# Copyright (c) 2021 PaddlePaddle Authors. All Rights Reserved. # Copyright 2019 Mobvoi Inc. All Rights Reserved. # # Licensed under the Apache License, Version 2.0 (the "License"); # you may not use this file except in compliance with the License. # You may obtain a copy of the License at # # http://www.apache.org/licenses/LICENSE-2.0 # # Unless required by applicable law or agreed to in writing, software # distributed under the License is distributed on an "AS IS" BASIS, # WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied. # See the License for the specific language governing permissions and # limitations under the License. # Modified from wenet(https://github.com/wenet-e2e/wenet) """Encoder self-attention layer definition.""" from typing import Optional from typing import Tuple import paddle from paddle import nn from paddlespeech.s2t.utils.log import Log logger = Log(__name__).getlog() __all__ = ["TransformerEncoderLayer", "ConformerEncoderLayer"] class TransformerEncoderLayer(nn.Layer): """Encoder layer module.""" def __init__( self, size: int, self_attn: nn.Layer, feed_forward: nn.Layer, dropout_rate: float, normalize_before: bool=True, concat_after: bool=False, ): """Construct an EncoderLayer object. Args: size (int): Input dimension. self_attn (nn.Layer): Self-attention module instance. `MultiHeadedAttention` or `RelPositionMultiHeadedAttention` instance can be used as the argument. feed_forward (nn.Layer): Feed-forward module instance. `PositionwiseFeedForward`, instance can be used as the argument. dropout_rate (float): Dropout rate. normalize_before (bool): True: use layer_norm before each sub-block. False: to use layer_norm after each sub-block. concat_after (bool): Whether to concat attention layer's input and output. True: x -> x + linear(concat(x, att(x))) False: x -> x + att(x) """ super().__init__() self.self_attn = self_attn self.feed_forward = feed_forward self.norm1 = nn.LayerNorm(size, epsilon=1e-12) self.norm2 = nn.LayerNorm(size, epsilon=1e-12) self.dropout = nn.Dropout(dropout_rate) self.size = size self.normalize_before = normalize_before self.concat_after = concat_after # concat_linear may be not used in forward fuction, # but will be saved in the *.pt self.concat_linear = nn.Linear(size + size, size) def forward( self, x: paddle.Tensor, mask: paddle.Tensor, pos_emb: Optional[paddle.Tensor]=None, mask_pad: Optional[paddle.Tensor]=None, output_cache: Optional[paddle.Tensor]=None, cnn_cache: Optional[paddle.Tensor]=None, ) -> Tuple[paddle.Tensor, paddle.Tensor, paddle.Tensor]: """Compute encoded features. Args: x (paddle.Tensor): Input tensor (#batch, time, size). mask (paddle.Tensor): Mask tensor for the input (#batch, time). pos_emb (paddle.Tensor): just for interface compatibility to ConformerEncoderLayer mask_pad (paddle.Tensor): not used here, it's for interface compatibility to ConformerEncoderLayer output_cache (paddle.Tensor): Cache tensor of the output (#batch, time2, size), time2 < time in x. cnn_cache (paddle.Tensor): not used here, it's for interface compatibility to ConformerEncoderLayer Returns: paddle.Tensor: Output tensor (#batch, time, size). paddle.Tensor: Mask tensor (#batch, time). paddle.Tensor: Fake cnn cache tensor for api compatibility with Conformer (#batch, channels, time'). """ residual = x if self.normalize_before: x = self.norm1(x) if output_cache is None: x_q = x else: assert output_cache.shape[0] == x.shape[0] assert output_cache.shape[1] < x.shape[1] assert output_cache.shape[2] == self.size chunk = x.shape[1] - output_cache.shape[1] x_q = x[:, -chunk:, :] residual = residual[:, -chunk:, :] mask = mask[:, -chunk:, :] if self.concat_after: x_concat = paddle.concat( (x, self.self_attn(x_q, x, x, mask)), axis=-1) x = residual + self.concat_linear(x_concat) else: x = residual + self.dropout(self.self_attn(x_q, x, x, mask)) if not self.normalize_before: x = self.norm1(x) residual = x if self.normalize_before: x = self.norm2(x) x = residual + self.dropout(self.feed_forward(x)) if not self.normalize_before: x = self.norm2(x) if output_cache is not None: x = paddle.concat([output_cache, x], axis=1) fake_cnn_cache = paddle.zeros([1], dtype=x.dtype) return x, mask, fake_cnn_cache class ConformerEncoderLayer(nn.Layer): """Encoder layer module.""" def __init__( self, size: int, self_attn: nn.Layer, feed_forward: Optional[nn.Layer]=None, feed_forward_macaron: Optional[nn.Layer]=None, conv_module: Optional[nn.Layer]=None, dropout_rate: float=0.1, normalize_before: bool=True, concat_after: bool=False, ): """Construct an EncoderLayer object. Args: size (int): Input dimension. self_attn (nn.Layer): Self-attention module instance. `MultiHeadedAttention` or `RelPositionMultiHeadedAttention` instance can be used as the argument. feed_forward (nn.Layer): Feed-forward module instance. `PositionwiseFeedForward` instance can be used as the argument. feed_forward_macaron (nn.Layer): Additional feed-forward module instance. `PositionwiseFeedForward` instance can be used as the argument. conv_module (nn.Layer): Convolution module instance. `ConvlutionModule` instance can be used as the argument. dropout_rate (float): Dropout rate. normalize_before (bool): True: use layer_norm before each sub-block. False: use layer_norm after each sub-block. concat_after (bool): Whether to concat attention layer's input and output. True: x -> x + linear(concat(x, att(x))) False: x -> x + att(x) """ super().__init__() self.self_attn = self_attn self.feed_forward = feed_forward self.feed_forward_macaron = feed_forward_macaron self.conv_module = conv_module self.norm_ff = nn.LayerNorm( size, epsilon=1e-12, weight_attr=paddle.ParamAttr( initializer=nn.initializer.Constant(1.0)), bias_attr=paddle.ParamAttr( initializer=nn.initializer.Constant(0.0))) # for the FNN module self.norm_mha = nn.LayerNorm( size, epsilon=1e-12, weight_attr=paddle.ParamAttr( initializer=nn.initializer.Constant(1.0)), bias_attr=paddle.ParamAttr( initializer=nn.initializer.Constant(0.0))) # for the MHA module if feed_forward_macaron is not None: self.norm_ff_macaron = nn.LayerNorm( size, epsilon=1e-12, weight_attr=paddle.ParamAttr( initializer=nn.initializer.Constant(1.0)), bias_attr=paddle.ParamAttr( initializer=nn.initializer.Constant(0.0))) self.ff_scale = 0.5 else: self.ff_scale = 1.0 if self.conv_module is not None: self.norm_conv = nn.LayerNorm( size, epsilon=1e-12, weight_attr=paddle.ParamAttr( initializer=nn.initializer.Constant(1.0)), bias_attr=paddle.ParamAttr(initializer=nn.initializer.Constant( 0.0))) # for the CNN module self.norm_final = nn.LayerNorm( size, epsilon=1e-12, weight_attr=paddle.ParamAttr( initializer=nn.initializer.Constant(1.0)), bias_attr=paddle.ParamAttr(initializer=nn.initializer.Constant( 0.0))) # for the final output of the block self.dropout = nn.Dropout(dropout_rate) self.size = size self.normalize_before = normalize_before self.concat_after = concat_after self.concat_linear = nn.Linear(size + size, size) def forward( self, x: paddle.Tensor, mask: paddle.Tensor, pos_emb: paddle.Tensor, mask_pad: Optional[paddle.Tensor]=None, output_cache: Optional[paddle.Tensor]=None, cnn_cache: Optional[paddle.Tensor]=None, ) -> Tuple[paddle.Tensor, paddle.Tensor, paddle.Tensor]: """Compute encoded features. Args: x (paddle.Tensor): (#batch, time, size) mask (paddle.Tensor): Mask tensor for the input (#batch, timeļ¼Œtime). pos_emb (paddle.Tensor): positional encoding, must not be None for ConformerEncoderLayer. mask_pad (paddle.Tensor): batch padding mask used for conv module, (B, 1, T). output_cache (paddle.Tensor): Cache tensor of the encoder output (#batch, time2, size), time2 < time in x. cnn_cache (paddle.Tensor): Convolution cache in conformer layer Returns: paddle.Tensor: Output tensor (#batch, time, size). paddle.Tensor: Mask tensor (#batch, time). paddle.Tensor: New cnn cache tensor (#batch, channels, time'). """ # whether to use macaron style FFN if self.feed_forward_macaron is not None: residual = x if self.normalize_before: x = self.norm_ff_macaron(x) x = residual + self.ff_scale * self.dropout( self.feed_forward_macaron(x)) if not self.normalize_before: x = self.norm_ff_macaron(x) # multi-headed self-attention module residual = x if self.normalize_before: x = self.norm_mha(x) if output_cache is None: x_q = x else: assert output_cache.shape[0] == x.shape[0] assert output_cache.shape[1] < x.shape[1] assert output_cache.shape[2] == self.size chunk = x.shape[1] - output_cache.shape[1] x_q = x[:, -chunk:, :] residual = residual[:, -chunk:, :] mask = mask[:, -chunk:, :] x_att = self.self_attn(x_q, x, x, pos_emb, mask) if self.concat_after: x_concat = paddle.concat((x, x_att), axis=-1) x = residual + self.concat_linear(x_concat) else: x = residual + self.dropout(x_att) if not self.normalize_before: x = self.norm_mha(x) # convolution module # Fake new cnn cache here, and then change it in conv_module new_cnn_cache = paddle.zeros([1], dtype=x.dtype) if self.conv_module is not None: residual = x if self.normalize_before: x = self.norm_conv(x) x, new_cnn_cache = self.conv_module(x, mask_pad, cnn_cache) x = residual + self.dropout(x) if not self.normalize_before: x = self.norm_conv(x) # feed forward module residual = x if self.normalize_before: x = self.norm_ff(x) x = residual + self.ff_scale * self.dropout(self.feed_forward(x)) if not self.normalize_before: x = self.norm_ff(x) if self.conv_module is not None: x = self.norm_final(x) if output_cache is not None: x = paddle.concat([output_cache, x], axis=1) return x, mask, new_cnn_cache