python/FunASR-XL.git

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			from typing import Tuple

			import torch
			import torch.nn as nn

			from funasr.models.encoder.sanm_encoder import SANMEncoder
			from funasr.export.models.encoder.sanm_encoder import SANMEncoder as SANMEncoder_export
			from funasr.models.encoder.sanm_encoder import SANMVadEncoder
			from funasr.export.models.encoder.sanm_encoder import SANMVadEncoder as SANMVadEncoder_export

			class CT_Transformer(nn.Module):
			"""
			Author: Speech Lab, Alibaba Group, China
			CT-Transformer: Controllable time-delay transformer for real-time punctuation prediction and disfluency detection
			https://arxiv.org/pdf/2003.01309.pdf
			"""
			def __init__(
			self,
			model,
			max_seq_len=512,
			model_name='punc_model',
			**kwargs,
			):
			super().__init__()
			onnx = False
			if "onnx" in kwargs:
			onnx = kwargs["onnx"]
			self.embed = model.embed
			self.decoder = model.decoder
			# self.model = model
			self.feats_dim = self.embed.embedding_dim
			self.num_embeddings = self.embed.num_embeddings
			self.model_name = model_name

			if isinstance(model.encoder, SANMEncoder):
			self.encoder = SANMEncoder_export(model.encoder, onnx=onnx)
			else:
			assert False, "Only support samn encode."

			def forward(self, inputs: torch.Tensor, text_lengths: torch.Tensor) -> Tuple[torch.Tensor, None]:
			"""Compute loss value from buffer sequences.

			Args:
			input (torch.Tensor): Input ids. (batch, len)
			hidden (torch.Tensor): Target ids. (batch, len)

			"""
			x = self.embed(inputs)
			# mask = self._target_mask(input)
			h, _ = self.encoder(x, text_lengths)
			y = self.decoder(h)
			return y

			def get_dummy_inputs(self):
			length = 120
			text_indexes = torch.randint(0, self.embed.num_embeddings, (2, length))
			text_lengths = torch.tensor([length-20, length], dtype=torch.int32)
			return (text_indexes, text_lengths)

			def get_input_names(self):
			return ['inputs', 'text_lengths']

			def get_output_names(self):
			return ['logits']

			def get_dynamic_axes(self):
			return {
			'inputs': {
			0: 'batch_size',
			1: 'feats_length'
			},
			'text_lengths': {
			0: 'batch_size',
			},
			'logits': {
			0: 'batch_size',
			1: 'logits_length'
			},
			}


			class CT_Transformer_VadRealtime(nn.Module):
			"""
			Author: Speech Lab, Alibaba Group, China
			CT-Transformer: Controllable time-delay transformer for real-time punctuation prediction and disfluency detection
			https://arxiv.org/pdf/2003.01309.pdf
			"""
			def __init__(
			self,
			model,
			max_seq_len=512,
			model_name='punc_model',
			**kwargs,
			):
			super().__init__()
			onnx = False
			if "onnx" in kwargs:
			onnx = kwargs["onnx"]

			self.embed = model.embed
			if isinstance(model.encoder, SANMVadEncoder):
			self.encoder = SANMVadEncoder_export(model.encoder, onnx=onnx)
			else:
			assert False, "Only support samn encode."
			self.decoder = model.decoder
			self.model_name = model_name



			def forward(self, inputs: torch.Tensor,
			text_lengths: torch.Tensor,
			vad_indexes: torch.Tensor,
			sub_masks: torch.Tensor,
			) -> Tuple[torch.Tensor, None]:
			"""Compute loss value from buffer sequences.

			Args:
			input (torch.Tensor): Input ids. (batch, len)
			hidden (torch.Tensor): Target ids. (batch, len)

			"""
			x = self.embed(inputs)
			# mask = self._target_mask(input)
			h, _ = self.encoder(x, text_lengths, vad_indexes, sub_masks)
			y = self.decoder(h)
			return y

			def with_vad(self):
			return True

			def get_dummy_inputs(self):
			length = 120
			text_indexes = torch.randint(0, self.embed.num_embeddings, (1, length))
			text_lengths = torch.tensor([length], dtype=torch.int32)
			vad_mask = torch.ones(length, length, dtype=torch.float32)[None, None, :, :]
			sub_masks = torch.ones(length, length, dtype=torch.float32)
			sub_masks = torch.tril(sub_masks).type(torch.float32)
			return (text_indexes, text_lengths, vad_mask, sub_masks[None, None, :, :])

			def get_input_names(self):
			return ['inputs', 'text_lengths', 'vad_masks', 'sub_masks']

			def get_output_names(self):
			return ['logits']

			def get_dynamic_axes(self):
			return {
			'inputs': {
			1: 'feats_length'
			},
			'vad_masks': {
			2: 'feats_length1',
			3: 'feats_length2'
			},
			'sub_masks': {
			2: 'feats_length1',
			3: 'feats_length2'
			},
			'logits': {
			1: 'logits_length'
			},
			}