fairseq/models/lightconv.py

# Copyright (c) Facebook, Inc. and its affiliates.
#
# This source code is licensed under the MIT license found in the
# LICENSE file in the root directory of this source tree.

import math

import torch
import torch.nn as nn
import torch.nn.functional as F
from fairseq import utils
from fairseq.models import (
    FairseqEncoder,
    FairseqEncoderDecoderModel,
    FairseqIncrementalDecoder,
    register_model,
    register_model_architecture,
)
from fairseq.modules import (
    AdaptiveSoftmax,
    DynamicConv,
    FairseqDropout,
    LayerNorm,
    LightweightConv,
    MultiheadAttention,
    PositionalEmbedding,
)


@register_model("lightconv")
class LightConvModel(FairseqEncoderDecoderModel):
    """
    LightConv and DynamicConv model from `"Pay Less Attention with Lightweight and Dynamic Convolutions" (Wu, et al, 2019)
    <https://openreview.net/pdf?id=SkVhlh09tX>`_.
    To use LightConv please set ``--encoder-conv-type lightweight --decoder-conv-type lightweight``
    To use DynamicConv please set ``--encoder-conv-type dynamic --decoder-conv-type dynamic``

    Args:
        encoder (LightConvEncoder): the encoder
        decoder (LightConvDecoder): the decoder

    The LightConv model provides the following named architectures and
    command-line arguments:

    .. argparse::
        :ref: fairseq.models.lightconv_parser
        :prog:
    """

    @classmethod
    def hub_models(cls):
        # fmt: off

        def moses_subword(path):
            return {
                'path': path,
                'tokenizer': 'moses',
                'bpe': 'subword_nmt',
            }

        return {
            'lightconv.no_glu.iwslt14.de-en': moses_subword('https://dl.fbaipublicfiles.com/fairseq/models/dynamicconv/iwslt14.de-en.lightconv.tar.gz'),
            'dynamicconv.no_glu.iwslt14.de-en': moses_subword('https://dl.fbaipublicfiles.com/fairseq/models/dynamicconv/iwslt14.de-en.dynamicconv.tar.gz'),
            'lightconv.no_glu.wmt16.en-de': moses_subword('https://dl.fbaipublicfiles.com/fairseq/models/dynamicconv/wmt16.en-de.joined-dict.lightconv.tar.gz'),
            'dynamicconv.no_glu.wmt16.en-de': moses_subword('https://dl.fbaipublicfiles.com/fairseq/models/dynamicconv/wmt16.en-de.joined-dict.dynamicconv.tar.gz'),
            'lightconv.glu.wmt16.en-de': moses_subword('https://dl.fbaipublicfiles.com/fairseq/models/dynamicconv/wmt16.en-de.joined-dict.lightconv-glu.tar.gz'),
            'dynamicconv.glu.wmt16.en-de': moses_subword('https://dl.fbaipublicfiles.com/fairseq/models/dynamicconv/wmt16.en-de.joined-dict.dynamicconv-glu.tar.gz'),
            'lightconv.glu.wmt17.en-de': moses_subword('https://dl.fbaipublicfiles.com/fairseq/models/dynamicconv/wmt16.en-de.joined-dict.lightconv-glu.tar.gz'),
            'dynamicconv.glu.wmt17.en-de': moses_subword('https://dl.fbaipublicfiles.com/fairseq/models/dynamicconv/wmt16.en-de.joined-dict.dynamicconv-glu.tar.gz'),
            'lightconv.glu.wmt14.en-fr': moses_subword('https://dl.fbaipublicfiles.com/fairseq/models/dynamicconv/wmt14.en-fr.joined-dict.lightconv-glu.tar.gz'),
            'dynamicconv.glu.wmt14.en-fr': moses_subword('https://dl.fbaipublicfiles.com/fairseq/models/dynamicconv/wmt14.en-fr.joined-dict.dynamicconv-glu.tar.gz'),
            'lightconv.glu.wmt17.zh-en': moses_subword('https://dl.fbaipublicfiles.com/fairseq/models/dynamicconv/wmt17.zh-en.lightconv-glu.tar.gz'),
            'dynamicconv.glu.wmt17.zh-en': moses_subword('https://dl.fbaipublicfiles.com/fairseq/models/dynamicconv/wmt17.zh-en.dynamicconv-glu.tar.gz'),
        }
        # fmt: on

    def __init__(self, encoder, decoder):
        super().__init__(encoder, decoder)

    @staticmethod
    def add_args(parser):
        """Add model-specific arguments to the parser."""
        parser.add_argument(
            "--dropout", type=float, metavar="D", help="dropout probability"
        )
        parser.add_argument(
            "--attention-dropout",
            type=float,
            metavar="D",
            help="dropout probability for attention weights",
        )
        parser.add_argument(
            "--relu-dropout",
            type=float,
            metavar="D",
            help="dropout probability after ReLU in FFN",
        )
        parser.add_argument(
            "--input-dropout",
            type=float,
            metavar="D",
            help="dropout probability of the inputs",
        )
        parser.add_argument(
            "--encoder-embed-path",
            type=str,
            metavar="STR",
            help="path to pre-trained encoder embedding",
        )
        parser.add_argument(
            "--encoder-embed-dim",
            type=int,
            metavar="N",
            help="encoder embedding dimension",
        )
        parser.add_argument(
            "--encoder-conv-dim",
            type=int,
            metavar="N",
            help="encoder embedding dimension",
        )
        parser.add_argument(
            "--encoder-ffn-embed-dim",
            type=int,
            metavar="N",
            help="encoder embedding dimension for FFN",
        )
        parser.add_argument(
            "--encoder-layers", type=int, metavar="N", help="num encoder layers"
        )
        parser.add_argument(
            "--encoder-attention-heads",
            type=int,
            metavar="N",
            help="num encoder attention heads or LightConv/DynamicConv heads",
        )
        parser.add_argument(
            "--encoder-normalize-before",
            action="store_true",
            help="apply layernorm before each encoder block",
        )
        parser.add_argument(
            "--encoder-learned-pos",
            action="store_true",
            help="use learned positional embeddings in the encoder",
        )
        parser.add_argument(
            "--decoder-embed-path",
            type=str,
            metavar="STR",
            help="path to pre-trained decoder embedding",
        )
        parser.add_argument(
            "--decoder-embed-dim",
            type=int,
            metavar="N",
            help="decoder embedding dimension",
        )
        parser.add_argument(
            "--decoder-conv-dim",
            type=int,
            metavar="N",
            help="decoder embedding dimension",
        )
        parser.add_argument(
            "--decoder-ffn-embed-dim",
            type=int,
            metavar="N",
            help="decoder embedding dimension for FFN",
        )
        parser.add_argument(
            "--decoder-layers", type=int, metavar="N", help="num decoder layers"
        )
        parser.add_argument(
            "--decoder-attention-heads",
            type=int,
            metavar="N",
            help="num decoder attention heads or LightConv/DynamicConv heads",
        )
        parser.add_argument(
            "--decoder-learned-pos",
            action="store_true",
            help="use learned positional embeddings in the decoder",
        )
        parser.add_argument(
            "--decoder-normalize-before",
            action="store_true",
            help="apply layernorm before each decoder block",
        )
        parser.add_argument(
            "--share-decoder-input-output-embed",
            action="store_true",
            help="share decoder input and output embeddings",
        )
        parser.add_argument(
            "--share-all-embeddings",
            action="store_true",
            help="share encoder, decoder and output embeddings"
            " (requires shared dictionary and embed dim)",
        )
        parser.add_argument(
            "--adaptive-softmax-cutoff",
            metavar="EXPR",
            help="comma separated list of adaptive softmax cutoff points. "
            "Must be used with adaptive_loss criterion",
        ),
        parser.add_argument(
            "--adaptive-softmax-dropout",
            type=float,
            metavar="D",
            help="sets adaptive softmax dropout for the tail projections",
        )

        """LightConv and DynamicConv arguments"""
        parser.add_argument(
            "--encoder-kernel-size-list",
            type=lambda x: utils.eval_str_list(x, int),
            help='list of kernel size (default: "[3,7,15,31,31,31,31]")',
        )
        parser.add_argument(
            "--decoder-kernel-size-list",
            type=lambda x: utils.eval_str_list(x, int),
            help='list of kernel size (default: "[3,7,15,31,31,31]")',
        )
        parser.add_argument(
            "--encoder-glu", type=utils.eval_bool, help="glu after in proj"
        )
        parser.add_argument(
            "--decoder-glu", type=utils.eval_bool, help="glu after in proj"
        )
        parser.add_argument(
            "--encoder-conv-type",
            default="dynamic",
            type=str,
            choices=["dynamic", "lightweight"],
            help="type of convolution",
        )
        parser.add_argument(
            "--decoder-conv-type",
            default="dynamic",
            type=str,
            choices=["dynamic", "lightweight"],
            help="type of convolution",
        )
        parser.add_argument("--weight-softmax", default=True, type=utils.eval_bool)
        parser.add_argument(
            "--weight-dropout",
            type=float,
            metavar="D",
            help="dropout probability for conv weights",
        )

    @classmethod
    def build_model(cls, args, task):
        """Build a new model instance."""

        # make sure all arguments are present in older models
        base_architecture(args)

        if not hasattr(args, "max_source_positions"):
            args.max_source_positions = 1024
        if not hasattr(args, "max_target_positions"):
            args.max_target_positions = 1024

        src_dict, tgt_dict = task.source_dictionary, task.target_dictionary

        def build_embedding(dictionary, embed_dim, path=None):
            num_embeddings = len(dictionary)
            padding_idx = dictionary.pad()
            emb = Embedding(num_embeddings, embed_dim, padding_idx)
            # if provided, load from preloaded dictionaries
            if path:
                embed_dict = utils.parse_embedding(path)
                utils.load_embedding(embed_dict, dictionary, emb)
            return emb

        if args.share_all_embeddings:
            if src_dict != tgt_dict:
                raise RuntimeError(
                    "--share-all-embeddings requires a joined dictionary"
                )
            if args.encoder_embed_dim != args.decoder_embed_dim:
                raise RuntimeError(
                    "--share-all-embeddings requires --encoder-embed-dim to match --decoder-embed-dim"
                )
            if args.decoder_embed_path and (
                args.decoder_embed_path != args.encoder_embed_path
            ):
                raise RuntimeError(
                    "--share-all-embeddings not compatible with --decoder-embed-path"
                )
            encoder_embed_tokens = build_embedding(
                src_dict, args.encoder_embed_dim, args.encoder_embed_path
            )
            decoder_embed_tokens = encoder_embed_tokens
            args.share_decoder_input_output_embed = True
        else:
            encoder_embed_tokens = build_embedding(
                src_dict, args.encoder_embed_dim, args.encoder_embed_path
            )
            decoder_embed_tokens = build_embedding(
                tgt_dict, args.decoder_embed_dim, args.decoder_embed_path
            )

        encoder = LightConvEncoder(args, src_dict, encoder_embed_tokens)
        decoder = LightConvDecoder(args, tgt_dict, decoder_embed_tokens)
        return LightConvModel(encoder, decoder)


class LightConvEncoder(FairseqEncoder):
    """
    LightConv encoder consisting of *args.encoder_layers* layers. Each layer
    is a :class:`LightConvEncoderLayer`.

    Args:
        args (argparse.Namespace): parsed command-line arguments
        dictionary (~fairseq.data.Dictionary): encoding dictionary
        embed_tokens (torch.nn.Embedding): input embedding
    """

    def __init__(self, args, dictionary, embed_tokens):
        super().__init__(dictionary)
        self.dropout_module = FairseqDropout(
            args.dropout, module_name=self.__class__.__name__
        )

        embed_dim = embed_tokens.embedding_dim
        self.padding_idx = embed_tokens.padding_idx
        self.max_source_positions = args.max_source_positions

        self.embed_tokens = embed_tokens
        self.embed_scale = math.sqrt(embed_dim)
        self.embed_positions = (
            PositionalEmbedding(
                args.max_source_positions,
                embed_dim,
                self.padding_idx,
                learned=args.encoder_learned_pos,
            )
            if not args.no_token_positional_embeddings
            else None
        )

        self.layers = nn.ModuleList([])
        self.layers.extend(
            [
                LightConvEncoderLayer(
                    args, kernel_size=args.encoder_kernel_size_list[i]
                )
                for i in range(args.encoder_layers)
            ]
        )
        self.register_buffer("version", torch.Tensor([2]))
        self.normalize = args.encoder_normalize_before
        if self.normalize:
            self.layer_norm = LayerNorm(embed_dim)

    def forward(self, src_tokens, **unused):
        """
        Args:
            src_tokens (LongTensor): tokens in the source language of shape
                `(batch, src_len)`

        Returns:
            dict:
                - **encoder_out** (Tensor): the last encoder layer's output of
                  shape `(src_len, batch, embed_dim)`
                - **encoder_padding_mask** (ByteTensor): the positions of
                  padding elements of shape `(batch, src_len)`
        """
        # embed tokens and positions
        x = self.embed_scale * self.embed_tokens(src_tokens)
        if self.embed_positions is not None:
            x += self.embed_positions(src_tokens)
        x = self.dropout_module(x)

        # B x T x C -> T x B x C
        x = x.transpose(0, 1)

        # compute padding mask
        encoder_padding_mask = src_tokens.eq(self.padding_idx)
        if not encoder_padding_mask.any():
            encoder_padding_mask = None

        # encoder layers
        for layer in self.layers:
            x = layer(x, encoder_padding_mask)

        if self.normalize:
            x = self.layer_norm(x)

        return {
            "encoder_out": x,  # T x B x C
            "encoder_padding_mask": encoder_padding_mask,  # B x T
        }

    def reorder_encoder_out(self, encoder_out, new_order):
        """
        Reorder encoder output according to *new_order*.

        Args:
            encoder_out: output from the ``forward()`` method
            new_order (LongTensor): desired order

        Returns:
            *encoder_out* rearranged according to *new_order*
        """
        if encoder_out["encoder_out"] is not None:
            encoder_out["encoder_out"] = encoder_out["encoder_out"].index_select(
                1, new_order
            )
        if encoder_out["encoder_padding_mask"] is not None:
            encoder_out["encoder_padding_mask"] = encoder_out[
                "encoder_padding_mask"
            ].index_select(0, new_order)
        return encoder_out

    def max_positions(self):
        """Maximum input length supported by the encoder."""
        if self.embed_positions is None:
            return self.max_source_positions
        return min(self.max_source_positions, self.embed_positions.max_positions)


class LightConvDecoder(FairseqIncrementalDecoder):
    """
    LightConv decoder consisting of *args.decoder_layers* layers. Each layer
    is a :class:`LightConvDecoderLayer`.

    Args:
        args (argparse.Namespace): parsed command-line arguments
        dictionary (~fairseq.data.Dictionary): decoding dictionary
        embed_tokens (torch.nn.Embedding): output embedding
        no_encoder_attn (bool, optional): whether to attend to encoder outputs.
            Default: ``False``
    """

    def __init__(
        self, args, dictionary, embed_tokens, no_encoder_attn=False, final_norm=True
    ):
        super().__init__(dictionary)
        self.dropout_module = FairseqDropout(
            args.dropout, module_name=self.__class__.__name__
        )
        self.share_input_output_embed = args.share_decoder_input_output_embed

        input_embed_dim = embed_tokens.embedding_dim
        embed_dim = args.decoder_embed_dim
        output_embed_dim = args.decoder_output_dim

        padding_idx = embed_tokens.padding_idx
        self.max_target_positions = args.max_target_positions

        self.embed_tokens = embed_tokens
        self.embed_scale = math.sqrt(embed_dim)  # todo: try with input_embed_dim

        self.project_in_dim = (
            Linear(input_embed_dim, embed_dim, bias=False)
            if embed_dim != input_embed_dim
            else None
        )

        self.embed_positions = (
            PositionalEmbedding(
                args.max_target_positions,
                embed_dim,
                padding_idx,
                learned=args.decoder_learned_pos,
            )
            if not args.no_token_positional_embeddings
            else None
        )

        self.layers = nn.ModuleList([])
        self.layers.extend(
            [
                LightConvDecoderLayer(
                    args, no_encoder_attn, kernel_size=args.decoder_kernel_size_list[i]
                )
                for i in range(args.decoder_layers)
            ]
        )

        self.adaptive_softmax = None

        self.project_out_dim = (
            Linear(embed_dim, output_embed_dim, bias=False)
            if embed_dim != output_embed_dim and not args.tie_adaptive_weights
            else None
        )

        if args.adaptive_softmax_cutoff is not None:
            self.adaptive_softmax = AdaptiveSoftmax(
                len(dictionary),
                output_embed_dim,
                utils.eval_str_list(args.adaptive_softmax_cutoff, type=int),
                dropout=args.adaptive_softmax_dropout,
                adaptive_inputs=embed_tokens if args.tie_adaptive_weights else None,
                factor=args.adaptive_softmax_factor,
                tie_proj=args.tie_adaptive_proj,
            )
        elif not self.share_input_output_embed:
            self.embed_out = nn.Parameter(
                torch.Tensor(len(dictionary), output_embed_dim)
            )
            nn.init.normal_(self.embed_out, mean=0, std=output_embed_dim ** -0.5)
        self.register_buffer("version", torch.Tensor([2]))
        self.normalize = args.decoder_normalize_before and final_norm
        if self.normalize:
            self.layer_norm = LayerNorm(embed_dim)

    def forward(
        self, prev_output_tokens, encoder_out=None, incremental_state=None, **kwargs
    ):
        """
        Args:
            prev_output_tokens (LongTensor): previous decoder outputs of shape
                `(batch, tgt_len)`, for teacher forcing
            encoder_out (Tensor, optional): output from the encoder, used for
                encoder-side attention
            incremental_state (dict): dictionary used for storing state during
                :ref:`Incremental decoding`

        Returns:
            tuple:
                - the last decoder layer's output of shape `(batch, tgt_len,
                  vocab)`
                - the last decoder layer's attention weights of shape `(batch,
                  tgt_len, src_len)`
        """
        # embed positions
        positions = (
            self.embed_positions(
                prev_output_tokens,
                incremental_state=incremental_state,
            )
            if self.embed_positions is not None
            else None
        )

        if incremental_state is not None:
            prev_output_tokens = prev_output_tokens[:, -1:]
            if positions is not None:
                positions = positions[:, -1:]

        # embed tokens and positions
        x = self.embed_scale * self.embed_tokens(prev_output_tokens)

        if self.project_in_dim is not None:
            x = self.project_in_dim(x)

        if positions is not None:
            x += positions
        x = self.dropout_module(x)

        # B x T x C -> T x B x C
        x = x.transpose(0, 1)
        attn = None

        inner_states = [x]

        # decoder layers
        for layer in self.layers:
            x, attn = layer(
                x,
                encoder_out["encoder_out"] if encoder_out is not None else None,
                encoder_out["encoder_padding_mask"]
                if encoder_out is not None
                else None,
                incremental_state,
            )
            inner_states.append(x)

        if self.normalize:
            x = self.layer_norm(x)

        # T x B x C -> B x T x C
        x = x.transpose(0, 1)

        if self.project_out_dim is not None:
            x = self.project_out_dim(x)

        if self.adaptive_softmax is None:
            # project back to size of vocabulary
            if self.share_input_output_embed:
                x = F.linear(x, self.embed_tokens.weight)
            else:
                x = F.linear(x, self.embed_out)

        return x, {"attn": attn, "inner_states": inner_states}

    def max_positions(self):
        """Maximum output length supported by the decoder."""
        if self.embed_positions is None:
            return self.max_target_positions
        return min(self.max_target_positions, self.embed_positions.max_positions)

    def buffered_future_mask(self, tensor):
        dim = tensor.size(0)
        if (
            not hasattr(self, "_future_mask")
            or self._future_mask is None
            or self._future_mask.device != tensor.device
        ):
            self._future_mask = torch.triu(
                utils.fill_with_neg_inf(tensor.new(dim, dim)), 1
            )
        if self._future_mask.size(0) < dim:
            self._future_mask = torch.triu(
                utils.fill_with_neg_inf(self._future_mask.resize_(dim, dim)), 1
            )
        return self._future_mask[:dim, :dim]


class LightConvEncoderLayer(nn.Module):
    """Encoder layer block.

    Args:
        args (argparse.Namespace): parsed command-line arguments
        kernel_size: kernel size of the convolution
    """

    def __init__(self, args, kernel_size=0):
        super().__init__()
        self.embed_dim = args.encoder_embed_dim
        self.conv_dim = args.encoder_conv_dim
        padding_l = (
            kernel_size // 2
            if kernel_size % 2 == 1
            else ((kernel_size - 1) // 2, kernel_size // 2)
        )

        if args.encoder_glu:
            self.linear1 = Linear(self.embed_dim, 2 * self.conv_dim)
            self.act = nn.GLU()
        else:
            self.linear1 = Linear(self.embed_dim, self.conv_dim)
            self.act = None
        if args.encoder_conv_type == "lightweight":
            self.conv = LightweightConv(
                self.conv_dim,
                kernel_size,
                padding_l=padding_l,
                weight_softmax=args.weight_softmax,
                num_heads=args.encoder_attention_heads,
                weight_dropout=args.weight_dropout,
            )
        elif args.encoder_conv_type == "dynamic":
            self.conv = DynamicConv(
                self.conv_dim,
                kernel_size,
                padding_l=padding_l,
                weight_softmax=args.weight_softmax,
                num_heads=args.encoder_attention_heads,
                weight_dropout=args.weight_dropout,
            )
        else:
            raise NotImplementedError
        self.linear2 = Linear(self.conv_dim, self.embed_dim)

        self.dropout_module = FairseqDropout(
            args.dropout, module_name=self.__class__.__name__
        )
        self.relu_dropout_module = FairseqDropout(
            args.relu_dropout, module_name=self.__class__.__name__
        )
        self.input_dropout_module = FairseqDropout(
            args.input_dropout, module_name=self.__class__.__name__
        )
        self.normalize_before = args.encoder_normalize_before
        self.fc1 = Linear(self.embed_dim, args.encoder_ffn_embed_dim)
        self.fc2 = Linear(args.encoder_ffn_embed_dim, self.embed_dim)
        self.layer_norms = nn.ModuleList([LayerNorm(self.embed_dim) for _ in range(2)])

    def forward(self, x, encoder_padding_mask):
        """
        Args:
            x (Tensor): input to the layer of shape `(seq_len, batch, embed_dim)`
            encoder_padding_mask (ByteTensor): binary ByteTensor of shape
                `(batch, src_len)` where padding elements are indicated by ``1``.

        Returns:
            encoded output of shape `(batch, src_len, embed_dim)`
        """
        residual = x
        x = self.maybe_layer_norm(0, x, before=True)
        x = self.input_dropout_module(x)
        x = self.linear1(x)
        if self.act is not None:
            x = self.act(x)
        if encoder_padding_mask is not None:
            x = x.masked_fill(encoder_padding_mask.transpose(0, 1).unsqueeze(2), 0)
        x = self.conv(x)
        x = self.linear2(x)
        x = self.dropout_module(x)
        x = residual + x
        x = self.maybe_layer_norm(0, x, after=True)

        residual = x
        x = self.maybe_layer_norm(1, x, before=True)
        x = F.relu(self.fc1(x))
        x = self.relu_dropout_module(x)
        x = self.fc2(x)
        x = self.dropout_module(x)
        x = residual + x
        x = self.maybe_layer_norm(1, x, after=True)
        return x

    def maybe_layer_norm(self, i, x, before=False, after=False):
        assert before ^ after
        if after ^ self.normalize_before:
            return self.layer_norms[i](x)
        else:
            return x

    def extra_repr(self):
        return (
            "dropout={}, relu_dropout={}, input_dropout={}, normalize_before={}".format(
                self.dropout_module.p,
                self.relu_dropout_module.p,
                self.input_dropout_module.p,
                self.normalize_before,
            )
        )


class LightConvDecoderLayer(nn.Module):
    """Decoder layer block.

    Args:
        args (argparse.Namespace): parsed command-line arguments
        no_encoder_attn (bool, optional): whether to attend to encoder outputs.
            Default: ``False``
        kernel_size: kernel size of the convolution
    """

    def __init__(self, args, no_encoder_attn=False, kernel_size=0):
        super().__init__()
        self.embed_dim = args.decoder_embed_dim
        self.conv_dim = args.decoder_conv_dim
        if args.decoder_glu:
            self.linear1 = Linear(self.embed_dim, 2 * self.conv_dim)
            self.act = nn.GLU()
        else:
            self.linear1 = Linear(self.embed_dim, self.conv_dim)
            self.act = None
        if args.decoder_conv_type == "lightweight":
            self.conv = LightweightConv(
                self.conv_dim,
                kernel_size,
                padding_l=kernel_size - 1,
                weight_softmax=args.weight_softmax,
                num_heads=args.decoder_attention_heads,
                weight_dropout=args.weight_dropout,
            )
        elif args.decoder_conv_type == "dynamic":
            self.conv = DynamicConv(
                self.conv_dim,
                kernel_size,
                padding_l=kernel_size - 1,
                weight_softmax=args.weight_softmax,
                num_heads=args.decoder_attention_heads,
                weight_dropout=args.weight_dropout,
            )
        else:
            raise NotImplementedError
        self.linear2 = Linear(self.conv_dim, self.embed_dim)

        self.dropout_module = FairseqDropout(
            args.dropout, module_name=self.__class__.__name__
        )
        self.relu_dropout_module = FairseqDropout(
            args.relu_dropout, module_name=self.__class__.__name__
        )
        self.input_dropout_module = FairseqDropout(
            args.input_dropout, module_name=self.__class__.__name__
        )
        self.normalize_before = args.decoder_normalize_before

        self.conv_layer_norm = LayerNorm(self.embed_dim)

        if no_encoder_attn:
            self.encoder_attn = None
            self.encoder_attn_layer_norm = None
        else:
            self.encoder_attn = MultiheadAttention(
                self.embed_dim,
                args.decoder_attention_heads,
                dropout=args.attention_dropout,
                encoder_decoder_attention=True,
            )
            self.encoder_attn_layer_norm = LayerNorm(self.embed_dim)

        self.fc1 = Linear(self.embed_dim, args.decoder_ffn_embed_dim)
        self.fc2 = Linear(args.decoder_ffn_embed_dim, self.embed_dim)

        self.final_layer_norm = LayerNorm(self.embed_dim)
        self.need_attn = True

    def forward(
        self,
        x,
        encoder_out,
        encoder_padding_mask,
        incremental_state,
        prev_conv_state=None,
        prev_attn_state=None,
        conv_mask=None,
        conv_padding_mask=None,
    ):
        """
        Args:
            x (Tensor): input to the layer of shape `(seq_len, batch, embed_dim)`
            encoder_padding_mask (ByteTensor): binary ByteTensor of shape
                `(batch, src_len)` where padding elements are indicated by ``1``.

        Returns:
            encoded output of shape `(batch, src_len, embed_dim)`
        """
        residual = x
        x = self.maybe_layer_norm(self.conv_layer_norm, x, before=True)
        if prev_conv_state is not None:
            if incremental_state is None:
                incremental_state = {}
            self.conv._set_input_buffer(incremental_state, prev_conv_state)
        x = self.input_dropout_module(x)
        x = self.linear1(x)
        if self.act is not None:
            x = self.act(x)
        x = self.conv(x, incremental_state=incremental_state)
        x = self.linear2(x)
        x = self.dropout_module(x)
        x = residual + x
        x = self.maybe_layer_norm(self.conv_layer_norm, x, after=True)

        attn = None
        if self.encoder_attn is not None:
            residual = x
            x = self.maybe_layer_norm(self.encoder_attn_layer_norm, x, before=True)
            if prev_attn_state is not None:
                if incremental_state is None:
                    incremental_state = {}
                prev_key, prev_value = prev_attn_state
                saved_state = {"prev_key": prev_key, "prev_value": prev_value}
                self.encoder_attn._set_input_buffer(incremental_state, saved_state)
            x, attn = self.encoder_attn(
                query=x,
                key=encoder_out,
                value=encoder_out,
                key_padding_mask=encoder_padding_mask,
                incremental_state=incremental_state,
                static_kv=True,
                need_weights=(not self.training and self.need_attn),
            )
            x = self.dropout_module(x)
            x = residual + x
            x = self.maybe_layer_norm(self.encoder_attn_layer_norm, x, after=True)

        residual = x
        x = self.maybe_layer_norm(self.final_layer_norm, x, before=True)
        x = F.relu(self.fc1(x))
        x = self.relu_dropout_module(x)
        x = self.fc2(x)
        x = self.dropout_module(x)
        x = residual + x
        x = self.maybe_layer_norm(self.final_layer_norm, x, after=True)
        return x, attn

    def maybe_layer_norm(self, layer_norm, x, before=False, after=False):
        assert before ^ after
        if after ^ self.normalize_before:
            return layer_norm(x)
        else:
            return x

    def make_generation_fast_(self, need_attn=False, **kwargs):
        self.need_attn = need_attn

    def extra_repr(self):
        return (
            "dropout={}, relu_dropout={}, input_dropout={}, normalize_before={}".format(
                self.dropout_module.p,
                self.relu_dropout_module.p,
                self.input_dropout_module.p,
                self.normalize_before,
            )
        )


def Embedding(num_embeddings, embedding_dim, padding_idx):
    m = nn.Embedding(num_embeddings, embedding_dim, padding_idx=padding_idx)
    nn.init.normal_(m.weight, mean=0, std=embedding_dim ** -0.5)
    nn.init.constant_(m.weight[padding_idx], 0)
    return m


def Linear(in_features, out_features, bias=True):
    m = nn.Linear(in_features, out_features, bias)
    nn.init.xavier_uniform_(m.weight)
    if bias:
        nn.init.constant_(m.bias, 0.0)
    return m


@register_model_architecture("lightconv", "lightconv")
def base_architecture(args):
    args.encoder_embed_path = getattr(args, "encoder_embed_path", None)
    args.encoder_embed_dim = getattr(args, "encoder_embed_dim", 512)
    args.encoder_ffn_embed_dim = getattr(args, "encoder_ffn_embed_dim", 2048)
    args.encoder_layers = getattr(args, "encoder_layers", 7)
    args.encoder_attention_heads = getattr(args, "encoder_attention_heads", 8)
    args.encoder_normalize_before = getattr(args, "encoder_normalize_before", False)
    args.encoder_learned_pos = getattr(args, "encoder_learned_pos", False)
    args.decoder_embed_path = getattr(args, "decoder_embed_path", None)
    args.decoder_embed_dim = getattr(args, "decoder_embed_dim", args.encoder_embed_dim)
    args.decoder_ffn_embed_dim = getattr(
        args, "decoder_ffn_embed_dim", args.encoder_ffn_embed_dim
    )
    args.decoder_layers = getattr(args, "decoder_layers", 6)
    args.decoder_attention_heads = getattr(args, "decoder_attention_heads", 8)
    args.decoder_normalize_before = getattr(args, "decoder_normalize_before", False)
    args.decoder_learned_pos = getattr(args, "decoder_learned_pos", False)
    args.attention_dropout = getattr(args, "attention_dropout", 0.0)
    args.relu_dropout = getattr(args, "relu_dropout", 0.0)
    args.dropout = getattr(args, "dropout", 0.1)
    args.adaptive_softmax_cutoff = getattr(args, "adaptive_softmax_cutoff", None)
    args.adaptive_softmax_dropout = getattr(args, "adaptive_softmax_dropout", 0)
    args.share_decoder_input_output_embed = getattr(
        args, "share_decoder_input_output_embed", False
    )
    args.share_all_embeddings = getattr(args, "share_all_embeddings", False)
    args.no_token_positional_embeddings = getattr(
        args, "no_token_positional_embeddings", False
    )

    args.decoder_output_dim = getattr(
        args, "decoder_output_dim", args.decoder_embed_dim
    )
    args.decoder_input_dim = getattr(args, "decoder_input_dim", args.decoder_embed_dim)

    args.encoder_conv_dim = getattr(args, "encoder_conv_dim", args.encoder_embed_dim)
    args.decoder_conv_dim = getattr(args, "decoder_conv_dim", args.decoder_embed_dim)

    args.encoder_kernel_size_list = getattr(
        args, "encoder_kernel_size_list", [3, 7, 15, 31, 31, 31, 31]
    )
    args.decoder_kernel_size_list = getattr(
        args, "decoder_kernel_size_list", [3, 7, 15, 31, 31, 31]
    )
    if len(args.encoder_kernel_size_list) == 1:
        args.encoder_kernel_size_list = (
            args.encoder_kernel_size_list * args.encoder_layers
        )
    if len(args.decoder_kernel_size_list) == 1:
        args.decoder_kernel_size_list = (
            args.decoder_kernel_size_list * args.decoder_layers
        )
    assert (
        len(args.encoder_kernel_size_list) == args.encoder_layers
    ), "encoder_kernel_size_list doesn't match encoder_layers"
    assert (
        len(args.decoder_kernel_size_list) == args.decoder_layers
    ), "decoder_kernel_size_list doesn't match decoder_layers"
    args.encoder_glu = getattr(args, "encoder_glu", True)
    args.decoder_glu = getattr(args, "decoder_glu", True)
    args.input_dropout = getattr(args, "input_dropout", 0.1)
    args.weight_dropout = getattr(args, "weight_dropout", args.attention_dropout)


@register_model_architecture("lightconv", "lightconv_iwslt_de_en")
def lightconv_iwslt_de_en(args):
    args.encoder_embed_dim = getattr(args, "encoder_embed_dim", 512)
    args.encoder_ffn_embed_dim = getattr(args, "encoder_ffn_embed_dim", 1024)
    args.encoder_attention_heads = getattr(args, "encoder_attention_heads", 4)
    args.encoder_layers = getattr(args, "encoder_layers", 7)
    args.decoder_embed_dim = getattr(args, "decoder_embed_dim", 512)
    args.decoder_ffn_embed_dim = getattr(args, "decoder_ffn_embed_dim", 1024)
    args.decoder_attention_heads = getattr(args, "decoder_attention_heads", 4)
    args.decoder_layers = getattr(args, "decoder_layers", 6)
    args.attention_dropout = getattr(args, "attention_dropout", 0.1)
    args.weight_dropout = getattr(args, "weight_dropout", 0.1)
    args.encoder_glu = getattr(args, "encoder_glu", False)
    args.decoder_glu = getattr(args, "decoder_glu", False)
    args.input_dropout = getattr(args, "input_dropout", 0.0)
    base_architecture(args)


@register_model_architecture("lightconv", "lightconv_wmt_en_de")
def lightconv_wmt_en_de(args):
    base_architecture(args)


@register_model_architecture("lightconv", "lightconv_wmt_en_de_big")
def lightconv_wmt_en_de_big(args):
    args.attention_dropout = getattr(args, "attention_dropout", 0.1)
    args.encoder_embed_dim = getattr(args, "encoder_embed_dim", 1024)
    args.encoder_ffn_embed_dim = getattr(args, "encoder_ffn_embed_dim", 4096)
    args.encoder_attention_heads = getattr(args, "encoder_attention_heads", 16)
    args.encoder_normalize_before = getattr(args, "encoder_normalize_before", False)
    args.decoder_embed_dim = getattr(args, "decoder_embed_dim", 1024)
    args.decoder_ffn_embed_dim = getattr(args, "decoder_ffn_embed_dim", 4096)
    args.decoder_attention_heads = getattr(args, "decoder_attention_heads", 16)
    args.dropout = getattr(args, "dropout", 0.3)
    base_architecture(args)


@register_model_architecture("lightconv", "lightconv_wmt_en_fr_big")
def lightconv_wmt_en_fr_big(args):
    args.dropout = getattr(args, "dropout", 0.1)
    lightconv_wmt_en_de_big(args)


@register_model_architecture("lightconv", "lightconv_wmt_zh_en_big")
def lightconv_wmt_zh_en_big(args):
    args.dropout = getattr(args, "dropout", 0.2)
    args.attention_dropout = getattr(args, "attention_dropout", 0.2)
    args.weight_dropout = getattr(args, "weight_dropout", 0.2)
    lightconv_wmt_en_de_big(args)