 <= buffer_val_2_load_reg_655 when (brmerge1_2_fu_488_p2(0) = '1') else p_val_2_reg_636; -- buffer_val_2_we0 assign process. -- buffer_val_2_we0_assign_proc : process(exitcond1_reg_607, ap_reg_ppiten_pp0_it0, ap_sig_cseq_ST_pp0_stg1_fsm_3, ap_sig_bdd_190, ap_sig_cseq_ST_pp0_stg2_fsm_4) begin if ((((ap_const_logic_1 = ap_reg_ppiten_pp0_it0) and (exitcond1_reg_607 = ap_const_lv1_0) and (ap_const_logic_1 = ap_sig_cseq_ST_pp0_stg1_fsm_3) and not(((ap_const_logic_1 = ap_reg_ppiten_pp0_it0) and ap_sig_bdd_190))) or ((ap_const_logic_1 = ap_reg_ppiten_pp0_it0) and (exitcond1_reg_607 = ap_const_lv1_0) and (ap_const_logic_1 = ap_sig_cseq_ST_pp0_stg2_fsm_4)))) then buffer_val_2_we0 <= ap_const_logic_1; else buffer_val_2_we0 <= ap_const_logic_0; end if; end process; -- buffer_val_2_we1 assign process. -- buffer_val_2_we1_assign_proc : process(exitcond1_reg_607, ap_reg_ppiten_pp0_it0, ap_sig_cseq_ST_pp0_stg1_fsm_3, ap_sig_bdd_190) begin if ((((ap_const_logic_1 = ap_reg_ppiten_pp0_it0) and (exitcond1_reg_607 = ap_const_lv1_0) and (ap_const_logic_1 = ap_sig_cseq_ST_pp0_stg1_fsm_3) and not(((ap_const_logic_1 = ap_reg_ppiten_pp0_it0) and ap_sig_bdd_190))))) then buffer_val_2_we1 <= ap_const_logic_1; else buffer_val_2_we1 <= ap_const_logic_0; end if; end process; c_0_not_1_fu_439_p2 <= (c_1_reg_691 xor ap_const_lv1_1); c_0_not_2_fu_472_p2 <= (c_2_reg_707 xor ap_const_lv1_1); c_0_not_fu_406_p2 <= (c_reg_675 xor ap_const_lv1_1); c_1_fu_359_p2 <= "1" when (unsigned(buffer_val_1_q1) > unsigned(img_0_data_stream_1_V_dout)) else "0"; c_2_fu_383_p2 <= "1" when (unsigned(buffer_val_2_q1) > unsigned(img_0_data_stream_2_V_dout)) else "0"; c_fu_335_p2 <= "1" when (unsigned(buffer_val_0_q1) > unsigned(img_0_data_stream_0_V_dout)) else "0"; col_1_fu_313_p2 <= std_logic_vector(unsigned(col_phi_fu_273_p4) + unsigned(ap_const_lv11_1)); col_cast_fu_304_p1 <= std_logic_vector(resize(unsigned(col_phi_fu_273_p4),12)); -- col_phi_fu_273_p4 assign process. -- col_phi_fu_273_p4_assign_proc : process(col_reg_269, exitcond1_reg_607, ap_sig_cseq_ST_pp0_stg0_fsm_2, ap_reg_ppiten_pp0_it1, col_1_reg_611) begin if (((ap_const_logic_1 = ap_sig_cseq_ST_pp0_stg0_fsm_2) and (exitcond1_reg_607 = ap_const_lv1_0) and (ap_const_logic_1 = ap_reg_ppiten_pp0_it1))) then col_phi_fu_273_p4 <= col_1_reg_611; else col_phi_fu_273_p4 <= col_reg_269; end if; end process; exitcond1_fu_308_p2 <= "1" when (col_cast_fu_304_p1 = tmp_2_fu_285_p1) else "0"; exitcond2_fu_293_p2 <= "1" when (row_cast_fu_289_p1 = tmp_fu_281_p1) else "0"; icmp_fu_329_p2 <= "0" when (tmp_3_fu_319_p4 = ap_const_lv10_0) else "1"; -- img_0_data_stream_0_V_read assign process. -- img_0_data_stream_0_V_read_assign_proc : process(exitcond1_reg_607, ap_reg_ppiten_pp0_it0, ap_sig_cseq_ST_pp0_stg1_fsm_3, ap_sig_bdd_190) begin if (((ap_const_logic_1 = ap_reg_ppiten_pp0_it0) and (exitcond1_reg_607 = ap_const_lv1_0) and (ap_const_logic_1 = ap_sig_cseq_ST_pp0_stg1_fsm_3) and not(((ap_const_logic_1 = ap_reg_ppiten_pp0_it0) and ap_sig_bdd_190)))) then img_0_data_stream_0_V_read <= ap_const_logic_1; else img_0_data_stream_0_V_read <= ap_const_logic_0; end if; end process; -- img_0_data_stream_1_V_read assign process. -- img_0_data_stream_1_V_read_assign_proc : process(exitcond1_reg_607, ap_reg_ppiten_pp0_it0, ap_sig_cseq_ST_pp0_stg1_fsm_3, ap_sig_bdd_190) begin if (((ap_const_logic_1 = ap_reg_ppiten_pp0_it0) and (exitcond1_reg_607 = ap_const_lv1_0) and (ap_const_logic_1 = ap_sig_cseq_ST_pp0_stg1_fsm_3) and not(((ap_const_logic_1 = ap_reg_ppiten_pp0_it0) and ap_sig_bdd_190)))) then img_0_data_stream_1_V_read <= ap_const_logic_1; else img_0_data_stream_1_V_read <= ap_const_logic_0; end if; end process; -- img_0_data_stream_2_V_read assign process. -- img_0_data_stream_2_V_read_assign_proc : process(exitcond1_reg_607, ap_reg_ppiten_pp0_it0, ap_sig_cseq_ST_pp0_stg1_fsm_3, ap_sig_bdd_190) begin if (((ap_const_logic_1 = ap_reg_ppiten_pp0_it0) and (exitcond1_reg_607 = ap_const_lv1_0) and (ap_const_logic_1 = ap_sig_cseq_ST_pp0_stg1_fsm_3) and not(((ap_const_logic_1 = ap_reg_ppiten_pp0_it0) and ap_sig_bdd_190)))) then img_0_data_stream_2_V_read <= ap_const_logic_1; else img_0_data_stream_2_V_read <= ap_const_logic_0; end if; end process; img_1_data_stream_0_V_din <= p_val_0_1_reg_723 when (sel_tmp2_reg_738(0) = '1') else p_val_0_2_reg_733; -- img_1_data_stream_0_V_write assign process. -- img_1_data_stream_0_V_write_assign_proc : process(exitcond1_reg_607, ap_sig_cseq_ST_pp0_stg0_fsm_2, ap_sig_bdd_159, ap_reg_ppiten_pp0_it1) begin if (((ap_const_logic_1 = ap_sig_cseq_ST_pp0_stg0_fsm_2) and (exitcond1_reg_607 = ap_const_lv1_0) and (ap_const_logic_1 = ap_reg_ppiten_pp0_it1) and not((ap_sig_bdd_159 and (ap_const_logic_1 = ap_reg_ppiten_pp0_it1))))) then img_1_data_stream_0_V_write <= ap_const_logic_1; else img_1_data_stream_0_V_write <= ap_const_logic_0; end if; end process; img_1_data_stream_1_V_din <= p_val_1_1_reg_728 when (sel_tmp2_reg_738(0) = '1') else p_val_1_2_reg_744; -- img_1_data_stream_1_V_write assign process. -- img_1_data_stream_1_V_write_assign_proc : process(exitcond1_reg_607, ap_sig_cseq_ST_pp0_stg0_fsm_2, ap_sig_bdd_159, ap_reg_ppiten_pp0_it1) begin if (((ap_const_logic_1 = ap_sig_cseq_ST_pp0_stg0_fsm_2) and (exitcond1_reg_607 = ap_const_lv1_0) and (ap_const_logic_1 = ap_reg_ppiten_pp0_it1) and not((ap_sig_bdd_159 and (ap_const_logic_1 = ap_reg_ppiten_pp0_it1))))) then img_1_data_stream_1_V_write <= ap_const_logic_1; else img_1_data_stream_1_V_write <= ap_const_logic_0; end if; end process; img_1_data_stream_2_V_din <= tmp_6_reg_749; -- img_1_data_stream_2_V_write assign process. -- img_1_data_stream_2_V_write_assign_proc : process(exitcond1_reg_607, ap_sig_cseq_ST_pp0_stg0_fsm_2, ap_sig_bdd_159, ap_reg_ppiten_pp0_it1) begin if (((ap_const_logic_1 = ap_sig_cseq_ST_pp0_stg0_fsm_2) and (exitcond1_reg_607 = ap_const_lv1_0) and (ap_const_logic_1 = ap_reg_ppiten_pp0_it1) and not((ap_sig_bdd_159 and (ap_const_logic_1 = ap_reg_ppiten_pp0_it1))))) then img_1_data_stream_2_V_write <= ap_const_logic_1; else img_1_data_stream_2_V_write <= ap_const_logic_0; end if; end process; p_val_0_1_fu_427_p3 <= buffer_val_0_load_scl_val_0_fu_421_p3 when (brmerge_fu_411_p2(0) = '1') else buffer_val_0_load_1_reg_660; p_val_0_2_fu_499_p3 <= p_val_0_1_fu_427_p3 when (icmp_reg_616(0) = '1') else scl_val_0_reg_624; p_val_1_1_fu_460_p3 <= buffer_val_1_load_scl_val_1_fu_454_p3 when (brmerge_1_fu_444_p2(0) = '1') else buffer_val_1_load_1_reg_665; p_val_1_2_fu_510_p3 <= p_val_1_1_fu_460_p3 when (icmp_reg_616(0) = '1') else scl_val_1_reg_630; rev1_fu_353_p2 <= (ult1_fu_347_p2 xor ap_const_lv1_1); rev2_fu_434_p2 <= (ult2_reg_697 xor ap_const_lv1_1); rev3_fu_377_p2 <= (ult3_fu_371_p2 xor ap_const_lv1_1); rev4_fu_467_p2 <= (ult4_reg_713 xor ap_const_lv1_1); rev5_fu_483_p2 <= (ult5_reg_718 xor ap_const_lv1_1); rev_fu_401_p2 <= (ult_reg_681 xor ap_const_lv1_1); row_1_fu_298_p2 <= std_logic_vector(unsigned(row_reg_258) + unsigned(ap_const_lv11_1)); row_cast_fu_289_p1 <= std_logic_vector(resize(unsigned(row_reg_258),12)); sel_tmp2_fu_505_p2 <= (icmp_reg_616 and brmerge_2_fu_477_p2); sel_tmp9_fu_516_p3 <= buffer_val_2_load_1_reg_670 when (icmp_reg_616(0) = '1') else p_val_2_reg_636; tmp_2_fu_285_p1 <= cols(12 - 1 downto 0); tmp_3_fu_319_p4 <= col_phi_fu_273_p4(10 downto 1); tmp_6_fu_521_p3 <= buffer_val_2_load_p_val_2_fu_493_p3 when (sel_tmp2_fu_505_p2(0) = '1') else sel_tmp9_fu_516_p3; tmp_fu_281_p1 <= rows(12 - 1 downto 0); ult1_fu_347_p2 <= "1" when (unsigned(img_0_data_stream_0_V_dout) < unsigned(buffer_val_0_q0)) else "0"; ult2_fu_365_p2 <= "1" when (unsigned(buffer_val_1_q1) < unsigned(buffer_val_1_q0)) else "0"; ult3_fu_371_p2 <= "1" when (unsigned(img_0_data_stream_1_V_dout) < unsigned(buffer_val_1_q0)) else "0"; ult4_fu_389_p2 <= "1" when (unsigned(buffer_val_2_q1) < unsigned(buffer_val_2_q0)) else "0"; ult5_fu_395_p2 <= "1" when (unsigned(img_0_data_stream_2_V_dout) < unsigned(buffer_val_2_q0)) else "0"; ult_fu_341_p2 <= "1" when (unsigned(buffer_val_0_q1) < unsigned(buffer_val_0_q0)) else "0"; end behav;	gpl-3.0	19f7bf2117513b45b54b97634b37387e	0.599486	2.58978	false	false	false	false
mistryalok/Zedboard	learning/opencv_hls/xapp1167_ise/hw/xps_proj/pcores/logicvc_v3_00_a/doc/logicvc_comp.vhd	1	22,930	package logicbricks is -- START COMPONENT component logicvc is generic ( -- Version generics C_IP_LICENSE_TYPE : integer := 0; -- IP encryption type: 0 = source, 1 = evaluation, 2 = release, 3 = university evaluation C_IP_MAJOR_REVISION : integer := 0; -- IP major revision: 0 - 31; vXX_yy_z C_IP_MINOR_REVISION : integer := 0; -- IP minor revision: 0 - 31; vxx_YY_z C_IP_PATCH_LEVEL : integer := 0; -- IP patch level: 0 - 25; vxx_yy_Z C_IP_LICENSE_CHECK : integer := 0; -- IP license check: 0 = no, 1 = yes C_IP_TIME_BEFORE_BREAK : integer := 0; -- IP time before break: 0 = infinite, 1 = 1h, 2 = 12h, 3 = 24h C_FAMILY : string := "spartan6"; -- Video memory generics C_VMEM_INTERFACE : integer := 0; -- Use PLB, XMB or AXI to access video memory: 0 - PLB, 1 - XMB, 2 - AXI C_VMEM_BASEADDR : std_logic_vector := x"FFFFFFFF"; C_VMEM_HIGHADDR : std_logic_vector := x"00000000"; C_MEM_BURST : integer := 4; -- Memory burst width; 4, 5 or 6. (4 means burst lasts 16 transfers), Used for XMB and AXI C_MEM_BYTE_SWAP : integer := 0; -- Memory access byte swap: 0 - Do not swap, 1 - Swap C_MEM_LITTLE_ENDIAN : integer := 1; -- Memory access endianness: 0 - Big endian, 1 - Little endian C_INCREASE_FIFO : integer := 1; -- FIFO size multiplication factor: 1=1x, 2=2x, 4=4x, 8=8x -- Master PLB generics C_MPLB_NUM_MASTERS : integer := 8; C_MPLB_AWIDTH : integer := 32; C_MPLB_DWIDTH : integer := 64; C_MPLB_PRIORITY : integer := 3; C_MPLB_SMALLEST_SLAVE : integer := 32; -- XMB generics C_XMB_DATA_BUS_WIDTH : integer := 64; -- XMB Memory interface data bus width -- Master AXI generics C_M_AXI_THREAD_ID_WIDTH : integer := 1; C_M_AXI_DATA_WIDTH : integer := 64; C_M_AXI_ADDR_WIDTH : integer := 32; -- Registers generics C_REGS_INTERFACE : integer := 0; -- Use OPB, PLB or AXI interface for registers: 0 - OPB, 1 - PLB, 2 - AXI C_READABLE_REGS : integer := 1; -- Are logiCVC registers readable?: 0 - no, 1 - yes C_REG_BYTE_SWAP : integer := 0; -- Registers access byte swap: 0 - Do not swap, 1 - Swap -- OPB generics C_REGS_BASEADDR : std_logic_vector := x"FFFFFFFF"; C_REGS_HIGHADDR : std_logic_vector := x"00000000"; C_OPB_AWIDTH : integer := 32; C_OPB_DWIDTH : integer := 32; -- Slave PLB generics C_SPLB_NUM_MASTERS : integer := 8; C_SPLB_MID_WIDTH : integer := 1; C_SPLB_AWIDTH : integer := 32; C_SPLB_DWIDTH : integer := 32; C_SPLB_NATIVE_DWIDTH : integer := 32; -- AXI4-Lite Slave generics C_S_AXI_ADDR_WIDTH : integer := 32; C_S_AXI_DATA_WIDTH : integer := 32; -- Output format C_PIXEL_DATA_WIDTH : integer := 24; -- Output data width: 12, 15, 16, 18 or 24 C_USE_VCLK2 : integer := 1; -- pix_clk rising edge will be in the middle of the DDR RGB data eye or synchronous if not used C_ROW_STRIDE : integer := 1024; -- Row stride in number of pixels C_XCOLOR : integer := 0; C_USE_SIZE_POSITION : integer := 0; -- Use layer size, position and offset functionality: 0 - no, 1 - yes C_DISPLAY_INTERFACE : integer := 0; -- Select output interface type: 0 - parallel only, 1 - ITU656, 2 - LVDS 4bit, 3 - camera link, 4 - LVDS 3bit, 5 - DVI C_DISPLAY_COLOR_SPACE : integer := 0; -- Select output interface color space: 0 - RGB, 1 - YCbCr 4:2:2, 2 - YCbCr 4:4:4 C_LVDS_DATA_WIDTH : integer := 4; -- 3 or 4 C_VCLK_PERIOD : integer := 25000; -- vclk clock period in ps -- Multilayer generics C_NUM_OF_LAYERS : positive := 3; -- Number of logiCVC layers: 1, 2, 3, 4 or 5 C_LAYER_0_TYPE : integer := 0; -- Layer 0 type: 0 - RGB, 1 - YCbCr C_LAYER_1_TYPE : integer := 0; -- Layer 0 type: 0 - RGB, 1 - YCbCr, 2 - Alpha C_LAYER_2_TYPE : integer := 0; -- Layer 0 type: 0 - RGB, 1 - YCbCr C_LAYER_3_TYPE : integer := 0; -- Layer 0 type: 0 - RGB, 1 - YCbCr, 2 - Alpha C_LAYER_4_TYPE : integer := 0; -- Layer 0 type: 0 - RGB, 1 - YCbCr C_LAYER_0_DATA_WIDTH : positive := 16; -- Layer 0 data width: 8, 16, 24 bit C_LAYER_1_DATA_WIDTH : positive := 16; -- Layer 1 data width: 8, 16, 24 bit C_LAYER_2_DATA_WIDTH : positive := 16; -- Layer 2 data width: 8, 16, 24 bit C_LAYER_3_DATA_WIDTH : positive := 16; -- Layer 3 data width: 8, 16, 24 bit C_LAYER_4_DATA_WIDTH : positive := 16; -- Layer 4 data width: 8, 16, 24 bit C_LAYER_0_ALPHA_MODE : integer := 0; -- Layer 0 alpha blending mode: 0 - layer, 1 - pixel, 2 - clut 16, 3 - clut 24 C_LAYER_1_ALPHA_MODE : integer := 0; -- Layer 1 alpha blending mode: 0 - layer, 1 - pixel, 2 - clut 16, 3 - clut 24 C_LAYER_2_ALPHA_MODE : integer := 0; -- Layer 2 alpha blending mode: 0 - layer, 1 - pixel, 2 - clut 16, 3 - clut 24 C_LAYER_3_ALPHA_MODE : integer := 0; -- Layer 3 alpha blending mode: 0 - layer, 1 - pixel, 2 - clut 16, 3 - clut 24 C_LAYER_4_ALPHA_MODE : integer := 0; -- Layer 4 alpha blending mode: 0 - layer, 1 - pixel, 2 - clut 16, 3 - clut 24 C_USE_BACKGROUND : integer := 0; -- configure last layer as background: 0 - no, 1 - yes C_USE_XTREME_DSP : integer := 2; -- enable or disable use of DSP resources: 0 - no, 1 - yes, 2 - auto C_USE_MULTIPLIER : integer := 2; -- control way in which multipliers in blender are implemented: 0 - lut, 1 - block, 2 - auto C_LAYER_0_OFFSET : natural := 0; -- address offset for layer 0 in 2k steps for 16bpp and 1k steps for 8bpp C_LAYER_1_OFFSET : natural := 2048; -- address offset for layer 1 in 2k steps for 16bpp and 1k steps for 8bpp C_LAYER_2_OFFSET : natural := 4096; -- address offset for layer 2 in 2k steps for 16bpp and 1k steps for 8bpp C_LAYER_3_OFFSET : natural := 6144; -- address offset for layer 3 in 2k steps for 16bpp and 1k steps for 8bpp C_LAYER_4_OFFSET : natural := 8192; -- address offset for layer 4 in 2k steps for 16bpp and 1k steps for 8bpp C_BUFFER_0_OFFSET : natural := 1024; -- address offset for layer 0 double buffer relative to LAYER_0_OFFSET C_BUFFER_1_OFFSET : natural := 1024; -- address offset for layer 1 double buffer relative to LAYER_1_OFFSET C_BUFFER_2_OFFSET : natural := 1024; -- address offset for layer 2 double buffer relative to LAYER_2_OFFSET C_BUFFER_3_OFFSET : natural := 1024; -- address offset for layer 3 double buffer relative to LAYER_3_OFFSET C_BUFFER_4_OFFSET : natural := 1024; -- address offset for layer 4 double buffer relative to LAYER_4_OFFSET -- Extern parallel input generics C_USE_E_PARALLEL_INPUT : integer := 0; -- Syncronize logiCVC to external parallel input and use data as one layer: 0 - no, 1 - yes C_USE_E_VCLK_BUFGMUX : integer := 1; -- Use BUFGMUX for switching video clock to e_vclk, else use vclk C_E_LAYER : integer := 0; -- External parallel input layer: 0, 1, 2, 3, 4 C_E_DATA_WIDTH : integer := 24 -- External parallel input data width: 8, 16, 24 bit ); port( rst : in std_logic; -- Global reset mclk : in std_logic; -- Memory clock vclk : in std_logic; -- Video clock vclk2 : in std_logic; -- Video clock x2 itu_clk_in : in std_logic; -- It has to be 27 MHz and synchronous to vclk lvds_clk : in std_logic; -- lvds clock is 3.5x video clock lvds_clkn : in std_logic; -- Inverted lvds_clk -- Xylon Memory Bus (XMB) mem_req : out std_logic; mem_wr : out std_logic; mem_ack : in std_logic := '0'; mem_addr : out std_logic_vector(31 downto 0); mem_data : out std_logic_vector(C_XMB_DATA_BUS_WIDTH - 1 downto 0); mem_data_be : out std_logic_vector(C_XMB_DATA_BUS_WIDTH / 8 - 1 downto 0); mem_wrack : in std_logic := '0'; mem_burst : out std_logic_vector(C_MEM_BURST - 1 downto 0); mem_data_valid : in std_logic := '0'; mem_data_in : in std_logic_vector(C_XMB_DATA_BUS_WIDTH - 1 downto 0) := (others => '0'); -- PLB -------------- -- Master mplb_rst : in std_logic; plb_maddrack : in std_logic; plb_mrearbitrate : in std_logic; plb_mssize : in std_logic_vector(0 to 1); plb_mbusy : in std_logic; plb_mrderr : in std_logic; plb_mwrerr : in std_logic; plb_mtimeout : in std_logic; plb_mirq : in std_logic; m_request : out std_logic; m_priority : out std_logic_vector(0 to 1); m_buslock : out std_logic; m_rnw : out std_logic; m_be : out std_logic_vector(0 to (C_MPLB_DWIDTH / 8) - 1); m_size : out std_logic_vector(0 to 3); m_type : out std_logic_vector(0 to 2); m_msize : out std_logic_vector(0 to 1); m_tattribute : out std_logic_vector(0 to 15); m_lockerr : out std_logic; m_abort : out std_logic; m_abus : out std_logic_vector(0 to (C_MPLB_AWIDTH - 1)); m_uabus : out std_logic_vector(0 to (C_MPLB_AWIDTH - 1)); plb_mwrdack : in std_logic; plb_mwrbterm : in std_logic; m_wrburst : out std_logic; m_wrdbus : out std_logic_vector(0 to (C_MPLB_DWIDTH - 1)); plb_mrddack : in std_logic; plb_mrdbterm : in std_logic; plb_mrdwdaddr : in std_logic_vector(0 to 3); plb_mrddbus : in std_logic_vector(0 to (C_MPLB_DWIDTH - 1)); m_rdburst : out std_logic; -- AXI -------------- -- Master M_AXI_ARESETN : in std_logic; M_AXI_AWID : out std_logic_vector(C_M_AXI_THREAD_ID_WIDTH - 1 downto 0); M_AXI_AWADDR : out std_logic_vector(C_M_AXI_ADDR_WIDTH - 1 downto 0); M_AXI_AWLEN : out std_logic_vector(7 downto 0); M_AXI_AWSIZE : out std_logic_vector(2 downto 0); M_AXI_AWBURST : out std_logic_vector(1 downto 0); M_AXI_AWLOCK : out std_logic_vector(1 downto 0); M_AXI_AWCACHE : out std_logic_vector(3 downto 0); M_AXI_AWPROT : out std_logic_vector(2 downto 0); M_AXI_AWQOS : out std_logic_vector(3 downto 0); M_AXI_AWVALID : out std_logic; M_AXI_AWREADY : in std_logic; M_AXI_WDATA : out std_logic_vector(C_M_AXI_DATA_WIDTH - 1 downto 0); M_AXI_WSTRB : out std_logic_vector(C_M_AXI_DATA_WIDTH / 8 - 1 downto 0); M_AXI_WLAST : out std_logic; M_AXI_WVALID : out std_logic; M_AXI_WREADY : in std_logic; M_AXI_BID : in std_logic_vector(C_M_AXI_THREAD_ID_WIDTH - 1 downto 0); M_AXI_BRESP : in std_logic_vector(1 downto 0); M_AXI_BVALID : in std_logic; M_AXI_BREADY : out std_logic; M_AXI_ARID : out std_logic_vector(C_M_AXI_THREAD_ID_WIDTH - 1 downto 0); M_AXI_ARADDR : out std_logic_vector(C_M_AXI_ADDR_WIDTH - 1 downto 0); M_AXI_ARLEN : out std_logic_vector(7 downto 0); M_AXI_ARSIZE : out std_logic_vector(2 downto 0); M_AXI_ARBURST : out std_logic_vector(1 downto 0); M_AXI_ARLOCK : out std_logic_vector(1 downto 0); M_AXI_ARCACHE : out std_logic_vector(3 downto 0); M_AXI_ARPROT : out std_logic_vector(2 downto 0); M_AXI_ARQOS : out std_logic_vector(3 downto 0); M_AXI_ARVALID : out std_logic; M_AXI_ARREADY : in std_logic; M_AXI_RID : in std_logic_vector(C_M_AXI_THREAD_ID_WIDTH - 1 downto 0); M_AXI_RDATA : in std_logic_vector(C_M_AXI_DATA_WIDTH - 1 downto 0); M_AXI_RRESP : in std_logic_vector(1 downto 0); M_AXI_RLAST : in std_logic; M_AXI_RVALID : in std_logic; M_AXI_RREADY : out std_logic; ---------------------- -- OPB -------------- -- Slave OPB_Clk : in std_logic; OPB_Rst : in std_logic; OPB_ABus : in std_logic_vector(0 to C_OPB_AWIDTH - 1); OPB_BE : in std_logic_vector(0 to C_OPB_DWIDTH / 8 - 1); OPB_RNW : in std_logic; OPB_select : in std_logic; OPB_seqAddr : in std_logic; OPB_DBus : in std_logic_vector(0 to C_OPB_DWIDTH - 1); Sl_DBus : out std_logic_vector(0 to C_OPB_DWIDTH - 1); Sl_errAck : out std_logic; Sl_retry : out std_logic; Sl_toutSup : out std_logic; Sl_xferAck : out std_logic; ---------------------- -- PLB -------------- -- Slave SPLB_Clk : in std_logic; SPLB_Rst : in std_logic; PLB_ABus : in std_logic_vector(0 to C_SPLB_AWIDTH - 1); PLB_UABus : in std_logic_vector(0 to C_SPLB_AWIDTH - 1); PLB_PAValid : in std_logic; PLB_SAValid : in std_logic; PLB_rdPrim : in std_logic; PLB_wrPrim : in std_logic; PLB_masterID : in std_logic_vector(0 to C_SPLB_MID_WIDTH - 1); PLB_abort : in std_logic; PLB_busLock : in std_logic; PLB_RNW : in std_logic; PLB_BE : in std_logic_vector(0 to C_SPLB_DWIDTH / 8 - 1); PLB_MSize : in std_logic_vector(0 to 1); PLB_size : in std_logic_vector(0 to 3); PLB_type : in std_logic_vector(0 to 2); PLB_tattribute : in std_logic_vector(0 to 15); PLB_lockErr : in std_logic; PLB_wrDBus : in std_logic_vector(0 to C_SPLB_DWIDTH - 1); PLB_wrBurst : in std_logic; PLB_rdBurst : in std_logic; PLB_rdPendReq : in std_logic; PLB_wrPendReq : in std_logic; PLB_rdPendPri : in std_logic_vector(0 to 1); PLB_wrPendPri : in std_logic_vector(0 to 1); PLB_reqPri : in std_logic_vector(0 to 1); Sl_addrAck : out std_logic; Sl_SSize : out std_logic_vector(0 to 1); Sl_wait : out std_logic; Sl_rearbitrate : out std_logic; Sl_wrDAck : out std_logic; Sl_wrComp : out std_logic; Sl_wrBTerm : out std_logic; Sl_rdDBus : out std_logic_vector(0 to C_SPLB_DWIDTH - 1); Sl_rdWdAddr : out std_logic_vector(0 to 3); Sl_rdDAck : out std_logic; Sl_rdComp : out std_logic; Sl_rdBTerm : out std_logic; Sl_MBusy : out std_logic_vector(0 to C_SPLB_NUM_MASTERS - 1); Sl_MRdErr : out std_logic_vector(0 to C_SPLB_NUM_MASTERS - 1); Sl_MWrErr : out std_logic_vector(0 to C_SPLB_NUM_MASTERS - 1); Sl_MIRQ : out std_logic_vector(0 to C_SPLB_NUM_MASTERS - 1); ---------------------- -- AXI4-Lite -------- -- Slave S_AXI_ACLK : in std_logic; S_AXI_ARESETN : in std_logic; S_AXI_AWADDR : in std_logic_vector(C_S_AXI_ADDR_WIDTH - 1 downto 0); S_AXI_AWVALID : in std_logic; S_AXI_AWREADY : out std_logic; S_AXI_WDATA : in std_logic_vector(C_S_AXI_DATA_WIDTH - 1 downto 0); S_AXI_WSTRB : in std_logic_vector((C_S_AXI_DATA_WIDTH / 8) - 1 downto 0); S_AXI_WVALID : in std_logic; S_AXI_WREADY : out std_logic; S_AXI_BRESP : out std_logic_vector(1 downto 0); S_AXI_BVALID : out std_logic; S_AXI_BREADY : in std_logic; S_AXI_ARADDR : in std_logic_vector(C_S_AXI_ADDR_WIDTH - 1 downto 0); S_AXI_ARVALID : in std_logic; S_AXI_ARREADY : out std_logic; S_AXI_RDATA : out std_logic_vector(C_S_AXI_DATA_WIDTH - 1 downto 0); S_AXI_RRESP : out std_logic_vector(1 downto 0); S_AXI_RVALID : out std_logic; S_AXI_RREADY : in std_logic; ---------------------- -- Video Outputs -------------- pix_clk_i : in std_logic; -- Pixel clock pix_clk_o : out std_logic; -- Pixel clock pix_clk_t : out std_logic; -- Pixel clock pix_clk_n_i : in std_logic; -- Pixel clock inverted pix_clk_n_o : out std_logic; -- Pixel clock inverted pix_clk_n_t : out std_logic; -- Pixel clock inverted d_pix_i : in std_logic_vector(C_PIXEL_DATA_WIDTH - 1 downto 0); -- Pixel data bus d_pix_o : out std_logic_vector(C_PIXEL_DATA_WIDTH - 1 downto 0); -- Pixel data bus d_pix_t : out std_logic; -- Pixel data bus hsync_i : in std_logic; -- Hsync hsync_o : out std_logic; -- Hsync hsync_t : out std_logic; -- Hsync vsync_i : in std_logic; -- Vsync vsync_o : out std_logic; -- Vsync vsync_t : out std_logic; -- Vsync blank_i : in std_logic; -- Blank blank_o : out std_logic; -- Blank blank_t : out std_logic; -- Blank itu656_clk_o : out std_logic; -- ITU656 clock output itu656_data_o : out std_logic_vector(7 downto 0); -- ITU656 data output lvds_data_out_p : out std_logic_vector(C_LVDS_DATA_WIDTH - 1 downto 0); -- lvds data, positive lvds_data_out_n : out std_logic_vector(C_LVDS_DATA_WIDTH - 1 downto 0); -- lvds data, negative lvds_clk_out_p : out std_logic; -- lvds clk, positive lvds_clk_out_n : out std_logic; -- lvds clk, negative pllvclk_locked : in std_logic; -- PLL_BASE LOCKED (spartan6, LVDS clk gen) dvi_clk_p : out std_logic; -- DVI clock, positive dvi_clk_n : out std_logic; -- DVI clock, negative dvi_data_p : out std_logic_vector(2 downto 0); -- DVI data, positive dvi_data_n : out std_logic_vector(2 downto 0); -- DVI data, negative ---------------------- -- External parallel input -------------- e_vclk : in std_logic; -- External video clock e_vsync : in std_logic; -- External vsync e_hsync : in std_logic; -- External hsync e_blank : in std_logic; -- External blank e_data : in std_logic_vector(C_E_DATA_WIDTH - 1 downto 0); -- External data e_video_present : in std_logic; -- External video present flag ---------------------- -- Other -------------- e_curr_vbuff : in std_logic_vector(C_NUM_OF_LAYERS * 2 - 1 downto 0); -- Current external stream vbuffer e_next_vbuff : out std_logic_vector(C_NUM_OF_LAYERS * 2 - 1 downto 0); -- Next external stream vbuffer to write to e_sw_vbuff : in std_logic_vector(C_NUM_OF_LAYERS - 1 downto 0); -- Switch video buffers from external source e_sw_grant : out std_logic_vector(C_NUM_OF_LAYERS - 1 downto 0); -- Video buffers switch req granted vcdivsel : out std_logic_vector(1 downto 0); -- vclk div select bits vclksel : out std_logic_vector(2 downto 0); -- vclk select bits en_vdd : out std_logic; -- vdd enable en_blight : out std_logic; -- backlight enable v_en : out std_logic; -- Enable display control/data signals en_vee : out std_logic; -- vee enable interrupt : out std_logic -- logiCVC interrupt signal, level sensitive, high active ); end component; end logicbricks;	gpl-3.0	8401381d27bcbb1e092e55e94ffd8307	0.477191	3.73879	false	false	false	false
Fairyland0902/BlockyRoads	src/BlockyRoads/ipcore_dir/game_over/simulation/game_over_tb.vhd	1	4,361	-------------------------------------------------------------------------------- -- -- BLK MEM GEN v7_3 Core - Top File for the Example Testbench -- -------------------------------------------------------------------------------- -- -- (c) Copyright 2006_3010 Xilinx, Inc. All rights reserved. -- -- This file contains confidential and proprietary information -- of Xilinx, Inc. and is protected under U.S. and -- international copyright and other intellectual property -- laws. -- -- DISCLAIMER -- This disclaimer is not a license and does not grant any -- rights to the materials distributed herewith. Except as -- otherwise provided in a valid license issued to you by -- Xilinx, and to the maximum extent permitted by applicable -- law: (1) THESE MATERIALS ARE MADE AVAILABLE "AS IS" AND -- WITH ALL FAULTS, AND XILINX HEREBY DISCLAIMS ALL WARRANTIES -- AND CONDITIONS, EXPRESS, IMPLIED, OR STATUTORY, INCLUDING -- BUT NOT LIMITED TO WARRANTIES OF MERCHANTABILITY, NON- -- INFRINGEMENT, OR FITNESS FOR ANY PARTICULAR PURPOSE; and -- (2) Xilinx shall not be liable (whether in contract or tort, -- including negligence, or under any other theory of -- liability) for any loss or damage of any kind or nature -- related to, arising under or in connection with these -- materials, including for any direct, or any indirect, -- special, incidental, or consequential loss or damage -- (including loss of data, profits, goodwill, or any type of -- loss or damage suffered as a result of any action brought -- by a third party) even if such damage or loss was -- reasonably foreseeable or Xilinx had been advised of the -- possibility of the same. -- -- CRITICAL APPLICATIONS -- Xilinx products are not designed or intended to be fail- -- safe, or for use in any application requiring fail-safe -- performance, such as life-support or safety devices or -- systems, Class III medical devices, nuclear facilities, -- applications related to the deployment of airbags, or any -- other applications that could lead to death, personal -- injury, or severe property or environmental damage -- (individually and collectively, "Critical -- Applications"). Customer assumes the sole risk and -- liability of any use of Xilinx products in Critical -- Applications, subject only to applicable laws and -- regulations governing limitations on product liability. -- -- THIS COPYRIGHT NOTICE AND DISCLAIMER MUST BE RETAINED AS -- PART OF THIS FILE AT ALL TIMES. -------------------------------------------------------------------------------- -- Filename: game_over_tb.vhd -- Description: -- Testbench Top -------------------------------------------------------------------------------- -- Author: IP Solutions Division -- -- History: Sep 12, 2011 - First Release -------------------------------------------------------------------------------- -- -------------------------------------------------------------------------------- -- Library Declarations -------------------------------------------------------------------------------- LIBRARY IEEE; USE IEEE.STD_LOGIC_1164.ALL; USE IEEE.STD_LOGIC_ARITH.ALL; USE IEEE.STD_LOGIC_UNSIGNED.ALL; LIBRARY work; USE work.ALL; ENTITY game_over_tb IS END ENTITY; ARCHITECTURE game_over_tb_ARCH OF game_over_tb IS SIGNAL STATUS : STD_LOGIC_VECTOR(8 DOWNTO 0); SIGNAL CLK : STD_LOGIC := '1'; SIGNAL RESET : STD_LOGIC; BEGIN CLK_GEN: PROCESS BEGIN CLK <= NOT CLK; WAIT FOR 100 NS; CLK <= NOT CLK; WAIT FOR 100 NS; END PROCESS; RST_GEN: PROCESS BEGIN RESET <= '1'; WAIT FOR 1000 NS; RESET <= '0'; WAIT; END PROCESS; --STOP_SIM: PROCESS BEGIN -- WAIT FOR 200 US; -- STOP SIMULATION AFTER 1 MS -- ASSERT FALSE -- REPORT "END SIMULATION TIME REACHED" -- SEVERITY FAILURE; --END PROCESS; -- PROCESS BEGIN WAIT UNTIL STATUS(8)='1'; IF( STATUS(7 downto 0)/="0") THEN ASSERT false REPORT "Test Completed Successfully" SEVERITY NOTE; REPORT "Simulation Failed" SEVERITY FAILURE; ELSE ASSERT false REPORT "TEST PASS" SEVERITY NOTE; REPORT "Test Completed Successfully" SEVERITY FAILURE; END IF; END PROCESS; game_over_synth_inst:ENTITY work.game_over_synth GENERIC MAP (C_ROM_SYNTH => 0) PORT MAP( CLK_IN => CLK, RESET_IN => RESET, STATUS => STATUS ); END ARCHITECTURE;	mit	cbf1c1d0d8b8a830a73ec550143d30f2	0.619583	4.629512	false	false	false	false
marco-c/leon-nexys2	grlib-gpl-1.3.4-b4140/designs/leon3-gr-cpci-xc2v6000/testbench.vhd	1	19,150	------------------------------------------------------------------------------ -- LEON3 Demonstration design test bench -- Copyright (C) 2004 Jiri Gaisler, Gaisler Research ------------------------------------------------------------------------------ -- This file is a part of the GRLIB VHDL IP LIBRARY -- Copyright (C) 2003 - 2008, Gaisler Research -- Copyright (C) 2008 - 2013, Aeroflex Gaisler -- -- This program is free software; you can redistribute it and/or modify -- it under the terms of the GNU General Public License as published by -- the Free Software Foundation; either version 2 of the License, or -- (at your option) any later version. -- -- This program is distributed in the hope that it will be useful, -- but WITHOUT ANY WARRANTY; without even the implied warranty of -- MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the -- GNU General Public License for more details. -- -- You should have received a copy of the GNU General Public License -- along with this program; if not, write to the Free Software -- Foundation, Inc., 59 Temple Place, Suite 330, Boston, MA 02111-1307 USA ------------------------------------------------------------------------------ library ieee; use ieee.std_logic_1164.all; library gaisler; use gaisler.libdcom.all; use gaisler.sim.all; use work.debug.all; library techmap; use techmap.gencomp.all; library micron; use micron.components.all; use work.config.all; -- configuration entity testbench is generic ( fabtech : integer := CFG_FABTECH; memtech : integer := CFG_MEMTECH; padtech : integer := CFG_PADTECH; clktech : integer := CFG_CLKTECH; disas : integer := CFG_DISAS; -- Enable disassembly to console dbguart : integer := CFG_DUART; -- Print UART on console pclow : integer := CFG_PCLOW; clkperiod : integer := 20; -- system clock period romwidth : integer := 32; -- rom data width (8/32) romdepth : integer := 16; -- rom address depth sramwidth : integer := 32; -- ram data width (8/16/32) sramdepth : integer := 20; -- ram address depth srambanks : integer := 2 -- number of ram banks ); port ( pci_rst : inout std_logic; -- PCI bus pci_clk : in std_logic; pci_gnt : in std_logic; pci_idsel : in std_logic; pci_lock : inout std_logic; pci_ad : inout std_logic_vector(31 downto 0); pci_cbe : inout std_logic_vector(3 downto 0); pci_frame : inout std_logic; pci_irdy : inout std_logic; pci_trdy : inout std_logic; pci_devsel : inout std_logic; pci_stop : inout std_logic; pci_perr : inout std_logic; pci_par : inout std_logic; pci_req : inout std_logic; pci_serr : inout std_logic; pci_host : in std_logic := 'L'; pci_66 : in std_logic ); end; architecture behav of testbench is constant promfile : string := "prom.srec"; -- rom contents constant sramfile : string := "ram.srec"; -- ram contents constant sdramfile : string := "ram.srec"; -- sdram contents component leon3mp generic ( fabtech : integer := CFG_FABTECH; memtech : integer := CFG_MEMTECH; padtech : integer := CFG_PADTECH; clktech : integer := CFG_CLKTECH; disas : integer := CFG_DISAS; -- Enable disassembly to console dbguart : integer := CFG_DUART; -- Print UART on console pclow : integer := CFG_PCLOW ); port ( resetn : in std_logic; clk : in std_logic; pllref : in std_logic; errorn : out std_logic; address : out std_logic_vector(27 downto 0); data : inout std_logic_vector(31 downto 0); sa : out std_logic_vector(14 downto 0); sd : inout std_logic_vector(63 downto 0); sdclk : out std_logic; sdcke : out std_logic_vector (1 downto 0); -- sdram clock enable sdcsn : out std_logic_vector (1 downto 0); -- sdram chip select sdwen : out std_logic; -- sdram write enable sdrasn : out std_logic; -- sdram ras sdcasn : out std_logic; -- sdram cas sddqm : out std_logic_vector (7 downto 0); -- sdram dqm dsutx : out std_logic; -- DSU tx data dsurx : in std_logic; -- DSU rx data dsuen : in std_logic; dsubre : in std_logic; dsuact : out std_logic; txd1 : out std_logic; -- UART1 tx data rxd1 : in std_logic; -- UART1 rx data txd2 : out std_logic; -- UART1 tx data rxd2 : in std_logic; -- UART1 rx data ramsn : out std_logic_vector (4 downto 0); ramoen : out std_logic_vector (4 downto 0); rwen : out std_logic_vector (3 downto 0); oen : out std_logic; writen : out std_logic; read : out std_logic; iosn : out std_logic; romsn : out std_logic_vector (1 downto 0); gpio : inout std_logic_vector(7 downto 0); -- I/O port emdio : inout std_logic; -- ethernet PHY interface etx_clk : in std_logic; erx_clk : in std_logic; erxd : in std_logic_vector(3 downto 0); erx_dv : in std_logic; erx_er : in std_logic; erx_col : in std_logic; erx_crs : in std_logic; etxd : out std_logic_vector(3 downto 0); etx_en : out std_logic; etx_er : out std_logic; emdc : out std_logic; pci_rst : inout std_logic; -- PCI bus pci_clk : in std_logic; pci_gnt : in std_logic; pci_idsel : in std_logic; pci_lock : inout std_logic; pci_ad : inout std_logic_vector(31 downto 0); pci_cbe : inout std_logic_vector(3 downto 0); pci_frame : inout std_logic; pci_irdy : inout std_logic; pci_trdy : inout std_logic; pci_devsel : inout std_logic; pci_stop : inout std_logic; pci_perr : inout std_logic; pci_par : inout std_logic; pci_req : inout std_logic; pci_serr : inout std_logic; pci_host : in std_logic; pci_66 : in std_logic; pci_arb_req : in std_logic_vector(0 to 3); pci_arb_gnt : out std_logic_vector(0 to 3); can_txd : out std_logic_vector(0 to 1); can_rxd : in std_logic_vector(0 to 1); can_stb : out std_logic_vector(0 to 1); spw_rxd : in std_logic_vector(0 to 2); spw_rxdn : in std_logic_vector(0 to 2); spw_rxs : in std_logic_vector(0 to 2); spw_rxsn : in std_logic_vector(0 to 2); spw_txd : out std_logic_vector(0 to 2); spw_txdn : out std_logic_vector(0 to 2); spw_txs : out std_logic_vector(0 to 2); spw_txsn : out std_logic_vector(0 to 2) ); end component; signal clk : std_logic := '0'; signal Rst : std_logic := '0'; -- Reset constant ct : integer := clkperiod/2; signal address : std_logic_vector(27 downto 0); signal data : std_logic_vector(31 downto 0); signal ramsn : std_logic_vector(4 downto 0); signal ramoen : std_logic_vector(4 downto 0); signal rwen : std_logic_vector(3 downto 0); signal rwenx : std_logic_vector(3 downto 0); signal romsn : std_logic_vector(1 downto 0); signal iosn : std_logic; signal oen : std_logic; signal read : std_logic; signal writen : std_logic; signal brdyn : std_logic; signal bexcn : std_logic; signal wdog : std_logic; signal dsuen, dsutx, dsurx, dsubre, dsuact : std_logic; signal dsurst : std_logic; signal test : std_logic; signal error : std_logic; signal gpio : std_logic_vector(7 downto 0); signal GND : std_logic := '0'; signal VCC : std_logic := '1'; signal NC : std_logic := 'Z'; signal clk2 : std_logic := '1'; signal sdcke : std_logic_vector ( 1 downto 0); -- clk en signal sdcsn : std_logic_vector ( 1 downto 0); -- chip sel signal sdwen : std_logic; -- write en signal sdrasn : std_logic; -- row addr stb signal sdcasn : std_logic; -- col addr stb signal sddqm : std_logic_vector ( 7 downto 0); -- data i/o mask signal sdclk : std_logic; signal plllock : std_logic; signal txd1, rxd1 : std_logic; signal txd2, rxd2 : std_logic; signal etx_clk, erx_clk, erx_dv, erx_er, erx_col, erx_crs, etx_en, etx_er : std_logic:='0'; signal erxd, etxd: std_logic_vector(3 downto 0):=(others=>'0'); signal erxdt, etxdt: std_logic_vector(7 downto 0):=(others=>'0'); signal emdc, emdio: std_logic; --dummy signal for the mdc,mdio in the phy which is not used signal gtx_clk : std_logic; signal emddis : std_logic; signal epwrdwn : std_logic; signal ereset : std_logic; signal esleep : std_logic; signal epause : std_logic; signal led_cfg: std_logic_vector(2 downto 0); constant lresp : boolean := false; signal sa : std_logic_vector(14 downto 0); signal sd : std_logic_vector(63 downto 0); signal pci_arb_req, pci_arb_gnt : std_logic_vector(0 to 3); signal can_txd : std_logic_vector(0 to 1); signal can_rxd : std_logic_vector(0 to 1); signal can_stb : std_logic_vector(0 to 1); signal spw_rxd : std_logic_vector(0 to 2) := "000"; signal spw_rxdn : std_logic_vector(0 to 2) := "000"; signal spw_rxs : std_logic_vector(0 to 2) := "000"; signal spw_rxsn : std_logic_vector(0 to 2) := "000"; signal spw_txd : std_logic_vector(0 to 2); signal spw_txdn : std_logic_vector(0 to 2); signal spw_txs : std_logic_vector(0 to 2); signal spw_txsn : std_logic_vector(0 to 2); begin -- clock and reset clk <= not clk after ct * 1 ns; rst <= dsurst; dsuen <= '1'; dsubre <= '0'; rxd1 <= '1'; can_rxd <= (others => '1'); spw_rxd(0) <= spw_txd(0); spw_rxdn(0) <= spw_txdn(0); spw_rxs(0) <= spw_txs(0); spw_rxsn(0) <= spw_txsn(0); spw_rxd(1) <= spw_txd(1); spw_rxdn(1) <= spw_txdn(1); spw_rxs(1) <= spw_txs(1); spw_rxsn(1) <= spw_txsn(1); spw_rxd(2) <= spw_txd(0); spw_rxdn(2) <= spw_txdn(2); spw_rxs(2) <= spw_txs(0); spw_rxsn(2) <= spw_txsn(2); d3 : leon3mp generic map ( fabtech, memtech, padtech, clktech, disas, dbguart, pclow ) port map (rst, clk, sdclk, error, address(27 downto 0), data, sa, sd, sdclk, sdcke, sdcsn, sdwen, sdrasn, sdcasn, sddqm, dsutx, dsurx, dsuen, dsubre, dsuact, txd1, rxd1, txd2, rxd2, ramsn, ramoen, rwen, oen, writen, read, iosn, romsn, gpio, emdio, etx_clk, erx_clk, erxd, erx_dv, erx_er, erx_col, erx_crs, etxd, etx_en, etx_er, emdc, pci_rst, pci_clk, pci_gnt, pci_idsel, pci_lock, pci_ad, pci_cbe, pci_frame, pci_irdy, pci_trdy, pci_devsel, pci_stop, pci_perr, pci_par, pci_req, pci_serr, pci_host, pci_66, pci_arb_req, pci_arb_gnt, can_txd, can_rxd, can_stb, spw_rxd, spw_rxdn, spw_rxs, spw_rxsn, spw_txd, spw_txdn, spw_txs, spw_txsn); -- optional sdram sd0 : if (CFG_SDEN = 1) and (CFG_SEPBUS = 0) generate u0: mt48lc16m16a2 generic map (index => 0, fname => sdramfile) PORT MAP( Dq => data(31 downto 16), Addr => address(14 downto 2), Ba => address(16 downto 15), Clk => sdclk, Cke => sdcke(0), Cs_n => sdcsn(0), Ras_n => sdrasn, Cas_n => sdcasn, We_n => sdwen, Dqm => sddqm(3 downto 2)); u1: mt48lc16m16a2 generic map (index => 16, fname => sdramfile) PORT MAP( Dq => data(15 downto 0), Addr => address(14 downto 2), Ba => address(16 downto 15), Clk => sdclk, Cke => sdcke(0), Cs_n => sdcsn(0), Ras_n => sdrasn, Cas_n => sdcasn, We_n => sdwen, Dqm => sddqm(1 downto 0)); u2: mt48lc16m16a2 generic map (index => 0, fname => sdramfile) PORT MAP( Dq => data(31 downto 16), Addr => address(14 downto 2), Ba => address(16 downto 15), Clk => sdclk, Cke => sdcke(0), Cs_n => sdcsn(1), Ras_n => sdrasn, Cas_n => sdcasn, We_n => sdwen, Dqm => sddqm(3 downto 2)); u3: mt48lc16m16a2 generic map (index => 16, fname => sdramfile) PORT MAP( Dq => data(15 downto 0), Addr => address(14 downto 2), Ba => address(16 downto 15), Clk => sdclk, Cke => sdcke(0), Cs_n => sdcsn(1), Ras_n => sdrasn, Cas_n => sdcasn, We_n => sdwen, Dqm => sddqm(1 downto 0)); end generate; sd1 : if (CFG_SDEN = 1) and (CFG_SEPBUS = 1) generate u0: mt48lc16m16a2 generic map (index => 0, fname => sdramfile) PORT MAP( Dq => sd(31 downto 16), Addr => sa(12 downto 0), Ba => sa(14 downto 13), Clk => sdclk, Cke => sdcke(0), Cs_n => sdcsn(0), Ras_n => sdrasn, Cas_n => sdcasn, We_n => sdwen, Dqm => sddqm(3 downto 2)); u1: mt48lc16m16a2 generic map (index => 16, fname => sdramfile) PORT MAP( Dq => sd(15 downto 0), Addr => sa(12 downto 0), Ba => sa(14 downto 13), Clk => sdclk, Cke => sdcke(0), Cs_n => sdcsn(0), Ras_n => sdrasn, Cas_n => sdcasn, We_n => sdwen, Dqm => sddqm(1 downto 0)); u2: mt48lc16m16a2 generic map (index => 0, fname => sdramfile) PORT MAP( Dq => sd(31 downto 16), Addr => sa(12 downto 0), Ba => sa(14 downto 13), Clk => sdclk, Cke => sdcke(0), Cs_n => sdcsn(1), Ras_n => sdrasn, Cas_n => sdcasn, We_n => sdwen, Dqm => sddqm(3 downto 2)); u3: mt48lc16m16a2 generic map (index => 16, fname => sdramfile) PORT MAP( Dq => sd(15 downto 0), Addr => sa(12 downto 0), Ba => sa(14 downto 13), Clk => sdclk, Cke => sdcke(0), Cs_n => sdcsn(1), Ras_n => sdrasn, Cas_n => sdcasn, We_n => sdwen, Dqm => sddqm(1 downto 0)); sd64 : if (CFG_SD64 = 1) generate u4: mt48lc16m16a2 generic map (index => 0, fname => sdramfile) PORT MAP( Dq => sd(63 downto 48), Addr => sa(12 downto 0), Ba => sa(14 downto 13), Clk => sdclk, Cke => sdcke(0), Cs_n => sdcsn(0), Ras_n => sdrasn, Cas_n => sdcasn, We_n => sdwen, Dqm => sddqm(7 downto 6)); u5: mt48lc16m16a2 generic map (index => 16, fname => sdramfile) PORT MAP( Dq => sd(47 downto 32), Addr => sa(12 downto 0), Ba => sa(14 downto 13), Clk => sdclk, Cke => sdcke(0), Cs_n => sdcsn(0), Ras_n => sdrasn, Cas_n => sdcasn, We_n => sdwen, Dqm => sddqm(5 downto 4)); u6: mt48lc16m16a2 generic map (index => 0, fname => sdramfile) PORT MAP( Dq => sd(63 downto 48), Addr => sa(12 downto 0), Ba => sa(14 downto 13), Clk => sdclk, Cke => sdcke(0), Cs_n => sdcsn(1), Ras_n => sdrasn, Cas_n => sdcasn, We_n => sdwen, Dqm => sddqm(7 downto 6)); u7: mt48lc16m16a2 generic map (index => 16, fname => sdramfile) PORT MAP( Dq => sd(47 downto 32), Addr => sa(12 downto 0), Ba => sa(14 downto 13), Clk => sdclk, Cke => sdcke(0), Cs_n => sdcsn(1), Ras_n => sdrasn, Cas_n => sdcasn, We_n => sdwen, Dqm => sddqm(5 downto 4)); end generate; end generate; prom0 : for i in 0 to (romwidth/8)-1 generate sr0 : sram generic map (index => i, abits => romdepth, fname => promfile) port map (address(romdepth+1 downto 2), data(31-i8 downto 24-i8), romsn(0), rwen(i), oen); end generate; sram0 : for i in 0 to (sramwidth/8)-1 generate sr0 : sram generic map (index => i, abits => sramdepth, fname => sramfile) port map (address(sramdepth+1 downto 2), data(31-i8 downto 24-i8), ramsn(0), rwen(0), ramoen(0)); end generate; phy0 : if (CFG_GRETH = 1) generate emdio <= 'H'; erxd <= erxdt(3 downto 0); etxdt <= "0000" & etxd; p0: phy generic map(base1000_t_fd => 0, base1000_t_hd => 0) port map(rst, emdio, etx_clk, erx_clk, erxdt, erx_dv, erx_er, erx_col, erx_crs, etxdt, etx_en, etx_er, emdc, gtx_clk); end generate; error <= 'H'; -- ERROR pull-up iuerr : process begin wait for 2500 ns; if to_x01(error) = '1' then wait on error; end if; assert (to_x01(error) = '1') report "* IU in error mode, simulation halted " severity failure ; end process; test0 : grtestmod port map ( rst, clk, error, address(21 downto 2), data, iosn, oen, writen, brdyn); data <= buskeep(data), (others => 'H') after 250 ns; sd <= buskeep(sd), (others => 'H') after 250 ns; dsucom : process procedure dsucfg(signal dsurx : in std_logic; signal dsutx : out std_logic) is variable w32 : std_logic_vector(31 downto 0); variable c8 : std_logic_vector(7 downto 0); constant txp : time := 160 1 ns; begin dsutx <= '1'; dsurst <= '0'; wait for 500 ns; dsurst <= '1'; wait; wait for 5000 ns; txc(dsutx, 16#55#, txp); -- sync uart -- txc(dsutx, 16#c0#, txp); -- txa(dsutx, 16#90#, 16#00#, 16#00#, 16#00#, txp); -- txa(dsutx, 16#00#, 16#00#, 16#02#, 16#ae#, txp); -- txc(dsutx, 16#c0#, txp); -- txa(dsutx, 16#91#, 16#00#, 16#00#, 16#00#, txp); -- txa(dsutx, 16#00#, 16#00#, 16#06#, 16#ae#, txp); -- txc(dsutx, 16#c0#, txp); -- txa(dsutx, 16#90#, 16#00#, 16#00#, 16#24#, txp); -- txa(dsutx, 16#00#, 16#00#, 16#06#, 16#03#, txp); -- txc(dsutx, 16#c0#, txp); -- txa(dsutx, 16#90#, 16#00#, 16#00#, 16#20#, txp); -- txa(dsutx, 16#00#, 16#00#, 16#06#, 16#fc#, txp); txc(dsutx, 16#c0#, txp); txa(dsutx, 16#90#, 16#00#, 16#00#, 16#00#, txp); txa(dsutx, 16#00#, 16#00#, 16#00#, 16#2f#, txp); txc(dsutx, 16#c0#, txp); txa(dsutx, 16#91#, 16#00#, 16#00#, 16#00#, txp); txa(dsutx, 16#00#, 16#00#, 16#00#, 16#6f#, txp); txc(dsutx, 16#c0#, txp); txa(dsutx, 16#90#, 16#11#, 16#00#, 16#00#, txp); txa(dsutx, 16#00#, 16#00#, 16#00#, 16#00#, txp); txc(dsutx, 16#c0#, txp); txa(dsutx, 16#90#, 16#40#, 16#00#, 16#04#, txp); txa(dsutx, 16#00#, 16#02#, 16#20#, 16#01#, txp); txc(dsutx, 16#c0#, txp); txa(dsutx, 16#90#, 16#00#, 16#00#, 16#20#, txp); txa(dsutx, 16#00#, 16#00#, 16#00#, 16#02#, txp); txc(dsutx, 16#c0#, txp); txa(dsutx, 16#90#, 16#00#, 16#00#, 16#20#, txp); txa(dsutx, 16#00#, 16#00#, 16#00#, 16#0f#, txp); txc(dsutx, 16#c0#, txp); txa(dsutx, 16#40#, 16#00#, 16#43#, 16#10#, txp); txa(dsutx, 16#00#, 16#00#, 16#00#, 16#0f#, txp); txc(dsutx, 16#c0#, txp); txa(dsutx, 16#91#, 16#40#, 16#00#, 16#24#, txp); txa(dsutx, 16#00#, 16#00#, 16#00#, 16#24#, txp); txc(dsutx, 16#c0#, txp); txa(dsutx, 16#91#, 16#70#, 16#00#, 16#00#, txp); txa(dsutx, 16#00#, 16#00#, 16#00#, 16#03#, txp); txc(dsutx, 16#c0#, txp); txa(dsutx, 16#90#, 16#00#, 16#00#, 16#20#, txp); txa(dsutx, 16#00#, 16#00#, 16#ff#, 16#ff#, txp); txc(dsutx, 16#c0#, txp); txa(dsutx, 16#90#, 16#40#, 16#00#, 16#48#, txp); txa(dsutx, 16#00#, 16#00#, 16#00#, 16#12#, txp); txc(dsutx, 16#c0#, txp); txa(dsutx, 16#90#, 16#40#, 16#00#, 16#60#, txp); txa(dsutx, 16#00#, 16#00#, 16#12#, 16#10#, txp); txc(dsutx, 16#80#, txp); txa(dsutx, 16#90#, 16#00#, 16#00#, 16#00#, txp); rxi(dsurx, w32, txp, lresp); txc(dsutx, 16#a0#, txp); txa(dsutx, 16#40#, 16#00#, 16#00#, 16#00#, txp); rxi(dsurx, w32, txp, lresp); end; begin dsucfg(dsutx, dsurx); wait; end process; end ;	gpl-2.0	12c0ed14a007a9f163086fb1c4602f3f	0.568982	3.038236	false	false	false	false
marco-c/leon-nexys2	grlib-gpl-1.3.4-b4140/lib/gaisler/ddr/ahb2avl_async.vhd	1	5,671	------------------------------------------------------------------------------ -- This file is a part of the GRLIB VHDL IP LIBRARY -- Copyright (C) 2003 - 2008, Gaisler Research -- Copyright (C) 2008 - 2013, Aeroflex Gaisler -- -- This program is free software; you can redistribute it and/or modify -- it under the terms of the GNU General Public License as published by -- the Free Software Foundation; either version 2 of the License, or -- (at your option) any later version. -- -- This program is distributed in the hope that it will be useful, -- but WITHOUT ANY WARRANTY; without even the implied warranty of -- MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the -- GNU General Public License for more details. -- -- You should have received a copy of the GNU General Public License -- along with this program; if not, write to the Free Software -- Foundation, Inc., 59 Temple Place, Suite 330, Boston, MA 02111-1307 USA ----------------------------------------------------------------------------- -- Entity: ahb2avl_async -- File: ahb2avl_async.vhd -- Author: Magnus Hjorth - Aeroflex Gaisler -- Description: Asynchronous AHB to Avalon-MM interface based on ddr2spa -------------------------------------------------------------------------------- library ieee; use ieee.std_logic_1164.all; library grlib; use grlib.amba.all; use grlib.stdlib.all; use grlib.devices.all; library gaisler; use gaisler.ddrpkg.all; use gaisler.ddrintpkg.all; entity ahb2avl_async is generic ( hindex : integer := 0; haddr : integer := 0; hmask : integer := 16#f00#; burstlen : integer := 8; nosync : integer := 0; ahbbits : integer := ahbdw; avldbits : integer := 32; avlabits : integer := 20 ); port ( rst_ahb : in std_ulogic; clk_ahb : in std_ulogic; ahbsi : in ahb_slv_in_type; ahbso : out ahb_slv_out_type; rst_avl : in std_ulogic; clk_avl : in std_ulogic; avlsi : out ddravl_slv_in_type; avlso : in ddravl_slv_out_type ); end; architecture struct of ahb2avl_async is constant l2blen: integer := log2(burstlen)+log2(32); constant l2ddrw: integer := log2(avldbits); constant l2ahbw: integer := log2(ahbbits); -- Write buffer dimensions constant wbuf_rabits_s: integer := 1+l2blen-l2ddrw; constant wbuf_rabits_r: integer := wbuf_rabits_s; constant wbuf_rdbits: integer := avldbits; constant wbuf_wabits: integer := 1+l2blen-5; constant wbuf_wdbits: integer := ahbbits; -- Read buffer dimensions constant rbuf_rabits: integer := l2blen-l2ahbw; constant rbuf_rdbits: integer := wbuf_wdbits; constant rbuf_wabits: integer := l2blen-l2ddrw; -- log2((burstlen32)/(2ddrbits)); constant rbuf_wdbits: integer := avldbits; signal request : ddr_request_type; signal start_tog : std_ulogic; signal response : ddr_response_type; signal wbwaddr: std_logic_vector(wbuf_wabits-1 downto 0); signal wbwdata: std_logic_vector(wbuf_wdbits-1 downto 0); signal wbraddr: std_logic_vector(wbuf_rabits_s-1 downto 0); signal wbrdata: std_logic_vector(wbuf_rdbits-1 downto 0); signal rbwaddr: std_logic_vector(rbuf_wabits-1 downto 0); signal rbwdata: std_logic_vector(rbuf_wdbits-1 downto 0); signal rbraddr: std_logic_vector(rbuf_rabits-1 downto 0); signal rbrdata: std_logic_vector(rbuf_rdbits-1 downto 0); signal wbwrite,wbwritebig,rbwrite: std_ulogic; signal gnd: std_logic_vector(3 downto 0); signal vcc: std_ulogic; begin gnd <= (others => '0'); vcc <= '1'; fe0: ddr2spax_ahb generic map ( hindex => hindex, haddr => haddr, hmask => hmask, ioaddr => 0, iomask => 0, burstlen => burstlen, nosync => nosync, ahbbits => ahbbits, devid => GAISLER_AHB2AVLA, ddrbits => avldbits/2 ) port map ( rst => rst_ahb, clk_ahb => clk_ahb, ahbsi => ahbsi, ahbso => ahbso, request => request, start_tog => start_tog, response => response, wbwaddr => wbwaddr, wbwdata => wbwdata, wbwrite => wbwrite, wbwritebig => wbwritebig, rbraddr => rbraddr, rbrdata => rbrdata, hwidth => gnd(0), beid => gnd(3 downto 0) ); be0: ahb2avl_async_be generic map ( avldbits => avldbits, avlabits => avlabits, burstlen => burstlen, nosync => nosync ) port map ( rst => rst_avl, clk => clk_avl, avlsi => avlsi, avlso => avlso, request => request, start_tog => start_tog, response => response, wbraddr => wbraddr, wbrdata => wbrdata, rbwaddr => rbwaddr, rbwdata => rbwdata, rbwrite => rbwrite ); wbuf: ddr2buf generic map (tech => 0, wabits => wbuf_wabits, wdbits => wbuf_wdbits, rabits => wbuf_rabits_r, rdbits => wbuf_rdbits, sepclk => 1, wrfst => 0) port map ( rclk => clk_avl, renable => vcc, raddress => wbraddr(wbuf_rabits_r-1 downto 0), dataout => wbrdata, wclk => clk_ahb, write => wbwrite, writebig => wbwritebig, waddress => wbwaddr, datain => wbwdata); rbuf: ddr2buf generic map (tech => 0, wabits => rbuf_wabits, wdbits => rbuf_wdbits, rabits => rbuf_rabits, rdbits => rbuf_rdbits, sepclk => 1, wrfst => 0) port map ( rclk => clk_ahb, renable => vcc, raddress => rbraddr, dataout => rbrdata, wclk => clk_avl, write => rbwrite, writebig => '0', waddress => rbwaddr, datain => rbwdata); end;	gpl-2.0	a508829e566544e37fe4e673029fb8bc	0.59478	3.924567	false	false	false	false
mistryalok/Zedboard	learning/opencv_hls/xapp1167_vivado/sw/fast-corner/prj/solution1/syn/vhdl/FIFO_image_filter_p_src_data_stream_0_V.vhd	2	4,629	-- ============================================================== -- File generated by Vivado(TM) HLS - High-Level Synthesis from C, C++ and SystemC -- Version: 2014.4 -- Copyright (C) 2014 Xilinx Inc. All rights reserved. -- -- ============================================================== library IEEE; use IEEE.std_logic_1164.all; use IEEE.std_logic_unsigned.all; entity FIFO_image_filter_p_src_data_stream_0_V_shiftReg is generic ( DATA_WIDTH : integer := 8; ADDR_WIDTH : integer := 1; DEPTH : integer := 2); port ( clk : in std_logic; data : in std_logic_vector(DATA_WIDTH-1 downto 0); ce : in std_logic; a : in std_logic_vector(ADDR_WIDTH-1 downto 0); q : out std_logic_vector(DATA_WIDTH-1 downto 0)); end FIFO_image_filter_p_src_data_stream_0_V_shiftReg; architecture rtl of FIFO_image_filter_p_src_data_stream_0_V_shiftReg is --constant DEPTH_WIDTH: integer := 16; type SRL_ARRAY is array (0 to DEPTH-1) of std_logic_vector(DATA_WIDTH-1 downto 0); signal SRL_SIG : SRL_ARRAY; begin p_shift: process (clk) begin if (clk'event and clk = '1') then if (ce = '1') then SRL_SIG <= data & SRL_SIG(0 to DEPTH-2); end if; end if; end process; q <= SRL_SIG(conv_integer(a)); end rtl; library ieee; use ieee.std_logic_1164.all; use ieee.std_logic_unsigned.all; entity FIFO_image_filter_p_src_data_stream_0_V is generic ( MEM_STYLE : string := "auto"; DATA_WIDTH : integer := 8; ADDR_WIDTH : integer := 1; DEPTH : integer := 2); port ( clk : IN STD_LOGIC; reset : IN STD_LOGIC; if_empty_n : OUT STD_LOGIC; if_read_ce : IN STD_LOGIC; if_read : IN STD_LOGIC; if_dout : OUT STD_LOGIC_VECTOR(DATA_WIDTH - 1 downto 0); if_full_n : OUT STD_LOGIC; if_write_ce : IN STD_LOGIC; if_write : IN STD_LOGIC; if_din : IN STD_LOGIC_VECTOR(DATA_WIDTH - 1 downto 0)); end entity; architecture rtl of FIFO_image_filter_p_src_data_stream_0_V is component FIFO_image_filter_p_src_data_stream_0_V_shiftReg is generic ( DATA_WIDTH : integer := 8; ADDR_WIDTH : integer := 1; DEPTH : integer := 2); port ( clk : in std_logic; data : in std_logic_vector(DATA_WIDTH-1 downto 0); ce : in std_logic; a : in std_logic_vector(ADDR_WIDTH-1 downto 0); q : out std_logic_vector(DATA_WIDTH-1 downto 0)); end component; signal shiftReg_addr : STD_LOGIC_VECTOR(ADDR_WIDTH - 1 downto 0); signal shiftReg_data, shiftReg_q : STD_LOGIC_VECTOR(DATA_WIDTH - 1 downto 0); signal shiftReg_ce : STD_LOGIC; signal mOutPtr : STD_LOGIC_VECTOR(ADDR_WIDTH downto 0) := (others => '1'); signal internal_empty_n : STD_LOGIC := '0'; signal internal_full_n : STD_LOGIC := '1'; begin if_empty_n <= internal_empty_n; if_full_n <= internal_full_n; shiftReg_data <= if_din; if_dout <= shiftReg_q; process (clk) begin if clk'event and clk = '1' then if reset = '1' then mOutPtr <= (others => '1'); internal_empty_n <= '0'; internal_full_n <= '1'; else if ((if_read and if_read_ce) = '1' and internal_empty_n = '1') and ((if_write and if_write_ce) = '0' or internal_full_n = '0') then mOutPtr <= mOutPtr -1; if (mOutPtr = 0) then internal_empty_n <= '0'; end if; internal_full_n <= '1'; elsif ((if_read and if_read_ce) = '0' or internal_empty_n = '0') and ((if_write and if_write_ce) = '1' and internal_full_n = '1') then mOutPtr <= mOutPtr +1; internal_empty_n <= '1'; if (mOutPtr = DEPTH -2) then internal_full_n <= '0'; end if; end if; end if; end if; end process; shiftReg_addr <= (others => '0') when mOutPtr(ADDR_WIDTH) = '1' else mOutPtr(ADDR_WIDTH-1 downto 0); shiftReg_ce <= (if_write and if_write_ce) and internal_full_n; U_FIFO_image_filter_p_src_data_stream_0_V_shiftReg : FIFO_image_filter_p_src_data_stream_0_V_shiftReg generic map ( DATA_WIDTH => DATA_WIDTH, ADDR_WIDTH => ADDR_WIDTH, DEPTH => DEPTH) port map ( clk => clk, data => shiftReg_data, ce => shiftReg_ce, a => shiftReg_addr, q => shiftReg_q); end rtl;	gpl-3.0	3b3269b788d2112b5acdb7f5e67b62da	0.537697	3.449329	false	false	false	false
laurocruz/snakes_vhdl	src/snake_lib/make_map.vhd	1	2,607	LIBRARY ieee; USE ieee.std_logic_1164.all; LIBRARY snake_lib; USE snake_lib.snake_pack.all; -- controlador do mapa do jogo ENTITY make_map IS -- DImensões do mapa GENERIC (N : INTEGER := 10; M : INTEGER := 10; INITIAL_SIZE : INTEGER := 2); -- clock do jogo PORT (clock : IN STD_LOGIC; -- reseta o jogo reset : IN STD_LOGIC; -- aumento do tamanho eaten : IN STD_LOGIC; snake_size : IN INTEGER RANGE 0 TO NM; -- direcao para onde a cobra esta se movendo -- 11 : cima -- 00 : baixo -- 10 : esquerda -- 01 : direita dir : IN STD_LOGIC_VECTOR(1 DOWNTO 0); -- posicoes da cobra no mapa snake_body : OUT int_array); END make_map; ARCHITECTURE Behavior OF make_map IS -- Vetor de estruturas de dois inteiros que representam a posição de cada parte da cobra (l,c) --TYPE snake_body IS array (0 to NM-1) OF INTEGER RANGE 0 TO NM-1; --SIGNAL snake : snake_body; SIGNAL snake : int_array; SIGNAL dir_s : STD_LOGIC_VECTOR(1 DOWNTO 0); BEGIN snake_body <= snake; dir_s <= dir; PROCESS (clock, reset, eaten) VARIABLE j : INTEGER RANGE 0 TO NM; VARIABLE DIF : INTEGER RANGE 0 TO M; --VARIABLE index : INTEGER RANGE 0 TO NM; --VARIABLE map_s : STD_LOGIC_VECTOR(0 TO NM-1); BEGIN IF (reset = '1') THEN FOR i in 0 to INITIAL_SIZE-1 LOOP snake(i) <= (N/2) + (i+M/2)M; END LOOP; FOR i in INITIAL_SIZE to NM-1 LOOP snake(i) <= -1; END LOOP; ELSIF (eaten = '1') THEN DIF := snake(snake_size-1) - snake(snake_size-2); snake(snake_size) <= snake(snake_size-1) + DIF; ELSIF (clock'EVENT and clock = '1') THEN j := 0; WHILE (j+1 < MN and not(snake(j+1) = -1)) LOOP snake(j+1) <= snake(j); j := j + 1; END LOOP; --FOR i IN 0 TO snake_size-2 LOOP -- snake(i+1) <= snake(i); --END LOOP; IF (dir_s = "00") THEN snake(0) <= snake(0) + M; ELSIF (dir_s = "01") THEN snake(0) <= snake(0) + 1; ELSIF (dir_s = "10") THEN snake(0) <= snake(0) - 1; ELSE snake(0) <= snake(0) - M; END IF; --map_s := (OTHERS => '0'); --j := 0; --WHILE (j < MN and not(snake(j) = -1)) LOOP -- index := snake(j); -- map_s(index) := '1'; -- j := j + 1; --END LOOP; END IF; --gmap <= map_s; END PROCESS; END Behavior;	mit	afd52d16422faa9ad2870e4a05a62c08	0.508065	2.955732	false	false	false	false
marco-c/leon-nexys2	grlib-gpl-1.3.4-b4140/designs/leon3-nuhorizons-3s1500/testbench.vhd	1	13,633	----------------------------------------------------------------------------- -- LEON3 Demonstration design test bench -- Copyright (C) 2004 Jiri Gaisler, Gaisler Research ------------------------------------------------------------------------------ -- This file is a part of the GRLIB VHDL IP LIBRARY -- Copyright (C) 2003 - 2008, Gaisler Research -- Copyright (C) 2008 - 2013, Aeroflex Gaisler -- -- This program is free software; you can redistribute it and/or modify -- it under the terms of the GNU General Public License as published by -- the Free Software Foundation; either version 2 of the License, or -- (at your option) any later version. -- -- This program is distributed in the hope that it will be useful, -- but WITHOUT ANY WARRANTY; without even the implied warranty of -- MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the -- GNU General Public License for more details. -- -- You should have received a copy of the GNU General Public License -- along with this program; if not, write to the Free Software -- Foundation, Inc., 59 Temple Place, Suite 330, Boston, MA 02111-1307 USA ------------------------------------------------------------------------------ library ieee; use ieee.std_logic_1164.all; library gaisler; use gaisler.libdcom.all; use gaisler.sim.all; library techmap; use techmap.gencomp.all; library micron; use micron.components.all; use work.config.all; -- configuration use work.debug.all; entity testbench is generic ( fabtech : integer := CFG_FABTECH; memtech : integer := CFG_MEMTECH; padtech : integer := CFG_PADTECH; clktech : integer := CFG_CLKTECH; disas : integer := CFG_DISAS; -- Enable disassembly to console dbguart : integer := CFG_DUART; -- Print UART on console pclow : integer := CFG_PCLOW; clkperiod : integer := 20; -- system clock period romwidth : integer := 8+8CFG_MCTRL_RAM16BIT; -- rom data width (8/16) romdepth : integer := 16; -- rom address depth sramwidth : integer := 32; -- ram data width (8/16/32) sramdepth : integer := 18; -- ram address depth srambanks : integer := 2 -- number of ram banks ); end; architecture behav of testbench is constant promfile : string := "prom.srec"; -- rom contents constant sramfile : string := "ram.srec"; -- ram contents constant sdramfile : string := "ram.srec"; -- sdram contents component leon3mp generic ( fabtech : integer := CFG_FABTECH; memtech : integer := CFG_MEMTECH; padtech : integer := CFG_PADTECH; clktech : integer := CFG_CLKTECH; disas : integer := CFG_DISAS; -- Enable disassembly to console dbguart : integer := CFG_DUART; -- Print UART on console pclow : integer := CFG_PCLOW ); port ( pb_sw : in std_logic_vector (4 downto 1); -- push buttons pll_clk : in std_ulogic; -- PLL clock led : out std_logic_vector(8 downto 1); flash_a : out std_logic_vector(20 downto 0); flash_d : inout std_logic_vector(15 downto 0); sdram_a : out std_logic_vector(11 downto 0); sdram_d : inout std_logic_vector(31 downto 0); sdram_ba : out std_logic_vector(3 downto 0); sdram_dqm : out std_logic_vector(3 downto 0); sdram_clk : inout std_ulogic; sdram_cke : out std_ulogic; -- sdram clock enable sdram_csn : out std_ulogic; -- sdram chip select sdram_wen : out std_ulogic; -- sdram write enable sdram_rasn : out std_ulogic; -- sdram ras sdram_casn : out std_ulogic; -- sdram cas uart1_txd : out std_ulogic; uart1_rxd : in std_ulogic; uart1_rts : out std_ulogic; uart1_cts : in std_ulogic; uart2_txd : out std_ulogic; uart2_rxd : in std_ulogic; uart2_rts : out std_ulogic; uart2_cts : in std_ulogic; flash_oen : out std_ulogic; flash_wen : out std_ulogic; flash_cen : out std_ulogic; flash_byte : out std_ulogic; flash_ready : in std_ulogic; flash_rpn : out std_ulogic; flash_wpn : out std_ulogic; phy_mii_data: inout std_logic; -- ethernet PHY interface phy_tx_clk : in std_ulogic; phy_rx_clk : in std_ulogic; phy_rx_data : in std_logic_vector(3 downto 0); phy_dv : in std_ulogic; phy_rx_er : in std_ulogic; phy_col : in std_ulogic; phy_crs : in std_ulogic; phy_tx_data : out std_logic_vector(3 downto 0); phy_tx_en : out std_ulogic; phy_mii_clk : out std_ulogic; phy_100 : in std_ulogic; -- 100 Mbit indicator phy_rst_n : out std_ulogic; gpio : inout std_logic_vector(CFG_GRGPIO_WIDTH-1 downto 0); -- lcd_data : inout std_logic_vector(7 downto 0); -- lcd_rs : out std_ulogic; -- lcd_rw : out std_ulogic; -- lcd_en : out std_ulogic; -- lcd_backl : out std_ulogic; can_txd : out std_ulogic; can_rxd : in std_ulogic; smsc_addr : out std_logic_vector(14 downto 0); smsc_data : inout std_logic_vector(31 downto 0); smsc_nbe : out std_logic_vector(3 downto 0); smsc_resetn : out std_ulogic; smsc_ardy : in std_ulogic; -- smsc_intr : in std_ulogic; smsc_nldev : in std_ulogic; smsc_nrd : out std_ulogic; smsc_nwr : out std_ulogic; smsc_ncs : out std_ulogic; smsc_aen : out std_ulogic; smsc_lclk : out std_ulogic; smsc_wnr : out std_ulogic; smsc_rdyrtn : out std_ulogic; smsc_cycle : out std_ulogic; smsc_nads : out std_ulogic ); end component; signal clk : std_logic := '0'; signal Rst : std_logic := '0'; -- Reset constant ct : integer := clkperiod/2; signal address : std_logic_vector(21 downto 0); signal flash_d : std_logic_vector(15 downto 0); signal romsn : std_ulogic; signal oen : std_ulogic; signal writen : std_ulogic; signal dsuen, dsutx, dsurx, dsubre, dsuact : std_ulogic; signal dsurst : std_ulogic; signal test : std_ulogic; signal error : std_logic; signal GND : std_ulogic := '0'; signal VCC : std_ulogic := '1'; signal NC : std_ulogic := 'Z'; signal clk2 : std_ulogic := '1'; signal sdcke : std_ulogic; -- clk en signal sdcsn : std_ulogic; -- chip sel signal sdwen : std_ulogic; -- write en signal sdrasn : std_ulogic; -- row addr stb signal sdcasn : std_ulogic; -- col addr stb signal sddqm : std_logic_vector ( 3 downto 0); -- data i/o mask signal sdclk : std_ulogic; signal txd1, rxd1 : std_ulogic; signal txd2, rxd2 : std_ulogic; signal etx_clk, erx_clk, erx_dv, erx_er, erx_col, erx_crs, etx_en, etx_er : std_logic:='0'; signal erxd, etxd: std_logic_vector(3 downto 0):=(others=>'0'); signal erxdt, etxdt: std_logic_vector(7 downto 0):=(others=>'0'); signal emdc, emdio: std_logic; signal gtx_clk : std_ulogic; signal ereset : std_logic; signal led : std_logic_vector(8 downto 1); constant lresp : boolean := false; signal sa : std_logic_vector(14 downto 0); signal ba : std_logic_vector(3 downto 0); signal sd : std_logic_vector(31 downto 0); signal pb_sw : std_logic_vector(4 downto 1); signal lcd_data : std_logic_vector(7 downto 0); signal lcd_rs : std_ulogic; signal lcd_rw : std_ulogic; signal lcd_en : std_ulogic; signal lcd_backl: std_ulogic; signal can_txd : std_ulogic; signal can_rxd : std_ulogic; signal gpio : std_logic_vector(CFG_GRGPIO_WIDTH-1 downto 0); signal smsc_addr : std_logic_vector(21 downto 0); signal smsc_data : std_logic_vector(31 downto 0); signal smsc_nbe : std_logic_vector(3 downto 0); signal smsc_resetn : std_ulogic; signal smsc_ardy : std_ulogic; signal smsc_intr : std_ulogic; signal smsc_nldev : std_ulogic; signal smsc_nrd : std_ulogic; signal smsc_nwr : std_ulogic; signal smsc_ncs : std_ulogic; signal smsc_aen : std_ulogic; signal smsc_lclk : std_ulogic; signal smsc_wnr : std_ulogic; signal smsc_rdyrtn : std_ulogic; signal smsc_cycle : std_ulogic; signal smsc_nads : std_ulogic; begin -- clock and reset clk <= not clk after ct 1 ns; rst <= dsurst; dsuen <= '1'; dsubre <= '0'; rxd1 <= '1'; can_rxd <= '1'; error <= led(8); sa(14 downto 12) <= "000"; pb_sw <= rst & "00" & dsubre; cpu : leon3mp generic map ( fabtech, memtech, padtech, clktech, disas, dbguart, pclow ) port map (pb_sw, clk, led, address(21 downto 1), flash_d, sa(11 downto 0), sd, ba, sddqm, sdclk, sdcke, sdcsn, sdwen, sdrasn, sdcasn, txd1, rxd1, open, gnd, dsutx, dsurx, open, gnd, oen, writen, romsn, open, vcc, open, open, emdio, etx_clk, erx_clk, erxd, erx_dv, erx_er, erx_col, erx_crs, etxd, etx_en, emdc, gnd, ereset, gpio, -- lcd_data, lcd_rs, lcd_rw, lcd_en, lcd_backl, can_txd, can_rxd, smsc_addr(14 downto 0), smsc_data, smsc_nbe, smsc_resetn, smsc_ardy,-- smsc_intr, smsc_nldev, smsc_nrd, smsc_nwr, smsc_ncs, smsc_aen, smsc_lclk, smsc_wnr, smsc_rdyrtn, smsc_cycle, smsc_nads); u0: mt48lc16m16a2 generic map (index => 0, fname => sdramfile) PORT MAP( Dq => sd(31 downto 16), Addr => sa(12 downto 0), Ba => ba(1 downto 0), Clk => sdclk, Cke => sdcke, Cs_n => sdcsn, Ras_n => sdrasn, Cas_n => sdcasn, We_n => sdwen, Dqm => sddqm(3 downto 2)); u1: mt48lc16m16a2 generic map (index => 16, fname => sdramfile) PORT MAP( Dq => sd(15 downto 0), Addr => sa(12 downto 0), Ba => ba(3 downto 2), Clk => sdclk, Cke => sdcke, Cs_n => sdcsn, Ras_n => sdrasn, Cas_n => sdcasn, We_n => sdwen, Dqm => sddqm(1 downto 0)); rom8 : if romwidth /= 16 generate prom0 : sram16 generic map (index => 4, abits => romdepth, fname => promfile) port map (address(romdepth downto 1), flash_d(15 downto 0), gnd, gnd, romsn, writen, oen); address(0) <= flash_d(15); end generate; rom16 : if romwidth = 16 generate prom0 : sram16 generic map (index => 4, abits => romdepth, fname => promfile) port map (address(romdepth downto 1), flash_d(15 downto 0), gnd, gnd, romsn, writen, oen); address(0) <= '0'; end generate; emdio <= 'H'; erxd <= erxdt(3 downto 0); etxdt <= "0000" & etxd; p0: phy generic map(base1000_t_fd => 0, base1000_t_hd => 0) port map(rst, emdio, etx_clk, erx_clk, erxdt, erx_dv, erx_er, erx_col, erx_crs, etxdt, etx_en, etx_er, emdc, gtx_clk); error <= 'H'; -- ERROR pull-up iuerr : process begin wait for 2000 ns; if to_x01(error) = '1' then wait on error; end if; assert (to_x01(error) = '1') report "* IU in error mode, simulation halted " severity failure ; end process; flash_d <= buskeep(flash_d) after 5 ns; sd <= buskeep(sd) after 5 ns; smsc_data <= buskeep(smsc_data) after 5 ns; smsc_addr(21 downto 15) <= (others => '0'); test0 : grtestmod port map ( rst, clk, error, address(21 downto 2), smsc_data, smsc_ncs, oen, writen, open); dsucom : process procedure dsucfg(signal dsurx : in std_ulogic; signal dsutx : out std_ulogic) is variable w32 : std_logic_vector(31 downto 0); variable c8 : std_logic_vector(7 downto 0); constant txp : time := 160 1 ns; begin dsutx <= '1'; dsurst <= '0'; wait for 500 ns; dsurst <= '1'; wait; wait for 5000 ns; txc(dsutx, 16#55#, txp); -- sync uart txc(dsutx, 16#c0#, txp); txa(dsutx, 16#90#, 16#40#, 16#00#, 16#44#, txp); txa(dsutx, 16#00#, 16#00#, 16#20#, 16#00#, txp); txc(dsutx, 16#80#, txp); txa(dsutx, 16#90#, 16#40#, 16#00#, 16#44#, txp); wait; txc(dsutx, 16#c0#, txp); txa(dsutx, 16#00#, 16#00#, 16#0a#, 16#aa#, txp); txa(dsutx, 16#00#, 16#55#, 16#00#, 16#55#, txp); txc(dsutx, 16#c0#, txp); txa(dsutx, 16#00#, 16#00#, 16#0a#, 16#a0#, txp); txa(dsutx, 16#01#, 16#02#, 16#09#, 16#33#, txp); txc(dsutx, 16#c0#, txp); txa(dsutx, 16#90#, 16#00#, 16#00#, 16#00#, txp); txa(dsutx, 16#00#, 16#00#, 16#00#, 16#2e#, txp); txc(dsutx, 16#c0#, txp); txa(dsutx, 16#91#, 16#00#, 16#00#, 16#00#, txp); txa(dsutx, 16#00#, 16#00#, 16#00#, 16#2e#, txp); txc(dsutx, 16#c0#, txp); txa(dsutx, 16#90#, 16#00#, 16#00#, 16#20#, txp); txa(dsutx, 16#00#, 16#00#, 16#00#, 16#0f#, txp); txc(dsutx, 16#c0#, txp); txa(dsutx, 16#90#, 16#00#, 16#00#, 16#20#, txp); txa(dsutx, 16#00#, 16#00#, 16#00#, 16#00#, txp); txc(dsutx, 16#c0#, txp); txa(dsutx, 16#80#, 16#00#, 16#02#, 16#10#, txp); txa(dsutx, 16#00#, 16#00#, 16#00#, 16#0f#, txp); txc(dsutx, 16#c0#, txp); txa(dsutx, 16#91#, 16#40#, 16#00#, 16#24#, txp); txa(dsutx, 16#00#, 16#00#, 16#00#, 16#24#, txp); txc(dsutx, 16#c0#, txp); txa(dsutx, 16#91#, 16#70#, 16#00#, 16#00#, txp); txa(dsutx, 16#00#, 16#00#, 16#00#, 16#03#, txp); txc(dsutx, 16#c0#, txp); txa(dsutx, 16#90#, 16#00#, 16#00#, 16#20#, txp); txa(dsutx, 16#00#, 16#00#, 16#ff#, 16#ff#, txp); txc(dsutx, 16#c0#, txp); txa(dsutx, 16#90#, 16#40#, 16#00#, 16#48#, txp); txa(dsutx, 16#00#, 16#00#, 16#00#, 16#12#, txp); txc(dsutx, 16#c0#, txp); txa(dsutx, 16#90#, 16#40#, 16#00#, 16#60#, txp); txa(dsutx, 16#00#, 16#00#, 16#12#, 16#10#, txp); txc(dsutx, 16#80#, txp); txa(dsutx, 16#90#, 16#00#, 16#00#, 16#00#, txp); rxi(dsurx, w32, txp, lresp); txc(dsutx, 16#a0#, txp); txa(dsutx, 16#40#, 16#00#, 16#00#, 16#00#, txp); rxi(dsurx, w32, txp, lresp); end; begin dsucfg(dsutx, dsurx); wait; end process; end ;	gpl-2.0	a6ef3c9b1ea70705254894133c477b6a	0.591946	3.045119	false	false	false	false
marco-c/leon-nexys2	grlib-gpl-1.3.4-b4140/designs/leon3-avnet-3s1500/leon3mp.vhd	1	26,269	----------------------------------------------------------------------------- -- LEON3 Demonstration design for AVNET Spartan3 Evaluation Board -- Copyright (C) 2004 Jiri Gaisler, Gaisler Research ------------------------------------------------------------------------------ -- This file is a part of the GRLIB VHDL IP LIBRARY -- Copyright (C) 2003 - 2008, Gaisler Research -- Copyright (C) 2008 - 2013, Aeroflex Gaisler -- -- This program is free software; you can redistribute it and/or modify -- it under the terms of the GNU General Public License as published by -- the Free Software Foundation; either version 2 of the License, or -- (at your option) any later version. -- -- This program is distributed in the hope that it will be useful, -- but WITHOUT ANY WARRANTY; without even the implied warranty of -- MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the -- GNU General Public License for more details. -- -- You should have received a copy of the GNU General Public License -- along with this program; if not, write to the Free Software -- Foundation, Inc., 59 Temple Place, Suite 330, Boston, MA 02111-1307 USA ------------------------------------------------------------------------------ library ieee; use ieee.std_logic_1164.all; library grlib; use grlib.amba.all; use grlib.stdlib.all; library techmap; use techmap.gencomp.all; use techmap.allclkgen.all; library gaisler; use gaisler.memctrl.all; use gaisler.leon3.all; use gaisler.uart.all; use gaisler.misc.all; use gaisler.pci.all; use gaisler.net.all; use gaisler.jtag.all; use gaisler.can.all; library esa; use esa.memoryctrl.all; use esa.pcicomp.all; use work.config.all; entity leon3mp is generic ( fabtech : integer := CFG_FABTECH; memtech : integer := CFG_MEMTECH; padtech : integer := CFG_PADTECH; clktech : integer := CFG_CLKTECH; disas : integer := CFG_DISAS; -- Enable disassembly to console dbguart : integer := CFG_DUART; -- Print UART on console pclow : integer := CFG_PCLOW; mezz : integer := CFG_ADS_DAU_MEZZ ); port ( clk_66mhz : in std_logic; clk_socket : in std_logic; leds : out std_logic_vector(7 downto 0); switches : in std_logic_vector(5 downto 0); sram_a : out std_logic_vector(24 downto 0); sram_ben_l : out std_logic_vector(0 to 3); sram_cs_l : out std_logic_vector(1 downto 0); sram_oe_l : out std_logic; sram_we_l : out std_logic; sram_dq : inout std_logic_vector(31 downto 0); flash_cs_l : out std_logic; flash_rst_l : out std_logic; iosn : out std_logic; sdclk : out std_logic; rasn : out std_logic; casn : out std_logic; sdcke : out std_logic; sdcsn : out std_logic; tx : out std_logic; rx : in std_logic; can_txd : out std_logic; can_rxd : in std_logic; phy_txck : in std_logic; phy_rxck : in std_logic; phy_rxd : in std_logic_vector(3 downto 0); phy_rxdv : in std_logic; phy_rxer : in std_logic; phy_col : in std_logic; phy_crs : in std_logic; phy_txd : out std_logic_vector(3 downto 0); phy_txen : out std_logic; phy_txer : out std_logic; phy_mdc : out std_logic; phy_mdio : inout std_logic; -- ethernet PHY interface phy_reset_l : inout std_logic; video_clk : in std_logic; comp_sync : out std_logic; horiz_sync : out std_logic; vert_sync : out std_logic; blank : out std_logic; video_out : out std_logic_vector(23 downto 0); msclk : inout std_logic; msdata : inout std_logic; kbclk : inout std_logic; kbdata : inout std_logic; disp_seg1 : out std_logic_vector(7 downto 0); disp_seg2 : out std_logic_vector(7 downto 0); pci_clk : in std_logic; pci_gnt : in std_logic; pci_idsel : in std_logic; pci_lock : inout std_logic; pci_ad : inout std_logic_vector(31 downto 0); pci_cbe : inout std_logic_vector(3 downto 0); pci_frame : inout std_logic; pci_irdy : inout std_logic; pci_trdy : inout std_logic; pci_devsel : inout std_logic; pci_stop : inout std_logic; pci_perr : inout std_logic; pci_par : inout std_logic; pci_req : inout std_logic; pci_serr : inout std_logic; pci_host : in std_logic; pci_66 : in std_logic ); end; architecture rtl of leon3mp is constant blength : integer := 12; constant fifodepth : integer := 8; constant mahbmax : integer := CFG_NCPU+CFG_AHB_UART+CFG_PCI+ CFG_SVGA_ENABLE + CFG_GRETH+CFG_AHB_JTAG; signal vcc, gnd : std_logic_vector(23 downto 0); signal memi : memory_in_type; signal memo : memory_out_type; signal wpo : wprot_out_type; signal sdi : sdctrl_in_type; signal sdo : sdram_out_type; signal abus : std_logic_vector(17 downto 0); signal apbi : apb_slv_in_type; signal apbo : apb_slv_out_vector := (others => apb_none); signal ahbsi : ahb_slv_in_type; signal ahbso : ahb_slv_out_vector := (others => ahbs_none); signal ahbmi : ahb_mst_in_type; signal ahbmo : ahb_mst_out_vector := (others => ahbm_none); signal clk, rstn, rstraw, pciclk, sdclkl : std_logic; signal cgi : clkgen_in_type; signal cgo : clkgen_out_type; signal u1i, u2i, dui : uart_in_type; signal u1o, u2o, duo : uart_out_type; signal irqi : irq_in_vector(0 to CFG_NCPU-1); signal irqo : irq_out_vector(0 to CFG_NCPU-1); signal dbgi : l3_debug_in_vector(0 to CFG_NCPU-1); signal dbgo : l3_debug_out_vector(0 to CFG_NCPU-1); signal dsui : dsu_in_type; signal dsuo : dsu_out_type; signal kbdi : ps2_in_type; signal kbdo : ps2_out_type; signal moui : ps2_in_type; signal mouo : ps2_out_type; signal vgao : apbvga_out_type; signal pcii : pci_in_type; signal pcio : pci_out_type; signal ethi, ethi1, ethi2 : eth_in_type; signal etho, etho1, etho2 : eth_out_type; signal gpti : gptimer_in_type; signal tck, tms, tdi, tdo : std_logic; signal pllref, errorn, pci_rst : std_logic; signal pci_arb_req_n, pci_arb_gnt_n : std_logic_vector(0 to 3); signal dac_clk, clk25, clk_66mhzl, pci_lclk : std_logic; signal can_ltx, can_lrx : std_logic; attribute keep : boolean; attribute syn_keep : boolean; attribute syn_preserve : boolean; attribute syn_keep of clk : signal is true; attribute syn_preserve of clk : signal is true; attribute keep of clk : signal is true; signal switchesl : std_logic_vector(5 downto 0); constant padlevel : integer := 0; constant IOAEN : integer := CFG_CAN; constant BOARD_FREQ : integer := 66667; -- input frequency in KHz constant CPU_FREQ : integer := (BOARD_FREQ * CFG_CLKMUL) / CFG_CLKDIV; begin ---------------------------------------------------------------------- --- Reset and Clock generation ------------------------------------- --------------------------------------------------------------------- vcc <= (others => '1'); gnd <= (others => '0'); pllref <= '0'; cgi.pllctrl <= "00"; cgi.pllrst <= rstraw; cgi.pllref <= pllref; clkgen0 : clkgen -- clock generator generic map (clktech, CFG_CLKMUL, CFG_CLKDIV, CFG_MCTRL_SDEN, CFG_CLK_NOFB, CFG_PCI, CFG_PCIDLL, CFG_PCISYSCLK, 66000) port map (clk_66mhzl, pci_lclk, clk, open, open, sdclkl, pciclk, cgi, cgo); sdclk_pad : outpad generic map (tech => padtech, slew => 1, strength => 8) port map (sdclk, sdclkl); clk_pad : clkpad generic map (tech => padtech, level => padlevel) port map (clk_66mhz, clk_66mhzl); clk2_pad : clkpad generic map (tech => padtech, level => padlevel) port map (clk_socket, open); pci_clk_pad : clkpad generic map (tech => padtech, level => pci33) port map (pci_clk, pci_lclk); rst0 : rstgen generic map (acthigh => 1) port map (switchesl(4), clk, cgo.clklock, rstn, rstraw); flash_rst_l_pad : outpad generic map (level => padlevel, tech => padtech) port map (flash_rst_l, rstraw); ---------------------------------------------------------------------- --- AHB CONTROLLER -------------------------------------------------- ---------------------------------------------------------------------- ahb0 : ahbctrl -- AHB arbiter/multiplexer generic map (defmast => CFG_DEFMST, split => CFG_SPLIT, rrobin => CFG_RROBIN, ioaddr => CFG_AHBIO, nahbm => mahbmax, nahbs => 8, ioen => IOAEN) port map (rstn, clk, ahbmi, ahbmo, ahbsi, ahbso); ---------------------------------------------------------------------- --- LEON3 processor and DSU ----------------------------------------- ---------------------------------------------------------------------- l3 : if CFG_LEON3 = 1 generate cpu : for i in 0 to CFG_NCPU-1 generate u0 : leon3s -- LEON3 processor generic map (i, fabtech, memtech, CFG_NWIN, CFG_DSU, CFG_FPU, CFG_V8, 0, CFG_MAC, pclow, CFG_NOTAG, CFG_NWP, CFG_ICEN, CFG_IREPL, CFG_ISETS, CFG_ILINE, CFG_ISETSZ, CFG_ILOCK, CFG_DCEN, CFG_DREPL, CFG_DSETS, CFG_DLINE, CFG_DSETSZ, CFG_DLOCK, CFG_DSNOOP, CFG_ILRAMEN, CFG_ILRAMSZ, CFG_ILRAMADDR, CFG_DLRAMEN, CFG_DLRAMSZ, CFG_DLRAMADDR, CFG_MMUEN, CFG_ITLBNUM, CFG_DTLBNUM, CFG_TLB_TYPE, CFG_TLB_REP, CFG_LDDEL, disas, CFG_ITBSZ, CFG_PWD, CFG_SVT, CFG_RSTADDR, CFG_NCPU-1, 0, 0, CFG_MMU_PAGE, CFG_BP) port map (clk, rstn, ahbmi, ahbmo(i), ahbsi, ahbso, irqi(i), irqo(i), dbgi(i), dbgo(i)); dsugen : if CFG_DSU = 1 generate dsu0 : dsu3 -- LEON3 Debug Support Unit generic map (hindex => 2, haddr => 16#900#, hmask => 16#F00#, ncpu => CFG_NCPU, tbits => 30, tech => memtech, irq => 0, kbytes => CFG_ATBSZ) port map (rstn, clk, ahbmi, ahbsi, ahbso(2), dbgo, dbgi, dsui, dsuo); end generate; dsui.break <= switchesl(5); dsui.enable <= '1'; dsuact_pad : outpad generic map (tech => padtech, level => padlevel) port map (leds(1), dsuo.active); end generate; end generate; nodsu : if CFG_DSU = 0 generate ahbso(2) <= ahbs_none; dsuo.tstop <= '0'; dsuo.active <= '0'; end generate; dcomgen : if CFG_AHB_UART = 1 generate dcom0: ahbuart -- Debug UART generic map (hindex => CFG_NCPU, pindex => 7, paddr => 7) port map (rstn, clk, dui, duo, apbi, apbo(7), ahbmi, ahbmo(CFG_NCPU)); end generate; nouah : if CFG_AHB_UART = 0 generate apbo(7) <= apb_none; end generate; ahbjtaggen0 :if CFG_AHB_JTAG = 1 generate ahbjtag0 : ahbjtag generic map(tech => fabtech, hindex => CFG_NCPU+CFG_AHB_UART) port map(rstn, clk, tck, tms, tdi, tdo, ahbmi, ahbmo(CFG_NCPU+CFG_AHB_UART), open, open, open, open, open, open, open, gnd(0)); end generate; dcompads : if CFG_AHB_UART = 1 generate dsurx_pad : inpad generic map (tech => padtech, level => padlevel) port map (rx, dui.rxd); dsutx_pad : outpad generic map (tech => padtech, level => padlevel) port map (tx, duo.txd); u1i.rxd <= '1'; end generate; ---------------------------------------------------------------------- --- Memory controllers ---------------------------------------------- ---------------------------------------------------------------------- mg2 : if CFG_MCTRL_LEON2 = 1 generate -- LEON2 memory controller sr1 : entity work.mctrl_avnet generic map (hindex => 0, pindex => 0, paddr => 0, srbanks => 4, sden => CFG_MCTRL_SDEN, invclk => CFG_MCTRL_INVCLK, pageburst => CFG_MCTRL_PAGE, avnetmezz => mezz) port map (rstn, clk, memi, memo, ahbsi, ahbso(0), apbi, apbo(0), wpo, sdo); sdpads : if CFG_MCTRL_SDEN = 1 generate -- no SDRAM controller -- sdwen_pad : outpad generic map (tech => padtech) -- port map (sdwen, sdo.sdwen); sdras_pad : outpad generic map (tech => padtech) port map (rasn, sdo.rasn); sdcas_pad : outpad generic map (tech => padtech) port map (casn, sdo.casn); -- sddqm_pad : outpadv generic map (width =>4, tech => padtech) -- port map (sddqm, sdo.dqm); end generate; sdcke_pad : outpad generic map (tech => padtech) port map (sdcke, sdo.sdcke(0)); sdcsn_pad : outpad generic map (tech => padtech) port map (sdcsn, sdo.sdcsn(0)); end generate; nosd0 : if (CFG_MCTRL_SDEN = 0) generate -- no SDRAM controller sdcke_pad : outpad generic map (tech => padtech) port map (sdcke, vcc(0)); sdcsn_pad : outpad generic map (tech => padtech) port map (sdcsn, vcc(0)); end generate; memi.brdyn <= '1'; memi.bexcn <= '1'; memi.writen <= '1'; memi.wrn <= "1111"; memi.bwidth <= "10"; mg0 : if CFG_MCTRL_LEON2 = 0 generate -- None PROM/SRAM controller apbo(0) <= apb_none; ahbso(0) <= ahbs_none; rams_pad : outpadv generic map (level => padlevel, tech => padtech, width => 2) port map (sram_cs_l, vcc(1 downto 0)); end generate; mgpads : if CFG_MCTRL_LEON2 /= 0 generate -- prom/sram pads addr_pad : outpadv generic map (level => padlevel, width => 25, tech => padtech) port map (sram_a, memo.address(24 downto 0)); rams_pad : outpadv generic map (level => padlevel, tech => padtech, width => 2) port map (sram_cs_l, memo.ramsn(1 downto 0)); flash_pad : outpad generic map (level => padlevel, tech => padtech) port map (flash_cs_l, memo.romsn(0)); oen_pad : outpad generic map (level => padlevel, tech => padtech) port map (sram_oe_l, memo.oen); iosn_pad : outpad generic map (level => padlevel, tech => padtech) port map (iosn, memo.iosn); wri_pad : outpad generic map (level => padlevel, tech => padtech) port map (sram_we_l, memo.writen); bdr : for i in 0 to 3 generate data_pad : iopadv generic map (level => padlevel, tech => padtech, width => 8) port map (sram_dq(31-i8 downto 24-i8), memo.data(31-i8 downto 24-i8), memo.bdrive(i), memi.data(31-i8 downto 24-i8)); end generate; ben_pad : outpadv generic map (level => padlevel, width => 4, tech => padtech) port map (sram_ben_l, memo.mben); end generate; ---------------------------------------------------------------------- --- APB Bridge and various periherals ------------------------------- ---------------------------------------------------------------------- apb0 : apbctrl -- AHB/APB bridge generic map (hindex => 1, haddr => CFG_APBADDR) port map (rstn, clk, ahbsi, ahbso(1), apbi, apbo ); ua1 : if CFG_UART1_ENABLE /= 0 generate uart1 : apbuart -- UART 1 generic map (pindex => 1, paddr => 1, pirq => 2, console => dbguart, fifosize => CFG_UART1_FIFO) port map (rstn, clk, apbi, apbo(1), u1i, u1o); u1i.ctsn <= '0'; u1i.extclk <= '0'; end generate; noua0 : if CFG_UART1_ENABLE = 0 generate apbo(1) <= apb_none; end generate; ua1pads : if CFG_AHB_UART = 0 generate rx_pad : inpad generic map (tech => padtech, level => padlevel) port map (rx, u1i.rxd); tx_pad : outpad generic map (tech => padtech, level => padlevel) port map (tx, u1o.txd); end generate; irqctrl : if CFG_IRQ3_ENABLE /= 0 generate irqctrl0 : irqmp -- interrupt controller generic map (pindex => 2, paddr => 2, ncpu => CFG_NCPU) port map (rstn, clk, apbi, apbo(2), irqo, irqi); end generate; irq3 : if CFG_IRQ3_ENABLE = 0 generate x : for i in 0 to CFG_NCPU-1 generate irqi(i).irl <= "0000"; end generate; apbo(2) <= apb_none; end generate; gpt : if CFG_GPT_ENABLE /= 0 generate timer0 : gptimer -- timer unit generic map (pindex => 3, paddr => 3, pirq => CFG_GPT_IRQ, sepirq => CFG_GPT_SEPIRQ, sbits => CFG_GPT_SW, ntimers => CFG_GPT_NTIM, nbits => CFG_GPT_TW) port map (rstn, clk, apbi, apbo(3), gpti, open); gpti.dhalt <= dsuo.tstop; gpti.extclk <= '0'; end generate; notim : if CFG_GPT_ENABLE = 0 generate apbo(3) <= apb_none; end generate; kbd : if CFG_KBD_ENABLE /= 0 generate ps21 : apbps2 generic map(pindex => 4, paddr => 4, pirq => 4) port map(rstn, clk, apbi, apbo(4), moui, mouo); ps20 : apbps2 generic map(pindex => 5, paddr => 5, pirq => 5) port map(rstn, clk, apbi, apbo(5), kbdi, kbdo); end generate; nokbd : if CFG_KBD_ENABLE = 0 generate apbo(4) <= apb_none; mouo <= ps2o_none; apbo(5) <= apb_none; kbdo <= ps2o_none; end generate; kbdclk_pad : iopad generic map (tech => padtech) port map (kbclk,kbdo.ps2_clk_o, kbdo.ps2_clk_oe, kbdi.ps2_clk_i); kbdata_pad : iopad generic map (tech => padtech) port map (kbdata, kbdo.ps2_data_o, kbdo.ps2_data_oe, kbdi.ps2_data_i); mouclk_pad : iopad generic map (tech => padtech) port map (msclk,mouo.ps2_clk_o, mouo.ps2_clk_oe, moui.ps2_clk_i); mouata_pad : iopad generic map (tech => padtech) port map (msdata, mouo.ps2_data_o, mouo.ps2_data_oe, moui.ps2_data_i); vga : if CFG_VGA_ENABLE /= 0 generate vga0 : apbvga generic map(memtech => memtech, pindex => 6, paddr => 6) port map(rstn, clk, clk25, apbi, apbo(6), vgao); vgaclk0 : entity techmap.clkmul_virtex2 generic map (3, 8) -- 25 MHz video clock port map (rstn, clk, dac_clk, open); end generate; svga : if CFG_SVGA_ENABLE /= 0 generate svga0 : svgactrl generic map(memtech => memtech, pindex => 6, paddr => 6, hindex => CFG_NCPU+CFG_AHB_UART+CFG_AHB_JTAG, clk0 => 39722, clk1 => 0, clk2 => 0, clk3 => 0, burstlen => 5) port map(rstn, clk, clk25, apbi, apbo(6), vgao, ahbmi, ahbmo(CFG_NCPU+CFG_AHB_UART+CFG_AHB_JTAG), open); clk25 <= not dac_clk; end generate; novga : if (CFG_VGA_ENABLE = 0 and CFG_SVGA_ENABLE = 0) generate apbo(6) <= apb_none; vgao <= vgao_none; end generate; video_clk_pad : inpad generic map (tech => padtech) port map (video_clk, dac_clk); blank_pad : outpad generic map (tech => padtech) port map (blank, vgao.blank); comp_sync_pad : outpad generic map (tech => padtech) port map (comp_sync, vgao.comp_sync); vert_sync_pad : outpad generic map (tech => padtech) port map (vert_sync, vgao.vsync); horiz_sync_pad : outpad generic map (tech => padtech) port map (horiz_sync, vgao.hsync); video_out_r_pad : outpadv generic map (width => 8, tech => padtech) port map (video_out(23 downto 16), vgao.video_out_r); video_out_g_pad : outpadv generic map (width => 8, tech => padtech) port map (video_out(15 downto 8), vgao.video_out_g); video_out_b_pad : outpadv generic map (width => 8, tech => padtech) port map (video_out(7 downto 0), vgao.video_out_b); ----------------------------------------------------------------------- --- PCI ------------------------------------------------------------ ----------------------------------------------------------------------- pp : if CFG_PCI /= 0 generate pci_gr0 : if CFG_PCI = 1 generate -- simple target-only pci0 : pci_target generic map (hindex => CFG_NCPU+CFG_AHB_UART+CFG_AHB_JTAG+CFG_SVGA_ENABLE, device_id => CFG_PCIDID, vendor_id => CFG_PCIVID) port map (rstn, clk, pciclk, pcii, pcio, ahbmi, ahbmo(CFG_NCPU+CFG_AHB_UART+CFG_AHB_JTAG+CFG_SVGA_ENABLE)); end generate; pci_mtf0 : if CFG_PCI = 2 generate -- master/target with fifo pci0 : pci_mtf generic map (memtech => memtech, hmstndx => CFG_NCPU+CFG_AHB_UART+CFG_AHB_JTAG+CFG_SVGA_ENABLE, fifodepth => log2(CFG_PCIDEPTH), device_id => CFG_PCIDID, vendor_id => CFG_PCIVID, hslvndx => 4, pindex => 9, paddr => 9, haddr => 16#E00#, ioaddr => 16#400#, nsync => 2) port map (rstn, clk, pciclk, pcii, pcio, apbi, apbo(9), ahbmi, ahbmo(CFG_NCPU+CFG_AHB_UART+CFG_AHB_JTAG+CFG_SVGA_ENABLE), ahbsi, ahbso(4)); end generate; pci_mtf1 : if CFG_PCI = 3 generate -- master/target with fifo and DMA dma : pcidma generic map (memtech => memtech, dmstndx => CFG_NCPU+CFG_AHB_UART+CFG_AHB_JTAG+1+CFG_SVGA_ENABLE, dapbndx => 5, dapbaddr => 5, blength => blength, mstndx => CFG_NCPU+CFG_AHB_UART+CFG_AHB_JTAG+CFG_SVGA_ENABLE, fifodepth => log2(fifodepth), device_id => CFG_PCIDID, vendor_id => CFG_PCIVID, slvndx => 4, apbndx => 9, apbaddr => 9, haddr => 16#E00#, ioaddr => 16#800#, nsync => 1) port map (rstn, clk, pciclk, pcii, pcio, apbo(9), ahbmo(CFG_NCPU+CFG_AHB_UART+CFG_AHB_JTAG+1+CFG_SVGA_ENABLE), apbi, apbo(4), ahbmi, ahbmo(CFG_NCPU+CFG_AHB_UART+CFG_AHB_JTAG+CFG_SVGA_ENABLE), ahbsi, ahbso(4)); end generate; pci_trc0 : if CFG_PCITBUFEN /= 0 generate -- PCI trace buffer pt0 : pcitrace generic map (depth => (6 + log2(CFG_PCITBUF/256)), memtech => memtech, pindex => 8, paddr => 16#100#, pmask => 16#f00#) port map ( rstn, clk, pciclk, pcii, apbi, apbo(8)); end generate; end generate; pcipads0 : pcipads generic map (padtech => padtech, noreset => 1, host => 0)-- PCI pads port map ( pci_rst, pci_gnt, pci_idsel, pci_lock, pci_ad, pci_cbe, pci_frame, pci_irdy, pci_trdy, pci_devsel, pci_stop, pci_perr, pci_par, pci_req, pci_serr, pci_host, pci_66, pcii, pcio ); ----------------------------------------------------------------------- --- ETHERNET --------------------------------------------------------- ----------------------------------------------------------------------- eth0 : if CFG_GRETH = 1 generate -- Gaisler ethernet MAC e1 : greth generic map(hindex => CFG_NCPU+CFG_AHB_UART+CFG_PCI+CFG_AHB_JTAG+CFG_SVGA_ENABLE, pindex => 11, paddr => 11, pirq => 12, memtech => memtech, mdcscaler => CPU_FREQ/1000, enable_mdio => 1, fifosize => CFG_ETH_FIFO, nsync => 1, edcl => CFG_DSU_ETH, edclbufsz => CFG_ETH_BUF, macaddrh => CFG_ETH_ENM, macaddrl => CFG_ETH_ENL, ipaddrh => CFG_ETH_IPM, ipaddrl => CFG_ETH_IPL) port map( rst => rstn, clk => clk, ahbmi => ahbmi, ahbmo => ahbmo(CFG_NCPU+CFG_AHB_UART+CFG_PCI+CFG_AHB_JTAG+CFG_SVGA_ENABLE), apbi => apbi, apbo => apbo(11), ethi => ethi, etho => etho); end generate; ethpads : if (CFG_GRETH = 0) generate -- no eth etho <= eth_out_none; end generate; emdio_pad : iopad generic map (tech => padtech, level => padlevel) port map (phy_mdio, etho.mdio_o, etho.mdio_oe, ethi.mdio_i); etxc_pad : clkpad generic map (tech => padtech, level => padlevel, arch => 1) port map (phy_txck, ethi.tx_clk); erxc_pad : clkpad generic map (tech => padtech, level => padlevel, arch => 1) port map (phy_rxck, ethi.rx_clk); erxd_pad : inpadv generic map (tech => padtech, level => padlevel, width => 4) port map (phy_rxd, ethi.rxd(3 downto 0)); erxdv_pad : inpad generic map (tech => padtech, level => padlevel) port map (phy_rxdv, ethi.rx_dv); erxer_pad : inpad generic map (tech => padtech, level => padlevel) port map (phy_rxer, ethi.rx_er); erxco_pad : inpad generic map (tech => padtech, level => padlevel) port map (phy_col, ethi.rx_col); erxcr_pad : inpad generic map (tech => padtech, level => padlevel) port map (phy_crs, ethi.rx_crs); etxd_pad : outpadv generic map (tech => padtech, level => padlevel, width => 4) port map (phy_txd, etho.txd(3 downto 0)); etxen_pad : outpad generic map (tech => padtech, level => padlevel) port map ( phy_txen, etho.tx_en); etxer_pad : outpad generic map (tech => padtech, level => padlevel) port map (phy_txer, etho.tx_er); emdc_pad : outpad generic map (tech => padtech, level => padlevel) port map (phy_mdc, etho.mdc); phy_reset_pad : iodpad generic map (tech => padtech, level => padlevel) port map (phy_reset_l, rstn, pci_rst); can0 : if CFG_CAN = 1 generate can0 : can_oc generic map (slvndx => 6, ioaddr => CFG_CANIO, iomask => 16#FF0#, irq => CFG_CANIRQ, memtech => memtech) port map (rstn, clk, ahbsi, ahbso(6), can_lrx, can_ltx ); can_tx_pad : outpad generic map (tech => padtech) port map (can_txd, can_ltx); can_rx_pad : inpad generic map (tech => padtech) port map (can_rxd, can_lrx); end generate; ncan : if CFG_CAN = 0 generate ahbso(6) <= ahbs_none; end generate; ----------------------------------------------------------------------- --- AHB RAM ---------------------------------------------------------- ----------------------------------------------------------------------- ocram : if CFG_AHBRAMEN = 1 generate ahbram0 : ahbram generic map (hindex => 7, haddr => CFG_AHBRADDR, tech => CFG_MEMTECH, kbytes => CFG_AHBRSZ, pipe => CFG_AHBRPIPE) port map (rstn, clk, ahbsi, ahbso(7)); end generate; nram : if CFG_AHBRAMEN = 0 generate ahbso(7) <= ahbs_none; end generate; ----------------------------------------------------------------------- --- Misc ---------------------------------------------------------- ----------------------------------------------------------------------- errorn <= not dbgo(0).error; led0_pad : outpad generic map (level => padlevel, tech => padtech) port map (leds(0), errorn); led2_7_pad : outpadv generic map (level => padlevel, width => 6, tech => padtech) port map (leds(7 downto 2), gnd(5 downto 0)); disp_seg1_pad : outpadv generic map (level => padlevel, width => 8, tech => padtech) port map (disp_seg1, gnd(7 downto 0)); disp_seg2_pad : outpadv generic map (level => padlevel, width => 8, tech => padtech) port map (disp_seg2, gnd(7 downto 0)); switche_pad : inpadv generic map (tech => padtech, level => padlevel, width => 6) port map (switches, switchesl); ----------------------------------------------------------------------- --- Drive unused bus elements --------------------------------------- ----------------------------------------------------------------------- nam1 : for i in (CFG_NCPU+CFG_AHB_UART+CFG_PCI+ CFG_AHB_JTAG+CFG_GRETH+CFG_SVGA_ENABLE) to NAHBMST-1 generate ahbmo(i) <= ahbm_none; end generate; nam2 : if CFG_PCI > 1 generate ahbmo(CFG_NCPU+CFG_AHB_UART+CFG_PCI+CFG_AHB_JTAG-1+CFG_SVGA_ENABLE) <= ahbm_none; end generate; nap0 : for i in 12 to NAPBSLV-1 generate apbo(i) <= apb_none; end generate; -- nah0 : for i in 8 to NAHBSLV-1 generate ahbso(i) <= ahbs_none; end generate; ----------------------------------------------------------------------- --- Boot message ---------------------------------------------------- ----------------------------------------------------------------------- -- pragma translate_off x : report_design generic map ( msg1 => "LEON3 Avnet Spartan3-1500 Demonstration design", fabtech => tech_table(fabtech), memtech => tech_table(memtech), mdel => 1 ); -- pragma translate_on end;	gpl-2.0	ae2f0752b35c0665c97991a184f71a9f	0.582017	3.421334	false	false	false	false
marco-c/leon-nexys2	grlib-gpl-1.3.4-b4140/designs/leon3-terasic-de2-115/leon3mp.vhd	1	26,071	----------------------------------------------------------------------------- -- LEON3 Demonstration design -- Copyright (C) 2004 Jiri Gaisler, Gaisler Research ------------------------------------------------------------------------------ -- This file is a part of the GRLIB VHDL IP LIBRARY -- Copyright (C) 2003 - 2008, Gaisler Research -- Copyright (C) 2008 - 2013, Aeroflex Gaisler -- -- This program is free software; you can redistribute it and/or modify -- it under the terms of the GNU General Public License as published by -- the Free Software Foundation; either version 2 of the License, or -- (at your option) any later version. -- -- This program is distributed in the hope that it will be useful, -- but WITHOUT ANY WARRANTY; without even the implied warranty of -- MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the -- GNU General Public License for more details. -- -- You should have received a copy of the GNU General Public License -- along with this program; if not, write to the Free Software -- Foundation, Inc., 59 Temple Place, Suite 330, Boston, MA 02111-1307 USA ------------------------------------------------------------------------------ library ieee; use ieee.std_logic_1164.all; library grlib, techmap; use grlib.amba.all; use grlib.stdlib.all; use techmap.gencomp.all; library gaisler; use gaisler.memctrl.all; use gaisler.leon3.all; use gaisler.uart.all; use gaisler.misc.all; use gaisler.spi.all; use gaisler.can.all; use gaisler.net.all; use gaisler.jtag.all; -- pragma translate_off use gaisler.sim.all; -- pragma translate_on library esa; use esa.memoryctrl.all; use work.config.all; entity leon3mp is generic ( fabtech : integer := CFG_FABTECH; memtech : integer := CFG_MEMTECH; padtech : integer := CFG_PADTECH; clktech : integer := CFG_CLKTECH; disas : integer := CFG_DISAS; -- Enable disassembly to console dbguart : integer := CFG_DUART; -- Print UART on console pclow : integer := CFG_PCLOW ); port ( resetn : in std_logic; clock_50 : in std_logic; sma_clkout : out std_ulogic; errorn : out std_logic; fl_addr : out std_logic_vector(22 downto 0); fl_dq : inout std_logic_vector(7 downto 0); dram_addr : out std_logic_vector(12 downto 0); dram_ba : out std_logic_vector(1 downto 0); dram_dq : inout std_logic_vector(31 downto 0); dram_clk : out std_logic; dram_cke : out std_logic; dram_cs_n : out std_logic; dram_we_n : out std_logic; -- sdram write enable dram_ras_n : out std_logic; -- sdram ras dram_cas_n : out std_logic; -- sdram cas dram_dqm : out std_logic_vector (3 downto 0); -- sdram dqm uart_txd : out std_logic; -- DSU tx data uart_rxd : in std_logic; -- DSU rx data dsubre : in std_logic; dsuact : out std_logic; fl_oe_n : out std_logic; fl_we_n : out std_logic; fl_rst_n : out std_logic; fl_wp_n : out std_logic; fl_ce_n : out std_logic; -- gpio : inout std_logic_vector(CFG_GRGPIO_WIDTH-1 downto 0); -- I/O port gpio : inout std_logic_vector(35 downto 0); -- I/O port enet0_mdio : inout std_logic; -- ethernet PHY interface enet0_gtx_clk : in std_logic; enet0_rx_clk : in std_logic; enet0_tx_clk : in std_logic; enet0_rx_data: in std_logic_vector(3 downto 0); enet0_rx_dv : in std_logic; enet0_rx_er : in std_logic; enet0_rx_col : in std_logic; enet0_rx_crs : in std_logic; enet0_int_n : in std_logic; enet0_rst_n : out std_logic; enet0_tx_data: out std_logic_vector(3 downto 0); enet0_tx_en : out std_logic; enet0_tx_er : out std_logic; enet0_mdc : out std_logic; can_txd : out std_logic_vector(0 to CFG_CAN_NUM-1); can_rxd : in std_logic_vector(0 to CFG_CAN_NUM-1); can_stb : out std_logic_vector(0 to CFG_CAN_NUM-1); sw : in std_logic_vector(0 to 2) := "000" ); end; architecture rtl of leon3mp is constant blength : integer := 12; constant fifodepth : integer := 8; signal vcc, gnd : std_logic_vector(4 downto 0); signal memi : memory_in_type; signal memo : memory_out_type; signal wpo : wprot_out_type; signal sdi : sdctrl_in_type; signal sdo : sdram_out_type; signal apbi : apb_slv_in_type; signal apbo : apb_slv_out_vector := (others => apb_none); signal ahbsi : ahb_slv_in_type; signal ahbso : ahb_slv_out_vector := (others => ahbs_none); signal ahbmi : ahb_mst_in_type; signal ahbmo : ahb_mst_out_vector := (others => ahbm_none); signal clkm, rstn, rstraw, pciclk, sdclkl : std_logic; signal cgi, cgi2 : clkgen_in_type; signal cgo, cgo2 : clkgen_out_type; signal u1i, u2i, dui : uart_in_type; signal u1o, u2o, duo : uart_out_type; signal irqi : irq_in_vector(0 to CFG_NCPU-1); signal irqo : irq_out_vector(0 to CFG_NCPU-1); signal dbgi : l3_debug_in_vector(0 to CFG_NCPU-1); signal dbgo : l3_debug_out_vector(0 to CFG_NCPU-1); signal dsui : dsu_in_type; signal dsuo : dsu_out_type; signal spii, spislvi : spi_in_type; signal spio, spislvo : spi_out_type; signal slvsel : std_logic_vector(CFG_SPICTRL_SLVS-1 downto 0); signal stati : ahbstat_in_type; signal ethi, ethi1, ethi2 : eth_in_type; signal etho, etho1, etho2 : eth_out_type; signal ethclk, egtx_clk_fb : std_logic; signal egtx_clk, legtx_clk, l2egtx_clk : std_logic; signal gpti : gptimer_in_type; signal gpto : gptimer_out_type; signal gpioi : gpio_in_type; signal gpioo : gpio_out_type; signal clklock, elock : std_ulogic; signal can_lrx, can_ltx : std_logic_vector(0 to 7); signal dsubren : std_logic; signal pci_arb_req_n, pci_arb_gnt_n : std_logic_vector(0 to 3); signal tck, tms, tdi, tdo : std_logic; signal fpi : grfpu_in_vector_type; signal fpo : grfpu_out_vector_type; constant BOARD_FREQ : integer := 50000; -- Board frequency in KHz constant CPU_FREQ : integer := BOARD_FREQ * CFG_CLKMUL / CFG_CLKDIV; -- cpu frequency in KHz constant IOAEN : integer := CFG_CAN; constant CFG_SDEN : integer := CFG_MCTRL_SDEN; constant CFG_INVCLK : integer := CFG_MCTRL_INVCLK; constant OEPOL : integer := padoen_polarity(padtech); attribute syn_keep : boolean; attribute syn_preserve : boolean; attribute keep : boolean; begin ---------------------------------------------------------------------- --- Reset and Clock generation ------------------------------------- ---------------------------------------------------------------------- vcc <= (others => '1'); gnd <= (others => '0'); cgi.pllctrl <= "00"; cgi.pllrst <= rstraw; clkgen0 : clkgen -- clock generator using toplevel generic 'freq' generic map (tech => CFG_CLKTECH, clk_mul => CFG_CLKMUL, clk_div => CFG_CLKDIV, sdramen => CFG_MCTRL_SDEN, noclkfb => CFG_CLK_NOFB, freq => BOARD_FREQ, clk2xen => 1) port map (clkin => clock_50, pciclkin => gnd(0), clk => clkm, clkn => open, clk2x => sma_clkout, sdclk => sdclkl, pciclk => open, cgi => cgi, cgo => cgo); sdclk_pad : outpad generic map (tech => padtech, slew => 1) port map (dram_clk, sdclkl); rst0 : rstgen -- reset generator port map (resetn, clkm, clklock, rstn, rstraw); clklock <= cgo.clklock and elock; ---------------------------------------------------------------------- --- AHB CONTROLLER -------------------------------------------------- ---------------------------------------------------------------------- ahb0 : ahbctrl -- AHB arbiter/multiplexer generic map (defmast => CFG_DEFMST, split => CFG_SPLIT, rrobin => CFG_RROBIN, ioaddr => CFG_AHBIO, ioen => IOAEN, nahbm => CFG_NCPU+CFG_AHB_UART+CFG_AHB_JTAG+CFG_SPI2AHB+CFG_GRETH, nahbs => 8) port map (rstn, clkm, ahbmi, ahbmo, ahbsi, ahbso); ---------------------------------------------------------------------- --- LEON3 processor and DSU ----------------------------------------- ---------------------------------------------------------------------- cpu : for i in 0 to CFG_NCPU-1 generate nosh : if CFG_GRFPUSH = 0 generate u0 : leon3s -- LEON3 processor generic map (i, fabtech, memtech, CFG_NWIN, CFG_DSU, CFG_FPU(1-CFG_GRFPUSH), CFG_V8, 0, CFG_MAC, pclow, CFG_NOTAG, CFG_NWP, CFG_ICEN, CFG_IREPL, CFG_ISETS, CFG_ILINE, CFG_ISETSZ, CFG_ILOCK, CFG_DCEN, CFG_DREPL, CFG_DSETS, CFG_DLINE, CFG_DSETSZ, CFG_DLOCK, CFG_DSNOOP, CFG_ILRAMEN, CFG_ILRAMSZ, CFG_ILRAMADDR, CFG_DLRAMEN, CFG_DLRAMSZ, CFG_DLRAMADDR, CFG_MMUEN, CFG_ITLBNUM, CFG_DTLBNUM, CFG_TLB_TYPE, CFG_TLB_REP, CFG_LDDEL, disas, CFG_ITBSZ, CFG_PWD, CFG_SVT, CFG_RSTADDR, CFG_NCPU-1, 0, 0, CFG_MMU_PAGE) port map (clkm, rstn, ahbmi, ahbmo(i), ahbsi, ahbso, irqi(i), irqo(i), dbgi(i), dbgo(i)); end generate; end generate; sh : if CFG_GRFPUSH = 1 generate cpu : for i in 0 to CFG_NCPU-1 generate u0 : leon3sh -- LEON3 processor generic map (i, fabtech, memtech, CFG_NWIN, CFG_DSU, CFG_FPU, CFG_V8, 0, CFG_MAC, pclow, CFG_NOTAG, CFG_NWP, CFG_ICEN, CFG_IREPL, CFG_ISETS, CFG_ILINE, CFG_ISETSZ, CFG_ILOCK, CFG_DCEN, CFG_DREPL, CFG_DSETS, CFG_DLINE, CFG_DSETSZ, CFG_DLOCK, CFG_DSNOOP, CFG_ILRAMEN, CFG_ILRAMSZ, CFG_ILRAMADDR, CFG_DLRAMEN, CFG_DLRAMSZ, CFG_DLRAMADDR, CFG_MMUEN, CFG_ITLBNUM, CFG_DTLBNUM, CFG_TLB_TYPE, CFG_TLB_REP, CFG_LDDEL, disas, CFG_ITBSZ, CFG_PWD, CFG_SVT, CFG_RSTADDR, CFG_NCPU-1, 0, 0, CFG_MMU_PAGE) port map (clkm, rstn, ahbmi, ahbmo(i), ahbsi, ahbso, irqi(i), irqo(i), dbgi(i), dbgo(i), fpi(i), fpo(i)); end generate; grfpush0 : grfpushwx generic map ((CFG_FPU-1), CFG_NCPU, fabtech) port map (clkm, rstn, fpi, fpo); end generate; errorn_pad : odpad generic map (tech => padtech) port map (errorn, dbgo(0).error); dsugen : if CFG_DSU = 1 generate dsu0 : dsu3 -- LEON3 Debug Support Unit generic map (hindex => 2, haddr => 16#900#, hmask => 16#F00#, ncpu => CFG_NCPU, tbits => 30, tech => memtech, irq => 0, kbytes => CFG_ATBSZ) port map (rstn, clkm, ahbmi, ahbsi, ahbso(2), dbgo, dbgi, dsui, dsuo); dsui.enable <= '1'; dsubre_pad : inpad generic map (tech => padtech) port map (dsubre, dsubren); dsui.break <= not dsubren; dsuact_pad : outpad generic map (tech => padtech) port map (dsuact, dsuo.active); end generate; nodsu : if CFG_DSU = 0 generate ahbso(2) <= ahbs_none; dsuo.tstop <= '0'; dsuo.active <= '0'; end generate; dcomgen : if CFG_AHB_UART = 1 generate dcom0: ahbuart -- Debug UART generic map (hindex => CFG_NCPU, pindex => 7, paddr => 7) port map (rstn, clkm, dui, duo, apbi, apbo(7), ahbmi, ahbmo(CFG_NCPU)); -- dsurx_pad : inpad generic map (tech => padtech) port map (dsurx, dui.rxd); dui.rxd <= uart_rxd when sw(0) = '0' else '1'; -- dsutx_pad : outpad generic map (tech => padtech) port map (dsutx, duo.txd); end generate; -- nouah : if CFG_AHB_UART = 0 generate apbo(7) <= apb_none; end generate; ahbjtaggen0 :if CFG_AHB_JTAG = 1 generate ahbjtag0 : ahbjtag generic map(tech => fabtech, hindex => CFG_NCPU+CFG_AHB_UART) port map(rstn, clkm, tck, tms, tdi, tdo, ahbmi, ahbmo(CFG_NCPU+CFG_AHB_UART), open, open, open, open, open, open, open, gnd(0)); end generate; ---------------------------------------------------------------------- --- Memory controllers ---------------------------------------------- ---------------------------------------------------------------------- memi.edac <= '0'; memi.bwidth <= "00"; mctrl0 : if CFG_MCTRL_LEON2 = 1 generate -- LEON2 memory controller sr1 : mctrl generic map (hindex => 0, pindex => 0, paddr => 0, srbanks => 4, sden => CFG_MCTRL_SDEN, ram8 => CFG_MCTRL_RAM8BIT, ram16 => CFG_MCTRL_RAM16BIT, invclk => CFG_MCTRL_INVCLK, sepbus => CFG_MCTRL_SEPBUS, oepol => OEPOL, iomask => 0, sdbits => 32 + 32CFG_MCTRL_SD64, pageburst => CFG_MCTRL_PAGE) port map (rstn, clkm, memi, memo, ahbsi, ahbso(0), apbi, apbo(0), wpo, sdo); addr_pad : outpadv generic map (width => 23, tech => padtech) port map (fl_addr, memo.address(22 downto 0)); roms_pad : outpad generic map (tech => padtech) port map (fl_ce_n, memo.romsn(0)); oen_pad : outpad generic map (tech => padtech) port map (fl_oe_n, memo.oen); wri_pad : outpad generic map (tech => padtech) port map (fl_we_n, memo.writen); fl_rst_pad : outpad generic map (tech => padtech) port map (fl_rst_n, rstn); fl_wp_pad : outpad generic map (tech => padtech) port map (fl_wp_n, vcc(0)); data_pad : iopadvv generic map (tech => padtech, width => 8, oepol => OEPOL) port map (fl_dq, memo.data(31 downto 24), memo.vbdrive(31 downto 24), memi.data(31 downto 24)); memi.brdyn <= '1'; memi.bexcn <= '1'; memi.writen <= '1'; memi.wrn <= "1111"; sdpads : if CFG_MCTRL_SDEN = 1 generate -- SDRAM controller sd2 : if CFG_MCTRL_SEPBUS = 1 generate sa_pad : outpadv generic map (width => 13) port map (dram_addr, memo.sa(12 downto 0)); ba_pad : outpadv generic map (width => 2) port map (dram_ba, memo.sa(14 downto 13)); sd_pad : iopadvv generic map (tech => padtech, width => 32, oepol => OEPOL) port map (dram_dq(31 downto 0), memo.sddata(31 downto 0), memo.svbdrive(31 downto 0), memi.sd(31 downto 0)); end generate; sdwen_pad : outpad generic map (tech => padtech) port map (dram_we_n, sdo.sdwen); sdras_pad : outpad generic map (tech => padtech) port map (dram_ras_n, sdo.rasn); sdcas_pad : outpad generic map (tech => padtech) port map (dram_cas_n, sdo.casn); sddqm_pad : outpadv generic map (width => 4, tech => padtech) port map (dram_dqm, sdo.dqm(3 downto 0)); sdcke_pad : outpad generic map (tech => padtech) port map (dram_cke, sdo.sdcke(0)); sdcsn_pad : outpad generic map (tech => padtech) port map (dram_cs_n, sdo.sdcsn(0)); end generate; end generate; nosd0 : if (CFG_SDEN = 0) generate -- no SDRAM controller sdcke_pad : outpad generic map (tech => padtech) port map (dram_cke, vcc(0)); sdcsn_pad : outpad generic map (tech => padtech) port map (dram_cs_n, vcc(0)); end generate; mg0 : if CFG_MCTRL_LEON2 = 0 generate -- No PROM/SRAM controller apbo(0) <= apb_none; ahbso(0) <= ahbs_none; roms_pad : outpad generic map (tech => padtech) port map (fl_ce_n, vcc(0)); end generate; ---------------------------------------------------------------------- --- APB Bridge and various periherals ------------------------------- ---------------------------------------------------------------------- apb0 : apbctrl -- AHB/APB bridge generic map (hindex => 1, haddr => CFG_APBADDR) port map (rstn, clkm, ahbsi, ahbso(1), apbi, apbo ); ua1 : if CFG_UART1_ENABLE /= 0 generate uart1 : apbuart -- UART 1 generic map (pindex => 1, paddr => 1, pirq => 2, console => dbguart, fifosize => CFG_UART1_FIFO) port map (rstn, clkm, apbi, apbo(1), u1i, u1o); u1i.rxd <= '1' when sw(0) = '0' else uart_rxd; u1i.ctsn <= '0'; u1i.extclk <= '0'; end generate; uart_txd <= u1o.txd when sw(0) = '1' else duo.txd; noua0 : if CFG_UART1_ENABLE = 0 generate apbo(1) <= apb_none; end generate; irqctrl : if CFG_IRQ3_ENABLE /= 0 generate irqctrl0 : irqmp -- interrupt controller generic map (pindex => 2, paddr => 2, ncpu => CFG_NCPU) port map (rstn, clkm, apbi, apbo(2), irqo, irqi); end generate; irq3 : if CFG_IRQ3_ENABLE = 0 generate x : for i in 0 to CFG_NCPU-1 generate irqi(i).irl <= "0000"; end generate; -- apbo(2) <= apb_none; end generate; gpt : if CFG_GPT_ENABLE /= 0 generate timer0 : gptimer -- timer unit generic map (pindex => 3, paddr => 3, pirq => CFG_GPT_IRQ, sepirq => CFG_GPT_SEPIRQ, sbits => CFG_GPT_SW, ntimers => CFG_GPT_NTIM, nbits => CFG_GPT_TW) port map (rstn, clkm, apbi, apbo(3), gpti, open); gpti.dhalt <= dsuo.tstop; gpti.extclk <= '0'; end generate; -- notim : if CFG_GPT_ENABLE = 0 generate apbo(3) <= apb_none; end generate; gpio0 : if CFG_GRGPIO_ENABLE /= 0 generate -- GR GPIO unit grgpio0: grgpio generic map( pindex => 9, paddr => 9, imask => CFG_GRGPIO_IMASK, nbits => CFG_GRGPIO_WIDTH) port map( rstn, clkm, apbi, apbo(9), gpioi, gpioo); pio_pads : for i in 0 to CFG_GRGPIO_WIDTH-1 generate pio_pad : iopad generic map (tech => padtech) port map (gpio(i), gpioo.dout(i), gpioo.oen(i), gpioi.din(i)); end generate; end generate; spic: if CFG_SPICTRL_ENABLE = 1 generate -- SPI controller spi1 : spictrl generic map (pindex => 10, paddr => 10, pmask => 16#fff#, pirq => 10, fdepth => CFG_SPICTRL_FIFO, slvselen => CFG_SPICTRL_SLVREG, slvselsz => CFG_SPICTRL_SLVS, odmode => 0, netlist => 0, syncram => CFG_SPICTRL_SYNCRAM, ft => CFG_SPICTRL_FT) port map (rstn, clkm, apbi, apbo(10), spii, spio, slvsel); spii.spisel <= '1'; -- Master only miso_pad : iopad generic map (tech => padtech) port map (gpio(35), spio.miso, spio.misooen, spii.miso); mosi_pad : iopad generic map (tech => padtech) port map (gpio(34), spio.mosi, spio.mosioen, spii.mosi); sck_pad : iopad generic map (tech => padtech) port map (gpio(33), spio.sck, spio.sckoen, spii.sck); slvsel_pad : iopad generic map (tech => padtech) port map (gpio(32), slvsel(0), gnd(0), open); end generate spic; spibridge : if CFG_SPI2AHB /= 0 generate -- SPI to AHB bridge withapb : if CFG_SPI2AHB_APB /= 0 generate spi2ahb0 : spi2ahb_apb generic map(hindex => CFG_NCPU+CFG_AHB_UART+CFG_AHB_JTAG, ahbaddrh => CFG_SPI2AHB_ADDRH, ahbaddrl => CFG_SPI2AHB_ADDRL, ahbmaskh => CFG_SPI2AHB_MASKH, ahbmaskl => CFG_SPI2AHB_MASKL, resen => CFG_SPI2AHB_RESEN, pindex => 11, paddr => 11, pmask => 16#fff#, pirq => 11, filter => CFG_SPI2AHB_FILTER, cpol => CFG_SPI2AHB_CPOL, cpha => CFG_SPI2AHB_CPHA) port map (rstn, clkm, ahbmi, ahbmo(CFG_NCPU+CFG_AHB_UART+CFG_AHB_JTAG), apbi, apbo(11), spislvi, spislvo); end generate; woapb : if CFG_SPI2AHB_APB = 0 generate spi2ahb0 : spi2ahb generic map(hindex => CFG_NCPU+CFG_AHB_UART+CFG_AHB_JTAG, ahbaddrh => CFG_SPI2AHB_ADDRH, ahbaddrl => CFG_SPI2AHB_ADDRL, ahbmaskh => CFG_SPI2AHB_MASKH, ahbmaskl => CFG_SPI2AHB_MASKL, filter => CFG_SPI2AHB_FILTER, cpol => CFG_SPI2AHB_CPOL, cpha => CFG_SPI2AHB_CPHA) port map (rstn, clkm, ahbmi, ahbmo(CFG_NCPU+CFG_AHB_UART+CFG_AHB_JTAG), spislvi, spislvo); end generate; spislv_miso_pad : iopad generic map (tech => padtech) port map (gpio(31), spislvo.miso, spislvo.misooen, spislvi.miso); spislvl_mosi_pad : iopad generic map (tech => padtech) port map (gpio(30), spislvo.mosi, spislvo.mosioen, spislvi.mosi); spislv_sck_pad : iopad generic map (tech => padtech) port map (gpio(29), spislvo.sck, spislvo.sckoen, spislvi.sck); spislv_slvsel_pad : iopad generic map (tech => padtech) port map (gpio(28), gnd(0), vcc(0), spislvi.spisel); end generate; nospibridge : if CFG_SPI2AHB = 0 or CFG_SPI2AHB_APB = 0 generate apbo(11) <= apb_none; end generate; ahbs : if CFG_AHBSTAT = 1 generate -- AHB status register stati.cerror(0) <= memo.ce; ahbstat0 : ahbstat generic map (pindex => 15, paddr => 15, pirq => 1, nftslv => CFG_AHBSTATN) port map (rstn, clkm, ahbmi, ahbsi, stati, apbi, apbo(15)); end generate; nop2 : if CFG_AHBSTAT = 0 generate apbo(15) <= apb_none; end generate; ----------------------------------------------------------------------- --- ETHERNET --------------------------------------------------------- ----------------------------------------------------------------------- eth1 : if CFG_GRETH = 1 generate -- Gaisler ethernet MAC e1 : grethm generic map( hindex => CFG_NCPU+CFG_AHB_UART+CFG_AHB_JTAG+CFG_SPI2AHB, pindex => 14, paddr => 14, pirq => 12, memtech => memtech, mdcscaler => CPU_FREQ/1000, enable_mdio => 1, fifosize => CFG_ETH_FIFO, nsync => 1, edcl => CFG_DSU_ETH, edclbufsz => CFG_ETH_BUF, macaddrh => CFG_ETH_ENM, macaddrl => CFG_ETH_ENL, phyrstadr => 16, ipaddrh => CFG_ETH_IPM, ipaddrl => CFG_ETH_IPL, giga => CFG_GRETH1G, enable_mdint => 1) port map( rst => rstn, clk => clkm, ahbmi => ahbmi, ahbmo => ahbmo(CFG_NCPU+CFG_AHB_UART+CFG_AHB_JTAG+CFG_SPI2AHB), apbi => apbi, apbo => apbo(14), ethi => ethi, etho => etho); greth1g: if CFG_GRETH1G = 1 generate eth_macclk_pad : clkpad generic map (tech => padtech, arch => 3, hf => 1) port map (enet0_gtx_clk, egtx_clk, cgo.clklock, elock); end generate greth1g; emdio_pad : iopad generic map (tech => padtech) port map (enet0_mdio, etho.mdio_o, etho.mdio_oe, ethi.mdio_i); etxc_pad : clkpad generic map (tech => padtech, arch => 2) port map (enet0_tx_clk, ethi.tx_clk); erxc_pad : clkpad generic map (tech => padtech, arch => 2) port map (enet0_rx_clk, ethi.rx_clk); erxd_pad : inpadv generic map (tech => padtech, width => 4) port map (enet0_rx_data, ethi.rxd(3 downto 0)); erxdv_pad : inpad generic map (tech => padtech) port map (enet0_rx_dv, ethi.rx_dv); erxer_pad : inpad generic map (tech => padtech) port map (enet0_rx_er, ethi.rx_er); erxco_pad : inpad generic map (tech => padtech) port map (enet0_rx_col, ethi.rx_col); erxcr_pad : inpad generic map (tech => padtech) port map (enet0_rx_crs, ethi.rx_crs); emdintn_pad : inpad generic map (tech => padtech) port map (enet0_int_n, ethi.mdint); etxd_pad : outpadv generic map (tech => padtech, width => 4) port map (enet0_tx_data, etho.txd(3 downto 0)); etxen_pad : outpad generic map (tech => padtech) port map (enet0_tx_en, etho.tx_en); etxer_pad : outpad generic map (tech => padtech) port map (enet0_tx_er, etho.tx_er); emdc_pad : outpad generic map (tech => padtech) port map (enet0_mdc, etho.mdc); eth0_rst_pad : odpad generic map (tech => padtech) port map (enet0_rst_n, rstn); -- emdis_pad : outpad generic map (tech => padtech) -- port map (emddis, vcc(0)); -- eepwrdwn_pad : outpad generic map (tech => padtech) -- port map (epwrdwn, gnd(0)); -- esleep_pad : outpad generic map (tech => padtech) -- port map (esleep, gnd(0)); -- epause_pad : outpad generic map (tech => padtech) -- port map (epause, gnd(0)); -- ereset_pad : outpad generic map (tech => padtech) -- port map (ereset, gnd(0)); ethi.gtx_clk <= egtx_clk; end generate; noeth: if CFG_GRETH = 0 or CFG_GRETH1G = 0 generate elock <= '1'; end generate noeth; ----------------------------------------------------------------------- --- CAN -------------------------------------------------------------- ----------------------------------------------------------------------- can0 : if CFG_CAN = 1 generate can0 : can_mc generic map (slvndx => 6, ioaddr => CFG_CANIO, iomask => 16#FF0#, irq => CFG_CANIRQ, memtech => memtech, ncores => CFG_CAN_NUM, sepirq => CFG_CANSEPIRQ) port map (rstn, clkm, ahbsi, ahbso(6), can_lrx, can_ltx ); can_pads : for i in 0 to CFG_CAN_NUM-1 generate can_tx_pad : outpad generic map (tech => padtech) port map (can_txd(i), can_ltx(i)); can_rx_pad : inpad generic map (tech => padtech) port map (can_rxd(i), can_lrx(i)); end generate; end generate; -- can_stb <= '0'; -- no standby ncan : if CFG_CAN = 0 generate ahbso(6) <= ahbs_none; end generate; ----------------------------------------------------------------------- --- AHB RAM ---------------------------------------------------------- ----------------------------------------------------------------------- -- ocram : if CFG_AHBRAMEN = 1 generate -- ahbram0 : ftahbram generic map (hindex => 7, haddr => CFG_AHBRADDR, -- tech => CFG_MEMTECH, kbytes => CFG_AHBRSZ, pindex => 6, -- paddr => 6, edacen => CFG_AHBRAEDAC, autoscrub => CFG_AHBRASCRU, -- errcnten => CFG_AHBRAECNT, cntbits => CFG_AHBRAEBIT) -- port map ( rstn, clkm, ahbsi, ahbso(7), apbi, apbo(6), open); -- end generate; -- -- nram : if CFG_AHBRAMEN = 0 generate ahbso(7) <= ahbs_none; end generate; ----------------------------------------------------------------------- --- Drive unused bus elements --------------------------------------- ----------------------------------------------------------------------- -- nam1 : for i in (CFG_NCPU+CFG_AHB_UART+log2x(CFG_PCI)+CFG_AHB_JTAG) to NAHBMST-1 generate -- ahbmo(i) <= ahbm_none; -- end generate; -- nam2 : if CFG_PCI > 1 generate -- ahbmo(CFG_NCPU+CFG_AHB_UART+CFG_AHB_JTAG+log2x(CFG_PCI)-1) <= ahbm_none; -- end generate; -- nap0 : for i in 11 to NAPBSLV-1 generate apbo(i) <= apb_none; end generate; -- apbo(6) <= apb_none; ----------------------------------------------------------------------- --- Test report module ---------------------------------------------- ----------------------------------------------------------------------- -- pragma translate_off test0 : ahbrep generic map (hindex => 7, haddr => 16#200#) port map (rstn, clkm, ahbsi, ahbso(7)); -- pragma translate_on ----------------------------------------------------------------------- --- Boot message ---------------------------------------------------- ----------------------------------------------------------------------- -- pragma translate_off x : report_design generic map ( msg1 => "LEON3 TerAsic DE2_115 Demonstration design", fabtech => tech_table(fabtech), memtech => tech_table(memtech), mdel => 1 ); -- pragma translate_on end;	gpl-2.0	e81010a8f1a28a3cd8e3a6a467d9191a	0.56933	3.459528	false	false	false	false
marco-c/leon-nexys2	grlib-gpl-1.3.4-b4140/designs/leon3-gr-xc3s-1500/testbench.vhd	1	16,236	----------------------------------------------------------------------------- -- LEON3 Demonstration design test bench -- Copyright (C) 2004 Jiri Gaisler, Gaisler Research ------------------------------------------------------------------------------ -- This file is a part of the GRLIB VHDL IP LIBRARY -- Copyright (C) 2003 - 2008, Gaisler Research -- Copyright (C) 2008 - 2013, Aeroflex Gaisler -- -- This program is free software; you can redistribute it and/or modify -- it under the terms of the GNU General Public License as published by -- the Free Software Foundation; either version 2 of the License, or -- (at your option) any later version. -- -- This program is distributed in the hope that it will be useful, -- but WITHOUT ANY WARRANTY; without even the implied warranty of -- MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the -- GNU General Public License for more details. -- -- You should have received a copy of the GNU General Public License -- along with this program; if not, write to the Free Software -- Foundation, Inc., 59 Temple Place, Suite 330, Boston, MA 02111-1307 USA ------------------------------------------------------------------------------ library ieee; use ieee.std_logic_1164.all; library gaisler; use gaisler.libdcom.all; use gaisler.sim.all; library techmap; use techmap.gencomp.all; library micron; use micron.components.all; use work.debug.all; use work.config.all; -- configuration entity testbench is generic ( fabtech : integer := CFG_FABTECH; memtech : integer := CFG_MEMTECH; padtech : integer := CFG_PADTECH; clktech : integer := CFG_CLKTECH; disas : integer := CFG_DISAS; -- Enable disassembly to console dbguart : integer := CFG_DUART; -- Print UART on console pclow : integer := CFG_PCLOW; clkperiod : integer := 20; -- system clock period romwidth : integer := 32; -- rom data width (8/32) romdepth : integer := 16; -- rom address depth sramwidth : integer := 32; -- ram data width (8/16/32) sramdepth : integer := 18; -- ram address depth srambanks : integer := 2 -- number of ram banks ); end; architecture behav of testbench is constant promfile : string := "prom.srec"; -- rom contents constant sramfile : string := "ram.srec"; -- ram contents constant sdramfile : string := "ram.srec"; -- sdram contents component leon3mp generic ( fabtech : integer := CFG_FABTECH; memtech : integer := CFG_MEMTECH; padtech : integer := CFG_PADTECH; clktech : integer := CFG_CLKTECH; disas : integer := CFG_DISAS; -- Enable disassembly to console dbguart : integer := CFG_DUART; -- Print UART on console pclow : integer := CFG_PCLOW ); port ( resetn : in std_ulogic; clk : in std_ulogic; clk3 : in std_ulogic; pllref : in std_ulogic; errorn : out std_ulogic; wdogn : out std_ulogic; address : out std_logic_vector(27 downto 0); data : inout std_logic_vector(31 downto 0); ramsn : out std_logic_vector (4 downto 0); ramoen : out std_logic_vector (4 downto 0); rwen : out std_logic_vector (3 downto 0); oen : out std_ulogic; writen : out std_ulogic; read : out std_ulogic; iosn : out std_ulogic; bexcn : in std_ulogic; -- DSU rx data brdyn : in std_ulogic; -- DSU rx data romsn : out std_logic_vector (1 downto 0); sdclk : out std_ulogic; sdcsn : out std_logic_vector (1 downto 0); -- sdram chip select sdwen : out std_ulogic; -- sdram write enable sdrasn : out std_ulogic; -- sdram ras sdcasn : out std_ulogic; -- sdram cas sddqm : out std_logic_vector (3 downto 0); -- sdram dqm dsuen : in std_ulogic; dsubre : in std_ulogic; dsuact : out std_ulogic; txd1 : out std_ulogic; -- UART1 tx data rxd1 : in std_ulogic; -- UART1 rx data ctsn1 : in std_ulogic; -- UART1 rx data rtsn1 : out std_ulogic; -- UART1 rx data txd2 : out std_ulogic; -- UART2 tx data rxd2 : in std_ulogic; -- UART2 rx data ctsn2 : in std_ulogic; -- UART1 rx data rtsn2 : out std_ulogic; -- UART1 rx data pio : inout std_logic_vector(17 downto 0); -- I/O port emdio : inout std_logic; -- ethernet PHY interface etx_clk : in std_ulogic; erx_clk : in std_ulogic; erxd : in std_logic_vector(3 downto 0); erx_dv : in std_ulogic; erx_er : in std_ulogic; erx_col : in std_ulogic; erx_crs : in std_ulogic; emdint : in std_ulogic; etxd : out std_logic_vector(3 downto 0); etx_en : out std_ulogic; etx_er : out std_ulogic; emdc : out std_ulogic; ps2clk : inout std_logic_vector(1 downto 0); ps2data : inout std_logic_vector(1 downto 0); vid_clock : out std_ulogic; vid_blankn : out std_ulogic; vid_syncn : out std_ulogic; vid_hsync : out std_ulogic; vid_vsync : out std_ulogic; vid_r : out std_logic_vector(7 downto 0); vid_g : out std_logic_vector(7 downto 0); vid_b : out std_logic_vector(7 downto 0); spw_clk : in std_ulogic; spw_rxdp : in std_logic_vector(0 to CFG_SPW_NUM-1); spw_rxdn : in std_logic_vector(0 to CFG_SPW_NUM-1); spw_rxsp : in std_logic_vector(0 to CFG_SPW_NUM-1); spw_rxsn : in std_logic_vector(0 to CFG_SPW_NUM-1); spw_txdp : out std_logic_vector(0 to CFG_SPW_NUM-1); spw_txdn : out std_logic_vector(0 to CFG_SPW_NUM-1); spw_txsp : out std_logic_vector(0 to CFG_SPW_NUM-1); spw_txsn : out std_logic_vector(0 to CFG_SPW_NUM-1); usb_clkout : in std_ulogic; usb_d : inout std_logic_vector(15 downto 0); usb_linestate : in std_logic_vector(1 downto 0); usb_opmode : out std_logic_vector(1 downto 0); usb_reset : out std_ulogic; usb_rxactive : in std_ulogic; usb_rxerror : in std_ulogic; usb_rxvalid : in std_ulogic; usb_suspend : out std_ulogic; usb_termsel : out std_ulogic; usb_txready : in std_ulogic; usb_txvalid : out std_ulogic; usb_validh : inout std_ulogic; usb_xcvrsel : out std_ulogic; usb_vbus : in std_ulogic ); end component; signal clk : std_logic := '0'; signal Rst : std_logic := '0'; -- Reset constant ct : integer := clkperiod/2; signal address : std_logic_vector(27 downto 0); signal data : std_logic_vector(31 downto 0); signal pio : std_logic_vector(17 downto 0); signal romsn : std_logic_vector(1 downto 0); signal ramsn : std_logic_vector(4 downto 0); signal ramoen : std_logic_vector(4 downto 0); signal rwen : std_logic_vector(3 downto 0); signal oen : std_ulogic; signal writen : std_ulogic; signal read : std_ulogic; signal iosn : std_ulogic; signal bexcn : std_ulogic; signal brdyn : std_ulogic; signal dsuen, dsutx, dsurx, dsubre, dsuact : std_ulogic; signal dsurst : std_ulogic; signal GND : std_ulogic := '0'; signal VCC : std_ulogic := '1'; signal NC : std_ulogic := 'Z'; signal clk2 : std_ulogic := '1'; signal wdogn : std_logic; signal sdcke : std_ulogic; -- clk en signal sdcsn : std_logic_vector ( 1 downto 0); signal sdwen : std_ulogic; -- write en signal sdrasn : std_ulogic; -- row addr stb signal sdcasn : std_ulogic; -- col addr stb signal sddqm : std_logic_vector ( 3 downto 0); -- data i/o mask signal sdclk : std_ulogic; signal pllref : std_ulogic; signal txd1, rxd1 : std_logic; signal txd2, rxd2 : std_logic; signal ctsn1, rtsn1 : std_ulogic; signal ctsn2, rtsn2 : std_ulogic; signal errorn : std_logic; signal etx_clk, erx_clk, erx_dv, erx_er, erx_col, erx_crs, etx_en, etx_er : std_logic:='0'; signal erxd, etxd: std_logic_vector(3 downto 0):=(others=>'0'); signal erxdt, etxdt : std_logic_vector(7 downto 0); signal emdc, emdio: std_logic; --dummy signal for the mdc,mdio in the phy which is not used signal eth_macclk : std_ulogic := '0'; signal emdint : std_ulogic; signal ps2clk : std_logic_vector(1 downto 0); signal ps2data : std_logic_vector(1 downto 0); signal vid_clock : std_ulogic; signal vid_blankn : std_ulogic; signal vid_syncn : std_ulogic; signal vid_hsync : std_ulogic; signal vid_vsync : std_ulogic; signal vid_r : std_logic_vector(7 downto 0); signal vid_g : std_logic_vector(7 downto 0); signal vid_b : std_logic_vector(7 downto 0); signal clk3 : std_ulogic := '0'; signal spw_clk : std_ulogic := '0'; signal spw_rxdp : std_logic_vector(0 to CFG_SPW_NUM-1) := (others => '0'); signal spw_rxdn : std_logic_vector(0 to CFG_SPW_NUM-1) := (others => '0'); signal spw_rxsp : std_logic_vector(0 to CFG_SPW_NUM-1) := (others => '0'); signal spw_rxsn : std_logic_vector(0 to CFG_SPW_NUM-1) := (others => '0'); signal spw_txdp : std_logic_vector(0 to CFG_SPW_NUM-1); signal spw_txdn : std_logic_vector(0 to CFG_SPW_NUM-1); signal spw_txsp : std_logic_vector(0 to CFG_SPW_NUM-1); signal spw_txsn : std_logic_vector(0 to CFG_SPW_NUM-1); signal usb_clkout : std_ulogic := '0'; signal usb_d : std_logic_vector(15 downto 0); signal usb_linestate : std_logic_vector(1 downto 0); signal usb_opmode : std_logic_vector(1 downto 0); signal usb_reset : std_ulogic; signal usb_rxactive : std_ulogic; signal usb_rxerror : std_ulogic; signal usb_rxvalid : std_ulogic; signal usb_suspend : std_ulogic; signal usb_termsel : std_ulogic; signal usb_txready : std_ulogic; signal usb_txvalid : std_ulogic; signal usb_validh : std_logic; signal usb_xcvrsel : std_ulogic; signal usb_vbus : std_ulogic; signal rhvalid : std_ulogic; constant lresp : boolean := false; begin -- clock and reset clk <= not clk after ct * 1 ns; clk3 <= not clk3 after 20 ns; rst <= dsurst and wdogn; dsuen <= '1'; dsubre <= '0'; rxd1 <= 'H'; ctsn1 <= '0'; rxd2 <= 'H'; ctsn2 <= '0'; pllref <= sdclk; ps2clk <= "HH"; ps2data <= "HH"; pio(4) <= pio(5); pio(1) <= pio(2); pio <= (others => 'H'); wdogn <= 'H'; usb_clkout <= not usb_clkout after 8.33 ns; -- ~60MHz spw_rxdp <= spw_txdp; spw_rxdn <= spw_txdn; spw_rxsp <= spw_txsp; spw_rxsn <= spw_txsn; cpu : leon3mp generic map ( fabtech, memtech, padtech, clktech, disas, dbguart, pclow ) port map (rst, clk, clk3, pllref, errorn, wdogn, address(27 downto 0), data, ramsn, ramoen, rwen, oen, writen, read, iosn, bexcn, brdyn, romsn, sdclk, sdcsn, sdwen, sdrasn, sdcasn, sddqm, dsuen, dsubre, dsuact, txd1, rxd1, ctsn1, rtsn1, txd2, rxd2, ctsn2, rtsn2, pio, emdio, etx_clk, erx_clk, erxd, erx_dv, erx_er, erx_col, erx_crs, emdint, etxd, etx_en, etx_er, emdc, ps2clk, ps2data, vid_clock, vid_blankn, vid_syncn, vid_hsync, vid_vsync, vid_r, vid_g, vid_b, spw_clk, spw_rxdp, spw_rxdn, spw_rxsp, spw_rxsn, spw_txdp, spw_txdn, spw_txsp, spw_txsn, usb_clkout, usb_d, usb_linestate, usb_opmode, usb_reset, usb_rxactive, usb_rxerror, usb_rxvalid, usb_suspend, usb_termsel, usb_txready, usb_txvalid, usb_validh, usb_xcvrsel, usb_vbus ); u0: mt48lc16m16a2 generic map (index => 0, fname => sdramfile) PORT MAP( Dq => data(31 downto 16), Addr => address(14 downto 2), Ba => address(16 downto 15), Clk => sdclk, Cke => vcc, Cs_n => sdcsn(0), Ras_n => sdrasn, Cas_n => sdcasn, We_n => sdwen, Dqm => sddqm(3 downto 2)); u1: mt48lc16m16a2 generic map (index => 16, fname => sdramfile) PORT MAP( Dq => data(15 downto 0), Addr => address(14 downto 2), Ba => address(16 downto 15), Clk => sdclk, Cke => vcc, Cs_n => sdcsn(0), Ras_n => sdrasn, Cas_n => sdcasn, We_n => sdwen, Dqm => sddqm(1 downto 0)); prom0 : sram generic map (index => 6, abits => romdepth, fname => promfile) port map (address(romdepth-1 downto 0), data(31 downto 24), romsn(0), writen, oen); phy0 : if (CFG_GRETH = 1) generate emdio <= 'H'; erxd <= erxdt(3 downto 0); etxdt <= "0000" & etxd; p0: phy generic map(base1000_t_fd => 0, base1000_t_hd => 0) port map(rst, emdio, etx_clk, erx_clk, erxdt, erx_dv, erx_er, erx_col, erx_crs, etxdt, etx_en, etx_er, emdc, eth_macclk); end generate; ps2devs: for i in 0 to 1 generate ps2_device(ps2clk(i), ps2data(i)); end generate ps2devs; errorn <= 'H'; -- ERROR pull-up iuerr : process begin wait for 5000 ns; if to_x01(errorn) = '1' then wait on errorn; end if; assert (to_x01(errorn) = '1') report "* IU in error mode, simulation halted " severity failure ; end process; test0 : grtestmod port map ( rst, clk, errorn, address(21 downto 2), data, iosn, oen, writen, brdyn); data <= buskeep(data) after 5 ns; dsucom : process procedure dsucfg(signal dsurx : in std_ulogic; signal dsutx : out std_ulogic) is variable w32 : std_logic_vector(31 downto 0); variable c8 : std_logic_vector(7 downto 0); constant txp : time := 320 1 ns; begin dsutx <= '1'; dsurst <= '0'; wait for 2500 ns; dsurst <= '1'; wait; wait for 5000 ns; txc(dsutx, 16#55#, txp); -- sync uart txc(dsutx, 16#c0#, txp); txa(dsutx, 16#90#, 16#00#, 16#00#, 16#00#, txp); txa(dsutx, 16#00#, 16#00#, 16#20#, 16#2e#, txp); wait for 25000 ns; txc(dsutx, 16#c0#, txp); txa(dsutx, 16#90#, 16#00#, 16#00#, 16#20#, txp); txa(dsutx, 16#00#, 16#00#, 16#00#, 16#01#, txp); txc(dsutx, 16#c0#, txp); txa(dsutx, 16#90#, 16#40#, 16#00#, 16#24#, txp); txa(dsutx, 16#00#, 16#00#, 16#00#, 16#0D#, txp); txc(dsutx, 16#c0#, txp); txa(dsutx, 16#90#, 16#70#, 16#11#, 16#78#, txp); txa(dsutx, 16#91#, 16#00#, 16#00#, 16#0D#, txp); txa(dsutx, 16#90#, 16#40#, 16#00#, 16#44#, txp); txa(dsutx, 16#00#, 16#00#, 16#20#, 16#00#, txp); txc(dsutx, 16#80#, txp); txa(dsutx, 16#90#, 16#40#, 16#00#, 16#44#, txp); wait; txc(dsutx, 16#c0#, txp); txa(dsutx, 16#00#, 16#00#, 16#0a#, 16#aa#, txp); txa(dsutx, 16#00#, 16#55#, 16#00#, 16#55#, txp); txc(dsutx, 16#c0#, txp); txa(dsutx, 16#00#, 16#00#, 16#0a#, 16#a0#, txp); txa(dsutx, 16#01#, 16#02#, 16#09#, 16#33#, txp); txc(dsutx, 16#c0#, txp); txa(dsutx, 16#90#, 16#00#, 16#00#, 16#00#, txp); txa(dsutx, 16#00#, 16#00#, 16#00#, 16#2e#, txp); txc(dsutx, 16#c0#, txp); txa(dsutx, 16#91#, 16#00#, 16#00#, 16#00#, txp); txa(dsutx, 16#00#, 16#00#, 16#00#, 16#2e#, txp); txc(dsutx, 16#c0#, txp); txa(dsutx, 16#90#, 16#00#, 16#00#, 16#20#, txp); txa(dsutx, 16#00#, 16#00#, 16#00#, 16#0f#, txp); txc(dsutx, 16#c0#, txp); txa(dsutx, 16#90#, 16#00#, 16#00#, 16#20#, txp); txa(dsutx, 16#00#, 16#00#, 16#00#, 16#00#, txp); txc(dsutx, 16#c0#, txp); txa(dsutx, 16#80#, 16#00#, 16#02#, 16#10#, txp); txa(dsutx, 16#00#, 16#00#, 16#00#, 16#0f#, txp); txc(dsutx, 16#c0#, txp); txa(dsutx, 16#91#, 16#40#, 16#00#, 16#24#, txp); txa(dsutx, 16#00#, 16#00#, 16#00#, 16#24#, txp); txc(dsutx, 16#c0#, txp); txa(dsutx, 16#91#, 16#70#, 16#00#, 16#00#, txp); txa(dsutx, 16#00#, 16#00#, 16#00#, 16#03#, txp); txc(dsutx, 16#c0#, txp); txa(dsutx, 16#90#, 16#00#, 16#00#, 16#20#, txp); txa(dsutx, 16#00#, 16#00#, 16#ff#, 16#ff#, txp); txc(dsutx, 16#c0#, txp); txa(dsutx, 16#90#, 16#40#, 16#00#, 16#48#, txp); txa(dsutx, 16#00#, 16#00#, 16#00#, 16#12#, txp); txc(dsutx, 16#c0#, txp); txa(dsutx, 16#90#, 16#40#, 16#00#, 16#60#, txp); txa(dsutx, 16#00#, 16#00#, 16#12#, 16#10#, txp); txc(dsutx, 16#80#, txp); txa(dsutx, 16#90#, 16#00#, 16#00#, 16#00#, txp); rxi(dsurx, w32, txp, lresp); txc(dsutx, 16#a0#, txp); txa(dsutx, 16#40#, 16#00#, 16#00#, 16#00#, txp); rxi(dsurx, w32, txp, lresp); end; begin dsucfg(txd2, rxd2); wait; end process; end ;	gpl-2.0	456e6f19334e203846d3dff024196a53	0.587645	3.038742	false	false	false	false
marco-c/leon-nexys2	grlib-gpl-1.3.4-b4140/lib/gaisler/pci/grpci1/pci_mt.vhd	1	28,846	------------------------------------------------------------------------------ -- This file is a part of the GRLIB VHDL IP LIBRARY -- Copyright (C) 2003 - 2008, Gaisler Research -- Copyright (C) 2008 - 2013, Aeroflex Gaisler -- -- This program is free software; you can redistribute it and/or modify -- it under the terms of the GNU General Public License as published by -- the Free Software Foundation; either version 2 of the License, or -- (at your option) any later version. -- -- This program is distributed in the hope that it will be useful, -- but WITHOUT ANY WARRANTY; without even the implied warranty of -- MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the -- GNU General Public License for more details. -- -- You should have received a copy of the GNU General Public License -- along with this program; if not, write to the Free Software -- Foundation, Inc., 59 Temple Place, Suite 330, Boston, MA 02111-1307 USA ----------------------------------------------------------------------------- -- Entity: pci_mt -- File: pci_mt.vhd -- Author: Jiri Gaisler - Gaisler Research -- Modified: Alf Vaerneus - Gaisler Research -- Description: Simple PCI master and target interface ------------------------------------------------------------------------------ library ieee; use ieee.std_logic_1164.all; library grlib; use grlib.amba.all; use grlib.stdlib.all; use grlib.devices.all; library gaisler; use gaisler.pci.all; use gaisler.pcilib.all; entity pci_mt is generic ( hmstndx : integer := 0; abits : integer := 21; device_id : integer := 0; -- PCI device ID vendor_id : integer := 0; -- PCI vendor ID master : integer := 1; -- Enable PCI Master hslvndx : integer := 0; haddr : integer := 16#F00#; hmask : integer := 16#F00#; ioaddr : integer := 16#000#; nsync : integer range 1 to 2 := 1; -- 1 or 2 sync regs between clocks oepol : integer := 0 ); port( rst : in std_logic; clk : in std_logic; pciclk : in std_logic; pcii : in pci_in_type; pcio : out pci_out_type; ahbmi : in ahb_mst_in_type; ahbmo : out ahb_mst_out_type; ahbsi : in ahb_slv_in_type; ahbso : out ahb_slv_out_type ); end; architecture rtl of pci_mt is constant REVISION : amba_version_type := 0; constant hconfig : ahb_config_type := ( 0 => ahb_device_reg ( VENDOR_GAISLER, GAISLER_PCISBRG, 0, REVISION, 0), 4 => ahb_membar(haddr, '0', '0', hmask), 5 => ahb_iobar (ioaddr, 16#E00#), others => zero32); constant CSYNC : integer := nsync-1; constant MADDR_WIDTH : integer := abits; constant HADDR_WIDTH : integer := 28; type pci_input_type is record ad : std_logic_vector(31 downto 0); cbe : std_logic_vector(3 downto 0); frame : std_logic; devsel : std_logic; idsel : std_logic; trdy : std_logic; irdy : std_logic; par : std_logic; stop : std_logic; rst : std_logic; gnt : std_logic; end record; type ahbs_input_type is record haddr : std_logic_vector(HADDR_WIDTH - 1 downto 0); htrans : std_logic_vector(1 downto 0); hwrite : std_logic; hsize : std_logic_vector(1 downto 0); hburst : std_logic_vector(2 downto 0); hwdata : std_logic_vector(31 downto 0); hsel : std_logic; hiosel : std_logic; hready : std_logic; end record; type pci_target_state_type is (idle, b_busy, s_data, backoff, turn_ar); type pci_master_state_type is (idle, addr, m_data, turn_ar, s_tar, dr_bus); type pci_config_command_type is record ioen : std_logic; -- I/O access enable men : std_logic; -- Memory access enable msen : std_logic; -- Master enable spcen : std_logic; -- Special cycle enable mwie : std_logic; -- Memory write and invalidate enable vgaps : std_logic; -- VGA palette snooping enable per : std_logic; -- Parity error response enable wcc : std_logic; -- Address stepping enable serre : std_logic; -- Enable SERR# driver fbtbe : std_logic; -- Fast back-to-back enable end record; type pci_config_status_type is record c66mhz : std_logic; -- 66MHz capability udf : std_logic; -- UDF supported fbtbc : std_logic; -- Fast back-to-back capability dped : std_logic; -- Data parity error detected dst : std_logic_vector(1 downto 0); -- DEVSEL timing sta : std_logic; -- Signaled target abort rta : std_logic; -- Received target abort rma : std_logic; -- Received master abort sse : std_logic; -- Signaled system error dpe : std_logic; -- Detected parity error end record; type pci_reg_type is record addr : std_logic_vector(MADDR_WIDTH-1 downto 0); ad : std_logic_vector(31 downto 0); cbe : std_logic_vector(3 downto 0); lcbe : std_logic_vector(3 downto 0); t_state : pci_target_state_type; -- PCI target state machine m_state : pci_master_state_type; -- PCI master state machine csel : std_logic; -- Configuration chip select msel : std_logic; -- Memory hit read : std_logic; devsel : std_logic; -- PCI device select trdy : std_logic; -- Target ready irdy : std_logic; -- Master ready stop : std_logic; -- Target stop request par : std_logic; -- PCI bus parity req : std_logic; -- Master bus request oe_par : std_logic; oe_ad : std_logic; oe_trdy : std_logic; oe_devsel: std_logic; oe_ctrl : std_logic; oe_cbe : std_logic; oe_stop : std_logic; oe_frame : std_logic; oe_irdy : std_logic; oe_req : std_logic; noe_par : std_logic; noe_ad : std_logic; noe_trdy : std_logic; noe_devsel: std_logic; noe_ctrl : std_logic; noe_cbe : std_logic; noe_stop : std_logic; noe_frame : std_logic; noe_irdy : std_logic; noe_req : std_logic; request : std_logic; -- Request from Back-end frame : std_logic; -- Master frame bar0 : std_logic_vector(31 downto MADDR_WIDTH); page : std_logic_vector(31 downto MADDR_WIDTH-1); comm : pci_config_command_type; stat : pci_config_status_type; laddr : std_logic_vector(31 downto 0); ldata : std_logic_vector(31 downto 0); pwrite : std_logic; hwrite : std_logic; start : std_logic; hreq : std_logic; hreq_ack : std_logic_vector(csync downto 0); preq : std_logic_vector(csync downto 0); preq_ack : std_logic; rready : std_logic_vector(csync downto 0); wready : std_logic_vector(csync downto 0); sync : std_logic_vector(csync downto 0); pabort : std_logic; mcnt : std_logic_vector(2 downto 0); maddr : std_logic_vector(31 downto 0); mdata : std_logic_vector(31 downto 0); stop_req : std_logic; end record; type cpu_master_state_type is (idle, sync1, busy, sync2); type cpu_slave_state_type is (idle, getd, req, sync, read, sync2, t_done); type cpu_reg_type is record tdata : std_logic_vector(31 downto 0); -- Target data maddr : std_logic_vector(31 downto 0); -- Master data mdata : std_logic_vector(31 downto 0); -- Master data be : std_logic_vector(3 downto 0); m_state : cpu_master_state_type; -- AMBA master state machine s_state : cpu_slave_state_type; -- AMBA slave state machine start : std_logic_vector(csync downto 0); hreq : std_logic_vector(csync downto 0); hreq_ack : std_logic; preq : std_logic; preq_ack : std_logic_vector(csync downto 0); sync : std_logic; hwrite : std_logic; -- AHB write on PCI pabort : std_logic_vector(csync downto 0); perror : std_logic; rready : std_logic; wready : std_logic; hrdata : std_logic_vector(31 downto 0); hresp : std_logic_vector(1 downto 0); pciba : std_logic_vector(3 downto 0); end record; signal clk_int : std_logic; signal pr : pci_input_type; signal hr : ahbs_input_type; signal r, rin : pci_reg_type; signal r2, r2in : cpu_reg_type; signal dmai : ahb_dma_in_type; signal dmao : ahb_dma_out_type; signal roe_ad, rioe_ad : std_logic_vector(31 downto 0); attribute syn_preserve : boolean; attribute syn_preserve of roe_ad : signal is true; begin -- Back-end state machine (AHB clock domain) comb : process (rst, r2, r, dmao, hr, ahbsi) variable vdmai : ahb_dma_in_type; variable v : cpu_reg_type; variable request : std_logic; variable hready : std_logic; variable hresp, hsize, htrans : std_logic_vector(1 downto 0); variable p_done : std_logic; begin v := r2; vdmai.start := '0'; vdmai.burst := '0'; vdmai.size := "010"; vdmai.address := r.laddr; v.sync := '1'; vdmai.wdata := ahbdrivedata(r.ldata); vdmai.write := r.pwrite; v.start(0) := r2.start(csync); v.start(csync) := r.start; v.hreq(0) := r2.hreq(csync); v.hreq(csync) := r.hreq; v.pabort(0) := r2.pabort(csync); v.pabort(csync) := r.pabort; v.preq_ack(0) := r2.preq_ack(csync); v.preq_ack(csync) := r.preq_ack; hready := '1'; hresp := HRESP_OKAY; request := '0'; hsize := "10"; htrans := "00"; p_done := r2.hreq(0) or r2.pabort(0); ---- * APB register access * ---- --if (apbi.psel and apbi.penable and apbi.pwrite) = '1' then --v.pciba := apbi.pwdata(31 downto 28); --end if; --apbo.prdata <= r2.pciba & addzero; if hr.hiosel = '1' then if hr.hwrite = '1' then v.pciba := ahbreadword(ahbsi.hwdata)(31 downto 28); end if; v.hrdata := r2.pciba & addzero(27 downto 0); end if; ---- * AHB MASTER * ---- case r2.m_state is when idle => v.sync := '0'; if r2.start(0) = '1' then if r.pwrite = '1' then v.m_state := sync1; v.wready := '0'; else v.m_state := busy; vdmai.start := '1'; end if; end if; when sync1 => if r2.start(0) = '0' then v.m_state := busy; vdmai.start := '1'; end if; when busy => if dmao.active = '1' then if dmao.ready = '1' then v.rready := not r.pwrite; v.tdata := dmao.rdata(31 downto 0); v.m_state := sync2; end if; else vdmai.start := '1'; end if; when sync2 => if r2.start(0) = '0' then v.m_state := idle; v.wready := '1'; v.rready := '0'; end if; end case; ---- * AHB MASTER END * ---- ---- * AHB SLAVE * ---- if MASTER = 1 then if (hr.hready and hr.hsel) = '1' then hsize := hr.hsize; htrans := hr.htrans; if (hr.htrans(1) and r.comm.msen) = '1' then request := '1'; end if; end if; if (request = '1' and r2.s_state = idle) then v.maddr := r2.pciba & hr.haddr; v.hwrite := hr.hwrite; case hsize is when "00" => v.be := "1110"; -- Decode byte enable when "01" => v.be := "1100"; when "10" => v.be := "0000"; when others => v.be := "1111"; end case; elsif r2.s_state = getd and r2.hwrite = '1' then v.mdata := hr.hwdata; end if; if r2.hreq(0) = '1' then v.hrdata := r.ldata; end if; if r2.preq_ack(0) = '1' then v.preq := '0'; end if; if r2.pabort(0) = '1' then v.perror := '1'; end if; if p_done = '0' then v.hreq_ack := '0'; end if; -- AHB slave state machine case r2.s_state is when idle => if request = '1' then v.s_state := getd; end if; when getd => v.s_state := req; v.preq := '1'; when req => if r2.preq_ack(0) = '1' then v.s_state := sync; end if; when sync => if r2.preq_ack(0) = '0' then v.s_state := read; end if; when read => if p_done = '1' then v.hreq_ack := '1'; v.s_state := sync2; end if; when sync2 => if p_done = '0' then v.s_state := t_done; end if; when t_done => if request = '1' then v.s_state := idle; end if; when others => v.s_state := idle; end case; if request = '1' then if r2.s_state = t_done then if r2.perror = '1' then hresp := HRESP_ERROR; else hresp := HRESP_OKAY; end if; v.perror := '0'; else hresp := HRESP_RETRY; end if; end if; if r.comm.msen = '0' then hresp := HRESP_ERROR; end if; -- Master disabled if htrans(1) = '0' then hresp := HRESP_OKAY; end if; -- Response OK for BUSY and IDLE if (hresp /= HRESP_OKAY and (hr.hready and hr.hsel) = '1') then -- insert one wait cycle hready := '0'; end if; if hr.hready = '0' then hresp := r2.hresp; end if; v.hresp := hresp; end if; ---- * AHB SLAVE END * ---- if rst = '0' then v.s_state := idle; v.rready := '0'; v.wready := '1'; v.m_state := idle; v.preq := '0'; v.hreq_ack := '0'; v.perror := '0'; v.be := (others => '1'); v.pciba := (others => '0'); v.hresp := (others => '0'); end if; r2in <= v; dmai <= vdmai; ahbso.hready <= hready; ahbso.hresp <= hresp; ahbso.hrdata <= ahbdrivedata(r2.hrdata); end process; ahbso.hconfig <= hconfig when MASTER = 1 else (others => zero32); ahbso.hsplit <= (others => '0'); ahbso.hirq <= (others => '0'); ahbso.hindex <= hslvndx; -- PCI target core (PCI clock domain) pcicomb : process(pcii.rst, pr, pcii, r, r2, roe_ad) variable v : pci_reg_type; variable chit, mhit, hit, ready, cwrite : std_logic; variable cdata, cwdata : std_logic_vector(31 downto 0); variable comp : std_logic; -- Last transaction cycle on PCI bus variable iready : std_logic; variable mto : std_logic; variable tad, mad : std_logic_vector(31 downto 0); -- variable cbe : std_logic_vector(3 downto 0); variable caddr : std_logic_vector(7 downto 2); variable voe_ad : std_logic_vector(31 downto 0); variable oe_par : std_logic; variable oe_ad : std_logic; variable oe_ctrl : std_logic; variable oe_trdy : std_logic; variable oe_devsel: std_logic; variable oe_cbe : std_logic; variable oe_stop : std_logic; variable oe_frame : std_logic; variable oe_irdy : std_logic; variable oe_req : std_logic; begin -- Process defaults v := r; v.trdy := '1'; v.stop := '1'; v.frame := '1'; v.oe_ad := '1'; v.devsel := '1'; v.oe_frame := '1'; v.irdy := '1'; v.req := '1'; voe_ad := roe_ad; v.oe_req := '0'; v.oe_cbe := '1'; v.oe_irdy := '1'; v.rready(0) := r.rready(csync); v.rready(csync) := r2.rready; v.wready(0) := r.wready(csync); v.wready(csync) := r2.wready; v.sync(0) := r.sync(csync); v.sync(csync) := r2.sync; v.preq(0) := r.preq(csync); v.preq(csync) := r2.preq; v.hreq_ack(0) := r.hreq_ack(csync); v.hreq_ack(csync) := r2.hreq_ack; comp := '0'; mto := '0'; tad := r.ad; mad := r.ad; v.stop_req := '0'; --cbe := r.cbe; ----- * PCI TARGET * -------- -- address decoding if (r.t_state = s_data) and ((pr.irdy or r.trdy or r.read) = '0') then cwrite := r.csel; if ((r.msel and r.addr(MADDR_WIDTH-1)) = '1') and (pr.cbe = "0000") then v.page := pr.ad(31 downto MADDR_WIDTH-1); end if; if (pr.cbe = "0000") and (r.addr(MADDR_WIDTH-1) = '1') then end if; else cwrite := '0'; end if; cdata := (others => '0'); caddr := r.addr(7 downto 2); case caddr is when "000000" => -- 0x00, device & vendor id cdata := conv_std_logic_vector(DEVICE_ID, 16) & conv_std_logic_vector(VENDOR_ID, 16); when "000001" => -- 0x04, status & command cdata(1) := r.comm.men; cdata(2) := r.comm.msen; cdata(25) := '1'; cdata(28) := r.stat.rta; cdata(29) := r.stat.rma; when "000010" => -- 0x08, class code & revision when "000011" => -- 0x0c, latency & cacheline size when "000100" => -- 0x10, BAR0 cdata(31 downto MADDR_WIDTH) := r.bar0; when others => end case; cwdata := pr.ad; if pr.cbe(3) = '1' then cwdata(31 downto 24) := cdata(31 downto 24); end if; if pr.cbe(2) = '1' then cwdata(23 downto 16) := cdata(23 downto 16); end if; if pr.cbe(1) = '1' then cwdata(15 downto 8) := cdata(15 downto 8); end if; if pr.cbe(0) = '1' then cwdata( 7 downto 0) := cdata( 7 downto 0); end if; if cwrite = '1' then case caddr is when "000001" => -- 0x04, status & command v.comm.men := cwdata(1); v.comm.msen := cwdata(2); v.stat.rta := r.stat.rta and not cwdata(28); v.stat.rma := r.stat.rma and not cwdata(29); when "000100" => -- 0x10, BAR0 v.bar0 := cwdata(31 downto MADDR_WIDTH); when others => end case; end if; if (((pr.cbe = pci_config_read) or (pr.cbe = pci_config_write)) and (pr.ad(1 downto 0) = "00")) then chit := '1'; else chit := '0'; end if; if ((pr.cbe = pci_memory_read) or (pr.cbe = pci_memory_write)) and (r.bar0 = pr.ad(31 downto MADDR_WIDTH)) and (r.bar0 /= zero(31 downto MADDR_WIDTH)) then mhit := '1'; else mhit := '0'; end if; hit := r.csel or r.msel; ready := r.csel or (r.rready(0) and r.read) or (r.wready(0) and not r.read and not r.start) or r.addr(MADDR_WIDTH-1); -- target state machine case r.t_state is when idle => if pr.frame = '0' then v.t_state := b_busy; end if; -- !HIT ? v.addr := pr.ad(MADDR_WIDTH-1 downto 0); -- v.cbe := pr.cbe; v.csel := pr.idsel and chit; v.msel := r.comm.men and mhit; v.read := not pr.cbe(0); if (r.sync(0) and r.start and r.pwrite) = '1' then v.start := '0'; end if; when turn_ar => if pr.frame = '1' then v.t_state := idle; end if; if pr.frame = '0' then v.t_state := b_busy; end if; -- !HIT ? v.addr := pr.ad(MADDR_WIDTH-1 downto 0); -- v.cbe := pr.cbe; v.csel := pr.idsel and chit; v.msel := r.comm.men and mhit; v.read := not pr.cbe(0); if (r.sync(0) and r.start and r.pwrite) = '1' then v.start := '0'; end if; when b_busy => if hit = '1' then v.t_state := s_data; v.trdy := not ready; v.stop := pr.frame and ready; v.devsel := '0'; else v.t_state := backoff; end if; when s_data => v.stop := r.stop; v.devsel := '0'; v.trdy := r.trdy or not pcii.irdy; if (pcii.frame and not pcii.irdy) = '1' then v.t_state := turn_ar; v.stop := '1'; v.trdy := '1'; v.devsel := '1'; end if; when backoff => if pr.frame = '1' then v.t_state := idle; end if; end case; if ((r.t_state = s_data) or (r.t_state = turn_ar)) and (((pr.irdy or pr.trdy) = '0') or ((not pr.irdy and not pr.stop and pr.trdy and not r.start and r.wready(0)) = '1')) then if (pr.trdy and r.read)= '0' then v.start := '0'; end if; if (r.start = '0') and ((r.msel and not r.addr(MADDR_WIDTH-1)) = '1') and (((pr.trdy and r.read and not r.rready(0)) or (not pr.trdy and not r.read)) = '1') then v.laddr := r.page & r.addr(MADDR_WIDTH-2 downto 0); v.ldata := pr.ad; v.pwrite := not r.read; v.start := '1'; end if; end if; -- if (v.t_state = s_data) and (r.read = '1') then v.oe_ad := '0'; end if; -- v.oe_par := r.oe_ad; if r.csel = '1' then tad := cdata; elsif r.addr(MADDR_WIDTH-1) = '1' then tad(31 downto MADDR_WIDTH-1) := r.page; tad(MADDR_WIDTH-2 downto 0) := (others => '0'); else tad := r2.tdata; end if; if (v.t_state = s_data) or (r.t_state = s_data) then v.oe_ctrl := '0'; else v.oe_ctrl := '1'; end if; ----- * PCI TARGET END* -------- ----- * PCI MASTER * -------- if MASTER = 1 then if r.preq(0) = '1' then if (r.m_state = idle or r.m_state = dr_bus) and r.request = '0' and r.hreq = '0' then v.request := '1'; v.hwrite := r2.hwrite; v.lcbe := r2.be; v.mdata := r2.mdata; v.maddr :=r2.maddr; end if; end if; if r.hreq_ack(0) = '1' then v.hreq := '0'; v.pabort := '0'; end if; if r.preq(0) = '0' then v.preq_ack := '0'; end if; comp := not(pcii.trdy or pcii.irdy); if ((pr.irdy and not pr.frame) or (pr.devsel and r.frame and not r.oe_frame)) = '1' then -- Covers both master timeout and devsel timeout if r.mcnt /= "000" then v.mcnt := r.mcnt - 1; else mto := '1'; end if; else v.mcnt := (others => '1'); end if; -- PCI master state machine case r.m_state is when idle => -- Master idle if (pr.gnt = '0' and (pr.frame and pr.irdy) = '1') then if r.request = '1' then v.m_state := addr; v.preq_ack := '1'; else v.m_state := dr_bus; end if; end if; when addr => -- Always one address cycle at the beginning of an transaction v.m_state := m_data; when m_data => -- Master transfers data --if (r.request and not pr.gnt and pr.frame and not pr.trdy -- Not supporting address stepping! --and pr.stop and l_cycle and sa) = '1' then --v.m_state <= addr; v.hreq := comp; if (pr.frame = '0') or ((pr.frame and pcii.trdy and pcii.stop and not mto) = '1') then v.m_state := m_data; elsif ((pr.frame and (mto or not pcii.stop)) = '1') then v.m_state := s_tar; else v.m_state := turn_ar; v.request := '0'; end if; when turn_ar => -- Transaction complete if (r.request and not pr.gnt) = '1' then v.m_state := addr; elsif (r.request or pr.gnt) = '0' then v.m_state := dr_bus; else v.m_state := idle; end if; when s_tar => -- Stop was asserted v.request := pr.trdy and not pr.stop and not pr.devsel; v.stop_req := '1'; if (pr.stop or pr.devsel or pr.trdy) = '0' then -- Disconnect with data v.m_state := turn_ar; elsif pr.gnt = '0' then v.pabort := not v.request; v.m_state := dr_bus; else v.m_state := idle; v.pabort := not v.request; end if; when dr_bus => -- Drive bus when parked on this agent if (r.request = '1' and (pcii.gnt or r.req) = '0') then v.m_state := addr; v.preq_ack := '1'; elsif pcii.gnt = '1' then v.m_state := idle; end if; end case; if v.m_state = addr then mad := r.maddr; else mad := r.mdata; end if; if (pr.irdy or pr.trdy or r.hwrite) = '0' then v.ldata := pr.ad; end if; -- Target abort if ((pr.devsel and pr.trdy and not pr.gnt and not pr.stop) = '1') then v.stat.rta := '1'; end if; -- Master abort if mto = '1' then v.stat.rma := '1'; end if; -- Drive FRAME# and IRDY# if (v.m_state = addr or v.m_state = m_data) then v.oe_frame := '0'; end if; -- Drive CBE# if (v.m_state = addr or v.m_state = m_data or v.m_state = dr_bus) then v.oe_cbe := '0'; end if; -- Drive IRDY# (FRAME# delayed one pciclk) v.oe_irdy := r.oe_frame; -- FRAME# assert if v.m_state = addr then v.frame := '0'; end if; -- Only single transfers valid -- IRDY# assert if v.m_state = m_data then v.irdy := '0'; end if; -- REQ# assert if (v.request = '1' and (v.m_state = idle or r.m_state = idle) and (v.stop_req or r.stop_req) = '0') then v.req := '0'; end if; -- C/BE# assert if v.m_state = addr then v.cbe := "011" & r.hwrite; else v.cbe := r.lcbe; end if; end if; ----- * PCI MASTER END * -------- ----- * SHARED BUS SIGNALS * ------- -- Drive PAR v.oe_par := r.oe_ad; --Delayed one clock v.par := xorv(r.ad & r.cbe); -- Default asserted by master v.ad := mad; -- Default asserted by master -- Master if (v.m_state = addr or (v.m_state = m_data and r.hwrite = '1') or v.m_state = dr_bus) then v.oe_ad := '0'; end if; -- Drive AD -- Target if r.read = '1' then if v.t_state = s_data then v.oe_ad := '0'; v.ad := tad; elsif r.t_state = s_data then v.par := xorv(r.ad & pcii.cbe); end if; end if; v.oe_stop := v.oe_ctrl; v.oe_devsel := v.oe_ctrl; v.oe_trdy := v.oe_ctrl; v.noe_ad := not v.oe_ad; v.noe_ctrl := not v.oe_ctrl; v.noe_par := not v.oe_par; v.noe_req := not v.oe_req; v.noe_frame := not v.oe_frame; v.noe_cbe := not v.oe_cbe; v.noe_irdy := not v.oe_irdy; v.noe_stop := not v.oe_ctrl; v.noe_devsel := not v.oe_ctrl; v.noe_trdy := not v.oe_ctrl; if oepol = 0 then voe_ad := (others => v.oe_ad); oe_ad := r.oe_ad; oe_ctrl := r.oe_ctrl; oe_par := r.oe_par; oe_req := r.oe_req; oe_frame := r.oe_frame; oe_cbe := r.oe_cbe; oe_irdy := r.oe_irdy; oe_stop := r.oe_stop; oe_trdy := r.oe_trdy; oe_devsel := r.oe_devsel; else voe_ad := (others => v.noe_ad); oe_ad := r.noe_ad; oe_ctrl := r.noe_ctrl; oe_par := r.noe_par; oe_req := r.noe_req; oe_frame := r.noe_frame; oe_cbe := r.noe_cbe; oe_irdy := r.noe_irdy; oe_stop := r.noe_stop; oe_trdy := r.noe_trdy; oe_devsel := r.noe_devsel; end if; ----- * SHARED BUS SIGNALS END * ------- if pr.rst = '0' then v.t_state := idle; v.m_state := idle; v.comm.men := '0'; v.start := '0'; v.bar0 := (others => '0'); v.msel := '0'; v.csel := '0'; v.page := (others => '0'); v.page(31 downto 30) := "01"; v.par := '0'; v.hwrite := '0'; v.request := '0'; v.comm.msen := '0'; v.laddr := (others => '0'); v.ldata := (others => '0'); v.hreq := '0'; v.preq_ack := '0'; v.pabort := '0'; v.mcnt := (others => '1'); v.maddr := (others => '0'); v.lcbe := (others => '0'); v.mdata := (others => '0'); v.pwrite := '0'; v.stop_req := '0'; v.stat.rta := '0'; v.stat.rma := '0'; end if; rin <= v; rioe_ad <= voe_ad; pcio.reqen <= oe_req; pcio.req <= r.req; pcio.frameen <= oe_frame; pcio.frame <= r.frame; pcio.irdyen <= oe_irdy; pcio.irdy <= r.irdy; pcio.cbeen <= (others => oe_cbe); pcio.cbe <= r.cbe; pcio.vaden <= roe_ad; pcio.aden <= oe_ad; pcio.ad <= r.ad; pcio.trdy <= r.trdy; pcio.ctrlen <= oe_ctrl; pcio.trdyen <= oe_trdy; pcio.devselen <= oe_devsel; pcio.stopen <= oe_stop; pcio.stop <= r.stop; pcio.devsel <= r.devsel; pcio.par <= r.par; pcio.paren <= oe_par; pcio.rst <= '1'; end process; pcir : process (pciclk, pcii.rst) begin if rising_edge (pciclk) then pr.ad <= to_x01(pcii.ad); pr.cbe <= to_x01(pcii.cbe); pr.devsel <= to_x01(pcii.devsel); pr.frame <= to_x01(pcii.frame); pr.idsel <= to_x01(pcii.idsel); pr.irdy <= to_x01(pcii.irdy); pr.trdy <= to_x01(pcii.trdy); pr.par <= to_x01(pcii.par); pr.stop <= to_x01(pcii.stop); pr.rst <= to_x01(pcii.rst); pr.gnt <= to_x01(pcii.gnt); r <= rin; roe_ad <= rioe_ad; end if; if pcii.rst = '0' then -- asynch reset required r.oe_ad <= '1'; r.oe_ctrl <= '1'; r.oe_par <= '1'; r.oe_stop <= '1'; r.oe_req <= '1'; r.oe_frame <= '1'; r.oe_cbe <= '1'; r.oe_irdy <= '1'; r.oe_trdy <= '1'; r.oe_devsel <= '1'; r.noe_ad <= '0'; r.noe_ctrl <= '0'; r.noe_par <= '0'; r.noe_req <= '0'; r.noe_frame <= '0'; r.noe_cbe <= '0'; r.noe_irdy <= '0'; r.noe_stop <= '0'; r.noe_trdy <= '0'; r.noe_devsel <= '0'; if oepol = 0 then roe_ad <= (others => '1'); else roe_ad <= (others => '0'); end if; end if; end process; cpur : process (rst,clk) begin if rising_edge (clk) then hr.haddr <= ahbsi.haddr(HADDR_WIDTH - 1 downto 0); hr.htrans <= ahbsi.htrans; hr.hwrite <= ahbsi.hwrite; hr.hsize <= ahbsi.hsize(1 downto 0); hr.hburst <= ahbsi.hburst; hr.hwdata <= ahbreadword(ahbsi.hwdata); hr.hsel <= ahbsi.hsel(hslvndx) and ahbsi.hmbsel(0); hr.hiosel <= ahbsi.hsel(hslvndx) and ahbsi.hmbsel(1); hr.hready <= ahbsi.hready; r2 <= r2in; end if; end process; oe0 : if oepol = 0 generate pcio.perren <= '1'; pcio.serren <= '1'; pcio.inten <= '1'; pcio.vinten <= (others => '1'); pcio.locken <= '1'; end generate; oe1 : if oepol = 1 generate pcio.perren <= '0'; pcio.serren <= '0'; pcio.inten <= '0'; pcio.vinten <= (others => '0'); pcio.locken <= '0'; end generate; pcio.perr <= '1'; pcio.serr <= '1'; pcio.int <= '1'; msttgt : if MASTER = 1 generate ahbmst0 : ahbmst generic map (hindex => hmstndx, devid => GAISLER_PCISBRG) port map (rst, clk, dmai, dmao, ahbmi, ahbmo); -- pragma translate_off bootmsg : report_version generic map ("pci_mt" & tost(hslvndx) & ": Simple 32-bit PCI Bridge, rev " & tost(REVISION) & ", " & tost(2abits/220) & " Mbyte PCI memory BAR" ); -- pragma translate_on end generate; tgtonly : if MASTER = 0 generate ahbmst0 : ahbmst generic map (hindex => hmstndx, devid => GAISLER_PCITRG) port map (rst, clk, dmai, dmao, ahbmi, ahbmo); -- pragma translate_off bootmsg : report_version generic map ("pci_mt" & tost(hmstndx) & ": Simple 32-bit Bridge, target-only, rev " & tost(REVISION) & ", " & tost(2abits/220) & " Mbyte PCI memory BAR" ); -- pragma translate_on end generate; end;	gpl-2.0	a0aade0367da5dc8ec3a8464ebf7f985	0.559003	2.923186	false	false	false	false
marco-c/leon-nexys2	grlib-gpl-1.3.4-b4140/lib/gaisler/pci/pcitrace/pcitrace.vhd	1	7,716	------------------------------------------------------------------------------ -- This file is a part of the GRLIB VHDL IP LIBRARY -- Copyright (C) 2003 - 2008, Gaisler Research -- Copyright (C) 2008 - 2013, Aeroflex Gaisler -- -- This program is free software; you can redistribute it and/or modify -- it under the terms of the GNU General Public License as published by -- the Free Software Foundation; either version 2 of the License, or -- (at your option) any later version. -- -- This program is distributed in the hope that it will be useful, -- but WITHOUT ANY WARRANTY; without even the implied warranty of -- MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the -- GNU General Public License for more details. -- -- You should have received a copy of the GNU General Public License -- along with this program; if not, write to the Free Software -- Foundation, Inc., 59 Temple Place, Suite 330, Boston, MA 02111-1307 USA ----------------------------------------------------------------------------- -- Entity: pcitrace -- File: pcitrace.vhd -- Author: Jiri Gaisler - Gaisler Research -- Description: PCI trace buffer ------------------------------------------------------------------------------ library ieee; use ieee.std_logic_1164.all; library grlib; use grlib.amba.all; use grlib.stdlib.all; use grlib.devices.all; library techmap; use techmap.gencomp.all; library gaisler; use gaisler.pci.all; entity pcitrace is generic ( depth : integer range 6 to 12 := 8; iregs : integer := 1; memtech : integer := DEFMEMTECH; pindex : integer := 0; paddr : integer := 0; pmask : integer := 16#f00# ); port ( rst : in std_ulogic; clk : in std_ulogic; pciclk : in std_ulogic; pcii : in pci_in_type; apbi : in apb_slv_in_type; apbo : out apb_slv_out_type ); end; architecture rtl of pcitrace is constant REVISION : amba_version_type := 0; constant pconfig : apb_config_type := ( 0 => ahb_device_reg ( VENDOR_GAISLER, GAISLER_PCITRACE, 0, REVISION, 0), 1 => apb_iobar(paddr, pmask)); type reg_type is record sample : std_ulogic; armed : std_ulogic; busy : std_ulogic; timeout : std_logic_vector(depth-1 downto 0); admask : std_logic_vector(31 downto 0); adpattern : std_logic_vector(31 downto 0); sigmask : std_logic_vector(15 downto 0); sigpattern : std_logic_vector(15 downto 0); count : std_logic_vector(7 downto 0); end record; type pci_reg_type is record sample : std_ulogic; armed : std_ulogic; sync : std_ulogic; start : std_ulogic; timeout : std_logic_vector(depth-1 downto 0); baddr : std_logic_vector(depth-1 downto 0); count : std_logic_vector(7 downto 0); end record; signal r, rin : reg_type; signal csad, csctrl : std_ulogic; signal pr, prin : pci_reg_type; signal bufout : std_logic_vector(47 downto 0); signal pciad : std_logic_vector(31 downto 0); signal vcc : std_ulogic; signal pcictrlin, pcictrl : std_logic_vector(15 downto 0); begin vcc <= '1'; comb: process(pcii, apbi, rst, r, pr, bufout) variable v : reg_type; variable rdata : std_logic_vector(31 downto 0); variable paddr : std_logic_vector(3 downto 0); variable vcsad, vcssig : std_ulogic; begin v := r; vcsad := '0'; vcssig := '0'; rdata := (others => '0'); v.sample := r.armed and not pr.armed; v.busy := pr.sample; if (r.sample and pr.armed) = '1' then v.armed := '0'; end if; --registers paddr := apbi.paddr(15) & apbi.paddr(4 downto 2); if apbi.penable = '1' then if (apbi.pwrite and apbi.psel(pindex)) = '1' then case paddr is when "0000" => v.admask := apbi.pwdata; when "0001" => v.sigmask := apbi.pwdata(15 downto 0); when "0010" => v.adpattern := apbi.pwdata; when "0011" => v.sigpattern := apbi.pwdata(15 downto 0); when "0100" => v.timeout := apbi.pwdata(depth-1 downto 0); when "0101" => v.armed := '1'; when "0111" => v.count := apbi.pwdata(7 downto 0); when others => if apbi.paddr(15 downto 14) = "10" then vcsad := '1'; elsif apbi.paddr(15 downto 14) = "11" then vcssig := '1'; end if; end case; end if; case paddr is when "0000" => rdata := r.admask; when "0001" => rdata(15 downto 0) := r.sigmask; when "0010" => rdata := r.adpattern; when "0011" => rdata(15 downto 0) := r.sigpattern; when "0100" => rdata(depth-1 downto 0) := r.timeout; when "0101" => rdata(0) := r.busy; when "0110" => rdata(3 downto 0) := conv_std_logic_vector(depth, 4); when "0111" => rdata(depth-1+16 downto 16) := pr.baddr; rdata(15 downto 0) := pr.count & r.count; when others => if apbi.paddr(15 downto 14) = "10" then vcsad := '1'; rdata := bufout(31 downto 0); elsif apbi.paddr(15 downto 14) = "11" then vcssig := '1'; rdata(15 downto 0) := bufout(47 downto 32); end if; end case; end if; if rst = '0' then v.sample := '0'; v.armed := '0'; v.admask := (others => '0'); v.sigmask := (others => '0'); v.adpattern := (others => '0'); v.sigpattern := (others => '0'); v.timeout := (others => '0'); end if; csad <= vcsad; csctrl <= vcssig; apbo.prdata <= rdata; rin <= v; end process; comb2 : process(r, pr, pciclk, pcii, pcictrl, rst) variable v : pci_reg_type; constant z : std_logic_vector(47 downto 0) := (others => '0'); begin v := pr; v.sync := (r.sample and not pr.armed); if (pr.sample = '1') then v.baddr := pr.baddr + 1; if ((((pcii.ad & pcictrl) xor (r.adpattern & r.sigpattern)) and (r.admask & r.sigmask)) = z) then if pr.count = "00000000" then v.start := '0'; else v.count := pr.count -1; end if; end if; if (pr.start = '0') then v.timeout := pr.timeout - 1; if (v.timeout(depth-1) and not pr.timeout(depth-1)) = '1' then v.sample := '0'; v.armed := '0'; end if; end if; end if; if pr.sync = '1' then v.start := '1'; v.sample := '1'; v.armed := '1'; v.timeout := r.timeout; v.count := r.count; end if; if rst = '0' then v.sample := '0'; v.armed := '0'; v.start := '0'; v.timeout := (others => '0'); v.baddr := (others => '0'); v.count := (others => '0'); end if; prin <= v; end process ; pcictrlin <= pcii.rst & pcii.idsel & pcii.frame & pcii.trdy & pcii.irdy & pcii.devsel & pcii.gnt & pcii.stop & pcii.lock & pcii.perr & pcii.serr & pcii.par & pcii.cbe; apbo.pconfig <= pconfig; apbo.pindex <= pindex; apbo.pirq <= (others => '0'); seq: process (clk) begin if clk'event and clk = '1' then r <= rin; end if; end process seq; pseq: process (pciclk) begin if pciclk'event and pciclk = '1' then pr <= prin; end if; end process ; ir : if iregs = 1 generate pseq: process (pciclk) begin if pciclk'event and pciclk = '1' then pcictrl <= pcictrlin; pciad <= pcii.ad; end if; end process ; end generate; noir : if iregs = 0 generate pcictrl <= pcictrlin; pciad <= pcii.ad; end generate; admem : syncram_2p generic map (tech => memtech, abits => depth, dbits => 32, sepclk => 1) port map (clk, csad, apbi.paddr(depth+1 downto 2), bufout(31 downto 0), pciclk, pr.sample, pr.baddr, pciad); ctrlmem : syncram_2p generic map (tech => memtech, abits => depth, dbits => 16, sepclk => 1) port map (clk, csctrl, apbi.paddr(depth+1 downto 2), bufout(47 downto 32), pciclk, pr.sample, pr.baddr, pcictrl); end;	gpl-2.0	7ae560b08ee462505ecd501da85a4bba	0.57776	3.335927	false	false	false	false
marco-c/leon-nexys2	grlib-gpl-1.3.4-b4140/lib/esa/memoryctrl/memoryctrl.vhd	1	2,669	------------------------------------------------------------------------------ -- This file is a part of the GRLIB VHDL IP LIBRARY -- Copyright (C) 2003 - 2008, Gaisler Research -- Copyright (C) 2008 - 2013, Aeroflex Gaisler -- -- This program is free software; you can redistribute it and/or modify -- it under the terms of the GNU General Public License as published by -- the Free Software Foundation; either version 2 of the License, or -- (at your option) any later version. -- -- This program is distributed in the hope that it will be useful, -- but WITHOUT ANY WARRANTY; without even the implied warranty of -- MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the -- GNU General Public License for more details. -- -- You should have received a copy of the GNU General Public License -- along with this program; if not, write to the Free Software -- Foundation, Inc., 59 Temple Place, Suite 330, Boston, MA 02111-1307 USA ------------------------------------------------------------------------------ -- Entity: memctrl -- File: memctrl.vhd -- Author: Jiri Gaisler - Gaisler Research -- Description: Memory controller package ------------------------------------------------------------------------------ library ieee; use ieee.std_logic_1164.all; library grlib; use grlib.amba.all; library gaisler; use gaisler.memctrl.all; package memoryctrl is component mctrl generic ( hindex : integer := 0; pindex : integer := 0; romaddr : integer := 16#000#; rommask : integer := 16#E00#; ioaddr : integer := 16#200#; iomask : integer := 16#E00#; ramaddr : integer := 16#400#; rammask : integer := 16#C00#; paddr : integer := 0; pmask : integer := 16#fff#; wprot : integer := 0; invclk : integer := 0; fast : integer := 0; romasel : integer := 28; sdrasel : integer := 29; srbanks : integer := 4; ram8 : integer := 0; ram16 : integer := 0; sden : integer := 0; sepbus : integer := 0; sdbits : integer := 32; sdlsb : integer := 2; oepol : integer := 0; syncrst : integer := 0; pageburst : integer := 0; scantest : integer := 0; mobile : integer := 0 ); port ( rst : in std_ulogic; clk : in std_ulogic; memi : in memory_in_type; memo : out memory_out_type; ahbsi : in ahb_slv_in_type; ahbso : out ahb_slv_out_type; apbi : in apb_slv_in_type; apbo : out apb_slv_out_type; wpo : in wprot_out_type; sdo : out sdram_out_type ); end component; end;	gpl-2.0	65e3d6fcbdf13c82464e1995c4dea5ae	0.553391	3.936578	false	false	false	false
marco-c/leon-nexys2	grlib-gpl-1.3.4-b4140/lib/gaisler/leon3v3/mmu_dcache.vhd	1	66,774	------------------------------------------------------------------------------ -- This file is a part of the GRLIB VHDL IP LIBRARY -- Copyright (C) 2003 - 2008, Gaisler Research -- Copyright (C) 2008 - 2013, Aeroflex Gaisler -- -- This program is free software; you can redistribute it and/or modify -- it under the terms of the GNU General Public License as published by -- the Free Software Foundation; either version 2 of the License, or -- (at your option) any later version. -- -- This program is distributed in the hope that it will be useful, -- but WITHOUT ANY WARRANTY; without even the implied warranty of -- MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the -- GNU General Public License for more details. -- -- You should have received a copy of the GNU General Public License -- along with this program; if not, write to the Free Software -- Foundation, Inc., 59 Temple Place, Suite 330, Boston, MA 02111-1307 USA ----------------------------------------------------------------------------- -- Entity: mmu_dcache -- File: mmu_dcache.vhd -- Author: Jiri Gaisler - Gaisler Research -- Modified: Edvin Catovic - Gaisler Research -- Description: This unit implements the data cache controller. ------------------------------------------------------------------------------ library ieee; use ieee.std_logic_1164.all; library techmap; use techmap.gencomp.all; library grlib; use grlib.config_types.all; use grlib.config.all; use grlib.amba.all; use grlib.sparc.all; use grlib.stdlib.all; library gaisler; use gaisler.libiu.all; use gaisler.libcache.all; use gaisler.libmmu.all; use gaisler.mmuconfig.all; use gaisler.mmuiface.all; entity mmu_dcache is generic ( dsu : integer range 0 to 1 := 0; dcen : integer range 0 to 1 := 0; drepl : integer range 0 to 3 := 0; dsets : integer range 1 to 4 := 1; dlinesize : integer range 4 to 8 := 4; dsetsize : integer range 1 to 256 := 1; dsetlock : integer range 0 to 1 := 0; dsnoop : integer range 0 to 6 := 0; dlram : integer range 0 to 1 := 0; dlramsize : integer range 1 to 512 := 1; dlramstart : integer range 0 to 255 := 16#8f#; ilram : integer range 0 to 1 := 0; ilramstart : integer range 0 to 255 := 16#8e#; itlbnum : integer range 2 to 64 := 8; dtlbnum : integer range 2 to 64 := 8; tlb_type : integer range 0 to 3 := 1; memtech : integer range 0 to NTECH := 0; cached : integer := 0; mmupgsz : integer range 0 to 5 := 0; smp : integer := 0; mmuen : integer := 0); port ( rst : in std_ulogic; clk : in std_ulogic; dci : in dcache_in_type; dco : out dcache_out_type; ico : in icache_out_type; mcdi : out memory_dc_in_type; mcdo : in memory_dc_out_type; ahbsi : in ahb_slv_in_type; dcrami : out dcram_in_type; dcramo : in dcram_out_type; fpuholdn : in std_ulogic; mmudci : out mmudc_in_type; mmudco : in mmudc_out_type; sclk : in std_ulogic; ahbso : in ahb_slv_out_vector ); end; architecture rtl of mmu_dcache is constant M_EN : boolean := (mmuen = 1); constant DSNOOP2 : integer := dsnoop mod 4; constant DSNOOPSEP : boolean := (dsnoop > 3); constant M_TLB_TYPE : integer range 0 to 1 := -- either split or combined conv_integer(conv_std_logic_vector(tlb_type, 2) and conv_std_logic_vector(1, 2)); constant M_TLB_FASTWRITE : integer range 0 to 3 := -- fast writebuffer conv_integer(conv_std_logic_vector(tlb_type, 2) and conv_std_logic_vector(2, 2)); constant M_ENT_I : integer range 2 to 64 := itlbnum; -- icache tlb entries: number constant M_ENT_ILOG : integer := log2(M_ENT_I); -- icache tlb entries: address bits constant M_ENT_D : integer range 2 to 64 := dtlbnum; -- dcache tlb entries: number constant M_ENT_DLOG : integer := log2(M_ENT_D); -- dcache tlb entries: address bits constant M_ENT_C : integer range 2 to 64 := M_ENT_I; -- i/dcache tlb entries: number constant M_ENT_CLOG : integer := M_ENT_ILOG; -- i/dcache tlb entries: address bits constant DLINE_BITS : integer := log2(dlinesize); constant DOFFSET_BITS : integer := 8 +log2(dsetsize) - DLINE_BITS; constant LRR_BIT : integer := TAG_HIGH + 1; constant TAG_LOW : integer := DOFFSET_BITS + DLINE_BITS + 2; constant OFFSET_HIGH : integer := TAG_LOW - 1; constant OFFSET_LOW : integer := DLINE_BITS + 2; constant LINE_HIGH : integer := OFFSET_LOW - 1; constant LINE_LOW : integer := 2; constant LINE_ZERO : std_logic_vector(DLINE_BITS-1 downto 0) := (others => '0'); constant SETBITS : integer := log2x(DSETS); constant DLRUBITS : integer := lru_table(DSETS); constant LOCAL_RAM_START : std_logic_vector(7 downto 0) := conv_std_logic_vector(dlramstart, 8); constant ILRAM_START : std_logic_vector(7 downto 0) := conv_std_logic_vector(ilramstart, 8); constant DIR_BITS : integer := log2x(DSETS); constant bend : std_logic_vector(4 downto 2) := "101"; type rdatatype is (dtag, ddata, dddata, dctx, icache, memory, sysr , misc, mmusnoop_dtag); -- sources during cache read type vmasktype is (clearone, clearall, merge, tnew); -- valid bits operation type valid_type is array (0 to DSETS-1) of std_logic_vector(dlinesize - 1 downto 0); type write_buffer_type is record -- write buffer addr, data1, data2 : std_logic_vector(31 downto 0); size : std_logic_vector(1 downto 0); asi : std_logic_vector(3 downto 0); read : std_ulogic; lock : std_ulogic; smask : std_logic_vector(DSETS-1 downto 0);-- snoop mask end record; type dstatetype is (idle, wread, rtrans, wwrite, wtrans, wflush, asi_idtag, dblwrite, loadpend); type dcache_control_type is record -- all registers read : std_ulogic; -- access direction size : std_logic_vector(1 downto 0); -- access size req, burst, rburst, holdn, nomds, stpend : std_ulogic; xaddress : std_logic_vector(31 downto 0); -- common address buffer paddress : std_logic_vector(31 downto 0); -- physical address buffer faddr : std_logic_vector(DOFFSET_BITS - 1 downto 0); -- flush address efaddr : std_logic_vector(DOFFSET_BITS - 1 downto 0); -- error flush address dstate : dstatetype; -- FSM vector hit, valid : std_ulogic; flush : std_ulogic; -- flush in progress flush2 : std_ulogic; -- flush in progress mexc : std_ulogic; -- latched mexc bmexc : std_ulogic; -- latched mexc from burst read wb : write_buffer_type; -- write buffer asi : std_logic_vector(4 downto 0); icenable : std_ulogic; -- icache diag access rndcnt : std_logic_vector(log2x(DSETS)-1 downto 0); -- replace counter setrepl : std_logic_vector(log2x(DSETS)-1 downto 0); -- set to replace lrr : std_ulogic; dsuset : std_logic_vector(log2x(DSETS)-1 downto 0); lock : std_ulogic; lramrd : std_ulogic; ilramen : std_ulogic; cctrl : cctrltype; cctrlwr : std_ulogic; flushl2 : std_ulogic; tadj, dadj, sadj : std_logic_vector(1 downto 0); mmctrl1 : mmctrl_type1; mmctrl1wr : std_ulogic; pflush : std_logic; pflushr : std_logic; pflushaddr : std_logic_vector(VA_I_U downto VA_I_D); pflushtyp : std_logic; vaddr : std_logic_vector(31 downto 0); ready : std_logic; wbinit : std_logic; cache : std_logic; dlock : std_logic; su : std_logic; trans_op : std_logic; flush_op : std_logic; diag_op : std_logic; reqst : std_logic; set : integer range 0 to DSETS-1; noflush : std_logic; end record; type snoop_reg_type is record -- snoop control registers snoop : std_ulogic; -- snoop access to tags addr : std_logic_vector(TAG_HIGH downto OFFSET_LOW);-- snoop tag address mask : std_logic_vector(DSETS-1 downto 0);-- snoop mask snhit : std_logic_vector(0 to MAXSETS-1); end record; subtype lru_type is std_logic_vector(DLRUBITS-1 downto 0); type lru_array is array (0 to 2**DOFFSET_BITS-1) of lru_type; -- lru registers type lru_reg_type is record write : std_ulogic; waddr : std_logic_vector(DOFFSET_BITS-1 downto 0); set : std_logic_vector(SETBITS-1 downto 0); lru : lru_array; end record; subtype lock_type is std_logic_vector(0 to DSETS-1); function lru_set (lru : lru_type; lock : lock_type) return std_logic_vector is variable xlru : std_logic_vector(4 downto 0); variable set : std_logic_vector(SETBITS-1 downto 0); variable xset : std_logic_vector(1 downto 0); variable unlocked : integer range 0 to DSETS-1; begin set := (others => '0'); xlru := (others => '0'); xset := (others => '0'); xlru(DLRUBITS-1 downto 0) := lru; if dsetlock = 1 then unlocked := DSETS-1; for i in DSETS-1 downto 0 loop if lock(i) = '0' then unlocked := i; end if; end loop; end if; case DSETS is when 2 => if dsetlock = 1 then if lock(0) = '1' then xset(0) := '1'; else xset(0) := xlru(0); end if; else xset(0) := xlru(0); end if; when 3 => if dsetlock = 1 then xset := conv_std_logic_vector(lru3_repl_table(conv_integer(xlru)) (unlocked), 2); else -- xset := conv_std_logic_vector(lru3_repl_table(conv_integer(xlru)) (0), 2); xset := xlru(2) & (xlru(1) and not xlru(2)); end if; when 4 => if dsetlock = 1 then xset := conv_std_logic_vector(lru4_repl_table(conv_integer(xlru)) (unlocked), 2); else -- xset := conv_std_logic_vector(lru4_repl_table(conv_integer(xlru)) (0), 2); xset := xlru(4 downto 3); end if; when others => end case; set := xset(SETBITS-1 downto 0); return(set); end; function lru_calc (lru : lru_type; xset : std_logic_vector) return lru_type is variable new_lru : lru_type; variable xnew_lru: std_logic_vector(4 downto 0); variable xlru : std_logic_vector(4 downto 0); variable vset: std_logic_vector(SETBITS-1 downto 0); variable set: integer; begin vset := xset; set := conv_integer(vset); new_lru := (others => '0'); xnew_lru := (others => '0'); xlru := (others => '0'); xlru(DLRUBITS-1 downto 0) := lru; case DSETS is when 2 => if set = 0 then xnew_lru(0) := '1'; else xnew_lru(0) := '0'; end if; when 3 => xnew_lru(2 downto 0) := lru_3set_table(conv_integer(lru))(set); when 4 => xnew_lru(4 downto 0) := lru_4set_table(conv_integer(lru))(set); xnew_lru(SETBITS-1 downto 0) := vset; when others => end case; new_lru := xnew_lru(DLRUBITS-1 downto 0); return(new_lru); end; subtype word is std_logic_vector(31 downto 0); constant write_buffer_none : write_buffer_type := ( addr => (others => '0'), data1 => (others => '0'), data2 => (others => '0'), size => (others => '0'), asi => (others => '0'), read => '0', lock => '0', smask => (others => '0') ); constant RESET_ALL : boolean := GRLIB_CONFIG_ARRAY(grlib_sync_reset_enable_all) = 1; constant RRES : dcache_control_type := ( read => '0', size => (others => '0'), req => '0', burst => '0', rburst => '0', holdn => '1', nomds => '0', stpend => '0', xaddress => (others => '0'), paddress => (others => '0'), faddr => (others => '0'), efaddr => (others => '0'), dstate => idle, hit => '0', valid => '0', flush => '0', flush2 => '1', mexc => '0', bmexc => '0', wb => write_buffer_none, asi => (others => '0'), icenable => '0', rndcnt => (others => '0'), setrepl => (others => '0'), lrr => '0', dsuset => (others => '0'), lock => '0', lramrd => '0', ilramen => '0', cctrl => cctrl_none, cctrlwr => '0', flushl2 => '0', tadj => (others => '0'), dadj => (others => '0'), sadj => (others => '0'), mmctrl1 => mmctrl_type1_none, mmctrl1wr => '0', pflush => '0', pflushr => '0', pflushaddr => (others => '0'), pflushtyp => '0', vaddr => (others => '0'), ready => '0', wbinit => '0', cache => '0', dlock => '0', su => '0', trans_op => '0', flush_op => '0', diag_op => '0', reqst => '0', set => 0, noflush => '0' ); constant SRES : snoop_reg_type := ( snoop => '0', addr => (others => '0'), mask => (others => '0'), snhit => (others => '0') ); constant LRES : lru_reg_type := ( write => '0', waddr => (others => '0'), set => (others => '0'), lru => (others => (others => '0')) ); signal r, c : dcache_control_type; -- r is registers, c is combinational signal rs, cs : snoop_reg_type; -- rs is registers, cs is combinational signal rl, cl : lru_reg_type; -- rl is registers, cl is combinational constant ctbl : std_logic_vector(15 downto 0) := conv_std_logic_vector(cached, 16); begin dctrl : process(rst, r, rs, rl, dci, mcdo, ico, dcramo, ahbsi, fpuholdn, mmudco, ahbso) variable dcramov : dcram_out_type; variable rdatasel : rdatatype; variable maddress : std_logic_vector(31 downto 0); variable maddrlow : std_logic_vector(1 downto 0); variable edata : std_logic_vector(31 downto 0); variable size : std_logic_vector(1 downto 0); variable read : std_ulogic; variable twrite, tpwrite, tdiagwrite, ddiagwrite, dwrite : std_ulogic; variable taddr : std_logic_vector(OFFSET_HIGH downto LINE_LOW); -- tag address variable newtag : std_logic_vector(TAG_HIGH downto TAG_LOW); -- new tag variable newptag : std_logic_vector(TAG_HIGH downto TAG_LOW); -- new tag variable align_data : std_logic_vector(31 downto 0); -- aligned data variable ddatainv, rdatav, align_datav : cdatatype; variable rdata : std_logic_vector(31 downto 0); variable vmask : valid_type; --std_logic_vector((dlinesize -1) downto 0); variable enable, senable, scanen : std_logic_vector(0 to 3); variable mds : std_ulogic; variable mexc : std_ulogic; variable hit, valid, forcemiss : std_ulogic; variable flush : std_ulogic; variable iflush : std_ulogic; variable v : dcache_control_type; variable eholdn : std_ulogic; -- external hold variable snoopwe : std_ulogic; variable hcache : std_ulogic; variable lramcs, lramen, lramrd, lramwr, ilramen : std_ulogic; variable snoopaddr : std_logic_vector(OFFSET_HIGH downto OFFSET_LOW); variable flushaddr : std_logic_vector(OFFSET_HIGH downto OFFSET_LOW); variable vs : snoop_reg_type; variable dsudata : std_logic_vector(31 downto 0); variable set, eset : integer range 0 to DSETS-1; variable ddset : integer range 0 to MAXSETS-1; variable snoopset : integer range 0 to DSETS-1; variable validraw : std_logic_vector(0 to DSETS-1); variable validv, hitv : std_logic_vector(0 to MAXSETS-1); variable csnoopwe, snhit : std_logic_vector(0 to MAXSETS-1); variable ctwrite, ctpwrite, cdwrite : std_logic_vector(0 to MAXSETS-1); variable setrepl : std_logic_vector(log2x(DSETS)-1 downto 0); variable lrusetval: std_logic_vector(SETBITS-1 downto 0); variable wlrr : std_logic_vector(0 to 3); variable vl : lru_reg_type; variable diagset : std_logic_vector(TAG_LOW + SETBITS -1 downto TAG_LOW); variable lock : std_logic_vector(0 to DSETS-1); variable wlock : std_logic_vector(0 to MAXSETS-1); variable laddr : std_logic_vector(31 downto 0); -- local ram addr variable tag : cdatatype; --std_logic_vector(31 downto 0); variable ptag : cdatatype; --std_logic_vector(31 downto 0); variable rlramrd : std_ulogic; variable cache : std_ulogic; variable ctx : ctxdatatype; variable flushl : std_ulogic; variable miscdata : std_logic_vector(31 downto 0); variable pflush : std_logic; variable pflushaddr : std_logic_vector(VA_I_U downto VA_I_D); variable pflushtyp : std_logic; variable pftag : std_logic_vector(31 downto 2); variable mmudci_fsread, tagclear : std_logic; variable mmudci_trans_op : std_logic; variable mmudci_flush_op : std_logic; variable mmudci_wb_op : std_logic; variable mmudci_diag_op : std_logic; variable mmudci_su : std_logic; variable mmudci_read : std_logic; variable su : std_logic; variable mmuisdis : std_logic; variable mmudci_transdata_data : std_logic_vector(31 downto 0); variable paddress : std_logic_vector(31 downto 0); -- physical address buffer variable pagesize : integer range 0 to 3; begin -- init local variables v := r; vs := rs; dcramov := dcramo; vl := rl; vl.write := '0'; lramen := '0'; lramrd := '0'; lramwr := '0'; lramcs := '0'; laddr := (others => '0'); v.cctrlwr := '0'; ilramen := '0'; v.flush2 := r.flush; snhit := (others => '0'); pagesize := MMU_getpagesize(mmupgsz,r.mmctrl1); if ((dci.eenaddr or dci.enaddr) = '1') or (r.dstate /= idle) or ((dsu = 1) and (dci.dsuen = '1')) or (r.flush = '1') or (is_fpga(memtech) = 1) then enable := (others => '1'); else enable := (others => '0'); end if; v.mmctrl1wr := '0'; tagclear := '0'; mmuisdis := '0'; if (not M_EN) or ((r.asi(4 downto 0) = ASI_MMU_BP) or (r.mmctrl1.e = '0')) then mmuisdis := '1'; end if; if (mmuisdis = '1') then paddress := r.xaddress; else paddress := r.paddress; end if; mds := '1'; dwrite := '0'; twrite := '0'; tpwrite := '0'; ddiagwrite := '0'; tdiagwrite := '0'; v.holdn := '1'; mexc := '0'; flush := '0'; v.icenable := '0'; iflush := '0'; eholdn := ico.hold and fpuholdn; ddset := 0; vs.snoop := '0'; snoopwe := '0'; snoopaddr := ahbsi.haddr(OFFSET_HIGH downto OFFSET_LOW); flushaddr := r.xaddress(OFFSET_HIGH downto OFFSET_LOW); hcache := '0'; validv := (others => '0'); hitv := (others => '0'); cache := '0'; if (dlram = 1) then rlramrd := r.lramrd; else rlramrd := '0'; end if; miscdata := (others => '0'); pflush := '0'; pflushaddr := dci.maddress(VA_I_U downto VA_I_D); pflushtyp := PFLUSH_PAGE; pftag := (others => '0'); ctx := (others => (others => '0')); mmudci_fsread := '0'; ddatainv := (others => (others => '0')); tag := (others => (others => '0')); ptag := (others => (others => '0')); v.flushl2 := dci.flushl and not r.flush; newptag := (others => '0'); v.trans_op := r.trans_op and (not mmudco.grant); v.flush_op := r.flush_op and (not mmudco.grant); v.diag_op := r.diag_op and (not mmudco.grant); mmudci_trans_op := r.trans_op; mmudci_flush_op := r.flush_op; mmudci_diag_op := r.diag_op; mmudci_wb_op := '0'; mmudci_transdata_data := r.vaddr; mmudci_su := '0'; mmudci_read := '0'; su := '0'; rdatasel := ddata; -- read data from cache as default senable := (others => '0'); scanen := (others => mcdo.scanen); set := 0; snoopset := 0; csnoopwe := (others => '0'); ctwrite := (others => '0'); ctpwrite := (others => '0'); cdwrite := (others => '0'); wlock := (others => '0'); for i in 0 to DSETS-1 loop wlock(i) := dcramov.tag(i)(CTAG_LOCKPOS); end loop; wlrr := (others => '0'); for i in 0 to 3 loop wlrr(i) := dcramov.tag(i)(CTAG_LRRPOS); end loop; if (DSETS > 1) then setrepl := r.setrepl; else setrepl := (others => '0'); end if; -- random replacement counter if DSETS > 1 then if conv_integer(r.rndcnt) = (DSETS - 1) then v.rndcnt := (others => '0'); else v.rndcnt := r.rndcnt + 1; end if; end if; -- generate lock bits lock := (others => '0'); if dsetlock = 1 then for i in 0 to DSETS-1 loop lock(i) := dcramov.tag(i)(CTAG_LOCKPOS); end loop; end if; -- AHB snoop handling if (DSNOOP2 /= 0) then -- snoop on NONSEQ or SEQ and first word in cache line -- do not snoop during own transfers or during cache flush if (ahbsi.hready and ahbsi.hwrite and (not mcdo.bg or r.mmctrl1.e)) = '1' and ((ahbsi.htrans = HTRANS_NONSEQ) or ((ahbsi.htrans = HTRANS_SEQ) and (ahbsi.haddr(LINE_HIGH downto LINE_LOW) = LINE_ZERO))) then vs.snoop := r.cctrl.dsnoop; vs.addr := ahbsi.haddr(TAG_HIGH downto OFFSET_LOW); if (r.mmctrl1.e = '1') and (mcdo.bg = '1') then vs.mask := r.wb.smask; else vs.mask := (others => '1'); end if; end if; if DSNOOP /= 0 then for i in 0 to DSETS-1 loop senable(i) := vs.snoop or rs.snoop; end loop; end if; for i in DSETS-1 downto 0 loop if ((rs.snoop and not (r.flush or r.flush2)) = '1') then if (DSNOOP2 /= 0) and (rs.mask(i) = '1') and ((dcramov.stag(i)(TAG_HIGH downto TAG_LOW) = rs.addr(TAG_HIGH downto TAG_LOW)) ) then if DSNOOPSEP then flushaddr := rs.addr(OFFSET_HIGH downto OFFSET_LOW); else snoopaddr := rs.addr(OFFSET_HIGH downto OFFSET_LOW); end if; snoopwe := '1'; snoopset := i; snhit(i) := '1'; end if; end if; end loop; end if; vs.snhit := snhit; -- not needed, debug only -- generate access parameters during pipeline stall if ((r.holdn) = '0') or ((dsu = 1) and (dci.dsuen = '1')) then taddr := r.xaddress(OFFSET_HIGH downto LINE_LOW); elsif ((dci.enaddr and not dci.read) = '1') or (eholdn = '0') then taddr := dci.maddress(OFFSET_HIGH downto LINE_LOW); else taddr := dci.eaddress(OFFSET_HIGH downto LINE_LOW); end if; if (dci.write or not r.holdn) = '1' then maddress := r.xaddress(31 downto 0); read := r.read; size := r.size; edata := dci.maddress; mmudci_su := r.su; mmudci_read := r.read and not r.dlock; else maddress := dci.maddress(31 downto 0); read := dci.read; size := dci.size; edata := dci.edata; mmudci_su := dci.msu; mmudci_read := dci.read and not dci.lock; end if; newtag := dci.maddress(TAG_HIGH downto TAG_LOW); newptag := dci.maddress(TAG_HIGH downto TAG_LOW); vl.waddr := maddress(OFFSET_HIGH downto OFFSET_LOW); -- lru write address if (dsnoop = 6) and (r.cctrl.dsnoop = '0') then snoopaddr := taddr(OFFSET_HIGH downto OFFSET_LOW); senable := enable; end if; lrusetval := lru_set(rl.lru(conv_integer(maddress(OFFSET_HIGH downto OFFSET_LOW))), lock(0 to DSETS-1)); -- generate cache hit and valid bits if (r.mmctrl1.e = '0') then hcache := ahb_slv_dec_cache(dci.maddress, ahbso, cached); else hcache := '1'; end if; forcemiss := (not dci.asi(3)) or dci.lock; if (M_EN and (dci.asi(4 downto 0) = ASI_MMU_BP)) or (r.cctrl.dcs(0) = '0') or ((r.flush or r.flush2) = '1') then hcache := '0'; end if; hit := '0'; set := 0; for i in DSETS-1 downto 0 loop if (dcramov.tag(i)(TAG_HIGH downto TAG_LOW) = dci.maddress(TAG_HIGH downto TAG_LOW)) and ((dcramov.ctx(i) = r.mmctrl1.ctx) or (r.mmctrl1.e = '0')) then hitv(i) := '1'; end if; validv(i) := hcache and hitv(i) and (not r.flush) and (not r.flush2) and dcramov.tag(i)(dlinesize-1); validraw(i) := dcramov.tag(i)(dlinesize-1); end loop; if drepl = dir then hit := hitv(conv_integer(dci.maddress(OFFSET_HIGH+DIR_BITS downto OFFSET_HIGH+1))) and not r.flush and (not r.flush2); valid := validv(conv_integer(dci.maddress(OFFSET_HIGH+DIR_BITS downto OFFSET_HIGH+1))); else hit := orv(hitv) and not r.flush and (not r.flush2); valid := orv(validv); end if; -- force cache miss if mmu-enabled but off or BYPASS, or on flush if ((M_EN) and (dci.asi(4 downto 0) = ASI_MMU_BP)) or (r.cctrl.dcs(0) = '0') or ((r.flush or r.flush2) = '1') then hit := '0'; end if; if DSETS > 1 then if drepl = dir then set := conv_integer(dci.maddress(OFFSET_HIGH+DIR_BITS downto OFFSET_HIGH+1)); else for i in DSETS-1 downto 0 loop if (hitv(i) = '1') then set := i; end if; end loop; end if; if rlramrd = '1' then set := 1; end if; else set := 0; end if; if (dci.dsuen = '1') then diagset := r.xaddress(TAG_LOW+SETBITS-1 downto TAG_LOW); else diagset := maddress(TAG_LOW + SETBITS - 1 downto TAG_LOW); end if; case DSETS is when 1 => ddset := 0; when 3 => if conv_integer(diagset) < 3 then ddset := conv_integer(diagset); end if; when others => ddset := conv_integer(diagset); end case; if ((r.holdn and dci.enaddr) = '1') and (r.dstate = idle) then v.hit := hit; v.xaddress := dci.maddress; v.read := dci.read; v.size := dci.size; v.asi := dci.asi(4 downto 0); v.su := dci.msu; v.set := set; v.valid := valid; v.dlock := dci.lock; end if; -- Store buffer if mcdo.ready = '1' then v.wb.addr(LINE_HIGH downto 2) := r.wb.addr(LINE_HIGH downto 2) + 1; if r.stpend = '1' then v.stpend := r.req; v.wb.data1 := r.wb.data2; v.wb.lock := r.wb.lock and r.req; end if; end if; if mcdo.grant = '1' then v.req := r.burst; v.burst := '0'; end if; if (mcdo.grant and not r.wb.read and r.req) = '1' then v.wb.lock := '0'; end if; if (dlram = 1) then if ((r.holdn) = '0') or ((dsu = 1) and (dci.dsuen = '1')) then laddr := r.xaddress; elsif ((dci.enaddr and not dci.read) = '1') or (eholdn = '0') then laddr := dci.maddress; else laddr := dci.eaddress; end if; if (dci.enaddr = '1') and (dci.maddress(31 downto 24) = LOCAL_RAM_START) then lramen := '1'; end if; if ((laddr(31 downto 24) = LOCAL_RAM_START)) or ((dci.dsuen = '1') and (dci.asi(4 downto 1) = "0101")) then lramcs := '1'; end if; end if; if (ilram = 1) then if (dci.enaddr = '1') and (dci.maddress(31 downto 24) = ILRAM_START) then ilramen := '1'; end if; end if; -- cache freeze operation if (r.cctrl.ifrz and dci.intack and r.cctrl.ics(0)) = '1' then v.cctrl.ics := "01"; end if; if (r.cctrl.dfrz and dci.intack and r.cctrl.dcs(0)) = '1' then v.cctrl.dcs := "01"; end if; if (r.cctrlwr and not dci.nullify) = '1' then if (r.xaddress(7 downto 2) = "000000") and (dci.read = '0') then v.noflush := dci.maddress(30); v.cctrl.dsnoop := dci.maddress(23); flush := dci.maddress(22); iflush := dci.maddress(21); v.cctrl.burst:= dci.maddress(16); v.cctrl.dfrz := dci.maddress(5); v.cctrl.ifrz := dci.maddress(4); v.cctrl.dcs := dci.maddress(3 downto 2); v.cctrl.ics := dci.maddress(1 downto 0); end if; if (memtech = rhlib18t) and (r.xaddress(7 downto 2) = "000001") and (dci.read = '0') then v.tadj := dci.maddress(5 downto 4); v.sadj := dci.maddress(3 downto 2); v.dadj := dci.maddress(1 downto 0); end if; end if; -- main Dcache state machine case r.dstate is when idle => -- Idle state if (M_TLB_FASTWRITE /= 0) then mmudci_transdata_data := dci.maddress; end if; v.nomds := r.nomds and not eholdn; v.bmexc := '0'; if ((r.reqst = '0') and (r.stpend = '0')) or ((mcdo.ready and not r.req)= '1') then -- wait for store queue v.wb.addr := dci.maddress; v.wb.size := dci.size; v.wb.read := dci.read; v.wb.data1 := dci.edata; v.wb.lock := dci.lock and not dci.nullify and ico.hold; v.wb.asi := dci.asi(3 downto 0); if ((M_EN) and (dci.asi(4 downto 0) /= ASI_MMU_BP) and (r.mmctrl1.e = '1') and ((M_TLB_FASTWRITE /= 0) or ((dci.enaddr and eholdn and dci.lock and not dci.read) = '1'))) then if (dci.enaddr and eholdn and dci.lock and not dci.read) = '1' then -- skip address translation on store in LDST v.wb.addr := r.wb.addr(31 downto 8) & dci.maddress(7 downto 0); newptag := r.wb.addr(TAG_HIGH downto TAG_LOW); else v.wb.addr := mmudco.wbtransdata.data; newptag := mmudco.wbtransdata.data(TAG_HIGH downto TAG_LOW); end if; end if; if (dci.read and hcache) = '1' then v.wb.addr(LINE_HIGH downto 0) := (others => '0'); end if; end if; if (eholdn and (not r.nomds)) = '1' then -- avoid false path through nullify case dci.asi(4 downto 0) is when ASI_SYSR => rdatasel := sysr; when ASI_DTAG => rdatasel := dtag; when ASI_DDATA => rdatasel := dddata; when ASI_DCTX => if M_EN then rdatasel := dctx; end if; when ASI_MMUREGS => if M_EN then rdatasel := misc; end if; when ASI_MMUSNOOP_DTAG => rdatasel := mmusnoop_dtag; when others => end case; end if; if (dci.enaddr and eholdn and (not r.nomds) and not dci.nullify) = '1' then case dci.asi(4 downto 0) is when ASI_SYSR => -- system registers v.cctrlwr := not dci.read and not (dci.dsuen and not dci.eenaddr); when ASI_MMUREGS => if M_EN then if (dsu = 0) or dci.dsuen = '0' then -- clean fault valid bit if dci.read = '1' then case dci.maddress(CNR_U downto CNR_D) is when CNR_F => mmudci_fsread := '1'; when others => null; end case; end if; end if; v.mmctrl1wr := not dci.read and not (r.mmctrl1wr and dci.dsuen); end if; when ASI_ITAG \| ASI_IDATA \| ASI_ICTX => -- Read/write Icache tags -- CTX write has to be done through ctxnr & ASI_ITAG if (ico.flush = '1') or (dci.asi(4) = '1') then mexc := '1'; else v.dstate := asi_idtag; v.holdn := dci.dsuen; end if; when ASI_UINST \| ASI_SINST => if (ilram = 1) then v.dstate := asi_idtag; v.ilramen := '1'; end if; when ASI_DFLUSH => -- flush data cache if dci.read = '0' then flush := '1'; end if; when ASI_DDATA => -- Read/write Dcache data if DSNOOPSEP then flushaddr := taddr(OFFSET_HIGH downto OFFSET_LOW); end if; if (r.flush = '1') then -- No access on flush mexc := '1'; elsif (dci.read = '0') then dwrite := '1'; ddiagwrite := '1'; end if; when ASI_DTAG => -- Read/write Dcache tags if DSNOOPSEP then flushaddr := taddr(OFFSET_HIGH downto OFFSET_LOW); end if; if (dci.size /= "10") or (r.flush = '1') then -- allow only word access mexc := '1'; elsif (dci.read = '0') then twrite := '1'; tdiagwrite := '1'; end if; when ASI_MMUSNOOP_DTAG => -- Read/write MMU physical snoop tags if DSNOOPSEP then snoopaddr := taddr(OFFSET_HIGH downto OFFSET_LOW); if (dci.size /= "10") or (r.flush = '1') then -- allow only word access mexc := '1'; elsif (dci.read = '0') then tpwrite := '1'; tdiagwrite := '1'; end if; end if; when ASI_DCTX => -- write has to be done through ctxnr & ASI_DTAG if DSNOOPSEP then flushaddr := taddr(OFFSET_HIGH downto OFFSET_LOW); end if; if (dci.size /= "10") or (r.flush = '1') or (dci.read = '0') then -- allow only word access mexc := '1'; end if; when ASI_FLUSH_PAGE => -- i/dcache flush page if dci.read = '0' then iflush := '1'; end if; if M_EN then if dci.read = '0' then flush := '1'; --pflush := '1'; pflushtyp := PFLUSH_PAGE; end if; end if; when ASI_FLUSH_CTX => -- i/dcache flush ctx if M_EN then if dci.read = '0' then flush := '1'; iflush := '1'; --pflush := '1'; pflushtyp := PFLUSH_CTX; end if; end if; when ASI_MMUFLUSHPROBE => if M_EN then if dci.read = '0' then -- flush mmudci_flush_op := '1'; v.flush_op := not mmudco.grant; v.dstate := wflush; v.vaddr := dci.maddress; v.holdn := '0'; flush := '1'; iflush := '1'; end if; end if; when ASI_MMU_DIAG => if dci.read = '0' then -- diag access mmudci_diag_op := '1'; v.diag_op := not mmudco.grant; v.vaddr := dci.maddress; end if; when others => if dci.read = '1' then -- read access v.rburst := hcache; -- and not forcemiss; if (dlram = 1) and (lramen = '1') then lramrd := '1'; elsif (ilram = 1) and (ilramen = '1') then if (ico.flush = '1') or (dci.size /= "10") then mexc := '1'; else v.dstate := asi_idtag; v.holdn := dci.dsuen; v.ilramen := '1'; end if; elsif dci.dsuen = '0' then if not ((hit and valid and not forcemiss) = '1') then -- read miss v.holdn := '0'; v.dstate := wread; v.ready := '0'; v.cache := hcache; if (not M_EN) or ((dci.asi(4 downto 0) = ASI_MMU_BP) or (r.mmctrl1.e = '0')) then -- cache disabled if mmu-enabled but off or BYPASS if ((r.stpend = '0') or ((mcdo.ready and not r.req) = '1')) then v.req := '1'; v.burst := v.rburst; end if; else -- ## mmu case > if (r.stpend = '0') or ((mcdo.ready and not r.req)= '1') then v.wbinit := '1'; -- wb init in idle v.burst := v.rburst; else v.wbinit := '0'; end if; mmudci_trans_op := '1'; -- start translation v.trans_op := not mmudco.grant; v.vaddr := dci.maddress; v.dstate := rtrans; -- ## < mmu case end if; else -- read hit if (DSETS > 1) and (drepl = lru) then vl.write := '1'; end if; cache := '1'; end if; end if; else -- write access if (dlram = 1) and (lramen = '1') then lramwr := '1'; if (dci.size = "11") then -- double store v.dstate := dblwrite; v.xaddress(2) := '1'; end if; elsif (ilram = 1) and (ilramen = '1') then if (ico.flush = '1') or (dci.size /= "10") then mexc := '1'; else v.dstate := asi_idtag; v.holdn := dci.dsuen; v.ilramen := '1'; end if; elsif dci.dsuen = '0' then v.ready := '0'; if (not M_EN) or ((dci.asi(4 downto 0) = ASI_MMU_BP) or (r.mmctrl1.e = '0')) then if ((r.stpend = '0') or ((mcdo.ready and not r.req)= '1')) then -- wait for store queue v.reqst := '1'; v.burst := dci.size(1) and dci.size(0); if (dci.size = "11") then v.dstate := dblwrite; end if; -- double store v.wb.smask := (others => '1'); else -- wait for store queue v.dstate := wwrite; v.holdn := '0'; v.wb.read := r.wb.read; end if; else -- ## mmu case > false and if ((r.stpend = '0') or ((mcdo.ready and not r.req)= '1')) and (((mmudco.wbtransdata.accexc = '0') and (M_TLB_FASTWRITE /= 0)) or (dci.lock = '1')) then v.reqst := '1'; v.burst := dci.size(1) and dci.size(0); if (dci.size = "11") then v.dstate := dblwrite; end if; -- double store v.wb.smask := (others => '1'); if hit = '1' then v.wb.smask(set) := '0'; end if; else if (r.stpend = '0') or ((mcdo.ready and not r.req)= '1') then v.wbinit := '1'; -- wb init in idle v.burst := dci.size(1) and dci.size(0); v.wb.smask := (others => '1'); if hit = '1' then v.wb.smask(set) := '0'; end if; else v.wbinit := '0'; end if; mmudci_trans_op := '1'; -- start translation v.trans_op := not mmudco.grant; v.vaddr := dci.maddress; v.holdn := '0'; v.dstate := wtrans; -- ## < mmu case end if; end if; if (hit and valid) = '1' then -- write hit dwrite := '1'; if (DSETS > 1) and (drepl = lru) then vl.write := '1'; end if; setrepl := conv_std_logic_vector(set, SETBITS); if DSNOOP2 /= 0 then if ((dci.enaddr and not dci.read) = '1') or (eholdn = '0') then v.xaddress := dci.maddress; else v.xaddress := dci.eaddress; end if; end if; end if; if (dci.size = "11") then v.xaddress(2) := '1'; end if; end if; end if; eset := set; if (DSETS > 1) then vl.set := conv_std_logic_vector(set, SETBITS); v.setrepl := conv_std_logic_vector(set, SETBITS); if (andv(validraw) = '0') and (drepl /= dir) and false then for i in DSETS-1 downto 0 loop if validraw(i) = '0' then eset := i; end if; end loop; v.setrepl := conv_std_logic_vector(eset, SETBITS); elsif ((not hit) and (not r.flush)) = '1' then case drepl is when rnd => if dsetlock = 1 then if lock(conv_integer(r.rndcnt)) = '0' then v.setrepl := r.rndcnt; else v.setrepl := conv_std_logic_vector(DSETS-1, SETBITS); for i in DSETS-1 downto 0 loop if (lock(i) = '0') and (i>conv_integer(r.rndcnt)) then v.setrepl := conv_std_logic_vector(i, SETBITS); end if; end loop; end if; else v.setrepl := r.rndcnt; end if; when dir => v.setrepl := dci.maddress(OFFSET_HIGH+log2x(DSETS) downto OFFSET_HIGH+1); when lru => v.setrepl := lrusetval; when lrr => v.setrepl := (others => '0'); if dsetlock = 1 then if lock(0) = '1' then v.setrepl(0) := '1'; else v.setrepl(0) := dcramov.tag(0)(CTAG_LRRPOS) xor dcramov.tag(1)(CTAG_LRRPOS); end if; else v.setrepl(0) := dcramov.tag(0)(CTAG_LRRPOS) xor dcramov.tag(1)(CTAG_LRRPOS); end if; if v.setrepl(0) = '0' then v.lrr := not dcramov.tag(0)(CTAG_LRRPOS); else v.lrr := dcramov.tag(0)(CTAG_LRRPOS); end if; end case; end if; if (dsetlock = 1) then if (hit and lock(set)) = '1' then v.lock := '1'; else v.lock := '0'; end if; end if; end if; end case; end if; when rtrans => if M_EN then if r.stpend = '1' then if ((mcdo.ready and not r.req) = '1') then v.ready := '1'; -- buffer store finish end if; end if; v.holdn := '0'; if mmudco.transdata.finish = '1' then -- translation error, i.e. page fault if (mmudco.transdata.accexc) = '1' then v.holdn := '1'; v.dstate := idle; mds := '0'; mexc := not r.mmctrl1.nf; else v.dstate := wread; v.cache := r.cache and mmudco.transdata.cache; v.paddress := mmudco.transdata.data; v.rburst := r.rburst and v.cache; if r.wbinit = '1' then v.wb.addr := v.paddress; --mmudco.transdata.data; v.req := '1'; v.burst := v.rburst; if v.rburst = '1' then v.wb.addr(LINE_HIGH downto 0) := (others => '0'); end if; end if; end if; end if; end if; when wread => -- read miss, wait for memory data if drepl=lru and mcdo.ready='0' and r.hit='0' then v.setrepl := lrusetval; end if; taddr := r.wb.addr(OFFSET_HIGH downto LINE_LOW); newtag := r.xaddress(TAG_HIGH downto TAG_LOW); newptag := paddress(TAG_HIGH downto TAG_LOW); v.nomds := r.nomds and not eholdn; v.holdn := v.nomds; rdatasel := memory; for i in 0 to DSETS-1 loop wlock(i) := r.lock; end loop; for i in 0 to 3 loop wlrr(i) := r.lrr; end loop; if (r.stpend = '0') and (r.ready = '0') then if (r.rburst) = '1' then if (mcdo.grant = '1') and (r.wb.addr(LINE_HIGH downto LINE_LOW) >= bend(LINE_HIGH downto LINE_LOW)) and not ((r.wb.addr(LINE_HIGH downto LINE_LOW) = bend(LINE_HIGH downto LINE_LOW)) and (mcdo.ready = '0')) then v.burst := '0'; else v.burst := r.burst; end if; end if; if mcdo.ready = '1' then if (r.cache or r.hit) = '0' then mds := r.holdn or r.nomds; v.xaddress(2) := '1'; v.holdn := '1'; else if r.wb.addr(LINE_HIGH downto LINE_LOW) = r.xaddress(LINE_HIGH downto LINE_LOW) then mds := '0'; end if; end if; dwrite := r.cache and r.cctrl.dcs(1); rdatasel := memory; mexc := mcdo.mexc; v.bmexc := r.bmexc or mcdo.mexc or dci.flushl; if r.req = '0' then twrite := r.cache and r.cctrl.dcs(1); tagclear := v.bmexc; if (((dci.enaddr and not mds) = '1') or (dci.flushl = '1') or ((dci.enaddr and twrite) = '1')) and ((r.cctrl.dcs(0) = '1') or (dlram = 1)) then v.dstate := loadpend; v.holdn := '0'; else v.dstate := idle; v.holdn := '1'; end if; else v.nomds := not r.cache; end if; tpwrite := twrite; end if; v.mexc := mcdo.mexc and not r.rburst; v.wb.data2 := mcdo.data; else if (r.ready or (mcdo.ready and not r.req)) = '1' then -- wait for store queue v.wb.addr := paddress; v.wb.size := r.size; v.burst := r.rburst; if r.rburst = '1' then v.wb.addr(LINE_HIGH downto 0) := (others => '0'); end if; v.wb.read := r.read; v.wb.data1 := dci.maddress; v.req := '1'; v.wb.lock := dci.lock; v.wb.asi := r.asi(3 downto 0); v.ready := '0'; end if; end if; when loadpend => -- return from read miss with load pending taddr := dci.maddress(OFFSET_HIGH downto LINE_LOW); if (dlram = 1) then laddr := dci.maddress; if laddr(31 downto 24) = LOCAL_RAM_START then lramcs := '1'; end if; end if; if (r.flushl2 and dci.enaddr) = '1' then v.holdn := '0'; else v.dstate := idle; end if; when dblwrite => -- second part of double store cycle edata := dci.edata; -- needed for STD store hit taddr := r.xaddress(OFFSET_HIGH downto LINE_LOW); if (dlram = 1) and (rlramrd = '1') then laddr := r.xaddress; lramwr := '1'; else if r.hit = '1' then dwrite := r.valid; end if; v.wb.data2 := dci.edata; end if; if (dci.flushl and ico.hold) = '1' then v.dstate := loadpend; v.holdn := '0'; elsif ico.hold = '0' then v.reqst := '0'; else v.dstate := idle; end if; when asi_idtag => -- icache diag and inst local ram access rdatasel := icache; v.icenable := '1'; v.holdn := dci.dsuen; if ico.diagrdy = '1' then v.dstate := loadpend; v.icenable := '0'; v.ilramen := '0'; if (dsu = 0) or ((dsu = 1) and (dci.dsuen = '0')) then mds := not r.read; end if; end if; when wtrans => edata := dci.edata; -- needed for STD store hit taddr := r.xaddress(OFFSET_HIGH downto LINE_LOW); newtag := r.xaddress(TAG_HIGH downto TAG_LOW); if M_EN then if r.stpend = '1' then if ((mcdo.ready and not r.req) = '1') then v.ready := '1'; -- buffer store finish end if; end if; v.holdn := '0'; if mmudco.transdata.finish = '1' then if (mmudco.transdata.accexc) = '1' then v.holdn := '1'; v.dstate := idle; mds := '0'; mexc := not r.mmctrl1.nf; tagclear := r.hit; twrite := tagclear; if (twrite = '1') and (((dci.enaddr and not mds) = '1') or ((dci.eenaddr and mds and eholdn) = '1')) and (r.cctrl.dcs(0) = '1') then v.dstate := loadpend; v.holdn := '0'; end if; else v.dstate := wwrite; v.cache := mmudco.transdata.cache; v.paddress := mmudco.transdata.data; if (r.wbinit) = '1' then v.wb.data2 := dci.edata; v.wb.addr := mmudco.transdata.data; v.dstate := idle; v.holdn := '1'; if (dci.nullify = '0') then v.req := '1'; v.stpend := '1'; else v.reqst := '1'; end if; v.burst := r.size(1) and r.size(0) and not v.wb.addr(2); if (r.hit = '1') and (r.size = "11") then -- write hit dwrite := r.valid; end if; end if; end if; end if; end if; when wwrite => -- wait for store buffer to empty (store access) edata := dci.edata; -- needed for STD store hit if ( (dci.lock = '1')) and (dci.nullify = '1') then v.dstate := idle; v.wb.lock := '0'; elsif ((v.ready or (mcdo.ready and not r.req)) = '1') or ( (dci.lock = '1')) then -- store queue emptied if (r.hit = '1') and (r.size = "11") then -- write hit taddr := r.xaddress(OFFSET_HIGH downto LINE_LOW); dwrite := r.valid; end if; v.dstate := idle; v.burst := r.size(1) and r.size(0); if (dci.nullify = '0') then v.reqst := '1'; end if; v.wb.addr := paddress; v.wb.size := r.size; v.wb.read := r.read; v.wb.data1 := dci.maddress; v.wb.lock := dci.lock; v.wb.data2 := dci.edata; v.wb.asi := r.asi(3 downto 0); if r.size = "11" then v.wb.addr(2) := '0'; end if; v.wb.smask := (others => '1'); if r.hit = '1' then v.wb.smask(r.set) := '0'; end if; else -- hold cpu until buffer empty v.holdn := '0'; end if; when wflush => v.holdn := '0'; if mmudco.transdata.finish = '1' then v.dstate := idle; v.holdn := '1'; end if; when others => v.dstate := idle; end case; v.req := v.req or v.reqst; v.stpend := v.stpend or v.reqst; v.reqst := '0'; if (dlram = 1) then v.lramrd := lramcs; end if; -- read local ram data -- select data to return on read access -- align if byte/half word read from cache or memory. if (dsu = 1) and (dci.dsuen = '1') then v.dsuset := conv_std_logic_vector(ddset, SETBITS); case dci.asi(4 downto 0) is when ASI_ITAG \| ASI_IDATA => v.icenable := not ico.diagrdy; rdatasel := icache; when ASI_DTAG => tdiagwrite := not dci.eenaddr and dci.enaddr and dci.write; twrite := not dci.eenaddr and dci.enaddr and dci.write; rdatasel := dtag; when ASI_MMUSNOOP_DTAG => if DSNOOPSEP then snoopaddr := taddr(OFFSET_HIGH downto OFFSET_LOW); end if; tdiagwrite := not dci.eenaddr and dci.enaddr and dci.write; tpwrite := not dci.eenaddr and dci.enaddr and dci.write; rdatasel := mmusnoop_dtag; senable := (others => '1'); when ASI_DDATA => if M_EN then ddiagwrite := not dci.eenaddr and dci.enaddr and dci.write; dwrite := not dci.eenaddr and dci.enaddr and dci.write; rdatasel := dddata; end if; when ASI_UDATA \| ASI_SDATA => lramwr := not dci.eenaddr and dci.enaddr and dci.write; when ASI_MMUREGS => rdatasel := misc; when others => end case; end if; -- read if M_EN then case dci.maddress(CNR_U downto CNR_D) is when CNR_CTRL => miscdata(MMCTRL_E) := r.mmctrl1.e; miscdata(MMCTRL_NF) := r.mmctrl1.nf; miscdata(MMCTRL_PSO) := r.mmctrl1.pso; miscdata(MMCTRL_VER_U downto MMCTRL_VER_D) := "0001"; miscdata(MMCTRL_IMPL_U downto MMCTRL_IMPL_D) := "0000"; miscdata(23 downto 21) := conv_std_logic_vector(M_ENT_ILOG,3); miscdata(20 downto 18) := conv_std_logic_vector(M_ENT_DLOG,3); if M_TLB_TYPE = 0 then miscdata(MMCTRL_TLBSEP) := '1'; else miscdata(23 downto 21) := conv_std_logic_vector(M_ENT_CLOG,3); miscdata(20 downto 18) := (others => '0'); end if; miscdata(MMCTRL_TLBDIS) := r.mmctrl1.tlbdis; miscdata(MMCTRL_PGSZ_U downto MMCTRL_PGSZ_D) := conv_std_logic_vector(pagesize,2); -- r.mmctrl1.pagesize; --custom when CNR_CTXP => miscdata(MMCTXP_U downto MMCTXP_D) := r.mmctrl1.ctxp; when CNR_CTX => miscdata(MMCTXNR_U downto MMCTXNR_D) := r.mmctrl1.ctx; when CNR_F => miscdata(FS_OW) := mmudco.mmctrl2.fs.ow; miscdata(FS_FAV) := mmudco.mmctrl2.fs.fav; miscdata(FS_FT_U downto FS_FT_D) := mmudco.mmctrl2.fs.ft; miscdata(FS_AT_LS) := mmudco.mmctrl2.fs.at_ls; miscdata(FS_AT_ID) := mmudco.mmctrl2.fs.at_id; miscdata(FS_AT_SU) := mmudco.mmctrl2.fs.at_su; miscdata(FS_L_U downto FS_L_D) := mmudco.mmctrl2.fs.l; miscdata(FS_EBE_U downto FS_EBE_D) := mmudco.mmctrl2.fs.ebe; when CNR_FADDR => miscdata(VA_I_U downto VA_I_D) := mmudco.mmctrl2.fa; when others => null; end case; end if; rdata := (others => '0'); rdatav := (others => (others => '0')); align_data := (others => '0'); align_datav := (others => (others => '0')); maddrlow := maddress(1 downto 0); -- stupid Synopsys VSS bug ... case rdatasel is when misc => if M_EN then set := 0; rdatav(0) := miscdata; end if; when dddata => rdatav := dcramov.data; if dci.dsuen = '1' then set := conv_integer(r.dsuset); else set := ddset; end if; when dtag => rdatav := dcramov.tag; if dci.dsuen = '1' then set := conv_integer(r.dsuset); else set := ddset; end if; when mmusnoop_dtag => rdatav := dcramov.stag; if dci.dsuen = '1' then set := conv_integer(r.dsuset); else set := ddset; end if; when dctx => --rdata(M_CTX_SZ-1 downto 0) := dcramov.dtramout(ddset).ctx; when icache => rdatav(0) := ico.diagdata; set := 0; when ddata \| memory => if rdatasel = memory then rdatav(0) := mcdo.data; set := 0; else for i in 0 to DSETS-1 loop rdatav(i) := dcramov.data(i); end loop; end if; when sysr => set := 0; case dci.maddress(3 downto 2) is when "00" => rdatav(0)(30) := r.noflush; rdatav(0)(23) := r.cctrl.dsnoop; if dsnoop > 4 then rdatav(0)(17) := '1'; end if; rdatav(0)(16 downto 14) := r.cctrl.burst & ico.flush & r.flush; rdatav(0)(5 downto 0) := r.cctrl.dfrz & r.cctrl.ifrz & r.cctrl.dcs & r.cctrl.ics; when "01" => rdatav(0)(7 downto 0) := "00" & r.tadj & r.sadj & r.dadj; when "10" => rdatav(0) := ico.cfg; when others => rdatav(0) := cache_cfg(drepl, dsets, dlinesize, dsetsize, dsetlock, dsnoop, dlram, dlramsize, dlramstart, mmuen); end case; end case; -- select which data to update the data cache with for i in 0 to DSETS-1 loop case size is -- merge data during partial write when "00" => case maddrlow is when "00" => ddatainv(i) := edata(7 downto 0) & dcramov.data(i)(23 downto 0); when "01" => ddatainv(i) := dcramov.data(i)(31 downto 24) & edata(7 downto 0) & dcramov.data(i)(15 downto 0); when "10" => ddatainv(i) := dcramov.data(i)(31 downto 16) & edata(7 downto 0) & dcramov.data(i)(7 downto 0); when others => ddatainv(i) := dcramov.data(i)(31 downto 8) & edata(7 downto 0); end case; when "01" => if maddress(1) = '0' then ddatainv(i) := edata(15 downto 0) & dcramov.data(i)(15 downto 0); else ddatainv(i) := dcramov.data(i)(31 downto 16) & edata(15 downto 0); end if; when others => ddatainv(i) := edata; end case; end loop; -- handle double load with pipeline hold if (r.dstate = idle) and (r.nomds = '1') then rdatav(0) := r.wb.data2; mexc := r.mexc; set := 0; end if; -- Handle AHB retry. Re-generate bus request and burst if mcdo.retry = '1' then v.req := '1'; if r.wb.read = '0' then v.burst := r.wb.size(0) and r.wb.size(1) and not r.wb.addr(2); else v.burst := ((r.rburst) and not andv(r.wb.addr(LINE_HIGH downto LINE_LOW))) or (not r.rburst and r.wb.size(0) and r.wb.size(1) and not r.wb.addr(2)); end if; end if; -- Generate new valid bits if r.flush = '1' then twrite := '0'; dwrite := '0'; end if; vmask := (others => (others => '1')); if twrite = '1' then if tagclear = '1' then vmask := (others => (others => '0')); end if; if (DSETS>1) and (drepl = lru) and (tdiagwrite = '0') then vl.write := '1'; vl.set := setrepl; end if; end if; if (DSETS>1) and (drepl = lru) and (rl.write = '1') then vl.lru(conv_integer(rl.waddr)) := lru_calc(rl.lru(conv_integer(rl.waddr)), rl.set); end if; if tdiagwrite = '1' then -- diagnostic tag write if (dsu = 1) and (dci.dsuen = '1') then vmask := (others => dci.maddress(dlinesize - 1 downto 0)); else vmask := (others => dci.edata(dlinesize - 1 downto 0)); newtag(TAG_HIGH downto TAG_LOW) := dci.edata(TAG_HIGH downto TAG_LOW); newptag(TAG_HIGH downto TAG_LOW) := dci.edata(TAG_HIGH downto TAG_LOW); for i in 0 to 3 loop wlrr(i) := dci.edata(CTAG_LRRPOS); end loop; for i in 0 to DSETS-1 loop wlock(i) := dci.edata(CTAG_LOCKPOS); end loop; end if; end if; -- mmureg write if r.mmctrl1wr = '1' then case r.xaddress(CNR_U downto CNR_D) is when CNR_CTRL => v.mmctrl1.e := dci.maddress(MMCTRL_E); v.mmctrl1.nf := dci.maddress(MMCTRL_NF); v.mmctrl1.pso := dci.maddress(MMCTRL_PSO); v.mmctrl1.tlbdis := dci.maddress(MMCTRL_TLBDIS); v.mmctrl1.pagesize := dci.maddress(MMCTRL_PGSZ_U downto MMCTRL_PGSZ_D); --custom -- Note: before tlb disable tlb flush is required !!! when CNR_CTXP => v.mmctrl1.ctxp := dci.maddress(MMCTXP_U downto MMCTXP_D); when CNR_CTX => v.mmctrl1.ctx := dci.maddress(MMCTXNR_U downto MMCTXNR_D); when CNR_F => null; when CNR_FADDR => null; when others => null; end case; end if; -- cache flush if ((dci.flush or dci.flushl or flush) = '1') and (dcen /= 0) then v.flush := not r.noflush; v.faddr := (others => '0'); if (dci.flushl = '1') then v.flush := '1'; v.faddr := r.efaddr; end if; end if; if eholdn = '1' then v.efaddr := v.xaddress(OFFSET_HIGH downto OFFSET_LOW); end if; if (r.flush = '1') and (dcen /= 0) then twrite := '1'; vmask := (others => (others => '0')); v.faddr := r.faddr +1; newtag(TAG_HIGH downto TAG_LOW) := (others => '0'); newptag := (others => '0'); if DSNOOPSEP then flushaddr := r.faddr; end if; taddr(OFFSET_HIGH downto OFFSET_LOW) := r.faddr; wlrr := (others => '0'); if ((r.faddr(DOFFSET_BITS -1) and not v.faddr(DOFFSET_BITS -1)) or r.flushl2) = '1' then v.flush := '0'; end if; end if; -- update cache with memory data during read miss if read = '1' then for i in 0 to DSETS-1 loop ddatainv(i) := mcdo.data; end loop; end if; -- cache write signals if twrite = '1' then if tdiagwrite = '1' then ctwrite(ddset) := '1'; else ctwrite(conv_integer(setrepl)) := '1'; end if; end if; if DSNOOPSEP then if tpwrite = '1' then if tdiagwrite = '1' then ctpwrite(ddset) := '1'; else ctpwrite(conv_integer(setrepl)) := '1'; end if; end if; end if; if dwrite = '1' then if ddiagwrite = '1' then cdwrite(ddset) := '1'; else cdwrite(conv_integer(setrepl)) := '1'; end if; end if; if (r.flush and twrite) = '1' then -- flush ctwrite := (others => '1'); wlrr := (others => '0'); wlock := (others => '0'); if DSNOOPSEP then ctpwrite := (others => '1'); end if; end if; csnoopwe := (others => '0'); flushl := '0'; if ((snoopwe and not mcdo.scanen) = '1') then csnoopwe := snhit; end if; if DSNOOPSEP then csnoopwe := csnoopwe or ctwrite; if orv(snhit) = '1' then flushl := '1'; end if; -- flush tag on snoop hit end if; if r.flush2 = '1' then vl.lru := (others => (others => '0')); end if; -- reset if (not RESET_ALL) and (rst = '0') then v.dstate := idle; v.stpend := '0'; v.req := '0'; v.burst := '0'; v.read := '0'; v.flush := '0'; v.nomds := '0'; v.holdn := '1'; v.rndcnt := (others => '0'); v.setrepl := (others => '0'); v.dsuset := (others => '0'); v.flush2 := '1'; v.lrr := '0'; v.lock := '0'; v.ilramen := '0'; v.cctrl.dcs := "00"; v.cctrl.ics := "00"; v.cctrl.burst := '0'; v.cctrl.dsnoop := '0'; v.tadj := (others => '0'); v.dadj := (others => '0'); v.sadj := (others => '0'); --if M_EN then v.mmctrl1.e := '0'; v.mmctrl1.nf := '0'; v.mmctrl1.ctx := (others => '0'); v.mmctrl1.tlbdis := '0'; v.mmctrl1.pso := '0'; v.trans_op := '0'; v.flush_op := '0'; v.diag_op := '0'; v.pflush := '0'; v.pflushr := '0'; v.mmctrl1.pagesize := (others => '0'); --end if; v.mmctrl1.bar := (others => '0'); v.faddr := (others => '0'); v.reqst := '0'; v.cache := '0'; v.wb.lock := '0'; v.wb.data1 := (others => '0'); v.wb.data2 := (others => '0'); v.noflush := '0'; v.mexc := '0'; end if; if dsnoop = 0 then v.cctrl.dsnoop := '0'; end if; if not M_EN then v.mmctrl1 := mmctrl_type1_none; end if; -- kill MMU regs if not enabled -- Drive signals c <= v; cs <= vs; -- register inputs cl <= vl; -- tag ram inputs senable := senable and not scanen; enable := enable and not scanen; if mcdo.scanen = '1' then ctpwrite := (others => '0'); end if; for i in 0 to DSETS-1 loop tag(i)(dlinesize-1 downto 0) := vmask(i); tag(i)(TAG_HIGH downto TAG_LOW) := newtag(TAG_HIGH downto TAG_LOW); tag(i)(CTAG_LRRPOS) := wlrr(i); tag(i)(CTAG_LOCKPOS) := wlock(i); ctx(i) := r.mmctrl1.ctx; ptag(i)(TAG_HIGH downto TAG_LOW) := newptag(TAG_HIGH downto TAG_LOW); end loop; dcrami.tag <= tag; -- virtual tag dcrami.ptag <= ptag; -- physical tag dcrami.ctx <= ctx; -- context dcrami.tenable <= enable; -- virtual tag ram enable dcrami.twrite <= ctwrite; -- virtual tag ram write (port 1) dcrami.tpwrite <= ctpwrite; -- virtual tag ram write (port 2) dcrami.flush <= r.flush or flushl; dcrami.senable <= senable; -- physical tag ram enable dcrami.swrite <= csnoopwe; -- physical tag ram write dcrami.saddress(19 downto (OFFSET_HIGH - OFFSET_LOW +1)) <= zero32(19 downto (OFFSET_HIGH - OFFSET_LOW +1)); dcrami.saddress(OFFSET_HIGH - OFFSET_LOW downto 0) <= snoopaddr; dcrami.faddress(19 downto (OFFSET_HIGH - OFFSET_LOW +1)) <= zero32(19 downto (OFFSET_HIGH - OFFSET_LOW +1)); dcrami.faddress(OFFSET_HIGH - OFFSET_LOW downto 0) <= flushaddr; -- data ram inputs dcrami.denable <= enable; dcrami.address(19 downto (OFFSET_HIGH - LINE_LOW + 1)) <= zero32(19 downto (OFFSET_HIGH - LINE_LOW + 1)); dcrami.address(OFFSET_HIGH - LINE_LOW downto 0) <= taddr; dcrami.data <= ddatainv; dcrami.dwrite <= cdwrite; dcrami.ldramin.address(23 downto 2) <= laddr(23 downto 2); dcrami.ldramin.enable <= (lramcs or lramwr) and not mcdo.scanen; dcrami.ldramin.read <= rlramrd; dcrami.ldramin.write <= lramwr; dcrami.tdiag <= mcdo.testen & mcdo.scanen & r.tadj; dcrami.sdiag <= mcdo.testen & mcdo.scanen & r.sadj; dcrami.ddiag <= mcdo.testen & mcdo.scanen & r.dadj; -- memory controller inputs mcdi.address <= r.wb.addr; mcdi.data <= r.wb.data1; mcdi.burst <= r.burst; mcdi.size <= r.wb.size; mcdi.read <= r.wb.read; mcdi.asi <= r.wb.asi; mcdi.lock <= r.wb.lock; mcdi.req <= r.req; mcdi.cache <= r.cache; -- diagnostic instruction cache access dco.icdiag.flush <= iflush; dco.icdiag.pflush <= pflush; dco.icdiag.pflushaddr <= pflushaddr; dco.icdiag.pflushtyp <= pflushtyp; dco.icdiag.read <= read; dco.icdiag.tag <= not r.asi(0); dco.icdiag.ctx <= r.asi(4); --ASI_ICTX "10101" dco.icdiag.addr <= r.xaddress; dco.icdiag.enable <= r.icenable; dco.icdiag.ilramen <= r.ilramen; dco.icdiag.cctrl <= r.cctrl; dco.icdiag.scanen <= mcdo.scanen; -- IU data cache inputs dco.data <= rdatav; dco.mexc <= mexc; dco.set <= conv_std_logic_vector(set, 2); dco.hold <= r.holdn; dco.mds <= mds; dco.werr <= mcdo.werr; dco.cache <= cache; dco.hit <= r.hit; if r.dstate = idle then dco.idle <= not r.stpend; else dco.idle <= '0'; end if; dco.scanen <= mcdo.scanen; dco.testen <= mcdo.testen; -- MMU mmudci.trans_op <= mmudci_trans_op; mmudci.transdata.data <= mmudci_transdata_data; --r.vaddr; mmudci.transdata.su <= mmudci_su; mmudci.transdata.read <= mmudci_read; mmudci.transdata.isid <= id_dcache; mmudci.transdata.wb_data <= dci.maddress; mmudci.flush_op <= mmudci_flush_op; mmudci.wb_op <= mmudci_wb_op; mmudci.diag_op <= mmudci_diag_op; mmudci.fsread <= mmudci_fsread; mmudci.mmctrl1 <= r.mmctrl1; mmudci.testin <= ahbsi.testin; end process; -- Local registers reg1 : process(clk) begin if rising_edge(clk) then r <= c; if RESET_ALL and (rst = '0') then r <= RRES; end if; end if; end process; sn2 : if DSNOOP2 /= 0 generate reg2 : process(sclk) begin if rising_edge(sclk) then rs <= cs; if RESET_ALL and (rst = '0') then rs <= SRES; end if; end if; end process; end generate; nosn2 : if DSNOOP2 = 0 generate rs.snoop <= '0'; rs.addr <= (others => '0'); rs.snhit <= (others => '0'); rs.mask <= (others => '0'); end generate; reg2 : if (DSETS>1) and (drepl = lru) generate reg2 : process(clk) begin if rising_edge(clk) then rl <= cl; if RESET_ALL and (rst = '0') then rl <= LRES; end if; end if; end process; end generate; noreg2 : if (DSETS = 1) or (drepl /= lru) generate rl.write <= '0'; rl.waddr <= (others => '0'); rl.set <= (others => '0'); rl.lru <= (others => (others => '0')); end generate; -- pragma translate_off chk : process begin assert not ((DSETS > 2) and (drepl = lrr)) report "Wrong data cache configuration detected: LRR replacement requires 2 ways" severity failure; assert not ((DSETS = 3) and (drepl = dir)) report "Wrong data cache configuration detected: Direct replacement requires 2 or 4 ways" severity failure; wait; end process; -- pragma translate_on end ;	gpl-2.0	d36eb533fdb306c9a622c23fd50e5223	0.525459	3.459434	false	false	false	false
marco-c/leon-nexys2	grlib-gpl-1.3.4-b4140/lib/eth/core/greth_tx.vhd	1	16,823	------------------------------------------------------------------------------ -- This file is a part of the GRLIB VHDL IP LIBRARY -- Copyright (C) 2003 - 2008, Gaisler Research -- Copyright (C) 2008 - 2013, Aeroflex Gaisler -- -- This program is free software; you can redistribute it and/or modify -- it under the terms of the GNU General Public License as published by -- the Free Software Foundation; either version 2 of the License, or -- (at your option) any later version. -- -- This program is distributed in the hope that it will be useful, -- but WITHOUT ANY WARRANTY; without even the implied warranty of -- MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the -- GNU General Public License for more details. -- -- You should have received a copy of the GNU General Public License -- along with this program; if not, write to the Free Software -- Foundation, Inc., 59 Temple Place, Suite 330, Boston, MA 02111-1307 USA ----------------------------------------------------------------------------- -- Entity: greth_tx -- File: greth_tx.vhd -- Author: Marko Isomaki -- Description: Ethernet transmitter ------------------------------------------------------------------------------ library ieee; use ieee.std_logic_1164.all; library grlib; use grlib.stdlib.all; library eth; use eth.grethpkg.all; entity greth_tx is generic( ifg_gap : integer := 24; attempt_limit : integer := 16; backoff_limit : integer := 10; nsync : integer range 1 to 2 := 2; rmii : integer range 0 to 1 := 0); port( rst : in std_ulogic; clk : in std_ulogic; txi : in host_tx_type; txo : out tx_host_type ); attribute sync_set_reset of rst : signal is "true"; end entity; architecture rtl of greth_tx is function mirror2(din : in std_logic_vector(3 downto 0)) return std_logic_vector is variable do : std_logic_vector(3 downto 0); begin do(3) := din(0); do(2) := din(1); do(1) := din(2); do(0) := din(3); return do; end function; function init_ifg( ifg_gap : in integer; rmii : in integer) return integer is begin if rmii = 0 then return log2(ifg_gap); else return log2(ifg_gap20); end if; end function; constant maxattempts : std_logic_vector(4 downto 0) := conv_std_logic_vector(attempt_limit, 5); --transmitter constants constant ifg_bits : integer := init_ifg(ifg_gap, rmii); constant ifg_p1 : std_logic_vector(ifg_bits-1 downto 0) := conv_std_logic_vector((ifg_gap)/3, ifg_bits); constant ifg_p2 : std_logic_vector(ifg_bits-1 downto 0) := conv_std_logic_vector((ifg_gap2)/3, ifg_bits); constant ifg_p1_r100 : std_logic_vector(ifg_bits-1 downto 0) := conv_std_logic_vector((ifg_gap2)/3, ifg_bits); constant ifg_p2_r100 : std_logic_vector(ifg_bits-1 downto 0) := conv_std_logic_vector(rmii(ifg_gap4)/3, ifg_bits); constant ifg_p1_r10 : std_logic_vector(ifg_bits-1 downto 0) := conv_std_logic_vector(rmii(ifg_gap20)/3, ifg_bits); constant ifg_p2_r10 : std_logic_vector(ifg_bits-1 downto 0) := conv_std_logic_vector(rmii(ifg_gap*40)/3, ifg_bits); function ifg_sel( rmii : in integer; p1 : in integer; speed : in std_ulogic) return std_logic_vector is begin if p1 = 1 then if rmii = 0 then return ifg_p1; else if speed = '1' then return ifg_p1_r100; else return ifg_p1_r10; end if; end if; else if rmii = 0 then return ifg_p2; else if speed = '1' then return ifg_p2_r100; else return ifg_p2_r10; end if; end if; end if; end function; --transmitter types type tx_state_type is (idle, preamble, sfd, data1, data2, pad1, pad2, fcs, fcs2, finish, calc_backoff, wait_backoff, send_jam, send_jam2, check_attempts); type def_state_type is (monitor, def_on, ifg1, ifg2, frame_waitingst); type tx_reg_type is record --deference process def_state : def_state_type; ifg_cycls : std_logic_vector(ifg_bits-1 downto 0); deferring : std_ulogic; was_transmitting : std_ulogic; --tx process main_state : tx_state_type; transmitting : std_ulogic; tx_en : std_ulogic; txd : std_logic_vector(3 downto 0); cnt : std_logic_vector(3 downto 0); icnt : std_logic_vector(1 downto 0); crc : std_logic_vector(31 downto 0); crc_en : std_ulogic; byte_count : std_logic_vector(10 downto 0); slot_count : std_logic_vector(6 downto 0); random : std_logic_vector(9 downto 0); delay_val : std_logic_vector(9 downto 0); retry_cnt : std_logic_vector(4 downto 0); status : std_logic_vector(1 downto 0); data : std_logic_vector(31 downto 0); --synchronization read : std_ulogic; done : std_ulogic; restart : std_ulogic; start : std_logic_vector(nsync downto 0); read_ack : std_logic_vector(nsync-1 downto 0); crs : std_logic_vector(1 downto 0); col : std_logic_vector(1 downto 0); fullduplex : std_logic_vector(1 downto 0); --rmii crs_act : std_ulogic; crs_prev : std_ulogic; speed : std_logic_vector(1 downto 0); rcnt : std_logic_vector(3 downto 0); switch : std_ulogic; txd_msb : std_logic_vector(1 downto 0); zero : std_ulogic; rmii_crc_en : std_ulogic; end record; --transmitter signals signal r, rin : tx_reg_type; signal txrst : std_ulogic; signal vcc : std_ulogic; --attribute sync_set_reset : string; attribute sync_set_reset of txrst : signal is "true"; begin vcc <= '1'; tx_rst : eth_rstgen port map(rst, clk, vcc, txrst, open); tx : process(txrst, r, txi) is variable collision : std_ulogic; variable frame_waiting : std_ulogic; variable index : integer range 0 to 7; variable start : std_ulogic; variable read_ack : std_ulogic; variable v : tx_reg_type; variable crs : std_ulogic; variable col : std_ulogic; variable tx_done : std_ulogic; begin v := r; frame_waiting := '0'; tx_done := '0'; v.rmii_crc_en := '0'; --synchronization v.col(1) := r.col(0); v.col(0) := txi.rx_col; v.crs(1) := r.crs(0); v.crs(0) := txi.rx_crs; v.fullduplex(0) := txi.full_duplex; v.fullduplex(1) := r.fullduplex(0); v.start(0) := txi.start; v.read_ack(0) := txi.readack; if nsync = 2 then v.start(1) := r.start(0); v.read_ack(1) := r.read_ack(0); end if; start := r.start(nsync) xor r.start(nsync-1); read_ack := not (r.read xor r.read_ack(nsync-1)); --crc generation if (r.crc_en = '1') and ((rmii = 0) or (r.rmii_crc_en = '1')) then v.crc := calccrc(r.txd, r.crc); end if; --rmii if rmii = 0 then col := r.col(1); crs := r.crs(1); tx_done := '1'; else v.crs_prev := r.crs(1); if (r.crs(0) and not r.crs_act) = '1' then v.crs_act := '1'; end if; if (r.crs(1) or r.crs(0)) = '0' then v.crs_act := '0'; end if; crs := r.crs(1) and not ((not r.crs_prev) and r.crs_act); col := crs and r.tx_en; v.speed(1) := r.speed(0); v.speed(0) := txi.speed; if r.tx_en = '1' then v.rcnt := r.rcnt - 1; if r.speed(1) = '1' then v.switch := not r.switch; if r.switch = '1' then tx_done := '1'; v.rmii_crc_en := '1'; end if; if r.switch = '0' then v.txd(1 downto 0) := r.txd_msb; end if; else v.zero := '0'; if r.rcnt = "0001" then v.zero := '1'; end if; if r.zero = '1' then v.switch := not r.switch; v.rcnt := "1001"; if r.switch = '0' then v.txd(1 downto 0) := r.txd_msb; end if; end if; if (r.switch and r.zero) = '1' then tx_done := '1'; v.rmii_crc_en := '1'; end if; end if; end if; end if; collision := col and not r.fullduplex(1); --main fsm case r.main_state is when idle => v.transmitting := '0'; if rmii = 1 then v.rcnt := "1001"; v.switch := '0'; end if; if (start and not r.deferring) = '1' then v.main_state := preamble; v.transmitting := '1'; v.tx_en := '1'; v.byte_count := (others => '1'); v.status := (others => '0'); v.read := not r.read; v.start(nsync) := r.start(nsync-1); elsif start = '1' then frame_waiting := '1'; end if; v.txd := "0101"; v.cnt := "1110"; when preamble => if tx_done = '1' then v.cnt := r.cnt - 1; if r.cnt = "0000" then v.txd := "1101"; v.main_state := sfd; end if; if collision = '1' then v.main_state := send_jam; end if; end if; when sfd => if tx_done = '1' then v.main_state := data1; v.icnt := (others => '0'); v.crc_en := '1'; v.crc := (others => '1'); v.byte_count := (others => '0'); v.txd := txi.data(27 downto 24); if (read_ack and txi.valid) = '0' then v.status(0) := '1'; v.main_state := finish; v.tx_en := '0'; else v.data := txi.data; v.read := not r.read; end if; if collision = '1' then v.main_state := send_jam; end if; end if; when data1 => index := conv_integer(r.icnt); if tx_done = '1' then v.byte_count := r.byte_count + 1; v.main_state := data2; v.icnt := r.icnt + 1; case index is when 0 => v.txd := r.data(31 downto 28); when 1 => v.txd := r.data(23 downto 20); when 2 => v.txd := r.data(15 downto 12); when 3 => v.txd := r.data(7 downto 4); when others => null; end case; if v.byte_count = txi.len then v.tx_en := '1'; if conv_integer(v.byte_count) >= 60 then v.main_state := fcs; v.cnt := (others => '0'); else v.main_state := pad1; end if; elsif index = 3 then if (read_ack and txi.valid) = '0' then v.status(0) := '1'; v.main_state := finish; v.tx_en := '0'; else v.data := txi.data; v.read := not r.read; end if; end if; if collision = '1' then v.main_state := send_jam; end if; end if; when data2 => index := conv_integer(r.icnt); if tx_done = '1' then v.main_state := data1; case index is when 0 => v.txd := r.data(27 downto 24); when 1 => v.txd := r.data(19 downto 16); when 2 => v.txd := r.data(11 downto 8); when 3 => v.txd := r.data(3 downto 0); when others => null; end case; if collision = '1' then v.main_state := send_jam; end if; end if; when pad1 => if tx_done = '1' then v.main_state := pad2; if collision = '1' then v.main_state := send_jam; end if; end if; when pad2 => if tx_done = '1' then v.byte_count := r.byte_count + 1; if conv_integer(v.byte_count) = 60 then v.main_state := fcs; v.cnt := (others => '0'); else v.main_state := pad1; end if; if collision = '1' then v.main_state := send_jam; end if; end if; when fcs => if tx_done = '1' then v.cnt := r.cnt + 1; v.crc_en := '0'; index := conv_integer(r.cnt); case index is when 0 => v.txd := mirror2(not v.crc(31 downto 28)); when 1 => v.txd := mirror2(not r.crc(27 downto 24)); when 2 => v.txd := mirror2(not r.crc(23 downto 20)); when 3 => v.txd := mirror2(not r.crc(19 downto 16)); when 4 => v.txd := mirror2(not r.crc(15 downto 12)); when 5 => v.txd := mirror2(not r.crc(11 downto 8)); when 6 => v.txd := mirror2(not r.crc(7 downto 4)); when 7 => v.txd := mirror2(not r.crc(3 downto 0)); v.main_state := fcs2; when others => null; end case; end if; when fcs2 => if tx_done = '1' then v.main_state := finish; v.tx_en := '0'; end if; when finish => v.tx_en := '0'; v.transmitting := '0'; v.main_state := idle; v.retry_cnt := (others => '0'); v.done := not r.done; when send_jam => if tx_done = '1' then v.cnt := "0110"; v.main_state := send_jam2; v.crc_en := '0'; end if; when send_jam2 => if tx_done = '1' then v.cnt := r.cnt - 1; if r.cnt = "0000" then v.main_state := check_attempts; v.retry_cnt := r.retry_cnt + 1; v.tx_en := '0'; end if; end if; when check_attempts => v.transmitting := '0'; if r.retry_cnt = maxattempts then v.main_state := finish; v.status(1) := '1'; else v.main_state := calc_backoff; v.restart := not r.restart; end if; v.tx_en := '0'; when calc_backoff => v.delay_val := (others => '0'); for i in 1 to backoff_limit-1 loop if i < conv_integer(r.retry_cnt)+1 then v.delay_val(i) := r.random(i); end if; end loop; v.main_state := wait_backoff; v.slot_count := (others => '1'); when wait_backoff => if conv_integer(r.delay_val) = 0 then v.main_state := idle; end if; v.slot_count := r.slot_count - 1; if conv_integer(r.slot_count) = 0 then v.slot_count := (others => '1'); v.delay_val := r.delay_val - 1; end if; when others => v.main_state := idle; end case; --random values; v.random := r.random(8 downto 0) & (not (r.random(2) xor r.random(9))); --deference case r.def_state is when monitor => v.was_transmitting := '0'; if ( (crs and not r.fullduplex(1)) or (r.transmitting and r.fullduplex(1)) ) = '1' then v.deferring := '1'; v.def_state := def_on; v.was_transmitting := r.transmitting; end if; when def_on => v.was_transmitting := r.was_transmitting or r.transmitting; if r.fullduplex(1) = '1' then if r.transmitting = '0' then v.def_state := ifg1; end if; v.ifg_cycls := ifg_sel(rmii, 1, r.speed(1)); else if (r.transmitting or crs) = '0' then v.def_state := ifg1; v.ifg_cycls := ifg_sel(rmii, 1, r.speed(1)); end if; end if; when ifg1 => v.ifg_cycls := r.ifg_cycls - 1; if r.ifg_cycls = zero32(ifg_bits-1 downto 0) then v.def_state := ifg2; v.ifg_cycls := ifg_sel(rmii, 0, r.speed(1)); elsif (crs and not r.fullduplex(1)) = '1' then v.ifg_cycls := ifg_sel(rmii, 1, r.speed(1)); end if; when ifg2 => v.ifg_cycls := r.ifg_cycls - 1; if r.ifg_cycls = zero32(ifg_bits-1 downto 0) then v.deferring := '0'; if (r.fullduplex(1) or not frame_waiting) = '1' then v.def_state := monitor; elsif frame_waiting = '1' then v.def_state := frame_waitingst; end if; end if; when frame_waitingst => if frame_waiting = '0' then v.def_state := monitor; end if; when others => v.def_state := monitor; end case; if rmii = 1 then v.txd_msb := v.txd(3 downto 2); end if; if txrst = '0' then v.main_state := idle; v.random := (others => '0'); v.def_state := monitor; v.deferring := '0'; v.tx_en := '0'; v.done := '0'; v.restart := '0'; v.read := '0'; v.start := (others => '0'); v.read_ack := (others => '0'); v.icnt := (others => '0'); v.delay_val := (others => '0'); v.ifg_cycls := (others => '0'); v.crs_act := '0'; v.slot_count := (others => '1'); v.retry_cnt := (others => '0'); v.cnt := (others => '0'); end if; rin <= v; txo.tx_er <= '0'; txo.tx_en <= r.tx_en; txo.txd <= r.txd; txo.done <= r.done; txo.read <= r.read; txo.restart <= r.restart; txo.status <= r.status; end process; txregs : process(clk) is begin if rising_edge(clk) then r <= rin; if rst = '0' then r.icnt <= (others => '0'); r.delay_val <= (others => '0'); r.cnt <= (others => '0'); else r.icnt <= rin.icnt; r.delay_val <= rin.delay_val; r.cnt <= rin.cnt; end if; end if; end process; end architecture;	gpl-2.0	973ac5f4e1aab69ee8e232873648b935	0.518219	3.187382	false	false	false	false
IamVNIE/Hardware-Security	Interfaces/UART_Version_2/UART_TX_CTRL.vhd	2	2,829	---------------------------------------------------------------------------------- -- Company: -- Engineer: Vinayaka Jyothi -- -- Create Date: 21:49:51 11/23/2016 -- Design Name: -- Module Name: UART_TX_CTRL - Behavioral -- Project Name: -- Target Devices: -- Tool versions: -- Description: -- -- Dependencies: -- -- Revision: -- Revision 0.01 - File Created -- Additional Comments: ---------------------------------------------------------------------------------- library IEEE; use IEEE.STD_LOGIC_1164.ALL; use IEEE.std_logic_unsigned.all; entity UART_TX_CTRL is Port ( SEND : in STD_LOGIC; DATA : in STD_LOGIC_VECTOR (7 downto 0); CLK : in STD_LOGIC; READY : out STD_LOGIC; UART_TX : out STD_LOGIC); end UART_TX_CTRL; architecture Behavioral of UART_TX_CTRL is type TX_STATE_TYPE is (RDY, LOAD_BIT, SEND_BIT); constant BIT_TMR_MAX : std_logic_vector(13 downto 0) := "10100010110000"; --10416 = (round(100MHz / 9600)) - 1 constant BIT_INDEX_MAX : natural := 10; signal bitTmr : std_logic_vector(13 downto 0) := (others => '0'); signal bitDone : std_logic; signal bitIndex : natural; signal txBit : std_logic := '1'; signal txData : std_logic_vector(9 downto 0); signal txState : TX_STATE_TYPE := RDY; begin next_txState_process : process (CLK) begin if (rising_edge(CLK)) then case txState is when RDY => if (SEND = '1') then txState <= LOAD_BIT; end if; when LOAD_BIT => txState <= SEND_BIT; when SEND_BIT => if (bitDone = '1') then if (bitIndex = BIT_INDEX_MAX) then txState <= RDY; else txState <= LOAD_BIT; end if; end if; when others => txState <= RDY; end case; end if; end process; bit_timing_process : process (CLK) begin if (rising_edge(CLK)) then if (txState = RDY) then bitTmr <= (others => '0'); else if (bitDone = '1') then bitTmr <= (others => '0'); else bitTmr <= bitTmr + 1; end if; end if; end if; end process; bitDone <= '1' when (bitTmr = BIT_TMR_MAX) else '0'; bit_counting_process : process (CLK) begin if (rising_edge(CLK)) then if (txState = RDY) then bitIndex <= 0; elsif (txState = LOAD_BIT) then bitIndex <= bitIndex + 1; end if; end if; end process; tx_data_latch_process : process (CLK) begin if (rising_edge(CLK)) then if (SEND = '1') then txData <= '1' & DATA & '0'; end if; end if; end process; tx_bit_process : process (CLK) begin if (rising_edge(CLK)) then if (txState = RDY) then txBit <= '1'; elsif (txState = LOAD_BIT) then txBit <= txData(bitIndex); end if; end if; end process; UART_TX <= txBit; READY <= '1' when (txState = RDY) else '0'; end Behavioral;	mit	23db18ab165ad173b060d3e5b8cae399	0.557441	3.101974	false	false	false	false
marco-c/leon-nexys2	grlib-gpl-1.3.4-b4140/designs/leon3-xilinx-ml403/testbench.vhd	1	9,339	----------------------------------------------------------------------------- -- LEON3 Demonstration design test bench -- Copyright (C) 2004 Jiri Gaisler, Gaisler Research ------------------------------------------------------------------------------ -- This file is a part of the GRLIB VHDL IP LIBRARY -- Copyright (C) 2003 - 2008, Gaisler Research -- Copyright (C) 2008 - 2013, Aeroflex Gaisler -- -- This program is free software; you can redistribute it and/or modify -- it under the terms of the GNU General Public License as published by -- the Free Software Foundation; either version 2 of the License, or -- (at your option) any later version. -- -- This program is distributed in the hope that it will be useful, -- but WITHOUT ANY WARRANTY; without even the implied warranty of -- MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the -- GNU General Public License for more details. -- -- You should have received a copy of the GNU General Public License -- along with this program; if not, write to the Free Software -- Foundation, Inc., 59 Temple Place, Suite 330, Boston, MA 02111-1307 USA ------------------------------------------------------------------------------ library ieee; use ieee.std_logic_1164.all; library gaisler; use gaisler.libdcom.all; use gaisler.sim.all; library techmap; use techmap.gencomp.all; library micron; use micron.components.all; library cypress; use cypress.components.all; use work.debug.all; use work.config.all; -- configuration entity testbench is generic ( fabtech : integer := CFG_FABTECH; memtech : integer := CFG_MEMTECH; padtech : integer := CFG_PADTECH; clktech : integer := CFG_CLKTECH; ncpu : integer := CFG_NCPU; disas : integer := CFG_DISAS; -- Enable disassembly to console dbguart : integer := CFG_DUART; -- Print UART on console pclow : integer := CFG_PCLOW; clkperiod : integer := 10; -- system clock period romwidth : integer := 32; -- rom data width (8/32) romdepth : integer := 16; -- rom address depth sramwidth : integer := 32; -- ram data width (8/16/32) sramdepth : integer := 18; -- ram address depth srambanks : integer := 2 -- number of ram banks ); end; architecture behav of testbench is constant promfile : string := "prom.srec"; -- rom contents constant sramfile : string := "ram.srec"; -- ram contents constant sdramfile : string := "ram.srec"; -- sdram contents signal sys_clk : std_logic := '0'; signal sys_rst_in : std_logic := '0'; -- Reset constant ct : integer := clkperiod/2; signal plb_error : std_logic; signal opb_error : std_logic; signal flash_a23 : std_ulogic; signal sram_flash_addr : std_logic_vector(20 downto 0); signal sram_flash_data : std_logic_vector(31 downto 0); signal sram_cen : std_logic; signal sram_bw : std_logic_vector (3 downto 0); signal sram_flash_oe_n : std_ulogic; signal sram_flash_we_n : std_ulogic; signal flash_ce : std_logic; signal sram_clk : std_ulogic; signal sram_clk_fb : std_ulogic; signal sram_mode : std_ulogic; signal sram_adv_ld_n : std_ulogic; signal sram_zz : std_ulogic; signal iosn : std_ulogic; signal ddr_clk : std_logic; signal ddr_clkb : std_logic; signal ddr_clk_fb : std_logic; signal ddr_cke : std_logic; signal ddr_csb : std_logic; signal ddr_web : std_ulogic; -- ddr write enable signal ddr_rasb : std_ulogic; -- ddr ras signal ddr_casb : std_ulogic; -- ddr cas signal ddr_dm : std_logic_vector (3 downto 0); -- ddr dm signal ddr_dqs : std_logic_vector (3 downto 0); -- ddr dqs signal ddr_ad : std_logic_vector (12 downto 0); -- ddr address signal ddr_ba : std_logic_vector (1 downto 0); -- ddr bank address signal ddr_dq : std_logic_vector (31 downto 0); -- ddr data signal txd1 : std_ulogic; -- UART1 tx data signal rxd1 : std_ulogic; -- UART1 rx data signal gpio : std_logic_vector(13 downto 0); -- I/O port signal phy_mii_data: std_logic; -- ethernet PHY interface signal phy_tx_clk : std_ulogic; signal phy_rx_clk : std_ulogic; signal phy_rx_data : std_logic_vector(7 downto 0); signal phy_dv : std_ulogic; signal phy_rx_er : std_ulogic; signal phy_col : std_ulogic; signal phy_crs : std_ulogic; signal phy_tx_data : std_logic_vector(7 downto 0); signal phy_tx_en : std_ulogic; signal phy_tx_er : std_ulogic; signal phy_mii_clk : std_ulogic; signal phy_rst_n : std_ulogic; signal phy_gtx_clk : std_ulogic; signal ps2_keyb_clk: std_logic; signal ps2_keyb_data: std_logic; signal ps2_mouse_clk: std_logic; signal ps2_mouse_data: std_logic; signal tft_lcd_clk : std_ulogic; signal vid_blankn : std_ulogic; signal vid_syncn : std_ulogic; signal vid_hsync : std_ulogic; signal vid_vsync : std_ulogic; signal vid_r : std_logic_vector(7 downto 3); signal vid_g : std_logic_vector(7 downto 3); signal vid_b : std_logic_vector(7 downto 3); signal usb_csn : std_logic; signal flash_cex : std_logic; signal iic_scl : std_logic; signal iic_sda : std_logic; signal GND : std_ulogic := '0'; signal VCC : std_ulogic := '1'; signal NC : std_ulogic := 'Z'; signal spw_clk : std_ulogic := '0'; signal spw_rxdp : std_logic_vector(0 to 2) := "000"; signal spw_rxdn : std_logic_vector(0 to 2) := "000"; signal spw_rxsp : std_logic_vector(0 to 2) := "000"; signal spw_rxsn : std_logic_vector(0 to 2) := "000"; signal spw_txdp : std_logic_vector(0 to 2); signal spw_txdn : std_logic_vector(0 to 2); signal spw_txsp : std_logic_vector(0 to 2); signal spw_txsn : std_logic_vector(0 to 2); signal datazz : std_logic_vector(0 to 3); constant lresp : boolean := false; begin -- clock and reset sys_clk <= not sys_clk after ct * 1 ns; sys_rst_in <= '0', '1' after 200 ns; rxd1 <= 'H'; sram_clk_fb <= sram_clk; ddr_clk_fb <= ddr_clk; ps2_keyb_data <= 'H'; ps2_keyb_clk <= 'H'; ps2_mouse_clk <= 'H'; ps2_mouse_data <= 'H'; iic_scl <= 'H'; iic_sda <= 'H'; flash_cex <= not flash_ce; gpio <= (others => 'L'); cpu : entity work.leon3mp generic map ( fabtech, memtech, padtech, ncpu, disas, dbguart, pclow ) port map ( sys_rst_in, sys_clk, plb_error, opb_error, sram_flash_addr, sram_flash_data, sram_cen, sram_bw, sram_flash_oe_n, sram_flash_we_n, flash_ce, sram_clk, sram_clk_fb, sram_adv_ld_n, iosn, ddr_clk, ddr_clkb, ddr_clk_fb, ddr_cke, ddr_csb, ddr_web, ddr_rasb, ddr_casb, ddr_dm, ddr_dqs, ddr_ad, ddr_ba, ddr_dq, txd1, rxd1, gpio, phy_gtx_clk, phy_mii_data, phy_tx_clk, phy_rx_clk, phy_rx_data, phy_dv, phy_rx_er, phy_col, phy_crs, phy_tx_data, phy_tx_en, phy_tx_er, phy_mii_clk, phy_rst_n, ps2_keyb_clk, ps2_keyb_data, ps2_mouse_clk, ps2_mouse_data, tft_lcd_clk, vid_hsync, vid_vsync, vid_r, vid_g, vid_b, usb_csn, iic_scl, iic_sda ); datazz <= "HHHH"; u0 : cy7c1354 generic map (fname => sramfile) port map( Dq(35 downto 32) => datazz, Dq(31 downto 0) => sram_flash_data, Addr => sram_flash_addr(17 downto 0), Mode => sram_mode, Clk => sram_clk, CEN_n => gnd, AdvLd_n => sram_adv_ld_n, Bwa_n => sram_bw(3), Bwb_n => sram_bw(2), Bwc_n => sram_bw(1), Bwd_n => sram_bw(0), Rw_n => sram_flash_we_n, Oe_n => sram_flash_oe_n, Ce1_n => sram_cen, Ce2 => vcc, Ce3_n => gnd, Zz => sram_zz); sram_zz <= '0'; u1 : mt46v16m16 generic map (index => 1, fname => sdramfile, bbits => 32) PORT MAP( Dq => ddr_dq(15 downto 0), Dqs => ddr_dqs(1 downto 0), Addr => ddr_ad(12 downto 0), Ba => ddr_ba, Clk => ddr_clk, Clk_n => ddr_clkb, Cke => ddr_cke, Cs_n => ddr_csb, Ras_n => ddr_rasb, Cas_n => ddr_casb, We_n => ddr_web, Dm => ddr_dm(1 downto 0)); u2 : mt46v16m16 generic map (index => 0, fname => sdramfile, bbits => 32) PORT MAP( Dq => ddr_dq(31 downto 16), Dqs => ddr_dqs(3 downto 2), Addr => ddr_ad(12 downto 0), Ba => ddr_ba, Clk => ddr_clk, Clk_n => ddr_clkb, Cke => ddr_cke, Cs_n => ddr_csb, Ras_n => ddr_rasb, Cas_n => ddr_casb, We_n => ddr_web, Dm => ddr_dm(3 downto 2)); prom0 : for i in 0 to (romwidth/8)-1 generate sr0 : sram generic map (index => i, abits => romdepth, fname => promfile) port map (sram_flash_addr(romdepth-1 downto 0), sram_flash_data(31-i8 downto 24-i8), flash_cex, sram_bw(i), sram_flash_oe_n); end generate; phy_mii_data <= 'H'; p0: phy port map(sys_rst_in, phy_mii_data, phy_tx_clk, phy_rx_clk, phy_rx_data, phy_dv, phy_rx_er, phy_col, phy_crs, phy_tx_data, phy_tx_en, phy_tx_er, phy_mii_clk, phy_gtx_clk); i0: i2c_slave_model port map (iic_scl, iic_sda); plb_error <= 'H'; -- ERROR pull-up iuerr : process begin wait for 5000 ns; if to_x01(plb_error) = '1' then wait on plb_error; end if; assert (to_x01(plb_error) = '1') report "* IU in error mode, simulation halted *" severity failure ; end process; test0 : grtestmod port map ( sys_rst_in, sys_clk, plb_error, sram_flash_addr(19 downto 0), sram_flash_data, iosn, sram_flash_oe_n, sram_bw(0), open); sram_flash_data <= buskeep(sram_flash_data), (others => 'H') after 250 ns; ddr_dq <= buskeep(ddr_dq), (others => 'H') after 250 ns; end ;	gpl-2.0	ca4f30b67ae6e86b93bcd355f5017c25	0.617732	3.002894	false	false	false	false
marco-c/leon-nexys2	grlib-gpl-1.3.4-b4140/designs/leon3-digilent-nexys4/config.vhd	1	7,716	----------------------------------------------------------------------------- -- LEON3 Demonstration design test bench configuration -- Copyright (C) 2009 Aeroflex Gaisler ------------------------------------------------------------------------------ library techmap; use techmap.gencomp.all; package config is -- Technology and synthesis options constant CFG_FABTECH : integer := artix7; constant CFG_MEMTECH : integer := artix7; constant CFG_PADTECH : integer := artix7; constant CFG_NOASYNC : integer := 0; constant CFG_SCAN : integer := 0; -- Clock generator constant CFG_CLKTECH : integer := artix7; constant CFG_CLKMUL : integer := (10); constant CFG_CLKDIV : integer := (20); constant CFG_OCLKDIV : integer := 1; constant CFG_OCLKBDIV : integer := 0; constant CFG_OCLKCDIV : integer := 0; constant CFG_PCIDLL : integer := 0; constant CFG_PCISYSCLK: integer := 0; constant CFG_CLK_NOFB : integer := 0; -- LEON3 processor core constant CFG_LEON3 : integer := 1; constant CFG_NCPU : integer := (1); constant CFG_NWIN : integer := (8); constant CFG_V8 : integer := 16#32# + 40; constant CFG_MAC : integer := 0; constant CFG_BP : integer := 1; constant CFG_SVT : integer := 1; constant CFG_RSTADDR : integer := 16#00000#; constant CFG_LDDEL : integer := (1); constant CFG_NOTAG : integer := 1; constant CFG_NWP : integer := (0); constant CFG_PWD : integer := 02; constant CFG_FPU : integer := 0 + 160 + 320; constant CFG_GRFPUSH : integer := 0; constant CFG_ICEN : integer := 1; constant CFG_ISETS : integer := 2; constant CFG_ISETSZ : integer := 8; constant CFG_ILINE : integer := 4; constant CFG_IREPL : integer := 0; constant CFG_ILOCK : integer := 0; constant CFG_ILRAMEN : integer := 0; constant CFG_ILRAMADDR: integer := 16#8E#; constant CFG_ILRAMSZ : integer := 1; constant CFG_DCEN : integer := 1; constant CFG_DSETS : integer := 2; constant CFG_DSETSZ : integer := 4; constant CFG_DLINE : integer := 4; constant CFG_DREPL : integer := 0; constant CFG_DLOCK : integer := 0; constant CFG_DSNOOP : integer := 0 + 0 + 40; constant CFG_DFIXED : integer := 16#0#; constant CFG_DLRAMEN : integer := 0; constant CFG_DLRAMADDR: integer := 16#8F#; constant CFG_DLRAMSZ : integer := 1; constant CFG_MMUEN : integer := 0; constant CFG_ITLBNUM : integer := 2; constant CFG_DTLBNUM : integer := 2; constant CFG_TLB_TYPE : integer := 1 + 02; constant CFG_TLB_REP : integer := 1; constant CFG_MMU_PAGE : integer := 0; constant CFG_DSU : integer := 1; constant CFG_ITBSZ : integer := 2; constant CFG_ATBSZ : integer := 2; constant CFG_LEON3FT_EN : integer := 0; constant CFG_IUFT_EN : integer := 0; constant CFG_FPUFT_EN : integer := 0; constant CFG_RF_ERRINJ : integer := 0; constant CFG_CACHE_FT_EN : integer := 0; constant CFG_CACHE_ERRINJ : integer := 0; constant CFG_LEON3_NETLIST: integer := 0; constant CFG_DISAS : integer := 1 + 0; constant CFG_PCLOW : integer := 2; -- AMBA settings constant CFG_DEFMST : integer := (0); constant CFG_RROBIN : integer := 1; constant CFG_SPLIT : integer := 0; constant CFG_FPNPEN : integer := 1; constant CFG_AHBIO : integer := 16#FFF#; constant CFG_APBADDR : integer := 16#800#; constant CFG_AHB_MON : integer := 0; constant CFG_AHB_MONERR : integer := 0; constant CFG_AHB_MONWAR : integer := 0; constant CFG_AHB_DTRACE : integer := 0; -- DSU UART constant CFG_AHB_UART : integer := 1; -- JTAG based DSU interface constant CFG_AHB_JTAG : integer := 1; -- Ethernet DSU constant CFG_DSU_ETH : integer := 1 + 0 + 0; constant CFG_ETH_BUF : integer := 2; constant CFG_ETH_IPM : integer := 16#C0A8#; constant CFG_ETH_IPL : integer := 16#0033#; constant CFG_ETH_ENM : integer := 16#020000#; constant CFG_ETH_ENL : integer := 16#000000#; -- LEON2 memory controller constant CFG_MCTRL_LEON2 : integer := 1; constant CFG_MCTRL_RAM8BIT : integer := 0; constant CFG_MCTRL_RAM16BIT : integer := 1; constant CFG_MCTRL_5CS : integer := 0; constant CFG_MCTRL_SDEN : integer := 0; constant CFG_MCTRL_SEPBUS : integer := 0; constant CFG_MCTRL_INVCLK : integer := 0; constant CFG_MCTRL_SD64 : integer := 0; constant CFG_MCTRL_PAGE : integer := 0 + 0; -- DDR controller constant CFG_DDR2SP : integer := 0; constant CFG_DDR2SP_INIT : integer := 0; constant CFG_DDR2SP_FREQ : integer := 100; constant CFG_DDR2SP_TRFC : integer := 130; constant CFG_DDR2SP_DATAWIDTH : integer := 64; constant CFG_DDR2SP_FTEN : integer := 0; constant CFG_DDR2SP_FTWIDTH : integer := 0; constant CFG_DDR2SP_COL : integer := 9; constant CFG_DDR2SP_SIZE : integer := 8; constant CFG_DDR2SP_DELAY0 : integer := 0; constant CFG_DDR2SP_DELAY1 : integer := 0; constant CFG_DDR2SP_DELAY2 : integer := 0; constant CFG_DDR2SP_DELAY3 : integer := 0; constant CFG_DDR2SP_DELAY4 : integer := 0; constant CFG_DDR2SP_DELAY5 : integer := 0; constant CFG_DDR2SP_DELAY6 : integer := 0; constant CFG_DDR2SP_DELAY7 : integer := 0; constant CFG_DDR2SP_NOSYNC : integer := 0; -- Xilinx MIG constant CFG_MIG_DDR2 : integer := 1; constant CFG_MIG_RANKS : integer := (1); constant CFG_MIG_COLBITS : integer := (10); constant CFG_MIG_ROWBITS : integer := (13); constant CFG_MIG_BANKBITS: integer := (2); constant CFG_MIG_HMASK : integer := 16#F00#; -- AHB ROM constant CFG_AHBROMEN : integer := 1; constant CFG_AHBROPIP : integer := 0; constant CFG_AHBRODDR : integer := 16#000#; constant CFG_ROMADDR : integer := 16#100#; constant CFG_ROMMASK : integer := 16#E00# + 16#100#; -- AHB RAM constant CFG_AHBRAMEN : integer := 0; constant CFG_AHBRSZ : integer := 1; constant CFG_AHBRADDR : integer := 16#A00#; constant CFG_AHBRPIPE : integer := 0; -- Gaisler Ethernet core constant CFG_GRETH : integer := 1; constant CFG_GRETH1G : integer := 0; constant CFG_ETH_FIFO : integer := 4; -- UART 1 constant CFG_UART1_ENABLE : integer := 1; constant CFG_UART1_FIFO : integer := 1; -- LEON3 interrupt controller constant CFG_IRQ3_ENABLE : integer := 1; constant CFG_IRQ3_NSEC : integer := 0; -- Modular timer constant CFG_GPT_ENABLE : integer := 1; constant CFG_GPT_NTIM : integer := (2); constant CFG_GPT_SW : integer := (8); constant CFG_GPT_TW : integer := (32); constant CFG_GPT_IRQ : integer := (8); constant CFG_GPT_SEPIRQ : integer := 1; constant CFG_GPT_WDOGEN : integer := 0; constant CFG_GPT_WDOG : integer := 16#0#; -- GPIO port constant CFG_GRGPIO_ENABLE : integer := 1; constant CFG_GRGPIO_IMASK : integer := 16#0000#; constant CFG_GRGPIO_WIDTH : integer := (8); -- SPI memory controller constant CFG_SPIMCTRL : integer := 0; constant CFG_SPIMCTRL_SDCARD : integer := 0; constant CFG_SPIMCTRL_READCMD : integer := 16#0#; constant CFG_SPIMCTRL_DUMMYBYTE : integer := 0; constant CFG_SPIMCTRL_DUALOUTPUT : integer := 0; constant CFG_SPIMCTRL_SCALER : integer := 1; constant CFG_SPIMCTRL_ASCALER : integer := 1; constant CFG_SPIMCTRL_PWRUPCNT : integer := 0; constant CFG_SPIMCTRL_OFFSET : integer := 16#0#; -- SPI controller constant CFG_SPICTRL_ENABLE : integer := 0; constant CFG_SPICTRL_NUM : integer := 1; constant CFG_SPICTRL_SLVS : integer := 1; constant CFG_SPICTRL_FIFO : integer := 1; constant CFG_SPICTRL_SLVREG : integer := 0; constant CFG_SPICTRL_ODMODE : integer := 0; constant CFG_SPICTRL_AM : integer := 0; constant CFG_SPICTRL_ASEL : integer := 0; constant CFG_SPICTRL_TWEN : integer := 0; constant CFG_SPICTRL_MAXWLEN : integer := 0; constant CFG_SPICTRL_SYNCRAM : integer := 0; constant CFG_SPICTRL_FT : integer := 0; -- GRLIB debugging constant CFG_DUART : integer := 1; end;	gpl-2.0	ffac693043ecfe0ca72e94b345579e7c	0.653836	3.577191	false	false	false	false
marco-c/leon-nexys2	grlib-gpl-1.3.4-b4140/designs/leon3-terasic-de2-115/config.vhd	1	6,811	----------------------------------------------------------------------------- -- LEON3 Demonstration design test bench configuration -- Copyright (C) 2009 Aeroflex Gaisler ------------------------------------------------------------------------------ library techmap; use techmap.gencomp.all; package config is -- Technology and synthesis options constant CFG_FABTECH : integer := cyclone3; constant CFG_MEMTECH : integer := cyclone3; constant CFG_PADTECH : integer := cyclone3; constant CFG_NOASYNC : integer := 0; constant CFG_SCAN : integer := 0; -- Clock generator constant CFG_CLKTECH : integer := cyclone3; constant CFG_CLKMUL : integer := (5); constant CFG_CLKDIV : integer := (5); constant CFG_OCLKDIV : integer := 1; constant CFG_OCLKBDIV : integer := 0; constant CFG_OCLKCDIV : integer := 0; constant CFG_PCIDLL : integer := 0; constant CFG_PCISYSCLK: integer := 0; constant CFG_CLK_NOFB : integer := 0; -- LEON3 processor core constant CFG_LEON3 : integer := 1; constant CFG_NCPU : integer := (1); constant CFG_NWIN : integer := (8); constant CFG_V8 : integer := 16#32# + 40; constant CFG_MAC : integer := 0; constant CFG_BP : integer := 1; constant CFG_SVT : integer := 1; constant CFG_RSTADDR : integer := 16#00000#; constant CFG_LDDEL : integer := (1); constant CFG_NOTAG : integer := 0; constant CFG_NWP : integer := (2); constant CFG_PWD : integer := 12; constant CFG_FPU : integer := 0 + 160 + 320; constant CFG_GRFPUSH : integer := 0; constant CFG_ICEN : integer := 1; constant CFG_ISETS : integer := 4; constant CFG_ISETSZ : integer := 4; constant CFG_ILINE : integer := 8; constant CFG_IREPL : integer := 0; constant CFG_ILOCK : integer := 0; constant CFG_ILRAMEN : integer := 0; constant CFG_ILRAMADDR: integer := 16#8E#; constant CFG_ILRAMSZ : integer := 1; constant CFG_DCEN : integer := 1; constant CFG_DSETS : integer := 4; constant CFG_DSETSZ : integer := 4; constant CFG_DLINE : integer := 4; constant CFG_DREPL : integer := 0; constant CFG_DLOCK : integer := 0; constant CFG_DSNOOP : integer := 1 + 1 + 41; constant CFG_DFIXED : integer := 16#0#; constant CFG_DLRAMEN : integer := 0; constant CFG_DLRAMADDR: integer := 16#8F#; constant CFG_DLRAMSZ : integer := 1; constant CFG_MMUEN : integer := 1; constant CFG_ITLBNUM : integer := 8; constant CFG_DTLBNUM : integer := 8; constant CFG_TLB_TYPE : integer := 0 + 12; constant CFG_TLB_REP : integer := 0; constant CFG_MMU_PAGE : integer := 0; constant CFG_DSU : integer := 1; constant CFG_ITBSZ : integer := 2; constant CFG_ATBSZ : integer := 2; constant CFG_LEON3FT_EN : integer := 0; constant CFG_IUFT_EN : integer := 0; constant CFG_FPUFT_EN : integer := 0; constant CFG_RF_ERRINJ : integer := 0; constant CFG_CACHE_FT_EN : integer := 0; constant CFG_CACHE_ERRINJ : integer := 0; constant CFG_LEON3_NETLIST: integer := 0; constant CFG_DISAS : integer := 0 + 0; constant CFG_PCLOW : integer := 2; -- AMBA settings constant CFG_DEFMST : integer := (0); constant CFG_RROBIN : integer := 1; constant CFG_SPLIT : integer := 0; constant CFG_FPNPEN : integer := 0; constant CFG_AHBIO : integer := 16#FFF#; constant CFG_APBADDR : integer := 16#800#; constant CFG_AHB_MON : integer := 0; constant CFG_AHB_MONERR : integer := 0; constant CFG_AHB_MONWAR : integer := 0; constant CFG_AHB_DTRACE : integer := 0; -- DSU UART constant CFG_AHB_UART : integer := 1; -- JTAG based DSU interface constant CFG_AHB_JTAG : integer := 1; -- Ethernet DSU constant CFG_DSU_ETH : integer := 1 + 0 + 0; constant CFG_ETH_BUF : integer := 2; constant CFG_ETH_IPM : integer := 16#C0A8#; constant CFG_ETH_IPL : integer := 16#0033#; constant CFG_ETH_ENM : integer := 16#020000#; constant CFG_ETH_ENL : integer := 16#0d0007#; -- LEON2 memory controller constant CFG_MCTRL_LEON2 : integer := 1; constant CFG_MCTRL_RAM8BIT : integer := 1; constant CFG_MCTRL_RAM16BIT : integer := 0; constant CFG_MCTRL_5CS : integer := 0; constant CFG_MCTRL_SDEN : integer := 1; constant CFG_MCTRL_SEPBUS : integer := 1; constant CFG_MCTRL_INVCLK : integer := 0; constant CFG_MCTRL_SD64 : integer := 0; constant CFG_MCTRL_PAGE : integer := 0 + 0; -- AHB status register constant CFG_AHBSTAT : integer := 1; constant CFG_AHBSTATN : integer := (1); -- AHB RAM constant CFG_AHBRAMEN : integer := 0; constant CFG_AHBRSZ : integer := 1; constant CFG_AHBRADDR : integer := 16#A00#; constant CFG_AHBRPIPE : integer := 0; -- Gaisler Ethernet core constant CFG_GRETH : integer := 1; constant CFG_GRETH1G : integer := 0; constant CFG_ETH_FIFO : integer := 32; -- CAN 2.0 interface constant CFG_CAN : integer := 0; constant CFG_CAN_NUM : integer := 1; constant CFG_CANIO : integer := 16#0#; constant CFG_CANIRQ : integer := 0; constant CFG_CANSEPIRQ: integer := 0; constant CFG_CAN_SYNCRST : integer := 0; constant CFG_CANFT : integer := 0; -- SPI controller constant CFG_SPICTRL_ENABLE : integer := 1; constant CFG_SPICTRL_NUM : integer := (1); constant CFG_SPICTRL_SLVS : integer := (1); constant CFG_SPICTRL_FIFO : integer := (2); constant CFG_SPICTRL_SLVREG : integer := 1; constant CFG_SPICTRL_ODMODE : integer := 1; constant CFG_SPICTRL_AM : integer := 0; constant CFG_SPICTRL_ASEL : integer := 0; constant CFG_SPICTRL_TWEN : integer := 1; constant CFG_SPICTRL_MAXWLEN : integer := (0); constant CFG_SPICTRL_SYNCRAM : integer := 1; constant CFG_SPICTRL_FT : integer := 0; -- SPI to AHB bridge constant CFG_SPI2AHB : integer := 0; constant CFG_SPI2AHB_APB : integer := 0; constant CFG_SPI2AHB_ADDRH : integer := 16#0#; constant CFG_SPI2AHB_ADDRL : integer := 16#0#; constant CFG_SPI2AHB_MASKH : integer := 16#0#; constant CFG_SPI2AHB_MASKL : integer := 16#0#; constant CFG_SPI2AHB_RESEN : integer := 0; constant CFG_SPI2AHB_FILTER : integer := 2; constant CFG_SPI2AHB_CPOL : integer := 0; constant CFG_SPI2AHB_CPHA : integer := 0; -- UART 1 constant CFG_UART1_ENABLE : integer := 1; constant CFG_UART1_FIFO : integer := 4; -- LEON3 interrupt controller constant CFG_IRQ3_ENABLE : integer := 1; constant CFG_IRQ3_NSEC : integer := 0; -- Modular timer constant CFG_GPT_ENABLE : integer := 1; constant CFG_GPT_NTIM : integer := (2); constant CFG_GPT_SW : integer := (16); constant CFG_GPT_TW : integer := (32); constant CFG_GPT_IRQ : integer := (8); constant CFG_GPT_SEPIRQ : integer := 1; constant CFG_GPT_WDOGEN : integer := 0; constant CFG_GPT_WDOG : integer := 16#0#; -- GPIO port constant CFG_GRGPIO_ENABLE : integer := 1; constant CFG_GRGPIO_IMASK : integer := 16#fe#; constant CFG_GRGPIO_WIDTH : integer := (32); -- GRLIB debugging constant CFG_DUART : integer := 0; end;	gpl-2.0	18a0146aa5da1eace81484ea15ac513c	0.648069	3.582851	false	false	false	false
marco-c/leon-nexys2	grlib-gpl-1.3.4-b4140/lib/openchip/sui/apbsui.vhd	3	5,854	---------------------------------------------------------------------------- -- This file is a part of the GRLIB VHDL IP LIBRARY -- Copyright (C) 2004 GAISLER RESEARCH -- -- This program is free software; you can redistribute it and/or modify -- it under the terms of the GNU General Public License as published by -- the Free Software Foundation; either version 2 of the License, or -- (at your option) any later version. -- -- See the file COPYING for the full details of the license. -- ----------------------------------------------------------------------------- -- Entity: sui -- File: apbsui.vhd -- Author: Antti Lukats, OpenChip -- Description: Simple User Interface -- -- Single Peripheral containting the following: -- Input: -- Switches 0..31 -- Buttons 0..31 -- Output -- LED 7 Segment, 4 digits non multiplexed, 32 digits in multiplexed mode -- Single LED 0..31 -- Buzzer -- Character LCD -- -- Version 0: All functions are software assisted, IP Core has minimal -- intelligence providing bit-bang access to all the connected hardware -- -- -- -- -- -- -- -- ------------------------------------------------------------------------------ library ieee; use ieee.std_logic_1164.all; library grlib; use grlib.amba.all; use grlib.stdlib.all; use grlib.devices.all; library openchip; use openchip.sui.all; --pragma translate_off use std.textio.all; --pragma translate_on entity apbsui is generic ( pindex : integer := 0; paddr : integer := 0; pmask : integer := 16#fff#; pirq : integer := 0; -- active level for Segment LED segments led7act : integer := 1; -- active level for single LED's ledact : integer := 1); port ( rst : in std_ulogic; clk : in std_ulogic; apbi : in apb_slv_in_type; apbo : out apb_slv_out_type; suii : in sui_in_type; suio : out sui_out_type); end; architecture rtl of apbsui is constant REVISION : integer := 0; constant pconfig : apb_config_type := ( 0 => ahb_device_reg ( VENDOR_OPENCHIP, OPENCHIP_APBSUI, 0, REVISION, pirq), 1 => apb_iobar(paddr, pmask)); type suiregs is record ledreg : std_logic_vector(31 downto 0); -- Output Latch, single LEDs led7reg : std_logic_vector(31 downto 0); -- Output Latch, 7 Seg LEDs lcdreg : std_logic_vector(15 downto 0); -- Output Latch LCD buzreg : std_logic_vector(0 downto 0); -- Buzzer sw_inreg : std_logic_vector(31 downto 0); -- Switches in btn_inreg : std_logic_vector(31 downto 0); -- Buttons in irq : std_ulogic; -- interrupt (internal), not used end record; signal r, rin : suiregs; begin comb : process(rst, r, apbi, suii ) variable rdata : std_logic_vector(31 downto 0); variable irq : std_logic_vector(NAHBIRQ-1 downto 0); variable v : suiregs; begin v := r; v.sw_inreg := suii.switch_in; v.btn_inreg := suii.button_in; irq := (others => '0'); --irq(pirq) := r.irq; v.irq := '0'; rdata := (others => '0'); -- read/write registers case apbi.paddr(4 downto 2) is when "100" => rdata(31 downto 0) := r.sw_inreg; -- read switches when "101" => rdata(31 downto 0) := r.btn_inreg; -- read buttons when others => end case; if (apbi.psel(pindex) and apbi.penable and apbi.pwrite) = '1' then case apbi.paddr(4 downto 2) is when "000" => v.ledreg := apbi.pwdata(31 downto 0); when "001" => v.led7reg := apbi.pwdata(31 downto 0); when "010" => v.lcdreg(15 downto 0) := apbi.pwdata(15 downto 0); when "011" => v.buzreg(0) := apbi.pwdata(0); when others => end case; end if; -- reset operation if rst = '0' then v.ledreg := (others => '0'); v.led7reg := (others => '0'); end if; -- update registers rin <= v; -- drive outputs suio.lcd_out <= r.lcdreg(7 downto 0); suio.lcd_en <= r.lcdreg(11 downto 8); suio.lcd_rs <= r.lcdreg(12); suio.lcd_r_wn <= r.lcdreg(13); suio.lcd_backlight <= r.lcdreg(14); suio.lcd_oe <= r.lcdreg(15); suio.buzzer <= r.buzreg(0); suio.led_out <= r.ledreg; suio.led_a_out(0) <= r.led7reg(0); suio.led_b_out(0) <= r.led7reg(1); suio.led_c_out(0) <= r.led7reg(2); suio.led_d_out(0) <= r.led7reg(3); suio.led_e_out(0) <= r.led7reg(4); suio.led_f_out(0) <= r.led7reg(5); suio.led_g_out(0) <= r.led7reg(6); suio.led_dp_out(0) <= r.led7reg(7); suio.led_a_out(1) <= r.led7reg(8); suio.led_b_out(1) <= r.led7reg(9); suio.led_c_out(1) <= r.led7reg(10); suio.led_d_out(1) <= r.led7reg(11); suio.led_e_out(1) <= r.led7reg(12); suio.led_f_out(1) <= r.led7reg(13); suio.led_g_out(1) <= r.led7reg(14); suio.led_dp_out(1) <= r.led7reg(15); suio.led_a_out(2) <= r.led7reg(16); suio.led_b_out(2) <= r.led7reg(17); suio.led_c_out(2) <= r.led7reg(18); suio.led_d_out(2) <= r.led7reg(19); suio.led_e_out(2) <= r.led7reg(20); suio.led_f_out(2) <= r.led7reg(21); suio.led_g_out(2) <= r.led7reg(22); suio.led_dp_out(2) <= r.led7reg(23); suio.led_a_out(3) <= r.led7reg(24); suio.led_b_out(3) <= r.led7reg(25); suio.led_c_out(3) <= r.led7reg(26); suio.led_d_out(3) <= r.led7reg(27); suio.led_e_out(3) <= r.led7reg(28); suio.led_f_out(3) <= r.led7reg(29); suio.led_g_out(3) <= r.led7reg(30); suio.led_dp_out(3) <= r.led7reg(31); apbo.prdata <= rdata; apbo.pirq <= irq; apbo.pindex <= pindex; end process; apbo.pconfig <= pconfig; regs : process(clk) begin if rising_edge(clk) then r <= rin; end if; end process; -- pragma translate_off bootmsg : report_version generic map ("apbsui" & tost(pindex) & ": SUI rev " & tost(REVISION) & ", irq " & tost(pirq)); -- pragma translate_on end;	gpl-2.0	5e297fc5a1e962c7915a5d71a917af30	0.572429	2.800957	false	false	false	false
marco-c/leon-nexys2	grlib-gpl-1.3.4-b4140/designs/leon3-asic/config.vhd	1	7,517	----------------------------------------------------------------------------- -- LEON3 Demonstration design test bench configuration -- Copyright (C) 2013 Aeroflex Gaisler ------------------------------------------------------------------------------ library techmap; use techmap.gencomp.all; package config is -- Technology and synthesis options constant CFG_FABTECH : integer := saed32; constant CFG_MEMTECH : integer := saed32; constant CFG_PADTECH : integer := saed32; constant CFG_NOASYNC : integer := 1; constant CFG_SCAN : integer := 1; -- JTAG boundary-scan chain constant CFG_BOUNDSCAN_EN : integer := 0; -- Clock generator constant CFG_CLKTECH : integer := saed32; constant CFG_CLKMUL : integer := 2; constant CFG_CLKDIV : integer := 2; constant CFG_OCLKDIV : integer := 1; constant CFG_OCLKBDIV : integer := 0; constant CFG_OCLKCDIV : integer := 0; constant CFG_PCIDLL : integer := 0; constant CFG_PCISYSCLK: integer := 0; constant CFG_CLK_NOFB : integer := 0; -- LEON3 processor core constant CFG_LEON3 : integer := 1; constant CFG_NCPU : integer := (1); constant CFG_NWIN : integer := (8); constant CFG_V8 : integer := 2 + 40; constant CFG_MAC : integer := 0; constant CFG_BP : integer := 1; constant CFG_SVT : integer := 1; constant CFG_RSTADDR : integer := 16#00000#; constant CFG_LDDEL : integer := (1); constant CFG_NOTAG : integer := 0; constant CFG_NWP : integer := (2); constant CFG_PWD : integer := 12; constant CFG_FPU : integer := 0 + 160 + 320; constant CFG_GRFPUSH : integer := 0; constant CFG_ICEN : integer := 1; constant CFG_ISETS : integer := 1; constant CFG_ISETSZ : integer := 4; constant CFG_ILINE : integer := 8; constant CFG_IREPL : integer := 0; constant CFG_ILOCK : integer := 0; constant CFG_ILRAMEN : integer := 0; constant CFG_ILRAMADDR: integer := 16#8E#; constant CFG_ILRAMSZ : integer := 1; constant CFG_DCEN : integer := 1; constant CFG_DSETS : integer := 1; constant CFG_DSETSZ : integer := 4; constant CFG_DLINE : integer := 8; constant CFG_DREPL : integer := 0; constant CFG_DLOCK : integer := 0; constant CFG_DSNOOP : integer := 0 + 0 + 40; constant CFG_DFIXED : integer := 16#0#; constant CFG_DLRAMEN : integer := 0; constant CFG_DLRAMADDR: integer := 16#8F#; constant CFG_DLRAMSZ : integer := 1; constant CFG_MMUEN : integer := 0; constant CFG_ITLBNUM : integer := 2; constant CFG_DTLBNUM : integer := 2; constant CFG_TLB_TYPE : integer := 1 + 02; constant CFG_TLB_REP : integer := 1; constant CFG_MMU_PAGE : integer := 0; constant CFG_DSU : integer := 1; constant CFG_ITBSZ : integer := 1; constant CFG_ATBSZ : integer := 1; constant CFG_LEON3FT_EN : integer := 0; constant CFG_IUFT_EN : integer := 0; constant CFG_FPUFT_EN : integer := 0; constant CFG_RF_ERRINJ : integer := 0; constant CFG_CACHE_FT_EN : integer := 0; constant CFG_CACHE_ERRINJ : integer := 0; constant CFG_LEON3_NETLIST: integer := 0; constant CFG_DISAS : integer := 0 + 0; constant CFG_PCLOW : integer := 2; -- AMBA settings constant CFG_DEFMST : integer := (0); constant CFG_RROBIN : integer := 1; constant CFG_SPLIT : integer := 0; constant CFG_FPNPEN : integer := 0; constant CFG_AHBIO : integer := 16#FFF#; constant CFG_APBADDR : integer := 16#800#; constant CFG_AHB_MON : integer := 0; constant CFG_AHB_MONERR : integer := 0; constant CFG_AHB_MONWAR : integer := 0; constant CFG_AHB_DTRACE : integer := 0; -- DSU UART constant CFG_AHB_UART : integer := 1; -- JTAG based DSU interface constant CFG_AHB_JTAG : integer := 0; -- Ethernet DSU constant CFG_DSU_ETH : integer := 0 + 0 + 0; constant CFG_ETH_BUF : integer := 1; constant CFG_ETH_IPM : integer := 16#C0A8#; constant CFG_ETH_IPL : integer := 16#0033#; constant CFG_ETH_ENM : integer := 16#020000#; constant CFG_ETH_ENL : integer := 16#000009#; -- LEON2 memory controller constant CFG_MCTRL_LEON2 : integer := 1; constant CFG_MCTRL_RAM8BIT : integer := 1; constant CFG_MCTRL_RAM16BIT : integer := 0; constant CFG_MCTRL_5CS : integer := 0; constant CFG_MCTRL_SDEN : integer := 1; constant CFG_MCTRL_SEPBUS : integer := 0; constant CFG_MCTRL_INVCLK : integer := 0; constant CFG_MCTRL_SD64 : integer := 0; constant CFG_MCTRL_PAGE : integer := 0 + 0; -- AHB status register constant CFG_AHBSTAT : integer := 1; constant CFG_AHBSTATN : integer := (1); -- Spacewire interface constant CFG_SPW_EN : integer := 0; constant CFG_SPW_NUM : integer := 1; constant CFG_SPW_AHBFIFO : integer := 4; constant CFG_SPW_RXFIFO : integer := 16; constant CFG_SPW_RMAP : integer := 0; constant CFG_SPW_RMAPBUF : integer := 4; constant CFG_SPW_RMAPCRC : integer := 0; constant CFG_SPW_NETLIST : integer := 0; constant CFG_SPW_FT : integer := 0; constant CFG_SPW_GRSPW : integer := 2; constant CFG_SPW_RXUNAL : integer := 0; constant CFG_SPW_DMACHAN : integer := 1; constant CFG_SPW_PORTS : integer := 1; constant CFG_SPW_INPUT : integer := 2; constant CFG_SPW_OUTPUT : integer := 0; constant CFG_SPW_RTSAME : integer := 0; -- Gaisler Ethernet core constant CFG_GRETH : integer := 1; constant CFG_GRETH1G : integer := 0; constant CFG_ETH_FIFO : integer := 8; -- SPI memory controller constant CFG_SPIMCTRL : integer := 0; constant CFG_SPIMCTRL_SDCARD : integer := 0; constant CFG_SPIMCTRL_READCMD : integer := 16#0#; constant CFG_SPIMCTRL_DUMMYBYTE : integer := 0; constant CFG_SPIMCTRL_DUALOUTPUT : integer := 0; constant CFG_SPIMCTRL_SCALER : integer := 1; constant CFG_SPIMCTRL_ASCALER : integer := 1; constant CFG_SPIMCTRL_PWRUPCNT : integer := 0; constant CFG_SPIMCTRL_OFFSET : integer := 16#0#; -- SPI controller constant CFG_SPICTRL_ENABLE : integer := 1; constant CFG_SPICTRL_NUM : integer := (1); constant CFG_SPICTRL_SLVS : integer := (6); constant CFG_SPICTRL_FIFO : integer := (4); constant CFG_SPICTRL_SLVREG : integer := 1; constant CFG_SPICTRL_ODMODE : integer := 0; constant CFG_SPICTRL_AM : integer := 0; constant CFG_SPICTRL_ASEL : integer := 0; constant CFG_SPICTRL_TWEN : integer := 0; constant CFG_SPICTRL_MAXWLEN : integer := (0); constant CFG_SPICTRL_SYNCRAM : integer := 0; constant CFG_SPICTRL_FT : integer := 0; -- CAN 2.0 interface constant CFG_CAN : integer := 0; constant CFG_CAN_NUM : integer := 1; constant CFG_CANIO : integer := 16#0#; constant CFG_CANIRQ : integer := 0; constant CFG_CANSEPIRQ: integer := 0; constant CFG_CAN_SYNCRST : integer := 0; constant CFG_CANFT : integer := 0; -- UART 1 constant CFG_UART1_ENABLE : integer := 1; constant CFG_UART1_FIFO : integer := 4; -- UART 2 constant CFG_UART2_ENABLE : integer := 1; constant CFG_UART2_FIFO : integer := 4; -- LEON3 interrupt controller constant CFG_IRQ3_ENABLE : integer := 1; constant CFG_IRQ3_NSEC : integer := 0; -- Modular timer constant CFG_GPT_ENABLE : integer := 1; constant CFG_GPT_NTIM : integer := (4); constant CFG_GPT_SW : integer := (12); constant CFG_GPT_TW : integer := (32); constant CFG_GPT_IRQ : integer := (6); constant CFG_GPT_SEPIRQ : integer := 1; constant CFG_GPT_WDOGEN : integer := 1; constant CFG_GPT_WDOG : integer := 16#FFFFF#; -- GPIO port constant CFG_GRGPIO_ENABLE : integer := 1; constant CFG_GRGPIO_IMASK : integer := 16#FE#; constant CFG_GRGPIO_WIDTH : integer := (16); -- I2C master constant CFG_I2C_ENABLE : integer := 1; -- GRLIB debugging constant CFG_DUART : integer := 0; end;	gpl-2.0	8064b9bb4555c1b609cdd60b728670b1	0.65159	3.624397	false	false	false	false
mistryalok/Zedboard	learning/training/MSD/s09/axi_dma_sg/vivado/project_1/project_1.srcs/sources_1/ipshared/xilinx.com/axi_sg_v4_1/0535f152/hdl/src/vhdl/axi_sg_ftch_noqueue.vhd	3	24,145	-- *********************************************************************** -- -- (c) Copyright 2010-2011 Xilinx, Inc. All rights reserved. -- -- This file contains confidential and proprietary information -- of Xilinx, Inc. and is protected under U.S. and -- international copyright and other intellectual property -- laws. -- -- DISCLAIMER -- This disclaimer is not a license and does not grant any -- rights to the materials distributed herewith. Except as -- otherwise provided in a valid license issued to you by -- Xilinx, and to the maximum extent permitted by applicable -- law: (1) THESE MATERIALS ARE MADE AVAILABLE "AS IS" AND -- WITH ALL FAULTS, AND XILINX HEREBY DISCLAIMS ALL WARRANTIES -- AND CONDITIONS, EXPRESS, IMPLIED, OR STATUTORY, INCLUDING -- BUT NOT LIMITED TO WARRANTIES OF MERCHANTABILITY, NON- -- INFRINGEMENT, OR FITNESS FOR ANY PARTICULAR PURPOSE; and -- (2) Xilinx shall not be liable (whether in contract or tort, -- including negligence, or under any other theory of -- liability) for any loss or damage of any kind or nature -- related to, arising under or in connection with these -- materials, including for any direct, or any indirect, -- special, incidental, or consequential loss or damage -- (including loss of data, profits, goodwill, or any type of -- loss or damage suffered as a result of any action brought -- by a third party) even if such damage or loss was -- reasonably foreseeable or Xilinx had been advised of the -- possibility of the same. -- -- CRITICAL APPLICATIONS -- Xilinx products are not designed or intended to be fail- -- safe, or for use in any application requiring fail-safe -- performance, such as life-support or safety devices or -- systems, Class III medical devices, nuclear facilities, -- applications related to the deployment of airbags, or any -- other applications that could lead to death, personal -- injury, or severe property or environmental damage -- (individually and collectively, "Critical -- Applications"). Customer assumes the sole risk and -- liability of any use of Xilinx products in Critical -- Applications, subject only to applicable laws and -- regulations governing limitations on product liability. -- -- THIS COPYRIGHT NOTICE AND DISCLAIMER MUST BE RETAINED AS -- PART OF THIS FILE AT ALL TIMES. -- -- *********************************************************************** -- ------------------------------------------------------------------------------- -- Filename: axi_sg_ftch_noqueue.vhd -- Description: This entity is the no queue version -- -- VHDL-Standard: VHDL'93 ------------------------------------------------------------------------------- library ieee; use ieee.std_logic_1164.all; use ieee.numeric_std.all; use ieee.std_logic_misc.all; library axi_sg_v4_1; use axi_sg_v4_1.axi_sg_pkg.all; library lib_pkg_v1_0; use lib_pkg_v1_0.lib_pkg.all; ------------------------------------------------------------------------------- entity axi_sg_ftch_noqueue is generic ( C_M_AXI_SG_ADDR_WIDTH : integer range 32 to 64 := 32; -- Master AXI Memory Map Address Width C_M_AXIS_SG_TDATA_WIDTH : integer range 32 to 32 := 32; -- Master AXI Stream Data Width C_ENABLE_MULTI_CHANNEL : integer range 0 to 1 := 0; C_AXIS_IS_ASYNC : integer range 0 to 1 := 0; C_ASYNC : integer range 0 to 1 := 0; C_SG_WORDS_TO_FETCH : integer range 8 to 13 := 8; C_ENABLE_CDMA : integer range 0 to 1 := 0; C_ENABLE_CH1 : integer range 0 to 1 := 0; C_FAMILY : string := "virtex7" -- Device family used for proper BRAM selection ); port ( ----------------------------------------------------------------------- -- AXI Scatter Gather Interface ----------------------------------------------------------------------- m_axi_sg_aclk : in std_logic ; -- m_axi_primary_aclk : in std_logic ; m_axi_sg_aresetn : in std_logic ; -- p_reset_n : in std_logic ; -- -- Channel Control -- desc_flush : in std_logic ; -- ch1_cntrl_strm_stop : in std_logic ; ftch_active : in std_logic ; -- ftch_queue_empty : out std_logic ; -- ftch_queue_full : out std_logic ; -- sof_ftch_desc : in std_logic ; desc2_flush : in std_logic ; -- ftch2_active : in std_logic ; -- ftch2_queue_empty : out std_logic ; -- ftch2_queue_full : out std_logic ; -- -- writing_nxtdesc_in : in std_logic ; -- writing_curdesc_out : out std_logic ; -- writing2_curdesc_out : out std_logic ; -- -- DataMover Command -- ftch_cmnd_wr : in std_logic ; -- ftch_cmnd_data : in std_logic_vector -- ((C_M_AXI_SG_ADDR_WIDTH+CMD_BASE_WIDTH)-1 downto 0); -- -- -- MM2S Stream In from DataMover -- m_axis_mm2s_tdata : in std_logic_vector -- (C_M_AXIS_SG_TDATA_WIDTH-1 downto 0) ; -- m_axis_mm2s_tlast : in std_logic ; -- m_axis_mm2s_tvalid : in std_logic ; -- m_axis_mm2s_tready : out std_logic ; -- m_axis2_mm2s_tready : out std_logic ; -- data_concat : in std_logic_vector -- (95 downto 0) ; -- data_concat_mcdma : in std_logic_vector -- (63 downto 0) ; -- next_bd : in std_logic_vector (31 downto 0); data_concat_tlast : in std_logic ; -- data_concat_valid : in std_logic ; -- -- -- Channel 1 AXI Fetch Stream Out -- m_axis_ftch_tdata : out std_logic_vector -- (C_M_AXIS_SG_TDATA_WIDTH-1 downto 0) ; -- m_axis_ftch_tvalid : out std_logic ; -- m_axis_ftch_tready : in std_logic ; -- m_axis_ftch_tlast : out std_logic ; -- m_axis_ftch_tdata_new : out std_logic_vector -- (96+31C_ENABLE_CDMA downto 0); -- m_axis_ftch_tdata_mcdma_new : out std_logic_vector -- (63 downto 0); -- m_axis_ftch_tvalid_new : out std_logic ; -- m_axis_ftch_desc_available : out std_logic ; m_axis2_ftch_tdata : out std_logic_vector -- (C_M_AXIS_SG_TDATA_WIDTH-1 downto 0) ; -- m_axis2_ftch_tvalid : out std_logic ; -- m_axis2_ftch_tready : in std_logic ; -- m_axis2_ftch_tlast : out std_logic ; -- m_axis2_ftch_tdata_new : out std_logic_vector -- (96+31C_ENABLE_CDMA downto 0); -- m_axis2_ftch_tdata_mcdma_new : out std_logic_vector -- (63 downto 0); -- m_axis2_ftch_tdata_mcdma_nxt : out std_logic_vector -- (31 downto 0); -- m_axis2_ftch_tvalid_new : out std_logic ; -- m_axis2_ftch_desc_available : out std_logic ; m_axis_mm2s_cntrl_tdata : out std_logic_vector -- (31 downto 0); -- m_axis_mm2s_cntrl_tkeep : out std_logic_vector -- (3 downto 0); -- m_axis_mm2s_cntrl_tvalid : out std_logic ; -- m_axis_mm2s_cntrl_tready : in std_logic := '0'; -- m_axis_mm2s_cntrl_tlast : out std_logic -- ); end axi_sg_ftch_noqueue; ------------------------------------------------------------------------------- -- Architecture ------------------------------------------------------------------------------- architecture implementation of axi_sg_ftch_noqueue is attribute DowngradeIPIdentifiedWarnings: string; attribute DowngradeIPIdentifiedWarnings of implementation : architecture is "yes"; ------------------------------------------------------------------------------- -- Functions ------------------------------------------------------------------------------- -- No Functions Declared ------------------------------------------------------------------------------- -- Constants Declarations ------------------------------------------------------------------------------- -- No Constants Declared ------------------------------------------------------------------------------- -- Signal / Type Declarations ------------------------------------------------------------------------------- -- Channel 1 internal signals signal curdesc_tdata : std_logic_vector (C_M_AXIS_SG_TDATA_WIDTH-1 downto 0) := (others => '0'); signal curdesc_tvalid : std_logic := '0'; signal ftch_tvalid : std_logic := '0'; signal ftch_tdata : std_logic_vector (C_M_AXIS_SG_TDATA_WIDTH-1 downto 0) := (others => '0'); signal ftch_tlast : std_logic := '0'; signal ftch_tready : std_logic := '0'; -- Misc Signals signal writing_curdesc : std_logic := '0'; signal writing_nxtdesc : std_logic := '0'; signal msb_curdesc : std_logic_vector(31 downto 0) := (others => '0'); signal writing_lsb : std_logic := '0'; signal writing_msb : std_logic := '0'; signal ftch_active_int : std_logic := '0'; signal ftch_tvalid_mult : std_logic := '0'; signal ftch_tdata_mult : std_logic_vector (C_M_AXIS_SG_TDATA_WIDTH-1 downto 0) := (others => '0'); signal ftch_tlast_mult : std_logic := '0'; signal counter : std_logic_vector (3 downto 0) := (others => '0'); signal wr_cntl : std_logic := '0'; signal ftch_tdata_new : std_logic_vector (96+31*C_ENABLE_CDMA downto 0); signal queue_wren, queue_rden : std_logic := '0'; signal queue_din : std_logic_vector (32 downto 0); signal queue_dout : std_logic_vector (32 downto 0); signal queue_empty, queue_full : std_logic := '0'; signal sof_ftch_desc_del, sof_ftch_desc_pulse : std_logic := '0'; signal sof_ftch_desc_del1 : std_logic := '0'; signal queue_sinit : std_logic := '0'; signal data_concat_mcdma_nxt : std_logic_vector (31 downto 0) := (others => '0'); signal current_bd : std_logic_vector (31 downto 0) := (others => '0'); ------------------------------------------------------------------------------- -- Begin architecture logic ------------------------------------------------------------------------------- begin queue_sinit <= not m_axi_sg_aresetn; ftch_active_int <= ftch_active or ftch2_active; CDMA_FIELDS : if C_ENABLE_CDMA = 1 generate begin ftch_tdata_new (95 downto 0) <= data_concat;-- when (ftch_active = '1') else (others =>'0'); ftch_tdata_new (127 downto 96) <= current_bd; end generate CDMA_FIELDS; DMA_FIELDS : if C_ENABLE_CDMA = 0 generate begin ftch_tdata_new (64 downto 0) <= data_concat (95) & data_concat (63 downto 0);-- when (ftch_active = '1') else (others =>'0'); ftch_tdata_new (96 downto 65) <= current_bd; end generate DMA_FIELDS; --------------------------------------------------------------------------- -- Write current descriptor to FIFO or out channel port --------------------------------------------------------------------------- NXT_BD_MCDMA : if C_ENABLE_MULTI_CHANNEL = 1 generate begin NEXT_BD_S2MM : process(m_axi_sg_aclk) begin if(m_axi_sg_aclk'EVENT and m_axi_sg_aclk = '1')then if(m_axi_sg_aresetn = '0' )then data_concat_mcdma_nxt <= (others => '0'); elsif (ftch2_active = '1') then data_concat_mcdma_nxt <= next_bd; end if; end if; end process NEXT_BD_S2MM; end generate NXT_BD_MCDMA; WRITE_CURDESC_PROCESS : process(m_axi_sg_aclk) begin if(m_axi_sg_aclk'EVENT and m_axi_sg_aclk = '1')then if(m_axi_sg_aresetn = '0' )then current_bd <= (others => '0'); -- -- -- Write LSB Address on command write elsif(ftch_cmnd_wr = '1' and ftch_active_int = '1')then current_bd <= ftch_cmnd_data(DATAMOVER_CMD_ADDRMSB_BOFST + DATAMOVER_CMD_ADDRLSB_BIT downto DATAMOVER_CMD_ADDRLSB_BIT); end if; end if; end process WRITE_CURDESC_PROCESS; GEN_MULT_CHANNEL : if C_ENABLE_MULTI_CHANNEL = 1 generate begin ftch_tvalid_mult <= m_axis_mm2s_tvalid; ftch_tdata_mult <= m_axis_mm2s_tdata; ftch_tlast_mult <= m_axis_mm2s_tlast; wr_cntl <= m_axis_mm2s_tvalid; m_axis_mm2s_cntrl_tdata <= (others => '0'); m_axis_mm2s_cntrl_tkeep <= "0000"; m_axis_mm2s_cntrl_tvalid <= '0'; m_axis_mm2s_cntrl_tlast <= '0'; end generate GEN_MULT_CHANNEL; GEN_NOMULT_CHANNEL : if C_ENABLE_MULTI_CHANNEL = 0 generate begin ftch_tvalid_mult <= '0'; --m_axis_mm2s_tvalid; ftch_tdata_mult <= (others => '0'); --m_axis_mm2s_tdata; ftch_tlast_mult <= '0'; --m_axis_mm2s_tlast; CONTROL_STREAM : if C_SG_WORDS_TO_FETCH = 13 and C_ENABLE_CH1 = 1 generate begin SOF_DEL_PROCESS : process(m_axi_sg_aclk) begin if(m_axi_sg_aclk'EVENT and m_axi_sg_aclk = '1')then if(m_axi_sg_aresetn = '0')then sof_ftch_desc_del <= '0'; else sof_ftch_desc_del <= sof_ftch_desc; end if; end if; end process SOF_DEL_PROCESS; SOF_DEL1_PROCESS : process(m_axi_sg_aclk) begin if(m_axi_sg_aclk'EVENT and m_axi_sg_aclk = '1')then if(m_axi_sg_aresetn = '0' or m_axis_mm2s_tlast = '1')then sof_ftch_desc_del1 <= '0'; elsif (m_axis_mm2s_tvalid = '1') then sof_ftch_desc_del1 <= sof_ftch_desc; end if; end if; end process SOF_DEL1_PROCESS; sof_ftch_desc_pulse <= sof_ftch_desc and (not sof_ftch_desc_del1); queue_wren <= not queue_full and sof_ftch_desc and m_axis_mm2s_tvalid and ftch_active; queue_rden <= not queue_empty and m_axis_mm2s_cntrl_tready; queue_din(C_M_AXIS_SG_TDATA_WIDTH) <= m_axis_mm2s_tlast; queue_din(C_M_AXIS_SG_TDATA_WIDTH-1 downto 0) <= x"A0000000" when (sof_ftch_desc_pulse = '1') else m_axis_mm2s_tdata; I_MM2S_CNTRL_STREAM : entity axi_sg_v4_1.axi_sg_cntrl_strm generic map( C_PRMRY_IS_ACLK_ASYNC => C_ASYNC , C_PRMY_CMDFIFO_DEPTH => 16, --FETCH_QUEUE_DEPTH , C_M_AXIS_MM2S_CNTRL_TDATA_WIDTH => C_M_AXIS_SG_TDATA_WIDTH , C_FAMILY => C_FAMILY ) port map( -- Secondary clock / reset m_axi_sg_aclk => m_axi_sg_aclk , m_axi_sg_aresetn => m_axi_sg_aresetn , -- Primary clock / reset axi_prmry_aclk => m_axi_primary_aclk , p_reset_n => p_reset_n , -- MM2S Error mm2s_stop => ch1_cntrl_strm_stop , -- Control Stream input cntrlstrm_fifo_wren => queue_wren , cntrlstrm_fifo_full => queue_full , cntrlstrm_fifo_din => queue_din , -- Memory Map to Stream Control Stream Interface m_axis_mm2s_cntrl_tdata => m_axis_mm2s_cntrl_tdata , m_axis_mm2s_cntrl_tkeep => m_axis_mm2s_cntrl_tkeep , m_axis_mm2s_cntrl_tvalid => m_axis_mm2s_cntrl_tvalid , m_axis_mm2s_cntrl_tready => m_axis_mm2s_cntrl_tready , m_axis_mm2s_cntrl_tlast => m_axis_mm2s_cntrl_tlast ); end generate CONTROL_STREAM; NO_CONTROL_STREAM : if C_SG_WORDS_TO_FETCH /= 13 or C_ENABLE_CH1 = 0 generate begin m_axis_mm2s_cntrl_tdata <= (others => '0'); m_axis_mm2s_cntrl_tkeep <= "0000"; m_axis_mm2s_cntrl_tvalid <= '0'; m_axis_mm2s_cntrl_tlast <= '0'; end generate NO_CONTROL_STREAM; end generate GEN_NOMULT_CHANNEL; --------------------------------------------------------------------------- -- Map internal stream to external --------------------------------------------------------------------------- ftch_tready <= (m_axis_ftch_tready and ftch_active) or (m_axis2_ftch_tready and ftch2_active); m_axis_ftch_tdata_new <= ftch_tdata_new; m_axis_ftch_tdata_mcdma_new <= data_concat_mcdma; m_axis_ftch_tvalid_new <= data_concat_valid and ftch_active; m_axis_ftch_desc_available <= data_concat_tlast and ftch_active; REG_FOR_STS_CNTRL : if C_SG_WORDS_TO_FETCH = 13 generate begin LATCH_PROCESS : process(m_axi_sg_aclk) begin if(m_axi_sg_aclk'EVENT and m_axi_sg_aclk = '1')then if(m_axi_sg_aresetn = '0')then m_axis2_ftch_tvalid_new <= '0'; m_axis2_ftch_desc_available <= '0'; else m_axis2_ftch_tvalid_new <= data_concat_valid and ftch2_active; m_axis2_ftch_desc_available <= data_concat_valid and ftch2_active; end if; end if; end process LATCH_PROCESS; LATCH2_PROCESS : process(m_axi_sg_aclk) begin if(m_axi_sg_aclk'EVENT and m_axi_sg_aclk = '1')then if(m_axi_sg_aresetn = '0')then m_axis2_ftch_tdata_new <= (others => '0'); elsif (data_concat_valid = '1' and ftch2_active = '1') then m_axis2_ftch_tdata_new <= ftch_tdata_new; end if; end if; end process LATCH2_PROCESS; end generate REG_FOR_STS_CNTRL; NO_REG_FOR_STS_CNTRL : if C_SG_WORDS_TO_FETCH /= 13 generate begin m_axis2_ftch_tvalid_new <= data_concat_valid and ftch2_active; m_axis2_ftch_desc_available <= data_concat_valid and ftch2_active; m_axis2_ftch_tdata_new <= ftch_tdata_new; m_axis2_ftch_tdata_mcdma_new <= data_concat_mcdma; m_axis2_ftch_tdata_mcdma_nxt <= data_concat_mcdma_nxt; end generate NO_REG_FOR_STS_CNTRL; m_axis_mm2s_tready <= ftch_tready; m_axis2_mm2s_tready <= ftch_tready; --------------------------------------------------------------------------- -- generate psuedo empty flag for Idle generation --------------------------------------------------------------------------- Q_EMPTY_PROCESS : process(m_axi_sg_aclk) begin if(m_axi_sg_aclk'EVENT and m_axi_sg_aclk='1')then if(m_axi_sg_aresetn = '0' or desc_flush = '1')then ftch_queue_empty <= '1'; -- Else on valid and ready modify empty flag elsif(ftch_tvalid = '1' and m_axis_ftch_tready = '1' and ftch_active = '1')then -- On last mark as empty if(ftch_tlast = '1' )then ftch_queue_empty <= '1'; -- Otherwise mark as not empty else ftch_queue_empty <= '0'; end if; end if; end if; end process Q_EMPTY_PROCESS; Q2_EMPTY_PROCESS : process(m_axi_sg_aclk) begin if(m_axi_sg_aclk'EVENT and m_axi_sg_aclk='1')then if(m_axi_sg_aresetn = '0' or desc2_flush = '1')then ftch2_queue_empty <= '1'; -- Else on valid and ready modify empty flag elsif(ftch_tvalid = '1' and m_axis2_ftch_tready = '1' and ftch2_active = '1')then -- On last mark as empty if(ftch_tlast = '1' )then ftch2_queue_empty <= '1'; -- Otherwise mark as not empty else ftch2_queue_empty <= '0'; end if; end if; end if; end process Q2_EMPTY_PROCESS; -- do not need to indicate full to axi_sg_ftch_sm. Only -- needed for queue case to allow other channel to be serviced -- if it had queue room ftch_queue_full <= '0'; ftch2_queue_full <= '0'; -- If writing curdesc out then flag for proper mux selection writing_curdesc <= curdesc_tvalid; -- Map intnal signal to port writing_curdesc_out <= writing_curdesc and ftch_active; writing2_curdesc_out <= writing_curdesc and ftch2_active; -- Map port to internal signal writing_nxtdesc <= writing_nxtdesc_in; end implementation;	gpl-3.0	da623fee8672d69ff718078824956efc	0.440712	4.263641	false	false	false	false
mistryalok/Zedboard	learning/training/Microsystem/axi_interface_part2/project_1/project_1.srcs/sources_1/bd/design_1/ip/design_1_blk_mem_gen_0_0/synth/design_1_blk_mem_gen_0_0.vhd	1	14,879	-- (c) Copyright 1995-2016 Xilinx, Inc. All rights reserved. -- -- This file contains confidential and proprietary information -- of Xilinx, Inc. and is protected under U.S. and -- international copyright and other intellectual property -- laws. -- -- DISCLAIMER -- This disclaimer is not a license and does not grant any -- rights to the materials distributed herewith. Except as -- otherwise provided in a valid license issued to you by -- Xilinx, and to the maximum extent permitted by applicable -- law: (1) THESE MATERIALS ARE MADE AVAILABLE "AS IS" AND -- WITH ALL FAULTS, AND XILINX HEREBY DISCLAIMS ALL WARRANTIES -- AND CONDITIONS, EXPRESS, IMPLIED, OR STATUTORY, INCLUDING -- BUT NOT LIMITED TO WARRANTIES OF MERCHANTABILITY, NON- -- INFRINGEMENT, OR FITNESS FOR ANY PARTICULAR PURPOSE; and -- (2) Xilinx shall not be liable (whether in contract or tort, -- including negligence, or under any other theory of -- liability) for any loss or damage of any kind or nature -- related to, arising under or in connection with these -- materials, including for any direct, or any indirect, -- special, incidental, or consequential loss or damage -- (including loss of data, profits, goodwill, or any type of -- loss or damage suffered as a result of any action brought -- by a third party) even if such damage or loss was -- reasonably foreseeable or Xilinx had been advised of the -- possibility of the same. -- -- CRITICAL APPLICATIONS -- Xilinx products are not designed or intended to be fail- -- safe, or for use in any application requiring fail-safe -- performance, such as life-support or safety devices or -- systems, Class III medical devices, nuclear facilities, -- applications related to the deployment of airbags, or any -- other applications that could lead to death, personal -- injury, or severe property or environmental damage -- (individually and collectively, "Critical -- Applications"). Customer assumes the sole risk and -- liability of any use of Xilinx products in Critical -- Applications, subject only to applicable laws and -- regulations governing limitations on product liability. -- -- THIS COPYRIGHT NOTICE AND DISCLAIMER MUST BE RETAINED AS -- PART OF THIS FILE AT ALL TIMES. -- -- DO NOT MODIFY THIS FILE. -- IP VLNV: xilinx.com:ip:blk_mem_gen:8.2 -- IP Revision: 3 LIBRARY ieee; USE ieee.std_logic_1164.ALL; USE ieee.numeric_std.ALL; LIBRARY blk_mem_gen_v8_2; USE blk_mem_gen_v8_2.blk_mem_gen_v8_2; ENTITY design_1_blk_mem_gen_0_0 IS PORT ( clka : IN STD_LOGIC; rsta : IN STD_LOGIC; ena : IN STD_LOGIC; wea : IN STD_LOGIC_VECTOR(3 DOWNTO 0); addra : IN STD_LOGIC_VECTOR(31 DOWNTO 0); dina : IN STD_LOGIC_VECTOR(31 DOWNTO 0); douta : OUT STD_LOGIC_VECTOR(31 DOWNTO 0); clkb : IN STD_LOGIC; rstb : IN STD_LOGIC; enb : IN STD_LOGIC; web : IN STD_LOGIC_VECTOR(3 DOWNTO 0); addrb : IN STD_LOGIC_VECTOR(31 DOWNTO 0); dinb : IN STD_LOGIC_VECTOR(31 DOWNTO 0); doutb : OUT STD_LOGIC_VECTOR(31 DOWNTO 0) ); END design_1_blk_mem_gen_0_0; ARCHITECTURE design_1_blk_mem_gen_0_0_arch OF design_1_blk_mem_gen_0_0 IS ATTRIBUTE DowngradeIPIdentifiedWarnings : string; ATTRIBUTE DowngradeIPIdentifiedWarnings OF design_1_blk_mem_gen_0_0_arch: ARCHITECTURE IS "yes"; COMPONENT blk_mem_gen_v8_2 IS GENERIC ( C_FAMILY : STRING; C_XDEVICEFAMILY : STRING; C_ELABORATION_DIR : STRING; C_INTERFACE_TYPE : INTEGER; C_AXI_TYPE : INTEGER; C_AXI_SLAVE_TYPE : INTEGER; C_USE_BRAM_BLOCK : INTEGER; C_ENABLE_32BIT_ADDRESS : INTEGER; C_CTRL_ECC_ALGO : STRING; C_HAS_AXI_ID : INTEGER; C_AXI_ID_WIDTH : INTEGER; C_MEM_TYPE : INTEGER; C_BYTE_SIZE : INTEGER; C_ALGORITHM : INTEGER; C_PRIM_TYPE : INTEGER; C_LOAD_INIT_FILE : INTEGER; C_INIT_FILE_NAME : STRING; C_INIT_FILE : STRING; C_USE_DEFAULT_DATA : INTEGER; C_DEFAULT_DATA : STRING; C_HAS_RSTA : INTEGER; C_RST_PRIORITY_A : STRING; C_RSTRAM_A : INTEGER; C_INITA_VAL : STRING; C_HAS_ENA : INTEGER; C_HAS_REGCEA : INTEGER; C_USE_BYTE_WEA : INTEGER; C_WEA_WIDTH : INTEGER; C_WRITE_MODE_A : STRING; C_WRITE_WIDTH_A : INTEGER; C_READ_WIDTH_A : INTEGER; C_WRITE_DEPTH_A : INTEGER; C_READ_DEPTH_A : INTEGER; C_ADDRA_WIDTH : INTEGER; C_HAS_RSTB : INTEGER; C_RST_PRIORITY_B : STRING; C_RSTRAM_B : INTEGER; C_INITB_VAL : STRING; C_HAS_ENB : INTEGER; C_HAS_REGCEB : INTEGER; C_USE_BYTE_WEB : INTEGER; C_WEB_WIDTH : INTEGER; C_WRITE_MODE_B : STRING; C_WRITE_WIDTH_B : INTEGER; C_READ_WIDTH_B : INTEGER; C_WRITE_DEPTH_B : INTEGER; C_READ_DEPTH_B : INTEGER; C_ADDRB_WIDTH : INTEGER; C_HAS_MEM_OUTPUT_REGS_A : INTEGER; C_HAS_MEM_OUTPUT_REGS_B : INTEGER; C_HAS_MUX_OUTPUT_REGS_A : INTEGER; C_HAS_MUX_OUTPUT_REGS_B : INTEGER; C_MUX_PIPELINE_STAGES : INTEGER; C_HAS_SOFTECC_INPUT_REGS_A : INTEGER; C_HAS_SOFTECC_OUTPUT_REGS_B : INTEGER; C_USE_SOFTECC : INTEGER; C_USE_ECC : INTEGER; C_EN_ECC_PIPE : INTEGER; C_HAS_INJECTERR : INTEGER; C_SIM_COLLISION_CHECK : STRING; C_COMMON_CLK : INTEGER; C_DISABLE_WARN_BHV_COLL : INTEGER; C_EN_SLEEP_PIN : INTEGER; C_DISABLE_WARN_BHV_RANGE : INTEGER; C_COUNT_36K_BRAM : STRING; C_COUNT_18K_BRAM : STRING; C_EST_POWER_SUMMARY : STRING ); PORT ( clka : IN STD_LOGIC; rsta : IN STD_LOGIC; ena : IN STD_LOGIC; regcea : IN STD_LOGIC; wea : IN STD_LOGIC_VECTOR(3 DOWNTO 0); addra : IN STD_LOGIC_VECTOR(31 DOWNTO 0); dina : IN STD_LOGIC_VECTOR(31 DOWNTO 0); douta : OUT STD_LOGIC_VECTOR(31 DOWNTO 0); clkb : IN STD_LOGIC; rstb : IN STD_LOGIC; enb : IN STD_LOGIC; regceb : IN STD_LOGIC; web : IN STD_LOGIC_VECTOR(3 DOWNTO 0); addrb : IN STD_LOGIC_VECTOR(31 DOWNTO 0); dinb : IN STD_LOGIC_VECTOR(31 DOWNTO 0); doutb : OUT STD_LOGIC_VECTOR(31 DOWNTO 0); injectsbiterr : IN STD_LOGIC; injectdbiterr : IN STD_LOGIC; eccpipece : IN STD_LOGIC; sbiterr : OUT STD_LOGIC; dbiterr : OUT STD_LOGIC; rdaddrecc : OUT STD_LOGIC_VECTOR(31 DOWNTO 0); sleep : IN STD_LOGIC; s_aclk : IN STD_LOGIC; s_aresetn : IN STD_LOGIC; s_axi_awid : IN STD_LOGIC_VECTOR(3 DOWNTO 0); s_axi_awaddr : IN STD_LOGIC_VECTOR(31 DOWNTO 0); s_axi_awlen : IN STD_LOGIC_VECTOR(7 DOWNTO 0); s_axi_awsize : IN STD_LOGIC_VECTOR(2 DOWNTO 0); s_axi_awburst : IN STD_LOGIC_VECTOR(1 DOWNTO 0); s_axi_awvalid : IN STD_LOGIC; s_axi_awready : OUT STD_LOGIC; s_axi_wdata : IN STD_LOGIC_VECTOR(31 DOWNTO 0); s_axi_wstrb : IN STD_LOGIC_VECTOR(3 DOWNTO 0); s_axi_wlast : IN STD_LOGIC; s_axi_wvalid : IN STD_LOGIC; s_axi_wready : OUT STD_LOGIC; s_axi_bid : OUT STD_LOGIC_VECTOR(3 DOWNTO 0); s_axi_bresp : OUT STD_LOGIC_VECTOR(1 DOWNTO 0); s_axi_bvalid : OUT STD_LOGIC; s_axi_bready : IN STD_LOGIC; s_axi_arid : IN STD_LOGIC_VECTOR(3 DOWNTO 0); s_axi_araddr : IN STD_LOGIC_VECTOR(31 DOWNTO 0); s_axi_arlen : IN STD_LOGIC_VECTOR(7 DOWNTO 0); s_axi_arsize : IN STD_LOGIC_VECTOR(2 DOWNTO 0); s_axi_arburst : IN STD_LOGIC_VECTOR(1 DOWNTO 0); s_axi_arvalid : IN STD_LOGIC; s_axi_arready : OUT STD_LOGIC; s_axi_rid : OUT STD_LOGIC_VECTOR(3 DOWNTO 0); s_axi_rdata : OUT STD_LOGIC_VECTOR(31 DOWNTO 0); s_axi_rresp : OUT STD_LOGIC_VECTOR(1 DOWNTO 0); s_axi_rlast : OUT STD_LOGIC; s_axi_rvalid : OUT STD_LOGIC; s_axi_rready : IN STD_LOGIC; s_axi_injectsbiterr : IN STD_LOGIC; s_axi_injectdbiterr : IN STD_LOGIC; s_axi_sbiterr : OUT STD_LOGIC; s_axi_dbiterr : OUT STD_LOGIC; s_axi_rdaddrecc : OUT STD_LOGIC_VECTOR(31 DOWNTO 0) ); END COMPONENT blk_mem_gen_v8_2; ATTRIBUTE X_CORE_INFO : STRING; ATTRIBUTE X_CORE_INFO OF design_1_blk_mem_gen_0_0_arch: ARCHITECTURE IS "blk_mem_gen_v8_2,Vivado 2014.4"; ATTRIBUTE CHECK_LICENSE_TYPE : STRING; ATTRIBUTE CHECK_LICENSE_TYPE OF design_1_blk_mem_gen_0_0_arch : ARCHITECTURE IS "design_1_blk_mem_gen_0_0,blk_mem_gen_v8_2,{}"; ATTRIBUTE CORE_GENERATION_INFO : STRING; ATTRIBUTE CORE_GENERATION_INFO OF design_1_blk_mem_gen_0_0_arch: ARCHITECTURE IS "design_1_blk_mem_gen_0_0,blk_mem_gen_v8_2,{x_ipProduct=Vivado 2014.4,x_ipVendor=xilinx.com,x_ipLibrary=ip,x_ipName=blk_mem_gen,x_ipVersion=8.2,x_ipCoreRevision=3,x_ipLanguage=VERILOG,x_ipSimLanguage=MIXED,C_FAMILY=zynq,C_XDEVICEFAMILY=zynq,C_ELABORATION_DIR=./,C_INTERFACE_TYPE=0,C_AXI_TYPE=1,C_AXI_SLAVE_TYPE=0,C_USE_BRAM_BLOCK=1,C_ENABLE_32BIT_ADDRESS=1,C_CTRL_ECC_ALGO=NONE,C_HAS_AXI_ID=0,C_AXI_ID_WIDTH=4,C_MEM_TYPE=2,C_BYTE_SIZE=8,C_ALGORITHM=1,C_PRIM_TYPE=1,C_LOAD_INIT_FILE=0,C_INIT_FILE_NAME=no_coe_file_loaded,C_INIT_FILE=NONE,C_USE_DEFAULT_DATA=0,C_DEFAULT_DATA=0,C_HAS_RSTA=1,C_RST_PRIORITY_A=CE,C_RSTRAM_A=0,C_INITA_VAL=0,C_HAS_ENA=1,C_HAS_REGCEA=0,C_USE_BYTE_WEA=1,C_WEA_WIDTH=4,C_WRITE_MODE_A=WRITE_FIRST,C_WRITE_WIDTH_A=32,C_READ_WIDTH_A=32,C_WRITE_DEPTH_A=2048,C_READ_DEPTH_A=2048,C_ADDRA_WIDTH=32,C_HAS_RSTB=1,C_RST_PRIORITY_B=CE,C_RSTRAM_B=0,C_INITB_VAL=0,C_HAS_ENB=1,C_HAS_REGCEB=0,C_USE_BYTE_WEB=1,C_WEB_WIDTH=4,C_WRITE_MODE_B=WRITE_FIRST,C_WRITE_WIDTH_B=32,C_READ_WIDTH_B=32,C_WRITE_DEPTH_B=2048,C_READ_DEPTH_B=2048,C_ADDRB_WIDTH=32,C_HAS_MEM_OUTPUT_REGS_A=0,C_HAS_MEM_OUTPUT_REGS_B=0,C_HAS_MUX_OUTPUT_REGS_A=0,C_HAS_MUX_OUTPUT_REGS_B=0,C_MUX_PIPELINE_STAGES=0,C_HAS_SOFTECC_INPUT_REGS_A=0,C_HAS_SOFTECC_OUTPUT_REGS_B=0,C_USE_SOFTECC=0,C_USE_ECC=0,C_EN_ECC_PIPE=0,C_HAS_INJECTERR=0,C_SIM_COLLISION_CHECK=ALL,C_COMMON_CLK=0,C_DISABLE_WARN_BHV_COLL=0,C_EN_SLEEP_PIN=0,C_DISABLE_WARN_BHV_RANGE=0,C_COUNT_36K_BRAM=2,C_COUNT_18K_BRAM=0,C_EST_POWER_SUMMARY=Estimated Power for IP _ 10.7492 mW}"; ATTRIBUTE X_INTERFACE_INFO : STRING; ATTRIBUTE X_INTERFACE_INFO OF clka: SIGNAL IS "xilinx.com:interface:bram:1.0 BRAM_PORTA CLK"; ATTRIBUTE X_INTERFACE_INFO OF rsta: SIGNAL IS "xilinx.com:interface:bram:1.0 BRAM_PORTA RST"; ATTRIBUTE X_INTERFACE_INFO OF ena: SIGNAL IS "xilinx.com:interface:bram:1.0 BRAM_PORTA EN"; ATTRIBUTE X_INTERFACE_INFO OF wea: SIGNAL IS "xilinx.com:interface:bram:1.0 BRAM_PORTA WE"; ATTRIBUTE X_INTERFACE_INFO OF addra: SIGNAL IS "xilinx.com:interface:bram:1.0 BRAM_PORTA ADDR"; ATTRIBUTE X_INTERFACE_INFO OF dina: SIGNAL IS "xilinx.com:interface:bram:1.0 BRAM_PORTA DIN"; ATTRIBUTE X_INTERFACE_INFO OF douta: SIGNAL IS "xilinx.com:interface:bram:1.0 BRAM_PORTA DOUT"; ATTRIBUTE X_INTERFACE_INFO OF clkb: SIGNAL IS "xilinx.com:interface:bram:1.0 BRAM_PORTB CLK"; ATTRIBUTE X_INTERFACE_INFO OF rstb: SIGNAL IS "xilinx.com:interface:bram:1.0 BRAM_PORTB RST"; ATTRIBUTE X_INTERFACE_INFO OF enb: SIGNAL IS "xilinx.com:interface:bram:1.0 BRAM_PORTB EN"; ATTRIBUTE X_INTERFACE_INFO OF web: SIGNAL IS "xilinx.com:interface:bram:1.0 BRAM_PORTB WE"; ATTRIBUTE X_INTERFACE_INFO OF addrb: SIGNAL IS "xilinx.com:interface:bram:1.0 BRAM_PORTB ADDR"; ATTRIBUTE X_INTERFACE_INFO OF dinb: SIGNAL IS "xilinx.com:interface:bram:1.0 BRAM_PORTB DIN"; ATTRIBUTE X_INTERFACE_INFO OF doutb: SIGNAL IS "xilinx.com:interface:bram:1.0 BRAM_PORTB DOUT"; BEGIN U0 : blk_mem_gen_v8_2 GENERIC MAP ( C_FAMILY => "zynq", C_XDEVICEFAMILY => "zynq", C_ELABORATION_DIR => "./", C_INTERFACE_TYPE => 0, C_AXI_TYPE => 1, C_AXI_SLAVE_TYPE => 0, C_USE_BRAM_BLOCK => 1, C_ENABLE_32BIT_ADDRESS => 1, C_CTRL_ECC_ALGO => "NONE", C_HAS_AXI_ID => 0, C_AXI_ID_WIDTH => 4, C_MEM_TYPE => 2, C_BYTE_SIZE => 8, C_ALGORITHM => 1, C_PRIM_TYPE => 1, C_LOAD_INIT_FILE => 0, C_INIT_FILE_NAME => "no_coe_file_loaded", C_INIT_FILE => "NONE", C_USE_DEFAULT_DATA => 0, C_DEFAULT_DATA => "0", C_HAS_RSTA => 1, C_RST_PRIORITY_A => "CE", C_RSTRAM_A => 0, C_INITA_VAL => "0", C_HAS_ENA => 1, C_HAS_REGCEA => 0, C_USE_BYTE_WEA => 1, C_WEA_WIDTH => 4, C_WRITE_MODE_A => "WRITE_FIRST", C_WRITE_WIDTH_A => 32, C_READ_WIDTH_A => 32, C_WRITE_DEPTH_A => 2048, C_READ_DEPTH_A => 2048, C_ADDRA_WIDTH => 32, C_HAS_RSTB => 1, C_RST_PRIORITY_B => "CE", C_RSTRAM_B => 0, C_INITB_VAL => "0", C_HAS_ENB => 1, C_HAS_REGCEB => 0, C_USE_BYTE_WEB => 1, C_WEB_WIDTH => 4, C_WRITE_MODE_B => "WRITE_FIRST", C_WRITE_WIDTH_B => 32, C_READ_WIDTH_B => 32, C_WRITE_DEPTH_B => 2048, C_READ_DEPTH_B => 2048, C_ADDRB_WIDTH => 32, C_HAS_MEM_OUTPUT_REGS_A => 0, C_HAS_MEM_OUTPUT_REGS_B => 0, C_HAS_MUX_OUTPUT_REGS_A => 0, C_HAS_MUX_OUTPUT_REGS_B => 0, C_MUX_PIPELINE_STAGES => 0, C_HAS_SOFTECC_INPUT_REGS_A => 0, C_HAS_SOFTECC_OUTPUT_REGS_B => 0, C_USE_SOFTECC => 0, C_USE_ECC => 0, C_EN_ECC_PIPE => 0, C_HAS_INJECTERR => 0, C_SIM_COLLISION_CHECK => "ALL", C_COMMON_CLK => 0, C_DISABLE_WARN_BHV_COLL => 0, C_EN_SLEEP_PIN => 0, C_DISABLE_WARN_BHV_RANGE => 0, C_COUNT_36K_BRAM => "2", C_COUNT_18K_BRAM => "0", C_EST_POWER_SUMMARY => "Estimated Power for IP : 10.7492 mW" ) PORT MAP ( clka => clka, rsta => rsta, ena => ena, regcea => '0', wea => wea, addra => addra, dina => dina, douta => douta, clkb => clkb, rstb => rstb, enb => enb, regceb => '0', web => web, addrb => addrb, dinb => dinb, doutb => doutb, injectsbiterr => '0', injectdbiterr => '0', eccpipece => '0', sleep => '0', s_aclk => '0', s_aresetn => '0', s_axi_awid => STD_LOGIC_VECTOR(TO_UNSIGNED(0, 4)), s_axi_awaddr => STD_LOGIC_VECTOR(TO_UNSIGNED(0, 32)), s_axi_awlen => STD_LOGIC_VECTOR(TO_UNSIGNED(0, 8)), s_axi_awsize => STD_LOGIC_VECTOR(TO_UNSIGNED(0, 3)), s_axi_awburst => STD_LOGIC_VECTOR(TO_UNSIGNED(0, 2)), s_axi_awvalid => '0', s_axi_wdata => STD_LOGIC_VECTOR(TO_UNSIGNED(0, 32)), s_axi_wstrb => STD_LOGIC_VECTOR(TO_UNSIGNED(0, 4)), s_axi_wlast => '0', s_axi_wvalid => '0', s_axi_bready => '0', s_axi_arid => STD_LOGIC_VECTOR(TO_UNSIGNED(0, 4)), s_axi_araddr => STD_LOGIC_VECTOR(TO_UNSIGNED(0, 32)), s_axi_arlen => STD_LOGIC_VECTOR(TO_UNSIGNED(0, 8)), s_axi_arsize => STD_LOGIC_VECTOR(TO_UNSIGNED(0, 3)), s_axi_arburst => STD_LOGIC_VECTOR(TO_UNSIGNED(0, 2)), s_axi_arvalid => '0', s_axi_rready => '0', s_axi_injectsbiterr => '0', s_axi_injectdbiterr => '0' ); END design_1_blk_mem_gen_0_0_arch;	gpl-3.0	0e8296ab2425a358859afdb1e1b0bae9	0.636131	3.032817	false	false	false	false
mistryalok/Zedboard	learning/training/Microsystem/axi_interface_part2/project_1/project_1.srcs/sources_1/bd/design_1/ip/design_1_axi_bram_ctrl_0_0/synth/design_1_axi_bram_ctrl_0_0.vhd	1	16,618	-- (c) Copyright 1995-2016 Xilinx, Inc. All rights reserved. -- -- This file contains confidential and proprietary information -- of Xilinx, Inc. and is protected under U.S. and -- international copyright and other intellectual property -- laws. -- -- DISCLAIMER -- This disclaimer is not a license and does not grant any -- rights to the materials distributed herewith. Except as -- otherwise provided in a valid license issued to you by -- Xilinx, and to the maximum extent permitted by applicable -- law: (1) THESE MATERIALS ARE MADE AVAILABLE "AS IS" AND -- WITH ALL FAULTS, AND XILINX HEREBY DISCLAIMS ALL WARRANTIES -- AND CONDITIONS, EXPRESS, IMPLIED, OR STATUTORY, INCLUDING -- BUT NOT LIMITED TO WARRANTIES OF MERCHANTABILITY, NON- -- INFRINGEMENT, OR FITNESS FOR ANY PARTICULAR PURPOSE; and -- (2) Xilinx shall not be liable (whether in contract or tort, -- including negligence, or under any other theory of -- liability) for any loss or damage of any kind or nature -- related to, arising under or in connection with these -- materials, including for any direct, or any indirect, -- special, incidental, or consequential loss or damage -- (including loss of data, profits, goodwill, or any type of -- loss or damage suffered as a result of any action brought -- by a third party) even if such damage or loss was -- reasonably foreseeable or Xilinx had been advised of the -- possibility of the same. -- -- CRITICAL APPLICATIONS -- Xilinx products are not designed or intended to be fail- -- safe, or for use in any application requiring fail-safe -- performance, such as life-support or safety devices or -- systems, Class III medical devices, nuclear facilities, -- applications related to the deployment of airbags, or any -- other applications that could lead to death, personal -- injury, or severe property or environmental damage -- (individually and collectively, "Critical -- Applications"). Customer assumes the sole risk and -- liability of any use of Xilinx products in Critical -- Applications, subject only to applicable laws and -- regulations governing limitations on product liability. -- -- THIS COPYRIGHT NOTICE AND DISCLAIMER MUST BE RETAINED AS -- PART OF THIS FILE AT ALL TIMES. -- -- DO NOT MODIFY THIS FILE. -- IP VLNV: xilinx.com:ip:axi_bram_ctrl:4.0 -- IP Revision: 3 LIBRARY ieee; USE ieee.std_logic_1164.ALL; USE ieee.numeric_std.ALL; LIBRARY axi_bram_ctrl_v4_0; USE axi_bram_ctrl_v4_0.axi_bram_ctrl; ENTITY design_1_axi_bram_ctrl_0_0 IS PORT ( s_axi_aclk : IN STD_LOGIC; s_axi_aresetn : IN STD_LOGIC; s_axi_awid : IN STD_LOGIC_VECTOR(11 DOWNTO 0); s_axi_awaddr : IN STD_LOGIC_VECTOR(12 DOWNTO 0); s_axi_awlen : IN STD_LOGIC_VECTOR(7 DOWNTO 0); s_axi_awsize : IN STD_LOGIC_VECTOR(2 DOWNTO 0); s_axi_awburst : IN STD_LOGIC_VECTOR(1 DOWNTO 0); s_axi_awlock : IN STD_LOGIC; s_axi_awcache : IN STD_LOGIC_VECTOR(3 DOWNTO 0); s_axi_awprot : IN STD_LOGIC_VECTOR(2 DOWNTO 0); s_axi_awvalid : IN STD_LOGIC; s_axi_awready : OUT STD_LOGIC; s_axi_wdata : IN STD_LOGIC_VECTOR(31 DOWNTO 0); s_axi_wstrb : IN STD_LOGIC_VECTOR(3 DOWNTO 0); s_axi_wlast : IN STD_LOGIC; s_axi_wvalid : IN STD_LOGIC; s_axi_wready : OUT STD_LOGIC; s_axi_bid : OUT STD_LOGIC_VECTOR(11 DOWNTO 0); s_axi_bresp : OUT STD_LOGIC_VECTOR(1 DOWNTO 0); s_axi_bvalid : OUT STD_LOGIC; s_axi_bready : IN STD_LOGIC; s_axi_arid : IN STD_LOGIC_VECTOR(11 DOWNTO 0); s_axi_araddr : IN STD_LOGIC_VECTOR(12 DOWNTO 0); s_axi_arlen : IN STD_LOGIC_VECTOR(7 DOWNTO 0); s_axi_arsize : IN STD_LOGIC_VECTOR(2 DOWNTO 0); s_axi_arburst : IN STD_LOGIC_VECTOR(1 DOWNTO 0); s_axi_arlock : IN STD_LOGIC; s_axi_arcache : IN STD_LOGIC_VECTOR(3 DOWNTO 0); s_axi_arprot : IN STD_LOGIC_VECTOR(2 DOWNTO 0); s_axi_arvalid : IN STD_LOGIC; s_axi_arready : OUT STD_LOGIC; s_axi_rid : OUT STD_LOGIC_VECTOR(11 DOWNTO 0); s_axi_rdata : OUT STD_LOGIC_VECTOR(31 DOWNTO 0); s_axi_rresp : OUT STD_LOGIC_VECTOR(1 DOWNTO 0); s_axi_rlast : OUT STD_LOGIC; s_axi_rvalid : OUT STD_LOGIC; s_axi_rready : IN STD_LOGIC; bram_rst_a : OUT STD_LOGIC; bram_clk_a : OUT STD_LOGIC; bram_en_a : OUT STD_LOGIC; bram_we_a : OUT STD_LOGIC_VECTOR(3 DOWNTO 0); bram_addr_a : OUT STD_LOGIC_VECTOR(12 DOWNTO 0); bram_wrdata_a : OUT STD_LOGIC_VECTOR(31 DOWNTO 0); bram_rddata_a : IN STD_LOGIC_VECTOR(31 DOWNTO 0) ); END design_1_axi_bram_ctrl_0_0; ARCHITECTURE design_1_axi_bram_ctrl_0_0_arch OF design_1_axi_bram_ctrl_0_0 IS ATTRIBUTE DowngradeIPIdentifiedWarnings : string; ATTRIBUTE DowngradeIPIdentifiedWarnings OF design_1_axi_bram_ctrl_0_0_arch: ARCHITECTURE IS "yes"; COMPONENT axi_bram_ctrl IS GENERIC ( C_BRAM_INST_MODE : STRING; C_MEMORY_DEPTH : INTEGER; C_BRAM_ADDR_WIDTH : INTEGER; C_S_AXI_ADDR_WIDTH : INTEGER; C_S_AXI_DATA_WIDTH : INTEGER; C_S_AXI_ID_WIDTH : INTEGER; C_S_AXI_PROTOCOL : STRING; C_S_AXI_SUPPORTS_NARROW_BURST : INTEGER; C_SINGLE_PORT_BRAM : INTEGER; C_FAMILY : STRING; C_S_AXI_CTRL_ADDR_WIDTH : INTEGER; C_S_AXI_CTRL_DATA_WIDTH : INTEGER; C_ECC : INTEGER; C_ECC_TYPE : INTEGER; C_FAULT_INJECT : INTEGER; C_ECC_ONOFF_RESET_VALUE : INTEGER ); PORT ( s_axi_aclk : IN STD_LOGIC; s_axi_aresetn : IN STD_LOGIC; ecc_interrupt : OUT STD_LOGIC; ecc_ue : OUT STD_LOGIC; s_axi_awid : IN STD_LOGIC_VECTOR(11 DOWNTO 0); s_axi_awaddr : IN STD_LOGIC_VECTOR(12 DOWNTO 0); s_axi_awlen : IN STD_LOGIC_VECTOR(7 DOWNTO 0); s_axi_awsize : IN STD_LOGIC_VECTOR(2 DOWNTO 0); s_axi_awburst : IN STD_LOGIC_VECTOR(1 DOWNTO 0); s_axi_awlock : IN STD_LOGIC; s_axi_awcache : IN STD_LOGIC_VECTOR(3 DOWNTO 0); s_axi_awprot : IN STD_LOGIC_VECTOR(2 DOWNTO 0); s_axi_awvalid : IN STD_LOGIC; s_axi_awready : OUT STD_LOGIC; s_axi_wdata : IN STD_LOGIC_VECTOR(31 DOWNTO 0); s_axi_wstrb : IN STD_LOGIC_VECTOR(3 DOWNTO 0); s_axi_wlast : IN STD_LOGIC; s_axi_wvalid : IN STD_LOGIC; s_axi_wready : OUT STD_LOGIC; s_axi_bid : OUT STD_LOGIC_VECTOR(11 DOWNTO 0); s_axi_bresp : OUT STD_LOGIC_VECTOR(1 DOWNTO 0); s_axi_bvalid : OUT STD_LOGIC; s_axi_bready : IN STD_LOGIC; s_axi_arid : IN STD_LOGIC_VECTOR(11 DOWNTO 0); s_axi_araddr : IN STD_LOGIC_VECTOR(12 DOWNTO 0); s_axi_arlen : IN STD_LOGIC_VECTOR(7 DOWNTO 0); s_axi_arsize : IN STD_LOGIC_VECTOR(2 DOWNTO 0); s_axi_arburst : IN STD_LOGIC_VECTOR(1 DOWNTO 0); s_axi_arlock : IN STD_LOGIC; s_axi_arcache : IN STD_LOGIC_VECTOR(3 DOWNTO 0); s_axi_arprot : IN STD_LOGIC_VECTOR(2 DOWNTO 0); s_axi_arvalid : IN STD_LOGIC; s_axi_arready : OUT STD_LOGIC; s_axi_rid : OUT STD_LOGIC_VECTOR(11 DOWNTO 0); s_axi_rdata : OUT STD_LOGIC_VECTOR(31 DOWNTO 0); s_axi_rresp : OUT STD_LOGIC_VECTOR(1 DOWNTO 0); s_axi_rlast : OUT STD_LOGIC; s_axi_rvalid : OUT STD_LOGIC; s_axi_rready : IN STD_LOGIC; s_axi_ctrl_awvalid : IN STD_LOGIC; s_axi_ctrl_awready : OUT STD_LOGIC; s_axi_ctrl_awaddr : IN STD_LOGIC_VECTOR(31 DOWNTO 0); s_axi_ctrl_wdata : IN STD_LOGIC_VECTOR(31 DOWNTO 0); s_axi_ctrl_wvalid : IN STD_LOGIC; s_axi_ctrl_wready : OUT STD_LOGIC; s_axi_ctrl_bresp : OUT STD_LOGIC_VECTOR(1 DOWNTO 0); s_axi_ctrl_bvalid : OUT STD_LOGIC; s_axi_ctrl_bready : IN STD_LOGIC; s_axi_ctrl_araddr : IN STD_LOGIC_VECTOR(31 DOWNTO 0); s_axi_ctrl_arvalid : IN STD_LOGIC; s_axi_ctrl_arready : OUT STD_LOGIC; s_axi_ctrl_rdata : OUT STD_LOGIC_VECTOR(31 DOWNTO 0); s_axi_ctrl_rresp : OUT STD_LOGIC_VECTOR(1 DOWNTO 0); s_axi_ctrl_rvalid : OUT STD_LOGIC; s_axi_ctrl_rready : IN STD_LOGIC; bram_rst_a : OUT STD_LOGIC; bram_clk_a : OUT STD_LOGIC; bram_en_a : OUT STD_LOGIC; bram_we_a : OUT STD_LOGIC_VECTOR(3 DOWNTO 0); bram_addr_a : OUT STD_LOGIC_VECTOR(12 DOWNTO 0); bram_wrdata_a : OUT STD_LOGIC_VECTOR(31 DOWNTO 0); bram_rddata_a : IN STD_LOGIC_VECTOR(31 DOWNTO 0); bram_rst_b : OUT STD_LOGIC; bram_clk_b : OUT STD_LOGIC; bram_en_b : OUT STD_LOGIC; bram_we_b : OUT STD_LOGIC_VECTOR(3 DOWNTO 0); bram_addr_b : OUT STD_LOGIC_VECTOR(12 DOWNTO 0); bram_wrdata_b : OUT STD_LOGIC_VECTOR(31 DOWNTO 0); bram_rddata_b : IN STD_LOGIC_VECTOR(31 DOWNTO 0) ); END COMPONENT axi_bram_ctrl; ATTRIBUTE X_CORE_INFO : STRING; ATTRIBUTE X_CORE_INFO OF design_1_axi_bram_ctrl_0_0_arch: ARCHITECTURE IS "axi_bram_ctrl,Vivado 2014.4"; ATTRIBUTE CHECK_LICENSE_TYPE : STRING; ATTRIBUTE CHECK_LICENSE_TYPE OF design_1_axi_bram_ctrl_0_0_arch : ARCHITECTURE IS "design_1_axi_bram_ctrl_0_0,axi_bram_ctrl,{}"; ATTRIBUTE CORE_GENERATION_INFO : STRING; ATTRIBUTE CORE_GENERATION_INFO OF design_1_axi_bram_ctrl_0_0_arch: ARCHITECTURE IS "design_1_axi_bram_ctrl_0_0,axi_bram_ctrl,{x_ipProduct=Vivado 2014.4,x_ipVendor=xilinx.com,x_ipLibrary=ip,x_ipName=axi_bram_ctrl,x_ipVersion=4.0,x_ipCoreRevision=3,x_ipLanguage=VERILOG,x_ipSimLanguage=MIXED,C_BRAM_INST_MODE=EXTERNAL,C_MEMORY_DEPTH=2048,C_BRAM_ADDR_WIDTH=11,C_S_AXI_ADDR_WIDTH=13,C_S_AXI_DATA_WIDTH=32,C_S_AXI_ID_WIDTH=12,C_S_AXI_PROTOCOL=AXI4,C_S_AXI_SUPPORTS_NARROW_BURST=0,C_SINGLE_PORT_BRAM=1,C_FAMILY=zynq,C_S_AXI_CTRL_ADDR_WIDTH=32,C_S_AXI_CTRL_DATA_WIDTH=32,C_ECC=0,C_ECC_TYPE=0,C_FAULT_INJECT=0,C_ECC_ONOFF_RESET_VALUE=0}"; ATTRIBUTE X_INTERFACE_INFO : STRING; ATTRIBUTE X_INTERFACE_INFO OF s_axi_aclk: SIGNAL IS "xilinx.com:signal:clock:1.0 CLKIF CLK"; ATTRIBUTE X_INTERFACE_INFO OF s_axi_aresetn: SIGNAL IS "xilinx.com:signal:reset:1.0 RSTIF RST"; ATTRIBUTE X_INTERFACE_INFO OF s_axi_awid: SIGNAL IS "xilinx.com:interface:aximm:1.0 S_AXI AWID"; ATTRIBUTE X_INTERFACE_INFO OF s_axi_awaddr: SIGNAL IS "xilinx.com:interface:aximm:1.0 S_AXI AWADDR"; ATTRIBUTE X_INTERFACE_INFO OF s_axi_awlen: SIGNAL IS "xilinx.com:interface:aximm:1.0 S_AXI AWLEN"; ATTRIBUTE X_INTERFACE_INFO OF s_axi_awsize: SIGNAL IS "xilinx.com:interface:aximm:1.0 S_AXI AWSIZE"; ATTRIBUTE X_INTERFACE_INFO OF s_axi_awburst: SIGNAL IS "xilinx.com:interface:aximm:1.0 S_AXI AWBURST"; ATTRIBUTE X_INTERFACE_INFO OF s_axi_awlock: SIGNAL IS "xilinx.com:interface:aximm:1.0 S_AXI AWLOCK"; ATTRIBUTE X_INTERFACE_INFO OF s_axi_awcache: SIGNAL IS "xilinx.com:interface:aximm:1.0 S_AXI AWCACHE"; ATTRIBUTE X_INTERFACE_INFO OF s_axi_awprot: SIGNAL IS "xilinx.com:interface:aximm:1.0 S_AXI AWPROT"; ATTRIBUTE X_INTERFACE_INFO OF s_axi_awvalid: SIGNAL IS "xilinx.com:interface:aximm:1.0 S_AXI AWVALID"; ATTRIBUTE X_INTERFACE_INFO OF s_axi_awready: SIGNAL IS "xilinx.com:interface:aximm:1.0 S_AXI AWREADY"; ATTRIBUTE X_INTERFACE_INFO OF s_axi_wdata: SIGNAL IS "xilinx.com:interface:aximm:1.0 S_AXI WDATA"; ATTRIBUTE X_INTERFACE_INFO OF s_axi_wstrb: SIGNAL IS "xilinx.com:interface:aximm:1.0 S_AXI WSTRB"; ATTRIBUTE X_INTERFACE_INFO OF s_axi_wlast: SIGNAL IS "xilinx.com:interface:aximm:1.0 S_AXI WLAST"; ATTRIBUTE X_INTERFACE_INFO OF s_axi_wvalid: SIGNAL IS "xilinx.com:interface:aximm:1.0 S_AXI WVALID"; ATTRIBUTE X_INTERFACE_INFO OF s_axi_wready: SIGNAL IS "xilinx.com:interface:aximm:1.0 S_AXI WREADY"; ATTRIBUTE X_INTERFACE_INFO OF s_axi_bid: SIGNAL IS "xilinx.com:interface:aximm:1.0 S_AXI BID"; ATTRIBUTE X_INTERFACE_INFO OF s_axi_bresp: SIGNAL IS "xilinx.com:interface:aximm:1.0 S_AXI BRESP"; ATTRIBUTE X_INTERFACE_INFO OF s_axi_bvalid: SIGNAL IS "xilinx.com:interface:aximm:1.0 S_AXI BVALID"; ATTRIBUTE X_INTERFACE_INFO OF s_axi_bready: SIGNAL IS "xilinx.com:interface:aximm:1.0 S_AXI BREADY"; ATTRIBUTE X_INTERFACE_INFO OF s_axi_arid: SIGNAL IS "xilinx.com:interface:aximm:1.0 S_AXI ARID"; ATTRIBUTE X_INTERFACE_INFO OF s_axi_araddr: SIGNAL IS "xilinx.com:interface:aximm:1.0 S_AXI ARADDR"; ATTRIBUTE X_INTERFACE_INFO OF s_axi_arlen: SIGNAL IS "xilinx.com:interface:aximm:1.0 S_AXI ARLEN"; ATTRIBUTE X_INTERFACE_INFO OF s_axi_arsize: SIGNAL IS "xilinx.com:interface:aximm:1.0 S_AXI ARSIZE"; ATTRIBUTE X_INTERFACE_INFO OF s_axi_arburst: SIGNAL IS "xilinx.com:interface:aximm:1.0 S_AXI ARBURST"; ATTRIBUTE X_INTERFACE_INFO OF s_axi_arlock: SIGNAL IS "xilinx.com:interface:aximm:1.0 S_AXI ARLOCK"; ATTRIBUTE X_INTERFACE_INFO OF s_axi_arcache: SIGNAL IS "xilinx.com:interface:aximm:1.0 S_AXI ARCACHE"; ATTRIBUTE X_INTERFACE_INFO OF s_axi_arprot: SIGNAL IS "xilinx.com:interface:aximm:1.0 S_AXI ARPROT"; ATTRIBUTE X_INTERFACE_INFO OF s_axi_arvalid: SIGNAL IS "xilinx.com:interface:aximm:1.0 S_AXI ARVALID"; ATTRIBUTE X_INTERFACE_INFO OF s_axi_arready: SIGNAL IS "xilinx.com:interface:aximm:1.0 S_AXI ARREADY"; ATTRIBUTE X_INTERFACE_INFO OF s_axi_rid: SIGNAL IS "xilinx.com:interface:aximm:1.0 S_AXI RID"; ATTRIBUTE X_INTERFACE_INFO OF s_axi_rdata: SIGNAL IS "xilinx.com:interface:aximm:1.0 S_AXI RDATA"; ATTRIBUTE X_INTERFACE_INFO OF s_axi_rresp: SIGNAL IS "xilinx.com:interface:aximm:1.0 S_AXI RRESP"; ATTRIBUTE X_INTERFACE_INFO OF s_axi_rlast: SIGNAL IS "xilinx.com:interface:aximm:1.0 S_AXI RLAST"; ATTRIBUTE X_INTERFACE_INFO OF s_axi_rvalid: SIGNAL IS "xilinx.com:interface:aximm:1.0 S_AXI RVALID"; ATTRIBUTE X_INTERFACE_INFO OF s_axi_rready: SIGNAL IS "xilinx.com:interface:aximm:1.0 S_AXI RREADY"; ATTRIBUTE X_INTERFACE_INFO OF bram_rst_a: SIGNAL IS "xilinx.com:interface:bram:1.0 BRAM_PORTA RST"; ATTRIBUTE X_INTERFACE_INFO OF bram_clk_a: SIGNAL IS "xilinx.com:interface:bram:1.0 BRAM_PORTA CLK"; ATTRIBUTE X_INTERFACE_INFO OF bram_en_a: SIGNAL IS "xilinx.com:interface:bram:1.0 BRAM_PORTA EN"; ATTRIBUTE X_INTERFACE_INFO OF bram_we_a: SIGNAL IS "xilinx.com:interface:bram:1.0 BRAM_PORTA WE"; ATTRIBUTE X_INTERFACE_INFO OF bram_addr_a: SIGNAL IS "xilinx.com:interface:bram:1.0 BRAM_PORTA ADDR"; ATTRIBUTE X_INTERFACE_INFO OF bram_wrdata_a: SIGNAL IS "xilinx.com:interface:bram:1.0 BRAM_PORTA DIN"; ATTRIBUTE X_INTERFACE_INFO OF bram_rddata_a: SIGNAL IS "xilinx.com:interface:bram:1.0 BRAM_PORTA DOUT"; BEGIN U0 : axi_bram_ctrl GENERIC MAP ( C_BRAM_INST_MODE => "EXTERNAL", C_MEMORY_DEPTH => 2048, C_BRAM_ADDR_WIDTH => 11, C_S_AXI_ADDR_WIDTH => 13, C_S_AXI_DATA_WIDTH => 32, C_S_AXI_ID_WIDTH => 12, C_S_AXI_PROTOCOL => "AXI4", C_S_AXI_SUPPORTS_NARROW_BURST => 0, C_SINGLE_PORT_BRAM => 1, C_FAMILY => "zynq", C_S_AXI_CTRL_ADDR_WIDTH => 32, C_S_AXI_CTRL_DATA_WIDTH => 32, C_ECC => 0, C_ECC_TYPE => 0, C_FAULT_INJECT => 0, C_ECC_ONOFF_RESET_VALUE => 0 ) PORT MAP ( s_axi_aclk => s_axi_aclk, s_axi_aresetn => s_axi_aresetn, s_axi_awid => s_axi_awid, s_axi_awaddr => s_axi_awaddr, s_axi_awlen => s_axi_awlen, s_axi_awsize => s_axi_awsize, s_axi_awburst => s_axi_awburst, s_axi_awlock => s_axi_awlock, s_axi_awcache => s_axi_awcache, s_axi_awprot => s_axi_awprot, s_axi_awvalid => s_axi_awvalid, s_axi_awready => s_axi_awready, s_axi_wdata => s_axi_wdata, s_axi_wstrb => s_axi_wstrb, s_axi_wlast => s_axi_wlast, s_axi_wvalid => s_axi_wvalid, s_axi_wready => s_axi_wready, s_axi_bid => s_axi_bid, s_axi_bresp => s_axi_bresp, s_axi_bvalid => s_axi_bvalid, s_axi_bready => s_axi_bready, s_axi_arid => s_axi_arid, s_axi_araddr => s_axi_araddr, s_axi_arlen => s_axi_arlen, s_axi_arsize => s_axi_arsize, s_axi_arburst => s_axi_arburst, s_axi_arlock => s_axi_arlock, s_axi_arcache => s_axi_arcache, s_axi_arprot => s_axi_arprot, s_axi_arvalid => s_axi_arvalid, s_axi_arready => s_axi_arready, s_axi_rid => s_axi_rid, s_axi_rdata => s_axi_rdata, s_axi_rresp => s_axi_rresp, s_axi_rlast => s_axi_rlast, s_axi_rvalid => s_axi_rvalid, s_axi_rready => s_axi_rready, s_axi_ctrl_awvalid => '0', s_axi_ctrl_awaddr => STD_LOGIC_VECTOR(TO_UNSIGNED(0, 32)), s_axi_ctrl_wdata => STD_LOGIC_VECTOR(TO_UNSIGNED(0, 32)), s_axi_ctrl_wvalid => '0', s_axi_ctrl_bready => '0', s_axi_ctrl_araddr => STD_LOGIC_VECTOR(TO_UNSIGNED(0, 32)), s_axi_ctrl_arvalid => '0', s_axi_ctrl_rready => '0', bram_rst_a => bram_rst_a, bram_clk_a => bram_clk_a, bram_en_a => bram_en_a, bram_we_a => bram_we_a, bram_addr_a => bram_addr_a, bram_wrdata_a => bram_wrdata_a, bram_rddata_a => bram_rddata_a, bram_rddata_b => STD_LOGIC_VECTOR(TO_UNSIGNED(0, 32)) ); END design_1_axi_bram_ctrl_0_0_arch;	gpl-3.0	c5bb4866f0060cd796ab1f7cbc087b66	0.676014	3.060969	false	false	false	false
marco-c/leon-nexys2	grlib-gpl-1.3.4-b4140/lib/techmap/stratixii/clkgen_stratixii.vhd	1	6,703	------------------------------------------------------------------------------ -- This file is a part of the GRLIB VHDL IP LIBRARY -- Copyright (C) 2003 - 2008, Gaisler Research -- Copyright (C) 2008 - 2013, Aeroflex Gaisler -- -- This program is free software; you can redistribute it and/or modify -- it under the terms of the GNU General Public License as published by -- the Free Software Foundation; either version 2 of the License, or -- (at your option) any later version. -- -- This program is distributed in the hope that it will be useful, -- but WITHOUT ANY WARRANTY; without even the implied warranty of -- MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the -- GNU General Public License for more details. -- -- You should have received a copy of the GNU General Public License -- along with this program; if not, write to the Free Software -- Foundation, Inc., 59 Temple Place, Suite 330, Boston, MA 02111-1307 USA ------------------------------------------------------------------------------- library ieee; use ieee.std_logic_1164.all; library techmap; use techmap.gencomp.all; library altera_mf; -- pragma translate_off use altera_mf.altpll; -- pragma translate_on entity stratix2_pll is generic ( clk_mul : integer := 1; clk_div : integer := 1; clk_freq : integer := 25000; clk2xen : integer := 0; sdramen : integer := 0 ); port ( inclk0 : in std_ulogic; c0 : out std_ulogic; c0_2x : out std_ulogic; e0 : out std_ulogic; locked : out std_ulogic ); end; architecture rtl of stratix2_pll is component altpll generic ( intended_device_family : string := "Stratix" ; operation_mode : string := "NORMAL" ; compensate_clock : string := "CLK0" ; inclk0_input_frequency : positive; width_clock : positive := 6; clk0_multiply_by : positive := 1; clk0_divide_by : positive := 1; clk1_multiply_by : positive := 1; clk1_divide_by : positive := 1; clk2_multiply_by : positive := 1; clk2_divide_by : positive := 1 ); port ( inclk : in std_logic_vector(1 downto 0); clk : out std_logic_vector(width_clock-1 downto 0); locked : out std_logic ); end component; signal clkout : std_logic_vector (5 downto 0); signal inclk : std_logic_vector (1 downto 0); constant clk_period : integer := 1000000000/clk_freq; constant CLK_MUL2X : integer := clk_mul * 2; begin inclk <= '0' & inclk0; c0 <= clkout(0); c0_2x <= clkout(1); sden : if sdramen = 1 generate altpll0 : altpll generic map ( intended_device_family => "Stratix II", operation_mode => "ZERO_DELAY_BUFFER", compensate_clock => "CLK2", inclk0_input_frequency => clk_period, clk0_multiply_by => clk_mul, clk0_divide_by => clk_div, clk1_multiply_by => CLK_MUL2X, clk1_divide_by => clk_div, clk2_multiply_by => clk_mul, clk2_divide_by => clk_div) port map (inclk => inclk, clk => clkout, locked => locked); e0 <= clkout(2); end generate; nosd : if sdramen = 0 generate altpll0 : altpll generic map ( intended_device_family => "Stratix II", operation_mode => "NORMAL", inclk0_input_frequency => clk_period, clk0_multiply_by => clk_mul, clk0_divide_by => clk_div, clk1_multiply_by => CLK_MUL2X, clk1_divide_by => clk_div) port map (inclk => inclk, clk => clkout, locked => locked); e0 <= '0'; end generate; end; library ieee; use ieee.std_logic_1164.all; -- pragma translate_off library altera_mf; library grlib; use grlib.stdlib.all; -- pragma translate_on library techmap; use techmap.gencomp.all; entity clkgen_stratixii is generic ( clk_mul : integer := 1; clk_div : integer := 1; sdramen : integer := 0; sdinvclk : integer := 0; pcien : integer := 0; pcidll : integer := 0; pcisysclk: integer := 0; freq : integer := 25000; clk2xen : integer := 0); port ( clkin : in std_logic; pciclkin: in std_logic; clk : out std_logic; -- main clock clkn : out std_logic; -- inverted main clock clk2x : out std_logic; -- double clock sdclk : out std_logic; -- SDRAM clock pciclk : out std_logic; -- PCI clock cgi : in clkgen_in_type; cgo : out clkgen_out_type); end; architecture rtl of clkgen_stratixii is constant VERSION : integer := 1; constant CLKIN_PERIOD : integer := 20; signal clk_i : std_logic; signal clkint, pciclkint : std_logic; signal pllclk, pllclkn : std_logic; -- generated clocks signal s_clk : std_logic; -- altera pll component stratix2_pll generic ( clk_mul : integer := 1; clk_div : integer := 1; clk_freq : integer := 25000; clk2xen : integer := 0; sdramen : integer := 0 ); port ( inclk0 : in std_ulogic; e0 : out std_ulogic; c0 : out std_ulogic; c0_2x : out std_ulogic; locked : out std_ulogic); end component; begin cgo.pcilock <= '1'; -- c0 : if (PCISYSCLK = 0) generate -- Clkint <= Clkin; -- end generate; -- c1 : if (PCISYSCLK = 1) generate -- Clkint <= pciclkin; -- end generate; -- c2 : if (PCIEN = 1) generate -- p0 : if (PCIDLL = 1) generate -- pciclkint <= pciclkin; -- pciclk <= pciclkint; -- end generate; -- p1 : if (PCIDLL = 0) generate -- u0 : if (PCISYSCLK = 0) generate -- pciclkint <= pciclkin; -- end generate; -- pciclk <= clk_i when (PCISYSCLK = 1) else pciclkint; -- end generate; -- end generate; -- c3 : if (PCIEN = 0) generate -- pciclk <= Clkint; -- end generate; c0: if (PCISYSCLK = 0) or (PCIEN = 0) generate clkint <= clkin; end generate c0; c1: if PCIEN /= 0 generate d0: if PCISYSCLK = 1 generate clkint <= pciclkin; end generate d0; pciclk <= pciclkin; end generate c1; c2: if PCIEN = 0 generate pciclk <= '0'; end generate c2; sdclk_pll : stratix2_pll generic map (clk_mul, clk_div, freq, clk2xen, sdramen) port map ( inclk0 => clkint, e0 => sdclk, c0 => s_clk, c0_2x => clk2x, locked => cgo.clklock); clk <= s_clk; clkn <= not s_clk; -- pragma translate_off bootmsg : report_version generic map ( "clkgen_stratixii" & ": altpll sdram/pci clock generator, version " & tost(VERSION), "clkgen_stratixii" & ": Frequency " & tost(freq) & " KHz, PLL scaler " & tost(clk_mul) & "/" & tost(clk_div)); -- pragma translate_on end;	gpl-2.0	216a35e308b2eed49aed647efc545b3f	0.584962	3.513103	false	false	false	false
marco-c/leon-nexys2	grlib-gpl-1.3.4-b4140/designs/leon3-gr-xc6s/leon3mp.vhd	1	47,744	----------------------------------------------------------------------------- -- LEON3 Demonstration design -- Copyright (C) 2011 Jiri Gaisler, Gaisler Research ------------------------------------------------------------------------------ -- This file is a part of the GRLIB VHDL IP LIBRARY -- Copyright (C) 2003 - 2008, Gaisler Research -- Copyright (C) 2008 - 2013, Aeroflex Gaisler -- -- This program is free software; you can redistribute it and/or modify -- it under the terms of the GNU General Public License as published by -- the Free Software Foundation; either version 2 of the License, or -- (at your option) any later version. -- -- This program is distributed in the hope that it will be useful, -- but WITHOUT ANY WARRANTY; without even the implied warranty of -- MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the -- GNU General Public License for more details. -- -- You should have received a copy of the GNU General Public License -- along with this program; if not, write to the Free Software -- Foundation, Inc., 59 Temple Place, Suite 330, Boston, MA 02111-1307 USA ------------------------------------------------------------------------------ library ieee; use ieee.std_logic_1164.all; library grlib, techmap; use grlib.amba.all; use grlib.amba.all; use grlib.stdlib.all; use techmap.gencomp.all; use techmap.allclkgen.all; library gaisler; use gaisler.memctrl.all; use gaisler.leon3.all; use gaisler.uart.all; use gaisler.misc.all; use gaisler.spi.all; use gaisler.i2c.all; use gaisler.can.all; use gaisler.net.all; use gaisler.jtag.all; use gaisler.spacewire.all; -- pragma translate_off use gaisler.sim.all; library unisim; use unisim.all; -- pragma translate_on library esa; use esa.memoryctrl.all; use work.config.all; entity leon3mp is generic ( fabtech : integer := CFG_FABTECH; memtech : integer := CFG_MEMTECH; padtech : integer := CFG_PADTECH; clktech : integer := CFG_CLKTECH; disas : integer := CFG_DISAS; -- Enable disassembly to console dbguart : integer := CFG_DUART; -- Print UART on console pclow : integer := CFG_PCLOW ); port ( resetn : in std_ulogic; clk : in std_ulogic; -- 50 MHz main clock clk2 : in std_ulogic; -- User clock clk125 : in std_ulogic; -- 125 MHz clock from PHY wdogn : out std_ulogic; address : out std_logic_vector(24 downto 0); data : inout std_logic_vector(31 downto 24); oen : out std_ulogic; writen : out std_ulogic; romsn : out std_logic; ddr_clk : out std_logic; ddr_clkb : out std_logic; ddr_cke : out std_logic; ddr_odt : out std_logic; ddr_we : out std_ulogic; -- ddr write enable ddr_ras : out std_ulogic; -- ddr ras ddr_csn : out std_ulogic; -- ddr csn ddr_cas : out std_ulogic; -- ddr cas ddr_dm : out std_logic_vector (1 downto 0); -- ddr dm ddr_dqs : inout std_logic_vector (1 downto 0); -- ddr dqs ddr_dqsn : inout std_logic_vector (1 downto 0); -- ddr dqs n ddr_ad : out std_logic_vector (12 downto 0); -- ddr address ddr_ba : out std_logic_vector (2 downto 0); -- ddr bank address ddr_dq : inout std_logic_vector (15 downto 0); -- ddr data ddr_rzq : inout std_ulogic; ddr_zio : inout std_ulogic; -- dsuen : in std_ulogic; -- dip swtich 7 -- dsubre : in std_ulogic; -- switch 9 -- dsuact : out std_ulogic; -- led (0) txd1 : out std_ulogic; -- UART1 tx data rxd1 : in std_ulogic; -- UART1 rx data ctsn1 : in std_ulogic; -- UART1 ctsn rtsn1 : out std_ulogic; -- UART1 trsn txd2 : out std_ulogic; -- UART2 tx data rxd2 : in std_ulogic; -- UART2 rx data ctsn2 : in std_ulogic; -- UART2 ctsn rtsn2 : out std_ulogic; -- UART2 rtsn pio : inout std_logic_vector(17 downto 0); -- I/O port genio : inout std_logic_vector(59 downto 0); -- I/O port switch : in std_logic_vector(9 downto 0); -- I/O port led : out std_logic_vector(3 downto 0); -- I/O port erx_clk : in std_ulogic; emdio : inout std_logic; -- ethernet PHY interface erxd : in std_logic_vector(3 downto 0); erx_dv : in std_ulogic; emdint : in std_ulogic; etx_clk : out std_ulogic; etxd : out std_logic_vector(3 downto 0); etx_en : out std_ulogic; emdc : out std_ulogic; ps2clk : inout std_logic_vector(1 downto 0); ps2data : inout std_logic_vector(1 downto 0); iic_scl : inout std_ulogic; iic_sda : inout std_ulogic; ddc_scl : inout std_ulogic; ddc_sda : inout std_ulogic; dvi_iic_scl : inout std_logic; dvi_iic_sda : inout std_logic; tft_lcd_data : out std_logic_vector(11 downto 0); tft_lcd_clk_p : out std_ulogic; tft_lcd_clk_n : out std_ulogic; tft_lcd_hsync : out std_ulogic; tft_lcd_vsync : out std_ulogic; tft_lcd_de : out std_ulogic; tft_lcd_reset_b : out std_ulogic; spw_clk : in std_ulogic; spw_rxdp : in std_logic_vector(0 to CFG_SPW_NUM-1); spw_rxdn : in std_logic_vector(0 to CFG_SPW_NUM-1); spw_rxsp : in std_logic_vector(0 to CFG_SPW_NUM-1); spw_rxsn : in std_logic_vector(0 to CFG_SPW_NUM-1); spw_txdp : out std_logic_vector(0 to CFG_SPW_NUM-1); spw_txdn : out std_logic_vector(0 to CFG_SPW_NUM-1); spw_txsp : out std_logic_vector(0 to CFG_SPW_NUM-1); spw_txsn : out std_logic_vector(0 to CFG_SPW_NUM-1); -- SPI flash spi_sel_n : inout std_ulogic; spi_clk : out std_ulogic; spi_mosi : out std_ulogic -- SD Card interface (SD SPI interface) -- sdata : inout std_ulogic_vector(3 downto 0); -- sd_clk : out std_ulogic; -- spi_cmd : out std_ulogic; -- sd_prot : in std_logic; -- sd_detect : in std_logic ); end; architecture rtl of leon3mp is component BUFG port (O : out std_logic; I : in std_logic); end component; component IODELAY2 generic ( COUNTER_WRAPAROUND : string := "WRAPAROUND"; DATA_RATE : string := "SDR"; DELAY_SRC : string := "IO"; IDELAY2_VALUE : integer := 0; IDELAY_MODE : string := "NORMAL"; IDELAY_TYPE : string := "DEFAULT"; IDELAY_VALUE : integer := 0; ODELAY_VALUE : integer := 0; SERDES_MODE : string := "NONE"; SIM_TAPDELAY_VALUE : integer := 75 ); port ( BUSY : out std_ulogic; DATAOUT : out std_ulogic; DATAOUT2 : out std_ulogic; DOUT : out std_ulogic; TOUT : out std_ulogic; CAL : in std_ulogic; CE : in std_ulogic; CLK : in std_ulogic; IDATAIN : in std_ulogic; INC : in std_ulogic; IOCLK0 : in std_ulogic; IOCLK1 : in std_ulogic; ODATAIN : in std_ulogic; RST : in std_ulogic; T : in std_ulogic ); end component; attribute syn_netlist_hierarchy : boolean; attribute syn_netlist_hierarchy of rtl : architecture is false; constant use_eth_input_delay : integer := 1; constant use_eth_output_delay : integer := 1; constant blength : integer := 12; constant fifodepth : integer := 8; constant maxahbm : integer := CFG_NCPU+CFG_AHB_UART+CFG_GRETH+ CFG_AHB_JTAG+CFG_SPW_NUMCFG_SPW_EN; signal vcc, gnd : std_logic; signal memi : memory_in_type; signal memo : memory_out_type; signal wpo : wprot_out_type; signal sdi : sdctrl_in_type; signal sdo : sdram_out_type; signal leds : std_logic_vector(3 downto 0); -- I/O port signal apbi, apbi2 : apb_slv_in_type; signal apbo, apbo2 : apb_slv_out_vector := (others => apb_none); signal ahbsi : ahb_slv_in_type; signal ahbso : ahb_slv_out_vector := (others => ahbs_none); signal ahbmi : ahb_mst_in_type; signal vahbmi : ahb_mst_in_type; signal ahbmo : ahb_mst_out_vector := (others => ahbm_none); signal vahbmo : ahb_mst_out_type; signal clkm, rstn, rstraw, sdclkl : std_ulogic; signal clk_200 : std_ulogic; signal clk25, clk40, clk65 : std_ulogic; signal cgi, cgi2, cgi3 : clkgen_in_type; signal cgo, cgo2, cgo3 : clkgen_out_type; signal u1i, u2i, dui : uart_in_type; signal u1o, u2o, duo : uart_out_type; signal irqi : irq_in_vector(0 to CFG_NCPU-1); signal irqo : irq_out_vector(0 to CFG_NCPU-1); signal dbgi : l3_debug_in_vector(0 to CFG_NCPU-1); signal dbgo : l3_debug_out_vector(0 to CFG_NCPU-1); signal dsui : dsu_in_type; signal dsuo : dsu_out_type; signal gmiii, rgmiii, rgmiii_buf : eth_in_type; signal gmiio, rgmiio : eth_out_type; signal gpti : gptimer_in_type; signal gpto : gptimer_out_type; signal gpioi : gpio_in_type; signal gpioo : gpio_out_type; signal gpioi2 : gpio_in_type; signal gpioo2 : gpio_out_type; signal gpioi3 : gpio_in_type; signal gpioo3 : gpio_out_type; signal can_lrx, can_ltx : std_logic_vector(0 to 7); signal lock, calib_done, clkml, lclk, rst, ndsuact, wdogl : std_ulogic := '0'; signal tck, tckn, tms, tdi, tdo : std_ulogic; signal ethclk, ddr2clk : std_ulogic; signal kbdi : ps2_in_type; signal kbdo : ps2_out_type; signal moui : ps2_in_type; signal mouo : ps2_out_type; signal vgao : apbvga_out_type; signal lcd_datal : std_logic_vector(11 downto 0); signal lcd_hsyncl, lcd_vsyncl, lcd_del, lcd_reset_bl : std_ulogic; signal i2ci, dvi_i2ci : i2c_in_type; signal i2co, dvi_i2co : i2c_out_type; signal spmi : spimctrl_in_type; signal spmo : spimctrl_out_type; signal spmi2 : spimctrl_in_type; signal spmo2 : spimctrl_out_type; constant BOARD_FREQ : integer := 50000; -- input frequency in KHz constant CPU_FREQ : integer := BOARD_FREQ CFG_CLKMUL / CFG_CLKDIV; -- cpu frequency in KHz constant IOAEN : integer := CFG_CAN; constant DDR2_FREQ : integer := 200000; -- DDR2 input frequency in KHz signal spwi : grspw_in_type_vector(0 to CFG_SPW_NUM-1); signal spwo : grspw_out_type_vector(0 to CFG_SPW_NUM-1); signal dtmp : std_logic_vector(CFG_SPW_NUMCFG_SPW_PORTS-1 downto 0); signal stmp : std_logic_vector(CFG_SPW_NUMCFG_SPW_PORTS-1 downto 0); signal spw_rxtxclk : std_ulogic; signal spw_rxclkn : std_ulogic; signal spw_rxclk : std_logic_vector(0 to CFG_SPW_NUMCFG_SPW_PORTS); signal spw_rstn : std_ulogic; signal spw_rstn_sync : std_ulogic; signal stati : ahbstat_in_type; signal fpi : grfpu_in_vector_type; signal fpo : grfpu_out_vector_type; signal rstgtxn : std_logic; signal idelay_reset_cnt : std_logic_vector(3 downto 0); signal idelay_cal_cnt : std_logic_vector(3 downto 0); signal idelayctrl_reset : std_logic; signal idelayctrl_cal : std_logic; signal rgmiii_rx_clk_n : std_logic; signal rgmiii_rx_clk_n_buf : std_logic; signal rgmiio_tx_clk,rgmiio_tx_en : std_logic; signal rgmiio_txd : std_logic_vector(3 downto 0); -- Used for connecting input/output signals to the DDR2 controller signal core_ddr_clk : std_logic_vector(2 downto 0); signal core_ddr_clkb : std_logic_vector(2 downto 0); signal core_ddr_cke : std_logic_vector(1 downto 0); signal core_ddr_csb : std_logic_vector(1 downto 0); signal core_ddr_ad : std_logic_vector(13 downto 0); signal core_ddr_odt : std_logic_vector(1 downto 0); constant SPW_LOOP_BACK : integer := 0; signal video_clk, clk50, clk100, spw100 : std_logic; -- signals to vga_clkgen. signal clk_sel : std_logic_vector(1 downto 0); signal clkvga, clkvga_p, clkvga_n : std_ulogic; signal clk_125 : std_ulogic; signal nerror : std_ulogic; attribute keep : boolean; attribute syn_keep : boolean; attribute syn_preserve : boolean; attribute syn_keep of clk50 : signal is true; attribute syn_preserve of clk50 : signal is true; attribute keep of clk50 : signal is true; attribute syn_keep of video_clk : signal is true; attribute syn_preserve of video_clk : signal is true; attribute keep of video_clk : signal is true; attribute syn_preserve of ddr2clk : signal is true; attribute keep of ddr2clk : signal is true; attribute syn_keep of ddr2clk : signal is true; attribute syn_preserve of spw100 : signal is true; attribute keep of spw100 : signal is true; attribute syn_preserve of clkm : signal is true; attribute keep of clkm : signal is true; begin ---------------------------------------------------------------------- --- Reset and Clock generation ------------------------------------- ---------------------------------------------------------------------- vcc <= '1'; gnd <= '0'; cgi.pllctrl <= "00"; cgi.pllrst <= rstraw; clk_pad : clkpad generic map (tech => padtech) port map (clk, lclk); ddr2clk <= lclk; ethclk <= lclk; no_clk_mig : if CFG_MIG_DDR2 = 0 generate clkgen0 : clkgen -- clock generator generic map (clktech, CFG_CLKMUL, CFG_CLKDIV, CFG_MCTRL_SDEN, CFG_CLK_NOFB, 0, 0, 0, BOARD_FREQ) port map (lclk, lclk, clkm, open, open, sdclkl, open, cgi, cgo, open, clk50, clk100); rst0 : rstgen -- reset generator generic map(syncin => 1) port map (rst, clkm, lock, rstn, rstraw); end generate; clk_mig : if CFG_MIG_DDR2 = 1 generate clk50 <= clkm; rstraw <= rst; cgo.clklock <= '1'; end generate; resetn_pad : inpad generic map (tech => padtech) port map (resetn, rst); lock <= cgo.clklock and calib_done; ---------------------------------------------------------------------- --- AHB CONTROLLER -------------------------------------------------- ---------------------------------------------------------------------- ahb0 : ahbctrl -- AHB arbiter/multiplexer generic map (defmast => CFG_DEFMST, split => CFG_SPLIT, rrobin => CFG_RROBIN, ioaddr => CFG_AHBIO, ioen => IOAEN, nahbm => maxahbm, nahbs => 16) port map (rstn, clkm, ahbmi, ahbmo, ahbsi, ahbso); ---------------------------------------------------------------------- --- LEON3 processor and DSU ----------------------------------------- ---------------------------------------------------------------------- nosh : if CFG_GRFPUSH = 0 generate cpu : for i in 0 to CFG_NCPU-1 generate l3ft : if CFG_LEON3FT_EN /= 0 generate leon3ft0 : leon3ft -- LEON3 processor generic map (i, fabtech, memtech, CFG_NWIN, CFG_DSU, CFG_FPU(1-CFG_GRFPUSH), CFG_V8, 0, CFG_MAC, pclow, CFG_NOTAG, CFG_NWP, CFG_ICEN, CFG_IREPL, CFG_ISETS, CFG_ILINE, CFG_ISETSZ, CFG_ILOCK, CFG_DCEN, CFG_DREPL, CFG_DSETS, CFG_DLINE, CFG_DSETSZ, CFG_DLOCK, CFG_DSNOOP, CFG_ILRAMEN, CFG_ILRAMSZ, CFG_ILRAMADDR, CFG_DLRAMEN, CFG_DLRAMSZ, CFG_DLRAMADDR, CFG_MMUEN, CFG_ITLBNUM, CFG_DTLBNUM, CFG_TLB_TYPE, CFG_TLB_REP, CFG_LDDEL, disas, CFG_ITBSZ, CFG_PWD, CFG_SVT, CFG_RSTADDR, CFG_NCPU-1, CFG_IUFT_EN, CFG_FPUFT_EN, CFG_CACHE_FT_EN, CFG_RF_ERRINJ, CFG_CACHE_ERRINJ, CFG_DFIXED, CFG_LEON3_NETLIST, CFG_SCAN, CFG_MMU_PAGE, CFG_BP) port map (clkm, rstn, ahbmi, ahbmo(i), ahbsi, ahbso, irqi(i), irqo(i), dbgi(i), dbgo(i), clkm); end generate; l3s : if CFG_LEON3FT_EN = 0 generate u0 : leon3s -- LEON3 processor generic map (i, fabtech, memtech, CFG_NWIN, CFG_DSU, CFG_FPU(1-CFG_GRFPUSH), CFG_V8, 0, CFG_MAC, pclow, CFG_NOTAG, CFG_NWP, CFG_ICEN, CFG_IREPL, CFG_ISETS, CFG_ILINE, CFG_ISETSZ, CFG_ILOCK, CFG_DCEN, CFG_DREPL, CFG_DSETS, CFG_DLINE, CFG_DSETSZ, CFG_DLOCK, CFG_DSNOOP, CFG_ILRAMEN, CFG_ILRAMSZ, CFG_ILRAMADDR, CFG_DLRAMEN, CFG_DLRAMSZ, CFG_DLRAMADDR, CFG_MMUEN, CFG_ITLBNUM, CFG_DTLBNUM, CFG_TLB_TYPE, CFG_TLB_REP, CFG_LDDEL, disas, CFG_ITBSZ, CFG_PWD, CFG_SVT, CFG_RSTADDR, CFG_NCPU-1, CFG_DFIXED, CFG_SCAN, CFG_MMU_PAGE, CFG_BP) port map (clkm, rstn, ahbmi, ahbmo(i), ahbsi, ahbso, irqi(i), irqo(i), dbgi(i), dbgo(i)); end generate; end generate; end generate; sh : if CFG_GRFPUSH = 1 generate cpu : for i in 0 to CFG_NCPU-1 generate l3ft : if CFG_LEON3FT_EN /= 0 generate leon3ft0 : leon3ftsh -- LEON3 processor generic map (i, fabtech, memtech, CFG_NWIN, CFG_DSU, CFG_FPU, CFG_V8, 0, CFG_MAC, pclow, CFG_NOTAG, CFG_NWP, CFG_ICEN, CFG_IREPL, CFG_ISETS, CFG_ILINE, CFG_ISETSZ, CFG_ILOCK, CFG_DCEN, CFG_DREPL, CFG_DSETS, CFG_DLINE, CFG_DSETSZ, CFG_DLOCK, CFG_DSNOOP, CFG_ILRAMEN, CFG_ILRAMSZ, CFG_ILRAMADDR, CFG_DLRAMEN, CFG_DLRAMSZ, CFG_DLRAMADDR, CFG_MMUEN, CFG_ITLBNUM, CFG_DTLBNUM, CFG_TLB_TYPE, CFG_TLB_REP, CFG_LDDEL, disas, CFG_ITBSZ, CFG_PWD, CFG_SVT, CFG_RSTADDR, CFG_NCPU-1, CFG_IUFT_EN, CFG_FPUFT_EN, CFG_CACHE_FT_EN, CFG_RF_ERRINJ, CFG_CACHE_ERRINJ, CFG_DFIXED, CFG_LEON3_NETLIST, CFG_SCAN, CFG_MMU_PAGE) port map (clkm, rstn, ahbmi, ahbmo(i), ahbsi, ahbso, irqi(i), irqo(i), dbgi(i), dbgo(i), clkm, fpi(i), fpo(i)); end generate; l3s : if CFG_LEON3FT_EN = 0 generate u0 : leon3sh -- LEON3 processor generic map (i, fabtech, memtech, CFG_NWIN, CFG_DSU, CFG_FPU, CFG_V8, 0, CFG_MAC, pclow, CFG_NOTAG, CFG_NWP, CFG_ICEN, CFG_IREPL, CFG_ISETS, CFG_ILINE, CFG_ISETSZ, CFG_ILOCK, CFG_DCEN, CFG_DREPL, CFG_DSETS, CFG_DLINE, CFG_DSETSZ, CFG_DLOCK, CFG_DSNOOP, CFG_ILRAMEN, CFG_ILRAMSZ, CFG_ILRAMADDR, CFG_DLRAMEN, CFG_DLRAMSZ, CFG_DLRAMADDR, CFG_MMUEN, CFG_ITLBNUM, CFG_DTLBNUM, CFG_TLB_TYPE, CFG_TLB_REP, CFG_LDDEL, disas, CFG_ITBSZ, CFG_PWD, CFG_SVT, CFG_RSTADDR, CFG_NCPU-1, CFG_DFIXED, CFG_SCAN, CFG_MMU_PAGE) port map (clkm, rstn, ahbmi, ahbmo(i), ahbsi, ahbso, irqi(i), irqo(i), dbgi(i), dbgo(i), fpi(i), fpo(i)); end generate; end generate; grfpush0 : grfpushwx generic map ((CFG_FPU-1), CFG_NCPU, fabtech) port map (clkm, rstn, fpi, fpo); end generate; nerror <= dbgo(0).error; led1_pad : odpad generic map (tech => padtech) port map (led(1), nerror); dsugen : if CFG_DSU = 1 generate dsu0 : dsu3 -- LEON3 Debug Support Unit generic map (hindex => 2, haddr => 16#900#, hmask => 16#F00#, ncpu => CFG_NCPU, tbits => 30, tech => memtech, irq => 0, kbytes => CFG_ATBSZ) port map (rstn, clkm, ahbmi, ahbsi, ahbso(2), dbgo, dbgi, dsui, dsuo); dsuen_pad : inpad generic map (tech => padtech) port map (switch(7), dsui.enable); dsubre_pad : inpad generic map (tech => padtech) port map (switch(8), dsui.break); dsuact_pad : outpad generic map (tech => padtech) port map (led(0), ndsuact); ndsuact <= not dsuo.active; end generate; nodsu : if CFG_DSU = 0 generate dsuo.tstop <= '0'; dsuo.active <= '0'; ahbso(2) <= ahbs_none; end generate; dcomgen : if CFG_AHB_UART = 1 generate dcom0: ahbuart -- Debug UART generic map (hindex => CFG_NCPU, pindex => 7, paddr => 7) port map (rstn, clkm, dui, duo, apbi, apbo(7), ahbmi, ahbmo(CFG_NCPU)); dsurx_pad : inpad generic map (tech => padtech) port map (rxd2, dui.rxd); dsutx_pad : outpad generic map (tech => padtech) port map (txd2, duo.txd); end generate; nouah : if CFG_AHB_UART = 0 generate apbo(7) <= apb_none; end generate; ahbjtaggen0 :if CFG_AHB_JTAG = 1 generate ahbjtag0 : ahbjtag generic map(tech => fabtech, hindex => CFG_NCPU+CFG_AHB_UART) port map(rstn, clkm, tck, tms, tdi, tdo, ahbmi, ahbmo(CFG_NCPU+CFG_AHB_UART), open, open, open, open, open, open, open, gnd); end generate; ---------------------------------------------------------------------- --- Memory controllers ---------------------------------------------- ---------------------------------------------------------------------- memi.writen <= '1'; memi.wrn <= "1111"; memi.bwidth <= "00"; memi.brdyn <= '0'; memi.bexcn <= '1'; mctrl0 : if CFG_MCTRL_LEON2 /= 0 generate mctrl0 : mctrl generic map (hindex => 0, pindex => 0, paddr => 0, srbanks => 2, ram8 => CFG_MCTRL_RAM8BIT, ram16 => CFG_MCTRL_RAM16BIT, sden => CFG_MCTRL_SDEN, invclk => CFG_CLK_NOFB, sepbus => CFG_MCTRL_SEPBUS, pageburst => CFG_MCTRL_PAGE, rammask => 0, iomask => 0) port map (rstn, clkm, memi, memo, ahbsi, ahbso(0), apbi, apbo(0), wpo, sdo); addr_pad : outpadv generic map (width => 25, tech => padtech) port map (address, memo.address(24 downto 0)); roms_pad : outpad generic map (tech => padtech) port map (romsn, memo.romsn(0)); oen_pad : outpad generic map (tech => padtech) port map (oen, memo.oen); wri_pad : outpad generic map (tech => padtech) port map (writen, memo.writen); bdr : for i in 0 to 0 generate data_pad : iopadv generic map (tech => padtech, width => 8) port map (data(31-i8 downto 24-i8), memo.data(31-i8 downto 24-i8), memo.bdrive(i), memi.data(31-i8 downto 24-i8)); end generate; end generate; nomctrl : if CFG_MCTRL_LEON2 = 0 generate romsn <= '1'; ahbso(0) <= ahbs_none; end generate; ----------------------------------------------------------------------- --- Test report module ---------------------------------------------- ----------------------------------------------------------------------- -- pragma translate_off test0 : ahbrep generic map (hindex => 6, haddr => 16#200#) port map (rstn, clkm, ahbsi, ahbso(6)); -- pragma translate_on ---------------------------------------------------------------------- --- DDR2 memory controller ------------------------------------------ ---------------------------------------------------------------------- ddr_csn <= '0'; mig_gen : if (CFG_MIG_DDR2 = 1) generate ddrc : entity work.ahb2mig_grxc6s_2p generic map( hindex => 4, haddr => 16#400#, hmask => 16#F80#, pindex => 0, paddr => 0, vgamst => CFG_SVGA_ENABLE, vgaburst => 64, clkdiv => 10) port map( mcb3_dram_dq => ddr_dq, mcb3_dram_a => ddr_ad, mcb3_dram_ba => ddr_ba, mcb3_dram_ras_n => ddr_ras, mcb3_dram_cas_n => ddr_cas, mcb3_dram_we_n => ddr_we, mcb3_dram_odt => ddr_odt, mcb3_dram_cke => ddr_cke, mcb3_dram_dm => ddr_dm(0), mcb3_dram_udqs => ddr_dqs(1), mcb3_dram_udqs_n => ddr_dqsn(1), mcb3_rzq => ddr_rzq, mcb3_zio => ddr_zio, mcb3_dram_udm => ddr_dm(1), mcb3_dram_dqs => ddr_dqs(0), mcb3_dram_dqs_n => ddr_dqsn(0), mcb3_dram_ck => ddr_clk, mcb3_dram_ck_n => ddr_clkb, ahbsi => ahbsi, ahbso => ahbso(4), ahbmi => vahbmi, ahbmo => vahbmo, apbi => apbi2, apbo => apbo2(0), calib_done => calib_done, rst_n_syn => rstn, rst_n_async => rstraw, clk_amba => clkm, clk_mem_n => ddr2clk, clk_mem_p => ddr2clk, test_error => open, clk_125 => clk_125, clk_100 => clk100 ); end generate; noddr : if (CFG_DDR2SP+CFG_MIG_DDR2) = 0 generate calib_done <= '1'; end generate; ---------------------------------------------------------------------- --- SPI Memory Controller-------------------------------------------- ---------------------------------------------------------------------- spimc: if CFG_SPICTRL_ENABLE = 0 and CFG_SPIMCTRL = 1 generate spimctrl0 : spimctrl -- SPI Memory Controller generic map (hindex => 3, hirq => 7, faddr => 16#e00#, fmask => 16#ff8#, ioaddr => 16#002#, iomask => 16#fff#, spliten => CFG_SPLIT, oepol => 0, sdcard => CFG_SPIMCTRL_SDCARD, readcmd => CFG_SPIMCTRL_READCMD, dummybyte => CFG_SPIMCTRL_DUMMYBYTE, dualoutput => CFG_SPIMCTRL_DUALOUTPUT, scaler => CFG_SPIMCTRL_SCALER, altscaler => CFG_SPIMCTRL_ASCALER, pwrupcnt => CFG_SPIMCTRL_PWRUPCNT) port map (rstn, clkm, ahbsi, ahbso(3), spmi, spmo); -- MISO is shared with Flash data 0 spmi.miso <= memi.data(24); mosi_pad : outpad generic map (tech => padtech) port map (spi_mosi, spmo.mosi); sck_pad : outpad generic map (tech => padtech) port map (spi_clk, spmo.sck); slvsel0_pad : odpad generic map (tech => padtech) port map (spi_sel_n, spmo.csn); end generate; nospimc: if ((CFG_SPICTRL_ENABLE = 0 and CFG_SPIMCTRL = 0) or (CFG_SPICTRL_ENABLE = 1 and CFG_SPIMCTRL = 1) or (CFG_SPICTRL_ENABLE = 1 and CFG_SPIMCTRL = 0))generate mosi_pad : outpad generic map (tech => padtech) port map (spi_mosi, '0'); sck_pad : outpad generic map (tech => padtech) port map (spi_clk, '0'); end generate; ---------------------------------------------------------------------- --- APB Bridge and various periherals ------------------------------- ---------------------------------------------------------------------- apb0 : apbctrl -- AHB/APB bridge generic map (hindex => 1, haddr => CFG_APBADDR, nslaves => 16) port map (rstn, clkm, ahbsi, ahbso(1), apbi, apbo ); apb1 : apbctrl -- AHB/APB bridge generic map (hindex => 13, haddr => CFG_APBADDR+1, nslaves => 16) port map (rstn, clkm, ahbsi, ahbso(13), apbi2, apbo2 ); ua1 : if CFG_UART1_ENABLE /= 0 generate uart1 : apbuart -- UART 1 generic map (pindex => 1, paddr => 1, pirq => 2, console => dbguart, fifosize => CFG_UART1_FIFO) port map (rstn, clkm, apbi, apbo(1), u1i, u1o); u1i.extclk <= '0'; rxd1_pad : inpad generic map (tech => padtech) port map (rxd1, u1i.rxd); txd1_pad : outpad generic map (tech => padtech) port map (txd1, u1o.txd); cts1_pad : inpad generic map (tech => padtech) port map (ctsn1, u1i.ctsn); rts1_pad : outpad generic map (tech => padtech) port map (rtsn1, u1o.rtsn); end generate; noua0 : if CFG_UART1_ENABLE = 0 generate apbo(1) <= apb_none; end generate; rts1_pad : outpad generic map (tech => padtech) port map (rtsn2, '0'); irqctrl : if CFG_IRQ3_ENABLE /= 0 generate irqctrl0 : irqmp -- interrupt controller generic map (pindex => 2, paddr => 2, ncpu => CFG_NCPU) port map (rstn, clkm, apbi, apbo(2), irqo, irqi); end generate; irq3 : if CFG_IRQ3_ENABLE = 0 generate x : for i in 0 to CFG_NCPU-1 generate irqi(i).irl <= "0000"; end generate; apbo(2) <= apb_none; end generate; gpt : if CFG_GPT_ENABLE /= 0 generate timer0 : gptimer -- timer unit generic map (pindex => 3, paddr => 3, pirq => CFG_GPT_IRQ, sepirq => CFG_GPT_SEPIRQ, sbits => CFG_GPT_SW, ntimers => CFG_GPT_NTIM, nbits => CFG_GPT_TW, wdog => CFG_GPT_WDOGENCFG_GPT_WDOG) port map (rstn, clkm, apbi, apbo(3), gpti, gpto); gpti.dhalt <= dsuo.tstop; gpti.extclk <= '0'; end generate; wden : if CFG_GPT_WDOGEN /= 0 generate wdogl <= gpto.wdogn or not rstn; wdogn_pad : odpad generic map (tech => padtech) port map (wdogn, wdogl); end generate; wddis : if CFG_GPT_WDOGEN = 0 generate wdogn_pad : odpad generic map (tech => padtech) port map (wdogn, vcc); end generate; nogpt : if CFG_GPT_ENABLE = 0 generate apbo(3) <= apb_none; end generate; kbd : if CFG_KBD_ENABLE /= 0 generate ps21 : apbps2 generic map(pindex => 4, paddr => 4, pirq => 4) port map(rstn, clkm, apbi, apbo(4), moui, mouo); ps20 : apbps2 generic map(pindex => 5, paddr => 5, pirq => 5) port map(rstn, clkm, apbi, apbo(5), kbdi, kbdo); end generate; nokbd : if CFG_KBD_ENABLE = 0 generate apbo(4) <= apb_none; mouo <= ps2o_none; apbo(5) <= apb_none; kbdo <= ps2o_none; end generate; kbdclk_pad : iopad generic map (tech => padtech) port map (ps2clk(1),kbdo.ps2_clk_o, kbdo.ps2_clk_oe, kbdi.ps2_clk_i); kbdata_pad : iopad generic map (tech => padtech) port map (ps2data(1), kbdo.ps2_data_o, kbdo.ps2_data_oe, kbdi.ps2_data_i); mouclk_pad : iopad generic map (tech => padtech) port map (ps2clk(0),mouo.ps2_clk_o, mouo.ps2_clk_oe, moui.ps2_clk_i); mouata_pad : iopad generic map (tech => padtech) port map (ps2data(0), mouo.ps2_data_o, mouo.ps2_data_oe, moui.ps2_data_i); vga : if CFG_VGA_ENABLE /= 0 generate vga0 : apbvga generic map(memtech => memtech, pindex => 6, paddr => 6) port map(rstn, clkm, ethclk, apbi, apbo(6), vgao); video_clk <= not ethclk; end generate; svga : if CFG_SVGA_ENABLE /= 0 generate svga0 : svgactrl generic map(memtech => memtech, pindex => 6, paddr => 6, hindex => CFG_NCPU+CFG_AHB_UART+CFG_AHB_JTAG, clk0 => 20000, clk1 => 0, --1000000000/((BOARD_FREQ * CFG_CLKMUL)/CFG_CLKDIV), clk2 => 0, clk3 => 0, burstlen => 6) port map(rstn, clkm, video_clk, apbi, apbo(6), vgao, vahbmi, vahbmo, clk_sel); end generate; --b0 : techbuf generic map (2, fabtech) port map (clk50, video_clk); video_clk <= clk50; vgadvi : if (CFG_VGA_ENABLE + CFG_SVGA_ENABLE) /= 0 generate dvi0 : entity work.svga2ch7301c generic map (tech => fabtech, dynamic => 1) port map (clkm, vgao, video_clk, clkvga_p, clkvga_n, lcd_datal, lcd_hsyncl, lcd_vsyncl, lcd_del); i2cdvi : i2cmst generic map (pindex => 9, paddr => 9, pmask => 16#FFF#, pirq => 3) port map (rstn, clkm, apbi, apbo(9), dvi_i2ci, dvi_i2co); end generate; novga : if (CFG_VGA_ENABLE = 0 and CFG_SVGA_ENABLE = 0) generate apbo(6) <= apb_none; vgao <= vgao_none; end generate; tft_lcd_data_pad : outpadv generic map (width => 12, tech => padtech) port map (tft_lcd_data, lcd_datal); tft_lcd_clkp_pad : outpad generic map (tech => padtech) port map (tft_lcd_clk_p, clkvga_p); tft_lcd_clkn_pad : outpad generic map (tech => padtech) port map (tft_lcd_clk_n, clkvga_n); tft_lcd_hsync_pad : outpad generic map (tech => padtech) port map (tft_lcd_hsync, lcd_hsyncl); tft_lcd_vsync_pad : outpad generic map (tech => padtech) port map (tft_lcd_vsync, lcd_vsyncl); tft_lcd_de_pad : outpad generic map (tech => padtech) port map (tft_lcd_de, lcd_del); tft_lcd_reset_pad : outpad generic map (tech => padtech) port map (tft_lcd_reset_b, rstn); dvi_i2c_scl_pad : iopad generic map (tech => padtech) port map (dvi_iic_scl, dvi_i2co.scl, dvi_i2co.scloen, dvi_i2ci.scl); dvi_i2c_sda_pad : iopad generic map (tech => padtech) port map (dvi_iic_sda, dvi_i2co.sda, dvi_i2co.sdaoen, dvi_i2ci.sda); gpio0 : if CFG_GRGPIO_ENABLE /= 0 generate -- GPIO unit grgpio0: grgpio generic map(pindex => 10, paddr => 10, imask => CFG_GRGPIO_IMASK, nbits => 16) port map(rst => rstn, clk => clkm, apbi => apbi, apbo => apbo(10), gpioi => gpioi, gpioo => gpioo); p0 : if (CFG_CAN = 0) or (CFG_CAN_NUM = 1) generate pio_pads : for i in 1 to 2 generate pio_pad : iopad generic map (tech => padtech) port map (pio(i), gpioo.dout(i), gpioo.oen(i), gpioi.din(i)); end generate; end generate; p1 : if (CFG_CAN = 0) generate pio_pads : for i in 4 to 5 generate pio_pad : iopad generic map (tech => padtech) port map (pio(i), gpioo.dout(i), gpioo.oen(i), gpioi.din(i)); end generate; end generate; pio_pad0 : iopad generic map (tech => padtech) port map (pio(0), gpioo.dout(0), gpioo.oen(0), gpioi.din(0)); pio_pad1 : iopad generic map (tech => padtech) port map (pio(3), gpioo.dout(3), gpioo.oen(3), gpioi.din(3)); pio_pads : for i in 6 to 15 generate pio_pad : iopad generic map (tech => padtech) port map (pio(i), gpioo.dout(i), gpioo.oen(i), gpioi.din(i)); end generate; end generate; -- make an additonal 32 bit GPIO port for genio(31..0) gpio1 : if CFG_GRGPIO_ENABLE /= 0 generate -- GPIO unit grgpio1: grgpio generic map(pindex => 11, paddr => 11, imask => CFG_GRGPIO_IMASK, nbits => 32) port map(rst => rstn, clk => clkm, apbi => apbi, apbo => apbo(11), gpioi => gpioi2, gpioo => gpioo2); pio_pads : for i in 0 to 31 generate pio_pad : iopad generic map (tech => padtech) port map (genio(i), gpioo2.dout(i), gpioo2.oen(i), gpioi2.din(i)); end generate; end generate; gpio2 : if CFG_GRGPIO_ENABLE /= 0 generate -- GPIO unit grgpio2: grgpio generic map(pindex => 12, paddr => 12, imask => CFG_GRGPIO_IMASK, nbits => 28) port map(rst => rstn, clk => clkm, apbi => apbi, apbo => apbo(12), gpioi => gpioi3, gpioo => gpioo3); pio_pads : for i in 0 to 27 generate pio_pad : iopad generic map (tech => padtech) port map (genio(i+32), gpioo3.dout(i), gpioo3.oen(i), gpioi3.din(i)); end generate; end generate; ahbs : if CFG_AHBSTAT = 1 generate -- AHB status register ahbstat0 : ahbstat generic map (pindex => 13, paddr => 13, pirq => 1, nftslv => CFG_AHBSTATN) port map (rstn, clkm, ahbmi, ahbsi, stati, apbi, apbo(13)); end generate; ----------------------------------------------------------------------- --- ETHERNET --------------------------------------------------------- ----------------------------------------------------------------------- eth0 : if CFG_GRETH = 1 generate -- Gaisler ethernet MAC e1 : grethm generic map( hindex => CFG_NCPU+CFG_AHB_UART+CFG_AHB_JTAG, pindex => 14, paddr => 14, pirq => 6, memtech => memtech, mdcscaler => CPU_FREQ/1000, rmii => 0, enable_mdio => 1, fifosize => CFG_ETH_FIFO, nsync => 1, edcl => CFG_DSU_ETH, edclbufsz => CFG_ETH_BUF, phyrstadr => 1, macaddrh => CFG_ETH_ENM, macaddrl => CFG_ETH_ENL, enable_mdint => 1, ipaddrh => CFG_ETH_IPM, ipaddrl => CFG_ETH_IPL, giga => CFG_GRETH1G) port map( rst => rstn, clk => clkm, ahbmi => ahbmi, ahbmo => ahbmo(CFG_NCPU+CFG_AHB_UART+CFG_AHB_JTAG), apbi => apbi, apbo => apbo(14), ethi => gmiii, etho => gmiio); end generate; led(3 downto 2) <= not (gmiio.gbit & gmiio.speed); noethindelay0 : if (use_eth_input_delay = 0) generate rgmiii.rx_dv <= rgmiii_buf.rx_dv; rgmiii.rxd <= rgmiii_buf.rxd; end generate; noethoutdelay0 : if (use_eth_output_delay = 0) generate rgmiio_tx_clk <= rgmiio.tx_clk; rgmiio_tx_en <= rgmiio.tx_en; rgmiio_txd <= rgmiio.txd(3 downto 0); end generate; ethindelay0 : if (use_eth_input_delay /= 0) generate delay_rgmii_rx_ctl0 : IODELAY2 generic map( DELAY_SRC => "IDATAIN", IDELAY_TYPE => "FIXED", IDELAY_VALUE => 16 -- Delay (256/8)424ps30% + n/8424ps + Ttap(See table 39 in Xilinx ds162.pdf) ) port map( IDATAIN => rgmiii_buf.rx_dv, T => '1', ODATAIN => '0', CAL => '0', IOCLK0 => '0', IOCLK1 => '0', CLK => '0', INC => '0', CE => '0', RST => '0', BUSY => OPEN, DATAOUT => rgmiii.rx_dv, DATAOUT2 => OPEN, TOUT => OPEN, DOUT => OPEN ); rgmii_rxd : for i in 0 to 3 generate delay_rgmii_rxd0 : IODELAY2 generic map( DELAY_SRC => "IDATAIN", IDELAY_TYPE => "FIXED", IDELAY_VALUE => 16 -- Delay (256/8)424ps30% + n/8424ps + Ttap(See table 39 in Xilinx ds162.pdf) ) port map( IDATAIN => rgmiii_buf.rxd(i), T => '1', ODATAIN => '0', CAL => '0', IOCLK0 => '0', IOCLK1 => '0', CLK => '0', INC => '0', CE => '0', RST => '0', BUSY => OPEN, DATAOUT => rgmiii.rxd(i), DATAOUT2 => OPEN, TOUT => OPEN, DOUT => OPEN ); end generate; end generate; ethoutdelay0 : if (use_eth_output_delay /= 0) generate delay_rgmii_tx_clk0 : IODELAY2 generic map( DELAY_SRC => "ODATAIN", IDELAY_TYPE => "FIXED", ODELAY_VALUE => 16 -- Delay (256/8)424ps30% + n/8424ps + Ttap(See table 39 in Xilinx ds162.pdf) ) port map( IDATAIN => '0', T => '1', ODATAIN => rgmiio.tx_clk, CAL => '0', IOCLK0 => '0', IOCLK1 => '0', CLK => '0', INC => '0', CE => '0', RST => '0', BUSY => OPEN, DATAOUT => OPEN, DATAOUT2 => OPEN, TOUT => OPEN, DOUT => rgmiio_tx_clk ); delay_rgmii_tx_en0 : IODELAY2 generic map( DELAY_SRC => "ODATAIN", IDELAY_TYPE => "FIXED", ODELAY_VALUE => 0 ) port map( IDATAIN => '0', T => '1', ODATAIN => rgmiio.tx_en, CAL => '0', IOCLK0 => '0', IOCLK1 => '0', CLK => '0', INC => '0', CE => '0', RST => '0', BUSY => OPEN, DATAOUT => OPEN, DATAOUT2 => OPEN, TOUT => OPEN, DOUT => rgmiio_tx_en ); rgmii_txd : for i in 0 to 3 generate delay_rgmii_txd0 : IODELAY2 generic map( DELAY_SRC => "ODATAIN", IDELAY_TYPE => "FIXED", ODELAY_VALUE => 0 ) port map( IDATAIN => '0', T => '1', ODATAIN => rgmiio.txd(i), CAL => '0', IOCLK0 => '0', IOCLK1 => '0', CLK => '0', INC => '0', CE => '0', RST => '0', BUSY => OPEN, DATAOUT => OPEN, DATAOUT2 => OPEN, TOUT => OPEN, DOUT => rgmiio_txd(i) ); end generate; end generate; rgmii0 : rgmii generic map (15, 16#010# , 16#ff0#, fabtech, CFG_GRETH1G, 1, 0, 1) port map (rstn, rgmiii.gtx_clk, gmiii, gmiio, rgmiii, rgmiio, clkm, rstn, apbi, apbo(15)); ethpads : if (CFG_GRETH = 1) generate -- eth pads etxc_pad : outpad generic map (tech => padtech) port map (etx_clk, rgmiio_tx_clk); erxc_pad : clkpad generic map (tech => padtech, arch => 2) port map (erx_clk, rgmiii.rx_clk); erxd_pad : inpadv generic map (tech => padtech, width => 4) port map (erxd, rgmiii_buf.rxd(3 downto 0)); erxdv_pad : inpad generic map (tech => padtech) port map (erx_dv, rgmiii_buf.rx_dv); etxd_pad : outpadv generic map (tech => padtech, width => 4) port map (etxd, rgmiio_txd(3 downto 0)); etxen_pad : outpad generic map (tech => padtech) port map ( etx_en, rgmiio_tx_en); emdio_pad : iopad generic map (tech => padtech) port map (emdio, rgmiio.mdio_o, rgmiio.mdio_oe, rgmiii.mdio_i); emdc_pad : outpad generic map (tech => padtech) port map (emdc, rgmiio.mdc); emdint_pad : inpad generic map (tech => padtech) port map (emdint, rgmiii.mdint); -- Incoming 125Mhz ref clock clk125_pad : clkpad generic map (tech => padtech, arch => 2) port map (clk125, rgmiii.gtx_clk); end generate; ----------------------------------------------------------------------- --- AHB RAM ---------------------------------------------------------- ----------------------------------------------------------------------- ocram : if CFG_AHBRAMEN = 1 generate ahbram0 : ahbram generic map (hindex => 7, haddr => CFG_AHBRADDR, tech => CFG_MEMTECH, kbytes => CFG_AHBRSZ, pipe => CFG_AHBRPIPE) port map ( rstn, clkm, ahbsi, ahbso(7)); end generate; ----------------------------------------------------------------------- --- Multi-core CAN --------------------------------------------------- ----------------------------------------------------------------------- can0 : if CFG_CAN = 1 generate can0 : can_mc generic map (slvndx => 4, ioaddr => CFG_CANIO, iomask => 16#FF0#, irq => CFG_CANIRQ, memtech => memtech, ncores => CFG_CAN_NUM, sepirq => CFG_CANSEPIRQ) port map (rstn, clkm, ahbsi, ahbso(4), can_lrx, can_ltx ); can_tx_pad1 : iopad generic map (tech => padtech) port map (pio(5), can_ltx(0), gnd, gpioi.din(5)); can_rx_pad1 : iopad generic map (tech => padtech) port map (pio(4), gnd, vcc, can_lrx(0)); canpas : if CFG_CAN_NUM = 2 generate can_tx_pad2 : iopad generic map (tech => padtech) port map (pio(2), can_ltx(1), gnd, gpioi.din(2)); can_rx_pad2 : iopad generic map (tech => padtech) port map (pio(1), gnd, vcc, can_lrx(1)); end generate; end generate; -- standby controlled by pio(3) and pio(0) ----------------------------------------------------------------------- --- SPACEWIRE ------------------------------------------------------- ----------------------------------------------------------------------- -- temporary, just to make sure the SPW pins are instantiated correctly no_spw : if CFG_SPW_EN = 0 generate pad_gen: for i in 0 to CFG_SPW_NUM-1 generate spw_rxd_pad : inpad_ds generic map (padtech, lvds, x33v) port map (spw_rxdp(i), spw_rxdn(i), dtmp(i)); spw_rxs_pad : inpad_ds generic map (padtech, lvds, x33v) port map (spw_rxsp(i), spw_rxsn(i), stmp(i)); spw_txd_pad : outpad_ds generic map (padtech, lvds, x33v) port map (spw_txdp(i), spw_txdn(i), dtmp(i), gnd); spw_txs_pad : outpad_ds generic map (padtech, lvds, x33v) port map (spw_txsp(i), spw_txsn(i), stmp(i), gnd); end generate; end generate; spw : if CFG_SPW_EN > 0 generate core0: if CFG_SPW_GRSPW = 1 generate spw_rxtxclk <= clkm; spw_rstn <= rstn; end generate; core1 : if CFG_SPW_GRSPW = 2 generate spw_rxtxclk <= clk100; spw_rstn_sync_proc : process(rstn,spw_rxtxclk) begin if rstn = '0' then spw_rstn_sync <= '0'; spw_rstn <= '0'; elsif rising_edge(spw_rxtxclk) then spw_rstn_sync <= '1'; spw_rstn <= spw_rstn_sync; end if; end process spw_rstn_sync_proc; end generate; spw_rxclkn <= not spw_rxtxclk; swloop : for i in 0 to CFG_SPW_NUM-1 generate -- GRSPW2 PHY spw2_input : if CFG_SPW_GRSPW = 2 generate spw_inputloop: for j in 0 to CFG_SPW_PORTS-1 generate spw_phy0 : grspw2_phy generic map( scantest => 0, tech => fabtech, input_type => CFG_SPW_INPUT) port map( rstn => spw_rstn, rxclki => spw_rxtxclk, rxclkin => spw_rxclkn, nrxclki => spw_rxtxclk, di => dtmp(iCFG_SPW_PORTS+j), si => stmp(iCFG_SPW_PORTS+j), do => spwi(i).d(j2+1 downto j2), dov => spwi(i).dv(j2+1 downto j2), dconnect => spwi(i).dconnect(j2+1 downto j2), rxclko => spw_rxclk(iCFG_SPW_PORTS+j)); end generate; oneport : if CFG_SPW_PORTS = 1 generate spwi(i).d(3 downto 2) <= "00"; -- For second port spwi(i).dv(3 downto 2) <= "00"; -- For second port spwi(i).dconnect(3 downto 2) <= "00"; -- For second port end generate; spwi(i).nd <= (others => '0'); -- Only used in GRSPW end generate; spw1_input: if CFG_SPW_GRSPW = 1 generate spw_inputloop: for j in 0 to CFG_SPW_PORTS-1 generate spw_phy0 : grspw_phy generic map( tech => fabtech, rxclkbuftype => 2, scantest => 0) port map( rxrst => spwo(i).rxrst, di => dtmp(iCFG_SPW_PORTS+j), si => stmp(iCFG_SPW_PORTS+j), rxclko => spw_rxclk(iCFG_SPW_PORTS+j), do => spwi(i).d(j), ndo => spwi(i).nd(j5+4 downto j5), dconnect => spwi(i).dconnect(j2+1 downto j2)); end generate spw_inputloop; oneport : if CFG_SPW_PORTS = 1 generate spwi(i).d(1) <= '0'; -- For second port spwi(i).d(3 downto 2) <= "00"; -- For GRSPW2 second port spwi(i).nd(9 downto 5) <= "00000"; -- For second port spwi(i).dconnect(3 downto 2) <= "00"; -- For second port end generate; spwi(i).dv <= (others => '0'); -- Only used in GRSPW2 end generate spw1_input; sw0 : grspwm generic map(tech => memtech, hindex => CFG_NCPU+CFG_AHB_UART+CFG_GRETH+CFG_AHB_JTAG+i, sysfreq => CPU_FREQ, usegen => 1, pindex => 10+i, paddr => 10+i, pirq => 10+i, nsync => 1, rmap => CFG_SPW_RMAP, rxunaligned => CFG_SPW_RXUNAL, rmapcrc => CFG_SPW_RMAPCRC, fifosize1 => CFG_SPW_AHBFIFO, fifosize2 => CFG_SPW_RXFIFO, rxclkbuftype => 2, dmachan => CFG_SPW_DMACHAN, rmapbufs => CFG_SPW_RMAPBUF, ft => CFG_SPW_FT, ports => CFG_SPW_PORTS, spwcore => CFG_SPW_GRSPW, netlist => CFG_SPW_NETLIST, rxtx_sameclk => CFG_SPW_RTSAME, input_type => CFG_SPW_INPUT, output_type => CFG_SPW_OUTPUT) port map(rstn, clkm, spw_rxclk(iCFG_SPW_PORTS), spw_rxclk(iCFG_SPW_PORTS+1), spw_rxtxclk, spw_rxtxclk, ahbmi, ahbmo(CFG_NCPU+CFG_AHB_UART+CFG_GRETH+CFG_AHB_JTAG+i), apbi2, apbo2(10+i), spwi(i), spwo(i)); spwi(i).tickin <= '0'; spwi(i).rmapen <= '1'; spwi(i).clkdiv10 <= conv_std_logic_vector(CPU_FREQ/10000-1, 8) when CFG_SPW_GRSPW = 1 else conv_std_logic_vector(10-1, 8); spwi(i).tickinraw <= '0'; spwi(i).timein <= (others => '0'); spwi(i).dcrstval <= (others => '0'); spwi(i).timerrstval <= (others => '0'); swportloop1: for j in 0 to CFG_SPW_PORTS-1 generate spwlb0 : if SPW_LOOP_BACK = 1 generate dtmp(iCFG_SPW_PORTS+j) <= spwo(i).d(j); stmp(iCFG_SPW_PORTS+j) <= spwo(i).s(j); end generate; nospwlb0 : if SPW_LOOP_BACK = 0 generate spw_rxd_pad : inpad_ds generic map (padtech, lvds, x33v, 1) port map (spw_rxdp(iCFG_SPW_PORTS+j), spw_rxdn(iCFG_SPW_PORTS+j), dtmp(iCFG_SPW_PORTS+j)); spw_rxs_pad : inpad_ds generic map (padtech, lvds, x33v, 1) port map (spw_rxsp(iCFG_SPW_PORTS+j), spw_rxsn(iCFG_SPW_PORTS+j), stmp(iCFG_SPW_PORTS+j)); spw_txd_pad : outpad_ds generic map (padtech, lvds, x33v) port map (spw_txdp(iCFG_SPW_PORTS+j), spw_txdn(iCFG_SPW_PORTS+j), spwo(i).d(j), gnd); spw_txs_pad : outpad_ds generic map (padtech, lvds, x33v) port map (spw_txsp(iCFG_SPW_PORTS+j), spw_txsn(i*CFG_SPW_PORTS+j), spwo(i).s(j), gnd); end generate; end generate; end generate; end generate; ----------------------------------------------------------------------- --- Drive unused bus elements --------------------------------------- ----------------------------------------------------------------------- -- nam1 : for i in (CFG_NCPU+CFG_AHB_UART+CFG_GRETH+CFG_AHB_JTAG) to NAHBMST-1 generate -- ahbmo(i) <= ahbm_none; -- end generate; -- nap0 : for i in 11 to NAPBSLV-1 generate apbo(i) <= apb_none; end generate; -- nah0 : for i in 8 to NAHBSLV-1 generate ahbso(i) <= ahbs_none; end generate; ----------------------------------------------------------------------- --- Boot message ---------------------------------------------------- ----------------------------------------------------------------------- -- pragma translate_off x : report_design generic map ( msg1 => "LEON3 GR-XC6S-LX75 Demonstration design", fabtech => tech_table(fabtech), memtech => tech_table(memtech), mdel => 1 ); -- pragma translate_on end;	gpl-2.0	42623f44201ae3d4dee6d39fef66336d	0.553221	3.425456	false	false	false	false
capitanov/Stupid_watch	src/top/top_xc3s500e_ex.vhd	1	14,017	-------------------------------------------------------------------------------- -- -- Title : top_xc3s500e_ex.vhd -- Design : Example -- Author : Kapitanov -- Company : InSys -- -- Version : 1.0 -------------------------------------------------------------------------------- -- -- Description : Top level for timer based on Spartan3E Starter Kit -- -- Xilinx Spartan3e - XC3S500E-4FG320C -- Switches, LEDs, TIMER (ds1302), display (lcd1602) -- -- SW<0> - RESET -- SW<1> - ENABLE -- SW<2> - PWM -- SW<3> - START -- -- -------------------------------------------------------------------------------- library IEEE; --! main standard libs use IEEE.STD_LOGIC_1164.all; use IEEE.STD_LOGIC_UNSIGNED.all; library UNISIM; --! xilinx unusim libs use UNISIM.VCOMPONENTS.ALL; library WORK; --! user work libs use WORK.ctrl_types_pkg.all; entity top_xc3s500e_ex is generic ( TD : in time := 1 ns ; --! simulation time; DIV_SCL : in integer := 100 --! clock division for logic counters ); port( ---- SWITCHES ---- RESET : in std_logic; --! asycnchronous reset: SW(0) PWM : in std_logic; --! PWM Enable : SW(1) LCD : in std_logic; --! LCD/LED Switch : SW(2) START : in std_logic; --! LCD Controller Start : SW(3) RESTART : in std_logic; --! RESTART Timer DS1302 TEST_LCD : in std_logic; --! TEST LCD DISPLAY ---- PS/2 IO ---- PS2_CLK : in std_logic; --! PS/2 clk (keyboard) PS2_DATA : in std_logic; --! PS/2 data (keyboad) ---- CLOCK 50 MHz ---- CLK : in std_logic; --! main clock 50 MHz ---- VGA SYNC ---- VGA_HSYNC : out std_logic; --! horiztonal sync VGA_VSYNC : out std_logic; --! vertical sync VGA_R : out std_logic; --! VGA Red VGA_G : out std_logic; --! VGA Green VGA_B : out std_logic; --! VGA Blue ---- LED DISPLAY ---- LED_X : out std_logic_vector(7 downto 3); --! LEDs Y --LED_Y : out std_logic_vector(7 downto 0); --! LEDs X ---- BUTTONS ---- KB : in std_logic_vector(5 downto 1); --! Five Buttons ---- SERIAL TIMER ---- T_DT : inout std_logic; --! timer serial data T_CK : out std_logic; --! timer serial clock (~1 MHz) T_CE : out std_logic; --! timer serial enable -- LCD1602 INTERFACE LCD_DT : out std_logic_vector(7 downto 0); --! LCD Data LCD_EN : out std_logic; --! LCD Enable LCD_RW : out std_logic; --! LCD R/W (write - '0', read - '1') LCD_RS : out std_logic; --! LCD RS (command - '0', data - '1') -- TEST POINTS TST : out std_logic_vector(2 downto 0); --! Test points ---- DOORBELL ---- BELL : out std_logic --! BELL (tie to VCC) ); end top_xc3s500e_ex; architecture top_xc3s500e_ex of top_xc3s500e_ex is ---------------- SIGNALS DECLARATION ---------------- signal ps2_clock : std_logic; signal ps2_din : std_logic; signal sys_reset : std_logic; signal reset_v : std_logic_vector(6 downto 0); signal rst : std_logic; signal rstz : std_logic; signal RGB : std_logic_vector(2 downto 0); signal clk_fb : std_logic; signal clk0 : std_logic; signal clk_in : std_logic; signal locked : std_logic; signal clk_dv : std_logic; signal rst_dcm : std_logic; signal v, h : std_logic; --signal leds : std_logic_vector(8 downto 1); signal led_hearty : std_logic_vector(7 downto 0); signal led_heartx : std_logic_vector(7 downto 0); signal pwm_ena : std_logic; signal button : std_logic_vector(5 downto 1); signal switch_lcd : std_logic; signal time_addr : std_logic_vector(7 downto 0); signal time_data_i : std_logic_vector(7 downto 0); signal time_data_o : std_logic_vector(7 downto 0); signal time_data_v : std_logic; signal time_rdy : std_logic; signal time_enable : std_logic; signal disp_dt : std_logic_vector(7 downto 0); signal disp_en : std_logic; signal disp_rw : std_logic; signal disp_rs : std_logic; signal disp_start : std_logic; signal disp_rdy : std_logic; signal disp_init : std_logic; signal disp_data : std_logic_vector(7 downto 0); signal disp_com : std_logic:='0'; signal disp_ena : std_logic; signal buff_dt : std_logic_vector(7 downto 0); signal buff_en : std_logic; signal buff_rw : std_logic; signal buff_rs : std_logic; signal buff_xx : std_logic_vector(7 downto 3); --signal cnt : std_logic_vector(5 downto 0):="000000"; signal rstart : std_logic; signal disp_rdyz : std_logic; signal disp_rdyt : std_logic; signal ds_data_i : std_logic; signal ds_data_o : std_logic; signal ds_data_t : std_logic; signal ds_data_tn : std_logic; signal load_ena : std_logic; signal load_dat : std_logic_vector(7 downto 0); signal load_addr : std_logic_vector(4 downto 0); signal test_mode : std_logic; begin disp_rdyz <= not disp_rdy after td when rising_edge(clk_in); disp_rdyt <= disp_rdyz and disp_rdy after td when rising_edge(clk_in); ---------------- TIMER TRANSFER ---------------- x_SET_TIME: cl_timer_data generic map ( TIME_SECS => 47, -- seconds TIME_MINS => 59, -- minutes TIME_HRS => 13, -- hours TIME_DTS => 19, -- dates TIME_MTHS => 09, -- months TIME_DAYS => 06, -- days TIME_YRS => 15, -- years TD => TD -- simulation time; ) port map( ---- Global signals ---- reset => reset_v(0), -- asycnchronous reset clk => clk_in, -- clock 50 MHz restart => rstart, -- restart timer ---- DS1302 signals ---- addr => time_addr, -- address for timer data_o => time_data_i, -- input data (to timer) data_i => time_data_o, -- output data (from timer) data_v => time_data_v, -- valid data (from timer) ready => time_rdy, -- timer is ready for data enable => time_enable, -- timer enable ---- LCD1602 signals ---- load_ena => load_ena, -- enable writing to LCD RAM load_dat => load_dat, -- data to LCD RAM load_addr => load_addr -- address to LCD RAM ); ---------------- LCD1602 TRANSFER ---------------- x_LCD_TST: cl_lcd_data generic map ( TD => TD -- simulation time; ) port map( reset => reset_v(1), -- system frequency (50 MHz) clk => clk_in, -- '0' - negative reset test_mode => test_mode, -- select mode: test message or timer load_ena => load_ena, -- load new data load_dat => load_dat, -- new data; load_addr => load_addr, -- new address; disp_data => disp_data, -- data to display disp_ena => disp_ena, -- enable for data disp_init => disp_init, -- ready for data disp_rdyt => disp_rdyt -- valid pulse for data ); ---------------- LCD1602 CONTROLLER ---------------- x_LCD1602: rtl_lcd1602 generic map ( TD => TD, -- simulation time; DIV_SCL => 5000 -- clock division for SCL: clk50m/DIV_SCL ) port map( -- global ports clk50m => clk_in, -- system frequency (50 MHz) rstn => reset_v(2), -- '0' - negative reset -- main interface start => disp_start, -- start data_ena => disp_ena, -- data enable (S) data_int => disp_data, -- data Tx data_sel => disp_com, -- select: '0' - data, '1' - command data_rw => '0', -- WRITE ONLY; lcd_ready => disp_rdy, -- ready for data lcd_init => disp_init, -- lcd initialization complete -- lcd1602 interface lcd_dt => disp_dt, -- lcd data lcd_en => disp_en, -- lcd clock enable lcd_rw => disp_rw, -- lcd r/w: write - '0', read - '1' lcd_rs => disp_rs -- lcd set: command - '0', data - '1' ); ---------------- DS1302 CONTROLLER ---------------- x_DS1302: rtl_ds1302 generic map ( TD => TD, -- simulation time; DIV_SCL => DIV_SCL -- clock division for SCL: clk50m/DIV_SCL ) port map( -- global ports clk50m => clk_in, -- system frequency (50 MHz) rstn => reset_v(3), -- '0' - negative reset -- main interface enable => time_enable, -- i2c start (S) addr_i => time_addr, -- address Tx: 7 bit - always '1', 0 bit - R/W ('0' - write, '1' - read) data_i => time_data_i, -- data Tx data_o => time_data_o, -- data Rx data_v => time_data_v, -- valid Rx ready => time_rdy, -- ready -- serial interface --ds_data => T_DT,--ds_data, -- serial data ds_data_i => ds_data_i, -- serial data input ds_data_o => ds_data_o, -- serial data output ds_data_t => ds_data_t, -- serial data enable ds_clk => T_CK, -- serial clock ds_ena => T_CE -- clock enable for i2c ); ---------------- MINESWEEPER GAME ---------------- x_MAIN_BLOCK : rtl_game_int port map( clk => clk_dv, -- 25 MHz freq; reset => reset_v(4), -- GLOBAL RESET ps2_clk => ps2_clock, -- PS/2 CLOCK ps2_data => ps2_din, -- PS/2 SERIAL DATA h_vga => H, -- HORIZONTAL v_vga => V, -- VERTICAL rgb => RGB -- (R-G-B) --leds => LEDS -- LEDs ); ---------------- HEART XY 8X8 ---------------- pr_lcd_sw: process(clk_in, reset_v(5)) is begin if (reset_v(5) = '0') then buff_dt <= x"00"; buff_en <= '0'; buff_rw <= '0'; buff_rs <= '0'; elsif rising_edge(clk_in) then if switch_lcd = '1' then buff_dt <= disp_dt; buff_en <= disp_en; buff_rw <= disp_rw; buff_rs <= disp_rs; else x_rev: for ii in 0 to 7 loop buff_dt(ii) <= led_hearty(7-ii); end loop; buff_rs <= led_heartx(0); buff_rw <= led_heartx(1); buff_en <= led_heartx(2); buff_xx <= led_heartx(7 downto 3); end if; end if; end process; ds_data_tn <= ds_data_t; ---------------- I/O BUFFERS ---------------- TST(0) <= ds_data_o; TST(1) <= ds_data_tn; TST(2) <= ds_data_i; xDSIO: iobuf port map(i => ds_data_o, o => ds_data_i, io => T_DT, t => ds_data_tn); xPS2C: ibuf port map(i => ps2_clk, o => ps2_clock); xPS2D: ibuf port map(i => ps2_data, o => ps2_din); xRESET: ibuf port map(i => RESET, o => rst); xPWM: ibuf port map(i => PWM, o => pwm_ena); xSTART: ibuf port map(i => START, o => disp_start); xRESTART: ibuf port map(i => RESTART, o => rstart); xBELL: obuf port map(i => '1', o => BELL); xVGA_v: obuf port map(i => v, o => VGA_VSYNC); xVGA_h: obuf port map(i => h, o => VGA_HSYNC); xVGA_R: obuf port map(i => RGB(2), o => VGA_R); xVGA_G: obuf port map(i => RGB(1), o => VGA_G); xVGA_B: obuf port map(i => RGB(0), o => VGA_B); xLCD_EN: obuf port map(i => buff_en, o => LCD_EN); xLCD_RW: obuf port map(i => buff_rw, o => LCD_RW); xLCD_RS: obuf port map(i => buff_rs, o => LCD_RS); xLCD_DT: for ii in 0 to 7 generate xLCD_DATA: obuf port map(i => buff_dt(ii), o => LCD_DT(ii)); end generate; xLCD_SW: ibuf port map(i => LCD, o => switch_lcd); xLCD_TST: ibuf port map(i => TEST_LCD, o => test_mode); xBUTS: for ii in 1 to 5 generate xswitch: ibuf port map(i => KB(ii), o => button(ii)); end generate; -- LEDS: xLED_XY: for ii in 3 to 7 generate ledx: obuf port map(i => buff_xx(ii), o => LED_X(ii)); -- ledy: obuf port map(i => led_hearty(ii), o => LED_Y(ii)); end generate; ---------------- DEBOUNCE ---------------- xCTRL_8x8 : ctrl_leds port map ( -- System signals: clk => clk0, clk_dv => clk_dv, reset => reset_v(6), pwm_ena => pwm_ena, -- Buttons: cbut => button, -- Leds vectors: led_x => led_heartx, led_y => led_hearty ); ---------------- DCM CLOCK ---------------- xCLKFB: bufg port map(i => clk0, o => clk_fb); xCLKIN: ibufg port map(i => clk,o => clk_in); sys_reset <= (rstz and locked) after td when rising_edge(clk_in); xFD_RST: ctrl_fanout generic map( FD_WIDTH => 7) port map( clk => clk_in, data_in => sys_reset, data_out => reset_v ); --xgen_rst: for ii in 0 to 7 generate --reset_v(ii) <= sys_reset after td when rising_edge(clk_in); --end generate; xSRL_RESET: srlc16 generic map ( init => x"0000" ) port map( Q15 => rstz, A0 => '1', A1 => '1', A2 => '1', A3 => '1', CLK => clk_in, D => rst -- '1', ); rst_dcm <= not rst; ---------------- CLOCK GENERATOR - DCM ---------------- xDCM_CLK_VGA : dcm generic map( --DCM_AUTOCALIBRATION => FALSE, -- DCM ADV CLKDV_DIVIDE => 2.0, -- clk divide for CLKIN: Fdv = Fclkin / CLK_DIV CLKFX_DIVIDE => 2, -- clk divide for CLKFX and CLKFX180 : Ffx = (Fclkin * MULTIPLY) / CLKFX_DIV CLKFX_MULTIPLY => 2, -- clk multiply for CLKFX and CLKFX180 : Ffx = (Fclkin * MULTIPLY) / CLKFX_DIV CLKIN_DIVIDE_BY_2 => FALSE, -- divide clk / 2 before DCM block CLKIN_PERIOD => 20.0, -- clk period in ns (for DRC) CLKOUT_PHASE_SHIFT => "NONE", -- phase shift mode: NONE, FIXED, VARIABLE CLK_FEEDBACK => "1X", -- freq on the feedback clock: 1x, 2x, None DESKEW_ADJUST => "SYSTEM_SYNCHRONOUS", -- clk delay alignment DFS_FREQUENCY_MODE => "LOW", -- freq mode CLKFX and CLKFX180: LOW, HIGH DLL_FREQUENCY_MODE => "LOW", -- freq mode CLKIN: LOW, HIGH DUTY_CYCLE_CORRECTION => TRUE, -- 50% duty-cycle correction for the CLK0, CLK90, CLK180 and CLK270: TRUE, FALSE PHASE_SHIFT => 0 -- phase shift (with CLKOUT_PHASE_SHIFT): -255 to 255 ) port map( clk0 => clk0, -- clk180 => clk180, -- clk270 => clk270, -- clk2x => clk2x, -- clk2x180 => clk2x180, -- clk90 => clk90, clkdv => clk_dv, -- clkfx => clkfx, -- clkfx180 => clkfx180, locked => locked, -- status => status, -- psdone => psdone, clkfb => clk_fb, clkin => clk_in, -- dssen => dssen, -- psclk => psclk, psen => '0', psincdec => '0', rst => rst_dcm ); end top_xc3s500e_ex;	mit	b99a5ab849e596536e7280c5a4b1aef8	0.538346	2.693505	false	false	false	false
IamVNIE/Hardware-Security	RC5 CryptoCore/Rc5 Codes/RC5encryptAllSteps.vhd	2	6,997	Library IEEE; Use IEEE.std_logic_1164.all; Use IEEE.std_logic_unsigned.all; Use Work.RC5_Pkg.all; Entity rc5_enc Is Port ( clr : in std_logic; clk : in std_logic; din : in std_logic_vector(63 downto 0); di_vld : in std_logic; key_rdy : in std_logic; skey : in rom; dout : out std_logic_vector(63 downto 0); do_rdy : out std_logic ); End rc5_enc; Architecture rtl of rc5_enc is signal i_cnt : Std_logic_vector(3 downto 0); --Signals signal ab_xor : Std_logic_vector(31 downto 0); signal a_rot : Std_logic_vector(31 downto 0); signal a : Std_logic_vector(31 downto 0); signal a_pre : Std_logic_vector(31 downto 0); signal a_reg : Std_logic_vector(31 downto 0); signal ba_xor : Std_logic_vector(31 downto 0); signal b_rot : Std_logic_vector(31 downto 0); signal b : Std_logic_vector(31 downto 0); signal b_pre : Std_logic_vector(31 downto 0); signal b_reg : Std_logic_vector(31 downto 0); --RC5 State Machine Type StateType is --Type for state machine ( ST_idle, ST_pre_round, ST_round_op, ST_ready ); Signal state_en : StateType; --Signal type of state machine Begin ab_xor <= a_reg XOR b_reg; --A_reg _reg XOR With b_reg(4 downto 0) Select --Rotate left XOR result a_rot <= ab_xor(30 downto 0) & ab_xor(31) when "00001", ab_xor(29 downto 0) & ab_xor(31 downto 30) when "00010", ab_xor(28 downto 0) & ab_xor(31 downto 29) when "00011", ab_xor(27 downto 0) & ab_xor(31 downto 28) when "00100", ab_xor(26 downto 0) & ab_xor(31 downto 27) when "00101", ab_xor(25 downto 0) & ab_xor(31 downto 26) when "00110", ab_xor(24 downto 0) & ab_xor(31 downto 25) when "00111", ab_xor(23 downto 0) & ab_xor(31 downto 24) when "01000", ab_xor(22 downto 0) & ab_xor(31 downto 23) when "01001", ab_xor(21 downto 0) & ab_xor(31 downto 22) when "01010", ab_xor(20 downto 0) & ab_xor(31 downto 21) when "01011", ab_xor(19 downto 0) & ab_xor(31 downto 20) when "01100", ab_xor(18 downto 0) & ab_xor(31 downto 19) when "01101", ab_xor(17 downto 0) & ab_xor(31 downto 18) when "01110", ab_xor(16 downto 0) & ab_xor(31 downto 17) when "01111", ab_xor(15 downto 0) & ab_xor(31 downto 16) when "10000", ab_xor(14 downto 0) & ab_xor(31 downto 15) when "10001", ab_xor(13 downto 0) & ab_xor(31 downto 14) when "10010", ab_xor(12 downto 0) & ab_xor(31 downto 13) when "10011", ab_xor(11 downto 0) & ab_xor(31 downto 12) when "10100", ab_xor(10 downto 0) & ab_xor(31 downto 11) when "10101", ab_xor(9 downto 0) & ab_xor(31 downto 10) when "10110", ab_xor(8 downto 0) & ab_xor(31 downto 9) when "10111", ab_xor(7 downto 0) & ab_xor(31 downto 8) when "11000", ab_xor(6 downto 0) & ab_xor(31 downto 7) when "11001", ab_xor(5 downto 0) & ab_xor(31 downto 6) when "11010", ab_xor(4 downto 0) & ab_xor(31 downto 5) when "11011", ab_xor(3 downto 0) & ab_xor(31 downto 4) when "11100", ab_xor(2 downto 0) & ab_xor(31 downto 3) when "11101", ab_xor(1 downto 0) & ab_xor(31 downto 2) when "11110", ab_xor(0) & ab_xor(31 downto 1) when "11111", ab_xor when others; a_pre <= din(63 downto 32) + skey(0); --A_pre output after add din and skey a <= a_rot + skey(CONV_INTEGER(i_cnt & '0')); --A output after add left rotate and skey ba_xor <= b_reg XOR a; --B_reg XOR with A with a(4 downto 0) Select --Rotate left result of XOR b_rot <= ba_xor(30 downto 0) & ba_xor(31) when "00001", ba_xor(29 downto 0) & ba_xor(31 downto 30) when "00010", ba_xor(28 downto 0) & ba_xor(31 downto 29) when "00011", ba_xor(27 downto 0) & ba_xor(31 downto 28) when "00100", ba_xor(26 downto 0) & ba_xor(31 downto 27) when "00101", ba_xor(25 downto 0) & ba_xor(31 downto 26) when "00110", ba_xor(24 downto 0) & ba_xor(31 downto 25) when "00111", ba_xor(23 downto 0) & ba_xor(31 downto 24) when "01000", ba_xor(22 downto 0) & ba_xor(31 downto 23) when "01001", ba_xor(21 downto 0) & ba_xor(31 downto 22) when "01010", ba_xor(20 downto 0) & ba_xor(31 downto 21) when "01011", ba_xor(19 downto 0) & ba_xor(31 downto 20) when "01100", ba_xor(18 downto 0) & ba_xor(31 downto 19) when "01101", ba_xor(17 downto 0) & ba_xor(31 downto 18) when "01110", ba_xor(16 downto 0) & ba_xor(31 downto 17) when "01111", ba_xor(15 downto 0) & ba_xor(31 downto 16) when "10000", ba_xor(14 downto 0) & ba_xor(31 downto 15) when "10001", ba_xor(13 downto 0) & ba_xor(31 downto 14) when "10010", ba_xor(12 downto 0) & ba_xor(31 downto 13) when "10011", ba_xor(11 downto 0) & ba_xor(31 downto 12) when "10100", ba_xor(10 downto 0) & ba_xor(31 downto 11) when "10101", ba_xor(9 downto 0) & ba_xor(31 downto 10) when "10110", ba_xor(8 downto 0) & ba_xor(31 downto 9) when "10111", ba_xor(7 downto 0) & ba_xor(31 downto 8) when "11000", ba_xor(6 downto 0) & ba_xor(31 downto 7) when "11001", ba_xor(5 downto 0) & ba_xor(31 downto 6) when "11010", ba_xor(4 downto 0) & ba_xor(31 downto 5) when "11011", ba_xor(3 downto 0) & ba_xor(31 downto 4) when "11100", ba_xor(2 downto 0) & ba_xor(31 downto 3) when "11101", ba_xor(1 downto 0) & ba_xor(31 downto 2) when "11110", ba_xor(0) & ba_xor(31 downto 1) when "11111", ba_xor when others; b_pre <= din(31 downto 0) + skey(1); --B output when add din and skey 1 b <= b_rot + skey(CONV_INTEGER(i_cnt & '1')); --B output when add left rotate and skey --Register A --Register A Process(clr, clk) Begin If(clr='0') Then a_reg <= (Others => '0'); elsif(clk'Event and clk='1') Then If (state_en=ST_pre_round) Then a_reg <= a_pre; Elsif (state_en=ST_round_op) Then a_reg <= a; End if; End If; End Process; --Register B --Register B Process(clr, clk) Begin If(clr='0') Then b_reg <= (Others => '0'); Elsif(clk'Event and clk='1') Then If (state_en=ST_pre_round) Then b_reg <= b_pre; Elsif (state_en=ST_round_op) Then b_reg <= b; End if; End If; End Process; Process (clr, clk) --State Machine Begin If (clr='0') Then state_en <= ST_idle; Elsif (clk'Event And clk = '1') Then Case state_en is When ST_idle => If (di_vld='1' and key_rdy='1') Then state_en <= ST_pre_round; End If; When ST_pre_round => state_en <= ST_round_op; When ST_round_op => If (i_cnt="1100") Then state_en <= ST_ready; End If; When ST_ready => state_en <= ST_idle; End Case; End If; End Process; Process(clr, clk) Begin --Round Counter If(clr='0') Then i_cnt <= "0001"; Elsif(clk'Event And clk='1') Then If (state_en = ST_round_op) Then If(i_cnt="1100") Then i_cnt <= "0001"; Else i_cnt <= i_cnt + '1'; End If; End If; End If; End Process; dout <= a_reg & b_reg; With state_en Select do_rdy <= '1' When ST_ready, '0' When Others; End rtl;	mit	cfba38df647b19f195c6d5db4b11a2ce	0.605688	2.629463	false	false	false	false
Luisda199824/ProcesadorMonociclo	TB_DataMemory.vhd	1	1,459	library IEEE; use IEEE.STD_LOGIC_1164.ALL; use IEEE.STD_LOGIC_ARITH.ALL; use IEEE.STD_LOGIC_UNSIGNED.ALL; ENTITY TB_DataMemory IS END TB_DataMemory; ARCHITECTURE behavior OF TB_DataMemory IS COMPONENT DataMemory PORT( Rst : IN std_logic; cRD : IN std_logic_vector(31 downto 0); AluResult : IN std_logic_vector(31 downto 0); WrENMem : IN std_logic; RdENMem : IN std_logic; Data : OUT std_logic_vector(31 downto 0) ); END COMPONENT; --Inputs signal Rst : std_logic := '0'; signal cRD : std_logic_vector(31 downto 0) := (others => '0'); signal AluResult : std_logic_vector(31 downto 0) := (others => '0'); signal WrENMem : std_logic := '0'; signal RdENMem : std_logic := '0'; --Outputs signal Data : std_logic_vector(31 downto 0); BEGIN -- Instantiate the Unit Under Test (UUT) uut: DataMemory PORT MAP ( Rst => Rst, cRD => cRD, AluResult => AluResult, WrENMem => WrENMem, RdENMem => RdENMem, Data => Data ); -- Stimulus process stim_proc: process begin Rst <= '1'; cRD <= x"00000001"; AluResult <= x"00000001"; WrENMem <= '0'; RdENMem <= '0'; wait for 10 ns; Rst <= '0'; WrENMem <= '1'; RdENMem <= '1'; wait for 10 ns; WrENMem <= '0'; RdENMem <= '1'; wait for 10 ns; WrENMem <= '0'; RdENMem <= '0'; wait; end process; END;	mit	3c61aa91b42709073a05b2b8e3429871	0.566827	3.199561	false	false	false	false
marco-c/leon-nexys2	grlib-gpl-1.3.4-b4140/designs/leon3-asic/leon3mp.vhd	1	18,140	----------------------------------------------------------------------------- -- LEON3 Demonstration design -- Copyright (C) 2013 Aeroflex Gaisler AB ------------------------------------------------------------------------------ -- This file is a part of the GRLIB VHDL IP LIBRARY -- Copyright (C) 2003 - 2008, Gaisler Research -- Copyright (C) 2008 - 2013, Aeroflex Gaisler -- -- This program is free software; you can redistribute it and/or modify -- it under the terms of the GNU General Public License as published by -- the Free Software Foundation; either version 2 of the License, or -- (at your option) any later version. -- -- This program is distributed in the hope that it will be useful, -- but WITHOUT ANY WARRANTY; without even the implied warranty of -- MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the -- GNU General Public License for more details. -- -- You should have received a copy of the GNU General Public License -- along with this program; if not, write to the Free Software -- Foundation, Inc., 59 Temple Place, Suite 330, Boston, MA 02111-1307 USA ------------------------------------------------------------------------------ library ieee; use ieee.std_logic_1164.all; use work.config.all; library techmap; use techmap.gencomp.all; entity leon3mp is generic ( fabtech : integer := CFG_FABTECH; memtech : integer := CFG_MEMTECH; padtech : integer := CFG_PADTECH; clktech : integer := CFG_CLKTECH; disas : integer := CFG_DISAS; -- Enable disassembly to console dbguart : integer := CFG_DUART; -- Print UART on console pclow : integer := CFG_PCLOW; scantest : integer := CFG_SCAN ); port ( resetn : in std_ulogic; clksel : in std_logic_vector(1 downto 0); clk : in std_ulogic; lock : out std_ulogic; errorn : inout std_ulogic; wdogn : inout std_ulogic; address : out std_logic_vector(27 downto 0); data : inout std_logic_vector(31 downto 0); cb : inout std_logic_vector(7 downto 0); sdclk : out std_ulogic; sdcsn : out std_logic_vector (1 downto 0); -- sdram chip select sdwen : out std_ulogic; -- sdram write enable sdrasn : out std_ulogic; -- sdram ras sdcasn : out std_ulogic; -- sdram cas sddqm : out std_logic_vector (3 downto 0); -- sdram dqm dsutx : out std_ulogic; -- DSU tx data / scanout dsurx : in std_ulogic; -- DSU rx data / scanin dsuen : in std_ulogic; dsubre : in std_ulogic; -- DSU break / scanen dsuact : out std_ulogic; -- DSU active / NT txd1 : out std_ulogic; -- UART1 tx data rxd1 : in std_ulogic; -- UART1 rx data txd2 : out std_ulogic; -- UART2 tx data rxd2 : in std_ulogic; -- UART2 rx data ramsn : out std_logic_vector (4 downto 0); ramoen : out std_logic_vector (4 downto 0); rwen : out std_logic_vector (3 downto 0); oen : out std_ulogic; writen : out std_ulogic; read : out std_ulogic; iosn : out std_ulogic; romsn : out std_logic_vector (1 downto 0); brdyn : in std_ulogic; bexcn : in std_ulogic; gpio : inout std_logic_vector(CFG_GRGPIO_WIDTH-1 downto 0); -- I/O port i2c_scl : inout std_ulogic; i2c_sda : inout std_ulogic; spi_miso : in std_ulogic; spi_mosi : out std_ulogic; spi_sck : out std_ulogic; spi_slvsel : out std_logic_vector(CFG_SPICTRL_SLVS-1 downto 0); prom32 : in std_ulogic; spw_clksel : in std_logic_vector(1 downto 0); spw_clk : in std_ulogic; spw_rxd : in std_logic_vector(0 to CFG_SPW_NUM-1); spw_rxs : in std_logic_vector(0 to CFG_SPW_NUM-1); spw_txd : out std_logic_vector(0 to CFG_SPW_NUM-1); spw_txs : out std_logic_vector(0 to CFG_SPW_NUM-1); gtx_clk : in std_ulogic; erx_clk : in std_ulogic; erxd : in std_logic_vector(7 downto 0); erx_dv : in std_ulogic; etx_clk : in std_ulogic; etxd : out std_logic_vector(7 downto 0); etx_en : out std_ulogic; etx_er : out std_ulogic; erx_er : in std_ulogic; erx_col : in std_ulogic; erx_crs : in std_ulogic; emdint : in std_ulogic; emdio : inout std_logic; emdc : out std_ulogic; testen : in std_ulogic; trst : in std_ulogic; tck : in std_ulogic; tms : in std_ulogic; tdi : in std_ulogic; tdo : out std_ulogic ); end; architecture rtl of leon3mp is signal lresetn : std_ulogic; signal lclksel : std_logic_vector (1 downto 0); signal lclk : std_ulogic; signal llock : std_ulogic; signal lerrorn : std_ulogic; signal laddress : std_logic_vector(27 downto 0); signal ldatain : std_logic_vector(31 downto 0); signal ldataout : std_logic_vector(31 downto 0); signal ldataen : std_logic_vector(31 downto 0); signal lcbin : std_logic_vector(7 downto 0); signal lcbout : std_logic_vector(7 downto 0); signal lcben : std_logic_vector(7 downto 0); signal lsdclk : std_ulogic; signal lsdcsn : std_logic_vector (1 downto 0); signal lsdwen : std_ulogic; signal lsdrasn : std_ulogic; signal lsdcasn : std_ulogic; signal lsddqm : std_logic_vector (3 downto 0); signal ldsutx : std_ulogic; signal ldsurx : std_ulogic; signal ldsuen : std_ulogic; signal ldsubre : std_ulogic; signal ldsuact : std_ulogic; signal ltxd1 : std_ulogic; signal lrxd1 : std_ulogic; signal ltxd2 : std_ulogic; signal lrxd2 : std_ulogic; signal lramsn : std_logic_vector (4 downto 0); signal lramoen : std_logic_vector (4 downto 0); signal lrwen : std_logic_vector (3 downto 0); signal loen : std_ulogic; signal lwriten : std_ulogic; signal lread : std_ulogic; signal liosn : std_ulogic; signal lromsn : std_logic_vector (1 downto 0); signal lbrdyn : std_ulogic; signal lbexcn : std_ulogic; signal lwdogn : std_ulogic; signal lgpioin : std_logic_vector(CFG_GRGPIO_WIDTH-1 downto 0); signal lgpioout : std_logic_vector(CFG_GRGPIO_WIDTH-1 downto 0); signal lgpioen : std_logic_vector(CFG_GRGPIO_WIDTH-1 downto 0); signal li2c_sclout : std_ulogic; signal li2c_sclen : std_ulogic; signal li2c_sclin : std_ulogic; signal li2c_sdaout : std_ulogic; signal li2c_sdaen : std_ulogic; signal li2c_sdain : std_ulogic; signal lspi_miso : std_ulogic; signal lspi_mosi : std_ulogic; signal lspi_sck : std_ulogic; signal lspi_slvsel : std_logic_vector(CFG_SPICTRL_SLVS-1 downto 0); signal lprom32 : std_ulogic; signal lspw_clksel : std_logic_vector (1 downto 0); signal lspw_clk : std_ulogic; signal lspw_rxd : std_logic_vector(0 to CFG_SPW_NUM-1); signal lspw_rxs : std_logic_vector(0 to CFG_SPW_NUM-1); signal lspw_txd : std_logic_vector(0 to CFG_SPW_NUM-1); signal lspw_txs : std_logic_vector(0 to CFG_SPW_NUM-1); signal lgtx_clk : std_ulogic; signal lerx_clk : std_ulogic; signal lerxd : std_logic_vector(7 downto 0); signal lerx_dv : std_ulogic; signal letx_clk : std_ulogic; signal letxd : std_logic_vector(7 downto 0); signal letx_en : std_ulogic; signal letx_er : std_ulogic; signal lerx_er : std_ulogic; signal lerx_col : std_ulogic; signal lerx_crs : std_ulogic; signal lemdint : std_ulogic; signal lemdioin : std_logic; signal lemdioout : std_logic; signal lemdioen : std_logic; signal lemdc : std_ulogic; signal ltesten : std_ulogic; signal ltrst : std_ulogic; signal ltck : std_ulogic; signal ltms : std_ulogic; signal ltdi : std_ulogic; signal ltdo : std_ulogic; signal ltdoen : std_ulogic; -- Use for ASIC --constant padvoltage : integer := x33v; --constant padlevel : integer := ttl; -- Use for FPGA constant padvoltage : integer := x18v; constant padlevel : integer := cmos; begin -- TODO: Move PAD options to 'xconfig' pads0 : entity work.pads generic map ( padtech => CFG_PADTECH, padlevel => padlevel, padstrength => 4, jtag_padfilter => pullup, testen_padfilter => pulldown, resetn_padfilter => schmitt, clk_padfilter => 0, spw_padstrength => 12, jtag_padstrength => 4, uart_padstrength => 4, dsu_padstrength => 4, padvoltage => padvoltage, spw_input_type => CFG_SPW_INPUT, oepol => padoen_polarity(CFG_PADTECH) ) port map ( --------------------------- --to chip boundary --------------------------- resetn => resetn , clksel => clksel , clk => clk , lock => lock , errorn => errorn , address => address , data => data , cb => cb , sdclk => sdclk , sdcsn => sdcsn , sdwen => sdwen , sdrasn => sdrasn , sdcasn => sdcasn , sddqm => sddqm , dsutx => dsutx , dsurx => dsurx , dsuen => dsuen , dsubre => dsubre , dsuact => dsuact , txd1 => txd1 , rxd1 => rxd1 , txd2 => txd2 , rxd2 => rxd2 , ramsn => ramsn , ramoen => ramoen , rwen => rwen , oen => oen , writen => writen , read => read , iosn => iosn , romsn => romsn , brdyn => brdyn , bexcn => bexcn , wdogn => wdogn , gpio => gpio , i2c_scl => i2c_scl , i2c_sda => i2c_sda , spi_miso => spi_miso , spi_mosi => spi_mosi , spi_sck => spi_sck , spi_slvsel => spi_slvsel, prom32 => prom32 , spw_clksel => spw_clksel, spw_clk => spw_clk , spw_rxd => spw_rxd , spw_rxs => spw_rxs , spw_txd => spw_txd , spw_txs => spw_txs , gtx_clk => gtx_clk , erx_clk => erx_clk , erxd => erxd , erx_dv => erx_dv , etx_clk => etx_clk , etxd => etxd , etx_en => etx_en , etx_er => etx_er , erx_er => erx_er , erx_col => erx_col , erx_crs => erx_crs , emdint => emdint , emdio => emdio , emdc => emdc , testen => testen , trst => trst , tck => tck , tms => tms , tdi => tdi , tdo => tdo , ------------------------- --- --to core ---------------------------- lresetn => lresetn , lclksel => lclksel , lclk => lclk , llock => llock , lerrorn => lerrorn , laddress => laddress , ldatain => ldatain , ldataout => ldataout , ldataen => ldataen , lcbin => lcbin , lcbout => lcbout , lcben => lcben , lsdclk => lsdclk , lsdcsn => lsdcsn , lsdwen => lsdwen , lsdrasn => lsdrasn , lsdcasn => lsdcasn , lsddqm => lsddqm , ldsutx => ldsutx , ldsurx => ldsurx , ldsuen => ldsuen , ldsubre => ldsubre , ldsuact => ldsuact , ltxd1 => ltxd1 , lrxd1 => lrxd1 , ltxd2 => ltxd2 , lrxd2 => lrxd2 , lramsn => lramsn , lramoen => lramoen , lrwen => lrwen , loen => loen , lwriten => lwriten , lread => lread , liosn => liosn , lromsn => lromsn , lbrdyn => lbrdyn , lbexcn => lbexcn , lwdogn => lwdogn , lgpioin => lgpioin , lgpioout => lgpioout , lgpioen => lgpioen , li2c_sclout => li2c_sclout, li2c_sclen => li2c_sclen , li2c_sclin => li2c_sclin , li2c_sdaout => li2c_sdaout, li2c_sdaen => li2c_sdaen , li2c_sdain => li2c_sdain , lspi_miso => lspi_miso , lspi_mosi => lspi_mosi , lspi_sck => lspi_sck , lspi_slvsel => lspi_slvsel, lprom32 => lprom32 , lspw_clksel => lspw_clksel, lspw_clk => lspw_clk , lspw_rxd => lspw_rxd , lspw_rxs => lspw_rxs , lspw_txd => lspw_txd , lspw_txs => lspw_txs , lgtx_clk => lgtx_clk , lerx_clk => lerx_clk , lerxd => lerxd , lerx_dv => lerx_dv , letx_clk => letx_clk , letxd => letxd , letx_en => letx_en , letx_er => letx_er , lerx_er => lerx_er , lerx_col => lerx_col , lerx_crs => lerx_crs , lemdint => lemdint , lemdioin => lemdioin , lemdioout => lemdioout , lemdioen => lemdioen , lemdc => lemdc , ltesten => ltesten , ltrst => ltrst , ltck => ltck , ltms => ltms , ltdi => ltdi , ltdo => ltdo , ltdoen => ltdoen ); -- ASIC Core core0 : entity work.core generic map ( fabtech => CFG_FABTECH, memtech => CFG_MEMTECH, padtech => CFG_PADTECH, clktech => CFG_CLKTECH, disas => CFG_DISAS, dbguart => CFG_DUART, pclow => CFG_PCLOW, scantest => CFG_SCAN, bscanen => CFG_BOUNDSCAN_EN, oepol => padoen_polarity(CFG_PADTECH) ) port map ( ---------------------------- -- ASIC Ports/Pads ---------------------------- resetn => lresetn , clksel => lclksel , clk => lclk , lock => llock , errorn => lerrorn , address => laddress , datain => ldatain , dataout => ldataout , dataen => ldataen , cbin => lcbin , cbout => lcbout , cben => lcben , sdclk => lsdclk , sdcsn => lsdcsn , sdwen => lsdwen , sdrasn => lsdrasn , sdcasn => lsdcasn , sddqm => lsddqm , dsutx => ldsutx , dsurx => ldsurx , dsuen => ldsuen , dsubre => ldsubre , dsuact => ldsuact , txd1 => ltxd1 , rxd1 => lrxd1 , txd2 => ltxd2 , rxd2 => lrxd2 , ramsn => lramsn , ramoen => lramoen , rwen => lrwen , oen => loen , writen => lwriten , read => lread , iosn => liosn , romsn => lromsn , brdyn => lbrdyn , bexcn => lbexcn , wdogn => lwdogn , gpioin => lgpioin , gpioout => lgpioout , gpioen => lgpioen , i2c_sclout => li2c_sclout, i2c_sclen => li2c_sclen , i2c_sclin => li2c_sclin , i2c_sdaout => li2c_sdaout, i2c_sdaen => li2c_sdaen , i2c_sdain => li2c_sdain , spi_miso => lspi_miso , spi_mosi => lspi_mosi , spi_sck => lspi_sck , spi_slvsel => lspi_slvsel, prom32 => lprom32 , spw_clksel => lspw_clksel, spw_clk => lspw_clk , spw_rxd => lspw_rxd , spw_rxs => lspw_rxs , spw_txd => lspw_txd , spw_txs => lspw_txs , gtx_clk => lgtx_clk , erx_clk => lerx_clk , erxd => lerxd , erx_dv => lerx_dv , etx_clk => letx_clk , etxd => letxd , etx_en => letx_en , etx_er => letx_er , erx_er => lerx_er , erx_col => lerx_col , erx_crs => lerx_crs , emdint => lemdint , emdioin => lemdioin , emdioout => lemdioout , emdioen => lemdioen , emdc => lemdc , testen => ltesten , trst => ltrst , tck => ltck , tms => ltms , tdi => ltdi , tdo => ltdo , tdoen => ltdoen , ---------------------------- -- BSCAN ---------------------------- chain_tck => OPEN , chain_tckn => OPEN , chain_tdi => OPEN , chain_tdo => '0', bsshft => OPEN , bscapt => OPEN , bsupdi => OPEN , bsupdo => OPEN , bsdrive => OPEN , bshighz => OPEN ); -- BSCAN -- TODO: ADD BSCAN end;	gpl-2.0	be52bbfa08be7ddf5a9b876e0ae35b59	0.463286	3.690743	false	false	false	false
Luisda199824/ProcesadorMonociclo	unionModulos.vhd	1	9,234	library IEEE; use IEEE.STD_LOGIC_1164.ALL; entity unionModulos is Port ( clk : in STD_LOGIC; rst : in STD_LOGIC; salida : out STD_LOGIC_VECTOR (31 downto 0)); end unionModulos; architecture Behavioral of unionModulos is signal SumDisp22, SumDisp30, aux1, PcCounterPlus, PC, aux2, address, instruction, Crs1, Crs2, cRD, aux7, AluResult, aux10, DataToMem, DataToReg, SEU_Disp30_Out, SEU_Disp22_Out, nPC_Source: std_logic_vector(31 downto 0) := (others => '0'); signal AluOp, Op3, NRs1, NRs2, NRd, Mux_NRd: std_logic_vector(5 downto 0) := (others => '0'); signal rs1, rs2, rd : std_logic_vector(4 downto 0) := (others => '0'); signal Op, PcSource, RfSource: std_logic_vector(1 downto 0) := (others => '0'); signal ncwp, cwp, Carry, weRF, RFDest, ReENMemory, WrENMemory: std_logic := '0'; signal imm13: std_logic_vector(12 downto 0) := (others => '0'); signal NZVC, cond, icc: std_logic_vector(3 downto 0) := (others => '0'); signal disp30 : std_logic_vector(29 downto 0) := (others => '0'); signal disp22 : std_logic_vector(21 downto 0) := (others => '0'); component ProgrammingCounter port ( clk : in STD_LOGIC; rst : in STD_LOGIC; dato : in STD_LOGIC_VECTOR (31 downto 0); -- addres PCOut : out STD_LOGIC_VECTOR (31 downto 0) -- sig ); end component; component RD_Mux Port ( RfDest : in STD_LOGIC; RD : in STD_LOGIC_VECTOR (5 downto 0); nRD : out STD_LOGIC_VECTOR (5 downto 0)); end component; component DataMemory Port ( Rst : in STD_LOGIC; cRD : in STD_LOGIC_VECTOR (31 downto 0); AluResult : in STD_LOGIC_VECTOR (31 downto 0); WrENMem : in STD_LOGIC; RdENMem : in STD_LOGIC; Data : out STD_LOGIC_VECTOR (31 downto 0)); end component; component Sumador32B port ( A : in STD_LOGIC_VECTOR (31 downto 0); B : in STD_LOGIC_VECTOR (31 downto 0); SumOut : out STD_LOGIC_VECTOR (31 downto 0) ); end component; component instructionMemory port ( address : in STD_LOGIC_VECTOR (31 downto 0); rst : in STD_LOGIC; outInstruction : out STD_LOGIC_VECTOR (31 downto 0) ); end component; component registerFile Port ( we : in STD_LOGIC; rs1 : in STD_LOGIC_VECTOR (5 downto 0); rs2 : in STD_LOGIC_VECTOR (5 downto 0); rd : in STD_LOGIC_VECTOR (5 downto 0); rst : in STD_LOGIC; dataToWrite : in STD_LOGIC_VECTOR (31 downto 0); CRs1 : out STD_LOGIC_VECTOR (31 downto 0); CRs2 : out STD_LOGIC_VECTOR (31 downto 0); CRd : out STD_LOGIC_VECTOR (31 downto 0)); end component; component UnityControl Port ( Op : in STD_LOGIC_VECTOR (1 downto 0); Op3 : in STD_LOGIC_VECTOR (5 downto 0); cond : in STD_LOGIC_VECTOR (3 downto 0); icc : in STD_LOGIC_VECTOR (3 downto 0); we : out STD_LOGIC; RFDest : out STD_LOGIC; WrENMemory : out STD_LOGIC; ReENMemory : out STD_LOGIC; RfSource : out STD_LOGIC_VECTOR(1 downto 0); PcSource : out STD_LOGIC_VECTOR(1 downto 0); AluOp : out STD_LOGIC_VECTOR (5 downto 0) ); end component; component Alu Port ( AluOp : in STD_LOGIC_VECTOR (5 downto 0); rs1 : in STD_LOGIC_VECTOR (31 downto 0); rs2 : in STD_LOGIC_VECTOR (31 downto 0); c : in STD_LOGIC; AluResult : out STD_LOGIC_VECTOR (31 downto 0) ); end component; component WindowsManager Port ( rs1 : in STD_LOGIC_VECTOR (4 downto 0); rs2 : in STD_LOGIC_VECTOR (4 downto 0); rd : in STD_LOGIC_VECTOR (4 downto 0); cwp : in STD_LOGIC; op3 : in STD_LOGIC_VECTOR (5 downto 0); op : in STD_LOGIC_VECTOR (1 downto 0); nrs1 : out STD_LOGIC_VECTOR (5 downto 0); nrs2 : out STD_LOGIC_VECTOR (5 downto 0); ncwp : out STD_LOGIC; nrd : out STD_LOGIC_VECTOR (5 downto 0)); end component; component PSR_Modifier Port ( AluOp : in STD_LOGIC_VECTOR (5 downto 0); Crs1 : in STD_LOGIC_VECTOR (31 downto 0); Crs2 : in STD_LOGIC_VECTOR (31 downto 0); ALU_Result : in STD_LOGIC_VECTOR (31 downto 0); nzvc : out STD_LOGIC_VECTOR (3 downto 0); rst: in STD_LOGIC); end component; component PSR Port ( nzvc : in STD_LOGIC_VECTOR (3 downto 0); rst : in STD_LOGIC; clk : in STD_LOGIC; ncwp: in STD_LOGIC; cond : in STD_LOGIC_VECTOR (3 downto 0); carry : out STD_LOGIC; cwp : out STD_LOGIC; icc : out STD_LOGIC_VECTOR (3 downto 0)); end component; component Mux32B Port ( A : in STD_LOGIC_VECTOR (31 downto 0); B : in STD_LOGIC_VECTOR (31 downto 0); Sc : in STD_LOGIC; MuxOut : out STD_LOGIC_VECTOR (31 downto 0) ); end component; component SignExtender Port ( A : in STD_LOGIC_VECTOR (12 downto 0); SEOut : out STD_LOGIC_VECTOR (31 downto 0)); end component; component SEU_Disp30 Port ( Disp30 : in STD_LOGIC_VECTOR (29 downto 0); SEU_Disp30_Out : out STD_LOGIC_VECTOR (31 downto 0)); end component; component SEU_Disp22 Port ( Disp22 : in STD_LOGIC_VECTOR (21 downto 0); Seu_Disp22_Out : out STD_LOGIC_VECTOR (31 downto 0)); end component; component PC_Mux Port ( clk : in STD_LOGIC; PcSource : in STD_LOGIC_VECTOR (1 downto 0); AluResult : in STD_LOGIC_VECTOR (31 downto 0); Pc : in STD_LOGIC_VECTOR (31 downto 0); Pc_Disp22 : in STD_LOGIC_VECTOR (31 downto 0); Pc_Disp30 : in STD_LOGIC_VECTOR (31 downto 0); nPC_Source : out STD_LOGIC_VECTOR (31 downto 0)); end component; component DataRF_Mux Port ( clk : in STD_LOGIC; RfSource : in STD_LOGIC_VECTOR (1 downto 0); DataToMem : in STD_LOGIC_VECTOR (31 downto 0); AluResult : in STD_LOGIC_VECTOR (31 downto 0); PC : in STD_LOGIC_VECTOR (31 downto 0); DataToReg : out STD_LOGIC_VECTOR (31 downto 0)); end component; begin Inst_pc_next: ProgrammingCounter port map ( clk => clk, rst => rst, dato => nPC_Source, PCOut => aux1 ); Inst_pc: ProgrammingCounter port map ( clk => clk, rst => rst, dato => aux1, PCOut => address ); Inst_sumPC: Sumador32B port map ( A => aux1, B => x"00000001", SumOut => PcCounterPlus ); Inst_instructionMemory: instructionMemory port map ( address => address, rst => rst, outInstruction => instruction ); rs1 <= instruction(18 downto 14); rs2 <= instruction(4 downto 0); rd <= instruction(29 downto 25); Op <= instruction(31 downto 30); Op3 <= instruction(24 downto 19); imm13 <= instruction(12 downto 0); cond <= instruction(28 downto 25); disp30 <= instruction(29 downto 0); disp22 <= instruction(21 downto 0); Inst_WindowsManager: WindowsManager Port Map ( rs1 => rs1, rs2 => rs2, rd => rd, cwp => cwp, op3 => Op3, op => Op, nrs1 => NRs1, nrs2 => NRs2, ncwp => ncwp, nrd => NRd ); Inst_RD_Mux: RD_Mux Port Map ( RfDest => RfDest, RD => NRd, nRD => Mux_NRd ); Inst_PSR: PSR Port Map ( nzvc => NZVC, rst => rst, clk => clk, ncwp => ncwp, cond => cond, carry => Carry, cwp => cwp, icc => icc ); Inst_register_file: registerFile port map( we => weRF, rs1 => NRs1, rs2 => NRs2, rd => Mux_NRd, rst => rst, dataToWrite => DataToReg, CRs1 => Crs1, CRs2 => aux7, CRd => cRD ); Inst_UC: UnityControl Port Map( Op => Op, Op3=> Op3, AluOp => AluOp, cond => cond, icc => icc, we => weRF, RFDest => RFDest, WrENMemory => WrENMemory, ReENMemory => ReENMemory, RfSource => RfSource, PcSource => PcSource ); Inst_Sign_ext_unit: SignExtender port map ( A => imm13, SEOut => aux10 ); Inst_PSR_Modifier: PSR_Modifier Port Map ( AluOp => AluOp, Crs1 => Crs1, Crs2 => Crs2, ALU_Result => AluResult, nzvc => NZVC, rst => rst ); Inst_mux32b: Mux32B port map ( A => aux7, B => aux10, Sc => instruction(13), MuxOut => Crs2 ); Inst_ALU: Alu port map ( AluOp => AluOp, rs1 => Crs1, rs2 => Crs2, c => Carry, AluResult => AluResult ); Inst_DataMemory: DataMemory port map ( Rst => Rst, cRD => cRD, AluResult => AluResult, WrENMem => WrENMemory, RdENMem => ReENMemory, Data => DataToMem ); Inst_DataRf_Mux: DataRF_Mux port map ( clk => clk, RfSource => RfSource, DataToMem => DataToMem, AluResult => AluResult, PC => address, DataToReg => DataToReg ); Inst_SeuDisp30: SEU_Disp30 port map ( Disp30 => disp30, SEU_Disp30_Out => SEU_Disp30_Out ); Inst_Disp30_Sumador : Sumador32B port map( A => SEU_Disp30_Out, B => PcCounterPlus, SumOut => SumDisp30 ); Inst_SeuDisp22: SEU_Disp22 port map ( Disp22 => disp22, Seu_Disp22_Out => Seu_Disp22_Out ); Inst_Disp22_Sumador : Sumador32B port map( A => SEU_Disp22_Out, B => PcCounterPlus, SumOut => SumDisp22 ); Inst_PcMux: PC_Mux port map ( clk => clk, PcSource => PcSource, AluResult => AluResult, Pc => PcCounterPlus, Pc_Disp22 => SumDisp22, Pc_Disp30 => SumDisp30, nPC_Source => nPC_Source ); salida <= AluResult; end Behavioral;	mit	e150619ca85e6eb989d174d75c236aaf	0.603964	2.987383	false	false	false	false
marco-c/leon-nexys2	grlib-gpl-1.3.4-b4140/designs/leon3-xilinx-ml510/leon3mp.vhd	1	51,575	----------------------------------------------------------------------------- -- LEON3 Demonstration design -- Copyright (C) 2008 Jiri Gaisler, Jan Andersson, Aeroflex Gaisler ------------------------------------------------------------------------------ -- This file is a part of the GRLIB VHDL IP LIBRARY -- Copyright (C) 2003 - 2008, Gaisler Research -- Copyright (C) 2008 - 2013, Aeroflex Gaisler -- -- This program is free software; you can redistribute it and/or modify -- it under the terms of the GNU General Public License as published by -- the Free Software Foundation; either version 2 of the License, or -- (at your option) any later version. -- -- This program is distributed in the hope that it will be useful, -- but WITHOUT ANY WARRANTY; without even the implied warranty of -- MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the -- GNU General Public License for more details. -- -- You should have received a copy of the GNU General Public License -- along with this program; if not, write to the Free Software -- Foundation, Inc., 59 Temple Place, Suite 330, Boston, MA 02111-1307 USA ------------------------------------------------------------------------------ library ieee; use ieee.std_logic_1164.all; library grlib, techmap; use grlib.amba.all; use grlib.stdlib.all; use grlib.devices.all; use techmap.gencomp.all; use techmap.allclkgen.all; library gaisler; use gaisler.memctrl.all; use gaisler.leon3.all; use gaisler.uart.all; use gaisler.misc.all; use gaisler.spi.all; use gaisler.i2c.all; use gaisler.net.all; use gaisler.jtag.all; use gaisler.pci.all; use gaisler.ddrpkg.all; library esa; use esa.memoryctrl.all; use esa.pcicomp.all; use work.config.all; -- pragma translate_off library unisim; use unisim.BUFG; -- pragma translate_on entity leon3mp is generic ( fabtech : integer := CFG_FABTECH; memtech : integer := CFG_MEMTECH; padtech : integer := CFG_PADTECH; ncpu : integer := CFG_NCPU; disas : integer := CFG_DISAS; -- Enable disassembly to console dbguart : integer := CFG_DUART; -- Print UART on console pclow : integer := CFG_PCLOW ); port ( fpga_cpu_reset_b : in std_ulogic; user_clksys : in std_ulogic; -- 100 MHz main clock sysace_fpga_clk : in std_ulogic; -- 33 MHz -- Flash flash_we_b : out std_ulogic; flash_wait : in std_ulogic; flash_reset_b : out std_ulogic; flash_oe_b : out std_ulogic; flash_d : inout std_logic_vector(15 downto 0); flash_clk : out std_ulogic; flash_ce_b : out std_ulogic; flash_adv_b : out std_logic; flash_a : out std_logic_vector(21 downto 0); --pragma translate_off -- For debug output module sram_bw : out std_ulogic; sim_d : inout std_logic_vector(31 downto 16); iosn : out std_ulogic; --pragma translate_on -- DDR2 slot 1 dimm1_ddr2_we_b : out std_ulogic; dimm1_ddr2_s_b : out std_logic_vector(1 downto 0); dimm1_ddr2_ras_b : out std_ulogic; dimm1_ddr2_pll_clkin_p : out std_ulogic; dimm1_ddr2_pll_clkin_n : out std_ulogic; dimm1_ddr2_odt : out std_logic_vector(1 downto 0); dimm1_ddr2_dqs_p : inout std_logic_vector(8 downto 0); dimm1_ddr2_dqs_n : inout std_logic_vector(8 downto 0); dimm1_ddr2_dqm : out std_logic_vector(8 downto 0); dimm1_ddr2_dq : inout std_logic_vector(71 downto 0); dimm1_ddr2_cke : out std_logic_vector(1 downto 0); -- dimm1_ddr2_cb : inout std_logic_vector(7 downto 0); dimm1_ddr2_cas_b : out std_ulogic; dimm1_ddr2_ba : out std_logic_vector(2 downto 0); dimm1_ddr2_a : out std_logic_vector(13 downto 0); -- DDR2 slot 0 dimm0_ddr2_we_b : out std_ulogic; dimm0_ddr2_s_b : out std_logic_vector(1 downto 0); dimm0_ddr2_ras_b : out std_ulogic; dimm0_ddr2_pll_clkin_p : out std_ulogic; dimm0_ddr2_pll_clkin_n : out std_ulogic; dimm0_ddr2_odt : out std_logic_vector(1 downto 0); dimm0_ddr2_dqs_p : inout std_logic_vector(8 downto 0); dimm0_ddr2_dqs_n : inout std_logic_vector(8 downto 0); dimm0_ddr2_dqm : out std_logic_vector(8 downto 0); dimm0_ddr2_dq : inout std_logic_vector(71 downto 0); dimm0_ddr2_cke : out std_logic_vector(1 downto 0); -- dimm0_ddr2_cb : inout std_logic_vector(7 downto 0); dimm0_ddr2_cas_b : out std_ulogic; dimm0_ddr2_ba : out std_logic_vector(2 downto 0); dimm0_ddr2_a : out std_logic_vector(13 downto 0); dimm0_ddr2_reset_n : out std_ulogic; -- Ethernet PHY phy0_txer : out std_ulogic; phy0_txd : out std_logic_vector(3 downto 0); phy0_txctl_txen : out std_ulogic; phy0_txclk : in std_ulogic; phy0_rxer : in std_ulogic; phy0_rxd : in std_logic_vector(3 downto 0); phy0_rxctl_rxdv : in std_ulogic; phy0_rxclk : in std_ulogic; phy0_reset : out std_ulogic; phy0_mdio : inout std_logic; phy0_mdc : out std_ulogic; -- phy0_int : in std_ulogic; -- System ACE MPU sysace_mpa : out std_logic_vector(6 downto 0); sysace_mpce : out std_ulogic; sysace_mpirq : in std_ulogic; sysace_mpoe : out std_ulogic; sysace_mpwe : out std_ulogic; sysace_mpd : inout std_logic_vector(15 downto 0); -- GPIO/Green LEDs dbg_led : inout std_logic_vector(3 downto 0); -- Red/Green LEDs opb_bus_error : out std_ulogic; plb_bus_error : out std_ulogic; -- LCD -- fpga_lcd_rw : out std_ulogic; -- fpga_lcd_rs : out std_ulogic; -- fpga_lcd_e : out std_ulogic; -- fpga_lcd_db : out std_logic_vector(7 downto 0); -- DVI dvi_xclk_p : out std_ulogic; dvi_xclk_n : out std_ulogic; dvi_v : out std_ulogic; dvi_reset_b : out std_ulogic; dvi_h : out std_ulogic; dvi_gpio1 : inout std_logic; dvi_de : out std_ulogic; dvi_d : out std_logic_vector(11 downto 0); -- PCI pci_p_trdy_b : inout std_logic; pci_p_stop_b : inout std_logic; pci_p_serr_b : inout std_logic; pci_p_rst_b : inout std_logic; pci_p_req_b : in std_logic_vector(0 to 4); pci_p_perr_b : inout std_logic; pci_p_par : inout std_logic; pci_p_lock_b : inout std_logic; pci_p_irdy_b : inout std_logic; pci_p_intd_b : in std_logic; pci_p_intc_b : in std_logic; pci_p_intb_b : in std_logic; pci_p_inta_b : in std_logic; pci_p_gnt_b : out std_logic_vector(0 to 4); pci_p_frame_b : inout std_logic; pci_p_devsel_b : inout std_logic; pci_p_clk5_r : out std_ulogic; pci_p_clk5 : in std_ulogic; pci_p_clk4_r : out std_ulogic; pci_p_clk3_r : out std_ulogic; pci_p_clk1_r : out std_ulogic; pci_p_clk0_r : out std_ulogic; pci_p_cbe_b : inout std_logic_vector(3 downto 0); pci_p_ad : inout std_logic_vector(31 downto 0); -- pci_fpga_idsel : in std_ulogic; sbr_pwg_rsm_rstj : inout std_logic; sbr_nmi_r : in std_ulogic; sbr_intr_r : in std_ulogic; sbr_ide_rst_b : inout std_logic; -- IIC/SMBus and sideband signals iic_sda_dvi : inout std_logic; iic_scl_dvi : inout std_logic; fpga_sda : inout std_logic; fpga_scl : inout std_logic; iic_therm_b : in std_ulogic; iic_reset_b : out std_ulogic; iic_irq_b : in std_ulogic; iic_alert_b : in std_ulogic; -- SPI spi_data_out : in std_logic; spi_data_in : out std_ulogic; spi_data_cs_b : out std_ulogic; spi_clk : out std_ulogic; -- UARTs uart1_txd : out std_ulogic; uart1_rxd : in std_ulogic; uart1_rts_b : out std_ulogic; uart1_cts_b : in std_ulogic; uart0_txd : out std_ulogic; uart0_rxd : in std_ulogic; uart0_rts_b : out std_ulogic -- uart0_cts_b : in std_ulogic -- System monitor -- test_mon_vrefp : in std_ulogic; -- test_mon_vp0_p : in std_ulogic; -- test_mon_vn0_n : in std_ulogic -- test_mon_avdd : in std_ulogic ); end; architecture rtl of leon3mp is component svga2ch7301c generic ( tech : integer := 0; idf : integer := 0; dynamic : integer := 0 ); port ( clk : in std_ulogic; rstn : in std_ulogic; clksel : in std_logic_vector(1 downto 0); vgao : in apbvga_out_type; vgaclk_fb : in std_ulogic; clk25_fb : in std_ulogic; clk40_fb : in std_ulogic; clk65_fb : in std_ulogic; vgaclk : out std_ulogic; clk25 : out std_ulogic; clk40 : out std_ulogic; clk65 : out std_ulogic; dclk_p : out std_ulogic; dclk_n : out std_ulogic; locked : out std_ulogic; data : out std_logic_vector(11 downto 0); hsync : out std_ulogic; vsync : out std_ulogic; de : out std_ulogic ); end component; component BUFG port (O : out std_logic; I : in std_logic); end component; constant blength : integer := 12; constant fifodepth : integer := 8; constant maxahbm : integer := NCPU+CFG_AHB_UART+CFG_AHB_JTAG+ CFG_SVGA_ENABLE+CFG_PCI; -- Set this constant to 1 to include an APB bridge with the Logan logic -- analyzer attached to the PCI signals constant CFG_LOGAN : integer := 0; signal ddr0_clk_fb, ddr1_clk_fb : std_logic; signal vcc, gnd : std_logic_vector(31 downto 0); signal memi : memory_in_type; signal memo : memory_out_type; signal wpo : wprot_out_type; signal apbi, apbi1 : apb_slv_in_type; signal apbo, apbo1 : apb_slv_out_vector := (others => apb_none); signal ahbsi : ahb_slv_in_type; signal ahbso : ahb_slv_out_vector := (others => ahbs_none); signal ahbmi : ahb_mst_in_type; signal ahbmo : ahb_mst_out_vector := (others => ahbm_none); signal clkm, clkm2x, rstn, rstraw, flashclkl : std_ulogic; signal clkddr, clk_200 : std_ulogic; signal clk25, clk40, clk65 : std_ulogic; signal cgi, cgi2, cgi3 : clkgen_in_type; signal cgo, cgo2, cgo3 : clkgen_out_type; signal u1i, dui : uart_in_type; signal u1o, duo : uart_out_type; signal irqi : irq_in_vector(0 to NCPU-1); signal irqo : irq_out_vector(0 to NCPU-1); signal dbgi : l3_debug_in_vector(0 to NCPU-1); signal dbgo : l3_debug_out_vector(0 to NCPU-1); signal dsui : dsu_in_type; signal dsuo : dsu_out_type; signal opb_bus_errorl, plb_bus_errorl : std_ulogic; signal ethi, ethi1, ethi2 : eth_in_type; signal etho, etho1, etho2 : eth_out_type; signal gpti : gptimer_in_type; signal gpioi : gpio_in_type; signal gpioo : gpio_out_type; signal clklock, lock0, lock1, lclk, clkml0, clkml1 : std_ulogic; signal tck, tckn, tms, tdi, tdo : std_ulogic; signal rst : std_ulogic; signal egtx_clk_fb : std_ulogic; signal egtx_clk, legtx_clk, l2egtx_clk : std_ulogic; signal vgao : apbvga_out_type; signal lcd_datal : std_logic_vector(11 downto 0); signal lcd_hsyncl, lcd_vsyncl, lcd_del, lcd_reset_bl : std_ulogic; signal clk_sel : std_logic_vector(1 downto 0); signal vgalock : std_ulogic; signal clkvga, clkvga_p, clkvga_n : std_ulogic; signal i2ci, dvi_i2ci : i2c_in_type; signal i2co, dvi_i2co : i2c_out_type; signal spii : spi_in_type; signal spio : spi_out_type; signal slvsel : std_logic_vector(CFG_SPICTRL_SLVS-1 downto 0); constant BOARD_FREQ_200 : integer := 200000; -- input frequency in KHz constant BOARD_FREQ : integer := 100000; -- input frequency in KHz constant CPU_FREQ : integer := BOARD_FREQ * CFG_CLKMUL / CFG_CLKDIV; -- cpu frequency in KHz constant I2C_FILTER : integer := (CPU_FREQ5+50000)/100000+1; -- DDR clock is 200 MHz clock unless CFG_DDR2SP_NOSYNC is set. If that config -- option is set the DDR clock is 2x CPU clock. constant DDR_FREQ : integer := BOARD_FREQ_200 - (BOARD_FREQ_200 - 2CPU_FREQ)CFG_DDR2SP_NOSYNC; constant IOAEN : integer := CFG_DDR2SP; signal stati : ahbstat_in_type; signal ddr0_clkv : std_logic_vector(2 downto 0); signal ddr0_clkbv : std_logic_vector(2 downto 0); signal ddr1_clkv : std_logic_vector(2 downto 0); signal ddr1_clkbv : std_logic_vector(2 downto 0); signal clkace : std_ulogic; signal acei : gracectrl_in_type; signal aceo : gracectrl_out_type; signal sysmoni : grsysmon_in_type; signal sysmono : grsysmon_out_type; signal pciclk, pci_clk, pci_clk_fb : std_ulogic; signal pci_arb_gnt : std_logic_vector(0 to 7); signal pci_arb_req : std_logic_vector(0 to 7); signal pci_arb_reql : std_logic_vector(0 to 4); signal pci_reql : std_ulogic; signal pci_host, pci_66 : std_ulogic; signal pci_intv : std_logic_vector(3 downto 0); signal pcii : pci_in_type; signal pcio : pci_out_type; signal clkma, clkmb, clkmc : std_ulogic; signal clk0_tb, rst0_tb, rst0_tbn : std_ulogic; signal phy_init_done : std_ulogic; -- Logan signals signal signals : std_logic_vector(63CFG_LOGAN downto 0); attribute syn_keep : boolean; attribute syn_preserve : boolean; attribute syn_keep of clkml0 : signal is true; attribute syn_preserve of clkml0 : signal is true; attribute syn_keep of clkml1 : signal is true; attribute syn_preserve of clkml1 : signal is true; attribute syn_keep of clkm : signal is true; attribute syn_preserve of clkm : signal is true; attribute syn_keep of egtx_clk : signal is true; attribute syn_preserve of egtx_clk : signal is true; attribute syn_keep of clkvga : signal is true; attribute syn_preserve of clkvga : signal is true; attribute syn_keep of clk25 : signal is true; attribute syn_preserve of clk25 : signal is true; attribute syn_keep of clk40 : signal is true; attribute syn_preserve of clk40 : signal is true; attribute syn_keep of clk65 : signal is true; attribute syn_preserve of clk65 : signal is true; attribute syn_keep of phy_init_done : signal is true; attribute syn_preserve of phy_init_done : signal is true; attribute keep : boolean; attribute keep of lock0 : signal is true; attribute keep of lock1 : signal is true; attribute keep of clkml0 : signal is true; attribute keep of clkml1 : signal is true; attribute keep of clkm : signal is true; attribute keep of egtx_clk : signal is true; attribute keep of clkvga : signal is true; attribute keep of clk25 : signal is true; attribute keep of clk40 : signal is true; attribute keep of clk65 : signal is true; attribute syn_noprune : boolean; attribute syn_noprune of sysace_fpga_clk_pad : label is true; begin vcc <= (others => '1'); gnd <= (others => '0'); rst0_tbn <= not rst0_tb; ---------------------------------------------------------------------- --- Reset and Clock generation ------------------------------------- ---------------------------------------------------------------------- flashclk_pad : outpad generic map (tech => padtech, slew => 1, strength => 24) port map (flash_clk, flashclkl); sysace_fpga_clk_pad : clkpad generic map (tech => padtech, level => cmos, voltage => x25v) port map (sysace_fpga_clk, clkace); pci_p_clk5_pad : clkpad generic map (tech => padtech, level => cmos, voltage => x25v) port map (pci_p_clk5, pci_clk_fb); pci_p_clk5_r_pad : outpad generic map (tech => padtech, level => pci33) port map (pci_p_clk5_r, pci_clk); pci_p_clk4_r_pad : outpad generic map (tech => padtech, level => pci33) port map (pci_p_clk4_r, pci_clk); pci_p_clk3_r_pad : outpad generic map (tech => padtech, level => pci33) port map (pci_p_clk3_r, pci_clk); pci_p_clk1_r_pad : outpad generic map (tech => padtech, level => pci33) port map (pci_p_clk1_r, pci_clk); pci_p_clk0_r_pad : outpad generic map (tech => padtech, level => pci33) port map (pci_p_clk0_r, pci_clk); clkgen0 : clkgen -- system clock generator generic map (CFG_FABTECH, CFG_CLKMUL, CFG_CLKDIV, 1, 1, 1, CFG_PCIDLL, CFG_PCISYSCLK, BOARD_FREQ, 1) port map (lclk, pci_clk_fb, clkmc, open, clkm2x, flashclkl, pciclk, cgi, cgo, open, open, clk_200); cgi.pllctrl <= "00"; cgi.pllrst <= rstraw; cgi.pllref <= '0'; -- clkgen1 : clkgen -- Ethernet 1G PHY clock generator -- generic map (CFG_FABTECH, 5, 4, 0, 0, 0, 0, 0, BOARD_FREQ, 0) -- port map (lclk, gnd(0), egtx_clk, open, open, open, open, cgi2, cgo2); -- cgi2.pllctrl <= "00"; cgi2.pllrst <= rstraw; --cgi2.pllref <= egtx_clk_fb; -- egtx_clk_pad : outpad generic map (tech => padtech) -- port map (phy_gtx_clk, egtx_clk); clkgen2 : clkgen -- PCI clock generator generic map (CFG_FABTECH, 2, 6, 0, 0, 0, 0, 0, BOARD_FREQ, 0) port map (lclk, gnd(0), pci_clk, open, open, open, open, cgi3, cgo3); cgi3.pllctrl <= "00"; cgi3.pllrst <= rstraw; cgi3.pllref <= '0'; iic_reset_b_pad : outpad generic map (tech => padtech) port map (iic_reset_b, rstn); resetn_pad : inpad generic map (tech => padtech, level => cmos, voltage => x25v) port map (fpga_cpu_reset_b, rst); rst0 : rstgen -- reset generator port map (rst, clkm, clklock, rstn, rstraw); clklock <= lock0 and lock1 and cgo.clklock and cgo3.clklock; clk_pad : clkpad generic map (tech => padtech, arch => 2, level => cmos, voltage => x25v) port map (user_clksys, lclk); ---------------------------------------------------------------------- --- AHB CONTROLLER -------------------------------------------------- ---------------------------------------------------------------------- ahb0 : ahbctrl -- AHB arbiter/multiplexer generic map (defmast => CFG_DEFMST, split => CFG_SPLIT, rrobin => CFG_RROBIN, ioaddr => CFG_AHBIO, devid => XILINX_ML510, ioen => IOAEN, nahbm => maxahbm, nahbs => 11 + CFG_LOGAN) port map (rstn, clkm, ahbmi, ahbmo, ahbsi, ahbso); ---------------------------------------------------------------------- --- LEON3 processor and DSU ----------------------------------------- ---------------------------------------------------------------------- l3 : if CFG_LEON3 = 1 generate cpu : for i in 0 to NCPU-1 generate u0 : leon3s -- LEON3 processor generic map (i, fabtech, memtech, CFG_NWIN, CFG_DSU, CFG_FPU, CFG_V8, 0, CFG_MAC, pclow, CFG_NOTAG, CFG_NWP, CFG_ICEN, CFG_IREPL, CFG_ISETS, CFG_ILINE, CFG_ISETSZ, CFG_ILOCK, CFG_DCEN, CFG_DREPL, CFG_DSETS, CFG_DLINE, CFG_DSETSZ, CFG_DLOCK, CFG_DSNOOP, CFG_ILRAMEN, CFG_ILRAMSZ, CFG_ILRAMADDR, CFG_DLRAMEN, CFG_DLRAMSZ, CFG_DLRAMADDR, CFG_MMUEN, CFG_ITLBNUM, CFG_DTLBNUM, CFG_TLB_TYPE, CFG_TLB_REP, CFG_LDDEL, disas, CFG_ITBSZ, CFG_PWD, CFG_SVT, CFG_RSTADDR, NCPU-1, CFG_DFIXED, CFG_SCAN, CFG_MMU_PAGE, CFG_BP) port map (clkm, rstn, ahbmi, ahbmo(i), ahbsi, ahbso, irqi(i), irqo(i), dbgi(i), dbgo(i)); end generate; opb_bus_errorl <= not dbgo(0).error; dsugen : if CFG_DSU = 1 generate dsu0 : dsu3 -- LEON3 Debug Support Unit generic map (hindex => 2, haddr => 16#D00#, hmask => 16#F00#, ncpu => NCPU, tbits => 30, tech => memtech, irq => 0, kbytes => CFG_ATBSZ) port map (rstn, clkm, ahbmi, ahbsi, ahbso(2), dbgo, dbgi, dsui, dsuo); dsui.enable <= '1'; dsui.break <= not gpioo.val(0); -- Position on on GPIO DIP switch plb_bus_errorl <= dsuo.active; end generate; end generate; nodsu : if CFG_DSU = 0 generate dsuo.tstop <= '0'; dsuo.active <= '0'; plb_bus_errorl <= '0'; end generate; opb_bus_error_pad : outpad generic map (tech => padtech) port map (opb_bus_error, opb_bus_errorl); plb_bus_error_pad : outpad generic map (tech => padtech) port map (plb_bus_error, plb_bus_errorl); dcomgen : if CFG_AHB_UART = 1 generate dcom0: ahbuart -- Debug UART generic map (hindex => NCPU, pindex => 7, paddr => 7) port map (rstn, clkm, dui, duo, apbi, apbo(7), ahbmi, ahbmo(NCPU)); end generate; nodcom : if CFG_AHB_UART = 0 generate duo.txd <= '0'; duo.rtsn <= '1'; end generate; dsurx_pad : inpad generic map (tech => padtech, level => cmos, voltage => x33v) port map (uart0_rxd, dui.rxd); dsutx_pad : outpad generic map (tech => padtech, level => cmos, voltage => x33v) port map (uart0_txd, duo.txd); -- dsucts_pad : inpad generic map (tech => padtech, level => cmos, voltage => x33v) -- port map (uart0_cts_b, dui.ctsn); dsurts_pad : outpad generic map (tech => padtech, level => cmos, voltage => x33v) port map (uart0_rts_b, duo.rtsn); ahbjtaggen0 :if CFG_AHB_JTAG = 1 generate ahbjtag0 : ahbjtag generic map(tech => fabtech, hindex => NCPU+CFG_AHB_UART) port map(rstn, clkm, tck, tms, tdi, tdo, ahbmi, ahbmo(NCPU+CFG_AHB_UART), open, open, open, open, open, open, open, gnd(0)); end generate; ---------------------------------------------------------------------- --- Memory controllers ---------------------------------------------- ---------------------------------------------------------------------- memi.writen <= '1'; memi.wrn <= "1111"; memi.bwidth <= "01"; memi.brdyn <= '1'; memi.bexcn <= '1'; mctrl0 : if CFG_MCTRL_LEON2 = 1 generate mctrl0 : mctrl generic map (hindex => 3, pindex => 0, ramaddr => 0, rammask => 0, paddr => 0, srbanks => 0, ram8 => CFG_MCTRL_RAM8BIT, ram16 => CFG_MCTRL_RAM16BIT, sden => CFG_MCTRL_SDEN, invclk => CFG_MCTRL_INVCLK, sepbus => CFG_MCTRL_SEPBUS) port map (rstn, clkm, memi, memo, ahbsi, ahbso(3), apbi, apbo(0), wpo); end generate; nomctrl: if CFG_MCTRL_LEON2 = 0 generate memo.address <= (others => '0'); memo.romsn <= (others => '1'); memo.oen <= '1'; memo.wrn <= (others => '1'); memo.vbdrive <= (others => '1'); memo.writen <= '1'; end generate; flash_reset_b_pad : outpad generic map (tech => padtech) port map (flash_reset_b, rstn); -- flash_wait_pad : inpad generic map (tech => padtech) -- port map (flash_wait, ); flash_adv_b_pad : outpad generic map (tech => padtech) port map (flash_adv_b, gnd(0)); flash_a_pads : outpadv generic map (width => 22, tech => padtech) port map (flash_a, memo.address(22 downto 1)); flash_ce_b_pad : outpad generic map (tech => padtech) port map (flash_ce_b, memo.romsn(0)); flash_oe_b_pad : outpad generic map (tech => padtech) port map (flash_oe_b, memo.oen); --pragma translate_off rwen_pad : outpad generic map (tech => padtech) port map (sram_bw, memo.wrn(3)); sim_d_pads : iopadvv generic map (tech => padtech, width => 16) port map (sim_d, memo.data(15 downto 0), memo.vbdrive(15 downto 0), memi.data(15 downto 0)); iosn_pad : outpad generic map (tech => padtech) port map (iosn, memo.iosn); --pragma translate_on flash_we_b_pad : outpad generic map (tech => padtech) port map (flash_we_b, memo.writen); flash_d_pads : iopadvv generic map (tech => padtech, width => 16) port map (flash_d, memo.data(31 downto 16), memo.vbdrive(31 downto 16), memi.data(31 downto 16)); dbg_led0_pad : outpad generic map (tech => padtech, level => cmos, voltage => x33v) port map (dbg_led(3), phy_init_done); clkm <= clkma; clkma <= clkmb; clkmb <= clkmc; ddrsp0 : if (CFG_DDR2SP /= 0) generate phy_init_done <= '1'; -- DDR clock selection -- If the synchronization registers are removed in the DDR controller, we -- assume that the user wants to run at 2x the system clock. Otherwise the -- DDR clock is generated from the 200 MHz clock. ddrclkselarb: if CFG_DDR2SP_NOSYNC = 0 generate BUFGDDR : BUFG port map (I => clk_200, O => clkddr); end generate; ddrclksel2x: if CFG_DDR2SP_NOSYNC /= 0 generate clkddr <= clkm2x; end generate; dimm0_ddr2_reset_n_pad : outpad generic map (tech => padtech, level => cmos, voltage => x33v) port map (dimm0_ddr2_reset_n, rst); -- Slot 0 ddrc0 : ddr2spa generic map ( fabtech => fabtech, memtech => memtech, hindex => 0, haddr => 16#400#, hmask => 16#e00#, ioaddr => 1, pwron => CFG_DDR2SP_INIT, MHz => DDR_FREQ/1000, TRFC => CFG_DDR2SP_TRFC, clkmul => CFG_DDR2SP_FREQ/10 - (CFG_DDR2SP_FREQ/10-1)CFG_DDR2SP_NOSYNC, clkdiv => 20 - (19)CFG_DDR2SP_NOSYNC, ahbfreq => CPU_FREQ/1000, col => CFG_DDR2SP_COL, Mbyte => CFG_DDR2SP_SIZE, ddrbits => CFG_DDR2SP_DATAWIDTH, ddelayb0 => CFG_DDR2SP_DELAY0, ddelayb1 => CFG_DDR2SP_DELAY1, ddelayb2 => CFG_DDR2SP_DELAY2, ddelayb3 => CFG_DDR2SP_DELAY3, ddelayb4 => CFG_DDR2SP_DELAY4, ddelayb5 => CFG_DDR2SP_DELAY5, ddelayb6 => CFG_DDR2SP_DELAY6, ddelayb7 => CFG_DDR2SP_DELAY7, readdly => 1, rskew => 0, oepol => 0, dqsgating => 0, rstdel => 200, eightbanks => 1, numidelctrl => 2 + CFG_DDR2SP_DATAWIDTH/64, norefclk => 0, odten => 3, nosync => CFG_DDR2SP_NOSYNC) port map (rst, rstn, clkddr, clkm, clk_200, lock0, clkml0, clkml0, ahbsi, ahbso(0), ddr0_clkv, ddr0_clkbv, ddr0_clk_fb, ddr0_clk_fb, dimm0_ddr2_cke, dimm0_ddr2_s_b, dimm0_ddr2_we_b, dimm0_ddr2_ras_b, dimm0_ddr2_cas_b, dimm0_ddr2_dqm(7 downto 4(32/CFG_DDR2SP_DATAWIDTH)), dimm0_ddr2_dqs_p(7 downto 4(32/CFG_DDR2SP_DATAWIDTH)), dimm0_ddr2_dqs_n(7 downto 4(32/CFG_DDR2SP_DATAWIDTH)), dimm0_ddr2_a, dimm0_ddr2_ba(2 downto 0), dimm0_ddr2_dq(63 downto 32(32/CFG_DDR2SP_DATAWIDTH)), dimm0_ddr2_odt); dimm0_ddr2_pll_clkin_p <= ddr0_clkv(0); dimm0_ddr2_pll_clkin_n <= ddr0_clkbv(0); -- Ground unused bank address and memory mask -- dimm0_ddr2_ba_notused_pad : outpad generic map (tech => padtech, level => SSTL18_I) -- port map (dimm0_ddr2_ba(2), gnd(0)); dimm0_ddr2_dqm_notused8_pad : outpad generic map (tech => padtech, level => SSTL18_I) port map (dimm0_ddr2_dqm(8), gnd(0)); -- Tri-state unused data strobe dimm0_dqsp_notused8_pad : iopad generic map (tech => padtech, level => SSTL18_II) port map (dimm0_ddr2_dqs_p(8), gnd(0), vcc(0), open); dimm0_dqsn_notused8_pad : iopad generic map (tech => padtech, level => SSTL18_II) port map (dimm0_ddr2_dqs_n(8), gnd(0), vcc(0), open); -- Tristate unused check bits dimm0_cb_notused_pad : iopadv generic map (tech => padtech, width => 8, level => SSTL18_II) port map (dimm0_ddr2_dq(71 downto 64), gnd(7 downto 0), vcc(0), open); -- Handle signals not used with 32-bit interface ddr032bit: if CFG_DDR2SP_DATAWIDTH /= 64 generate dimm0_ddr2_dqm_notused30_pads : outpadv generic map (tech => padtech, width => 4, level => SSTL18_I) port map (dimm0_ddr2_dqm(3 downto 0), gnd(3 downto 0)); dimm0_dqsp_notused30_pads : iopadv generic map (tech => padtech, width => 4, level => SSTL18_II) port map (dimm0_ddr2_dqs_p(3 downto 0), gnd(3 downto 0), vcc(0), open); dimm0_dqsn_notused30_pads : iopadv generic map (tech => padtech, width => 4, level => SSTL18_II) port map (dimm0_ddr2_dqs_n(3 downto 0), gnd(3 downto 0), vcc(0), open); dimm0_dq_notused_pads : iopadv generic map (tech => padtech, width => 32, level => SSTL18_II) port map (dimm0_ddr2_dq(31 downto 0), gnd, vcc(0), open); end generate; -- Slot 1 ddrc1 : ddr2spa generic map ( fabtech => fabtech, memtech => memtech, hindex => 1, haddr => 16#600#, hmask => 16#E00#, ioaddr => 2, pwron => CFG_DDR2SP_INIT, MHz => DDR_FREQ/1000, TRFC => CFG_DDR2SP_TRFC, clkmul => CFG_DDR2SP_FREQ/10 - (CFG_DDR2SP_FREQ/10-1)CFG_DDR2SP_NOSYNC, clkdiv => 20 - (19)CFG_DDR2SP_NOSYNC, ahbfreq => CPU_FREQ/1000, col => CFG_DDR2SP_COL, Mbyte => CFG_DDR2SP_SIZE, ddrbits => CFG_DDR2SP_DATAWIDTH, ddelayb0 => CFG_DDR2SP_DELAY0, ddelayb1 => CFG_DDR2SP_DELAY1, ddelayb2 => CFG_DDR2SP_DELAY2, ddelayb3 => CFG_DDR2SP_DELAY3, ddelayb4 => CFG_DDR2SP_DELAY4, ddelayb5 => CFG_DDR2SP_DELAY5, ddelayb6 => CFG_DDR2SP_DELAY6, ddelayb7 => CFG_DDR2SP_DELAY7, readdly => 1, rskew => 0, oepol => 0, dqsgating => 0, rstdel => 200, eightbanks => 1, numidelctrl => 2 + CFG_DDR2SP_DATAWIDTH/64, norefclk => 0, odten => 3, nosync => CFG_DDR2SP_NOSYNC) port map (rst, rstn, clkddr, clkm, clk_200, lock1, clkml1, clkml1, ahbsi, ahbso(1), ddr1_clkv, ddr1_clkbv, ddr1_clk_fb, ddr1_clk_fb, dimm1_ddr2_cke, dimm1_ddr2_s_b, dimm1_ddr2_we_b, dimm1_ddr2_ras_b, dimm1_ddr2_cas_b, dimm1_ddr2_dqm(7 downto 4(32/CFG_DDR2SP_DATAWIDTH)), dimm1_ddr2_dqs_p(7 downto 4(32/CFG_DDR2SP_DATAWIDTH)), dimm1_ddr2_dqs_n(7 downto 4(32/CFG_DDR2SP_DATAWIDTH)), dimm1_ddr2_a, dimm1_ddr2_ba(2 downto 0), dimm1_ddr2_dq(63 downto 32(32/ CFG_DDR2SP_DATAWIDTH)), dimm1_ddr2_odt); dimm1_ddr2_pll_clkin_p <= ddr1_clkv(0); dimm1_ddr2_pll_clkin_n <= ddr1_clkbv(0); -- Ground unused bank address and memory mask -- dimm1_ddr2_ba_notused_pad : outpad generic map (tech => padtech, level => SSTL18_I) -- port map (dimm1_ddr2_ba(2), gnd(0)); dimm1_ddr2_dqm_notused8_pad : outpad generic map (tech => padtech, level => SSTL18_I) port map (dimm1_ddr2_dqm(8), gnd(0)); -- Tri-state unused data strobe dimm1_dqsp_notused8_pad : iopad generic map (tech => padtech, level => SSTL18_II) port map (dimm1_ddr2_dqs_p(8), gnd(0), vcc(0), open); dimm1_dqsn_notused8_pad : iopad generic map (tech => padtech, level => SSTL18_II) port map (dimm1_ddr2_dqs_n(8), gnd(0), vcc(0), open); -- Tristate unused check bits dimm1_cb_notused_pad : iopadv generic map (tech => padtech, width => 8, level => SSTL18_II) port map (dimm1_ddr2_dq(71 downto 64), gnd(7 downto 0), vcc(0), open); -- Handle signals not used with 32-bit interface ddr132bit: if CFG_DDR2SP_DATAWIDTH /= 64 generate dimm1_ddr2_dqm_notused30_pads : outpadv generic map (tech => padtech, width => 4, level => SSTL18_I) port map (dimm1_ddr2_dqm(3 downto 0), gnd(3 downto 0)); dimm1_dqsp_notused30_pads : iopadv generic map (tech => padtech, width => 4, level => SSTL18_II) port map (dimm1_ddr2_dqs_p(3 downto 0), gnd(3 downto 0), vcc(0), open); dimm1_dqsn_notused30_pads : iopadv generic map (tech => padtech, width => 4, level => SSTL18_II) port map (dimm1_ddr2_dqs_n(3 downto 0), gnd(3 downto 0), vcc(0), open); dimm1_dq_notused_pads : iopadv generic map (tech => padtech, width => 32, level => SSTL18_II) port map (dimm1_ddr2_dq(31 downto 0), gnd, vcc(0), open); end generate; end generate; -- noddr : if (CFG_DDR2SP = 0) generate lock0 <= '1'; lock1 <= '1'; end generate; ---------------------------------------------------------------------- --- System ACE I/F Controller --------------------------------------- ---------------------------------------------------------------------- grace: if CFG_GRACECTRL = 1 generate grace0 : gracectrl generic map (hindex => 5, hirq => 5, haddr => 16#000#, hmask => 16#fff#, split => CFG_SPLIT) port map (rstn, clkm, clkace, ahbsi, ahbso(5), acei, aceo); end generate; nograce: if CFG_GRACECTRL = 0 generate aceo <= gracectrl_none; end generate nograce; sysace_mpa_pads : outpadv generic map (width => 7, tech => padtech) port map (sysace_mpa, aceo.addr); sysace_mpce_pad : outpad generic map (tech => padtech) port map (sysace_mpce, aceo.cen); sysace_mpd_pads : iopadv generic map (tech => padtech, width => 16) port map (sysace_mpd, aceo.do, aceo.doen, acei.di); sysace_mpoe_pad : outpad generic map (tech => padtech) port map (sysace_mpoe, aceo.oen); sysace_mpwe_pad : outpad generic map (tech => padtech) port map (sysace_mpwe, aceo.wen); sysace_mpirq_pad : inpad generic map (tech => padtech) port map (sysace_mpirq, acei.irq); ---------------------------------------------------------------------- --- AHB ROM --------------------------------------------------------- ---------------------------------------------------------------------- bpromgen : if CFG_AHBROMEN /= 0 generate brom : entity work.ahbrom generic map (hindex => 10, haddr => CFG_AHBRODDR, pipe => CFG_AHBROPIP) port map (rstn, clkm, ahbsi, ahbso(10)); end generate; ---------------------------------------------------------------------- --- APB Bridge and various periherals ------------------------------- ---------------------------------------------------------------------- apb0 : apbctrl -- AHB/APB bridge generic map (hindex => 4, haddr => CFG_APBADDR, nslaves => 16) port map (rstn, clkm, ahbsi, ahbso(4), apbi, apbo); ua1 : if CFG_UART1_ENABLE /= 0 generate uart1 : apbuart -- UART 1 generic map (pindex => 1, paddr => 1, pirq => 2, console => dbguart, fifosize => CFG_UART1_FIFO) port map (rstn, clkm, apbi, apbo(1), u1i, u1o); u1i.extclk <= '0'; end generate; noua1: if CFG_UART1_ENABLE = 0 generate u1o.txd <= '0'; u1o.rtsn <= '1'; end generate; ua1rx_pad : inpad generic map (tech => padtech) port map (uart1_rxd, u1i.rxd); ua1tx_pad : outpad generic map (tech => padtech) port map (uart1_txd, u1o.txd); ua1cts_pad : inpad generic map (tech => padtech) port map (uart1_cts_b, u1i.ctsn); ua1rts_pad : outpad generic map (tech => padtech) port map (uart1_rts_b, u1o.rtsn); irqctrl : if CFG_IRQ3_ENABLE /= 0 generate irqctrl0 : irqmp -- interrupt controller generic map (pindex => 2, paddr => 2, ncpu => NCPU) port map (rstn, clkm, apbi, apbo(2), irqo, irqi); end generate; irq3 : if CFG_IRQ3_ENABLE = 0 generate x : for i in 0 to NCPU-1 generate irqi(i).irl <= "0000"; end generate; apbo(2) <= apb_none; end generate; gpt : if CFG_GPT_ENABLE /= 0 generate timer0 : gptimer -- timer unit generic map (pindex => 3, paddr => 3, pirq => CFG_GPT_IRQ, sepirq => CFG_GPT_SEPIRQ, sbits => CFG_GPT_SW, ntimers => CFG_GPT_NTIM, nbits => CFG_GPT_TW) port map (rstn, clkm, apbi, apbo(3), gpti, open); gpti.dhalt <= dsuo.tstop; gpti.extclk <= '0'; end generate; nogpt : if CFG_GPT_ENABLE = 0 generate apbo(3) <= apb_none; end generate; svga : if CFG_SVGA_ENABLE /= 0 generate svga0 : svgactrl generic map(memtech => memtech, pindex => 14, paddr => 14, hindex => CFG_NCPU+CFG_AHB_UART+CFG_AHB_JTAG, clk0 => 40000, clk1 => 40000, clk2 => 25000, clk3 => 15385, burstlen => 6) port map(rstn, clkm, clkvga, apbi, apbo(14), vgao, ahbmi, ahbmo(CFG_NCPU+CFG_AHB_UART+CFG_AHB_JTAG), clk_sel); dvi0 : svga2ch7301c generic map (tech => fabtech, idf => 2) port map (lclk, rstraw, clk_sel, vgao, clkvga, clk25, clk40, clk65, clkvga, clk25, clk40, clk65, clkvga_p, clkvga_n, vgalock, lcd_datal, lcd_hsyncl, lcd_vsyncl, lcd_del); i2cdvi : i2cmst generic map (pindex => 6, paddr => 6, pmask => 16#FFF#, pirq => 6, filter => I2C_FILTER) port map (rstn, clkm, apbi, apbo(6), dvi_i2ci, dvi_i2co); end generate; novga : if CFG_SVGA_ENABLE = 0 generate apbo(14) <= apb_none; apbo(6) <= apb_none; lcd_datal <= (others => '0'); clkvga_p <= '0'; clkvga_n <= '0'; lcd_hsyncl <= '0'; lcd_vsyncl <= '0'; lcd_del <= '0'; dvi_i2co.scloen <= '1'; dvi_i2co.sdaoen <= '1'; end generate; dvi_d_pad : outpadv generic map (width => 12, tech => padtech) port map (dvi_d, lcd_datal); dvi_xclk_p_pad : outpad generic map (tech => padtech) port map (dvi_xclk_p, clkvga_p); dvi_xclk_n_pad : outpad generic map (tech => padtech) port map (dvi_xclk_n, clkvga_n); dvi_h_pad : outpad generic map (tech => padtech) port map (dvi_h, lcd_hsyncl); dvi_v_pad : outpad generic map (tech => padtech) port map (dvi_v, lcd_vsyncl); dvi_de_pad : outpad generic map (tech => padtech) port map (dvi_de, lcd_del); dvi_reset_b_pad : outpad generic map (tech => padtech) port map (dvi_reset_b, rstn); iic_scl_dvi_pad : iopad generic map (tech => padtech) port map (iic_scl_dvi, dvi_i2co.scl, dvi_i2co.scloen, dvi_i2ci.scl); iic_sda_dvi_pad : iopad generic map (tech => padtech) port map (iic_sda_dvi, dvi_i2co.sda, dvi_i2co.sdaoen, dvi_i2ci.sda); gpio0 : if CFG_GRGPIO_ENABLE /= 0 generate -- GPIO unit grgpio0: grgpio generic map(pindex => 8, paddr => 8, imask => CFG_GRGPIO_IMASK, nbits => CFG_GRGPIO_WIDTH) port map(rst => rstn, clk => clkm, apbi => apbi, apbo => apbo(8), gpioi => gpioi, gpioo => gpioo); end generate; nogpio0: if CFG_GRGPIO_ENABLE = 0 generate gpioo.oen <= (others => '1'); gpioo.val <= (others => '0'); gpioo.dout <= (others => '1'); end generate; dbg_led_pads : iopadvv generic map (tech => padtech, width => 3, level => cmos, voltage => x33v) port map (dbg_led(2 downto 0), gpioo.dout(2 downto 0), gpioo.oen(2 downto 0), gpioi.din(2 downto 0)); dvi_gpio_pad : iopad generic map (tech => padtech) port map (dvi_gpio1, gpioo.dout(4), gpioo.oen(4), gpioi.din(4)); iic_therm_b_pad : inpad generic map (tech => padtech) port map (iic_therm_b, gpioi.din(9)); iic_irq_b_pad : inpad generic map (tech => padtech) port map (iic_irq_b, gpioi.din(10)); iic_alert_b_pad : inpad generic map (tech => padtech) port map (iic_alert_b, gpioi.din(11)); sbr_pwg_rsm_rstj_pad : iopad generic map (tech => padtech, level => cmos, voltage => x25v) port map (sbr_pwg_rsm_rstj, gpioo.dout(7), gpioo.oen(7), gpioi.din(7)); sbr_nmi_r_pad : inpad generic map (tech => padtech) port map (sbr_nmi_r, gpioi.din(6)); sbr_intr_r_pad : inpad generic map (tech => padtech, level => cmos, voltage => x25v) port map (sbr_intr_r, gpioi.din(5)); sbr_ide_rst_b_pad : iopad generic map (tech => padtech) port map (sbr_ide_rst_b, gpioo.dout(8), gpioo.oen(8), gpioi.din(8)); i2cm: if CFG_I2C_ENABLE = 1 generate -- I2C master i2c0 : i2cmst generic map (pindex => 9, paddr => 9, pmask => 16#FFF#, pirq => 3, filter => I2C_FILTER) port map (rstn, clkm, apbi, apbo(9), i2ci, i2co); end generate; noi2cm: if CFG_I2C_ENABLE = 0 generate i2co.scloen <= '1'; i2co.sdaoen <= '1'; i2co.scl <= '0'; i2co.sda <= '0'; end generate; i2c_scl_pad : iopad generic map (tech => padtech) port map (fpga_scl, i2co.scl, i2co.scloen, i2ci.scl); i2c_sda_pad : iopad generic map (tech => padtech) port map (fpga_sda, i2co.sda, i2co.sdaoen, i2ci.sda); spic: if CFG_SPICTRL_ENABLE = 1 generate -- SPI controller spi1 : spictrl generic map (pindex => 10, paddr => 10, pmask => 16#fff#, pirq => 12, fdepth => CFG_SPICTRL_FIFO, slvselen => CFG_SPICTRL_SLVREG, slvselsz => CFG_SPICTRL_SLVS, odmode => 0, netlist => 0, syncram => CFG_SPICTRL_SYNCRAM, ft => CFG_SPICTRL_FT) port map (rstn, clkm, apbi, apbo(10), spii, spio, slvsel); spii.spisel <= '1'; -- Master only miso_pad : inpad generic map (tech => padtech) port map (spi_data_out, spii.miso); mosi_pad : outpad generic map (tech => padtech) port map (spi_data_in, spio.mosi); sck_pad : outpad generic map (tech => padtech) port map (spi_clk, spio.sck); slvsel_pad : outpad generic map (tech => padtech) port map (spi_data_cs_b, slvsel(0)); end generate spic; nospi: if CFG_SPICTRL_ENABLE = 0 generate miso_pad : inpad generic map (tech => padtech) port map (spi_data_out, spii.miso); mosi_pad : outpad generic map (tech => padtech) port map (spi_data_in, vcc(0)); sck_pad : outpad generic map (tech => padtech) port map (spi_clk, gnd(0)); slvsel_pad : outpad generic map (tech => padtech) port map (spi_data_cs_b, vcc(0)); end generate; ahbs : if CFG_AHBSTAT = 1 generate -- AHB status register ahbstat0 : ahbstat generic map (pindex => 15, paddr => 15, pirq => 7, nftslv => CFG_AHBSTATN) port map (rstn, clkm, ahbmi, ahbsi, stati, apbi, apbo(15)); end generate; ----------------------------------------------------------------------- --- ETHERNET --------------------------------------------------------- ----------------------------------------------------------------------- eth1 : if CFG_GRETH = 1 generate -- Gaisler ethernet MAC e1 : grethm generic map(hindex => NCPU+CFG_AHB_UART+CFG_AHB_JTAG+CFG_SVGA_ENABLE, pindex => 11, paddr => 11, pirq => 4, memtech => memtech, mdcscaler => CPU_FREQ/1000, enable_mdio => 1, fifosize => CFG_ETH_FIFO, nsync => 1, edcl => CFG_DSU_ETH, edclbufsz => CFG_ETH_BUF, macaddrh => CFG_ETH_ENM, macaddrl => CFG_ETH_ENL, phyrstadr => 7, ipaddrh => CFG_ETH_IPM, ipaddrl => CFG_ETH_IPL, giga => CFG_GRETH1G) port map( rst => rstn, clk => clkm, ahbmi => ahbmi, ahbmo => ahbmo(NCPU+CFG_AHB_UART+CFG_AHB_JTAG+CFG_SVGA_ENABLE), apbi => apbi, apbo => apbo(11), ethi => ethi, etho => etho); emdio_pad : iopad generic map (tech => padtech) port map (phy0_mdio, etho.mdio_o, etho.mdio_oe, ethi.mdio_i); etxc_pad : clkpad generic map (tech => padtech, arch => 2, level => cmos, voltage => x25v) port map (phy0_txclk, ethi.tx_clk); erxc_pad : clkpad generic map (tech => padtech, arch => 2, level => cmos, voltage => x25v) port map (phy0_rxclk, ethi.rx_clk); erxd_pad : inpadv generic map (tech => padtech, width => 4) port map (phy0_rxd, ethi.rxd(3 downto 0)); erxdv_pad : inpad generic map (tech => padtech) port map (phy0_rxctl_rxdv, ethi.rx_dv); erxer_pad : inpad generic map (tech => padtech) port map (phy0_rxer, ethi.rx_er); -- Collision detect and carrier sense are not connected on the -- board. ethi.rx_col <= '0'; ethi.rx_crs <= ethi.rx_dv; etxd_pad : outpadv generic map (tech => padtech, width => 4) port map (phy0_txd, etho.txd(3 downto 0)); etxen_pad : outpad generic map (tech => padtech) port map (phy0_txctl_txen, etho.tx_en); etxer_pad : outpad generic map (tech => padtech) port map (phy0_txer, etho.tx_er); emdc_pad : outpad generic map (tech => padtech) port map (phy0_mdc, etho.mdc); erst_pad : outpad generic map (tech => padtech) port map (phy0_reset, rstn); -- ethi.gtx_clk <= egtx_clk; end generate; ----------------------------------------------------------------------- --- PCI ------------------------------------------------------------ ---------------------------------------------------------------------- pp : if CFG_PCI /= 0 generate pci_mtf0 : if CFG_PCI = 2 generate -- master/target with fifo pci0 : pci_mtf generic map (memtech => memtech, hmstndx => NCPU+CFG_AHB_UART+CFG_AHB_JTAG+CFG_SVGA_ENABLE+CFG_GRETH, fifodepth => log2(CFG_PCIDEPTH), device_id => CFG_PCIDID, vendor_id => CFG_PCIVID, hslvndx => 7, pindex => 4, paddr => 4, haddr => 16#800#, hmask => 16#c00#, ioaddr => 16#400#, irq => 5, irqmask => 16#F#, nsync => 2, hostrst => 1) port map (rstn, clkm, pciclk, pcii, pcio, apbi, apbo(4), ahbmi, ahbmo(NCPU+CFG_AHB_UART+CFG_AHB_JTAG+CFG_SVGA_ENABLE+CFG_GRETH), ahbsi, ahbso(7)); end generate; pci_mtf1 : if CFG_PCI = 3 generate -- master/target with fifo and DMA dma : pcidma generic map (memtech => memtech, dmstndx => NCPU+CFG_AHB_UART+CFG_AHB_JTAG+CFG_SVGA_ENABLE+CFG_GRETH+1, dapbndx => 5, dapbaddr => 5, blength => blength, mstndx => NCPU+CFG_AHB_UART+CFG_AHB_JTAG+CFG_SVGA_ENABLE+CFG_GRETH, fifodepth => log2(fifodepth), device_id => CFG_PCIDID, vendor_id => CFG_PCIVID, slvndx => 7, apbndx => 4, apbaddr => 4, haddr => 16#800#, hmask => 16#c00#, ioaddr => 16#400#, irq => 5, irqmask => 16#F#, nsync => 2, hostrst => 1) port map (rstn, clkm, pciclk, pcii, pcio, apbo(5), ahbmo(NCPU+CFG_AHB_UART+CFG_AHB_JTAG+CFG_SVGA_ENABLE+CFG_GRETH+1), apbi, apbo(4), ahbmi, ahbmo(NCPU+CFG_AHB_UART+CFG_AHB_JTAG+CFG_SVGA_ENABLE+CFG_GRETH), ahbsi, ahbso(7)); end generate; pci_trc0 : if CFG_PCITBUFEN /= 0 generate -- PCI trace buffer pt0 : pcitrace generic map (depth => (6 + log2(CFG_PCITBUF/256)), memtech => memtech, pindex => 12, paddr => 16#100#, pmask => 16#f00#) port map (rstn, clkm, pciclk, pcii, apbi, apbo(12)); end generate; pcia0 : if CFG_PCI_ARB = 1 generate -- PCI arbiter pciarb0 : pciarb generic map (pindex => 13, paddr => 13, nb_agents => CFG_PCI_ARB_NGNT, apb_en => CFG_PCI_ARBAPB) port map (clk => pciclk, rst_n => pcii.rst, req_n => pci_arb_req, frame_n => pcii.frame, gnt_n => pci_arb_gnt, pclk => clkm, prst_n => rstn, apbi => apbi, apbo => apbo(13)); -- Internal connection of req(2) pci_arb_req(0 to 4) <= pci_arb_reql(0 to 1) & pci_reql & pci_arb_reql(3 to 4); pci_arb_req(5 to 7) <= (others => '1'); end generate; end generate; nopcia0: if CFG_PCI = 0 or CFG_PCI_ARB = 0 generate pci_arb_gnt <= (others => '1'); end generate; nopci_mtf: if CFG_PCI /= 2 and CFG_PCI /= 3 generate pcio <= pci_out_none; end generate; pgnt_pad : outpadv generic map (tech => padtech, width => 5, level => pci33) port map (pci_p_gnt_b, pci_arb_gnt(0 to 4)); preq_pad : inpadv generic map (tech => padtech, width => 5, level => pci33) port map (pci_p_req_b, pci_arb_reql); pcipads0 : pcipads -- PCI pads generic map (padtech => padtech, host => 2, int => 14, no66 => 1, onchipreqgnt => 1, drivereset => 1, constidsel => 1) port map (pci_rst => pci_p_rst_b, pci_gnt => pci_arb_gnt(2), pci_idsel => '0', --pci_fpga_idsel, pci_lock => pci_p_lock_b, pci_ad => pci_p_ad, pci_cbe => pci_p_cbe_b, pci_frame => pci_p_frame_b, pci_irdy => pci_p_irdy_b, pci_trdy => pci_p_trdy_b, pci_devsel => pci_p_devsel_b, pci_stop => pci_p_stop_b, pci_perr => pci_p_perr_b, pci_par => pci_p_par, pci_req => pci_reql, pci_serr => pci_p_serr_b, pci_host => pci_host, pci_66 => pci_66, pcii => pcii, pcio => pcio, pci_int => pci_intv); pci_intv <= pci_p_intd_b & pci_p_intc_b & pci_p_intb_b & pci_p_inta_b; pci_host <= '0'; -- Always host pci_66 <= '0'; ----------------------------------------------------------------------- --- SYSTEM MONITOR --------------------------------------------------- ----------------------------------------------------------------------- grsmon: if CFG_GRSYSMON = 1 generate sysm0 : grsysmon generic map (tech => fabtech, hindex => 8, hirq => 1, caddr => 16#003#, cmask => 16#fff#, saddr => 16#004#, smask => 16#ffe#, split => CFG_SPLIT, extconvst => 0, wrdalign => 1, INIT_40 => X"0000", INIT_41 => X"0000", INIT_42 => X"0800", INIT_43 => X"0000", INIT_44 => X"0000", INIT_45 => X"0000", INIT_46 => X"0000", INIT_47 => X"0000", INIT_48 => X"0000", INIT_49 => X"0000", INIT_4A => X"0000", INIT_4B => X"0000", INIT_4C => X"0000", INIT_4D => X"0000", INIT_4E => X"0000", INIT_4F => X"0000", INIT_50 => X"0000", INIT_51 => X"0000", INIT_52 => X"0000", INIT_53 => X"0000", INIT_54 => X"0000", INIT_55 => X"0000", INIT_56 => X"0000", INIT_57 => X"0000", SIM_MONITOR_FILE => "sysmon.txt") port map (rstn, clkm, ahbsi, ahbso(8), sysmoni, sysmono); sysmoni.convst <= '0'; sysmoni.convstclk <= '0'; sysmoni.vauxn <= (others => '0'); sysmoni.vauxp <= (others => '0'); -- sysmoni.vn <= test_mon_vn0_n; -- sysmoni.vp <= test_mon_vp0_p; end generate grsmon; ----------------------------------------------------------------------- --- AHB RAM ---------------------------------------------------------- ----------------------------------------------------------------------- ocram : if CFG_AHBRAMEN = 1 generate ahbram0 : ahbram generic map (hindex => 9, haddr => CFG_AHBRADDR, tech => CFG_MEMTECH, kbytes => CFG_AHBRSZ, pipe => CFG_AHBRPIPE) port map ( rstn, clkm, ahbsi, ahbso(9)); end generate; ----------------------------------------------------------------------- --- APB bridge with LOGAN -------------------------------------------- ----------------------------------------------------------------------- -- log: if CFG_LOGAN = 1 generate -- Logan is enabled by constant -- -- declared above -- apb0 : apbctrl -- AHB/APB bridge -- generic map (hindex => 11, haddr => 16#F00#, nslaves => 1) -- port map (rstn, clkm, ahbsi, ahbso(11), apbi1, apbo1); -- logan0 : logan -- Logic analyzer -- generic map (dbits => 64, depth => 4096, trigl => 2, usereg => 1, -- usequal => 0, pindex => 0, paddr => 0, pmask => 16#F00#, -- memtech => memtech) -- port map (rstn, clkm, pciclk, apbi1, apbo1(0), signals); -- signals(0) <= pcii.rst; -- signals(1) <= pcii.gnt; -- signals(2) <= pcii.idsel; -- signals(34 downto 3) <= pcii.ad; -- signals(38 downto 35) <= pcii.cbe; -- signals(39) <= pcii.frame; -- signals(40) <= pcii.irdy; -- signals(41) <= pcii.trdy; -- signals(42) <= pcii.devsel; -- signals(43) <= pcii.stop; -- signals(44) <= pcii.lock; -- signals(45) <= pcii.perr; -- signals(46) <= pcii.serr; -- signals(47) <= pcii.par; -- signals(48) <= pcii.host; -- signals(49) <= pcii.pci66; -- signals(53 downto 50) <= pcii.int; -- signals(58 downto 54) <= pci_arb_gnt(0 to 4); -- signals(63 downto 59) <= pci_arb_req(0 to 4); -- end generate log; nolog: if CFG_LOGAN /= 1 generate signals <= (others => '0'); end generate nolog; ----------------------------------------------------------------------- --- AHB DEBUG -------------------------------------------------------- ----------------------------------------------------------------------- -- dma0 : ahbdma -- generic map (hindex => CFG_NCPU+CFG_AHB_UART+CFG_GRETH+CFG_AHB_JTAG, -- pindex => 13, paddr => 13, dbuf => 6) -- port map (rstn, clkm, apbi, apbo(13), ahbmi, -- ahbmo(CFG_NCPU+CFG_AHB_UART+CFG_GRETH+CFG_AHB_JTAG)); -- at0 : ahbtrace -- generic map ( hindex => 7, ioaddr => 16#200#, iomask => 16#E00#, -- tech => memtech, irq => 0, kbytes => 8) -- port map ( rstn, clkm, ahbmi, ahbsi, ahbso(7)); ----------------------------------------------------------------------- --- Drive unused bus elements --------------------------------------- ----------------------------------------------------------------------- -- nam1 : for i in (NCPU+CFG_AHB_UART+CFG_ETH+CFG_AHB_ETH+CFG_AHB_JTAG) to NAHBMST-1 generate -- ahbmo(i) <= ahbm_none; -- end generate; -- nap0 : for i in 11 to NAPBSLV-1 generate apbo(i) <= apb_none; end generate; -- nah0 : for i in 8 to NAHBSLV-1 generate ahbso(i) <= ahbs_none; end generate; ----------------------------------------------------------------------- --- Boot message ---------------------------------------------------- ----------------------------------------------------------------------- -- pragma translate_off x : report_design generic map ( msg1 => system_table(XILINX_ML510), fabtech => tech_table(fabtech), memtech => tech_table(memtech), mdel => 1 ); -- pragma translate_on end;	gpl-2.0	8bce9f6dc6b440b040d0b761063a1433	0.577625	3.272525	false	false	false	false
marco-c/leon-nexys2	grlib-gpl-1.3.4-b4140/designs/leon3-gr-pci-xc2v3000/config.vhd	1	6,842	----------------------------------------------------------------------------- -- LEON3 Demonstration design test bench configuration -- Copyright (C) 2009 Aeroflex Gaisler ------------------------------------------------------------------------------ library techmap; use techmap.gencomp.all; package config is -- Technology and synthesis options constant CFG_FABTECH : integer := virtex2; constant CFG_MEMTECH : integer := virtex2; constant CFG_PADTECH : integer := virtex2; constant CFG_NOASYNC : integer := 0; constant CFG_SCAN : integer := 0; -- Clock generator constant CFG_CLKTECH : integer := virtex2; constant CFG_CLKMUL : integer := (4); constant CFG_CLKDIV : integer := (4); constant CFG_OCLKDIV : integer := 1; constant CFG_OCLKBDIV : integer := 0; constant CFG_OCLKCDIV : integer := 0; constant CFG_PCIDLL : integer := 0; constant CFG_PCISYSCLK: integer := 0; constant CFG_CLK_NOFB : integer := 0; -- LEON3 processor core constant CFG_LEON3 : integer := 1; constant CFG_NCPU : integer := (1); constant CFG_NWIN : integer := (8); constant CFG_V8 : integer := 2 + 40; constant CFG_MAC : integer := 0; constant CFG_BP : integer := 0; constant CFG_SVT : integer := 1; constant CFG_RSTADDR : integer := 16#00000#; constant CFG_LDDEL : integer := (1); constant CFG_NOTAG : integer := 0; constant CFG_NWP : integer := (2); constant CFG_PWD : integer := 02; constant CFG_FPU : integer := 0 + 160 + 320; constant CFG_GRFPUSH : integer := 0; constant CFG_ICEN : integer := 1; constant CFG_ISETS : integer := 2; constant CFG_ISETSZ : integer := 8; constant CFG_ILINE : integer := 8; constant CFG_IREPL : integer := 0; constant CFG_ILOCK : integer := 0; constant CFG_ILRAMEN : integer := 0; constant CFG_ILRAMADDR: integer := 16#8E#; constant CFG_ILRAMSZ : integer := 1; constant CFG_DCEN : integer := 1; constant CFG_DSETS : integer := 2; constant CFG_DSETSZ : integer := 4; constant CFG_DLINE : integer := 4; constant CFG_DREPL : integer := 0; constant CFG_DLOCK : integer := 0; constant CFG_DSNOOP : integer := 1 + 0 + 40; constant CFG_DFIXED : integer := 16#0#; constant CFG_DLRAMEN : integer := 0; constant CFG_DLRAMADDR: integer := 16#8F#; constant CFG_DLRAMSZ : integer := 1; constant CFG_MMUEN : integer := 1; constant CFG_ITLBNUM : integer := 8; constant CFG_DTLBNUM : integer := 8; constant CFG_TLB_TYPE : integer := 0 + 12; constant CFG_TLB_REP : integer := 0; constant CFG_MMU_PAGE : integer := 0; constant CFG_DSU : integer := 1; constant CFG_ITBSZ : integer := 2; constant CFG_ATBSZ : integer := 2; constant CFG_LEON3FT_EN : integer := 0; constant CFG_IUFT_EN : integer := 0; constant CFG_FPUFT_EN : integer := 0; constant CFG_RF_ERRINJ : integer := 0; constant CFG_CACHE_FT_EN : integer := 0; constant CFG_CACHE_ERRINJ : integer := 0; constant CFG_LEON3_NETLIST: integer := 0; constant CFG_DISAS : integer := 0 + 0; constant CFG_PCLOW : integer := 2; -- AMBA settings constant CFG_DEFMST : integer := (0); constant CFG_RROBIN : integer := 1; constant CFG_SPLIT : integer := 0; constant CFG_FPNPEN : integer := 0; constant CFG_AHBIO : integer := 16#FFF#; constant CFG_APBADDR : integer := 16#800#; constant CFG_AHB_MON : integer := 0; constant CFG_AHB_MONERR : integer := 0; constant CFG_AHB_MONWAR : integer := 0; constant CFG_AHB_DTRACE : integer := 0; -- DSU UART constant CFG_AHB_UART : integer := 1; -- JTAG based DSU interface constant CFG_AHB_JTAG : integer := 1; -- Ethernet DSU constant CFG_DSU_ETH : integer := 1 + 0 + 0; constant CFG_ETH_BUF : integer := 2; constant CFG_ETH_IPM : integer := 16#C0A8#; constant CFG_ETH_IPL : integer := 16#0034#; constant CFG_ETH_ENM : integer := 16#020000#; constant CFG_ETH_ENL : integer := 16#000006#; -- LEON2 memory controller constant CFG_MCTRL_LEON2 : integer := 1; constant CFG_MCTRL_RAM8BIT : integer := 0; constant CFG_MCTRL_RAM16BIT : integer := 0; constant CFG_MCTRL_5CS : integer := 0; constant CFG_MCTRL_SDEN : integer := 1; constant CFG_MCTRL_SEPBUS : integer := 0; constant CFG_MCTRL_INVCLK : integer := 0; constant CFG_MCTRL_SD64 : integer := 0; constant CFG_MCTRL_PAGE : integer := 1 + 0; -- AHB ROM constant CFG_AHBROMEN : integer := 0; constant CFG_AHBROPIP : integer := 0; constant CFG_AHBRODDR : integer := 16#000#; constant CFG_ROMADDR : integer := 16#000#; constant CFG_ROMMASK : integer := 16#E00# + 16#000#; -- AHB RAM constant CFG_AHBRAMEN : integer := 0; constant CFG_AHBRSZ : integer := 1; constant CFG_AHBRADDR : integer := 16#A00#; constant CFG_AHBRPIPE : integer := 0; -- Gaisler Ethernet core constant CFG_GRETH : integer := 1; constant CFG_GRETH1G : integer := 0; constant CFG_ETH_FIFO : integer := 32; -- PCI interface constant CFG_PCI : integer := 0; constant CFG_PCIVID : integer := 16#0#; constant CFG_PCIDID : integer := 16#0#; constant CFG_PCIDEPTH : integer := 8; constant CFG_PCI_MTF : integer := 1; -- PCI arbiter constant CFG_PCI_ARB : integer := 0; constant CFG_PCI_ARBAPB : integer := 0; constant CFG_PCI_ARB_NGNT : integer := 4; -- PCI trace buffer constant CFG_PCITBUFEN: integer := 0; constant CFG_PCITBUF : integer := 256; -- Spacewire interface constant CFG_SPW_EN : integer := 0; constant CFG_SPW_NUM : integer := 1; constant CFG_SPW_AHBFIFO : integer := 4; constant CFG_SPW_RXFIFO : integer := 16; constant CFG_SPW_RMAP : integer := 0; constant CFG_SPW_RMAPBUF : integer := 4; constant CFG_SPW_RMAPCRC : integer := 0; constant CFG_SPW_NETLIST : integer := 0; constant CFG_SPW_FT : integer := 0; constant CFG_SPW_GRSPW : integer := 2; constant CFG_SPW_RXUNAL : integer := 0; constant CFG_SPW_DMACHAN : integer := 1; constant CFG_SPW_PORTS : integer := 1; constant CFG_SPW_INPUT : integer := 2; constant CFG_SPW_OUTPUT : integer := 0; constant CFG_SPW_RTSAME : integer := 0; -- UART 1 constant CFG_UART1_ENABLE : integer := 1; constant CFG_UART1_FIFO : integer := 4; -- UART 2 constant CFG_UART2_ENABLE : integer := 1; constant CFG_UART2_FIFO : integer := 4; -- LEON3 interrupt controller constant CFG_IRQ3_ENABLE : integer := 1; constant CFG_IRQ3_NSEC : integer := 0; -- Modular timer constant CFG_GPT_ENABLE : integer := 1; constant CFG_GPT_NTIM : integer := (2); constant CFG_GPT_SW : integer := (8); constant CFG_GPT_TW : integer := (32); constant CFG_GPT_IRQ : integer := (8); constant CFG_GPT_SEPIRQ : integer := 1; constant CFG_GPT_WDOGEN : integer := 0; constant CFG_GPT_WDOG : integer := 16#0#; -- GPIO port constant CFG_GRGPIO_ENABLE : integer := 1; constant CFG_GRGPIO_IMASK : integer := 16#00FE#; constant CFG_GRGPIO_WIDTH : integer := (16); -- GRLIB debugging constant CFG_DUART : integer := 0; end;	gpl-2.0	4ab635ae78549d1763696474c8b9d6f5	0.645718	3.593487	false	false	false	false
marco-c/leon-nexys2	grlib-gpl-1.3.4-b4140/lib/techmap/inferred/ddr_phy_inferred.vhd	1	16,449	------------------------------------------------------------------------------ -- This file is a part of the GRLIB VHDL IP LIBRARY -- Copyright (C) 2003 - 2008, Gaisler Research -- Copyright (C) 2008 - 2013, Aeroflex Gaisler -- -- This program is free software; you can redistribute it and/or modify -- it under the terms of the GNU General Public License as published by -- the Free Software Foundation; either version 2 of the License, or -- (at your option) any later version. -- -- This program is distributed in the hope that it will be useful, -- but WITHOUT ANY WARRANTY; without even the implied warranty of -- MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the -- GNU General Public License for more details. -- -- You should have received a copy of the GNU General Public License -- along with this program; if not, write to the Free Software -- Foundation, Inc., 59 Temple Place, Suite 330, Boston, MA 02111-1307 USA ----------------------------------------------------------------------------- -- Entity: generic_ddr_phy -- File: ddr_phy_inferred.vhd -- Author: Nils-Johan Wessman - Gaisler Research -- Modified: Magnus Hjorth - Aeroflex Gaisler -- Description: Generic DDR PHY (simulation only) ------------------------------------------------------------------------------ --################################################################################### -- Generic DDR1 PHY --################################################################################### library ieee; use ieee.std_logic_1164.all; library techmap; use techmap.gencomp.all; library grlib; use grlib.stdlib.all; entity generic_ddr_phy_wo_pads is generic (MHz : integer := 100; rstdelay : integer := 200; dbits : integer := 16; clk_mul : integer := 2 ; clk_div : integer := 2; rskew : integer := 0; mobile : integer := 0; abits: integer := 14; nclk: integer := 3; ncs: integer := 2); port( rst : in std_ulogic; clk : in std_logic; -- input clock clkout : out std_ulogic; -- system clock clk0r : in std_ulogic; lock : out std_ulogic; -- DCM locked ddr_clk : out std_logic_vector(nclk-1 downto 0); ddr_clkb : out std_logic_vector(nclk-1 downto 0); ddr_clk_fb_out : out std_logic; ddr_clk_fb: in std_logic; ddr_cke : out std_logic_vector(ncs-1 downto 0); ddr_csb : out std_logic_vector(ncs-1 downto 0); ddr_web : out std_ulogic; -- ddr write enable ddr_rasb : out std_ulogic; -- ddr ras ddr_casb : out std_ulogic; -- ddr cas ddr_dm : out std_logic_vector (dbits/8-1 downto 0); -- ddr dm ddr_dqs_in : in std_logic_vector (dbits/8-1 downto 0); -- ddr dqs ddr_dqs_out : out std_logic_vector (dbits/8-1 downto 0); -- ddr dqs ddr_dqs_oen : out std_logic_vector (dbits/8-1 downto 0); -- ddr dqs ddr_ad : out std_logic_vector (abits-1 downto 0); -- ddr address ddr_ba : out std_logic_vector (1 downto 0); -- ddr bank address ddr_dq_in : in std_logic_vector (dbits-1 downto 0); -- ddr data ddr_dq_out : out std_logic_vector (dbits-1 downto 0); -- ddr data ddr_dq_oen : out std_logic_vector (dbits-1 downto 0); -- ddr data addr : in std_logic_vector (abits-1 downto 0); -- data mask ba : in std_logic_vector ( 1 downto 0); -- data mask dqin : out std_logic_vector (dbits2-1 downto 0); -- ddr input data dqout : in std_logic_vector (dbits2-1 downto 0); -- ddr input data dm : in std_logic_vector (dbits/4-1 downto 0); -- data mask oen : in std_ulogic; dqs : in std_ulogic; dqsoen : in std_ulogic; rasn : in std_ulogic; casn : in std_ulogic; wen : in std_ulogic; csn : in std_logic_vector(ncs-1 downto 0); cke : in std_logic_vector(ncs-1 downto 0); ck : in std_logic_vector(nclk-1 downto 0); moben : in std_logic -- Mobile DDR enable ); end; architecture rtl of generic_ddr_phy_wo_pads is component sim_pll generic ( clkmul: integer := 1; clkdiv1: integer := 1; clkphase1: integer := 0; clkdiv2: integer := 1; clkphase2: integer := 0; clkdiv3: integer := 1; clkphase3: integer := 0; clkdiv4: integer := 1; clkphase4: integer := 0; minfreq: integer := 0; maxfreq: integer := 10000000 ); port ( i: in std_logic; o1: out std_logic; o2: out std_logic; o3: out std_logic; o4: out std_logic; lock: out std_logic; rst: in std_logic ); end component; constant freq_khz: integer := (1000MHzclk_mul)/(clk_div); constant freq_mhz: integer := freq_khz / 1000; constant td90: time := 250 us * (1.0 / real(freq_khz)); signal vcc, gnd : std_logic; -- VCC and GND signal clk0, clk90r, clk180r, clk270r : std_ulogic; signal lockl,vlockl,locked: std_ulogic; signal dqs90,dqs90n: std_logic_vector(dbits/8-1 downto 0); signal ckl: std_logic_vector(nclk-1 downto 0); signal ckel: std_logic_vector(ncs-1 downto 0); begin vcc <= '1'; gnd <= '0'; ----------------------------------------------------------------------------------- -- Clock generation (Only for simulation) ----------------------------------------------------------------------------------- -- Phase shifted clocks --pragma translate_off -- To avoid jitter problems when using ddr without sync regs we shift -- 10 degrees extra. pll0: sim_pll generic map ( clkmul => clk_mul, clkdiv1 => clk_div, clkphase1 => 0-10+360, clkdiv2 => clk_div, clkphase2 => 90-10, clkdiv3 => clk_div, clkphase3 => 180-10, clkdiv4 => clk_div, clkphase4 => 270-10, minfreq => MHz1000, maxfreq => MHz1000 ) port map ( i => clk, o1 => clk0, o2 => clk90r, o3 => clk180r, o4 => clk270r, lock => lockl, rst => rst); --pragma translate_on -- Clock to DDR controller clkout <= clk0; ddr_clk_fb_out <= '0'; ----------------------------------------------------------------------------------- -- Lock delay ----------------------------------------------------------------------------------- rdel : if rstdelay /= 0 generate rcnt : process (clk0r, lockl, rst) variable cnt : std_logic_vector(15 downto 0); variable vlock, co : std_ulogic; begin if rising_edge(clk0r) then co := cnt(15); vlockl <= vlock; if lockl = '0' then cnt := conv_std_logic_vector(rstdelayFREQ_MHZ, 16); vlock := '0'; else if vlock = '0' then cnt := cnt -1; vlock := cnt(15) and not co; end if; end if; end if; if lockl = '0' or rst='0' then vlock := '0'; end if; end process; end generate; locked <= lockl when rstdelay = 0 else vlockl; lock <= locked; ----------------------------------------------------------------------------- -- DQS shifting ----------------------------------------------------------------------------- -- pragma translate_off dqs90 <= transport ddr_dqs_in after td90; dqs90n <= not dqs90; -- pragma translate_on ----------------------------------------------------------------------------- -- Data path ----------------------------------------------------------------------------- -- For mobile SDRAM, force Cke high during reset and reset-delay, -- For regular SDRAM, force Cke low -- also disable outgoing clock until we have achieved PLL lock mobgen: if mobile > 1 generate ckel <= cke or (cke'range => not locked); end generate; nmobgen: if mobile < 2 generate ckel <= cke and (cke'range => locked); end generate; ckl <= ck and (ck'range => lockl); dp0: ddrphy_datapath generic map ( regtech => inferred, dbits => dbits, abits => abits, bankbits => 2, ncs => ncs, nclk => nclk, resync => 2 ) port map ( clk0 => clk0r, clk90 => clk90r, clk180 => clk180r, clk270 => clk270r, clkresync => gnd, ddr_clk => ddr_clk, ddr_clkb => ddr_clkb, ddr_dq_in => ddr_dq_in, ddr_dq_out => ddr_dq_out, ddr_dq_oen => ddr_dq_oen, ddr_dqs_in90 => dqs90, ddr_dqs_in90n => dqs90n, ddr_dqs_out => ddr_dqs_out, ddr_dqs_oen => ddr_dqs_oen, ddr_cke => ddr_cke, ddr_csb => ddr_csb, ddr_web => ddr_web, ddr_rasb => ddr_rasb, ddr_casb => ddr_casb, ddr_ad => ddr_ad, ddr_ba => ddr_ba, ddr_dm => ddr_dm, ddr_odt => open, dqin => dqin, dqout => dqout, addr => addr, ba => ba, dm => dm, oen => oen, rasn => rasn, casn => casn, wen => wen, csn => csn, cke => ckel, odt => (others => '0'), dqs_en => dqs, dqs_oen => dqsoen, ddrclk_en => ckl ); end; --################################################################################### -- Generic DDR2 PHY --################################################################################### library ieee; use ieee.std_logic_1164.all; library techmap; use techmap.gencomp.all; library grlib; use grlib.stdlib.all; entity generic_ddr2_phy_wo_pads is generic (MHz : integer := 100; rstdelay : integer := 200; dbits : integer := 16; clk_mul : integer := 2 ; clk_div : integer := 2; rskew : integer := 0; eightbanks: integer := 0; abits: integer := 14; cben: integer := 0; chkbits: integer := 8; nclk: integer := 3; ncs: integer := 2); port( rst : in std_ulogic; clk : in std_logic; -- input clock clkout : out std_ulogic; -- system clock clk0r : in std_ulogic; -- system clock returned lock : out std_ulogic; -- DCM locked ddr_clk : out std_logic_vector(nclk-1 downto 0); ddr_clkb : out std_logic_vector(nclk-1 downto 0); ddr_clk_fb_out : out std_logic; ddr_clk_fb : in std_logic; ddr_cke : out std_logic_vector(ncs-1 downto 0); ddr_csb : out std_logic_vector(ncs-1 downto 0); ddr_web : out std_ulogic; -- ddr write enable ddr_rasb : out std_ulogic; -- ddr ras ddr_casb : out std_ulogic; -- ddr cas ddr_dm : out std_logic_vector (dbits/8-1 downto 0); -- ddr dm ddr_dqs_in : in std_logic_vector (dbits/8-1 downto 0); -- ddr dqs ddr_dqs_out : out std_logic_vector (dbits/8-1 downto 0); -- ddr dqs ddr_dqs_oen : out std_logic_vector (dbits/8-1 downto 0); -- ddr dqs ddr_ad : out std_logic_vector (abits-1 downto 0); -- ddr address ddr_ba : out std_logic_vector (1+eightbanks downto 0); -- ddr bank address ddr_dq_in : in std_logic_vector (dbits-1 downto 0); -- ddr data ddr_dq_out : out std_logic_vector (dbits-1 downto 0); -- ddr data ddr_dq_oen : out std_logic_vector (dbits-1 downto 0); -- ddr data ddr_odt : out std_logic_vector(ncs-1 downto 0); -- ddr odt addr : in std_logic_vector (abits-1 downto 0); -- data mask ba : in std_logic_vector (2 downto 0); -- data mask dqin : out std_logic_vector (dbits2-1 downto 0); -- ddr input data dqout : in std_logic_vector (dbits2-1 downto 0); -- ddr input data dm : in std_logic_vector (dbits/4-1 downto 0); -- data mask oen : in std_ulogic; dqs : in std_ulogic; dqsoen : in std_ulogic; rasn : in std_ulogic; casn : in std_ulogic; wen : in std_ulogic; csn : in std_logic_vector(ncs-1 downto 0); cke : in std_logic_vector(ncs-1 downto 0); ck : in std_logic_vector(2 downto 0); odt : in std_logic_vector(1 downto 0) ); end; architecture rtl of generic_ddr2_phy_wo_pads is component sim_pll generic ( clkmul: integer := 1; clkdiv1: integer := 1; clkphase1: integer := 0; clkdiv2: integer := 1; clkphase2: integer := 0; clkdiv3: integer := 1; clkphase3: integer := 0; clkdiv4: integer := 1; clkphase4: integer := 0; minfreq: integer := 0; maxfreq: integer := 10000000 ); port ( i: in std_logic; o1: out std_logic; o2: out std_logic; o3: out std_logic; o4: out std_logic; lock: out std_logic; rst: in std_logic ); end component; constant freq_khz: integer := (1000MHzclk_mul)/(clk_div); constant freq_mhz: integer := freq_khz / 1000; constant td90: time := 250 us (1.0 / real(freq_khz)); signal vcc, gnd : std_logic; -- VCC and GND signal clk0, clk90r, clk180r, clk270r : std_ulogic; signal lockl,vlockl,locked: std_ulogic; signal dqs90,dqs90n: std_logic_vector(dbits/8-1 downto 0); begin vcc <= '1'; gnd <= '0'; ----------------------------------------------------------------------------------- -- Clock generation (Only for simulation) ----------------------------------------------------------------------------------- -- Phase shifted clocks --pragma translate_off -- To avoid jitter problems when using ddr2 without sync regs we shift -- 10 degrees extra. pll0: sim_pll generic map ( clkmul => clk_mul, clkdiv1 => clk_div, clkphase1 => 0-10+360, clkdiv2 => clk_div, clkphase2 => 90-10, clkdiv3 => clk_div, clkphase3 => 180-10, clkdiv4 => clk_div, clkphase4 => 270-10, minfreq => MHz1000, maxfreq => MHz1000 ) port map ( i => clk, o1 => clk0, o2 => clk90r, o3 => clk180r, o4 => clk270r, lock => lockl, rst => rst); --pragma translate_on -- Clock to DDR controller clkout <= clk0; ddr_clk_fb_out <= '0'; ----------------------------------------------------------------------------------- -- Lock delay ----------------------------------------------------------------------------------- rdel : if rstdelay /= 0 generate rcnt : process (clk0r, lockl) variable cnt : std_logic_vector(15 downto 0); variable vlock, co : std_ulogic; begin if rising_edge(clk0r) then co := cnt(15); vlockl <= vlock; if lockl = '0' then cnt := conv_std_logic_vector(rstdelay*FREQ_MHZ, 16); vlock := '0'; else if vlock = '0' then cnt := cnt -1; vlock := cnt(15) and not co; end if; end if; end if; if lockl = '0' then vlock := '0'; end if; end process; end generate; locked <= lockl when rstdelay = 0 else vlockl; lock <= locked; ----------------------------------------------------------------------------- -- DQS shifting ----------------------------------------------------------------------------- -- pragma translate_off dqs90 <= transport ddr_dqs_in after td90; dqs90n <= not dqs90; -- pragma translate_on ----------------------------------------------------------------------------- -- Data path ----------------------------------------------------------------------------- dp0: ddrphy_datapath generic map ( regtech => inferred, dbits => dbits, abits => abits, bankbits => 2+EIGHTBANKS, ncs => ncs, nclk => nclk, resync => 0 ) port map ( clk0 => clk0r, clk90 => clk90r, clk180 => clk180r, clk270 => clk270r, clkresync => gnd, ddr_clk => ddr_clk, ddr_clkb => ddr_clkb, ddr_dq_in => ddr_dq_in, ddr_dq_out => ddr_dq_out, ddr_dq_oen => ddr_dq_oen, ddr_dqs_in90 => dqs90, ddr_dqs_in90n => dqs90n, ddr_dqs_out => ddr_dqs_out, ddr_dqs_oen => ddr_dqs_oen, ddr_cke => ddr_cke, ddr_csb => ddr_csb, ddr_web => ddr_web, ddr_rasb => ddr_rasb, ddr_casb => ddr_casb, ddr_ad => ddr_ad, ddr_ba => ddr_ba, ddr_dm => ddr_dm, ddr_odt => ddr_odt, dqin => dqin, dqout => dqout, addr => addr, ba => ba(1+eightbanks downto 0), dm => dm, oen => oen, rasn => rasn, casn => casn, wen => wen, csn => csn, cke => cke, odt => odt, dqs_en => dqs, dqs_oen => dqsoen, ddrclk_en => ck(nclk-1 downto 0) ); end;	gpl-2.0	1328c5422d4e0923954c845bb1fc363e	0.500334	3.732471	false	false	false	false
marco-c/leon-nexys2	grlib-gpl-1.3.4-b4140/designs/leon3-digilent-nexys4/project_1/project_1.srcs/sources_1/imports/sources/bftLib/core_transform.vhdl	1	3,812	--///////////////////////////////////////////////////////////////////////// --// Copyright (c) 2008 Xilinx, Inc. All rights reserved. --// --// XILINX CONFIDENTIAL PROPERTY --// This document contains proprietary information which is --// protected by copyright. All rights are reserved. This notice --// refers to original work by Xilinx, Inc. which may be derivitive --// of other work distributed under license of the authors. In the --// case of derivitive work, nothing in this notice overrides the --// original author's license agreeement. Where applicable, the --// original license agreement is included in it's original --// unmodified form immediately below this header. --// --// Xilinx, Inc. --// XILINX IS PROVIDING THIS DESIGN, CODE, OR INFORMATION "AS IS" AS A --// COURTESY TO YOU. BY PROVIDING THIS DESIGN, CODE, OR INFORMATION AS --// ONE POSSIBLE IMPLEMENTATION OF THIS FEATURE, APPLICATION OR --// STANDARD, XILINX IS MAKING NO REPRESENTATION THAT THIS IMPLEMENTATION --// IS FREE FROM ANY CLAIMS OF INFRINGEMENT, AND YOU ARE RESPONSIBLE --// FOR OBTAINING ANY RIGHTS YOU MAY REQUIRE FOR YOUR IMPLEMENTATION. --// XILINX EXPRESSLY DISCLAIMS ANY WARRANTY WHATSOEVER WITH RESPECT TO --// THE ADEQUACY OF THE IMPLEMENTATION, INCLUDING BUT NOT LIMITED TO --// ANY WARRANTIES OR REPRESENTATIONS THAT THIS IMPLEMENTATION IS FREE --// FROM CLAIMS OF INFRINGEMENT, IMPLIED WARRANTIES OF MERCHANTABILITY --// AND FITNESS FOR A PARTICULAR PURPOSE. --// --///////////////////////////////////////////////////////////////////////// library IEEE; use IEEE.STD_LOGIC_1164.all; use IEEE.STD_LOGIC_ARITH.all; use IEEE.STD_LOGIC_SIGNED.all; entity coreTransform is generic ( DATA_WIDTH : integer := 16 ); port ( clk : in std_logic; x, xStep, u : in std_logic_vector (DATA_WIDTH-1 downto 0); xOut, xOutStep : out std_logic_vector (DATA_WIDTH-1 downto 0) ); --synthesis packing can change the resutls greatly --setting up some attributes to force the mapping I want --attribute register_duplication : string; --attribute register_duplication of coreTransform : entity is "yes"; --attribute register_balancing : string; --attribute register_balancing of coreTransform : entity is "yes"; ----force a mapping to DSP48s attribute use_dsp48 : string; attribute use_dsp48 of coreTransform : entity is "yes"; ----turn off resource sharing ----with resource sharing off this will map to two dsp48s. With it on, a dsp48 and some logic. attribute resource_sharing : string; attribute resource_sharing of coreTransform : entity is "no"; end entity coreTransform; architecture aCT of coreTransform is signal xReg, xStepReg, uReg : std_logic_vector (DATA_WIDTH-1 downto 0); signal xOutReg, xOutStepReg, xOutRegTemp, xOutStepRegTemp: std_logic_vector (2DATA_WIDTH -1 downto 0); begin process (clk) begin if rising_edge(clk) then xStepReg <= xStep; uReg <= u; xReg <= x; end if; end process; process (clk) begin if rising_edge(clk) then xOutReg <= SXT(xReg, 2DATA_WIDTH) + uRegxStepReg; xOutStepReg <= SXT(xReg, 2DATA_WIDTH) - uRegxStepReg; end if; end process; -- xOut <= xOutReg(DATA_WIDTH-1 downto 0) xor xOutReg(2DATA_WIDTH-1 downto DATA_WIDTH); -- xOutStep <= xOutStepReg(DATA_WIDTH-1 downto 0) xor xOutStepReg(2DATA_WIDTH-1 downto DATA_WIDTH); xOut <= xOutReg(DATA_WIDTH-1 downto 0) xor xOutReg(2DATA_WIDTH-1 downto DATA_WIDTH); xOutStep <= xOutStepReg(DATA_WIDTH-1 downto 0) xor xOutStepReg(2*DATA_WIDTH-1 downto DATA_WIDTH); end architecture aCT;	gpl-2.0	930514b635ec052c7721e634aec449ab	0.650839	3.92585	false	false	false	false
marco-c/leon-nexys2	grlib-gpl-1.3.4-b4140/lib/gaisler/ddr/ddrphy_wrap.vhd	1	57,878	------------------------------------------------------------------------------ -- This file is a part of the GRLIB VHDL IP LIBRARY -- Copyright (C) 2003 - 2008, Gaisler Research -- Copyright (C) 2008 - 2013, Aeroflex Gaisler -- -- This program is free software; you can redistribute it and/or modify -- it under the terms of the GNU General Public License as published by -- the Free Software Foundation; either version 2 of the License, or -- (at your option) any later version. -- -- This program is distributed in the hope that it will be useful, -- but WITHOUT ANY WARRANTY; without even the implied warranty of -- MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the -- GNU General Public License for more details. -- -- You should have received a copy of the GNU General Public License -- along with this program; if not, write to the Free Software -- Foundation, Inc., 59 Temple Place, Suite 330, Boston, MA 02111-1307 USA ----------------------------------------------------------------------------- -- Entity: ddr_phy -- File: ddr_phy.vhd -- Author: Jiri Gaisler, Gaisler Research -- Description: Wrapper entities for techmap ddrphy/ddr2phy ------------------------------------------------------------------------------ library ieee; use ieee.std_logic_1164.all; library grlib; use grlib.stdlib.all; library techmap; use techmap.gencomp.all; library gaisler; use gaisler.ddrpkg.all; ------------------------------------------------------------------ -- DDR1 PHY wrapper ------------------------------------------------------- ------------------------------------------------------------------ entity ddrphy_wrap is generic (tech : integer := virtex2; MHz : integer := 100; rstdelay : integer := 200; dbits : integer := 16; clk_mul : integer := 2 ; clk_div : integer := 2; rskew : integer :=0; mobile : integer := 0; scantest : integer := 0; phyiconf : integer := 0); port ( rst : in std_ulogic; clk : in std_logic; -- input clock clkout : out std_ulogic; -- system clock clkoutret : in std_ulogic; clkread : out std_ulogic; -- read clock lock : out std_ulogic; -- DCM locked ddr_clk : out std_logic_vector(2 downto 0); ddr_clkb : out std_logic_vector(2 downto 0); ddr_clk_fb_out : out std_logic; ddr_clk_fb : in std_logic; ddr_cke : out std_logic_vector(1 downto 0); ddr_csb : out std_logic_vector(1 downto 0); ddr_web : out std_ulogic; -- ddr write enable ddr_rasb : out std_ulogic; -- ddr ras ddr_casb : out std_ulogic; -- ddr cas ddr_dm : out std_logic_vector (dbits/8-1 downto 0); -- ddr dm ddr_dqs : inout std_logic_vector (dbits/8-1 downto 0); -- ddr dqs ddr_ad : out std_logic_vector (13 downto 0); -- ddr address ddr_ba : out std_logic_vector (1 downto 0); -- ddr bank address ddr_dq : inout std_logic_vector (dbits-1 downto 0); -- ddr data sdi : out ddrctrl_in_type; sdo : in ddrctrl_out_type; testen : in std_ulogic; testrst : in std_ulogic; scanen : in std_ulogic; testoen : in std_ulogic); end; architecture rtl of ddrphy_wrap is begin ddr_phy0 : ddrphy generic map (tech => tech, MHz => MHz, rstdelay => rstdelay -- reduce 200 us start-up delay during simulation -- pragma translate_off / 200 -- pragma translate_on , dbits => dbits, clk_mul => clk_mul, clk_div => clk_div, rskew => rskew, mobile => mobile, scantest => scantest, phyiconf => phyiconf) port map ( rst, clk, clkout, clkoutret, clkread, lock, ddr_clk, ddr_clkb, ddr_clk_fb_out, ddr_clk_fb, ddr_cke, ddr_csb, ddr_web, ddr_rasb, ddr_casb, ddr_dm, ddr_dqs, ddr_ad, ddr_ba, ddr_dq, sdo.address(13 downto 0), sdo.ba(1 downto 0), sdi.data(dbits2-1 downto 0), sdo.data(dbits2-1 downto 0), sdo.dqm(dbits/4-1 downto 0), sdo.bdrive, sdo.bdrive, sdo.qdrive, sdo.rasn, sdo.casn, sdo.sdwen, sdo.sdcsn, sdo.sdcke, sdo.sdck(2 downto 0), sdo.moben, sdi.datavalid, testen, testrst, scanen, testoen); drvdata : if dbits < 64 generate sdi.data(127 downto dbits2) <= (others => '0'); end generate; sdi.cb <= (others => '0'); sdi.regrdata <= (others => '0'); end; library ieee; use ieee.std_logic_1164.all; library grlib; use grlib.stdlib.all; library techmap; use techmap.gencomp.all; library gaisler; use gaisler.ddrpkg.all; ------------------------------------------------------------------ -- DDR1 PHY with checkbits merged on data bus -------------------- ------------------------------------------------------------------ entity ddrphy_wrap_cbd is generic (tech : integer := virtex2; MHz : integer := 100; rstdelay : integer := 200; dbits : integer := 16; chkbits: integer := 0; padbits : integer := 0; clk_mul : integer := 2 ; clk_div : integer := 2; rskew : integer :=0; mobile : integer := 0; abits: integer := 14; nclk: integer := 3; ncs: integer := 2; scantest: integer := 0; phyiconf : integer := 0); port ( rst : in std_ulogic; clk : in std_logic; -- input clock clkout : out std_ulogic; -- system clock clkoutret : in std_ulogic; -- system clock return clkread : out std_ulogic; lock : out std_ulogic; -- DCM locked ddr_clk : out std_logic_vector(nclk-1 downto 0); ddr_clkb : out std_logic_vector(nclk-1 downto 0); ddr_clk_fb_out : out std_logic; ddr_clk_fb : in std_logic; ddr_cke : out std_logic_vector(ncs-1 downto 0); ddr_csb : out std_logic_vector(ncs-1 downto 0); ddr_web : out std_ulogic; -- ddr write enable ddr_rasb : out std_ulogic; -- ddr ras ddr_casb : out std_ulogic; -- ddr cas ddr_dm : out std_logic_vector ((dbits+padbits+chkbits)/8-1 downto 0); -- ddr dm ddr_dqs : inout std_logic_vector ((dbits+padbits+chkbits)/8-1 downto 0); -- ddr dqs ddr_ad : out std_logic_vector (abits-1 downto 0); -- ddr address ddr_ba : out std_logic_vector (1 downto 0); -- ddr bank address ddr_dq : inout std_logic_vector (dbits+padbits+chkbits-1 downto 0); -- ddr data sdi : out ddrctrl_in_type; sdo : in ddrctrl_out_type; testen : in std_ulogic; testrst : in std_ulogic; scanen : in std_ulogic; testoen : in std_ulogic); end; architecture rtl of ddrphy_wrap_cbd is function ddr_widthconv(x: std_logic_vector; ow: integer) return std_logic_vector is variable r: std_logic_vector(2ow-1 downto 0); constant iw: integer := x'length/2; begin r := (others => '0'); if iw <= ow then r(iw+ow-1 downto ow) := x(2iw-1 downto iw); r(iw-1 downto 0) := x(iw-1 downto 0); else r := x(iw+ow-1 downto iw) & x(ow-1 downto 0); end if; return r; end; function sdr_widthconv(x: std_logic_vector; ow: integer) return std_logic_vector is variable r: std_logic_vector(ow-1 downto 0); constant iw: integer := x'length; variable xd : std_logic_vector(iw-1 downto 0); begin r := (others => '0'); xd := x; if iw >= ow then r := xd(ow-1 downto 0); else r(iw-1 downto 0) := xd; end if; return r; end; function ddrmerge(a,b: std_logic_vector) return std_logic_vector is constant aw: integer := a'length/2; constant bw: integer := b'length/2; begin return a(2aw-1 downto aw) & b(2bw-1 downto bw) & a(aw-1 downto 0) & b(bw-1 downto 0); end; signal dqin: std_logic_vector(2(chkbits+dbits+padbits)-1 downto 0); signal dqout: std_logic_vector(2(chkbits+dbits+padbits)-1 downto 0); signal dqm: std_logic_vector((chkbits+dbits+padbits)/4-1 downto 0); signal cal_en: std_logic_vector((chkbits+dbits+padbits)/8-1 downto 0); signal cal_inc: std_logic_vector((chkbits+dbits+padbits)/8-1 downto 0); signal odt,csn,cke: std_logic_vector(ncs-1 downto 0); signal sdck: std_logic_vector(nclk-1 downto 0); begin -- Merge checkbit and data buses comb: process(sdo,dqin) variable dq: std_logic_vector(2dbits-1 downto 0); variable dqpad: std_logic_vector(2(dbits+padbits)-1 downto 0); variable cb: std_logic_vector(dbits-1 downto 0); variable cbpad: std_logic_vector(2chkbits downto 0); -- Extra bit to handle chkbits=0 variable dqcb: std_logic_vector(2(dbits+padbits+chkbits)-1 downto 0); variable dm: std_logic_vector(dbits/4-1 downto 0); variable dmpad: std_logic_vector((dbits+padbits)/4-1 downto 0); variable cbdm: std_logic_vector(dbits/8-1 downto 0); variable cbdmpad: std_logic_vector(chkbits/4 downto 0); variable dqcbdm: std_logic_vector((dbits+padbits+chkbits)/4-1 downto 0); variable vcsn,vcke: std_logic_vector(ncs-1 downto 0); variable vsdck: std_logic_vector(nclk-1 downto 0); begin dq := sdo.data(2dbits-1 downto 0); dqpad := ddr_widthconv(dq, dbits+padbits ); if chkbits > 0 then cb := sdo.cb(dbits-1 downto 0); cbpad := '0' & ddr_widthconv(cb, chkbits); dqcb := ddrmerge(cbpad(2chkbits-1 downto 0), dqpad); else dqcb := dqpad; end if; dqout <= dqcb; dqcb := dqin; if chkbits > 0 then cbpad := '0' & dqin(2(chkbits+dbits+padbits)-1 downto 2(dbits+padbits)+chkbits) & dqin(chkbits+dbits+padbits-1 downto dbits+padbits); cb := ddr_widthconv(cbpad(2chkbits-1 downto 0), dbits/2); else cb := (others => '0'); end if; dq := dqcb(2dbits+chkbits+padbits-1 downto dbits+chkbits+padbits) & dqcb(dbits-1 downto 0); sdi.cb(dbits-1 downto 0) <= cb; sdi.data(2dbits-1 downto 0) <= dq; if sdi.cb'length > dbits then sdi.cb(sdi.cb'length-1 downto dbits) <= (others => '0'); end if; if sdi.data'length > 2dbits then sdi.data(sdi.data'length-1 downto 2dbits) <= (others => '0'); end if; dm := sdo.dqm(dbits/4-1 downto 0); dmpad := ddr_widthconv(dm, (dbits+padbits)/8); if chkbits > 0 then cbdm := sdo.cbdqm(dbits/8-1 downto 0); cbdmpad := '0' & ddr_widthconv(cbdm(dbits/8-1 downto 0), chkbits/8); dqcbdm := ddrmerge(cbdmpad(chkbits/4-1 downto 0), dmpad); else dqcbdm := dmpad; end if; dqm <= dqcbdm; cal_en <= sdr_widthconv(sdo.cbcal_en (dbits/16-1 downto 0) & sdo.cal_en (dbits/8-1 downto 0), (dbits+padbits+chkbits)/8 ); cal_inc <= sdr_widthconv(sdo.cbcal_inc(dbits/16-1 downto 0) & sdo.cal_inc(dbits/8-1 downto 0), (dbits+padbits+chkbits)/8 ); vcsn := (others => '1'); for x in 0 to ncs-1 loop if x<2 then vcsn(x) := sdo.sdcsn(x); end if; vcke(x) := sdo.sdcke(x mod 2); end loop; for x in 0 to nclk-1 loop vsdck(x) := sdo.sdck(x mod 2); end loop; csn <= vcsn; cke <= vcke; sdck <= vsdck; end process; -- Phy instantiation ddr_phy0 : ddrphy generic map (tech => tech, MHz => MHz, rstdelay => rstdelay -- reduce 200 us start-up delay during simulation -- pragma translate_off / 200 -- pragma translate_on , dbits => dbits+padbits+chkbits,clk_mul => clk_mul, clk_div => clk_div, rskew => rskew, mobile => mobile, abits => abits, nclk => nclk, ncs => ncs, scantest => scantest, phyiconf => phyiconf) port map ( rst, clk, clkout, clkoutret, clkread, lock, ddr_clk, ddr_clkb, ddr_clk_fb_out, ddr_clk_fb, ddr_cke, ddr_csb, ddr_web, ddr_rasb, ddr_casb, ddr_dm, ddr_dqs, ddr_ad, ddr_ba, ddr_dq, sdo.address(abits-1 downto 0), sdo.ba(1 downto 0), dqin, dqout, dqm, sdo.bdrive, sdo.bdrive, sdo.qdrive, sdo.rasn, sdo.casn, sdo.sdwen, csn, cke, sdck, sdo.moben,sdi.datavalid, testen,testrst,scanen,testoen); sdi.regrdata <= (others => '0'); end; library ieee; use ieee.std_logic_1164.all; library grlib; use grlib.stdlib.all; library techmap; use techmap.gencomp.all; library gaisler; use gaisler.ddrpkg.all; ------------------------------------------------------------------ -- DDR1 PHY with checkbits merged on data bus, pads not in phy -- ------------------------------------------------------------------ entity ddrphy_wrap_cbd_wo_pads is generic (tech : integer := virtex2; MHz : integer := 100; rstdelay : integer := 200; dbits : integer := 16; padbits : integer := 0; clk_mul : integer := 2 ; clk_div : integer := 2; rskew : integer := 0; mobile : integer := 0; abits : integer := 14; nclk : integer := 3; ncs : integer := 2; chkbits : integer := 0; scantest : integer := 0; phyiconf : integer := 0); port ( rst : in std_ulogic; clk : in std_logic; -- input clock clkout : out std_ulogic; -- system clock clkoutret : in std_ulogic; -- system clock return lock : out std_ulogic; -- DCM locked ddr_clk : out std_logic_vector(nclk-1 downto 0); ddr_clkb : out std_logic_vector(nclk-1 downto 0); ddr_clk_fb_out : out std_logic; ddr_clk_fb : in std_logic; ddr_cke : out std_logic_vector(ncs-1 downto 0); ddr_csb : out std_logic_vector(ncs-1 downto 0); ddr_web : out std_ulogic; -- ddr write enable ddr_rasb : out std_ulogic; -- ddr ras ddr_casb : out std_ulogic; -- ddr cas ddr_dm : out std_logic_vector ((dbits+padbits+chkbits)/8-1 downto 0); -- ddr dm ddr_dqs_in : in std_logic_vector ((dbits+padbits+chkbits)/8-1 downto 0); -- ddr dqs ddr_dqs_out : out std_logic_vector ((dbits+padbits+chkbits)/8-1 downto 0); -- ddr dqs ddr_dqs_oen : out std_logic_vector ((dbits+padbits+chkbits)/8-1 downto 0); -- ddr dqs ddr_ad : out std_logic_vector (abits-1 downto 0); -- ddr address ddr_ba : out std_logic_vector (1 downto 0); -- ddr bank address ddr_dq_in : in std_logic_vector (dbits+padbits+chkbits-1 downto 0); -- ddr data ddr_dq_out : out std_logic_vector (dbits+padbits+chkbits-1 downto 0); -- ddr data ddr_dq_oen : out std_logic_vector (dbits+padbits+chkbits-1 downto 0); sdi : out ddrctrl_in_type; sdo : in ddrctrl_out_type; testen : in std_ulogic; testrst : in std_ulogic; scanen : in std_ulogic; testoen : in std_ulogic); end; architecture rtl of ddrphy_wrap_cbd_wo_pads is function ddr_widthconv(x: std_logic_vector; ow: integer) return std_logic_vector is variable r: std_logic_vector(2ow-1 downto 0); constant iw: integer := x'length/2; begin r := (others => '0'); if iw <= ow then r(iw+ow-1 downto ow) := x(2iw-1 downto iw); r(iw-1 downto 0) := x(iw-1 downto 0); else r := x(iw+ow-1 downto iw) & x(ow-1 downto 0); end if; return r; end; function sdr_widthconv(x: std_logic_vector; ow: integer) return std_logic_vector is variable r: std_logic_vector(ow-1 downto 0); constant iw: integer := x'length; variable xd : std_logic_vector(iw-1 downto 0); begin r := (others => '0'); xd := x; if iw >= ow then r := xd(ow-1 downto 0); else r(iw-1 downto 0) := xd; end if; return r; end; function ddrmerge(a,b: std_logic_vector) return std_logic_vector is constant aw: integer := a'length/2; constant bw: integer := b'length/2; begin return a(2aw-1 downto aw) & b(2bw-1 downto bw) & a(aw-1 downto 0) & b(bw-1 downto 0); end; signal dqin: std_logic_vector(2(chkbits+dbits+padbits)-1 downto 0); signal dqout: std_logic_vector(2(chkbits+dbits+padbits)-1 downto 0); signal dqm: std_logic_vector((chkbits+dbits+padbits)/4-1 downto 0); signal odt,csn,cke: std_logic_vector(ncs-1 downto 0); signal sdck: std_logic_vector(nclk-1 downto 0); signal gnd : std_logic_vector(chkbits2-1 downto 0); begin gnd <= (others => '0'); -- Merge checkbit and data buses comb: process(sdo,dqin) variable dq: std_logic_vector(2dbits-1 downto 0); variable dqpad: std_logic_vector(2(dbits+padbits)-1 downto 0); variable cb: std_logic_vector(dbits-1 downto 0); variable cbpad: std_logic_vector(2chkbits downto 0); -- Extra bit to handle chkbits=0 variable dqcb: std_logic_vector(2(dbits+padbits+chkbits)-1 downto 0); variable dm: std_logic_vector(dbits/4-1 downto 0); variable dmpad: std_logic_vector((dbits+padbits)/4-1 downto 0); variable cbdm: std_logic_vector(dbits/8-1 downto 0); variable cbdmpad: std_logic_vector(chkbits/4 downto 0); variable dqcbdm: std_logic_vector((dbits+padbits+chkbits)/4-1 downto 0); variable vcsn,vodt,vcke: std_logic_vector(ncs-1 downto 0); variable vsdck: std_logic_vector(nclk-1 downto 0); begin dq := sdo.data(2dbits-1 downto 0); dqpad := ddr_widthconv(dq, dbits+padbits ); if chkbits > 0 then cb := sdo.cb(dbits-1 downto 0); cbpad := '0' & ddr_widthconv(cb, chkbits); dqcb := ddrmerge(cbpad(2chkbits-1 downto 0), dqpad); else dqcb := dqpad; end if; dqout <= dqcb; dqcb := dqin; if chkbits > 0 then cbpad := '0' & dqin(2(chkbits+dbits+padbits)-1 downto 2(dbits+padbits)+chkbits) & dqin(chkbits+dbits+padbits-1 downto dbits+padbits); cb := ddr_widthconv(cbpad(2chkbits-1 downto 0), dbits/2); else cb := (others => '0'); end if; dq := dqcb(2dbits+chkbits+padbits-1 downto dbits+chkbits+padbits) & dqcb(dbits-1 downto 0); sdi.cb(dbits-1 downto 0) <= cb; sdi.data(2dbits-1 downto 0) <= dq; if sdi.cb'length > dbits then sdi.cb(sdi.cb'length-1 downto dbits) <= (others => '0'); end if; if sdi.data'length > 2dbits then sdi.data(sdi.data'length-1 downto 2dbits) <= (others => '0'); end if; dm := sdo.dqm(dbits/4-1 downto 0); dmpad := ddr_widthconv(dm, (dbits+padbits)/8); if chkbits > 0 then cbdm := sdo.cbdqm(dbits/8-1 downto 0); cbdmpad := '0' & ddr_widthconv(cbdm(dbits/8-1 downto 0), chkbits/8); dqcbdm := ddrmerge(cbdmpad(chkbits/4-1 downto 0), dmpad); else dqcbdm := dmpad; end if; dqm <= dqcbdm; vcsn := (others => '1'); for x in 0 to ncs-1 loop if x<2 then vcsn(x) := sdo.sdcsn(x); end if; vodt(x) := sdo.odt(x mod 2); vcke(x) := sdo.sdcke(x mod 2); end loop; for x in 0 to nclk-1 loop vsdck(x) := sdo.sdck(x mod 2); end loop; csn <= vcsn; cke <= vcke; sdck <= vsdck; end process; -- Phy instantiation ddr_phy0 : ddrphy_wo_pads generic map ( tech => tech, MHz => MHz, rstdelay => rstdelay -- reduce 200 us start-up delay during simulation -- pragma translate_off / 200 -- pragma translate_on , dbits => dbits+padbits+chkbits, clk_mul => clk_mul, clk_div => clk_div, rskew => rskew, abits => abits, nclk => nclk, ncs => ncs, mobile => mobile, scantest => scantest, phyiconf => phyiconf) port map ( rst => rst, clk => clk, clkout => clkout, clkoutret => clkoutret, lock => lock, ddr_clk => ddr_clk, ddr_clkb => ddr_clkb, ddr_clk_fb_out => ddr_clk_fb_out, ddr_clk_fb => ddr_clk_fb, ddr_cke => ddr_cke, ddr_csb => ddr_csb, ddr_web => ddr_web, ddr_rasb => ddr_rasb, ddr_casb => ddr_casb, ddr_dm => ddr_dm, ddr_dqs_in => ddr_dqs_in, ddr_dqs_out => ddr_dqs_out, ddr_dqs_oen => ddr_dqs_oen, ddr_ad => ddr_ad, ddr_ba => ddr_ba, ddr_dq_in => ddr_dq_in, ddr_dq_out => ddr_dq_out, ddr_dq_oen => ddr_dq_oen, addr => sdo.address(abits-1 downto 0), ba => sdo.ba(1 downto 0), dqin => dqin, dqout => dqout, dm => dqm, oen => sdo.bdrive, dqs => sdo.bdrive, dqsoen => sdo.qdrive, rasn => sdo.rasn, casn => sdo.casn, wen => sdo.sdwen, csn => csn, cke => cke, ck => sdck, moben => sdo.moben, dqvalid => sdi.datavalid, testen => testen, testrst => testrst, scanen => scanen, testoen => testoen ); sdi.regrdata <= (others => '0'); end; library ieee; use ieee.std_logic_1164.all; library grlib; use grlib.stdlib.all; library techmap; use techmap.gencomp.all; library gaisler; use gaisler.ddrpkg.all; ------------------------------------------------------------------ -- DDR2 PHY wrapper ----------------------------------------------- ------------------------------------------------------------------ ------------------------------------------------------------------------------- -- There are three variants of the PHY wrapper depending on pads/checkbits: -- 1. ddr2phy_wrap: -- This provides pads and outputs checkbits on separate vectors -- 2. ddr2phy_wrap_cbd: -- This provides pads and merges checkbits+data on same vector -- 3. ddr2phy_wrap_cbd_wo_pads: -- This does not provide pads and merges checkbits+data on same vectors -- -- Variants (1),(3) can not be used when ddr2phy_builtin_pads(tech)=1 ------------------------------------------------------------------------------- entity ddr2phy_wrap is generic (tech : integer := virtex2; MHz : integer := 100; rstdelay : integer := 200; dbits : integer := 16; padbits : integer := 0; clk_mul : integer := 2 ; clk_div : integer := 2; ddelayb0 : integer := 0; ddelayb1 : integer := 0; ddelayb2 : integer := 0; ddelayb3 : integer := 0; ddelayb4 : integer := 0; ddelayb5 : integer := 0; ddelayb6 : integer := 0; ddelayb7 : integer := 0; cbdelayb0 : integer := 0; cbdelayb1: integer := 0; cbdelayb2: integer := 0; cbdelayb3 : integer := 0; numidelctrl : integer := 4; norefclk : integer := 0; odten : integer := 0; rskew : integer := 0; eightbanks : integer range 0 to 1 := 0; dqsse : integer range 0 to 1 := 0; abits : integer := 14; nclk : integer := 3; ncs : integer := 2; cben : integer := 0; chkbits : integer := 8; ctrl2en : integer := 0; resync : integer := 0; custombits: integer := 8; scantest : integer := 0); port ( rst : in std_ulogic; clk : in std_logic; -- input clock clkref200 : in std_logic; -- input 200MHz clock clkout : out std_ulogic; -- system clock clkoutret : in std_ulogic; -- system clock return clkresync : in std_ulogic; -- resync clock (if resync/=0) lock : out std_ulogic; -- DCM locked ddr_clk : out std_logic_vector(nclk-1 downto 0); ddr_clkb : out std_logic_vector(nclk-1 downto 0); ddr_clk_fb_out : out std_logic; ddr_clk_fb : in std_logic; ddr_cke : out std_logic_vector(ncs-1 downto 0); ddr_csb : out std_logic_vector(ncs-1 downto 0); ddr_web : out std_ulogic; -- ddr write enable ddr_rasb : out std_ulogic; -- ddr ras ddr_casb : out std_ulogic; -- ddr cas ddr_dm : out std_logic_vector ((dbits+padbits)/8-1 downto 0); -- ddr dm ddr_dqs : inout std_logic_vector ((dbits+padbits)/8-1 downto 0); -- ddr dqs ddr_dqsn : inout std_logic_vector ((dbits+padbits)/8-1 downto 0); -- ddr dqs ddr_ad : out std_logic_vector (abits-1 downto 0); -- ddr address ddr_ba : out std_logic_vector (1+eightbanks downto 0); -- ddr bank address ddr_dq : inout std_logic_vector ((dbits+padbits)-1 downto 0); -- ddr data ddr_odt : out std_logic_vector(ncs-1 downto 0); ddr_cbdm : out std_logic_vector(chkbits/8-1 downto 0); ddr_cbdqs : inout std_logic_vector(chkbits/8-1 downto 0); ddr_cbdqsn : inout std_logic_vector(chkbits/8-1 downto 0); ddr_cbdq : inout std_logic_vector(chkbits-1 downto 0); ddr_web2 : out std_ulogic; -- ddr write enable ddr_rasb2 : out std_ulogic; -- ddr ras ddr_casb2 : out std_ulogic; -- ddr cas ddr_ad2 : out std_logic_vector (abits-1 downto 0); -- ddr address ddr_ba2 : out std_logic_vector (1+eightbanks downto 0); -- ddr bank address sdi : out ddrctrl_in_type; sdo : in ddrctrl_out_type; customclk : in std_ulogic; customdin : in std_logic_vector(custombits-1 downto 0); customdout : out std_logic_vector(custombits-1 downto 0); testen : in std_ulogic; testrst : in std_ulogic; scanen : in std_ulogic; testoen : in std_ulogic ); end; architecture rtl of ddr2phy_wrap is signal lddr_clk,lddr_clkb: std_logic_vector(nclk-1 downto 0); signal lddr_clk_fb_out,lddr_clk_fb: std_ulogic; signal lddr_cke,lddr_csb,lddr_odt: std_logic_vector(ncs-1 downto 0); signal lddr_web,lddr_rasb,lddr_casb: std_ulogic; signal lddr_dm,lddr_dqs_in,lddr_dqs_out,lddr_dqs_oen: std_logic_vector((dbits+padbits+chkbits)/8-1 downto 0); signal lddr_ad: std_logic_vector(abits-1 downto 0); signal lddr_ba: std_logic_vector(1+eightbanks downto 0); signal lddr_dq_in,lddr_dq_out,lddr_dq_oen: std_logic_vector(dbits+padbits+chkbits-1 downto 0); begin -- Instantiate PHY without pads via other wrapper w0: ddr2phy_wrap_cbd_wo_pads generic map (tech,MHz,rstdelay,dbits,padbits,clk_mul,clk_div, ddelayb0,ddelayb1,ddelayb2,ddelayb3,ddelayb4,ddelayb5,ddelayb6,ddelayb7, cbdelayb0,cbdelayb1,cbdelayb2,cbdelayb3, numidelctrl,norefclk,odten,rskew, eightbanks,dqsse,abits,nclk,ncs,chkbits,resync,custombits,scantest) port map ( rst,clk,clkref200,clkout,clkoutret,clkresync,lock, lddr_clk,lddr_clkb,lddr_clk_fb_out,lddr_clk_fb, lddr_cke,lddr_csb,lddr_web,lddr_rasb,lddr_casb,lddr_dm, lddr_dqs_in,lddr_dqs_out,lddr_dqs_oen, lddr_ad,lddr_ba,lddr_dq_in,lddr_dq_out,lddr_dq_oen, lddr_odt, sdi,sdo,customclk,customdin,customdout,testen,testrst,scanen,testoen); -- Instantiate pads for control signals and data bus p0: ddr2pads generic map (tech,dbits+padbits,eightbanks,dqsse,abits,nclk,ncs,ctrl2en) port map ( ddr_clk,ddr_clkb,ddr_clk_fb_out,ddr_clk_fb, ddr_cke,ddr_csb,ddr_web,ddr_rasb,ddr_casb, ddr_dm,ddr_dqs,ddr_dqsn,ddr_ad,ddr_ba,ddr_dq,ddr_odt, ddr_web2,ddr_rasb2,ddr_casb2,ddr_ad2,ddr_ba2, lddr_clk,lddr_clkb,lddr_clk_fb_out,lddr_clk_fb, lddr_cke,lddr_csb,lddr_web,lddr_rasb,lddr_casb, lddr_dm(dbits/8+padbits/8-1 downto 0), lddr_dqs_in(dbits/8+padbits/8-1 downto 0), lddr_dqs_out(dbits/8+padbits/8-1 downto 0), lddr_dqs_oen(dbits/8+padbits/8-1 downto 0), lddr_ad,lddr_ba, lddr_dq_in(dbits+padbits-1 downto 0), lddr_dq_out(dbits+padbits-1 downto 0), lddr_dq_oen(dbits+padbits-1 downto 0), lddr_odt); -- Instantiate pads for checkbit bus cbdqpad: iopadvv generic map (tech => tech, slew => 1, level => sstl18_ii, width => chkbits) port map (pad => ddr_cbdq, i => lddr_dq_out(dbits+padbits+chkbits-1 downto dbits+padbits), en => lddr_dq_oen(dbits+padbits+chkbits-1 downto dbits+padbits), o => lddr_dq_in(dbits+padbits+chkbits-1 downto dbits+padbits)); cbdqmpad: outpadv generic map (tech => tech, slew => 1, level => sstl18_i, width => chkbits/8) port map (pad => ddr_cbdm, i => lddr_dm(dbits/8+padbits/8+chkbits/8-1 downto dbits/8+padbits/8)); cbdqspad: iopad_dsvv generic map (tech => tech, slew => 1, level => sstl18_ii, width => chkbits/8) port map (padp => ddr_cbdqs, padn => ddr_cbdqsn, i => lddr_dqs_out(dbits/8+padbits/8+chkbits/8-1 downto dbits/8+padbits/8), en => lddr_dqs_oen(dbits/8+padbits/8+chkbits/8-1 downto dbits/8+padbits/8), o => lddr_dqs_in(dbits/8+padbits/8+chkbits/8-1 downto dbits/8+padbits/8)); end; library ieee; use ieee.std_logic_1164.all; library grlib; use grlib.stdlib.all; library techmap; use techmap.gencomp.all; library gaisler; use gaisler.ddrpkg.all; ------------------------------------------------------------------ -- DDR2 PHY with checkbits merged on data bus -------------------- ------------------------------------------------------------------ entity ddr2phy_wrap_cbd is generic (tech : integer := virtex2; MHz : integer := 100; rstdelay : integer := 200; dbits : integer := 16; padbits : integer := 0; clk_mul : integer := 2 ; clk_div : integer := 2; ddelayb0 : integer := 0; ddelayb1 : integer := 0; ddelayb2 : integer := 0; ddelayb3 : integer := 0; ddelayb4 : integer := 0; ddelayb5 : integer := 0; ddelayb6 : integer := 0; ddelayb7 : integer := 0; cbdelayb0 : integer := 0; cbdelayb1: integer := 0; cbdelayb2: integer := 0; cbdelayb3 : integer := 0; numidelctrl : integer := 4; norefclk : integer := 0; odten : integer := 0; rskew : integer := 0; eightbanks : integer range 0 to 1 := 0; dqsse : integer range 0 to 1 := 0; abits : integer := 14; nclk : integer := 3; ncs : integer := 2; chkbits : integer := 0; ctrl2en : integer := 0; resync : integer := 0; custombits: integer := 8; extraio : integer := 0; scantest : integer := 0); port ( rst : in std_ulogic; clk : in std_logic; -- input clock clkref200 : in std_logic; -- input 200MHz clock clkout : out std_ulogic; -- system clock clkoutret : in std_ulogic; -- system clock return clkresync : in std_ulogic; lock : out std_ulogic; -- DCM locked ddr_clk : out std_logic_vector(nclk-1 downto 0); ddr_clkb : out std_logic_vector(nclk-1 downto 0); ddr_clk_fb_out : out std_logic; ddr_clk_fb : in std_logic; ddr_cke : out std_logic_vector(ncs-1 downto 0); ddr_csb : out std_logic_vector(ncs-1 downto 0); ddr_web : out std_ulogic; -- ddr write enable ddr_rasb : out std_ulogic; -- ddr ras ddr_casb : out std_ulogic; -- ddr cas ddr_dm : out std_logic_vector ((dbits+padbits+chkbits)/8-1 downto 0); -- ddr dm ddr_dqs : inout std_logic_vector (extraio+(dbits+padbits+chkbits)/8-1 downto 0); -- ddr dqs ddr_dqsn : inout std_logic_vector ((dbits+padbits+chkbits)/8-1 downto 0); -- ddr dqs ddr_ad : out std_logic_vector (abits-1 downto 0); -- ddr address ddr_ba : out std_logic_vector (1+eightbanks downto 0); -- ddr bank address ddr_dq : inout std_logic_vector (dbits+padbits+chkbits-1 downto 0); -- ddr data ddr_odt : out std_logic_vector(ncs-1 downto 0); ddr_web2 : out std_ulogic; -- ddr write enable ddr_rasb2 : out std_ulogic; -- ddr ras ddr_casb2 : out std_ulogic; -- ddr cas ddr_ad2 : out std_logic_vector (abits-1 downto 0); -- ddr address ddr_ba2 : out std_logic_vector (1+eightbanks downto 0); -- ddr bank address sdi : out ddrctrl_in_type; sdo : in ddrctrl_out_type; customclk : in std_ulogic; customdin : in std_logic_vector(custombits-1 downto 0); customdout : out std_logic_vector(custombits-1 downto 0); testen : in std_ulogic; testrst : in std_ulogic; scanen : in std_ulogic; testoen : in std_ulogic); end; architecture rtl of ddr2phy_wrap_cbd is function ddr_widthconv(x: std_logic_vector; ow: integer) return std_logic_vector is variable r: std_logic_vector(2ow-1 downto 0); constant iw: integer := x'length/2; begin r := (others => '0'); if iw <= ow then r(iw+ow-1 downto ow) := x(2iw-1 downto iw); r(iw-1 downto 0) := x(iw-1 downto 0); else r := x(iw+ow-1 downto iw) & x(ow-1 downto 0); end if; return r; end; function sdr_widthconv(x: std_logic_vector; ow: integer) return std_logic_vector is variable r: std_logic_vector(ow-1 downto 0); constant iw: integer := x'length; variable xd : std_logic_vector(iw-1 downto 0); begin r := (others => '0'); xd := x; if iw >= ow then r := xd(ow-1 downto 0); else r(iw-1 downto 0) := xd; end if; return r; end; function ddrmerge(a,b: std_logic_vector) return std_logic_vector is constant aw: integer := a'length/2; constant bw: integer := b'length/2; begin return a(2aw-1 downto aw) & b(2bw-1 downto bw) & a(aw-1 downto 0) & b(bw-1 downto 0); end; type int_array is array (natural range <>) of integer; constant delays: int_array(0 to 7) := (ddelayb0,ddelayb1,ddelayb2,ddelayb3, ddelayb4,ddelayb5,ddelayb6,ddelayb7); constant cbdelays: int_array(0 to 11) := (cbdelayb0,cbdelayb1,cbdelayb2,cbdelayb3,0,0,0,0,0,0,0,0); constant cbddelays: int_array(0 to 11) := delays(0 to (dbits+padbits)/8-1) & cbdelays(0 to 11-(dbits+padbits)/8); signal dqin: std_logic_vector(2(chkbits+dbits+padbits)-1 downto 0); signal dqout: std_logic_vector(2(chkbits+dbits+padbits)-1 downto 0); signal dqm: std_logic_vector((chkbits+dbits+padbits)/4-1 downto 0); signal cal_en: std_logic_vector((chkbits+dbits+padbits)/8-1 downto 0); signal cal_inc: std_logic_vector((chkbits+dbits+padbits)/8-1 downto 0); signal odt,csn,cke: std_logic_vector(ncs-1 downto 0); begin -- Merge checkbit and data buses comb: process(sdo,dqin) variable dq: std_logic_vector(2dbits-1 downto 0); variable dqpad: std_logic_vector(2(dbits+padbits)-1 downto 0); variable cb: std_logic_vector(dbits-1 downto 0); variable cbpad: std_logic_vector(2chkbits downto 0); -- Extra bit to handle chkbits=0 variable dqcb: std_logic_vector(2(dbits+padbits+chkbits)-1 downto 0); variable dm: std_logic_vector(dbits/4-1 downto 0); variable dmpad: std_logic_vector((dbits+padbits)/4-1 downto 0); variable cbdm: std_logic_vector(dbits/8-1 downto 0); variable cbdmpad: std_logic_vector(chkbits/4 downto 0); variable dqcbdm: std_logic_vector((dbits+padbits+chkbits)/4-1 downto 0); variable vcsn,vodt,vcke: std_logic_vector(ncs-1 downto 0); begin dq := sdo.data(2dbits-1 downto 0); dqpad := ddr_widthconv(dq, dbits+padbits ); if chkbits > 0 then cb := sdo.cb(dbits-1 downto 0); cbpad := '0' & ddr_widthconv(cb, chkbits); dqcb := ddrmerge(cbpad(2chkbits-1 downto 0), dqpad); else dqcb := dqpad; end if; dqout <= dqcb; dqcb := dqin; if chkbits > 0 then cbpad := '0' & dqin(2(chkbits+dbits+padbits)-1 downto 2(dbits+padbits)+chkbits) & dqin(chkbits+dbits+padbits-1 downto dbits+padbits); cb := ddr_widthconv(cbpad(2chkbits-1 downto 0), dbits/2); else cb := (others => '0'); end if; dq := dqcb(2dbits+chkbits+padbits-1 downto dbits+chkbits+padbits) & dqcb(dbits-1 downto 0); sdi.cb(dbits-1 downto 0) <= cb; sdi.data(2dbits-1 downto 0) <= dq; if sdi.cb'length > dbits then sdi.cb(sdi.cb'length-1 downto dbits) <= (others => '0'); end if; if sdi.data'length > 2dbits then sdi.data(sdi.data'length-1 downto 2dbits) <= (others => '0'); end if; dm := sdo.dqm(dbits/4-1 downto 0); dmpad := ddr_widthconv(dm, (dbits+padbits)/8); if chkbits > 0 then cbdm := sdo.cbdqm(dbits/8-1 downto 0); cbdmpad := '0' & ddr_widthconv(cbdm(dbits/8-1 downto 0), chkbits/8); dqcbdm := ddrmerge(cbdmpad(chkbits/4-1 downto 0), dmpad); else dqcbdm := dmpad; end if; dqm <= dqcbdm; cal_en <= sdr_widthconv(sdo.cbcal_en (dbits/16-1 downto 0) & sdo.cal_en (dbits/8-1 downto 0), (dbits+padbits+chkbits)/8 ); cal_inc <= sdr_widthconv(sdo.cbcal_inc(dbits/16-1 downto 0) & sdo.cal_inc(dbits/8-1 downto 0), (dbits+padbits+chkbits)/8 ); vcsn := (others => '1'); for x in 0 to ncs-1 loop if x<2 then vcsn(x) := sdo.sdcsn(x); end if; vodt(x) := sdo.odt(x mod 2); vcke(x) := sdo.sdcke(x mod 2); end loop; csn <= vcsn; odt <= vodt; cke <= vcke; end process; -- Phy instantiation ddr_phy0 : ddr2phy generic map (tech => tech, MHz => MHz, rstdelay => rstdelay -- reduce 200 us start-up delay during simulation -- pragma translate_off / 200 -- pragma translate_on , dbits => dbits+padbits+chkbits,clk_mul => clk_mul, clk_div => clk_div, ddelayb0 => cbddelays(0), ddelayb1 => cbddelays(1), ddelayb2 => cbddelays(2), ddelayb3 => cbddelays(3), ddelayb4 => cbddelays(4), ddelayb5 => cbddelays(5), ddelayb6 => cbddelays(6), ddelayb7 => cbddelays(7), ddelayb8 => cbddelays(8), ddelayb9 => cbddelays(9), ddelayb10 => cbddelays(10), ddelayb11 => cbddelays(11), numidelctrl => numidelctrl, norefclk => norefclk, rskew => rskew, eightbanks => eightbanks, dqsse => dqsse, abits => abits, nclk => nclk, ncs => ncs, ctrl2en => ctrl2en, resync => resync, custombits => custombits, extraio => extraio, scantest => scantest) port map ( rst, clk, clkref200, clkout, clkoutret, clkresync, lock, ddr_clk, ddr_clkb, ddr_clk_fb_out, ddr_clk_fb, ddr_cke, ddr_csb, ddr_web, ddr_rasb, ddr_casb, ddr_dm, ddr_dqs, ddr_dqsn, ddr_ad, ddr_ba, ddr_dq, ddr_odt, sdo.address(abits-1 downto 0), sdo.ba, dqin, dqout, dqm, sdo.bdrive, sdo.nbdrive, sdo.bdrive, sdo.qdrive, sdo.rasn, sdo.casn, sdo.sdwen, csn, cke, cal_en, cal_inc, sdo.cal_pll, sdo.cal_rst, odt, sdo.oct, sdo.read_pend, sdo.regwdata, sdo.regwrite, sdi.regrdata, sdi.datavalid, customclk, customdin, customdout, ddr_web2, ddr_rasb2, ddr_casb2, ddr_ad2, ddr_ba2, testen, testrst, scanen, testoen ); end; library ieee; use ieee.std_logic_1164.all; library grlib; use grlib.stdlib.all; library techmap; use techmap.gencomp.all; library gaisler; use gaisler.ddrpkg.all; ------------------------------------------------------------------ -- DDR2 PHY with checkbits merged on data bus, pads not in phy -- ------------------------------------------------------------------ entity ddr2phy_wrap_cbd_wo_pads is generic (tech : integer := virtex2; MHz : integer := 100; rstdelay : integer := 200; dbits : integer := 16; padbits : integer := 0; clk_mul : integer := 2 ; clk_div : integer := 2; ddelayb0 : integer := 0; ddelayb1 : integer := 0; ddelayb2 : integer := 0; ddelayb3 : integer := 0; ddelayb4 : integer := 0; ddelayb5 : integer := 0; ddelayb6 : integer := 0; ddelayb7 : integer := 0; cbdelayb0 : integer := 0; cbdelayb1: integer := 0; cbdelayb2: integer := 0; cbdelayb3 : integer := 0; numidelctrl : integer := 4; norefclk : integer := 0; odten : integer := 0; rskew : integer := 0; eightbanks : integer range 0 to 1 := 0; dqsse : integer range 0 to 1 := 0; abits : integer := 14; nclk : integer := 3; ncs : integer := 2; chkbits : integer := 0; resync : integer := 0; custombits: integer := 8; scantest : integer := 0); port ( rst : in std_ulogic; clk : in std_logic; -- input clock clkref200 : in std_logic; -- input 200MHz clock clkout : out std_ulogic; -- system clock clkoutret : in std_ulogic; -- system clock return clkresync : in std_ulogic; lock : out std_ulogic; -- DCM locked ddr_clk : out std_logic_vector(nclk-1 downto 0); ddr_clkb : out std_logic_vector(nclk-1 downto 0); ddr_clk_fb_out : out std_logic; ddr_clk_fb : in std_logic; ddr_cke : out std_logic_vector(ncs-1 downto 0); ddr_csb : out std_logic_vector(ncs-1 downto 0); ddr_web : out std_ulogic; -- ddr write enable ddr_rasb : out std_ulogic; -- ddr ras ddr_casb : out std_ulogic; -- ddr cas ddr_dm : out std_logic_vector ((dbits+padbits+chkbits)/8-1 downto 0); -- ddr dm ddr_dqs_in : in std_logic_vector ((dbits+padbits+chkbits)/8-1 downto 0); -- ddr dqs ddr_dqs_out : out std_logic_vector ((dbits+padbits+chkbits)/8-1 downto 0); -- ddr dqs ddr_dqs_oen : out std_logic_vector ((dbits+padbits+chkbits)/8-1 downto 0); -- ddr dqs ddr_ad : out std_logic_vector (abits-1 downto 0); -- ddr address ddr_ba : out std_logic_vector (1+eightbanks downto 0); -- ddr bank address ddr_dq_in : in std_logic_vector (dbits+padbits+chkbits-1 downto 0); -- ddr data ddr_dq_out : out std_logic_vector (dbits+padbits+chkbits-1 downto 0); -- ddr data ddr_dq_oen : out std_logic_vector (dbits+padbits+chkbits-1 downto 0); -- ddr data ddr_odt : out std_logic_vector(ncs-1 downto 0); sdi : out ddrctrl_in_type; sdo : in ddrctrl_out_type; customclk : in std_ulogic; customdin : in std_logic_vector(custombits-1 downto 0); customdout : out std_logic_vector(custombits-1 downto 0); testen : in std_ulogic; testrst : in std_ulogic; scanen : in std_ulogic; testoen : in std_ulogic); end; architecture rtl of ddr2phy_wrap_cbd_wo_pads is function ddr_widthconv(x: std_logic_vector; ow: integer) return std_logic_vector is variable r: std_logic_vector(2ow-1 downto 0); constant iw: integer := x'length/2; begin r := (others => '0'); if iw <= ow then r(iw+ow-1 downto ow) := x(2iw-1 downto iw); r(iw-1 downto 0) := x(iw-1 downto 0); else r := x(iw+ow-1 downto iw) & x(ow-1 downto 0); end if; return r; end; function sdr_widthconv(x: std_logic_vector; ow: integer) return std_logic_vector is variable r: std_logic_vector(ow-1 downto 0); constant iw: integer := x'length; variable xd : std_logic_vector(iw-1 downto 0); begin r := (others => '0'); xd := x; if iw >= ow then r := xd(ow-1 downto 0); else r(iw-1 downto 0) := xd; end if; return r; end; function ddrmerge(a,b: std_logic_vector) return std_logic_vector is constant aw: integer := a'length/2; constant bw: integer := b'length/2; begin return a(2aw-1 downto aw) & b(2bw-1 downto bw) & a(aw-1 downto 0) & b(bw-1 downto 0); end; type int_array is array (natural range <>) of integer; constant delays: int_array(0 to 7) := (ddelayb0,ddelayb1,ddelayb2,ddelayb3, ddelayb4,ddelayb5,ddelayb6,ddelayb7); constant cbdelays: int_array(0 to 11) := (cbdelayb0,cbdelayb1,cbdelayb2,cbdelayb3,0,0,0,0,0,0,0,0); constant cbddelays: int_array(0 to 11) := delays(0 to (dbits+padbits)/8-1) & cbdelays(0 to 11-(dbits+padbits)/8); signal dqin: std_logic_vector(2(chkbits+dbits+padbits)-1 downto 0); signal dqout: std_logic_vector(2(chkbits+dbits+padbits)-1 downto 0); signal dqm: std_logic_vector((chkbits+dbits+padbits)/4-1 downto 0); signal cal_en: std_logic_vector((chkbits+dbits+padbits)/8-1 downto 0); signal cal_inc: std_logic_vector((chkbits+dbits+padbits)/8-1 downto 0); signal odt,csn,cke: std_logic_vector(ncs-1 downto 0); signal gnd : std_logic_vector(chkbits2-1 downto 0); begin gnd <= (others => '0'); -- Merge checkbit and data buses comb: process(sdo,dqin) variable dq: std_logic_vector(2dbits-1 downto 0); variable dqpad: std_logic_vector(2(dbits+padbits)-1 downto 0); variable cb: std_logic_vector(dbits-1 downto 0); variable cbpad: std_logic_vector(2chkbits downto 0); -- Extra bit to handle chkbits=0 variable dqcb: std_logic_vector(2(dbits+padbits+chkbits)-1 downto 0); variable dm: std_logic_vector(dbits/4-1 downto 0); variable dmpad: std_logic_vector((dbits+padbits)/4-1 downto 0); variable cbdm: std_logic_vector(dbits/8-1 downto 0); variable cbdmpad: std_logic_vector(chkbits/4 downto 0); variable dqcbdm: std_logic_vector((dbits+padbits+chkbits)/4-1 downto 0); variable vcsn,vodt,vcke: std_logic_vector(ncs-1 downto 0); begin dq := sdo.data(2dbits-1 downto 0); dqpad := ddr_widthconv(dq, dbits+padbits ); if chkbits > 0 then cb := sdo.cb(dbits-1 downto 0); cbpad := '0' & ddr_widthconv(cb, chkbits); dqcb := ddrmerge(cbpad(2chkbits-1 downto 0), dqpad); else dqcb := dqpad; end if; dqout <= dqcb; dqcb := dqin; if chkbits > 0 then cbpad := '0' & dqin(2(chkbits+dbits+padbits)-1 downto 2(dbits+padbits)+chkbits) & dqin(chkbits+dbits+padbits-1 downto dbits+padbits); cb := ddr_widthconv(cbpad(2chkbits-1 downto 0), dbits/2); else cb := (others => '0'); end if; dq := dqcb(2dbits+chkbits+padbits-1 downto dbits+chkbits+padbits) & dqcb(dbits-1 downto 0); sdi.cb(dbits-1 downto 0) <= cb; sdi.data(2dbits-1 downto 0) <= dq; if sdi.cb'length > dbits then sdi.cb(sdi.cb'length-1 downto dbits) <= (others => '0'); end if; if sdi.data'length > 2dbits then sdi.data(sdi.data'length-1 downto 2dbits) <= (others => '0'); end if; dm := sdo.dqm(dbits/4-1 downto 0); dmpad := ddr_widthconv(dm, (dbits+padbits)/8); if chkbits > 0 then cbdm := sdo.cbdqm(dbits/8-1 downto 0); cbdmpad := '0' & ddr_widthconv(cbdm(dbits/8-1 downto 0), chkbits/8); dqcbdm := ddrmerge(cbdmpad(chkbits/4-1 downto 0), dmpad); else dqcbdm := dmpad; end if; dqm <= dqcbdm; cal_en <= sdr_widthconv(sdo.cbcal_en (dbits/16-1 downto 0) & sdo.cal_en (dbits/8-1 downto 0), (dbits+padbits+chkbits)/8 ); cal_inc <= sdr_widthconv(sdo.cbcal_inc(dbits/16-1 downto 0) & sdo.cal_inc(dbits/8-1 downto 0), (dbits+padbits+chkbits)/8 ); vcsn := (others => '1'); for x in 0 to ncs-1 loop if x<2 then vcsn(x) := sdo.sdcsn(x); end if; vodt(x) := sdo.odt(x mod 2); vcke(x) := sdo.sdcke(x mod 2); end loop; csn <= vcsn; odt <= vodt; cke <= vcke; end process; -- Phy instantiation ddr_phy0 : ddr2phy_wo_pads generic map (tech => tech, MHz => MHz, rstdelay => rstdelay -- reduce 200 us start-up delay during simulation -- pragma translate_off / 200 -- pragma translate_on , dbits => dbits+padbits+chkbits,clk_mul => clk_mul, clk_div => clk_div, ddelayb0 => cbddelays(0), ddelayb1 => cbddelays(1), ddelayb2 => cbddelays(2), ddelayb3 => cbddelays(3), ddelayb4 => cbddelays(4), ddelayb5 => cbddelays(5), ddelayb6 => cbddelays(6), ddelayb7 => cbddelays(7), ddelayb8 => cbddelays(8), ddelayb9 => cbddelays(9), ddelayb10 => cbddelays(10), ddelayb11 => cbddelays(11), numidelctrl => numidelctrl, norefclk => norefclk, rskew => rskew, eightbanks => eightbanks, dqsse => dqsse, abits => abits, nclk => nclk, ncs => ncs, resync => resync, custombits => custombits, scantest => scantest) port map ( rst => rst, clk => clk, clkref => clkref200, clkout => clkout, clkoutret => clkoutret, clkresync => clkresync, lock => lock, ddr_clk => ddr_clk, ddr_clkb => ddr_clkb, ddr_clk_fb_out => ddr_clk_fb_out, ddr_clk_fb => ddr_clk_fb, ddr_cke => ddr_cke, ddr_csb => ddr_csb, ddr_web => ddr_web, ddr_rasb => ddr_rasb, ddr_casb => ddr_casb, ddr_dm => ddr_dm, ddr_dqs_in => ddr_dqs_in, ddr_dqs_out => ddr_dqs_out, ddr_dqs_oen => ddr_dqs_oen, ddr_ad => ddr_ad, ddr_ba => ddr_ba, ddr_dq_in => ddr_dq_in, ddr_dq_out => ddr_dq_out, ddr_dq_oen => ddr_dq_oen, ddr_odt => ddr_odt, addr => sdo.address(abits-1 downto 0), ba => sdo.ba, dqin => dqin, dqout => dqout, dm => dqm, oen => sdo.bdrive, noen => sdo.nbdrive, dqs => sdo.bdrive, dqsoen => sdo.qdrive, rasn => sdo.rasn, casn => sdo.casn, wen => sdo.sdwen, csn => csn, cke => cke, cal_en => cal_en, cal_inc => cal_inc, cal_pll => sdo.cal_pll, cal_rst => sdo.cal_rst, odt => odt, oct => sdo.oct, read_pend => sdo.read_pend, regwdata => sdo.regwdata, regwrite => sdo.regwrite, regrdata => sdi.regrdata, dqin_valid => sdi.datavalid, customclk => customclk, customdin => customdin, customdout => customdout, testen => testen, testrst => testrst, scanen => scanen, testoen => testoen ); end; ------------------------------------------------------------------ -- LPDDR2/LPDDR3 PHY with checkbits merged on data bus, no pads -- ------------------------------------------------------------------ library ieee; use ieee.std_logic_1164.all; library grlib; use grlib.stdlib.all; library techmap; use techmap.gencomp.all; library gaisler; use gaisler.ddrpkg.all; entity lpddr2phy_wrap_cbd_wo_pads is generic (tech : integer := virtex2; dbits : integer := 16; nclk : integer := 3; ncs : integer := 2; chkbits : integer := 0; padbits : integer := 0; scantest : integer := 0); port ( rst : in std_ulogic; clkin : in std_ulogic; -- input clock clkin2 : in std_ulogic; -- input clock clkout : out std_ulogic; -- system clock clkoutret : in std_ulogic; -- system clock return clkout2 : out std_ulogic; -- system clock lock : out std_ulogic; -- DCM locked ddr_clk : out std_logic_vector(nclk-1 downto 0); ddr_clkb : out std_logic_vector(nclk-1 downto 0); ddr_cke : out std_logic_vector(ncs-1 downto 0); ddr_csb : out std_logic_vector(ncs-1 downto 0); ddr_ca : out std_logic_vector(9 downto 0); -- ddr cmd/addr ddr_dm : out std_logic_vector ((dbits+padbits+chkbits)/8-1 downto 0); -- ddr dm ddr_dqs_in : in std_logic_vector ((dbits+padbits+chkbits)/8-1 downto 0); -- ddr dqs ddr_dqs_out : out std_logic_vector ((dbits+padbits+chkbits)/8-1 downto 0); -- ddr dqs ddr_dqs_oen : out std_logic_vector ((dbits+padbits+chkbits)/8-1 downto 0); -- ddr dqs ddr_dq_in : in std_logic_vector (dbits+padbits+chkbits-1 downto 0); -- ddr data ddr_dq_out : out std_logic_vector (dbits+padbits+chkbits-1 downto 0); -- ddr data ddr_dq_oen : out std_logic_vector (dbits+padbits+chkbits-1 downto 0); sdi : out ddrctrl_in_type; sdo : in ddrctrl_out_type; testen : in std_ulogic; testrst : in std_ulogic; scanen : in std_ulogic; testoen : in std_ulogic); end; architecture rtl of lpddr2phy_wrap_cbd_wo_pads is function ddr_widthconv(x: std_logic_vector; ow: integer) return std_logic_vector is variable r: std_logic_vector(2ow-1 downto 0); constant iw: integer := x'length/2; begin r := (others => '0'); if iw <= ow then r(iw+ow-1 downto ow) := x(2iw-1 downto iw); r(iw-1 downto 0) := x(iw-1 downto 0); else r := x(iw+ow-1 downto iw) & x(ow-1 downto 0); end if; return r; end; function sdr_widthconv(x: std_logic_vector; ow: integer) return std_logic_vector is variable r: std_logic_vector(ow-1 downto 0); constant iw: integer := x'length; variable xd : std_logic_vector(iw-1 downto 0); begin r := (others => '0'); xd := x; if iw >= ow then r := xd(ow-1 downto 0); else r(iw-1 downto 0) := xd; end if; return r; end; function ddrmerge(a,b: std_logic_vector) return std_logic_vector is constant aw: integer := a'length/2; constant bw: integer := b'length/2; begin return a(2aw-1 downto aw) & b(2bw-1 downto bw) & a(aw-1 downto 0) & b(bw-1 downto 0); end; signal dqin: std_logic_vector(2(chkbits+dbits+padbits)-1 downto 0); signal dqout: std_logic_vector(2(chkbits+dbits+padbits)-1 downto 0); signal dqm: std_logic_vector((chkbits+dbits+padbits)/4-1 downto 0); signal odt,csn,cke: std_logic_vector(ncs-1 downto 0); signal sdck: std_logic_vector(nclk-1 downto 0); signal gnd : std_logic_vector(chkbits2-1 downto 0); begin gnd <= (others => '0'); -- Merge checkbit and data buses comb: process(sdo,dqin) variable dq: std_logic_vector(2dbits-1 downto 0); variable dqpad: std_logic_vector(2(dbits+padbits)-1 downto 0); variable cb: std_logic_vector(dbits-1 downto 0); variable cbpad: std_logic_vector(2chkbits downto 0); -- Extra bit to handle chkbits=0 variable dqcb: std_logic_vector(2(dbits+padbits+chkbits)-1 downto 0); variable dm: std_logic_vector(dbits/4-1 downto 0); variable dmpad: std_logic_vector((dbits+padbits)/4-1 downto 0); variable cbdm: std_logic_vector(dbits/8-1 downto 0); variable cbdmpad: std_logic_vector(chkbits/4 downto 0); variable dqcbdm: std_logic_vector((dbits+padbits+chkbits)/4-1 downto 0); variable vcsn,vcke: std_logic_vector(ncs-1 downto 0); variable vsdck: std_logic_vector(nclk-1 downto 0); begin dq := sdo.data(2dbits-1 downto 0); dqpad := ddr_widthconv(dq, dbits+padbits ); if chkbits > 0 then cb := sdo.cb(dbits-1 downto 0); cbpad := '0' & ddr_widthconv(cb, chkbits); dqcb := ddrmerge(cbpad(2chkbits-1 downto 0), dqpad); else dqcb := dqpad; end if; dqout <= dqcb; dqcb := dqin; if chkbits > 0 then cbpad := '0' & dqin(2(chkbits+dbits+padbits)-1 downto 2(dbits+padbits)+chkbits) & dqin(chkbits+dbits+padbits-1 downto dbits+padbits); cb := ddr_widthconv(cbpad(2chkbits-1 downto 0), dbits/2); else cb := (others => '0'); end if; dq := dqcb(2dbits+chkbits+padbits-1 downto dbits+chkbits+padbits) & dqcb(dbits-1 downto 0); sdi.cb(dbits-1 downto 0) <= cb; sdi.data(2dbits-1 downto 0) <= dq; if sdi.cb'length > dbits then sdi.cb(sdi.cb'length-1 downto dbits) <= (others => '0'); end if; if sdi.data'length > 2dbits then sdi.data(sdi.data'length-1 downto 2*dbits) <= (others => '0'); end if; dm := sdo.dqm(dbits/4-1 downto 0); dmpad := ddr_widthconv(dm, (dbits+padbits)/8); if chkbits > 0 then cbdm := sdo.cbdqm(dbits/8-1 downto 0); cbdmpad := '0' & ddr_widthconv(cbdm(dbits/8-1 downto 0), chkbits/8); dqcbdm := ddrmerge(cbdmpad(chkbits/4-1 downto 0), dmpad); else dqcbdm := dmpad; end if; dqm <= dqcbdm; vcsn := (others => '1'); for x in 0 to ncs-1 loop if x<2 then vcsn(x) := sdo.sdcsn(x); end if; vcke(x) := sdo.sdcke(x mod 2); end loop; for x in 0 to nclk-1 loop vsdck(x) := sdo.sdck(x mod 2); end loop; csn <= vcsn; cke <= vcke; sdck <= vsdck; end process; -- Phy instantiation ddr_phy0 : lpddr2phy_wo_pads generic map ( tech => tech, dbits => dbits+padbits+chkbits, nclk => nclk, ncs => ncs, clkratio => 1, scantest => scantest) port map ( rst => rst, clkin => clkin, clkin2 => clkin2, clkout => clkout, clkoutret => clkoutret, clkout2 => clkout2, lock => lock, ddr_clk => ddr_clk, ddr_clkb => ddr_clkb, ddr_cke => ddr_cke, ddr_csb => ddr_csb, ddr_ca => ddr_ca, ddr_dm => ddr_dm, ddr_dqs_in => ddr_dqs_in, ddr_dqs_out => ddr_dqs_out, ddr_dqs_oen => ddr_dqs_oen, ddr_dq_in => ddr_dq_in, ddr_dq_out => ddr_dq_out, ddr_dq_oen => ddr_dq_oen, ca => sdo.ca, cke => cke, csn => csn, dqin => dqin, dqout => dqout, dm => dqm, ckstop => sdo.sdck(0), boot => sdo.boot, wrpend => sdo.wrpend, rdpend => sdo.read_pend, wrreq(0) => sdi.writereq, rdvalid(0) => sdi.datavalid, refcal => '0', refcalwu => '0', refcaldone => open, phycmd => "00000000", phycmden => '0', phycmdin => x"00000000", phycmdout => open, testen => '0', testrst => '1', scanen => '0', testoen => '0' ); sdi.regrdata <= (others => '0'); end;	gpl-2.0	8bab2567d3f9b14edb2e70c0cf7281f8	0.570441	3.393609	false	false	false	false
Yuriu5/MiniBlaze	src/peripherals/UART.vhd	1	11,862	-- ******************************************************************************** -- Project : MiniBlaze -- Author : Benjamin Lemoine -- Module : UART -- Date : 07/25/2016 -- -- Description : -- -- -------------------------------------------------------------------------------- -- Modifications -- -------------------------------------------------------------------------------- -- Date : Ver. : Author : Modification comments -- -------------------------------------------------------------------------------- -- : : : -- 07/25/2016 : 1.0 : B.Lemoine : First draft -- : : : -- ****************************************************************************** -- MIT License -- -- Copyright (c) 07/25/2016, Benjamin Lemoine -- -- Permission is hereby granted, free of charge, to any person obtaining a copy -- of this software and associated documentation files (the "Software"), to deal -- in the Software without restriction, including without limitation the rights -- to use, copy, modify, merge, publish, distribute, sublicense, and/or sell -- copies of the Software, and to permit persons to whom the Software is -- furnished to do so, subject to the following conditions: -- -- The above copyright notice and this permission notice shall be included in all -- copies or substantial portions of the Software. -- -- THE SOFTWARE IS PROVIDED "AS IS", WITHOUT WARRANTY OF ANY KIND, EXPRESS OR -- IMPLIED, INCLUDING BUT NOT LIMITED TO THE WARRANTIES OF MERCHANTABILITY, -- FITNESS FOR A PARTICULAR PURPOSE AND NONINFRINGEMENT. IN NO EVENT SHALL THE -- AUTHORS OR COPYRIGHT HOLDERS BE LIABLE FOR ANY CLAIM, DAMAGES OR OTHER -- LIABILITY, WHETHER IN AN ACTION OF CONTRACT, TORT OR OTHERWISE, ARISING FROM, -- OUT OF OR IN CONNECTION WITH THE SOFTWARE OR THE USE OR OTHER DEALINGS IN THE -- SOFTWARE. -- ******************************************************************************** library ieee; use ieee.std_logic_1164.all; use ieee.numeric_std.all; entity UART is generic ( CLK_IN : integer := 10000000; BAUDRATE : integer := 115200; DATA_BITS : integer := 8; STOP_BITS : integer := 1; USE_PARITY : integer := 0; ODD_PARITY : integer := 0 ); port ( clk : in std_logic; rst_n : in std_logic; -- User intf data_in : in std_logic_vector(DATA_BITS-1 downto 0); data_in_en : in std_logic; data_in_ack : out std_logic; data_out : out std_logic_vector(DATA_BITS-1 downto 0); data_out_en : out std_logic; frame_error : out std_logic; parity_error : out std_logic; -- TX/RX RX : in std_logic; TX : out std_logic ); end UART; architecture rtl of UART is function CALC_RATIO ( C_BAUDRATE : integer; C_CLKIN : integer) return integer is constant C_RATIO : integer := C_CLKIN/C_BAUDRATE; constant C_REMAIN : integer := C_CLKIN rem C_BAUDRATE; begin if C_BAUDRATE/2 < C_REMAIN then return C_RATIO; else return C_RATIO + 1; end if; end function CALC_RATIO; constant c_nb_clk_per_bit : integer := CALC_RATIO(BAUDRATE, CLK_IN); constant c_nb_clk_per_bit_div2 : integer := c_nb_clk_per_bit/2; -- RX type fsm_rx is (st_wait_start_bit, st_get_data, st_get_stop_bit); signal r_fsm_rx : fsm_rx := st_wait_start_bit; signal r_RX : std_logic := '0'; signal r2_RX : std_logic := '0'; signal r_data_rx : std_logic_vector(DATA_BITS-1 downto 0) := (others => '0'); signal r_data_rx_en : std_logic := '0'; signal r_cnt_bit_uart : unsigned(31 downto 0) := (others => '0'); signal r_cnt_data : unsigned(31 downto 0) := (others => '0'); signal r_cnt_stop : unsigned(31 downto 0) := (others => '0'); signal r_frame_error : std_logic := '0'; -- TX type fsm_tx is (st_wait_data, st_send_start, st_send_data, st_send_stop, st_wait_1b_for_ack); signal r_fsm_tx : fsm_tx := st_wait_data; signal r_cnt_bit_uart_tx : unsigned(31 downto 0) := (others => '0'); signal r_cnt_data_tx : unsigned(31 downto 0) := (others => '0'); signal r_cnt_stop_tx : unsigned(31 downto 0) := (others => '0'); signal r_data_in : std_logic_vector(DATA_BITS-1 downto 0) := (others => '0'); signal r_data_in_en : std_logic := '0'; signal r_TX : std_logic := '1'; signal r_data_tx : std_logic_vector(DATA_BITS-1 downto 0) := (others => '0'); signal r_tx_ack : std_logic := '0'; begin -- --------------------------------------------- -- RX side -- --------------------------------------------- p_pipe_in : process(clk) -- Two pipes to avoid metastability begin if rising_edge(clk) then r_RX <= RX; r2_RX <= r_RX; end if; end process; p_RX : process(clk) begin if rising_edge(clk) then if rst_n = '0' then r_fsm_rx <= st_wait_start_bit; r_data_rx_en <= '0'; else -- default values r_data_rx_en <= '0'; case r_fsm_rx is when st_wait_start_bit => if r2_RX = '0' then r_cnt_bit_uart <= r_cnt_bit_uart + 1; else r_cnt_bit_uart <= (others => '0'); end if; if r_cnt_bit_uart = c_nb_clk_per_bit_div2 - 1 then r_fsm_rx <= st_get_data; r_cnt_bit_uart <= (others => '0'); r_cnt_data <= (others => '0'); r_cnt_stop <= (others => '0'); r_frame_error <= '0'; end if; when st_get_data => -- Sample at the center of each bit if r_cnt_bit_uart = c_nb_clk_per_bit - 1 then r_data_rx(to_integer(r_cnt_data)) <= r2_RX; r_cnt_bit_uart <= (others => '0'); if r_cnt_data = DATA_BITS - 1 then r_fsm_rx <= st_get_stop_bit; else r_cnt_data <= r_cnt_data + 1; end if; else r_cnt_bit_uart <= r_cnt_bit_uart + 1; end if; when st_get_stop_bit => if r_cnt_bit_uart = c_nb_clk_per_bit - 1 then if r2_RX = '0' then -- NOK r_cnt_bit_uart <= (others => '0'); r_fsm_rx <= st_wait_start_bit; r_frame_error <= '1'; else -- OK if r_cnt_stop = STOP_BITS - 1 then r_fsm_rx <= st_wait_start_bit; r_data_rx_en <= '1'; else r_cnt_stop <= r_cnt_stop + 1; r_cnt_bit_uart <= (others => '0'); end if; end if; else r_cnt_bit_uart <= r_cnt_bit_uart + 1; end if; when others => r_fsm_rx <= st_wait_start_bit; end case; end if; end if; end process; data_out <= r_data_rx; data_out_en <= r_data_rx_en; -- --------------------------------------------- -- TX side -- --------------------------------------------- p_pipe_tx_in : process(clk) begin if rising_edge(clk) then r_data_in <= data_in; r_data_in_en <= data_in_en; end if; end process; p_TX : process(clk) begin if rising_edge(clk) then if rst_n = '0' then r_cnt_bit_uart_tx <= (others => '0'); r_cnt_data_tx <= (others => '0'); r_cnt_stop_tx <= (others => '0'); r_fsm_tx <= st_wait_data; r_TX <= '1'; else -- Default values r_tx_ack <= '0'; case r_fsm_tx is when st_wait_data => r_TX <= '1'; if r_data_in_en = '1' then r_data_tx <= r_data_in; r_fsm_tx <= st_send_start; r_cnt_bit_uart_tx <= (others => '0'); r_cnt_data_tx <= (others => '0'); r_cnt_stop_tx <= (others => '0'); end if; when st_send_start => r_TX <= '0'; if r_cnt_bit_uart_tx = c_nb_clk_per_bit - 1 then r_cnt_bit_uart_tx <= (others => '0'); r_fsm_tx <= st_send_data; else r_cnt_bit_uart_tx <= r_cnt_bit_uart_tx + 1; end if; when st_send_data => if r_cnt_data_tx = DATA_BITS then r_fsm_tx <= st_send_stop; r_TX <= '1'; else if r_cnt_bit_uart_tx = c_nb_clk_per_bit - 1 then r_cnt_data_tx <= r_cnt_data_tx + 1; r_cnt_bit_uart_tx <= (others => '0'); r_data_tx <= r_data_tx(0) & r_data_tx(DATA_BITS - 1 downto 1); else r_cnt_bit_uart_tx <= r_cnt_bit_uart_tx + 1; r_TX <= r_data_tx(0); end if; end if; when st_send_stop => r_TX <= '1'; if r_cnt_stop_tx = STOP_BITS -1 then r_fsm_tx <= st_wait_1b_for_ack; r_cnt_bit_uart_tx <= (others => '0'); else if r_cnt_bit_uart_tx = c_nb_clk_per_bit - 1 then r_cnt_bit_uart_tx <= (others => '0'); r_cnt_stop_tx <= r_cnt_stop_tx + 1; else r_cnt_bit_uart_tx <= r_cnt_bit_uart_tx + 1; end if; end if; when st_wait_1b_for_ack => r_TX <= '1'; if r_cnt_bit_uart_tx = c_nb_clk_per_bit - 1 then r_fsm_tx <= st_wait_data; r_tx_ack <= '1'; else r_cnt_bit_uart_tx <= r_cnt_bit_uart_tx + 1; end if; when others => r_fsm_tx <= st_wait_data; end case; end if; end if; end process; TX <= r_TX; data_in_ack <= r_tx_ack; end;	mit	63f42e87b07217dded5d300758df35df	0.386023	3.999326	false	false	false	false
mistryalok/Zedboard	learning/training/MSD/s09/axi_dma_sg/vivado/project_1/project_1.srcs/sources_1/ipshared/xilinx.com/axi_sg_v4_1/0535f152/hdl/src/vhdl/axi_sg_scc_wr.vhd	13	44,376	-- *********************************************************************** -- -- (c) Copyright 2010-2011 Xilinx, Inc. All rights reserved. -- -- This file contains confidential and proprietary information -- of Xilinx, Inc. and is protected under U.S. and -- international copyright and other intellectual property -- laws. -- -- DISCLAIMER -- This disclaimer is not a license and does not grant any -- rights to the materials distributed herewith. Except as -- otherwise provided in a valid license issued to you by -- Xilinx, and to the maximum extent permitted by applicable -- law: (1) THESE MATERIALS ARE MADE AVAILABLE "AS IS" AND -- WITH ALL FAULTS, AND XILINX HEREBY DISCLAIMS ALL WARRANTIES -- AND CONDITIONS, EXPRESS, IMPLIED, OR STATUTORY, INCLUDING -- BUT NOT LIMITED TO WARRANTIES OF MERCHANTABILITY, NON- -- INFRINGEMENT, OR FITNESS FOR ANY PARTICULAR PURPOSE; and -- (2) Xilinx shall not be liable (whether in contract or tort, -- including negligence, or under any other theory of -- liability) for any loss or damage of any kind or nature -- related to, arising under or in connection with these -- materials, including for any direct, or any indirect, -- special, incidental, or consequential loss or damage -- (including loss of data, profits, goodwill, or any type of -- loss or damage suffered as a result of any action brought -- by a third party) even if such damage or loss was -- reasonably foreseeable or Xilinx had been advised of the -- possibility of the same. -- -- CRITICAL APPLICATIONS -- Xilinx products are not designed or intended to be fail- -- safe, or for use in any application requiring fail-safe -- performance, such as life-support or safety devices or -- systems, Class III medical devices, nuclear facilities, -- applications related to the deployment of airbags, or any -- other applications that could lead to death, personal -- injury, or severe property or environmental damage -- (individually and collectively, "Critical -- Applications"). Customer assumes the sole risk and -- liability of any use of Xilinx products in Critical -- Applications, subject only to applicable laws and -- regulations governing limitations on product liability. -- -- THIS COPYRIGHT NOTICE AND DISCLAIMER MUST BE RETAINED AS -- PART OF THIS FILE AT ALL TIMES. -- -- *********************************************************************** -- ------------------------------------------------------------------------------- -- Filename: axi_sg_scc_wr.vhd -- -- Description: -- This file implements the DataMover Lite Master Simple Command Calculator (SCC). -- -- -- -- -- VHDL-Standard: VHDL'93 ------------------------------------------------------------------------------- library IEEE; use IEEE.std_logic_1164.all; use IEEE.numeric_std.all; ------------------------------------------------------------------------------- entity axi_sg_scc_wr is generic ( C_SEL_ADDR_WIDTH : Integer range 1 to 8 := 5; -- Sets the width of the LS address bus used for -- Muxing/Demuxing data to/from a wider AXI4 data bus C_ADDR_WIDTH : Integer range 32 to 64 := 32; -- Sets the width of the AXi Address Channel C_STREAM_DWIDTH : Integer range 8 to 64 := 32; -- Sets the width of the Native Data width that -- is being supported by the PCC C_MAX_BURST_LEN : Integer range 16 to 64 := 16; -- Indicates the max allowed burst length to use for -- AXI4 transfer calculations C_CMD_WIDTH : Integer := 68; -- Sets the width of the input command port C_TAG_WIDTH : Integer range 1 to 8 := 4; -- Sets the width of the Tag field in the input command C_ENABLE_EXTRA_FIELD : Integer range 0 to 1 := 1 ); port ( -- Clock and Reset inputs ------------------------------------- primary_aclk : in std_logic; -- -- Primary synchronization clock for the Master side -- -- interface and internal logic. It is also used -- -- for the User interface synchronization when -- -- C_STSCMD_IS_ASYNC = 0. -- -- -- Reset input -- mmap_reset : in std_logic; -- -- Reset used for the internal master logic -- --------------------------------------------------------------- -- Command Input Interface --------------------------------------------------------- -- cmd2mstr_command : in std_logic_vector(C_CMD_WIDTH-1 downto 0); -- -- The next command value available from the Command FIFO/Register -- -- cache2mstr_command : in std_logic_vector(7 downto 0); -- -- The next command value available from the Command FIFO/Register -- -- cmd2mstr_cmd_valid : in std_logic; -- -- Handshake bit indicating if the Command FIFO/Register has at leasdt 1 entry -- -- mst2cmd_cmd_ready : out std_logic; -- -- Handshake bit indicating the Command Calculator is ready to accept -- -- another command -- ------------------------------------------------------------------------------------ -- Address Channel Controller Interface -------------------------------------------- -- mstr2addr_tag : out std_logic_vector(C_TAG_WIDTH-1 downto 0); -- -- The next command tag -- -- mstr2addr_addr : out std_logic_vector(C_ADDR_WIDTH-1 downto 0); -- -- The next command address to put on the AXI MMap ADDR -- -- mstr2addr_len : out std_logic_vector(7 downto 0); -- -- The next command length to put on the AXI MMap LEN -- -- mstr2addr_size : out std_logic_vector(2 downto 0); -- -- The next command size to put on the AXI MMap SIZE -- -- mstr2addr_burst : out std_logic_vector(1 downto 0); -- -- The next command burst type to put on the AXI MMap BURST -- -- mstr2addr_cache : out std_logic_vector(3 downto 0); -- -- The next command burst type to put on the AXI MMap BURST -- -- mstr2addr_user : out std_logic_vector(3 downto 0); -- -- The next command burst type to put on the AXI MMap BURST -- -- mstr2addr_cmd_cmplt : out std_logic; -- -- The indication to the Address Channel that the current -- -- sub-command output is the last one compiled from the -- -- parent command pulled from the Command FIFO -- -- mstr2addr_calc_error : out std_logic; -- -- Indication if the next command in the calculation pipe -- -- has a calcualtion error -- -- mstr2addr_cmd_valid : out std_logic; -- -- The next command valid indication to the Address Channel -- -- Controller for the AXI MMap -- -- addr2mstr_cmd_ready : In std_logic; -- -- Indication from the Address Channel Controller that the -- -- command is being accepted -- ------------------------------------------------------------------------------------ -- Data Channel Controller Interface ---------------------------------------------- -- mstr2data_tag : out std_logic_vector(C_TAG_WIDTH-1 downto 0); -- -- The next command tag -- -- mstr2data_saddr_lsb : out std_logic_vector(C_SEL_ADDR_WIDTH-1 downto 0); -- -- The next command start address LSbs to use for the read data -- -- mux (only used if Stream data width is 8 or 16 bits). -- -- mstr2data_len : out std_logic_vector(7 downto 0); -- -- The LEN value output to the Address Channel -- -- mstr2data_strt_strb : out std_logic_vector((C_STREAM_DWIDTH/8)-1 downto 0); -- -- The starting strobe value to use for the data transfer -- -- mstr2data_last_strb : out std_logic_vector((C_STREAM_DWIDTH/8)-1 downto 0); -- -- The endiing (LAST) strobe value to use for the data transfer -- -- mstr2data_sof : out std_logic; -- -- The starting tranfer of a sequence of transfers -- -- mstr2data_eof : out std_logic; -- -- The endiing tranfer of a sequence of parent transfer commands -- -- mstr2data_calc_error : out std_logic; -- -- Indication if the next command in the calculation pipe -- -- has a calculation error -- -- mstr2data_cmd_cmplt : out std_logic; -- -- The indication to the Data Channel that the current -- -- sub-command output is the last one compiled from the -- -- parent command pulled from the Command FIFO -- -- mstr2data_cmd_valid : out std_logic; -- -- The next command valid indication to the Data Channel -- -- Controller for the AXI MMap -- -- data2mstr_cmd_ready : In std_logic ; -- -- Indication from the Data Channel Controller that the -- -- command is being accepted on the AXI Address -- -- Channel -- -- calc_error : Out std_logic -- -- Indication from the Command Calculator that a calculation -- -- error has occured. -- ------------------------------------------------------------------------------------ ); end entity axi_sg_scc_wr; architecture implementation of axi_sg_scc_wr is attribute DowngradeIPIdentifiedWarnings: string; attribute DowngradeIPIdentifiedWarnings of implementation : architecture is "yes"; ------------------------------------------------------------------- -- Function -- -- Function Name: funct_get_slice_width -- -- Function Description: -- Calculates the bits to rip from the Command BTT field to calculate -- the LEN value output to the AXI Address Channel. -- ------------------------------------------------------------------- function funct_get_slice_width (max_burst_len : integer) return integer is Variable temp_slice_width : Integer := 0; begin case max_burst_len is -- coverage off when 64 => temp_slice_width := 7; when 32 => temp_slice_width := 6; when others => -- assume 16 dbeats is max LEN temp_slice_width := 5; -- coverage on end case; Return (temp_slice_width); end function funct_get_slice_width; ------------------------------------------------------------------- -- Function -- -- Function Name: funct_get_residue_width -- -- Function Description: -- Calculates the number of Least significant bits of the BTT field -- that are unused for the LEN calculation -- ------------------------------------------------------------------- function funct_get_btt_ls_unused (transfer_width : integer) return integer is Variable temp_btt_ls_unused : Integer := 0; -- 8-bit stream begin case transfer_width is -- coverage off when 64 => temp_btt_ls_unused := 3; -- coverage on when 32 => temp_btt_ls_unused := 2; -- coverage off when 16 => temp_btt_ls_unused := 1; when others => -- assume 8-bit transfers temp_btt_ls_unused := 0; -- coverage on end case; Return (temp_btt_ls_unused); end function funct_get_btt_ls_unused; -- Constant Declarations ---------------------------------------- Constant BASE_CMD_WIDTH : integer := 32; -- Bit Width of Command LS (no address) Constant CMD_TYPE_INDEX : integer := 23; Constant CMD_ADDR_LS_INDEX : integer := BASE_CMD_WIDTH; Constant CMD_ADDR_MS_INDEX : integer := (C_ADDR_WIDTH+BASE_CMD_WIDTH)-1; Constant CMD_TAG_WIDTH : integer := C_TAG_WIDTH; Constant CMD_TAG_LS_INDEX : integer := C_ADDR_WIDTH+BASE_CMD_WIDTH; Constant CMD_TAG_MS_INDEX : integer := (CMD_TAG_LS_INDEX+CMD_TAG_WIDTH)-1; Constant AXI_BURST_FIXED : std_logic_vector(1 downto 0) := "00"; Constant AXI_BURST_INCR : std_logic_vector(1 downto 0) := "01"; Constant AXI_BURST_WRAP : std_logic_vector(1 downto 0) := "10"; Constant AXI_BURST_RESVD : std_logic_vector(1 downto 0) := "11"; Constant AXI_SIZE_1BYTE : std_logic_vector(2 downto 0) := "000"; Constant AXI_SIZE_2BYTE : std_logic_vector(2 downto 0) := "001"; Constant AXI_SIZE_4BYTE : std_logic_vector(2 downto 0) := "010"; Constant AXI_SIZE_8BYTE : std_logic_vector(2 downto 0) := "011"; Constant AXI_SIZE_16BYTE : std_logic_vector(2 downto 0) := "100"; Constant AXI_SIZE_32BYTE : std_logic_vector(2 downto 0) := "101"; Constant AXI_SIZE_64BYTE : std_logic_vector(2 downto 0) := "110"; Constant AXI_SIZE_128BYTE : std_logic_vector(2 downto 0) := "111"; Constant BTT_SLICE_SIZE : integer := funct_get_slice_width(C_MAX_BURST_LEN); Constant MAX_BURST_LEN_US : unsigned(BTT_SLICE_SIZE-1 downto 0) := TO_UNSIGNED(C_MAX_BURST_LEN-1, BTT_SLICE_SIZE); Constant BTT_LS_UNUSED_WIDTH : integer := funct_get_btt_ls_unused(C_STREAM_DWIDTH); Constant CMD_BTT_WIDTH : integer := BTT_SLICE_SIZE+BTT_LS_UNUSED_WIDTH; Constant CMD_BTT_LS_INDEX : integer := 0; Constant CMD_BTT_MS_INDEX : integer := CMD_BTT_WIDTH-1; Constant BTT_ZEROS : std_logic_vector(CMD_BTT_WIDTH-1 downto 0) := (others => '0'); Constant BTT_RESIDUE_ZEROS : unsigned(BTT_LS_UNUSED_WIDTH-1 downto 0) := (others => '0'); Constant BTT_SLICE_ONE : unsigned(BTT_SLICE_SIZE-1 downto 0) := TO_UNSIGNED(1, BTT_SLICE_SIZE); Constant STRB_WIDTH : integer := C_STREAM_DWIDTH/8; -- Number of bytes in the Stream Constant LEN_WIDTH : integer := 8; -- Type Declarations -------------------------------------------- type SCC_SM_STATE_TYPE is ( INIT, POP_RECOVER, GET_NXT_CMD, CHK_AND_CALC, PUSH_TO_AXI, ERROR_TRAP ); -- Signal Declarations -------------------------------------------- signal sm_scc_state : SCC_SM_STATE_TYPE := INIT; signal sm_scc_state_ns : SCC_SM_STATE_TYPE := INIT; signal sm_pop_input_cmd : std_logic := '0'; signal sm_pop_input_cmd_ns : std_logic := '0'; signal sm_set_push2axi : std_logic := '0'; signal sm_set_push2axi_ns : std_logic := '0'; signal sm_set_error : std_logic := '0'; signal sm_set_error_ns : std_logic := '0'; Signal sm_scc_sm_ready : std_logic := '0'; Signal sm_scc_sm_ready_ns : std_logic := '0'; signal sig_cmd2data_valid : std_logic := '0'; signal sig_clr_cmd2data_valid : std_logic := '0'; signal sig_cmd2addr_valid : std_logic := '0'; signal sig_cmd2addr_valid1 : std_logic := '0'; signal sig_clr_cmd2addr_valid : std_logic := '0'; signal sig_addr_data_rdy_pending : std_logic := '0'; signal sig_cmd_btt_slice : std_logic_vector(CMD_BTT_WIDTH-1 downto 0) := (others => '0'); signal sig_load_input_cmd : std_logic := '0'; signal sig_cmd_reg_empty : std_logic := '0'; signal sig_cmd_reg_full : std_logic := '0'; signal sig_cmd_addr_reg : std_logic_vector(C_ADDR_WIDTH-1 downto 0) := (others => '0'); signal sig_cmd_btt_reg : std_logic_vector(CMD_BTT_WIDTH-1 downto 0) := (others => '0'); signal sig_cmd_type_reg : std_logic := '0'; signal sig_cmd_burst_reg : std_logic_vector (1 downto 0) := "00"; signal sig_cmd_tag_reg : std_logic_vector(CMD_TAG_WIDTH-1 downto 0) := (others => '0'); signal sig_addr_data_rdy4cmd : std_logic := '0'; signal sig_btt_raw : std_logic := '0'; signal sig_btt_is_zero : std_logic := '0'; signal sig_btt_is_zero_reg : std_logic := '0'; signal sig_next_tag : std_logic_vector(CMD_TAG_WIDTH-1 downto 0) := (others => '0'); signal sig_next_addr : std_logic_vector(C_ADDR_WIDTH-1 downto 0) := (others => '0'); signal sig_next_len : std_logic_vector(LEN_WIDTH-1 downto 0) := (others => '0'); signal sig_next_size : std_logic_vector(2 downto 0) := (others => '0'); signal sig_next_burst : std_logic_vector(1 downto 0) := (others => '0'); signal sig_next_cache : std_logic_vector(3 downto 0) := (others => '0'); signal sig_next_user : std_logic_vector(3 downto 0) := (others => '0'); signal sig_next_strt_strb : std_logic_vector((C_STREAM_DWIDTH/8)-1 downto 0) := (others => '0'); signal sig_next_end_strb : std_logic_vector((C_STREAM_DWIDTH/8)-1 downto 0) := (others => '0'); begin --(architecture implementation) -- Assign calculation error output calc_error <= sm_set_error; -- Assign the ready output to the Command FIFO mst2cmd_cmd_ready <= sig_cmd_reg_empty and addr2mstr_cmd_ready; --sm_scc_sm_ready; -- Assign the Address Channel Controller Qualifiers mstr2addr_tag <= sig_next_tag ; mstr2addr_addr <= sig_next_addr ; mstr2addr_len <= sig_next_len ; mstr2addr_size <= sig_next_size ; mstr2addr_burst <= sig_cmd_burst_reg; mstr2addr_cache <= sig_next_cache; mstr2addr_user <= sig_next_user; mstr2addr_cmd_valid <= sig_cmd2addr_valid1; mstr2addr_calc_error <= sm_set_error ; mstr2addr_cmd_cmplt <= '1' ; -- Lite mode is always 1 -- Assign the Data Channel Controller Qualifiers mstr2data_tag <= sig_next_tag ; mstr2data_saddr_lsb <= sig_cmd_addr_reg(C_SEL_ADDR_WIDTH-1 downto 0); mstr2data_len <= sig_next_len ; mstr2data_strt_strb <= (others => '1'); --sig_next_strt_strb; -- always F mstr2data_last_strb <= (others => '1'); --sig_next_end_strb; -- always F mstr2data_sof <= '1'; -- Lite mode is always 1 cmd mstr2data_eof <= '1'; -- Lite mode is always 1 cmd mstr2data_cmd_cmplt <= '1'; -- Lite mode is always 1 cmd -- mstr2data_cmd_valid <= sig_cmd2data_valid; mstr2data_cmd_valid <= sig_cmd2addr_valid1; --sig_cmd2data_valid; mstr2data_calc_error <= sm_set_error; -- Internal logic ------------------------------ sig_addr_data_rdy_pending <= sig_cmd2addr_valid or sig_cmd2data_valid; sig_clr_cmd2data_valid <= sig_cmd2data_valid and data2mstr_cmd_ready; sig_clr_cmd2addr_valid <= sig_cmd2addr_valid and addr2mstr_cmd_ready; sig_load_input_cmd <= cmd2mstr_cmd_valid and sig_cmd_reg_empty;-- and -- sm_scc_sm_ready; sig_next_tag <= sig_cmd_tag_reg; sig_next_addr <= sig_cmd_addr_reg; sig_addr_data_rdy4cmd <= addr2mstr_cmd_ready and data2mstr_cmd_ready; sig_cmd_btt_slice <= cmd2mstr_command(CMD_BTT_MS_INDEX downto CMD_BTT_LS_INDEX); sig_btt_is_zero <= '1' when (sig_cmd_btt_slice = BTT_ZEROS) Else '0'; ------------------------------------------------------------ -- If Generate -- -- Label: GEN_NO_RESIDUE_BITS -- -- If Generate Description: -- -- -- ------------------------------------------------------------ GEN_NO_RESIDUE_BITS : if (BTT_LS_UNUSED_WIDTH = 0) generate -- signals signal sig_len_btt_slice : unsigned(BTT_SLICE_SIZE-1 downto 0) := (others => '0'); signal sig_len_btt_slice_minus_1 : unsigned(BTT_SLICE_SIZE-1 downto 0) := (others => '0'); signal sig_len2use : unsigned(BTT_SLICE_SIZE-1 downto 0) := (others => '0'); begin -- LEN Calculation logic ------------------------------------------ sig_next_len <= STD_LOGIC_VECTOR(RESIZE(sig_len2use, LEN_WIDTH)); sig_len_btt_slice <= UNSIGNED(sig_cmd_btt_reg(CMD_BTT_MS_INDEX downto 0)); sig_len_btt_slice_minus_1 <= sig_len_btt_slice-BTT_SLICE_ONE when sig_btt_is_zero_reg = '0' else (others => '0'); -- clip at zero -- If most significant bit of BTT set then limit to -- Max Burst Len, else rip it from the BTT value, -- otheriwse subtract 1 from the BTT ripped value -- 1 from the BTT ripped value sig_len2use <= MAX_BURST_LEN_US When (sig_cmd_btt_reg(CMD_BTT_MS_INDEX) = '1') Else sig_len_btt_slice_minus_1; end generate GEN_NO_RESIDUE_BITS; ------------------------------------------------------------ -- If Generate -- -- Label: GEN_HAS_RESIDUE_BITS -- -- If Generate Description: -- -- -- ------------------------------------------------------------ GEN_HAS_RESIDUE_BITS : if (BTT_LS_UNUSED_WIDTH > 0) generate -- signals signal sig_btt_len_residue : unsigned(BTT_LS_UNUSED_WIDTH-1 downto 0) := (others => '0'); signal sig_len_btt_slice : unsigned(BTT_SLICE_SIZE-1 downto 0) := (others => '0'); signal sig_len_btt_slice_minus_1 : unsigned(BTT_SLICE_SIZE-1 downto 0) := (others => '0'); signal sig_len2use : unsigned(BTT_SLICE_SIZE-1 downto 0) := (others => '0'); begin -- LEN Calculation logic ------------------------------------------ WR_EXTRA_FIELDS : if (C_ENABLE_EXTRA_FIELD = 1) generate sig_next_len <= "00000000" when sig_cmd_tag_reg (0) = '1' else "00000101"; --STD_LOGIC_VECTOR(RESIZE(sig_len2use, LEN_WIDTH)); end generate WR_EXTRA_FIELDS; NOWR_EXTRA_FIELDS : if (C_ENABLE_EXTRA_FIELD = 0) generate sig_next_len <= "00000000"; end generate NOWR_EXTRA_FIELDS; -- sig_next_len <= STD_LOGIC_VECTOR(RESIZE(sig_len2use, LEN_WIDTH)); sig_len_btt_slice <= UNSIGNED(sig_cmd_btt_reg(CMD_BTT_MS_INDEX downto BTT_LS_UNUSED_WIDTH)); sig_len_btt_slice_minus_1 <= sig_len_btt_slice-BTT_SLICE_ONE when sig_btt_is_zero_reg = '0' else (others => '0'); -- clip at zero sig_btt_len_residue <= UNSIGNED(sig_cmd_btt_reg(BTT_LS_UNUSED_WIDTH-1 downto 0)); -- If most significant bit of BTT set then limit to -- Max Burst Len, else rip it from the BTT value -- However if residue bits are zeroes then subtract -- 1 from the BTT ripped value sig_len2use <= MAX_BURST_LEN_US When (sig_cmd_btt_reg(CMD_BTT_MS_INDEX) = '1') Else sig_len_btt_slice_minus_1 when (sig_btt_len_residue = BTT_RESIDUE_ZEROS) Else sig_len_btt_slice; end generate GEN_HAS_RESIDUE_BITS; ------------------------------------------------------------- -- Synchronous Process with Sync Reset -- -- Label: REG_INPUT_CMD -- -- Process Description: -- Implements the input command holding registers -- ------------------------------------------------------------- REG_INPUT_CMD : process (primary_aclk) begin if (primary_aclk'event and primary_aclk = '1') then if (mmap_reset = '1' or addr2mstr_cmd_ready = '0') then -- sm_pop_input_cmd = '1') then sig_cmd_btt_reg <= (others => '0'); sig_cmd_type_reg <= '0'; sig_cmd_addr_reg <= (others => '0'); sig_cmd_tag_reg <= (others => '0'); sig_btt_is_zero_reg <= '0'; sig_cmd_reg_empty <= '1'; sig_cmd_reg_full <= '0'; sig_cmd_burst_reg <= "00"; sig_cmd2addr_valid1 <= '0'; elsif (sig_load_input_cmd = '1') then sig_cmd_btt_reg <= sig_cmd_btt_slice; sig_cmd_type_reg <= cmd2mstr_command(CMD_TYPE_INDEX); sig_cmd_addr_reg <= cmd2mstr_command(CMD_ADDR_MS_INDEX downto CMD_ADDR_LS_INDEX); sig_cmd_tag_reg <= cmd2mstr_command(CMD_TAG_MS_INDEX downto CMD_TAG_LS_INDEX); sig_btt_is_zero_reg <= sig_btt_is_zero; sig_cmd_reg_empty <= '0'; sig_cmd_reg_full <= '1'; sig_cmd2addr_valid1 <= '1'; sig_cmd_burst_reg <= sig_next_burst; else null; -- Hold current State end if; end if; end process REG_INPUT_CMD; -- Only Incrementing Burst type supported (per Interface_X guidelines) sig_next_burst <= AXI_BURST_INCR when (cmd2mstr_command(CMD_TYPE_INDEX) = '1') else AXI_BURST_FIXED; sig_next_user <= cache2mstr_command (7 downto 4); sig_next_cache <= cache2mstr_command (3 downto 0); ------------------------------------------------------------ -- If Generate -- -- Label: GEN_LEN_SDWIDTH_64 -- -- If Generate Description: -- This IfGen implements the AXI LEN qualifier calculation -- and the Stream data channel start/end STRB value. -- -- This IfGen is for the 64-bit Stream data Width case. -- ------------------------------------------------------------ GEN_LEN_SDWIDTH_64 : if (C_STREAM_DWIDTH = 64) generate -- Local Constants Constant AXI_SIZE2USE : std_logic_vector(2 downto 0) := AXI_SIZE_8BYTE; Constant RESIDUE_BIT_WIDTH : integer := 3; -- local signals signal sig_last_strb2use : std_logic_vector(STRB_WIDTH-1 downto 0) := (others => '0'); signal sig_last_strb : std_logic_vector(STRB_WIDTH-1 downto 0) := (others => '0'); Signal sig_btt_ms_bit_value : std_logic := '0'; signal lsig_btt_len_residue : std_logic_vector(BTT_LS_UNUSED_WIDTH-1 downto 0) := (others => '0'); signal sig_btt_len_residue_composite : std_logic_vector(RESIDUE_BIT_WIDTH downto 0) := (others => '0'); -- note 1 extra bit implied begin -- Assign the Address Channel Controller Size Qualifier Value sig_next_size <= AXI_SIZE2USE; -- Assign the Strobe Values sig_next_strt_strb <= (others => '1'); -- always aligned on first databeat for LITE DataMover sig_next_end_strb <= sig_last_strb; -- Local calculations ------------------------------ lsig_btt_len_residue <= sig_cmd_btt_reg(BTT_LS_UNUSED_WIDTH-1 downto 0); sig_btt_ms_bit_value <= sig_cmd_btt_reg(CMD_BTT_MS_INDEX); sig_btt_len_residue_composite <= sig_btt_ms_bit_value & lsig_btt_len_residue; ------------------------------------------------------------- -- Combinational Process -- -- Label: IMP_LAST_STRB_8bit -- -- Process Description: -- Generates the Strobe values for the LAST databeat of the -- Burst to MMap when the Stream is 64 bits wide and 8 strobe -- bits are required. -- ------------------------------------------------------------- IMP_LAST_STRB_8bit : process (sig_btt_len_residue_composite) begin case sig_btt_len_residue_composite is when "0001" => sig_last_strb <= "00000001"; when "0010" => sig_last_strb <= "00000011"; when "0011" => sig_last_strb <= "00000111"; when "0100" => sig_last_strb <= "00001111"; when "0101" => sig_last_strb <= "00011111"; when "0110" => sig_last_strb <= "00111111"; when "0111" => sig_last_strb <= "01111111"; when others => sig_last_strb <= "11111111"; end case; end process IMP_LAST_STRB_8bit; end generate GEN_LEN_SDWIDTH_64; ------------------------------------------------------------ -- If Generate -- -- Label: GEN_LEN_SDWIDTH_32 -- -- If Generate Description: -- This IfGen implements the AXI LEN qualifier calculation -- and the Stream data channel start/end STRB value. -- -- This IfGen is for the 32-bit Stream data Width case. -- ------------------------------------------------------------ GEN_LEN_SDWIDTH_32 : if (C_STREAM_DWIDTH = 32) generate -- Local Constants Constant AXI_SIZE2USE : std_logic_vector(2 downto 0) := AXI_SIZE_4BYTE; Constant RESIDUE_BIT_WIDTH : integer := 2; -- local signals signal sig_last_strb2use : std_logic_vector(STRB_WIDTH-1 downto 0) := (others => '0'); signal sig_last_strb : std_logic_vector(STRB_WIDTH-1 downto 0) := (others => '0'); Signal sig_btt_ms_bit_value : std_logic := '0'; signal sig_btt_len_residue_composite : std_logic_vector(RESIDUE_BIT_WIDTH downto 0) := (others => '0'); -- 1 extra bit signal lsig_btt_len_residue : std_logic_vector(BTT_LS_UNUSED_WIDTH-1 downto 0) := (others => '0'); begin -- Assign the Address Channel Controller Size Qualifier Value sig_next_size <= AXI_SIZE2USE; -- Assign the Strobe Values sig_next_strt_strb <= (others => '1'); -- always aligned on first databeat for LITE DataMover sig_next_end_strb <= sig_last_strb; -- Local calculations ------------------------------ lsig_btt_len_residue <= sig_cmd_btt_reg(BTT_LS_UNUSED_WIDTH-1 downto 0); sig_btt_ms_bit_value <= sig_cmd_btt_reg(CMD_BTT_MS_INDEX); sig_btt_len_residue_composite <= sig_btt_ms_bit_value & lsig_btt_len_residue; ------------------------------------------------------------- -- Combinational Process -- -- Label: IMP_LAST_STRB_4bit -- -- Process Description: -- Generates the Strobe values for the LAST databeat of the -- Burst to MMap when the Stream is 32 bits wide and 4 strobe -- bits are required. -- ------------------------------------------------------------- IMP_LAST_STRB_4bit : process (sig_btt_len_residue_composite) begin case sig_btt_len_residue_composite is -- coverage off when "001" => sig_last_strb <= "0001"; when "010" => sig_last_strb <= "0011"; when "011" => sig_last_strb <= "0111"; -- coverage on when others => sig_last_strb <= "1111"; end case; end process IMP_LAST_STRB_4bit; end generate GEN_LEN_SDWIDTH_32; ------------------------------------------------------------ -- If Generate -- -- Label: GEN_LEN_SDWIDTH_16 -- -- If Generate Description: -- This IfGen implements the AXI LEN qualifier calculation -- and the Stream data channel start/end STRB value. -- -- This IfGen is for the 16-bit Stream data Width case. -- ------------------------------------------------------------ GEN_LEN_SDWIDTH_16 : if (C_STREAM_DWIDTH = 16) generate -- Local Constants Constant AXI_SIZE2USE : std_logic_vector(2 downto 0) := AXI_SIZE_2BYTE; Constant RESIDUE_BIT_WIDTH : integer := 1; -- local signals signal sig_last_strb2use : std_logic_vector(STRB_WIDTH-1 downto 0) := (others => '0'); signal sig_last_strb : std_logic_vector(STRB_WIDTH-1 downto 0) := (others => '0'); Signal sig_btt_ms_bit_value : std_logic := '0'; signal sig_btt_len_residue_composite : std_logic_vector(RESIDUE_BIT_WIDTH downto 0) := (others => '0'); -- 1 extra bit signal lsig_btt_len_residue : std_logic_vector(BTT_LS_UNUSED_WIDTH-1 downto 0) := (others => '0'); begin -- Assign the Address Channel Controller Size Qualifier Value sig_next_size <= AXI_SIZE2USE; -- Assign the Strobe Values sig_next_strt_strb <= (others => '1'); -- always aligned on first databeat for LITE DataMover sig_next_end_strb <= sig_last_strb; -- Local calculations ------------------------------ lsig_btt_len_residue <= sig_cmd_btt_reg(BTT_LS_UNUSED_WIDTH-1 downto 0); sig_btt_ms_bit_value <= sig_cmd_btt_reg(CMD_BTT_MS_INDEX); sig_btt_len_residue_composite <= sig_btt_ms_bit_value & lsig_btt_len_residue; ------------------------------------------------------------- -- Combinational Process -- -- Label: IMP_LAST_STRB_2bit -- -- Process Description: -- Generates the Strobe values for the LAST databeat of the -- Burst to MMap when the Stream is 16 bits wide and 2 strobe -- bits are required. -- ------------------------------------------------------------- IMP_LAST_STRB_2bit : process (sig_btt_len_residue_composite) begin case sig_btt_len_residue_composite is when "01" => sig_last_strb <= "01"; when others => sig_last_strb <= "11"; end case; end process IMP_LAST_STRB_2bit; end generate GEN_LEN_SDWIDTH_16; ------------------------------------------------------------ -- If Generate -- -- Label: GEN_LEN_SDWIDTH_8 -- -- If Generate Description: -- This IfGen implements the AXI LEN qualifier calculation -- and the Stream data channel start/end STRB value. -- -- This IfGen is for the 8-bit Stream data Width case. -- ------------------------------------------------------------ GEN_LEN_SDWIDTH_8 : if (C_STREAM_DWIDTH = 8) generate -- Local Constants Constant AXI_SIZE2USE : std_logic_vector(2 downto 0) := AXI_SIZE_1BYTE; begin -- Assign the Address Channel Controller Qualifiers sig_next_size <= AXI_SIZE2USE; -- Assign the Data Channel Controller Qualifiers sig_next_strt_strb <= (others => '1'); sig_next_end_strb <= (others => '1'); end generate GEN_LEN_SDWIDTH_8; ------------------------------------------------------------- -- Synchronous Process with Sync Reset -- -- Label: CMD2DATA_VALID_FLOP -- -- Process Description: -- Implements the set/reset flop for the Command Ready control -- to the Data Controller Module. -- ------------------------------------------------------------- CMD2DATA_VALID_FLOP : process (primary_aclk) begin if (primary_aclk'event and primary_aclk = '1') then if (mmap_reset = '1' or sig_clr_cmd2data_valid = '1') then sig_cmd2data_valid <= '0'; elsif (sm_set_push2axi_ns = '1') then sig_cmd2data_valid <= '1'; else null; -- hold current state end if; end if; end process CMD2DATA_VALID_FLOP; ------------------------------------------------------------- -- Synchronous Process with Sync Reset -- -- Label: CMD2ADDR_VALID_FLOP -- -- Process Description: -- Implements the set/reset flop for the Command Ready control -- to the Address Controller Module. -- ------------------------------------------------------------- CMD2ADDR_VALID_FLOP : process (primary_aclk) begin if (primary_aclk'event and primary_aclk = '1') then if (mmap_reset = '1' or sig_clr_cmd2addr_valid = '1') then sig_cmd2addr_valid <= '0'; elsif (sm_set_push2axi_ns = '1') then sig_cmd2addr_valid <= '1'; else null; -- hold current state end if; end if; end process CMD2ADDR_VALID_FLOP; ------------------------------------------------------------- -- Synchronous Process with Sync Reset -- -- Label: SCC_SM_REG -- -- Process Description: -- Implements registered portion of state machine -- ------------------------------------------------------------- SCC_SM_REG : process (primary_aclk) begin if (primary_aclk'event and primary_aclk = '1') then if (mmap_reset = '1') then -- sm_scc_state <= INIT; -- sm_pop_input_cmd <= '0' ; -- sm_set_push2axi <= '0' ; sm_set_error <= '0' ; -- sm_scc_sm_ready <= '0' ; elsif (sig_btt_is_zero_reg = '1') then sm_set_error <= '1'; -- sm_scc_state <= sm_scc_state_ns ; -- sm_pop_input_cmd <= sm_pop_input_cmd_ns ; -- sm_set_push2axi <= sm_set_push2axi_ns ; -- sm_set_error <= sm_set_error_ns ; -- sm_scc_sm_ready <= sm_scc_sm_ready_ns ; end if; end if; end process SCC_SM_REG; end implementation;	gpl-3.0	96fe44f55d29501cc9aff291722adf2f	0.440891	4.716837	false	false	false	false
Fairyland0902/BlockyRoads	src/BlockyRoads/ipcore_dir/side/example_design/side_prod.vhd	1	9,891	-------------------------------------------------------------------------------- -- -- BLK MEM GEN v7.1 Core - Top-level wrapper -- -------------------------------------------------------------------------------- -- -- (c) Copyright 2006-2011 Xilinx, Inc. All rights reserved. -- -- This file contains confidential and proprietary information -- of Xilinx, Inc. and is protected under U.S. and -- international copyright and other intellectual property -- laws. -- -- DISCLAIMER -- This disclaimer is not a license and does not grant any -- rights to the materials distributed herewith. Except as -- otherwise provided in a valid license issued to you by -- Xilinx, and to the maximum extent permitted by applicable -- law: (1) THESE MATERIALS ARE MADE AVAILABLE "AS IS" AND -- WITH ALL FAULTS, AND XILINX HEREBY DISCLAIMS ALL WARRANTIES -- AND CONDITIONS, EXPRESS, IMPLIED, OR STATUTORY, INCLUDING -- BUT NOT LIMITED TO WARRANTIES OF MERCHANTABILITY, NON- -- INFRINGEMENT, OR FITNESS FOR ANY PARTICULAR PURPOSE; and -- (2) Xilinx shall not be liable (whether in contract or tort, -- including negligence, or under any other theory of -- liability) for any loss or damage of any kind or nature -- related to, arising under or in connection with these -- materials, including for any direct, or any indirect, -- special, incidental, or consequential loss or damage -- (including loss of data, profits, goodwill, or any type of -- loss or damage suffered as a result of any action brought -- by a third party) even if such damage or loss was -- reasonably foreseeable or Xilinx had been advised of the -- possibility of the same. -- -- CRITICAL APPLICATIONS -- Xilinx products are not designed or intended to be fail- -- safe, or for use in any application requiring fail-safe -- performance, such as life-support or safety devices or -- systems, Class III medical devices, nuclear facilities, -- applications related to the deployment of airbags, or any -- other applications that could lead to death, personal -- injury, or severe property or environmental damage -- (individually and collectively, "Critical -- Applications"). Customer assumes the sole risk and -- liability of any use of Xilinx products in Critical -- Applications, subject only to applicable laws and -- regulations governing limitations on product liability. -- -- THIS COPYRIGHT NOTICE AND DISCLAIMER MUST BE RETAINED AS -- PART OF THIS FILE AT ALL TIMES. -- -------------------------------------------------------------------------------- -- -- Filename: side_prod.vhd -- -- Description: -- This is the top-level BMG wrapper (over BMG core). -- -------------------------------------------------------------------------------- -- Author: IP Solutions Division -- -- History: August 31, 2005 - First Release -------------------------------------------------------------------------------- -- -- Configured Core Parameter Values: -- (Refer to the SIM Parameters table in the datasheet for more information on -- the these parameters.) -- C_FAMILY : artix7 -- C_XDEVICEFAMILY : artix7 -- C_INTERFACE_TYPE : 0 -- C_ENABLE_32BIT_ADDRESS : 0 -- C_AXI_TYPE : 1 -- C_AXI_SLAVE_TYPE : 0 -- C_AXI_ID_WIDTH : 4 -- C_MEM_TYPE : 3 -- C_BYTE_SIZE : 9 -- C_ALGORITHM : 1 -- C_PRIM_TYPE : 1 -- C_LOAD_INIT_FILE : 1 -- C_INIT_FILE_NAME : side.mif -- C_USE_DEFAULT_DATA : 0 -- C_DEFAULT_DATA : 0 -- C_RST_TYPE : SYNC -- C_HAS_RSTA : 0 -- C_RST_PRIORITY_A : CE -- C_RSTRAM_A : 0 -- C_INITA_VAL : 0 -- C_HAS_ENA : 0 -- C_HAS_REGCEA : 0 -- C_USE_BYTE_WEA : 0 -- C_WEA_WIDTH : 1 -- C_WRITE_MODE_A : WRITE_FIRST -- C_WRITE_WIDTH_A : 12 -- C_READ_WIDTH_A : 12 -- C_WRITE_DEPTH_A : 76800 -- C_READ_DEPTH_A : 76800 -- C_ADDRA_WIDTH : 17 -- C_HAS_RSTB : 0 -- C_RST_PRIORITY_B : CE -- C_RSTRAM_B : 0 -- C_INITB_VAL : 0 -- C_HAS_ENB : 0 -- C_HAS_REGCEB : 0 -- C_USE_BYTE_WEB : 0 -- C_WEB_WIDTH : 1 -- C_WRITE_MODE_B : WRITE_FIRST -- C_WRITE_WIDTH_B : 12 -- C_READ_WIDTH_B : 12 -- C_WRITE_DEPTH_B : 76800 -- C_READ_DEPTH_B : 76800 -- C_ADDRB_WIDTH : 17 -- C_HAS_MEM_OUTPUT_REGS_A : 0 -- C_HAS_MEM_OUTPUT_REGS_B : 0 -- C_HAS_MUX_OUTPUT_REGS_A : 0 -- C_HAS_MUX_OUTPUT_REGS_B : 0 -- C_HAS_SOFTECC_INPUT_REGS_A : 0 -- C_HAS_SOFTECC_OUTPUT_REGS_B : 0 -- C_MUX_PIPELINE_STAGES : 0 -- C_USE_ECC : 0 -- C_USE_SOFTECC : 0 -- C_HAS_INJECTERR : 0 -- C_SIM_COLLISION_CHECK : ALL -- C_COMMON_CLK : 0 -- C_DISABLE_WARN_BHV_COLL : 0 -- C_DISABLE_WARN_BHV_RANGE : 0 -------------------------------------------------------------------------------- -- Library Declarations -------------------------------------------------------------------------------- LIBRARY IEEE; USE IEEE.STD_LOGIC_1164.ALL; USE IEEE.STD_LOGIC_ARITH.ALL; USE IEEE.STD_LOGIC_UNSIGNED.ALL; LIBRARY UNISIM; USE UNISIM.VCOMPONENTS.ALL; -------------------------------------------------------------------------------- -- Entity Declaration -------------------------------------------------------------------------------- ENTITY side_prod IS PORT ( --Port A CLKA : IN STD_LOGIC; RSTA : IN STD_LOGIC; --opt port ENA : IN STD_LOGIC; --optional port REGCEA : IN STD_LOGIC; --optional port WEA : IN STD_LOGIC_VECTOR(0 DOWNTO 0); ADDRA : IN STD_LOGIC_VECTOR(16 DOWNTO 0); DINA : IN STD_LOGIC_VECTOR(11 DOWNTO 0); DOUTA : OUT STD_LOGIC_VECTOR(11 DOWNTO 0); --Port B CLKB : IN STD_LOGIC; RSTB : IN STD_LOGIC; --opt port ENB : IN STD_LOGIC; --optional port REGCEB : IN STD_LOGIC; --optional port WEB : IN STD_LOGIC_VECTOR(0 DOWNTO 0); ADDRB : IN STD_LOGIC_VECTOR(16 DOWNTO 0); DINB : IN STD_LOGIC_VECTOR(11 DOWNTO 0); DOUTB : OUT STD_LOGIC_VECTOR(11 DOWNTO 0); --ECC INJECTSBITERR : IN STD_LOGIC; --optional port INJECTDBITERR : IN STD_LOGIC; --optional port SBITERR : OUT STD_LOGIC; --optional port DBITERR : OUT STD_LOGIC; --optional port RDADDRECC : OUT STD_LOGIC_VECTOR(16 DOWNTO 0); --optional port -- AXI BMG Input and Output Port Declarations -- AXI Global Signals S_ACLK : IN STD_LOGIC; S_AXI_AWID : IN STD_LOGIC_VECTOR(3 DOWNTO 0); S_AXI_AWADDR : IN STD_LOGIC_VECTOR(31 DOWNTO 0); S_AXI_AWLEN : IN STD_LOGIC_VECTOR(7 DOWNTO 0); S_AXI_AWSIZE : IN STD_LOGIC_VECTOR(2 DOWNTO 0); S_AXI_AWBURST : IN STD_LOGIC_VECTOR(1 DOWNTO 0); S_AXI_AWVALID : IN STD_LOGIC; S_AXI_AWREADY : OUT STD_LOGIC; S_AXI_WDATA : IN STD_LOGIC_VECTOR(11 DOWNTO 0); S_AXI_WSTRB : IN STD_LOGIC_VECTOR(0 DOWNTO 0); S_AXI_WLAST : IN STD_LOGIC; S_AXI_WVALID : IN STD_LOGIC; S_AXI_WREADY : OUT STD_LOGIC; S_AXI_BID : OUT STD_LOGIC_VECTOR(3 DOWNTO 0):= (OTHERS => '0'); S_AXI_BRESP : OUT STD_LOGIC_VECTOR(1 DOWNTO 0); S_AXI_BVALID : OUT STD_LOGIC; S_AXI_BREADY : IN STD_LOGIC; -- AXI Full/Lite Slave Read (Write side) S_AXI_ARID : IN STD_LOGIC_VECTOR(3 DOWNTO 0); S_AXI_ARADDR : IN STD_LOGIC_VECTOR(31 DOWNTO 0); S_AXI_ARLEN : IN STD_LOGIC_VECTOR(7 DOWNTO 0); S_AXI_ARSIZE : IN STD_LOGIC_VECTOR(2 DOWNTO 0); S_AXI_ARBURST : IN STD_LOGIC_VECTOR(1 DOWNTO 0); S_AXI_ARVALID : IN STD_LOGIC; S_AXI_ARREADY : OUT STD_LOGIC; S_AXI_RID : OUT STD_LOGIC_VECTOR(3 DOWNTO 0):= (OTHERS => '0'); S_AXI_RDATA : OUT STD_LOGIC_VECTOR(11 DOWNTO 0); S_AXI_RRESP : OUT STD_LOGIC_VECTOR(1 DOWNTO 0); S_AXI_RLAST : OUT STD_LOGIC; S_AXI_RVALID : OUT STD_LOGIC; S_AXI_RREADY : IN STD_LOGIC; -- AXI Full/Lite Sideband Signals S_AXI_INJECTSBITERR : IN STD_LOGIC; S_AXI_INJECTDBITERR : IN STD_LOGIC; S_AXI_SBITERR : OUT STD_LOGIC; S_AXI_DBITERR : OUT STD_LOGIC; S_AXI_RDADDRECC : OUT STD_LOGIC_VECTOR(16 DOWNTO 0); S_ARESETN : IN STD_LOGIC ); END side_prod; ARCHITECTURE xilinx OF side_prod IS COMPONENT side_exdes IS PORT ( --Port A ADDRA : IN STD_LOGIC_VECTOR(16 DOWNTO 0); DOUTA : OUT STD_LOGIC_VECTOR(11 DOWNTO 0); CLKA : IN STD_LOGIC ); END COMPONENT; BEGIN bmg0 : side_exdes PORT MAP ( --Port A ADDRA => ADDRA, DOUTA => DOUTA, CLKA => CLKA ); END xilinx;	mit	647cf060539644620b57709379457c62	0.493984	3.835207	false	false	false	false
marco-c/leon-nexys2	grlib-gpl-1.3.4-b4140/lib/techmap/inferred/mul_inferred.vhd	1	4,244	------------------------------------------------------------------------------ -- This file is a part of the GRLIB VHDL IP LIBRARY -- Copyright (C) 2003 - 2008, Gaisler Research -- Copyright (C) 2008 - 2013, Aeroflex Gaisler -- -- This program is free software; you can redistribute it and/or modify -- it under the terms of the GNU General Public License as published by -- the Free Software Foundation; either version 2 of the License, or -- (at your option) any later version. -- -- This program is distributed in the hope that it will be useful, -- but WITHOUT ANY WARRANTY; without even the implied warranty of -- MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the -- GNU General Public License for more details. -- -- You should have received a copy of the GNU General Public License -- along with this program; if not, write to the Free Software -- Foundation, Inc., 59 Temple Place, Suite 330, Boston, MA 02111-1307 USA ----------------------------------------------------------------------------- -- Entity: gen_mul_61x61 -- File: mul_inferred.vhd -- Author: Edvin Catovic - Gaisler Research -- Description: Generic 61x61 multplier ------------------------------------------------------------------------------ library ieee; use ieee.std_logic_1164.all; use ieee.numeric_std.all; library grlib; use grlib.stdlib.all; entity gen_mul_61x61 is port(A : in std_logic_vector(60 downto 0); B : in std_logic_vector(60 downto 0); EN : in std_logic; CLK : in std_logic; PRODUCT : out std_logic_vector(121 downto 0)); end; architecture rtl of gen_mul_61x61 is signal r1, r1in, r2, r2in : std_logic_vector(121 downto 0); begin comb : process(A, B, r1) begin -- pragma translate_off if not (is_x(A) or is_x(B)) then -- pragma translate_on r1in <= std_logic_vector(unsigned(A) * unsigned(B)); -- pragma translate_off end if; -- pragma translate_on r2in <= r1; end process; reg : process(clk) begin if rising_edge(clk) then if EN = '1' then r1 <= r1in; r2 <= r2in; end if; end if; end process; PRODUCT <= r2; end; library IEEE; use IEEE.std_logic_1164.all; use IEEE.std_logic_arith.all; library grlib; use grlib.stdlib.all; entity gen_mult_pipe is generic ( a_width : positive; -- multiplier word width b_width : positive; -- multiplicand word width num_stages : positive := 2; -- number of pipeline stages stall_mode : natural range 0 to 1 := 1); -- '0': non-stallable; '1': stallable port ( clk : in std_logic; -- register clock en : in std_logic; -- register enable tc : in std_logic; -- '0' : unsigned, '1' : signed a : in std_logic_vector(a_width-1 downto 0); -- multiplier b : in std_logic_vector(b_width-1 downto 0); -- multiplicand product : out std_logic_vector(a_width+b_width-1 downto 0)); -- product end ; architecture simple of gen_mult_pipe is subtype resw is std_logic_vector(A_width+B_width-1 downto 0); type pipet is array (num_stages-1 downto 1) of resw; signal p_i : pipet; signal prod : resw; begin comb : process(A, B, TC) begin -- pragma translate_off if notx(A) and notx(B) and notx(tc) then -- pragma translate_on if TC = '1' then prod <= signed(A) * signed(B); else prod <= unsigned(A) * unsigned(B); end if; -- pragma translate_off else prod <= (others => 'X'); end if; -- pragma translate_on end process; w2 : if num_stages = 2 generate reg : process(clk) begin if rising_edge(clk) then if (stall_mode = 0) or (en = '1') then p_i(1) <= prod; end if; end if; end process; end generate; w3 : if num_stages > 2 generate reg : process(clk) begin if rising_edge(clk) then if (stall_mode = 0) or (en = '1') then p_i <= p_i(num_stages-2 downto 1) & prod; end if; end if; end process; end generate; product <= p_i(num_stages-1); end;	gpl-2.0	3f2f71ec8eb001a17149b935abd97ace	0.56951	3.566387	false	false	false	false
capitanov/Stupid_watch	src/rtl/keyboard/debounce.vhd	1	2,498	-------------------------------------------------------------------------------- -- -- FileName: debounce.vhd -- Dependencies: none -- Design Software: Quartus II 32-bit Version 11.1 Build 173 SJ Full Version -- -- HDL CODE IS PROVIDED "AS IS." DIGI-KEY EXPRESSLY DISCLAIMS ANY -- WARRANTY OF ANY KIND, WHETHER EXPRESS OR IMPLIED, INCLUDING BUT NOT -- LIMITED TO, THE IMPLIED WARRANTIES OF MERCHANTABILITY, FITNESS FOR A -- PARTICULAR PURPOSE, OR NON-INFRINGEMENT. IN NO EVENT SHALL DIGI-KEY -- BE LIABLE FOR ANY INCIDENTAL, SPECIAL, INDIRECT OR CONSEQUENTIAL -- DAMAGES, LOST PROFITS OR LOST DATA, HARM TO YOUR EQUIPMENT, COST OF -- PROCUREMENT OF SUBSTITUTE GOODS, TECHNOLOGY OR SERVICES, ANY CLAIMS -- BY THIRD PARTIES (INCLUDING BUT NOT LIMITED TO ANY DEFENSE THEREOF), -- ANY CLAIMS FOR INDEMNITY OR CONTRIBUTION, OR OTHER SIMILAR COSTS. -- -- Version History -- Version 1.0 3/26/2012 Scott Larson -- Initial Public Release -- -------------------------------------------------------------------------------- LIBRARY ieee; USE ieee.std_logic_1164.all; USE ieee.std_logic_unsigned.all; entity debounce is generic( counter_size : integer --! counter size (19 bits gives 10.5ms with 50MHz clock) ); port( clk : in std_logic; --! input clock button : in std_logic; --! input signal to be debounced result : out std_logic --! debounced signal ); end debounce; architecture debounce of debounce is signal flipflops : std_logic_vector(1 downto 0); --input flip flops signal counter_set : std_logic; --sync reset to zero signal counter_out : std_logic_vector(counter_size downto 0) := (others => '0'); --counter output begin counter_set <= flipflops(0) xor flipflops(1); --determine when to start/reset counter pr_deb: process(clk) begin if (clk'event and clk = '1') then flipflops(0) <= button; flipflops(1) <= flipflops(0); if (counter_set = '1') then --reset counter because input is changing counter_out <= (others => '0'); elsif (counter_out(counter_size) = '0') then --stable input time is not yet met counter_out <= counter_out + 1; else --stable input time is met result <= flipflops(1); end if; end if; end process; end debounce;	mit	ab0d1eb681b87232402c4178e26f1512	0.580064	4.321799	false	false	false	false
marco-c/leon-nexys2	grlib-gpl-1.3.4-b4140/designs/leon3-altera-ep2s60-sdr/config.vhd	1	5,586	----------------------------------------------------------------------------- -- LEON3 Demonstration design test bench configuration -- Copyright (C) 2009 Aeroflex Gaisler ------------------------------------------------------------------------------ library techmap; use techmap.gencomp.all; package config is -- Technology and synthesis options constant CFG_FABTECH : integer := stratix2; constant CFG_MEMTECH : integer := stratix2; constant CFG_PADTECH : integer := stratix2; constant CFG_NOASYNC : integer := 0; constant CFG_SCAN : integer := 0; -- Clock generator constant CFG_CLKTECH : integer := stratix2; constant CFG_CLKMUL : integer := (8); constant CFG_CLKDIV : integer := (10); constant CFG_OCLKDIV : integer := 1; constant CFG_OCLKBDIV : integer := 0; constant CFG_OCLKCDIV : integer := 0; constant CFG_PCIDLL : integer := 0; constant CFG_PCISYSCLK: integer := 0; constant CFG_CLK_NOFB : integer := 0; -- LEON3 processor core constant CFG_LEON3 : integer := 1; constant CFG_NCPU : integer := (1); constant CFG_NWIN : integer := (8); constant CFG_V8 : integer := 2 + 40; constant CFG_MAC : integer := 0; constant CFG_BP : integer := 0; constant CFG_SVT : integer := 0; constant CFG_RSTADDR : integer := 16#00000#; constant CFG_LDDEL : integer := (1); constant CFG_NOTAG : integer := 0; constant CFG_NWP : integer := (2); constant CFG_PWD : integer := 02; constant CFG_FPU : integer := 0 + 160 + 320; constant CFG_GRFPUSH : integer := 0; constant CFG_ICEN : integer := 1; constant CFG_ISETS : integer := 2; constant CFG_ISETSZ : integer := 8; constant CFG_ILINE : integer := 8; constant CFG_IREPL : integer := 0; constant CFG_ILOCK : integer := 0; constant CFG_ILRAMEN : integer := 0; constant CFG_ILRAMADDR: integer := 16#8E#; constant CFG_ILRAMSZ : integer := 1; constant CFG_DCEN : integer := 1; constant CFG_DSETS : integer := 2; constant CFG_DSETSZ : integer := 4; constant CFG_DLINE : integer := 4; constant CFG_DREPL : integer := 0; constant CFG_DLOCK : integer := 0; constant CFG_DSNOOP : integer := 1 + 0 + 40; constant CFG_DFIXED : integer := 16#0#; constant CFG_DLRAMEN : integer := 0; constant CFG_DLRAMADDR: integer := 16#8F#; constant CFG_DLRAMSZ : integer := 1; constant CFG_MMUEN : integer := 1; constant CFG_ITLBNUM : integer := 8; constant CFG_DTLBNUM : integer := 8; constant CFG_TLB_TYPE : integer := 0 + 12; constant CFG_TLB_REP : integer := 0; constant CFG_MMU_PAGE : integer := 0; constant CFG_DSU : integer := 1; constant CFG_ITBSZ : integer := 2; constant CFG_ATBSZ : integer := 2; constant CFG_LEON3FT_EN : integer := 0; constant CFG_IUFT_EN : integer := 0; constant CFG_FPUFT_EN : integer := 0; constant CFG_RF_ERRINJ : integer := 0; constant CFG_CACHE_FT_EN : integer := 0; constant CFG_CACHE_ERRINJ : integer := 0; constant CFG_LEON3_NETLIST: integer := 0; constant CFG_DISAS : integer := 0 + 0; constant CFG_PCLOW : integer := 2; -- AMBA settings constant CFG_DEFMST : integer := (0); constant CFG_RROBIN : integer := 1; constant CFG_SPLIT : integer := 0; constant CFG_FPNPEN : integer := 0; constant CFG_AHBIO : integer := 16#FFF#; constant CFG_APBADDR : integer := 16#800#; constant CFG_AHB_MON : integer := 0; constant CFG_AHB_MONERR : integer := 0; constant CFG_AHB_MONWAR : integer := 0; constant CFG_AHB_DTRACE : integer := 0; -- DSU UART constant CFG_AHB_UART : integer := 1; -- JTAG based DSU interface constant CFG_AHB_JTAG : integer := 1; -- PROM/SRAM controller constant CFG_SRCTRL : integer := 0; constant CFG_SRCTRL_PROMWS : integer := 0; constant CFG_SRCTRL_RAMWS : integer := 0; constant CFG_SRCTRL_IOWS : integer := 0; constant CFG_SRCTRL_RMW : integer := 0; constant CFG_SRCTRL_8BIT : integer := 0; constant CFG_SRCTRL_SRBANKS : integer := 1; constant CFG_SRCTRL_BANKSZ : integer := 0; constant CFG_SRCTRL_ROMASEL : integer := 0; -- LEON2 memory controller constant CFG_MCTRL_LEON2 : integer := 1; constant CFG_MCTRL_RAM8BIT : integer := 1; constant CFG_MCTRL_RAM16BIT : integer := 0; constant CFG_MCTRL_5CS : integer := 0; constant CFG_MCTRL_SDEN : integer := 1; constant CFG_MCTRL_SEPBUS : integer := 1; constant CFG_MCTRL_INVCLK : integer := 0; constant CFG_MCTRL_SD64 : integer := 0; constant CFG_MCTRL_PAGE : integer := 1 + 0; -- AHB ROM constant CFG_AHBROMEN : integer := 0; constant CFG_AHBROPIP : integer := 0; constant CFG_AHBRODDR : integer := 16#000#; constant CFG_ROMADDR : integer := 16#000#; constant CFG_ROMMASK : integer := 16#E00# + 16#000#; -- AHB RAM constant CFG_AHBRAMEN : integer := 0; constant CFG_AHBRSZ : integer := 1; constant CFG_AHBRADDR : integer := 16#A00#; constant CFG_AHBRPIPE : integer := 0; -- UART 1 constant CFG_UART1_ENABLE : integer := 1; constant CFG_UART1_FIFO : integer := 8; -- LEON3 interrupt controller constant CFG_IRQ3_ENABLE : integer := 1; constant CFG_IRQ3_NSEC : integer := 0; -- Modular timer constant CFG_GPT_ENABLE : integer := 1; constant CFG_GPT_NTIM : integer := (2); constant CFG_GPT_SW : integer := (8); constant CFG_GPT_TW : integer := (32); constant CFG_GPT_IRQ : integer := (8); constant CFG_GPT_SEPIRQ : integer := 1; constant CFG_GPT_WDOGEN : integer := 0; constant CFG_GPT_WDOG : integer := 16#0#; -- GPIO port constant CFG_GRGPIO_ENABLE : integer := 1; constant CFG_GRGPIO_IMASK : integer := 16#FFFF#; constant CFG_GRGPIO_WIDTH : integer := (32); -- GRLIB debugging constant CFG_DUART : integer := 0; end;	gpl-2.0	43a50b3a7ca53553a0e7258e17f2a461	0.645184	3.670171	false	false	false	false
marco-c/leon-nexys2	grlib-gpl-1.3.4-b4140/designs/leon3-ztex-ufm-115/testbench.vhd	1	7,756	------------------------------------------------------------------------------- -- LEON3 Demonstration design test bench -- Copyright (C) 2011 Aeroflex Gaisler AB ------------------------------------------------------------------------------ -- This file is a part of the GRLIB VHDL IP LIBRARY -- Copyright (C) 2003 - 2008, Gaisler Research -- Copyright (C) 2008 - 2013, Aeroflex Gaisler -- -- This program is free software; you can redistribute it and/or modify -- it under the terms of the GNU General Public License as published by -- the Free Software Foundation; either version 2 of the License, or -- (at your option) any later version. -- -- This program is distributed in the hope that it will be useful, -- but WITHOUT ANY WARRANTY; without even the implied warranty of -- MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the -- GNU General Public License for more details. -- -- You should have received a copy of the GNU General Public License -- along with this program; if not, write to the Free Software -- Foundation, Inc., 59 Temple Place, Suite 330, Boston, MA 02111-1307 USA ------------------------------------------------------------------------------- library ieee; use ieee.std_logic_1164.all; library gaisler; use gaisler.libdcom.all; use gaisler.sim.all; library techmap; use techmap.gencomp.all; library micron; use micron.components.all; library hynix; use hynix.components.all; use work.debug.all; use work.config.all; library hynix; use hynix.components.all; use hynix.HY5PS121621F_PACK.all; entity testbench is generic ( fabtech : integer := CFG_FABTECH; memtech : integer := CFG_MEMTECH; padtech : integer := CFG_PADTECH; clktech : integer := CFG_CLKTECH; disas : integer := CFG_DISAS; -- Enable disassembly to console dbguart : integer := CFG_DUART; -- Print UART on console pclow : integer := CFG_PCLOW ); end; architecture behav of testbench is constant promfile : string := "prom.srec"; -- rom contents constant sdramfile : string := "ram.srec"; -- sdram contents constant lresp : boolean := false; signal reset : std_ulogic := '1'; signal clk48 : std_ulogic := '0'; signal errorn : std_logic; signal mcb3_dram_dq : std_logic_vector(15 downto 0); signal mcb3_rzq : std_logic; signal mcb3_zio : std_logic; signal mcb3_dram_udqs : std_logic; signal mcb3_dram_udqs_n : std_logic; signal mcb3_dram_dqs : std_logic; signal mcb3_dram_dqs_n : std_logic; signal mcb3_dram_a : std_logic_vector(12 downto 0); signal mcb3_dram_ba : std_logic_vector(2 downto 0); signal mcb3_dram_cke : std_logic; signal mcb3_dram_ras_n : std_logic; signal mcb3_dram_cas_n : std_logic; signal mcb3_dram_we_n : std_logic; signal mcb3_dram_dm : std_logic; signal mcb3_dram_udm : std_logic; signal mcb3_dram_ck : std_logic; signal mcb3_dram_ck_n : std_logic; signal dsubre : std_ulogic; -- Debug Unit break (connect to button) signal dsuact : std_ulogic; -- Debug Unit break (connect to button) signal dsurx : std_ulogic; signal dsutx : std_ulogic; signal rxd1 : std_ulogic; signal txd1 : std_ulogic; signal sd_dat : std_logic; signal sd_cmd : std_logic; signal sd_sck : std_logic; signal sd_dat3 : std_logic; signal csb : std_logic := '0'; -- dummy begin -- clock and reset clk48 <= not clk48 after 10.05 ns; reset <= '1', '0' after 300 ns; dsubre <= '0'; sd_dat <= 'H'; sd_cmd <= 'H'; sd_sck <= 'H'; d3 : entity work.leon3mp generic map (fabtech, memtech, padtech, clktech, disas, dbguart, pclow) port map ( reset => reset, clk48 => clk48, -- Processor error output errorn => errorn, -- DDR SDRAM mcb3_dram_dq => mcb3_dram_dq, mcb3_rzq => mcb3_rzq, mcb3_zio => mcb3_zio, mcb3_dram_udqs => mcb3_dram_udqs, mcb3_dram_udqs_n => mcb3_dram_udqs_n, mcb3_dram_dqs => mcb3_dram_dqs, mcb3_dram_dqs_n => mcb3_dram_dqs_n, mcb3_dram_a => mcb3_dram_a, mcb3_dram_ba => mcb3_dram_ba, mcb3_dram_cke => mcb3_dram_cke, mcb3_dram_ras_n => mcb3_dram_ras_n, mcb3_dram_cas_n => mcb3_dram_cas_n, mcb3_dram_we_n => mcb3_dram_we_n, mcb3_dram_dm => mcb3_dram_dm, mcb3_dram_udm => mcb3_dram_udm, mcb3_dram_ck => mcb3_dram_ck, mcb3_dram_ck_n => mcb3_dram_ck_n, -- Debug support unit dsubre => dsubre, dsuact => dsuact, -- AHB UART (debug link) dsurx => dsurx, dsutx => dsutx, -- UART rxd1 => rxd1, txd1 => txd1, -- SD card sd_dat => sd_dat, sd_cmd => sd_cmd, sd_sck => sd_sck, sd_dat3 => sd_dat3 ); migddr2mem : if (CFG_MIG_DDR2 = 1) generate u0 : HY5PS121621F generic map (TimingCheckFlag => false, PUSCheckFlag => false, index => 0, bbits => 16, fname => sdramfile, fdelay => 115, part_number => B800) port map (DQ => mcb3_dram_dq, LDQS => mcb3_dram_dqs, LDQSB => mcb3_dram_dqs_n, UDQS => mcb3_dram_udqs, UDQSB => mcb3_dram_udqs_n, LDM => mcb3_dram_dm, WEB => mcb3_dram_we_n, CASB => mcb3_dram_cas_n, RASB => mcb3_dram_ras_n, CSB => csb, BA => mcb3_dram_ba(1 downto 0), ADDR => mcb3_dram_a, CKE => mcb3_dram_cke, CLK => mcb3_dram_ck, CLKB => mcb3_dram_ck_n, UDM => mcb3_dram_udm); end generate; --spimem0: if CFG_SPIMCTRL = 1 generate -- s0 : spi_flash generic map (ftype => 4, debug => 0, fname => promfile, -- readcmd => CFG_SPIMCTRL_READCMD, -- dummybyte => CFG_SPIMCTRL_DUMMYBYTE, -- dualoutput => 0) -- Dual output is not supported in this design -- port map (spi_clk, spi_mosi, data(24), spi_sel_n); --end generate spimem0; iuerr : process begin wait for 5 us; assert (to_X01(errorn) = '1') report "* IU in error mode, simulation halted " severity failure; end process; dsucom : process procedure dsucfg(signal dsurx : in std_ulogic; signal dsutx : out std_ulogic) is variable w32 : std_logic_vector(31 downto 0); variable c8 : std_logic_vector(7 downto 0); constant txp : time := 160 1 ns; begin dsutx <= '1'; wait; wait for 5000 ns; txc(dsutx, 16#55#, txp); -- sync uart txc(dsutx, 16#a0#, txp); txa(dsutx, 16#40#, 16#00#, 16#00#, 16#00#, txp); rxi(dsurx, w32, txp, lresp); -- txc(dsutx, 16#c0#, txp); -- txa(dsutx, 16#90#, 16#00#, 16#00#, 16#00#, txp); -- txa(dsutx, 16#00#, 16#00#, 16#00#, 16#ef#, txp); -- -- txc(dsutx, 16#c0#, txp); -- txa(dsutx, 16#90#, 16#00#, 16#00#, 16#20#, txp); -- txa(dsutx, 16#00#, 16#00#, 16#ff#, 16#ff#, txp); -- -- txc(dsutx, 16#c0#, txp); -- txa(dsutx, 16#90#, 16#40#, 16#00#, 16#48#, txp); -- txa(dsutx, 16#00#, 16#00#, 16#00#, 16#12#, txp); -- -- txc(dsutx, 16#c0#, txp); -- txa(dsutx, 16#90#, 16#40#, 16#00#, 16#60#, txp); -- txa(dsutx, 16#00#, 16#00#, 16#12#, 16#10#, txp); -- -- txc(dsutx, 16#80#, txp); -- txa(dsutx, 16#90#, 16#00#, 16#00#, 16#00#, txp); -- rxi(dsurx, w32, txp, lresp); end; begin dsucfg(dsutx, dsurx); wait; end process; end;	gpl-2.0	855131504a4f344108d4444e2b14a596	0.54835	3.318785	false	false	false	false
mistryalok/Zedboard	learning/opencv_hls/xapp1167_vivado/sw/median/prj/solution1/syn/vhdl/image_filter_Mat2AXIvideo.vhd	2	23,118	-- ============================================================== -- RTL generated by Vivado(TM) HLS - High-Level Synthesis from C, C++ and SystemC -- Version: 2014.4 -- Copyright (C) 2014 Xilinx Inc. All rights reserved. -- -- =========================================================== library IEEE; use IEEE.std_logic_1164.all; use IEEE.numeric_std.all; entity image_filter_Mat2AXIvideo is port ( ap_clk : IN STD_LOGIC; ap_rst : IN STD_LOGIC; ap_start : IN STD_LOGIC; ap_done : OUT STD_LOGIC; ap_continue : IN STD_LOGIC; ap_idle : OUT STD_LOGIC; ap_ready : OUT STD_LOGIC; img_rows_V_read : IN STD_LOGIC_VECTOR (11 downto 0); img_cols_V_read : IN STD_LOGIC_VECTOR (11 downto 0); img_data_stream_0_V_dout : IN STD_LOGIC_VECTOR (7 downto 0); img_data_stream_0_V_empty_n : IN STD_LOGIC; img_data_stream_0_V_read : OUT STD_LOGIC; img_data_stream_1_V_dout : IN STD_LOGIC_VECTOR (7 downto 0); img_data_stream_1_V_empty_n : IN STD_LOGIC; img_data_stream_1_V_read : OUT STD_LOGIC; img_data_stream_2_V_dout : IN STD_LOGIC_VECTOR (7 downto 0); img_data_stream_2_V_empty_n : IN STD_LOGIC; img_data_stream_2_V_read : OUT STD_LOGIC; OUTPUT_STREAM_TDATA : OUT STD_LOGIC_VECTOR (31 downto 0); OUTPUT_STREAM_TVALID : OUT STD_LOGIC; OUTPUT_STREAM_TREADY : IN STD_LOGIC; OUTPUT_STREAM_TKEEP : OUT STD_LOGIC_VECTOR (3 downto 0); OUTPUT_STREAM_TSTRB : OUT STD_LOGIC_VECTOR (3 downto 0); OUTPUT_STREAM_TUSER : OUT STD_LOGIC_VECTOR (0 downto 0); OUTPUT_STREAM_TLAST : OUT STD_LOGIC_VECTOR (0 downto 0); OUTPUT_STREAM_TID : OUT STD_LOGIC_VECTOR (0 downto 0); OUTPUT_STREAM_TDEST : OUT STD_LOGIC_VECTOR (0 downto 0) ); end; architecture behav of image_filter_Mat2AXIvideo is constant ap_const_logic_1 : STD_LOGIC := '1'; constant ap_const_logic_0 : STD_LOGIC := '0'; constant ap_ST_st1_fsm_0 : STD_LOGIC_VECTOR (3 downto 0) := "0001"; constant ap_ST_st2_fsm_1 : STD_LOGIC_VECTOR (3 downto 0) := "0010"; constant ap_ST_pp0_stg0_fsm_2 : STD_LOGIC_VECTOR (3 downto 0) := "0100"; constant ap_ST_st5_fsm_3 : STD_LOGIC_VECTOR (3 downto 0) := "1000"; constant ap_const_lv32_0 : STD_LOGIC_VECTOR (31 downto 0) := "00000000000000000000000000000000"; constant ap_const_lv1_1 : STD_LOGIC_VECTOR (0 downto 0) := "1"; constant ap_const_lv32_1 : STD_LOGIC_VECTOR (31 downto 0) := "00000000000000000000000000000001"; constant ap_const_lv32_2 : STD_LOGIC_VECTOR (31 downto 0) := "00000000000000000000000000000010"; constant ap_const_lv1_0 : STD_LOGIC_VECTOR (0 downto 0) := "0"; constant ap_const_lv12_0 : STD_LOGIC_VECTOR (11 downto 0) := "000000000000"; constant ap_const_lv32_3 : STD_LOGIC_VECTOR (31 downto 0) := "00000000000000000000000000000011"; constant ap_const_lv4_F : STD_LOGIC_VECTOR (3 downto 0) := "1111"; constant ap_const_lv4_0 : STD_LOGIC_VECTOR (3 downto 0) := "0000"; constant ap_const_lv13_1FFF : STD_LOGIC_VECTOR (12 downto 0) := "1111111111111"; constant ap_const_lv12_1 : STD_LOGIC_VECTOR (11 downto 0) := "000000000001"; constant ap_const_lv8_FF : STD_LOGIC_VECTOR (7 downto 0) := "11111111"; signal ap_done_reg : STD_LOGIC := '0'; signal ap_CS_fsm : STD_LOGIC_VECTOR (3 downto 0) := "0001"; attribute fsm_encoding : string; attribute fsm_encoding of ap_CS_fsm : signal is "none"; signal ap_sig_cseq_ST_st1_fsm_0 : STD_LOGIC; signal ap_sig_bdd_23 : BOOLEAN; signal p_3_reg_170 : STD_LOGIC_VECTOR (11 downto 0); signal ap_sig_bdd_60 : BOOLEAN; signal op2_assign_fu_186_p2 : STD_LOGIC_VECTOR (12 downto 0); signal op2_assign_reg_267 : STD_LOGIC_VECTOR (12 downto 0); signal exitcond3_fu_197_p2 : STD_LOGIC_VECTOR (0 downto 0); signal ap_sig_cseq_ST_st2_fsm_1 : STD_LOGIC; signal ap_sig_bdd_74 : BOOLEAN; signal i_V_fu_202_p2 : STD_LOGIC_VECTOR (11 downto 0); signal i_V_reg_276 : STD_LOGIC_VECTOR (11 downto 0); signal exitcond4_fu_208_p2 : STD_LOGIC_VECTOR (0 downto 0); signal exitcond4_reg_281 : STD_LOGIC_VECTOR (0 downto 0); signal ap_sig_cseq_ST_pp0_stg0_fsm_2 : STD_LOGIC; signal ap_sig_bdd_85 : BOOLEAN; signal ap_reg_ppiten_pp0_it0 : STD_LOGIC := '0'; signal ap_sig_bdd_99 : BOOLEAN; signal ap_sig_ioackin_OUTPUT_STREAM_TREADY : STD_LOGIC; signal ap_reg_ppiten_pp0_it1 : STD_LOGIC := '0'; signal j_V_fu_213_p2 : STD_LOGIC_VECTOR (11 downto 0); signal axi_last_V_fu_223_p2 : STD_LOGIC_VECTOR (0 downto 0); signal axi_last_V_reg_290 : STD_LOGIC_VECTOR (0 downto 0); signal p_s_reg_159 : STD_LOGIC_VECTOR (11 downto 0); signal ap_sig_cseq_ST_st5_fsm_3 : STD_LOGIC; signal ap_sig_bdd_130 : BOOLEAN; signal tmp_user_V_fu_96 : STD_LOGIC_VECTOR (0 downto 0); signal ap_reg_ioackin_OUTPUT_STREAM_TREADY : STD_LOGIC := '0'; signal tmp_cast_fu_182_p1 : STD_LOGIC_VECTOR (12 downto 0); signal tmp_cast_35_fu_219_p1 : STD_LOGIC_VECTOR (12 downto 0); signal ap_NS_fsm : STD_LOGIC_VECTOR (3 downto 0); begin -- the current state (ap_CS_fsm) of the state machine. -- ap_CS_fsm_assign_proc : process(ap_clk) begin if (ap_clk'event and ap_clk = '1') then if (ap_rst = '1') then ap_CS_fsm <= ap_ST_st1_fsm_0; else ap_CS_fsm <= ap_NS_fsm; end if; end if; end process; -- ap_done_reg assign process. -- ap_done_reg_assign_proc : process(ap_clk) begin if (ap_clk'event and ap_clk = '1') then if (ap_rst = '1') then ap_done_reg <= ap_const_logic_0; else if ((ap_const_logic_1 = ap_continue)) then ap_done_reg <= ap_const_logic_0; elsif (((ap_const_logic_1 = ap_sig_cseq_ST_st2_fsm_1) and not((exitcond3_fu_197_p2 = ap_const_lv1_0)))) then ap_done_reg <= ap_const_logic_1; end if; end if; end if; end process; -- ap_reg_ioackin_OUTPUT_STREAM_TREADY assign process. -- ap_reg_ioackin_OUTPUT_STREAM_TREADY_assign_proc : process(ap_clk) begin if (ap_clk'event and ap_clk = '1') then if (ap_rst = '1') then ap_reg_ioackin_OUTPUT_STREAM_TREADY <= ap_const_logic_0; else if ((((ap_const_logic_1 = ap_sig_cseq_ST_pp0_stg0_fsm_2) and (exitcond4_reg_281 = ap_const_lv1_0) and (ap_const_logic_1 = ap_reg_ppiten_pp0_it1) and not(((ap_sig_bdd_99 or ((exitcond4_reg_281 = ap_const_lv1_0) and (ap_const_logic_0 = ap_sig_ioackin_OUTPUT_STREAM_TREADY))) and (ap_const_logic_1 = ap_reg_ppiten_pp0_it1)))))) then ap_reg_ioackin_OUTPUT_STREAM_TREADY <= ap_const_logic_0; elsif ((((ap_const_logic_1 = ap_sig_cseq_ST_pp0_stg0_fsm_2) and (exitcond4_reg_281 = ap_const_lv1_0) and (ap_const_logic_1 = ap_reg_ppiten_pp0_it1) and not((ap_sig_bdd_99 and (ap_const_logic_1 = ap_reg_ppiten_pp0_it1))) and (ap_const_logic_1 = OUTPUT_STREAM_TREADY)))) then ap_reg_ioackin_OUTPUT_STREAM_TREADY <= ap_const_logic_1; end if; end if; end if; end process; -- ap_reg_ppiten_pp0_it0 assign process. -- ap_reg_ppiten_pp0_it0_assign_proc : process(ap_clk) begin if (ap_clk'event and ap_clk = '1') then if (ap_rst = '1') then ap_reg_ppiten_pp0_it0 <= ap_const_logic_0; else if (((ap_const_logic_1 = ap_sig_cseq_ST_pp0_stg0_fsm_2) and not(((ap_sig_bdd_99 or ((exitcond4_reg_281 = ap_const_lv1_0) and (ap_const_logic_0 = ap_sig_ioackin_OUTPUT_STREAM_TREADY))) and (ap_const_logic_1 = ap_reg_ppiten_pp0_it1))) and not((exitcond4_fu_208_p2 = ap_const_lv1_0)))) then ap_reg_ppiten_pp0_it0 <= ap_const_logic_0; elsif (((ap_const_logic_1 = ap_sig_cseq_ST_st2_fsm_1) and (exitcond3_fu_197_p2 = ap_const_lv1_0))) then ap_reg_ppiten_pp0_it0 <= ap_const_logic_1; end if; end if; end if; end process; -- ap_reg_ppiten_pp0_it1 assign process. -- ap_reg_ppiten_pp0_it1_assign_proc : process(ap_clk) begin if (ap_clk'event and ap_clk = '1') then if (ap_rst = '1') then ap_reg_ppiten_pp0_it1 <= ap_const_logic_0; else if (((ap_const_logic_1 = ap_sig_cseq_ST_pp0_stg0_fsm_2) and not(((ap_sig_bdd_99 or ((exitcond4_reg_281 = ap_const_lv1_0) and (ap_const_logic_0 = ap_sig_ioackin_OUTPUT_STREAM_TREADY))) and (ap_const_logic_1 = ap_reg_ppiten_pp0_it1))) and (exitcond4_fu_208_p2 = ap_const_lv1_0))) then ap_reg_ppiten_pp0_it1 <= ap_const_logic_1; elsif ((((ap_const_logic_1 = ap_sig_cseq_ST_st2_fsm_1) and (exitcond3_fu_197_p2 = ap_const_lv1_0)) or ((ap_const_logic_1 = ap_sig_cseq_ST_pp0_stg0_fsm_2) and not(((ap_sig_bdd_99 or ((exitcond4_reg_281 = ap_const_lv1_0) and (ap_const_logic_0 = ap_sig_ioackin_OUTPUT_STREAM_TREADY))) and (ap_const_logic_1 = ap_reg_ppiten_pp0_it1))) and not((exitcond4_fu_208_p2 = ap_const_lv1_0))))) then ap_reg_ppiten_pp0_it1 <= ap_const_logic_0; end if; end if; end if; end process; -- p_3_reg_170 assign process. -- p_3_reg_170_assign_proc : process (ap_clk) begin if (ap_clk'event and ap_clk = '1') then if (((ap_const_logic_1 = ap_sig_cseq_ST_pp0_stg0_fsm_2) and (ap_const_logic_1 = ap_reg_ppiten_pp0_it0) and not(((ap_sig_bdd_99 or ((exitcond4_reg_281 = ap_const_lv1_0) and (ap_const_logic_0 = ap_sig_ioackin_OUTPUT_STREAM_TREADY))) and (ap_const_logic_1 = ap_reg_ppiten_pp0_it1))) and (exitcond4_fu_208_p2 = ap_const_lv1_0))) then p_3_reg_170 <= j_V_fu_213_p2; elsif (((ap_const_logic_1 = ap_sig_cseq_ST_st2_fsm_1) and (exitcond3_fu_197_p2 = ap_const_lv1_0))) then p_3_reg_170 <= ap_const_lv12_0; end if; end if; end process; -- p_s_reg_159 assign process. -- p_s_reg_159_assign_proc : process (ap_clk) begin if (ap_clk'event and ap_clk = '1') then if ((ap_const_logic_1 = ap_sig_cseq_ST_st5_fsm_3)) then p_s_reg_159 <= i_V_reg_276; elsif (((ap_const_logic_1 = ap_sig_cseq_ST_st1_fsm_0) and not(ap_sig_bdd_60))) then p_s_reg_159 <= ap_const_lv12_0; end if; end if; end process; -- tmp_user_V_fu_96 assign process. -- tmp_user_V_fu_96_assign_proc : process (ap_clk) begin if (ap_clk'event and ap_clk = '1') then if (((ap_const_logic_1 = ap_sig_cseq_ST_pp0_stg0_fsm_2) and (exitcond4_reg_281 = ap_const_lv1_0) and (ap_const_logic_1 = ap_reg_ppiten_pp0_it1) and not(((ap_sig_bdd_99 or ((exitcond4_reg_281 = ap_const_lv1_0) and (ap_const_logic_0 = ap_sig_ioackin_OUTPUT_STREAM_TREADY))) and (ap_const_logic_1 = ap_reg_ppiten_pp0_it1))))) then tmp_user_V_fu_96 <= ap_const_lv1_0; elsif (((ap_const_logic_1 = ap_sig_cseq_ST_st1_fsm_0) and not(ap_sig_bdd_60))) then tmp_user_V_fu_96 <= ap_const_lv1_1; end if; end if; end process; -- assign process. -- process (ap_clk) begin if (ap_clk'event and ap_clk = '1') then if (((ap_const_logic_1 = ap_sig_cseq_ST_pp0_stg0_fsm_2) and not(((ap_sig_bdd_99 or ((exitcond4_reg_281 = ap_const_lv1_0) and (ap_const_logic_0 = ap_sig_ioackin_OUTPUT_STREAM_TREADY))) and (ap_const_logic_1 = ap_reg_ppiten_pp0_it1))) and (exitcond4_fu_208_p2 = ap_const_lv1_0))) then axi_last_V_reg_290 <= axi_last_V_fu_223_p2; end if; end if; end process; -- assign process. -- process (ap_clk) begin if (ap_clk'event and ap_clk = '1') then if (((ap_const_logic_1 = ap_sig_cseq_ST_pp0_stg0_fsm_2) and not(((ap_sig_bdd_99 or ((exitcond4_reg_281 = ap_const_lv1_0) and (ap_const_logic_0 = ap_sig_ioackin_OUTPUT_STREAM_TREADY))) and (ap_const_logic_1 = ap_reg_ppiten_pp0_it1))))) then exitcond4_reg_281 <= exitcond4_fu_208_p2; end if; end if; end process; -- assign process. -- process (ap_clk) begin if (ap_clk'event and ap_clk = '1') then if ((ap_const_logic_1 = ap_sig_cseq_ST_st2_fsm_1)) then i_V_reg_276 <= i_V_fu_202_p2; end if; end if; end process; -- assign process. -- process (ap_clk) begin if (ap_clk'event and ap_clk = '1') then if (((ap_const_logic_1 = ap_sig_cseq_ST_st1_fsm_0) and not(ap_sig_bdd_60))) then op2_assign_reg_267 <= op2_assign_fu_186_p2; end if; end if; end process; -- the next state (ap_NS_fsm) of the state machine. -- ap_NS_fsm_assign_proc : process (ap_CS_fsm, ap_sig_bdd_60, exitcond3_fu_197_p2, exitcond4_fu_208_p2, exitcond4_reg_281, ap_reg_ppiten_pp0_it0, ap_sig_bdd_99, ap_sig_ioackin_OUTPUT_STREAM_TREADY, ap_reg_ppiten_pp0_it1) begin case ap_CS_fsm is when ap_ST_st1_fsm_0 => if (not(ap_sig_bdd_60)) then ap_NS_fsm <= ap_ST_st2_fsm_1; else ap_NS_fsm <= ap_ST_st1_fsm_0; end if; when ap_ST_st2_fsm_1 => if (not((exitcond3_fu_197_p2 = ap_const_lv1_0))) then ap_NS_fsm <= ap_ST_st1_fsm_0; else ap_NS_fsm <= ap_ST_pp0_stg0_fsm_2; end if; when ap_ST_pp0_stg0_fsm_2 => if (not(((ap_const_logic_1 = ap_reg_ppiten_pp0_it0) and not(((ap_sig_bdd_99 or ((exitcond4_reg_281 = ap_const_lv1_0) and (ap_const_logic_0 = ap_sig_ioackin_OUTPUT_STREAM_TREADY))) and (ap_const_logic_1 = ap_reg_ppiten_pp0_it1))) and not((exitcond4_fu_208_p2 = ap_const_lv1_0))))) then ap_NS_fsm <= ap_ST_pp0_stg0_fsm_2; elsif (((ap_const_logic_1 = ap_reg_ppiten_pp0_it0) and not(((ap_sig_bdd_99 or ((exitcond4_reg_281 = ap_const_lv1_0) and (ap_const_logic_0 = ap_sig_ioackin_OUTPUT_STREAM_TREADY))) and (ap_const_logic_1 = ap_reg_ppiten_pp0_it1))) and not((exitcond4_fu_208_p2 = ap_const_lv1_0)))) then ap_NS_fsm <= ap_ST_st5_fsm_3; else ap_NS_fsm <= ap_ST_pp0_stg0_fsm_2; end if; when ap_ST_st5_fsm_3 => ap_NS_fsm <= ap_ST_st2_fsm_1; when others => ap_NS_fsm <= "XXXX"; end case; end process; OUTPUT_STREAM_TDATA <= (((ap_const_lv8_FF & img_data_stream_2_V_dout) & img_data_stream_1_V_dout) & img_data_stream_0_V_dout); OUTPUT_STREAM_TDEST <= ap_const_lv1_0; OUTPUT_STREAM_TID <= ap_const_lv1_0; OUTPUT_STREAM_TKEEP <= ap_const_lv4_F; OUTPUT_STREAM_TLAST <= axi_last_V_reg_290; OUTPUT_STREAM_TSTRB <= ap_const_lv4_0; OUTPUT_STREAM_TUSER <= tmp_user_V_fu_96; -- OUTPUT_STREAM_TVALID assign process. -- OUTPUT_STREAM_TVALID_assign_proc : process(exitcond4_reg_281, ap_sig_cseq_ST_pp0_stg0_fsm_2, ap_sig_bdd_99, ap_reg_ppiten_pp0_it1, ap_reg_ioackin_OUTPUT_STREAM_TREADY) begin if ((((ap_const_logic_1 = ap_sig_cseq_ST_pp0_stg0_fsm_2) and (exitcond4_reg_281 = ap_const_lv1_0) and (ap_const_logic_1 = ap_reg_ppiten_pp0_it1) and not((ap_sig_bdd_99 and (ap_const_logic_1 = ap_reg_ppiten_pp0_it1))) and (ap_const_logic_0 = ap_reg_ioackin_OUTPUT_STREAM_TREADY)))) then OUTPUT_STREAM_TVALID <= ap_const_logic_1; else OUTPUT_STREAM_TVALID <= ap_const_logic_0; end if; end process; -- ap_done assign process. -- ap_done_assign_proc : process(ap_done_reg, exitcond3_fu_197_p2, ap_sig_cseq_ST_st2_fsm_1) begin if (((ap_const_logic_1 = ap_done_reg) or ((ap_const_logic_1 = ap_sig_cseq_ST_st2_fsm_1) and not((exitcond3_fu_197_p2 = ap_const_lv1_0))))) then ap_done <= ap_const_logic_1; else ap_done <= ap_const_logic_0; end if; end process; -- ap_idle assign process. -- ap_idle_assign_proc : process(ap_start, ap_sig_cseq_ST_st1_fsm_0) begin if ((not((ap_const_logic_1 = ap_start)) and (ap_const_logic_1 = ap_sig_cseq_ST_st1_fsm_0))) then ap_idle <= ap_const_logic_1; else ap_idle <= ap_const_logic_0; end if; end process; -- ap_ready assign process. -- ap_ready_assign_proc : process(exitcond3_fu_197_p2, ap_sig_cseq_ST_st2_fsm_1) begin if (((ap_const_logic_1 = ap_sig_cseq_ST_st2_fsm_1) and not((exitcond3_fu_197_p2 = ap_const_lv1_0)))) then ap_ready <= ap_const_logic_1; else ap_ready <= ap_const_logic_0; end if; end process; -- ap_sig_bdd_130 assign process. -- ap_sig_bdd_130_assign_proc : process(ap_CS_fsm) begin ap_sig_bdd_130 <= (ap_const_lv1_1 = ap_CS_fsm(3 downto 3)); end process; -- ap_sig_bdd_23 assign process. -- ap_sig_bdd_23_assign_proc : process(ap_CS_fsm) begin ap_sig_bdd_23 <= (ap_CS_fsm(0 downto 0) = ap_const_lv1_1); end process; -- ap_sig_bdd_60 assign process. -- ap_sig_bdd_60_assign_proc : process(ap_start, ap_done_reg) begin ap_sig_bdd_60 <= ((ap_start = ap_const_logic_0) or (ap_done_reg = ap_const_logic_1)); end process; -- ap_sig_bdd_74 assign process. -- ap_sig_bdd_74_assign_proc : process(ap_CS_fsm) begin ap_sig_bdd_74 <= (ap_const_lv1_1 = ap_CS_fsm(1 downto 1)); end process; -- ap_sig_bdd_85 assign process. -- ap_sig_bdd_85_assign_proc : process(ap_CS_fsm) begin ap_sig_bdd_85 <= (ap_const_lv1_1 = ap_CS_fsm(2 downto 2)); end process; -- ap_sig_bdd_99 assign process. -- ap_sig_bdd_99_assign_proc : process(img_data_stream_0_V_empty_n, img_data_stream_1_V_empty_n, img_data_stream_2_V_empty_n, exitcond4_reg_281) begin ap_sig_bdd_99 <= (((img_data_stream_0_V_empty_n = ap_const_logic_0) and (exitcond4_reg_281 = ap_const_lv1_0)) or ((exitcond4_reg_281 = ap_const_lv1_0) and (img_data_stream_1_V_empty_n = ap_const_logic_0)) or ((exitcond4_reg_281 = ap_const_lv1_0) and (img_data_stream_2_V_empty_n = ap_const_logic_0))); end process; -- ap_sig_cseq_ST_pp0_stg0_fsm_2 assign process. -- ap_sig_cseq_ST_pp0_stg0_fsm_2_assign_proc : process(ap_sig_bdd_85) begin if (ap_sig_bdd_85) then ap_sig_cseq_ST_pp0_stg0_fsm_2 <= ap_const_logic_1; else ap_sig_cseq_ST_pp0_stg0_fsm_2 <= ap_const_logic_0; end if; end process; -- ap_sig_cseq_ST_st1_fsm_0 assign process. -- ap_sig_cseq_ST_st1_fsm_0_assign_proc : process(ap_sig_bdd_23) begin if (ap_sig_bdd_23) then ap_sig_cseq_ST_st1_fsm_0 <= ap_const_logic_1; else ap_sig_cseq_ST_st1_fsm_0 <= ap_const_logic_0; end if; end process; -- ap_sig_cseq_ST_st2_fsm_1 assign process. -- ap_sig_cseq_ST_st2_fsm_1_assign_proc : process(ap_sig_bdd_74) begin if (ap_sig_bdd_74) then ap_sig_cseq_ST_st2_fsm_1 <= ap_const_logic_1; else ap_sig_cseq_ST_st2_fsm_1 <= ap_const_logic_0; end if; end process; -- ap_sig_cseq_ST_st5_fsm_3 assign process. -- ap_sig_cseq_ST_st5_fsm_3_assign_proc : process(ap_sig_bdd_130) begin if (ap_sig_bdd_130) then ap_sig_cseq_ST_st5_fsm_3 <= ap_const_logic_1; else ap_sig_cseq_ST_st5_fsm_3 <= ap_const_logic_0; end if; end process; -- ap_sig_ioackin_OUTPUT_STREAM_TREADY assign process. -- ap_sig_ioackin_OUTPUT_STREAM_TREADY_assign_proc : process(OUTPUT_STREAM_TREADY, ap_reg_ioackin_OUTPUT_STREAM_TREADY) begin if ((ap_const_logic_0 = ap_reg_ioackin_OUTPUT_STREAM_TREADY)) then ap_sig_ioackin_OUTPUT_STREAM_TREADY <= OUTPUT_STREAM_TREADY; else ap_sig_ioackin_OUTPUT_STREAM_TREADY <= ap_const_logic_1; end if; end process; axi_last_V_fu_223_p2 <= "1" when (tmp_cast_35_fu_219_p1 = op2_assign_reg_267) else "0"; exitcond3_fu_197_p2 <= "1" when (p_s_reg_159 = img_rows_V_read) else "0"; exitcond4_fu_208_p2 <= "1" when (p_3_reg_170 = img_cols_V_read) else "0"; i_V_fu_202_p2 <= std_logic_vector(unsigned(p_s_reg_159) + unsigned(ap_const_lv12_1)); -- img_data_stream_0_V_read assign process. -- img_data_stream_0_V_read_assign_proc : process(exitcond4_reg_281, ap_sig_cseq_ST_pp0_stg0_fsm_2, ap_sig_bdd_99, ap_sig_ioackin_OUTPUT_STREAM_TREADY, ap_reg_ppiten_pp0_it1) begin if (((ap_const_logic_1 = ap_sig_cseq_ST_pp0_stg0_fsm_2) and (exitcond4_reg_281 = ap_const_lv1_0) and (ap_const_logic_1 = ap_reg_ppiten_pp0_it1) and not(((ap_sig_bdd_99 or ((exitcond4_reg_281 = ap_const_lv1_0) and (ap_const_logic_0 = ap_sig_ioackin_OUTPUT_STREAM_TREADY))) and (ap_const_logic_1 = ap_reg_ppiten_pp0_it1))))) then img_data_stream_0_V_read <= ap_const_logic_1; else img_data_stream_0_V_read <= ap_const_logic_0; end if; end process; -- img_data_stream_1_V_read assign process. -- img_data_stream_1_V_read_assign_proc : process(exitcond4_reg_281, ap_sig_cseq_ST_pp0_stg0_fsm_2, ap_sig_bdd_99, ap_sig_ioackin_OUTPUT_STREAM_TREADY, ap_reg_ppiten_pp0_it1) begin if (((ap_const_logic_1 = ap_sig_cseq_ST_pp0_stg0_fsm_2) and (exitcond4_reg_281 = ap_const_lv1_0) and (ap_const_logic_1 = ap_reg_ppiten_pp0_it1) and not(((ap_sig_bdd_99 or ((exitcond4_reg_281 = ap_const_lv1_0) and (ap_const_logic_0 = ap_sig_ioackin_OUTPUT_STREAM_TREADY))) and (ap_const_logic_1 = ap_reg_ppiten_pp0_it1))))) then img_data_stream_1_V_read <= ap_const_logic_1; else img_data_stream_1_V_read <= ap_const_logic_0; end if; end process; -- img_data_stream_2_V_read assign process. -- img_data_stream_2_V_read_assign_proc : process(exitcond4_reg_281, ap_sig_cseq_ST_pp0_stg0_fsm_2, ap_sig_bdd_99, ap_sig_ioackin_OUTPUT_STREAM_TREADY, ap_reg_ppiten_pp0_it1) begin if (((ap_const_logic_1 = ap_sig_cseq_ST_pp0_stg0_fsm_2) and (exitcond4_reg_281 = ap_const_lv1_0) and (ap_const_logic_1 = ap_reg_ppiten_pp0_it1) and not(((ap_sig_bdd_99 or ((exitcond4_reg_281 = ap_const_lv1_0) and (ap_const_logic_0 = ap_sig_ioackin_OUTPUT_STREAM_TREADY))) and (ap_const_logic_1 = ap_reg_ppiten_pp0_it1))))) then img_data_stream_2_V_read <= ap_const_logic_1; else img_data_stream_2_V_read <= ap_const_logic_0; end if; end process; j_V_fu_213_p2 <= std_logic_vector(unsigned(p_3_reg_170) + unsigned(ap_const_lv12_1)); op2_assign_fu_186_p2 <= std_logic_vector(unsigned(tmp_cast_fu_182_p1) + unsigned(ap_const_lv13_1FFF)); tmp_cast_35_fu_219_p1 <= std_logic_vector(resize(unsigned(p_3_reg_170),13)); tmp_cast_fu_182_p1 <= std_logic_vector(resize(unsigned(img_cols_V_read),13)); end behav;	gpl-3.0	ab320e548b93e556b0b39b0d0b86ba4f	0.592093	2.795067	false	false	false	false
marco-c/leon-nexys2	grlib-gpl-1.3.4-b4140/lib/micron/ddr_sdram/mt46v16m16.vhd	1	62,181	----------------------------------------------------------------------------------------- -- -- File Name: MT46V16M16.VHD -- Version: 3.1 -- Date: January 14th, 2002 -- Model: Behavioral -- Simulator: NCDesktop - http://www.cadence.com -- ModelSim PE - http://www.model.com -- -- Dependencies: None -- -- Email: [email protected] -- Company: Micron Technology, Inc. -- Part Number: MT46V16M16 (4 Mb x 16 x 4 Banks) -- -- Description: Micron 256 Mb SDRAM DDR (Double Data Rate) -- -- Limitation: Doesn't model internal refresh counter -- -- Note: -- -- Disclaimer: THESE DESIGNS ARE PROVIDED "AS IS" WITH NO WARRANTY -- WHATSOEVER AND MICRON SPECIFICALLY DISCLAIMS ANY -- IMPLIED WARRANTIES OF MERCHANTABILITY, FITNESS FOR -- A PARTICULAR PURPOSE, OR AGAINST INFRINGEMENT. -- -- Copyright (c) 1998 Micron Semiconductor Products, Inc. -- All rights researved -- -- Rev Author Date Changes -- --- ---------------------------- ---------- ------------------------------------- -- 2.1 SH 01/14/2002 - Fix Burst_counter -- Micron Technology, Inc. -- -- 2.0 SH 11/08/2001 - Second release -- Micron Technology, Inc. - Rewrote and remove SHARED VARIABLE -- 3.1 Craig Hanson cahanson 05/28/2003 - update all models to release version 3.1 -- @micron.com (no changes to this model) ----------------------------------------------------------------------------------------- LIBRARY IEEE; USE IEEE.STD_LOGIC_1164.ALL; USE IEEE.NUMERIC_STD.ALL; LIBRARY WORK; USE WORK.MTI_PKG.ALL; use std.textio.all; library grlib; use grlib.stdlib.all; use grlib.stdio.all; ENTITY MT46V16M16 IS GENERIC ( -- Timing for -75Z CL2 tCK : TIME := 7.500 ns; tCH : TIME := 3.375 ns; -- 0.45tCK tCL : TIME := 3.375 ns; -- 0.45tCK tDH : TIME := 0.500 ns; tDS : TIME := 0.500 ns; tIH : TIME := 0.900 ns; tIS : TIME := 0.900 ns; tMRD : TIME := 15.000 ns; tRAS : TIME := 40.000 ns; tRAP : TIME := 20.000 ns; tRC : TIME := 65.000 ns; tRFC : TIME := 75.000 ns; tRCD : TIME := 20.000 ns; tRP : TIME := 20.000 ns; tRRD : TIME := 15.000 ns; tWR : TIME := 15.000 ns; addr_bits : INTEGER := 13; data_bits : INTEGER := 16; cols_bits : INTEGER := 9; index : INTEGER := 0; fname : string := "ram.srec"; -- File to read from bbits : INTEGER := 16; fdelay : INTEGER := 0; chktiming : boolean := true -- Perform timing checks ); PORT ( Dq : INOUT STD_LOGIC_VECTOR (data_bits - 1 DOWNTO 0) := (OTHERS => 'Z'); Dqs : INOUT STD_LOGIC_VECTOR (1 DOWNTO 0) := "ZZ"; Addr : IN STD_LOGIC_VECTOR (addr_bits - 1 DOWNTO 0); Ba : IN STD_LOGIC_VECTOR (1 DOWNTO 0); Clk : IN STD_LOGIC; Clk_n : IN STD_LOGIC; Cke : IN STD_LOGIC; Cs_n : IN STD_LOGIC; Ras_n : IN STD_LOGIC; Cas_n : IN STD_LOGIC; We_n : IN STD_LOGIC; Dm : IN STD_LOGIC_VECTOR (1 DOWNTO 0) ); END MT46V16M16; ARCHITECTURE behave OF MT46V16M16 IS -- Array for Read pipeline TYPE Array_Read_cmnd IS ARRAY (cols_bits-1 DOWNTO 0) OF STD_LOGIC; TYPE Array_Read_bank IS ARRAY (cols_bits-1 DOWNTO 0) OF STD_LOGIC_VECTOR (1 DOWNTO 0); TYPE Array_Read_cols IS ARRAY (cols_bits-1 DOWNTO 0) OF STD_LOGIC_VECTOR (cols_bits - 1 DOWNTO 0); -- Array for Write pipeline TYPE Array_Write_cmnd IS ARRAY (2 DOWNTO 0) OF STD_LOGIC; TYPE Array_Write_bank IS ARRAY (2 DOWNTO 0) OF STD_LOGIC_VECTOR (1 DOWNTO 0); TYPE Array_Write_cols IS ARRAY (2 DOWNTO 0) OF STD_LOGIC_VECTOR (cols_bits - 1 DOWNTO 0); -- Array for Auto Precharge TYPE Array_Read_precharge IS ARRAY (3 DOWNTO 0) OF STD_LOGIC; TYPE Array_Write_precharge IS ARRAY (3 DOWNTO 0) OF STD_LOGIC; TYPE Array_Count_precharge IS ARRAY (3 DOWNTO 0) OF INTEGER; -- Array for Manual Precharge TYPE Array_A10_precharge IS ARRAY (cols_bits-1 DOWNTO 0) OF STD_LOGIC; TYPE Array_Bank_precharge IS ARRAY (cols_bits-1 DOWNTO 0) OF STD_LOGIC_VECTOR (1 DOWNTO 0); TYPE Array_Cmnd_precharge IS ARRAY (cols_bits-1 DOWNTO 0) OF STD_LOGIC; -- Array for Burst Terminate TYPE Array_Cmnd_bst IS ARRAY (cols_bits-1 DOWNTO 0) OF STD_LOGIC; -- Array for Memory Access TYPE Array_ram_type IS ARRAY (2cols_bits - 1 DOWNTO 0) OF STD_LOGIC_VECTOR (data_bits - 1 DOWNTO 0); TYPE Array_ram_pntr IS ACCESS Array_ram_type; TYPE Array_ram_stor IS ARRAY (2addr_bits - 1 DOWNTO 0) OF Array_ram_pntr; -- Data pair SIGNAL Dq_pair : STD_LOGIC_VECTOR (2 * data_bits - 1 DOWNTO 0); SIGNAL Dm_pair : STD_LOGIC_VECTOR (3 DOWNTO 0); -- Mode Register SIGNAL Mode_reg : STD_LOGIC_VECTOR (addr_bits - 1 DOWNTO 0) := (OTHERS => '0'); -- Command Decode Variables SIGNAL Active_enable, Aref_enable, Burst_term, Ext_mode_enable : STD_LOGIC := '0'; SIGNAL Mode_reg_enable, Prech_enable, Read_enable, Write_enable : STD_LOGIC := '0'; -- Burst Length Decode Variables SIGNAL Burst_length_2, Burst_length_4, Burst_length_8, Burst_length_f : STD_LOGIC := '0'; -- Cas Latency Decode Variables SIGNAL Cas_latency_15, Cas_latency_2, Cas_latency_25, Cas_latency_3, Cas_latency_4 : STD_LOGIC := '0'; -- Internal Control Signals SIGNAL Cs_in, Ras_in, Cas_in, We_in : STD_LOGIC := '0'; -- System Clock SIGNAL Sys_clk : STD_LOGIC := '0'; -- Dqs buffer SIGNAL Dqs_out : STD_LOGIC_VECTOR (1 DOWNTO 0) := "ZZ"; BEGIN -- Strip the strength Cs_in <= To_X01 (Cs_n); Ras_in <= To_X01 (Ras_n); Cas_in <= To_X01 (Cas_n); We_in <= To_X01 (We_n); -- Commands Decode Active_enable <= NOT(Cs_in) AND NOT(Ras_in) AND Cas_in AND We_in; Aref_enable <= NOT(Cs_in) AND NOT(Ras_in) AND NOT(Cas_in) AND We_in; Burst_term <= NOT(Cs_in) AND Ras_in AND Cas_in AND NOT(We_in); Ext_mode_enable <= NOT(Cs_in) AND NOT(Ras_in) AND NOT(Cas_in) AND NOT(We_in) AND Ba(0) AND NOT(Ba(1)); Mode_reg_enable <= NOT(Cs_in) AND NOT(Ras_in) AND NOT(Cas_in) AND NOT(We_in) AND NOT(Ba(0)) AND NOT(Ba(1)); Prech_enable <= NOT(Cs_in) AND NOT(Ras_in) AND Cas_in AND NOT(We_in); Read_enable <= NOT(Cs_in) AND Ras_in AND NOT(Cas_in) AND We_in; Write_enable <= NOT(Cs_in) AND Ras_in AND NOT(Cas_in) AND NOT(We_in); -- Burst Length Decode Burst_length_2 <= NOT(Mode_reg(2)) AND NOT(Mode_reg(1)) AND Mode_reg(0); Burst_length_4 <= NOT(Mode_reg(2)) AND Mode_reg(1) AND NOT(Mode_reg(0)); Burst_length_8 <= NOT(Mode_reg(2)) AND Mode_reg(1) AND Mode_reg(0); Burst_length_f <= (Mode_reg(2)) AND Mode_reg(1) AND Mode_reg(0); -- CAS Latency Decode Cas_latency_15 <= Mode_reg(6) AND NOT(Mode_reg(5)) AND (Mode_reg(4)); Cas_latency_2 <= NOT(Mode_reg(6)) AND Mode_reg(5) AND NOT(Mode_reg(4)); Cas_latency_25 <= Mode_reg(6) AND Mode_reg(5) AND NOT(Mode_reg(4)); Cas_latency_3 <= NOT(Mode_reg(6)) AND Mode_reg(5) AND Mode_reg(4); Cas_latency_4 <= (Mode_reg(6)) AND NOT(Mode_reg(5)) AND NOT(Mode_reg(4)); -- Dqs buffer Dqs <= Dqs_out; -- -- System Clock -- int_clk : PROCESS (Clk, Clk_n) VARIABLE ClkZ, CkeZ : STD_LOGIC := '0'; begin IF Clk = '1' AND Clk_n = '0' THEN ClkZ := '1'; CkeZ := Cke; ELSIF Clk = '0' AND Clk_n = '1' THEN ClkZ := '0'; END IF; Sys_clk <= CkeZ AND ClkZ; END PROCESS; -- -- Main Process -- state_register : PROCESS -- Precharge Variables VARIABLE Pc_b0, Pc_b1, Pc_b2, Pc_b3 : STD_LOGIC := '0'; -- Activate Variables VARIABLE Act_b0, Act_b1, Act_b2, Act_b3 : STD_LOGIC := '1'; -- Data IO variables VARIABLE Data_in_enable, Data_out_enable : STD_LOGIC := '0'; -- Internal address mux variables VARIABLE Cols_brst : STD_LOGIC_VECTOR (2 DOWNTO 0); VARIABLE Prev_bank : STD_LOGIC_VECTOR (1 DOWNTO 0) := "00"; VARIABLE Bank_addr : STD_LOGIC_VECTOR (1 DOWNTO 0) := "00"; VARIABLE Cols_addr : STD_LOGIC_VECTOR (cols_bits - 1 DOWNTO 0); VARIABLE Rows_addr : STD_LOGIC_VECTOR (addr_bits - 1 DOWNTO 0); VARIABLE B0_row_addr : STD_LOGIC_VECTOR (addr_bits - 1 DOWNTO 0); VARIABLE B1_row_addr : STD_LOGIC_VECTOR (addr_bits - 1 DOWNTO 0); VARIABLE B2_row_addr : STD_LOGIC_VECTOR (addr_bits - 1 DOWNTO 0); VARIABLE B3_row_addr : STD_LOGIC_VECTOR (addr_bits - 1 DOWNTO 0); -- DLL Reset variables VARIABLE DLL_enable : STD_LOGIC := '0'; VARIABLE DLL_reset : STD_LOGIC := '0'; VARIABLE DLL_done : STD_LOGIC := '0'; VARIABLE DLL_count : INTEGER := 0; -- Timing Check VARIABLE MRD_chk : TIME := 0 ns; VARIABLE RFC_chk : TIME := 0 ns; VARIABLE RRD_chk : TIME := 0 ns; VARIABLE RAS_chk0, RAS_chk1, RAS_chk2, RAS_chk3 : TIME := 0 ns; VARIABLE RAP_chk0, RAP_chk1, RAP_chk2, RAP_chk3 : TIME := 0 ns; VARIABLE RC_chk0, RC_chk1, RC_chk2, RC_chk3 : TIME := 0 ns; VARIABLE RCD_chk0, RCD_chk1, RCD_chk2, RCD_chk3 : TIME := 0 ns; VARIABLE RP_chk0, RP_chk1, RP_chk2, RP_chk3 : TIME := 0 ns; VARIABLE WR_chk0, WR_chk1, WR_chk2, WR_chk3 : TIME := 0 ns; -- Read pipeline variables VARIABLE Read_cmnd : Array_Read_cmnd; VARIABLE Read_bank : Array_Read_bank; VARIABLE Read_cols : Array_Read_cols; -- Write pipeline variables VARIABLE Write_cmnd : Array_Write_cmnd; VARIABLE Write_bank : Array_Write_bank; VARIABLE Write_cols : Array_Write_cols; -- Auto Precharge variables VARIABLE Read_precharge : Array_Read_precharge := ('0' & '0' & '0' & '0'); VARIABLE Write_precharge : Array_Write_precharge := ('0' & '0' & '0' & '0'); VARIABLE Count_precharge : Array_Count_precharge := ( 0 & 0 & 0 & 0 ); -- Manual Precharge variables VARIABLE A10_precharge : Array_A10_precharge; VARIABLE Bank_precharge : Array_Bank_precharge; VARIABLE Cmnd_precharge : Array_Cmnd_precharge; -- Burst Terminate variable VARIABLE Cmnd_bst : Array_Cmnd_bst; -- Memory Banks VARIABLE Bank0 : Array_ram_stor; VARIABLE Bank1 : Array_ram_stor; VARIABLE Bank2 : Array_ram_stor; VARIABLE Bank3 : Array_ram_stor; -- Burst Counter VARIABLE Burst_counter : STD_LOGIC_VECTOR (cols_bits - 1 DOWNTO 0); -- Internal Dqs initialize VARIABLE Dqs_int : STD_LOGIC := '0'; -- Data buffer for DM Mask VARIABLE Data_buf : STD_LOGIC_VECTOR (data_bits - 1 DOWNTO 0) := (OTHERS => 'Z'); -- Load and Dumb variables FILE file_load : TEXT open read_mode is fname; -- Data load FILE file_dump : TEXT open write_mode is "dumpdata.txt"; -- Data dump VARIABLE Bank_Load : std_logic_vector ( 1 DOWNTO 0); VARIABLE Rows_Load : std_logic_vector (addr_bits-1 DOWNTO 0); VARIABLE Cols_Load : std_logic_vector ( cols_bits-1 DOWNTO 0); VARIABLE Data_Load : std_logic_vector (15 DOWNTO 0); VARIABLE i, j : INTEGER; VARIABLE good_load : BOOLEAN; VARIABLE l : LINE; variable file_loaded : boolean := false; variable dump : std_logic := '0'; variable ch : character; variable rectype : std_logic_vector(3 downto 0); variable recaddr : std_logic_vector(31 downto 0); variable reclen : std_logic_vector(7 downto 0); variable recdata : std_logic_vector(0 to 168-1); -- -- Initialize empty rows -- PROCEDURE Init_mem (Bank : STD_LOGIC_VECTOR; Row_index : INTEGER) IS VARIABLE i, j : INTEGER := 0; BEGIN IF Bank = "00" THEN IF Bank0 (Row_index) = NULL THEN -- Check to see if row empty Bank0 (Row_index) := NEW Array_ram_type; -- Open new row for access FOR i IN (2cols_bits - 1) DOWNTO 0 LOOP -- Filled row with zeros FOR j IN (data_bits - 1) DOWNTO 0 LOOP Bank0 (Row_index) (i) (j) := '0'; END LOOP; END LOOP; END IF; ELSIF Bank = "01" THEN IF Bank1 (Row_index) = NULL THEN Bank1 (Row_index) := NEW Array_ram_type; FOR i IN (2cols_bits - 1) DOWNTO 0 LOOP FOR j IN (data_bits - 1) DOWNTO 0 LOOP Bank1 (Row_index) (i) (j) := '0'; END LOOP; END LOOP; END IF; ELSIF Bank = "10" THEN IF Bank2 (Row_index) = NULL THEN Bank2 (Row_index) := NEW Array_ram_type; FOR i IN (2cols_bits - 1) DOWNTO 0 LOOP FOR j IN (data_bits - 1) DOWNTO 0 LOOP Bank2 (Row_index) (i) (j) := '0'; END LOOP; END LOOP; END IF; ELSIF Bank = "11" THEN IF Bank3 (Row_index) = NULL THEN Bank3 (Row_index) := NEW Array_ram_type; FOR i IN (2cols_bits - 1) DOWNTO 0 LOOP FOR j IN (data_bits - 1) DOWNTO 0 LOOP Bank3 (Row_index) (i) (j) := '0'; END LOOP; END LOOP; END IF; END IF; END; -- -- Burst Counter -- PROCEDURE Burst_decode IS VARIABLE Cols_temp : STD_LOGIC_VECTOR (cols_bits - 1 DOWNTO 0) := (OTHERS => '0'); BEGIN -- Advance burst counter Burst_counter := Burst_counter + 1; -- Burst Type IF Mode_reg (3) = '0' THEN Cols_temp := Cols_addr + 1; ELSIF Mode_reg (3) = '1' THEN Cols_temp (2) := Burst_counter (2) XOR Cols_brst (2); Cols_temp (1) := Burst_counter (1) XOR Cols_brst (1); Cols_temp (0) := Burst_counter (0) XOR Cols_brst (0); END IF; -- Burst Length IF Burst_length_2 = '1' THEN Cols_addr (0) := Cols_temp (0); ELSIF Burst_length_4 = '1' THEN Cols_addr (1 DOWNTO 0) := Cols_temp (1 DOWNTO 0); ELSIF Burst_length_8 = '1' THEN Cols_addr (2 DOWNTO 0) := Cols_temp (2 DOWNTO 0); ELSE Cols_addr := Cols_temp; END IF; -- Data counter IF Burst_length_2 = '1' THEN IF conv_integer(Burst_counter) >= 2 THEN IF Data_in_enable = '1' THEN Data_in_enable := '0'; ELSIF Data_out_enable = '1' THEN Data_out_enable := '0'; END IF; END IF; ELSIF Burst_length_4 = '1' THEN IF conv_integer(Burst_counter) >= 4 THEN IF Data_in_enable = '1' THEN Data_in_enable := '0'; ELSIF Data_out_enable = '1' THEN Data_out_enable := '0'; END IF; END IF; ELSIF Burst_length_8 = '1' THEN IF conv_integer(Burst_counter) >= 8 THEN IF Data_in_enable = '1' THEN Data_in_enable := '0'; ELSIF Data_out_enable = '1' THEN Data_out_enable := '0'; END IF; END IF; END IF; END; BEGIN WAIT ON Sys_clk; -- -- Manual Precharge Pipeline -- IF ((Sys_clk'EVENT AND Sys_clk = '0') OR (Sys_clk'EVENT AND Sys_clk = '1')) THEN -- A10 Precharge Pipeline A10_precharge(0) := A10_precharge(1); A10_precharge(1) := A10_precharge(2); A10_precharge(2) := A10_precharge(3); A10_precharge(3) := A10_precharge(4); A10_precharge(4) := A10_precharge(5); A10_precharge(5) := A10_precharge(6); A10_precharge(6) := A10_precharge(7); A10_precharge(7) := A10_precharge(8); A10_precharge(8) := '0'; -- Bank Precharge Pipeline Bank_precharge(0) := Bank_precharge(1); Bank_precharge(1) := Bank_precharge(2); Bank_precharge(2) := Bank_precharge(3); Bank_precharge(3) := Bank_precharge(4); Bank_precharge(4) := Bank_precharge(5); Bank_precharge(5) := Bank_precharge(6); Bank_precharge(6) := Bank_precharge(7); Bank_precharge(7) := Bank_precharge(8); Bank_precharge(8) := "00"; -- Command Precharge Pipeline Cmnd_precharge(0) := Cmnd_precharge(1); Cmnd_precharge(1) := Cmnd_precharge(2); Cmnd_precharge(2) := Cmnd_precharge(3); Cmnd_precharge(3) := Cmnd_precharge(4); Cmnd_precharge(4) := Cmnd_precharge(5); Cmnd_precharge(5) := Cmnd_precharge(6); Cmnd_precharge(6) := Cmnd_precharge(7); Cmnd_precharge(7) := Cmnd_precharge(8); Cmnd_precharge(8) := '0'; -- Terminate Read if same bank or all banks IF ((Cmnd_precharge (0) = '1') AND (Bank_precharge (0) = Bank_addr OR A10_precharge (0) = '1') AND (Data_out_enable = '1')) THEN Data_out_enable := '0'; END IF; END IF; -- -- Burst Terminate Pipeline -- IF ((Sys_clk'EVENT AND Sys_clk = '0') OR (Sys_clk'EVENT AND Sys_clk = '1')) THEN -- Burst Terminate pipeline Cmnd_bst (0) := Cmnd_bst (1); Cmnd_bst (1) := Cmnd_bst (2); Cmnd_bst (2) := Cmnd_bst (3); Cmnd_bst (3) := Cmnd_bst (4); Cmnd_bst (4) := Cmnd_bst (5); Cmnd_bst (5) := Cmnd_bst (6); Cmnd_bst (6) := Cmnd_bst (7); Cmnd_bst (7) := Cmnd_bst (8); Cmnd_bst (8) := '0'; -- Terminate current Read IF ((Cmnd_bst (0) = '1') AND (Data_out_enable = '1')) THEN Data_out_enable := '0'; END IF; END IF; -- -- Dq and Dqs Drivers -- IF ((Sys_clk'EVENT AND Sys_clk = '0') OR (Sys_clk'EVENT AND Sys_clk = '1')) THEN -- Read Command Pipeline Read_cmnd (0) := Read_cmnd (1); Read_cmnd (1) := Read_cmnd (2); Read_cmnd (2) := Read_cmnd (3); Read_cmnd (3) := Read_cmnd (4); Read_cmnd (4) := Read_cmnd (5); Read_cmnd (5) := Read_cmnd (6); Read_cmnd (6) := Read_cmnd (7); Read_cmnd (7) := Read_cmnd (8); Read_cmnd (8) := '0'; -- Read Bank Pipeline Read_bank (0) := Read_bank (1); Read_bank (1) := Read_bank (2); Read_bank (2) := Read_bank (3); Read_bank (3) := Read_bank (4); Read_bank (4) := Read_bank (5); Read_bank (5) := Read_bank (6); Read_bank (6) := Read_bank (7); Read_bank (7) := Read_bank (8); Read_bank (8) := "00"; -- Read Column Pipeline Read_cols (0) := Read_cols (1); Read_cols (1) := Read_cols (2); Read_cols (2) := Read_cols (3); Read_cols (3) := Read_cols (4); Read_cols (4) := Read_cols (5); Read_cols (5) := Read_cols (6); Read_cols (6) := Read_cols (7); Read_cols (7) := Read_cols (8); Read_cols (8) := (OTHERS => '0'); -- Initialize Read command IF Read_cmnd (0) = '1' THEN Data_out_enable := '1'; Bank_addr := Read_bank (0); Cols_addr := Read_cols (0); Cols_brst := Cols_addr (2 DOWNTO 0); Burst_counter := (OTHERS => '0'); -- Row address mux CASE Bank_addr IS WHEN "00" => Rows_addr := B0_row_addr; WHEN "01" => Rows_addr := B1_row_addr; WHEN "10" => Rows_addr := B2_row_addr; WHEN OTHERS => Rows_addr := B3_row_addr; END CASE; END IF; -- Toggle Dqs during Read command IF Data_out_enable = '1' THEN Dqs_int := '0'; IF Dqs_out = "00" THEN Dqs_out <= "11"; ELSIF Dqs_out = "11" THEN Dqs_out <= "00"; ELSE Dqs_out <= "00"; END IF; ELSIF Data_out_enable = '0' AND Dqs_int = '0' THEN Dqs_out <= "ZZ"; END IF; -- Initialize Dqs for Read command IF Read_cmnd (2) = '1' THEN IF Data_out_enable = '0' THEN Dqs_int := '1'; Dqs_out <= "00"; END IF; END IF; -- Read Latch IF Data_out_enable = '1' THEN -- Initialize Memory Init_mem (Bank_addr, CONV_INTEGER(Rows_addr)); -- Output Data CASE Bank_addr IS WHEN "00" => Dq <= Bank0 (CONV_INTEGER(Rows_addr)) (CONV_INTEGER(Cols_addr)); WHEN "01" => Dq <= Bank1 (CONV_INTEGER(Rows_addr)) (CONV_INTEGER(Cols_addr)); WHEN "10" => Dq <= Bank2 (CONV_INTEGER(Rows_addr)) (CONV_INTEGER(Cols_addr)); WHEN OTHERS => Dq <= Bank3 (CONV_INTEGER(Rows_addr)) (CONV_INTEGER(Cols_addr)); END CASE; -- Increase Burst Counter Burst_decode; ELSE Dq <= (OTHERS => 'Z'); END IF; END IF; -- -- Write FIFO and DM Mask Logic -- IF Sys_clk'EVENT AND Sys_clk = '1' THEN -- Write command pipeline Write_cmnd (0) := Write_cmnd (1); Write_cmnd (1) := Write_cmnd (2); Write_cmnd (2) := '0'; -- Write command pipeline Write_bank (0) := Write_bank (1); Write_bank (1) := Write_bank (2); Write_bank (2) := "00"; -- Write column pipeline Write_cols (0) := Write_cols (1); Write_cols (1) := Write_cols (2); Write_cols (2) := (OTHERS => '0'); -- Initialize Write command IF Write_cmnd (0) = '1' THEN Data_in_enable := '1'; Bank_addr := Write_bank (0); Cols_addr := Write_cols (0); Cols_brst := Cols_addr (2 DOWNTO 0); Burst_counter := (OTHERS => '0'); -- Row address mux CASE Bank_addr IS WHEN "00" => Rows_addr := B0_row_addr; WHEN "01" => Rows_addr := B1_row_addr; WHEN "10" => Rows_addr := B2_row_addr; WHEN OTHERS => Rows_addr := B3_row_addr; END CASE; END IF; -- Write data IF Data_in_enable = '1' THEN -- Initialize memory Init_mem (Bank_addr, CONV_INTEGER(Rows_addr)); -- Write first data IF Dm_pair (1) = '0' OR Dm_pair (0) = '0' THEN -- Data Buffer CASE Bank_addr IS WHEN "00" => Data_buf := Bank0 (CONV_INTEGER(Rows_addr)) (CONV_INTEGER(Cols_addr)); WHEN "01" => Data_buf := Bank1 (CONV_INTEGER(Rows_addr)) (CONV_INTEGER(Cols_addr)); WHEN "10" => Data_buf := Bank2 (CONV_INTEGER(Rows_addr)) (CONV_INTEGER(Cols_addr)); WHEN OTHERS => Data_buf := Bank3 (CONV_INTEGER(Rows_addr)) (CONV_INTEGER(Cols_addr)); END CASE; -- Perform DM Mask IF Dm_pair (0) = '0' THEN Data_buf ( 7 DOWNTO 0) := Dq_pair ( 7 DOWNTO 0); END IF; IF Dm_pair (1) = '0' THEN Data_buf (15 DOWNTO 8) := Dq_pair (15 DOWNTO 8); END IF; -- Write Data CASE Bank_addr IS WHEN "00" => Bank0 (CONV_INTEGER(Rows_addr)) (CONV_INTEGER(Cols_addr)) := Data_buf; WHEN "01" => Bank1 (CONV_INTEGER(Rows_addr)) (CONV_INTEGER(Cols_addr)) := Data_buf; WHEN "10" => Bank2 (CONV_INTEGER(Rows_addr)) (CONV_INTEGER(Cols_addr)) := Data_buf; WHEN OTHERS => Bank3 (CONV_INTEGER(Rows_addr)) (CONV_INTEGER(Cols_addr)) := Data_buf; END CASE; END IF; -- Increase Burst Counter Burst_decode; -- Write second data IF Dm_pair (3) = '0' OR Dm_pair (2) = '0' THEN -- Data Buffer CASE Bank_addr IS WHEN "00" => Data_buf := Bank0 (CONV_INTEGER(Rows_addr)) (CONV_INTEGER(Cols_addr)); WHEN "01" => Data_buf := Bank1 (CONV_INTEGER(Rows_addr)) (CONV_INTEGER(Cols_addr)); WHEN "10" => Data_buf := Bank2 (CONV_INTEGER(Rows_addr)) (CONV_INTEGER(Cols_addr)); WHEN OTHERS => Data_buf := Bank3 (CONV_INTEGER(Rows_addr)) (CONV_INTEGER(Cols_addr)); END CASE; -- Perform DM Mask IF Dm_pair (2) = '0' THEN Data_buf ( 7 DOWNTO 0) := Dq_pair (23 DOWNTO 16); END IF; IF Dm_pair (3) = '0' THEN Data_buf (15 DOWNTO 8) := Dq_pair (31 DOWNTO 24); END IF; -- Write Data CASE Bank_addr IS WHEN "00" => Bank0 (CONV_INTEGER(Rows_addr)) (CONV_INTEGER(Cols_addr)) := Data_buf; WHEN "01" => Bank1 (CONV_INTEGER(Rows_addr)) (CONV_INTEGER(Cols_addr)) := Data_buf; WHEN "10" => Bank2 (CONV_INTEGER(Rows_addr)) (CONV_INTEGER(Cols_addr)) := Data_buf; WHEN OTHERS => Bank3 (CONV_INTEGER(Rows_addr)) (CONV_INTEGER(Cols_addr)) := Data_buf; END CASE; END IF; -- Increase Burst Counter Burst_decode; -- tWR start and tWTR check IF Dm_pair (3 DOWNTO 2) = "00" OR Dm_pair (1 DOWNTO 0) = "00" THEN CASE Bank_addr IS WHEN "00" => WR_chk0 := NOW; WHEN "01" => WR_chk1 := NOW; WHEN "10" => WR_chk2 := NOW; WHEN OTHERS => WR_chk3 := NOW; END CASE; -- tWTR check ASSERT (Read_enable = '0') REPORT "tWTR violation during Read" SEVERITY WARNING; END IF; END IF; END IF; -- -- Auto Precharge Calculation -- IF Sys_clk'EVENT AND Sys_clk = '1' THEN -- Precharge counter IF Read_precharge (0) = '1' OR Write_precharge (0) = '1' THEN Count_precharge (0) := Count_precharge (0) + 1; END IF; IF Read_precharge (1) = '1' OR Write_precharge (1) = '1' THEN Count_precharge (1) := Count_precharge (1) + 1; END IF; IF Read_precharge (2) = '1' OR Write_precharge (2) = '1' THEN Count_precharge (2) := Count_precharge (2) + 1; END IF; IF Read_precharge (3) = '1' OR Write_precharge (3) = '1' THEN Count_precharge (3) := Count_precharge (3) + 1; END IF; -- Read with AutoPrecharge Calculation -- The device start internal precharge when: -- 1. Meet tRAS requirement -- 2. BL/2 cycles after command IF ((Read_precharge(0) = '1') AND (NOW - RAS_chk0 >= tRAS)) THEN IF ((Burst_length_2 = '1' AND Count_precharge(0) >= 1) OR (Burst_length_4 = '1' AND Count_precharge(0) >= 2) OR (Burst_length_8 = '1' AND Count_precharge(0) >= 4)) THEN Pc_b0 := '1'; Act_b0 := '0'; RP_chk0 := NOW; Read_precharge(0) := '0'; END IF; END IF; IF ((Read_precharge(1) = '1') AND (NOW - RAS_chk1 >= tRAS)) THEN IF ((Burst_length_2 = '1' AND Count_precharge(1) >= 1) OR (Burst_length_4 = '1' AND Count_precharge(1) >= 2) OR (Burst_length_8 = '1' AND Count_precharge(1) >= 4)) THEN Pc_b1 := '1'; Act_b1 := '0'; RP_chk1 := NOW; Read_precharge(1) := '0'; END IF; END IF; IF ((Read_precharge(2) = '1') AND (NOW - RAS_chk2 >= tRAS)) THEN IF ((Burst_length_2 = '1' AND Count_precharge(2) >= 1) OR (Burst_length_4 = '1' AND Count_precharge(2) >= 2) OR (Burst_length_8 = '1' AND Count_precharge(2) >= 4)) THEN Pc_b2 := '1'; Act_b2 := '0'; RP_chk2 := NOW; Read_precharge(2) := '0'; END IF; END IF; IF ((Read_precharge(3) = '1') AND (NOW - RAS_chk3 >= tRAS)) THEN IF ((Burst_length_2 = '1' AND Count_precharge(3) >= 1) OR (Burst_length_4 = '1' AND Count_precharge(3) >= 2) OR (Burst_length_8 = '1' AND Count_precharge(3) >= 4)) THEN Pc_b3 := '1'; Act_b3 := '0'; RP_chk3 := NOW; Read_precharge(3) := '0'; END IF; END IF; -- Write with AutoPrecharge Calculation -- The device start internal precharge when: -- 1. Meet tRAS requirement -- 2. Two clock after last burst -- Since tWR is time base, the model will compensate tRP IF ((Write_precharge(0) = '1') AND (NOW - RAS_chk0 >= tRAS)) THEN IF ((Burst_length_2 = '1' AND Count_precharge (0) >= 4) OR (Burst_length_4 = '1' AND Count_precharge (0) >= 5) OR (Burst_length_8 = '1' AND Count_precharge (0) >= 7)) THEN Pc_b0 := '1'; Act_b0 := '0'; RP_chk0 := NOW - ((2 tCK) - tWR); Write_precharge(0) := '0'; END IF; END IF; IF ((Write_precharge(1) = '1') AND (NOW - RAS_chk1 >= tRAS)) THEN IF ((Burst_length_2 = '1' AND Count_precharge (1) >= 4) OR (Burst_length_4 = '1' AND Count_precharge (1) >= 5) OR (Burst_length_8 = '1' AND Count_precharge (1) >= 7)) THEN Pc_b1 := '1'; Act_b1 := '0'; RP_chk1 := NOW - ((2 * tCK) - tWR); Write_precharge(1) := '0'; END IF; END IF; IF ((Write_precharge(2) = '1') AND (NOW - RAS_chk2 >= tRAS)) THEN IF ((Burst_length_2 = '1' AND Count_precharge (2) >= 4) OR (Burst_length_4 = '1' AND Count_precharge (2) >= 5) OR (Burst_length_8 = '1' AND Count_precharge (2) >= 7)) THEN Pc_b2 := '1'; Act_b2 := '0'; RP_chk2 := NOW - ((2 * tCK) - tWR); Write_precharge(2) := '0'; END IF; END IF; IF ((Write_precharge(3) = '1') AND (NOW - RAS_chk3 >= tRAS)) THEN IF ((Burst_length_2 = '1' AND Count_precharge (3) >= 4) OR (Burst_length_4 = '1' AND Count_precharge (3) >= 5) OR (Burst_length_8 = '1' AND Count_precharge (3) >= 7)) THEN Pc_b3 := '1'; Act_b3 := '0'; RP_chk3 := NOW - ((2 * tCK) - tWR); Write_precharge(3) := '0'; END IF; END IF; END IF; -- -- DLL Counter -- IF Sys_clk'EVENT AND Sys_clk = '1' THEN IF (DLL_Reset = '1' AND DLL_done = '0') THEN DLL_count := DLL_count + 1; IF (DLL_count >= 200) THEN DLL_done := '1'; END IF; END IF; END IF; -- -- Control Logic -- IF Sys_clk'EVENT AND Sys_clk = '1' THEN -- Auto Refresh IF Aref_enable = '1' THEN -- Auto Refresh to Auto Refresh ASSERT (NOW - RFC_chk >= tRFC) or (not chktiming) REPORT "tRFC violation during Auto Refresh" SEVERITY WARNING; -- Precharge to Auto Refresh ASSERT ((NOW - RP_chk0 >= tRP) AND (NOW - RP_chk1 >= tRP) AND (NOW - RP_chk2 >= tRP) AND (NOW - RP_chk3 >= tRP)) or (not chktiming) REPORT "tRP violation during Auto Refresh" SEVERITY WARNING; -- Precharge to Auto Refresh ASSERT (Pc_b0 = '1' AND Pc_b1 = '1' AND Pc_b2 = '1' AND Pc_b3 = '1') REPORT "All banks must be Precharge before Auto Refresh" SEVERITY WARNING; -- Record current tRFC time RFC_chk := NOW; END IF; -- Extended Load Mode Register IF Ext_mode_enable = '1' THEN IF (Pc_b0 = '1' AND Pc_b1 = '1' AND Pc_b2 = '1' AND Pc_b3 = '1') THEN IF (Addr (0) = '0') THEN DLL_enable := '1'; ELSE DLL_enable := '0'; END IF; END IF; -- Precharge to EMR ASSERT (Pc_b0 = '1' AND Pc_b1 = '1' AND Pc_b2 = '1' AND Pc_b3 = '1') REPORT "All bank must be Precharged before Extended Mode Register" SEVERITY WARNING; -- Precharge to EMR ASSERT ((NOW - RP_chk0 >= tRP) AND (NOW - RP_chk1 >= tRP) AND (NOW - RP_chk2 >= tRP) AND (NOW - RP_chk3 >= tRP)) or (not chktiming) REPORT "tRP violation during Extended Load Register" SEVERITY WARNING; -- LMR/EMR to EMR ASSERT (NOW - MRD_chk >= tMRD) or (not chktiming) REPORT "tMRD violation during Extended Mode Register" SEVERITY WARNING; -- Record current tMRD time MRD_chk := NOW; END IF; -- Load Mode Register IF Mode_reg_enable = '1' THEN -- Register mode Mode_reg <= Addr; -- DLL Reset IF (DLL_enable = '1' AND Addr (8) = '1') THEN DLL_reset := '1'; DLL_done := '0'; DLL_count := 0; ELSIF (DLL_enable = '1' AND DLL_reset = '0' AND Addr (8) = '0') THEN ASSERT (FALSE) REPORT "DLL is ENABLE: DLL RESET is require" SEVERITY WARNING; ELSIF (DLL_enable = '0' AND Addr (8) = '1') THEN ASSERT (FALSE) REPORT "DLL is DISABLE: DLL RESET will be ignored" SEVERITY WARNING; END IF; -- Precharge to LMR ASSERT (Pc_b0 = '1' AND Pc_b1 = '1' AND Pc_b2 = '1' AND Pc_b3 = '1') REPORT "All bank must be Precharged before Load Mode Register" SEVERITY WARNING; -- Precharge to EMR ASSERT ((NOW - RP_chk0 >= tRP) AND (NOW - RP_chk1 >= tRP) AND (NOW - RP_chk2 >= tRP) AND (NOW - RP_chk3 >= tRP)) or (not chktiming) REPORT "tRP violation during Load Mode Register" SEVERITY WARNING; -- LMR/ELMR to LMR ASSERT (NOW - MRD_chk >= tMRD) or (not chktiming) REPORT "tMRD violation during Load Mode Register" SEVERITY WARNING; -- Check for invalid Burst Length ASSERT ((Addr (2 DOWNTO 0) = "001") OR -- BL = 2 (Addr (2 DOWNTO 0) = "010") OR -- BL = 4 (Addr (2 DOWNTO 0) = "011")) -- BL = 8 REPORT "Invalid Burst Length during Load Mode Register" SEVERITY WARNING; -- Check for invalid CAS Latency ASSERT ((Addr (6 DOWNTO 4) = "010") OR -- CL = 2.0 (Addr (6 DOWNTO 4) = "110")) -- CL = 2.5 REPORT "Invalid CAS Latency during Load Mode Register" SEVERITY WARNING; -- Record current tMRD time MRD_chk := NOW; END IF; -- Active Block (latch Bank and Row Address) IF Active_enable = '1' THEN -- Activate an OPEN bank can corrupt data ASSERT ((Ba = "00" AND Act_b0 = '0') OR (Ba = "01" AND Act_b1 = '0') OR (Ba = "10" AND Act_b2 = '0') OR (Ba = "11" AND Act_b3 = '0')) REPORT "Bank is already activated - data can be corrupted" SEVERITY WARNING; -- Activate Bank 0 IF Ba = "00" AND Pc_b0 = '1' THEN -- Activate to Activate (same bank) ASSERT (NOW - RC_chk0 >= tRC) or (not chktiming) REPORT "tRC violation during Activate Bank 0" SEVERITY WARNING; -- Precharge to Active ASSERT (NOW - RP_chk0 >= tRP) or (not chktiming) REPORT "tRP violation during Activate Bank 0" SEVERITY WARNING; -- Record Variables for checking violation Act_b0 := '1'; Pc_b0 := '0'; B0_row_addr := Addr; RC_chk0 := NOW; RCD_chk0 := NOW; RAS_chk0 := NOW; RAP_chk0 := NOW; END IF; -- Activate Bank 1 IF Ba = "01" AND Pc_b1 = '1' THEN -- Activate to Activate (same bank) ASSERT (NOW - RC_chk1 >= tRC) or (not chktiming) REPORT "tRC violation during Activate Bank 1" SEVERITY WARNING; -- Precharge to Active ASSERT (NOW - RP_chk1 >= tRP) or (not chktiming) REPORT "tRP violation during Activate Bank 1" SEVERITY WARNING; -- Record Variables for checking violation Act_b1 := '1'; Pc_b1 := '0'; B1_row_addr := Addr; RC_chk1 := NOW; RCD_chk1 := NOW; RAS_chk1 := NOW; RAP_chk1 := NOW; END IF; -- Activate Bank 2 IF Ba = "10" AND Pc_b2 = '1' THEN -- Activate to Activate (same bank) ASSERT (NOW - RC_chk2 >= tRC) or (not chktiming) REPORT "tRC violation during Activate Bank 2" SEVERITY WARNING; -- Precharge to Active ASSERT (NOW - RP_chk2 >= tRP) or (not chktiming) REPORT "tRP violation during Activate Bank 2" SEVERITY WARNING; -- Record Variables for checking violation Act_b2 := '1'; Pc_b2 := '0'; B2_row_addr := Addr; RC_chk2 := NOW; RCD_chk2 := NOW; RAS_chk2 := NOW; RAP_chk2 := NOW; END IF; -- Activate Bank 3 IF Ba = "11" AND Pc_b3 = '1' THEN -- Activate to Activate (same bank) ASSERT (NOW - RC_chk3 >= tRC) or (not chktiming) REPORT "tRC violation during Activate Bank 3" SEVERITY WARNING; -- Precharge to Active ASSERT (NOW - RP_chk3 >= tRP) or (not chktiming) REPORT "tRP violation during Activate Bank 3" SEVERITY WARNING; -- Record Variables for checking violation Act_b3 := '1'; Pc_b3 := '0'; B3_row_addr := Addr; RC_chk3 := NOW; RCD_chk3 := NOW; RAS_chk3 := NOW; RAP_chk3 := NOW; END IF; -- Activate Bank A to Activate Bank B IF (Prev_bank /= Ba) THEN ASSERT (NOW - RRD_chk >= tRRD) or (not chktiming) REPORT "tRRD violation during Activate" SEVERITY WARNING; END IF; -- AutoRefresh to Activate ASSERT (NOW - RFC_chk >= tRFC) or (not chktiming) REPORT "tRFC violation during Activate" SEVERITY WARNING; -- Record Variables for Checking Violation RRD_chk := NOW; Prev_bank := Ba; END IF; -- Precharge Block - Consider NOP if bank already precharged or in process of precharging IF Prech_enable = '1' THEN -- EMR or LMR to Precharge ASSERT (NOW - MRD_chk >= tMRD) or (not chktiming) REPORT "tMRD violation during Precharge" SEVERITY WARNING; -- Precharge Bank 0 IF ((Addr (10) = '1' OR (Addr (10) = '0' AND Ba = "00")) AND Act_b0 = '1') THEN Act_b0 := '0'; Pc_b0 := '1'; RP_chk0 := NOW; -- Activate to Precharge bank 0 ASSERT (NOW - RAS_chk0 >= tRAS) or (not chktiming) REPORT "tRAS violation during Precharge" SEVERITY WARNING; -- tWR violation check for Write ASSERT (NOW - WR_chk0 >= tWR) or (not chktiming) REPORT "tWR violation during Precharge" SEVERITY WARNING; END IF; -- Precharge Bank 1 IF ((Addr (10) = '1' OR (Addr (10) = '0' AND Ba = "01")) AND Act_b1 = '1') THEN Act_b1 := '0'; Pc_b1 := '1'; RP_chk1 := NOW; -- Activate to Precharge ASSERT (NOW - RAS_chk1 >= tRAS) or (not chktiming) REPORT "tRAS violation during Precharge" SEVERITY WARNING; -- tWR violation check for Write ASSERT (NOW - WR_chk1 >= tWR) or (not chktiming) REPORT "tWR violation during Precharge" SEVERITY WARNING; END IF; -- Precharge Bank 2 IF ((Addr (10) = '1' OR (Addr (10) = '0' AND Ba = "10")) AND Act_b2 = '1') THEN Act_b2 := '0'; Pc_b2 := '1'; RP_chk2 := NOW; -- Activate to Precharge ASSERT (NOW - RAS_chk2 >= tRAS) or (not chktiming) REPORT "tRAS violation during Precharge" SEVERITY WARNING; -- tWR violation check for Write ASSERT (NOW - WR_chk2 >= tWR) or (not chktiming) REPORT "tWR violation during Precharge" SEVERITY WARNING; END IF; -- Precharge Bank 3 IF ((Addr (10) = '1' OR (Addr (10) = '0' AND Ba = "11")) AND Act_b3 = '1') THEN Act_b3 := '0'; Pc_b3 := '1'; RP_chk3 := NOW; -- Activate to Precharge ASSERT (NOW - RAS_chk3 >= tRAS) or (not chktiming) REPORT "tRAS violation during Precharge" SEVERITY WARNING; -- tWR violation check for Write ASSERT (NOW - WR_chk3 >= tWR) or (not chktiming) REPORT "tWR violation during Precharge" SEVERITY WARNING; END IF; -- Pipeline for READ IF CAS_latency_15 = '1' THEN A10_precharge (3) := Addr(10); Bank_precharge (3) := Ba; Cmnd_precharge (3) := '1'; ELSIF CAS_latency_2 = '1' THEN A10_precharge (4) := Addr(10); Bank_precharge (4) := Ba; Cmnd_precharge (4) := '1'; ELSIF CAS_latency_25 = '1' THEN A10_precharge (5) := Addr(10); Bank_precharge (5) := Ba; Cmnd_precharge (5) := '1'; ELSIF CAS_latency_3 = '1' THEN A10_precharge (6) := Addr(10); Bank_precharge (6) := Ba; Cmnd_precharge (6) := '1'; ELSIF CAS_latency_4 = '1' THEN A10_precharge (8) := Addr(10); Bank_precharge (8) := Ba; Cmnd_precharge (8) := '1'; END IF; END IF; -- Burst Terminate IF Burst_term = '1' THEN -- Pipeline for Read IF CAS_latency_15 = '1' THEN Cmnd_bst (3) := '1'; ELSIF CAS_latency_2 = '1' THEN Cmnd_bst (4) := '1'; ELSIF CAS_latency_25 = '1' THEN Cmnd_bst (5) := '1'; ELSIF CAS_latency_3 = '1' THEN Cmnd_bst (6) := '1'; ELSIF CAS_latency_4 = '1' THEN Cmnd_bst (8) := '1'; END IF; -- Terminate Write ASSERT (Data_in_enable = '0') REPORT "It's illegal to Burst Terminate a Write" SEVERITY WARNING; -- Terminate Read with Auto Precharge ASSERT (Read_precharge (0) = '0' AND Read_precharge (1) = '0' AND Read_precharge (2) = '0' AND Read_precharge (3) = '0') REPORT "It's illegal to Burst Terminate a Read with Auto Precharge" SEVERITY WARNING; END IF; -- Read Command IF Read_enable = '1' THEN -- CAS Latency Pipeline IF Cas_latency_15 = '1' THEN Read_cmnd (3) := '1'; Read_bank (3) := Ba; Read_cols (3) := Addr (cols_bits-1 DOWNTO 0); ELSIF Cas_latency_2 = '1' THEN Read_cmnd (4) := '1'; Read_bank (4) := Ba; Read_cols (4) := Addr (cols_bits-1 DOWNTO 0); ELSIF Cas_latency_25 = '1' THEN Read_cmnd (5) := '1'; Read_bank (5) := Ba; Read_cols (5) := Addr (cols_bits-1 DOWNTO 0); ELSIF Cas_latency_3 = '1' THEN Read_cmnd (6) := '1'; Read_bank (6) := Ba; Read_cols (6) := Addr (cols_bits-1 DOWNTO 0); ELSIF Cas_latency_4 = '1' THEN Read_cmnd (8) := '1'; Read_bank (8) := Ba; Read_cols (8) := Addr (cols_bits-1 DOWNTO 0); END IF; -- Write to Read: Terminate Write Immediately IF Data_in_enable = '1' THEN Data_in_enable := '0'; END IF; -- Interrupting a Read with Auto Precharge (same bank only) ASSERT (Read_precharge(CONV_INTEGER(Ba)) = '0') REPORT "It's illegal to interrupt a Read with Auto Precharge" SEVERITY WARNING; -- Activate to Read ASSERT ((Ba = "00" AND Act_b0 = '1') OR (Ba = "01" AND Act_b1 = '1') OR (Ba = "10" AND Act_b2 = '1') OR (Ba = "11" AND Act_b3 = '1')) REPORT "Bank is not Activated for Read" SEVERITY WARNING; -- Activate to Read without Auto Precharge IF Addr (10) = '0' THEN ASSERT ((Ba = "00" AND NOW - RCD_chk0 >= tRCD) OR (Ba = "01" AND NOW - RCD_chk1 >= tRCD) OR (Ba = "10" AND NOW - RCD_chk2 >= tRCD) OR (Ba = "11" AND NOW - RCD_chk3 >= tRCD)) or (not chktiming) REPORT "tRCD violation during Read" SEVERITY WARNING; END IF; -- Activate to Read with Auto Precharge IF Addr (10) = '1' THEN ASSERT ((Ba = "00" AND NOW - RAP_chk0 >= tRAP) OR (Ba = "01" AND NOW - RAP_chk1 >= tRAP) OR (Ba = "10" AND NOW - RAP_chk2 >= tRAP) OR (Ba = "11" AND NOW - RAP_chk3 >= tRAP)) or (not chktiming) REPORT "tRAP violation during Read" SEVERITY WARNING; END IF; -- Auto precharge IF Addr (10) = '1' THEN Read_precharge (Conv_INTEGER(Ba)) := '1'; Count_precharge (Conv_INTEGER(Ba)) := 0; END IF; -- DLL Check IF (DLL_reset = '1') THEN ASSERT (DLL_done = '1') REPORT "DLL RESET not complete" SEVERITY WARNING; END IF; END IF; -- Write Command IF Write_enable = '1' THEN -- Pipeline for Write Write_cmnd (2) := '1'; Write_bank (2) := Ba; Write_cols (2) := Addr (cols_bits-1 DOWNTO 0); -- Interrupting a Write with Auto Precharge (same bank only) ASSERT (Write_precharge(CONV_INTEGER(Ba)) = '0') REPORT "It's illegal to interrupt a Write with Auto Precharge" SEVERITY WARNING; -- Activate to Write ASSERT ((Ba = "00" AND Act_b0 = '1') OR (Ba = "01" AND Act_b1 = '1') OR (Ba = "10" AND Act_b2 = '1') OR (Ba = "11" AND Act_b3 = '1')) REPORT "Bank is not Activated for Write" SEVERITY WARNING; -- Activate to Write ASSERT ((Ba = "00" AND NOW - RCD_chk0 >= tRCD) OR (Ba = "01" AND NOW - RCD_chk1 >= tRCD) OR (Ba = "10" AND NOW - RCD_chk2 >= tRCD) OR (Ba = "11" AND NOW - RCD_chk3 >= tRCD)) or (not chktiming) REPORT "tRCD violation during Write" SEVERITY WARNING; -- Auto precharge IF Addr (10) = '1' THEN Write_precharge (Conv_INTEGER(Ba)) := '1'; Count_precharge (Conv_INTEGER(Ba)) := 0; END IF; END IF; END IF; IF (now >= (fdelay * 1 us)) and not file_loaded THEN --' file_loaded := true; WHILE NOT endfile(file_load) LOOP readline(file_load, l); read(l, ch); if (ch /= 'S') or (ch /= 's') then hread(l, rectype); hread(l, reclen); recaddr := (others => '0'); case rectype is when "0001" => hread(l, recaddr(15 downto 0)); when "0010" => hread(l, recaddr(23 downto 0)); when "0011" => hread(l, recaddr); when "0111" => hread(l, recaddr); -- if (index = 0) then print("Start address : " & tost(recaddr)); end if; next; when others => next; end case; case bbits is when 64 => -- 64-bit bank with four 16-bit DDRs recaddr(31 downto 18+cols_bits) := (others => '0'); hread(l, recdata); Bank_Load := recaddr(17+cols_bits downto 16+cols_bits); Rows_Load := recaddr(15+cols_bits downto 3+cols_bits); Cols_Load := recaddr(2+cols_bits downto 3); Init_mem (Bank_Load, To_Integer(Rows_Load)); IF Bank_Load = "00" THEN for i in 0 to 1 loop Bank0 (To_Integer(Rows_Load)) (To_Integer(Cols_Load)+i) := (recdata(i64+index16 to i64+index16+15)); end loop; ELSIF Bank_Load = "01" THEN for i in 0 to 1 loop Bank1 (To_Integer(Rows_Load)) (To_Integer(Cols_Load)+i) := (recdata(i64+index16 to i64+index16+15)); end loop; ELSIF Bank_Load = "10" THEN for i in 0 to 1 loop Bank2 (To_Integer(Rows_Load)) (To_Integer(Cols_Load)+i) := (recdata(i64+index16 to i64+index16+15)); end loop; ELSIF Bank_Load = "11" THEN for i in 0 to 1 loop Bank3 (To_Integer(Rows_Load)) (To_Integer(Cols_Load)+i) := (recdata(i64+index16 to i64+index16+15)); end loop; END IF; when 32 => -- 32-bit bank with two 16-bit DDRs recaddr(31 downto 17+cols_bits) := (others => '0'); hread(l, recdata); Bank_Load := recaddr(16+cols_bits downto 15+cols_bits); Rows_Load := recaddr(14+cols_bits downto 2+cols_bits); Cols_Load := recaddr(1+cols_bits downto 2); Init_mem (Bank_Load, To_Integer(Rows_Load)); IF Bank_Load = "00" THEN for i in 0 to 3 loop Bank0 (To_Integer(Rows_Load)) (To_Integer(Cols_Load)+i) := (recdata(i32+index16 to i32+index16+15)); end loop; ELSIF Bank_Load = "01" THEN for i in 0 to 3 loop Bank1 (To_Integer(Rows_Load)) (To_Integer(Cols_Load)+i) := (recdata(i32+index16 to i32+index16+15)); end loop; ELSIF Bank_Load = "10" THEN for i in 0 to 3 loop Bank2 (To_Integer(Rows_Load)) (To_Integer(Cols_Load)+i) := (recdata(i32+index16 to i32+index16+15)); end loop; ELSIF Bank_Load = "11" THEN for i in 0 to 3 loop Bank3 (To_Integer(Rows_Load)) (To_Integer(Cols_Load)+i) := (recdata(i32+index16 to i32+index16+15)); end loop; END IF; when others => -- 16-bit bank with one 16-bit DDR hread(l, recdata); recaddr(31 downto 16+cols_bits) := (others => '0'); Bank_Load := recaddr(15+cols_bits downto 14+cols_bits); Rows_Load := recaddr(13+cols_bits downto 1+cols_bits); Cols_Load := recaddr(cols_bits downto 1); Init_mem (Bank_Load, To_Integer(Rows_Load)); IF Bank_Load = "00" THEN for i in 0 to 3 loop Bank0 (To_Integer(Rows_Load)) (To_Integer(Cols_Load)+i) := (recdata(i16 to i16+15)); Bank0 (To_Integer(Rows_Load)) (To_Integer(Cols_Load)+i+4) := (recdata((i+4)16 to (i+4)16+15)); end loop; ELSIF Bank_Load = "01" THEN for i in 0 to 3 loop Bank1 (To_Integer(Rows_Load)) (To_Integer(Cols_Load)+i) := (recdata(i16 to i16+15)); Bank1 (To_Integer(Rows_Load)) (To_Integer(Cols_Load)+i+4) := (recdata((i+4)16 to (i+4)16+15)); end loop; ELSIF Bank_Load = "10" THEN for i in 0 to 3 loop Bank2 (To_Integer(Rows_Load)) (To_Integer(Cols_Load)+i) := (recdata(i16 to i16+15)); Bank2 (To_Integer(Rows_Load)) (To_Integer(Cols_Load)+i+4) := (recdata((i+4)16 to (i+4)16+15)); end loop; ELSIF Bank_Load = "11" THEN for i in 0 to 3 loop Bank3 (To_Integer(Rows_Load)) (To_Integer(Cols_Load)+i) := (recdata(i16 to i16+15)); Bank3 (To_Integer(Rows_Load)) (To_Integer(Cols_Load)+i+4) := (recdata((i+4)16 to (i+4)16+15)); end loop; END IF; END case; END IF; END LOOP; END IF; END PROCESS; -- -- Dqs Receiver -- dqs_rcvrs : PROCESS VARIABLE Dm_temp : STD_LOGIC_VECTOR (1 DOWNTO 0); VARIABLE Dq_temp : STD_LOGIC_VECTOR (data_bits - 1 DOWNTO 0); BEGIN WAIT ON Dqs; -- Latch data at posedge Dqs IF Dqs'EVENT AND Dqs (1) = '1' AND Dqs (0) = '1' THEN Dq_temp := Dq; Dm_temp := Dm; END IF; -- Latch data at negedge Dqs IF Dqs'EVENT AND Dqs (1) = '0' AND Dqs (0) = '0' THEN Dq_pair <= (Dq & Dq_temp); Dm_pair <= (Dm & Dm_temp); END IF; END PROCESS; -- -- Setup timing checks -- Setup_check : PROCESS BEGIN WAIT ON Sys_clk; IF Sys_clk'EVENT AND Sys_clk = '1' THEN ASSERT(Cke'LAST_EVENT >= tIS) or (not chktiming) REPORT "CKE Setup time violation -- tIS" SEVERITY WARNING; ASSERT(Cs_n'LAST_EVENT >= tIS) or (not chktiming) REPORT "CS# Setup time violation -- tIS" SEVERITY WARNING; ASSERT(Cas_n'LAST_EVENT >= tIS) or (not chktiming) REPORT "CAS# Setup time violation -- tIS" SEVERITY WARNING; ASSERT(Ras_n'LAST_EVENT >= tIS) or (not chktiming) REPORT "RAS# Setup time violation -- tIS" SEVERITY WARNING; ASSERT(We_n'LAST_EVENT >= tIS) or (not chktiming) REPORT "WE# Setup time violation -- tIS" SEVERITY WARNING; ASSERT(Addr'LAST_EVENT >= tIS) or (not chktiming) REPORT "ADDR Setup time violation -- tIS" SEVERITY WARNING; ASSERT(Ba'LAST_EVENT >= tIS) or (not chktiming) REPORT "BA Setup time violation -- tIS" SEVERITY WARNING; END IF; END PROCESS; -- -- Hold timing checks -- Hold_check : PROCESS BEGIN WAIT ON Sys_clk'DELAYED (tIH); IF Sys_clk'DELAYED (tIH) = '1' THEN ASSERT(Cke'LAST_EVENT >= tIH) or (not chktiming) REPORT "CKE Hold time violation -- tIH" SEVERITY WARNING; ASSERT(Cs_n'LAST_EVENT >= tIH) or (not chktiming) REPORT "CS# Hold time violation -- tIH" SEVERITY WARNING; ASSERT(Cas_n'LAST_EVENT >= tIH) or (not chktiming) REPORT "CAS# Hold time violation -- tIH" SEVERITY WARNING; ASSERT(Ras_n'LAST_EVENT >= tIH) or (not chktiming) REPORT "RAS# Hold time violation -- tIH" SEVERITY WARNING; ASSERT(We_n'LAST_EVENT >= tIH) or (not chktiming) REPORT "WE# Hold time violation -- tIH" SEVERITY WARNING; ASSERT(Addr'LAST_EVENT >= tIH) or (not chktiming) REPORT "ADDR Hold time violation -- tIH" SEVERITY WARNING; ASSERT(Ba'LAST_EVENT >= tIH) or (not chktiming) REPORT "BA Hold time violation -- tIH" SEVERITY WARNING; END IF; END PROCESS; END behave;	gpl-2.0	26e31580908490c833985e09ba8542f4	0.450765	3.993385	false	false	false	false
marco-c/leon-nexys2	grlib-gpl-1.3.4-b4140/lib/gaisler/net/net.vhd	1	13,684	------------------------------------------------------------------------------ -- This file is a part of the GRLIB VHDL IP LIBRARY -- Copyright (C) 2003 - 2008, Gaisler Research -- Copyright (C) 2008 - 2013, Aeroflex Gaisler -- -- This program is free software; you can redistribute it and/or modify -- it under the terms of the GNU General Public License as published by -- the Free Software Foundation; either version 2 of the License, or -- (at your option) any later version. -- -- This program is distributed in the hope that it will be useful, -- but WITHOUT ANY WARRANTY; without even the implied warranty of -- MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the -- GNU General Public License for more details. -- -- You should have received a copy of the GNU General Public License -- along with this program; if not, write to the Free Software -- Foundation, Inc., 59 Temple Place, Suite 330, Boston, MA 02111-1307 USA ----------------------------------------------------------------------------- -- Entity: net -- File: net.vhd -- Author: Jiri Gaisler - Gaisler Research -- Description: Package with component and type declarations for network cores ------------------------------------------------------------------------------ library ieee; use ieee.std_logic_1164.all; library grlib; use grlib.amba.all; package net is type eth_in_type is record gtx_clk : std_ulogic; rmii_clk : std_ulogic; tx_clk : std_ulogic; rx_clk : std_ulogic; rxd : std_logic_vector(7 downto 0); rx_dv : std_ulogic; rx_er : std_ulogic; rx_col : std_ulogic; rx_crs : std_ulogic; mdio_i : std_ulogic; mdint : std_ulogic; phyrstaddr : std_logic_vector(4 downto 0); edcladdr : std_logic_vector(3 downto 0); edclsepahb : std_ulogic; edcldisable: std_ulogic; end record; constant eth_in_none : eth_in_type := ('0', '0', '0', '0', (others => '0'), '0', '0', '0', '0', '0', '0', (others => '0'), (others => '0'), '0', '0'); type eth_out_type is record reset : std_ulogic; txd : std_logic_vector(7 downto 0); tx_en : std_ulogic; tx_er : std_ulogic; tx_clk : std_ulogic; mdc : std_ulogic; mdio_o : std_ulogic; mdio_oe : std_ulogic; gbit : std_ulogic; speed : std_ulogic; end record; constant eth_out_none : eth_out_type := ('0', (others => '0'), '0', '0', '0', '0', '0', '1', '0', '0'); type eth_sgmii_in_type is record clkp : std_ulogic; clkn : std_ulogic; rxp : std_ulogic; rxn : std_ulogic; mdio_i : std_ulogic; mdint : std_ulogic; end record; type eth_sgmii_out_type is record reset : std_ulogic; txp : std_ulogic; txn : std_ulogic; mdc : std_ulogic; mdio_o : std_ulogic; mdio_oe : std_ulogic; end record; component eth_arb generic( fullduplex : integer := 0; mdiomaster : integer := 0); port( rst : in std_logic; clk : in std_logic; ethi : in eth_in_type; etho : out eth_out_type; methi : in eth_out_type; metho : out eth_in_type; dethi : in eth_out_type; detho : out eth_in_type ); end component; component greth is generic( hindex : integer := 0; pindex : integer := 0; paddr : integer := 0; pmask : integer := 16#FFF#; pirq : integer := 0; memtech : integer := 0; ifg_gap : integer := 24; attempt_limit : integer := 16; backoff_limit : integer := 10; slot_time : integer := 128; mdcscaler : integer range 0 to 255 := 25; enable_mdio : integer range 0 to 1 := 0; fifosize : integer range 4 to 512 := 8; nsync : integer range 1 to 2 := 2; edcl : integer range 0 to 3 := 0; edclbufsz : integer range 1 to 64 := 1; macaddrh : integer := 16#00005E#; macaddrl : integer := 16#000000#; ipaddrh : integer := 16#c0a8#; ipaddrl : integer := 16#0035#; phyrstadr : integer range 0 to 32 := 0; rmii : integer range 0 to 1 := 0; oepol : integer range 0 to 1 := 0; scanen : integer range 0 to 1 := 0; ft : integer range 0 to 2 := 0; edclft : integer range 0 to 2 := 0; mdint_pol : integer range 0 to 1 := 0; enable_mdint : integer range 0 to 1 := 0; multicast : integer range 0 to 1 := 0; ramdebug : integer range 0 to 2 := 0; mdiohold : integer := 1; maxsize : integer := 1500 ); port( rst : in std_ulogic; clk : in std_ulogic; ahbmi : in ahb_mst_in_type; ahbmo : out ahb_mst_out_type; apbi : in apb_slv_in_type; apbo : out apb_slv_out_type; ethi : in eth_in_type; etho : out eth_out_type ); end component; component greth_mb is generic( hindex : integer := 0; ehindex : integer := 0; pindex : integer := 0; paddr : integer := 0; pmask : integer := 16#FFF#; pirq : integer := 0; memtech : integer := 0; ifg_gap : integer := 24; attempt_limit : integer := 16; backoff_limit : integer := 10; slot_time : integer := 128; mdcscaler : integer range 0 to 255 := 25; enable_mdio : integer range 0 to 1 := 0; fifosize : integer range 4 to 512 := 8; nsync : integer range 1 to 2 := 2; edcl : integer range 0 to 3 := 0; edclbufsz : integer range 1 to 64 := 1; macaddrh : integer := 16#00005E#; macaddrl : integer := 16#000000#; ipaddrh : integer := 16#c0a8#; ipaddrl : integer := 16#0035#; phyrstadr : integer range 0 to 32 := 0; rmii : integer range 0 to 1 := 0; oepol : integer range 0 to 1 := 0; scanen : integer range 0 to 1 := 0; ft : integer range 0 to 2 := 0; edclft : integer range 0 to 2 := 0; mdint_pol : integer range 0 to 1 := 0; enable_mdint : integer range 0 to 1 := 0; multicast : integer range 0 to 1 := 0; edclsepahb : integer range 0 to 1 := 0; ramdebug : integer range 0 to 2 := 0; mdiohold : integer := 1; maxsize : integer := 1500 ); port( rst : in std_ulogic; clk : in std_ulogic; ahbmi : in ahb_mst_in_type; ahbmo : out ahb_mst_out_type; ahbmi2 : in ahb_mst_in_type; ahbmo2 : out ahb_mst_out_type; apbi : in apb_slv_in_type; apbo : out apb_slv_out_type; ethi : in eth_in_type; etho : out eth_out_type ); end component; component greth_gbit_mb is generic( hindex : integer := 0; ehindex : integer := 0; pindex : integer := 0; paddr : integer := 0; pmask : integer := 16#FFF#; pirq : integer := 0; memtech : integer := 0; ifg_gap : integer := 24; attempt_limit : integer := 16; backoff_limit : integer := 10; slot_time : integer := 128; mdcscaler : integer range 0 to 255 := 25; nsync : integer range 1 to 2 := 2; edcl : integer range 0 to 3 := 0; edclbufsz : integer range 1 to 64 := 1; burstlength : integer range 4 to 128 := 32; macaddrh : integer := 16#00005E#; macaddrl : integer := 16#000000#; ipaddrh : integer := 16#c0a8#; ipaddrl : integer := 16#0035#; phyrstadr : integer range 0 to 32 := 0; sim : integer range 0 to 1 := 0; oepol : integer range 0 to 1 := 0; scanen : integer range 0 to 1 := 0; ft : integer range 0 to 2 := 0; edclft : integer range 0 to 2 := 0; mdint_pol : integer range 0 to 1 := 0; enable_mdint : integer range 0 to 1 := 0; multicast : integer range 0 to 1 := 0; edclsepahb : integer range 0 to 1 := 0; ramdebug : integer range 0 to 2 := 0; mdiohold : integer := 1); port( rst : in std_ulogic; clk : in std_ulogic; ahbmi : in ahb_mst_in_type; ahbmo : out ahb_mst_out_type; ahbmi2 : in ahb_mst_in_type; ahbmo2 : out ahb_mst_out_type; apbi : in apb_slv_in_type; apbo : out apb_slv_out_type; ethi : in eth_in_type; etho : out eth_out_type ); end component; component greth_gbit is generic( hindex : integer := 0; pindex : integer := 0; paddr : integer := 0; pmask : integer := 16#FFF#; pirq : integer := 0; memtech : integer := 0; ifg_gap : integer := 24; attempt_limit : integer := 16; backoff_limit : integer := 10; slot_time : integer := 128; mdcscaler : integer range 0 to 255 := 25; nsync : integer range 1 to 2 := 2; edcl : integer range 0 to 3 := 0; edclbufsz : integer range 1 to 64 := 1; burstlength : integer range 4 to 128 := 32; macaddrh : integer := 16#00005E#; macaddrl : integer := 16#000000#; ipaddrh : integer := 16#c0a8#; ipaddrl : integer := 16#0035#; phyrstadr : integer range 0 to 32 := 0; sim : integer range 0 to 1 := 0; oepol : integer range 0 to 1 := 0; scanen : integer range 0 to 1 := 0; ft : integer range 0 to 2 := 0; edclft : integer range 0 to 2 := 0; mdint_pol : integer range 0 to 1 := 0; enable_mdint : integer range 0 to 1 := 0; multicast : integer range 0 to 1 := 0; ramdebug : integer range 0 to 2 := 0; mdiohold : integer := 1); port( rst : in std_ulogic; clk : in std_ulogic; ahbmi : in ahb_mst_in_type; ahbmo : out ahb_mst_out_type; apbi : in apb_slv_in_type; apbo : out apb_slv_out_type; ethi : in eth_in_type; etho : out eth_out_type ); end component; component grethm generic( hindex : integer := 0; pindex : integer := 0; paddr : integer := 0; pmask : integer := 16#FFF#; pirq : integer := 0; memtech : integer := 0; ifg_gap : integer := 24; attempt_limit : integer := 16; backoff_limit : integer := 10; slot_time : integer := 128; mdcscaler : integer range 0 to 255 := 25; enable_mdio : integer range 0 to 1 := 0; fifosize : integer range 4 to 64 := 8; nsync : integer range 1 to 2 := 2; edcl : integer range 0 to 3 := 0; edclbufsz : integer range 1 to 64 := 1; burstlength : integer range 4 to 128 := 32; macaddrh : integer := 16#00005E#; macaddrl : integer := 16#000000#; ipaddrh : integer := 16#c0a8#; ipaddrl : integer := 16#0035#; phyrstadr : integer range 0 to 32 := 0; rmii : integer range 0 to 1 := 0; sim : integer range 0 to 1 := 0; giga : integer range 0 to 1 := 0; oepol : integer range 0 to 1 := 0; scanen : integer range 0 to 1 := 0; ft : integer range 0 to 2 := 0; edclft : integer range 0 to 1 := 0; mdint_pol : integer range 0 to 1 := 0; enable_mdint : integer range 0 to 1 := 0; multicast : integer range 0 to 1 := 0; ramdebug : integer range 0 to 2 := 0; mdiohold : integer := 1); port( rst : in std_ulogic; clk : in std_ulogic; ahbmi : in ahb_mst_in_type; ahbmo : out ahb_mst_out_type; apbi : in apb_slv_in_type; apbo : out apb_slv_out_type; ethi : in eth_in_type; etho : out eth_out_type ); end component; component rgmii is generic ( pindex : integer := 0; paddr : integer := 0; pmask : integer := 16#fff#; tech : integer := 0; gmii : integer := 0; extclk : integer := 0; clkdiv2 : integer := 0; debugmem : integer := 0 ); port ( rstn : in std_ulogic; clk_tx_g : in std_ulogic; gmiii : out eth_in_type; gmiio : in eth_out_type; rgmiii : in eth_in_type; rgmiio : out eth_out_type ; -- APB Status bus apb_clk : in std_logic; apb_rstn : in std_logic; apbi : in apb_slv_in_type; apbo : out apb_slv_out_type ); end component; end;	gpl-2.0	4dbd3d0c6638b59a4e7b3c17b31216e0	0.48005	3.825552	false	false	false	false
marco-c/leon-nexys2	grlib-gpl-1.3.4-b4140/lib/gaisler/pci/grpci1/pci_target.vhd	1	16,673	------------------------------------------------------------------------------ -- This file is a part of the GRLIB VHDL IP LIBRARY -- Copyright (C) 2003 - 2008, Gaisler Research -- Copyright (C) 2008 - 2013, Aeroflex Gaisler -- -- This program is free software; you can redistribute it and/or modify -- it under the terms of the GNU General Public License as published by -- the Free Software Foundation; either version 2 of the License, or -- (at your option) any later version. -- -- This program is distributed in the hope that it will be useful, -- but WITHOUT ANY WARRANTY; without even the implied warranty of -- MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the -- GNU General Public License for more details. -- -- You should have received a copy of the GNU General Public License -- along with this program; if not, write to the Free Software -- Foundation, Inc., 59 Temple Place, Suite 330, Boston, MA 02111-1307 USA ----------------------------------------------------------------------------- -- Entity: pci_target -- File: pci_target.vhd -- Author: Jiri Gaisler - Gaisler Research -- Description: Simple PCI target interface ------------------------------------------------------------------------------ library ieee; use ieee.std_logic_1164.all; library grlib; use grlib.amba.all; use grlib.stdlib.all; use grlib.devices.all; library gaisler; use gaisler.pci.all; entity pci_target is generic ( hindex : integer := 0; abits : integer := 21; device_id : integer := 0; -- PCI device ID vendor_id : integer := 0; -- PCI vendor ID nsync : integer range 1 to 2 := 1; -- 1 or 2 sync regs between clocks oepol : integer := 0); port( rst : in std_logic; clk : in std_logic; pciclk : in std_logic; pcii : in pci_in_type; pcio : out pci_out_type; ahbmi : in ahb_mst_in_type; ahbmo : out ahb_mst_out_type ); end; architecture rtl of pci_target is constant REVISION : amba_version_type := 0; constant hconfig : ahb_config_type := ( 0 => ahb_device_reg(VENDOR_GAISLER, GAISLER_PCITRG, 0, REVISION, 0), others => zero32); constant CSYNC : integer := nsync-1; constant MADDR_WIDTH : integer := abits; constant zero : std_logic_vector(31 downto 0) := (others => '0'); subtype word4 is std_logic_vector(3 downto 0); subtype word32 is std_logic_vector(31 downto 0); constant pci_memory_read : word4 := "0110"; constant pci_memory_write : word4 := "0111"; constant pci_config_read : word4 := "1010"; constant pci_config_write : word4 := "1011"; constant pci_memory_read_m : word4 := "1100"; -- Aliased to Memory Read constant pci_memory_read_l : word4 := "1110"; -- Aliased to Memory Read constant pci_memory_write_i: word4 := "1111"; -- Aliased to Memory Write type pci_input_type is record ad : std_logic_vector(31 downto 0); cbe : std_logic_vector(3 downto 0); frame : std_logic; devsel : std_logic; idsel : std_logic; trdy : std_logic; irdy : std_logic; par : std_logic; stop : std_logic; rst : std_logic; end record; type pci_target_state_type is (idle, b_busy, s_data, backoff, turn_ar); type pci_reg_type is record addr : std_logic_vector(MADDR_WIDTH-1 downto 0); data : std_logic_vector(31 downto 0); cmd : std_logic_vector(3 downto 0); state : pci_target_state_type; csel : std_logic; msel : std_logic; read : std_logic; devsel : std_logic; trdy : std_logic; stop : std_logic; par : std_logic; oe_par : std_logic; oe_ad : std_logic; oe_ctrl : std_logic; noe_par : std_logic; noe_ad : std_logic; noe_ctrl : std_logic; bar0 : std_logic_vector(31 downto MADDR_WIDTH); page : std_logic_vector(31 downto MADDR_WIDTH-1); men : std_logic; twist : std_logic; laddr : std_logic_vector(31 downto 0); ldata : std_logic_vector(31 downto 0); lsize : std_logic_vector(2 downto 0); lwrite : std_logic; start : std_logic; rready : std_logic_vector(csync downto 0); wready : std_logic_vector(csync downto 0); sync : std_logic_vector(csync downto 0); end record; type cpu_state_type is (idle, sync1, busy, sync2); type cpu_reg_type is record data : std_logic_vector(31 downto 0); state : cpu_state_type; start : std_logic_vector(csync downto 0); sync : std_logic; rready : std_logic; wready : std_logic; end record; signal clk_int : std_logic; signal pr : pci_input_type; signal r, rin : pci_reg_type; signal r2, r2in : cpu_reg_type; signal dmai : ahb_dma_in_type; signal dmao : ahb_dma_out_type; signal roe_ad, rioe_ad : std_logic_vector(31 downto 0); attribute syn_preserve : boolean; attribute syn_preserve of roe_ad : signal is true; function byte_twist(di : in std_logic_vector(31 downto 0); twist : in std_logic) return std_logic_vector is variable do : std_logic_vector(31 downto 0); begin if twist = '1' then for i in 0 to 3 loop do(31-i8 downto 24-i8) := di(31-(3-i)8 downto 24-(3-i)8); end loop; else do := di; end if; return do; end function; function set_size_from_cbe(cbe : in std_logic_vector(3 downto 0)) return std_logic_vector is variable res : std_logic_vector(1 downto 0); begin case cbe is -- FIXME: this may need to be swaped when "0111" => res := "00"; when "1011" => res := "00"; when "1101" => res := "00"; when "1110" => res := "00"; when "0011" => res := "01"; when "1100" => res := "01"; when others => res := "10"; end case; return res; end function; function set_addr_from_cbe(cbe : in std_logic_vector(3 downto 0); twist: in std_logic) return std_logic_vector is variable res : std_logic_vector(1 downto 0); begin if twist = '1' then -- Little (PCI) to big (AHB) endian case cbe is when "0111" => res := "11"; when "1011" => res := "10"; when "1101" => res := "01"; when "1110" => res := "00"; when "0011" => res := "10"; when "1100" => res := "00"; when others => res := "00"; end case; else -- Big (PCI) to big (AHB) endian case cbe is when "0111" => res := "00"; when "1011" => res := "01"; when "1101" => res := "10"; when "1110" => res := "11"; when "0011" => res := "00"; when "1100" => res := "10"; when others => res := "00"; end case; end if; return res; end function; begin -- Back-end state machine (AHB clock domain) comb : process (rst, r2, r, dmao) variable vdmai : ahb_dma_in_type; variable v : cpu_reg_type; begin v := r2; vdmai.start := '0'; vdmai.burst := '0'; vdmai.size := r.lsize; --"010"; vdmai.address := r.laddr; v.sync := '1'; vdmai.wdata := ahbdrivedata(r.ldata); vdmai.write := r.lwrite; vdmai.irq := '0'; v.start(0) := r2.start(csync); v.start(csync) := r.start; case r2.state is when idle => v.sync := '0'; if r2.start(0) = '1' then if r.lwrite = '1' then v.state := sync1; v.wready := '0'; else v.state := busy; vdmai.start := '1'; end if; end if; when sync1 => if r2.start(0) = '0' then v.state := busy; vdmai.start := '1'; end if; when busy => if dmao.active = '1' then if dmao.ready = '1' then v.rready := not r.lwrite; v.data := dmao.rdata(31 downto 0); v.state := sync2; end if; else vdmai.start := '1'; end if; when sync2 => if r2.start(0) = '0' then v.state := idle; v.wready := '1'; v.rready := '0'; end if; end case; if rst = '0' then v.state := idle; v.rready := '0'; v.wready := '1'; end if; r2in <= v; dmai <= vdmai; end process; -- PCI target core (PCI clock domain) pcicomb : process(pr, pcii, r, r2, roe_ad) variable v : pci_reg_type; variable chit, mhit, hit, ready, cwrite, mwrite : std_logic; variable cdata, cwdata : std_logic_vector(31 downto 0); variable caddr : std_logic_vector(7 downto 2); variable voe_ad : std_logic_vector(31 downto 0); variable oe_ctrl, oe_par, oe_ad : std_ulogic; begin v := r; v.trdy := '1'; v.stop := '1'; voe_ad := roe_ad; v.oe_ad := '1'; v.devsel := '1'; mwrite := '0'; v.rready(0) := r.rready(csync); v.rready(csync) := r2.rready; v.wready(0) := r.wready(csync); v.wready(csync) := r2.wready; v.sync(0) := r.sync(csync); v.sync(csync) := r2.sync; -- address decoding --if (r.state = s_data) and ((pr.irdy or r.trdy or r.read) = '0') then if (r.state = turn_ar) and ((pr.irdy or pr.trdy or r.read) = '0') then cwrite := r.csel; if ((r.msel and r.addr(MADDR_WIDTH-1)) = '1') and (pr.cbe = "0000") then v.page := pr.ad(31 downto MADDR_WIDTH-1); v.twist := pr.ad(0); end if; if (pr.cbe = "0000") and (r.addr(MADDR_WIDTH-1) = '1') then mwrite := r.msel; end if; else cwrite := '0'; end if; cdata := (others => '0'); caddr := r.addr(7 downto 2); case caddr is when "000000" => -- 0x00, device & vendor id cdata := conv_std_logic_vector(DEVICE_ID, 16) & conv_std_logic_vector(VENDOR_ID, 16); when "000001" => -- 0x04, status & command cdata(1) := r.men; cdata(26) := '1'; when "000010" => -- 0x08, class code & revision when "000011" => -- 0x0c, latency & cacheline size when "000100" => -- 0x10, BAR0 cdata(31 downto MADDR_WIDTH) := r.bar0; when others => end case; cwdata := pr.ad; if pr.cbe(3) = '1' then cwdata(31 downto 24) := cdata(31 downto 24); end if; if pr.cbe(2) = '1' then cwdata(23 downto 16) := cdata(23 downto 16); end if; if pr.cbe(1) = '1' then cwdata(15 downto 8) := cdata(15 downto 8); end if; if pr.cbe(0) = '1' then cwdata( 7 downto 0) := cdata( 7 downto 0); end if; if cwrite = '1' then case caddr is when "000001" => -- 0x04, status & command v.men := cwdata(1); when "000100" => -- 0x10, BAR0 v.bar0 := cwdata(31 downto MADDR_WIDTH); when others => end case; end if; if (((pr.cbe = pci_config_read) or (pr.cbe = pci_config_write)) and (pr.ad(1 downto 0) = "00")) then chit := '1'; else chit := '0'; end if; if ((pr.cbe = pci_memory_read) or (pr.cbe = pci_memory_write) or (pr.cbe = pci_memory_read_m) or (pr.cbe = pci_memory_read_l) or (pr.cbe = pci_memory_write_i)) and (r.bar0 = pr.ad(31 downto MADDR_WIDTH)) and (r.bar0 /= zero(31 downto MADDR_WIDTH)) then mhit := '1'; else mhit := '0'; end if; hit := r.csel or r.msel; ready := r.csel or (r.rready(0) and r.read) or (r.wready(0) and not r.read and not r.start) or r.addr(MADDR_WIDTH-1); -- target state machine case r.state is when idle => if pr.frame = '0' then v.state := b_busy; end if; -- !HIT ? v.addr := pr.ad(MADDR_WIDTH-1 downto 0); v.cmd := pr.cbe; v.csel := pr.idsel and chit; v.msel := r.men and mhit; v.read := not pr.cbe(0); if (r.sync(0) and r.start and r.lwrite) = '1' then v.start := '0'; end if; when turn_ar => if pr.frame = '1' then v.state := idle; end if; if pr.frame = '0' then v.state := b_busy; end if; -- !HIT ? v.addr := pr.ad(MADDR_WIDTH-1 downto 0); v.cmd := pr.cbe; v.csel := pr.idsel and chit; v.msel := r.men and mhit; v.read := not pr.cbe(0); if (r.sync(0) and r.start and r.lwrite) = '1' then v.start := '0'; end if; when b_busy => if hit = '1' then v.state := s_data; v.trdy := not ready; v.stop := pr.frame and ready; v.devsel := '0'; else v.state := backoff; end if; when s_data => v.stop := r.stop; v.devsel := '0'; v.trdy := r.trdy or not pcii.irdy; if (pcii.frame and not pcii.irdy) = '1' then v.state := turn_ar; v.stop := '1'; v.trdy := '1'; v.devsel := '1'; end if; when backoff => if pr.frame = '1' then v.state := idle; end if; end case; if ((r.state = s_data) or (r.state = turn_ar)) and (((pr.irdy or pr.trdy) = '0') or ((not pr.irdy and not pr.stop and pr.trdy and not r.start and r.wready(0)) = '1')) then if (pr.trdy and r.read)= '0' then v.start := '0'; end if; if (r.start = '0') and ((r.msel and not r.addr(MADDR_WIDTH-1)) = '1') and (((pr.trdy and r.read and not r.rready(0)) or (not pr.trdy and not r.read)) = '1') then v.laddr := r.page & r.addr(MADDR_WIDTH-2 downto 0); v.ldata := pr.ad; v.lwrite := not r.read; v.start := '1'; -- Added little/big endian support v.laddr := v.laddr(31 downto 2) & set_addr_from_cbe(pr.cbe, r.twist); v.ldata := byte_twist(v.ldata, r.twist); v.lsize := '0' & set_size_from_cbe(pr.cbe); end if; end if; if (v.state = s_data) and (r.read = '1') then v.oe_ad := '0'; end if; v.oe_par := r.oe_ad; if r.csel = '1' then v.data := cdata; elsif r.addr(MADDR_WIDTH-1) = '1' then v.data(31 downto MADDR_WIDTH-1) := r.page; v.data(MADDR_WIDTH-2 downto 0) := (others => '0'); v.data(0) := r.twist; -- Addded little/bit endian support --else v.data := r2.data; end if; else v.data := byte_twist(r2.data, r.twist); end if; v.par := xorv(r.data & pcii.cbe); if (v.state = s_data) or (r.state = s_data) then v.oe_ctrl := '0'; else v.oe_ctrl := '1'; end if; v.noe_ctrl := not v.oe_ctrl; v.noe_ad := not v.oe_ad; v.noe_par := not v.oe_par; if oepol = 1 then oe_ctrl := r.noe_ctrl; oe_ad := r.noe_ad; oe_par := r.noe_par; voe_ad := (others => v.noe_ad); else oe_ctrl := r.oe_ctrl; oe_ad := r.oe_ad; oe_par := r.oe_par; voe_ad := (others => v.oe_ad); end if; if pr.rst = '0' then v.state := idle; v.men := '0'; v.start := '0'; v.bar0 := (others => '0'); v.msel := '0'; v.csel := '0'; v.page := (others => '0'); v.page(31 downto 30) := "01"; v.twist := '0'; end if; rin <= v; rioe_ad <= voe_ad; pcio.ctrlen <= oe_ctrl; pcio.trdy <= r.trdy; pcio.trdyen <= oe_ctrl; pcio.stop <= r.stop; pcio.stopen <= oe_ctrl; pcio.devsel <= r.devsel; pcio.devselen <= oe_ctrl; pcio.par <= r.par; pcio.paren <= oe_par; pcio.aden <= oe_ad; pcio.ad <= r.data; pcio.rst <= '1'; end process; pcir : process (pciclk, pcii.rst, r2) begin if rising_edge (pciclk) then pr.ad <= to_x01(pcii.ad); pr.cbe <= to_x01(pcii.cbe); pr.devsel <= to_x01(pcii.devsel); pr.frame <= to_x01(pcii.frame); pr.idsel <= to_x01(pcii.idsel); pr.irdy <= to_x01(pcii.irdy); pr.trdy <= to_x01(pcii.trdy); pr.par <= to_x01(pcii.par); pr.stop <= to_x01(pcii.stop); pr.rst <= to_x01(pcii.rst); r <= rin; roe_ad <= rioe_ad; end if; if pcii.rst = '0' then -- asynch reset required r.oe_ctrl <= '1'; r.oe_par <= '1'; r.oe_ad <= '1'; r.noe_ctrl <= '0'; r.noe_par <= '0'; r.noe_ad <= '0'; if oepol = 0 then roe_ad <= (others => '1'); else roe_ad <= (others => '0'); end if; end if; end process; cpur : process (clk) begin if rising_edge (clk) then r2 <= r2in; end if; end process; oe0 : if oepol = 0 generate pcio.perren <= '1'; pcio.cbeen <= (others => '1'); pcio.serren <= '1'; pcio.inten <= '1'; pcio.vinten <= (others => '1'); pcio.reqen <= not pcii.rst; pcio.frameen <= '1'; pcio.irdyen <= '1'; pcio.locken <= '1'; end generate; oe1 : if oepol = 1 generate pcio.perren <= '0'; pcio.cbeen <= (others => '0'); pcio.serren <= '0'; pcio.inten <= '0'; pcio.vinten <= (others => '0'); pcio.reqen <= pcii.rst; pcio.frameen <= '0'; pcio.irdyen <= '0'; pcio.locken <= '0'; end generate; pcio.vaden <= roe_ad; pcio.cbe <= "1111"; pcio.perr <= '1'; pcio.serr <= '1'; pcio.int <= '1'; pcio.req <= '1'; pcio.frame <= '1'; pcio.irdy <= '1'; ahbmst0 : ahbmst generic map (hindex => hindex, devid => GAISLER_PCITRG) port map (rst, clk, dmai, dmao, ahbmi, ahbmo); -- pragma translate_off bootmsg : report_version generic map ("pci_target" & tost(hindex) & ": 32-bit PCI Target rev " & tost(REVISION) & ", " & tost(abits) & "-bit PCI memory BAR" ); -- pragma translate_on end;	gpl-2.0	1e9fbc3cc3e9c22dfa07ce2221726183	0.55179	2.974135	false	false	false	false
mistryalok/Zedboard	learning/training/MSD/s05/project_1/project_1.srcs/sources_1/ipshared/xilinx.com/axi_cdma_v4_1/25515467/hdl/src/vhdl/axi_cdma_lite_if.vhd	1	61,561	------------------------------------------------------------------------------- -- axi_cdma_lite_if ------------------------------------------------------------------------------- -- -- *********************************************************************** -- -- (c) Copyright 2010, 2011 Xilinx, Inc. All rights reserved. -- -- This file contains confidential and proprietary information -- of Xilinx, Inc. and is protected under U.S. and -- international copyright and other intellectual property -- laws. -- -- DISCLAIMER -- This disclaimer is not a license and does not grant any -- rights to the materials distributed herewith. Except as -- otherwise provided in a valid license issued to you by -- Xilinx, and to the maximum extent permitted by applicable -- law: (1) THESE MATERIALS ARE MADE AVAILABLE "AS IS" AND -- WITH ALL FAULTS, AND XILINX HEREBY DISCLAIMS ALL WARRANTIES -- AND CONDITIONS, EXPRESS, IMPLIED, OR STATUTORY, INCLUDING -- BUT NOT LIMITED TO WARRANTIES OF MERCHANTABILITY, NON- -- INFRINGEMENT, OR FITNESS FOR ANY PARTICULAR PURPOSE; and -- (2) Xilinx shall not be liable (whether in contract or tort, -- including negligence, or under any other theory of -- liability) for any loss or damage of any kind or nature -- related to, arising under or in connection with these -- materials, including for any direct, or any indirect, -- special, incidental, or consequential loss or damage -- (including loss of data, profits, goodwill, or any type of -- loss or damage suffered as a result of any action brought -- by a third party) even if such damage or loss was -- reasonably foreseeable or Xilinx had been advised of the -- possibility of the same. -- -- CRITICAL APPLICATIONS -- Xilinx products are not designed or intended to be fail- -- safe, or for use in any application requiring fail-safe -- performance, such as life-support or safety devices or -- systems, Class III medical devices, nuclear facilities, -- applications related to the deployment of airbags, or any -- other applications that could lead to death, personal -- injury, or severe property or environmental damage -- (individually and collectively, "Critical -- Applications"). Customer assumes the sole risk and -- liability of any use of Xilinx products in Critical -- Applications, subject only to applicable laws and -- regulations governing limitations on product liability. -- -- THIS COPYRIGHT NOTICE AND DISCLAIMER MUST BE RETAINED AS -- PART OF THIS FILE AT ALL TIMES. -- -- ********************************************************************* -- ------------------------------------------------------------------------------- -- Filename: axi_cdma_lite_if.vhd -- Description: This entity is AXI Lite Interface Module for the AXI DMA -- -- VHDL-Standard: VHDL'93 ------------------------------------------------------------------------------- ------------------------------------------------------------------------------- library ieee; use ieee.std_logic_1164.all; use ieee.numeric_std.all; use ieee.std_logic_misc.all; library unisim; use unisim.vcomponents.all; library axi_cdma_v4_1; use axi_cdma_v4_1.axi_cdma_pkg.all; library lib_pkg_v1_0; use lib_pkg_v1_0.lib_pkg.clog2; library lib_cdc_v1_0; ------------------------------------------------------------------------------- entity axi_cdma_lite_if is generic( C_NUM_CE : integer := 8 ; C_AXI_LITE_IS_ASYNC : integer range 0 to 1 := 0 ; C_S_AXI_LITE_ADDR_WIDTH : integer range 2 to 32 := 32 ; C_S_AXI_LITE_DATA_WIDTH : integer range 32 to 32 := 32 ); port ( -- Async clock input ip2axi_aclk : in std_logic ; -- ip2axi_aresetn : in std_logic ; -- ----------------------------------------------------------------------- -- AXI Lite Control Interface ----------------------------------------------------------------------- s_axi_lite_aclk : in std_logic ; -- s_axi_lite_aresetn : in std_logic ; -- -- -- AXI Lite Write Address Channel -- s_axi_lite_awvalid : in std_logic ; -- s_axi_lite_awready : out std_logic ; -- s_axi_lite_awaddr : in std_logic_vector -- (C_S_AXI_LITE_ADDR_WIDTH-1 downto 0); -- -- -- AXI Lite Write Data Channel -- s_axi_lite_wvalid : in std_logic ; -- s_axi_lite_wready : out std_logic ; -- s_axi_lite_wdata : in std_logic_vector -- (C_S_AXI_LITE_DATA_WIDTH-1 downto 0); -- -- -- AXI Lite Write Response Channel -- s_axi_lite_bresp : out std_logic_vector(1 downto 0) ; -- s_axi_lite_bvalid : out std_logic ; -- s_axi_lite_bready : in std_logic ; -- -- -- AXI Lite Read Address Channel -- s_axi_lite_arvalid : in std_logic ; -- s_axi_lite_arready : out std_logic ; -- s_axi_lite_araddr : in std_logic_vector -- (C_S_AXI_LITE_ADDR_WIDTH-1 downto 0); -- s_axi_lite_rvalid : out std_logic ; -- s_axi_lite_rready : in std_logic ; -- s_axi_lite_rdata : out std_logic_vector -- (C_S_AXI_LITE_DATA_WIDTH-1 downto 0); -- s_axi_lite_rresp : out std_logic_vector(1 downto 0) ; -- -- -- User IP Interface -- axi2ip_wrce : out std_logic_vector -- (C_NUM_CE-1 downto 0) ; -- axi2ip_wrdata : out std_logic_vector -- (C_S_AXI_LITE_DATA_WIDTH-1 downto 0); -- -- axi2ip_rdce : out std_logic_vector -- (C_NUM_CE-1 downto 0) ; -- axi2ip_rdaddr : out std_logic_vector -- (C_S_AXI_LITE_ADDR_WIDTH-1 downto 0); -- ip2axi_rddata : in std_logic_vector -- (C_S_AXI_LITE_DATA_WIDTH-1 downto 0) -- ); end axi_cdma_lite_if; ------------------------------------------------------------------------------- -- Architecture ------------------------------------------------------------------------------- architecture implementation of axi_cdma_lite_if is attribute DowngradeIPIdentifiedWarnings: string; attribute DowngradeIPIdentifiedWarnings of implementation : architecture is "yes"; ------------------------------------------------------------------------------- -- Functions ------------------------------------------------------------------------------- -- No Functions Declared ------------------------------------------------------------------------------- -- Constants Declarations ------------------------------------------------------------------------------- -- Register I/F Address offset constant ADDR_OFFSET : integer := clog2(C_S_AXI_LITE_DATA_WIDTH/8); -- Register I/F CE number constant CE_ADDR_SIZE : integer := clog2(C_NUM_CE); ------------------------------------------------------------------------------- -- Signal / Type Declarations ------------------------------------------------------------------------------- -- AXI Lite slave interface signals signal awvalid : std_logic := '0'; signal awaddr : std_logic_vector (C_S_AXI_LITE_ADDR_WIDTH-1 downto 0) := (others => '0'); signal wvalid : std_logic := '0'; signal wdata : std_logic_vector (C_S_AXI_LITE_DATA_WIDTH-1 downto 0) := (others => '0'); signal arvalid : std_logic := '0'; signal araddr : std_logic_vector (C_S_AXI_LITE_ADDR_WIDTH-1 downto 0) := (others => '0'); signal awvalid_d1 : std_logic := '0'; signal awvalid_re : std_logic := '0'; signal awready_i : std_logic := '0'; signal wvalid_d1 : std_logic := '0'; signal wvalid_re : std_logic := '0'; signal wready_i : std_logic := '0'; signal bvalid_i : std_logic := '0'; signal wr_addr_cap : std_logic := '0'; signal wr_data_cap : std_logic := '0'; -- AXI to IP interface signals signal axi2ip_wraddr_i : std_logic_vector (C_S_AXI_LITE_ADDR_WIDTH-1 downto 0) := (others => '0'); signal axi2ip_wrdata_i : std_logic_vector (C_S_AXI_LITE_DATA_WIDTH-1 downto 0) := (others => '0'); signal axi2ip_wren : std_logic := '0'; signal wrce : std_logic_vector(C_NUM_CE-1 downto 0); signal rdce : std_logic_vector(C_NUM_CE-1 downto 0) := (others => '0'); signal arvalid_d1 : std_logic := '0'; signal arvalid_re : std_logic := '0'; signal arvalid_re_d1 : std_logic := '0'; signal arvalid_i : std_logic := '0'; signal arready_i : std_logic := '0'; signal rvalid : std_logic := '0'; signal axi2ip_rdaddr_i : std_logic_vector (C_S_AXI_LITE_ADDR_WIDTH-1 downto 0) := (others => '0'); signal s_axi_lite_rvalid_i : std_logic := '0'; signal read_in_progress : std_logic := '0'; -- CR607165 signal rst_rvalid_re : std_logic := '0'; -- CR576999 signal rst_wvalid_re : std_logic := '0'; -- CR576999 signal rdy : std_logic := '0'; signal rdy1 : std_logic := '0'; signal wr_in_progress : std_logic := '0'; ------------------------------------------------------------------------------- -- Begin architecture logic ------------------------------------------------------------------------------- begin --************************************************************************* -- AXI LITE READ --*************************************************************************** s_axi_lite_wready <= wready_i; s_axi_lite_awready <= awready_i; s_axi_lite_arready <= arready_i; s_axi_lite_bvalid <= bvalid_i; ------------------------------------------------------------------------------- -- Register AXI Inputs ------------------------------------------------------------------------------- REG_INPUTS : process(s_axi_lite_aclk) begin if(s_axi_lite_aclk'EVENT and s_axi_lite_aclk = '1')then if(s_axi_lite_aresetn = '0')then awvalid <= '0' ; awaddr <= (others => '0') ; wvalid <= '0' ; wdata <= (others => '0') ; arvalid <= '0' ; araddr <= (others => '0') ; else awvalid <= s_axi_lite_awvalid ; awaddr <= s_axi_lite_awaddr ; wvalid <= s_axi_lite_wvalid ; wdata <= s_axi_lite_wdata ; arvalid <= s_axi_lite_arvalid ; araddr <= s_axi_lite_araddr ; end if; end if; end process REG_INPUTS; -- s_axi_lite_aclk is synchronous to ip clock GEN_SYNC_WRITE : if C_AXI_LITE_IS_ASYNC = 0 generate begin ------------------------------------------------------------------------------- -- Assert Write Adddress Ready Handshake -- Capture rising edge of valid and register out as ready. This creates -- a 3 clock cycle address phase but also registers all inputs and outputs. -- Note : Single clock cycle address phase can be accomplished using -- combinatorial logic. ------------------------------------------------------------------------------- REG_AWVALID : process(s_axi_lite_aclk) begin if(s_axi_lite_aclk'EVENT and s_axi_lite_aclk = '1')then if(s_axi_lite_aresetn = '0' or rst_wvalid_re = '1')then awvalid_d1 <= '0'; -- awvalid_re <= '0'; -- CR605883 else awvalid_d1 <= awvalid; -- awvalid_re <= awvalid and not awvalid_d1; -- CR605883 end if; end if; end process REG_AWVALID; awvalid_re <= awvalid and not awvalid_d1 and (not (wr_in_progress)); -- CR605883 ------------------------------------------------------------------------------- -- Capture assertion of awvalid to indicate that we have captured -- a valid address ------------------------------------------------------------------------------- ------------------------------------------------------------------------------- -- Assert Write Data Ready Handshake -- Capture rising edge of valid and register out as ready. This creates -- a 3 clock cycle address phase but also registers all inputs and outputs. -- Note : Single clock cycle address phase can be accomplished using -- combinatorial logic. ------------------------------------------------------------------------------- REG_WVALID : process(s_axi_lite_aclk) begin if(s_axi_lite_aclk'EVENT and s_axi_lite_aclk = '1')then if(s_axi_lite_aresetn = '0' or rst_wvalid_re = '1')then wvalid_d1 <= '0'; -- wvalid_re <= '0'; else wvalid_d1 <= wvalid; -- wvalid_re <= wvalid and not wvalid_d1; -- CR605883 end if; end if; end process REG_WVALID; wvalid_re <= wvalid and not wvalid_d1; -- CR605883 WRITE_IN_PROGRESS : process(s_axi_lite_aclk) begin if(s_axi_lite_aclk'EVENT and s_axi_lite_aclk = '1')then if(s_axi_lite_aresetn = '0' or rst_wvalid_re = '1')then wr_in_progress <= '0'; elsif(awvalid_re = '1')then wr_in_progress <= '1'; end if; end if; end process WRITE_IN_PROGRESS; -- CR605883 (CDC) provide pure register output to synchronizers --wvalid_re <= wvalid and not wvalid_d1 and not rst_wvalid_re; ------------------------------------------------------------------------------- -- Capture assertion of wvalid to indicate that we have captured -- valid data ------------------------------------------------------------------------------- WRDATA_CAP_FLAG : process(s_axi_lite_aclk) begin if(s_axi_lite_aclk'EVENT and s_axi_lite_aclk = '1')then if(s_axi_lite_aresetn = '0' or rdy = '1')then wr_data_cap <= '0'; elsif(wvalid_re = '1')then wr_data_cap <= '1'; end if; end if; end process WRDATA_CAP_FLAG; REG_WREADY : process(s_axi_lite_aclk) begin if(s_axi_lite_aclk'EVENT and s_axi_lite_aclk = '1')then if(s_axi_lite_aresetn = '0' or rdy = '1') then rdy <= '0'; elsif (wr_data_cap = '1' and wr_addr_cap = '1') then rdy <= '1'; end if; wready_i <= rdy; awready_i <= rdy; rdy1 <= rdy; end if; end process REG_WREADY; WRADDR_CAP_FLAG : process(s_axi_lite_aclk) begin if(s_axi_lite_aclk'EVENT and s_axi_lite_aclk = '1')then if(s_axi_lite_aresetn = '0' or rdy = '1')then wr_addr_cap <= '0'; elsif(awvalid_re = '1')then wr_addr_cap <= '1'; end if; end if; end process WRADDR_CAP_FLAG; ------------------------------------------------------------------------------- -- Capture Write Address ------------------------------------------------------------------------------- REG_WRITE_ADDRESS : process(s_axi_lite_aclk) begin if(s_axi_lite_aclk'EVENT and s_axi_lite_aclk = '1')then if(s_axi_lite_aresetn = '0')then -- axi2ip_wraddr_i <= (others => '0'); -- Register address on valid elsif(awvalid_re = '1')then -- axi2ip_wraddr_i <= awaddr; end if; end if; end process REG_WRITE_ADDRESS; ------------------------------------------------------------------------------- -- Capture Write Data ------------------------------------------------------------------------------- REG_WRITE_DATA : process(s_axi_lite_aclk) begin if(s_axi_lite_aclk'EVENT and s_axi_lite_aclk = '1')then if(s_axi_lite_aresetn = '0')then axi2ip_wrdata_i <= (others => '0'); -- Register address and assert ready elsif(wvalid_re = '1')then axi2ip_wrdata_i <= wdata; end if; end if; end process REG_WRITE_DATA; ------------------------------------------------------------------------------- -- Must have both a valid address and valid data before updating -- a register. Note in AXI write address can come before or -- after AXI write data. -- axi2ip_wren <= '1' when wr_data_cap = '1' and wr_addr_cap = '1' -- else '0'; axi2ip_wren <= rdy; -- or rdy1; ------------------------------------------------------------------------------- -- Decode and assert proper chip enable per captured axi lite write address ------------------------------------------------------------------------------- WRCE_GEN: for j in 0 to C_NUM_CE - 1 generate constant BAR : std_logic_vector(CE_ADDR_SIZE-1 downto 0) := std_logic_vector(to_unsigned(j,CE_ADDR_SIZE)); begin wrce(j) <= axi2ip_wren when s_axi_lite_awaddr ((CE_ADDR_SIZE + ADDR_OFFSET) - 1 downto ADDR_OFFSET) = BAR(CE_ADDR_SIZE-1 downto 0) else '0'; end generate WRCE_GEN; ------------------------------------------------------------------------------- -- register write ce's and data out to axi dma register module ------------------------------------------------------------------------------- REG_WR_OUT : process(s_axi_lite_aclk) begin if(s_axi_lite_aclk'EVENT and s_axi_lite_aclk = '1')then if(s_axi_lite_aresetn = '0')then axi2ip_wrce <= (others => '0'); -- axi2ip_wrdata <= (others => '0'); else axi2ip_wrce <= wrce; -- axi2ip_wrdata <= axi2ip_wrdata_i; end if; end if; end process REG_WR_OUT; axi2ip_wrdata <= s_axi_lite_wdata; ------------------------------------------------------------------------------- -- Write Response ------------------------------------------------------------------------------- s_axi_lite_bresp <= OKAY_RESP; WRESP_PROCESS : process(s_axi_lite_aclk) begin if(s_axi_lite_aclk'EVENT and s_axi_lite_aclk = '1')then if(s_axi_lite_aresetn = '0')then bvalid_i <= '0'; rst_wvalid_re <= '0'; -- CR576999 -- If response issued and target indicates ready then -- clear response elsif(bvalid_i = '1' and s_axi_lite_bready = '1')then bvalid_i <= '0'; rst_wvalid_re <= '0'; -- CR576999 -- Issue a resonse on write elsif(rdy1 = '1')then bvalid_i <= '1'; rst_wvalid_re <= '1'; -- CR576999 end if; end if; end process WRESP_PROCESS; end generate GEN_SYNC_WRITE; -- s_axi_lite_aclk is asynchronous to ip clock GEN_ASYNC_WRITE : if C_AXI_LITE_IS_ASYNC = 1 generate -- Data support ----------------------------------------------------------------------------- -- ATTRIBUTE Declarations ----------------------------------------------------------------------------- -- Prevent x-propagation on clock-domain crossing register ATTRIBUTE async_reg : STRING; Attribute KEEP : string; -- declaration Attribute EQUIVALENT_REGISTER_REMOVAL : string; -- declaration signal ip_wvalid_d1_cdc_to : std_logic := '0'; signal ip_wvalid_d2 : std_logic := '0'; signal ip_wvalid_re : std_logic := '0'; signal wr_wvalid_re_cdc_from : std_logic := '0'; signal wr_data_cdc_from : std_logic_vector -- CR605883 (C_S_AXI_LITE_DATA_WIDTH-1 downto 0) := (others => '0'); -- CR605883 signal wdata_d1_cdc_to : std_logic_vector (C_S_AXI_LITE_DATA_WIDTH-1 downto 0) := (others => '0'); signal wdata_d2 : std_logic_vector (C_S_AXI_LITE_DATA_WIDTH-1 downto 0) := (others => '0'); signal axi2ip_wrdata_cdc_tig : std_logic_vector (C_S_AXI_LITE_DATA_WIDTH-1 downto 0) := (others => '0'); signal ip_data_cap : std_logic := '0'; -- Address support signal ip_awvalid_d1_cdc_to : std_logic := '0'; signal ip_awvalid_d2 : std_logic := '0'; signal ip_awvalid_re : std_logic := '0'; signal wr_awvalid_re_cdc_from : std_logic := '0'; signal wr_addr_cdc_from : std_logic_vector -- CR605883 (C_S_AXI_LITE_ADDR_WIDTH-1 downto 0) := (others => '0'); -- CR605883 signal awaddr_d1_cdc_tig : std_logic_vector (C_S_AXI_LITE_ADDR_WIDTH-1 downto 0) := (others => '0'); signal awaddr_d2 : std_logic_vector (C_S_AXI_LITE_ADDR_WIDTH-1 downto 0) := (others => '0'); signal ip_addr_cap : std_logic := '0'; -- Bvalid support signal lite_data_cap_d1 : std_logic := '0'; signal lite_data_cap_d2 : std_logic := '0'; signal lite_addr_cap_d1 : std_logic := '0'; signal lite_addr_cap_d2 : std_logic := '0'; signal lite_axi2ip_wren : std_logic := '0'; signal awvalid_cdc_from : std_logic := '0'; signal awvalid_cdc_to : std_logic := '0'; signal awvalid_to : std_logic := '0'; signal awvalid_to2 : std_logic := '0'; -- ATTRIBUTE async_reg OF awvalid_cdc_to : SIGNAL IS "true"; -- ATTRIBUTE async_reg OF awvalid_to : SIGNAL IS "true"; signal wvalid_cdc_from : std_logic := '0'; signal wvalid_cdc_to : std_logic := '0'; signal wvalid_to : std_logic := '0'; signal wvalid_to2 : std_logic := '0'; -- ATTRIBUTE async_reg OF wvalid_cdc_to : SIGNAL IS "true"; -- ATTRIBUTE async_reg OF wvalid_to : SIGNAL IS "true"; signal rdy_cdc_to : std_logic := '0'; signal rdy_cdc_from : std_logic := '0'; signal rdy_to : std_logic := '0'; signal rdy_to2 : std_logic := '0'; signal rdy_to2_cdc_from : std_logic := '0'; signal rdy_out : std_logic := '0'; -- ATTRIBUTE async_reg OF rdy_cdc_to : SIGNAL IS "true"; -- ATTRIBUTE async_reg OF rdy_to : SIGNAL IS "true"; Attribute KEEP of rdy_to2_cdc_from : signal is "TRUE"; Attribute EQUIVALENT_REGISTER_REMOVAL of rdy_to2_cdc_from : signal is "no"; signal rdy_back_cdc_to : std_logic := '0'; signal rdy_back_to : std_logic :='0'; -- ATTRIBUTE async_reg OF rdy_back_cdc_to : SIGNAL IS "true"; -- ATTRIBUTE async_reg OF rdy_back_to : SIGNAL IS "true"; signal rdy_back : std_logic := '0'; signal rdy_shut : std_logic := '0'; begin REG_AWVALID : process(s_axi_lite_aclk) begin if(s_axi_lite_aclk'EVENT and s_axi_lite_aclk = '1')then if(s_axi_lite_aresetn = '0' or rst_wvalid_re = '1')then awvalid_d1 <= '0'; else awvalid_d1 <= awvalid; end if; end if; end process REG_AWVALID; awvalid_re <= awvalid and not awvalid_d1 and (not (wr_in_progress)); -- CR605883 ------------------------------------------------------------------------------- -- Capture assertion of awvalid to indicate that we have captured -- a valid address ------------------------------------------------------------------------------- ------------------------------------------------------------------------------- -- Assert Write Data Ready Handshake -- Capture rising edge of valid and register out as ready. This creates -- a 3 clock cycle address phase but also registers all inputs and outputs. -- Note : Single clock cycle address phase can be accomplished using -- combinatorial logic. ------------------------------------------------------------------------------- REG_WVALID : process(s_axi_lite_aclk) begin if(s_axi_lite_aclk'EVENT and s_axi_lite_aclk = '1')then if(s_axi_lite_aresetn = '0' or rst_wvalid_re = '1')then wvalid_d1 <= '0'; else wvalid_d1 <= wvalid; end if; end if; end process REG_WVALID; wvalid_re <= wvalid and not wvalid_d1; -- CR605883 --********************************************************************* -- Write Address Support --*********************************************************************** AWVLD_CDC_FROM : process(s_axi_lite_aclk) begin if(s_axi_lite_aclk'EVENT and s_axi_lite_aclk = '1')then if(s_axi_lite_aresetn = '0' or rst_wvalid_re = '1')then awvalid_cdc_from <= '0'; elsif(awvalid_re = '1')then awvalid_cdc_from <= '1'; end if; end if; end process AWVLD_CDC_FROM; AWVLD_CDC_TO : entity lib_cdc_v1_0.cdc_sync generic map ( C_CDC_TYPE => 1, C_RESET_STATE => 0, C_SINGLE_BIT => 1, C_VECTOR_WIDTH => 32, C_MTBF_STAGES => MTBF_STAGES ) port map ( prmry_aclk => s_axi_lite_aclk, prmry_resetn => '0', prmry_in => awvalid_cdc_from, prmry_vect_in => (others => '0'), scndry_aclk => ip2axi_aclk, scndry_resetn => '0', scndry_out => awvalid_to, scndry_vect_out => open ); -- AWVLD_CDC_TO : process(ip2axi_aclk) -- begin -- if(ip2axi_aclk'EVENT and ip2axi_aclk = '1')then -- awvalid_cdc_to <= awvalid_cdc_from; -- awvalid_to <= awvalid_cdc_to; -- end if; -- end process AWVLD_CDC_TO; AWVLD_CDC_TO2 : process(ip2axi_aclk) begin if(ip2axi_aclk'EVENT and ip2axi_aclk = '1')then if(ip2axi_aresetn = '0')then awvalid_to2 <= '0'; else awvalid_to2 <= awvalid_to; end if; end if; end process AWVLD_CDC_TO2; ip_awvalid_re <= awvalid_to and (not awvalid_to2); WVLD_CDC_FROM : process(s_axi_lite_aclk) begin if(s_axi_lite_aclk'EVENT and s_axi_lite_aclk = '1')then if(s_axi_lite_aresetn = '0' or rst_wvalid_re = '1')then wvalid_cdc_from <= '0'; elsif(wvalid_re = '1')then wvalid_cdc_from <= '1'; end if; end if; end process WVLD_CDC_FROM; WVLD_CDC_TO : entity lib_cdc_v1_0.cdc_sync generic map ( C_CDC_TYPE => 1, C_RESET_STATE => 0, C_SINGLE_BIT => 1, C_VECTOR_WIDTH => 32, C_MTBF_STAGES => MTBF_STAGES ) port map ( prmry_aclk => s_axi_lite_aclk, prmry_resetn => '0', prmry_in => wvalid_cdc_from, prmry_vect_in => (others => '0'), scndry_aclk => ip2axi_aclk, scndry_resetn => '0', scndry_out => wvalid_to, scndry_vect_out => open ); -- WVLD_CDC_TO : process(ip2axi_aclk) -- begin -- if(ip2axi_aclk'EVENT and ip2axi_aclk = '1')then -- wvalid_cdc_to <= wvalid_cdc_from; -- wvalid_to <= wvalid_cdc_to; -- end if; -- end process WVLD_CDC_TO; WVLD_CDC_TO2 : process(ip2axi_aclk) begin if(ip2axi_aclk'EVENT and ip2axi_aclk = '1')then if(ip2axi_aresetn = '0')then wvalid_to2 <= '0'; else wvalid_to2 <= wvalid_to; end if; end if; end process WVLD_CDC_TO2; ip_wvalid_re <= wvalid_to and (not wvalid_to2); REG_WADDR_TO_IPCLK : entity lib_cdc_v1_0.cdc_sync generic map ( C_CDC_TYPE => 1, C_RESET_STATE => 0, C_SINGLE_BIT => 0, C_VECTOR_WIDTH => C_S_AXI_LITE_ADDR_WIDTH, C_MTBF_STAGES => 1 ) port map ( prmry_aclk => s_axi_lite_aclk, prmry_resetn => '0', prmry_in => '0', prmry_vect_in => s_axi_lite_awaddr, scndry_aclk => ip2axi_aclk, scndry_resetn => '0', scndry_out => open, scndry_vect_out => awaddr_d1_cdc_tig ); REG_WADDR_TO_IPCLK1 : entity lib_cdc_v1_0.cdc_sync generic map ( C_CDC_TYPE => 1, C_RESET_STATE => 0, C_SINGLE_BIT => 0, C_VECTOR_WIDTH => C_S_AXI_LITE_DATA_WIDTH, C_MTBF_STAGES => 1 ) port map ( prmry_aclk => s_axi_lite_aclk, prmry_resetn => '0', prmry_in => '0', prmry_vect_in => s_axi_lite_wdata, scndry_aclk => ip2axi_aclk, scndry_resetn => '0', scndry_out => open, scndry_vect_out => axi2ip_wrdata_cdc_tig ); -- Double register address in -- REG_WADDR_TO_IPCLK : process(ip2axi_aclk) -- begin -- if(ip2axi_aclk'EVENT and ip2axi_aclk = '1')then -- if(ip2axi_aresetn = '0')then -- awaddr_d1_cdc_tig <= (others => '0'); -- -- axi2ip_wraddr_i <= (others => '0'); -- axi2ip_wrdata_cdc_tig <= (others => '0'); -- else -- awaddr_d1_cdc_tig <= s_axi_lite_awaddr; -- axi2ip_wrdata_cdc_tig <= s_axi_lite_wdata; -- -- axi2ip_wraddr_i <= awaddr_d1_cdc_tig; -- CR605883 -- end if; -- end if; -- end process REG_WADDR_TO_IPCLK; -- Flag that address has been captured REG_IP_ADDR_CAP : process(ip2axi_aclk) begin if(ip2axi_aclk'EVENT and ip2axi_aclk = '1')then if(ip2axi_aresetn = '0' or rdy_shut = '1')then ip_addr_cap <= '0'; elsif(ip_awvalid_re = '1')then ip_addr_cap <= '1'; end if; end if; end process REG_IP_ADDR_CAP; REG_WREADY : process(ip2axi_aclk) begin if(ip2axi_aclk'EVENT and ip2axi_aclk = '1')then if(ip2axi_aresetn = '0' or rdy_shut = '1') then -- or rdy = '1') then rdy <= '0'; elsif (ip_data_cap = '1' and ip_addr_cap = '1') then rdy <= '1'; end if; end if; end process REG_WREADY; REG3_WREADY : entity lib_cdc_v1_0.cdc_sync generic map ( C_CDC_TYPE => 1, C_RESET_STATE => 0, C_SINGLE_BIT => 1, C_VECTOR_WIDTH => 32, C_MTBF_STAGES => MTBF_STAGES ) port map ( prmry_aclk => s_axi_lite_aclk, prmry_resetn => '0', prmry_in => rdy_to2_cdc_from, prmry_vect_in => (others => '0'), scndry_aclk => ip2axi_aclk, scndry_resetn => '0', scndry_out => rdy_back_to, scndry_vect_out => open ); -- REG3_WREADY : process(ip2axi_aclk) -- begin -- if(ip2axi_aclk'EVENT and ip2axi_aclk = '1')then -- rdy_back_cdc_to <= rdy_to2_cdc_from; -- rdy_back_to <= rdy_back_cdc_to; -- end if; -- end process REG3_WREADY; REG3_WREADY2 : process(ip2axi_aclk) begin if(ip2axi_aclk'EVENT and ip2axi_aclk = '1')then if(ip2axi_aresetn = '0') then rdy_back <= '0'; else rdy_back <= rdy_back_to; end if; end if; end process REG3_WREADY2; rdy_shut <= rdy_back_to and (not rdy_back); REG1_WREADY : process(ip2axi_aclk) begin if(ip2axi_aclk'EVENT and ip2axi_aclk = '1')then if(ip2axi_aresetn = '0' or rdy_shut = '1') then rdy_cdc_from <= '0'; elsif (rdy = '1') then rdy_cdc_from <= '1'; end if; end if; end process REG1_WREADY; REG2_WREADY : entity lib_cdc_v1_0.cdc_sync generic map ( C_CDC_TYPE => 1, C_RESET_STATE => 0, C_SINGLE_BIT => 1, C_VECTOR_WIDTH => 32, C_MTBF_STAGES => MTBF_STAGES ) port map ( prmry_aclk => ip2axi_aclk, prmry_resetn => '0', prmry_in => rdy_cdc_from, prmry_vect_in => (others => '0'), scndry_aclk => s_axi_lite_aclk, scndry_resetn => '0', scndry_out => rdy_to, scndry_vect_out => open ); -- REG2_WREADY : process(s_axi_lite_aclk) -- begin -- if(s_axi_lite_aclk'EVENT and s_axi_lite_aclk = '1')then -- rdy_cdc_to <= rdy_cdc_from; -- rdy_to <= rdy_cdc_to; -- end if; -- end process REG2_WREADY; REG2_WREADY2 : process(s_axi_lite_aclk) begin if(s_axi_lite_aclk'EVENT and s_axi_lite_aclk = '1')then if(s_axi_lite_aresetn = '0') then rdy_to2 <= '0'; rdy_to2_cdc_from <= '0'; else rdy_to2 <= rdy_to; rdy_to2_cdc_from <= rdy_to; end if; end if; end process REG2_WREADY2; rdy_out <= not (rdy_to) and rdy_to2; wready_i <= rdy_out; awready_i <= rdy_out; --********************************************************************* -- Write Data Support --*********************************************************************** ------------------------------------------------------------------------------- -- Capture write data ------------------------------------------------------------------------------- -- WRDATA_S_H : process(s_axi_lite_aclk) -- begin -- if(s_axi_lite_aclk'EVENT and s_axi_lite_aclk = '1')then -- if(s_axi_lite_aresetn = '0')then -- wr_data_cdc_from <= (others => '0'); -- elsif(wvalid_re = '1')then -- wr_data_cdc_from <= wdata; -- end if; -- end if; -- end process WRDATA_S_H; -- Flag that data has been captured REG_IP_DATA_CAP : process(ip2axi_aclk) begin if(ip2axi_aclk'EVENT and ip2axi_aclk = '1')then if(ip2axi_aresetn = '0' or rdy_shut = '1')then ip_data_cap <= '0'; elsif(ip_wvalid_re = '1')then ip_data_cap <= '1'; end if; end if; end process REG_IP_DATA_CAP; -- Must have both a valid address and valid data before updating -- a register. Note in AXI write address can come before or -- after AXI write data. axi2ip_wren <= rdy; -- axi2ip_wren <= '1' when ip_data_cap = '1' and ip_addr_cap = '1' -- else '0'; ------------------------------------------------------------------------------- -- Decode and assert proper chip enable per captured axi lite write address ------------------------------------------------------------------------------- WRCE_GEN: for j in 0 to C_NUM_CE - 1 generate constant BAR : std_logic_vector(CE_ADDR_SIZE-1 downto 0) := std_logic_vector(to_unsigned(j,CE_ADDR_SIZE)); begin wrce(j) <= axi2ip_wren when awaddr_d1_cdc_tig ((CE_ADDR_SIZE + ADDR_OFFSET) - 1 downto ADDR_OFFSET) = BAR(CE_ADDR_SIZE-1 downto 0) else '0'; end generate WRCE_GEN; ------------------------------------------------------------------------------- -- register write ce's and data out to axi dma register module ------------------------------------------------------------------------------- REG_WR_OUT : process(ip2axi_aclk) begin if(ip2axi_aclk'EVENT and ip2axi_aclk = '1')then if(ip2axi_aresetn = '0')then axi2ip_wrce <= (others => '0'); else axi2ip_wrce <= wrce; end if; end if; end process REG_WR_OUT; axi2ip_wrdata <= axi2ip_wrdata_cdc_tig; --s_axi_lite_wdata; --********************************************************************* -- Write Response Support --*********************************************************************** -- Minimum of 2 IP clocks for addr and data capture, therefore delaying -- Lite clock addr and data capture by 2 Lite clocks will guarenttee bvalid -- responce occurs after write data acutally written. -- REG_ALIGN_CAP : process(s_axi_lite_aclk) -- begin -- if(s_axi_lite_aclk'EVENT and s_axi_lite_aclk = '1')then -- if(s_axi_lite_aresetn = '0')then -- lite_data_cap_d1 <= '0'; -- lite_data_cap_d2 <= '0'; -- lite_addr_cap_d1 <= '0'; -- lite_addr_cap_d2 <= '0'; -- else -- lite_data_cap_d1 <= rdy; --wr_data_cap; -- lite_data_cap_d2 <= lite_data_cap_d1; -- lite_addr_cap_d1 <= rdy; --wr_addr_cap; -- lite_addr_cap_d2 <= lite_addr_cap_d1; -- end if; -- end if; -- end process REG_ALIGN_CAP; -- Pseudo write enable used simply to assert bvalid -- lite_axi2ip_wren <= rdy; --'1' when wr_data_cap = '1' and wr_addr_cap = '1' -- else '0'; WRESP_PROCESS : process(s_axi_lite_aclk) begin if(s_axi_lite_aclk'EVENT and s_axi_lite_aclk = '1')then if(s_axi_lite_aresetn = '0')then bvalid_i <= '0'; rst_wvalid_re <= '0'; -- CR576999 -- If response issued and target indicates ready then -- clear response elsif(bvalid_i = '1' and s_axi_lite_bready = '1')then bvalid_i <= '0'; rst_wvalid_re <= '0'; -- CR576999 -- Issue a resonse on write elsif(rdy_out = '1')then -- elsif(lite_axi2ip_wren = '1')then bvalid_i <= '1'; rst_wvalid_re <= '1'; -- CR576999 end if; end if; end process WRESP_PROCESS; s_axi_lite_bresp <= OKAY_RESP; end generate GEN_ASYNC_WRITE; --************************************************************************* -- AXI LITE READ --***************************************************************************** ------------------------------------------------------------------------------- -- Assert Read Adddress Ready Handshake -- Capture rising edge of valid and register out as ready. This creates -- a 3 clock cycle address phase but also registers all inputs and outputs. -- Note : Single clock cycle address phase can be accomplished using -- combinatorial logic. ------------------------------------------------------------------------------- REG_ARVALID : process(s_axi_lite_aclk) begin if(s_axi_lite_aclk'EVENT and s_axi_lite_aclk = '1')then if(s_axi_lite_aresetn = '0' or rst_rvalid_re = '1')then arvalid_d1 <= '0'; else arvalid_d1 <= arvalid; end if; end if; end process REG_ARVALID; arvalid_re <= arvalid and not arvalid_d1 and not rst_rvalid_re and not read_in_progress; -- CR607165 -- register for proper alignment REG_ARREADY : process(s_axi_lite_aclk) begin if(s_axi_lite_aclk'EVENT and s_axi_lite_aclk = '1')then if(s_axi_lite_aresetn = '0')then arready_i <= '0'; else arready_i <= arvalid_re; end if; end if; end process REG_ARREADY; -- Always respond 'okay' axi lite read s_axi_lite_rresp <= OKAY_RESP; s_axi_lite_rvalid <= s_axi_lite_rvalid_i; -- s_axi_lite_aclk is synchronous to ip clock GEN_SYNC_READ : if C_AXI_LITE_IS_ASYNC = 0 generate begin read_in_progress <= '0'; --Not used for sync mode (CR607165) ------------------------------------------------------------------------------- -- Capture Read Address ------------------------------------------------------------------------------- REG_READ_ADDRESS : process(s_axi_lite_aclk) begin if(s_axi_lite_aclk'EVENT and s_axi_lite_aclk = '1')then if(s_axi_lite_aresetn = '0')then axi2ip_rdaddr_i <= (others => '0'); -- Register address on valid elsif(arvalid_re = '1')then axi2ip_rdaddr_i <= araddr; end if; end if; end process REG_READ_ADDRESS; ------------------------------------------------------------------------------- -- Generate RdCE based on address match to address bar ------------------------------------------------------------------------------- RDCE_GEN: for j in 0 to C_NUM_CE - 1 generate constant BAR : std_logic_vector(CE_ADDR_SIZE-1 downto 0) := std_logic_vector(to_unsigned(j,CE_ADDR_SIZE)); begin rdce(j) <= arvalid_re_d1 when axi2ip_rdaddr_i((CE_ADDR_SIZE + ADDR_OFFSET) - 1 downto ADDR_OFFSET) = BAR(CE_ADDR_SIZE-1 downto 0) else '0'; end generate RDCE_GEN; ------------------------------------------------------------------------------- -- Register out to IP ------------------------------------------------------------------------------- REG_RDCNTRL_OUT : process(s_axi_lite_aclk) begin if(s_axi_lite_aclk'EVENT and s_axi_lite_aclk = '1')then if(s_axi_lite_aresetn = '0')then --axi2ip_rdce <= (others => '0'); axi2ip_rdaddr <= (others => '0'); else --axi2ip_rdce <= rdce; axi2ip_rdaddr <= axi2ip_rdaddr_i; end if; end if; end process REG_RDCNTRL_OUT; -- Sample and hold rdce value until rvalid assertion REG_RDCE_OUT : process(s_axi_lite_aclk) begin if(s_axi_lite_aclk'EVENT and s_axi_lite_aclk = '1')then if(s_axi_lite_aresetn = '0' or rst_rvalid_re = '1')then axi2ip_rdce <= (others => '0'); elsif(arvalid_re_d1 = '1')then axi2ip_rdce <= rdce; end if; end if; end process REG_RDCE_OUT; -- Register for proper alignment REG_RVALID : process(s_axi_lite_aclk) begin if(s_axi_lite_aclk'EVENT and s_axi_lite_aclk = '1')then if(s_axi_lite_aresetn = '0')then arvalid_re_d1 <= '0'; rvalid <= '0'; else arvalid_re_d1 <= arvalid_re; rvalid <= arvalid_re_d1; end if; end if; end process REG_RVALID; ------------------------------------------------------------------------------- -- Drive read data and read data valid out on capture of valid address. ------------------------------------------------------------------------------- REG_RD_OUT : process(s_axi_lite_aclk) begin if(s_axi_lite_aclk'EVENT and s_axi_lite_aclk = '1')then if(s_axi_lite_aresetn = '0')then s_axi_lite_rdata <= (others => '0'); s_axi_lite_rvalid_i <= '0'; rst_rvalid_re <= '0'; -- CR576999 -- If rvalid driving out to target and target indicates ready -- then de-assert rvalid. (structure guarentees min 1 clock of rvalid) elsif(s_axi_lite_rvalid_i = '1' and s_axi_lite_rready = '1')then s_axi_lite_rdata <= (others => '0'); s_axi_lite_rvalid_i <= '0'; rst_rvalid_re <= '0'; -- CR576999 -- If read cycle then assert rvalid and rdata out to target elsif(rvalid = '1')then s_axi_lite_rdata <= ip2axi_rddata; s_axi_lite_rvalid_i <= '1'; rst_rvalid_re <= '1'; -- CR576999 end if; end if; end process REG_RD_OUT; end generate GEN_SYNC_READ; -- s_axi_lite_aclk is asynchronous to ip clock GEN_ASYNC_READ : if C_AXI_LITE_IS_ASYNC = 1 generate ATTRIBUTE async_reg : STRING; signal ip_arvalid_d1_cdc_tig : std_logic := '0'; signal ip_arvalid_d2 : std_logic := '0'; signal ip_arvalid_d3 : std_logic := '0'; signal ip_arvalid_re : std_logic := '0'; signal araddr_d1_cdc_tig : std_logic_vector(C_S_AXI_LITE_ADDR_WIDTH-1 downto 0) :=(others => '0'); signal araddr_d2 : std_logic_vector(C_S_AXI_LITE_ADDR_WIDTH-1 downto 0) :=(others => '0'); signal araddr_d3 : std_logic_vector(C_S_AXI_LITE_ADDR_WIDTH-1 downto 0) :=(others => '0'); signal lite_rdata_cdc_from : std_logic_vector(C_S_AXI_LITE_DATA_WIDTH-1 downto 0) :=(others => '0'); signal lite_rdata_d1_cdc_to : std_logic_vector(C_S_AXI_LITE_DATA_WIDTH-1 downto 0) :=(others => '0'); signal lite_rdata_d2 : std_logic_vector(C_S_AXI_LITE_DATA_WIDTH-1 downto 0) :=(others => '0'); -- ATTRIBUTE async_reg OF ip_arvalid_d1_cdc_tig : SIGNAL IS "true"; -- ATTRIBUTE async_reg OF ip_arvalid_d2 : SIGNAL IS "true"; -- ATTRIBUTE async_reg OF araddr_d1_cdc_tig : SIGNAL IS "true"; -- ATTRIBUTE async_reg OF araddr_d2 : SIGNAL IS "true"; -- ATTRIBUTE async_reg OF lite_rdata_d1_cdc_to : SIGNAL IS "true"; -- ATTRIBUTE async_reg OF lite_rdata_d2 : SIGNAL IS "true"; signal p_pulse_s_h : std_logic := '0'; signal p_pulse_s_h_clr : std_logic := '0'; signal s_pulse_d1 : std_logic := '0'; signal s_pulse_d2 : std_logic := '0'; signal s_pulse_d3 : std_logic := '0'; signal s_pulse_re : std_logic := '0'; signal p_pulse_re_d1 : std_logic := '0'; signal p_pulse_re_d2 : std_logic := '0'; signal p_pulse_re_d3 : std_logic := '0'; signal arready_d1 : std_logic := '0'; -- CR605883 signal arready_d2 : std_logic := '0'; -- CR605883 signal arready_d3 : std_logic := '0'; -- CR605883 signal arready_d4 : std_logic := '0'; -- CR605883 signal arready_d5 : std_logic := '0'; -- CR605883 signal arready_d6 : std_logic := '0'; -- CR605883 signal arready_d7 : std_logic := '0'; -- CR605883 signal arready_d8 : std_logic := '0'; -- CR605883 signal arready_d9 : std_logic := '0'; -- CR605883 signal arready_d10 : std_logic := '0'; -- CR605883 signal arready_d11 : std_logic := '0'; -- CR605883 signal arready_d12 : std_logic := '0'; -- CR605883 begin -- CR607165 -- Flag to prevent overlapping reads RD_PROGRESS : process(s_axi_lite_aclk) begin if(s_axi_lite_aclk'EVENT and s_axi_lite_aclk = '1')then if(s_axi_lite_aresetn = '0' or rst_rvalid_re = '1')then read_in_progress <= '0'; elsif(arvalid_re = '1')then read_in_progress <= '1'; end if; end if; end process RD_PROGRESS; -- Double register address in REG_RADDR_TO_IPCLK : entity lib_cdc_v1_0.cdc_sync generic map ( C_CDC_TYPE => 1, C_RESET_STATE => 0, C_SINGLE_BIT => 0, C_VECTOR_WIDTH => C_S_AXI_LITE_ADDR_WIDTH, C_MTBF_STAGES => MTBF_STAGES ) port map ( prmry_aclk => s_axi_lite_aclk, prmry_resetn => '0', prmry_in => '0', prmry_vect_in => s_axi_lite_araddr, scndry_aclk => ip2axi_aclk, scndry_resetn => '0', scndry_out => open, scndry_vect_out => araddr_d3 ); -- REG_RADDR_TO_IPCLK : process(ip2axi_aclk) -- begin -- if(ip2axi_aclk'EVENT and ip2axi_aclk = '1')then -- if(ip2axi_aresetn = '0')then -- araddr_d1_cdc_tig <= (others => '0'); -- araddr_d2 <= (others => '0'); -- araddr_d3 <= (others => '0'); -- else -- araddr_d1_cdc_tig <= s_axi_lite_araddr; -- araddr_d2 <= araddr_d1_cdc_tig; -- araddr_d3 <= araddr_d2; -- end if; -- end if; -- end process REG_RADDR_TO_IPCLK; -- Latch and hold read address REG_ARADDR_PROCESS : process(ip2axi_aclk) begin if(ip2axi_aclk'EVENT and ip2axi_aclk = '1')then if(ip2axi_aresetn = '0')then axi2ip_rdaddr_i <= (others => '0'); elsif(ip_arvalid_re = '1')then axi2ip_rdaddr_i <= araddr_d3; end if; end if; end process REG_ARADDR_PROCESS; axi2ip_rdaddr <= axi2ip_rdaddr_i; -- Register awready into IP clock domain. awready -- is a 1 axi_lite clock delay of the rising edge of -- arvalid. This provides a signal that asserts when -- araddr is known to be stable. REG_ARVALID_TO_IPCLK : entity lib_cdc_v1_0.cdc_sync generic map ( C_CDC_TYPE => 1, C_RESET_STATE => 0, C_SINGLE_BIT => 1, C_VECTOR_WIDTH => C_S_AXI_LITE_ADDR_WIDTH, C_MTBF_STAGES => MTBF_STAGES ) port map ( prmry_aclk => s_axi_lite_aclk, prmry_resetn => '0', prmry_in => arready_i, prmry_vect_in => (others => '0'), scndry_aclk => ip2axi_aclk, scndry_resetn => '0', scndry_out => ip_arvalid_d2, scndry_vect_out => open ); REG_ARVALID_TO_IPCLK1 : process(ip2axi_aclk) begin if(ip2axi_aclk'EVENT and ip2axi_aclk = '1')then if(ip2axi_aresetn = '0')then -- ip_arvalid_d1_cdc_tig <= '0'; -- ip_arvalid_d2 <= '0'; ip_arvalid_d3 <= '0'; else -- ip_arvalid_d1_cdc_tig <= arready_i; -- ip_arvalid_d2 <= ip_arvalid_d1_cdc_tig; ip_arvalid_d3 <= ip_arvalid_d2; end if; end if; end process REG_ARVALID_TO_IPCLK1; ip_arvalid_re <= ip_arvalid_d2 and not ip_arvalid_d3; ------------------------------------------------------------------------------- -- Generate Read CE's ------------------------------------------------------------------------------- RDCE_GEN: for j in 0 to C_NUM_CE - 1 generate constant BAR : std_logic_vector(CE_ADDR_SIZE-1 downto 0) := std_logic_vector(to_unsigned(j,CE_ADDR_SIZE)); begin rdce(j) <= ip_arvalid_re when araddr_d3((CE_ADDR_SIZE + ADDR_OFFSET) - 1 downto ADDR_OFFSET) = BAR(CE_ADDR_SIZE-1 downto 0) else '0'; end generate RDCE_GEN; ------------------------------------------------------------------------------- -- Register RDCE and RD Data out to IP ------------------------------------------------------------------------------- REG_RDCNTRL_OUT : process(ip2axi_aclk) begin if(ip2axi_aclk'EVENT and ip2axi_aclk = '1')then if(ip2axi_aresetn = '0')then axi2ip_rdce <= (others => '0'); elsif(ip_arvalid_re = '1')then axi2ip_rdce <= rdce; else axi2ip_rdce <= (others => '0'); end if; end if; end process REG_RDCNTRL_OUT; -- Generate sample and hold pulse to capture read data from IP REG_RVALID : process(ip2axi_aclk) begin if(ip2axi_aclk'EVENT and ip2axi_aclk = '1')then if(ip2axi_aresetn = '0')then rvalid <= '0'; else rvalid <= ip_arvalid_re; end if; end if; end process REG_RVALID; ------------------------------------------------------------------------------- -- Sample and hold read data from IP ------------------------------------------------------------------------------- S_H_READ_DATA : process(ip2axi_aclk) begin if(ip2axi_aclk'EVENT and ip2axi_aclk = '1')then if(ip2axi_aresetn = '0')then lite_rdata_cdc_from <= (others => '0'); -- If read cycle then assert rvalid and rdata out to target elsif(rvalid = '1')then lite_rdata_cdc_from <= ip2axi_rddata; end if; end if; end process S_H_READ_DATA; -- Cross read data to axi_lite clock domain REG_DATA2LITE_CLOCK : entity lib_cdc_v1_0.cdc_sync generic map ( C_CDC_TYPE => 1, C_RESET_STATE => 0, C_SINGLE_BIT => 0, C_VECTOR_WIDTH => 32, C_MTBF_STAGES => MTBF_STAGES ) port map ( prmry_aclk => ip2axi_aclk, prmry_resetn => '0', prmry_in => '0', --lite_rdata_cdc_from, prmry_vect_in => lite_rdata_cdc_from, scndry_aclk => s_axi_lite_aclk, scndry_resetn => '0', scndry_out => open, --lite_rdata_d2, scndry_vect_out => lite_rdata_d2 ); -- REG_DATA2LITE_CLOCK : process(s_axi_lite_aclk) -- begin -- if(s_axi_lite_aclk'EVENT and s_axi_lite_aclk = '1')then -- if(s_axi_lite_aresetn = '0')then -- lite_rdata_d1_cdc_to <= (others => '0'); -- lite_rdata_d2 <= (others => '0'); -- else -- lite_rdata_d1_cdc_to <= lite_rdata_cdc_from; -- lite_rdata_d2 <= lite_rdata_d1_cdc_to; -- end if; -- end if; -- end process REG_DATA2LITE_CLOCK; -- CR605883 (CDC) modified to remove -- Because axi_lite_aclk must be less than or equal to ip2axi_aclk -- then read data will appear a maximum 6 clocks from assertion -- of arready. REG_ALIGN_RDATA_LATCH : process(s_axi_lite_aclk) begin if(s_axi_lite_aclk'EVENT and s_axi_lite_aclk = '1')then if(s_axi_lite_aresetn = '0')then arready_d1 <= '0'; arready_d2 <= '0'; arready_d3 <= '0'; arready_d4 <= '0'; arready_d5 <= '0'; arready_d6 <= '0'; arready_d7 <= '0'; arready_d8 <= '0'; arready_d9 <= '0'; arready_d10 <= '0'; arready_d11 <= '0'; arready_d12 <= '0'; else arready_d1 <= arready_i; arready_d2 <= arready_d1; arready_d3 <= arready_d2; arready_d4 <= arready_d3; arready_d5 <= arready_d4; arready_d6 <= arready_d5; arready_d7 <= arready_d6; arready_d8 <= arready_d7; arready_d9 <= arready_d8; arready_d10 <= arready_d9; arready_d11 <= arready_d10; arready_d12 <= arready_d11; end if; end if; end process REG_ALIGN_RDATA_LATCH; ------------------------------------------------------------------------------- -- Drive read data and read data valid out on capture of valid address. ------------------------------------------------------------------------------- REG_RD_OUT : process(s_axi_lite_aclk) begin if(s_axi_lite_aclk'EVENT and s_axi_lite_aclk = '1')then if(s_axi_lite_aresetn = '0')then s_axi_lite_rdata <= (others => '0'); s_axi_lite_rvalid_i <= '0'; rst_rvalid_re <= '0'; -- CR576999 -- If rvalid driving out to target and target indicates ready -- then de-assert rvalid. (structure guarentees min 1 clock of rvalid) elsif(s_axi_lite_rvalid_i = '1' and s_axi_lite_rready = '1')then s_axi_lite_rdata <= (others => '0'); s_axi_lite_rvalid_i <= '0'; rst_rvalid_re <= '0'; -- CR576999 -- If read cycle then assert rvalid and rdata out to target -- CR605883 --elsif(s_pulse_re = '1')then elsif(arready_d12 = '1')then s_axi_lite_rdata <= lite_rdata_d2; s_axi_lite_rvalid_i <= '1'; rst_rvalid_re <= '1'; -- CR576999 end if; end if; end process REG_RD_OUT; end generate GEN_ASYNC_READ; end implementation;	gpl-3.0	95b0bfed1971dc1bff3addd4772f3fdd	0.426374	4.122204	false	false	false	false
mistryalok/Zedboard	learning/training/MSD/s09/axi_dma_sg/vivado/project_1/project_1.srcs/sources_1/ipshared/xilinx.com/axi_sg_v4_1/0535f152/hdl/src/vhdl/axi_sg_updt_queue.vhd	3	53,827	-- *********************************************************************** -- -- (c) Copyright 2010-2011 Xilinx, Inc. All rights reserved. -- -- This file contains confidential and proprietary information -- of Xilinx, Inc. and is protected under U.S. and -- international copyright and other intellectual property -- laws. -- -- DISCLAIMER -- This disclaimer is not a license and does not grant any -- rights to the materials distributed herewith. Except as -- otherwise provided in a valid license issued to you by -- Xilinx, and to the maximum extent permitted by applicable -- law: (1) THESE MATERIALS ARE MADE AVAILABLE "AS IS" AND -- WITH ALL FAULTS, AND XILINX HEREBY DISCLAIMS ALL WARRANTIES -- AND CONDITIONS, EXPRESS, IMPLIED, OR STATUTORY, INCLUDING -- BUT NOT LIMITED TO WARRANTIES OF MERCHANTABILITY, NON- -- INFRINGEMENT, OR FITNESS FOR ANY PARTICULAR PURPOSE; and -- (2) Xilinx shall not be liable (whether in contract or tort, -- including negligence, or under any other theory of -- liability) for any loss or damage of any kind or nature -- related to, arising under or in connection with these -- materials, including for any direct, or any indirect, -- special, incidental, or consequential loss or damage -- (including loss of data, profits, goodwill, or any type of -- loss or damage suffered as a result of any action brought -- by a third party) even if such damage or loss was -- reasonably foreseeable or Xilinx had been advised of the -- possibility of the same. -- -- CRITICAL APPLICATIONS -- Xilinx products are not designed or intended to be fail- -- safe, or for use in any application requiring fail-safe -- performance, such as life-support or safety devices or -- systems, Class III medical devices, nuclear facilities, -- applications related to the deployment of airbags, or any -- other applications that could lead to death, personal -- injury, or severe property or environmental damage -- (individually and collectively, "Critical -- Applications"). Customer assumes the sole risk and -- liability of any use of Xilinx products in Critical -- Applications, subject only to applicable laws and -- regulations governing limitations on product liability. -- -- THIS COPYRIGHT NOTICE AND DISCLAIMER MUST BE RETAINED AS -- PART OF THIS FILE AT ALL TIMES. -- -- ********************************************************************* -- ------------------------------------------------------------------------------- -- Filename: axi_sg_updt_queue.vhd -- Description: This entity is the descriptor fetch queue interface -- -- VHDL-Standard: VHDL'93 ------------------------------------------------------------------------------- library ieee; use ieee.std_logic_1164.all; use ieee.numeric_std.all; use ieee.std_logic_misc.all; library axi_sg_v4_1; use axi_sg_v4_1.axi_sg_pkg.all; library lib_srl_fifo_v1_0; use lib_srl_fifo_v1_0.srl_fifo_f; library lib_pkg_v1_0; use lib_pkg_v1_0.lib_pkg.all; ------------------------------------------------------------------------------- entity axi_sg_updt_queue is generic ( C_M_AXI_SG_ADDR_WIDTH : integer range 32 to 64 := 32; -- Master AXI Memory Map Address Width for Scatter Gather R/W Port C_M_AXIS_UPDT_DATA_WIDTH : integer range 32 to 32 := 32; -- Master AXI Memory Map Data Width for Scatter Gather R/W Port C_S_AXIS_UPDPTR_TDATA_WIDTH : integer range 32 to 32 := 32; -- 32 Update Status Bits C_S_AXIS_UPDSTS_TDATA_WIDTH : integer range 33 to 33 := 33; -- 1 IOC bit + 32 Update Status Bits C_SG_UPDT_DESC2QUEUE : integer range 0 to 8 := 0; -- Number of descriptors to fetch and queue for each channel. -- A value of zero excludes the fetch queues. C_SG_WORDS_TO_UPDATE : integer range 1 to 16 := 8; -- Number of words to update C_SG2_WORDS_TO_UPDATE : integer range 1 to 16 := 8; -- Number of words to update C_AXIS_IS_ASYNC : integer range 0 to 1 := 0; -- Channel 1 is async to sg_aclk -- 0 = Synchronous to SG ACLK -- 1 = Asynchronous to SG ACLK C_INCLUDE_MM2S : integer range 0 to 1 := 0; C_INCLUDE_S2MM : integer range 0 to 1 := 0; C_FAMILY : string := "virtex7" -- Device family used for proper BRAM selection ); port ( ----------------------------------------------------------------------- -- AXI Scatter Gather Interface ----------------------------------------------------------------------- m_axi_sg_aclk : in std_logic ; -- m_axi_sg_aresetn : in std_logic ; -- s_axis_updt_aclk : in std_logic ; -- -- --****************************-- -- -- Control and Status -- -- --****************************-- -- updt_curdesc_wren : out std_logic ; -- updt_curdesc : out std_logic_vector -- (C_M_AXI_SG_ADDR_WIDTH-1 downto 0) ; -- updt_active : in std_logic ; -- updt_queue_empty : out std_logic ; -- updt_ioc : out std_logic ; -- updt_ioc_irq_set : in std_logic ; -- -- dma_interr : out std_logic ; -- dma_slverr : out std_logic ; -- dma_decerr : out std_logic ; -- dma_interr_set : in std_logic ; -- dma_slverr_set : in std_logic ; -- dma_decerr_set : in std_logic ; -- updt2_active : in std_logic ; -- updt2_queue_empty : out std_logic ; -- updt2_ioc : out std_logic ; -- updt2_ioc_irq_set : in std_logic ; -- -- dma2_interr : out std_logic ; -- dma2_slverr : out std_logic ; -- dma2_decerr : out std_logic ; -- dma2_interr_set : in std_logic ; -- dma2_slverr_set : in std_logic ; -- dma2_decerr_set : in std_logic ; -- -- --****************************-- -- -- Update Interfaces In -- -- --****************************-- -- -- Update Pointer Stream -- s_axis_updtptr_tdata : in std_logic_vector -- (C_S_AXIS_UPDPTR_TDATA_WIDTH-1 downto 0); -- s_axis_updtptr_tvalid : in std_logic ; -- s_axis_updtptr_tready : out std_logic ; -- s_axis_updtptr_tlast : in std_logic ; -- -- -- Update Status Stream -- s_axis_updtsts_tdata : in std_logic_vector -- (C_S_AXIS_UPDSTS_TDATA_WIDTH-1 downto 0); -- s_axis_updtsts_tvalid : in std_logic ; -- s_axis_updtsts_tready : out std_logic ; -- s_axis_updtsts_tlast : in std_logic ; -- s_axis2_updtptr_tdata : in std_logic_vector -- (C_S_AXIS_UPDPTR_TDATA_WIDTH-1 downto 0); -- s_axis2_updtptr_tvalid : in std_logic ; -- s_axis2_updtptr_tready : out std_logic ; -- s_axis2_updtptr_tlast : in std_logic ; -- -- -- Update Status Stream -- s_axis2_updtsts_tdata : in std_logic_vector -- (C_S_AXIS_UPDSTS_TDATA_WIDTH-1 downto 0); -- s_axis2_updtsts_tvalid : in std_logic ; -- s_axis2_updtsts_tready : out std_logic ; -- s_axis2_updtsts_tlast : in std_logic ; -- -- --****************************-- -- -- Update Interfaces Out -- -- --*****************************-- -- -- S2MM Stream Out To DataMover -- m_axis_updt_tdata : out std_logic_vector -- (C_M_AXIS_UPDT_DATA_WIDTH-1 downto 0); -- m_axis_updt_tlast : out std_logic ; -- m_axis_updt_tvalid : out std_logic ; -- m_axis_updt_tready : in std_logic -- ); end axi_sg_updt_queue; ------------------------------------------------------------------------------- -- Architecture ------------------------------------------------------------------------------- architecture implementation of axi_sg_updt_queue is attribute DowngradeIPIdentifiedWarnings: string; attribute DowngradeIPIdentifiedWarnings of implementation : architecture is "yes"; attribute mark_debug : string; ------------------------------------------------------------------------------- -- Functions ------------------------------------------------------------------------------- -- No Functions Declared ------------------------------------------------------------------------------- -- Constants Declarations ------------------------------------------------------------------------------- constant USE_LOGIC_FIFOS : integer := 0; -- Use Logic FIFOs constant USE_BRAM_FIFOS : integer := 1; -- Use BRAM FIFOs -- Number of words deep fifo needs to be. Depth required to store 2 word -- porters for each descriptor is C_SG_UPDT_DESC2QUEUE x 2 --constant UPDATE_QUEUE_DEPTH : integer := max2(16,C_SG_UPDT_DESC2QUEUE 2); constant UPDATE_QUEUE_DEPTH : integer := max2(16,pad_power2(C_SG_UPDT_DESC2QUEUE * 2)); -- Width of fifo rd and wr counts - only used for proper fifo operation constant UPDATE_QUEUE_CNT_WIDTH : integer := clog2(UPDATE_QUEUE_DEPTH+1); -- Select between BRAM or LOGIC memory type constant UPD_Q_MEMORY_TYPE : integer := bo2int(UPDATE_QUEUE_DEPTH > 16); -- Number of words deep fifo needs to be. Depth required to store all update -- words is C_SG_UPDT_DESC2QUEUE x C_SG_WORDS_TO_UPDATE constant UPDATE_STS_QUEUE_DEPTH : integer := max2(16,pad_power2(C_SG_UPDT_DESC2QUEUE * C_SG_WORDS_TO_UPDATE)); constant UPDATE_STS2_QUEUE_DEPTH : integer := max2(16,pad_power2(C_SG_UPDT_DESC2QUEUE * C_SG2_WORDS_TO_UPDATE)); -- Select between BRAM or LOGIC memory type constant STS_Q_MEMORY_TYPE : integer := bo2int(UPDATE_STS_QUEUE_DEPTH > 16); -- Select between BRAM or LOGIC memory type constant STS2_Q_MEMORY_TYPE : integer := bo2int(UPDATE_STS2_QUEUE_DEPTH > 16); -- Width of fifo rd and wr counts - only used for proper fifo operation constant UPDATE_STS_QUEUE_CNT_WIDTH : integer := clog2(C_SG_UPDT_DESC2QUEUE+1); ------------------------------------------------------------------------------- -- Signal / Type Declarations ------------------------------------------------------------------------------- -- Channel signals signal write_curdesc_lsb : std_logic := '0'; signal write_curdesc_lsb_sm : std_logic := '0'; signal write_curdesc_msb : std_logic := '0'; signal write_curdesc_lsb1 : std_logic := '0'; signal write_curdesc_msb1 : std_logic := '0'; signal rden_del : std_logic := '0'; signal updt_active_d1 : std_logic := '0'; signal updt_active_d2 : std_logic := '0'; signal updt_active_re1 : std_logic := '0'; signal updt_active_re2 : std_logic := '0'; signal updt_active_re : std_logic := '0'; type PNTR_STATE_TYPE is (IDLE, READ_CURDESC_LSB, READ_CURDESC_MSB, WRITE_STATUS ); signal pntr_cs : PNTR_STATE_TYPE; signal pntr_ns : PNTR_STATE_TYPE; -- State Machine Signal signal writing_status : std_logic := '0'; signal dataq_rden : std_logic := '0'; signal stsq_rden : std_logic := '0'; -- Pointer Queue FIFO Signals signal ptr_queue_rden : std_logic := '0'; signal ptr_queue_wren : std_logic := '0'; signal ptr_queue_empty : std_logic := '0'; signal ptr_queue_full : std_logic := '0'; signal ptr_queue_din : std_logic_vector (C_S_AXIS_UPDPTR_TDATA_WIDTH-1 downto 0) := (others => '0'); signal ptr_queue_dout : std_logic_vector (C_S_AXIS_UPDPTR_TDATA_WIDTH-1 downto 0) := (others => '0'); signal ptr_queue_dout_int : std_logic_vector (C_S_AXIS_UPDPTR_TDATA_WIDTH-1 downto 0) := (others => '0'); -- Status Queue FIFO Signals signal sts_queue_wren : std_logic := '0'; signal sts_queue_rden : std_logic := '0'; signal sts_queue_din : std_logic_vector (C_S_AXIS_UPDSTS_TDATA_WIDTH downto 0) := (others => '0'); signal sts_queue_dout : std_logic_vector (C_S_AXIS_UPDSTS_TDATA_WIDTH downto 0) := (others => '0'); signal sts_queue_dout_int : std_logic_vector (3 downto 0) := (others => '0'); signal sts_queue_full : std_logic := '0'; signal sts_queue_empty : std_logic := '0'; signal ptr2_queue_rden : std_logic := '0'; signal ptr2_queue_wren : std_logic := '0'; signal ptr2_queue_empty : std_logic := '0'; signal ptr2_queue_full : std_logic := '0'; signal ptr2_queue_din : std_logic_vector (C_S_AXIS_UPDPTR_TDATA_WIDTH-1 downto 0) := (others => '0'); signal ptr2_queue_dout : std_logic_vector (C_S_AXIS_UPDPTR_TDATA_WIDTH-1 downto 0) := (others => '0'); -- Status Queue FIFO Signals signal sts2_queue_wren : std_logic := '0'; signal sts2_queue_rden : std_logic := '0'; signal sts2_queue_din : std_logic_vector (C_S_AXIS_UPDSTS_TDATA_WIDTH downto 0) := (others => '0'); signal sts2_queue_dout : std_logic_vector (C_S_AXIS_UPDSTS_TDATA_WIDTH downto 0) := (others => '0'); signal sts2_queue_full : std_logic := '0'; signal sts2_queue_empty : std_logic := '0'; signal sts2_queue_empty_del : std_logic := '0'; signal sts2_dout_valid : std_logic := '0'; signal sts_dout_valid : std_logic := '0'; signal sts2_dout_valid_del : std_logic := '0'; signal valid_new : std_logic := '0'; signal valid_latch : std_logic := '0'; signal valid1_new : std_logic := '0'; signal valid1_latch : std_logic := '0'; signal empty_low : std_logic := '0'; -- Misc Support Signals signal writing_status_d1 : std_logic := '0'; signal writing_status_re : std_logic := '0'; signal writing_status_re_ch1 : std_logic := '0'; signal writing_status_re_ch2 : std_logic := '0'; signal sinit : std_logic := '0'; signal updt_tvalid : std_logic := '0'; signal updt_tlast : std_logic := '0'; signal updt2_tvalid : std_logic := '0'; signal updt2_tlast : std_logic := '0'; attribute mark_debug of updt_tvalid : signal is "true"; attribute mark_debug of updt2_tvalid : signal is "true"; attribute mark_debug of updt_tlast : signal is "true"; attribute mark_debug of updt2_tlast : signal is "true"; signal status_d1, status_d2 : std_logic := '0'; signal updt_tvalid_int : std_logic := '0'; signal updt_tlast_int : std_logic := '0'; signal ptr_queue_empty_int : std_logic := '0'; signal updt_active_int : std_logic := '0'; signal follower_reg_mm2s : std_logic_vector (33 downto 0) := (others => '0'); attribute mark_debug of follower_reg_mm2s : signal is "true"; signal follower_full_mm2s :std_logic := '0'; signal follower_empty_mm2s : std_logic := '0'; signal follower_reg_s2mm : std_logic_vector (33 downto 0) := (others => '0'); attribute mark_debug of follower_reg_s2mm : signal is "true"; signal follower_full_s2mm :std_logic := '0'; signal follower_empty_s2mm : std_logic := '0'; signal follower_reg, m_axis_updt_tdata_tmp : std_logic_vector (33 downto 0); signal follower_full :std_logic := '0'; signal follower_empty : std_logic := '0'; signal sts_rden : std_logic := '0'; signal sts2_rden : std_logic := '0'; signal follower_tlast : std_logic := '0'; signal follower_reg_image : std_logic := '0'; signal m_axis_updt_tready_mm2s, m_axis_updt_tready_s2mm : std_logic := '0'; ------------------------------------------------------------------------------- -- Begin architecture logic ------------------------------------------------------------------------------- begin m_axis_updt_tdata <= follower_reg_mm2s (C_S_AXIS_UPDSTS_TDATA_WIDTH-2 downto 0) when updt_active = '1' else follower_reg_s2mm (C_S_AXIS_UPDSTS_TDATA_WIDTH-2 downto 0) ; m_axis_updt_tvalid <= updt_tvalid when updt_active = '1' else updt2_tvalid; m_axis_updt_tlast <= updt_tlast when updt_active = '1' else updt2_tlast; m_axis_updt_tready_mm2s <= m_axis_updt_tready when updt_active = '1' else '0'; m_axis_updt_tready_s2mm <= m_axis_updt_tready when updt2_active = '1' else '0'; -- Asset active strobe on rising edge of update active -- asertion. This kicks off the update process for -- channel 1 updt_active_re <= updt_active_re1 or updt_active_re2; -- Current Descriptor Pointer Fetch. This state machine controls -- reading out the current pointer from the Queue or channel port -- and writing it to the update manager for use in command -- generation to the DataMover for Descriptor update. CURDESC_PNTR_STATE : process(pntr_cs, updt_active_re, ptr_queue_empty_int, m_axis_updt_tready, updt_tvalid_int, updt_tlast_int) begin write_curdesc_lsb_sm <= '0'; write_curdesc_msb <= '0'; writing_status <= '0'; dataq_rden <= '0'; stsq_rden <= '0'; pntr_ns <= pntr_cs; case pntr_cs is when IDLE => if(updt_active_re = '1')then pntr_ns <= READ_CURDESC_LSB; else pntr_ns <= IDLE; end if; --------------------------------------------------------------- -- Get lower current descriptor pointer -- Reads one word from data queue fifo --------------------------------------------------------------- when READ_CURDESC_LSB => -- on tvalid from Queue or channel port then register -- lsb curdesc and setup to register msb curdesc if(ptr_queue_empty_int = '0')then write_curdesc_lsb_sm <= '1'; dataq_rden <= '1'; -- pntr_ns <= READ_CURDESC_MSB; pntr_ns <= WRITE_STATUS; --READ_CURDESC_MSB; else -- coverage off pntr_ns <= READ_CURDESC_LSB; -- coverage on end if; --------------------------------------------------------------- -- Get upper current descriptor -- Reads one word from data queue fifo --------------------------------------------------------------- -- when READ_CURDESC_MSB => -- On tvalid from Queue or channel port then register -- msb. This will also write curdesc out to update -- manager. -- if(ptr_queue_empty_int = '0')then -- dataq_rden <= '1'; -- write_curdesc_msb <= '1'; -- pntr_ns <= WRITE_STATUS; -- else -- -- coverage off -- pntr_ns <= READ_CURDESC_MSB; -- -- coverage on -- end if; --------------------------------------------------------------- -- Hold in this state until remainder of descriptor is -- written out. when WRITE_STATUS => -- De-MUX appropriage tvalid/tlast signals writing_status <= '1'; -- Enable reading of Status Queue if datamover can -- accept data stsq_rden <= m_axis_updt_tready; -- Hold in the status state until tlast is pulled -- from status fifo if(updt_tvalid_int = '1' and m_axis_updt_tready = '1' and updt_tlast_int = '1')then -- if(follower_full = '1' and m_axis_updt_tready = '1' -- and follower_tlast = '1')then pntr_ns <= IDLE; else pntr_ns <= WRITE_STATUS; end if; -- coverage off when others => pntr_ns <= IDLE; -- coverage on end case; end process CURDESC_PNTR_STATE; updt_tvalid_int <= updt_tvalid or updt2_tvalid; updt_tlast_int <= updt_tlast or updt2_tlast; ptr_queue_empty_int <= ptr_queue_empty when updt_active = '1' else ptr2_queue_empty when updt2_active = '1' else '1'; --------------------------------------------------------------------------- -- Register for CURDESC Pointer state machine --------------------------------------------------------------------------- REG_PNTR_STATES : process(m_axi_sg_aclk) begin if(m_axi_sg_aclk'EVENT and m_axi_sg_aclk = '1')then if(m_axi_sg_aresetn = '0')then pntr_cs <= IDLE; else pntr_cs <= pntr_ns; end if; end if; end process REG_PNTR_STATES; GEN_Q_FOR_SYNC : if C_AXIS_IS_ASYNC = 0 generate begin MM2S_CHANNEL : if C_INCLUDE_MM2S = 1 generate updt_tvalid <= follower_full_mm2s and updt_active; updt_tlast <= follower_reg_mm2s(C_S_AXIS_UPDSTS_TDATA_WIDTH) and updt_active; sts_rden <= follower_empty_mm2s and (not sts_queue_empty); -- and updt_active; VALID_REG_MM2S_ACTIVE : process(m_axi_sg_aclk) begin if(m_axi_sg_aclk'EVENT and m_axi_sg_aclk = '1')then if(m_axi_sg_aresetn = '0' or (m_axis_updt_tready_mm2s = '1' and follower_full_mm2s = '1'))then -- follower_reg_mm2s <= (others => '0'); follower_full_mm2s <= '0'; follower_empty_mm2s <= '1'; else if (sts_rden = '1') then -- follower_reg_mm2s <= sts_queue_dout; follower_full_mm2s <= '1'; follower_empty_mm2s <= '0'; end if; end if; end if; end process VALID_REG_MM2S_ACTIVE; VALID_REG_MM2S_ACTIVE1 : process(m_axi_sg_aclk) begin if(m_axi_sg_aclk'EVENT and m_axi_sg_aclk = '1')then if(m_axi_sg_aresetn = '0')then follower_reg_mm2s <= (others => '0'); else if (sts_rden = '1') then follower_reg_mm2s <= sts_queue_dout; end if; end if; end if; end process VALID_REG_MM2S_ACTIVE1; REG_ACTIVE : process(m_axi_sg_aclk) begin if(m_axi_sg_aclk'EVENT and m_axi_sg_aclk = '1')then if(m_axi_sg_aresetn = '0' )then updt_active_d1 <= '0'; else updt_active_d1 <= updt_active; end if; end if; end process REG_ACTIVE; updt_active_re1 <= updt_active and not updt_active_d1; -- I_UPDT_DATA_FIFO : entity lib_srl_fifo_v1_0.srl_fifo_f -- generic map ( -- C_DWIDTH => 32 , -- C_DEPTH => 8 , -- C_FAMILY => C_FAMILY -- ) -- port map ( -- Clk => m_axi_sg_aclk , -- Reset => sinit , -- FIFO_Write => ptr_queue_wren , -- Data_In => ptr_queue_din , -- FIFO_Read => ptr_queue_rden , -- Data_Out => ptr_queue_dout , -- FIFO_Empty => ptr_queue_empty , -- FIFO_Full => ptr_queue_full, -- Addr => open -- ); process (m_axi_sg_aclk) begin if (m_axi_sg_aclk'event and m_axi_sg_aclk = '1') then if (sinit = '1') then ptr_queue_dout <= (others => '0'); elsif (ptr_queue_wren = '1') then ptr_queue_dout <= ptr_queue_din; end if; end if; end process; process (m_axi_sg_aclk) begin if (m_axi_sg_aclk'event and m_axi_sg_aclk = '1') then if (sinit = '1' or ptr_queue_rden = '1') then ptr_queue_empty <= '1'; ptr_queue_full <= '0'; elsif (ptr_queue_wren = '1') then ptr_queue_empty <= '0'; ptr_queue_full <= '1'; end if; end if; end process; -- Channel Pointer Queue (Generate Synchronous FIFO) -- I_UPDT_STS_FIFO : entity lib_srl_fifo_v1_0.srl_fifo_f -- generic map ( -- C_DWIDTH => 34 , -- C_DEPTH => 4 , -- C_FAMILY => C_FAMILY -- ) -- port map ( -- Clk => m_axi_sg_aclk , -- Reset => sinit , -- FIFO_Write => sts_queue_wren , -- Data_In => sts_queue_din , -- FIFO_Read => sts_rden, --sts_queue_rden , -- Data_Out => sts_queue_dout , -- FIFO_Empty => sts_queue_empty , -- FIFO_Full => sts_queue_full , -- Addr => open -- ); process (m_axi_sg_aclk) begin if (m_axi_sg_aclk'event and m_axi_sg_aclk = '1') then if (sinit = '1') then sts_queue_dout <= (others => '0'); elsif (sts_queue_wren = '1') then sts_queue_dout <= sts_queue_din; end if; end if; end process; process (m_axi_sg_aclk) begin if (m_axi_sg_aclk'event and m_axi_sg_aclk = '1') then if (sinit = '1' or sts_rden = '1') then sts_queue_empty <= '1'; sts_queue_full <= '0'; elsif (sts_queue_wren = '1') then sts_queue_empty <= '0'; sts_queue_full <= '1'; end if; end if; end process; -- Channel Status Queue (Generate Synchronous FIFO) --*************************************** -- Channel Data Port Side of Queues --*************************************** -- Pointer Queue Update - Descriptor Pointer (32bits) -- i.e. 2 current descriptor pointers and any app fields ptr_queue_din(C_S_AXIS_UPDPTR_TDATA_WIDTH-1 downto 0) <= s_axis_updtptr_tdata( -- DESC DATA C_S_AXIS_UPDPTR_TDATA_WIDTH-1 downto 0); -- Data Queue Write Enable - based on tvalid and queue not full ptr_queue_wren <= s_axis_updtptr_tvalid -- TValid and not ptr_queue_full; -- Data Queue NOT Full -- Drive channel port with ready if room in data queue s_axis_updtptr_tready <= not ptr_queue_full; --************************************* -- Channel Status Port Side of Queues --*************************************** -- Status Queue Update - TLAST(1bit) & Includes IOC(1bit) & Descriptor Status(32bits) -- Note: Type field is stripped off sts_queue_din(C_S_AXIS_UPDSTS_TDATA_WIDTH) <= s_axis_updtsts_tlast; -- Store with tlast sts_queue_din(C_S_AXIS_UPDSTS_TDATA_WIDTH-1 downto 0) <= s_axis_updtsts_tdata( -- IOC & DESC STS C_S_AXIS_UPDSTS_TDATA_WIDTH-1 downto 0); -- Status Queue Write Enable - based on tvalid and queue not full sts_queue_wren <= s_axis_updtsts_tvalid and not sts_queue_full; -- Drive channel port with ready if room in status queue s_axis_updtsts_tready <= not sts_queue_full; --********************************* -- SG Engine Side of Queues --*********************************** -- Indicate NOT empty if both status queue and data queue are not empty -- updt_queue_empty <= ptr_queue_empty -- or (sts_queue_empty and follower_empty and updt_active); updt_queue_empty <= ptr_queue_empty or follower_empty_mm2s; -- and updt_active); -- Data queue read enable ptr_queue_rden <= '1' when dataq_rden = '1' -- Cur desc read enable and ptr_queue_empty = '0' -- Data Queue NOT empty and updt_active = '1' else '0'; -- Status queue read enable sts_queue_rden <= '1' when stsq_rden = '1' -- Writing desc status and sts_queue_empty = '0' -- Status fifo NOT empty and updt_active = '1' else '0'; ----------------------------------------------------------------------- -- TVALID - status queue not empty and writing status ----------------------------------------------------------------------- ----------------------------------------------------------------------- -- TLAST - status queue not empty, writing status, and last asserted ----------------------------------------------------------------------- -- Drive last as long as tvalid is asserted and last from fifo -- is asserted end generate MM2S_CHANNEL; NO_MM2S_CHANNEL : if C_INCLUDE_MM2S = 0 generate begin updt_active_re1 <= '0'; updt_queue_empty <= '0'; s_axis_updtptr_tready <= '0'; s_axis_updtsts_tready <= '0'; sts_queue_dout <= (others => '0'); sts_queue_full <= '0'; sts_queue_empty <= '0'; ptr_queue_dout <= (others => '0'); ptr_queue_empty <= '0'; ptr_queue_full <= '0'; end generate NO_MM2S_CHANNEL; S2MM_CHANNEL : if C_INCLUDE_S2MM = 1 generate begin updt2_tvalid <= follower_full_s2mm and updt2_active; updt2_tlast <= follower_reg_s2mm(C_S_AXIS_UPDSTS_TDATA_WIDTH) and updt2_active; sts2_rden <= follower_empty_s2mm and (not sts2_queue_empty); -- and updt2_active; VALID_REG_S2MM_ACTIVE : process(m_axi_sg_aclk) begin if(m_axi_sg_aclk'EVENT and m_axi_sg_aclk = '1')then if(m_axi_sg_aresetn = '0' or (m_axis_updt_tready_s2mm = '1' and follower_full_s2mm = '1'))then -- follower_reg_s2mm <= (others => '0'); follower_full_s2mm <= '0'; follower_empty_s2mm <= '1'; else if (sts2_rden = '1') then -- follower_reg_s2mm <= sts2_queue_dout; follower_full_s2mm <= '1'; follower_empty_s2mm <= '0'; end if; end if; end if; end process VALID_REG_S2MM_ACTIVE; VALID_REG_S2MM_ACTIVE1 : process(m_axi_sg_aclk) begin if(m_axi_sg_aclk'EVENT and m_axi_sg_aclk = '1')then if(m_axi_sg_aresetn = '0')then follower_reg_s2mm <= (others => '0'); else if (sts2_rden = '1') then follower_reg_s2mm <= sts2_queue_dout; end if; end if; end if; end process VALID_REG_S2MM_ACTIVE1; REG2_ACTIVE : process(m_axi_sg_aclk) begin if(m_axi_sg_aclk'EVENT and m_axi_sg_aclk = '1')then if(m_axi_sg_aresetn = '0' )then updt_active_d2 <= '0'; else updt_active_d2 <= updt2_active; end if; end if; end process REG2_ACTIVE; updt_active_re2 <= updt2_active and not updt_active_d2; -- I_UPDT2_DATA_FIFO : entity lib_srl_fifo_v1_0.srl_fifo_f -- generic map ( -- C_DWIDTH => 32 , -- C_DEPTH => 8 , -- C_FAMILY => C_FAMILY -- ) -- port map ( -- Clk => m_axi_sg_aclk , -- Reset => sinit , -- FIFO_Write => ptr2_queue_wren , -- Data_In => ptr2_queue_din , -- FIFO_Read => ptr2_queue_rden , -- Data_Out => ptr2_queue_dout , -- FIFO_Empty => ptr2_queue_empty , -- FIFO_Full => ptr2_queue_full, -- Addr => open -- ); process (m_axi_sg_aclk) begin if (m_axi_sg_aclk'event and m_axi_sg_aclk = '1') then if (sinit = '1') then ptr2_queue_dout <= (others => '0'); elsif (ptr2_queue_wren = '1') then ptr2_queue_dout <= ptr2_queue_din; end if; end if; end process; process (m_axi_sg_aclk) begin if (m_axi_sg_aclk'event and m_axi_sg_aclk = '1') then if (sinit = '1' or ptr2_queue_rden = '1') then ptr2_queue_empty <= '1'; ptr2_queue_full <= '0'; elsif (ptr2_queue_wren = '1') then ptr2_queue_empty <= '0'; ptr2_queue_full <= '1'; end if; end if; end process; APP_UPDATE: if C_SG2_WORDS_TO_UPDATE /= 1 generate begin I_UPDT2_STS_FIFO : entity lib_srl_fifo_v1_0.srl_fifo_f generic map ( C_DWIDTH => 34 , C_DEPTH => 12 , C_FAMILY => C_FAMILY ) port map ( Clk => m_axi_sg_aclk , Reset => sinit , FIFO_Write => sts2_queue_wren , Data_In => sts2_queue_din , FIFO_Read => sts2_rden, Data_Out => sts2_queue_dout , FIFO_Empty => sts2_queue_empty , FIFO_Full => sts2_queue_full , Addr => open ); end generate APP_UPDATE; NO_APP_UPDATE: if C_SG2_WORDS_TO_UPDATE = 1 generate begin process (m_axi_sg_aclk) begin if (m_axi_sg_aclk'event and m_axi_sg_aclk = '1') then if (sinit = '1') then sts2_queue_dout <= (others => '0'); elsif (sts2_queue_wren = '1') then sts2_queue_dout <= sts2_queue_din; end if; end if; end process; process (m_axi_sg_aclk) begin if (m_axi_sg_aclk'event and m_axi_sg_aclk = '1') then if (sinit = '1' or sts2_rden = '1') then sts2_queue_empty <= '1'; sts2_queue_full <= '0'; elsif (sts2_queue_wren = '1') then sts2_queue_empty <= '0'; sts2_queue_full <= '1'; end if; end if; end process; end generate NO_APP_UPDATE; -- Pointer Queue Update - Descriptor Pointer (32bits) -- i.e. 2 current descriptor pointers and any app fields ptr2_queue_din(C_S_AXIS_UPDPTR_TDATA_WIDTH-1 downto 0) <= s_axis2_updtptr_tdata( -- DESC DATA C_S_AXIS_UPDPTR_TDATA_WIDTH-1 downto 0); -- Data Queue Write Enable - based on tvalid and queue not full ptr2_queue_wren <= s_axis2_updtptr_tvalid -- TValid and not ptr2_queue_full; -- Data Queue NOT Full -- Drive channel port with ready if room in data queue s_axis2_updtptr_tready <= not ptr2_queue_full; --************************************* -- Channel Status Port Side of Queues --*************************************** -- Status Queue Update - TLAST(1bit) & Includes IOC(1bit) & Descriptor Status(32bits) -- Note: Type field is stripped off sts2_queue_din(C_S_AXIS_UPDSTS_TDATA_WIDTH) <= s_axis2_updtsts_tlast; -- Store with tlast sts2_queue_din(C_S_AXIS_UPDSTS_TDATA_WIDTH-1 downto 0) <= s_axis2_updtsts_tdata( -- IOC & DESC STS C_S_AXIS_UPDSTS_TDATA_WIDTH-1 downto 0); -- Status Queue Write Enable - based on tvalid and queue not full sts2_queue_wren <= s_axis2_updtsts_tvalid and not sts2_queue_full; -- Drive channel port with ready if room in status queue s_axis2_updtsts_tready <= not sts2_queue_full; --********************************* -- SG Engine Side of Queues --*********************************** -- Indicate NOT empty if both status queue and data queue are not empty updt2_queue_empty <= ptr2_queue_empty or follower_empty_s2mm; --or (sts2_queue_empty and follower_empty and updt2_active); -- Data queue read enable ptr2_queue_rden <= '1' when dataq_rden = '1' -- Cur desc read enable and ptr2_queue_empty = '0' -- Data Queue NOT empty and updt2_active = '1' else '0'; -- Status queue read enable sts2_queue_rden <= '1' when stsq_rden = '1' -- Writing desc status and sts2_queue_empty = '0' -- Status fifo NOT empty and updt2_active = '1' else '0'; end generate S2MM_CHANNEL; NO_S2MM_CHANNEL : if C_INCLUDE_S2MM = 0 generate begin updt_active_re2 <= '0'; updt2_queue_empty <= '0'; s_axis2_updtptr_tready <= '0'; s_axis2_updtsts_tready <= '0'; sts2_queue_dout <= (others => '0'); sts2_queue_full <= '0'; sts2_queue_empty <= '0'; ptr2_queue_dout <= (others => '0'); ptr2_queue_empty <= '0'; ptr2_queue_full <= '0'; end generate NO_S2MM_CHANNEL; end generate GEN_Q_FOR_SYNC; -- FIFO Reset is active high sinit <= not m_axi_sg_aresetn; -- LSB_PROC : process(m_axi_sg_aclk) -- begin -- if(m_axi_sg_aclk'EVENT and m_axi_sg_aclk = '1')then -- if(m_axi_sg_aresetn = '0' )then -- write_curdesc_lsb <= '0'; -- -- Capture lower pointer from FIFO or channel port -- else -- if(write_curdesc_lsb = '1' and updt_active_int = '1')then write_curdesc_lsb <= write_curdesc_lsb_sm; -- end if; -- end if; -- end process LSB_PROC; --***************************************************************** -- POINTER CAPTURE LOGIC --******************************************************************* ptr_queue_dout_int <= ptr2_queue_dout when (updt2_active = '1') else ptr_queue_dout; --------------------------------------------------------------------------- -- Write lower order Next Descriptor Pointer out to pntr_mngr --------------------------------------------------------------------------- updt_active_int <= updt_active or updt2_active; REG_LSB_CURPNTR : process(m_axi_sg_aclk) begin if(m_axi_sg_aclk'EVENT and m_axi_sg_aclk = '1')then if(m_axi_sg_aresetn = '0' )then updt_curdesc(31 downto 0) <= (others => '0'); -- Capture lower pointer from FIFO or channel port elsif(write_curdesc_lsb = '1' and updt_active_int = '1')then updt_curdesc(31 downto 0) <= ptr_queue_dout_int(C_S_AXIS_UPDPTR_TDATA_WIDTH-1 downto 0); end if; end if; end process REG_LSB_CURPNTR; --------------------------------------------------------------------------- -- 64 Bit Scatter Gather addresses enabled --------------------------------------------------------------------------- GEN_UPPER_MSB_CURDESC : if C_M_AXI_SG_ADDR_WIDTH = 64 generate begin --------------------------------------------------------------------------- -- Write upper order Next Descriptor Pointer out to pntr_mngr --------------------------------------------------------------------------- REG_MSB_CURPNTR : process(m_axi_sg_aclk) begin if(m_axi_sg_aclk'EVENT and m_axi_sg_aclk = '1')then if(m_axi_sg_aresetn = '0' )then updt_curdesc(63 downto 32) <= (others => '0'); updt_curdesc_wren <= '0'; -- Capture upper pointer from FIFO or channel port -- and also write curdesc out elsif(write_curdesc_msb = '1' and updt_active_int = '1')then updt_curdesc(63 downto 32) <= ptr_queue_dout_int(C_S_AXIS_UPDPTR_TDATA_WIDTH-1 downto 0); updt_curdesc_wren <= '1'; -- Assert tready/wren for only 1 clock else updt_curdesc_wren <= '0'; end if; end if; end process REG_MSB_CURPNTR; end generate GEN_UPPER_MSB_CURDESC; --------------------------------------------------------------------------- -- 32 Bit Scatter Gather addresses enabled --------------------------------------------------------------------------- GEN_NO_UPR_MSB_CURDESC : if C_M_AXI_SG_ADDR_WIDTH = 32 generate begin ----------------------------------------------------------------------- -- No upper order therefore dump fetched word and write pntr lower next -- pointer to pntr mngr ----------------------------------------------------------------------- REG_MSB_CURPNTR : process(m_axi_sg_aclk) begin if(m_axi_sg_aclk'EVENT and m_axi_sg_aclk = '1')then if(m_axi_sg_aresetn = '0' )then updt_curdesc_wren <= '0'; -- Throw away second word, only write curdesc out with msb -- set to zero elsif(write_curdesc_lsb = '1' and updt_active_int = '1')then --elsif(write_curdesc_msb = '1' and updt_active_int = '1')then updt_curdesc_wren <= '1'; -- Assert for only 1 clock else updt_curdesc_wren <= '0'; end if; end if; end process REG_MSB_CURPNTR; end generate GEN_NO_UPR_MSB_CURDESC; --***************************************************************** -- ERROR CAPTURE LOGIC --********************************************************************* ----------------------------------------------------------------------- -- Generate rising edge pulse on writing status signal. This will -- assert at the beginning of the status write. Coupled with status -- fifo set to first word fall through status will be on dout -- regardless of target ready. ----------------------------------------------------------------------- REG_WRITE_STATUS : process(m_axi_sg_aclk) begin if(m_axi_sg_aclk'EVENT and m_axi_sg_aclk = '1')then if(m_axi_sg_aresetn = '0')then writing_status_d1 <= '0'; else writing_status_d1 <= writing_status; end if; end if; end process REG_WRITE_STATUS; writing_status_re <= writing_status and not writing_status_d1; writing_status_re_ch1 <= writing_status_re and updt_active; writing_status_re_ch2 <= writing_status_re and updt2_active; ----------------------------------------------------------------------- -- Caputure IOC begin set ----------------------------------------------------------------------- REG_IOC_PROCESS : process(m_axi_sg_aclk) begin if(m_axi_sg_aclk'EVENT and m_axi_sg_aclk = '1')then if(m_axi_sg_aresetn = '0' or updt_ioc_irq_set = '1')then updt_ioc <= '0'; elsif(writing_status_re_ch1 = '1')then -- updt_ioc <= sts_queue_dout(DESC_IOC_TAG_BIT) and updt_active; updt_ioc <= follower_reg_mm2s(DESC_IOC_TAG_BIT); end if; end if; end process REG_IOC_PROCESS; ----------------------------------------------------------------------- -- Capture DMA Internal Errors ----------------------------------------------------------------------- CAPTURE_DMAINT_ERROR: process(m_axi_sg_aclk) begin if(m_axi_sg_aclk'EVENT and m_axi_sg_aclk = '1')then if(m_axi_sg_aresetn = '0' or dma_interr_set = '1')then dma_interr <= '0'; elsif(writing_status_re_ch1 = '1')then --dma_interr <= sts_queue_dout(DESC_STS_INTERR_BIT) and updt_active; dma_interr <= follower_reg_mm2s(DESC_STS_INTERR_BIT); end if; end if; end process CAPTURE_DMAINT_ERROR; ----------------------------------------------------------------------- -- Capture DMA Slave Errors ----------------------------------------------------------------------- CAPTURE_DMASLV_ERROR: process(m_axi_sg_aclk) begin if(m_axi_sg_aclk'EVENT and m_axi_sg_aclk = '1')then if(m_axi_sg_aresetn = '0' or dma_slverr_set = '1')then dma_slverr <= '0'; elsif(writing_status_re_ch1 = '1')then -- dma_slverr <= sts_queue_dout(DESC_STS_SLVERR_BIT) and updt_active; dma_slverr <= follower_reg_mm2s(DESC_STS_SLVERR_BIT); end if; end if; end process CAPTURE_DMASLV_ERROR; ----------------------------------------------------------------------- -- Capture DMA Decode Errors ----------------------------------------------------------------------- CAPTURE_DMADEC_ERROR: process(m_axi_sg_aclk) begin if(m_axi_sg_aclk'EVENT and m_axi_sg_aclk = '1')then if(m_axi_sg_aresetn = '0' or dma_decerr_set = '1')then dma_decerr <= '0'; elsif(writing_status_re_ch1 = '1')then -- dma_decerr <= sts_queue_dout(DESC_STS_DECERR_BIT) and updt_active; dma_decerr <= follower_reg_mm2s(DESC_STS_DECERR_BIT); end if; end if; end process CAPTURE_DMADEC_ERROR; ----------------------------------------------------------------------- -- Caputure IOC begin set ----------------------------------------------------------------------- REG_IOC2_PROCESS : process(m_axi_sg_aclk) begin if(m_axi_sg_aclk'EVENT and m_axi_sg_aclk = '1')then if(m_axi_sg_aresetn = '0' or updt2_ioc_irq_set = '1')then updt2_ioc <= '0'; elsif(writing_status_re_ch2 = '1')then -- updt2_ioc <= sts2_queue_dout(DESC_IOC_TAG_BIT) and updt2_active; updt2_ioc <= follower_reg_s2mm(DESC_IOC_TAG_BIT); end if; end if; end process REG_IOC2_PROCESS; ----------------------------------------------------------------------- -- Capture DMA Internal Errors ----------------------------------------------------------------------- CAPTURE_DMAINT2_ERROR: process(m_axi_sg_aclk) begin if(m_axi_sg_aclk'EVENT and m_axi_sg_aclk = '1')then if(m_axi_sg_aresetn = '0' or dma2_interr_set = '1')then dma2_interr <= '0'; elsif(writing_status_re_ch2 = '1')then -- dma2_interr <= sts2_queue_dout(DESC_STS_INTERR_BIT) and updt2_active; dma2_interr <= follower_reg_s2mm (DESC_STS_INTERR_BIT); end if; end if; end process CAPTURE_DMAINT2_ERROR; ----------------------------------------------------------------------- -- Capture DMA Slave Errors ----------------------------------------------------------------------- CAPTURE_DMASLV2_ERROR: process(m_axi_sg_aclk) begin if(m_axi_sg_aclk'EVENT and m_axi_sg_aclk = '1')then if(m_axi_sg_aresetn = '0' or dma2_slverr_set = '1')then dma2_slverr <= '0'; elsif(writing_status_re_ch2 = '1')then -- dma2_slverr <= sts2_queue_dout(DESC_STS_SLVERR_BIT) and updt2_active; dma2_slverr <= follower_reg_s2mm(DESC_STS_SLVERR_BIT); end if; end if; end process CAPTURE_DMASLV2_ERROR; ----------------------------------------------------------------------- -- Capture DMA Decode Errors ----------------------------------------------------------------------- CAPTURE_DMADEC2_ERROR: process(m_axi_sg_aclk) begin if(m_axi_sg_aclk'EVENT and m_axi_sg_aclk = '1')then if(m_axi_sg_aresetn = '0' or dma2_decerr_set = '1')then dma2_decerr <= '0'; elsif(writing_status_re_ch2 = '1')then -- dma2_decerr <= sts2_queue_dout(DESC_STS_DECERR_BIT) and updt2_active; dma2_decerr <= follower_reg_s2mm(DESC_STS_DECERR_BIT); end if; end if; end process CAPTURE_DMADEC2_ERROR; end implementation;	gpl-3.0	d9b76d8b94797ff9db15832593634ecb	0.433834	4.277416	false	false	false	false
laurocruz/snakes_vhdl	src/snake_lib/snake_pack.vhd	1	2,402	LIBRARY ieee; USE ieee.std_logic_1164.all; USE ieee.math_real.all; PACKAGE snake_pack IS --TYPE int_s IS INTEGER RANGE -20 TO 255; TYPE int_array IS array (0 to 127) OF INTEGER RANGE -20 TO 255; COMPONENT conv_7seg IS PORT (digit : IN STD_LOGIC_VECTOR(3 DOWNTO 0) ; seg : OUT STD_LOGIC_VECTOR(6 DOWNTO 0) ) ; END COMPONENT; COMPONENT create_food IS -- Altura e comprimento do mapa GENERIC (N : INTEGER := 10; M : INTEGER := 10; width : INTEGER := 6); PORT (reset : IN STD_LOGIC; eaten : IN STD_LOGIC; gmap : IN STD_LOGIC_VECTOR(0 TO NM-1); new_food : OUT INTEGER RANGE 0 TO NM-1); END COMPONENT; COMPONENT gclock IS -- Frequencia de 1Hz -- clock do hardware PORT (CLOCK_27 : IN STD_LOGIC ; reset : IN STD_LOGIC ; clock_out : OUT STD_LOGIC) ; END COMPONENT; COMPONENT make_map IS -- DImensões do mapa GENERIC (N : INTEGER := 10; M : INTEGER := 10; INITIAL_SIZE : INTEGER := 2); -- clock do jogo PORT (clock : IN STD_LOGIC; -- reseta o jogo reset : IN STD_LOGIC; -- aumento do tamanho eaten : IN STD_LOGIC; snake_size : IN INTEGER RANGE 0 TO NM; -- direcao para onde a cobra esta se movendo -- 11 : cima -- 00 : baixo -- 10 : esquerda -- 01 : direita dir : IN STD_LOGIC_VECTOR(1 DOWNTO 0); -- posicoes da cobra no mapa snake_body : OUT int_array); END COMPONENT; COMPONENT size_counter IS -- DImensões do mapa GENERIC (N : INTEGER := 10; M : INTEGER := 10; INITIAL_SIZE : INTEGER := 2); PORT (reset : IN STD_LOGIC; food_pos : IN INTEGER RANGE -20 TO 255; --food_pos : IN INTEGER RANGE 0 TO NM-1; snake_head : IN INTEGER RANGE -20 TO 255; snake_size : OUT INTEGER RANGE 0 TO NM; eaten : OUT STD_LOGIC); END COMPONENT; COMPONENT colision IS -- Dimensoes do mapa GENERIC (N : INTEGER := 10; M : INTEGER := 10); PORT (snake_body : IN int_array; dir : IN STD_LOGIC_VECTOR(1 DOWNTO 0); reset : IN STD_LOGIC; gmap : OUT STD_LOGIC_VECTOR(0 to NM-1); lost : OUT STD_LOGIC); END COMPONENT ; COMPONENT snake_dir IS PORT (reset : IN STD_LOGIC; snake_turn : IN STD_LOGIC_VECTOR(1 downto 0); dir : BUFFER STD_LOGIC_VECTOR(0 to 1)); END COMPONENT; END snake_pack;	mit	a8b2d5bc443f1aa2e8a0963a5fdcf925	0.592083	3.137255	false	false	false	false
marco-c/leon-nexys2	grlib-gpl-1.3.4-b4140/lib/gaisler/leon3v3/leon3x.vhd	1	9,494	------------------------------------------------------------------------------ -- This file is a part of the GRLIB VHDL IP LIBRARY -- Copyright (C) 2003 - 2008, Gaisler Research -- Copyright (C) 2008 - 2013, Aeroflex Gaisler -- -- This program is free software; you can redistribute it and/or modify -- it under the terms of the GNU General Public License as published by -- the Free Software Foundation; either version 2 of the License, or -- (at your option) any later version. -- -- This program is distributed in the hope that it will be useful, -- but WITHOUT ANY WARRANTY; without even the implied warranty of -- MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the -- GNU General Public License for more details. -- -- You should have received a copy of the GNU General Public License -- along with this program; if not, write to the Free Software -- Foundation, Inc., 59 Temple Place, Suite 330, Boston, MA 02111-1307 USA ------------------------------------------------------------------------------ -- Entity: leon3x -- File: leon3x.vhd -- Author: Jiri Gaisler, Jan Andersson, Aeroflex Gaisler -- Description: Top-level LEON3v3 component with all options ------------------------------------------------------------------------------ library ieee; use ieee.std_logic_1164.all; library grlib; use grlib.amba.all; use grlib.stdlib.all; library techmap; use techmap.gencomp.all; use techmap.netcomp.all; library gaisler; use gaisler.leon3.all; use gaisler.libiu.all; use gaisler.libcache.all; use gaisler.libleon3.all; use gaisler.libfpu.all; use gaisler.arith.all; entity leon3x is generic ( hindex : integer := 0; fabtech : integer range 0 to NTECH := DEFFABTECH; memtech : integer range 0 to NTECH := DEFMEMTECH; nwindows : integer range 2 to 32 := 8; dsu : integer range 0 to 1 := 0; fpu : integer range 0 to 63 := 0; v8 : integer range 0 to 63 := 0; cp : integer range 0 to 1 := 0; mac : integer range 0 to 1 := 0; pclow : integer range 0 to 2 := 2; notag : integer range 0 to 1 := 0; nwp : integer range 0 to 4 := 0; icen : integer range 0 to 1 := 0; irepl : integer range 0 to 3 := 2; isets : integer range 1 to 4 := 1; ilinesize : integer range 4 to 8 := 4; isetsize : integer range 1 to 256 := 1; isetlock : integer range 0 to 1 := 0; dcen : integer range 0 to 1 := 0; drepl : integer range 0 to 3 := 2; dsets : integer range 1 to 4 := 1; dlinesize : integer range 4 to 8 := 4; dsetsize : integer range 1 to 256 := 1; dsetlock : integer range 0 to 1 := 0; dsnoop : integer range 0 to 6 := 0; ilram : integer range 0 to 1 := 0; ilramsize : integer range 1 to 512 := 1; ilramstart : integer range 0 to 255 := 16#8e#; dlram : integer range 0 to 1 := 0; dlramsize : integer range 1 to 512 := 1; dlramstart : integer range 0 to 255 := 16#8f#; mmuen : integer range 0 to 1 := 0; itlbnum : integer range 2 to 64 := 8; dtlbnum : integer range 2 to 64 := 8; tlb_type : integer range 0 to 3 := 1; tlb_rep : integer range 0 to 1 := 0; lddel : integer range 1 to 2 := 2; disas : integer range 0 to 2 := 0; tbuf : integer range 0 to 64 := 0; pwd : integer range 0 to 2 := 2; svt : integer range 0 to 1 := 1; rstaddr : integer := 0; smp : integer range 0 to 15 := 0; iuft : integer range 0 to 4 := 0; fpft : integer range 0 to 4 := 0; cmft : integer range 0 to 1 := 0; iuinj : integer := 0; ceinj : integer range 0 to 3 := 0; cached : integer := 0; clk2x : integer := 1; netlist : integer := 0; scantest : integer := 0; mmupgsz : integer range 0 to 5 := 0; bp : integer := 1 ); port ( clk : in std_ulogic; -- free-running clock gclk2 : in std_ulogic; -- gated 2x clock gfclk2 : in std_ulogic; -- gated 2x FPU clock clk2 : in std_ulogic; -- free-running 2x clock rstn : in std_ulogic; ahbi : in ahb_mst_in_type; ahbo : out ahb_mst_out_type; ahbsi : in ahb_slv_in_type; ahbso : in ahb_slv_out_vector; irqi : in l3_irq_in_type; irqo : out l3_irq_out_type; dbgi : in l3_debug_in_type; dbgo : out l3_debug_out_type; fpui : out grfpu_in_type; fpuo : in grfpu_out_type; clken : in std_ulogic ); end; architecture rtl of leon3x is constant IRFBITS : integer range 6 to 10 := log2(NWINDOWS+1) + 4; constant IREGNUM : integer := NWINDOWS * 16 + 8; constant IRFWT : integer := 1;--regfile_3p_write_through(memtech); constant fpuarch : integer := fpu mod 16; constant fpunet : integer := (fpu mod 32) / 16; constant fpushared : boolean := (fpu / 32) /= 0; signal holdn : std_logic; signal rfi : iregfile_in_type; signal rfo : iregfile_out_type; signal crami : cram_in_type; signal cramo : cram_out_type; signal tbi : tracebuf_in_type; signal tbo : tracebuf_out_type; signal rst : std_ulogic; signal fpi : fpc_in_type; signal fpo : fpc_out_type; signal cpi : fpc_in_type; signal cpo : fpc_out_type; signal gnd, vcc : std_logic; attribute sync_set_reset : string; attribute sync_set_reset of rst : signal is "true"; begin gnd <= '0'; vcc <= '1'; -- leon3 processor core (iu, caches & mul/div) p0 : proc3 generic map ( hindex, fabtech, memtech, nwindows, dsu, fpuarch, v8, cp, mac, pclow, notag, nwp, icen, irepl, isets, ilinesize, isetsize, isetlock, dcen, drepl, dsets, dlinesize, dsetsize, dsetlock, dsnoop, ilram, ilramsize, ilramstart, dlram, dlramsize, dlramstart, mmuen, itlbnum, dtlbnum, tlb_type, tlb_rep, lddel, disas, tbuf, pwd, svt, rstaddr, smp, cached, clk2x, scantest, mmupgsz, bp) port map (gclk2, rst, holdn, ahbi, ahbo, ahbsi, ahbso, rfi, rfo, crami, cramo, tbi, tbo, fpi, fpo, cpi, cpo, irqi, irqo, dbgi, dbgo, clk, clk2, clken); -- IU register file rf0 : regfile_3p_l3 generic map (memtech, IRFBITS, 32, IRFWT, IREGNUM, scantest) port map (gclk2, rfi.waddr(IRFBITS-1 downto 0), rfi.wdata, rfi.wren, gclk2, rfi.raddr1(IRFBITS-1 downto 0), rfi.ren1, rfo.data1, rfi.raddr2(IRFBITS-1 downto 0), rfi.ren2, rfo.data2, rfi.diag ); -- cache memory cmem0 : cachemem generic map (memtech, icen, irepl, isets, ilinesize, isetsize, isetlock, dcen, drepl, dsets, dlinesize, dsetsize, dsetlock, dsnoop, ilram, ilramsize, dlram, dlramsize, mmuen, scantest ) port map (gclk2, crami, cramo, clk2); -- instruction trace buffer memory tbmem_gen : if (tbuf /= 0) generate tbmem0 : tbufmem generic map (memtech, tbuf, scantest) port map (gclk2, tbi, tbo); end generate; -- FPU fpu0 : if (fpu = 0) generate fpo <= fpc_out_none; end generate; fpshare : if fpushared generate grfpw0gen : if (fpuarch > 0) and (fpuarch < 8) generate fpu0: grfpwxsh generic map (memtech, pclow, dsu, disas, hindex ) port map (rst, gclk2, holdn, fpi, fpo, fpui, fpuo); end generate; nogrfpw0gen : if not ((fpuarch > 0) and (fpuarch < 8)) generate fpui <= grfpu_in_none; end generate; end generate; nofpshare : if not fpushared generate grfpw1gen : if (fpuarch > 0) and (fpuarch < 8) generate fpu0: grfpwx generic map (fabtech, memtech, (fpuarch-1), pclow, dsu, disas, fpunet, hindex) port map (rst, gfclk2, holdn, fpi, fpo); end generate; mfpw1gen : if (fpuarch = 15) generate fpu0 : mfpwx generic map (memtech, pclow, dsu, disas ) port map (rst, gfclk2, holdn, fpi, fpo); end generate; grlfpc1gen : if (fpuarch >=8) and (fpuarch < 15) generate fpu0 : grlfpwx generic map (memtech, pclow, dsu, disas, (fpuarch-8), fpunet, hindex) port map (rst, gfclk2, holdn, fpi, fpo); end generate; fpui <= grfpu_in_none; end generate; -- CP cpo <= fpc_out_none; -- 1-clock reset delay rstreg : process(gclk2) begin if rising_edge(gclk2) then rst <= rstn; end if; end process; -- pragma translate_off bootmsg : report_version generic map ( "leon3_" & tost(hindex) & ": LEON3 SPARC V8 processor rev " & tost(LEON3_VERSION) , "leon3_" & tost(hindex) & ": icache " & tost(isetsicen) & "" & tost(isetsizeicen) & " kbyte, dcache " & tost(dsetsdcen) & "" & tost(dsetsizedcen) & " kbyte" ); -- pragma translate_on end;	gpl-2.0	c33522c587c113e9d4c1b2da8b7e0df5	0.545818	3.651538	false	false	false	false
mistryalok/Zedboard	learning/opencv_hls/xapp1167_vivado/sw/fast-corner/prj/solution1/syn/vhdl/FIFO_image_filter_dmask_rows_V.vhd	2	4,564	-- ============================================================== -- File generated by Vivado(TM) HLS - High-Level Synthesis from C, C++ and SystemC -- Version: 2014.4 -- Copyright (C) 2014 Xilinx Inc. All rights reserved. -- -- ============================================================== library IEEE; use IEEE.std_logic_1164.all; use IEEE.std_logic_unsigned.all; entity FIFO_image_filter_dmask_rows_V_shiftReg is generic ( DATA_WIDTH : integer := 12; ADDR_WIDTH : integer := 2; DEPTH : integer := 3); port ( clk : in std_logic; data : in std_logic_vector(DATA_WIDTH-1 downto 0); ce : in std_logic; a : in std_logic_vector(ADDR_WIDTH-1 downto 0); q : out std_logic_vector(DATA_WIDTH-1 downto 0)); end FIFO_image_filter_dmask_rows_V_shiftReg; architecture rtl of FIFO_image_filter_dmask_rows_V_shiftReg is --constant DEPTH_WIDTH: integer := 16; type SRL_ARRAY is array (0 to DEPTH-1) of std_logic_vector(DATA_WIDTH-1 downto 0); signal SRL_SIG : SRL_ARRAY; begin p_shift: process (clk) begin if (clk'event and clk = '1') then if (ce = '1') then SRL_SIG <= data & SRL_SIG(0 to DEPTH-2); end if; end if; end process; q <= SRL_SIG(conv_integer(a)); end rtl; library ieee; use ieee.std_logic_1164.all; use ieee.std_logic_unsigned.all; entity FIFO_image_filter_dmask_rows_V is generic ( MEM_STYLE : string := "shiftreg"; DATA_WIDTH : integer := 12; ADDR_WIDTH : integer := 2; DEPTH : integer := 3); port ( clk : IN STD_LOGIC; reset : IN STD_LOGIC; if_empty_n : OUT STD_LOGIC; if_read_ce : IN STD_LOGIC; if_read : IN STD_LOGIC; if_dout : OUT STD_LOGIC_VECTOR(DATA_WIDTH - 1 downto 0); if_full_n : OUT STD_LOGIC; if_write_ce : IN STD_LOGIC; if_write : IN STD_LOGIC; if_din : IN STD_LOGIC_VECTOR(DATA_WIDTH - 1 downto 0)); end entity; architecture rtl of FIFO_image_filter_dmask_rows_V is component FIFO_image_filter_dmask_rows_V_shiftReg is generic ( DATA_WIDTH : integer := 12; ADDR_WIDTH : integer := 2; DEPTH : integer := 3); port ( clk : in std_logic; data : in std_logic_vector(DATA_WIDTH-1 downto 0); ce : in std_logic; a : in std_logic_vector(ADDR_WIDTH-1 downto 0); q : out std_logic_vector(DATA_WIDTH-1 downto 0)); end component; signal shiftReg_addr : STD_LOGIC_VECTOR(ADDR_WIDTH - 1 downto 0); signal shiftReg_data, shiftReg_q : STD_LOGIC_VECTOR(DATA_WIDTH - 1 downto 0); signal shiftReg_ce : STD_LOGIC; signal mOutPtr : STD_LOGIC_VECTOR(ADDR_WIDTH downto 0) := (others => '1'); signal internal_empty_n : STD_LOGIC := '0'; signal internal_full_n : STD_LOGIC := '1'; begin if_empty_n <= internal_empty_n; if_full_n <= internal_full_n; shiftReg_data <= if_din; if_dout <= shiftReg_q; process (clk) begin if clk'event and clk = '1' then if reset = '1' then mOutPtr <= (others => '1'); internal_empty_n <= '0'; internal_full_n <= '1'; else if ((if_read and if_read_ce) = '1' and internal_empty_n = '1') and ((if_write and if_write_ce) = '0' or internal_full_n = '0') then mOutPtr <= mOutPtr -1; if (mOutPtr = 0) then internal_empty_n <= '0'; end if; internal_full_n <= '1'; elsif ((if_read and if_read_ce) = '0' or internal_empty_n = '0') and ((if_write and if_write_ce) = '1' and internal_full_n = '1') then mOutPtr <= mOutPtr +1; internal_empty_n <= '1'; if (mOutPtr = DEPTH -2) then internal_full_n <= '0'; end if; end if; end if; end if; end process; shiftReg_addr <= (others => '0') when mOutPtr(ADDR_WIDTH) = '1' else mOutPtr(ADDR_WIDTH-1 downto 0); shiftReg_ce <= (if_write and if_write_ce) and internal_full_n; U_FIFO_image_filter_dmask_rows_V_shiftReg : FIFO_image_filter_dmask_rows_V_shiftReg generic map ( DATA_WIDTH => DATA_WIDTH, ADDR_WIDTH => ADDR_WIDTH, DEPTH => DEPTH) port map ( clk => clk, data => shiftReg_data, ce => shiftReg_ce, a => shiftReg_addr, q => shiftReg_q); end rtl;	gpl-3.0	3fb169d8ab8ec045492127b1db970526	0.536372	3.505376	false	false	false	false
capitanov/Stupid_watch	src/rtl/pwm_test/ctrl_led8x8_heart.vhd	1	3,940	------------------------------------------------------------------------------- -- -- Title : ctrl_led8x8_heart -- Author : Alexander Kapitanov -- Company : Instrumental Systems -- E-mail : [email protected] -- -- Version : 1.0 -- ------------------------------------------------------------------------------- -- -- Description : Controller for LED Matrix -- ------------------------------------------------------------------------------- library ieee; use ieee.std_logic_1164.all; use ieee.std_logic_arith.all; use ieee.std_logic_unsigned.all; entity ctrl_led8x8_heart is port ( clk : in std_logic; --! clock rst : in std_logic; --! reset rst_reg : in std_logic; --! count reset ch_freq : in std_logic; --! change frequency led_y : out std_logic_vector(7 downto 0); --! LED Y led_x : out std_logic_vector(7 downto 0) --! LED X ); end ctrl_led8x8_heart; architecture ctr_led8x8 of ctrl_led8x8_heart is constant Nled : integer:=12; -- 12 signal cnt_led : std_logic_vector(Nled downto 0); signal cnt_cmd : std_logic_vector(2 downto 0); signal led_cmd : std_logic_vector(3 downto 0); signal data_led : std_logic_vector(7 downto 0); signal en_xhdl : std_logic_vector(7 downto 0); signal ch_freqz : std_logic; signal ch_freqx : std_logic; signal case_cnt : std_logic_vector(1 downto 0); begin ch_freqz <= ch_freq after 1 ns when rising_edge(clk); ch_freqx <= ch_freq and not ch_freqz when rising_edge(clk); led_y <= data_led; led_x <= en_xhdl; pr_case: process(clk, rst) is begin if rst = '0' then case_cnt <= (others => '0'); elsif rising_edge(clk) then -- if rst_reg = '0' then -- case_cnt <= (others => '0'); -- elsif ch_freqx = '1' then -- case_cnt <= case_cnt + '1'; -- else -- null; -- end if; if ch_freqx = '1' then case_cnt <= case_cnt + '1'; else null; end if; end if; end process; pr_cnt: process(clk, rst) is begin if rst = '0' then cnt_led <= (others => '0'); elsif rising_edge(clk) then if rst_reg = '0' then cnt_led <= (others => '0'); else case case_cnt is when "00" => cnt_led <= cnt_led + '1'; when "01" => cnt_led <= cnt_led + "10"; when "10" => cnt_led <= cnt_led + "11"; when others => cnt_led <= cnt_led + "100"; end case; end if; end if; end process; cnt_cmd <= cnt_led(Nled downto Nled-2); pr_3x8: process(cnt_cmd) is begin case cnt_cmd is when "000" => en_xhdl <= "11111110"; when "001" => en_xhdl <= "11111101"; when "010" => en_xhdl <= "11111011"; when "011" => en_xhdl <= "11110111"; when "100" => en_xhdl <= "11101111"; when "101" => en_xhdl <= "11011111"; when "110" => en_xhdl <= "10111111"; when "111" => en_xhdl <= "01111111"; when others => en_xhdl <= "11111110"; end case; end process; pr_8x4: process(en_xhdl) is begin case en_xhdl is when "11111110" => led_cmd <= "0000"; when "11111101" => led_cmd <= "0001"; when "11111011" => led_cmd <= "0010"; when "11110111" => led_cmd <= "0011"; when "11101111" => led_cmd <= "0100"; when "11011111" => led_cmd <= "0101"; when "10111111" => led_cmd <= "0110"; when "01111111" => led_cmd <= "0111"; when others => led_cmd <= "1000"; end case; end process; pr_4x8: process(led_cmd) is begin case led_cmd is when "0000" => data_led <= "11111111"; when "0001" => data_led <= "11100111"; when "0010" => data_led <= "11011011"; when "0011" => data_led <= "10111101"; when "0100" => data_led <= "01111110"; when "0101" => data_led <= "01100110"; when "0110" => data_led <= "10011001"; when "0111" => data_led <= "11111111"; when others => data_led <= "11111111"; end case; end process; end ctr_led8x8;	mit	156f237b05a6f1a94777b462ae738bd9	0.523604	2.730423	false	false	false	false

marco-c/leon-nexys2

grlib-gpl-1.3.4-b4140/designs/leon3-digilent-xc3s1600e/config.vhd

1

6,040

----------------------------------------------------------------------------- -- LEON3 Demonstration design test bench configuration -- Copyright (C) 2009 Aeroflex Gaisler ------------------------------------------------------------------------------ library techmap; use techmap.gencomp.all; package config is -- Technology and synthesis options constant CFG_FABTECH : integer := spartan3e; constant CFG_MEMTECH : integer := spartan3e; constant CFG_PADTECH : integer := spartan3e; constant CFG_NOASYNC : integer := 0; constant CFG_SCAN : integer := 0; -- Clock generator constant CFG_CLKTECH : integer := spartan3e; constant CFG_CLKMUL : integer := (4); constant CFG_CLKDIV : integer := (5); constant CFG_OCLKDIV : integer := 1; constant CFG_OCLKBDIV : integer := 0; constant CFG_OCLKCDIV : integer := 0; constant CFG_PCIDLL : integer := 0; constant CFG_PCISYSCLK: integer := 0; constant CFG_CLK_NOFB : integer := 0; -- LEON3 processor core constant CFG_LEON3 : integer := 1; constant CFG_NCPU : integer := (1); constant CFG_NWIN : integer := (8); constant CFG_V8 : integer := 2 + 4*0; constant CFG_MAC : integer := 0; constant CFG_BP : integer := 1; constant CFG_SVT : integer := 1; constant CFG_RSTADDR : integer := 16#00000#; constant CFG_LDDEL : integer := (1); constant CFG_NOTAG : integer := 1; constant CFG_NWP : integer := (2); constant CFG_PWD : integer := 1*2; constant CFG_FPU : integer := 0 + 16*0 + 32*0; constant CFG_GRFPUSH : integer := 0; constant CFG_ICEN : integer := 1; constant CFG_ISETS : integer := 2; constant CFG_ISETSZ : integer := 4; constant CFG_ILINE : integer := 8; constant CFG_IREPL : integer := 2; constant CFG_ILOCK : integer := 0; constant CFG_ILRAMEN : integer := 0; constant CFG_ILRAMADDR: integer := 16#8E#; constant CFG_ILRAMSZ : integer := 1; constant CFG_DCEN : integer := 1; constant CFG_DSETS : integer := 2; constant CFG_DSETSZ : integer := 4; constant CFG_DLINE : integer := 4; constant CFG_DREPL : integer := 2; constant CFG_DLOCK : integer := 0; constant CFG_DSNOOP : integer := 1 + 0 + 4*0; constant CFG_DFIXED : integer := 16#0#; constant CFG_DLRAMEN : integer := 0; constant CFG_DLRAMADDR: integer := 16#8F#; constant CFG_DLRAMSZ : integer := 1; constant CFG_MMUEN : integer := 1; constant CFG_ITLBNUM : integer := 8; constant CFG_DTLBNUM : integer := 8; constant CFG_TLB_TYPE : integer := 0 + 1*2; constant CFG_TLB_REP : integer := 0; constant CFG_MMU_PAGE : integer := 0; constant CFG_DSU : integer := 1; constant CFG_ITBSZ : integer := 4; constant CFG_ATBSZ : integer := 4; constant CFG_LEON3FT_EN : integer := 0; constant CFG_IUFT_EN : integer := 0; constant CFG_FPUFT_EN : integer := 0; constant CFG_RF_ERRINJ : integer := 0; constant CFG_CACHE_FT_EN : integer := 0; constant CFG_CACHE_ERRINJ : integer := 0; constant CFG_LEON3_NETLIST: integer := 0; constant CFG_DISAS : integer := 0 + 0; constant CFG_PCLOW : integer := 2; -- AMBA settings constant CFG_DEFMST : integer := (0); constant CFG_RROBIN : integer := 1; constant CFG_SPLIT : integer := 0; constant CFG_FPNPEN : integer := 0; constant CFG_AHBIO : integer := 16#FFF#; constant CFG_APBADDR : integer := 16#800#; constant CFG_AHB_MON : integer := 0; constant CFG_AHB_MONERR : integer := 0; constant CFG_AHB_MONWAR : integer := 0; constant CFG_AHB_DTRACE : integer := 0; -- DSU UART constant CFG_AHB_UART : integer := 1; -- JTAG based DSU interface constant CFG_AHB_JTAG : integer := 1; -- Ethernet DSU constant CFG_DSU_ETH : integer := 1 + 0 + 0; constant CFG_ETH_BUF : integer := 2; constant CFG_ETH_IPM : integer := 16#C0A8#; constant CFG_ETH_IPL : integer := 16#0033#; constant CFG_ETH_ENM : integer := 16#020000#; constant CFG_ETH_ENL : integer := 16#000018#; -- LEON2 memory controller constant CFG_MCTRL_LEON2 : integer := 1; constant CFG_MCTRL_RAM8BIT : integer := 0; constant CFG_MCTRL_RAM16BIT : integer := 1; constant CFG_MCTRL_5CS : integer := 0; constant CFG_MCTRL_SDEN : integer := 0; constant CFG_MCTRL_SEPBUS : integer := 0; constant CFG_MCTRL_INVCLK : integer := 0; constant CFG_MCTRL_SD64 : integer := 0; constant CFG_MCTRL_PAGE : integer := 0 + 0; -- DDR controller constant CFG_DDRSP : integer := 1; constant CFG_DDRSP_INIT : integer := 1; constant CFG_DDRSP_FREQ : integer := (90); constant CFG_DDRSP_COL : integer := (10); constant CFG_DDRSP_SIZE : integer := (64); constant CFG_DDRSP_RSKEW : integer := (40); -- AHB ROM constant CFG_AHBROMEN : integer := 0; constant CFG_AHBROPIP : integer := 0; constant CFG_AHBRODDR : integer := 16#000#; constant CFG_ROMADDR : integer := 16#000#; constant CFG_ROMMASK : integer := 16#E00# + 16#000#; -- AHB RAM constant CFG_AHBRAMEN : integer := 0; constant CFG_AHBRSZ : integer := 1; constant CFG_AHBRADDR : integer := 16#A00#; constant CFG_AHBRPIPE : integer := 0; -- Gaisler Ethernet core constant CFG_GRETH : integer := 1; constant CFG_GRETH1G : integer := 0; constant CFG_ETH_FIFO : integer := 32; -- UART 1 constant CFG_UART1_ENABLE : integer := 1; constant CFG_UART1_FIFO : integer := 8; -- LEON3 interrupt controller constant CFG_IRQ3_ENABLE : integer := 1; constant CFG_IRQ3_NSEC : integer := 0; -- Modular timer constant CFG_GPT_ENABLE : integer := 1; constant CFG_GPT_NTIM : integer := (2); constant CFG_GPT_SW : integer := (8); constant CFG_GPT_TW : integer := (32); constant CFG_GPT_IRQ : integer := (8); constant CFG_GPT_SEPIRQ : integer := 1; constant CFG_GPT_WDOGEN : integer := 0; constant CFG_GPT_WDOG : integer := 16#0#; -- GPIO port constant CFG_GRGPIO_ENABLE : integer := 1; constant CFG_GRGPIO_IMASK : integer := 16#0000#; constant CFG_GRGPIO_WIDTH : integer := (8); -- VGA and PS2/ interface constant CFG_KBD_ENABLE : integer := 1; constant CFG_VGA_ENABLE : integer := 0; constant CFG_SVGA_ENABLE : integer := 1; -- GRLIB debugging constant CFG_DUART : integer := 0; end;

gpl-2.0

a5a7209b77fbbdef297ec7e87d04493c

0.643709

3.616766

false

marco-c/leon-nexys2

grlib-gpl-1.3.4-b4140/lib/gaisler/leon3v3/tbufmem.vhd

1

2,221

------------------------------------------------------------------------------ -- This file is a part of the GRLIB VHDL IP LIBRARY -- Copyright (C) 2003 - 2008, Gaisler Research -- Copyright (C) 2008 - 2013, Aeroflex Gaisler -- -- This program is free software; you can redistribute it and/or modify -- it under the terms of the GNU General Public License as published by -- the Free Software Foundation; either version 2 of the License, or -- (at your option) any later version. -- -- This program is distributed in the hope that it will be useful, -- but WITHOUT ANY WARRANTY; without even the implied warranty of -- MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the -- GNU General Public License for more details. -- -- You should have received a copy of the GNU General Public License -- along with this program; if not, write to the Free Software -- Foundation, Inc., 59 Temple Place, Suite 330, Boston, MA 02111-1307 USA ----------------------------------------------------------------------------- -- Entity: tbufmem -- File: tbufmem.vhd -- Author: Jiri Gaisler - Gaisler Research -- Description: 128-bit trace buffer memory (CPU/AHB) ------------------------------------------------------------------------------ library ieee; use ieee.std_logic_1164.all; library gaisler; use gaisler.leon3.all; library techmap; use techmap.gencomp.all; library grlib; use grlib.stdlib.all; entity tbufmem is generic ( tech : integer := 0; tbuf : integer := 0; -- trace buf size in kB (0 - no trace buffer) testen : integer := 0 ); port ( clk : in std_ulogic; di : in tracebuf_in_type; do : out tracebuf_out_type); end; architecture rtl of tbufmem is constant ADDRBITS : integer := 10 + log2(tbuf) - 4; signal enable : std_logic_vector(1 downto 0); begin enable <= di.enable & di.enable; mem0 : for i in 0 to 1 generate ram0 : syncram64 generic map (tech => tech, abits => addrbits, testen => testen) port map ( clk, di.addr(addrbits-1 downto 0), di.data(((i*64)+63) downto (i*64)), do.data(((i*64)+63) downto (i*64)), enable ,di.write(i*2+1 downto i*2), di.diag); end generate; end;

gpl-2.0

0df27dfc6a8b3c71ca624c6125a25f65

0.60018

3.973166

false

marco-c/leon-nexys2

grlib-gpl-1.3.4-b4140/designs/leon3-altera-c5ekit/memifsim.vhd

1

12,367

------------------------------------------------------------------------------ -- This file is a part of the GRLIB VHDL IP LIBRARY -- Copyright (C) 2003 - 2008, Gaisler Research -- Copyright (C) 2008 - 2013, Aeroflex Gaisler -- -- This program is free software; you can redistribute it and/or modify -- it under the terms of the GNU General Public License as published by -- the Free Software Foundation; either version 2 of the License, or -- (at your option) any later version. -- -- This program is distributed in the hope that it will be useful, -- but WITHOUT ANY WARRANTY; without even the implied warranty of -- MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the -- GNU General Public License for more details. -- -- You should have received a copy of the GNU General Public License -- along with this program; if not, write to the Free Software -- Foundation, Inc., 59 Temple Place, Suite 330, Boston, MA 02111-1307 USA use std.textio.all; library ieee; use ieee.std_logic_1164.all; library grlib; use grlib.stdlib.all; use grlib.stdio.all; entity ddr3ctrl1 is port ( pll_ref_clk : in std_logic; global_reset_n : in std_logic; soft_reset_n : in std_logic; afi_clk : out std_logic; afi_half_clk : out std_logic; afi_reset_n : out std_logic; afi_reset_export_n : out std_logic; mem_a : out std_logic_vector(13 downto 0); mem_ba : out std_logic_vector(2 downto 0); mem_ck : out std_logic_vector(0 downto 0); mem_ck_n : out std_logic_vector(0 downto 0); mem_cke : out std_logic_vector(0 downto 0); mem_cs_n : out std_logic_vector(0 downto 0); mem_dm : out std_logic_vector(3 downto 0); mem_ras_n : out std_logic_vector(0 downto 0); mem_cas_n : out std_logic_vector(0 downto 0); mem_we_n : out std_logic_vector(0 downto 0); mem_reset_n : out std_logic; mem_dq : inout std_logic_vector(31 downto 0); mem_dqs : inout std_logic_vector(3 downto 0); mem_dqs_n : inout std_logic_vector(3 downto 0); mem_odt : out std_logic_vector(0 downto 0); avl_ready : out std_logic; avl_burstbegin : in std_logic; avl_addr : in std_logic_vector(24 downto 0); avl_rdata_valid : out std_logic; avl_rdata : out std_logic_vector(127 downto 0); avl_wdata : in std_logic_vector(127 downto 0); avl_be : in std_logic_vector(15 downto 0); avl_read_req : in std_logic; avl_write_req : in std_logic; avl_size : in std_logic_vector(2 downto 0); local_init_done : out std_logic; local_cal_success : out std_logic; local_cal_fail : out std_logic; oct_rzqin : in std_logic; pll_mem_clk : out std_logic; pll_write_clk : out std_logic; pll_write_clk_pre_phy_clk : out std_logic; pll_addr_cmd_clk : out std_logic; pll_locked : out std_logic; pll_avl_clk : out std_logic; pll_config_clk : out std_logic; pll_mem_phy_clk : out std_logic; afi_phy_clk : out std_logic; pll_avl_phy_clk : out std_logic ); end; architecture sim of ddr3ctrl1 is signal lafi_clk, lafi_rst_n: std_ulogic; signal lafi_half_clk: std_ulogic; begin afi_clk <= lafi_clk; afi_half_clk <= lafi_half_clk; afi_reset_n <= lafi_rst_n; mem_a <= (others => '0'); mem_ba <= (others => '0'); mem_ck <= (others => '0'); mem_ck_n <= (others => '1'); mem_cke <= (others => '0'); mem_cs_n <= (others => '1'); mem_dm <= (others => '0'); mem_ras_n <= (others => '1'); mem_cas_n <= (others => '1'); mem_we_n <= (others => '1'); mem_reset_n <= '0'; mem_dq <= (others => 'Z'); mem_dqs <= (others => 'Z'); mem_dqs_n <= (others => 'Z'); mem_odt <= (others => '0'); avl_ready <= '1'; local_init_done <= '1'; local_cal_success <= '1'; local_cal_fail <= '0'; pll_mem_clk <= '0'; pll_write_clk <= '0'; pll_write_clk_pre_phy_clk <= '0'; pll_addr_cmd_clk <= '0'; pll_locked <= '1'; pll_avl_clk <= '0'; pll_config_clk <= '0'; pll_mem_phy_clk <= '0'; afi_phy_clk <= '0'; pll_avl_phy_clk <= '0'; clkproc: process begin lafi_clk <= '0'; lafi_half_clk <= '0'; loop wait for 3.3 ns; lafi_clk <= not lafi_clk; if lafi_clk='0' then lafi_half_clk <= not lafi_half_clk; end if; end loop; end process; rstproc: process begin lafi_rst_n <= '0'; wait for 10 ns; loop if global_reset_n='0' then lafi_rst_n <= '0'; wait until global_reset_n/='0'; wait until rising_edge(lafi_clk); end if; lafi_rst_n <= '1'; wait until global_reset_n='0'; end loop; end process; avlproc: process subtype BYTE is std_logic_vector(7 downto 0); type MEM is array(0 to ((2**20)-1)) of BYTE; variable MEMA: MEM; procedure load_srec is file TCF : text open read_mode is "ram.srec"; variable L1: line; variable CH: character; variable ai: integer; variable rectype: std_logic_vector(3 downto 0); variable recaddr: std_logic_vector(31 downto 0); variable reclen: std_logic_vector(7 downto 0); variable recdata: std_logic_vector(0 to 16*8-1); variable len: integer; begin L1:= new string'(""); --' while not endfile(TCF) loop readline(TCF,L1); if (L1'length /= 0) then --' while (not (L1'length=0)) and (L1(L1'left) = ' ') loop std.textio.read(L1,CH); end loop; if L1'length > 0 then --' read(L1, ch); if (ch = 'S') or (ch = 's') then hread(L1, rectype); hread(L1, reclen); len := conv_integer(reclen)-1; recaddr := (others => '0'); case rectype is when "0001" => hread(L1, recaddr(15 downto 0)); len := len-2; when "0010" => hread(L1, recaddr(23 downto 0)); len := len-3; when "0011" => hread(L1, recaddr); len := len-4; when others => next; end case; hread(L1, recdata(0 to 8*len-1)); recaddr(31 downto 20) := (others => '0'); ai := conv_integer(recaddr); -- print("Setting " & tost(len) & "bytes at " & tost(recaddr)); for i in 0 to len-1 loop MEMA(ai+i) := recdata((i*8) to (i*8+7)); end loop; end if; end if; end if; end loop; end load_srec; constant avldbits: integer := 128; variable outqueue: std_logic_vector(0 to 4*avldbits-1) := (others => 'X'); variable outqueue_valid: std_logic_vector(0 to 3) := (others => '0'); variable ai,p: integer; variable wbleft: integer := 0; begin load_srec; loop wait until rising_edge(lafi_clk); avl_rdata_valid <= outqueue_valid(0); avl_rdata <= outqueue(0 to avldbits-1); outqueue(0 to 3*avldbits-1) := outqueue(avldbits to 4*avldbits-1); outqueue(3*avldbits to 4*avldbits-1) := (others => 'X'); outqueue_valid := outqueue_valid(1 to 3) & '0'; if avl_burstbegin='1' then wbleft:=0; end if; if lafi_rst_n='0' then outqueue_valid := (others => '0'); elsif avl_read_req='1' then ai := conv_integer(avl_addr(16 downto 0)); p := 0; while outqueue_valid(p)='1' loop p:=p+1; end loop; for x in 0 to conv_integer(avl_size)-1 loop for y in 0 to avldbits/8-1 loop outqueue((p+x)*avldbits+y*8 to (p+x)*avldbits+y*8+7) := MEMA((ai+x)*avldbits/8+y); end loop; outqueue_valid(p+x) := '1'; end loop; elsif avl_write_req='1' then if wbleft=0 then wbleft := conv_integer(avl_size); ai := conv_integer(avl_addr(16 downto 0)); end if; for y in 0 to avldbits/8-1 loop if avl_be(avldbits/8-1-y)='1' then MEMA(ai*avldbits/8+y) := avl_wdata(avldbits-8*y-1 downto avldbits-8*y-8); end if; end loop; wbleft := wbleft-1; ai := ai+1; end if; end loop; end process; end; library ieee; use ieee.std_logic_1164.all; entity lpddr2ctrl1 is port ( pll_ref_clk : in std_logic; global_reset_n : in std_logic; soft_reset_n : in std_logic; afi_clk : out std_logic; afi_half_clk : out std_logic; afi_reset_n : out std_logic; afi_reset_export_n : out std_logic; mem_ca : out std_logic_vector(9 downto 0); mem_ck : out std_logic_vector(0 downto 0); mem_ck_n : out std_logic_vector(0 downto 0); mem_cke : out std_logic_vector(0 downto 0); mem_cs_n : out std_logic_vector(0 downto 0); mem_dm : out std_logic_vector(1 downto 0); mem_dq : inout std_logic_vector(15 downto 0); mem_dqs : inout std_logic_vector(1 downto 0); mem_dqs_n : inout std_logic_vector(1 downto 0); avl_ready : out std_logic; avl_burstbegin : in std_logic; avl_addr : in std_logic_vector(24 downto 0); avl_rdata_valid : out std_logic; avl_rdata : out std_logic_vector(63 downto 0); avl_wdata : in std_logic_vector(63 downto 0); avl_be : in std_logic_vector(7 downto 0); avl_read_req : in std_logic; avl_write_req : in std_logic; avl_size : in std_logic_vector(2 downto 0); local_init_done : out std_logic; local_cal_success : out std_logic; local_cal_fail : out std_logic; oct_rzqin : in std_logic; pll_mem_clk : out std_logic; pll_write_clk : out std_logic; pll_write_clk_pre_phy_clk : out std_logic; pll_addr_cmd_clk : out std_logic; pll_locked : out std_logic; pll_avl_clk : out std_logic; pll_config_clk : out std_logic; pll_mem_phy_clk : out std_logic; afi_phy_clk : out std_logic; pll_avl_phy_clk : out std_logic ); end; architecture sim of lpddr2ctrl1 is signal lafi_clk: std_ulogic; begin afi_clk <= lafi_clk; afi_reset_n <= '0'; afi_reset_export_n <= '0'; mem_ca <= (others => '0'); mem_ck <= (others => '0'); mem_ck_n <= (others => '1'); mem_cke <= (others => '0'); mem_cs_n <= (others => '1'); mem_dm <= (others => '0'); mem_dq <= (others => 'Z'); mem_dqs <= (others => 'Z'); mem_dqs_n <= (others => 'Z'); avl_ready <= '1'; avl_rdata_valid <= '1'; avl_rdata <= (others => '0'); local_init_done <= '1'; local_cal_success <= '1'; local_cal_fail <= '0'; pll_mem_clk <= '0'; pll_write_clk <= '0'; pll_write_clk_pre_phy_clk <= '0'; pll_addr_cmd_clk <= '0'; pll_locked <= '1'; pll_avl_clk <= '0'; pll_config_clk <= '0'; pll_mem_phy_clk <= '0'; afi_phy_clk <= '0'; pll_avl_phy_clk <= '0'; clkproc: process variable vclk,vhclk: std_logic := '0'; begin lafi_clk <= vclk; afi_half_clk <= vhclk; wait for 4 ns; vclk := not vclk; if vclk='0' then vhclk:=not vhclk; end if; end process; rstproc: process begin afi_reset_n <= '0'; for x in 1 to 10 loop wait until rising_edge(lafi_clk); end loop; afi_reset_n <= '1'; wait; end process; end;

gpl-2.0

29bcd84323267e4f7a26e062a0a960fa

0.508612

3.33073

false

marco-c/leon-nexys2

grlib-gpl-1.3.4-b4140/lib/hynix/ddr2/HY5PS121621F_PACK.vhd

3

17,071

------------------------------------------------------ -- Hynix 4BANKS X 8M X 16bits DDR2 SDRAM -- -- -- -- Packages for HY5PS121621F.vhd -- -- -- -- HHHH HHHH -- -- HHHH HHHH -- -- ,O0O. ,O0 .HH ,O0 .HH -- -- (O000O)(000 )H(000 )H Hynix -- -- `O0O' `O0 'HH `O0 'HH -- -- HHHH HHHH Semiconductor -- -- HHHH HHHH -- ------------------------------------------------------ --------------------------------------------------------------------------------------------------------- LIBRARY IEEE; USE IEEE.STD_LOGIC_1164.all; library grlib; use grlib.stdlib.all; --USE IEEE.STD_LOGIC_ARITH.all; --USE IEEE.STD_LOGIC_UNSIGNED.all; --------------------------------------------------------------------------------------------------- package HY5PS121621F_PACK is --------------------------------------------------------------------------------------------------- constant NUM_OF_MROPCODE : integer := 13; constant NUM_OF_ROW_ADD : integer := 13; constant NUM_OF_COL_ADD : integer := 10; constant NUM_OF_BANK_ADD : integer := 2; constant WORD_SIZE : integer := 16; constant NUM_OF_ROWS : integer := 2**NUM_OF_ROW_ADD; constant NUM_OF_COLS : integer := 2**NUM_OF_COL_ADD; constant NUM_OF_BANKS : integer := 2**NUM_OF_BANK_ADD; constant NUM_OF_BUFFERS : integer := 3; type PART_NUM_TYPE is (B400, B533, B667, B800); type PART_NUM is array (B400 to B800) of time; constant tCKmin : PART_NUM := (B400 => 5 ns, B533 => 3.75 ns, B667 => 3 ns, B800 => 2.5 ns); constant tCKmax : PART_NUM := (B400 => 8 ns, B533 => 8 ns, B667 => 8 ns, B800 => 8 ns); constant tWR : PART_NUM := (B400 => 15 ns, B533 => 15 ns, B667 => 15 ns, B800 => 15 ns); constant tDS : PART_NUM := (B400 => 0.4 ns, B533 => 0.35 ns, B667 => 0.3 ns, B800 => 0.3 ns); constant tDH : PART_NUM := (B400 => 0.4 ns, B533 => 0.35 ns, B667 => 0.3 ns, B800 => 0.3 ns); constant tIS : PART_NUM := (B400 => 0.6 ns, B533 => 0.5 ns, B667 => 0.5 ns, B800 => 0.4 ns); constant tIH : PART_NUM := (B400 => 0.6 ns, B533 => 0.5 ns, B667 => 0.5 ns, B800 => 0.4 ns); constant tWTR : PART_NUM := (B400 => 10 ns, B533 => 7.5 ns, B667 => 7.5 ns, B800 => 7.5 ns); constant tRASmax : PART_NUM := (B400 => 70000 ns, B533 => 70000 ns, B667 => 70000 ns, B800 => 70000 ns); constant tRRD : time := 10 ns; constant tREF : time := 64 ms; constant tRFC : time := 75 ns; constant tRTP : time := 7.5 ns; constant tXSNR : time := tRFC + 10 ns; constant tXP : integer := 2; constant tCKE : integer := 3; constant tXARD : integer := 2; constant tXARDS : integer := 2; constant tXSRD : integer := 200; constant tPUS : time := 200 us; type STATE_TYPE is ( PWRDN, PWRUP, SLFREF, IDLE, RACT, READ, WRITE); type COMMAND_TYPE is ( DSEL, NOP, MRS, EMRS1, EMRS2, EMRS3, ACT, RD, RDAP, WR, WRAP, PCG, PCGA, AREF, SREF, SREX, PDEN, PDEX, ERROR, ILLEGAL); type BURST_MODE_TYPE is ( SEQUENTIAL, INTERLEAVE); type OCD_DRIVE_MODE_TYPE is ( CAL_EXIT, DRIVE1, DRIVE0, ADJUST, CAL_DEFAULT); subtype CL_TYPE is integer range 0 to 6; subtype BL_TYPE is integer range 4 to 8; subtype TWR_TYPE is integer range 2 to 6; type DLL_RST is ( RST, NORST); type MODE_REGISTER is record CAS_LATENCY : CL_TYPE; BURST_MODE : BURST_MODE_TYPE; BURST_LENGTH : BL_TYPE; DLL_STATE : DLL_RST; SAPD : std_logic; TWR : TWR_TYPE; end record; type EMR_TYPE is record DLL_EN : std_logic; AL : CL_TYPE; QOFF : std_logic; DQSB_ENB : std_logic; RDQS_EN : std_logic; OCD_PGM : OCD_DRIVE_MODE_TYPE; end record; type EMR2_TYPE is record SREF_HOT : std_logic; end record; type REF_CHECK is array (0 to (NUM_OF_BANKS - 1), 0 to (NUM_OF_ROWS - 1)) of time; type COL_ADDR_TYPE is array (0 to 3) of std_logic_vector((NUM_OF_COL_ADD - 1) downto 0); type DATA_BUFFER_TYPE is array (0 to 6) of std_logic_vector(8 downto 0); subtype COL_DATA_TYPE is integer range 0 to 65535; type SA_TYPE is array (0 to (NUM_OF_COLS - 1)) of COL_DATA_TYPE; type ROW_DATA_TYPE is array (0 to (NUM_OF_COLS - 1)) of COL_DATA_TYPE; type RAM_PNTR is ACCESS ROW_DATA_TYPE; type SA_ARRAY_TYPE is array (0 to (NUM_OF_BANKS - 1)) of SA_TYPE; type MEM_CELL_TYPE is array (0 to (NUM_OF_ROWS - 1)) of RAM_PNTR; subtype DATA_TYPE is std_logic_vector ((WORD_SIZE - 1) downto 0); type BUFFER_TYPE is array (0 to NUM_OF_BUFFERS - 1, 0 to 3) of DATA_TYPE; type ADD_PIPE_TYPE is array (0 to 12) of std_logic_vector((NUM_OF_COL_ADD + NUM_OF_BANK_ADD - 1) downto 0); type CKE_TYPE is array (integer range -1 to 0) of std_logic; subtype MROPCODE_TYPE is std_logic_vector ((NUM_OF_MROPCODE - 1) downto 0); procedure COMMAND_DECODE ( variable CSB, RASB, CASB, WEB, A10 : in std_logic; variable Bank_Add : in std_logic_vector((NUM_OF_BANK_ADD - 1) downto 0); variable CKE : in CKE_TYPE; variable COMMAND : out COMMAND_TYPE; variable BankState : in std_logic_vector((NUM_OF_BANKS - 1) downto 0); variable State : in STATE_TYPE); procedure MODE_REGISTER_SET ( MROPCODE : in MROPCODE_TYPE; MR : out MODE_REGISTER); procedure EXT_MODE_REGISTER_SET ( MROPCODE : in MROPCODE_TYPE; EMR : out EMR_TYPE); procedure EXT_MODE_REGISTER_SET2 ( MROPCODE : in MROPCODE_TYPE; EMR : out EMR2_TYPE); function REMAINDER ( val0 : in integer; val1 : in integer) return integer; function XOR_FUNC ( val0 : in std_logic_vector; val1 : in std_logic_vector) return std_logic_vector; function CHAR_TO_STD_LOGIC ( c : in character) return std_logic; function STD_LOGIC_TO_BIT (V: STD_LOGIC) return BIT; end HY5PS121621F_PACK; ------------------------------------------------------HY5DU121622T Package --------------------------------------------------------------------------------------------------- package body HY5PS121621F_PACK is --------------------------------------------------------------------------------------------------- procedure COMMAND_DECODE ( variable CSB, RASB, CASB, WEB, A10 : in std_logic; variable Bank_Add : in std_logic_vector((NUM_OF_BANK_ADD - 1) downto 0); variable CKE : in CKE_TYPE; variable COMMAND : out COMMAND_TYPE; variable BankState : in std_logic_vector((NUM_OF_BANKS - 1) downto 0); variable State : in STATE_TYPE) Is begin case CKE (-1) is when '1' => case CKE (0) is when '0' => if (BankState = "0000") then if (CSB = '0' and RASB = '0' and CASB = '0' and WEB = '1') then COMMAND := SREF; elsif ((CSB = '1') or (CSB = '0' and RASB = '1' and CASB = '1' and WEB = '1')) then COMMAND := PDEN; else COMMAND := ILLEGAL; end if; elsif ((CSB = '1') or (CSB = '0' and RASB = '1' and CASB = '1' and WEB = '1')) then COMMAND := PDEN; else COMMAND := ILLEGAL; end if; when '1' => if (CSB = '1') then COMMAND := DSEL; elsif (CSB = '0' and RASB = '1' and CASB = '1' and WEB ='1') then COMMAND := NOP; elsif (CSB = '0' and RASB = '1' and CASB = '0' and WEB ='1') then if (A10 = '0') then COMMAND := RD; else COMMAND := RDAP; end if; elsif (CSB = '0' and RASB = '1' and CASB = '0' and WEB ='0') then if (A10 = '0') then COMMAND := WR; else COMMAND := WRAP; end if; elsif (CSB = '0' and RASB = '0' and CASB = '1' and WEB ='1') then COMMAND := ACT; elsif (CSB = '0' and RASB = '0' and CASB = '1' and WEB ='0') then if (A10 = '0') then COMMAND := PCG; else COMMAND := PCGA; end if; elsif (CSB = '0' and RASB = '0' and CASB = '0' and WEB ='1') then COMMAND := AREF; elsif (CSB = '0' and RASB = '0' and CASB = '0' and WEB ='0') then if (BankState = "0000") then if (Bank_Add = "00") then COMMAND := MRS; elsif (Bank_Add = "01") then COMMAND := EMRS1; elsif (Bank_Add = "10") then COMMAND := EMRS2; elsif (Bank_Add = "11") then COMMAND := EMRS3; end if; else COMMAND := ILLEGAL; end if; end if; when others => COMMAND := ERROR; end case; when '0' => case CKE (0) is when '0' => COMMAND := NOP; when '1' => if (State = PWRUP) then COMMAND := NOP; elsif (CSB = '1') then if (State = SLFREF) then COMMAND := SREX; elsif (State = PWRDN) then COMMAND := PDEX; end if; elsif (CSB = '0' and RASB = '1' and CASB = '1' and WEB ='1') then if (State = SLFREF) then COMMAND := SREX; elsif (State = PWRDN) then COMMAND := PDEX; end if; else COMMAND := ERROR; end if; when others => COMMAND := ERROR; end case; when others => COMMAND := ERROR; end case; end COMMAND_DECODE; ------------------------------------------------------------------------------------------------ procedure MODE_REGISTER_SET ( MROPCODE : in MROPCODE_TYPE; MR : out MODE_REGISTER) is begin if (MROPCODE(6) = '0' and MROPCODE(5) = '1' and MROPCODE(4) = '0')then MR.CAS_LATENCY := 2; elsif (MROPCODE(6) = '0' and MROPCODE(5) = '1' and MROPCODE(4) = '1')then MR.CAS_LATENCY := 3; elsif (MROPCODE(6) = '1' and MROPCODE(5) = '0' and MROPCODE(4) = '0')then MR.CAS_LATENCY := 4; elsif (MROPCODE(6) = '1' and MROPCODE(5) = '0' and MROPCODE(4) = '1')then MR.CAS_LATENCY := 5; elsif (MROPCODE(6) = '1' and MROPCODE(5) = '1' and MROPCODE(4) = '0')then MR.CAS_LATENCY := 6; else assert false report "ERROR : (MODE_REGISTER_SET_PROCEDURE) : Invalid Cas_Latency Encountered!" severity WARNING; end if; if MROPCODE(3) = '0' then MR.BURST_MODE := SEQUENTIAL; elsif MROPCODE(3) = '1' then MR.BURST_MODE := INTERLEAVE; end if; if MROPCODE(8) = '0' then MR.DLL_STATE := NORST; elsif MROPCODE(8) = '1' then MR.DLL_STATE := RST; end if; if MROPCODE(2) = '0' and MROPCODE(1) = '1' and MROPCODE(0) = '0' then MR.BURST_LENGTH := 4; elsif MROPCODE(2) = '0' and MROPCODE(1) = '1' and MROPCODE(0) = '1' then MR.BURST_LENGTH := 8; else assert false report "ERROR : (MODE_REGISTER_SET_PROCEDURE) : Invalid Burst_Length Encountered!" severity ERROR; end if; if MROPCODE(12) = '0' then MR.SAPD := '0'; elsif MROPCODE(12) = '1' then MR.SAPD := '1'; end if; if MROPCODE(11) = '0' and MROPCODE(10) = '0' and MROPCODE(9) = '1' then MR.TWR := 2; elsif MROPCODE(11) = '0' and MROPCODE(10) = '1' and MROPCODE(9) = '0' then MR.TWR := 3; elsif MROPCODE(11) = '0' and MROPCODE(10) = '1' and MROPCODE(9) = '1' then MR.TWR := 4; elsif MROPCODE(11) = '1' and MROPCODE(10) = '0' and MROPCODE(9) = '0' then MR.TWR := 5; elsif MROPCODE(11) = '1' and MROPCODE(10) = '0' and MROPCODE(9) = '1' then MR.TWR := 6; else assert false report "ERROR : (MODE_REGISTER_SET_PROCEDURE) : Invalid Write Recovery Value Encountered!" severity ERROR; end if; end MODE_REGISTER_SET; ------------------------------------------------------------------------------------------------ procedure EXT_MODE_REGISTER_SET ( MROPCODE : in MROPCODE_TYPE; EMR : out EMR_TYPE) is begin if (MROPCODE(0) = '0') then EMR.DLL_EN := '1'; elsif (MROPCODE(0) = '1') then EMR.DLL_EN := '0'; end if; if (MROPCODE(5) = '0' and MROPCODE(4) = '0' and MROPCODE(3) = '0')then EMR.AL := 0; elsif (MROPCODE(5) = '0' and MROPCODE(4) = '0' and MROPCODE(3) = '1')then EMR.AL := 1; elsif (MROPCODE(5) = '0' and MROPCODE(4) = '1' and MROPCODE(3) = '0')then EMR.AL := 2; elsif (MROPCODE(5) = '0' and MROPCODE(4) = '1' and MROPCODE(3) = '1')then EMR.AL := 3; elsif (MROPCODE(5) = '1' and MROPCODE(4) = '0' and MROPCODE(3) = '0')then EMR.AL := 4; elsif (MROPCODE(5) = '1' and MROPCODE(4) = '0' and MROPCODE(3) = '1')then EMR.AL := 5; else assert false report "ERROR : (EXT_MODE_REGISTER_SET_PROCEDURE) : Invalid Additive_Latency Encountered!" severity WARNING; end if; if MROPCODE(12) = '0' then EMR.QOFF := '0'; elsif MROPCODE(12) = '1' then EMR.QOFF := '1'; end if; if MROPCODE(10) = '0' then EMR.DQSB_ENB := '0'; elsif MROPCODE(10) = '1' then EMR.DQSB_ENB := '1'; end if; if MROPCODE(11) = '0' then EMR.RDQS_EN := '0'; elsif MROPCODE(11) = '1' then EMR.RDQS_EN := '1'; end if; if MROPCODE(9) = '0' and MROPCODE(8) = '0' and MROPCODE(7) = '0' then EMR.OCD_PGM := CAL_EXIT; elsif MROPCODE(9) = '0' and MROPCODE(8) = '0' and MROPCODE(7) = '1' then EMR.OCD_PGM := DRIVE1; elsif MROPCODE(9) = '0' and MROPCODE(8) = '1' and MROPCODE(7) = '0' then EMR.OCD_PGM := DRIVE0; elsif MROPCODE(9) = '1' and MROPCODE(8) = '0' and MROPCODE(7) = '0' then EMR.OCD_PGM := ADJUST; elsif MROPCODE(9) = '1' and MROPCODE(8) = '1' and MROPCODE(7) = '1' then EMR.OCD_PGM := CAL_DEFAULT; else assert false report "ERROR : (EXT_MODE_REGISTER_SET_PROCEDURE) : Invalid OCD Calibration Program Encountered!" severity ERROR; end if; end EXT_MODE_REGISTER_SET; ------------------------------------------------------------------------------------------------ procedure EXT_MODE_REGISTER_SET2 ( MROPCODE : in MROPCODE_TYPE; EMR : out EMR2_TYPE) is begin if (MROPCODE(7) = '0') then EMR.SREF_HOT := '0'; elsif (MROPCODE(7) = '1') then EMR.SREF_HOT := '1'; end if; end EXT_MODE_REGISTER_SET2; ------------------------------------------------------------------------------------------------ function REMAINDER (val0 : in integer; val1 : in integer) return integer is variable Result : integer; begin Result := val0; loop exit when Result < val1; Result := Result - val1; end loop; return Result; end REMAINDER; ------------------------------------------------------------------------------------------------ function XOR_FUNC (val0 : in std_logic_vector; val1 : in std_logic_vector) return std_logic_vector is variable Result : std_logic_vector(2 downto 0); variable j : integer := 0; begin for i in val0'RANGE LOOP if (val0(i) /= val1(i)) then Result(i) := '1'; else Result(i) := '0'; end if; j := j + 1; end loop; return Result((j - 1) downto 0); end XOR_FUNC; ------------------------------------------------------------------------------------------------ function CHAR_TO_STD_LOGIC ( c : in character) return std_logic is variable r : std_logic; begin case c is when '0' => r := '0'; when 'L' => r := 'L'; when '1' => r := '1'; when 'H' => r := 'H'; when 'W' => r := 'W'; when 'Z' => r := 'Z'; when 'U' => r := 'U'; when '-' => r := '-'; when others => r := 'X'; end case; return r; end CHAR_TO_STD_LOGIC; ------------------------------------------------------------------------------------------------ function STD_LOGIC_TO_BIT (V: STD_LOGIC) return BIT is variable Result: BIT; begin case V is when '0' | 'L' => Result := '0'; when '1' | 'H' => Result := '1'; when 'X' | 'W' | 'Z' | 'U' | '-' => Result := '0'; end case; return Result; end STD_LOGIC_TO_BIT; ------------------------------------------------------------------------------------------------ end HY5PS121621F_PACK;

gpl-2.0

138eca33ee86695e85a1e489d7a18d85

0.47402

3.39789

false

marco-c/leon-nexys2

grlib-gpl-1.3.4-b4140/lib/gaisler/misc/ahbtrace.vhd

1

2,278

------------------------------------------------------------------------------ -- This file is a part of the GRLIB VHDL IP LIBRARY -- Copyright (C) 2003 - 2008, Gaisler Research -- Copyright (C) 2008 - 2013, Aeroflex Gaisler -- -- This program is free software; you can redistribute it and/or modify -- it under the terms of the GNU General Public License as published by -- the Free Software Foundation; either version 2 of the License, or -- (at your option) any later version. -- -- This program is distributed in the hope that it will be useful, -- but WITHOUT ANY WARRANTY; without even the implied warranty of -- MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the -- GNU General Public License for more details. -- -- You should have received a copy of the GNU General Public License -- along with this program; if not, write to the Free Software -- Foundation, Inc., 59 Temple Place, Suite 330, Boston, MA 02111-1307 USA ----------------------------------------------------------------------------- -- Entity: ahbtrace -- File: ahbtrace.vhd -- Author: Jiri Gaisler - Gaisler Research -- Description: AHB trace unit ------------------------------------------------------------------------------ library ieee; use ieee.std_logic_1164.all; library grlib; use grlib.amba.all; use grlib.stdlib.all; use grlib.devices.all; library techmap; use techmap.gencomp.all; library gaisler; use gaisler.misc.all; entity ahbtrace is generic ( hindex : integer := 0; ioaddr : integer := 16#000#; iomask : integer := 16#E00#; tech : integer := DEFMEMTECH; irq : integer := 0; kbytes : integer := 1; ahbfilt : integer := 0); port ( rst : in std_ulogic; clk : in std_ulogic; ahbmi : in ahb_mst_in_type; ahbsi : in ahb_slv_in_type; ahbso : out ahb_slv_out_type ); end; architecture rtl of ahbtrace is begin ahbt0 : ahbtrace_mb generic map ( hindex => hindex, ioaddr => ioaddr, iomask => iomask, tech => tech, irq => irq, kbytes => kbytes, ahbfilt => ahbfilt) port map( rst => rst, clk => clk, ahbsi => ahbsi, ahbso => ahbso, tahbmi => ahbmi, tahbsi => ahbsi); end;

gpl-2.0

6e61c17c4f52932fb8e0ccd989e77b2f

0.575505

4.017637

false

marco-c/leon-nexys2

grlib-gpl-1.3.4-b4140/lib/techmap/unisim/buffer_unisim.vhd

1

2,757

------------------------------------------------------------------------------ -- This file is a part of the GRLIB VHDL IP LIBRARY -- Copyright (C) 2003 - 2008, Gaisler Research -- Copyright (C) 2008 - 2013, Aeroflex Gaisler -- -- This program is free software; you can redistribute it and/or modify -- it under the terms of the GNU General Public License as published by -- the Free Software Foundation; either version 2 of the License, or -- (at your option) any later version. -- -- This program is distributed in the hope that it will be useful, -- but WITHOUT ANY WARRANTY; without even the implied warranty of -- MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the -- GNU General Public License for more details. -- -- You should have received a copy of the GNU General Public License -- along with this program; if not, write to the Free Software -- Foundation, Inc., 59 Temple Place, Suite 330, Boston, MA 02111-1307 USA ----------------------------------------------------------------------------- -- Entity: clkbuf_xilinx -- File: clkbuf_xilinx.vhd -- Author: Marko Isomaki, Jiri GAisler - Gaisler Research -- Description: Clock buffer generator for Xilinx devices ------------------------------------------------------------------------------ library ieee; use ieee.std_logic_1164.all; -- pragma translate_off library unisim; use unisim.BUFGMUX; use unisim.BUFG; -- pragma translate_on entity clkbuf_xilinx is generic( buftype : integer range 0 to 3 := 0); port( i : in std_ulogic; o : out std_ulogic ); end entity; architecture rtl of clkbuf_xilinx is component BUFGMUX port (O : out std_logic; I0, I1, S : in std_logic); end component; component BUFG port (O : out std_logic; I : in std_logic); end component; signal gnd : std_ulogic; signal x : std_ulogic; attribute syn_noclockbuf : boolean; attribute syn_noclockbuf of x : signal is true; begin gnd <= '0'; buf0 : if (buftype = 0) or (buftype > 2) generate x <= i; o <= x; end generate; buf1 : if buftype = 1 generate buf : bufgmux port map(S => gnd, I0 => i, I1 => gnd, O => o); end generate; buf2 : if (buftype = 2) generate buf : bufg port map(I => i, O => o); end generate; end architecture; library ieee; use ieee.std_logic_1164.all; -- pragma translate_off library unisim; use unisim.BUFGMUX; -- pragma translate_on entity clkmux_xilinx is port( i0, i1 : in std_ulogic; sel : in std_ulogic; o : out std_ulogic ); end entity; architecture rtl of clkmux_xilinx is component BUFGMUX port (O : out std_logic; I0, I1, S : in std_logic); end component; begin buf : bufgmux port map(S => sel, I0 => i0, I1 => i1, O => o); end architecture;

gpl-2.0

d2d54c9febd1b3ec4ac322915e6c5d79

0.620239

3.75102

false

marco-c/leon-nexys2

grlib-gpl-1.3.4-b4140/lib/gaisler/gr1553b/simtrans1553.vhd

1

3,690

------------------------------------------------------------------------------ -- This file is a part of the GRLIB VHDL IP LIBRARY -- Copyright (C) 2003 - 2008, Gaisler Research -- Copyright (C) 2008 - 2013, Aeroflex Gaisler -- -- This program is free software; you can redistribute it and/or modify -- it under the terms of the GNU General Public License as published by -- the Free Software Foundation; either version 2 of the License, or -- (at your option) any later version. -- -- This program is distributed in the hope that it will be useful, -- but WITHOUT ANY WARRANTY; without even the implied warranty of -- MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the -- GNU General Public License for more details. -- -- You should have received a copy of the GNU General Public License -- along with this program; if not, write to the Free Software -- Foundation, Inc., 59 Temple Place, Suite 330, Boston, MA 02111-1307 USA ----------------------------------------------------------------------------- -- Entity: simtrans1553 -- File: simtrans1553.vhd -- Author: Magnus Hjorth - Aeroflex Gaisler -- Description: 1553 Transceiver simulation model ------------------------------------------------------------------------------ library ieee; use ieee.std_logic_1164.all; library gaisler; use gaisler.gr1553b_pkg.all; entity simtrans1553_single is generic ( txdelay: time := 200 ns; rxdelay: time := 450 ns ); port ( buswire: inout wire1553; rxen: in std_logic; txin: in std_logic; txP: in std_logic; txN: in std_logic; rxP: out std_logic; rxN: out std_logic ); end; architecture b of simtrans1553_single is signal bw_rxd, bw_txd: wire1553; begin bw_rxd <= transport buswire after rxdelay; buswire <= bw_txd after txdelay; rxpr: process(bw_rxd,rxen) variable p,n: std_ulogic; begin p:='U'; n:='U'; case rxen is when '0' => p:='0'; n:='0'; when '1' => case bw_rxd is when 'U' => null; when 'X' => p := 'X'; n := 'X'; when '0' => p := '0'; n := '0'; when '+' => p := '1'; n := '0'; when '-' => p := '0'; n := '1'; end case; when 'X' => p:='X'; n:='X'; when others => null; end case; rxP <= p; rxN <= n; end process; txpr: process(txin, txP, txN) variable w: wire1553; begin w := 'U'; if txin='1' or (txP='0' and txN='0') or (txP='1' and txN='1') then w := '0'; elsif txin='0' and txP='1' and txN='0' then w := '+'; elsif txin='0' and txP='0' and txN='1' then w := '-'; elsif txin='X' or txP='X' or txN='X' then w := 'X'; elsif txin='U' or (txP='U' and txN='U') then w := 'U'; else w := 'X'; end if; bw_txd <= w; end process; end; library ieee; use ieee.std_logic_1164.all; library gaisler; use gaisler.gr1553b_pkg.all; entity simtrans1553 is generic ( txdelay: time := 200 ns; rxdelay: time := 450 ns ); port ( busA: inout wire1553; busB: inout wire1553; rxenA: in std_logic; txinA: in std_logic; txAP: in std_logic; txAN: in std_logic; rxAP: out std_logic; rxAN: out std_logic; rxenB: in std_logic; txinB: in std_logic; txBP: in std_logic; txBN: in std_logic; rxBP: out std_logic; rxBN: out std_logic ); end; architecture s of simtrans1553 is begin at: simtrans1553_single generic map (txdelay,rxdelay) port map (busA,rxenA,txinA,txAP,txAN,rxAP,rxAN); bt: simtrans1553_single generic map (txdelay,rxdelay) port map (busB,rxenB,txinB,txBP,txBN,rxBP,rxBN); end;

gpl-2.0

5592a9d1493f2217edde1d134690819c

0.561789

3.419833

false

marco-c/leon-nexys2

grlib-gpl-1.3.4-b4140/lib/techmap/unisim/clkgen_unisim.vhd

1

18,422

------------------------------------------------------------------------------ -- This file is a part of the GRLIB VHDL IP LIBRARY -- Copyright (C) 2003 - 2008, Gaisler Research -- Copyright (C) 2008 - 2013, Aeroflex Gaisler -- -- This program is free software; you can redistribute it and/or modify -- it under the terms of the GNU General Public License as published by -- the Free Software Foundation; either version 2 of the License, or -- (at your option) any later version. -- -- This program is distributed in the hope that it will be useful, -- but WITHOUT ANY WARRANTY; without even the implied warranty of -- MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the -- GNU General Public License for more details. -- -- You should have received a copy of the GNU General Public License -- along with this program; if not, write to the Free Software -- Foundation, Inc., 59 Temple Place, Suite 330, Boston, MA 02111-1307 USA ----------------------------------------------------------------------------- -- Entity: various -- File: clkgen_xilinx.vhd -- Author: Jiri Gaisler, Gaisler Research -- Author: Richard Pender, Pender Electronic Design -- Description: Clock generators for Virtex and Virtex-2 fpgas ------------------------------------------------------------------------------ ------------------------------------------------------------------ -- Virtex5 clock generator --------------------------------------- ------------------------------------------------------------------ library ieee; use ieee.std_logic_1164.all; -- pragma translate_off library grlib; use grlib.stdlib.all; library unisim; use unisim.BUFG; use unisim.DCM; --use unisim.BUFGDLL; use unisim.BUFGMUX; -- pragma translate_on library techmap; use techmap.gencomp.all; entity clkgen_virtex5 is generic ( clk_mul : integer := 1; clk_div : integer := 1; sdramen : integer := 0; noclkfb : integer := 0; pcien : integer := 0; pcidll : integer := 0; pcisysclk: integer := 0; freq : integer := 25000; -- clock frequency in KHz clk2xen : integer := 0; clksel : integer := 0); -- enable clock select port ( clkin : in std_ulogic; pciclkin: in std_ulogic; clk : out std_ulogic; -- main clock clkn : out std_ulogic; -- inverted main clock clk2x : out std_ulogic; -- double clock sdclk : out std_ulogic; -- SDRAM clock pciclk : out std_ulogic; -- PCI clock cgi : in clkgen_in_type; cgo : out clkgen_out_type; clk1xu : out std_ulogic; -- unscaled clock clk2xu : out std_ulogic -- unscaled 2X clock ); end; architecture struct of clkgen_virtex5 is component BUFG port (O : out std_logic; I : in std_logic); end component; component BUFGMUX port ( O : out std_ulogic; I0 : in std_ulogic; I1 : in std_ulogic; S : in std_ulogic); end component; component DCM generic ( CLKDV_DIVIDE : real := 2.0; CLKFX_DIVIDE : integer := 1; CLKFX_MULTIPLY : integer := 4; CLKIN_DIVIDE_BY_2 : boolean := false; CLKIN_PERIOD : real := 10.0; CLKOUT_PHASE_SHIFT : string := "NONE"; CLK_FEEDBACK : string := "1X"; DESKEW_ADJUST : string := "SYSTEM_SYNCHRONOUS"; DFS_FREQUENCY_MODE : string := "LOW"; DLL_FREQUENCY_MODE : string := "LOW"; DSS_MODE : string := "NONE"; DUTY_CYCLE_CORRECTION : boolean := true; FACTORY_JF : bit_vector := X"C080"; PHASE_SHIFT : integer := 0; STARTUP_WAIT : boolean := false ); port ( CLKFB : in std_logic; CLKIN : in std_logic; DSSEN : in std_logic; PSCLK : in std_logic; PSEN : in std_logic; PSINCDEC : in std_logic; RST : in std_logic; CLK0 : out std_logic; CLK90 : out std_logic; CLK180 : out std_logic; CLK270 : out std_logic; CLK2X : out std_logic; CLK2X180 : out std_logic; CLKDV : out std_logic; CLKFX : out std_logic; CLKFX180 : out std_logic; LOCKED : out std_logic; PSDONE : out std_logic; STATUS : out std_logic_vector (7 downto 0)); end component; -- component BUFGDLL port (O : out std_logic; I : in std_logic); end component; constant VERSION : integer := 1; --constant CLKIN_PERIOD_ST : string := "20.0"; constant FREQ_MHZ : integer := freq/1000; --attribute CLKIN_PERIOD : string; --attribute CLKIN_PERIOD of dll0: label is CLKIN_PERIOD_ST; signal gnd, clk_i, clk_j, clk_k, clk_l, clk_m, lsdclk : std_logic; signal clk_x, clk_n, clk_o, clk_p, clk_i2, clk_sd, clk_r: std_logic; signal dll0rst, dll0lock, dll1lock, dll2xlock : std_logic; signal dll1rst, dll2xrst : std_logic_vector(0 to 3); signal clk0B, clkint, pciclkint : std_logic; begin gnd <= '0'; clk <= clk_i when (CLK2XEN = 0) else clk_p; clkn <= clk_m; clk2x <= clk_i2; c0 : if (PCISYSCLK = 0) or (PCIEN = 0) generate clkint <= clkin; end generate; c2 : if PCIEN /= 0 generate pciclkint <= pciclkin; p3 : if PCISYSCLK = 1 generate clkint <= pciclkint; end generate; p0 : if PCIDLL = 1 generate -- x1 : BUFGDLL port map (I => pciclkint, O => pciclk); --pragma translate_off assert false report "PCIDLL = 1 currently not supported for virtex5_clkgen" severity failure; --pragma translate_on end generate; p1 : if PCIDLL = 0 generate x1 : BUFG port map (I => pciclkint, O => pciclk); end generate; end generate; c3 : if PCIEN = 0 generate pciclk <= '0'; end generate; clk1xu <= clk_k; clk2xu <= clk_x; bufg0 : BUFG port map (I => clk0B, O => clk_i); bufg1 : BUFG port map (I => clk_j, O => clk_k); bufg2 : BUFG port map (I => clk_l, O => clk_m); buf34gen : if (CLK2XEN /= 0) generate cs0 : if (clksel = 0) generate bufg3 : BUFG port map (I => clk_n, O => clk_i2); end generate; cs1 : if (clksel /= 0) generate bufg3 : BUFGMUX port map (S => cgi.clksel(0), I0 => clk_o, I1 => clk_n, O => clk_i2); end generate; bufg4 : BUFG port map (I => clk_o, O => clk_p); end generate; dll0rst <= not cgi.pllrst; -- HMODE_dll0 : if (((FREQ_MHZ*clk_mul)/clk_div >= 140) or (FREQ_MHZ >= 120)) generate -- dll0 : DCM -- generic map (CLKFX_MULTIPLY => clk_mul, CLKFX_DIVIDE => clk_div, -- DFS_FREQUENCY_MODE => "HIGH", DLL_FREQUENCY_MODE => "HIGH") -- port map ( CLKIN => clkint, CLKFB => clk_k, DSSEN => gnd, PSCLK => gnd, -- PSEN => gnd, PSINCDEC => gnd, RST => dll0rst, CLK0 => clk_j, -- CLKFX => clk0B, CLK2X => clk_x, CLKFX180 => clk_l, LOCKED => dll0lock); -- end generate; -- LMODE_dll0 : if not (((FREQ_MHZ*clk_mul)/clk_div >= 140) or (FREQ_MHZ >= 120)) generate dll0 : DCM generic map (CLKFX_MULTIPLY => clk_mul, CLKFX_DIVIDE => clk_div, DFS_FREQUENCY_MODE => "LOW", DLL_FREQUENCY_MODE => "LOW") port map ( CLKIN => clkint, CLKFB => clk_k, DSSEN => gnd, PSCLK => gnd, PSEN => gnd, PSINCDEC => gnd, RST => dll0rst, CLK0 => clk_j, CLKFX => clk0B, CLK2X => clk_x, CLKFX180 => clk_l, LOCKED => dll0lock); -- end generate; clk2xgen : if (CLK2XEN /= 0) generate -- HMODE_dll2x : if ((FREQ_MHZ*clk_mul)/clk_div >= 120) generate -- dll2x : DCM generic map (CLKFX_MULTIPLY => 2, CLKFX_DIVIDE => 2, -- DFS_FREQUENCY_MODE => "HIGH", DLL_FREQUENCY_MODE => "HIGH") -- port map ( CLKIN => clk_i, CLKFB => clk_p, DSSEN => gnd, PSCLK => gnd, -- PSEN => gnd, PSINCDEC => gnd, RST => dll2xrst(0), CLK0 => clk_o, -- CLK2X => clk_n, LOCKED => dll2xlock); -- end generate; -- LMODE_dll2x : if not ((FREQ_MHZ*clk_mul)/clk_div >= 120) generate dll2x : DCM generic map (CLKFX_MULTIPLY => 2, CLKFX_DIVIDE => 2, DFS_FREQUENCY_MODE => "LOW", DLL_FREQUENCY_MODE => "LOW") port map ( CLKIN => clk_i, CLKFB => clk_p, DSSEN => gnd, PSCLK => gnd, PSEN => gnd, PSINCDEC => gnd, RST => dll2xrst(0), CLK0 => clk_o, CLK2X => clk_n, LOCKED => dll2xlock); -- end generate; rstdel2x : process (clk_i, dll0lock) begin if dll0lock = '0' then dll2xrst <= (others => '1'); elsif rising_edge(clk_i) then dll2xrst <= dll2xrst(1 to 3) & '0'; end if; end process; end generate; clk_sd1 : if (CLK2XEN = 0) generate clk_i2 <= clk_x; dll2xlock <= dll0lock; clk_sd <= clk_i; end generate; clk_sd2 : if (CLK2XEN = 1) generate clk_sd <= clk_p; end generate; clk_sd3 : if (CLK2XEN = 2) generate clk_sd <= clk_i2; end generate; sd0 : if (SDRAMEN /= 0) and (NOCLKFB=0) generate cgo.clklock <= dll1lock; -- HMODE_dll1 : if ((FREQ_MHZ*clk_mul)/clk_div >= (120-60*(CLK2XEN/2))) generate -- dll1 : DCM generic map (CLKFX_MULTIPLY => 2, CLKFX_DIVIDE => 2, -- DFS_FREQUENCY_MODE => "HIGH", DLL_FREQUENCY_MODE => "HIGH", -- DESKEW_ADJUST => "SOURCE_SYNCHRONOUS") -- port map ( CLKIN => clk_sd, CLKFB => cgi.pllref, DSSEN => gnd, PSCLK => gnd, -- PSEN => gnd, PSINCDEC => gnd, RST => dll1rst(0), CLK0 => lsdclk, --CLK2X => clk2x, -- LOCKED => dll1lock); -- end generate; -- LMODE_dll1 : if not ((FREQ_MHZ*clk_mul)/clk_div >= (120-60*(CLK2XEN/2))) generate dll1 : DCM generic map (CLKFX_MULTIPLY => 2, CLKFX_DIVIDE => 2, DFS_FREQUENCY_MODE => "LOW", DLL_FREQUENCY_MODE => "LOW", DESKEW_ADJUST => "SOURCE_SYNCHRONOUS") port map ( CLKIN => clk_sd, CLKFB => cgi.pllref, DSSEN => gnd, PSCLK => gnd, PSEN => gnd, PSINCDEC => gnd, RST => dll1rst(0), CLK0 => lsdclk, --CLK2X => clk2x, LOCKED => dll1lock); -- end generate; bufgx : BUFG port map (I => lsdclk, O => sdclk); rstdel : process (clk_sd, dll2xlock) begin if dll2xlock = '0' then dll1rst <= (others => '1'); elsif rising_edge(clk_sd) then dll1rst <= dll1rst(1 to 3) & '0'; end if; end process; end generate; sd1 : if ((SDRAMEN = 0) or (NOCLKFB = 1)) and (CLK2XEN /= 2) generate sdclk <= clk_i; cgo.clklock <= dll0lock when (CLK2XEN = 0) else dll2xlock; end generate; sd1_2x : if ((SDRAMEN = 0) or (NOCLKFB = 1)) and (CLK2XEN = 2) generate sdclk <= clk_i2; cgo.clklock <= dll2xlock; end generate; cgo.pcilock <= '1'; -- pragma translate_off bootmsg : report_version generic map ( "clkgen_virtex5" & ": virtex-5 sdram/pci clock generator, version " & tost(VERSION), "clkgen_virtex5" & ": Frequency " & tost(freq) & " KHz, DCM divisor " & tost(clk_mul) & "/" & tost(clk_div)); -- pragma translate_on end; ------------------------------------------------------------------ -- Virtex7 clock generator --------------------------------------- ------------------------------------------------------------------ library ieee; use ieee.std_logic_1164.all; -- pragma translate_off library grlib; use grlib.stdlib.all; library unisim; use UNISIM.vcomponents.all; -- pragma translate_on library techmap; use techmap.gencomp.all; entity clkgen_virtex7 is generic ( clk_mul : integer := 1; clk_div : integer := 1; freq : integer := 200000 -- clock frequency in KHz ); port ( clkin : in std_ulogic; clk : out std_ulogic; -- main clock clk90 : out std_ulogic; -- main clock 90deg clkio : out std_ulogic; -- IO ref clock cgi : in clkgen_in_type; cgo : out clkgen_out_type ); end; architecture struct of clkgen_virtex7 is component BUFG port (O : out std_logic; I : in std_logic); end component; ----- component PLLE2_ADV ----- component PLLE2_ADV generic ( BANDWIDTH : string := "OPTIMIZED"; CLKFBOUT_MULT : integer := 5; CLKFBOUT_PHASE : real := 0.0; CLKIN1_PERIOD : real := 0.0; CLKIN2_PERIOD : real := 0.0; CLKOUT0_DIVIDE : integer := 1; CLKOUT0_DUTY_CYCLE : real := 0.5; CLKOUT0_PHASE : real := 0.0; CLKOUT1_DIVIDE : integer := 1; CLKOUT1_DUTY_CYCLE : real := 0.5; CLKOUT1_PHASE : real := 0.0; CLKOUT2_DIVIDE : integer := 1; CLKOUT2_DUTY_CYCLE : real := 0.5; CLKOUT2_PHASE : real := 0.0; CLKOUT3_DIVIDE : integer := 1; CLKOUT3_DUTY_CYCLE : real := 0.5; CLKOUT3_PHASE : real := 0.0; CLKOUT4_DIVIDE : integer := 1; CLKOUT4_DUTY_CYCLE : real := 0.5; CLKOUT4_PHASE : real := 0.0; CLKOUT5_DIVIDE : integer := 1; CLKOUT5_DUTY_CYCLE : real := 0.5; CLKOUT5_PHASE : real := 0.0; COMPENSATION : string := "ZHOLD"; DIVCLK_DIVIDE : integer := 1; REF_JITTER1 : real := 0.0; REF_JITTER2 : real := 0.0; STARTUP_WAIT : string := "FALSE" ); port ( CLKFBOUT : out std_ulogic := '0'; CLKOUT0 : out std_ulogic := '0'; CLKOUT1 : out std_ulogic := '0'; CLKOUT2 : out std_ulogic := '0'; CLKOUT3 : out std_ulogic := '0'; CLKOUT4 : out std_ulogic := '0'; CLKOUT5 : out std_ulogic := '0'; DO : out std_logic_vector (15 downto 0); DRDY : out std_ulogic := '0'; LOCKED : out std_ulogic := '0'; CLKFBIN : in std_ulogic; CLKIN1 : in std_ulogic; CLKIN2 : in std_ulogic; CLKINSEL : in std_ulogic; DADDR : in std_logic_vector(6 downto 0); DCLK : in std_ulogic; DEN : in std_ulogic; DI : in std_logic_vector(15 downto 0); DWE : in std_ulogic; PWRDWN : in std_ulogic; RST : in std_ulogic ); end component; constant VERSION : integer := 1; constant period : real := 1000000.0/real(freq); constant clkio_div : integer := freq*clk_mul/200000; signal CLKFBOUT : std_logic; signal CLKFBIN : std_logic; signal int_rst : std_logic; signal clk_nobuf : std_logic; signal clk90_nobuf : std_logic; signal clkio_nobuf : std_logic; begin CLKFBIN <= CLKFBOUT; int_rst <= not cgi.pllrst; PLLE2_ADV_inst : PLLE2_ADV generic map ( BANDWIDTH => "OPTIMIZED", -- OPTIMIZED, HIGH, LOW CLKFBOUT_MULT => clk_mul, -- Multiply value for all CLKOUT, (2-64) CLKFBOUT_PHASE => 0.0, -- Phase offset in degrees of CLKFB, (-360.000-360.000). -- CLKIN_PERIOD: Input clock period in nS to ps resolution (i.e. 33.333 is 30 MHz). CLKIN1_PERIOD => period, CLKIN2_PERIOD => 0.0, -- CLKOUT0_DIVIDE - CLKOUT5_DIVIDE: Divide amount for CLKOUT (1-128) CLKOUT0_DIVIDE => clk_div, CLKOUT1_DIVIDE => clk_div, CLKOUT2_DIVIDE => clkio_div, CLKOUT3_DIVIDE => 1, CLKOUT4_DIVIDE => 1, CLKOUT5_DIVIDE => 1, -- CLKOUT0_DUTY_CYCLE - CLKOUT5_DUTY_CYCLE: Duty cycle for CLKOUT outputs (0.001-0.999). CLKOUT0_DUTY_CYCLE => 0.5, CLKOUT1_DUTY_CYCLE => 0.5, CLKOUT2_DUTY_CYCLE => 0.5, CLKOUT3_DUTY_CYCLE => 0.5, CLKOUT4_DUTY_CYCLE => 0.5, CLKOUT5_DUTY_CYCLE => 0.5, -- CLKOUT0_PHASE - CLKOUT5_PHASE: Phase offset for CLKOUT outputs (-360.000-360.000). CLKOUT0_PHASE => 0.0, CLKOUT1_PHASE => 90.0, CLKOUT2_PHASE => 0.0, CLKOUT3_PHASE => 0.0, CLKOUT4_PHASE => 0.0, CLKOUT5_PHASE => 0.0, COMPENSATION => "ZHOLD", -- ZHOLD, BUF_IN, EXTERNAL, INTERNAL DIVCLK_DIVIDE => 1, -- Master division value (1-56) -- REF_JITTER: Reference input jitter in UI (0.000-0.999). REF_JITTER1 => 0.0, REF_JITTER2 => 0.0, STARTUP_WAIT => "TRUE" -- Delay DONE until PLL Locks, ("TRUE"/"FALSE") ) port map ( -- Clock Outputs: 1-bit (each) output: User configurable clock outputs CLKOUT0 => clk_nobuf, CLKOUT1 => clk90_nobuf, CLKOUT2 => clkio_nobuf, CLKOUT3 => OPEN, CLKOUT4 => OPEN, CLKOUT5 => OPEN, -- DRP Ports: 16-bit (each) output: Dynamic reconfigration ports DO => OPEN, DRDY => OPEN, -- Feedback Clocks: 1-bit (each) output: Clock feedback ports CLKFBOUT => CLKFBOUT, -- Status Ports: 1-bit (each) output: PLL status ports LOCKED => cgo.clklock, -- Clock Inputs: 1-bit (each) input: Clock inputs CLKIN1 => clkin, CLKIN2 => '0', -- Con trol Ports: 1-bit (each) input: PLL control ports CLKINSEL => '1', PWRDWN => '0', RST => int_rst, -- DRP Ports: 7-bit (each) input: Dynamic reconfigration ports DADDR => "0000000", DCLK => '0', DEN => '0', DI => "0000000000000000", DWE => '0', -- Feedback Clocks: 1-bit (each) input: Clock feedback ports CLKFBIN => CLKFBIN ); cgo.pcilock <= '0'; bufgclk0 : BUFG port map (I => clk_nobuf, O => clk); bufgclk90 : BUFG port map (I => clk90_nobuf, O => clk90); bufgclkio : BUFG port map (I => clkio_nobuf, O => clkio); -- pragma translate_off bootmsg : report_version generic map ( "clkgen_virtex7" & ": virtex-7 sdram/pci clock generator, version " & tost(VERSION), "clkgen_virtex7" & ": Frequency " & tost(freq) & " KHz, DCM divisor " & tost(clk_mul) & "/" & tost(clk_div)); -- pragma translate_on end; library ieee; use ieee.std_logic_1164.all; -- pragma translate_off library unisim; use unisim.BUFGMUX; -- pragma translate_on entity clkand_unisim is port( i : in std_ulogic; en : in std_ulogic; o : out std_ulogic ); end entity; architecture rtl of clkand_unisim is component BUFGCE port( O : out STD_ULOGIC; CE: in STD_ULOGIC; I : in STD_ULOGIC ); end component; begin buf : bufgce port map(I => i, CE => en, O => o); end architecture; library ieee; use ieee.std_logic_1164.all; -- pragma translate_off library unisim; use unisim.BUFGMUX; -- pragma translate_on entity clkmux_unisim is port( i0, i1 : in std_ulogic; sel : in std_ulogic; o : out std_ulogic ); end entity; architecture rtl of clkmux_unisim is component bufgmux is port( i0, i1 : in std_ulogic; s : in std_ulogic; o : out std_ulogic); end component; signal sel0, sel1, cg0, cg1 : std_ulogic; begin buf : bufgmux port map(S => sel, I0 => i0, I1 => i1, O => o); end architecture;

gpl-2.0

84aad10c54f1dfb16576f3f05baba44a

0.56438

3.417177

false

mistryalok/Zedboard

learning/training/MSD/s09/axi_dma_sg/vivado/project_1/project_1.srcs/sources_1/ipshared/xilinx.com/axi_sg_v4_1/0535f152/hdl/src/vhdl/axi_sg_updt_noqueue.vhd

3

30,514

-- ************************************************************************* -- -- (c) Copyright 2010-2011 Xilinx, Inc. All rights reserved. -- -- This file contains confidential and proprietary information -- of Xilinx, Inc. and is protected under U.S. and -- international copyright and other intellectual property -- laws. -- -- DISCLAIMER -- This disclaimer is not a license and does not grant any -- rights to the materials distributed herewith. Except as -- otherwise provided in a valid license issued to you by -- Xilinx, and to the maximum extent permitted by applicable -- law: (1) THESE MATERIALS ARE MADE AVAILABLE "AS IS" AND -- WITH ALL FAULTS, AND XILINX HEREBY DISCLAIMS ALL WARRANTIES -- AND CONDITIONS, EXPRESS, IMPLIED, OR STATUTORY, INCLUDING -- BUT NOT LIMITED TO WARRANTIES OF MERCHANTABILITY, NON- -- INFRINGEMENT, OR FITNESS FOR ANY PARTICULAR PURPOSE; and -- (2) Xilinx shall not be liable (whether in contract or tort, -- including negligence, or under any other theory of -- liability) for any loss or damage of any kind or nature -- related to, arising under or in connection with these -- materials, including for any direct, or any indirect, -- special, incidental, or consequential loss or damage -- (including loss of data, profits, goodwill, or any type of -- loss or damage suffered as a result of any action brought -- by a third party) even if such damage or loss was -- reasonably foreseeable or Xilinx had been advised of the -- possibility of the same. -- -- CRITICAL APPLICATIONS -- Xilinx products are not designed or intended to be fail- -- safe, or for use in any application requiring fail-safe -- performance, such as life-support or safety devices or -- systems, Class III medical devices, nuclear facilities, -- applications related to the deployment of airbags, or any -- other applications that could lead to death, personal -- injury, or severe property or environmental damage -- (individually and collectively, "Critical -- Applications"). Customer assumes the sole risk and -- liability of any use of Xilinx products in Critical -- Applications, subject only to applicable laws and -- regulations governing limitations on product liability. -- -- THIS COPYRIGHT NOTICE AND DISCLAIMER MUST BE RETAINED AS -- PART OF THIS FILE AT ALL TIMES. -- -- ************************************************************************* -- ------------------------------------------------------------------------------- -- Filename: axi_sg_updt_noqueue.vhd -- Description: This entity provides the descriptor update for the No Queue mode -- -- VHDL-Standard: VHDL'93 ------------------------------------------------------------------------------- library ieee; use ieee.std_logic_1164.all; use ieee.numeric_std.all; use ieee.std_logic_misc.all; library axi_sg_v4_1; use axi_sg_v4_1.axi_sg_pkg.all; library lib_pkg_v1_0; use lib_pkg_v1_0.lib_pkg.all; ------------------------------------------------------------------------------- entity axi_sg_updt_noqueue is generic ( C_M_AXI_SG_ADDR_WIDTH : integer range 32 to 64 := 32; -- Master AXI Memory Map Address Width for Scatter Gather R/W Port C_M_AXIS_UPDT_DATA_WIDTH : integer range 32 to 32 := 32; -- Master AXI Memory Map Data Width for Scatter Gather R/W Port C_S_AXIS_UPDPTR_TDATA_WIDTH : integer range 32 to 32 := 32; -- 32 Update Status Bits C_S_AXIS_UPDSTS_TDATA_WIDTH : integer range 33 to 33 := 33 -- 1 IOC bit + 32 Update Status Bits ); port ( ----------------------------------------------------------------------- -- AXI Scatter Gather Interface ----------------------------------------------------------------------- m_axi_sg_aclk : in std_logic ; -- m_axi_sg_aresetn : in std_logic ; -- -- -- Channel 1 Control -- updt_curdesc_wren : out std_logic ; -- updt_curdesc : out std_logic_vector -- (C_M_AXI_SG_ADDR_WIDTH-1 downto 0) ; -- updt_active : in std_logic ; -- updt_queue_empty : out std_logic ; -- updt_ioc : out std_logic ; -- updt_ioc_irq_set : in std_logic ; -- -- dma_interr : out std_logic ; -- dma_slverr : out std_logic ; -- dma_decerr : out std_logic ; -- dma_interr_set : in std_logic ; -- dma_slverr_set : in std_logic ; -- dma_decerr_set : in std_logic ; -- updt2_active : in std_logic ; -- updt2_queue_empty : out std_logic ; -- updt2_ioc : out std_logic ; -- updt2_ioc_irq_set : in std_logic ; -- -- dma2_interr : out std_logic ; -- dma2_slverr : out std_logic ; -- dma2_decerr : out std_logic ; -- dma2_interr_set : in std_logic ; -- dma2_slverr_set : in std_logic ; -- dma2_decerr_set : in std_logic ; -- -- --*********************************-- -- --** Channel Update Interface In **-- -- --*********************************-- -- -- Update Pointer Stream -- s_axis_updtptr_tdata : in std_logic_vector -- (C_S_AXIS_UPDPTR_TDATA_WIDTH-1 downto 0) ; -- s_axis_updtptr_tvalid : in std_logic ; -- s_axis_updtptr_tready : out std_logic ; -- s_axis_updtptr_tlast : in std_logic ; -- -- -- Update Status Stream -- s_axis_updtsts_tdata : in std_logic_vector -- (C_S_AXIS_UPDSTS_TDATA_WIDTH-1 downto 0); -- s_axis_updtsts_tvalid : in std_logic ; -- s_axis_updtsts_tready : out std_logic ; -- s_axis_updtsts_tlast : in std_logic ; -- -- Update Pointer Stream -- s_axis2_updtptr_tdata : in std_logic_vector -- (C_S_AXIS_UPDPTR_TDATA_WIDTH-1 downto 0) ; -- s_axis2_updtptr_tvalid : in std_logic ; -- s_axis2_updtptr_tready : out std_logic ; -- s_axis2_updtptr_tlast : in std_logic ; -- -- -- Update Status Stream -- s_axis2_updtsts_tdata : in std_logic_vector -- (C_S_AXIS_UPDSTS_TDATA_WIDTH-1 downto 0); -- s_axis2_updtsts_tvalid : in std_logic ; -- s_axis2_updtsts_tready : out std_logic ; -- s_axis2_updtsts_tlast : in std_logic ; -- -- --*********************************-- -- --** Channel Update Interface Out**-- -- --*********************************-- -- -- S2MM Stream Out To DataMover -- m_axis_updt_tdata : out std_logic_vector -- (C_M_AXIS_UPDT_DATA_WIDTH-1 downto 0); -- m_axis_updt_tlast : out std_logic ; -- m_axis_updt_tvalid : out std_logic ; -- m_axis_updt_tready : in std_logic -- ); end axi_sg_updt_noqueue; ------------------------------------------------------------------------------- -- Architecture ------------------------------------------------------------------------------- architecture implementation of axi_sg_updt_noqueue is attribute DowngradeIPIdentifiedWarnings: string; attribute DowngradeIPIdentifiedWarnings of implementation : architecture is "yes"; ------------------------------------------------------------------------------- -- Functions ------------------------------------------------------------------------------- -- No Functions Declared ------------------------------------------------------------------------------- -- Constants Declarations ------------------------------------------------------------------------------- -- No Contstants Declared ------------------------------------------------------------------------------- -- Signal / Type Declarations ------------------------------------------------------------------------------- -- Channel signals signal writing_curdesc : std_logic := '0'; signal write_curdesc_lsb : std_logic := '0'; signal write_curdesc_msb : std_logic := '0'; signal updt_active_d1 : std_logic := '0'; signal updt_active_re : std_logic := '0'; type PNTR_STATE_TYPE is (IDLE, READ_CURDESC_LSB, READ_CURDESC_MSB, WRITE_STATUS ); signal pntr_cs : PNTR_STATE_TYPE; signal pntr_ns : PNTR_STATE_TYPE; signal writing_status : std_logic := '0'; signal curdesc_tready : std_logic := '0'; signal writing_status_d1 : std_logic := '0'; signal writing_status_re : std_logic := '0'; signal writing_status_re_ch1 : std_logic := '0'; signal writing_status_re_ch2 : std_logic := '0'; signal updt_active_int : std_logic := '0'; signal s_axis_updtptr_tvalid_int : std_logic := '0'; signal s_axis_updtsts_tvalid_int : std_logic := '0'; signal s_axis_updtsts_tlast_int : std_logic := '0'; signal s_axis_updtptr_tdata_int : std_logic_vector (C_S_AXIS_UPDPTR_TDATA_WIDTH-1 downto 0) := (others => '0'); signal s_axis_qual : std_logic := '0'; signal s_axis2_qual : std_logic := '0'; signal m_axis_updt_tdata_mm2s : std_logic_vector (31 downto 0); -- signal m_axis_updt_tlast_mm2s : std_logic ; -- signal m_axis_updt_tvalid_mm2s : std_logic ; signal m_axis_updt_tdata_s2mm : std_logic_vector (31 downto 0); -- signal m_axis_updt_tlast_s2mm : std_logic ; -- signal m_axis_updt_tvalid_s2mm : std_logic ; ------------------------------------------------------------------------------- -- Begin architecture logic ------------------------------------------------------------------------------- begin m_axis_updt_tdata <= m_axis_updt_tdata_mm2s when updt_active = '1' else m_axis_updt_tdata_s2mm; m_axis_updt_tvalid <= m_axis_updt_tvalid_mm2s when updt_active = '1' else m_axis_updt_tvalid_s2mm; m_axis_updt_tlast <= m_axis_updt_tlast_mm2s when updt_active = '1' else m_axis_updt_tlast_s2mm; updt_active_int <= updt_active or updt2_active; s_axis_updtptr_tvalid_int <= s_axis_updtptr_tvalid or s_axis2_updtptr_tvalid; s_axis_updtsts_tvalid_int <= s_axis_updtsts_tvalid or s_axis2_updtsts_tvalid; s_axis_updtsts_tlast_int <= s_axis_updtsts_tlast or s_axis2_updtsts_tlast; s_axis_qual <= s_axis_updtsts_tvalid and s_axis_updtsts_tlast and updt_active; s_axis2_qual <= s_axis2_updtsts_tvalid and s_axis2_updtsts_tlast and updt2_active; -- Asset active strobe on rising edge of update active -- asertion. This kicks off the update process for -- the channel REG_ACTIVE : process(m_axi_sg_aclk) begin if(m_axi_sg_aclk'EVENT and m_axi_sg_aclk = '1')then if(m_axi_sg_aresetn = '0')then updt_active_d1 <= '0'; else updt_active_d1 <= updt_active or updt2_active; end if; end if; end process REG_ACTIVE; updt_active_re <= (updt_active or updt2_active) and not updt_active_d1; -- Current Descriptor Pointer Fetch. This state machine controls -- reading out the current pointer from the Queue or channel port -- and writing it to the update manager for use in command -- generation to the DataMover for Descriptor update. CURDESC_PNTR_STATE : process(pntr_cs, updt_active_int, s_axis_updtptr_tvalid_int, updt_active, updt2_active, s_axis_qual, s_axis2_qual, s_axis_updtptr_tvalid, s_axis2_updtptr_tvalid, s_axis_updtsts_tvalid_int, m_axis_updt_tready) begin write_curdesc_lsb <= '0'; write_curdesc_msb <= '0'; writing_status <= '0'; writing_curdesc <= '0'; curdesc_tready <= '0'; pntr_ns <= pntr_cs; case pntr_cs is when IDLE => if((s_axis_updtptr_tvalid = '1' and updt_active = '1') or (s_axis2_updtptr_tvalid = '1' and updt2_active = '1')) then writing_curdesc <= '1'; pntr_ns <= READ_CURDESC_LSB; else pntr_ns <= IDLE; end if; --------------------------------------------------------------- -- Get lower current descriptor when READ_CURDESC_LSB => curdesc_tready <= '1'; writing_curdesc <= '1'; -- on tvalid from Queue or channel port then register -- lsb curdesc and setup to register msb curdesc if(s_axis_updtptr_tvalid_int = '1' and updt_active_int = '1')then write_curdesc_lsb <= '1'; -- pntr_ns <= READ_CURDESC_MSB; pntr_ns <= WRITE_STATUS; else -- coverage off pntr_ns <= READ_CURDESC_LSB; -- coverage on end if; -- coverage off --------------------------------------------------------------- -- Get upper current descriptor when READ_CURDESC_MSB => curdesc_tready <= '1'; writing_curdesc <= '1'; -- On tvalid from Queue or channel port then register -- msb. This will also write curdesc out to update -- manager. if(s_axis_updtptr_tvalid_int = '1')then write_curdesc_msb <= '1'; pntr_ns <= WRITE_STATUS; else pntr_ns <= READ_CURDESC_MSB; end if; -- coverage on --------------------------------------------------------------- -- Hold in this state until remainder of descriptor is -- written out. when WRITE_STATUS => writing_status <= '1'; --s_axis_updtsts_tvalid_int; if((s_axis_qual = '1' and m_axis_updt_tready = '1') or (s_axis2_qual = '1' and m_axis_updt_tready = '1')) then pntr_ns <= IDLE; else pntr_ns <= WRITE_STATUS; end if; -- coverage off when others => pntr_ns <= IDLE; -- coverage on end case; end process CURDESC_PNTR_STATE; --------------------------------------------------------------------------- -- Register for CURDESC Pointer state machine --------------------------------------------------------------------------- REG_PNTR_STATES : process(m_axi_sg_aclk) begin if(m_axi_sg_aclk'EVENT and m_axi_sg_aclk = '1')then if(m_axi_sg_aresetn = '0')then pntr_cs <= IDLE; else pntr_cs <= pntr_ns; end if; end if; end process REG_PNTR_STATES; -- Status stream signals m_axis_updt_tdata_mm2s <= s_axis_updtsts_tdata(C_S_AXIS_UPDSTS_TDATA_WIDTH-2 downto 0); m_axis_updt_tvalid_mm2s <= s_axis_updtsts_tvalid and writing_status; m_axis_updt_tlast_mm2s <= s_axis_updtsts_tlast and writing_status; s_axis_updtsts_tready <= m_axis_updt_tready and writing_status and updt_active; -- Pointer stream signals s_axis_updtptr_tready <= curdesc_tready and updt_active; -- Indicate need for channel service for update state machine updt_queue_empty <= not (s_axis_updtsts_tvalid); -- and writing_status); m_axis_updt_tdata_s2mm <= s_axis2_updtsts_tdata(C_S_AXIS_UPDSTS_TDATA_WIDTH-2 downto 0); m_axis_updt_tvalid_s2mm <= s_axis2_updtsts_tvalid and writing_status; m_axis_updt_tlast_s2mm <= s_axis2_updtsts_tlast and writing_status; s_axis2_updtsts_tready <= m_axis_updt_tready and writing_status and updt2_active; -- Pointer stream signals s_axis2_updtptr_tready <= curdesc_tready and updt2_active; -- Indicate need for channel service for update state machine updt2_queue_empty <= not (s_axis2_updtsts_tvalid); -- and writing_status); --********************************************************************* --** POINTER CAPTURE LOGIC --********************************************************************* s_axis_updtptr_tdata_int <= s_axis_updtptr_tdata when (updt_active = '1') else s_axis2_updtptr_tdata; --------------------------------------------------------------------------- -- Write lower order Next Descriptor Pointer out to pntr_mngr --------------------------------------------------------------------------- REG_LSB_CURPNTR : process(m_axi_sg_aclk) begin if(m_axi_sg_aclk'EVENT and m_axi_sg_aclk = '1')then if(m_axi_sg_aresetn = '0' )then updt_curdesc(31 downto 0) <= (others => '0'); -- Capture lower pointer from FIFO or channel port elsif(write_curdesc_lsb = '1')then updt_curdesc(31 downto 0) <= s_axis_updtptr_tdata_int(C_S_AXIS_UPDPTR_TDATA_WIDTH - 1 downto 0); end if; end if; end process REG_LSB_CURPNTR; --------------------------------------------------------------------------- -- 64 Bit Scatter Gather addresses enabled --------------------------------------------------------------------------- GEN_UPPER_MSB_CURDESC : if C_M_AXI_SG_ADDR_WIDTH = 64 generate begin --------------------------------------------------------------------------- -- Write upper order Next Descriptor Pointer out to pntr_mngr --------------------------------------------------------------------------- REG_MSB_CURPNTR : process(m_axi_sg_aclk) begin if(m_axi_sg_aclk'EVENT and m_axi_sg_aclk = '1')then if(m_axi_sg_aresetn = '0' )then updt_curdesc(63 downto 32) <= (others => '0'); updt_curdesc_wren <= '0'; -- Capture upper pointer from FIFO or channel port -- and also write curdesc out elsif(write_curdesc_msb = '1')then updt_curdesc(63 downto 32) <= s_axis_updtptr_tdata(C_S_AXIS_UPDPTR_TDATA_WIDTH - 1 downto 0); updt_curdesc_wren <= '1'; -- Assert tready/wren for only 1 clock else updt_curdesc_wren <= '0'; end if; end if; end process REG_MSB_CURPNTR; end generate GEN_UPPER_MSB_CURDESC; --------------------------------------------------------------------------- -- 32 Bit Scatter Gather addresses enabled --------------------------------------------------------------------------- GEN_NO_UPR_MSB_CURDESC : if C_M_AXI_SG_ADDR_WIDTH = 32 generate begin ----------------------------------------------------------------------- -- No upper order therefore dump fetched word and write pntr lower next -- pointer to pntr mngr ----------------------------------------------------------------------- REG_MSB_CURPNTR : process(m_axi_sg_aclk) begin if(m_axi_sg_aclk'EVENT and m_axi_sg_aclk = '1')then if(m_axi_sg_aresetn = '0' )then updt_curdesc_wren <= '0'; -- Throw away second word, only write curdesc out with msb -- set to zero elsif(write_curdesc_lsb = '1')then -- elsif(write_curdesc_msb = '1')then updt_curdesc_wren <= '1'; -- Assert for only 1 clock else updt_curdesc_wren <= '0'; end if; end if; end process REG_MSB_CURPNTR; end generate GEN_NO_UPR_MSB_CURDESC; --********************************************************************* --** ERROR CAPTURE LOGIC --********************************************************************* ----------------------------------------------------------------------- -- Generate rising edge pulse on writing status signal. This will -- assert at the beginning of the status write. Coupled with status -- fifo set to first word fall through status will be on dout -- regardless of target ready. ----------------------------------------------------------------------- REG_WRITE_STATUS : process(m_axi_sg_aclk) begin if(m_axi_sg_aclk'EVENT and m_axi_sg_aclk = '1')then if(m_axi_sg_aresetn = '0')then writing_status_d1 <= '0'; else writing_status_d1 <= writing_status; end if; end if; end process REG_WRITE_STATUS; writing_status_re <= writing_status and not writing_status_d1; writing_status_re_ch1 <= writing_status_re and updt_active; writing_status_re_ch2 <= writing_status_re and updt2_active; --------------------------------------------------------------------------- -- Caputure IOC begin set --------------------------------------------------------------------------- REG_IOC_PROCESS : process(m_axi_sg_aclk) begin if(m_axi_sg_aclk'EVENT and m_axi_sg_aclk = '1')then if(m_axi_sg_aresetn = '0' or updt_ioc_irq_set = '1')then updt_ioc <= '0'; elsif(writing_status_re_ch1 = '1')then updt_ioc <= s_axis_updtsts_tdata(DESC_IOC_TAG_BIT); end if; end if; end process REG_IOC_PROCESS; ----------------------------------------------------------------------- -- Capture DMA Internal Errors ----------------------------------------------------------------------- CAPTURE_DMAINT_ERROR: process(m_axi_sg_aclk) begin if(m_axi_sg_aclk'EVENT and m_axi_sg_aclk = '1')then if(m_axi_sg_aresetn = '0' or dma_interr_set = '1')then dma_interr <= '0'; elsif(writing_status_re_ch1 = '1')then dma_interr <= s_axis_updtsts_tdata(DESC_STS_INTERR_BIT); end if; end if; end process CAPTURE_DMAINT_ERROR; ----------------------------------------------------------------------- -- Capture DMA Slave Errors ----------------------------------------------------------------------- CAPTURE_DMASLV_ERROR: process(m_axi_sg_aclk) begin if(m_axi_sg_aclk'EVENT and m_axi_sg_aclk = '1')then if(m_axi_sg_aresetn = '0' or dma_slverr_set = '1')then dma_slverr <= '0'; elsif(writing_status_re_ch1 = '1')then dma_slverr <= s_axis_updtsts_tdata(DESC_STS_SLVERR_BIT); end if; end if; end process CAPTURE_DMASLV_ERROR; ----------------------------------------------------------------------- -- Capture DMA Decode Errors ----------------------------------------------------------------------- CAPTURE_DMADEC_ERROR: process(m_axi_sg_aclk) begin if(m_axi_sg_aclk'EVENT and m_axi_sg_aclk = '1')then if(m_axi_sg_aresetn = '0' or dma_decerr_set = '1')then dma_decerr <= '0'; elsif(writing_status_re_ch1 = '1')then dma_decerr <= s_axis_updtsts_tdata(DESC_STS_DECERR_BIT); end if; end if; end process CAPTURE_DMADEC_ERROR; --------------------------------------------------------------------------- -- Caputure IOC begin set --------------------------------------------------------------------------- REG2_IOC_PROCESS : process(m_axi_sg_aclk) begin if(m_axi_sg_aclk'EVENT and m_axi_sg_aclk = '1')then if(m_axi_sg_aresetn = '0' or updt2_ioc_irq_set = '1')then updt2_ioc <= '0'; elsif(writing_status_re_ch2 = '1')then updt2_ioc <= s_axis2_updtsts_tdata(DESC_IOC_TAG_BIT); end if; end if; end process REG2_IOC_PROCESS; ----------------------------------------------------------------------- -- Capture DMA Internal Errors ----------------------------------------------------------------------- CAPTURE2_DMAINT_ERROR: process(m_axi_sg_aclk) begin if(m_axi_sg_aclk'EVENT and m_axi_sg_aclk = '1')then if(m_axi_sg_aresetn = '0' or dma2_interr_set = '1')then dma2_interr <= '0'; elsif(writing_status_re_ch2 = '1')then dma2_interr <= s_axis2_updtsts_tdata(DESC_STS_INTERR_BIT); end if; end if; end process CAPTURE2_DMAINT_ERROR; ----------------------------------------------------------------------- -- Capture DMA Slave Errors ----------------------------------------------------------------------- CAPTURE2_DMASLV_ERROR: process(m_axi_sg_aclk) begin if(m_axi_sg_aclk'EVENT and m_axi_sg_aclk = '1')then if(m_axi_sg_aresetn = '0' or dma2_slverr_set = '1')then dma2_slverr <= '0'; elsif(writing_status_re_ch2 = '1')then dma2_slverr <= s_axis2_updtsts_tdata(DESC_STS_SLVERR_BIT); end if; end if; end process CAPTURE2_DMASLV_ERROR; ----------------------------------------------------------------------- -- Capture DMA Decode Errors ----------------------------------------------------------------------- CAPTURE2_DMADEC_ERROR: process(m_axi_sg_aclk) begin if(m_axi_sg_aclk'EVENT and m_axi_sg_aclk = '1')then if(m_axi_sg_aresetn = '0' or dma2_decerr_set = '1')then dma2_decerr <= '0'; elsif(writing_status_re_ch2 = '1')then dma2_decerr <= s_axis2_updtsts_tdata(DESC_STS_DECERR_BIT); end if; end if; end process CAPTURE2_DMADEC_ERROR; end implementation;

gpl-3.0

9f9ea00202212e89b3e97678d602f678

0.403356

4.911315

false

mistryalok/Zedboard

learning/training/MSD/s09/axi_dma_sg/vivado/project_1/project_1.srcs/sources_1/ipshared/xilinx.com/axi_dma_v7_1/2a047f91/hdl/src/vhdl/axi_dma_afifo_autord.vhd

3

17,911

-- (c) Copyright 2012 Xilinx, Inc. All rights reserved. -- -- This file contains confidential and proprietary information -- of Xilinx, Inc. and is protected under U.S. and -- international copyright and other intellectual property -- laws. -- -- DISCLAIMER -- This disclaimer is not a license and does not grant any -- rights to the materials distributed herewith. Except as -- otherwise provided in a valid license issued to you by -- Xilinx, and to the maximum extent permitted by applicable -- law: (1) THESE MATERIALS ARE MADE AVAILABLE "AS IS" AND -- WITH ALL FAULTS, AND XILINX HEREBY DISCLAIMS ALL WARRANTIES -- AND CONDITIONS, EXPRESS, IMPLIED, OR STATUTORY, INCLUDING -- BUT NOT LIMITED TO WARRANTIES OF MERCHANTABILITY, NON- -- INFRINGEMENT, OR FITNESS FOR ANY PARTICULAR PURPOSE; and -- (2) Xilinx shall not be liable (whether in contract or tort, -- including negligence, or under any other theory of -- liability) for any loss or damage of any kind or nature -- related to, arising under or in connection with these -- materials, including for any direct, or any indirect, -- special, incidental, or consequential loss or damage -- (including loss of data, profits, goodwill, or any type of -- loss or damage suffered as a result of any action brought -- by a third party) even if such damage or loss was -- reasonably foreseeable or Xilinx had been advised of the -- possibility of the same. -- -- CRITICAL APPLICATIONS -- Xilinx products are not designed or intended to be fail- -- safe, or for use in any application requiring fail-safe -- performance, such as life-support or safety devices or -- systems, Class III medical devices, nuclear facilities, -- applications related to the deployment of airbags, or any -- other applications that could lead to death, personal -- injury, or severe property or environmental damage -- (individually and collectively, "Critical -- Applications"). Customer assumes the sole risk and -- liability of any use of Xilinx products in Critical -- Applications, subject only to applicable laws and -- regulations governing limitations on product liability. -- -- THIS COPYRIGHT NOTICE AND DISCLAIMER MUST BE RETAINED AS -- PART OF THIS FILE AT ALL TIMES. ------------------------------------------------------------ -- ************************************************************************* -- ------------------------------------------------------------------------------- -- Filename: axi_dma_afifo_autord.vhd -- Version: initial -- Description: -- This file contains the logic to generate a CoreGen call to create a -- asynchronous FIFO as part of the synthesis process of XST. This eliminates -- the need for multiple fixed netlists for various sizes and widths of FIFOs. -- -- -- VHDL-Standard: VHDL'93 ------------------------------------------------------------------------------- library IEEE; use IEEE.std_logic_1164.all; use IEEE.std_logic_arith.all; use IEEE.std_logic_unsigned.all; library lib_cdc_v1_0; library lib_fifo_v1_0; use lib_fifo_v1_0.async_fifo_fg; library axi_dma_v7_1; use axi_dma_v7_1.axi_dma_pkg.all; ----------------------------------------------------------------------------- -- Entity section ----------------------------------------------------------------------------- entity axi_dma_afifo_autord is generic ( C_DWIDTH : integer := 32; C_DEPTH : integer := 16; C_CNT_WIDTH : Integer := 5; C_USE_BLKMEM : Integer := 0 ; C_USE_AUTORD : Integer := 1; C_PRMRY_IS_ACLK_ASYNC : integer := 1; C_FAMILY : String := "virtex7" ); port ( -- Inputs AFIFO_Ainit : In std_logic; -- AFIFO_Wr_clk : In std_logic; -- AFIFO_Wr_en : In std_logic; -- AFIFO_Din : In std_logic_vector(C_DWIDTH-1 downto 0); -- AFIFO_Rd_clk : In std_logic; -- AFIFO_Rd_en : In std_logic; -- AFIFO_Clr_Rd_Data_Valid : In std_logic; -- -- -- Outputs -- AFIFO_DValid : Out std_logic; -- AFIFO_Dout : Out std_logic_vector(C_DWIDTH-1 downto 0); -- AFIFO_Full : Out std_logic; -- AFIFO_Empty : Out std_logic; -- AFIFO_Almost_full : Out std_logic; -- AFIFO_Almost_empty : Out std_logic; -- AFIFO_Wr_count : Out std_logic_vector(C_CNT_WIDTH-1 downto 0); -- AFIFO_Rd_count : Out std_logic_vector(C_CNT_WIDTH-1 downto 0); -- AFIFO_Corr_Rd_count : Out std_logic_vector(C_CNT_WIDTH downto 0); -- AFIFO_Corr_Rd_count_minus1 : Out std_logic_vector(C_CNT_WIDTH downto 0); -- AFIFO_Rd_ack : Out std_logic -- ); end entity axi_dma_afifo_autord; ----------------------------------------------------------------------------- -- Architecture section ----------------------------------------------------------------------------- architecture imp of axi_dma_afifo_autord is attribute DowngradeIPIdentifiedWarnings: string; attribute DowngradeIPIdentifiedWarnings of imp : architecture is "yes"; -- Constant declarations ATTRIBUTE async_reg : STRING; -- Signal declarations signal write_data_lil_end : std_logic_vector(C_DWIDTH-1 downto 0) := (others => '0'); signal read_data_lil_end : std_logic_vector(C_DWIDTH-1 downto 0) := (others => '0'); signal wr_count_lil_end : std_logic_vector(C_CNT_WIDTH-1 downto 0) := (others => '0'); signal rd_count_lil_end : std_logic_vector(C_CNT_WIDTH-1 downto 0) := (others => '0'); signal rd_count_int : integer range 0 to C_DEPTH+1 := 0; signal rd_count_int_corr : integer range 0 to C_DEPTH+1 := 0; signal rd_count_int_corr_minus1 : integer range 0 to C_DEPTH+1 := 0; Signal corrected_empty : std_logic := '0'; Signal corrected_almost_empty : std_logic := '0'; Signal sig_afifo_empty : std_logic := '0'; Signal sig_afifo_almost_empty : std_logic := '0'; -- backend fifo read ack sample and hold Signal sig_rddata_valid : std_logic := '0'; Signal hold_ff_q : std_logic := '0'; Signal ored_ack_ff_reset : std_logic := '0'; Signal autoread : std_logic := '0'; Signal sig_wrfifo_rdack : std_logic := '0'; Signal fifo_read_enable : std_logic := '0'; Signal first_write : std_logic := '0'; Signal first_read_cdc_tig : std_logic := '0'; Signal first_read1 : std_logic := '0'; Signal first_read2 : std_logic := '0'; signal AFIFO_Ainit_d1_cdc_tig : std_logic; signal AFIFO_Ainit_d2 : std_logic; --ATTRIBUTE async_reg OF AFIFO_Ainit_d1_cdc_tig : SIGNAL IS "true"; --ATTRIBUTE async_reg OF AFIFO_Ainit_d2 : SIGNAL IS "true"; --ATTRIBUTE async_reg OF first_read_cdc_tig : SIGNAL IS "true"; --ATTRIBUTE async_reg OF first_read1 : SIGNAL IS "true"; -- Component declarations ----------------------------------------------------------------------------- -- Begin architecture ----------------------------------------------------------------------------- begin -- Bit ordering translations write_data_lil_end <= AFIFO_Din; -- translate from Big Endian to little -- endian. AFIFO_Rd_ack <= sig_wrfifo_rdack; AFIFO_Dout <= read_data_lil_end; -- translate from Little Endian to -- Big endian. AFIFO_Almost_empty <= corrected_almost_empty; GEN_EMPTY : if (C_USE_AUTORD = 1) generate begin AFIFO_Empty <= corrected_empty; end generate GEN_EMPTY; GEN_EMPTY1 : if (C_USE_AUTORD = 0) generate begin AFIFO_Empty <= sig_afifo_empty; end generate GEN_EMPTY1; AFIFO_Wr_count <= wr_count_lil_end; AFIFO_Rd_count <= rd_count_lil_end; AFIFO_Corr_Rd_count <= CONV_STD_LOGIC_VECTOR(rd_count_int_corr, C_CNT_WIDTH+1); AFIFO_Corr_Rd_count_minus1 <= CONV_STD_LOGIC_VECTOR(rd_count_int_corr_minus1, C_CNT_WIDTH+1); AFIFO_DValid <= sig_rddata_valid; -- Output data valid indicator fifo_read_enable <= AFIFO_Rd_en or autoread; ------------------------------------------------------------------------------- -- Instantiate the CoreGen FIFO -- -- NOTE: -- This instance refers to a wrapper file that interm will use the -- CoreGen FIFO Generator Async FIFO utility. -- ------------------------------------------------------------------------------- I_ASYNC_FIFOGEN_FIFO : entity lib_fifo_v1_0.async_fifo_fg generic map ( -- C_ALLOW_2N_DEPTH => 1, C_ALLOW_2N_DEPTH => 0, C_FAMILY => C_FAMILY, C_DATA_WIDTH => C_DWIDTH, C_ENABLE_RLOCS => 0, C_FIFO_DEPTH => C_DEPTH, C_HAS_ALMOST_EMPTY => 1, C_HAS_ALMOST_FULL => 1, C_HAS_RD_ACK => 1, C_HAS_RD_COUNT => 1, C_HAS_RD_ERR => 0, C_HAS_WR_ACK => 0, C_HAS_WR_COUNT => 1, C_HAS_WR_ERR => 0, C_RD_ACK_LOW => 0, C_RD_COUNT_WIDTH => C_CNT_WIDTH, C_RD_ERR_LOW => 0, C_USE_BLOCKMEM => C_USE_BLKMEM, C_WR_ACK_LOW => 0, C_WR_COUNT_WIDTH => C_CNT_WIDTH, C_WR_ERR_LOW => 0, C_SYNCHRONIZER_STAGE => C_FIFO_MTBF -- C_USE_EMBEDDED_REG => 1, -- 0 ; -- C_PRELOAD_REGS => 0, -- 0 ; -- C_PRELOAD_LATENCY => 1 -- 1 ; ) port Map ( Din => write_data_lil_end, Wr_en => AFIFO_Wr_en, Wr_clk => AFIFO_Wr_clk, Rd_en => fifo_read_enable, Rd_clk => AFIFO_Rd_clk, Ainit => AFIFO_Ainit, Dout => read_data_lil_end, Full => AFIFO_Full, Empty => sig_afifo_empty, Almost_full => AFIFO_Almost_full, Almost_empty => sig_afifo_almost_empty, Wr_count => wr_count_lil_end, Rd_count => rd_count_lil_end, Rd_ack => sig_wrfifo_rdack, Rd_err => open, -- Not used by axi_dma Wr_ack => open, -- Not used by axi_dma Wr_err => open -- Not used by axi_dma ); ---------------------------------------------------------------------------- -- Read Ack assert & hold logic (needed because: -- 1) The Async FIFO has to be read once to get valid -- data to the read data port (data is discarded). -- 2) The Read ack from the fifo is only asserted for 1 clock. -- 3) A signal is needed that indicates valid data is at the read -- port of the FIFO and has not yet been read. This signal needs -- to be held until the next read operation occurs or a clear -- signal is received. ored_ack_ff_reset <= fifo_read_enable or AFIFO_Ainit_d2 or AFIFO_Clr_Rd_Data_Valid; sig_rddata_valid <= hold_ff_q or sig_wrfifo_rdack; ------------------------------------------------------------- -- Synchronous Process with Sync Reset -- -- Label: IMP_ACK_HOLD_FLOP -- -- Process Description: -- Flop for registering the hold flag -- ------------------------------------------------------------- ASYNC_CDC_SYNC : if C_PRMRY_IS_ACLK_ASYNC = 1 generate IMP_SYNC_FLOP : entity lib_cdc_v1_0.cdc_sync generic map ( C_CDC_TYPE => 1, C_RESET_STATE => 0, C_SINGLE_BIT => 1, C_VECTOR_WIDTH => 32, C_MTBF_STAGES => MTBF_STAGES ) port map ( prmry_aclk => '0', prmry_resetn => '0', prmry_in => AFIFO_Ainit, prmry_vect_in => (others => '0'), scndry_aclk => AFIFO_Rd_clk, scndry_resetn => '0', scndry_out => AFIFO_Ainit_d2, scndry_vect_out => open ); end generate ASYNC_CDC_SYNC; SYNC_CDC_SYNC : if C_PRMRY_IS_ACLK_ASYNC = 0 generate AFIFO_Ainit_d2 <= AFIFO_Ainit; end generate SYNC_CDC_SYNC; -- IMP_SYNC_FLOP : process (AFIFO_Rd_clk) -- begin -- if (AFIFO_Rd_clk'event and AFIFO_Rd_clk = '1') then -- AFIFO_Ainit_d1_cdc_tig <= AFIFO_Ainit; -- AFIFO_Ainit_d2 <= AFIFO_Ainit_d1_cdc_tig; -- end if; -- end process IMP_SYNC_FLOP; IMP_ACK_HOLD_FLOP : process (AFIFO_Rd_clk) begin if (AFIFO_Rd_clk'event and AFIFO_Rd_clk = '1') then if (ored_ack_ff_reset = '1') then hold_ff_q <= '0'; else hold_ff_q <= sig_rddata_valid; end if; end if; end process IMP_ACK_HOLD_FLOP; -- I_ACK_HOLD_FF : FDRE -- port map( -- Q => hold_ff_q, -- C => AFIFO_Rd_clk, -- CE => '1', -- D => sig_rddata_valid, -- R => ored_ack_ff_reset -- ); -- generate auto-read enable. This keeps fresh data at the output -- of the FIFO whenever it is available. GEN_AUTORD1 : if C_USE_AUTORD = 1 generate autoread <= '1' -- create a read strobe when the when (sig_rddata_valid = '0' and -- output data is NOT valid sig_afifo_empty = '0') -- and the FIFO is not empty Else '0'; end generate GEN_AUTORD1; GEN_AUTORD2 : if C_USE_AUTORD = 0 generate process (AFIFO_Wr_clk) begin if (AFIFO_Wr_clk'event and AFIFO_Wr_clk = '1') then if (AFIFO_Ainit = '0') then first_write <= '0'; elsif (AFIFO_Wr_en = '1') then first_write <= '1'; end if; end if; end process; IMP_SYNC_FLOP1 : entity lib_cdc_v1_0.cdc_sync generic map ( C_CDC_TYPE => 1, C_RESET_STATE => 0, C_SINGLE_BIT => 1, C_VECTOR_WIDTH => 32, C_MTBF_STAGES => MTBF_STAGES ) port map ( prmry_aclk => '0', prmry_resetn => '0', prmry_in => first_write, prmry_vect_in => (others => '0'), scndry_aclk => AFIFO_Rd_clk, scndry_resetn => '0', scndry_out => first_read1, scndry_vect_out => open ); process (AFIFO_Rd_clk) begin if (AFIFO_Rd_clk'event and AFIFO_Rd_clk = '1') then if (AFIFO_Ainit_d2 = '0') then first_read2 <= '0'; elsif (sig_afifo_empty = '0') then first_read2 <= first_read1; end if; end if; end process; autoread <= first_read1 xor first_read2; end generate GEN_AUTORD2; rd_count_int <= CONV_INTEGER(rd_count_lil_end); ------------------------------------------------------------- -- Combinational Process -- -- Label: CORRECT_RD_CNT -- -- Process Description: -- This process corrects the FIFO Read Count output for the -- auto read function. -- ------------------------------------------------------------- CORRECT_RD_CNT : process (sig_rddata_valid, sig_afifo_empty, sig_afifo_almost_empty, rd_count_int) begin if (sig_rddata_valid = '0') then rd_count_int_corr <= 0; rd_count_int_corr_minus1 <= 0; corrected_empty <= '1'; corrected_almost_empty <= '0'; elsif (sig_afifo_empty = '1') then -- rddata valid and fifo empty rd_count_int_corr <= 1; rd_count_int_corr_minus1 <= 0; corrected_empty <= '0'; corrected_almost_empty <= '1'; Elsif (sig_afifo_almost_empty = '1') Then -- rddata valid and fifo almost empty rd_count_int_corr <= 2; rd_count_int_corr_minus1 <= 1; corrected_empty <= '0'; corrected_almost_empty <= '0'; else -- rddata valid and modify rd count from FIFO rd_count_int_corr <= rd_count_int+1; rd_count_int_corr_minus1 <= rd_count_int; corrected_empty <= '0'; corrected_almost_empty <= '0'; end if; end process CORRECT_RD_CNT; end imp;

gpl-3.0

22208a35fc5ccb8783b5d129aa75dbc2

0.475853

4.081814

false

Yuriu5/MiniBlaze

src/hw1/Sequencer.vhd

1

29,275

-- ********************************************************************************** -- Project : MiniBlaze -- Author : Benjamin Lemoine -- Module : Sequencer -- Date : 07/25/2016 -- -- Description : Sequencer of the core. Fetch, decode, execute and store. -- This implementation (v1) does not aim to be fast. There is -- no pipeline, memory access are slow. The goal is to have -- a functionnal core that can be played with. -- -- -------------------------------------------------------------------------------- -- Modifications -- -------------------------------------------------------------------------------- -- Date : Ver. : Author : Modification comments -- -------------------------------------------------------------------------------- -- : : : -- 07/25/2016 : 1.0 : B.Lemoine : First draft -- : : : -- ********************************************************************************** -- MIT License -- -- Copyright (c) 07/25/2016, Benjamin Lemoine -- -- Permission is hereby granted, free of charge, to any person obtaining a copy -- of this software and associated documentation files (the "Software"), to deal -- in the Software without restriction, including without limitation the rights -- to use, copy, modify, merge, publish, distribute, sublicense, and/or sell -- copies of the Software, and to permit persons to whom the Software is -- furnished to do so, subject to the following conditions: -- -- The above copyright notice and this permission notice shall be included in all -- copies or substantial portions of the Software. -- -- THE SOFTWARE IS PROVIDED "AS IS", WITHOUT WARRANTY OF ANY KIND, EXPRESS OR -- IMPLIED, INCLUDING BUT NOT LIMITED TO THE WARRANTIES OF MERCHANTABILITY, -- FITNESS FOR A PARTICULAR PURPOSE AND NONINFRINGEMENT. IN NO EVENT SHALL THE -- AUTHORS OR COPYRIGHT HOLDERS BE LIABLE FOR ANY CLAIM, DAMAGES OR OTHER -- LIABILITY, WHETHER IN AN ACTION OF CONTRACT, TORT OR OTHERWISE, ARISING FROM, -- OUT OF OR IN CONNECTION WITH THE SOFTWARE OR THE USE OR OTHER DEALINGS IN THE -- SOFTWARE. -- ********************************************************************************** library ieee; use ieee.std_logic_1164.all; use ieee.numeric_std.all; library work; use work.ALU_pkg.all; use work.spec_reg_pkg.all; entity sequencer is generic( D_WIDTH : natural := 32 ); port( -- Clock and reset clk : in std_logic; reset_n : in std_logic; -- Interface memory in data_mem_in_i : in std_logic_vector(D_WIDTH-1 downto 0); data_mem_in_en_i : in std_logic; addr_mem_in_o : out std_logic_vector(D_WIDTH-1 downto 0); rd_en_mem_in_o : out std_logic; -- Interface memory out addr_mem_out_o : out std_logic_vector(D_WIDTH-1 downto 0); data_mem_out_o : out std_logic_vector(D_WIDTH-1 downto 0); wr_en_mem_out_o : out std_logic_vector(3 downto 0) ); end sequencer; architecture rtl of sequencer is -- Components declaration component ALU is generic( DATA_WIDTH : natural := D_WIDTH ); port( param_i : in t_param_alu; carry_i : in std_logic; operandA_i : in std_logic_vector(DATA_WIDTH - 1 downto 0); operandB_i : in std_logic_vector(DATA_WIDTH - 1 downto 0); operandD_o : out std_logic_vector(DATA_WIDTH - 1 downto 0); status_o : out t_status_alu_out ); end component; -- Signals declaration type fsm_seq is (st_fetch, st_decode, st_execute); signal r_fsm_seq : fsm_seq := st_fetch; signal r_last_state : fsm_seq; -- Special purpose registers signal r_ProgramCounter : unsigned(D_WIDTH-1 downto 0) := (others => '0'); signal r_LastProgramCounter : unsigned(D_WIDTH-1 downto 0) := (others => '0'); signal r_MSR : std_logic_vector(D_WIDTH-1 downto 0) := (others => '0'); signal r_imm : std_logic_vector(D_WIDTH/2-1 downto 0) := (others => '0'); -- General purpose registers type vect_32x32b is array (0 to 31) of std_logic_vector(D_WIDTH-1 downto 0); signal v_GeneralReg : vect_32x32b := (others => (others => '0')); -- Mem in signal r_addr_mem_in : unsigned(D_WIDTH-1 downto 0) := (others => '0'); signal r_rd_en_mem_in : std_logic := '0'; signal s_instruction : std_logic_vector(D_WIDTH-1 downto 0) := (others => '0'); signal r_instruction : std_logic_vector(D_WIDTH-1 downto 0) := (others => '0'); -- Mem out signal r_wr_en_mem_out : std_logic_vector(3 downto 0) := (others => '0'); signal r_addr_mem_out : std_logic_vector(D_WIDTH-1 downto 0) := (others => '0'); signal r_data_mem_out : std_logic_vector(D_WIDTH-1 downto 0) := (others => '0'); -- ALU signal r_input_alu_A : std_logic_vector(D_WIDTH-1 downto 0) := (others => '0'); signal r_input_alu_B : std_logic_vector(D_WIDTH-1 downto 0) := (others => '0'); signal s_input_alu_B : std_logic_vector(D_WIDTH-1 downto 0) := (others => '0'); signal r_param_alu : t_param_alu := c_param_alu_null; signal s_carry_alu_in : std_logic := '0'; signal s_output_alu : std_logic_vector(D_WIDTH-1 downto 0) := (others => '0'); signal s_status_alu : t_status_alu_out := c_status_alu_out_null; -- Sequencer signal r_wr_carry_output : std_logic := '0'; signal r_allow_next_instruction : std_logic := '0'; signal r_isInstructionBranchDelay : std_logic := '0'; signal r_last_op_was_imm : std_logic := '0'; signal r_is_imm_instruction : std_logic := '0'; signal r_is_branch_cond : std_logic := '0'; signal r_is_branch_uncond : std_logic := '0'; signal r_is_load_instruction : std_logic := '0'; signal r_is_store_instruction : std_logic := '0'; signal r_load_store_exclusive : std_logic := '0'; signal r_rD_address : std_logic_vector(4 downto 0) := (others => '0'); signal r_return_from_subroutine : std_logic := '0'; signal r_branch_op : std_logic_vector(3 downto 0) := (others => '0'); signal r_op_load_store : std_logic_vector(1 downto 0) := (others => '0'); signal r_step_load : unsigned(1 downto 0) := (others => '0'); signal r_step_fetch : std_logic := '0'; type fsm_fetch is (st_set_address, st_wait_data); signal r_fsm_fetch : fsm_fetch := st_set_address; signal r_fsm_load : fsm_fetch := st_set_address; begin s_instruction <= data_mem_in_i; p_seq : process(clk) variable v_instruction_6_5 : std_logic_vector(1 downto 0); variable v_addr_mem_in_1_0 : unsigned(1 downto 0); variable v_output_alu_1_0 : std_logic_vector(1 downto 0); begin if rising_edge(clk) then if reset_n = '0' then r_fsm_seq <= st_fetch; r_last_state <= st_fetch; r_ProgramCounter <= (others => '0'); r_LastProgramCounter <= (others => '0'); r_fsm_fetch <= st_set_address; r_fsm_load <= st_set_address; else -- Default values r_rd_en_mem_in <= '0'; r_wr_en_mem_out <= (others => '0'); r_last_state <= r_fsm_seq; case r_fsm_seq is when st_fetch => -- Fetch instruction case r_fsm_fetch is when st_set_address => if r_isInstructionBranchDelay = '1' then r_addr_mem_in <= r_LastProgramCounter + 4; else r_addr_mem_in <= r_ProgramCounter; end if; r_rd_en_mem_in <= '1'; r_fsm_fetch <= st_wait_data; when st_wait_data => if data_mem_in_en_i = '1' then r_fsm_seq <= st_decode; r_instruction <= s_instruction; r_fsm_fetch <= st_set_address; end if; when others => r_fsm_fetch <= st_set_address; end case; when st_decode => report " ---- "; report integer'image(to_integer(r_ProgramCounter)); --default value r_input_alu_A <= v_GeneralReg(to_integer(unsigned(r_instruction(20 downto 16)))); r_param_alu.ctrl_op.whichCarry <= CARRY_INPUT; r_param_alu.ctrl_op.ctrlShift <= LEFT_SHIFT; r_param_alu.ctrl_op.negOperandA <= '0'; r_param_alu.ctrl_op.negOperandB <= '0'; r_param_alu.ctrl_op.multType <= LSW; r_wr_carry_output <= '0'; r_allow_next_instruction <= '0'; r_is_branch_cond <= '0'; r_is_branch_uncond <= '0'; r_is_load_instruction <= '0'; r_is_store_instruction <= '0'; r_load_store_exclusive <= '0'; r_return_from_subroutine <= '0'; r_is_imm_instruction <= '0'; r_fsm_load <= st_set_address; -- Next stage r_fsm_seq <= st_execute; -- Type A / Type B instruction if r_instruction(29) = '0' then -- rB r_input_alu_B <= v_GeneralReg(to_integer(unsigned(r_instruction(15 downto 11)))); else -- imm r_input_alu_B <= std_logic_vector(resize(unsigned(r_instruction(15 downto 0)), D_WIDTH)); end if; -- Store rD address r_rD_address <= r_instruction(25 downto 21); -- add, addc, addk, addkc, addi, addic, addik, addikc -- rsub, rsubi if (r_instruction(31 downto 30) = "00") then r_param_alu.operation <= OP_ADD; if r_instruction(27) = '1' then -- C Bit r_param_alu.ctrl_op.whichCarry <= CARRY_INPUT; else if r_instruction(26) = '1' then -- sub r_param_alu.ctrl_op.whichCarry <= CARRY_ONE; else -- add r_param_alu.ctrl_op.whichCarry <= CARRY_ZERO; end if; end if; if r_instruction(26) = '1' then -- Substrate bit r_param_alu.ctrl_op.negOperandA <= '1'; end if; r_wr_carry_output <= not r_instruction(28); -- and, andi elsif r_instruction(31 downto 30) = "10" and r_instruction(28 downto 26) = "001" then r_param_alu.operation <= OP_AND; -- andn, andni elsif r_instruction(31 downto 30) = "10" and r_instruction(28 downto 26) = "011" then r_param_alu.operation <= OP_AND; r_param_alu.ctrl_op.negOperandB <= r_instruction(27); -- or, ori elsif r_instruction(31 downto 30) = "10" and r_instruction(28 downto 26) = "000" then r_param_alu.operation <= OP_OR; -- xor, xori elsif r_instruction(31 downto 30) = "10" and r_instruction(28 downto 26) = "010" then r_param_alu.operation <= OP_XOR; -- conditional branch instructions elsif (r_instruction(31 downto 30) = "10") and (r_instruction(28 downto 26) = "111") then -- D bit, allow following instruction to complete exection r_allow_next_instruction <= r_instruction(25); r_is_branch_cond <= '1'; r_branch_op <= r_instruction(24 downto 21); r_param_alu.operation <= OP_PTA; -- unconditional branch instructions elsif (r_instruction(31 downto 30) = "10") and (r_instruction(28 downto 26) = "110") then r_allow_next_instruction <= r_instruction(20); r_is_branch_uncond <= '1'; r_branch_op <= r_instruction(19 downto 16); r_param_alu.operation <= OP_PTB; -- Barrel Shift : bsrl, bsra, bsll elsif (r_instruction(31 downto 30) = "01") and (r_instruction(28 downto 26) = "001") then r_param_alu.operation <= OP_BS; if r_instruction(10) = '1' then -- bit S (Side bit) r_param_alu.ctrl_op.ctrlShift <= LEFT_SHIFT; else if r_instruction(9) = '1' then -- bit T (Type bit) r_param_alu.ctrl_op.ctrlShift <= RIGHT_SHIFT_ARITH; else r_param_alu.ctrl_op.ctrlShift <= RIGHT_SHIFT_LOGIC; end if; end if; -- Integer Compare : cmp, cmpu elsif r_instruction(31 downto 26) = "000101" then r_param_alu.operation <= OP_ADD; r_param_alu.ctrl_op.whichCarry <= CARRY_ONE; r_param_alu.ctrl_op.negOperandA <= '1'; -- Immediate : imm elsif r_instruction(31 downto 26) = "101100" then r_is_imm_instruction <= '1'; r_param_alu.operation <= OP_PTB; -- Load/Store instruction elsif r_instruction(31 downto 30) = "11" then r_is_load_instruction <= not r_instruction(28); r_is_store_instruction <= r_instruction(28); r_op_load_store <= r_instruction(27 downto 26); r_param_alu.operation <= OP_ADD; r_param_alu.ctrl_op.whichCarry <= CARRY_ZERO; if r_instruction(10) = '1' and r_instruction(29) = '0' then r_load_store_exclusive <= '1'; end if; -- Multipy instruction : only mul, muli (C_USE_HW_MUL = '1') elsif r_instruction(31 downto 30) = "01" and r_instruction(28 downto 26) = "000" then r_param_alu.operation <= OP_MULT; -- Return from Subroutine elsif (r_instruction(31 downto 25) = "1011011") then r_allow_next_instruction <= '1'; r_param_alu.operation <= OP_ADD; r_param_alu.ctrl_op.whichCarry <= CARRY_ZERO; r_return_from_subroutine <= '1'; -- Sign Extend Halfword / Byte and Shift elsif (r_instruction(31 downto 26) = "100100") then if r_instruction(0) = '1' then v_instruction_6_5 := r_instruction(6 downto 5); case v_instruction_6_5 is -- SRA when "00" => r_param_alu.operation <= OP_SHIFT; r_param_alu.ctrl_op.whichCarry <= CARRY_ARITH; -- SRC when "01" => r_param_alu.operation <= OP_SHIFT; r_param_alu.ctrl_op.whichCarry <= CARRY_INPUT; r_wr_carry_output <= '1'; -- SRL when "10" => r_param_alu.operation <= OP_SHIFT; r_param_alu.ctrl_op.whichCarry <= CARRY_ZERO; r_wr_carry_output <= '1'; -- SEXT16 when others => r_param_alu.operation <= OP_SEXT16; r_param_alu.ctrl_op.whichCarry <= CARRY_ZERO; end case; else r_param_alu.operation <= OP_SEXT8; end if; end if; when st_execute => -- Go to fecth step unless we wait for a memory access r_fsm_seq <= st_fetch; r_isInstructionBranchDelay <= '0'; r_last_op_was_imm <= '0'; -- Increment r_ProgramCounter of 4 to fetch the next instruction -- Overwrite the value after if a branch is requested if(r_last_state /= st_execute and r_isInstructionBranchDelay = '0') then r_ProgramCounter <= r_ProgramCounter + 4; end if; -- Store ALU output v_GeneralReg(to_integer(unsigned(r_rD_address))) <= s_output_alu; -- Change MSR carry bit if needed if r_wr_carry_output = '1' then r_MSR(MSR_C) <= s_status_alu.carry; end if; -- Branch execution cond if r_is_branch_cond = '1' then v_GeneralReg(to_integer(unsigned(r_rD_address))) <= v_GeneralReg(to_integer(unsigned(r_rD_address))); if r_branch_op = "0000" and s_status_alu.zero = '1' then -- Branch if Equal r_ProgramCounter <= r_ProgramCounter + unsigned(v_GeneralReg(to_integer(unsigned(r_instruction(15 downto 11))))); elsif r_branch_op = "0101" and ((s_status_alu.negative = '0') or (s_status_alu.zero = '1')) then -- Branch if Greater or Equal r_ProgramCounter <= r_ProgramCounter + unsigned(v_GeneralReg(to_integer(unsigned(r_instruction(15 downto 11))))); elsif r_branch_op = "0100" and s_status_alu.negative = '0' then -- Branch if Greater Than r_ProgramCounter <= r_ProgramCounter + unsigned(v_GeneralReg(to_integer(unsigned(r_instruction(15 downto 11))))); elsif r_branch_op = "0011" and ((s_status_alu.negative = '1') or (s_status_alu.zero = '1')) then -- Branch if Less or Equal r_ProgramCounter <= r_ProgramCounter + unsigned(v_GeneralReg(to_integer(unsigned(r_instruction(15 downto 11))))); elsif r_branch_op = "0010" and s_status_alu.negative = '1' then -- Branch if Less Than r_ProgramCounter <= r_ProgramCounter + unsigned(v_GeneralReg(to_integer(unsigned(r_instruction(15 downto 11))))); elsif r_branch_op = "0001" and s_status_alu.zero = '0' then -- Branch if Not Equal r_ProgramCounter <= r_ProgramCounter + unsigned(v_GeneralReg(to_integer(unsigned(r_instruction(15 downto 11))))); end if; if r_allow_next_instruction = '1' then r_isInstructionBranchDelay <= '1'; r_LastProgramCounter <= r_ProgramCounter; end if; -- Return from subroutine elsif r_return_from_subroutine = '1' then r_ProgramCounter <= unsigned(s_output_alu); -- Branch execution uncond elsif r_is_branch_uncond = '1' then v_GeneralReg(to_integer(unsigned(r_rD_address))) <= v_GeneralReg(to_integer(unsigned(r_rD_address))); if r_branch_op(2) = '1' then -- L bit v_GeneralReg(to_integer(unsigned(r_rD_address))) <= std_logic_vector(r_ProgramCounter); end if; if r_branch_op(3) = '1' then -- A bit r_ProgramCounter <= unsigned(s_output_alu); else r_ProgramCounter <= r_ProgramCounter + unsigned(s_output_alu); end if; if r_allow_next_instruction = '1' then r_isInstructionBranchDelay <= '1'; r_LastProgramCounter <= r_ProgramCounter; end if; -- Note : Load & Write this way only works for one cycle access memory -- Load execution elsif r_is_load_instruction = '1' then v_GeneralReg(to_integer(unsigned(r_rD_address))) <= v_GeneralReg(to_integer(unsigned(r_rD_address))); r_fsm_seq <= st_execute; case r_fsm_load is when st_set_address => r_addr_mem_in <= unsigned(s_output_alu); r_rd_en_mem_in <= '1'; r_fsm_load <= st_wait_data; when st_wait_data => if data_mem_in_en_i = '1' then r_fsm_seq <= st_fetch; if r_op_load_store = "00" then v_addr_mem_in_1_0 := r_addr_mem_in(1 downto 0); case v_addr_mem_in_1_0 is when "00" => v_GeneralReg(to_integer(unsigned(r_rD_address))) <= x"000000" & data_mem_in_i(7 downto 0); when "01" => v_GeneralReg(to_integer(unsigned(r_rD_address))) <= x"000000" & data_mem_in_i(15 downto 8); when "10" => v_GeneralReg(to_integer(unsigned(r_rD_address))) <= x"000000" & data_mem_in_i(23 downto 16); when others => v_GeneralReg(to_integer(unsigned(r_rD_address))) <= x"000000" & data_mem_in_i(31 downto 24); end case; elsif r_op_load_store = "01" then v_addr_mem_in_1_0 := r_addr_mem_in(1 downto 0); case v_addr_mem_in_1_0 is when "00" => v_GeneralReg(to_integer(unsigned(r_rD_address))) <= x"0000" & data_mem_in_i(15 downto 0); when "10" => v_GeneralReg(to_integer(unsigned(r_rD_address))) <= x"0000" & data_mem_in_i(31 downto 16); when others => assert false report "Address non-aligned on 16b access" severity error; end case; elsif r_op_load_store = "10" then if r_addr_mem_in(1 downto 0) = "00" then v_GeneralReg(to_integer(unsigned(r_rD_address)))(31 downto 0) <= data_mem_in_i(31 downto 0); else assert false report "Address non-aligned on 32b access" severity error; end if; if r_load_store_exclusive = '1' then r_MSR(MSR_C) <= '0'; end if; end if; end if; when others => r_fsm_load <= st_set_address; end case; -- Store execution elsif r_is_store_instruction = '1' then v_GeneralReg(to_integer(unsigned(r_rD_address))) <= v_GeneralReg(to_integer(unsigned(r_rD_address))); r_addr_mem_out <= s_output_alu; if r_op_load_store = "00" then r_wr_en_mem_out(to_integer(unsigned(s_output_alu(1 downto 0)))) <= '1'; -- others are at '0' v_output_alu_1_0 := s_output_alu(1 downto 0); case v_output_alu_1_0 is when "00" => r_data_mem_out(7 downto 0) <= v_GeneralReg(to_integer(unsigned(r_rD_address)))(7 downto 0); when "01" => r_data_mem_out(15 downto 8) <= v_GeneralReg(to_integer(unsigned(r_rD_address)))(7 downto 0); when "10" => r_data_mem_out(23 downto 16) <= v_GeneralReg(to_integer(unsigned(r_rD_address)))(7 downto 0); when others => r_data_mem_out(31 downto 24) <= v_GeneralReg(to_integer(unsigned(r_rD_address)))(7 downto 0); end case; elsif r_op_load_store = "01" then if s_output_alu(1) = '0' then r_wr_en_mem_out <= "0011"; else r_wr_en_mem_out <= "1100"; end if; v_output_alu_1_0 := s_output_alu(1 downto 0); case v_output_alu_1_0 is when "00" => r_data_mem_out(15 downto 0) <= v_GeneralReg(to_integer(unsigned(r_rD_address)))(15 downto 0); when others => r_data_mem_out(31 downto 16) <= v_GeneralReg(to_integer(unsigned(r_rD_address)))(15 downto 0); end case; elsif r_op_load_store = "10" then r_wr_en_mem_out <= "1111"; r_data_mem_out <= v_GeneralReg(to_integer(unsigned(r_rD_address))); if r_load_store_exclusive = '1' then r_MSR(MSR_C) <= '0'; end if; end if; elsif r_is_imm_instruction = '1' then v_GeneralReg(to_integer(unsigned(r_rD_address))) <= v_GeneralReg(to_integer(unsigned(r_rD_address))); r_imm <= s_output_alu(15 downto 0); r_last_op_was_imm <= '1'; end if; end case; end if; end if; end process; -- Type B instruction, ALU input B depends of the precedent instruction s_input_alu_B <= r_input_alu_B when r_last_op_was_imm = '0' else (r_imm & r_input_alu_B(15 downto 0)); -- Carry input of the ALU depends of the bit C of the MSR s_carry_alu_in <= r_MSR(MSR_C); -- ALU i_ALU : ALU generic map( DATA_WIDTH => D_WIDTH ) port map( param_i => r_param_alu, carry_i => s_carry_alu_in, operandA_i => r_input_alu_A, operandB_i => s_input_alu_B, operandD_o => s_output_alu, status_o => s_status_alu ); -- =============================== -- Mapping output -- =============================== addr_mem_in_o <= std_logic_vector(r_addr_mem_in); rd_en_mem_in_o <= r_rd_en_mem_in; addr_mem_out_o <= r_addr_mem_out; data_mem_out_o <= r_data_mem_out; wr_en_mem_out_o <= r_wr_en_mem_out; end rtl;

mit

ce0cac8770c3f29c474c5a8523ed4fcf

0.439522

4.172011

false

mistryalok/Zedboard

learning/opencv_hls/xapp1167_vivado/sw/median/prj/solution1/syn/vhdl/FIFO_image_filter_img_0_cols_V_channel.vhd

4

4,628

-- ============================================================== -- File generated by Vivado(TM) HLS - High-Level Synthesis from C, C++ and SystemC -- Version: 2014.4 -- Copyright (C) 2014 Xilinx Inc. All rights reserved. -- -- ============================================================== library IEEE; use IEEE.std_logic_1164.all; use IEEE.std_logic_unsigned.all; entity FIFO_image_filter_img_0_cols_V_channel_shiftReg is generic ( DATA_WIDTH : integer := 12; ADDR_WIDTH : integer := 2; DEPTH : integer := 3); port ( clk : in std_logic; data : in std_logic_vector(DATA_WIDTH-1 downto 0); ce : in std_logic; a : in std_logic_vector(ADDR_WIDTH-1 downto 0); q : out std_logic_vector(DATA_WIDTH-1 downto 0)); end FIFO_image_filter_img_0_cols_V_channel_shiftReg; architecture rtl of FIFO_image_filter_img_0_cols_V_channel_shiftReg is --constant DEPTH_WIDTH: integer := 16; type SRL_ARRAY is array (0 to DEPTH-1) of std_logic_vector(DATA_WIDTH-1 downto 0); signal SRL_SIG : SRL_ARRAY; begin p_shift: process (clk) begin if (clk'event and clk = '1') then if (ce = '1') then SRL_SIG <= data & SRL_SIG(0 to DEPTH-2); end if; end if; end process; q <= SRL_SIG(conv_integer(a)); end rtl; library ieee; use ieee.std_logic_1164.all; use ieee.std_logic_unsigned.all; entity FIFO_image_filter_img_0_cols_V_channel is generic ( MEM_STYLE : string := "shiftreg"; DATA_WIDTH : integer := 12; ADDR_WIDTH : integer := 2; DEPTH : integer := 3); port ( clk : IN STD_LOGIC; reset : IN STD_LOGIC; if_empty_n : OUT STD_LOGIC; if_read_ce : IN STD_LOGIC; if_read : IN STD_LOGIC; if_dout : OUT STD_LOGIC_VECTOR(DATA_WIDTH - 1 downto 0); if_full_n : OUT STD_LOGIC; if_write_ce : IN STD_LOGIC; if_write : IN STD_LOGIC; if_din : IN STD_LOGIC_VECTOR(DATA_WIDTH - 1 downto 0)); end entity; architecture rtl of FIFO_image_filter_img_0_cols_V_channel is component FIFO_image_filter_img_0_cols_V_channel_shiftReg is generic ( DATA_WIDTH : integer := 12; ADDR_WIDTH : integer := 2; DEPTH : integer := 3); port ( clk : in std_logic; data : in std_logic_vector(DATA_WIDTH-1 downto 0); ce : in std_logic; a : in std_logic_vector(ADDR_WIDTH-1 downto 0); q : out std_logic_vector(DATA_WIDTH-1 downto 0)); end component; signal shiftReg_addr : STD_LOGIC_VECTOR(ADDR_WIDTH - 1 downto 0); signal shiftReg_data, shiftReg_q : STD_LOGIC_VECTOR(DATA_WIDTH - 1 downto 0); signal shiftReg_ce : STD_LOGIC; signal mOutPtr : STD_LOGIC_VECTOR(ADDR_WIDTH downto 0) := (others => '1'); signal internal_empty_n : STD_LOGIC := '0'; signal internal_full_n : STD_LOGIC := '1'; begin if_empty_n <= internal_empty_n; if_full_n <= internal_full_n; shiftReg_data <= if_din; if_dout <= shiftReg_q; process (clk) begin if clk'event and clk = '1' then if reset = '1' then mOutPtr <= (others => '1'); internal_empty_n <= '0'; internal_full_n <= '1'; else if ((if_read and if_read_ce) = '1' and internal_empty_n = '1') and ((if_write and if_write_ce) = '0' or internal_full_n = '0') then mOutPtr <= mOutPtr -1; if (mOutPtr = 0) then internal_empty_n <= '0'; end if; internal_full_n <= '1'; elsif ((if_read and if_read_ce) = '0' or internal_empty_n = '0') and ((if_write and if_write_ce) = '1' and internal_full_n = '1') then mOutPtr <= mOutPtr +1; internal_empty_n <= '1'; if (mOutPtr = DEPTH -2) then internal_full_n <= '0'; end if; end if; end if; end if; end process; shiftReg_addr <= (others => '0') when mOutPtr(ADDR_WIDTH) = '1' else mOutPtr(ADDR_WIDTH-1 downto 0); shiftReg_ce <= (if_write and if_write_ce) and internal_full_n; U_FIFO_image_filter_img_0_cols_V_channel_shiftReg : FIFO_image_filter_img_0_cols_V_channel_shiftReg generic map ( DATA_WIDTH => DATA_WIDTH, ADDR_WIDTH => ADDR_WIDTH, DEPTH => DEPTH) port map ( clk => clk, data => shiftReg_data, ce => shiftReg_ce, a => shiftReg_addr, q => shiftReg_q); end rtl;

gpl-3.0

0cff247708909cf76ad3ff91aad77838

0.539326

3.490196

false

mistryalok/Zedboard

learning/training/MSD/s09/axi_dma_sg/vivado/project_1/project_1.srcs/sources_1/ipshared/xilinx.com/axi_dma_v7_1/2a047f91/hdl/src/vhdl/axi_dma_lite_if.vhd

3

61,552

------------------------------------------------------------------------------- -- axi_dma_lite_if ------------------------------------------------------------------------------- -- -- ************************************************************************* -- -- (c) Copyright 2010, 2011 Xilinx, Inc. All rights reserved. -- -- This file contains confidential and proprietary information -- of Xilinx, Inc. and is protected under U.S. and -- international copyright and other intellectual property -- laws. -- -- DISCLAIMER -- This disclaimer is not a license and does not grant any -- rights to the materials distributed herewith. Except as -- otherwise provided in a valid license issued to you by -- Xilinx, and to the maximum extent permitted by applicable -- law: (1) THESE MATERIALS ARE MADE AVAILABLE "AS IS" AND -- WITH ALL FAULTS, AND XILINX HEREBY DISCLAIMS ALL WARRANTIES -- AND CONDITIONS, EXPRESS, IMPLIED, OR STATUTORY, INCLUDING -- BUT NOT LIMITED TO WARRANTIES OF MERCHANTABILITY, NON- -- INFRINGEMENT, OR FITNESS FOR ANY PARTICULAR PURPOSE; and -- (2) Xilinx shall not be liable (whether in contract or tort, -- including negligence, or under any other theory of -- liability) for any loss or damage of any kind or nature -- related to, arising under or in connection with these -- materials, including for any direct, or any indirect, -- special, incidental, or consequential loss or damage -- (including loss of data, profits, goodwill, or any type of -- loss or damage suffered as a result of any action brought -- by a third party) even if such damage or loss was -- reasonably foreseeable or Xilinx had been advised of the -- possibility of the same. -- -- CRITICAL APPLICATIONS -- Xilinx products are not designed or intended to be fail- -- safe, or for use in any application requiring fail-safe -- performance, such as life-support or safety devices or -- systems, Class III medical devices, nuclear facilities, -- applications related to the deployment of airbags, or any -- other applications that could lead to death, personal -- injury, or severe property or environmental damage -- (individually and collectively, "Critical -- Applications"). Customer assumes the sole risk and -- liability of any use of Xilinx products in Critical -- Applications, subject only to applicable laws and -- regulations governing limitations on product liability. -- -- THIS COPYRIGHT NOTICE AND DISCLAIMER MUST BE RETAINED AS -- PART OF THIS FILE AT ALL TIMES. -- -- ************************************************************************* -- ------------------------------------------------------------------------------- -- Filename: axi_dma_lite_if.vhd -- Description: This entity is AXI Lite Interface Module for the AXI DMA -- -- VHDL-Standard: VHDL'93 ------------------------------------------------------------------------------- ------------------------------------------------------------------------------- library ieee; use ieee.std_logic_1164.all; use ieee.numeric_std.all; use ieee.std_logic_misc.all; library unisim; use unisim.vcomponents.all; library axi_dma_v7_1; use axi_dma_v7_1.axi_dma_pkg.all; library lib_pkg_v1_0; library lib_cdc_v1_0; use lib_pkg_v1_0.lib_pkg.clog2; ------------------------------------------------------------------------------- entity axi_dma_lite_if is generic( C_NUM_CE : integer := 8 ; C_AXI_LITE_IS_ASYNC : integer range 0 to 1 := 0 ; C_S_AXI_LITE_ADDR_WIDTH : integer range 2 to 32 := 32 ; C_S_AXI_LITE_DATA_WIDTH : integer range 32 to 32 := 32 ); port ( -- Async clock input ip2axi_aclk : in std_logic ; -- ip2axi_aresetn : in std_logic ; -- ----------------------------------------------------------------------- -- AXI Lite Control Interface ----------------------------------------------------------------------- s_axi_lite_aclk : in std_logic ; -- s_axi_lite_aresetn : in std_logic ; -- -- -- AXI Lite Write Address Channel -- s_axi_lite_awvalid : in std_logic ; -- s_axi_lite_awready : out std_logic ; -- s_axi_lite_awaddr : in std_logic_vector -- (C_S_AXI_LITE_ADDR_WIDTH-1 downto 0); -- -- -- AXI Lite Write Data Channel -- s_axi_lite_wvalid : in std_logic ; -- s_axi_lite_wready : out std_logic ; -- s_axi_lite_wdata : in std_logic_vector -- (C_S_AXI_LITE_DATA_WIDTH-1 downto 0); -- -- -- AXI Lite Write Response Channel -- s_axi_lite_bresp : out std_logic_vector(1 downto 0) ; -- s_axi_lite_bvalid : out std_logic ; -- s_axi_lite_bready : in std_logic ; -- -- -- AXI Lite Read Address Channel -- s_axi_lite_arvalid : in std_logic ; -- s_axi_lite_arready : out std_logic ; -- s_axi_lite_araddr : in std_logic_vector -- (C_S_AXI_LITE_ADDR_WIDTH-1 downto 0); -- s_axi_lite_rvalid : out std_logic ; -- s_axi_lite_rready : in std_logic ; -- s_axi_lite_rdata : out std_logic_vector -- (C_S_AXI_LITE_DATA_WIDTH-1 downto 0); -- s_axi_lite_rresp : out std_logic_vector(1 downto 0) ; -- -- -- User IP Interface -- axi2ip_wrce : out std_logic_vector -- (C_NUM_CE-1 downto 0) ; -- axi2ip_wrdata : out std_logic_vector -- (C_S_AXI_LITE_DATA_WIDTH-1 downto 0); -- -- axi2ip_rdce : out std_logic_vector -- (C_NUM_CE-1 downto 0) ; -- axi2ip_rdaddr : out std_logic_vector -- (C_S_AXI_LITE_ADDR_WIDTH-1 downto 0); -- ip2axi_rddata : in std_logic_vector -- (C_S_AXI_LITE_DATA_WIDTH-1 downto 0) -- ); end axi_dma_lite_if; ------------------------------------------------------------------------------- -- Architecture ------------------------------------------------------------------------------- architecture implementation of axi_dma_lite_if is attribute DowngradeIPIdentifiedWarnings: string; attribute DowngradeIPIdentifiedWarnings of implementation : architecture is "yes"; ------------------------------------------------------------------------------- -- Functions ------------------------------------------------------------------------------- -- No Functions Declared ------------------------------------------------------------------------------- -- Constants Declarations ------------------------------------------------------------------------------- -- Register I/F Address offset constant ADDR_OFFSET : integer := clog2(C_S_AXI_LITE_DATA_WIDTH/8); -- Register I/F CE number constant CE_ADDR_SIZE : integer := clog2(C_NUM_CE); ------------------------------------------------------------------------------- -- Signal / Type Declarations ------------------------------------------------------------------------------- -- AXI Lite slave interface signals signal awvalid : std_logic := '0'; signal awaddr : std_logic_vector (C_S_AXI_LITE_ADDR_WIDTH-1 downto 0) := (others => '0'); signal wvalid : std_logic := '0'; signal wdata : std_logic_vector (C_S_AXI_LITE_DATA_WIDTH-1 downto 0) := (others => '0'); signal arvalid : std_logic := '0'; signal araddr : std_logic_vector (C_S_AXI_LITE_ADDR_WIDTH-1 downto 0) := (others => '0'); signal awvalid_d1 : std_logic := '0'; signal awvalid_re : std_logic := '0'; signal awready_i : std_logic := '0'; signal wvalid_d1 : std_logic := '0'; signal wvalid_re : std_logic := '0'; signal wready_i : std_logic := '0'; signal bvalid_i : std_logic := '0'; signal wr_addr_cap : std_logic := '0'; signal wr_data_cap : std_logic := '0'; -- AXI to IP interface signals signal axi2ip_wraddr_i : std_logic_vector (C_S_AXI_LITE_ADDR_WIDTH-1 downto 0) := (others => '0'); signal axi2ip_wrdata_i : std_logic_vector (C_S_AXI_LITE_DATA_WIDTH-1 downto 0) := (others => '0'); signal axi2ip_wren : std_logic := '0'; signal wrce : std_logic_vector(C_NUM_CE-1 downto 0); signal rdce : std_logic_vector(C_NUM_CE-1 downto 0) := (others => '0'); signal arvalid_d1 : std_logic := '0'; signal arvalid_re : std_logic := '0'; signal arvalid_re_d1 : std_logic := '0'; signal arvalid_i : std_logic := '0'; signal arready_i : std_logic := '0'; signal rvalid : std_logic := '0'; signal axi2ip_rdaddr_i : std_logic_vector (C_S_AXI_LITE_ADDR_WIDTH-1 downto 0) := (others => '0'); signal s_axi_lite_rvalid_i : std_logic := '0'; signal read_in_progress : std_logic := '0'; -- CR607165 signal rst_rvalid_re : std_logic := '0'; -- CR576999 signal rst_wvalid_re : std_logic := '0'; -- CR576999 signal rdy : std_logic := '0'; signal rdy1 : std_logic := '0'; signal wr_in_progress : std_logic := '0'; ------------------------------------------------------------------------------- -- Begin architecture logic ------------------------------------------------------------------------------- begin --***************************************************************************** --** AXI LITE READ --***************************************************************************** s_axi_lite_wready <= wready_i; s_axi_lite_awready <= awready_i; s_axi_lite_arready <= arready_i; s_axi_lite_bvalid <= bvalid_i; ------------------------------------------------------------------------------- -- Register AXI Inputs ------------------------------------------------------------------------------- REG_INPUTS : process(s_axi_lite_aclk) begin if(s_axi_lite_aclk'EVENT and s_axi_lite_aclk = '1')then if(s_axi_lite_aresetn = '0')then awvalid <= '0' ; awaddr <= (others => '0') ; wvalid <= '0' ; wdata <= (others => '0') ; arvalid <= '0' ; araddr <= (others => '0') ; else awvalid <= s_axi_lite_awvalid ; awaddr <= s_axi_lite_awaddr ; wvalid <= s_axi_lite_wvalid ; wdata <= s_axi_lite_wdata ; arvalid <= s_axi_lite_arvalid ; araddr <= s_axi_lite_araddr ; end if; end if; end process REG_INPUTS; -- s_axi_lite_aclk is synchronous to ip clock GEN_SYNC_WRITE : if C_AXI_LITE_IS_ASYNC = 0 generate begin ------------------------------------------------------------------------------- -- Assert Write Adddress Ready Handshake -- Capture rising edge of valid and register out as ready. This creates -- a 3 clock cycle address phase but also registers all inputs and outputs. -- Note : Single clock cycle address phase can be accomplished using -- combinatorial logic. ------------------------------------------------------------------------------- REG_AWVALID : process(s_axi_lite_aclk) begin if(s_axi_lite_aclk'EVENT and s_axi_lite_aclk = '1')then if(s_axi_lite_aresetn = '0' or rst_wvalid_re = '1')then awvalid_d1 <= '0'; -- awvalid_re <= '0'; -- CR605883 else awvalid_d1 <= awvalid; -- awvalid_re <= awvalid and not awvalid_d1; -- CR605883 end if; end if; end process REG_AWVALID; awvalid_re <= awvalid and not awvalid_d1 and (not (wr_in_progress)); -- CR605883 ------------------------------------------------------------------------------- -- Capture assertion of awvalid to indicate that we have captured -- a valid address ------------------------------------------------------------------------------- ------------------------------------------------------------------------------- -- Assert Write Data Ready Handshake -- Capture rising edge of valid and register out as ready. This creates -- a 3 clock cycle address phase but also registers all inputs and outputs. -- Note : Single clock cycle address phase can be accomplished using -- combinatorial logic. ------------------------------------------------------------------------------- REG_WVALID : process(s_axi_lite_aclk) begin if(s_axi_lite_aclk'EVENT and s_axi_lite_aclk = '1')then if(s_axi_lite_aresetn = '0' or rst_wvalid_re = '1')then wvalid_d1 <= '0'; -- wvalid_re <= '0'; else wvalid_d1 <= wvalid; -- wvalid_re <= wvalid and not wvalid_d1; -- CR605883 end if; end if; end process REG_WVALID; wvalid_re <= wvalid and not wvalid_d1; -- CR605883 WRITE_IN_PROGRESS : process(s_axi_lite_aclk) begin if(s_axi_lite_aclk'EVENT and s_axi_lite_aclk = '1')then if(s_axi_lite_aresetn = '0' or rst_wvalid_re = '1')then wr_in_progress <= '0'; elsif(awvalid_re = '1')then wr_in_progress <= '1'; end if; end if; end process WRITE_IN_PROGRESS; -- CR605883 (CDC) provide pure register output to synchronizers --wvalid_re <= wvalid and not wvalid_d1 and not rst_wvalid_re; ------------------------------------------------------------------------------- -- Capture assertion of wvalid to indicate that we have captured -- valid data ------------------------------------------------------------------------------- WRDATA_CAP_FLAG : process(s_axi_lite_aclk) begin if(s_axi_lite_aclk'EVENT and s_axi_lite_aclk = '1')then if(s_axi_lite_aresetn = '0' or rdy = '1')then wr_data_cap <= '0'; elsif(wvalid_re = '1')then wr_data_cap <= '1'; end if; end if; end process WRDATA_CAP_FLAG; REG_WREADY : process(s_axi_lite_aclk) begin if(s_axi_lite_aclk'EVENT and s_axi_lite_aclk = '1')then if(s_axi_lite_aresetn = '0' or rdy = '1') then rdy <= '0'; elsif (wr_data_cap = '1' and wr_addr_cap = '1') then rdy <= '1'; end if; wready_i <= rdy; awready_i <= rdy; rdy1 <= rdy; end if; end process REG_WREADY; WRADDR_CAP_FLAG : process(s_axi_lite_aclk) begin if(s_axi_lite_aclk'EVENT and s_axi_lite_aclk = '1')then if(s_axi_lite_aresetn = '0' or rdy = '1')then wr_addr_cap <= '0'; elsif(awvalid_re = '1')then wr_addr_cap <= '1'; end if; end if; end process WRADDR_CAP_FLAG; ------------------------------------------------------------------------------- -- Capture Write Address ------------------------------------------------------------------------------- REG_WRITE_ADDRESS : process(s_axi_lite_aclk) begin if(s_axi_lite_aclk'EVENT and s_axi_lite_aclk = '1')then if(s_axi_lite_aresetn = '0')then -- axi2ip_wraddr_i <= (others => '0'); -- Register address on valid elsif(awvalid_re = '1')then -- axi2ip_wraddr_i <= awaddr; end if; end if; end process REG_WRITE_ADDRESS; ------------------------------------------------------------------------------- -- Capture Write Data ------------------------------------------------------------------------------- REG_WRITE_DATA : process(s_axi_lite_aclk) begin if(s_axi_lite_aclk'EVENT and s_axi_lite_aclk = '1')then if(s_axi_lite_aresetn = '0')then axi2ip_wrdata_i <= (others => '0'); -- Register address and assert ready elsif(wvalid_re = '1')then axi2ip_wrdata_i <= wdata; end if; end if; end process REG_WRITE_DATA; ------------------------------------------------------------------------------- -- Must have both a valid address and valid data before updating -- a register. Note in AXI write address can come before or -- after AXI write data. -- axi2ip_wren <= '1' when wr_data_cap = '1' and wr_addr_cap = '1' -- else '0'; axi2ip_wren <= rdy; -- or rdy1; ------------------------------------------------------------------------------- -- Decode and assert proper chip enable per captured axi lite write address ------------------------------------------------------------------------------- WRCE_GEN: for j in 0 to C_NUM_CE - 1 generate constant BAR : std_logic_vector(CE_ADDR_SIZE-1 downto 0) := std_logic_vector(to_unsigned(j,CE_ADDR_SIZE)); begin wrce(j) <= axi2ip_wren when s_axi_lite_awaddr ((CE_ADDR_SIZE + ADDR_OFFSET) - 1 downto ADDR_OFFSET) = BAR(CE_ADDR_SIZE-1 downto 0) else '0'; end generate WRCE_GEN; ------------------------------------------------------------------------------- -- register write ce's and data out to axi dma register module ------------------------------------------------------------------------------- REG_WR_OUT : process(s_axi_lite_aclk) begin if(s_axi_lite_aclk'EVENT and s_axi_lite_aclk = '1')then if(s_axi_lite_aresetn = '0')then axi2ip_wrce <= (others => '0'); -- axi2ip_wrdata <= (others => '0'); else axi2ip_wrce <= wrce; -- axi2ip_wrdata <= axi2ip_wrdata_i; end if; end if; end process REG_WR_OUT; axi2ip_wrdata <= s_axi_lite_wdata; ------------------------------------------------------------------------------- -- Write Response ------------------------------------------------------------------------------- s_axi_lite_bresp <= OKAY_RESP; WRESP_PROCESS : process(s_axi_lite_aclk) begin if(s_axi_lite_aclk'EVENT and s_axi_lite_aclk = '1')then if(s_axi_lite_aresetn = '0')then bvalid_i <= '0'; rst_wvalid_re <= '0'; -- CR576999 -- If response issued and target indicates ready then -- clear response elsif(bvalid_i = '1' and s_axi_lite_bready = '1')then bvalid_i <= '0'; rst_wvalid_re <= '0'; -- CR576999 -- Issue a resonse on write elsif(rdy1 = '1')then bvalid_i <= '1'; rst_wvalid_re <= '1'; -- CR576999 end if; end if; end process WRESP_PROCESS; end generate GEN_SYNC_WRITE; -- s_axi_lite_aclk is asynchronous to ip clock GEN_ASYNC_WRITE : if C_AXI_LITE_IS_ASYNC = 1 generate -- Data support ----------------------------------------------------------------------------- -- ATTRIBUTE Declarations ----------------------------------------------------------------------------- -- Prevent x-propagation on clock-domain crossing register ATTRIBUTE async_reg : STRING; Attribute KEEP : string; -- declaration Attribute EQUIVALENT_REGISTER_REMOVAL : string; -- declaration signal ip_wvalid_d1_cdc_to : std_logic := '0'; signal ip_wvalid_d2 : std_logic := '0'; signal ip_wvalid_re : std_logic := '0'; signal wr_wvalid_re_cdc_from : std_logic := '0'; signal wr_data_cdc_from : std_logic_vector -- CR605883 (C_S_AXI_LITE_DATA_WIDTH-1 downto 0) := (others => '0'); -- CR605883 signal wdata_d1_cdc_to : std_logic_vector (C_S_AXI_LITE_DATA_WIDTH-1 downto 0) := (others => '0'); signal wdata_d2 : std_logic_vector (C_S_AXI_LITE_DATA_WIDTH-1 downto 0) := (others => '0'); signal axi2ip_wrdata_cdc_tig : std_logic_vector (C_S_AXI_LITE_DATA_WIDTH-1 downto 0) := (others => '0'); signal ip_data_cap : std_logic := '0'; -- Address support signal ip_awvalid_d1_cdc_to : std_logic := '0'; signal ip_awvalid_d2 : std_logic := '0'; signal ip_awvalid_re : std_logic := '0'; signal wr_awvalid_re_cdc_from : std_logic := '0'; signal wr_addr_cdc_from : std_logic_vector -- CR605883 (C_S_AXI_LITE_ADDR_WIDTH-1 downto 0) := (others => '0'); -- CR605883 signal awaddr_d1_cdc_tig : std_logic_vector (C_S_AXI_LITE_ADDR_WIDTH-1 downto 0) := (others => '0'); signal awaddr_d2 : std_logic_vector (C_S_AXI_LITE_ADDR_WIDTH-1 downto 0) := (others => '0'); signal ip_addr_cap : std_logic := '0'; -- Bvalid support signal lite_data_cap_d1 : std_logic := '0'; signal lite_data_cap_d2 : std_logic := '0'; signal lite_addr_cap_d1 : std_logic := '0'; signal lite_addr_cap_d2 : std_logic := '0'; signal lite_axi2ip_wren : std_logic := '0'; signal awvalid_cdc_from : std_logic := '0'; signal awvalid_cdc_to : std_logic := '0'; signal awvalid_to : std_logic := '0'; signal awvalid_to2 : std_logic := '0'; --ATTRIBUTE async_reg OF awvalid_cdc_to : SIGNAL IS "true"; --ATTRIBUTE async_reg OF awvalid_to : SIGNAL IS "true"; signal wvalid_cdc_from : std_logic := '0'; signal wvalid_cdc_to : std_logic := '0'; signal wvalid_to : std_logic := '0'; signal wvalid_to2 : std_logic := '0'; --ATTRIBUTE async_reg OF wvalid_cdc_to : SIGNAL IS "true"; --ATTRIBUTE async_reg OF wvalid_to : SIGNAL IS "true"; signal rdy_cdc_to : std_logic := '0'; signal rdy_cdc_from : std_logic := '0'; signal rdy_to : std_logic := '0'; signal rdy_to2 : std_logic := '0'; signal rdy_to2_cdc_from : std_logic := '0'; signal rdy_out : std_logic := '0'; --ATTRIBUTE async_reg OF rdy_cdc_to : SIGNAL IS "true"; --ATTRIBUTE async_reg OF rdy_to : SIGNAL IS "true"; Attribute KEEP of rdy_to2_cdc_from : signal is "TRUE"; Attribute EQUIVALENT_REGISTER_REMOVAL of rdy_to2_cdc_from : signal is "no"; signal rdy_back_cdc_to : std_logic := '0'; signal rdy_back_to : std_logic :='0'; --ATTRIBUTE async_reg OF rdy_back_cdc_to : SIGNAL IS "true"; --ATTRIBUTE async_reg OF rdy_back_to : SIGNAL IS "true"; signal rdy_back : std_logic := '0'; signal rdy_shut : std_logic := '0'; begin REG_AWVALID : process(s_axi_lite_aclk) begin if(s_axi_lite_aclk'EVENT and s_axi_lite_aclk = '1')then if(s_axi_lite_aresetn = '0' or rst_wvalid_re = '1')then awvalid_d1 <= '0'; else awvalid_d1 <= awvalid; end if; end if; end process REG_AWVALID; awvalid_re <= awvalid and not awvalid_d1 and (not (wr_in_progress)); -- CR605883 ------------------------------------------------------------------------------- -- Capture assertion of awvalid to indicate that we have captured -- a valid address ------------------------------------------------------------------------------- ------------------------------------------------------------------------------- -- Assert Write Data Ready Handshake -- Capture rising edge of valid and register out as ready. This creates -- a 3 clock cycle address phase but also registers all inputs and outputs. -- Note : Single clock cycle address phase can be accomplished using -- combinatorial logic. ------------------------------------------------------------------------------- REG_WVALID : process(s_axi_lite_aclk) begin if(s_axi_lite_aclk'EVENT and s_axi_lite_aclk = '1')then if(s_axi_lite_aresetn = '0' or rst_wvalid_re = '1')then wvalid_d1 <= '0'; else wvalid_d1 <= wvalid; end if; end if; end process REG_WVALID; wvalid_re <= wvalid and not wvalid_d1; -- CR605883 --************************************************************************* --** Write Address Support --************************************************************************* AWVLD_CDC_FROM : process(s_axi_lite_aclk) begin if(s_axi_lite_aclk'EVENT and s_axi_lite_aclk = '1')then if(s_axi_lite_aresetn = '0' or rst_wvalid_re = '1')then awvalid_cdc_from <= '0'; elsif(awvalid_re = '1')then awvalid_cdc_from <= '1'; end if; end if; end process AWVLD_CDC_FROM; AWVLD_CDC_TO : entity lib_cdc_v1_0.cdc_sync generic map ( C_CDC_TYPE => 1, C_RESET_STATE => 0, C_SINGLE_BIT => 1, C_VECTOR_WIDTH => 32, C_MTBF_STAGES => MTBF_STAGES ) port map ( prmry_aclk => s_axi_lite_aclk, prmry_resetn => '0', prmry_in => awvalid_cdc_from, prmry_vect_in => (others => '0'), scndry_aclk => ip2axi_aclk, scndry_resetn => '0', scndry_out => awvalid_to, scndry_vect_out => open ); -- AWVLD_CDC_TO : process(ip2axi_aclk) -- begin -- if(ip2axi_aclk'EVENT and ip2axi_aclk = '1')then -- awvalid_cdc_to <= awvalid_cdc_from; -- awvalid_to <= awvalid_cdc_to; -- end if; -- end process AWVLD_CDC_TO; AWVLD_CDC_TO2 : process(ip2axi_aclk) begin if(ip2axi_aclk'EVENT and ip2axi_aclk = '1')then if(ip2axi_aresetn = '0')then awvalid_to2 <= '0'; else awvalid_to2 <= awvalid_to; end if; end if; end process AWVLD_CDC_TO2; ip_awvalid_re <= awvalid_to and (not awvalid_to2); WVLD_CDC_FROM : process(s_axi_lite_aclk) begin if(s_axi_lite_aclk'EVENT and s_axi_lite_aclk = '1')then if(s_axi_lite_aresetn = '0' or rst_wvalid_re = '1')then wvalid_cdc_from <= '0'; elsif(wvalid_re = '1')then wvalid_cdc_from <= '1'; end if; end if; end process WVLD_CDC_FROM; WVLD_CDC_TO : entity lib_cdc_v1_0.cdc_sync generic map ( C_CDC_TYPE => 1, C_RESET_STATE => 0, C_SINGLE_BIT => 1, C_VECTOR_WIDTH => 32, C_MTBF_STAGES => MTBF_STAGES ) port map ( prmry_aclk => s_axi_lite_aclk, prmry_resetn => '0', prmry_in => wvalid_cdc_from, prmry_vect_in => (others => '0'), scndry_aclk => ip2axi_aclk, scndry_resetn => '0', scndry_out => wvalid_to, scndry_vect_out => open ); -- WVLD_CDC_TO : process(ip2axi_aclk) -- begin -- if(ip2axi_aclk'EVENT and ip2axi_aclk = '1')then -- wvalid_cdc_to <= wvalid_cdc_from; -- wvalid_to <= wvalid_cdc_to; -- end if; -- end process WVLD_CDC_TO; WVLD_CDC_TO2 : process(ip2axi_aclk) begin if(ip2axi_aclk'EVENT and ip2axi_aclk = '1')then if(ip2axi_aresetn = '0')then wvalid_to2 <= '0'; else wvalid_to2 <= wvalid_to; end if; end if; end process WVLD_CDC_TO2; ip_wvalid_re <= wvalid_to and (not wvalid_to2); REG_WADDR_TO_IPCLK : entity lib_cdc_v1_0.cdc_sync generic map ( C_CDC_TYPE => 1, C_RESET_STATE => 0, C_SINGLE_BIT => 0, C_VECTOR_WIDTH => C_S_AXI_LITE_ADDR_WIDTH, C_MTBF_STAGES => 1 ) port map ( prmry_aclk => s_axi_lite_aclk, prmry_resetn => '0', prmry_in => '0', prmry_vect_in => s_axi_lite_awaddr, scndry_aclk => ip2axi_aclk, scndry_resetn => '0', scndry_out => open, scndry_vect_out => awaddr_d1_cdc_tig ); REG_WADDR_TO_IPCLK1 : entity lib_cdc_v1_0.cdc_sync generic map ( C_CDC_TYPE => 1, C_RESET_STATE => 0, C_SINGLE_BIT => 0, C_VECTOR_WIDTH => C_S_AXI_LITE_DATA_WIDTH, C_MTBF_STAGES => 1 ) port map ( prmry_aclk => s_axi_lite_aclk, prmry_resetn => '0', prmry_in => '0', prmry_vect_in => s_axi_lite_wdata, scndry_aclk => ip2axi_aclk, scndry_resetn => '0', scndry_out => open, scndry_vect_out => axi2ip_wrdata_cdc_tig ); -- Double register address in -- REG_WADDR_TO_IPCLK : process(ip2axi_aclk) -- begin -- if(ip2axi_aclk'EVENT and ip2axi_aclk = '1')then -- if(ip2axi_aresetn = '0')then -- awaddr_d1_cdc_tig <= (others => '0'); -- -- axi2ip_wraddr_i <= (others => '0'); -- axi2ip_wrdata_cdc_tig <= (others => '0'); -- else -- awaddr_d1_cdc_tig <= s_axi_lite_awaddr; -- axi2ip_wrdata_cdc_tig <= s_axi_lite_wdata; -- -- axi2ip_wraddr_i <= awaddr_d1_cdc_tig; -- CR605883 -- end if; -- end if; -- end process REG_WADDR_TO_IPCLK; -- Flag that address has been captured REG_IP_ADDR_CAP : process(ip2axi_aclk) begin if(ip2axi_aclk'EVENT and ip2axi_aclk = '1')then if(ip2axi_aresetn = '0' or rdy_shut = '1')then ip_addr_cap <= '0'; elsif(ip_awvalid_re = '1')then ip_addr_cap <= '1'; end if; end if; end process REG_IP_ADDR_CAP; REG_WREADY : process(ip2axi_aclk) begin if(ip2axi_aclk'EVENT and ip2axi_aclk = '1')then if(ip2axi_aresetn = '0' or rdy_shut = '1') then -- or rdy = '1') then rdy <= '0'; elsif (ip_data_cap = '1' and ip_addr_cap = '1') then rdy <= '1'; end if; end if; end process REG_WREADY; REG3_WREADY : entity lib_cdc_v1_0.cdc_sync generic map ( C_CDC_TYPE => 1, C_RESET_STATE => 0, C_SINGLE_BIT => 1, C_VECTOR_WIDTH => 32, C_MTBF_STAGES => MTBF_STAGES ) port map ( prmry_aclk => s_axi_lite_aclk, prmry_resetn => '0', prmry_in => rdy_to2_cdc_from, prmry_vect_in => (others => '0'), scndry_aclk => ip2axi_aclk, scndry_resetn => '0', scndry_out => rdy_back_to, scndry_vect_out => open ); -- REG3_WREADY : process(ip2axi_aclk) -- begin -- if(ip2axi_aclk'EVENT and ip2axi_aclk = '1')then -- rdy_back_cdc_to <= rdy_to2_cdc_from; -- rdy_back_to <= rdy_back_cdc_to; -- end if; -- end process REG3_WREADY; REG3_WREADY2 : process(ip2axi_aclk) begin if(ip2axi_aclk'EVENT and ip2axi_aclk = '1')then if(ip2axi_aresetn = '0') then rdy_back <= '0'; else rdy_back <= rdy_back_to; end if; end if; end process REG3_WREADY2; rdy_shut <= rdy_back_to and (not rdy_back); REG1_WREADY : process(ip2axi_aclk) begin if(ip2axi_aclk'EVENT and ip2axi_aclk = '1')then if(ip2axi_aresetn = '0' or rdy_shut = '1') then rdy_cdc_from <= '0'; elsif (rdy = '1') then rdy_cdc_from <= '1'; end if; end if; end process REG1_WREADY; REG2_WREADY : entity lib_cdc_v1_0.cdc_sync generic map ( C_CDC_TYPE => 1, C_RESET_STATE => 0, C_SINGLE_BIT => 1, C_VECTOR_WIDTH => 32, C_MTBF_STAGES => MTBF_STAGES ) port map ( prmry_aclk => ip2axi_aclk, prmry_resetn => '0', prmry_in => rdy_cdc_from, prmry_vect_in => (others => '0'), scndry_aclk => s_axi_lite_aclk, scndry_resetn => '0', scndry_out => rdy_to, scndry_vect_out => open ); -- REG2_WREADY : process(s_axi_lite_aclk) -- begin -- if(s_axi_lite_aclk'EVENT and s_axi_lite_aclk = '1')then -- rdy_cdc_to <= rdy_cdc_from; -- rdy_to <= rdy_cdc_to; -- end if; -- end process REG2_WREADY; REG2_WREADY2 : process(s_axi_lite_aclk) begin if(s_axi_lite_aclk'EVENT and s_axi_lite_aclk = '1')then if(s_axi_lite_aresetn = '0') then rdy_to2 <= '0'; rdy_to2_cdc_from <= '0'; else rdy_to2 <= rdy_to; rdy_to2_cdc_from <= rdy_to; end if; end if; end process REG2_WREADY2; rdy_out <= not (rdy_to) and rdy_to2; wready_i <= rdy_out; awready_i <= rdy_out; --************************************************************************* --** Write Data Support --************************************************************************* ------------------------------------------------------------------------------- -- Capture write data ------------------------------------------------------------------------------- -- WRDATA_S_H : process(s_axi_lite_aclk) -- begin -- if(s_axi_lite_aclk'EVENT and s_axi_lite_aclk = '1')then -- if(s_axi_lite_aresetn = '0')then -- wr_data_cdc_from <= (others => '0'); -- elsif(wvalid_re = '1')then -- wr_data_cdc_from <= wdata; -- end if; -- end if; -- end process WRDATA_S_H; -- Flag that data has been captured REG_IP_DATA_CAP : process(ip2axi_aclk) begin if(ip2axi_aclk'EVENT and ip2axi_aclk = '1')then if(ip2axi_aresetn = '0' or rdy_shut = '1')then ip_data_cap <= '0'; elsif(ip_wvalid_re = '1')then ip_data_cap <= '1'; end if; end if; end process REG_IP_DATA_CAP; -- Must have both a valid address and valid data before updating -- a register. Note in AXI write address can come before or -- after AXI write data. axi2ip_wren <= rdy; -- axi2ip_wren <= '1' when ip_data_cap = '1' and ip_addr_cap = '1' -- else '0'; ------------------------------------------------------------------------------- -- Decode and assert proper chip enable per captured axi lite write address ------------------------------------------------------------------------------- WRCE_GEN: for j in 0 to C_NUM_CE - 1 generate constant BAR : std_logic_vector(CE_ADDR_SIZE-1 downto 0) := std_logic_vector(to_unsigned(j,CE_ADDR_SIZE)); begin wrce(j) <= axi2ip_wren when awaddr_d1_cdc_tig ((CE_ADDR_SIZE + ADDR_OFFSET) - 1 downto ADDR_OFFSET) = BAR(CE_ADDR_SIZE-1 downto 0) else '0'; end generate WRCE_GEN; ------------------------------------------------------------------------------- -- register write ce's and data out to axi dma register module ------------------------------------------------------------------------------- REG_WR_OUT : process(ip2axi_aclk) begin if(ip2axi_aclk'EVENT and ip2axi_aclk = '1')then if(ip2axi_aresetn = '0')then axi2ip_wrce <= (others => '0'); else axi2ip_wrce <= wrce; end if; end if; end process REG_WR_OUT; axi2ip_wrdata <= axi2ip_wrdata_cdc_tig; --s_axi_lite_wdata; --************************************************************************* --** Write Response Support --************************************************************************* -- Minimum of 2 IP clocks for addr and data capture, therefore delaying -- Lite clock addr and data capture by 2 Lite clocks will guarenttee bvalid -- responce occurs after write data acutally written. -- REG_ALIGN_CAP : process(s_axi_lite_aclk) -- begin -- if(s_axi_lite_aclk'EVENT and s_axi_lite_aclk = '1')then -- if(s_axi_lite_aresetn = '0')then -- lite_data_cap_d1 <= '0'; -- lite_data_cap_d2 <= '0'; -- lite_addr_cap_d1 <= '0'; -- lite_addr_cap_d2 <= '0'; -- else -- lite_data_cap_d1 <= rdy; --wr_data_cap; -- lite_data_cap_d2 <= lite_data_cap_d1; -- lite_addr_cap_d1 <= rdy; --wr_addr_cap; -- lite_addr_cap_d2 <= lite_addr_cap_d1; -- end if; -- end if; -- end process REG_ALIGN_CAP; -- Pseudo write enable used simply to assert bvalid -- lite_axi2ip_wren <= rdy; --'1' when wr_data_cap = '1' and wr_addr_cap = '1' -- else '0'; WRESP_PROCESS : process(s_axi_lite_aclk) begin if(s_axi_lite_aclk'EVENT and s_axi_lite_aclk = '1')then if(s_axi_lite_aresetn = '0')then bvalid_i <= '0'; rst_wvalid_re <= '0'; -- CR576999 -- If response issued and target indicates ready then -- clear response elsif(bvalid_i = '1' and s_axi_lite_bready = '1')then bvalid_i <= '0'; rst_wvalid_re <= '0'; -- CR576999 -- Issue a resonse on write elsif(rdy_out = '1')then -- elsif(lite_axi2ip_wren = '1')then bvalid_i <= '1'; rst_wvalid_re <= '1'; -- CR576999 end if; end if; end process WRESP_PROCESS; s_axi_lite_bresp <= OKAY_RESP; end generate GEN_ASYNC_WRITE; --***************************************************************************** --** AXI LITE READ --***************************************************************************** ------------------------------------------------------------------------------- -- Assert Read Adddress Ready Handshake -- Capture rising edge of valid and register out as ready. This creates -- a 3 clock cycle address phase but also registers all inputs and outputs. -- Note : Single clock cycle address phase can be accomplished using -- combinatorial logic. ------------------------------------------------------------------------------- REG_ARVALID : process(s_axi_lite_aclk) begin if(s_axi_lite_aclk'EVENT and s_axi_lite_aclk = '1')then if(s_axi_lite_aresetn = '0' or rst_rvalid_re = '1')then arvalid_d1 <= '0'; else arvalid_d1 <= arvalid; end if; end if; end process REG_ARVALID; arvalid_re <= arvalid and not arvalid_d1 and not rst_rvalid_re and not read_in_progress; -- CR607165 -- register for proper alignment REG_ARREADY : process(s_axi_lite_aclk) begin if(s_axi_lite_aclk'EVENT and s_axi_lite_aclk = '1')then if(s_axi_lite_aresetn = '0')then arready_i <= '0'; else arready_i <= arvalid_re; end if; end if; end process REG_ARREADY; -- Always respond 'okay' axi lite read s_axi_lite_rresp <= OKAY_RESP; s_axi_lite_rvalid <= s_axi_lite_rvalid_i; -- s_axi_lite_aclk is synchronous to ip clock GEN_SYNC_READ : if C_AXI_LITE_IS_ASYNC = 0 generate begin read_in_progress <= '0'; --Not used for sync mode (CR607165) ------------------------------------------------------------------------------- -- Capture Read Address ------------------------------------------------------------------------------- REG_READ_ADDRESS : process(s_axi_lite_aclk) begin if(s_axi_lite_aclk'EVENT and s_axi_lite_aclk = '1')then if(s_axi_lite_aresetn = '0')then axi2ip_rdaddr_i <= (others => '0'); -- Register address on valid elsif(arvalid_re = '1')then axi2ip_rdaddr_i <= araddr; end if; end if; end process REG_READ_ADDRESS; ------------------------------------------------------------------------------- -- Generate RdCE based on address match to address bar ------------------------------------------------------------------------------- RDCE_GEN: for j in 0 to C_NUM_CE - 1 generate constant BAR : std_logic_vector(CE_ADDR_SIZE-1 downto 0) := std_logic_vector(to_unsigned(j,CE_ADDR_SIZE)); begin rdce(j) <= arvalid_re_d1 when axi2ip_rdaddr_i((CE_ADDR_SIZE + ADDR_OFFSET) - 1 downto ADDR_OFFSET) = BAR(CE_ADDR_SIZE-1 downto 0) else '0'; end generate RDCE_GEN; ------------------------------------------------------------------------------- -- Register out to IP ------------------------------------------------------------------------------- REG_RDCNTRL_OUT : process(s_axi_lite_aclk) begin if(s_axi_lite_aclk'EVENT and s_axi_lite_aclk = '1')then if(s_axi_lite_aresetn = '0')then --axi2ip_rdce <= (others => '0'); axi2ip_rdaddr <= (others => '0'); else --axi2ip_rdce <= rdce; axi2ip_rdaddr <= axi2ip_rdaddr_i; end if; end if; end process REG_RDCNTRL_OUT; -- Sample and hold rdce value until rvalid assertion REG_RDCE_OUT : process(s_axi_lite_aclk) begin if(s_axi_lite_aclk'EVENT and s_axi_lite_aclk = '1')then if(s_axi_lite_aresetn = '0' or rst_rvalid_re = '1')then axi2ip_rdce <= (others => '0'); elsif(arvalid_re_d1 = '1')then axi2ip_rdce <= rdce; end if; end if; end process REG_RDCE_OUT; -- Register for proper alignment REG_RVALID : process(s_axi_lite_aclk) begin if(s_axi_lite_aclk'EVENT and s_axi_lite_aclk = '1')then if(s_axi_lite_aresetn = '0')then arvalid_re_d1 <= '0'; rvalid <= '0'; else arvalid_re_d1 <= arvalid_re; rvalid <= arvalid_re_d1; end if; end if; end process REG_RVALID; ------------------------------------------------------------------------------- -- Drive read data and read data valid out on capture of valid address. ------------------------------------------------------------------------------- REG_RD_OUT : process(s_axi_lite_aclk) begin if(s_axi_lite_aclk'EVENT and s_axi_lite_aclk = '1')then if(s_axi_lite_aresetn = '0')then s_axi_lite_rdata <= (others => '0'); s_axi_lite_rvalid_i <= '0'; rst_rvalid_re <= '0'; -- CR576999 -- If rvalid driving out to target and target indicates ready -- then de-assert rvalid. (structure guarentees min 1 clock of rvalid) elsif(s_axi_lite_rvalid_i = '1' and s_axi_lite_rready = '1')then s_axi_lite_rdata <= (others => '0'); s_axi_lite_rvalid_i <= '0'; rst_rvalid_re <= '0'; -- CR576999 -- If read cycle then assert rvalid and rdata out to target elsif(rvalid = '1')then s_axi_lite_rdata <= ip2axi_rddata; s_axi_lite_rvalid_i <= '1'; rst_rvalid_re <= '1'; -- CR576999 end if; end if; end process REG_RD_OUT; end generate GEN_SYNC_READ; -- s_axi_lite_aclk is asynchronous to ip clock GEN_ASYNC_READ : if C_AXI_LITE_IS_ASYNC = 1 generate ATTRIBUTE async_reg : STRING; signal ip_arvalid_d1_cdc_tig : std_logic := '0'; signal ip_arvalid_d2 : std_logic := '0'; signal ip_arvalid_d3 : std_logic := '0'; signal ip_arvalid_re : std_logic := '0'; signal araddr_d1_cdc_tig : std_logic_vector(C_S_AXI_LITE_ADDR_WIDTH-1 downto 0) :=(others => '0'); signal araddr_d2 : std_logic_vector(C_S_AXI_LITE_ADDR_WIDTH-1 downto 0) :=(others => '0'); signal araddr_d3 : std_logic_vector(C_S_AXI_LITE_ADDR_WIDTH-1 downto 0) :=(others => '0'); signal lite_rdata_cdc_from : std_logic_vector(C_S_AXI_LITE_DATA_WIDTH-1 downto 0) :=(others => '0'); signal lite_rdata_d1_cdc_to : std_logic_vector(C_S_AXI_LITE_DATA_WIDTH-1 downto 0) :=(others => '0'); signal lite_rdata_d2 : std_logic_vector(C_S_AXI_LITE_DATA_WIDTH-1 downto 0) :=(others => '0'); --ATTRIBUTE async_reg OF ip_arvalid_d1_cdc_tig : SIGNAL IS "true"; --ATTRIBUTE async_reg OF ip_arvalid_d2 : SIGNAL IS "true"; --ATTRIBUTE async_reg OF araddr_d1_cdc_tig : SIGNAL IS "true"; --ATTRIBUTE async_reg OF araddr_d2 : SIGNAL IS "true"; --ATTRIBUTE async_reg OF lite_rdata_d1_cdc_to : SIGNAL IS "true"; --ATTRIBUTE async_reg OF lite_rdata_d2 : SIGNAL IS "true"; signal p_pulse_s_h : std_logic := '0'; signal p_pulse_s_h_clr : std_logic := '0'; signal s_pulse_d1 : std_logic := '0'; signal s_pulse_d2 : std_logic := '0'; signal s_pulse_d3 : std_logic := '0'; signal s_pulse_re : std_logic := '0'; signal p_pulse_re_d1 : std_logic := '0'; signal p_pulse_re_d2 : std_logic := '0'; signal p_pulse_re_d3 : std_logic := '0'; signal arready_d1 : std_logic := '0'; -- CR605883 signal arready_d2 : std_logic := '0'; -- CR605883 signal arready_d3 : std_logic := '0'; -- CR605883 signal arready_d4 : std_logic := '0'; -- CR605883 signal arready_d5 : std_logic := '0'; -- CR605883 signal arready_d6 : std_logic := '0'; -- CR605883 signal arready_d7 : std_logic := '0'; -- CR605883 signal arready_d8 : std_logic := '0'; -- CR605883 signal arready_d9 : std_logic := '0'; -- CR605883 signal arready_d10 : std_logic := '0'; -- CR605883 signal arready_d11 : std_logic := '0'; -- CR605883 signal arready_d12 : std_logic := '0'; -- CR605883 begin -- CR607165 -- Flag to prevent overlapping reads RD_PROGRESS : process(s_axi_lite_aclk) begin if(s_axi_lite_aclk'EVENT and s_axi_lite_aclk = '1')then if(s_axi_lite_aresetn = '0' or rst_rvalid_re = '1')then read_in_progress <= '0'; elsif(arvalid_re = '1')then read_in_progress <= '1'; end if; end if; end process RD_PROGRESS; -- Double register address in REG_RADDR_TO_IPCLK : entity lib_cdc_v1_0.cdc_sync generic map ( C_CDC_TYPE => 1, C_RESET_STATE => 0, C_SINGLE_BIT => 0, C_VECTOR_WIDTH => C_S_AXI_LITE_ADDR_WIDTH, C_MTBF_STAGES => MTBF_STAGES ) port map ( prmry_aclk => s_axi_lite_aclk, prmry_resetn => '0', prmry_in => '0', prmry_vect_in => s_axi_lite_araddr, scndry_aclk => ip2axi_aclk, scndry_resetn => '0', scndry_out => open, scndry_vect_out => araddr_d3 ); -- REG_RADDR_TO_IPCLK : process(ip2axi_aclk) -- begin -- if(ip2axi_aclk'EVENT and ip2axi_aclk = '1')then -- if(ip2axi_aresetn = '0')then -- araddr_d1_cdc_tig <= (others => '0'); -- araddr_d2 <= (others => '0'); -- araddr_d3 <= (others => '0'); -- else -- araddr_d1_cdc_tig <= s_axi_lite_araddr; -- araddr_d2 <= araddr_d1_cdc_tig; -- araddr_d3 <= araddr_d2; -- end if; -- end if; -- end process REG_RADDR_TO_IPCLK; -- Latch and hold read address REG_ARADDR_PROCESS : process(ip2axi_aclk) begin if(ip2axi_aclk'EVENT and ip2axi_aclk = '1')then if(ip2axi_aresetn = '0')then axi2ip_rdaddr_i <= (others => '0'); elsif(ip_arvalid_re = '1')then axi2ip_rdaddr_i <= araddr_d3; end if; end if; end process REG_ARADDR_PROCESS; axi2ip_rdaddr <= axi2ip_rdaddr_i; -- Register awready into IP clock domain. awready -- is a 1 axi_lite clock delay of the rising edge of -- arvalid. This provides a signal that asserts when -- araddr is known to be stable. REG_ARVALID_TO_IPCLK : entity lib_cdc_v1_0.cdc_sync generic map ( C_CDC_TYPE => 1, C_RESET_STATE => 0, C_SINGLE_BIT => 1, C_VECTOR_WIDTH => C_S_AXI_LITE_ADDR_WIDTH, C_MTBF_STAGES => MTBF_STAGES ) port map ( prmry_aclk => s_axi_lite_aclk, prmry_resetn => '0', prmry_in => arready_i, prmry_vect_in => (others => '0'), scndry_aclk => ip2axi_aclk, scndry_resetn => '0', scndry_out => ip_arvalid_d2, scndry_vect_out => open ); REG_ARVALID_TO_IPCLK1 : process(ip2axi_aclk) begin if(ip2axi_aclk'EVENT and ip2axi_aclk = '1')then if(ip2axi_aresetn = '0')then -- ip_arvalid_d1_cdc_tig <= '0'; -- ip_arvalid_d2 <= '0'; ip_arvalid_d3 <= '0'; else -- ip_arvalid_d1_cdc_tig <= arready_i; -- ip_arvalid_d2 <= ip_arvalid_d1_cdc_tig; ip_arvalid_d3 <= ip_arvalid_d2; end if; end if; end process REG_ARVALID_TO_IPCLK1; ip_arvalid_re <= ip_arvalid_d2 and not ip_arvalid_d3; ------------------------------------------------------------------------------- -- Generate Read CE's ------------------------------------------------------------------------------- RDCE_GEN: for j in 0 to C_NUM_CE - 1 generate constant BAR : std_logic_vector(CE_ADDR_SIZE-1 downto 0) := std_logic_vector(to_unsigned(j,CE_ADDR_SIZE)); begin rdce(j) <= ip_arvalid_re when araddr_d3((CE_ADDR_SIZE + ADDR_OFFSET) - 1 downto ADDR_OFFSET) = BAR(CE_ADDR_SIZE-1 downto 0) else '0'; end generate RDCE_GEN; ------------------------------------------------------------------------------- -- Register RDCE and RD Data out to IP ------------------------------------------------------------------------------- REG_RDCNTRL_OUT : process(ip2axi_aclk) begin if(ip2axi_aclk'EVENT and ip2axi_aclk = '1')then if(ip2axi_aresetn = '0')then axi2ip_rdce <= (others => '0'); elsif(ip_arvalid_re = '1')then axi2ip_rdce <= rdce; else axi2ip_rdce <= (others => '0'); end if; end if; end process REG_RDCNTRL_OUT; -- Generate sample and hold pulse to capture read data from IP REG_RVALID : process(ip2axi_aclk) begin if(ip2axi_aclk'EVENT and ip2axi_aclk = '1')then if(ip2axi_aresetn = '0')then rvalid <= '0'; else rvalid <= ip_arvalid_re; end if; end if; end process REG_RVALID; ------------------------------------------------------------------------------- -- Sample and hold read data from IP ------------------------------------------------------------------------------- S_H_READ_DATA : process(ip2axi_aclk) begin if(ip2axi_aclk'EVENT and ip2axi_aclk = '1')then if(ip2axi_aresetn = '0')then lite_rdata_cdc_from <= (others => '0'); -- If read cycle then assert rvalid and rdata out to target elsif(rvalid = '1')then lite_rdata_cdc_from <= ip2axi_rddata; end if; end if; end process S_H_READ_DATA; -- Cross read data to axi_lite clock domain REG_DATA2LITE_CLOCK : entity lib_cdc_v1_0.cdc_sync generic map ( C_CDC_TYPE => 1, C_RESET_STATE => 0, C_SINGLE_BIT => 0, C_VECTOR_WIDTH => 32, C_MTBF_STAGES => MTBF_STAGES ) port map ( prmry_aclk => ip2axi_aclk, prmry_resetn => '0', prmry_in => '0', --lite_rdata_cdc_from, prmry_vect_in => lite_rdata_cdc_from, scndry_aclk => s_axi_lite_aclk, scndry_resetn => '0', scndry_out => open, --lite_rdata_d2, scndry_vect_out => lite_rdata_d2 ); -- REG_DATA2LITE_CLOCK : process(s_axi_lite_aclk) -- begin -- if(s_axi_lite_aclk'EVENT and s_axi_lite_aclk = '1')then -- if(s_axi_lite_aresetn = '0')then -- lite_rdata_d1_cdc_to <= (others => '0'); -- lite_rdata_d2 <= (others => '0'); -- else -- lite_rdata_d1_cdc_to <= lite_rdata_cdc_from; -- lite_rdata_d2 <= lite_rdata_d1_cdc_to; -- end if; -- end if; -- end process REG_DATA2LITE_CLOCK; -- CR605883 (CDC) modified to remove -- Because axi_lite_aclk must be less than or equal to ip2axi_aclk -- then read data will appear a maximum 6 clocks from assertion -- of arready. REG_ALIGN_RDATA_LATCH : process(s_axi_lite_aclk) begin if(s_axi_lite_aclk'EVENT and s_axi_lite_aclk = '1')then if(s_axi_lite_aresetn = '0')then arready_d1 <= '0'; arready_d2 <= '0'; arready_d3 <= '0'; arready_d4 <= '0'; arready_d5 <= '0'; arready_d6 <= '0'; arready_d7 <= '0'; arready_d8 <= '0'; arready_d9 <= '0'; arready_d10 <= '0'; arready_d11 <= '0'; arready_d12 <= '0'; else arready_d1 <= arready_i; arready_d2 <= arready_d1; arready_d3 <= arready_d2; arready_d4 <= arready_d3; arready_d5 <= arready_d4; arready_d6 <= arready_d5; arready_d7 <= arready_d6; arready_d8 <= arready_d7; arready_d9 <= arready_d8; arready_d10 <= arready_d9; arready_d11 <= arready_d10; arready_d12 <= arready_d11; end if; end if; end process REG_ALIGN_RDATA_LATCH; ------------------------------------------------------------------------------- -- Drive read data and read data valid out on capture of valid address. ------------------------------------------------------------------------------- REG_RD_OUT : process(s_axi_lite_aclk) begin if(s_axi_lite_aclk'EVENT and s_axi_lite_aclk = '1')then if(s_axi_lite_aresetn = '0')then s_axi_lite_rdata <= (others => '0'); s_axi_lite_rvalid_i <= '0'; rst_rvalid_re <= '0'; -- CR576999 -- If rvalid driving out to target and target indicates ready -- then de-assert rvalid. (structure guarentees min 1 clock of rvalid) elsif(s_axi_lite_rvalid_i = '1' and s_axi_lite_rready = '1')then s_axi_lite_rdata <= (others => '0'); s_axi_lite_rvalid_i <= '0'; rst_rvalid_re <= '0'; -- CR576999 -- If read cycle then assert rvalid and rdata out to target -- CR605883 --elsif(s_pulse_re = '1')then elsif(arready_d12 = '1')then s_axi_lite_rdata <= lite_rdata_d2; s_axi_lite_rvalid_i <= '1'; rst_rvalid_re <= '1'; -- CR576999 end if; end if; end process REG_RD_OUT; end generate GEN_ASYNC_READ; end implementation;

gpl-3.0

a49b7840501260aa0af25dbe2a11f8f6

0.426306

4.126575

false

marco-c/leon-nexys2

grlib-gpl-1.3.4-b4140/designs/leon3-xilinx-sp605/leon3mp.vhd

1

35,477

----------------------------------------------------------------------------- -- LEON3 Xilinx SP605 Demonstration design -- Copyright (C) 2011 Jiri Gaisler, Aeroflex Gaisler ------------------------------------------------------------------------------ -- This file is a part of the GRLIB VHDL IP LIBRARY -- Copyright (C) 2003 - 2008, Gaisler Research -- Copyright (C) 2008 - 2013, Aeroflex Gaisler -- -- This program is free software; you can redistribute it and/or modify -- it under the terms of the GNU General Public License as published by -- the Free Software Foundation; either version 2 of the License, or -- (at your option) any later version. -- -- This program is distributed in the hope that it will be useful, -- but WITHOUT ANY WARRANTY; without even the implied warranty of -- MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the -- GNU General Public License for more details. -- -- You should have received a copy of the GNU General Public License -- along with this program; if not, write to the Free Software -- Foundation, Inc., 59 Temple Place, Suite 330, Boston, MA 02111-1307 USA ------------------------------------------------------------------------------ library ieee; use ieee.std_logic_1164.all; library grlib, techmap; use grlib.amba.all; use grlib.amba.all; use grlib.stdlib.all; use techmap.gencomp.all; use techmap.allclkgen.all; library gaisler; use gaisler.memctrl.all; use gaisler.leon3.all; use gaisler.uart.all; use gaisler.misc.all; use gaisler.spi.all; use gaisler.i2c.all; use gaisler.can.all; use gaisler.net.all; use gaisler.jtag.all; use gaisler.spacewire.all; -- pragma translate_off use gaisler.sim.all; library unisim; use unisim.ODDR2; -- pragma translate_on library esa; use esa.memoryctrl.all; use work.config.all; use work.pcie.all; entity leon3mp is generic ( fabtech : integer := CFG_FABTECH; memtech : integer := CFG_MEMTECH; padtech : integer := CFG_PADTECH; clktech : integer := CFG_CLKTECH; disas : integer := CFG_DISAS; -- Enable disassembly to console dbguart : integer := CFG_DUART; -- Print UART on console pclow : integer := CFG_PCLOW ); port ( reset : in std_ulogic; clk27 : in std_ulogic; -- 27 MHz clock clk200p : in std_ulogic; -- 200 MHz clock clk200n : in std_ulogic; -- 200 MHz clock clk33 : in std_ulogic; -- 32 MHz clock from sysace address : out std_logic_vector(23 downto 0); data : inout std_logic_vector(15 downto 0); oen : out std_ulogic; writen : out std_ulogic; romsn : out std_logic; ddr_clk : out std_logic; ddr_clkb : out std_logic; ddr_cke : out std_logic; ddr_odt : out std_logic; ddr_reset_n : out std_logic; ddr_we : out std_ulogic; -- ddr write enable ddr_ras : out std_ulogic; -- ddr ras ddr_cas : out std_ulogic; -- ddr cas ddr_dm : out std_logic_vector (1 downto 0); -- ddr dm ddr_dqs : inout std_logic_vector (1 downto 0); -- ddr dqs ddr_dqs_n : inout std_logic_vector (1 downto 0); -- ddr dqs_n ddr_ad : out std_logic_vector (12 downto 0); -- ddr address ddr_ba : out std_logic_vector (2 downto 0); -- ddr bank address ddr_dq : inout std_logic_vector (15 downto 0); -- ddr data ddr_rzq : inout std_ulogic; ddr_zio : inout std_ulogic; txd1 : out std_ulogic; -- UART1 tx data rxd1 : in std_ulogic; -- UART1 rx data ctsn1 : in std_ulogic; -- UART1 ctsn rtsn1 : out std_ulogic; -- UART1 trsn button : inout std_logic_vector(3 downto 0); -- I/O port switch : inout std_logic_vector(3 downto 0); -- I/O port led : out std_logic_vector(3 downto 0); -- I/O port phy_gtx_clk : out std_logic; phy_mii_data : inout std_logic; -- ethernet PHY interface phy_tx_clk : in std_ulogic; phy_rx_clk : in std_ulogic; phy_rx_data : in std_logic_vector(7 downto 0); phy_dv : in std_ulogic; phy_rx_er : in std_ulogic; phy_col : in std_ulogic; phy_crs : in std_ulogic; phy_tx_data : out std_logic_vector(7 downto 0); phy_tx_en : out std_ulogic; phy_tx_er : out std_ulogic; phy_mii_clk : out std_ulogic; phy_rst_n : out std_ulogic; phy_mii_int_n : in std_ulogic; iic_scl : inout std_ulogic; iic_sda : inout std_ulogic; ddc_scl : inout std_ulogic; ddc_sda : inout std_ulogic; dvi_iic_scl : inout std_logic; dvi_iic_sda : inout std_logic; tft_lcd_data : out std_logic_vector(11 downto 0); tft_lcd_clk_p : out std_ulogic; tft_lcd_clk_n : out std_ulogic; tft_lcd_hsync : out std_ulogic; tft_lcd_vsync : out std_ulogic; tft_lcd_de : out std_ulogic; tft_lcd_reset_b : out std_ulogic; -- SPI flash spi_sel_n : inout std_ulogic; spi_clk : out std_ulogic; spi_mosi : out std_ulogic; --pcie pci_exp_txp : out std_logic; pci_exp_txn : out std_logic; pci_exp_rxp : in std_logic; pci_exp_rxn : in std_logic; sys_clk_p : in std_logic; sys_clk_n : in std_logic; sys_reset_n : in std_logic; sysace_mpa : out std_logic_vector(6 downto 0); sysace_mpce : out std_ulogic; sysace_mpirq : in std_ulogic; sysace_mpoe : out std_ulogic; sysace_mpwe : out std_ulogic; sysace_d : inout std_logic_vector(7 downto 0) ); end; architecture rtl of leon3mp is --attribute syn_netlist_hierarchy : boolean; --attribute syn_netlist_hierarchy of rtl : architecture is false; component ODDR2 generic ( DDR_ALIGNMENT : string := "NONE"; INIT : bit := '0'; SRTYPE : string := "SYNC" ); port ( Q : out std_ulogic; C0 : in std_ulogic; C1 : in std_ulogic; CE : in std_ulogic := 'H'; D0 : in std_ulogic; D1 : in std_ulogic; R : in std_ulogic := 'L'; S : in std_ulogic := 'L' ); end component; constant blength : integer := 12; constant fifodepth : integer := 8; constant maxahbm : integer := CFG_NCPU+CFG_GRETH+CFG_AHB_JTAG+CFG_PCIEXP; signal vcc, gnd : std_logic; signal memi : memory_in_type; signal memo : memory_out_type; signal wpo : wprot_out_type; signal sdi : sdctrl_in_type; signal sdo : sdram_out_type; signal apbi : apb_slv_in_type; signal apbo : apb_slv_out_vector := (others => apb_none); signal ahbsi : ahb_slv_in_type; signal ahbso : ahb_slv_out_vector := (others => ahbs_none); signal ahbmi : ahb_mst_in_type; signal vahbmi : ahb_mst_in_type; signal ahbmo : ahb_mst_out_vector := (others => ahbm_none); signal vahbmo : ahb_mst_out_type; signal clkm, rstn, rstraw, sdclkl : std_ulogic; signal clk_200 : std_ulogic; signal clk25, clk40, clk65 : std_ulogic; signal cgi, cgi2 : clkgen_in_type; signal cgo, cgo2 : clkgen_out_type; signal u1i, u2i, dui : uart_in_type; signal u1o, u2o, duo : uart_out_type; signal irqi : irq_in_vector(0 to CFG_NCPU-1); signal irqo : irq_out_vector(0 to CFG_NCPU-1); signal dbgi : l3_debug_in_vector(0 to CFG_NCPU-1); signal dbgo : l3_debug_out_vector(0 to CFG_NCPU-1); signal dsui : dsu_in_type; signal dsuo : dsu_out_type; signal ethi : eth_in_type; signal etho : eth_out_type; signal egtx_clk :std_ulogic; signal negtx_clk :std_ulogic; signal gpti : gptimer_in_type; signal gpto : gptimer_out_type; signal gpioi : gpio_in_type; signal gpioo : gpio_out_type; signal clklock, elock, ulock : std_ulogic; signal lock, calib_done, clkml, lclk, rst, ndsuact : std_ulogic; signal tck, tckn, tms, tdi, tdo : std_ulogic; signal ethclk : std_ulogic; signal vgao : apbvga_out_type; signal lcd_datal : std_logic_vector(11 downto 0); signal lcd_hsyncl, lcd_vsyncl, lcd_del, lcd_reset_bl : std_ulogic; signal i2ci, dvi_i2ci : i2c_in_type; signal i2co, dvi_i2co : i2c_out_type; signal spmi : spimctrl_in_type; signal spmo : spimctrl_out_type; signal spmi2 : spimctrl_in_type; signal spmo2 : spimctrl_out_type; constant BOARD_FREQ : integer := 33000; -- input frequency in KHz constant CPU_FREQ : integer := BOARD_FREQ * CFG_CLKMUL / CFG_CLKDIV; -- cpu frequency in KHz constant IOAEN : integer := CFG_GRACECTRL; constant DDR2_FREQ : integer := 200000; -- DDR2 input frequency in KHz signal stati : ahbstat_in_type; signal fpi : grfpu_in_vector_type; signal fpo : grfpu_out_vector_type; -- Used for connecting input/output signals to the DDR2 controller signal core_ddr_clk : std_logic_vector(2 downto 0); signal core_ddr_clkb : std_logic_vector(2 downto 0); signal core_ddr_cke : std_logic_vector(1 downto 0); signal core_ddr_csb : std_logic_vector(1 downto 0); signal core_ddr_ad : std_logic_vector(13 downto 0); signal core_ddr_odt : std_logic_vector(1 downto 0); signal video_clk : std_ulogic; -- signals to vga_clkgen. signal clk_sel : std_logic_vector(1 downto 0); signal clkvga, clkvga_p, clkvga_n : std_ulogic; signal acei : gracectrl_in_type; signal aceo : gracectrl_out_type; attribute keep : boolean; attribute syn_keep : boolean; attribute syn_preserve : boolean; attribute syn_keep of video_clk : signal is true; attribute syn_preserve of video_clk : signal is true; attribute keep of video_clk : signal is true; attribute syn_preserve of clkm : signal is true; attribute keep of clkm : signal is true; begin ---------------------------------------------------------------------- --- Reset and Clock generation ------------------------------------- ---------------------------------------------------------------------- vcc <= '1'; gnd <= '0'; cgi.pllctrl <= "00"; cgi.pllrst <= rstraw; ethclk <= lclk; clk_pad : clkpad generic map (tech => padtech) port map (clk33, lclk); clkgen0 : clkgen -- clock generator generic map (clktech, CFG_CLKMUL, CFG_CLKDIV, CFG_MCTRL_SDEN, CFG_CLK_NOFB, 0, 0, 0, BOARD_FREQ) port map (lclk, lclk, clkm, open, open, sdclkl, open, cgi, cgo, open, open, open); reset_pad : inpad generic map (tech => padtech) port map (reset, rst); rst0 : rstgen -- reset generator generic map (acthigh => 1) port map (rst, clkm, lock, rstn, rstraw); lock <= cgo.clklock and calib_done when CFG_MIG_DDR2 = 1 else cgo.clklock; ---------------------------------------------------------------------- --- AHB CONTROLLER -------------------------------------------------- ---------------------------------------------------------------------- ahb0 : ahbctrl -- AHB arbiter/multiplexer generic map (defmast => CFG_DEFMST, split => CFG_SPLIT, rrobin => CFG_RROBIN, ioaddr => CFG_AHBIO, fpnpen => CFG_FPNPEN, ioen => IOAEN, nahbm => maxahbm, nahbs => 16) port map (rstn, clkm, ahbmi, ahbmo, ahbsi, ahbso); ---------------------------------------------------------------------- --- LEON3 processor and DSU ----------------------------------------- ---------------------------------------------------------------------- nosh : if CFG_GRFPUSH = 0 generate cpu : for i in 0 to CFG_NCPU-1 generate l3ft : if CFG_LEON3FT_EN /= 0 generate leon3ft0 : leon3ft -- LEON3 processor generic map (i, fabtech, memtech, CFG_NWIN, CFG_DSU, CFG_FPU*(1-CFG_GRFPUSH), CFG_V8, 0, CFG_MAC, pclow, CFG_NOTAG, CFG_NWP, CFG_ICEN, CFG_IREPL, CFG_ISETS, CFG_ILINE, CFG_ISETSZ, CFG_ILOCK, CFG_DCEN, CFG_DREPL, CFG_DSETS, CFG_DLINE, CFG_DSETSZ, CFG_DLOCK, CFG_DSNOOP, CFG_ILRAMEN, CFG_ILRAMSZ, CFG_ILRAMADDR, CFG_DLRAMEN, CFG_DLRAMSZ, CFG_DLRAMADDR, CFG_MMUEN, CFG_ITLBNUM, CFG_DTLBNUM, CFG_TLB_TYPE, CFG_TLB_REP, CFG_LDDEL, disas, CFG_ITBSZ, CFG_PWD, CFG_SVT, CFG_RSTADDR, CFG_NCPU-1, CFG_IUFT_EN, CFG_FPUFT_EN, CFG_CACHE_FT_EN, CFG_RF_ERRINJ, CFG_CACHE_ERRINJ, CFG_DFIXED, CFG_LEON3_NETLIST, CFG_SCAN, CFG_MMU_PAGE) port map (clkm, rstn, ahbmi, ahbmo(i), ahbsi, ahbso, irqi(i), irqo(i), dbgi(i), dbgo(i), clkm); end generate; l3s : if CFG_LEON3FT_EN = 0 generate u0 : leon3s -- LEON3 processor generic map (i, fabtech, memtech, CFG_NWIN, CFG_DSU, CFG_FPU*(1-CFG_GRFPUSH), CFG_V8, 0, CFG_MAC, pclow, CFG_NOTAG, CFG_NWP, CFG_ICEN, CFG_IREPL, CFG_ISETS, CFG_ILINE, CFG_ISETSZ, CFG_ILOCK, CFG_DCEN, CFG_DREPL, CFG_DSETS, CFG_DLINE, CFG_DSETSZ, CFG_DLOCK, CFG_DSNOOP, CFG_ILRAMEN, CFG_ILRAMSZ, CFG_ILRAMADDR, CFG_DLRAMEN, CFG_DLRAMSZ, CFG_DLRAMADDR, CFG_MMUEN, CFG_ITLBNUM, CFG_DTLBNUM, CFG_TLB_TYPE, CFG_TLB_REP, CFG_LDDEL, disas, CFG_ITBSZ, CFG_PWD, CFG_SVT, CFG_RSTADDR, CFG_NCPU-1, CFG_DFIXED, CFG_SCAN, CFG_MMU_PAGE, CFG_BP) port map (clkm, rstn, ahbmi, ahbmo(i), ahbsi, ahbso, irqi(i), irqo(i), dbgi(i), dbgo(i)); end generate; end generate; end generate; sh : if CFG_GRFPUSH = 1 generate cpu : for i in 0 to CFG_NCPU-1 generate l3ft : if CFG_LEON3FT_EN /= 0 generate leon3ft0 : leon3ftsh -- LEON3 processor generic map (i, fabtech, memtech, CFG_NWIN, CFG_DSU, CFG_FPU, CFG_V8, 0, CFG_MAC, pclow, CFG_NOTAG, CFG_NWP, CFG_ICEN, CFG_IREPL, CFG_ISETS, CFG_ILINE, CFG_ISETSZ, CFG_ILOCK, CFG_DCEN, CFG_DREPL, CFG_DSETS, CFG_DLINE, CFG_DSETSZ, CFG_DLOCK, CFG_DSNOOP, CFG_ILRAMEN, CFG_ILRAMSZ, CFG_ILRAMADDR, CFG_DLRAMEN, CFG_DLRAMSZ, CFG_DLRAMADDR, CFG_MMUEN, CFG_ITLBNUM, CFG_DTLBNUM, CFG_TLB_TYPE, CFG_TLB_REP, CFG_LDDEL, disas, CFG_ITBSZ, CFG_PWD, CFG_SVT, CFG_RSTADDR, CFG_NCPU-1, CFG_IUFT_EN, CFG_FPUFT_EN, CFG_CACHE_FT_EN, CFG_RF_ERRINJ, CFG_CACHE_ERRINJ, CFG_DFIXED, CFG_LEON3_NETLIST, CFG_SCAN, CFG_MMU_PAGE) port map (clkm, rstn, ahbmi, ahbmo(i), ahbsi, ahbso, irqi(i), irqo(i), dbgi(i), dbgo(i), clkm, fpi(i), fpo(i)); end generate; l3s : if CFG_LEON3FT_EN = 0 generate u0 : leon3sh -- LEON3 processor generic map (i, fabtech, memtech, CFG_NWIN, CFG_DSU, CFG_FPU, CFG_V8, 0, CFG_MAC, pclow, CFG_NOTAG, CFG_NWP, CFG_ICEN, CFG_IREPL, CFG_ISETS, CFG_ILINE, CFG_ISETSZ, CFG_ILOCK, CFG_DCEN, CFG_DREPL, CFG_DSETS, CFG_DLINE, CFG_DSETSZ, CFG_DLOCK, CFG_DSNOOP, CFG_ILRAMEN, CFG_ILRAMSZ, CFG_ILRAMADDR, CFG_DLRAMEN, CFG_DLRAMSZ, CFG_DLRAMADDR, CFG_MMUEN, CFG_ITLBNUM, CFG_DTLBNUM, CFG_TLB_TYPE, CFG_TLB_REP, CFG_LDDEL, disas, CFG_ITBSZ, CFG_PWD, CFG_SVT, CFG_RSTADDR, CFG_NCPU-1, CFG_DFIXED, CFG_SCAN, CFG_MMU_PAGE) port map (clkm, rstn, ahbmi, ahbmo(i), ahbsi, ahbso, irqi(i), irqo(i), dbgi(i), dbgo(i), fpi(i), fpo(i)); end generate; end generate; grfpush0 : grfpushwx generic map ((CFG_FPU-1), CFG_NCPU, fabtech) port map (clkm, rstn, fpi, fpo); end generate; led1_pad : odpad generic map (tech => padtech) port map (led(1), dbgo(0).error); dsugen : if CFG_DSU = 1 generate dsu0 : dsu3 -- LEON3 Debug Support Unit generic map (hindex => 2, haddr => 16#900#, hmask => 16#F00#, ncpu => CFG_NCPU, tbits => 30, tech => memtech, irq => 0, kbytes => CFG_ATBSZ) port map (rstn, clkm, ahbmi, ahbsi, ahbso(2), dbgo, dbgi, dsui, dsuo); dsui.enable <= '1'; dsui.break <= button(3); dsuact_pad : outpad generic map (tech => padtech) port map (led(0), ndsuact); ndsuact <= not dsuo.active; end generate; nodsu : if CFG_DSU = 0 generate dsuo.tstop <= '0'; dsuo.active <= '0'; ahbso(2) <= ahbs_none; end generate; ahbjtaggen0 :if CFG_AHB_JTAG = 1 generate ahbjtag0 : ahbjtag generic map(tech => fabtech, hindex => CFG_NCPU) port map(rstn, clkm, tck, tms, tdi, tdo, ahbmi, ahbmo(CFG_NCPU), open, open, open, open, open, open, open, gnd); end generate; ---------------------------------------------------------------------- --- Memory controllers ---------------------------------------------- ---------------------------------------------------------------------- memi.writen <= '1'; memi.wrn <= "1111"; memi.bwidth <= "01"; memi.brdyn <= '0'; memi.bexcn <= '1'; mctrl_gen : if CFG_MCTRL_LEON2 /= 0 generate mctrl0 : mctrl generic map (hindex => 0, pindex => 0, paddr => 0, srbanks => 2, ram8 => CFG_MCTRL_RAM8BIT, ram16 => CFG_MCTRL_RAM16BIT, sden => CFG_MCTRL_SDEN, invclk => CFG_CLK_NOFB, sepbus => CFG_MCTRL_SEPBUS, pageburst => CFG_MCTRL_PAGE, rammask => 0, iomask => 0) port map (rstn, clkm, memi, memo, ahbsi, ahbso(0), apbi, apbo(0), wpo, sdo); addr_pad : outpadv generic map (width => 24, tech => padtech) port map (address, memo.address(24 downto 1)); roms_pad : outpad generic map (tech => padtech) port map (romsn, memo.romsn(0)); oen_pad : outpad generic map (tech => padtech) port map (oen, memo.oen); wri_pad : outpad generic map (tech => padtech) port map (writen, memo.writen); data_pad : iopadvv generic map (tech => padtech, width => 16) port map (data(15 downto 0), memo.data(31 downto 16), memo.vbdrive(31 downto 16), memi.data(31 downto 16)); end generate; nomctrl : if CFG_MCTRL_LEON2 = 0 generate roms_pad : outpad generic map (tech => padtech) port map (romsn, vcc); --ahbso(0) <= ahbso_none; end generate; ----------------------------------------------------------------------- --- Test report module ---------------------------------------------- ----------------------------------------------------------------------- -- pragma translate_off test0 : ahbrep generic map (hindex => 6, haddr => 16#200#) port map (rstn, clkm, ahbsi, ahbso(6)); -- pragma translate_on ---------------------------------------------------------------------- --- DDR2 memory controller ------------------------------------------ ---------------------------------------------------------------------- mig_gen : if (CFG_MIG_DDR2 = 1) generate ddrc : entity work.ahb2mig_sp605 generic map( hindex => 4, haddr => 16#400#, hmask => 16#F80#, pindex => 4, paddr => 4, vgamst => CFG_SVGA_ENABLE, vgaburst => 64) port map( mcb3_dram_dq => ddr_dq, mcb3_dram_a => ddr_ad, mcb3_dram_ba => ddr_ba, mcb3_dram_ras_n => ddr_ras, mcb3_dram_cas_n => ddr_cas, mcb3_dram_we_n => ddr_we, mcb3_dram_odt => ddr_odt, mcb3_dram_reset_n=> ddr_reset_n, mcb3_dram_cke => ddr_cke, mcb3_dram_dm => ddr_dm(0), mcb3_dram_udqs => ddr_dqs(1), mcb3_dram_udqs_n=> ddr_dqs_n(1), mcb3_rzq => ddr_rzq, mcb3_zio => ddr_zio, mcb3_dram_udm => ddr_dm(1), mcb3_dram_dqs => ddr_dqs(0), mcb3_dram_dqs_n => ddr_dqs_n(0), mcb3_dram_ck => ddr_clk, mcb3_dram_ck_n => ddr_clkb, ahbsi => ahbsi, ahbso => ahbso(4), ahbmi => vahbmi, ahbmo => vahbmo, apbi => apbi, apbo => apbo(4), calib_done => calib_done, rst_n_syn => rstn, rst_n_async => rstraw, clk_amba => clkm, clk_mem_p => clk200p, clk_mem_n => clk200n, clk_125 => egtx_clk, clk_50 => video_clk ); end generate; led(2) <= calib_done; led(3) <= lock; noddr : if CFG_MIG_DDR2 = 0 generate lock <= '1'; end generate; -----------------PCI-EXPRESS-Master-Target------------------------------------------ pcie_mt : if CFG_PCIE_TYPE = 1 generate -- master/target without fifo EP:pcie_master_target_sp605 generic map ( master => CFG_PCIE_SIM_MAS, hmstndx => CFG_NCPU+CFG_GRETH+CFG_AHB_JTAG, hslvndx => 7, abits => 21, device_id => CFG_PCIEXPDID, -- PCIE device ID vendor_id => CFG_PCIEXPVID, -- PCIE vendor ID nsync => 2, -- 1 or 2 sync regs between clocks pcie_bar_mask => 16#FFE#, haddr => 16#a00#, hmask => 16#fff#, pindex => 5, paddr => 5, pmask => 16#fff# ) port map( rst => rstn, clk => clkm, -- System Interface sys_clk_p => sys_clk_p, sys_clk_n => sys_clk_n, sys_reset_n => sys_reset_n, -- PCI Express Fabric Interface pci_exp_txp => pci_exp_txp, pci_exp_txn => pci_exp_txn, pci_exp_rxp => pci_exp_rxp, pci_exp_rxn => pci_exp_rxn, ahbso => ahbso(7), ahbsi => ahbsi, apbi => apbi, apbo => apbo(5), ahbmi => ahbmi, ahbmo => ahbmo(CFG_NCPU+CFG_GRETH+CFG_AHB_JTAG) ); end generate; ---------------------------------------------------------------------- -----------------PCI-EXPRESS-Master-FIFO------------------------------------------ pcie_mf_dma : if CFG_PCIE_TYPE = 3 generate -- master with fifo and DMA dma:pciedma generic map (memtech => memtech, dmstndx => CFG_NCPU+CFG_GRETH+CFG_AHB_JTAG, dapbndx => 7, dapbaddr => 7,dapbmask => 16#FFF#, dapbirq => 4, blength => 12, device_id => CFG_PCIEXPDID, vendor_id => CFG_PCIEXPVID, slvndx => 7, apbndx => 5, apbaddr => 5, apbmask =>16#FFF#, haddr => 16#A00#, hmask => 16#FFF#, nsync => 2, pcie_bar_mask => 16#FFE# ) port map( rst => rstn, clk => clkm, -- System Interface sys_clk_p => sys_clk_p, sys_clk_n => sys_clk_n, sys_reset_n => sys_reset_n, -- PCI Express Fabric Interface pci_exp_txp => pci_exp_txp, pci_exp_txn => pci_exp_txn, pci_exp_rxp => pci_exp_rxp, pci_exp_rxn => pci_exp_rxn, dapbo => apbo(7), dahbmo =>ahbmo(CFG_NCPU+CFG_GRETH+CFG_AHB_JTAG), apbi =>apbi, apbo =>apbo(5), ahbmi =>ahbmi, ahbsi =>ahbsi, ahbso =>ahbso(7) ); end generate; pcie_mf: if CFG_PCIE_TYPE = 2 generate -- master with fifo EP:pcie_master_fifo_sp605 generic map ( memtech => memtech, hslvndx => 7, device_id => CFG_PCIEXPDID, -- PCIE device ID vendor_id => CFG_PCIEXPVID, -- PCIE vendor ID nsync => 2, -- 1 or 2 sync regs between clocks pcie_bar_mask => 16#FFE#, haddr => 16#A00#, hmask => 16#fff#, pindex => 5, paddr => 5, pmask => 16#fff#) port map( rst => rstn, clk => clkm, -- System In sys_clk_p => sys_clk_p, sys_clk_n => sys_clk_n, sys_reset_n => sys_reset_n, -- PCI Expre pci_exp_txp => pci_exp_txp, pci_exp_txn => pci_exp_txn, pci_exp_rxp => pci_exp_rxp, pci_exp_rxn => pci_exp_rxn, ahbso => ahbso(7), ahbsi => ahbsi, apbi => apbi, apbo => apbo(5) ); end generate; ---------------------------------------------------------------------- ---------------------------------------------------------------------- ---------------------------------------------------------------------- --- SPI Memory Controller-------------------------------------------- ---------------------------------------------------------------------- spimc: if CFG_SPICTRL_ENABLE = 0 and CFG_SPIMCTRL = 1 generate spimctrl0 : spimctrl -- SPI Memory Controller generic map (hindex => 3, hirq => 5, faddr => 16#e00#, fmask => 16#ff8#, ioaddr => 16#002#, iomask => 16#fff#, spliten => CFG_SPLIT, oepol => 0, sdcard => CFG_SPIMCTRL_SDCARD, readcmd => CFG_SPIMCTRL_READCMD, dummybyte => CFG_SPIMCTRL_DUMMYBYTE, dualoutput => CFG_SPIMCTRL_DUALOUTPUT, scaler => CFG_SPIMCTRL_SCALER, altscaler => CFG_SPIMCTRL_ASCALER, pwrupcnt => CFG_SPIMCTRL_PWRUPCNT) port map (rstn, clkm, ahbsi, ahbso(3), spmi, spmo); -- MISO is shared with Flash data 0 spmi.miso <= memi.data(16); mosi_pad : outpad generic map (tech => padtech) port map (spi_mosi, spmo.mosi); sck_pad : outpad generic map (tech => padtech) port map (spi_clk, spmo.sck); slvsel0_pad : odpad generic map (tech => padtech) port map (spi_sel_n, spmo.csn); end generate; nospimc: if ((CFG_SPICTRL_ENABLE = 0 and CFG_SPIMCTRL = 0) or (CFG_SPICTRL_ENABLE = 1 and CFG_SPIMCTRL = 1) or (CFG_SPICTRL_ENABLE = 1 and CFG_SPIMCTRL = 0))generate mosi_pad : outpad generic map (tech => padtech) port map (spi_mosi, '0'); sck_pad : outpad generic map (tech => padtech) port map (spi_clk, '0'); end generate; ---------------------------------------------------------------------- --- System ACE I/F Controller --------------------------------------- ---------------------------------------------------------------------- grace: if CFG_GRACECTRL = 1 generate grace0 : gracectrl generic map (hindex => 8, hirq => 10, haddr => 16#002#, hmask => 16#fff#, split => CFG_SPLIT, mode => 2) port map (rstn, clkm, lclk, ahbsi, ahbso(8), acei, aceo); end generate; nograce: if CFG_GRACECTRL /= 1 generate aceo <= gracectrl_none; end generate; sysace_mpa_pads : outpadv generic map (width => 7, tech => padtech) port map (sysace_mpa, aceo.addr); sysace_mpce_pad : outpad generic map (tech => padtech) port map (sysace_mpce, aceo.cen); sysace_d_pads : iopadv generic map (tech => padtech, width => 8) port map (sysace_d, aceo.do(7 downto 0), aceo.doen, acei.di(7 downto 0)); acei.di(15 downto 8) <= (others => '0'); sysace_mpoe_pad : outpad generic map (tech => padtech) port map (sysace_mpoe, aceo.oen); sysace_mpwe_pad : outpad generic map (tech => padtech) port map (sysace_mpwe, aceo.wen); sysace_mpirq_pad : inpad generic map (tech => padtech) port map (sysace_mpirq, acei.irq); ---------------------------------------------------------------------- --- APB Bridge and various periherals ------------------------------- ---------------------------------------------------------------------- apb0 : apbctrl -- AHB/APB bridge generic map (hindex => 1, haddr => CFG_APBADDR, nslaves => 16) port map (rstn, clkm, ahbsi, ahbso(1), apbi, apbo ); ua1 : if CFG_UART1_ENABLE /= 0 generate uart1 : apbuart -- UART 1 generic map (pindex => 1, paddr => 1, pirq => 2, console => dbguart, fifosize => CFG_UART1_FIFO) port map (rstn, clkm, apbi, apbo(1), u1i, u1o); u1i.extclk <= '0'; rxd1_pad : inpad generic map (tech => padtech) port map (rxd1, u1i.rxd); txd1_pad : outpad generic map (tech => padtech) port map (txd1, u1o.txd); cts1_pad : inpad generic map (tech => padtech) port map (ctsn1, u1i.ctsn); rts1_pad : outpad generic map (tech => padtech) port map (rtsn1, u1o.rtsn); end generate; noua0 : if CFG_UART1_ENABLE = 0 generate apbo(1) <= apb_none; end generate; irqctrl : if CFG_IRQ3_ENABLE /= 0 generate irqctrl0 : irqmp -- interrupt controller generic map (pindex => 2, paddr => 2, ncpu => CFG_NCPU) port map (rstn, clkm, apbi, apbo(2), irqo, irqi); end generate; irq3 : if CFG_IRQ3_ENABLE = 0 generate x : for i in 0 to CFG_NCPU-1 generate irqi(i).irl <= "0000"; end generate; apbo(2) <= apb_none; end generate; gpt : if CFG_GPT_ENABLE /= 0 generate timer0 : gptimer -- timer unit generic map (pindex => 3, paddr => 3, pirq => CFG_GPT_IRQ, sepirq => CFG_GPT_SEPIRQ, sbits => CFG_GPT_SW, ntimers => CFG_GPT_NTIM, nbits => CFG_GPT_TW, wdog => 0) port map (rstn, clkm, apbi, apbo(3), gpti, gpto); gpti.dhalt <= dsuo.tstop; gpti.extclk <= '0'; end generate; nogpt : if CFG_GPT_ENABLE = 0 generate apbo(3) <= apb_none; end generate; vga : if CFG_VGA_ENABLE /= 0 generate vga0 : apbvga generic map(memtech => memtech, pindex => 6, paddr => 6) port map(rstn, clkm, ethclk, apbi, apbo(6), vgao); -- video_clk <= not ethclk; end generate; svga : if CFG_SVGA_ENABLE /= 0 generate svga0 : svgactrl generic map(memtech => memtech, pindex => 6, paddr => 6, hindex => CFG_NCPU+CFG_AHB_JTAG, clk0 => 20000, clk1 => 0, --1000000000/((BOARD_FREQ * CFG_CLKMUL)/CFG_CLKDIV), clk2 => 0, clk3 => 0, burstlen => 6) port map(rstn, clkm, video_clk, apbi, apbo(6), vgao, vahbmi, vahbmo, clk_sel); end generate; vgadvi : if (CFG_VGA_ENABLE + CFG_SVGA_ENABLE) /= 0 generate -- b0 : techbuf generic map (2, fabtech) port map (clk50, video_clk); dvi0 : entity work.svga2ch7301c generic map (tech => fabtech, dynamic => 1) port map (clkm, vgao, video_clk, clkvga_p, clkvga_n, lcd_datal, lcd_hsyncl, lcd_vsyncl, lcd_del); i2cdvi : i2cmst generic map (pindex => 9, paddr => 9, pmask => 16#FFF#, pirq => 11) port map (rstn, clkm, apbi, apbo(9), dvi_i2ci, dvi_i2co); end generate; novga : if (CFG_VGA_ENABLE = 0 and CFG_SVGA_ENABLE = 0) generate apbo(6) <= apb_none; vgao <= vgao_none; end generate; tft_lcd_data_pad : outpadv generic map (width => 12, tech => padtech) port map (tft_lcd_data, lcd_datal); tft_lcd_clkp_pad : outpad generic map (tech => padtech) port map (tft_lcd_clk_p, clkvga_p); tft_lcd_clkn_pad : outpad generic map (tech => padtech) port map (tft_lcd_clk_n, clkvga_n); tft_lcd_hsync_pad : outpad generic map (tech => padtech) port map (tft_lcd_hsync, lcd_hsyncl); tft_lcd_vsync_pad : outpad generic map (tech => padtech) port map (tft_lcd_vsync, lcd_vsyncl); tft_lcd_de_pad : outpad generic map (tech => padtech) port map (tft_lcd_de, lcd_del); tft_lcd_reset_pad : outpad generic map (tech => padtech) port map (tft_lcd_reset_b, rstn); dvi_i2c_scl_pad : iopad generic map (tech => padtech) port map (dvi_iic_scl, dvi_i2co.scl, dvi_i2co.scloen, dvi_i2ci.scl); dvi_i2c_sda_pad : iopad generic map (tech => padtech) port map (dvi_iic_sda, dvi_i2co.sda, dvi_i2co.sdaoen, dvi_i2ci.sda); gpio0 : if CFG_GRGPIO_ENABLE /= 0 generate -- GPIO unit grgpio0: grgpio generic map(pindex => 10, paddr => 10, imask => CFG_GRGPIO_IMASK, nbits => 7) port map(rst => rstn, clk => clkm, apbi => apbi, apbo => apbo(10), gpioi => gpioi, gpioo => gpioo); pio_pads : for i in 0 to 3 generate pio_pad : iopad generic map (tech => padtech) port map (switch(i), gpioo.dout(i), gpioo.oen(i), gpioi.din(i)); end generate; pio_pads2 : for i in 4 to 6 generate pio_pad : iopad generic map (tech => padtech) port map (button(i-4), gpioo.dout(i), gpioo.oen(i), gpioi.din(i)); end generate; end generate; ahbs : if CFG_AHBSTAT = 1 generate -- AHB status register ahbstat0 : ahbstat generic map (pindex => 15, paddr => 15, pirq => 7, nftslv => CFG_AHBSTATN) port map (rstn, clkm, ahbmi, ahbsi, stati, apbi, apbo(15)); end generate; ----------------------------------------------------------------------- --- ETHERNET --------------------------------------------------------- ----------------------------------------------------------------------- eth0 : if CFG_GRETH = 1 generate -- Gaisler ethernet MAC negtx_clk <= not egtx_clk; x0 : ODDR2 port map ( Q => phy_gtx_clk, C0 => egtx_clk, C1 => negtx_clk, CE => vcc, D0 => vcc, D1 => gnd, R => gnd, S => gnd); e1 : grethm generic map( hindex => CFG_NCPU+CFG_AHB_JTAG, pindex => 14, paddr => 14, pirq => 12, memtech => memtech, mdcscaler => CPU_FREQ/1000, rmii => 0, enable_mdio => 1, fifosize => CFG_ETH_FIFO, nsync => 1, edcl => CFG_DSU_ETH, edclbufsz => CFG_ETH_BUF, phyrstadr => 7, macaddrh => CFG_ETH_ENM, macaddrl => CFG_ETH_ENL, enable_mdint => 1, ipaddrh => CFG_ETH_IPM, ipaddrl => CFG_ETH_IPL, giga => CFG_GRETH1G) port map( rst => rstn, clk => clkm, ahbmi => ahbmi, ahbmo => ahbmo(CFG_NCPU+CFG_AHB_JTAG), apbi => apbi, apbo => apbo(14), ethi => ethi, etho => etho); emdio_pad : iopad generic map (tech => padtech) port map (phy_mii_data, etho.mdio_o, etho.mdio_oe, ethi.mdio_i); etxc_pad : clkpad generic map (tech => padtech, arch => 2) port map (phy_tx_clk, ethi.tx_clk); erxc_pad : clkpad generic map (tech => padtech, arch => 2) port map (phy_rx_clk, ethi.rx_clk); erxd_pad : inpadv generic map (tech => padtech, width => 8) port map (phy_rx_data, ethi.rxd(7 downto 0)); erxdv_pad : inpad generic map (tech => padtech) port map (phy_dv, ethi.rx_dv); erxer_pad : inpad generic map (tech => padtech) port map (phy_rx_er, ethi.rx_er); erxco_pad : inpad generic map (tech => padtech) port map (phy_col, ethi.rx_col); erxcr_pad : inpad generic map (tech => padtech) port map (phy_crs, ethi.rx_crs); etxd_pad : outpadv generic map (tech => padtech, width => 8) port map (phy_tx_data, etho.txd(7 downto 0)); etxen_pad : outpad generic map (tech => padtech) port map ( phy_tx_en, etho.tx_en); etxer_pad : outpad generic map (tech => padtech) port map (phy_tx_er, etho.tx_er); emdc_pad : outpad generic map (tech => padtech) port map (phy_mii_clk, etho.mdc); erst_pad : outpad generic map (tech => padtech) port map (phy_rst_n, rstn); emdintn_pad : inpad generic map (tech => padtech) port map (phy_mii_int_n, ethi.mdint); ethi.gtx_clk <= egtx_clk; end generate; ----------------------------------------------------------------------- --- AHB ROM ---------------------------------------------------------- ----------------------------------------------------------------------- bpromgen : if CFG_AHBROMEN /= 0 generate brom : entity work.ahbrom generic map (hindex => 5, haddr => CFG_AHBRODDR, pipe => CFG_AHBROPIP) port map ( rstn, clkm, ahbsi, ahbso(5)); end generate; ----------------------------------------------------------------------- --- AHB RAM ---------------------------------------------------------- ----------------------------------------------------------------------- ocram : if CFG_AHBRAMEN = 1 generate ahbram0 : ahbram generic map (hindex => 7, haddr => CFG_AHBRADDR, tech => CFG_MEMTECH, kbytes => CFG_AHBRSZ, pipe => CFG_AHBRPIPE) port map ( rstn, clkm, ahbsi, ahbso(7)); end generate; ----------------------------------------------------------------------- --- Drive unused bus elements --------------------------------------- ----------------------------------------------------------------------- -- nam1 : for i in (CFG_NCPU+CFG_GRETH+CFG_AHB_JTAG+CFG_PCIEXP) to NAHBMST-1 generate -- ahbmo(i) <= ahbm_none; -- end generate; -- nap0 : for i in 11 to NAPBSLV-1 generate apbo(i) <= apb_none; end generate; -- nah0 : for i in 8 to NAHBSLV-1 generate ahbso(i) <= ahbs_none; end generate; ----------------------------------------------------------------------- --- Boot message ---------------------------------------------------- ----------------------------------------------------------------------- -- pragma translate_off x : report_design generic map ( msg1 => "LEON3 Xilinx SP605 Demonstration design", fabtech => tech_table(fabtech), memtech => tech_table(memtech), mdel => 1 ); -- pragma translate_on end;

gpl-2.0

b2967103dc4375399875203242fe750e

0.548496

3.498373

false

mistryalok/Zedboard

learning/opencv_hls/xapp1167_vivado/sw/fast-corner/prj/solution1/syn/vhdl/FIFO_image_filter_p_dst_data_stream_2_V.vhd

2

4,629

-- ============================================================== -- File generated by Vivado(TM) HLS - High-Level Synthesis from C, C++ and SystemC -- Version: 2014.4 -- Copyright (C) 2014 Xilinx Inc. All rights reserved. -- -- ============================================================== library IEEE; use IEEE.std_logic_1164.all; use IEEE.std_logic_unsigned.all; entity FIFO_image_filter_p_dst_data_stream_2_V_shiftReg is generic ( DATA_WIDTH : integer := 8; ADDR_WIDTH : integer := 1; DEPTH : integer := 2); port ( clk : in std_logic; data : in std_logic_vector(DATA_WIDTH-1 downto 0); ce : in std_logic; a : in std_logic_vector(ADDR_WIDTH-1 downto 0); q : out std_logic_vector(DATA_WIDTH-1 downto 0)); end FIFO_image_filter_p_dst_data_stream_2_V_shiftReg; architecture rtl of FIFO_image_filter_p_dst_data_stream_2_V_shiftReg is --constant DEPTH_WIDTH: integer := 16; type SRL_ARRAY is array (0 to DEPTH-1) of std_logic_vector(DATA_WIDTH-1 downto 0); signal SRL_SIG : SRL_ARRAY; begin p_shift: process (clk) begin if (clk'event and clk = '1') then if (ce = '1') then SRL_SIG <= data & SRL_SIG(0 to DEPTH-2); end if; end if; end process; q <= SRL_SIG(conv_integer(a)); end rtl; library ieee; use ieee.std_logic_1164.all; use ieee.std_logic_unsigned.all; entity FIFO_image_filter_p_dst_data_stream_2_V is generic ( MEM_STYLE : string := "auto"; DATA_WIDTH : integer := 8; ADDR_WIDTH : integer := 1; DEPTH : integer := 2); port ( clk : IN STD_LOGIC; reset : IN STD_LOGIC; if_empty_n : OUT STD_LOGIC; if_read_ce : IN STD_LOGIC; if_read : IN STD_LOGIC; if_dout : OUT STD_LOGIC_VECTOR(DATA_WIDTH - 1 downto 0); if_full_n : OUT STD_LOGIC; if_write_ce : IN STD_LOGIC; if_write : IN STD_LOGIC; if_din : IN STD_LOGIC_VECTOR(DATA_WIDTH - 1 downto 0)); end entity; architecture rtl of FIFO_image_filter_p_dst_data_stream_2_V is component FIFO_image_filter_p_dst_data_stream_2_V_shiftReg is generic ( DATA_WIDTH : integer := 8; ADDR_WIDTH : integer := 1; DEPTH : integer := 2); port ( clk : in std_logic; data : in std_logic_vector(DATA_WIDTH-1 downto 0); ce : in std_logic; a : in std_logic_vector(ADDR_WIDTH-1 downto 0); q : out std_logic_vector(DATA_WIDTH-1 downto 0)); end component; signal shiftReg_addr : STD_LOGIC_VECTOR(ADDR_WIDTH - 1 downto 0); signal shiftReg_data, shiftReg_q : STD_LOGIC_VECTOR(DATA_WIDTH - 1 downto 0); signal shiftReg_ce : STD_LOGIC; signal mOutPtr : STD_LOGIC_VECTOR(ADDR_WIDTH downto 0) := (others => '1'); signal internal_empty_n : STD_LOGIC := '0'; signal internal_full_n : STD_LOGIC := '1'; begin if_empty_n <= internal_empty_n; if_full_n <= internal_full_n; shiftReg_data <= if_din; if_dout <= shiftReg_q; process (clk) begin if clk'event and clk = '1' then if reset = '1' then mOutPtr <= (others => '1'); internal_empty_n <= '0'; internal_full_n <= '1'; else if ((if_read and if_read_ce) = '1' and internal_empty_n = '1') and ((if_write and if_write_ce) = '0' or internal_full_n = '0') then mOutPtr <= mOutPtr -1; if (mOutPtr = 0) then internal_empty_n <= '0'; end if; internal_full_n <= '1'; elsif ((if_read and if_read_ce) = '0' or internal_empty_n = '0') and ((if_write and if_write_ce) = '1' and internal_full_n = '1') then mOutPtr <= mOutPtr +1; internal_empty_n <= '1'; if (mOutPtr = DEPTH -2) then internal_full_n <= '0'; end if; end if; end if; end if; end process; shiftReg_addr <= (others => '0') when mOutPtr(ADDR_WIDTH) = '1' else mOutPtr(ADDR_WIDTH-1 downto 0); shiftReg_ce <= (if_write and if_write_ce) and internal_full_n; U_FIFO_image_filter_p_dst_data_stream_2_V_shiftReg : FIFO_image_filter_p_dst_data_stream_2_V_shiftReg generic map ( DATA_WIDTH => DATA_WIDTH, ADDR_WIDTH => ADDR_WIDTH, DEPTH => DEPTH) port map ( clk => clk, data => shiftReg_data, ce => shiftReg_ce, a => shiftReg_addr, q => shiftReg_q); end rtl;

gpl-3.0

ca92a440104dd9b08a2d0a544f2277b9

0.537697

3.449329

false

mistryalok/Zedboard

learning/training/Microsystem/axi_interface_part2/project_1/project_1.srcs/sources_1/ipshared/xilinx.com/axi_bram_ctrl_v4_0/b6365b74/hdl/vhdl/srl_fifo.vhd

6

11,823

------------------------------------------------------------------------------- -- SRL_FIFO entity and architecture ------------------------------------------------------------------------------- -- -- ************************************************************************* -- ** ** -- ** DISCLAIMER OF LIABILITY ** -- ** ** -- ** This text/file contains proprietary, confidential ** -- ** information of Xilinx, Inc., is distributed under ** -- ** license from Xilinx, Inc., and may be used, copied ** -- ** and/or disclosed only pursuant to the terms of a valid ** -- ** license agreement with Xilinx, Inc. Xilinx hereby ** -- ** grants you a license to use this text/file solely for ** -- ** design, simulation, implementation and creation of ** -- ** design files limited to Xilinx devices or technologies. ** -- ** Use with non-Xilinx devices or technologies is expressly ** -- ** prohibited and immediately terminates your license unless ** -- ** covered by a separate agreement. ** -- ** ** -- ** Xilinx is providing this design, code, or information ** -- ** "as-is" solely for use in developing programs and ** -- ** solutions for Xilinx devices, with no obligation on the ** -- ** part of Xilinx to provide support. By providing this design, ** -- ** code, or information as one possible implementation of ** -- ** this feature, application or standard, Xilinx is making no ** -- ** representation that this implementation is free from any ** -- ** claims of infringement. You are responsible for obtaining ** -- ** any rights you may require for your implementation. ** -- ** Xilinx expressly disclaims any warranty whatsoever with ** -- ** respect to the adequacy of the implementation, including ** -- ** but not limited to any warranties or representations that this ** -- ** implementation is free from claims of infringement, implied ** -- ** warranties of merchantability or fitness for a particular ** -- ** purpose. ** -- ** ** -- ** Xilinx products are not intended for use in life support ** -- ** appliances, devices, or systems. Use in such applications is ** -- ** expressly prohibited. ** -- ** ** -- ** Any modifications that are made to the Source Code are ** -- ** done at the users sole risk and will be unsupported. ** -- ** The Xilinx Support Hotline does not have access to source ** -- ** code and therefore cannot answer specific questions related ** -- ** to source HDL. The Xilinx Hotline support of original source ** -- ** code IP shall only address issues and questions related ** -- ** to the standard Netlist version of the core (and thus ** -- ** indirectly, the original core source). ** -- ** ** -- ** Copyright (c) 2001-2013 Xilinx, Inc. All rights reserved. ** -- ** ** -- ** This copyright and support notice must be retained as part ** -- ** of this text at all times. ** -- ** ** -- ************************************************************************* -- ------------------------------------------------------------------------------- -- Filename: srl_fifo.vhd -- -- Description: -- -- VHDL-Standard: VHDL'93 ------------------------------------------------------------------------------- -- Structure: -- srl_fifo.vhd -- ------------------------------------------------------------------------------- -- Author: goran -- Revision: $Revision: 1.1.4.1 $ -- Date: $Date: 2010/09/14 22:35:47 $ -- -- History: -- goran 2001-05-11 First Version -- KC 2001-06-20 Added Addr as an output port, for use as an occupancy -- value -- -- DCW 2002-03-12 Structural implementation of synchronous reset for -- Data_Exists DFF (using FDR) -- jam 2002-04-12 added C_XON generic for mixed vhdl/verilog sims -- -- als 2002-04-18 added default for XON generic in SRL16E, FDRE, and FDR -- component declarations -- -- DET 1/17/2008 v4_00_a -- ~~~~~~ -- - Incorporated new disclaimer header -- ^^^^^^ -- ------------------------------------------------------------------------------- -- Naming Conventions: -- active low signals: "*_n" -- clock signals: "clk", "clk_div#", "clk_#x" -- reset signals: "rst", "rst_n" -- generics: "C_*" -- user defined types: "*_TYPE" -- state machine next state: "*_ns" -- state machine current state: "*_cs" -- combinatorial signals: "*_com" -- pipelined or register delay signals: "*_d#" -- counter signals: "*cnt*" -- clock enable signals: "*_ce" -- internal version of output port "*_i" -- device pins: "*_pin" -- ports: - Names begin with Uppercase -- processes: "*_PROCESS" -- component instantiations: "<ENTITY_>I_<#|FUNC> ------------------------------------------------------------------------------- library IEEE; use IEEE.std_logic_1164.all; library unisim; use unisim.all; entity SRL_FIFO is generic ( C_DATA_BITS : natural := 8; C_DEPTH : natural := 16; C_XON : boolean := false ); port ( Clk : in std_logic; Reset : in std_logic; FIFO_Write : in std_logic; Data_In : in std_logic_vector(0 to C_DATA_BITS-1); FIFO_Read : in std_logic; Data_Out : out std_logic_vector(0 to C_DATA_BITS-1); FIFO_Full : out std_logic; Data_Exists : out std_logic; Addr : out std_logic_vector(0 to 3) -- Added Addr as a port ); end entity SRL_FIFO; architecture IMP of SRL_FIFO is attribute DowngradeIPIdentifiedWarnings: string; attribute DowngradeIPIdentifiedWarnings of IMP : architecture is "yes"; component SRL16E is -- pragma translate_off generic ( INIT : bit_vector := X"0000" ); -- pragma translate_on port ( CE : in std_logic; D : in std_logic; Clk : in std_logic; A0 : in std_logic; A1 : in std_logic; A2 : in std_logic; A3 : in std_logic; Q : out std_logic); end component SRL16E; component LUT4 generic( INIT : bit_vector := X"0000" ); port ( O : out std_logic; I0 : in std_logic; I1 : in std_logic; I2 : in std_logic; I3 : in std_logic); end component; component MULT_AND port ( I0 : in std_logic; I1 : in std_logic; LO : out std_logic); end component; component MUXCY_L port ( DI : in std_logic; CI : in std_logic; S : in std_logic; LO : out std_logic); end component; component XORCY port ( LI : in std_logic; CI : in std_logic; O : out std_logic); end component; component FDRE is port ( Q : out std_logic; C : in std_logic; CE : in std_logic; D : in std_logic; R : in std_logic); end component FDRE; component FDR is port ( Q : out std_logic; C : in std_logic; D : in std_logic; R : in std_logic); end component FDR; signal addr_i : std_logic_vector(0 to 3); signal buffer_Full : std_logic; signal buffer_Empty : std_logic; signal next_Data_Exists : std_logic; signal data_Exists_I : std_logic; signal valid_Write : std_logic; signal hsum_A : std_logic_vector(0 to 3); signal sum_A : std_logic_vector(0 to 3); signal addr_cy : std_logic_vector(0 to 4); begin -- architecture IMP buffer_Full <= '1' when (addr_i = "1111") else '0'; FIFO_Full <= buffer_Full; buffer_Empty <= '1' when (addr_i = "0000") else '0'; next_Data_Exists <= (data_Exists_I and not buffer_Empty) or (buffer_Empty and FIFO_Write) or (data_Exists_I and not FIFO_Read); Data_Exists_DFF : FDR port map ( Q => data_Exists_I, -- [out std_logic] C => Clk, -- [in std_logic] D => next_Data_Exists, -- [in std_logic] R => Reset); -- [in std_logic] Data_Exists <= data_Exists_I; valid_Write <= FIFO_Write and (FIFO_Read or not buffer_Full); addr_cy(0) <= valid_Write; Addr_Counters : for I in 0 to 3 generate hsum_A(I) <= (FIFO_Read xor addr_i(I)) and (FIFO_Write or not buffer_Empty); MUXCY_L_I : MUXCY_L port map ( DI => addr_i(I), -- [in std_logic] CI => addr_cy(I), -- [in std_logic] S => hsum_A(I), -- [in std_logic] LO => addr_cy(I+1)); -- [out std_logic] XORCY_I : XORCY port map ( LI => hsum_A(I), -- [in std_logic] CI => addr_cy(I), -- [in std_logic] O => sum_A(I)); -- [out std_logic] FDRE_I : FDRE port map ( Q => addr_i(I), -- [out std_logic] C => Clk, -- [in std_logic] CE => data_Exists_I, -- [in std_logic] D => sum_A(I), -- [in std_logic] R => Reset); -- [in std_logic] end generate Addr_Counters; FIFO_RAM : for I in 0 to C_DATA_BITS-1 generate SRL16E_I : SRL16E -- pragma translate_off generic map ( INIT => x"0000") -- pragma translate_on port map ( CE => valid_Write, -- [in std_logic] D => Data_In(I), -- [in std_logic] Clk => Clk, -- [in std_logic] A0 => addr_i(0), -- [in std_logic] A1 => addr_i(1), -- [in std_logic] A2 => addr_i(2), -- [in std_logic] A3 => addr_i(3), -- [in std_logic] Q => Data_Out(I)); -- [out std_logic] end generate FIFO_RAM; ------------------------------------------------------------------------------- -- INT_ADDR_PROCESS ------------------------------------------------------------------------------- -- This process assigns the internal address to the output port ------------------------------------------------------------------------------- INT_ADDR_PROCESS:process (addr_i) begin -- process Addr <= addr_i; end process; end architecture IMP;

gpl-3.0

ba29c0ebc30e926b5a221414e80d0cf0

0.438806

4.375648

false

mistryalok/Zedboard

learning/training/MSD/s09/axi_dma_sg/vivado/project_1/project_1.srcs/sources_1/ipshared/xilinx.com/axi_sg_v4_1/0535f152/hdl/src/vhdl/axi_sg_ftch_sm.vhd

4

47,863

-- ************************************************************************* -- -- (c) Copyright 2010-2011 Xilinx, Inc. All rights reserved. -- -- This file contains confidential and proprietary information -- of Xilinx, Inc. and is protected under U.S. and -- international copyright and other intellectual property -- laws. -- -- DISCLAIMER -- This disclaimer is not a license and does not grant any -- rights to the materials distributed herewith. Except as -- otherwise provided in a valid license issued to you by -- Xilinx, and to the maximum extent permitted by applicable -- law: (1) THESE MATERIALS ARE MADE AVAILABLE "AS IS" AND -- WITH ALL FAULTS, AND XILINX HEREBY DISCLAIMS ALL WARRANTIES -- AND CONDITIONS, EXPRESS, IMPLIED, OR STATUTORY, INCLUDING -- BUT NOT LIMITED TO WARRANTIES OF MERCHANTABILITY, NON- -- INFRINGEMENT, OR FITNESS FOR ANY PARTICULAR PURPOSE; and -- (2) Xilinx shall not be liable (whether in contract or tort, -- including negligence, or under any other theory of -- liability) for any loss or damage of any kind or nature -- related to, arising under or in connection with these -- materials, including for any direct, or any indirect, -- special, incidental, or consequential loss or damage -- (including loss of data, profits, goodwill, or any type of -- loss or damage suffered as a result of any action brought -- by a third party) even if such damage or loss was -- reasonably foreseeable or Xilinx had been advised of the -- possibility of the same. -- -- CRITICAL APPLICATIONS -- Xilinx products are not designed or intended to be fail- -- safe, or for use in any application requiring fail-safe -- performance, such as life-support or safety devices or -- systems, Class III medical devices, nuclear facilities, -- applications related to the deployment of airbags, or any -- other applications that could lead to death, personal -- injury, or severe property or environmental damage -- (individually and collectively, "Critical -- Applications"). Customer assumes the sole risk and -- liability of any use of Xilinx products in Critical -- Applications, subject only to applicable laws and -- regulations governing limitations on product liability. -- -- THIS COPYRIGHT NOTICE AND DISCLAIMER MUST BE RETAINED AS -- PART OF THIS FILE AT ALL TIMES. -- -- ************************************************************************* -- ------------------------------------------------------------------------------- -- Filename: axi_sg_ftch_sm.vhd -- Description: This entity manages fetching of descriptors. -- -- VHDL-Standard: VHDL'93 ------------------------------------------------------------------------------- library ieee; use ieee.std_logic_1164.all; use ieee.numeric_std.all; use ieee.std_logic_misc.all; library unisim; use unisim.vcomponents.all; library axi_sg_v4_1; use axi_sg_v4_1.axi_sg_pkg.all; library lib_pkg_v1_0; use lib_pkg_v1_0.lib_pkg.clog2; ------------------------------------------------------------------------------- entity axi_sg_ftch_sm is generic ( C_M_AXI_SG_ADDR_WIDTH : integer range 32 to 64 := 32; -- Master AXI Memory Map Address Width for Scatter Gather R/W Port C_ENABLE_MULTI_CHANNEL : integer range 0 to 1 := 0; C_INCLUDE_CH1 : integer range 0 to 1 := 1; -- Include or Exclude channel 1 scatter gather engine -- 0 = Exclude Channel 1 SG Engine -- 1 = Include Channel 1 SG Engine C_INCLUDE_CH2 : integer range 0 to 1 := 1; -- Include or Exclude channel 2 scatter gather engine -- 0 = Exclude Channel 2 SG Engine -- 1 = Include Channel 2 SG Engine C_SG_CH1_WORDS_TO_FETCH : integer range 4 to 16 := 8; -- Number of words to fetch C_SG_CH2_WORDS_TO_FETCH : integer range 4 to 16 := 8; -- Number of words to fetch C_SG_FTCH_DESC2QUEUE : integer range 0 to 8 := 0; -- Number of descriptors to fetch and queue for each channel. -- A value of zero excludes the fetch queues. C_SG_CH1_ENBL_STALE_ERROR : integer range 0 to 1 := 1; -- Enable or disable stale descriptor check -- 0 = Disable stale descriptor error check -- 1 = Enable stale descriptor error check C_SG_CH2_ENBL_STALE_ERROR : integer range 0 to 1 := 1 -- Enable or disable stale descriptor check -- 0 = Disable stale descriptor error check -- 1 = Enable stale descriptor error check ); port ( ----------------------------------------------------------------------- -- AXI Scatter Gather Interface ----------------------------------------------------------------------- m_axi_sg_aclk : in std_logic ; -- m_axi_sg_aresetn : in std_logic ; -- -- updt_error : in std_logic ; -- -- -- Channel 1 Control and Status -- ch1_run_stop : in std_logic ; -- ch1_desc_flush : in std_logic ; -- ch1_updt_done : in std_logic ; -- ch1_sg_idle : in std_logic ; -- ch1_tailpntr_enabled : in std_logic ; -- ch1_ftch_queue_full : in std_logic ; -- ch1_ftch_queue_empty : in std_logic ; -- ch1_ftch_pause : in std_logic ; -- ch1_fetch_address : in std_logic_vector -- (C_M_AXI_SG_ADDR_WIDTH-1 downto 0) ; -- ch1_ftch_active : out std_logic ; -- ch1_ftch_idle : out std_logic ; -- ch1_ftch_interr_set : out std_logic ; -- ch1_ftch_slverr_set : out std_logic ; -- ch1_ftch_decerr_set : out std_logic ; -- ch1_ftch_err_early : out std_logic ; -- ch1_ftch_stale_desc : out std_logic ; -- -- -- Channel 2 Control and Status -- ch2_run_stop : in std_logic ; -- ch2_desc_flush : in std_logic ; -- ch2_updt_done : in std_logic ; -- ch2_sg_idle : in std_logic ; -- ch2_tailpntr_enabled : in std_logic ; -- ch2_ftch_queue_full : in std_logic ; -- ch2_ftch_queue_empty : in std_logic ; -- ch2_ftch_pause : in std_logic ; -- ch2_fetch_address : in std_logic_vector -- (C_M_AXI_SG_ADDR_WIDTH-1 downto 0) ; -- ch2_ftch_active : out std_logic ; -- ch2_ftch_idle : out std_logic ; -- ch2_ftch_interr_set : out std_logic ; -- ch2_ftch_slverr_set : out std_logic ; -- ch2_ftch_decerr_set : out std_logic ; -- ch2_ftch_err_early : out std_logic ; -- ch2_ftch_stale_desc : out std_logic ; -- -- -- DataMover Command -- ftch_cmnd_wr : out std_logic ; -- ftch_cmnd_data : out std_logic_vector -- ((C_M_AXI_SG_ADDR_WIDTH+CMD_BASE_WIDTH)-1 downto 0); -- -- DataMover Status -- ftch_done : in std_logic ; -- ftch_error : in std_logic ; -- ftch_interr : in std_logic ; -- ftch_slverr : in std_logic ; -- ftch_decerr : in std_logic ; -- ftch_stale_desc : in std_logic ; -- ftch_error_early : in std_logic ; -- ftch_error_addr : out std_logic_vector -- (C_M_AXI_SG_ADDR_WIDTH-1 downto 0) -- ); end axi_sg_ftch_sm; ------------------------------------------------------------------------------- -- Architecture ------------------------------------------------------------------------------- architecture implementation of axi_sg_ftch_sm is attribute DowngradeIPIdentifiedWarnings: string; attribute DowngradeIPIdentifiedWarnings of implementation : architecture is "yes"; attribute mark_debug : string; ------------------------------------------------------------------------------- -- Functions ------------------------------------------------------------------------------- -- No Functions Declared ------------------------------------------------------------------------------- -- Constants Declarations ------------------------------------------------------------------------------- -- DataMover Command Type constant FETCH_CMD_TYPE : std_logic := '1'; -- DataMover Cmnd Reserved Bits constant FETCH_MSB_IGNORED : std_logic_vector(7 downto 0) := (others => '0'); -- DataMover Cmnd Reserved Bits constant FETCH_LSB_IGNORED : std_logic_vector(15 downto 0) := (others => '0'); -- DataMover Cmnd Bytes to Xfer for Channel 1 constant FETCH_CH1_CMD_BTT : std_logic_vector(SG_BTT_WIDTH-1 downto 0) := std_logic_vector(to_unsigned( (C_SG_CH1_WORDS_TO_FETCH*4),SG_BTT_WIDTH)); -- DataMover Cmnd Bytes to Xfer for Channel 2 constant FETCH_CH2_CMD_BTT : std_logic_vector(SG_BTT_WIDTH-1 downto 0) := std_logic_vector(to_unsigned( (C_SG_CH2_WORDS_TO_FETCH*4),SG_BTT_WIDTH)); -- DataMover Cmnd Reserved Bits constant FETCH_CMD_RSVD : std_logic_vector( DATAMOVER_CMD_RSVMSB_BOFST + C_M_AXI_SG_ADDR_WIDTH downto DATAMOVER_CMD_RSVLSB_BOFST + C_M_AXI_SG_ADDR_WIDTH) := (others => '0'); -- CR585958 Constant declaration in axi_sg_ftch_sm needs to move under associated generate -- Required width in bits for C_SG_FTCH_DESC2QUEUE --constant SG_FTCH_DESC2QUEUE_WIDTH : integer := clog2(C_SG_FTCH_DESC2QUEUE+1); -- ---- Vector version of C_SG_FTCH_DESC2QUEUE --constant SG_FTCH_DESC2QUEUE_VEC : std_logic_vector(SG_FTCH_DESC2QUEUE_WIDTH-1 downto 0) -- := std_logic_vector(to_unsigned -- (C_SG_FTCH_DESC2QUEUE,SG_FTCH_DESC2QUEUE_WIDTH)); ------------------------------------------------------------------------------- -- Signal / Type Declarations ------------------------------------------------------------------------------- -- DataMover Commmand TAG signal fetch_tag : std_logic_vector(3 downto 0) := (others => '0'); type SG_FTCH_STATE_TYPE is ( IDLE, FETCH_DESCRIPTOR, FETCH_STATUS, FETCH_ERROR ); signal ftch_cs : SG_FTCH_STATE_TYPE; signal ftch_ns : SG_FTCH_STATE_TYPE; -- State Machine Signals signal ch1_active_set : std_logic := '0'; signal ch2_active_set : std_logic := '0'; signal write_cmnd_cmb : std_logic := '0'; signal ch1_ftch_sm_idle : std_logic := '0'; signal ch2_ftch_sm_idle : std_logic := '0'; signal ch1_pause_fetch : std_logic := '0'; signal ch2_pause_fetch : std_logic := '0'; signal ch2_pause_fetch1 : std_logic := '0'; signal ch2_pause_fetch2 : std_logic := '0'; signal ch2_pause_fetch3 : std_logic := '0'; signal ch2_updt_done1 : std_logic := '0'; signal ch2_updt_done2 : std_logic := '0'; -- Misc Signals signal fetch_cmd_addr : std_logic_vector (C_M_AXI_SG_ADDR_WIDTH-1 downto 0) := (others => '0'); signal ch1_active_i : std_logic := '0'; signal service_ch1 : std_logic := '0'; signal ch2_active_i : std_logic := '0'; signal service_ch2 : std_logic := '0'; attribute mark_debug of ch1_active_i : signal is "true"; attribute mark_debug of ch2_active_i : signal is "true"; signal fetch_cmd_btt : std_logic_vector (SG_BTT_WIDTH-1 downto 0) := (others => '0'); signal ch1_stale_descriptor : std_logic := '0'; signal ch2_stale_descriptor : std_logic := '0'; attribute mark_debug of ch1_stale_descriptor : signal is "true"; attribute mark_debug of ch2_stale_descriptor : signal is "true"; signal ch1_ftch_interr_set_i : std_logic := '0'; signal ch2_ftch_interr_set_i : std_logic := '0'; -- CR585958 Constant declaration in axi_sg_ftch_sm needs to move under associated generate -- counts for keeping track of queue descriptors to prevent -- fifo fill --signal ch1_desc_ftched_count : std_logic_vector -- (SG_FTCH_DESC2QUEUE_WIDTH-1 downto 0) := (others => '0'); --signal ch2_desc_ftched_count : std_logic_vector -- (SG_FTCH_DESC2QUEUE_WIDTH-1 downto 0) := (others => '0'); ------------------------------------------------------------------------------- -- Begin architecture logic ------------------------------------------------------------------------------- begin ch1_ftch_active <= ch1_active_i; ch2_ftch_active <= ch2_active_i; ------------------------------------------------------------------------------- -- Scatter Gather Fetch State Machine ------------------------------------------------------------------------------- SG_FTCH_MACHINE : process(ftch_cs, ch1_active_i, ch2_active_i, service_ch1, service_ch2, ftch_error, ftch_done) begin -- Default signal assignment ch1_active_set <= '0'; ch2_active_set <= '0'; write_cmnd_cmb <= '0'; ch1_ftch_sm_idle <= '0'; ch2_ftch_sm_idle <= '0'; ftch_ns <= ftch_cs; case ftch_cs is ------------------------------------------------------------------- when IDLE => ch1_ftch_sm_idle <= not service_ch1; ch2_ftch_sm_idle <= not service_ch2; -- sg error during fetch - shut down if(ftch_error = '1')then ftch_ns <= FETCH_ERROR; -- If channel 1 is running and not idle and queue is not full -- then fetch descriptor for channel 1 elsif(service_ch1 = '1')then ch1_active_set <= '1'; ftch_ns <= FETCH_DESCRIPTOR; -- If channel 2 is running and not idle and queue is not full -- then fetch descriptor for channel 2 elsif(service_ch2 = '1')then ch2_active_set <= '1'; ftch_ns <= FETCH_DESCRIPTOR; else ftch_ns <= IDLE; end if; ------------------------------------------------------------------- when FETCH_DESCRIPTOR => -- sg error during fetch - shut down if(ftch_error = '1')then ftch_ns <= FETCH_ERROR; else ch1_ftch_sm_idle <= not ch1_active_i and not service_ch1; ch2_ftch_sm_idle <= not ch2_active_i and not service_ch2; write_cmnd_cmb <= '1'; ftch_ns <= FETCH_STATUS; end if; ------------------------------------------------------------------- when FETCH_STATUS => ch1_ftch_sm_idle <= not ch1_active_i and not service_ch1; ch2_ftch_sm_idle <= not ch2_active_i and not service_ch2; -- sg error during fetch - shut down if(ftch_error = '1')then ftch_ns <= FETCH_ERROR; elsif(ftch_done = '1')then -- If just finished fethcing for channel 2 then... if(ch2_active_i = '1')then -- If ready, fetch descriptor for channel 1 if(service_ch1 = '1')then ch1_active_set <= '1'; ftch_ns <= FETCH_DESCRIPTOR; -- Else if channel 2 still ready then fetch -- another descriptor for channel 2 elsif(service_ch2 = '1')then ch1_ftch_sm_idle <= '1'; ftch_ns <= FETCH_DESCRIPTOR; -- Otherwise return to IDLE else ftch_ns <= IDLE; end if; -- If just finished fethcing for channel 1 then... elsif(ch1_active_i = '1')then -- If ready, fetch descriptor for channel 2 if(service_ch2 = '1')then ch2_active_set <= '1'; ftch_ns <= FETCH_DESCRIPTOR; -- Else if channel 1 still ready then fetch -- another descriptor for channel 1 elsif(service_ch1 = '1')then ch2_ftch_sm_idle <= '1'; ftch_ns <= FETCH_DESCRIPTOR; -- Otherwise return to IDLE else ftch_ns <= IDLE; end if; else ftch_ns <= IDLE; end if; else ftch_ns <= FETCH_STATUS; end if; ------------------------------------------------------------------- when FETCH_ERROR => ch1_ftch_sm_idle <= '1'; ch2_ftch_sm_idle <= '1'; ftch_ns <= FETCH_ERROR; ------------------------------------------------------------------- -- coverage off when others => ftch_ns <= IDLE; -- coverage on end case; end process SG_FTCH_MACHINE; ------------------------------------------------------------------------------- ------------------------------------------------------------------------------- REGISTER_STATE : process(m_axi_sg_aclk) begin if(m_axi_sg_aclk'EVENT and m_axi_sg_aclk = '1')then if(m_axi_sg_aresetn = '0')then ftch_cs <= IDLE; else ftch_cs <= ftch_ns; end if; end if; end process REGISTER_STATE; ------------------------------------------------------------------------------- -- Channel included therefore generate fetch logic ------------------------------------------------------------------------------- GEN_CH1_FETCH : if C_INCLUDE_CH1 = 1 generate begin ------------------------------------------------------------------------------- -- Active channel flag. Indicates which channel is active. -- 0 = channel active -- 1 = channel active ------------------------------------------------------------------------------- CH1_ACTIVE_PROCESS : process(m_axi_sg_aclk) begin if(m_axi_sg_aclk'EVENT and m_axi_sg_aclk = '1')then if(m_axi_sg_aresetn = '0' or ch2_active_set = '1')then ch1_active_i <= '0'; elsif(ch1_active_set = '1')then ch1_active_i <= '1'; end if; end if; end process CH1_ACTIVE_PROCESS; ------------------------------------------------------------------------------- -- Channel 1 IDLE process. Indicates channel 1 fetch process is IDLE -- This is 1 part of determining IDLE for a channel ------------------------------------------------------------------------------- CH1_IDLE_PROCESS : process(m_axi_sg_aclk) begin if(m_axi_sg_aclk'EVENT and m_axi_sg_aclk = '1')then -- If reset or stopped then clear idle bit if(m_axi_sg_aresetn = '0')then ch1_ftch_idle <= '1'; -- SG Error therefore force IDLE -- CR564855 - fetch idle asserted too soon when update error occured. -- fetch idle does not need to be concerned with updt_error. This is -- because on going fetch is guarentteed to complete regardless of dma -- controller or sg update engine. --elsif(updt_error = '1' or ftch_error = '1' elsif(ftch_error = '1' or ch1_ftch_interr_set_i = '1')then ch1_ftch_idle <= '1'; -- When SG Fetch no longer idle then clear fetch idle elsif(ch1_sg_idle = '0')then ch1_ftch_idle <= '0'; -- If tail = cur and fetch queue is empty then elsif(ch1_sg_idle = '1' and ch1_ftch_queue_empty = '1' and ch1_ftch_sm_idle = '1')then ch1_ftch_idle <= '1'; end if; end if; end process CH1_IDLE_PROCESS; ------------------------------------------------------------------------------- -- For No Fetch Queue, generate pause logic to prevent partial descriptor from -- being fetched and then endless throttle on AXI read bus ------------------------------------------------------------------------------- GEN_CH1_FETCH_PAUSE : if C_SG_FTCH_DESC2QUEUE = 0 generate begin REG_PAUSE_FETCH : process(m_axi_sg_aclk) begin if(m_axi_sg_aclk'EVENT and m_axi_sg_aclk = '1')then -- On descriptor update done clear pause if(m_axi_sg_aresetn = '0' or ch1_updt_done = '1')then ch1_pause_fetch <= '0'; -- If channel active and command written then pause elsif(ch1_active_i='1' and write_cmnd_cmb = '1')then ch1_pause_fetch <= '1'; end if; end if; end process REG_PAUSE_FETCH; end generate GEN_CH1_FETCH_PAUSE; -- Fetch queues so do not need to pause GEN_CH1_NO_FETCH_PAUSE : if C_SG_FTCH_DESC2QUEUE /= 0 generate -- -- CR585958 -- -- Required width in bits for C_SG_FTCH_DESC2QUEUE -- constant SG_FTCH_DESC2QUEUE_WIDTH : integer := clog2(C_SG_FTCH_DESC2QUEUE+1); -- -- Vector version of C_SG_FTCH_DESC2QUEUE -- constant SG_FTCH_DESC2QUEUE_VEC : std_logic_vector(SG_FTCH_DESC2QUEUE_WIDTH-1 downto 0) -- := std_logic_vector(to_unsigned -- (C_SG_FTCH_DESC2QUEUE,SG_FTCH_DESC2QUEUE_WIDTH)); -- signal desc_queued_incr : std_logic := '0'; -- signal desc_queued_decr : std_logic := '0'; -- -- -- CR585958 -- signal ch1_desc_ftched_count: std_logic_vector -- (SG_FTCH_DESC2QUEUE_WIDTH-1 downto 0) := (others => '0'); -- begin -- -- desc_queued_incr <= '1' when ch1_active_i = '1' -- and write_cmnd_cmb = '1' -- and ch1_ftch_descpulled = '0' -- else '0'; -- -- desc_queued_decr <= '1' when ch1_ftch_descpulled = '1' -- and not (ch1_active_i = '1' and write_cmnd_cmb = '1') -- else '0'; -- -- -- Keep track of descriptors queued version descriptors updated -- DESC_FETCHED_CNTR : process(m_axi_sg_aclk) -- begin -- if(m_axi_sg_aclk'EVENT and m_axi_sg_aclk = '1')then -- if(m_axi_sg_aresetn = '0')then -- ch1_desc_ftched_count <= (others => '0'); -- elsif(desc_queued_incr = '1')then -- ch1_desc_ftched_count <= std_logic_vector(unsigned(ch1_desc_ftched_count) + 1); -- elsif(desc_queued_decr = '1')then -- ch1_desc_ftched_count <= std_logic_vector(unsigned(ch1_desc_ftched_count) - 1); -- end if; -- end if; -- end process DESC_FETCHED_CNTR; -- -- REG_PAUSE_FETCH : process(m_axi_sg_aclk) -- begin -- if(m_axi_sg_aclk'EVENT and m_axi_sg_aclk = '1')then -- if(m_axi_sg_aresetn = '0')then -- ch1_pause_fetch <= '0'; -- elsif(ch1_desc_ftched_count >= SG_FTCH_DESC2QUEUE_VEC)then -- ch1_pause_fetch <= '1'; -- else -- ch1_pause_fetch <= '0'; -- end if; -- end if; -- end process REG_PAUSE_FETCH; -- -- -- ch1_pause_fetch <= ch1_ftch_pause; end generate GEN_CH1_NO_FETCH_PAUSE; ------------------------------------------------------------------------------- -- Channel 1 ready to be serviced? ------------------------------------------------------------------------------- service_ch1 <= '1' when ch1_run_stop = '1' -- Channel running and ch1_sg_idle = '0' -- SG Engine running and ch1_ftch_queue_full = '0' -- Queue not full and updt_error = '0' -- No SG Update error and ch1_stale_descriptor = '0' -- No Stale Descriptors and ch1_desc_flush = '0' -- Not flushing desc and ch1_pause_fetch = '0' -- Not pausing else '0'; ------------------------------------------------------------------------------- -- Log Fetch Errors ------------------------------------------------------------------------------- INT_ERROR_PROCESS : process(m_axi_sg_aclk) begin if(m_axi_sg_aclk'EVENT and m_axi_sg_aclk = '1')then -- If reset or stopped then clear idle bit if(m_axi_sg_aresetn = '0')then ch1_ftch_interr_set_i <= '0'; -- Channel active and datamover int error or fetch done and descriptor stale elsif((ch1_active_i = '1' and ftch_interr = '1') or ((ftch_done = '1' or ftch_error = '1') and ch1_stale_descriptor = '1'))then ch1_ftch_interr_set_i <= '1'; end if; end if; end process INT_ERROR_PROCESS; ch1_ftch_interr_set <= ch1_ftch_interr_set_i; SLV_ERROR_PROCESS : process(m_axi_sg_aclk) begin if(m_axi_sg_aclk'EVENT and m_axi_sg_aclk = '1')then -- If reset or stopped then clear idle bit if(m_axi_sg_aresetn = '0')then ch1_ftch_slverr_set <= '0'; elsif(ch1_active_i = '1' and ftch_slverr = '1')then ch1_ftch_slverr_set <= '1'; end if; end if; end process SLV_ERROR_PROCESS; DEC_ERROR_PROCESS : process(m_axi_sg_aclk) begin if(m_axi_sg_aclk'EVENT and m_axi_sg_aclk = '1')then -- If reset or stopped then clear idle bit if(m_axi_sg_aresetn = '0')then ch1_ftch_decerr_set <= '0'; elsif(ch1_active_i = '1' and ftch_decerr = '1')then ch1_ftch_decerr_set <= '1'; end if; end if; end process DEC_ERROR_PROCESS; -- Early detection of SlvErr or DecErr, used to prevent error'ed descriptor -- from being used by dma controller ch1_ftch_err_early <= '1' when ftch_error_early = '1' and ch1_active_i = '1' else '0'; -- Enable stale descriptor check GEN_CH1_STALE_CHECK : if C_SG_CH1_ENBL_STALE_ERROR = 1 generate begin ----------------------------------------------------------------------- -- Stale Descriptor Error ----------------------------------------------------------------------- CH1_STALE_DESC : process(m_axi_sg_aclk) begin if(m_axi_sg_aclk'EVENT and m_axi_sg_aclk = '1')then -- If reset then clear flag if(m_axi_sg_aresetn = '0')then ch1_stale_descriptor <= '0'; elsif(ftch_stale_desc = '1' and ch1_active_i = '1' )then ch1_stale_descriptor <= '1'; end if; end if; end process CH1_STALE_DESC; end generate GEN_CH1_STALE_CHECK; -- Disable stale descriptor check GEN_CH1_NO_STALE_CHECK : if C_SG_CH1_ENBL_STALE_ERROR = 0 generate begin ch1_stale_descriptor <= '0'; end generate GEN_CH1_NO_STALE_CHECK; -- Early detection of Stale Descriptor (valid only in tailpntr mode) used -- to prevent error'ed descriptor from being used. ch1_ftch_stale_desc <= ch1_stale_descriptor; end generate GEN_CH1_FETCH; ------------------------------------------------------------------------------- -- Channel excluded therefore do not generate fetch logic ------------------------------------------------------------------------------- GEN_NO_CH1_FETCH : if C_INCLUDE_CH1 = 0 generate begin service_ch1 <= '0'; ch1_active_i <= '0'; ch1_ftch_idle <= '0'; ch1_ftch_interr_set <= '0'; ch1_ftch_slverr_set <= '0'; ch1_ftch_decerr_set <= '0'; ch1_ftch_err_early <= '0'; ch1_ftch_stale_desc <= '0'; end generate GEN_NO_CH1_FETCH; ------------------------------------------------------------------------------- -- Channel included therefore generate fetch logic ------------------------------------------------------------------------------- GEN_CH2_FETCH : if C_INCLUDE_CH2 = 1 generate begin ------------------------------------------------------------------------------- -- Active channel flag. Indicates which channel is active. -- 0 = channel active -- 1 = channel active ------------------------------------------------------------------------------- CH2_ACTIVE_PROCESS : process(m_axi_sg_aclk) begin if(m_axi_sg_aclk'EVENT and m_axi_sg_aclk = '1')then if(m_axi_sg_aresetn = '0' or ch1_active_set = '1')then ch2_active_i <= '0'; elsif(ch2_active_set = '1')then ch2_active_i <= '1'; end if; end if; end process CH2_ACTIVE_PROCESS; ------------------------------------------------------------------------------- -- Channel 2 IDLE process. Indicates channel 2 fetch process is IDLE -- This is 1 part of determining IDLE for a channel ------------------------------------------------------------------------------- CH2_IDLE_PROCESS : process(m_axi_sg_aclk) begin if(m_axi_sg_aclk'EVENT and m_axi_sg_aclk = '1')then -- If reset or stopped then clear idle bit if(m_axi_sg_aresetn = '0')then ch2_ftch_idle <= '1'; -- SG Error therefore force IDLE -- CR564855 - fetch idle asserted too soon when update error occured. -- fetch idle does not need to be concerned with updt_error. This is -- because on going fetch is guarentteed to complete regardless of dma -- controller or sg update engine. -- elsif(updt_error = '1' or ftch_error = '1' elsif(ftch_error = '1' or ch2_ftch_interr_set_i = '1')then ch2_ftch_idle <= '1'; -- When SG Fetch no longer idle then clear fetch idle elsif(ch2_sg_idle = '0')then ch2_ftch_idle <= '0'; -- If tail = cur and fetch queue is empty then elsif(ch2_sg_idle = '1' and ch2_ftch_queue_empty = '1' and ch2_ftch_sm_idle = '1')then ch2_ftch_idle <= '1'; end if; end if; end process CH2_IDLE_PROCESS; ------------------------------------------------------------------------------- -- For No Fetch Queue, generate pause logic to prevent partial descriptor from -- being fetched and then endless throttle on AXI read bus ------------------------------------------------------------------------------- GEN_CH2_FETCH_PAUSE : if C_SG_FTCH_DESC2QUEUE = 0 generate begin REG_PAUSE_FETCH : process(m_axi_sg_aclk) begin if(m_axi_sg_aclk'EVENT and m_axi_sg_aclk = '1')then -- On descriptor update done clear pause if(m_axi_sg_aresetn = '0' or ch2_updt_done = '1')then ch2_pause_fetch <= '0'; -- If channel active and command written then pause elsif(ch2_active_i='1' and write_cmnd_cmb = '1')then ch2_pause_fetch <= '1'; end if; ch2_pause_fetch1 <= ch2_pause_fetch; ch2_pause_fetch2 <= ch2_pause_fetch1; ch2_pause_fetch3 <= ch2_pause_fetch2; end if; end process REG_PAUSE_FETCH; end generate GEN_CH2_FETCH_PAUSE; -- Fetch queues so do not need to pause GEN_CH2_NO_FETCH_PAUSE : if C_SG_FTCH_DESC2QUEUE /= 0 generate -- -- CR585958 -- -- Required width in bits for C_SG_FTCH_DESC2QUEUE -- constant SG_FTCH_DESC2QUEUE_WIDTH : integer := clog2(C_SG_FTCH_DESC2QUEUE+1); -- -- Vector version of C_SG_FTCH_DESC2QUEUE -- constant SG_FTCH_DESC2QUEUE_VEC : std_logic_vector(SG_FTCH_DESC2QUEUE_WIDTH-1 downto 0) -- := std_logic_vector(to_unsigned -- (C_SG_FTCH_DESC2QUEUE,SG_FTCH_DESC2QUEUE_WIDTH)); -- signal desc_queued_incr : std_logic := '0'; -- signal desc_queued_decr : std_logic := '0'; -- -- -- CR585958 -- signal ch2_desc_ftched_count: std_logic_vector -- (SG_FTCH_DESC2QUEUE_WIDTH-1 downto 0) := (others => '0'); -- -- begin -- -- desc_queued_incr <= '1' when ch2_active_i = '1' -- and write_cmnd_cmb = '1' -- and ch2_ftch_descpulled = '0' -- else '0'; -- -- desc_queued_decr <= '1' when ch2_ftch_descpulled = '1' -- and not (ch2_active_i = '1' and write_cmnd_cmb = '1') -- else '0'; -- -- -- Keep track of descriptors queued version descriptors updated -- DESC_FETCHED_CNTR : process(m_axi_sg_aclk) -- begin -- if(m_axi_sg_aclk'EVENT and m_axi_sg_aclk = '1')then -- if(m_axi_sg_aresetn = '0')then -- ch2_desc_ftched_count <= (others => '0'); -- elsif(desc_queued_incr = '1')then -- ch2_desc_ftched_count <= std_logic_vector(unsigned(ch2_desc_ftched_count) + 1); -- elsif(desc_queued_decr = '1')then -- ch2_desc_ftched_count <= std_logic_vector(unsigned(ch2_desc_ftched_count) - 1); -- end if; -- end if; -- end process DESC_FETCHED_CNTR; -- -- REG_PAUSE_FETCH : process(m_axi_sg_aclk) -- begin -- if(m_axi_sg_aclk'EVENT and m_axi_sg_aclk = '1')then -- if(m_axi_sg_aresetn = '0')then -- ch2_pause_fetch <= '0'; -- elsif(ch2_desc_ftched_count >= SG_FTCH_DESC2QUEUE_VEC)then -- ch2_pause_fetch <= '1'; -- else -- ch2_pause_fetch <= '0'; -- end if; -- end if; -- end process REG_PAUSE_FETCH; -- ch2_pause_fetch <= ch2_ftch_pause; end generate GEN_CH2_NO_FETCH_PAUSE; ------------------------------------------------------------------------------- -- Channel 2 ready to be serviced? ------------------------------------------------------------------------------- MCDMA : if (C_ENABLE_MULTI_CHANNEL = 1) generate NOQUEUE : if (C_SG_FTCH_DESC2QUEUE = 0) generate service_ch2 <= '1' when ch2_run_stop = '1' -- Channel running and ch2_sg_idle = '0' -- SG Engine running and ch2_ftch_queue_full = '0' -- Queue not full and updt_error = '0' -- No SG Update error and ch2_stale_descriptor = '0' -- No Stale Descriptors and ch2_desc_flush = '0' -- Not flushing desc and ch2_pause_fetch3 = '0' -- No fetch pause else '0'; end generate NOQUEUE; QUEUE : if (C_SG_FTCH_DESC2QUEUE /= 0) generate service_ch2 <= '1' when ch2_run_stop = '1' -- Channel running and ch2_sg_idle = '0' -- SG Engine running and ch2_ftch_queue_full = '0' -- Queue not full and updt_error = '0' -- No SG Update error and ch2_stale_descriptor = '0' -- No Stale Descriptors and ch2_desc_flush = '0' -- Not flushing desc and ch2_pause_fetch = '0' -- No fetch pause else '0'; end generate QUEUE; end generate MCDMA; NO_MCDMA : if (C_ENABLE_MULTI_CHANNEL = 0) generate service_ch2 <= '1' when ch2_run_stop = '1' -- Channel running and ch2_sg_idle = '0' -- SG Engine running and ch2_ftch_queue_full = '0' -- Queue not full and updt_error = '0' -- No SG Update error and ch2_stale_descriptor = '0' -- No Stale Descriptors and ch2_desc_flush = '0' -- Not flushing desc and ch2_pause_fetch = '0' -- No fetch pause else '0'; end generate NO_MCDMA; ------------------------------------------------------------------------------- -- Log Fetch Errors ------------------------------------------------------------------------------- INT_ERROR_PROCESS : process(m_axi_sg_aclk) begin if(m_axi_sg_aclk'EVENT and m_axi_sg_aclk = '1')then -- If reset or stopped then clear idle bit if(m_axi_sg_aresetn = '0')then ch2_ftch_interr_set_i <= '0'; -- Channel active and datamover int error or fetch done and descriptor stale elsif((ch2_active_i = '1' and ftch_interr = '1') or ((ftch_done = '1' or ftch_error = '1') and ch2_stale_descriptor = '1'))then ch2_ftch_interr_set_i <= '1'; end if; end if; end process INT_ERROR_PROCESS; ch2_ftch_interr_set <= ch2_ftch_interr_set_i; SLV_ERROR_PROCESS : process(m_axi_sg_aclk) begin if(m_axi_sg_aclk'EVENT and m_axi_sg_aclk = '1')then -- If reset or stopped then clear idle bit if(m_axi_sg_aresetn = '0')then ch2_ftch_slverr_set <= '0'; elsif(ch2_active_i = '1' and ftch_slverr = '1')then ch2_ftch_slverr_set <= '1'; end if; end if; end process SLV_ERROR_PROCESS; DEC_ERROR_PROCESS : process(m_axi_sg_aclk) begin if(m_axi_sg_aclk'EVENT and m_axi_sg_aclk = '1')then -- If reset or stopped then clear idle bit if(m_axi_sg_aresetn = '0')then ch2_ftch_decerr_set <= '0'; elsif(ch2_active_i = '1' and ftch_decerr = '1')then ch2_ftch_decerr_set <= '1'; end if; end if; end process DEC_ERROR_PROCESS; -- Early detection of SlvErr or DecErr, used to prevent error'ed descriptor -- from being used by dma controller ch2_ftch_err_early <= '1' when ftch_error_early = '1' and ch2_active_i = '1' else '0'; -- Enable stale descriptor check GEN_CH2_STALE_CHECK : if C_SG_CH2_ENBL_STALE_ERROR = 1 generate begin ----------------------------------------------------------------------- -- Stale Descriptor Error ----------------------------------------------------------------------- CH2_STALE_DESC : process(m_axi_sg_aclk) begin if(m_axi_sg_aclk'EVENT and m_axi_sg_aclk = '1')then -- If reset then clear flag if(m_axi_sg_aresetn = '0')then ch2_stale_descriptor <= '0'; elsif(ftch_stale_desc = '1' and ch2_active_i = '1' )then ch2_stale_descriptor <= '1'; end if; end if; end process CH2_STALE_DESC; end generate GEN_CH2_STALE_CHECK; -- Disable stale descriptor check GEN_CH2_NO_STALE_CHECK : if C_SG_CH2_ENBL_STALE_ERROR = 0 generate begin ch2_stale_descriptor <= '0'; end generate GEN_CH2_NO_STALE_CHECK; -- Early detection of Stale Descriptor (valid only in tailpntr mode) used -- to prevent error'ed descriptor from being used. ch2_ftch_stale_desc <= ch2_stale_descriptor; end generate GEN_CH2_FETCH; ------------------------------------------------------------------------------- -- Channel excluded therefore do not generate fetch logic ------------------------------------------------------------------------------- GEN_NO_CH2_FETCH : if C_INCLUDE_CH2 = 0 generate begin service_ch2 <= '0'; ch2_active_i <= '0'; ch2_ftch_idle <= '0'; ch2_ftch_interr_set <= '0'; ch2_ftch_slverr_set <= '0'; ch2_ftch_decerr_set <= '0'; ch2_ftch_err_early <= '0'; ch2_ftch_stale_desc <= '0'; end generate GEN_NO_CH2_FETCH; ------------------------------------------------------------------------------- -- Build DataMover command ------------------------------------------------------------------------------- -- Assign fetch address fetch_cmd_addr <= ch1_fetch_address when ch1_active_i = '1' else ch2_fetch_address; -- Assign bytes to transfer (BTT) fetch_cmd_btt <= FETCH_CH1_CMD_BTT when ch1_active_i = '1' else FETCH_CH2_CMD_BTT; fetch_tag <= "0001" when ch1_active_i = '1' else "0000"; -- When command by sm, drive command to ftch_cmdsts_if --GEN_DATAMOVER_CMND : process(m_axi_sg_aclk) -- begin -- if(m_axi_sg_aclk'EVENT and m_axi_sg_aclk = '1')then -- if(m_axi_sg_aresetn = '0')then -- ftch_cmnd_wr <= '0'; -- ftch_cmnd_data <= (others => '0'); -- -- Fetch SM issued a command write -- elsif(write_cmnd_cmb = '1')then -- ftch_cmnd_wr <= '1'; -- ftch_cmnd_data <= FETCH_CMD_RSVD -- & fetch_tag -- & fetch_cmd_addr -- & FETCH_MSB_IGNORED -- & FETCH_CMD_TYPE -- & FETCH_LSB_IGNORED -- & fetch_cmd_btt; -- else -- ftch_cmnd_wr <= '0'; -- end if; -- end if; -- end process GEN_DATAMOVER_CMND; ftch_cmnd_wr <= write_cmnd_cmb; ftch_cmnd_data <= FETCH_CMD_RSVD & fetch_tag & fetch_cmd_addr & FETCH_MSB_IGNORED & FETCH_CMD_TYPE & FETCH_LSB_IGNORED & fetch_cmd_btt; ------------------------------------------------------------------------------- -- Capture and hold fetch address in case an error occurs ------------------------------------------------------------------------------- LOG_ERROR_ADDR : process(m_axi_sg_aclk) begin if(m_axi_sg_aclk'EVENT and m_axi_sg_aclk = '1')then if(m_axi_sg_aresetn = '0')then ftch_error_addr (C_M_AXI_SG_ADDR_WIDTH-1 downto SG_ADDR_LSB) <= (others => '0'); elsif(write_cmnd_cmb = '1')then ftch_error_addr (C_M_AXI_SG_ADDR_WIDTH-1 downto SG_ADDR_LSB) <= fetch_cmd_addr (C_M_AXI_SG_ADDR_WIDTH-1 downto SG_ADDR_LSB); end if; end if; end process LOG_ERROR_ADDR; ftch_error_addr (5 downto 0) <= "000000"; end implementation;

gpl-3.0

b55ba81ac6a6813173f6ca17fd630a17

0.425652

4.418259

false

marco-c/leon-nexys2

grlib-gpl-1.3.4-b4140/designs/leon3-gr-xc6s/config.vhd

1

9,158

----------------------------------------------------------------------------- -- LEON3 Demonstration design test bench configuration -- Copyright (C) 2009 Aeroflex Gaisler ------------------------------------------------------------------------------ library techmap; use techmap.gencomp.all; package config is -- Technology and synthesis options constant CFG_FABTECH : integer := spartan6; constant CFG_MEMTECH : integer := spartan6; constant CFG_PADTECH : integer := spartan6; constant CFG_NOASYNC : integer := 0; constant CFG_SCAN : integer := 0; -- Clock generator constant CFG_CLKTECH : integer := spartan6; constant CFG_CLKMUL : integer := (2); constant CFG_CLKDIV : integer := (2); constant CFG_OCLKDIV : integer := 1; constant CFG_OCLKBDIV : integer := 0; constant CFG_OCLKCDIV : integer := 0; constant CFG_PCIDLL : integer := 0; constant CFG_PCISYSCLK: integer := 0; constant CFG_CLK_NOFB : integer := 0; -- LEON3 processor core constant CFG_LEON3 : integer := 1; constant CFG_NCPU : integer := (1); constant CFG_NWIN : integer := (8); constant CFG_V8 : integer := 16#32# + 4*0; constant CFG_MAC : integer := 0; constant CFG_BP : integer := 1; constant CFG_SVT : integer := 1; constant CFG_RSTADDR : integer := 16#00000#; constant CFG_LDDEL : integer := (1); constant CFG_NOTAG : integer := 1; constant CFG_NWP : integer := (2); constant CFG_PWD : integer := 1*2; constant CFG_FPU : integer := 0 + 16*0 + 32*0; constant CFG_GRFPUSH : integer := 0; constant CFG_ICEN : integer := 1; constant CFG_ISETS : integer := 2; constant CFG_ISETSZ : integer := 8; constant CFG_ILINE : integer := 8; constant CFG_IREPL : integer := 2; constant CFG_ILOCK : integer := 0; constant CFG_ILRAMEN : integer := 0; constant CFG_ILRAMADDR: integer := 16#8E#; constant CFG_ILRAMSZ : integer := 1; constant CFG_DCEN : integer := 1; constant CFG_DSETS : integer := 2; constant CFG_DSETSZ : integer := 4; constant CFG_DLINE : integer := 4; constant CFG_DREPL : integer := 2; constant CFG_DLOCK : integer := 0; constant CFG_DSNOOP : integer := 1 + 1 + 4*1; constant CFG_DFIXED : integer := 16#0#; constant CFG_DLRAMEN : integer := 0; constant CFG_DLRAMADDR: integer := 16#8F#; constant CFG_DLRAMSZ : integer := 1; constant CFG_MMUEN : integer := 1; constant CFG_ITLBNUM : integer := 8; constant CFG_DTLBNUM : integer := 8; constant CFG_TLB_TYPE : integer := 0 + 1*2; constant CFG_TLB_REP : integer := 0; constant CFG_MMU_PAGE : integer := 0; constant CFG_DSU : integer := 1; constant CFG_ITBSZ : integer := 4; constant CFG_ATBSZ : integer := 4; constant CFG_LEON3FT_EN : integer := 0; constant CFG_IUFT_EN : integer := 0; constant CFG_FPUFT_EN : integer := 0; constant CFG_RF_ERRINJ : integer := 0; constant CFG_CACHE_FT_EN : integer := 0; constant CFG_CACHE_ERRINJ : integer := 0; constant CFG_LEON3_NETLIST: integer := 0; constant CFG_DISAS : integer := 0 + 0; constant CFG_PCLOW : integer := 2; -- AMBA settings constant CFG_DEFMST : integer := (0); constant CFG_RROBIN : integer := 1; constant CFG_SPLIT : integer := 0; constant CFG_FPNPEN : integer := 0; constant CFG_AHBIO : integer := 16#FFF#; constant CFG_APBADDR : integer := 16#800#; constant CFG_AHB_MON : integer := 0; constant CFG_AHB_MONERR : integer := 0; constant CFG_AHB_MONWAR : integer := 0; constant CFG_AHB_DTRACE : integer := 0; -- DSU UART constant CFG_AHB_UART : integer := 1; -- JTAG based DSU interface constant CFG_AHB_JTAG : integer := 1; -- Ethernet DSU constant CFG_DSU_ETH : integer := 1 + 0 + 0; constant CFG_ETH_BUF : integer := 16; constant CFG_ETH_IPM : integer := 16#C0A8#; constant CFG_ETH_IPL : integer := 16#0033#; constant CFG_ETH_ENM : integer := 16#020000#; constant CFG_ETH_ENL : integer := 16#000000#; -- LEON2 memory controller constant CFG_MCTRL_LEON2 : integer := 1; constant CFG_MCTRL_RAM8BIT : integer := 1; constant CFG_MCTRL_RAM16BIT : integer := 0; constant CFG_MCTRL_5CS : integer := 0; constant CFG_MCTRL_SDEN : integer := 0; constant CFG_MCTRL_SEPBUS : integer := 0; constant CFG_MCTRL_INVCLK : integer := 0; constant CFG_MCTRL_SD64 : integer := 0; constant CFG_MCTRL_PAGE : integer := 0 + 0; -- DDR controller constant CFG_DDR2SP : integer := 0; constant CFG_DDR2SP_INIT : integer := 0; constant CFG_DDR2SP_FREQ : integer := 100; constant CFG_DDR2SP_TRFC : integer := 130; constant CFG_DDR2SP_DATAWIDTH : integer := 64; constant CFG_DDR2SP_FTEN : integer := 0; constant CFG_DDR2SP_FTWIDTH : integer := 0; constant CFG_DDR2SP_COL : integer := 9; constant CFG_DDR2SP_SIZE : integer := 8; constant CFG_DDR2SP_DELAY0 : integer := 0; constant CFG_DDR2SP_DELAY1 : integer := 0; constant CFG_DDR2SP_DELAY2 : integer := 0; constant CFG_DDR2SP_DELAY3 : integer := 0; constant CFG_DDR2SP_DELAY4 : integer := 0; constant CFG_DDR2SP_DELAY5 : integer := 0; constant CFG_DDR2SP_DELAY6 : integer := 0; constant CFG_DDR2SP_DELAY7 : integer := 0; constant CFG_DDR2SP_NOSYNC : integer := 0; -- Xilinx MIG constant CFG_MIG_DDR2 : integer := 1; constant CFG_MIG_RANKS : integer := (1); constant CFG_MIG_COLBITS : integer := (10); constant CFG_MIG_ROWBITS : integer := (13); constant CFG_MIG_BANKBITS: integer := (2); constant CFG_MIG_HMASK : integer := 16#F00#; -- AHB status register constant CFG_AHBSTAT : integer := 1; constant CFG_AHBSTATN : integer := (1); -- AHB ROM constant CFG_AHBROMEN : integer := 0; constant CFG_AHBROPIP : integer := 0; constant CFG_AHBRODDR : integer := 16#000#; constant CFG_ROMADDR : integer := 16#000#; constant CFG_ROMMASK : integer := 16#E00# + 16#000#; -- AHB RAM constant CFG_AHBRAMEN : integer := 0; constant CFG_AHBRSZ : integer := 1; constant CFG_AHBRADDR : integer := 16#A00#; constant CFG_AHBRPIPE : integer := 0; -- Gaisler Ethernet core constant CFG_GRETH : integer := 1; constant CFG_GRETH1G : integer := 1; constant CFG_ETH_FIFO : integer := 8; constant CFG_GRETH_FT : integer := 0; constant CFG_GRETH_EDCLFT : integer := 0; -- CAN 2.0 interface constant CFG_CAN : integer := 0; constant CFG_CAN_NUM : integer := 1; constant CFG_CANIO : integer := 16#0#; constant CFG_CANIRQ : integer := 0; constant CFG_CANSEPIRQ: integer := 0; constant CFG_CAN_SYNCRST : integer := 0; constant CFG_CANFT : integer := 0; -- UART 1 constant CFG_UART1_ENABLE : integer := 1; constant CFG_UART1_FIFO : integer := 4; -- UART 2 constant CFG_UART2_ENABLE : integer := 0; constant CFG_UART2_FIFO : integer := 1; -- LEON3 interrupt controller constant CFG_IRQ3_ENABLE : integer := 1; constant CFG_IRQ3_NSEC : integer := 0; -- Modular timer constant CFG_GPT_ENABLE : integer := 1; constant CFG_GPT_NTIM : integer := (2); constant CFG_GPT_SW : integer := (8); constant CFG_GPT_TW : integer := (32); constant CFG_GPT_IRQ : integer := (8); constant CFG_GPT_SEPIRQ : integer := 1; constant CFG_GPT_WDOGEN : integer := 0; constant CFG_GPT_WDOG : integer := 16#0#; -- GPIO port constant CFG_GRGPIO_ENABLE : integer := 1; constant CFG_GRGPIO_IMASK : integer := 16#0000#; constant CFG_GRGPIO_WIDTH : integer := (8); -- Spacewire interface constant CFG_SPW_EN : integer := 0; constant CFG_SPW_NUM : integer := 1; constant CFG_SPW_AHBFIFO : integer := 4; constant CFG_SPW_RXFIFO : integer := 16; constant CFG_SPW_RMAP : integer := 0; constant CFG_SPW_RMAPBUF : integer := 4; constant CFG_SPW_RMAPCRC : integer := 0; constant CFG_SPW_NETLIST : integer := 0; constant CFG_SPW_FT : integer := 0; constant CFG_SPW_GRSPW : integer := 2; constant CFG_SPW_RXUNAL : integer := 0; constant CFG_SPW_DMACHAN : integer := 1; constant CFG_SPW_PORTS : integer := 1; constant CFG_SPW_INPUT : integer := 2; constant CFG_SPW_OUTPUT : integer := 0; constant CFG_SPW_RTSAME : integer := 0; -- VGA and PS2/ interface constant CFG_KBD_ENABLE : integer := 1; constant CFG_VGA_ENABLE : integer := 0; constant CFG_SVGA_ENABLE : integer := 1; -- SPI memory controller constant CFG_SPIMCTRL : integer := 1; constant CFG_SPIMCTRL_SDCARD : integer := 0; constant CFG_SPIMCTRL_READCMD : integer := 16#0B#; constant CFG_SPIMCTRL_DUMMYBYTE : integer := 0; constant CFG_SPIMCTRL_DUALOUTPUT : integer := 0; constant CFG_SPIMCTRL_SCALER : integer := (1); constant CFG_SPIMCTRL_ASCALER : integer := (8); constant CFG_SPIMCTRL_PWRUPCNT : integer := (0); constant CFG_SPIMCTRL_OFFSET : integer := 16#0#; -- SPI controller constant CFG_SPICTRL_ENABLE : integer := 1; constant CFG_SPICTRL_NUM : integer := (1); constant CFG_SPICTRL_SLVS : integer := (1); constant CFG_SPICTRL_FIFO : integer := (1); constant CFG_SPICTRL_SLVREG : integer := 1; constant CFG_SPICTRL_ODMODE : integer := 0; constant CFG_SPICTRL_AM : integer := 0; constant CFG_SPICTRL_ASEL : integer := 0; constant CFG_SPICTRL_TWEN : integer := 0; constant CFG_SPICTRL_MAXWLEN : integer := (0); constant CFG_SPICTRL_SYNCRAM : integer := 0; constant CFG_SPICTRL_FT : integer := 0; -- GRLIB debugging constant CFG_DUART : integer := 0; end;

gpl-2.0

8bc0f6dcefa0c908858f33a164a816c7

0.65451

3.560653

false

Fairyland0902/BlockyRoads

src/BlockyRoads/ipcore_dir/road/example_design/road_prod.vhd

1

9,891

-------------------------------------------------------------------------------- -- -- BLK MEM GEN v7.1 Core - Top-level wrapper -- -------------------------------------------------------------------------------- -- -- (c) Copyright 2006-2011 Xilinx, Inc. All rights reserved. -- -- This file contains confidential and proprietary information -- of Xilinx, Inc. and is protected under U.S. and -- international copyright and other intellectual property -- laws. -- -- DISCLAIMER -- This disclaimer is not a license and does not grant any -- rights to the materials distributed herewith. Except as -- otherwise provided in a valid license issued to you by -- Xilinx, and to the maximum extent permitted by applicable -- law: (1) THESE MATERIALS ARE MADE AVAILABLE "AS IS" AND -- WITH ALL FAULTS, AND XILINX HEREBY DISCLAIMS ALL WARRANTIES -- AND CONDITIONS, EXPRESS, IMPLIED, OR STATUTORY, INCLUDING -- BUT NOT LIMITED TO WARRANTIES OF MERCHANTABILITY, NON- -- INFRINGEMENT, OR FITNESS FOR ANY PARTICULAR PURPOSE; and -- (2) Xilinx shall not be liable (whether in contract or tort, -- including negligence, or under any other theory of -- liability) for any loss or damage of any kind or nature -- related to, arising under or in connection with these -- materials, including for any direct, or any indirect, -- special, incidental, or consequential loss or damage -- (including loss of data, profits, goodwill, or any type of -- loss or damage suffered as a result of any action brought -- by a third party) even if such damage or loss was -- reasonably foreseeable or Xilinx had been advised of the -- possibility of the same. -- -- CRITICAL APPLICATIONS -- Xilinx products are not designed or intended to be fail- -- safe, or for use in any application requiring fail-safe -- performance, such as life-support or safety devices or -- systems, Class III medical devices, nuclear facilities, -- applications related to the deployment of airbags, or any -- other applications that could lead to death, personal -- injury, or severe property or environmental damage -- (individually and collectively, "Critical -- Applications"). Customer assumes the sole risk and -- liability of any use of Xilinx products in Critical -- Applications, subject only to applicable laws and -- regulations governing limitations on product liability. -- -- THIS COPYRIGHT NOTICE AND DISCLAIMER MUST BE RETAINED AS -- PART OF THIS FILE AT ALL TIMES. -- -------------------------------------------------------------------------------- -- -- Filename: road_prod.vhd -- -- Description: -- This is the top-level BMG wrapper (over BMG core). -- -------------------------------------------------------------------------------- -- Author: IP Solutions Division -- -- History: August 31, 2005 - First Release -------------------------------------------------------------------------------- -- -- Configured Core Parameter Values: -- (Refer to the SIM Parameters table in the datasheet for more information on -- the these parameters.) -- C_FAMILY : artix7 -- C_XDEVICEFAMILY : artix7 -- C_INTERFACE_TYPE : 0 -- C_ENABLE_32BIT_ADDRESS : 0 -- C_AXI_TYPE : 1 -- C_AXI_SLAVE_TYPE : 0 -- C_AXI_ID_WIDTH : 4 -- C_MEM_TYPE : 3 -- C_BYTE_SIZE : 9 -- C_ALGORITHM : 1 -- C_PRIM_TYPE : 1 -- C_LOAD_INIT_FILE : 1 -- C_INIT_FILE_NAME : road.mif -- C_USE_DEFAULT_DATA : 0 -- C_DEFAULT_DATA : 0 -- C_RST_TYPE : SYNC -- C_HAS_RSTA : 0 -- C_RST_PRIORITY_A : CE -- C_RSTRAM_A : 0 -- C_INITA_VAL : 0 -- C_HAS_ENA : 0 -- C_HAS_REGCEA : 0 -- C_USE_BYTE_WEA : 0 -- C_WEA_WIDTH : 1 -- C_WRITE_MODE_A : WRITE_FIRST -- C_WRITE_WIDTH_A : 12 -- C_READ_WIDTH_A : 12 -- C_WRITE_DEPTH_A : 99200 -- C_READ_DEPTH_A : 99200 -- C_ADDRA_WIDTH : 17 -- C_HAS_RSTB : 0 -- C_RST_PRIORITY_B : CE -- C_RSTRAM_B : 0 -- C_INITB_VAL : 0 -- C_HAS_ENB : 0 -- C_HAS_REGCEB : 0 -- C_USE_BYTE_WEB : 0 -- C_WEB_WIDTH : 1 -- C_WRITE_MODE_B : WRITE_FIRST -- C_WRITE_WIDTH_B : 12 -- C_READ_WIDTH_B : 12 -- C_WRITE_DEPTH_B : 99200 -- C_READ_DEPTH_B : 99200 -- C_ADDRB_WIDTH : 17 -- C_HAS_MEM_OUTPUT_REGS_A : 0 -- C_HAS_MEM_OUTPUT_REGS_B : 0 -- C_HAS_MUX_OUTPUT_REGS_A : 0 -- C_HAS_MUX_OUTPUT_REGS_B : 0 -- C_HAS_SOFTECC_INPUT_REGS_A : 0 -- C_HAS_SOFTECC_OUTPUT_REGS_B : 0 -- C_MUX_PIPELINE_STAGES : 0 -- C_USE_ECC : 0 -- C_USE_SOFTECC : 0 -- C_HAS_INJECTERR : 0 -- C_SIM_COLLISION_CHECK : ALL -- C_COMMON_CLK : 0 -- C_DISABLE_WARN_BHV_COLL : 0 -- C_DISABLE_WARN_BHV_RANGE : 0 -------------------------------------------------------------------------------- -- Library Declarations -------------------------------------------------------------------------------- LIBRARY IEEE; USE IEEE.STD_LOGIC_1164.ALL; USE IEEE.STD_LOGIC_ARITH.ALL; USE IEEE.STD_LOGIC_UNSIGNED.ALL; LIBRARY UNISIM; USE UNISIM.VCOMPONENTS.ALL; -------------------------------------------------------------------------------- -- Entity Declaration -------------------------------------------------------------------------------- ENTITY road_prod IS PORT ( --Port A CLKA : IN STD_LOGIC; RSTA : IN STD_LOGIC; --opt port ENA : IN STD_LOGIC; --optional port REGCEA : IN STD_LOGIC; --optional port WEA : IN STD_LOGIC_VECTOR(0 DOWNTO 0); ADDRA : IN STD_LOGIC_VECTOR(16 DOWNTO 0); DINA : IN STD_LOGIC_VECTOR(11 DOWNTO 0); DOUTA : OUT STD_LOGIC_VECTOR(11 DOWNTO 0); --Port B CLKB : IN STD_LOGIC; RSTB : IN STD_LOGIC; --opt port ENB : IN STD_LOGIC; --optional port REGCEB : IN STD_LOGIC; --optional port WEB : IN STD_LOGIC_VECTOR(0 DOWNTO 0); ADDRB : IN STD_LOGIC_VECTOR(16 DOWNTO 0); DINB : IN STD_LOGIC_VECTOR(11 DOWNTO 0); DOUTB : OUT STD_LOGIC_VECTOR(11 DOWNTO 0); --ECC INJECTSBITERR : IN STD_LOGIC; --optional port INJECTDBITERR : IN STD_LOGIC; --optional port SBITERR : OUT STD_LOGIC; --optional port DBITERR : OUT STD_LOGIC; --optional port RDADDRECC : OUT STD_LOGIC_VECTOR(16 DOWNTO 0); --optional port -- AXI BMG Input and Output Port Declarations -- AXI Global Signals S_ACLK : IN STD_LOGIC; S_AXI_AWID : IN STD_LOGIC_VECTOR(3 DOWNTO 0); S_AXI_AWADDR : IN STD_LOGIC_VECTOR(31 DOWNTO 0); S_AXI_AWLEN : IN STD_LOGIC_VECTOR(7 DOWNTO 0); S_AXI_AWSIZE : IN STD_LOGIC_VECTOR(2 DOWNTO 0); S_AXI_AWBURST : IN STD_LOGIC_VECTOR(1 DOWNTO 0); S_AXI_AWVALID : IN STD_LOGIC; S_AXI_AWREADY : OUT STD_LOGIC; S_AXI_WDATA : IN STD_LOGIC_VECTOR(11 DOWNTO 0); S_AXI_WSTRB : IN STD_LOGIC_VECTOR(0 DOWNTO 0); S_AXI_WLAST : IN STD_LOGIC; S_AXI_WVALID : IN STD_LOGIC; S_AXI_WREADY : OUT STD_LOGIC; S_AXI_BID : OUT STD_LOGIC_VECTOR(3 DOWNTO 0):= (OTHERS => '0'); S_AXI_BRESP : OUT STD_LOGIC_VECTOR(1 DOWNTO 0); S_AXI_BVALID : OUT STD_LOGIC; S_AXI_BREADY : IN STD_LOGIC; -- AXI Full/Lite Slave Read (Write side) S_AXI_ARID : IN STD_LOGIC_VECTOR(3 DOWNTO 0); S_AXI_ARADDR : IN STD_LOGIC_VECTOR(31 DOWNTO 0); S_AXI_ARLEN : IN STD_LOGIC_VECTOR(7 DOWNTO 0); S_AXI_ARSIZE : IN STD_LOGIC_VECTOR(2 DOWNTO 0); S_AXI_ARBURST : IN STD_LOGIC_VECTOR(1 DOWNTO 0); S_AXI_ARVALID : IN STD_LOGIC; S_AXI_ARREADY : OUT STD_LOGIC; S_AXI_RID : OUT STD_LOGIC_VECTOR(3 DOWNTO 0):= (OTHERS => '0'); S_AXI_RDATA : OUT STD_LOGIC_VECTOR(11 DOWNTO 0); S_AXI_RRESP : OUT STD_LOGIC_VECTOR(1 DOWNTO 0); S_AXI_RLAST : OUT STD_LOGIC; S_AXI_RVALID : OUT STD_LOGIC; S_AXI_RREADY : IN STD_LOGIC; -- AXI Full/Lite Sideband Signals S_AXI_INJECTSBITERR : IN STD_LOGIC; S_AXI_INJECTDBITERR : IN STD_LOGIC; S_AXI_SBITERR : OUT STD_LOGIC; S_AXI_DBITERR : OUT STD_LOGIC; S_AXI_RDADDRECC : OUT STD_LOGIC_VECTOR(16 DOWNTO 0); S_ARESETN : IN STD_LOGIC ); END road_prod; ARCHITECTURE xilinx OF road_prod IS COMPONENT road_exdes IS PORT ( --Port A ADDRA : IN STD_LOGIC_VECTOR(16 DOWNTO 0); DOUTA : OUT STD_LOGIC_VECTOR(11 DOWNTO 0); CLKA : IN STD_LOGIC ); END COMPONENT; BEGIN bmg0 : road_exdes PORT MAP ( --Port A ADDRA => ADDRA, DOUTA => DOUTA, CLKA => CLKA ); END xilinx;

mit

13a290a1984d223526d26f30b16742b5

0.493984

3.818919

false

marco-c/leon-nexys2

grlib-gpl-1.3.4-b4140/lib/grlib/amba/amba.vhd

1

44,534

------------------------------------------------------------------------------ -- This file is a part of the GRLIB VHDL IP LIBRARY -- Copyright (C) 2003 - 2008, Gaisler Research -- Copyright (C) 2008 - 2013, Aeroflex Gaisler -- -- This program is free software; you can redistribute it and/or modify -- it under the terms of the GNU General Public License as published by -- the Free Software Foundation; either version 2 of the License, or -- (at your option) any later version. -- -- This program is distributed in the hope that it will be useful, -- but WITHOUT ANY WARRANTY; without even the implied warranty of -- MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the -- GNU General Public License for more details. -- -- You should have received a copy of the GNU General Public License -- along with this program; if not, write to the Free Software -- Foundation, Inc., 59 Temple Place, Suite 330, Boston, MA 02111-1307 USA ----------------------------------------------------------------------------- -- Package: amba -- File: amba.vhd -- Author: Jiri Gaisler, Gaisler Research -- Modified by: Jan Andersson, Aeroflex Gaisler -- Description: AMBA 2.0 bus signal definitions + support for plug&play ------------------------------------------------------------------------------ library ieee; use ieee.std_logic_1164.all; use ieee.numeric_std.all; -- pragma translate_off use std.textio.all; -- pragma translate_on library grlib; use grlib.config_types.all; use grlib.config.all; use grlib.stdlib.all; package amba is ------------------------------------------------------------------------------- -- AMBA configuration ------------------------------------------------------------------------------- -- AHBDW - AHB data with -- -- Valid values are 32, 64, 128 and 256 -- -- The value here sets the width of the AMBA AHB data vectors for all -- cores in the library. -- constant AHBDW : integer := CFG_AHBDW; -- CORE_ACDM - Enable AMBA Compliant Data Muxing in cores -- -- Valid values are 0 and 1 -- -- 0: All GRLIB cores that use the ahbread* programs defined in this package -- will read their data from the low part of the AHB data vector. -- -- 1: All GRLIB cores that use the ahbread* programs defined in this package -- will select valid data, as defined in the AMBA AHB standard, from the -- AHB data vectors based on the address input. If a core uses a function -- that does not have the address input, a failure will be asserted. -- constant CORE_ACDM : integer := CFG_AHB_ACDM; constant NAHBMST : integer := 16; -- maximum AHB masters constant NAHBSLV : integer := 16; -- maximum AHB slaves constant NAPBSLV : integer := 16; -- maximum APB slaves constant NAHBIRQ : integer := 32; -- maximum interrupts constant NAHBAMR : integer := 4; -- maximum address mapping registers constant NAHBIR : integer := 4; -- maximum AHB identification registers constant NAHBCFG : integer := NAHBIR + NAHBAMR; -- words in AHB config block constant NAPBIR : integer := 1; -- maximum APB configuration words constant NAPBAMR : integer := 1; -- maximum APB configuration words constant NAPBCFG : integer := NAPBIR + NAPBAMR; -- words in APB config block constant NBUS : integer := 4; -- Number of test vector bits constant NTESTINBITS : integer := 4+GRLIB_CONFIG_ARRAY(grlib_techmap_testin_extra); ------------------------------------------------------------------------------- -- AMBA interface type declarations and constant ------------------------------------------------------------------------------- subtype amba_config_word is std_logic_vector(31 downto 0); type ahb_config_type is array (0 to NAHBCFG-1) of amba_config_word; type apb_config_type is array (0 to NAPBCFG-1) of amba_config_word; -- AHB master inputs type ahb_mst_in_type is record hgrant : std_logic_vector(0 to NAHBMST-1); -- bus grant hready : std_ulogic; -- transfer done hresp : std_logic_vector(1 downto 0); -- response type hrdata : std_logic_vector(AHBDW-1 downto 0); -- read data bus hirq : std_logic_vector(NAHBIRQ-1 downto 0); -- interrupt result bus testen : std_ulogic; -- scan test enable testrst : std_ulogic; -- scan test reset scanen : std_ulogic; -- scan enable testoen : std_ulogic; -- test output enable testin : std_logic_vector(NTESTINBITS-1 downto 0); -- test vector for syncrams end record; -- AHB master outputs type ahb_mst_out_type is record hbusreq : std_ulogic; -- bus request hlock : std_ulogic; -- lock request htrans : std_logic_vector(1 downto 0); -- transfer type haddr : std_logic_vector(31 downto 0); -- address bus (byte) hwrite : std_ulogic; -- read/write hsize : std_logic_vector(2 downto 0); -- transfer size hburst : std_logic_vector(2 downto 0); -- burst type hprot : std_logic_vector(3 downto 0); -- protection control hwdata : std_logic_vector(AHBDW-1 downto 0); -- write data bus hirq : std_logic_vector(NAHBIRQ-1 downto 0); -- interrupt bus hconfig : ahb_config_type; -- memory access reg. hindex : integer range 0 to NAHBMST-1; -- diagnostic use only end record; -- AHB slave inputs type ahb_slv_in_type is record hsel : std_logic_vector(0 to NAHBSLV-1); -- slave select haddr : std_logic_vector(31 downto 0); -- address bus (byte) hwrite : std_ulogic; -- read/write htrans : std_logic_vector(1 downto 0); -- transfer type hsize : std_logic_vector(2 downto 0); -- transfer size hburst : std_logic_vector(2 downto 0); -- burst type hwdata : std_logic_vector(AHBDW-1 downto 0); -- write data bus hprot : std_logic_vector(3 downto 0); -- protection control hready : std_ulogic; -- transfer done hmaster : std_logic_vector(3 downto 0); -- current master hmastlock : std_ulogic; -- locked access hmbsel : std_logic_vector(0 to NAHBAMR-1); -- memory bank select hirq : std_logic_vector(NAHBIRQ-1 downto 0); -- interrupt result bus testen : std_ulogic; -- scan test enable testrst : std_ulogic; -- scan test reset scanen : std_ulogic; -- scan enable testoen : std_ulogic; -- test output enable testin : std_logic_vector(NTESTINBITS-1 downto 0); -- test vector for syncrams end record; -- AHB slave outputs type ahb_slv_out_type is record hready : std_ulogic; -- transfer done hresp : std_logic_vector(1 downto 0); -- response type hrdata : std_logic_vector(AHBDW-1 downto 0); -- read data bus hsplit : std_logic_vector(NAHBMST-1 downto 0); -- split completion hirq : std_logic_vector(NAHBIRQ-1 downto 0); -- interrupt bus hconfig : ahb_config_type; -- memory access reg. hindex : integer range 0 to NAHBSLV-1; -- diagnostic use only end record; -- array types type ahb_mst_out_vector_type is array (natural range <>) of ahb_mst_out_type; type ahb_mst_in_vector_type is array (natural range <>) of ahb_mst_in_type; type ahb_slv_out_vector_type is array (natural range <>) of ahb_slv_out_type; type ahb_slv_in_vector_type is array (natural range <>) of ahb_slv_in_type; subtype ahb_mst_out_vector is ahb_mst_out_vector_type(NAHBMST-1 downto 0); subtype ahb_slv_out_vector is ahb_slv_out_vector_type(NAHBSLV-1 downto 0); type ahb_mst_out_bus_vector is array (0 to NBUS-1) of ahb_mst_out_vector; type ahb_slv_out_bus_vector is array (0 to NBUS-1) of ahb_slv_out_vector; -- constants constant HTRANS_IDLE: std_logic_vector(1 downto 0) := "00"; constant HTRANS_BUSY: std_logic_vector(1 downto 0) := "01"; constant HTRANS_NONSEQ: std_logic_vector(1 downto 0) := "10"; constant HTRANS_SEQ: std_logic_vector(1 downto 0) := "11"; constant HBURST_SINGLE: std_logic_vector(2 downto 0) := "000"; constant HBURST_INCR: std_logic_vector(2 downto 0) := "001"; constant HBURST_WRAP4: std_logic_vector(2 downto 0) := "010"; constant HBURST_INCR4: std_logic_vector(2 downto 0) := "011"; constant HBURST_WRAP8: std_logic_vector(2 downto 0) := "100"; constant HBURST_INCR8: std_logic_vector(2 downto 0) := "101"; constant HBURST_WRAP16: std_logic_vector(2 downto 0) := "110"; constant HBURST_INCR16: std_logic_vector(2 downto 0) := "111"; constant HSIZE_BYTE: std_logic_vector(2 downto 0) := "000"; constant HSIZE_HWORD: std_logic_vector(2 downto 0) := "001"; constant HSIZE_WORD: std_logic_vector(2 downto 0) := "010"; constant HSIZE_DWORD: std_logic_vector(2 downto 0) := "011"; constant HSIZE_4WORD: std_logic_vector(2 downto 0) := "100"; constant HSIZE_8WORD: std_logic_vector(2 downto 0) := "101"; constant HSIZE_16WORD: std_logic_vector(2 downto 0) := "110"; constant HSIZE_32WORD: std_logic_vector(2 downto 0) := "111"; constant HRESP_OKAY: std_logic_vector(1 downto 0) := "00"; constant HRESP_ERROR: std_logic_vector(1 downto 0) := "01"; constant HRESP_RETRY: std_logic_vector(1 downto 0) := "10"; constant HRESP_SPLIT: std_logic_vector(1 downto 0) := "11"; -- APB slave inputs type apb_slv_in_type is record psel : std_logic_vector(0 to NAPBSLV-1); -- slave select penable : std_ulogic; -- strobe paddr : std_logic_vector(31 downto 0); -- address bus (byte) pwrite : std_ulogic; -- write pwdata : std_logic_vector(31 downto 0); -- write data bus pirq : std_logic_vector(NAHBIRQ-1 downto 0); -- interrupt result bus testen : std_ulogic; -- scan test enable testrst : std_ulogic; -- scan test reset scanen : std_ulogic; -- scan enable testoen : std_ulogic; -- test output enable testin : std_logic_vector(NTESTINBITS-1 downto 0); -- test vector for syncrams end record; -- APB slave outputs type apb_slv_out_type is record prdata : std_logic_vector(31 downto 0); -- read data bus pirq : std_logic_vector(NAHBIRQ-1 downto 0); -- interrupt bus pconfig : apb_config_type; -- memory access reg. pindex : integer range 0 to NAPBSLV -1; -- diag use only end record; -- array types type apb_slv_out_vector is array (0 to NAPBSLV-1) of apb_slv_out_type; -- support for plug&play configuration constant AMBA_CONFIG_VER0 : std_logic_vector(1 downto 0) := "00"; subtype amba_vendor_type is integer range 0 to 16#ff#; subtype amba_device_type is integer range 0 to 16#3ff#; subtype amba_version_type is integer range 0 to 16#3f#; subtype amba_cfgver_type is integer range 0 to 3; subtype amba_irq_type is integer range 0 to NAHBIRQ-1; subtype ahb_addr_type is integer range 0 to 16#fff#; constant zx : std_logic_vector(31 downto 0) := (others => '0'); constant zahbdw : std_logic_vector(AHBDW-1 downto 0) := (others => '0'); constant zxirq : std_logic_vector(NAHBIRQ-1 downto 0) := (others => '0'); constant zy : std_logic_vector(0 to 31) := (others => '0'); constant ztestin : std_logic_vector(NTESTINBITS-1 downto 0) := (others => '0'); constant apb_none : apb_slv_out_type := (zx, zxirq(NAHBIRQ-1 downto 0), (others => zx), 0); constant ahbm_none : ahb_mst_out_type := ( '0', '0', "00", zx, '0', "000", "000", "0000", zahbdw, zxirq(NAHBIRQ-1 downto 0), (others => zx), 0); constant ahbm_in_none : ahb_mst_in_type := ((others => '0'), '0', (others => '0'), zahbdw, zxirq(NAHBIRQ-1 downto 0), '0', '0', '0', '0', ztestin); constant ahbs_none : ahb_slv_out_type := ( '1', "00", zahbdw, zx(NAHBMST-1 downto 0), zxirq(NAHBIRQ-1 downto 0), (others => zx), 0); constant ahbs_in_none : ahb_slv_in_type := ( zy(0 to NAHBSLV-1), zx, '0', "00", "000", "000", zahbdw, "0000", '1', "0000", '0', zy(0 to NAHBAMR-1), zxirq(NAHBIRQ-1 downto 0), '0', '0', '0', '0', ztestin); constant ahbsv_none : ahb_slv_out_vector := (others => ahbs_none); constant apb_slv_in_none : apb_slv_in_type := ((others => '0'), '0', (others => '0'), '0', (others => '0'), (others => '0'), '0', '0', '0', '0', ztestin); ------------------------------------------------------------------------------- -- Subprograms ------------------------------------------------------------------------------- function ahb_device_reg(vendor : amba_vendor_type; device : amba_device_type; cfgver : amba_cfgver_type; version : amba_version_type; interrupt : amba_irq_type) return std_logic_vector; function ahb_membar(memaddr : ahb_addr_type; prefetch, cache : std_ulogic; addrmask : ahb_addr_type) return std_logic_vector; function ahb_membar_opt(memaddr : ahb_addr_type; prefetch, cache : std_ulogic; addrmask : ahb_addr_type; enable : integer) return std_logic_vector; function ahb_iobar(memaddr : ahb_addr_type; addrmask : ahb_addr_type) return std_logic_vector; function apb_iobar(memaddr : ahb_addr_type; addrmask : ahb_addr_type) return std_logic_vector; function ahb_slv_dec_cache(haddr : std_logic_vector(31 downto 0); ahbso : ahb_slv_out_vector; cached : integer) return std_ulogic; function ahb_slv_dec_pfetch(haddr : std_logic_vector(31 downto 0); ahbso : ahb_slv_out_vector) return std_ulogic; function ahb_membar_size (addrmask : ahb_addr_type) return integer; function ahb_iobar_size (addrmask : ahb_addr_type) return integer; function ahbdrivedata (hdata : std_logic_vector) return std_logic_vector; function ahbselectdata (hdata : std_logic_vector(AHBDW-1 downto 0); haddr : std_logic_vector(4 downto 2); hsize : std_logic_vector(2 downto 0)) return std_logic_vector; function ahbreadword ( hdata : std_logic_vector(AHBDW-1 downto 0); haddr : std_logic_vector(4 downto 2)) return std_logic_vector; procedure ahbreadword ( hdata : in std_logic_vector(AHBDW-1 downto 0); haddr : in std_logic_vector(4 downto 2); data : out std_logic_vector(31 downto 0)); function ahbreadword ( hdata : std_logic_vector(AHBDW-1 downto 0)) return std_logic_vector; procedure ahbreadword ( hdata : in std_logic_vector(AHBDW-1 downto 0); data : out std_logic_vector(31 downto 0)); function ahbreaddword ( hdata : std_logic_vector(AHBDW-1 downto 0); haddr : std_logic_vector(4 downto 2)) return std_logic_vector; procedure ahbreaddword ( hdata : in std_logic_vector(AHBDW-1 downto 0); haddr : in std_logic_vector(4 downto 2); data : out std_logic_vector(63 downto 0)); function ahbreaddword ( hdata : std_logic_vector(AHBDW-1 downto 0)) return std_logic_vector; procedure ahbreaddword ( hdata : in std_logic_vector(AHBDW-1 downto 0); data : out std_logic_vector(63 downto 0)); function ahbread4word ( hdata : std_logic_vector(AHBDW-1 downto 0); haddr : std_logic_vector(4 downto 2)) return std_logic_vector; procedure ahbread4word ( hdata : in std_logic_vector(AHBDW-1 downto 0); haddr : in std_logic_vector(4 downto 2); data : out std_logic_vector(127 downto 0)); function ahbread4word ( hdata : std_logic_vector(AHBDW-1 downto 0)) return std_logic_vector; procedure ahbread4word ( hdata : in std_logic_vector(AHBDW-1 downto 0); data : out std_logic_vector(127 downto 0)); function ahbread8word ( hdata : std_logic_vector(AHBDW-1 downto 0); haddr : std_logic_vector(4 downto 2)) return std_logic_vector; procedure ahbread8word ( hdata : in std_logic_vector(AHBDW-1 downto 0); haddr : in std_logic_vector(4 downto 2); data : out std_logic_vector(255 downto 0)); function ahbread8word ( hdata : std_logic_vector(AHBDW-1 downto 0)) return std_logic_vector; procedure ahbread8word ( hdata : in std_logic_vector(AHBDW-1 downto 0); data : out std_logic_vector(255 downto 0)); function ahbreaddata ( hdata : std_logic_vector(AHBDW-1 downto 0); haddr : std_logic_vector(4 downto 2); hsize : std_logic_vector(2 downto 0)) return std_logic_vector; function ahbreaddata ( hdata : std_logic_vector(AHBDW-1 downto 0); hsize : std_logic_vector(2 downto 0)) return std_logic_vector; procedure ahbmomux ( signal ai : in ahb_mst_out_type; signal ao : out ahb_mst_out_type; signal en : in std_ulogic); procedure ahbsomux ( signal ai : in ahb_slv_out_type; signal ao : out ahb_slv_out_type; signal en : in std_ulogic); procedure apbsomux ( signal ai : in apb_slv_out_type; signal ao : out apb_slv_out_type; signal en : in std_ulogic); ------------------------------------------------------------------------------- -- Components ------------------------------------------------------------------------------- component ahbctrl generic ( defmast : integer := 0; -- default master split : integer := 0; -- split support rrobin : integer := 0; -- round-robin arbitration timeout : integer range 0 to 255 := 0; -- HREADY timeout ioaddr : ahb_addr_type := 16#fff#; -- I/O area MSB address iomask : ahb_addr_type := 16#fff#; -- I/O area address mask cfgaddr : ahb_addr_type := 16#ff0#; -- config area MSB address cfgmask : ahb_addr_type := 16#ff0#; -- config area address mask nahbm : integer range 1 to NAHBMST := NAHBMST; -- number of masters nahbs : integer range 1 to NAHBSLV := NAHBSLV; -- number of slaves ioen : integer range 0 to 15 := 1; -- enable I/O area disirq : integer range 0 to 1 := 0; -- disable interrupt routing fixbrst : integer range 0 to 1 := 0; -- support fix-length bursts debug : integer range 0 to 2 := 2; -- print config to console fpnpen : integer range 0 to 1 := 0; -- full PnP configuration decoding icheck : integer range 0 to 1 := 1; devid : integer := 0; -- unique device ID enbusmon : integer range 0 to 1 := 0; --enable bus monitor assertwarn : integer range 0 to 1 := 0; --enable assertions for warnings asserterr : integer range 0 to 1 := 0; --enable assertions for errors hmstdisable : integer := 0; --disable master checks hslvdisable : integer := 0; --disable slave checks arbdisable : integer := 0; --disable arbiter checks mprio : integer := 0; --master with highest priority mcheck : integer range 0 to 2 := 1; --check memory map for intersects ccheck : integer range 0 to 1 := 1; --perform sanity checks on pnp config acdm : integer := 0; --AMBA compliant data muxing (for hsize > word) index : integer := 0; --index for trace print-out ahbtrace : integer := 0; --AHB trace enable hwdebug : integer := 0; fourgslv : integer := 0 ); port ( rst : in std_ulogic; clk : in std_ulogic; msti : out ahb_mst_in_type; msto : in ahb_mst_out_vector; slvi : out ahb_slv_in_type; slvo : in ahb_slv_out_vector; testen : in std_ulogic := '0'; testrst : in std_ulogic := '1'; scanen : in std_ulogic := '0'; testoen : in std_ulogic := '1'; testsig : in std_logic_vector(1+GRLIB_CONFIG_ARRAY(grlib_techmap_testin_extra) downto 0) := (others => '0') ); end component; component apbctrl generic ( hindex : integer := 0; haddr : integer := 0; hmask : integer := 16#fff#; nslaves : integer range 1 to NAPBSLV := NAPBSLV; debug : integer range 0 to 2 := 2; -- print config to console icheck : integer range 0 to 1 := 1; enbusmon : integer range 0 to 1 := 0; asserterr : integer range 0 to 1 := 0; assertwarn : integer range 0 to 1 := 0; pslvdisable : integer := 0; mcheck : integer range 0 to 1 := 1; ccheck : integer range 0 to 1 := 1 ); port ( rst : in std_ulogic; clk : in std_ulogic; ahbi : in ahb_slv_in_type; ahbo : out ahb_slv_out_type; apbi : out apb_slv_in_type; apbo : in apb_slv_out_vector ); end component; component ahbctrl_mb generic ( defmast : integer := 0; -- default master split : integer := 0; -- split support rrobin : integer := 0; -- round-robin arbitration timeout : integer range 0 to 255 := 0; -- HREADY timeout ioaddr : ahb_addr_type := 16#fff#; -- I/O area MSB address iomask : ahb_addr_type := 16#fff#; -- I/O area address mask cfgaddr : ahb_addr_type := 16#ff0#; -- config area MSB address cfgmask : ahb_addr_type := 16#ff0#; -- config area address mask nahbm : integer range 1 to NAHBMST := NAHBMST; -- number of masters nahbs : integer range 1 to NAHBSLV := NAHBSLV; -- number of slaves ioen : integer range 0 to 15 := 1; -- enable I/O area disirq : integer range 0 to 1 := 0; -- disable interrupt routing fixbrst : integer range 0 to 1 := 0; -- support fix-length bursts debug : integer range 0 to 2 := 2; -- report cores to console fpnpen : integer range 0 to 1 := 0; -- full PnP configuration decoding busndx : integer range 0 to 3 := 0; icheck : integer range 0 to 1 := 1; devid : integer := 0; -- unique device ID enbusmon : integer range 0 to 1 := 0; --enable bus monitor assertwarn : integer range 0 to 1 := 0; --enable assertions for warnings asserterr : integer range 0 to 1 := 0; --enable assertions for errors hmstdisable : integer := 0; --disable master checks hslvdisable : integer := 0; --disable slave checks arbdisable : integer := 0; --disable arbiter checks mprio : integer := 0; --master with highest priority mcheck : integer range 0 to 2 := 1; --check memory map for intersect ccheck : integer range 0 to 1 := 1; --perform sanity checks on pnp config acdm : integer := 0 --AMBA compliant data muxing (for hsize > word) ); port ( rst : in std_ulogic; clk : in std_ulogic; msti : out ahb_mst_in_type; msto : in ahb_mst_out_bus_vector; slvi : out ahb_slv_in_type; slvo : in ahb_slv_out_bus_vector; testen : in std_ulogic := '0'; testrst : in std_ulogic := '1'; scanen : in std_ulogic := '0'; testoen : in std_ulogic := '1' ); end component; component ahbdefmst generic ( hindex : integer range 0 to NAHBMST-1 := 0); port ( ahbmo : out ahb_mst_out_type); end component; type ahb_dma_in_type is record address : std_logic_vector(31 downto 0); wdata : std_logic_vector(AHBDW-1 downto 0); start : std_ulogic; burst : std_ulogic; write : std_ulogic; busy : std_ulogic; irq : std_ulogic; size : std_logic_vector(2 downto 0); end record; type ahb_dma_out_type is record start : std_ulogic; active : std_ulogic; ready : std_ulogic; retry : std_ulogic; mexc : std_ulogic; haddr : std_logic_vector(9 downto 0); rdata : std_logic_vector(AHBDW-1 downto 0); end record; component ahbmst generic ( hindex : integer := 0; hirq : integer := 0; venid : integer := 1; devid : integer := 0; version : integer := 0; chprot : integer := 3; incaddr : integer := 0); port ( rst : in std_ulogic; clk : in std_ulogic; dmai : in ahb_dma_in_type; dmao : out ahb_dma_out_type; ahbi : in ahb_mst_in_type; ahbo : out ahb_mst_out_type ); end component; -- pragma translate_off component ahbmon is generic( asserterr : integer range 0 to 1 := 1; assertwarn : integer range 0 to 1 := 1; hmstdisable : integer := 0; hslvdisable : integer := 0; arbdisable : integer := 0; nahbm : integer range 0 to NAHBMST := NAHBMST; nahbs : integer range 0 to NAHBSLV := NAHBSLV; ebterm : integer range 0 to 1 := 0 ); port( rst : in std_ulogic; clk : in std_ulogic; ahbmi : in ahb_mst_in_type; ahbmo : in ahb_mst_out_vector; ahbsi : in ahb_slv_in_type; ahbso : in ahb_slv_out_vector; err : out std_ulogic); end component; component apbmon is generic( asserterr : integer range 0 to 1 := 1; assertwarn : integer range 0 to 1 := 1; pslvdisable : integer := 0; napb : integer range 0 to NAPBSLV := NAPBSLV ); port( rst : in std_ulogic; clk : in std_ulogic; apbi : in apb_slv_in_type; apbo : in apb_slv_out_vector; err : out std_ulogic); end component; component ambamon is generic( asserterr : integer range 0 to 1 := 1; assertwarn : integer range 0 to 1 := 1; hmstdisable : integer := 0; hslvdisable : integer := 0; pslvdisable : integer := 0; arbdisable : integer := 0; nahbm : integer range 0 to NAHBMST := NAHBMST; nahbs : integer range 0 to NAHBSLV := NAHBSLV; napb : integer range 0 to NAPBSLV := NAPBSLV; ebterm : integer range 0 to 1 := 0 ); port( rst : in std_ulogic; clk : in std_ulogic; ahbmi : in ahb_mst_in_type; ahbmo : in ahb_mst_out_vector; ahbsi : in ahb_slv_in_type; ahbso : in ahb_slv_out_vector; apbi : in apb_slv_in_type; apbo : in apb_slv_out_vector; err : out std_ulogic); end component; subtype vendor_description is string(1 to 24); subtype device_description is string(1 to 31); type device_table_type is array (0 to 1023) of device_description; type vendor_library_type is record vendorid : amba_vendor_type; vendordesc : vendor_description; device_table : device_table_type; end record; type device_array is array (0 to 255) of vendor_library_type; -- pragma translate_on end; package body amba is function ahb_device_reg(vendor : amba_vendor_type; device : amba_device_type; cfgver : amba_cfgver_type; version : amba_version_type; interrupt : amba_irq_type) return std_logic_vector is variable cfg : std_logic_vector(31 downto 0); begin case cfgver is when 0 => cfg(31 downto 24) := std_logic_vector(to_unsigned(vendor, 8)); cfg(23 downto 12) := std_logic_vector(to_unsigned(device, 12)); cfg(11 downto 10) := std_logic_vector(to_unsigned(cfgver, 2)); cfg( 9 downto 5) := std_logic_vector(to_unsigned(version, 5)); cfg( 4 downto 0) := std_logic_vector(to_unsigned(interrupt, 5)); when others => cfg := (others => '0'); end case; return(cfg); end; function ahb_membar(memaddr : ahb_addr_type; prefetch, cache : std_ulogic; addrmask : ahb_addr_type) return std_logic_vector is variable cfg : std_logic_vector(31 downto 0); begin cfg(31 downto 20) := std_logic_vector(to_unsigned(memaddr, 12)); cfg(19 downto 16) := "00" & prefetch & cache; cfg(15 downto 4) := std_logic_vector(to_unsigned(addrmask, 12)); cfg( 3 downto 0) := "0010"; return(cfg); end; function ahb_membar_opt(memaddr : ahb_addr_type; prefetch, cache : std_ulogic; addrmask : ahb_addr_type; enable : integer) return std_logic_vector is variable cfg : std_logic_vector(31 downto 0); begin cfg := (others => '0'); if enable /= 0 then return (ahb_membar(memaddr, prefetch, cache, addrmask)); else return(cfg); end if; end; function ahb_iobar(memaddr : ahb_addr_type; addrmask : ahb_addr_type) return std_logic_vector is variable cfg : std_logic_vector(31 downto 0); begin cfg(31 downto 20) := std_logic_vector(to_unsigned(memaddr, 12)); cfg(19 downto 16) := "0000"; cfg(15 downto 4) := std_logic_vector(to_unsigned(addrmask, 12)); cfg( 3 downto 0) := "0011"; return(cfg); end; function apb_iobar(memaddr : ahb_addr_type; addrmask : ahb_addr_type) return std_logic_vector is variable cfg : std_logic_vector(31 downto 0); begin cfg(31 downto 20) := std_logic_vector(to_unsigned(memaddr, 12)); cfg(19 downto 16) := "0000"; cfg(15 downto 4) := std_logic_vector(to_unsigned(addrmask, 12)); cfg( 3 downto 0) := "0001"; return(cfg); end; function ahb_slv_dec_cache(haddr : std_logic_vector(31 downto 0); ahbso : ahb_slv_out_vector; cached : integer) return std_ulogic is variable hcache : std_ulogic; variable ctbl : std_logic_vector(15 downto 0); begin hcache := '0'; ctbl := (others => '0'); if cached = 0 then for i in 0 to NAHBSLV-1 loop for j in NAHBAMR to NAHBCFG-1 loop if (ahbso(i).hconfig(j)(16) = '1') and (ahbso(i).hconfig(j)(15 downto 4) /= "000000000000") then if (haddr(31 downto 20) and ahbso(i).hconfig(j)(15 downto 4)) = (ahbso(i).hconfig(j)(31 downto 20) and ahbso(i).hconfig(j)(15 downto 4)) then hcache := '1'; end if; end if; end loop; end loop; else ctbl := conv_std_logic_vector(cached, 16); hcache := ctbl(conv_integer(haddr(31 downto 28))); end if; return(hcache); end; function ahb_slv_dec_pfetch(haddr : std_logic_vector(31 downto 0); ahbso : ahb_slv_out_vector) return std_ulogic is variable pfetch : std_ulogic; begin pfetch := '0'; for i in 0 to NAHBSLV-1 loop for j in NAHBAMR to NAHBCFG-1 loop if ((ahbso(i).hconfig(j)(17) = '1') and (ahbso(i).hconfig(j)(15 downto 4) /= "000000000000")) then if (haddr(31 downto 20) and ahbso(i).hconfig(j)(15 downto 4)) = (ahbso(i).hconfig(j)(31 downto 20) and ahbso(i).hconfig(j)(15 downto 4)) then pfetch := '1'; end if; end if; end loop; end loop; return(pfetch); end; function ahb_membar_size (addrmask : ahb_addr_type) return integer is begin if addrmask = 0 then return 0; end if; return (4096 - addrmask) * 1024 * 1024; end; function ahb_iobar_size (addrmask : ahb_addr_type) return integer is begin return (4096 - addrmask) * 256; end; -- purpose: Duplicates 'hdata' to suite AHB data width. If the input vector's -- length exceeds AHBDW the low part is returned. function ahbdrivedata ( hdata : std_logic_vector) return std_logic_vector is variable data : std_logic_vector(AHBDW-1 downto 0); begin -- ahbdrivedata if AHBDW < hdata'length then data := hdata(AHBDW+hdata'low-1 downto hdata'low); else for i in 0 to AHBDW/hdata'length-1 loop data(hdata'length-1+hdata'length*i downto hdata'length*i) := hdata; end loop; end if; return data; end ahbdrivedata; -- Takes in AHB data vector 'hdata' and returns valid data on the full -- data vector output based on 'haddr' and 'hsize' inputs together with -- GRLIB AHB bus width. The function works down to word granularity. function ahbselectdata ( hdata : std_logic_vector(AHBDW-1 downto 0); haddr : std_logic_vector(4 downto 2); hsize : std_logic_vector(2 downto 0)) return std_logic_vector is variable ret : std_logic_vector(AHBDW-1 downto 0); begin -- ahbselectdata ret := hdata; case hsize is when HSIZE_8WORD => if AHBDW = 256 then ret := hdata; end if; when HSIZE_4WORD => if AHBDW = 256 then if haddr(4) = '0' then ret := ahbdrivedata(hdata(AHBDW-1 downto AHBDW/2)); else ret := ahbdrivedata(hdata(AHBDW/2-1 downto 0)); end if; end if; when HSIZE_DWORD => if AHBDW = 256 then case haddr(4 downto 3) is when "00" => ret := ahbdrivedata(hdata(4*(AHBDW/4)-1 downto 3*(AHBDW/4))); when "01" => ret := ahbdrivedata(hdata(3*(AHBDW/4)-1 downto 2*(AHBDW/4))); when "10" => ret := ahbdrivedata(hdata(2*(AHBDW/4)-1 downto 1*(AHBDW/4))); when others => ret := ahbdrivedata(hdata(1*(AHBDW/4)-1 downto 0*(AHBDW/4))); end case; elsif AHBDW = 128 then if haddr(3) = '0' then ret := ahbdrivedata(hdata(AHBDW-1 downto AHBDW/2)); else ret := ahbdrivedata(hdata(AHBDW/2-1 downto 0)); end if; end if; when others => if AHBDW = 256 then case haddr(4 downto 2) is when "000" => ret := ahbdrivedata(hdata(8*(AHBDW/8)-1 downto 7*(AHBDW/8))); when "001" => ret := ahbdrivedata(hdata(7*(AHBDW/8)-1 downto 6*(AHBDW/8))); when "010" => ret := ahbdrivedata(hdata(6*(AHBDW/8)-1 downto 5*(AHBDW/8))); when "011" => ret := ahbdrivedata(hdata(5*(AHBDW/8)-1 downto 4*(AHBDW/8))); when "100" => ret := ahbdrivedata(hdata(4*(AHBDW/8)-1 downto 3*(AHBDW/8))); when "101" => ret := ahbdrivedata(hdata(3*(AHBDW/8)-1 downto 2*(AHBDW/8))); when "110" => ret := ahbdrivedata(hdata(2*(AHBDW/8)-1 downto 1*(AHBDW/8))); when others => ret := ahbdrivedata(hdata(1*(AHBDW/8)-1 downto 0*(AHBDW/8))); end case; elsif AHBDW = 128 then case haddr(3 downto 2) is when "00" => ret := ahbdrivedata(hdata(4*(AHBDW/4)-1 downto 3*(AHBDW/4))); when "01" => ret := ahbdrivedata(hdata(3*(AHBDW/4)-1 downto 2*(AHBDW/4))); when "10" => ret := ahbdrivedata(hdata(2*(AHBDW/4)-1 downto 1*(AHBDW/4))); when others => ret := ahbdrivedata(hdata(1*(AHBDW/4)-1 downto 0*(AHBDW/4))); end case; elsif AHBDW = 64 then if haddr(2) = '0' then ret := ahbdrivedata(hdata(AHBDW-1 downto AHBDW/2)); else ret := ahbdrivedata(hdata(AHBDW/2-1 downto 0)); end if; end if; end case; return ret; end ahbselectdata; -- Description of ahbread* functions and procedures. -- -- The ahbread* subprograms with an 'haddr' input selects the valid slice of -- data from the AHB data vector, 'hdata', based on the 'haddr' input if -- CORE_ACDM is set to 1 (see top of this package). Otherwise the low part of -- the AHB data vector will be returned. -- -- The ahbread* subprograms that do not have a 'haddr' input will always -- return the low slice of the 'hdata' input. These subprograms will assert a -- failure if CORE_ACDM is set to 1. -- function ahbreadword ( hdata : std_logic_vector(AHBDW-1 downto 0); haddr : std_logic_vector(4 downto 2)) return std_logic_vector is variable data : std_logic_vector(31 downto 0); begin if CORE_ACDM = 1 then data := ahbselectdata(hdata, haddr, HSIZE_WORD)(31 downto 0); else data := hdata(31 downto 0); end if; return data; end ahbreadword; procedure ahbreadword ( hdata : in std_logic_vector(AHBDW-1 downto 0); haddr : in std_logic_vector(4 downto 2); data : out std_logic_vector(31 downto 0)) is begin data := ahbreadword(hdata, haddr); end ahbreadword; function ahbreadword ( hdata : std_logic_vector(AHBDW-1 downto 0)) return std_logic_vector is variable data : std_logic_vector(31 downto 0); begin -- pragma translate_off assert CORE_ACDM = 0 report "ahbreadword without address input used when CORE_ACDM /= 0" severity failure; -- pragma translate_on data := hdata(31 downto 0); return data; end ahbreadword; procedure ahbreadword ( hdata : in std_logic_vector(AHBDW-1 downto 0); data : out std_logic_vector(31 downto 0)) is begin data := ahbreadword(hdata); end ahbreadword; function ahbreaddword ( hdata : std_logic_vector(AHBDW-1 downto 0); haddr : std_logic_vector(4 downto 2)) return std_logic_vector is variable data : std_logic_vector(255 downto 0); begin -- pragma translate_off assert AHBDW > 32 report "ahbreaddword can not be used in system with AHB data width < 64" severity failure; -- pragma translate_on if AHBDW = 256 then if CORE_ACDM = 1 then data(AHBDW/4-1 downto 0) := ahbselectdata(hdata, haddr, HSIZE_DWORD)(AHBDW/4-1 downto 0); else data(AHBDW/4-1 downto 0) := hdata(AHBDW/4-1 downto 0); end if; elsif AHBDW = 128 then if CORE_ACDM = 1 then data(AHBDW/2-1 downto 0) := ahbselectdata(hdata, haddr, HSIZE_DWORD)(AHBDW/2-1 downto 0); else data(AHBDW/2-1 downto 0) := hdata(AHBDW/2-1 downto 0); end if; elsif AHBDW = 64 then if CORE_ACDM = 1 then data(AHBDW-1 downto 0) := ahbselectdata(hdata, haddr, HSIZE_DWORD)(AHBDW-1 downto 0); else data(AHBDW-1 downto 0) := hdata(AHBDW-1 downto 0); end if; end if; return data(63 downto 0); end ahbreaddword; procedure ahbreaddword ( hdata : in std_logic_vector(AHBDW-1 downto 0); haddr : in std_logic_vector(4 downto 2); data : out std_logic_vector(63 downto 0)) is begin data := ahbreaddword(hdata, haddr); end ahbreaddword; function ahbreaddword ( hdata : std_logic_vector(AHBDW-1 downto 0)) return std_logic_vector is variable data : std_logic_vector(255 downto 0); begin -- pragma translate_off assert AHBDW > 32 report "ahbreaddword can not be used in system with AHB data width < 64" severity failure; assert CORE_ACDM = 0 report "ahbreaddword without address input used when CORE_ACDM /= 0" severity failure; -- pragma translate_on if AHBDW = 256 then data(AHBDW/4-1 downto 0) := hdata(AHBDW/4-1 downto 0); elsif AHBDW = 128 then data(AHBDW/2-1 downto 0) := hdata(AHBDW/2-1 downto 0); elsif AHBDW = 64 then data(AHBDW-1 downto 0) := hdata(AHBDW-1 downto 0); end if; return data(63 downto 0); end ahbreaddword; procedure ahbreaddword ( hdata : in std_logic_vector(AHBDW-1 downto 0); data : out std_logic_vector(63 downto 0)) is begin data := ahbreaddword(hdata); end ahbreaddword; function ahbread4word ( hdata : std_logic_vector(AHBDW-1 downto 0); haddr : std_logic_vector(4 downto 2)) return std_logic_vector is variable data : std_logic_vector(255 downto 0); begin -- pragma translate_off assert AHBDW > 64 report "ahbread4word can not be used in system with AHB data width < 128 bits" severity failure; -- pragma translate_on if AHBDW = 256 then if CORE_ACDM = 1 then data(AHBDW/2-1 downto 0) := ahbselectdata(hdata, haddr, HSIZE_4WORD)(AHBDW/2-1 downto 0); else data(AHBDW/2-1 downto 0) := hdata(AHBDW/2-1 downto 0); end if; elsif AHBDW = 128 then if CORE_ACDM = 1 then data(AHBDW-1 downto 0) := ahbselectdata(hdata, haddr, HSIZE_4WORD)(AHBDW-1 downto 0); else data(AHBDW-1 downto 0) := hdata(AHBDW-1 downto 0); end if; end if; return data(127 downto 0); end ahbread4word; procedure ahbread4word ( hdata : in std_logic_vector(AHBDW-1 downto 0); haddr : in std_logic_vector(4 downto 2); data : out std_logic_vector(127 downto 0)) is begin data := ahbread4word(hdata, haddr); end ahbread4word; function ahbread4word ( hdata : std_logic_vector(AHBDW-1 downto 0)) return std_logic_vector is variable data : std_logic_vector(255 downto 0); begin -- pragma translate_off assert AHBDW > 64 report "ahbread4word can not be used in system with AHB data width < 128 bits" severity failure; assert CORE_ACDM = 0 report "ahbread4word without address input used when CORE_ACDM /= 0" severity failure; -- pragma translate_on if AHBDW = 256 then data(AHBDW/2-1 downto 0) := hdata(AHBDW/2-1 downto 0); elsif AHBDW = 128 then data(AHBDW-1 downto 0) := hdata(AHBDW-1 downto 0); end if; return data(127 downto 0); end ahbread4word; procedure ahbread4word ( hdata : in std_logic_vector(AHBDW-1 downto 0); data : out std_logic_vector(127 downto 0)) is begin data := ahbread4word(hdata); end ahbread4word; function ahbread8word ( hdata : std_logic_vector(AHBDW-1 downto 0); haddr : std_logic_vector(4 downto 2)) return std_logic_vector is variable data : std_logic_vector(AHBDW-1 downto 0); begin -- pragma translate_off assert AHBDW > 128 report "ahbread8word can not be used in system with AHB data width < 256 bits" severity failure; -- pragma translate_on if CORE_ACDM = 1 then data(AHBDW-1 downto 0) := ahbselectdata(hdata, haddr, HSIZE_8WORD)(AHBDW-1 downto 0); else data(AHBDW-1 downto 0) := hdata(AHBDW-1 downto 0); end if; return data; end ahbread8word; procedure ahbread8word ( hdata : in std_logic_vector(AHBDW-1 downto 0); haddr : in std_logic_vector(4 downto 2); data : out std_logic_vector(255 downto 0)) is begin data := ahbread8word(hdata, haddr); end ahbread8word; function ahbread8word ( hdata : std_logic_vector(AHBDW-1 downto 0)) return std_logic_vector is variable data : std_logic_vector(AHBDW-1 downto 0); begin -- pragma translate_off assert AHBDW > 128 report "ahbread8word can not be used in system with AHB data width < 256 bits" severity failure; assert CORE_ACDM = 0 report "ahbread8word without address input used when CORE_ACDM /= 0" severity failure; -- pragma translate_on data(AHBDW-1 downto 0) := hdata(AHBDW-1 downto 0); return data; end ahbread8word; procedure ahbread8word ( hdata : in std_logic_vector(AHBDW-1 downto 0); data : out std_logic_vector(255 downto 0)) is begin data := ahbread8word(hdata); end ahbread8word; function ahbreaddata ( hdata : std_logic_vector(AHBDW-1 downto 0); haddr : std_logic_vector(4 downto 2); hsize : std_logic_vector(2 downto 0)) return std_logic_vector is begin case hsize is when HSIZE_8WORD => return ahbread8word(hdata, haddr); when HSIZE_4WORD => return ahbread4word(hdata, haddr); when HSIZE_DWORD => return ahbreaddword(hdata, haddr); when others => null; end case; return ahbreadword(hdata, haddr); end ahbreaddata; function ahbreaddata ( hdata : std_logic_vector(AHBDW-1 downto 0); hsize : std_logic_vector(2 downto 0)) return std_logic_vector is begin case hsize is when HSIZE_8WORD => return ahbread8word(hdata); when HSIZE_4WORD => return ahbread4word(hdata); when HSIZE_DWORD => return ahbreaddword(hdata); when others => null; end case; return ahbreadword(hdata); end ahbreaddata; -- a*mux below drives their amba output records with the amba input record if -- the en input is '1'. Otherwise the amba output record is driven to an idle -- state. Plug'n'play information is kept constant. procedure ahbmomux ( signal ai : in ahb_mst_out_type; signal ao : out ahb_mst_out_type; signal en : in std_ulogic) is begin if en = '1' then ao <= ai; else ao <= ahbm_none; end if; ao.haddr <= ai.haddr; ao.hwrite <= ai.hwrite; ao.hsize <= ai.hsize; ao.hprot <= ai.hprot; ao.hwdata <= ai.hwdata; ao.hconfig <= ai.hconfig; ao.hindex <= ai.hindex; end ahbmomux; procedure ahbsomux ( signal ai : in ahb_slv_out_type; signal ao : out ahb_slv_out_type; signal en : in std_ulogic) is begin if en = '1' then ao <= ai; else ao <= ahbs_none; end if; ao.hrdata <= ai.hrdata; ao.hconfig <= ai.hconfig; ao.hindex <= ai.hindex; end ahbsomux; procedure apbsomux ( signal ai : in apb_slv_out_type; signal ao : out apb_slv_out_type; signal en : in std_ulogic) is begin if en = '1' then ao <= ai; else ao <= apb_none; end if; ao.prdata <= ai.prdata; ao.pconfig <= ai.pconfig; ao.pindex <= ai.pindex; end apbsomux; end;

gpl-2.0

9d5c050131f8e8a5152e5affb134c3e3

0.609422

3.623596

false

marco-c/leon-nexys2

grlib-gpl-1.3.4-b4140/lib/gaisler/can/can_oc.vhd

1

5,690

------------------------------------------------------------------------------ -- This file is a part of the GRLIB VHDL IP LIBRARY -- Copyright (C) 2003 - 2008, Gaisler Research -- Copyright (C) 2008 - 2013, Aeroflex Gaisler -- -- This program is free software; you can redistribute it and/or modify -- it under the terms of the GNU General Public License as published by -- the Free Software Foundation; either version 2 of the License, or -- (at your option) any later version. -- -- This program is distributed in the hope that it will be useful, -- but WITHOUT ANY WARRANTY; without even the implied warranty of -- MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the -- GNU General Public License for more details. -- -- You should have received a copy of the GNU General Public License -- along with this program; if not, write to the Free Software -- Foundation, Inc., 59 Temple Place, Suite 330, Boston, MA 02111-1307 USA ----------------------------------------------------------------------------- -- Entity: can_oc -- File: can_oc.vhd -- Author: Jiri Gaisler - Gaisler Research -- Description: AHB interface for the OpenCores CAN MAC ------------------------------------------------------------------------------ library ieee; use ieee.std_logic_1164.all; library grlib; use grlib.amba.all; use grlib.stdlib.all; use grlib.devices.all; library techmap; use techmap.gencomp.all; library gaisler; use gaisler.can.all; entity can_oc is generic ( slvndx : integer := 0; ioaddr : integer := 16#000#; iomask : integer := 16#FF0#; irq : integer := 0; memtech : integer := DEFMEMTECH; syncrst : integer := 0; ft : integer := 0); port ( resetn : in std_logic; clk : in std_logic; ahbsi : in ahb_slv_in_type; ahbso : out ahb_slv_out_type; can_rxi : in std_logic; can_txo : out std_logic ); end; architecture rtl of can_oc is constant ncores : integer := 1; constant sepirq : integer := 0; constant REVISION : amba_version_type := ncores-1; constant hconfig : ahb_config_type := ( 0 => ahb_device_reg ( VENDOR_GAISLER, GAISLER_CANAHB, 0, REVISION, irq), 4 => ahb_iobar(ioaddr, iomask), others => zero32); type ahbregs is record hsel : std_ulogic; hwrite : std_ulogic; hwrite2 : std_ulogic; htrans : std_logic_vector(1 downto 0); haddr : std_logic_vector(10 downto 0); hwdata : std_logic_vector(7 downto 0); herr : std_ulogic; hready : std_ulogic; ws : std_logic_vector(1 downto 0); irqi : std_logic_vector(ncores-1 downto 0); irqo : std_logic_vector(ncores-1 downto 0); end record; subtype cdata is std_logic_vector(7 downto 0); type cdataarr is array (0 to 7) of cdata; signal data_out : cdataarr; signal reset : std_logic; signal irqo : std_logic_vector(ncores-1 downto 0); signal vcc, gnd : std_ulogic; signal r, rin : ahbregs; attribute sync_set_reset : string; attribute sync_set_reset of reset : signal is "true"; begin gnd <= '0'; vcc <= '1'; reset <= not resetn; comb : process(ahbsi, r, resetn, data_out, irqo) variable v : ahbregs; variable hresp : std_logic_vector(1 downto 0); variable dataout : std_logic_vector(7 downto 0); variable irqvec : std_logic_vector(NAHBIRQ-1 downto 0); variable hwdata : std_logic_vector(31 downto 0); begin v := r; hwdata := ahbreadword(ahbsi.hwdata, r.haddr(4 downto 2)); if (r.hsel = '1' ) and (r.ws /= "11") then v.ws := r.ws + 1; end if; if ahbsi.hready = '1' then v.hsel := ahbsi.hsel(slvndx); v.haddr := ahbsi.haddr(10 downto 0); v.htrans := ahbsi.htrans; v.hwrite := ahbsi.hwrite; v.herr := orv(ahbsi.hsize) and ahbsi.hwrite; v.ws := "00"; end if; v.hready := (r.hsel and r.ws(1) and not r.ws(0)) or not resetn or (ahbsi.hready and not ahbsi.htrans(1)) or not v.hsel; v.hwrite2 := r.hwrite and r.hsel and r.htrans(1) and r.ws(1) and not r.ws(0) and not r.herr; if (r.herr and r.ws(1)) = '1' then hresp := HRESP_ERROR; else hresp := HRESP_OKAY; end if; case r.haddr(1 downto 0) is when "00" => v.hwdata := hwdata(31 downto 24); when "01" => v.hwdata := hwdata(23 downto 16); when "10" => v.hwdata := hwdata(15 downto 8); when others => v.hwdata := hwdata(7 downto 0); end case; dataout := data_out(0); -- Interrupt goes to low when appeard and is normal high -- but the irq controller from leon is active high and the interrupt should appear only -- for 1 Clk cycle, v.irqi := irqo; v.irqo:= (r.irqi and not irqo); irqvec := (others => '0'); if sepirq = 1 then irqvec(ncores-1+irq downto irq) := r.irqo; else irqvec(irq) := orv(r.irqo); end if; ahbso.hirq <= irqvec; ahbso.hrdata <= ahbdrivedata(dataout); ahbso.hresp <= hresp; rin <= v; end process; reg : process(clk) begin if clk'event and clk = '1' then r <= rin; end if; end process; cmod : can_mod generic map (memtech, syncrst, ft) port map (reset, clk, r.hsel, r.hwrite2, r.haddr(7 downto 0), r.hwdata, data_out(0), irqo(0), can_rxi, can_txo, ahbsi.testen); ahbso.hconfig <= hconfig; ahbso.hindex <= slvndx; ahbso.hsplit <= (others => '0'); ahbso.hready <= r.hready; -- pragma translate_off bootmsg : report_version generic map ( "can_oc" & tost(slvndx) & ": SJA1000 Compatible CAN MAC, revision " & tost(REVISION) & ", irq " & tost(irq)); -- pragma translate_on end;

gpl-2.0

22ce04b3418fb65c9d819c4e90870528

0.595079

3.540759

false

marco-c/leon-nexys2

grlib-gpl-1.3.4-b4140/lib/techmap/maps/clkmux.vhd

1

3,820

------------------------------------------------------------------------------ -- This file is a part of the GRLIB VHDL IP LIBRARY -- Copyright (C) 2003 - 2008, Gaisler Research -- Copyright (C) 2008 - 2013, Aeroflex Gaisler -- -- This program is free software; you can redistribute it and/or modify -- it under the terms of the GNU General Public License as published by -- the Free Software Foundation; either version 2 of the License, or -- (at your option) any later version. -- -- This program is distributed in the hope that it will be useful, -- but WITHOUT ANY WARRANTY; without even the implied warranty of -- MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the -- GNU General Public License for more details. -- -- You should have received a copy of the GNU General Public License -- along with this program; if not, write to the Free Software -- Foundation, Inc., 59 Temple Place, Suite 330, Boston, MA 02111-1307 USA ----------------------------------------------------------------------------- -- Entity: clkmux -- File: clkmux.vhd -- Author: Edvin Catovic - Gaisler Research -- Description: Glitch-free clock multiplexer ------------------------------------------------------------------------------ library ieee; use ieee.std_logic_1164.all; use work.gencomp.all; use work.allclkgen.all; entity clkmux is generic(tech : integer := 0; rsel : integer range 0 to 1 := 0); -- registered sel port( i0, i1 : in std_ulogic; sel : in std_ulogic; o : out std_ulogic; rst : in std_ulogic := '1' ); end entity; architecture rtl of clkmux is signal seli, sel0, sel1, cg0, cg1 : std_ulogic; begin rs : if rsel = 1 generate rsproc : process(i0) begin if rising_edge(i0) then seli <= sel; end if; end process; end generate; cs : if rsel = 0 generate seli <= sel; end generate; tec : if has_clkmux(tech) = 1 generate xil : if is_unisim(tech) = 1 generate buf : clkmux_unisim port map(sel => seli, I0 => i0, I1 => i1, O => o); end generate; rhl : if tech = rhlib18t generate buf : clkmux_rhlib18t port map(sel => seli, I0 => i0, I1 => i1, O => o); end generate; ut13 : if tech = ut130 generate x0 : clkmux_ut130hbd port map (i0 => i0, i1 => i1, sel => sel, o => o); end generate; n2x : if tech = easic45 generate mux : clkmux_n2x port map (i0 => i0, i1 => i1, sel => sel, o => o); end generate; ut90n : if tech = ut90 generate x0 : clkmux_ut90nhbd port map (i0 => i0, i1 => i1, sel => seli, o => o); end generate; saed : if tech = saed32 generate x0 : clkmux_saed32 port map (i0 => i0, i1 => i1, sel => seli, o => o); end generate; dar : if tech = dare generate x0 : clkmux_dare port map (i0 => i0, i1 => i1, sel => seli, o => o); end generate; rhu : if tech = rhumc generate x0 : clkmux_rhumc port map (i0 => i0, i1 => i1, sel => seli, o => o); end generate; noxil : if not((is_unisim(tech) = 1) or (tech = rhlib18t) or (tech = ut130) or (tech = easic45) or (tech = ut90) or (tech = saed32) or (tech = dare) or (tech = rhumc)) generate o <= i0 when seli = '0' else i1; end generate; end generate; gen : if has_clkmux(tech) = 0 generate p0 : process(i0, rst) begin if rst = '0' then sel0 <= '1'; elsif falling_edge(i0) then sel0 <= (not seli) and (not sel1); end if; end process; p1 : process(i1, rst) begin if rst = '0' then sel1 <= '0'; elsif falling_edge(i1) then sel1 <= seli and (not sel0); end if; end process; cg0 <= i0 and sel0; cg1 <= i1 and sel1; o <= cg0 or cg1; end generate; end architecture;

gpl-2.0

1639a995be2e00c463b01be3ed9b8272

0.564398

3.475887

false

marco-c/leon-nexys2

grlib-gpl-1.3.4-b4140/designs/leon3-avnet-eval-xc4vlx60/leon3mp.vhd

1

27,300

------------------------------------------------------------------------------ -- LEON3 Demonstration design -- Copyright (C) 2006 Jiri Gaisler, Gaisler Research ------------------------------------------------------------------------------ -- This file is a part of the GRLIB VHDL IP LIBRARY -- Copyright (C) 2003 - 2008, Gaisler Research -- Copyright (C) 2008 - 2013, Aeroflex Gaisler -- -- This program is free software; you can redistribute it and/or modify -- it under the terms of the GNU General Public License as published by -- the Free Software Foundation; either version 2 of the License, or -- (at your option) any later version. -- -- This program is distributed in the hope that it will be useful, -- but WITHOUT ANY WARRANTY; without even the implied warranty of -- MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the -- GNU General Public License for more details. -- -- You should have received a copy of the GNU General Public License -- along with this program; if not, write to the Free Software -- Foundation, Inc., 59 Temple Place, Suite 330, Boston, MA 02111-1307 USA ------------------------------------------------------------------------------ library ieee; use ieee.std_logic_1164.all; library grlib; use grlib.amba.all; use grlib.stdlib.all; use grlib.devices.all; library techmap; use techmap.gencomp.all; use techmap.allclkgen.all; library gaisler; use gaisler.memctrl.all; use gaisler.ddrpkg.all; use gaisler.leon3.all; use gaisler.uart.all; use gaisler.misc.all; use gaisler.net.all; use gaisler.jtag.all; library esa; use esa.memoryctrl.all; use work.config.all; use work.avnet_eval.all; entity leon3mp is generic ( fabtech : integer := CFG_FABTECH; memtech : integer := CFG_MEMTECH; padtech : integer := CFG_PADTECH; clktech : integer := CFG_CLKTECH; disas : integer := CFG_DISAS; -- Enable disassembly to console dbguart : integer := CFG_DUART; -- Print UART on console pclow : integer := CFG_PCLOW; ddrfreq : integer := 100000 -- frequency of ddr clock in kHz ); port ( resetn : in std_ulogic; resoutn : out std_logic; clk_100mhz : in std_ulogic; clk_50mhz : in std_ulogic; clk_200p : in std_ulogic; clk_200n : in std_ulogic; errorn : out std_ulogic; -- prom interface address : out std_logic_vector(21 downto 0); data : inout std_logic_vector(15 downto 0); romsn : out std_ulogic; oen : out std_ulogic; writen : out std_ulogic; romrstn : out std_ulogic; -- pragma translate_off iosn : out std_ulogic; testdata : inout std_logic_vector(15 downto 0); -- pragma translate_on -- ddr memory ddr_clk0 : out std_logic; ddr_clk0b : out std_logic; ddr_clk_fb_out : out std_logic; ddr_clk_fb : in std_logic; ddr_cke0 : out std_logic; ddr_cs0b : out std_logic; ddr_web : out std_ulogic; -- ddr write enable ddr_rasb : out std_ulogic; -- ddr ras ddr_casb : out std_ulogic; -- ddr cas ddr_dm : out std_logic_vector (1 downto 0); -- ddr dm ddr_dqs : inout std_logic_vector (1 downto 0); -- ddr dqs ddr_ad : out std_logic_vector (12 downto 0); -- ddr address ddr_ba : out std_logic_vector (1 downto 0); -- ddr bank address ddr_dq : inout std_logic_vector (15 downto 0); -- ddr data -- debug support unit dsuen : in std_ulogic; dsubre : in std_ulogic; dsuact : out std_ulogic; -- UART for serial DCL/console I/O serrx : in std_ulogic; sertx : out std_ulogic; rtsn : out std_ulogic; ctsn : in std_ulogic; led_rx : out std_ulogic; led_tx : out std_ulogic; -- ethernet signals emdio : inout std_logic; -- ethernet PHY interface etx_clk : in std_ulogic; erx_clk : in std_ulogic; erxd : in std_logic_vector(3 downto 0); erx_dv : in std_ulogic; erx_er : in std_ulogic; erx_col : in std_ulogic; erx_crs : in std_ulogic; etxd : out std_logic_vector(3 downto 0); etx_en : out std_ulogic; etx_er : out std_ulogic; emdc : out std_ulogic; erstn : out std_ulogic; -- OLED display signals disp_dcn : out std_ulogic; disp_csn : out std_ulogic; disp_rdn : out std_ulogic; disp_wrn : out std_ulogic; disp_d : inout std_logic_vector(7 downto 0); phy_done : out std_ulogic; rst_done : out std_ulogic ); end; architecture rtl of leon3mp is component mig_36_1 port( cntrl0_ddr_dq : inout std_logic_vector(15 downto 0); cntrl0_ddr_a : out std_logic_vector(12 downto 0); cntrl0_ddr_ba : out std_logic_vector(1 downto 0); cntrl0_ddr_cke : out std_logic; cntrl0_ddr_cs_n : out std_logic; cntrl0_ddr_ras_n : out std_logic; cntrl0_ddr_cas_n : out std_logic; cntrl0_ddr_we_n : out std_logic; cntrl0_ddr_dm : out std_logic_vector(1 downto 0); sys_clk_p : in std_logic; sys_clk_n : in std_logic; clk200_p : in std_logic; clk200_n : in std_logic; init_done : out std_logic; sys_reset_in_n : in std_logic; cntrl0_clk_tb : out std_logic; cntrl0_reset_tb : out std_logic; cntrl0_wdf_almost_full : out std_logic; cntrl0_af_almost_full : out std_logic; cntrl0_read_data_valid : out std_logic; cntrl0_app_wdf_wren : in std_logic; cntrl0_app_af_wren : in std_logic; cntrl0_burst_length_div2 : out std_logic_vector(2 downto 0); cntrl0_app_af_addr : in std_logic_vector(35 downto 0); cntrl0_app_wdf_data : in std_logic_vector(31 downto 0); cntrl0_read_data_fifo_out : out std_logic_vector(31 downto 0); cntrl0_app_mask_data : in std_logic_vector(3 downto 0); cntrl0_ddr_dqs : inout std_logic_vector(1 downto 0); cntrl0_ddr_ck : out std_logic_vector(0 downto 0); cntrl0_ddr_ck_n : out std_logic_vector(0 downto 0) ); end component; constant blength : integer := 12; constant fifodepth : integer := 8; signal vcc, gnd : std_logic_vector(4 downto 0); signal memi : memory_in_type; signal memo : memory_out_type; signal wpo : wprot_out_type; signal sdi : sdctrl_in_type; signal sdo : sdctrl_out_type; signal gpioi : gpio_in_type; signal gpioo : gpio_out_type; signal apbi : apb_slv_in_type; signal apbo : apb_slv_out_vector := (others => apb_none); signal ahbsi : ahb_slv_in_type; signal ahbso : ahb_slv_out_vector := (others => ahbs_none); signal ahbmi : ahb_mst_in_type; signal ahbmo : ahb_mst_out_vector := (others => ahbm_none); signal lclk : std_ulogic; signal ddrclk, ddrrst, ddrclkfb : std_ulogic; signal clkm, rstn, clkml, clk2x : std_ulogic; signal cgi : clkgen_in_type; signal cgo : clkgen_out_type; signal u1i, dui : uart_in_type; signal u1o, duo : uart_out_type; signal irqi : irq_in_vector(0 to CFG_NCPU-1); signal irqo : irq_out_vector(0 to CFG_NCPU-1); signal dbgi : l3_debug_in_vector(0 to CFG_NCPU-1); signal dbgo : l3_debug_out_vector(0 to CFG_NCPU-1); signal dsui : dsu_in_type; signal dsuo : dsu_out_type; signal ethi, ethi1, ethi2 : eth_in_type; signal etho, etho1, etho2 : eth_out_type; signal gpti : gptimer_in_type; signal tck, tms, tdi, tdo : std_ulogic; signal fpi : grfpu_in_vector_type; signal fpo : grfpu_out_vector_type; -- signal dsubre : std_logic; signal duart, ldsuen : std_logic; signal rsertx, rserrx, rdsuen : std_logic; signal rstraw : std_logic; signal rstneg : std_logic; signal rxd1 : std_logic; signal txd1 : std_logic; signal lock : std_logic; signal lclk50 : std_logic; signal rst0_tb, rst0_tbn, clk0_tb : std_logic; signal migi : mig_app_in_type; signal migo : mig_app_out_type; signal init_done : std_ulogic; signal migrst : std_ulogic; signal ddr_clk : std_logic_vector(2 downto 0); signal ddr_clkb : std_logic_vector(2 downto 0); signal ddr_cke : std_logic_vector(1 downto 0); signal ddr_csb : std_logic_vector(1 downto 0); signal ddr_adl : std_logic_vector(13 downto 0); -- ddr address attribute keep : boolean; attribute syn_keep : boolean; attribute syn_preserve : boolean; attribute syn_keep of lock : signal is true; attribute syn_keep of clkml : signal is true; attribute syn_preserve of clkml : signal is true; attribute keep of lock : signal is true; attribute keep of clkml : signal is true; attribute keep of clkm : signal is true; constant BOARD_FREQ : integer := 50000; -- input frequency in KHz constant CPU_FREQ : integer := BOARD_FREQ * CFG_CLKMUL / CFG_CLKDIV; -- cpu frequency in KHz begin romrstn <= rstn; ---------------------------------------------------------------------- --- Reset and Clock generation ------------------------------------- ---------------------------------------------------------------------- vcc <= (others => '1'); gnd <= (others => '0'); cgi.pllctrl <= "00"; cgi.pllrst <= rstneg; rstneg <= not resetn; rst0 : rstgen port map (rstneg, clkm, lock, rstn, rstraw); clk50_pad : clkpad generic map (tech => padtech) port map (clk_50mhz, lclk50); clkgen0 : clkgen -- clock generator generic map (clktech, CFG_CLKMUL, CFG_CLKDIV, 0, 1, 0, 0, 0, BOARD_FREQ, 0) port map (lclk50, gnd(0), clkm, open, open, open, open, cgi, cgo); ---------------------------------------------------------------------- --- AHB CONTROLLER -------------------------------------------------- ---------------------------------------------------------------------- ahb0 : ahbctrl -- AHB arbiter/multiplexer generic map (defmast => CFG_DEFMST, split => CFG_SPLIT, rrobin => CFG_RROBIN, ioaddr => CFG_AHBIO, ioen => 1, nahbm => CFG_NCPU+CFG_AHB_UART+CFG_AHB_JTAG+CFG_GRETH+1, nahbs => 8) port map (rstn, clkm, ahbmi, ahbmo, ahbsi, ahbso); ---------------------------------------------------------------------- --- LEON3 processor and DSU ----------------------------------------- ---------------------------------------------------------------------- leon3gen : if CFG_LEON3 = 1 generate cpu : for i in 0 to CFG_NCPU-1 generate nosh : if CFG_GRFPUSH = 0 generate u0 : leon3s -- LEON3 processor generic map (i, fabtech, memtech, CFG_NWIN, CFG_DSU, CFG_FPU*(1-CFG_GRFPUSH), CFG_V8, 0, CFG_MAC, pclow, CFG_NOTAG, CFG_NWP, CFG_ICEN, CFG_IREPL, CFG_ISETS, CFG_ILINE, CFG_ISETSZ, CFG_ILOCK, CFG_DCEN, CFG_DREPL, CFG_DSETS, CFG_DLINE, CFG_DSETSZ, CFG_DLOCK, CFG_DSNOOP, CFG_ILRAMEN, CFG_ILRAMSZ, CFG_ILRAMADDR, CFG_DLRAMEN, CFG_DLRAMSZ, CFG_DLRAMADDR, CFG_MMUEN, CFG_ITLBNUM, CFG_DTLBNUM, CFG_TLB_TYPE, CFG_TLB_REP, CFG_LDDEL, disas, CFG_ITBSZ, CFG_PWD, CFG_SVT, CFG_RSTADDR, CFG_NCPU-1, CFG_DFIXED, 0, CFG_MMU_PAGE, CFG_BP) port map (clkm, rstn, ahbmi, ahbmo(i), ahbsi, ahbso, irqi(i), irqo(i), dbgi(i), dbgo(i)); end generate; sh : if CFG_GRFPUSH = 1 generate u0 : leon3sh -- LEON3 processor generic map (i, fabtech, memtech, CFG_NWIN, CFG_DSU, CFG_FPU*(1-CFG_GRFPUSH), CFG_V8, 0, CFG_MAC, pclow, CFG_NOTAG, CFG_NWP, CFG_ICEN, CFG_IREPL, CFG_ISETS, CFG_ILINE, CFG_ISETSZ, CFG_ILOCK, CFG_DCEN, CFG_DREPL, CFG_DSETS, CFG_DLINE, CFG_DSETSZ, CFG_DLOCK, CFG_DSNOOP, CFG_ILRAMEN, CFG_ILRAMSZ, CFG_ILRAMADDR, CFG_DLRAMEN, CFG_DLRAMSZ, CFG_DLRAMADDR, CFG_MMUEN, CFG_ITLBNUM, CFG_DTLBNUM, CFG_TLB_TYPE, CFG_TLB_REP, CFG_LDDEL, disas, CFG_ITBSZ, CFG_PWD, CFG_SVT, CFG_RSTADDR, CFG_NCPU-1, CFG_DFIXED, 0, CFG_MMU_PAGE, CFG_BP) port map (clkm, rstn, ahbmi, ahbmo(i), ahbsi, ahbso, irqi(i), irqo(i), dbgi(i), dbgo(i), fpi(i), fpo(i)); end generate; end generate; sh : if CFG_GRFPUSH = 1 generate grfpush0 : grfpushwx generic map ((CFG_FPU-1), CFG_NCPU, fabtech) port map (clkm, rstn, fpi, fpo); end generate; error_pad : odpad generic map (tech => padtech) port map (errorn, dbgo(0).error); dsugen : if CFG_DSU = 1 generate dsu0 : dsu3 -- LEON3 Debug Support Unit generic map (hindex => 2, haddr => 16#900#, hmask => 16#F00#, ncpu => CFG_NCPU, tbits => 30, tech => memtech, irq => 0, kbytes => CFG_ATBSZ) port map (rstn, clkm, ahbmi, ahbsi, ahbso(2), dbgo, dbgi, dsui, dsuo); -- dsuen_pad : inpad generic map (tech => padtech) port map (dsuen, dsui.enable); dsui.enable <= '1'; dsubre_pad : inpad generic map (tech => padtech) port map (dsubre, dsui.break); dsuact_pad : outpad generic map (tech => padtech) port map (dsuact, dsuo.active); end generate; end generate; nodsu : if CFG_DSU = 0 generate ahbso(2) <= ahbs_none; dsuo.tstop <= '0'; dsuo.active <= '0'; end generate; dcomgen : if CFG_AHB_UART = 1 generate dcom0 : ahbuart -- Debug UART generic map (hindex => CFG_NCPU, pindex => 4, paddr => 7) port map (rstn, clkm, dui, duo, apbi, apbo(4), ahbmi, ahbmo(CFG_NCPU)); end generate; nouah : if CFG_AHB_UART = 0 generate apbo(4) <= apb_none; end generate; ahbjtaggen0 :if CFG_AHB_JTAG = 1 generate ahbjtag0 : ahbjtag generic map(tech => fabtech, hindex => CFG_NCPU+CFG_AHB_UART) port map(rstn, clkm, tck, tms, tdi, tdo, ahbmi, ahbmo(CFG_NCPU+CFG_AHB_UART), open, open, open, open, open, open, open, gnd(0)); end generate; ---------------------------------------------------------------------- --- Memory controllers ---------------------------------------------- ---------------------------------------------------------------------- mg2 : if CFG_MCTRL_LEON2 = 1 generate -- LEON2 memory controller sr1 : mctrl generic map (hindex => 5, pindex => 0, paddr => 0, srbanks => 1, ramaddr => 16#600#, rammask => 16#F00#, ram16 => 1 ) port map (rstn, clkm, memi, memo, ahbsi, ahbso(5), apbi, apbo(0), wpo, open); end generate; memi.brdyn <= '1'; memi.bexcn <= '1'; memi.writen <= '1'; memi.wrn <= "1111"; memi.bwidth <= "01"; mg0 : if (CFG_MCTRL_LEON2 = 0) generate apbo(0) <= apb_none; ahbso(5) <= ahbs_none; roms_pad : outpad generic map (tech => padtech) port map (romsn, vcc(0)); end generate; mgpads : if (CFG_MCTRL_LEON2 /= 0) generate addr_pad : outpadv generic map (width => 22, tech => padtech) port map (address, memo.address(22 downto 1)); roms_pad : outpad generic map (tech => padtech) port map (romsn, memo.romsn(0)); oen_pad : outpad generic map (tech => padtech) port map (oen, memo.oen); wri_pad : outpad generic map (tech => padtech) port map (writen, memo.writen); -- pragma translate_off iosn_pad : outpad generic map (tech => padtech) port map (iosn, memo.iosn); tbdr : for i in 0 to 1 generate data_pad : iopadv generic map (tech => padtech, width => 8) port map (testdata(15-i*8 downto 8-i*8), memo.data(15-i*8 downto 8-i*8), memo.bdrive(i+2), memi.data(15-i*8 downto 8-i*8)); end generate; -- pragma translate_on bdr : for i in 0 to 1 generate data_pad : iopadv generic map (tech => padtech, width => 8) port map (data(15-i*8 downto 8-i*8), memo.data(31-i*8 downto 24-i*8), memo.bdrive(i), memi.data(31-i*8 downto 24-i*8)); end generate; end generate; ---------------------------------------------------------------------- --- DDR memory controller ------------------------------------------- ---------------------------------------------------------------------- ddrsp0 : if (CFG_DDRSP /= 0) generate clk_pad : clkpad generic map (tech => padtech) port map (clk_100mhz, lclk); ddrc : ddrspa generic map ( fabtech => virtex4, memtech => memtech, hindex => 4, haddr => 16#400#, hmask => 16#F00#, ioaddr => 1, pwron => CFG_DDRSP_INIT, MHz => 100, rskew => -95 -- pragma translate_off * 0 -- disable clock skew during simulation -- pragma translate_on , clkmul => CFG_DDRSP_FREQ/5, clkdiv => 20, col => CFG_DDRSP_COL, Mbyte => CFG_DDRSP_SIZE, ahbfreq => CPU_FREQ/1000, ddrbits => 16) port map ( rstneg, rstn, lclk, clkm, lock, clkml, clkml, ahbsi, ahbso(4), ddr_clk, ddr_clkb, ddr_clk_fb_out, ddr_clk_fb, ddr_cke, ddr_csb, ddr_web, ddr_rasb, ddr_casb, ddr_dm, ddr_dqs, ddr_adl, ddr_ba, ddr_dq); ddr_clk0 <= ddr_clk(0); ddr_clk0b <= ddr_clkb(0); ddr_cke0 <= ddr_cke(0); ddr_cs0b <= ddr_csb(0); ddr_ad <= ddr_adl(12 downto 0); end generate; migsp0 : if (CFG_MIG_DDR2 = 1) generate ahb2mig0 : entity work.ahb2mig_avnet_eval generic map ( hindex => 0, haddr => 16#400#, hmask => 16#FE0#, MHz => 100, Mbyte => 32) port map ( rst_ahb => rstn, rst_ddr => rst0_tbn, rst_50 => rstneg, clk_ahb => clkm, clk_ddr => clk0_tb, clk_50 => lclk50, init_done => init_done, ahbsi => ahbsi, ahbso => ahbso(0), migi => migi, migo => migo); migv5 : mig_36_1 port map( cntrl0_ddr_dq => ddr_dq, cntrl0_ddr_a => ddr_ad(12 downto 0), cntrl0_ddr_ba => ddr_ba, cntrl0_ddr_cke => ddr_cke0, cntrl0_ddr_cs_n => ddr_cs0b, cntrl0_ddr_ras_n => ddr_rasb, cntrl0_ddr_cas_n => ddr_casb, cntrl0_ddr_we_n => ddr_web, cntrl0_ddr_dm => ddr_dm, sys_clk_p => clk_100mhz, clk200_p => clk_200p, sys_clk_n => clk_100mhz, clk200_n => clk_200n, init_done => init_done, sys_reset_in_n => migi.mig_rst, cntrl0_reset_tb => rst0_tb, cntrl0_clk_tb => clk0_tb, cntrl0_wdf_almost_full => migo.app_wdf_afull, cntrl0_af_almost_full => migo.app_af_afull, cntrl0_read_data_valid => migo.app_rd_data_valid, cntrl0_app_wdf_wren => migi.app_wdf_wren, cntrl0_app_af_wren => migi.app_en, cntrl0_app_af_addr => migi.app_addr, cntrl0_app_wdf_data => migi.app_wdf_data, cntrl0_read_data_fifo_out => migo.app_rd_data, cntrl0_app_mask_data => migi.app_wdf_mask, cntrl0_ddr_dqs => ddr_dqs, cntrl0_ddr_ck => ddr_clk(0 downto 0), cntrl0_ddr_ck_n => ddr_clkb(0 downto 0) ); ddr_clk0 <= ddr_clk(0); ddr_clk0b <= ddr_clkb(0); rst0_tbn <= not rst0_tb; -- lock <= cgo.clklock; lock <= init_done and rst0_tbn; -- led(7) <= init_done; end generate; phy_done <= init_done; rst_done <= migi.mig_rst; noddr : if (CFG_DDRSP + CFG_MIG_DDR2) = 0 generate lock <= '1'; end generate; ---------------------------------------------------------------------- --- APB Bridge and various periherals ------------------------------- ---------------------------------------------------------------------- apb0 : apbctrl -- AHB/APB bridge generic map (hindex => 1, haddr => CFG_APBADDR) port map (rstn, clkm, ahbsi, ahbso(1), apbi, apbo); ua1 : if CFG_UART1_ENABLE /= 0 generate uart1 : apbuart -- UART 1 generic map (pindex => 1, paddr => 1, pirq => 2, console => dbguart, fifosize => CFG_UART1_FIFO) port map (rstn, clkm, apbi, apbo(1), u1i, u1o); u1i.rxd <= rxd1; u1i.ctsn <= '0'; u1i.extclk <= '0'; txd1 <= u1o.txd; end generate; noua0 : if CFG_UART1_ENABLE = 0 generate apbo(1) <= apb_none; end generate; irqctrl : if CFG_IRQ3_ENABLE /= 0 generate irqctrl0 : irqmp -- interrupt controller generic map (pindex => 2, paddr => 2, ncpu => CFG_NCPU) port map (rstn, clkm, apbi, apbo(2), irqo, irqi); end generate; irq3 : if CFG_IRQ3_ENABLE = 0 generate x : for i in 0 to CFG_NCPU-1 generate irqi(i).irl <= "0000"; end generate; apbo(2) <= apb_none; end generate; gpt : if CFG_GPT_ENABLE /= 0 generate timer0 : gptimer -- timer unit generic map (pindex => 3, paddr => 3, pirq => CFG_GPT_IRQ, sepirq => CFG_GPT_SEPIRQ, sbits => CFG_GPT_SW, ntimers => CFG_GPT_NTIM, nbits => CFG_GPT_TW) port map (rstn, clkm, apbi, apbo(3), gpti, open); gpti.dhalt <= dsuo.tstop; gpti.extclk <= '0'; end generate; notim : if CFG_GPT_ENABLE = 0 generate apbo(3) <= apb_none; end generate; gpio0 : if CFG_GRGPIO_ENABLE /= 0 generate -- GR GPIO unit grgpio0: grgpio generic map( pindex => 11, paddr => 11, imask => CFG_GRGPIO_IMASK, nbits => 12 --CFG_GRGPIO_WIDTH ) port map( rstn, clkm, apbi, apbo(11), gpioi, gpioo); disp_csn_pad : outpad generic map (tech => padtech) port map (disp_csn, gpioo.dout(8)); disp_dcn_pad : outpad generic map (tech => padtech) port map (disp_dcn, gpioo.dout(9)); disp_rdn_pad : outpad generic map (tech => padtech) port map (disp_rdn, gpioo.dout(10)); disp_wrn_pad : outpad generic map (tech => padtech) port map (disp_wrn, gpioo.dout(11)); disp_d_pads : for i in 0 to 7 generate pio_pad : iopad generic map (tech => padtech) port map (disp_d(i), gpioo.dout(i), gpioo.oen(i), gpioi.din(i)); end generate; end generate; ----------------------------------------------------------------------- --- ETHERNET --------------------------------------------------------- ----------------------------------------------------------------------- eth0 : if CFG_GRETH = 1 generate -- Gaisler ethernet MAC e1 : grethm generic map(hindex => CFG_NCPU+CFG_AHB_UART+CFG_AHB_JTAG, pindex => 15, paddr => 15, pirq => 12, memtech => memtech, mdcscaler => CPU_FREQ/1000, enable_mdio => 1, fifosize => CFG_ETH_FIFO, nsync => 1, edcl => CFG_DSU_ETH, edclbufsz => CFG_ETH_BUF, macaddrh => CFG_ETH_ENM, macaddrl => CFG_ETH_ENL, ipaddrh => CFG_ETH_IPM, ipaddrl => CFG_ETH_IPL, phyrstadr => 3, giga => CFG_GRETH1G) port map( rst => rstn, clk => clkm, ahbmi => ahbmi, ahbmo => ahbmo(CFG_NCPU+CFG_AHB_UART+CFG_AHB_JTAG), apbi => apbi, apbo => apbo(15), ethi => ethi, etho => etho); emdio_pad : iopad generic map (tech => padtech) port map (emdio, etho.mdio_o, etho.mdio_oe, ethi.mdio_i); etxc_pad : clkpad generic map (tech => padtech) port map (etx_clk, ethi.tx_clk); erxc_pad : clkpad generic map (tech => padtech) port map (erx_clk, ethi.rx_clk); erxd_pad : inpadv generic map (tech => padtech, width => 4) port map (erxd, ethi.rxd(3 downto 0)); erxdv_pad : inpad generic map (tech => padtech) port map (erx_dv, ethi.rx_dv); erxer_pad : inpad generic map (tech => padtech) port map (erx_er, ethi.rx_er); erxco_pad : inpad generic map (tech => padtech) port map (erx_col, ethi.rx_col); erxcr_pad : inpad generic map (tech => padtech) port map (erx_crs, ethi.rx_crs); etxd_pad : outpadv generic map (tech => padtech, width => 4) port map (etxd, etho.txd(3 downto 0)); etxen_pad : outpad generic map (tech => padtech) port map (etx_en, etho.tx_en); etxer_pad : outpad generic map (tech => padtech) port map (etx_er, etho.tx_er); emdc_pad : outpad generic map (tech => padtech) port map (emdc, etho.mdc); erstn_pad : outpad generic map (tech => padtech) port map (erstn, rstn); end generate; ----------------------------------------------------------------------- --- AHB DMA ---------------------------------------------------------- ----------------------------------------------------------------------- -- dma0 : ahbdma -- generic map (hindex => CFG_NCPU+CFG_AHB_UART+CFG_GRETH, -- pindex => 12, paddr => 12, dbuf => 32) -- port map (rstn, clkm, apbi, apbo(12), ahbmi, -- ahbmo(CFG_NCPU+CFG_AHB_UART+CFG_GRETH)); -- -- at0 : ahbtrace -- generic map ( hindex => 7, ioaddr => 16#200#, iomask => 16#E00#, -- tech => memtech, irq => 0, kbytes => 8) -- port map ( rstn, clkm, ahbmi, ahbsi, ahbso(7)); ----------------------------------------------------------------------- --- AHB ROM ---------------------------------------------------------- ----------------------------------------------------------------------- bpromgen : if CFG_AHBROMEN /= 0 generate brom : entity work.ahbrom generic map (hindex => 6, haddr => CFG_AHBRODDR, pipe => CFG_AHBROPIP) port map ( rstn, clkm, ahbsi, ahbso(6)); end generate; nobpromgen : if CFG_AHBROMEN = 0 generate ahbso(6) <= ahbs_none; end generate; ----------------------------------------------------------------------- --- AHB RAM ---------------------------------------------------------- ----------------------------------------------------------------------- ahbramgen : if CFG_AHBRAMEN = 1 generate ahbram0 : ahbram generic map (hindex => 3, haddr => CFG_AHBRADDR, tech => CFG_MEMTECH, kbytes => CFG_AHBRSZ, pipe => CFG_AHBRPIPE) port map (rstn, clkm, ahbsi, ahbso(3)); end generate; nram : if CFG_AHBRAMEN = 0 generate ahbso(3) <= ahbs_none; end generate; ----------------------------------------------------------------------- --- Drive unused bus elements --------------------------------------- ----------------------------------------------------------------------- nam1 : for i in (CFG_NCPU+CFG_AHB_UART+CFG_AHB_JTAG+CFG_GRETH+1) to NAHBMST-1 generate ahbmo(i) <= ahbm_none; end generate; -- nap0 : for i in 9 to NAPBSLV-1-CFG_GRETH generate apbo(i) <= apb_none; end generate; -- nah0 : for i in 8 to NAHBSLV-1 generate ahbso(i) <= ahbs_none; end generate; resoutn <= rstn; ----------------------------------------------------------------------- --- Boot message ---------------------------------------------------- ----------------------------------------------------------------------- -- pragma translate_off x : report_design generic map ( msg1 => "LEON3 MP Demonstration design for Avnet Virtex4 Eval board", fabtech => tech_table(fabtech), memtech => tech_table(memtech), mdel => 1 ); -- pragma translate_on -- use switch 1 to multiplex DSU UART and UART1 dsuen_pad : inpad generic map (tech => padtech) port map (dsuen, ldsuen); duart <= rdsuen when CFG_AHB_UART /= 0 else '0'; rxd1 <= txd1 when duart = '1' else rserrx; rsertx <= duo.txd when duart = '1' else txd1; dui.rxd <= rserrx when duart = '1' else '1'; led_rx <= not rserrx; p1 : process(clkm) begin if rising_edge(clkm) then sertx <= rsertx; rserrx <= serrx; rdsuen <= ldsuen; rtsn <= '0'; led_tx <= not rsertx; end if; end process; end rtl;

gpl-2.0

13680519433fc03e4e1d02e8ac4e7e28

0.540769

3.570961

false

marco-c/leon-nexys2

grlib-gpl-1.3.4-b4140/lib/techmap/maps/ddr_oreg.vhd

1

2,899

------------------------------------------------------------------------------ -- This file is a part of the GRLIB VHDL IP LIBRARY -- Copyright (C) 2003 - 2008, Gaisler Research -- Copyright (C) 2008 - 2013, Aeroflex Gaisler -- -- This program is free software; you can redistribute it and/or modify -- it under the terms of the GNU General Public License as published by -- the Free Software Foundation; either version 2 of the License, or -- (at your option) any later version. -- -- This program is distributed in the hope that it will be useful, -- but WITHOUT ANY WARRANTY; without even the implied warranty of -- MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the -- GNU General Public License for more details. -- -- You should have received a copy of the GNU General Public License -- along with this program; if not, write to the Free Software -- Foundation, Inc., 59 Temple Place, Suite 330, Boston, MA 02111-1307 USA ----------------------------------------------------------------------------- -- Entity: ddr_oreg -- File: ddr_oreg.vhd -- Author: Jiri Gaisler - Gaisler Research -- Description: DDR output reg with tech selection ------------------------------------------------------------------------------ library ieee; use ieee.std_logic_1164.all; library techmap; use techmap.gencomp.all; use techmap.allddr.all; entity ddr_oreg is generic (tech : integer; arch : integer := 0); port ( Q : out std_ulogic; C1 : in std_ulogic; C2 : in std_ulogic; CE : in std_ulogic; D1 : in std_ulogic; D2 : in std_ulogic; R : in std_ulogic; S : in std_ulogic); end; architecture rtl of ddr_oreg is begin inf : if not ((tech = lattice) or (is_unisim(tech) = 1) or (tech = axcel) or (tech = axdsp) or (tech = apa3) or (tech = apa3e) or (tech = apa3l)) generate inf0 : gen_oddr_reg port map (Q, C1, C2, CE, D1, D2, R, S); end generate; ax : if (tech = axcel) or (tech = axdsp) generate ax0 : axcel_oddr_reg port map (Q, C1, C2, CE, D1, D2, R, S); end generate; pa3 : if (tech = apa3) generate pa0 : apa3_oddr_reg port map (Q, C1, C2, CE, D1, D2, R, S); end generate; pa3e : if (tech = apa3e) generate pa0 : apa3e_oddr_reg port map (Q, C1, C2, CE, D1, D2, R, S); end generate; pa3l : if (tech = apa3l) generate pa0 : apa3l_oddr_reg port map (Q, C1, C2, CE, D1, D2, R, S); end generate; lat : if tech = lattice generate lat0 : ec_oddr_reg port map (Q, C1, C2, CE, D1, D2, R, S); end generate; xil : if is_unisim(tech) = 1 generate xil0 : unisim_oddr_reg generic map (tech, arch) port map (Q, C1, C2, CE, D1, D2, R, S); end generate; --pragma translate_off assert (tech /= easic45) and (tech /= easic90) report "ddr_oreg: Not supported on eASIC. Use DDR pad instead." severity failure; --pragma translate_on end;

gpl-2.0

952085e6fb4099146053c2fddacba297

0.595723

3.378788

false

Fairyland0902/BlockyRoads

src/BlockyRoads/ipcore_dir/explosion/simulation/explosion_tb.vhd

1

4,361

-------------------------------------------------------------------------------- -- -- BLK MEM GEN v7_3 Core - Top File for the Example Testbench -- -------------------------------------------------------------------------------- -- -- (c) Copyright 2006_3010 Xilinx, Inc. All rights reserved. -- -- This file contains confidential and proprietary information -- of Xilinx, Inc. and is protected under U.S. and -- international copyright and other intellectual property -- laws. -- -- DISCLAIMER -- This disclaimer is not a license and does not grant any -- rights to the materials distributed herewith. Except as -- otherwise provided in a valid license issued to you by -- Xilinx, and to the maximum extent permitted by applicable -- law: (1) THESE MATERIALS ARE MADE AVAILABLE "AS IS" AND -- WITH ALL FAULTS, AND XILINX HEREBY DISCLAIMS ALL WARRANTIES -- AND CONDITIONS, EXPRESS, IMPLIED, OR STATUTORY, INCLUDING -- BUT NOT LIMITED TO WARRANTIES OF MERCHANTABILITY, NON- -- INFRINGEMENT, OR FITNESS FOR ANY PARTICULAR PURPOSE; and -- (2) Xilinx shall not be liable (whether in contract or tort, -- including negligence, or under any other theory of -- liability) for any loss or damage of any kind or nature -- related to, arising under or in connection with these -- materials, including for any direct, or any indirect, -- special, incidental, or consequential loss or damage -- (including loss of data, profits, goodwill, or any type of -- loss or damage suffered as a result of any action brought -- by a third party) even if such damage or loss was -- reasonably foreseeable or Xilinx had been advised of the -- possibility of the same. -- -- CRITICAL APPLICATIONS -- Xilinx products are not designed or intended to be fail- -- safe, or for use in any application requiring fail-safe -- performance, such as life-support or safety devices or -- systems, Class III medical devices, nuclear facilities, -- applications related to the deployment of airbags, or any -- other applications that could lead to death, personal -- injury, or severe property or environmental damage -- (individually and collectively, "Critical -- Applications"). Customer assumes the sole risk and -- liability of any use of Xilinx products in Critical -- Applications, subject only to applicable laws and -- regulations governing limitations on product liability. -- -- THIS COPYRIGHT NOTICE AND DISCLAIMER MUST BE RETAINED AS -- PART OF THIS FILE AT ALL TIMES. -------------------------------------------------------------------------------- -- Filename: explosion_tb.vhd -- Description: -- Testbench Top -------------------------------------------------------------------------------- -- Author: IP Solutions Division -- -- History: Sep 12, 2011 - First Release -------------------------------------------------------------------------------- -- -------------------------------------------------------------------------------- -- Library Declarations -------------------------------------------------------------------------------- LIBRARY IEEE; USE IEEE.STD_LOGIC_1164.ALL; USE IEEE.STD_LOGIC_ARITH.ALL; USE IEEE.STD_LOGIC_UNSIGNED.ALL; LIBRARY work; USE work.ALL; ENTITY explosion_tb IS END ENTITY; ARCHITECTURE explosion_tb_ARCH OF explosion_tb IS SIGNAL STATUS : STD_LOGIC_VECTOR(8 DOWNTO 0); SIGNAL CLK : STD_LOGIC := '1'; SIGNAL RESET : STD_LOGIC; BEGIN CLK_GEN: PROCESS BEGIN CLK <= NOT CLK; WAIT FOR 100 NS; CLK <= NOT CLK; WAIT FOR 100 NS; END PROCESS; RST_GEN: PROCESS BEGIN RESET <= '1'; WAIT FOR 1000 NS; RESET <= '0'; WAIT; END PROCESS; --STOP_SIM: PROCESS BEGIN -- WAIT FOR 200 US; -- STOP SIMULATION AFTER 1 MS -- ASSERT FALSE -- REPORT "END SIMULATION TIME REACHED" -- SEVERITY FAILURE; --END PROCESS; -- PROCESS BEGIN WAIT UNTIL STATUS(8)='1'; IF( STATUS(7 downto 0)/="0") THEN ASSERT false REPORT "Test Completed Successfully" SEVERITY NOTE; REPORT "Simulation Failed" SEVERITY FAILURE; ELSE ASSERT false REPORT "TEST PASS" SEVERITY NOTE; REPORT "Test Completed Successfully" SEVERITY FAILURE; END IF; END PROCESS; explosion_synth_inst:ENTITY work.explosion_synth GENERIC MAP (C_ROM_SYNTH => 0) PORT MAP( CLK_IN => CLK, RESET_IN => RESET, STATUS => STATUS ); END ARCHITECTURE;

mit

373bafdd3956c4a7a5150380a33cf84a

0.620958

4.684211

false

marco-c/leon-nexys2

grlib-gpl-1.3.4-b4140/designs/leon3-altera-ep3sl150/config.vhd

1

6,555

----------------------------------------------------------------------------- -- LEON3 Demonstration design test bench configuration -- Copyright (C) 2009 Aeroflex Gaisler ------------------------------------------------------------------------------ library techmap; use techmap.gencomp.all; package config is -- Technology and synthesis options constant CFG_FABTECH : integer := stratix3; constant CFG_MEMTECH : integer := stratix3; constant CFG_PADTECH : integer := stratix3; constant CFG_NOASYNC : integer := 0; constant CFG_SCAN : integer := 0; -- Clock generator constant CFG_CLKTECH : integer := stratix3; constant CFG_CLKMUL : integer := (30); constant CFG_CLKDIV : integer := (10); constant CFG_OCLKDIV : integer := 1; constant CFG_OCLKBDIV : integer := 0; constant CFG_OCLKCDIV : integer := 0; constant CFG_PCIDLL : integer := 0; constant CFG_PCISYSCLK: integer := 0; constant CFG_CLK_NOFB : integer := 0; -- LEON3 processor core constant CFG_LEON3 : integer := 1; constant CFG_NCPU : integer := (1); constant CFG_NWIN : integer := (8); constant CFG_V8 : integer := 16#32# + 4*0; constant CFG_MAC : integer := 0; constant CFG_BP : integer := 0; constant CFG_SVT : integer := 0; constant CFG_RSTADDR : integer := 16#00000#; constant CFG_LDDEL : integer := (1); constant CFG_NOTAG : integer := 0; constant CFG_NWP : integer := (2); constant CFG_PWD : integer := 0*2; constant CFG_FPU : integer := 0 + 16*0 + 32*0; constant CFG_GRFPUSH : integer := 0; constant CFG_ICEN : integer := 1; constant CFG_ISETS : integer := 2; constant CFG_ISETSZ : integer := 8; constant CFG_ILINE : integer := 8; constant CFG_IREPL : integer := 0; constant CFG_ILOCK : integer := 0; constant CFG_ILRAMEN : integer := 0; constant CFG_ILRAMADDR: integer := 16#8E#; constant CFG_ILRAMSZ : integer := 1; constant CFG_DCEN : integer := 1; constant CFG_DSETS : integer := 2; constant CFG_DSETSZ : integer := 4; constant CFG_DLINE : integer := 8; constant CFG_DREPL : integer := 0; constant CFG_DLOCK : integer := 0; constant CFG_DSNOOP : integer := 1 + 0 + 4*0; constant CFG_DFIXED : integer := 16#0#; constant CFG_DLRAMEN : integer := 0; constant CFG_DLRAMADDR: integer := 16#8F#; constant CFG_DLRAMSZ : integer := 1; constant CFG_MMUEN : integer := 0; constant CFG_ITLBNUM : integer := 2; constant CFG_DTLBNUM : integer := 2; constant CFG_TLB_TYPE : integer := 1 + 0*2; constant CFG_TLB_REP : integer := 1; constant CFG_MMU_PAGE : integer := 0; constant CFG_DSU : integer := 1; constant CFG_ITBSZ : integer := 2; constant CFG_ATBSZ : integer := 2; constant CFG_LEON3FT_EN : integer := 0; constant CFG_IUFT_EN : integer := 0; constant CFG_FPUFT_EN : integer := 0; constant CFG_RF_ERRINJ : integer := 0; constant CFG_CACHE_FT_EN : integer := 0; constant CFG_CACHE_ERRINJ : integer := 0; constant CFG_LEON3_NETLIST: integer := 0; constant CFG_DISAS : integer := 0 + 0; constant CFG_PCLOW : integer := 2; -- AMBA settings constant CFG_DEFMST : integer := (0); constant CFG_RROBIN : integer := 1; constant CFG_SPLIT : integer := 0; constant CFG_FPNPEN : integer := 0; constant CFG_AHBIO : integer := 16#FFF#; constant CFG_APBADDR : integer := 16#800#; constant CFG_AHB_MON : integer := 0; constant CFG_AHB_MONERR : integer := 0; constant CFG_AHB_MONWAR : integer := 0; constant CFG_AHB_DTRACE : integer := 0; -- DSU UART constant CFG_AHB_UART : integer := 0; -- JTAG based DSU interface constant CFG_AHB_JTAG : integer := 1; -- Ethernet DSU constant CFG_DSU_ETH : integer := 1 + 0 + 0; constant CFG_ETH_BUF : integer := 2; constant CFG_ETH_IPM : integer := 16#C0A8#; constant CFG_ETH_IPL : integer := 16#0058#; constant CFG_ETH_ENM : integer := 16#020000#; constant CFG_ETH_ENL : integer := 16#000012#; -- LEON2 memory controller constant CFG_MCTRL_LEON2 : integer := 1; constant CFG_MCTRL_RAM8BIT : integer := 0; constant CFG_MCTRL_RAM16BIT : integer := 1; constant CFG_MCTRL_5CS : integer := 0; constant CFG_MCTRL_SDEN : integer := 0; constant CFG_MCTRL_SEPBUS : integer := 0; constant CFG_MCTRL_INVCLK : integer := 0; constant CFG_MCTRL_SD64 : integer := 0; constant CFG_MCTRL_PAGE : integer := 0 + 0; -- SSRAM controller constant CFG_SSCTRL : integer := 0; constant CFG_SSCTRLP16 : integer := 0; -- DDR controller constant CFG_DDR2SP : integer := 1; constant CFG_DDR2SP_INIT : integer := 1; constant CFG_DDR2SP_FREQ : integer := (200); constant CFG_DDR2SP_TRFC : integer := (130); constant CFG_DDR2SP_DATAWIDTH : integer := (64); constant CFG_DDR2SP_FTEN : integer := 0; constant CFG_DDR2SP_FTWIDTH : integer := 0; constant CFG_DDR2SP_COL : integer := (10); constant CFG_DDR2SP_SIZE : integer := (256); constant CFG_DDR2SP_DELAY0 : integer := (0); constant CFG_DDR2SP_DELAY1 : integer := (0); constant CFG_DDR2SP_DELAY2 : integer := (0); constant CFG_DDR2SP_DELAY3 : integer := (0); constant CFG_DDR2SP_DELAY4 : integer := (0); constant CFG_DDR2SP_DELAY5 : integer := (0); constant CFG_DDR2SP_DELAY6 : integer := (0); constant CFG_DDR2SP_DELAY7 : integer := (0); constant CFG_DDR2SP_NOSYNC : integer := 0; -- AHB ROM constant CFG_AHBROMEN : integer := 0; constant CFG_AHBROPIP : integer := 0; constant CFG_AHBRODDR : integer := 16#000#; constant CFG_ROMADDR : integer := 16#000#; constant CFG_ROMMASK : integer := 16#E00# + 16#000#; -- AHB RAM constant CFG_AHBRAMEN : integer := 0; constant CFG_AHBRSZ : integer := 1; constant CFG_AHBRADDR : integer := 16#A00#; constant CFG_AHBRPIPE : integer := 0; -- Gaisler Ethernet core constant CFG_GRETH : integer := 1; constant CFG_GRETH1G : integer := 0; constant CFG_ETH_FIFO : integer := 16; -- UART 1 constant CFG_UART1_ENABLE : integer := 1; constant CFG_UART1_FIFO : integer := 8; -- LEON3 interrupt controller constant CFG_IRQ3_ENABLE : integer := 1; constant CFG_IRQ3_NSEC : integer := 0; -- Modular timer constant CFG_GPT_ENABLE : integer := 1; constant CFG_GPT_NTIM : integer := (2); constant CFG_GPT_SW : integer := (8); constant CFG_GPT_TW : integer := (32); constant CFG_GPT_IRQ : integer := (8); constant CFG_GPT_SEPIRQ : integer := 1; constant CFG_GPT_WDOGEN : integer := 0; constant CFG_GPT_WDOG : integer := 16#0#; -- GPIO port constant CFG_GRGPIO_ENABLE : integer := 1; constant CFG_GRGPIO_IMASK : integer := 16#6#; constant CFG_GRGPIO_WIDTH : integer := (3); -- GRLIB debugging constant CFG_DUART : integer := 0; end;

gpl-2.0

82a354c034b7a1272106bb76758cda6f

0.645919

3.550921

false

freecores/usb_fpga_1_11

examples/usb-fpga-2.16/2.16b/ucecho/fpga-vivado/ucecho.vhd

4

738

library ieee; use IEEE.std_logic_1164.all; use IEEE.numeric_std.all; Library UNISIM; use UNISIM.vcomponents.all; entity ucecho is port( pd : in unsigned(7 downto 0); pb : out unsigned(7 downto 0); fxclk_in : in std_logic ); end ucecho; architecture RTL of ucecho is --signal declaration signal pb_buf : unsigned(7 downto 0); signal clk : std_logic; begin clk_buf : IBUFG port map ( I => fxclk_in, O => clk ); dpUCECHO: process(CLK) begin if CLK' event and CLK = '1' then if ( pd >= 97 ) and ( pd <= 122) then pb_buf <= pd - 32; else pb_buf <= pd; end if; pb <= pb_buf; end if; end process dpUCECHO; end RTL;

gpl-3.0

9bbe0a9a7f3b9c80a6a6ab1b5e6491ec

0.566396

3.167382

false

marco-c/leon-nexys2

grlib-gpl-1.3.4-b4140/lib/techmap/maps/leon4_net.vhd

1

22,827

------------------------------------------------------------------------------ -- This file is a part of the GRLIB VHDL IP LIBRARY -- Copyright (C) 2003 - 2008, Gaisler Research -- Copyright (C) 2008 - 2013, Aeroflex Gaisler -- -- This program is free software; you can redistribute it and/or modify -- it under the terms of the GNU General Public License as published by -- the Free Software Foundation; either version 2 of the License, or -- (at your option) any later version. -- -- This program is distributed in the hope that it will be useful, -- but WITHOUT ANY WARRANTY; without even the implied warranty of -- MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the -- GNU General Public License for more details. -- -- You should have received a copy of the GNU General Public License -- along with this program; if not, write to the Free Software -- Foundation, Inc., 59 Temple Place, Suite 330, Boston, MA 02111-1307 USA ------------------------------------------------------------------------------ library ieee; use ieee.std_logic_1164.all; library grlib; use grlib.amba.all; use grlib.stdlib.all; use grlib.devices.all; use work.gencomp.all; entity leon4_net is generic ( hindex : integer := 0; fabtech : integer range 0 to NTECH := DEFFABTECH; memtech : integer range 0 to NTECH := DEFMEMTECH; nwindows : integer range 2 to 32 := 8; dsu : integer range 0 to 1 := 0; fpu : integer range 0 to 31 := 0; v8 : integer range 0 to 63 := 0; cp : integer range 0 to 1 := 0; mac : integer range 0 to 1 := 0; pclow : integer range 0 to 2 := 2; notag : integer range 0 to 1 := 0; nwp : integer range 0 to 4 := 0; icen : integer range 0 to 1 := 0; irepl : integer range 0 to 2 := 2; isets : integer range 1 to 4 := 1; ilinesize : integer range 4 to 8 := 4; isetsize : integer range 1 to 256 := 1; isetlock : integer range 0 to 1 := 0; dcen : integer range 0 to 1 := 0; drepl : integer range 0 to 2 := 2; dsets : integer range 1 to 4 := 1; dlinesize : integer range 4 to 8 := 4; dsetsize : integer range 1 to 256 := 1; dsetlock : integer range 0 to 1 := 0; dsnoop : integer range 0 to 6 := 0; ilram : integer range 0 to 1 := 0; ilramsize : integer range 1 to 512 := 1; ilramstart : integer range 0 to 255 := 16#8e#; dlram : integer range 0 to 1 := 0; dlramsize : integer range 1 to 512 := 1; dlramstart : integer range 0 to 255 := 16#8f#; mmuen : integer range 0 to 1 := 0; itlbnum : integer range 2 to 64 := 8; dtlbnum : integer range 2 to 64 := 8; tlb_type : integer range 0 to 3 := 1; tlb_rep : integer range 0 to 1 := 0; lddel : integer range 1 to 2 := 2; disas : integer range 0 to 2 := 0; tbuf : integer range 0 to 64 := 0; pwd : integer range 0 to 2 := 2; -- power-down svt : integer range 0 to 1 := 1; -- single vector trapping rstaddr : integer := 0; smp : integer range 0 to 31 := 0; -- support SMP systems iuft : integer range 0 to 4 := 0; fpft : integer range 0 to 4 := 0; cmft : integer range 0 to 1 := 0; cached : integer := 0; scantest : integer := 0 ); port ( clk : in std_ulogic; gclk : in std_ulogic; hclken : in std_ulogic; rstn : in std_ulogic; ahbix : in ahb_mst_in_type; ahbox : out ahb_mst_out_type; ahbsix : in ahb_slv_in_type; ahbso : in ahb_slv_out_vector; irqi_irl: in std_logic_vector(3 downto 0); irqi_rst: in std_ulogic; irqi_run: in std_ulogic; irqi_rstvec: in std_logic_vector(31 downto 12); irqi_iact: in std_ulogic; irqi_index: in std_logic_vector(3 downto 0); irqo_intack: out std_ulogic; irqo_irl: out std_logic_vector(3 downto 0); irqo_pwd: out std_ulogic; irqo_fpen: out std_ulogic; irqo_idle: out std_ulogic; dbgi_dsuen: in std_ulogic; -- DSU enable dbgi_denable: in std_ulogic; -- diagnostic register access enable dbgi_dbreak: in std_ulogic; -- debug break-in dbgi_step: in std_ulogic; -- single step dbgi_halt: in std_ulogic; -- halt processor dbgi_reset: in std_ulogic; -- reset processor dbgi_dwrite: in std_ulogic; -- read/write dbgi_daddr: in std_logic_vector(23 downto 2); -- diagnostic address dbgi_ddata: in std_logic_vector(31 downto 0); -- diagnostic data dbgi_btrapa: in std_ulogic; -- break on IU trap dbgi_btrape: in std_ulogic; -- break on IU trap dbgi_berror: in std_ulogic; -- break on IU error mode dbgi_bwatch: in std_ulogic; -- break on IU watchpoint dbgi_bsoft: in std_ulogic; -- break on software breakpoint (TA 1) dbgi_tenable: in std_ulogic; dbgi_timer: in std_logic_vector(30 downto 0); dbgo_data: out std_logic_vector(31 downto 0); dbgo_crdy: out std_ulogic; dbgo_dsu: out std_ulogic; dbgo_dsumode: out std_ulogic; dbgo_error: out std_ulogic; dbgo_halt: out std_ulogic; dbgo_pwd: out std_ulogic; dbgo_idle: out std_ulogic; dbgo_ipend: out std_ulogic; dbgo_icnt: out std_ulogic; dbgo_fcnt : out std_ulogic; dbgo_optype : out std_logic_vector(5 downto 0); -- instruction type dbgo_bpmiss : out std_ulogic; -- branch predict miss dbgo_istat_cmiss: out std_ulogic; dbgo_istat_tmiss: out std_ulogic; dbgo_istat_chold: out std_ulogic; dbgo_istat_mhold: out std_ulogic; dbgo_dstat_cmiss: out std_ulogic; dbgo_dstat_tmiss: out std_ulogic; dbgo_dstat_chold: out std_ulogic; dbgo_dstat_mhold: out std_ulogic; dbgo_wbhold : out std_ulogic; -- write buffer hold dbgo_su : out std_ulogic); end ; architecture rtl of leon4_net is signal disasen : std_ulogic; component leon4_ut90nhbd generic ( hindex : integer := 0; fabtech : integer range 0 to NTECH := DEFFABTECH; memtech : integer range 0 to NTECH := DEFMEMTECH; nwindows : integer range 2 to 32 := 8; dsu : integer range 0 to 1 := 0; fpu : integer range 0 to 31 := 0; v8 : integer range 0 to 63 := 0; cp : integer range 0 to 1 := 0; mac : integer range 0 to 1 := 0; pclow : integer range 0 to 2 := 2; notag : integer range 0 to 1 := 0; nwp : integer range 0 to 4 := 0; icen : integer range 0 to 1 := 0; irepl : integer range 0 to 2 := 2; isets : integer range 1 to 4 := 1; ilinesize : integer range 4 to 8 := 4; isetsize : integer range 1 to 256 := 1; isetlock : integer range 0 to 1 := 0; dcen : integer range 0 to 1 := 0; drepl : integer range 0 to 2 := 2; dsets : integer range 1 to 4 := 1; dlinesize : integer range 4 to 8 := 4; dsetsize : integer range 1 to 256 := 1; dsetlock : integer range 0 to 1 := 0; dsnoop : integer range 0 to 6 := 0; ilram : integer range 0 to 1 := 0; ilramsize : integer range 1 to 512 := 1; ilramstart : integer range 0 to 255 := 16#8e#; dlram : integer range 0 to 1 := 0; dlramsize : integer range 1 to 512 := 1; dlramstart : integer range 0 to 255 := 16#8f#; mmuen : integer range 0 to 1 := 0; itlbnum : integer range 2 to 64 := 8; dtlbnum : integer range 2 to 64 := 8; tlb_type : integer range 0 to 1 := 1; tlb_rep : integer range 0 to 1 := 0; lddel : integer range 1 to 2 := 2; disas : integer range 0 to 1 := 0; tbuf : integer range 0 to 64 := 0; pwd : integer range 0 to 2 := 2; -- power-down svt : integer range 0 to 1 := 1; -- single vector trapping rstaddr : integer := 0; smp : integer range 0 to 31 := 0; -- support SMP systems iuft : integer range 0 to 4 := 0; fpft : integer range 0 to 4 := 0; cmft : integer range 0 to 1 := 0; cached : integer := 0; scantest : integer := 0 ); port ( clk: in std_ulogic; gclk: in std_ulogic; hclken: in std_ulogic; rstn: in std_ulogic; ahbi_hgrant: in std_logic_vector(0 to NAHBMST-1); -- bus grant ahbi_hready: in std_ulogic; -- transfer done ahbi_hresp: in std_logic_vector(1 downto 0); -- response type ahbi_hrdata: in std_logic_vector(127 downto 0); -- read data bus ahbi_hirq: in std_logic_vector(NAHBIRQ-1 downto 0); -- interrupt result bus ahbi_testen: in std_ulogic; ahbi_testrst: in std_ulogic; ahbi_scanen: in std_ulogic; ahbi_testoen: in std_ulogic; ahbo_hbusreq: out std_ulogic; -- bus request ahbo_hlock: out std_ulogic; -- lock request ahbo_htrans: out std_logic_vector(1 downto 0); -- transfer type ahbo_haddr: out std_logic_vector(31 downto 0); -- address bus (byte) ahbo_hwrite: out std_ulogic; -- read/write ahbo_hsize: out std_logic_vector(2 downto 0); -- transfer size ahbo_hburst: out std_logic_vector(2 downto 0); -- burst type ahbo_hprot: out std_logic_vector(3 downto 0); -- protection control ahbo_hwdata: out std_logic_vector(127 downto 0); -- write data bus ahbo_hirq: out std_logic_vector(NAHBIRQ-1 downto 0); -- interrupt bus ahbsi_hsel: in std_logic_vector(0 to NAHBSLV-1); -- slave select ahbsi_haddr: in std_logic_vector(31 downto 0); -- address bus (byte) ahbsi_hwrite: in std_ulogic; -- read/write ahbsi_htrans: in std_logic_vector(1 downto 0); -- transfer type ahbsi_hsize: in std_logic_vector(2 downto 0); -- transfer size ahbsi_hburst: in std_logic_vector(2 downto 0); -- burst type ahbsi_hwdata: in std_logic_vector(127 downto 0); -- write data bus ahbsi_hprot: in std_logic_vector(3 downto 0); -- protection control ahbsi_hready: in std_ulogic; -- transfer done ahbsi_hmaster: in std_logic_vector(3 downto 0); -- current master ahbsi_hmastlock: in std_ulogic; -- locked access ahbsi_hmbsel: in std_logic_vector(0 to NAHBAMR-1); -- memory bank select ahbsi_hirq: in std_logic_vector(NAHBIRQ-1 downto 0); -- interrupt result bus irqi_irl: in std_logic_vector(3 downto 0); irqi_rst: in std_ulogic; irqi_run: in std_ulogic; irqi_rstvec: in std_logic_vector(31 downto 12); irqi_iact: in std_ulogic; irqi_index: in std_logic_vector(3 downto 0); irqo_intack: out std_ulogic; irqo_irl: out std_logic_vector(3 downto 0); irqo_pwd: out std_ulogic; irqo_fpen: out std_ulogic; irqo_idle: out std_ulogic; dbgi_dsuen: in std_ulogic; -- DSU enable dbgi_denable: in std_ulogic; -- diagnostic register access enable dbgi_dbreak: in std_ulogic; -- debug break-in dbgi_step: in std_ulogic; -- single step dbgi_halt: in std_ulogic; -- halt processor dbgi_reset: in std_ulogic; -- reset processor dbgi_dwrite: in std_ulogic; -- read/write dbgi_daddr: in std_logic_vector(23 downto 2); -- diagnostic address dbgi_ddata: in std_logic_vector(31 downto 0); -- diagnostic data dbgi_btrapa: in std_ulogic; -- break on IU trap dbgi_btrape: in std_ulogic; -- break on IU trap dbgi_berror: in std_ulogic; -- break on IU error mode dbgi_bwatch: in std_ulogic; -- break on IU watchpoint dbgi_bsoft: in std_ulogic; -- break on software breakpoint (TA 1) dbgi_tenable: in std_ulogic; dbgi_timer: in std_logic_vector(30 downto 0); dbgo_data: out std_logic_vector(31 downto 0); dbgo_crdy: out std_ulogic; dbgo_dsu: out std_ulogic; dbgo_dsumode: out std_ulogic; dbgo_error: out std_ulogic; dbgo_halt: out std_ulogic; dbgo_pwd: out std_ulogic; dbgo_idle: out std_ulogic; dbgo_ipend: out std_ulogic; dbgo_icnt: out std_ulogic; dbgo_fcnt : out std_ulogic; dbgo_optype : out std_logic_vector(5 downto 0); -- instruction type dbgo_bpmiss : out std_ulogic; -- branch predict miss dbgo_istat_cmiss: out std_ulogic; dbgo_istat_tmiss: out std_ulogic; dbgo_istat_chold: out std_ulogic; dbgo_istat_mhold: out std_ulogic; dbgo_dstat_cmiss: out std_ulogic; dbgo_dstat_tmiss: out std_ulogic; dbgo_dstat_chold: out std_ulogic; dbgo_dstat_mhold: out std_ulogic; dbgo_wbhold : out std_ulogic; -- write buffer hold dbgo_su : out std_ulogic; disasen : in std_ulogic); end component; signal ahbi_hgrant: std_logic_vector(0 to NAHBMST-1); signal ahbi_hready: std_ulogic; signal ahbi_hresp: std_logic_vector(1 downto 0); signal ahbi_hrdata: std_logic_vector(127 downto 0); signal ahbi_hirq: std_logic_vector(NAHBIRQ-1 downto 0); signal ahbi_testen: std_ulogic; signal ahbi_testrst: std_ulogic; signal ahbi_scanen: std_ulogic; signal ahbi_testoen: std_ulogic; signal ahbo_hbusreq: std_ulogic; signal ahbo_hlock: std_ulogic; signal ahbo_htrans: std_logic_vector(1 downto 0); signal ahbo_haddr: std_logic_vector(31 downto 0); signal ahbo_hwrite: std_ulogic; signal ahbo_hsize: std_logic_vector(2 downto 0); signal ahbo_hburst: std_logic_vector(2 downto 0); signal ahbo_hprot: std_logic_vector(3 downto 0); signal ahbo_hwdata: std_logic_vector(127 downto 0); signal ahbo_hirq: std_logic_vector(NAHBIRQ-1 downto 0); signal ahbsi_hsel: std_logic_vector(0 to NAHBSLV-1); signal ahbsi_haddr: std_logic_vector(31 downto 0); signal ahbsi_hwrite: std_ulogic; signal ahbsi_htrans: std_logic_vector(1 downto 0); signal ahbsi_hsize: std_logic_vector(2 downto 0); signal ahbsi_hburst: std_logic_vector(2 downto 0); signal ahbsi_hwdata: std_logic_vector(127 downto 0); signal ahbsi_hprot: std_logic_vector(3 downto 0); signal ahbsi_hready: std_ulogic; signal ahbsi_hmaster: std_logic_vector(3 downto 0); signal ahbsi_hmastlock: std_ulogic; signal ahbsi_hmbsel: std_logic_vector(0 to NAHBAMR-1); signal ahbsi_hirq: std_logic_vector(NAHBIRQ-1 downto 0); constant hconfig: ahb_config_type := ( 0 => ahb_device_reg ( VENDOR_GAISLER, GAISLER_LEON4, 0, 0, 0), others => zero32); begin disasen <= '1' when disas /= 0 else '0'; -- Plug&Play information ahbox.hconfig <= hconfig; ahbox.hindex <= hindex; ut09 : if fabtech = ut90 generate wrp: leon4_ut90nhbd generic map (fpu => fpu, v8 => v8, mmuen => mmuen, isets => isets, isetsize => isetsize, smp => smp) port map( clk => clk, gclk => gclk, hclken => hclken, rstn => rstn, ahbi_hgrant => ahbi_hgrant, ahbi_hready => ahbi_hready, ahbi_hresp => ahbi_hresp, ahbi_hrdata => ahbi_hrdata, ahbi_hirq => ahbi_hirq, ahbi_testen => ahbi_testen, ahbi_testrst => ahbi_testrst, ahbi_scanen => ahbi_scanen, ahbi_testoen => ahbi_testoen, ahbo_hbusreq => ahbo_hbusreq, ahbo_hlock => ahbo_hlock, ahbo_htrans => ahbo_htrans, ahbo_haddr => ahbo_haddr, ahbo_hwrite => ahbo_hwrite, ahbo_hsize => ahbo_hsize, ahbo_hburst => ahbo_hburst, ahbo_hprot => ahbo_hprot, ahbo_hwdata => ahbo_hwdata, ahbo_hirq => ahbo_hirq, ahbsi_hsel => ahbsi_hsel, ahbsi_haddr => ahbsi_haddr, ahbsi_hwrite => ahbsi_hwrite, ahbsi_htrans => ahbsi_htrans, ahbsi_hsize => ahbsi_hsize, ahbsi_hburst => ahbsi_hburst, ahbsi_hwdata => ahbsi_hwdata, ahbsi_hprot => ahbsi_hprot, ahbsi_hready => ahbsi_hready, ahbsi_hmaster => ahbsi_hmaster, ahbsi_hmastlock => ahbsi_hmastlock, ahbsi_hmbsel => ahbsi_hmbsel, ahbsi_hirq => ahbsi_hirq, irqi_irl => irqi_irl, irqi_rst => irqi_rst, irqi_run => irqi_run, irqi_rstvec => irqi_rstvec, irqi_iact => irqi_iact, irqi_index => irqi_index, irqo_intack => irqo_intack, irqo_irl => irqo_irl, irqo_pwd => irqo_pwd, irqo_fpen => irqo_fpen, irqo_idle => irqo_idle, dbgi_dsuen => dbgi_dsuen, dbgi_denable => dbgi_denable, dbgi_dbreak => dbgi_dbreak, dbgi_step => dbgi_step, dbgi_halt => dbgi_halt, dbgi_reset => dbgi_reset, dbgi_dwrite => dbgi_dwrite, dbgi_daddr => dbgi_daddr, dbgi_ddata => dbgi_ddata, dbgi_btrapa => dbgi_btrapa, dbgi_btrape => dbgi_btrape, dbgi_berror => dbgi_berror, dbgi_bwatch => dbgi_bwatch, dbgi_bsoft => dbgi_bsoft, dbgi_tenable => dbgi_tenable, dbgi_timer => dbgi_timer, dbgo_data => dbgo_data, dbgo_crdy => dbgo_crdy, dbgo_dsu => dbgo_dsu, dbgo_dsumode => dbgo_dsumode, dbgo_error => dbgo_error, dbgo_halt => dbgo_halt, dbgo_pwd => dbgo_pwd, dbgo_idle => dbgo_idle, dbgo_ipend => dbgo_ipend, dbgo_icnt => dbgo_icnt, dbgo_fcnt => dbgo_fcnt, dbgo_optype => dbgo_optype, dbgo_bpmiss => dbgo_bpmiss, dbgo_istat_cmiss => dbgo_istat_cmiss, dbgo_istat_tmiss => dbgo_istat_tmiss, dbgo_istat_chold => dbgo_istat_chold, dbgo_istat_mhold => dbgo_istat_mhold, dbgo_dstat_cmiss => dbgo_dstat_cmiss, dbgo_dstat_tmiss => dbgo_dstat_tmiss, dbgo_dstat_chold => dbgo_dstat_chold, dbgo_dstat_mhold => dbgo_dstat_mhold, dbgo_wbhold => dbgo_wbhold, dbgo_su => dbgo_su, disasen => disasen); end generate; ahbi_hgrant(0) <= ahbix.hgrant(hindex); ahbi_hgrant(1 to NAHBMST-1) <= (others => '0'); ahbi_hready <= ahbix.hready; ahbi_hresp <= ahbix.hresp; ahbi_hrdata(127 mod AHBDW downto 0) <= ahbix.hrdata(127 mod AHBDW downto 0); ahbi_hirq <= ahbix.hirq; ahbi_testen <= ahbix.testen; ahbi_testrst <= ahbix.testrst; ahbi_scanen <= ahbix.scanen; ahbi_testoen <= ahbix.testoen; ahbox.hbusreq <= ahbo_hbusreq; ahbox.hlock <= ahbo_hlock; ahbox.htrans <= ahbo_htrans; ahbox.haddr <= ahbo_haddr; ahbox.hwrite <= ahbo_hwrite; ahbox.hsize <= ahbo_hsize(2 downto 0); ahbox.hburst <= "00" & ahbo_hburst(0); ahbox.hprot <= ahbo_hprot; ahbox.hwdata(127 mod AHBDW downto 0) <= ahbo_hwdata(127 mod AHBDW downto 0); ahbox.hirq <= (others => '0'); --ahbo_hirq; ahbsi_hsel <= ahbsix.hsel; ahbsi_haddr <= ahbsix.haddr; ahbsi_hwrite <= ahbsix.hwrite; ahbsi_htrans <= ahbsix.htrans; ahbsi_hsize <= ahbsix.hsize; ahbsi_hburst <= ahbsix.hburst; ahbsi_hwdata(127 mod AHBDW downto 0) <= ahbsix.hwdata(127 mod AHBDW downto 0); ahbsi_hprot <= ahbsix.hprot; ahbsi_hready <= ahbsix.hready; ahbsi_hmaster <= ahbsix.hmaster; ahbsi_hmastlock <= ahbsix.hmastlock; ahbsi_hmbsel <= ahbsix.hmbsel; ahbsi_hirq <= ahbsix.hirq; -- pragma translate_off assert NAHBSLV=16 report "LEON3FT netlist: Only NAHBSLV=16 supported by wrapper" severity Failure; -- pragma translate_on end architecture;

gpl-2.0

2c0572cc3831a9777e4ece175637f1c8

0.51093

3.878845

false

marco-c/leon-nexys2

grlib-gpl-1.3.4-b4140/lib/gaisler/memctrl/memctrl.vhd

1

19,714

------------------------------------------------------------------------------ -- This file is a part of the GRLIB VHDL IP LIBRARY -- Copyright (C) 2003 - 2008, Gaisler Research -- Copyright (C) 2008 - 2013, Aeroflex Gaisler -- -- This program is free software; you can redistribute it and/or modify -- it under the terms of the GNU General Public License as published by -- the Free Software Foundation; either version 2 of the License, or -- (at your option) any later version. -- -- This program is distributed in the hope that it will be useful, -- but WITHOUT ANY WARRANTY; without even the implied warranty of -- MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the -- GNU General Public License for more details. -- -- You should have received a copy of the GNU General Public License -- along with this program; if not, write to the Free Software -- Foundation, Inc., 59 Temple Place, Suite 330, Boston, MA 02111-1307 USA ----------------------------------------------------------------------------- -- Entity: memctrl -- File: memctrl.vhd -- Author: Jiri Gaisler - Gaisler Research -- Description: Memory controller package ------------------------------------------------------------------------------ library ieee; use ieee.std_logic_1164.all; library grlib; use grlib.amba.all; use grlib.stdlib.log2; library techmap; use techmap.gencomp.all; package memctrl is type memory_in_type is record data : std_logic_vector(31 downto 0); -- Data bus address brdyn : std_logic; bexcn : std_logic; writen : std_logic; wrn : std_logic_vector(3 downto 0); bwidth : std_logic_vector(1 downto 0); sd : std_logic_vector(63 downto 0); cb : std_logic_vector(15 downto 0); scb : std_logic_vector(15 downto 0); edac : std_logic; end record; constant memory_in_none : memory_in_type := ((others => '0'), '0', '0', '0', (others => '0'), (others => '0'), (others => '0'), (others => '0'), (others => '0'), '0'); type memory_out_type is record address : std_logic_vector(31 downto 0); data : std_logic_vector(31 downto 0); sddata : std_logic_vector(63 downto 0); ramsn : std_logic_vector(7 downto 0); ramoen : std_logic_vector(7 downto 0); ramn : std_ulogic; romn : std_ulogic; mben : std_logic_vector(3 downto 0); iosn : std_logic; romsn : std_logic_vector(7 downto 0); oen : std_logic; writen : std_logic; wrn : std_logic_vector(3 downto 0); bdrive : std_logic_vector(3 downto 0); vbdrive : std_logic_vector(31 downto 0); --vector bus drive svbdrive : std_logic_vector(63 downto 0); --vector bus drive sdram read : std_logic; sa : std_logic_vector(14 downto 0); cb : std_logic_vector(15 downto 0); scb : std_logic_vector(15 downto 0); vcdrive : std_logic_vector(15 downto 0); --vector bus drive cb svcdrive : std_logic_vector(15 downto 0); --vector bus drive cb sdram ce : std_ulogic; sdram_en : std_ulogic; -- SDRAM enabled rs_edac_en : std_ulogic; -- Reed-Solomon enabled end record; constant memory_out_none : memory_out_type := ((others => '0'), (others => '0'), (others => '0'), (others => '1'), (others => '1'), '1', '1', (others => '1'), '1', (others => '1'), '1', '1', (others => '1'), (others => '1'), (others => '1'), (others => '1'), '0', (others => '0'), (others => '1'), (others => '1'), (others => '1'), (others => '1'), '0', '0', '0'); type sdctrl_in_type is record wprot : std_ulogic; data : std_logic_vector (127 downto 0); -- data in cb : std_logic_vector(63 downto 0); regrdata : std_logic_vector(63 downto 0); -- PHY-specific reg in datavalid : std_logic; -- Data-valid signal end record; constant sdctrl_in_none : sdctrl_in_type := ('0', (others => '0'), (others => '0'), (others => '0'), '0'); type sdctrl_out_type is record sdcke : std_logic_vector ( 1 downto 0); -- clk en sdcsn : std_logic_vector ( 1 downto 0); -- chip sel xsdcsn : std_logic_vector ( 7 downto 0); -- ext. chip sel sdwen : std_ulogic; -- write en rasn : std_ulogic; -- row addr stb casn : std_ulogic; -- col addr stb dqm : std_logic_vector ( 15 downto 0); -- data i/o mask bdrive : std_ulogic; -- bus drive qdrive : std_ulogic; -- bus drive nbdrive : std_ulogic; -- bdrive 1 cycle early vbdrive : std_logic_vector(63 downto 0); -- vector bus drive address : std_logic_vector (16 downto 2); -- address out data : std_logic_vector (127 downto 0); -- data out cb : std_logic_vector(63 downto 0); ce : std_ulogic; ba : std_logic_vector (2 downto 0); -- bank address sdck : std_logic_vector(2 downto 0); moben : std_logic; -- Mobile support cal_en : std_logic_vector(7 downto 0); -- enable delay calibration cal_inc : std_logic_vector(7 downto 0); -- inc/dec delay cal_pll : std_logic_vector(1 downto 0); -- (enable,inc/dec) pll phase cal_rst : std_logic; -- calibration reset odt : std_logic_vector(1 downto 0); -- In Die Termination conf : std_logic_vector(63 downto 0); oct : std_logic; -- On Chip Termination vcbdrive : std_logic_vector(31 downto 0); -- cb vector bus drive dqs_gate : std_logic; cbdqm : std_logic_vector(7 downto 0); cbcal_en : std_logic_vector(3 downto 0); cbcal_inc : std_logic_vector(3 downto 0); read_pend : std_logic_vector(7 downto 0); -- Read pending within 7...0 -- cycles (not including phy delays) -- PHY-specific register interface regwdata : std_logic_vector(63 downto 0); regwrite : std_logic_vector(1 downto 0); end record; constant sdctrl_out_none : sdctrl_out_type := ((others => '0'), (others => '0'), (others => '0'), '0', '0', '0', (others => '0'), '0', '0', '0', (others => '0'), (others => '0'), (others => '0'), (others => '0'), '0', (others => '0'), (others => '0'), '0', (others => '0'), (others => '0'), (others => '0'), '0', (others => '0'), (others => '0'), '0', (others => '0'), '0', (others => '0'), (others => '0'), (others => '0'), "00000000", (others => '0'), "00"); type sdram_out_type is record sdcke : std_logic_vector ( 1 downto 0); -- clk en sdcsn : std_logic_vector ( 1 downto 0); -- chip sel sdwen : std_ulogic; -- write en rasn : std_ulogic; -- row addr stb casn : std_ulogic; -- col addr stb dqm : std_logic_vector ( 7 downto 0); -- data i/o mask end record; type zbtssram_out_type is record cen : std_ulogic; oen : std_ulogic; wen : std_ulogic; advld : std_ulogic; addr : std_logic_vector(22 downto 0); bwn : std_logic_vector(15 downto 0); data : std_logic_vector(127 downto 0); dqoen : std_logic_vector(127 downto 0); zz : std_ulogic; shutdown : std_ulogic; end record; constant zbtssram_out_none : zbtssram_out_type := ( '1','1','1','1',(others => '0'),(others => '1'),(others => '0'),(others => '1'),'0','0'); type zbtssram_in_type is record data : std_logic_vector(127 downto 0); mbe : std_logic_vector(7 downto 0); end record; constant zbtssram_in_none : zbtssram_in_type := ( data => (others => '0'), mbe => (others => '0') ); component sdctrl generic ( hindex : integer := 0; haddr : integer := 0; hmask : integer := 16#f00#; ioaddr : integer := 16#000#; iomask : integer := 16#fff#; wprot : integer := 0; invclk : integer := 0; fast : integer := 0; pwron : integer := 0; sdbits : integer := 32; oepol : integer := 0; pageburst : integer := 0; mobile : integer := 0 ); port ( rst : in std_ulogic; clk : in std_ulogic; ahbsi : in ahb_slv_in_type; ahbso : out ahb_slv_out_type; sdi : in sdctrl_in_type; sdo : out sdctrl_out_type ); end component; component sdctrl64 generic ( hindex : integer := 0; haddr : integer := 0; hmask : integer := 16#f00#; ioaddr : integer := 16#000#; iomask : integer := 16#fff#; wprot : integer := 0; invclk : integer := 0; fast : integer := 0; pwron : integer := 0; oepol : integer := 0; pageburst : integer := 0; mobile : integer := 0 ); port ( rst : in std_ulogic; clk : in std_ulogic; ahbsi : in ahb_slv_in_type; ahbso : out ahb_slv_out_type; sdi : in sdctrl_in_type; sdo : out sdctrl_out_type ); end component; component ftsdctrl is generic ( hindex : integer := 0; haddr : integer := 0; hmask : integer := 16#f00#; ioaddr : integer := 16#000#; iomask : integer := 16#fff#; wprot : integer := 0; invclk : integer := 0; fast : integer := 0; pwron : integer := 0; sdbits : integer := 32; edacen : integer := 1; errcnt : integer := 0; cntbits : integer range 1 to 8 := 1; oepol : integer := 0; pageburst : integer := 0 ); port ( rst : in std_ulogic; clk : in std_ulogic; ahbsi : in ahb_slv_in_type; ahbso : out ahb_slv_out_type; sdi : in sdctrl_in_type; sdo : out sdctrl_out_type ); end component; component ftsdctrl64 generic ( hindex : integer := 0; haddr : integer := 0; hmask : integer := 16#f00#; ioaddr : integer := 16#000#; iomask : integer := 16#fff#; wprot : integer := 0; invclk : integer := 0; fast : integer := 0; pwron : integer := 0; oepol : integer := 0; pageburst : integer := 0; mobile : integer := 0; edac : integer := 0 ); port ( rst : in std_ulogic; clk : in std_ulogic; ahbsi : in ahb_slv_in_type; ahbso : out ahb_slv_out_type; sdi : in sdctrl_in_type; sdo : out sdctrl_out_type ); end component; component srctrl generic ( hindex : integer := 0; romaddr : integer := 0; rommask : integer := 16#ff0#; ramaddr : integer := 16#400#; rammask : integer := 16#ff0#; ioaddr : integer := 16#200#; iomask : integer := 16#ff0#; ramws : integer := 0; romws : integer := 2; iows : integer := 2; rmw : integer := 0; prom8en : integer := 0; oepol : integer := 0; srbanks : integer range 1 to 5 := 1; banksz : integer range 0 to 13 := 13; romasel : integer range 0 to 28 := 19 ); port ( rst : in std_ulogic; clk : in std_ulogic; ahbsi : in ahb_slv_in_type; ahbso : out ahb_slv_out_type; sri : in memory_in_type; sro : out memory_out_type; sdo : out sdctrl_out_type ); end component; component ftsrctrl is generic ( hindex : integer := 0; romaddr : integer := 0; rommask : integer := 16#ff0#; ramaddr : integer := 16#400#; rammask : integer := 16#ff0#; ioaddr : integer := 16#200#; iomask : integer := 16#ff0#; ramws : integer := 0; romws : integer := 2; iows : integer := 2; rmw : integer := 0; srbanks : integer range 1 to 8 := 1; banksz : integer range 0 to 15 := 15; rombanks : integer range 1 to 8 := 1; rombanksz : integer range 0 to 15 := 15; rombankszdef : integer range 0 to 15 := 15; pindex : integer := 0; paddr : integer := 0; pmask : integer := 16#fff#; edacen : integer range 0 to 1 := 1; errcnt : integer range 0 to 1 := 0; cntbits : integer range 1 to 8 := 1; wsreg : integer := 0; oepol : integer := 0; prom8en : integer := 0; netlist : integer := 0; tech : integer := 0 ); port ( rst : in std_ulogic; clk : in std_ulogic; ahbsi : in ahb_slv_in_type; ahbso : out ahb_slv_out_type; apbi : in apb_slv_in_type; apbo : out apb_slv_out_type; sri : in memory_in_type; sro : out memory_out_type; sdo : out sdctrl_out_type ); end component; type sdram_in_type is record haddr : std_logic_vector(31 downto 0); -- memory address rhaddr : std_logic_vector(31 downto 0); -- latched memory address hready : std_ulogic; hsize : std_logic_vector(1 downto 0); hsel : std_ulogic; hwrite : std_ulogic; htrans : std_logic_vector(1 downto 0); rhtrans : std_logic_vector(1 downto 0); nhtrans : std_logic_vector(1 downto 0); idle : std_ulogic; enable : std_ulogic; error : std_ulogic; merror : std_ulogic; brmw : std_ulogic; edac : std_ulogic; srdis : std_logic; end record; type sdram_mctrl_out_type is record address : std_logic_vector(16 downto 2); busy : std_ulogic; aload : std_ulogic; bdrive : std_ulogic; hready : std_ulogic; hsel : std_ulogic; bsel : std_ulogic; hresp : std_logic_vector (1 downto 0); vhready : std_ulogic; prdata : std_logic_vector (31 downto 0); end record; type wprot_out_type is record wprothit : std_ulogic; end record; component sdmctrl generic ( pindex : integer := 0; invclk : integer := 0; fast : integer := 0; wprot : integer := 0; sdbits : integer := 32; pageburst : integer := 0; mobile : integer := 0 ); port ( rst : in std_ulogic; clk : in std_ulogic; sdi : in sdram_in_type; sdo : out sdram_out_type; apbi : in apb_slv_in_type; wpo : in wprot_out_type; sdmo : out sdram_mctrl_out_type ); end component; component ftsdmctrl generic ( pindex : integer := 0; invclk : integer := 0; fast : integer := 0; wprot : integer := 0; sdbits : integer := 32; syncrst : integer := 0; pageburst : integer := 0 ); port ( rst : in std_ulogic; clk : in std_ulogic; sdi : in sdram_in_type; sdo : out sdram_out_type; apbi : in apb_slv_in_type; wpo : in wprot_out_type; sdmo : out sdram_mctrl_out_type ); end component; component ftmctrl generic ( hindex : integer := 0; pindex : integer := 0; romaddr : integer := 16#000#; rommask : integer := 16#E00#; ioaddr : integer := 16#200#; iomask : integer := 16#E00#; ramaddr : integer := 16#400#; rammask : integer := 16#C00#; paddr : integer := 0; pmask : integer := 16#fff#; wprot : integer := 0; invclk : integer := 0; fast : integer := 0; romasel : integer := 28; sdrasel : integer := 29; srbanks : integer := 4; ram8 : integer := 0; ram16 : integer := 0; sden : integer := 0; sepbus : integer := 0; sdbits : integer := 32; sdlsb : integer := 2; -- set to 12 for the GE-HPE board oepol : integer := 0; edac : integer := 0; syncrst : integer := 0; pageburst : integer := 0; scantest : integer := 0; writefb : integer := 0; netlist : integer := 0; tech : integer := 0; rahold : integer := 0; wsshift : integer := 0 ); port ( rst : in std_ulogic; clk : in std_ulogic; memi : in memory_in_type; memo : out memory_out_type; ahbsi : in ahb_slv_in_type; ahbso : out ahb_slv_out_type; apbi : in apb_slv_in_type; apbo : out apb_slv_out_type; wpo : in wprot_out_type; sdo : out sdram_out_type ); end component; component ssrctrl generic ( hindex : integer := 0; pindex : integer := 0; romaddr : integer := 0; rommask : integer := 16#ff0#; ramaddr : integer := 16#400#; rammask : integer := 16#ff0#; ioaddr : integer := 16#200#; iomask : integer := 16#ff0#; paddr : integer := 0; pmask : integer := 16#fff#; oepol : integer := 0; bus16 : integer := 0 ); port ( rst : in std_ulogic; clk : in std_ulogic; ahbsi : in ahb_slv_in_type; ahbso : out ahb_slv_out_type; apbi : in apb_slv_in_type; apbo : out apb_slv_out_type; sri : in memory_in_type; sro : out memory_out_type ); end component; component ftsrctrl_v1 generic ( hindex: Integer := 1; romaddr: Integer := 16#000#; rommask: Integer := 16#ff0#; ramaddr: Integer := 16#400#; rammask: Integer := 16#ff0#; ioaddr: Integer := 16#200#; iomask: Integer := 16#ff0#; ramws: Integer := 0; romws: Integer := 0; iows: Integer := 0; rmw: Integer := 1; srbanks: Integer range 1 to 8 := 8; banksz: Integer range 0 to 13 := 0; rombanks: Integer range 1 to 8 := 8; rombanksz: Integer range 0 to 13 := 0; rombankszdef: Integer range 0 to 13 := 6; romasel: Integer range 0 to 28 := 0; pindex: Integer := 0; paddr: Integer := 16#000#; pmask: Integer := 16#fff#; edacen: Integer range 0 to 1 := 1; errcnt: Integer range 0 to 1 := 0; cntbits: Integer range 1 to 8 := 1; wsreg: Integer := 1; oepol: Integer := 0); port ( rst : in std_ulogic; clk : in std_ulogic; ahbsi : in ahb_slv_in_type; ahbso : out ahb_slv_out_type; apbi : in apb_slv_in_type; apbo : out apb_slv_out_type; sri : in memory_in_type; sro : out memory_out_type; sdo : out sdctrl_out_type ); end component; component ftsrctrl8 is generic ( hindex : integer := 0; ramaddr : integer := 16#400#; rammask : integer := 16#ff0#; ioaddr : integer := 16#200#; iomask : integer := 16#ff0#; ramws : integer := 0; iows : integer := 2; srbanks : integer range 1 to 8 := 1; banksz : integer range 0 to 15 := 15; pindex : integer := 0; paddr : integer := 0; pmask : integer := 16#fff#; edacen : integer range 0 to 1 := 1; errcnt : integer range 0 to 1 := 1; cntbits : integer range 1 to 8 := 1; wsreg : integer := 0; oepol : integer := 0 ); port ( rst : in std_ulogic; clk : in std_ulogic; ahbsi : in ahb_slv_in_type; ahbso : out ahb_slv_out_type; apbi : in apb_slv_in_type; apbo : out apb_slv_out_type; sri : in memory_in_type; sro : out memory_out_type ); end component; end;

gpl-2.0

8afada040e4673d6eacc2b645b4c65bf

0.516232

3.476896

false

marco-c/leon-nexys2

grlib-gpl-1.3.4-b4140/designs/leon3-altera-de2-ep2c35/clkgen_de2.vhd

1

3,543

------------------------------------------------------------------------------ -- This file is a part of the GRLIB VHDL IP LIBRARY -- Copyright (C) 2003 - 2008, Gaisler Research -- Copyright (C) 2008 - 2013, Aeroflex Gaisler -- -- This program is free software; you can redistribute it and/or modify -- it under the terms of the GNU General Public License as published by -- the Free Software Foundation; either version 2 of the License, or -- (at your option) any later version. -- -- This program is distributed in the hope that it will be useful, -- but WITHOUT ANY WARRANTY; without even the implied warranty of -- MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the -- GNU General Public License for more details. -- -- You should have received a copy of the GNU General Public License -- along with this program; if not, write to the Free Software -- Foundation, Inc., 59 Temple Place, Suite 330, Boston, MA 02111-1307 USA ------------------------------------------------------------------------------- library ieee; use ieee.std_logic_1164.all; library techmap; use techmap.gencomp.all; library altera_mf; -- pragma translate_off use altera_mf.altpll; -- pragma translate_on entity clkgen_de2 is generic ( clk_mul : integer := 1; clk_div : integer := 1; clk_freq : integer := 25000; clk2xen : integer := 0; sdramen : integer := 0 ); port ( inclk0 : in std_ulogic; c0 : out std_ulogic; c0_2x : out std_ulogic; e0 : out std_ulogic; locked : out std_ulogic ); end; architecture rtl of clkgen_de2 is component altpll generic ( intended_device_family : string := "Stratix" ; operation_mode : string := "NORMAL" ; compensate_clock : string := "CLK0" ; inclk0_input_frequency : positive; width_clock : positive := 6; clk0_multiply_by : positive := 1; clk0_divide_by : positive := 1; clk1_multiply_by : positive := 1; clk1_divide_by : positive := 1; clk2_multiply_by : positive := 1; clk2_divide_by : positive := 1 ); port ( inclk : in std_logic_vector(1 downto 0); clk : out std_logic_vector(width_clock-1 downto 0); locked : out std_logic ); end component; signal clkout : std_logic_vector (5 downto 0); signal inclk : std_logic_vector (1 downto 0); constant clk_period : integer := 1000000000/clk_freq; constant CLK_MUL2X : integer := clk_mul * 2; begin inclk <= '0' & inclk0; c0 <= clkout(0); c0_2x <= clkout(1); sden : if sdramen = 1 generate altpll0 : altpll generic map ( intended_device_family => "Cyclone II", operation_mode => "ZERO_DELAY_BUFFER", compensate_clock => "CLK2", inclk0_input_frequency => clk_period, clk0_multiply_by => clk_mul, clk0_divide_by => clk_div, clk1_multiply_by => 5, clk1_divide_by => 10, clk2_multiply_by => clk_mul, clk2_divide_by => clk_div) port map (inclk => inclk, clk => clkout, locked => locked); e0 <= clkout(2); end generate; nosd : if sdramen = 0 generate altpll0 : altpll generic map ( intended_device_family => "Cyclone II", operation_mode => "NORMAL", inclk0_input_frequency => clk_period, clk0_multiply_by => clk_mul, clk0_divide_by => clk_div, clk1_multiply_by => 5, clk1_divide_by => 10) port map (inclk => inclk, clk => clkout, locked => locked); e0 <= '0'; end generate; end;

gpl-2.0

a4552d87309f27ee42d3a7ae1fbd753c

0.594694

3.675311

false

mistryalok/Zedboard

learning/training/MSD/s05/project_1/project_1.srcs/sources_1/ipshared/xilinx.com/axi_cdma_v4_1/25515467/hdl/src/vhdl/axi_cdma_pkg.vhd

1

12,302

------------------------------------------------------------------------------- -- axi_cdma_pkg ------------------------------------------------------------------------------- -- -- ************************************************************************* -- -- (c) Copyright 2010-2011 Xilinx, Inc. All rights reserved. -- -- This file contains confidential and proprietary information -- of Xilinx, Inc. and is protected under U.S. and -- international copyright and other intellectual property -- laws. -- -- DISCLAIMER -- This disclaimer is not a license and does not grant any -- rights to the materials distributed herewith. Except as -- otherwise provided in a valid license issued to you by -- Xilinx, and to the maximum extent permitted by applicable -- law: (1) THESE MATERIALS ARE MADE AVAILABLE "AS IS" AND -- WITH ALL FAULTS, AND XILINX HEREBY DISCLAIMS ALL WARRANTIES -- AND CONDITIONS, EXPRESS, IMPLIED, OR STATUTORY, INCLUDING -- BUT NOT LIMITED TO WARRANTIES OF MERCHANTABILITY, NON- -- INFRINGEMENT, OR FITNESS FOR ANY PARTICULAR PURPOSE; and -- (2) Xilinx shall not be liable (whether in contract or tort, -- including negligence, or under any other theory of -- liability) for any loss or damage of any kind or nature -- related to, arising under or in connection with these -- materials, including for any direct, or any indirect, -- special, incidental, or consequential loss or damage -- (including loss of data, profits, goodwill, or any type of -- loss or damage suffered as a result of any action brought -- by a third party) even if such damage or loss was -- reasonably foreseeable or Xilinx had been advised of the -- possibility of the same. -- -- CRITICAL APPLICATIONS -- Xilinx products are not designed or intended to be fail- -- safe, or for use in any application requiring fail-safe -- performance, such as life-support or safety devices or -- systems, Class III medical devices, nuclear facilities, -- applications related to the deployment of airbags, or any -- other applications that could lead to death, personal -- injury, or severe property or environmental damage -- (individually and collectively, "Critical -- Applications"). Customer assumes the sole risk and -- liability of any use of Xilinx products in Critical -- Applications, subject only to applicable laws and -- regulations governing limitations on product liability. -- -- THIS COPYRIGHT NOTICE AND DISCLAIMER MUST BE RETAINED AS -- PART OF THIS FILE AT ALL TIMES. -- -- ************************************************************************* -- ------------------------------------------------------------------------------- -- Filename: axi_cdma_pkg.vhd -- Description: This package contains various constants and functions for -- AXI DMA operations. -- -- VHDL-Standard: VHDL'93 ------------------------------------------------------------------------------- ------------------------------------------------------------------------------- library ieee; use ieee.std_logic_1164.all; use ieee.numeric_std.all; library lib_pkg_v1_0; use lib_pkg_v1_0.lib_pkg.clog2; package axi_cdma_pkg is ------------------------------------------------------------------------------- -- Function declarations ------------------------------------------------------------------------------- -- Find minimum required btt width function required_btt_width1 (dwidth, burst_size, btt_width : integer) return integer; ------------------------------------------------------------------------------- -- Constant Declarations ------------------------------------------------------------------------------- ------------------------------------------------------------------------------- -- AXI Responce Values ------------------------------------------------------------------------------- constant OKAY_RESP : std_logic_vector(1 downto 0) := "00"; constant EXOKAY_RESP : std_logic_vector(1 downto 0) := "01"; constant SLVERR_RESP : std_logic_vector(1 downto 0) := "10"; constant DECERR_RESP : std_logic_vector(1 downto 0) := "11"; ------------------------------------------------------------------------------- -- Misc Constants ------------------------------------------------------------------------------- constant NUM_REG_TOTAL : integer := 18; constant NUM_REG_PER_CHANNEL : integer := 6; constant REG_MSB_ADDR_BIT : integer := clog2(NUM_REG_TOTAL)-1; --constant CMD_BASE_WIDTH : integer := 40; constant CMD_BASE_WIDTH : integer := 104; constant BUFFER_LENGTH_WIDTH : integer := 23; -- Constants Used in Desc Updates constant DESC_STS_TYPE : std_logic := '1'; constant DESC_DATA_TYPE : std_logic := '0'; constant DESC_LAST : std_logic := '1'; constant DESC_NOT_LAST : std_logic := '0'; -- Interrupt Coalescing constant ZERO_THRESHOLD : std_logic_vector(7 downto 0) := (others => '0'); constant ONE_THRESHOLD : std_logic_vector(7 downto 0) := "00000001"; constant ZERO_DELAY : std_logic_vector(7 downto 0) := (others => '0'); constant MTBF_STAGES : integer := 4; ------------------------------------------------------------------------------- -- Register Bit Constants ------------------------------------------------------------------------------- -- DMACR constant DMACR_RESERVED0_BIT : integer := 0; constant DMACR_TAILPEN_BIT : integer := 1; constant DMACR_RESET_BIT : integer := 2; constant DMACR_SGMODE_BIT : integer := 3; constant DMACR_KHREAD_BIT : integer := 4; constant DMACR_KHWRITE_BIT : integer := 5; --constant DMACR_RESERVED4_BIT : integer := 4; --constant DMACR_RESERVED5_BIT : integer := 5; constant DMACR_CYCLIC_BIT : integer := 6; constant DMACR_RESERVED7_BIT : integer := 7; constant DMACR_RESERVED8_BIT : integer := 8; constant DMACR_RESERVED9_BIT : integer := 9; constant DMACR_RESERVED10_BIT : integer := 10; constant DMACR_RESERVED11_BIT : integer := 11; constant DMACR_IOC_IRQEN_BIT : integer := 12; constant DMACR_DLY_IRQEN_BIT : integer := 13; constant DMACR_ERR_IRQEN_BIT : integer := 14; constant DMACR_RESERVED15_BIT : integer := 15; constant DMACR_IRQTHRESH_LSB_BIT : integer := 16; constant DMACR_IRQTHRESH_MSB_BIT : integer := 23; constant DMACR_IRQDELAY_LSB_BIT : integer := 24; constant DMACR_IRQDELAY_MSB_BIT : integer := 31; -- DMASR constant DMASR_HALTED_BIT : integer := 0; constant DMASR_IDLE_BIT : integer := 1; constant DMASR_CMPLT_BIT : integer := 2; constant DMASR_ERROR_BIT : integer := 3; constant DMASR_DMAINTERR_BIT : integer := 4; constant DMASR_DMASLVERR_BIT : integer := 5; constant DMASR_DMADECERR_BIT : integer := 6; constant DMASR_RESERVED7_BIT : integer := 7; constant DMASR_SGINTERR_BIT : integer := 8; constant DMASR_SGSLVERR_BIT : integer := 9; constant DMASR_SGDECERR_BIT : integer := 10; constant DMASR_RESERVED11_BIT : integer := 11; constant DMASR_IOCIRQ_BIT : integer := 12; constant DMASR_DLYIRQ_BIT : integer := 13; constant DMASR_ERRIRQ_BIT : integer := 14; constant DMASR_RESERVED15_BIT : integer := 15; constant DMASR_IRQTHRESH_LSB_BIT : integer := 16; constant DMASR_IRQTHRESH_MSB_BIT : integer := 23; constant DMASR_IRQDELAY_LSB_BIT : integer := 24; constant DMASR_IRQDELAY_MSB_BIT : integer := 31; -- CURDESC constant CURDESC_LOWER_MSB_BIT : integer := 31; constant CURDESC_LOWER_LSB_BIT : integer := 6; constant CURDESC_RESERVED_BIT5 : integer := 5; constant CURDESC_RESERVED_BIT4 : integer := 4; constant CURDESC_RESERVED_BIT3 : integer := 3; constant CURDESC_RESERVED_BIT2 : integer := 2; constant CURDESC_RESERVED_BIT1 : integer := 1; constant CURDESC_RESERVED_BIT0 : integer := 0; -- TAILDESC constant TAILDESC_LOWER_MSB_BIT : integer := 31; constant TAILDESC_LOWER_LSB_BIT : integer := 6; constant TAILDESC_RESERVED_BIT5 : integer := 5; constant TAILDESC_RESERVED_BIT4 : integer := 4; constant TAILDESC_RESERVED_BIT3 : integer := 3; constant TAILDESC_RESERVED_BIT2 : integer := 2; constant TAILDESC_RESERVED_BIT1 : integer := 1; constant TAILDESC_RESERVED_BIT0 : integer := 0; -- BTT constant BTT_MSB_BIT : integer := 22; -- DataMover Command / Status Constants constant DATAMOVER_CMDDONE_BIT : integer := 7; constant DATAMOVER_SLVERR_BIT : integer := 6; constant DATAMOVER_DECERR_BIT : integer := 5; constant DATAMOVER_INTERR_BIT : integer := 4; constant DATAMOVER_TAGMSB_BIT : integer := 3; constant DATAMOVER_TAGLSB_BIT : integer := 0; -- Descriptor Control Bits constant DESC_BLENGTH_LSB_BIT : integer := 0; constant DESC_BLENGTH_MSB_BIT : integer := 22; constant DESC_RSVD23_BIT : integer := 23; constant DESC_RSVD24_BIT : integer := 24; constant DESC_RSVD25_BIT : integer := 25; constant DESC_EOF_BIT : integer := 26; constant DESC_SOF_BIT : integer := 27; constant DESC_RSVD28_BIT : integer := 28; constant DESC_RSVD29_BIT : integer := 29; constant DESC_RSVD30_BIT : integer := 30; constant DESC_IOC_BIT : integer := 31; -- Descriptor Status Bits constant DESC_STS_CMPLTD_BIT : integer := 31; constant DESC_STS_DECERR_BIT : integer := 30; constant DESC_STS_SLVERR_BIT : integer := 29; constant DESC_STS_INTERR_BIT : integer := 28; constant DESC_STS_RXSOF_BIT : integer := 27; constant DESC_STS_RXEOF_BIT : integer := 26; constant DESC_STS_RSVD25_BIT : integer := 25; constant DESC_STS_RSVD24_BIT : integer := 24; constant DESC_STS_RSVD23_BIT : integer := 23; constant DESC_STS_XFRDBYTS_MSB_BIT : integer := 22; constant DESC_STS_XFRDBYTS_LSB_BIT : integer := 0; -- DataMover Command / Status Constants constant DATAMOVER_STS_CMDDONE_BIT : integer := 7; constant DATAMOVER_STS_SLVERR_BIT : integer := 6; constant DATAMOVER_STS_DECERR_BIT : integer := 5; constant DATAMOVER_STS_INTERR_BIT : integer := 4; constant DATAMOVER_STS_TAGMSB_BIT : integer := 3; constant DATAMOVER_STS_TAGLSB_BIT : integer := 0; constant DATAMOVER_STS_TAGEOF_BIT : integer := 1; constant DATAMOVER_STS_TLAST_BIT : integer := 31; constant DATAMOVER_CMD_BTTLSB_BIT : integer := 0; constant DATAMOVER_CMD_BTTMSB_BIT : integer := 22; constant DATAMOVER_CMD_TYPE_BIT : integer := 23; constant DATAMOVER_CMD_DSALSB_BIT : integer := 24; constant DATAMOVER_CMD_DSAMSB_BIT : integer := 29; constant DATAMOVER_CMD_EOF_BIT : integer := 30; constant DATAMOVER_CMD_DRR_BIT : integer := 31; constant DATAMOVER_CMD_ADDRLSB_BIT : integer := 32; -- Note: Bit offset require adding ADDR WIDTH to get to actual bit index constant DATAMOVER_CMD_ADDRMSB_BOFST: integer := 31; constant DATAMOVER_CMD_TAGLSB_BOFST : integer := 32; constant DATAMOVER_CMD_TAGMSB_BOFST : integer := 35; constant DATAMOVER_CMD_RSVLSB_BOFST : integer := 36; constant DATAMOVER_CMD_RSVMSB_BOFST : integer := 39; end axi_cdma_pkg; ------------------------------------------------------------------------------- -- PACKAGE BODY ------------------------------------------------------------------------------- package body axi_cdma_pkg is ------------------------------------------------------------------------------- -- Function to determine minimum bits required for BTT_SIZE field ------------------------------------------------------------------------------- function required_btt_width1 ( dwidth, burst_size, btt_width : integer) return integer is variable min_width : integer; begin min_width := clog2((dwidth/8)*burst_size)+1; if(min_width > btt_width)then return min_width; else return btt_width; end if; end function required_btt_width1; end package body axi_cdma_pkg;

gpl-3.0

908a75919102bf41140864f6033b3401

0.569257

4.379494

false

marco-c/leon-nexys2

grlib-gpl-1.3.4-b4140/designs/leon3-digilent-xc3s1000/leon3mp.vhd

1

16,901

----------------------------------------------------------------------------- -- LEON3 Demonstration design -- Copyright (C) 2004 Jiri Gaisler, Gaisler Research ------------------------------------------------------------------------------ -- This file is a part of the GRLIB VHDL IP LIBRARY -- Copyright (C) 2003 - 2008, Gaisler Research -- Copyright (C) 2008 - 2013, Aeroflex Gaisler -- -- This program is free software; you can redistribute it and/or modify -- it under the terms of the GNU General Public License as published by -- the Free Software Foundation; either version 2 of the License, or -- (at your option) any later version. -- -- This program is distributed in the hope that it will be useful, -- but WITHOUT ANY WARRANTY; without even the implied warranty of -- MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the -- GNU General Public License for more details. -- -- You should have received a copy of the GNU General Public License -- along with this program; if not, write to the Free Software -- Foundation, Inc., 59 Temple Place, Suite 330, Boston, MA 02111-1307 USA ------------------------------------------------------------------------------ library ieee; use ieee.std_logic_1164.all; library grlib, techmap; use grlib.amba.all; use grlib.stdlib.all; use techmap.gencomp.all; library gaisler; use gaisler.memctrl.all; use gaisler.leon3.all; use gaisler.uart.all; use gaisler.misc.all; use gaisler.jtag.all; -- pragma translate_off use gaisler.sim.all; -- pragma translate_on library esa; use esa.memoryctrl.all; use work.config.all; entity leon3mp is generic ( fabtech : integer := CFG_FABTECH; memtech : integer := CFG_MEMTECH; padtech : integer := CFG_PADTECH; clktech : integer := CFG_CLKTECH; disas : integer := CFG_DISAS; -- Enable disassembly to console dbguart : integer := CFG_DUART; -- Print UART on console pclow : integer := CFG_PCLOW ); port ( reset : in std_ulogic; clk : in std_ulogic; -- 50 MHz main clock error : out std_ulogic; address : out std_logic_vector(19 downto 2); data : inout std_logic_vector(31 downto 0); ramsn : out std_logic_vector (1 downto 0); mben : out std_logic_vector (3 downto 0); oen : out std_ulogic; writen : out std_ulogic; dsubre : in std_ulogic; dsuact : out std_ulogic; txd1 : out std_ulogic; -- UART1 tx data rxd1 : in std_ulogic; -- UART1 rx data pio : inout std_logic_vector(17 downto 0); -- I/O port -- switch : in std_logic_vector(7 downto 0); -- switches -- button : in std_logic_vector(2 downto 0); -- buttons ps2clk : inout std_logic; ps2data : inout std_logic; vid_hsync : out std_ulogic; vid_vsync : out std_ulogic; vid_r : out std_logic; vid_g : out std_logic; vid_b : out std_logic ); end; architecture rtl of leon3mp is constant blength : integer := 12; constant fifodepth : integer := 8; constant maxahbm : integer := CFG_NCPU+ CFG_AHB_JTAG+CFG_SVGA_ENABLE; signal vcc, gnd : std_logic_vector(4 downto 0); signal memi : memory_in_type; signal memo : memory_out_type; signal wpo : wprot_out_type; signal sdi : sdctrl_in_type; signal sdo : sdram_out_type; signal apbi : apb_slv_in_type; signal apbo : apb_slv_out_vector := (others => apb_none); signal ahbsi : ahb_slv_in_type; signal ahbso : ahb_slv_out_vector := (others => ahbs_none); signal ahbmi : ahb_mst_in_type; signal ahbmo : ahb_mst_out_vector := (others => ahbm_none); signal clkm, rstn, rstraw, nerror : std_ulogic; signal cgi : clkgen_in_type; signal cgo : clkgen_out_type; signal u1i, u2i, dui : uart_in_type; signal u1o, u2o, duo : uart_out_type; signal irqi : irq_in_vector(0 to CFG_NCPU-1); signal irqo : irq_out_vector(0 to CFG_NCPU-1); signal dbgi : l3_debug_in_vector(0 to CFG_NCPU-1); signal dbgo : l3_debug_out_vector(0 to CFG_NCPU-1); signal dsui : dsu_in_type; signal dsuo : dsu_out_type; signal gpti : gptimer_in_type; signal gpioi : gpio_in_type; signal gpioo : gpio_out_type; signal lclk, rst : std_ulogic; signal tck, tckn, tms, tdi, tdo : std_ulogic; signal kbdi : ps2_in_type; signal kbdo : ps2_out_type; signal vgao : apbvga_out_type; signal clkval : std_logic_vector(1 downto 0); constant BOARD_FREQ : integer := 50000; -- input frequency in KHz constant CPU_FREQ : integer := BOARD_FREQ * CFG_CLKMUL / CFG_CLKDIV; -- cpu frequency in KHz constant IOAEN : integer := 0; signal stati : ahbstat_in_type; signal dac_clk, clk1x, vid_clock, video_clk, clkvga : std_logic; -- signals to vga_clkgen. signal clk_sel : std_logic_vector(1 downto 0); attribute keep : boolean; attribute syn_keep : boolean; attribute syn_preserve : boolean; attribute syn_keep of video_clk : signal is true; attribute syn_preserve of video_clk : signal is true; attribute keep of video_clk : signal is true; begin ---------------------------------------------------------------------- --- Reset and Clock generation ------------------------------------- ---------------------------------------------------------------------- vcc <= (others => '1'); gnd <= (others => '0'); cgi.pllctrl <= "00"; cgi.pllrst <= rstraw; clk_pad : clkpad generic map (tech => padtech) port map (clk, lclk); clkgen0 : clkgen -- clock generator generic map (clktech, CFG_CLKMUL, CFG_CLKDIV, CFG_MCTRL_SDEN, CFG_CLK_NOFB, 0, 0, 0, BOARD_FREQ) port map (lclk, lclk, clkm, open, open, open, open, cgi, cgo, open, clk1x); resetn_pad : inpad generic map (tech => padtech) port map (reset, rst); rst0 : rstgen -- reset generator generic map (acthigh => 1) port map (rst, clkm, cgo.clklock, rstn, rstraw); ---------------------------------------------------------------------- --- AHB CONTROLLER -------------------------------------------------- ---------------------------------------------------------------------- ahb0 : ahbctrl -- AHB arbiter/multiplexer generic map (defmast => CFG_DEFMST, split => CFG_SPLIT, rrobin => CFG_RROBIN, ioaddr => CFG_AHBIO, ioen => IOAEN, nahbm => maxahbm, nahbs => 8) port map (rstn, clkm, ahbmi, ahbmo, ahbsi, ahbso); ---------------------------------------------------------------------- --- LEON3 processor and DSU ----------------------------------------- ---------------------------------------------------------------------- l3 : if CFG_LEON3 = 1 generate cpu : for i in 0 to CFG_NCPU-1 generate u0 : leon3s -- LEON3 processor generic map (i, fabtech, memtech, CFG_NWIN, CFG_DSU, CFG_FPU, CFG_V8, 0, CFG_MAC, pclow, CFG_NOTAG, CFG_NWP, CFG_ICEN, CFG_IREPL, CFG_ISETS, CFG_ILINE, CFG_ISETSZ, CFG_ILOCK, CFG_DCEN, CFG_DREPL, CFG_DSETS, CFG_DLINE, CFG_DSETSZ, CFG_DLOCK, CFG_DSNOOP, CFG_ILRAMEN, CFG_ILRAMSZ, CFG_ILRAMADDR, CFG_DLRAMEN, CFG_DLRAMSZ, CFG_DLRAMADDR, CFG_MMUEN, CFG_ITLBNUM, CFG_DTLBNUM, CFG_TLB_TYPE, CFG_TLB_REP, CFG_LDDEL, disas, CFG_ITBSZ, CFG_PWD, CFG_SVT, CFG_RSTADDR, CFG_NCPU-1) port map (clkm, rstn, ahbmi, ahbmo(i), ahbsi, ahbso, irqi(i), irqo(i), dbgi(i), dbgo(i)); end generate; nerror <= not dbgo(0).error; error_pad : outpad generic map (tech => padtech) port map (error, nerror); dsugen : if CFG_DSU = 1 generate dsu0 : dsu3 -- LEON3 Debug Support Unit generic map (hindex => 2, haddr => 16#900#, hmask => 16#F00#, ncpu => CFG_NCPU, tbits => 30, tech => memtech, irq => 0, kbytes => CFG_ATBSZ) port map (rstn, clkm, ahbmi, ahbsi, ahbso(2), dbgo, dbgi, dsui, dsuo); dsui.enable <= '1'; dsubre_pad : inpad generic map (tech => padtech) port map (dsubre, dsui.break); dsuact_pad : outpad generic map (tech => padtech) port map (dsuact, dsuo.active); end generate; end generate; nodsu : if CFG_DSU = 0 generate dsuo.tstop <= '0'; dsuo.active <= '0'; end generate; -- dcomgen : if CFG_AHB_UART = 1 generate -- dcom0: ahbuart -- Debug UART -- generic map (hindex => CFG_NCPU, pindex => 7, paddr => 7) -- port map (rstn, clkm, dui, duo, apbi, apbo(7), ahbmi, ahbmo(CFG_NCPU)); -- dsurx_pad : inpad generic map (tech => padtech) port map (rxd2, dui.rxd); -- dsutx_pad : outpad generic map (tech => padtech) port map (txd2, duo.txd); -- end generate; -- nouah : if CFG_AHB_UART = 0 generate apbo(7) <= apb_none; end generate; ahbjtaggen0 :if CFG_AHB_JTAG = 1 generate ahbjtag0 : ahbjtag generic map(tech => fabtech, hindex => CFG_NCPU) port map(rstn, clkm, tck, tms, tdi, tdo, ahbmi, ahbmo(CFG_NCPU), open, open, open, open, open, open, open, gnd(0)); end generate; ---------------------------------------------------------------------- --- Memory controllers ---------------------------------------------- ---------------------------------------------------------------------- memi.writen <= '1'; memi.wrn <= "1111"; memi.bwidth <= "00"; mctrl0 : mctrl generic map (hindex => 0, pindex => 0, rommask => 16#000#, iomask => 16#000#, paddr => 0, srbanks => 1, ram8 => CFG_MCTRL_RAM8BIT, ram16 => CFG_MCTRL_RAM16BIT, sden => CFG_MCTRL_SDEN, invclk => CFG_CLK_NOFB, sepbus => CFG_MCTRL_SEPBUS) port map (rstn, clkm, memi, memo, ahbsi, ahbso(0), apbi, apbo(0), wpo, sdo); addr_pad : outpadv generic map (width => 18, tech => padtech) port map (address, memo.address(19 downto 2)); ramsa_pad : outpad generic map (tech => padtech) port map (ramsn(0), memo.ramsn(0)); ramsb_pad : outpad generic map (tech => padtech) port map (ramsn(1), memo.ramsn(0)); oen_pad : outpad generic map (tech => padtech) port map (oen, memo.oen); wri_pad : outpad generic map (tech => padtech) port map (writen, memo.writen); mben_pads : outpadv generic map (tech => padtech, width => 4) port map (mben, memo.mben); data_pads : iopadvv generic map (tech => padtech, width => 32) port map (data, memo.data(31 downto 0), memo.vbdrive(31 downto 0), memi.data(31 downto 0)); ---------------------------------------------------------------------- --- APB Bridge and various periherals ------------------------------- ---------------------------------------------------------------------- bpromgen : if CFG_AHBROMEN /= 0 generate brom : entity work.ahbrom generic map (hindex => 6, haddr => CFG_AHBRODDR, pipe => CFG_AHBROPIP) port map ( rstn, clkm, ahbsi, ahbso(6)); end generate; ---------------------------------------------------------------------- --- APB Bridge and various periherals ------------------------------- ---------------------------------------------------------------------- apb0 : apbctrl -- AHB/APB bridge generic map (hindex => 1, haddr => CFG_APBADDR, nslaves => 16) port map (rstn, clkm, ahbsi, ahbso(1), apbi, apbo ); ua1 : if CFG_UART1_ENABLE /= 0 generate uart1 : apbuart -- UART 1 generic map (pindex => 1, paddr => 1, pirq => 2, console => dbguart, fifosize => CFG_UART1_FIFO) port map (rstn, clkm, apbi, apbo(1), u1i, u1o); u1i.extclk <= '0'; rxd1_pad : inpad generic map (tech => padtech) port map (rxd1, u1i.rxd); txd1_pad : outpad generic map (tech => padtech) port map (txd1, u1o.txd); end generate; noua0 : if CFG_UART1_ENABLE = 0 generate apbo(1) <= apb_none; end generate; irqctrl : if CFG_IRQ3_ENABLE /= 0 generate irqctrl0 : irqmp -- interrupt controller generic map (pindex => 2, paddr => 2, ncpu => CFG_NCPU) port map (rstn, clkm, apbi, apbo(2), irqo, irqi); end generate; irq3 : if CFG_IRQ3_ENABLE = 0 generate x : for i in 0 to CFG_NCPU-1 generate irqi(i).irl <= "0000"; end generate; apbo(2) <= apb_none; end generate; gpt : if CFG_GPT_ENABLE /= 0 generate timer0 : gptimer -- timer unit generic map (pindex => 3, paddr => 3, pirq => CFG_GPT_IRQ, sepirq => CFG_GPT_SEPIRQ, sbits => CFG_GPT_SW, ntimers => CFG_GPT_NTIM, nbits => CFG_GPT_TW) port map (rstn, clkm, apbi, apbo(3), gpti, open); gpti.dhalt <= dsuo.tstop; gpti.extclk <= '0'; end generate; nogpt : if CFG_GPT_ENABLE = 0 generate apbo(3) <= apb_none; end generate; kbd : if CFG_KBD_ENABLE /= 0 generate ps20 : apbps2 generic map(pindex => 5, paddr => 5, pirq => 5) port map(rstn, clkm, apbi, apbo(5), kbdi, kbdo); end generate; nokbd : if CFG_KBD_ENABLE = 0 generate apbo(5) <= apb_none; kbdo <= ps2o_none; end generate; kbdclk_pad : iopad generic map (tech => padtech) port map (ps2clk,kbdo.ps2_clk_o, kbdo.ps2_clk_oe, kbdi.ps2_clk_i); kbdata_pad : iopad generic map (tech => padtech) port map (ps2data, kbdo.ps2_data_o, kbdo.ps2_data_oe, kbdi.ps2_data_i); clkdiv : process(clk1x, rstn) begin if rstn = '0' then clkval <= "00"; elsif rising_edge(clk1x) then clkval <= clkval + 1; end if; end process; vga : if CFG_VGA_ENABLE /= 0 generate vga0 : apbvga generic map(memtech => memtech, pindex => 6, paddr => 6) port map(rstn, clkm, video_clk, apbi, apbo(6), vgao); video_clock_pad : outpad generic map ( tech => padtech) port map (vid_clock, dac_clk); dac_clk <= not video_clk; b1 : techbuf generic map (2, virtex2) port map (clkval(0), video_clk); end generate; svga : if CFG_SVGA_ENABLE /= 0 generate clkvga <= clkval(1) when clk_sel = "00" else clkval(0) when clk_sel = "01" else clkm; b1 : techbuf generic map (2, virtex2) port map (clkvga, video_clk); svga0 : svgactrl generic map(memtech => memtech, pindex => 6, paddr => 6, hindex => CFG_NCPU+CFG_AHB_JTAG, clk0 => 40000, clk1 => 20000, clk2 => 25000) port map(rstn, clkm, video_clk, apbi, apbo(6), vgao, ahbmi, ahbmo(CFG_NCPU+CFG_AHB_JTAG), clk_sel); dac_clk <= not video_clk; video_clock_pad : outpad generic map ( tech => padtech) port map (vid_clock, dac_clk); end generate; novga : if (CFG_VGA_ENABLE = 0 and CFG_SVGA_ENABLE = 0) generate apbo(6) <= apb_none; vgao <= vgao_none; end generate; vert_sync_pad : outpad generic map (tech => padtech) port map (vid_vsync, vgao.vsync); horiz_sync_pad : outpad generic map (tech => padtech) port map (vid_hsync, vgao.hsync); video_out_r_pad : outpad generic map (tech => padtech) port map (vid_r, vgao.video_out_r(7)); video_out_g_pad : outpad generic map (tech => padtech) port map (vid_g, vgao.video_out_g(7)); video_out_b_pad : outpad generic map (tech => padtech) port map (vid_b, vgao.video_out_b(7)); gpio0 : if CFG_GRGPIO_ENABLE /= 0 generate -- GPIO unit grgpio0: grgpio generic map(pindex => 8, paddr => 8, imask => CFG_GRGPIO_IMASK, nbits => 18) port map(rst => rstn, clk => clkm, apbi => apbi, apbo => apbo(8), gpioi => gpioi, gpioo => gpioo); pio_pads : iopadvv generic map (width => 18, tech => padtech) port map (pio, gpioo.dout(17 downto 0), gpioo.oen(17 downto 0), gpioi.din(17 downto 0)); end generate; ----------------------------------------------------------------------- --- AHB RAM ---------------------------------------------------------- ----------------------------------------------------------------------- ocram : if CFG_AHBRAMEN = 1 generate ahbram0 : ahbram generic map (hindex => 7, haddr => CFG_AHBRADDR, tech => CFG_MEMTECH, kbytes => CFG_AHBRSZ, pipe => CFG_AHBRPIPE) port map ( rstn, clkm, ahbsi, ahbso(7)); end generate; ----------------------------------------------------------------------- --- Drive unused bus elements --------------------------------------- ----------------------------------------------------------------------- -- nam1 : for i in (CFG_NCPU+FG_AHB_UART+CFG_GRETH+CFG_AHB_JTAG) to NAHBMST-1 generate -- ahbmo(i) <= ahbm_none; -- end generate; -- nap0 : for i in 11 to NAPBSLV-1 generate apbo(i) <= apb_none; end generate; -- nah0 : for i in 8 to NAHBSLV-1 generate ahbso(i) <= ahbs_none; end generate; ----------------------------------------------------------------------- --- Test report module ---------------------------------------------- ----------------------------------------------------------------------- -- pragma translate_off test0 : ahbrep generic map (hindex => 4, haddr => 16#200#) port map (rstn, clkm, ahbsi, ahbso(4)); -- pragma translate_on ----------------------------------------------------------------------- --- Boot message ---------------------------------------------------- ----------------------------------------------------------------------- -- pragma translate_off x : report_design generic map ( msg1 => "LEON3 Digilent XC3S1000 Demonstration design", fabtech => tech_table(fabtech), memtech => tech_table(memtech), mdel => 1 ); -- pragma translate_on end;

gpl-2.0

5836097d76ace44c6de57a8e42d6c0ef

0.558251

3.663776

false

marco-c/leon-nexys2

grlib-gpl-1.3.4-b4140/designs/leon3-xilinx-ml50x/grlib_config.vhd

1

2,564

------------------------------------------------------------------------------ -- This file is a part of the GRLIB VHDL IP LIBRARY -- Copyright (C) 2003 - 2008, Gaisler Research -- Copyright (C) 2008 - 2013, Aeroflex Gaisler -- -- This program is free software; you can redistribute it and/or modify -- it under the terms of the GNU General Public License as published by -- the Free Software Foundation; either version 2 of the License, or -- (at your option) any later version. -- -- This program is distributed in the hope that it will be useful, -- but WITHOUT ANY WARRANTY; without even the implied warranty of -- MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the -- GNU General Public License for more details. -- -- You should have received a copy of the GNU General Public License -- along with this program; if not, write to the Free Software -- Foundation, Inc., 59 Temple Place, Suite 330, Boston, MA 02111-1307 USA ----------------------------------------------------------------------------- -- Package: config -- File: config.vhd -- Author: Jiri Gaisler, Gaisler Research -- Description: GRLIB Global configuration package. Can be overriden -- by local config packages in template designs. ------------------------------------------------------------------------------ library ieee; use ieee.std_logic_1164.all; library grlib; use grlib.config_types.all; package config is -- AHBDW - AHB data with -- -- Valid values are 32, 64, 128 and 256 -- -- The value here sets the width of the AMBA AHB data vectors for all -- cores in the library. -- constant CFG_AHBDW : integer := 64; -- CORE_ACDM - Enable AMBA Compliant Data Muxing in cores -- -- Valid values are 0 and 1 -- -- 0: All GRLIB cores that use the ahbread* programs defined in the AMBA package -- will read their data from the low part of the AHB data vector. -- -- 1: All GRLIB cores that use the ahbread* programs defined in the AMBA package -- will select valid data, as defined in the AMBA AHB standard, from the -- AHB data vectors based on the address input. If a core uses a function -- that does not have the address input, a failure will be asserted. -- constant CFG_AHB_ACDM : integer := 0; -- GRLIB_CONFIG_ARRAY - Array of configuration values -- -- The length of this array and the meaning of different positions is defined -- in the grlib.config_types package. constant GRLIB_CONFIG_ARRAY : grlib_config_array_type := ( grlib_debug_level => 0, grlib_debug_mask => 0, grlib_techmap_strict_ram => 0, others => 0); end;

gpl-2.0

e8136af418a0f6882007fc933bf21ebd

0.654446

4.175896

false

true

false

marco-c/leon-nexys2

grlib-gpl-1.3.4-b4140/lib/gaisler/leon3/leon3.vhd

1

35,770

------------------------------------------------------------------------------ -- This file is a part of the GRLIB VHDL IP LIBRARY -- Copyright (C) 2003 - 2008, Gaisler Research -- Copyright (C) 2008 - 2013, Aeroflex Gaisler -- -- This program is free software; you can redistribute it and/or modify -- it under the terms of the GNU General Public License as published by -- the Free Software Foundation; either version 2 of the License, or -- (at your option) any later version. -- -- This program is distributed in the hope that it will be useful, -- but WITHOUT ANY WARRANTY; without even the implied warranty of -- MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the -- GNU General Public License for more details. -- -- You should have received a copy of the GNU General Public License -- along with this program; if not, write to the Free Software -- Foundation, Inc., 59 Temple Place, Suite 330, Boston, MA 02111-1307 USA ----------------------------------------------------------------------------- -- Package: leon3 -- File: leon3.vhd -- Author: Jiri Gaisler, Gaisler Research -- Description: LEON3 types and components ------------------------------------------------------------------------------ library ieee; use ieee.std_logic_1164.all; library grlib; use grlib.amba.all; library techmap; use techmap.gencomp.all; package leon3 is constant LEON3_VERSION : integer := 3; type l3_irq_in_type is record irl : std_logic_vector(3 downto 0); rst : std_ulogic; run : std_ulogic; rstvec : std_logic_vector(31 downto 12); iact : std_ulogic; index : std_logic_vector(3 downto 0); hrdrst : std_ulogic; end record; type l3_irq_out_type is record intack : std_ulogic; irl : std_logic_vector(3 downto 0); pwd : std_ulogic; fpen : std_ulogic; idle : std_ulogic; end record; type l3_debug_in_type is record dsuen : std_ulogic; -- DSU enable denable : std_ulogic; -- diagnostic register access enable dbreak : std_ulogic; -- debug break-in step : std_ulogic; -- single step halt : std_ulogic; -- halt processor reset : std_ulogic; -- reset processor dwrite : std_ulogic; -- read/write daddr : std_logic_vector(23 downto 2); -- diagnostic address ddata : std_logic_vector(31 downto 0); -- diagnostic data btrapa : std_ulogic; -- break on IU trap btrape : std_ulogic; -- break on IU trap berror : std_ulogic; -- break on IU error mode bwatch : std_ulogic; -- break on IU watchpoint bsoft : std_ulogic; -- break on software breakpoint (TA 1) tenable : std_ulogic; timer : std_logic_vector(30 downto 0); -- end record; constant dbgi_none : l3_debug_in_type := ('0', '0', '0', '0', '0', '0', '0', (others => '0'), (others => '0'), '0', '0', '0', '0', '0', '0', (others => '0')); constant l3_dbgi_none : l3_debug_in_type := dbgi_none; type l3_cstat_type is record cmiss : std_ulogic; -- cache miss tmiss : std_ulogic; -- TLB miss chold : std_ulogic; -- cache hold mhold : std_ulogic; -- cache mmu hold end record; constant cstat_none : l3_cstat_type := ('0', '0', '0', '0'); type l3_debug_out_type is record data : std_logic_vector(31 downto 0); crdy : std_ulogic; dsu : std_ulogic; dsumode : std_ulogic; error : std_ulogic; halt : std_ulogic; pwd : std_ulogic; idle : std_ulogic; ipend : std_ulogic; icnt : std_ulogic; fcnt : std_ulogic; optype : std_logic_vector(5 downto 0); -- instruction type bpmiss : std_ulogic; -- branch predict miss istat : l3_cstat_type; dstat : l3_cstat_type; wbhold : std_ulogic; -- write buffer hold su : std_ulogic; -- supervisor state end record; type l3_debug_in_vector is array (natural range <>) of l3_debug_in_type; type l3_debug_out_vector is array (natural range <>) of l3_debug_out_type; constant dbgo_none : l3_debug_out_type := (X"00000000", '0', '0', '0', '0', '0', '0', '0', '0', '0', '0', "000000", '0', cstat_none, cstat_none, '0', '0'); constant l3_dbgo_none : l3_debug_out_type := dbgo_none; type tracebuf_in_type is record addr : std_logic_vector(11 downto 0); data : std_logic_vector(127 downto 0); enable : std_logic; write : std_logic_vector(3 downto 0); diag : std_logic_vector(3 downto 0); end record; type tracebuf_out_type is record data : std_logic_vector(127 downto 0); end record; component tbufmem generic ( tech : integer := 0; tbuf : integer := 0; testen: integer := 0); port ( clk : in std_ulogic; di : in tracebuf_in_type; do : out tracebuf_out_type); end component; component leon3s generic ( hindex : integer := 0; fabtech : integer range 0 to NTECH := DEFFABTECH; memtech : integer range 0 to NTECH := DEFMEMTECH; nwindows : integer range 2 to 32 := 8; dsu : integer range 0 to 1 := 0; fpu : integer range 0 to 31 := 0; v8 : integer range 0 to 63 := 0; cp : integer range 0 to 1 := 0; mac : integer range 0 to 1 := 0; pclow : integer range 0 to 2 := 2; notag : integer range 0 to 1 := 0; nwp : integer range 0 to 4 := 0; icen : integer range 0 to 1 := 0; irepl : integer range 0 to 3 := 2; isets : integer range 1 to 4 := 1; ilinesize : integer range 4 to 8 := 4; isetsize : integer range 1 to 256 := 1; isetlock : integer range 0 to 1 := 0; dcen : integer range 0 to 1 := 0; drepl : integer range 0 to 3 := 2; dsets : integer range 1 to 4 := 1; dlinesize : integer range 4 to 8 := 4; dsetsize : integer range 1 to 256 := 1; dsetlock : integer range 0 to 1 := 0; dsnoop : integer range 0 to 6 := 0; ilram : integer range 0 to 1 := 0; ilramsize : integer range 1 to 512 := 1; ilramstart: integer range 0 to 255 := 16#8e#; dlram : integer range 0 to 1 := 0; dlramsize : integer range 1 to 512 := 1; dlramstart: integer range 0 to 255 := 16#8f#; mmuen : integer range 0 to 1 := 0; itlbnum : integer range 2 to 64 := 8; dtlbnum : integer range 2 to 64 := 8; tlb_type : integer range 0 to 3 := 1; tlb_rep : integer range 0 to 1 := 0; lddel : integer range 1 to 2 := 2; disas : integer range 0 to 2 := 0; tbuf : integer range 0 to 64 := 0; pwd : integer range 0 to 2 := 2; svt : integer range 0 to 1 := 1; rstaddr : integer := 16#00000#; smp : integer range 0 to 15 := 0; cached : integer := 0; scantest : integer := 0; mmupgsz : integer range 0 to 5 := 0; bp : integer := 1 ); port ( clk : in std_ulogic; rstn : in std_ulogic; ahbi : in ahb_mst_in_type; ahbo : out ahb_mst_out_type; ahbsi : in ahb_slv_in_type; ahbso : in ahb_slv_out_vector; irqi : in l3_irq_in_type; irqo : out l3_irq_out_type; dbgi : in l3_debug_in_type; dbgo : out l3_debug_out_type ); end component; component leon3cg generic ( hindex : integer := 0; fabtech : integer range 0 to NTECH := DEFFABTECH; memtech : integer range 0 to NTECH := DEFMEMTECH; nwindows : integer range 2 to 32 := 8; dsu : integer range 0 to 1 := 0; fpu : integer range 0 to 31 := 0; v8 : integer range 0 to 63 := 0; cp : integer range 0 to 1 := 0; mac : integer range 0 to 1 := 0; pclow : integer range 0 to 2 := 2; notag : integer range 0 to 1 := 0; nwp : integer range 0 to 4 := 0; icen : integer range 0 to 1 := 0; irepl : integer range 0 to 3 := 2; isets : integer range 1 to 4 := 1; ilinesize : integer range 4 to 8 := 4; isetsize : integer range 1 to 256 := 1; isetlock : integer range 0 to 1 := 0; dcen : integer range 0 to 1 := 0; drepl : integer range 0 to 3 := 2; dsets : integer range 1 to 4 := 1; dlinesize : integer range 4 to 8 := 4; dsetsize : integer range 1 to 256 := 1; dsetlock : integer range 0 to 1 := 0; dsnoop : integer range 0 to 6 := 0; ilram : integer range 0 to 1 := 0; ilramsize : integer range 1 to 512 := 1; ilramstart: integer range 0 to 255 := 16#8e#; dlram : integer range 0 to 1 := 0; dlramsize : integer range 1 to 512 := 1; dlramstart: integer range 0 to 255 := 16#8f#; mmuen : integer range 0 to 1 := 0; itlbnum : integer range 2 to 64 := 8; dtlbnum : integer range 2 to 64 := 8; tlb_type : integer range 0 to 3 := 1; tlb_rep : integer range 0 to 1 := 0; lddel : integer range 1 to 2 := 2; disas : integer range 0 to 2 := 0; tbuf : integer range 0 to 64 := 0; pwd : integer range 0 to 2 := 2; svt : integer range 0 to 1 := 1; rstaddr : integer := 16#00000#; smp : integer range 0 to 15 := 0; cached : integer := 0; scantest : integer := 0; mmupgsz : integer range 0 to 5 := 0; bp : integer := 1 ); port ( clk : in std_ulogic; rstn : in std_ulogic; ahbi : in ahb_mst_in_type; ahbo : out ahb_mst_out_type; ahbsi : in ahb_slv_in_type; ahbso : in ahb_slv_out_vector; irqi : in l3_irq_in_type; irqo : out l3_irq_out_type; dbgi : in l3_debug_in_type; dbgo : out l3_debug_out_type; gclk : in std_ulogic ); end component; component leon3ft generic ( hindex : integer := 0; fabtech : integer range 0 to NTECH := DEFFABTECH; memtech : integer range 0 to NTECH := DEFMEMTECH; nwindows : integer range 2 to 32 := 8; dsu : integer range 0 to 1 := 0; fpu : integer range 0 to 31 := 0; v8 : integer range 0 to 63 := 0; cp : integer range 0 to 1 := 0; mac : integer range 0 to 1 := 0; pclow : integer range 0 to 2 := 2; notag : integer range 0 to 1 := 0; nwp : integer range 0 to 4 := 0; icen : integer range 0 to 1 := 0; irepl : integer range 0 to 3 := 2; isets : integer range 1 to 4 := 1; ilinesize : integer range 4 to 8 := 4; isetsize : integer range 1 to 256 := 1; isetlock : integer range 0 to 1 := 0; dcen : integer range 0 to 1 := 0; drepl : integer range 0 to 3 := 2; dsets : integer range 1 to 4 := 1; dlinesize : integer range 4 to 8 := 4; dsetsize : integer range 1 to 256 := 1; dsetlock : integer range 0 to 1 := 0; dsnoop : integer range 0 to 6 := 0; ilram : integer range 0 to 1 := 0; ilramsize : integer range 1 to 512 := 1; ilramstart: integer range 0 to 255 := 16#8e#; dlram : integer range 0 to 1 := 0; dlramsize : integer range 1 to 512 := 1; dlramstart: integer range 0 to 255 := 16#8f#; mmuen : integer range 0 to 1 := 0; itlbnum : integer range 2 to 64 := 8; dtlbnum : integer range 2 to 64 := 8; tlb_type : integer range 0 to 3 := 1; tlb_rep : integer range 0 to 1 := 0; lddel : integer range 1 to 2 := 2; disas : integer range 0 to 2 := 0; tbuf : integer range 0 to 64 := 0; pwd : integer range 0 to 2 := 2; svt : integer range 0 to 1 := 1; rstaddr : integer := 16#00000#; smp : integer range 0 to 15 := 0; -- support SMP systems iuft : integer range 0 to 4 := 0; fpft : integer range 0 to 4 := 0; cmft : integer range 0 to 1 := 0; iuinj : integer := 0; ceinj : integer range 0 to 3 := 0; cached : integer := 0; -- cacheability table netlist : integer := 0; -- use netlist scantest : integer := 0; -- enable scan test support mmupgsz : integer range 0 to 5 := 0; bp : integer := 1 ); port ( clk : in std_ulogic; rstn : in std_ulogic; ahbi : in ahb_mst_in_type; ahbo : out ahb_mst_out_type; ahbsi : in ahb_slv_in_type; ahbso : in ahb_slv_out_vector; irqi : in l3_irq_in_type; irqo : out l3_irq_out_type; dbgi : in l3_debug_in_type; dbgo : out l3_debug_out_type; gclk : in std_ulogic ); end component; type grfpu_in_type is record start : std_logic; nonstd : std_logic; flop : std_logic_vector(8 downto 0); op1 : std_logic_vector(63 downto 0); op2 : std_logic_vector(63 downto 0); opid : std_logic_vector(7 downto 0); flush : std_logic; flushid : std_logic_vector(5 downto 0); rndmode : std_logic_vector(1 downto 0); req : std_logic_vector(2 downto 0); end record; constant grfpu_in_none : grfpu_in_type := ('0', '0', (others => '0'), (others => '0'), (others => '0'), (others => '0'), '0', (others => '0'), (others => '0'), (others => '0')); type grfpu_out_type is record res : std_logic_vector(63 downto 0); exc : std_logic_vector(5 downto 0); allow : std_logic_vector(2 downto 0); rdy : std_logic; cc : std_logic_vector(1 downto 0); idout : std_logic_vector(7 downto 0); end record; constant grfpu_out_none : grfpu_out_type := ((others => '0'), (others => '0'), (others => '0'), '0', (others => '0'), (others => '0')); type grfpu_out_vector_type is array (integer range 0 to 7) of grfpu_out_type; type grfpu_in_vector_type is array (integer range 0 to 7) of grfpu_in_type; component grfpushwx generic (mul : integer := 0; nshare : integer range 0 to 8 := 0; tech : integer; arb : integer range 0 to 2 := 1); port( clk : in std_logic; reset : in std_logic; fpvi : in grfpu_in_vector_type; fpvo : out grfpu_out_vector_type ); end component; component leon3sh generic ( hindex : integer := 0; fabtech : integer range 0 to NTECH := DEFFABTECH; memtech : integer range 0 to NTECH := DEFMEMTECH; nwindows : integer range 2 to 32 := 8; dsu : integer range 0 to 1 := 0; fpu : integer range 0 to 63 := 0; v8 : integer range 0 to 63 := 0; cp : integer range 0 to 1 := 0; mac : integer range 0 to 1 := 0; pclow : integer range 0 to 2 := 2; notag : integer range 0 to 1 := 0; nwp : integer range 0 to 4 := 0; icen : integer range 0 to 1 := 0; irepl : integer range 0 to 3 := 2; isets : integer range 1 to 4 := 1; ilinesize : integer range 4 to 8 := 4; isetsize : integer range 1 to 256 := 1; isetlock : integer range 0 to 1 := 0; dcen : integer range 0 to 1 := 0; drepl : integer range 0 to 3 := 2; dsets : integer range 1 to 4 := 1; dlinesize : integer range 4 to 8 := 4; dsetsize : integer range 1 to 256 := 1; dsetlock : integer range 0 to 1 := 0; dsnoop : integer range 0 to 6 := 0; ilram : integer range 0 to 1 := 0; ilramsize : integer range 1 to 512 := 1; ilramstart : integer range 0 to 255 := 16#8e#; dlram : integer range 0 to 1 := 0; dlramsize : integer range 1 to 512 := 1; dlramstart : integer range 0 to 255 := 16#8f#; mmuen : integer range 0 to 1 := 0; itlbnum : integer range 2 to 64 := 8; dtlbnum : integer range 2 to 64 := 8; tlb_type : integer range 0 to 3 := 1; tlb_rep : integer range 0 to 1 := 0; lddel : integer range 1 to 2 := 2; disas : integer range 0 to 2 := 0; tbuf : integer range 0 to 64 := 0; pwd : integer range 0 to 2 := 2; -- power-down svt : integer range 0 to 1 := 1; -- single vector trapping rstaddr : integer := 0; smp : integer range 0 to 15 := 0; -- support SMP systems cached : integer := 0; -- cacheability table scantest : integer := 0; mmupgsz : integer range 0 to 5 := 0; bp : integer := 1 ); port ( clk : in std_ulogic; rstn : in std_ulogic; ahbi : in ahb_mst_in_type; ahbo : out ahb_mst_out_type; ahbsi : in ahb_slv_in_type; ahbso : in ahb_slv_out_vector; irqi : in l3_irq_in_type; irqo : out l3_irq_out_type; dbgi : in l3_debug_in_type; dbgo : out l3_debug_out_type; fpui : out grfpu_in_type; fpuo : in grfpu_out_type ); end component; component leon3s2x generic ( hindex : integer := 0; fabtech : integer range 0 to NTECH := DEFFABTECH; memtech : integer range 0 to NTECH := DEFMEMTECH; nwindows : integer range 2 to 32 := 8; dsu : integer range 0 to 1 := 0; fpu : integer range 0 to 31 := 0; v8 : integer range 0 to 63 := 0; cp : integer range 0 to 1 := 0; mac : integer range 0 to 1 := 0; pclow : integer range 0 to 2 := 2; notag : integer range 0 to 1 := 0; nwp : integer range 0 to 4 := 0; icen : integer range 0 to 1 := 0; irepl : integer range 0 to 3 := 2; isets : integer range 1 to 4 := 1; ilinesize : integer range 4 to 8 := 4; isetsize : integer range 1 to 256 := 1; isetlock : integer range 0 to 1 := 0; dcen : integer range 0 to 1 := 0; drepl : integer range 0 to 3 := 2; dsets : integer range 1 to 4 := 1; dlinesize : integer range 4 to 8 := 4; dsetsize : integer range 1 to 256 := 1; dsetlock : integer range 0 to 1 := 0; dsnoop : integer range 0 to 6 := 0; ilram : integer range 0 to 1 := 0; ilramsize : integer range 1 to 512 := 1; ilramstart : integer range 0 to 255 := 16#8e#; dlram : integer range 0 to 1 := 0; dlramsize : integer range 1 to 512 := 1; dlramstart : integer range 0 to 255 := 16#8f#; mmuen : integer range 0 to 1 := 0; itlbnum : integer range 2 to 64 := 8; dtlbnum : integer range 2 to 64 := 8; tlb_type : integer range 0 to 3 := 1; tlb_rep : integer range 0 to 1 := 0; lddel : integer range 1 to 2 := 2; disas : integer range 0 to 2 := 0; tbuf : integer range 0 to 64 := 0; pwd : integer range 0 to 2 := 2; -- power-down svt : integer range 0 to 1 := 1; -- single vector trapping rstaddr : integer := 0; smp : integer range 0 to 15 := 0; -- support SMP systems cached : integer := 0; -- cacheability table clk2x : integer := 1; scantest : integer := 0; mmupgsz : integer range 0 to 5 := 0; bp : integer := 1 ); port ( clk : in std_ulogic; gclk2 : in std_ulogic; clk2 : in std_ulogic; -- snoop clock rstn : in std_ulogic; ahbi : in ahb_mst_in_type; ahbo : out ahb_mst_out_type; ahbsi : in ahb_slv_in_type; ahbso : in ahb_slv_out_vector; irqi : in l3_irq_in_type; irqo : out l3_irq_out_type; dbgi : in l3_debug_in_type; dbgo : out l3_debug_out_type; clken : in std_ulogic ); end component; component leon3ft2x generic ( hindex : integer := 0; fabtech : integer range 0 to NTECH := DEFFABTECH; memtech : integer range 0 to NTECH := DEFMEMTECH; nwindows : integer range 2 to 32 := 8; dsu : integer range 0 to 1 := 0; fpu : integer range 0 to 63 := 0; v8 : integer range 0 to 63 := 0; cp : integer range 0 to 1 := 0; mac : integer range 0 to 1 := 0; pclow : integer range 0 to 2 := 2; notag : integer range 0 to 1 := 0; nwp : integer range 0 to 4 := 0; icen : integer range 0 to 1 := 0; irepl : integer range 0 to 3 := 2; isets : integer range 1 to 4 := 1; ilinesize : integer range 4 to 8 := 4; isetsize : integer range 1 to 256 := 1; isetlock : integer range 0 to 1 := 0; dcen : integer range 0 to 1 := 0; drepl : integer range 0 to 3 := 2; dsets : integer range 1 to 4 := 1; dlinesize : integer range 4 to 8 := 4; dsetsize : integer range 1 to 256 := 1; dsetlock : integer range 0 to 1 := 0; dsnoop : integer range 0 to 6 := 0; ilram : integer range 0 to 1 := 0; ilramsize : integer range 1 to 512 := 1; ilramstart : integer range 0 to 255 := 16#8e#; dlram : integer range 0 to 1 := 0; dlramsize : integer range 1 to 512 := 1; dlramstart : integer range 0 to 255 := 16#8f#; mmuen : integer range 0 to 1 := 0; itlbnum : integer range 2 to 64 := 8; dtlbnum : integer range 2 to 64 := 8; tlb_type : integer range 0 to 3 := 1; tlb_rep : integer range 0 to 1 := 0; lddel : integer range 1 to 2 := 2; disas : integer range 0 to 2 := 0; tbuf : integer range 0 to 64 := 0; pwd : integer range 0 to 2 := 2; -- power-down svt : integer range 0 to 1 := 1; -- single vector trapping rstaddr : integer := 0; smp : integer range 0 to 15 := 0; -- support SMP systems iuft : integer range 0 to 4 := 0; fpft : integer range 0 to 4 := 0; cmft : integer range 0 to 1 := 0; iuinj : integer := 0; ceinj : integer range 0 to 3 := 0; cached : integer := 0; clk2x : integer := 1; netlist : integer := 0; scantest : integer := 0; mmupgsz : integer range 0 to 5 := 0; bp : integer := 1 ); port ( clk : in std_ulogic; -- free-running clock gclk2 : in std_ulogic; -- gated 2x clock gfclk2 : in std_ulogic; -- gated 2x FPU clock clk2 : in std_ulogic; -- free-running 2x clock rstn : in std_ulogic; ahbi : in ahb_mst_in_type; ahbo : out ahb_mst_out_type; ahbsi : in ahb_slv_in_type; ahbso : in ahb_slv_out_vector; irqi : in l3_irq_in_type; irqo : out l3_irq_out_type; dbgi : in l3_debug_in_type; dbgo : out l3_debug_out_type; fpui : out grfpu_in_type; fpuo : in grfpu_out_type; clken : in std_ulogic ); end component; type dsu_in_type is record enable : std_ulogic; break : std_ulogic; end record; type dsu_out_type is record active : std_ulogic; tstop : std_ulogic; pwd : std_logic_vector(15 downto 0); end record; component dsu3 generic ( hindex : integer := 0; haddr : integer := 16#900#; hmask : integer := 16#f00#; ncpu : integer := 1; tbits : integer := 30; -- timer bits (instruction trace time tag) tech : integer := DEFMEMTECH; irq : integer := 0; kbytes : integer := 0; testen : integer := 0 ); port ( rst : in std_ulogic; clk : in std_ulogic; ahbmi : in ahb_mst_in_type; ahbsi : in ahb_slv_in_type; ahbso : out ahb_slv_out_type; dbgi : in l3_debug_out_vector(0 to NCPU-1); dbgo : out l3_debug_in_vector(0 to NCPU-1); dsui : in dsu_in_type; dsuo : out dsu_out_type ); end component; component dsu3_2x generic ( hindex : integer := 0; haddr : integer := 16#900#; hmask : integer := 16#f00#; ncpu : integer := 1; tbits : integer := 30; -- timer bits (instruction trace time tag) tech : integer := DEFMEMTECH; irq : integer := 0; kbytes : integer := 0; testen : integer := 0 ); port ( rst : in std_ulogic; hclk : in std_ulogic; cpuclk : in std_ulogic; ahbmi : in ahb_mst_in_type; ahbsi : in ahb_slv_in_type; ahbso : out ahb_slv_out_type; dbgi : in l3_debug_out_vector(0 to NCPU-1); dbgo : out l3_debug_in_vector(0 to NCPU-1); dsui : in dsu_in_type; dsuo : out dsu_out_type; hclken : in std_ulogic ); end component; component dsu3x generic ( hindex : integer := 0; haddr : integer := 16#900#; hmask : integer := 16#f00#; ncpu : integer := 1; tbits : integer := 30; -- timer bits (instruction trace time tag) tech : integer := DEFMEMTECH; irq : integer := 0; kbytes : integer := 0; clk2x : integer range 0 to 1 := 0; testen : integer := 0 ); port ( rst : in std_ulogic; hclk : in std_ulogic; cpuclk : in std_ulogic; ahbmi : in ahb_mst_in_type; ahbsi : in ahb_slv_in_type; ahbso : out ahb_slv_out_type; dbgi : in l3_debug_out_vector(0 to NCPU-1); dbgo : out l3_debug_in_vector(0 to NCPU-1); dsui : in dsu_in_type; dsuo : out dsu_out_type; hclken : in std_ulogic ); end component; type irq_in_vector is array (Natural range <> ) of l3_irq_in_type; type irq_out_vector is array (Natural range <> ) of l3_irq_out_type; component irqmp generic ( pindex : integer := 0; paddr : integer := 0; pmask : integer := 16#fff#; ncpu : integer := 1; eirq : integer := 0 ); port ( rst : in std_ulogic; clk : in std_ulogic; apbi : in apb_slv_in_type; apbo : out apb_slv_out_type; irqi : in irq_out_vector(0 to ncpu-1); irqo : out irq_in_vector(0 to ncpu-1) ); end component; component irqmp2x generic ( pindex : integer := 0; paddr : integer := 0; pmask : integer := 16#fff#; ncpu : integer := 1; eirq : integer := 0; clkfact : integer := 2 ); port ( rst : in std_ulogic; hclk : in std_ulogic; cpuclk : in std_ulogic; apbi : in apb_slv_in_type; apbo : out apb_slv_out_type; irqi : in irq_out_vector(0 to ncpu-1); irqo : out irq_in_vector(0 to ncpu-1); hclken : in std_ulogic ); end component; component irqamp generic ( pindex : integer := 0; paddr : integer := 0; pmask : integer := 16#fff#; ncpu : integer := 1; eirq : integer := 0; nctrl : integer range 1 to 16 := 1; tstamp : integer range 0 to 16 := 0; wdogen : integer range 0 to 1 := 0; nwdog : integer range 1 to 16 := 1; dynrstaddr : integer range 0 to 1 := 0; rstaddr : integer range 0 to 16#fffff# := 0; extrun : integer range 0 to 1 := 0 ); port ( rst : in std_ulogic; clk : in std_ulogic; apbi : in apb_slv_in_type; apbo : out apb_slv_out_type; irqi : in irq_out_vector(0 to ncpu-1); irqo : out irq_in_vector(0 to ncpu-1); wdog : in std_logic_vector(nwdog-1 downto 0) := (others => '0'); cpurun : in std_logic_vector(ncpu-1 downto 0) := (others => '0') ); end component; component irqamp2x generic ( pindex : integer := 0; paddr : integer := 0; pmask : integer := 16#fff#; ncpu : integer := 1; eirq : integer := 0; nctrl : integer range 1 to 16 := 1; tstamp : integer range 0 to 16 := 0; wdogen : integer range 0 to 1 := 0; nwdog : integer range 1 to 16 := 1; dynrstaddr : integer range 0 to 1 := 0; rstaddr : integer range 0 to 16#fffff# := 0; extrun : integer range 0 to 1 := 0; clkfact : integer := 2 ); port ( rst : in std_ulogic; hclk : in std_ulogic; cpuclk : in std_ulogic; apbi : in apb_slv_in_type; apbo : out apb_slv_out_type; irqi : in irq_out_vector(0 to ncpu-1); irqo : out irq_in_vector(0 to ncpu-1); wdog : in std_logic_vector(nwdog-1 downto 0) := (others => '0'); cpurun : in std_logic_vector(ncpu-1 downto 0) := (others => '0'); hclken : in std_ulogic ); end component; component leon3ftsh generic ( hindex : integer := 0; fabtech : integer range 0 to NTECH := DEFFABTECH; memtech : integer range 0 to NTECH := DEFMEMTECH; nwindows : integer range 2 to 32 := 8; dsu : integer range 0 to 1 := 0; fpu : integer range 0 to 63 := 0; v8 : integer range 0 to 63 := 0; cp : integer range 0 to 1 := 0; mac : integer range 0 to 1 := 0; pclow : integer range 0 to 2 := 2; notag : integer range 0 to 1 := 0; nwp : integer range 0 to 4 := 0; icen : integer range 0 to 1 := 0; irepl : integer range 0 to 3 := 2; isets : integer range 1 to 4 := 1; ilinesize : integer range 4 to 8 := 4; isetsize : integer range 1 to 256 := 1; isetlock : integer range 0 to 1 := 0; dcen : integer range 0 to 1 := 0; drepl : integer range 0 to 3 := 2; dsets : integer range 1 to 4 := 1; dlinesize : integer range 4 to 8 := 4; dsetsize : integer range 1 to 256 := 1; dsetlock : integer range 0 to 1 := 0; dsnoop : integer range 0 to 6 := 0; ilram : integer range 0 to 1 := 0; ilramsize : integer range 1 to 512 := 1; ilramstart : integer range 0 to 255 := 16#8e#; dlram : integer range 0 to 1 := 0; dlramsize : integer range 1 to 512 := 1; dlramstart : integer range 0 to 255 := 16#8f#; mmuen : integer range 0 to 1 := 0; itlbnum : integer range 2 to 64 := 8; dtlbnum : integer range 2 to 64 := 8; tlb_type : integer range 0 to 3 := 1; tlb_rep : integer range 0 to 1 := 0; lddel : integer range 1 to 2 := 2; disas : integer range 0 to 2 := 0; tbuf : integer range 0 to 64 := 0; pwd : integer range 0 to 2 := 2; -- power-down svt : integer range 0 to 1 := 1; -- single vector trapping rstaddr : integer := 0; smp : integer range 0 to 15 := 0; -- support SMP systems iuft : integer range 0 to 4 := 0; fpft : integer range 0 to 4 := 0; cmft : integer range 0 to 1 := 0; iuinj : integer := 0; ceinj : integer range 0 to 3 := 0; cached : integer := 0; netlist : integer := 0; scantest : integer := 0; mmupgsz : integer range 0 to 5 := 0; bp : integer := 1 ); port ( clk : in std_ulogic; -- free-running clock rstn : in std_ulogic; ahbi : in ahb_mst_in_type; ahbo : out ahb_mst_out_type; ahbsi : in ahb_slv_in_type; ahbso : in ahb_slv_out_vector; irqi : in l3_irq_in_type; irqo : out l3_irq_out_type; dbgi : in l3_debug_in_type; dbgo : out l3_debug_out_type; gclk : in std_ulogic; -- gated clock fpui : out grfpu_in_type; fpuo : in grfpu_out_type ); end component; component leon3x generic ( hindex : integer := 0; fabtech : integer range 0 to NTECH := DEFFABTECH; memtech : integer range 0 to NTECH := DEFMEMTECH; nwindows : integer range 2 to 32 := 8; dsu : integer range 0 to 1 := 0; fpu : integer range 0 to 63 := 0; v8 : integer range 0 to 63 := 0; cp : integer range 0 to 1 := 0; mac : integer range 0 to 1 := 0; pclow : integer range 0 to 2 := 2; notag : integer range 0 to 1 := 0; nwp : integer range 0 to 4 := 0; icen : integer range 0 to 1 := 0; irepl : integer range 0 to 3 := 2; isets : integer range 1 to 4 := 1; ilinesize : integer range 4 to 8 := 4; isetsize : integer range 1 to 256 := 1; isetlock : integer range 0 to 1 := 0; dcen : integer range 0 to 1 := 0; drepl : integer range 0 to 3 := 2; dsets : integer range 1 to 4 := 1; dlinesize : integer range 4 to 8 := 4; dsetsize : integer range 1 to 256 := 1; dsetlock : integer range 0 to 1 := 0; dsnoop : integer range 0 to 6 := 0; ilram : integer range 0 to 1 := 0; ilramsize : integer range 1 to 512 := 1; ilramstart : integer range 0 to 255 := 16#8e#; dlram : integer range 0 to 1 := 0; dlramsize : integer range 1 to 512 := 1; dlramstart : integer range 0 to 255 := 16#8f#; mmuen : integer range 0 to 1 := 0; itlbnum : integer range 2 to 64 := 8; dtlbnum : integer range 2 to 64 := 8; tlb_type : integer range 0 to 3 := 1; tlb_rep : integer range 0 to 1 := 0; lddel : integer range 1 to 2 := 2; disas : integer range 0 to 2 := 0; tbuf : integer range 0 to 64 := 0; pwd : integer range 0 to 2 := 2; -- power-down svt : integer range 0 to 1 := 1; -- single vector trapping rstaddr : integer := 0; smp : integer range 0 to 15 := 0; -- support SMP systems iuft : integer range 0 to 4 := 0; fpft : integer range 0 to 4 := 0; cmft : integer range 0 to 1 := 0; iuinj : integer := 0; ceinj : integer range 0 to 3 := 0; cached : integer := 0; clk2x : integer := 1; netlist : integer := 0; scantest : integer := 0; mmupgsz : integer range 0 to 5 := 0; bp : integer := 1 ); port ( clk : in std_ulogic; -- free-running clock gclk2 : in std_ulogic; -- gated 2x clock gfclk2 : in std_ulogic; -- gated 2x FPU clock clk2 : in std_ulogic; -- free-running 2x clock rstn : in std_ulogic; ahbi : in ahb_mst_in_type; ahbo : out ahb_mst_out_type; ahbsi : in ahb_slv_in_type; ahbso : in ahb_slv_out_vector; irqi : in l3_irq_in_type; irqo : out l3_irq_out_type; dbgi : in l3_debug_in_type; dbgo : out l3_debug_out_type; fpui : out grfpu_in_type; fpuo : in grfpu_out_type; clken : in std_ulogic ); end component; -- disassembly dummy module component cpu_disasx port ( clk : in std_ulogic; rstn : in std_ulogic; dummy : out std_ulogic; inst : in std_logic_vector(31 downto 0); pc : in std_logic_vector(31 downto 2); result : in std_logic_vector(31 downto 0); index : in std_logic_vector(3 downto 0); wreg : in std_ulogic; annul : in std_ulogic; holdn : in std_ulogic; pv : in std_ulogic; trap : in std_ulogic; disas : in std_ulogic); end component; end;

gpl-2.0

252274f86c21776ab5c1dcc41fc45efb

0.52544

3.440746

false

mistryalok/Zedboard

learning/opencv_hls/xapp1167_vivado/sw/fast-corner/prj/solution1/syn/vhdl/FIFO_image_filter_p_src_cols_V_2_loc_channel1.vhd

2

4,684

-- ============================================================== -- File generated by Vivado(TM) HLS - High-Level Synthesis from C, C++ and SystemC -- Version: 2014.4 -- Copyright (C) 2014 Xilinx Inc. All rights reserved. -- -- ============================================================== library IEEE; use IEEE.std_logic_1164.all; use IEEE.std_logic_unsigned.all; entity FIFO_image_filter_p_src_cols_V_2_loc_channel1_shiftReg is generic ( DATA_WIDTH : integer := 12; ADDR_WIDTH : integer := 2; DEPTH : integer := 3); port ( clk : in std_logic; data : in std_logic_vector(DATA_WIDTH-1 downto 0); ce : in std_logic; a : in std_logic_vector(ADDR_WIDTH-1 downto 0); q : out std_logic_vector(DATA_WIDTH-1 downto 0)); end FIFO_image_filter_p_src_cols_V_2_loc_channel1_shiftReg; architecture rtl of FIFO_image_filter_p_src_cols_V_2_loc_channel1_shiftReg is --constant DEPTH_WIDTH: integer := 16; type SRL_ARRAY is array (0 to DEPTH-1) of std_logic_vector(DATA_WIDTH-1 downto 0); signal SRL_SIG : SRL_ARRAY; begin p_shift: process (clk) begin if (clk'event and clk = '1') then if (ce = '1') then SRL_SIG <= data & SRL_SIG(0 to DEPTH-2); end if; end if; end process; q <= SRL_SIG(conv_integer(a)); end rtl; library ieee; use ieee.std_logic_1164.all; use ieee.std_logic_unsigned.all; entity FIFO_image_filter_p_src_cols_V_2_loc_channel1 is generic ( MEM_STYLE : string := "shiftreg"; DATA_WIDTH : integer := 12; ADDR_WIDTH : integer := 2; DEPTH : integer := 3); port ( clk : IN STD_LOGIC; reset : IN STD_LOGIC; if_empty_n : OUT STD_LOGIC; if_read_ce : IN STD_LOGIC; if_read : IN STD_LOGIC; if_dout : OUT STD_LOGIC_VECTOR(DATA_WIDTH - 1 downto 0); if_full_n : OUT STD_LOGIC; if_write_ce : IN STD_LOGIC; if_write : IN STD_LOGIC; if_din : IN STD_LOGIC_VECTOR(DATA_WIDTH - 1 downto 0)); end entity; architecture rtl of FIFO_image_filter_p_src_cols_V_2_loc_channel1 is component FIFO_image_filter_p_src_cols_V_2_loc_channel1_shiftReg is generic ( DATA_WIDTH : integer := 12; ADDR_WIDTH : integer := 2; DEPTH : integer := 3); port ( clk : in std_logic; data : in std_logic_vector(DATA_WIDTH-1 downto 0); ce : in std_logic; a : in std_logic_vector(ADDR_WIDTH-1 downto 0); q : out std_logic_vector(DATA_WIDTH-1 downto 0)); end component; signal shiftReg_addr : STD_LOGIC_VECTOR(ADDR_WIDTH - 1 downto 0); signal shiftReg_data, shiftReg_q : STD_LOGIC_VECTOR(DATA_WIDTH - 1 downto 0); signal shiftReg_ce : STD_LOGIC; signal mOutPtr : STD_LOGIC_VECTOR(ADDR_WIDTH downto 0) := (others => '1'); signal internal_empty_n : STD_LOGIC := '0'; signal internal_full_n : STD_LOGIC := '1'; begin if_empty_n <= internal_empty_n; if_full_n <= internal_full_n; shiftReg_data <= if_din; if_dout <= shiftReg_q; process (clk) begin if clk'event and clk = '1' then if reset = '1' then mOutPtr <= (others => '1'); internal_empty_n <= '0'; internal_full_n <= '1'; else if ((if_read and if_read_ce) = '1' and internal_empty_n = '1') and ((if_write and if_write_ce) = '0' or internal_full_n = '0') then mOutPtr <= mOutPtr -1; if (mOutPtr = 0) then internal_empty_n <= '0'; end if; internal_full_n <= '1'; elsif ((if_read and if_read_ce) = '0' or internal_empty_n = '0') and ((if_write and if_write_ce) = '1' and internal_full_n = '1') then mOutPtr <= mOutPtr +1; internal_empty_n <= '1'; if (mOutPtr = DEPTH -2) then internal_full_n <= '0'; end if; end if; end if; end if; end process; shiftReg_addr <= (others => '0') when mOutPtr(ADDR_WIDTH) = '1' else mOutPtr(ADDR_WIDTH-1 downto 0); shiftReg_ce <= (if_write and if_write_ce) and internal_full_n; U_FIFO_image_filter_p_src_cols_V_2_loc_channel1_shiftReg : FIFO_image_filter_p_src_cols_V_2_loc_channel1_shiftReg generic map ( DATA_WIDTH => DATA_WIDTH, ADDR_WIDTH => ADDR_WIDTH, DEPTH => DEPTH) port map ( clk => clk, data => shiftReg_data, ce => shiftReg_ce, a => shiftReg_addr, q => shiftReg_q); end rtl;

gpl-3.0

ed81fefe4a44812fb1a09e70427df479

0.541418

3.42899

false

mistryalok/Zedboard

learning/training/MSD/s05/project_1/project_1.srcs/sources_1/ipshared/xilinx.com/axi_cdma_v4_1/25515467/hdl/src/vhdl/axi_cdma_sf.vhd

1

40,689

------------------------------------------------------------------------------- -- axi_cdma_sf.vhd ------------------------------------------------------------------------------- -- -- ************************************************************************* -- -- (c) Copyright 2010-2011 Xilinx, Inc. All rights reserved. -- -- This file contains confidential and proprietary information -- of Xilinx, Inc. and is protected under U.S. and -- international copyright and other intellectual property -- laws. -- -- DISCLAIMER -- This disclaimer is not a license and does not grant any -- rights to the materials distributed herewith. Except as -- otherwise provided in a valid license issued to you by -- Xilinx, and to the maximum extent permitted by applicable -- law: (1) THESE MATERIALS ARE MADE AVAILABLE "AS IS" AND -- WITH ALL FAULTS, AND XILINX HEREBY DISCLAIMS ALL WARRANTIES -- AND CONDITIONS, EXPRESS, IMPLIED, OR STATUTORY, INCLUDING -- BUT NOT LIMITED TO WARRANTIES OF MERCHANTABILITY, NON- -- INFRINGEMENT, OR FITNESS FOR ANY PARTICULAR PURPOSE; and -- (2) Xilinx shall not be liable (whether in contract or tort, -- including negligence, or under any other theory of -- liability) for any loss or damage of any kind or nature -- related to, arising under or in connection with these -- materials, including for any direct, or any indirect, -- special, incidental, or consequential loss or damage -- (including loss of data, profits, goodwill, or any type of -- loss or damage suffered as a result of any action brought -- by a third party) even if such damage or loss was -- reasonably foreseeable or Xilinx had been advised of the -- possibility of the same. -- -- CRITICAL APPLICATIONS -- Xilinx products are not designed or intended to be fail- -- safe, or for use in any application requiring fail-safe -- performance, such as life-support or safety devices or -- systems, Class III medical devices, nuclear facilities, -- applications related to the deployment of airbags, or any -- other applications that could lead to death, personal -- injury, or severe property or environmental damage -- (individually and collectively, "Critical -- Applications"). Customer assumes the sole risk and -- liability of any use of Xilinx products in Critical -- Applications, subject only to applicable laws and -- regulations governing limitations on product liability. -- -- THIS COPYRIGHT NOTICE AND DISCLAIMER MUST BE RETAINED AS -- PART OF THIS FILE AT ALL TIMES. -- -- ************************************************************************* -- ------------------------------------------------------------------------------- -- Filename: axi_cdma_sf.vhd -- -- Description: -- This file implements the AXI CDMA store and Forward module. -- The design utilizes the AXI DataMover's new address pipelining -- control interfaces. The design is such that predictive address -- pipelining can be supported on the AXI Read Bus without over-commiting -- the internal Data FIFO and potentially throttling the Read Data Channel -- if the Data FIFO goes full. On the AXI Write side, the Write Master is -- only allowed to post AXI WRite Requests if the associated write data needed -- to complete the Write Data transfer is present in the Data FIFO. In -- addition, the Write side logic is such that Write transfer requests can -- be pipelined to the AXI bus based on the Data FIFO contents but ahead of -- the actual Write Data transfers. -- -- -- VHDL-Standard: VHDL'93 ------------------------------------------------------------------------------- ------------------------------------------------------------------------------- library IEEE; use IEEE.std_logic_1164.all; use IEEE.numeric_std.all; library lib_pkg_v1_0; use lib_pkg_v1_0.lib_pkg.all; use lib_pkg_v1_0.lib_pkg.clog2; library lib_srl_fifo_v1_0; use lib_srl_fifo_v1_0.srl_fifo_f; library axi_cdma_v4_1; use axi_cdma_v4_1.axi_cdma_sfifo_autord; ------------------------------------------------------------------------------- entity axi_cdma_sf is generic ( C_WR_ADDR_PIPE_DEPTH : Integer range 1 to 30 := 4; -- This parameter indicates the depth of the DataMover -- write address pipelining queues for the Main data transport -- channels. The effective address pipelining on the AXI4 -- Write Address Channel will be the value assigned plus 2. C_SF_FIFO_DEPTH : Integer range 128 to 8192 := 512; -- Sets the desired depth of the internal Data FIFO. C_MAX_BURST_LEN : Integer range 2 to 256 := 16; -- Indicates the max burst length being used by the external -- AXI4 Master for each AXI4 transfer request. C_DRE_IS_USED : Integer range 0 to 1 := 0; -- Indicates if the external Master is utilizing a DRE on -- the stream input to this module. C_STREAM_DWIDTH : Integer range 8 to 1024 := 32; -- Sets the Stream Data Width for the Input and Output -- Data streams. C_FAMILY : String := "virtex7" -- Indicates the target FPGA Family. ); port ( -- Clock input aclk : in std_logic; -- Primary synchronization clock for the Master side -- interface and internal logic. It is also used -- for the User interface synchronization when -- C_STSCMD_IS_ASYNC = 0. -- Reset input reset : in std_logic; -- Reset used for the internal syncronization logic -- DataMover Read Side Address Pipelining Control Interface --------------- ok_to_post_rd_addr : Out Std_logic; -- Indicates that the transfer token pool has at least -- one token available to borrow rd_addr_posted : In std_logic; -- Indication that a read address has been posted to AXI4 rd_xfer_cmplt : In std_logic; -- Indicates that the Datamover has completed a Read Data -- transfer on the AXI4 -- Read Side Stream In from DataMover MM2S ----------------------------------- sf2sin_tready : Out Std_logic; -- DRE Stream READY input sin2sf_tvalid : In std_logic; -- DRE Stream VALID Output sin2sf_tdata : In std_logic_vector(C_STREAM_DWIDTH-1 downto 0); -- DRE Stream DATA input sin2sf_tkeep : In std_logic_vector((C_STREAM_DWIDTH/8)-1 downto 0); -- DRE Stream STRB input sin2sf_tlast : In std_logic; -- DRE Xfer LAST input -- DataMover Write Side Address Pipelining Control Interface -------------- ok_to_post_wr_addr : Out Std_logic; -- Indicates that the internal FIFO has enough data -- physically present to supply one more max length -- burst transfer or a completion burst -- (tlast asserted) wr_addr_posted : In std_logic; -- Indication that a write address has been posted to AXI4 wr_xfer_cmplt : In Std_logic; -- Indicates that the Datamover has completed a Write Data -- transfer on the AXI4 wr_ld_nxt_len : in std_logic; -- Active high pulse indicating a new transfer LEN qualifier -- has been queued to the DataMover Write Data Controller wr_len : in std_logic_vector(7 downto 0); -- The actual LEN qualifier value that has been queued to the -- DataMover Write Data Controller -- Write Side Stream Out to DataMover S2MM ------------------------------- sout2sf_tready : In std_logic; -- Write READY input from the Stream Master sf2sout_tvalid : Out std_logic; -- Write VALID output to the Stream Master sf2sout_tdata : Out std_logic_vector(C_STREAM_DWIDTH-1 downto 0); -- Write DATA output to the Stream Master sf2sout_tkeep : Out std_logic_vector((C_STREAM_DWIDTH/8)-1 downto 0); -- Write DATA output to the Stream Master sf2sout_tlast : Out std_logic -- Write LAST output to the Stream Master ); end entity axi_cdma_sf; architecture implementation of axi_cdma_sf is attribute DowngradeIPIdentifiedWarnings: string; attribute DowngradeIPIdentifiedWarnings of implementation : architecture is "yes"; -- Functions --------------------------------------------------------------------------- ------------------------------------------------------------------- -- Function -- -- Function Name: funct_get_dbcntr_width -- -- Function Description: -- simple function to set the width of the burst counter -- based on the parameterized max burst length. -- ------------------------------------------------------------------- function funct_get_dbcntr_width (max_burst_length : integer) return integer is Variable temp_width : integer := 0; begin case max_burst_length is when 2 => temp_width := 1; when 4 => temp_width := 2; when 8 => temp_width := 3; when 16 => temp_width := 4; when 32 => temp_width := 5; when 64 => temp_width := 6; when 128 => temp_width := 7; when others => -- 256 beats temp_width := 8; end case; Return (temp_width); end function funct_get_dbcntr_width; ------------------------------------------------------------------- -- Function -- -- Function Name: funct_get_pwr2_depth -- -- Function Description: -- Rounds up to the next power of 2 depth value in an input -- range of 1 to 8192 -- ------------------------------------------------------------------- function funct_get_pwr2_depth (min_depth : integer) return integer is Variable var_temp_depth : Integer := 16; begin if (min_depth = 1) then var_temp_depth := 1; elsif (min_depth = 2) then var_temp_depth := 2; elsif (min_depth <= 4) then var_temp_depth := 4; elsif (min_depth <= 8) then var_temp_depth := 8; elsif (min_depth <= 16) then var_temp_depth := 16; elsif (min_depth <= 32) then var_temp_depth := 32; elsif (min_depth <= 64) then var_temp_depth := 64; elsif (min_depth <= 128) then var_temp_depth := 128; elsif (min_depth <= 256) then var_temp_depth := 256; elsif (min_depth <= 512) then var_temp_depth := 512; elsif (min_depth <= 1024) then var_temp_depth := 1024; elsif (min_depth <= 2048) then var_temp_depth := 2048; elsif (min_depth <= 4096) then var_temp_depth := 4096; else -- assume 8192 depth var_temp_depth := 8192; end if; Return (var_temp_depth); end function funct_get_pwr2_depth; ------------------------------------------------------------------- -- Function -- -- Function Name: funct_get_fifo_cnt_width -- -- Function Description: -- simple function to set the width of the data fifo read -- and write count outputs. ------------------------------------------------------------------- function funct_get_fifo_cnt_width (fifo_depth : integer) return integer is Variable temp_width : integer := 8; begin if (fifo_depth = 1) then temp_width := 1; elsif (fifo_depth = 2) then temp_width := 2; elsif (fifo_depth <= 4) then temp_width := 3; elsif (fifo_depth <= 8) then temp_width := 4; elsif (fifo_depth <= 16) then temp_width := 5; elsif (fifo_depth <= 32) then temp_width := 6; elsif (fifo_depth <= 64) then temp_width := 7; elsif (fifo_depth <= 128) then temp_width := 8; elsif (fifo_depth <= 256) then temp_width := 9; elsif (fifo_depth <= 512) then temp_width := 10; elsif (fifo_depth <= 1024) then temp_width := 11; elsif (fifo_depth <= 2048) then temp_width := 12; elsif (fifo_depth <= 4096) then temp_width := 13; else -- assume 8192 depth temp_width := 14; end if; Return (temp_width); end function funct_get_fifo_cnt_width; ------------------------------------------------------------------- -- Function -- -- Function Name: funct_get_wrcnt_lsrip -- -- Function Description: -- Calculates the ls index of the upper slice of the data fifo -- write count needed to repesent one max burst worth of data -- present in the fifo. -- ------------------------------------------------------------------- function funct_get_wrcnt_lsrip (max_burst_dbeats : integer) return integer is Variable temp_ls_index : Integer := 0; begin if (max_burst_dbeats <= 2) then temp_ls_index := 1; elsif (max_burst_dbeats <= 4) then temp_ls_index := 2; elsif (max_burst_dbeats <= 8) then temp_ls_index := 3; elsif (max_burst_dbeats <= 16) then temp_ls_index := 4; elsif (max_burst_dbeats <= 32) then temp_ls_index := 5; elsif (max_burst_dbeats <= 64) then temp_ls_index := 6; elsif (max_burst_dbeats <= 128) then temp_ls_index := 7; else temp_ls_index := 8; end if; Return (temp_ls_index); end function funct_get_wrcnt_lsrip; ------------------------------------------------------------------- -- Function -- -- Function Name: funct_get_stall_thresh -- -- Function Description: -- Calculates the Stall threshold for the input side of the Data -- FIFO. If DRE is being used by the DataMover, then the threshold -- must be reduced to account for the potential of an extra write -- databeat per request (DRE alignment dependent). -- ------------------------------------------------------------------- function funct_get_stall_thresh (dre_is_used : integer; max_xfer_length : integer; data_fifo_depth : integer; pipeline_delay_clks : integer; fifo_settling_clks : integer) return integer is Constant DRE_PIPE_DELAY : integer := 2; -- clks Variable var_num_max_xfers_allowed : Integer := 0; Variable var_dre_dbeat_overhead : Integer := 0; Variable var_delay_fudge_factor : Integer := 0; Variable var_thresh_headroom : Integer := 0; Variable var_stall_thresh : Integer := 0; begin var_num_max_xfers_allowed := data_fifo_depth/max_xfer_length; var_dre_dbeat_overhead := var_num_max_xfers_allowed * dre_is_used; var_delay_fudge_factor := (dre_is_used * DRE_PIPE_DELAY) + pipeline_delay_clks + fifo_settling_clks; var_thresh_headroom := max_xfer_length + var_dre_dbeat_overhead + var_delay_fudge_factor; -- Scale the result to be in max transfer length increments var_stall_thresh := (data_fifo_depth - var_thresh_headroom)/max_xfer_length; Return (var_stall_thresh); end function funct_get_stall_thresh; -- Constants --------------------------------------------------------------------------- Constant LOGIC_LOW : std_logic := '0'; Constant LOGIC_HIGH : std_logic := '1'; Constant BLK_MEM_FIFO : integer := 1; Constant SRL_FIFO : integer := 0; Constant NOT_NEEDED : integer := 0; Constant WSTB_WIDTH : integer := C_STREAM_DWIDTH/8; -- bits Constant TLAST_WIDTH : integer := 1; -- bits Constant DATA_FIFO_DEPTH : integer := C_SF_FIFO_DEPTH; Constant DATA_FIFO_CNT_WIDTH : integer := funct_get_fifo_cnt_width(DATA_FIFO_DEPTH); Constant DF_WRCNT_RIP_LS_INDEX : integer := funct_get_wrcnt_lsrip(C_MAX_BURST_LEN); Constant DATA_FIFO_WIDTH : integer := C_STREAM_DWIDTH+ WSTB_WIDTH + TLAST_WIDTH; Constant DATA_OUT_MSB_INDEX : integer := C_STREAM_DWIDTH-1; Constant DATA_OUT_LSB_INDEX : integer := 0; Constant TSTRB_OUT_LSB_INDEX : integer := DATA_OUT_MSB_INDEX+1; Constant TSTRB_OUT_MSB_INDEX : integer := (TSTRB_OUT_LSB_INDEX+WSTB_WIDTH)-1; Constant TLAST_OUT_INDEX : integer := TSTRB_OUT_MSB_INDEX+1; Constant DBEAT_CNTR_WIDTH : integer := funct_get_dbcntr_width(C_MAX_BURST_LEN); Constant MAX_BURST_DBEATS : Unsigned(DBEAT_CNTR_WIDTH-1 downto 0) := TO_UNSIGNED(C_MAX_BURST_LEN-1, DBEAT_CNTR_WIDTH); Constant DBC_ONE : Unsigned(DBEAT_CNTR_WIDTH-1 downto 0) := TO_UNSIGNED(1, DBEAT_CNTR_WIDTH); Constant TOKEN_POOL_SIZE : integer := C_SF_FIFO_DEPTH / C_MAX_BURST_LEN; Constant TOKEN_CNTR_WIDTH : integer := clog2(TOKEN_POOL_SIZE)+1; Constant TOKEN_CNT_ZERO : Unsigned(TOKEN_CNTR_WIDTH-1 downto 0) := TO_UNSIGNED(0, TOKEN_CNTR_WIDTH); Constant TOKEN_CNT_ONE : Unsigned(TOKEN_CNTR_WIDTH-1 downto 0) := TO_UNSIGNED(1, TOKEN_CNTR_WIDTH); Constant TOKEN_CNT_MAX : Unsigned(TOKEN_CNTR_WIDTH-1 downto 0) := TO_UNSIGNED(TOKEN_POOL_SIZE, TOKEN_CNTR_WIDTH); Constant THRESH_COMPARE_WIDTH : integer := TOKEN_CNTR_WIDTH+2; Constant RD_PATH_PIPE_DEPTH : integer := 2; -- clocks excluding DRE Constant WRCNT_SETTLING_TIME : integer := 2; -- data fifo push or pop settling clocks Constant RD_ADDR_POST_STALL_THRESH : integer := funct_get_stall_thresh(C_DRE_IS_USED , C_MAX_BURST_LEN , C_SF_FIFO_DEPTH , RD_PATH_PIPE_DEPTH , WRCNT_SETTLING_TIME); Constant RD_ADDR_POST_STALL_THRESH_US : Unsigned(THRESH_COMPARE_WIDTH-1 downto 0) := TO_UNSIGNED(RD_ADDR_POST_STALL_THRESH , THRESH_COMPARE_WIDTH); Constant WR_LEN_FIFO_DWIDTH : integer := 8; Constant WR_LEN_FIFO_DEPTH : integer := funct_get_pwr2_depth(C_WR_ADDR_PIPE_DEPTH + 2); Constant LEN_CNTR_WIDTH : integer := 8; Constant LEN_CNT_ZERO : Unsigned(LEN_CNTR_WIDTH-1 downto 0) := TO_UNSIGNED(0, LEN_CNTR_WIDTH); Constant LEN_CNT_ONE : Unsigned(LEN_CNTR_WIDTH-1 downto 0) := TO_UNSIGNED(1, LEN_CNTR_WIDTH); Constant WR_XFER_CNTR_WIDTH : integer := 8; Constant WR_XFER_CNT_ZERO : Unsigned(WR_XFER_CNTR_WIDTH-1 downto 0) := TO_UNSIGNED(0, WR_XFER_CNTR_WIDTH); Constant WR_XFER_CNT_ONE : Unsigned(WR_XFER_CNTR_WIDTH-1 downto 0) := TO_UNSIGNED(1, WR_XFER_CNTR_WIDTH); Constant UNCOM_WRCNT_1 : Unsigned(DATA_FIFO_CNT_WIDTH-1 downto 0) := TO_UNSIGNED(1, DATA_FIFO_CNT_WIDTH); Constant UNCOM_WRCNT_0 : Unsigned(DATA_FIFO_CNT_WIDTH-1 downto 0) := TO_UNSIGNED(0, DATA_FIFO_CNT_WIDTH); -- Signals --------------------------------------------------------------------------- signal sig_good_sin_strm_dbeat : std_logic := '0'; signal sig_strm_sin_ready : std_logic := '0'; signal sig_sout2sf_tready : std_logic := '0'; signal sig_sf2sout_tvalid : std_logic := '0'; signal sig_sf2sout_tdata : std_logic_vector(C_STREAM_DWIDTH-1 downto 0) := (others => '0'); signal sig_sf2sout_tkeep : std_logic_vector(WSTB_WIDTH-1 downto 0) := (others => '0'); signal sig_sf2sout_tlast : std_logic := '0'; signal sig_push_data_fifo : std_logic := '0'; signal sig_pop_data_fifo : std_logic := '0'; signal sig_data_fifo_full : std_logic := '0'; signal sig_data_fifo_data_in : std_logic_vector(DATA_FIFO_WIDTH-1 downto 0) := (others => '0'); signal sig_data_fifo_dvalid : std_logic := '0'; signal sig_data_fifo_data_out : std_logic_vector(DATA_FIFO_WIDTH-1 downto 0) := (others => '0'); signal sig_data_fifo_wr_cnt : std_logic_vector(DATA_FIFO_CNT_WIDTH-1 downto 0) := (others => '0'); signal sig_fifo_wr_cnt_unsgnd : unsigned(DATA_FIFO_CNT_WIDTH-1 downto 0) := (others => '0'); signal sig_wrcnt_mblen_slice : unsigned(DATA_FIFO_CNT_WIDTH-1 downto DF_WRCNT_RIP_LS_INDEX) := (others => '0'); signal sig_ok_to_post_rd_addr : std_logic := '0'; signal sig_rd_addr_posted : std_logic := '0'; signal sig_rd_xfer_cmplt : std_logic := '0'; signal sig_taking_last_token : std_logic := '0'; signal sig_stall_rd_addr_posts : std_logic := '0'; signal sig_incr_token_cntr : std_logic := '0'; signal sig_decr_token_cntr : std_logic := '0'; signal sig_token_eq_max : std_logic := '0'; signal sig_token_eq_zero : std_logic := '0'; signal sig_token_eq_one : std_logic := '0'; signal sig_token_cntr : Unsigned(TOKEN_CNTR_WIDTH-1 downto 0) := (others => '0'); signal sig_tokens_commited : Unsigned(TOKEN_CNTR_WIDTH-1 downto 0) := (others => '0'); signal sig_commit_plus_actual : unsigned(THRESH_COMPARE_WIDTH-1 downto 0) := (others => '0'); signal sig_ok_to_post_wr_addr : std_logic := '0'; signal sig_wr_addr_posted : std_logic := '0'; signal sig_wr_xfer_cmplt : std_logic := '0'; signal sig_wr_ld_nxt_len : std_logic := '0'; signal sig_push_len_fifo : std_logic := '0'; signal sig_pop_len_fifo : std_logic := '0'; signal sig_len_fifo_full : std_logic := '0'; signal sig_len_fifo_empty : std_logic := '0'; signal sig_len_fifo_data_in : std_logic_vector(WR_LEN_FIFO_DWIDTH-1 downto 0) := (others => '0'); signal sig_len_fifo_data_out : std_logic_vector(WR_LEN_FIFO_DWIDTH-1 downto 0) := (others => '0'); signal sig_len_fifo_len_out_un : unsigned(WR_LEN_FIFO_DWIDTH-1 downto 0) := (others => '0'); signal sig_uncom_wrcnt : unsigned(DATA_FIFO_CNT_WIDTH-1 downto 0) := (others => '0'); signal sig_sub_len_uncom_wrcnt : std_logic := '0'; signal sig_incr_uncom_wrcnt : std_logic := '0'; signal sig_resized_fifo_len : unsigned(DATA_FIFO_CNT_WIDTH-1 downto 0) := (others => '0'); signal sig_num_wr_dbeats_needed : unsigned(DATA_FIFO_CNT_WIDTH-1 downto 0) := (others => '0'); signal sig_enough_dbeats_rcvd : std_logic := '0'; begin --(architecture implementation) -- Read Side (MM2S) Control Flags port connections ok_to_post_rd_addr <= sig_ok_to_post_rd_addr ; sig_rd_addr_posted <= rd_addr_posted ; sig_rd_xfer_cmplt <= rd_xfer_cmplt ; -- Write Side (S2MM) Control Flags port connections ok_to_post_wr_addr <= sig_ok_to_post_wr_addr ; sig_wr_addr_posted <= wr_addr_posted ; sig_wr_xfer_cmplt <= wr_xfer_cmplt ; sig_wr_ld_nxt_len <= wr_ld_nxt_len ; sig_len_fifo_data_in <= wr_len ; -- Output Stream Port connections sig_sout2sf_tready <= sout2sf_tready ; sf2sout_tvalid <= sig_sf2sout_tvalid ; sf2sout_tdata <= sig_sf2sout_tdata ; sf2sout_tkeep <= sig_sf2sout_tkeep ; sf2sout_tlast <= sig_sf2sout_tlast and sig_sf2sout_tvalid ; -- Input Stream port connections sf2sin_tready <= sig_strm_sin_ready; sig_strm_sin_ready <= not(sig_data_fifo_full); -- Throttle if Read Side Data fifo goes full. -- This should never happen if read address -- posting control is working properly. sig_good_sin_strm_dbeat <= sin2sf_tvalid and sig_strm_sin_ready; ---------------------------------------------------------------- -- Token Counter Logic -- Predicting fifo space availability at some point in the -- future is based on managing a virtual pool of transfer tokens. -- A token represents 1 max length burst worth of space in the -- Data FIFO. ---------------------------------------------------------------- -- calculate how many tokens are commited to pending transfers sig_tokens_commited <= TOKEN_CNT_MAX - sig_token_cntr; -- Decrement the token counter when a token is -- borrowed sig_decr_token_cntr <= '1' when (sig_rd_addr_posted = '1' and sig_token_eq_zero = '0') else '0'; -- Increment the token counter when a -- token is returned. sig_incr_token_cntr <= '1' when (sig_rd_xfer_cmplt = '1' and sig_token_eq_max = '0') else '0'; -- Detect when the xfer token count is at max value sig_token_eq_max <= '1' when (sig_token_cntr = TOKEN_CNT_MAX) Else '0'; -- Detect when the xfer token count is at one sig_token_eq_one <= '1' when (sig_token_cntr = TOKEN_CNT_ONE) Else '0'; -- Detect when the xfer token count is at zero sig_token_eq_zero <= '1' when (sig_token_cntr = TOKEN_CNT_ZERO) Else '0'; -- Look ahead to see if the xfer token pool is going empty sig_taking_last_token <= '1' When (sig_token_eq_one = '1' and sig_rd_addr_posted = '1') Else '0'; ------------------------------------------------------------- -- Synchronous Process with Sync Reset -- -- Label: IMP_TOKEN_CMTR -- -- Process Description: -- Implements the Token counter -- ------------------------------------------------------------- IMP_TOKEN_CMTR : process (aclk) begin if (aclk'event and aclk = '1') then if (reset = '1' ) then sig_token_cntr <= TOKEN_CNT_MAX; elsif (sig_incr_token_cntr = '1' and sig_decr_token_cntr = '0') then sig_token_cntr <= sig_token_cntr + TOKEN_CNT_ONE; elsif (sig_incr_token_cntr = '0' and sig_decr_token_cntr = '1') then sig_token_cntr <= sig_token_cntr - TOKEN_CNT_ONE; else null; -- hold current value end if; end if; end process IMP_TOKEN_CMTR; ------------------------------------------------------------- -- Synchronous Process with Sync Reset -- -- Label: IMP_TOKEN_AVAIL_FLAG -- -- Process Description: -- Implements the flag indicating that the AXI Read Master -- can post a read address request on the AXI4 bus. -- -- Read address posting can occur if: -- -- - The write side LEN fifo is not empty. -- - The commited plus actual Data FIFO space is less than -- the stall threshold (a max length read burst can fit -- in the data FIFO without overflow). -- - The max allowed commited read count has not been reached. -- -- The flag is cleared after each address has been posted to -- ensure a second unauthotized post occurs. ------------------------------------------------------------- IMP_TOKEN_AVAIL_FLAG : process (aclk) begin if (aclk'event and aclk = '1') then if (reset = '1' or sig_rd_addr_posted = '1') then sig_ok_to_post_rd_addr <= '0'; else sig_ok_to_post_rd_addr <= not(sig_stall_rd_addr_posts) and -- the commited Data FIFO space is approaching full not(sig_token_eq_zero) and -- max allowed pending reads has not been reached not(sig_taking_last_token); -- the max allowed pending reads is about to be reached end if; end if; end process IMP_TOKEN_AVAIL_FLAG; ---------------------------------------------------------------- -- Data FIFO Logic ------------------------------------------ ---------------------------------------------------------------- -- FIFO Output to output stream attachments sig_sf2sout_tvalid <= sig_data_fifo_dvalid ; sig_sf2sout_tdata <= sig_data_fifo_data_out(DATA_OUT_MSB_INDEX downto DATA_OUT_LSB_INDEX); sig_sf2sout_tkeep <= sig_data_fifo_data_out(TSTRB_OUT_MSB_INDEX downto TSTRB_OUT_LSB_INDEX); sig_sf2sout_tlast <= sig_data_fifo_data_out(TLAST_OUT_INDEX) ; -- Stall Threshold calculations sig_fifo_wr_cnt_unsgnd <= UNSIGNED(sig_data_fifo_wr_cnt); sig_wrcnt_mblen_slice <= sig_fifo_wr_cnt_unsgnd(DATA_FIFO_CNT_WIDTH-1 downto DF_WRCNT_RIP_LS_INDEX); sig_commit_plus_actual <= RESIZE(sig_tokens_commited, THRESH_COMPARE_WIDTH) + RESIZE(sig_wrcnt_mblen_slice, THRESH_COMPARE_WIDTH); -- Compare the commited read space plus the actual used space against the -- stall threshold. Assert the read address posting stall flag if the -- threshold is met or exceeded. sig_stall_rd_addr_posts <= '1' when (sig_commit_plus_actual > RD_ADDR_POST_STALL_THRESH_US) Else '0'; -- FIFO Rd/WR Controls sig_push_data_fifo <= sig_good_sin_strm_dbeat; sig_pop_data_fifo <= sig_sout2sf_tready and sig_data_fifo_dvalid; -- Concatonate the Stream inputs into the single FIFO data in value sig_data_fifo_data_in <= sin2sf_tlast & sin2sf_tkeep & sin2sf_tdata; ------------------------------------------------------------ -- Instance: I_DATA_FIFO -- -- Description: -- Implements the Store and Forward data FIFO (synchronous) -- ------------------------------------------------------------ I_DATA_FIFO : entity axi_cdma_v4_1.axi_cdma_sfifo_autord generic map ( C_DWIDTH => DATA_FIFO_WIDTH , C_DEPTH => DATA_FIFO_DEPTH , C_DATA_CNT_WIDTH => DATA_FIFO_CNT_WIDTH , C_NEED_ALMOST_EMPTY => NOT_NEEDED , C_NEED_ALMOST_FULL => NOT_NEEDED , C_USE_BLKMEM => BLK_MEM_FIFO , C_FAMILY => C_FAMILY ) port map ( -- Inputs SFIFO_Sinit => reset , SFIFO_Clk => aclk , SFIFO_Wr_en => sig_push_data_fifo , SFIFO_Din => sig_data_fifo_data_in , SFIFO_Rd_en => sig_pop_data_fifo , SFIFO_Clr_Rd_Data_Valid => LOGIC_LOW , -- Outputs SFIFO_DValid => sig_data_fifo_dvalid , SFIFO_Dout => sig_data_fifo_data_out , SFIFO_Full => sig_data_fifo_full , SFIFO_Empty => open , SFIFO_Almost_full => open , SFIFO_Almost_empty => open , SFIFO_Rd_count => open , SFIFO_Rd_count_minus1 => open , SFIFO_Wr_count => sig_data_fifo_wr_cnt , SFIFO_Rd_ack => open ); -------------------------------------------------------------------- -- Write Side Control Logic -------------------------------------------------------------------- -- Convert the LEN fifo data output to unsigned sig_len_fifo_len_out_un <= unsigned(sig_len_fifo_data_out); -- Resize the unsigned LEN output to the Data FIFO writecount width sig_resized_fifo_len <= RESIZE(sig_len_fifo_len_out_un , DATA_FIFO_CNT_WIDTH); -- The actual number of databeats needed for the queued write transfer -- is the current LEN fifo output plus 1. sig_num_wr_dbeats_needed <= sig_resized_fifo_len + UNCOM_WRCNT_1; -- Compare the uncommited receved data beat count to that needed -- for the next queued write request. sig_enough_dbeats_rcvd <= '1' When (sig_num_wr_dbeats_needed <= sig_uncom_wrcnt) else '0'; -- Increment the uncommited databeat counter on a good input -- stream databeat (Read Side of SF) sig_incr_uncom_wrcnt <= sig_good_sin_strm_dbeat; -- Subtract the current number of databeats needed from the -- uncommited databeat counter when the associated transfer -- address/qualifiers have been posted to the AXI Write -- Address Channel sig_sub_len_uncom_wrcnt <= sig_wr_addr_posted; ------------------------------------------------------------- -- Synchronous Process with Sync Reset -- -- Label: IMP_UNCOM_DBEAT_CNTR -- -- Process Description: -- Implements the counter that keeps track of the received read -- data beat count that has not been commited to a transfer on -- the write side with a Write Address posting. -- ------------------------------------------------------------- IMP_UNCOM_DBEAT_CNTR : process (aclk) begin if (aclk'event and aclk = '1') then if (reset = '1') then sig_uncom_wrcnt <= UNCOM_WRCNT_0; elsif (sig_incr_uncom_wrcnt = '1' and sig_sub_len_uncom_wrcnt = '1') then sig_uncom_wrcnt <= sig_uncom_wrcnt - sig_resized_fifo_len; elsif (sig_incr_uncom_wrcnt = '1' and sig_sub_len_uncom_wrcnt = '0') then sig_uncom_wrcnt <= sig_uncom_wrcnt + UNCOM_WRCNT_1; elsif (sig_incr_uncom_wrcnt = '0' and sig_sub_len_uncom_wrcnt = '1') then sig_uncom_wrcnt <= sig_uncom_wrcnt - sig_num_wr_dbeats_needed; else null; -- hold current value end if; end if; end process IMP_UNCOM_DBEAT_CNTR; ------------------------------------------------------------- -- Synchronous Process with Sync Reset -- -- Label: IMP_WR_ADDR_POST_FLAG -- -- Process Description: -- Implements the flag indicating that the pending write -- transfer's data beat count has been received on the input -- side of the Data FIFO. This means the Write side can post -- the associated write address to the AXI4 bus and the -- associated write data transfer can complete without CDMA -- throttling the Write Data Channel. -- -- The flag is cleared immediately after an address is posted -- to prohibit a second unauthorized posting while the control -- logic stabilizes to the next LEN FIFO value --. ------------------------------------------------------------- IMP_WR_ADDR_POST_FLAG : process (aclk) begin if (aclk'event and aclk = '1') then if (reset = '1' or sig_wr_addr_posted = '1') then sig_ok_to_post_wr_addr <= '0'; else sig_ok_to_post_wr_addr <= not(sig_len_fifo_empty) and sig_enough_dbeats_rcvd; end if; end if; end process IMP_WR_ADDR_POST_FLAG; ------------------------------------------------------------- -- LEN FIFO logic sig_push_len_fifo <= sig_wr_ld_nxt_len and not(sig_len_fifo_full); sig_pop_len_fifo <= wr_addr_posted and not(sig_len_fifo_empty); ------------------------------------------------------------ -- Instance: I_WR_LEN_FIFO -- -- Description: -- Implement the LEN FIFO using SRL FIFO elements -- ------------------------------------------------------------ I_WR_LEN_FIFO : entity lib_srl_fifo_v1_0.srl_fifo_f generic map ( C_DWIDTH => WR_LEN_FIFO_DWIDTH , C_DEPTH => WR_LEN_FIFO_DEPTH , C_FAMILY => C_FAMILY ) port map ( Clk => aclk , Reset => reset , FIFO_Write => sig_push_len_fifo , Data_In => sig_len_fifo_data_in , FIFO_Read => sig_pop_len_fifo , Data_Out => sig_len_fifo_data_out , FIFO_Empty => sig_len_fifo_empty , FIFO_Full => sig_len_fifo_full , Addr => open ); end implementation;

gpl-3.0

ec7a13ef49b119d66341a495658075c9

0.482047

4.521

false

mistryalok/Zedboard

learning/opencv_hls/xapp1167_vivado/sw/fast-corner/prj/solution1/syn/vhdl/image_filter_reg_int_s.vhd

2

1,002

-- ============================================================== -- RTL generated by Vivado(TM) HLS - High-Level Synthesis from C, C++ and SystemC -- Version: 2014.4 -- Copyright (C) 2014 Xilinx Inc. All rights reserved. -- -- =========================================================== library IEEE; use IEEE.std_logic_1164.all; use IEEE.numeric_std.all; entity image_filter_reg_int_s is port ( ap_clk : IN STD_LOGIC; ap_rst : IN STD_LOGIC; in_r : IN STD_LOGIC_VECTOR (31 downto 0); ap_return : OUT STD_LOGIC_VECTOR (31 downto 0); ap_ce : IN STD_LOGIC ); end; architecture behav of image_filter_reg_int_s is constant ap_const_logic_1 : STD_LOGIC := '1'; constant ap_const_logic_0 : STD_LOGIC := '0'; begin -- assign process. -- process (ap_clk) begin if (ap_clk'event and ap_clk = '1') then if ((ap_const_logic_1 = ap_ce)) then ap_return <= in_r; end if; end if; end process; end behav;

gpl-3.0

c8cc7babbf2badb0221072fe0044b77d

0.522954

3.515789

false

marco-c/leon-nexys2

grlib-gpl-1.3.4-b4140/designs/leon3-avnet-eval-xc4vlx60/config.vhd

1

6,156

----------------------------------------------------------------------------- -- LEON3 Demonstration design test bench configuration -- Copyright (C) 2009 Aeroflex Gaisler ------------------------------------------------------------------------------ library techmap; use techmap.gencomp.all; package config is -- Technology and synthesis options constant CFG_FABTECH : integer := virtex4; constant CFG_MEMTECH : integer := virtex4; constant CFG_PADTECH : integer := virtex4; constant CFG_NOASYNC : integer := 0; constant CFG_SCAN : integer := 0; -- Clock generator constant CFG_CLKTECH : integer := virtex4; constant CFG_CLKMUL : integer := (7); constant CFG_CLKDIV : integer := (5); constant CFG_OCLKDIV : integer := 1; constant CFG_OCLKBDIV : integer := 0; constant CFG_OCLKCDIV : integer := 0; constant CFG_PCIDLL : integer := 0; constant CFG_PCISYSCLK: integer := 0; constant CFG_CLK_NOFB : integer := 0; -- LEON3 processor core constant CFG_LEON3 : integer := 1; constant CFG_NCPU : integer := (1); constant CFG_NWIN : integer := (8); constant CFG_V8 : integer := 16#32# + 4*0; constant CFG_MAC : integer := 0; constant CFG_BP : integer := 1; constant CFG_SVT : integer := 1; constant CFG_RSTADDR : integer := 16#00000#; constant CFG_LDDEL : integer := (1); constant CFG_NOTAG : integer := 0; constant CFG_NWP : integer := (2); constant CFG_PWD : integer := 1*2; constant CFG_FPU : integer := 0 + 16*0 + 32*0; constant CFG_GRFPUSH : integer := 0; constant CFG_ICEN : integer := 1; constant CFG_ISETS : integer := 2; constant CFG_ISETSZ : integer := 8; constant CFG_ILINE : integer := 8; constant CFG_IREPL : integer := 0; constant CFG_ILOCK : integer := 0; constant CFG_ILRAMEN : integer := 0; constant CFG_ILRAMADDR: integer := 16#8E#; constant CFG_ILRAMSZ : integer := 1; constant CFG_DCEN : integer := 1; constant CFG_DSETS : integer := 2; constant CFG_DSETSZ : integer := 4; constant CFG_DLINE : integer := 4; constant CFG_DREPL : integer := 0; constant CFG_DLOCK : integer := 0; constant CFG_DSNOOP : integer := 0 + 0 + 4*0; constant CFG_DFIXED : integer := 16#0#; constant CFG_DLRAMEN : integer := 0; constant CFG_DLRAMADDR: integer := 16#8F#; constant CFG_DLRAMSZ : integer := 1; constant CFG_MMUEN : integer := 1; constant CFG_ITLBNUM : integer := 8; constant CFG_DTLBNUM : integer := 8; constant CFG_TLB_TYPE : integer := 0 + 1*2; constant CFG_TLB_REP : integer := 0; constant CFG_MMU_PAGE : integer := 0; constant CFG_DSU : integer := 1; constant CFG_ITBSZ : integer := 2; constant CFG_ATBSZ : integer := 2; constant CFG_LEON3FT_EN : integer := 0; constant CFG_IUFT_EN : integer := 0; constant CFG_FPUFT_EN : integer := 0; constant CFG_RF_ERRINJ : integer := 0; constant CFG_CACHE_FT_EN : integer := 0; constant CFG_CACHE_ERRINJ : integer := 0; constant CFG_LEON3_NETLIST: integer := 0; constant CFG_DISAS : integer := 0 + 0; constant CFG_PCLOW : integer := 2; -- AMBA settings constant CFG_DEFMST : integer := (0); constant CFG_RROBIN : integer := 1; constant CFG_SPLIT : integer := 0; constant CFG_FPNPEN : integer := 0; constant CFG_AHBIO : integer := 16#FFF#; constant CFG_APBADDR : integer := 16#800#; constant CFG_AHB_MON : integer := 0; constant CFG_AHB_MONERR : integer := 0; constant CFG_AHB_MONWAR : integer := 0; constant CFG_AHB_DTRACE : integer := 0; -- DSU UART constant CFG_AHB_UART : integer := 0; -- JTAG based DSU interface constant CFG_AHB_JTAG : integer := 1; -- Ethernet DSU constant CFG_DSU_ETH : integer := 1 + 0 + 0; constant CFG_ETH_BUF : integer := 4; constant CFG_ETH_IPM : integer := 16#C0A8#; constant CFG_ETH_IPL : integer := 16#010a#; constant CFG_ETH_ENM : integer := 16#020060#; constant CFG_ETH_ENL : integer := 16#000015#; -- LEON2 memory controller constant CFG_MCTRL_LEON2 : integer := 1; constant CFG_MCTRL_RAM8BIT : integer := 0; constant CFG_MCTRL_RAM16BIT : integer := 1; constant CFG_MCTRL_5CS : integer := 0; constant CFG_MCTRL_SDEN : integer := 0; constant CFG_MCTRL_SEPBUS : integer := 0; constant CFG_MCTRL_INVCLK : integer := 0; constant CFG_MCTRL_SD64 : integer := 0; constant CFG_MCTRL_PAGE : integer := 0 + 0; -- DDR controller constant CFG_DDRSP : integer := 0; constant CFG_DDRSP_INIT : integer := 0; constant CFG_DDRSP_FREQ : integer := 100; constant CFG_DDRSP_COL : integer := 9; constant CFG_DDRSP_SIZE : integer := 8; constant CFG_DDRSP_RSKEW : integer := 0; -- Xilinx MIG constant CFG_MIG_DDR2 : integer := 1; constant CFG_MIG_RANKS : integer := (1); constant CFG_MIG_COLBITS : integer := (10); constant CFG_MIG_ROWBITS : integer := (13); constant CFG_MIG_BANKBITS: integer := (2); constant CFG_MIG_HMASK : integer := 16#FE0#; -- AHB ROM constant CFG_AHBROMEN : integer := 0; constant CFG_AHBROPIP : integer := 0; constant CFG_AHBRODDR : integer := 16#000#; constant CFG_ROMADDR : integer := 16#000#; constant CFG_ROMMASK : integer := 16#E00# + 16#000#; -- AHB RAM constant CFG_AHBRAMEN : integer := 0; constant CFG_AHBRSZ : integer := 1; constant CFG_AHBRADDR : integer := 16#A00#; constant CFG_AHBRPIPE : integer := 0; -- Gaisler Ethernet core constant CFG_GRETH : integer := 1; constant CFG_GRETH1G : integer := 0; constant CFG_ETH_FIFO : integer := 32; -- UART 1 constant CFG_UART1_ENABLE : integer := 1; constant CFG_UART1_FIFO : integer := 8; -- LEON3 interrupt controller constant CFG_IRQ3_ENABLE : integer := 1; constant CFG_IRQ3_NSEC : integer := 0; -- Modular timer constant CFG_GPT_ENABLE : integer := 1; constant CFG_GPT_NTIM : integer := (2); constant CFG_GPT_SW : integer := (8); constant CFG_GPT_TW : integer := (32); constant CFG_GPT_IRQ : integer := (8); constant CFG_GPT_SEPIRQ : integer := 1; constant CFG_GPT_WDOGEN : integer := 0; constant CFG_GPT_WDOG : integer := 16#0#; -- GPIO port constant CFG_GRGPIO_ENABLE : integer := 1; constant CFG_GRGPIO_IMASK : integer := 16#0000#; constant CFG_GRGPIO_WIDTH : integer := (8); -- GRLIB debugging constant CFG_DUART : integer := 0; end;

gpl-2.0

23c4bee071778e2625c35685fe26dc45

0.643437

3.608441

false

marco-c/leon-nexys2

grlib-gpl-1.3.4-b4140/designs/leon3-xilinx-sp601/ahb2mig_sp601.vhd

1

17,376

------------------------------------------------------------------------------ -- This file is a part of the GRLIB VHDL IP LIBRARY -- Copyright (C) 2003 - 2008, Gaisler Research -- Copyright (C) 2008 - 2013, Aeroflex Gaisler -- -- This program is free software; you can redistribute it and/or modify -- it under the terms of the GNU General Public License as published by -- the Free Software Foundation; either version 2 of the License, or -- (at your option) any later version. -- -- This program is distributed in the hope that it will be useful, -- but WITHOUT ANY WARRANTY; without even the implied warranty of -- MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the -- GNU General Public License for more details. -- -- You should have received a copy of the GNU General Public License -- along with this program; if not, write to the Free Software -- Foundation, Inc., 59 Temple Place, Suite 330, Boston, MA 02111-1307 USA ------------------------------------------------------------------------------- -- Entity: ahb2mig_sp601 -- File: ahb2mig_sp601.vhd -- Author: Jiri Gaisler - Aeroflex Gaisler AB -- -- This is a AHB-2.0 interface for the Xilinx Spartan-6 MIG. -- One bidir 32-bit port is used for the main AHB bus. ------------------------------------------------------------------------------- library ieee; use ieee.std_logic_1164.all; library grlib; use grlib.amba.all; use grlib.stdlib.all; use grlib.devices.all; entity ahb2mig_sp601 is generic( hindex : integer := 0; haddr : integer := 0; hmask : integer := 16#f00#; pindex : integer := 0; paddr : integer := 0; pmask : integer := 16#fff# ); port( mcb3_dram_dq : inout std_logic_vector(15 downto 0); mcb3_dram_a : out std_logic_vector(12 downto 0); mcb3_dram_ba : out std_logic_vector(2 downto 0); mcb3_dram_ras_n : out std_logic; mcb3_dram_cas_n : out std_logic; mcb3_dram_we_n : out std_logic; mcb3_dram_odt : out std_logic; mcb3_dram_cke : out std_logic; mcb3_dram_dm : out std_logic; mcb3_dram_udqs : inout std_logic; mcb3_rzq : inout std_logic; mcb3_zio : inout std_logic; mcb3_dram_udm : out std_logic; mcb3_dram_dqs : inout std_logic; mcb3_dram_ck : out std_logic; mcb3_dram_ck_n : out std_logic; ahbso : out ahb_slv_out_type; ahbsi : in ahb_slv_in_type; apbi : in apb_slv_in_type; apbo : out apb_slv_out_type; calib_done : out std_logic; test_error : out std_logic; rst_n_syn : in std_logic; rst_n_async : in std_logic; clk_amba : in std_logic; clk_mem_n : in std_logic; clk_mem_p : in std_logic ); end ; architecture rtl of ahb2mig_sp601 is component mig_37 generic ( C3_P0_MASK_SIZE : integer := 4; C3_P0_DATA_PORT_SIZE : integer := 32; C3_P1_MASK_SIZE : integer := 4; C3_P1_DATA_PORT_SIZE : integer := 32; C3_MEMCLK_PERIOD : integer := 5000; -- Memory data transfer clock period. C3_RST_ACT_LOW : integer := 0; -- # = 1 for active low reset, -- # = 0 for active high reset. C3_INPUT_CLK_TYPE : string := "DIFFERENTIAL"; -- input clock type DIFFERENTIAL or SINGLE_ENDED. C3_CALIB_SOFT_IP : string := "TRUE"; -- # = TRUE, Enables the soft calibration logic, -- # = FALSE, Disables the soft calibration logic. C3_SIMULATION : string := "FALSE"; -- # = TRUE, Simulating the design. Useful to reduce the simulation time, -- # = FALSE, Implementing the design. DEBUG_EN : integer := 0; -- # = 1, Enable debug signals/controls, -- = 0, Disable debug signals/controls. C3_MEM_ADDR_ORDER : string := "ROW_BANK_COLUMN"; -- The order in which user address is provided to the memory controller, -- ROW_BANK_COLUMN or BANK_ROW_COLUMN. C3_NUM_DQ_PINS : integer := 16; -- External memory data width. C3_MEM_ADDR_WIDTH : integer := 13; -- External memory address width. C3_MEM_BANKADDR_WIDTH : integer := 3 -- External memory bank address width. ); port ( mcb3_dram_dq : inout std_logic_vector(C3_NUM_DQ_PINS-1 downto 0); mcb3_dram_a : out std_logic_vector(C3_MEM_ADDR_WIDTH-1 downto 0); mcb3_dram_ba : out std_logic_vector(C3_MEM_BANKADDR_WIDTH-1 downto 0); mcb3_dram_ras_n : out std_logic; mcb3_dram_cas_n : out std_logic; mcb3_dram_we_n : out std_logic; mcb3_dram_odt : out std_logic; mcb3_dram_cke : out std_logic; mcb3_dram_dm : out std_logic; mcb3_dram_udqs : inout std_logic; mcb3_dram_udqs_n : inout std_logic; mcb3_rzq : inout std_logic; mcb3_zio : inout std_logic; mcb3_dram_udm : out std_logic; c3_sys_clk_p : in std_logic; c3_sys_clk_n : in std_logic; c3_sys_rst_n : in std_logic; c3_calib_done : out std_logic; c3_clk0 : out std_logic; c3_rst0 : out std_logic; mcb3_dram_dqs : inout std_logic; mcb3_dram_dqs_n : inout std_logic; mcb3_dram_ck : out std_logic; mcb3_dram_ck_n : out std_logic; c3_p0_cmd_clk : in std_logic; c3_p0_cmd_en : in std_logic; c3_p0_cmd_instr : in std_logic_vector(2 downto 0); c3_p0_cmd_bl : in std_logic_vector(5 downto 0); c3_p0_cmd_byte_addr : in std_logic_vector(29 downto 0); c3_p0_cmd_empty : out std_logic; c3_p0_cmd_full : out std_logic; c3_p0_wr_clk : in std_logic; c3_p0_wr_en : in std_logic; c3_p0_wr_mask : in std_logic_vector(C3_P0_MASK_SIZE - 1 downto 0); c3_p0_wr_data : in std_logic_vector(C3_P0_DATA_PORT_SIZE - 1 downto 0); c3_p0_wr_full : out std_logic; c3_p0_wr_empty : out std_logic; c3_p0_wr_count : out std_logic_vector(6 downto 0); c3_p0_wr_underrun : out std_logic; c3_p0_wr_error : out std_logic; c3_p0_rd_clk : in std_logic; c3_p0_rd_en : in std_logic; c3_p0_rd_data : out std_logic_vector(C3_P0_DATA_PORT_SIZE - 1 downto 0); c3_p0_rd_full : out std_logic; c3_p0_rd_empty : out std_logic; c3_p0_rd_count : out std_logic_vector(6 downto 0); c3_p0_rd_overflow : out std_logic; c3_p0_rd_error : out std_logic ); end component; type bstate_type is (idle, start, read1); constant hconfig : ahb_config_type := ( 0 => ahb_device_reg ( VENDOR_GAISLER, GAISLER_MIGDDR2, 0, 0, 0), 4 => ahb_membar(haddr, '1', '1', hmask), -- 5 => ahb_iobar(ioaddr, iomask), others => zero32); constant pconfig : apb_config_type := ( 0 => ahb_device_reg ( VENDOR_GAISLER, GAISLER_MIGDDR2, 0, 0, 0), 1 => apb_iobar(paddr, pmask)); type reg_type is record bstate : bstate_type; cmd_bl : std_logic_vector(5 downto 0); wr_count : std_logic_vector(6 downto 0); rd_cnt : std_logic_vector(5 downto 0); hready : std_logic; hsel : std_logic; hwrite : std_logic; htrans : std_logic_vector(1 downto 0); hburst : std_logic_vector(2 downto 0); hsize : std_logic_vector(2 downto 0); hrdata : std_logic_vector(31 downto 0); haddr : std_logic_vector(31 downto 0); hmaster : std_logic_vector(3 downto 0); end record; type mcb_type is record cmd_en : std_logic; cmd_instr : std_logic_vector(2 downto 0); cmd_empty : std_logic; cmd_full : std_logic; cmd_bl : std_logic_vector(5 downto 0); cmd_byte_addr : std_logic_vector(29 downto 0); wr_full : std_logic; wr_empty : std_logic; wr_underrun : std_logic; wr_error : std_logic; wr_mask : std_logic_vector(3 downto 0); wr_en : std_logic; wr_data : std_logic_vector(31 downto 0); wr_count : std_logic_vector(6 downto 0); rd_data : std_logic_vector(31 downto 0); rd_full : std_logic; rd_empty : std_logic; rd_count : std_logic_vector(6 downto 0); rd_overflow : std_logic; rd_error : std_logic; rd_en : std_logic; end record; signal r, rin : reg_type; signal i : mcb_type; begin comb: process( rst_n_syn, r, ahbsi, i ) variable v : reg_type; variable wmask : std_logic_vector(3 downto 0); variable wr_en : std_logic; variable cmd_en : std_logic; variable cmd_instr : std_logic_vector(2 downto 0); variable rd_en : std_logic; variable cmd_bl : std_logic_vector(5 downto 0); variable hwdata : std_logic_vector(31 downto 0); variable readdata : std_logic_vector(31 downto 0); begin v := r; wr_en := '0'; cmd_en := '0'; cmd_instr := "000"; rd_en := '0'; if (ahbsi.hready = '1') then if (ahbsi.hsel(hindex) and ahbsi.htrans(1)) = '1' then v.hsel := '1'; v.hburst := ahbsi.hburst; v.hwrite := ahbsi.hwrite; v.hsize := ahbsi.hsize; v.hmaster := ahbsi.hmaster; v.hready := '0'; if ahbsi.htrans(0) = '0' then v.haddr := ahbsi.haddr; end if; else v.hsel := '0'; v.hready := '1'; end if; v.htrans := ahbsi.htrans; end if; hwdata := ahbsi.hwdata(15 downto 0) & ahbsi.hwdata(31 downto 16); case r.hsize(1 downto 0) is when "00" => wmask := not decode(r.haddr(1 downto 0)); case r.haddr(1 downto 0) is when "00" => wmask := "1101"; when "01" => wmask := "1110"; when "10" => wmask := "0111"; when others => wmask := "1011"; end case; when "01" => wmask := not decode(r.haddr(1 downto 0)); wmask(3) := wmask(2); wmask(1) := wmask(0); when others => wmask := "0000"; end case; i.wr_mask <= wmask; cmd_bl := r.cmd_bl; case r.bstate is when idle => if v.hsel = '1' then v.bstate := start; v.hready := ahbsi.hwrite and not i.cmd_full and not i.wr_full; v.haddr := ahbsi.haddr; end if; v.cmd_bl := (others => '0'); when start => if r.hwrite = '1' then v.haddr := r.haddr; if r.hready = '1' then v.cmd_bl := r.cmd_bl + 1; v.hready := '1'; wr_en := '1'; if (ahbsi.htrans /= "11") then if v.hsel = '1' then if (ahbsi.hwrite = '0') or (i.wr_count >= "0000100") then v.hready := '0'; else v.hready := '1'; end if; else v.bstate := idle; end if; v.cmd_bl := (others => '0'); v.haddr := ahbsi.haddr; cmd_en := '1'; elsif (i.cmd_full = '1') then v.hready := '0'; elsif (i.wr_count >= "0101111") then v.hready := '0'; cmd_en := '1'; v.cmd_bl := (others => '0'); v.haddr := ahbsi.haddr; end if; else if (i.cmd_full = '0') and (i.wr_count <= "0001111") then v.hready := '1'; end if; end if; else if i.cmd_full = '0' then cmd_en := '1'; cmd_instr(0) := '1'; v.cmd_bl := "000" & not r.haddr(4 downto 2); cmd_bl := v.cmd_bl; v.bstate := read1; end if; end if; when read1 => v.hready := '0'; if (r.rd_cnt = "000000") then -- flush data from previous line if (i.rd_empty = '0') or ((r.hready = '1') and (ahbsi.htrans /= "11")) then v.hrdata(31 downto 0) := i.rd_data(15 downto 0) & i.rd_data(31 downto 16); v.hready := '1'; if (i.rd_empty = '0') then v.cmd_bl := r.cmd_bl - 1; rd_en := '1'; end if; if (r.cmd_bl = "000000") or (ahbsi.htrans /= "11") then if (ahbsi.hsel(hindex) = '1') and (ahbsi.htrans = "10") and (r.hready = '1') then v.bstate := start; v.hready := ahbsi.hwrite and not i.cmd_full and not i.wr_full; v.cmd_bl := (others => '0'); else v.bstate := idle; end if; if (i.rd_empty = '1') then v.rd_cnt := r.cmd_bl + 1; else v.rd_cnt := r.cmd_bl; end if; end if; end if; end if; when others => end case; readdata := (others => '0'); -- case apbi.paddr(5 downto 2) is -- when "0000" => readdata(nbits-1 downto 0) := r.din2; -- when "0001" => readdata(nbits-1 downto 0) := r.dout; -- when others => -- end case; readdata(20 downto 0) := i.rd_error & i.rd_overflow & i.wr_error & i.wr_underrun & i.cmd_full & i.rd_full & i.rd_empty & i.wr_full & i.wr_empty & r.rd_cnt & r.cmd_bl; if (r.rd_cnt /= "000000") and (i.rd_empty = '0') then rd_en := '1'; v.rd_cnt := r.rd_cnt - 1; end if; if rst_n_syn = '0' then v.rd_cnt := "000000"; v.bstate := idle; v.hready := '1'; end if; rin <= v; apbo.prdata <= readdata; i.rd_en <= rd_en; i.wr_en <= wr_en; i.cmd_bl <= cmd_bl; i.cmd_en <= cmd_en; i.cmd_instr <= cmd_instr; i.wr_data <= hwdata; end process; i.cmd_byte_addr <= r.haddr(29 downto 2) & "00"; ahbso.hready <= r.hready; ahbso.hresp <= "00"; --r.hresp; ahbso.hrdata <= r.hrdata; ahbso.hconfig <= hconfig; ahbso.hirq <= (others => '0'); ahbso.hindex <= hindex; ahbso.hsplit <= (others => '0'); apbo.pindex <= pindex; apbo.pconfig <= pconfig; regs : process(clk_amba) begin if rising_edge(clk_amba) then r <= rin; end if; end process; MCB_inst : entity work.mig_37 generic map( C3_P0_MASK_SIZE => 4, C3_P0_DATA_PORT_SIZE => 32, C3_P1_MASK_SIZE => 4, C3_P1_DATA_PORT_SIZE => 32, C3_MEMCLK_PERIOD => 5000, C3_RST_ACT_LOW => 1, -- C3_INPUT_CLK_TYPE => "DIFFERENTIAL", C3_CALIB_SOFT_IP => "TRUE", -- pragma translate_off C3_SIMULATION => "TRUE", -- pragma translate_on C3_MEM_ADDR_ORDER => "BANK_ROW_COLUMN", C3_NUM_DQ_PINS => 16, C3_MEM_ADDR_WIDTH => 13, C3_MEM_BANKADDR_WIDTH => 3 -- C3_MC_CALIB_BYPASS => "YES" ) port map ( mcb3_dram_dq => mcb3_dram_dq, mcb3_dram_a => mcb3_dram_a, mcb3_dram_ba => mcb3_dram_ba, mcb3_dram_ras_n => mcb3_dram_ras_n, mcb3_dram_cas_n => mcb3_dram_cas_n, mcb3_dram_we_n => mcb3_dram_we_n, mcb3_dram_odt => mcb3_dram_odt, mcb3_dram_cke => mcb3_dram_cke, mcb3_dram_dm => mcb3_dram_dm, mcb3_dram_udqs => mcb3_dram_udqs, mcb3_rzq => mcb3_rzq, mcb3_zio => mcb3_zio, mcb3_dram_udm => mcb3_dram_udm, c3_sys_clk_p => clk_mem_p, c3_sys_clk_n => clk_mem_n, c3_sys_rst_n => rst_n_async, c3_calib_done => calib_done, c3_clk0 => open, c3_rst0 => open, mcb3_dram_dqs => mcb3_dram_dqs, mcb3_dram_ck => mcb3_dram_ck, mcb3_dram_ck_n => mcb3_dram_ck_n, c3_p0_cmd_clk => clk_amba, c3_p0_cmd_en => i.cmd_en, c3_p0_cmd_instr => i.cmd_instr, c3_p0_cmd_bl => i.cmd_bl, c3_p0_cmd_byte_addr => i.cmd_byte_addr, c3_p0_cmd_empty => i.cmd_empty, c3_p0_cmd_full => i.cmd_full, c3_p0_wr_clk => clk_amba, c3_p0_wr_en => i.wr_en, c3_p0_wr_mask => i.wr_mask, c3_p0_wr_data => i.wr_data, c3_p0_wr_full => i.wr_full, c3_p0_wr_empty => i.wr_empty, c3_p0_wr_count => i.wr_count, c3_p0_wr_underrun => i.wr_underrun, c3_p0_wr_error => i.wr_error, c3_p0_rd_clk => clk_amba, c3_p0_rd_en => i.rd_en, c3_p0_rd_data => i.rd_data, c3_p0_rd_full => i.rd_full, c3_p0_rd_empty => i.rd_empty, c3_p0_rd_count => i.rd_count, c3_p0_rd_overflow => i.rd_overflow, c3_p0_rd_error => i.rd_error ); end;

gpl-2.0

70231b66c9d79aa795f970bf84697229

0.493669

3.176019

false

marco-c/leon-nexys2

grlib-gpl-1.3.4-b4140/lib/techmap/unisim/tap_unisim.vhd

1

24,308

------------------------------------------------------------------------------ -- This file is a part of the GRLIB VHDL IP LIBRARY -- Copyright (C) 2003 - 2008, Gaisler Research -- Copyright (C) 2008 - 2013, Aeroflex Gaisler -- -- This program is free software; you can redistribute it and/or modify -- it under the terms of the GNU General Public License as published by -- the Free Software Foundation; either version 2 of the License, or -- (at your option) any later version. -- -- This program is distributed in the hope that it will be useful, -- but WITHOUT ANY WARRANTY; without even the implied warranty of -- MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the -- GNU General Public License for more details. -- -- You should have received a copy of the GNU General Public License -- along with this program; if not, write to the Free Software -- Foundation, Inc., 59 Temple Place, Suite 330, Boston, MA 02111-1307 USA ----------------------------------------------------------------------------- -- Entity: tap_xilinx -- File: tap_xilinx.vhd -- Author: Edvin Catovic, Jiri Gaisler - Gaisler Research -- Description: Xilinx TAP controllers wrappers ------------------------------------------------------------------------------ library ieee; use ieee.std_logic_1164.all; -- pragma translate_off library unisim; use unisim.all; -- pragma translate_on entity virtex_tap is port ( tapi_tdo1 : in std_ulogic; tapi_tdo2 : in std_ulogic; tapo_tck : out std_ulogic; tapo_tdi : out std_ulogic; tapo_rst : out std_ulogic; tapo_capt : out std_ulogic; tapo_shft : out std_ulogic; tapo_upd : out std_ulogic; tapo_xsel1 : out std_ulogic; tapo_xsel2 : out std_ulogic ); end; architecture rtl of virtex_tap is component BSCAN_VIRTEX port (CAPTURE : out STD_ULOGIC; DRCK1 : out STD_ULOGIC; DRCK2 : out STD_ULOGIC; RESET : out STD_ULOGIC; SEL1 : out STD_ULOGIC; SEL2 : out STD_ULOGIC; SHIFT : out STD_ULOGIC; TDI : out STD_ULOGIC; UPDATE : out STD_ULOGIC; TDO1 : in STD_ULOGIC; TDO2 : in STD_ULOGIC); end component; signal drck1, drck2, sel1, sel2 : std_ulogic; attribute dont_touch : boolean; attribute dont_touch of u0 : label is true; begin u0 : BSCAN_VIRTEX port map ( DRCK1 => drck1, DRCK2 => drck2, RESET => tapo_rst, SEL1 => sel1, SEL2 => sel2, SHIFT => tapo_shft, TDI => tapo_tdi, UPDATE => tapo_upd, TDO1 => tapi_tdo1, TDO2 => tapi_tdo2); tapo_tck <= drck1 when sel1 = '1' else drck2; tapo_xsel1 <= sel1; tapo_xsel2 <= sel2; tapo_capt <= '0'; end; library ieee; use ieee.std_logic_1164.all; -- pragma translate_off library unisim; use unisim.all; -- pragma translate_on entity virtex2_tap is port ( tapi_tdo1 : in std_ulogic; tapi_tdo2 : in std_ulogic; tapo_tck : out std_ulogic; tapo_tdi : out std_ulogic; tapo_rst : out std_ulogic; tapo_capt : out std_ulogic; tapo_shft : out std_ulogic; tapo_upd : out std_ulogic; tapo_xsel1 : out std_ulogic; tapo_xsel2 : out std_ulogic ); end; architecture rtl of virtex2_tap is component BSCAN_VIRTEX2 port (CAPTURE : out STD_ULOGIC; DRCK1 : out STD_ULOGIC; DRCK2 : out STD_ULOGIC; RESET : out STD_ULOGIC; SEL1 : out STD_ULOGIC; SEL2 : out STD_ULOGIC; SHIFT : out STD_ULOGIC; TDI : out STD_ULOGIC; UPDATE : out STD_ULOGIC; TDO1 : in STD_ULOGIC; TDO2 : in STD_ULOGIC); end component; signal drck1, drck2, sel1, sel2 : std_ulogic; attribute dont_touch : boolean; attribute dont_touch of u0 : label is true; begin u0 : BSCAN_VIRTEX2 port map (CAPTURE => tapo_capt, DRCK1 => drck1, DRCK2 => drck2, RESET => tapo_rst, SEL1 => sel1, SEL2 => sel2, SHIFT => tapo_shft, TDI => tapo_tdi, UPDATE => tapo_upd, TDO1 => tapi_tdo1, TDO2 => tapi_tdo2); tapo_tck <= drck1 when sel1 = '1' else drck2; tapo_xsel1 <= sel1; tapo_xsel2 <= sel2; end; library ieee; use ieee.std_logic_1164.all; -- pragma translate_off library unisim; use unisim.BSCAN_SPARTAN3; -- pragma translate_on entity spartan3_tap is port ( tapi_tdo1 : in std_ulogic; tapi_tdo2 : in std_ulogic; tapo_tck : out std_ulogic; tapo_tdi : out std_ulogic; tapo_rst : out std_ulogic; tapo_capt : out std_ulogic; tapo_shft : out std_ulogic; tapo_upd : out std_ulogic; tapo_xsel1 : out std_ulogic; tapo_xsel2 : out std_ulogic ); end; architecture rtl of spartan3_tap is component BSCAN_SPARTAN3 port (CAPTURE : out STD_ULOGIC; DRCK1 : out STD_ULOGIC; DRCK2 : out STD_ULOGIC; RESET : out STD_ULOGIC; SEL1 : out STD_ULOGIC; SEL2 : out STD_ULOGIC; SHIFT : out STD_ULOGIC; TDI : out STD_ULOGIC; UPDATE : out STD_ULOGIC; TDO1 : in STD_ULOGIC; TDO2 : in STD_ULOGIC); end component; signal drck1, drck2, sel1, sel2 : std_ulogic; attribute dont_touch : boolean; attribute dont_touch of u0 : label is true; begin u0 : BSCAN_SPARTAN3 port map (CAPTURE => tapo_capt, DRCK1 => drck1, DRCK2 => drck2, RESET => tapo_rst, SEL1 => sel1, SEL2 => sel2, SHIFT => tapo_shft, TDI => tapo_tdi, UPDATE => tapo_upd, TDO1 => tapi_tdo1, TDO2 => tapi_tdo2); tapo_tck <= drck1 when sel1 = '1' else drck2; tapo_xsel1 <= sel1; tapo_xsel2 <= sel2; end; library ieee; use ieee.std_logic_1164.all; -- pragma translate_off library unisim; use unisim.BSCAN_VIRTEX4; -- pragma translate_on entity virtex4_tap is port ( tapi_tdo1 : in std_ulogic; tapi_tdo2 : in std_ulogic; tapo_tck : out std_ulogic; tapo_tdi : out std_ulogic; tapo_rst : out std_ulogic; tapo_capt : out std_ulogic; tapo_shft : out std_ulogic; tapo_upd : out std_ulogic; tapo_xsel1 : out std_ulogic; tapo_xsel2 : out std_ulogic ); end; architecture rtl of virtex4_tap is component BSCAN_VIRTEX4 generic ( JTAG_CHAIN : integer := 1); port ( CAPTURE : out std_ulogic; DRCK : out std_ulogic; RESET : out std_ulogic; SEL : out std_ulogic; SHIFT : out std_ulogic; TDI : out std_ulogic; UPDATE : out std_ulogic; TDO : in std_ulogic); end component; signal drck1, drck2, sel1, sel2 : std_ulogic; signal capt1, capt2, rst1, rst2 : std_ulogic; signal shift1, shift2, tdi1, tdi2 : std_ulogic; signal update1, update2 : std_ulogic; attribute dont_touch : boolean; attribute dont_touch of u0 : label is true; attribute dont_touch of u1 : label is true; begin u0 : BSCAN_VIRTEX4 generic map (JTAG_CHAIN => 1) port map ( CAPTURE => capt1, DRCK => drck1, RESET => rst1, SEL => sel1, SHIFT => shift1, TDI => tdi1, UPDATE => update1, TDO => tapi_tdo1 ); u1 : BSCAN_VIRTEX4 generic map (JTAG_CHAIN => 2) port map ( CAPTURE => capt2, DRCK => drck2, RESET => rst2, SEL => sel2, SHIFT => shift2, TDI => tdi2, UPDATE => update2, TDO => tapi_tdo2 ); tapo_capt <= capt1 when sel1 = '1' else capt2; tapo_tck <= drck1 when sel1 = '1' else drck2; tapo_rst <= rst1 when sel1 = '1' else rst2; tapo_shft <= shift1 when sel1 = '1' else shift2; tapo_tdi <= tdi1 when sel1 = '1' else tdi2; tapo_upd <= update1 when sel1 ='1' else update2; tapo_xsel1 <= sel1; tapo_xsel2 <= sel2; end; library ieee; use ieee.std_logic_1164.all; -- pragma translate_off library unisim; use unisim.BSCAN_VIRTEX5; -- pragma translate_on entity virtex5_tap is port ( tapi_tdo1 : in std_ulogic; tapi_tdo2 : in std_ulogic; tapo_tck : out std_ulogic; tapo_tdi : out std_ulogic; tapo_rst : out std_ulogic; tapo_capt : out std_ulogic; tapo_shft : out std_ulogic; tapo_upd : out std_ulogic; tapo_xsel1 : out std_ulogic; tapo_xsel2 : out std_ulogic ); end; architecture rtl of virtex5_tap is component BSCAN_VIRTEX5 generic ( JTAG_CHAIN : integer := 1); port ( CAPTURE : out std_ulogic; DRCK : out std_ulogic; RESET : out std_ulogic; SEL : out std_ulogic; SHIFT : out std_ulogic; TDI : out std_ulogic; UPDATE : out std_ulogic; TDO : in std_ulogic); end component; signal drck1, drck2, sel1, sel2 : std_ulogic; signal capt1, capt2, rst1, rst2 : std_ulogic; signal shift1, shift2, tdi1, tdi2 : std_ulogic; signal update1, update2 : std_ulogic; attribute dont_touch : boolean; attribute dont_touch of u0 : label is true; attribute dont_touch of u1 : label is true; begin u0 : BSCAN_VIRTEX5 generic map (JTAG_CHAIN => 1) port map ( CAPTURE => capt1, DRCK => drck1, RESET => rst1, SEL => sel1, SHIFT => shift1, TDI => tdi1, UPDATE => update1, TDO => tapi_tdo1 ); u1 : BSCAN_VIRTEX5 generic map (JTAG_CHAIN => 2) port map ( CAPTURE => capt2, DRCK => drck2, RESET => rst2, SEL => sel2, SHIFT => shift2, TDI => tdi2, UPDATE => update2, TDO => tapi_tdo2 ); tapo_capt <= capt1 when sel1 = '1' else capt2; tapo_tck <= drck1 when sel1 = '1' else drck2; tapo_rst <= rst1 when sel1 = '1' else rst2; tapo_shft <= shift1 when sel1 = '1' else shift2; tapo_tdi <= tdi1 when sel1 = '1' else tdi2; tapo_upd <= update1 when sel1 ='1' else update2; tapo_xsel1 <= sel1; tapo_xsel2 <= sel2; end; library ieee; use ieee.std_logic_1164.all; -- pragma translate_off library unisim; use unisim.all; -- pragma translate_on entity virtex6_tap is port ( tapi_tdo1 : in std_ulogic; tapi_tdo2 : in std_ulogic; tapo_tck : out std_ulogic; tapo_tdi : out std_ulogic; tapo_rst : out std_ulogic; tapo_capt : out std_ulogic; tapo_shft : out std_ulogic; tapo_upd : out std_ulogic; tapo_xsel1 : out std_ulogic; tapo_xsel2 : out std_ulogic ); end; architecture rtl of virtex6_tap is component BSCAN_VIRTEX6 generic ( DISABLE_JTAG : boolean := FALSE; JTAG_CHAIN : integer := 1 ); port ( CAPTURE : out std_ulogic := 'H'; DRCK : out std_ulogic := 'H'; RESET : out std_ulogic := 'H'; RUNTEST : out std_ulogic := 'L'; SEL : out std_ulogic := 'L'; SHIFT : out std_ulogic := 'L'; TCK : out std_ulogic := 'L'; TDI : out std_ulogic := 'L'; TMS : out std_ulogic := 'L'; UPDATE : out std_ulogic := 'L'; TDO : in std_ulogic := 'X' ); end component; signal drck1, drck2, sel1, sel2 : std_ulogic; signal capt1, capt2, rst1, rst2 : std_ulogic; signal shift1, shift2, tdi1, tdi2 : std_ulogic; signal update1, update2 : std_ulogic; attribute dont_touch : boolean; attribute dont_touch of u0 : label is true; attribute dont_touch of u1 : label is true; begin u0 : BSCAN_VIRTEX6 generic map (JTAG_CHAIN => 1) port map ( CAPTURE => capt1, DRCK => drck1, RESET => rst1, SEL => sel1, SHIFT => shift1, TDI => tdi1, UPDATE => update1, TDO => tapi_tdo1, TCK => tapo_tck ); u1 : BSCAN_VIRTEX6 generic map (JTAG_CHAIN => 2) port map ( CAPTURE => capt2, DRCK => drck2, RESET => rst2, SEL => sel2, SHIFT => shift2, TDI => tdi2, UPDATE => update2, TDO => tapi_tdo2 ); tapo_capt <= capt1 when sel1 = '1' else capt2; tapo_rst <= rst1 when sel1 = '1' else rst2; tapo_shft <= shift1 when sel1 = '1' else shift2; tapo_tdi <= tdi1 when sel1 = '1' else tdi2; tapo_upd <= update1 when sel1 ='1' else update2; tapo_xsel1 <= sel1; tapo_xsel2 <= sel2; end; library ieee; use ieee.std_logic_1164.all; -- pragma translate_off library unisim; use unisim.all; -- pragma translate_on entity spartan6_tap is port ( tapi_tdo1 : in std_ulogic; tapi_tdo2 : in std_ulogic; tapo_tck : out std_ulogic; tapo_tdi : out std_ulogic; tapo_rst : out std_ulogic; tapo_capt : out std_ulogic; tapo_shft : out std_ulogic; tapo_upd : out std_ulogic; tapo_xsel1 : out std_ulogic; tapo_xsel2 : out std_ulogic ); end; architecture rtl of spartan6_tap is component BSCAN_SPARTAN6 generic ( JTAG_CHAIN : integer := 1 ); port ( CAPTURE : out std_ulogic := 'H'; DRCK : out std_ulogic := 'H'; RESET : out std_ulogic := 'H'; RUNTEST : out std_ulogic := 'L'; SEL : out std_ulogic := 'L'; SHIFT : out std_ulogic := 'L'; TCK : out std_ulogic := 'L'; TDI : out std_ulogic := 'L'; TMS : out std_ulogic := 'L'; UPDATE : out std_ulogic := 'L'; TDO : in std_ulogic := 'X' ); end component; signal drck1, drck2, sel1, sel2 : std_ulogic; signal capt1, capt2, rst1, rst2 : std_ulogic; signal shift1, shift2, tdi1, tdi2 : std_ulogic; signal update1, update2 : std_ulogic; attribute dont_touch : boolean; attribute dont_touch of u0 : label is true; attribute dont_touch of u1 : label is true; begin u0 : BSCAN_SPARTAN6 generic map (JTAG_CHAIN => 1) port map ( CAPTURE => capt1, DRCK => drck1, RESET => rst1, SEL => sel1, SHIFT => shift1, TDI => tdi1, UPDATE => update1, TDO => tapi_tdo1, TCK => tapo_tck ); u1 : BSCAN_SPARTAN6 generic map (JTAG_CHAIN => 2) port map ( CAPTURE => capt2, DRCK => drck2, RESET => rst2, SEL => sel2, SHIFT => shift2, TDI => tdi2, UPDATE => update2, TDO => tapi_tdo2 ); tapo_capt <= capt1 when sel1 = '1' else capt2; tapo_rst <= rst1 when sel1 = '1' else rst2; tapo_shft <= shift1 when sel1 = '1' else shift2; tapo_tdi <= tdi1 when sel1 = '1' else tdi2; tapo_upd <= update1 when sel1 ='1' else update2; tapo_xsel1 <= sel1; tapo_xsel2 <= sel2; end; library ieee; use ieee.std_logic_1164.all; -- pragma translate_off library unisim; use unisim.all; -- pragma translate_on entity virtex7_tap is port ( tapi_tdo1 : in std_ulogic; tapi_tdo2 : in std_ulogic; tapo_tck : out std_ulogic; tapo_tdi : out std_ulogic; tapo_rst : out std_ulogic; tapo_capt : out std_ulogic; tapo_shft : out std_ulogic; tapo_upd : out std_ulogic; tapo_xsel1 : out std_ulogic; tapo_xsel2 : out std_ulogic ); end; architecture rtl of virtex7_tap is component BSCANE2 generic ( DISABLE_JTAG : string := "FALSE"; JTAG_CHAIN : integer := 1 ); port ( CAPTURE : out std_ulogic := 'H'; DRCK : out std_ulogic := 'H'; RESET : out std_ulogic := 'H'; RUNTEST : out std_ulogic := 'L'; SEL : out std_ulogic := 'L'; SHIFT : out std_ulogic := 'L'; TCK : out std_ulogic := 'L'; TDI : out std_ulogic := 'L'; TMS : out std_ulogic := 'L'; UPDATE : out std_ulogic := 'L'; TDO : in std_ulogic := 'X' ); end component; signal drck1, drck2, sel1, sel2 : std_ulogic; signal capt1, capt2, rst1, rst2 : std_ulogic; signal shift1, shift2, tdi1, tdi2 : std_ulogic; signal update1, update2 : std_ulogic; attribute dont_touch : boolean; attribute dont_touch of u0 : label is true; attribute dont_touch of u1 : label is true; begin u0 : BSCANE2 generic map (JTAG_CHAIN => 1) port map ( CAPTURE => capt1, DRCK => drck1, RESET => rst1, SEL => sel1, SHIFT => shift1, TDI => tdi1, UPDATE => update1, TDO => tapi_tdo1, TCK => tapo_tck ); u1 : BSCANE2 generic map (JTAG_CHAIN => 2) port map ( CAPTURE => capt2, DRCK => drck2, RESET => rst2, SEL => sel2, SHIFT => shift2, TDI => tdi2, UPDATE => update2, TDO => tapi_tdo2 ); tapo_capt <= capt1 when sel1 = '1' else capt2; tapo_rst <= rst1 when sel1 = '1' else rst2; tapo_shft <= shift1 when sel1 = '1' else shift2; tapo_tdi <= tdi1 when sel1 = '1' else tdi2; tapo_upd <= update1 when sel1 ='1' else update2; tapo_xsel1 <= sel1; tapo_xsel2 <= sel2; end; library ieee; use ieee.std_logic_1164.all; -- pragma translate_off library unisim; use unisim.all; -- pragma translate_on entity kintex7_tap is port ( tapi_tdo1 : in std_ulogic; tapi_tdo2 : in std_ulogic; tapo_tck : out std_ulogic; tapo_tdi : out std_ulogic; tapo_rst : out std_ulogic; tapo_capt : out std_ulogic; tapo_shft : out std_ulogic; tapo_upd : out std_ulogic; tapo_xsel1 : out std_ulogic; tapo_xsel2 : out std_ulogic ); end; architecture rtl of kintex7_tap is component BSCANE2 generic ( DISABLE_JTAG : string := "FALSE"; JTAG_CHAIN : integer := 1 ); port ( CAPTURE : out std_ulogic := 'H'; DRCK : out std_ulogic := 'H'; RESET : out std_ulogic := 'H'; RUNTEST : out std_ulogic := 'L'; SEL : out std_ulogic := 'L'; SHIFT : out std_ulogic := 'L'; TCK : out std_ulogic := 'L'; TDI : out std_ulogic := 'L'; TMS : out std_ulogic := 'L'; UPDATE : out std_ulogic := 'L'; TDO : in std_ulogic := 'X' ); end component; signal drck1, drck2, sel1, sel2 : std_ulogic; signal capt1, capt2, rst1, rst2 : std_ulogic; signal shift1, shift2, tdi1, tdi2 : std_ulogic; signal update1, update2 : std_ulogic; attribute dont_touch : boolean; attribute dont_touch of u0 : label is true; attribute dont_touch of u1 : label is true; begin u0 : BSCANE2 generic map (JTAG_CHAIN => 1) port map ( CAPTURE => capt1, DRCK => drck1, RESET => rst1, SEL => sel1, SHIFT => shift1, TDI => tdi1, UPDATE => update1, TDO => tapi_tdo1, TCK => tapo_tck ); u1 : BSCANE2 generic map (JTAG_CHAIN => 2) port map ( CAPTURE => capt2, DRCK => drck2, RESET => rst2, SEL => sel2, SHIFT => shift2, TDI => tdi2, UPDATE => update2, TDO => tapi_tdo2 ); tapo_capt <= capt1 when sel1 = '1' else capt2; tapo_rst <= rst1 when sel1 = '1' else rst2; tapo_shft <= shift1 when sel1 = '1' else shift2; tapo_tdi <= tdi1 when sel1 = '1' else tdi2; tapo_upd <= update1 when sel1 ='1' else update2; tapo_xsel1 <= sel1; tapo_xsel2 <= sel2; end; library ieee; use ieee.std_logic_1164.all; -- pragma translate_off library unisim; use unisim.all; -- pragma translate_on entity artix7_tap is port ( tapi_tdo1 : in std_ulogic; tapi_tdo2 : in std_ulogic; tapo_tck : out std_ulogic; tapo_tdi : out std_ulogic; tapo_rst : out std_ulogic; tapo_capt : out std_ulogic; tapo_shft : out std_ulogic; tapo_upd : out std_ulogic; tapo_xsel1 : out std_ulogic; tapo_xsel2 : out std_ulogic ); end; architecture rtl of artix7_tap is component BSCANE2 generic ( DISABLE_JTAG : string := "FALSE"; JTAG_CHAIN : integer := 1 ); port ( CAPTURE : out std_ulogic := 'H'; DRCK : out std_ulogic := 'H'; RESET : out std_ulogic := 'H'; RUNTEST : out std_ulogic := 'L'; SEL : out std_ulogic := 'L'; SHIFT : out std_ulogic := 'L'; TCK : out std_ulogic := 'L'; TDI : out std_ulogic := 'L'; TMS : out std_ulogic := 'L'; UPDATE : out std_ulogic := 'L'; TDO : in std_ulogic := 'X' ); end component; signal drck1, drck2, sel1, sel2 : std_ulogic; signal capt1, capt2, rst1, rst2 : std_ulogic; signal shift1, shift2, tdi1, tdi2 : std_ulogic; signal update1, update2 : std_ulogic; attribute dont_touch : boolean; attribute dont_touch of u0 : label is true; attribute dont_touch of u1 : label is true; begin u0 : BSCANE2 generic map (JTAG_CHAIN => 1) port map ( CAPTURE => capt1, DRCK => drck1, RESET => rst1, SEL => sel1, SHIFT => shift1, TDI => tdi1, UPDATE => update1, TDO => tapi_tdo1, TCK => tapo_tck ); u1 : BSCANE2 generic map (JTAG_CHAIN => 2) port map ( CAPTURE => capt2, DRCK => drck2, RESET => rst2, SEL => sel2, SHIFT => shift2, TDI => tdi2, UPDATE => update2, TDO => tapi_tdo2 ); tapo_capt <= capt1 when sel1 = '1' else capt2; tapo_rst <= rst1 when sel1 = '1' else rst2; tapo_shft <= shift1 when sel1 = '1' else shift2; tapo_tdi <= tdi1 when sel1 = '1' else tdi2; tapo_upd <= update1 when sel1 ='1' else update2; tapo_xsel1 <= sel1; tapo_xsel2 <= sel2; end;

gpl-2.0

1640683f72e97b87baadca2d0fb807dc

0.498025

3.750656

false

marco-c/leon-nexys2

grlib-gpl-1.3.4-b4140/lib/eth/wrapper/greth_gbit_gen.vhd

1

13,434

------------------------------------------------------------------------------ -- This file is a part of the GRLIB VHDL IP LIBRARY -- Copyright (C) 2003 - 2008, Gaisler Research -- Copyright (C) 2008 - 2013, Aeroflex Gaisler -- -- This program is free software; you can redistribute it and/or modify -- it under the terms of the GNU General Public License as published by -- the Free Software Foundation; either version 2 of the License, or -- (at your option) any later version. -- -- This program is distributed in the hope that it will be useful, -- but WITHOUT ANY WARRANTY; without even the implied warranty of -- MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the -- GNU General Public License for more details. -- -- You should have received a copy of the GNU General Public License -- along with this program; if not, write to the Free Software -- Foundation, Inc., 59 Temple Place, Suite 330, Boston, MA 02111-1307 USA ----------------------------------------------------------------------------- -- Entity: greth_gbit_gen -- File: greth_gbit_gen.vhd -- Author: Marko Isomaki -- Description: Generic Gigabit Ethernet MAC ------------------------------------------------------------------------------ library ieee; library grlib; use ieee.std_logic_1164.all; use grlib.stdlib.all; library techmap; use techmap.gencomp.all; library eth; use eth.ethcomp.all; entity greth_gbit_gen is generic( memtech : integer := 0; ifg_gap : integer := 24; attempt_limit : integer := 16; backoff_limit : integer := 10; slot_time : integer := 128; mdcscaler : integer range 0 to 255 := 25; nsync : integer range 1 to 2 := 2; edcl : integer range 0 to 3 := 1; edclbufsz : integer range 1 to 64 := 1; burstlength : integer range 4 to 128 := 32; macaddrh : integer := 16#00005E#; macaddrl : integer := 16#000000#; ipaddrh : integer := 16#c0a8#; ipaddrl : integer := 16#0035#; phyrstadr : integer range 0 to 32 := 0; sim : integer range 0 to 1 := 0; oepol : integer range 0 to 1 := 0; scanen : integer range 0 to 1 := 0; ft : integer range 0 to 2 := 0; edclft : integer range 0 to 2 := 0; mdint_pol : integer range 0 to 1 := 0; enable_mdint : integer range 0 to 1 := 0; multicast : integer range 0 to 1 := 0; edclsepahbg : integer range 0 to 1 := 0; ramdebug : integer range 0 to 2 := 0); port( rst : in std_ulogic; clk : in std_ulogic; --ahb mst in hgrant : in std_ulogic; hready : in std_ulogic; hresp : in std_logic_vector(1 downto 0); hrdata : in std_logic_vector(31 downto 0); --ahb mst out hbusreq : out std_ulogic; hlock : out std_ulogic; htrans : out std_logic_vector(1 downto 0); haddr : out std_logic_vector(31 downto 0); hwrite : out std_ulogic; hsize : out std_logic_vector(2 downto 0); hburst : out std_logic_vector(2 downto 0); hprot : out std_logic_vector(3 downto 0); hwdata : out std_logic_vector(31 downto 0); --edcl ahb mst in ehgrant : in std_ulogic; ehready : in std_ulogic; ehresp : in std_logic_vector(1 downto 0); ehrdata : in std_logic_vector(31 downto 0); --edcl ahb mst out ehbusreq : out std_ulogic; ehlock : out std_ulogic; ehtrans : out std_logic_vector(1 downto 0); ehaddr : out std_logic_vector(31 downto 0); ehwrite : out std_ulogic; ehsize : out std_logic_vector(2 downto 0); ehburst : out std_logic_vector(2 downto 0); ehprot : out std_logic_vector(3 downto 0); ehwdata : out std_logic_vector(31 downto 0); --apb slv in psel : in std_ulogic; penable : in std_ulogic; paddr : in std_logic_vector(31 downto 0); pwrite : in std_ulogic; pwdata : in std_logic_vector(31 downto 0); --apb slv out prdata : out std_logic_vector(31 downto 0); --irq irq : out std_logic; --ethernet input signals gtx_clk : in std_ulogic; tx_clk : in std_ulogic; rx_clk : in std_ulogic; rxd : in std_logic_vector(7 downto 0); rx_dv : in std_ulogic; rx_er : in std_ulogic; rx_col : in std_ulogic; rx_crs : in std_ulogic; mdio_i : in std_ulogic; phyrstaddr : in std_logic_vector(4 downto 0); mdint : in std_ulogic; --ethernet output signals reset : out std_ulogic; txd : out std_logic_vector(7 downto 0); tx_en : out std_ulogic; tx_er : out std_ulogic; mdc : out std_ulogic; mdio_o : out std_ulogic; mdio_oe : out std_ulogic; --scantest testrst : in std_ulogic; testen : in std_ulogic; testoen : in std_ulogic; edcladdr : in std_logic_vector(3 downto 0); edclsepahb : in std_ulogic; edcldisable : in std_ulogic; speed : out std_ulogic; gbit : out std_ulogic ); end entity; architecture rtl of greth_gbit_gen is --host constants constant fifosize : integer := 512; constant fabits : integer := log2(fifosize); constant fsize : std_logic_vector(fabits downto 0) := conv_std_logic_vector(fifosize, fabits+1); --edcl constants type szvct is array (0 to 6) of integer; constant ebuf : szvct := (64, 128, 128, 256, 256, 256, 256); constant eabits: integer := log2(edclbufsz) + 8; constant ebufsize : integer := ebuf(log2(edclbufsz)); --rx ahb fifo signal rxrenable : std_ulogic; signal rxraddress : std_logic_vector(8 downto 0); signal rxwrite : std_ulogic; signal rxwdata : std_logic_vector(31 downto 0); signal rxwaddress : std_logic_vector(8 downto 0); signal rxrdata : std_logic_vector(31 downto 0); --tx ahb fifo signal txrenable : std_ulogic; signal txraddress : std_logic_vector(8 downto 0); signal txwrite : std_ulogic; signal txwdata : std_logic_vector(31 downto 0); signal txwaddress : std_logic_vector(8 downto 0); signal txrdata : std_logic_vector(31 downto 0); --edcl buf signal erenable : std_ulogic; signal eraddress : std_logic_vector(15 downto 0); signal ewritem : std_ulogic; signal ewritel : std_ulogic; signal ewaddressm : std_logic_vector(15 downto 0); signal ewaddressl : std_logic_vector(15 downto 0); signal ewdata : std_logic_vector(31 downto 0); signal erdata : std_logic_vector(31 downto 0); begin gtxc0: greth_gbitc generic map( ifg_gap => ifg_gap, attempt_limit => attempt_limit, backoff_limit => backoff_limit, slot_time => slot_time, mdcscaler => mdcscaler, nsync => nsync, edcl => edcl, edclbufsz => edclbufsz, burstlength => burstlength, macaddrh => macaddrh, macaddrl => macaddrl, ipaddrh => ipaddrh, ipaddrl => ipaddrl, phyrstadr => phyrstadr, sim => sim, oepol => oepol, scanen => scanen, mdint_pol => mdint_pol, enable_mdint => enable_mdint, multicast => multicast, edclsepahbg => edclsepahbg, ramdebug => ramdebug) port map( rst => rst, clk => clk, --ahb mst in hgrant => hgrant, hready => hready, hresp => hresp, hrdata => hrdata, --ahb mst out hbusreq => hbusreq, hlock => hlock, htrans => htrans, haddr => haddr, hwrite => hwrite, hsize => hsize, hburst => hburst, hprot => hprot, hwdata => hwdata, --edcl ahb mst in ehgrant => ehgrant, ehready => ehready, ehresp => ehresp, ehrdata => ehrdata, --edcl ahb mst out ehbusreq => ehbusreq, ehlock => ehlock, ehtrans => ehtrans, ehaddr => ehaddr, ehwrite => ehwrite, ehsize => ehsize, ehburst => ehburst, ehprot => ehprot, ehwdata => ehwdata, --apb slv in psel => psel, penable => penable, paddr => paddr, pwrite => pwrite, pwdata => pwdata, --apb slv out prdata => prdata, --irq irq => irq, --rx ahb fifo rxrenable => rxrenable, rxraddress => rxraddress, rxwrite => rxwrite, rxwdata => rxwdata, rxwaddress => rxwaddress, rxrdata => rxrdata, --tx ahb fifo txrenable => txrenable, txraddress => txraddress, txwrite => txwrite, txwdata => txwdata, txwaddress => txwaddress, txrdata => txrdata, --edcl buf erenable => erenable, eraddress => eraddress, ewritem => ewritem, ewritel => ewritel, ewaddressm => ewaddressm, ewaddressl => ewaddressl, ewdata => ewdata, erdata => erdata, --ethernet input signals gtx_clk => gtx_clk, tx_clk => tx_clk, rx_clk => rx_clk, rxd => rxd, rx_dv => rx_dv, rx_er => rx_er, rx_col => rx_col, rx_crs => rx_crs, mdio_i => mdio_i, phyrstaddr => phyrstaddr, mdint => mdint, --ethernet output signals reset => reset, txd => txd, tx_en => tx_en, tx_er => tx_er, mdc => mdc, mdio_o => mdio_o, mdio_oe => mdio_oe, --scantest testrst => testrst, testen => testen, testoen => testoen, edcladdr => edcladdr, edclsepahb => edclsepahb, edcldisable => edcldisable, speed => speed, gbit => gbit); ------------------------------------------------------------------------------- -- FIFOS ---------------------------------------------------------------------- ------------------------------------------------------------------------------- nft : if ft = 0 generate tx_fifo0 : syncram_2p generic map(tech => memtech, abits => fabits, dbits => 32, sepclk => 0) port map(clk, txrenable, txraddress(fabits-1 downto 0), txrdata, clk, txwrite, txwaddress(fabits-1 downto 0), txwdata); rx_fifo0 : syncram_2p generic map(tech => memtech, abits => fabits, dbits => 32, sepclk => 0) port map(clk, rxrenable, rxraddress(fabits-1 downto 0), rxrdata, clk, rxwrite, rxwaddress(fabits-1 downto 0), rxwdata); end generate; ft1 : if ft /= 0 generate tx_fifo0 : syncram_2pft generic map(tech => memtech, abits => fabits, dbits => 32, sepclk => 0, ft => ft) port map(clk, txrenable, txraddress(fabits-1 downto 0), txrdata, clk, txwrite, txwaddress(fabits-1 downto 0), txwdata); rx_fifo0 : syncram_2pft generic map(tech => memtech, abits => fabits, dbits => 32, sepclk => 0, ft => ft) port map(clk, rxrenable, rxraddress(fabits-1 downto 0), rxrdata, clk, rxwrite, rxwaddress(fabits-1 downto 0), rxwdata); end generate; ------------------------------------------------------------------------------- -- EDCL buffer ram ------------------------------------------------------------ ------------------------------------------------------------------------------- edclramnft : if (edcl /= 0) and (edclft = 0) generate r0 : syncram_2p generic map (memtech, eabits, 16) port map ( clk, erenable, eraddress(eabits-1 downto 0), erdata(31 downto 16), clk, ewritem, ewaddressm(eabits-1 downto 0), ewdata(31 downto 16)); r1 : syncram_2p generic map (memtech, eabits, 16) port map ( clk, erenable, eraddress(eabits-1 downto 0), erdata(15 downto 0), clk, ewritel, ewaddressl(eabits-1 downto 0), ewdata(15 downto 0)); end generate; edclramft1 : if (edcl /= 0) and (edclft /= 0) generate r0 : syncram_2pft generic map (memtech, eabits, 16, 0, 0, edclft) port map ( clk, erenable, eraddress(eabits-1 downto 0), erdata(31 downto 16), clk, ewritem, ewaddressm(eabits-1 downto 0), ewdata(31 downto 16)); r1 : syncram_2pft generic map (memtech, eabits, 16, 0, 0, edclft) port map ( clk, erenable, eraddress(eabits-1 downto 0), erdata(15 downto 0), clk, ewritel, ewaddressl(eabits-1 downto 0), ewdata(15 downto 0)); end generate; end architecture;

gpl-2.0

3d9798233e8e5d196a98a32334ec7c8a

0.511389

4.173346

false

marco-c/leon-nexys2

grlib-gpl-1.3.4-b4140/lib/techmap/maps/syncram128bw.vhd

1

6,251

------------------------------------------------------------------------------ -- This file is a part of the GRLIB VHDL IP LIBRARY -- Copyright (C) 2003 - 2008, Gaisler Research -- Copyright (C) 2008 - 2013, Aeroflex Gaisler -- -- This program is free software; you can redistribute it and/or modify -- it under the terms of the GNU General Public License as published by -- the Free Software Foundation; either version 2 of the License, or -- (at your option) any later version. -- -- This program is distributed in the hope that it will be useful, -- but WITHOUT ANY WARRANTY; without even the implied warranty of -- MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the -- GNU General Public License for more details. -- -- You should have received a copy of the GNU General Public License -- along with this program; if not, write to the Free Software -- Foundation, Inc., 59 Temple Place, Suite 330, Boston, MA 02111-1307 USA ----------------------------------------------------------------------------- -- Entity: syncram128bw -- File: syncram128bw.vhd -- Author: Jiri Gaisler - Gaisler Research -- Description: 128-bit syncronous 1-port ram with 8-bit write strobes -- and tech selection ------------------------------------------------------------------------------ library ieee; library techmap; use ieee.std_logic_1164.all; use techmap.gencomp.all; library grlib; use grlib.config.all; use grlib.config_types.all; use grlib.stdlib.all; entity syncram128bw is generic (tech : integer := 0; abits : integer := 6; testen : integer := 0; custombits: integer := 1); port ( clk : in std_ulogic; address : in std_logic_vector (abits -1 downto 0); datain : in std_logic_vector (127 downto 0); dataout : out std_logic_vector (127 downto 0); enable : in std_logic_vector (15 downto 0); write : in std_logic_vector (15 downto 0); testin : in std_logic_vector (TESTIN_WIDTH-1 downto 0) := testin_none; customclk: in std_ulogic := '0'; customin : in std_logic_vector(16*custombits-1 downto 0) := (others => '0'); customout:out std_logic_vector(16*custombits-1 downto 0)); end; architecture rtl of syncram128bw is component unisim_syncram128bw generic ( abits : integer := 9); port ( clk : in std_ulogic; address : in std_logic_vector (abits -1 downto 0); datain : in std_logic_vector (127 downto 0); dataout : out std_logic_vector (127 downto 0); enable : in std_logic_vector (15 downto 0); write : in std_logic_vector (15 downto 0) ); end component; component altera_syncram128bw generic ( abits : integer := 9); port ( clk : in std_ulogic; address : in std_logic_vector (abits -1 downto 0); datain : in std_logic_vector (127 downto 0); dataout : out std_logic_vector (127 downto 0); enable : in std_logic_vector (15 downto 0); write : in std_logic_vector (15 downto 0) ); end component; component tm65gplus_syncram128bw generic ( abits : integer := 9); port ( clk : in std_ulogic; address : in std_logic_vector (abits -1 downto 0); datain : in std_logic_vector (127 downto 0); dataout : out std_logic_vector (127 downto 0); enable : in std_logic_vector (15 downto 0); write : in std_logic_vector (15 downto 0); testin : in std_logic_vector (3 downto 0) := "0000" ); end component; component ut90nhbd_syncram128bw generic ( abits : integer := 9); port ( clk : in std_ulogic; address : in std_logic_vector (abits -1 downto 0); datain : in std_logic_vector (127 downto 0); dataout : out std_logic_vector (127 downto 0); enable : in std_logic_vector (15 downto 0); write : in std_logic_vector (15 downto 0); tdbn : in std_ulogic ); end component; signal xenable, xwrite : std_logic_vector(15 downto 0); signal custominx,customoutx: std_logic_vector(syncram_customif_maxwidth downto 0); begin xenable <= enable when testen=0 or testin(TESTIN_WIDTH-2)='0' else (others => '0'); xwrite <= write when testen=0 or testin(TESTIN_WIDTH-2)='0' else (others => '0'); custominx(custominx'high downto custombits) <= (others => '0'); custominx(custombits-1 downto 0) <= customin(custombits-1 downto 0); nocust: if syncram_has_customif(tech)=0 or has_sram128bw(tech)=0 generate customoutx <= (others => '0'); end generate; s64 : if has_sram128bw(tech) = 1 generate xc2v : if (is_unisim(tech) = 1) generate x0 : unisim_syncram128bw generic map (abits) port map (clk, address, datain, dataout, xenable, xwrite); end generate; alt : if (tech = stratix2) or (tech = stratix3) or (tech = stratix4) or (tech = cyclone3) or (tech = altera) generate x0 : altera_syncram128bw generic map (abits) port map (clk, address, datain, dataout, xenable, xwrite); end generate; tm65: if tech = tm65gplus generate x0 : tm65gplus_syncram128bw generic map (abits) port map (clk, address, datain, dataout, xenable, xwrite, testin); end generate; ut09: if tech = ut90 generate x0 : ut90nhbd_syncram128bw generic map (abits) port map (clk, address, datain, dataout, xenable, xwrite, testin(TESTIN_WIDTH-3)); end generate; customout(16*custombits-1 downto custombits) <= (others => '0'); customout(custombits-1 downto 0) <= customoutx(custombits-1 downto 0); -- pragma translate_off dmsg : if GRLIB_CONFIG_ARRAY(grlib_debug_level) >= 2 generate x : process begin assert false report "syncram128bw: " & tost(2**abits) & "x128" & " (" & tech_table(tech) & ")" severity note; wait; end process; end generate; -- pragma translate_on end generate; nos64 : if has_sram128bw(tech) = 0 generate rx : for i in 0 to 15 generate x0 : syncram generic map (tech, abits, 8, testen, custombits) port map (clk, address, datain(i*8+7 downto i*8), dataout(i*8+7 downto i*8), enable(i), write(i), testin, customclk, customin((i+1)*custombits-1 downto i*custombits), customout((i+1)*custombits-1 downto i*custombits)); end generate; end generate; end;

gpl-2.0

9ef54fad13e42c996b112a7b005de961

0.633019

3.647025

false

true

false

marco-c/leon-nexys2

grlib-gpl-1.3.4-b4140/lib/techmap/maps/clkinv.vhd

1

1,888

------------------------------------------------------------------------------ -- This file is a part of the GRLIB VHDL IP LIBRARY -- Copyright (C) 2003 - 2008, Gaisler Research -- Copyright (C) 2008 - 2013, Aeroflex Gaisler -- -- This program is free software; you can redistribute it and/or modify -- it under the terms of the GNU General Public License as published by -- the Free Software Foundation; either version 2 of the License, or -- (at your option) any later version. -- -- This program is distributed in the hope that it will be useful, -- but WITHOUT ANY WARRANTY; without even the implied warranty of -- MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the -- GNU General Public License for more details. -- -- You should have received a copy of the GNU General Public License -- along with this program; if not, write to the Free Software -- Foundation, Inc., 59 Temple Place, Suite 330, Boston, MA 02111-1307 USA ----------------------------------------------------------------------------- -- Entity: clkinv -- File: clkinv.vhd -- Author: Fredrik Ringhage - Aeroflex Gaisler Research -- Description: SET protected inverters for clock tree ------------------------------------------------------------------------------ library ieee; use ieee.std_logic_1164.all; use work.gencomp.all; use work.allclkgen.all; entity clkinv is generic(tech : integer := 0); port( i : in std_ulogic; o : out std_ulogic ); end entity; architecture rtl of clkinv is begin tec : if has_clkinv(tech) = 1 generate saed : if (tech = saed32) generate x0 : clkinv_saed32 port map (i => i, o => o); end generate; dar : if (tech = dare) generate x0 : clkinv_dare port map (i => i, o => o); end generate; end generate; gen : if has_clkinv(tech) = 0 generate o <= not i; end generate; end architecture;

gpl-2.0

331f74a4d9d6a2042672d8262450854c

0.601695

4.15859

false

Fairyland0902/BlockyRoads

src/BlockyRoads/ipcore_dir/game_over/simulation/bmg_stim_gen.vhd

1

12,587

-------------------------------------------------------------------------------- -- -- BLK MEM GEN v7_3 Core - Stimulus Generator For Single Port ROM -- -------------------------------------------------------------------------------- -- -- (c) Copyright 2006_3010 Xilinx, Inc. All rights reserved. -- -- This file contains confidential and proprietary information -- of Xilinx, Inc. and is protected under U.S. and -- international copyright and other intellectual property -- laws. -- -- DISCLAIMER -- This disclaimer is not a license and does not grant any -- rights to the materials distributed herewith. Except as -- otherwise provided in a valid license issued to you by -- Xilinx, and to the maximum extent permitted by applicable -- law: (1) THESE MATERIALS ARE MADE AVAILABLE "AS IS" AND -- WITH ALL FAULTS, AND XILINX HEREBY DISCLAIMS ALL WARRANTIES -- AND CONDITIONS, EXPRESS, IMPLIED, OR STATUTORY, INCLUDING -- BUT NOT LIMITED TO WARRANTIES OF MERCHANTABILITY, NON- -- INFRINGEMENT, OR FITNESS FOR ANY PARTICULAR PURPOSE; and -- (2) Xilinx shall not be liable (whether in contract or tort, -- including negligence, or under any other theory of -- liability) for any loss or damage of any kind or nature -- related to, arising under or in connection with these -- materials, including for any direct, or any indirect, -- special, incidental, or consequential loss or damage -- (including loss of data, profits, goodwill, or any type of -- loss or damage suffered as a result of any action brought -- by a third party) even if such damage or loss was -- reasonably foreseeable or Xilinx had been advised of the -- possibility of the same. -- -- CRITICAL APPLICATIONS -- Xilinx products are not designed or intended to be fail- -- safe, or for use in any application requiring fail-safe -- performance, such as life-support or safety devices or -- systems, Class III medical devices, nuclear facilities, -- applications related to the deployment of airbags, or any -- other applications that could lead to death, personal -- injury, or severe property or environmental damage -- (individually and collectively, "Critical -- Applications"). Customer assumes the sole risk and -- liability of any use of Xilinx products in Critical -- Applications, subject only to applicable laws and -- regulations governing limitations on product liability. -- -- THIS COPYRIGHT NOTICE AND DISCLAIMER MUST BE RETAINED AS -- PART OF THIS FILE AT ALL TIMES. -------------------------------------------------------------------------------- -- -- Filename: bmg_stim_gen.vhd -- -- Description: -- Stimulus Generation For SROM -- -------------------------------------------------------------------------------- -- Author: IP Solutions Division -- -- History: Sep 12, 2011 - First Release -------------------------------------------------------------------------------- -- -------------------------------------------------------------------------------- -- Library Declarations -------------------------------------------------------------------------------- LIBRARY IEEE; USE IEEE.STD_LOGIC_1164.ALL; USE IEEE.STD_LOGIC_ARITH.ALL; USE IEEE.STD_LOGIC_UNSIGNED.ALL; USE IEEE.STD_LOGIC_MISC.ALL; LIBRARY work; USE work.ALL; USE work.BMG_TB_PKG.ALL; ENTITY REGISTER_LOGIC_SROM IS PORT( Q : OUT STD_LOGIC; CLK : IN STD_LOGIC; RST : IN STD_LOGIC; D : IN STD_LOGIC ); END REGISTER_LOGIC_SROM; ARCHITECTURE REGISTER_ARCH OF REGISTER_LOGIC_SROM IS SIGNAL Q_O : STD_LOGIC :='0'; BEGIN Q <= Q_O; FF_BEH: PROCESS(CLK) BEGIN IF(RISING_EDGE(CLK)) THEN IF(RST /= '0' ) THEN Q_O <= '0'; ELSE Q_O <= D; END IF; END IF; END PROCESS; END REGISTER_ARCH; LIBRARY STD; USE STD.TEXTIO.ALL; LIBRARY IEEE; USE IEEE.STD_LOGIC_1164.ALL; USE IEEE.STD_LOGIC_ARITH.ALL; --USE IEEE.NUMERIC_STD.ALL; USE IEEE.STD_LOGIC_UNSIGNED.ALL; USE IEEE.STD_LOGIC_MISC.ALL; LIBRARY work; USE work.ALL; USE work.BMG_TB_PKG.ALL; ENTITY BMG_STIM_GEN IS GENERIC ( C_ROM_SYNTH : INTEGER := 0 ); PORT ( CLK : IN STD_LOGIC; RST : IN STD_LOGIC; ADDRA: OUT STD_LOGIC_VECTOR(14 DOWNTO 0) := (OTHERS => '0'); DATA_IN : IN STD_LOGIC_VECTOR (11 DOWNTO 0); --OUTPUT VECTOR STATUS : OUT STD_LOGIC:= '0' ); END BMG_STIM_GEN; ARCHITECTURE BEHAVIORAL OF BMG_STIM_GEN IS FUNCTION hex_to_std_logic_vector( hex_str : STRING; return_width : INTEGER) RETURN STD_LOGIC_VECTOR IS VARIABLE tmp : STD_LOGIC_VECTOR((hex_str'LENGTH*4)+return_width-1 DOWNTO 0); BEGIN tmp := (OTHERS => '0'); FOR i IN 1 TO hex_str'LENGTH LOOP CASE hex_str((hex_str'LENGTH+1)-i) IS WHEN '0' => tmp(i*4-1 DOWNTO (i-1)*4) := "0000"; WHEN '1' => tmp(i*4-1 DOWNTO (i-1)*4) := "0001"; WHEN '2' => tmp(i*4-1 DOWNTO (i-1)*4) := "0010"; WHEN '3' => tmp(i*4-1 DOWNTO (i-1)*4) := "0011"; WHEN '4' => tmp(i*4-1 DOWNTO (i-1)*4) := "0100"; WHEN '5' => tmp(i*4-1 DOWNTO (i-1)*4) := "0101"; WHEN '6' => tmp(i*4-1 DOWNTO (i-1)*4) := "0110"; WHEN '7' => tmp(i*4-1 DOWNTO (i-1)*4) := "0111"; WHEN '8' => tmp(i*4-1 DOWNTO (i-1)*4) := "1000"; WHEN '9' => tmp(i*4-1 DOWNTO (i-1)*4) := "1001"; WHEN 'a' | 'A' => tmp(i*4-1 DOWNTO (i-1)*4) := "1010"; WHEN 'b' | 'B' => tmp(i*4-1 DOWNTO (i-1)*4) := "1011"; WHEN 'c' | 'C' => tmp(i*4-1 DOWNTO (i-1)*4) := "1100"; WHEN 'd' | 'D' => tmp(i*4-1 DOWNTO (i-1)*4) := "1101"; WHEN 'e' | 'E' => tmp(i*4-1 DOWNTO (i-1)*4) := "1110"; WHEN 'f' | 'F' => tmp(i*4-1 DOWNTO (i-1)*4) := "1111"; WHEN OTHERS => tmp(i*4-1 DOWNTO (i-1)*4) := "1111"; END CASE; END LOOP; RETURN tmp(return_width-1 DOWNTO 0); END hex_to_std_logic_vector; CONSTANT ZERO : STD_LOGIC_VECTOR(31 DOWNTO 0) := (OTHERS => '0'); SIGNAL READ_ADDR_INT : STD_LOGIC_VECTOR(14 DOWNTO 0) := (OTHERS => '0'); SIGNAL READ_ADDR : STD_LOGIC_VECTOR(31 DOWNTO 0) := (OTHERS => '0'); SIGNAL CHECK_READ_ADDR : STD_LOGIC_VECTOR(31 DOWNTO 0) := (OTHERS => '0'); SIGNAL EXPECTED_DATA : STD_LOGIC_VECTOR(11 DOWNTO 0) := (OTHERS => '0'); SIGNAL DO_READ : STD_LOGIC := '0'; SIGNAL CHECK_DATA : STD_LOGIC := '0'; SIGNAL CHECK_DATA_R : STD_LOGIC := '0'; SIGNAL CHECK_DATA_2R : STD_LOGIC := '0'; SIGNAL DO_READ_REG: STD_LOGIC_VECTOR(4 DOWNTO 0) :=(OTHERS => '0'); CONSTANT DEFAULT_DATA : STD_LOGIC_VECTOR(11 DOWNTO 0):= hex_to_std_logic_vector("0",12); BEGIN SYNTH_COE: IF(C_ROM_SYNTH =0 ) GENERATE type mem_type is array (19199 downto 0) of std_logic_vector(11 downto 0); FUNCTION bit_to_sl(input: BIT) RETURN STD_LOGIC IS VARIABLE temp_return : STD_LOGIC; BEGIN IF (input = '0') THEN temp_return := '0'; ELSE temp_return := '1'; END IF; RETURN temp_return; END bit_to_sl; function char_to_std_logic ( char : in character) return std_logic is variable data : std_logic; begin if char = '0' then data := '0'; elsif char = '1' then data := '1'; elsif char = 'X' then data := 'X'; else assert false report "character which is not '0', '1' or 'X'." severity warning; data := 'U'; end if; return data; end char_to_std_logic; impure FUNCTION init_memory( C_USE_DEFAULT_DATA : INTEGER; C_LOAD_INIT_FILE : INTEGER ; C_INIT_FILE_NAME : STRING ; DEFAULT_DATA : STD_LOGIC_VECTOR(11 DOWNTO 0); width : INTEGER; depth : INTEGER) RETURN mem_type IS VARIABLE init_return : mem_type := (OTHERS => (OTHERS => '0')); FILE init_file : TEXT; VARIABLE mem_vector : BIT_VECTOR(width-1 DOWNTO 0); VARIABLE bitline : LINE; variable bitsgood : boolean := true; variable bitchar : character; VARIABLE i : INTEGER; VARIABLE j : INTEGER; BEGIN --Display output message indicating that the behavioral model is being --initialized ASSERT (NOT (C_USE_DEFAULT_DATA=1 OR C_LOAD_INIT_FILE=1)) REPORT " Block Memory Generator CORE Generator module loading initial data..." SEVERITY NOTE; -- Setup the default data -- Default data is with respect to write_port_A and may be wider -- or narrower than init_return width. The following loops map -- default data into the memory IF (C_USE_DEFAULT_DATA=1) THEN FOR i IN 0 TO depth-1 LOOP init_return(i) := DEFAULT_DATA; END LOOP; END IF; -- Read in the .mif file -- The init data is formatted with respect to write port A dimensions. -- The init_return vector is formatted with respect to minimum width and -- maximum depth; the following loops map the .mif file into the memory IF (C_LOAD_INIT_FILE=1) THEN file_open(init_file, C_INIT_FILE_NAME, read_mode); i := 0; WHILE (i < depth AND NOT endfile(init_file)) LOOP mem_vector := (OTHERS => '0'); readline(init_file, bitline); -- read(file_buffer, mem_vector(file_buffer'LENGTH-1 DOWNTO 0)); FOR j IN 0 TO width-1 LOOP read(bitline,bitchar,bitsgood); init_return(i)(width-1-j) := char_to_std_logic(bitchar); END LOOP; i := i + 1; END LOOP; file_close(init_file); END IF; RETURN init_return; END FUNCTION; --*************************************************************** -- convert bit to STD_LOGIC --*************************************************************** constant c_init : mem_type := init_memory(0, 1, "game_over.mif", DEFAULT_DATA, 12, 19200); constant rom : mem_type := c_init; BEGIN EXPECTED_DATA <= rom(conv_integer(unsigned(check_read_addr))); CHECKER_RD_ADDR_GEN_INST:ENTITY work.ADDR_GEN GENERIC MAP( C_MAX_DEPTH =>19200 ) PORT MAP( CLK => CLK, RST => RST, EN => CHECK_DATA_2R, LOAD => '0', LOAD_VALUE => ZERO, ADDR_OUT => CHECK_READ_ADDR ); PROCESS(CLK) BEGIN IF(RISING_EDGE(CLK)) THEN IF(CHECK_DATA_2R ='1') THEN IF(EXPECTED_DATA = DATA_IN) THEN STATUS<='0'; ELSE STATUS <= '1'; END IF; END IF; END IF; END PROCESS; END GENERATE; -- Simulatable ROM --Synthesizable ROM SYNTH_CHECKER: IF(C_ROM_SYNTH = 1) GENERATE PROCESS(CLK) BEGIN IF(RISING_EDGE(CLK)) THEN IF(CHECK_DATA_2R='1') THEN IF(DATA_IN=DEFAULT_DATA) THEN STATUS <= '0'; ELSE STATUS <= '1'; END IF; END IF; END IF; END PROCESS; END GENERATE; READ_ADDR_INT(14 DOWNTO 0) <= READ_ADDR(14 DOWNTO 0); ADDRA <= READ_ADDR_INT ; CHECK_DATA <= DO_READ; RD_ADDR_GEN_INST:ENTITY work.ADDR_GEN GENERIC MAP( C_MAX_DEPTH => 19200 ) PORT MAP( CLK => CLK, RST => RST, EN => DO_READ, LOAD => '0', LOAD_VALUE => ZERO, ADDR_OUT => READ_ADDR ); RD_PROCESS: PROCESS (CLK) BEGIN IF (RISING_EDGE(CLK)) THEN IF(RST='1') THEN DO_READ <= '0'; ELSE DO_READ <= '1'; END IF; END IF; END PROCESS; BEGIN_SHIFT_REG: FOR I IN 0 TO 4 GENERATE BEGIN DFF_RIGHT: IF I=0 GENERATE BEGIN SHIFT_INST_0: ENTITY work.REGISTER_LOGIC_SROM PORT MAP( Q => DO_READ_REG(0), CLK =>CLK, RST=>RST, D =>DO_READ ); END GENERATE DFF_RIGHT; DFF_OTHERS: IF ((I>0) AND (I<=4)) GENERATE BEGIN SHIFT_INST: ENTITY work.REGISTER_LOGIC_SROM PORT MAP( Q => DO_READ_REG(I), CLK =>CLK, RST=>RST, D =>DO_READ_REG(I-1) ); END GENERATE DFF_OTHERS; END GENERATE BEGIN_SHIFT_REG; CHECK_DATA_REG_1: ENTITY work.REGISTER_LOGIC_SROM PORT MAP( Q => CHECK_DATA_2R, CLK =>CLK, RST=>RST, D =>CHECK_DATA_R ); CHECK_DATA_REG: ENTITY work.REGISTER_LOGIC_SROM PORT MAP( Q => CHECK_DATA_R, CLK =>CLK, RST=>RST, D =>CHECK_DATA ); END ARCHITECTURE;

mit

72965741547e82cdc9b11f7b91e6c288

0.547946

3.686878

false

borti4938/sd2snes

verilog/sd2snes_sdd1/Golomb_N_Decoder.vhd

2

3,249

---------------------------------------------------------------------------------- -- Company: Traducciones Magno -- Engineer: Magno -- -- Create Date: 20.03.2018 18:42:09 -- Design Name: -- Module Name: Golomb_Decoder - Behavioral -- Project Name: -- Target Devices: -- Tool Versions: -- Description: -- -- Dependencies: -- -- Revision: -- Revision 0.01 - File Created -- Additional Comments: -- ---------------------------------------------------------------------------------- library IEEE; use IEEE.STD_LOGIC_1164.ALL; use IEEE.STD_LOGIC_ARITH.ALL; use IEEE.STD_LOGIC_UNSIGNED.ALL; -- Uncomment the following library declaration if using -- arithmetic functions with Signed or Unsigned values --use IEEE.NUMERIC_STD.ALL; -- Uncomment the following library declaration if instantiating -- any Xilinx leaf cells in this code. --library UNISIM; --use UNISIM.VComponents.all; entity Golomb_N_Decoder is Generic( N : integer); Port( clk : IN STD_LOGIC; rst : IN STD_LOGIC; din_tready : OUT STD_LOGIC; din_tdata : IN STD_LOGIC_VECTOR(N DOWNTO 0); din_tuser : OUT STD_LOGIC_VECTOR(2 downto 0); dout_tready : IN STD_LOGIC; dout_tdata : OUT STD_LOGIC; dout_tlast : OUT STD_LOGIC); end Golomb_N_Decoder; architecture Behavioral of Golomb_N_Decoder is signal zero_count : integer range 0 to 2**N-1 := 0; signal max_count : integer range 0 to 2**N-1 := 0; signal LPS_Flag : STD_LOGIC := '0'; signal end_bit : STD_LOGIC := '0'; begin -- number of zero bits and tail bit max_count <= 2**N - conv_integer(din_tdata(N downto 1)) - 1 when din_tdata(0) = '1' else 2**N - 1; LPS_Flag <= '0' when din_tdata(0) = '0' else '1'; Process( clk ) Begin if rising_edge( clk ) then if( rst = '1' ) then zero_count <= 0; end_bit <= '0'; else -- each new output bit run, counter is loaded with number of consecutive zeros -- and input code is registered if( dout_tready = '1' ) then if( zero_count = 0 ) then end_bit <= LPS_Flag; zero_count <= max_count; else zero_count <= zero_count-1; end if; end if; end if; end if; End Process; -- select how many input bits to shift Process( zero_count, dout_tready, LPS_Flag ) Begin if( zero_count = 0 ) then din_tready <= dout_tready; -- if input bit is '0', shift 1 bit, else shift N bits if( LPS_Flag = '0' ) then din_tuser <= "000"; else din_tuser <= conv_std_logic_vector(N, 3); end if; else din_tready <= '0'; din_tuser <= "000"; end if; End Process; -- select output data depending on run counter Process( zero_count, max_count, end_bit ) Begin -- new input code must be read to generate run if( zero_count = 0 ) then if( max_count = 0 ) then dout_tdata <= '1'; dout_tlast <= '1'; else dout_tdata <= '0'; dout_tlast <= '0'; end if; elsif( zero_count = 1 ) then dout_tdata <= end_bit; dout_tlast <= '1'; else dout_tdata <= '0'; dout_tlast <= '0'; end if; End Process; end Behavioral;

gpl-2.0

e213b287267fc78c14198eeec1c825a5

0.556479

3.056444

false

mistryalok/Zedboard

learning/training/MSD/s06v2/hls/solution1/syn/vhdl/axi_stream_gpio.vhd

3

4,500

-- ============================================================== -- RTL generated by Vivado(TM) HLS - High-Level Synthesis from C, C++ and SystemC -- Version: 2014.4 -- Copyright (C) 2014 Xilinx Inc. All rights reserved. -- -- =========================================================== library IEEE; use IEEE.std_logic_1164.all; use IEEE.numeric_std.all; entity axi_stream_gpio is port ( ap_clk : IN STD_LOGIC; ap_rst_n : IN STD_LOGIC; ap_start : IN STD_LOGIC; ap_done : OUT STD_LOGIC; ap_idle : OUT STD_LOGIC; ap_ready : OUT STD_LOGIC; inputData_V : IN STD_LOGIC_VECTOR (0 downto 0); inputData_V_ap_vld : IN STD_LOGIC; outputData_TDATA : IN STD_LOGIC_VECTOR (31 downto 0); outputData_TVALID : IN STD_LOGIC; outputData_TREADY : OUT STD_LOGIC; ap_return : OUT STD_LOGIC_VECTOR (31 downto 0) ); end; architecture behav of axi_stream_gpio is attribute CORE_GENERATION_INFO : STRING; attribute CORE_GENERATION_INFO of behav : architecture is "axi_stream_gpio,hls_ip_2014_4,{HLS_INPUT_TYPE=cxx,HLS_INPUT_FLOAT=0,HLS_INPUT_FIXED=1,HLS_INPUT_PART=xc7z020clg484-1,HLS_INPUT_CLOCK=10.000000,HLS_INPUT_ARCH=others,HLS_SYN_CLOCK=0.000000,HLS_SYN_LAT=0,HLS_SYN_TPT=none,HLS_SYN_MEM=0,HLS_SYN_DSP=0,HLS_SYN_FF=1,HLS_SYN_LUT=0}"; constant ap_const_logic_1 : STD_LOGIC := '1'; constant ap_const_logic_0 : STD_LOGIC := '0'; constant ap_ST_st1_fsm_0 : STD_LOGIC_VECTOR (0 downto 0) := "1"; constant ap_const_lv32_0 : STD_LOGIC_VECTOR (31 downto 0) := "00000000000000000000000000000000"; constant ap_const_lv1_1 : STD_LOGIC_VECTOR (0 downto 0) := "1"; signal ap_rst_n_inv : STD_LOGIC; signal ap_CS_fsm : STD_LOGIC_VECTOR (0 downto 0) := "1"; attribute fsm_encoding : string; attribute fsm_encoding of ap_CS_fsm : signal is "none"; signal ap_sig_cseq_ST_st1_fsm_0 : STD_LOGIC; signal ap_sig_bdd_19 : BOOLEAN; signal ap_NS_fsm : STD_LOGIC_VECTOR (0 downto 0); begin -- the current state (ap_CS_fsm) of the state machine. -- ap_CS_fsm_assign_proc : process(ap_clk) begin if (ap_clk'event and ap_clk = '1') then if (ap_rst_n_inv = '1') then ap_CS_fsm <= ap_ST_st1_fsm_0; else ap_CS_fsm <= ap_NS_fsm; end if; end if; end process; -- the next state (ap_NS_fsm) of the state machine. -- ap_NS_fsm_assign_proc : process (ap_start, ap_CS_fsm) begin case ap_CS_fsm is when ap_ST_st1_fsm_0 => ap_NS_fsm <= ap_ST_st1_fsm_0; when others => ap_NS_fsm <= "X"; end case; end process; -- ap_done assign process. -- ap_done_assign_proc : process(ap_start, ap_sig_cseq_ST_st1_fsm_0) begin if (((ap_const_logic_1 = ap_sig_cseq_ST_st1_fsm_0) and not((ap_start = ap_const_logic_0)))) then ap_done <= ap_const_logic_1; else ap_done <= ap_const_logic_0; end if; end process; -- ap_idle assign process. -- ap_idle_assign_proc : process(ap_start, ap_sig_cseq_ST_st1_fsm_0) begin if ((not((ap_const_logic_1 = ap_start)) and (ap_const_logic_1 = ap_sig_cseq_ST_st1_fsm_0))) then ap_idle <= ap_const_logic_1; else ap_idle <= ap_const_logic_0; end if; end process; -- ap_ready assign process. -- ap_ready_assign_proc : process(ap_start, ap_sig_cseq_ST_st1_fsm_0) begin if (((ap_const_logic_1 = ap_sig_cseq_ST_st1_fsm_0) and not((ap_start = ap_const_logic_0)))) then ap_ready <= ap_const_logic_1; else ap_ready <= ap_const_logic_0; end if; end process; ap_return <= ap_const_lv32_0; -- ap_rst_n_inv assign process. -- ap_rst_n_inv_assign_proc : process(ap_rst_n) begin ap_rst_n_inv <= not(ap_rst_n); end process; -- ap_sig_bdd_19 assign process. -- ap_sig_bdd_19_assign_proc : process(ap_CS_fsm) begin ap_sig_bdd_19 <= (ap_CS_fsm(0 downto 0) = ap_const_lv1_1); end process; -- ap_sig_cseq_ST_st1_fsm_0 assign process. -- ap_sig_cseq_ST_st1_fsm_0_assign_proc : process(ap_sig_bdd_19) begin if (ap_sig_bdd_19) then ap_sig_cseq_ST_st1_fsm_0 <= ap_const_logic_1; else ap_sig_cseq_ST_st1_fsm_0 <= ap_const_logic_0; end if; end process; outputData_TREADY <= ap_const_logic_0; end behav;

gpl-3.0

922eca5f1f107d07adddc208e1ac1319

0.574222

3.028264

false

mistryalok/Zedboard

learning/opencv_hls/xapp1167_vivado/sw/median/prj/solution1/syn/vhdl/image_filter_Loop_1_proc.vhd

2

51,389

-- ============================================================== -- RTL generated by Vivado(TM) HLS - High-Level Synthesis from C, C++ and SystemC -- Version: 2014.4 -- Copyright (C) 2014 Xilinx Inc. All rights reserved. -- -- =========================================================== library IEEE; use IEEE.std_logic_1164.all; use IEEE.numeric_std.all; entity image_filter_Loop_1_proc is port ( ap_clk : IN STD_LOGIC; ap_rst : IN STD_LOGIC; ap_start : IN STD_LOGIC; ap_done : OUT STD_LOGIC; ap_continue : IN STD_LOGIC; ap_idle : OUT STD_LOGIC; ap_ready : OUT STD_LOGIC; rows : IN STD_LOGIC_VECTOR (31 downto 0); cols : IN STD_LOGIC_VECTOR (31 downto 0); img_1_data_stream_0_V_din : OUT STD_LOGIC_VECTOR (7 downto 0); img_1_data_stream_0_V_full_n : IN STD_LOGIC; img_1_data_stream_0_V_write : OUT STD_LOGIC; img_1_data_stream_1_V_din : OUT STD_LOGIC_VECTOR (7 downto 0); img_1_data_stream_1_V_full_n : IN STD_LOGIC; img_1_data_stream_1_V_write : OUT STD_LOGIC; img_1_data_stream_2_V_din : OUT STD_LOGIC_VECTOR (7 downto 0); img_1_data_stream_2_V_full_n : IN STD_LOGIC; img_1_data_stream_2_V_write : OUT STD_LOGIC; img_0_data_stream_0_V_dout : IN STD_LOGIC_VECTOR (7 downto 0); img_0_data_stream_0_V_empty_n : IN STD_LOGIC; img_0_data_stream_0_V_read : OUT STD_LOGIC; img_0_data_stream_1_V_dout : IN STD_LOGIC_VECTOR (7 downto 0); img_0_data_stream_1_V_empty_n : IN STD_LOGIC; img_0_data_stream_1_V_read : OUT STD_LOGIC; img_0_data_stream_2_V_dout : IN STD_LOGIC_VECTOR (7 downto 0); img_0_data_stream_2_V_empty_n : IN STD_LOGIC; img_0_data_stream_2_V_read : OUT STD_LOGIC; buffer_val_0_address0 : OUT STD_LOGIC_VECTOR (1 downto 0); buffer_val_0_ce0 : OUT STD_LOGIC; buffer_val_0_we0 : OUT STD_LOGIC; buffer_val_0_d0 : OUT STD_LOGIC_VECTOR (7 downto 0); buffer_val_0_q0 : IN STD_LOGIC_VECTOR (7 downto 0); buffer_val_0_address1 : OUT STD_LOGIC_VECTOR (1 downto 0); buffer_val_0_ce1 : OUT STD_LOGIC; buffer_val_0_we1 : OUT STD_LOGIC; buffer_val_0_d1 : OUT STD_LOGIC_VECTOR (7 downto 0); buffer_val_0_q1 : IN STD_LOGIC_VECTOR (7 downto 0); buffer_val_1_address0 : OUT STD_LOGIC_VECTOR (1 downto 0); buffer_val_1_ce0 : OUT STD_LOGIC; buffer_val_1_we0 : OUT STD_LOGIC; buffer_val_1_d0 : OUT STD_LOGIC_VECTOR (7 downto 0); buffer_val_1_q0 : IN STD_LOGIC_VECTOR (7 downto 0); buffer_val_1_address1 : OUT STD_LOGIC_VECTOR (1 downto 0); buffer_val_1_ce1 : OUT STD_LOGIC; buffer_val_1_we1 : OUT STD_LOGIC; buffer_val_1_d1 : OUT STD_LOGIC_VECTOR (7 downto 0); buffer_val_1_q1 : IN STD_LOGIC_VECTOR (7 downto 0); buffer_val_2_address0 : OUT STD_LOGIC_VECTOR (1 downto 0); buffer_val_2_ce0 : OUT STD_LOGIC; buffer_val_2_we0 : OUT STD_LOGIC; buffer_val_2_d0 : OUT STD_LOGIC_VECTOR (7 downto 0); buffer_val_2_q0 : IN STD_LOGIC_VECTOR (7 downto 0); buffer_val_2_address1 : OUT STD_LOGIC_VECTOR (1 downto 0); buffer_val_2_ce1 : OUT STD_LOGIC; buffer_val_2_we1 : OUT STD_LOGIC; buffer_val_2_d1 : OUT STD_LOGIC_VECTOR (7 downto 0); buffer_val_2_q1 : IN STD_LOGIC_VECTOR (7 downto 0) ); end; architecture behav of image_filter_Loop_1_proc is constant ap_const_logic_1 : STD_LOGIC := '1'; constant ap_const_logic_0 : STD_LOGIC := '0'; constant ap_ST_st1_fsm_0 : STD_LOGIC_VECTOR (5 downto 0) := "000001"; constant ap_ST_st2_fsm_1 : STD_LOGIC_VECTOR (5 downto 0) := "000010"; constant ap_ST_pp0_stg0_fsm_2 : STD_LOGIC_VECTOR (5 downto 0) := "000100"; constant ap_ST_pp0_stg1_fsm_3 : STD_LOGIC_VECTOR (5 downto 0) := "001000"; constant ap_ST_pp0_stg2_fsm_4 : STD_LOGIC_VECTOR (5 downto 0) := "010000"; constant ap_ST_st7_fsm_5 : STD_LOGIC_VECTOR (5 downto 0) := "100000"; constant ap_const_lv32_0 : STD_LOGIC_VECTOR (31 downto 0) := "00000000000000000000000000000000"; constant ap_const_lv1_1 : STD_LOGIC_VECTOR (0 downto 0) := "1"; constant ap_const_lv32_1 : STD_LOGIC_VECTOR (31 downto 0) := "00000000000000000000000000000001"; constant ap_const_lv32_2 : STD_LOGIC_VECTOR (31 downto 0) := "00000000000000000000000000000010"; constant ap_const_lv1_0 : STD_LOGIC_VECTOR (0 downto 0) := "0"; constant ap_const_lv32_3 : STD_LOGIC_VECTOR (31 downto 0) := "00000000000000000000000000000011"; constant ap_const_lv32_4 : STD_LOGIC_VECTOR (31 downto 0) := "00000000000000000000000000000100"; constant ap_const_lv32_5 : STD_LOGIC_VECTOR (31 downto 0) := "00000000000000000000000000000101"; constant ap_const_lv11_0 : STD_LOGIC_VECTOR (10 downto 0) := "00000000000"; constant ap_const_lv64_1 : STD_LOGIC_VECTOR (63 downto 0) := "0000000000000000000000000000000000000000000000000000000000000001"; constant ap_const_lv64_2 : STD_LOGIC_VECTOR (63 downto 0) := "0000000000000000000000000000000000000000000000000000000000000010"; constant ap_const_lv64_0 : STD_LOGIC_VECTOR (63 downto 0) := "0000000000000000000000000000000000000000000000000000000000000000"; constant ap_const_lv11_1 : STD_LOGIC_VECTOR (10 downto 0) := "00000000001"; constant ap_const_lv32_A : STD_LOGIC_VECTOR (31 downto 0) := "00000000000000000000000000001010"; constant ap_const_lv10_0 : STD_LOGIC_VECTOR (9 downto 0) := "0000000000"; signal ap_done_reg : STD_LOGIC := '0'; signal ap_CS_fsm : STD_LOGIC_VECTOR (5 downto 0) := "000001"; attribute fsm_encoding : string; attribute fsm_encoding of ap_CS_fsm : signal is "none"; signal ap_sig_cseq_ST_st1_fsm_0 : STD_LOGIC; signal ap_sig_bdd_25 : BOOLEAN; signal col_reg_269 : STD_LOGIC_VECTOR (10 downto 0); signal tmp_fu_281_p1 : STD_LOGIC_VECTOR (11 downto 0); signal ap_sig_bdd_104 : BOOLEAN; signal tmp_2_fu_285_p1 : STD_LOGIC_VECTOR (11 downto 0); signal buffer_val_0_addr_gep_fu_159_p3 : STD_LOGIC_VECTOR (1 downto 0); signal buffer_val_0_addr_reg_551 : STD_LOGIC_VECTOR (1 downto 0); signal buffer_val_0_addr_1_gep_fu_167_p3 : STD_LOGIC_VECTOR (1 downto 0); signal buffer_val_0_addr_1_reg_556 : STD_LOGIC_VECTOR (1 downto 0); signal buffer_val_1_addr_gep_fu_175_p3 : STD_LOGIC_VECTOR (1 downto 0); signal buffer_val_1_addr_reg_561 : STD_LOGIC_VECTOR (1 downto 0); signal buffer_val_1_addr_1_gep_fu_183_p3 : STD_LOGIC_VECTOR (1 downto 0); signal buffer_val_1_addr_1_reg_566 : STD_LOGIC_VECTOR (1 downto 0); signal buffer_val_2_addr_gep_fu_191_p3 : STD_LOGIC_VECTOR (1 downto 0); signal buffer_val_2_addr_reg_571 : STD_LOGIC_VECTOR (1 downto 0); signal buffer_val_2_addr_1_gep_fu_199_p3 : STD_LOGIC_VECTOR (1 downto 0); signal buffer_val_2_addr_1_reg_577 : STD_LOGIC_VECTOR (1 downto 0); signal buffer_val_0_addr_2_gep_fu_207_p3 : STD_LOGIC_VECTOR (1 downto 0); signal buffer_val_0_addr_2_reg_582 : STD_LOGIC_VECTOR (1 downto 0); signal buffer_val_1_addr_2_gep_fu_215_p3 : STD_LOGIC_VECTOR (1 downto 0); signal buffer_val_1_addr_2_reg_587 : STD_LOGIC_VECTOR (1 downto 0); signal buffer_val_2_addr_2_gep_fu_223_p3 : STD_LOGIC_VECTOR (1 downto 0); signal buffer_val_2_addr_2_reg_592 : STD_LOGIC_VECTOR (1 downto 0); signal exitcond2_fu_293_p2 : STD_LOGIC_VECTOR (0 downto 0); signal ap_sig_cseq_ST_st2_fsm_1 : STD_LOGIC; signal ap_sig_bdd_134 : BOOLEAN; signal row_1_fu_298_p2 : STD_LOGIC_VECTOR (10 downto 0); signal row_1_reg_602 : STD_LOGIC_VECTOR (10 downto 0); signal exitcond1_fu_308_p2 : STD_LOGIC_VECTOR (0 downto 0); signal exitcond1_reg_607 : STD_LOGIC_VECTOR (0 downto 0); signal ap_sig_cseq_ST_pp0_stg0_fsm_2 : STD_LOGIC; signal ap_sig_bdd_145 : BOOLEAN; signal ap_reg_ppiten_pp0_it0 : STD_LOGIC := '0'; signal ap_sig_bdd_159 : BOOLEAN; signal ap_reg_ppiten_pp0_it1 : STD_LOGIC := '0'; signal col_1_fu_313_p2 : STD_LOGIC_VECTOR (10 downto 0); signal col_1_reg_611 : STD_LOGIC_VECTOR (10 downto 0); signal icmp_fu_329_p2 : STD_LOGIC_VECTOR (0 downto 0); signal icmp_reg_616 : STD_LOGIC_VECTOR (0 downto 0); signal scl_val_0_reg_624 : STD_LOGIC_VECTOR (7 downto 0); signal ap_sig_cseq_ST_pp0_stg1_fsm_3 : STD_LOGIC; signal ap_sig_bdd_180 : BOOLEAN; signal ap_sig_bdd_190 : BOOLEAN; signal scl_val_1_reg_630 : STD_LOGIC_VECTOR (7 downto 0); signal p_val_2_reg_636 : STD_LOGIC_VECTOR (7 downto 0); signal buffer_val_0_load_reg_643 : STD_LOGIC_VECTOR (7 downto 0); signal buffer_val_1_load_reg_649 : STD_LOGIC_VECTOR (7 downto 0); signal buffer_val_2_load_reg_655 : STD_LOGIC_VECTOR (7 downto 0); signal buffer_val_0_load_1_reg_660 : STD_LOGIC_VECTOR (7 downto 0); signal buffer_val_1_load_1_reg_665 : STD_LOGIC_VECTOR (7 downto 0); signal buffer_val_2_load_1_reg_670 : STD_LOGIC_VECTOR (7 downto 0); signal c_fu_335_p2 : STD_LOGIC_VECTOR (0 downto 0); signal c_reg_675 : STD_LOGIC_VECTOR (0 downto 0); signal ult_fu_341_p2 : STD_LOGIC_VECTOR (0 downto 0); signal ult_reg_681 : STD_LOGIC_VECTOR (0 downto 0); signal rev1_fu_353_p2 : STD_LOGIC_VECTOR (0 downto 0); signal rev1_reg_686 : STD_LOGIC_VECTOR (0 downto 0); signal c_1_fu_359_p2 : STD_LOGIC_VECTOR (0 downto 0); signal c_1_reg_691 : STD_LOGIC_VECTOR (0 downto 0); signal ult2_fu_365_p2 : STD_LOGIC_VECTOR (0 downto 0); signal ult2_reg_697 : STD_LOGIC_VECTOR (0 downto 0); signal rev3_fu_377_p2 : STD_LOGIC_VECTOR (0 downto 0); signal rev3_reg_702 : STD_LOGIC_VECTOR (0 downto 0); signal c_2_fu_383_p2 : STD_LOGIC_VECTOR (0 downto 0); signal c_2_reg_707 : STD_LOGIC_VECTOR (0 downto 0); signal ult4_fu_389_p2 : STD_LOGIC_VECTOR (0 downto 0); signal ult4_reg_713 : STD_LOGIC_VECTOR (0 downto 0); signal ult5_fu_395_p2 : STD_LOGIC_VECTOR (0 downto 0); signal ult5_reg_718 : STD_LOGIC_VECTOR (0 downto 0); signal p_val_0_1_fu_427_p3 : STD_LOGIC_VECTOR (7 downto 0); signal p_val_0_1_reg_723 : STD_LOGIC_VECTOR (7 downto 0); signal ap_sig_cseq_ST_pp0_stg2_fsm_4 : STD_LOGIC; signal ap_sig_bdd_230 : BOOLEAN; signal p_val_1_1_fu_460_p3 : STD_LOGIC_VECTOR (7 downto 0); signal p_val_1_1_reg_728 : STD_LOGIC_VECTOR (7 downto 0); signal p_val_0_2_fu_499_p3 : STD_LOGIC_VECTOR (7 downto 0); signal p_val_0_2_reg_733 : STD_LOGIC_VECTOR (7 downto 0); signal sel_tmp2_fu_505_p2 : STD_LOGIC_VECTOR (0 downto 0); signal sel_tmp2_reg_738 : STD_LOGIC_VECTOR (0 downto 0); signal p_val_1_2_fu_510_p3 : STD_LOGIC_VECTOR (7 downto 0); signal p_val_1_2_reg_744 : STD_LOGIC_VECTOR (7 downto 0); signal tmp_6_fu_521_p3 : STD_LOGIC_VECTOR (7 downto 0); signal tmp_6_reg_749 : STD_LOGIC_VECTOR (7 downto 0); signal row_reg_258 : STD_LOGIC_VECTOR (10 downto 0); signal ap_sig_cseq_ST_st7_fsm_5 : STD_LOGIC; signal ap_sig_bdd_257 : BOOLEAN; signal col_phi_fu_273_p4 : STD_LOGIC_VECTOR (10 downto 0); signal row_cast_fu_289_p1 : STD_LOGIC_VECTOR (11 downto 0); signal col_cast_fu_304_p1 : STD_LOGIC_VECTOR (11 downto 0); signal tmp_3_fu_319_p4 : STD_LOGIC_VECTOR (9 downto 0); signal ult1_fu_347_p2 : STD_LOGIC_VECTOR (0 downto 0); signal ult3_fu_371_p2 : STD_LOGIC_VECTOR (0 downto 0); signal rev_fu_401_p2 : STD_LOGIC_VECTOR (0 downto 0); signal c_0_not_fu_406_p2 : STD_LOGIC_VECTOR (0 downto 0); signal brmerge1_fu_417_p2 : STD_LOGIC_VECTOR (0 downto 0); signal brmerge_fu_411_p2 : STD_LOGIC_VECTOR (0 downto 0); signal buffer_val_0_load_scl_val_0_fu_421_p3 : STD_LOGIC_VECTOR (7 downto 0); signal rev2_fu_434_p2 : STD_LOGIC_VECTOR (0 downto 0); signal c_0_not_1_fu_439_p2 : STD_LOGIC_VECTOR (0 downto 0); signal brmerge1_1_fu_450_p2 : STD_LOGIC_VECTOR (0 downto 0); signal brmerge_1_fu_444_p2 : STD_LOGIC_VECTOR (0 downto 0); signal buffer_val_1_load_scl_val_1_fu_454_p3 : STD_LOGIC_VECTOR (7 downto 0); signal rev4_fu_467_p2 : STD_LOGIC_VECTOR (0 downto 0); signal c_0_not_2_fu_472_p2 : STD_LOGIC_VECTOR (0 downto 0); signal rev5_fu_483_p2 : STD_LOGIC_VECTOR (0 downto 0); signal brmerge1_2_fu_488_p2 : STD_LOGIC_VECTOR (0 downto 0); signal brmerge_2_fu_477_p2 : STD_LOGIC_VECTOR (0 downto 0); signal buffer_val_2_load_p_val_2_fu_493_p3 : STD_LOGIC_VECTOR (7 downto 0); signal sel_tmp9_fu_516_p3 : STD_LOGIC_VECTOR (7 downto 0); signal ap_NS_fsm : STD_LOGIC_VECTOR (5 downto 0); begin -- the current state (ap_CS_fsm) of the state machine. -- ap_CS_fsm_assign_proc : process(ap_clk) begin if (ap_clk'event and ap_clk = '1') then if (ap_rst = '1') then ap_CS_fsm <= ap_ST_st1_fsm_0; else ap_CS_fsm <= ap_NS_fsm; end if; end if; end process; -- ap_done_reg assign process. -- ap_done_reg_assign_proc : process(ap_clk) begin if (ap_clk'event and ap_clk = '1') then if (ap_rst = '1') then ap_done_reg <= ap_const_logic_0; else if ((ap_const_logic_1 = ap_continue)) then ap_done_reg <= ap_const_logic_0; elsif (((ap_const_logic_1 = ap_sig_cseq_ST_st2_fsm_1) and not((exitcond2_fu_293_p2 = ap_const_lv1_0)))) then ap_done_reg <= ap_const_logic_1; end if; end if; end if; end process; -- ap_reg_ppiten_pp0_it0 assign process. -- ap_reg_ppiten_pp0_it0_assign_proc : process(ap_clk) begin if (ap_clk'event and ap_clk = '1') then if (ap_rst = '1') then ap_reg_ppiten_pp0_it0 <= ap_const_logic_0; else if (((ap_const_logic_1 = ap_sig_cseq_ST_pp0_stg0_fsm_2) and not((ap_sig_bdd_159 and (ap_const_logic_1 = ap_reg_ppiten_pp0_it1))) and not((exitcond1_fu_308_p2 = ap_const_lv1_0)))) then ap_reg_ppiten_pp0_it0 <= ap_const_logic_0; elsif (((ap_const_logic_1 = ap_sig_cseq_ST_st2_fsm_1) and (exitcond2_fu_293_p2 = ap_const_lv1_0))) then ap_reg_ppiten_pp0_it0 <= ap_const_logic_1; end if; end if; end if; end process; -- ap_reg_ppiten_pp0_it1 assign process. -- ap_reg_ppiten_pp0_it1_assign_proc : process(ap_clk) begin if (ap_clk'event and ap_clk = '1') then if (ap_rst = '1') then ap_reg_ppiten_pp0_it1 <= ap_const_logic_0; else if (((exitcond1_reg_607 = ap_const_lv1_0) and (ap_const_logic_1 = ap_sig_cseq_ST_pp0_stg2_fsm_4))) then ap_reg_ppiten_pp0_it1 <= ap_const_logic_1; elsif ((((ap_const_logic_1 = ap_sig_cseq_ST_st2_fsm_1) and (exitcond2_fu_293_p2 = ap_const_lv1_0)) or ((ap_const_logic_1 = ap_sig_cseq_ST_pp0_stg2_fsm_4) and not((exitcond1_reg_607 = ap_const_lv1_0))))) then ap_reg_ppiten_pp0_it1 <= ap_const_logic_0; end if; end if; end if; end process; -- col_reg_269 assign process. -- col_reg_269_assign_proc : process (ap_clk) begin if (ap_clk'event and ap_clk = '1') then if (((ap_const_logic_1 = ap_sig_cseq_ST_pp0_stg0_fsm_2) and (exitcond1_reg_607 = ap_const_lv1_0) and (ap_const_logic_1 = ap_reg_ppiten_pp0_it1) and not((ap_sig_bdd_159 and (ap_const_logic_1 = ap_reg_ppiten_pp0_it1))))) then col_reg_269 <= col_1_reg_611; elsif (((ap_const_logic_1 = ap_sig_cseq_ST_st2_fsm_1) and (exitcond2_fu_293_p2 = ap_const_lv1_0))) then col_reg_269 <= ap_const_lv11_0; end if; end if; end process; -- row_reg_258 assign process. -- row_reg_258_assign_proc : process (ap_clk) begin if (ap_clk'event and ap_clk = '1') then if (((ap_const_logic_1 = ap_sig_cseq_ST_st1_fsm_0) and not(ap_sig_bdd_104))) then row_reg_258 <= ap_const_lv11_0; elsif ((ap_const_logic_1 = ap_sig_cseq_ST_st7_fsm_5)) then row_reg_258 <= row_1_reg_602; end if; end if; end process; -- assign process. -- process (ap_clk) begin if (ap_clk'event and ap_clk = '1') then if (((exitcond1_reg_607 = ap_const_lv1_0) and (ap_const_logic_1 = ap_sig_cseq_ST_pp0_stg1_fsm_3) and not(((ap_const_logic_1 = ap_reg_ppiten_pp0_it0) and ap_sig_bdd_190)))) then buffer_val_0_load_1_reg_660 <= buffer_val_0_q1; buffer_val_0_load_reg_643 <= buffer_val_0_q0; buffer_val_1_load_1_reg_665 <= buffer_val_1_q1; buffer_val_1_load_reg_649 <= buffer_val_1_q0; buffer_val_2_load_1_reg_670 <= buffer_val_2_q1; buffer_val_2_load_reg_655 <= buffer_val_2_q0; c_1_reg_691 <= c_1_fu_359_p2; c_2_reg_707 <= c_2_fu_383_p2; c_reg_675 <= c_fu_335_p2; p_val_2_reg_636 <= img_0_data_stream_2_V_dout; rev1_reg_686 <= rev1_fu_353_p2; rev3_reg_702 <= rev3_fu_377_p2; scl_val_0_reg_624 <= img_0_data_stream_0_V_dout; scl_val_1_reg_630 <= img_0_data_stream_1_V_dout; ult2_reg_697 <= ult2_fu_365_p2; ult4_reg_713 <= ult4_fu_389_p2; ult5_reg_718 <= ult5_fu_395_p2; ult_reg_681 <= ult_fu_341_p2; end if; end if; end process; -- assign process. -- process (ap_clk) begin if (ap_clk'event and ap_clk = '1') then if (((ap_const_logic_1 = ap_sig_cseq_ST_pp0_stg0_fsm_2) and (ap_const_logic_1 = ap_reg_ppiten_pp0_it0) and not((ap_sig_bdd_159 and (ap_const_logic_1 = ap_reg_ppiten_pp0_it1))))) then col_1_reg_611 <= col_1_fu_313_p2; end if; end if; end process; -- assign process. -- process (ap_clk) begin if (ap_clk'event and ap_clk = '1') then if (((ap_const_logic_1 = ap_sig_cseq_ST_pp0_stg0_fsm_2) and not((ap_sig_bdd_159 and (ap_const_logic_1 = ap_reg_ppiten_pp0_it1))))) then exitcond1_reg_607 <= exitcond1_fu_308_p2; end if; end if; end process; -- assign process. -- process (ap_clk) begin if (ap_clk'event and ap_clk = '1') then if (((ap_const_logic_1 = ap_sig_cseq_ST_pp0_stg0_fsm_2) and not((ap_sig_bdd_159 and (ap_const_logic_1 = ap_reg_ppiten_pp0_it1))) and (exitcond1_fu_308_p2 = ap_const_lv1_0))) then icmp_reg_616 <= icmp_fu_329_p2; end if; end if; end process; -- assign process. -- process (ap_clk) begin if (ap_clk'event and ap_clk = '1') then if (((exitcond1_reg_607 = ap_const_lv1_0) and (ap_const_logic_1 = ap_sig_cseq_ST_pp0_stg2_fsm_4))) then p_val_0_1_reg_723 <= p_val_0_1_fu_427_p3; p_val_0_2_reg_733 <= p_val_0_2_fu_499_p3; p_val_1_1_reg_728 <= p_val_1_1_fu_460_p3; p_val_1_2_reg_744 <= p_val_1_2_fu_510_p3; sel_tmp2_reg_738 <= sel_tmp2_fu_505_p2; tmp_6_reg_749 <= tmp_6_fu_521_p3; end if; end if; end process; -- assign process. -- process (ap_clk) begin if (ap_clk'event and ap_clk = '1') then if ((ap_const_logic_1 = ap_sig_cseq_ST_st2_fsm_1)) then row_1_reg_602 <= row_1_fu_298_p2; end if; end if; end process; buffer_val_0_addr_reg_551(1 downto 0) <= "01"; buffer_val_0_addr_1_reg_556(1 downto 0) <= "10"; buffer_val_1_addr_reg_561(1 downto 0) <= "01"; buffer_val_1_addr_1_reg_566(1 downto 0) <= "10"; buffer_val_2_addr_reg_571(1 downto 0) <= "01"; buffer_val_2_addr_1_reg_577(1 downto 0) <= "10"; buffer_val_0_addr_2_reg_582(1 downto 0) <= "00"; buffer_val_1_addr_2_reg_587(1 downto 0) <= "00"; buffer_val_2_addr_2_reg_592(1 downto 0) <= "00"; -- the next state (ap_NS_fsm) of the state machine. -- ap_NS_fsm_assign_proc : process (ap_CS_fsm, ap_sig_bdd_104, exitcond2_fu_293_p2, exitcond1_fu_308_p2, ap_reg_ppiten_pp0_it0, ap_sig_bdd_159, ap_reg_ppiten_pp0_it1, ap_sig_bdd_190) begin case ap_CS_fsm is when ap_ST_st1_fsm_0 => if (not(ap_sig_bdd_104)) then ap_NS_fsm <= ap_ST_st2_fsm_1; else ap_NS_fsm <= ap_ST_st1_fsm_0; end if; when ap_ST_st2_fsm_1 => if (not((exitcond2_fu_293_p2 = ap_const_lv1_0))) then ap_NS_fsm <= ap_ST_st1_fsm_0; else ap_NS_fsm <= ap_ST_pp0_stg0_fsm_2; end if; when ap_ST_pp0_stg0_fsm_2 => if ((not((ap_sig_bdd_159 and (ap_const_logic_1 = ap_reg_ppiten_pp0_it1))) and not(((ap_const_logic_1 = ap_reg_ppiten_pp0_it0) and not((ap_sig_bdd_159 and (ap_const_logic_1 = ap_reg_ppiten_pp0_it1))) and not((exitcond1_fu_308_p2 = ap_const_lv1_0)))))) then ap_NS_fsm <= ap_ST_pp0_stg1_fsm_3; elsif (((ap_const_logic_1 = ap_reg_ppiten_pp0_it0) and not((ap_sig_bdd_159 and (ap_const_logic_1 = ap_reg_ppiten_pp0_it1))) and not((exitcond1_fu_308_p2 = ap_const_lv1_0)))) then ap_NS_fsm <= ap_ST_st7_fsm_5; else ap_NS_fsm <= ap_ST_pp0_stg0_fsm_2; end if; when ap_ST_pp0_stg1_fsm_3 => if (not(((ap_const_logic_1 = ap_reg_ppiten_pp0_it0) and ap_sig_bdd_190))) then ap_NS_fsm <= ap_ST_pp0_stg2_fsm_4; else ap_NS_fsm <= ap_ST_pp0_stg1_fsm_3; end if; when ap_ST_pp0_stg2_fsm_4 => ap_NS_fsm <= ap_ST_pp0_stg0_fsm_2; when ap_ST_st7_fsm_5 => ap_NS_fsm <= ap_ST_st2_fsm_1; when others => ap_NS_fsm <= "XXXXXX"; end case; end process; -- ap_done assign process. -- ap_done_assign_proc : process(ap_done_reg, exitcond2_fu_293_p2, ap_sig_cseq_ST_st2_fsm_1) begin if (((ap_const_logic_1 = ap_done_reg) or ((ap_const_logic_1 = ap_sig_cseq_ST_st2_fsm_1) and not((exitcond2_fu_293_p2 = ap_const_lv1_0))))) then ap_done <= ap_const_logic_1; else ap_done <= ap_const_logic_0; end if; end process; -- ap_idle assign process. -- ap_idle_assign_proc : process(ap_start, ap_sig_cseq_ST_st1_fsm_0) begin if ((not((ap_const_logic_1 = ap_start)) and (ap_const_logic_1 = ap_sig_cseq_ST_st1_fsm_0))) then ap_idle <= ap_const_logic_1; else ap_idle <= ap_const_logic_0; end if; end process; -- ap_ready assign process. -- ap_ready_assign_proc : process(exitcond2_fu_293_p2, ap_sig_cseq_ST_st2_fsm_1) begin if (((ap_const_logic_1 = ap_sig_cseq_ST_st2_fsm_1) and not((exitcond2_fu_293_p2 = ap_const_lv1_0)))) then ap_ready <= ap_const_logic_1; else ap_ready <= ap_const_logic_0; end if; end process; -- ap_sig_bdd_104 assign process. -- ap_sig_bdd_104_assign_proc : process(ap_start, ap_done_reg) begin ap_sig_bdd_104 <= ((ap_start = ap_const_logic_0) or (ap_done_reg = ap_const_logic_1)); end process; -- ap_sig_bdd_134 assign process. -- ap_sig_bdd_134_assign_proc : process(ap_CS_fsm) begin ap_sig_bdd_134 <= (ap_const_lv1_1 = ap_CS_fsm(1 downto 1)); end process; -- ap_sig_bdd_145 assign process. -- ap_sig_bdd_145_assign_proc : process(ap_CS_fsm) begin ap_sig_bdd_145 <= (ap_const_lv1_1 = ap_CS_fsm(2 downto 2)); end process; -- ap_sig_bdd_159 assign process. -- ap_sig_bdd_159_assign_proc : process(img_1_data_stream_0_V_full_n, img_1_data_stream_1_V_full_n, img_1_data_stream_2_V_full_n, exitcond1_reg_607) begin ap_sig_bdd_159 <= (((img_1_data_stream_0_V_full_n = ap_const_logic_0) and (exitcond1_reg_607 = ap_const_lv1_0)) or ((exitcond1_reg_607 = ap_const_lv1_0) and (img_1_data_stream_1_V_full_n = ap_const_logic_0)) or ((exitcond1_reg_607 = ap_const_lv1_0) and (img_1_data_stream_2_V_full_n = ap_const_logic_0))); end process; -- ap_sig_bdd_180 assign process. -- ap_sig_bdd_180_assign_proc : process(ap_CS_fsm) begin ap_sig_bdd_180 <= (ap_const_lv1_1 = ap_CS_fsm(3 downto 3)); end process; -- ap_sig_bdd_190 assign process. -- ap_sig_bdd_190_assign_proc : process(img_0_data_stream_0_V_empty_n, img_0_data_stream_1_V_empty_n, img_0_data_stream_2_V_empty_n, exitcond1_reg_607) begin ap_sig_bdd_190 <= (((exitcond1_reg_607 = ap_const_lv1_0) and (img_0_data_stream_0_V_empty_n = ap_const_logic_0)) or ((exitcond1_reg_607 = ap_const_lv1_0) and (img_0_data_stream_1_V_empty_n = ap_const_logic_0)) or ((exitcond1_reg_607 = ap_const_lv1_0) and (img_0_data_stream_2_V_empty_n = ap_const_logic_0))); end process; -- ap_sig_bdd_230 assign process. -- ap_sig_bdd_230_assign_proc : process(ap_CS_fsm) begin ap_sig_bdd_230 <= (ap_const_lv1_1 = ap_CS_fsm(4 downto 4)); end process; -- ap_sig_bdd_25 assign process. -- ap_sig_bdd_25_assign_proc : process(ap_CS_fsm) begin ap_sig_bdd_25 <= (ap_CS_fsm(0 downto 0) = ap_const_lv1_1); end process; -- ap_sig_bdd_257 assign process. -- ap_sig_bdd_257_assign_proc : process(ap_CS_fsm) begin ap_sig_bdd_257 <= (ap_const_lv1_1 = ap_CS_fsm(5 downto 5)); end process; -- ap_sig_cseq_ST_pp0_stg0_fsm_2 assign process. -- ap_sig_cseq_ST_pp0_stg0_fsm_2_assign_proc : process(ap_sig_bdd_145) begin if (ap_sig_bdd_145) then ap_sig_cseq_ST_pp0_stg0_fsm_2 <= ap_const_logic_1; else ap_sig_cseq_ST_pp0_stg0_fsm_2 <= ap_const_logic_0; end if; end process; -- ap_sig_cseq_ST_pp0_stg1_fsm_3 assign process. -- ap_sig_cseq_ST_pp0_stg1_fsm_3_assign_proc : process(ap_sig_bdd_180) begin if (ap_sig_bdd_180) then ap_sig_cseq_ST_pp0_stg1_fsm_3 <= ap_const_logic_1; else ap_sig_cseq_ST_pp0_stg1_fsm_3 <= ap_const_logic_0; end if; end process; -- ap_sig_cseq_ST_pp0_stg2_fsm_4 assign process. -- ap_sig_cseq_ST_pp0_stg2_fsm_4_assign_proc : process(ap_sig_bdd_230) begin if (ap_sig_bdd_230) then ap_sig_cseq_ST_pp0_stg2_fsm_4 <= ap_const_logic_1; else ap_sig_cseq_ST_pp0_stg2_fsm_4 <= ap_const_logic_0; end if; end process; -- ap_sig_cseq_ST_st1_fsm_0 assign process. -- ap_sig_cseq_ST_st1_fsm_0_assign_proc : process(ap_sig_bdd_25) begin if (ap_sig_bdd_25) then ap_sig_cseq_ST_st1_fsm_0 <= ap_const_logic_1; else ap_sig_cseq_ST_st1_fsm_0 <= ap_const_logic_0; end if; end process; -- ap_sig_cseq_ST_st2_fsm_1 assign process. -- ap_sig_cseq_ST_st2_fsm_1_assign_proc : process(ap_sig_bdd_134) begin if (ap_sig_bdd_134) then ap_sig_cseq_ST_st2_fsm_1 <= ap_const_logic_1; else ap_sig_cseq_ST_st2_fsm_1 <= ap_const_logic_0; end if; end process; -- ap_sig_cseq_ST_st7_fsm_5 assign process. -- ap_sig_cseq_ST_st7_fsm_5_assign_proc : process(ap_sig_bdd_257) begin if (ap_sig_bdd_257) then ap_sig_cseq_ST_st7_fsm_5 <= ap_const_logic_1; else ap_sig_cseq_ST_st7_fsm_5 <= ap_const_logic_0; end if; end process; brmerge1_1_fu_450_p2 <= (rev3_reg_702 or c_1_reg_691); brmerge1_2_fu_488_p2 <= (rev5_fu_483_p2 or c_2_reg_707); brmerge1_fu_417_p2 <= (rev1_reg_686 or c_reg_675); brmerge_1_fu_444_p2 <= (rev2_fu_434_p2 or c_0_not_1_fu_439_p2); brmerge_2_fu_477_p2 <= (rev4_fu_467_p2 or c_0_not_2_fu_472_p2); brmerge_fu_411_p2 <= (rev_fu_401_p2 or c_0_not_fu_406_p2); buffer_val_0_addr_1_gep_fu_167_p3 <= ap_const_lv64_2(2 - 1 downto 0); buffer_val_0_addr_2_gep_fu_207_p3 <= ap_const_lv64_0(2 - 1 downto 0); buffer_val_0_addr_gep_fu_159_p3 <= ap_const_lv64_1(2 - 1 downto 0); -- buffer_val_0_address0 assign process. -- buffer_val_0_address0_assign_proc : process(buffer_val_0_addr_reg_551, buffer_val_0_addr_1_reg_556, ap_sig_cseq_ST_pp0_stg0_fsm_2, ap_reg_ppiten_pp0_it0, ap_sig_cseq_ST_pp0_stg1_fsm_3, ap_sig_cseq_ST_pp0_stg2_fsm_4) begin if (((ap_const_logic_1 = ap_reg_ppiten_pp0_it0) and (ap_const_logic_1 = ap_sig_cseq_ST_pp0_stg2_fsm_4))) then buffer_val_0_address0 <= buffer_val_0_addr_1_reg_556; elsif ((((ap_const_logic_1 = ap_sig_cseq_ST_pp0_stg0_fsm_2) and (ap_const_logic_1 = ap_reg_ppiten_pp0_it0)) or ((ap_const_logic_1 = ap_reg_ppiten_pp0_it0) and (ap_const_logic_1 = ap_sig_cseq_ST_pp0_stg1_fsm_3)))) then buffer_val_0_address0 <= buffer_val_0_addr_reg_551; else buffer_val_0_address0 <= "XX"; end if; end process; buffer_val_0_address1 <= buffer_val_0_addr_2_reg_582; -- buffer_val_0_ce0 assign process. -- buffer_val_0_ce0_assign_proc : process(ap_sig_cseq_ST_pp0_stg0_fsm_2, ap_reg_ppiten_pp0_it0, ap_sig_bdd_159, ap_reg_ppiten_pp0_it1, ap_sig_cseq_ST_pp0_stg1_fsm_3, ap_sig_bdd_190, ap_sig_cseq_ST_pp0_stg2_fsm_4) begin if ((((ap_const_logic_1 = ap_sig_cseq_ST_pp0_stg0_fsm_2) and (ap_const_logic_1 = ap_reg_ppiten_pp0_it0) and not((ap_sig_bdd_159 and (ap_const_logic_1 = ap_reg_ppiten_pp0_it1)))) or ((ap_const_logic_1 = ap_reg_ppiten_pp0_it0) and (ap_const_logic_1 = ap_sig_cseq_ST_pp0_stg1_fsm_3) and not(((ap_const_logic_1 = ap_reg_ppiten_pp0_it0) and ap_sig_bdd_190))) or ((ap_const_logic_1 = ap_reg_ppiten_pp0_it0) and (ap_const_logic_1 = ap_sig_cseq_ST_pp0_stg2_fsm_4)))) then buffer_val_0_ce0 <= ap_const_logic_1; else buffer_val_0_ce0 <= ap_const_logic_0; end if; end process; -- buffer_val_0_ce1 assign process. -- buffer_val_0_ce1_assign_proc : process(ap_sig_cseq_ST_pp0_stg0_fsm_2, ap_reg_ppiten_pp0_it0, ap_sig_bdd_159, ap_reg_ppiten_pp0_it1, ap_sig_cseq_ST_pp0_stg1_fsm_3, ap_sig_bdd_190) begin if ((((ap_const_logic_1 = ap_sig_cseq_ST_pp0_stg0_fsm_2) and (ap_const_logic_1 = ap_reg_ppiten_pp0_it0) and not((ap_sig_bdd_159 and (ap_const_logic_1 = ap_reg_ppiten_pp0_it1)))) or ((ap_const_logic_1 = ap_reg_ppiten_pp0_it0) and (ap_const_logic_1 = ap_sig_cseq_ST_pp0_stg1_fsm_3) and not(((ap_const_logic_1 = ap_reg_ppiten_pp0_it0) and ap_sig_bdd_190))))) then buffer_val_0_ce1 <= ap_const_logic_1; else buffer_val_0_ce1 <= ap_const_logic_0; end if; end process; -- buffer_val_0_d0 assign process. -- buffer_val_0_d0_assign_proc : process(buffer_val_0_q1, ap_reg_ppiten_pp0_it0, ap_sig_cseq_ST_pp0_stg1_fsm_3, buffer_val_0_load_reg_643, ap_sig_cseq_ST_pp0_stg2_fsm_4) begin if ((ap_const_logic_1 = ap_reg_ppiten_pp0_it0)) then if ((ap_const_logic_1 = ap_sig_cseq_ST_pp0_stg2_fsm_4)) then buffer_val_0_d0 <= buffer_val_0_load_reg_643; elsif ((ap_const_logic_1 = ap_sig_cseq_ST_pp0_stg1_fsm_3)) then buffer_val_0_d0 <= buffer_val_0_q1; else buffer_val_0_d0 <= "XXXXXXXX"; end if; else buffer_val_0_d0 <= "XXXXXXXX"; end if; end process; buffer_val_0_d1 <= img_0_data_stream_0_V_dout; buffer_val_0_load_scl_val_0_fu_421_p3 <= buffer_val_0_load_reg_643 when (brmerge1_fu_417_p2(0) = '1') else scl_val_0_reg_624; -- buffer_val_0_we0 assign process. -- buffer_val_0_we0_assign_proc : process(exitcond1_reg_607, ap_reg_ppiten_pp0_it0, ap_sig_cseq_ST_pp0_stg1_fsm_3, ap_sig_bdd_190, ap_sig_cseq_ST_pp0_stg2_fsm_4) begin if ((((ap_const_logic_1 = ap_reg_ppiten_pp0_it0) and (exitcond1_reg_607 = ap_const_lv1_0) and (ap_const_logic_1 = ap_sig_cseq_ST_pp0_stg1_fsm_3) and not(((ap_const_logic_1 = ap_reg_ppiten_pp0_it0) and ap_sig_bdd_190))) or ((ap_const_logic_1 = ap_reg_ppiten_pp0_it0) and (exitcond1_reg_607 = ap_const_lv1_0) and (ap_const_logic_1 = ap_sig_cseq_ST_pp0_stg2_fsm_4)))) then buffer_val_0_we0 <= ap_const_logic_1; else buffer_val_0_we0 <= ap_const_logic_0; end if; end process; -- buffer_val_0_we1 assign process. -- buffer_val_0_we1_assign_proc : process(exitcond1_reg_607, ap_reg_ppiten_pp0_it0, ap_sig_cseq_ST_pp0_stg1_fsm_3, ap_sig_bdd_190) begin if ((((ap_const_logic_1 = ap_reg_ppiten_pp0_it0) and (exitcond1_reg_607 = ap_const_lv1_0) and (ap_const_logic_1 = ap_sig_cseq_ST_pp0_stg1_fsm_3) and not(((ap_const_logic_1 = ap_reg_ppiten_pp0_it0) and ap_sig_bdd_190))))) then buffer_val_0_we1 <= ap_const_logic_1; else buffer_val_0_we1 <= ap_const_logic_0; end if; end process; buffer_val_1_addr_1_gep_fu_183_p3 <= ap_const_lv64_2(2 - 1 downto 0); buffer_val_1_addr_2_gep_fu_215_p3 <= ap_const_lv64_0(2 - 1 downto 0); buffer_val_1_addr_gep_fu_175_p3 <= ap_const_lv64_1(2 - 1 downto 0); -- buffer_val_1_address0 assign process. -- buffer_val_1_address0_assign_proc : process(buffer_val_1_addr_reg_561, buffer_val_1_addr_1_reg_566, ap_sig_cseq_ST_pp0_stg0_fsm_2, ap_reg_ppiten_pp0_it0, ap_sig_cseq_ST_pp0_stg1_fsm_3, ap_sig_cseq_ST_pp0_stg2_fsm_4) begin if (((ap_const_logic_1 = ap_reg_ppiten_pp0_it0) and (ap_const_logic_1 = ap_sig_cseq_ST_pp0_stg2_fsm_4))) then buffer_val_1_address0 <= buffer_val_1_addr_1_reg_566; elsif ((((ap_const_logic_1 = ap_sig_cseq_ST_pp0_stg0_fsm_2) and (ap_const_logic_1 = ap_reg_ppiten_pp0_it0)) or ((ap_const_logic_1 = ap_reg_ppiten_pp0_it0) and (ap_const_logic_1 = ap_sig_cseq_ST_pp0_stg1_fsm_3)))) then buffer_val_1_address0 <= buffer_val_1_addr_reg_561; else buffer_val_1_address0 <= "XX"; end if; end process; buffer_val_1_address1 <= buffer_val_1_addr_2_reg_587; -- buffer_val_1_ce0 assign process. -- buffer_val_1_ce0_assign_proc : process(ap_sig_cseq_ST_pp0_stg0_fsm_2, ap_reg_ppiten_pp0_it0, ap_sig_bdd_159, ap_reg_ppiten_pp0_it1, ap_sig_cseq_ST_pp0_stg1_fsm_3, ap_sig_bdd_190, ap_sig_cseq_ST_pp0_stg2_fsm_4) begin if ((((ap_const_logic_1 = ap_sig_cseq_ST_pp0_stg0_fsm_2) and (ap_const_logic_1 = ap_reg_ppiten_pp0_it0) and not((ap_sig_bdd_159 and (ap_const_logic_1 = ap_reg_ppiten_pp0_it1)))) or ((ap_const_logic_1 = ap_reg_ppiten_pp0_it0) and (ap_const_logic_1 = ap_sig_cseq_ST_pp0_stg1_fsm_3) and not(((ap_const_logic_1 = ap_reg_ppiten_pp0_it0) and ap_sig_bdd_190))) or ((ap_const_logic_1 = ap_reg_ppiten_pp0_it0) and (ap_const_logic_1 = ap_sig_cseq_ST_pp0_stg2_fsm_4)))) then buffer_val_1_ce0 <= ap_const_logic_1; else buffer_val_1_ce0 <= ap_const_logic_0; end if; end process; -- buffer_val_1_ce1 assign process. -- buffer_val_1_ce1_assign_proc : process(ap_sig_cseq_ST_pp0_stg0_fsm_2, ap_reg_ppiten_pp0_it0, ap_sig_bdd_159, ap_reg_ppiten_pp0_it1, ap_sig_cseq_ST_pp0_stg1_fsm_3, ap_sig_bdd_190) begin if ((((ap_const_logic_1 = ap_sig_cseq_ST_pp0_stg0_fsm_2) and (ap_const_logic_1 = ap_reg_ppiten_pp0_it0) and not((ap_sig_bdd_159 and (ap_const_logic_1 = ap_reg_ppiten_pp0_it1)))) or ((ap_const_logic_1 = ap_reg_ppiten_pp0_it0) and (ap_const_logic_1 = ap_sig_cseq_ST_pp0_stg1_fsm_3) and not(((ap_const_logic_1 = ap_reg_ppiten_pp0_it0) and ap_sig_bdd_190))))) then buffer_val_1_ce1 <= ap_const_logic_1; else buffer_val_1_ce1 <= ap_const_logic_0; end if; end process; -- buffer_val_1_d0 assign process. -- buffer_val_1_d0_assign_proc : process(buffer_val_1_q1, ap_reg_ppiten_pp0_it0, ap_sig_cseq_ST_pp0_stg1_fsm_3, buffer_val_1_load_reg_649, ap_sig_cseq_ST_pp0_stg2_fsm_4) begin if ((ap_const_logic_1 = ap_reg_ppiten_pp0_it0)) then if ((ap_const_logic_1 = ap_sig_cseq_ST_pp0_stg2_fsm_4)) then buffer_val_1_d0 <= buffer_val_1_load_reg_649; elsif ((ap_const_logic_1 = ap_sig_cseq_ST_pp0_stg1_fsm_3)) then buffer_val_1_d0 <= buffer_val_1_q1; else buffer_val_1_d0 <= "XXXXXXXX"; end if; else buffer_val_1_d0 <= "XXXXXXXX"; end if; end process; buffer_val_1_d1 <= img_0_data_stream_1_V_dout; buffer_val_1_load_scl_val_1_fu_454_p3 <= buffer_val_1_load_reg_649 when (brmerge1_1_fu_450_p2(0) = '1') else scl_val_1_reg_630; -- buffer_val_1_we0 assign process. -- buffer_val_1_we0_assign_proc : process(exitcond1_reg_607, ap_reg_ppiten_pp0_it0, ap_sig_cseq_ST_pp0_stg1_fsm_3, ap_sig_bdd_190, ap_sig_cseq_ST_pp0_stg2_fsm_4) begin if ((((ap_const_logic_1 = ap_reg_ppiten_pp0_it0) and (exitcond1_reg_607 = ap_const_lv1_0) and (ap_const_logic_1 = ap_sig_cseq_ST_pp0_stg1_fsm_3) and not(((ap_const_logic_1 = ap_reg_ppiten_pp0_it0) and ap_sig_bdd_190))) or ((ap_const_logic_1 = ap_reg_ppiten_pp0_it0) and (exitcond1_reg_607 = ap_const_lv1_0) and (ap_const_logic_1 = ap_sig_cseq_ST_pp0_stg2_fsm_4)))) then buffer_val_1_we0 <= ap_const_logic_1; else buffer_val_1_we0 <= ap_const_logic_0; end if; end process; -- buffer_val_1_we1 assign process. -- buffer_val_1_we1_assign_proc : process(exitcond1_reg_607, ap_reg_ppiten_pp0_it0, ap_sig_cseq_ST_pp0_stg1_fsm_3, ap_sig_bdd_190) begin if ((((ap_const_logic_1 = ap_reg_ppiten_pp0_it0) and (exitcond1_reg_607 = ap_const_lv1_0) and (ap_const_logic_1 = ap_sig_cseq_ST_pp0_stg1_fsm_3) and not(((ap_const_logic_1 = ap_reg_ppiten_pp0_it0) and ap_sig_bdd_190))))) then buffer_val_1_we1 <= ap_const_logic_1; else buffer_val_1_we1 <= ap_const_logic_0; end if; end process; buffer_val_2_addr_1_gep_fu_199_p3 <= ap_const_lv64_2(2 - 1 downto 0); buffer_val_2_addr_2_gep_fu_223_p3 <= ap_const_lv64_0(2 - 1 downto 0); buffer_val_2_addr_gep_fu_191_p3 <= ap_const_lv64_1(2 - 1 downto 0); -- buffer_val_2_address0 assign process. -- buffer_val_2_address0_assign_proc : process(buffer_val_2_addr_reg_571, buffer_val_2_addr_1_reg_577, buffer_val_2_addr_2_reg_592, ap_sig_cseq_ST_pp0_stg0_fsm_2, ap_reg_ppiten_pp0_it0, ap_sig_cseq_ST_pp0_stg1_fsm_3, ap_sig_cseq_ST_pp0_stg2_fsm_4) begin if ((ap_const_logic_1 = ap_reg_ppiten_pp0_it0)) then if ((ap_const_logic_1 = ap_sig_cseq_ST_pp0_stg2_fsm_4)) then buffer_val_2_address0 <= buffer_val_2_addr_2_reg_592; elsif ((ap_const_logic_1 = ap_sig_cseq_ST_pp0_stg1_fsm_3)) then buffer_val_2_address0 <= buffer_val_2_addr_1_reg_577; elsif ((ap_const_logic_1 = ap_sig_cseq_ST_pp0_stg0_fsm_2)) then buffer_val_2_address0 <= buffer_val_2_addr_reg_571; else buffer_val_2_address0 <= "XX"; end if; else buffer_val_2_address0 <= "XX"; end if; end process; -- buffer_val_2_address1 assign process. -- buffer_val_2_address1_assign_proc : process(buffer_val_2_addr_reg_571, buffer_val_2_addr_2_reg_592, ap_sig_cseq_ST_pp0_stg0_fsm_2, ap_reg_ppiten_pp0_it0, ap_sig_cseq_ST_pp0_stg1_fsm_3) begin if ((ap_const_logic_1 = ap_reg_ppiten_pp0_it0)) then if ((ap_const_logic_1 = ap_sig_cseq_ST_pp0_stg1_fsm_3)) then buffer_val_2_address1 <= buffer_val_2_addr_reg_571; elsif ((ap_const_logic_1 = ap_sig_cseq_ST_pp0_stg0_fsm_2)) then buffer_val_2_address1 <= buffer_val_2_addr_2_reg_592; else buffer_val_2_address1 <= "XX"; end if; else buffer_val_2_address1 <= "XX"; end if; end process; -- buffer_val_2_ce0 assign process. -- buffer_val_2_ce0_assign_proc : process(ap_sig_cseq_ST_pp0_stg0_fsm_2, ap_reg_ppiten_pp0_it0, ap_sig_bdd_159, ap_reg_ppiten_pp0_it1, ap_sig_cseq_ST_pp0_stg1_fsm_3, ap_sig_bdd_190, ap_sig_cseq_ST_pp0_stg2_fsm_4) begin if ((((ap_const_logic_1 = ap_sig_cseq_ST_pp0_stg0_fsm_2) and (ap_const_logic_1 = ap_reg_ppiten_pp0_it0) and not((ap_sig_bdd_159 and (ap_const_logic_1 = ap_reg_ppiten_pp0_it1)))) or ((ap_const_logic_1 = ap_reg_ppiten_pp0_it0) and (ap_const_logic_1 = ap_sig_cseq_ST_pp0_stg1_fsm_3) and not(((ap_const_logic_1 = ap_reg_ppiten_pp0_it0) and ap_sig_bdd_190))) or ((ap_const_logic_1 = ap_reg_ppiten_pp0_it0) and (ap_const_logic_1 = ap_sig_cseq_ST_pp0_stg2_fsm_4)))) then buffer_val_2_ce0 <= ap_const_logic_1; else buffer_val_2_ce0 <= ap_const_logic_0; end if; end process; -- buffer_val_2_ce1 assign process. -- buffer_val_2_ce1_assign_proc : process(ap_sig_cseq_ST_pp0_stg0_fsm_2, ap_reg_ppiten_pp0_it0, ap_sig_bdd_159, ap_reg_ppiten_pp0_it1, ap_sig_cseq_ST_pp0_stg1_fsm_3, ap_sig_bdd_190) begin if ((((ap_const_logic_1 = ap_sig_cseq_ST_pp0_stg0_fsm_2) and (ap_const_logic_1 = ap_reg_ppiten_pp0_it0) and not((ap_sig_bdd_159 and (ap_const_logic_1 = ap_reg_ppiten_pp0_it1)))) or ((ap_const_logic_1 = ap_reg_ppiten_pp0_it0) and (ap_const_logic_1 = ap_sig_cseq_ST_pp0_stg1_fsm_3) and not(((ap_const_logic_1 = ap_reg_ppiten_pp0_it0) and ap_sig_bdd_190))))) then buffer_val_2_ce1 <= ap_const_logic_1; else buffer_val_2_ce1 <= ap_const_logic_0; end if; end process; -- buffer_val_2_d0 assign process. -- buffer_val_2_d0_assign_proc : process(buffer_val_2_q0, ap_reg_ppiten_pp0_it0, ap_sig_cseq_ST_pp0_stg1_fsm_3, p_val_2_reg_636, ap_sig_cseq_ST_pp0_stg2_fsm_4) begin if ((ap_const_logic_1 = ap_reg_ppiten_pp0_it0)) then if ((ap_const_logic_1 = ap_sig_cseq_ST_pp0_stg2_fsm_4)) then buffer_val_2_d0 <= p_val_2_reg_636; elsif ((ap_const_logic_1 = ap_sig_cseq_ST_pp0_stg1_fsm_3)) then buffer_val_2_d0 <= buffer_val_2_q0; else buffer_val_2_d0 <= "XXXXXXXX"; end if; else buffer_val_2_d0 <= "XXXXXXXX"; end if; end process; buffer_val_2_d1 <= buffer_val_2_q1; buffer_val_2_load_p_val_2_fu_493_p3 <= buffer_val_2_load_reg_655 when (brmerge1_2_fu_488_p2(0) = '1') else p_val_2_reg_636; -- buffer_val_2_we0 assign process. -- buffer_val_2_we0_assign_proc : process(exitcond1_reg_607, ap_reg_ppiten_pp0_it0, ap_sig_cseq_ST_pp0_stg1_fsm_3, ap_sig_bdd_190, ap_sig_cseq_ST_pp0_stg2_fsm_4) begin if ((((ap_const_logic_1 = ap_reg_ppiten_pp0_it0) and (exitcond1_reg_607 = ap_const_lv1_0) and (ap_const_logic_1 = ap_sig_cseq_ST_pp0_stg1_fsm_3) and not(((ap_const_logic_1 = ap_reg_ppiten_pp0_it0) and ap_sig_bdd_190))) or ((ap_const_logic_1 = ap_reg_ppiten_pp0_it0) and (exitcond1_reg_607 = ap_const_lv1_0) and (ap_const_logic_1 = ap_sig_cseq_ST_pp0_stg2_fsm_4)))) then buffer_val_2_we0 <= ap_const_logic_1; else buffer_val_2_we0 <= ap_const_logic_0; end if; end process; -- buffer_val_2_we1 assign process. -- buffer_val_2_we1_assign_proc : process(exitcond1_reg_607, ap_reg_ppiten_pp0_it0, ap_sig_cseq_ST_pp0_stg1_fsm_3, ap_sig_bdd_190) begin if ((((ap_const_logic_1 = ap_reg_ppiten_pp0_it0) and (exitcond1_reg_607 = ap_const_lv1_0) and (ap_const_logic_1 = ap_sig_cseq_ST_pp0_stg1_fsm_3) and not(((ap_const_logic_1 = ap_reg_ppiten_pp0_it0) and ap_sig_bdd_190))))) then buffer_val_2_we1 <= ap_const_logic_1; else buffer_val_2_we1 <= ap_const_logic_0; end if; end process; c_0_not_1_fu_439_p2 <= (c_1_reg_691 xor ap_const_lv1_1); c_0_not_2_fu_472_p2 <= (c_2_reg_707 xor ap_const_lv1_1); c_0_not_fu_406_p2 <= (c_reg_675 xor ap_const_lv1_1); c_1_fu_359_p2 <= "1" when (unsigned(buffer_val_1_q1) > unsigned(img_0_data_stream_1_V_dout)) else "0"; c_2_fu_383_p2 <= "1" when (unsigned(buffer_val_2_q1) > unsigned(img_0_data_stream_2_V_dout)) else "0"; c_fu_335_p2 <= "1" when (unsigned(buffer_val_0_q1) > unsigned(img_0_data_stream_0_V_dout)) else "0"; col_1_fu_313_p2 <= std_logic_vector(unsigned(col_phi_fu_273_p4) + unsigned(ap_const_lv11_1)); col_cast_fu_304_p1 <= std_logic_vector(resize(unsigned(col_phi_fu_273_p4),12)); -- col_phi_fu_273_p4 assign process. -- col_phi_fu_273_p4_assign_proc : process(col_reg_269, exitcond1_reg_607, ap_sig_cseq_ST_pp0_stg0_fsm_2, ap_reg_ppiten_pp0_it1, col_1_reg_611) begin if (((ap_const_logic_1 = ap_sig_cseq_ST_pp0_stg0_fsm_2) and (exitcond1_reg_607 = ap_const_lv1_0) and (ap_const_logic_1 = ap_reg_ppiten_pp0_it1))) then col_phi_fu_273_p4 <= col_1_reg_611; else col_phi_fu_273_p4 <= col_reg_269; end if; end process; exitcond1_fu_308_p2 <= "1" when (col_cast_fu_304_p1 = tmp_2_fu_285_p1) else "0"; exitcond2_fu_293_p2 <= "1" when (row_cast_fu_289_p1 = tmp_fu_281_p1) else "0"; icmp_fu_329_p2 <= "0" when (tmp_3_fu_319_p4 = ap_const_lv10_0) else "1"; -- img_0_data_stream_0_V_read assign process. -- img_0_data_stream_0_V_read_assign_proc : process(exitcond1_reg_607, ap_reg_ppiten_pp0_it0, ap_sig_cseq_ST_pp0_stg1_fsm_3, ap_sig_bdd_190) begin if (((ap_const_logic_1 = ap_reg_ppiten_pp0_it0) and (exitcond1_reg_607 = ap_const_lv1_0) and (ap_const_logic_1 = ap_sig_cseq_ST_pp0_stg1_fsm_3) and not(((ap_const_logic_1 = ap_reg_ppiten_pp0_it0) and ap_sig_bdd_190)))) then img_0_data_stream_0_V_read <= ap_const_logic_1; else img_0_data_stream_0_V_read <= ap_const_logic_0; end if; end process; -- img_0_data_stream_1_V_read assign process. -- img_0_data_stream_1_V_read_assign_proc : process(exitcond1_reg_607, ap_reg_ppiten_pp0_it0, ap_sig_cseq_ST_pp0_stg1_fsm_3, ap_sig_bdd_190) begin if (((ap_const_logic_1 = ap_reg_ppiten_pp0_it0) and (exitcond1_reg_607 = ap_const_lv1_0) and (ap_const_logic_1 = ap_sig_cseq_ST_pp0_stg1_fsm_3) and not(((ap_const_logic_1 = ap_reg_ppiten_pp0_it0) and ap_sig_bdd_190)))) then img_0_data_stream_1_V_read <= ap_const_logic_1; else img_0_data_stream_1_V_read <= ap_const_logic_0; end if; end process; -- img_0_data_stream_2_V_read assign process. -- img_0_data_stream_2_V_read_assign_proc : process(exitcond1_reg_607, ap_reg_ppiten_pp0_it0, ap_sig_cseq_ST_pp0_stg1_fsm_3, ap_sig_bdd_190) begin if (((ap_const_logic_1 = ap_reg_ppiten_pp0_it0) and (exitcond1_reg_607 = ap_const_lv1_0) and (ap_const_logic_1 = ap_sig_cseq_ST_pp0_stg1_fsm_3) and not(((ap_const_logic_1 = ap_reg_ppiten_pp0_it0) and ap_sig_bdd_190)))) then img_0_data_stream_2_V_read <= ap_const_logic_1; else img_0_data_stream_2_V_read <= ap_const_logic_0; end if; end process; img_1_data_stream_0_V_din <= p_val_0_1_reg_723 when (sel_tmp2_reg_738(0) = '1') else p_val_0_2_reg_733; -- img_1_data_stream_0_V_write assign process. -- img_1_data_stream_0_V_write_assign_proc : process(exitcond1_reg_607, ap_sig_cseq_ST_pp0_stg0_fsm_2, ap_sig_bdd_159, ap_reg_ppiten_pp0_it1) begin if (((ap_const_logic_1 = ap_sig_cseq_ST_pp0_stg0_fsm_2) and (exitcond1_reg_607 = ap_const_lv1_0) and (ap_const_logic_1 = ap_reg_ppiten_pp0_it1) and not((ap_sig_bdd_159 and (ap_const_logic_1 = ap_reg_ppiten_pp0_it1))))) then img_1_data_stream_0_V_write <= ap_const_logic_1; else img_1_data_stream_0_V_write <= ap_const_logic_0; end if; end process; img_1_data_stream_1_V_din <= p_val_1_1_reg_728 when (sel_tmp2_reg_738(0) = '1') else p_val_1_2_reg_744; -- img_1_data_stream_1_V_write assign process. -- img_1_data_stream_1_V_write_assign_proc : process(exitcond1_reg_607, ap_sig_cseq_ST_pp0_stg0_fsm_2, ap_sig_bdd_159, ap_reg_ppiten_pp0_it1) begin if (((ap_const_logic_1 = ap_sig_cseq_ST_pp0_stg0_fsm_2) and (exitcond1_reg_607 = ap_const_lv1_0) and (ap_const_logic_1 = ap_reg_ppiten_pp0_it1) and not((ap_sig_bdd_159 and (ap_const_logic_1 = ap_reg_ppiten_pp0_it1))))) then img_1_data_stream_1_V_write <= ap_const_logic_1; else img_1_data_stream_1_V_write <= ap_const_logic_0; end if; end process; img_1_data_stream_2_V_din <= tmp_6_reg_749; -- img_1_data_stream_2_V_write assign process. -- img_1_data_stream_2_V_write_assign_proc : process(exitcond1_reg_607, ap_sig_cseq_ST_pp0_stg0_fsm_2, ap_sig_bdd_159, ap_reg_ppiten_pp0_it1) begin if (((ap_const_logic_1 = ap_sig_cseq_ST_pp0_stg0_fsm_2) and (exitcond1_reg_607 = ap_const_lv1_0) and (ap_const_logic_1 = ap_reg_ppiten_pp0_it1) and not((ap_sig_bdd_159 and (ap_const_logic_1 = ap_reg_ppiten_pp0_it1))))) then img_1_data_stream_2_V_write <= ap_const_logic_1; else img_1_data_stream_2_V_write <= ap_const_logic_0; end if; end process; p_val_0_1_fu_427_p3 <= buffer_val_0_load_scl_val_0_fu_421_p3 when (brmerge_fu_411_p2(0) = '1') else buffer_val_0_load_1_reg_660; p_val_0_2_fu_499_p3 <= p_val_0_1_fu_427_p3 when (icmp_reg_616(0) = '1') else scl_val_0_reg_624; p_val_1_1_fu_460_p3 <= buffer_val_1_load_scl_val_1_fu_454_p3 when (brmerge_1_fu_444_p2(0) = '1') else buffer_val_1_load_1_reg_665; p_val_1_2_fu_510_p3 <= p_val_1_1_fu_460_p3 when (icmp_reg_616(0) = '1') else scl_val_1_reg_630; rev1_fu_353_p2 <= (ult1_fu_347_p2 xor ap_const_lv1_1); rev2_fu_434_p2 <= (ult2_reg_697 xor ap_const_lv1_1); rev3_fu_377_p2 <= (ult3_fu_371_p2 xor ap_const_lv1_1); rev4_fu_467_p2 <= (ult4_reg_713 xor ap_const_lv1_1); rev5_fu_483_p2 <= (ult5_reg_718 xor ap_const_lv1_1); rev_fu_401_p2 <= (ult_reg_681 xor ap_const_lv1_1); row_1_fu_298_p2 <= std_logic_vector(unsigned(row_reg_258) + unsigned(ap_const_lv11_1)); row_cast_fu_289_p1 <= std_logic_vector(resize(unsigned(row_reg_258),12)); sel_tmp2_fu_505_p2 <= (icmp_reg_616 and brmerge_2_fu_477_p2); sel_tmp9_fu_516_p3 <= buffer_val_2_load_1_reg_670 when (icmp_reg_616(0) = '1') else p_val_2_reg_636; tmp_2_fu_285_p1 <= cols(12 - 1 downto 0); tmp_3_fu_319_p4 <= col_phi_fu_273_p4(10 downto 1); tmp_6_fu_521_p3 <= buffer_val_2_load_p_val_2_fu_493_p3 when (sel_tmp2_fu_505_p2(0) = '1') else sel_tmp9_fu_516_p3; tmp_fu_281_p1 <= rows(12 - 1 downto 0); ult1_fu_347_p2 <= "1" when (unsigned(img_0_data_stream_0_V_dout) < unsigned(buffer_val_0_q0)) else "0"; ult2_fu_365_p2 <= "1" when (unsigned(buffer_val_1_q1) < unsigned(buffer_val_1_q0)) else "0"; ult3_fu_371_p2 <= "1" when (unsigned(img_0_data_stream_1_V_dout) < unsigned(buffer_val_1_q0)) else "0"; ult4_fu_389_p2 <= "1" when (unsigned(buffer_val_2_q1) < unsigned(buffer_val_2_q0)) else "0"; ult5_fu_395_p2 <= "1" when (unsigned(img_0_data_stream_2_V_dout) < unsigned(buffer_val_2_q0)) else "0"; ult_fu_341_p2 <= "1" when (unsigned(buffer_val_0_q1) < unsigned(buffer_val_0_q0)) else "0"; end behav;

gpl-3.0

19f7bf2117513b45b54b97634b37387e

0.599486

2.58978

false

mistryalok/Zedboard

learning/opencv_hls/xapp1167_ise/hw/xps_proj/pcores/logicvc_v3_00_a/doc/logicvc_comp.vhd

1

22,930

package logicbricks is -- START COMPONENT component logicvc is generic ( -- Version generics C_IP_LICENSE_TYPE : integer := 0; -- IP encryption type: 0 = source, 1 = evaluation, 2 = release, 3 = university evaluation C_IP_MAJOR_REVISION : integer := 0; -- IP major revision: 0 - 31; vXX_yy_z C_IP_MINOR_REVISION : integer := 0; -- IP minor revision: 0 - 31; vxx_YY_z C_IP_PATCH_LEVEL : integer := 0; -- IP patch level: 0 - 25; vxx_yy_Z C_IP_LICENSE_CHECK : integer := 0; -- IP license check: 0 = no, 1 = yes C_IP_TIME_BEFORE_BREAK : integer := 0; -- IP time before break: 0 = infinite, 1 = 1h, 2 = 12h, 3 = 24h C_FAMILY : string := "spartan6"; -- Video memory generics C_VMEM_INTERFACE : integer := 0; -- Use PLB, XMB or AXI to access video memory: 0 - PLB, 1 - XMB, 2 - AXI C_VMEM_BASEADDR : std_logic_vector := x"FFFFFFFF"; C_VMEM_HIGHADDR : std_logic_vector := x"00000000"; C_MEM_BURST : integer := 4; -- Memory burst width; 4, 5 or 6. (4 means burst lasts 16 transfers), Used for XMB and AXI C_MEM_BYTE_SWAP : integer := 0; -- Memory access byte swap: 0 - Do not swap, 1 - Swap C_MEM_LITTLE_ENDIAN : integer := 1; -- Memory access endianness: 0 - Big endian, 1 - Little endian C_INCREASE_FIFO : integer := 1; -- FIFO size multiplication factor: 1=1x, 2=2x, 4=4x, 8=8x -- Master PLB generics C_MPLB_NUM_MASTERS : integer := 8; C_MPLB_AWIDTH : integer := 32; C_MPLB_DWIDTH : integer := 64; C_MPLB_PRIORITY : integer := 3; C_MPLB_SMALLEST_SLAVE : integer := 32; -- XMB generics C_XMB_DATA_BUS_WIDTH : integer := 64; -- XMB Memory interface data bus width -- Master AXI generics C_M_AXI_THREAD_ID_WIDTH : integer := 1; C_M_AXI_DATA_WIDTH : integer := 64; C_M_AXI_ADDR_WIDTH : integer := 32; -- Registers generics C_REGS_INTERFACE : integer := 0; -- Use OPB, PLB or AXI interface for registers: 0 - OPB, 1 - PLB, 2 - AXI C_READABLE_REGS : integer := 1; -- Are logiCVC registers readable?: 0 - no, 1 - yes C_REG_BYTE_SWAP : integer := 0; -- Registers access byte swap: 0 - Do not swap, 1 - Swap -- OPB generics C_REGS_BASEADDR : std_logic_vector := x"FFFFFFFF"; C_REGS_HIGHADDR : std_logic_vector := x"00000000"; C_OPB_AWIDTH : integer := 32; C_OPB_DWIDTH : integer := 32; -- Slave PLB generics C_SPLB_NUM_MASTERS : integer := 8; C_SPLB_MID_WIDTH : integer := 1; C_SPLB_AWIDTH : integer := 32; C_SPLB_DWIDTH : integer := 32; C_SPLB_NATIVE_DWIDTH : integer := 32; -- AXI4-Lite Slave generics C_S_AXI_ADDR_WIDTH : integer := 32; C_S_AXI_DATA_WIDTH : integer := 32; -- Output format C_PIXEL_DATA_WIDTH : integer := 24; -- Output data width: 12, 15, 16, 18 or 24 C_USE_VCLK2 : integer := 1; -- pix_clk rising edge will be in the middle of the DDR RGB data eye or synchronous if not used C_ROW_STRIDE : integer := 1024; -- Row stride in number of pixels C_XCOLOR : integer := 0; C_USE_SIZE_POSITION : integer := 0; -- Use layer size, position and offset functionality: 0 - no, 1 - yes C_DISPLAY_INTERFACE : integer := 0; -- Select output interface type: 0 - parallel only, 1 - ITU656, 2 - LVDS 4bit, 3 - camera link, 4 - LVDS 3bit, 5 - DVI C_DISPLAY_COLOR_SPACE : integer := 0; -- Select output interface color space: 0 - RGB, 1 - YCbCr 4:2:2, 2 - YCbCr 4:4:4 C_LVDS_DATA_WIDTH : integer := 4; -- 3 or 4 C_VCLK_PERIOD : integer := 25000; -- vclk clock period in ps -- Multilayer generics C_NUM_OF_LAYERS : positive := 3; -- Number of logiCVC layers: 1, 2, 3, 4 or 5 C_LAYER_0_TYPE : integer := 0; -- Layer 0 type: 0 - RGB, 1 - YCbCr C_LAYER_1_TYPE : integer := 0; -- Layer 0 type: 0 - RGB, 1 - YCbCr, 2 - Alpha C_LAYER_2_TYPE : integer := 0; -- Layer 0 type: 0 - RGB, 1 - YCbCr C_LAYER_3_TYPE : integer := 0; -- Layer 0 type: 0 - RGB, 1 - YCbCr, 2 - Alpha C_LAYER_4_TYPE : integer := 0; -- Layer 0 type: 0 - RGB, 1 - YCbCr C_LAYER_0_DATA_WIDTH : positive := 16; -- Layer 0 data width: 8, 16, 24 bit C_LAYER_1_DATA_WIDTH : positive := 16; -- Layer 1 data width: 8, 16, 24 bit C_LAYER_2_DATA_WIDTH : positive := 16; -- Layer 2 data width: 8, 16, 24 bit C_LAYER_3_DATA_WIDTH : positive := 16; -- Layer 3 data width: 8, 16, 24 bit C_LAYER_4_DATA_WIDTH : positive := 16; -- Layer 4 data width: 8, 16, 24 bit C_LAYER_0_ALPHA_MODE : integer := 0; -- Layer 0 alpha blending mode: 0 - layer, 1 - pixel, 2 - clut 16, 3 - clut 24 C_LAYER_1_ALPHA_MODE : integer := 0; -- Layer 1 alpha blending mode: 0 - layer, 1 - pixel, 2 - clut 16, 3 - clut 24 C_LAYER_2_ALPHA_MODE : integer := 0; -- Layer 2 alpha blending mode: 0 - layer, 1 - pixel, 2 - clut 16, 3 - clut 24 C_LAYER_3_ALPHA_MODE : integer := 0; -- Layer 3 alpha blending mode: 0 - layer, 1 - pixel, 2 - clut 16, 3 - clut 24 C_LAYER_4_ALPHA_MODE : integer := 0; -- Layer 4 alpha blending mode: 0 - layer, 1 - pixel, 2 - clut 16, 3 - clut 24 C_USE_BACKGROUND : integer := 0; -- configure last layer as background: 0 - no, 1 - yes C_USE_XTREME_DSP : integer := 2; -- enable or disable use of DSP resources: 0 - no, 1 - yes, 2 - auto C_USE_MULTIPLIER : integer := 2; -- control way in which multipliers in blender are implemented: 0 - lut, 1 - block, 2 - auto C_LAYER_0_OFFSET : natural := 0; -- address offset for layer 0 in 2k steps for 16bpp and 1k steps for 8bpp C_LAYER_1_OFFSET : natural := 2048; -- address offset for layer 1 in 2k steps for 16bpp and 1k steps for 8bpp C_LAYER_2_OFFSET : natural := 4096; -- address offset for layer 2 in 2k steps for 16bpp and 1k steps for 8bpp C_LAYER_3_OFFSET : natural := 6144; -- address offset for layer 3 in 2k steps for 16bpp and 1k steps for 8bpp C_LAYER_4_OFFSET : natural := 8192; -- address offset for layer 4 in 2k steps for 16bpp and 1k steps for 8bpp C_BUFFER_0_OFFSET : natural := 1024; -- address offset for layer 0 double buffer relative to LAYER_0_OFFSET C_BUFFER_1_OFFSET : natural := 1024; -- address offset for layer 1 double buffer relative to LAYER_1_OFFSET C_BUFFER_2_OFFSET : natural := 1024; -- address offset for layer 2 double buffer relative to LAYER_2_OFFSET C_BUFFER_3_OFFSET : natural := 1024; -- address offset for layer 3 double buffer relative to LAYER_3_OFFSET C_BUFFER_4_OFFSET : natural := 1024; -- address offset for layer 4 double buffer relative to LAYER_4_OFFSET -- Extern parallel input generics C_USE_E_PARALLEL_INPUT : integer := 0; -- Syncronize logiCVC to external parallel input and use data as one layer: 0 - no, 1 - yes C_USE_E_VCLK_BUFGMUX : integer := 1; -- Use BUFGMUX for switching video clock to e_vclk, else use vclk C_E_LAYER : integer := 0; -- External parallel input layer: 0, 1, 2, 3, 4 C_E_DATA_WIDTH : integer := 24 -- External parallel input data width: 8, 16, 24 bit ); port( rst : in std_logic; -- Global reset mclk : in std_logic; -- Memory clock vclk : in std_logic; -- Video clock vclk2 : in std_logic; -- Video clock x2 itu_clk_in : in std_logic; -- It has to be 27 MHz and synchronous to vclk lvds_clk : in std_logic; -- lvds clock is 3.5x video clock lvds_clkn : in std_logic; -- Inverted lvds_clk -- Xylon Memory Bus (XMB) mem_req : out std_logic; mem_wr : out std_logic; mem_ack : in std_logic := '0'; mem_addr : out std_logic_vector(31 downto 0); mem_data : out std_logic_vector(C_XMB_DATA_BUS_WIDTH - 1 downto 0); mem_data_be : out std_logic_vector(C_XMB_DATA_BUS_WIDTH / 8 - 1 downto 0); mem_wrack : in std_logic := '0'; mem_burst : out std_logic_vector(C_MEM_BURST - 1 downto 0); mem_data_valid : in std_logic := '0'; mem_data_in : in std_logic_vector(C_XMB_DATA_BUS_WIDTH - 1 downto 0) := (others => '0'); -- PLB -------------- -- Master mplb_rst : in std_logic; plb_maddrack : in std_logic; plb_mrearbitrate : in std_logic; plb_mssize : in std_logic_vector(0 to 1); plb_mbusy : in std_logic; plb_mrderr : in std_logic; plb_mwrerr : in std_logic; plb_mtimeout : in std_logic; plb_mirq : in std_logic; m_request : out std_logic; m_priority : out std_logic_vector(0 to 1); m_buslock : out std_logic; m_rnw : out std_logic; m_be : out std_logic_vector(0 to (C_MPLB_DWIDTH / 8) - 1); m_size : out std_logic_vector(0 to 3); m_type : out std_logic_vector(0 to 2); m_msize : out std_logic_vector(0 to 1); m_tattribute : out std_logic_vector(0 to 15); m_lockerr : out std_logic; m_abort : out std_logic; m_abus : out std_logic_vector(0 to (C_MPLB_AWIDTH - 1)); m_uabus : out std_logic_vector(0 to (C_MPLB_AWIDTH - 1)); plb_mwrdack : in std_logic; plb_mwrbterm : in std_logic; m_wrburst : out std_logic; m_wrdbus : out std_logic_vector(0 to (C_MPLB_DWIDTH - 1)); plb_mrddack : in std_logic; plb_mrdbterm : in std_logic; plb_mrdwdaddr : in std_logic_vector(0 to 3); plb_mrddbus : in std_logic_vector(0 to (C_MPLB_DWIDTH - 1)); m_rdburst : out std_logic; -- AXI -------------- -- Master M_AXI_ARESETN : in std_logic; M_AXI_AWID : out std_logic_vector(C_M_AXI_THREAD_ID_WIDTH - 1 downto 0); M_AXI_AWADDR : out std_logic_vector(C_M_AXI_ADDR_WIDTH - 1 downto 0); M_AXI_AWLEN : out std_logic_vector(7 downto 0); M_AXI_AWSIZE : out std_logic_vector(2 downto 0); M_AXI_AWBURST : out std_logic_vector(1 downto 0); M_AXI_AWLOCK : out std_logic_vector(1 downto 0); M_AXI_AWCACHE : out std_logic_vector(3 downto 0); M_AXI_AWPROT : out std_logic_vector(2 downto 0); M_AXI_AWQOS : out std_logic_vector(3 downto 0); M_AXI_AWVALID : out std_logic; M_AXI_AWREADY : in std_logic; M_AXI_WDATA : out std_logic_vector(C_M_AXI_DATA_WIDTH - 1 downto 0); M_AXI_WSTRB : out std_logic_vector(C_M_AXI_DATA_WIDTH / 8 - 1 downto 0); M_AXI_WLAST : out std_logic; M_AXI_WVALID : out std_logic; M_AXI_WREADY : in std_logic; M_AXI_BID : in std_logic_vector(C_M_AXI_THREAD_ID_WIDTH - 1 downto 0); M_AXI_BRESP : in std_logic_vector(1 downto 0); M_AXI_BVALID : in std_logic; M_AXI_BREADY : out std_logic; M_AXI_ARID : out std_logic_vector(C_M_AXI_THREAD_ID_WIDTH - 1 downto 0); M_AXI_ARADDR : out std_logic_vector(C_M_AXI_ADDR_WIDTH - 1 downto 0); M_AXI_ARLEN : out std_logic_vector(7 downto 0); M_AXI_ARSIZE : out std_logic_vector(2 downto 0); M_AXI_ARBURST : out std_logic_vector(1 downto 0); M_AXI_ARLOCK : out std_logic_vector(1 downto 0); M_AXI_ARCACHE : out std_logic_vector(3 downto 0); M_AXI_ARPROT : out std_logic_vector(2 downto 0); M_AXI_ARQOS : out std_logic_vector(3 downto 0); M_AXI_ARVALID : out std_logic; M_AXI_ARREADY : in std_logic; M_AXI_RID : in std_logic_vector(C_M_AXI_THREAD_ID_WIDTH - 1 downto 0); M_AXI_RDATA : in std_logic_vector(C_M_AXI_DATA_WIDTH - 1 downto 0); M_AXI_RRESP : in std_logic_vector(1 downto 0); M_AXI_RLAST : in std_logic; M_AXI_RVALID : in std_logic; M_AXI_RREADY : out std_logic; ---------------------- -- OPB -------------- -- Slave OPB_Clk : in std_logic; OPB_Rst : in std_logic; OPB_ABus : in std_logic_vector(0 to C_OPB_AWIDTH - 1); OPB_BE : in std_logic_vector(0 to C_OPB_DWIDTH / 8 - 1); OPB_RNW : in std_logic; OPB_select : in std_logic; OPB_seqAddr : in std_logic; OPB_DBus : in std_logic_vector(0 to C_OPB_DWIDTH - 1); Sl_DBus : out std_logic_vector(0 to C_OPB_DWIDTH - 1); Sl_errAck : out std_logic; Sl_retry : out std_logic; Sl_toutSup : out std_logic; Sl_xferAck : out std_logic; ---------------------- -- PLB -------------- -- Slave SPLB_Clk : in std_logic; SPLB_Rst : in std_logic; PLB_ABus : in std_logic_vector(0 to C_SPLB_AWIDTH - 1); PLB_UABus : in std_logic_vector(0 to C_SPLB_AWIDTH - 1); PLB_PAValid : in std_logic; PLB_SAValid : in std_logic; PLB_rdPrim : in std_logic; PLB_wrPrim : in std_logic; PLB_masterID : in std_logic_vector(0 to C_SPLB_MID_WIDTH - 1); PLB_abort : in std_logic; PLB_busLock : in std_logic; PLB_RNW : in std_logic; PLB_BE : in std_logic_vector(0 to C_SPLB_DWIDTH / 8 - 1); PLB_MSize : in std_logic_vector(0 to 1); PLB_size : in std_logic_vector(0 to 3); PLB_type : in std_logic_vector(0 to 2); PLB_tattribute : in std_logic_vector(0 to 15); PLB_lockErr : in std_logic; PLB_wrDBus : in std_logic_vector(0 to C_SPLB_DWIDTH - 1); PLB_wrBurst : in std_logic; PLB_rdBurst : in std_logic; PLB_rdPendReq : in std_logic; PLB_wrPendReq : in std_logic; PLB_rdPendPri : in std_logic_vector(0 to 1); PLB_wrPendPri : in std_logic_vector(0 to 1); PLB_reqPri : in std_logic_vector(0 to 1); Sl_addrAck : out std_logic; Sl_SSize : out std_logic_vector(0 to 1); Sl_wait : out std_logic; Sl_rearbitrate : out std_logic; Sl_wrDAck : out std_logic; Sl_wrComp : out std_logic; Sl_wrBTerm : out std_logic; Sl_rdDBus : out std_logic_vector(0 to C_SPLB_DWIDTH - 1); Sl_rdWdAddr : out std_logic_vector(0 to 3); Sl_rdDAck : out std_logic; Sl_rdComp : out std_logic; Sl_rdBTerm : out std_logic; Sl_MBusy : out std_logic_vector(0 to C_SPLB_NUM_MASTERS - 1); Sl_MRdErr : out std_logic_vector(0 to C_SPLB_NUM_MASTERS - 1); Sl_MWrErr : out std_logic_vector(0 to C_SPLB_NUM_MASTERS - 1); Sl_MIRQ : out std_logic_vector(0 to C_SPLB_NUM_MASTERS - 1); ---------------------- -- AXI4-Lite -------- -- Slave S_AXI_ACLK : in std_logic; S_AXI_ARESETN : in std_logic; S_AXI_AWADDR : in std_logic_vector(C_S_AXI_ADDR_WIDTH - 1 downto 0); S_AXI_AWVALID : in std_logic; S_AXI_AWREADY : out std_logic; S_AXI_WDATA : in std_logic_vector(C_S_AXI_DATA_WIDTH - 1 downto 0); S_AXI_WSTRB : in std_logic_vector((C_S_AXI_DATA_WIDTH / 8) - 1 downto 0); S_AXI_WVALID : in std_logic; S_AXI_WREADY : out std_logic; S_AXI_BRESP : out std_logic_vector(1 downto 0); S_AXI_BVALID : out std_logic; S_AXI_BREADY : in std_logic; S_AXI_ARADDR : in std_logic_vector(C_S_AXI_ADDR_WIDTH - 1 downto 0); S_AXI_ARVALID : in std_logic; S_AXI_ARREADY : out std_logic; S_AXI_RDATA : out std_logic_vector(C_S_AXI_DATA_WIDTH - 1 downto 0); S_AXI_RRESP : out std_logic_vector(1 downto 0); S_AXI_RVALID : out std_logic; S_AXI_RREADY : in std_logic; ---------------------- -- Video Outputs -------------- pix_clk_i : in std_logic; -- Pixel clock pix_clk_o : out std_logic; -- Pixel clock pix_clk_t : out std_logic; -- Pixel clock pix_clk_n_i : in std_logic; -- Pixel clock inverted pix_clk_n_o : out std_logic; -- Pixel clock inverted pix_clk_n_t : out std_logic; -- Pixel clock inverted d_pix_i : in std_logic_vector(C_PIXEL_DATA_WIDTH - 1 downto 0); -- Pixel data bus d_pix_o : out std_logic_vector(C_PIXEL_DATA_WIDTH - 1 downto 0); -- Pixel data bus d_pix_t : out std_logic; -- Pixel data bus hsync_i : in std_logic; -- Hsync hsync_o : out std_logic; -- Hsync hsync_t : out std_logic; -- Hsync vsync_i : in std_logic; -- Vsync vsync_o : out std_logic; -- Vsync vsync_t : out std_logic; -- Vsync blank_i : in std_logic; -- Blank blank_o : out std_logic; -- Blank blank_t : out std_logic; -- Blank itu656_clk_o : out std_logic; -- ITU656 clock output itu656_data_o : out std_logic_vector(7 downto 0); -- ITU656 data output lvds_data_out_p : out std_logic_vector(C_LVDS_DATA_WIDTH - 1 downto 0); -- lvds data, positive lvds_data_out_n : out std_logic_vector(C_LVDS_DATA_WIDTH - 1 downto 0); -- lvds data, negative lvds_clk_out_p : out std_logic; -- lvds clk, positive lvds_clk_out_n : out std_logic; -- lvds clk, negative pllvclk_locked : in std_logic; -- PLL_BASE LOCKED (spartan6, LVDS clk gen) dvi_clk_p : out std_logic; -- DVI clock, positive dvi_clk_n : out std_logic; -- DVI clock, negative dvi_data_p : out std_logic_vector(2 downto 0); -- DVI data, positive dvi_data_n : out std_logic_vector(2 downto 0); -- DVI data, negative ---------------------- -- External parallel input -------------- e_vclk : in std_logic; -- External video clock e_vsync : in std_logic; -- External vsync e_hsync : in std_logic; -- External hsync e_blank : in std_logic; -- External blank e_data : in std_logic_vector(C_E_DATA_WIDTH - 1 downto 0); -- External data e_video_present : in std_logic; -- External video present flag ---------------------- -- Other -------------- e_curr_vbuff : in std_logic_vector(C_NUM_OF_LAYERS * 2 - 1 downto 0); -- Current external stream vbuffer e_next_vbuff : out std_logic_vector(C_NUM_OF_LAYERS * 2 - 1 downto 0); -- Next external stream vbuffer to write to e_sw_vbuff : in std_logic_vector(C_NUM_OF_LAYERS - 1 downto 0); -- Switch video buffers from external source e_sw_grant : out std_logic_vector(C_NUM_OF_LAYERS - 1 downto 0); -- Video buffers switch req granted vcdivsel : out std_logic_vector(1 downto 0); -- vclk div select bits vclksel : out std_logic_vector(2 downto 0); -- vclk select bits en_vdd : out std_logic; -- vdd enable en_blight : out std_logic; -- backlight enable v_en : out std_logic; -- Enable display control/data signals en_vee : out std_logic; -- vee enable interrupt : out std_logic -- logiCVC interrupt signal, level sensitive, high active ); end component; end logicbricks;

gpl-3.0

8401381d27bcbb1e092e55e94ffd8307

0.477191

3.73879

false

Fairyland0902/BlockyRoads

src/BlockyRoads/ipcore_dir/game_over/simulation/game_over_tb.vhd

1

4,361

-------------------------------------------------------------------------------- -- -- BLK MEM GEN v7_3 Core - Top File for the Example Testbench -- -------------------------------------------------------------------------------- -- -- (c) Copyright 2006_3010 Xilinx, Inc. All rights reserved. -- -- This file contains confidential and proprietary information -- of Xilinx, Inc. and is protected under U.S. and -- international copyright and other intellectual property -- laws. -- -- DISCLAIMER -- This disclaimer is not a license and does not grant any -- rights to the materials distributed herewith. Except as -- otherwise provided in a valid license issued to you by -- Xilinx, and to the maximum extent permitted by applicable -- law: (1) THESE MATERIALS ARE MADE AVAILABLE "AS IS" AND -- WITH ALL FAULTS, AND XILINX HEREBY DISCLAIMS ALL WARRANTIES -- AND CONDITIONS, EXPRESS, IMPLIED, OR STATUTORY, INCLUDING -- BUT NOT LIMITED TO WARRANTIES OF MERCHANTABILITY, NON- -- INFRINGEMENT, OR FITNESS FOR ANY PARTICULAR PURPOSE; and -- (2) Xilinx shall not be liable (whether in contract or tort, -- including negligence, or under any other theory of -- liability) for any loss or damage of any kind or nature -- related to, arising under or in connection with these -- materials, including for any direct, or any indirect, -- special, incidental, or consequential loss or damage -- (including loss of data, profits, goodwill, or any type of -- loss or damage suffered as a result of any action brought -- by a third party) even if such damage or loss was -- reasonably foreseeable or Xilinx had been advised of the -- possibility of the same. -- -- CRITICAL APPLICATIONS -- Xilinx products are not designed or intended to be fail- -- safe, or for use in any application requiring fail-safe -- performance, such as life-support or safety devices or -- systems, Class III medical devices, nuclear facilities, -- applications related to the deployment of airbags, or any -- other applications that could lead to death, personal -- injury, or severe property or environmental damage -- (individually and collectively, "Critical -- Applications"). Customer assumes the sole risk and -- liability of any use of Xilinx products in Critical -- Applications, subject only to applicable laws and -- regulations governing limitations on product liability. -- -- THIS COPYRIGHT NOTICE AND DISCLAIMER MUST BE RETAINED AS -- PART OF THIS FILE AT ALL TIMES. -------------------------------------------------------------------------------- -- Filename: game_over_tb.vhd -- Description: -- Testbench Top -------------------------------------------------------------------------------- -- Author: IP Solutions Division -- -- History: Sep 12, 2011 - First Release -------------------------------------------------------------------------------- -- -------------------------------------------------------------------------------- -- Library Declarations -------------------------------------------------------------------------------- LIBRARY IEEE; USE IEEE.STD_LOGIC_1164.ALL; USE IEEE.STD_LOGIC_ARITH.ALL; USE IEEE.STD_LOGIC_UNSIGNED.ALL; LIBRARY work; USE work.ALL; ENTITY game_over_tb IS END ENTITY; ARCHITECTURE game_over_tb_ARCH OF game_over_tb IS SIGNAL STATUS : STD_LOGIC_VECTOR(8 DOWNTO 0); SIGNAL CLK : STD_LOGIC := '1'; SIGNAL RESET : STD_LOGIC; BEGIN CLK_GEN: PROCESS BEGIN CLK <= NOT CLK; WAIT FOR 100 NS; CLK <= NOT CLK; WAIT FOR 100 NS; END PROCESS; RST_GEN: PROCESS BEGIN RESET <= '1'; WAIT FOR 1000 NS; RESET <= '0'; WAIT; END PROCESS; --STOP_SIM: PROCESS BEGIN -- WAIT FOR 200 US; -- STOP SIMULATION AFTER 1 MS -- ASSERT FALSE -- REPORT "END SIMULATION TIME REACHED" -- SEVERITY FAILURE; --END PROCESS; -- PROCESS BEGIN WAIT UNTIL STATUS(8)='1'; IF( STATUS(7 downto 0)/="0") THEN ASSERT false REPORT "Test Completed Successfully" SEVERITY NOTE; REPORT "Simulation Failed" SEVERITY FAILURE; ELSE ASSERT false REPORT "TEST PASS" SEVERITY NOTE; REPORT "Test Completed Successfully" SEVERITY FAILURE; END IF; END PROCESS; game_over_synth_inst:ENTITY work.game_over_synth GENERIC MAP (C_ROM_SYNTH => 0) PORT MAP( CLK_IN => CLK, RESET_IN => RESET, STATUS => STATUS ); END ARCHITECTURE;

mit

cbf1c1d0d8b8a830a73ec550143d30f2

0.619583

4.629512

false

marco-c/leon-nexys2

grlib-gpl-1.3.4-b4140/designs/leon3-gr-cpci-xc2v6000/testbench.vhd

1

19,150

------------------------------------------------------------------------------ -- LEON3 Demonstration design test bench -- Copyright (C) 2004 Jiri Gaisler, Gaisler Research ------------------------------------------------------------------------------ -- This file is a part of the GRLIB VHDL IP LIBRARY -- Copyright (C) 2003 - 2008, Gaisler Research -- Copyright (C) 2008 - 2013, Aeroflex Gaisler -- -- This program is free software; you can redistribute it and/or modify -- it under the terms of the GNU General Public License as published by -- the Free Software Foundation; either version 2 of the License, or -- (at your option) any later version. -- -- This program is distributed in the hope that it will be useful, -- but WITHOUT ANY WARRANTY; without even the implied warranty of -- MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the -- GNU General Public License for more details. -- -- You should have received a copy of the GNU General Public License -- along with this program; if not, write to the Free Software -- Foundation, Inc., 59 Temple Place, Suite 330, Boston, MA 02111-1307 USA ------------------------------------------------------------------------------ library ieee; use ieee.std_logic_1164.all; library gaisler; use gaisler.libdcom.all; use gaisler.sim.all; use work.debug.all; library techmap; use techmap.gencomp.all; library micron; use micron.components.all; use work.config.all; -- configuration entity testbench is generic ( fabtech : integer := CFG_FABTECH; memtech : integer := CFG_MEMTECH; padtech : integer := CFG_PADTECH; clktech : integer := CFG_CLKTECH; disas : integer := CFG_DISAS; -- Enable disassembly to console dbguart : integer := CFG_DUART; -- Print UART on console pclow : integer := CFG_PCLOW; clkperiod : integer := 20; -- system clock period romwidth : integer := 32; -- rom data width (8/32) romdepth : integer := 16; -- rom address depth sramwidth : integer := 32; -- ram data width (8/16/32) sramdepth : integer := 20; -- ram address depth srambanks : integer := 2 -- number of ram banks ); port ( pci_rst : inout std_logic; -- PCI bus pci_clk : in std_logic; pci_gnt : in std_logic; pci_idsel : in std_logic; pci_lock : inout std_logic; pci_ad : inout std_logic_vector(31 downto 0); pci_cbe : inout std_logic_vector(3 downto 0); pci_frame : inout std_logic; pci_irdy : inout std_logic; pci_trdy : inout std_logic; pci_devsel : inout std_logic; pci_stop : inout std_logic; pci_perr : inout std_logic; pci_par : inout std_logic; pci_req : inout std_logic; pci_serr : inout std_logic; pci_host : in std_logic := 'L'; pci_66 : in std_logic ); end; architecture behav of testbench is constant promfile : string := "prom.srec"; -- rom contents constant sramfile : string := "ram.srec"; -- ram contents constant sdramfile : string := "ram.srec"; -- sdram contents component leon3mp generic ( fabtech : integer := CFG_FABTECH; memtech : integer := CFG_MEMTECH; padtech : integer := CFG_PADTECH; clktech : integer := CFG_CLKTECH; disas : integer := CFG_DISAS; -- Enable disassembly to console dbguart : integer := CFG_DUART; -- Print UART on console pclow : integer := CFG_PCLOW ); port ( resetn : in std_logic; clk : in std_logic; pllref : in std_logic; errorn : out std_logic; address : out std_logic_vector(27 downto 0); data : inout std_logic_vector(31 downto 0); sa : out std_logic_vector(14 downto 0); sd : inout std_logic_vector(63 downto 0); sdclk : out std_logic; sdcke : out std_logic_vector (1 downto 0); -- sdram clock enable sdcsn : out std_logic_vector (1 downto 0); -- sdram chip select sdwen : out std_logic; -- sdram write enable sdrasn : out std_logic; -- sdram ras sdcasn : out std_logic; -- sdram cas sddqm : out std_logic_vector (7 downto 0); -- sdram dqm dsutx : out std_logic; -- DSU tx data dsurx : in std_logic; -- DSU rx data dsuen : in std_logic; dsubre : in std_logic; dsuact : out std_logic; txd1 : out std_logic; -- UART1 tx data rxd1 : in std_logic; -- UART1 rx data txd2 : out std_logic; -- UART1 tx data rxd2 : in std_logic; -- UART1 rx data ramsn : out std_logic_vector (4 downto 0); ramoen : out std_logic_vector (4 downto 0); rwen : out std_logic_vector (3 downto 0); oen : out std_logic; writen : out std_logic; read : out std_logic; iosn : out std_logic; romsn : out std_logic_vector (1 downto 0); gpio : inout std_logic_vector(7 downto 0); -- I/O port emdio : inout std_logic; -- ethernet PHY interface etx_clk : in std_logic; erx_clk : in std_logic; erxd : in std_logic_vector(3 downto 0); erx_dv : in std_logic; erx_er : in std_logic; erx_col : in std_logic; erx_crs : in std_logic; etxd : out std_logic_vector(3 downto 0); etx_en : out std_logic; etx_er : out std_logic; emdc : out std_logic; pci_rst : inout std_logic; -- PCI bus pci_clk : in std_logic; pci_gnt : in std_logic; pci_idsel : in std_logic; pci_lock : inout std_logic; pci_ad : inout std_logic_vector(31 downto 0); pci_cbe : inout std_logic_vector(3 downto 0); pci_frame : inout std_logic; pci_irdy : inout std_logic; pci_trdy : inout std_logic; pci_devsel : inout std_logic; pci_stop : inout std_logic; pci_perr : inout std_logic; pci_par : inout std_logic; pci_req : inout std_logic; pci_serr : inout std_logic; pci_host : in std_logic; pci_66 : in std_logic; pci_arb_req : in std_logic_vector(0 to 3); pci_arb_gnt : out std_logic_vector(0 to 3); can_txd : out std_logic_vector(0 to 1); can_rxd : in std_logic_vector(0 to 1); can_stb : out std_logic_vector(0 to 1); spw_rxd : in std_logic_vector(0 to 2); spw_rxdn : in std_logic_vector(0 to 2); spw_rxs : in std_logic_vector(0 to 2); spw_rxsn : in std_logic_vector(0 to 2); spw_txd : out std_logic_vector(0 to 2); spw_txdn : out std_logic_vector(0 to 2); spw_txs : out std_logic_vector(0 to 2); spw_txsn : out std_logic_vector(0 to 2) ); end component; signal clk : std_logic := '0'; signal Rst : std_logic := '0'; -- Reset constant ct : integer := clkperiod/2; signal address : std_logic_vector(27 downto 0); signal data : std_logic_vector(31 downto 0); signal ramsn : std_logic_vector(4 downto 0); signal ramoen : std_logic_vector(4 downto 0); signal rwen : std_logic_vector(3 downto 0); signal rwenx : std_logic_vector(3 downto 0); signal romsn : std_logic_vector(1 downto 0); signal iosn : std_logic; signal oen : std_logic; signal read : std_logic; signal writen : std_logic; signal brdyn : std_logic; signal bexcn : std_logic; signal wdog : std_logic; signal dsuen, dsutx, dsurx, dsubre, dsuact : std_logic; signal dsurst : std_logic; signal test : std_logic; signal error : std_logic; signal gpio : std_logic_vector(7 downto 0); signal GND : std_logic := '0'; signal VCC : std_logic := '1'; signal NC : std_logic := 'Z'; signal clk2 : std_logic := '1'; signal sdcke : std_logic_vector ( 1 downto 0); -- clk en signal sdcsn : std_logic_vector ( 1 downto 0); -- chip sel signal sdwen : std_logic; -- write en signal sdrasn : std_logic; -- row addr stb signal sdcasn : std_logic; -- col addr stb signal sddqm : std_logic_vector ( 7 downto 0); -- data i/o mask signal sdclk : std_logic; signal plllock : std_logic; signal txd1, rxd1 : std_logic; signal txd2, rxd2 : std_logic; signal etx_clk, erx_clk, erx_dv, erx_er, erx_col, erx_crs, etx_en, etx_er : std_logic:='0'; signal erxd, etxd: std_logic_vector(3 downto 0):=(others=>'0'); signal erxdt, etxdt: std_logic_vector(7 downto 0):=(others=>'0'); signal emdc, emdio: std_logic; --dummy signal for the mdc,mdio in the phy which is not used signal gtx_clk : std_logic; signal emddis : std_logic; signal epwrdwn : std_logic; signal ereset : std_logic; signal esleep : std_logic; signal epause : std_logic; signal led_cfg: std_logic_vector(2 downto 0); constant lresp : boolean := false; signal sa : std_logic_vector(14 downto 0); signal sd : std_logic_vector(63 downto 0); signal pci_arb_req, pci_arb_gnt : std_logic_vector(0 to 3); signal can_txd : std_logic_vector(0 to 1); signal can_rxd : std_logic_vector(0 to 1); signal can_stb : std_logic_vector(0 to 1); signal spw_rxd : std_logic_vector(0 to 2) := "000"; signal spw_rxdn : std_logic_vector(0 to 2) := "000"; signal spw_rxs : std_logic_vector(0 to 2) := "000"; signal spw_rxsn : std_logic_vector(0 to 2) := "000"; signal spw_txd : std_logic_vector(0 to 2); signal spw_txdn : std_logic_vector(0 to 2); signal spw_txs : std_logic_vector(0 to 2); signal spw_txsn : std_logic_vector(0 to 2); begin -- clock and reset clk <= not clk after ct * 1 ns; rst <= dsurst; dsuen <= '1'; dsubre <= '0'; rxd1 <= '1'; can_rxd <= (others => '1'); spw_rxd(0) <= spw_txd(0); spw_rxdn(0) <= spw_txdn(0); spw_rxs(0) <= spw_txs(0); spw_rxsn(0) <= spw_txsn(0); spw_rxd(1) <= spw_txd(1); spw_rxdn(1) <= spw_txdn(1); spw_rxs(1) <= spw_txs(1); spw_rxsn(1) <= spw_txsn(1); spw_rxd(2) <= spw_txd(0); spw_rxdn(2) <= spw_txdn(2); spw_rxs(2) <= spw_txs(0); spw_rxsn(2) <= spw_txsn(2); d3 : leon3mp generic map ( fabtech, memtech, padtech, clktech, disas, dbguart, pclow ) port map (rst, clk, sdclk, error, address(27 downto 0), data, sa, sd, sdclk, sdcke, sdcsn, sdwen, sdrasn, sdcasn, sddqm, dsutx, dsurx, dsuen, dsubre, dsuact, txd1, rxd1, txd2, rxd2, ramsn, ramoen, rwen, oen, writen, read, iosn, romsn, gpio, emdio, etx_clk, erx_clk, erxd, erx_dv, erx_er, erx_col, erx_crs, etxd, etx_en, etx_er, emdc, pci_rst, pci_clk, pci_gnt, pci_idsel, pci_lock, pci_ad, pci_cbe, pci_frame, pci_irdy, pci_trdy, pci_devsel, pci_stop, pci_perr, pci_par, pci_req, pci_serr, pci_host, pci_66, pci_arb_req, pci_arb_gnt, can_txd, can_rxd, can_stb, spw_rxd, spw_rxdn, spw_rxs, spw_rxsn, spw_txd, spw_txdn, spw_txs, spw_txsn); -- optional sdram sd0 : if (CFG_SDEN = 1) and (CFG_SEPBUS = 0) generate u0: mt48lc16m16a2 generic map (index => 0, fname => sdramfile) PORT MAP( Dq => data(31 downto 16), Addr => address(14 downto 2), Ba => address(16 downto 15), Clk => sdclk, Cke => sdcke(0), Cs_n => sdcsn(0), Ras_n => sdrasn, Cas_n => sdcasn, We_n => sdwen, Dqm => sddqm(3 downto 2)); u1: mt48lc16m16a2 generic map (index => 16, fname => sdramfile) PORT MAP( Dq => data(15 downto 0), Addr => address(14 downto 2), Ba => address(16 downto 15), Clk => sdclk, Cke => sdcke(0), Cs_n => sdcsn(0), Ras_n => sdrasn, Cas_n => sdcasn, We_n => sdwen, Dqm => sddqm(1 downto 0)); u2: mt48lc16m16a2 generic map (index => 0, fname => sdramfile) PORT MAP( Dq => data(31 downto 16), Addr => address(14 downto 2), Ba => address(16 downto 15), Clk => sdclk, Cke => sdcke(0), Cs_n => sdcsn(1), Ras_n => sdrasn, Cas_n => sdcasn, We_n => sdwen, Dqm => sddqm(3 downto 2)); u3: mt48lc16m16a2 generic map (index => 16, fname => sdramfile) PORT MAP( Dq => data(15 downto 0), Addr => address(14 downto 2), Ba => address(16 downto 15), Clk => sdclk, Cke => sdcke(0), Cs_n => sdcsn(1), Ras_n => sdrasn, Cas_n => sdcasn, We_n => sdwen, Dqm => sddqm(1 downto 0)); end generate; sd1 : if (CFG_SDEN = 1) and (CFG_SEPBUS = 1) generate u0: mt48lc16m16a2 generic map (index => 0, fname => sdramfile) PORT MAP( Dq => sd(31 downto 16), Addr => sa(12 downto 0), Ba => sa(14 downto 13), Clk => sdclk, Cke => sdcke(0), Cs_n => sdcsn(0), Ras_n => sdrasn, Cas_n => sdcasn, We_n => sdwen, Dqm => sddqm(3 downto 2)); u1: mt48lc16m16a2 generic map (index => 16, fname => sdramfile) PORT MAP( Dq => sd(15 downto 0), Addr => sa(12 downto 0), Ba => sa(14 downto 13), Clk => sdclk, Cke => sdcke(0), Cs_n => sdcsn(0), Ras_n => sdrasn, Cas_n => sdcasn, We_n => sdwen, Dqm => sddqm(1 downto 0)); u2: mt48lc16m16a2 generic map (index => 0, fname => sdramfile) PORT MAP( Dq => sd(31 downto 16), Addr => sa(12 downto 0), Ba => sa(14 downto 13), Clk => sdclk, Cke => sdcke(0), Cs_n => sdcsn(1), Ras_n => sdrasn, Cas_n => sdcasn, We_n => sdwen, Dqm => sddqm(3 downto 2)); u3: mt48lc16m16a2 generic map (index => 16, fname => sdramfile) PORT MAP( Dq => sd(15 downto 0), Addr => sa(12 downto 0), Ba => sa(14 downto 13), Clk => sdclk, Cke => sdcke(0), Cs_n => sdcsn(1), Ras_n => sdrasn, Cas_n => sdcasn, We_n => sdwen, Dqm => sddqm(1 downto 0)); sd64 : if (CFG_SD64 = 1) generate u4: mt48lc16m16a2 generic map (index => 0, fname => sdramfile) PORT MAP( Dq => sd(63 downto 48), Addr => sa(12 downto 0), Ba => sa(14 downto 13), Clk => sdclk, Cke => sdcke(0), Cs_n => sdcsn(0), Ras_n => sdrasn, Cas_n => sdcasn, We_n => sdwen, Dqm => sddqm(7 downto 6)); u5: mt48lc16m16a2 generic map (index => 16, fname => sdramfile) PORT MAP( Dq => sd(47 downto 32), Addr => sa(12 downto 0), Ba => sa(14 downto 13), Clk => sdclk, Cke => sdcke(0), Cs_n => sdcsn(0), Ras_n => sdrasn, Cas_n => sdcasn, We_n => sdwen, Dqm => sddqm(5 downto 4)); u6: mt48lc16m16a2 generic map (index => 0, fname => sdramfile) PORT MAP( Dq => sd(63 downto 48), Addr => sa(12 downto 0), Ba => sa(14 downto 13), Clk => sdclk, Cke => sdcke(0), Cs_n => sdcsn(1), Ras_n => sdrasn, Cas_n => sdcasn, We_n => sdwen, Dqm => sddqm(7 downto 6)); u7: mt48lc16m16a2 generic map (index => 16, fname => sdramfile) PORT MAP( Dq => sd(47 downto 32), Addr => sa(12 downto 0), Ba => sa(14 downto 13), Clk => sdclk, Cke => sdcke(0), Cs_n => sdcsn(1), Ras_n => sdrasn, Cas_n => sdcasn, We_n => sdwen, Dqm => sddqm(5 downto 4)); end generate; end generate; prom0 : for i in 0 to (romwidth/8)-1 generate sr0 : sram generic map (index => i, abits => romdepth, fname => promfile) port map (address(romdepth+1 downto 2), data(31-i*8 downto 24-i*8), romsn(0), rwen(i), oen); end generate; sram0 : for i in 0 to (sramwidth/8)-1 generate sr0 : sram generic map (index => i, abits => sramdepth, fname => sramfile) port map (address(sramdepth+1 downto 2), data(31-i*8 downto 24-i*8), ramsn(0), rwen(0), ramoen(0)); end generate; phy0 : if (CFG_GRETH = 1) generate emdio <= 'H'; erxd <= erxdt(3 downto 0); etxdt <= "0000" & etxd; p0: phy generic map(base1000_t_fd => 0, base1000_t_hd => 0) port map(rst, emdio, etx_clk, erx_clk, erxdt, erx_dv, erx_er, erx_col, erx_crs, etxdt, etx_en, etx_er, emdc, gtx_clk); end generate; error <= 'H'; -- ERROR pull-up iuerr : process begin wait for 2500 ns; if to_x01(error) = '1' then wait on error; end if; assert (to_x01(error) = '1') report "*** IU in error mode, simulation halted ***" severity failure ; end process; test0 : grtestmod port map ( rst, clk, error, address(21 downto 2), data, iosn, oen, writen, brdyn); data <= buskeep(data), (others => 'H') after 250 ns; sd <= buskeep(sd), (others => 'H') after 250 ns; dsucom : process procedure dsucfg(signal dsurx : in std_logic; signal dsutx : out std_logic) is variable w32 : std_logic_vector(31 downto 0); variable c8 : std_logic_vector(7 downto 0); constant txp : time := 160 * 1 ns; begin dsutx <= '1'; dsurst <= '0'; wait for 500 ns; dsurst <= '1'; wait; wait for 5000 ns; txc(dsutx, 16#55#, txp); -- sync uart -- txc(dsutx, 16#c0#, txp); -- txa(dsutx, 16#90#, 16#00#, 16#00#, 16#00#, txp); -- txa(dsutx, 16#00#, 16#00#, 16#02#, 16#ae#, txp); -- txc(dsutx, 16#c0#, txp); -- txa(dsutx, 16#91#, 16#00#, 16#00#, 16#00#, txp); -- txa(dsutx, 16#00#, 16#00#, 16#06#, 16#ae#, txp); -- txc(dsutx, 16#c0#, txp); -- txa(dsutx, 16#90#, 16#00#, 16#00#, 16#24#, txp); -- txa(dsutx, 16#00#, 16#00#, 16#06#, 16#03#, txp); -- txc(dsutx, 16#c0#, txp); -- txa(dsutx, 16#90#, 16#00#, 16#00#, 16#20#, txp); -- txa(dsutx, 16#00#, 16#00#, 16#06#, 16#fc#, txp); txc(dsutx, 16#c0#, txp); txa(dsutx, 16#90#, 16#00#, 16#00#, 16#00#, txp); txa(dsutx, 16#00#, 16#00#, 16#00#, 16#2f#, txp); txc(dsutx, 16#c0#, txp); txa(dsutx, 16#91#, 16#00#, 16#00#, 16#00#, txp); txa(dsutx, 16#00#, 16#00#, 16#00#, 16#6f#, txp); txc(dsutx, 16#c0#, txp); txa(dsutx, 16#90#, 16#11#, 16#00#, 16#00#, txp); txa(dsutx, 16#00#, 16#00#, 16#00#, 16#00#, txp); txc(dsutx, 16#c0#, txp); txa(dsutx, 16#90#, 16#40#, 16#00#, 16#04#, txp); txa(dsutx, 16#00#, 16#02#, 16#20#, 16#01#, txp); txc(dsutx, 16#c0#, txp); txa(dsutx, 16#90#, 16#00#, 16#00#, 16#20#, txp); txa(dsutx, 16#00#, 16#00#, 16#00#, 16#02#, txp); txc(dsutx, 16#c0#, txp); txa(dsutx, 16#90#, 16#00#, 16#00#, 16#20#, txp); txa(dsutx, 16#00#, 16#00#, 16#00#, 16#0f#, txp); txc(dsutx, 16#c0#, txp); txa(dsutx, 16#40#, 16#00#, 16#43#, 16#10#, txp); txa(dsutx, 16#00#, 16#00#, 16#00#, 16#0f#, txp); txc(dsutx, 16#c0#, txp); txa(dsutx, 16#91#, 16#40#, 16#00#, 16#24#, txp); txa(dsutx, 16#00#, 16#00#, 16#00#, 16#24#, txp); txc(dsutx, 16#c0#, txp); txa(dsutx, 16#91#, 16#70#, 16#00#, 16#00#, txp); txa(dsutx, 16#00#, 16#00#, 16#00#, 16#03#, txp); txc(dsutx, 16#c0#, txp); txa(dsutx, 16#90#, 16#00#, 16#00#, 16#20#, txp); txa(dsutx, 16#00#, 16#00#, 16#ff#, 16#ff#, txp); txc(dsutx, 16#c0#, txp); txa(dsutx, 16#90#, 16#40#, 16#00#, 16#48#, txp); txa(dsutx, 16#00#, 16#00#, 16#00#, 16#12#, txp); txc(dsutx, 16#c0#, txp); txa(dsutx, 16#90#, 16#40#, 16#00#, 16#60#, txp); txa(dsutx, 16#00#, 16#00#, 16#12#, 16#10#, txp); txc(dsutx, 16#80#, txp); txa(dsutx, 16#90#, 16#00#, 16#00#, 16#00#, txp); rxi(dsurx, w32, txp, lresp); txc(dsutx, 16#a0#, txp); txa(dsutx, 16#40#, 16#00#, 16#00#, 16#00#, txp); rxi(dsurx, w32, txp, lresp); end; begin dsucfg(dsutx, dsurx); wait; end process; end ;

gpl-2.0

12c0ed14a007a9f163086fb1c4602f3f

0.568982

3.038236

false

marco-c/leon-nexys2

grlib-gpl-1.3.4-b4140/lib/gaisler/ddr/ahb2avl_async.vhd

1

5,671

------------------------------------------------------------------------------ -- This file is a part of the GRLIB VHDL IP LIBRARY -- Copyright (C) 2003 - 2008, Gaisler Research -- Copyright (C) 2008 - 2013, Aeroflex Gaisler -- -- This program is free software; you can redistribute it and/or modify -- it under the terms of the GNU General Public License as published by -- the Free Software Foundation; either version 2 of the License, or -- (at your option) any later version. -- -- This program is distributed in the hope that it will be useful, -- but WITHOUT ANY WARRANTY; without even the implied warranty of -- MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the -- GNU General Public License for more details. -- -- You should have received a copy of the GNU General Public License -- along with this program; if not, write to the Free Software -- Foundation, Inc., 59 Temple Place, Suite 330, Boston, MA 02111-1307 USA ----------------------------------------------------------------------------- -- Entity: ahb2avl_async -- File: ahb2avl_async.vhd -- Author: Magnus Hjorth - Aeroflex Gaisler -- Description: Asynchronous AHB to Avalon-MM interface based on ddr2spa -------------------------------------------------------------------------------- library ieee; use ieee.std_logic_1164.all; library grlib; use grlib.amba.all; use grlib.stdlib.all; use grlib.devices.all; library gaisler; use gaisler.ddrpkg.all; use gaisler.ddrintpkg.all; entity ahb2avl_async is generic ( hindex : integer := 0; haddr : integer := 0; hmask : integer := 16#f00#; burstlen : integer := 8; nosync : integer := 0; ahbbits : integer := ahbdw; avldbits : integer := 32; avlabits : integer := 20 ); port ( rst_ahb : in std_ulogic; clk_ahb : in std_ulogic; ahbsi : in ahb_slv_in_type; ahbso : out ahb_slv_out_type; rst_avl : in std_ulogic; clk_avl : in std_ulogic; avlsi : out ddravl_slv_in_type; avlso : in ddravl_slv_out_type ); end; architecture struct of ahb2avl_async is constant l2blen: integer := log2(burstlen)+log2(32); constant l2ddrw: integer := log2(avldbits); constant l2ahbw: integer := log2(ahbbits); -- Write buffer dimensions constant wbuf_rabits_s: integer := 1+l2blen-l2ddrw; constant wbuf_rabits_r: integer := wbuf_rabits_s; constant wbuf_rdbits: integer := avldbits; constant wbuf_wabits: integer := 1+l2blen-5; constant wbuf_wdbits: integer := ahbbits; -- Read buffer dimensions constant rbuf_rabits: integer := l2blen-l2ahbw; constant rbuf_rdbits: integer := wbuf_wdbits; constant rbuf_wabits: integer := l2blen-l2ddrw; -- log2((burstlen*32)/(2*ddrbits)); constant rbuf_wdbits: integer := avldbits; signal request : ddr_request_type; signal start_tog : std_ulogic; signal response : ddr_response_type; signal wbwaddr: std_logic_vector(wbuf_wabits-1 downto 0); signal wbwdata: std_logic_vector(wbuf_wdbits-1 downto 0); signal wbraddr: std_logic_vector(wbuf_rabits_s-1 downto 0); signal wbrdata: std_logic_vector(wbuf_rdbits-1 downto 0); signal rbwaddr: std_logic_vector(rbuf_wabits-1 downto 0); signal rbwdata: std_logic_vector(rbuf_wdbits-1 downto 0); signal rbraddr: std_logic_vector(rbuf_rabits-1 downto 0); signal rbrdata: std_logic_vector(rbuf_rdbits-1 downto 0); signal wbwrite,wbwritebig,rbwrite: std_ulogic; signal gnd: std_logic_vector(3 downto 0); signal vcc: std_ulogic; begin gnd <= (others => '0'); vcc <= '1'; fe0: ddr2spax_ahb generic map ( hindex => hindex, haddr => haddr, hmask => hmask, ioaddr => 0, iomask => 0, burstlen => burstlen, nosync => nosync, ahbbits => ahbbits, devid => GAISLER_AHB2AVLA, ddrbits => avldbits/2 ) port map ( rst => rst_ahb, clk_ahb => clk_ahb, ahbsi => ahbsi, ahbso => ahbso, request => request, start_tog => start_tog, response => response, wbwaddr => wbwaddr, wbwdata => wbwdata, wbwrite => wbwrite, wbwritebig => wbwritebig, rbraddr => rbraddr, rbrdata => rbrdata, hwidth => gnd(0), beid => gnd(3 downto 0) ); be0: ahb2avl_async_be generic map ( avldbits => avldbits, avlabits => avlabits, burstlen => burstlen, nosync => nosync ) port map ( rst => rst_avl, clk => clk_avl, avlsi => avlsi, avlso => avlso, request => request, start_tog => start_tog, response => response, wbraddr => wbraddr, wbrdata => wbrdata, rbwaddr => rbwaddr, rbwdata => rbwdata, rbwrite => rbwrite ); wbuf: ddr2buf generic map (tech => 0, wabits => wbuf_wabits, wdbits => wbuf_wdbits, rabits => wbuf_rabits_r, rdbits => wbuf_rdbits, sepclk => 1, wrfst => 0) port map ( rclk => clk_avl, renable => vcc, raddress => wbraddr(wbuf_rabits_r-1 downto 0), dataout => wbrdata, wclk => clk_ahb, write => wbwrite, writebig => wbwritebig, waddress => wbwaddr, datain => wbwdata); rbuf: ddr2buf generic map (tech => 0, wabits => rbuf_wabits, wdbits => rbuf_wdbits, rabits => rbuf_rabits, rdbits => rbuf_rdbits, sepclk => 1, wrfst => 0) port map ( rclk => clk_ahb, renable => vcc, raddress => rbraddr, dataout => rbrdata, wclk => clk_avl, write => rbwrite, writebig => '0', waddress => rbwaddr, datain => rbwdata); end;

gpl-2.0

a508829e566544e37fe4e673029fb8bc

0.59478

3.924567

false

mistryalok/Zedboard

learning/opencv_hls/xapp1167_vivado/sw/fast-corner/prj/solution1/syn/vhdl/FIFO_image_filter_p_src_data_stream_0_V.vhd

2

4,629

-- ============================================================== -- File generated by Vivado(TM) HLS - High-Level Synthesis from C, C++ and SystemC -- Version: 2014.4 -- Copyright (C) 2014 Xilinx Inc. All rights reserved. -- -- ============================================================== library IEEE; use IEEE.std_logic_1164.all; use IEEE.std_logic_unsigned.all; entity FIFO_image_filter_p_src_data_stream_0_V_shiftReg is generic ( DATA_WIDTH : integer := 8; ADDR_WIDTH : integer := 1; DEPTH : integer := 2); port ( clk : in std_logic; data : in std_logic_vector(DATA_WIDTH-1 downto 0); ce : in std_logic; a : in std_logic_vector(ADDR_WIDTH-1 downto 0); q : out std_logic_vector(DATA_WIDTH-1 downto 0)); end FIFO_image_filter_p_src_data_stream_0_V_shiftReg; architecture rtl of FIFO_image_filter_p_src_data_stream_0_V_shiftReg is --constant DEPTH_WIDTH: integer := 16; type SRL_ARRAY is array (0 to DEPTH-1) of std_logic_vector(DATA_WIDTH-1 downto 0); signal SRL_SIG : SRL_ARRAY; begin p_shift: process (clk) begin if (clk'event and clk = '1') then if (ce = '1') then SRL_SIG <= data & SRL_SIG(0 to DEPTH-2); end if; end if; end process; q <= SRL_SIG(conv_integer(a)); end rtl; library ieee; use ieee.std_logic_1164.all; use ieee.std_logic_unsigned.all; entity FIFO_image_filter_p_src_data_stream_0_V is generic ( MEM_STYLE : string := "auto"; DATA_WIDTH : integer := 8; ADDR_WIDTH : integer := 1; DEPTH : integer := 2); port ( clk : IN STD_LOGIC; reset : IN STD_LOGIC; if_empty_n : OUT STD_LOGIC; if_read_ce : IN STD_LOGIC; if_read : IN STD_LOGIC; if_dout : OUT STD_LOGIC_VECTOR(DATA_WIDTH - 1 downto 0); if_full_n : OUT STD_LOGIC; if_write_ce : IN STD_LOGIC; if_write : IN STD_LOGIC; if_din : IN STD_LOGIC_VECTOR(DATA_WIDTH - 1 downto 0)); end entity; architecture rtl of FIFO_image_filter_p_src_data_stream_0_V is component FIFO_image_filter_p_src_data_stream_0_V_shiftReg is generic ( DATA_WIDTH : integer := 8; ADDR_WIDTH : integer := 1; DEPTH : integer := 2); port ( clk : in std_logic; data : in std_logic_vector(DATA_WIDTH-1 downto 0); ce : in std_logic; a : in std_logic_vector(ADDR_WIDTH-1 downto 0); q : out std_logic_vector(DATA_WIDTH-1 downto 0)); end component; signal shiftReg_addr : STD_LOGIC_VECTOR(ADDR_WIDTH - 1 downto 0); signal shiftReg_data, shiftReg_q : STD_LOGIC_VECTOR(DATA_WIDTH - 1 downto 0); signal shiftReg_ce : STD_LOGIC; signal mOutPtr : STD_LOGIC_VECTOR(ADDR_WIDTH downto 0) := (others => '1'); signal internal_empty_n : STD_LOGIC := '0'; signal internal_full_n : STD_LOGIC := '1'; begin if_empty_n <= internal_empty_n; if_full_n <= internal_full_n; shiftReg_data <= if_din; if_dout <= shiftReg_q; process (clk) begin if clk'event and clk = '1' then if reset = '1' then mOutPtr <= (others => '1'); internal_empty_n <= '0'; internal_full_n <= '1'; else if ((if_read and if_read_ce) = '1' and internal_empty_n = '1') and ((if_write and if_write_ce) = '0' or internal_full_n = '0') then mOutPtr <= mOutPtr -1; if (mOutPtr = 0) then internal_empty_n <= '0'; end if; internal_full_n <= '1'; elsif ((if_read and if_read_ce) = '0' or internal_empty_n = '0') and ((if_write and if_write_ce) = '1' and internal_full_n = '1') then mOutPtr <= mOutPtr +1; internal_empty_n <= '1'; if (mOutPtr = DEPTH -2) then internal_full_n <= '0'; end if; end if; end if; end if; end process; shiftReg_addr <= (others => '0') when mOutPtr(ADDR_WIDTH) = '1' else mOutPtr(ADDR_WIDTH-1 downto 0); shiftReg_ce <= (if_write and if_write_ce) and internal_full_n; U_FIFO_image_filter_p_src_data_stream_0_V_shiftReg : FIFO_image_filter_p_src_data_stream_0_V_shiftReg generic map ( DATA_WIDTH => DATA_WIDTH, ADDR_WIDTH => ADDR_WIDTH, DEPTH => DEPTH) port map ( clk => clk, data => shiftReg_data, ce => shiftReg_ce, a => shiftReg_addr, q => shiftReg_q); end rtl;

gpl-3.0

3b3269b788d2112b5acdb7f5e67b62da

0.537697

3.449329

false

laurocruz/snakes_vhdl

src/snake_lib/make_map.vhd

1

2,607

LIBRARY ieee; USE ieee.std_logic_1164.all; LIBRARY snake_lib; USE snake_lib.snake_pack.all; -- controlador do mapa do jogo ENTITY make_map IS -- DImensões do mapa GENERIC (N : INTEGER := 10; M : INTEGER := 10; INITIAL_SIZE : INTEGER := 2); -- clock do jogo PORT (clock : IN STD_LOGIC; -- reseta o jogo reset : IN STD_LOGIC; -- aumento do tamanho eaten : IN STD_LOGIC; snake_size : IN INTEGER RANGE 0 TO N*M; -- direcao para onde a cobra esta se movendo -- 11 : cima -- 00 : baixo -- 10 : esquerda -- 01 : direita dir : IN STD_LOGIC_VECTOR(1 DOWNTO 0); -- posicoes da cobra no mapa snake_body : OUT int_array); END make_map; ARCHITECTURE Behavior OF make_map IS -- Vetor de estruturas de dois inteiros que representam a posição de cada parte da cobra (l,c) --TYPE snake_body IS array (0 to N*M-1) OF INTEGER RANGE 0 TO N*M-1; --SIGNAL snake : snake_body; SIGNAL snake : int_array; SIGNAL dir_s : STD_LOGIC_VECTOR(1 DOWNTO 0); BEGIN snake_body <= snake; dir_s <= dir; PROCESS (clock, reset, eaten) VARIABLE j : INTEGER RANGE 0 TO N*M; VARIABLE DIF : INTEGER RANGE 0 TO M; --VARIABLE index : INTEGER RANGE 0 TO N*M; --VARIABLE map_s : STD_LOGIC_VECTOR(0 TO N*M-1); BEGIN IF (reset = '1') THEN FOR i in 0 to INITIAL_SIZE-1 LOOP snake(i) <= (N/2) + (i+M/2)*M; END LOOP; FOR i in INITIAL_SIZE to N*M-1 LOOP snake(i) <= -1; END LOOP; ELSIF (eaten = '1') THEN DIF := snake(snake_size-1) - snake(snake_size-2); snake(snake_size) <= snake(snake_size-1) + DIF; ELSIF (clock'EVENT and clock = '1') THEN j := 0; WHILE (j+1 < M*N and not(snake(j+1) = -1)) LOOP snake(j+1) <= snake(j); j := j + 1; END LOOP; --FOR i IN 0 TO snake_size-2 LOOP -- snake(i+1) <= snake(i); --END LOOP; IF (dir_s = "00") THEN snake(0) <= snake(0) + M; ELSIF (dir_s = "01") THEN snake(0) <= snake(0) + 1; ELSIF (dir_s = "10") THEN snake(0) <= snake(0) - 1; ELSE snake(0) <= snake(0) - M; END IF; --map_s := (OTHERS => '0'); --j := 0; --WHILE (j < M*N and not(snake(j) = -1)) LOOP -- index := snake(j); -- map_s(index) := '1'; -- j := j + 1; --END LOOP; END IF; --gmap <= map_s; END PROCESS; END Behavior;

mit

afd52d16422faa9ad2870e4a05a62c08

0.508065

2.955732

false

marco-c/leon-nexys2

grlib-gpl-1.3.4-b4140/designs/leon3-nuhorizons-3s1500/testbench.vhd

1

13,633

----------------------------------------------------------------------------- -- LEON3 Demonstration design test bench -- Copyright (C) 2004 Jiri Gaisler, Gaisler Research ------------------------------------------------------------------------------ -- This file is a part of the GRLIB VHDL IP LIBRARY -- Copyright (C) 2003 - 2008, Gaisler Research -- Copyright (C) 2008 - 2013, Aeroflex Gaisler -- -- This program is free software; you can redistribute it and/or modify -- it under the terms of the GNU General Public License as published by -- the Free Software Foundation; either version 2 of the License, or -- (at your option) any later version. -- -- This program is distributed in the hope that it will be useful, -- but WITHOUT ANY WARRANTY; without even the implied warranty of -- MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the -- GNU General Public License for more details. -- -- You should have received a copy of the GNU General Public License -- along with this program; if not, write to the Free Software -- Foundation, Inc., 59 Temple Place, Suite 330, Boston, MA 02111-1307 USA ------------------------------------------------------------------------------ library ieee; use ieee.std_logic_1164.all; library gaisler; use gaisler.libdcom.all; use gaisler.sim.all; library techmap; use techmap.gencomp.all; library micron; use micron.components.all; use work.config.all; -- configuration use work.debug.all; entity testbench is generic ( fabtech : integer := CFG_FABTECH; memtech : integer := CFG_MEMTECH; padtech : integer := CFG_PADTECH; clktech : integer := CFG_CLKTECH; disas : integer := CFG_DISAS; -- Enable disassembly to console dbguart : integer := CFG_DUART; -- Print UART on console pclow : integer := CFG_PCLOW; clkperiod : integer := 20; -- system clock period romwidth : integer := 8+8*CFG_MCTRL_RAM16BIT; -- rom data width (8/16) romdepth : integer := 16; -- rom address depth sramwidth : integer := 32; -- ram data width (8/16/32) sramdepth : integer := 18; -- ram address depth srambanks : integer := 2 -- number of ram banks ); end; architecture behav of testbench is constant promfile : string := "prom.srec"; -- rom contents constant sramfile : string := "ram.srec"; -- ram contents constant sdramfile : string := "ram.srec"; -- sdram contents component leon3mp generic ( fabtech : integer := CFG_FABTECH; memtech : integer := CFG_MEMTECH; padtech : integer := CFG_PADTECH; clktech : integer := CFG_CLKTECH; disas : integer := CFG_DISAS; -- Enable disassembly to console dbguart : integer := CFG_DUART; -- Print UART on console pclow : integer := CFG_PCLOW ); port ( pb_sw : in std_logic_vector (4 downto 1); -- push buttons pll_clk : in std_ulogic; -- PLL clock led : out std_logic_vector(8 downto 1); flash_a : out std_logic_vector(20 downto 0); flash_d : inout std_logic_vector(15 downto 0); sdram_a : out std_logic_vector(11 downto 0); sdram_d : inout std_logic_vector(31 downto 0); sdram_ba : out std_logic_vector(3 downto 0); sdram_dqm : out std_logic_vector(3 downto 0); sdram_clk : inout std_ulogic; sdram_cke : out std_ulogic; -- sdram clock enable sdram_csn : out std_ulogic; -- sdram chip select sdram_wen : out std_ulogic; -- sdram write enable sdram_rasn : out std_ulogic; -- sdram ras sdram_casn : out std_ulogic; -- sdram cas uart1_txd : out std_ulogic; uart1_rxd : in std_ulogic; uart1_rts : out std_ulogic; uart1_cts : in std_ulogic; uart2_txd : out std_ulogic; uart2_rxd : in std_ulogic; uart2_rts : out std_ulogic; uart2_cts : in std_ulogic; flash_oen : out std_ulogic; flash_wen : out std_ulogic; flash_cen : out std_ulogic; flash_byte : out std_ulogic; flash_ready : in std_ulogic; flash_rpn : out std_ulogic; flash_wpn : out std_ulogic; phy_mii_data: inout std_logic; -- ethernet PHY interface phy_tx_clk : in std_ulogic; phy_rx_clk : in std_ulogic; phy_rx_data : in std_logic_vector(3 downto 0); phy_dv : in std_ulogic; phy_rx_er : in std_ulogic; phy_col : in std_ulogic; phy_crs : in std_ulogic; phy_tx_data : out std_logic_vector(3 downto 0); phy_tx_en : out std_ulogic; phy_mii_clk : out std_ulogic; phy_100 : in std_ulogic; -- 100 Mbit indicator phy_rst_n : out std_ulogic; gpio : inout std_logic_vector(CFG_GRGPIO_WIDTH-1 downto 0); -- lcd_data : inout std_logic_vector(7 downto 0); -- lcd_rs : out std_ulogic; -- lcd_rw : out std_ulogic; -- lcd_en : out std_ulogic; -- lcd_backl : out std_ulogic; can_txd : out std_ulogic; can_rxd : in std_ulogic; smsc_addr : out std_logic_vector(14 downto 0); smsc_data : inout std_logic_vector(31 downto 0); smsc_nbe : out std_logic_vector(3 downto 0); smsc_resetn : out std_ulogic; smsc_ardy : in std_ulogic; -- smsc_intr : in std_ulogic; smsc_nldev : in std_ulogic; smsc_nrd : out std_ulogic; smsc_nwr : out std_ulogic; smsc_ncs : out std_ulogic; smsc_aen : out std_ulogic; smsc_lclk : out std_ulogic; smsc_wnr : out std_ulogic; smsc_rdyrtn : out std_ulogic; smsc_cycle : out std_ulogic; smsc_nads : out std_ulogic ); end component; signal clk : std_logic := '0'; signal Rst : std_logic := '0'; -- Reset constant ct : integer := clkperiod/2; signal address : std_logic_vector(21 downto 0); signal flash_d : std_logic_vector(15 downto 0); signal romsn : std_ulogic; signal oen : std_ulogic; signal writen : std_ulogic; signal dsuen, dsutx, dsurx, dsubre, dsuact : std_ulogic; signal dsurst : std_ulogic; signal test : std_ulogic; signal error : std_logic; signal GND : std_ulogic := '0'; signal VCC : std_ulogic := '1'; signal NC : std_ulogic := 'Z'; signal clk2 : std_ulogic := '1'; signal sdcke : std_ulogic; -- clk en signal sdcsn : std_ulogic; -- chip sel signal sdwen : std_ulogic; -- write en signal sdrasn : std_ulogic; -- row addr stb signal sdcasn : std_ulogic; -- col addr stb signal sddqm : std_logic_vector ( 3 downto 0); -- data i/o mask signal sdclk : std_ulogic; signal txd1, rxd1 : std_ulogic; signal txd2, rxd2 : std_ulogic; signal etx_clk, erx_clk, erx_dv, erx_er, erx_col, erx_crs, etx_en, etx_er : std_logic:='0'; signal erxd, etxd: std_logic_vector(3 downto 0):=(others=>'0'); signal erxdt, etxdt: std_logic_vector(7 downto 0):=(others=>'0'); signal emdc, emdio: std_logic; signal gtx_clk : std_ulogic; signal ereset : std_logic; signal led : std_logic_vector(8 downto 1); constant lresp : boolean := false; signal sa : std_logic_vector(14 downto 0); signal ba : std_logic_vector(3 downto 0); signal sd : std_logic_vector(31 downto 0); signal pb_sw : std_logic_vector(4 downto 1); signal lcd_data : std_logic_vector(7 downto 0); signal lcd_rs : std_ulogic; signal lcd_rw : std_ulogic; signal lcd_en : std_ulogic; signal lcd_backl: std_ulogic; signal can_txd : std_ulogic; signal can_rxd : std_ulogic; signal gpio : std_logic_vector(CFG_GRGPIO_WIDTH-1 downto 0); signal smsc_addr : std_logic_vector(21 downto 0); signal smsc_data : std_logic_vector(31 downto 0); signal smsc_nbe : std_logic_vector(3 downto 0); signal smsc_resetn : std_ulogic; signal smsc_ardy : std_ulogic; signal smsc_intr : std_ulogic; signal smsc_nldev : std_ulogic; signal smsc_nrd : std_ulogic; signal smsc_nwr : std_ulogic; signal smsc_ncs : std_ulogic; signal smsc_aen : std_ulogic; signal smsc_lclk : std_ulogic; signal smsc_wnr : std_ulogic; signal smsc_rdyrtn : std_ulogic; signal smsc_cycle : std_ulogic; signal smsc_nads : std_ulogic; begin -- clock and reset clk <= not clk after ct * 1 ns; rst <= dsurst; dsuen <= '1'; dsubre <= '0'; rxd1 <= '1'; can_rxd <= '1'; error <= led(8); sa(14 downto 12) <= "000"; pb_sw <= rst & "00" & dsubre; cpu : leon3mp generic map ( fabtech, memtech, padtech, clktech, disas, dbguart, pclow ) port map (pb_sw, clk, led, address(21 downto 1), flash_d, sa(11 downto 0), sd, ba, sddqm, sdclk, sdcke, sdcsn, sdwen, sdrasn, sdcasn, txd1, rxd1, open, gnd, dsutx, dsurx, open, gnd, oen, writen, romsn, open, vcc, open, open, emdio, etx_clk, erx_clk, erxd, erx_dv, erx_er, erx_col, erx_crs, etxd, etx_en, emdc, gnd, ereset, gpio, -- lcd_data, lcd_rs, lcd_rw, lcd_en, lcd_backl, can_txd, can_rxd, smsc_addr(14 downto 0), smsc_data, smsc_nbe, smsc_resetn, smsc_ardy,-- smsc_intr, smsc_nldev, smsc_nrd, smsc_nwr, smsc_ncs, smsc_aen, smsc_lclk, smsc_wnr, smsc_rdyrtn, smsc_cycle, smsc_nads); u0: mt48lc16m16a2 generic map (index => 0, fname => sdramfile) PORT MAP( Dq => sd(31 downto 16), Addr => sa(12 downto 0), Ba => ba(1 downto 0), Clk => sdclk, Cke => sdcke, Cs_n => sdcsn, Ras_n => sdrasn, Cas_n => sdcasn, We_n => sdwen, Dqm => sddqm(3 downto 2)); u1: mt48lc16m16a2 generic map (index => 16, fname => sdramfile) PORT MAP( Dq => sd(15 downto 0), Addr => sa(12 downto 0), Ba => ba(3 downto 2), Clk => sdclk, Cke => sdcke, Cs_n => sdcsn, Ras_n => sdrasn, Cas_n => sdcasn, We_n => sdwen, Dqm => sddqm(1 downto 0)); rom8 : if romwidth /= 16 generate prom0 : sram16 generic map (index => 4, abits => romdepth, fname => promfile) port map (address(romdepth downto 1), flash_d(15 downto 0), gnd, gnd, romsn, writen, oen); address(0) <= flash_d(15); end generate; rom16 : if romwidth = 16 generate prom0 : sram16 generic map (index => 4, abits => romdepth, fname => promfile) port map (address(romdepth downto 1), flash_d(15 downto 0), gnd, gnd, romsn, writen, oen); address(0) <= '0'; end generate; emdio <= 'H'; erxd <= erxdt(3 downto 0); etxdt <= "0000" & etxd; p0: phy generic map(base1000_t_fd => 0, base1000_t_hd => 0) port map(rst, emdio, etx_clk, erx_clk, erxdt, erx_dv, erx_er, erx_col, erx_crs, etxdt, etx_en, etx_er, emdc, gtx_clk); error <= 'H'; -- ERROR pull-up iuerr : process begin wait for 2000 ns; if to_x01(error) = '1' then wait on error; end if; assert (to_x01(error) = '1') report "*** IU in error mode, simulation halted ***" severity failure ; end process; flash_d <= buskeep(flash_d) after 5 ns; sd <= buskeep(sd) after 5 ns; smsc_data <= buskeep(smsc_data) after 5 ns; smsc_addr(21 downto 15) <= (others => '0'); test0 : grtestmod port map ( rst, clk, error, address(21 downto 2), smsc_data, smsc_ncs, oen, writen, open); dsucom : process procedure dsucfg(signal dsurx : in std_ulogic; signal dsutx : out std_ulogic) is variable w32 : std_logic_vector(31 downto 0); variable c8 : std_logic_vector(7 downto 0); constant txp : time := 160 * 1 ns; begin dsutx <= '1'; dsurst <= '0'; wait for 500 ns; dsurst <= '1'; wait; wait for 5000 ns; txc(dsutx, 16#55#, txp); -- sync uart txc(dsutx, 16#c0#, txp); txa(dsutx, 16#90#, 16#40#, 16#00#, 16#44#, txp); txa(dsutx, 16#00#, 16#00#, 16#20#, 16#00#, txp); txc(dsutx, 16#80#, txp); txa(dsutx, 16#90#, 16#40#, 16#00#, 16#44#, txp); wait; txc(dsutx, 16#c0#, txp); txa(dsutx, 16#00#, 16#00#, 16#0a#, 16#aa#, txp); txa(dsutx, 16#00#, 16#55#, 16#00#, 16#55#, txp); txc(dsutx, 16#c0#, txp); txa(dsutx, 16#00#, 16#00#, 16#0a#, 16#a0#, txp); txa(dsutx, 16#01#, 16#02#, 16#09#, 16#33#, txp); txc(dsutx, 16#c0#, txp); txa(dsutx, 16#90#, 16#00#, 16#00#, 16#00#, txp); txa(dsutx, 16#00#, 16#00#, 16#00#, 16#2e#, txp); txc(dsutx, 16#c0#, txp); txa(dsutx, 16#91#, 16#00#, 16#00#, 16#00#, txp); txa(dsutx, 16#00#, 16#00#, 16#00#, 16#2e#, txp); txc(dsutx, 16#c0#, txp); txa(dsutx, 16#90#, 16#00#, 16#00#, 16#20#, txp); txa(dsutx, 16#00#, 16#00#, 16#00#, 16#0f#, txp); txc(dsutx, 16#c0#, txp); txa(dsutx, 16#90#, 16#00#, 16#00#, 16#20#, txp); txa(dsutx, 16#00#, 16#00#, 16#00#, 16#00#, txp); txc(dsutx, 16#c0#, txp); txa(dsutx, 16#80#, 16#00#, 16#02#, 16#10#, txp); txa(dsutx, 16#00#, 16#00#, 16#00#, 16#0f#, txp); txc(dsutx, 16#c0#, txp); txa(dsutx, 16#91#, 16#40#, 16#00#, 16#24#, txp); txa(dsutx, 16#00#, 16#00#, 16#00#, 16#24#, txp); txc(dsutx, 16#c0#, txp); txa(dsutx, 16#91#, 16#70#, 16#00#, 16#00#, txp); txa(dsutx, 16#00#, 16#00#, 16#00#, 16#03#, txp); txc(dsutx, 16#c0#, txp); txa(dsutx, 16#90#, 16#00#, 16#00#, 16#20#, txp); txa(dsutx, 16#00#, 16#00#, 16#ff#, 16#ff#, txp); txc(dsutx, 16#c0#, txp); txa(dsutx, 16#90#, 16#40#, 16#00#, 16#48#, txp); txa(dsutx, 16#00#, 16#00#, 16#00#, 16#12#, txp); txc(dsutx, 16#c0#, txp); txa(dsutx, 16#90#, 16#40#, 16#00#, 16#60#, txp); txa(dsutx, 16#00#, 16#00#, 16#12#, 16#10#, txp); txc(dsutx, 16#80#, txp); txa(dsutx, 16#90#, 16#00#, 16#00#, 16#00#, txp); rxi(dsurx, w32, txp, lresp); txc(dsutx, 16#a0#, txp); txa(dsutx, 16#40#, 16#00#, 16#00#, 16#00#, txp); rxi(dsurx, w32, txp, lresp); end; begin dsucfg(dsutx, dsurx); wait; end process; end ;

gpl-2.0

a6ef3c9b1ea70705254894133c477b6a

0.591946

3.045119

false

marco-c/leon-nexys2

grlib-gpl-1.3.4-b4140/designs/leon3-avnet-3s1500/leon3mp.vhd

1

26,269

----------------------------------------------------------------------------- -- LEON3 Demonstration design for AVNET Spartan3 Evaluation Board -- Copyright (C) 2004 Jiri Gaisler, Gaisler Research ------------------------------------------------------------------------------ -- This file is a part of the GRLIB VHDL IP LIBRARY -- Copyright (C) 2003 - 2008, Gaisler Research -- Copyright (C) 2008 - 2013, Aeroflex Gaisler -- -- This program is free software; you can redistribute it and/or modify -- it under the terms of the GNU General Public License as published by -- the Free Software Foundation; either version 2 of the License, or -- (at your option) any later version. -- -- This program is distributed in the hope that it will be useful, -- but WITHOUT ANY WARRANTY; without even the implied warranty of -- MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the -- GNU General Public License for more details. -- -- You should have received a copy of the GNU General Public License -- along with this program; if not, write to the Free Software -- Foundation, Inc., 59 Temple Place, Suite 330, Boston, MA 02111-1307 USA ------------------------------------------------------------------------------ library ieee; use ieee.std_logic_1164.all; library grlib; use grlib.amba.all; use grlib.stdlib.all; library techmap; use techmap.gencomp.all; use techmap.allclkgen.all; library gaisler; use gaisler.memctrl.all; use gaisler.leon3.all; use gaisler.uart.all; use gaisler.misc.all; use gaisler.pci.all; use gaisler.net.all; use gaisler.jtag.all; use gaisler.can.all; library esa; use esa.memoryctrl.all; use esa.pcicomp.all; use work.config.all; entity leon3mp is generic ( fabtech : integer := CFG_FABTECH; memtech : integer := CFG_MEMTECH; padtech : integer := CFG_PADTECH; clktech : integer := CFG_CLKTECH; disas : integer := CFG_DISAS; -- Enable disassembly to console dbguart : integer := CFG_DUART; -- Print UART on console pclow : integer := CFG_PCLOW; mezz : integer := CFG_ADS_DAU_MEZZ ); port ( clk_66mhz : in std_logic; clk_socket : in std_logic; leds : out std_logic_vector(7 downto 0); switches : in std_logic_vector(5 downto 0); sram_a : out std_logic_vector(24 downto 0); sram_ben_l : out std_logic_vector(0 to 3); sram_cs_l : out std_logic_vector(1 downto 0); sram_oe_l : out std_logic; sram_we_l : out std_logic; sram_dq : inout std_logic_vector(31 downto 0); flash_cs_l : out std_logic; flash_rst_l : out std_logic; iosn : out std_logic; sdclk : out std_logic; rasn : out std_logic; casn : out std_logic; sdcke : out std_logic; sdcsn : out std_logic; tx : out std_logic; rx : in std_logic; can_txd : out std_logic; can_rxd : in std_logic; phy_txck : in std_logic; phy_rxck : in std_logic; phy_rxd : in std_logic_vector(3 downto 0); phy_rxdv : in std_logic; phy_rxer : in std_logic; phy_col : in std_logic; phy_crs : in std_logic; phy_txd : out std_logic_vector(3 downto 0); phy_txen : out std_logic; phy_txer : out std_logic; phy_mdc : out std_logic; phy_mdio : inout std_logic; -- ethernet PHY interface phy_reset_l : inout std_logic; video_clk : in std_logic; comp_sync : out std_logic; horiz_sync : out std_logic; vert_sync : out std_logic; blank : out std_logic; video_out : out std_logic_vector(23 downto 0); msclk : inout std_logic; msdata : inout std_logic; kbclk : inout std_logic; kbdata : inout std_logic; disp_seg1 : out std_logic_vector(7 downto 0); disp_seg2 : out std_logic_vector(7 downto 0); pci_clk : in std_logic; pci_gnt : in std_logic; pci_idsel : in std_logic; pci_lock : inout std_logic; pci_ad : inout std_logic_vector(31 downto 0); pci_cbe : inout std_logic_vector(3 downto 0); pci_frame : inout std_logic; pci_irdy : inout std_logic; pci_trdy : inout std_logic; pci_devsel : inout std_logic; pci_stop : inout std_logic; pci_perr : inout std_logic; pci_par : inout std_logic; pci_req : inout std_logic; pci_serr : inout std_logic; pci_host : in std_logic; pci_66 : in std_logic ); end; architecture rtl of leon3mp is constant blength : integer := 12; constant fifodepth : integer := 8; constant mahbmax : integer := CFG_NCPU+CFG_AHB_UART+CFG_PCI+ CFG_SVGA_ENABLE + CFG_GRETH+CFG_AHB_JTAG; signal vcc, gnd : std_logic_vector(23 downto 0); signal memi : memory_in_type; signal memo : memory_out_type; signal wpo : wprot_out_type; signal sdi : sdctrl_in_type; signal sdo : sdram_out_type; signal abus : std_logic_vector(17 downto 0); signal apbi : apb_slv_in_type; signal apbo : apb_slv_out_vector := (others => apb_none); signal ahbsi : ahb_slv_in_type; signal ahbso : ahb_slv_out_vector := (others => ahbs_none); signal ahbmi : ahb_mst_in_type; signal ahbmo : ahb_mst_out_vector := (others => ahbm_none); signal clk, rstn, rstraw, pciclk, sdclkl : std_logic; signal cgi : clkgen_in_type; signal cgo : clkgen_out_type; signal u1i, u2i, dui : uart_in_type; signal u1o, u2o, duo : uart_out_type; signal irqi : irq_in_vector(0 to CFG_NCPU-1); signal irqo : irq_out_vector(0 to CFG_NCPU-1); signal dbgi : l3_debug_in_vector(0 to CFG_NCPU-1); signal dbgo : l3_debug_out_vector(0 to CFG_NCPU-1); signal dsui : dsu_in_type; signal dsuo : dsu_out_type; signal kbdi : ps2_in_type; signal kbdo : ps2_out_type; signal moui : ps2_in_type; signal mouo : ps2_out_type; signal vgao : apbvga_out_type; signal pcii : pci_in_type; signal pcio : pci_out_type; signal ethi, ethi1, ethi2 : eth_in_type; signal etho, etho1, etho2 : eth_out_type; signal gpti : gptimer_in_type; signal tck, tms, tdi, tdo : std_logic; signal pllref, errorn, pci_rst : std_logic; signal pci_arb_req_n, pci_arb_gnt_n : std_logic_vector(0 to 3); signal dac_clk, clk25, clk_66mhzl, pci_lclk : std_logic; signal can_ltx, can_lrx : std_logic; attribute keep : boolean; attribute syn_keep : boolean; attribute syn_preserve : boolean; attribute syn_keep of clk : signal is true; attribute syn_preserve of clk : signal is true; attribute keep of clk : signal is true; signal switchesl : std_logic_vector(5 downto 0); constant padlevel : integer := 0; constant IOAEN : integer := CFG_CAN; constant BOARD_FREQ : integer := 66667; -- input frequency in KHz constant CPU_FREQ : integer := (BOARD_FREQ * CFG_CLKMUL) / CFG_CLKDIV; begin ---------------------------------------------------------------------- --- Reset and Clock generation ------------------------------------- --------------------------------------------------------------------- vcc <= (others => '1'); gnd <= (others => '0'); pllref <= '0'; cgi.pllctrl <= "00"; cgi.pllrst <= rstraw; cgi.pllref <= pllref; clkgen0 : clkgen -- clock generator generic map (clktech, CFG_CLKMUL, CFG_CLKDIV, CFG_MCTRL_SDEN, CFG_CLK_NOFB, CFG_PCI, CFG_PCIDLL, CFG_PCISYSCLK, 66000) port map (clk_66mhzl, pci_lclk, clk, open, open, sdclkl, pciclk, cgi, cgo); sdclk_pad : outpad generic map (tech => padtech, slew => 1, strength => 8) port map (sdclk, sdclkl); clk_pad : clkpad generic map (tech => padtech, level => padlevel) port map (clk_66mhz, clk_66mhzl); clk2_pad : clkpad generic map (tech => padtech, level => padlevel) port map (clk_socket, open); pci_clk_pad : clkpad generic map (tech => padtech, level => pci33) port map (pci_clk, pci_lclk); rst0 : rstgen generic map (acthigh => 1) port map (switchesl(4), clk, cgo.clklock, rstn, rstraw); flash_rst_l_pad : outpad generic map (level => padlevel, tech => padtech) port map (flash_rst_l, rstraw); ---------------------------------------------------------------------- --- AHB CONTROLLER -------------------------------------------------- ---------------------------------------------------------------------- ahb0 : ahbctrl -- AHB arbiter/multiplexer generic map (defmast => CFG_DEFMST, split => CFG_SPLIT, rrobin => CFG_RROBIN, ioaddr => CFG_AHBIO, nahbm => mahbmax, nahbs => 8, ioen => IOAEN) port map (rstn, clk, ahbmi, ahbmo, ahbsi, ahbso); ---------------------------------------------------------------------- --- LEON3 processor and DSU ----------------------------------------- ---------------------------------------------------------------------- l3 : if CFG_LEON3 = 1 generate cpu : for i in 0 to CFG_NCPU-1 generate u0 : leon3s -- LEON3 processor generic map (i, fabtech, memtech, CFG_NWIN, CFG_DSU, CFG_FPU, CFG_V8, 0, CFG_MAC, pclow, CFG_NOTAG, CFG_NWP, CFG_ICEN, CFG_IREPL, CFG_ISETS, CFG_ILINE, CFG_ISETSZ, CFG_ILOCK, CFG_DCEN, CFG_DREPL, CFG_DSETS, CFG_DLINE, CFG_DSETSZ, CFG_DLOCK, CFG_DSNOOP, CFG_ILRAMEN, CFG_ILRAMSZ, CFG_ILRAMADDR, CFG_DLRAMEN, CFG_DLRAMSZ, CFG_DLRAMADDR, CFG_MMUEN, CFG_ITLBNUM, CFG_DTLBNUM, CFG_TLB_TYPE, CFG_TLB_REP, CFG_LDDEL, disas, CFG_ITBSZ, CFG_PWD, CFG_SVT, CFG_RSTADDR, CFG_NCPU-1, 0, 0, CFG_MMU_PAGE, CFG_BP) port map (clk, rstn, ahbmi, ahbmo(i), ahbsi, ahbso, irqi(i), irqo(i), dbgi(i), dbgo(i)); dsugen : if CFG_DSU = 1 generate dsu0 : dsu3 -- LEON3 Debug Support Unit generic map (hindex => 2, haddr => 16#900#, hmask => 16#F00#, ncpu => CFG_NCPU, tbits => 30, tech => memtech, irq => 0, kbytes => CFG_ATBSZ) port map (rstn, clk, ahbmi, ahbsi, ahbso(2), dbgo, dbgi, dsui, dsuo); end generate; dsui.break <= switchesl(5); dsui.enable <= '1'; dsuact_pad : outpad generic map (tech => padtech, level => padlevel) port map (leds(1), dsuo.active); end generate; end generate; nodsu : if CFG_DSU = 0 generate ahbso(2) <= ahbs_none; dsuo.tstop <= '0'; dsuo.active <= '0'; end generate; dcomgen : if CFG_AHB_UART = 1 generate dcom0: ahbuart -- Debug UART generic map (hindex => CFG_NCPU, pindex => 7, paddr => 7) port map (rstn, clk, dui, duo, apbi, apbo(7), ahbmi, ahbmo(CFG_NCPU)); end generate; nouah : if CFG_AHB_UART = 0 generate apbo(7) <= apb_none; end generate; ahbjtaggen0 :if CFG_AHB_JTAG = 1 generate ahbjtag0 : ahbjtag generic map(tech => fabtech, hindex => CFG_NCPU+CFG_AHB_UART) port map(rstn, clk, tck, tms, tdi, tdo, ahbmi, ahbmo(CFG_NCPU+CFG_AHB_UART), open, open, open, open, open, open, open, gnd(0)); end generate; dcompads : if CFG_AHB_UART = 1 generate dsurx_pad : inpad generic map (tech => padtech, level => padlevel) port map (rx, dui.rxd); dsutx_pad : outpad generic map (tech => padtech, level => padlevel) port map (tx, duo.txd); u1i.rxd <= '1'; end generate; ---------------------------------------------------------------------- --- Memory controllers ---------------------------------------------- ---------------------------------------------------------------------- mg2 : if CFG_MCTRL_LEON2 = 1 generate -- LEON2 memory controller sr1 : entity work.mctrl_avnet generic map (hindex => 0, pindex => 0, paddr => 0, srbanks => 4, sden => CFG_MCTRL_SDEN, invclk => CFG_MCTRL_INVCLK, pageburst => CFG_MCTRL_PAGE, avnetmezz => mezz) port map (rstn, clk, memi, memo, ahbsi, ahbso(0), apbi, apbo(0), wpo, sdo); sdpads : if CFG_MCTRL_SDEN = 1 generate -- no SDRAM controller -- sdwen_pad : outpad generic map (tech => padtech) -- port map (sdwen, sdo.sdwen); sdras_pad : outpad generic map (tech => padtech) port map (rasn, sdo.rasn); sdcas_pad : outpad generic map (tech => padtech) port map (casn, sdo.casn); -- sddqm_pad : outpadv generic map (width =>4, tech => padtech) -- port map (sddqm, sdo.dqm); end generate; sdcke_pad : outpad generic map (tech => padtech) port map (sdcke, sdo.sdcke(0)); sdcsn_pad : outpad generic map (tech => padtech) port map (sdcsn, sdo.sdcsn(0)); end generate; nosd0 : if (CFG_MCTRL_SDEN = 0) generate -- no SDRAM controller sdcke_pad : outpad generic map (tech => padtech) port map (sdcke, vcc(0)); sdcsn_pad : outpad generic map (tech => padtech) port map (sdcsn, vcc(0)); end generate; memi.brdyn <= '1'; memi.bexcn <= '1'; memi.writen <= '1'; memi.wrn <= "1111"; memi.bwidth <= "10"; mg0 : if CFG_MCTRL_LEON2 = 0 generate -- None PROM/SRAM controller apbo(0) <= apb_none; ahbso(0) <= ahbs_none; rams_pad : outpadv generic map (level => padlevel, tech => padtech, width => 2) port map (sram_cs_l, vcc(1 downto 0)); end generate; mgpads : if CFG_MCTRL_LEON2 /= 0 generate -- prom/sram pads addr_pad : outpadv generic map (level => padlevel, width => 25, tech => padtech) port map (sram_a, memo.address(24 downto 0)); rams_pad : outpadv generic map (level => padlevel, tech => padtech, width => 2) port map (sram_cs_l, memo.ramsn(1 downto 0)); flash_pad : outpad generic map (level => padlevel, tech => padtech) port map (flash_cs_l, memo.romsn(0)); oen_pad : outpad generic map (level => padlevel, tech => padtech) port map (sram_oe_l, memo.oen); iosn_pad : outpad generic map (level => padlevel, tech => padtech) port map (iosn, memo.iosn); wri_pad : outpad generic map (level => padlevel, tech => padtech) port map (sram_we_l, memo.writen); bdr : for i in 0 to 3 generate data_pad : iopadv generic map (level => padlevel, tech => padtech, width => 8) port map (sram_dq(31-i*8 downto 24-i*8), memo.data(31-i*8 downto 24-i*8), memo.bdrive(i), memi.data(31-i*8 downto 24-i*8)); end generate; ben_pad : outpadv generic map (level => padlevel, width => 4, tech => padtech) port map (sram_ben_l, memo.mben); end generate; ---------------------------------------------------------------------- --- APB Bridge and various periherals ------------------------------- ---------------------------------------------------------------------- apb0 : apbctrl -- AHB/APB bridge generic map (hindex => 1, haddr => CFG_APBADDR) port map (rstn, clk, ahbsi, ahbso(1), apbi, apbo ); ua1 : if CFG_UART1_ENABLE /= 0 generate uart1 : apbuart -- UART 1 generic map (pindex => 1, paddr => 1, pirq => 2, console => dbguart, fifosize => CFG_UART1_FIFO) port map (rstn, clk, apbi, apbo(1), u1i, u1o); u1i.ctsn <= '0'; u1i.extclk <= '0'; end generate; noua0 : if CFG_UART1_ENABLE = 0 generate apbo(1) <= apb_none; end generate; ua1pads : if CFG_AHB_UART = 0 generate rx_pad : inpad generic map (tech => padtech, level => padlevel) port map (rx, u1i.rxd); tx_pad : outpad generic map (tech => padtech, level => padlevel) port map (tx, u1o.txd); end generate; irqctrl : if CFG_IRQ3_ENABLE /= 0 generate irqctrl0 : irqmp -- interrupt controller generic map (pindex => 2, paddr => 2, ncpu => CFG_NCPU) port map (rstn, clk, apbi, apbo(2), irqo, irqi); end generate; irq3 : if CFG_IRQ3_ENABLE = 0 generate x : for i in 0 to CFG_NCPU-1 generate irqi(i).irl <= "0000"; end generate; apbo(2) <= apb_none; end generate; gpt : if CFG_GPT_ENABLE /= 0 generate timer0 : gptimer -- timer unit generic map (pindex => 3, paddr => 3, pirq => CFG_GPT_IRQ, sepirq => CFG_GPT_SEPIRQ, sbits => CFG_GPT_SW, ntimers => CFG_GPT_NTIM, nbits => CFG_GPT_TW) port map (rstn, clk, apbi, apbo(3), gpti, open); gpti.dhalt <= dsuo.tstop; gpti.extclk <= '0'; end generate; notim : if CFG_GPT_ENABLE = 0 generate apbo(3) <= apb_none; end generate; kbd : if CFG_KBD_ENABLE /= 0 generate ps21 : apbps2 generic map(pindex => 4, paddr => 4, pirq => 4) port map(rstn, clk, apbi, apbo(4), moui, mouo); ps20 : apbps2 generic map(pindex => 5, paddr => 5, pirq => 5) port map(rstn, clk, apbi, apbo(5), kbdi, kbdo); end generate; nokbd : if CFG_KBD_ENABLE = 0 generate apbo(4) <= apb_none; mouo <= ps2o_none; apbo(5) <= apb_none; kbdo <= ps2o_none; end generate; kbdclk_pad : iopad generic map (tech => padtech) port map (kbclk,kbdo.ps2_clk_o, kbdo.ps2_clk_oe, kbdi.ps2_clk_i); kbdata_pad : iopad generic map (tech => padtech) port map (kbdata, kbdo.ps2_data_o, kbdo.ps2_data_oe, kbdi.ps2_data_i); mouclk_pad : iopad generic map (tech => padtech) port map (msclk,mouo.ps2_clk_o, mouo.ps2_clk_oe, moui.ps2_clk_i); mouata_pad : iopad generic map (tech => padtech) port map (msdata, mouo.ps2_data_o, mouo.ps2_data_oe, moui.ps2_data_i); vga : if CFG_VGA_ENABLE /= 0 generate vga0 : apbvga generic map(memtech => memtech, pindex => 6, paddr => 6) port map(rstn, clk, clk25, apbi, apbo(6), vgao); vgaclk0 : entity techmap.clkmul_virtex2 generic map (3, 8) -- 25 MHz video clock port map (rstn, clk, dac_clk, open); end generate; svga : if CFG_SVGA_ENABLE /= 0 generate svga0 : svgactrl generic map(memtech => memtech, pindex => 6, paddr => 6, hindex => CFG_NCPU+CFG_AHB_UART+CFG_AHB_JTAG, clk0 => 39722, clk1 => 0, clk2 => 0, clk3 => 0, burstlen => 5) port map(rstn, clk, clk25, apbi, apbo(6), vgao, ahbmi, ahbmo(CFG_NCPU+CFG_AHB_UART+CFG_AHB_JTAG), open); clk25 <= not dac_clk; end generate; novga : if (CFG_VGA_ENABLE = 0 and CFG_SVGA_ENABLE = 0) generate apbo(6) <= apb_none; vgao <= vgao_none; end generate; video_clk_pad : inpad generic map (tech => padtech) port map (video_clk, dac_clk); blank_pad : outpad generic map (tech => padtech) port map (blank, vgao.blank); comp_sync_pad : outpad generic map (tech => padtech) port map (comp_sync, vgao.comp_sync); vert_sync_pad : outpad generic map (tech => padtech) port map (vert_sync, vgao.vsync); horiz_sync_pad : outpad generic map (tech => padtech) port map (horiz_sync, vgao.hsync); video_out_r_pad : outpadv generic map (width => 8, tech => padtech) port map (video_out(23 downto 16), vgao.video_out_r); video_out_g_pad : outpadv generic map (width => 8, tech => padtech) port map (video_out(15 downto 8), vgao.video_out_g); video_out_b_pad : outpadv generic map (width => 8, tech => padtech) port map (video_out(7 downto 0), vgao.video_out_b); ----------------------------------------------------------------------- --- PCI ------------------------------------------------------------ ----------------------------------------------------------------------- pp : if CFG_PCI /= 0 generate pci_gr0 : if CFG_PCI = 1 generate -- simple target-only pci0 : pci_target generic map (hindex => CFG_NCPU+CFG_AHB_UART+CFG_AHB_JTAG+CFG_SVGA_ENABLE, device_id => CFG_PCIDID, vendor_id => CFG_PCIVID) port map (rstn, clk, pciclk, pcii, pcio, ahbmi, ahbmo(CFG_NCPU+CFG_AHB_UART+CFG_AHB_JTAG+CFG_SVGA_ENABLE)); end generate; pci_mtf0 : if CFG_PCI = 2 generate -- master/target with fifo pci0 : pci_mtf generic map (memtech => memtech, hmstndx => CFG_NCPU+CFG_AHB_UART+CFG_AHB_JTAG+CFG_SVGA_ENABLE, fifodepth => log2(CFG_PCIDEPTH), device_id => CFG_PCIDID, vendor_id => CFG_PCIVID, hslvndx => 4, pindex => 9, paddr => 9, haddr => 16#E00#, ioaddr => 16#400#, nsync => 2) port map (rstn, clk, pciclk, pcii, pcio, apbi, apbo(9), ahbmi, ahbmo(CFG_NCPU+CFG_AHB_UART+CFG_AHB_JTAG+CFG_SVGA_ENABLE), ahbsi, ahbso(4)); end generate; pci_mtf1 : if CFG_PCI = 3 generate -- master/target with fifo and DMA dma : pcidma generic map (memtech => memtech, dmstndx => CFG_NCPU+CFG_AHB_UART+CFG_AHB_JTAG+1+CFG_SVGA_ENABLE, dapbndx => 5, dapbaddr => 5, blength => blength, mstndx => CFG_NCPU+CFG_AHB_UART+CFG_AHB_JTAG+CFG_SVGA_ENABLE, fifodepth => log2(fifodepth), device_id => CFG_PCIDID, vendor_id => CFG_PCIVID, slvndx => 4, apbndx => 9, apbaddr => 9, haddr => 16#E00#, ioaddr => 16#800#, nsync => 1) port map (rstn, clk, pciclk, pcii, pcio, apbo(9), ahbmo(CFG_NCPU+CFG_AHB_UART+CFG_AHB_JTAG+1+CFG_SVGA_ENABLE), apbi, apbo(4), ahbmi, ahbmo(CFG_NCPU+CFG_AHB_UART+CFG_AHB_JTAG+CFG_SVGA_ENABLE), ahbsi, ahbso(4)); end generate; pci_trc0 : if CFG_PCITBUFEN /= 0 generate -- PCI trace buffer pt0 : pcitrace generic map (depth => (6 + log2(CFG_PCITBUF/256)), memtech => memtech, pindex => 8, paddr => 16#100#, pmask => 16#f00#) port map ( rstn, clk, pciclk, pcii, apbi, apbo(8)); end generate; end generate; pcipads0 : pcipads generic map (padtech => padtech, noreset => 1, host => 0)-- PCI pads port map ( pci_rst, pci_gnt, pci_idsel, pci_lock, pci_ad, pci_cbe, pci_frame, pci_irdy, pci_trdy, pci_devsel, pci_stop, pci_perr, pci_par, pci_req, pci_serr, pci_host, pci_66, pcii, pcio ); ----------------------------------------------------------------------- --- ETHERNET --------------------------------------------------------- ----------------------------------------------------------------------- eth0 : if CFG_GRETH = 1 generate -- Gaisler ethernet MAC e1 : greth generic map(hindex => CFG_NCPU+CFG_AHB_UART+CFG_PCI+CFG_AHB_JTAG+CFG_SVGA_ENABLE, pindex => 11, paddr => 11, pirq => 12, memtech => memtech, mdcscaler => CPU_FREQ/1000, enable_mdio => 1, fifosize => CFG_ETH_FIFO, nsync => 1, edcl => CFG_DSU_ETH, edclbufsz => CFG_ETH_BUF, macaddrh => CFG_ETH_ENM, macaddrl => CFG_ETH_ENL, ipaddrh => CFG_ETH_IPM, ipaddrl => CFG_ETH_IPL) port map( rst => rstn, clk => clk, ahbmi => ahbmi, ahbmo => ahbmo(CFG_NCPU+CFG_AHB_UART+CFG_PCI+CFG_AHB_JTAG+CFG_SVGA_ENABLE), apbi => apbi, apbo => apbo(11), ethi => ethi, etho => etho); end generate; ethpads : if (CFG_GRETH = 0) generate -- no eth etho <= eth_out_none; end generate; emdio_pad : iopad generic map (tech => padtech, level => padlevel) port map (phy_mdio, etho.mdio_o, etho.mdio_oe, ethi.mdio_i); etxc_pad : clkpad generic map (tech => padtech, level => padlevel, arch => 1) port map (phy_txck, ethi.tx_clk); erxc_pad : clkpad generic map (tech => padtech, level => padlevel, arch => 1) port map (phy_rxck, ethi.rx_clk); erxd_pad : inpadv generic map (tech => padtech, level => padlevel, width => 4) port map (phy_rxd, ethi.rxd(3 downto 0)); erxdv_pad : inpad generic map (tech => padtech, level => padlevel) port map (phy_rxdv, ethi.rx_dv); erxer_pad : inpad generic map (tech => padtech, level => padlevel) port map (phy_rxer, ethi.rx_er); erxco_pad : inpad generic map (tech => padtech, level => padlevel) port map (phy_col, ethi.rx_col); erxcr_pad : inpad generic map (tech => padtech, level => padlevel) port map (phy_crs, ethi.rx_crs); etxd_pad : outpadv generic map (tech => padtech, level => padlevel, width => 4) port map (phy_txd, etho.txd(3 downto 0)); etxen_pad : outpad generic map (tech => padtech, level => padlevel) port map ( phy_txen, etho.tx_en); etxer_pad : outpad generic map (tech => padtech, level => padlevel) port map (phy_txer, etho.tx_er); emdc_pad : outpad generic map (tech => padtech, level => padlevel) port map (phy_mdc, etho.mdc); phy_reset_pad : iodpad generic map (tech => padtech, level => padlevel) port map (phy_reset_l, rstn, pci_rst); can0 : if CFG_CAN = 1 generate can0 : can_oc generic map (slvndx => 6, ioaddr => CFG_CANIO, iomask => 16#FF0#, irq => CFG_CANIRQ, memtech => memtech) port map (rstn, clk, ahbsi, ahbso(6), can_lrx, can_ltx ); can_tx_pad : outpad generic map (tech => padtech) port map (can_txd, can_ltx); can_rx_pad : inpad generic map (tech => padtech) port map (can_rxd, can_lrx); end generate; ncan : if CFG_CAN = 0 generate ahbso(6) <= ahbs_none; end generate; ----------------------------------------------------------------------- --- AHB RAM ---------------------------------------------------------- ----------------------------------------------------------------------- ocram : if CFG_AHBRAMEN = 1 generate ahbram0 : ahbram generic map (hindex => 7, haddr => CFG_AHBRADDR, tech => CFG_MEMTECH, kbytes => CFG_AHBRSZ, pipe => CFG_AHBRPIPE) port map (rstn, clk, ahbsi, ahbso(7)); end generate; nram : if CFG_AHBRAMEN = 0 generate ahbso(7) <= ahbs_none; end generate; ----------------------------------------------------------------------- --- Misc ---------------------------------------------------------- ----------------------------------------------------------------------- errorn <= not dbgo(0).error; led0_pad : outpad generic map (level => padlevel, tech => padtech) port map (leds(0), errorn); led2_7_pad : outpadv generic map (level => padlevel, width => 6, tech => padtech) port map (leds(7 downto 2), gnd(5 downto 0)); disp_seg1_pad : outpadv generic map (level => padlevel, width => 8, tech => padtech) port map (disp_seg1, gnd(7 downto 0)); disp_seg2_pad : outpadv generic map (level => padlevel, width => 8, tech => padtech) port map (disp_seg2, gnd(7 downto 0)); switche_pad : inpadv generic map (tech => padtech, level => padlevel, width => 6) port map (switches, switchesl); ----------------------------------------------------------------------- --- Drive unused bus elements --------------------------------------- ----------------------------------------------------------------------- nam1 : for i in (CFG_NCPU+CFG_AHB_UART+CFG_PCI+ CFG_AHB_JTAG+CFG_GRETH+CFG_SVGA_ENABLE) to NAHBMST-1 generate ahbmo(i) <= ahbm_none; end generate; nam2 : if CFG_PCI > 1 generate ahbmo(CFG_NCPU+CFG_AHB_UART+CFG_PCI+CFG_AHB_JTAG-1+CFG_SVGA_ENABLE) <= ahbm_none; end generate; nap0 : for i in 12 to NAPBSLV-1 generate apbo(i) <= apb_none; end generate; -- nah0 : for i in 8 to NAHBSLV-1 generate ahbso(i) <= ahbs_none; end generate; ----------------------------------------------------------------------- --- Boot message ---------------------------------------------------- ----------------------------------------------------------------------- -- pragma translate_off x : report_design generic map ( msg1 => "LEON3 Avnet Spartan3-1500 Demonstration design", fabtech => tech_table(fabtech), memtech => tech_table(memtech), mdel => 1 ); -- pragma translate_on end;

gpl-2.0

ae2f0752b35c0665c97991a184f71a9f

0.582017

3.421334

false

marco-c/leon-nexys2

grlib-gpl-1.3.4-b4140/designs/leon3-terasic-de2-115/leon3mp.vhd

1

26,071

----------------------------------------------------------------------------- -- LEON3 Demonstration design -- Copyright (C) 2004 Jiri Gaisler, Gaisler Research ------------------------------------------------------------------------------ -- This file is a part of the GRLIB VHDL IP LIBRARY -- Copyright (C) 2003 - 2008, Gaisler Research -- Copyright (C) 2008 - 2013, Aeroflex Gaisler -- -- This program is free software; you can redistribute it and/or modify -- it under the terms of the GNU General Public License as published by -- the Free Software Foundation; either version 2 of the License, or -- (at your option) any later version. -- -- This program is distributed in the hope that it will be useful, -- but WITHOUT ANY WARRANTY; without even the implied warranty of -- MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the -- GNU General Public License for more details. -- -- You should have received a copy of the GNU General Public License -- along with this program; if not, write to the Free Software -- Foundation, Inc., 59 Temple Place, Suite 330, Boston, MA 02111-1307 USA ------------------------------------------------------------------------------ library ieee; use ieee.std_logic_1164.all; library grlib, techmap; use grlib.amba.all; use grlib.stdlib.all; use techmap.gencomp.all; library gaisler; use gaisler.memctrl.all; use gaisler.leon3.all; use gaisler.uart.all; use gaisler.misc.all; use gaisler.spi.all; use gaisler.can.all; use gaisler.net.all; use gaisler.jtag.all; -- pragma translate_off use gaisler.sim.all; -- pragma translate_on library esa; use esa.memoryctrl.all; use work.config.all; entity leon3mp is generic ( fabtech : integer := CFG_FABTECH; memtech : integer := CFG_MEMTECH; padtech : integer := CFG_PADTECH; clktech : integer := CFG_CLKTECH; disas : integer := CFG_DISAS; -- Enable disassembly to console dbguart : integer := CFG_DUART; -- Print UART on console pclow : integer := CFG_PCLOW ); port ( resetn : in std_logic; clock_50 : in std_logic; sma_clkout : out std_ulogic; errorn : out std_logic; fl_addr : out std_logic_vector(22 downto 0); fl_dq : inout std_logic_vector(7 downto 0); dram_addr : out std_logic_vector(12 downto 0); dram_ba : out std_logic_vector(1 downto 0); dram_dq : inout std_logic_vector(31 downto 0); dram_clk : out std_logic; dram_cke : out std_logic; dram_cs_n : out std_logic; dram_we_n : out std_logic; -- sdram write enable dram_ras_n : out std_logic; -- sdram ras dram_cas_n : out std_logic; -- sdram cas dram_dqm : out std_logic_vector (3 downto 0); -- sdram dqm uart_txd : out std_logic; -- DSU tx data uart_rxd : in std_logic; -- DSU rx data dsubre : in std_logic; dsuact : out std_logic; fl_oe_n : out std_logic; fl_we_n : out std_logic; fl_rst_n : out std_logic; fl_wp_n : out std_logic; fl_ce_n : out std_logic; -- gpio : inout std_logic_vector(CFG_GRGPIO_WIDTH-1 downto 0); -- I/O port gpio : inout std_logic_vector(35 downto 0); -- I/O port enet0_mdio : inout std_logic; -- ethernet PHY interface enet0_gtx_clk : in std_logic; enet0_rx_clk : in std_logic; enet0_tx_clk : in std_logic; enet0_rx_data: in std_logic_vector(3 downto 0); enet0_rx_dv : in std_logic; enet0_rx_er : in std_logic; enet0_rx_col : in std_logic; enet0_rx_crs : in std_logic; enet0_int_n : in std_logic; enet0_rst_n : out std_logic; enet0_tx_data: out std_logic_vector(3 downto 0); enet0_tx_en : out std_logic; enet0_tx_er : out std_logic; enet0_mdc : out std_logic; can_txd : out std_logic_vector(0 to CFG_CAN_NUM-1); can_rxd : in std_logic_vector(0 to CFG_CAN_NUM-1); can_stb : out std_logic_vector(0 to CFG_CAN_NUM-1); sw : in std_logic_vector(0 to 2) := "000" ); end; architecture rtl of leon3mp is constant blength : integer := 12; constant fifodepth : integer := 8; signal vcc, gnd : std_logic_vector(4 downto 0); signal memi : memory_in_type; signal memo : memory_out_type; signal wpo : wprot_out_type; signal sdi : sdctrl_in_type; signal sdo : sdram_out_type; signal apbi : apb_slv_in_type; signal apbo : apb_slv_out_vector := (others => apb_none); signal ahbsi : ahb_slv_in_type; signal ahbso : ahb_slv_out_vector := (others => ahbs_none); signal ahbmi : ahb_mst_in_type; signal ahbmo : ahb_mst_out_vector := (others => ahbm_none); signal clkm, rstn, rstraw, pciclk, sdclkl : std_logic; signal cgi, cgi2 : clkgen_in_type; signal cgo, cgo2 : clkgen_out_type; signal u1i, u2i, dui : uart_in_type; signal u1o, u2o, duo : uart_out_type; signal irqi : irq_in_vector(0 to CFG_NCPU-1); signal irqo : irq_out_vector(0 to CFG_NCPU-1); signal dbgi : l3_debug_in_vector(0 to CFG_NCPU-1); signal dbgo : l3_debug_out_vector(0 to CFG_NCPU-1); signal dsui : dsu_in_type; signal dsuo : dsu_out_type; signal spii, spislvi : spi_in_type; signal spio, spislvo : spi_out_type; signal slvsel : std_logic_vector(CFG_SPICTRL_SLVS-1 downto 0); signal stati : ahbstat_in_type; signal ethi, ethi1, ethi2 : eth_in_type; signal etho, etho1, etho2 : eth_out_type; signal ethclk, egtx_clk_fb : std_logic; signal egtx_clk, legtx_clk, l2egtx_clk : std_logic; signal gpti : gptimer_in_type; signal gpto : gptimer_out_type; signal gpioi : gpio_in_type; signal gpioo : gpio_out_type; signal clklock, elock : std_ulogic; signal can_lrx, can_ltx : std_logic_vector(0 to 7); signal dsubren : std_logic; signal pci_arb_req_n, pci_arb_gnt_n : std_logic_vector(0 to 3); signal tck, tms, tdi, tdo : std_logic; signal fpi : grfpu_in_vector_type; signal fpo : grfpu_out_vector_type; constant BOARD_FREQ : integer := 50000; -- Board frequency in KHz constant CPU_FREQ : integer := BOARD_FREQ * CFG_CLKMUL / CFG_CLKDIV; -- cpu frequency in KHz constant IOAEN : integer := CFG_CAN; constant CFG_SDEN : integer := CFG_MCTRL_SDEN; constant CFG_INVCLK : integer := CFG_MCTRL_INVCLK; constant OEPOL : integer := padoen_polarity(padtech); attribute syn_keep : boolean; attribute syn_preserve : boolean; attribute keep : boolean; begin ---------------------------------------------------------------------- --- Reset and Clock generation ------------------------------------- ---------------------------------------------------------------------- vcc <= (others => '1'); gnd <= (others => '0'); cgi.pllctrl <= "00"; cgi.pllrst <= rstraw; clkgen0 : clkgen -- clock generator using toplevel generic 'freq' generic map (tech => CFG_CLKTECH, clk_mul => CFG_CLKMUL, clk_div => CFG_CLKDIV, sdramen => CFG_MCTRL_SDEN, noclkfb => CFG_CLK_NOFB, freq => BOARD_FREQ, clk2xen => 1) port map (clkin => clock_50, pciclkin => gnd(0), clk => clkm, clkn => open, clk2x => sma_clkout, sdclk => sdclkl, pciclk => open, cgi => cgi, cgo => cgo); sdclk_pad : outpad generic map (tech => padtech, slew => 1) port map (dram_clk, sdclkl); rst0 : rstgen -- reset generator port map (resetn, clkm, clklock, rstn, rstraw); clklock <= cgo.clklock and elock; ---------------------------------------------------------------------- --- AHB CONTROLLER -------------------------------------------------- ---------------------------------------------------------------------- ahb0 : ahbctrl -- AHB arbiter/multiplexer generic map (defmast => CFG_DEFMST, split => CFG_SPLIT, rrobin => CFG_RROBIN, ioaddr => CFG_AHBIO, ioen => IOAEN, nahbm => CFG_NCPU+CFG_AHB_UART+CFG_AHB_JTAG+CFG_SPI2AHB+CFG_GRETH, nahbs => 8) port map (rstn, clkm, ahbmi, ahbmo, ahbsi, ahbso); ---------------------------------------------------------------------- --- LEON3 processor and DSU ----------------------------------------- ---------------------------------------------------------------------- cpu : for i in 0 to CFG_NCPU-1 generate nosh : if CFG_GRFPUSH = 0 generate u0 : leon3s -- LEON3 processor generic map (i, fabtech, memtech, CFG_NWIN, CFG_DSU, CFG_FPU*(1-CFG_GRFPUSH), CFG_V8, 0, CFG_MAC, pclow, CFG_NOTAG, CFG_NWP, CFG_ICEN, CFG_IREPL, CFG_ISETS, CFG_ILINE, CFG_ISETSZ, CFG_ILOCK, CFG_DCEN, CFG_DREPL, CFG_DSETS, CFG_DLINE, CFG_DSETSZ, CFG_DLOCK, CFG_DSNOOP, CFG_ILRAMEN, CFG_ILRAMSZ, CFG_ILRAMADDR, CFG_DLRAMEN, CFG_DLRAMSZ, CFG_DLRAMADDR, CFG_MMUEN, CFG_ITLBNUM, CFG_DTLBNUM, CFG_TLB_TYPE, CFG_TLB_REP, CFG_LDDEL, disas, CFG_ITBSZ, CFG_PWD, CFG_SVT, CFG_RSTADDR, CFG_NCPU-1, 0, 0, CFG_MMU_PAGE) port map (clkm, rstn, ahbmi, ahbmo(i), ahbsi, ahbso, irqi(i), irqo(i), dbgi(i), dbgo(i)); end generate; end generate; sh : if CFG_GRFPUSH = 1 generate cpu : for i in 0 to CFG_NCPU-1 generate u0 : leon3sh -- LEON3 processor generic map (i, fabtech, memtech, CFG_NWIN, CFG_DSU, CFG_FPU, CFG_V8, 0, CFG_MAC, pclow, CFG_NOTAG, CFG_NWP, CFG_ICEN, CFG_IREPL, CFG_ISETS, CFG_ILINE, CFG_ISETSZ, CFG_ILOCK, CFG_DCEN, CFG_DREPL, CFG_DSETS, CFG_DLINE, CFG_DSETSZ, CFG_DLOCK, CFG_DSNOOP, CFG_ILRAMEN, CFG_ILRAMSZ, CFG_ILRAMADDR, CFG_DLRAMEN, CFG_DLRAMSZ, CFG_DLRAMADDR, CFG_MMUEN, CFG_ITLBNUM, CFG_DTLBNUM, CFG_TLB_TYPE, CFG_TLB_REP, CFG_LDDEL, disas, CFG_ITBSZ, CFG_PWD, CFG_SVT, CFG_RSTADDR, CFG_NCPU-1, 0, 0, CFG_MMU_PAGE) port map (clkm, rstn, ahbmi, ahbmo(i), ahbsi, ahbso, irqi(i), irqo(i), dbgi(i), dbgo(i), fpi(i), fpo(i)); end generate; grfpush0 : grfpushwx generic map ((CFG_FPU-1), CFG_NCPU, fabtech) port map (clkm, rstn, fpi, fpo); end generate; errorn_pad : odpad generic map (tech => padtech) port map (errorn, dbgo(0).error); dsugen : if CFG_DSU = 1 generate dsu0 : dsu3 -- LEON3 Debug Support Unit generic map (hindex => 2, haddr => 16#900#, hmask => 16#F00#, ncpu => CFG_NCPU, tbits => 30, tech => memtech, irq => 0, kbytes => CFG_ATBSZ) port map (rstn, clkm, ahbmi, ahbsi, ahbso(2), dbgo, dbgi, dsui, dsuo); dsui.enable <= '1'; dsubre_pad : inpad generic map (tech => padtech) port map (dsubre, dsubren); dsui.break <= not dsubren; dsuact_pad : outpad generic map (tech => padtech) port map (dsuact, dsuo.active); end generate; nodsu : if CFG_DSU = 0 generate ahbso(2) <= ahbs_none; dsuo.tstop <= '0'; dsuo.active <= '0'; end generate; dcomgen : if CFG_AHB_UART = 1 generate dcom0: ahbuart -- Debug UART generic map (hindex => CFG_NCPU, pindex => 7, paddr => 7) port map (rstn, clkm, dui, duo, apbi, apbo(7), ahbmi, ahbmo(CFG_NCPU)); -- dsurx_pad : inpad generic map (tech => padtech) port map (dsurx, dui.rxd); dui.rxd <= uart_rxd when sw(0) = '0' else '1'; -- dsutx_pad : outpad generic map (tech => padtech) port map (dsutx, duo.txd); end generate; -- nouah : if CFG_AHB_UART = 0 generate apbo(7) <= apb_none; end generate; ahbjtaggen0 :if CFG_AHB_JTAG = 1 generate ahbjtag0 : ahbjtag generic map(tech => fabtech, hindex => CFG_NCPU+CFG_AHB_UART) port map(rstn, clkm, tck, tms, tdi, tdo, ahbmi, ahbmo(CFG_NCPU+CFG_AHB_UART), open, open, open, open, open, open, open, gnd(0)); end generate; ---------------------------------------------------------------------- --- Memory controllers ---------------------------------------------- ---------------------------------------------------------------------- memi.edac <= '0'; memi.bwidth <= "00"; mctrl0 : if CFG_MCTRL_LEON2 = 1 generate -- LEON2 memory controller sr1 : mctrl generic map (hindex => 0, pindex => 0, paddr => 0, srbanks => 4, sden => CFG_MCTRL_SDEN, ram8 => CFG_MCTRL_RAM8BIT, ram16 => CFG_MCTRL_RAM16BIT, invclk => CFG_MCTRL_INVCLK, sepbus => CFG_MCTRL_SEPBUS, oepol => OEPOL, iomask => 0, sdbits => 32 + 32*CFG_MCTRL_SD64, pageburst => CFG_MCTRL_PAGE) port map (rstn, clkm, memi, memo, ahbsi, ahbso(0), apbi, apbo(0), wpo, sdo); addr_pad : outpadv generic map (width => 23, tech => padtech) port map (fl_addr, memo.address(22 downto 0)); roms_pad : outpad generic map (tech => padtech) port map (fl_ce_n, memo.romsn(0)); oen_pad : outpad generic map (tech => padtech) port map (fl_oe_n, memo.oen); wri_pad : outpad generic map (tech => padtech) port map (fl_we_n, memo.writen); fl_rst_pad : outpad generic map (tech => padtech) port map (fl_rst_n, rstn); fl_wp_pad : outpad generic map (tech => padtech) port map (fl_wp_n, vcc(0)); data_pad : iopadvv generic map (tech => padtech, width => 8, oepol => OEPOL) port map (fl_dq, memo.data(31 downto 24), memo.vbdrive(31 downto 24), memi.data(31 downto 24)); memi.brdyn <= '1'; memi.bexcn <= '1'; memi.writen <= '1'; memi.wrn <= "1111"; sdpads : if CFG_MCTRL_SDEN = 1 generate -- SDRAM controller sd2 : if CFG_MCTRL_SEPBUS = 1 generate sa_pad : outpadv generic map (width => 13) port map (dram_addr, memo.sa(12 downto 0)); ba_pad : outpadv generic map (width => 2) port map (dram_ba, memo.sa(14 downto 13)); sd_pad : iopadvv generic map (tech => padtech, width => 32, oepol => OEPOL) port map (dram_dq(31 downto 0), memo.sddata(31 downto 0), memo.svbdrive(31 downto 0), memi.sd(31 downto 0)); end generate; sdwen_pad : outpad generic map (tech => padtech) port map (dram_we_n, sdo.sdwen); sdras_pad : outpad generic map (tech => padtech) port map (dram_ras_n, sdo.rasn); sdcas_pad : outpad generic map (tech => padtech) port map (dram_cas_n, sdo.casn); sddqm_pad : outpadv generic map (width => 4, tech => padtech) port map (dram_dqm, sdo.dqm(3 downto 0)); sdcke_pad : outpad generic map (tech => padtech) port map (dram_cke, sdo.sdcke(0)); sdcsn_pad : outpad generic map (tech => padtech) port map (dram_cs_n, sdo.sdcsn(0)); end generate; end generate; nosd0 : if (CFG_SDEN = 0) generate -- no SDRAM controller sdcke_pad : outpad generic map (tech => padtech) port map (dram_cke, vcc(0)); sdcsn_pad : outpad generic map (tech => padtech) port map (dram_cs_n, vcc(0)); end generate; mg0 : if CFG_MCTRL_LEON2 = 0 generate -- No PROM/SRAM controller apbo(0) <= apb_none; ahbso(0) <= ahbs_none; roms_pad : outpad generic map (tech => padtech) port map (fl_ce_n, vcc(0)); end generate; ---------------------------------------------------------------------- --- APB Bridge and various periherals ------------------------------- ---------------------------------------------------------------------- apb0 : apbctrl -- AHB/APB bridge generic map (hindex => 1, haddr => CFG_APBADDR) port map (rstn, clkm, ahbsi, ahbso(1), apbi, apbo ); ua1 : if CFG_UART1_ENABLE /= 0 generate uart1 : apbuart -- UART 1 generic map (pindex => 1, paddr => 1, pirq => 2, console => dbguart, fifosize => CFG_UART1_FIFO) port map (rstn, clkm, apbi, apbo(1), u1i, u1o); u1i.rxd <= '1' when sw(0) = '0' else uart_rxd; u1i.ctsn <= '0'; u1i.extclk <= '0'; end generate; uart_txd <= u1o.txd when sw(0) = '1' else duo.txd; noua0 : if CFG_UART1_ENABLE = 0 generate apbo(1) <= apb_none; end generate; irqctrl : if CFG_IRQ3_ENABLE /= 0 generate irqctrl0 : irqmp -- interrupt controller generic map (pindex => 2, paddr => 2, ncpu => CFG_NCPU) port map (rstn, clkm, apbi, apbo(2), irqo, irqi); end generate; irq3 : if CFG_IRQ3_ENABLE = 0 generate x : for i in 0 to CFG_NCPU-1 generate irqi(i).irl <= "0000"; end generate; -- apbo(2) <= apb_none; end generate; gpt : if CFG_GPT_ENABLE /= 0 generate timer0 : gptimer -- timer unit generic map (pindex => 3, paddr => 3, pirq => CFG_GPT_IRQ, sepirq => CFG_GPT_SEPIRQ, sbits => CFG_GPT_SW, ntimers => CFG_GPT_NTIM, nbits => CFG_GPT_TW) port map (rstn, clkm, apbi, apbo(3), gpti, open); gpti.dhalt <= dsuo.tstop; gpti.extclk <= '0'; end generate; -- notim : if CFG_GPT_ENABLE = 0 generate apbo(3) <= apb_none; end generate; gpio0 : if CFG_GRGPIO_ENABLE /= 0 generate -- GR GPIO unit grgpio0: grgpio generic map( pindex => 9, paddr => 9, imask => CFG_GRGPIO_IMASK, nbits => CFG_GRGPIO_WIDTH) port map( rstn, clkm, apbi, apbo(9), gpioi, gpioo); pio_pads : for i in 0 to CFG_GRGPIO_WIDTH-1 generate pio_pad : iopad generic map (tech => padtech) port map (gpio(i), gpioo.dout(i), gpioo.oen(i), gpioi.din(i)); end generate; end generate; spic: if CFG_SPICTRL_ENABLE = 1 generate -- SPI controller spi1 : spictrl generic map (pindex => 10, paddr => 10, pmask => 16#fff#, pirq => 10, fdepth => CFG_SPICTRL_FIFO, slvselen => CFG_SPICTRL_SLVREG, slvselsz => CFG_SPICTRL_SLVS, odmode => 0, netlist => 0, syncram => CFG_SPICTRL_SYNCRAM, ft => CFG_SPICTRL_FT) port map (rstn, clkm, apbi, apbo(10), spii, spio, slvsel); spii.spisel <= '1'; -- Master only miso_pad : iopad generic map (tech => padtech) port map (gpio(35), spio.miso, spio.misooen, spii.miso); mosi_pad : iopad generic map (tech => padtech) port map (gpio(34), spio.mosi, spio.mosioen, spii.mosi); sck_pad : iopad generic map (tech => padtech) port map (gpio(33), spio.sck, spio.sckoen, spii.sck); slvsel_pad : iopad generic map (tech => padtech) port map (gpio(32), slvsel(0), gnd(0), open); end generate spic; spibridge : if CFG_SPI2AHB /= 0 generate -- SPI to AHB bridge withapb : if CFG_SPI2AHB_APB /= 0 generate spi2ahb0 : spi2ahb_apb generic map(hindex => CFG_NCPU+CFG_AHB_UART+CFG_AHB_JTAG, ahbaddrh => CFG_SPI2AHB_ADDRH, ahbaddrl => CFG_SPI2AHB_ADDRL, ahbmaskh => CFG_SPI2AHB_MASKH, ahbmaskl => CFG_SPI2AHB_MASKL, resen => CFG_SPI2AHB_RESEN, pindex => 11, paddr => 11, pmask => 16#fff#, pirq => 11, filter => CFG_SPI2AHB_FILTER, cpol => CFG_SPI2AHB_CPOL, cpha => CFG_SPI2AHB_CPHA) port map (rstn, clkm, ahbmi, ahbmo(CFG_NCPU+CFG_AHB_UART+CFG_AHB_JTAG), apbi, apbo(11), spislvi, spislvo); end generate; woapb : if CFG_SPI2AHB_APB = 0 generate spi2ahb0 : spi2ahb generic map(hindex => CFG_NCPU+CFG_AHB_UART+CFG_AHB_JTAG, ahbaddrh => CFG_SPI2AHB_ADDRH, ahbaddrl => CFG_SPI2AHB_ADDRL, ahbmaskh => CFG_SPI2AHB_MASKH, ahbmaskl => CFG_SPI2AHB_MASKL, filter => CFG_SPI2AHB_FILTER, cpol => CFG_SPI2AHB_CPOL, cpha => CFG_SPI2AHB_CPHA) port map (rstn, clkm, ahbmi, ahbmo(CFG_NCPU+CFG_AHB_UART+CFG_AHB_JTAG), spislvi, spislvo); end generate; spislv_miso_pad : iopad generic map (tech => padtech) port map (gpio(31), spislvo.miso, spislvo.misooen, spislvi.miso); spislvl_mosi_pad : iopad generic map (tech => padtech) port map (gpio(30), spislvo.mosi, spislvo.mosioen, spislvi.mosi); spislv_sck_pad : iopad generic map (tech => padtech) port map (gpio(29), spislvo.sck, spislvo.sckoen, spislvi.sck); spislv_slvsel_pad : iopad generic map (tech => padtech) port map (gpio(28), gnd(0), vcc(0), spislvi.spisel); end generate; nospibridge : if CFG_SPI2AHB = 0 or CFG_SPI2AHB_APB = 0 generate apbo(11) <= apb_none; end generate; ahbs : if CFG_AHBSTAT = 1 generate -- AHB status register stati.cerror(0) <= memo.ce; ahbstat0 : ahbstat generic map (pindex => 15, paddr => 15, pirq => 1, nftslv => CFG_AHBSTATN) port map (rstn, clkm, ahbmi, ahbsi, stati, apbi, apbo(15)); end generate; nop2 : if CFG_AHBSTAT = 0 generate apbo(15) <= apb_none; end generate; ----------------------------------------------------------------------- --- ETHERNET --------------------------------------------------------- ----------------------------------------------------------------------- eth1 : if CFG_GRETH = 1 generate -- Gaisler ethernet MAC e1 : grethm generic map( hindex => CFG_NCPU+CFG_AHB_UART+CFG_AHB_JTAG+CFG_SPI2AHB, pindex => 14, paddr => 14, pirq => 12, memtech => memtech, mdcscaler => CPU_FREQ/1000, enable_mdio => 1, fifosize => CFG_ETH_FIFO, nsync => 1, edcl => CFG_DSU_ETH, edclbufsz => CFG_ETH_BUF, macaddrh => CFG_ETH_ENM, macaddrl => CFG_ETH_ENL, phyrstadr => 16, ipaddrh => CFG_ETH_IPM, ipaddrl => CFG_ETH_IPL, giga => CFG_GRETH1G, enable_mdint => 1) port map( rst => rstn, clk => clkm, ahbmi => ahbmi, ahbmo => ahbmo(CFG_NCPU+CFG_AHB_UART+CFG_AHB_JTAG+CFG_SPI2AHB), apbi => apbi, apbo => apbo(14), ethi => ethi, etho => etho); greth1g: if CFG_GRETH1G = 1 generate eth_macclk_pad : clkpad generic map (tech => padtech, arch => 3, hf => 1) port map (enet0_gtx_clk, egtx_clk, cgo.clklock, elock); end generate greth1g; emdio_pad : iopad generic map (tech => padtech) port map (enet0_mdio, etho.mdio_o, etho.mdio_oe, ethi.mdio_i); etxc_pad : clkpad generic map (tech => padtech, arch => 2) port map (enet0_tx_clk, ethi.tx_clk); erxc_pad : clkpad generic map (tech => padtech, arch => 2) port map (enet0_rx_clk, ethi.rx_clk); erxd_pad : inpadv generic map (tech => padtech, width => 4) port map (enet0_rx_data, ethi.rxd(3 downto 0)); erxdv_pad : inpad generic map (tech => padtech) port map (enet0_rx_dv, ethi.rx_dv); erxer_pad : inpad generic map (tech => padtech) port map (enet0_rx_er, ethi.rx_er); erxco_pad : inpad generic map (tech => padtech) port map (enet0_rx_col, ethi.rx_col); erxcr_pad : inpad generic map (tech => padtech) port map (enet0_rx_crs, ethi.rx_crs); emdintn_pad : inpad generic map (tech => padtech) port map (enet0_int_n, ethi.mdint); etxd_pad : outpadv generic map (tech => padtech, width => 4) port map (enet0_tx_data, etho.txd(3 downto 0)); etxen_pad : outpad generic map (tech => padtech) port map (enet0_tx_en, etho.tx_en); etxer_pad : outpad generic map (tech => padtech) port map (enet0_tx_er, etho.tx_er); emdc_pad : outpad generic map (tech => padtech) port map (enet0_mdc, etho.mdc); eth0_rst_pad : odpad generic map (tech => padtech) port map (enet0_rst_n, rstn); -- emdis_pad : outpad generic map (tech => padtech) -- port map (emddis, vcc(0)); -- eepwrdwn_pad : outpad generic map (tech => padtech) -- port map (epwrdwn, gnd(0)); -- esleep_pad : outpad generic map (tech => padtech) -- port map (esleep, gnd(0)); -- epause_pad : outpad generic map (tech => padtech) -- port map (epause, gnd(0)); -- ereset_pad : outpad generic map (tech => padtech) -- port map (ereset, gnd(0)); ethi.gtx_clk <= egtx_clk; end generate; noeth: if CFG_GRETH = 0 or CFG_GRETH1G = 0 generate elock <= '1'; end generate noeth; ----------------------------------------------------------------------- --- CAN -------------------------------------------------------------- ----------------------------------------------------------------------- can0 : if CFG_CAN = 1 generate can0 : can_mc generic map (slvndx => 6, ioaddr => CFG_CANIO, iomask => 16#FF0#, irq => CFG_CANIRQ, memtech => memtech, ncores => CFG_CAN_NUM, sepirq => CFG_CANSEPIRQ) port map (rstn, clkm, ahbsi, ahbso(6), can_lrx, can_ltx ); can_pads : for i in 0 to CFG_CAN_NUM-1 generate can_tx_pad : outpad generic map (tech => padtech) port map (can_txd(i), can_ltx(i)); can_rx_pad : inpad generic map (tech => padtech) port map (can_rxd(i), can_lrx(i)); end generate; end generate; -- can_stb <= '0'; -- no standby ncan : if CFG_CAN = 0 generate ahbso(6) <= ahbs_none; end generate; ----------------------------------------------------------------------- --- AHB RAM ---------------------------------------------------------- ----------------------------------------------------------------------- -- ocram : if CFG_AHBRAMEN = 1 generate -- ahbram0 : ftahbram generic map (hindex => 7, haddr => CFG_AHBRADDR, -- tech => CFG_MEMTECH, kbytes => CFG_AHBRSZ, pindex => 6, -- paddr => 6, edacen => CFG_AHBRAEDAC, autoscrub => CFG_AHBRASCRU, -- errcnten => CFG_AHBRAECNT, cntbits => CFG_AHBRAEBIT) -- port map ( rstn, clkm, ahbsi, ahbso(7), apbi, apbo(6), open); -- end generate; -- -- nram : if CFG_AHBRAMEN = 0 generate ahbso(7) <= ahbs_none; end generate; ----------------------------------------------------------------------- --- Drive unused bus elements --------------------------------------- ----------------------------------------------------------------------- -- nam1 : for i in (CFG_NCPU+CFG_AHB_UART+log2x(CFG_PCI)+CFG_AHB_JTAG) to NAHBMST-1 generate -- ahbmo(i) <= ahbm_none; -- end generate; -- nam2 : if CFG_PCI > 1 generate -- ahbmo(CFG_NCPU+CFG_AHB_UART+CFG_AHB_JTAG+log2x(CFG_PCI)-1) <= ahbm_none; -- end generate; -- nap0 : for i in 11 to NAPBSLV-1 generate apbo(i) <= apb_none; end generate; -- apbo(6) <= apb_none; ----------------------------------------------------------------------- --- Test report module ---------------------------------------------- ----------------------------------------------------------------------- -- pragma translate_off test0 : ahbrep generic map (hindex => 7, haddr => 16#200#) port map (rstn, clkm, ahbsi, ahbso(7)); -- pragma translate_on ----------------------------------------------------------------------- --- Boot message ---------------------------------------------------- ----------------------------------------------------------------------- -- pragma translate_off x : report_design generic map ( msg1 => "LEON3 TerAsic DE2_115 Demonstration design", fabtech => tech_table(fabtech), memtech => tech_table(memtech), mdel => 1 ); -- pragma translate_on end;

gpl-2.0

e81010a8f1a28a3cd8e3a6a467d9191a

0.56933

3.459528

false

marco-c/leon-nexys2

grlib-gpl-1.3.4-b4140/designs/leon3-gr-xc3s-1500/testbench.vhd

1

16,236

----------------------------------------------------------------------------- -- LEON3 Demonstration design test bench -- Copyright (C) 2004 Jiri Gaisler, Gaisler Research ------------------------------------------------------------------------------ -- This file is a part of the GRLIB VHDL IP LIBRARY -- Copyright (C) 2003 - 2008, Gaisler Research -- Copyright (C) 2008 - 2013, Aeroflex Gaisler -- -- This program is free software; you can redistribute it and/or modify -- it under the terms of the GNU General Public License as published by -- the Free Software Foundation; either version 2 of the License, or -- (at your option) any later version. -- -- This program is distributed in the hope that it will be useful, -- but WITHOUT ANY WARRANTY; without even the implied warranty of -- MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the -- GNU General Public License for more details. -- -- You should have received a copy of the GNU General Public License -- along with this program; if not, write to the Free Software -- Foundation, Inc., 59 Temple Place, Suite 330, Boston, MA 02111-1307 USA ------------------------------------------------------------------------------ library ieee; use ieee.std_logic_1164.all; library gaisler; use gaisler.libdcom.all; use gaisler.sim.all; library techmap; use techmap.gencomp.all; library micron; use micron.components.all; use work.debug.all; use work.config.all; -- configuration entity testbench is generic ( fabtech : integer := CFG_FABTECH; memtech : integer := CFG_MEMTECH; padtech : integer := CFG_PADTECH; clktech : integer := CFG_CLKTECH; disas : integer := CFG_DISAS; -- Enable disassembly to console dbguart : integer := CFG_DUART; -- Print UART on console pclow : integer := CFG_PCLOW; clkperiod : integer := 20; -- system clock period romwidth : integer := 32; -- rom data width (8/32) romdepth : integer := 16; -- rom address depth sramwidth : integer := 32; -- ram data width (8/16/32) sramdepth : integer := 18; -- ram address depth srambanks : integer := 2 -- number of ram banks ); end; architecture behav of testbench is constant promfile : string := "prom.srec"; -- rom contents constant sramfile : string := "ram.srec"; -- ram contents constant sdramfile : string := "ram.srec"; -- sdram contents component leon3mp generic ( fabtech : integer := CFG_FABTECH; memtech : integer := CFG_MEMTECH; padtech : integer := CFG_PADTECH; clktech : integer := CFG_CLKTECH; disas : integer := CFG_DISAS; -- Enable disassembly to console dbguart : integer := CFG_DUART; -- Print UART on console pclow : integer := CFG_PCLOW ); port ( resetn : in std_ulogic; clk : in std_ulogic; clk3 : in std_ulogic; pllref : in std_ulogic; errorn : out std_ulogic; wdogn : out std_ulogic; address : out std_logic_vector(27 downto 0); data : inout std_logic_vector(31 downto 0); ramsn : out std_logic_vector (4 downto 0); ramoen : out std_logic_vector (4 downto 0); rwen : out std_logic_vector (3 downto 0); oen : out std_ulogic; writen : out std_ulogic; read : out std_ulogic; iosn : out std_ulogic; bexcn : in std_ulogic; -- DSU rx data brdyn : in std_ulogic; -- DSU rx data romsn : out std_logic_vector (1 downto 0); sdclk : out std_ulogic; sdcsn : out std_logic_vector (1 downto 0); -- sdram chip select sdwen : out std_ulogic; -- sdram write enable sdrasn : out std_ulogic; -- sdram ras sdcasn : out std_ulogic; -- sdram cas sddqm : out std_logic_vector (3 downto 0); -- sdram dqm dsuen : in std_ulogic; dsubre : in std_ulogic; dsuact : out std_ulogic; txd1 : out std_ulogic; -- UART1 tx data rxd1 : in std_ulogic; -- UART1 rx data ctsn1 : in std_ulogic; -- UART1 rx data rtsn1 : out std_ulogic; -- UART1 rx data txd2 : out std_ulogic; -- UART2 tx data rxd2 : in std_ulogic; -- UART2 rx data ctsn2 : in std_ulogic; -- UART1 rx data rtsn2 : out std_ulogic; -- UART1 rx data pio : inout std_logic_vector(17 downto 0); -- I/O port emdio : inout std_logic; -- ethernet PHY interface etx_clk : in std_ulogic; erx_clk : in std_ulogic; erxd : in std_logic_vector(3 downto 0); erx_dv : in std_ulogic; erx_er : in std_ulogic; erx_col : in std_ulogic; erx_crs : in std_ulogic; emdint : in std_ulogic; etxd : out std_logic_vector(3 downto 0); etx_en : out std_ulogic; etx_er : out std_ulogic; emdc : out std_ulogic; ps2clk : inout std_logic_vector(1 downto 0); ps2data : inout std_logic_vector(1 downto 0); vid_clock : out std_ulogic; vid_blankn : out std_ulogic; vid_syncn : out std_ulogic; vid_hsync : out std_ulogic; vid_vsync : out std_ulogic; vid_r : out std_logic_vector(7 downto 0); vid_g : out std_logic_vector(7 downto 0); vid_b : out std_logic_vector(7 downto 0); spw_clk : in std_ulogic; spw_rxdp : in std_logic_vector(0 to CFG_SPW_NUM-1); spw_rxdn : in std_logic_vector(0 to CFG_SPW_NUM-1); spw_rxsp : in std_logic_vector(0 to CFG_SPW_NUM-1); spw_rxsn : in std_logic_vector(0 to CFG_SPW_NUM-1); spw_txdp : out std_logic_vector(0 to CFG_SPW_NUM-1); spw_txdn : out std_logic_vector(0 to CFG_SPW_NUM-1); spw_txsp : out std_logic_vector(0 to CFG_SPW_NUM-1); spw_txsn : out std_logic_vector(0 to CFG_SPW_NUM-1); usb_clkout : in std_ulogic; usb_d : inout std_logic_vector(15 downto 0); usb_linestate : in std_logic_vector(1 downto 0); usb_opmode : out std_logic_vector(1 downto 0); usb_reset : out std_ulogic; usb_rxactive : in std_ulogic; usb_rxerror : in std_ulogic; usb_rxvalid : in std_ulogic; usb_suspend : out std_ulogic; usb_termsel : out std_ulogic; usb_txready : in std_ulogic; usb_txvalid : out std_ulogic; usb_validh : inout std_ulogic; usb_xcvrsel : out std_ulogic; usb_vbus : in std_ulogic ); end component; signal clk : std_logic := '0'; signal Rst : std_logic := '0'; -- Reset constant ct : integer := clkperiod/2; signal address : std_logic_vector(27 downto 0); signal data : std_logic_vector(31 downto 0); signal pio : std_logic_vector(17 downto 0); signal romsn : std_logic_vector(1 downto 0); signal ramsn : std_logic_vector(4 downto 0); signal ramoen : std_logic_vector(4 downto 0); signal rwen : std_logic_vector(3 downto 0); signal oen : std_ulogic; signal writen : std_ulogic; signal read : std_ulogic; signal iosn : std_ulogic; signal bexcn : std_ulogic; signal brdyn : std_ulogic; signal dsuen, dsutx, dsurx, dsubre, dsuact : std_ulogic; signal dsurst : std_ulogic; signal GND : std_ulogic := '0'; signal VCC : std_ulogic := '1'; signal NC : std_ulogic := 'Z'; signal clk2 : std_ulogic := '1'; signal wdogn : std_logic; signal sdcke : std_ulogic; -- clk en signal sdcsn : std_logic_vector ( 1 downto 0); signal sdwen : std_ulogic; -- write en signal sdrasn : std_ulogic; -- row addr stb signal sdcasn : std_ulogic; -- col addr stb signal sddqm : std_logic_vector ( 3 downto 0); -- data i/o mask signal sdclk : std_ulogic; signal pllref : std_ulogic; signal txd1, rxd1 : std_logic; signal txd2, rxd2 : std_logic; signal ctsn1, rtsn1 : std_ulogic; signal ctsn2, rtsn2 : std_ulogic; signal errorn : std_logic; signal etx_clk, erx_clk, erx_dv, erx_er, erx_col, erx_crs, etx_en, etx_er : std_logic:='0'; signal erxd, etxd: std_logic_vector(3 downto 0):=(others=>'0'); signal erxdt, etxdt : std_logic_vector(7 downto 0); signal emdc, emdio: std_logic; --dummy signal for the mdc,mdio in the phy which is not used signal eth_macclk : std_ulogic := '0'; signal emdint : std_ulogic; signal ps2clk : std_logic_vector(1 downto 0); signal ps2data : std_logic_vector(1 downto 0); signal vid_clock : std_ulogic; signal vid_blankn : std_ulogic; signal vid_syncn : std_ulogic; signal vid_hsync : std_ulogic; signal vid_vsync : std_ulogic; signal vid_r : std_logic_vector(7 downto 0); signal vid_g : std_logic_vector(7 downto 0); signal vid_b : std_logic_vector(7 downto 0); signal clk3 : std_ulogic := '0'; signal spw_clk : std_ulogic := '0'; signal spw_rxdp : std_logic_vector(0 to CFG_SPW_NUM-1) := (others => '0'); signal spw_rxdn : std_logic_vector(0 to CFG_SPW_NUM-1) := (others => '0'); signal spw_rxsp : std_logic_vector(0 to CFG_SPW_NUM-1) := (others => '0'); signal spw_rxsn : std_logic_vector(0 to CFG_SPW_NUM-1) := (others => '0'); signal spw_txdp : std_logic_vector(0 to CFG_SPW_NUM-1); signal spw_txdn : std_logic_vector(0 to CFG_SPW_NUM-1); signal spw_txsp : std_logic_vector(0 to CFG_SPW_NUM-1); signal spw_txsn : std_logic_vector(0 to CFG_SPW_NUM-1); signal usb_clkout : std_ulogic := '0'; signal usb_d : std_logic_vector(15 downto 0); signal usb_linestate : std_logic_vector(1 downto 0); signal usb_opmode : std_logic_vector(1 downto 0); signal usb_reset : std_ulogic; signal usb_rxactive : std_ulogic; signal usb_rxerror : std_ulogic; signal usb_rxvalid : std_ulogic; signal usb_suspend : std_ulogic; signal usb_termsel : std_ulogic; signal usb_txready : std_ulogic; signal usb_txvalid : std_ulogic; signal usb_validh : std_logic; signal usb_xcvrsel : std_ulogic; signal usb_vbus : std_ulogic; signal rhvalid : std_ulogic; constant lresp : boolean := false; begin -- clock and reset clk <= not clk after ct * 1 ns; clk3 <= not clk3 after 20 ns; rst <= dsurst and wdogn; dsuen <= '1'; dsubre <= '0'; rxd1 <= 'H'; ctsn1 <= '0'; rxd2 <= 'H'; ctsn2 <= '0'; pllref <= sdclk; ps2clk <= "HH"; ps2data <= "HH"; pio(4) <= pio(5); pio(1) <= pio(2); pio <= (others => 'H'); wdogn <= 'H'; usb_clkout <= not usb_clkout after 8.33 ns; -- ~60MHz spw_rxdp <= spw_txdp; spw_rxdn <= spw_txdn; spw_rxsp <= spw_txsp; spw_rxsn <= spw_txsn; cpu : leon3mp generic map ( fabtech, memtech, padtech, clktech, disas, dbguart, pclow ) port map (rst, clk, clk3, pllref, errorn, wdogn, address(27 downto 0), data, ramsn, ramoen, rwen, oen, writen, read, iosn, bexcn, brdyn, romsn, sdclk, sdcsn, sdwen, sdrasn, sdcasn, sddqm, dsuen, dsubre, dsuact, txd1, rxd1, ctsn1, rtsn1, txd2, rxd2, ctsn2, rtsn2, pio, emdio, etx_clk, erx_clk, erxd, erx_dv, erx_er, erx_col, erx_crs, emdint, etxd, etx_en, etx_er, emdc, ps2clk, ps2data, vid_clock, vid_blankn, vid_syncn, vid_hsync, vid_vsync, vid_r, vid_g, vid_b, spw_clk, spw_rxdp, spw_rxdn, spw_rxsp, spw_rxsn, spw_txdp, spw_txdn, spw_txsp, spw_txsn, usb_clkout, usb_d, usb_linestate, usb_opmode, usb_reset, usb_rxactive, usb_rxerror, usb_rxvalid, usb_suspend, usb_termsel, usb_txready, usb_txvalid, usb_validh, usb_xcvrsel, usb_vbus ); u0: mt48lc16m16a2 generic map (index => 0, fname => sdramfile) PORT MAP( Dq => data(31 downto 16), Addr => address(14 downto 2), Ba => address(16 downto 15), Clk => sdclk, Cke => vcc, Cs_n => sdcsn(0), Ras_n => sdrasn, Cas_n => sdcasn, We_n => sdwen, Dqm => sddqm(3 downto 2)); u1: mt48lc16m16a2 generic map (index => 16, fname => sdramfile) PORT MAP( Dq => data(15 downto 0), Addr => address(14 downto 2), Ba => address(16 downto 15), Clk => sdclk, Cke => vcc, Cs_n => sdcsn(0), Ras_n => sdrasn, Cas_n => sdcasn, We_n => sdwen, Dqm => sddqm(1 downto 0)); prom0 : sram generic map (index => 6, abits => romdepth, fname => promfile) port map (address(romdepth-1 downto 0), data(31 downto 24), romsn(0), writen, oen); phy0 : if (CFG_GRETH = 1) generate emdio <= 'H'; erxd <= erxdt(3 downto 0); etxdt <= "0000" & etxd; p0: phy generic map(base1000_t_fd => 0, base1000_t_hd => 0) port map(rst, emdio, etx_clk, erx_clk, erxdt, erx_dv, erx_er, erx_col, erx_crs, etxdt, etx_en, etx_er, emdc, eth_macclk); end generate; ps2devs: for i in 0 to 1 generate ps2_device(ps2clk(i), ps2data(i)); end generate ps2devs; errorn <= 'H'; -- ERROR pull-up iuerr : process begin wait for 5000 ns; if to_x01(errorn) = '1' then wait on errorn; end if; assert (to_x01(errorn) = '1') report "*** IU in error mode, simulation halted ***" severity failure ; end process; test0 : grtestmod port map ( rst, clk, errorn, address(21 downto 2), data, iosn, oen, writen, brdyn); data <= buskeep(data) after 5 ns; dsucom : process procedure dsucfg(signal dsurx : in std_ulogic; signal dsutx : out std_ulogic) is variable w32 : std_logic_vector(31 downto 0); variable c8 : std_logic_vector(7 downto 0); constant txp : time := 320 * 1 ns; begin dsutx <= '1'; dsurst <= '0'; wait for 2500 ns; dsurst <= '1'; wait; wait for 5000 ns; txc(dsutx, 16#55#, txp); -- sync uart txc(dsutx, 16#c0#, txp); txa(dsutx, 16#90#, 16#00#, 16#00#, 16#00#, txp); txa(dsutx, 16#00#, 16#00#, 16#20#, 16#2e#, txp); wait for 25000 ns; txc(dsutx, 16#c0#, txp); txa(dsutx, 16#90#, 16#00#, 16#00#, 16#20#, txp); txa(dsutx, 16#00#, 16#00#, 16#00#, 16#01#, txp); txc(dsutx, 16#c0#, txp); txa(dsutx, 16#90#, 16#40#, 16#00#, 16#24#, txp); txa(dsutx, 16#00#, 16#00#, 16#00#, 16#0D#, txp); txc(dsutx, 16#c0#, txp); txa(dsutx, 16#90#, 16#70#, 16#11#, 16#78#, txp); txa(dsutx, 16#91#, 16#00#, 16#00#, 16#0D#, txp); txa(dsutx, 16#90#, 16#40#, 16#00#, 16#44#, txp); txa(dsutx, 16#00#, 16#00#, 16#20#, 16#00#, txp); txc(dsutx, 16#80#, txp); txa(dsutx, 16#90#, 16#40#, 16#00#, 16#44#, txp); wait; txc(dsutx, 16#c0#, txp); txa(dsutx, 16#00#, 16#00#, 16#0a#, 16#aa#, txp); txa(dsutx, 16#00#, 16#55#, 16#00#, 16#55#, txp); txc(dsutx, 16#c0#, txp); txa(dsutx, 16#00#, 16#00#, 16#0a#, 16#a0#, txp); txa(dsutx, 16#01#, 16#02#, 16#09#, 16#33#, txp); txc(dsutx, 16#c0#, txp); txa(dsutx, 16#90#, 16#00#, 16#00#, 16#00#, txp); txa(dsutx, 16#00#, 16#00#, 16#00#, 16#2e#, txp); txc(dsutx, 16#c0#, txp); txa(dsutx, 16#91#, 16#00#, 16#00#, 16#00#, txp); txa(dsutx, 16#00#, 16#00#, 16#00#, 16#2e#, txp); txc(dsutx, 16#c0#, txp); txa(dsutx, 16#90#, 16#00#, 16#00#, 16#20#, txp); txa(dsutx, 16#00#, 16#00#, 16#00#, 16#0f#, txp); txc(dsutx, 16#c0#, txp); txa(dsutx, 16#90#, 16#00#, 16#00#, 16#20#, txp); txa(dsutx, 16#00#, 16#00#, 16#00#, 16#00#, txp); txc(dsutx, 16#c0#, txp); txa(dsutx, 16#80#, 16#00#, 16#02#, 16#10#, txp); txa(dsutx, 16#00#, 16#00#, 16#00#, 16#0f#, txp); txc(dsutx, 16#c0#, txp); txa(dsutx, 16#91#, 16#40#, 16#00#, 16#24#, txp); txa(dsutx, 16#00#, 16#00#, 16#00#, 16#24#, txp); txc(dsutx, 16#c0#, txp); txa(dsutx, 16#91#, 16#70#, 16#00#, 16#00#, txp); txa(dsutx, 16#00#, 16#00#, 16#00#, 16#03#, txp); txc(dsutx, 16#c0#, txp); txa(dsutx, 16#90#, 16#00#, 16#00#, 16#20#, txp); txa(dsutx, 16#00#, 16#00#, 16#ff#, 16#ff#, txp); txc(dsutx, 16#c0#, txp); txa(dsutx, 16#90#, 16#40#, 16#00#, 16#48#, txp); txa(dsutx, 16#00#, 16#00#, 16#00#, 16#12#, txp); txc(dsutx, 16#c0#, txp); txa(dsutx, 16#90#, 16#40#, 16#00#, 16#60#, txp); txa(dsutx, 16#00#, 16#00#, 16#12#, 16#10#, txp); txc(dsutx, 16#80#, txp); txa(dsutx, 16#90#, 16#00#, 16#00#, 16#00#, txp); rxi(dsurx, w32, txp, lresp); txc(dsutx, 16#a0#, txp); txa(dsutx, 16#40#, 16#00#, 16#00#, 16#00#, txp); rxi(dsurx, w32, txp, lresp); end; begin dsucfg(txd2, rxd2); wait; end process; end ;

gpl-2.0

456e6f19334e203846d3dff024196a53

0.587645

3.038742

false

marco-c/leon-nexys2

grlib-gpl-1.3.4-b4140/lib/gaisler/pci/grpci1/pci_mt.vhd

1

28,846

------------------------------------------------------------------------------ -- This file is a part of the GRLIB VHDL IP LIBRARY -- Copyright (C) 2003 - 2008, Gaisler Research -- Copyright (C) 2008 - 2013, Aeroflex Gaisler -- -- This program is free software; you can redistribute it and/or modify -- it under the terms of the GNU General Public License as published by -- the Free Software Foundation; either version 2 of the License, or -- (at your option) any later version. -- -- This program is distributed in the hope that it will be useful, -- but WITHOUT ANY WARRANTY; without even the implied warranty of -- MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the -- GNU General Public License for more details. -- -- You should have received a copy of the GNU General Public License -- along with this program; if not, write to the Free Software -- Foundation, Inc., 59 Temple Place, Suite 330, Boston, MA 02111-1307 USA ----------------------------------------------------------------------------- -- Entity: pci_mt -- File: pci_mt.vhd -- Author: Jiri Gaisler - Gaisler Research -- Modified: Alf Vaerneus - Gaisler Research -- Description: Simple PCI master and target interface ------------------------------------------------------------------------------ library ieee; use ieee.std_logic_1164.all; library grlib; use grlib.amba.all; use grlib.stdlib.all; use grlib.devices.all; library gaisler; use gaisler.pci.all; use gaisler.pcilib.all; entity pci_mt is generic ( hmstndx : integer := 0; abits : integer := 21; device_id : integer := 0; -- PCI device ID vendor_id : integer := 0; -- PCI vendor ID master : integer := 1; -- Enable PCI Master hslvndx : integer := 0; haddr : integer := 16#F00#; hmask : integer := 16#F00#; ioaddr : integer := 16#000#; nsync : integer range 1 to 2 := 1; -- 1 or 2 sync regs between clocks oepol : integer := 0 ); port( rst : in std_logic; clk : in std_logic; pciclk : in std_logic; pcii : in pci_in_type; pcio : out pci_out_type; ahbmi : in ahb_mst_in_type; ahbmo : out ahb_mst_out_type; ahbsi : in ahb_slv_in_type; ahbso : out ahb_slv_out_type ); end; architecture rtl of pci_mt is constant REVISION : amba_version_type := 0; constant hconfig : ahb_config_type := ( 0 => ahb_device_reg ( VENDOR_GAISLER, GAISLER_PCISBRG, 0, REVISION, 0), 4 => ahb_membar(haddr, '0', '0', hmask), 5 => ahb_iobar (ioaddr, 16#E00#), others => zero32); constant CSYNC : integer := nsync-1; constant MADDR_WIDTH : integer := abits; constant HADDR_WIDTH : integer := 28; type pci_input_type is record ad : std_logic_vector(31 downto 0); cbe : std_logic_vector(3 downto 0); frame : std_logic; devsel : std_logic; idsel : std_logic; trdy : std_logic; irdy : std_logic; par : std_logic; stop : std_logic; rst : std_logic; gnt : std_logic; end record; type ahbs_input_type is record haddr : std_logic_vector(HADDR_WIDTH - 1 downto 0); htrans : std_logic_vector(1 downto 0); hwrite : std_logic; hsize : std_logic_vector(1 downto 0); hburst : std_logic_vector(2 downto 0); hwdata : std_logic_vector(31 downto 0); hsel : std_logic; hiosel : std_logic; hready : std_logic; end record; type pci_target_state_type is (idle, b_busy, s_data, backoff, turn_ar); type pci_master_state_type is (idle, addr, m_data, turn_ar, s_tar, dr_bus); type pci_config_command_type is record ioen : std_logic; -- I/O access enable men : std_logic; -- Memory access enable msen : std_logic; -- Master enable spcen : std_logic; -- Special cycle enable mwie : std_logic; -- Memory write and invalidate enable vgaps : std_logic; -- VGA palette snooping enable per : std_logic; -- Parity error response enable wcc : std_logic; -- Address stepping enable serre : std_logic; -- Enable SERR# driver fbtbe : std_logic; -- Fast back-to-back enable end record; type pci_config_status_type is record c66mhz : std_logic; -- 66MHz capability udf : std_logic; -- UDF supported fbtbc : std_logic; -- Fast back-to-back capability dped : std_logic; -- Data parity error detected dst : std_logic_vector(1 downto 0); -- DEVSEL timing sta : std_logic; -- Signaled target abort rta : std_logic; -- Received target abort rma : std_logic; -- Received master abort sse : std_logic; -- Signaled system error dpe : std_logic; -- Detected parity error end record; type pci_reg_type is record addr : std_logic_vector(MADDR_WIDTH-1 downto 0); ad : std_logic_vector(31 downto 0); cbe : std_logic_vector(3 downto 0); lcbe : std_logic_vector(3 downto 0); t_state : pci_target_state_type; -- PCI target state machine m_state : pci_master_state_type; -- PCI master state machine csel : std_logic; -- Configuration chip select msel : std_logic; -- Memory hit read : std_logic; devsel : std_logic; -- PCI device select trdy : std_logic; -- Target ready irdy : std_logic; -- Master ready stop : std_logic; -- Target stop request par : std_logic; -- PCI bus parity req : std_logic; -- Master bus request oe_par : std_logic; oe_ad : std_logic; oe_trdy : std_logic; oe_devsel: std_logic; oe_ctrl : std_logic; oe_cbe : std_logic; oe_stop : std_logic; oe_frame : std_logic; oe_irdy : std_logic; oe_req : std_logic; noe_par : std_logic; noe_ad : std_logic; noe_trdy : std_logic; noe_devsel: std_logic; noe_ctrl : std_logic; noe_cbe : std_logic; noe_stop : std_logic; noe_frame : std_logic; noe_irdy : std_logic; noe_req : std_logic; request : std_logic; -- Request from Back-end frame : std_logic; -- Master frame bar0 : std_logic_vector(31 downto MADDR_WIDTH); page : std_logic_vector(31 downto MADDR_WIDTH-1); comm : pci_config_command_type; stat : pci_config_status_type; laddr : std_logic_vector(31 downto 0); ldata : std_logic_vector(31 downto 0); pwrite : std_logic; hwrite : std_logic; start : std_logic; hreq : std_logic; hreq_ack : std_logic_vector(csync downto 0); preq : std_logic_vector(csync downto 0); preq_ack : std_logic; rready : std_logic_vector(csync downto 0); wready : std_logic_vector(csync downto 0); sync : std_logic_vector(csync downto 0); pabort : std_logic; mcnt : std_logic_vector(2 downto 0); maddr : std_logic_vector(31 downto 0); mdata : std_logic_vector(31 downto 0); stop_req : std_logic; end record; type cpu_master_state_type is (idle, sync1, busy, sync2); type cpu_slave_state_type is (idle, getd, req, sync, read, sync2, t_done); type cpu_reg_type is record tdata : std_logic_vector(31 downto 0); -- Target data maddr : std_logic_vector(31 downto 0); -- Master data mdata : std_logic_vector(31 downto 0); -- Master data be : std_logic_vector(3 downto 0); m_state : cpu_master_state_type; -- AMBA master state machine s_state : cpu_slave_state_type; -- AMBA slave state machine start : std_logic_vector(csync downto 0); hreq : std_logic_vector(csync downto 0); hreq_ack : std_logic; preq : std_logic; preq_ack : std_logic_vector(csync downto 0); sync : std_logic; hwrite : std_logic; -- AHB write on PCI pabort : std_logic_vector(csync downto 0); perror : std_logic; rready : std_logic; wready : std_logic; hrdata : std_logic_vector(31 downto 0); hresp : std_logic_vector(1 downto 0); pciba : std_logic_vector(3 downto 0); end record; signal clk_int : std_logic; signal pr : pci_input_type; signal hr : ahbs_input_type; signal r, rin : pci_reg_type; signal r2, r2in : cpu_reg_type; signal dmai : ahb_dma_in_type; signal dmao : ahb_dma_out_type; signal roe_ad, rioe_ad : std_logic_vector(31 downto 0); attribute syn_preserve : boolean; attribute syn_preserve of roe_ad : signal is true; begin -- Back-end state machine (AHB clock domain) comb : process (rst, r2, r, dmao, hr, ahbsi) variable vdmai : ahb_dma_in_type; variable v : cpu_reg_type; variable request : std_logic; variable hready : std_logic; variable hresp, hsize, htrans : std_logic_vector(1 downto 0); variable p_done : std_logic; begin v := r2; vdmai.start := '0'; vdmai.burst := '0'; vdmai.size := "010"; vdmai.address := r.laddr; v.sync := '1'; vdmai.wdata := ahbdrivedata(r.ldata); vdmai.write := r.pwrite; v.start(0) := r2.start(csync); v.start(csync) := r.start; v.hreq(0) := r2.hreq(csync); v.hreq(csync) := r.hreq; v.pabort(0) := r2.pabort(csync); v.pabort(csync) := r.pabort; v.preq_ack(0) := r2.preq_ack(csync); v.preq_ack(csync) := r.preq_ack; hready := '1'; hresp := HRESP_OKAY; request := '0'; hsize := "10"; htrans := "00"; p_done := r2.hreq(0) or r2.pabort(0); ---- *** APB register access *** ---- --if (apbi.psel and apbi.penable and apbi.pwrite) = '1' then --v.pciba := apbi.pwdata(31 downto 28); --end if; --apbo.prdata <= r2.pciba & addzero; if hr.hiosel = '1' then if hr.hwrite = '1' then v.pciba := ahbreadword(ahbsi.hwdata)(31 downto 28); end if; v.hrdata := r2.pciba & addzero(27 downto 0); end if; ---- *** AHB MASTER *** ---- case r2.m_state is when idle => v.sync := '0'; if r2.start(0) = '1' then if r.pwrite = '1' then v.m_state := sync1; v.wready := '0'; else v.m_state := busy; vdmai.start := '1'; end if; end if; when sync1 => if r2.start(0) = '0' then v.m_state := busy; vdmai.start := '1'; end if; when busy => if dmao.active = '1' then if dmao.ready = '1' then v.rready := not r.pwrite; v.tdata := dmao.rdata(31 downto 0); v.m_state := sync2; end if; else vdmai.start := '1'; end if; when sync2 => if r2.start(0) = '0' then v.m_state := idle; v.wready := '1'; v.rready := '0'; end if; end case; ---- *** AHB MASTER END *** ---- ---- *** AHB SLAVE *** ---- if MASTER = 1 then if (hr.hready and hr.hsel) = '1' then hsize := hr.hsize; htrans := hr.htrans; if (hr.htrans(1) and r.comm.msen) = '1' then request := '1'; end if; end if; if (request = '1' and r2.s_state = idle) then v.maddr := r2.pciba & hr.haddr; v.hwrite := hr.hwrite; case hsize is when "00" => v.be := "1110"; -- Decode byte enable when "01" => v.be := "1100"; when "10" => v.be := "0000"; when others => v.be := "1111"; end case; elsif r2.s_state = getd and r2.hwrite = '1' then v.mdata := hr.hwdata; end if; if r2.hreq(0) = '1' then v.hrdata := r.ldata; end if; if r2.preq_ack(0) = '1' then v.preq := '0'; end if; if r2.pabort(0) = '1' then v.perror := '1'; end if; if p_done = '0' then v.hreq_ack := '0'; end if; -- AHB slave state machine case r2.s_state is when idle => if request = '1' then v.s_state := getd; end if; when getd => v.s_state := req; v.preq := '1'; when req => if r2.preq_ack(0) = '1' then v.s_state := sync; end if; when sync => if r2.preq_ack(0) = '0' then v.s_state := read; end if; when read => if p_done = '1' then v.hreq_ack := '1'; v.s_state := sync2; end if; when sync2 => if p_done = '0' then v.s_state := t_done; end if; when t_done => if request = '1' then v.s_state := idle; end if; when others => v.s_state := idle; end case; if request = '1' then if r2.s_state = t_done then if r2.perror = '1' then hresp := HRESP_ERROR; else hresp := HRESP_OKAY; end if; v.perror := '0'; else hresp := HRESP_RETRY; end if; end if; if r.comm.msen = '0' then hresp := HRESP_ERROR; end if; -- Master disabled if htrans(1) = '0' then hresp := HRESP_OKAY; end if; -- Response OK for BUSY and IDLE if (hresp /= HRESP_OKAY and (hr.hready and hr.hsel) = '1') then -- insert one wait cycle hready := '0'; end if; if hr.hready = '0' then hresp := r2.hresp; end if; v.hresp := hresp; end if; ---- *** AHB SLAVE END *** ---- if rst = '0' then v.s_state := idle; v.rready := '0'; v.wready := '1'; v.m_state := idle; v.preq := '0'; v.hreq_ack := '0'; v.perror := '0'; v.be := (others => '1'); v.pciba := (others => '0'); v.hresp := (others => '0'); end if; r2in <= v; dmai <= vdmai; ahbso.hready <= hready; ahbso.hresp <= hresp; ahbso.hrdata <= ahbdrivedata(r2.hrdata); end process; ahbso.hconfig <= hconfig when MASTER = 1 else (others => zero32); ahbso.hsplit <= (others => '0'); ahbso.hirq <= (others => '0'); ahbso.hindex <= hslvndx; -- PCI target core (PCI clock domain) pcicomb : process(pcii.rst, pr, pcii, r, r2, roe_ad) variable v : pci_reg_type; variable chit, mhit, hit, ready, cwrite : std_logic; variable cdata, cwdata : std_logic_vector(31 downto 0); variable comp : std_logic; -- Last transaction cycle on PCI bus variable iready : std_logic; variable mto : std_logic; variable tad, mad : std_logic_vector(31 downto 0); -- variable cbe : std_logic_vector(3 downto 0); variable caddr : std_logic_vector(7 downto 2); variable voe_ad : std_logic_vector(31 downto 0); variable oe_par : std_logic; variable oe_ad : std_logic; variable oe_ctrl : std_logic; variable oe_trdy : std_logic; variable oe_devsel: std_logic; variable oe_cbe : std_logic; variable oe_stop : std_logic; variable oe_frame : std_logic; variable oe_irdy : std_logic; variable oe_req : std_logic; begin -- Process defaults v := r; v.trdy := '1'; v.stop := '1'; v.frame := '1'; v.oe_ad := '1'; v.devsel := '1'; v.oe_frame := '1'; v.irdy := '1'; v.req := '1'; voe_ad := roe_ad; v.oe_req := '0'; v.oe_cbe := '1'; v.oe_irdy := '1'; v.rready(0) := r.rready(csync); v.rready(csync) := r2.rready; v.wready(0) := r.wready(csync); v.wready(csync) := r2.wready; v.sync(0) := r.sync(csync); v.sync(csync) := r2.sync; v.preq(0) := r.preq(csync); v.preq(csync) := r2.preq; v.hreq_ack(0) := r.hreq_ack(csync); v.hreq_ack(csync) := r2.hreq_ack; comp := '0'; mto := '0'; tad := r.ad; mad := r.ad; v.stop_req := '0'; --cbe := r.cbe; ----- *** PCI TARGET *** -------- -- address decoding if (r.t_state = s_data) and ((pr.irdy or r.trdy or r.read) = '0') then cwrite := r.csel; if ((r.msel and r.addr(MADDR_WIDTH-1)) = '1') and (pr.cbe = "0000") then v.page := pr.ad(31 downto MADDR_WIDTH-1); end if; if (pr.cbe = "0000") and (r.addr(MADDR_WIDTH-1) = '1') then end if; else cwrite := '0'; end if; cdata := (others => '0'); caddr := r.addr(7 downto 2); case caddr is when "000000" => -- 0x00, device & vendor id cdata := conv_std_logic_vector(DEVICE_ID, 16) & conv_std_logic_vector(VENDOR_ID, 16); when "000001" => -- 0x04, status & command cdata(1) := r.comm.men; cdata(2) := r.comm.msen; cdata(25) := '1'; cdata(28) := r.stat.rta; cdata(29) := r.stat.rma; when "000010" => -- 0x08, class code & revision when "000011" => -- 0x0c, latency & cacheline size when "000100" => -- 0x10, BAR0 cdata(31 downto MADDR_WIDTH) := r.bar0; when others => end case; cwdata := pr.ad; if pr.cbe(3) = '1' then cwdata(31 downto 24) := cdata(31 downto 24); end if; if pr.cbe(2) = '1' then cwdata(23 downto 16) := cdata(23 downto 16); end if; if pr.cbe(1) = '1' then cwdata(15 downto 8) := cdata(15 downto 8); end if; if pr.cbe(0) = '1' then cwdata( 7 downto 0) := cdata( 7 downto 0); end if; if cwrite = '1' then case caddr is when "000001" => -- 0x04, status & command v.comm.men := cwdata(1); v.comm.msen := cwdata(2); v.stat.rta := r.stat.rta and not cwdata(28); v.stat.rma := r.stat.rma and not cwdata(29); when "000100" => -- 0x10, BAR0 v.bar0 := cwdata(31 downto MADDR_WIDTH); when others => end case; end if; if (((pr.cbe = pci_config_read) or (pr.cbe = pci_config_write)) and (pr.ad(1 downto 0) = "00")) then chit := '1'; else chit := '0'; end if; if ((pr.cbe = pci_memory_read) or (pr.cbe = pci_memory_write)) and (r.bar0 = pr.ad(31 downto MADDR_WIDTH)) and (r.bar0 /= zero(31 downto MADDR_WIDTH)) then mhit := '1'; else mhit := '0'; end if; hit := r.csel or r.msel; ready := r.csel or (r.rready(0) and r.read) or (r.wready(0) and not r.read and not r.start) or r.addr(MADDR_WIDTH-1); -- target state machine case r.t_state is when idle => if pr.frame = '0' then v.t_state := b_busy; end if; -- !HIT ? v.addr := pr.ad(MADDR_WIDTH-1 downto 0); -- v.cbe := pr.cbe; v.csel := pr.idsel and chit; v.msel := r.comm.men and mhit; v.read := not pr.cbe(0); if (r.sync(0) and r.start and r.pwrite) = '1' then v.start := '0'; end if; when turn_ar => if pr.frame = '1' then v.t_state := idle; end if; if pr.frame = '0' then v.t_state := b_busy; end if; -- !HIT ? v.addr := pr.ad(MADDR_WIDTH-1 downto 0); -- v.cbe := pr.cbe; v.csel := pr.idsel and chit; v.msel := r.comm.men and mhit; v.read := not pr.cbe(0); if (r.sync(0) and r.start and r.pwrite) = '1' then v.start := '0'; end if; when b_busy => if hit = '1' then v.t_state := s_data; v.trdy := not ready; v.stop := pr.frame and ready; v.devsel := '0'; else v.t_state := backoff; end if; when s_data => v.stop := r.stop; v.devsel := '0'; v.trdy := r.trdy or not pcii.irdy; if (pcii.frame and not pcii.irdy) = '1' then v.t_state := turn_ar; v.stop := '1'; v.trdy := '1'; v.devsel := '1'; end if; when backoff => if pr.frame = '1' then v.t_state := idle; end if; end case; if ((r.t_state = s_data) or (r.t_state = turn_ar)) and (((pr.irdy or pr.trdy) = '0') or ((not pr.irdy and not pr.stop and pr.trdy and not r.start and r.wready(0)) = '1')) then if (pr.trdy and r.read)= '0' then v.start := '0'; end if; if (r.start = '0') and ((r.msel and not r.addr(MADDR_WIDTH-1)) = '1') and (((pr.trdy and r.read and not r.rready(0)) or (not pr.trdy and not r.read)) = '1') then v.laddr := r.page & r.addr(MADDR_WIDTH-2 downto 0); v.ldata := pr.ad; v.pwrite := not r.read; v.start := '1'; end if; end if; -- if (v.t_state = s_data) and (r.read = '1') then v.oe_ad := '0'; end if; -- v.oe_par := r.oe_ad; if r.csel = '1' then tad := cdata; elsif r.addr(MADDR_WIDTH-1) = '1' then tad(31 downto MADDR_WIDTH-1) := r.page; tad(MADDR_WIDTH-2 downto 0) := (others => '0'); else tad := r2.tdata; end if; if (v.t_state = s_data) or (r.t_state = s_data) then v.oe_ctrl := '0'; else v.oe_ctrl := '1'; end if; ----- *** PCI TARGET END*** -------- ----- *** PCI MASTER *** -------- if MASTER = 1 then if r.preq(0) = '1' then if (r.m_state = idle or r.m_state = dr_bus) and r.request = '0' and r.hreq = '0' then v.request := '1'; v.hwrite := r2.hwrite; v.lcbe := r2.be; v.mdata := r2.mdata; v.maddr :=r2.maddr; end if; end if; if r.hreq_ack(0) = '1' then v.hreq := '0'; v.pabort := '0'; end if; if r.preq(0) = '0' then v.preq_ack := '0'; end if; comp := not(pcii.trdy or pcii.irdy); if ((pr.irdy and not pr.frame) or (pr.devsel and r.frame and not r.oe_frame)) = '1' then -- Covers both master timeout and devsel timeout if r.mcnt /= "000" then v.mcnt := r.mcnt - 1; else mto := '1'; end if; else v.mcnt := (others => '1'); end if; -- PCI master state machine case r.m_state is when idle => -- Master idle if (pr.gnt = '0' and (pr.frame and pr.irdy) = '1') then if r.request = '1' then v.m_state := addr; v.preq_ack := '1'; else v.m_state := dr_bus; end if; end if; when addr => -- Always one address cycle at the beginning of an transaction v.m_state := m_data; when m_data => -- Master transfers data --if (r.request and not pr.gnt and pr.frame and not pr.trdy -- Not supporting address stepping! --and pr.stop and l_cycle and sa) = '1' then --v.m_state <= addr; v.hreq := comp; if (pr.frame = '0') or ((pr.frame and pcii.trdy and pcii.stop and not mto) = '1') then v.m_state := m_data; elsif ((pr.frame and (mto or not pcii.stop)) = '1') then v.m_state := s_tar; else v.m_state := turn_ar; v.request := '0'; end if; when turn_ar => -- Transaction complete if (r.request and not pr.gnt) = '1' then v.m_state := addr; elsif (r.request or pr.gnt) = '0' then v.m_state := dr_bus; else v.m_state := idle; end if; when s_tar => -- Stop was asserted v.request := pr.trdy and not pr.stop and not pr.devsel; v.stop_req := '1'; if (pr.stop or pr.devsel or pr.trdy) = '0' then -- Disconnect with data v.m_state := turn_ar; elsif pr.gnt = '0' then v.pabort := not v.request; v.m_state := dr_bus; else v.m_state := idle; v.pabort := not v.request; end if; when dr_bus => -- Drive bus when parked on this agent if (r.request = '1' and (pcii.gnt or r.req) = '0') then v.m_state := addr; v.preq_ack := '1'; elsif pcii.gnt = '1' then v.m_state := idle; end if; end case; if v.m_state = addr then mad := r.maddr; else mad := r.mdata; end if; if (pr.irdy or pr.trdy or r.hwrite) = '0' then v.ldata := pr.ad; end if; -- Target abort if ((pr.devsel and pr.trdy and not pr.gnt and not pr.stop) = '1') then v.stat.rta := '1'; end if; -- Master abort if mto = '1' then v.stat.rma := '1'; end if; -- Drive FRAME# and IRDY# if (v.m_state = addr or v.m_state = m_data) then v.oe_frame := '0'; end if; -- Drive CBE# if (v.m_state = addr or v.m_state = m_data or v.m_state = dr_bus) then v.oe_cbe := '0'; end if; -- Drive IRDY# (FRAME# delayed one pciclk) v.oe_irdy := r.oe_frame; -- FRAME# assert if v.m_state = addr then v.frame := '0'; end if; -- Only single transfers valid -- IRDY# assert if v.m_state = m_data then v.irdy := '0'; end if; -- REQ# assert if (v.request = '1' and (v.m_state = idle or r.m_state = idle) and (v.stop_req or r.stop_req) = '0') then v.req := '0'; end if; -- C/BE# assert if v.m_state = addr then v.cbe := "011" & r.hwrite; else v.cbe := r.lcbe; end if; end if; ----- *** PCI MASTER END *** -------- ----- *** SHARED BUS SIGNALS *** ------- -- Drive PAR v.oe_par := r.oe_ad; --Delayed one clock v.par := xorv(r.ad & r.cbe); -- Default asserted by master v.ad := mad; -- Default asserted by master -- Master if (v.m_state = addr or (v.m_state = m_data and r.hwrite = '1') or v.m_state = dr_bus) then v.oe_ad := '0'; end if; -- Drive AD -- Target if r.read = '1' then if v.t_state = s_data then v.oe_ad := '0'; v.ad := tad; elsif r.t_state = s_data then v.par := xorv(r.ad & pcii.cbe); end if; end if; v.oe_stop := v.oe_ctrl; v.oe_devsel := v.oe_ctrl; v.oe_trdy := v.oe_ctrl; v.noe_ad := not v.oe_ad; v.noe_ctrl := not v.oe_ctrl; v.noe_par := not v.oe_par; v.noe_req := not v.oe_req; v.noe_frame := not v.oe_frame; v.noe_cbe := not v.oe_cbe; v.noe_irdy := not v.oe_irdy; v.noe_stop := not v.oe_ctrl; v.noe_devsel := not v.oe_ctrl; v.noe_trdy := not v.oe_ctrl; if oepol = 0 then voe_ad := (others => v.oe_ad); oe_ad := r.oe_ad; oe_ctrl := r.oe_ctrl; oe_par := r.oe_par; oe_req := r.oe_req; oe_frame := r.oe_frame; oe_cbe := r.oe_cbe; oe_irdy := r.oe_irdy; oe_stop := r.oe_stop; oe_trdy := r.oe_trdy; oe_devsel := r.oe_devsel; else voe_ad := (others => v.noe_ad); oe_ad := r.noe_ad; oe_ctrl := r.noe_ctrl; oe_par := r.noe_par; oe_req := r.noe_req; oe_frame := r.noe_frame; oe_cbe := r.noe_cbe; oe_irdy := r.noe_irdy; oe_stop := r.noe_stop; oe_trdy := r.noe_trdy; oe_devsel := r.noe_devsel; end if; ----- *** SHARED BUS SIGNALS END *** ------- if pr.rst = '0' then v.t_state := idle; v.m_state := idle; v.comm.men := '0'; v.start := '0'; v.bar0 := (others => '0'); v.msel := '0'; v.csel := '0'; v.page := (others => '0'); v.page(31 downto 30) := "01"; v.par := '0'; v.hwrite := '0'; v.request := '0'; v.comm.msen := '0'; v.laddr := (others => '0'); v.ldata := (others => '0'); v.hreq := '0'; v.preq_ack := '0'; v.pabort := '0'; v.mcnt := (others => '1'); v.maddr := (others => '0'); v.lcbe := (others => '0'); v.mdata := (others => '0'); v.pwrite := '0'; v.stop_req := '0'; v.stat.rta := '0'; v.stat.rma := '0'; end if; rin <= v; rioe_ad <= voe_ad; pcio.reqen <= oe_req; pcio.req <= r.req; pcio.frameen <= oe_frame; pcio.frame <= r.frame; pcio.irdyen <= oe_irdy; pcio.irdy <= r.irdy; pcio.cbeen <= (others => oe_cbe); pcio.cbe <= r.cbe; pcio.vaden <= roe_ad; pcio.aden <= oe_ad; pcio.ad <= r.ad; pcio.trdy <= r.trdy; pcio.ctrlen <= oe_ctrl; pcio.trdyen <= oe_trdy; pcio.devselen <= oe_devsel; pcio.stopen <= oe_stop; pcio.stop <= r.stop; pcio.devsel <= r.devsel; pcio.par <= r.par; pcio.paren <= oe_par; pcio.rst <= '1'; end process; pcir : process (pciclk, pcii.rst) begin if rising_edge (pciclk) then pr.ad <= to_x01(pcii.ad); pr.cbe <= to_x01(pcii.cbe); pr.devsel <= to_x01(pcii.devsel); pr.frame <= to_x01(pcii.frame); pr.idsel <= to_x01(pcii.idsel); pr.irdy <= to_x01(pcii.irdy); pr.trdy <= to_x01(pcii.trdy); pr.par <= to_x01(pcii.par); pr.stop <= to_x01(pcii.stop); pr.rst <= to_x01(pcii.rst); pr.gnt <= to_x01(pcii.gnt); r <= rin; roe_ad <= rioe_ad; end if; if pcii.rst = '0' then -- asynch reset required r.oe_ad <= '1'; r.oe_ctrl <= '1'; r.oe_par <= '1'; r.oe_stop <= '1'; r.oe_req <= '1'; r.oe_frame <= '1'; r.oe_cbe <= '1'; r.oe_irdy <= '1'; r.oe_trdy <= '1'; r.oe_devsel <= '1'; r.noe_ad <= '0'; r.noe_ctrl <= '0'; r.noe_par <= '0'; r.noe_req <= '0'; r.noe_frame <= '0'; r.noe_cbe <= '0'; r.noe_irdy <= '0'; r.noe_stop <= '0'; r.noe_trdy <= '0'; r.noe_devsel <= '0'; if oepol = 0 then roe_ad <= (others => '1'); else roe_ad <= (others => '0'); end if; end if; end process; cpur : process (rst,clk) begin if rising_edge (clk) then hr.haddr <= ahbsi.haddr(HADDR_WIDTH - 1 downto 0); hr.htrans <= ahbsi.htrans; hr.hwrite <= ahbsi.hwrite; hr.hsize <= ahbsi.hsize(1 downto 0); hr.hburst <= ahbsi.hburst; hr.hwdata <= ahbreadword(ahbsi.hwdata); hr.hsel <= ahbsi.hsel(hslvndx) and ahbsi.hmbsel(0); hr.hiosel <= ahbsi.hsel(hslvndx) and ahbsi.hmbsel(1); hr.hready <= ahbsi.hready; r2 <= r2in; end if; end process; oe0 : if oepol = 0 generate pcio.perren <= '1'; pcio.serren <= '1'; pcio.inten <= '1'; pcio.vinten <= (others => '1'); pcio.locken <= '1'; end generate; oe1 : if oepol = 1 generate pcio.perren <= '0'; pcio.serren <= '0'; pcio.inten <= '0'; pcio.vinten <= (others => '0'); pcio.locken <= '0'; end generate; pcio.perr <= '1'; pcio.serr <= '1'; pcio.int <= '1'; msttgt : if MASTER = 1 generate ahbmst0 : ahbmst generic map (hindex => hmstndx, devid => GAISLER_PCISBRG) port map (rst, clk, dmai, dmao, ahbmi, ahbmo); -- pragma translate_off bootmsg : report_version generic map ("pci_mt" & tost(hslvndx) & ": Simple 32-bit PCI Bridge, rev " & tost(REVISION) & ", " & tost(2**abits/2**20) & " Mbyte PCI memory BAR" ); -- pragma translate_on end generate; tgtonly : if MASTER = 0 generate ahbmst0 : ahbmst generic map (hindex => hmstndx, devid => GAISLER_PCITRG) port map (rst, clk, dmai, dmao, ahbmi, ahbmo); -- pragma translate_off bootmsg : report_version generic map ("pci_mt" & tost(hmstndx) & ": Simple 32-bit Bridge, target-only, rev " & tost(REVISION) & ", " & tost(2**abits/2**20) & " Mbyte PCI memory BAR" ); -- pragma translate_on end generate; end;

gpl-2.0

a0aade0367da5dc8ec3a8464ebf7f985

0.559003

2.923186

false

marco-c/leon-nexys2

grlib-gpl-1.3.4-b4140/lib/gaisler/pci/pcitrace/pcitrace.vhd

1

7,716

------------------------------------------------------------------------------ -- This file is a part of the GRLIB VHDL IP LIBRARY -- Copyright (C) 2003 - 2008, Gaisler Research -- Copyright (C) 2008 - 2013, Aeroflex Gaisler -- -- This program is free software; you can redistribute it and/or modify -- it under the terms of the GNU General Public License as published by -- the Free Software Foundation; either version 2 of the License, or -- (at your option) any later version. -- -- This program is distributed in the hope that it will be useful, -- but WITHOUT ANY WARRANTY; without even the implied warranty of -- MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the -- GNU General Public License for more details. -- -- You should have received a copy of the GNU General Public License -- along with this program; if not, write to the Free Software -- Foundation, Inc., 59 Temple Place, Suite 330, Boston, MA 02111-1307 USA ----------------------------------------------------------------------------- -- Entity: pcitrace -- File: pcitrace.vhd -- Author: Jiri Gaisler - Gaisler Research -- Description: PCI trace buffer ------------------------------------------------------------------------------ library ieee; use ieee.std_logic_1164.all; library grlib; use grlib.amba.all; use grlib.stdlib.all; use grlib.devices.all; library techmap; use techmap.gencomp.all; library gaisler; use gaisler.pci.all; entity pcitrace is generic ( depth : integer range 6 to 12 := 8; iregs : integer := 1; memtech : integer := DEFMEMTECH; pindex : integer := 0; paddr : integer := 0; pmask : integer := 16#f00# ); port ( rst : in std_ulogic; clk : in std_ulogic; pciclk : in std_ulogic; pcii : in pci_in_type; apbi : in apb_slv_in_type; apbo : out apb_slv_out_type ); end; architecture rtl of pcitrace is constant REVISION : amba_version_type := 0; constant pconfig : apb_config_type := ( 0 => ahb_device_reg ( VENDOR_GAISLER, GAISLER_PCITRACE, 0, REVISION, 0), 1 => apb_iobar(paddr, pmask)); type reg_type is record sample : std_ulogic; armed : std_ulogic; busy : std_ulogic; timeout : std_logic_vector(depth-1 downto 0); admask : std_logic_vector(31 downto 0); adpattern : std_logic_vector(31 downto 0); sigmask : std_logic_vector(15 downto 0); sigpattern : std_logic_vector(15 downto 0); count : std_logic_vector(7 downto 0); end record; type pci_reg_type is record sample : std_ulogic; armed : std_ulogic; sync : std_ulogic; start : std_ulogic; timeout : std_logic_vector(depth-1 downto 0); baddr : std_logic_vector(depth-1 downto 0); count : std_logic_vector(7 downto 0); end record; signal r, rin : reg_type; signal csad, csctrl : std_ulogic; signal pr, prin : pci_reg_type; signal bufout : std_logic_vector(47 downto 0); signal pciad : std_logic_vector(31 downto 0); signal vcc : std_ulogic; signal pcictrlin, pcictrl : std_logic_vector(15 downto 0); begin vcc <= '1'; comb: process(pcii, apbi, rst, r, pr, bufout) variable v : reg_type; variable rdata : std_logic_vector(31 downto 0); variable paddr : std_logic_vector(3 downto 0); variable vcsad, vcssig : std_ulogic; begin v := r; vcsad := '0'; vcssig := '0'; rdata := (others => '0'); v.sample := r.armed and not pr.armed; v.busy := pr.sample; if (r.sample and pr.armed) = '1' then v.armed := '0'; end if; --registers paddr := apbi.paddr(15) & apbi.paddr(4 downto 2); if apbi.penable = '1' then if (apbi.pwrite and apbi.psel(pindex)) = '1' then case paddr is when "0000" => v.admask := apbi.pwdata; when "0001" => v.sigmask := apbi.pwdata(15 downto 0); when "0010" => v.adpattern := apbi.pwdata; when "0011" => v.sigpattern := apbi.pwdata(15 downto 0); when "0100" => v.timeout := apbi.pwdata(depth-1 downto 0); when "0101" => v.armed := '1'; when "0111" => v.count := apbi.pwdata(7 downto 0); when others => if apbi.paddr(15 downto 14) = "10" then vcsad := '1'; elsif apbi.paddr(15 downto 14) = "11" then vcssig := '1'; end if; end case; end if; case paddr is when "0000" => rdata := r.admask; when "0001" => rdata(15 downto 0) := r.sigmask; when "0010" => rdata := r.adpattern; when "0011" => rdata(15 downto 0) := r.sigpattern; when "0100" => rdata(depth-1 downto 0) := r.timeout; when "0101" => rdata(0) := r.busy; when "0110" => rdata(3 downto 0) := conv_std_logic_vector(depth, 4); when "0111" => rdata(depth-1+16 downto 16) := pr.baddr; rdata(15 downto 0) := pr.count & r.count; when others => if apbi.paddr(15 downto 14) = "10" then vcsad := '1'; rdata := bufout(31 downto 0); elsif apbi.paddr(15 downto 14) = "11" then vcssig := '1'; rdata(15 downto 0) := bufout(47 downto 32); end if; end case; end if; if rst = '0' then v.sample := '0'; v.armed := '0'; v.admask := (others => '0'); v.sigmask := (others => '0'); v.adpattern := (others => '0'); v.sigpattern := (others => '0'); v.timeout := (others => '0'); end if; csad <= vcsad; csctrl <= vcssig; apbo.prdata <= rdata; rin <= v; end process; comb2 : process(r, pr, pciclk, pcii, pcictrl, rst) variable v : pci_reg_type; constant z : std_logic_vector(47 downto 0) := (others => '0'); begin v := pr; v.sync := (r.sample and not pr.armed); if (pr.sample = '1') then v.baddr := pr.baddr + 1; if ((((pcii.ad & pcictrl) xor (r.adpattern & r.sigpattern)) and (r.admask & r.sigmask)) = z) then if pr.count = "00000000" then v.start := '0'; else v.count := pr.count -1; end if; end if; if (pr.start = '0') then v.timeout := pr.timeout - 1; if (v.timeout(depth-1) and not pr.timeout(depth-1)) = '1' then v.sample := '0'; v.armed := '0'; end if; end if; end if; if pr.sync = '1' then v.start := '1'; v.sample := '1'; v.armed := '1'; v.timeout := r.timeout; v.count := r.count; end if; if rst = '0' then v.sample := '0'; v.armed := '0'; v.start := '0'; v.timeout := (others => '0'); v.baddr := (others => '0'); v.count := (others => '0'); end if; prin <= v; end process ; pcictrlin <= pcii.rst & pcii.idsel & pcii.frame & pcii.trdy & pcii.irdy & pcii.devsel & pcii.gnt & pcii.stop & pcii.lock & pcii.perr & pcii.serr & pcii.par & pcii.cbe; apbo.pconfig <= pconfig; apbo.pindex <= pindex; apbo.pirq <= (others => '0'); seq: process (clk) begin if clk'event and clk = '1' then r <= rin; end if; end process seq; pseq: process (pciclk) begin if pciclk'event and pciclk = '1' then pr <= prin; end if; end process ; ir : if iregs = 1 generate pseq: process (pciclk) begin if pciclk'event and pciclk = '1' then pcictrl <= pcictrlin; pciad <= pcii.ad; end if; end process ; end generate; noir : if iregs = 0 generate pcictrl <= pcictrlin; pciad <= pcii.ad; end generate; admem : syncram_2p generic map (tech => memtech, abits => depth, dbits => 32, sepclk => 1) port map (clk, csad, apbi.paddr(depth+1 downto 2), bufout(31 downto 0), pciclk, pr.sample, pr.baddr, pciad); ctrlmem : syncram_2p generic map (tech => memtech, abits => depth, dbits => 16, sepclk => 1) port map (clk, csctrl, apbi.paddr(depth+1 downto 2), bufout(47 downto 32), pciclk, pr.sample, pr.baddr, pcictrl); end;

gpl-2.0

7ae560b08ee462505ecd501da85a4bba

0.57776

3.335927

false

marco-c/leon-nexys2

grlib-gpl-1.3.4-b4140/lib/esa/memoryctrl/memoryctrl.vhd

1

2,669

------------------------------------------------------------------------------ -- This file is a part of the GRLIB VHDL IP LIBRARY -- Copyright (C) 2003 - 2008, Gaisler Research -- Copyright (C) 2008 - 2013, Aeroflex Gaisler -- -- This program is free software; you can redistribute it and/or modify -- it under the terms of the GNU General Public License as published by -- the Free Software Foundation; either version 2 of the License, or -- (at your option) any later version. -- -- This program is distributed in the hope that it will be useful, -- but WITHOUT ANY WARRANTY; without even the implied warranty of -- MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the -- GNU General Public License for more details. -- -- You should have received a copy of the GNU General Public License -- along with this program; if not, write to the Free Software -- Foundation, Inc., 59 Temple Place, Suite 330, Boston, MA 02111-1307 USA ------------------------------------------------------------------------------ -- Entity: memctrl -- File: memctrl.vhd -- Author: Jiri Gaisler - Gaisler Research -- Description: Memory controller package ------------------------------------------------------------------------------ library ieee; use ieee.std_logic_1164.all; library grlib; use grlib.amba.all; library gaisler; use gaisler.memctrl.all; package memoryctrl is component mctrl generic ( hindex : integer := 0; pindex : integer := 0; romaddr : integer := 16#000#; rommask : integer := 16#E00#; ioaddr : integer := 16#200#; iomask : integer := 16#E00#; ramaddr : integer := 16#400#; rammask : integer := 16#C00#; paddr : integer := 0; pmask : integer := 16#fff#; wprot : integer := 0; invclk : integer := 0; fast : integer := 0; romasel : integer := 28; sdrasel : integer := 29; srbanks : integer := 4; ram8 : integer := 0; ram16 : integer := 0; sden : integer := 0; sepbus : integer := 0; sdbits : integer := 32; sdlsb : integer := 2; oepol : integer := 0; syncrst : integer := 0; pageburst : integer := 0; scantest : integer := 0; mobile : integer := 0 ); port ( rst : in std_ulogic; clk : in std_ulogic; memi : in memory_in_type; memo : out memory_out_type; ahbsi : in ahb_slv_in_type; ahbso : out ahb_slv_out_type; apbi : in apb_slv_in_type; apbo : out apb_slv_out_type; wpo : in wprot_out_type; sdo : out sdram_out_type ); end component; end;

gpl-2.0

65e3d6fcbdf13c82464e1995c4dea5ae

0.553391

3.936578

false

marco-c/leon-nexys2

grlib-gpl-1.3.4-b4140/lib/gaisler/leon3v3/mmu_dcache.vhd

1

66,774

------------------------------------------------------------------------------ -- This file is a part of the GRLIB VHDL IP LIBRARY -- Copyright (C) 2003 - 2008, Gaisler Research -- Copyright (C) 2008 - 2013, Aeroflex Gaisler -- -- This program is free software; you can redistribute it and/or modify -- it under the terms of the GNU General Public License as published by -- the Free Software Foundation; either version 2 of the License, or -- (at your option) any later version. -- -- This program is distributed in the hope that it will be useful, -- but WITHOUT ANY WARRANTY; without even the implied warranty of -- MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the -- GNU General Public License for more details. -- -- You should have received a copy of the GNU General Public License -- along with this program; if not, write to the Free Software -- Foundation, Inc., 59 Temple Place, Suite 330, Boston, MA 02111-1307 USA ----------------------------------------------------------------------------- -- Entity: mmu_dcache -- File: mmu_dcache.vhd -- Author: Jiri Gaisler - Gaisler Research -- Modified: Edvin Catovic - Gaisler Research -- Description: This unit implements the data cache controller. ------------------------------------------------------------------------------ library ieee; use ieee.std_logic_1164.all; library techmap; use techmap.gencomp.all; library grlib; use grlib.config_types.all; use grlib.config.all; use grlib.amba.all; use grlib.sparc.all; use grlib.stdlib.all; library gaisler; use gaisler.libiu.all; use gaisler.libcache.all; use gaisler.libmmu.all; use gaisler.mmuconfig.all; use gaisler.mmuiface.all; entity mmu_dcache is generic ( dsu : integer range 0 to 1 := 0; dcen : integer range 0 to 1 := 0; drepl : integer range 0 to 3 := 0; dsets : integer range 1 to 4 := 1; dlinesize : integer range 4 to 8 := 4; dsetsize : integer range 1 to 256 := 1; dsetlock : integer range 0 to 1 := 0; dsnoop : integer range 0 to 6 := 0; dlram : integer range 0 to 1 := 0; dlramsize : integer range 1 to 512 := 1; dlramstart : integer range 0 to 255 := 16#8f#; ilram : integer range 0 to 1 := 0; ilramstart : integer range 0 to 255 := 16#8e#; itlbnum : integer range 2 to 64 := 8; dtlbnum : integer range 2 to 64 := 8; tlb_type : integer range 0 to 3 := 1; memtech : integer range 0 to NTECH := 0; cached : integer := 0; mmupgsz : integer range 0 to 5 := 0; smp : integer := 0; mmuen : integer := 0); port ( rst : in std_ulogic; clk : in std_ulogic; dci : in dcache_in_type; dco : out dcache_out_type; ico : in icache_out_type; mcdi : out memory_dc_in_type; mcdo : in memory_dc_out_type; ahbsi : in ahb_slv_in_type; dcrami : out dcram_in_type; dcramo : in dcram_out_type; fpuholdn : in std_ulogic; mmudci : out mmudc_in_type; mmudco : in mmudc_out_type; sclk : in std_ulogic; ahbso : in ahb_slv_out_vector ); end; architecture rtl of mmu_dcache is constant M_EN : boolean := (mmuen = 1); constant DSNOOP2 : integer := dsnoop mod 4; constant DSNOOPSEP : boolean := (dsnoop > 3); constant M_TLB_TYPE : integer range 0 to 1 := -- either split or combined conv_integer(conv_std_logic_vector(tlb_type, 2) and conv_std_logic_vector(1, 2)); constant M_TLB_FASTWRITE : integer range 0 to 3 := -- fast writebuffer conv_integer(conv_std_logic_vector(tlb_type, 2) and conv_std_logic_vector(2, 2)); constant M_ENT_I : integer range 2 to 64 := itlbnum; -- icache tlb entries: number constant M_ENT_ILOG : integer := log2(M_ENT_I); -- icache tlb entries: address bits constant M_ENT_D : integer range 2 to 64 := dtlbnum; -- dcache tlb entries: number constant M_ENT_DLOG : integer := log2(M_ENT_D); -- dcache tlb entries: address bits constant M_ENT_C : integer range 2 to 64 := M_ENT_I; -- i/dcache tlb entries: number constant M_ENT_CLOG : integer := M_ENT_ILOG; -- i/dcache tlb entries: address bits constant DLINE_BITS : integer := log2(dlinesize); constant DOFFSET_BITS : integer := 8 +log2(dsetsize) - DLINE_BITS; constant LRR_BIT : integer := TAG_HIGH + 1; constant TAG_LOW : integer := DOFFSET_BITS + DLINE_BITS + 2; constant OFFSET_HIGH : integer := TAG_LOW - 1; constant OFFSET_LOW : integer := DLINE_BITS + 2; constant LINE_HIGH : integer := OFFSET_LOW - 1; constant LINE_LOW : integer := 2; constant LINE_ZERO : std_logic_vector(DLINE_BITS-1 downto 0) := (others => '0'); constant SETBITS : integer := log2x(DSETS); constant DLRUBITS : integer := lru_table(DSETS); constant LOCAL_RAM_START : std_logic_vector(7 downto 0) := conv_std_logic_vector(dlramstart, 8); constant ILRAM_START : std_logic_vector(7 downto 0) := conv_std_logic_vector(ilramstart, 8); constant DIR_BITS : integer := log2x(DSETS); constant bend : std_logic_vector(4 downto 2) := "101"; type rdatatype is (dtag, ddata, dddata, dctx, icache, memory, sysr , misc, mmusnoop_dtag); -- sources during cache read type vmasktype is (clearone, clearall, merge, tnew); -- valid bits operation type valid_type is array (0 to DSETS-1) of std_logic_vector(dlinesize - 1 downto 0); type write_buffer_type is record -- write buffer addr, data1, data2 : std_logic_vector(31 downto 0); size : std_logic_vector(1 downto 0); asi : std_logic_vector(3 downto 0); read : std_ulogic; lock : std_ulogic; smask : std_logic_vector(DSETS-1 downto 0);-- snoop mask end record; type dstatetype is (idle, wread, rtrans, wwrite, wtrans, wflush, asi_idtag, dblwrite, loadpend); type dcache_control_type is record -- all registers read : std_ulogic; -- access direction size : std_logic_vector(1 downto 0); -- access size req, burst, rburst, holdn, nomds, stpend : std_ulogic; xaddress : std_logic_vector(31 downto 0); -- common address buffer paddress : std_logic_vector(31 downto 0); -- physical address buffer faddr : std_logic_vector(DOFFSET_BITS - 1 downto 0); -- flush address efaddr : std_logic_vector(DOFFSET_BITS - 1 downto 0); -- error flush address dstate : dstatetype; -- FSM vector hit, valid : std_ulogic; flush : std_ulogic; -- flush in progress flush2 : std_ulogic; -- flush in progress mexc : std_ulogic; -- latched mexc bmexc : std_ulogic; -- latched mexc from burst read wb : write_buffer_type; -- write buffer asi : std_logic_vector(4 downto 0); icenable : std_ulogic; -- icache diag access rndcnt : std_logic_vector(log2x(DSETS)-1 downto 0); -- replace counter setrepl : std_logic_vector(log2x(DSETS)-1 downto 0); -- set to replace lrr : std_ulogic; dsuset : std_logic_vector(log2x(DSETS)-1 downto 0); lock : std_ulogic; lramrd : std_ulogic; ilramen : std_ulogic; cctrl : cctrltype; cctrlwr : std_ulogic; flushl2 : std_ulogic; tadj, dadj, sadj : std_logic_vector(1 downto 0); mmctrl1 : mmctrl_type1; mmctrl1wr : std_ulogic; pflush : std_logic; pflushr : std_logic; pflushaddr : std_logic_vector(VA_I_U downto VA_I_D); pflushtyp : std_logic; vaddr : std_logic_vector(31 downto 0); ready : std_logic; wbinit : std_logic; cache : std_logic; dlock : std_logic; su : std_logic; trans_op : std_logic; flush_op : std_logic; diag_op : std_logic; reqst : std_logic; set : integer range 0 to DSETS-1; noflush : std_logic; end record; type snoop_reg_type is record -- snoop control registers snoop : std_ulogic; -- snoop access to tags addr : std_logic_vector(TAG_HIGH downto OFFSET_LOW);-- snoop tag address mask : std_logic_vector(DSETS-1 downto 0);-- snoop mask snhit : std_logic_vector(0 to MAXSETS-1); end record; subtype lru_type is std_logic_vector(DLRUBITS-1 downto 0); type lru_array is array (0 to 2**DOFFSET_BITS-1) of lru_type; -- lru registers type lru_reg_type is record write : std_ulogic; waddr : std_logic_vector(DOFFSET_BITS-1 downto 0); set : std_logic_vector(SETBITS-1 downto 0); lru : lru_array; end record; subtype lock_type is std_logic_vector(0 to DSETS-1); function lru_set (lru : lru_type; lock : lock_type) return std_logic_vector is variable xlru : std_logic_vector(4 downto 0); variable set : std_logic_vector(SETBITS-1 downto 0); variable xset : std_logic_vector(1 downto 0); variable unlocked : integer range 0 to DSETS-1; begin set := (others => '0'); xlru := (others => '0'); xset := (others => '0'); xlru(DLRUBITS-1 downto 0) := lru; if dsetlock = 1 then unlocked := DSETS-1; for i in DSETS-1 downto 0 loop if lock(i) = '0' then unlocked := i; end if; end loop; end if; case DSETS is when 2 => if dsetlock = 1 then if lock(0) = '1' then xset(0) := '1'; else xset(0) := xlru(0); end if; else xset(0) := xlru(0); end if; when 3 => if dsetlock = 1 then xset := conv_std_logic_vector(lru3_repl_table(conv_integer(xlru)) (unlocked), 2); else -- xset := conv_std_logic_vector(lru3_repl_table(conv_integer(xlru)) (0), 2); xset := xlru(2) & (xlru(1) and not xlru(2)); end if; when 4 => if dsetlock = 1 then xset := conv_std_logic_vector(lru4_repl_table(conv_integer(xlru)) (unlocked), 2); else -- xset := conv_std_logic_vector(lru4_repl_table(conv_integer(xlru)) (0), 2); xset := xlru(4 downto 3); end if; when others => end case; set := xset(SETBITS-1 downto 0); return(set); end; function lru_calc (lru : lru_type; xset : std_logic_vector) return lru_type is variable new_lru : lru_type; variable xnew_lru: std_logic_vector(4 downto 0); variable xlru : std_logic_vector(4 downto 0); variable vset: std_logic_vector(SETBITS-1 downto 0); variable set: integer; begin vset := xset; set := conv_integer(vset); new_lru := (others => '0'); xnew_lru := (others => '0'); xlru := (others => '0'); xlru(DLRUBITS-1 downto 0) := lru; case DSETS is when 2 => if set = 0 then xnew_lru(0) := '1'; else xnew_lru(0) := '0'; end if; when 3 => xnew_lru(2 downto 0) := lru_3set_table(conv_integer(lru))(set); when 4 => xnew_lru(4 downto 0) := lru_4set_table(conv_integer(lru))(set); xnew_lru(SETBITS-1 downto 0) := vset; when others => end case; new_lru := xnew_lru(DLRUBITS-1 downto 0); return(new_lru); end; subtype word is std_logic_vector(31 downto 0); constant write_buffer_none : write_buffer_type := ( addr => (others => '0'), data1 => (others => '0'), data2 => (others => '0'), size => (others => '0'), asi => (others => '0'), read => '0', lock => '0', smask => (others => '0') ); constant RESET_ALL : boolean := GRLIB_CONFIG_ARRAY(grlib_sync_reset_enable_all) = 1; constant RRES : dcache_control_type := ( read => '0', size => (others => '0'), req => '0', burst => '0', rburst => '0', holdn => '1', nomds => '0', stpend => '0', xaddress => (others => '0'), paddress => (others => '0'), faddr => (others => '0'), efaddr => (others => '0'), dstate => idle, hit => '0', valid => '0', flush => '0', flush2 => '1', mexc => '0', bmexc => '0', wb => write_buffer_none, asi => (others => '0'), icenable => '0', rndcnt => (others => '0'), setrepl => (others => '0'), lrr => '0', dsuset => (others => '0'), lock => '0', lramrd => '0', ilramen => '0', cctrl => cctrl_none, cctrlwr => '0', flushl2 => '0', tadj => (others => '0'), dadj => (others => '0'), sadj => (others => '0'), mmctrl1 => mmctrl_type1_none, mmctrl1wr => '0', pflush => '0', pflushr => '0', pflushaddr => (others => '0'), pflushtyp => '0', vaddr => (others => '0'), ready => '0', wbinit => '0', cache => '0', dlock => '0', su => '0', trans_op => '0', flush_op => '0', diag_op => '0', reqst => '0', set => 0, noflush => '0' ); constant SRES : snoop_reg_type := ( snoop => '0', addr => (others => '0'), mask => (others => '0'), snhit => (others => '0') ); constant LRES : lru_reg_type := ( write => '0', waddr => (others => '0'), set => (others => '0'), lru => (others => (others => '0')) ); signal r, c : dcache_control_type; -- r is registers, c is combinational signal rs, cs : snoop_reg_type; -- rs is registers, cs is combinational signal rl, cl : lru_reg_type; -- rl is registers, cl is combinational constant ctbl : std_logic_vector(15 downto 0) := conv_std_logic_vector(cached, 16); begin dctrl : process(rst, r, rs, rl, dci, mcdo, ico, dcramo, ahbsi, fpuholdn, mmudco, ahbso) variable dcramov : dcram_out_type; variable rdatasel : rdatatype; variable maddress : std_logic_vector(31 downto 0); variable maddrlow : std_logic_vector(1 downto 0); variable edata : std_logic_vector(31 downto 0); variable size : std_logic_vector(1 downto 0); variable read : std_ulogic; variable twrite, tpwrite, tdiagwrite, ddiagwrite, dwrite : std_ulogic; variable taddr : std_logic_vector(OFFSET_HIGH downto LINE_LOW); -- tag address variable newtag : std_logic_vector(TAG_HIGH downto TAG_LOW); -- new tag variable newptag : std_logic_vector(TAG_HIGH downto TAG_LOW); -- new tag variable align_data : std_logic_vector(31 downto 0); -- aligned data variable ddatainv, rdatav, align_datav : cdatatype; variable rdata : std_logic_vector(31 downto 0); variable vmask : valid_type; --std_logic_vector((dlinesize -1) downto 0); variable enable, senable, scanen : std_logic_vector(0 to 3); variable mds : std_ulogic; variable mexc : std_ulogic; variable hit, valid, forcemiss : std_ulogic; variable flush : std_ulogic; variable iflush : std_ulogic; variable v : dcache_control_type; variable eholdn : std_ulogic; -- external hold variable snoopwe : std_ulogic; variable hcache : std_ulogic; variable lramcs, lramen, lramrd, lramwr, ilramen : std_ulogic; variable snoopaddr : std_logic_vector(OFFSET_HIGH downto OFFSET_LOW); variable flushaddr : std_logic_vector(OFFSET_HIGH downto OFFSET_LOW); variable vs : snoop_reg_type; variable dsudata : std_logic_vector(31 downto 0); variable set, eset : integer range 0 to DSETS-1; variable ddset : integer range 0 to MAXSETS-1; variable snoopset : integer range 0 to DSETS-1; variable validraw : std_logic_vector(0 to DSETS-1); variable validv, hitv : std_logic_vector(0 to MAXSETS-1); variable csnoopwe, snhit : std_logic_vector(0 to MAXSETS-1); variable ctwrite, ctpwrite, cdwrite : std_logic_vector(0 to MAXSETS-1); variable setrepl : std_logic_vector(log2x(DSETS)-1 downto 0); variable lrusetval: std_logic_vector(SETBITS-1 downto 0); variable wlrr : std_logic_vector(0 to 3); variable vl : lru_reg_type; variable diagset : std_logic_vector(TAG_LOW + SETBITS -1 downto TAG_LOW); variable lock : std_logic_vector(0 to DSETS-1); variable wlock : std_logic_vector(0 to MAXSETS-1); variable laddr : std_logic_vector(31 downto 0); -- local ram addr variable tag : cdatatype; --std_logic_vector(31 downto 0); variable ptag : cdatatype; --std_logic_vector(31 downto 0); variable rlramrd : std_ulogic; variable cache : std_ulogic; variable ctx : ctxdatatype; variable flushl : std_ulogic; variable miscdata : std_logic_vector(31 downto 0); variable pflush : std_logic; variable pflushaddr : std_logic_vector(VA_I_U downto VA_I_D); variable pflushtyp : std_logic; variable pftag : std_logic_vector(31 downto 2); variable mmudci_fsread, tagclear : std_logic; variable mmudci_trans_op : std_logic; variable mmudci_flush_op : std_logic; variable mmudci_wb_op : std_logic; variable mmudci_diag_op : std_logic; variable mmudci_su : std_logic; variable mmudci_read : std_logic; variable su : std_logic; variable mmuisdis : std_logic; variable mmudci_transdata_data : std_logic_vector(31 downto 0); variable paddress : std_logic_vector(31 downto 0); -- physical address buffer variable pagesize : integer range 0 to 3; begin -- init local variables v := r; vs := rs; dcramov := dcramo; vl := rl; vl.write := '0'; lramen := '0'; lramrd := '0'; lramwr := '0'; lramcs := '0'; laddr := (others => '0'); v.cctrlwr := '0'; ilramen := '0'; v.flush2 := r.flush; snhit := (others => '0'); pagesize := MMU_getpagesize(mmupgsz,r.mmctrl1); if ((dci.eenaddr or dci.enaddr) = '1') or (r.dstate /= idle) or ((dsu = 1) and (dci.dsuen = '1')) or (r.flush = '1') or (is_fpga(memtech) = 1) then enable := (others => '1'); else enable := (others => '0'); end if; v.mmctrl1wr := '0'; tagclear := '0'; mmuisdis := '0'; if (not M_EN) or ((r.asi(4 downto 0) = ASI_MMU_BP) or (r.mmctrl1.e = '0')) then mmuisdis := '1'; end if; if (mmuisdis = '1') then paddress := r.xaddress; else paddress := r.paddress; end if; mds := '1'; dwrite := '0'; twrite := '0'; tpwrite := '0'; ddiagwrite := '0'; tdiagwrite := '0'; v.holdn := '1'; mexc := '0'; flush := '0'; v.icenable := '0'; iflush := '0'; eholdn := ico.hold and fpuholdn; ddset := 0; vs.snoop := '0'; snoopwe := '0'; snoopaddr := ahbsi.haddr(OFFSET_HIGH downto OFFSET_LOW); flushaddr := r.xaddress(OFFSET_HIGH downto OFFSET_LOW); hcache := '0'; validv := (others => '0'); hitv := (others => '0'); cache := '0'; if (dlram = 1) then rlramrd := r.lramrd; else rlramrd := '0'; end if; miscdata := (others => '0'); pflush := '0'; pflushaddr := dci.maddress(VA_I_U downto VA_I_D); pflushtyp := PFLUSH_PAGE; pftag := (others => '0'); ctx := (others => (others => '0')); mmudci_fsread := '0'; ddatainv := (others => (others => '0')); tag := (others => (others => '0')); ptag := (others => (others => '0')); v.flushl2 := dci.flushl and not r.flush; newptag := (others => '0'); v.trans_op := r.trans_op and (not mmudco.grant); v.flush_op := r.flush_op and (not mmudco.grant); v.diag_op := r.diag_op and (not mmudco.grant); mmudci_trans_op := r.trans_op; mmudci_flush_op := r.flush_op; mmudci_diag_op := r.diag_op; mmudci_wb_op := '0'; mmudci_transdata_data := r.vaddr; mmudci_su := '0'; mmudci_read := '0'; su := '0'; rdatasel := ddata; -- read data from cache as default senable := (others => '0'); scanen := (others => mcdo.scanen); set := 0; snoopset := 0; csnoopwe := (others => '0'); ctwrite := (others => '0'); ctpwrite := (others => '0'); cdwrite := (others => '0'); wlock := (others => '0'); for i in 0 to DSETS-1 loop wlock(i) := dcramov.tag(i)(CTAG_LOCKPOS); end loop; wlrr := (others => '0'); for i in 0 to 3 loop wlrr(i) := dcramov.tag(i)(CTAG_LRRPOS); end loop; if (DSETS > 1) then setrepl := r.setrepl; else setrepl := (others => '0'); end if; -- random replacement counter if DSETS > 1 then if conv_integer(r.rndcnt) = (DSETS - 1) then v.rndcnt := (others => '0'); else v.rndcnt := r.rndcnt + 1; end if; end if; -- generate lock bits lock := (others => '0'); if dsetlock = 1 then for i in 0 to DSETS-1 loop lock(i) := dcramov.tag(i)(CTAG_LOCKPOS); end loop; end if; -- AHB snoop handling if (DSNOOP2 /= 0) then -- snoop on NONSEQ or SEQ and first word in cache line -- do not snoop during own transfers or during cache flush if (ahbsi.hready and ahbsi.hwrite and (not mcdo.bg or r.mmctrl1.e)) = '1' and ((ahbsi.htrans = HTRANS_NONSEQ) or ((ahbsi.htrans = HTRANS_SEQ) and (ahbsi.haddr(LINE_HIGH downto LINE_LOW) = LINE_ZERO))) then vs.snoop := r.cctrl.dsnoop; vs.addr := ahbsi.haddr(TAG_HIGH downto OFFSET_LOW); if (r.mmctrl1.e = '1') and (mcdo.bg = '1') then vs.mask := r.wb.smask; else vs.mask := (others => '1'); end if; end if; if DSNOOP /= 0 then for i in 0 to DSETS-1 loop senable(i) := vs.snoop or rs.snoop; end loop; end if; for i in DSETS-1 downto 0 loop if ((rs.snoop and not (r.flush or r.flush2)) = '1') then if (DSNOOP2 /= 0) and (rs.mask(i) = '1') and ((dcramov.stag(i)(TAG_HIGH downto TAG_LOW) = rs.addr(TAG_HIGH downto TAG_LOW)) ) then if DSNOOPSEP then flushaddr := rs.addr(OFFSET_HIGH downto OFFSET_LOW); else snoopaddr := rs.addr(OFFSET_HIGH downto OFFSET_LOW); end if; snoopwe := '1'; snoopset := i; snhit(i) := '1'; end if; end if; end loop; end if; vs.snhit := snhit; -- not needed, debug only -- generate access parameters during pipeline stall if ((r.holdn) = '0') or ((dsu = 1) and (dci.dsuen = '1')) then taddr := r.xaddress(OFFSET_HIGH downto LINE_LOW); elsif ((dci.enaddr and not dci.read) = '1') or (eholdn = '0') then taddr := dci.maddress(OFFSET_HIGH downto LINE_LOW); else taddr := dci.eaddress(OFFSET_HIGH downto LINE_LOW); end if; if (dci.write or not r.holdn) = '1' then maddress := r.xaddress(31 downto 0); read := r.read; size := r.size; edata := dci.maddress; mmudci_su := r.su; mmudci_read := r.read and not r.dlock; else maddress := dci.maddress(31 downto 0); read := dci.read; size := dci.size; edata := dci.edata; mmudci_su := dci.msu; mmudci_read := dci.read and not dci.lock; end if; newtag := dci.maddress(TAG_HIGH downto TAG_LOW); newptag := dci.maddress(TAG_HIGH downto TAG_LOW); vl.waddr := maddress(OFFSET_HIGH downto OFFSET_LOW); -- lru write address if (dsnoop = 6) and (r.cctrl.dsnoop = '0') then snoopaddr := taddr(OFFSET_HIGH downto OFFSET_LOW); senable := enable; end if; lrusetval := lru_set(rl.lru(conv_integer(maddress(OFFSET_HIGH downto OFFSET_LOW))), lock(0 to DSETS-1)); -- generate cache hit and valid bits if (r.mmctrl1.e = '0') then hcache := ahb_slv_dec_cache(dci.maddress, ahbso, cached); else hcache := '1'; end if; forcemiss := (not dci.asi(3)) or dci.lock; if (M_EN and (dci.asi(4 downto 0) = ASI_MMU_BP)) or (r.cctrl.dcs(0) = '0') or ((r.flush or r.flush2) = '1') then hcache := '0'; end if; hit := '0'; set := 0; for i in DSETS-1 downto 0 loop if (dcramov.tag(i)(TAG_HIGH downto TAG_LOW) = dci.maddress(TAG_HIGH downto TAG_LOW)) and ((dcramov.ctx(i) = r.mmctrl1.ctx) or (r.mmctrl1.e = '0')) then hitv(i) := '1'; end if; validv(i) := hcache and hitv(i) and (not r.flush) and (not r.flush2) and dcramov.tag(i)(dlinesize-1); validraw(i) := dcramov.tag(i)(dlinesize-1); end loop; if drepl = dir then hit := hitv(conv_integer(dci.maddress(OFFSET_HIGH+DIR_BITS downto OFFSET_HIGH+1))) and not r.flush and (not r.flush2); valid := validv(conv_integer(dci.maddress(OFFSET_HIGH+DIR_BITS downto OFFSET_HIGH+1))); else hit := orv(hitv) and not r.flush and (not r.flush2); valid := orv(validv); end if; -- force cache miss if mmu-enabled but off or BYPASS, or on flush if ((M_EN) and (dci.asi(4 downto 0) = ASI_MMU_BP)) or (r.cctrl.dcs(0) = '0') or ((r.flush or r.flush2) = '1') then hit := '0'; end if; if DSETS > 1 then if drepl = dir then set := conv_integer(dci.maddress(OFFSET_HIGH+DIR_BITS downto OFFSET_HIGH+1)); else for i in DSETS-1 downto 0 loop if (hitv(i) = '1') then set := i; end if; end loop; end if; if rlramrd = '1' then set := 1; end if; else set := 0; end if; if (dci.dsuen = '1') then diagset := r.xaddress(TAG_LOW+SETBITS-1 downto TAG_LOW); else diagset := maddress(TAG_LOW + SETBITS - 1 downto TAG_LOW); end if; case DSETS is when 1 => ddset := 0; when 3 => if conv_integer(diagset) < 3 then ddset := conv_integer(diagset); end if; when others => ddset := conv_integer(diagset); end case; if ((r.holdn and dci.enaddr) = '1') and (r.dstate = idle) then v.hit := hit; v.xaddress := dci.maddress; v.read := dci.read; v.size := dci.size; v.asi := dci.asi(4 downto 0); v.su := dci.msu; v.set := set; v.valid := valid; v.dlock := dci.lock; end if; -- Store buffer if mcdo.ready = '1' then v.wb.addr(LINE_HIGH downto 2) := r.wb.addr(LINE_HIGH downto 2) + 1; if r.stpend = '1' then v.stpend := r.req; v.wb.data1 := r.wb.data2; v.wb.lock := r.wb.lock and r.req; end if; end if; if mcdo.grant = '1' then v.req := r.burst; v.burst := '0'; end if; if (mcdo.grant and not r.wb.read and r.req) = '1' then v.wb.lock := '0'; end if; if (dlram = 1) then if ((r.holdn) = '0') or ((dsu = 1) and (dci.dsuen = '1')) then laddr := r.xaddress; elsif ((dci.enaddr and not dci.read) = '1') or (eholdn = '0') then laddr := dci.maddress; else laddr := dci.eaddress; end if; if (dci.enaddr = '1') and (dci.maddress(31 downto 24) = LOCAL_RAM_START) then lramen := '1'; end if; if ((laddr(31 downto 24) = LOCAL_RAM_START)) or ((dci.dsuen = '1') and (dci.asi(4 downto 1) = "0101")) then lramcs := '1'; end if; end if; if (ilram = 1) then if (dci.enaddr = '1') and (dci.maddress(31 downto 24) = ILRAM_START) then ilramen := '1'; end if; end if; -- cache freeze operation if (r.cctrl.ifrz and dci.intack and r.cctrl.ics(0)) = '1' then v.cctrl.ics := "01"; end if; if (r.cctrl.dfrz and dci.intack and r.cctrl.dcs(0)) = '1' then v.cctrl.dcs := "01"; end if; if (r.cctrlwr and not dci.nullify) = '1' then if (r.xaddress(7 downto 2) = "000000") and (dci.read = '0') then v.noflush := dci.maddress(30); v.cctrl.dsnoop := dci.maddress(23); flush := dci.maddress(22); iflush := dci.maddress(21); v.cctrl.burst:= dci.maddress(16); v.cctrl.dfrz := dci.maddress(5); v.cctrl.ifrz := dci.maddress(4); v.cctrl.dcs := dci.maddress(3 downto 2); v.cctrl.ics := dci.maddress(1 downto 0); end if; if (memtech = rhlib18t) and (r.xaddress(7 downto 2) = "000001") and (dci.read = '0') then v.tadj := dci.maddress(5 downto 4); v.sadj := dci.maddress(3 downto 2); v.dadj := dci.maddress(1 downto 0); end if; end if; -- main Dcache state machine case r.dstate is when idle => -- Idle state if (M_TLB_FASTWRITE /= 0) then mmudci_transdata_data := dci.maddress; end if; v.nomds := r.nomds and not eholdn; v.bmexc := '0'; if ((r.reqst = '0') and (r.stpend = '0')) or ((mcdo.ready and not r.req)= '1') then -- wait for store queue v.wb.addr := dci.maddress; v.wb.size := dci.size; v.wb.read := dci.read; v.wb.data1 := dci.edata; v.wb.lock := dci.lock and not dci.nullify and ico.hold; v.wb.asi := dci.asi(3 downto 0); if ((M_EN) and (dci.asi(4 downto 0) /= ASI_MMU_BP) and (r.mmctrl1.e = '1') and ((M_TLB_FASTWRITE /= 0) or ((dci.enaddr and eholdn and dci.lock and not dci.read) = '1'))) then if (dci.enaddr and eholdn and dci.lock and not dci.read) = '1' then -- skip address translation on store in LDST v.wb.addr := r.wb.addr(31 downto 8) & dci.maddress(7 downto 0); newptag := r.wb.addr(TAG_HIGH downto TAG_LOW); else v.wb.addr := mmudco.wbtransdata.data; newptag := mmudco.wbtransdata.data(TAG_HIGH downto TAG_LOW); end if; end if; if (dci.read and hcache) = '1' then v.wb.addr(LINE_HIGH downto 0) := (others => '0'); end if; end if; if (eholdn and (not r.nomds)) = '1' then -- avoid false path through nullify case dci.asi(4 downto 0) is when ASI_SYSR => rdatasel := sysr; when ASI_DTAG => rdatasel := dtag; when ASI_DDATA => rdatasel := dddata; when ASI_DCTX => if M_EN then rdatasel := dctx; end if; when ASI_MMUREGS => if M_EN then rdatasel := misc; end if; when ASI_MMUSNOOP_DTAG => rdatasel := mmusnoop_dtag; when others => end case; end if; if (dci.enaddr and eholdn and (not r.nomds) and not dci.nullify) = '1' then case dci.asi(4 downto 0) is when ASI_SYSR => -- system registers v.cctrlwr := not dci.read and not (dci.dsuen and not dci.eenaddr); when ASI_MMUREGS => if M_EN then if (dsu = 0) or dci.dsuen = '0' then -- clean fault valid bit if dci.read = '1' then case dci.maddress(CNR_U downto CNR_D) is when CNR_F => mmudci_fsread := '1'; when others => null; end case; end if; end if; v.mmctrl1wr := not dci.read and not (r.mmctrl1wr and dci.dsuen); end if; when ASI_ITAG | ASI_IDATA | ASI_ICTX => -- Read/write Icache tags -- CTX write has to be done through ctxnr & ASI_ITAG if (ico.flush = '1') or (dci.asi(4) = '1') then mexc := '1'; else v.dstate := asi_idtag; v.holdn := dci.dsuen; end if; when ASI_UINST | ASI_SINST => if (ilram = 1) then v.dstate := asi_idtag; v.ilramen := '1'; end if; when ASI_DFLUSH => -- flush data cache if dci.read = '0' then flush := '1'; end if; when ASI_DDATA => -- Read/write Dcache data if DSNOOPSEP then flushaddr := taddr(OFFSET_HIGH downto OFFSET_LOW); end if; if (r.flush = '1') then -- No access on flush mexc := '1'; elsif (dci.read = '0') then dwrite := '1'; ddiagwrite := '1'; end if; when ASI_DTAG => -- Read/write Dcache tags if DSNOOPSEP then flushaddr := taddr(OFFSET_HIGH downto OFFSET_LOW); end if; if (dci.size /= "10") or (r.flush = '1') then -- allow only word access mexc := '1'; elsif (dci.read = '0') then twrite := '1'; tdiagwrite := '1'; end if; when ASI_MMUSNOOP_DTAG => -- Read/write MMU physical snoop tags if DSNOOPSEP then snoopaddr := taddr(OFFSET_HIGH downto OFFSET_LOW); if (dci.size /= "10") or (r.flush = '1') then -- allow only word access mexc := '1'; elsif (dci.read = '0') then tpwrite := '1'; tdiagwrite := '1'; end if; end if; when ASI_DCTX => -- write has to be done through ctxnr & ASI_DTAG if DSNOOPSEP then flushaddr := taddr(OFFSET_HIGH downto OFFSET_LOW); end if; if (dci.size /= "10") or (r.flush = '1') or (dci.read = '0') then -- allow only word access mexc := '1'; end if; when ASI_FLUSH_PAGE => -- i/dcache flush page if dci.read = '0' then iflush := '1'; end if; if M_EN then if dci.read = '0' then flush := '1'; --pflush := '1'; pflushtyp := PFLUSH_PAGE; end if; end if; when ASI_FLUSH_CTX => -- i/dcache flush ctx if M_EN then if dci.read = '0' then flush := '1'; iflush := '1'; --pflush := '1'; pflushtyp := PFLUSH_CTX; end if; end if; when ASI_MMUFLUSHPROBE => if M_EN then if dci.read = '0' then -- flush mmudci_flush_op := '1'; v.flush_op := not mmudco.grant; v.dstate := wflush; v.vaddr := dci.maddress; v.holdn := '0'; flush := '1'; iflush := '1'; end if; end if; when ASI_MMU_DIAG => if dci.read = '0' then -- diag access mmudci_diag_op := '1'; v.diag_op := not mmudco.grant; v.vaddr := dci.maddress; end if; when others => if dci.read = '1' then -- read access v.rburst := hcache; -- and not forcemiss; if (dlram = 1) and (lramen = '1') then lramrd := '1'; elsif (ilram = 1) and (ilramen = '1') then if (ico.flush = '1') or (dci.size /= "10") then mexc := '1'; else v.dstate := asi_idtag; v.holdn := dci.dsuen; v.ilramen := '1'; end if; elsif dci.dsuen = '0' then if not ((hit and valid and not forcemiss) = '1') then -- read miss v.holdn := '0'; v.dstate := wread; v.ready := '0'; v.cache := hcache; if (not M_EN) or ((dci.asi(4 downto 0) = ASI_MMU_BP) or (r.mmctrl1.e = '0')) then -- cache disabled if mmu-enabled but off or BYPASS if ((r.stpend = '0') or ((mcdo.ready and not r.req) = '1')) then v.req := '1'; v.burst := v.rburst; end if; else -- ## mmu case > if (r.stpend = '0') or ((mcdo.ready and not r.req)= '1') then v.wbinit := '1'; -- wb init in idle v.burst := v.rburst; else v.wbinit := '0'; end if; mmudci_trans_op := '1'; -- start translation v.trans_op := not mmudco.grant; v.vaddr := dci.maddress; v.dstate := rtrans; -- ## < mmu case end if; else -- read hit if (DSETS > 1) and (drepl = lru) then vl.write := '1'; end if; cache := '1'; end if; end if; else -- write access if (dlram = 1) and (lramen = '1') then lramwr := '1'; if (dci.size = "11") then -- double store v.dstate := dblwrite; v.xaddress(2) := '1'; end if; elsif (ilram = 1) and (ilramen = '1') then if (ico.flush = '1') or (dci.size /= "10") then mexc := '1'; else v.dstate := asi_idtag; v.holdn := dci.dsuen; v.ilramen := '1'; end if; elsif dci.dsuen = '0' then v.ready := '0'; if (not M_EN) or ((dci.asi(4 downto 0) = ASI_MMU_BP) or (r.mmctrl1.e = '0')) then if ((r.stpend = '0') or ((mcdo.ready and not r.req)= '1')) then -- wait for store queue v.reqst := '1'; v.burst := dci.size(1) and dci.size(0); if (dci.size = "11") then v.dstate := dblwrite; end if; -- double store v.wb.smask := (others => '1'); else -- wait for store queue v.dstate := wwrite; v.holdn := '0'; v.wb.read := r.wb.read; end if; else -- ## mmu case > false and if ((r.stpend = '0') or ((mcdo.ready and not r.req)= '1')) and (((mmudco.wbtransdata.accexc = '0') and (M_TLB_FASTWRITE /= 0)) or (dci.lock = '1')) then v.reqst := '1'; v.burst := dci.size(1) and dci.size(0); if (dci.size = "11") then v.dstate := dblwrite; end if; -- double store v.wb.smask := (others => '1'); if hit = '1' then v.wb.smask(set) := '0'; end if; else if (r.stpend = '0') or ((mcdo.ready and not r.req)= '1') then v.wbinit := '1'; -- wb init in idle v.burst := dci.size(1) and dci.size(0); v.wb.smask := (others => '1'); if hit = '1' then v.wb.smask(set) := '0'; end if; else v.wbinit := '0'; end if; mmudci_trans_op := '1'; -- start translation v.trans_op := not mmudco.grant; v.vaddr := dci.maddress; v.holdn := '0'; v.dstate := wtrans; -- ## < mmu case end if; end if; if (hit and valid) = '1' then -- write hit dwrite := '1'; if (DSETS > 1) and (drepl = lru) then vl.write := '1'; end if; setrepl := conv_std_logic_vector(set, SETBITS); if DSNOOP2 /= 0 then if ((dci.enaddr and not dci.read) = '1') or (eholdn = '0') then v.xaddress := dci.maddress; else v.xaddress := dci.eaddress; end if; end if; end if; if (dci.size = "11") then v.xaddress(2) := '1'; end if; end if; end if; eset := set; if (DSETS > 1) then vl.set := conv_std_logic_vector(set, SETBITS); v.setrepl := conv_std_logic_vector(set, SETBITS); if (andv(validraw) = '0') and (drepl /= dir) and false then for i in DSETS-1 downto 0 loop if validraw(i) = '0' then eset := i; end if; end loop; v.setrepl := conv_std_logic_vector(eset, SETBITS); elsif ((not hit) and (not r.flush)) = '1' then case drepl is when rnd => if dsetlock = 1 then if lock(conv_integer(r.rndcnt)) = '0' then v.setrepl := r.rndcnt; else v.setrepl := conv_std_logic_vector(DSETS-1, SETBITS); for i in DSETS-1 downto 0 loop if (lock(i) = '0') and (i>conv_integer(r.rndcnt)) then v.setrepl := conv_std_logic_vector(i, SETBITS); end if; end loop; end if; else v.setrepl := r.rndcnt; end if; when dir => v.setrepl := dci.maddress(OFFSET_HIGH+log2x(DSETS) downto OFFSET_HIGH+1); when lru => v.setrepl := lrusetval; when lrr => v.setrepl := (others => '0'); if dsetlock = 1 then if lock(0) = '1' then v.setrepl(0) := '1'; else v.setrepl(0) := dcramov.tag(0)(CTAG_LRRPOS) xor dcramov.tag(1)(CTAG_LRRPOS); end if; else v.setrepl(0) := dcramov.tag(0)(CTAG_LRRPOS) xor dcramov.tag(1)(CTAG_LRRPOS); end if; if v.setrepl(0) = '0' then v.lrr := not dcramov.tag(0)(CTAG_LRRPOS); else v.lrr := dcramov.tag(0)(CTAG_LRRPOS); end if; end case; end if; if (dsetlock = 1) then if (hit and lock(set)) = '1' then v.lock := '1'; else v.lock := '0'; end if; end if; end if; end case; end if; when rtrans => if M_EN then if r.stpend = '1' then if ((mcdo.ready and not r.req) = '1') then v.ready := '1'; -- buffer store finish end if; end if; v.holdn := '0'; if mmudco.transdata.finish = '1' then -- translation error, i.e. page fault if (mmudco.transdata.accexc) = '1' then v.holdn := '1'; v.dstate := idle; mds := '0'; mexc := not r.mmctrl1.nf; else v.dstate := wread; v.cache := r.cache and mmudco.transdata.cache; v.paddress := mmudco.transdata.data; v.rburst := r.rburst and v.cache; if r.wbinit = '1' then v.wb.addr := v.paddress; --mmudco.transdata.data; v.req := '1'; v.burst := v.rburst; if v.rburst = '1' then v.wb.addr(LINE_HIGH downto 0) := (others => '0'); end if; end if; end if; end if; end if; when wread => -- read miss, wait for memory data if drepl=lru and mcdo.ready='0' and r.hit='0' then v.setrepl := lrusetval; end if; taddr := r.wb.addr(OFFSET_HIGH downto LINE_LOW); newtag := r.xaddress(TAG_HIGH downto TAG_LOW); newptag := paddress(TAG_HIGH downto TAG_LOW); v.nomds := r.nomds and not eholdn; v.holdn := v.nomds; rdatasel := memory; for i in 0 to DSETS-1 loop wlock(i) := r.lock; end loop; for i in 0 to 3 loop wlrr(i) := r.lrr; end loop; if (r.stpend = '0') and (r.ready = '0') then if (r.rburst) = '1' then if (mcdo.grant = '1') and (r.wb.addr(LINE_HIGH downto LINE_LOW) >= bend(LINE_HIGH downto LINE_LOW)) and not ((r.wb.addr(LINE_HIGH downto LINE_LOW) = bend(LINE_HIGH downto LINE_LOW)) and (mcdo.ready = '0')) then v.burst := '0'; else v.burst := r.burst; end if; end if; if mcdo.ready = '1' then if (r.cache or r.hit) = '0' then mds := r.holdn or r.nomds; v.xaddress(2) := '1'; v.holdn := '1'; else if r.wb.addr(LINE_HIGH downto LINE_LOW) = r.xaddress(LINE_HIGH downto LINE_LOW) then mds := '0'; end if; end if; dwrite := r.cache and r.cctrl.dcs(1); rdatasel := memory; mexc := mcdo.mexc; v.bmexc := r.bmexc or mcdo.mexc or dci.flushl; if r.req = '0' then twrite := r.cache and r.cctrl.dcs(1); tagclear := v.bmexc; if (((dci.enaddr and not mds) = '1') or (dci.flushl = '1') or ((dci.enaddr and twrite) = '1')) and ((r.cctrl.dcs(0) = '1') or (dlram = 1)) then v.dstate := loadpend; v.holdn := '0'; else v.dstate := idle; v.holdn := '1'; end if; else v.nomds := not r.cache; end if; tpwrite := twrite; end if; v.mexc := mcdo.mexc and not r.rburst; v.wb.data2 := mcdo.data; else if (r.ready or (mcdo.ready and not r.req)) = '1' then -- wait for store queue v.wb.addr := paddress; v.wb.size := r.size; v.burst := r.rburst; if r.rburst = '1' then v.wb.addr(LINE_HIGH downto 0) := (others => '0'); end if; v.wb.read := r.read; v.wb.data1 := dci.maddress; v.req := '1'; v.wb.lock := dci.lock; v.wb.asi := r.asi(3 downto 0); v.ready := '0'; end if; end if; when loadpend => -- return from read miss with load pending taddr := dci.maddress(OFFSET_HIGH downto LINE_LOW); if (dlram = 1) then laddr := dci.maddress; if laddr(31 downto 24) = LOCAL_RAM_START then lramcs := '1'; end if; end if; if (r.flushl2 and dci.enaddr) = '1' then v.holdn := '0'; else v.dstate := idle; end if; when dblwrite => -- second part of double store cycle edata := dci.edata; -- needed for STD store hit taddr := r.xaddress(OFFSET_HIGH downto LINE_LOW); if (dlram = 1) and (rlramrd = '1') then laddr := r.xaddress; lramwr := '1'; else if r.hit = '1' then dwrite := r.valid; end if; v.wb.data2 := dci.edata; end if; if (dci.flushl and ico.hold) = '1' then v.dstate := loadpend; v.holdn := '0'; elsif ico.hold = '0' then v.reqst := '0'; else v.dstate := idle; end if; when asi_idtag => -- icache diag and inst local ram access rdatasel := icache; v.icenable := '1'; v.holdn := dci.dsuen; if ico.diagrdy = '1' then v.dstate := loadpend; v.icenable := '0'; v.ilramen := '0'; if (dsu = 0) or ((dsu = 1) and (dci.dsuen = '0')) then mds := not r.read; end if; end if; when wtrans => edata := dci.edata; -- needed for STD store hit taddr := r.xaddress(OFFSET_HIGH downto LINE_LOW); newtag := r.xaddress(TAG_HIGH downto TAG_LOW); if M_EN then if r.stpend = '1' then if ((mcdo.ready and not r.req) = '1') then v.ready := '1'; -- buffer store finish end if; end if; v.holdn := '0'; if mmudco.transdata.finish = '1' then if (mmudco.transdata.accexc) = '1' then v.holdn := '1'; v.dstate := idle; mds := '0'; mexc := not r.mmctrl1.nf; tagclear := r.hit; twrite := tagclear; if (twrite = '1') and (((dci.enaddr and not mds) = '1') or ((dci.eenaddr and mds and eholdn) = '1')) and (r.cctrl.dcs(0) = '1') then v.dstate := loadpend; v.holdn := '0'; end if; else v.dstate := wwrite; v.cache := mmudco.transdata.cache; v.paddress := mmudco.transdata.data; if (r.wbinit) = '1' then v.wb.data2 := dci.edata; v.wb.addr := mmudco.transdata.data; v.dstate := idle; v.holdn := '1'; if (dci.nullify = '0') then v.req := '1'; v.stpend := '1'; else v.reqst := '1'; end if; v.burst := r.size(1) and r.size(0) and not v.wb.addr(2); if (r.hit = '1') and (r.size = "11") then -- write hit dwrite := r.valid; end if; end if; end if; end if; end if; when wwrite => -- wait for store buffer to empty (store access) edata := dci.edata; -- needed for STD store hit if ( (dci.lock = '1')) and (dci.nullify = '1') then v.dstate := idle; v.wb.lock := '0'; elsif ((v.ready or (mcdo.ready and not r.req)) = '1') or ( (dci.lock = '1')) then -- store queue emptied if (r.hit = '1') and (r.size = "11") then -- write hit taddr := r.xaddress(OFFSET_HIGH downto LINE_LOW); dwrite := r.valid; end if; v.dstate := idle; v.burst := r.size(1) and r.size(0); if (dci.nullify = '0') then v.reqst := '1'; end if; v.wb.addr := paddress; v.wb.size := r.size; v.wb.read := r.read; v.wb.data1 := dci.maddress; v.wb.lock := dci.lock; v.wb.data2 := dci.edata; v.wb.asi := r.asi(3 downto 0); if r.size = "11" then v.wb.addr(2) := '0'; end if; v.wb.smask := (others => '1'); if r.hit = '1' then v.wb.smask(r.set) := '0'; end if; else -- hold cpu until buffer empty v.holdn := '0'; end if; when wflush => v.holdn := '0'; if mmudco.transdata.finish = '1' then v.dstate := idle; v.holdn := '1'; end if; when others => v.dstate := idle; end case; v.req := v.req or v.reqst; v.stpend := v.stpend or v.reqst; v.reqst := '0'; if (dlram = 1) then v.lramrd := lramcs; end if; -- read local ram data -- select data to return on read access -- align if byte/half word read from cache or memory. if (dsu = 1) and (dci.dsuen = '1') then v.dsuset := conv_std_logic_vector(ddset, SETBITS); case dci.asi(4 downto 0) is when ASI_ITAG | ASI_IDATA => v.icenable := not ico.diagrdy; rdatasel := icache; when ASI_DTAG => tdiagwrite := not dci.eenaddr and dci.enaddr and dci.write; twrite := not dci.eenaddr and dci.enaddr and dci.write; rdatasel := dtag; when ASI_MMUSNOOP_DTAG => if DSNOOPSEP then snoopaddr := taddr(OFFSET_HIGH downto OFFSET_LOW); end if; tdiagwrite := not dci.eenaddr and dci.enaddr and dci.write; tpwrite := not dci.eenaddr and dci.enaddr and dci.write; rdatasel := mmusnoop_dtag; senable := (others => '1'); when ASI_DDATA => if M_EN then ddiagwrite := not dci.eenaddr and dci.enaddr and dci.write; dwrite := not dci.eenaddr and dci.enaddr and dci.write; rdatasel := dddata; end if; when ASI_UDATA | ASI_SDATA => lramwr := not dci.eenaddr and dci.enaddr and dci.write; when ASI_MMUREGS => rdatasel := misc; when others => end case; end if; -- read if M_EN then case dci.maddress(CNR_U downto CNR_D) is when CNR_CTRL => miscdata(MMCTRL_E) := r.mmctrl1.e; miscdata(MMCTRL_NF) := r.mmctrl1.nf; miscdata(MMCTRL_PSO) := r.mmctrl1.pso; miscdata(MMCTRL_VER_U downto MMCTRL_VER_D) := "0001"; miscdata(MMCTRL_IMPL_U downto MMCTRL_IMPL_D) := "0000"; miscdata(23 downto 21) := conv_std_logic_vector(M_ENT_ILOG,3); miscdata(20 downto 18) := conv_std_logic_vector(M_ENT_DLOG,3); if M_TLB_TYPE = 0 then miscdata(MMCTRL_TLBSEP) := '1'; else miscdata(23 downto 21) := conv_std_logic_vector(M_ENT_CLOG,3); miscdata(20 downto 18) := (others => '0'); end if; miscdata(MMCTRL_TLBDIS) := r.mmctrl1.tlbdis; miscdata(MMCTRL_PGSZ_U downto MMCTRL_PGSZ_D) := conv_std_logic_vector(pagesize,2); -- r.mmctrl1.pagesize; --custom when CNR_CTXP => miscdata(MMCTXP_U downto MMCTXP_D) := r.mmctrl1.ctxp; when CNR_CTX => miscdata(MMCTXNR_U downto MMCTXNR_D) := r.mmctrl1.ctx; when CNR_F => miscdata(FS_OW) := mmudco.mmctrl2.fs.ow; miscdata(FS_FAV) := mmudco.mmctrl2.fs.fav; miscdata(FS_FT_U downto FS_FT_D) := mmudco.mmctrl2.fs.ft; miscdata(FS_AT_LS) := mmudco.mmctrl2.fs.at_ls; miscdata(FS_AT_ID) := mmudco.mmctrl2.fs.at_id; miscdata(FS_AT_SU) := mmudco.mmctrl2.fs.at_su; miscdata(FS_L_U downto FS_L_D) := mmudco.mmctrl2.fs.l; miscdata(FS_EBE_U downto FS_EBE_D) := mmudco.mmctrl2.fs.ebe; when CNR_FADDR => miscdata(VA_I_U downto VA_I_D) := mmudco.mmctrl2.fa; when others => null; end case; end if; rdata := (others => '0'); rdatav := (others => (others => '0')); align_data := (others => '0'); align_datav := (others => (others => '0')); maddrlow := maddress(1 downto 0); -- stupid Synopsys VSS bug ... case rdatasel is when misc => if M_EN then set := 0; rdatav(0) := miscdata; end if; when dddata => rdatav := dcramov.data; if dci.dsuen = '1' then set := conv_integer(r.dsuset); else set := ddset; end if; when dtag => rdatav := dcramov.tag; if dci.dsuen = '1' then set := conv_integer(r.dsuset); else set := ddset; end if; when mmusnoop_dtag => rdatav := dcramov.stag; if dci.dsuen = '1' then set := conv_integer(r.dsuset); else set := ddset; end if; when dctx => --rdata(M_CTX_SZ-1 downto 0) := dcramov.dtramout(ddset).ctx; when icache => rdatav(0) := ico.diagdata; set := 0; when ddata | memory => if rdatasel = memory then rdatav(0) := mcdo.data; set := 0; else for i in 0 to DSETS-1 loop rdatav(i) := dcramov.data(i); end loop; end if; when sysr => set := 0; case dci.maddress(3 downto 2) is when "00" => rdatav(0)(30) := r.noflush; rdatav(0)(23) := r.cctrl.dsnoop; if dsnoop > 4 then rdatav(0)(17) := '1'; end if; rdatav(0)(16 downto 14) := r.cctrl.burst & ico.flush & r.flush; rdatav(0)(5 downto 0) := r.cctrl.dfrz & r.cctrl.ifrz & r.cctrl.dcs & r.cctrl.ics; when "01" => rdatav(0)(7 downto 0) := "00" & r.tadj & r.sadj & r.dadj; when "10" => rdatav(0) := ico.cfg; when others => rdatav(0) := cache_cfg(drepl, dsets, dlinesize, dsetsize, dsetlock, dsnoop, dlram, dlramsize, dlramstart, mmuen); end case; end case; -- select which data to update the data cache with for i in 0 to DSETS-1 loop case size is -- merge data during partial write when "00" => case maddrlow is when "00" => ddatainv(i) := edata(7 downto 0) & dcramov.data(i)(23 downto 0); when "01" => ddatainv(i) := dcramov.data(i)(31 downto 24) & edata(7 downto 0) & dcramov.data(i)(15 downto 0); when "10" => ddatainv(i) := dcramov.data(i)(31 downto 16) & edata(7 downto 0) & dcramov.data(i)(7 downto 0); when others => ddatainv(i) := dcramov.data(i)(31 downto 8) & edata(7 downto 0); end case; when "01" => if maddress(1) = '0' then ddatainv(i) := edata(15 downto 0) & dcramov.data(i)(15 downto 0); else ddatainv(i) := dcramov.data(i)(31 downto 16) & edata(15 downto 0); end if; when others => ddatainv(i) := edata; end case; end loop; -- handle double load with pipeline hold if (r.dstate = idle) and (r.nomds = '1') then rdatav(0) := r.wb.data2; mexc := r.mexc; set := 0; end if; -- Handle AHB retry. Re-generate bus request and burst if mcdo.retry = '1' then v.req := '1'; if r.wb.read = '0' then v.burst := r.wb.size(0) and r.wb.size(1) and not r.wb.addr(2); else v.burst := ((r.rburst) and not andv(r.wb.addr(LINE_HIGH downto LINE_LOW))) or (not r.rburst and r.wb.size(0) and r.wb.size(1) and not r.wb.addr(2)); end if; end if; -- Generate new valid bits if r.flush = '1' then twrite := '0'; dwrite := '0'; end if; vmask := (others => (others => '1')); if twrite = '1' then if tagclear = '1' then vmask := (others => (others => '0')); end if; if (DSETS>1) and (drepl = lru) and (tdiagwrite = '0') then vl.write := '1'; vl.set := setrepl; end if; end if; if (DSETS>1) and (drepl = lru) and (rl.write = '1') then vl.lru(conv_integer(rl.waddr)) := lru_calc(rl.lru(conv_integer(rl.waddr)), rl.set); end if; if tdiagwrite = '1' then -- diagnostic tag write if (dsu = 1) and (dci.dsuen = '1') then vmask := (others => dci.maddress(dlinesize - 1 downto 0)); else vmask := (others => dci.edata(dlinesize - 1 downto 0)); newtag(TAG_HIGH downto TAG_LOW) := dci.edata(TAG_HIGH downto TAG_LOW); newptag(TAG_HIGH downto TAG_LOW) := dci.edata(TAG_HIGH downto TAG_LOW); for i in 0 to 3 loop wlrr(i) := dci.edata(CTAG_LRRPOS); end loop; for i in 0 to DSETS-1 loop wlock(i) := dci.edata(CTAG_LOCKPOS); end loop; end if; end if; -- mmureg write if r.mmctrl1wr = '1' then case r.xaddress(CNR_U downto CNR_D) is when CNR_CTRL => v.mmctrl1.e := dci.maddress(MMCTRL_E); v.mmctrl1.nf := dci.maddress(MMCTRL_NF); v.mmctrl1.pso := dci.maddress(MMCTRL_PSO); v.mmctrl1.tlbdis := dci.maddress(MMCTRL_TLBDIS); v.mmctrl1.pagesize := dci.maddress(MMCTRL_PGSZ_U downto MMCTRL_PGSZ_D); --custom -- Note: before tlb disable tlb flush is required !!! when CNR_CTXP => v.mmctrl1.ctxp := dci.maddress(MMCTXP_U downto MMCTXP_D); when CNR_CTX => v.mmctrl1.ctx := dci.maddress(MMCTXNR_U downto MMCTXNR_D); when CNR_F => null; when CNR_FADDR => null; when others => null; end case; end if; -- cache flush if ((dci.flush or dci.flushl or flush) = '1') and (dcen /= 0) then v.flush := not r.noflush; v.faddr := (others => '0'); if (dci.flushl = '1') then v.flush := '1'; v.faddr := r.efaddr; end if; end if; if eholdn = '1' then v.efaddr := v.xaddress(OFFSET_HIGH downto OFFSET_LOW); end if; if (r.flush = '1') and (dcen /= 0) then twrite := '1'; vmask := (others => (others => '0')); v.faddr := r.faddr +1; newtag(TAG_HIGH downto TAG_LOW) := (others => '0'); newptag := (others => '0'); if DSNOOPSEP then flushaddr := r.faddr; end if; taddr(OFFSET_HIGH downto OFFSET_LOW) := r.faddr; wlrr := (others => '0'); if ((r.faddr(DOFFSET_BITS -1) and not v.faddr(DOFFSET_BITS -1)) or r.flushl2) = '1' then v.flush := '0'; end if; end if; -- update cache with memory data during read miss if read = '1' then for i in 0 to DSETS-1 loop ddatainv(i) := mcdo.data; end loop; end if; -- cache write signals if twrite = '1' then if tdiagwrite = '1' then ctwrite(ddset) := '1'; else ctwrite(conv_integer(setrepl)) := '1'; end if; end if; if DSNOOPSEP then if tpwrite = '1' then if tdiagwrite = '1' then ctpwrite(ddset) := '1'; else ctpwrite(conv_integer(setrepl)) := '1'; end if; end if; end if; if dwrite = '1' then if ddiagwrite = '1' then cdwrite(ddset) := '1'; else cdwrite(conv_integer(setrepl)) := '1'; end if; end if; if (r.flush and twrite) = '1' then -- flush ctwrite := (others => '1'); wlrr := (others => '0'); wlock := (others => '0'); if DSNOOPSEP then ctpwrite := (others => '1'); end if; end if; csnoopwe := (others => '0'); flushl := '0'; if ((snoopwe and not mcdo.scanen) = '1') then csnoopwe := snhit; end if; if DSNOOPSEP then csnoopwe := csnoopwe or ctwrite; if orv(snhit) = '1' then flushl := '1'; end if; -- flush tag on snoop hit end if; if r.flush2 = '1' then vl.lru := (others => (others => '0')); end if; -- reset if (not RESET_ALL) and (rst = '0') then v.dstate := idle; v.stpend := '0'; v.req := '0'; v.burst := '0'; v.read := '0'; v.flush := '0'; v.nomds := '0'; v.holdn := '1'; v.rndcnt := (others => '0'); v.setrepl := (others => '0'); v.dsuset := (others => '0'); v.flush2 := '1'; v.lrr := '0'; v.lock := '0'; v.ilramen := '0'; v.cctrl.dcs := "00"; v.cctrl.ics := "00"; v.cctrl.burst := '0'; v.cctrl.dsnoop := '0'; v.tadj := (others => '0'); v.dadj := (others => '0'); v.sadj := (others => '0'); --if M_EN then v.mmctrl1.e := '0'; v.mmctrl1.nf := '0'; v.mmctrl1.ctx := (others => '0'); v.mmctrl1.tlbdis := '0'; v.mmctrl1.pso := '0'; v.trans_op := '0'; v.flush_op := '0'; v.diag_op := '0'; v.pflush := '0'; v.pflushr := '0'; v.mmctrl1.pagesize := (others => '0'); --end if; v.mmctrl1.bar := (others => '0'); v.faddr := (others => '0'); v.reqst := '0'; v.cache := '0'; v.wb.lock := '0'; v.wb.data1 := (others => '0'); v.wb.data2 := (others => '0'); v.noflush := '0'; v.mexc := '0'; end if; if dsnoop = 0 then v.cctrl.dsnoop := '0'; end if; if not M_EN then v.mmctrl1 := mmctrl_type1_none; end if; -- kill MMU regs if not enabled -- Drive signals c <= v; cs <= vs; -- register inputs cl <= vl; -- tag ram inputs senable := senable and not scanen; enable := enable and not scanen; if mcdo.scanen = '1' then ctpwrite := (others => '0'); end if; for i in 0 to DSETS-1 loop tag(i)(dlinesize-1 downto 0) := vmask(i); tag(i)(TAG_HIGH downto TAG_LOW) := newtag(TAG_HIGH downto TAG_LOW); tag(i)(CTAG_LRRPOS) := wlrr(i); tag(i)(CTAG_LOCKPOS) := wlock(i); ctx(i) := r.mmctrl1.ctx; ptag(i)(TAG_HIGH downto TAG_LOW) := newptag(TAG_HIGH downto TAG_LOW); end loop; dcrami.tag <= tag; -- virtual tag dcrami.ptag <= ptag; -- physical tag dcrami.ctx <= ctx; -- context dcrami.tenable <= enable; -- virtual tag ram enable dcrami.twrite <= ctwrite; -- virtual tag ram write (port 1) dcrami.tpwrite <= ctpwrite; -- virtual tag ram write (port 2) dcrami.flush <= r.flush or flushl; dcrami.senable <= senable; -- physical tag ram enable dcrami.swrite <= csnoopwe; -- physical tag ram write dcrami.saddress(19 downto (OFFSET_HIGH - OFFSET_LOW +1)) <= zero32(19 downto (OFFSET_HIGH - OFFSET_LOW +1)); dcrami.saddress(OFFSET_HIGH - OFFSET_LOW downto 0) <= snoopaddr; dcrami.faddress(19 downto (OFFSET_HIGH - OFFSET_LOW +1)) <= zero32(19 downto (OFFSET_HIGH - OFFSET_LOW +1)); dcrami.faddress(OFFSET_HIGH - OFFSET_LOW downto 0) <= flushaddr; -- data ram inputs dcrami.denable <= enable; dcrami.address(19 downto (OFFSET_HIGH - LINE_LOW + 1)) <= zero32(19 downto (OFFSET_HIGH - LINE_LOW + 1)); dcrami.address(OFFSET_HIGH - LINE_LOW downto 0) <= taddr; dcrami.data <= ddatainv; dcrami.dwrite <= cdwrite; dcrami.ldramin.address(23 downto 2) <= laddr(23 downto 2); dcrami.ldramin.enable <= (lramcs or lramwr) and not mcdo.scanen; dcrami.ldramin.read <= rlramrd; dcrami.ldramin.write <= lramwr; dcrami.tdiag <= mcdo.testen & mcdo.scanen & r.tadj; dcrami.sdiag <= mcdo.testen & mcdo.scanen & r.sadj; dcrami.ddiag <= mcdo.testen & mcdo.scanen & r.dadj; -- memory controller inputs mcdi.address <= r.wb.addr; mcdi.data <= r.wb.data1; mcdi.burst <= r.burst; mcdi.size <= r.wb.size; mcdi.read <= r.wb.read; mcdi.asi <= r.wb.asi; mcdi.lock <= r.wb.lock; mcdi.req <= r.req; mcdi.cache <= r.cache; -- diagnostic instruction cache access dco.icdiag.flush <= iflush; dco.icdiag.pflush <= pflush; dco.icdiag.pflushaddr <= pflushaddr; dco.icdiag.pflushtyp <= pflushtyp; dco.icdiag.read <= read; dco.icdiag.tag <= not r.asi(0); dco.icdiag.ctx <= r.asi(4); --ASI_ICTX "10101" dco.icdiag.addr <= r.xaddress; dco.icdiag.enable <= r.icenable; dco.icdiag.ilramen <= r.ilramen; dco.icdiag.cctrl <= r.cctrl; dco.icdiag.scanen <= mcdo.scanen; -- IU data cache inputs dco.data <= rdatav; dco.mexc <= mexc; dco.set <= conv_std_logic_vector(set, 2); dco.hold <= r.holdn; dco.mds <= mds; dco.werr <= mcdo.werr; dco.cache <= cache; dco.hit <= r.hit; if r.dstate = idle then dco.idle <= not r.stpend; else dco.idle <= '0'; end if; dco.scanen <= mcdo.scanen; dco.testen <= mcdo.testen; -- MMU mmudci.trans_op <= mmudci_trans_op; mmudci.transdata.data <= mmudci_transdata_data; --r.vaddr; mmudci.transdata.su <= mmudci_su; mmudci.transdata.read <= mmudci_read; mmudci.transdata.isid <= id_dcache; mmudci.transdata.wb_data <= dci.maddress; mmudci.flush_op <= mmudci_flush_op; mmudci.wb_op <= mmudci_wb_op; mmudci.diag_op <= mmudci_diag_op; mmudci.fsread <= mmudci_fsread; mmudci.mmctrl1 <= r.mmctrl1; mmudci.testin <= ahbsi.testin; end process; -- Local registers reg1 : process(clk) begin if rising_edge(clk) then r <= c; if RESET_ALL and (rst = '0') then r <= RRES; end if; end if; end process; sn2 : if DSNOOP2 /= 0 generate reg2 : process(sclk) begin if rising_edge(sclk) then rs <= cs; if RESET_ALL and (rst = '0') then rs <= SRES; end if; end if; end process; end generate; nosn2 : if DSNOOP2 = 0 generate rs.snoop <= '0'; rs.addr <= (others => '0'); rs.snhit <= (others => '0'); rs.mask <= (others => '0'); end generate; reg2 : if (DSETS>1) and (drepl = lru) generate reg2 : process(clk) begin if rising_edge(clk) then rl <= cl; if RESET_ALL and (rst = '0') then rl <= LRES; end if; end if; end process; end generate; noreg2 : if (DSETS = 1) or (drepl /= lru) generate rl.write <= '0'; rl.waddr <= (others => '0'); rl.set <= (others => '0'); rl.lru <= (others => (others => '0')); end generate; -- pragma translate_off chk : process begin assert not ((DSETS > 2) and (drepl = lrr)) report "Wrong data cache configuration detected: LRR replacement requires 2 ways" severity failure; assert not ((DSETS = 3) and (drepl = dir)) report "Wrong data cache configuration detected: Direct replacement requires 2 or 4 ways" severity failure; wait; end process; -- pragma translate_on end ;

gpl-2.0

d36eb533fdb306c9a622c23fd50e5223

0.525459

3.459434

false

marco-c/leon-nexys2

grlib-gpl-1.3.4-b4140/lib/eth/core/greth_tx.vhd

1

16,823

------------------------------------------------------------------------------ -- This file is a part of the GRLIB VHDL IP LIBRARY -- Copyright (C) 2003 - 2008, Gaisler Research -- Copyright (C) 2008 - 2013, Aeroflex Gaisler -- -- This program is free software; you can redistribute it and/or modify -- it under the terms of the GNU General Public License as published by -- the Free Software Foundation; either version 2 of the License, or -- (at your option) any later version. -- -- This program is distributed in the hope that it will be useful, -- but WITHOUT ANY WARRANTY; without even the implied warranty of -- MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the -- GNU General Public License for more details. -- -- You should have received a copy of the GNU General Public License -- along with this program; if not, write to the Free Software -- Foundation, Inc., 59 Temple Place, Suite 330, Boston, MA 02111-1307 USA ----------------------------------------------------------------------------- -- Entity: greth_tx -- File: greth_tx.vhd -- Author: Marko Isomaki -- Description: Ethernet transmitter ------------------------------------------------------------------------------ library ieee; use ieee.std_logic_1164.all; library grlib; use grlib.stdlib.all; library eth; use eth.grethpkg.all; entity greth_tx is generic( ifg_gap : integer := 24; attempt_limit : integer := 16; backoff_limit : integer := 10; nsync : integer range 1 to 2 := 2; rmii : integer range 0 to 1 := 0); port( rst : in std_ulogic; clk : in std_ulogic; txi : in host_tx_type; txo : out tx_host_type ); attribute sync_set_reset of rst : signal is "true"; end entity; architecture rtl of greth_tx is function mirror2(din : in std_logic_vector(3 downto 0)) return std_logic_vector is variable do : std_logic_vector(3 downto 0); begin do(3) := din(0); do(2) := din(1); do(1) := din(2); do(0) := din(3); return do; end function; function init_ifg( ifg_gap : in integer; rmii : in integer) return integer is begin if rmii = 0 then return log2(ifg_gap); else return log2(ifg_gap*20); end if; end function; constant maxattempts : std_logic_vector(4 downto 0) := conv_std_logic_vector(attempt_limit, 5); --transmitter constants constant ifg_bits : integer := init_ifg(ifg_gap, rmii); constant ifg_p1 : std_logic_vector(ifg_bits-1 downto 0) := conv_std_logic_vector((ifg_gap)/3, ifg_bits); constant ifg_p2 : std_logic_vector(ifg_bits-1 downto 0) := conv_std_logic_vector((ifg_gap*2)/3, ifg_bits); constant ifg_p1_r100 : std_logic_vector(ifg_bits-1 downto 0) := conv_std_logic_vector((ifg_gap*2)/3, ifg_bits); constant ifg_p2_r100 : std_logic_vector(ifg_bits-1 downto 0) := conv_std_logic_vector(rmii*(ifg_gap*4)/3, ifg_bits); constant ifg_p1_r10 : std_logic_vector(ifg_bits-1 downto 0) := conv_std_logic_vector(rmii*(ifg_gap*20)/3, ifg_bits); constant ifg_p2_r10 : std_logic_vector(ifg_bits-1 downto 0) := conv_std_logic_vector(rmii*(ifg_gap*40)/3, ifg_bits); function ifg_sel( rmii : in integer; p1 : in integer; speed : in std_ulogic) return std_logic_vector is begin if p1 = 1 then if rmii = 0 then return ifg_p1; else if speed = '1' then return ifg_p1_r100; else return ifg_p1_r10; end if; end if; else if rmii = 0 then return ifg_p2; else if speed = '1' then return ifg_p2_r100; else return ifg_p2_r10; end if; end if; end if; end function; --transmitter types type tx_state_type is (idle, preamble, sfd, data1, data2, pad1, pad2, fcs, fcs2, finish, calc_backoff, wait_backoff, send_jam, send_jam2, check_attempts); type def_state_type is (monitor, def_on, ifg1, ifg2, frame_waitingst); type tx_reg_type is record --deference process def_state : def_state_type; ifg_cycls : std_logic_vector(ifg_bits-1 downto 0); deferring : std_ulogic; was_transmitting : std_ulogic; --tx process main_state : tx_state_type; transmitting : std_ulogic; tx_en : std_ulogic; txd : std_logic_vector(3 downto 0); cnt : std_logic_vector(3 downto 0); icnt : std_logic_vector(1 downto 0); crc : std_logic_vector(31 downto 0); crc_en : std_ulogic; byte_count : std_logic_vector(10 downto 0); slot_count : std_logic_vector(6 downto 0); random : std_logic_vector(9 downto 0); delay_val : std_logic_vector(9 downto 0); retry_cnt : std_logic_vector(4 downto 0); status : std_logic_vector(1 downto 0); data : std_logic_vector(31 downto 0); --synchronization read : std_ulogic; done : std_ulogic; restart : std_ulogic; start : std_logic_vector(nsync downto 0); read_ack : std_logic_vector(nsync-1 downto 0); crs : std_logic_vector(1 downto 0); col : std_logic_vector(1 downto 0); fullduplex : std_logic_vector(1 downto 0); --rmii crs_act : std_ulogic; crs_prev : std_ulogic; speed : std_logic_vector(1 downto 0); rcnt : std_logic_vector(3 downto 0); switch : std_ulogic; txd_msb : std_logic_vector(1 downto 0); zero : std_ulogic; rmii_crc_en : std_ulogic; end record; --transmitter signals signal r, rin : tx_reg_type; signal txrst : std_ulogic; signal vcc : std_ulogic; --attribute sync_set_reset : string; attribute sync_set_reset of txrst : signal is "true"; begin vcc <= '1'; tx_rst : eth_rstgen port map(rst, clk, vcc, txrst, open); tx : process(txrst, r, txi) is variable collision : std_ulogic; variable frame_waiting : std_ulogic; variable index : integer range 0 to 7; variable start : std_ulogic; variable read_ack : std_ulogic; variable v : tx_reg_type; variable crs : std_ulogic; variable col : std_ulogic; variable tx_done : std_ulogic; begin v := r; frame_waiting := '0'; tx_done := '0'; v.rmii_crc_en := '0'; --synchronization v.col(1) := r.col(0); v.col(0) := txi.rx_col; v.crs(1) := r.crs(0); v.crs(0) := txi.rx_crs; v.fullduplex(0) := txi.full_duplex; v.fullduplex(1) := r.fullduplex(0); v.start(0) := txi.start; v.read_ack(0) := txi.readack; if nsync = 2 then v.start(1) := r.start(0); v.read_ack(1) := r.read_ack(0); end if; start := r.start(nsync) xor r.start(nsync-1); read_ack := not (r.read xor r.read_ack(nsync-1)); --crc generation if (r.crc_en = '1') and ((rmii = 0) or (r.rmii_crc_en = '1')) then v.crc := calccrc(r.txd, r.crc); end if; --rmii if rmii = 0 then col := r.col(1); crs := r.crs(1); tx_done := '1'; else v.crs_prev := r.crs(1); if (r.crs(0) and not r.crs_act) = '1' then v.crs_act := '1'; end if; if (r.crs(1) or r.crs(0)) = '0' then v.crs_act := '0'; end if; crs := r.crs(1) and not ((not r.crs_prev) and r.crs_act); col := crs and r.tx_en; v.speed(1) := r.speed(0); v.speed(0) := txi.speed; if r.tx_en = '1' then v.rcnt := r.rcnt - 1; if r.speed(1) = '1' then v.switch := not r.switch; if r.switch = '1' then tx_done := '1'; v.rmii_crc_en := '1'; end if; if r.switch = '0' then v.txd(1 downto 0) := r.txd_msb; end if; else v.zero := '0'; if r.rcnt = "0001" then v.zero := '1'; end if; if r.zero = '1' then v.switch := not r.switch; v.rcnt := "1001"; if r.switch = '0' then v.txd(1 downto 0) := r.txd_msb; end if; end if; if (r.switch and r.zero) = '1' then tx_done := '1'; v.rmii_crc_en := '1'; end if; end if; end if; end if; collision := col and not r.fullduplex(1); --main fsm case r.main_state is when idle => v.transmitting := '0'; if rmii = 1 then v.rcnt := "1001"; v.switch := '0'; end if; if (start and not r.deferring) = '1' then v.main_state := preamble; v.transmitting := '1'; v.tx_en := '1'; v.byte_count := (others => '1'); v.status := (others => '0'); v.read := not r.read; v.start(nsync) := r.start(nsync-1); elsif start = '1' then frame_waiting := '1'; end if; v.txd := "0101"; v.cnt := "1110"; when preamble => if tx_done = '1' then v.cnt := r.cnt - 1; if r.cnt = "0000" then v.txd := "1101"; v.main_state := sfd; end if; if collision = '1' then v.main_state := send_jam; end if; end if; when sfd => if tx_done = '1' then v.main_state := data1; v.icnt := (others => '0'); v.crc_en := '1'; v.crc := (others => '1'); v.byte_count := (others => '0'); v.txd := txi.data(27 downto 24); if (read_ack and txi.valid) = '0' then v.status(0) := '1'; v.main_state := finish; v.tx_en := '0'; else v.data := txi.data; v.read := not r.read; end if; if collision = '1' then v.main_state := send_jam; end if; end if; when data1 => index := conv_integer(r.icnt); if tx_done = '1' then v.byte_count := r.byte_count + 1; v.main_state := data2; v.icnt := r.icnt + 1; case index is when 0 => v.txd := r.data(31 downto 28); when 1 => v.txd := r.data(23 downto 20); when 2 => v.txd := r.data(15 downto 12); when 3 => v.txd := r.data(7 downto 4); when others => null; end case; if v.byte_count = txi.len then v.tx_en := '1'; if conv_integer(v.byte_count) >= 60 then v.main_state := fcs; v.cnt := (others => '0'); else v.main_state := pad1; end if; elsif index = 3 then if (read_ack and txi.valid) = '0' then v.status(0) := '1'; v.main_state := finish; v.tx_en := '0'; else v.data := txi.data; v.read := not r.read; end if; end if; if collision = '1' then v.main_state := send_jam; end if; end if; when data2 => index := conv_integer(r.icnt); if tx_done = '1' then v.main_state := data1; case index is when 0 => v.txd := r.data(27 downto 24); when 1 => v.txd := r.data(19 downto 16); when 2 => v.txd := r.data(11 downto 8); when 3 => v.txd := r.data(3 downto 0); when others => null; end case; if collision = '1' then v.main_state := send_jam; end if; end if; when pad1 => if tx_done = '1' then v.main_state := pad2; if collision = '1' then v.main_state := send_jam; end if; end if; when pad2 => if tx_done = '1' then v.byte_count := r.byte_count + 1; if conv_integer(v.byte_count) = 60 then v.main_state := fcs; v.cnt := (others => '0'); else v.main_state := pad1; end if; if collision = '1' then v.main_state := send_jam; end if; end if; when fcs => if tx_done = '1' then v.cnt := r.cnt + 1; v.crc_en := '0'; index := conv_integer(r.cnt); case index is when 0 => v.txd := mirror2(not v.crc(31 downto 28)); when 1 => v.txd := mirror2(not r.crc(27 downto 24)); when 2 => v.txd := mirror2(not r.crc(23 downto 20)); when 3 => v.txd := mirror2(not r.crc(19 downto 16)); when 4 => v.txd := mirror2(not r.crc(15 downto 12)); when 5 => v.txd := mirror2(not r.crc(11 downto 8)); when 6 => v.txd := mirror2(not r.crc(7 downto 4)); when 7 => v.txd := mirror2(not r.crc(3 downto 0)); v.main_state := fcs2; when others => null; end case; end if; when fcs2 => if tx_done = '1' then v.main_state := finish; v.tx_en := '0'; end if; when finish => v.tx_en := '0'; v.transmitting := '0'; v.main_state := idle; v.retry_cnt := (others => '0'); v.done := not r.done; when send_jam => if tx_done = '1' then v.cnt := "0110"; v.main_state := send_jam2; v.crc_en := '0'; end if; when send_jam2 => if tx_done = '1' then v.cnt := r.cnt - 1; if r.cnt = "0000" then v.main_state := check_attempts; v.retry_cnt := r.retry_cnt + 1; v.tx_en := '0'; end if; end if; when check_attempts => v.transmitting := '0'; if r.retry_cnt = maxattempts then v.main_state := finish; v.status(1) := '1'; else v.main_state := calc_backoff; v.restart := not r.restart; end if; v.tx_en := '0'; when calc_backoff => v.delay_val := (others => '0'); for i in 1 to backoff_limit-1 loop if i < conv_integer(r.retry_cnt)+1 then v.delay_val(i) := r.random(i); end if; end loop; v.main_state := wait_backoff; v.slot_count := (others => '1'); when wait_backoff => if conv_integer(r.delay_val) = 0 then v.main_state := idle; end if; v.slot_count := r.slot_count - 1; if conv_integer(r.slot_count) = 0 then v.slot_count := (others => '1'); v.delay_val := r.delay_val - 1; end if; when others => v.main_state := idle; end case; --random values; v.random := r.random(8 downto 0) & (not (r.random(2) xor r.random(9))); --deference case r.def_state is when monitor => v.was_transmitting := '0'; if ( (crs and not r.fullduplex(1)) or (r.transmitting and r.fullduplex(1)) ) = '1' then v.deferring := '1'; v.def_state := def_on; v.was_transmitting := r.transmitting; end if; when def_on => v.was_transmitting := r.was_transmitting or r.transmitting; if r.fullduplex(1) = '1' then if r.transmitting = '0' then v.def_state := ifg1; end if; v.ifg_cycls := ifg_sel(rmii, 1, r.speed(1)); else if (r.transmitting or crs) = '0' then v.def_state := ifg1; v.ifg_cycls := ifg_sel(rmii, 1, r.speed(1)); end if; end if; when ifg1 => v.ifg_cycls := r.ifg_cycls - 1; if r.ifg_cycls = zero32(ifg_bits-1 downto 0) then v.def_state := ifg2; v.ifg_cycls := ifg_sel(rmii, 0, r.speed(1)); elsif (crs and not r.fullduplex(1)) = '1' then v.ifg_cycls := ifg_sel(rmii, 1, r.speed(1)); end if; when ifg2 => v.ifg_cycls := r.ifg_cycls - 1; if r.ifg_cycls = zero32(ifg_bits-1 downto 0) then v.deferring := '0'; if (r.fullduplex(1) or not frame_waiting) = '1' then v.def_state := monitor; elsif frame_waiting = '1' then v.def_state := frame_waitingst; end if; end if; when frame_waitingst => if frame_waiting = '0' then v.def_state := monitor; end if; when others => v.def_state := monitor; end case; if rmii = 1 then v.txd_msb := v.txd(3 downto 2); end if; if txrst = '0' then v.main_state := idle; v.random := (others => '0'); v.def_state := monitor; v.deferring := '0'; v.tx_en := '0'; v.done := '0'; v.restart := '0'; v.read := '0'; v.start := (others => '0'); v.read_ack := (others => '0'); v.icnt := (others => '0'); v.delay_val := (others => '0'); v.ifg_cycls := (others => '0'); v.crs_act := '0'; v.slot_count := (others => '1'); v.retry_cnt := (others => '0'); v.cnt := (others => '0'); end if; rin <= v; txo.tx_er <= '0'; txo.tx_en <= r.tx_en; txo.txd <= r.txd; txo.done <= r.done; txo.read <= r.read; txo.restart <= r.restart; txo.status <= r.status; end process; txregs : process(clk) is begin if rising_edge(clk) then r <= rin; if rst = '0' then r.icnt <= (others => '0'); r.delay_val <= (others => '0'); r.cnt <= (others => '0'); else r.icnt <= rin.icnt; r.delay_val <= rin.delay_val; r.cnt <= rin.cnt; end if; end if; end process; end architecture;

gpl-2.0

973ac5f4e1aab69ee8e232873648b935

0.518219

3.187382

false

IamVNIE/Hardware-Security

Interfaces/UART_Version_2/UART_TX_CTRL.vhd

2

2,829

---------------------------------------------------------------------------------- -- Company: -- Engineer: Vinayaka Jyothi -- -- Create Date: 21:49:51 11/23/2016 -- Design Name: -- Module Name: UART_TX_CTRL - Behavioral -- Project Name: -- Target Devices: -- Tool versions: -- Description: -- -- Dependencies: -- -- Revision: -- Revision 0.01 - File Created -- Additional Comments: ---------------------------------------------------------------------------------- library IEEE; use IEEE.STD_LOGIC_1164.ALL; use IEEE.std_logic_unsigned.all; entity UART_TX_CTRL is Port ( SEND : in STD_LOGIC; DATA : in STD_LOGIC_VECTOR (7 downto 0); CLK : in STD_LOGIC; READY : out STD_LOGIC; UART_TX : out STD_LOGIC); end UART_TX_CTRL; architecture Behavioral of UART_TX_CTRL is type TX_STATE_TYPE is (RDY, LOAD_BIT, SEND_BIT); constant BIT_TMR_MAX : std_logic_vector(13 downto 0) := "10100010110000"; --10416 = (round(100MHz / 9600)) - 1 constant BIT_INDEX_MAX : natural := 10; signal bitTmr : std_logic_vector(13 downto 0) := (others => '0'); signal bitDone : std_logic; signal bitIndex : natural; signal txBit : std_logic := '1'; signal txData : std_logic_vector(9 downto 0); signal txState : TX_STATE_TYPE := RDY; begin next_txState_process : process (CLK) begin if (rising_edge(CLK)) then case txState is when RDY => if (SEND = '1') then txState <= LOAD_BIT; end if; when LOAD_BIT => txState <= SEND_BIT; when SEND_BIT => if (bitDone = '1') then if (bitIndex = BIT_INDEX_MAX) then txState <= RDY; else txState <= LOAD_BIT; end if; end if; when others => txState <= RDY; end case; end if; end process; bit_timing_process : process (CLK) begin if (rising_edge(CLK)) then if (txState = RDY) then bitTmr <= (others => '0'); else if (bitDone = '1') then bitTmr <= (others => '0'); else bitTmr <= bitTmr + 1; end if; end if; end if; end process; bitDone <= '1' when (bitTmr = BIT_TMR_MAX) else '0'; bit_counting_process : process (CLK) begin if (rising_edge(CLK)) then if (txState = RDY) then bitIndex <= 0; elsif (txState = LOAD_BIT) then bitIndex <= bitIndex + 1; end if; end if; end process; tx_data_latch_process : process (CLK) begin if (rising_edge(CLK)) then if (SEND = '1') then txData <= '1' & DATA & '0'; end if; end if; end process; tx_bit_process : process (CLK) begin if (rising_edge(CLK)) then if (txState = RDY) then txBit <= '1'; elsif (txState = LOAD_BIT) then txBit <= txData(bitIndex); end if; end if; end process; UART_TX <= txBit; READY <= '1' when (txState = RDY) else '0'; end Behavioral;

mit

23db18ab165ad173b060d3e5b8cae399

0.557441

3.101974

false

marco-c/leon-nexys2

grlib-gpl-1.3.4-b4140/designs/leon3-xilinx-ml403/testbench.vhd

1

9,339

----------------------------------------------------------------------------- -- LEON3 Demonstration design test bench -- Copyright (C) 2004 Jiri Gaisler, Gaisler Research ------------------------------------------------------------------------------ -- This file is a part of the GRLIB VHDL IP LIBRARY -- Copyright (C) 2003 - 2008, Gaisler Research -- Copyright (C) 2008 - 2013, Aeroflex Gaisler -- -- This program is free software; you can redistribute it and/or modify -- it under the terms of the GNU General Public License as published by -- the Free Software Foundation; either version 2 of the License, or -- (at your option) any later version. -- -- This program is distributed in the hope that it will be useful, -- but WITHOUT ANY WARRANTY; without even the implied warranty of -- MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the -- GNU General Public License for more details. -- -- You should have received a copy of the GNU General Public License -- along with this program; if not, write to the Free Software -- Foundation, Inc., 59 Temple Place, Suite 330, Boston, MA 02111-1307 USA ------------------------------------------------------------------------------ library ieee; use ieee.std_logic_1164.all; library gaisler; use gaisler.libdcom.all; use gaisler.sim.all; library techmap; use techmap.gencomp.all; library micron; use micron.components.all; library cypress; use cypress.components.all; use work.debug.all; use work.config.all; -- configuration entity testbench is generic ( fabtech : integer := CFG_FABTECH; memtech : integer := CFG_MEMTECH; padtech : integer := CFG_PADTECH; clktech : integer := CFG_CLKTECH; ncpu : integer := CFG_NCPU; disas : integer := CFG_DISAS; -- Enable disassembly to console dbguart : integer := CFG_DUART; -- Print UART on console pclow : integer := CFG_PCLOW; clkperiod : integer := 10; -- system clock period romwidth : integer := 32; -- rom data width (8/32) romdepth : integer := 16; -- rom address depth sramwidth : integer := 32; -- ram data width (8/16/32) sramdepth : integer := 18; -- ram address depth srambanks : integer := 2 -- number of ram banks ); end; architecture behav of testbench is constant promfile : string := "prom.srec"; -- rom contents constant sramfile : string := "ram.srec"; -- ram contents constant sdramfile : string := "ram.srec"; -- sdram contents signal sys_clk : std_logic := '0'; signal sys_rst_in : std_logic := '0'; -- Reset constant ct : integer := clkperiod/2; signal plb_error : std_logic; signal opb_error : std_logic; signal flash_a23 : std_ulogic; signal sram_flash_addr : std_logic_vector(20 downto 0); signal sram_flash_data : std_logic_vector(31 downto 0); signal sram_cen : std_logic; signal sram_bw : std_logic_vector (3 downto 0); signal sram_flash_oe_n : std_ulogic; signal sram_flash_we_n : std_ulogic; signal flash_ce : std_logic; signal sram_clk : std_ulogic; signal sram_clk_fb : std_ulogic; signal sram_mode : std_ulogic; signal sram_adv_ld_n : std_ulogic; signal sram_zz : std_ulogic; signal iosn : std_ulogic; signal ddr_clk : std_logic; signal ddr_clkb : std_logic; signal ddr_clk_fb : std_logic; signal ddr_cke : std_logic; signal ddr_csb : std_logic; signal ddr_web : std_ulogic; -- ddr write enable signal ddr_rasb : std_ulogic; -- ddr ras signal ddr_casb : std_ulogic; -- ddr cas signal ddr_dm : std_logic_vector (3 downto 0); -- ddr dm signal ddr_dqs : std_logic_vector (3 downto 0); -- ddr dqs signal ddr_ad : std_logic_vector (12 downto 0); -- ddr address signal ddr_ba : std_logic_vector (1 downto 0); -- ddr bank address signal ddr_dq : std_logic_vector (31 downto 0); -- ddr data signal txd1 : std_ulogic; -- UART1 tx data signal rxd1 : std_ulogic; -- UART1 rx data signal gpio : std_logic_vector(13 downto 0); -- I/O port signal phy_mii_data: std_logic; -- ethernet PHY interface signal phy_tx_clk : std_ulogic; signal phy_rx_clk : std_ulogic; signal phy_rx_data : std_logic_vector(7 downto 0); signal phy_dv : std_ulogic; signal phy_rx_er : std_ulogic; signal phy_col : std_ulogic; signal phy_crs : std_ulogic; signal phy_tx_data : std_logic_vector(7 downto 0); signal phy_tx_en : std_ulogic; signal phy_tx_er : std_ulogic; signal phy_mii_clk : std_ulogic; signal phy_rst_n : std_ulogic; signal phy_gtx_clk : std_ulogic; signal ps2_keyb_clk: std_logic; signal ps2_keyb_data: std_logic; signal ps2_mouse_clk: std_logic; signal ps2_mouse_data: std_logic; signal tft_lcd_clk : std_ulogic; signal vid_blankn : std_ulogic; signal vid_syncn : std_ulogic; signal vid_hsync : std_ulogic; signal vid_vsync : std_ulogic; signal vid_r : std_logic_vector(7 downto 3); signal vid_g : std_logic_vector(7 downto 3); signal vid_b : std_logic_vector(7 downto 3); signal usb_csn : std_logic; signal flash_cex : std_logic; signal iic_scl : std_logic; signal iic_sda : std_logic; signal GND : std_ulogic := '0'; signal VCC : std_ulogic := '1'; signal NC : std_ulogic := 'Z'; signal spw_clk : std_ulogic := '0'; signal spw_rxdp : std_logic_vector(0 to 2) := "000"; signal spw_rxdn : std_logic_vector(0 to 2) := "000"; signal spw_rxsp : std_logic_vector(0 to 2) := "000"; signal spw_rxsn : std_logic_vector(0 to 2) := "000"; signal spw_txdp : std_logic_vector(0 to 2); signal spw_txdn : std_logic_vector(0 to 2); signal spw_txsp : std_logic_vector(0 to 2); signal spw_txsn : std_logic_vector(0 to 2); signal datazz : std_logic_vector(0 to 3); constant lresp : boolean := false; begin -- clock and reset sys_clk <= not sys_clk after ct * 1 ns; sys_rst_in <= '0', '1' after 200 ns; rxd1 <= 'H'; sram_clk_fb <= sram_clk; ddr_clk_fb <= ddr_clk; ps2_keyb_data <= 'H'; ps2_keyb_clk <= 'H'; ps2_mouse_clk <= 'H'; ps2_mouse_data <= 'H'; iic_scl <= 'H'; iic_sda <= 'H'; flash_cex <= not flash_ce; gpio <= (others => 'L'); cpu : entity work.leon3mp generic map ( fabtech, memtech, padtech, ncpu, disas, dbguart, pclow ) port map ( sys_rst_in, sys_clk, plb_error, opb_error, sram_flash_addr, sram_flash_data, sram_cen, sram_bw, sram_flash_oe_n, sram_flash_we_n, flash_ce, sram_clk, sram_clk_fb, sram_adv_ld_n, iosn, ddr_clk, ddr_clkb, ddr_clk_fb, ddr_cke, ddr_csb, ddr_web, ddr_rasb, ddr_casb, ddr_dm, ddr_dqs, ddr_ad, ddr_ba, ddr_dq, txd1, rxd1, gpio, phy_gtx_clk, phy_mii_data, phy_tx_clk, phy_rx_clk, phy_rx_data, phy_dv, phy_rx_er, phy_col, phy_crs, phy_tx_data, phy_tx_en, phy_tx_er, phy_mii_clk, phy_rst_n, ps2_keyb_clk, ps2_keyb_data, ps2_mouse_clk, ps2_mouse_data, tft_lcd_clk, vid_hsync, vid_vsync, vid_r, vid_g, vid_b, usb_csn, iic_scl, iic_sda ); datazz <= "HHHH"; u0 : cy7c1354 generic map (fname => sramfile) port map( Dq(35 downto 32) => datazz, Dq(31 downto 0) => sram_flash_data, Addr => sram_flash_addr(17 downto 0), Mode => sram_mode, Clk => sram_clk, CEN_n => gnd, AdvLd_n => sram_adv_ld_n, Bwa_n => sram_bw(3), Bwb_n => sram_bw(2), Bwc_n => sram_bw(1), Bwd_n => sram_bw(0), Rw_n => sram_flash_we_n, Oe_n => sram_flash_oe_n, Ce1_n => sram_cen, Ce2 => vcc, Ce3_n => gnd, Zz => sram_zz); sram_zz <= '0'; u1 : mt46v16m16 generic map (index => 1, fname => sdramfile, bbits => 32) PORT MAP( Dq => ddr_dq(15 downto 0), Dqs => ddr_dqs(1 downto 0), Addr => ddr_ad(12 downto 0), Ba => ddr_ba, Clk => ddr_clk, Clk_n => ddr_clkb, Cke => ddr_cke, Cs_n => ddr_csb, Ras_n => ddr_rasb, Cas_n => ddr_casb, We_n => ddr_web, Dm => ddr_dm(1 downto 0)); u2 : mt46v16m16 generic map (index => 0, fname => sdramfile, bbits => 32) PORT MAP( Dq => ddr_dq(31 downto 16), Dqs => ddr_dqs(3 downto 2), Addr => ddr_ad(12 downto 0), Ba => ddr_ba, Clk => ddr_clk, Clk_n => ddr_clkb, Cke => ddr_cke, Cs_n => ddr_csb, Ras_n => ddr_rasb, Cas_n => ddr_casb, We_n => ddr_web, Dm => ddr_dm(3 downto 2)); prom0 : for i in 0 to (romwidth/8)-1 generate sr0 : sram generic map (index => i, abits => romdepth, fname => promfile) port map (sram_flash_addr(romdepth-1 downto 0), sram_flash_data(31-i*8 downto 24-i*8), flash_cex, sram_bw(i), sram_flash_oe_n); end generate; phy_mii_data <= 'H'; p0: phy port map(sys_rst_in, phy_mii_data, phy_tx_clk, phy_rx_clk, phy_rx_data, phy_dv, phy_rx_er, phy_col, phy_crs, phy_tx_data, phy_tx_en, phy_tx_er, phy_mii_clk, phy_gtx_clk); i0: i2c_slave_model port map (iic_scl, iic_sda); plb_error <= 'H'; -- ERROR pull-up iuerr : process begin wait for 5000 ns; if to_x01(plb_error) = '1' then wait on plb_error; end if; assert (to_x01(plb_error) = '1') report "*** IU in error mode, simulation halted ***" severity failure ; end process; test0 : grtestmod port map ( sys_rst_in, sys_clk, plb_error, sram_flash_addr(19 downto 0), sram_flash_data, iosn, sram_flash_oe_n, sram_bw(0), open); sram_flash_data <= buskeep(sram_flash_data), (others => 'H') after 250 ns; ddr_dq <= buskeep(ddr_dq), (others => 'H') after 250 ns; end ;

gpl-2.0

ca4f30b67ae6e86b93bcd355f5017c25

0.617732

3.002894

false

marco-c/leon-nexys2

grlib-gpl-1.3.4-b4140/designs/leon3-digilent-nexys4/config.vhd

1

7,716

----------------------------------------------------------------------------- -- LEON3 Demonstration design test bench configuration -- Copyright (C) 2009 Aeroflex Gaisler ------------------------------------------------------------------------------ library techmap; use techmap.gencomp.all; package config is -- Technology and synthesis options constant CFG_FABTECH : integer := artix7; constant CFG_MEMTECH : integer := artix7; constant CFG_PADTECH : integer := artix7; constant CFG_NOASYNC : integer := 0; constant CFG_SCAN : integer := 0; -- Clock generator constant CFG_CLKTECH : integer := artix7; constant CFG_CLKMUL : integer := (10); constant CFG_CLKDIV : integer := (20); constant CFG_OCLKDIV : integer := 1; constant CFG_OCLKBDIV : integer := 0; constant CFG_OCLKCDIV : integer := 0; constant CFG_PCIDLL : integer := 0; constant CFG_PCISYSCLK: integer := 0; constant CFG_CLK_NOFB : integer := 0; -- LEON3 processor core constant CFG_LEON3 : integer := 1; constant CFG_NCPU : integer := (1); constant CFG_NWIN : integer := (8); constant CFG_V8 : integer := 16#32# + 4*0; constant CFG_MAC : integer := 0; constant CFG_BP : integer := 1; constant CFG_SVT : integer := 1; constant CFG_RSTADDR : integer := 16#00000#; constant CFG_LDDEL : integer := (1); constant CFG_NOTAG : integer := 1; constant CFG_NWP : integer := (0); constant CFG_PWD : integer := 0*2; constant CFG_FPU : integer := 0 + 16*0 + 32*0; constant CFG_GRFPUSH : integer := 0; constant CFG_ICEN : integer := 1; constant CFG_ISETS : integer := 2; constant CFG_ISETSZ : integer := 8; constant CFG_ILINE : integer := 4; constant CFG_IREPL : integer := 0; constant CFG_ILOCK : integer := 0; constant CFG_ILRAMEN : integer := 0; constant CFG_ILRAMADDR: integer := 16#8E#; constant CFG_ILRAMSZ : integer := 1; constant CFG_DCEN : integer := 1; constant CFG_DSETS : integer := 2; constant CFG_DSETSZ : integer := 4; constant CFG_DLINE : integer := 4; constant CFG_DREPL : integer := 0; constant CFG_DLOCK : integer := 0; constant CFG_DSNOOP : integer := 0 + 0 + 4*0; constant CFG_DFIXED : integer := 16#0#; constant CFG_DLRAMEN : integer := 0; constant CFG_DLRAMADDR: integer := 16#8F#; constant CFG_DLRAMSZ : integer := 1; constant CFG_MMUEN : integer := 0; constant CFG_ITLBNUM : integer := 2; constant CFG_DTLBNUM : integer := 2; constant CFG_TLB_TYPE : integer := 1 + 0*2; constant CFG_TLB_REP : integer := 1; constant CFG_MMU_PAGE : integer := 0; constant CFG_DSU : integer := 1; constant CFG_ITBSZ : integer := 2; constant CFG_ATBSZ : integer := 2; constant CFG_LEON3FT_EN : integer := 0; constant CFG_IUFT_EN : integer := 0; constant CFG_FPUFT_EN : integer := 0; constant CFG_RF_ERRINJ : integer := 0; constant CFG_CACHE_FT_EN : integer := 0; constant CFG_CACHE_ERRINJ : integer := 0; constant CFG_LEON3_NETLIST: integer := 0; constant CFG_DISAS : integer := 1 + 0; constant CFG_PCLOW : integer := 2; -- AMBA settings constant CFG_DEFMST : integer := (0); constant CFG_RROBIN : integer := 1; constant CFG_SPLIT : integer := 0; constant CFG_FPNPEN : integer := 1; constant CFG_AHBIO : integer := 16#FFF#; constant CFG_APBADDR : integer := 16#800#; constant CFG_AHB_MON : integer := 0; constant CFG_AHB_MONERR : integer := 0; constant CFG_AHB_MONWAR : integer := 0; constant CFG_AHB_DTRACE : integer := 0; -- DSU UART constant CFG_AHB_UART : integer := 1; -- JTAG based DSU interface constant CFG_AHB_JTAG : integer := 1; -- Ethernet DSU constant CFG_DSU_ETH : integer := 1 + 0 + 0; constant CFG_ETH_BUF : integer := 2; constant CFG_ETH_IPM : integer := 16#C0A8#; constant CFG_ETH_IPL : integer := 16#0033#; constant CFG_ETH_ENM : integer := 16#020000#; constant CFG_ETH_ENL : integer := 16#000000#; -- LEON2 memory controller constant CFG_MCTRL_LEON2 : integer := 1; constant CFG_MCTRL_RAM8BIT : integer := 0; constant CFG_MCTRL_RAM16BIT : integer := 1; constant CFG_MCTRL_5CS : integer := 0; constant CFG_MCTRL_SDEN : integer := 0; constant CFG_MCTRL_SEPBUS : integer := 0; constant CFG_MCTRL_INVCLK : integer := 0; constant CFG_MCTRL_SD64 : integer := 0; constant CFG_MCTRL_PAGE : integer := 0 + 0; -- DDR controller constant CFG_DDR2SP : integer := 0; constant CFG_DDR2SP_INIT : integer := 0; constant CFG_DDR2SP_FREQ : integer := 100; constant CFG_DDR2SP_TRFC : integer := 130; constant CFG_DDR2SP_DATAWIDTH : integer := 64; constant CFG_DDR2SP_FTEN : integer := 0; constant CFG_DDR2SP_FTWIDTH : integer := 0; constant CFG_DDR2SP_COL : integer := 9; constant CFG_DDR2SP_SIZE : integer := 8; constant CFG_DDR2SP_DELAY0 : integer := 0; constant CFG_DDR2SP_DELAY1 : integer := 0; constant CFG_DDR2SP_DELAY2 : integer := 0; constant CFG_DDR2SP_DELAY3 : integer := 0; constant CFG_DDR2SP_DELAY4 : integer := 0; constant CFG_DDR2SP_DELAY5 : integer := 0; constant CFG_DDR2SP_DELAY6 : integer := 0; constant CFG_DDR2SP_DELAY7 : integer := 0; constant CFG_DDR2SP_NOSYNC : integer := 0; -- Xilinx MIG constant CFG_MIG_DDR2 : integer := 1; constant CFG_MIG_RANKS : integer := (1); constant CFG_MIG_COLBITS : integer := (10); constant CFG_MIG_ROWBITS : integer := (13); constant CFG_MIG_BANKBITS: integer := (2); constant CFG_MIG_HMASK : integer := 16#F00#; -- AHB ROM constant CFG_AHBROMEN : integer := 1; constant CFG_AHBROPIP : integer := 0; constant CFG_AHBRODDR : integer := 16#000#; constant CFG_ROMADDR : integer := 16#100#; constant CFG_ROMMASK : integer := 16#E00# + 16#100#; -- AHB RAM constant CFG_AHBRAMEN : integer := 0; constant CFG_AHBRSZ : integer := 1; constant CFG_AHBRADDR : integer := 16#A00#; constant CFG_AHBRPIPE : integer := 0; -- Gaisler Ethernet core constant CFG_GRETH : integer := 1; constant CFG_GRETH1G : integer := 0; constant CFG_ETH_FIFO : integer := 4; -- UART 1 constant CFG_UART1_ENABLE : integer := 1; constant CFG_UART1_FIFO : integer := 1; -- LEON3 interrupt controller constant CFG_IRQ3_ENABLE : integer := 1; constant CFG_IRQ3_NSEC : integer := 0; -- Modular timer constant CFG_GPT_ENABLE : integer := 1; constant CFG_GPT_NTIM : integer := (2); constant CFG_GPT_SW : integer := (8); constant CFG_GPT_TW : integer := (32); constant CFG_GPT_IRQ : integer := (8); constant CFG_GPT_SEPIRQ : integer := 1; constant CFG_GPT_WDOGEN : integer := 0; constant CFG_GPT_WDOG : integer := 16#0#; -- GPIO port constant CFG_GRGPIO_ENABLE : integer := 1; constant CFG_GRGPIO_IMASK : integer := 16#0000#; constant CFG_GRGPIO_WIDTH : integer := (8); -- SPI memory controller constant CFG_SPIMCTRL : integer := 0; constant CFG_SPIMCTRL_SDCARD : integer := 0; constant CFG_SPIMCTRL_READCMD : integer := 16#0#; constant CFG_SPIMCTRL_DUMMYBYTE : integer := 0; constant CFG_SPIMCTRL_DUALOUTPUT : integer := 0; constant CFG_SPIMCTRL_SCALER : integer := 1; constant CFG_SPIMCTRL_ASCALER : integer := 1; constant CFG_SPIMCTRL_PWRUPCNT : integer := 0; constant CFG_SPIMCTRL_OFFSET : integer := 16#0#; -- SPI controller constant CFG_SPICTRL_ENABLE : integer := 0; constant CFG_SPICTRL_NUM : integer := 1; constant CFG_SPICTRL_SLVS : integer := 1; constant CFG_SPICTRL_FIFO : integer := 1; constant CFG_SPICTRL_SLVREG : integer := 0; constant CFG_SPICTRL_ODMODE : integer := 0; constant CFG_SPICTRL_AM : integer := 0; constant CFG_SPICTRL_ASEL : integer := 0; constant CFG_SPICTRL_TWEN : integer := 0; constant CFG_SPICTRL_MAXWLEN : integer := 0; constant CFG_SPICTRL_SYNCRAM : integer := 0; constant CFG_SPICTRL_FT : integer := 0; -- GRLIB debugging constant CFG_DUART : integer := 1; end;

gpl-2.0

ffac693043ecfe0ca72e94b345579e7c

0.653836

3.577191

false

marco-c/leon-nexys2

grlib-gpl-1.3.4-b4140/designs/leon3-terasic-de2-115/config.vhd

1

6,811

----------------------------------------------------------------------------- -- LEON3 Demonstration design test bench configuration -- Copyright (C) 2009 Aeroflex Gaisler ------------------------------------------------------------------------------ library techmap; use techmap.gencomp.all; package config is -- Technology and synthesis options constant CFG_FABTECH : integer := cyclone3; constant CFG_MEMTECH : integer := cyclone3; constant CFG_PADTECH : integer := cyclone3; constant CFG_NOASYNC : integer := 0; constant CFG_SCAN : integer := 0; -- Clock generator constant CFG_CLKTECH : integer := cyclone3; constant CFG_CLKMUL : integer := (5); constant CFG_CLKDIV : integer := (5); constant CFG_OCLKDIV : integer := 1; constant CFG_OCLKBDIV : integer := 0; constant CFG_OCLKCDIV : integer := 0; constant CFG_PCIDLL : integer := 0; constant CFG_PCISYSCLK: integer := 0; constant CFG_CLK_NOFB : integer := 0; -- LEON3 processor core constant CFG_LEON3 : integer := 1; constant CFG_NCPU : integer := (1); constant CFG_NWIN : integer := (8); constant CFG_V8 : integer := 16#32# + 4*0; constant CFG_MAC : integer := 0; constant CFG_BP : integer := 1; constant CFG_SVT : integer := 1; constant CFG_RSTADDR : integer := 16#00000#; constant CFG_LDDEL : integer := (1); constant CFG_NOTAG : integer := 0; constant CFG_NWP : integer := (2); constant CFG_PWD : integer := 1*2; constant CFG_FPU : integer := 0 + 16*0 + 32*0; constant CFG_GRFPUSH : integer := 0; constant CFG_ICEN : integer := 1; constant CFG_ISETS : integer := 4; constant CFG_ISETSZ : integer := 4; constant CFG_ILINE : integer := 8; constant CFG_IREPL : integer := 0; constant CFG_ILOCK : integer := 0; constant CFG_ILRAMEN : integer := 0; constant CFG_ILRAMADDR: integer := 16#8E#; constant CFG_ILRAMSZ : integer := 1; constant CFG_DCEN : integer := 1; constant CFG_DSETS : integer := 4; constant CFG_DSETSZ : integer := 4; constant CFG_DLINE : integer := 4; constant CFG_DREPL : integer := 0; constant CFG_DLOCK : integer := 0; constant CFG_DSNOOP : integer := 1 + 1 + 4*1; constant CFG_DFIXED : integer := 16#0#; constant CFG_DLRAMEN : integer := 0; constant CFG_DLRAMADDR: integer := 16#8F#; constant CFG_DLRAMSZ : integer := 1; constant CFG_MMUEN : integer := 1; constant CFG_ITLBNUM : integer := 8; constant CFG_DTLBNUM : integer := 8; constant CFG_TLB_TYPE : integer := 0 + 1*2; constant CFG_TLB_REP : integer := 0; constant CFG_MMU_PAGE : integer := 0; constant CFG_DSU : integer := 1; constant CFG_ITBSZ : integer := 2; constant CFG_ATBSZ : integer := 2; constant CFG_LEON3FT_EN : integer := 0; constant CFG_IUFT_EN : integer := 0; constant CFG_FPUFT_EN : integer := 0; constant CFG_RF_ERRINJ : integer := 0; constant CFG_CACHE_FT_EN : integer := 0; constant CFG_CACHE_ERRINJ : integer := 0; constant CFG_LEON3_NETLIST: integer := 0; constant CFG_DISAS : integer := 0 + 0; constant CFG_PCLOW : integer := 2; -- AMBA settings constant CFG_DEFMST : integer := (0); constant CFG_RROBIN : integer := 1; constant CFG_SPLIT : integer := 0; constant CFG_FPNPEN : integer := 0; constant CFG_AHBIO : integer := 16#FFF#; constant CFG_APBADDR : integer := 16#800#; constant CFG_AHB_MON : integer := 0; constant CFG_AHB_MONERR : integer := 0; constant CFG_AHB_MONWAR : integer := 0; constant CFG_AHB_DTRACE : integer := 0; -- DSU UART constant CFG_AHB_UART : integer := 1; -- JTAG based DSU interface constant CFG_AHB_JTAG : integer := 1; -- Ethernet DSU constant CFG_DSU_ETH : integer := 1 + 0 + 0; constant CFG_ETH_BUF : integer := 2; constant CFG_ETH_IPM : integer := 16#C0A8#; constant CFG_ETH_IPL : integer := 16#0033#; constant CFG_ETH_ENM : integer := 16#020000#; constant CFG_ETH_ENL : integer := 16#0d0007#; -- LEON2 memory controller constant CFG_MCTRL_LEON2 : integer := 1; constant CFG_MCTRL_RAM8BIT : integer := 1; constant CFG_MCTRL_RAM16BIT : integer := 0; constant CFG_MCTRL_5CS : integer := 0; constant CFG_MCTRL_SDEN : integer := 1; constant CFG_MCTRL_SEPBUS : integer := 1; constant CFG_MCTRL_INVCLK : integer := 0; constant CFG_MCTRL_SD64 : integer := 0; constant CFG_MCTRL_PAGE : integer := 0 + 0; -- AHB status register constant CFG_AHBSTAT : integer := 1; constant CFG_AHBSTATN : integer := (1); -- AHB RAM constant CFG_AHBRAMEN : integer := 0; constant CFG_AHBRSZ : integer := 1; constant CFG_AHBRADDR : integer := 16#A00#; constant CFG_AHBRPIPE : integer := 0; -- Gaisler Ethernet core constant CFG_GRETH : integer := 1; constant CFG_GRETH1G : integer := 0; constant CFG_ETH_FIFO : integer := 32; -- CAN 2.0 interface constant CFG_CAN : integer := 0; constant CFG_CAN_NUM : integer := 1; constant CFG_CANIO : integer := 16#0#; constant CFG_CANIRQ : integer := 0; constant CFG_CANSEPIRQ: integer := 0; constant CFG_CAN_SYNCRST : integer := 0; constant CFG_CANFT : integer := 0; -- SPI controller constant CFG_SPICTRL_ENABLE : integer := 1; constant CFG_SPICTRL_NUM : integer := (1); constant CFG_SPICTRL_SLVS : integer := (1); constant CFG_SPICTRL_FIFO : integer := (2); constant CFG_SPICTRL_SLVREG : integer := 1; constant CFG_SPICTRL_ODMODE : integer := 1; constant CFG_SPICTRL_AM : integer := 0; constant CFG_SPICTRL_ASEL : integer := 0; constant CFG_SPICTRL_TWEN : integer := 1; constant CFG_SPICTRL_MAXWLEN : integer := (0); constant CFG_SPICTRL_SYNCRAM : integer := 1; constant CFG_SPICTRL_FT : integer := 0; -- SPI to AHB bridge constant CFG_SPI2AHB : integer := 0; constant CFG_SPI2AHB_APB : integer := 0; constant CFG_SPI2AHB_ADDRH : integer := 16#0#; constant CFG_SPI2AHB_ADDRL : integer := 16#0#; constant CFG_SPI2AHB_MASKH : integer := 16#0#; constant CFG_SPI2AHB_MASKL : integer := 16#0#; constant CFG_SPI2AHB_RESEN : integer := 0; constant CFG_SPI2AHB_FILTER : integer := 2; constant CFG_SPI2AHB_CPOL : integer := 0; constant CFG_SPI2AHB_CPHA : integer := 0; -- UART 1 constant CFG_UART1_ENABLE : integer := 1; constant CFG_UART1_FIFO : integer := 4; -- LEON3 interrupt controller constant CFG_IRQ3_ENABLE : integer := 1; constant CFG_IRQ3_NSEC : integer := 0; -- Modular timer constant CFG_GPT_ENABLE : integer := 1; constant CFG_GPT_NTIM : integer := (2); constant CFG_GPT_SW : integer := (16); constant CFG_GPT_TW : integer := (32); constant CFG_GPT_IRQ : integer := (8); constant CFG_GPT_SEPIRQ : integer := 1; constant CFG_GPT_WDOGEN : integer := 0; constant CFG_GPT_WDOG : integer := 16#0#; -- GPIO port constant CFG_GRGPIO_ENABLE : integer := 1; constant CFG_GRGPIO_IMASK : integer := 16#fe#; constant CFG_GRGPIO_WIDTH : integer := (32); -- GRLIB debugging constant CFG_DUART : integer := 0; end;

gpl-2.0

18a0146aa5da1eace81484ea15ac513c

0.648069

3.582851

false

marco-c/leon-nexys2

grlib-gpl-1.3.4-b4140/lib/openchip/sui/apbsui.vhd

3

5,854

---------------------------------------------------------------------------- -- This file is a part of the GRLIB VHDL IP LIBRARY -- Copyright (C) 2004 GAISLER RESEARCH -- -- This program is free software; you can redistribute it and/or modify -- it under the terms of the GNU General Public License as published by -- the Free Software Foundation; either version 2 of the License, or -- (at your option) any later version. -- -- See the file COPYING for the full details of the license. -- ----------------------------------------------------------------------------- -- Entity: sui -- File: apbsui.vhd -- Author: Antti Lukats, OpenChip -- Description: Simple User Interface -- -- Single Peripheral containting the following: -- Input: -- Switches 0..31 -- Buttons 0..31 -- Output -- LED 7 Segment, 4 digits non multiplexed, 32 digits in multiplexed mode -- Single LED 0..31 -- Buzzer -- Character LCD -- -- Version 0: All functions are software assisted, IP Core has minimal -- intelligence providing bit-bang access to all the connected hardware -- -- -- -- -- -- -- -- ------------------------------------------------------------------------------ library ieee; use ieee.std_logic_1164.all; library grlib; use grlib.amba.all; use grlib.stdlib.all; use grlib.devices.all; library openchip; use openchip.sui.all; --pragma translate_off use std.textio.all; --pragma translate_on entity apbsui is generic ( pindex : integer := 0; paddr : integer := 0; pmask : integer := 16#fff#; pirq : integer := 0; -- active level for Segment LED segments led7act : integer := 1; -- active level for single LED's ledact : integer := 1); port ( rst : in std_ulogic; clk : in std_ulogic; apbi : in apb_slv_in_type; apbo : out apb_slv_out_type; suii : in sui_in_type; suio : out sui_out_type); end; architecture rtl of apbsui is constant REVISION : integer := 0; constant pconfig : apb_config_type := ( 0 => ahb_device_reg ( VENDOR_OPENCHIP, OPENCHIP_APBSUI, 0, REVISION, pirq), 1 => apb_iobar(paddr, pmask)); type suiregs is record ledreg : std_logic_vector(31 downto 0); -- Output Latch, single LEDs led7reg : std_logic_vector(31 downto 0); -- Output Latch, 7 Seg LEDs lcdreg : std_logic_vector(15 downto 0); -- Output Latch LCD buzreg : std_logic_vector(0 downto 0); -- Buzzer sw_inreg : std_logic_vector(31 downto 0); -- Switches in btn_inreg : std_logic_vector(31 downto 0); -- Buttons in irq : std_ulogic; -- interrupt (internal), not used end record; signal r, rin : suiregs; begin comb : process(rst, r, apbi, suii ) variable rdata : std_logic_vector(31 downto 0); variable irq : std_logic_vector(NAHBIRQ-1 downto 0); variable v : suiregs; begin v := r; v.sw_inreg := suii.switch_in; v.btn_inreg := suii.button_in; irq := (others => '0'); --irq(pirq) := r.irq; v.irq := '0'; rdata := (others => '0'); -- read/write registers case apbi.paddr(4 downto 2) is when "100" => rdata(31 downto 0) := r.sw_inreg; -- read switches when "101" => rdata(31 downto 0) := r.btn_inreg; -- read buttons when others => end case; if (apbi.psel(pindex) and apbi.penable and apbi.pwrite) = '1' then case apbi.paddr(4 downto 2) is when "000" => v.ledreg := apbi.pwdata(31 downto 0); when "001" => v.led7reg := apbi.pwdata(31 downto 0); when "010" => v.lcdreg(15 downto 0) := apbi.pwdata(15 downto 0); when "011" => v.buzreg(0) := apbi.pwdata(0); when others => end case; end if; -- reset operation if rst = '0' then v.ledreg := (others => '0'); v.led7reg := (others => '0'); end if; -- update registers rin <= v; -- drive outputs suio.lcd_out <= r.lcdreg(7 downto 0); suio.lcd_en <= r.lcdreg(11 downto 8); suio.lcd_rs <= r.lcdreg(12); suio.lcd_r_wn <= r.lcdreg(13); suio.lcd_backlight <= r.lcdreg(14); suio.lcd_oe <= r.lcdreg(15); suio.buzzer <= r.buzreg(0); suio.led_out <= r.ledreg; suio.led_a_out(0) <= r.led7reg(0); suio.led_b_out(0) <= r.led7reg(1); suio.led_c_out(0) <= r.led7reg(2); suio.led_d_out(0) <= r.led7reg(3); suio.led_e_out(0) <= r.led7reg(4); suio.led_f_out(0) <= r.led7reg(5); suio.led_g_out(0) <= r.led7reg(6); suio.led_dp_out(0) <= r.led7reg(7); suio.led_a_out(1) <= r.led7reg(8); suio.led_b_out(1) <= r.led7reg(9); suio.led_c_out(1) <= r.led7reg(10); suio.led_d_out(1) <= r.led7reg(11); suio.led_e_out(1) <= r.led7reg(12); suio.led_f_out(1) <= r.led7reg(13); suio.led_g_out(1) <= r.led7reg(14); suio.led_dp_out(1) <= r.led7reg(15); suio.led_a_out(2) <= r.led7reg(16); suio.led_b_out(2) <= r.led7reg(17); suio.led_c_out(2) <= r.led7reg(18); suio.led_d_out(2) <= r.led7reg(19); suio.led_e_out(2) <= r.led7reg(20); suio.led_f_out(2) <= r.led7reg(21); suio.led_g_out(2) <= r.led7reg(22); suio.led_dp_out(2) <= r.led7reg(23); suio.led_a_out(3) <= r.led7reg(24); suio.led_b_out(3) <= r.led7reg(25); suio.led_c_out(3) <= r.led7reg(26); suio.led_d_out(3) <= r.led7reg(27); suio.led_e_out(3) <= r.led7reg(28); suio.led_f_out(3) <= r.led7reg(29); suio.led_g_out(3) <= r.led7reg(30); suio.led_dp_out(3) <= r.led7reg(31); apbo.prdata <= rdata; apbo.pirq <= irq; apbo.pindex <= pindex; end process; apbo.pconfig <= pconfig; regs : process(clk) begin if rising_edge(clk) then r <= rin; end if; end process; -- pragma translate_off bootmsg : report_version generic map ("apbsui" & tost(pindex) & ": SUI rev " & tost(REVISION) & ", irq " & tost(pirq)); -- pragma translate_on end;

gpl-2.0

5e297fc5a1e962c7915a5d71a917af30

0.572429

2.800957

false

marco-c/leon-nexys2

grlib-gpl-1.3.4-b4140/designs/leon3-asic/config.vhd

1

7,517

----------------------------------------------------------------------------- -- LEON3 Demonstration design test bench configuration -- Copyright (C) 2013 Aeroflex Gaisler ------------------------------------------------------------------------------ library techmap; use techmap.gencomp.all; package config is -- Technology and synthesis options constant CFG_FABTECH : integer := saed32; constant CFG_MEMTECH : integer := saed32; constant CFG_PADTECH : integer := saed32; constant CFG_NOASYNC : integer := 1; constant CFG_SCAN : integer := 1; -- JTAG boundary-scan chain constant CFG_BOUNDSCAN_EN : integer := 0; -- Clock generator constant CFG_CLKTECH : integer := saed32; constant CFG_CLKMUL : integer := 2; constant CFG_CLKDIV : integer := 2; constant CFG_OCLKDIV : integer := 1; constant CFG_OCLKBDIV : integer := 0; constant CFG_OCLKCDIV : integer := 0; constant CFG_PCIDLL : integer := 0; constant CFG_PCISYSCLK: integer := 0; constant CFG_CLK_NOFB : integer := 0; -- LEON3 processor core constant CFG_LEON3 : integer := 1; constant CFG_NCPU : integer := (1); constant CFG_NWIN : integer := (8); constant CFG_V8 : integer := 2 + 4*0; constant CFG_MAC : integer := 0; constant CFG_BP : integer := 1; constant CFG_SVT : integer := 1; constant CFG_RSTADDR : integer := 16#00000#; constant CFG_LDDEL : integer := (1); constant CFG_NOTAG : integer := 0; constant CFG_NWP : integer := (2); constant CFG_PWD : integer := 1*2; constant CFG_FPU : integer := 0 + 16*0 + 32*0; constant CFG_GRFPUSH : integer := 0; constant CFG_ICEN : integer := 1; constant CFG_ISETS : integer := 1; constant CFG_ISETSZ : integer := 4; constant CFG_ILINE : integer := 8; constant CFG_IREPL : integer := 0; constant CFG_ILOCK : integer := 0; constant CFG_ILRAMEN : integer := 0; constant CFG_ILRAMADDR: integer := 16#8E#; constant CFG_ILRAMSZ : integer := 1; constant CFG_DCEN : integer := 1; constant CFG_DSETS : integer := 1; constant CFG_DSETSZ : integer := 4; constant CFG_DLINE : integer := 8; constant CFG_DREPL : integer := 0; constant CFG_DLOCK : integer := 0; constant CFG_DSNOOP : integer := 0 + 0 + 4*0; constant CFG_DFIXED : integer := 16#0#; constant CFG_DLRAMEN : integer := 0; constant CFG_DLRAMADDR: integer := 16#8F#; constant CFG_DLRAMSZ : integer := 1; constant CFG_MMUEN : integer := 0; constant CFG_ITLBNUM : integer := 2; constant CFG_DTLBNUM : integer := 2; constant CFG_TLB_TYPE : integer := 1 + 0*2; constant CFG_TLB_REP : integer := 1; constant CFG_MMU_PAGE : integer := 0; constant CFG_DSU : integer := 1; constant CFG_ITBSZ : integer := 1; constant CFG_ATBSZ : integer := 1; constant CFG_LEON3FT_EN : integer := 0; constant CFG_IUFT_EN : integer := 0; constant CFG_FPUFT_EN : integer := 0; constant CFG_RF_ERRINJ : integer := 0; constant CFG_CACHE_FT_EN : integer := 0; constant CFG_CACHE_ERRINJ : integer := 0; constant CFG_LEON3_NETLIST: integer := 0; constant CFG_DISAS : integer := 0 + 0; constant CFG_PCLOW : integer := 2; -- AMBA settings constant CFG_DEFMST : integer := (0); constant CFG_RROBIN : integer := 1; constant CFG_SPLIT : integer := 0; constant CFG_FPNPEN : integer := 0; constant CFG_AHBIO : integer := 16#FFF#; constant CFG_APBADDR : integer := 16#800#; constant CFG_AHB_MON : integer := 0; constant CFG_AHB_MONERR : integer := 0; constant CFG_AHB_MONWAR : integer := 0; constant CFG_AHB_DTRACE : integer := 0; -- DSU UART constant CFG_AHB_UART : integer := 1; -- JTAG based DSU interface constant CFG_AHB_JTAG : integer := 0; -- Ethernet DSU constant CFG_DSU_ETH : integer := 0 + 0 + 0; constant CFG_ETH_BUF : integer := 1; constant CFG_ETH_IPM : integer := 16#C0A8#; constant CFG_ETH_IPL : integer := 16#0033#; constant CFG_ETH_ENM : integer := 16#020000#; constant CFG_ETH_ENL : integer := 16#000009#; -- LEON2 memory controller constant CFG_MCTRL_LEON2 : integer := 1; constant CFG_MCTRL_RAM8BIT : integer := 1; constant CFG_MCTRL_RAM16BIT : integer := 0; constant CFG_MCTRL_5CS : integer := 0; constant CFG_MCTRL_SDEN : integer := 1; constant CFG_MCTRL_SEPBUS : integer := 0; constant CFG_MCTRL_INVCLK : integer := 0; constant CFG_MCTRL_SD64 : integer := 0; constant CFG_MCTRL_PAGE : integer := 0 + 0; -- AHB status register constant CFG_AHBSTAT : integer := 1; constant CFG_AHBSTATN : integer := (1); -- Spacewire interface constant CFG_SPW_EN : integer := 0; constant CFG_SPW_NUM : integer := 1; constant CFG_SPW_AHBFIFO : integer := 4; constant CFG_SPW_RXFIFO : integer := 16; constant CFG_SPW_RMAP : integer := 0; constant CFG_SPW_RMAPBUF : integer := 4; constant CFG_SPW_RMAPCRC : integer := 0; constant CFG_SPW_NETLIST : integer := 0; constant CFG_SPW_FT : integer := 0; constant CFG_SPW_GRSPW : integer := 2; constant CFG_SPW_RXUNAL : integer := 0; constant CFG_SPW_DMACHAN : integer := 1; constant CFG_SPW_PORTS : integer := 1; constant CFG_SPW_INPUT : integer := 2; constant CFG_SPW_OUTPUT : integer := 0; constant CFG_SPW_RTSAME : integer := 0; -- Gaisler Ethernet core constant CFG_GRETH : integer := 1; constant CFG_GRETH1G : integer := 0; constant CFG_ETH_FIFO : integer := 8; -- SPI memory controller constant CFG_SPIMCTRL : integer := 0; constant CFG_SPIMCTRL_SDCARD : integer := 0; constant CFG_SPIMCTRL_READCMD : integer := 16#0#; constant CFG_SPIMCTRL_DUMMYBYTE : integer := 0; constant CFG_SPIMCTRL_DUALOUTPUT : integer := 0; constant CFG_SPIMCTRL_SCALER : integer := 1; constant CFG_SPIMCTRL_ASCALER : integer := 1; constant CFG_SPIMCTRL_PWRUPCNT : integer := 0; constant CFG_SPIMCTRL_OFFSET : integer := 16#0#; -- SPI controller constant CFG_SPICTRL_ENABLE : integer := 1; constant CFG_SPICTRL_NUM : integer := (1); constant CFG_SPICTRL_SLVS : integer := (6); constant CFG_SPICTRL_FIFO : integer := (4); constant CFG_SPICTRL_SLVREG : integer := 1; constant CFG_SPICTRL_ODMODE : integer := 0; constant CFG_SPICTRL_AM : integer := 0; constant CFG_SPICTRL_ASEL : integer := 0; constant CFG_SPICTRL_TWEN : integer := 0; constant CFG_SPICTRL_MAXWLEN : integer := (0); constant CFG_SPICTRL_SYNCRAM : integer := 0; constant CFG_SPICTRL_FT : integer := 0; -- CAN 2.0 interface constant CFG_CAN : integer := 0; constant CFG_CAN_NUM : integer := 1; constant CFG_CANIO : integer := 16#0#; constant CFG_CANIRQ : integer := 0; constant CFG_CANSEPIRQ: integer := 0; constant CFG_CAN_SYNCRST : integer := 0; constant CFG_CANFT : integer := 0; -- UART 1 constant CFG_UART1_ENABLE : integer := 1; constant CFG_UART1_FIFO : integer := 4; -- UART 2 constant CFG_UART2_ENABLE : integer := 1; constant CFG_UART2_FIFO : integer := 4; -- LEON3 interrupt controller constant CFG_IRQ3_ENABLE : integer := 1; constant CFG_IRQ3_NSEC : integer := 0; -- Modular timer constant CFG_GPT_ENABLE : integer := 1; constant CFG_GPT_NTIM : integer := (4); constant CFG_GPT_SW : integer := (12); constant CFG_GPT_TW : integer := (32); constant CFG_GPT_IRQ : integer := (6); constant CFG_GPT_SEPIRQ : integer := 1; constant CFG_GPT_WDOGEN : integer := 1; constant CFG_GPT_WDOG : integer := 16#FFFFF#; -- GPIO port constant CFG_GRGPIO_ENABLE : integer := 1; constant CFG_GRGPIO_IMASK : integer := 16#FE#; constant CFG_GRGPIO_WIDTH : integer := (16); -- I2C master constant CFG_I2C_ENABLE : integer := 1; -- GRLIB debugging constant CFG_DUART : integer := 0; end;

gpl-2.0

8064b9bb4555c1b609cdd60b728670b1

0.65159

3.624397

false

mistryalok/Zedboard

learning/training/MSD/s09/axi_dma_sg/vivado/project_1/project_1.srcs/sources_1/ipshared/xilinx.com/axi_sg_v4_1/0535f152/hdl/src/vhdl/axi_sg_ftch_noqueue.vhd

3

24,145

-- ************************************************************************* -- -- (c) Copyright 2010-2011 Xilinx, Inc. All rights reserved. -- -- This file contains confidential and proprietary information -- of Xilinx, Inc. and is protected under U.S. and -- international copyright and other intellectual property -- laws. -- -- DISCLAIMER -- This disclaimer is not a license and does not grant any -- rights to the materials distributed herewith. Except as -- otherwise provided in a valid license issued to you by -- Xilinx, and to the maximum extent permitted by applicable -- law: (1) THESE MATERIALS ARE MADE AVAILABLE "AS IS" AND -- WITH ALL FAULTS, AND XILINX HEREBY DISCLAIMS ALL WARRANTIES -- AND CONDITIONS, EXPRESS, IMPLIED, OR STATUTORY, INCLUDING -- BUT NOT LIMITED TO WARRANTIES OF MERCHANTABILITY, NON- -- INFRINGEMENT, OR FITNESS FOR ANY PARTICULAR PURPOSE; and -- (2) Xilinx shall not be liable (whether in contract or tort, -- including negligence, or under any other theory of -- liability) for any loss or damage of any kind or nature -- related to, arising under or in connection with these -- materials, including for any direct, or any indirect, -- special, incidental, or consequential loss or damage -- (including loss of data, profits, goodwill, or any type of -- loss or damage suffered as a result of any action brought -- by a third party) even if such damage or loss was -- reasonably foreseeable or Xilinx had been advised of the -- possibility of the same. -- -- CRITICAL APPLICATIONS -- Xilinx products are not designed or intended to be fail- -- safe, or for use in any application requiring fail-safe -- performance, such as life-support or safety devices or -- systems, Class III medical devices, nuclear facilities, -- applications related to the deployment of airbags, or any -- other applications that could lead to death, personal -- injury, or severe property or environmental damage -- (individually and collectively, "Critical -- Applications"). Customer assumes the sole risk and -- liability of any use of Xilinx products in Critical -- Applications, subject only to applicable laws and -- regulations governing limitations on product liability. -- -- THIS COPYRIGHT NOTICE AND DISCLAIMER MUST BE RETAINED AS -- PART OF THIS FILE AT ALL TIMES. -- -- ************************************************************************* -- ------------------------------------------------------------------------------- -- Filename: axi_sg_ftch_noqueue.vhd -- Description: This entity is the no queue version -- -- VHDL-Standard: VHDL'93 ------------------------------------------------------------------------------- library ieee; use ieee.std_logic_1164.all; use ieee.numeric_std.all; use ieee.std_logic_misc.all; library axi_sg_v4_1; use axi_sg_v4_1.axi_sg_pkg.all; library lib_pkg_v1_0; use lib_pkg_v1_0.lib_pkg.all; ------------------------------------------------------------------------------- entity axi_sg_ftch_noqueue is generic ( C_M_AXI_SG_ADDR_WIDTH : integer range 32 to 64 := 32; -- Master AXI Memory Map Address Width C_M_AXIS_SG_TDATA_WIDTH : integer range 32 to 32 := 32; -- Master AXI Stream Data Width C_ENABLE_MULTI_CHANNEL : integer range 0 to 1 := 0; C_AXIS_IS_ASYNC : integer range 0 to 1 := 0; C_ASYNC : integer range 0 to 1 := 0; C_SG_WORDS_TO_FETCH : integer range 8 to 13 := 8; C_ENABLE_CDMA : integer range 0 to 1 := 0; C_ENABLE_CH1 : integer range 0 to 1 := 0; C_FAMILY : string := "virtex7" -- Device family used for proper BRAM selection ); port ( ----------------------------------------------------------------------- -- AXI Scatter Gather Interface ----------------------------------------------------------------------- m_axi_sg_aclk : in std_logic ; -- m_axi_primary_aclk : in std_logic ; m_axi_sg_aresetn : in std_logic ; -- p_reset_n : in std_logic ; -- -- Channel Control -- desc_flush : in std_logic ; -- ch1_cntrl_strm_stop : in std_logic ; ftch_active : in std_logic ; -- ftch_queue_empty : out std_logic ; -- ftch_queue_full : out std_logic ; -- sof_ftch_desc : in std_logic ; desc2_flush : in std_logic ; -- ftch2_active : in std_logic ; -- ftch2_queue_empty : out std_logic ; -- ftch2_queue_full : out std_logic ; -- -- writing_nxtdesc_in : in std_logic ; -- writing_curdesc_out : out std_logic ; -- writing2_curdesc_out : out std_logic ; -- -- DataMover Command -- ftch_cmnd_wr : in std_logic ; -- ftch_cmnd_data : in std_logic_vector -- ((C_M_AXI_SG_ADDR_WIDTH+CMD_BASE_WIDTH)-1 downto 0); -- -- -- MM2S Stream In from DataMover -- m_axis_mm2s_tdata : in std_logic_vector -- (C_M_AXIS_SG_TDATA_WIDTH-1 downto 0) ; -- m_axis_mm2s_tlast : in std_logic ; -- m_axis_mm2s_tvalid : in std_logic ; -- m_axis_mm2s_tready : out std_logic ; -- m_axis2_mm2s_tready : out std_logic ; -- data_concat : in std_logic_vector -- (95 downto 0) ; -- data_concat_mcdma : in std_logic_vector -- (63 downto 0) ; -- next_bd : in std_logic_vector (31 downto 0); data_concat_tlast : in std_logic ; -- data_concat_valid : in std_logic ; -- -- -- Channel 1 AXI Fetch Stream Out -- m_axis_ftch_tdata : out std_logic_vector -- (C_M_AXIS_SG_TDATA_WIDTH-1 downto 0) ; -- m_axis_ftch_tvalid : out std_logic ; -- m_axis_ftch_tready : in std_logic ; -- m_axis_ftch_tlast : out std_logic ; -- m_axis_ftch_tdata_new : out std_logic_vector -- (96+31*C_ENABLE_CDMA downto 0); -- m_axis_ftch_tdata_mcdma_new : out std_logic_vector -- (63 downto 0); -- m_axis_ftch_tvalid_new : out std_logic ; -- m_axis_ftch_desc_available : out std_logic ; m_axis2_ftch_tdata : out std_logic_vector -- (C_M_AXIS_SG_TDATA_WIDTH-1 downto 0) ; -- m_axis2_ftch_tvalid : out std_logic ; -- m_axis2_ftch_tready : in std_logic ; -- m_axis2_ftch_tlast : out std_logic ; -- m_axis2_ftch_tdata_new : out std_logic_vector -- (96+31*C_ENABLE_CDMA downto 0); -- m_axis2_ftch_tdata_mcdma_new : out std_logic_vector -- (63 downto 0); -- m_axis2_ftch_tdata_mcdma_nxt : out std_logic_vector -- (31 downto 0); -- m_axis2_ftch_tvalid_new : out std_logic ; -- m_axis2_ftch_desc_available : out std_logic ; m_axis_mm2s_cntrl_tdata : out std_logic_vector -- (31 downto 0); -- m_axis_mm2s_cntrl_tkeep : out std_logic_vector -- (3 downto 0); -- m_axis_mm2s_cntrl_tvalid : out std_logic ; -- m_axis_mm2s_cntrl_tready : in std_logic := '0'; -- m_axis_mm2s_cntrl_tlast : out std_logic -- ); end axi_sg_ftch_noqueue; ------------------------------------------------------------------------------- -- Architecture ------------------------------------------------------------------------------- architecture implementation of axi_sg_ftch_noqueue is attribute DowngradeIPIdentifiedWarnings: string; attribute DowngradeIPIdentifiedWarnings of implementation : architecture is "yes"; ------------------------------------------------------------------------------- -- Functions ------------------------------------------------------------------------------- -- No Functions Declared ------------------------------------------------------------------------------- -- Constants Declarations ------------------------------------------------------------------------------- -- No Constants Declared ------------------------------------------------------------------------------- -- Signal / Type Declarations ------------------------------------------------------------------------------- -- Channel 1 internal signals signal curdesc_tdata : std_logic_vector (C_M_AXIS_SG_TDATA_WIDTH-1 downto 0) := (others => '0'); signal curdesc_tvalid : std_logic := '0'; signal ftch_tvalid : std_logic := '0'; signal ftch_tdata : std_logic_vector (C_M_AXIS_SG_TDATA_WIDTH-1 downto 0) := (others => '0'); signal ftch_tlast : std_logic := '0'; signal ftch_tready : std_logic := '0'; -- Misc Signals signal writing_curdesc : std_logic := '0'; signal writing_nxtdesc : std_logic := '0'; signal msb_curdesc : std_logic_vector(31 downto 0) := (others => '0'); signal writing_lsb : std_logic := '0'; signal writing_msb : std_logic := '0'; signal ftch_active_int : std_logic := '0'; signal ftch_tvalid_mult : std_logic := '0'; signal ftch_tdata_mult : std_logic_vector (C_M_AXIS_SG_TDATA_WIDTH-1 downto 0) := (others => '0'); signal ftch_tlast_mult : std_logic := '0'; signal counter : std_logic_vector (3 downto 0) := (others => '0'); signal wr_cntl : std_logic := '0'; signal ftch_tdata_new : std_logic_vector (96+31*C_ENABLE_CDMA downto 0); signal queue_wren, queue_rden : std_logic := '0'; signal queue_din : std_logic_vector (32 downto 0); signal queue_dout : std_logic_vector (32 downto 0); signal queue_empty, queue_full : std_logic := '0'; signal sof_ftch_desc_del, sof_ftch_desc_pulse : std_logic := '0'; signal sof_ftch_desc_del1 : std_logic := '0'; signal queue_sinit : std_logic := '0'; signal data_concat_mcdma_nxt : std_logic_vector (31 downto 0) := (others => '0'); signal current_bd : std_logic_vector (31 downto 0) := (others => '0'); ------------------------------------------------------------------------------- -- Begin architecture logic ------------------------------------------------------------------------------- begin queue_sinit <= not m_axi_sg_aresetn; ftch_active_int <= ftch_active or ftch2_active; CDMA_FIELDS : if C_ENABLE_CDMA = 1 generate begin ftch_tdata_new (95 downto 0) <= data_concat;-- when (ftch_active = '1') else (others =>'0'); ftch_tdata_new (127 downto 96) <= current_bd; end generate CDMA_FIELDS; DMA_FIELDS : if C_ENABLE_CDMA = 0 generate begin ftch_tdata_new (64 downto 0) <= data_concat (95) & data_concat (63 downto 0);-- when (ftch_active = '1') else (others =>'0'); ftch_tdata_new (96 downto 65) <= current_bd; end generate DMA_FIELDS; --------------------------------------------------------------------------- -- Write current descriptor to FIFO or out channel port --------------------------------------------------------------------------- NXT_BD_MCDMA : if C_ENABLE_MULTI_CHANNEL = 1 generate begin NEXT_BD_S2MM : process(m_axi_sg_aclk) begin if(m_axi_sg_aclk'EVENT and m_axi_sg_aclk = '1')then if(m_axi_sg_aresetn = '0' )then data_concat_mcdma_nxt <= (others => '0'); elsif (ftch2_active = '1') then data_concat_mcdma_nxt <= next_bd; end if; end if; end process NEXT_BD_S2MM; end generate NXT_BD_MCDMA; WRITE_CURDESC_PROCESS : process(m_axi_sg_aclk) begin if(m_axi_sg_aclk'EVENT and m_axi_sg_aclk = '1')then if(m_axi_sg_aresetn = '0' )then current_bd <= (others => '0'); -- -- -- Write LSB Address on command write elsif(ftch_cmnd_wr = '1' and ftch_active_int = '1')then current_bd <= ftch_cmnd_data(DATAMOVER_CMD_ADDRMSB_BOFST + DATAMOVER_CMD_ADDRLSB_BIT downto DATAMOVER_CMD_ADDRLSB_BIT); end if; end if; end process WRITE_CURDESC_PROCESS; GEN_MULT_CHANNEL : if C_ENABLE_MULTI_CHANNEL = 1 generate begin ftch_tvalid_mult <= m_axis_mm2s_tvalid; ftch_tdata_mult <= m_axis_mm2s_tdata; ftch_tlast_mult <= m_axis_mm2s_tlast; wr_cntl <= m_axis_mm2s_tvalid; m_axis_mm2s_cntrl_tdata <= (others => '0'); m_axis_mm2s_cntrl_tkeep <= "0000"; m_axis_mm2s_cntrl_tvalid <= '0'; m_axis_mm2s_cntrl_tlast <= '0'; end generate GEN_MULT_CHANNEL; GEN_NOMULT_CHANNEL : if C_ENABLE_MULTI_CHANNEL = 0 generate begin ftch_tvalid_mult <= '0'; --m_axis_mm2s_tvalid; ftch_tdata_mult <= (others => '0'); --m_axis_mm2s_tdata; ftch_tlast_mult <= '0'; --m_axis_mm2s_tlast; CONTROL_STREAM : if C_SG_WORDS_TO_FETCH = 13 and C_ENABLE_CH1 = 1 generate begin SOF_DEL_PROCESS : process(m_axi_sg_aclk) begin if(m_axi_sg_aclk'EVENT and m_axi_sg_aclk = '1')then if(m_axi_sg_aresetn = '0')then sof_ftch_desc_del <= '0'; else sof_ftch_desc_del <= sof_ftch_desc; end if; end if; end process SOF_DEL_PROCESS; SOF_DEL1_PROCESS : process(m_axi_sg_aclk) begin if(m_axi_sg_aclk'EVENT and m_axi_sg_aclk = '1')then if(m_axi_sg_aresetn = '0' or m_axis_mm2s_tlast = '1')then sof_ftch_desc_del1 <= '0'; elsif (m_axis_mm2s_tvalid = '1') then sof_ftch_desc_del1 <= sof_ftch_desc; end if; end if; end process SOF_DEL1_PROCESS; sof_ftch_desc_pulse <= sof_ftch_desc and (not sof_ftch_desc_del1); queue_wren <= not queue_full and sof_ftch_desc and m_axis_mm2s_tvalid and ftch_active; queue_rden <= not queue_empty and m_axis_mm2s_cntrl_tready; queue_din(C_M_AXIS_SG_TDATA_WIDTH) <= m_axis_mm2s_tlast; queue_din(C_M_AXIS_SG_TDATA_WIDTH-1 downto 0) <= x"A0000000" when (sof_ftch_desc_pulse = '1') else m_axis_mm2s_tdata; I_MM2S_CNTRL_STREAM : entity axi_sg_v4_1.axi_sg_cntrl_strm generic map( C_PRMRY_IS_ACLK_ASYNC => C_ASYNC , C_PRMY_CMDFIFO_DEPTH => 16, --FETCH_QUEUE_DEPTH , C_M_AXIS_MM2S_CNTRL_TDATA_WIDTH => C_M_AXIS_SG_TDATA_WIDTH , C_FAMILY => C_FAMILY ) port map( -- Secondary clock / reset m_axi_sg_aclk => m_axi_sg_aclk , m_axi_sg_aresetn => m_axi_sg_aresetn , -- Primary clock / reset axi_prmry_aclk => m_axi_primary_aclk , p_reset_n => p_reset_n , -- MM2S Error mm2s_stop => ch1_cntrl_strm_stop , -- Control Stream input cntrlstrm_fifo_wren => queue_wren , cntrlstrm_fifo_full => queue_full , cntrlstrm_fifo_din => queue_din , -- Memory Map to Stream Control Stream Interface m_axis_mm2s_cntrl_tdata => m_axis_mm2s_cntrl_tdata , m_axis_mm2s_cntrl_tkeep => m_axis_mm2s_cntrl_tkeep , m_axis_mm2s_cntrl_tvalid => m_axis_mm2s_cntrl_tvalid , m_axis_mm2s_cntrl_tready => m_axis_mm2s_cntrl_tready , m_axis_mm2s_cntrl_tlast => m_axis_mm2s_cntrl_tlast ); end generate CONTROL_STREAM; NO_CONTROL_STREAM : if C_SG_WORDS_TO_FETCH /= 13 or C_ENABLE_CH1 = 0 generate begin m_axis_mm2s_cntrl_tdata <= (others => '0'); m_axis_mm2s_cntrl_tkeep <= "0000"; m_axis_mm2s_cntrl_tvalid <= '0'; m_axis_mm2s_cntrl_tlast <= '0'; end generate NO_CONTROL_STREAM; end generate GEN_NOMULT_CHANNEL; --------------------------------------------------------------------------- -- Map internal stream to external --------------------------------------------------------------------------- ftch_tready <= (m_axis_ftch_tready and ftch_active) or (m_axis2_ftch_tready and ftch2_active); m_axis_ftch_tdata_new <= ftch_tdata_new; m_axis_ftch_tdata_mcdma_new <= data_concat_mcdma; m_axis_ftch_tvalid_new <= data_concat_valid and ftch_active; m_axis_ftch_desc_available <= data_concat_tlast and ftch_active; REG_FOR_STS_CNTRL : if C_SG_WORDS_TO_FETCH = 13 generate begin LATCH_PROCESS : process(m_axi_sg_aclk) begin if(m_axi_sg_aclk'EVENT and m_axi_sg_aclk = '1')then if(m_axi_sg_aresetn = '0')then m_axis2_ftch_tvalid_new <= '0'; m_axis2_ftch_desc_available <= '0'; else m_axis2_ftch_tvalid_new <= data_concat_valid and ftch2_active; m_axis2_ftch_desc_available <= data_concat_valid and ftch2_active; end if; end if; end process LATCH_PROCESS; LATCH2_PROCESS : process(m_axi_sg_aclk) begin if(m_axi_sg_aclk'EVENT and m_axi_sg_aclk = '1')then if(m_axi_sg_aresetn = '0')then m_axis2_ftch_tdata_new <= (others => '0'); elsif (data_concat_valid = '1' and ftch2_active = '1') then m_axis2_ftch_tdata_new <= ftch_tdata_new; end if; end if; end process LATCH2_PROCESS; end generate REG_FOR_STS_CNTRL; NO_REG_FOR_STS_CNTRL : if C_SG_WORDS_TO_FETCH /= 13 generate begin m_axis2_ftch_tvalid_new <= data_concat_valid and ftch2_active; m_axis2_ftch_desc_available <= data_concat_valid and ftch2_active; m_axis2_ftch_tdata_new <= ftch_tdata_new; m_axis2_ftch_tdata_mcdma_new <= data_concat_mcdma; m_axis2_ftch_tdata_mcdma_nxt <= data_concat_mcdma_nxt; end generate NO_REG_FOR_STS_CNTRL; m_axis_mm2s_tready <= ftch_tready; m_axis2_mm2s_tready <= ftch_tready; --------------------------------------------------------------------------- -- generate psuedo empty flag for Idle generation --------------------------------------------------------------------------- Q_EMPTY_PROCESS : process(m_axi_sg_aclk) begin if(m_axi_sg_aclk'EVENT and m_axi_sg_aclk='1')then if(m_axi_sg_aresetn = '0' or desc_flush = '1')then ftch_queue_empty <= '1'; -- Else on valid and ready modify empty flag elsif(ftch_tvalid = '1' and m_axis_ftch_tready = '1' and ftch_active = '1')then -- On last mark as empty if(ftch_tlast = '1' )then ftch_queue_empty <= '1'; -- Otherwise mark as not empty else ftch_queue_empty <= '0'; end if; end if; end if; end process Q_EMPTY_PROCESS; Q2_EMPTY_PROCESS : process(m_axi_sg_aclk) begin if(m_axi_sg_aclk'EVENT and m_axi_sg_aclk='1')then if(m_axi_sg_aresetn = '0' or desc2_flush = '1')then ftch2_queue_empty <= '1'; -- Else on valid and ready modify empty flag elsif(ftch_tvalid = '1' and m_axis2_ftch_tready = '1' and ftch2_active = '1')then -- On last mark as empty if(ftch_tlast = '1' )then ftch2_queue_empty <= '1'; -- Otherwise mark as not empty else ftch2_queue_empty <= '0'; end if; end if; end if; end process Q2_EMPTY_PROCESS; -- do not need to indicate full to axi_sg_ftch_sm. Only -- needed for queue case to allow other channel to be serviced -- if it had queue room ftch_queue_full <= '0'; ftch2_queue_full <= '0'; -- If writing curdesc out then flag for proper mux selection writing_curdesc <= curdesc_tvalid; -- Map intnal signal to port writing_curdesc_out <= writing_curdesc and ftch_active; writing2_curdesc_out <= writing_curdesc and ftch2_active; -- Map port to internal signal writing_nxtdesc <= writing_nxtdesc_in; end implementation;

gpl-3.0

da623fee8672d69ff718078824956efc

0.440712

4.263641

false

mistryalok/Zedboard

learning/training/Microsystem/axi_interface_part2/project_1/project_1.srcs/sources_1/bd/design_1/ip/design_1_blk_mem_gen_0_0/synth/design_1_blk_mem_gen_0_0.vhd

1

14,879

-- (c) Copyright 1995-2016 Xilinx, Inc. All rights reserved. -- -- This file contains confidential and proprietary information -- of Xilinx, Inc. and is protected under U.S. and -- international copyright and other intellectual property -- laws. -- -- DISCLAIMER -- This disclaimer is not a license and does not grant any -- rights to the materials distributed herewith. Except as -- otherwise provided in a valid license issued to you by -- Xilinx, and to the maximum extent permitted by applicable -- law: (1) THESE MATERIALS ARE MADE AVAILABLE "AS IS" AND -- WITH ALL FAULTS, AND XILINX HEREBY DISCLAIMS ALL WARRANTIES -- AND CONDITIONS, EXPRESS, IMPLIED, OR STATUTORY, INCLUDING -- BUT NOT LIMITED TO WARRANTIES OF MERCHANTABILITY, NON- -- INFRINGEMENT, OR FITNESS FOR ANY PARTICULAR PURPOSE; and -- (2) Xilinx shall not be liable (whether in contract or tort, -- including negligence, or under any other theory of -- liability) for any loss or damage of any kind or nature -- related to, arising under or in connection with these -- materials, including for any direct, or any indirect, -- special, incidental, or consequential loss or damage -- (including loss of data, profits, goodwill, or any type of -- loss or damage suffered as a result of any action brought -- by a third party) even if such damage or loss was -- reasonably foreseeable or Xilinx had been advised of the -- possibility of the same. -- -- CRITICAL APPLICATIONS -- Xilinx products are not designed or intended to be fail- -- safe, or for use in any application requiring fail-safe -- performance, such as life-support or safety devices or -- systems, Class III medical devices, nuclear facilities, -- applications related to the deployment of airbags, or any -- other applications that could lead to death, personal -- injury, or severe property or environmental damage -- (individually and collectively, "Critical -- Applications"). Customer assumes the sole risk and -- liability of any use of Xilinx products in Critical -- Applications, subject only to applicable laws and -- regulations governing limitations on product liability. -- -- THIS COPYRIGHT NOTICE AND DISCLAIMER MUST BE RETAINED AS -- PART OF THIS FILE AT ALL TIMES. -- -- DO NOT MODIFY THIS FILE. -- IP VLNV: xilinx.com:ip:blk_mem_gen:8.2 -- IP Revision: 3 LIBRARY ieee; USE ieee.std_logic_1164.ALL; USE ieee.numeric_std.ALL; LIBRARY blk_mem_gen_v8_2; USE blk_mem_gen_v8_2.blk_mem_gen_v8_2; ENTITY design_1_blk_mem_gen_0_0 IS PORT ( clka : IN STD_LOGIC; rsta : IN STD_LOGIC; ena : IN STD_LOGIC; wea : IN STD_LOGIC_VECTOR(3 DOWNTO 0); addra : IN STD_LOGIC_VECTOR(31 DOWNTO 0); dina : IN STD_LOGIC_VECTOR(31 DOWNTO 0); douta : OUT STD_LOGIC_VECTOR(31 DOWNTO 0); clkb : IN STD_LOGIC; rstb : IN STD_LOGIC; enb : IN STD_LOGIC; web : IN STD_LOGIC_VECTOR(3 DOWNTO 0); addrb : IN STD_LOGIC_VECTOR(31 DOWNTO 0); dinb : IN STD_LOGIC_VECTOR(31 DOWNTO 0); doutb : OUT STD_LOGIC_VECTOR(31 DOWNTO 0) ); END design_1_blk_mem_gen_0_0; ARCHITECTURE design_1_blk_mem_gen_0_0_arch OF design_1_blk_mem_gen_0_0 IS ATTRIBUTE DowngradeIPIdentifiedWarnings : string; ATTRIBUTE DowngradeIPIdentifiedWarnings OF design_1_blk_mem_gen_0_0_arch: ARCHITECTURE IS "yes"; COMPONENT blk_mem_gen_v8_2 IS GENERIC ( C_FAMILY : STRING; C_XDEVICEFAMILY : STRING; C_ELABORATION_DIR : STRING; C_INTERFACE_TYPE : INTEGER; C_AXI_TYPE : INTEGER; C_AXI_SLAVE_TYPE : INTEGER; C_USE_BRAM_BLOCK : INTEGER; C_ENABLE_32BIT_ADDRESS : INTEGER; C_CTRL_ECC_ALGO : STRING; C_HAS_AXI_ID : INTEGER; C_AXI_ID_WIDTH : INTEGER; C_MEM_TYPE : INTEGER; C_BYTE_SIZE : INTEGER; C_ALGORITHM : INTEGER; C_PRIM_TYPE : INTEGER; C_LOAD_INIT_FILE : INTEGER; C_INIT_FILE_NAME : STRING; C_INIT_FILE : STRING; C_USE_DEFAULT_DATA : INTEGER; C_DEFAULT_DATA : STRING; C_HAS_RSTA : INTEGER; C_RST_PRIORITY_A : STRING; C_RSTRAM_A : INTEGER; C_INITA_VAL : STRING; C_HAS_ENA : INTEGER; C_HAS_REGCEA : INTEGER; C_USE_BYTE_WEA : INTEGER; C_WEA_WIDTH : INTEGER; C_WRITE_MODE_A : STRING; C_WRITE_WIDTH_A : INTEGER; C_READ_WIDTH_A : INTEGER; C_WRITE_DEPTH_A : INTEGER; C_READ_DEPTH_A : INTEGER; C_ADDRA_WIDTH : INTEGER; C_HAS_RSTB : INTEGER; C_RST_PRIORITY_B : STRING; C_RSTRAM_B : INTEGER; C_INITB_VAL : STRING; C_HAS_ENB : INTEGER; C_HAS_REGCEB : INTEGER; C_USE_BYTE_WEB : INTEGER; C_WEB_WIDTH : INTEGER; C_WRITE_MODE_B : STRING; C_WRITE_WIDTH_B : INTEGER; C_READ_WIDTH_B : INTEGER; C_WRITE_DEPTH_B : INTEGER; C_READ_DEPTH_B : INTEGER; C_ADDRB_WIDTH : INTEGER; C_HAS_MEM_OUTPUT_REGS_A : INTEGER; C_HAS_MEM_OUTPUT_REGS_B : INTEGER; C_HAS_MUX_OUTPUT_REGS_A : INTEGER; C_HAS_MUX_OUTPUT_REGS_B : INTEGER; C_MUX_PIPELINE_STAGES : INTEGER; C_HAS_SOFTECC_INPUT_REGS_A : INTEGER; C_HAS_SOFTECC_OUTPUT_REGS_B : INTEGER; C_USE_SOFTECC : INTEGER; C_USE_ECC : INTEGER; C_EN_ECC_PIPE : INTEGER; C_HAS_INJECTERR : INTEGER; C_SIM_COLLISION_CHECK : STRING; C_COMMON_CLK : INTEGER; C_DISABLE_WARN_BHV_COLL : INTEGER; C_EN_SLEEP_PIN : INTEGER; C_DISABLE_WARN_BHV_RANGE : INTEGER; C_COUNT_36K_BRAM : STRING; C_COUNT_18K_BRAM : STRING; C_EST_POWER_SUMMARY : STRING ); PORT ( clka : IN STD_LOGIC; rsta : IN STD_LOGIC; ena : IN STD_LOGIC; regcea : IN STD_LOGIC; wea : IN STD_LOGIC_VECTOR(3 DOWNTO 0); addra : IN STD_LOGIC_VECTOR(31 DOWNTO 0); dina : IN STD_LOGIC_VECTOR(31 DOWNTO 0); douta : OUT STD_LOGIC_VECTOR(31 DOWNTO 0); clkb : IN STD_LOGIC; rstb : IN STD_LOGIC; enb : IN STD_LOGIC; regceb : IN STD_LOGIC; web : IN STD_LOGIC_VECTOR(3 DOWNTO 0); addrb : IN STD_LOGIC_VECTOR(31 DOWNTO 0); dinb : IN STD_LOGIC_VECTOR(31 DOWNTO 0); doutb : OUT STD_LOGIC_VECTOR(31 DOWNTO 0); injectsbiterr : IN STD_LOGIC; injectdbiterr : IN STD_LOGIC; eccpipece : IN STD_LOGIC; sbiterr : OUT STD_LOGIC; dbiterr : OUT STD_LOGIC; rdaddrecc : OUT STD_LOGIC_VECTOR(31 DOWNTO 0); sleep : IN STD_LOGIC; s_aclk : IN STD_LOGIC; s_aresetn : IN STD_LOGIC; s_axi_awid : IN STD_LOGIC_VECTOR(3 DOWNTO 0); s_axi_awaddr : IN STD_LOGIC_VECTOR(31 DOWNTO 0); s_axi_awlen : IN STD_LOGIC_VECTOR(7 DOWNTO 0); s_axi_awsize : IN STD_LOGIC_VECTOR(2 DOWNTO 0); s_axi_awburst : IN STD_LOGIC_VECTOR(1 DOWNTO 0); s_axi_awvalid : IN STD_LOGIC; s_axi_awready : OUT STD_LOGIC; s_axi_wdata : IN STD_LOGIC_VECTOR(31 DOWNTO 0); s_axi_wstrb : IN STD_LOGIC_VECTOR(3 DOWNTO 0); s_axi_wlast : IN STD_LOGIC; s_axi_wvalid : IN STD_LOGIC; s_axi_wready : OUT STD_LOGIC; s_axi_bid : OUT STD_LOGIC_VECTOR(3 DOWNTO 0); s_axi_bresp : OUT STD_LOGIC_VECTOR(1 DOWNTO 0); s_axi_bvalid : OUT STD_LOGIC; s_axi_bready : IN STD_LOGIC; s_axi_arid : IN STD_LOGIC_VECTOR(3 DOWNTO 0); s_axi_araddr : IN STD_LOGIC_VECTOR(31 DOWNTO 0); s_axi_arlen : IN STD_LOGIC_VECTOR(7 DOWNTO 0); s_axi_arsize : IN STD_LOGIC_VECTOR(2 DOWNTO 0); s_axi_arburst : IN STD_LOGIC_VECTOR(1 DOWNTO 0); s_axi_arvalid : IN STD_LOGIC; s_axi_arready : OUT STD_LOGIC; s_axi_rid : OUT STD_LOGIC_VECTOR(3 DOWNTO 0); s_axi_rdata : OUT STD_LOGIC_VECTOR(31 DOWNTO 0); s_axi_rresp : OUT STD_LOGIC_VECTOR(1 DOWNTO 0); s_axi_rlast : OUT STD_LOGIC; s_axi_rvalid : OUT STD_LOGIC; s_axi_rready : IN STD_LOGIC; s_axi_injectsbiterr : IN STD_LOGIC; s_axi_injectdbiterr : IN STD_LOGIC; s_axi_sbiterr : OUT STD_LOGIC; s_axi_dbiterr : OUT STD_LOGIC; s_axi_rdaddrecc : OUT STD_LOGIC_VECTOR(31 DOWNTO 0) ); END COMPONENT blk_mem_gen_v8_2; ATTRIBUTE X_CORE_INFO : STRING; ATTRIBUTE X_CORE_INFO OF design_1_blk_mem_gen_0_0_arch: ARCHITECTURE IS "blk_mem_gen_v8_2,Vivado 2014.4"; ATTRIBUTE CHECK_LICENSE_TYPE : STRING; ATTRIBUTE CHECK_LICENSE_TYPE OF design_1_blk_mem_gen_0_0_arch : ARCHITECTURE IS "design_1_blk_mem_gen_0_0,blk_mem_gen_v8_2,{}"; ATTRIBUTE CORE_GENERATION_INFO : STRING; ATTRIBUTE CORE_GENERATION_INFO OF design_1_blk_mem_gen_0_0_arch: ARCHITECTURE IS "design_1_blk_mem_gen_0_0,blk_mem_gen_v8_2,{x_ipProduct=Vivado 2014.4,x_ipVendor=xilinx.com,x_ipLibrary=ip,x_ipName=blk_mem_gen,x_ipVersion=8.2,x_ipCoreRevision=3,x_ipLanguage=VERILOG,x_ipSimLanguage=MIXED,C_FAMILY=zynq,C_XDEVICEFAMILY=zynq,C_ELABORATION_DIR=./,C_INTERFACE_TYPE=0,C_AXI_TYPE=1,C_AXI_SLAVE_TYPE=0,C_USE_BRAM_BLOCK=1,C_ENABLE_32BIT_ADDRESS=1,C_CTRL_ECC_ALGO=NONE,C_HAS_AXI_ID=0,C_AXI_ID_WIDTH=4,C_MEM_TYPE=2,C_BYTE_SIZE=8,C_ALGORITHM=1,C_PRIM_TYPE=1,C_LOAD_INIT_FILE=0,C_INIT_FILE_NAME=no_coe_file_loaded,C_INIT_FILE=NONE,C_USE_DEFAULT_DATA=0,C_DEFAULT_DATA=0,C_HAS_RSTA=1,C_RST_PRIORITY_A=CE,C_RSTRAM_A=0,C_INITA_VAL=0,C_HAS_ENA=1,C_HAS_REGCEA=0,C_USE_BYTE_WEA=1,C_WEA_WIDTH=4,C_WRITE_MODE_A=WRITE_FIRST,C_WRITE_WIDTH_A=32,C_READ_WIDTH_A=32,C_WRITE_DEPTH_A=2048,C_READ_DEPTH_A=2048,C_ADDRA_WIDTH=32,C_HAS_RSTB=1,C_RST_PRIORITY_B=CE,C_RSTRAM_B=0,C_INITB_VAL=0,C_HAS_ENB=1,C_HAS_REGCEB=0,C_USE_BYTE_WEB=1,C_WEB_WIDTH=4,C_WRITE_MODE_B=WRITE_FIRST,C_WRITE_WIDTH_B=32,C_READ_WIDTH_B=32,C_WRITE_DEPTH_B=2048,C_READ_DEPTH_B=2048,C_ADDRB_WIDTH=32,C_HAS_MEM_OUTPUT_REGS_A=0,C_HAS_MEM_OUTPUT_REGS_B=0,C_HAS_MUX_OUTPUT_REGS_A=0,C_HAS_MUX_OUTPUT_REGS_B=0,C_MUX_PIPELINE_STAGES=0,C_HAS_SOFTECC_INPUT_REGS_A=0,C_HAS_SOFTECC_OUTPUT_REGS_B=0,C_USE_SOFTECC=0,C_USE_ECC=0,C_EN_ECC_PIPE=0,C_HAS_INJECTERR=0,C_SIM_COLLISION_CHECK=ALL,C_COMMON_CLK=0,C_DISABLE_WARN_BHV_COLL=0,C_EN_SLEEP_PIN=0,C_DISABLE_WARN_BHV_RANGE=0,C_COUNT_36K_BRAM=2,C_COUNT_18K_BRAM=0,C_EST_POWER_SUMMARY=Estimated Power for IP _ 10.7492 mW}"; ATTRIBUTE X_INTERFACE_INFO : STRING; ATTRIBUTE X_INTERFACE_INFO OF clka: SIGNAL IS "xilinx.com:interface:bram:1.0 BRAM_PORTA CLK"; ATTRIBUTE X_INTERFACE_INFO OF rsta: SIGNAL IS "xilinx.com:interface:bram:1.0 BRAM_PORTA RST"; ATTRIBUTE X_INTERFACE_INFO OF ena: SIGNAL IS "xilinx.com:interface:bram:1.0 BRAM_PORTA EN"; ATTRIBUTE X_INTERFACE_INFO OF wea: SIGNAL IS "xilinx.com:interface:bram:1.0 BRAM_PORTA WE"; ATTRIBUTE X_INTERFACE_INFO OF addra: SIGNAL IS "xilinx.com:interface:bram:1.0 BRAM_PORTA ADDR"; ATTRIBUTE X_INTERFACE_INFO OF dina: SIGNAL IS "xilinx.com:interface:bram:1.0 BRAM_PORTA DIN"; ATTRIBUTE X_INTERFACE_INFO OF douta: SIGNAL IS "xilinx.com:interface:bram:1.0 BRAM_PORTA DOUT"; ATTRIBUTE X_INTERFACE_INFO OF clkb: SIGNAL IS "xilinx.com:interface:bram:1.0 BRAM_PORTB CLK"; ATTRIBUTE X_INTERFACE_INFO OF rstb: SIGNAL IS "xilinx.com:interface:bram:1.0 BRAM_PORTB RST"; ATTRIBUTE X_INTERFACE_INFO OF enb: SIGNAL IS "xilinx.com:interface:bram:1.0 BRAM_PORTB EN"; ATTRIBUTE X_INTERFACE_INFO OF web: SIGNAL IS "xilinx.com:interface:bram:1.0 BRAM_PORTB WE"; ATTRIBUTE X_INTERFACE_INFO OF addrb: SIGNAL IS "xilinx.com:interface:bram:1.0 BRAM_PORTB ADDR"; ATTRIBUTE X_INTERFACE_INFO OF dinb: SIGNAL IS "xilinx.com:interface:bram:1.0 BRAM_PORTB DIN"; ATTRIBUTE X_INTERFACE_INFO OF doutb: SIGNAL IS "xilinx.com:interface:bram:1.0 BRAM_PORTB DOUT"; BEGIN U0 : blk_mem_gen_v8_2 GENERIC MAP ( C_FAMILY => "zynq", C_XDEVICEFAMILY => "zynq", C_ELABORATION_DIR => "./", C_INTERFACE_TYPE => 0, C_AXI_TYPE => 1, C_AXI_SLAVE_TYPE => 0, C_USE_BRAM_BLOCK => 1, C_ENABLE_32BIT_ADDRESS => 1, C_CTRL_ECC_ALGO => "NONE", C_HAS_AXI_ID => 0, C_AXI_ID_WIDTH => 4, C_MEM_TYPE => 2, C_BYTE_SIZE => 8, C_ALGORITHM => 1, C_PRIM_TYPE => 1, C_LOAD_INIT_FILE => 0, C_INIT_FILE_NAME => "no_coe_file_loaded", C_INIT_FILE => "NONE", C_USE_DEFAULT_DATA => 0, C_DEFAULT_DATA => "0", C_HAS_RSTA => 1, C_RST_PRIORITY_A => "CE", C_RSTRAM_A => 0, C_INITA_VAL => "0", C_HAS_ENA => 1, C_HAS_REGCEA => 0, C_USE_BYTE_WEA => 1, C_WEA_WIDTH => 4, C_WRITE_MODE_A => "WRITE_FIRST", C_WRITE_WIDTH_A => 32, C_READ_WIDTH_A => 32, C_WRITE_DEPTH_A => 2048, C_READ_DEPTH_A => 2048, C_ADDRA_WIDTH => 32, C_HAS_RSTB => 1, C_RST_PRIORITY_B => "CE", C_RSTRAM_B => 0, C_INITB_VAL => "0", C_HAS_ENB => 1, C_HAS_REGCEB => 0, C_USE_BYTE_WEB => 1, C_WEB_WIDTH => 4, C_WRITE_MODE_B => "WRITE_FIRST", C_WRITE_WIDTH_B => 32, C_READ_WIDTH_B => 32, C_WRITE_DEPTH_B => 2048, C_READ_DEPTH_B => 2048, C_ADDRB_WIDTH => 32, C_HAS_MEM_OUTPUT_REGS_A => 0, C_HAS_MEM_OUTPUT_REGS_B => 0, C_HAS_MUX_OUTPUT_REGS_A => 0, C_HAS_MUX_OUTPUT_REGS_B => 0, C_MUX_PIPELINE_STAGES => 0, C_HAS_SOFTECC_INPUT_REGS_A => 0, C_HAS_SOFTECC_OUTPUT_REGS_B => 0, C_USE_SOFTECC => 0, C_USE_ECC => 0, C_EN_ECC_PIPE => 0, C_HAS_INJECTERR => 0, C_SIM_COLLISION_CHECK => "ALL", C_COMMON_CLK => 0, C_DISABLE_WARN_BHV_COLL => 0, C_EN_SLEEP_PIN => 0, C_DISABLE_WARN_BHV_RANGE => 0, C_COUNT_36K_BRAM => "2", C_COUNT_18K_BRAM => "0", C_EST_POWER_SUMMARY => "Estimated Power for IP : 10.7492 mW" ) PORT MAP ( clka => clka, rsta => rsta, ena => ena, regcea => '0', wea => wea, addra => addra, dina => dina, douta => douta, clkb => clkb, rstb => rstb, enb => enb, regceb => '0', web => web, addrb => addrb, dinb => dinb, doutb => doutb, injectsbiterr => '0', injectdbiterr => '0', eccpipece => '0', sleep => '0', s_aclk => '0', s_aresetn => '0', s_axi_awid => STD_LOGIC_VECTOR(TO_UNSIGNED(0, 4)), s_axi_awaddr => STD_LOGIC_VECTOR(TO_UNSIGNED(0, 32)), s_axi_awlen => STD_LOGIC_VECTOR(TO_UNSIGNED(0, 8)), s_axi_awsize => STD_LOGIC_VECTOR(TO_UNSIGNED(0, 3)), s_axi_awburst => STD_LOGIC_VECTOR(TO_UNSIGNED(0, 2)), s_axi_awvalid => '0', s_axi_wdata => STD_LOGIC_VECTOR(TO_UNSIGNED(0, 32)), s_axi_wstrb => STD_LOGIC_VECTOR(TO_UNSIGNED(0, 4)), s_axi_wlast => '0', s_axi_wvalid => '0', s_axi_bready => '0', s_axi_arid => STD_LOGIC_VECTOR(TO_UNSIGNED(0, 4)), s_axi_araddr => STD_LOGIC_VECTOR(TO_UNSIGNED(0, 32)), s_axi_arlen => STD_LOGIC_VECTOR(TO_UNSIGNED(0, 8)), s_axi_arsize => STD_LOGIC_VECTOR(TO_UNSIGNED(0, 3)), s_axi_arburst => STD_LOGIC_VECTOR(TO_UNSIGNED(0, 2)), s_axi_arvalid => '0', s_axi_rready => '0', s_axi_injectsbiterr => '0', s_axi_injectdbiterr => '0' ); END design_1_blk_mem_gen_0_0_arch;

gpl-3.0

0e8296ab2425a358859afdb1e1b0bae9

0.636131

3.032817

false

mistryalok/Zedboard

learning/training/Microsystem/axi_interface_part2/project_1/project_1.srcs/sources_1/bd/design_1/ip/design_1_axi_bram_ctrl_0_0/synth/design_1_axi_bram_ctrl_0_0.vhd

1

16,618

-- (c) Copyright 1995-2016 Xilinx, Inc. All rights reserved. -- -- This file contains confidential and proprietary information -- of Xilinx, Inc. and is protected under U.S. and -- international copyright and other intellectual property -- laws. -- -- DISCLAIMER -- This disclaimer is not a license and does not grant any -- rights to the materials distributed herewith. Except as -- otherwise provided in a valid license issued to you by -- Xilinx, and to the maximum extent permitted by applicable -- law: (1) THESE MATERIALS ARE MADE AVAILABLE "AS IS" AND -- WITH ALL FAULTS, AND XILINX HEREBY DISCLAIMS ALL WARRANTIES -- AND CONDITIONS, EXPRESS, IMPLIED, OR STATUTORY, INCLUDING -- BUT NOT LIMITED TO WARRANTIES OF MERCHANTABILITY, NON- -- INFRINGEMENT, OR FITNESS FOR ANY PARTICULAR PURPOSE; and -- (2) Xilinx shall not be liable (whether in contract or tort, -- including negligence, or under any other theory of -- liability) for any loss or damage of any kind or nature -- related to, arising under or in connection with these -- materials, including for any direct, or any indirect, -- special, incidental, or consequential loss or damage -- (including loss of data, profits, goodwill, or any type of -- loss or damage suffered as a result of any action brought -- by a third party) even if such damage or loss was -- reasonably foreseeable or Xilinx had been advised of the -- possibility of the same. -- -- CRITICAL APPLICATIONS -- Xilinx products are not designed or intended to be fail- -- safe, or for use in any application requiring fail-safe -- performance, such as life-support or safety devices or -- systems, Class III medical devices, nuclear facilities, -- applications related to the deployment of airbags, or any -- other applications that could lead to death, personal -- injury, or severe property or environmental damage -- (individually and collectively, "Critical -- Applications"). Customer assumes the sole risk and -- liability of any use of Xilinx products in Critical -- Applications, subject only to applicable laws and -- regulations governing limitations on product liability. -- -- THIS COPYRIGHT NOTICE AND DISCLAIMER MUST BE RETAINED AS -- PART OF THIS FILE AT ALL TIMES. -- -- DO NOT MODIFY THIS FILE. -- IP VLNV: xilinx.com:ip:axi_bram_ctrl:4.0 -- IP Revision: 3 LIBRARY ieee; USE ieee.std_logic_1164.ALL; USE ieee.numeric_std.ALL; LIBRARY axi_bram_ctrl_v4_0; USE axi_bram_ctrl_v4_0.axi_bram_ctrl; ENTITY design_1_axi_bram_ctrl_0_0 IS PORT ( s_axi_aclk : IN STD_LOGIC; s_axi_aresetn : IN STD_LOGIC; s_axi_awid : IN STD_LOGIC_VECTOR(11 DOWNTO 0); s_axi_awaddr : IN STD_LOGIC_VECTOR(12 DOWNTO 0); s_axi_awlen : IN STD_LOGIC_VECTOR(7 DOWNTO 0); s_axi_awsize : IN STD_LOGIC_VECTOR(2 DOWNTO 0); s_axi_awburst : IN STD_LOGIC_VECTOR(1 DOWNTO 0); s_axi_awlock : IN STD_LOGIC; s_axi_awcache : IN STD_LOGIC_VECTOR(3 DOWNTO 0); s_axi_awprot : IN STD_LOGIC_VECTOR(2 DOWNTO 0); s_axi_awvalid : IN STD_LOGIC; s_axi_awready : OUT STD_LOGIC; s_axi_wdata : IN STD_LOGIC_VECTOR(31 DOWNTO 0); s_axi_wstrb : IN STD_LOGIC_VECTOR(3 DOWNTO 0); s_axi_wlast : IN STD_LOGIC; s_axi_wvalid : IN STD_LOGIC; s_axi_wready : OUT STD_LOGIC; s_axi_bid : OUT STD_LOGIC_VECTOR(11 DOWNTO 0); s_axi_bresp : OUT STD_LOGIC_VECTOR(1 DOWNTO 0); s_axi_bvalid : OUT STD_LOGIC; s_axi_bready : IN STD_LOGIC; s_axi_arid : IN STD_LOGIC_VECTOR(11 DOWNTO 0); s_axi_araddr : IN STD_LOGIC_VECTOR(12 DOWNTO 0); s_axi_arlen : IN STD_LOGIC_VECTOR(7 DOWNTO 0); s_axi_arsize : IN STD_LOGIC_VECTOR(2 DOWNTO 0); s_axi_arburst : IN STD_LOGIC_VECTOR(1 DOWNTO 0); s_axi_arlock : IN STD_LOGIC; s_axi_arcache : IN STD_LOGIC_VECTOR(3 DOWNTO 0); s_axi_arprot : IN STD_LOGIC_VECTOR(2 DOWNTO 0); s_axi_arvalid : IN STD_LOGIC; s_axi_arready : OUT STD_LOGIC; s_axi_rid : OUT STD_LOGIC_VECTOR(11 DOWNTO 0); s_axi_rdata : OUT STD_LOGIC_VECTOR(31 DOWNTO 0); s_axi_rresp : OUT STD_LOGIC_VECTOR(1 DOWNTO 0); s_axi_rlast : OUT STD_LOGIC; s_axi_rvalid : OUT STD_LOGIC; s_axi_rready : IN STD_LOGIC; bram_rst_a : OUT STD_LOGIC; bram_clk_a : OUT STD_LOGIC; bram_en_a : OUT STD_LOGIC; bram_we_a : OUT STD_LOGIC_VECTOR(3 DOWNTO 0); bram_addr_a : OUT STD_LOGIC_VECTOR(12 DOWNTO 0); bram_wrdata_a : OUT STD_LOGIC_VECTOR(31 DOWNTO 0); bram_rddata_a : IN STD_LOGIC_VECTOR(31 DOWNTO 0) ); END design_1_axi_bram_ctrl_0_0; ARCHITECTURE design_1_axi_bram_ctrl_0_0_arch OF design_1_axi_bram_ctrl_0_0 IS ATTRIBUTE DowngradeIPIdentifiedWarnings : string; ATTRIBUTE DowngradeIPIdentifiedWarnings OF design_1_axi_bram_ctrl_0_0_arch: ARCHITECTURE IS "yes"; COMPONENT axi_bram_ctrl IS GENERIC ( C_BRAM_INST_MODE : STRING; C_MEMORY_DEPTH : INTEGER; C_BRAM_ADDR_WIDTH : INTEGER; C_S_AXI_ADDR_WIDTH : INTEGER; C_S_AXI_DATA_WIDTH : INTEGER; C_S_AXI_ID_WIDTH : INTEGER; C_S_AXI_PROTOCOL : STRING; C_S_AXI_SUPPORTS_NARROW_BURST : INTEGER; C_SINGLE_PORT_BRAM : INTEGER; C_FAMILY : STRING; C_S_AXI_CTRL_ADDR_WIDTH : INTEGER; C_S_AXI_CTRL_DATA_WIDTH : INTEGER; C_ECC : INTEGER; C_ECC_TYPE : INTEGER; C_FAULT_INJECT : INTEGER; C_ECC_ONOFF_RESET_VALUE : INTEGER ); PORT ( s_axi_aclk : IN STD_LOGIC; s_axi_aresetn : IN STD_LOGIC; ecc_interrupt : OUT STD_LOGIC; ecc_ue : OUT STD_LOGIC; s_axi_awid : IN STD_LOGIC_VECTOR(11 DOWNTO 0); s_axi_awaddr : IN STD_LOGIC_VECTOR(12 DOWNTO 0); s_axi_awlen : IN STD_LOGIC_VECTOR(7 DOWNTO 0); s_axi_awsize : IN STD_LOGIC_VECTOR(2 DOWNTO 0); s_axi_awburst : IN STD_LOGIC_VECTOR(1 DOWNTO 0); s_axi_awlock : IN STD_LOGIC; s_axi_awcache : IN STD_LOGIC_VECTOR(3 DOWNTO 0); s_axi_awprot : IN STD_LOGIC_VECTOR(2 DOWNTO 0); s_axi_awvalid : IN STD_LOGIC; s_axi_awready : OUT STD_LOGIC; s_axi_wdata : IN STD_LOGIC_VECTOR(31 DOWNTO 0); s_axi_wstrb : IN STD_LOGIC_VECTOR(3 DOWNTO 0); s_axi_wlast : IN STD_LOGIC; s_axi_wvalid : IN STD_LOGIC; s_axi_wready : OUT STD_LOGIC; s_axi_bid : OUT STD_LOGIC_VECTOR(11 DOWNTO 0); s_axi_bresp : OUT STD_LOGIC_VECTOR(1 DOWNTO 0); s_axi_bvalid : OUT STD_LOGIC; s_axi_bready : IN STD_LOGIC; s_axi_arid : IN STD_LOGIC_VECTOR(11 DOWNTO 0); s_axi_araddr : IN STD_LOGIC_VECTOR(12 DOWNTO 0); s_axi_arlen : IN STD_LOGIC_VECTOR(7 DOWNTO 0); s_axi_arsize : IN STD_LOGIC_VECTOR(2 DOWNTO 0); s_axi_arburst : IN STD_LOGIC_VECTOR(1 DOWNTO 0); s_axi_arlock : IN STD_LOGIC; s_axi_arcache : IN STD_LOGIC_VECTOR(3 DOWNTO 0); s_axi_arprot : IN STD_LOGIC_VECTOR(2 DOWNTO 0); s_axi_arvalid : IN STD_LOGIC; s_axi_arready : OUT STD_LOGIC; s_axi_rid : OUT STD_LOGIC_VECTOR(11 DOWNTO 0); s_axi_rdata : OUT STD_LOGIC_VECTOR(31 DOWNTO 0); s_axi_rresp : OUT STD_LOGIC_VECTOR(1 DOWNTO 0); s_axi_rlast : OUT STD_LOGIC; s_axi_rvalid : OUT STD_LOGIC; s_axi_rready : IN STD_LOGIC; s_axi_ctrl_awvalid : IN STD_LOGIC; s_axi_ctrl_awready : OUT STD_LOGIC; s_axi_ctrl_awaddr : IN STD_LOGIC_VECTOR(31 DOWNTO 0); s_axi_ctrl_wdata : IN STD_LOGIC_VECTOR(31 DOWNTO 0); s_axi_ctrl_wvalid : IN STD_LOGIC; s_axi_ctrl_wready : OUT STD_LOGIC; s_axi_ctrl_bresp : OUT STD_LOGIC_VECTOR(1 DOWNTO 0); s_axi_ctrl_bvalid : OUT STD_LOGIC; s_axi_ctrl_bready : IN STD_LOGIC; s_axi_ctrl_araddr : IN STD_LOGIC_VECTOR(31 DOWNTO 0); s_axi_ctrl_arvalid : IN STD_LOGIC; s_axi_ctrl_arready : OUT STD_LOGIC; s_axi_ctrl_rdata : OUT STD_LOGIC_VECTOR(31 DOWNTO 0); s_axi_ctrl_rresp : OUT STD_LOGIC_VECTOR(1 DOWNTO 0); s_axi_ctrl_rvalid : OUT STD_LOGIC; s_axi_ctrl_rready : IN STD_LOGIC; bram_rst_a : OUT STD_LOGIC; bram_clk_a : OUT STD_LOGIC; bram_en_a : OUT STD_LOGIC; bram_we_a : OUT STD_LOGIC_VECTOR(3 DOWNTO 0); bram_addr_a : OUT STD_LOGIC_VECTOR(12 DOWNTO 0); bram_wrdata_a : OUT STD_LOGIC_VECTOR(31 DOWNTO 0); bram_rddata_a : IN STD_LOGIC_VECTOR(31 DOWNTO 0); bram_rst_b : OUT STD_LOGIC; bram_clk_b : OUT STD_LOGIC; bram_en_b : OUT STD_LOGIC; bram_we_b : OUT STD_LOGIC_VECTOR(3 DOWNTO 0); bram_addr_b : OUT STD_LOGIC_VECTOR(12 DOWNTO 0); bram_wrdata_b : OUT STD_LOGIC_VECTOR(31 DOWNTO 0); bram_rddata_b : IN STD_LOGIC_VECTOR(31 DOWNTO 0) ); END COMPONENT axi_bram_ctrl; ATTRIBUTE X_CORE_INFO : STRING; ATTRIBUTE X_CORE_INFO OF design_1_axi_bram_ctrl_0_0_arch: ARCHITECTURE IS "axi_bram_ctrl,Vivado 2014.4"; ATTRIBUTE CHECK_LICENSE_TYPE : STRING; ATTRIBUTE CHECK_LICENSE_TYPE OF design_1_axi_bram_ctrl_0_0_arch : ARCHITECTURE IS "design_1_axi_bram_ctrl_0_0,axi_bram_ctrl,{}"; ATTRIBUTE CORE_GENERATION_INFO : STRING; ATTRIBUTE CORE_GENERATION_INFO OF design_1_axi_bram_ctrl_0_0_arch: ARCHITECTURE IS "design_1_axi_bram_ctrl_0_0,axi_bram_ctrl,{x_ipProduct=Vivado 2014.4,x_ipVendor=xilinx.com,x_ipLibrary=ip,x_ipName=axi_bram_ctrl,x_ipVersion=4.0,x_ipCoreRevision=3,x_ipLanguage=VERILOG,x_ipSimLanguage=MIXED,C_BRAM_INST_MODE=EXTERNAL,C_MEMORY_DEPTH=2048,C_BRAM_ADDR_WIDTH=11,C_S_AXI_ADDR_WIDTH=13,C_S_AXI_DATA_WIDTH=32,C_S_AXI_ID_WIDTH=12,C_S_AXI_PROTOCOL=AXI4,C_S_AXI_SUPPORTS_NARROW_BURST=0,C_SINGLE_PORT_BRAM=1,C_FAMILY=zynq,C_S_AXI_CTRL_ADDR_WIDTH=32,C_S_AXI_CTRL_DATA_WIDTH=32,C_ECC=0,C_ECC_TYPE=0,C_FAULT_INJECT=0,C_ECC_ONOFF_RESET_VALUE=0}"; ATTRIBUTE X_INTERFACE_INFO : STRING; ATTRIBUTE X_INTERFACE_INFO OF s_axi_aclk: SIGNAL IS "xilinx.com:signal:clock:1.0 CLKIF CLK"; ATTRIBUTE X_INTERFACE_INFO OF s_axi_aresetn: SIGNAL IS "xilinx.com:signal:reset:1.0 RSTIF RST"; ATTRIBUTE X_INTERFACE_INFO OF s_axi_awid: SIGNAL IS "xilinx.com:interface:aximm:1.0 S_AXI AWID"; ATTRIBUTE X_INTERFACE_INFO OF s_axi_awaddr: SIGNAL IS "xilinx.com:interface:aximm:1.0 S_AXI AWADDR"; ATTRIBUTE X_INTERFACE_INFO OF s_axi_awlen: SIGNAL IS "xilinx.com:interface:aximm:1.0 S_AXI AWLEN"; ATTRIBUTE X_INTERFACE_INFO OF s_axi_awsize: SIGNAL IS "xilinx.com:interface:aximm:1.0 S_AXI AWSIZE"; ATTRIBUTE X_INTERFACE_INFO OF s_axi_awburst: SIGNAL IS "xilinx.com:interface:aximm:1.0 S_AXI AWBURST"; ATTRIBUTE X_INTERFACE_INFO OF s_axi_awlock: SIGNAL IS "xilinx.com:interface:aximm:1.0 S_AXI AWLOCK"; ATTRIBUTE X_INTERFACE_INFO OF s_axi_awcache: SIGNAL IS "xilinx.com:interface:aximm:1.0 S_AXI AWCACHE"; ATTRIBUTE X_INTERFACE_INFO OF s_axi_awprot: SIGNAL IS "xilinx.com:interface:aximm:1.0 S_AXI AWPROT"; ATTRIBUTE X_INTERFACE_INFO OF s_axi_awvalid: SIGNAL IS "xilinx.com:interface:aximm:1.0 S_AXI AWVALID"; ATTRIBUTE X_INTERFACE_INFO OF s_axi_awready: SIGNAL IS "xilinx.com:interface:aximm:1.0 S_AXI AWREADY"; ATTRIBUTE X_INTERFACE_INFO OF s_axi_wdata: SIGNAL IS "xilinx.com:interface:aximm:1.0 S_AXI WDATA"; ATTRIBUTE X_INTERFACE_INFO OF s_axi_wstrb: SIGNAL IS "xilinx.com:interface:aximm:1.0 S_AXI WSTRB"; ATTRIBUTE X_INTERFACE_INFO OF s_axi_wlast: SIGNAL IS "xilinx.com:interface:aximm:1.0 S_AXI WLAST"; ATTRIBUTE X_INTERFACE_INFO OF s_axi_wvalid: SIGNAL IS "xilinx.com:interface:aximm:1.0 S_AXI WVALID"; ATTRIBUTE X_INTERFACE_INFO OF s_axi_wready: SIGNAL IS "xilinx.com:interface:aximm:1.0 S_AXI WREADY"; ATTRIBUTE X_INTERFACE_INFO OF s_axi_bid: SIGNAL IS "xilinx.com:interface:aximm:1.0 S_AXI BID"; ATTRIBUTE X_INTERFACE_INFO OF s_axi_bresp: SIGNAL IS "xilinx.com:interface:aximm:1.0 S_AXI BRESP"; ATTRIBUTE X_INTERFACE_INFO OF s_axi_bvalid: SIGNAL IS "xilinx.com:interface:aximm:1.0 S_AXI BVALID"; ATTRIBUTE X_INTERFACE_INFO OF s_axi_bready: SIGNAL IS "xilinx.com:interface:aximm:1.0 S_AXI BREADY"; ATTRIBUTE X_INTERFACE_INFO OF s_axi_arid: SIGNAL IS "xilinx.com:interface:aximm:1.0 S_AXI ARID"; ATTRIBUTE X_INTERFACE_INFO OF s_axi_araddr: SIGNAL IS "xilinx.com:interface:aximm:1.0 S_AXI ARADDR"; ATTRIBUTE X_INTERFACE_INFO OF s_axi_arlen: SIGNAL IS "xilinx.com:interface:aximm:1.0 S_AXI ARLEN"; ATTRIBUTE X_INTERFACE_INFO OF s_axi_arsize: SIGNAL IS "xilinx.com:interface:aximm:1.0 S_AXI ARSIZE"; ATTRIBUTE X_INTERFACE_INFO OF s_axi_arburst: SIGNAL IS "xilinx.com:interface:aximm:1.0 S_AXI ARBURST"; ATTRIBUTE X_INTERFACE_INFO OF s_axi_arlock: SIGNAL IS "xilinx.com:interface:aximm:1.0 S_AXI ARLOCK"; ATTRIBUTE X_INTERFACE_INFO OF s_axi_arcache: SIGNAL IS "xilinx.com:interface:aximm:1.0 S_AXI ARCACHE"; ATTRIBUTE X_INTERFACE_INFO OF s_axi_arprot: SIGNAL IS "xilinx.com:interface:aximm:1.0 S_AXI ARPROT"; ATTRIBUTE X_INTERFACE_INFO OF s_axi_arvalid: SIGNAL IS "xilinx.com:interface:aximm:1.0 S_AXI ARVALID"; ATTRIBUTE X_INTERFACE_INFO OF s_axi_arready: SIGNAL IS "xilinx.com:interface:aximm:1.0 S_AXI ARREADY"; ATTRIBUTE X_INTERFACE_INFO OF s_axi_rid: SIGNAL IS "xilinx.com:interface:aximm:1.0 S_AXI RID"; ATTRIBUTE X_INTERFACE_INFO OF s_axi_rdata: SIGNAL IS "xilinx.com:interface:aximm:1.0 S_AXI RDATA"; ATTRIBUTE X_INTERFACE_INFO OF s_axi_rresp: SIGNAL IS "xilinx.com:interface:aximm:1.0 S_AXI RRESP"; ATTRIBUTE X_INTERFACE_INFO OF s_axi_rlast: SIGNAL IS "xilinx.com:interface:aximm:1.0 S_AXI RLAST"; ATTRIBUTE X_INTERFACE_INFO OF s_axi_rvalid: SIGNAL IS "xilinx.com:interface:aximm:1.0 S_AXI RVALID"; ATTRIBUTE X_INTERFACE_INFO OF s_axi_rready: SIGNAL IS "xilinx.com:interface:aximm:1.0 S_AXI RREADY"; ATTRIBUTE X_INTERFACE_INFO OF bram_rst_a: SIGNAL IS "xilinx.com:interface:bram:1.0 BRAM_PORTA RST"; ATTRIBUTE X_INTERFACE_INFO OF bram_clk_a: SIGNAL IS "xilinx.com:interface:bram:1.0 BRAM_PORTA CLK"; ATTRIBUTE X_INTERFACE_INFO OF bram_en_a: SIGNAL IS "xilinx.com:interface:bram:1.0 BRAM_PORTA EN"; ATTRIBUTE X_INTERFACE_INFO OF bram_we_a: SIGNAL IS "xilinx.com:interface:bram:1.0 BRAM_PORTA WE"; ATTRIBUTE X_INTERFACE_INFO OF bram_addr_a: SIGNAL IS "xilinx.com:interface:bram:1.0 BRAM_PORTA ADDR"; ATTRIBUTE X_INTERFACE_INFO OF bram_wrdata_a: SIGNAL IS "xilinx.com:interface:bram:1.0 BRAM_PORTA DIN"; ATTRIBUTE X_INTERFACE_INFO OF bram_rddata_a: SIGNAL IS "xilinx.com:interface:bram:1.0 BRAM_PORTA DOUT"; BEGIN U0 : axi_bram_ctrl GENERIC MAP ( C_BRAM_INST_MODE => "EXTERNAL", C_MEMORY_DEPTH => 2048, C_BRAM_ADDR_WIDTH => 11, C_S_AXI_ADDR_WIDTH => 13, C_S_AXI_DATA_WIDTH => 32, C_S_AXI_ID_WIDTH => 12, C_S_AXI_PROTOCOL => "AXI4", C_S_AXI_SUPPORTS_NARROW_BURST => 0, C_SINGLE_PORT_BRAM => 1, C_FAMILY => "zynq", C_S_AXI_CTRL_ADDR_WIDTH => 32, C_S_AXI_CTRL_DATA_WIDTH => 32, C_ECC => 0, C_ECC_TYPE => 0, C_FAULT_INJECT => 0, C_ECC_ONOFF_RESET_VALUE => 0 ) PORT MAP ( s_axi_aclk => s_axi_aclk, s_axi_aresetn => s_axi_aresetn, s_axi_awid => s_axi_awid, s_axi_awaddr => s_axi_awaddr, s_axi_awlen => s_axi_awlen, s_axi_awsize => s_axi_awsize, s_axi_awburst => s_axi_awburst, s_axi_awlock => s_axi_awlock, s_axi_awcache => s_axi_awcache, s_axi_awprot => s_axi_awprot, s_axi_awvalid => s_axi_awvalid, s_axi_awready => s_axi_awready, s_axi_wdata => s_axi_wdata, s_axi_wstrb => s_axi_wstrb, s_axi_wlast => s_axi_wlast, s_axi_wvalid => s_axi_wvalid, s_axi_wready => s_axi_wready, s_axi_bid => s_axi_bid, s_axi_bresp => s_axi_bresp, s_axi_bvalid => s_axi_bvalid, s_axi_bready => s_axi_bready, s_axi_arid => s_axi_arid, s_axi_araddr => s_axi_araddr, s_axi_arlen => s_axi_arlen, s_axi_arsize => s_axi_arsize, s_axi_arburst => s_axi_arburst, s_axi_arlock => s_axi_arlock, s_axi_arcache => s_axi_arcache, s_axi_arprot => s_axi_arprot, s_axi_arvalid => s_axi_arvalid, s_axi_arready => s_axi_arready, s_axi_rid => s_axi_rid, s_axi_rdata => s_axi_rdata, s_axi_rresp => s_axi_rresp, s_axi_rlast => s_axi_rlast, s_axi_rvalid => s_axi_rvalid, s_axi_rready => s_axi_rready, s_axi_ctrl_awvalid => '0', s_axi_ctrl_awaddr => STD_LOGIC_VECTOR(TO_UNSIGNED(0, 32)), s_axi_ctrl_wdata => STD_LOGIC_VECTOR(TO_UNSIGNED(0, 32)), s_axi_ctrl_wvalid => '0', s_axi_ctrl_bready => '0', s_axi_ctrl_araddr => STD_LOGIC_VECTOR(TO_UNSIGNED(0, 32)), s_axi_ctrl_arvalid => '0', s_axi_ctrl_rready => '0', bram_rst_a => bram_rst_a, bram_clk_a => bram_clk_a, bram_en_a => bram_en_a, bram_we_a => bram_we_a, bram_addr_a => bram_addr_a, bram_wrdata_a => bram_wrdata_a, bram_rddata_a => bram_rddata_a, bram_rddata_b => STD_LOGIC_VECTOR(TO_UNSIGNED(0, 32)) ); END design_1_axi_bram_ctrl_0_0_arch;

gpl-3.0

c5bb4866f0060cd796ab1f7cbc087b66

0.676014

3.060969

false

marco-c/leon-nexys2

grlib-gpl-1.3.4-b4140/lib/techmap/stratixii/clkgen_stratixii.vhd

1

6,703

------------------------------------------------------------------------------ -- This file is a part of the GRLIB VHDL IP LIBRARY -- Copyright (C) 2003 - 2008, Gaisler Research -- Copyright (C) 2008 - 2013, Aeroflex Gaisler -- -- This program is free software; you can redistribute it and/or modify -- it under the terms of the GNU General Public License as published by -- the Free Software Foundation; either version 2 of the License, or -- (at your option) any later version. -- -- This program is distributed in the hope that it will be useful, -- but WITHOUT ANY WARRANTY; without even the implied warranty of -- MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the -- GNU General Public License for more details. -- -- You should have received a copy of the GNU General Public License -- along with this program; if not, write to the Free Software -- Foundation, Inc., 59 Temple Place, Suite 330, Boston, MA 02111-1307 USA ------------------------------------------------------------------------------- library ieee; use ieee.std_logic_1164.all; library techmap; use techmap.gencomp.all; library altera_mf; -- pragma translate_off use altera_mf.altpll; -- pragma translate_on entity stratix2_pll is generic ( clk_mul : integer := 1; clk_div : integer := 1; clk_freq : integer := 25000; clk2xen : integer := 0; sdramen : integer := 0 ); port ( inclk0 : in std_ulogic; c0 : out std_ulogic; c0_2x : out std_ulogic; e0 : out std_ulogic; locked : out std_ulogic ); end; architecture rtl of stratix2_pll is component altpll generic ( intended_device_family : string := "Stratix" ; operation_mode : string := "NORMAL" ; compensate_clock : string := "CLK0" ; inclk0_input_frequency : positive; width_clock : positive := 6; clk0_multiply_by : positive := 1; clk0_divide_by : positive := 1; clk1_multiply_by : positive := 1; clk1_divide_by : positive := 1; clk2_multiply_by : positive := 1; clk2_divide_by : positive := 1 ); port ( inclk : in std_logic_vector(1 downto 0); clk : out std_logic_vector(width_clock-1 downto 0); locked : out std_logic ); end component; signal clkout : std_logic_vector (5 downto 0); signal inclk : std_logic_vector (1 downto 0); constant clk_period : integer := 1000000000/clk_freq; constant CLK_MUL2X : integer := clk_mul * 2; begin inclk <= '0' & inclk0; c0 <= clkout(0); c0_2x <= clkout(1); sden : if sdramen = 1 generate altpll0 : altpll generic map ( intended_device_family => "Stratix II", operation_mode => "ZERO_DELAY_BUFFER", compensate_clock => "CLK2", inclk0_input_frequency => clk_period, clk0_multiply_by => clk_mul, clk0_divide_by => clk_div, clk1_multiply_by => CLK_MUL2X, clk1_divide_by => clk_div, clk2_multiply_by => clk_mul, clk2_divide_by => clk_div) port map (inclk => inclk, clk => clkout, locked => locked); e0 <= clkout(2); end generate; nosd : if sdramen = 0 generate altpll0 : altpll generic map ( intended_device_family => "Stratix II", operation_mode => "NORMAL", inclk0_input_frequency => clk_period, clk0_multiply_by => clk_mul, clk0_divide_by => clk_div, clk1_multiply_by => CLK_MUL2X, clk1_divide_by => clk_div) port map (inclk => inclk, clk => clkout, locked => locked); e0 <= '0'; end generate; end; library ieee; use ieee.std_logic_1164.all; -- pragma translate_off library altera_mf; library grlib; use grlib.stdlib.all; -- pragma translate_on library techmap; use techmap.gencomp.all; entity clkgen_stratixii is generic ( clk_mul : integer := 1; clk_div : integer := 1; sdramen : integer := 0; sdinvclk : integer := 0; pcien : integer := 0; pcidll : integer := 0; pcisysclk: integer := 0; freq : integer := 25000; clk2xen : integer := 0); port ( clkin : in std_logic; pciclkin: in std_logic; clk : out std_logic; -- main clock clkn : out std_logic; -- inverted main clock clk2x : out std_logic; -- double clock sdclk : out std_logic; -- SDRAM clock pciclk : out std_logic; -- PCI clock cgi : in clkgen_in_type; cgo : out clkgen_out_type); end; architecture rtl of clkgen_stratixii is constant VERSION : integer := 1; constant CLKIN_PERIOD : integer := 20; signal clk_i : std_logic; signal clkint, pciclkint : std_logic; signal pllclk, pllclkn : std_logic; -- generated clocks signal s_clk : std_logic; -- altera pll component stratix2_pll generic ( clk_mul : integer := 1; clk_div : integer := 1; clk_freq : integer := 25000; clk2xen : integer := 0; sdramen : integer := 0 ); port ( inclk0 : in std_ulogic; e0 : out std_ulogic; c0 : out std_ulogic; c0_2x : out std_ulogic; locked : out std_ulogic); end component; begin cgo.pcilock <= '1'; -- c0 : if (PCISYSCLK = 0) generate -- Clkint <= Clkin; -- end generate; -- c1 : if (PCISYSCLK = 1) generate -- Clkint <= pciclkin; -- end generate; -- c2 : if (PCIEN = 1) generate -- p0 : if (PCIDLL = 1) generate -- pciclkint <= pciclkin; -- pciclk <= pciclkint; -- end generate; -- p1 : if (PCIDLL = 0) generate -- u0 : if (PCISYSCLK = 0) generate -- pciclkint <= pciclkin; -- end generate; -- pciclk <= clk_i when (PCISYSCLK = 1) else pciclkint; -- end generate; -- end generate; -- c3 : if (PCIEN = 0) generate -- pciclk <= Clkint; -- end generate; c0: if (PCISYSCLK = 0) or (PCIEN = 0) generate clkint <= clkin; end generate c0; c1: if PCIEN /= 0 generate d0: if PCISYSCLK = 1 generate clkint <= pciclkin; end generate d0; pciclk <= pciclkin; end generate c1; c2: if PCIEN = 0 generate pciclk <= '0'; end generate c2; sdclk_pll : stratix2_pll generic map (clk_mul, clk_div, freq, clk2xen, sdramen) port map ( inclk0 => clkint, e0 => sdclk, c0 => s_clk, c0_2x => clk2x, locked => cgo.clklock); clk <= s_clk; clkn <= not s_clk; -- pragma translate_off bootmsg : report_version generic map ( "clkgen_stratixii" & ": altpll sdram/pci clock generator, version " & tost(VERSION), "clkgen_stratixii" & ": Frequency " & tost(freq) & " KHz, PLL scaler " & tost(clk_mul) & "/" & tost(clk_div)); -- pragma translate_on end;

gpl-2.0

216a35e308b2eed49aed647efc545b3f

0.584962

3.513103

false

marco-c/leon-nexys2

grlib-gpl-1.3.4-b4140/designs/leon3-gr-xc6s/leon3mp.vhd

1

47,744

----------------------------------------------------------------------------- -- LEON3 Demonstration design -- Copyright (C) 2011 Jiri Gaisler, Gaisler Research ------------------------------------------------------------------------------ -- This file is a part of the GRLIB VHDL IP LIBRARY -- Copyright (C) 2003 - 2008, Gaisler Research -- Copyright (C) 2008 - 2013, Aeroflex Gaisler -- -- This program is free software; you can redistribute it and/or modify -- it under the terms of the GNU General Public License as published by -- the Free Software Foundation; either version 2 of the License, or -- (at your option) any later version. -- -- This program is distributed in the hope that it will be useful, -- but WITHOUT ANY WARRANTY; without even the implied warranty of -- MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the -- GNU General Public License for more details. -- -- You should have received a copy of the GNU General Public License -- along with this program; if not, write to the Free Software -- Foundation, Inc., 59 Temple Place, Suite 330, Boston, MA 02111-1307 USA ------------------------------------------------------------------------------ library ieee; use ieee.std_logic_1164.all; library grlib, techmap; use grlib.amba.all; use grlib.amba.all; use grlib.stdlib.all; use techmap.gencomp.all; use techmap.allclkgen.all; library gaisler; use gaisler.memctrl.all; use gaisler.leon3.all; use gaisler.uart.all; use gaisler.misc.all; use gaisler.spi.all; use gaisler.i2c.all; use gaisler.can.all; use gaisler.net.all; use gaisler.jtag.all; use gaisler.spacewire.all; -- pragma translate_off use gaisler.sim.all; library unisim; use unisim.all; -- pragma translate_on library esa; use esa.memoryctrl.all; use work.config.all; entity leon3mp is generic ( fabtech : integer := CFG_FABTECH; memtech : integer := CFG_MEMTECH; padtech : integer := CFG_PADTECH; clktech : integer := CFG_CLKTECH; disas : integer := CFG_DISAS; -- Enable disassembly to console dbguart : integer := CFG_DUART; -- Print UART on console pclow : integer := CFG_PCLOW ); port ( resetn : in std_ulogic; clk : in std_ulogic; -- 50 MHz main clock clk2 : in std_ulogic; -- User clock clk125 : in std_ulogic; -- 125 MHz clock from PHY wdogn : out std_ulogic; address : out std_logic_vector(24 downto 0); data : inout std_logic_vector(31 downto 24); oen : out std_ulogic; writen : out std_ulogic; romsn : out std_logic; ddr_clk : out std_logic; ddr_clkb : out std_logic; ddr_cke : out std_logic; ddr_odt : out std_logic; ddr_we : out std_ulogic; -- ddr write enable ddr_ras : out std_ulogic; -- ddr ras ddr_csn : out std_ulogic; -- ddr csn ddr_cas : out std_ulogic; -- ddr cas ddr_dm : out std_logic_vector (1 downto 0); -- ddr dm ddr_dqs : inout std_logic_vector (1 downto 0); -- ddr dqs ddr_dqsn : inout std_logic_vector (1 downto 0); -- ddr dqs n ddr_ad : out std_logic_vector (12 downto 0); -- ddr address ddr_ba : out std_logic_vector (2 downto 0); -- ddr bank address ddr_dq : inout std_logic_vector (15 downto 0); -- ddr data ddr_rzq : inout std_ulogic; ddr_zio : inout std_ulogic; -- dsuen : in std_ulogic; -- dip swtich 7 -- dsubre : in std_ulogic; -- switch 9 -- dsuact : out std_ulogic; -- led (0) txd1 : out std_ulogic; -- UART1 tx data rxd1 : in std_ulogic; -- UART1 rx data ctsn1 : in std_ulogic; -- UART1 ctsn rtsn1 : out std_ulogic; -- UART1 trsn txd2 : out std_ulogic; -- UART2 tx data rxd2 : in std_ulogic; -- UART2 rx data ctsn2 : in std_ulogic; -- UART2 ctsn rtsn2 : out std_ulogic; -- UART2 rtsn pio : inout std_logic_vector(17 downto 0); -- I/O port genio : inout std_logic_vector(59 downto 0); -- I/O port switch : in std_logic_vector(9 downto 0); -- I/O port led : out std_logic_vector(3 downto 0); -- I/O port erx_clk : in std_ulogic; emdio : inout std_logic; -- ethernet PHY interface erxd : in std_logic_vector(3 downto 0); erx_dv : in std_ulogic; emdint : in std_ulogic; etx_clk : out std_ulogic; etxd : out std_logic_vector(3 downto 0); etx_en : out std_ulogic; emdc : out std_ulogic; ps2clk : inout std_logic_vector(1 downto 0); ps2data : inout std_logic_vector(1 downto 0); iic_scl : inout std_ulogic; iic_sda : inout std_ulogic; ddc_scl : inout std_ulogic; ddc_sda : inout std_ulogic; dvi_iic_scl : inout std_logic; dvi_iic_sda : inout std_logic; tft_lcd_data : out std_logic_vector(11 downto 0); tft_lcd_clk_p : out std_ulogic; tft_lcd_clk_n : out std_ulogic; tft_lcd_hsync : out std_ulogic; tft_lcd_vsync : out std_ulogic; tft_lcd_de : out std_ulogic; tft_lcd_reset_b : out std_ulogic; spw_clk : in std_ulogic; spw_rxdp : in std_logic_vector(0 to CFG_SPW_NUM-1); spw_rxdn : in std_logic_vector(0 to CFG_SPW_NUM-1); spw_rxsp : in std_logic_vector(0 to CFG_SPW_NUM-1); spw_rxsn : in std_logic_vector(0 to CFG_SPW_NUM-1); spw_txdp : out std_logic_vector(0 to CFG_SPW_NUM-1); spw_txdn : out std_logic_vector(0 to CFG_SPW_NUM-1); spw_txsp : out std_logic_vector(0 to CFG_SPW_NUM-1); spw_txsn : out std_logic_vector(0 to CFG_SPW_NUM-1); -- SPI flash spi_sel_n : inout std_ulogic; spi_clk : out std_ulogic; spi_mosi : out std_ulogic -- SD Card interface (SD SPI interface) -- sdata : inout std_ulogic_vector(3 downto 0); -- sd_clk : out std_ulogic; -- spi_cmd : out std_ulogic; -- sd_prot : in std_logic; -- sd_detect : in std_logic ); end; architecture rtl of leon3mp is component BUFG port (O : out std_logic; I : in std_logic); end component; component IODELAY2 generic ( COUNTER_WRAPAROUND : string := "WRAPAROUND"; DATA_RATE : string := "SDR"; DELAY_SRC : string := "IO"; IDELAY2_VALUE : integer := 0; IDELAY_MODE : string := "NORMAL"; IDELAY_TYPE : string := "DEFAULT"; IDELAY_VALUE : integer := 0; ODELAY_VALUE : integer := 0; SERDES_MODE : string := "NONE"; SIM_TAPDELAY_VALUE : integer := 75 ); port ( BUSY : out std_ulogic; DATAOUT : out std_ulogic; DATAOUT2 : out std_ulogic; DOUT : out std_ulogic; TOUT : out std_ulogic; CAL : in std_ulogic; CE : in std_ulogic; CLK : in std_ulogic; IDATAIN : in std_ulogic; INC : in std_ulogic; IOCLK0 : in std_ulogic; IOCLK1 : in std_ulogic; ODATAIN : in std_ulogic; RST : in std_ulogic; T : in std_ulogic ); end component; attribute syn_netlist_hierarchy : boolean; attribute syn_netlist_hierarchy of rtl : architecture is false; constant use_eth_input_delay : integer := 1; constant use_eth_output_delay : integer := 1; constant blength : integer := 12; constant fifodepth : integer := 8; constant maxahbm : integer := CFG_NCPU+CFG_AHB_UART+CFG_GRETH+ CFG_AHB_JTAG+CFG_SPW_NUM*CFG_SPW_EN; signal vcc, gnd : std_logic; signal memi : memory_in_type; signal memo : memory_out_type; signal wpo : wprot_out_type; signal sdi : sdctrl_in_type; signal sdo : sdram_out_type; signal leds : std_logic_vector(3 downto 0); -- I/O port signal apbi, apbi2 : apb_slv_in_type; signal apbo, apbo2 : apb_slv_out_vector := (others => apb_none); signal ahbsi : ahb_slv_in_type; signal ahbso : ahb_slv_out_vector := (others => ahbs_none); signal ahbmi : ahb_mst_in_type; signal vahbmi : ahb_mst_in_type; signal ahbmo : ahb_mst_out_vector := (others => ahbm_none); signal vahbmo : ahb_mst_out_type; signal clkm, rstn, rstraw, sdclkl : std_ulogic; signal clk_200 : std_ulogic; signal clk25, clk40, clk65 : std_ulogic; signal cgi, cgi2, cgi3 : clkgen_in_type; signal cgo, cgo2, cgo3 : clkgen_out_type; signal u1i, u2i, dui : uart_in_type; signal u1o, u2o, duo : uart_out_type; signal irqi : irq_in_vector(0 to CFG_NCPU-1); signal irqo : irq_out_vector(0 to CFG_NCPU-1); signal dbgi : l3_debug_in_vector(0 to CFG_NCPU-1); signal dbgo : l3_debug_out_vector(0 to CFG_NCPU-1); signal dsui : dsu_in_type; signal dsuo : dsu_out_type; signal gmiii, rgmiii, rgmiii_buf : eth_in_type; signal gmiio, rgmiio : eth_out_type; signal gpti : gptimer_in_type; signal gpto : gptimer_out_type; signal gpioi : gpio_in_type; signal gpioo : gpio_out_type; signal gpioi2 : gpio_in_type; signal gpioo2 : gpio_out_type; signal gpioi3 : gpio_in_type; signal gpioo3 : gpio_out_type; signal can_lrx, can_ltx : std_logic_vector(0 to 7); signal lock, calib_done, clkml, lclk, rst, ndsuact, wdogl : std_ulogic := '0'; signal tck, tckn, tms, tdi, tdo : std_ulogic; signal ethclk, ddr2clk : std_ulogic; signal kbdi : ps2_in_type; signal kbdo : ps2_out_type; signal moui : ps2_in_type; signal mouo : ps2_out_type; signal vgao : apbvga_out_type; signal lcd_datal : std_logic_vector(11 downto 0); signal lcd_hsyncl, lcd_vsyncl, lcd_del, lcd_reset_bl : std_ulogic; signal i2ci, dvi_i2ci : i2c_in_type; signal i2co, dvi_i2co : i2c_out_type; signal spmi : spimctrl_in_type; signal spmo : spimctrl_out_type; signal spmi2 : spimctrl_in_type; signal spmo2 : spimctrl_out_type; constant BOARD_FREQ : integer := 50000; -- input frequency in KHz constant CPU_FREQ : integer := BOARD_FREQ * CFG_CLKMUL / CFG_CLKDIV; -- cpu frequency in KHz constant IOAEN : integer := CFG_CAN; constant DDR2_FREQ : integer := 200000; -- DDR2 input frequency in KHz signal spwi : grspw_in_type_vector(0 to CFG_SPW_NUM-1); signal spwo : grspw_out_type_vector(0 to CFG_SPW_NUM-1); signal dtmp : std_logic_vector(CFG_SPW_NUM*CFG_SPW_PORTS-1 downto 0); signal stmp : std_logic_vector(CFG_SPW_NUM*CFG_SPW_PORTS-1 downto 0); signal spw_rxtxclk : std_ulogic; signal spw_rxclkn : std_ulogic; signal spw_rxclk : std_logic_vector(0 to CFG_SPW_NUM*CFG_SPW_PORTS); signal spw_rstn : std_ulogic; signal spw_rstn_sync : std_ulogic; signal stati : ahbstat_in_type; signal fpi : grfpu_in_vector_type; signal fpo : grfpu_out_vector_type; signal rstgtxn : std_logic; signal idelay_reset_cnt : std_logic_vector(3 downto 0); signal idelay_cal_cnt : std_logic_vector(3 downto 0); signal idelayctrl_reset : std_logic; signal idelayctrl_cal : std_logic; signal rgmiii_rx_clk_n : std_logic; signal rgmiii_rx_clk_n_buf : std_logic; signal rgmiio_tx_clk,rgmiio_tx_en : std_logic; signal rgmiio_txd : std_logic_vector(3 downto 0); -- Used for connecting input/output signals to the DDR2 controller signal core_ddr_clk : std_logic_vector(2 downto 0); signal core_ddr_clkb : std_logic_vector(2 downto 0); signal core_ddr_cke : std_logic_vector(1 downto 0); signal core_ddr_csb : std_logic_vector(1 downto 0); signal core_ddr_ad : std_logic_vector(13 downto 0); signal core_ddr_odt : std_logic_vector(1 downto 0); constant SPW_LOOP_BACK : integer := 0; signal video_clk, clk50, clk100, spw100 : std_logic; -- signals to vga_clkgen. signal clk_sel : std_logic_vector(1 downto 0); signal clkvga, clkvga_p, clkvga_n : std_ulogic; signal clk_125 : std_ulogic; signal nerror : std_ulogic; attribute keep : boolean; attribute syn_keep : boolean; attribute syn_preserve : boolean; attribute syn_keep of clk50 : signal is true; attribute syn_preserve of clk50 : signal is true; attribute keep of clk50 : signal is true; attribute syn_keep of video_clk : signal is true; attribute syn_preserve of video_clk : signal is true; attribute keep of video_clk : signal is true; attribute syn_preserve of ddr2clk : signal is true; attribute keep of ddr2clk : signal is true; attribute syn_keep of ddr2clk : signal is true; attribute syn_preserve of spw100 : signal is true; attribute keep of spw100 : signal is true; attribute syn_preserve of clkm : signal is true; attribute keep of clkm : signal is true; begin ---------------------------------------------------------------------- --- Reset and Clock generation ------------------------------------- ---------------------------------------------------------------------- vcc <= '1'; gnd <= '0'; cgi.pllctrl <= "00"; cgi.pllrst <= rstraw; clk_pad : clkpad generic map (tech => padtech) port map (clk, lclk); ddr2clk <= lclk; ethclk <= lclk; no_clk_mig : if CFG_MIG_DDR2 = 0 generate clkgen0 : clkgen -- clock generator generic map (clktech, CFG_CLKMUL, CFG_CLKDIV, CFG_MCTRL_SDEN, CFG_CLK_NOFB, 0, 0, 0, BOARD_FREQ) port map (lclk, lclk, clkm, open, open, sdclkl, open, cgi, cgo, open, clk50, clk100); rst0 : rstgen -- reset generator generic map(syncin => 1) port map (rst, clkm, lock, rstn, rstraw); end generate; clk_mig : if CFG_MIG_DDR2 = 1 generate clk50 <= clkm; rstraw <= rst; cgo.clklock <= '1'; end generate; resetn_pad : inpad generic map (tech => padtech) port map (resetn, rst); lock <= cgo.clklock and calib_done; ---------------------------------------------------------------------- --- AHB CONTROLLER -------------------------------------------------- ---------------------------------------------------------------------- ahb0 : ahbctrl -- AHB arbiter/multiplexer generic map (defmast => CFG_DEFMST, split => CFG_SPLIT, rrobin => CFG_RROBIN, ioaddr => CFG_AHBIO, ioen => IOAEN, nahbm => maxahbm, nahbs => 16) port map (rstn, clkm, ahbmi, ahbmo, ahbsi, ahbso); ---------------------------------------------------------------------- --- LEON3 processor and DSU ----------------------------------------- ---------------------------------------------------------------------- nosh : if CFG_GRFPUSH = 0 generate cpu : for i in 0 to CFG_NCPU-1 generate l3ft : if CFG_LEON3FT_EN /= 0 generate leon3ft0 : leon3ft -- LEON3 processor generic map (i, fabtech, memtech, CFG_NWIN, CFG_DSU, CFG_FPU*(1-CFG_GRFPUSH), CFG_V8, 0, CFG_MAC, pclow, CFG_NOTAG, CFG_NWP, CFG_ICEN, CFG_IREPL, CFG_ISETS, CFG_ILINE, CFG_ISETSZ, CFG_ILOCK, CFG_DCEN, CFG_DREPL, CFG_DSETS, CFG_DLINE, CFG_DSETSZ, CFG_DLOCK, CFG_DSNOOP, CFG_ILRAMEN, CFG_ILRAMSZ, CFG_ILRAMADDR, CFG_DLRAMEN, CFG_DLRAMSZ, CFG_DLRAMADDR, CFG_MMUEN, CFG_ITLBNUM, CFG_DTLBNUM, CFG_TLB_TYPE, CFG_TLB_REP, CFG_LDDEL, disas, CFG_ITBSZ, CFG_PWD, CFG_SVT, CFG_RSTADDR, CFG_NCPU-1, CFG_IUFT_EN, CFG_FPUFT_EN, CFG_CACHE_FT_EN, CFG_RF_ERRINJ, CFG_CACHE_ERRINJ, CFG_DFIXED, CFG_LEON3_NETLIST, CFG_SCAN, CFG_MMU_PAGE, CFG_BP) port map (clkm, rstn, ahbmi, ahbmo(i), ahbsi, ahbso, irqi(i), irqo(i), dbgi(i), dbgo(i), clkm); end generate; l3s : if CFG_LEON3FT_EN = 0 generate u0 : leon3s -- LEON3 processor generic map (i, fabtech, memtech, CFG_NWIN, CFG_DSU, CFG_FPU*(1-CFG_GRFPUSH), CFG_V8, 0, CFG_MAC, pclow, CFG_NOTAG, CFG_NWP, CFG_ICEN, CFG_IREPL, CFG_ISETS, CFG_ILINE, CFG_ISETSZ, CFG_ILOCK, CFG_DCEN, CFG_DREPL, CFG_DSETS, CFG_DLINE, CFG_DSETSZ, CFG_DLOCK, CFG_DSNOOP, CFG_ILRAMEN, CFG_ILRAMSZ, CFG_ILRAMADDR, CFG_DLRAMEN, CFG_DLRAMSZ, CFG_DLRAMADDR, CFG_MMUEN, CFG_ITLBNUM, CFG_DTLBNUM, CFG_TLB_TYPE, CFG_TLB_REP, CFG_LDDEL, disas, CFG_ITBSZ, CFG_PWD, CFG_SVT, CFG_RSTADDR, CFG_NCPU-1, CFG_DFIXED, CFG_SCAN, CFG_MMU_PAGE, CFG_BP) port map (clkm, rstn, ahbmi, ahbmo(i), ahbsi, ahbso, irqi(i), irqo(i), dbgi(i), dbgo(i)); end generate; end generate; end generate; sh : if CFG_GRFPUSH = 1 generate cpu : for i in 0 to CFG_NCPU-1 generate l3ft : if CFG_LEON3FT_EN /= 0 generate leon3ft0 : leon3ftsh -- LEON3 processor generic map (i, fabtech, memtech, CFG_NWIN, CFG_DSU, CFG_FPU, CFG_V8, 0, CFG_MAC, pclow, CFG_NOTAG, CFG_NWP, CFG_ICEN, CFG_IREPL, CFG_ISETS, CFG_ILINE, CFG_ISETSZ, CFG_ILOCK, CFG_DCEN, CFG_DREPL, CFG_DSETS, CFG_DLINE, CFG_DSETSZ, CFG_DLOCK, CFG_DSNOOP, CFG_ILRAMEN, CFG_ILRAMSZ, CFG_ILRAMADDR, CFG_DLRAMEN, CFG_DLRAMSZ, CFG_DLRAMADDR, CFG_MMUEN, CFG_ITLBNUM, CFG_DTLBNUM, CFG_TLB_TYPE, CFG_TLB_REP, CFG_LDDEL, disas, CFG_ITBSZ, CFG_PWD, CFG_SVT, CFG_RSTADDR, CFG_NCPU-1, CFG_IUFT_EN, CFG_FPUFT_EN, CFG_CACHE_FT_EN, CFG_RF_ERRINJ, CFG_CACHE_ERRINJ, CFG_DFIXED, CFG_LEON3_NETLIST, CFG_SCAN, CFG_MMU_PAGE) port map (clkm, rstn, ahbmi, ahbmo(i), ahbsi, ahbso, irqi(i), irqo(i), dbgi(i), dbgo(i), clkm, fpi(i), fpo(i)); end generate; l3s : if CFG_LEON3FT_EN = 0 generate u0 : leon3sh -- LEON3 processor generic map (i, fabtech, memtech, CFG_NWIN, CFG_DSU, CFG_FPU, CFG_V8, 0, CFG_MAC, pclow, CFG_NOTAG, CFG_NWP, CFG_ICEN, CFG_IREPL, CFG_ISETS, CFG_ILINE, CFG_ISETSZ, CFG_ILOCK, CFG_DCEN, CFG_DREPL, CFG_DSETS, CFG_DLINE, CFG_DSETSZ, CFG_DLOCK, CFG_DSNOOP, CFG_ILRAMEN, CFG_ILRAMSZ, CFG_ILRAMADDR, CFG_DLRAMEN, CFG_DLRAMSZ, CFG_DLRAMADDR, CFG_MMUEN, CFG_ITLBNUM, CFG_DTLBNUM, CFG_TLB_TYPE, CFG_TLB_REP, CFG_LDDEL, disas, CFG_ITBSZ, CFG_PWD, CFG_SVT, CFG_RSTADDR, CFG_NCPU-1, CFG_DFIXED, CFG_SCAN, CFG_MMU_PAGE) port map (clkm, rstn, ahbmi, ahbmo(i), ahbsi, ahbso, irqi(i), irqo(i), dbgi(i), dbgo(i), fpi(i), fpo(i)); end generate; end generate; grfpush0 : grfpushwx generic map ((CFG_FPU-1), CFG_NCPU, fabtech) port map (clkm, rstn, fpi, fpo); end generate; nerror <= dbgo(0).error; led1_pad : odpad generic map (tech => padtech) port map (led(1), nerror); dsugen : if CFG_DSU = 1 generate dsu0 : dsu3 -- LEON3 Debug Support Unit generic map (hindex => 2, haddr => 16#900#, hmask => 16#F00#, ncpu => CFG_NCPU, tbits => 30, tech => memtech, irq => 0, kbytes => CFG_ATBSZ) port map (rstn, clkm, ahbmi, ahbsi, ahbso(2), dbgo, dbgi, dsui, dsuo); dsuen_pad : inpad generic map (tech => padtech) port map (switch(7), dsui.enable); dsubre_pad : inpad generic map (tech => padtech) port map (switch(8), dsui.break); dsuact_pad : outpad generic map (tech => padtech) port map (led(0), ndsuact); ndsuact <= not dsuo.active; end generate; nodsu : if CFG_DSU = 0 generate dsuo.tstop <= '0'; dsuo.active <= '0'; ahbso(2) <= ahbs_none; end generate; dcomgen : if CFG_AHB_UART = 1 generate dcom0: ahbuart -- Debug UART generic map (hindex => CFG_NCPU, pindex => 7, paddr => 7) port map (rstn, clkm, dui, duo, apbi, apbo(7), ahbmi, ahbmo(CFG_NCPU)); dsurx_pad : inpad generic map (tech => padtech) port map (rxd2, dui.rxd); dsutx_pad : outpad generic map (tech => padtech) port map (txd2, duo.txd); end generate; nouah : if CFG_AHB_UART = 0 generate apbo(7) <= apb_none; end generate; ahbjtaggen0 :if CFG_AHB_JTAG = 1 generate ahbjtag0 : ahbjtag generic map(tech => fabtech, hindex => CFG_NCPU+CFG_AHB_UART) port map(rstn, clkm, tck, tms, tdi, tdo, ahbmi, ahbmo(CFG_NCPU+CFG_AHB_UART), open, open, open, open, open, open, open, gnd); end generate; ---------------------------------------------------------------------- --- Memory controllers ---------------------------------------------- ---------------------------------------------------------------------- memi.writen <= '1'; memi.wrn <= "1111"; memi.bwidth <= "00"; memi.brdyn <= '0'; memi.bexcn <= '1'; mctrl0 : if CFG_MCTRL_LEON2 /= 0 generate mctrl0 : mctrl generic map (hindex => 0, pindex => 0, paddr => 0, srbanks => 2, ram8 => CFG_MCTRL_RAM8BIT, ram16 => CFG_MCTRL_RAM16BIT, sden => CFG_MCTRL_SDEN, invclk => CFG_CLK_NOFB, sepbus => CFG_MCTRL_SEPBUS, pageburst => CFG_MCTRL_PAGE, rammask => 0, iomask => 0) port map (rstn, clkm, memi, memo, ahbsi, ahbso(0), apbi, apbo(0), wpo, sdo); addr_pad : outpadv generic map (width => 25, tech => padtech) port map (address, memo.address(24 downto 0)); roms_pad : outpad generic map (tech => padtech) port map (romsn, memo.romsn(0)); oen_pad : outpad generic map (tech => padtech) port map (oen, memo.oen); wri_pad : outpad generic map (tech => padtech) port map (writen, memo.writen); bdr : for i in 0 to 0 generate data_pad : iopadv generic map (tech => padtech, width => 8) port map (data(31-i*8 downto 24-i*8), memo.data(31-i*8 downto 24-i*8), memo.bdrive(i), memi.data(31-i*8 downto 24-i*8)); end generate; end generate; nomctrl : if CFG_MCTRL_LEON2 = 0 generate romsn <= '1'; ahbso(0) <= ahbs_none; end generate; ----------------------------------------------------------------------- --- Test report module ---------------------------------------------- ----------------------------------------------------------------------- -- pragma translate_off test0 : ahbrep generic map (hindex => 6, haddr => 16#200#) port map (rstn, clkm, ahbsi, ahbso(6)); -- pragma translate_on ---------------------------------------------------------------------- --- DDR2 memory controller ------------------------------------------ ---------------------------------------------------------------------- ddr_csn <= '0'; mig_gen : if (CFG_MIG_DDR2 = 1) generate ddrc : entity work.ahb2mig_grxc6s_2p generic map( hindex => 4, haddr => 16#400#, hmask => 16#F80#, pindex => 0, paddr => 0, vgamst => CFG_SVGA_ENABLE, vgaburst => 64, clkdiv => 10) port map( mcb3_dram_dq => ddr_dq, mcb3_dram_a => ddr_ad, mcb3_dram_ba => ddr_ba, mcb3_dram_ras_n => ddr_ras, mcb3_dram_cas_n => ddr_cas, mcb3_dram_we_n => ddr_we, mcb3_dram_odt => ddr_odt, mcb3_dram_cke => ddr_cke, mcb3_dram_dm => ddr_dm(0), mcb3_dram_udqs => ddr_dqs(1), mcb3_dram_udqs_n => ddr_dqsn(1), mcb3_rzq => ddr_rzq, mcb3_zio => ddr_zio, mcb3_dram_udm => ddr_dm(1), mcb3_dram_dqs => ddr_dqs(0), mcb3_dram_dqs_n => ddr_dqsn(0), mcb3_dram_ck => ddr_clk, mcb3_dram_ck_n => ddr_clkb, ahbsi => ahbsi, ahbso => ahbso(4), ahbmi => vahbmi, ahbmo => vahbmo, apbi => apbi2, apbo => apbo2(0), calib_done => calib_done, rst_n_syn => rstn, rst_n_async => rstraw, clk_amba => clkm, clk_mem_n => ddr2clk, clk_mem_p => ddr2clk, test_error => open, clk_125 => clk_125, clk_100 => clk100 ); end generate; noddr : if (CFG_DDR2SP+CFG_MIG_DDR2) = 0 generate calib_done <= '1'; end generate; ---------------------------------------------------------------------- --- SPI Memory Controller-------------------------------------------- ---------------------------------------------------------------------- spimc: if CFG_SPICTRL_ENABLE = 0 and CFG_SPIMCTRL = 1 generate spimctrl0 : spimctrl -- SPI Memory Controller generic map (hindex => 3, hirq => 7, faddr => 16#e00#, fmask => 16#ff8#, ioaddr => 16#002#, iomask => 16#fff#, spliten => CFG_SPLIT, oepol => 0, sdcard => CFG_SPIMCTRL_SDCARD, readcmd => CFG_SPIMCTRL_READCMD, dummybyte => CFG_SPIMCTRL_DUMMYBYTE, dualoutput => CFG_SPIMCTRL_DUALOUTPUT, scaler => CFG_SPIMCTRL_SCALER, altscaler => CFG_SPIMCTRL_ASCALER, pwrupcnt => CFG_SPIMCTRL_PWRUPCNT) port map (rstn, clkm, ahbsi, ahbso(3), spmi, spmo); -- MISO is shared with Flash data 0 spmi.miso <= memi.data(24); mosi_pad : outpad generic map (tech => padtech) port map (spi_mosi, spmo.mosi); sck_pad : outpad generic map (tech => padtech) port map (spi_clk, spmo.sck); slvsel0_pad : odpad generic map (tech => padtech) port map (spi_sel_n, spmo.csn); end generate; nospimc: if ((CFG_SPICTRL_ENABLE = 0 and CFG_SPIMCTRL = 0) or (CFG_SPICTRL_ENABLE = 1 and CFG_SPIMCTRL = 1) or (CFG_SPICTRL_ENABLE = 1 and CFG_SPIMCTRL = 0))generate mosi_pad : outpad generic map (tech => padtech) port map (spi_mosi, '0'); sck_pad : outpad generic map (tech => padtech) port map (spi_clk, '0'); end generate; ---------------------------------------------------------------------- --- APB Bridge and various periherals ------------------------------- ---------------------------------------------------------------------- apb0 : apbctrl -- AHB/APB bridge generic map (hindex => 1, haddr => CFG_APBADDR, nslaves => 16) port map (rstn, clkm, ahbsi, ahbso(1), apbi, apbo ); apb1 : apbctrl -- AHB/APB bridge generic map (hindex => 13, haddr => CFG_APBADDR+1, nslaves => 16) port map (rstn, clkm, ahbsi, ahbso(13), apbi2, apbo2 ); ua1 : if CFG_UART1_ENABLE /= 0 generate uart1 : apbuart -- UART 1 generic map (pindex => 1, paddr => 1, pirq => 2, console => dbguart, fifosize => CFG_UART1_FIFO) port map (rstn, clkm, apbi, apbo(1), u1i, u1o); u1i.extclk <= '0'; rxd1_pad : inpad generic map (tech => padtech) port map (rxd1, u1i.rxd); txd1_pad : outpad generic map (tech => padtech) port map (txd1, u1o.txd); cts1_pad : inpad generic map (tech => padtech) port map (ctsn1, u1i.ctsn); rts1_pad : outpad generic map (tech => padtech) port map (rtsn1, u1o.rtsn); end generate; noua0 : if CFG_UART1_ENABLE = 0 generate apbo(1) <= apb_none; end generate; rts1_pad : outpad generic map (tech => padtech) port map (rtsn2, '0'); irqctrl : if CFG_IRQ3_ENABLE /= 0 generate irqctrl0 : irqmp -- interrupt controller generic map (pindex => 2, paddr => 2, ncpu => CFG_NCPU) port map (rstn, clkm, apbi, apbo(2), irqo, irqi); end generate; irq3 : if CFG_IRQ3_ENABLE = 0 generate x : for i in 0 to CFG_NCPU-1 generate irqi(i).irl <= "0000"; end generate; apbo(2) <= apb_none; end generate; gpt : if CFG_GPT_ENABLE /= 0 generate timer0 : gptimer -- timer unit generic map (pindex => 3, paddr => 3, pirq => CFG_GPT_IRQ, sepirq => CFG_GPT_SEPIRQ, sbits => CFG_GPT_SW, ntimers => CFG_GPT_NTIM, nbits => CFG_GPT_TW, wdog => CFG_GPT_WDOGEN*CFG_GPT_WDOG) port map (rstn, clkm, apbi, apbo(3), gpti, gpto); gpti.dhalt <= dsuo.tstop; gpti.extclk <= '0'; end generate; wden : if CFG_GPT_WDOGEN /= 0 generate wdogl <= gpto.wdogn or not rstn; wdogn_pad : odpad generic map (tech => padtech) port map (wdogn, wdogl); end generate; wddis : if CFG_GPT_WDOGEN = 0 generate wdogn_pad : odpad generic map (tech => padtech) port map (wdogn, vcc); end generate; nogpt : if CFG_GPT_ENABLE = 0 generate apbo(3) <= apb_none; end generate; kbd : if CFG_KBD_ENABLE /= 0 generate ps21 : apbps2 generic map(pindex => 4, paddr => 4, pirq => 4) port map(rstn, clkm, apbi, apbo(4), moui, mouo); ps20 : apbps2 generic map(pindex => 5, paddr => 5, pirq => 5) port map(rstn, clkm, apbi, apbo(5), kbdi, kbdo); end generate; nokbd : if CFG_KBD_ENABLE = 0 generate apbo(4) <= apb_none; mouo <= ps2o_none; apbo(5) <= apb_none; kbdo <= ps2o_none; end generate; kbdclk_pad : iopad generic map (tech => padtech) port map (ps2clk(1),kbdo.ps2_clk_o, kbdo.ps2_clk_oe, kbdi.ps2_clk_i); kbdata_pad : iopad generic map (tech => padtech) port map (ps2data(1), kbdo.ps2_data_o, kbdo.ps2_data_oe, kbdi.ps2_data_i); mouclk_pad : iopad generic map (tech => padtech) port map (ps2clk(0),mouo.ps2_clk_o, mouo.ps2_clk_oe, moui.ps2_clk_i); mouata_pad : iopad generic map (tech => padtech) port map (ps2data(0), mouo.ps2_data_o, mouo.ps2_data_oe, moui.ps2_data_i); vga : if CFG_VGA_ENABLE /= 0 generate vga0 : apbvga generic map(memtech => memtech, pindex => 6, paddr => 6) port map(rstn, clkm, ethclk, apbi, apbo(6), vgao); video_clk <= not ethclk; end generate; svga : if CFG_SVGA_ENABLE /= 0 generate svga0 : svgactrl generic map(memtech => memtech, pindex => 6, paddr => 6, hindex => CFG_NCPU+CFG_AHB_UART+CFG_AHB_JTAG, clk0 => 20000, clk1 => 0, --1000000000/((BOARD_FREQ * CFG_CLKMUL)/CFG_CLKDIV), clk2 => 0, clk3 => 0, burstlen => 6) port map(rstn, clkm, video_clk, apbi, apbo(6), vgao, vahbmi, vahbmo, clk_sel); end generate; --b0 : techbuf generic map (2, fabtech) port map (clk50, video_clk); video_clk <= clk50; vgadvi : if (CFG_VGA_ENABLE + CFG_SVGA_ENABLE) /= 0 generate dvi0 : entity work.svga2ch7301c generic map (tech => fabtech, dynamic => 1) port map (clkm, vgao, video_clk, clkvga_p, clkvga_n, lcd_datal, lcd_hsyncl, lcd_vsyncl, lcd_del); i2cdvi : i2cmst generic map (pindex => 9, paddr => 9, pmask => 16#FFF#, pirq => 3) port map (rstn, clkm, apbi, apbo(9), dvi_i2ci, dvi_i2co); end generate; novga : if (CFG_VGA_ENABLE = 0 and CFG_SVGA_ENABLE = 0) generate apbo(6) <= apb_none; vgao <= vgao_none; end generate; tft_lcd_data_pad : outpadv generic map (width => 12, tech => padtech) port map (tft_lcd_data, lcd_datal); tft_lcd_clkp_pad : outpad generic map (tech => padtech) port map (tft_lcd_clk_p, clkvga_p); tft_lcd_clkn_pad : outpad generic map (tech => padtech) port map (tft_lcd_clk_n, clkvga_n); tft_lcd_hsync_pad : outpad generic map (tech => padtech) port map (tft_lcd_hsync, lcd_hsyncl); tft_lcd_vsync_pad : outpad generic map (tech => padtech) port map (tft_lcd_vsync, lcd_vsyncl); tft_lcd_de_pad : outpad generic map (tech => padtech) port map (tft_lcd_de, lcd_del); tft_lcd_reset_pad : outpad generic map (tech => padtech) port map (tft_lcd_reset_b, rstn); dvi_i2c_scl_pad : iopad generic map (tech => padtech) port map (dvi_iic_scl, dvi_i2co.scl, dvi_i2co.scloen, dvi_i2ci.scl); dvi_i2c_sda_pad : iopad generic map (tech => padtech) port map (dvi_iic_sda, dvi_i2co.sda, dvi_i2co.sdaoen, dvi_i2ci.sda); gpio0 : if CFG_GRGPIO_ENABLE /= 0 generate -- GPIO unit grgpio0: grgpio generic map(pindex => 10, paddr => 10, imask => CFG_GRGPIO_IMASK, nbits => 16) port map(rst => rstn, clk => clkm, apbi => apbi, apbo => apbo(10), gpioi => gpioi, gpioo => gpioo); p0 : if (CFG_CAN = 0) or (CFG_CAN_NUM = 1) generate pio_pads : for i in 1 to 2 generate pio_pad : iopad generic map (tech => padtech) port map (pio(i), gpioo.dout(i), gpioo.oen(i), gpioi.din(i)); end generate; end generate; p1 : if (CFG_CAN = 0) generate pio_pads : for i in 4 to 5 generate pio_pad : iopad generic map (tech => padtech) port map (pio(i), gpioo.dout(i), gpioo.oen(i), gpioi.din(i)); end generate; end generate; pio_pad0 : iopad generic map (tech => padtech) port map (pio(0), gpioo.dout(0), gpioo.oen(0), gpioi.din(0)); pio_pad1 : iopad generic map (tech => padtech) port map (pio(3), gpioo.dout(3), gpioo.oen(3), gpioi.din(3)); pio_pads : for i in 6 to 15 generate pio_pad : iopad generic map (tech => padtech) port map (pio(i), gpioo.dout(i), gpioo.oen(i), gpioi.din(i)); end generate; end generate; -- make an additonal 32 bit GPIO port for genio(31..0) gpio1 : if CFG_GRGPIO_ENABLE /= 0 generate -- GPIO unit grgpio1: grgpio generic map(pindex => 11, paddr => 11, imask => CFG_GRGPIO_IMASK, nbits => 32) port map(rst => rstn, clk => clkm, apbi => apbi, apbo => apbo(11), gpioi => gpioi2, gpioo => gpioo2); pio_pads : for i in 0 to 31 generate pio_pad : iopad generic map (tech => padtech) port map (genio(i), gpioo2.dout(i), gpioo2.oen(i), gpioi2.din(i)); end generate; end generate; gpio2 : if CFG_GRGPIO_ENABLE /= 0 generate -- GPIO unit grgpio2: grgpio generic map(pindex => 12, paddr => 12, imask => CFG_GRGPIO_IMASK, nbits => 28) port map(rst => rstn, clk => clkm, apbi => apbi, apbo => apbo(12), gpioi => gpioi3, gpioo => gpioo3); pio_pads : for i in 0 to 27 generate pio_pad : iopad generic map (tech => padtech) port map (genio(i+32), gpioo3.dout(i), gpioo3.oen(i), gpioi3.din(i)); end generate; end generate; ahbs : if CFG_AHBSTAT = 1 generate -- AHB status register ahbstat0 : ahbstat generic map (pindex => 13, paddr => 13, pirq => 1, nftslv => CFG_AHBSTATN) port map (rstn, clkm, ahbmi, ahbsi, stati, apbi, apbo(13)); end generate; ----------------------------------------------------------------------- --- ETHERNET --------------------------------------------------------- ----------------------------------------------------------------------- eth0 : if CFG_GRETH = 1 generate -- Gaisler ethernet MAC e1 : grethm generic map( hindex => CFG_NCPU+CFG_AHB_UART+CFG_AHB_JTAG, pindex => 14, paddr => 14, pirq => 6, memtech => memtech, mdcscaler => CPU_FREQ/1000, rmii => 0, enable_mdio => 1, fifosize => CFG_ETH_FIFO, nsync => 1, edcl => CFG_DSU_ETH, edclbufsz => CFG_ETH_BUF, phyrstadr => 1, macaddrh => CFG_ETH_ENM, macaddrl => CFG_ETH_ENL, enable_mdint => 1, ipaddrh => CFG_ETH_IPM, ipaddrl => CFG_ETH_IPL, giga => CFG_GRETH1G) port map( rst => rstn, clk => clkm, ahbmi => ahbmi, ahbmo => ahbmo(CFG_NCPU+CFG_AHB_UART+CFG_AHB_JTAG), apbi => apbi, apbo => apbo(14), ethi => gmiii, etho => gmiio); end generate; led(3 downto 2) <= not (gmiio.gbit & gmiio.speed); noethindelay0 : if (use_eth_input_delay = 0) generate rgmiii.rx_dv <= rgmiii_buf.rx_dv; rgmiii.rxd <= rgmiii_buf.rxd; end generate; noethoutdelay0 : if (use_eth_output_delay = 0) generate rgmiio_tx_clk <= rgmiio.tx_clk; rgmiio_tx_en <= rgmiio.tx_en; rgmiio_txd <= rgmiio.txd(3 downto 0); end generate; ethindelay0 : if (use_eth_input_delay /= 0) generate delay_rgmii_rx_ctl0 : IODELAY2 generic map( DELAY_SRC => "IDATAIN", IDELAY_TYPE => "FIXED", IDELAY_VALUE => 16 -- Delay (256/8)*424ps*30% + n/8*424ps + Ttap(See table 39 in Xilinx ds162.pdf) ) port map( IDATAIN => rgmiii_buf.rx_dv, T => '1', ODATAIN => '0', CAL => '0', IOCLK0 => '0', IOCLK1 => '0', CLK => '0', INC => '0', CE => '0', RST => '0', BUSY => OPEN, DATAOUT => rgmiii.rx_dv, DATAOUT2 => OPEN, TOUT => OPEN, DOUT => OPEN ); rgmii_rxd : for i in 0 to 3 generate delay_rgmii_rxd0 : IODELAY2 generic map( DELAY_SRC => "IDATAIN", IDELAY_TYPE => "FIXED", IDELAY_VALUE => 16 -- Delay (256/8)*424ps*30% + n/8*424ps + Ttap(See table 39 in Xilinx ds162.pdf) ) port map( IDATAIN => rgmiii_buf.rxd(i), T => '1', ODATAIN => '0', CAL => '0', IOCLK0 => '0', IOCLK1 => '0', CLK => '0', INC => '0', CE => '0', RST => '0', BUSY => OPEN, DATAOUT => rgmiii.rxd(i), DATAOUT2 => OPEN, TOUT => OPEN, DOUT => OPEN ); end generate; end generate; ethoutdelay0 : if (use_eth_output_delay /= 0) generate delay_rgmii_tx_clk0 : IODELAY2 generic map( DELAY_SRC => "ODATAIN", IDELAY_TYPE => "FIXED", ODELAY_VALUE => 16 -- Delay (256/8)*424ps*30% + n/8*424ps + Ttap(See table 39 in Xilinx ds162.pdf) ) port map( IDATAIN => '0', T => '1', ODATAIN => rgmiio.tx_clk, CAL => '0', IOCLK0 => '0', IOCLK1 => '0', CLK => '0', INC => '0', CE => '0', RST => '0', BUSY => OPEN, DATAOUT => OPEN, DATAOUT2 => OPEN, TOUT => OPEN, DOUT => rgmiio_tx_clk ); delay_rgmii_tx_en0 : IODELAY2 generic map( DELAY_SRC => "ODATAIN", IDELAY_TYPE => "FIXED", ODELAY_VALUE => 0 ) port map( IDATAIN => '0', T => '1', ODATAIN => rgmiio.tx_en, CAL => '0', IOCLK0 => '0', IOCLK1 => '0', CLK => '0', INC => '0', CE => '0', RST => '0', BUSY => OPEN, DATAOUT => OPEN, DATAOUT2 => OPEN, TOUT => OPEN, DOUT => rgmiio_tx_en ); rgmii_txd : for i in 0 to 3 generate delay_rgmii_txd0 : IODELAY2 generic map( DELAY_SRC => "ODATAIN", IDELAY_TYPE => "FIXED", ODELAY_VALUE => 0 ) port map( IDATAIN => '0', T => '1', ODATAIN => rgmiio.txd(i), CAL => '0', IOCLK0 => '0', IOCLK1 => '0', CLK => '0', INC => '0', CE => '0', RST => '0', BUSY => OPEN, DATAOUT => OPEN, DATAOUT2 => OPEN, TOUT => OPEN, DOUT => rgmiio_txd(i) ); end generate; end generate; rgmii0 : rgmii generic map (15, 16#010# , 16#ff0#, fabtech, CFG_GRETH1G, 1, 0, 1) port map (rstn, rgmiii.gtx_clk, gmiii, gmiio, rgmiii, rgmiio, clkm, rstn, apbi, apbo(15)); ethpads : if (CFG_GRETH = 1) generate -- eth pads etxc_pad : outpad generic map (tech => padtech) port map (etx_clk, rgmiio_tx_clk); erxc_pad : clkpad generic map (tech => padtech, arch => 2) port map (erx_clk, rgmiii.rx_clk); erxd_pad : inpadv generic map (tech => padtech, width => 4) port map (erxd, rgmiii_buf.rxd(3 downto 0)); erxdv_pad : inpad generic map (tech => padtech) port map (erx_dv, rgmiii_buf.rx_dv); etxd_pad : outpadv generic map (tech => padtech, width => 4) port map (etxd, rgmiio_txd(3 downto 0)); etxen_pad : outpad generic map (tech => padtech) port map ( etx_en, rgmiio_tx_en); emdio_pad : iopad generic map (tech => padtech) port map (emdio, rgmiio.mdio_o, rgmiio.mdio_oe, rgmiii.mdio_i); emdc_pad : outpad generic map (tech => padtech) port map (emdc, rgmiio.mdc); emdint_pad : inpad generic map (tech => padtech) port map (emdint, rgmiii.mdint); -- Incoming 125Mhz ref clock clk125_pad : clkpad generic map (tech => padtech, arch => 2) port map (clk125, rgmiii.gtx_clk); end generate; ----------------------------------------------------------------------- --- AHB RAM ---------------------------------------------------------- ----------------------------------------------------------------------- ocram : if CFG_AHBRAMEN = 1 generate ahbram0 : ahbram generic map (hindex => 7, haddr => CFG_AHBRADDR, tech => CFG_MEMTECH, kbytes => CFG_AHBRSZ, pipe => CFG_AHBRPIPE) port map ( rstn, clkm, ahbsi, ahbso(7)); end generate; ----------------------------------------------------------------------- --- Multi-core CAN --------------------------------------------------- ----------------------------------------------------------------------- can0 : if CFG_CAN = 1 generate can0 : can_mc generic map (slvndx => 4, ioaddr => CFG_CANIO, iomask => 16#FF0#, irq => CFG_CANIRQ, memtech => memtech, ncores => CFG_CAN_NUM, sepirq => CFG_CANSEPIRQ) port map (rstn, clkm, ahbsi, ahbso(4), can_lrx, can_ltx ); can_tx_pad1 : iopad generic map (tech => padtech) port map (pio(5), can_ltx(0), gnd, gpioi.din(5)); can_rx_pad1 : iopad generic map (tech => padtech) port map (pio(4), gnd, vcc, can_lrx(0)); canpas : if CFG_CAN_NUM = 2 generate can_tx_pad2 : iopad generic map (tech => padtech) port map (pio(2), can_ltx(1), gnd, gpioi.din(2)); can_rx_pad2 : iopad generic map (tech => padtech) port map (pio(1), gnd, vcc, can_lrx(1)); end generate; end generate; -- standby controlled by pio(3) and pio(0) ----------------------------------------------------------------------- --- SPACEWIRE ------------------------------------------------------- ----------------------------------------------------------------------- -- temporary, just to make sure the SPW pins are instantiated correctly no_spw : if CFG_SPW_EN = 0 generate pad_gen: for i in 0 to CFG_SPW_NUM-1 generate spw_rxd_pad : inpad_ds generic map (padtech, lvds, x33v) port map (spw_rxdp(i), spw_rxdn(i), dtmp(i)); spw_rxs_pad : inpad_ds generic map (padtech, lvds, x33v) port map (spw_rxsp(i), spw_rxsn(i), stmp(i)); spw_txd_pad : outpad_ds generic map (padtech, lvds, x33v) port map (spw_txdp(i), spw_txdn(i), dtmp(i), gnd); spw_txs_pad : outpad_ds generic map (padtech, lvds, x33v) port map (spw_txsp(i), spw_txsn(i), stmp(i), gnd); end generate; end generate; spw : if CFG_SPW_EN > 0 generate core0: if CFG_SPW_GRSPW = 1 generate spw_rxtxclk <= clkm; spw_rstn <= rstn; end generate; core1 : if CFG_SPW_GRSPW = 2 generate spw_rxtxclk <= clk100; spw_rstn_sync_proc : process(rstn,spw_rxtxclk) begin if rstn = '0' then spw_rstn_sync <= '0'; spw_rstn <= '0'; elsif rising_edge(spw_rxtxclk) then spw_rstn_sync <= '1'; spw_rstn <= spw_rstn_sync; end if; end process spw_rstn_sync_proc; end generate; spw_rxclkn <= not spw_rxtxclk; swloop : for i in 0 to CFG_SPW_NUM-1 generate -- GRSPW2 PHY spw2_input : if CFG_SPW_GRSPW = 2 generate spw_inputloop: for j in 0 to CFG_SPW_PORTS-1 generate spw_phy0 : grspw2_phy generic map( scantest => 0, tech => fabtech, input_type => CFG_SPW_INPUT) port map( rstn => spw_rstn, rxclki => spw_rxtxclk, rxclkin => spw_rxclkn, nrxclki => spw_rxtxclk, di => dtmp(i*CFG_SPW_PORTS+j), si => stmp(i*CFG_SPW_PORTS+j), do => spwi(i).d(j*2+1 downto j*2), dov => spwi(i).dv(j*2+1 downto j*2), dconnect => spwi(i).dconnect(j*2+1 downto j*2), rxclko => spw_rxclk(i*CFG_SPW_PORTS+j)); end generate; oneport : if CFG_SPW_PORTS = 1 generate spwi(i).d(3 downto 2) <= "00"; -- For second port spwi(i).dv(3 downto 2) <= "00"; -- For second port spwi(i).dconnect(3 downto 2) <= "00"; -- For second port end generate; spwi(i).nd <= (others => '0'); -- Only used in GRSPW end generate; spw1_input: if CFG_SPW_GRSPW = 1 generate spw_inputloop: for j in 0 to CFG_SPW_PORTS-1 generate spw_phy0 : grspw_phy generic map( tech => fabtech, rxclkbuftype => 2, scantest => 0) port map( rxrst => spwo(i).rxrst, di => dtmp(i*CFG_SPW_PORTS+j), si => stmp(i*CFG_SPW_PORTS+j), rxclko => spw_rxclk(i*CFG_SPW_PORTS+j), do => spwi(i).d(j), ndo => spwi(i).nd(j*5+4 downto j*5), dconnect => spwi(i).dconnect(j*2+1 downto j*2)); end generate spw_inputloop; oneport : if CFG_SPW_PORTS = 1 generate spwi(i).d(1) <= '0'; -- For second port spwi(i).d(3 downto 2) <= "00"; -- For GRSPW2 second port spwi(i).nd(9 downto 5) <= "00000"; -- For second port spwi(i).dconnect(3 downto 2) <= "00"; -- For second port end generate; spwi(i).dv <= (others => '0'); -- Only used in GRSPW2 end generate spw1_input; sw0 : grspwm generic map(tech => memtech, hindex => CFG_NCPU+CFG_AHB_UART+CFG_GRETH+CFG_AHB_JTAG+i, sysfreq => CPU_FREQ, usegen => 1, pindex => 10+i, paddr => 10+i, pirq => 10+i, nsync => 1, rmap => CFG_SPW_RMAP, rxunaligned => CFG_SPW_RXUNAL, rmapcrc => CFG_SPW_RMAPCRC, fifosize1 => CFG_SPW_AHBFIFO, fifosize2 => CFG_SPW_RXFIFO, rxclkbuftype => 2, dmachan => CFG_SPW_DMACHAN, rmapbufs => CFG_SPW_RMAPBUF, ft => CFG_SPW_FT, ports => CFG_SPW_PORTS, spwcore => CFG_SPW_GRSPW, netlist => CFG_SPW_NETLIST, rxtx_sameclk => CFG_SPW_RTSAME, input_type => CFG_SPW_INPUT, output_type => CFG_SPW_OUTPUT) port map(rstn, clkm, spw_rxclk(i*CFG_SPW_PORTS), spw_rxclk(i*CFG_SPW_PORTS+1), spw_rxtxclk, spw_rxtxclk, ahbmi, ahbmo(CFG_NCPU+CFG_AHB_UART+CFG_GRETH+CFG_AHB_JTAG+i), apbi2, apbo2(10+i), spwi(i), spwo(i)); spwi(i).tickin <= '0'; spwi(i).rmapen <= '1'; spwi(i).clkdiv10 <= conv_std_logic_vector(CPU_FREQ/10000-1, 8) when CFG_SPW_GRSPW = 1 else conv_std_logic_vector(10-1, 8); spwi(i).tickinraw <= '0'; spwi(i).timein <= (others => '0'); spwi(i).dcrstval <= (others => '0'); spwi(i).timerrstval <= (others => '0'); swportloop1: for j in 0 to CFG_SPW_PORTS-1 generate spwlb0 : if SPW_LOOP_BACK = 1 generate dtmp(i*CFG_SPW_PORTS+j) <= spwo(i).d(j); stmp(i*CFG_SPW_PORTS+j) <= spwo(i).s(j); end generate; nospwlb0 : if SPW_LOOP_BACK = 0 generate spw_rxd_pad : inpad_ds generic map (padtech, lvds, x33v, 1) port map (spw_rxdp(i*CFG_SPW_PORTS+j), spw_rxdn(i*CFG_SPW_PORTS+j), dtmp(i*CFG_SPW_PORTS+j)); spw_rxs_pad : inpad_ds generic map (padtech, lvds, x33v, 1) port map (spw_rxsp(i*CFG_SPW_PORTS+j), spw_rxsn(i*CFG_SPW_PORTS+j), stmp(i*CFG_SPW_PORTS+j)); spw_txd_pad : outpad_ds generic map (padtech, lvds, x33v) port map (spw_txdp(i*CFG_SPW_PORTS+j), spw_txdn(i*CFG_SPW_PORTS+j), spwo(i).d(j), gnd); spw_txs_pad : outpad_ds generic map (padtech, lvds, x33v) port map (spw_txsp(i*CFG_SPW_PORTS+j), spw_txsn(i*CFG_SPW_PORTS+j), spwo(i).s(j), gnd); end generate; end generate; end generate; end generate; ----------------------------------------------------------------------- --- Drive unused bus elements --------------------------------------- ----------------------------------------------------------------------- -- nam1 : for i in (CFG_NCPU+CFG_AHB_UART+CFG_GRETH+CFG_AHB_JTAG) to NAHBMST-1 generate -- ahbmo(i) <= ahbm_none; -- end generate; -- nap0 : for i in 11 to NAPBSLV-1 generate apbo(i) <= apb_none; end generate; -- nah0 : for i in 8 to NAHBSLV-1 generate ahbso(i) <= ahbs_none; end generate; ----------------------------------------------------------------------- --- Boot message ---------------------------------------------------- ----------------------------------------------------------------------- -- pragma translate_off x : report_design generic map ( msg1 => "LEON3 GR-XC6S-LX75 Demonstration design", fabtech => tech_table(fabtech), memtech => tech_table(memtech), mdel => 1 ); -- pragma translate_on end;

gpl-2.0

42623f44201ae3d4dee6d39fef66336d

0.553221

3.425456

false

capitanov/Stupid_watch

src/top/top_xc3s500e_ex.vhd

1

14,017

-------------------------------------------------------------------------------- -- -- Title : top_xc3s500e_ex.vhd -- Design : Example -- Author : Kapitanov -- Company : InSys -- -- Version : 1.0 -------------------------------------------------------------------------------- -- -- Description : Top level for timer based on Spartan3E Starter Kit -- -- Xilinx Spartan3e - XC3S500E-4FG320C -- Switches, LEDs, TIMER (ds1302), display (lcd1602) -- -- SW<0> - RESET -- SW<1> - ENABLE -- SW<2> - PWM -- SW<3> - START -- -- -------------------------------------------------------------------------------- library IEEE; --! main standard libs use IEEE.STD_LOGIC_1164.all; use IEEE.STD_LOGIC_UNSIGNED.all; library UNISIM; --! xilinx unusim libs use UNISIM.VCOMPONENTS.ALL; library WORK; --! user work libs use WORK.ctrl_types_pkg.all; entity top_xc3s500e_ex is generic ( TD : in time := 1 ns ; --! simulation time; DIV_SCL : in integer := 100 --! clock division for logic counters ); port( ---- SWITCHES ---- RESET : in std_logic; --! asycnchronous reset: SW(0) PWM : in std_logic; --! PWM Enable : SW(1) LCD : in std_logic; --! LCD/LED Switch : SW(2) START : in std_logic; --! LCD Controller Start : SW(3) RESTART : in std_logic; --! RESTART Timer DS1302 TEST_LCD : in std_logic; --! TEST LCD DISPLAY ---- PS/2 IO ---- PS2_CLK : in std_logic; --! PS/2 clk (keyboard) PS2_DATA : in std_logic; --! PS/2 data (keyboad) ---- CLOCK 50 MHz ---- CLK : in std_logic; --! main clock 50 MHz ---- VGA SYNC ---- VGA_HSYNC : out std_logic; --! horiztonal sync VGA_VSYNC : out std_logic; --! vertical sync VGA_R : out std_logic; --! VGA Red VGA_G : out std_logic; --! VGA Green VGA_B : out std_logic; --! VGA Blue ---- LED DISPLAY ---- LED_X : out std_logic_vector(7 downto 3); --! LEDs Y --LED_Y : out std_logic_vector(7 downto 0); --! LEDs X ---- BUTTONS ---- KB : in std_logic_vector(5 downto 1); --! Five Buttons ---- SERIAL TIMER ---- T_DT : inout std_logic; --! timer serial data T_CK : out std_logic; --! timer serial clock (~1 MHz) T_CE : out std_logic; --! timer serial enable -- LCD1602 INTERFACE LCD_DT : out std_logic_vector(7 downto 0); --! LCD Data LCD_EN : out std_logic; --! LCD Enable LCD_RW : out std_logic; --! LCD R/W (write - '0', read - '1') LCD_RS : out std_logic; --! LCD RS (command - '0', data - '1') -- TEST POINTS TST : out std_logic_vector(2 downto 0); --! Test points ---- DOORBELL ---- BELL : out std_logic --! BELL (tie to VCC) ); end top_xc3s500e_ex; architecture top_xc3s500e_ex of top_xc3s500e_ex is ---------------- SIGNALS DECLARATION ---------------- signal ps2_clock : std_logic; signal ps2_din : std_logic; signal sys_reset : std_logic; signal reset_v : std_logic_vector(6 downto 0); signal rst : std_logic; signal rstz : std_logic; signal RGB : std_logic_vector(2 downto 0); signal clk_fb : std_logic; signal clk0 : std_logic; signal clk_in : std_logic; signal locked : std_logic; signal clk_dv : std_logic; signal rst_dcm : std_logic; signal v, h : std_logic; --signal leds : std_logic_vector(8 downto 1); signal led_hearty : std_logic_vector(7 downto 0); signal led_heartx : std_logic_vector(7 downto 0); signal pwm_ena : std_logic; signal button : std_logic_vector(5 downto 1); signal switch_lcd : std_logic; signal time_addr : std_logic_vector(7 downto 0); signal time_data_i : std_logic_vector(7 downto 0); signal time_data_o : std_logic_vector(7 downto 0); signal time_data_v : std_logic; signal time_rdy : std_logic; signal time_enable : std_logic; signal disp_dt : std_logic_vector(7 downto 0); signal disp_en : std_logic; signal disp_rw : std_logic; signal disp_rs : std_logic; signal disp_start : std_logic; signal disp_rdy : std_logic; signal disp_init : std_logic; signal disp_data : std_logic_vector(7 downto 0); signal disp_com : std_logic:='0'; signal disp_ena : std_logic; signal buff_dt : std_logic_vector(7 downto 0); signal buff_en : std_logic; signal buff_rw : std_logic; signal buff_rs : std_logic; signal buff_xx : std_logic_vector(7 downto 3); --signal cnt : std_logic_vector(5 downto 0):="000000"; signal rstart : std_logic; signal disp_rdyz : std_logic; signal disp_rdyt : std_logic; signal ds_data_i : std_logic; signal ds_data_o : std_logic; signal ds_data_t : std_logic; signal ds_data_tn : std_logic; signal load_ena : std_logic; signal load_dat : std_logic_vector(7 downto 0); signal load_addr : std_logic_vector(4 downto 0); signal test_mode : std_logic; begin disp_rdyz <= not disp_rdy after td when rising_edge(clk_in); disp_rdyt <= disp_rdyz and disp_rdy after td when rising_edge(clk_in); ---------------- TIMER TRANSFER ---------------- x_SET_TIME: cl_timer_data generic map ( TIME_SECS => 47, -- seconds TIME_MINS => 59, -- minutes TIME_HRS => 13, -- hours TIME_DTS => 19, -- dates TIME_MTHS => 09, -- months TIME_DAYS => 06, -- days TIME_YRS => 15, -- years TD => TD -- simulation time; ) port map( ---- Global signals ---- reset => reset_v(0), -- asycnchronous reset clk => clk_in, -- clock 50 MHz restart => rstart, -- restart timer ---- DS1302 signals ---- addr => time_addr, -- address for timer data_o => time_data_i, -- input data (to timer) data_i => time_data_o, -- output data (from timer) data_v => time_data_v, -- valid data (from timer) ready => time_rdy, -- timer is ready for data enable => time_enable, -- timer enable ---- LCD1602 signals ---- load_ena => load_ena, -- enable writing to LCD RAM load_dat => load_dat, -- data to LCD RAM load_addr => load_addr -- address to LCD RAM ); ---------------- LCD1602 TRANSFER ---------------- x_LCD_TST: cl_lcd_data generic map ( TD => TD -- simulation time; ) port map( reset => reset_v(1), -- system frequency (50 MHz) clk => clk_in, -- '0' - negative reset test_mode => test_mode, -- select mode: test message or timer load_ena => load_ena, -- load new data load_dat => load_dat, -- new data; load_addr => load_addr, -- new address; disp_data => disp_data, -- data to display disp_ena => disp_ena, -- enable for data disp_init => disp_init, -- ready for data disp_rdyt => disp_rdyt -- valid pulse for data ); ---------------- LCD1602 CONTROLLER ---------------- x_LCD1602: rtl_lcd1602 generic map ( TD => TD, -- simulation time; DIV_SCL => 5000 -- clock division for SCL: clk50m/DIV_SCL ) port map( -- global ports clk50m => clk_in, -- system frequency (50 MHz) rstn => reset_v(2), -- '0' - negative reset -- main interface start => disp_start, -- start data_ena => disp_ena, -- data enable (S) data_int => disp_data, -- data Tx data_sel => disp_com, -- select: '0' - data, '1' - command data_rw => '0', -- WRITE ONLY; lcd_ready => disp_rdy, -- ready for data lcd_init => disp_init, -- lcd initialization complete -- lcd1602 interface lcd_dt => disp_dt, -- lcd data lcd_en => disp_en, -- lcd clock enable lcd_rw => disp_rw, -- lcd r/w: write - '0', read - '1' lcd_rs => disp_rs -- lcd set: command - '0', data - '1' ); ---------------- DS1302 CONTROLLER ---------------- x_DS1302: rtl_ds1302 generic map ( TD => TD, -- simulation time; DIV_SCL => DIV_SCL -- clock division for SCL: clk50m/DIV_SCL ) port map( -- global ports clk50m => clk_in, -- system frequency (50 MHz) rstn => reset_v(3), -- '0' - negative reset -- main interface enable => time_enable, -- i2c start (S) addr_i => time_addr, -- address Tx: 7 bit - always '1', 0 bit - R/W ('0' - write, '1' - read) data_i => time_data_i, -- data Tx data_o => time_data_o, -- data Rx data_v => time_data_v, -- valid Rx ready => time_rdy, -- ready -- serial interface --ds_data => T_DT,--ds_data, -- serial data ds_data_i => ds_data_i, -- serial data input ds_data_o => ds_data_o, -- serial data output ds_data_t => ds_data_t, -- serial data enable ds_clk => T_CK, -- serial clock ds_ena => T_CE -- clock enable for i2c ); ---------------- MINESWEEPER GAME ---------------- x_MAIN_BLOCK : rtl_game_int port map( clk => clk_dv, -- 25 MHz freq; reset => reset_v(4), -- GLOBAL RESET ps2_clk => ps2_clock, -- PS/2 CLOCK ps2_data => ps2_din, -- PS/2 SERIAL DATA h_vga => H, -- HORIZONTAL v_vga => V, -- VERTICAL rgb => RGB -- (R-G-B) --leds => LEDS -- LEDs ); ---------------- HEART XY 8X8 ---------------- pr_lcd_sw: process(clk_in, reset_v(5)) is begin if (reset_v(5) = '0') then buff_dt <= x"00"; buff_en <= '0'; buff_rw <= '0'; buff_rs <= '0'; elsif rising_edge(clk_in) then if switch_lcd = '1' then buff_dt <= disp_dt; buff_en <= disp_en; buff_rw <= disp_rw; buff_rs <= disp_rs; else x_rev: for ii in 0 to 7 loop buff_dt(ii) <= led_hearty(7-ii); end loop; buff_rs <= led_heartx(0); buff_rw <= led_heartx(1); buff_en <= led_heartx(2); buff_xx <= led_heartx(7 downto 3); end if; end if; end process; ds_data_tn <= ds_data_t; ---------------- I/O BUFFERS ---------------- TST(0) <= ds_data_o; TST(1) <= ds_data_tn; TST(2) <= ds_data_i; xDSIO: iobuf port map(i => ds_data_o, o => ds_data_i, io => T_DT, t => ds_data_tn); xPS2C: ibuf port map(i => ps2_clk, o => ps2_clock); xPS2D: ibuf port map(i => ps2_data, o => ps2_din); xRESET: ibuf port map(i => RESET, o => rst); xPWM: ibuf port map(i => PWM, o => pwm_ena); xSTART: ibuf port map(i => START, o => disp_start); xRESTART: ibuf port map(i => RESTART, o => rstart); xBELL: obuf port map(i => '1', o => BELL); xVGA_v: obuf port map(i => v, o => VGA_VSYNC); xVGA_h: obuf port map(i => h, o => VGA_HSYNC); xVGA_R: obuf port map(i => RGB(2), o => VGA_R); xVGA_G: obuf port map(i => RGB(1), o => VGA_G); xVGA_B: obuf port map(i => RGB(0), o => VGA_B); xLCD_EN: obuf port map(i => buff_en, o => LCD_EN); xLCD_RW: obuf port map(i => buff_rw, o => LCD_RW); xLCD_RS: obuf port map(i => buff_rs, o => LCD_RS); xLCD_DT: for ii in 0 to 7 generate xLCD_DATA: obuf port map(i => buff_dt(ii), o => LCD_DT(ii)); end generate; xLCD_SW: ibuf port map(i => LCD, o => switch_lcd); xLCD_TST: ibuf port map(i => TEST_LCD, o => test_mode); xBUTS: for ii in 1 to 5 generate xswitch: ibuf port map(i => KB(ii), o => button(ii)); end generate; -- LEDS: xLED_XY: for ii in 3 to 7 generate ledx: obuf port map(i => buff_xx(ii), o => LED_X(ii)); -- ledy: obuf port map(i => led_hearty(ii), o => LED_Y(ii)); end generate; ---------------- DEBOUNCE ---------------- xCTRL_8x8 : ctrl_leds port map ( -- System signals: clk => clk0, clk_dv => clk_dv, reset => reset_v(6), pwm_ena => pwm_ena, -- Buttons: cbut => button, -- Leds vectors: led_x => led_heartx, led_y => led_hearty ); ---------------- DCM CLOCK ---------------- xCLKFB: bufg port map(i => clk0, o => clk_fb); xCLKIN: ibufg port map(i => clk,o => clk_in); sys_reset <= (rstz and locked) after td when rising_edge(clk_in); xFD_RST: ctrl_fanout generic map( FD_WIDTH => 7) port map( clk => clk_in, data_in => sys_reset, data_out => reset_v ); --xgen_rst: for ii in 0 to 7 generate --reset_v(ii) <= sys_reset after td when rising_edge(clk_in); --end generate; xSRL_RESET: srlc16 generic map ( init => x"0000" ) port map( Q15 => rstz, A0 => '1', A1 => '1', A2 => '1', A3 => '1', CLK => clk_in, D => rst -- '1', ); rst_dcm <= not rst; ---------------- CLOCK GENERATOR - DCM ---------------- xDCM_CLK_VGA : dcm generic map( --DCM_AUTOCALIBRATION => FALSE, -- DCM ADV CLKDV_DIVIDE => 2.0, -- clk divide for CLKIN: Fdv = Fclkin / CLK_DIV CLKFX_DIVIDE => 2, -- clk divide for CLKFX and CLKFX180 : Ffx = (Fclkin * MULTIPLY) / CLKFX_DIV CLKFX_MULTIPLY => 2, -- clk multiply for CLKFX and CLKFX180 : Ffx = (Fclkin * MULTIPLY) / CLKFX_DIV CLKIN_DIVIDE_BY_2 => FALSE, -- divide clk / 2 before DCM block CLKIN_PERIOD => 20.0, -- clk period in ns (for DRC) CLKOUT_PHASE_SHIFT => "NONE", -- phase shift mode: NONE, FIXED, VARIABLE CLK_FEEDBACK => "1X", -- freq on the feedback clock: 1x, 2x, None DESKEW_ADJUST => "SYSTEM_SYNCHRONOUS", -- clk delay alignment DFS_FREQUENCY_MODE => "LOW", -- freq mode CLKFX and CLKFX180: LOW, HIGH DLL_FREQUENCY_MODE => "LOW", -- freq mode CLKIN: LOW, HIGH DUTY_CYCLE_CORRECTION => TRUE, -- 50% duty-cycle correction for the CLK0, CLK90, CLK180 and CLK270: TRUE, FALSE PHASE_SHIFT => 0 -- phase shift (with CLKOUT_PHASE_SHIFT): -255 to 255 ) port map( clk0 => clk0, -- clk180 => clk180, -- clk270 => clk270, -- clk2x => clk2x, -- clk2x180 => clk2x180, -- clk90 => clk90, clkdv => clk_dv, -- clkfx => clkfx, -- clkfx180 => clkfx180, locked => locked, -- status => status, -- psdone => psdone, clkfb => clk_fb, clkin => clk_in, -- dssen => dssen, -- psclk => psclk, psen => '0', psincdec => '0', rst => rst_dcm ); end top_xc3s500e_ex;

mit

b99a5ab849e596536e7280c5a4b1aef8

0.538346

2.693505

false

IamVNIE/Hardware-Security

RC5 CryptoCore/Rc5 Codes/RC5encryptAllSteps.vhd

2

6,997

Library IEEE; Use IEEE.std_logic_1164.all; Use IEEE.std_logic_unsigned.all; Use Work.RC5_Pkg.all; Entity rc5_enc Is Port ( clr : in std_logic; clk : in std_logic; din : in std_logic_vector(63 downto 0); di_vld : in std_logic; key_rdy : in std_logic; skey : in rom; dout : out std_logic_vector(63 downto 0); do_rdy : out std_logic ); End rc5_enc; Architecture rtl of rc5_enc is signal i_cnt : Std_logic_vector(3 downto 0); --Signals signal ab_xor : Std_logic_vector(31 downto 0); signal a_rot : Std_logic_vector(31 downto 0); signal a : Std_logic_vector(31 downto 0); signal a_pre : Std_logic_vector(31 downto 0); signal a_reg : Std_logic_vector(31 downto 0); signal ba_xor : Std_logic_vector(31 downto 0); signal b_rot : Std_logic_vector(31 downto 0); signal b : Std_logic_vector(31 downto 0); signal b_pre : Std_logic_vector(31 downto 0); signal b_reg : Std_logic_vector(31 downto 0); --RC5 State Machine Type StateType is --Type for state machine ( ST_idle, ST_pre_round, ST_round_op, ST_ready ); Signal state_en : StateType; --Signal type of state machine Begin ab_xor <= a_reg XOR b_reg; --A_reg _reg XOR With b_reg(4 downto 0) Select --Rotate left XOR result a_rot <= ab_xor(30 downto 0) & ab_xor(31) when "00001", ab_xor(29 downto 0) & ab_xor(31 downto 30) when "00010", ab_xor(28 downto 0) & ab_xor(31 downto 29) when "00011", ab_xor(27 downto 0) & ab_xor(31 downto 28) when "00100", ab_xor(26 downto 0) & ab_xor(31 downto 27) when "00101", ab_xor(25 downto 0) & ab_xor(31 downto 26) when "00110", ab_xor(24 downto 0) & ab_xor(31 downto 25) when "00111", ab_xor(23 downto 0) & ab_xor(31 downto 24) when "01000", ab_xor(22 downto 0) & ab_xor(31 downto 23) when "01001", ab_xor(21 downto 0) & ab_xor(31 downto 22) when "01010", ab_xor(20 downto 0) & ab_xor(31 downto 21) when "01011", ab_xor(19 downto 0) & ab_xor(31 downto 20) when "01100", ab_xor(18 downto 0) & ab_xor(31 downto 19) when "01101", ab_xor(17 downto 0) & ab_xor(31 downto 18) when "01110", ab_xor(16 downto 0) & ab_xor(31 downto 17) when "01111", ab_xor(15 downto 0) & ab_xor(31 downto 16) when "10000", ab_xor(14 downto 0) & ab_xor(31 downto 15) when "10001", ab_xor(13 downto 0) & ab_xor(31 downto 14) when "10010", ab_xor(12 downto 0) & ab_xor(31 downto 13) when "10011", ab_xor(11 downto 0) & ab_xor(31 downto 12) when "10100", ab_xor(10 downto 0) & ab_xor(31 downto 11) when "10101", ab_xor(9 downto 0) & ab_xor(31 downto 10) when "10110", ab_xor(8 downto 0) & ab_xor(31 downto 9) when "10111", ab_xor(7 downto 0) & ab_xor(31 downto 8) when "11000", ab_xor(6 downto 0) & ab_xor(31 downto 7) when "11001", ab_xor(5 downto 0) & ab_xor(31 downto 6) when "11010", ab_xor(4 downto 0) & ab_xor(31 downto 5) when "11011", ab_xor(3 downto 0) & ab_xor(31 downto 4) when "11100", ab_xor(2 downto 0) & ab_xor(31 downto 3) when "11101", ab_xor(1 downto 0) & ab_xor(31 downto 2) when "11110", ab_xor(0) & ab_xor(31 downto 1) when "11111", ab_xor when others; a_pre <= din(63 downto 32) + skey(0); --A_pre output after add din and skey a <= a_rot + skey(CONV_INTEGER(i_cnt & '0')); --A output after add left rotate and skey ba_xor <= b_reg XOR a; --B_reg XOR with A with a(4 downto 0) Select --Rotate left result of XOR b_rot <= ba_xor(30 downto 0) & ba_xor(31) when "00001", ba_xor(29 downto 0) & ba_xor(31 downto 30) when "00010", ba_xor(28 downto 0) & ba_xor(31 downto 29) when "00011", ba_xor(27 downto 0) & ba_xor(31 downto 28) when "00100", ba_xor(26 downto 0) & ba_xor(31 downto 27) when "00101", ba_xor(25 downto 0) & ba_xor(31 downto 26) when "00110", ba_xor(24 downto 0) & ba_xor(31 downto 25) when "00111", ba_xor(23 downto 0) & ba_xor(31 downto 24) when "01000", ba_xor(22 downto 0) & ba_xor(31 downto 23) when "01001", ba_xor(21 downto 0) & ba_xor(31 downto 22) when "01010", ba_xor(20 downto 0) & ba_xor(31 downto 21) when "01011", ba_xor(19 downto 0) & ba_xor(31 downto 20) when "01100", ba_xor(18 downto 0) & ba_xor(31 downto 19) when "01101", ba_xor(17 downto 0) & ba_xor(31 downto 18) when "01110", ba_xor(16 downto 0) & ba_xor(31 downto 17) when "01111", ba_xor(15 downto 0) & ba_xor(31 downto 16) when "10000", ba_xor(14 downto 0) & ba_xor(31 downto 15) when "10001", ba_xor(13 downto 0) & ba_xor(31 downto 14) when "10010", ba_xor(12 downto 0) & ba_xor(31 downto 13) when "10011", ba_xor(11 downto 0) & ba_xor(31 downto 12) when "10100", ba_xor(10 downto 0) & ba_xor(31 downto 11) when "10101", ba_xor(9 downto 0) & ba_xor(31 downto 10) when "10110", ba_xor(8 downto 0) & ba_xor(31 downto 9) when "10111", ba_xor(7 downto 0) & ba_xor(31 downto 8) when "11000", ba_xor(6 downto 0) & ba_xor(31 downto 7) when "11001", ba_xor(5 downto 0) & ba_xor(31 downto 6) when "11010", ba_xor(4 downto 0) & ba_xor(31 downto 5) when "11011", ba_xor(3 downto 0) & ba_xor(31 downto 4) when "11100", ba_xor(2 downto 0) & ba_xor(31 downto 3) when "11101", ba_xor(1 downto 0) & ba_xor(31 downto 2) when "11110", ba_xor(0) & ba_xor(31 downto 1) when "11111", ba_xor when others; b_pre <= din(31 downto 0) + skey(1); --B output when add din and skey 1 b <= b_rot + skey(CONV_INTEGER(i_cnt & '1')); --B output when add left rotate and skey --Register A --Register A Process(clr, clk) Begin If(clr='0') Then a_reg <= (Others => '0'); elsif(clk'Event and clk='1') Then If (state_en=ST_pre_round) Then a_reg <= a_pre; Elsif (state_en=ST_round_op) Then a_reg <= a; End if; End If; End Process; --Register B --Register B Process(clr, clk) Begin If(clr='0') Then b_reg <= (Others => '0'); Elsif(clk'Event and clk='1') Then If (state_en=ST_pre_round) Then b_reg <= b_pre; Elsif (state_en=ST_round_op) Then b_reg <= b; End if; End If; End Process; Process (clr, clk) --State Machine Begin If (clr='0') Then state_en <= ST_idle; Elsif (clk'Event And clk = '1') Then Case state_en is When ST_idle => If (di_vld='1' and key_rdy='1') Then state_en <= ST_pre_round; End If; When ST_pre_round => state_en <= ST_round_op; When ST_round_op => If (i_cnt="1100") Then state_en <= ST_ready; End If; When ST_ready => state_en <= ST_idle; End Case; End If; End Process; Process(clr, clk) Begin --Round Counter If(clr='0') Then i_cnt <= "0001"; Elsif(clk'Event And clk='1') Then If (state_en = ST_round_op) Then If(i_cnt="1100") Then i_cnt <= "0001"; Else i_cnt <= i_cnt + '1'; End If; End If; End If; End Process; dout <= a_reg & b_reg; With state_en Select do_rdy <= '1' When ST_ready, '0' When Others; End rtl;

mit

cfba38df647b19f195c6d5db4b11a2ce

0.605688

2.629463

false

Luisda199824/ProcesadorMonociclo

TB_DataMemory.vhd

1

1,459

library IEEE; use IEEE.STD_LOGIC_1164.ALL; use IEEE.STD_LOGIC_ARITH.ALL; use IEEE.STD_LOGIC_UNSIGNED.ALL; ENTITY TB_DataMemory IS END TB_DataMemory; ARCHITECTURE behavior OF TB_DataMemory IS COMPONENT DataMemory PORT( Rst : IN std_logic; cRD : IN std_logic_vector(31 downto 0); AluResult : IN std_logic_vector(31 downto 0); WrENMem : IN std_logic; RdENMem : IN std_logic; Data : OUT std_logic_vector(31 downto 0) ); END COMPONENT; --Inputs signal Rst : std_logic := '0'; signal cRD : std_logic_vector(31 downto 0) := (others => '0'); signal AluResult : std_logic_vector(31 downto 0) := (others => '0'); signal WrENMem : std_logic := '0'; signal RdENMem : std_logic := '0'; --Outputs signal Data : std_logic_vector(31 downto 0); BEGIN -- Instantiate the Unit Under Test (UUT) uut: DataMemory PORT MAP ( Rst => Rst, cRD => cRD, AluResult => AluResult, WrENMem => WrENMem, RdENMem => RdENMem, Data => Data ); -- Stimulus process stim_proc: process begin Rst <= '1'; cRD <= x"00000001"; AluResult <= x"00000001"; WrENMem <= '0'; RdENMem <= '0'; wait for 10 ns; Rst <= '0'; WrENMem <= '1'; RdENMem <= '1'; wait for 10 ns; WrENMem <= '0'; RdENMem <= '1'; wait for 10 ns; WrENMem <= '0'; RdENMem <= '0'; wait; end process; END;

mit

3c61aa91b42709073a05b2b8e3429871

0.566827

3.199561

false

marco-c/leon-nexys2

grlib-gpl-1.3.4-b4140/designs/leon3-asic/leon3mp.vhd

1

18,140

----------------------------------------------------------------------------- -- LEON3 Demonstration design -- Copyright (C) 2013 Aeroflex Gaisler AB ------------------------------------------------------------------------------ -- This file is a part of the GRLIB VHDL IP LIBRARY -- Copyright (C) 2003 - 2008, Gaisler Research -- Copyright (C) 2008 - 2013, Aeroflex Gaisler -- -- This program is free software; you can redistribute it and/or modify -- it under the terms of the GNU General Public License as published by -- the Free Software Foundation; either version 2 of the License, or -- (at your option) any later version. -- -- This program is distributed in the hope that it will be useful, -- but WITHOUT ANY WARRANTY; without even the implied warranty of -- MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the -- GNU General Public License for more details. -- -- You should have received a copy of the GNU General Public License -- along with this program; if not, write to the Free Software -- Foundation, Inc., 59 Temple Place, Suite 330, Boston, MA 02111-1307 USA ------------------------------------------------------------------------------ library ieee; use ieee.std_logic_1164.all; use work.config.all; library techmap; use techmap.gencomp.all; entity leon3mp is generic ( fabtech : integer := CFG_FABTECH; memtech : integer := CFG_MEMTECH; padtech : integer := CFG_PADTECH; clktech : integer := CFG_CLKTECH; disas : integer := CFG_DISAS; -- Enable disassembly to console dbguart : integer := CFG_DUART; -- Print UART on console pclow : integer := CFG_PCLOW; scantest : integer := CFG_SCAN ); port ( resetn : in std_ulogic; clksel : in std_logic_vector(1 downto 0); clk : in std_ulogic; lock : out std_ulogic; errorn : inout std_ulogic; wdogn : inout std_ulogic; address : out std_logic_vector(27 downto 0); data : inout std_logic_vector(31 downto 0); cb : inout std_logic_vector(7 downto 0); sdclk : out std_ulogic; sdcsn : out std_logic_vector (1 downto 0); -- sdram chip select sdwen : out std_ulogic; -- sdram write enable sdrasn : out std_ulogic; -- sdram ras sdcasn : out std_ulogic; -- sdram cas sddqm : out std_logic_vector (3 downto 0); -- sdram dqm dsutx : out std_ulogic; -- DSU tx data / scanout dsurx : in std_ulogic; -- DSU rx data / scanin dsuen : in std_ulogic; dsubre : in std_ulogic; -- DSU break / scanen dsuact : out std_ulogic; -- DSU active / NT txd1 : out std_ulogic; -- UART1 tx data rxd1 : in std_ulogic; -- UART1 rx data txd2 : out std_ulogic; -- UART2 tx data rxd2 : in std_ulogic; -- UART2 rx data ramsn : out std_logic_vector (4 downto 0); ramoen : out std_logic_vector (4 downto 0); rwen : out std_logic_vector (3 downto 0); oen : out std_ulogic; writen : out std_ulogic; read : out std_ulogic; iosn : out std_ulogic; romsn : out std_logic_vector (1 downto 0); brdyn : in std_ulogic; bexcn : in std_ulogic; gpio : inout std_logic_vector(CFG_GRGPIO_WIDTH-1 downto 0); -- I/O port i2c_scl : inout std_ulogic; i2c_sda : inout std_ulogic; spi_miso : in std_ulogic; spi_mosi : out std_ulogic; spi_sck : out std_ulogic; spi_slvsel : out std_logic_vector(CFG_SPICTRL_SLVS-1 downto 0); prom32 : in std_ulogic; spw_clksel : in std_logic_vector(1 downto 0); spw_clk : in std_ulogic; spw_rxd : in std_logic_vector(0 to CFG_SPW_NUM-1); spw_rxs : in std_logic_vector(0 to CFG_SPW_NUM-1); spw_txd : out std_logic_vector(0 to CFG_SPW_NUM-1); spw_txs : out std_logic_vector(0 to CFG_SPW_NUM-1); gtx_clk : in std_ulogic; erx_clk : in std_ulogic; erxd : in std_logic_vector(7 downto 0); erx_dv : in std_ulogic; etx_clk : in std_ulogic; etxd : out std_logic_vector(7 downto 0); etx_en : out std_ulogic; etx_er : out std_ulogic; erx_er : in std_ulogic; erx_col : in std_ulogic; erx_crs : in std_ulogic; emdint : in std_ulogic; emdio : inout std_logic; emdc : out std_ulogic; testen : in std_ulogic; trst : in std_ulogic; tck : in std_ulogic; tms : in std_ulogic; tdi : in std_ulogic; tdo : out std_ulogic ); end; architecture rtl of leon3mp is signal lresetn : std_ulogic; signal lclksel : std_logic_vector (1 downto 0); signal lclk : std_ulogic; signal llock : std_ulogic; signal lerrorn : std_ulogic; signal laddress : std_logic_vector(27 downto 0); signal ldatain : std_logic_vector(31 downto 0); signal ldataout : std_logic_vector(31 downto 0); signal ldataen : std_logic_vector(31 downto 0); signal lcbin : std_logic_vector(7 downto 0); signal lcbout : std_logic_vector(7 downto 0); signal lcben : std_logic_vector(7 downto 0); signal lsdclk : std_ulogic; signal lsdcsn : std_logic_vector (1 downto 0); signal lsdwen : std_ulogic; signal lsdrasn : std_ulogic; signal lsdcasn : std_ulogic; signal lsddqm : std_logic_vector (3 downto 0); signal ldsutx : std_ulogic; signal ldsurx : std_ulogic; signal ldsuen : std_ulogic; signal ldsubre : std_ulogic; signal ldsuact : std_ulogic; signal ltxd1 : std_ulogic; signal lrxd1 : std_ulogic; signal ltxd2 : std_ulogic; signal lrxd2 : std_ulogic; signal lramsn : std_logic_vector (4 downto 0); signal lramoen : std_logic_vector (4 downto 0); signal lrwen : std_logic_vector (3 downto 0); signal loen : std_ulogic; signal lwriten : std_ulogic; signal lread : std_ulogic; signal liosn : std_ulogic; signal lromsn : std_logic_vector (1 downto 0); signal lbrdyn : std_ulogic; signal lbexcn : std_ulogic; signal lwdogn : std_ulogic; signal lgpioin : std_logic_vector(CFG_GRGPIO_WIDTH-1 downto 0); signal lgpioout : std_logic_vector(CFG_GRGPIO_WIDTH-1 downto 0); signal lgpioen : std_logic_vector(CFG_GRGPIO_WIDTH-1 downto 0); signal li2c_sclout : std_ulogic; signal li2c_sclen : std_ulogic; signal li2c_sclin : std_ulogic; signal li2c_sdaout : std_ulogic; signal li2c_sdaen : std_ulogic; signal li2c_sdain : std_ulogic; signal lspi_miso : std_ulogic; signal lspi_mosi : std_ulogic; signal lspi_sck : std_ulogic; signal lspi_slvsel : std_logic_vector(CFG_SPICTRL_SLVS-1 downto 0); signal lprom32 : std_ulogic; signal lspw_clksel : std_logic_vector (1 downto 0); signal lspw_clk : std_ulogic; signal lspw_rxd : std_logic_vector(0 to CFG_SPW_NUM-1); signal lspw_rxs : std_logic_vector(0 to CFG_SPW_NUM-1); signal lspw_txd : std_logic_vector(0 to CFG_SPW_NUM-1); signal lspw_txs : std_logic_vector(0 to CFG_SPW_NUM-1); signal lgtx_clk : std_ulogic; signal lerx_clk : std_ulogic; signal lerxd : std_logic_vector(7 downto 0); signal lerx_dv : std_ulogic; signal letx_clk : std_ulogic; signal letxd : std_logic_vector(7 downto 0); signal letx_en : std_ulogic; signal letx_er : std_ulogic; signal lerx_er : std_ulogic; signal lerx_col : std_ulogic; signal lerx_crs : std_ulogic; signal lemdint : std_ulogic; signal lemdioin : std_logic; signal lemdioout : std_logic; signal lemdioen : std_logic; signal lemdc : std_ulogic; signal ltesten : std_ulogic; signal ltrst : std_ulogic; signal ltck : std_ulogic; signal ltms : std_ulogic; signal ltdi : std_ulogic; signal ltdo : std_ulogic; signal ltdoen : std_ulogic; -- Use for ASIC --constant padvoltage : integer := x33v; --constant padlevel : integer := ttl; -- Use for FPGA constant padvoltage : integer := x18v; constant padlevel : integer := cmos; begin -- TODO: Move PAD options to 'xconfig' pads0 : entity work.pads generic map ( padtech => CFG_PADTECH, padlevel => padlevel, padstrength => 4, jtag_padfilter => pullup, testen_padfilter => pulldown, resetn_padfilter => schmitt, clk_padfilter => 0, spw_padstrength => 12, jtag_padstrength => 4, uart_padstrength => 4, dsu_padstrength => 4, padvoltage => padvoltage, spw_input_type => CFG_SPW_INPUT, oepol => padoen_polarity(CFG_PADTECH) ) port map ( --------------------------- --to chip boundary --------------------------- resetn => resetn , clksel => clksel , clk => clk , lock => lock , errorn => errorn , address => address , data => data , cb => cb , sdclk => sdclk , sdcsn => sdcsn , sdwen => sdwen , sdrasn => sdrasn , sdcasn => sdcasn , sddqm => sddqm , dsutx => dsutx , dsurx => dsurx , dsuen => dsuen , dsubre => dsubre , dsuact => dsuact , txd1 => txd1 , rxd1 => rxd1 , txd2 => txd2 , rxd2 => rxd2 , ramsn => ramsn , ramoen => ramoen , rwen => rwen , oen => oen , writen => writen , read => read , iosn => iosn , romsn => romsn , brdyn => brdyn , bexcn => bexcn , wdogn => wdogn , gpio => gpio , i2c_scl => i2c_scl , i2c_sda => i2c_sda , spi_miso => spi_miso , spi_mosi => spi_mosi , spi_sck => spi_sck , spi_slvsel => spi_slvsel, prom32 => prom32 , spw_clksel => spw_clksel, spw_clk => spw_clk , spw_rxd => spw_rxd , spw_rxs => spw_rxs , spw_txd => spw_txd , spw_txs => spw_txs , gtx_clk => gtx_clk , erx_clk => erx_clk , erxd => erxd , erx_dv => erx_dv , etx_clk => etx_clk , etxd => etxd , etx_en => etx_en , etx_er => etx_er , erx_er => erx_er , erx_col => erx_col , erx_crs => erx_crs , emdint => emdint , emdio => emdio , emdc => emdc , testen => testen , trst => trst , tck => tck , tms => tms , tdi => tdi , tdo => tdo , ------------------------- --- --to core ---------------------------- lresetn => lresetn , lclksel => lclksel , lclk => lclk , llock => llock , lerrorn => lerrorn , laddress => laddress , ldatain => ldatain , ldataout => ldataout , ldataen => ldataen , lcbin => lcbin , lcbout => lcbout , lcben => lcben , lsdclk => lsdclk , lsdcsn => lsdcsn , lsdwen => lsdwen , lsdrasn => lsdrasn , lsdcasn => lsdcasn , lsddqm => lsddqm , ldsutx => ldsutx , ldsurx => ldsurx , ldsuen => ldsuen , ldsubre => ldsubre , ldsuact => ldsuact , ltxd1 => ltxd1 , lrxd1 => lrxd1 , ltxd2 => ltxd2 , lrxd2 => lrxd2 , lramsn => lramsn , lramoen => lramoen , lrwen => lrwen , loen => loen , lwriten => lwriten , lread => lread , liosn => liosn , lromsn => lromsn , lbrdyn => lbrdyn , lbexcn => lbexcn , lwdogn => lwdogn , lgpioin => lgpioin , lgpioout => lgpioout , lgpioen => lgpioen , li2c_sclout => li2c_sclout, li2c_sclen => li2c_sclen , li2c_sclin => li2c_sclin , li2c_sdaout => li2c_sdaout, li2c_sdaen => li2c_sdaen , li2c_sdain => li2c_sdain , lspi_miso => lspi_miso , lspi_mosi => lspi_mosi , lspi_sck => lspi_sck , lspi_slvsel => lspi_slvsel, lprom32 => lprom32 , lspw_clksel => lspw_clksel, lspw_clk => lspw_clk , lspw_rxd => lspw_rxd , lspw_rxs => lspw_rxs , lspw_txd => lspw_txd , lspw_txs => lspw_txs , lgtx_clk => lgtx_clk , lerx_clk => lerx_clk , lerxd => lerxd , lerx_dv => lerx_dv , letx_clk => letx_clk , letxd => letxd , letx_en => letx_en , letx_er => letx_er , lerx_er => lerx_er , lerx_col => lerx_col , lerx_crs => lerx_crs , lemdint => lemdint , lemdioin => lemdioin , lemdioout => lemdioout , lemdioen => lemdioen , lemdc => lemdc , ltesten => ltesten , ltrst => ltrst , ltck => ltck , ltms => ltms , ltdi => ltdi , ltdo => ltdo , ltdoen => ltdoen ); -- ASIC Core core0 : entity work.core generic map ( fabtech => CFG_FABTECH, memtech => CFG_MEMTECH, padtech => CFG_PADTECH, clktech => CFG_CLKTECH, disas => CFG_DISAS, dbguart => CFG_DUART, pclow => CFG_PCLOW, scantest => CFG_SCAN, bscanen => CFG_BOUNDSCAN_EN, oepol => padoen_polarity(CFG_PADTECH) ) port map ( ---------------------------- -- ASIC Ports/Pads ---------------------------- resetn => lresetn , clksel => lclksel , clk => lclk , lock => llock , errorn => lerrorn , address => laddress , datain => ldatain , dataout => ldataout , dataen => ldataen , cbin => lcbin , cbout => lcbout , cben => lcben , sdclk => lsdclk , sdcsn => lsdcsn , sdwen => lsdwen , sdrasn => lsdrasn , sdcasn => lsdcasn , sddqm => lsddqm , dsutx => ldsutx , dsurx => ldsurx , dsuen => ldsuen , dsubre => ldsubre , dsuact => ldsuact , txd1 => ltxd1 , rxd1 => lrxd1 , txd2 => ltxd2 , rxd2 => lrxd2 , ramsn => lramsn , ramoen => lramoen , rwen => lrwen , oen => loen , writen => lwriten , read => lread , iosn => liosn , romsn => lromsn , brdyn => lbrdyn , bexcn => lbexcn , wdogn => lwdogn , gpioin => lgpioin , gpioout => lgpioout , gpioen => lgpioen , i2c_sclout => li2c_sclout, i2c_sclen => li2c_sclen , i2c_sclin => li2c_sclin , i2c_sdaout => li2c_sdaout, i2c_sdaen => li2c_sdaen , i2c_sdain => li2c_sdain , spi_miso => lspi_miso , spi_mosi => lspi_mosi , spi_sck => lspi_sck , spi_slvsel => lspi_slvsel, prom32 => lprom32 , spw_clksel => lspw_clksel, spw_clk => lspw_clk , spw_rxd => lspw_rxd , spw_rxs => lspw_rxs , spw_txd => lspw_txd , spw_txs => lspw_txs , gtx_clk => lgtx_clk , erx_clk => lerx_clk , erxd => lerxd , erx_dv => lerx_dv , etx_clk => letx_clk , etxd => letxd , etx_en => letx_en , etx_er => letx_er , erx_er => lerx_er , erx_col => lerx_col , erx_crs => lerx_crs , emdint => lemdint , emdioin => lemdioin , emdioout => lemdioout , emdioen => lemdioen , emdc => lemdc , testen => ltesten , trst => ltrst , tck => ltck , tms => ltms , tdi => ltdi , tdo => ltdo , tdoen => ltdoen , ---------------------------- -- BSCAN ---------------------------- chain_tck => OPEN , chain_tckn => OPEN , chain_tdi => OPEN , chain_tdo => '0', bsshft => OPEN , bscapt => OPEN , bsupdi => OPEN , bsupdo => OPEN , bsdrive => OPEN , bshighz => OPEN ); -- BSCAN -- TODO: ADD BSCAN end;

gpl-2.0

be52bbfa08be7ddf5a9b876e0ae35b59

0.463286

3.690743

false

Luisda199824/ProcesadorMonociclo

unionModulos.vhd

1

9,234

library IEEE; use IEEE.STD_LOGIC_1164.ALL; entity unionModulos is Port ( clk : in STD_LOGIC; rst : in STD_LOGIC; salida : out STD_LOGIC_VECTOR (31 downto 0)); end unionModulos; architecture Behavioral of unionModulos is signal SumDisp22, SumDisp30, aux1, PcCounterPlus, PC, aux2, address, instruction, Crs1, Crs2, cRD, aux7, AluResult, aux10, DataToMem, DataToReg, SEU_Disp30_Out, SEU_Disp22_Out, nPC_Source: std_logic_vector(31 downto 0) := (others => '0'); signal AluOp, Op3, NRs1, NRs2, NRd, Mux_NRd: std_logic_vector(5 downto 0) := (others => '0'); signal rs1, rs2, rd : std_logic_vector(4 downto 0) := (others => '0'); signal Op, PcSource, RfSource: std_logic_vector(1 downto 0) := (others => '0'); signal ncwp, cwp, Carry, weRF, RFDest, ReENMemory, WrENMemory: std_logic := '0'; signal imm13: std_logic_vector(12 downto 0) := (others => '0'); signal NZVC, cond, icc: std_logic_vector(3 downto 0) := (others => '0'); signal disp30 : std_logic_vector(29 downto 0) := (others => '0'); signal disp22 : std_logic_vector(21 downto 0) := (others => '0'); component ProgrammingCounter port ( clk : in STD_LOGIC; rst : in STD_LOGIC; dato : in STD_LOGIC_VECTOR (31 downto 0); -- addres PCOut : out STD_LOGIC_VECTOR (31 downto 0) -- sig ); end component; component RD_Mux Port ( RfDest : in STD_LOGIC; RD : in STD_LOGIC_VECTOR (5 downto 0); nRD : out STD_LOGIC_VECTOR (5 downto 0)); end component; component DataMemory Port ( Rst : in STD_LOGIC; cRD : in STD_LOGIC_VECTOR (31 downto 0); AluResult : in STD_LOGIC_VECTOR (31 downto 0); WrENMem : in STD_LOGIC; RdENMem : in STD_LOGIC; Data : out STD_LOGIC_VECTOR (31 downto 0)); end component; component Sumador32B port ( A : in STD_LOGIC_VECTOR (31 downto 0); B : in STD_LOGIC_VECTOR (31 downto 0); SumOut : out STD_LOGIC_VECTOR (31 downto 0) ); end component; component instructionMemory port ( address : in STD_LOGIC_VECTOR (31 downto 0); rst : in STD_LOGIC; outInstruction : out STD_LOGIC_VECTOR (31 downto 0) ); end component; component registerFile Port ( we : in STD_LOGIC; rs1 : in STD_LOGIC_VECTOR (5 downto 0); rs2 : in STD_LOGIC_VECTOR (5 downto 0); rd : in STD_LOGIC_VECTOR (5 downto 0); rst : in STD_LOGIC; dataToWrite : in STD_LOGIC_VECTOR (31 downto 0); CRs1 : out STD_LOGIC_VECTOR (31 downto 0); CRs2 : out STD_LOGIC_VECTOR (31 downto 0); CRd : out STD_LOGIC_VECTOR (31 downto 0)); end component; component UnityControl Port ( Op : in STD_LOGIC_VECTOR (1 downto 0); Op3 : in STD_LOGIC_VECTOR (5 downto 0); cond : in STD_LOGIC_VECTOR (3 downto 0); icc : in STD_LOGIC_VECTOR (3 downto 0); we : out STD_LOGIC; RFDest : out STD_LOGIC; WrENMemory : out STD_LOGIC; ReENMemory : out STD_LOGIC; RfSource : out STD_LOGIC_VECTOR(1 downto 0); PcSource : out STD_LOGIC_VECTOR(1 downto 0); AluOp : out STD_LOGIC_VECTOR (5 downto 0) ); end component; component Alu Port ( AluOp : in STD_LOGIC_VECTOR (5 downto 0); rs1 : in STD_LOGIC_VECTOR (31 downto 0); rs2 : in STD_LOGIC_VECTOR (31 downto 0); c : in STD_LOGIC; AluResult : out STD_LOGIC_VECTOR (31 downto 0) ); end component; component WindowsManager Port ( rs1 : in STD_LOGIC_VECTOR (4 downto 0); rs2 : in STD_LOGIC_VECTOR (4 downto 0); rd : in STD_LOGIC_VECTOR (4 downto 0); cwp : in STD_LOGIC; op3 : in STD_LOGIC_VECTOR (5 downto 0); op : in STD_LOGIC_VECTOR (1 downto 0); nrs1 : out STD_LOGIC_VECTOR (5 downto 0); nrs2 : out STD_LOGIC_VECTOR (5 downto 0); ncwp : out STD_LOGIC; nrd : out STD_LOGIC_VECTOR (5 downto 0)); end component; component PSR_Modifier Port ( AluOp : in STD_LOGIC_VECTOR (5 downto 0); Crs1 : in STD_LOGIC_VECTOR (31 downto 0); Crs2 : in STD_LOGIC_VECTOR (31 downto 0); ALU_Result : in STD_LOGIC_VECTOR (31 downto 0); nzvc : out STD_LOGIC_VECTOR (3 downto 0); rst: in STD_LOGIC); end component; component PSR Port ( nzvc : in STD_LOGIC_VECTOR (3 downto 0); rst : in STD_LOGIC; clk : in STD_LOGIC; ncwp: in STD_LOGIC; cond : in STD_LOGIC_VECTOR (3 downto 0); carry : out STD_LOGIC; cwp : out STD_LOGIC; icc : out STD_LOGIC_VECTOR (3 downto 0)); end component; component Mux32B Port ( A : in STD_LOGIC_VECTOR (31 downto 0); B : in STD_LOGIC_VECTOR (31 downto 0); Sc : in STD_LOGIC; MuxOut : out STD_LOGIC_VECTOR (31 downto 0) ); end component; component SignExtender Port ( A : in STD_LOGIC_VECTOR (12 downto 0); SEOut : out STD_LOGIC_VECTOR (31 downto 0)); end component; component SEU_Disp30 Port ( Disp30 : in STD_LOGIC_VECTOR (29 downto 0); SEU_Disp30_Out : out STD_LOGIC_VECTOR (31 downto 0)); end component; component SEU_Disp22 Port ( Disp22 : in STD_LOGIC_VECTOR (21 downto 0); Seu_Disp22_Out : out STD_LOGIC_VECTOR (31 downto 0)); end component; component PC_Mux Port ( clk : in STD_LOGIC; PcSource : in STD_LOGIC_VECTOR (1 downto 0); AluResult : in STD_LOGIC_VECTOR (31 downto 0); Pc : in STD_LOGIC_VECTOR (31 downto 0); Pc_Disp22 : in STD_LOGIC_VECTOR (31 downto 0); Pc_Disp30 : in STD_LOGIC_VECTOR (31 downto 0); nPC_Source : out STD_LOGIC_VECTOR (31 downto 0)); end component; component DataRF_Mux Port ( clk : in STD_LOGIC; RfSource : in STD_LOGIC_VECTOR (1 downto 0); DataToMem : in STD_LOGIC_VECTOR (31 downto 0); AluResult : in STD_LOGIC_VECTOR (31 downto 0); PC : in STD_LOGIC_VECTOR (31 downto 0); DataToReg : out STD_LOGIC_VECTOR (31 downto 0)); end component; begin Inst_pc_next: ProgrammingCounter port map ( clk => clk, rst => rst, dato => nPC_Source, PCOut => aux1 ); Inst_pc: ProgrammingCounter port map ( clk => clk, rst => rst, dato => aux1, PCOut => address ); Inst_sumPC: Sumador32B port map ( A => aux1, B => x"00000001", SumOut => PcCounterPlus ); Inst_instructionMemory: instructionMemory port map ( address => address, rst => rst, outInstruction => instruction ); rs1 <= instruction(18 downto 14); rs2 <= instruction(4 downto 0); rd <= instruction(29 downto 25); Op <= instruction(31 downto 30); Op3 <= instruction(24 downto 19); imm13 <= instruction(12 downto 0); cond <= instruction(28 downto 25); disp30 <= instruction(29 downto 0); disp22 <= instruction(21 downto 0); Inst_WindowsManager: WindowsManager Port Map ( rs1 => rs1, rs2 => rs2, rd => rd, cwp => cwp, op3 => Op3, op => Op, nrs1 => NRs1, nrs2 => NRs2, ncwp => ncwp, nrd => NRd ); Inst_RD_Mux: RD_Mux Port Map ( RfDest => RfDest, RD => NRd, nRD => Mux_NRd ); Inst_PSR: PSR Port Map ( nzvc => NZVC, rst => rst, clk => clk, ncwp => ncwp, cond => cond, carry => Carry, cwp => cwp, icc => icc ); Inst_register_file: registerFile port map( we => weRF, rs1 => NRs1, rs2 => NRs2, rd => Mux_NRd, rst => rst, dataToWrite => DataToReg, CRs1 => Crs1, CRs2 => aux7, CRd => cRD ); Inst_UC: UnityControl Port Map( Op => Op, Op3=> Op3, AluOp => AluOp, cond => cond, icc => icc, we => weRF, RFDest => RFDest, WrENMemory => WrENMemory, ReENMemory => ReENMemory, RfSource => RfSource, PcSource => PcSource ); Inst_Sign_ext_unit: SignExtender port map ( A => imm13, SEOut => aux10 ); Inst_PSR_Modifier: PSR_Modifier Port Map ( AluOp => AluOp, Crs1 => Crs1, Crs2 => Crs2, ALU_Result => AluResult, nzvc => NZVC, rst => rst ); Inst_mux32b: Mux32B port map ( A => aux7, B => aux10, Sc => instruction(13), MuxOut => Crs2 ); Inst_ALU: Alu port map ( AluOp => AluOp, rs1 => Crs1, rs2 => Crs2, c => Carry, AluResult => AluResult ); Inst_DataMemory: DataMemory port map ( Rst => Rst, cRD => cRD, AluResult => AluResult, WrENMem => WrENMemory, RdENMem => ReENMemory, Data => DataToMem ); Inst_DataRf_Mux: DataRF_Mux port map ( clk => clk, RfSource => RfSource, DataToMem => DataToMem, AluResult => AluResult, PC => address, DataToReg => DataToReg ); Inst_SeuDisp30: SEU_Disp30 port map ( Disp30 => disp30, SEU_Disp30_Out => SEU_Disp30_Out ); Inst_Disp30_Sumador : Sumador32B port map( A => SEU_Disp30_Out, B => PcCounterPlus, SumOut => SumDisp30 ); Inst_SeuDisp22: SEU_Disp22 port map ( Disp22 => disp22, Seu_Disp22_Out => Seu_Disp22_Out ); Inst_Disp22_Sumador : Sumador32B port map( A => SEU_Disp22_Out, B => PcCounterPlus, SumOut => SumDisp22 ); Inst_PcMux: PC_Mux port map ( clk => clk, PcSource => PcSource, AluResult => AluResult, Pc => PcCounterPlus, Pc_Disp22 => SumDisp22, Pc_Disp30 => SumDisp30, nPC_Source => nPC_Source ); salida <= AluResult; end Behavioral;

mit

e150619ca85e6eb989d174d75c236aaf

0.603964

2.987383

false

marco-c/leon-nexys2

grlib-gpl-1.3.4-b4140/designs/leon3-xilinx-ml510/leon3mp.vhd

1

51,575

----------------------------------------------------------------------------- -- LEON3 Demonstration design -- Copyright (C) 2008 Jiri Gaisler, Jan Andersson, Aeroflex Gaisler ------------------------------------------------------------------------------ -- This file is a part of the GRLIB VHDL IP LIBRARY -- Copyright (C) 2003 - 2008, Gaisler Research -- Copyright (C) 2008 - 2013, Aeroflex Gaisler -- -- This program is free software; you can redistribute it and/or modify -- it under the terms of the GNU General Public License as published by -- the Free Software Foundation; either version 2 of the License, or -- (at your option) any later version. -- -- This program is distributed in the hope that it will be useful, -- but WITHOUT ANY WARRANTY; without even the implied warranty of -- MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the -- GNU General Public License for more details. -- -- You should have received a copy of the GNU General Public License -- along with this program; if not, write to the Free Software -- Foundation, Inc., 59 Temple Place, Suite 330, Boston, MA 02111-1307 USA ------------------------------------------------------------------------------ library ieee; use ieee.std_logic_1164.all; library grlib, techmap; use grlib.amba.all; use grlib.stdlib.all; use grlib.devices.all; use techmap.gencomp.all; use techmap.allclkgen.all; library gaisler; use gaisler.memctrl.all; use gaisler.leon3.all; use gaisler.uart.all; use gaisler.misc.all; use gaisler.spi.all; use gaisler.i2c.all; use gaisler.net.all; use gaisler.jtag.all; use gaisler.pci.all; use gaisler.ddrpkg.all; library esa; use esa.memoryctrl.all; use esa.pcicomp.all; use work.config.all; -- pragma translate_off library unisim; use unisim.BUFG; -- pragma translate_on entity leon3mp is generic ( fabtech : integer := CFG_FABTECH; memtech : integer := CFG_MEMTECH; padtech : integer := CFG_PADTECH; ncpu : integer := CFG_NCPU; disas : integer := CFG_DISAS; -- Enable disassembly to console dbguart : integer := CFG_DUART; -- Print UART on console pclow : integer := CFG_PCLOW ); port ( fpga_cpu_reset_b : in std_ulogic; user_clksys : in std_ulogic; -- 100 MHz main clock sysace_fpga_clk : in std_ulogic; -- 33 MHz -- Flash flash_we_b : out std_ulogic; flash_wait : in std_ulogic; flash_reset_b : out std_ulogic; flash_oe_b : out std_ulogic; flash_d : inout std_logic_vector(15 downto 0); flash_clk : out std_ulogic; flash_ce_b : out std_ulogic; flash_adv_b : out std_logic; flash_a : out std_logic_vector(21 downto 0); --pragma translate_off -- For debug output module sram_bw : out std_ulogic; sim_d : inout std_logic_vector(31 downto 16); iosn : out std_ulogic; --pragma translate_on -- DDR2 slot 1 dimm1_ddr2_we_b : out std_ulogic; dimm1_ddr2_s_b : out std_logic_vector(1 downto 0); dimm1_ddr2_ras_b : out std_ulogic; dimm1_ddr2_pll_clkin_p : out std_ulogic; dimm1_ddr2_pll_clkin_n : out std_ulogic; dimm1_ddr2_odt : out std_logic_vector(1 downto 0); dimm1_ddr2_dqs_p : inout std_logic_vector(8 downto 0); dimm1_ddr2_dqs_n : inout std_logic_vector(8 downto 0); dimm1_ddr2_dqm : out std_logic_vector(8 downto 0); dimm1_ddr2_dq : inout std_logic_vector(71 downto 0); dimm1_ddr2_cke : out std_logic_vector(1 downto 0); -- dimm1_ddr2_cb : inout std_logic_vector(7 downto 0); dimm1_ddr2_cas_b : out std_ulogic; dimm1_ddr2_ba : out std_logic_vector(2 downto 0); dimm1_ddr2_a : out std_logic_vector(13 downto 0); -- DDR2 slot 0 dimm0_ddr2_we_b : out std_ulogic; dimm0_ddr2_s_b : out std_logic_vector(1 downto 0); dimm0_ddr2_ras_b : out std_ulogic; dimm0_ddr2_pll_clkin_p : out std_ulogic; dimm0_ddr2_pll_clkin_n : out std_ulogic; dimm0_ddr2_odt : out std_logic_vector(1 downto 0); dimm0_ddr2_dqs_p : inout std_logic_vector(8 downto 0); dimm0_ddr2_dqs_n : inout std_logic_vector(8 downto 0); dimm0_ddr2_dqm : out std_logic_vector(8 downto 0); dimm0_ddr2_dq : inout std_logic_vector(71 downto 0); dimm0_ddr2_cke : out std_logic_vector(1 downto 0); -- dimm0_ddr2_cb : inout std_logic_vector(7 downto 0); dimm0_ddr2_cas_b : out std_ulogic; dimm0_ddr2_ba : out std_logic_vector(2 downto 0); dimm0_ddr2_a : out std_logic_vector(13 downto 0); dimm0_ddr2_reset_n : out std_ulogic; -- Ethernet PHY phy0_txer : out std_ulogic; phy0_txd : out std_logic_vector(3 downto 0); phy0_txctl_txen : out std_ulogic; phy0_txclk : in std_ulogic; phy0_rxer : in std_ulogic; phy0_rxd : in std_logic_vector(3 downto 0); phy0_rxctl_rxdv : in std_ulogic; phy0_rxclk : in std_ulogic; phy0_reset : out std_ulogic; phy0_mdio : inout std_logic; phy0_mdc : out std_ulogic; -- phy0_int : in std_ulogic; -- System ACE MPU sysace_mpa : out std_logic_vector(6 downto 0); sysace_mpce : out std_ulogic; sysace_mpirq : in std_ulogic; sysace_mpoe : out std_ulogic; sysace_mpwe : out std_ulogic; sysace_mpd : inout std_logic_vector(15 downto 0); -- GPIO/Green LEDs dbg_led : inout std_logic_vector(3 downto 0); -- Red/Green LEDs opb_bus_error : out std_ulogic; plb_bus_error : out std_ulogic; -- LCD -- fpga_lcd_rw : out std_ulogic; -- fpga_lcd_rs : out std_ulogic; -- fpga_lcd_e : out std_ulogic; -- fpga_lcd_db : out std_logic_vector(7 downto 0); -- DVI dvi_xclk_p : out std_ulogic; dvi_xclk_n : out std_ulogic; dvi_v : out std_ulogic; dvi_reset_b : out std_ulogic; dvi_h : out std_ulogic; dvi_gpio1 : inout std_logic; dvi_de : out std_ulogic; dvi_d : out std_logic_vector(11 downto 0); -- PCI pci_p_trdy_b : inout std_logic; pci_p_stop_b : inout std_logic; pci_p_serr_b : inout std_logic; pci_p_rst_b : inout std_logic; pci_p_req_b : in std_logic_vector(0 to 4); pci_p_perr_b : inout std_logic; pci_p_par : inout std_logic; pci_p_lock_b : inout std_logic; pci_p_irdy_b : inout std_logic; pci_p_intd_b : in std_logic; pci_p_intc_b : in std_logic; pci_p_intb_b : in std_logic; pci_p_inta_b : in std_logic; pci_p_gnt_b : out std_logic_vector(0 to 4); pci_p_frame_b : inout std_logic; pci_p_devsel_b : inout std_logic; pci_p_clk5_r : out std_ulogic; pci_p_clk5 : in std_ulogic; pci_p_clk4_r : out std_ulogic; pci_p_clk3_r : out std_ulogic; pci_p_clk1_r : out std_ulogic; pci_p_clk0_r : out std_ulogic; pci_p_cbe_b : inout std_logic_vector(3 downto 0); pci_p_ad : inout std_logic_vector(31 downto 0); -- pci_fpga_idsel : in std_ulogic; sbr_pwg_rsm_rstj : inout std_logic; sbr_nmi_r : in std_ulogic; sbr_intr_r : in std_ulogic; sbr_ide_rst_b : inout std_logic; -- IIC/SMBus and sideband signals iic_sda_dvi : inout std_logic; iic_scl_dvi : inout std_logic; fpga_sda : inout std_logic; fpga_scl : inout std_logic; iic_therm_b : in std_ulogic; iic_reset_b : out std_ulogic; iic_irq_b : in std_ulogic; iic_alert_b : in std_ulogic; -- SPI spi_data_out : in std_logic; spi_data_in : out std_ulogic; spi_data_cs_b : out std_ulogic; spi_clk : out std_ulogic; -- UARTs uart1_txd : out std_ulogic; uart1_rxd : in std_ulogic; uart1_rts_b : out std_ulogic; uart1_cts_b : in std_ulogic; uart0_txd : out std_ulogic; uart0_rxd : in std_ulogic; uart0_rts_b : out std_ulogic -- uart0_cts_b : in std_ulogic -- System monitor -- test_mon_vrefp : in std_ulogic; -- test_mon_vp0_p : in std_ulogic; -- test_mon_vn0_n : in std_ulogic -- test_mon_avdd : in std_ulogic ); end; architecture rtl of leon3mp is component svga2ch7301c generic ( tech : integer := 0; idf : integer := 0; dynamic : integer := 0 ); port ( clk : in std_ulogic; rstn : in std_ulogic; clksel : in std_logic_vector(1 downto 0); vgao : in apbvga_out_type; vgaclk_fb : in std_ulogic; clk25_fb : in std_ulogic; clk40_fb : in std_ulogic; clk65_fb : in std_ulogic; vgaclk : out std_ulogic; clk25 : out std_ulogic; clk40 : out std_ulogic; clk65 : out std_ulogic; dclk_p : out std_ulogic; dclk_n : out std_ulogic; locked : out std_ulogic; data : out std_logic_vector(11 downto 0); hsync : out std_ulogic; vsync : out std_ulogic; de : out std_ulogic ); end component; component BUFG port (O : out std_logic; I : in std_logic); end component; constant blength : integer := 12; constant fifodepth : integer := 8; constant maxahbm : integer := NCPU+CFG_AHB_UART+CFG_AHB_JTAG+ CFG_SVGA_ENABLE+CFG_PCI; -- Set this constant to 1 to include an APB bridge with the Logan logic -- analyzer attached to the PCI signals constant CFG_LOGAN : integer := 0; signal ddr0_clk_fb, ddr1_clk_fb : std_logic; signal vcc, gnd : std_logic_vector(31 downto 0); signal memi : memory_in_type; signal memo : memory_out_type; signal wpo : wprot_out_type; signal apbi, apbi1 : apb_slv_in_type; signal apbo, apbo1 : apb_slv_out_vector := (others => apb_none); signal ahbsi : ahb_slv_in_type; signal ahbso : ahb_slv_out_vector := (others => ahbs_none); signal ahbmi : ahb_mst_in_type; signal ahbmo : ahb_mst_out_vector := (others => ahbm_none); signal clkm, clkm2x, rstn, rstraw, flashclkl : std_ulogic; signal clkddr, clk_200 : std_ulogic; signal clk25, clk40, clk65 : std_ulogic; signal cgi, cgi2, cgi3 : clkgen_in_type; signal cgo, cgo2, cgo3 : clkgen_out_type; signal u1i, dui : uart_in_type; signal u1o, duo : uart_out_type; signal irqi : irq_in_vector(0 to NCPU-1); signal irqo : irq_out_vector(0 to NCPU-1); signal dbgi : l3_debug_in_vector(0 to NCPU-1); signal dbgo : l3_debug_out_vector(0 to NCPU-1); signal dsui : dsu_in_type; signal dsuo : dsu_out_type; signal opb_bus_errorl, plb_bus_errorl : std_ulogic; signal ethi, ethi1, ethi2 : eth_in_type; signal etho, etho1, etho2 : eth_out_type; signal gpti : gptimer_in_type; signal gpioi : gpio_in_type; signal gpioo : gpio_out_type; signal clklock, lock0, lock1, lclk, clkml0, clkml1 : std_ulogic; signal tck, tckn, tms, tdi, tdo : std_ulogic; signal rst : std_ulogic; signal egtx_clk_fb : std_ulogic; signal egtx_clk, legtx_clk, l2egtx_clk : std_ulogic; signal vgao : apbvga_out_type; signal lcd_datal : std_logic_vector(11 downto 0); signal lcd_hsyncl, lcd_vsyncl, lcd_del, lcd_reset_bl : std_ulogic; signal clk_sel : std_logic_vector(1 downto 0); signal vgalock : std_ulogic; signal clkvga, clkvga_p, clkvga_n : std_ulogic; signal i2ci, dvi_i2ci : i2c_in_type; signal i2co, dvi_i2co : i2c_out_type; signal spii : spi_in_type; signal spio : spi_out_type; signal slvsel : std_logic_vector(CFG_SPICTRL_SLVS-1 downto 0); constant BOARD_FREQ_200 : integer := 200000; -- input frequency in KHz constant BOARD_FREQ : integer := 100000; -- input frequency in KHz constant CPU_FREQ : integer := BOARD_FREQ * CFG_CLKMUL / CFG_CLKDIV; -- cpu frequency in KHz constant I2C_FILTER : integer := (CPU_FREQ*5+50000)/100000+1; -- DDR clock is 200 MHz clock unless CFG_DDR2SP_NOSYNC is set. If that config -- option is set the DDR clock is 2x CPU clock. constant DDR_FREQ : integer := BOARD_FREQ_200 - (BOARD_FREQ_200 - 2*CPU_FREQ)*CFG_DDR2SP_NOSYNC; constant IOAEN : integer := CFG_DDR2SP; signal stati : ahbstat_in_type; signal ddr0_clkv : std_logic_vector(2 downto 0); signal ddr0_clkbv : std_logic_vector(2 downto 0); signal ddr1_clkv : std_logic_vector(2 downto 0); signal ddr1_clkbv : std_logic_vector(2 downto 0); signal clkace : std_ulogic; signal acei : gracectrl_in_type; signal aceo : gracectrl_out_type; signal sysmoni : grsysmon_in_type; signal sysmono : grsysmon_out_type; signal pciclk, pci_clk, pci_clk_fb : std_ulogic; signal pci_arb_gnt : std_logic_vector(0 to 7); signal pci_arb_req : std_logic_vector(0 to 7); signal pci_arb_reql : std_logic_vector(0 to 4); signal pci_reql : std_ulogic; signal pci_host, pci_66 : std_ulogic; signal pci_intv : std_logic_vector(3 downto 0); signal pcii : pci_in_type; signal pcio : pci_out_type; signal clkma, clkmb, clkmc : std_ulogic; signal clk0_tb, rst0_tb, rst0_tbn : std_ulogic; signal phy_init_done : std_ulogic; -- Logan signals signal signals : std_logic_vector(63*CFG_LOGAN downto 0); attribute syn_keep : boolean; attribute syn_preserve : boolean; attribute syn_keep of clkml0 : signal is true; attribute syn_preserve of clkml0 : signal is true; attribute syn_keep of clkml1 : signal is true; attribute syn_preserve of clkml1 : signal is true; attribute syn_keep of clkm : signal is true; attribute syn_preserve of clkm : signal is true; attribute syn_keep of egtx_clk : signal is true; attribute syn_preserve of egtx_clk : signal is true; attribute syn_keep of clkvga : signal is true; attribute syn_preserve of clkvga : signal is true; attribute syn_keep of clk25 : signal is true; attribute syn_preserve of clk25 : signal is true; attribute syn_keep of clk40 : signal is true; attribute syn_preserve of clk40 : signal is true; attribute syn_keep of clk65 : signal is true; attribute syn_preserve of clk65 : signal is true; attribute syn_keep of phy_init_done : signal is true; attribute syn_preserve of phy_init_done : signal is true; attribute keep : boolean; attribute keep of lock0 : signal is true; attribute keep of lock1 : signal is true; attribute keep of clkml0 : signal is true; attribute keep of clkml1 : signal is true; attribute keep of clkm : signal is true; attribute keep of egtx_clk : signal is true; attribute keep of clkvga : signal is true; attribute keep of clk25 : signal is true; attribute keep of clk40 : signal is true; attribute keep of clk65 : signal is true; attribute syn_noprune : boolean; attribute syn_noprune of sysace_fpga_clk_pad : label is true; begin vcc <= (others => '1'); gnd <= (others => '0'); rst0_tbn <= not rst0_tb; ---------------------------------------------------------------------- --- Reset and Clock generation ------------------------------------- ---------------------------------------------------------------------- flashclk_pad : outpad generic map (tech => padtech, slew => 1, strength => 24) port map (flash_clk, flashclkl); sysace_fpga_clk_pad : clkpad generic map (tech => padtech, level => cmos, voltage => x25v) port map (sysace_fpga_clk, clkace); pci_p_clk5_pad : clkpad generic map (tech => padtech, level => cmos, voltage => x25v) port map (pci_p_clk5, pci_clk_fb); pci_p_clk5_r_pad : outpad generic map (tech => padtech, level => pci33) port map (pci_p_clk5_r, pci_clk); pci_p_clk4_r_pad : outpad generic map (tech => padtech, level => pci33) port map (pci_p_clk4_r, pci_clk); pci_p_clk3_r_pad : outpad generic map (tech => padtech, level => pci33) port map (pci_p_clk3_r, pci_clk); pci_p_clk1_r_pad : outpad generic map (tech => padtech, level => pci33) port map (pci_p_clk1_r, pci_clk); pci_p_clk0_r_pad : outpad generic map (tech => padtech, level => pci33) port map (pci_p_clk0_r, pci_clk); clkgen0 : clkgen -- system clock generator generic map (CFG_FABTECH, CFG_CLKMUL, CFG_CLKDIV, 1, 1, 1, CFG_PCIDLL, CFG_PCISYSCLK, BOARD_FREQ, 1) port map (lclk, pci_clk_fb, clkmc, open, clkm2x, flashclkl, pciclk, cgi, cgo, open, open, clk_200); cgi.pllctrl <= "00"; cgi.pllrst <= rstraw; cgi.pllref <= '0'; -- clkgen1 : clkgen -- Ethernet 1G PHY clock generator -- generic map (CFG_FABTECH, 5, 4, 0, 0, 0, 0, 0, BOARD_FREQ, 0) -- port map (lclk, gnd(0), egtx_clk, open, open, open, open, cgi2, cgo2); -- cgi2.pllctrl <= "00"; cgi2.pllrst <= rstraw; --cgi2.pllref <= egtx_clk_fb; -- egtx_clk_pad : outpad generic map (tech => padtech) -- port map (phy_gtx_clk, egtx_clk); clkgen2 : clkgen -- PCI clock generator generic map (CFG_FABTECH, 2, 6, 0, 0, 0, 0, 0, BOARD_FREQ, 0) port map (lclk, gnd(0), pci_clk, open, open, open, open, cgi3, cgo3); cgi3.pllctrl <= "00"; cgi3.pllrst <= rstraw; cgi3.pllref <= '0'; iic_reset_b_pad : outpad generic map (tech => padtech) port map (iic_reset_b, rstn); resetn_pad : inpad generic map (tech => padtech, level => cmos, voltage => x25v) port map (fpga_cpu_reset_b, rst); rst0 : rstgen -- reset generator port map (rst, clkm, clklock, rstn, rstraw); clklock <= lock0 and lock1 and cgo.clklock and cgo3.clklock; clk_pad : clkpad generic map (tech => padtech, arch => 2, level => cmos, voltage => x25v) port map (user_clksys, lclk); ---------------------------------------------------------------------- --- AHB CONTROLLER -------------------------------------------------- ---------------------------------------------------------------------- ahb0 : ahbctrl -- AHB arbiter/multiplexer generic map (defmast => CFG_DEFMST, split => CFG_SPLIT, rrobin => CFG_RROBIN, ioaddr => CFG_AHBIO, devid => XILINX_ML510, ioen => IOAEN, nahbm => maxahbm, nahbs => 11 + CFG_LOGAN) port map (rstn, clkm, ahbmi, ahbmo, ahbsi, ahbso); ---------------------------------------------------------------------- --- LEON3 processor and DSU ----------------------------------------- ---------------------------------------------------------------------- l3 : if CFG_LEON3 = 1 generate cpu : for i in 0 to NCPU-1 generate u0 : leon3s -- LEON3 processor generic map (i, fabtech, memtech, CFG_NWIN, CFG_DSU, CFG_FPU, CFG_V8, 0, CFG_MAC, pclow, CFG_NOTAG, CFG_NWP, CFG_ICEN, CFG_IREPL, CFG_ISETS, CFG_ILINE, CFG_ISETSZ, CFG_ILOCK, CFG_DCEN, CFG_DREPL, CFG_DSETS, CFG_DLINE, CFG_DSETSZ, CFG_DLOCK, CFG_DSNOOP, CFG_ILRAMEN, CFG_ILRAMSZ, CFG_ILRAMADDR, CFG_DLRAMEN, CFG_DLRAMSZ, CFG_DLRAMADDR, CFG_MMUEN, CFG_ITLBNUM, CFG_DTLBNUM, CFG_TLB_TYPE, CFG_TLB_REP, CFG_LDDEL, disas, CFG_ITBSZ, CFG_PWD, CFG_SVT, CFG_RSTADDR, NCPU-1, CFG_DFIXED, CFG_SCAN, CFG_MMU_PAGE, CFG_BP) port map (clkm, rstn, ahbmi, ahbmo(i), ahbsi, ahbso, irqi(i), irqo(i), dbgi(i), dbgo(i)); end generate; opb_bus_errorl <= not dbgo(0).error; dsugen : if CFG_DSU = 1 generate dsu0 : dsu3 -- LEON3 Debug Support Unit generic map (hindex => 2, haddr => 16#D00#, hmask => 16#F00#, ncpu => NCPU, tbits => 30, tech => memtech, irq => 0, kbytes => CFG_ATBSZ) port map (rstn, clkm, ahbmi, ahbsi, ahbso(2), dbgo, dbgi, dsui, dsuo); dsui.enable <= '1'; dsui.break <= not gpioo.val(0); -- Position on on GPIO DIP switch plb_bus_errorl <= dsuo.active; end generate; end generate; nodsu : if CFG_DSU = 0 generate dsuo.tstop <= '0'; dsuo.active <= '0'; plb_bus_errorl <= '0'; end generate; opb_bus_error_pad : outpad generic map (tech => padtech) port map (opb_bus_error, opb_bus_errorl); plb_bus_error_pad : outpad generic map (tech => padtech) port map (plb_bus_error, plb_bus_errorl); dcomgen : if CFG_AHB_UART = 1 generate dcom0: ahbuart -- Debug UART generic map (hindex => NCPU, pindex => 7, paddr => 7) port map (rstn, clkm, dui, duo, apbi, apbo(7), ahbmi, ahbmo(NCPU)); end generate; nodcom : if CFG_AHB_UART = 0 generate duo.txd <= '0'; duo.rtsn <= '1'; end generate; dsurx_pad : inpad generic map (tech => padtech, level => cmos, voltage => x33v) port map (uart0_rxd, dui.rxd); dsutx_pad : outpad generic map (tech => padtech, level => cmos, voltage => x33v) port map (uart0_txd, duo.txd); -- dsucts_pad : inpad generic map (tech => padtech, level => cmos, voltage => x33v) -- port map (uart0_cts_b, dui.ctsn); dsurts_pad : outpad generic map (tech => padtech, level => cmos, voltage => x33v) port map (uart0_rts_b, duo.rtsn); ahbjtaggen0 :if CFG_AHB_JTAG = 1 generate ahbjtag0 : ahbjtag generic map(tech => fabtech, hindex => NCPU+CFG_AHB_UART) port map(rstn, clkm, tck, tms, tdi, tdo, ahbmi, ahbmo(NCPU+CFG_AHB_UART), open, open, open, open, open, open, open, gnd(0)); end generate; ---------------------------------------------------------------------- --- Memory controllers ---------------------------------------------- ---------------------------------------------------------------------- memi.writen <= '1'; memi.wrn <= "1111"; memi.bwidth <= "01"; memi.brdyn <= '1'; memi.bexcn <= '1'; mctrl0 : if CFG_MCTRL_LEON2 = 1 generate mctrl0 : mctrl generic map (hindex => 3, pindex => 0, ramaddr => 0, rammask => 0, paddr => 0, srbanks => 0, ram8 => CFG_MCTRL_RAM8BIT, ram16 => CFG_MCTRL_RAM16BIT, sden => CFG_MCTRL_SDEN, invclk => CFG_MCTRL_INVCLK, sepbus => CFG_MCTRL_SEPBUS) port map (rstn, clkm, memi, memo, ahbsi, ahbso(3), apbi, apbo(0), wpo); end generate; nomctrl: if CFG_MCTRL_LEON2 = 0 generate memo.address <= (others => '0'); memo.romsn <= (others => '1'); memo.oen <= '1'; memo.wrn <= (others => '1'); memo.vbdrive <= (others => '1'); memo.writen <= '1'; end generate; flash_reset_b_pad : outpad generic map (tech => padtech) port map (flash_reset_b, rstn); -- flash_wait_pad : inpad generic map (tech => padtech) -- port map (flash_wait, ); flash_adv_b_pad : outpad generic map (tech => padtech) port map (flash_adv_b, gnd(0)); flash_a_pads : outpadv generic map (width => 22, tech => padtech) port map (flash_a, memo.address(22 downto 1)); flash_ce_b_pad : outpad generic map (tech => padtech) port map (flash_ce_b, memo.romsn(0)); flash_oe_b_pad : outpad generic map (tech => padtech) port map (flash_oe_b, memo.oen); --pragma translate_off rwen_pad : outpad generic map (tech => padtech) port map (sram_bw, memo.wrn(3)); sim_d_pads : iopadvv generic map (tech => padtech, width => 16) port map (sim_d, memo.data(15 downto 0), memo.vbdrive(15 downto 0), memi.data(15 downto 0)); iosn_pad : outpad generic map (tech => padtech) port map (iosn, memo.iosn); --pragma translate_on flash_we_b_pad : outpad generic map (tech => padtech) port map (flash_we_b, memo.writen); flash_d_pads : iopadvv generic map (tech => padtech, width => 16) port map (flash_d, memo.data(31 downto 16), memo.vbdrive(31 downto 16), memi.data(31 downto 16)); dbg_led0_pad : outpad generic map (tech => padtech, level => cmos, voltage => x33v) port map (dbg_led(3), phy_init_done); clkm <= clkma; clkma <= clkmb; clkmb <= clkmc; ddrsp0 : if (CFG_DDR2SP /= 0) generate phy_init_done <= '1'; -- DDR clock selection -- If the synchronization registers are removed in the DDR controller, we -- assume that the user wants to run at 2x the system clock. Otherwise the -- DDR clock is generated from the 200 MHz clock. ddrclkselarb: if CFG_DDR2SP_NOSYNC = 0 generate BUFGDDR : BUFG port map (I => clk_200, O => clkddr); end generate; ddrclksel2x: if CFG_DDR2SP_NOSYNC /= 0 generate clkddr <= clkm2x; end generate; dimm0_ddr2_reset_n_pad : outpad generic map (tech => padtech, level => cmos, voltage => x33v) port map (dimm0_ddr2_reset_n, rst); -- Slot 0 ddrc0 : ddr2spa generic map ( fabtech => fabtech, memtech => memtech, hindex => 0, haddr => 16#400#, hmask => 16#e00#, ioaddr => 1, pwron => CFG_DDR2SP_INIT, MHz => DDR_FREQ/1000, TRFC => CFG_DDR2SP_TRFC, clkmul => CFG_DDR2SP_FREQ/10 - (CFG_DDR2SP_FREQ/10-1)*CFG_DDR2SP_NOSYNC, clkdiv => 20 - (19)*CFG_DDR2SP_NOSYNC, ahbfreq => CPU_FREQ/1000, col => CFG_DDR2SP_COL, Mbyte => CFG_DDR2SP_SIZE, ddrbits => CFG_DDR2SP_DATAWIDTH, ddelayb0 => CFG_DDR2SP_DELAY0, ddelayb1 => CFG_DDR2SP_DELAY1, ddelayb2 => CFG_DDR2SP_DELAY2, ddelayb3 => CFG_DDR2SP_DELAY3, ddelayb4 => CFG_DDR2SP_DELAY4, ddelayb5 => CFG_DDR2SP_DELAY5, ddelayb6 => CFG_DDR2SP_DELAY6, ddelayb7 => CFG_DDR2SP_DELAY7, readdly => 1, rskew => 0, oepol => 0, dqsgating => 0, rstdel => 200, eightbanks => 1, numidelctrl => 2 + CFG_DDR2SP_DATAWIDTH/64, norefclk => 0, odten => 3, nosync => CFG_DDR2SP_NOSYNC) port map (rst, rstn, clkddr, clkm, clk_200, lock0, clkml0, clkml0, ahbsi, ahbso(0), ddr0_clkv, ddr0_clkbv, ddr0_clk_fb, ddr0_clk_fb, dimm0_ddr2_cke, dimm0_ddr2_s_b, dimm0_ddr2_we_b, dimm0_ddr2_ras_b, dimm0_ddr2_cas_b, dimm0_ddr2_dqm(7 downto 4*(32/CFG_DDR2SP_DATAWIDTH)), dimm0_ddr2_dqs_p(7 downto 4*(32/CFG_DDR2SP_DATAWIDTH)), dimm0_ddr2_dqs_n(7 downto 4*(32/CFG_DDR2SP_DATAWIDTH)), dimm0_ddr2_a, dimm0_ddr2_ba(2 downto 0), dimm0_ddr2_dq(63 downto 32*(32/CFG_DDR2SP_DATAWIDTH)), dimm0_ddr2_odt); dimm0_ddr2_pll_clkin_p <= ddr0_clkv(0); dimm0_ddr2_pll_clkin_n <= ddr0_clkbv(0); -- Ground unused bank address and memory mask -- dimm0_ddr2_ba_notused_pad : outpad generic map (tech => padtech, level => SSTL18_I) -- port map (dimm0_ddr2_ba(2), gnd(0)); dimm0_ddr2_dqm_notused8_pad : outpad generic map (tech => padtech, level => SSTL18_I) port map (dimm0_ddr2_dqm(8), gnd(0)); -- Tri-state unused data strobe dimm0_dqsp_notused8_pad : iopad generic map (tech => padtech, level => SSTL18_II) port map (dimm0_ddr2_dqs_p(8), gnd(0), vcc(0), open); dimm0_dqsn_notused8_pad : iopad generic map (tech => padtech, level => SSTL18_II) port map (dimm0_ddr2_dqs_n(8), gnd(0), vcc(0), open); -- Tristate unused check bits dimm0_cb_notused_pad : iopadv generic map (tech => padtech, width => 8, level => SSTL18_II) port map (dimm0_ddr2_dq(71 downto 64), gnd(7 downto 0), vcc(0), open); -- Handle signals not used with 32-bit interface ddr032bit: if CFG_DDR2SP_DATAWIDTH /= 64 generate dimm0_ddr2_dqm_notused30_pads : outpadv generic map (tech => padtech, width => 4, level => SSTL18_I) port map (dimm0_ddr2_dqm(3 downto 0), gnd(3 downto 0)); dimm0_dqsp_notused30_pads : iopadv generic map (tech => padtech, width => 4, level => SSTL18_II) port map (dimm0_ddr2_dqs_p(3 downto 0), gnd(3 downto 0), vcc(0), open); dimm0_dqsn_notused30_pads : iopadv generic map (tech => padtech, width => 4, level => SSTL18_II) port map (dimm0_ddr2_dqs_n(3 downto 0), gnd(3 downto 0), vcc(0), open); dimm0_dq_notused_pads : iopadv generic map (tech => padtech, width => 32, level => SSTL18_II) port map (dimm0_ddr2_dq(31 downto 0), gnd, vcc(0), open); end generate; -- Slot 1 ddrc1 : ddr2spa generic map ( fabtech => fabtech, memtech => memtech, hindex => 1, haddr => 16#600#, hmask => 16#E00#, ioaddr => 2, pwron => CFG_DDR2SP_INIT, MHz => DDR_FREQ/1000, TRFC => CFG_DDR2SP_TRFC, clkmul => CFG_DDR2SP_FREQ/10 - (CFG_DDR2SP_FREQ/10-1)*CFG_DDR2SP_NOSYNC, clkdiv => 20 - (19)*CFG_DDR2SP_NOSYNC, ahbfreq => CPU_FREQ/1000, col => CFG_DDR2SP_COL, Mbyte => CFG_DDR2SP_SIZE, ddrbits => CFG_DDR2SP_DATAWIDTH, ddelayb0 => CFG_DDR2SP_DELAY0, ddelayb1 => CFG_DDR2SP_DELAY1, ddelayb2 => CFG_DDR2SP_DELAY2, ddelayb3 => CFG_DDR2SP_DELAY3, ddelayb4 => CFG_DDR2SP_DELAY4, ddelayb5 => CFG_DDR2SP_DELAY5, ddelayb6 => CFG_DDR2SP_DELAY6, ddelayb7 => CFG_DDR2SP_DELAY7, readdly => 1, rskew => 0, oepol => 0, dqsgating => 0, rstdel => 200, eightbanks => 1, numidelctrl => 2 + CFG_DDR2SP_DATAWIDTH/64, norefclk => 0, odten => 3, nosync => CFG_DDR2SP_NOSYNC) port map (rst, rstn, clkddr, clkm, clk_200, lock1, clkml1, clkml1, ahbsi, ahbso(1), ddr1_clkv, ddr1_clkbv, ddr1_clk_fb, ddr1_clk_fb, dimm1_ddr2_cke, dimm1_ddr2_s_b, dimm1_ddr2_we_b, dimm1_ddr2_ras_b, dimm1_ddr2_cas_b, dimm1_ddr2_dqm(7 downto 4*(32/CFG_DDR2SP_DATAWIDTH)), dimm1_ddr2_dqs_p(7 downto 4*(32/CFG_DDR2SP_DATAWIDTH)), dimm1_ddr2_dqs_n(7 downto 4*(32/CFG_DDR2SP_DATAWIDTH)), dimm1_ddr2_a, dimm1_ddr2_ba(2 downto 0), dimm1_ddr2_dq(63 downto 32*(32/ CFG_DDR2SP_DATAWIDTH)), dimm1_ddr2_odt); dimm1_ddr2_pll_clkin_p <= ddr1_clkv(0); dimm1_ddr2_pll_clkin_n <= ddr1_clkbv(0); -- Ground unused bank address and memory mask -- dimm1_ddr2_ba_notused_pad : outpad generic map (tech => padtech, level => SSTL18_I) -- port map (dimm1_ddr2_ba(2), gnd(0)); dimm1_ddr2_dqm_notused8_pad : outpad generic map (tech => padtech, level => SSTL18_I) port map (dimm1_ddr2_dqm(8), gnd(0)); -- Tri-state unused data strobe dimm1_dqsp_notused8_pad : iopad generic map (tech => padtech, level => SSTL18_II) port map (dimm1_ddr2_dqs_p(8), gnd(0), vcc(0), open); dimm1_dqsn_notused8_pad : iopad generic map (tech => padtech, level => SSTL18_II) port map (dimm1_ddr2_dqs_n(8), gnd(0), vcc(0), open); -- Tristate unused check bits dimm1_cb_notused_pad : iopadv generic map (tech => padtech, width => 8, level => SSTL18_II) port map (dimm1_ddr2_dq(71 downto 64), gnd(7 downto 0), vcc(0), open); -- Handle signals not used with 32-bit interface ddr132bit: if CFG_DDR2SP_DATAWIDTH /= 64 generate dimm1_ddr2_dqm_notused30_pads : outpadv generic map (tech => padtech, width => 4, level => SSTL18_I) port map (dimm1_ddr2_dqm(3 downto 0), gnd(3 downto 0)); dimm1_dqsp_notused30_pads : iopadv generic map (tech => padtech, width => 4, level => SSTL18_II) port map (dimm1_ddr2_dqs_p(3 downto 0), gnd(3 downto 0), vcc(0), open); dimm1_dqsn_notused30_pads : iopadv generic map (tech => padtech, width => 4, level => SSTL18_II) port map (dimm1_ddr2_dqs_n(3 downto 0), gnd(3 downto 0), vcc(0), open); dimm1_dq_notused_pads : iopadv generic map (tech => padtech, width => 32, level => SSTL18_II) port map (dimm1_ddr2_dq(31 downto 0), gnd, vcc(0), open); end generate; end generate; -- noddr : if (CFG_DDR2SP = 0) generate lock0 <= '1'; lock1 <= '1'; end generate; ---------------------------------------------------------------------- --- System ACE I/F Controller --------------------------------------- ---------------------------------------------------------------------- grace: if CFG_GRACECTRL = 1 generate grace0 : gracectrl generic map (hindex => 5, hirq => 5, haddr => 16#000#, hmask => 16#fff#, split => CFG_SPLIT) port map (rstn, clkm, clkace, ahbsi, ahbso(5), acei, aceo); end generate; nograce: if CFG_GRACECTRL = 0 generate aceo <= gracectrl_none; end generate nograce; sysace_mpa_pads : outpadv generic map (width => 7, tech => padtech) port map (sysace_mpa, aceo.addr); sysace_mpce_pad : outpad generic map (tech => padtech) port map (sysace_mpce, aceo.cen); sysace_mpd_pads : iopadv generic map (tech => padtech, width => 16) port map (sysace_mpd, aceo.do, aceo.doen, acei.di); sysace_mpoe_pad : outpad generic map (tech => padtech) port map (sysace_mpoe, aceo.oen); sysace_mpwe_pad : outpad generic map (tech => padtech) port map (sysace_mpwe, aceo.wen); sysace_mpirq_pad : inpad generic map (tech => padtech) port map (sysace_mpirq, acei.irq); ---------------------------------------------------------------------- --- AHB ROM --------------------------------------------------------- ---------------------------------------------------------------------- bpromgen : if CFG_AHBROMEN /= 0 generate brom : entity work.ahbrom generic map (hindex => 10, haddr => CFG_AHBRODDR, pipe => CFG_AHBROPIP) port map (rstn, clkm, ahbsi, ahbso(10)); end generate; ---------------------------------------------------------------------- --- APB Bridge and various periherals ------------------------------- ---------------------------------------------------------------------- apb0 : apbctrl -- AHB/APB bridge generic map (hindex => 4, haddr => CFG_APBADDR, nslaves => 16) port map (rstn, clkm, ahbsi, ahbso(4), apbi, apbo); ua1 : if CFG_UART1_ENABLE /= 0 generate uart1 : apbuart -- UART 1 generic map (pindex => 1, paddr => 1, pirq => 2, console => dbguart, fifosize => CFG_UART1_FIFO) port map (rstn, clkm, apbi, apbo(1), u1i, u1o); u1i.extclk <= '0'; end generate; noua1: if CFG_UART1_ENABLE = 0 generate u1o.txd <= '0'; u1o.rtsn <= '1'; end generate; ua1rx_pad : inpad generic map (tech => padtech) port map (uart1_rxd, u1i.rxd); ua1tx_pad : outpad generic map (tech => padtech) port map (uart1_txd, u1o.txd); ua1cts_pad : inpad generic map (tech => padtech) port map (uart1_cts_b, u1i.ctsn); ua1rts_pad : outpad generic map (tech => padtech) port map (uart1_rts_b, u1o.rtsn); irqctrl : if CFG_IRQ3_ENABLE /= 0 generate irqctrl0 : irqmp -- interrupt controller generic map (pindex => 2, paddr => 2, ncpu => NCPU) port map (rstn, clkm, apbi, apbo(2), irqo, irqi); end generate; irq3 : if CFG_IRQ3_ENABLE = 0 generate x : for i in 0 to NCPU-1 generate irqi(i).irl <= "0000"; end generate; apbo(2) <= apb_none; end generate; gpt : if CFG_GPT_ENABLE /= 0 generate timer0 : gptimer -- timer unit generic map (pindex => 3, paddr => 3, pirq => CFG_GPT_IRQ, sepirq => CFG_GPT_SEPIRQ, sbits => CFG_GPT_SW, ntimers => CFG_GPT_NTIM, nbits => CFG_GPT_TW) port map (rstn, clkm, apbi, apbo(3), gpti, open); gpti.dhalt <= dsuo.tstop; gpti.extclk <= '0'; end generate; nogpt : if CFG_GPT_ENABLE = 0 generate apbo(3) <= apb_none; end generate; svga : if CFG_SVGA_ENABLE /= 0 generate svga0 : svgactrl generic map(memtech => memtech, pindex => 14, paddr => 14, hindex => CFG_NCPU+CFG_AHB_UART+CFG_AHB_JTAG, clk0 => 40000, clk1 => 40000, clk2 => 25000, clk3 => 15385, burstlen => 6) port map(rstn, clkm, clkvga, apbi, apbo(14), vgao, ahbmi, ahbmo(CFG_NCPU+CFG_AHB_UART+CFG_AHB_JTAG), clk_sel); dvi0 : svga2ch7301c generic map (tech => fabtech, idf => 2) port map (lclk, rstraw, clk_sel, vgao, clkvga, clk25, clk40, clk65, clkvga, clk25, clk40, clk65, clkvga_p, clkvga_n, vgalock, lcd_datal, lcd_hsyncl, lcd_vsyncl, lcd_del); i2cdvi : i2cmst generic map (pindex => 6, paddr => 6, pmask => 16#FFF#, pirq => 6, filter => I2C_FILTER) port map (rstn, clkm, apbi, apbo(6), dvi_i2ci, dvi_i2co); end generate; novga : if CFG_SVGA_ENABLE = 0 generate apbo(14) <= apb_none; apbo(6) <= apb_none; lcd_datal <= (others => '0'); clkvga_p <= '0'; clkvga_n <= '0'; lcd_hsyncl <= '0'; lcd_vsyncl <= '0'; lcd_del <= '0'; dvi_i2co.scloen <= '1'; dvi_i2co.sdaoen <= '1'; end generate; dvi_d_pad : outpadv generic map (width => 12, tech => padtech) port map (dvi_d, lcd_datal); dvi_xclk_p_pad : outpad generic map (tech => padtech) port map (dvi_xclk_p, clkvga_p); dvi_xclk_n_pad : outpad generic map (tech => padtech) port map (dvi_xclk_n, clkvga_n); dvi_h_pad : outpad generic map (tech => padtech) port map (dvi_h, lcd_hsyncl); dvi_v_pad : outpad generic map (tech => padtech) port map (dvi_v, lcd_vsyncl); dvi_de_pad : outpad generic map (tech => padtech) port map (dvi_de, lcd_del); dvi_reset_b_pad : outpad generic map (tech => padtech) port map (dvi_reset_b, rstn); iic_scl_dvi_pad : iopad generic map (tech => padtech) port map (iic_scl_dvi, dvi_i2co.scl, dvi_i2co.scloen, dvi_i2ci.scl); iic_sda_dvi_pad : iopad generic map (tech => padtech) port map (iic_sda_dvi, dvi_i2co.sda, dvi_i2co.sdaoen, dvi_i2ci.sda); gpio0 : if CFG_GRGPIO_ENABLE /= 0 generate -- GPIO unit grgpio0: grgpio generic map(pindex => 8, paddr => 8, imask => CFG_GRGPIO_IMASK, nbits => CFG_GRGPIO_WIDTH) port map(rst => rstn, clk => clkm, apbi => apbi, apbo => apbo(8), gpioi => gpioi, gpioo => gpioo); end generate; nogpio0: if CFG_GRGPIO_ENABLE = 0 generate gpioo.oen <= (others => '1'); gpioo.val <= (others => '0'); gpioo.dout <= (others => '1'); end generate; dbg_led_pads : iopadvv generic map (tech => padtech, width => 3, level => cmos, voltage => x33v) port map (dbg_led(2 downto 0), gpioo.dout(2 downto 0), gpioo.oen(2 downto 0), gpioi.din(2 downto 0)); dvi_gpio_pad : iopad generic map (tech => padtech) port map (dvi_gpio1, gpioo.dout(4), gpioo.oen(4), gpioi.din(4)); iic_therm_b_pad : inpad generic map (tech => padtech) port map (iic_therm_b, gpioi.din(9)); iic_irq_b_pad : inpad generic map (tech => padtech) port map (iic_irq_b, gpioi.din(10)); iic_alert_b_pad : inpad generic map (tech => padtech) port map (iic_alert_b, gpioi.din(11)); sbr_pwg_rsm_rstj_pad : iopad generic map (tech => padtech, level => cmos, voltage => x25v) port map (sbr_pwg_rsm_rstj, gpioo.dout(7), gpioo.oen(7), gpioi.din(7)); sbr_nmi_r_pad : inpad generic map (tech => padtech) port map (sbr_nmi_r, gpioi.din(6)); sbr_intr_r_pad : inpad generic map (tech => padtech, level => cmos, voltage => x25v) port map (sbr_intr_r, gpioi.din(5)); sbr_ide_rst_b_pad : iopad generic map (tech => padtech) port map (sbr_ide_rst_b, gpioo.dout(8), gpioo.oen(8), gpioi.din(8)); i2cm: if CFG_I2C_ENABLE = 1 generate -- I2C master i2c0 : i2cmst generic map (pindex => 9, paddr => 9, pmask => 16#FFF#, pirq => 3, filter => I2C_FILTER) port map (rstn, clkm, apbi, apbo(9), i2ci, i2co); end generate; noi2cm: if CFG_I2C_ENABLE = 0 generate i2co.scloen <= '1'; i2co.sdaoen <= '1'; i2co.scl <= '0'; i2co.sda <= '0'; end generate; i2c_scl_pad : iopad generic map (tech => padtech) port map (fpga_scl, i2co.scl, i2co.scloen, i2ci.scl); i2c_sda_pad : iopad generic map (tech => padtech) port map (fpga_sda, i2co.sda, i2co.sdaoen, i2ci.sda); spic: if CFG_SPICTRL_ENABLE = 1 generate -- SPI controller spi1 : spictrl generic map (pindex => 10, paddr => 10, pmask => 16#fff#, pirq => 12, fdepth => CFG_SPICTRL_FIFO, slvselen => CFG_SPICTRL_SLVREG, slvselsz => CFG_SPICTRL_SLVS, odmode => 0, netlist => 0, syncram => CFG_SPICTRL_SYNCRAM, ft => CFG_SPICTRL_FT) port map (rstn, clkm, apbi, apbo(10), spii, spio, slvsel); spii.spisel <= '1'; -- Master only miso_pad : inpad generic map (tech => padtech) port map (spi_data_out, spii.miso); mosi_pad : outpad generic map (tech => padtech) port map (spi_data_in, spio.mosi); sck_pad : outpad generic map (tech => padtech) port map (spi_clk, spio.sck); slvsel_pad : outpad generic map (tech => padtech) port map (spi_data_cs_b, slvsel(0)); end generate spic; nospi: if CFG_SPICTRL_ENABLE = 0 generate miso_pad : inpad generic map (tech => padtech) port map (spi_data_out, spii.miso); mosi_pad : outpad generic map (tech => padtech) port map (spi_data_in, vcc(0)); sck_pad : outpad generic map (tech => padtech) port map (spi_clk, gnd(0)); slvsel_pad : outpad generic map (tech => padtech) port map (spi_data_cs_b, vcc(0)); end generate; ahbs : if CFG_AHBSTAT = 1 generate -- AHB status register ahbstat0 : ahbstat generic map (pindex => 15, paddr => 15, pirq => 7, nftslv => CFG_AHBSTATN) port map (rstn, clkm, ahbmi, ahbsi, stati, apbi, apbo(15)); end generate; ----------------------------------------------------------------------- --- ETHERNET --------------------------------------------------------- ----------------------------------------------------------------------- eth1 : if CFG_GRETH = 1 generate -- Gaisler ethernet MAC e1 : grethm generic map(hindex => NCPU+CFG_AHB_UART+CFG_AHB_JTAG+CFG_SVGA_ENABLE, pindex => 11, paddr => 11, pirq => 4, memtech => memtech, mdcscaler => CPU_FREQ/1000, enable_mdio => 1, fifosize => CFG_ETH_FIFO, nsync => 1, edcl => CFG_DSU_ETH, edclbufsz => CFG_ETH_BUF, macaddrh => CFG_ETH_ENM, macaddrl => CFG_ETH_ENL, phyrstadr => 7, ipaddrh => CFG_ETH_IPM, ipaddrl => CFG_ETH_IPL, giga => CFG_GRETH1G) port map( rst => rstn, clk => clkm, ahbmi => ahbmi, ahbmo => ahbmo(NCPU+CFG_AHB_UART+CFG_AHB_JTAG+CFG_SVGA_ENABLE), apbi => apbi, apbo => apbo(11), ethi => ethi, etho => etho); emdio_pad : iopad generic map (tech => padtech) port map (phy0_mdio, etho.mdio_o, etho.mdio_oe, ethi.mdio_i); etxc_pad : clkpad generic map (tech => padtech, arch => 2, level => cmos, voltage => x25v) port map (phy0_txclk, ethi.tx_clk); erxc_pad : clkpad generic map (tech => padtech, arch => 2, level => cmos, voltage => x25v) port map (phy0_rxclk, ethi.rx_clk); erxd_pad : inpadv generic map (tech => padtech, width => 4) port map (phy0_rxd, ethi.rxd(3 downto 0)); erxdv_pad : inpad generic map (tech => padtech) port map (phy0_rxctl_rxdv, ethi.rx_dv); erxer_pad : inpad generic map (tech => padtech) port map (phy0_rxer, ethi.rx_er); -- Collision detect and carrier sense are not connected on the -- board. ethi.rx_col <= '0'; ethi.rx_crs <= ethi.rx_dv; etxd_pad : outpadv generic map (tech => padtech, width => 4) port map (phy0_txd, etho.txd(3 downto 0)); etxen_pad : outpad generic map (tech => padtech) port map (phy0_txctl_txen, etho.tx_en); etxer_pad : outpad generic map (tech => padtech) port map (phy0_txer, etho.tx_er); emdc_pad : outpad generic map (tech => padtech) port map (phy0_mdc, etho.mdc); erst_pad : outpad generic map (tech => padtech) port map (phy0_reset, rstn); -- ethi.gtx_clk <= egtx_clk; end generate; ----------------------------------------------------------------------- --- PCI ------------------------------------------------------------ ---------------------------------------------------------------------- pp : if CFG_PCI /= 0 generate pci_mtf0 : if CFG_PCI = 2 generate -- master/target with fifo pci0 : pci_mtf generic map (memtech => memtech, hmstndx => NCPU+CFG_AHB_UART+CFG_AHB_JTAG+CFG_SVGA_ENABLE+CFG_GRETH, fifodepth => log2(CFG_PCIDEPTH), device_id => CFG_PCIDID, vendor_id => CFG_PCIVID, hslvndx => 7, pindex => 4, paddr => 4, haddr => 16#800#, hmask => 16#c00#, ioaddr => 16#400#, irq => 5, irqmask => 16#F#, nsync => 2, hostrst => 1) port map (rstn, clkm, pciclk, pcii, pcio, apbi, apbo(4), ahbmi, ahbmo(NCPU+CFG_AHB_UART+CFG_AHB_JTAG+CFG_SVGA_ENABLE+CFG_GRETH), ahbsi, ahbso(7)); end generate; pci_mtf1 : if CFG_PCI = 3 generate -- master/target with fifo and DMA dma : pcidma generic map (memtech => memtech, dmstndx => NCPU+CFG_AHB_UART+CFG_AHB_JTAG+CFG_SVGA_ENABLE+CFG_GRETH+1, dapbndx => 5, dapbaddr => 5, blength => blength, mstndx => NCPU+CFG_AHB_UART+CFG_AHB_JTAG+CFG_SVGA_ENABLE+CFG_GRETH, fifodepth => log2(fifodepth), device_id => CFG_PCIDID, vendor_id => CFG_PCIVID, slvndx => 7, apbndx => 4, apbaddr => 4, haddr => 16#800#, hmask => 16#c00#, ioaddr => 16#400#, irq => 5, irqmask => 16#F#, nsync => 2, hostrst => 1) port map (rstn, clkm, pciclk, pcii, pcio, apbo(5), ahbmo(NCPU+CFG_AHB_UART+CFG_AHB_JTAG+CFG_SVGA_ENABLE+CFG_GRETH+1), apbi, apbo(4), ahbmi, ahbmo(NCPU+CFG_AHB_UART+CFG_AHB_JTAG+CFG_SVGA_ENABLE+CFG_GRETH), ahbsi, ahbso(7)); end generate; pci_trc0 : if CFG_PCITBUFEN /= 0 generate -- PCI trace buffer pt0 : pcitrace generic map (depth => (6 + log2(CFG_PCITBUF/256)), memtech => memtech, pindex => 12, paddr => 16#100#, pmask => 16#f00#) port map (rstn, clkm, pciclk, pcii, apbi, apbo(12)); end generate; pcia0 : if CFG_PCI_ARB = 1 generate -- PCI arbiter pciarb0 : pciarb generic map (pindex => 13, paddr => 13, nb_agents => CFG_PCI_ARB_NGNT, apb_en => CFG_PCI_ARBAPB) port map (clk => pciclk, rst_n => pcii.rst, req_n => pci_arb_req, frame_n => pcii.frame, gnt_n => pci_arb_gnt, pclk => clkm, prst_n => rstn, apbi => apbi, apbo => apbo(13)); -- Internal connection of req(2) pci_arb_req(0 to 4) <= pci_arb_reql(0 to 1) & pci_reql & pci_arb_reql(3 to 4); pci_arb_req(5 to 7) <= (others => '1'); end generate; end generate; nopcia0: if CFG_PCI = 0 or CFG_PCI_ARB = 0 generate pci_arb_gnt <= (others => '1'); end generate; nopci_mtf: if CFG_PCI /= 2 and CFG_PCI /= 3 generate pcio <= pci_out_none; end generate; pgnt_pad : outpadv generic map (tech => padtech, width => 5, level => pci33) port map (pci_p_gnt_b, pci_arb_gnt(0 to 4)); preq_pad : inpadv generic map (tech => padtech, width => 5, level => pci33) port map (pci_p_req_b, pci_arb_reql); pcipads0 : pcipads -- PCI pads generic map (padtech => padtech, host => 2, int => 14, no66 => 1, onchipreqgnt => 1, drivereset => 1, constidsel => 1) port map (pci_rst => pci_p_rst_b, pci_gnt => pci_arb_gnt(2), pci_idsel => '0', --pci_fpga_idsel, pci_lock => pci_p_lock_b, pci_ad => pci_p_ad, pci_cbe => pci_p_cbe_b, pci_frame => pci_p_frame_b, pci_irdy => pci_p_irdy_b, pci_trdy => pci_p_trdy_b, pci_devsel => pci_p_devsel_b, pci_stop => pci_p_stop_b, pci_perr => pci_p_perr_b, pci_par => pci_p_par, pci_req => pci_reql, pci_serr => pci_p_serr_b, pci_host => pci_host, pci_66 => pci_66, pcii => pcii, pcio => pcio, pci_int => pci_intv); pci_intv <= pci_p_intd_b & pci_p_intc_b & pci_p_intb_b & pci_p_inta_b; pci_host <= '0'; -- Always host pci_66 <= '0'; ----------------------------------------------------------------------- --- SYSTEM MONITOR --------------------------------------------------- ----------------------------------------------------------------------- grsmon: if CFG_GRSYSMON = 1 generate sysm0 : grsysmon generic map (tech => fabtech, hindex => 8, hirq => 1, caddr => 16#003#, cmask => 16#fff#, saddr => 16#004#, smask => 16#ffe#, split => CFG_SPLIT, extconvst => 0, wrdalign => 1, INIT_40 => X"0000", INIT_41 => X"0000", INIT_42 => X"0800", INIT_43 => X"0000", INIT_44 => X"0000", INIT_45 => X"0000", INIT_46 => X"0000", INIT_47 => X"0000", INIT_48 => X"0000", INIT_49 => X"0000", INIT_4A => X"0000", INIT_4B => X"0000", INIT_4C => X"0000", INIT_4D => X"0000", INIT_4E => X"0000", INIT_4F => X"0000", INIT_50 => X"0000", INIT_51 => X"0000", INIT_52 => X"0000", INIT_53 => X"0000", INIT_54 => X"0000", INIT_55 => X"0000", INIT_56 => X"0000", INIT_57 => X"0000", SIM_MONITOR_FILE => "sysmon.txt") port map (rstn, clkm, ahbsi, ahbso(8), sysmoni, sysmono); sysmoni.convst <= '0'; sysmoni.convstclk <= '0'; sysmoni.vauxn <= (others => '0'); sysmoni.vauxp <= (others => '0'); -- sysmoni.vn <= test_mon_vn0_n; -- sysmoni.vp <= test_mon_vp0_p; end generate grsmon; ----------------------------------------------------------------------- --- AHB RAM ---------------------------------------------------------- ----------------------------------------------------------------------- ocram : if CFG_AHBRAMEN = 1 generate ahbram0 : ahbram generic map (hindex => 9, haddr => CFG_AHBRADDR, tech => CFG_MEMTECH, kbytes => CFG_AHBRSZ, pipe => CFG_AHBRPIPE) port map ( rstn, clkm, ahbsi, ahbso(9)); end generate; ----------------------------------------------------------------------- --- APB bridge with LOGAN -------------------------------------------- ----------------------------------------------------------------------- -- log: if CFG_LOGAN = 1 generate -- Logan is enabled by constant -- -- declared above -- apb0 : apbctrl -- AHB/APB bridge -- generic map (hindex => 11, haddr => 16#F00#, nslaves => 1) -- port map (rstn, clkm, ahbsi, ahbso(11), apbi1, apbo1); -- logan0 : logan -- Logic analyzer -- generic map (dbits => 64, depth => 4096, trigl => 2, usereg => 1, -- usequal => 0, pindex => 0, paddr => 0, pmask => 16#F00#, -- memtech => memtech) -- port map (rstn, clkm, pciclk, apbi1, apbo1(0), signals); -- signals(0) <= pcii.rst; -- signals(1) <= pcii.gnt; -- signals(2) <= pcii.idsel; -- signals(34 downto 3) <= pcii.ad; -- signals(38 downto 35) <= pcii.cbe; -- signals(39) <= pcii.frame; -- signals(40) <= pcii.irdy; -- signals(41) <= pcii.trdy; -- signals(42) <= pcii.devsel; -- signals(43) <= pcii.stop; -- signals(44) <= pcii.lock; -- signals(45) <= pcii.perr; -- signals(46) <= pcii.serr; -- signals(47) <= pcii.par; -- signals(48) <= pcii.host; -- signals(49) <= pcii.pci66; -- signals(53 downto 50) <= pcii.int; -- signals(58 downto 54) <= pci_arb_gnt(0 to 4); -- signals(63 downto 59) <= pci_arb_req(0 to 4); -- end generate log; nolog: if CFG_LOGAN /= 1 generate signals <= (others => '0'); end generate nolog; ----------------------------------------------------------------------- --- AHB DEBUG -------------------------------------------------------- ----------------------------------------------------------------------- -- dma0 : ahbdma -- generic map (hindex => CFG_NCPU+CFG_AHB_UART+CFG_GRETH+CFG_AHB_JTAG, -- pindex => 13, paddr => 13, dbuf => 6) -- port map (rstn, clkm, apbi, apbo(13), ahbmi, -- ahbmo(CFG_NCPU+CFG_AHB_UART+CFG_GRETH+CFG_AHB_JTAG)); -- at0 : ahbtrace -- generic map ( hindex => 7, ioaddr => 16#200#, iomask => 16#E00#, -- tech => memtech, irq => 0, kbytes => 8) -- port map ( rstn, clkm, ahbmi, ahbsi, ahbso(7)); ----------------------------------------------------------------------- --- Drive unused bus elements --------------------------------------- ----------------------------------------------------------------------- -- nam1 : for i in (NCPU+CFG_AHB_UART+CFG_ETH+CFG_AHB_ETH+CFG_AHB_JTAG) to NAHBMST-1 generate -- ahbmo(i) <= ahbm_none; -- end generate; -- nap0 : for i in 11 to NAPBSLV-1 generate apbo(i) <= apb_none; end generate; -- nah0 : for i in 8 to NAHBSLV-1 generate ahbso(i) <= ahbs_none; end generate; ----------------------------------------------------------------------- --- Boot message ---------------------------------------------------- ----------------------------------------------------------------------- -- pragma translate_off x : report_design generic map ( msg1 => system_table(XILINX_ML510), fabtech => tech_table(fabtech), memtech => tech_table(memtech), mdel => 1 ); -- pragma translate_on end;

gpl-2.0

8bce9f6dc6b440b040d0b761063a1433

0.577625

3.272525

false

marco-c/leon-nexys2

grlib-gpl-1.3.4-b4140/designs/leon3-gr-pci-xc2v3000/config.vhd

1

6,842

----------------------------------------------------------------------------- -- LEON3 Demonstration design test bench configuration -- Copyright (C) 2009 Aeroflex Gaisler ------------------------------------------------------------------------------ library techmap; use techmap.gencomp.all; package config is -- Technology and synthesis options constant CFG_FABTECH : integer := virtex2; constant CFG_MEMTECH : integer := virtex2; constant CFG_PADTECH : integer := virtex2; constant CFG_NOASYNC : integer := 0; constant CFG_SCAN : integer := 0; -- Clock generator constant CFG_CLKTECH : integer := virtex2; constant CFG_CLKMUL : integer := (4); constant CFG_CLKDIV : integer := (4); constant CFG_OCLKDIV : integer := 1; constant CFG_OCLKBDIV : integer := 0; constant CFG_OCLKCDIV : integer := 0; constant CFG_PCIDLL : integer := 0; constant CFG_PCISYSCLK: integer := 0; constant CFG_CLK_NOFB : integer := 0; -- LEON3 processor core constant CFG_LEON3 : integer := 1; constant CFG_NCPU : integer := (1); constant CFG_NWIN : integer := (8); constant CFG_V8 : integer := 2 + 4*0; constant CFG_MAC : integer := 0; constant CFG_BP : integer := 0; constant CFG_SVT : integer := 1; constant CFG_RSTADDR : integer := 16#00000#; constant CFG_LDDEL : integer := (1); constant CFG_NOTAG : integer := 0; constant CFG_NWP : integer := (2); constant CFG_PWD : integer := 0*2; constant CFG_FPU : integer := 0 + 16*0 + 32*0; constant CFG_GRFPUSH : integer := 0; constant CFG_ICEN : integer := 1; constant CFG_ISETS : integer := 2; constant CFG_ISETSZ : integer := 8; constant CFG_ILINE : integer := 8; constant CFG_IREPL : integer := 0; constant CFG_ILOCK : integer := 0; constant CFG_ILRAMEN : integer := 0; constant CFG_ILRAMADDR: integer := 16#8E#; constant CFG_ILRAMSZ : integer := 1; constant CFG_DCEN : integer := 1; constant CFG_DSETS : integer := 2; constant CFG_DSETSZ : integer := 4; constant CFG_DLINE : integer := 4; constant CFG_DREPL : integer := 0; constant CFG_DLOCK : integer := 0; constant CFG_DSNOOP : integer := 1 + 0 + 4*0; constant CFG_DFIXED : integer := 16#0#; constant CFG_DLRAMEN : integer := 0; constant CFG_DLRAMADDR: integer := 16#8F#; constant CFG_DLRAMSZ : integer := 1; constant CFG_MMUEN : integer := 1; constant CFG_ITLBNUM : integer := 8; constant CFG_DTLBNUM : integer := 8; constant CFG_TLB_TYPE : integer := 0 + 1*2; constant CFG_TLB_REP : integer := 0; constant CFG_MMU_PAGE : integer := 0; constant CFG_DSU : integer := 1; constant CFG_ITBSZ : integer := 2; constant CFG_ATBSZ : integer := 2; constant CFG_LEON3FT_EN : integer := 0; constant CFG_IUFT_EN : integer := 0; constant CFG_FPUFT_EN : integer := 0; constant CFG_RF_ERRINJ : integer := 0; constant CFG_CACHE_FT_EN : integer := 0; constant CFG_CACHE_ERRINJ : integer := 0; constant CFG_LEON3_NETLIST: integer := 0; constant CFG_DISAS : integer := 0 + 0; constant CFG_PCLOW : integer := 2; -- AMBA settings constant CFG_DEFMST : integer := (0); constant CFG_RROBIN : integer := 1; constant CFG_SPLIT : integer := 0; constant CFG_FPNPEN : integer := 0; constant CFG_AHBIO : integer := 16#FFF#; constant CFG_APBADDR : integer := 16#800#; constant CFG_AHB_MON : integer := 0; constant CFG_AHB_MONERR : integer := 0; constant CFG_AHB_MONWAR : integer := 0; constant CFG_AHB_DTRACE : integer := 0; -- DSU UART constant CFG_AHB_UART : integer := 1; -- JTAG based DSU interface constant CFG_AHB_JTAG : integer := 1; -- Ethernet DSU constant CFG_DSU_ETH : integer := 1 + 0 + 0; constant CFG_ETH_BUF : integer := 2; constant CFG_ETH_IPM : integer := 16#C0A8#; constant CFG_ETH_IPL : integer := 16#0034#; constant CFG_ETH_ENM : integer := 16#020000#; constant CFG_ETH_ENL : integer := 16#000006#; -- LEON2 memory controller constant CFG_MCTRL_LEON2 : integer := 1; constant CFG_MCTRL_RAM8BIT : integer := 0; constant CFG_MCTRL_RAM16BIT : integer := 0; constant CFG_MCTRL_5CS : integer := 0; constant CFG_MCTRL_SDEN : integer := 1; constant CFG_MCTRL_SEPBUS : integer := 0; constant CFG_MCTRL_INVCLK : integer := 0; constant CFG_MCTRL_SD64 : integer := 0; constant CFG_MCTRL_PAGE : integer := 1 + 0; -- AHB ROM constant CFG_AHBROMEN : integer := 0; constant CFG_AHBROPIP : integer := 0; constant CFG_AHBRODDR : integer := 16#000#; constant CFG_ROMADDR : integer := 16#000#; constant CFG_ROMMASK : integer := 16#E00# + 16#000#; -- AHB RAM constant CFG_AHBRAMEN : integer := 0; constant CFG_AHBRSZ : integer := 1; constant CFG_AHBRADDR : integer := 16#A00#; constant CFG_AHBRPIPE : integer := 0; -- Gaisler Ethernet core constant CFG_GRETH : integer := 1; constant CFG_GRETH1G : integer := 0; constant CFG_ETH_FIFO : integer := 32; -- PCI interface constant CFG_PCI : integer := 0; constant CFG_PCIVID : integer := 16#0#; constant CFG_PCIDID : integer := 16#0#; constant CFG_PCIDEPTH : integer := 8; constant CFG_PCI_MTF : integer := 1; -- PCI arbiter constant CFG_PCI_ARB : integer := 0; constant CFG_PCI_ARBAPB : integer := 0; constant CFG_PCI_ARB_NGNT : integer := 4; -- PCI trace buffer constant CFG_PCITBUFEN: integer := 0; constant CFG_PCITBUF : integer := 256; -- Spacewire interface constant CFG_SPW_EN : integer := 0; constant CFG_SPW_NUM : integer := 1; constant CFG_SPW_AHBFIFO : integer := 4; constant CFG_SPW_RXFIFO : integer := 16; constant CFG_SPW_RMAP : integer := 0; constant CFG_SPW_RMAPBUF : integer := 4; constant CFG_SPW_RMAPCRC : integer := 0; constant CFG_SPW_NETLIST : integer := 0; constant CFG_SPW_FT : integer := 0; constant CFG_SPW_GRSPW : integer := 2; constant CFG_SPW_RXUNAL : integer := 0; constant CFG_SPW_DMACHAN : integer := 1; constant CFG_SPW_PORTS : integer := 1; constant CFG_SPW_INPUT : integer := 2; constant CFG_SPW_OUTPUT : integer := 0; constant CFG_SPW_RTSAME : integer := 0; -- UART 1 constant CFG_UART1_ENABLE : integer := 1; constant CFG_UART1_FIFO : integer := 4; -- UART 2 constant CFG_UART2_ENABLE : integer := 1; constant CFG_UART2_FIFO : integer := 4; -- LEON3 interrupt controller constant CFG_IRQ3_ENABLE : integer := 1; constant CFG_IRQ3_NSEC : integer := 0; -- Modular timer constant CFG_GPT_ENABLE : integer := 1; constant CFG_GPT_NTIM : integer := (2); constant CFG_GPT_SW : integer := (8); constant CFG_GPT_TW : integer := (32); constant CFG_GPT_IRQ : integer := (8); constant CFG_GPT_SEPIRQ : integer := 1; constant CFG_GPT_WDOGEN : integer := 0; constant CFG_GPT_WDOG : integer := 16#0#; -- GPIO port constant CFG_GRGPIO_ENABLE : integer := 1; constant CFG_GRGPIO_IMASK : integer := 16#00FE#; constant CFG_GRGPIO_WIDTH : integer := (16); -- GRLIB debugging constant CFG_DUART : integer := 0; end;

gpl-2.0

4ab635ae78549d1763696474c8b9d6f5

0.645718

3.593487

false

marco-c/leon-nexys2

grlib-gpl-1.3.4-b4140/lib/techmap/inferred/ddr_phy_inferred.vhd

1

16,449

------------------------------------------------------------------------------ -- This file is a part of the GRLIB VHDL IP LIBRARY -- Copyright (C) 2003 - 2008, Gaisler Research -- Copyright (C) 2008 - 2013, Aeroflex Gaisler -- -- This program is free software; you can redistribute it and/or modify -- it under the terms of the GNU General Public License as published by -- the Free Software Foundation; either version 2 of the License, or -- (at your option) any later version. -- -- This program is distributed in the hope that it will be useful, -- but WITHOUT ANY WARRANTY; without even the implied warranty of -- MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the -- GNU General Public License for more details. -- -- You should have received a copy of the GNU General Public License -- along with this program; if not, write to the Free Software -- Foundation, Inc., 59 Temple Place, Suite 330, Boston, MA 02111-1307 USA ----------------------------------------------------------------------------- -- Entity: generic_ddr_phy -- File: ddr_phy_inferred.vhd -- Author: Nils-Johan Wessman - Gaisler Research -- Modified: Magnus Hjorth - Aeroflex Gaisler -- Description: Generic DDR PHY (simulation only) ------------------------------------------------------------------------------ --################################################################################### -- Generic DDR1 PHY --################################################################################### library ieee; use ieee.std_logic_1164.all; library techmap; use techmap.gencomp.all; library grlib; use grlib.stdlib.all; entity generic_ddr_phy_wo_pads is generic (MHz : integer := 100; rstdelay : integer := 200; dbits : integer := 16; clk_mul : integer := 2 ; clk_div : integer := 2; rskew : integer := 0; mobile : integer := 0; abits: integer := 14; nclk: integer := 3; ncs: integer := 2); port( rst : in std_ulogic; clk : in std_logic; -- input clock clkout : out std_ulogic; -- system clock clk0r : in std_ulogic; lock : out std_ulogic; -- DCM locked ddr_clk : out std_logic_vector(nclk-1 downto 0); ddr_clkb : out std_logic_vector(nclk-1 downto 0); ddr_clk_fb_out : out std_logic; ddr_clk_fb: in std_logic; ddr_cke : out std_logic_vector(ncs-1 downto 0); ddr_csb : out std_logic_vector(ncs-1 downto 0); ddr_web : out std_ulogic; -- ddr write enable ddr_rasb : out std_ulogic; -- ddr ras ddr_casb : out std_ulogic; -- ddr cas ddr_dm : out std_logic_vector (dbits/8-1 downto 0); -- ddr dm ddr_dqs_in : in std_logic_vector (dbits/8-1 downto 0); -- ddr dqs ddr_dqs_out : out std_logic_vector (dbits/8-1 downto 0); -- ddr dqs ddr_dqs_oen : out std_logic_vector (dbits/8-1 downto 0); -- ddr dqs ddr_ad : out std_logic_vector (abits-1 downto 0); -- ddr address ddr_ba : out std_logic_vector (1 downto 0); -- ddr bank address ddr_dq_in : in std_logic_vector (dbits-1 downto 0); -- ddr data ddr_dq_out : out std_logic_vector (dbits-1 downto 0); -- ddr data ddr_dq_oen : out std_logic_vector (dbits-1 downto 0); -- ddr data addr : in std_logic_vector (abits-1 downto 0); -- data mask ba : in std_logic_vector ( 1 downto 0); -- data mask dqin : out std_logic_vector (dbits*2-1 downto 0); -- ddr input data dqout : in std_logic_vector (dbits*2-1 downto 0); -- ddr input data dm : in std_logic_vector (dbits/4-1 downto 0); -- data mask oen : in std_ulogic; dqs : in std_ulogic; dqsoen : in std_ulogic; rasn : in std_ulogic; casn : in std_ulogic; wen : in std_ulogic; csn : in std_logic_vector(ncs-1 downto 0); cke : in std_logic_vector(ncs-1 downto 0); ck : in std_logic_vector(nclk-1 downto 0); moben : in std_logic -- Mobile DDR enable ); end; architecture rtl of generic_ddr_phy_wo_pads is component sim_pll generic ( clkmul: integer := 1; clkdiv1: integer := 1; clkphase1: integer := 0; clkdiv2: integer := 1; clkphase2: integer := 0; clkdiv3: integer := 1; clkphase3: integer := 0; clkdiv4: integer := 1; clkphase4: integer := 0; minfreq: integer := 0; maxfreq: integer := 10000000 ); port ( i: in std_logic; o1: out std_logic; o2: out std_logic; o3: out std_logic; o4: out std_logic; lock: out std_logic; rst: in std_logic ); end component; constant freq_khz: integer := (1000*MHz*clk_mul)/(clk_div); constant freq_mhz: integer := freq_khz / 1000; constant td90: time := 250 us * (1.0 / real(freq_khz)); signal vcc, gnd : std_logic; -- VCC and GND signal clk0, clk90r, clk180r, clk270r : std_ulogic; signal lockl,vlockl,locked: std_ulogic; signal dqs90,dqs90n: std_logic_vector(dbits/8-1 downto 0); signal ckl: std_logic_vector(nclk-1 downto 0); signal ckel: std_logic_vector(ncs-1 downto 0); begin vcc <= '1'; gnd <= '0'; ----------------------------------------------------------------------------------- -- Clock generation (Only for simulation) ----------------------------------------------------------------------------------- -- Phase shifted clocks --pragma translate_off -- To avoid jitter problems when using ddr without sync regs we shift -- 10 degrees extra. pll0: sim_pll generic map ( clkmul => clk_mul, clkdiv1 => clk_div, clkphase1 => 0-10+360, clkdiv2 => clk_div, clkphase2 => 90-10, clkdiv3 => clk_div, clkphase3 => 180-10, clkdiv4 => clk_div, clkphase4 => 270-10, minfreq => MHz*1000, maxfreq => MHz*1000 ) port map ( i => clk, o1 => clk0, o2 => clk90r, o3 => clk180r, o4 => clk270r, lock => lockl, rst => rst); --pragma translate_on -- Clock to DDR controller clkout <= clk0; ddr_clk_fb_out <= '0'; ----------------------------------------------------------------------------------- -- Lock delay ----------------------------------------------------------------------------------- rdel : if rstdelay /= 0 generate rcnt : process (clk0r, lockl, rst) variable cnt : std_logic_vector(15 downto 0); variable vlock, co : std_ulogic; begin if rising_edge(clk0r) then co := cnt(15); vlockl <= vlock; if lockl = '0' then cnt := conv_std_logic_vector(rstdelay*FREQ_MHZ, 16); vlock := '0'; else if vlock = '0' then cnt := cnt -1; vlock := cnt(15) and not co; end if; end if; end if; if lockl = '0' or rst='0' then vlock := '0'; end if; end process; end generate; locked <= lockl when rstdelay = 0 else vlockl; lock <= locked; ----------------------------------------------------------------------------- -- DQS shifting ----------------------------------------------------------------------------- -- pragma translate_off dqs90 <= transport ddr_dqs_in after td90; dqs90n <= not dqs90; -- pragma translate_on ----------------------------------------------------------------------------- -- Data path ----------------------------------------------------------------------------- -- For mobile SDRAM, force Cke high during reset and reset-delay, -- For regular SDRAM, force Cke low -- also disable outgoing clock until we have achieved PLL lock mobgen: if mobile > 1 generate ckel <= cke or (cke'range => not locked); end generate; nmobgen: if mobile < 2 generate ckel <= cke and (cke'range => locked); end generate; ckl <= ck and (ck'range => lockl); dp0: ddrphy_datapath generic map ( regtech => inferred, dbits => dbits, abits => abits, bankbits => 2, ncs => ncs, nclk => nclk, resync => 2 ) port map ( clk0 => clk0r, clk90 => clk90r, clk180 => clk180r, clk270 => clk270r, clkresync => gnd, ddr_clk => ddr_clk, ddr_clkb => ddr_clkb, ddr_dq_in => ddr_dq_in, ddr_dq_out => ddr_dq_out, ddr_dq_oen => ddr_dq_oen, ddr_dqs_in90 => dqs90, ddr_dqs_in90n => dqs90n, ddr_dqs_out => ddr_dqs_out, ddr_dqs_oen => ddr_dqs_oen, ddr_cke => ddr_cke, ddr_csb => ddr_csb, ddr_web => ddr_web, ddr_rasb => ddr_rasb, ddr_casb => ddr_casb, ddr_ad => ddr_ad, ddr_ba => ddr_ba, ddr_dm => ddr_dm, ddr_odt => open, dqin => dqin, dqout => dqout, addr => addr, ba => ba, dm => dm, oen => oen, rasn => rasn, casn => casn, wen => wen, csn => csn, cke => ckel, odt => (others => '0'), dqs_en => dqs, dqs_oen => dqsoen, ddrclk_en => ckl ); end; --################################################################################### -- Generic DDR2 PHY --################################################################################### library ieee; use ieee.std_logic_1164.all; library techmap; use techmap.gencomp.all; library grlib; use grlib.stdlib.all; entity generic_ddr2_phy_wo_pads is generic (MHz : integer := 100; rstdelay : integer := 200; dbits : integer := 16; clk_mul : integer := 2 ; clk_div : integer := 2; rskew : integer := 0; eightbanks: integer := 0; abits: integer := 14; cben: integer := 0; chkbits: integer := 8; nclk: integer := 3; ncs: integer := 2); port( rst : in std_ulogic; clk : in std_logic; -- input clock clkout : out std_ulogic; -- system clock clk0r : in std_ulogic; -- system clock returned lock : out std_ulogic; -- DCM locked ddr_clk : out std_logic_vector(nclk-1 downto 0); ddr_clkb : out std_logic_vector(nclk-1 downto 0); ddr_clk_fb_out : out std_logic; ddr_clk_fb : in std_logic; ddr_cke : out std_logic_vector(ncs-1 downto 0); ddr_csb : out std_logic_vector(ncs-1 downto 0); ddr_web : out std_ulogic; -- ddr write enable ddr_rasb : out std_ulogic; -- ddr ras ddr_casb : out std_ulogic; -- ddr cas ddr_dm : out std_logic_vector (dbits/8-1 downto 0); -- ddr dm ddr_dqs_in : in std_logic_vector (dbits/8-1 downto 0); -- ddr dqs ddr_dqs_out : out std_logic_vector (dbits/8-1 downto 0); -- ddr dqs ddr_dqs_oen : out std_logic_vector (dbits/8-1 downto 0); -- ddr dqs ddr_ad : out std_logic_vector (abits-1 downto 0); -- ddr address ddr_ba : out std_logic_vector (1+eightbanks downto 0); -- ddr bank address ddr_dq_in : in std_logic_vector (dbits-1 downto 0); -- ddr data ddr_dq_out : out std_logic_vector (dbits-1 downto 0); -- ddr data ddr_dq_oen : out std_logic_vector (dbits-1 downto 0); -- ddr data ddr_odt : out std_logic_vector(ncs-1 downto 0); -- ddr odt addr : in std_logic_vector (abits-1 downto 0); -- data mask ba : in std_logic_vector (2 downto 0); -- data mask dqin : out std_logic_vector (dbits*2-1 downto 0); -- ddr input data dqout : in std_logic_vector (dbits*2-1 downto 0); -- ddr input data dm : in std_logic_vector (dbits/4-1 downto 0); -- data mask oen : in std_ulogic; dqs : in std_ulogic; dqsoen : in std_ulogic; rasn : in std_ulogic; casn : in std_ulogic; wen : in std_ulogic; csn : in std_logic_vector(ncs-1 downto 0); cke : in std_logic_vector(ncs-1 downto 0); ck : in std_logic_vector(2 downto 0); odt : in std_logic_vector(1 downto 0) ); end; architecture rtl of generic_ddr2_phy_wo_pads is component sim_pll generic ( clkmul: integer := 1; clkdiv1: integer := 1; clkphase1: integer := 0; clkdiv2: integer := 1; clkphase2: integer := 0; clkdiv3: integer := 1; clkphase3: integer := 0; clkdiv4: integer := 1; clkphase4: integer := 0; minfreq: integer := 0; maxfreq: integer := 10000000 ); port ( i: in std_logic; o1: out std_logic; o2: out std_logic; o3: out std_logic; o4: out std_logic; lock: out std_logic; rst: in std_logic ); end component; constant freq_khz: integer := (1000*MHz*clk_mul)/(clk_div); constant freq_mhz: integer := freq_khz / 1000; constant td90: time := 250 us * (1.0 / real(freq_khz)); signal vcc, gnd : std_logic; -- VCC and GND signal clk0, clk90r, clk180r, clk270r : std_ulogic; signal lockl,vlockl,locked: std_ulogic; signal dqs90,dqs90n: std_logic_vector(dbits/8-1 downto 0); begin vcc <= '1'; gnd <= '0'; ----------------------------------------------------------------------------------- -- Clock generation (Only for simulation) ----------------------------------------------------------------------------------- -- Phase shifted clocks --pragma translate_off -- To avoid jitter problems when using ddr2 without sync regs we shift -- 10 degrees extra. pll0: sim_pll generic map ( clkmul => clk_mul, clkdiv1 => clk_div, clkphase1 => 0-10+360, clkdiv2 => clk_div, clkphase2 => 90-10, clkdiv3 => clk_div, clkphase3 => 180-10, clkdiv4 => clk_div, clkphase4 => 270-10, minfreq => MHz*1000, maxfreq => MHz*1000 ) port map ( i => clk, o1 => clk0, o2 => clk90r, o3 => clk180r, o4 => clk270r, lock => lockl, rst => rst); --pragma translate_on -- Clock to DDR controller clkout <= clk0; ddr_clk_fb_out <= '0'; ----------------------------------------------------------------------------------- -- Lock delay ----------------------------------------------------------------------------------- rdel : if rstdelay /= 0 generate rcnt : process (clk0r, lockl) variable cnt : std_logic_vector(15 downto 0); variable vlock, co : std_ulogic; begin if rising_edge(clk0r) then co := cnt(15); vlockl <= vlock; if lockl = '0' then cnt := conv_std_logic_vector(rstdelay*FREQ_MHZ, 16); vlock := '0'; else if vlock = '0' then cnt := cnt -1; vlock := cnt(15) and not co; end if; end if; end if; if lockl = '0' then vlock := '0'; end if; end process; end generate; locked <= lockl when rstdelay = 0 else vlockl; lock <= locked; ----------------------------------------------------------------------------- -- DQS shifting ----------------------------------------------------------------------------- -- pragma translate_off dqs90 <= transport ddr_dqs_in after td90; dqs90n <= not dqs90; -- pragma translate_on ----------------------------------------------------------------------------- -- Data path ----------------------------------------------------------------------------- dp0: ddrphy_datapath generic map ( regtech => inferred, dbits => dbits, abits => abits, bankbits => 2+EIGHTBANKS, ncs => ncs, nclk => nclk, resync => 0 ) port map ( clk0 => clk0r, clk90 => clk90r, clk180 => clk180r, clk270 => clk270r, clkresync => gnd, ddr_clk => ddr_clk, ddr_clkb => ddr_clkb, ddr_dq_in => ddr_dq_in, ddr_dq_out => ddr_dq_out, ddr_dq_oen => ddr_dq_oen, ddr_dqs_in90 => dqs90, ddr_dqs_in90n => dqs90n, ddr_dqs_out => ddr_dqs_out, ddr_dqs_oen => ddr_dqs_oen, ddr_cke => ddr_cke, ddr_csb => ddr_csb, ddr_web => ddr_web, ddr_rasb => ddr_rasb, ddr_casb => ddr_casb, ddr_ad => ddr_ad, ddr_ba => ddr_ba, ddr_dm => ddr_dm, ddr_odt => ddr_odt, dqin => dqin, dqout => dqout, addr => addr, ba => ba(1+eightbanks downto 0), dm => dm, oen => oen, rasn => rasn, casn => casn, wen => wen, csn => csn, cke => cke, odt => odt, dqs_en => dqs, dqs_oen => dqsoen, ddrclk_en => ck(nclk-1 downto 0) ); end;

gpl-2.0

1328c5422d4e0923954c845bb1fc363e

0.500334

3.732471

false

marco-c/leon-nexys2

grlib-gpl-1.3.4-b4140/designs/leon3-digilent-nexys4/project_1/project_1.srcs/sources_1/imports/sources/bftLib/core_transform.vhdl

1

3,812

--///////////////////////////////////////////////////////////////////////// --// Copyright (c) 2008 Xilinx, Inc. All rights reserved. --// --// XILINX CONFIDENTIAL PROPERTY --// This document contains proprietary information which is --// protected by copyright. All rights are reserved. This notice --// refers to original work by Xilinx, Inc. which may be derivitive --// of other work distributed under license of the authors. In the --// case of derivitive work, nothing in this notice overrides the --// original author's license agreeement. Where applicable, the --// original license agreement is included in it's original --// unmodified form immediately below this header. --// --// Xilinx, Inc. --// XILINX IS PROVIDING THIS DESIGN, CODE, OR INFORMATION "AS IS" AS A --// COURTESY TO YOU. BY PROVIDING THIS DESIGN, CODE, OR INFORMATION AS --// ONE POSSIBLE IMPLEMENTATION OF THIS FEATURE, APPLICATION OR --// STANDARD, XILINX IS MAKING NO REPRESENTATION THAT THIS IMPLEMENTATION --// IS FREE FROM ANY CLAIMS OF INFRINGEMENT, AND YOU ARE RESPONSIBLE --// FOR OBTAINING ANY RIGHTS YOU MAY REQUIRE FOR YOUR IMPLEMENTATION. --// XILINX EXPRESSLY DISCLAIMS ANY WARRANTY WHATSOEVER WITH RESPECT TO --// THE ADEQUACY OF THE IMPLEMENTATION, INCLUDING BUT NOT LIMITED TO --// ANY WARRANTIES OR REPRESENTATIONS THAT THIS IMPLEMENTATION IS FREE --// FROM CLAIMS OF INFRINGEMENT, IMPLIED WARRANTIES OF MERCHANTABILITY --// AND FITNESS FOR A PARTICULAR PURPOSE. --// --///////////////////////////////////////////////////////////////////////// library IEEE; use IEEE.STD_LOGIC_1164.all; use IEEE.STD_LOGIC_ARITH.all; use IEEE.STD_LOGIC_SIGNED.all; entity coreTransform is generic ( DATA_WIDTH : integer := 16 ); port ( clk : in std_logic; x, xStep, u : in std_logic_vector (DATA_WIDTH-1 downto 0); xOut, xOutStep : out std_logic_vector (DATA_WIDTH-1 downto 0) ); --synthesis packing can change the resutls greatly --setting up some attributes to force the mapping I want --attribute register_duplication : string; --attribute register_duplication of coreTransform : entity is "yes"; --attribute register_balancing : string; --attribute register_balancing of coreTransform : entity is "yes"; ----force a mapping to DSP48s attribute use_dsp48 : string; attribute use_dsp48 of coreTransform : entity is "yes"; ----turn off resource sharing ----with resource sharing off this will map to two dsp48s. With it on, a dsp48 and some logic. attribute resource_sharing : string; attribute resource_sharing of coreTransform : entity is "no"; end entity coreTransform; architecture aCT of coreTransform is signal xReg, xStepReg, uReg : std_logic_vector (DATA_WIDTH-1 downto 0); signal xOutReg, xOutStepReg, xOutRegTemp, xOutStepRegTemp: std_logic_vector (2*DATA_WIDTH -1 downto 0); begin process (clk) begin if rising_edge(clk) then xStepReg <= xStep; uReg <= u; xReg <= x; end if; end process; process (clk) begin if rising_edge(clk) then xOutReg <= SXT(xReg, 2*DATA_WIDTH) + uReg*xStepReg; xOutStepReg <= SXT(xReg, 2*DATA_WIDTH) - uReg*xStepReg; end if; end process; -- xOut <= xOutReg(DATA_WIDTH-1 downto 0) xor xOutReg(2*DATA_WIDTH-1 downto DATA_WIDTH); -- xOutStep <= xOutStepReg(DATA_WIDTH-1 downto 0) xor xOutStepReg(2*DATA_WIDTH-1 downto DATA_WIDTH); xOut <= xOutReg(DATA_WIDTH-1 downto 0) xor xOutReg(2*DATA_WIDTH-1 downto DATA_WIDTH); xOutStep <= xOutStepReg(DATA_WIDTH-1 downto 0) xor xOutStepReg(2*DATA_WIDTH-1 downto DATA_WIDTH); end architecture aCT;

gpl-2.0

930514b635ec052c7721e634aec449ab

0.650839

3.92585

false

marco-c/leon-nexys2

grlib-gpl-1.3.4-b4140/lib/gaisler/ddr/ddrphy_wrap.vhd

1

57,878

------------------------------------------------------------------------------ -- This file is a part of the GRLIB VHDL IP LIBRARY -- Copyright (C) 2003 - 2008, Gaisler Research -- Copyright (C) 2008 - 2013, Aeroflex Gaisler -- -- This program is free software; you can redistribute it and/or modify -- it under the terms of the GNU General Public License as published by -- the Free Software Foundation; either version 2 of the License, or -- (at your option) any later version. -- -- This program is distributed in the hope that it will be useful, -- but WITHOUT ANY WARRANTY; without even the implied warranty of -- MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the -- GNU General Public License for more details. -- -- You should have received a copy of the GNU General Public License -- along with this program; if not, write to the Free Software -- Foundation, Inc., 59 Temple Place, Suite 330, Boston, MA 02111-1307 USA ----------------------------------------------------------------------------- -- Entity: ddr_phy -- File: ddr_phy.vhd -- Author: Jiri Gaisler, Gaisler Research -- Description: Wrapper entities for techmap ddrphy/ddr2phy ------------------------------------------------------------------------------ library ieee; use ieee.std_logic_1164.all; library grlib; use grlib.stdlib.all; library techmap; use techmap.gencomp.all; library gaisler; use gaisler.ddrpkg.all; ------------------------------------------------------------------ -- DDR1 PHY wrapper ------------------------------------------------------- ------------------------------------------------------------------ entity ddrphy_wrap is generic (tech : integer := virtex2; MHz : integer := 100; rstdelay : integer := 200; dbits : integer := 16; clk_mul : integer := 2 ; clk_div : integer := 2; rskew : integer :=0; mobile : integer := 0; scantest : integer := 0; phyiconf : integer := 0); port ( rst : in std_ulogic; clk : in std_logic; -- input clock clkout : out std_ulogic; -- system clock clkoutret : in std_ulogic; clkread : out std_ulogic; -- read clock lock : out std_ulogic; -- DCM locked ddr_clk : out std_logic_vector(2 downto 0); ddr_clkb : out std_logic_vector(2 downto 0); ddr_clk_fb_out : out std_logic; ddr_clk_fb : in std_logic; ddr_cke : out std_logic_vector(1 downto 0); ddr_csb : out std_logic_vector(1 downto 0); ddr_web : out std_ulogic; -- ddr write enable ddr_rasb : out std_ulogic; -- ddr ras ddr_casb : out std_ulogic; -- ddr cas ddr_dm : out std_logic_vector (dbits/8-1 downto 0); -- ddr dm ddr_dqs : inout std_logic_vector (dbits/8-1 downto 0); -- ddr dqs ddr_ad : out std_logic_vector (13 downto 0); -- ddr address ddr_ba : out std_logic_vector (1 downto 0); -- ddr bank address ddr_dq : inout std_logic_vector (dbits-1 downto 0); -- ddr data sdi : out ddrctrl_in_type; sdo : in ddrctrl_out_type; testen : in std_ulogic; testrst : in std_ulogic; scanen : in std_ulogic; testoen : in std_ulogic); end; architecture rtl of ddrphy_wrap is begin ddr_phy0 : ddrphy generic map (tech => tech, MHz => MHz, rstdelay => rstdelay -- reduce 200 us start-up delay during simulation -- pragma translate_off / 200 -- pragma translate_on , dbits => dbits, clk_mul => clk_mul, clk_div => clk_div, rskew => rskew, mobile => mobile, scantest => scantest, phyiconf => phyiconf) port map ( rst, clk, clkout, clkoutret, clkread, lock, ddr_clk, ddr_clkb, ddr_clk_fb_out, ddr_clk_fb, ddr_cke, ddr_csb, ddr_web, ddr_rasb, ddr_casb, ddr_dm, ddr_dqs, ddr_ad, ddr_ba, ddr_dq, sdo.address(13 downto 0), sdo.ba(1 downto 0), sdi.data(dbits*2-1 downto 0), sdo.data(dbits*2-1 downto 0), sdo.dqm(dbits/4-1 downto 0), sdo.bdrive, sdo.bdrive, sdo.qdrive, sdo.rasn, sdo.casn, sdo.sdwen, sdo.sdcsn, sdo.sdcke, sdo.sdck(2 downto 0), sdo.moben, sdi.datavalid, testen, testrst, scanen, testoen); drvdata : if dbits < 64 generate sdi.data(127 downto dbits*2) <= (others => '0'); end generate; sdi.cb <= (others => '0'); sdi.regrdata <= (others => '0'); end; library ieee; use ieee.std_logic_1164.all; library grlib; use grlib.stdlib.all; library techmap; use techmap.gencomp.all; library gaisler; use gaisler.ddrpkg.all; ------------------------------------------------------------------ -- DDR1 PHY with checkbits merged on data bus -------------------- ------------------------------------------------------------------ entity ddrphy_wrap_cbd is generic (tech : integer := virtex2; MHz : integer := 100; rstdelay : integer := 200; dbits : integer := 16; chkbits: integer := 0; padbits : integer := 0; clk_mul : integer := 2 ; clk_div : integer := 2; rskew : integer :=0; mobile : integer := 0; abits: integer := 14; nclk: integer := 3; ncs: integer := 2; scantest: integer := 0; phyiconf : integer := 0); port ( rst : in std_ulogic; clk : in std_logic; -- input clock clkout : out std_ulogic; -- system clock clkoutret : in std_ulogic; -- system clock return clkread : out std_ulogic; lock : out std_ulogic; -- DCM locked ddr_clk : out std_logic_vector(nclk-1 downto 0); ddr_clkb : out std_logic_vector(nclk-1 downto 0); ddr_clk_fb_out : out std_logic; ddr_clk_fb : in std_logic; ddr_cke : out std_logic_vector(ncs-1 downto 0); ddr_csb : out std_logic_vector(ncs-1 downto 0); ddr_web : out std_ulogic; -- ddr write enable ddr_rasb : out std_ulogic; -- ddr ras ddr_casb : out std_ulogic; -- ddr cas ddr_dm : out std_logic_vector ((dbits+padbits+chkbits)/8-1 downto 0); -- ddr dm ddr_dqs : inout std_logic_vector ((dbits+padbits+chkbits)/8-1 downto 0); -- ddr dqs ddr_ad : out std_logic_vector (abits-1 downto 0); -- ddr address ddr_ba : out std_logic_vector (1 downto 0); -- ddr bank address ddr_dq : inout std_logic_vector (dbits+padbits+chkbits-1 downto 0); -- ddr data sdi : out ddrctrl_in_type; sdo : in ddrctrl_out_type; testen : in std_ulogic; testrst : in std_ulogic; scanen : in std_ulogic; testoen : in std_ulogic); end; architecture rtl of ddrphy_wrap_cbd is function ddr_widthconv(x: std_logic_vector; ow: integer) return std_logic_vector is variable r: std_logic_vector(2*ow-1 downto 0); constant iw: integer := x'length/2; begin r := (others => '0'); if iw <= ow then r(iw+ow-1 downto ow) := x(2*iw-1 downto iw); r(iw-1 downto 0) := x(iw-1 downto 0); else r := x(iw+ow-1 downto iw) & x(ow-1 downto 0); end if; return r; end; function sdr_widthconv(x: std_logic_vector; ow: integer) return std_logic_vector is variable r: std_logic_vector(ow-1 downto 0); constant iw: integer := x'length; variable xd : std_logic_vector(iw-1 downto 0); begin r := (others => '0'); xd := x; if iw >= ow then r := xd(ow-1 downto 0); else r(iw-1 downto 0) := xd; end if; return r; end; function ddrmerge(a,b: std_logic_vector) return std_logic_vector is constant aw: integer := a'length/2; constant bw: integer := b'length/2; begin return a(2*aw-1 downto aw) & b(2*bw-1 downto bw) & a(aw-1 downto 0) & b(bw-1 downto 0); end; signal dqin: std_logic_vector(2*(chkbits+dbits+padbits)-1 downto 0); signal dqout: std_logic_vector(2*(chkbits+dbits+padbits)-1 downto 0); signal dqm: std_logic_vector((chkbits+dbits+padbits)/4-1 downto 0); signal cal_en: std_logic_vector((chkbits+dbits+padbits)/8-1 downto 0); signal cal_inc: std_logic_vector((chkbits+dbits+padbits)/8-1 downto 0); signal odt,csn,cke: std_logic_vector(ncs-1 downto 0); signal sdck: std_logic_vector(nclk-1 downto 0); begin -- Merge checkbit and data buses comb: process(sdo,dqin) variable dq: std_logic_vector(2*dbits-1 downto 0); variable dqpad: std_logic_vector(2*(dbits+padbits)-1 downto 0); variable cb: std_logic_vector(dbits-1 downto 0); variable cbpad: std_logic_vector(2*chkbits downto 0); -- Extra bit to handle chkbits=0 variable dqcb: std_logic_vector(2*(dbits+padbits+chkbits)-1 downto 0); variable dm: std_logic_vector(dbits/4-1 downto 0); variable dmpad: std_logic_vector((dbits+padbits)/4-1 downto 0); variable cbdm: std_logic_vector(dbits/8-1 downto 0); variable cbdmpad: std_logic_vector(chkbits/4 downto 0); variable dqcbdm: std_logic_vector((dbits+padbits+chkbits)/4-1 downto 0); variable vcsn,vcke: std_logic_vector(ncs-1 downto 0); variable vsdck: std_logic_vector(nclk-1 downto 0); begin dq := sdo.data(2*dbits-1 downto 0); dqpad := ddr_widthconv(dq, dbits+padbits ); if chkbits > 0 then cb := sdo.cb(dbits-1 downto 0); cbpad := '0' & ddr_widthconv(cb, chkbits); dqcb := ddrmerge(cbpad(2*chkbits-1 downto 0), dqpad); else dqcb := dqpad; end if; dqout <= dqcb; dqcb := dqin; if chkbits > 0 then cbpad := '0' & dqin(2*(chkbits+dbits+padbits)-1 downto 2*(dbits+padbits)+chkbits) & dqin(chkbits+dbits+padbits-1 downto dbits+padbits); cb := ddr_widthconv(cbpad(2*chkbits-1 downto 0), dbits/2); else cb := (others => '0'); end if; dq := dqcb(2*dbits+chkbits+padbits-1 downto dbits+chkbits+padbits) & dqcb(dbits-1 downto 0); sdi.cb(dbits-1 downto 0) <= cb; sdi.data(2*dbits-1 downto 0) <= dq; if sdi.cb'length > dbits then sdi.cb(sdi.cb'length-1 downto dbits) <= (others => '0'); end if; if sdi.data'length > 2*dbits then sdi.data(sdi.data'length-1 downto 2*dbits) <= (others => '0'); end if; dm := sdo.dqm(dbits/4-1 downto 0); dmpad := ddr_widthconv(dm, (dbits+padbits)/8); if chkbits > 0 then cbdm := sdo.cbdqm(dbits/8-1 downto 0); cbdmpad := '0' & ddr_widthconv(cbdm(dbits/8-1 downto 0), chkbits/8); dqcbdm := ddrmerge(cbdmpad(chkbits/4-1 downto 0), dmpad); else dqcbdm := dmpad; end if; dqm <= dqcbdm; cal_en <= sdr_widthconv(sdo.cbcal_en (dbits/16-1 downto 0) & sdo.cal_en (dbits/8-1 downto 0), (dbits+padbits+chkbits)/8 ); cal_inc <= sdr_widthconv(sdo.cbcal_inc(dbits/16-1 downto 0) & sdo.cal_inc(dbits/8-1 downto 0), (dbits+padbits+chkbits)/8 ); vcsn := (others => '1'); for x in 0 to ncs-1 loop if x<2 then vcsn(x) := sdo.sdcsn(x); end if; vcke(x) := sdo.sdcke(x mod 2); end loop; for x in 0 to nclk-1 loop vsdck(x) := sdo.sdck(x mod 2); end loop; csn <= vcsn; cke <= vcke; sdck <= vsdck; end process; -- Phy instantiation ddr_phy0 : ddrphy generic map (tech => tech, MHz => MHz, rstdelay => rstdelay -- reduce 200 us start-up delay during simulation -- pragma translate_off / 200 -- pragma translate_on , dbits => dbits+padbits+chkbits,clk_mul => clk_mul, clk_div => clk_div, rskew => rskew, mobile => mobile, abits => abits, nclk => nclk, ncs => ncs, scantest => scantest, phyiconf => phyiconf) port map ( rst, clk, clkout, clkoutret, clkread, lock, ddr_clk, ddr_clkb, ddr_clk_fb_out, ddr_clk_fb, ddr_cke, ddr_csb, ddr_web, ddr_rasb, ddr_casb, ddr_dm, ddr_dqs, ddr_ad, ddr_ba, ddr_dq, sdo.address(abits-1 downto 0), sdo.ba(1 downto 0), dqin, dqout, dqm, sdo.bdrive, sdo.bdrive, sdo.qdrive, sdo.rasn, sdo.casn, sdo.sdwen, csn, cke, sdck, sdo.moben,sdi.datavalid, testen,testrst,scanen,testoen); sdi.regrdata <= (others => '0'); end; library ieee; use ieee.std_logic_1164.all; library grlib; use grlib.stdlib.all; library techmap; use techmap.gencomp.all; library gaisler; use gaisler.ddrpkg.all; ------------------------------------------------------------------ -- DDR1 PHY with checkbits merged on data bus, pads not in phy -- ------------------------------------------------------------------ entity ddrphy_wrap_cbd_wo_pads is generic (tech : integer := virtex2; MHz : integer := 100; rstdelay : integer := 200; dbits : integer := 16; padbits : integer := 0; clk_mul : integer := 2 ; clk_div : integer := 2; rskew : integer := 0; mobile : integer := 0; abits : integer := 14; nclk : integer := 3; ncs : integer := 2; chkbits : integer := 0; scantest : integer := 0; phyiconf : integer := 0); port ( rst : in std_ulogic; clk : in std_logic; -- input clock clkout : out std_ulogic; -- system clock clkoutret : in std_ulogic; -- system clock return lock : out std_ulogic; -- DCM locked ddr_clk : out std_logic_vector(nclk-1 downto 0); ddr_clkb : out std_logic_vector(nclk-1 downto 0); ddr_clk_fb_out : out std_logic; ddr_clk_fb : in std_logic; ddr_cke : out std_logic_vector(ncs-1 downto 0); ddr_csb : out std_logic_vector(ncs-1 downto 0); ddr_web : out std_ulogic; -- ddr write enable ddr_rasb : out std_ulogic; -- ddr ras ddr_casb : out std_ulogic; -- ddr cas ddr_dm : out std_logic_vector ((dbits+padbits+chkbits)/8-1 downto 0); -- ddr dm ddr_dqs_in : in std_logic_vector ((dbits+padbits+chkbits)/8-1 downto 0); -- ddr dqs ddr_dqs_out : out std_logic_vector ((dbits+padbits+chkbits)/8-1 downto 0); -- ddr dqs ddr_dqs_oen : out std_logic_vector ((dbits+padbits+chkbits)/8-1 downto 0); -- ddr dqs ddr_ad : out std_logic_vector (abits-1 downto 0); -- ddr address ddr_ba : out std_logic_vector (1 downto 0); -- ddr bank address ddr_dq_in : in std_logic_vector (dbits+padbits+chkbits-1 downto 0); -- ddr data ddr_dq_out : out std_logic_vector (dbits+padbits+chkbits-1 downto 0); -- ddr data ddr_dq_oen : out std_logic_vector (dbits+padbits+chkbits-1 downto 0); sdi : out ddrctrl_in_type; sdo : in ddrctrl_out_type; testen : in std_ulogic; testrst : in std_ulogic; scanen : in std_ulogic; testoen : in std_ulogic); end; architecture rtl of ddrphy_wrap_cbd_wo_pads is function ddr_widthconv(x: std_logic_vector; ow: integer) return std_logic_vector is variable r: std_logic_vector(2*ow-1 downto 0); constant iw: integer := x'length/2; begin r := (others => '0'); if iw <= ow then r(iw+ow-1 downto ow) := x(2*iw-1 downto iw); r(iw-1 downto 0) := x(iw-1 downto 0); else r := x(iw+ow-1 downto iw) & x(ow-1 downto 0); end if; return r; end; function sdr_widthconv(x: std_logic_vector; ow: integer) return std_logic_vector is variable r: std_logic_vector(ow-1 downto 0); constant iw: integer := x'length; variable xd : std_logic_vector(iw-1 downto 0); begin r := (others => '0'); xd := x; if iw >= ow then r := xd(ow-1 downto 0); else r(iw-1 downto 0) := xd; end if; return r; end; function ddrmerge(a,b: std_logic_vector) return std_logic_vector is constant aw: integer := a'length/2; constant bw: integer := b'length/2; begin return a(2*aw-1 downto aw) & b(2*bw-1 downto bw) & a(aw-1 downto 0) & b(bw-1 downto 0); end; signal dqin: std_logic_vector(2*(chkbits+dbits+padbits)-1 downto 0); signal dqout: std_logic_vector(2*(chkbits+dbits+padbits)-1 downto 0); signal dqm: std_logic_vector((chkbits+dbits+padbits)/4-1 downto 0); signal odt,csn,cke: std_logic_vector(ncs-1 downto 0); signal sdck: std_logic_vector(nclk-1 downto 0); signal gnd : std_logic_vector(chkbits*2-1 downto 0); begin gnd <= (others => '0'); -- Merge checkbit and data buses comb: process(sdo,dqin) variable dq: std_logic_vector(2*dbits-1 downto 0); variable dqpad: std_logic_vector(2*(dbits+padbits)-1 downto 0); variable cb: std_logic_vector(dbits-1 downto 0); variable cbpad: std_logic_vector(2*chkbits downto 0); -- Extra bit to handle chkbits=0 variable dqcb: std_logic_vector(2*(dbits+padbits+chkbits)-1 downto 0); variable dm: std_logic_vector(dbits/4-1 downto 0); variable dmpad: std_logic_vector((dbits+padbits)/4-1 downto 0); variable cbdm: std_logic_vector(dbits/8-1 downto 0); variable cbdmpad: std_logic_vector(chkbits/4 downto 0); variable dqcbdm: std_logic_vector((dbits+padbits+chkbits)/4-1 downto 0); variable vcsn,vodt,vcke: std_logic_vector(ncs-1 downto 0); variable vsdck: std_logic_vector(nclk-1 downto 0); begin dq := sdo.data(2*dbits-1 downto 0); dqpad := ddr_widthconv(dq, dbits+padbits ); if chkbits > 0 then cb := sdo.cb(dbits-1 downto 0); cbpad := '0' & ddr_widthconv(cb, chkbits); dqcb := ddrmerge(cbpad(2*chkbits-1 downto 0), dqpad); else dqcb := dqpad; end if; dqout <= dqcb; dqcb := dqin; if chkbits > 0 then cbpad := '0' & dqin(2*(chkbits+dbits+padbits)-1 downto 2*(dbits+padbits)+chkbits) & dqin(chkbits+dbits+padbits-1 downto dbits+padbits); cb := ddr_widthconv(cbpad(2*chkbits-1 downto 0), dbits/2); else cb := (others => '0'); end if; dq := dqcb(2*dbits+chkbits+padbits-1 downto dbits+chkbits+padbits) & dqcb(dbits-1 downto 0); sdi.cb(dbits-1 downto 0) <= cb; sdi.data(2*dbits-1 downto 0) <= dq; if sdi.cb'length > dbits then sdi.cb(sdi.cb'length-1 downto dbits) <= (others => '0'); end if; if sdi.data'length > 2*dbits then sdi.data(sdi.data'length-1 downto 2*dbits) <= (others => '0'); end if; dm := sdo.dqm(dbits/4-1 downto 0); dmpad := ddr_widthconv(dm, (dbits+padbits)/8); if chkbits > 0 then cbdm := sdo.cbdqm(dbits/8-1 downto 0); cbdmpad := '0' & ddr_widthconv(cbdm(dbits/8-1 downto 0), chkbits/8); dqcbdm := ddrmerge(cbdmpad(chkbits/4-1 downto 0), dmpad); else dqcbdm := dmpad; end if; dqm <= dqcbdm; vcsn := (others => '1'); for x in 0 to ncs-1 loop if x<2 then vcsn(x) := sdo.sdcsn(x); end if; vodt(x) := sdo.odt(x mod 2); vcke(x) := sdo.sdcke(x mod 2); end loop; for x in 0 to nclk-1 loop vsdck(x) := sdo.sdck(x mod 2); end loop; csn <= vcsn; cke <= vcke; sdck <= vsdck; end process; -- Phy instantiation ddr_phy0 : ddrphy_wo_pads generic map ( tech => tech, MHz => MHz, rstdelay => rstdelay -- reduce 200 us start-up delay during simulation -- pragma translate_off / 200 -- pragma translate_on , dbits => dbits+padbits+chkbits, clk_mul => clk_mul, clk_div => clk_div, rskew => rskew, abits => abits, nclk => nclk, ncs => ncs, mobile => mobile, scantest => scantest, phyiconf => phyiconf) port map ( rst => rst, clk => clk, clkout => clkout, clkoutret => clkoutret, lock => lock, ddr_clk => ddr_clk, ddr_clkb => ddr_clkb, ddr_clk_fb_out => ddr_clk_fb_out, ddr_clk_fb => ddr_clk_fb, ddr_cke => ddr_cke, ddr_csb => ddr_csb, ddr_web => ddr_web, ddr_rasb => ddr_rasb, ddr_casb => ddr_casb, ddr_dm => ddr_dm, ddr_dqs_in => ddr_dqs_in, ddr_dqs_out => ddr_dqs_out, ddr_dqs_oen => ddr_dqs_oen, ddr_ad => ddr_ad, ddr_ba => ddr_ba, ddr_dq_in => ddr_dq_in, ddr_dq_out => ddr_dq_out, ddr_dq_oen => ddr_dq_oen, addr => sdo.address(abits-1 downto 0), ba => sdo.ba(1 downto 0), dqin => dqin, dqout => dqout, dm => dqm, oen => sdo.bdrive, dqs => sdo.bdrive, dqsoen => sdo.qdrive, rasn => sdo.rasn, casn => sdo.casn, wen => sdo.sdwen, csn => csn, cke => cke, ck => sdck, moben => sdo.moben, dqvalid => sdi.datavalid, testen => testen, testrst => testrst, scanen => scanen, testoen => testoen ); sdi.regrdata <= (others => '0'); end; library ieee; use ieee.std_logic_1164.all; library grlib; use grlib.stdlib.all; library techmap; use techmap.gencomp.all; library gaisler; use gaisler.ddrpkg.all; ------------------------------------------------------------------ -- DDR2 PHY wrapper ----------------------------------------------- ------------------------------------------------------------------ ------------------------------------------------------------------------------- -- There are three variants of the PHY wrapper depending on pads/checkbits: -- 1. ddr2phy_wrap: -- This provides pads and outputs checkbits on separate vectors -- 2. ddr2phy_wrap_cbd: -- This provides pads and merges checkbits+data on same vector -- 3. ddr2phy_wrap_cbd_wo_pads: -- This does not provide pads and merges checkbits+data on same vectors -- -- Variants (1),(3) can not be used when ddr2phy_builtin_pads(tech)=1 ------------------------------------------------------------------------------- entity ddr2phy_wrap is generic (tech : integer := virtex2; MHz : integer := 100; rstdelay : integer := 200; dbits : integer := 16; padbits : integer := 0; clk_mul : integer := 2 ; clk_div : integer := 2; ddelayb0 : integer := 0; ddelayb1 : integer := 0; ddelayb2 : integer := 0; ddelayb3 : integer := 0; ddelayb4 : integer := 0; ddelayb5 : integer := 0; ddelayb6 : integer := 0; ddelayb7 : integer := 0; cbdelayb0 : integer := 0; cbdelayb1: integer := 0; cbdelayb2: integer := 0; cbdelayb3 : integer := 0; numidelctrl : integer := 4; norefclk : integer := 0; odten : integer := 0; rskew : integer := 0; eightbanks : integer range 0 to 1 := 0; dqsse : integer range 0 to 1 := 0; abits : integer := 14; nclk : integer := 3; ncs : integer := 2; cben : integer := 0; chkbits : integer := 8; ctrl2en : integer := 0; resync : integer := 0; custombits: integer := 8; scantest : integer := 0); port ( rst : in std_ulogic; clk : in std_logic; -- input clock clkref200 : in std_logic; -- input 200MHz clock clkout : out std_ulogic; -- system clock clkoutret : in std_ulogic; -- system clock return clkresync : in std_ulogic; -- resync clock (if resync/=0) lock : out std_ulogic; -- DCM locked ddr_clk : out std_logic_vector(nclk-1 downto 0); ddr_clkb : out std_logic_vector(nclk-1 downto 0); ddr_clk_fb_out : out std_logic; ddr_clk_fb : in std_logic; ddr_cke : out std_logic_vector(ncs-1 downto 0); ddr_csb : out std_logic_vector(ncs-1 downto 0); ddr_web : out std_ulogic; -- ddr write enable ddr_rasb : out std_ulogic; -- ddr ras ddr_casb : out std_ulogic; -- ddr cas ddr_dm : out std_logic_vector ((dbits+padbits)/8-1 downto 0); -- ddr dm ddr_dqs : inout std_logic_vector ((dbits+padbits)/8-1 downto 0); -- ddr dqs ddr_dqsn : inout std_logic_vector ((dbits+padbits)/8-1 downto 0); -- ddr dqs ddr_ad : out std_logic_vector (abits-1 downto 0); -- ddr address ddr_ba : out std_logic_vector (1+eightbanks downto 0); -- ddr bank address ddr_dq : inout std_logic_vector ((dbits+padbits)-1 downto 0); -- ddr data ddr_odt : out std_logic_vector(ncs-1 downto 0); ddr_cbdm : out std_logic_vector(chkbits/8-1 downto 0); ddr_cbdqs : inout std_logic_vector(chkbits/8-1 downto 0); ddr_cbdqsn : inout std_logic_vector(chkbits/8-1 downto 0); ddr_cbdq : inout std_logic_vector(chkbits-1 downto 0); ddr_web2 : out std_ulogic; -- ddr write enable ddr_rasb2 : out std_ulogic; -- ddr ras ddr_casb2 : out std_ulogic; -- ddr cas ddr_ad2 : out std_logic_vector (abits-1 downto 0); -- ddr address ddr_ba2 : out std_logic_vector (1+eightbanks downto 0); -- ddr bank address sdi : out ddrctrl_in_type; sdo : in ddrctrl_out_type; customclk : in std_ulogic; customdin : in std_logic_vector(custombits-1 downto 0); customdout : out std_logic_vector(custombits-1 downto 0); testen : in std_ulogic; testrst : in std_ulogic; scanen : in std_ulogic; testoen : in std_ulogic ); end; architecture rtl of ddr2phy_wrap is signal lddr_clk,lddr_clkb: std_logic_vector(nclk-1 downto 0); signal lddr_clk_fb_out,lddr_clk_fb: std_ulogic; signal lddr_cke,lddr_csb,lddr_odt: std_logic_vector(ncs-1 downto 0); signal lddr_web,lddr_rasb,lddr_casb: std_ulogic; signal lddr_dm,lddr_dqs_in,lddr_dqs_out,lddr_dqs_oen: std_logic_vector((dbits+padbits+chkbits)/8-1 downto 0); signal lddr_ad: std_logic_vector(abits-1 downto 0); signal lddr_ba: std_logic_vector(1+eightbanks downto 0); signal lddr_dq_in,lddr_dq_out,lddr_dq_oen: std_logic_vector(dbits+padbits+chkbits-1 downto 0); begin -- Instantiate PHY without pads via other wrapper w0: ddr2phy_wrap_cbd_wo_pads generic map (tech,MHz,rstdelay,dbits,padbits,clk_mul,clk_div, ddelayb0,ddelayb1,ddelayb2,ddelayb3,ddelayb4,ddelayb5,ddelayb6,ddelayb7, cbdelayb0,cbdelayb1,cbdelayb2,cbdelayb3, numidelctrl,norefclk,odten,rskew, eightbanks,dqsse,abits,nclk,ncs,chkbits,resync,custombits,scantest) port map ( rst,clk,clkref200,clkout,clkoutret,clkresync,lock, lddr_clk,lddr_clkb,lddr_clk_fb_out,lddr_clk_fb, lddr_cke,lddr_csb,lddr_web,lddr_rasb,lddr_casb,lddr_dm, lddr_dqs_in,lddr_dqs_out,lddr_dqs_oen, lddr_ad,lddr_ba,lddr_dq_in,lddr_dq_out,lddr_dq_oen, lddr_odt, sdi,sdo,customclk,customdin,customdout,testen,testrst,scanen,testoen); -- Instantiate pads for control signals and data bus p0: ddr2pads generic map (tech,dbits+padbits,eightbanks,dqsse,abits,nclk,ncs,ctrl2en) port map ( ddr_clk,ddr_clkb,ddr_clk_fb_out,ddr_clk_fb, ddr_cke,ddr_csb,ddr_web,ddr_rasb,ddr_casb, ddr_dm,ddr_dqs,ddr_dqsn,ddr_ad,ddr_ba,ddr_dq,ddr_odt, ddr_web2,ddr_rasb2,ddr_casb2,ddr_ad2,ddr_ba2, lddr_clk,lddr_clkb,lddr_clk_fb_out,lddr_clk_fb, lddr_cke,lddr_csb,lddr_web,lddr_rasb,lddr_casb, lddr_dm(dbits/8+padbits/8-1 downto 0), lddr_dqs_in(dbits/8+padbits/8-1 downto 0), lddr_dqs_out(dbits/8+padbits/8-1 downto 0), lddr_dqs_oen(dbits/8+padbits/8-1 downto 0), lddr_ad,lddr_ba, lddr_dq_in(dbits+padbits-1 downto 0), lddr_dq_out(dbits+padbits-1 downto 0), lddr_dq_oen(dbits+padbits-1 downto 0), lddr_odt); -- Instantiate pads for checkbit bus cbdqpad: iopadvv generic map (tech => tech, slew => 1, level => sstl18_ii, width => chkbits) port map (pad => ddr_cbdq, i => lddr_dq_out(dbits+padbits+chkbits-1 downto dbits+padbits), en => lddr_dq_oen(dbits+padbits+chkbits-1 downto dbits+padbits), o => lddr_dq_in(dbits+padbits+chkbits-1 downto dbits+padbits)); cbdqmpad: outpadv generic map (tech => tech, slew => 1, level => sstl18_i, width => chkbits/8) port map (pad => ddr_cbdm, i => lddr_dm(dbits/8+padbits/8+chkbits/8-1 downto dbits/8+padbits/8)); cbdqspad: iopad_dsvv generic map (tech => tech, slew => 1, level => sstl18_ii, width => chkbits/8) port map (padp => ddr_cbdqs, padn => ddr_cbdqsn, i => lddr_dqs_out(dbits/8+padbits/8+chkbits/8-1 downto dbits/8+padbits/8), en => lddr_dqs_oen(dbits/8+padbits/8+chkbits/8-1 downto dbits/8+padbits/8), o => lddr_dqs_in(dbits/8+padbits/8+chkbits/8-1 downto dbits/8+padbits/8)); end; library ieee; use ieee.std_logic_1164.all; library grlib; use grlib.stdlib.all; library techmap; use techmap.gencomp.all; library gaisler; use gaisler.ddrpkg.all; ------------------------------------------------------------------ -- DDR2 PHY with checkbits merged on data bus -------------------- ------------------------------------------------------------------ entity ddr2phy_wrap_cbd is generic (tech : integer := virtex2; MHz : integer := 100; rstdelay : integer := 200; dbits : integer := 16; padbits : integer := 0; clk_mul : integer := 2 ; clk_div : integer := 2; ddelayb0 : integer := 0; ddelayb1 : integer := 0; ddelayb2 : integer := 0; ddelayb3 : integer := 0; ddelayb4 : integer := 0; ddelayb5 : integer := 0; ddelayb6 : integer := 0; ddelayb7 : integer := 0; cbdelayb0 : integer := 0; cbdelayb1: integer := 0; cbdelayb2: integer := 0; cbdelayb3 : integer := 0; numidelctrl : integer := 4; norefclk : integer := 0; odten : integer := 0; rskew : integer := 0; eightbanks : integer range 0 to 1 := 0; dqsse : integer range 0 to 1 := 0; abits : integer := 14; nclk : integer := 3; ncs : integer := 2; chkbits : integer := 0; ctrl2en : integer := 0; resync : integer := 0; custombits: integer := 8; extraio : integer := 0; scantest : integer := 0); port ( rst : in std_ulogic; clk : in std_logic; -- input clock clkref200 : in std_logic; -- input 200MHz clock clkout : out std_ulogic; -- system clock clkoutret : in std_ulogic; -- system clock return clkresync : in std_ulogic; lock : out std_ulogic; -- DCM locked ddr_clk : out std_logic_vector(nclk-1 downto 0); ddr_clkb : out std_logic_vector(nclk-1 downto 0); ddr_clk_fb_out : out std_logic; ddr_clk_fb : in std_logic; ddr_cke : out std_logic_vector(ncs-1 downto 0); ddr_csb : out std_logic_vector(ncs-1 downto 0); ddr_web : out std_ulogic; -- ddr write enable ddr_rasb : out std_ulogic; -- ddr ras ddr_casb : out std_ulogic; -- ddr cas ddr_dm : out std_logic_vector ((dbits+padbits+chkbits)/8-1 downto 0); -- ddr dm ddr_dqs : inout std_logic_vector (extraio+(dbits+padbits+chkbits)/8-1 downto 0); -- ddr dqs ddr_dqsn : inout std_logic_vector ((dbits+padbits+chkbits)/8-1 downto 0); -- ddr dqs ddr_ad : out std_logic_vector (abits-1 downto 0); -- ddr address ddr_ba : out std_logic_vector (1+eightbanks downto 0); -- ddr bank address ddr_dq : inout std_logic_vector (dbits+padbits+chkbits-1 downto 0); -- ddr data ddr_odt : out std_logic_vector(ncs-1 downto 0); ddr_web2 : out std_ulogic; -- ddr write enable ddr_rasb2 : out std_ulogic; -- ddr ras ddr_casb2 : out std_ulogic; -- ddr cas ddr_ad2 : out std_logic_vector (abits-1 downto 0); -- ddr address ddr_ba2 : out std_logic_vector (1+eightbanks downto 0); -- ddr bank address sdi : out ddrctrl_in_type; sdo : in ddrctrl_out_type; customclk : in std_ulogic; customdin : in std_logic_vector(custombits-1 downto 0); customdout : out std_logic_vector(custombits-1 downto 0); testen : in std_ulogic; testrst : in std_ulogic; scanen : in std_ulogic; testoen : in std_ulogic); end; architecture rtl of ddr2phy_wrap_cbd is function ddr_widthconv(x: std_logic_vector; ow: integer) return std_logic_vector is variable r: std_logic_vector(2*ow-1 downto 0); constant iw: integer := x'length/2; begin r := (others => '0'); if iw <= ow then r(iw+ow-1 downto ow) := x(2*iw-1 downto iw); r(iw-1 downto 0) := x(iw-1 downto 0); else r := x(iw+ow-1 downto iw) & x(ow-1 downto 0); end if; return r; end; function sdr_widthconv(x: std_logic_vector; ow: integer) return std_logic_vector is variable r: std_logic_vector(ow-1 downto 0); constant iw: integer := x'length; variable xd : std_logic_vector(iw-1 downto 0); begin r := (others => '0'); xd := x; if iw >= ow then r := xd(ow-1 downto 0); else r(iw-1 downto 0) := xd; end if; return r; end; function ddrmerge(a,b: std_logic_vector) return std_logic_vector is constant aw: integer := a'length/2; constant bw: integer := b'length/2; begin return a(2*aw-1 downto aw) & b(2*bw-1 downto bw) & a(aw-1 downto 0) & b(bw-1 downto 0); end; type int_array is array (natural range <>) of integer; constant delays: int_array(0 to 7) := (ddelayb0,ddelayb1,ddelayb2,ddelayb3, ddelayb4,ddelayb5,ddelayb6,ddelayb7); constant cbdelays: int_array(0 to 11) := (cbdelayb0,cbdelayb1,cbdelayb2,cbdelayb3,0,0,0,0,0,0,0,0); constant cbddelays: int_array(0 to 11) := delays(0 to (dbits+padbits)/8-1) & cbdelays(0 to 11-(dbits+padbits)/8); signal dqin: std_logic_vector(2*(chkbits+dbits+padbits)-1 downto 0); signal dqout: std_logic_vector(2*(chkbits+dbits+padbits)-1 downto 0); signal dqm: std_logic_vector((chkbits+dbits+padbits)/4-1 downto 0); signal cal_en: std_logic_vector((chkbits+dbits+padbits)/8-1 downto 0); signal cal_inc: std_logic_vector((chkbits+dbits+padbits)/8-1 downto 0); signal odt,csn,cke: std_logic_vector(ncs-1 downto 0); begin -- Merge checkbit and data buses comb: process(sdo,dqin) variable dq: std_logic_vector(2*dbits-1 downto 0); variable dqpad: std_logic_vector(2*(dbits+padbits)-1 downto 0); variable cb: std_logic_vector(dbits-1 downto 0); variable cbpad: std_logic_vector(2*chkbits downto 0); -- Extra bit to handle chkbits=0 variable dqcb: std_logic_vector(2*(dbits+padbits+chkbits)-1 downto 0); variable dm: std_logic_vector(dbits/4-1 downto 0); variable dmpad: std_logic_vector((dbits+padbits)/4-1 downto 0); variable cbdm: std_logic_vector(dbits/8-1 downto 0); variable cbdmpad: std_logic_vector(chkbits/4 downto 0); variable dqcbdm: std_logic_vector((dbits+padbits+chkbits)/4-1 downto 0); variable vcsn,vodt,vcke: std_logic_vector(ncs-1 downto 0); begin dq := sdo.data(2*dbits-1 downto 0); dqpad := ddr_widthconv(dq, dbits+padbits ); if chkbits > 0 then cb := sdo.cb(dbits-1 downto 0); cbpad := '0' & ddr_widthconv(cb, chkbits); dqcb := ddrmerge(cbpad(2*chkbits-1 downto 0), dqpad); else dqcb := dqpad; end if; dqout <= dqcb; dqcb := dqin; if chkbits > 0 then cbpad := '0' & dqin(2*(chkbits+dbits+padbits)-1 downto 2*(dbits+padbits)+chkbits) & dqin(chkbits+dbits+padbits-1 downto dbits+padbits); cb := ddr_widthconv(cbpad(2*chkbits-1 downto 0), dbits/2); else cb := (others => '0'); end if; dq := dqcb(2*dbits+chkbits+padbits-1 downto dbits+chkbits+padbits) & dqcb(dbits-1 downto 0); sdi.cb(dbits-1 downto 0) <= cb; sdi.data(2*dbits-1 downto 0) <= dq; if sdi.cb'length > dbits then sdi.cb(sdi.cb'length-1 downto dbits) <= (others => '0'); end if; if sdi.data'length > 2*dbits then sdi.data(sdi.data'length-1 downto 2*dbits) <= (others => '0'); end if; dm := sdo.dqm(dbits/4-1 downto 0); dmpad := ddr_widthconv(dm, (dbits+padbits)/8); if chkbits > 0 then cbdm := sdo.cbdqm(dbits/8-1 downto 0); cbdmpad := '0' & ddr_widthconv(cbdm(dbits/8-1 downto 0), chkbits/8); dqcbdm := ddrmerge(cbdmpad(chkbits/4-1 downto 0), dmpad); else dqcbdm := dmpad; end if; dqm <= dqcbdm; cal_en <= sdr_widthconv(sdo.cbcal_en (dbits/16-1 downto 0) & sdo.cal_en (dbits/8-1 downto 0), (dbits+padbits+chkbits)/8 ); cal_inc <= sdr_widthconv(sdo.cbcal_inc(dbits/16-1 downto 0) & sdo.cal_inc(dbits/8-1 downto 0), (dbits+padbits+chkbits)/8 ); vcsn := (others => '1'); for x in 0 to ncs-1 loop if x<2 then vcsn(x) := sdo.sdcsn(x); end if; vodt(x) := sdo.odt(x mod 2); vcke(x) := sdo.sdcke(x mod 2); end loop; csn <= vcsn; odt <= vodt; cke <= vcke; end process; -- Phy instantiation ddr_phy0 : ddr2phy generic map (tech => tech, MHz => MHz, rstdelay => rstdelay -- reduce 200 us start-up delay during simulation -- pragma translate_off / 200 -- pragma translate_on , dbits => dbits+padbits+chkbits,clk_mul => clk_mul, clk_div => clk_div, ddelayb0 => cbddelays(0), ddelayb1 => cbddelays(1), ddelayb2 => cbddelays(2), ddelayb3 => cbddelays(3), ddelayb4 => cbddelays(4), ddelayb5 => cbddelays(5), ddelayb6 => cbddelays(6), ddelayb7 => cbddelays(7), ddelayb8 => cbddelays(8), ddelayb9 => cbddelays(9), ddelayb10 => cbddelays(10), ddelayb11 => cbddelays(11), numidelctrl => numidelctrl, norefclk => norefclk, rskew => rskew, eightbanks => eightbanks, dqsse => dqsse, abits => abits, nclk => nclk, ncs => ncs, ctrl2en => ctrl2en, resync => resync, custombits => custombits, extraio => extraio, scantest => scantest) port map ( rst, clk, clkref200, clkout, clkoutret, clkresync, lock, ddr_clk, ddr_clkb, ddr_clk_fb_out, ddr_clk_fb, ddr_cke, ddr_csb, ddr_web, ddr_rasb, ddr_casb, ddr_dm, ddr_dqs, ddr_dqsn, ddr_ad, ddr_ba, ddr_dq, ddr_odt, sdo.address(abits-1 downto 0), sdo.ba, dqin, dqout, dqm, sdo.bdrive, sdo.nbdrive, sdo.bdrive, sdo.qdrive, sdo.rasn, sdo.casn, sdo.sdwen, csn, cke, cal_en, cal_inc, sdo.cal_pll, sdo.cal_rst, odt, sdo.oct, sdo.read_pend, sdo.regwdata, sdo.regwrite, sdi.regrdata, sdi.datavalid, customclk, customdin, customdout, ddr_web2, ddr_rasb2, ddr_casb2, ddr_ad2, ddr_ba2, testen, testrst, scanen, testoen ); end; library ieee; use ieee.std_logic_1164.all; library grlib; use grlib.stdlib.all; library techmap; use techmap.gencomp.all; library gaisler; use gaisler.ddrpkg.all; ------------------------------------------------------------------ -- DDR2 PHY with checkbits merged on data bus, pads not in phy -- ------------------------------------------------------------------ entity ddr2phy_wrap_cbd_wo_pads is generic (tech : integer := virtex2; MHz : integer := 100; rstdelay : integer := 200; dbits : integer := 16; padbits : integer := 0; clk_mul : integer := 2 ; clk_div : integer := 2; ddelayb0 : integer := 0; ddelayb1 : integer := 0; ddelayb2 : integer := 0; ddelayb3 : integer := 0; ddelayb4 : integer := 0; ddelayb5 : integer := 0; ddelayb6 : integer := 0; ddelayb7 : integer := 0; cbdelayb0 : integer := 0; cbdelayb1: integer := 0; cbdelayb2: integer := 0; cbdelayb3 : integer := 0; numidelctrl : integer := 4; norefclk : integer := 0; odten : integer := 0; rskew : integer := 0; eightbanks : integer range 0 to 1 := 0; dqsse : integer range 0 to 1 := 0; abits : integer := 14; nclk : integer := 3; ncs : integer := 2; chkbits : integer := 0; resync : integer := 0; custombits: integer := 8; scantest : integer := 0); port ( rst : in std_ulogic; clk : in std_logic; -- input clock clkref200 : in std_logic; -- input 200MHz clock clkout : out std_ulogic; -- system clock clkoutret : in std_ulogic; -- system clock return clkresync : in std_ulogic; lock : out std_ulogic; -- DCM locked ddr_clk : out std_logic_vector(nclk-1 downto 0); ddr_clkb : out std_logic_vector(nclk-1 downto 0); ddr_clk_fb_out : out std_logic; ddr_clk_fb : in std_logic; ddr_cke : out std_logic_vector(ncs-1 downto 0); ddr_csb : out std_logic_vector(ncs-1 downto 0); ddr_web : out std_ulogic; -- ddr write enable ddr_rasb : out std_ulogic; -- ddr ras ddr_casb : out std_ulogic; -- ddr cas ddr_dm : out std_logic_vector ((dbits+padbits+chkbits)/8-1 downto 0); -- ddr dm ddr_dqs_in : in std_logic_vector ((dbits+padbits+chkbits)/8-1 downto 0); -- ddr dqs ddr_dqs_out : out std_logic_vector ((dbits+padbits+chkbits)/8-1 downto 0); -- ddr dqs ddr_dqs_oen : out std_logic_vector ((dbits+padbits+chkbits)/8-1 downto 0); -- ddr dqs ddr_ad : out std_logic_vector (abits-1 downto 0); -- ddr address ddr_ba : out std_logic_vector (1+eightbanks downto 0); -- ddr bank address ddr_dq_in : in std_logic_vector (dbits+padbits+chkbits-1 downto 0); -- ddr data ddr_dq_out : out std_logic_vector (dbits+padbits+chkbits-1 downto 0); -- ddr data ddr_dq_oen : out std_logic_vector (dbits+padbits+chkbits-1 downto 0); -- ddr data ddr_odt : out std_logic_vector(ncs-1 downto 0); sdi : out ddrctrl_in_type; sdo : in ddrctrl_out_type; customclk : in std_ulogic; customdin : in std_logic_vector(custombits-1 downto 0); customdout : out std_logic_vector(custombits-1 downto 0); testen : in std_ulogic; testrst : in std_ulogic; scanen : in std_ulogic; testoen : in std_ulogic); end; architecture rtl of ddr2phy_wrap_cbd_wo_pads is function ddr_widthconv(x: std_logic_vector; ow: integer) return std_logic_vector is variable r: std_logic_vector(2*ow-1 downto 0); constant iw: integer := x'length/2; begin r := (others => '0'); if iw <= ow then r(iw+ow-1 downto ow) := x(2*iw-1 downto iw); r(iw-1 downto 0) := x(iw-1 downto 0); else r := x(iw+ow-1 downto iw) & x(ow-1 downto 0); end if; return r; end; function sdr_widthconv(x: std_logic_vector; ow: integer) return std_logic_vector is variable r: std_logic_vector(ow-1 downto 0); constant iw: integer := x'length; variable xd : std_logic_vector(iw-1 downto 0); begin r := (others => '0'); xd := x; if iw >= ow then r := xd(ow-1 downto 0); else r(iw-1 downto 0) := xd; end if; return r; end; function ddrmerge(a,b: std_logic_vector) return std_logic_vector is constant aw: integer := a'length/2; constant bw: integer := b'length/2; begin return a(2*aw-1 downto aw) & b(2*bw-1 downto bw) & a(aw-1 downto 0) & b(bw-1 downto 0); end; type int_array is array (natural range <>) of integer; constant delays: int_array(0 to 7) := (ddelayb0,ddelayb1,ddelayb2,ddelayb3, ddelayb4,ddelayb5,ddelayb6,ddelayb7); constant cbdelays: int_array(0 to 11) := (cbdelayb0,cbdelayb1,cbdelayb2,cbdelayb3,0,0,0,0,0,0,0,0); constant cbddelays: int_array(0 to 11) := delays(0 to (dbits+padbits)/8-1) & cbdelays(0 to 11-(dbits+padbits)/8); signal dqin: std_logic_vector(2*(chkbits+dbits+padbits)-1 downto 0); signal dqout: std_logic_vector(2*(chkbits+dbits+padbits)-1 downto 0); signal dqm: std_logic_vector((chkbits+dbits+padbits)/4-1 downto 0); signal cal_en: std_logic_vector((chkbits+dbits+padbits)/8-1 downto 0); signal cal_inc: std_logic_vector((chkbits+dbits+padbits)/8-1 downto 0); signal odt,csn,cke: std_logic_vector(ncs-1 downto 0); signal gnd : std_logic_vector(chkbits*2-1 downto 0); begin gnd <= (others => '0'); -- Merge checkbit and data buses comb: process(sdo,dqin) variable dq: std_logic_vector(2*dbits-1 downto 0); variable dqpad: std_logic_vector(2*(dbits+padbits)-1 downto 0); variable cb: std_logic_vector(dbits-1 downto 0); variable cbpad: std_logic_vector(2*chkbits downto 0); -- Extra bit to handle chkbits=0 variable dqcb: std_logic_vector(2*(dbits+padbits+chkbits)-1 downto 0); variable dm: std_logic_vector(dbits/4-1 downto 0); variable dmpad: std_logic_vector((dbits+padbits)/4-1 downto 0); variable cbdm: std_logic_vector(dbits/8-1 downto 0); variable cbdmpad: std_logic_vector(chkbits/4 downto 0); variable dqcbdm: std_logic_vector((dbits+padbits+chkbits)/4-1 downto 0); variable vcsn,vodt,vcke: std_logic_vector(ncs-1 downto 0); begin dq := sdo.data(2*dbits-1 downto 0); dqpad := ddr_widthconv(dq, dbits+padbits ); if chkbits > 0 then cb := sdo.cb(dbits-1 downto 0); cbpad := '0' & ddr_widthconv(cb, chkbits); dqcb := ddrmerge(cbpad(2*chkbits-1 downto 0), dqpad); else dqcb := dqpad; end if; dqout <= dqcb; dqcb := dqin; if chkbits > 0 then cbpad := '0' & dqin(2*(chkbits+dbits+padbits)-1 downto 2*(dbits+padbits)+chkbits) & dqin(chkbits+dbits+padbits-1 downto dbits+padbits); cb := ddr_widthconv(cbpad(2*chkbits-1 downto 0), dbits/2); else cb := (others => '0'); end if; dq := dqcb(2*dbits+chkbits+padbits-1 downto dbits+chkbits+padbits) & dqcb(dbits-1 downto 0); sdi.cb(dbits-1 downto 0) <= cb; sdi.data(2*dbits-1 downto 0) <= dq; if sdi.cb'length > dbits then sdi.cb(sdi.cb'length-1 downto dbits) <= (others => '0'); end if; if sdi.data'length > 2*dbits then sdi.data(sdi.data'length-1 downto 2*dbits) <= (others => '0'); end if; dm := sdo.dqm(dbits/4-1 downto 0); dmpad := ddr_widthconv(dm, (dbits+padbits)/8); if chkbits > 0 then cbdm := sdo.cbdqm(dbits/8-1 downto 0); cbdmpad := '0' & ddr_widthconv(cbdm(dbits/8-1 downto 0), chkbits/8); dqcbdm := ddrmerge(cbdmpad(chkbits/4-1 downto 0), dmpad); else dqcbdm := dmpad; end if; dqm <= dqcbdm; cal_en <= sdr_widthconv(sdo.cbcal_en (dbits/16-1 downto 0) & sdo.cal_en (dbits/8-1 downto 0), (dbits+padbits+chkbits)/8 ); cal_inc <= sdr_widthconv(sdo.cbcal_inc(dbits/16-1 downto 0) & sdo.cal_inc(dbits/8-1 downto 0), (dbits+padbits+chkbits)/8 ); vcsn := (others => '1'); for x in 0 to ncs-1 loop if x<2 then vcsn(x) := sdo.sdcsn(x); end if; vodt(x) := sdo.odt(x mod 2); vcke(x) := sdo.sdcke(x mod 2); end loop; csn <= vcsn; odt <= vodt; cke <= vcke; end process; -- Phy instantiation ddr_phy0 : ddr2phy_wo_pads generic map (tech => tech, MHz => MHz, rstdelay => rstdelay -- reduce 200 us start-up delay during simulation -- pragma translate_off / 200 -- pragma translate_on , dbits => dbits+padbits+chkbits,clk_mul => clk_mul, clk_div => clk_div, ddelayb0 => cbddelays(0), ddelayb1 => cbddelays(1), ddelayb2 => cbddelays(2), ddelayb3 => cbddelays(3), ddelayb4 => cbddelays(4), ddelayb5 => cbddelays(5), ddelayb6 => cbddelays(6), ddelayb7 => cbddelays(7), ddelayb8 => cbddelays(8), ddelayb9 => cbddelays(9), ddelayb10 => cbddelays(10), ddelayb11 => cbddelays(11), numidelctrl => numidelctrl, norefclk => norefclk, rskew => rskew, eightbanks => eightbanks, dqsse => dqsse, abits => abits, nclk => nclk, ncs => ncs, resync => resync, custombits => custombits, scantest => scantest) port map ( rst => rst, clk => clk, clkref => clkref200, clkout => clkout, clkoutret => clkoutret, clkresync => clkresync, lock => lock, ddr_clk => ddr_clk, ddr_clkb => ddr_clkb, ddr_clk_fb_out => ddr_clk_fb_out, ddr_clk_fb => ddr_clk_fb, ddr_cke => ddr_cke, ddr_csb => ddr_csb, ddr_web => ddr_web, ddr_rasb => ddr_rasb, ddr_casb => ddr_casb, ddr_dm => ddr_dm, ddr_dqs_in => ddr_dqs_in, ddr_dqs_out => ddr_dqs_out, ddr_dqs_oen => ddr_dqs_oen, ddr_ad => ddr_ad, ddr_ba => ddr_ba, ddr_dq_in => ddr_dq_in, ddr_dq_out => ddr_dq_out, ddr_dq_oen => ddr_dq_oen, ddr_odt => ddr_odt, addr => sdo.address(abits-1 downto 0), ba => sdo.ba, dqin => dqin, dqout => dqout, dm => dqm, oen => sdo.bdrive, noen => sdo.nbdrive, dqs => sdo.bdrive, dqsoen => sdo.qdrive, rasn => sdo.rasn, casn => sdo.casn, wen => sdo.sdwen, csn => csn, cke => cke, cal_en => cal_en, cal_inc => cal_inc, cal_pll => sdo.cal_pll, cal_rst => sdo.cal_rst, odt => odt, oct => sdo.oct, read_pend => sdo.read_pend, regwdata => sdo.regwdata, regwrite => sdo.regwrite, regrdata => sdi.regrdata, dqin_valid => sdi.datavalid, customclk => customclk, customdin => customdin, customdout => customdout, testen => testen, testrst => testrst, scanen => scanen, testoen => testoen ); end; ------------------------------------------------------------------ -- LPDDR2/LPDDR3 PHY with checkbits merged on data bus, no pads -- ------------------------------------------------------------------ library ieee; use ieee.std_logic_1164.all; library grlib; use grlib.stdlib.all; library techmap; use techmap.gencomp.all; library gaisler; use gaisler.ddrpkg.all; entity lpddr2phy_wrap_cbd_wo_pads is generic (tech : integer := virtex2; dbits : integer := 16; nclk : integer := 3; ncs : integer := 2; chkbits : integer := 0; padbits : integer := 0; scantest : integer := 0); port ( rst : in std_ulogic; clkin : in std_ulogic; -- input clock clkin2 : in std_ulogic; -- input clock clkout : out std_ulogic; -- system clock clkoutret : in std_ulogic; -- system clock return clkout2 : out std_ulogic; -- system clock lock : out std_ulogic; -- DCM locked ddr_clk : out std_logic_vector(nclk-1 downto 0); ddr_clkb : out std_logic_vector(nclk-1 downto 0); ddr_cke : out std_logic_vector(ncs-1 downto 0); ddr_csb : out std_logic_vector(ncs-1 downto 0); ddr_ca : out std_logic_vector(9 downto 0); -- ddr cmd/addr ddr_dm : out std_logic_vector ((dbits+padbits+chkbits)/8-1 downto 0); -- ddr dm ddr_dqs_in : in std_logic_vector ((dbits+padbits+chkbits)/8-1 downto 0); -- ddr dqs ddr_dqs_out : out std_logic_vector ((dbits+padbits+chkbits)/8-1 downto 0); -- ddr dqs ddr_dqs_oen : out std_logic_vector ((dbits+padbits+chkbits)/8-1 downto 0); -- ddr dqs ddr_dq_in : in std_logic_vector (dbits+padbits+chkbits-1 downto 0); -- ddr data ddr_dq_out : out std_logic_vector (dbits+padbits+chkbits-1 downto 0); -- ddr data ddr_dq_oen : out std_logic_vector (dbits+padbits+chkbits-1 downto 0); sdi : out ddrctrl_in_type; sdo : in ddrctrl_out_type; testen : in std_ulogic; testrst : in std_ulogic; scanen : in std_ulogic; testoen : in std_ulogic); end; architecture rtl of lpddr2phy_wrap_cbd_wo_pads is function ddr_widthconv(x: std_logic_vector; ow: integer) return std_logic_vector is variable r: std_logic_vector(2*ow-1 downto 0); constant iw: integer := x'length/2; begin r := (others => '0'); if iw <= ow then r(iw+ow-1 downto ow) := x(2*iw-1 downto iw); r(iw-1 downto 0) := x(iw-1 downto 0); else r := x(iw+ow-1 downto iw) & x(ow-1 downto 0); end if; return r; end; function sdr_widthconv(x: std_logic_vector; ow: integer) return std_logic_vector is variable r: std_logic_vector(ow-1 downto 0); constant iw: integer := x'length; variable xd : std_logic_vector(iw-1 downto 0); begin r := (others => '0'); xd := x; if iw >= ow then r := xd(ow-1 downto 0); else r(iw-1 downto 0) := xd; end if; return r; end; function ddrmerge(a,b: std_logic_vector) return std_logic_vector is constant aw: integer := a'length/2; constant bw: integer := b'length/2; begin return a(2*aw-1 downto aw) & b(2*bw-1 downto bw) & a(aw-1 downto 0) & b(bw-1 downto 0); end; signal dqin: std_logic_vector(2*(chkbits+dbits+padbits)-1 downto 0); signal dqout: std_logic_vector(2*(chkbits+dbits+padbits)-1 downto 0); signal dqm: std_logic_vector((chkbits+dbits+padbits)/4-1 downto 0); signal odt,csn,cke: std_logic_vector(ncs-1 downto 0); signal sdck: std_logic_vector(nclk-1 downto 0); signal gnd : std_logic_vector(chkbits*2-1 downto 0); begin gnd <= (others => '0'); -- Merge checkbit and data buses comb: process(sdo,dqin) variable dq: std_logic_vector(2*dbits-1 downto 0); variable dqpad: std_logic_vector(2*(dbits+padbits)-1 downto 0); variable cb: std_logic_vector(dbits-1 downto 0); variable cbpad: std_logic_vector(2*chkbits downto 0); -- Extra bit to handle chkbits=0 variable dqcb: std_logic_vector(2*(dbits+padbits+chkbits)-1 downto 0); variable dm: std_logic_vector(dbits/4-1 downto 0); variable dmpad: std_logic_vector((dbits+padbits)/4-1 downto 0); variable cbdm: std_logic_vector(dbits/8-1 downto 0); variable cbdmpad: std_logic_vector(chkbits/4 downto 0); variable dqcbdm: std_logic_vector((dbits+padbits+chkbits)/4-1 downto 0); variable vcsn,vcke: std_logic_vector(ncs-1 downto 0); variable vsdck: std_logic_vector(nclk-1 downto 0); begin dq := sdo.data(2*dbits-1 downto 0); dqpad := ddr_widthconv(dq, dbits+padbits ); if chkbits > 0 then cb := sdo.cb(dbits-1 downto 0); cbpad := '0' & ddr_widthconv(cb, chkbits); dqcb := ddrmerge(cbpad(2*chkbits-1 downto 0), dqpad); else dqcb := dqpad; end if; dqout <= dqcb; dqcb := dqin; if chkbits > 0 then cbpad := '0' & dqin(2*(chkbits+dbits+padbits)-1 downto 2*(dbits+padbits)+chkbits) & dqin(chkbits+dbits+padbits-1 downto dbits+padbits); cb := ddr_widthconv(cbpad(2*chkbits-1 downto 0), dbits/2); else cb := (others => '0'); end if; dq := dqcb(2*dbits+chkbits+padbits-1 downto dbits+chkbits+padbits) & dqcb(dbits-1 downto 0); sdi.cb(dbits-1 downto 0) <= cb; sdi.data(2*dbits-1 downto 0) <= dq; if sdi.cb'length > dbits then sdi.cb(sdi.cb'length-1 downto dbits) <= (others => '0'); end if; if sdi.data'length > 2*dbits then sdi.data(sdi.data'length-1 downto 2*dbits) <= (others => '0'); end if; dm := sdo.dqm(dbits/4-1 downto 0); dmpad := ddr_widthconv(dm, (dbits+padbits)/8); if chkbits > 0 then cbdm := sdo.cbdqm(dbits/8-1 downto 0); cbdmpad := '0' & ddr_widthconv(cbdm(dbits/8-1 downto 0), chkbits/8); dqcbdm := ddrmerge(cbdmpad(chkbits/4-1 downto 0), dmpad); else dqcbdm := dmpad; end if; dqm <= dqcbdm; vcsn := (others => '1'); for x in 0 to ncs-1 loop if x<2 then vcsn(x) := sdo.sdcsn(x); end if; vcke(x) := sdo.sdcke(x mod 2); end loop; for x in 0 to nclk-1 loop vsdck(x) := sdo.sdck(x mod 2); end loop; csn <= vcsn; cke <= vcke; sdck <= vsdck; end process; -- Phy instantiation ddr_phy0 : lpddr2phy_wo_pads generic map ( tech => tech, dbits => dbits+padbits+chkbits, nclk => nclk, ncs => ncs, clkratio => 1, scantest => scantest) port map ( rst => rst, clkin => clkin, clkin2 => clkin2, clkout => clkout, clkoutret => clkoutret, clkout2 => clkout2, lock => lock, ddr_clk => ddr_clk, ddr_clkb => ddr_clkb, ddr_cke => ddr_cke, ddr_csb => ddr_csb, ddr_ca => ddr_ca, ddr_dm => ddr_dm, ddr_dqs_in => ddr_dqs_in, ddr_dqs_out => ddr_dqs_out, ddr_dqs_oen => ddr_dqs_oen, ddr_dq_in => ddr_dq_in, ddr_dq_out => ddr_dq_out, ddr_dq_oen => ddr_dq_oen, ca => sdo.ca, cke => cke, csn => csn, dqin => dqin, dqout => dqout, dm => dqm, ckstop => sdo.sdck(0), boot => sdo.boot, wrpend => sdo.wrpend, rdpend => sdo.read_pend, wrreq(0) => sdi.writereq, rdvalid(0) => sdi.datavalid, refcal => '0', refcalwu => '0', refcaldone => open, phycmd => "00000000", phycmden => '0', phycmdin => x"00000000", phycmdout => open, testen => '0', testrst => '1', scanen => '0', testoen => '0' ); sdi.regrdata <= (others => '0'); end;

gpl-2.0

8bab2567d3f9b14edb2e70c0cf7281f8

0.570441

3.393609

false

Yuriu5/MiniBlaze

src/peripherals/UART.vhd

1

11,862

-- ********************************************************************************** -- Project : MiniBlaze -- Author : Benjamin Lemoine -- Module : UART -- Date : 07/25/2016 -- -- Description : -- -- -------------------------------------------------------------------------------- -- Modifications -- -------------------------------------------------------------------------------- -- Date : Ver. : Author : Modification comments -- -------------------------------------------------------------------------------- -- : : : -- 07/25/2016 : 1.0 : B.Lemoine : First draft -- : : : -- ********************************************************************************** -- MIT License -- -- Copyright (c) 07/25/2016, Benjamin Lemoine -- -- Permission is hereby granted, free of charge, to any person obtaining a copy -- of this software and associated documentation files (the "Software"), to deal -- in the Software without restriction, including without limitation the rights -- to use, copy, modify, merge, publish, distribute, sublicense, and/or sell -- copies of the Software, and to permit persons to whom the Software is -- furnished to do so, subject to the following conditions: -- -- The above copyright notice and this permission notice shall be included in all -- copies or substantial portions of the Software. -- -- THE SOFTWARE IS PROVIDED "AS IS", WITHOUT WARRANTY OF ANY KIND, EXPRESS OR -- IMPLIED, INCLUDING BUT NOT LIMITED TO THE WARRANTIES OF MERCHANTABILITY, -- FITNESS FOR A PARTICULAR PURPOSE AND NONINFRINGEMENT. IN NO EVENT SHALL THE -- AUTHORS OR COPYRIGHT HOLDERS BE LIABLE FOR ANY CLAIM, DAMAGES OR OTHER -- LIABILITY, WHETHER IN AN ACTION OF CONTRACT, TORT OR OTHERWISE, ARISING FROM, -- OUT OF OR IN CONNECTION WITH THE SOFTWARE OR THE USE OR OTHER DEALINGS IN THE -- SOFTWARE. -- ********************************************************************************** library ieee; use ieee.std_logic_1164.all; use ieee.numeric_std.all; entity UART is generic ( CLK_IN : integer := 10000000; BAUDRATE : integer := 115200; DATA_BITS : integer := 8; STOP_BITS : integer := 1; USE_PARITY : integer := 0; ODD_PARITY : integer := 0 ); port ( clk : in std_logic; rst_n : in std_logic; -- User intf data_in : in std_logic_vector(DATA_BITS-1 downto 0); data_in_en : in std_logic; data_in_ack : out std_logic; data_out : out std_logic_vector(DATA_BITS-1 downto 0); data_out_en : out std_logic; frame_error : out std_logic; parity_error : out std_logic; -- TX/RX RX : in std_logic; TX : out std_logic ); end UART; architecture rtl of UART is function CALC_RATIO ( C_BAUDRATE : integer; C_CLKIN : integer) return integer is constant C_RATIO : integer := C_CLKIN/C_BAUDRATE; constant C_REMAIN : integer := C_CLKIN rem C_BAUDRATE; begin if C_BAUDRATE/2 < C_REMAIN then return C_RATIO; else return C_RATIO + 1; end if; end function CALC_RATIO; constant c_nb_clk_per_bit : integer := CALC_RATIO(BAUDRATE, CLK_IN); constant c_nb_clk_per_bit_div2 : integer := c_nb_clk_per_bit/2; -- RX type fsm_rx is (st_wait_start_bit, st_get_data, st_get_stop_bit); signal r_fsm_rx : fsm_rx := st_wait_start_bit; signal r_RX : std_logic := '0'; signal r2_RX : std_logic := '0'; signal r_data_rx : std_logic_vector(DATA_BITS-1 downto 0) := (others => '0'); signal r_data_rx_en : std_logic := '0'; signal r_cnt_bit_uart : unsigned(31 downto 0) := (others => '0'); signal r_cnt_data : unsigned(31 downto 0) := (others => '0'); signal r_cnt_stop : unsigned(31 downto 0) := (others => '0'); signal r_frame_error : std_logic := '0'; -- TX type fsm_tx is (st_wait_data, st_send_start, st_send_data, st_send_stop, st_wait_1b_for_ack); signal r_fsm_tx : fsm_tx := st_wait_data; signal r_cnt_bit_uart_tx : unsigned(31 downto 0) := (others => '0'); signal r_cnt_data_tx : unsigned(31 downto 0) := (others => '0'); signal r_cnt_stop_tx : unsigned(31 downto 0) := (others => '0'); signal r_data_in : std_logic_vector(DATA_BITS-1 downto 0) := (others => '0'); signal r_data_in_en : std_logic := '0'; signal r_TX : std_logic := '1'; signal r_data_tx : std_logic_vector(DATA_BITS-1 downto 0) := (others => '0'); signal r_tx_ack : std_logic := '0'; begin -- --------------------------------------------- -- RX side -- --------------------------------------------- p_pipe_in : process(clk) -- Two pipes to avoid metastability begin if rising_edge(clk) then r_RX <= RX; r2_RX <= r_RX; end if; end process; p_RX : process(clk) begin if rising_edge(clk) then if rst_n = '0' then r_fsm_rx <= st_wait_start_bit; r_data_rx_en <= '0'; else -- default values r_data_rx_en <= '0'; case r_fsm_rx is when st_wait_start_bit => if r2_RX = '0' then r_cnt_bit_uart <= r_cnt_bit_uart + 1; else r_cnt_bit_uart <= (others => '0'); end if; if r_cnt_bit_uart = c_nb_clk_per_bit_div2 - 1 then r_fsm_rx <= st_get_data; r_cnt_bit_uart <= (others => '0'); r_cnt_data <= (others => '0'); r_cnt_stop <= (others => '0'); r_frame_error <= '0'; end if; when st_get_data => -- Sample at the center of each bit if r_cnt_bit_uart = c_nb_clk_per_bit - 1 then r_data_rx(to_integer(r_cnt_data)) <= r2_RX; r_cnt_bit_uart <= (others => '0'); if r_cnt_data = DATA_BITS - 1 then r_fsm_rx <= st_get_stop_bit; else r_cnt_data <= r_cnt_data + 1; end if; else r_cnt_bit_uart <= r_cnt_bit_uart + 1; end if; when st_get_stop_bit => if r_cnt_bit_uart = c_nb_clk_per_bit - 1 then if r2_RX = '0' then -- NOK r_cnt_bit_uart <= (others => '0'); r_fsm_rx <= st_wait_start_bit; r_frame_error <= '1'; else -- OK if r_cnt_stop = STOP_BITS - 1 then r_fsm_rx <= st_wait_start_bit; r_data_rx_en <= '1'; else r_cnt_stop <= r_cnt_stop + 1; r_cnt_bit_uart <= (others => '0'); end if; end if; else r_cnt_bit_uart <= r_cnt_bit_uart + 1; end if; when others => r_fsm_rx <= st_wait_start_bit; end case; end if; end if; end process; data_out <= r_data_rx; data_out_en <= r_data_rx_en; -- --------------------------------------------- -- TX side -- --------------------------------------------- p_pipe_tx_in : process(clk) begin if rising_edge(clk) then r_data_in <= data_in; r_data_in_en <= data_in_en; end if; end process; p_TX : process(clk) begin if rising_edge(clk) then if rst_n = '0' then r_cnt_bit_uart_tx <= (others => '0'); r_cnt_data_tx <= (others => '0'); r_cnt_stop_tx <= (others => '0'); r_fsm_tx <= st_wait_data; r_TX <= '1'; else -- Default values r_tx_ack <= '0'; case r_fsm_tx is when st_wait_data => r_TX <= '1'; if r_data_in_en = '1' then r_data_tx <= r_data_in; r_fsm_tx <= st_send_start; r_cnt_bit_uart_tx <= (others => '0'); r_cnt_data_tx <= (others => '0'); r_cnt_stop_tx <= (others => '0'); end if; when st_send_start => r_TX <= '0'; if r_cnt_bit_uart_tx = c_nb_clk_per_bit - 1 then r_cnt_bit_uart_tx <= (others => '0'); r_fsm_tx <= st_send_data; else r_cnt_bit_uart_tx <= r_cnt_bit_uart_tx + 1; end if; when st_send_data => if r_cnt_data_tx = DATA_BITS then r_fsm_tx <= st_send_stop; r_TX <= '1'; else if r_cnt_bit_uart_tx = c_nb_clk_per_bit - 1 then r_cnt_data_tx <= r_cnt_data_tx + 1; r_cnt_bit_uart_tx <= (others => '0'); r_data_tx <= r_data_tx(0) & r_data_tx(DATA_BITS - 1 downto 1); else r_cnt_bit_uart_tx <= r_cnt_bit_uart_tx + 1; r_TX <= r_data_tx(0); end if; end if; when st_send_stop => r_TX <= '1'; if r_cnt_stop_tx = STOP_BITS -1 then r_fsm_tx <= st_wait_1b_for_ack; r_cnt_bit_uart_tx <= (others => '0'); else if r_cnt_bit_uart_tx = c_nb_clk_per_bit - 1 then r_cnt_bit_uart_tx <= (others => '0'); r_cnt_stop_tx <= r_cnt_stop_tx + 1; else r_cnt_bit_uart_tx <= r_cnt_bit_uart_tx + 1; end if; end if; when st_wait_1b_for_ack => r_TX <= '1'; if r_cnt_bit_uart_tx = c_nb_clk_per_bit - 1 then r_fsm_tx <= st_wait_data; r_tx_ack <= '1'; else r_cnt_bit_uart_tx <= r_cnt_bit_uart_tx + 1; end if; when others => r_fsm_tx <= st_wait_data; end case; end if; end if; end process; TX <= r_TX; data_in_ack <= r_tx_ack; end;

mit

63f42e87b07217dded5d300758df35df

0.386023

3.999326

false

mistryalok/Zedboard

learning/training/MSD/s09/axi_dma_sg/vivado/project_1/project_1.srcs/sources_1/ipshared/xilinx.com/axi_sg_v4_1/0535f152/hdl/src/vhdl/axi_sg_scc_wr.vhd

13

44,376

-- ************************************************************************* -- -- (c) Copyright 2010-2011 Xilinx, Inc. All rights reserved. -- -- This file contains confidential and proprietary information -- of Xilinx, Inc. and is protected under U.S. and -- international copyright and other intellectual property -- laws. -- -- DISCLAIMER -- This disclaimer is not a license and does not grant any -- rights to the materials distributed herewith. Except as -- otherwise provided in a valid license issued to you by -- Xilinx, and to the maximum extent permitted by applicable -- law: (1) THESE MATERIALS ARE MADE AVAILABLE "AS IS" AND -- WITH ALL FAULTS, AND XILINX HEREBY DISCLAIMS ALL WARRANTIES -- AND CONDITIONS, EXPRESS, IMPLIED, OR STATUTORY, INCLUDING -- BUT NOT LIMITED TO WARRANTIES OF MERCHANTABILITY, NON- -- INFRINGEMENT, OR FITNESS FOR ANY PARTICULAR PURPOSE; and -- (2) Xilinx shall not be liable (whether in contract or tort, -- including negligence, or under any other theory of -- liability) for any loss or damage of any kind or nature -- related to, arising under or in connection with these -- materials, including for any direct, or any indirect, -- special, incidental, or consequential loss or damage -- (including loss of data, profits, goodwill, or any type of -- loss or damage suffered as a result of any action brought -- by a third party) even if such damage or loss was -- reasonably foreseeable or Xilinx had been advised of the -- possibility of the same. -- -- CRITICAL APPLICATIONS -- Xilinx products are not designed or intended to be fail- -- safe, or for use in any application requiring fail-safe -- performance, such as life-support or safety devices or -- systems, Class III medical devices, nuclear facilities, -- applications related to the deployment of airbags, or any -- other applications that could lead to death, personal -- injury, or severe property or environmental damage -- (individually and collectively, "Critical -- Applications"). Customer assumes the sole risk and -- liability of any use of Xilinx products in Critical -- Applications, subject only to applicable laws and -- regulations governing limitations on product liability. -- -- THIS COPYRIGHT NOTICE AND DISCLAIMER MUST BE RETAINED AS -- PART OF THIS FILE AT ALL TIMES. -- -- ************************************************************************* -- ------------------------------------------------------------------------------- -- Filename: axi_sg_scc_wr.vhd -- -- Description: -- This file implements the DataMover Lite Master Simple Command Calculator (SCC). -- -- -- -- -- VHDL-Standard: VHDL'93 ------------------------------------------------------------------------------- library IEEE; use IEEE.std_logic_1164.all; use IEEE.numeric_std.all; ------------------------------------------------------------------------------- entity axi_sg_scc_wr is generic ( C_SEL_ADDR_WIDTH : Integer range 1 to 8 := 5; -- Sets the width of the LS address bus used for -- Muxing/Demuxing data to/from a wider AXI4 data bus C_ADDR_WIDTH : Integer range 32 to 64 := 32; -- Sets the width of the AXi Address Channel C_STREAM_DWIDTH : Integer range 8 to 64 := 32; -- Sets the width of the Native Data width that -- is being supported by the PCC C_MAX_BURST_LEN : Integer range 16 to 64 := 16; -- Indicates the max allowed burst length to use for -- AXI4 transfer calculations C_CMD_WIDTH : Integer := 68; -- Sets the width of the input command port C_TAG_WIDTH : Integer range 1 to 8 := 4; -- Sets the width of the Tag field in the input command C_ENABLE_EXTRA_FIELD : Integer range 0 to 1 := 1 ); port ( -- Clock and Reset inputs ------------------------------------- primary_aclk : in std_logic; -- -- Primary synchronization clock for the Master side -- -- interface and internal logic. It is also used -- -- for the User interface synchronization when -- -- C_STSCMD_IS_ASYNC = 0. -- -- -- Reset input -- mmap_reset : in std_logic; -- -- Reset used for the internal master logic -- --------------------------------------------------------------- -- Command Input Interface --------------------------------------------------------- -- cmd2mstr_command : in std_logic_vector(C_CMD_WIDTH-1 downto 0); -- -- The next command value available from the Command FIFO/Register -- -- cache2mstr_command : in std_logic_vector(7 downto 0); -- -- The next command value available from the Command FIFO/Register -- -- cmd2mstr_cmd_valid : in std_logic; -- -- Handshake bit indicating if the Command FIFO/Register has at leasdt 1 entry -- -- mst2cmd_cmd_ready : out std_logic; -- -- Handshake bit indicating the Command Calculator is ready to accept -- -- another command -- ------------------------------------------------------------------------------------ -- Address Channel Controller Interface -------------------------------------------- -- mstr2addr_tag : out std_logic_vector(C_TAG_WIDTH-1 downto 0); -- -- The next command tag -- -- mstr2addr_addr : out std_logic_vector(C_ADDR_WIDTH-1 downto 0); -- -- The next command address to put on the AXI MMap ADDR -- -- mstr2addr_len : out std_logic_vector(7 downto 0); -- -- The next command length to put on the AXI MMap LEN -- -- mstr2addr_size : out std_logic_vector(2 downto 0); -- -- The next command size to put on the AXI MMap SIZE -- -- mstr2addr_burst : out std_logic_vector(1 downto 0); -- -- The next command burst type to put on the AXI MMap BURST -- -- mstr2addr_cache : out std_logic_vector(3 downto 0); -- -- The next command burst type to put on the AXI MMap BURST -- -- mstr2addr_user : out std_logic_vector(3 downto 0); -- -- The next command burst type to put on the AXI MMap BURST -- -- mstr2addr_cmd_cmplt : out std_logic; -- -- The indication to the Address Channel that the current -- -- sub-command output is the last one compiled from the -- -- parent command pulled from the Command FIFO -- -- mstr2addr_calc_error : out std_logic; -- -- Indication if the next command in the calculation pipe -- -- has a calcualtion error -- -- mstr2addr_cmd_valid : out std_logic; -- -- The next command valid indication to the Address Channel -- -- Controller for the AXI MMap -- -- addr2mstr_cmd_ready : In std_logic; -- -- Indication from the Address Channel Controller that the -- -- command is being accepted -- ------------------------------------------------------------------------------------ -- Data Channel Controller Interface ---------------------------------------------- -- mstr2data_tag : out std_logic_vector(C_TAG_WIDTH-1 downto 0); -- -- The next command tag -- -- mstr2data_saddr_lsb : out std_logic_vector(C_SEL_ADDR_WIDTH-1 downto 0); -- -- The next command start address LSbs to use for the read data -- -- mux (only used if Stream data width is 8 or 16 bits). -- -- mstr2data_len : out std_logic_vector(7 downto 0); -- -- The LEN value output to the Address Channel -- -- mstr2data_strt_strb : out std_logic_vector((C_STREAM_DWIDTH/8)-1 downto 0); -- -- The starting strobe value to use for the data transfer -- -- mstr2data_last_strb : out std_logic_vector((C_STREAM_DWIDTH/8)-1 downto 0); -- -- The endiing (LAST) strobe value to use for the data transfer -- -- mstr2data_sof : out std_logic; -- -- The starting tranfer of a sequence of transfers -- -- mstr2data_eof : out std_logic; -- -- The endiing tranfer of a sequence of parent transfer commands -- -- mstr2data_calc_error : out std_logic; -- -- Indication if the next command in the calculation pipe -- -- has a calculation error -- -- mstr2data_cmd_cmplt : out std_logic; -- -- The indication to the Data Channel that the current -- -- sub-command output is the last one compiled from the -- -- parent command pulled from the Command FIFO -- -- mstr2data_cmd_valid : out std_logic; -- -- The next command valid indication to the Data Channel -- -- Controller for the AXI MMap -- -- data2mstr_cmd_ready : In std_logic ; -- -- Indication from the Data Channel Controller that the -- -- command is being accepted on the AXI Address -- -- Channel -- -- calc_error : Out std_logic -- -- Indication from the Command Calculator that a calculation -- -- error has occured. -- ------------------------------------------------------------------------------------ ); end entity axi_sg_scc_wr; architecture implementation of axi_sg_scc_wr is attribute DowngradeIPIdentifiedWarnings: string; attribute DowngradeIPIdentifiedWarnings of implementation : architecture is "yes"; ------------------------------------------------------------------- -- Function -- -- Function Name: funct_get_slice_width -- -- Function Description: -- Calculates the bits to rip from the Command BTT field to calculate -- the LEN value output to the AXI Address Channel. -- ------------------------------------------------------------------- function funct_get_slice_width (max_burst_len : integer) return integer is Variable temp_slice_width : Integer := 0; begin case max_burst_len is -- coverage off when 64 => temp_slice_width := 7; when 32 => temp_slice_width := 6; when others => -- assume 16 dbeats is max LEN temp_slice_width := 5; -- coverage on end case; Return (temp_slice_width); end function funct_get_slice_width; ------------------------------------------------------------------- -- Function -- -- Function Name: funct_get_residue_width -- -- Function Description: -- Calculates the number of Least significant bits of the BTT field -- that are unused for the LEN calculation -- ------------------------------------------------------------------- function funct_get_btt_ls_unused (transfer_width : integer) return integer is Variable temp_btt_ls_unused : Integer := 0; -- 8-bit stream begin case transfer_width is -- coverage off when 64 => temp_btt_ls_unused := 3; -- coverage on when 32 => temp_btt_ls_unused := 2; -- coverage off when 16 => temp_btt_ls_unused := 1; when others => -- assume 8-bit transfers temp_btt_ls_unused := 0; -- coverage on end case; Return (temp_btt_ls_unused); end function funct_get_btt_ls_unused; -- Constant Declarations ---------------------------------------- Constant BASE_CMD_WIDTH : integer := 32; -- Bit Width of Command LS (no address) Constant CMD_TYPE_INDEX : integer := 23; Constant CMD_ADDR_LS_INDEX : integer := BASE_CMD_WIDTH; Constant CMD_ADDR_MS_INDEX : integer := (C_ADDR_WIDTH+BASE_CMD_WIDTH)-1; Constant CMD_TAG_WIDTH : integer := C_TAG_WIDTH; Constant CMD_TAG_LS_INDEX : integer := C_ADDR_WIDTH+BASE_CMD_WIDTH; Constant CMD_TAG_MS_INDEX : integer := (CMD_TAG_LS_INDEX+CMD_TAG_WIDTH)-1; Constant AXI_BURST_FIXED : std_logic_vector(1 downto 0) := "00"; Constant AXI_BURST_INCR : std_logic_vector(1 downto 0) := "01"; Constant AXI_BURST_WRAP : std_logic_vector(1 downto 0) := "10"; Constant AXI_BURST_RESVD : std_logic_vector(1 downto 0) := "11"; Constant AXI_SIZE_1BYTE : std_logic_vector(2 downto 0) := "000"; Constant AXI_SIZE_2BYTE : std_logic_vector(2 downto 0) := "001"; Constant AXI_SIZE_4BYTE : std_logic_vector(2 downto 0) := "010"; Constant AXI_SIZE_8BYTE : std_logic_vector(2 downto 0) := "011"; Constant AXI_SIZE_16BYTE : std_logic_vector(2 downto 0) := "100"; Constant AXI_SIZE_32BYTE : std_logic_vector(2 downto 0) := "101"; Constant AXI_SIZE_64BYTE : std_logic_vector(2 downto 0) := "110"; Constant AXI_SIZE_128BYTE : std_logic_vector(2 downto 0) := "111"; Constant BTT_SLICE_SIZE : integer := funct_get_slice_width(C_MAX_BURST_LEN); Constant MAX_BURST_LEN_US : unsigned(BTT_SLICE_SIZE-1 downto 0) := TO_UNSIGNED(C_MAX_BURST_LEN-1, BTT_SLICE_SIZE); Constant BTT_LS_UNUSED_WIDTH : integer := funct_get_btt_ls_unused(C_STREAM_DWIDTH); Constant CMD_BTT_WIDTH : integer := BTT_SLICE_SIZE+BTT_LS_UNUSED_WIDTH; Constant CMD_BTT_LS_INDEX : integer := 0; Constant CMD_BTT_MS_INDEX : integer := CMD_BTT_WIDTH-1; Constant BTT_ZEROS : std_logic_vector(CMD_BTT_WIDTH-1 downto 0) := (others => '0'); Constant BTT_RESIDUE_ZEROS : unsigned(BTT_LS_UNUSED_WIDTH-1 downto 0) := (others => '0'); Constant BTT_SLICE_ONE : unsigned(BTT_SLICE_SIZE-1 downto 0) := TO_UNSIGNED(1, BTT_SLICE_SIZE); Constant STRB_WIDTH : integer := C_STREAM_DWIDTH/8; -- Number of bytes in the Stream Constant LEN_WIDTH : integer := 8; -- Type Declarations -------------------------------------------- type SCC_SM_STATE_TYPE is ( INIT, POP_RECOVER, GET_NXT_CMD, CHK_AND_CALC, PUSH_TO_AXI, ERROR_TRAP ); -- Signal Declarations -------------------------------------------- signal sm_scc_state : SCC_SM_STATE_TYPE := INIT; signal sm_scc_state_ns : SCC_SM_STATE_TYPE := INIT; signal sm_pop_input_cmd : std_logic := '0'; signal sm_pop_input_cmd_ns : std_logic := '0'; signal sm_set_push2axi : std_logic := '0'; signal sm_set_push2axi_ns : std_logic := '0'; signal sm_set_error : std_logic := '0'; signal sm_set_error_ns : std_logic := '0'; Signal sm_scc_sm_ready : std_logic := '0'; Signal sm_scc_sm_ready_ns : std_logic := '0'; signal sig_cmd2data_valid : std_logic := '0'; signal sig_clr_cmd2data_valid : std_logic := '0'; signal sig_cmd2addr_valid : std_logic := '0'; signal sig_cmd2addr_valid1 : std_logic := '0'; signal sig_clr_cmd2addr_valid : std_logic := '0'; signal sig_addr_data_rdy_pending : std_logic := '0'; signal sig_cmd_btt_slice : std_logic_vector(CMD_BTT_WIDTH-1 downto 0) := (others => '0'); signal sig_load_input_cmd : std_logic := '0'; signal sig_cmd_reg_empty : std_logic := '0'; signal sig_cmd_reg_full : std_logic := '0'; signal sig_cmd_addr_reg : std_logic_vector(C_ADDR_WIDTH-1 downto 0) := (others => '0'); signal sig_cmd_btt_reg : std_logic_vector(CMD_BTT_WIDTH-1 downto 0) := (others => '0'); signal sig_cmd_type_reg : std_logic := '0'; signal sig_cmd_burst_reg : std_logic_vector (1 downto 0) := "00"; signal sig_cmd_tag_reg : std_logic_vector(CMD_TAG_WIDTH-1 downto 0) := (others => '0'); signal sig_addr_data_rdy4cmd : std_logic := '0'; signal sig_btt_raw : std_logic := '0'; signal sig_btt_is_zero : std_logic := '0'; signal sig_btt_is_zero_reg : std_logic := '0'; signal sig_next_tag : std_logic_vector(CMD_TAG_WIDTH-1 downto 0) := (others => '0'); signal sig_next_addr : std_logic_vector(C_ADDR_WIDTH-1 downto 0) := (others => '0'); signal sig_next_len : std_logic_vector(LEN_WIDTH-1 downto 0) := (others => '0'); signal sig_next_size : std_logic_vector(2 downto 0) := (others => '0'); signal sig_next_burst : std_logic_vector(1 downto 0) := (others => '0'); signal sig_next_cache : std_logic_vector(3 downto 0) := (others => '0'); signal sig_next_user : std_logic_vector(3 downto 0) := (others => '0'); signal sig_next_strt_strb : std_logic_vector((C_STREAM_DWIDTH/8)-1 downto 0) := (others => '0'); signal sig_next_end_strb : std_logic_vector((C_STREAM_DWIDTH/8)-1 downto 0) := (others => '0'); begin --(architecture implementation) -- Assign calculation error output calc_error <= sm_set_error; -- Assign the ready output to the Command FIFO mst2cmd_cmd_ready <= sig_cmd_reg_empty and addr2mstr_cmd_ready; --sm_scc_sm_ready; -- Assign the Address Channel Controller Qualifiers mstr2addr_tag <= sig_next_tag ; mstr2addr_addr <= sig_next_addr ; mstr2addr_len <= sig_next_len ; mstr2addr_size <= sig_next_size ; mstr2addr_burst <= sig_cmd_burst_reg; mstr2addr_cache <= sig_next_cache; mstr2addr_user <= sig_next_user; mstr2addr_cmd_valid <= sig_cmd2addr_valid1; mstr2addr_calc_error <= sm_set_error ; mstr2addr_cmd_cmplt <= '1' ; -- Lite mode is always 1 -- Assign the Data Channel Controller Qualifiers mstr2data_tag <= sig_next_tag ; mstr2data_saddr_lsb <= sig_cmd_addr_reg(C_SEL_ADDR_WIDTH-1 downto 0); mstr2data_len <= sig_next_len ; mstr2data_strt_strb <= (others => '1'); --sig_next_strt_strb; -- always F mstr2data_last_strb <= (others => '1'); --sig_next_end_strb; -- always F mstr2data_sof <= '1'; -- Lite mode is always 1 cmd mstr2data_eof <= '1'; -- Lite mode is always 1 cmd mstr2data_cmd_cmplt <= '1'; -- Lite mode is always 1 cmd -- mstr2data_cmd_valid <= sig_cmd2data_valid; mstr2data_cmd_valid <= sig_cmd2addr_valid1; --sig_cmd2data_valid; mstr2data_calc_error <= sm_set_error; -- Internal logic ------------------------------ sig_addr_data_rdy_pending <= sig_cmd2addr_valid or sig_cmd2data_valid; sig_clr_cmd2data_valid <= sig_cmd2data_valid and data2mstr_cmd_ready; sig_clr_cmd2addr_valid <= sig_cmd2addr_valid and addr2mstr_cmd_ready; sig_load_input_cmd <= cmd2mstr_cmd_valid and sig_cmd_reg_empty;-- and -- sm_scc_sm_ready; sig_next_tag <= sig_cmd_tag_reg; sig_next_addr <= sig_cmd_addr_reg; sig_addr_data_rdy4cmd <= addr2mstr_cmd_ready and data2mstr_cmd_ready; sig_cmd_btt_slice <= cmd2mstr_command(CMD_BTT_MS_INDEX downto CMD_BTT_LS_INDEX); sig_btt_is_zero <= '1' when (sig_cmd_btt_slice = BTT_ZEROS) Else '0'; ------------------------------------------------------------ -- If Generate -- -- Label: GEN_NO_RESIDUE_BITS -- -- If Generate Description: -- -- -- ------------------------------------------------------------ GEN_NO_RESIDUE_BITS : if (BTT_LS_UNUSED_WIDTH = 0) generate -- signals signal sig_len_btt_slice : unsigned(BTT_SLICE_SIZE-1 downto 0) := (others => '0'); signal sig_len_btt_slice_minus_1 : unsigned(BTT_SLICE_SIZE-1 downto 0) := (others => '0'); signal sig_len2use : unsigned(BTT_SLICE_SIZE-1 downto 0) := (others => '0'); begin -- LEN Calculation logic ------------------------------------------ sig_next_len <= STD_LOGIC_VECTOR(RESIZE(sig_len2use, LEN_WIDTH)); sig_len_btt_slice <= UNSIGNED(sig_cmd_btt_reg(CMD_BTT_MS_INDEX downto 0)); sig_len_btt_slice_minus_1 <= sig_len_btt_slice-BTT_SLICE_ONE when sig_btt_is_zero_reg = '0' else (others => '0'); -- clip at zero -- If most significant bit of BTT set then limit to -- Max Burst Len, else rip it from the BTT value, -- otheriwse subtract 1 from the BTT ripped value -- 1 from the BTT ripped value sig_len2use <= MAX_BURST_LEN_US When (sig_cmd_btt_reg(CMD_BTT_MS_INDEX) = '1') Else sig_len_btt_slice_minus_1; end generate GEN_NO_RESIDUE_BITS; ------------------------------------------------------------ -- If Generate -- -- Label: GEN_HAS_RESIDUE_BITS -- -- If Generate Description: -- -- -- ------------------------------------------------------------ GEN_HAS_RESIDUE_BITS : if (BTT_LS_UNUSED_WIDTH > 0) generate -- signals signal sig_btt_len_residue : unsigned(BTT_LS_UNUSED_WIDTH-1 downto 0) := (others => '0'); signal sig_len_btt_slice : unsigned(BTT_SLICE_SIZE-1 downto 0) := (others => '0'); signal sig_len_btt_slice_minus_1 : unsigned(BTT_SLICE_SIZE-1 downto 0) := (others => '0'); signal sig_len2use : unsigned(BTT_SLICE_SIZE-1 downto 0) := (others => '0'); begin -- LEN Calculation logic ------------------------------------------ WR_EXTRA_FIELDS : if (C_ENABLE_EXTRA_FIELD = 1) generate sig_next_len <= "00000000" when sig_cmd_tag_reg (0) = '1' else "00000101"; --STD_LOGIC_VECTOR(RESIZE(sig_len2use, LEN_WIDTH)); end generate WR_EXTRA_FIELDS; NOWR_EXTRA_FIELDS : if (C_ENABLE_EXTRA_FIELD = 0) generate sig_next_len <= "00000000"; end generate NOWR_EXTRA_FIELDS; -- sig_next_len <= STD_LOGIC_VECTOR(RESIZE(sig_len2use, LEN_WIDTH)); sig_len_btt_slice <= UNSIGNED(sig_cmd_btt_reg(CMD_BTT_MS_INDEX downto BTT_LS_UNUSED_WIDTH)); sig_len_btt_slice_minus_1 <= sig_len_btt_slice-BTT_SLICE_ONE when sig_btt_is_zero_reg = '0' else (others => '0'); -- clip at zero sig_btt_len_residue <= UNSIGNED(sig_cmd_btt_reg(BTT_LS_UNUSED_WIDTH-1 downto 0)); -- If most significant bit of BTT set then limit to -- Max Burst Len, else rip it from the BTT value -- However if residue bits are zeroes then subtract -- 1 from the BTT ripped value sig_len2use <= MAX_BURST_LEN_US When (sig_cmd_btt_reg(CMD_BTT_MS_INDEX) = '1') Else sig_len_btt_slice_minus_1 when (sig_btt_len_residue = BTT_RESIDUE_ZEROS) Else sig_len_btt_slice; end generate GEN_HAS_RESIDUE_BITS; ------------------------------------------------------------- -- Synchronous Process with Sync Reset -- -- Label: REG_INPUT_CMD -- -- Process Description: -- Implements the input command holding registers -- ------------------------------------------------------------- REG_INPUT_CMD : process (primary_aclk) begin if (primary_aclk'event and primary_aclk = '1') then if (mmap_reset = '1' or addr2mstr_cmd_ready = '0') then -- sm_pop_input_cmd = '1') then sig_cmd_btt_reg <= (others => '0'); sig_cmd_type_reg <= '0'; sig_cmd_addr_reg <= (others => '0'); sig_cmd_tag_reg <= (others => '0'); sig_btt_is_zero_reg <= '0'; sig_cmd_reg_empty <= '1'; sig_cmd_reg_full <= '0'; sig_cmd_burst_reg <= "00"; sig_cmd2addr_valid1 <= '0'; elsif (sig_load_input_cmd = '1') then sig_cmd_btt_reg <= sig_cmd_btt_slice; sig_cmd_type_reg <= cmd2mstr_command(CMD_TYPE_INDEX); sig_cmd_addr_reg <= cmd2mstr_command(CMD_ADDR_MS_INDEX downto CMD_ADDR_LS_INDEX); sig_cmd_tag_reg <= cmd2mstr_command(CMD_TAG_MS_INDEX downto CMD_TAG_LS_INDEX); sig_btt_is_zero_reg <= sig_btt_is_zero; sig_cmd_reg_empty <= '0'; sig_cmd_reg_full <= '1'; sig_cmd2addr_valid1 <= '1'; sig_cmd_burst_reg <= sig_next_burst; else null; -- Hold current State end if; end if; end process REG_INPUT_CMD; -- Only Incrementing Burst type supported (per Interface_X guidelines) sig_next_burst <= AXI_BURST_INCR when (cmd2mstr_command(CMD_TYPE_INDEX) = '1') else AXI_BURST_FIXED; sig_next_user <= cache2mstr_command (7 downto 4); sig_next_cache <= cache2mstr_command (3 downto 0); ------------------------------------------------------------ -- If Generate -- -- Label: GEN_LEN_SDWIDTH_64 -- -- If Generate Description: -- This IfGen implements the AXI LEN qualifier calculation -- and the Stream data channel start/end STRB value. -- -- This IfGen is for the 64-bit Stream data Width case. -- ------------------------------------------------------------ GEN_LEN_SDWIDTH_64 : if (C_STREAM_DWIDTH = 64) generate -- Local Constants Constant AXI_SIZE2USE : std_logic_vector(2 downto 0) := AXI_SIZE_8BYTE; Constant RESIDUE_BIT_WIDTH : integer := 3; -- local signals signal sig_last_strb2use : std_logic_vector(STRB_WIDTH-1 downto 0) := (others => '0'); signal sig_last_strb : std_logic_vector(STRB_WIDTH-1 downto 0) := (others => '0'); Signal sig_btt_ms_bit_value : std_logic := '0'; signal lsig_btt_len_residue : std_logic_vector(BTT_LS_UNUSED_WIDTH-1 downto 0) := (others => '0'); signal sig_btt_len_residue_composite : std_logic_vector(RESIDUE_BIT_WIDTH downto 0) := (others => '0'); -- note 1 extra bit implied begin -- Assign the Address Channel Controller Size Qualifier Value sig_next_size <= AXI_SIZE2USE; -- Assign the Strobe Values sig_next_strt_strb <= (others => '1'); -- always aligned on first databeat for LITE DataMover sig_next_end_strb <= sig_last_strb; -- Local calculations ------------------------------ lsig_btt_len_residue <= sig_cmd_btt_reg(BTT_LS_UNUSED_WIDTH-1 downto 0); sig_btt_ms_bit_value <= sig_cmd_btt_reg(CMD_BTT_MS_INDEX); sig_btt_len_residue_composite <= sig_btt_ms_bit_value & lsig_btt_len_residue; ------------------------------------------------------------- -- Combinational Process -- -- Label: IMP_LAST_STRB_8bit -- -- Process Description: -- Generates the Strobe values for the LAST databeat of the -- Burst to MMap when the Stream is 64 bits wide and 8 strobe -- bits are required. -- ------------------------------------------------------------- IMP_LAST_STRB_8bit : process (sig_btt_len_residue_composite) begin case sig_btt_len_residue_composite is when "0001" => sig_last_strb <= "00000001"; when "0010" => sig_last_strb <= "00000011"; when "0011" => sig_last_strb <= "00000111"; when "0100" => sig_last_strb <= "00001111"; when "0101" => sig_last_strb <= "00011111"; when "0110" => sig_last_strb <= "00111111"; when "0111" => sig_last_strb <= "01111111"; when others => sig_last_strb <= "11111111"; end case; end process IMP_LAST_STRB_8bit; end generate GEN_LEN_SDWIDTH_64; ------------------------------------------------------------ -- If Generate -- -- Label: GEN_LEN_SDWIDTH_32 -- -- If Generate Description: -- This IfGen implements the AXI LEN qualifier calculation -- and the Stream data channel start/end STRB value. -- -- This IfGen is for the 32-bit Stream data Width case. -- ------------------------------------------------------------ GEN_LEN_SDWIDTH_32 : if (C_STREAM_DWIDTH = 32) generate -- Local Constants Constant AXI_SIZE2USE : std_logic_vector(2 downto 0) := AXI_SIZE_4BYTE; Constant RESIDUE_BIT_WIDTH : integer := 2; -- local signals signal sig_last_strb2use : std_logic_vector(STRB_WIDTH-1 downto 0) := (others => '0'); signal sig_last_strb : std_logic_vector(STRB_WIDTH-1 downto 0) := (others => '0'); Signal sig_btt_ms_bit_value : std_logic := '0'; signal sig_btt_len_residue_composite : std_logic_vector(RESIDUE_BIT_WIDTH downto 0) := (others => '0'); -- 1 extra bit signal lsig_btt_len_residue : std_logic_vector(BTT_LS_UNUSED_WIDTH-1 downto 0) := (others => '0'); begin -- Assign the Address Channel Controller Size Qualifier Value sig_next_size <= AXI_SIZE2USE; -- Assign the Strobe Values sig_next_strt_strb <= (others => '1'); -- always aligned on first databeat for LITE DataMover sig_next_end_strb <= sig_last_strb; -- Local calculations ------------------------------ lsig_btt_len_residue <= sig_cmd_btt_reg(BTT_LS_UNUSED_WIDTH-1 downto 0); sig_btt_ms_bit_value <= sig_cmd_btt_reg(CMD_BTT_MS_INDEX); sig_btt_len_residue_composite <= sig_btt_ms_bit_value & lsig_btt_len_residue; ------------------------------------------------------------- -- Combinational Process -- -- Label: IMP_LAST_STRB_4bit -- -- Process Description: -- Generates the Strobe values for the LAST databeat of the -- Burst to MMap when the Stream is 32 bits wide and 4 strobe -- bits are required. -- ------------------------------------------------------------- IMP_LAST_STRB_4bit : process (sig_btt_len_residue_composite) begin case sig_btt_len_residue_composite is -- coverage off when "001" => sig_last_strb <= "0001"; when "010" => sig_last_strb <= "0011"; when "011" => sig_last_strb <= "0111"; -- coverage on when others => sig_last_strb <= "1111"; end case; end process IMP_LAST_STRB_4bit; end generate GEN_LEN_SDWIDTH_32; ------------------------------------------------------------ -- If Generate -- -- Label: GEN_LEN_SDWIDTH_16 -- -- If Generate Description: -- This IfGen implements the AXI LEN qualifier calculation -- and the Stream data channel start/end STRB value. -- -- This IfGen is for the 16-bit Stream data Width case. -- ------------------------------------------------------------ GEN_LEN_SDWIDTH_16 : if (C_STREAM_DWIDTH = 16) generate -- Local Constants Constant AXI_SIZE2USE : std_logic_vector(2 downto 0) := AXI_SIZE_2BYTE; Constant RESIDUE_BIT_WIDTH : integer := 1; -- local signals signal sig_last_strb2use : std_logic_vector(STRB_WIDTH-1 downto 0) := (others => '0'); signal sig_last_strb : std_logic_vector(STRB_WIDTH-1 downto 0) := (others => '0'); Signal sig_btt_ms_bit_value : std_logic := '0'; signal sig_btt_len_residue_composite : std_logic_vector(RESIDUE_BIT_WIDTH downto 0) := (others => '0'); -- 1 extra bit signal lsig_btt_len_residue : std_logic_vector(BTT_LS_UNUSED_WIDTH-1 downto 0) := (others => '0'); begin -- Assign the Address Channel Controller Size Qualifier Value sig_next_size <= AXI_SIZE2USE; -- Assign the Strobe Values sig_next_strt_strb <= (others => '1'); -- always aligned on first databeat for LITE DataMover sig_next_end_strb <= sig_last_strb; -- Local calculations ------------------------------ lsig_btt_len_residue <= sig_cmd_btt_reg(BTT_LS_UNUSED_WIDTH-1 downto 0); sig_btt_ms_bit_value <= sig_cmd_btt_reg(CMD_BTT_MS_INDEX); sig_btt_len_residue_composite <= sig_btt_ms_bit_value & lsig_btt_len_residue; ------------------------------------------------------------- -- Combinational Process -- -- Label: IMP_LAST_STRB_2bit -- -- Process Description: -- Generates the Strobe values for the LAST databeat of the -- Burst to MMap when the Stream is 16 bits wide and 2 strobe -- bits are required. -- ------------------------------------------------------------- IMP_LAST_STRB_2bit : process (sig_btt_len_residue_composite) begin case sig_btt_len_residue_composite is when "01" => sig_last_strb <= "01"; when others => sig_last_strb <= "11"; end case; end process IMP_LAST_STRB_2bit; end generate GEN_LEN_SDWIDTH_16; ------------------------------------------------------------ -- If Generate -- -- Label: GEN_LEN_SDWIDTH_8 -- -- If Generate Description: -- This IfGen implements the AXI LEN qualifier calculation -- and the Stream data channel start/end STRB value. -- -- This IfGen is for the 8-bit Stream data Width case. -- ------------------------------------------------------------ GEN_LEN_SDWIDTH_8 : if (C_STREAM_DWIDTH = 8) generate -- Local Constants Constant AXI_SIZE2USE : std_logic_vector(2 downto 0) := AXI_SIZE_1BYTE; begin -- Assign the Address Channel Controller Qualifiers sig_next_size <= AXI_SIZE2USE; -- Assign the Data Channel Controller Qualifiers sig_next_strt_strb <= (others => '1'); sig_next_end_strb <= (others => '1'); end generate GEN_LEN_SDWIDTH_8; ------------------------------------------------------------- -- Synchronous Process with Sync Reset -- -- Label: CMD2DATA_VALID_FLOP -- -- Process Description: -- Implements the set/reset flop for the Command Ready control -- to the Data Controller Module. -- ------------------------------------------------------------- CMD2DATA_VALID_FLOP : process (primary_aclk) begin if (primary_aclk'event and primary_aclk = '1') then if (mmap_reset = '1' or sig_clr_cmd2data_valid = '1') then sig_cmd2data_valid <= '0'; elsif (sm_set_push2axi_ns = '1') then sig_cmd2data_valid <= '1'; else null; -- hold current state end if; end if; end process CMD2DATA_VALID_FLOP; ------------------------------------------------------------- -- Synchronous Process with Sync Reset -- -- Label: CMD2ADDR_VALID_FLOP -- -- Process Description: -- Implements the set/reset flop for the Command Ready control -- to the Address Controller Module. -- ------------------------------------------------------------- CMD2ADDR_VALID_FLOP : process (primary_aclk) begin if (primary_aclk'event and primary_aclk = '1') then if (mmap_reset = '1' or sig_clr_cmd2addr_valid = '1') then sig_cmd2addr_valid <= '0'; elsif (sm_set_push2axi_ns = '1') then sig_cmd2addr_valid <= '1'; else null; -- hold current state end if; end if; end process CMD2ADDR_VALID_FLOP; ------------------------------------------------------------- -- Synchronous Process with Sync Reset -- -- Label: SCC_SM_REG -- -- Process Description: -- Implements registered portion of state machine -- ------------------------------------------------------------- SCC_SM_REG : process (primary_aclk) begin if (primary_aclk'event and primary_aclk = '1') then if (mmap_reset = '1') then -- sm_scc_state <= INIT; -- sm_pop_input_cmd <= '0' ; -- sm_set_push2axi <= '0' ; sm_set_error <= '0' ; -- sm_scc_sm_ready <= '0' ; elsif (sig_btt_is_zero_reg = '1') then sm_set_error <= '1'; -- sm_scc_state <= sm_scc_state_ns ; -- sm_pop_input_cmd <= sm_pop_input_cmd_ns ; -- sm_set_push2axi <= sm_set_push2axi_ns ; -- sm_set_error <= sm_set_error_ns ; -- sm_scc_sm_ready <= sm_scc_sm_ready_ns ; end if; end if; end process SCC_SM_REG; end implementation;

gpl-3.0

96fe44f55d29501cc9aff291722adf2f

0.440891

4.716837

false

Fairyland0902/BlockyRoads

src/BlockyRoads/ipcore_dir/side/example_design/side_prod.vhd

1

9,891

-------------------------------------------------------------------------------- -- -- BLK MEM GEN v7.1 Core - Top-level wrapper -- -------------------------------------------------------------------------------- -- -- (c) Copyright 2006-2011 Xilinx, Inc. All rights reserved. -- -- This file contains confidential and proprietary information -- of Xilinx, Inc. and is protected under U.S. and -- international copyright and other intellectual property -- laws. -- -- DISCLAIMER -- This disclaimer is not a license and does not grant any -- rights to the materials distributed herewith. Except as -- otherwise provided in a valid license issued to you by -- Xilinx, and to the maximum extent permitted by applicable -- law: (1) THESE MATERIALS ARE MADE AVAILABLE "AS IS" AND -- WITH ALL FAULTS, AND XILINX HEREBY DISCLAIMS ALL WARRANTIES -- AND CONDITIONS, EXPRESS, IMPLIED, OR STATUTORY, INCLUDING -- BUT NOT LIMITED TO WARRANTIES OF MERCHANTABILITY, NON- -- INFRINGEMENT, OR FITNESS FOR ANY PARTICULAR PURPOSE; and -- (2) Xilinx shall not be liable (whether in contract or tort, -- including negligence, or under any other theory of -- liability) for any loss or damage of any kind or nature -- related to, arising under or in connection with these -- materials, including for any direct, or any indirect, -- special, incidental, or consequential loss or damage -- (including loss of data, profits, goodwill, or any type of -- loss or damage suffered as a result of any action brought -- by a third party) even if such damage or loss was -- reasonably foreseeable or Xilinx had been advised of the -- possibility of the same. -- -- CRITICAL APPLICATIONS -- Xilinx products are not designed or intended to be fail- -- safe, or for use in any application requiring fail-safe -- performance, such as life-support or safety devices or -- systems, Class III medical devices, nuclear facilities, -- applications related to the deployment of airbags, or any -- other applications that could lead to death, personal -- injury, or severe property or environmental damage -- (individually and collectively, "Critical -- Applications"). Customer assumes the sole risk and -- liability of any use of Xilinx products in Critical -- Applications, subject only to applicable laws and -- regulations governing limitations on product liability. -- -- THIS COPYRIGHT NOTICE AND DISCLAIMER MUST BE RETAINED AS -- PART OF THIS FILE AT ALL TIMES. -- -------------------------------------------------------------------------------- -- -- Filename: side_prod.vhd -- -- Description: -- This is the top-level BMG wrapper (over BMG core). -- -------------------------------------------------------------------------------- -- Author: IP Solutions Division -- -- History: August 31, 2005 - First Release -------------------------------------------------------------------------------- -- -- Configured Core Parameter Values: -- (Refer to the SIM Parameters table in the datasheet for more information on -- the these parameters.) -- C_FAMILY : artix7 -- C_XDEVICEFAMILY : artix7 -- C_INTERFACE_TYPE : 0 -- C_ENABLE_32BIT_ADDRESS : 0 -- C_AXI_TYPE : 1 -- C_AXI_SLAVE_TYPE : 0 -- C_AXI_ID_WIDTH : 4 -- C_MEM_TYPE : 3 -- C_BYTE_SIZE : 9 -- C_ALGORITHM : 1 -- C_PRIM_TYPE : 1 -- C_LOAD_INIT_FILE : 1 -- C_INIT_FILE_NAME : side.mif -- C_USE_DEFAULT_DATA : 0 -- C_DEFAULT_DATA : 0 -- C_RST_TYPE : SYNC -- C_HAS_RSTA : 0 -- C_RST_PRIORITY_A : CE -- C_RSTRAM_A : 0 -- C_INITA_VAL : 0 -- C_HAS_ENA : 0 -- C_HAS_REGCEA : 0 -- C_USE_BYTE_WEA : 0 -- C_WEA_WIDTH : 1 -- C_WRITE_MODE_A : WRITE_FIRST -- C_WRITE_WIDTH_A : 12 -- C_READ_WIDTH_A : 12 -- C_WRITE_DEPTH_A : 76800 -- C_READ_DEPTH_A : 76800 -- C_ADDRA_WIDTH : 17 -- C_HAS_RSTB : 0 -- C_RST_PRIORITY_B : CE -- C_RSTRAM_B : 0 -- C_INITB_VAL : 0 -- C_HAS_ENB : 0 -- C_HAS_REGCEB : 0 -- C_USE_BYTE_WEB : 0 -- C_WEB_WIDTH : 1 -- C_WRITE_MODE_B : WRITE_FIRST -- C_WRITE_WIDTH_B : 12 -- C_READ_WIDTH_B : 12 -- C_WRITE_DEPTH_B : 76800 -- C_READ_DEPTH_B : 76800 -- C_ADDRB_WIDTH : 17 -- C_HAS_MEM_OUTPUT_REGS_A : 0 -- C_HAS_MEM_OUTPUT_REGS_B : 0 -- C_HAS_MUX_OUTPUT_REGS_A : 0 -- C_HAS_MUX_OUTPUT_REGS_B : 0 -- C_HAS_SOFTECC_INPUT_REGS_A : 0 -- C_HAS_SOFTECC_OUTPUT_REGS_B : 0 -- C_MUX_PIPELINE_STAGES : 0 -- C_USE_ECC : 0 -- C_USE_SOFTECC : 0 -- C_HAS_INJECTERR : 0 -- C_SIM_COLLISION_CHECK : ALL -- C_COMMON_CLK : 0 -- C_DISABLE_WARN_BHV_COLL : 0 -- C_DISABLE_WARN_BHV_RANGE : 0 -------------------------------------------------------------------------------- -- Library Declarations -------------------------------------------------------------------------------- LIBRARY IEEE; USE IEEE.STD_LOGIC_1164.ALL; USE IEEE.STD_LOGIC_ARITH.ALL; USE IEEE.STD_LOGIC_UNSIGNED.ALL; LIBRARY UNISIM; USE UNISIM.VCOMPONENTS.ALL; -------------------------------------------------------------------------------- -- Entity Declaration -------------------------------------------------------------------------------- ENTITY side_prod IS PORT ( --Port A CLKA : IN STD_LOGIC; RSTA : IN STD_LOGIC; --opt port ENA : IN STD_LOGIC; --optional port REGCEA : IN STD_LOGIC; --optional port WEA : IN STD_LOGIC_VECTOR(0 DOWNTO 0); ADDRA : IN STD_LOGIC_VECTOR(16 DOWNTO 0); DINA : IN STD_LOGIC_VECTOR(11 DOWNTO 0); DOUTA : OUT STD_LOGIC_VECTOR(11 DOWNTO 0); --Port B CLKB : IN STD_LOGIC; RSTB : IN STD_LOGIC; --opt port ENB : IN STD_LOGIC; --optional port REGCEB : IN STD_LOGIC; --optional port WEB : IN STD_LOGIC_VECTOR(0 DOWNTO 0); ADDRB : IN STD_LOGIC_VECTOR(16 DOWNTO 0); DINB : IN STD_LOGIC_VECTOR(11 DOWNTO 0); DOUTB : OUT STD_LOGIC_VECTOR(11 DOWNTO 0); --ECC INJECTSBITERR : IN STD_LOGIC; --optional port INJECTDBITERR : IN STD_LOGIC; --optional port SBITERR : OUT STD_LOGIC; --optional port DBITERR : OUT STD_LOGIC; --optional port RDADDRECC : OUT STD_LOGIC_VECTOR(16 DOWNTO 0); --optional port -- AXI BMG Input and Output Port Declarations -- AXI Global Signals S_ACLK : IN STD_LOGIC; S_AXI_AWID : IN STD_LOGIC_VECTOR(3 DOWNTO 0); S_AXI_AWADDR : IN STD_LOGIC_VECTOR(31 DOWNTO 0); S_AXI_AWLEN : IN STD_LOGIC_VECTOR(7 DOWNTO 0); S_AXI_AWSIZE : IN STD_LOGIC_VECTOR(2 DOWNTO 0); S_AXI_AWBURST : IN STD_LOGIC_VECTOR(1 DOWNTO 0); S_AXI_AWVALID : IN STD_LOGIC; S_AXI_AWREADY : OUT STD_LOGIC; S_AXI_WDATA : IN STD_LOGIC_VECTOR(11 DOWNTO 0); S_AXI_WSTRB : IN STD_LOGIC_VECTOR(0 DOWNTO 0); S_AXI_WLAST : IN STD_LOGIC; S_AXI_WVALID : IN STD_LOGIC; S_AXI_WREADY : OUT STD_LOGIC; S_AXI_BID : OUT STD_LOGIC_VECTOR(3 DOWNTO 0):= (OTHERS => '0'); S_AXI_BRESP : OUT STD_LOGIC_VECTOR(1 DOWNTO 0); S_AXI_BVALID : OUT STD_LOGIC; S_AXI_BREADY : IN STD_LOGIC; -- AXI Full/Lite Slave Read (Write side) S_AXI_ARID : IN STD_LOGIC_VECTOR(3 DOWNTO 0); S_AXI_ARADDR : IN STD_LOGIC_VECTOR(31 DOWNTO 0); S_AXI_ARLEN : IN STD_LOGIC_VECTOR(7 DOWNTO 0); S_AXI_ARSIZE : IN STD_LOGIC_VECTOR(2 DOWNTO 0); S_AXI_ARBURST : IN STD_LOGIC_VECTOR(1 DOWNTO 0); S_AXI_ARVALID : IN STD_LOGIC; S_AXI_ARREADY : OUT STD_LOGIC; S_AXI_RID : OUT STD_LOGIC_VECTOR(3 DOWNTO 0):= (OTHERS => '0'); S_AXI_RDATA : OUT STD_LOGIC_VECTOR(11 DOWNTO 0); S_AXI_RRESP : OUT STD_LOGIC_VECTOR(1 DOWNTO 0); S_AXI_RLAST : OUT STD_LOGIC; S_AXI_RVALID : OUT STD_LOGIC; S_AXI_RREADY : IN STD_LOGIC; -- AXI Full/Lite Sideband Signals S_AXI_INJECTSBITERR : IN STD_LOGIC; S_AXI_INJECTDBITERR : IN STD_LOGIC; S_AXI_SBITERR : OUT STD_LOGIC; S_AXI_DBITERR : OUT STD_LOGIC; S_AXI_RDADDRECC : OUT STD_LOGIC_VECTOR(16 DOWNTO 0); S_ARESETN : IN STD_LOGIC ); END side_prod; ARCHITECTURE xilinx OF side_prod IS COMPONENT side_exdes IS PORT ( --Port A ADDRA : IN STD_LOGIC_VECTOR(16 DOWNTO 0); DOUTA : OUT STD_LOGIC_VECTOR(11 DOWNTO 0); CLKA : IN STD_LOGIC ); END COMPONENT; BEGIN bmg0 : side_exdes PORT MAP ( --Port A ADDRA => ADDRA, DOUTA => DOUTA, CLKA => CLKA ); END xilinx;

mit

647cf060539644620b57709379457c62

0.493984

3.835207

false

marco-c/leon-nexys2

grlib-gpl-1.3.4-b4140/lib/techmap/inferred/mul_inferred.vhd

1

4,244

------------------------------------------------------------------------------ -- This file is a part of the GRLIB VHDL IP LIBRARY -- Copyright (C) 2003 - 2008, Gaisler Research -- Copyright (C) 2008 - 2013, Aeroflex Gaisler -- -- This program is free software; you can redistribute it and/or modify -- it under the terms of the GNU General Public License as published by -- the Free Software Foundation; either version 2 of the License, or -- (at your option) any later version. -- -- This program is distributed in the hope that it will be useful, -- but WITHOUT ANY WARRANTY; without even the implied warranty of -- MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the -- GNU General Public License for more details. -- -- You should have received a copy of the GNU General Public License -- along with this program; if not, write to the Free Software -- Foundation, Inc., 59 Temple Place, Suite 330, Boston, MA 02111-1307 USA ----------------------------------------------------------------------------- -- Entity: gen_mul_61x61 -- File: mul_inferred.vhd -- Author: Edvin Catovic - Gaisler Research -- Description: Generic 61x61 multplier ------------------------------------------------------------------------------ library ieee; use ieee.std_logic_1164.all; use ieee.numeric_std.all; library grlib; use grlib.stdlib.all; entity gen_mul_61x61 is port(A : in std_logic_vector(60 downto 0); B : in std_logic_vector(60 downto 0); EN : in std_logic; CLK : in std_logic; PRODUCT : out std_logic_vector(121 downto 0)); end; architecture rtl of gen_mul_61x61 is signal r1, r1in, r2, r2in : std_logic_vector(121 downto 0); begin comb : process(A, B, r1) begin -- pragma translate_off if not (is_x(A) or is_x(B)) then -- pragma translate_on r1in <= std_logic_vector(unsigned(A) * unsigned(B)); -- pragma translate_off end if; -- pragma translate_on r2in <= r1; end process; reg : process(clk) begin if rising_edge(clk) then if EN = '1' then r1 <= r1in; r2 <= r2in; end if; end if; end process; PRODUCT <= r2; end; library IEEE; use IEEE.std_logic_1164.all; use IEEE.std_logic_arith.all; library grlib; use grlib.stdlib.all; entity gen_mult_pipe is generic ( a_width : positive; -- multiplier word width b_width : positive; -- multiplicand word width num_stages : positive := 2; -- number of pipeline stages stall_mode : natural range 0 to 1 := 1); -- '0': non-stallable; '1': stallable port ( clk : in std_logic; -- register clock en : in std_logic; -- register enable tc : in std_logic; -- '0' : unsigned, '1' : signed a : in std_logic_vector(a_width-1 downto 0); -- multiplier b : in std_logic_vector(b_width-1 downto 0); -- multiplicand product : out std_logic_vector(a_width+b_width-1 downto 0)); -- product end ; architecture simple of gen_mult_pipe is subtype resw is std_logic_vector(A_width+B_width-1 downto 0); type pipet is array (num_stages-1 downto 1) of resw; signal p_i : pipet; signal prod : resw; begin comb : process(A, B, TC) begin -- pragma translate_off if notx(A) and notx(B) and notx(tc) then -- pragma translate_on if TC = '1' then prod <= signed(A) * signed(B); else prod <= unsigned(A) * unsigned(B); end if; -- pragma translate_off else prod <= (others => 'X'); end if; -- pragma translate_on end process; w2 : if num_stages = 2 generate reg : process(clk) begin if rising_edge(clk) then if (stall_mode = 0) or (en = '1') then p_i(1) <= prod; end if; end if; end process; end generate; w3 : if num_stages > 2 generate reg : process(clk) begin if rising_edge(clk) then if (stall_mode = 0) or (en = '1') then p_i <= p_i(num_stages-2 downto 1) & prod; end if; end if; end process; end generate; product <= p_i(num_stages-1); end;

gpl-2.0

3f2f71ec8eb001a17149b935abd97ace

0.56951

3.566387

false

capitanov/Stupid_watch

src/rtl/keyboard/debounce.vhd

1

2,498

-------------------------------------------------------------------------------- -- -- FileName: debounce.vhd -- Dependencies: none -- Design Software: Quartus II 32-bit Version 11.1 Build 173 SJ Full Version -- -- HDL CODE IS PROVIDED "AS IS." DIGI-KEY EXPRESSLY DISCLAIMS ANY -- WARRANTY OF ANY KIND, WHETHER EXPRESS OR IMPLIED, INCLUDING BUT NOT -- LIMITED TO, THE IMPLIED WARRANTIES OF MERCHANTABILITY, FITNESS FOR A -- PARTICULAR PURPOSE, OR NON-INFRINGEMENT. IN NO EVENT SHALL DIGI-KEY -- BE LIABLE FOR ANY INCIDENTAL, SPECIAL, INDIRECT OR CONSEQUENTIAL -- DAMAGES, LOST PROFITS OR LOST DATA, HARM TO YOUR EQUIPMENT, COST OF -- PROCUREMENT OF SUBSTITUTE GOODS, TECHNOLOGY OR SERVICES, ANY CLAIMS -- BY THIRD PARTIES (INCLUDING BUT NOT LIMITED TO ANY DEFENSE THEREOF), -- ANY CLAIMS FOR INDEMNITY OR CONTRIBUTION, OR OTHER SIMILAR COSTS. -- -- Version History -- Version 1.0 3/26/2012 Scott Larson -- Initial Public Release -- -------------------------------------------------------------------------------- LIBRARY ieee; USE ieee.std_logic_1164.all; USE ieee.std_logic_unsigned.all; entity debounce is generic( counter_size : integer --! counter size (19 bits gives 10.5ms with 50MHz clock) ); port( clk : in std_logic; --! input clock button : in std_logic; --! input signal to be debounced result : out std_logic --! debounced signal ); end debounce; architecture debounce of debounce is signal flipflops : std_logic_vector(1 downto 0); --input flip flops signal counter_set : std_logic; --sync reset to zero signal counter_out : std_logic_vector(counter_size downto 0) := (others => '0'); --counter output begin counter_set <= flipflops(0) xor flipflops(1); --determine when to start/reset counter pr_deb: process(clk) begin if (clk'event and clk = '1') then flipflops(0) <= button; flipflops(1) <= flipflops(0); if (counter_set = '1') then --reset counter because input is changing counter_out <= (others => '0'); elsif (counter_out(counter_size) = '0') then --stable input time is not yet met counter_out <= counter_out + 1; else --stable input time is met result <= flipflops(1); end if; end if; end process; end debounce;

mit

ab0d1eb681b87232402c4178e26f1512

0.580064

4.321799

false

marco-c/leon-nexys2

grlib-gpl-1.3.4-b4140/designs/leon3-altera-ep2s60-sdr/config.vhd

1

5,586

----------------------------------------------------------------------------- -- LEON3 Demonstration design test bench configuration -- Copyright (C) 2009 Aeroflex Gaisler ------------------------------------------------------------------------------ library techmap; use techmap.gencomp.all; package config is -- Technology and synthesis options constant CFG_FABTECH : integer := stratix2; constant CFG_MEMTECH : integer := stratix2; constant CFG_PADTECH : integer := stratix2; constant CFG_NOASYNC : integer := 0; constant CFG_SCAN : integer := 0; -- Clock generator constant CFG_CLKTECH : integer := stratix2; constant CFG_CLKMUL : integer := (8); constant CFG_CLKDIV : integer := (10); constant CFG_OCLKDIV : integer := 1; constant CFG_OCLKBDIV : integer := 0; constant CFG_OCLKCDIV : integer := 0; constant CFG_PCIDLL : integer := 0; constant CFG_PCISYSCLK: integer := 0; constant CFG_CLK_NOFB : integer := 0; -- LEON3 processor core constant CFG_LEON3 : integer := 1; constant CFG_NCPU : integer := (1); constant CFG_NWIN : integer := (8); constant CFG_V8 : integer := 2 + 4*0; constant CFG_MAC : integer := 0; constant CFG_BP : integer := 0; constant CFG_SVT : integer := 0; constant CFG_RSTADDR : integer := 16#00000#; constant CFG_LDDEL : integer := (1); constant CFG_NOTAG : integer := 0; constant CFG_NWP : integer := (2); constant CFG_PWD : integer := 0*2; constant CFG_FPU : integer := 0 + 16*0 + 32*0; constant CFG_GRFPUSH : integer := 0; constant CFG_ICEN : integer := 1; constant CFG_ISETS : integer := 2; constant CFG_ISETSZ : integer := 8; constant CFG_ILINE : integer := 8; constant CFG_IREPL : integer := 0; constant CFG_ILOCK : integer := 0; constant CFG_ILRAMEN : integer := 0; constant CFG_ILRAMADDR: integer := 16#8E#; constant CFG_ILRAMSZ : integer := 1; constant CFG_DCEN : integer := 1; constant CFG_DSETS : integer := 2; constant CFG_DSETSZ : integer := 4; constant CFG_DLINE : integer := 4; constant CFG_DREPL : integer := 0; constant CFG_DLOCK : integer := 0; constant CFG_DSNOOP : integer := 1 + 0 + 4*0; constant CFG_DFIXED : integer := 16#0#; constant CFG_DLRAMEN : integer := 0; constant CFG_DLRAMADDR: integer := 16#8F#; constant CFG_DLRAMSZ : integer := 1; constant CFG_MMUEN : integer := 1; constant CFG_ITLBNUM : integer := 8; constant CFG_DTLBNUM : integer := 8; constant CFG_TLB_TYPE : integer := 0 + 1*2; constant CFG_TLB_REP : integer := 0; constant CFG_MMU_PAGE : integer := 0; constant CFG_DSU : integer := 1; constant CFG_ITBSZ : integer := 2; constant CFG_ATBSZ : integer := 2; constant CFG_LEON3FT_EN : integer := 0; constant CFG_IUFT_EN : integer := 0; constant CFG_FPUFT_EN : integer := 0; constant CFG_RF_ERRINJ : integer := 0; constant CFG_CACHE_FT_EN : integer := 0; constant CFG_CACHE_ERRINJ : integer := 0; constant CFG_LEON3_NETLIST: integer := 0; constant CFG_DISAS : integer := 0 + 0; constant CFG_PCLOW : integer := 2; -- AMBA settings constant CFG_DEFMST : integer := (0); constant CFG_RROBIN : integer := 1; constant CFG_SPLIT : integer := 0; constant CFG_FPNPEN : integer := 0; constant CFG_AHBIO : integer := 16#FFF#; constant CFG_APBADDR : integer := 16#800#; constant CFG_AHB_MON : integer := 0; constant CFG_AHB_MONERR : integer := 0; constant CFG_AHB_MONWAR : integer := 0; constant CFG_AHB_DTRACE : integer := 0; -- DSU UART constant CFG_AHB_UART : integer := 1; -- JTAG based DSU interface constant CFG_AHB_JTAG : integer := 1; -- PROM/SRAM controller constant CFG_SRCTRL : integer := 0; constant CFG_SRCTRL_PROMWS : integer := 0; constant CFG_SRCTRL_RAMWS : integer := 0; constant CFG_SRCTRL_IOWS : integer := 0; constant CFG_SRCTRL_RMW : integer := 0; constant CFG_SRCTRL_8BIT : integer := 0; constant CFG_SRCTRL_SRBANKS : integer := 1; constant CFG_SRCTRL_BANKSZ : integer := 0; constant CFG_SRCTRL_ROMASEL : integer := 0; -- LEON2 memory controller constant CFG_MCTRL_LEON2 : integer := 1; constant CFG_MCTRL_RAM8BIT : integer := 1; constant CFG_MCTRL_RAM16BIT : integer := 0; constant CFG_MCTRL_5CS : integer := 0; constant CFG_MCTRL_SDEN : integer := 1; constant CFG_MCTRL_SEPBUS : integer := 1; constant CFG_MCTRL_INVCLK : integer := 0; constant CFG_MCTRL_SD64 : integer := 0; constant CFG_MCTRL_PAGE : integer := 1 + 0; -- AHB ROM constant CFG_AHBROMEN : integer := 0; constant CFG_AHBROPIP : integer := 0; constant CFG_AHBRODDR : integer := 16#000#; constant CFG_ROMADDR : integer := 16#000#; constant CFG_ROMMASK : integer := 16#E00# + 16#000#; -- AHB RAM constant CFG_AHBRAMEN : integer := 0; constant CFG_AHBRSZ : integer := 1; constant CFG_AHBRADDR : integer := 16#A00#; constant CFG_AHBRPIPE : integer := 0; -- UART 1 constant CFG_UART1_ENABLE : integer := 1; constant CFG_UART1_FIFO : integer := 8; -- LEON3 interrupt controller constant CFG_IRQ3_ENABLE : integer := 1; constant CFG_IRQ3_NSEC : integer := 0; -- Modular timer constant CFG_GPT_ENABLE : integer := 1; constant CFG_GPT_NTIM : integer := (2); constant CFG_GPT_SW : integer := (8); constant CFG_GPT_TW : integer := (32); constant CFG_GPT_IRQ : integer := (8); constant CFG_GPT_SEPIRQ : integer := 1; constant CFG_GPT_WDOGEN : integer := 0; constant CFG_GPT_WDOG : integer := 16#0#; -- GPIO port constant CFG_GRGPIO_ENABLE : integer := 1; constant CFG_GRGPIO_IMASK : integer := 16#FFFF#; constant CFG_GRGPIO_WIDTH : integer := (32); -- GRLIB debugging constant CFG_DUART : integer := 0; end;

gpl-2.0

43a50b3a7ca53553a0e7258e17f2a461

0.645184

3.670171

false

marco-c/leon-nexys2

grlib-gpl-1.3.4-b4140/designs/leon3-ztex-ufm-115/testbench.vhd

1

7,756

------------------------------------------------------------------------------- -- LEON3 Demonstration design test bench -- Copyright (C) 2011 Aeroflex Gaisler AB ------------------------------------------------------------------------------ -- This file is a part of the GRLIB VHDL IP LIBRARY -- Copyright (C) 2003 - 2008, Gaisler Research -- Copyright (C) 2008 - 2013, Aeroflex Gaisler -- -- This program is free software; you can redistribute it and/or modify -- it under the terms of the GNU General Public License as published by -- the Free Software Foundation; either version 2 of the License, or -- (at your option) any later version. -- -- This program is distributed in the hope that it will be useful, -- but WITHOUT ANY WARRANTY; without even the implied warranty of -- MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the -- GNU General Public License for more details. -- -- You should have received a copy of the GNU General Public License -- along with this program; if not, write to the Free Software -- Foundation, Inc., 59 Temple Place, Suite 330, Boston, MA 02111-1307 USA ------------------------------------------------------------------------------- library ieee; use ieee.std_logic_1164.all; library gaisler; use gaisler.libdcom.all; use gaisler.sim.all; library techmap; use techmap.gencomp.all; library micron; use micron.components.all; library hynix; use hynix.components.all; use work.debug.all; use work.config.all; library hynix; use hynix.components.all; use hynix.HY5PS121621F_PACK.all; entity testbench is generic ( fabtech : integer := CFG_FABTECH; memtech : integer := CFG_MEMTECH; padtech : integer := CFG_PADTECH; clktech : integer := CFG_CLKTECH; disas : integer := CFG_DISAS; -- Enable disassembly to console dbguart : integer := CFG_DUART; -- Print UART on console pclow : integer := CFG_PCLOW ); end; architecture behav of testbench is constant promfile : string := "prom.srec"; -- rom contents constant sdramfile : string := "ram.srec"; -- sdram contents constant lresp : boolean := false; signal reset : std_ulogic := '1'; signal clk48 : std_ulogic := '0'; signal errorn : std_logic; signal mcb3_dram_dq : std_logic_vector(15 downto 0); signal mcb3_rzq : std_logic; signal mcb3_zio : std_logic; signal mcb3_dram_udqs : std_logic; signal mcb3_dram_udqs_n : std_logic; signal mcb3_dram_dqs : std_logic; signal mcb3_dram_dqs_n : std_logic; signal mcb3_dram_a : std_logic_vector(12 downto 0); signal mcb3_dram_ba : std_logic_vector(2 downto 0); signal mcb3_dram_cke : std_logic; signal mcb3_dram_ras_n : std_logic; signal mcb3_dram_cas_n : std_logic; signal mcb3_dram_we_n : std_logic; signal mcb3_dram_dm : std_logic; signal mcb3_dram_udm : std_logic; signal mcb3_dram_ck : std_logic; signal mcb3_dram_ck_n : std_logic; signal dsubre : std_ulogic; -- Debug Unit break (connect to button) signal dsuact : std_ulogic; -- Debug Unit break (connect to button) signal dsurx : std_ulogic; signal dsutx : std_ulogic; signal rxd1 : std_ulogic; signal txd1 : std_ulogic; signal sd_dat : std_logic; signal sd_cmd : std_logic; signal sd_sck : std_logic; signal sd_dat3 : std_logic; signal csb : std_logic := '0'; -- dummy begin -- clock and reset clk48 <= not clk48 after 10.05 ns; reset <= '1', '0' after 300 ns; dsubre <= '0'; sd_dat <= 'H'; sd_cmd <= 'H'; sd_sck <= 'H'; d3 : entity work.leon3mp generic map (fabtech, memtech, padtech, clktech, disas, dbguart, pclow) port map ( reset => reset, clk48 => clk48, -- Processor error output errorn => errorn, -- DDR SDRAM mcb3_dram_dq => mcb3_dram_dq, mcb3_rzq => mcb3_rzq, mcb3_zio => mcb3_zio, mcb3_dram_udqs => mcb3_dram_udqs, mcb3_dram_udqs_n => mcb3_dram_udqs_n, mcb3_dram_dqs => mcb3_dram_dqs, mcb3_dram_dqs_n => mcb3_dram_dqs_n, mcb3_dram_a => mcb3_dram_a, mcb3_dram_ba => mcb3_dram_ba, mcb3_dram_cke => mcb3_dram_cke, mcb3_dram_ras_n => mcb3_dram_ras_n, mcb3_dram_cas_n => mcb3_dram_cas_n, mcb3_dram_we_n => mcb3_dram_we_n, mcb3_dram_dm => mcb3_dram_dm, mcb3_dram_udm => mcb3_dram_udm, mcb3_dram_ck => mcb3_dram_ck, mcb3_dram_ck_n => mcb3_dram_ck_n, -- Debug support unit dsubre => dsubre, dsuact => dsuact, -- AHB UART (debug link) dsurx => dsurx, dsutx => dsutx, -- UART rxd1 => rxd1, txd1 => txd1, -- SD card sd_dat => sd_dat, sd_cmd => sd_cmd, sd_sck => sd_sck, sd_dat3 => sd_dat3 ); migddr2mem : if (CFG_MIG_DDR2 = 1) generate u0 : HY5PS121621F generic map (TimingCheckFlag => false, PUSCheckFlag => false, index => 0, bbits => 16, fname => sdramfile, fdelay => 115, part_number => B800) port map (DQ => mcb3_dram_dq, LDQS => mcb3_dram_dqs, LDQSB => mcb3_dram_dqs_n, UDQS => mcb3_dram_udqs, UDQSB => mcb3_dram_udqs_n, LDM => mcb3_dram_dm, WEB => mcb3_dram_we_n, CASB => mcb3_dram_cas_n, RASB => mcb3_dram_ras_n, CSB => csb, BA => mcb3_dram_ba(1 downto 0), ADDR => mcb3_dram_a, CKE => mcb3_dram_cke, CLK => mcb3_dram_ck, CLKB => mcb3_dram_ck_n, UDM => mcb3_dram_udm); end generate; --spimem0: if CFG_SPIMCTRL = 1 generate -- s0 : spi_flash generic map (ftype => 4, debug => 0, fname => promfile, -- readcmd => CFG_SPIMCTRL_READCMD, -- dummybyte => CFG_SPIMCTRL_DUMMYBYTE, -- dualoutput => 0) -- Dual output is not supported in this design -- port map (spi_clk, spi_mosi, data(24), spi_sel_n); --end generate spimem0; iuerr : process begin wait for 5 us; assert (to_X01(errorn) = '1') report "*** IU in error mode, simulation halted ***" severity failure; end process; dsucom : process procedure dsucfg(signal dsurx : in std_ulogic; signal dsutx : out std_ulogic) is variable w32 : std_logic_vector(31 downto 0); variable c8 : std_logic_vector(7 downto 0); constant txp : time := 160 * 1 ns; begin dsutx <= '1'; wait; wait for 5000 ns; txc(dsutx, 16#55#, txp); -- sync uart txc(dsutx, 16#a0#, txp); txa(dsutx, 16#40#, 16#00#, 16#00#, 16#00#, txp); rxi(dsurx, w32, txp, lresp); -- txc(dsutx, 16#c0#, txp); -- txa(dsutx, 16#90#, 16#00#, 16#00#, 16#00#, txp); -- txa(dsutx, 16#00#, 16#00#, 16#00#, 16#ef#, txp); -- -- txc(dsutx, 16#c0#, txp); -- txa(dsutx, 16#90#, 16#00#, 16#00#, 16#20#, txp); -- txa(dsutx, 16#00#, 16#00#, 16#ff#, 16#ff#, txp); -- -- txc(dsutx, 16#c0#, txp); -- txa(dsutx, 16#90#, 16#40#, 16#00#, 16#48#, txp); -- txa(dsutx, 16#00#, 16#00#, 16#00#, 16#12#, txp); -- -- txc(dsutx, 16#c0#, txp); -- txa(dsutx, 16#90#, 16#40#, 16#00#, 16#60#, txp); -- txa(dsutx, 16#00#, 16#00#, 16#12#, 16#10#, txp); -- -- txc(dsutx, 16#80#, txp); -- txa(dsutx, 16#90#, 16#00#, 16#00#, 16#00#, txp); -- rxi(dsurx, w32, txp, lresp); end; begin dsucfg(dsutx, dsurx); wait; end process; end;

gpl-2.0

855131504a4f344108d4444e2b14a596

0.54835

3.318785

false

mistryalok/Zedboard

learning/opencv_hls/xapp1167_vivado/sw/median/prj/solution1/syn/vhdl/image_filter_Mat2AXIvideo.vhd

2

23,118

-- ============================================================== -- RTL generated by Vivado(TM) HLS - High-Level Synthesis from C, C++ and SystemC -- Version: 2014.4 -- Copyright (C) 2014 Xilinx Inc. All rights reserved. -- -- =========================================================== library IEEE; use IEEE.std_logic_1164.all; use IEEE.numeric_std.all; entity image_filter_Mat2AXIvideo is port ( ap_clk : IN STD_LOGIC; ap_rst : IN STD_LOGIC; ap_start : IN STD_LOGIC; ap_done : OUT STD_LOGIC; ap_continue : IN STD_LOGIC; ap_idle : OUT STD_LOGIC; ap_ready : OUT STD_LOGIC; img_rows_V_read : IN STD_LOGIC_VECTOR (11 downto 0); img_cols_V_read : IN STD_LOGIC_VECTOR (11 downto 0); img_data_stream_0_V_dout : IN STD_LOGIC_VECTOR (7 downto 0); img_data_stream_0_V_empty_n : IN STD_LOGIC; img_data_stream_0_V_read : OUT STD_LOGIC; img_data_stream_1_V_dout : IN STD_LOGIC_VECTOR (7 downto 0); img_data_stream_1_V_empty_n : IN STD_LOGIC; img_data_stream_1_V_read : OUT STD_LOGIC; img_data_stream_2_V_dout : IN STD_LOGIC_VECTOR (7 downto 0); img_data_stream_2_V_empty_n : IN STD_LOGIC; img_data_stream_2_V_read : OUT STD_LOGIC; OUTPUT_STREAM_TDATA : OUT STD_LOGIC_VECTOR (31 downto 0); OUTPUT_STREAM_TVALID : OUT STD_LOGIC; OUTPUT_STREAM_TREADY : IN STD_LOGIC; OUTPUT_STREAM_TKEEP : OUT STD_LOGIC_VECTOR (3 downto 0); OUTPUT_STREAM_TSTRB : OUT STD_LOGIC_VECTOR (3 downto 0); OUTPUT_STREAM_TUSER : OUT STD_LOGIC_VECTOR (0 downto 0); OUTPUT_STREAM_TLAST : OUT STD_LOGIC_VECTOR (0 downto 0); OUTPUT_STREAM_TID : OUT STD_LOGIC_VECTOR (0 downto 0); OUTPUT_STREAM_TDEST : OUT STD_LOGIC_VECTOR (0 downto 0) ); end; architecture behav of image_filter_Mat2AXIvideo is constant ap_const_logic_1 : STD_LOGIC := '1'; constant ap_const_logic_0 : STD_LOGIC := '0'; constant ap_ST_st1_fsm_0 : STD_LOGIC_VECTOR (3 downto 0) := "0001"; constant ap_ST_st2_fsm_1 : STD_LOGIC_VECTOR (3 downto 0) := "0010"; constant ap_ST_pp0_stg0_fsm_2 : STD_LOGIC_VECTOR (3 downto 0) := "0100"; constant ap_ST_st5_fsm_3 : STD_LOGIC_VECTOR (3 downto 0) := "1000"; constant ap_const_lv32_0 : STD_LOGIC_VECTOR (31 downto 0) := "00000000000000000000000000000000"; constant ap_const_lv1_1 : STD_LOGIC_VECTOR (0 downto 0) := "1"; constant ap_const_lv32_1 : STD_LOGIC_VECTOR (31 downto 0) := "00000000000000000000000000000001"; constant ap_const_lv32_2 : STD_LOGIC_VECTOR (31 downto 0) := "00000000000000000000000000000010"; constant ap_const_lv1_0 : STD_LOGIC_VECTOR (0 downto 0) := "0"; constant ap_const_lv12_0 : STD_LOGIC_VECTOR (11 downto 0) := "000000000000"; constant ap_const_lv32_3 : STD_LOGIC_VECTOR (31 downto 0) := "00000000000000000000000000000011"; constant ap_const_lv4_F : STD_LOGIC_VECTOR (3 downto 0) := "1111"; constant ap_const_lv4_0 : STD_LOGIC_VECTOR (3 downto 0) := "0000"; constant ap_const_lv13_1FFF : STD_LOGIC_VECTOR (12 downto 0) := "1111111111111"; constant ap_const_lv12_1 : STD_LOGIC_VECTOR (11 downto 0) := "000000000001"; constant ap_const_lv8_FF : STD_LOGIC_VECTOR (7 downto 0) := "11111111"; signal ap_done_reg : STD_LOGIC := '0'; signal ap_CS_fsm : STD_LOGIC_VECTOR (3 downto 0) := "0001"; attribute fsm_encoding : string; attribute fsm_encoding of ap_CS_fsm : signal is "none"; signal ap_sig_cseq_ST_st1_fsm_0 : STD_LOGIC; signal ap_sig_bdd_23 : BOOLEAN; signal p_3_reg_170 : STD_LOGIC_VECTOR (11 downto 0); signal ap_sig_bdd_60 : BOOLEAN; signal op2_assign_fu_186_p2 : STD_LOGIC_VECTOR (12 downto 0); signal op2_assign_reg_267 : STD_LOGIC_VECTOR (12 downto 0); signal exitcond3_fu_197_p2 : STD_LOGIC_VECTOR (0 downto 0); signal ap_sig_cseq_ST_st2_fsm_1 : STD_LOGIC; signal ap_sig_bdd_74 : BOOLEAN; signal i_V_fu_202_p2 : STD_LOGIC_VECTOR (11 downto 0); signal i_V_reg_276 : STD_LOGIC_VECTOR (11 downto 0); signal exitcond4_fu_208_p2 : STD_LOGIC_VECTOR (0 downto 0); signal exitcond4_reg_281 : STD_LOGIC_VECTOR (0 downto 0); signal ap_sig_cseq_ST_pp0_stg0_fsm_2 : STD_LOGIC; signal ap_sig_bdd_85 : BOOLEAN; signal ap_reg_ppiten_pp0_it0 : STD_LOGIC := '0'; signal ap_sig_bdd_99 : BOOLEAN; signal ap_sig_ioackin_OUTPUT_STREAM_TREADY : STD_LOGIC; signal ap_reg_ppiten_pp0_it1 : STD_LOGIC := '0'; signal j_V_fu_213_p2 : STD_LOGIC_VECTOR (11 downto 0); signal axi_last_V_fu_223_p2 : STD_LOGIC_VECTOR (0 downto 0); signal axi_last_V_reg_290 : STD_LOGIC_VECTOR (0 downto 0); signal p_s_reg_159 : STD_LOGIC_VECTOR (11 downto 0); signal ap_sig_cseq_ST_st5_fsm_3 : STD_LOGIC; signal ap_sig_bdd_130 : BOOLEAN; signal tmp_user_V_fu_96 : STD_LOGIC_VECTOR (0 downto 0); signal ap_reg_ioackin_OUTPUT_STREAM_TREADY : STD_LOGIC := '0'; signal tmp_cast_fu_182_p1 : STD_LOGIC_VECTOR (12 downto 0); signal tmp_cast_35_fu_219_p1 : STD_LOGIC_VECTOR (12 downto 0); signal ap_NS_fsm : STD_LOGIC_VECTOR (3 downto 0); begin -- the current state (ap_CS_fsm) of the state machine. -- ap_CS_fsm_assign_proc : process(ap_clk) begin if (ap_clk'event and ap_clk = '1') then if (ap_rst = '1') then ap_CS_fsm <= ap_ST_st1_fsm_0; else ap_CS_fsm <= ap_NS_fsm; end if; end if; end process; -- ap_done_reg assign process. -- ap_done_reg_assign_proc : process(ap_clk) begin if (ap_clk'event and ap_clk = '1') then if (ap_rst = '1') then ap_done_reg <= ap_const_logic_0; else if ((ap_const_logic_1 = ap_continue)) then ap_done_reg <= ap_const_logic_0; elsif (((ap_const_logic_1 = ap_sig_cseq_ST_st2_fsm_1) and not((exitcond3_fu_197_p2 = ap_const_lv1_0)))) then ap_done_reg <= ap_const_logic_1; end if; end if; end if; end process; -- ap_reg_ioackin_OUTPUT_STREAM_TREADY assign process. -- ap_reg_ioackin_OUTPUT_STREAM_TREADY_assign_proc : process(ap_clk) begin if (ap_clk'event and ap_clk = '1') then if (ap_rst = '1') then ap_reg_ioackin_OUTPUT_STREAM_TREADY <= ap_const_logic_0; else if ((((ap_const_logic_1 = ap_sig_cseq_ST_pp0_stg0_fsm_2) and (exitcond4_reg_281 = ap_const_lv1_0) and (ap_const_logic_1 = ap_reg_ppiten_pp0_it1) and not(((ap_sig_bdd_99 or ((exitcond4_reg_281 = ap_const_lv1_0) and (ap_const_logic_0 = ap_sig_ioackin_OUTPUT_STREAM_TREADY))) and (ap_const_logic_1 = ap_reg_ppiten_pp0_it1)))))) then ap_reg_ioackin_OUTPUT_STREAM_TREADY <= ap_const_logic_0; elsif ((((ap_const_logic_1 = ap_sig_cseq_ST_pp0_stg0_fsm_2) and (exitcond4_reg_281 = ap_const_lv1_0) and (ap_const_logic_1 = ap_reg_ppiten_pp0_it1) and not((ap_sig_bdd_99 and (ap_const_logic_1 = ap_reg_ppiten_pp0_it1))) and (ap_const_logic_1 = OUTPUT_STREAM_TREADY)))) then ap_reg_ioackin_OUTPUT_STREAM_TREADY <= ap_const_logic_1; end if; end if; end if; end process; -- ap_reg_ppiten_pp0_it0 assign process. -- ap_reg_ppiten_pp0_it0_assign_proc : process(ap_clk) begin if (ap_clk'event and ap_clk = '1') then if (ap_rst = '1') then ap_reg_ppiten_pp0_it0 <= ap_const_logic_0; else if (((ap_const_logic_1 = ap_sig_cseq_ST_pp0_stg0_fsm_2) and not(((ap_sig_bdd_99 or ((exitcond4_reg_281 = ap_const_lv1_0) and (ap_const_logic_0 = ap_sig_ioackin_OUTPUT_STREAM_TREADY))) and (ap_const_logic_1 = ap_reg_ppiten_pp0_it1))) and not((exitcond4_fu_208_p2 = ap_const_lv1_0)))) then ap_reg_ppiten_pp0_it0 <= ap_const_logic_0; elsif (((ap_const_logic_1 = ap_sig_cseq_ST_st2_fsm_1) and (exitcond3_fu_197_p2 = ap_const_lv1_0))) then ap_reg_ppiten_pp0_it0 <= ap_const_logic_1; end if; end if; end if; end process; -- ap_reg_ppiten_pp0_it1 assign process. -- ap_reg_ppiten_pp0_it1_assign_proc : process(ap_clk) begin if (ap_clk'event and ap_clk = '1') then if (ap_rst = '1') then ap_reg_ppiten_pp0_it1 <= ap_const_logic_0; else if (((ap_const_logic_1 = ap_sig_cseq_ST_pp0_stg0_fsm_2) and not(((ap_sig_bdd_99 or ((exitcond4_reg_281 = ap_const_lv1_0) and (ap_const_logic_0 = ap_sig_ioackin_OUTPUT_STREAM_TREADY))) and (ap_const_logic_1 = ap_reg_ppiten_pp0_it1))) and (exitcond4_fu_208_p2 = ap_const_lv1_0))) then ap_reg_ppiten_pp0_it1 <= ap_const_logic_1; elsif ((((ap_const_logic_1 = ap_sig_cseq_ST_st2_fsm_1) and (exitcond3_fu_197_p2 = ap_const_lv1_0)) or ((ap_const_logic_1 = ap_sig_cseq_ST_pp0_stg0_fsm_2) and not(((ap_sig_bdd_99 or ((exitcond4_reg_281 = ap_const_lv1_0) and (ap_const_logic_0 = ap_sig_ioackin_OUTPUT_STREAM_TREADY))) and (ap_const_logic_1 = ap_reg_ppiten_pp0_it1))) and not((exitcond4_fu_208_p2 = ap_const_lv1_0))))) then ap_reg_ppiten_pp0_it1 <= ap_const_logic_0; end if; end if; end if; end process; -- p_3_reg_170 assign process. -- p_3_reg_170_assign_proc : process (ap_clk) begin if (ap_clk'event and ap_clk = '1') then if (((ap_const_logic_1 = ap_sig_cseq_ST_pp0_stg0_fsm_2) and (ap_const_logic_1 = ap_reg_ppiten_pp0_it0) and not(((ap_sig_bdd_99 or ((exitcond4_reg_281 = ap_const_lv1_0) and (ap_const_logic_0 = ap_sig_ioackin_OUTPUT_STREAM_TREADY))) and (ap_const_logic_1 = ap_reg_ppiten_pp0_it1))) and (exitcond4_fu_208_p2 = ap_const_lv1_0))) then p_3_reg_170 <= j_V_fu_213_p2; elsif (((ap_const_logic_1 = ap_sig_cseq_ST_st2_fsm_1) and (exitcond3_fu_197_p2 = ap_const_lv1_0))) then p_3_reg_170 <= ap_const_lv12_0; end if; end if; end process; -- p_s_reg_159 assign process. -- p_s_reg_159_assign_proc : process (ap_clk) begin if (ap_clk'event and ap_clk = '1') then if ((ap_const_logic_1 = ap_sig_cseq_ST_st5_fsm_3)) then p_s_reg_159 <= i_V_reg_276; elsif (((ap_const_logic_1 = ap_sig_cseq_ST_st1_fsm_0) and not(ap_sig_bdd_60))) then p_s_reg_159 <= ap_const_lv12_0; end if; end if; end process; -- tmp_user_V_fu_96 assign process. -- tmp_user_V_fu_96_assign_proc : process (ap_clk) begin if (ap_clk'event and ap_clk = '1') then if (((ap_const_logic_1 = ap_sig_cseq_ST_pp0_stg0_fsm_2) and (exitcond4_reg_281 = ap_const_lv1_0) and (ap_const_logic_1 = ap_reg_ppiten_pp0_it1) and not(((ap_sig_bdd_99 or ((exitcond4_reg_281 = ap_const_lv1_0) and (ap_const_logic_0 = ap_sig_ioackin_OUTPUT_STREAM_TREADY))) and (ap_const_logic_1 = ap_reg_ppiten_pp0_it1))))) then tmp_user_V_fu_96 <= ap_const_lv1_0; elsif (((ap_const_logic_1 = ap_sig_cseq_ST_st1_fsm_0) and not(ap_sig_bdd_60))) then tmp_user_V_fu_96 <= ap_const_lv1_1; end if; end if; end process; -- assign process. -- process (ap_clk) begin if (ap_clk'event and ap_clk = '1') then if (((ap_const_logic_1 = ap_sig_cseq_ST_pp0_stg0_fsm_2) and not(((ap_sig_bdd_99 or ((exitcond4_reg_281 = ap_const_lv1_0) and (ap_const_logic_0 = ap_sig_ioackin_OUTPUT_STREAM_TREADY))) and (ap_const_logic_1 = ap_reg_ppiten_pp0_it1))) and (exitcond4_fu_208_p2 = ap_const_lv1_0))) then axi_last_V_reg_290 <= axi_last_V_fu_223_p2; end if; end if; end process; -- assign process. -- process (ap_clk) begin if (ap_clk'event and ap_clk = '1') then if (((ap_const_logic_1 = ap_sig_cseq_ST_pp0_stg0_fsm_2) and not(((ap_sig_bdd_99 or ((exitcond4_reg_281 = ap_const_lv1_0) and (ap_const_logic_0 = ap_sig_ioackin_OUTPUT_STREAM_TREADY))) and (ap_const_logic_1 = ap_reg_ppiten_pp0_it1))))) then exitcond4_reg_281 <= exitcond4_fu_208_p2; end if; end if; end process; -- assign process. -- process (ap_clk) begin if (ap_clk'event and ap_clk = '1') then if ((ap_const_logic_1 = ap_sig_cseq_ST_st2_fsm_1)) then i_V_reg_276 <= i_V_fu_202_p2; end if; end if; end process; -- assign process. -- process (ap_clk) begin if (ap_clk'event and ap_clk = '1') then if (((ap_const_logic_1 = ap_sig_cseq_ST_st1_fsm_0) and not(ap_sig_bdd_60))) then op2_assign_reg_267 <= op2_assign_fu_186_p2; end if; end if; end process; -- the next state (ap_NS_fsm) of the state machine. -- ap_NS_fsm_assign_proc : process (ap_CS_fsm, ap_sig_bdd_60, exitcond3_fu_197_p2, exitcond4_fu_208_p2, exitcond4_reg_281, ap_reg_ppiten_pp0_it0, ap_sig_bdd_99, ap_sig_ioackin_OUTPUT_STREAM_TREADY, ap_reg_ppiten_pp0_it1) begin case ap_CS_fsm is when ap_ST_st1_fsm_0 => if (not(ap_sig_bdd_60)) then ap_NS_fsm <= ap_ST_st2_fsm_1; else ap_NS_fsm <= ap_ST_st1_fsm_0; end if; when ap_ST_st2_fsm_1 => if (not((exitcond3_fu_197_p2 = ap_const_lv1_0))) then ap_NS_fsm <= ap_ST_st1_fsm_0; else ap_NS_fsm <= ap_ST_pp0_stg0_fsm_2; end if; when ap_ST_pp0_stg0_fsm_2 => if (not(((ap_const_logic_1 = ap_reg_ppiten_pp0_it0) and not(((ap_sig_bdd_99 or ((exitcond4_reg_281 = ap_const_lv1_0) and (ap_const_logic_0 = ap_sig_ioackin_OUTPUT_STREAM_TREADY))) and (ap_const_logic_1 = ap_reg_ppiten_pp0_it1))) and not((exitcond4_fu_208_p2 = ap_const_lv1_0))))) then ap_NS_fsm <= ap_ST_pp0_stg0_fsm_2; elsif (((ap_const_logic_1 = ap_reg_ppiten_pp0_it0) and not(((ap_sig_bdd_99 or ((exitcond4_reg_281 = ap_const_lv1_0) and (ap_const_logic_0 = ap_sig_ioackin_OUTPUT_STREAM_TREADY))) and (ap_const_logic_1 = ap_reg_ppiten_pp0_it1))) and not((exitcond4_fu_208_p2 = ap_const_lv1_0)))) then ap_NS_fsm <= ap_ST_st5_fsm_3; else ap_NS_fsm <= ap_ST_pp0_stg0_fsm_2; end if; when ap_ST_st5_fsm_3 => ap_NS_fsm <= ap_ST_st2_fsm_1; when others => ap_NS_fsm <= "XXXX"; end case; end process; OUTPUT_STREAM_TDATA <= (((ap_const_lv8_FF & img_data_stream_2_V_dout) & img_data_stream_1_V_dout) & img_data_stream_0_V_dout); OUTPUT_STREAM_TDEST <= ap_const_lv1_0; OUTPUT_STREAM_TID <= ap_const_lv1_0; OUTPUT_STREAM_TKEEP <= ap_const_lv4_F; OUTPUT_STREAM_TLAST <= axi_last_V_reg_290; OUTPUT_STREAM_TSTRB <= ap_const_lv4_0; OUTPUT_STREAM_TUSER <= tmp_user_V_fu_96; -- OUTPUT_STREAM_TVALID assign process. -- OUTPUT_STREAM_TVALID_assign_proc : process(exitcond4_reg_281, ap_sig_cseq_ST_pp0_stg0_fsm_2, ap_sig_bdd_99, ap_reg_ppiten_pp0_it1, ap_reg_ioackin_OUTPUT_STREAM_TREADY) begin if ((((ap_const_logic_1 = ap_sig_cseq_ST_pp0_stg0_fsm_2) and (exitcond4_reg_281 = ap_const_lv1_0) and (ap_const_logic_1 = ap_reg_ppiten_pp0_it1) and not((ap_sig_bdd_99 and (ap_const_logic_1 = ap_reg_ppiten_pp0_it1))) and (ap_const_logic_0 = ap_reg_ioackin_OUTPUT_STREAM_TREADY)))) then OUTPUT_STREAM_TVALID <= ap_const_logic_1; else OUTPUT_STREAM_TVALID <= ap_const_logic_0; end if; end process; -- ap_done assign process. -- ap_done_assign_proc : process(ap_done_reg, exitcond3_fu_197_p2, ap_sig_cseq_ST_st2_fsm_1) begin if (((ap_const_logic_1 = ap_done_reg) or ((ap_const_logic_1 = ap_sig_cseq_ST_st2_fsm_1) and not((exitcond3_fu_197_p2 = ap_const_lv1_0))))) then ap_done <= ap_const_logic_1; else ap_done <= ap_const_logic_0; end if; end process; -- ap_idle assign process. -- ap_idle_assign_proc : process(ap_start, ap_sig_cseq_ST_st1_fsm_0) begin if ((not((ap_const_logic_1 = ap_start)) and (ap_const_logic_1 = ap_sig_cseq_ST_st1_fsm_0))) then ap_idle <= ap_const_logic_1; else ap_idle <= ap_const_logic_0; end if; end process; -- ap_ready assign process. -- ap_ready_assign_proc : process(exitcond3_fu_197_p2, ap_sig_cseq_ST_st2_fsm_1) begin if (((ap_const_logic_1 = ap_sig_cseq_ST_st2_fsm_1) and not((exitcond3_fu_197_p2 = ap_const_lv1_0)))) then ap_ready <= ap_const_logic_1; else ap_ready <= ap_const_logic_0; end if; end process; -- ap_sig_bdd_130 assign process. -- ap_sig_bdd_130_assign_proc : process(ap_CS_fsm) begin ap_sig_bdd_130 <= (ap_const_lv1_1 = ap_CS_fsm(3 downto 3)); end process; -- ap_sig_bdd_23 assign process. -- ap_sig_bdd_23_assign_proc : process(ap_CS_fsm) begin ap_sig_bdd_23 <= (ap_CS_fsm(0 downto 0) = ap_const_lv1_1); end process; -- ap_sig_bdd_60 assign process. -- ap_sig_bdd_60_assign_proc : process(ap_start, ap_done_reg) begin ap_sig_bdd_60 <= ((ap_start = ap_const_logic_0) or (ap_done_reg = ap_const_logic_1)); end process; -- ap_sig_bdd_74 assign process. -- ap_sig_bdd_74_assign_proc : process(ap_CS_fsm) begin ap_sig_bdd_74 <= (ap_const_lv1_1 = ap_CS_fsm(1 downto 1)); end process; -- ap_sig_bdd_85 assign process. -- ap_sig_bdd_85_assign_proc : process(ap_CS_fsm) begin ap_sig_bdd_85 <= (ap_const_lv1_1 = ap_CS_fsm(2 downto 2)); end process; -- ap_sig_bdd_99 assign process. -- ap_sig_bdd_99_assign_proc : process(img_data_stream_0_V_empty_n, img_data_stream_1_V_empty_n, img_data_stream_2_V_empty_n, exitcond4_reg_281) begin ap_sig_bdd_99 <= (((img_data_stream_0_V_empty_n = ap_const_logic_0) and (exitcond4_reg_281 = ap_const_lv1_0)) or ((exitcond4_reg_281 = ap_const_lv1_0) and (img_data_stream_1_V_empty_n = ap_const_logic_0)) or ((exitcond4_reg_281 = ap_const_lv1_0) and (img_data_stream_2_V_empty_n = ap_const_logic_0))); end process; -- ap_sig_cseq_ST_pp0_stg0_fsm_2 assign process. -- ap_sig_cseq_ST_pp0_stg0_fsm_2_assign_proc : process(ap_sig_bdd_85) begin if (ap_sig_bdd_85) then ap_sig_cseq_ST_pp0_stg0_fsm_2 <= ap_const_logic_1; else ap_sig_cseq_ST_pp0_stg0_fsm_2 <= ap_const_logic_0; end if; end process; -- ap_sig_cseq_ST_st1_fsm_0 assign process. -- ap_sig_cseq_ST_st1_fsm_0_assign_proc : process(ap_sig_bdd_23) begin if (ap_sig_bdd_23) then ap_sig_cseq_ST_st1_fsm_0 <= ap_const_logic_1; else ap_sig_cseq_ST_st1_fsm_0 <= ap_const_logic_0; end if; end process; -- ap_sig_cseq_ST_st2_fsm_1 assign process. -- ap_sig_cseq_ST_st2_fsm_1_assign_proc : process(ap_sig_bdd_74) begin if (ap_sig_bdd_74) then ap_sig_cseq_ST_st2_fsm_1 <= ap_const_logic_1; else ap_sig_cseq_ST_st2_fsm_1 <= ap_const_logic_0; end if; end process; -- ap_sig_cseq_ST_st5_fsm_3 assign process. -- ap_sig_cseq_ST_st5_fsm_3_assign_proc : process(ap_sig_bdd_130) begin if (ap_sig_bdd_130) then ap_sig_cseq_ST_st5_fsm_3 <= ap_const_logic_1; else ap_sig_cseq_ST_st5_fsm_3 <= ap_const_logic_0; end if; end process; -- ap_sig_ioackin_OUTPUT_STREAM_TREADY assign process. -- ap_sig_ioackin_OUTPUT_STREAM_TREADY_assign_proc : process(OUTPUT_STREAM_TREADY, ap_reg_ioackin_OUTPUT_STREAM_TREADY) begin if ((ap_const_logic_0 = ap_reg_ioackin_OUTPUT_STREAM_TREADY)) then ap_sig_ioackin_OUTPUT_STREAM_TREADY <= OUTPUT_STREAM_TREADY; else ap_sig_ioackin_OUTPUT_STREAM_TREADY <= ap_const_logic_1; end if; end process; axi_last_V_fu_223_p2 <= "1" when (tmp_cast_35_fu_219_p1 = op2_assign_reg_267) else "0"; exitcond3_fu_197_p2 <= "1" when (p_s_reg_159 = img_rows_V_read) else "0"; exitcond4_fu_208_p2 <= "1" when (p_3_reg_170 = img_cols_V_read) else "0"; i_V_fu_202_p2 <= std_logic_vector(unsigned(p_s_reg_159) + unsigned(ap_const_lv12_1)); -- img_data_stream_0_V_read assign process. -- img_data_stream_0_V_read_assign_proc : process(exitcond4_reg_281, ap_sig_cseq_ST_pp0_stg0_fsm_2, ap_sig_bdd_99, ap_sig_ioackin_OUTPUT_STREAM_TREADY, ap_reg_ppiten_pp0_it1) begin if (((ap_const_logic_1 = ap_sig_cseq_ST_pp0_stg0_fsm_2) and (exitcond4_reg_281 = ap_const_lv1_0) and (ap_const_logic_1 = ap_reg_ppiten_pp0_it1) and not(((ap_sig_bdd_99 or ((exitcond4_reg_281 = ap_const_lv1_0) and (ap_const_logic_0 = ap_sig_ioackin_OUTPUT_STREAM_TREADY))) and (ap_const_logic_1 = ap_reg_ppiten_pp0_it1))))) then img_data_stream_0_V_read <= ap_const_logic_1; else img_data_stream_0_V_read <= ap_const_logic_0; end if; end process; -- img_data_stream_1_V_read assign process. -- img_data_stream_1_V_read_assign_proc : process(exitcond4_reg_281, ap_sig_cseq_ST_pp0_stg0_fsm_2, ap_sig_bdd_99, ap_sig_ioackin_OUTPUT_STREAM_TREADY, ap_reg_ppiten_pp0_it1) begin if (((ap_const_logic_1 = ap_sig_cseq_ST_pp0_stg0_fsm_2) and (exitcond4_reg_281 = ap_const_lv1_0) and (ap_const_logic_1 = ap_reg_ppiten_pp0_it1) and not(((ap_sig_bdd_99 or ((exitcond4_reg_281 = ap_const_lv1_0) and (ap_const_logic_0 = ap_sig_ioackin_OUTPUT_STREAM_TREADY))) and (ap_const_logic_1 = ap_reg_ppiten_pp0_it1))))) then img_data_stream_1_V_read <= ap_const_logic_1; else img_data_stream_1_V_read <= ap_const_logic_0; end if; end process; -- img_data_stream_2_V_read assign process. -- img_data_stream_2_V_read_assign_proc : process(exitcond4_reg_281, ap_sig_cseq_ST_pp0_stg0_fsm_2, ap_sig_bdd_99, ap_sig_ioackin_OUTPUT_STREAM_TREADY, ap_reg_ppiten_pp0_it1) begin if (((ap_const_logic_1 = ap_sig_cseq_ST_pp0_stg0_fsm_2) and (exitcond4_reg_281 = ap_const_lv1_0) and (ap_const_logic_1 = ap_reg_ppiten_pp0_it1) and not(((ap_sig_bdd_99 or ((exitcond4_reg_281 = ap_const_lv1_0) and (ap_const_logic_0 = ap_sig_ioackin_OUTPUT_STREAM_TREADY))) and (ap_const_logic_1 = ap_reg_ppiten_pp0_it1))))) then img_data_stream_2_V_read <= ap_const_logic_1; else img_data_stream_2_V_read <= ap_const_logic_0; end if; end process; j_V_fu_213_p2 <= std_logic_vector(unsigned(p_3_reg_170) + unsigned(ap_const_lv12_1)); op2_assign_fu_186_p2 <= std_logic_vector(unsigned(tmp_cast_fu_182_p1) + unsigned(ap_const_lv13_1FFF)); tmp_cast_35_fu_219_p1 <= std_logic_vector(resize(unsigned(p_3_reg_170),13)); tmp_cast_fu_182_p1 <= std_logic_vector(resize(unsigned(img_cols_V_read),13)); end behav;

gpl-3.0

ab320e548b93e556b0b39b0d0b86ba4f

0.592093

2.795067

false

marco-c/leon-nexys2

grlib-gpl-1.3.4-b4140/lib/micron/ddr_sdram/mt46v16m16.vhd

1

62,181

----------------------------------------------------------------------------------------- -- -- File Name: MT46V16M16.VHD -- Version: 3.1 -- Date: January 14th, 2002 -- Model: Behavioral -- Simulator: NCDesktop - http://www.cadence.com -- ModelSim PE - http://www.model.com -- -- Dependencies: None -- -- Email: [email protected] -- Company: Micron Technology, Inc. -- Part Number: MT46V16M16 (4 Mb x 16 x 4 Banks) -- -- Description: Micron 256 Mb SDRAM DDR (Double Data Rate) -- -- Limitation: Doesn't model internal refresh counter -- -- Note: -- -- Disclaimer: THESE DESIGNS ARE PROVIDED "AS IS" WITH NO WARRANTY -- WHATSOEVER AND MICRON SPECIFICALLY DISCLAIMS ANY -- IMPLIED WARRANTIES OF MERCHANTABILITY, FITNESS FOR -- A PARTICULAR PURPOSE, OR AGAINST INFRINGEMENT. -- -- Copyright (c) 1998 Micron Semiconductor Products, Inc. -- All rights researved -- -- Rev Author Date Changes -- --- ---------------------------- ---------- ------------------------------------- -- 2.1 SH 01/14/2002 - Fix Burst_counter -- Micron Technology, Inc. -- -- 2.0 SH 11/08/2001 - Second release -- Micron Technology, Inc. - Rewrote and remove SHARED VARIABLE -- 3.1 Craig Hanson cahanson 05/28/2003 - update all models to release version 3.1 -- @micron.com (no changes to this model) ----------------------------------------------------------------------------------------- LIBRARY IEEE; USE IEEE.STD_LOGIC_1164.ALL; USE IEEE.NUMERIC_STD.ALL; LIBRARY WORK; USE WORK.MTI_PKG.ALL; use std.textio.all; library grlib; use grlib.stdlib.all; use grlib.stdio.all; ENTITY MT46V16M16 IS GENERIC ( -- Timing for -75Z CL2 tCK : TIME := 7.500 ns; tCH : TIME := 3.375 ns; -- 0.45*tCK tCL : TIME := 3.375 ns; -- 0.45*tCK tDH : TIME := 0.500 ns; tDS : TIME := 0.500 ns; tIH : TIME := 0.900 ns; tIS : TIME := 0.900 ns; tMRD : TIME := 15.000 ns; tRAS : TIME := 40.000 ns; tRAP : TIME := 20.000 ns; tRC : TIME := 65.000 ns; tRFC : TIME := 75.000 ns; tRCD : TIME := 20.000 ns; tRP : TIME := 20.000 ns; tRRD : TIME := 15.000 ns; tWR : TIME := 15.000 ns; addr_bits : INTEGER := 13; data_bits : INTEGER := 16; cols_bits : INTEGER := 9; index : INTEGER := 0; fname : string := "ram.srec"; -- File to read from bbits : INTEGER := 16; fdelay : INTEGER := 0; chktiming : boolean := true -- Perform timing checks ); PORT ( Dq : INOUT STD_LOGIC_VECTOR (data_bits - 1 DOWNTO 0) := (OTHERS => 'Z'); Dqs : INOUT STD_LOGIC_VECTOR (1 DOWNTO 0) := "ZZ"; Addr : IN STD_LOGIC_VECTOR (addr_bits - 1 DOWNTO 0); Ba : IN STD_LOGIC_VECTOR (1 DOWNTO 0); Clk : IN STD_LOGIC; Clk_n : IN STD_LOGIC; Cke : IN STD_LOGIC; Cs_n : IN STD_LOGIC; Ras_n : IN STD_LOGIC; Cas_n : IN STD_LOGIC; We_n : IN STD_LOGIC; Dm : IN STD_LOGIC_VECTOR (1 DOWNTO 0) ); END MT46V16M16; ARCHITECTURE behave OF MT46V16M16 IS -- Array for Read pipeline TYPE Array_Read_cmnd IS ARRAY (cols_bits-1 DOWNTO 0) OF STD_LOGIC; TYPE Array_Read_bank IS ARRAY (cols_bits-1 DOWNTO 0) OF STD_LOGIC_VECTOR (1 DOWNTO 0); TYPE Array_Read_cols IS ARRAY (cols_bits-1 DOWNTO 0) OF STD_LOGIC_VECTOR (cols_bits - 1 DOWNTO 0); -- Array for Write pipeline TYPE Array_Write_cmnd IS ARRAY (2 DOWNTO 0) OF STD_LOGIC; TYPE Array_Write_bank IS ARRAY (2 DOWNTO 0) OF STD_LOGIC_VECTOR (1 DOWNTO 0); TYPE Array_Write_cols IS ARRAY (2 DOWNTO 0) OF STD_LOGIC_VECTOR (cols_bits - 1 DOWNTO 0); -- Array for Auto Precharge TYPE Array_Read_precharge IS ARRAY (3 DOWNTO 0) OF STD_LOGIC; TYPE Array_Write_precharge IS ARRAY (3 DOWNTO 0) OF STD_LOGIC; TYPE Array_Count_precharge IS ARRAY (3 DOWNTO 0) OF INTEGER; -- Array for Manual Precharge TYPE Array_A10_precharge IS ARRAY (cols_bits-1 DOWNTO 0) OF STD_LOGIC; TYPE Array_Bank_precharge IS ARRAY (cols_bits-1 DOWNTO 0) OF STD_LOGIC_VECTOR (1 DOWNTO 0); TYPE Array_Cmnd_precharge IS ARRAY (cols_bits-1 DOWNTO 0) OF STD_LOGIC; -- Array for Burst Terminate TYPE Array_Cmnd_bst IS ARRAY (cols_bits-1 DOWNTO 0) OF STD_LOGIC; -- Array for Memory Access TYPE Array_ram_type IS ARRAY (2**cols_bits - 1 DOWNTO 0) OF STD_LOGIC_VECTOR (data_bits - 1 DOWNTO 0); TYPE Array_ram_pntr IS ACCESS Array_ram_type; TYPE Array_ram_stor IS ARRAY (2**addr_bits - 1 DOWNTO 0) OF Array_ram_pntr; -- Data pair SIGNAL Dq_pair : STD_LOGIC_VECTOR (2 * data_bits - 1 DOWNTO 0); SIGNAL Dm_pair : STD_LOGIC_VECTOR (3 DOWNTO 0); -- Mode Register SIGNAL Mode_reg : STD_LOGIC_VECTOR (addr_bits - 1 DOWNTO 0) := (OTHERS => '0'); -- Command Decode Variables SIGNAL Active_enable, Aref_enable, Burst_term, Ext_mode_enable : STD_LOGIC := '0'; SIGNAL Mode_reg_enable, Prech_enable, Read_enable, Write_enable : STD_LOGIC := '0'; -- Burst Length Decode Variables SIGNAL Burst_length_2, Burst_length_4, Burst_length_8, Burst_length_f : STD_LOGIC := '0'; -- Cas Latency Decode Variables SIGNAL Cas_latency_15, Cas_latency_2, Cas_latency_25, Cas_latency_3, Cas_latency_4 : STD_LOGIC := '0'; -- Internal Control Signals SIGNAL Cs_in, Ras_in, Cas_in, We_in : STD_LOGIC := '0'; -- System Clock SIGNAL Sys_clk : STD_LOGIC := '0'; -- Dqs buffer SIGNAL Dqs_out : STD_LOGIC_VECTOR (1 DOWNTO 0) := "ZZ"; BEGIN -- Strip the strength Cs_in <= To_X01 (Cs_n); Ras_in <= To_X01 (Ras_n); Cas_in <= To_X01 (Cas_n); We_in <= To_X01 (We_n); -- Commands Decode Active_enable <= NOT(Cs_in) AND NOT(Ras_in) AND Cas_in AND We_in; Aref_enable <= NOT(Cs_in) AND NOT(Ras_in) AND NOT(Cas_in) AND We_in; Burst_term <= NOT(Cs_in) AND Ras_in AND Cas_in AND NOT(We_in); Ext_mode_enable <= NOT(Cs_in) AND NOT(Ras_in) AND NOT(Cas_in) AND NOT(We_in) AND Ba(0) AND NOT(Ba(1)); Mode_reg_enable <= NOT(Cs_in) AND NOT(Ras_in) AND NOT(Cas_in) AND NOT(We_in) AND NOT(Ba(0)) AND NOT(Ba(1)); Prech_enable <= NOT(Cs_in) AND NOT(Ras_in) AND Cas_in AND NOT(We_in); Read_enable <= NOT(Cs_in) AND Ras_in AND NOT(Cas_in) AND We_in; Write_enable <= NOT(Cs_in) AND Ras_in AND NOT(Cas_in) AND NOT(We_in); -- Burst Length Decode Burst_length_2 <= NOT(Mode_reg(2)) AND NOT(Mode_reg(1)) AND Mode_reg(0); Burst_length_4 <= NOT(Mode_reg(2)) AND Mode_reg(1) AND NOT(Mode_reg(0)); Burst_length_8 <= NOT(Mode_reg(2)) AND Mode_reg(1) AND Mode_reg(0); Burst_length_f <= (Mode_reg(2)) AND Mode_reg(1) AND Mode_reg(0); -- CAS Latency Decode Cas_latency_15 <= Mode_reg(6) AND NOT(Mode_reg(5)) AND (Mode_reg(4)); Cas_latency_2 <= NOT(Mode_reg(6)) AND Mode_reg(5) AND NOT(Mode_reg(4)); Cas_latency_25 <= Mode_reg(6) AND Mode_reg(5) AND NOT(Mode_reg(4)); Cas_latency_3 <= NOT(Mode_reg(6)) AND Mode_reg(5) AND Mode_reg(4); Cas_latency_4 <= (Mode_reg(6)) AND NOT(Mode_reg(5)) AND NOT(Mode_reg(4)); -- Dqs buffer Dqs <= Dqs_out; -- -- System Clock -- int_clk : PROCESS (Clk, Clk_n) VARIABLE ClkZ, CkeZ : STD_LOGIC := '0'; begin IF Clk = '1' AND Clk_n = '0' THEN ClkZ := '1'; CkeZ := Cke; ELSIF Clk = '0' AND Clk_n = '1' THEN ClkZ := '0'; END IF; Sys_clk <= CkeZ AND ClkZ; END PROCESS; -- -- Main Process -- state_register : PROCESS -- Precharge Variables VARIABLE Pc_b0, Pc_b1, Pc_b2, Pc_b3 : STD_LOGIC := '0'; -- Activate Variables VARIABLE Act_b0, Act_b1, Act_b2, Act_b3 : STD_LOGIC := '1'; -- Data IO variables VARIABLE Data_in_enable, Data_out_enable : STD_LOGIC := '0'; -- Internal address mux variables VARIABLE Cols_brst : STD_LOGIC_VECTOR (2 DOWNTO 0); VARIABLE Prev_bank : STD_LOGIC_VECTOR (1 DOWNTO 0) := "00"; VARIABLE Bank_addr : STD_LOGIC_VECTOR (1 DOWNTO 0) := "00"; VARIABLE Cols_addr : STD_LOGIC_VECTOR (cols_bits - 1 DOWNTO 0); VARIABLE Rows_addr : STD_LOGIC_VECTOR (addr_bits - 1 DOWNTO 0); VARIABLE B0_row_addr : STD_LOGIC_VECTOR (addr_bits - 1 DOWNTO 0); VARIABLE B1_row_addr : STD_LOGIC_VECTOR (addr_bits - 1 DOWNTO 0); VARIABLE B2_row_addr : STD_LOGIC_VECTOR (addr_bits - 1 DOWNTO 0); VARIABLE B3_row_addr : STD_LOGIC_VECTOR (addr_bits - 1 DOWNTO 0); -- DLL Reset variables VARIABLE DLL_enable : STD_LOGIC := '0'; VARIABLE DLL_reset : STD_LOGIC := '0'; VARIABLE DLL_done : STD_LOGIC := '0'; VARIABLE DLL_count : INTEGER := 0; -- Timing Check VARIABLE MRD_chk : TIME := 0 ns; VARIABLE RFC_chk : TIME := 0 ns; VARIABLE RRD_chk : TIME := 0 ns; VARIABLE RAS_chk0, RAS_chk1, RAS_chk2, RAS_chk3 : TIME := 0 ns; VARIABLE RAP_chk0, RAP_chk1, RAP_chk2, RAP_chk3 : TIME := 0 ns; VARIABLE RC_chk0, RC_chk1, RC_chk2, RC_chk3 : TIME := 0 ns; VARIABLE RCD_chk0, RCD_chk1, RCD_chk2, RCD_chk3 : TIME := 0 ns; VARIABLE RP_chk0, RP_chk1, RP_chk2, RP_chk3 : TIME := 0 ns; VARIABLE WR_chk0, WR_chk1, WR_chk2, WR_chk3 : TIME := 0 ns; -- Read pipeline variables VARIABLE Read_cmnd : Array_Read_cmnd; VARIABLE Read_bank : Array_Read_bank; VARIABLE Read_cols : Array_Read_cols; -- Write pipeline variables VARIABLE Write_cmnd : Array_Write_cmnd; VARIABLE Write_bank : Array_Write_bank; VARIABLE Write_cols : Array_Write_cols; -- Auto Precharge variables VARIABLE Read_precharge : Array_Read_precharge := ('0' & '0' & '0' & '0'); VARIABLE Write_precharge : Array_Write_precharge := ('0' & '0' & '0' & '0'); VARIABLE Count_precharge : Array_Count_precharge := ( 0 & 0 & 0 & 0 ); -- Manual Precharge variables VARIABLE A10_precharge : Array_A10_precharge; VARIABLE Bank_precharge : Array_Bank_precharge; VARIABLE Cmnd_precharge : Array_Cmnd_precharge; -- Burst Terminate variable VARIABLE Cmnd_bst : Array_Cmnd_bst; -- Memory Banks VARIABLE Bank0 : Array_ram_stor; VARIABLE Bank1 : Array_ram_stor; VARIABLE Bank2 : Array_ram_stor; VARIABLE Bank3 : Array_ram_stor; -- Burst Counter VARIABLE Burst_counter : STD_LOGIC_VECTOR (cols_bits - 1 DOWNTO 0); -- Internal Dqs initialize VARIABLE Dqs_int : STD_LOGIC := '0'; -- Data buffer for DM Mask VARIABLE Data_buf : STD_LOGIC_VECTOR (data_bits - 1 DOWNTO 0) := (OTHERS => 'Z'); -- Load and Dumb variables FILE file_load : TEXT open read_mode is fname; -- Data load FILE file_dump : TEXT open write_mode is "dumpdata.txt"; -- Data dump VARIABLE Bank_Load : std_logic_vector ( 1 DOWNTO 0); VARIABLE Rows_Load : std_logic_vector (addr_bits-1 DOWNTO 0); VARIABLE Cols_Load : std_logic_vector ( cols_bits-1 DOWNTO 0); VARIABLE Data_Load : std_logic_vector (15 DOWNTO 0); VARIABLE i, j : INTEGER; VARIABLE good_load : BOOLEAN; VARIABLE l : LINE; variable file_loaded : boolean := false; variable dump : std_logic := '0'; variable ch : character; variable rectype : std_logic_vector(3 downto 0); variable recaddr : std_logic_vector(31 downto 0); variable reclen : std_logic_vector(7 downto 0); variable recdata : std_logic_vector(0 to 16*8-1); -- -- Initialize empty rows -- PROCEDURE Init_mem (Bank : STD_LOGIC_VECTOR; Row_index : INTEGER) IS VARIABLE i, j : INTEGER := 0; BEGIN IF Bank = "00" THEN IF Bank0 (Row_index) = NULL THEN -- Check to see if row empty Bank0 (Row_index) := NEW Array_ram_type; -- Open new row for access FOR i IN (2**cols_bits - 1) DOWNTO 0 LOOP -- Filled row with zeros FOR j IN (data_bits - 1) DOWNTO 0 LOOP Bank0 (Row_index) (i) (j) := '0'; END LOOP; END LOOP; END IF; ELSIF Bank = "01" THEN IF Bank1 (Row_index) = NULL THEN Bank1 (Row_index) := NEW Array_ram_type; FOR i IN (2**cols_bits - 1) DOWNTO 0 LOOP FOR j IN (data_bits - 1) DOWNTO 0 LOOP Bank1 (Row_index) (i) (j) := '0'; END LOOP; END LOOP; END IF; ELSIF Bank = "10" THEN IF Bank2 (Row_index) = NULL THEN Bank2 (Row_index) := NEW Array_ram_type; FOR i IN (2**cols_bits - 1) DOWNTO 0 LOOP FOR j IN (data_bits - 1) DOWNTO 0 LOOP Bank2 (Row_index) (i) (j) := '0'; END LOOP; END LOOP; END IF; ELSIF Bank = "11" THEN IF Bank3 (Row_index) = NULL THEN Bank3 (Row_index) := NEW Array_ram_type; FOR i IN (2**cols_bits - 1) DOWNTO 0 LOOP FOR j IN (data_bits - 1) DOWNTO 0 LOOP Bank3 (Row_index) (i) (j) := '0'; END LOOP; END LOOP; END IF; END IF; END; -- -- Burst Counter -- PROCEDURE Burst_decode IS VARIABLE Cols_temp : STD_LOGIC_VECTOR (cols_bits - 1 DOWNTO 0) := (OTHERS => '0'); BEGIN -- Advance burst counter Burst_counter := Burst_counter + 1; -- Burst Type IF Mode_reg (3) = '0' THEN Cols_temp := Cols_addr + 1; ELSIF Mode_reg (3) = '1' THEN Cols_temp (2) := Burst_counter (2) XOR Cols_brst (2); Cols_temp (1) := Burst_counter (1) XOR Cols_brst (1); Cols_temp (0) := Burst_counter (0) XOR Cols_brst (0); END IF; -- Burst Length IF Burst_length_2 = '1' THEN Cols_addr (0) := Cols_temp (0); ELSIF Burst_length_4 = '1' THEN Cols_addr (1 DOWNTO 0) := Cols_temp (1 DOWNTO 0); ELSIF Burst_length_8 = '1' THEN Cols_addr (2 DOWNTO 0) := Cols_temp (2 DOWNTO 0); ELSE Cols_addr := Cols_temp; END IF; -- Data counter IF Burst_length_2 = '1' THEN IF conv_integer(Burst_counter) >= 2 THEN IF Data_in_enable = '1' THEN Data_in_enable := '0'; ELSIF Data_out_enable = '1' THEN Data_out_enable := '0'; END IF; END IF; ELSIF Burst_length_4 = '1' THEN IF conv_integer(Burst_counter) >= 4 THEN IF Data_in_enable = '1' THEN Data_in_enable := '0'; ELSIF Data_out_enable = '1' THEN Data_out_enable := '0'; END IF; END IF; ELSIF Burst_length_8 = '1' THEN IF conv_integer(Burst_counter) >= 8 THEN IF Data_in_enable = '1' THEN Data_in_enable := '0'; ELSIF Data_out_enable = '1' THEN Data_out_enable := '0'; END IF; END IF; END IF; END; BEGIN WAIT ON Sys_clk; -- -- Manual Precharge Pipeline -- IF ((Sys_clk'EVENT AND Sys_clk = '0') OR (Sys_clk'EVENT AND Sys_clk = '1')) THEN -- A10 Precharge Pipeline A10_precharge(0) := A10_precharge(1); A10_precharge(1) := A10_precharge(2); A10_precharge(2) := A10_precharge(3); A10_precharge(3) := A10_precharge(4); A10_precharge(4) := A10_precharge(5); A10_precharge(5) := A10_precharge(6); A10_precharge(6) := A10_precharge(7); A10_precharge(7) := A10_precharge(8); A10_precharge(8) := '0'; -- Bank Precharge Pipeline Bank_precharge(0) := Bank_precharge(1); Bank_precharge(1) := Bank_precharge(2); Bank_precharge(2) := Bank_precharge(3); Bank_precharge(3) := Bank_precharge(4); Bank_precharge(4) := Bank_precharge(5); Bank_precharge(5) := Bank_precharge(6); Bank_precharge(6) := Bank_precharge(7); Bank_precharge(7) := Bank_precharge(8); Bank_precharge(8) := "00"; -- Command Precharge Pipeline Cmnd_precharge(0) := Cmnd_precharge(1); Cmnd_precharge(1) := Cmnd_precharge(2); Cmnd_precharge(2) := Cmnd_precharge(3); Cmnd_precharge(3) := Cmnd_precharge(4); Cmnd_precharge(4) := Cmnd_precharge(5); Cmnd_precharge(5) := Cmnd_precharge(6); Cmnd_precharge(6) := Cmnd_precharge(7); Cmnd_precharge(7) := Cmnd_precharge(8); Cmnd_precharge(8) := '0'; -- Terminate Read if same bank or all banks IF ((Cmnd_precharge (0) = '1') AND (Bank_precharge (0) = Bank_addr OR A10_precharge (0) = '1') AND (Data_out_enable = '1')) THEN Data_out_enable := '0'; END IF; END IF; -- -- Burst Terminate Pipeline -- IF ((Sys_clk'EVENT AND Sys_clk = '0') OR (Sys_clk'EVENT AND Sys_clk = '1')) THEN -- Burst Terminate pipeline Cmnd_bst (0) := Cmnd_bst (1); Cmnd_bst (1) := Cmnd_bst (2); Cmnd_bst (2) := Cmnd_bst (3); Cmnd_bst (3) := Cmnd_bst (4); Cmnd_bst (4) := Cmnd_bst (5); Cmnd_bst (5) := Cmnd_bst (6); Cmnd_bst (6) := Cmnd_bst (7); Cmnd_bst (7) := Cmnd_bst (8); Cmnd_bst (8) := '0'; -- Terminate current Read IF ((Cmnd_bst (0) = '1') AND (Data_out_enable = '1')) THEN Data_out_enable := '0'; END IF; END IF; -- -- Dq and Dqs Drivers -- IF ((Sys_clk'EVENT AND Sys_clk = '0') OR (Sys_clk'EVENT AND Sys_clk = '1')) THEN -- Read Command Pipeline Read_cmnd (0) := Read_cmnd (1); Read_cmnd (1) := Read_cmnd (2); Read_cmnd (2) := Read_cmnd (3); Read_cmnd (3) := Read_cmnd (4); Read_cmnd (4) := Read_cmnd (5); Read_cmnd (5) := Read_cmnd (6); Read_cmnd (6) := Read_cmnd (7); Read_cmnd (7) := Read_cmnd (8); Read_cmnd (8) := '0'; -- Read Bank Pipeline Read_bank (0) := Read_bank (1); Read_bank (1) := Read_bank (2); Read_bank (2) := Read_bank (3); Read_bank (3) := Read_bank (4); Read_bank (4) := Read_bank (5); Read_bank (5) := Read_bank (6); Read_bank (6) := Read_bank (7); Read_bank (7) := Read_bank (8); Read_bank (8) := "00"; -- Read Column Pipeline Read_cols (0) := Read_cols (1); Read_cols (1) := Read_cols (2); Read_cols (2) := Read_cols (3); Read_cols (3) := Read_cols (4); Read_cols (4) := Read_cols (5); Read_cols (5) := Read_cols (6); Read_cols (6) := Read_cols (7); Read_cols (7) := Read_cols (8); Read_cols (8) := (OTHERS => '0'); -- Initialize Read command IF Read_cmnd (0) = '1' THEN Data_out_enable := '1'; Bank_addr := Read_bank (0); Cols_addr := Read_cols (0); Cols_brst := Cols_addr (2 DOWNTO 0); Burst_counter := (OTHERS => '0'); -- Row address mux CASE Bank_addr IS WHEN "00" => Rows_addr := B0_row_addr; WHEN "01" => Rows_addr := B1_row_addr; WHEN "10" => Rows_addr := B2_row_addr; WHEN OTHERS => Rows_addr := B3_row_addr; END CASE; END IF; -- Toggle Dqs during Read command IF Data_out_enable = '1' THEN Dqs_int := '0'; IF Dqs_out = "00" THEN Dqs_out <= "11"; ELSIF Dqs_out = "11" THEN Dqs_out <= "00"; ELSE Dqs_out <= "00"; END IF; ELSIF Data_out_enable = '0' AND Dqs_int = '0' THEN Dqs_out <= "ZZ"; END IF; -- Initialize Dqs for Read command IF Read_cmnd (2) = '1' THEN IF Data_out_enable = '0' THEN Dqs_int := '1'; Dqs_out <= "00"; END IF; END IF; -- Read Latch IF Data_out_enable = '1' THEN -- Initialize Memory Init_mem (Bank_addr, CONV_INTEGER(Rows_addr)); -- Output Data CASE Bank_addr IS WHEN "00" => Dq <= Bank0 (CONV_INTEGER(Rows_addr)) (CONV_INTEGER(Cols_addr)); WHEN "01" => Dq <= Bank1 (CONV_INTEGER(Rows_addr)) (CONV_INTEGER(Cols_addr)); WHEN "10" => Dq <= Bank2 (CONV_INTEGER(Rows_addr)) (CONV_INTEGER(Cols_addr)); WHEN OTHERS => Dq <= Bank3 (CONV_INTEGER(Rows_addr)) (CONV_INTEGER(Cols_addr)); END CASE; -- Increase Burst Counter Burst_decode; ELSE Dq <= (OTHERS => 'Z'); END IF; END IF; -- -- Write FIFO and DM Mask Logic -- IF Sys_clk'EVENT AND Sys_clk = '1' THEN -- Write command pipeline Write_cmnd (0) := Write_cmnd (1); Write_cmnd (1) := Write_cmnd (2); Write_cmnd (2) := '0'; -- Write command pipeline Write_bank (0) := Write_bank (1); Write_bank (1) := Write_bank (2); Write_bank (2) := "00"; -- Write column pipeline Write_cols (0) := Write_cols (1); Write_cols (1) := Write_cols (2); Write_cols (2) := (OTHERS => '0'); -- Initialize Write command IF Write_cmnd (0) = '1' THEN Data_in_enable := '1'; Bank_addr := Write_bank (0); Cols_addr := Write_cols (0); Cols_brst := Cols_addr (2 DOWNTO 0); Burst_counter := (OTHERS => '0'); -- Row address mux CASE Bank_addr IS WHEN "00" => Rows_addr := B0_row_addr; WHEN "01" => Rows_addr := B1_row_addr; WHEN "10" => Rows_addr := B2_row_addr; WHEN OTHERS => Rows_addr := B3_row_addr; END CASE; END IF; -- Write data IF Data_in_enable = '1' THEN -- Initialize memory Init_mem (Bank_addr, CONV_INTEGER(Rows_addr)); -- Write first data IF Dm_pair (1) = '0' OR Dm_pair (0) = '0' THEN -- Data Buffer CASE Bank_addr IS WHEN "00" => Data_buf := Bank0 (CONV_INTEGER(Rows_addr)) (CONV_INTEGER(Cols_addr)); WHEN "01" => Data_buf := Bank1 (CONV_INTEGER(Rows_addr)) (CONV_INTEGER(Cols_addr)); WHEN "10" => Data_buf := Bank2 (CONV_INTEGER(Rows_addr)) (CONV_INTEGER(Cols_addr)); WHEN OTHERS => Data_buf := Bank3 (CONV_INTEGER(Rows_addr)) (CONV_INTEGER(Cols_addr)); END CASE; -- Perform DM Mask IF Dm_pair (0) = '0' THEN Data_buf ( 7 DOWNTO 0) := Dq_pair ( 7 DOWNTO 0); END IF; IF Dm_pair (1) = '0' THEN Data_buf (15 DOWNTO 8) := Dq_pair (15 DOWNTO 8); END IF; -- Write Data CASE Bank_addr IS WHEN "00" => Bank0 (CONV_INTEGER(Rows_addr)) (CONV_INTEGER(Cols_addr)) := Data_buf; WHEN "01" => Bank1 (CONV_INTEGER(Rows_addr)) (CONV_INTEGER(Cols_addr)) := Data_buf; WHEN "10" => Bank2 (CONV_INTEGER(Rows_addr)) (CONV_INTEGER(Cols_addr)) := Data_buf; WHEN OTHERS => Bank3 (CONV_INTEGER(Rows_addr)) (CONV_INTEGER(Cols_addr)) := Data_buf; END CASE; END IF; -- Increase Burst Counter Burst_decode; -- Write second data IF Dm_pair (3) = '0' OR Dm_pair (2) = '0' THEN -- Data Buffer CASE Bank_addr IS WHEN "00" => Data_buf := Bank0 (CONV_INTEGER(Rows_addr)) (CONV_INTEGER(Cols_addr)); WHEN "01" => Data_buf := Bank1 (CONV_INTEGER(Rows_addr)) (CONV_INTEGER(Cols_addr)); WHEN "10" => Data_buf := Bank2 (CONV_INTEGER(Rows_addr)) (CONV_INTEGER(Cols_addr)); WHEN OTHERS => Data_buf := Bank3 (CONV_INTEGER(Rows_addr)) (CONV_INTEGER(Cols_addr)); END CASE; -- Perform DM Mask IF Dm_pair (2) = '0' THEN Data_buf ( 7 DOWNTO 0) := Dq_pair (23 DOWNTO 16); END IF; IF Dm_pair (3) = '0' THEN Data_buf (15 DOWNTO 8) := Dq_pair (31 DOWNTO 24); END IF; -- Write Data CASE Bank_addr IS WHEN "00" => Bank0 (CONV_INTEGER(Rows_addr)) (CONV_INTEGER(Cols_addr)) := Data_buf; WHEN "01" => Bank1 (CONV_INTEGER(Rows_addr)) (CONV_INTEGER(Cols_addr)) := Data_buf; WHEN "10" => Bank2 (CONV_INTEGER(Rows_addr)) (CONV_INTEGER(Cols_addr)) := Data_buf; WHEN OTHERS => Bank3 (CONV_INTEGER(Rows_addr)) (CONV_INTEGER(Cols_addr)) := Data_buf; END CASE; END IF; -- Increase Burst Counter Burst_decode; -- tWR start and tWTR check IF Dm_pair (3 DOWNTO 2) = "00" OR Dm_pair (1 DOWNTO 0) = "00" THEN CASE Bank_addr IS WHEN "00" => WR_chk0 := NOW; WHEN "01" => WR_chk1 := NOW; WHEN "10" => WR_chk2 := NOW; WHEN OTHERS => WR_chk3 := NOW; END CASE; -- tWTR check ASSERT (Read_enable = '0') REPORT "tWTR violation during Read" SEVERITY WARNING; END IF; END IF; END IF; -- -- Auto Precharge Calculation -- IF Sys_clk'EVENT AND Sys_clk = '1' THEN -- Precharge counter IF Read_precharge (0) = '1' OR Write_precharge (0) = '1' THEN Count_precharge (0) := Count_precharge (0) + 1; END IF; IF Read_precharge (1) = '1' OR Write_precharge (1) = '1' THEN Count_precharge (1) := Count_precharge (1) + 1; END IF; IF Read_precharge (2) = '1' OR Write_precharge (2) = '1' THEN Count_precharge (2) := Count_precharge (2) + 1; END IF; IF Read_precharge (3) = '1' OR Write_precharge (3) = '1' THEN Count_precharge (3) := Count_precharge (3) + 1; END IF; -- Read with AutoPrecharge Calculation -- The device start internal precharge when: -- 1. Meet tRAS requirement -- 2. BL/2 cycles after command IF ((Read_precharge(0) = '1') AND (NOW - RAS_chk0 >= tRAS)) THEN IF ((Burst_length_2 = '1' AND Count_precharge(0) >= 1) OR (Burst_length_4 = '1' AND Count_precharge(0) >= 2) OR (Burst_length_8 = '1' AND Count_precharge(0) >= 4)) THEN Pc_b0 := '1'; Act_b0 := '0'; RP_chk0 := NOW; Read_precharge(0) := '0'; END IF; END IF; IF ((Read_precharge(1) = '1') AND (NOW - RAS_chk1 >= tRAS)) THEN IF ((Burst_length_2 = '1' AND Count_precharge(1) >= 1) OR (Burst_length_4 = '1' AND Count_precharge(1) >= 2) OR (Burst_length_8 = '1' AND Count_precharge(1) >= 4)) THEN Pc_b1 := '1'; Act_b1 := '0'; RP_chk1 := NOW; Read_precharge(1) := '0'; END IF; END IF; IF ((Read_precharge(2) = '1') AND (NOW - RAS_chk2 >= tRAS)) THEN IF ((Burst_length_2 = '1' AND Count_precharge(2) >= 1) OR (Burst_length_4 = '1' AND Count_precharge(2) >= 2) OR (Burst_length_8 = '1' AND Count_precharge(2) >= 4)) THEN Pc_b2 := '1'; Act_b2 := '0'; RP_chk2 := NOW; Read_precharge(2) := '0'; END IF; END IF; IF ((Read_precharge(3) = '1') AND (NOW - RAS_chk3 >= tRAS)) THEN IF ((Burst_length_2 = '1' AND Count_precharge(3) >= 1) OR (Burst_length_4 = '1' AND Count_precharge(3) >= 2) OR (Burst_length_8 = '1' AND Count_precharge(3) >= 4)) THEN Pc_b3 := '1'; Act_b3 := '0'; RP_chk3 := NOW; Read_precharge(3) := '0'; END IF; END IF; -- Write with AutoPrecharge Calculation -- The device start internal precharge when: -- 1. Meet tRAS requirement -- 2. Two clock after last burst -- Since tWR is time base, the model will compensate tRP IF ((Write_precharge(0) = '1') AND (NOW - RAS_chk0 >= tRAS)) THEN IF ((Burst_length_2 = '1' AND Count_precharge (0) >= 4) OR (Burst_length_4 = '1' AND Count_precharge (0) >= 5) OR (Burst_length_8 = '1' AND Count_precharge (0) >= 7)) THEN Pc_b0 := '1'; Act_b0 := '0'; RP_chk0 := NOW - ((2 * tCK) - tWR); Write_precharge(0) := '0'; END IF; END IF; IF ((Write_precharge(1) = '1') AND (NOW - RAS_chk1 >= tRAS)) THEN IF ((Burst_length_2 = '1' AND Count_precharge (1) >= 4) OR (Burst_length_4 = '1' AND Count_precharge (1) >= 5) OR (Burst_length_8 = '1' AND Count_precharge (1) >= 7)) THEN Pc_b1 := '1'; Act_b1 := '0'; RP_chk1 := NOW - ((2 * tCK) - tWR); Write_precharge(1) := '0'; END IF; END IF; IF ((Write_precharge(2) = '1') AND (NOW - RAS_chk2 >= tRAS)) THEN IF ((Burst_length_2 = '1' AND Count_precharge (2) >= 4) OR (Burst_length_4 = '1' AND Count_precharge (2) >= 5) OR (Burst_length_8 = '1' AND Count_precharge (2) >= 7)) THEN Pc_b2 := '1'; Act_b2 := '0'; RP_chk2 := NOW - ((2 * tCK) - tWR); Write_precharge(2) := '0'; END IF; END IF; IF ((Write_precharge(3) = '1') AND (NOW - RAS_chk3 >= tRAS)) THEN IF ((Burst_length_2 = '1' AND Count_precharge (3) >= 4) OR (Burst_length_4 = '1' AND Count_precharge (3) >= 5) OR (Burst_length_8 = '1' AND Count_precharge (3) >= 7)) THEN Pc_b3 := '1'; Act_b3 := '0'; RP_chk3 := NOW - ((2 * tCK) - tWR); Write_precharge(3) := '0'; END IF; END IF; END IF; -- -- DLL Counter -- IF Sys_clk'EVENT AND Sys_clk = '1' THEN IF (DLL_Reset = '1' AND DLL_done = '0') THEN DLL_count := DLL_count + 1; IF (DLL_count >= 200) THEN DLL_done := '1'; END IF; END IF; END IF; -- -- Control Logic -- IF Sys_clk'EVENT AND Sys_clk = '1' THEN -- Auto Refresh IF Aref_enable = '1' THEN -- Auto Refresh to Auto Refresh ASSERT (NOW - RFC_chk >= tRFC) or (not chktiming) REPORT "tRFC violation during Auto Refresh" SEVERITY WARNING; -- Precharge to Auto Refresh ASSERT ((NOW - RP_chk0 >= tRP) AND (NOW - RP_chk1 >= tRP) AND (NOW - RP_chk2 >= tRP) AND (NOW - RP_chk3 >= tRP)) or (not chktiming) REPORT "tRP violation during Auto Refresh" SEVERITY WARNING; -- Precharge to Auto Refresh ASSERT (Pc_b0 = '1' AND Pc_b1 = '1' AND Pc_b2 = '1' AND Pc_b3 = '1') REPORT "All banks must be Precharge before Auto Refresh" SEVERITY WARNING; -- Record current tRFC time RFC_chk := NOW; END IF; -- Extended Load Mode Register IF Ext_mode_enable = '1' THEN IF (Pc_b0 = '1' AND Pc_b1 = '1' AND Pc_b2 = '1' AND Pc_b3 = '1') THEN IF (Addr (0) = '0') THEN DLL_enable := '1'; ELSE DLL_enable := '0'; END IF; END IF; -- Precharge to EMR ASSERT (Pc_b0 = '1' AND Pc_b1 = '1' AND Pc_b2 = '1' AND Pc_b3 = '1') REPORT "All bank must be Precharged before Extended Mode Register" SEVERITY WARNING; -- Precharge to EMR ASSERT ((NOW - RP_chk0 >= tRP) AND (NOW - RP_chk1 >= tRP) AND (NOW - RP_chk2 >= tRP) AND (NOW - RP_chk3 >= tRP)) or (not chktiming) REPORT "tRP violation during Extended Load Register" SEVERITY WARNING; -- LMR/EMR to EMR ASSERT (NOW - MRD_chk >= tMRD) or (not chktiming) REPORT "tMRD violation during Extended Mode Register" SEVERITY WARNING; -- Record current tMRD time MRD_chk := NOW; END IF; -- Load Mode Register IF Mode_reg_enable = '1' THEN -- Register mode Mode_reg <= Addr; -- DLL Reset IF (DLL_enable = '1' AND Addr (8) = '1') THEN DLL_reset := '1'; DLL_done := '0'; DLL_count := 0; ELSIF (DLL_enable = '1' AND DLL_reset = '0' AND Addr (8) = '0') THEN ASSERT (FALSE) REPORT "DLL is ENABLE: DLL RESET is require" SEVERITY WARNING; ELSIF (DLL_enable = '0' AND Addr (8) = '1') THEN ASSERT (FALSE) REPORT "DLL is DISABLE: DLL RESET will be ignored" SEVERITY WARNING; END IF; -- Precharge to LMR ASSERT (Pc_b0 = '1' AND Pc_b1 = '1' AND Pc_b2 = '1' AND Pc_b3 = '1') REPORT "All bank must be Precharged before Load Mode Register" SEVERITY WARNING; -- Precharge to EMR ASSERT ((NOW - RP_chk0 >= tRP) AND (NOW - RP_chk1 >= tRP) AND (NOW - RP_chk2 >= tRP) AND (NOW - RP_chk3 >= tRP)) or (not chktiming) REPORT "tRP violation during Load Mode Register" SEVERITY WARNING; -- LMR/ELMR to LMR ASSERT (NOW - MRD_chk >= tMRD) or (not chktiming) REPORT "tMRD violation during Load Mode Register" SEVERITY WARNING; -- Check for invalid Burst Length ASSERT ((Addr (2 DOWNTO 0) = "001") OR -- BL = 2 (Addr (2 DOWNTO 0) = "010") OR -- BL = 4 (Addr (2 DOWNTO 0) = "011")) -- BL = 8 REPORT "Invalid Burst Length during Load Mode Register" SEVERITY WARNING; -- Check for invalid CAS Latency ASSERT ((Addr (6 DOWNTO 4) = "010") OR -- CL = 2.0 (Addr (6 DOWNTO 4) = "110")) -- CL = 2.5 REPORT "Invalid CAS Latency during Load Mode Register" SEVERITY WARNING; -- Record current tMRD time MRD_chk := NOW; END IF; -- Active Block (latch Bank and Row Address) IF Active_enable = '1' THEN -- Activate an OPEN bank can corrupt data ASSERT ((Ba = "00" AND Act_b0 = '0') OR (Ba = "01" AND Act_b1 = '0') OR (Ba = "10" AND Act_b2 = '0') OR (Ba = "11" AND Act_b3 = '0')) REPORT "Bank is already activated - data can be corrupted" SEVERITY WARNING; -- Activate Bank 0 IF Ba = "00" AND Pc_b0 = '1' THEN -- Activate to Activate (same bank) ASSERT (NOW - RC_chk0 >= tRC) or (not chktiming) REPORT "tRC violation during Activate Bank 0" SEVERITY WARNING; -- Precharge to Active ASSERT (NOW - RP_chk0 >= tRP) or (not chktiming) REPORT "tRP violation during Activate Bank 0" SEVERITY WARNING; -- Record Variables for checking violation Act_b0 := '1'; Pc_b0 := '0'; B0_row_addr := Addr; RC_chk0 := NOW; RCD_chk0 := NOW; RAS_chk0 := NOW; RAP_chk0 := NOW; END IF; -- Activate Bank 1 IF Ba = "01" AND Pc_b1 = '1' THEN -- Activate to Activate (same bank) ASSERT (NOW - RC_chk1 >= tRC) or (not chktiming) REPORT "tRC violation during Activate Bank 1" SEVERITY WARNING; -- Precharge to Active ASSERT (NOW - RP_chk1 >= tRP) or (not chktiming) REPORT "tRP violation during Activate Bank 1" SEVERITY WARNING; -- Record Variables for checking violation Act_b1 := '1'; Pc_b1 := '0'; B1_row_addr := Addr; RC_chk1 := NOW; RCD_chk1 := NOW; RAS_chk1 := NOW; RAP_chk1 := NOW; END IF; -- Activate Bank 2 IF Ba = "10" AND Pc_b2 = '1' THEN -- Activate to Activate (same bank) ASSERT (NOW - RC_chk2 >= tRC) or (not chktiming) REPORT "tRC violation during Activate Bank 2" SEVERITY WARNING; -- Precharge to Active ASSERT (NOW - RP_chk2 >= tRP) or (not chktiming) REPORT "tRP violation during Activate Bank 2" SEVERITY WARNING; -- Record Variables for checking violation Act_b2 := '1'; Pc_b2 := '0'; B2_row_addr := Addr; RC_chk2 := NOW; RCD_chk2 := NOW; RAS_chk2 := NOW; RAP_chk2 := NOW; END IF; -- Activate Bank 3 IF Ba = "11" AND Pc_b3 = '1' THEN -- Activate to Activate (same bank) ASSERT (NOW - RC_chk3 >= tRC) or (not chktiming) REPORT "tRC violation during Activate Bank 3" SEVERITY WARNING; -- Precharge to Active ASSERT (NOW - RP_chk3 >= tRP) or (not chktiming) REPORT "tRP violation during Activate Bank 3" SEVERITY WARNING; -- Record Variables for checking violation Act_b3 := '1'; Pc_b3 := '0'; B3_row_addr := Addr; RC_chk3 := NOW; RCD_chk3 := NOW; RAS_chk3 := NOW; RAP_chk3 := NOW; END IF; -- Activate Bank A to Activate Bank B IF (Prev_bank /= Ba) THEN ASSERT (NOW - RRD_chk >= tRRD) or (not chktiming) REPORT "tRRD violation during Activate" SEVERITY WARNING; END IF; -- AutoRefresh to Activate ASSERT (NOW - RFC_chk >= tRFC) or (not chktiming) REPORT "tRFC violation during Activate" SEVERITY WARNING; -- Record Variables for Checking Violation RRD_chk := NOW; Prev_bank := Ba; END IF; -- Precharge Block - Consider NOP if bank already precharged or in process of precharging IF Prech_enable = '1' THEN -- EMR or LMR to Precharge ASSERT (NOW - MRD_chk >= tMRD) or (not chktiming) REPORT "tMRD violation during Precharge" SEVERITY WARNING; -- Precharge Bank 0 IF ((Addr (10) = '1' OR (Addr (10) = '0' AND Ba = "00")) AND Act_b0 = '1') THEN Act_b0 := '0'; Pc_b0 := '1'; RP_chk0 := NOW; -- Activate to Precharge bank 0 ASSERT (NOW - RAS_chk0 >= tRAS) or (not chktiming) REPORT "tRAS violation during Precharge" SEVERITY WARNING; -- tWR violation check for Write ASSERT (NOW - WR_chk0 >= tWR) or (not chktiming) REPORT "tWR violation during Precharge" SEVERITY WARNING; END IF; -- Precharge Bank 1 IF ((Addr (10) = '1' OR (Addr (10) = '0' AND Ba = "01")) AND Act_b1 = '1') THEN Act_b1 := '0'; Pc_b1 := '1'; RP_chk1 := NOW; -- Activate to Precharge ASSERT (NOW - RAS_chk1 >= tRAS) or (not chktiming) REPORT "tRAS violation during Precharge" SEVERITY WARNING; -- tWR violation check for Write ASSERT (NOW - WR_chk1 >= tWR) or (not chktiming) REPORT "tWR violation during Precharge" SEVERITY WARNING; END IF; -- Precharge Bank 2 IF ((Addr (10) = '1' OR (Addr (10) = '0' AND Ba = "10")) AND Act_b2 = '1') THEN Act_b2 := '0'; Pc_b2 := '1'; RP_chk2 := NOW; -- Activate to Precharge ASSERT (NOW - RAS_chk2 >= tRAS) or (not chktiming) REPORT "tRAS violation during Precharge" SEVERITY WARNING; -- tWR violation check for Write ASSERT (NOW - WR_chk2 >= tWR) or (not chktiming) REPORT "tWR violation during Precharge" SEVERITY WARNING; END IF; -- Precharge Bank 3 IF ((Addr (10) = '1' OR (Addr (10) = '0' AND Ba = "11")) AND Act_b3 = '1') THEN Act_b3 := '0'; Pc_b3 := '1'; RP_chk3 := NOW; -- Activate to Precharge ASSERT (NOW - RAS_chk3 >= tRAS) or (not chktiming) REPORT "tRAS violation during Precharge" SEVERITY WARNING; -- tWR violation check for Write ASSERT (NOW - WR_chk3 >= tWR) or (not chktiming) REPORT "tWR violation during Precharge" SEVERITY WARNING; END IF; -- Pipeline for READ IF CAS_latency_15 = '1' THEN A10_precharge (3) := Addr(10); Bank_precharge (3) := Ba; Cmnd_precharge (3) := '1'; ELSIF CAS_latency_2 = '1' THEN A10_precharge (4) := Addr(10); Bank_precharge (4) := Ba; Cmnd_precharge (4) := '1'; ELSIF CAS_latency_25 = '1' THEN A10_precharge (5) := Addr(10); Bank_precharge (5) := Ba; Cmnd_precharge (5) := '1'; ELSIF CAS_latency_3 = '1' THEN A10_precharge (6) := Addr(10); Bank_precharge (6) := Ba; Cmnd_precharge (6) := '1'; ELSIF CAS_latency_4 = '1' THEN A10_precharge (8) := Addr(10); Bank_precharge (8) := Ba; Cmnd_precharge (8) := '1'; END IF; END IF; -- Burst Terminate IF Burst_term = '1' THEN -- Pipeline for Read IF CAS_latency_15 = '1' THEN Cmnd_bst (3) := '1'; ELSIF CAS_latency_2 = '1' THEN Cmnd_bst (4) := '1'; ELSIF CAS_latency_25 = '1' THEN Cmnd_bst (5) := '1'; ELSIF CAS_latency_3 = '1' THEN Cmnd_bst (6) := '1'; ELSIF CAS_latency_4 = '1' THEN Cmnd_bst (8) := '1'; END IF; -- Terminate Write ASSERT (Data_in_enable = '0') REPORT "It's illegal to Burst Terminate a Write" SEVERITY WARNING; -- Terminate Read with Auto Precharge ASSERT (Read_precharge (0) = '0' AND Read_precharge (1) = '0' AND Read_precharge (2) = '0' AND Read_precharge (3) = '0') REPORT "It's illegal to Burst Terminate a Read with Auto Precharge" SEVERITY WARNING; END IF; -- Read Command IF Read_enable = '1' THEN -- CAS Latency Pipeline IF Cas_latency_15 = '1' THEN Read_cmnd (3) := '1'; Read_bank (3) := Ba; Read_cols (3) := Addr (cols_bits-1 DOWNTO 0); ELSIF Cas_latency_2 = '1' THEN Read_cmnd (4) := '1'; Read_bank (4) := Ba; Read_cols (4) := Addr (cols_bits-1 DOWNTO 0); ELSIF Cas_latency_25 = '1' THEN Read_cmnd (5) := '1'; Read_bank (5) := Ba; Read_cols (5) := Addr (cols_bits-1 DOWNTO 0); ELSIF Cas_latency_3 = '1' THEN Read_cmnd (6) := '1'; Read_bank (6) := Ba; Read_cols (6) := Addr (cols_bits-1 DOWNTO 0); ELSIF Cas_latency_4 = '1' THEN Read_cmnd (8) := '1'; Read_bank (8) := Ba; Read_cols (8) := Addr (cols_bits-1 DOWNTO 0); END IF; -- Write to Read: Terminate Write Immediately IF Data_in_enable = '1' THEN Data_in_enable := '0'; END IF; -- Interrupting a Read with Auto Precharge (same bank only) ASSERT (Read_precharge(CONV_INTEGER(Ba)) = '0') REPORT "It's illegal to interrupt a Read with Auto Precharge" SEVERITY WARNING; -- Activate to Read ASSERT ((Ba = "00" AND Act_b0 = '1') OR (Ba = "01" AND Act_b1 = '1') OR (Ba = "10" AND Act_b2 = '1') OR (Ba = "11" AND Act_b3 = '1')) REPORT "Bank is not Activated for Read" SEVERITY WARNING; -- Activate to Read without Auto Precharge IF Addr (10) = '0' THEN ASSERT ((Ba = "00" AND NOW - RCD_chk0 >= tRCD) OR (Ba = "01" AND NOW - RCD_chk1 >= tRCD) OR (Ba = "10" AND NOW - RCD_chk2 >= tRCD) OR (Ba = "11" AND NOW - RCD_chk3 >= tRCD)) or (not chktiming) REPORT "tRCD violation during Read" SEVERITY WARNING; END IF; -- Activate to Read with Auto Precharge IF Addr (10) = '1' THEN ASSERT ((Ba = "00" AND NOW - RAP_chk0 >= tRAP) OR (Ba = "01" AND NOW - RAP_chk1 >= tRAP) OR (Ba = "10" AND NOW - RAP_chk2 >= tRAP) OR (Ba = "11" AND NOW - RAP_chk3 >= tRAP)) or (not chktiming) REPORT "tRAP violation during Read" SEVERITY WARNING; END IF; -- Auto precharge IF Addr (10) = '1' THEN Read_precharge (Conv_INTEGER(Ba)) := '1'; Count_precharge (Conv_INTEGER(Ba)) := 0; END IF; -- DLL Check IF (DLL_reset = '1') THEN ASSERT (DLL_done = '1') REPORT "DLL RESET not complete" SEVERITY WARNING; END IF; END IF; -- Write Command IF Write_enable = '1' THEN -- Pipeline for Write Write_cmnd (2) := '1'; Write_bank (2) := Ba; Write_cols (2) := Addr (cols_bits-1 DOWNTO 0); -- Interrupting a Write with Auto Precharge (same bank only) ASSERT (Write_precharge(CONV_INTEGER(Ba)) = '0') REPORT "It's illegal to interrupt a Write with Auto Precharge" SEVERITY WARNING; -- Activate to Write ASSERT ((Ba = "00" AND Act_b0 = '1') OR (Ba = "01" AND Act_b1 = '1') OR (Ba = "10" AND Act_b2 = '1') OR (Ba = "11" AND Act_b3 = '1')) REPORT "Bank is not Activated for Write" SEVERITY WARNING; -- Activate to Write ASSERT ((Ba = "00" AND NOW - RCD_chk0 >= tRCD) OR (Ba = "01" AND NOW - RCD_chk1 >= tRCD) OR (Ba = "10" AND NOW - RCD_chk2 >= tRCD) OR (Ba = "11" AND NOW - RCD_chk3 >= tRCD)) or (not chktiming) REPORT "tRCD violation during Write" SEVERITY WARNING; -- Auto precharge IF Addr (10) = '1' THEN Write_precharge (Conv_INTEGER(Ba)) := '1'; Count_precharge (Conv_INTEGER(Ba)) := 0; END IF; END IF; END IF; IF (now >= (fdelay * 1 us)) and not file_loaded THEN --' file_loaded := true; WHILE NOT endfile(file_load) LOOP readline(file_load, l); read(l, ch); if (ch /= 'S') or (ch /= 's') then hread(l, rectype); hread(l, reclen); recaddr := (others => '0'); case rectype is when "0001" => hread(l, recaddr(15 downto 0)); when "0010" => hread(l, recaddr(23 downto 0)); when "0011" => hread(l, recaddr); when "0111" => hread(l, recaddr); -- if (index = 0) then print("Start address : " & tost(recaddr)); end if; next; when others => next; end case; case bbits is when 64 => -- 64-bit bank with four 16-bit DDRs recaddr(31 downto 18+cols_bits) := (others => '0'); hread(l, recdata); Bank_Load := recaddr(17+cols_bits downto 16+cols_bits); Rows_Load := recaddr(15+cols_bits downto 3+cols_bits); Cols_Load := recaddr(2+cols_bits downto 3); Init_mem (Bank_Load, To_Integer(Rows_Load)); IF Bank_Load = "00" THEN for i in 0 to 1 loop Bank0 (To_Integer(Rows_Load)) (To_Integer(Cols_Load)+i) := (recdata(i*64+index*16 to i*64+index*16+15)); end loop; ELSIF Bank_Load = "01" THEN for i in 0 to 1 loop Bank1 (To_Integer(Rows_Load)) (To_Integer(Cols_Load)+i) := (recdata(i*64+index*16 to i*64+index*16+15)); end loop; ELSIF Bank_Load = "10" THEN for i in 0 to 1 loop Bank2 (To_Integer(Rows_Load)) (To_Integer(Cols_Load)+i) := (recdata(i*64+index*16 to i*64+index*16+15)); end loop; ELSIF Bank_Load = "11" THEN for i in 0 to 1 loop Bank3 (To_Integer(Rows_Load)) (To_Integer(Cols_Load)+i) := (recdata(i*64+index*16 to i*64+index*16+15)); end loop; END IF; when 32 => -- 32-bit bank with two 16-bit DDRs recaddr(31 downto 17+cols_bits) := (others => '0'); hread(l, recdata); Bank_Load := recaddr(16+cols_bits downto 15+cols_bits); Rows_Load := recaddr(14+cols_bits downto 2+cols_bits); Cols_Load := recaddr(1+cols_bits downto 2); Init_mem (Bank_Load, To_Integer(Rows_Load)); IF Bank_Load = "00" THEN for i in 0 to 3 loop Bank0 (To_Integer(Rows_Load)) (To_Integer(Cols_Load)+i) := (recdata(i*32+index*16 to i*32+index*16+15)); end loop; ELSIF Bank_Load = "01" THEN for i in 0 to 3 loop Bank1 (To_Integer(Rows_Load)) (To_Integer(Cols_Load)+i) := (recdata(i*32+index*16 to i*32+index*16+15)); end loop; ELSIF Bank_Load = "10" THEN for i in 0 to 3 loop Bank2 (To_Integer(Rows_Load)) (To_Integer(Cols_Load)+i) := (recdata(i*32+index*16 to i*32+index*16+15)); end loop; ELSIF Bank_Load = "11" THEN for i in 0 to 3 loop Bank3 (To_Integer(Rows_Load)) (To_Integer(Cols_Load)+i) := (recdata(i*32+index*16 to i*32+index*16+15)); end loop; END IF; when others => -- 16-bit bank with one 16-bit DDR hread(l, recdata); recaddr(31 downto 16+cols_bits) := (others => '0'); Bank_Load := recaddr(15+cols_bits downto 14+cols_bits); Rows_Load := recaddr(13+cols_bits downto 1+cols_bits); Cols_Load := recaddr(cols_bits downto 1); Init_mem (Bank_Load, To_Integer(Rows_Load)); IF Bank_Load = "00" THEN for i in 0 to 3 loop Bank0 (To_Integer(Rows_Load)) (To_Integer(Cols_Load)+i) := (recdata(i*16 to i*16+15)); Bank0 (To_Integer(Rows_Load)) (To_Integer(Cols_Load)+i+4) := (recdata((i+4)*16 to (i+4)*16+15)); end loop; ELSIF Bank_Load = "01" THEN for i in 0 to 3 loop Bank1 (To_Integer(Rows_Load)) (To_Integer(Cols_Load)+i) := (recdata(i*16 to i*16+15)); Bank1 (To_Integer(Rows_Load)) (To_Integer(Cols_Load)+i+4) := (recdata((i+4)*16 to (i+4)*16+15)); end loop; ELSIF Bank_Load = "10" THEN for i in 0 to 3 loop Bank2 (To_Integer(Rows_Load)) (To_Integer(Cols_Load)+i) := (recdata(i*16 to i*16+15)); Bank2 (To_Integer(Rows_Load)) (To_Integer(Cols_Load)+i+4) := (recdata((i+4)*16 to (i+4)*16+15)); end loop; ELSIF Bank_Load = "11" THEN for i in 0 to 3 loop Bank3 (To_Integer(Rows_Load)) (To_Integer(Cols_Load)+i) := (recdata(i*16 to i*16+15)); Bank3 (To_Integer(Rows_Load)) (To_Integer(Cols_Load)+i+4) := (recdata((i+4)*16 to (i+4)*16+15)); end loop; END IF; END case; END IF; END LOOP; END IF; END PROCESS; -- -- Dqs Receiver -- dqs_rcvrs : PROCESS VARIABLE Dm_temp : STD_LOGIC_VECTOR (1 DOWNTO 0); VARIABLE Dq_temp : STD_LOGIC_VECTOR (data_bits - 1 DOWNTO 0); BEGIN WAIT ON Dqs; -- Latch data at posedge Dqs IF Dqs'EVENT AND Dqs (1) = '1' AND Dqs (0) = '1' THEN Dq_temp := Dq; Dm_temp := Dm; END IF; -- Latch data at negedge Dqs IF Dqs'EVENT AND Dqs (1) = '0' AND Dqs (0) = '0' THEN Dq_pair <= (Dq & Dq_temp); Dm_pair <= (Dm & Dm_temp); END IF; END PROCESS; -- -- Setup timing checks -- Setup_check : PROCESS BEGIN WAIT ON Sys_clk; IF Sys_clk'EVENT AND Sys_clk = '1' THEN ASSERT(Cke'LAST_EVENT >= tIS) or (not chktiming) REPORT "CKE Setup time violation -- tIS" SEVERITY WARNING; ASSERT(Cs_n'LAST_EVENT >= tIS) or (not chktiming) REPORT "CS# Setup time violation -- tIS" SEVERITY WARNING; ASSERT(Cas_n'LAST_EVENT >= tIS) or (not chktiming) REPORT "CAS# Setup time violation -- tIS" SEVERITY WARNING; ASSERT(Ras_n'LAST_EVENT >= tIS) or (not chktiming) REPORT "RAS# Setup time violation -- tIS" SEVERITY WARNING; ASSERT(We_n'LAST_EVENT >= tIS) or (not chktiming) REPORT "WE# Setup time violation -- tIS" SEVERITY WARNING; ASSERT(Addr'LAST_EVENT >= tIS) or (not chktiming) REPORT "ADDR Setup time violation -- tIS" SEVERITY WARNING; ASSERT(Ba'LAST_EVENT >= tIS) or (not chktiming) REPORT "BA Setup time violation -- tIS" SEVERITY WARNING; END IF; END PROCESS; -- -- Hold timing checks -- Hold_check : PROCESS BEGIN WAIT ON Sys_clk'DELAYED (tIH); IF Sys_clk'DELAYED (tIH) = '1' THEN ASSERT(Cke'LAST_EVENT >= tIH) or (not chktiming) REPORT "CKE Hold time violation -- tIH" SEVERITY WARNING; ASSERT(Cs_n'LAST_EVENT >= tIH) or (not chktiming) REPORT "CS# Hold time violation -- tIH" SEVERITY WARNING; ASSERT(Cas_n'LAST_EVENT >= tIH) or (not chktiming) REPORT "CAS# Hold time violation -- tIH" SEVERITY WARNING; ASSERT(Ras_n'LAST_EVENT >= tIH) or (not chktiming) REPORT "RAS# Hold time violation -- tIH" SEVERITY WARNING; ASSERT(We_n'LAST_EVENT >= tIH) or (not chktiming) REPORT "WE# Hold time violation -- tIH" SEVERITY WARNING; ASSERT(Addr'LAST_EVENT >= tIH) or (not chktiming) REPORT "ADDR Hold time violation -- tIH" SEVERITY WARNING; ASSERT(Ba'LAST_EVENT >= tIH) or (not chktiming) REPORT "BA Hold time violation -- tIH" SEVERITY WARNING; END IF; END PROCESS; END behave;

gpl-2.0

26e31580908490c833985e09ba8542f4

0.450765

3.993385

false

marco-c/leon-nexys2

grlib-gpl-1.3.4-b4140/lib/gaisler/net/net.vhd

1

13,684

------------------------------------------------------------------------------ -- This file is a part of the GRLIB VHDL IP LIBRARY -- Copyright (C) 2003 - 2008, Gaisler Research -- Copyright (C) 2008 - 2013, Aeroflex Gaisler -- -- This program is free software; you can redistribute it and/or modify -- it under the terms of the GNU General Public License as published by -- the Free Software Foundation; either version 2 of the License, or -- (at your option) any later version. -- -- This program is distributed in the hope that it will be useful, -- but WITHOUT ANY WARRANTY; without even the implied warranty of -- MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the -- GNU General Public License for more details. -- -- You should have received a copy of the GNU General Public License -- along with this program; if not, write to the Free Software -- Foundation, Inc., 59 Temple Place, Suite 330, Boston, MA 02111-1307 USA ----------------------------------------------------------------------------- -- Entity: net -- File: net.vhd -- Author: Jiri Gaisler - Gaisler Research -- Description: Package with component and type declarations for network cores ------------------------------------------------------------------------------ library ieee; use ieee.std_logic_1164.all; library grlib; use grlib.amba.all; package net is type eth_in_type is record gtx_clk : std_ulogic; rmii_clk : std_ulogic; tx_clk : std_ulogic; rx_clk : std_ulogic; rxd : std_logic_vector(7 downto 0); rx_dv : std_ulogic; rx_er : std_ulogic; rx_col : std_ulogic; rx_crs : std_ulogic; mdio_i : std_ulogic; mdint : std_ulogic; phyrstaddr : std_logic_vector(4 downto 0); edcladdr : std_logic_vector(3 downto 0); edclsepahb : std_ulogic; edcldisable: std_ulogic; end record; constant eth_in_none : eth_in_type := ('0', '0', '0', '0', (others => '0'), '0', '0', '0', '0', '0', '0', (others => '0'), (others => '0'), '0', '0'); type eth_out_type is record reset : std_ulogic; txd : std_logic_vector(7 downto 0); tx_en : std_ulogic; tx_er : std_ulogic; tx_clk : std_ulogic; mdc : std_ulogic; mdio_o : std_ulogic; mdio_oe : std_ulogic; gbit : std_ulogic; speed : std_ulogic; end record; constant eth_out_none : eth_out_type := ('0', (others => '0'), '0', '0', '0', '0', '0', '1', '0', '0'); type eth_sgmii_in_type is record clkp : std_ulogic; clkn : std_ulogic; rxp : std_ulogic; rxn : std_ulogic; mdio_i : std_ulogic; mdint : std_ulogic; end record; type eth_sgmii_out_type is record reset : std_ulogic; txp : std_ulogic; txn : std_ulogic; mdc : std_ulogic; mdio_o : std_ulogic; mdio_oe : std_ulogic; end record; component eth_arb generic( fullduplex : integer := 0; mdiomaster : integer := 0); port( rst : in std_logic; clk : in std_logic; ethi : in eth_in_type; etho : out eth_out_type; methi : in eth_out_type; metho : out eth_in_type; dethi : in eth_out_type; detho : out eth_in_type ); end component; component greth is generic( hindex : integer := 0; pindex : integer := 0; paddr : integer := 0; pmask : integer := 16#FFF#; pirq : integer := 0; memtech : integer := 0; ifg_gap : integer := 24; attempt_limit : integer := 16; backoff_limit : integer := 10; slot_time : integer := 128; mdcscaler : integer range 0 to 255 := 25; enable_mdio : integer range 0 to 1 := 0; fifosize : integer range 4 to 512 := 8; nsync : integer range 1 to 2 := 2; edcl : integer range 0 to 3 := 0; edclbufsz : integer range 1 to 64 := 1; macaddrh : integer := 16#00005E#; macaddrl : integer := 16#000000#; ipaddrh : integer := 16#c0a8#; ipaddrl : integer := 16#0035#; phyrstadr : integer range 0 to 32 := 0; rmii : integer range 0 to 1 := 0; oepol : integer range 0 to 1 := 0; scanen : integer range 0 to 1 := 0; ft : integer range 0 to 2 := 0; edclft : integer range 0 to 2 := 0; mdint_pol : integer range 0 to 1 := 0; enable_mdint : integer range 0 to 1 := 0; multicast : integer range 0 to 1 := 0; ramdebug : integer range 0 to 2 := 0; mdiohold : integer := 1; maxsize : integer := 1500 ); port( rst : in std_ulogic; clk : in std_ulogic; ahbmi : in ahb_mst_in_type; ahbmo : out ahb_mst_out_type; apbi : in apb_slv_in_type; apbo : out apb_slv_out_type; ethi : in eth_in_type; etho : out eth_out_type ); end component; component greth_mb is generic( hindex : integer := 0; ehindex : integer := 0; pindex : integer := 0; paddr : integer := 0; pmask : integer := 16#FFF#; pirq : integer := 0; memtech : integer := 0; ifg_gap : integer := 24; attempt_limit : integer := 16; backoff_limit : integer := 10; slot_time : integer := 128; mdcscaler : integer range 0 to 255 := 25; enable_mdio : integer range 0 to 1 := 0; fifosize : integer range 4 to 512 := 8; nsync : integer range 1 to 2 := 2; edcl : integer range 0 to 3 := 0; edclbufsz : integer range 1 to 64 := 1; macaddrh : integer := 16#00005E#; macaddrl : integer := 16#000000#; ipaddrh : integer := 16#c0a8#; ipaddrl : integer := 16#0035#; phyrstadr : integer range 0 to 32 := 0; rmii : integer range 0 to 1 := 0; oepol : integer range 0 to 1 := 0; scanen : integer range 0 to 1 := 0; ft : integer range 0 to 2 := 0; edclft : integer range 0 to 2 := 0; mdint_pol : integer range 0 to 1 := 0; enable_mdint : integer range 0 to 1 := 0; multicast : integer range 0 to 1 := 0; edclsepahb : integer range 0 to 1 := 0; ramdebug : integer range 0 to 2 := 0; mdiohold : integer := 1; maxsize : integer := 1500 ); port( rst : in std_ulogic; clk : in std_ulogic; ahbmi : in ahb_mst_in_type; ahbmo : out ahb_mst_out_type; ahbmi2 : in ahb_mst_in_type; ahbmo2 : out ahb_mst_out_type; apbi : in apb_slv_in_type; apbo : out apb_slv_out_type; ethi : in eth_in_type; etho : out eth_out_type ); end component; component greth_gbit_mb is generic( hindex : integer := 0; ehindex : integer := 0; pindex : integer := 0; paddr : integer := 0; pmask : integer := 16#FFF#; pirq : integer := 0; memtech : integer := 0; ifg_gap : integer := 24; attempt_limit : integer := 16; backoff_limit : integer := 10; slot_time : integer := 128; mdcscaler : integer range 0 to 255 := 25; nsync : integer range 1 to 2 := 2; edcl : integer range 0 to 3 := 0; edclbufsz : integer range 1 to 64 := 1; burstlength : integer range 4 to 128 := 32; macaddrh : integer := 16#00005E#; macaddrl : integer := 16#000000#; ipaddrh : integer := 16#c0a8#; ipaddrl : integer := 16#0035#; phyrstadr : integer range 0 to 32 := 0; sim : integer range 0 to 1 := 0; oepol : integer range 0 to 1 := 0; scanen : integer range 0 to 1 := 0; ft : integer range 0 to 2 := 0; edclft : integer range 0 to 2 := 0; mdint_pol : integer range 0 to 1 := 0; enable_mdint : integer range 0 to 1 := 0; multicast : integer range 0 to 1 := 0; edclsepahb : integer range 0 to 1 := 0; ramdebug : integer range 0 to 2 := 0; mdiohold : integer := 1); port( rst : in std_ulogic; clk : in std_ulogic; ahbmi : in ahb_mst_in_type; ahbmo : out ahb_mst_out_type; ahbmi2 : in ahb_mst_in_type; ahbmo2 : out ahb_mst_out_type; apbi : in apb_slv_in_type; apbo : out apb_slv_out_type; ethi : in eth_in_type; etho : out eth_out_type ); end component; component greth_gbit is generic( hindex : integer := 0; pindex : integer := 0; paddr : integer := 0; pmask : integer := 16#FFF#; pirq : integer := 0; memtech : integer := 0; ifg_gap : integer := 24; attempt_limit : integer := 16; backoff_limit : integer := 10; slot_time : integer := 128; mdcscaler : integer range 0 to 255 := 25; nsync : integer range 1 to 2 := 2; edcl : integer range 0 to 3 := 0; edclbufsz : integer range 1 to 64 := 1; burstlength : integer range 4 to 128 := 32; macaddrh : integer := 16#00005E#; macaddrl : integer := 16#000000#; ipaddrh : integer := 16#c0a8#; ipaddrl : integer := 16#0035#; phyrstadr : integer range 0 to 32 := 0; sim : integer range 0 to 1 := 0; oepol : integer range 0 to 1 := 0; scanen : integer range 0 to 1 := 0; ft : integer range 0 to 2 := 0; edclft : integer range 0 to 2 := 0; mdint_pol : integer range 0 to 1 := 0; enable_mdint : integer range 0 to 1 := 0; multicast : integer range 0 to 1 := 0; ramdebug : integer range 0 to 2 := 0; mdiohold : integer := 1); port( rst : in std_ulogic; clk : in std_ulogic; ahbmi : in ahb_mst_in_type; ahbmo : out ahb_mst_out_type; apbi : in apb_slv_in_type; apbo : out apb_slv_out_type; ethi : in eth_in_type; etho : out eth_out_type ); end component; component grethm generic( hindex : integer := 0; pindex : integer := 0; paddr : integer := 0; pmask : integer := 16#FFF#; pirq : integer := 0; memtech : integer := 0; ifg_gap : integer := 24; attempt_limit : integer := 16; backoff_limit : integer := 10; slot_time : integer := 128; mdcscaler : integer range 0 to 255 := 25; enable_mdio : integer range 0 to 1 := 0; fifosize : integer range 4 to 64 := 8; nsync : integer range 1 to 2 := 2; edcl : integer range 0 to 3 := 0; edclbufsz : integer range 1 to 64 := 1; burstlength : integer range 4 to 128 := 32; macaddrh : integer := 16#00005E#; macaddrl : integer := 16#000000#; ipaddrh : integer := 16#c0a8#; ipaddrl : integer := 16#0035#; phyrstadr : integer range 0 to 32 := 0; rmii : integer range 0 to 1 := 0; sim : integer range 0 to 1 := 0; giga : integer range 0 to 1 := 0; oepol : integer range 0 to 1 := 0; scanen : integer range 0 to 1 := 0; ft : integer range 0 to 2 := 0; edclft : integer range 0 to 1 := 0; mdint_pol : integer range 0 to 1 := 0; enable_mdint : integer range 0 to 1 := 0; multicast : integer range 0 to 1 := 0; ramdebug : integer range 0 to 2 := 0; mdiohold : integer := 1); port( rst : in std_ulogic; clk : in std_ulogic; ahbmi : in ahb_mst_in_type; ahbmo : out ahb_mst_out_type; apbi : in apb_slv_in_type; apbo : out apb_slv_out_type; ethi : in eth_in_type; etho : out eth_out_type ); end component; component rgmii is generic ( pindex : integer := 0; paddr : integer := 0; pmask : integer := 16#fff#; tech : integer := 0; gmii : integer := 0; extclk : integer := 0; clkdiv2 : integer := 0; debugmem : integer := 0 ); port ( rstn : in std_ulogic; clk_tx_g : in std_ulogic; gmiii : out eth_in_type; gmiio : in eth_out_type; rgmiii : in eth_in_type; rgmiio : out eth_out_type ; -- APB Status bus apb_clk : in std_logic; apb_rstn : in std_logic; apbi : in apb_slv_in_type; apbo : out apb_slv_out_type ); end component; end;

gpl-2.0

4dbd3d0c6638b59a4e7b3c17b31216e0

0.48005

3.825552

false

marco-c/leon-nexys2

grlib-gpl-1.3.4-b4140/lib/gaisler/pci/grpci1/pci_target.vhd

1

16,673

------------------------------------------------------------------------------ -- This file is a part of the GRLIB VHDL IP LIBRARY -- Copyright (C) 2003 - 2008, Gaisler Research -- Copyright (C) 2008 - 2013, Aeroflex Gaisler -- -- This program is free software; you can redistribute it and/or modify -- it under the terms of the GNU General Public License as published by -- the Free Software Foundation; either version 2 of the License, or -- (at your option) any later version. -- -- This program is distributed in the hope that it will be useful, -- but WITHOUT ANY WARRANTY; without even the implied warranty of -- MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the -- GNU General Public License for more details. -- -- You should have received a copy of the GNU General Public License -- along with this program; if not, write to the Free Software -- Foundation, Inc., 59 Temple Place, Suite 330, Boston, MA 02111-1307 USA ----------------------------------------------------------------------------- -- Entity: pci_target -- File: pci_target.vhd -- Author: Jiri Gaisler - Gaisler Research -- Description: Simple PCI target interface ------------------------------------------------------------------------------ library ieee; use ieee.std_logic_1164.all; library grlib; use grlib.amba.all; use grlib.stdlib.all; use grlib.devices.all; library gaisler; use gaisler.pci.all; entity pci_target is generic ( hindex : integer := 0; abits : integer := 21; device_id : integer := 0; -- PCI device ID vendor_id : integer := 0; -- PCI vendor ID nsync : integer range 1 to 2 := 1; -- 1 or 2 sync regs between clocks oepol : integer := 0); port( rst : in std_logic; clk : in std_logic; pciclk : in std_logic; pcii : in pci_in_type; pcio : out pci_out_type; ahbmi : in ahb_mst_in_type; ahbmo : out ahb_mst_out_type ); end; architecture rtl of pci_target is constant REVISION : amba_version_type := 0; constant hconfig : ahb_config_type := ( 0 => ahb_device_reg(VENDOR_GAISLER, GAISLER_PCITRG, 0, REVISION, 0), others => zero32); constant CSYNC : integer := nsync-1; constant MADDR_WIDTH : integer := abits; constant zero : std_logic_vector(31 downto 0) := (others => '0'); subtype word4 is std_logic_vector(3 downto 0); subtype word32 is std_logic_vector(31 downto 0); constant pci_memory_read : word4 := "0110"; constant pci_memory_write : word4 := "0111"; constant pci_config_read : word4 := "1010"; constant pci_config_write : word4 := "1011"; constant pci_memory_read_m : word4 := "1100"; -- Aliased to Memory Read constant pci_memory_read_l : word4 := "1110"; -- Aliased to Memory Read constant pci_memory_write_i: word4 := "1111"; -- Aliased to Memory Write type pci_input_type is record ad : std_logic_vector(31 downto 0); cbe : std_logic_vector(3 downto 0); frame : std_logic; devsel : std_logic; idsel : std_logic; trdy : std_logic; irdy : std_logic; par : std_logic; stop : std_logic; rst : std_logic; end record; type pci_target_state_type is (idle, b_busy, s_data, backoff, turn_ar); type pci_reg_type is record addr : std_logic_vector(MADDR_WIDTH-1 downto 0); data : std_logic_vector(31 downto 0); cmd : std_logic_vector(3 downto 0); state : pci_target_state_type; csel : std_logic; msel : std_logic; read : std_logic; devsel : std_logic; trdy : std_logic; stop : std_logic; par : std_logic; oe_par : std_logic; oe_ad : std_logic; oe_ctrl : std_logic; noe_par : std_logic; noe_ad : std_logic; noe_ctrl : std_logic; bar0 : std_logic_vector(31 downto MADDR_WIDTH); page : std_logic_vector(31 downto MADDR_WIDTH-1); men : std_logic; twist : std_logic; laddr : std_logic_vector(31 downto 0); ldata : std_logic_vector(31 downto 0); lsize : std_logic_vector(2 downto 0); lwrite : std_logic; start : std_logic; rready : std_logic_vector(csync downto 0); wready : std_logic_vector(csync downto 0); sync : std_logic_vector(csync downto 0); end record; type cpu_state_type is (idle, sync1, busy, sync2); type cpu_reg_type is record data : std_logic_vector(31 downto 0); state : cpu_state_type; start : std_logic_vector(csync downto 0); sync : std_logic; rready : std_logic; wready : std_logic; end record; signal clk_int : std_logic; signal pr : pci_input_type; signal r, rin : pci_reg_type; signal r2, r2in : cpu_reg_type; signal dmai : ahb_dma_in_type; signal dmao : ahb_dma_out_type; signal roe_ad, rioe_ad : std_logic_vector(31 downto 0); attribute syn_preserve : boolean; attribute syn_preserve of roe_ad : signal is true; function byte_twist(di : in std_logic_vector(31 downto 0); twist : in std_logic) return std_logic_vector is variable do : std_logic_vector(31 downto 0); begin if twist = '1' then for i in 0 to 3 loop do(31-i*8 downto 24-i*8) := di(31-(3-i)*8 downto 24-(3-i)*8); end loop; else do := di; end if; return do; end function; function set_size_from_cbe(cbe : in std_logic_vector(3 downto 0)) return std_logic_vector is variable res : std_logic_vector(1 downto 0); begin case cbe is -- FIXME: this may need to be swaped when "0111" => res := "00"; when "1011" => res := "00"; when "1101" => res := "00"; when "1110" => res := "00"; when "0011" => res := "01"; when "1100" => res := "01"; when others => res := "10"; end case; return res; end function; function set_addr_from_cbe(cbe : in std_logic_vector(3 downto 0); twist: in std_logic) return std_logic_vector is variable res : std_logic_vector(1 downto 0); begin if twist = '1' then -- Little (PCI) to big (AHB) endian case cbe is when "0111" => res := "11"; when "1011" => res := "10"; when "1101" => res := "01"; when "1110" => res := "00"; when "0011" => res := "10"; when "1100" => res := "00"; when others => res := "00"; end case; else -- Big (PCI) to big (AHB) endian case cbe is when "0111" => res := "00"; when "1011" => res := "01"; when "1101" => res := "10"; when "1110" => res := "11"; when "0011" => res := "00"; when "1100" => res := "10"; when others => res := "00"; end case; end if; return res; end function; begin -- Back-end state machine (AHB clock domain) comb : process (rst, r2, r, dmao) variable vdmai : ahb_dma_in_type; variable v : cpu_reg_type; begin v := r2; vdmai.start := '0'; vdmai.burst := '0'; vdmai.size := r.lsize; --"010"; vdmai.address := r.laddr; v.sync := '1'; vdmai.wdata := ahbdrivedata(r.ldata); vdmai.write := r.lwrite; vdmai.irq := '0'; v.start(0) := r2.start(csync); v.start(csync) := r.start; case r2.state is when idle => v.sync := '0'; if r2.start(0) = '1' then if r.lwrite = '1' then v.state := sync1; v.wready := '0'; else v.state := busy; vdmai.start := '1'; end if; end if; when sync1 => if r2.start(0) = '0' then v.state := busy; vdmai.start := '1'; end if; when busy => if dmao.active = '1' then if dmao.ready = '1' then v.rready := not r.lwrite; v.data := dmao.rdata(31 downto 0); v.state := sync2; end if; else vdmai.start := '1'; end if; when sync2 => if r2.start(0) = '0' then v.state := idle; v.wready := '1'; v.rready := '0'; end if; end case; if rst = '0' then v.state := idle; v.rready := '0'; v.wready := '1'; end if; r2in <= v; dmai <= vdmai; end process; -- PCI target core (PCI clock domain) pcicomb : process(pr, pcii, r, r2, roe_ad) variable v : pci_reg_type; variable chit, mhit, hit, ready, cwrite, mwrite : std_logic; variable cdata, cwdata : std_logic_vector(31 downto 0); variable caddr : std_logic_vector(7 downto 2); variable voe_ad : std_logic_vector(31 downto 0); variable oe_ctrl, oe_par, oe_ad : std_ulogic; begin v := r; v.trdy := '1'; v.stop := '1'; voe_ad := roe_ad; v.oe_ad := '1'; v.devsel := '1'; mwrite := '0'; v.rready(0) := r.rready(csync); v.rready(csync) := r2.rready; v.wready(0) := r.wready(csync); v.wready(csync) := r2.wready; v.sync(0) := r.sync(csync); v.sync(csync) := r2.sync; -- address decoding --if (r.state = s_data) and ((pr.irdy or r.trdy or r.read) = '0') then if (r.state = turn_ar) and ((pr.irdy or pr.trdy or r.read) = '0') then cwrite := r.csel; if ((r.msel and r.addr(MADDR_WIDTH-1)) = '1') and (pr.cbe = "0000") then v.page := pr.ad(31 downto MADDR_WIDTH-1); v.twist := pr.ad(0); end if; if (pr.cbe = "0000") and (r.addr(MADDR_WIDTH-1) = '1') then mwrite := r.msel; end if; else cwrite := '0'; end if; cdata := (others => '0'); caddr := r.addr(7 downto 2); case caddr is when "000000" => -- 0x00, device & vendor id cdata := conv_std_logic_vector(DEVICE_ID, 16) & conv_std_logic_vector(VENDOR_ID, 16); when "000001" => -- 0x04, status & command cdata(1) := r.men; cdata(26) := '1'; when "000010" => -- 0x08, class code & revision when "000011" => -- 0x0c, latency & cacheline size when "000100" => -- 0x10, BAR0 cdata(31 downto MADDR_WIDTH) := r.bar0; when others => end case; cwdata := pr.ad; if pr.cbe(3) = '1' then cwdata(31 downto 24) := cdata(31 downto 24); end if; if pr.cbe(2) = '1' then cwdata(23 downto 16) := cdata(23 downto 16); end if; if pr.cbe(1) = '1' then cwdata(15 downto 8) := cdata(15 downto 8); end if; if pr.cbe(0) = '1' then cwdata( 7 downto 0) := cdata( 7 downto 0); end if; if cwrite = '1' then case caddr is when "000001" => -- 0x04, status & command v.men := cwdata(1); when "000100" => -- 0x10, BAR0 v.bar0 := cwdata(31 downto MADDR_WIDTH); when others => end case; end if; if (((pr.cbe = pci_config_read) or (pr.cbe = pci_config_write)) and (pr.ad(1 downto 0) = "00")) then chit := '1'; else chit := '0'; end if; if ((pr.cbe = pci_memory_read) or (pr.cbe = pci_memory_write) or (pr.cbe = pci_memory_read_m) or (pr.cbe = pci_memory_read_l) or (pr.cbe = pci_memory_write_i)) and (r.bar0 = pr.ad(31 downto MADDR_WIDTH)) and (r.bar0 /= zero(31 downto MADDR_WIDTH)) then mhit := '1'; else mhit := '0'; end if; hit := r.csel or r.msel; ready := r.csel or (r.rready(0) and r.read) or (r.wready(0) and not r.read and not r.start) or r.addr(MADDR_WIDTH-1); -- target state machine case r.state is when idle => if pr.frame = '0' then v.state := b_busy; end if; -- !HIT ? v.addr := pr.ad(MADDR_WIDTH-1 downto 0); v.cmd := pr.cbe; v.csel := pr.idsel and chit; v.msel := r.men and mhit; v.read := not pr.cbe(0); if (r.sync(0) and r.start and r.lwrite) = '1' then v.start := '0'; end if; when turn_ar => if pr.frame = '1' then v.state := idle; end if; if pr.frame = '0' then v.state := b_busy; end if; -- !HIT ? v.addr := pr.ad(MADDR_WIDTH-1 downto 0); v.cmd := pr.cbe; v.csel := pr.idsel and chit; v.msel := r.men and mhit; v.read := not pr.cbe(0); if (r.sync(0) and r.start and r.lwrite) = '1' then v.start := '0'; end if; when b_busy => if hit = '1' then v.state := s_data; v.trdy := not ready; v.stop := pr.frame and ready; v.devsel := '0'; else v.state := backoff; end if; when s_data => v.stop := r.stop; v.devsel := '0'; v.trdy := r.trdy or not pcii.irdy; if (pcii.frame and not pcii.irdy) = '1' then v.state := turn_ar; v.stop := '1'; v.trdy := '1'; v.devsel := '1'; end if; when backoff => if pr.frame = '1' then v.state := idle; end if; end case; if ((r.state = s_data) or (r.state = turn_ar)) and (((pr.irdy or pr.trdy) = '0') or ((not pr.irdy and not pr.stop and pr.trdy and not r.start and r.wready(0)) = '1')) then if (pr.trdy and r.read)= '0' then v.start := '0'; end if; if (r.start = '0') and ((r.msel and not r.addr(MADDR_WIDTH-1)) = '1') and (((pr.trdy and r.read and not r.rready(0)) or (not pr.trdy and not r.read)) = '1') then v.laddr := r.page & r.addr(MADDR_WIDTH-2 downto 0); v.ldata := pr.ad; v.lwrite := not r.read; v.start := '1'; -- Added little/big endian support v.laddr := v.laddr(31 downto 2) & set_addr_from_cbe(pr.cbe, r.twist); v.ldata := byte_twist(v.ldata, r.twist); v.lsize := '0' & set_size_from_cbe(pr.cbe); end if; end if; if (v.state = s_data) and (r.read = '1') then v.oe_ad := '0'; end if; v.oe_par := r.oe_ad; if r.csel = '1' then v.data := cdata; elsif r.addr(MADDR_WIDTH-1) = '1' then v.data(31 downto MADDR_WIDTH-1) := r.page; v.data(MADDR_WIDTH-2 downto 0) := (others => '0'); v.data(0) := r.twist; -- Addded little/bit endian support --else v.data := r2.data; end if; else v.data := byte_twist(r2.data, r.twist); end if; v.par := xorv(r.data & pcii.cbe); if (v.state = s_data) or (r.state = s_data) then v.oe_ctrl := '0'; else v.oe_ctrl := '1'; end if; v.noe_ctrl := not v.oe_ctrl; v.noe_ad := not v.oe_ad; v.noe_par := not v.oe_par; if oepol = 1 then oe_ctrl := r.noe_ctrl; oe_ad := r.noe_ad; oe_par := r.noe_par; voe_ad := (others => v.noe_ad); else oe_ctrl := r.oe_ctrl; oe_ad := r.oe_ad; oe_par := r.oe_par; voe_ad := (others => v.oe_ad); end if; if pr.rst = '0' then v.state := idle; v.men := '0'; v.start := '0'; v.bar0 := (others => '0'); v.msel := '0'; v.csel := '0'; v.page := (others => '0'); v.page(31 downto 30) := "01"; v.twist := '0'; end if; rin <= v; rioe_ad <= voe_ad; pcio.ctrlen <= oe_ctrl; pcio.trdy <= r.trdy; pcio.trdyen <= oe_ctrl; pcio.stop <= r.stop; pcio.stopen <= oe_ctrl; pcio.devsel <= r.devsel; pcio.devselen <= oe_ctrl; pcio.par <= r.par; pcio.paren <= oe_par; pcio.aden <= oe_ad; pcio.ad <= r.data; pcio.rst <= '1'; end process; pcir : process (pciclk, pcii.rst, r2) begin if rising_edge (pciclk) then pr.ad <= to_x01(pcii.ad); pr.cbe <= to_x01(pcii.cbe); pr.devsel <= to_x01(pcii.devsel); pr.frame <= to_x01(pcii.frame); pr.idsel <= to_x01(pcii.idsel); pr.irdy <= to_x01(pcii.irdy); pr.trdy <= to_x01(pcii.trdy); pr.par <= to_x01(pcii.par); pr.stop <= to_x01(pcii.stop); pr.rst <= to_x01(pcii.rst); r <= rin; roe_ad <= rioe_ad; end if; if pcii.rst = '0' then -- asynch reset required r.oe_ctrl <= '1'; r.oe_par <= '1'; r.oe_ad <= '1'; r.noe_ctrl <= '0'; r.noe_par <= '0'; r.noe_ad <= '0'; if oepol = 0 then roe_ad <= (others => '1'); else roe_ad <= (others => '0'); end if; end if; end process; cpur : process (clk) begin if rising_edge (clk) then r2 <= r2in; end if; end process; oe0 : if oepol = 0 generate pcio.perren <= '1'; pcio.cbeen <= (others => '1'); pcio.serren <= '1'; pcio.inten <= '1'; pcio.vinten <= (others => '1'); pcio.reqen <= not pcii.rst; pcio.frameen <= '1'; pcio.irdyen <= '1'; pcio.locken <= '1'; end generate; oe1 : if oepol = 1 generate pcio.perren <= '0'; pcio.cbeen <= (others => '0'); pcio.serren <= '0'; pcio.inten <= '0'; pcio.vinten <= (others => '0'); pcio.reqen <= pcii.rst; pcio.frameen <= '0'; pcio.irdyen <= '0'; pcio.locken <= '0'; end generate; pcio.vaden <= roe_ad; pcio.cbe <= "1111"; pcio.perr <= '1'; pcio.serr <= '1'; pcio.int <= '1'; pcio.req <= '1'; pcio.frame <= '1'; pcio.irdy <= '1'; ahbmst0 : ahbmst generic map (hindex => hindex, devid => GAISLER_PCITRG) port map (rst, clk, dmai, dmao, ahbmi, ahbmo); -- pragma translate_off bootmsg : report_version generic map ("pci_target" & tost(hindex) & ": 32-bit PCI Target rev " & tost(REVISION) & ", " & tost(abits) & "-bit PCI memory BAR" ); -- pragma translate_on end;

gpl-2.0

1e9fbc3cc3e9c22dfa07ce2221726183

0.55179

2.974135

false

mistryalok/Zedboard

learning/training/MSD/s05/project_1/project_1.srcs/sources_1/ipshared/xilinx.com/axi_cdma_v4_1/25515467/hdl/src/vhdl/axi_cdma_lite_if.vhd

1

61,561

------------------------------------------------------------------------------- -- axi_cdma_lite_if ------------------------------------------------------------------------------- -- -- ************************************************************************* -- -- (c) Copyright 2010, 2011 Xilinx, Inc. All rights reserved. -- -- This file contains confidential and proprietary information -- of Xilinx, Inc. and is protected under U.S. and -- international copyright and other intellectual property -- laws. -- -- DISCLAIMER -- This disclaimer is not a license and does not grant any -- rights to the materials distributed herewith. Except as -- otherwise provided in a valid license issued to you by -- Xilinx, and to the maximum extent permitted by applicable -- law: (1) THESE MATERIALS ARE MADE AVAILABLE "AS IS" AND -- WITH ALL FAULTS, AND XILINX HEREBY DISCLAIMS ALL WARRANTIES -- AND CONDITIONS, EXPRESS, IMPLIED, OR STATUTORY, INCLUDING -- BUT NOT LIMITED TO WARRANTIES OF MERCHANTABILITY, NON- -- INFRINGEMENT, OR FITNESS FOR ANY PARTICULAR PURPOSE; and -- (2) Xilinx shall not be liable (whether in contract or tort, -- including negligence, or under any other theory of -- liability) for any loss or damage of any kind or nature -- related to, arising under or in connection with these -- materials, including for any direct, or any indirect, -- special, incidental, or consequential loss or damage -- (including loss of data, profits, goodwill, or any type of -- loss or damage suffered as a result of any action brought -- by a third party) even if such damage or loss was -- reasonably foreseeable or Xilinx had been advised of the -- possibility of the same. -- -- CRITICAL APPLICATIONS -- Xilinx products are not designed or intended to be fail- -- safe, or for use in any application requiring fail-safe -- performance, such as life-support or safety devices or -- systems, Class III medical devices, nuclear facilities, -- applications related to the deployment of airbags, or any -- other applications that could lead to death, personal -- injury, or severe property or environmental damage -- (individually and collectively, "Critical -- Applications"). Customer assumes the sole risk and -- liability of any use of Xilinx products in Critical -- Applications, subject only to applicable laws and -- regulations governing limitations on product liability. -- -- THIS COPYRIGHT NOTICE AND DISCLAIMER MUST BE RETAINED AS -- PART OF THIS FILE AT ALL TIMES. -- -- ************************************************************************* -- ------------------------------------------------------------------------------- -- Filename: axi_cdma_lite_if.vhd -- Description: This entity is AXI Lite Interface Module for the AXI DMA -- -- VHDL-Standard: VHDL'93 ------------------------------------------------------------------------------- ------------------------------------------------------------------------------- library ieee; use ieee.std_logic_1164.all; use ieee.numeric_std.all; use ieee.std_logic_misc.all; library unisim; use unisim.vcomponents.all; library axi_cdma_v4_1; use axi_cdma_v4_1.axi_cdma_pkg.all; library lib_pkg_v1_0; use lib_pkg_v1_0.lib_pkg.clog2; library lib_cdc_v1_0; ------------------------------------------------------------------------------- entity axi_cdma_lite_if is generic( C_NUM_CE : integer := 8 ; C_AXI_LITE_IS_ASYNC : integer range 0 to 1 := 0 ; C_S_AXI_LITE_ADDR_WIDTH : integer range 2 to 32 := 32 ; C_S_AXI_LITE_DATA_WIDTH : integer range 32 to 32 := 32 ); port ( -- Async clock input ip2axi_aclk : in std_logic ; -- ip2axi_aresetn : in std_logic ; -- ----------------------------------------------------------------------- -- AXI Lite Control Interface ----------------------------------------------------------------------- s_axi_lite_aclk : in std_logic ; -- s_axi_lite_aresetn : in std_logic ; -- -- -- AXI Lite Write Address Channel -- s_axi_lite_awvalid : in std_logic ; -- s_axi_lite_awready : out std_logic ; -- s_axi_lite_awaddr : in std_logic_vector -- (C_S_AXI_LITE_ADDR_WIDTH-1 downto 0); -- -- -- AXI Lite Write Data Channel -- s_axi_lite_wvalid : in std_logic ; -- s_axi_lite_wready : out std_logic ; -- s_axi_lite_wdata : in std_logic_vector -- (C_S_AXI_LITE_DATA_WIDTH-1 downto 0); -- -- -- AXI Lite Write Response Channel -- s_axi_lite_bresp : out std_logic_vector(1 downto 0) ; -- s_axi_lite_bvalid : out std_logic ; -- s_axi_lite_bready : in std_logic ; -- -- -- AXI Lite Read Address Channel -- s_axi_lite_arvalid : in std_logic ; -- s_axi_lite_arready : out std_logic ; -- s_axi_lite_araddr : in std_logic_vector -- (C_S_AXI_LITE_ADDR_WIDTH-1 downto 0); -- s_axi_lite_rvalid : out std_logic ; -- s_axi_lite_rready : in std_logic ; -- s_axi_lite_rdata : out std_logic_vector -- (C_S_AXI_LITE_DATA_WIDTH-1 downto 0); -- s_axi_lite_rresp : out std_logic_vector(1 downto 0) ; -- -- -- User IP Interface -- axi2ip_wrce : out std_logic_vector -- (C_NUM_CE-1 downto 0) ; -- axi2ip_wrdata : out std_logic_vector -- (C_S_AXI_LITE_DATA_WIDTH-1 downto 0); -- -- axi2ip_rdce : out std_logic_vector -- (C_NUM_CE-1 downto 0) ; -- axi2ip_rdaddr : out std_logic_vector -- (C_S_AXI_LITE_ADDR_WIDTH-1 downto 0); -- ip2axi_rddata : in std_logic_vector -- (C_S_AXI_LITE_DATA_WIDTH-1 downto 0) -- ); end axi_cdma_lite_if; ------------------------------------------------------------------------------- -- Architecture ------------------------------------------------------------------------------- architecture implementation of axi_cdma_lite_if is attribute DowngradeIPIdentifiedWarnings: string; attribute DowngradeIPIdentifiedWarnings of implementation : architecture is "yes"; ------------------------------------------------------------------------------- -- Functions ------------------------------------------------------------------------------- -- No Functions Declared ------------------------------------------------------------------------------- -- Constants Declarations ------------------------------------------------------------------------------- -- Register I/F Address offset constant ADDR_OFFSET : integer := clog2(C_S_AXI_LITE_DATA_WIDTH/8); -- Register I/F CE number constant CE_ADDR_SIZE : integer := clog2(C_NUM_CE); ------------------------------------------------------------------------------- -- Signal / Type Declarations ------------------------------------------------------------------------------- -- AXI Lite slave interface signals signal awvalid : std_logic := '0'; signal awaddr : std_logic_vector (C_S_AXI_LITE_ADDR_WIDTH-1 downto 0) := (others => '0'); signal wvalid : std_logic := '0'; signal wdata : std_logic_vector (C_S_AXI_LITE_DATA_WIDTH-1 downto 0) := (others => '0'); signal arvalid : std_logic := '0'; signal araddr : std_logic_vector (C_S_AXI_LITE_ADDR_WIDTH-1 downto 0) := (others => '0'); signal awvalid_d1 : std_logic := '0'; signal awvalid_re : std_logic := '0'; signal awready_i : std_logic := '0'; signal wvalid_d1 : std_logic := '0'; signal wvalid_re : std_logic := '0'; signal wready_i : std_logic := '0'; signal bvalid_i : std_logic := '0'; signal wr_addr_cap : std_logic := '0'; signal wr_data_cap : std_logic := '0'; -- AXI to IP interface signals signal axi2ip_wraddr_i : std_logic_vector (C_S_AXI_LITE_ADDR_WIDTH-1 downto 0) := (others => '0'); signal axi2ip_wrdata_i : std_logic_vector (C_S_AXI_LITE_DATA_WIDTH-1 downto 0) := (others => '0'); signal axi2ip_wren : std_logic := '0'; signal wrce : std_logic_vector(C_NUM_CE-1 downto 0); signal rdce : std_logic_vector(C_NUM_CE-1 downto 0) := (others => '0'); signal arvalid_d1 : std_logic := '0'; signal arvalid_re : std_logic := '0'; signal arvalid_re_d1 : std_logic := '0'; signal arvalid_i : std_logic := '0'; signal arready_i : std_logic := '0'; signal rvalid : std_logic := '0'; signal axi2ip_rdaddr_i : std_logic_vector (C_S_AXI_LITE_ADDR_WIDTH-1 downto 0) := (others => '0'); signal s_axi_lite_rvalid_i : std_logic := '0'; signal read_in_progress : std_logic := '0'; -- CR607165 signal rst_rvalid_re : std_logic := '0'; -- CR576999 signal rst_wvalid_re : std_logic := '0'; -- CR576999 signal rdy : std_logic := '0'; signal rdy1 : std_logic := '0'; signal wr_in_progress : std_logic := '0'; ------------------------------------------------------------------------------- -- Begin architecture logic ------------------------------------------------------------------------------- begin --***************************************************************************** --** AXI LITE READ --***************************************************************************** s_axi_lite_wready <= wready_i; s_axi_lite_awready <= awready_i; s_axi_lite_arready <= arready_i; s_axi_lite_bvalid <= bvalid_i; ------------------------------------------------------------------------------- -- Register AXI Inputs ------------------------------------------------------------------------------- REG_INPUTS : process(s_axi_lite_aclk) begin if(s_axi_lite_aclk'EVENT and s_axi_lite_aclk = '1')then if(s_axi_lite_aresetn = '0')then awvalid <= '0' ; awaddr <= (others => '0') ; wvalid <= '0' ; wdata <= (others => '0') ; arvalid <= '0' ; araddr <= (others => '0') ; else awvalid <= s_axi_lite_awvalid ; awaddr <= s_axi_lite_awaddr ; wvalid <= s_axi_lite_wvalid ; wdata <= s_axi_lite_wdata ; arvalid <= s_axi_lite_arvalid ; araddr <= s_axi_lite_araddr ; end if; end if; end process REG_INPUTS; -- s_axi_lite_aclk is synchronous to ip clock GEN_SYNC_WRITE : if C_AXI_LITE_IS_ASYNC = 0 generate begin ------------------------------------------------------------------------------- -- Assert Write Adddress Ready Handshake -- Capture rising edge of valid and register out as ready. This creates -- a 3 clock cycle address phase but also registers all inputs and outputs. -- Note : Single clock cycle address phase can be accomplished using -- combinatorial logic. ------------------------------------------------------------------------------- REG_AWVALID : process(s_axi_lite_aclk) begin if(s_axi_lite_aclk'EVENT and s_axi_lite_aclk = '1')then if(s_axi_lite_aresetn = '0' or rst_wvalid_re = '1')then awvalid_d1 <= '0'; -- awvalid_re <= '0'; -- CR605883 else awvalid_d1 <= awvalid; -- awvalid_re <= awvalid and not awvalid_d1; -- CR605883 end if; end if; end process REG_AWVALID; awvalid_re <= awvalid and not awvalid_d1 and (not (wr_in_progress)); -- CR605883 ------------------------------------------------------------------------------- -- Capture assertion of awvalid to indicate that we have captured -- a valid address ------------------------------------------------------------------------------- ------------------------------------------------------------------------------- -- Assert Write Data Ready Handshake -- Capture rising edge of valid and register out as ready. This creates -- a 3 clock cycle address phase but also registers all inputs and outputs. -- Note : Single clock cycle address phase can be accomplished using -- combinatorial logic. ------------------------------------------------------------------------------- REG_WVALID : process(s_axi_lite_aclk) begin if(s_axi_lite_aclk'EVENT and s_axi_lite_aclk = '1')then if(s_axi_lite_aresetn = '0' or rst_wvalid_re = '1')then wvalid_d1 <= '0'; -- wvalid_re <= '0'; else wvalid_d1 <= wvalid; -- wvalid_re <= wvalid and not wvalid_d1; -- CR605883 end if; end if; end process REG_WVALID; wvalid_re <= wvalid and not wvalid_d1; -- CR605883 WRITE_IN_PROGRESS : process(s_axi_lite_aclk) begin if(s_axi_lite_aclk'EVENT and s_axi_lite_aclk = '1')then if(s_axi_lite_aresetn = '0' or rst_wvalid_re = '1')then wr_in_progress <= '0'; elsif(awvalid_re = '1')then wr_in_progress <= '1'; end if; end if; end process WRITE_IN_PROGRESS; -- CR605883 (CDC) provide pure register output to synchronizers --wvalid_re <= wvalid and not wvalid_d1 and not rst_wvalid_re; ------------------------------------------------------------------------------- -- Capture assertion of wvalid to indicate that we have captured -- valid data ------------------------------------------------------------------------------- WRDATA_CAP_FLAG : process(s_axi_lite_aclk) begin if(s_axi_lite_aclk'EVENT and s_axi_lite_aclk = '1')then if(s_axi_lite_aresetn = '0' or rdy = '1')then wr_data_cap <= '0'; elsif(wvalid_re = '1')then wr_data_cap <= '1'; end if; end if; end process WRDATA_CAP_FLAG; REG_WREADY : process(s_axi_lite_aclk) begin if(s_axi_lite_aclk'EVENT and s_axi_lite_aclk = '1')then if(s_axi_lite_aresetn = '0' or rdy = '1') then rdy <= '0'; elsif (wr_data_cap = '1' and wr_addr_cap = '1') then rdy <= '1'; end if; wready_i <= rdy; awready_i <= rdy; rdy1 <= rdy; end if; end process REG_WREADY; WRADDR_CAP_FLAG : process(s_axi_lite_aclk) begin if(s_axi_lite_aclk'EVENT and s_axi_lite_aclk = '1')then if(s_axi_lite_aresetn = '0' or rdy = '1')then wr_addr_cap <= '0'; elsif(awvalid_re = '1')then wr_addr_cap <= '1'; end if; end if; end process WRADDR_CAP_FLAG; ------------------------------------------------------------------------------- -- Capture Write Address ------------------------------------------------------------------------------- REG_WRITE_ADDRESS : process(s_axi_lite_aclk) begin if(s_axi_lite_aclk'EVENT and s_axi_lite_aclk = '1')then if(s_axi_lite_aresetn = '0')then -- axi2ip_wraddr_i <= (others => '0'); -- Register address on valid elsif(awvalid_re = '1')then -- axi2ip_wraddr_i <= awaddr; end if; end if; end process REG_WRITE_ADDRESS; ------------------------------------------------------------------------------- -- Capture Write Data ------------------------------------------------------------------------------- REG_WRITE_DATA : process(s_axi_lite_aclk) begin if(s_axi_lite_aclk'EVENT and s_axi_lite_aclk = '1')then if(s_axi_lite_aresetn = '0')then axi2ip_wrdata_i <= (others => '0'); -- Register address and assert ready elsif(wvalid_re = '1')then axi2ip_wrdata_i <= wdata; end if; end if; end process REG_WRITE_DATA; ------------------------------------------------------------------------------- -- Must have both a valid address and valid data before updating -- a register. Note in AXI write address can come before or -- after AXI write data. -- axi2ip_wren <= '1' when wr_data_cap = '1' and wr_addr_cap = '1' -- else '0'; axi2ip_wren <= rdy; -- or rdy1; ------------------------------------------------------------------------------- -- Decode and assert proper chip enable per captured axi lite write address ------------------------------------------------------------------------------- WRCE_GEN: for j in 0 to C_NUM_CE - 1 generate constant BAR : std_logic_vector(CE_ADDR_SIZE-1 downto 0) := std_logic_vector(to_unsigned(j,CE_ADDR_SIZE)); begin wrce(j) <= axi2ip_wren when s_axi_lite_awaddr ((CE_ADDR_SIZE + ADDR_OFFSET) - 1 downto ADDR_OFFSET) = BAR(CE_ADDR_SIZE-1 downto 0) else '0'; end generate WRCE_GEN; ------------------------------------------------------------------------------- -- register write ce's and data out to axi dma register module ------------------------------------------------------------------------------- REG_WR_OUT : process(s_axi_lite_aclk) begin if(s_axi_lite_aclk'EVENT and s_axi_lite_aclk = '1')then if(s_axi_lite_aresetn = '0')then axi2ip_wrce <= (others => '0'); -- axi2ip_wrdata <= (others => '0'); else axi2ip_wrce <= wrce; -- axi2ip_wrdata <= axi2ip_wrdata_i; end if; end if; end process REG_WR_OUT; axi2ip_wrdata <= s_axi_lite_wdata; ------------------------------------------------------------------------------- -- Write Response ------------------------------------------------------------------------------- s_axi_lite_bresp <= OKAY_RESP; WRESP_PROCESS : process(s_axi_lite_aclk) begin if(s_axi_lite_aclk'EVENT and s_axi_lite_aclk = '1')then if(s_axi_lite_aresetn = '0')then bvalid_i <= '0'; rst_wvalid_re <= '0'; -- CR576999 -- If response issued and target indicates ready then -- clear response elsif(bvalid_i = '1' and s_axi_lite_bready = '1')then bvalid_i <= '0'; rst_wvalid_re <= '0'; -- CR576999 -- Issue a resonse on write elsif(rdy1 = '1')then bvalid_i <= '1'; rst_wvalid_re <= '1'; -- CR576999 end if; end if; end process WRESP_PROCESS; end generate GEN_SYNC_WRITE; -- s_axi_lite_aclk is asynchronous to ip clock GEN_ASYNC_WRITE : if C_AXI_LITE_IS_ASYNC = 1 generate -- Data support ----------------------------------------------------------------------------- -- ATTRIBUTE Declarations ----------------------------------------------------------------------------- -- Prevent x-propagation on clock-domain crossing register ATTRIBUTE async_reg : STRING; Attribute KEEP : string; -- declaration Attribute EQUIVALENT_REGISTER_REMOVAL : string; -- declaration signal ip_wvalid_d1_cdc_to : std_logic := '0'; signal ip_wvalid_d2 : std_logic := '0'; signal ip_wvalid_re : std_logic := '0'; signal wr_wvalid_re_cdc_from : std_logic := '0'; signal wr_data_cdc_from : std_logic_vector -- CR605883 (C_S_AXI_LITE_DATA_WIDTH-1 downto 0) := (others => '0'); -- CR605883 signal wdata_d1_cdc_to : std_logic_vector (C_S_AXI_LITE_DATA_WIDTH-1 downto 0) := (others => '0'); signal wdata_d2 : std_logic_vector (C_S_AXI_LITE_DATA_WIDTH-1 downto 0) := (others => '0'); signal axi2ip_wrdata_cdc_tig : std_logic_vector (C_S_AXI_LITE_DATA_WIDTH-1 downto 0) := (others => '0'); signal ip_data_cap : std_logic := '0'; -- Address support signal ip_awvalid_d1_cdc_to : std_logic := '0'; signal ip_awvalid_d2 : std_logic := '0'; signal ip_awvalid_re : std_logic := '0'; signal wr_awvalid_re_cdc_from : std_logic := '0'; signal wr_addr_cdc_from : std_logic_vector -- CR605883 (C_S_AXI_LITE_ADDR_WIDTH-1 downto 0) := (others => '0'); -- CR605883 signal awaddr_d1_cdc_tig : std_logic_vector (C_S_AXI_LITE_ADDR_WIDTH-1 downto 0) := (others => '0'); signal awaddr_d2 : std_logic_vector (C_S_AXI_LITE_ADDR_WIDTH-1 downto 0) := (others => '0'); signal ip_addr_cap : std_logic := '0'; -- Bvalid support signal lite_data_cap_d1 : std_logic := '0'; signal lite_data_cap_d2 : std_logic := '0'; signal lite_addr_cap_d1 : std_logic := '0'; signal lite_addr_cap_d2 : std_logic := '0'; signal lite_axi2ip_wren : std_logic := '0'; signal awvalid_cdc_from : std_logic := '0'; signal awvalid_cdc_to : std_logic := '0'; signal awvalid_to : std_logic := '0'; signal awvalid_to2 : std_logic := '0'; -- ATTRIBUTE async_reg OF awvalid_cdc_to : SIGNAL IS "true"; -- ATTRIBUTE async_reg OF awvalid_to : SIGNAL IS "true"; signal wvalid_cdc_from : std_logic := '0'; signal wvalid_cdc_to : std_logic := '0'; signal wvalid_to : std_logic := '0'; signal wvalid_to2 : std_logic := '0'; -- ATTRIBUTE async_reg OF wvalid_cdc_to : SIGNAL IS "true"; -- ATTRIBUTE async_reg OF wvalid_to : SIGNAL IS "true"; signal rdy_cdc_to : std_logic := '0'; signal rdy_cdc_from : std_logic := '0'; signal rdy_to : std_logic := '0'; signal rdy_to2 : std_logic := '0'; signal rdy_to2_cdc_from : std_logic := '0'; signal rdy_out : std_logic := '0'; -- ATTRIBUTE async_reg OF rdy_cdc_to : SIGNAL IS "true"; -- ATTRIBUTE async_reg OF rdy_to : SIGNAL IS "true"; Attribute KEEP of rdy_to2_cdc_from : signal is "TRUE"; Attribute EQUIVALENT_REGISTER_REMOVAL of rdy_to2_cdc_from : signal is "no"; signal rdy_back_cdc_to : std_logic := '0'; signal rdy_back_to : std_logic :='0'; -- ATTRIBUTE async_reg OF rdy_back_cdc_to : SIGNAL IS "true"; -- ATTRIBUTE async_reg OF rdy_back_to : SIGNAL IS "true"; signal rdy_back : std_logic := '0'; signal rdy_shut : std_logic := '0'; begin REG_AWVALID : process(s_axi_lite_aclk) begin if(s_axi_lite_aclk'EVENT and s_axi_lite_aclk = '1')then if(s_axi_lite_aresetn = '0' or rst_wvalid_re = '1')then awvalid_d1 <= '0'; else awvalid_d1 <= awvalid; end if; end if; end process REG_AWVALID; awvalid_re <= awvalid and not awvalid_d1 and (not (wr_in_progress)); -- CR605883 ------------------------------------------------------------------------------- -- Capture assertion of awvalid to indicate that we have captured -- a valid address ------------------------------------------------------------------------------- ------------------------------------------------------------------------------- -- Assert Write Data Ready Handshake -- Capture rising edge of valid and register out as ready. This creates -- a 3 clock cycle address phase but also registers all inputs and outputs. -- Note : Single clock cycle address phase can be accomplished using -- combinatorial logic. ------------------------------------------------------------------------------- REG_WVALID : process(s_axi_lite_aclk) begin if(s_axi_lite_aclk'EVENT and s_axi_lite_aclk = '1')then if(s_axi_lite_aresetn = '0' or rst_wvalid_re = '1')then wvalid_d1 <= '0'; else wvalid_d1 <= wvalid; end if; end if; end process REG_WVALID; wvalid_re <= wvalid and not wvalid_d1; -- CR605883 --************************************************************************* --** Write Address Support --************************************************************************* AWVLD_CDC_FROM : process(s_axi_lite_aclk) begin if(s_axi_lite_aclk'EVENT and s_axi_lite_aclk = '1')then if(s_axi_lite_aresetn = '0' or rst_wvalid_re = '1')then awvalid_cdc_from <= '0'; elsif(awvalid_re = '1')then awvalid_cdc_from <= '1'; end if; end if; end process AWVLD_CDC_FROM; AWVLD_CDC_TO : entity lib_cdc_v1_0.cdc_sync generic map ( C_CDC_TYPE => 1, C_RESET_STATE => 0, C_SINGLE_BIT => 1, C_VECTOR_WIDTH => 32, C_MTBF_STAGES => MTBF_STAGES ) port map ( prmry_aclk => s_axi_lite_aclk, prmry_resetn => '0', prmry_in => awvalid_cdc_from, prmry_vect_in => (others => '0'), scndry_aclk => ip2axi_aclk, scndry_resetn => '0', scndry_out => awvalid_to, scndry_vect_out => open ); -- AWVLD_CDC_TO : process(ip2axi_aclk) -- begin -- if(ip2axi_aclk'EVENT and ip2axi_aclk = '1')then -- awvalid_cdc_to <= awvalid_cdc_from; -- awvalid_to <= awvalid_cdc_to; -- end if; -- end process AWVLD_CDC_TO; AWVLD_CDC_TO2 : process(ip2axi_aclk) begin if(ip2axi_aclk'EVENT and ip2axi_aclk = '1')then if(ip2axi_aresetn = '0')then awvalid_to2 <= '0'; else awvalid_to2 <= awvalid_to; end if; end if; end process AWVLD_CDC_TO2; ip_awvalid_re <= awvalid_to and (not awvalid_to2); WVLD_CDC_FROM : process(s_axi_lite_aclk) begin if(s_axi_lite_aclk'EVENT and s_axi_lite_aclk = '1')then if(s_axi_lite_aresetn = '0' or rst_wvalid_re = '1')then wvalid_cdc_from <= '0'; elsif(wvalid_re = '1')then wvalid_cdc_from <= '1'; end if; end if; end process WVLD_CDC_FROM; WVLD_CDC_TO : entity lib_cdc_v1_0.cdc_sync generic map ( C_CDC_TYPE => 1, C_RESET_STATE => 0, C_SINGLE_BIT => 1, C_VECTOR_WIDTH => 32, C_MTBF_STAGES => MTBF_STAGES ) port map ( prmry_aclk => s_axi_lite_aclk, prmry_resetn => '0', prmry_in => wvalid_cdc_from, prmry_vect_in => (others => '0'), scndry_aclk => ip2axi_aclk, scndry_resetn => '0', scndry_out => wvalid_to, scndry_vect_out => open ); -- WVLD_CDC_TO : process(ip2axi_aclk) -- begin -- if(ip2axi_aclk'EVENT and ip2axi_aclk = '1')then -- wvalid_cdc_to <= wvalid_cdc_from; -- wvalid_to <= wvalid_cdc_to; -- end if; -- end process WVLD_CDC_TO; WVLD_CDC_TO2 : process(ip2axi_aclk) begin if(ip2axi_aclk'EVENT and ip2axi_aclk = '1')then if(ip2axi_aresetn = '0')then wvalid_to2 <= '0'; else wvalid_to2 <= wvalid_to; end if; end if; end process WVLD_CDC_TO2; ip_wvalid_re <= wvalid_to and (not wvalid_to2); REG_WADDR_TO_IPCLK : entity lib_cdc_v1_0.cdc_sync generic map ( C_CDC_TYPE => 1, C_RESET_STATE => 0, C_SINGLE_BIT => 0, C_VECTOR_WIDTH => C_S_AXI_LITE_ADDR_WIDTH, C_MTBF_STAGES => 1 ) port map ( prmry_aclk => s_axi_lite_aclk, prmry_resetn => '0', prmry_in => '0', prmry_vect_in => s_axi_lite_awaddr, scndry_aclk => ip2axi_aclk, scndry_resetn => '0', scndry_out => open, scndry_vect_out => awaddr_d1_cdc_tig ); REG_WADDR_TO_IPCLK1 : entity lib_cdc_v1_0.cdc_sync generic map ( C_CDC_TYPE => 1, C_RESET_STATE => 0, C_SINGLE_BIT => 0, C_VECTOR_WIDTH => C_S_AXI_LITE_DATA_WIDTH, C_MTBF_STAGES => 1 ) port map ( prmry_aclk => s_axi_lite_aclk, prmry_resetn => '0', prmry_in => '0', prmry_vect_in => s_axi_lite_wdata, scndry_aclk => ip2axi_aclk, scndry_resetn => '0', scndry_out => open, scndry_vect_out => axi2ip_wrdata_cdc_tig ); -- Double register address in -- REG_WADDR_TO_IPCLK : process(ip2axi_aclk) -- begin -- if(ip2axi_aclk'EVENT and ip2axi_aclk = '1')then -- if(ip2axi_aresetn = '0')then -- awaddr_d1_cdc_tig <= (others => '0'); -- -- axi2ip_wraddr_i <= (others => '0'); -- axi2ip_wrdata_cdc_tig <= (others => '0'); -- else -- awaddr_d1_cdc_tig <= s_axi_lite_awaddr; -- axi2ip_wrdata_cdc_tig <= s_axi_lite_wdata; -- -- axi2ip_wraddr_i <= awaddr_d1_cdc_tig; -- CR605883 -- end if; -- end if; -- end process REG_WADDR_TO_IPCLK; -- Flag that address has been captured REG_IP_ADDR_CAP : process(ip2axi_aclk) begin if(ip2axi_aclk'EVENT and ip2axi_aclk = '1')then if(ip2axi_aresetn = '0' or rdy_shut = '1')then ip_addr_cap <= '0'; elsif(ip_awvalid_re = '1')then ip_addr_cap <= '1'; end if; end if; end process REG_IP_ADDR_CAP; REG_WREADY : process(ip2axi_aclk) begin if(ip2axi_aclk'EVENT and ip2axi_aclk = '1')then if(ip2axi_aresetn = '0' or rdy_shut = '1') then -- or rdy = '1') then rdy <= '0'; elsif (ip_data_cap = '1' and ip_addr_cap = '1') then rdy <= '1'; end if; end if; end process REG_WREADY; REG3_WREADY : entity lib_cdc_v1_0.cdc_sync generic map ( C_CDC_TYPE => 1, C_RESET_STATE => 0, C_SINGLE_BIT => 1, C_VECTOR_WIDTH => 32, C_MTBF_STAGES => MTBF_STAGES ) port map ( prmry_aclk => s_axi_lite_aclk, prmry_resetn => '0', prmry_in => rdy_to2_cdc_from, prmry_vect_in => (others => '0'), scndry_aclk => ip2axi_aclk, scndry_resetn => '0', scndry_out => rdy_back_to, scndry_vect_out => open ); -- REG3_WREADY : process(ip2axi_aclk) -- begin -- if(ip2axi_aclk'EVENT and ip2axi_aclk = '1')then -- rdy_back_cdc_to <= rdy_to2_cdc_from; -- rdy_back_to <= rdy_back_cdc_to; -- end if; -- end process REG3_WREADY; REG3_WREADY2 : process(ip2axi_aclk) begin if(ip2axi_aclk'EVENT and ip2axi_aclk = '1')then if(ip2axi_aresetn = '0') then rdy_back <= '0'; else rdy_back <= rdy_back_to; end if; end if; end process REG3_WREADY2; rdy_shut <= rdy_back_to and (not rdy_back); REG1_WREADY : process(ip2axi_aclk) begin if(ip2axi_aclk'EVENT and ip2axi_aclk = '1')then if(ip2axi_aresetn = '0' or rdy_shut = '1') then rdy_cdc_from <= '0'; elsif (rdy = '1') then rdy_cdc_from <= '1'; end if; end if; end process REG1_WREADY; REG2_WREADY : entity lib_cdc_v1_0.cdc_sync generic map ( C_CDC_TYPE => 1, C_RESET_STATE => 0, C_SINGLE_BIT => 1, C_VECTOR_WIDTH => 32, C_MTBF_STAGES => MTBF_STAGES ) port map ( prmry_aclk => ip2axi_aclk, prmry_resetn => '0', prmry_in => rdy_cdc_from, prmry_vect_in => (others => '0'), scndry_aclk => s_axi_lite_aclk, scndry_resetn => '0', scndry_out => rdy_to, scndry_vect_out => open ); -- REG2_WREADY : process(s_axi_lite_aclk) -- begin -- if(s_axi_lite_aclk'EVENT and s_axi_lite_aclk = '1')then -- rdy_cdc_to <= rdy_cdc_from; -- rdy_to <= rdy_cdc_to; -- end if; -- end process REG2_WREADY; REG2_WREADY2 : process(s_axi_lite_aclk) begin if(s_axi_lite_aclk'EVENT and s_axi_lite_aclk = '1')then if(s_axi_lite_aresetn = '0') then rdy_to2 <= '0'; rdy_to2_cdc_from <= '0'; else rdy_to2 <= rdy_to; rdy_to2_cdc_from <= rdy_to; end if; end if; end process REG2_WREADY2; rdy_out <= not (rdy_to) and rdy_to2; wready_i <= rdy_out; awready_i <= rdy_out; --************************************************************************* --** Write Data Support --************************************************************************* ------------------------------------------------------------------------------- -- Capture write data ------------------------------------------------------------------------------- -- WRDATA_S_H : process(s_axi_lite_aclk) -- begin -- if(s_axi_lite_aclk'EVENT and s_axi_lite_aclk = '1')then -- if(s_axi_lite_aresetn = '0')then -- wr_data_cdc_from <= (others => '0'); -- elsif(wvalid_re = '1')then -- wr_data_cdc_from <= wdata; -- end if; -- end if; -- end process WRDATA_S_H; -- Flag that data has been captured REG_IP_DATA_CAP : process(ip2axi_aclk) begin if(ip2axi_aclk'EVENT and ip2axi_aclk = '1')then if(ip2axi_aresetn = '0' or rdy_shut = '1')then ip_data_cap <= '0'; elsif(ip_wvalid_re = '1')then ip_data_cap <= '1'; end if; end if; end process REG_IP_DATA_CAP; -- Must have both a valid address and valid data before updating -- a register. Note in AXI write address can come before or -- after AXI write data. axi2ip_wren <= rdy; -- axi2ip_wren <= '1' when ip_data_cap = '1' and ip_addr_cap = '1' -- else '0'; ------------------------------------------------------------------------------- -- Decode and assert proper chip enable per captured axi lite write address ------------------------------------------------------------------------------- WRCE_GEN: for j in 0 to C_NUM_CE - 1 generate constant BAR : std_logic_vector(CE_ADDR_SIZE-1 downto 0) := std_logic_vector(to_unsigned(j,CE_ADDR_SIZE)); begin wrce(j) <= axi2ip_wren when awaddr_d1_cdc_tig ((CE_ADDR_SIZE + ADDR_OFFSET) - 1 downto ADDR_OFFSET) = BAR(CE_ADDR_SIZE-1 downto 0) else '0'; end generate WRCE_GEN; ------------------------------------------------------------------------------- -- register write ce's and data out to axi dma register module ------------------------------------------------------------------------------- REG_WR_OUT : process(ip2axi_aclk) begin if(ip2axi_aclk'EVENT and ip2axi_aclk = '1')then if(ip2axi_aresetn = '0')then axi2ip_wrce <= (others => '0'); else axi2ip_wrce <= wrce; end if; end if; end process REG_WR_OUT; axi2ip_wrdata <= axi2ip_wrdata_cdc_tig; --s_axi_lite_wdata; --************************************************************************* --** Write Response Support --************************************************************************* -- Minimum of 2 IP clocks for addr and data capture, therefore delaying -- Lite clock addr and data capture by 2 Lite clocks will guarenttee bvalid -- responce occurs after write data acutally written. -- REG_ALIGN_CAP : process(s_axi_lite_aclk) -- begin -- if(s_axi_lite_aclk'EVENT and s_axi_lite_aclk = '1')then -- if(s_axi_lite_aresetn = '0')then -- lite_data_cap_d1 <= '0'; -- lite_data_cap_d2 <= '0'; -- lite_addr_cap_d1 <= '0'; -- lite_addr_cap_d2 <= '0'; -- else -- lite_data_cap_d1 <= rdy; --wr_data_cap; -- lite_data_cap_d2 <= lite_data_cap_d1; -- lite_addr_cap_d1 <= rdy; --wr_addr_cap; -- lite_addr_cap_d2 <= lite_addr_cap_d1; -- end if; -- end if; -- end process REG_ALIGN_CAP; -- Pseudo write enable used simply to assert bvalid -- lite_axi2ip_wren <= rdy; --'1' when wr_data_cap = '1' and wr_addr_cap = '1' -- else '0'; WRESP_PROCESS : process(s_axi_lite_aclk) begin if(s_axi_lite_aclk'EVENT and s_axi_lite_aclk = '1')then if(s_axi_lite_aresetn = '0')then bvalid_i <= '0'; rst_wvalid_re <= '0'; -- CR576999 -- If response issued and target indicates ready then -- clear response elsif(bvalid_i = '1' and s_axi_lite_bready = '1')then bvalid_i <= '0'; rst_wvalid_re <= '0'; -- CR576999 -- Issue a resonse on write elsif(rdy_out = '1')then -- elsif(lite_axi2ip_wren = '1')then bvalid_i <= '1'; rst_wvalid_re <= '1'; -- CR576999 end if; end if; end process WRESP_PROCESS; s_axi_lite_bresp <= OKAY_RESP; end generate GEN_ASYNC_WRITE; --***************************************************************************** --** AXI LITE READ --***************************************************************************** ------------------------------------------------------------------------------- -- Assert Read Adddress Ready Handshake -- Capture rising edge of valid and register out as ready. This creates -- a 3 clock cycle address phase but also registers all inputs and outputs. -- Note : Single clock cycle address phase can be accomplished using -- combinatorial logic. ------------------------------------------------------------------------------- REG_ARVALID : process(s_axi_lite_aclk) begin if(s_axi_lite_aclk'EVENT and s_axi_lite_aclk = '1')then if(s_axi_lite_aresetn = '0' or rst_rvalid_re = '1')then arvalid_d1 <= '0'; else arvalid_d1 <= arvalid; end if; end if; end process REG_ARVALID; arvalid_re <= arvalid and not arvalid_d1 and not rst_rvalid_re and not read_in_progress; -- CR607165 -- register for proper alignment REG_ARREADY : process(s_axi_lite_aclk) begin if(s_axi_lite_aclk'EVENT and s_axi_lite_aclk = '1')then if(s_axi_lite_aresetn = '0')then arready_i <= '0'; else arready_i <= arvalid_re; end if; end if; end process REG_ARREADY; -- Always respond 'okay' axi lite read s_axi_lite_rresp <= OKAY_RESP; s_axi_lite_rvalid <= s_axi_lite_rvalid_i; -- s_axi_lite_aclk is synchronous to ip clock GEN_SYNC_READ : if C_AXI_LITE_IS_ASYNC = 0 generate begin read_in_progress <= '0'; --Not used for sync mode (CR607165) ------------------------------------------------------------------------------- -- Capture Read Address ------------------------------------------------------------------------------- REG_READ_ADDRESS : process(s_axi_lite_aclk) begin if(s_axi_lite_aclk'EVENT and s_axi_lite_aclk = '1')then if(s_axi_lite_aresetn = '0')then axi2ip_rdaddr_i <= (others => '0'); -- Register address on valid elsif(arvalid_re = '1')then axi2ip_rdaddr_i <= araddr; end if; end if; end process REG_READ_ADDRESS; ------------------------------------------------------------------------------- -- Generate RdCE based on address match to address bar ------------------------------------------------------------------------------- RDCE_GEN: for j in 0 to C_NUM_CE - 1 generate constant BAR : std_logic_vector(CE_ADDR_SIZE-1 downto 0) := std_logic_vector(to_unsigned(j,CE_ADDR_SIZE)); begin rdce(j) <= arvalid_re_d1 when axi2ip_rdaddr_i((CE_ADDR_SIZE + ADDR_OFFSET) - 1 downto ADDR_OFFSET) = BAR(CE_ADDR_SIZE-1 downto 0) else '0'; end generate RDCE_GEN; ------------------------------------------------------------------------------- -- Register out to IP ------------------------------------------------------------------------------- REG_RDCNTRL_OUT : process(s_axi_lite_aclk) begin if(s_axi_lite_aclk'EVENT and s_axi_lite_aclk = '1')then if(s_axi_lite_aresetn = '0')then --axi2ip_rdce <= (others => '0'); axi2ip_rdaddr <= (others => '0'); else --axi2ip_rdce <= rdce; axi2ip_rdaddr <= axi2ip_rdaddr_i; end if; end if; end process REG_RDCNTRL_OUT; -- Sample and hold rdce value until rvalid assertion REG_RDCE_OUT : process(s_axi_lite_aclk) begin if(s_axi_lite_aclk'EVENT and s_axi_lite_aclk = '1')then if(s_axi_lite_aresetn = '0' or rst_rvalid_re = '1')then axi2ip_rdce <= (others => '0'); elsif(arvalid_re_d1 = '1')then axi2ip_rdce <= rdce; end if; end if; end process REG_RDCE_OUT; -- Register for proper alignment REG_RVALID : process(s_axi_lite_aclk) begin if(s_axi_lite_aclk'EVENT and s_axi_lite_aclk = '1')then if(s_axi_lite_aresetn = '0')then arvalid_re_d1 <= '0'; rvalid <= '0'; else arvalid_re_d1 <= arvalid_re; rvalid <= arvalid_re_d1; end if; end if; end process REG_RVALID; ------------------------------------------------------------------------------- -- Drive read data and read data valid out on capture of valid address. ------------------------------------------------------------------------------- REG_RD_OUT : process(s_axi_lite_aclk) begin if(s_axi_lite_aclk'EVENT and s_axi_lite_aclk = '1')then if(s_axi_lite_aresetn = '0')then s_axi_lite_rdata <= (others => '0'); s_axi_lite_rvalid_i <= '0'; rst_rvalid_re <= '0'; -- CR576999 -- If rvalid driving out to target and target indicates ready -- then de-assert rvalid. (structure guarentees min 1 clock of rvalid) elsif(s_axi_lite_rvalid_i = '1' and s_axi_lite_rready = '1')then s_axi_lite_rdata <= (others => '0'); s_axi_lite_rvalid_i <= '0'; rst_rvalid_re <= '0'; -- CR576999 -- If read cycle then assert rvalid and rdata out to target elsif(rvalid = '1')then s_axi_lite_rdata <= ip2axi_rddata; s_axi_lite_rvalid_i <= '1'; rst_rvalid_re <= '1'; -- CR576999 end if; end if; end process REG_RD_OUT; end generate GEN_SYNC_READ; -- s_axi_lite_aclk is asynchronous to ip clock GEN_ASYNC_READ : if C_AXI_LITE_IS_ASYNC = 1 generate ATTRIBUTE async_reg : STRING; signal ip_arvalid_d1_cdc_tig : std_logic := '0'; signal ip_arvalid_d2 : std_logic := '0'; signal ip_arvalid_d3 : std_logic := '0'; signal ip_arvalid_re : std_logic := '0'; signal araddr_d1_cdc_tig : std_logic_vector(C_S_AXI_LITE_ADDR_WIDTH-1 downto 0) :=(others => '0'); signal araddr_d2 : std_logic_vector(C_S_AXI_LITE_ADDR_WIDTH-1 downto 0) :=(others => '0'); signal araddr_d3 : std_logic_vector(C_S_AXI_LITE_ADDR_WIDTH-1 downto 0) :=(others => '0'); signal lite_rdata_cdc_from : std_logic_vector(C_S_AXI_LITE_DATA_WIDTH-1 downto 0) :=(others => '0'); signal lite_rdata_d1_cdc_to : std_logic_vector(C_S_AXI_LITE_DATA_WIDTH-1 downto 0) :=(others => '0'); signal lite_rdata_d2 : std_logic_vector(C_S_AXI_LITE_DATA_WIDTH-1 downto 0) :=(others => '0'); -- ATTRIBUTE async_reg OF ip_arvalid_d1_cdc_tig : SIGNAL IS "true"; -- ATTRIBUTE async_reg OF ip_arvalid_d2 : SIGNAL IS "true"; -- ATTRIBUTE async_reg OF araddr_d1_cdc_tig : SIGNAL IS "true"; -- ATTRIBUTE async_reg OF araddr_d2 : SIGNAL IS "true"; -- ATTRIBUTE async_reg OF lite_rdata_d1_cdc_to : SIGNAL IS "true"; -- ATTRIBUTE async_reg OF lite_rdata_d2 : SIGNAL IS "true"; signal p_pulse_s_h : std_logic := '0'; signal p_pulse_s_h_clr : std_logic := '0'; signal s_pulse_d1 : std_logic := '0'; signal s_pulse_d2 : std_logic := '0'; signal s_pulse_d3 : std_logic := '0'; signal s_pulse_re : std_logic := '0'; signal p_pulse_re_d1 : std_logic := '0'; signal p_pulse_re_d2 : std_logic := '0'; signal p_pulse_re_d3 : std_logic := '0'; signal arready_d1 : std_logic := '0'; -- CR605883 signal arready_d2 : std_logic := '0'; -- CR605883 signal arready_d3 : std_logic := '0'; -- CR605883 signal arready_d4 : std_logic := '0'; -- CR605883 signal arready_d5 : std_logic := '0'; -- CR605883 signal arready_d6 : std_logic := '0'; -- CR605883 signal arready_d7 : std_logic := '0'; -- CR605883 signal arready_d8 : std_logic := '0'; -- CR605883 signal arready_d9 : std_logic := '0'; -- CR605883 signal arready_d10 : std_logic := '0'; -- CR605883 signal arready_d11 : std_logic := '0'; -- CR605883 signal arready_d12 : std_logic := '0'; -- CR605883 begin -- CR607165 -- Flag to prevent overlapping reads RD_PROGRESS : process(s_axi_lite_aclk) begin if(s_axi_lite_aclk'EVENT and s_axi_lite_aclk = '1')then if(s_axi_lite_aresetn = '0' or rst_rvalid_re = '1')then read_in_progress <= '0'; elsif(arvalid_re = '1')then read_in_progress <= '1'; end if; end if; end process RD_PROGRESS; -- Double register address in REG_RADDR_TO_IPCLK : entity lib_cdc_v1_0.cdc_sync generic map ( C_CDC_TYPE => 1, C_RESET_STATE => 0, C_SINGLE_BIT => 0, C_VECTOR_WIDTH => C_S_AXI_LITE_ADDR_WIDTH, C_MTBF_STAGES => MTBF_STAGES ) port map ( prmry_aclk => s_axi_lite_aclk, prmry_resetn => '0', prmry_in => '0', prmry_vect_in => s_axi_lite_araddr, scndry_aclk => ip2axi_aclk, scndry_resetn => '0', scndry_out => open, scndry_vect_out => araddr_d3 ); -- REG_RADDR_TO_IPCLK : process(ip2axi_aclk) -- begin -- if(ip2axi_aclk'EVENT and ip2axi_aclk = '1')then -- if(ip2axi_aresetn = '0')then -- araddr_d1_cdc_tig <= (others => '0'); -- araddr_d2 <= (others => '0'); -- araddr_d3 <= (others => '0'); -- else -- araddr_d1_cdc_tig <= s_axi_lite_araddr; -- araddr_d2 <= araddr_d1_cdc_tig; -- araddr_d3 <= araddr_d2; -- end if; -- end if; -- end process REG_RADDR_TO_IPCLK; -- Latch and hold read address REG_ARADDR_PROCESS : process(ip2axi_aclk) begin if(ip2axi_aclk'EVENT and ip2axi_aclk = '1')then if(ip2axi_aresetn = '0')then axi2ip_rdaddr_i <= (others => '0'); elsif(ip_arvalid_re = '1')then axi2ip_rdaddr_i <= araddr_d3; end if; end if; end process REG_ARADDR_PROCESS; axi2ip_rdaddr <= axi2ip_rdaddr_i; -- Register awready into IP clock domain. awready -- is a 1 axi_lite clock delay of the rising edge of -- arvalid. This provides a signal that asserts when -- araddr is known to be stable. REG_ARVALID_TO_IPCLK : entity lib_cdc_v1_0.cdc_sync generic map ( C_CDC_TYPE => 1, C_RESET_STATE => 0, C_SINGLE_BIT => 1, C_VECTOR_WIDTH => C_S_AXI_LITE_ADDR_WIDTH, C_MTBF_STAGES => MTBF_STAGES ) port map ( prmry_aclk => s_axi_lite_aclk, prmry_resetn => '0', prmry_in => arready_i, prmry_vect_in => (others => '0'), scndry_aclk => ip2axi_aclk, scndry_resetn => '0', scndry_out => ip_arvalid_d2, scndry_vect_out => open ); REG_ARVALID_TO_IPCLK1 : process(ip2axi_aclk) begin if(ip2axi_aclk'EVENT and ip2axi_aclk = '1')then if(ip2axi_aresetn = '0')then -- ip_arvalid_d1_cdc_tig <= '0'; -- ip_arvalid_d2 <= '0'; ip_arvalid_d3 <= '0'; else -- ip_arvalid_d1_cdc_tig <= arready_i; -- ip_arvalid_d2 <= ip_arvalid_d1_cdc_tig; ip_arvalid_d3 <= ip_arvalid_d2; end if; end if; end process REG_ARVALID_TO_IPCLK1; ip_arvalid_re <= ip_arvalid_d2 and not ip_arvalid_d3; ------------------------------------------------------------------------------- -- Generate Read CE's ------------------------------------------------------------------------------- RDCE_GEN: for j in 0 to C_NUM_CE - 1 generate constant BAR : std_logic_vector(CE_ADDR_SIZE-1 downto 0) := std_logic_vector(to_unsigned(j,CE_ADDR_SIZE)); begin rdce(j) <= ip_arvalid_re when araddr_d3((CE_ADDR_SIZE + ADDR_OFFSET) - 1 downto ADDR_OFFSET) = BAR(CE_ADDR_SIZE-1 downto 0) else '0'; end generate RDCE_GEN; ------------------------------------------------------------------------------- -- Register RDCE and RD Data out to IP ------------------------------------------------------------------------------- REG_RDCNTRL_OUT : process(ip2axi_aclk) begin if(ip2axi_aclk'EVENT and ip2axi_aclk = '1')then if(ip2axi_aresetn = '0')then axi2ip_rdce <= (others => '0'); elsif(ip_arvalid_re = '1')then axi2ip_rdce <= rdce; else axi2ip_rdce <= (others => '0'); end if; end if; end process REG_RDCNTRL_OUT; -- Generate sample and hold pulse to capture read data from IP REG_RVALID : process(ip2axi_aclk) begin if(ip2axi_aclk'EVENT and ip2axi_aclk = '1')then if(ip2axi_aresetn = '0')then rvalid <= '0'; else rvalid <= ip_arvalid_re; end if; end if; end process REG_RVALID; ------------------------------------------------------------------------------- -- Sample and hold read data from IP ------------------------------------------------------------------------------- S_H_READ_DATA : process(ip2axi_aclk) begin if(ip2axi_aclk'EVENT and ip2axi_aclk = '1')then if(ip2axi_aresetn = '0')then lite_rdata_cdc_from <= (others => '0'); -- If read cycle then assert rvalid and rdata out to target elsif(rvalid = '1')then lite_rdata_cdc_from <= ip2axi_rddata; end if; end if; end process S_H_READ_DATA; -- Cross read data to axi_lite clock domain REG_DATA2LITE_CLOCK : entity lib_cdc_v1_0.cdc_sync generic map ( C_CDC_TYPE => 1, C_RESET_STATE => 0, C_SINGLE_BIT => 0, C_VECTOR_WIDTH => 32, C_MTBF_STAGES => MTBF_STAGES ) port map ( prmry_aclk => ip2axi_aclk, prmry_resetn => '0', prmry_in => '0', --lite_rdata_cdc_from, prmry_vect_in => lite_rdata_cdc_from, scndry_aclk => s_axi_lite_aclk, scndry_resetn => '0', scndry_out => open, --lite_rdata_d2, scndry_vect_out => lite_rdata_d2 ); -- REG_DATA2LITE_CLOCK : process(s_axi_lite_aclk) -- begin -- if(s_axi_lite_aclk'EVENT and s_axi_lite_aclk = '1')then -- if(s_axi_lite_aresetn = '0')then -- lite_rdata_d1_cdc_to <= (others => '0'); -- lite_rdata_d2 <= (others => '0'); -- else -- lite_rdata_d1_cdc_to <= lite_rdata_cdc_from; -- lite_rdata_d2 <= lite_rdata_d1_cdc_to; -- end if; -- end if; -- end process REG_DATA2LITE_CLOCK; -- CR605883 (CDC) modified to remove -- Because axi_lite_aclk must be less than or equal to ip2axi_aclk -- then read data will appear a maximum 6 clocks from assertion -- of arready. REG_ALIGN_RDATA_LATCH : process(s_axi_lite_aclk) begin if(s_axi_lite_aclk'EVENT and s_axi_lite_aclk = '1')then if(s_axi_lite_aresetn = '0')then arready_d1 <= '0'; arready_d2 <= '0'; arready_d3 <= '0'; arready_d4 <= '0'; arready_d5 <= '0'; arready_d6 <= '0'; arready_d7 <= '0'; arready_d8 <= '0'; arready_d9 <= '0'; arready_d10 <= '0'; arready_d11 <= '0'; arready_d12 <= '0'; else arready_d1 <= arready_i; arready_d2 <= arready_d1; arready_d3 <= arready_d2; arready_d4 <= arready_d3; arready_d5 <= arready_d4; arready_d6 <= arready_d5; arready_d7 <= arready_d6; arready_d8 <= arready_d7; arready_d9 <= arready_d8; arready_d10 <= arready_d9; arready_d11 <= arready_d10; arready_d12 <= arready_d11; end if; end if; end process REG_ALIGN_RDATA_LATCH; ------------------------------------------------------------------------------- -- Drive read data and read data valid out on capture of valid address. ------------------------------------------------------------------------------- REG_RD_OUT : process(s_axi_lite_aclk) begin if(s_axi_lite_aclk'EVENT and s_axi_lite_aclk = '1')then if(s_axi_lite_aresetn = '0')then s_axi_lite_rdata <= (others => '0'); s_axi_lite_rvalid_i <= '0'; rst_rvalid_re <= '0'; -- CR576999 -- If rvalid driving out to target and target indicates ready -- then de-assert rvalid. (structure guarentees min 1 clock of rvalid) elsif(s_axi_lite_rvalid_i = '1' and s_axi_lite_rready = '1')then s_axi_lite_rdata <= (others => '0'); s_axi_lite_rvalid_i <= '0'; rst_rvalid_re <= '0'; -- CR576999 -- If read cycle then assert rvalid and rdata out to target -- CR605883 --elsif(s_pulse_re = '1')then elsif(arready_d12 = '1')then s_axi_lite_rdata <= lite_rdata_d2; s_axi_lite_rvalid_i <= '1'; rst_rvalid_re <= '1'; -- CR576999 end if; end if; end process REG_RD_OUT; end generate GEN_ASYNC_READ; end implementation;

gpl-3.0

95b0bfed1971dc1bff3addd4772f3fdd

0.426374

4.122204

false

mistryalok/Zedboard

learning/training/MSD/s09/axi_dma_sg/vivado/project_1/project_1.srcs/sources_1/ipshared/xilinx.com/axi_sg_v4_1/0535f152/hdl/src/vhdl/axi_sg_updt_queue.vhd

3

53,827

-- ************************************************************************* -- -- (c) Copyright 2010-2011 Xilinx, Inc. All rights reserved. -- -- This file contains confidential and proprietary information -- of Xilinx, Inc. and is protected under U.S. and -- international copyright and other intellectual property -- laws. -- -- DISCLAIMER -- This disclaimer is not a license and does not grant any -- rights to the materials distributed herewith. Except as -- otherwise provided in a valid license issued to you by -- Xilinx, and to the maximum extent permitted by applicable -- law: (1) THESE MATERIALS ARE MADE AVAILABLE "AS IS" AND -- WITH ALL FAULTS, AND XILINX HEREBY DISCLAIMS ALL WARRANTIES -- AND CONDITIONS, EXPRESS, IMPLIED, OR STATUTORY, INCLUDING -- BUT NOT LIMITED TO WARRANTIES OF MERCHANTABILITY, NON- -- INFRINGEMENT, OR FITNESS FOR ANY PARTICULAR PURPOSE; and -- (2) Xilinx shall not be liable (whether in contract or tort, -- including negligence, or under any other theory of -- liability) for any loss or damage of any kind or nature -- related to, arising under or in connection with these -- materials, including for any direct, or any indirect, -- special, incidental, or consequential loss or damage -- (including loss of data, profits, goodwill, or any type of -- loss or damage suffered as a result of any action brought -- by a third party) even if such damage or loss was -- reasonably foreseeable or Xilinx had been advised of the -- possibility of the same. -- -- CRITICAL APPLICATIONS -- Xilinx products are not designed or intended to be fail- -- safe, or for use in any application requiring fail-safe -- performance, such as life-support or safety devices or -- systems, Class III medical devices, nuclear facilities, -- applications related to the deployment of airbags, or any -- other applications that could lead to death, personal -- injury, or severe property or environmental damage -- (individually and collectively, "Critical -- Applications"). Customer assumes the sole risk and -- liability of any use of Xilinx products in Critical -- Applications, subject only to applicable laws and -- regulations governing limitations on product liability. -- -- THIS COPYRIGHT NOTICE AND DISCLAIMER MUST BE RETAINED AS -- PART OF THIS FILE AT ALL TIMES. -- -- ************************************************************************* -- ------------------------------------------------------------------------------- -- Filename: axi_sg_updt_queue.vhd -- Description: This entity is the descriptor fetch queue interface -- -- VHDL-Standard: VHDL'93 ------------------------------------------------------------------------------- library ieee; use ieee.std_logic_1164.all; use ieee.numeric_std.all; use ieee.std_logic_misc.all; library axi_sg_v4_1; use axi_sg_v4_1.axi_sg_pkg.all; library lib_srl_fifo_v1_0; use lib_srl_fifo_v1_0.srl_fifo_f; library lib_pkg_v1_0; use lib_pkg_v1_0.lib_pkg.all; ------------------------------------------------------------------------------- entity axi_sg_updt_queue is generic ( C_M_AXI_SG_ADDR_WIDTH : integer range 32 to 64 := 32; -- Master AXI Memory Map Address Width for Scatter Gather R/W Port C_M_AXIS_UPDT_DATA_WIDTH : integer range 32 to 32 := 32; -- Master AXI Memory Map Data Width for Scatter Gather R/W Port C_S_AXIS_UPDPTR_TDATA_WIDTH : integer range 32 to 32 := 32; -- 32 Update Status Bits C_S_AXIS_UPDSTS_TDATA_WIDTH : integer range 33 to 33 := 33; -- 1 IOC bit + 32 Update Status Bits C_SG_UPDT_DESC2QUEUE : integer range 0 to 8 := 0; -- Number of descriptors to fetch and queue for each channel. -- A value of zero excludes the fetch queues. C_SG_WORDS_TO_UPDATE : integer range 1 to 16 := 8; -- Number of words to update C_SG2_WORDS_TO_UPDATE : integer range 1 to 16 := 8; -- Number of words to update C_AXIS_IS_ASYNC : integer range 0 to 1 := 0; -- Channel 1 is async to sg_aclk -- 0 = Synchronous to SG ACLK -- 1 = Asynchronous to SG ACLK C_INCLUDE_MM2S : integer range 0 to 1 := 0; C_INCLUDE_S2MM : integer range 0 to 1 := 0; C_FAMILY : string := "virtex7" -- Device family used for proper BRAM selection ); port ( ----------------------------------------------------------------------- -- AXI Scatter Gather Interface ----------------------------------------------------------------------- m_axi_sg_aclk : in std_logic ; -- m_axi_sg_aresetn : in std_logic ; -- s_axis_updt_aclk : in std_logic ; -- -- --********************************-- -- --** Control and Status **-- -- --********************************-- -- updt_curdesc_wren : out std_logic ; -- updt_curdesc : out std_logic_vector -- (C_M_AXI_SG_ADDR_WIDTH-1 downto 0) ; -- updt_active : in std_logic ; -- updt_queue_empty : out std_logic ; -- updt_ioc : out std_logic ; -- updt_ioc_irq_set : in std_logic ; -- -- dma_interr : out std_logic ; -- dma_slverr : out std_logic ; -- dma_decerr : out std_logic ; -- dma_interr_set : in std_logic ; -- dma_slverr_set : in std_logic ; -- dma_decerr_set : in std_logic ; -- updt2_active : in std_logic ; -- updt2_queue_empty : out std_logic ; -- updt2_ioc : out std_logic ; -- updt2_ioc_irq_set : in std_logic ; -- -- dma2_interr : out std_logic ; -- dma2_slverr : out std_logic ; -- dma2_decerr : out std_logic ; -- dma2_interr_set : in std_logic ; -- dma2_slverr_set : in std_logic ; -- dma2_decerr_set : in std_logic ; -- -- --********************************-- -- --** Update Interfaces In **-- -- --********************************-- -- -- Update Pointer Stream -- s_axis_updtptr_tdata : in std_logic_vector -- (C_S_AXIS_UPDPTR_TDATA_WIDTH-1 downto 0); -- s_axis_updtptr_tvalid : in std_logic ; -- s_axis_updtptr_tready : out std_logic ; -- s_axis_updtptr_tlast : in std_logic ; -- -- -- Update Status Stream -- s_axis_updtsts_tdata : in std_logic_vector -- (C_S_AXIS_UPDSTS_TDATA_WIDTH-1 downto 0); -- s_axis_updtsts_tvalid : in std_logic ; -- s_axis_updtsts_tready : out std_logic ; -- s_axis_updtsts_tlast : in std_logic ; -- s_axis2_updtptr_tdata : in std_logic_vector -- (C_S_AXIS_UPDPTR_TDATA_WIDTH-1 downto 0); -- s_axis2_updtptr_tvalid : in std_logic ; -- s_axis2_updtptr_tready : out std_logic ; -- s_axis2_updtptr_tlast : in std_logic ; -- -- -- Update Status Stream -- s_axis2_updtsts_tdata : in std_logic_vector -- (C_S_AXIS_UPDSTS_TDATA_WIDTH-1 downto 0); -- s_axis2_updtsts_tvalid : in std_logic ; -- s_axis2_updtsts_tready : out std_logic ; -- s_axis2_updtsts_tlast : in std_logic ; -- -- --********************************-- -- --** Update Interfaces Out **-- -- --********************************-- -- -- S2MM Stream Out To DataMover -- m_axis_updt_tdata : out std_logic_vector -- (C_M_AXIS_UPDT_DATA_WIDTH-1 downto 0); -- m_axis_updt_tlast : out std_logic ; -- m_axis_updt_tvalid : out std_logic ; -- m_axis_updt_tready : in std_logic -- ); end axi_sg_updt_queue; ------------------------------------------------------------------------------- -- Architecture ------------------------------------------------------------------------------- architecture implementation of axi_sg_updt_queue is attribute DowngradeIPIdentifiedWarnings: string; attribute DowngradeIPIdentifiedWarnings of implementation : architecture is "yes"; attribute mark_debug : string; ------------------------------------------------------------------------------- -- Functions ------------------------------------------------------------------------------- -- No Functions Declared ------------------------------------------------------------------------------- -- Constants Declarations ------------------------------------------------------------------------------- constant USE_LOGIC_FIFOS : integer := 0; -- Use Logic FIFOs constant USE_BRAM_FIFOS : integer := 1; -- Use BRAM FIFOs -- Number of words deep fifo needs to be. Depth required to store 2 word -- porters for each descriptor is C_SG_UPDT_DESC2QUEUE x 2 --constant UPDATE_QUEUE_DEPTH : integer := max2(16,C_SG_UPDT_DESC2QUEUE * 2); constant UPDATE_QUEUE_DEPTH : integer := max2(16,pad_power2(C_SG_UPDT_DESC2QUEUE * 2)); -- Width of fifo rd and wr counts - only used for proper fifo operation constant UPDATE_QUEUE_CNT_WIDTH : integer := clog2(UPDATE_QUEUE_DEPTH+1); -- Select between BRAM or LOGIC memory type constant UPD_Q_MEMORY_TYPE : integer := bo2int(UPDATE_QUEUE_DEPTH > 16); -- Number of words deep fifo needs to be. Depth required to store all update -- words is C_SG_UPDT_DESC2QUEUE x C_SG_WORDS_TO_UPDATE constant UPDATE_STS_QUEUE_DEPTH : integer := max2(16,pad_power2(C_SG_UPDT_DESC2QUEUE * C_SG_WORDS_TO_UPDATE)); constant UPDATE_STS2_QUEUE_DEPTH : integer := max2(16,pad_power2(C_SG_UPDT_DESC2QUEUE * C_SG2_WORDS_TO_UPDATE)); -- Select between BRAM or LOGIC memory type constant STS_Q_MEMORY_TYPE : integer := bo2int(UPDATE_STS_QUEUE_DEPTH > 16); -- Select between BRAM or LOGIC memory type constant STS2_Q_MEMORY_TYPE : integer := bo2int(UPDATE_STS2_QUEUE_DEPTH > 16); -- Width of fifo rd and wr counts - only used for proper fifo operation constant UPDATE_STS_QUEUE_CNT_WIDTH : integer := clog2(C_SG_UPDT_DESC2QUEUE+1); ------------------------------------------------------------------------------- -- Signal / Type Declarations ------------------------------------------------------------------------------- -- Channel signals signal write_curdesc_lsb : std_logic := '0'; signal write_curdesc_lsb_sm : std_logic := '0'; signal write_curdesc_msb : std_logic := '0'; signal write_curdesc_lsb1 : std_logic := '0'; signal write_curdesc_msb1 : std_logic := '0'; signal rden_del : std_logic := '0'; signal updt_active_d1 : std_logic := '0'; signal updt_active_d2 : std_logic := '0'; signal updt_active_re1 : std_logic := '0'; signal updt_active_re2 : std_logic := '0'; signal updt_active_re : std_logic := '0'; type PNTR_STATE_TYPE is (IDLE, READ_CURDESC_LSB, READ_CURDESC_MSB, WRITE_STATUS ); signal pntr_cs : PNTR_STATE_TYPE; signal pntr_ns : PNTR_STATE_TYPE; -- State Machine Signal signal writing_status : std_logic := '0'; signal dataq_rden : std_logic := '0'; signal stsq_rden : std_logic := '0'; -- Pointer Queue FIFO Signals signal ptr_queue_rden : std_logic := '0'; signal ptr_queue_wren : std_logic := '0'; signal ptr_queue_empty : std_logic := '0'; signal ptr_queue_full : std_logic := '0'; signal ptr_queue_din : std_logic_vector (C_S_AXIS_UPDPTR_TDATA_WIDTH-1 downto 0) := (others => '0'); signal ptr_queue_dout : std_logic_vector (C_S_AXIS_UPDPTR_TDATA_WIDTH-1 downto 0) := (others => '0'); signal ptr_queue_dout_int : std_logic_vector (C_S_AXIS_UPDPTR_TDATA_WIDTH-1 downto 0) := (others => '0'); -- Status Queue FIFO Signals signal sts_queue_wren : std_logic := '0'; signal sts_queue_rden : std_logic := '0'; signal sts_queue_din : std_logic_vector (C_S_AXIS_UPDSTS_TDATA_WIDTH downto 0) := (others => '0'); signal sts_queue_dout : std_logic_vector (C_S_AXIS_UPDSTS_TDATA_WIDTH downto 0) := (others => '0'); signal sts_queue_dout_int : std_logic_vector (3 downto 0) := (others => '0'); signal sts_queue_full : std_logic := '0'; signal sts_queue_empty : std_logic := '0'; signal ptr2_queue_rden : std_logic := '0'; signal ptr2_queue_wren : std_logic := '0'; signal ptr2_queue_empty : std_logic := '0'; signal ptr2_queue_full : std_logic := '0'; signal ptr2_queue_din : std_logic_vector (C_S_AXIS_UPDPTR_TDATA_WIDTH-1 downto 0) := (others => '0'); signal ptr2_queue_dout : std_logic_vector (C_S_AXIS_UPDPTR_TDATA_WIDTH-1 downto 0) := (others => '0'); -- Status Queue FIFO Signals signal sts2_queue_wren : std_logic := '0'; signal sts2_queue_rden : std_logic := '0'; signal sts2_queue_din : std_logic_vector (C_S_AXIS_UPDSTS_TDATA_WIDTH downto 0) := (others => '0'); signal sts2_queue_dout : std_logic_vector (C_S_AXIS_UPDSTS_TDATA_WIDTH downto 0) := (others => '0'); signal sts2_queue_full : std_logic := '0'; signal sts2_queue_empty : std_logic := '0'; signal sts2_queue_empty_del : std_logic := '0'; signal sts2_dout_valid : std_logic := '0'; signal sts_dout_valid : std_logic := '0'; signal sts2_dout_valid_del : std_logic := '0'; signal valid_new : std_logic := '0'; signal valid_latch : std_logic := '0'; signal valid1_new : std_logic := '0'; signal valid1_latch : std_logic := '0'; signal empty_low : std_logic := '0'; -- Misc Support Signals signal writing_status_d1 : std_logic := '0'; signal writing_status_re : std_logic := '0'; signal writing_status_re_ch1 : std_logic := '0'; signal writing_status_re_ch2 : std_logic := '0'; signal sinit : std_logic := '0'; signal updt_tvalid : std_logic := '0'; signal updt_tlast : std_logic := '0'; signal updt2_tvalid : std_logic := '0'; signal updt2_tlast : std_logic := '0'; attribute mark_debug of updt_tvalid : signal is "true"; attribute mark_debug of updt2_tvalid : signal is "true"; attribute mark_debug of updt_tlast : signal is "true"; attribute mark_debug of updt2_tlast : signal is "true"; signal status_d1, status_d2 : std_logic := '0'; signal updt_tvalid_int : std_logic := '0'; signal updt_tlast_int : std_logic := '0'; signal ptr_queue_empty_int : std_logic := '0'; signal updt_active_int : std_logic := '0'; signal follower_reg_mm2s : std_logic_vector (33 downto 0) := (others => '0'); attribute mark_debug of follower_reg_mm2s : signal is "true"; signal follower_full_mm2s :std_logic := '0'; signal follower_empty_mm2s : std_logic := '0'; signal follower_reg_s2mm : std_logic_vector (33 downto 0) := (others => '0'); attribute mark_debug of follower_reg_s2mm : signal is "true"; signal follower_full_s2mm :std_logic := '0'; signal follower_empty_s2mm : std_logic := '0'; signal follower_reg, m_axis_updt_tdata_tmp : std_logic_vector (33 downto 0); signal follower_full :std_logic := '0'; signal follower_empty : std_logic := '0'; signal sts_rden : std_logic := '0'; signal sts2_rden : std_logic := '0'; signal follower_tlast : std_logic := '0'; signal follower_reg_image : std_logic := '0'; signal m_axis_updt_tready_mm2s, m_axis_updt_tready_s2mm : std_logic := '0'; ------------------------------------------------------------------------------- -- Begin architecture logic ------------------------------------------------------------------------------- begin m_axis_updt_tdata <= follower_reg_mm2s (C_S_AXIS_UPDSTS_TDATA_WIDTH-2 downto 0) when updt_active = '1' else follower_reg_s2mm (C_S_AXIS_UPDSTS_TDATA_WIDTH-2 downto 0) ; m_axis_updt_tvalid <= updt_tvalid when updt_active = '1' else updt2_tvalid; m_axis_updt_tlast <= updt_tlast when updt_active = '1' else updt2_tlast; m_axis_updt_tready_mm2s <= m_axis_updt_tready when updt_active = '1' else '0'; m_axis_updt_tready_s2mm <= m_axis_updt_tready when updt2_active = '1' else '0'; -- Asset active strobe on rising edge of update active -- asertion. This kicks off the update process for -- channel 1 updt_active_re <= updt_active_re1 or updt_active_re2; -- Current Descriptor Pointer Fetch. This state machine controls -- reading out the current pointer from the Queue or channel port -- and writing it to the update manager for use in command -- generation to the DataMover for Descriptor update. CURDESC_PNTR_STATE : process(pntr_cs, updt_active_re, ptr_queue_empty_int, m_axis_updt_tready, updt_tvalid_int, updt_tlast_int) begin write_curdesc_lsb_sm <= '0'; write_curdesc_msb <= '0'; writing_status <= '0'; dataq_rden <= '0'; stsq_rden <= '0'; pntr_ns <= pntr_cs; case pntr_cs is when IDLE => if(updt_active_re = '1')then pntr_ns <= READ_CURDESC_LSB; else pntr_ns <= IDLE; end if; --------------------------------------------------------------- -- Get lower current descriptor pointer -- Reads one word from data queue fifo --------------------------------------------------------------- when READ_CURDESC_LSB => -- on tvalid from Queue or channel port then register -- lsb curdesc and setup to register msb curdesc if(ptr_queue_empty_int = '0')then write_curdesc_lsb_sm <= '1'; dataq_rden <= '1'; -- pntr_ns <= READ_CURDESC_MSB; pntr_ns <= WRITE_STATUS; --READ_CURDESC_MSB; else -- coverage off pntr_ns <= READ_CURDESC_LSB; -- coverage on end if; --------------------------------------------------------------- -- Get upper current descriptor -- Reads one word from data queue fifo --------------------------------------------------------------- -- when READ_CURDESC_MSB => -- On tvalid from Queue or channel port then register -- msb. This will also write curdesc out to update -- manager. -- if(ptr_queue_empty_int = '0')then -- dataq_rden <= '1'; -- write_curdesc_msb <= '1'; -- pntr_ns <= WRITE_STATUS; -- else -- -- coverage off -- pntr_ns <= READ_CURDESC_MSB; -- -- coverage on -- end if; --------------------------------------------------------------- -- Hold in this state until remainder of descriptor is -- written out. when WRITE_STATUS => -- De-MUX appropriage tvalid/tlast signals writing_status <= '1'; -- Enable reading of Status Queue if datamover can -- accept data stsq_rden <= m_axis_updt_tready; -- Hold in the status state until tlast is pulled -- from status fifo if(updt_tvalid_int = '1' and m_axis_updt_tready = '1' and updt_tlast_int = '1')then -- if(follower_full = '1' and m_axis_updt_tready = '1' -- and follower_tlast = '1')then pntr_ns <= IDLE; else pntr_ns <= WRITE_STATUS; end if; -- coverage off when others => pntr_ns <= IDLE; -- coverage on end case; end process CURDESC_PNTR_STATE; updt_tvalid_int <= updt_tvalid or updt2_tvalid; updt_tlast_int <= updt_tlast or updt2_tlast; ptr_queue_empty_int <= ptr_queue_empty when updt_active = '1' else ptr2_queue_empty when updt2_active = '1' else '1'; --------------------------------------------------------------------------- -- Register for CURDESC Pointer state machine --------------------------------------------------------------------------- REG_PNTR_STATES : process(m_axi_sg_aclk) begin if(m_axi_sg_aclk'EVENT and m_axi_sg_aclk = '1')then if(m_axi_sg_aresetn = '0')then pntr_cs <= IDLE; else pntr_cs <= pntr_ns; end if; end if; end process REG_PNTR_STATES; GEN_Q_FOR_SYNC : if C_AXIS_IS_ASYNC = 0 generate begin MM2S_CHANNEL : if C_INCLUDE_MM2S = 1 generate updt_tvalid <= follower_full_mm2s and updt_active; updt_tlast <= follower_reg_mm2s(C_S_AXIS_UPDSTS_TDATA_WIDTH) and updt_active; sts_rden <= follower_empty_mm2s and (not sts_queue_empty); -- and updt_active; VALID_REG_MM2S_ACTIVE : process(m_axi_sg_aclk) begin if(m_axi_sg_aclk'EVENT and m_axi_sg_aclk = '1')then if(m_axi_sg_aresetn = '0' or (m_axis_updt_tready_mm2s = '1' and follower_full_mm2s = '1'))then -- follower_reg_mm2s <= (others => '0'); follower_full_mm2s <= '0'; follower_empty_mm2s <= '1'; else if (sts_rden = '1') then -- follower_reg_mm2s <= sts_queue_dout; follower_full_mm2s <= '1'; follower_empty_mm2s <= '0'; end if; end if; end if; end process VALID_REG_MM2S_ACTIVE; VALID_REG_MM2S_ACTIVE1 : process(m_axi_sg_aclk) begin if(m_axi_sg_aclk'EVENT and m_axi_sg_aclk = '1')then if(m_axi_sg_aresetn = '0')then follower_reg_mm2s <= (others => '0'); else if (sts_rden = '1') then follower_reg_mm2s <= sts_queue_dout; end if; end if; end if; end process VALID_REG_MM2S_ACTIVE1; REG_ACTIVE : process(m_axi_sg_aclk) begin if(m_axi_sg_aclk'EVENT and m_axi_sg_aclk = '1')then if(m_axi_sg_aresetn = '0' )then updt_active_d1 <= '0'; else updt_active_d1 <= updt_active; end if; end if; end process REG_ACTIVE; updt_active_re1 <= updt_active and not updt_active_d1; -- I_UPDT_DATA_FIFO : entity lib_srl_fifo_v1_0.srl_fifo_f -- generic map ( -- C_DWIDTH => 32 , -- C_DEPTH => 8 , -- C_FAMILY => C_FAMILY -- ) -- port map ( -- Clk => m_axi_sg_aclk , -- Reset => sinit , -- FIFO_Write => ptr_queue_wren , -- Data_In => ptr_queue_din , -- FIFO_Read => ptr_queue_rden , -- Data_Out => ptr_queue_dout , -- FIFO_Empty => ptr_queue_empty , -- FIFO_Full => ptr_queue_full, -- Addr => open -- ); process (m_axi_sg_aclk) begin if (m_axi_sg_aclk'event and m_axi_sg_aclk = '1') then if (sinit = '1') then ptr_queue_dout <= (others => '0'); elsif (ptr_queue_wren = '1') then ptr_queue_dout <= ptr_queue_din; end if; end if; end process; process (m_axi_sg_aclk) begin if (m_axi_sg_aclk'event and m_axi_sg_aclk = '1') then if (sinit = '1' or ptr_queue_rden = '1') then ptr_queue_empty <= '1'; ptr_queue_full <= '0'; elsif (ptr_queue_wren = '1') then ptr_queue_empty <= '0'; ptr_queue_full <= '1'; end if; end if; end process; -- Channel Pointer Queue (Generate Synchronous FIFO) -- I_UPDT_STS_FIFO : entity lib_srl_fifo_v1_0.srl_fifo_f -- generic map ( -- C_DWIDTH => 34 , -- C_DEPTH => 4 , -- C_FAMILY => C_FAMILY -- ) -- port map ( -- Clk => m_axi_sg_aclk , -- Reset => sinit , -- FIFO_Write => sts_queue_wren , -- Data_In => sts_queue_din , -- FIFO_Read => sts_rden, --sts_queue_rden , -- Data_Out => sts_queue_dout , -- FIFO_Empty => sts_queue_empty , -- FIFO_Full => sts_queue_full , -- Addr => open -- ); process (m_axi_sg_aclk) begin if (m_axi_sg_aclk'event and m_axi_sg_aclk = '1') then if (sinit = '1') then sts_queue_dout <= (others => '0'); elsif (sts_queue_wren = '1') then sts_queue_dout <= sts_queue_din; end if; end if; end process; process (m_axi_sg_aclk) begin if (m_axi_sg_aclk'event and m_axi_sg_aclk = '1') then if (sinit = '1' or sts_rden = '1') then sts_queue_empty <= '1'; sts_queue_full <= '0'; elsif (sts_queue_wren = '1') then sts_queue_empty <= '0'; sts_queue_full <= '1'; end if; end if; end process; -- Channel Status Queue (Generate Synchronous FIFO) --***************************************** --** Channel Data Port Side of Queues --***************************************** -- Pointer Queue Update - Descriptor Pointer (32bits) -- i.e. 2 current descriptor pointers and any app fields ptr_queue_din(C_S_AXIS_UPDPTR_TDATA_WIDTH-1 downto 0) <= s_axis_updtptr_tdata( -- DESC DATA C_S_AXIS_UPDPTR_TDATA_WIDTH-1 downto 0); -- Data Queue Write Enable - based on tvalid and queue not full ptr_queue_wren <= s_axis_updtptr_tvalid -- TValid and not ptr_queue_full; -- Data Queue NOT Full -- Drive channel port with ready if room in data queue s_axis_updtptr_tready <= not ptr_queue_full; --***************************************** --** Channel Status Port Side of Queues --***************************************** -- Status Queue Update - TLAST(1bit) & Includes IOC(1bit) & Descriptor Status(32bits) -- Note: Type field is stripped off sts_queue_din(C_S_AXIS_UPDSTS_TDATA_WIDTH) <= s_axis_updtsts_tlast; -- Store with tlast sts_queue_din(C_S_AXIS_UPDSTS_TDATA_WIDTH-1 downto 0) <= s_axis_updtsts_tdata( -- IOC & DESC STS C_S_AXIS_UPDSTS_TDATA_WIDTH-1 downto 0); -- Status Queue Write Enable - based on tvalid and queue not full sts_queue_wren <= s_axis_updtsts_tvalid and not sts_queue_full; -- Drive channel port with ready if room in status queue s_axis_updtsts_tready <= not sts_queue_full; --************************************* --** SG Engine Side of Queues --************************************* -- Indicate NOT empty if both status queue and data queue are not empty -- updt_queue_empty <= ptr_queue_empty -- or (sts_queue_empty and follower_empty and updt_active); updt_queue_empty <= ptr_queue_empty or follower_empty_mm2s; -- and updt_active); -- Data queue read enable ptr_queue_rden <= '1' when dataq_rden = '1' -- Cur desc read enable and ptr_queue_empty = '0' -- Data Queue NOT empty and updt_active = '1' else '0'; -- Status queue read enable sts_queue_rden <= '1' when stsq_rden = '1' -- Writing desc status and sts_queue_empty = '0' -- Status fifo NOT empty and updt_active = '1' else '0'; ----------------------------------------------------------------------- -- TVALID - status queue not empty and writing status ----------------------------------------------------------------------- ----------------------------------------------------------------------- -- TLAST - status queue not empty, writing status, and last asserted ----------------------------------------------------------------------- -- Drive last as long as tvalid is asserted and last from fifo -- is asserted end generate MM2S_CHANNEL; NO_MM2S_CHANNEL : if C_INCLUDE_MM2S = 0 generate begin updt_active_re1 <= '0'; updt_queue_empty <= '0'; s_axis_updtptr_tready <= '0'; s_axis_updtsts_tready <= '0'; sts_queue_dout <= (others => '0'); sts_queue_full <= '0'; sts_queue_empty <= '0'; ptr_queue_dout <= (others => '0'); ptr_queue_empty <= '0'; ptr_queue_full <= '0'; end generate NO_MM2S_CHANNEL; S2MM_CHANNEL : if C_INCLUDE_S2MM = 1 generate begin updt2_tvalid <= follower_full_s2mm and updt2_active; updt2_tlast <= follower_reg_s2mm(C_S_AXIS_UPDSTS_TDATA_WIDTH) and updt2_active; sts2_rden <= follower_empty_s2mm and (not sts2_queue_empty); -- and updt2_active; VALID_REG_S2MM_ACTIVE : process(m_axi_sg_aclk) begin if(m_axi_sg_aclk'EVENT and m_axi_sg_aclk = '1')then if(m_axi_sg_aresetn = '0' or (m_axis_updt_tready_s2mm = '1' and follower_full_s2mm = '1'))then -- follower_reg_s2mm <= (others => '0'); follower_full_s2mm <= '0'; follower_empty_s2mm <= '1'; else if (sts2_rden = '1') then -- follower_reg_s2mm <= sts2_queue_dout; follower_full_s2mm <= '1'; follower_empty_s2mm <= '0'; end if; end if; end if; end process VALID_REG_S2MM_ACTIVE; VALID_REG_S2MM_ACTIVE1 : process(m_axi_sg_aclk) begin if(m_axi_sg_aclk'EVENT and m_axi_sg_aclk = '1')then if(m_axi_sg_aresetn = '0')then follower_reg_s2mm <= (others => '0'); else if (sts2_rden = '1') then follower_reg_s2mm <= sts2_queue_dout; end if; end if; end if; end process VALID_REG_S2MM_ACTIVE1; REG2_ACTIVE : process(m_axi_sg_aclk) begin if(m_axi_sg_aclk'EVENT and m_axi_sg_aclk = '1')then if(m_axi_sg_aresetn = '0' )then updt_active_d2 <= '0'; else updt_active_d2 <= updt2_active; end if; end if; end process REG2_ACTIVE; updt_active_re2 <= updt2_active and not updt_active_d2; -- I_UPDT2_DATA_FIFO : entity lib_srl_fifo_v1_0.srl_fifo_f -- generic map ( -- C_DWIDTH => 32 , -- C_DEPTH => 8 , -- C_FAMILY => C_FAMILY -- ) -- port map ( -- Clk => m_axi_sg_aclk , -- Reset => sinit , -- FIFO_Write => ptr2_queue_wren , -- Data_In => ptr2_queue_din , -- FIFO_Read => ptr2_queue_rden , -- Data_Out => ptr2_queue_dout , -- FIFO_Empty => ptr2_queue_empty , -- FIFO_Full => ptr2_queue_full, -- Addr => open -- ); process (m_axi_sg_aclk) begin if (m_axi_sg_aclk'event and m_axi_sg_aclk = '1') then if (sinit = '1') then ptr2_queue_dout <= (others => '0'); elsif (ptr2_queue_wren = '1') then ptr2_queue_dout <= ptr2_queue_din; end if; end if; end process; process (m_axi_sg_aclk) begin if (m_axi_sg_aclk'event and m_axi_sg_aclk = '1') then if (sinit = '1' or ptr2_queue_rden = '1') then ptr2_queue_empty <= '1'; ptr2_queue_full <= '0'; elsif (ptr2_queue_wren = '1') then ptr2_queue_empty <= '0'; ptr2_queue_full <= '1'; end if; end if; end process; APP_UPDATE: if C_SG2_WORDS_TO_UPDATE /= 1 generate begin I_UPDT2_STS_FIFO : entity lib_srl_fifo_v1_0.srl_fifo_f generic map ( C_DWIDTH => 34 , C_DEPTH => 12 , C_FAMILY => C_FAMILY ) port map ( Clk => m_axi_sg_aclk , Reset => sinit , FIFO_Write => sts2_queue_wren , Data_In => sts2_queue_din , FIFO_Read => sts2_rden, Data_Out => sts2_queue_dout , FIFO_Empty => sts2_queue_empty , FIFO_Full => sts2_queue_full , Addr => open ); end generate APP_UPDATE; NO_APP_UPDATE: if C_SG2_WORDS_TO_UPDATE = 1 generate begin process (m_axi_sg_aclk) begin if (m_axi_sg_aclk'event and m_axi_sg_aclk = '1') then if (sinit = '1') then sts2_queue_dout <= (others => '0'); elsif (sts2_queue_wren = '1') then sts2_queue_dout <= sts2_queue_din; end if; end if; end process; process (m_axi_sg_aclk) begin if (m_axi_sg_aclk'event and m_axi_sg_aclk = '1') then if (sinit = '1' or sts2_rden = '1') then sts2_queue_empty <= '1'; sts2_queue_full <= '0'; elsif (sts2_queue_wren = '1') then sts2_queue_empty <= '0'; sts2_queue_full <= '1'; end if; end if; end process; end generate NO_APP_UPDATE; -- Pointer Queue Update - Descriptor Pointer (32bits) -- i.e. 2 current descriptor pointers and any app fields ptr2_queue_din(C_S_AXIS_UPDPTR_TDATA_WIDTH-1 downto 0) <= s_axis2_updtptr_tdata( -- DESC DATA C_S_AXIS_UPDPTR_TDATA_WIDTH-1 downto 0); -- Data Queue Write Enable - based on tvalid and queue not full ptr2_queue_wren <= s_axis2_updtptr_tvalid -- TValid and not ptr2_queue_full; -- Data Queue NOT Full -- Drive channel port with ready if room in data queue s_axis2_updtptr_tready <= not ptr2_queue_full; --***************************************** --** Channel Status Port Side of Queues --***************************************** -- Status Queue Update - TLAST(1bit) & Includes IOC(1bit) & Descriptor Status(32bits) -- Note: Type field is stripped off sts2_queue_din(C_S_AXIS_UPDSTS_TDATA_WIDTH) <= s_axis2_updtsts_tlast; -- Store with tlast sts2_queue_din(C_S_AXIS_UPDSTS_TDATA_WIDTH-1 downto 0) <= s_axis2_updtsts_tdata( -- IOC & DESC STS C_S_AXIS_UPDSTS_TDATA_WIDTH-1 downto 0); -- Status Queue Write Enable - based on tvalid and queue not full sts2_queue_wren <= s_axis2_updtsts_tvalid and not sts2_queue_full; -- Drive channel port with ready if room in status queue s_axis2_updtsts_tready <= not sts2_queue_full; --************************************* --** SG Engine Side of Queues --************************************* -- Indicate NOT empty if both status queue and data queue are not empty updt2_queue_empty <= ptr2_queue_empty or follower_empty_s2mm; --or (sts2_queue_empty and follower_empty and updt2_active); -- Data queue read enable ptr2_queue_rden <= '1' when dataq_rden = '1' -- Cur desc read enable and ptr2_queue_empty = '0' -- Data Queue NOT empty and updt2_active = '1' else '0'; -- Status queue read enable sts2_queue_rden <= '1' when stsq_rden = '1' -- Writing desc status and sts2_queue_empty = '0' -- Status fifo NOT empty and updt2_active = '1' else '0'; end generate S2MM_CHANNEL; NO_S2MM_CHANNEL : if C_INCLUDE_S2MM = 0 generate begin updt_active_re2 <= '0'; updt2_queue_empty <= '0'; s_axis2_updtptr_tready <= '0'; s_axis2_updtsts_tready <= '0'; sts2_queue_dout <= (others => '0'); sts2_queue_full <= '0'; sts2_queue_empty <= '0'; ptr2_queue_dout <= (others => '0'); ptr2_queue_empty <= '0'; ptr2_queue_full <= '0'; end generate NO_S2MM_CHANNEL; end generate GEN_Q_FOR_SYNC; -- FIFO Reset is active high sinit <= not m_axi_sg_aresetn; -- LSB_PROC : process(m_axi_sg_aclk) -- begin -- if(m_axi_sg_aclk'EVENT and m_axi_sg_aclk = '1')then -- if(m_axi_sg_aresetn = '0' )then -- write_curdesc_lsb <= '0'; -- -- Capture lower pointer from FIFO or channel port -- else -- if(write_curdesc_lsb = '1' and updt_active_int = '1')then write_curdesc_lsb <= write_curdesc_lsb_sm; -- end if; -- end if; -- end process LSB_PROC; --********************************************************************* --** POINTER CAPTURE LOGIC --********************************************************************* ptr_queue_dout_int <= ptr2_queue_dout when (updt2_active = '1') else ptr_queue_dout; --------------------------------------------------------------------------- -- Write lower order Next Descriptor Pointer out to pntr_mngr --------------------------------------------------------------------------- updt_active_int <= updt_active or updt2_active; REG_LSB_CURPNTR : process(m_axi_sg_aclk) begin if(m_axi_sg_aclk'EVENT and m_axi_sg_aclk = '1')then if(m_axi_sg_aresetn = '0' )then updt_curdesc(31 downto 0) <= (others => '0'); -- Capture lower pointer from FIFO or channel port elsif(write_curdesc_lsb = '1' and updt_active_int = '1')then updt_curdesc(31 downto 0) <= ptr_queue_dout_int(C_S_AXIS_UPDPTR_TDATA_WIDTH-1 downto 0); end if; end if; end process REG_LSB_CURPNTR; --------------------------------------------------------------------------- -- 64 Bit Scatter Gather addresses enabled --------------------------------------------------------------------------- GEN_UPPER_MSB_CURDESC : if C_M_AXI_SG_ADDR_WIDTH = 64 generate begin --------------------------------------------------------------------------- -- Write upper order Next Descriptor Pointer out to pntr_mngr --------------------------------------------------------------------------- REG_MSB_CURPNTR : process(m_axi_sg_aclk) begin if(m_axi_sg_aclk'EVENT and m_axi_sg_aclk = '1')then if(m_axi_sg_aresetn = '0' )then updt_curdesc(63 downto 32) <= (others => '0'); updt_curdesc_wren <= '0'; -- Capture upper pointer from FIFO or channel port -- and also write curdesc out elsif(write_curdesc_msb = '1' and updt_active_int = '1')then updt_curdesc(63 downto 32) <= ptr_queue_dout_int(C_S_AXIS_UPDPTR_TDATA_WIDTH-1 downto 0); updt_curdesc_wren <= '1'; -- Assert tready/wren for only 1 clock else updt_curdesc_wren <= '0'; end if; end if; end process REG_MSB_CURPNTR; end generate GEN_UPPER_MSB_CURDESC; --------------------------------------------------------------------------- -- 32 Bit Scatter Gather addresses enabled --------------------------------------------------------------------------- GEN_NO_UPR_MSB_CURDESC : if C_M_AXI_SG_ADDR_WIDTH = 32 generate begin ----------------------------------------------------------------------- -- No upper order therefore dump fetched word and write pntr lower next -- pointer to pntr mngr ----------------------------------------------------------------------- REG_MSB_CURPNTR : process(m_axi_sg_aclk) begin if(m_axi_sg_aclk'EVENT and m_axi_sg_aclk = '1')then if(m_axi_sg_aresetn = '0' )then updt_curdesc_wren <= '0'; -- Throw away second word, only write curdesc out with msb -- set to zero elsif(write_curdesc_lsb = '1' and updt_active_int = '1')then --elsif(write_curdesc_msb = '1' and updt_active_int = '1')then updt_curdesc_wren <= '1'; -- Assert for only 1 clock else updt_curdesc_wren <= '0'; end if; end if; end process REG_MSB_CURPNTR; end generate GEN_NO_UPR_MSB_CURDESC; --********************************************************************* --** ERROR CAPTURE LOGIC --********************************************************************* ----------------------------------------------------------------------- -- Generate rising edge pulse on writing status signal. This will -- assert at the beginning of the status write. Coupled with status -- fifo set to first word fall through status will be on dout -- regardless of target ready. ----------------------------------------------------------------------- REG_WRITE_STATUS : process(m_axi_sg_aclk) begin if(m_axi_sg_aclk'EVENT and m_axi_sg_aclk = '1')then if(m_axi_sg_aresetn = '0')then writing_status_d1 <= '0'; else writing_status_d1 <= writing_status; end if; end if; end process REG_WRITE_STATUS; writing_status_re <= writing_status and not writing_status_d1; writing_status_re_ch1 <= writing_status_re and updt_active; writing_status_re_ch2 <= writing_status_re and updt2_active; ----------------------------------------------------------------------- -- Caputure IOC begin set ----------------------------------------------------------------------- REG_IOC_PROCESS : process(m_axi_sg_aclk) begin if(m_axi_sg_aclk'EVENT and m_axi_sg_aclk = '1')then if(m_axi_sg_aresetn = '0' or updt_ioc_irq_set = '1')then updt_ioc <= '0'; elsif(writing_status_re_ch1 = '1')then -- updt_ioc <= sts_queue_dout(DESC_IOC_TAG_BIT) and updt_active; updt_ioc <= follower_reg_mm2s(DESC_IOC_TAG_BIT); end if; end if; end process REG_IOC_PROCESS; ----------------------------------------------------------------------- -- Capture DMA Internal Errors ----------------------------------------------------------------------- CAPTURE_DMAINT_ERROR: process(m_axi_sg_aclk) begin if(m_axi_sg_aclk'EVENT and m_axi_sg_aclk = '1')then if(m_axi_sg_aresetn = '0' or dma_interr_set = '1')then dma_interr <= '0'; elsif(writing_status_re_ch1 = '1')then --dma_interr <= sts_queue_dout(DESC_STS_INTERR_BIT) and updt_active; dma_interr <= follower_reg_mm2s(DESC_STS_INTERR_BIT); end if; end if; end process CAPTURE_DMAINT_ERROR; ----------------------------------------------------------------------- -- Capture DMA Slave Errors ----------------------------------------------------------------------- CAPTURE_DMASLV_ERROR: process(m_axi_sg_aclk) begin if(m_axi_sg_aclk'EVENT and m_axi_sg_aclk = '1')then if(m_axi_sg_aresetn = '0' or dma_slverr_set = '1')then dma_slverr <= '0'; elsif(writing_status_re_ch1 = '1')then -- dma_slverr <= sts_queue_dout(DESC_STS_SLVERR_BIT) and updt_active; dma_slverr <= follower_reg_mm2s(DESC_STS_SLVERR_BIT); end if; end if; end process CAPTURE_DMASLV_ERROR; ----------------------------------------------------------------------- -- Capture DMA Decode Errors ----------------------------------------------------------------------- CAPTURE_DMADEC_ERROR: process(m_axi_sg_aclk) begin if(m_axi_sg_aclk'EVENT and m_axi_sg_aclk = '1')then if(m_axi_sg_aresetn = '0' or dma_decerr_set = '1')then dma_decerr <= '0'; elsif(writing_status_re_ch1 = '1')then -- dma_decerr <= sts_queue_dout(DESC_STS_DECERR_BIT) and updt_active; dma_decerr <= follower_reg_mm2s(DESC_STS_DECERR_BIT); end if; end if; end process CAPTURE_DMADEC_ERROR; ----------------------------------------------------------------------- -- Caputure IOC begin set ----------------------------------------------------------------------- REG_IOC2_PROCESS : process(m_axi_sg_aclk) begin if(m_axi_sg_aclk'EVENT and m_axi_sg_aclk = '1')then if(m_axi_sg_aresetn = '0' or updt2_ioc_irq_set = '1')then updt2_ioc <= '0'; elsif(writing_status_re_ch2 = '1')then -- updt2_ioc <= sts2_queue_dout(DESC_IOC_TAG_BIT) and updt2_active; updt2_ioc <= follower_reg_s2mm(DESC_IOC_TAG_BIT); end if; end if; end process REG_IOC2_PROCESS; ----------------------------------------------------------------------- -- Capture DMA Internal Errors ----------------------------------------------------------------------- CAPTURE_DMAINT2_ERROR: process(m_axi_sg_aclk) begin if(m_axi_sg_aclk'EVENT and m_axi_sg_aclk = '1')then if(m_axi_sg_aresetn = '0' or dma2_interr_set = '1')then dma2_interr <= '0'; elsif(writing_status_re_ch2 = '1')then -- dma2_interr <= sts2_queue_dout(DESC_STS_INTERR_BIT) and updt2_active; dma2_interr <= follower_reg_s2mm (DESC_STS_INTERR_BIT); end if; end if; end process CAPTURE_DMAINT2_ERROR; ----------------------------------------------------------------------- -- Capture DMA Slave Errors ----------------------------------------------------------------------- CAPTURE_DMASLV2_ERROR: process(m_axi_sg_aclk) begin if(m_axi_sg_aclk'EVENT and m_axi_sg_aclk = '1')then if(m_axi_sg_aresetn = '0' or dma2_slverr_set = '1')then dma2_slverr <= '0'; elsif(writing_status_re_ch2 = '1')then -- dma2_slverr <= sts2_queue_dout(DESC_STS_SLVERR_BIT) and updt2_active; dma2_slverr <= follower_reg_s2mm(DESC_STS_SLVERR_BIT); end if; end if; end process CAPTURE_DMASLV2_ERROR; ----------------------------------------------------------------------- -- Capture DMA Decode Errors ----------------------------------------------------------------------- CAPTURE_DMADEC2_ERROR: process(m_axi_sg_aclk) begin if(m_axi_sg_aclk'EVENT and m_axi_sg_aclk = '1')then if(m_axi_sg_aresetn = '0' or dma2_decerr_set = '1')then dma2_decerr <= '0'; elsif(writing_status_re_ch2 = '1')then -- dma2_decerr <= sts2_queue_dout(DESC_STS_DECERR_BIT) and updt2_active; dma2_decerr <= follower_reg_s2mm(DESC_STS_DECERR_BIT); end if; end if; end process CAPTURE_DMADEC2_ERROR; end implementation;

gpl-3.0

d9b76d8b94797ff9db15832593634ecb

0.433834

4.277416

false

laurocruz/snakes_vhdl

src/snake_lib/snake_pack.vhd

1

2,402

LIBRARY ieee; USE ieee.std_logic_1164.all; USE ieee.math_real.all; PACKAGE snake_pack IS --TYPE int_s IS INTEGER RANGE -20 TO 255; TYPE int_array IS array (0 to 127) OF INTEGER RANGE -20 TO 255; COMPONENT conv_7seg IS PORT (digit : IN STD_LOGIC_VECTOR(3 DOWNTO 0) ; seg : OUT STD_LOGIC_VECTOR(6 DOWNTO 0) ) ; END COMPONENT; COMPONENT create_food IS -- Altura e comprimento do mapa GENERIC (N : INTEGER := 10; M : INTEGER := 10; width : INTEGER := 6); PORT (reset : IN STD_LOGIC; eaten : IN STD_LOGIC; gmap : IN STD_LOGIC_VECTOR(0 TO N*M-1); new_food : OUT INTEGER RANGE 0 TO N*M-1); END COMPONENT; COMPONENT gclock IS -- Frequencia de 1Hz -- clock do hardware PORT (CLOCK_27 : IN STD_LOGIC ; reset : IN STD_LOGIC ; clock_out : OUT STD_LOGIC) ; END COMPONENT; COMPONENT make_map IS -- DImensões do mapa GENERIC (N : INTEGER := 10; M : INTEGER := 10; INITIAL_SIZE : INTEGER := 2); -- clock do jogo PORT (clock : IN STD_LOGIC; -- reseta o jogo reset : IN STD_LOGIC; -- aumento do tamanho eaten : IN STD_LOGIC; snake_size : IN INTEGER RANGE 0 TO N*M; -- direcao para onde a cobra esta se movendo -- 11 : cima -- 00 : baixo -- 10 : esquerda -- 01 : direita dir : IN STD_LOGIC_VECTOR(1 DOWNTO 0); -- posicoes da cobra no mapa snake_body : OUT int_array); END COMPONENT; COMPONENT size_counter IS -- DImensões do mapa GENERIC (N : INTEGER := 10; M : INTEGER := 10; INITIAL_SIZE : INTEGER := 2); PORT (reset : IN STD_LOGIC; food_pos : IN INTEGER RANGE -20 TO 255; --food_pos : IN INTEGER RANGE 0 TO N*M-1; snake_head : IN INTEGER RANGE -20 TO 255; snake_size : OUT INTEGER RANGE 0 TO N*M; eaten : OUT STD_LOGIC); END COMPONENT; COMPONENT colision IS -- Dimensoes do mapa GENERIC (N : INTEGER := 10; M : INTEGER := 10); PORT (snake_body : IN int_array; dir : IN STD_LOGIC_VECTOR(1 DOWNTO 0); reset : IN STD_LOGIC; gmap : OUT STD_LOGIC_VECTOR(0 to N*M-1); lost : OUT STD_LOGIC); END COMPONENT ; COMPONENT snake_dir IS PORT (reset : IN STD_LOGIC; snake_turn : IN STD_LOGIC_VECTOR(1 downto 0); dir : BUFFER STD_LOGIC_VECTOR(0 to 1)); END COMPONENT; END snake_pack;

mit

a8b2d5bc443f1aa2e8a0963a5fdcf925

0.592083

3.137255

false

marco-c/leon-nexys2

grlib-gpl-1.3.4-b4140/lib/gaisler/leon3v3/leon3x.vhd

1

9,494

------------------------------------------------------------------------------ -- This file is a part of the GRLIB VHDL IP LIBRARY -- Copyright (C) 2003 - 2008, Gaisler Research -- Copyright (C) 2008 - 2013, Aeroflex Gaisler -- -- This program is free software; you can redistribute it and/or modify -- it under the terms of the GNU General Public License as published by -- the Free Software Foundation; either version 2 of the License, or -- (at your option) any later version. -- -- This program is distributed in the hope that it will be useful, -- but WITHOUT ANY WARRANTY; without even the implied warranty of -- MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the -- GNU General Public License for more details. -- -- You should have received a copy of the GNU General Public License -- along with this program; if not, write to the Free Software -- Foundation, Inc., 59 Temple Place, Suite 330, Boston, MA 02111-1307 USA ------------------------------------------------------------------------------ -- Entity: leon3x -- File: leon3x.vhd -- Author: Jiri Gaisler, Jan Andersson, Aeroflex Gaisler -- Description: Top-level LEON3v3 component with all options ------------------------------------------------------------------------------ library ieee; use ieee.std_logic_1164.all; library grlib; use grlib.amba.all; use grlib.stdlib.all; library techmap; use techmap.gencomp.all; use techmap.netcomp.all; library gaisler; use gaisler.leon3.all; use gaisler.libiu.all; use gaisler.libcache.all; use gaisler.libleon3.all; use gaisler.libfpu.all; use gaisler.arith.all; entity leon3x is generic ( hindex : integer := 0; fabtech : integer range 0 to NTECH := DEFFABTECH; memtech : integer range 0 to NTECH := DEFMEMTECH; nwindows : integer range 2 to 32 := 8; dsu : integer range 0 to 1 := 0; fpu : integer range 0 to 63 := 0; v8 : integer range 0 to 63 := 0; cp : integer range 0 to 1 := 0; mac : integer range 0 to 1 := 0; pclow : integer range 0 to 2 := 2; notag : integer range 0 to 1 := 0; nwp : integer range 0 to 4 := 0; icen : integer range 0 to 1 := 0; irepl : integer range 0 to 3 := 2; isets : integer range 1 to 4 := 1; ilinesize : integer range 4 to 8 := 4; isetsize : integer range 1 to 256 := 1; isetlock : integer range 0 to 1 := 0; dcen : integer range 0 to 1 := 0; drepl : integer range 0 to 3 := 2; dsets : integer range 1 to 4 := 1; dlinesize : integer range 4 to 8 := 4; dsetsize : integer range 1 to 256 := 1; dsetlock : integer range 0 to 1 := 0; dsnoop : integer range 0 to 6 := 0; ilram : integer range 0 to 1 := 0; ilramsize : integer range 1 to 512 := 1; ilramstart : integer range 0 to 255 := 16#8e#; dlram : integer range 0 to 1 := 0; dlramsize : integer range 1 to 512 := 1; dlramstart : integer range 0 to 255 := 16#8f#; mmuen : integer range 0 to 1 := 0; itlbnum : integer range 2 to 64 := 8; dtlbnum : integer range 2 to 64 := 8; tlb_type : integer range 0 to 3 := 1; tlb_rep : integer range 0 to 1 := 0; lddel : integer range 1 to 2 := 2; disas : integer range 0 to 2 := 0; tbuf : integer range 0 to 64 := 0; pwd : integer range 0 to 2 := 2; svt : integer range 0 to 1 := 1; rstaddr : integer := 0; smp : integer range 0 to 15 := 0; iuft : integer range 0 to 4 := 0; fpft : integer range 0 to 4 := 0; cmft : integer range 0 to 1 := 0; iuinj : integer := 0; ceinj : integer range 0 to 3 := 0; cached : integer := 0; clk2x : integer := 1; netlist : integer := 0; scantest : integer := 0; mmupgsz : integer range 0 to 5 := 0; bp : integer := 1 ); port ( clk : in std_ulogic; -- free-running clock gclk2 : in std_ulogic; -- gated 2x clock gfclk2 : in std_ulogic; -- gated 2x FPU clock clk2 : in std_ulogic; -- free-running 2x clock rstn : in std_ulogic; ahbi : in ahb_mst_in_type; ahbo : out ahb_mst_out_type; ahbsi : in ahb_slv_in_type; ahbso : in ahb_slv_out_vector; irqi : in l3_irq_in_type; irqo : out l3_irq_out_type; dbgi : in l3_debug_in_type; dbgo : out l3_debug_out_type; fpui : out grfpu_in_type; fpuo : in grfpu_out_type; clken : in std_ulogic ); end; architecture rtl of leon3x is constant IRFBITS : integer range 6 to 10 := log2(NWINDOWS+1) + 4; constant IREGNUM : integer := NWINDOWS * 16 + 8; constant IRFWT : integer := 1;--regfile_3p_write_through(memtech); constant fpuarch : integer := fpu mod 16; constant fpunet : integer := (fpu mod 32) / 16; constant fpushared : boolean := (fpu / 32) /= 0; signal holdn : std_logic; signal rfi : iregfile_in_type; signal rfo : iregfile_out_type; signal crami : cram_in_type; signal cramo : cram_out_type; signal tbi : tracebuf_in_type; signal tbo : tracebuf_out_type; signal rst : std_ulogic; signal fpi : fpc_in_type; signal fpo : fpc_out_type; signal cpi : fpc_in_type; signal cpo : fpc_out_type; signal gnd, vcc : std_logic; attribute sync_set_reset : string; attribute sync_set_reset of rst : signal is "true"; begin gnd <= '0'; vcc <= '1'; -- leon3 processor core (iu, caches & mul/div) p0 : proc3 generic map ( hindex, fabtech, memtech, nwindows, dsu, fpuarch, v8, cp, mac, pclow, notag, nwp, icen, irepl, isets, ilinesize, isetsize, isetlock, dcen, drepl, dsets, dlinesize, dsetsize, dsetlock, dsnoop, ilram, ilramsize, ilramstart, dlram, dlramsize, dlramstart, mmuen, itlbnum, dtlbnum, tlb_type, tlb_rep, lddel, disas, tbuf, pwd, svt, rstaddr, smp, cached, clk2x, scantest, mmupgsz, bp) port map (gclk2, rst, holdn, ahbi, ahbo, ahbsi, ahbso, rfi, rfo, crami, cramo, tbi, tbo, fpi, fpo, cpi, cpo, irqi, irqo, dbgi, dbgo, clk, clk2, clken); -- IU register file rf0 : regfile_3p_l3 generic map (memtech, IRFBITS, 32, IRFWT, IREGNUM, scantest) port map (gclk2, rfi.waddr(IRFBITS-1 downto 0), rfi.wdata, rfi.wren, gclk2, rfi.raddr1(IRFBITS-1 downto 0), rfi.ren1, rfo.data1, rfi.raddr2(IRFBITS-1 downto 0), rfi.ren2, rfo.data2, rfi.diag ); -- cache memory cmem0 : cachemem generic map (memtech, icen, irepl, isets, ilinesize, isetsize, isetlock, dcen, drepl, dsets, dlinesize, dsetsize, dsetlock, dsnoop, ilram, ilramsize, dlram, dlramsize, mmuen, scantest ) port map (gclk2, crami, cramo, clk2); -- instruction trace buffer memory tbmem_gen : if (tbuf /= 0) generate tbmem0 : tbufmem generic map (memtech, tbuf, scantest) port map (gclk2, tbi, tbo); end generate; -- FPU fpu0 : if (fpu = 0) generate fpo <= fpc_out_none; end generate; fpshare : if fpushared generate grfpw0gen : if (fpuarch > 0) and (fpuarch < 8) generate fpu0: grfpwxsh generic map (memtech, pclow, dsu, disas, hindex ) port map (rst, gclk2, holdn, fpi, fpo, fpui, fpuo); end generate; nogrfpw0gen : if not ((fpuarch > 0) and (fpuarch < 8)) generate fpui <= grfpu_in_none; end generate; end generate; nofpshare : if not fpushared generate grfpw1gen : if (fpuarch > 0) and (fpuarch < 8) generate fpu0: grfpwx generic map (fabtech, memtech, (fpuarch-1), pclow, dsu, disas, fpunet, hindex) port map (rst, gfclk2, holdn, fpi, fpo); end generate; mfpw1gen : if (fpuarch = 15) generate fpu0 : mfpwx generic map (memtech, pclow, dsu, disas ) port map (rst, gfclk2, holdn, fpi, fpo); end generate; grlfpc1gen : if (fpuarch >=8) and (fpuarch < 15) generate fpu0 : grlfpwx generic map (memtech, pclow, dsu, disas, (fpuarch-8), fpunet, hindex) port map (rst, gfclk2, holdn, fpi, fpo); end generate; fpui <= grfpu_in_none; end generate; -- CP cpo <= fpc_out_none; -- 1-clock reset delay rstreg : process(gclk2) begin if rising_edge(gclk2) then rst <= rstn; end if; end process; -- pragma translate_off bootmsg : report_version generic map ( "leon3_" & tost(hindex) & ": LEON3 SPARC V8 processor rev " & tost(LEON3_VERSION) , "leon3_" & tost(hindex) & ": icache " & tost(isets*icen) & "*" & tost(isetsize*icen) & " kbyte, dcache " & tost(dsets*dcen) & "*" & tost(dsetsize*dcen) & " kbyte" ); -- pragma translate_on end;

gpl-2.0

c33522c587c113e9d4c1b2da8b7e0df5

0.545818

3.651538

false

mistryalok/Zedboard

learning/opencv_hls/xapp1167_vivado/sw/fast-corner/prj/solution1/syn/vhdl/FIFO_image_filter_dmask_rows_V.vhd

2

4,564

-- ============================================================== -- File generated by Vivado(TM) HLS - High-Level Synthesis from C, C++ and SystemC -- Version: 2014.4 -- Copyright (C) 2014 Xilinx Inc. All rights reserved. -- -- ============================================================== library IEEE; use IEEE.std_logic_1164.all; use IEEE.std_logic_unsigned.all; entity FIFO_image_filter_dmask_rows_V_shiftReg is generic ( DATA_WIDTH : integer := 12; ADDR_WIDTH : integer := 2; DEPTH : integer := 3); port ( clk : in std_logic; data : in std_logic_vector(DATA_WIDTH-1 downto 0); ce : in std_logic; a : in std_logic_vector(ADDR_WIDTH-1 downto 0); q : out std_logic_vector(DATA_WIDTH-1 downto 0)); end FIFO_image_filter_dmask_rows_V_shiftReg; architecture rtl of FIFO_image_filter_dmask_rows_V_shiftReg is --constant DEPTH_WIDTH: integer := 16; type SRL_ARRAY is array (0 to DEPTH-1) of std_logic_vector(DATA_WIDTH-1 downto 0); signal SRL_SIG : SRL_ARRAY; begin p_shift: process (clk) begin if (clk'event and clk = '1') then if (ce = '1') then SRL_SIG <= data & SRL_SIG(0 to DEPTH-2); end if; end if; end process; q <= SRL_SIG(conv_integer(a)); end rtl; library ieee; use ieee.std_logic_1164.all; use ieee.std_logic_unsigned.all; entity FIFO_image_filter_dmask_rows_V is generic ( MEM_STYLE : string := "shiftreg"; DATA_WIDTH : integer := 12; ADDR_WIDTH : integer := 2; DEPTH : integer := 3); port ( clk : IN STD_LOGIC; reset : IN STD_LOGIC; if_empty_n : OUT STD_LOGIC; if_read_ce : IN STD_LOGIC; if_read : IN STD_LOGIC; if_dout : OUT STD_LOGIC_VECTOR(DATA_WIDTH - 1 downto 0); if_full_n : OUT STD_LOGIC; if_write_ce : IN STD_LOGIC; if_write : IN STD_LOGIC; if_din : IN STD_LOGIC_VECTOR(DATA_WIDTH - 1 downto 0)); end entity; architecture rtl of FIFO_image_filter_dmask_rows_V is component FIFO_image_filter_dmask_rows_V_shiftReg is generic ( DATA_WIDTH : integer := 12; ADDR_WIDTH : integer := 2; DEPTH : integer := 3); port ( clk : in std_logic; data : in std_logic_vector(DATA_WIDTH-1 downto 0); ce : in std_logic; a : in std_logic_vector(ADDR_WIDTH-1 downto 0); q : out std_logic_vector(DATA_WIDTH-1 downto 0)); end component; signal shiftReg_addr : STD_LOGIC_VECTOR(ADDR_WIDTH - 1 downto 0); signal shiftReg_data, shiftReg_q : STD_LOGIC_VECTOR(DATA_WIDTH - 1 downto 0); signal shiftReg_ce : STD_LOGIC; signal mOutPtr : STD_LOGIC_VECTOR(ADDR_WIDTH downto 0) := (others => '1'); signal internal_empty_n : STD_LOGIC := '0'; signal internal_full_n : STD_LOGIC := '1'; begin if_empty_n <= internal_empty_n; if_full_n <= internal_full_n; shiftReg_data <= if_din; if_dout <= shiftReg_q; process (clk) begin if clk'event and clk = '1' then if reset = '1' then mOutPtr <= (others => '1'); internal_empty_n <= '0'; internal_full_n <= '1'; else if ((if_read and if_read_ce) = '1' and internal_empty_n = '1') and ((if_write and if_write_ce) = '0' or internal_full_n = '0') then mOutPtr <= mOutPtr -1; if (mOutPtr = 0) then internal_empty_n <= '0'; end if; internal_full_n <= '1'; elsif ((if_read and if_read_ce) = '0' or internal_empty_n = '0') and ((if_write and if_write_ce) = '1' and internal_full_n = '1') then mOutPtr <= mOutPtr +1; internal_empty_n <= '1'; if (mOutPtr = DEPTH -2) then internal_full_n <= '0'; end if; end if; end if; end if; end process; shiftReg_addr <= (others => '0') when mOutPtr(ADDR_WIDTH) = '1' else mOutPtr(ADDR_WIDTH-1 downto 0); shiftReg_ce <= (if_write and if_write_ce) and internal_full_n; U_FIFO_image_filter_dmask_rows_V_shiftReg : FIFO_image_filter_dmask_rows_V_shiftReg generic map ( DATA_WIDTH => DATA_WIDTH, ADDR_WIDTH => ADDR_WIDTH, DEPTH => DEPTH) port map ( clk => clk, data => shiftReg_data, ce => shiftReg_ce, a => shiftReg_addr, q => shiftReg_q); end rtl;

gpl-3.0

3fb169d8ab8ec045492127b1db970526

0.536372

3.505376

false

capitanov/Stupid_watch

src/rtl/pwm_test/ctrl_led8x8_heart.vhd

1

3,940

------------------------------------------------------------------------------- -- -- Title : ctrl_led8x8_heart -- Author : Alexander Kapitanov -- Company : Instrumental Systems -- E-mail : [email protected] -- -- Version : 1.0 -- ------------------------------------------------------------------------------- -- -- Description : Controller for LED Matrix -- ------------------------------------------------------------------------------- library ieee; use ieee.std_logic_1164.all; use ieee.std_logic_arith.all; use ieee.std_logic_unsigned.all; entity ctrl_led8x8_heart is port ( clk : in std_logic; --! clock rst : in std_logic; --! reset rst_reg : in std_logic; --! count reset ch_freq : in std_logic; --! change frequency led_y : out std_logic_vector(7 downto 0); --! LED Y led_x : out std_logic_vector(7 downto 0) --! LED X ); end ctrl_led8x8_heart; architecture ctr_led8x8 of ctrl_led8x8_heart is constant Nled : integer:=12; -- 12 signal cnt_led : std_logic_vector(Nled downto 0); signal cnt_cmd : std_logic_vector(2 downto 0); signal led_cmd : std_logic_vector(3 downto 0); signal data_led : std_logic_vector(7 downto 0); signal en_xhdl : std_logic_vector(7 downto 0); signal ch_freqz : std_logic; signal ch_freqx : std_logic; signal case_cnt : std_logic_vector(1 downto 0); begin ch_freqz <= ch_freq after 1 ns when rising_edge(clk); ch_freqx <= ch_freq and not ch_freqz when rising_edge(clk); led_y <= data_led; led_x <= en_xhdl; pr_case: process(clk, rst) is begin if rst = '0' then case_cnt <= (others => '0'); elsif rising_edge(clk) then -- if rst_reg = '0' then -- case_cnt <= (others => '0'); -- elsif ch_freqx = '1' then -- case_cnt <= case_cnt + '1'; -- else -- null; -- end if; if ch_freqx = '1' then case_cnt <= case_cnt + '1'; else null; end if; end if; end process; pr_cnt: process(clk, rst) is begin if rst = '0' then cnt_led <= (others => '0'); elsif rising_edge(clk) then if rst_reg = '0' then cnt_led <= (others => '0'); else case case_cnt is when "00" => cnt_led <= cnt_led + '1'; when "01" => cnt_led <= cnt_led + "10"; when "10" => cnt_led <= cnt_led + "11"; when others => cnt_led <= cnt_led + "100"; end case; end if; end if; end process; cnt_cmd <= cnt_led(Nled downto Nled-2); pr_3x8: process(cnt_cmd) is begin case cnt_cmd is when "000" => en_xhdl <= "11111110"; when "001" => en_xhdl <= "11111101"; when "010" => en_xhdl <= "11111011"; when "011" => en_xhdl <= "11110111"; when "100" => en_xhdl <= "11101111"; when "101" => en_xhdl <= "11011111"; when "110" => en_xhdl <= "10111111"; when "111" => en_xhdl <= "01111111"; when others => en_xhdl <= "11111110"; end case; end process; pr_8x4: process(en_xhdl) is begin case en_xhdl is when "11111110" => led_cmd <= "0000"; when "11111101" => led_cmd <= "0001"; when "11111011" => led_cmd <= "0010"; when "11110111" => led_cmd <= "0011"; when "11101111" => led_cmd <= "0100"; when "11011111" => led_cmd <= "0101"; when "10111111" => led_cmd <= "0110"; when "01111111" => led_cmd <= "0111"; when others => led_cmd <= "1000"; end case; end process; pr_4x8: process(led_cmd) is begin case led_cmd is when "0000" => data_led <= "11111111"; when "0001" => data_led <= "11100111"; when "0010" => data_led <= "11011011"; when "0011" => data_led <= "10111101"; when "0100" => data_led <= "01111110"; when "0101" => data_led <= "01100110"; when "0110" => data_led <= "10011001"; when "0111" => data_led <= "11111111"; when others => data_led <= "11111111"; end case; end process; end ctr_led8x8;

mit

156f237b05a6f1a94777b462ae738bd9

0.523604

2.730423

false