python/FunASR-XL.git

			@@ -1,17 +1,21 @@
			import logging


			import torch
			import torch.nn as nn

			from funasr.export.utils.torch_function import MakePadMask
			from funasr.export.utils.torch_function import sequence_mask
			from funasr.models.encoder.sanm_encoder import SANMEncoder
			from funasr.models.encoder.conformer_encoder import ConformerEncoder
			from funasr.export.models.encoder.sanm_encoder import SANMEncoder as SANMEncoder_export
			from funasr.models.predictor.cif import CifPredictorV2
			from funasr.export.models.encoder.conformer_encoder import ConformerEncoder as ConformerEncoder_export
			from funasr.models.predictor.cif import CifPredictorV2, CifPredictorV3
			from funasr.export.models.predictor.cif import CifPredictorV2 as CifPredictorV2_export
			from funasr.export.models.predictor.cif import CifPredictorV3 as CifPredictorV3_export
			from funasr.models.decoder.sanm_decoder import ParaformerSANMDecoder
			from funasr.models.decoder.transformer_decoder import ParaformerDecoderSAN
			from funasr.export.models.decoder.sanm_decoder import ParaformerSANMDecoder as ParaformerSANMDecoder_export
			from funasr.export.models.decoder.transformer_decoder import ParaformerDecoderSAN as ParaformerDecoderSAN_export


			class Paraformer(nn.Module):
			"""
			@@ -34,10 +38,14 @@
			onnx = kwargs["onnx"]
			if isinstance(model.encoder, SANMEncoder):
			self.encoder = SANMEncoder_export(model.encoder, onnx=onnx)
			elif isinstance(model.encoder, ConformerEncoder):
			self.encoder = ConformerEncoder_export(model.encoder, onnx=onnx)
			if isinstance(model.predictor, CifPredictorV2):
			self.predictor = CifPredictorV2_export(model.predictor)
			if isinstance(model.decoder, ParaformerSANMDecoder):
			self.decoder = ParaformerSANMDecoder_export(model.decoder, onnx=onnx)
			elif isinstance(model.decoder, ParaformerDecoderSAN):
			self.decoder = ParaformerDecoderSAN_export(model.decoder, onnx=onnx)

			self.feats_dim = feats_dim
			self.model_name = model_name
			@@ -99,4 +107,113 @@
			0: 'batch_size',
			1: 'logits_length'
			},
			}


			class BiCifParaformer(nn.Module):
			"""
			Author: Speech Lab, Alibaba Group, China
			Paraformer: Fast and Accurate Parallel Transformer for Non-autoregressive End-to-End Speech Recognition
			https://arxiv.org/abs/2206.08317
			"""

			def __init__(
			self,
			model,
			max_seq_len=512,
			feats_dim=560,
			model_name='model',
			**kwargs,
			):
			super().__init__()
			onnx = False
			if "onnx" in kwargs:
			onnx = kwargs["onnx"]
			if isinstance(model.encoder, SANMEncoder):
			self.encoder = SANMEncoder_export(model.encoder, onnx=onnx)
			elif isinstance(model.encoder, ConformerEncoder):
			self.encoder = ConformerEncoder_export(model.encoder, onnx=onnx)
			else:
			logging.warning("Unsupported encoder type to export.")
			if isinstance(model.predictor, CifPredictorV3):
			self.predictor = CifPredictorV3_export(model.predictor)
			else:
			logging.warning("Wrong predictor type to export.")
			if isinstance(model.decoder, ParaformerSANMDecoder):
			self.decoder = ParaformerSANMDecoder_export(model.decoder, onnx=onnx)
			elif isinstance(model.decoder, ParaformerDecoderSAN):
			self.decoder = ParaformerDecoderSAN_export(model.decoder, onnx=onnx)
			else:
			logging.warning("Unsupported decoder type to export.")

			self.feats_dim = feats_dim
			self.model_name = model_name

			if onnx:
			self.make_pad_mask = MakePadMask(max_seq_len, flip=False)
			else:
			self.make_pad_mask = sequence_mask(max_seq_len, flip=False)

			def forward(
			self,
			speech: torch.Tensor,
			speech_lengths: torch.Tensor,
			):
			# a. To device
			batch = {"speech": speech, "speech_lengths": speech_lengths}
			# batch = to_device(batch, device=self.device)

			enc, enc_len = self.encoder(**batch)
			mask = self.make_pad_mask(enc_len)[:, None, :]
			pre_acoustic_embeds, pre_token_length, alphas, pre_peak_index = self.predictor(enc, mask)
			pre_token_length = pre_token_length.round().type(torch.int32)

			decoder_out, _ = self.decoder(enc, enc_len, pre_acoustic_embeds, pre_token_length)
			decoder_out = torch.log_softmax(decoder_out, dim=-1)

			# get predicted timestamps
			us_alphas, us_cif_peak = self.predictor.get_upsample_timestmap(enc, mask, pre_token_length)

			return decoder_out, pre_token_length, us_alphas, us_cif_peak

			def get_dummy_inputs(self):
			speech = torch.randn(2, 30, self.feats_dim)
			speech_lengths = torch.tensor([6, 30], dtype=torch.int32)
			return (speech, speech_lengths)

			def get_dummy_inputs_txt(self, txt_file: str = "/mnt/workspace/data_fbank/0207/12345.wav.fea.txt"):
			import numpy as np
			fbank = np.loadtxt(txt_file)
			fbank_lengths = np.array([fbank.shape[0], ], dtype=np.int32)
			speech = torch.from_numpy(fbank[None, :, :].astype(np.float32))
			speech_lengths = torch.from_numpy(fbank_lengths.astype(np.int32))
			return (speech, speech_lengths)

			def get_input_names(self):
			return ['speech', 'speech_lengths']

			def get_output_names(self):
			return ['logits', 'token_num', 'us_alphas', 'us_cif_peak']

			def get_dynamic_axes(self):
			return {
			'speech': {
			0: 'batch_size',
			1: 'feats_length'
			},
			'speech_lengths': {
			0: 'batch_size',
			},
			'logits': {
			0: 'batch_size',
			1: 'logits_length'
			},
			'us_alphas': {
			0: 'batch_size',
			1: 'alphas_length'
			},
			'us_cif_peak': {
			0: 'batch_size',
			1: 'alphas_length'
			},
			}