from typing import Optional from typing import Tuple import logging import torch from torch import nn from funasr_detach.models.encoder.encoder_layer_mfcca import EncoderLayer from funasr_detach.models.transformer.utils.nets_utils import get_activation from funasr_detach.models.transformer.utils.nets_utils import make_pad_mask from funasr_detach.models.transformer.attention import ( MultiHeadedAttention, # noqa: H301 RelPositionMultiHeadedAttention, # noqa: H301 LegacyRelPositionMultiHeadedAttention, # noqa: H301 ) from funasr_detach.models.transformer.embedding import ( PositionalEncoding, # noqa: H301 ScaledPositionalEncoding, # noqa: H301 RelPositionalEncoding, # noqa: H301 LegacyRelPositionalEncoding, # noqa: H301 ) from funasr_detach.models.transformer.layer_norm import LayerNorm from funasr_detach.models.transformer.utils.multi_layer_conv import Conv1dLinear from funasr_detach.models.transformer.utils.multi_layer_conv import MultiLayeredConv1d from funasr_detach.models.transformer.positionwise_feed_forward import ( PositionwiseFeedForward, # noqa: H301 ) from funasr_detach.models.transformer.utils.repeat import repeat from funasr_detach.models.transformer.utils.subsampling import Conv2dSubsampling from funasr_detach.models.transformer.utils.subsampling import Conv2dSubsampling2 from funasr_detach.models.transformer.utils.subsampling import Conv2dSubsampling6 from funasr_detach.models.transformer.utils.subsampling import Conv2dSubsampling8 from funasr_detach.models.transformer.utils.subsampling import TooShortUttError from funasr_detach.models.transformer.utils.subsampling import check_short_utt from funasr_detach.models.encoder.abs_encoder import AbsEncoder import pdb import math class ConvolutionModule(nn.Module): """ConvolutionModule in Conformer model. Args: channels (int): The number of channels of conv layers. kernel_size (int): Kernerl size of conv layers. """ def __init__(self, channels, kernel_size, activation=nn.ReLU(), bias=True): """Construct an ConvolutionModule object.""" super(ConvolutionModule, self).__init__() # kernerl_size should be a odd number for 'SAME' padding assert (kernel_size - 1) % 2 == 0 self.pointwise_conv1 = nn.Conv1d( channels, 2 * channels, kernel_size=1, stride=1, padding=0, bias=bias, ) self.depthwise_conv = nn.Conv1d( channels, channels, kernel_size, stride=1, padding=(kernel_size - 1) // 2, groups=channels, bias=bias, ) self.norm = nn.BatchNorm1d(channels) self.pointwise_conv2 = nn.Conv1d( channels, channels, kernel_size=1, stride=1, padding=0, bias=bias, ) self.activation = activation def forward(self, x): """Compute convolution module. Args: x (torch.Tensor): Input tensor (#batch, time, channels). Returns: torch.Tensor: Output tensor (#batch, time, channels). """ # exchange the temporal dimension and the feature dimension x = x.transpose(1, 2) # GLU mechanism x = self.pointwise_conv1(x) # (batch, 2*channel, dim) x = nn.functional.glu(x, dim=1) # (batch, channel, dim) # 1D Depthwise Conv x = self.depthwise_conv(x) x = self.activation(self.norm(x)) x = self.pointwise_conv2(x) return x.transpose(1, 2) class MFCCAEncoder(AbsEncoder): """Conformer encoder module. Args: input_size (int): Input dimension. output_size (int): Dimention of attention. attention_heads (int): The number of heads of multi head attention. linear_units (int): The number of units of position-wise feed forward. num_blocks (int): The number of decoder blocks. dropout_rate (float): Dropout rate. attention_dropout_rate (float): Dropout rate in attention. positional_dropout_rate (float): Dropout rate after adding positional encoding. input_layer (Union[str, torch.nn.Module]): Input layer type. normalize_before (bool): Whether to use layer_norm before the first block. concat_after (bool): Whether to concat attention layer's input and output. If True, additional linear will be applied. i.e. x -> x + linear(concat(x, att(x))) If False, no additional linear will be applied. i.e. x -> x + att(x) positionwise_layer_type (str): "linear", "conv1d", or "conv1d-linear". positionwise_conv_kernel_size (int): Kernel size of positionwise conv1d layer. rel_pos_type (str): Whether to use the latest relative positional encoding or the legacy one. The legacy relative positional encoding will be deprecated in the future. More Details can be found in https://github.com/espnet/espnet/pull/2816. encoder_pos_enc_layer_type (str): Encoder positional encoding layer type. encoder_attn_layer_type (str): Encoder attention layer type. activation_type (str): Encoder activation function type. macaron_style (bool): Whether to use macaron style for positionwise layer. use_cnn_module (bool): Whether to use convolution module. zero_triu (bool): Whether to zero the upper triangular part of attention matrix. cnn_module_kernel (int): Kernerl size of convolution module. padding_idx (int): Padding idx for input_layer=embed. """ def __init__( self, input_size: int, output_size: int = 256, attention_heads: int = 4, linear_units: int = 2048, num_blocks: int = 6, dropout_rate: float = 0.1, positional_dropout_rate: float = 0.1, attention_dropout_rate: float = 0.0, input_layer: str = "conv2d", normalize_before: bool = True, concat_after: bool = False, positionwise_layer_type: str = "linear", positionwise_conv_kernel_size: int = 3, macaron_style: bool = False, rel_pos_type: str = "legacy", pos_enc_layer_type: str = "rel_pos", selfattention_layer_type: str = "rel_selfattn", activation_type: str = "swish", use_cnn_module: bool = True, zero_triu: bool = False, cnn_module_kernel: int = 31, padding_idx: int = -1, ): super().__init__() self._output_size = output_size if rel_pos_type == "legacy": if pos_enc_layer_type == "rel_pos": pos_enc_layer_type = "legacy_rel_pos" if selfattention_layer_type == "rel_selfattn": selfattention_layer_type = "legacy_rel_selfattn" elif rel_pos_type == "latest": assert selfattention_layer_type != "legacy_rel_selfattn" assert pos_enc_layer_type != "legacy_rel_pos" else: raise ValueError("unknown rel_pos_type: " + rel_pos_type) activation = get_activation(activation_type) if pos_enc_layer_type == "abs_pos": pos_enc_class = PositionalEncoding elif pos_enc_layer_type == "scaled_abs_pos": pos_enc_class = ScaledPositionalEncoding elif pos_enc_layer_type == "rel_pos": assert selfattention_layer_type == "rel_selfattn" pos_enc_class = RelPositionalEncoding elif pos_enc_layer_type == "legacy_rel_pos": assert selfattention_layer_type == "legacy_rel_selfattn" pos_enc_class = LegacyRelPositionalEncoding logging.warning( "Using legacy_rel_pos and it will be deprecated in the future." ) else: raise ValueError("unknown pos_enc_layer: " + pos_enc_layer_type) if input_layer == "linear": self.embed = torch.nn.Sequential( torch.nn.Linear(input_size, output_size), torch.nn.LayerNorm(output_size), torch.nn.Dropout(dropout_rate), pos_enc_class(output_size, positional_dropout_rate), ) elif input_layer == "conv2d": self.embed = Conv2dSubsampling( input_size, output_size, dropout_rate, pos_enc_class(output_size, positional_dropout_rate), ) elif input_layer == "conv2d6": self.embed = Conv2dSubsampling6( input_size, output_size, dropout_rate, pos_enc_class(output_size, positional_dropout_rate), ) elif input_layer == "conv2d8": self.embed = Conv2dSubsampling8( input_size, output_size, dropout_rate, pos_enc_class(output_size, positional_dropout_rate), ) elif input_layer == "embed": self.embed = torch.nn.Sequential( torch.nn.Embedding(input_size, output_size, padding_idx=padding_idx), pos_enc_class(output_size, positional_dropout_rate), ) elif isinstance(input_layer, torch.nn.Module): self.embed = torch.nn.Sequential( input_layer, pos_enc_class(output_size, positional_dropout_rate), ) elif input_layer is None: self.embed = torch.nn.Sequential( pos_enc_class(output_size, positional_dropout_rate) ) else: raise ValueError("unknown input_layer: " + input_layer) self.normalize_before = normalize_before if positionwise_layer_type == "linear": positionwise_layer = PositionwiseFeedForward positionwise_layer_args = ( output_size, linear_units, dropout_rate, activation, ) elif positionwise_layer_type == "conv1d": positionwise_layer = MultiLayeredConv1d positionwise_layer_args = ( output_size, linear_units, positionwise_conv_kernel_size, dropout_rate, ) elif positionwise_layer_type == "conv1d-linear": positionwise_layer = Conv1dLinear positionwise_layer_args = ( output_size, linear_units, positionwise_conv_kernel_size, dropout_rate, ) else: raise NotImplementedError("Support only linear or conv1d.") if selfattention_layer_type == "selfattn": encoder_selfattn_layer = MultiHeadedAttention encoder_selfattn_layer_args = ( attention_heads, output_size, attention_dropout_rate, ) elif selfattention_layer_type == "legacy_rel_selfattn": assert pos_enc_layer_type == "legacy_rel_pos" encoder_selfattn_layer = LegacyRelPositionMultiHeadedAttention encoder_selfattn_layer_args = ( attention_heads, output_size, attention_dropout_rate, ) logging.warning( "Using legacy_rel_selfattn and it will be deprecated in the future." ) elif selfattention_layer_type == "rel_selfattn": assert pos_enc_layer_type == "rel_pos" encoder_selfattn_layer = RelPositionMultiHeadedAttention encoder_selfattn_layer_args = ( attention_heads, output_size, attention_dropout_rate, zero_triu, ) else: raise ValueError("unknown encoder_attn_layer: " + selfattention_layer_type) convolution_layer = ConvolutionModule convolution_layer_args = (output_size, cnn_module_kernel, activation) encoder_selfattn_layer_raw = MultiHeadedAttention encoder_selfattn_layer_args_raw = ( attention_heads, output_size, attention_dropout_rate, ) self.encoders = repeat( num_blocks, lambda lnum: EncoderLayer( output_size, encoder_selfattn_layer_raw(*encoder_selfattn_layer_args_raw), encoder_selfattn_layer(*encoder_selfattn_layer_args), positionwise_layer(*positionwise_layer_args), positionwise_layer(*positionwise_layer_args) if macaron_style else None, convolution_layer(*convolution_layer_args) if use_cnn_module else None, dropout_rate, normalize_before, concat_after, ), ) if self.normalize_before: self.after_norm = LayerNorm(output_size) self.conv1 = torch.nn.Conv2d(8, 16, [5, 7], stride=[1, 1], padding=(2, 3)) self.conv2 = torch.nn.Conv2d(16, 32, [5, 7], stride=[1, 1], padding=(2, 3)) self.conv3 = torch.nn.Conv2d(32, 16, [5, 7], stride=[1, 1], padding=(2, 3)) self.conv4 = torch.nn.Conv2d(16, 1, [5, 7], stride=[1, 1], padding=(2, 3)) def output_size(self) -> int: return self._output_size def forward( self, xs_pad: torch.Tensor, ilens: torch.Tensor, channel_size: torch.Tensor, prev_states: torch.Tensor = None, ) -> Tuple[torch.Tensor, torch.Tensor, Optional[torch.Tensor]]: """Calculate forward propagation. Args: xs_pad (torch.Tensor): Input tensor (#batch, L, input_size). ilens (torch.Tensor): Input length (#batch). prev_states (torch.Tensor): Not to be used now. Returns: torch.Tensor: Output tensor (#batch, L, output_size). torch.Tensor: Output length (#batch). torch.Tensor: Not to be used now. """ masks = (~make_pad_mask(ilens)[:, None, :]).to(xs_pad.device) if ( isinstance(self.embed, Conv2dSubsampling) or isinstance(self.embed, Conv2dSubsampling6) or isinstance(self.embed, Conv2dSubsampling8) ): short_status, limit_size = check_short_utt(self.embed, xs_pad.size(1)) if short_status: raise TooShortUttError( f"has {xs_pad.size(1)} frames and is too short for subsampling " + f"(it needs more than {limit_size} frames), return empty results", xs_pad.size(1), limit_size, ) xs_pad, masks = self.embed(xs_pad, masks) else: xs_pad = self.embed(xs_pad) xs_pad, masks, channel_size = self.encoders(xs_pad, masks, channel_size) if isinstance(xs_pad, tuple): xs_pad = xs_pad[0] t_leng = xs_pad.size(1) d_dim = xs_pad.size(2) xs_pad = xs_pad.reshape(-1, channel_size, t_leng, d_dim) # pdb.set_trace() if channel_size < 8: repeat_num = math.ceil(8 / channel_size) xs_pad = xs_pad.repeat(1, repeat_num, 1, 1)[:, 0:8, :, :] xs_pad = self.conv1(xs_pad) xs_pad = self.conv2(xs_pad) xs_pad = self.conv3(xs_pad) xs_pad = self.conv4(xs_pad) xs_pad = xs_pad.squeeze().reshape(-1, t_leng, d_dim) mask_tmp = masks.size(1) masks = masks.reshape(-1, channel_size, mask_tmp, t_leng)[:, 0, :, :] if self.normalize_before: xs_pad = self.after_norm(xs_pad) olens = masks.squeeze(1).sum(1) return xs_pad, olens, None def forward_hidden( self, xs_pad: torch.Tensor, ilens: torch.Tensor, prev_states: torch.Tensor = None, ) -> Tuple[torch.Tensor, torch.Tensor, Optional[torch.Tensor]]: """Calculate forward propagation. Args: xs_pad (torch.Tensor): Input tensor (#batch, L, input_size). ilens (torch.Tensor): Input length (#batch). prev_states (torch.Tensor): Not to be used now. Returns: torch.Tensor: Output tensor (#batch, L, output_size). torch.Tensor: Output length (#batch). torch.Tensor: Not to be used now. """ masks = (~make_pad_mask(ilens)[:, None, :]).to(xs_pad.device) if ( isinstance(self.embed, Conv2dSubsampling) or isinstance(self.embed, Conv2dSubsampling6) or isinstance(self.embed, Conv2dSubsampling8) ): short_status, limit_size = check_short_utt(self.embed, xs_pad.size(1)) if short_status: raise TooShortUttError( f"has {xs_pad.size(1)} frames and is too short for subsampling " + f"(it needs more than {limit_size} frames), return empty results", xs_pad.size(1), limit_size, ) xs_pad, masks = self.embed(xs_pad, masks) else: xs_pad = self.embed(xs_pad) num_layer = len(self.encoders) for idx, encoder in enumerate(self.encoders): xs_pad, masks = encoder(xs_pad, masks) if idx == num_layer // 2 - 1: hidden_feature = xs_pad if isinstance(xs_pad, tuple): xs_pad = xs_pad[0] hidden_feature = hidden_feature[0] if self.normalize_before: xs_pad = self.after_norm(xs_pad) self.hidden_feature = self.after_norm(hidden_feature) olens = masks.squeeze(1).sum(1) return xs_pad, olens, None