python/FunASR-XL.git

			@@ -581,6 +581,178 @@

			return y, new_cache

			class DecoderLayerSANMExport(torch.nn.Module):

			def __init__(
			self,
			model
			):
			super().__init__()
			self.self_attn = model.self_attn
			self.src_attn = model.src_attn
			self.feed_forward = model.feed_forward
			self.norm1 = model.norm1
			self.norm2 = model.norm2 if hasattr(model, 'norm2') else None
			self.norm3 = model.norm3 if hasattr(model, 'norm3') else None
			self.size = model.size


			def forward(self, tgt, tgt_mask, memory, memory_mask=None, cache=None):

			residual = tgt
			tgt = self.norm1(tgt)
			tgt = self.feed_forward(tgt)

			x = tgt
			if self.self_attn is not None:
			tgt = self.norm2(tgt)
			x, cache = self.self_attn(tgt, tgt_mask, cache=cache)
			x = residual + x

			if self.src_attn is not None:
			residual = x
			x = self.norm3(x)
			x = residual + self.src_attn(x, memory, memory_mask)


			return x, tgt_mask, memory, memory_mask, cache


			@tables.register("decoder_classes", "ParaformerSANMDecoderExport")
			class ParaformerSANMDecoderExport(torch.nn.Module):
			def __init__(self, model,
			max_seq_len=512,
			model_name='decoder',
			onnx: bool = True, ):
			super().__init__()
			# self.embed = model.embed #Embedding(model.embed, max_seq_len)
			from funasr.utils.torch_function import MakePadMask
			from funasr.utils.torch_function import sequence_mask

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

			from funasr.models.sanm.attention import MultiHeadedAttentionSANMDecoderExport
			from funasr.models.sanm.attention import MultiHeadedAttentionCrossAttExport


			for i, d in enumerate(self.model.decoders):
			if isinstance(d.self_attn, MultiHeadedAttentionSANMDecoder):
			d.self_attn = MultiHeadedAttentionSANMDecoderExport(d.self_attn)
			if isinstance(d.src_attn, MultiHeadedAttentionCrossAtt):
			d.src_attn = MultiHeadedAttentionCrossAttExport(d.src_attn)
			self.model.decoders[i] = DecoderLayerSANMExport(d)

			if self.model.decoders2 is not None:
			for i, d in enumerate(self.model.decoders2):
			if isinstance(d.self_attn, MultiHeadedAttentionSANMDecoder):
			d.self_attn = MultiHeadedAttentionSANMDecoderExport(d.self_attn)
			self.model.decoders2[i] = DecoderLayerSANMExport(d)

			for i, d in enumerate(self.model.decoders3):
			self.model.decoders3[i] = DecoderLayerSANMExport(d)

			self.output_layer = model.output_layer
			self.after_norm = model.after_norm
			self.model_name = model_name

			def prepare_mask(self, mask):
			mask_3d_btd = mask[:, :, None]
			if len(mask.shape) == 2:
			mask_4d_bhlt = 1 - mask[:, None, None, :]
			elif len(mask.shape) == 3:
			mask_4d_bhlt = 1 - mask[:, None, :]
			mask_4d_bhlt = mask_4d_bhlt * -10000.0

			return mask_3d_btd, mask_4d_bhlt

			def forward(
			self,
			hs_pad: torch.Tensor,
			hlens: torch.Tensor,
			ys_in_pad: torch.Tensor,
			ys_in_lens: torch.Tensor,
			):

			tgt = ys_in_pad
			tgt_mask = self.make_pad_mask(ys_in_lens)
			tgt_mask, _ = self.prepare_mask(tgt_mask)
			# tgt_mask = myutils.sequence_mask(ys_in_lens, device=tgt.device)[:, :, None]

			memory = hs_pad
			memory_mask = self.make_pad_mask(hlens)
			_, memory_mask = self.prepare_mask(memory_mask)
			# memory_mask = myutils.sequence_mask(hlens, device=memory.device)[:, None, :]

			x = tgt
			x, tgt_mask, memory, memory_mask, _ = self.model.decoders(
			x, tgt_mask, memory, memory_mask
			)
			if self.model.decoders2 is not None:
			x, tgt_mask, memory, memory_mask, _ = self.model.decoders2(
			x, tgt_mask, memory, memory_mask
			)
			x, tgt_mask, memory, memory_mask, _ = self.model.decoders3(
			x, tgt_mask, memory, memory_mask
			)
			x = self.after_norm(x)
			x = self.output_layer(x)

			return x, ys_in_lens

			def get_dummy_inputs(self, enc_size):
			tgt = torch.LongTensor([0]).unsqueeze(0)
			memory = torch.randn(1, 100, enc_size)
			pre_acoustic_embeds = torch.randn(1, 1, enc_size)
			cache_num = len(self.model.decoders) + len(self.model.decoders2)
			cache = [
			torch.zeros((1, self.model.decoders[0].size, self.model.decoders[0].self_attn.kernel_size))
			for _ in range(cache_num)
			]
			return (tgt, memory, pre_acoustic_embeds, cache)

			def is_optimizable(self):
			return True

			def get_input_names(self):
			cache_num = len(self.model.decoders) + len(self.model.decoders2)
			return ['tgt', 'memory', 'pre_acoustic_embeds'] \
			+ ['cache_%d' % i for i in range(cache_num)]

			def get_output_names(self):
			cache_num = len(self.model.decoders) + len(self.model.decoders2)
			return ['y'] \
			+ ['out_cache_%d' % i for i in range(cache_num)]

			def get_dynamic_axes(self):
			ret = {
			'tgt': {
			0: 'tgt_batch',
			1: 'tgt_length'
			},
			'memory': {
			0: 'memory_batch',
			1: 'memory_length'
			},
			'pre_acoustic_embeds': {
			0: 'acoustic_embeds_batch',
			1: 'acoustic_embeds_length',
			}
			}
			cache_num = len(self.model.decoders) + len(self.model.decoders2)
			ret.update({
			'cache_%d' % d: {
			0: 'cache_%d_batch' % d,
			2: 'cache_%d_length' % d
			}
			for d in range(cache_num)
			})
			return ret



			@tables.register("decoder_classes", "ParaformerSANDecoder")
			class ParaformerSANDecoder(BaseTransformerDecoder):