Datasets:

oongaboongahacker
/

allah

+0/1 Knapsack DP
+#include <stdio.h>
+#include <limits.h>
+void knapsack(int n, int m, int profits[], int weights[])
+{
+int v[n+1][m+1];
+int result[n];
+for(int i=0; i<=m; i++)
+v[0][i] = 0;
+for(int i=0; i<=n; i++)
+v[i][0] = 0;
+for(int i=1; i<=n; i++) {
+for(int w=1; w<=m; w++) {
+if(w - weights[i-1] <0) {
+v[i][w] = v[i-1][w];
+} else {
+int val1 = v[i-1][w];
+int val2 = v[i-1][w-weights[i-1]] + profits[i-1];
+v[i][w] = (val1 > val2) ? val1 : val2;
+}
+}
+}
+int k=n, j=m;
+while (k>0 && j>0) {
+if(v[k][j] != v[k-1][j]) {
+result[k-1] = 1;
+j = j-weights[k-1];
+}
+else {
+result[k-1] = 0;
+}
+k--;
+}
+for(int i=0; i<n; i++)
+printf("%d ", result[i]);
+}
+int main()
+{
+int n; //No. of objects
+scanf("%d", &n);
+int m; //Max capacity
+scanf("%d", &m);
+int profits[n], weights[n];
+for(int i=0; i<n; i++)
+scanf("%d", &profits[i]);
+for(int i=0; i<n; i++)
+scanf("%d", &weights[i]);
+knapsack(n, m, profits, weights);
+return 0;
+}
+LCS
+#include <stdio.h>
+#include <string.h>
+char S1[20], S2[20];
+int i, j, m, n, LCS_table[20][20];
+int max(int a, int b) {
+return (a>b) ? a: b;
+}
+void lcsAlgo()
+{
+printf("Reached\n");
+m = strlen(S1);
+n = strlen(S2);
+for(i = 0; i<=m; i++)
+LCS_table[i][0] = 0;
+for(i=0; i<=n; i++)
+LCS_table[0][i] = 0;
+for(i=1; i<=m; i++) {
+for(j=1; j<=n; j++) {
+if(S1[i-1] == S2[j-1])
+LCS_table[i][j] = LCS_table[i-1][j-1] + 1;
+else
+LCS_table[i][j] = max(LCS_table[i-1][j], LCS_table[i][j-1]);
+}
+}
+int index = LCS_table[m][n];
+char LCSAlgo[index+1];
+LCSAlgo[index] = '\0';
+printf("%d\n", index);
+i=m, j=n;
+while(i>0 && j>0)
+{
+if(S1[i-1] == S2[j-1]) {
+LCSAlgo[index-1] = S1[i-1];
+i--;
+j--;
+index--;
+} else {
+//max(LCS_table[i-1][j], LCS_table[i][j-1]);
+if(LCS_table[i - 1][j] > LCS_table[i][j - 1])
+i--;
+else
+j--;
+}
+}
+printf("%d\n", index);
+printf("The LCS is %s", LCSAlgo);
+}
+int main()
+{
+scanf("%[^\n]s", &S1);
+scanf("%s", &S2);
+lcsAlgo();
+}
+Matrix Chain
+#include <stdio.h>
+#include <limits.h>
+int MatrixChainMultiplication(int arr[], int n)
+{
+int minMul[n][n];
+for(int i=1; i<n; i++)
+minMul[i][i] = 0;
+int j, q=0;
+for(int L=2; L<n; L++) {
+for(int i=1; i<n-L+1; i++) {
+j = i+L-1;
+minMul[i][j] = INT_MAX;
+for(int k=i; k<=j; k++) {
+q = minMul[i][k] + minMul[k+1][j] + arr[i-1]*arr[k]*arr[j];
+if(q<minMul[i][j])
+minMul[i][j]=q;
+}
+}
+}
+return minMul[1][n-1];
+}
+int main()
+{
+int n;
+scanf("%d", &n);
+int arrS[n][2];
+int arr[n+1];
+for(int i=0; i<n; i++) {
+scanf("%d %d",&arrS[i][0], &arrS[i][1]);
+}
+arr[0] = arrS[0][0];
+for(int i=1; i<=n; i++)
+arr[i] = arrS[i-1][1];
+printf("Minimum number of multiplications required for matrix
+multiplication is %d\n", MatrixChainMultiplication(arr, n+1));
+getchar();
+return 0;
+}
+Assembly line scheduling
+Code:
+#include <stdio.h>
+#include <stdlib.h>
+#define min(a, b) ((a) < (b) ? (a) : (b))
+int fun(int a*2+*4+, int t*2+*4+, int cl, int cs, int x1, int x2, int n);
+int main() ,
+ int n = 4; // number of stations
+ int a*2+*4+ = , , 4, 5, 3, 2 -, , 2, 10, 1, 4 - -;
+ int t*2+*4+ = , , 0, 7, 4, 5 -, , 0, 9, 2, 8 - -;
+ int e1 = 10;
+ int e2 = 12;
+ int x1 = 18;
+ int x2 = 7;
+ // entry from 1st line
+ int x = fun(a, t, 0, 0, x1, x2, n) + e1 + a*0+*0+;
+ // entry from 2nd line
+ int y = fun(a, t, 1, 0, x1, x2, n) + e2 + a*1+*0+;
+ printf("%d\n", min(x, y));
+ return 0;
+-
+int fun(int a*2+*4+, int t*2+*4+, int cl, int cs, int x1, int x2, int n) ,
+ // base case
+ if (cs == n - 1) ,
+ if (cl == 0) , // exiting from (current) line =0
+ return x1;
+ - else , // exiting from line 2
+ return x2;
+ -
+ -
+ // continue on same line
+ int same = fun(a, t, cl, cs + 1, x1, x2, n) + a*cl+*cs + 1+;
+ // continue on different line
+ int diff = fun(a, t, !cl, cs + 1, x1, x2, n) + a*!cl+*cs + 1+ + t*cl+*cs + 1+;
+ return min(same, diff);
+-
+Max Sub Array Sum
+#include <stdio.h>
+#include <limits.h>
+int *maxSubArraySum(int nums[], int start, int end, int *max_sum, int
+*subarray_start, int *subarray_end)
+{
+if(start == end) {
+*max_sum = nums[start];
+*subarray_start = start;
+*subarray_end = start;
+return &nums[start];
+}
+int mid= (start+end)/2;
+int left_subarray = maxSubArraySum(nums, start, mid, &max_sum,
+&subarray_start, &subarray_end);
+int right_subarray = maxSubArraySum(nums, mid+1, end, &max_sum,
+&subarray_start, &subarray_end);
+int left_sum=INT_MIN;
+int curr_sum = 0;
+int cross_start = mid;
+for(int i=mid; i>=start; i--) {
+curr_sum += nums[i];
+if(curr_sum >= left_sum) {
+left_sum = curr_sum;
+cross_start = i;
+}
+}
+int right_sum=INT_MIN;
+curr_sum=0;
+int cross_end = mid+1;
+for(int i=mid+1; i<end; i++) {
+curr_sum+=nums[i];
+if(curr_sum>= right_sum) {
+right_sum = curr_sum;
+cross_end = i;
+}
+}
+}
+int main()
+{
+int n;
+scanf("%d", &n);
+int nums[n];
+for(int i=0; i<n; i++)
+scanf("%d ", &nums[i]);
+int max_sum, subarray_start, subarray_end;
+int *max_subarray =
+maxSubArraySum(nums, 0, n-1, &max_sum, &subarray_start,
+&subarray_end);
+printf("The sub array [");
+for(int i=subarray_start; i<=subarray_end; i++) {
+if(i==subarray_end)
+printf("%d", nums[i]);
+else
+printf("%d ", nums[i]);
+}
+printf("] has the largest sum %d", max_sum);
+return 0;
+}
+KARATSUBA ALGORITHM
+#include <stdio.h>
+#include <string.h>
+// Function to find the sum of larger
+// numbers represented as a string
+char* findSum(const char* str1, const char* str2)
+,
+// Before proceeding further, make
+// sure length of str2 is larger
+if (strlen(str1) > strlen(str2)) ,
+const char* temp = str1;
+str1 = str2;
+str2 = temp;
+-
+// Stores the result
+static char str*1000+;
+// Calculate length of both strings
+int n1 = strlen(str1);
+int n2 = strlen(str2);
+// Reverse both of strings
+strrev(str1);
+strrev(str2);
+int carry = 0;
+for (int i = 0; i < n1; i++) ,
+// Find the sum of the current
+// digits and carry
+int sum
+= ((str1*i+ - '0')
++ (str2*i+ - '0')
++ carry);
+str*i+ = (sum % 10) + '0';
+// Calculate carry for next step
+carry = sum / 10;
+-
+// Add remaining digits of larger number
+for (int i = n1; i < n2; i++) ,
+int sum = ((str2*i+ - '0') + carry);
+str*i+ = (sum % 10) + '0';
+carry = sum / 10;
+-
+// Add remaining carry
+if (carry)
+str*n2+ = carry + '0';
+else
+str*n2+ = '\0';
+// Reverse resultant string
+strrev(str);
+return str;
+-
+// Function to find difference of larger
+// numbers represented as strings
+char* findDiff(const char* str1, const char* str2)
+,
+// Stores the result of difference
+static char str*1000+;
+// Calculate length of both strings
+int n1 = strlen(str1), n2 = strlen(str2);
+// Reverse both of strings
+strrev(str1);
+strrev(str2);
+int carry = 0;
+// Run loop till small string length
+// and subtract digit of str1 to str2
+for (int i = 0; i < n2; i++) ,
+// Compute difference of the
+// current digits
+int sub
+= ((str1*i+ - '0')
+- (str2*i+ - '0')
+- carry);
+// If subtraction < 0 then add 10
+// into sub and take carry as 1
+if (sub < 0) ,
+sub = sub + 10;
+carry = 1;
+-
+else
+carry = 0;
+str*i+ = sub + '0';
+-
+// Subtract the remaining digits of
+// larger number
+for (int i = n2; i < n1; i++) ,
+int sub = ((str1*i+ - '0') - carry);
+// If the sub value is -ve,
+// then make it positive
+if (sub < 0) ,
+sub = sub + 10;
+carry = 1;
+-
+else
+carry = 0;
+str*i+ = sub + '0';
+-
+// Reverse resultant string
+strrev(str);
+// Return answer
+return str;
+-
+// Function to remove all leading 0s
+// from a given string
+char* removeLeadingZeros(char* str)
+,
+// Index to store the position of
+// the first non-zero digit
+int i, len = strlen(str);
+for (i = 0; i < len - 1; i++) ,
+if (str*i+ != '0')
+break;
+-
+// Shift all non-zero digits to the
+// beginning of the string
+for (int j = 0; j < len - i; j++)
+str*j+ = str*i + j+;
+// Null terminate the string
+str*len - i+ = '\0';
+return str;
+-
+// Function to multiply two numbers
+// using Karatsuba algorithm
+char* multiply(const char* A, const char* B)
+,
+const char* str1 = A;
+const char* str2 = B;
+if (strlen(A) > strlen(B)) ,
+str1 = B;
+str2 = A;
+-
+// Make both numbers to have
+// same digits
+int n1 = strlen(str1), n2 = strlen(str2);
+while (n2 > n1) ,
+n1++;
+-
+// Base case
+if (n1 == 1) ,
+// If the length of strings is 1,
+// then return their product
+int ans = atoi(str1) * atoi(str2);
+sprintf(str1, "%d", ans);
+return str1;
+-
+// Add zeros in the beginning of
+// the strings when length is odd
+if (n1 % 2 == 1) ,
+n1++;
+char temp*1000+;
+strcpy(temp, str1);
+strcpy(str1, "0");
+strcat(str1, temp);
+strcpy(temp, str2);
+strcpy(str2, "0");
+strcat(str2, temp);
+-
+char Al*1000+, Ar*1000+, Bl*1000+, Br*1000+;
+// Find the values of Al, Ar,
+// Bl, and Br.
+for (int i = 0; i < n1 / 2; ++i) ,
+Al*i+ = str1*i+;
+Bl*i+ = str2*i+;
+Ar*i+ = str1*n1 / 2 + i+;
+Br*i+ = str2*n1 / 2 + i+;
+-
+Al*n1 / 2+ = '\0';
+Ar*n1 / 2+ = '\0';
+Bl*n1 / 2+ = '\0';
+Br*n1 / 2+ = '\0';
+// Recursively call the function
+// to compute smaller product
+// Stores the value of Al * Bl
+char* p = multiply(Al, Bl);
+// Stores the value of Ar * Br
+char* q = multiply(Ar, Br);
+// Stores value of ((Al + Ar)*(Bl + Br)
+// - Al*Bl - Ar*Br)
+char* r = findDiff(
+findSum(Al, Ar),
+findSum(Bl, Br));
+// Multiply p by 10^n
+for (int i = 0; i < n1; ++i)
+strcat(p, "0");
+// Multiply s by 10^(n/2)
+for (int i = 0; i < n1 / 2; ++i)
+strcat(r, "0");
+// Calculate final answer p + r + s
+char* ans = findSum(p, findSum(q, r));
+Subset Sum
+#include <stdio.h>
+#include <limits.h>
+#include <stdbool.h>
+bool foundSolution = false;
+int weights[10];
+int solution[10];
+int n;
+int m;
+void subsetSum(int currentSum, int index)
+{
+if(index == n) {
+if(currentSum == m) {
+foundSolution = true;
+for(int i=0; i<n; i++)
+printf("%d ", solution[i]);
+printf("\n");
+}
+return;
+}
+solution[index] = 1;
+subsetSum(currentSum + weights[index], index+1);
+solution[index] = 0;
+subsetSum(currentSum, index + 1);
+}
+int main()
+{
+//int n, m;
+scanf("%d", &n);
+scanf("%d", &m);
+//int weights[n];
+for(int i=0; i<n; i++)
+scanf("%d", &weights[i]);
+subsetSum(0, 0);
+if(!foundSolution)
+printf("No solution found.\n");
+return 0;
+}
+FRACTIONAL KNAPSACK GREEDY APPROACH
+#include <stdio.h>
+#include <stdlib.h>
+// Structure for an item which stores weight and
+// corresponding value of Item
+struct Item ,
+int profit, weight;
+-;
+// Comparison function to sort Item
+// according to profit/weight ratio
+static int cmp(const void* a, const void* b)
+,
+double r1 = (double)((struct Item*)b)->profit / (double)((struct Item*)b)->weight;
+double r2 = (double)((struct Item*)a)->profit / (double)((struct Item*)a)->weight;
+if (r1 > r2) return 1;
+else if (r1 < r2) return -1;
+return 0;
+-
+// Main greedy function to solve problem
+double fractionalKnapsack(int W, struct Item arr*+, int N)
+,
+// Sorting Item on basis of ratio
+qsort(arr, N, sizeof(struct Item), cmp);
+double finalvalue = 0.0;
+// Looping through all items
+for (int i = 0; i < N; i++) ,
+// If adding Item won't overflow,
+// add it completely
+if (arr*i+.weight <= W) ,
+W -= arr*i+.weight;
+finalvalue += arr*i+.profit;
+-
+// If we can't add current Item,
+// add fractional part of it
+else ,
+finalvalue
++= arr*i+.profit
+* ((double)W / (double)arr*i+.weight);
+break;
+-
+-
+// Returning final value
+return finalvalue;
+-
+// Driver code
+int main()
+,
+int W = 50;
+struct Item arr*+ = , , 60, 10 -, , 100, 20 -, , 120, 30 - -;
+int N = sizeof(arr) / sizeof(arr*0+);
+// Function call
+printf("%.2lf\n", fractionalKnapsack(W, arr, N));
+return 0;
+-
+N QUENS
+CODE :
+// C program to solve N Queen Problem using backtracking
+#define N 4
+#include <stdbool.h>
+#include <stdio.h>
+// A utility function to print solution
+void printSolution(int board*N+*N+)
+,
+for (int i = 0; i < N; i++) ,
+for (int j = 0; j < N; j++) ,
+if(board*i+*j+)
+printf("Q ");
+else
+printf(". ");
+-
+printf("\n");
+-
+-
+// A utility function to check if a queen can
+// be placed on board*row+*col+. Note that this
+// function is called when "col" queens are
+// already placed in columns from 0 to col -1.
+// So we need to check only left side for
+// attacking queens
+bool isSafe(int board*N+*N+, int row, int col)
+,
+int i, j;
+// Check this row on left side
+for (i = 0; i < col; i++)
+if (board*row+*i+)
+return false;
+// Check upper diagonal on left side
+for (i = row, j = col; i >= 0 && j >= 0; i--, j--)
+if (board*i+*j+)
+return false;
+// Check lower diagonal on left side
+for (i = row, j = col; j >= 0 && i < N; i++, j--)
+if (board*i+*j+)
+return false;
+return true;
+-
+// A recursive utility function to solve N
+// Queen problem
+bool solveNQUtil(int board*N+*N+, int col)
+,
+// Base case: If all queens are placed
+// then return true
+if (col >= N)
+return true;
+// Consider this column and try placing
+// this queen in all rows one by one
+for (int i = 0; i < N; i++) ,
+// Check if the queen can be placed on
+// board*i+*col+
+if (isSafe(board, i, col)) ,
+// Place this queen in board*i+*col+
+board*i+*col+ = 1;
+// Recur to place rest of the queens
+if (solveNQUtil(board, col + 1))
+return true;
+// If placing queen in board*i+*col+
+// doesn't lead to a solution, then
+// remove queen from board*i+*col+
+board*i+*col+ = 0; // BACKTRACK
+-
+-
+// If the queen cannot be placed in any row in
+// this column col then return false
+return false;
+-
+// This function solves the N Queen problem using
+// Backtracking. It mainly uses solveNQUtil() to
+// solve the problem. It returns false if queens
+// cannot be placed, otherwise, return true and
+// prints placement of queens in the form of 1s.
+// Please note that there may be more than one
+// solutions, this function prints one of the
+// feasible solutions.
+bool solveNQ()
+,
+int board*N+*N+ = , , 0, 0, 0, 0 -,
+, 0, 0, 0, 0 -,
+, 0, 0, 0, 0 -,
+, 0, 0, 0, 0 - -;
+if (solveNQUtil(board, 0) == false) ,
+printf("Solution does not exist");
+return false;
+-
+printSolution(board);
+return true;
+-
+// Driver program to test above function
+int main()
+,
+solveNQ();
+return 0;
+-
+// This code is contributed by Aditya Kumar (adityakumar129)
+RANDOMIZED QUICK SORT
+#include <stdio.h>
+#include <stdlib.h>
+#include <time.h>
+int partition(int arr*+, int low, int high)
+,
+int pivot = arr*low+;
+int i = low - 1, j = high + 1;
+while (1) ,
+do ,
+i++;
+- while (arr*i+ < pivot);
+do ,
+j--;
+- while (arr*j+ > pivot);
+if (i >= j)
+return j;
+int temp = arr*i+;
+arr*i+ = arr*j+;
+arr*j+ = temp;
+-
+-
+int partition_r(int arr*+, int low, int high)
+,
+srand(time(0));
+int random = low + rand() % (high - low);
+int temp = arr*random+;
+arr*random+ = arr*low+;
+arr*low+ = temp;
+return partition(arr, low, high);
+-
+void quickSort(int arr*+, int low, int high)
+,
+if (low < high) ,
+int pi = partition_r(arr, low, high);
+quickSort(arr, low, pi);
+quickSort(arr, pi + 1, high);
+-
+-
+void printArray(int arr*+, int n)
+,
+for (int i = 0; i < n; i++)
+printf("%d ", arr*i+);
+printf("\n");
+-
+int main()
+,
+int arr*+ = , 10, 7, 8, 9, 1, 5 -;
+int n = sizeof(arr) / sizeof(arr*0+);
+quickSort(arr, 0, n - 1);
+printf("Sorted array: \n");
+printArray(arr, n);
+return 0;
+-

mpmc.txt ADDED Viewed

	@@ -0,0 +1,890 @@

+CODES
+OPERATIONS
+org 0000h
+//add
+mov a,#25h
+mov b,#12h
+add a,b
+mov 10h,a
+//sub
+mov a,#25h
+subb a,b
+mov 11h,a
+//mul
+mov a , #25h
+mul ab
+mov 12h,a
+mov 13h,b
+//div
+mov a,#25h
+mov b,#12h
+div ab
+mov 14h,a
+mov 15h,b
+//logical operators
+//AND
+mov a,#25h
+mov b,#12h
+anl a,b
+mov 10h,a
+//OR
+mov a,#25h
+mov b,#12h
+orl a,b
+mov 17h,a
+//XOR
+mov a,#25h
+mov b,#12h
+xrl a,b
+mov 18h,a
+//complement
+cpl a,
+mov 19h,a
+//clear
+clr a
+mov 20h, a
+halt:sjmp halt
+end
+To add following data and then use the simulator to examine the EY flag
+org 0000h
+mov a,#92h
+mov r0,#23h
+add a,r0
+jnc l1
+inc r7
+l1:mov r1,#66h
+add a,r1
+jnc l2
+inc r7
+l2:mov r2,#87h
+add a,r2
+jnc l3
+inc r7
+l3:mov r3,#073h
+add a,r3
+jnc l4
+jnc r7
+l4:
+here:sjmp here
+end
+TO LOAD VALUE INTO R0 R4 THEN PUSH INTO STACK THEN CLEAR AND POP THEM BACK
+org 0000h
+mov r0,#25h
+mov r1,#35h
+mov r2,#45h
+mov r3,#55h
+mov r4,#65h
+push 0
+push 1
+push 2
+push 3
+push 4
+mov r0,#00h
+mov r1,#00h
+mov r2,#00h
+mov r3,#00h
+mov r4,#00h
+pop 0
+pop 1
+pop 2
+pop 3
+pop 4
+end
+CALCULATE CUBE OF A NUMBER
+org 0000h
+mov a,20h
+mov b,a
+mul ab
+mov r0,b
+mov b,20h
+mul ab
+mov 23h,a
+mov r1,b
+mov a,r0
+mov b,20h
+mul ab
+mov 21h,b
+mov b,r1
+add a,b
+mov 22h,a
+mov a,21h
+addc a,#0h
+mov 21h,a
+stop:sjmp stop
+end
+FACTORIAL
+org 0000h
+mov r1,#05h
+mov r7,#01h
+lcall fact
+mov r7,a
+fact:
+mov a,r7
+cjnc r1,#00,up
+sjmp up1
+up:
+mov b,r1
+mul ab
+djnz r1,up
+up1:
+ret
+end
+LARGEST NUMBER IN THE SERIES
+ORG 0000H
+MOV R0,#50H
+MOV A,@R0
+MOV R2,A
+DEC R2
+INC R0
+MOV B,@R0
+INC RO
+BACK:MOV A,@R0
+CJNE A,B,LOOP
+JMP LOOP1
+LOOP: JC LOOP1
+MOV B,A
+LOOP1: INC R0
+DJNZ R2,BACK
+NEXT: MOV 60H,B
+END
+SMALLEST NUMBER
+ORG 0000H
+MOV R0,#50H
+MOV A,@R0
+MOV R2,A
+DEC R2
+INC R0
+MOV B,@R0
+INC RO
+BACK:MOV A,@R0
+CJNE A,B,LOOP
+JMP LOOP1
+LOOP: JNC LOOP1
+MOV B,A
+LOOP1: INC R0
+DJNZ R2,BACK
+NEXT: MOV 60H,B
+END
+VIT UNIVERSITY
+ORG 0000H
+MOV DPTR,#MYDATA
+MOV R0,#40H
+MOV R2,#13H
+BAC:CLR A
+MOVC A,@A+DPTR
+MOV @R0,A
+INC DPTR
+INC R0
+DJNZ R2,BACK
+HERE:SJMP HERE
+ORG 200H
+MY DATA:DB "VIT UNIVERSITY"
+END
+TRANSFERRING STRING ADDRESS STARTING FROM 200H TO RAM LOCATIONS STARTING
+AT 40H AND THEN MOVE TO 60H
+ORG 0000H
+MOV DPTR,#MYDATA
+MOV R0,#40H
+MOV R2,#11H
+MOV R1,#60H
+MOV R3,#11H
+BAC:CLR A
+MOVC A,@A+DPTR
+MOV @R0,A
+INC DPTR
+INC R0
+DJNZ R2,BACK
+MOV R0,#40H
+AGAIN:MOV A,@R0
+MOV @R1,A
+INC R0
+INC R1
+DJNZ R3,AGAIN
+HERE:SJMP HERE
+ORG 200H
+MY DATA:DB "VIT UNIVERSITY"
+END
+CONVERSION OF DATA- TO GET A BYTE OF HEX DATA FROM P1, CONVERT IT TO DECIMAL
+AND THEN TO ASCII. PLACE THE ASCII IN RAM LOCATIONS STARTING AT 40H
+ORG 0000H
+MOV P1,#0FBH
+MOV R0, #40H
+MOV A, P1
+LOOP: MOV B, #10
+DIV AB
+XCH A,B
+ADD A, #30H
+MOV @R0, A
+XCH A,B
+INC R0
+JNZ LOOP
+END
+TRANSFER CONTENT OF P1 TO P2 USING ACCUMULATOR
+mov a, #0ffh ;a=ff hex
+mov p1,a ; make p1 and i/p port
+back: mov a, p1
+mov p2, a
+sjmp back
+end
+GENERATE WAVE FORM HAVING XTAL=11.0592Hz
+ORG 000H
+MOV TMOD,#10H
+AGAIN:MOV TL1,#1AH
+MOV TH1,#0FFH
+SETB TR1
+BACK: JNB TF1,BACK
+CLR TR1
+CPL P1.5
+CLR TF1
+SJMP AGAIN
+END
+TOGGLE ALL BITS OF P1 USING 200 ms WITH CRYSTAL FREQUENCY OF 11.0592Hz
+MOV A,#55H
+AGAIN: MOV P0,A
+MOV P1,A
+MOV P2,A
+MOV P3,A
+ACALL DELAY
+CPL A
+SJMP AGAIN
+DELAY:MOV R5,#2
+HERE1:MOV R4,#180
+HERE2:MOV R3,#255
+HERE3:DJNZ R3,HERE3
+DJNZ R4, HERE2
+DJNZ R5, HERE1
+RET
+TO GET 40% AND 70% DUTY CYCLE USING INTERRUPTS
+ORG 0000H
+BACK:
+SETB P0.1
+SETB P1.1
+LCALL DELAY
+LCALL DELAY
+LCALL DELAY
+LCALL DELAY
+CPL P0.1
+LCALL DELAY
+LCALL DELAY
+LCALL DELAY
+CPL P1.1
+LCALL DELAY
+LCALL DELAY
+LCALL DELAY
+SJMP BACK
+DELAY:
+MOV R0,#01H
+MOV R1,#01H
+A1:MOV R1,A2
+DJNZ R0,A1
+RET
+END
+CREATE A PROGRAM FOR 50 ms on & 50 ms off
+ORG 0000H
+LJMP MAIN
+ORG 000BH
+DJNZ R0,TEN
+MOV R0,#36
+JB P1.1,ONN
+DJNZ R2,TEN
+MOV R2,#0
+SET B P1.1
+CPL P0.1
+SJMP TEN
+ONN: DJNZ R1,TEN
+MOV R1,#5
+CLR P1.1
+CLR P0.1
+TEN:RET I
+ORG 0030H
+MAIN:
+MOV R0,#36
+MOV R1,#5
+MOV R2,#0
+MOV TMOD,#2H
+MOV TH0,#-255
+MOV IE,#82H
+SETB P1.1
+SET B TR0
+BACK:SJMP BACK
+END
+Microprocessor Codes:
+1)CUBE OF A NUMBER
+ORG 0000H
+MOV A,20H
+MOV B,A
+MUL AB
+MOV 21H,A
+MOV 22H,B
+MOV A,20H
+MOV B,21H
+MUL AB
+MOV 23H,A
+MOV 24H,B
+MOV A,20H
+MOV B,22H
+MUL AB
+MOV 25H,A
+MOV 26H,B
+MOV 30H,23H
+MOV A,24H
+MOV A,25H
+MOV 31H,26H
+ADDC A,#0H
+MOV 32H,A
+2)PUSH OR POP
+ORG 0000H
+MOV R0,#25H
+MOV R1,#35H
+MOV R2,#45H
+MOV R3,#55H
+MOV R4,#65H
+PUSH 0
+PUSH 1
+PUSH 2
+PUSH 3
+PUSH 4
+MOV R0,#00H
+MOV R1,#00H
+MOV R2,#00H
+MOV R3,#00H
+MOV R4,#00H
+POP 4
+POP 3
+POP 2
+POP 1
+POP 0
+END
+3)FACTORIAL OF A NUMBER
+ORG 0000H
+MOV R1,#05H
+MOV R7,#01H
+LCALL FACT
+MOV R7,A
+FACT:
+MOV A,R7
+CJNE R1,#00,UP
+SJMP UP1
+UP:
+MOV B,R1
+MUL AB
+DJNZ R1,UP
+UP1:
+RET
+END
+4)FIND THE LARGEST ELEMENT IN A ARRAY
+ORG 0000H
+MOV R0,#50H
+MOV A,@R0
+MOV R2,A
+DEC R2
+INC R0
+MOV B,@R0
+INC R0
+BACK:MOV A,@R0
+CJNE A,B,LOOP
+JMP LOOP1
+LOOP:JC LOOP 1
+MOV B,A
+LOOP1:INC R0
+DJNZ R2,BACK
+NEXT:MOV 60H,B
+END
+5)Copy string from ram 200h to ram 40h
+ORG 0000H
+MOV DPTR,#MYDATA
+MOV R0,#40H
+MOV R2,#13H
+BACK: CLR A
+MOVC A,@A+DPTR
+MOV @R0,A
+INC DPTR
+INC R0
+DJNZ R2,BACK
+HERE :SJMP HERE
+ORG 200H
+MYDATA: DB “VITUNIVERSITY”
+END
+6)COPYING TO LOCATION 60H
+ORG 0000H
+MOV DPTR,#MYDATA
+MOV R0,#40H
+MOV R2,#11H
+MOV R1,#60H
+MOV R3,#11H
+BACK:CLR A
+MOVC A+@A+DPTR
+MOV @R0,A
+INC DPTR
+INC R0
+DJNZ R2,BACK
+MOV R0,#40H
+AGAIN: MOV A,@RO
+MOV @R1,A
+INC R0
+INC R1
+DJNZ R3,AGAIN
+HERE: SJMP HERE
+ORG 200H
+MYDATA:DB “ANYA SOROHI”
+END
+7)EXCHANGE VALUES
+ORG 0000H
+MOV P1,#0FBH
+MOV R0,#40H
+MOV A,P1
+LOOP:MOVB,#10
+DIV AB
+XCH A,B
+ADD A,#30H
+MOV @R0,A
+XCH A,B
+INC R0
+JNZ LOOP
+END
+8)MOV VALUE 55H TO P1,P2,P3 SIMULTANEOUSLY
+ORG 0000H
+MOV A,#55H
+AGAIN:MOV P0,A
+MOV P1,A
+MOV P2,A
+MOV P3,A
+ACALL DELAY
+CPL A
+SJMP AGAIN
+DELAY:MOV R5,#2
+HERE1:MOV R4,#180
+HERE2:MOV R3,#255
+HERE3:DJNZ R3,HERE3
+DJNZ R4,HERE2
+DJNZ R5,HERE1
+RET
+9)250 MICROSECS DELAY USING TIMERS
+ORG 0000H
+MOV TMOD,#10H
+AGAIN: TL1,#1AH
+MOV TH1, #0FFH
+SETB TR1
+BACK:JNB TF1,BACK
+CLR TR1
+CPL P1.5
+CLR TF1
+SJMP AGAIN
+END
+10)MOVING VALUES FROM P1 TO P2
+ORG 0000H
+MOV A,#0FFH
+MOV P1,A
+BACK: MOV A,P1
+MOV P2,A
+SJMP BACK
+END
+11)SERIAL COMMUNICATION- A
+ORG 000H
+SJMP MAIN
+MAIN:MOV TMOD,#20H
+MOV TH1,#-6
+MOV SCON,#50H
+SETB TR1
+AGAIN: MOV SBUF,#”A”
+HERE:JNB TI, HERE
+CLR TI
+SJMP AGAIN
+END
+12)VIT UNIVERSITY
+ORG 0000H
+SJMP MAIN
+MAIN: MOV DPTR,#3000H
+MOV TMOD,#20H
+MOV RO,#0EH
+MOV TH1,#0FDH
+MOV SCON,#50H
+SETB TR1
+UP:CLR A
+MOVC A,@A+DPTR
+AGAIN:MOV SBUF,A
+HERE:JNB T1, HERE
+CLR TI
+INC DPTR
+DJNZ R0,UP
+SJMP $
+ORG 3000H
+DB ‘VIT UNIVERSITY’
+END
+13)
+ORG 0000H
+MOV TMOD,#20H
+MOV SCON, #50H
+SETB TR1
+HERE: JNB RI,HERE
+MOV A,SBUF
+MOV P1,A
+CLR RI
+SJMP HERE
+END
+14) PROGRAM THAT CONTINUOUSLY SENDS 8 BIT DATA FROM
+P0 TO P1 WHILE CREATING A SQUARE WAVE OF 200US PERIOD
+ON PIN P2.1. USE TIMER 0
+ORG 0000H
+LJMP MAIN
+ORG 000BH
+CPL P2.1
+RETI
+ORG 0030H
+MAIN:MOV TMOD,#02H
+MOV P0,#0FFH
+MOV TH0,#-92
+MOV IE,#82H
+SETB TRO
+BACK:MOV A, P0
+MOV P1,A
+SJMP BACK
+END
+15)GENERATE TWO WAVES FOR DUTY CYCLE 40% AND 70%
+USING INTERRUPT
+ORG 0X000
+MOV TMOD,#01H
+MOV TH0,#0FDH
+MOV TH0,#0F0H
+MOV TH1,#0C9H
+MOV TL1,#0C7H
+MOV TCON,#52H
+MOV P1,#00H
+MOV P2,#00H
+SETB ET0
+SETB ET1
+SETB EA
+MAIN: LOOP:
+SJMP MAIN-LOOP
+TIME Q0-ISR
+CLR TF0
+MOV TH0,#0FDH
+MOV TL0,#0FDH
+CPL P1.0
+RETI
+TIME Q1-ISR
+CLR TF1
+MOV TH1,#0C7H
+MOV TL1,#0C7H RETE
+CPL P2.0
+END
+16)WAVEFORM THAT GENERATES (ON-50MS, OFF-80MS)
+ORG 0000H
+LJMP MAIN
+ORG 000BH
+DJNZ R0,TEN
+MOV R0,#36H
+JB P1.1,0HN
+DJNZ R2,TEN
+MOV R2,#8
+SETB P1.1
+CPL P0.1
+SJMP TEN
+CONN:DJNZ R1,TEN
+MOV R1,#5
+CPL P1.1
+CPL P0.1
+TEN RETI
+ORG 0030H
+MAIN:
+MOV R0,#36
+MOV R1,#5
+MOV R2,#8
+MOV TMOD,#24
+MOV THO,#-255
+MOV IE,#82H
+SETB P1.1
+SETB TR0
+BACK:SJMP BACK
+END
+Microprocessor Codes:
+1)CUBE OF A NUMBER
+ORG 0000H
+MOV A,20H
+MOV B,A
+MUL AB
+MOV 21H,A
+MOV 22H,B
+MOV A,20H
+MOV B,21H
+MUL AB
+MOV 23H,A
+MOV 24H,B
+MOV A,20H
+MOV B,22H
+MUL AB
+MOV 25H,A
+MOV 26H,B
+MOV 30H,23H
+MOV A,24H
+MOV A,25H
+MOV 31H,26H
+ADDC A,#0H
+MOV 32H,A
+2)PUSH OR POP
+ORG 0000H
+MOV R0,#25H
+MOV R1,#35H
+MOV R2,#45H
+MOV R3,#55H
+MOV R4,#65H
+PUSH 0
+PUSH 1
+PUSH 2
+PUSH 3
+PUSH 4
+MOV R0,#00H
+MOV R1,#00H
+MOV R2,#00H
+MOV R3,#00H
+MOV R4,#00H
+POP 4
+POP 3
+POP 2
+POP 1
+POP 0
+END
+3)FACTORIAL OF A NUMBER
+ORG 0000H
+MOV R1,#05H
+MOV R7,#01H
+LCALL FACT
+MOV R7,A
+FACT:
+MOV A,R7
+CJNE R1,#00,UP
+SJMP UP1
+UP:
+MOV B,R1
+MUL AB
+DJNZ R1,UP
+UP1:
+RET
+END
+4)FIND THE LARGEST ELEMENT IN A ARRAY
+ORG 0000H
+MOV R0,#50H
+MOV A,@R0
+MOV R2,A
+DEC R2
+INC R0
+MOV B,@R0
+INC R0
+BACK:MOV A,@R0
+CJNE A,B,LOOP
+JMP LOOP1
+LOOP:JC LOOP 1
+MOV B,A
+LOOP1:INC R0
+DJNZ R2,BACK
+NEXT:MOV 60H,B
+END
+5)Copy string from ram 200h to ram 40h
+ORG 0000H
+MOV DPTR,#MYDATA
+MOV R0,#40H
+MOV R2,#13H
+BACK: CLR A
+MOVC A,@A+DPTR
+MOV @R0,A
+INC DPTR
+INC R0
+DJNZ R2,BACK
+HERE :SJMP HERE
+ORG 200H
+MYDATA: DB “VITUNIVERSITY”
+END
+6)COPYING TO LOCATION 60H
+ORG 0000H
+MOV DPTR,#MYDATA
+MOV R0,#40H
+MOV R2,#11H
+MOV R1,#60H
+MOV R3,#11H
+BACK:CLR A
+MOVC A+@A+DPTR
+MOV @R0,A
+INC DPTR
+INC R0
+DJNZ R2,BACK
+MOV R0,#40H
+AGAIN: MOV A,@RO
+MOV @R1,A
+INC R0
+INC R1
+DJNZ R3,AGAIN
+HERE: SJMP HERE
+ORG 200H
+MYDATA:DB “ANYA SOROHI”
+END
+7)EXCHANGE VALUES
+ORG 0000H
+MOV P1,#0FBH
+MOV R0,#40H
+MOV A,P1
+LOOP:MOVB,#10
+DIV AB
+XCH A,B
+ADD A,#30H
+MOV @R0,A
+XCH A,B
+INC R0
+JNZ LOOP
+END
+8)MOV VALUE 55H TO P1,P2,P3 SIMULTANEOUSLY
+ORG 0000H
+MOV A,#55H
+AGAIN:MOV P0,A
+MOV P1,A
+MOV P2,A
+MOV P3,A
+ACALL DELAY
+CPL A
+SJMP AGAIN
+DELAY:MOV R5,#2
+HERE1:MOV R4,#180
+HERE2:MOV R3,#255
+HERE3:DJNZ R3,HERE3
+DJNZ R4,HERE2
+DJNZ R5,HERE1
+RET
+9)250 MICROSECS DELAY USING TIMERS
+ORG 0000H
+MOV TMOD,#10H
+AGAIN: TL1,#1AH
+MOV TH1, #0FFH
+SETB TR1
+BACK:JNB TF1,BACK
+CLR TR1
+CPL P1.5
+CLR TF1
+SJMP AGAIN
+END
+10)MOVING VALUES FROM P1 TO P2
+ORG 0000H
+MOV A,#0FFH
+MOV P1,A
+BACK: MOV A,P1
+MOV P2,A
+SJMP BACK
+END
+11)SERIAL COMMUNICATION- A
+ORG 000H
+SJMP MAIN
+MAIN:MOV TMOD,#20H
+MOV TH1,#-6
+MOV SCON,#50H
+SETB TR1
+AGAIN: MOV SBUF,#”A”
+HERE:JNB TI, HERE
+CLR TI
+SJMP AGAIN
+END
+12)VIT UNIVERSITY
+ORG 0000H
+SJMP MAIN
+MAIN: MOV DPTR,#3000H
+MOV TMOD,#20H
+MOV RO,#0EH
+MOV TH1,#0FDH
+MOV SCON,#50H
+SETB TR1
+UP:CLR A
+MOVC A,@A+DPTR
+AGAIN:MOV SBUF,A
+HERE:JNB T1, HERE
+CLR TI
+INC DPTR
+DJNZ R0,UP
+SJMP $
+ORG 3000H
+DB ‘VIT UNIVERSITY’
+END
+13)
+ORG 0000H
+MOV TMOD,#20H
+MOV SCON, #50H
+SETB TR1
+HERE: JNB RI,HERE
+MOV A,SBUF
+MOV P1,A
+CLR RI
+SJMP HERE
+END
+14) PROGRAM THAT CONTINUOUSLY SENDS 8 BIT DATA FROM
+P0 TO P1 WHILE CREATING A SQUARE WAVE OF 200US PERIOD
+ON PIN P2.1. USE TIMER 0
+ORG 0000H
+LJMP MAIN
+ORG 000BH
+CPL P2.1
+RETI
+ORG 0030H
+MAIN:MOV TMOD,#02H
+MOV P0,#0FFH
+MOV TH0,#-92
+MOV IE,#82H
+SETB TRO
+BACK:MOV A, P0
+MOV P1,A
+SJMP BACK
+END
+15)GENERATE TWO WAVES FOR DUTY CYCLE 40% AND 70%
+USING INTERRUPT
+ORG 0X000
+MOV TMOD,#01H
+MOV TH0,#0FDH
+MOV TH0,#0F0H
+MOV TH1,#0C9H
+MOV TL1,#0C7H
+MOV TCON,#52H
+MOV P1,#00H
+MOV P2,#00H
+SETB ET0
+SETB ET1
+SETB EA
+MAIN: LOOP:
+SJMP MAIN-LOOP
+TIME Q0-ISR
+CLR TF0
+MOV TH0,#0FDH
+MOV TL0,#0FDH
+CPL P1.0
+RETI
+TIME Q1-ISR
+CLR TF1
+MOV TH1,#0C7H
+MOV TL1,#0C7H RETE
+CPL P2.0
+END
+16)WAVEFORM THAT GENERATES (ON-50MS, OFF-80MS)
+ORG 0000H
+LJMP MAIN
+ORG 000BH
+DJNZ R0,TEN
+MOV R0,#36H
+JB P1.1,0HN
+DJNZ R2,TEN
+MOV R2,#8
+SETB P1.1
+CPL P0.1
+SJMP TEN
+CONN:DJNZ R1,TEN
+MOV R1,#5
+CPL P1.1
+CPL P0.1
+TEN RETI
+ORG 0030H
+MAIN:
+MOV R0,#36
+MOV R1,#5
+MOV R2,#8
+MOV TMOD,#24
+MOV THO,#-255
+MOV IE,#82H
+SETB P1.1
+SETB TR0
+BACK:SJMP BACK
+END