From 8827e26b8d487f123f8d7d5cbd8d00b81dcefcff Mon Sep 17 00:00:00 2001
From: 游雁 <zhifu.gzf@alibaba-inc.com>
Date: 星期五, 23 二月 2024 00:58:18 +0800
Subject: [PATCH] fp16
---
funasr/models/paraformer/cif_predictor.py | 417 +++-------------------------------------------------------
1 files changed, 27 insertions(+), 390 deletions(-)
diff --git a/funasr/models/paraformer/cif_predictor.py b/funasr/models/paraformer/cif_predictor.py
index 7cc088f..60ddc24 100644
--- a/funasr/models/paraformer/cif_predictor.py
+++ b/funasr/models/paraformer/cif_predictor.py
@@ -1,20 +1,25 @@
+#!/usr/bin/env python3
+# -*- encoding: utf-8 -*-
+# Copyright FunASR (https://github.com/alibaba-damo-academy/FunASR). All Rights Reserved.
+# MIT License (https://opensource.org/licenses/MIT)
+
import torch
-from torch import nn
-from torch import Tensor
import logging
import numpy as np
+
+from funasr.register import tables
from funasr.train_utils.device_funcs import to_device
from funasr.models.transformer.utils.nets_utils import make_pad_mask
-from funasr.models.scama.utils import sequence_mask
-from typing import Optional, Tuple
-class CifPredictor(nn.Module):
+
+@tables.register("predictor_classes", "CifPredictor")
+class CifPredictor(torch.nn.Module):
def __init__(self, idim, l_order, r_order, threshold=1.0, dropout=0.1, smooth_factor=1.0, noise_threshold=0, tail_threshold=0.45):
- super(CifPredictor, self).__init__()
+ super().__init__()
- self.pad = nn.ConstantPad1d((l_order, r_order), 0)
- self.cif_conv1d = nn.Conv1d(idim, idim, l_order + r_order + 1, groups=idim)
- self.cif_output = nn.Linear(idim, 1)
+ self.pad = torch.nn.ConstantPad1d((l_order, r_order), 0)
+ self.cif_conv1d = torch.nn.Conv1d(idim, idim, l_order + r_order + 1, groups=idim)
+ self.cif_output = torch.nn.Linear(idim, 1)
self.dropout = torch.nn.Dropout(p=dropout)
self.threshold = threshold
self.smooth_factor = smooth_factor
@@ -133,8 +138,8 @@
predictor_alignments_length = predictor_alignments.sum(-1).type(encoder_sequence_length.dtype)
return predictor_alignments.detach(), predictor_alignments_length.detach()
-
-class CifPredictorV2(nn.Module):
+@tables.register("predictor_classes", "CifPredictorV2")
+class CifPredictorV2(torch.nn.Module):
def __init__(self,
idim,
l_order,
@@ -150,9 +155,9 @@
):
super(CifPredictorV2, self).__init__()
- self.pad = nn.ConstantPad1d((l_order, r_order), 0)
- self.cif_conv1d = nn.Conv1d(idim, idim, l_order + r_order + 1)
- self.cif_output = nn.Linear(idim, 1)
+ self.pad = torch.nn.ConstantPad1d((l_order, r_order), 0)
+ self.cif_conv1d = torch.nn.Conv1d(idim, idim, l_order + r_order + 1)
+ self.cif_output = torch.nn.Linear(idim, 1)
self.dropout = torch.nn.Dropout(p=dropout)
self.threshold = threshold
self.smooth_factor = smooth_factor
@@ -181,7 +186,7 @@
alphas = alphas.squeeze(-1)
mask = mask.squeeze(-1)
if target_label_length is not None:
- target_length = target_label_length
+ target_length = target_label_length.squeeze(-1)
elif target_label is not None:
target_length = (target_label != ignore_id).float().sum(-1)
else:
@@ -202,7 +207,8 @@
return acoustic_embeds, token_num, alphas, cif_peak
- def forward_chunk(self, hidden, cache=None):
+ def forward_chunk(self, hidden, cache=None, **kwargs):
+ is_final = kwargs.get("is_final", False)
batch_size, len_time, hidden_size = hidden.shape
h = hidden
context = h.transpose(1, 2)
@@ -223,14 +229,14 @@
if cache is not None and "chunk_size" in cache:
alphas[:, :cache["chunk_size"][0]] = 0.0
- if "is_final" in cache and not cache["is_final"]:
+ if not is_final:
alphas[:, sum(cache["chunk_size"][:2]):] = 0.0
if cache is not None and "cif_alphas" in cache and "cif_hidden" in cache:
cache["cif_hidden"] = to_device(cache["cif_hidden"], device=hidden.device)
cache["cif_alphas"] = to_device(cache["cif_alphas"], device=alphas.device)
hidden = torch.cat((cache["cif_hidden"], hidden), dim=1)
alphas = torch.cat((cache["cif_alphas"], alphas), dim=1)
- if cache is not None and "is_final" in cache and cache["is_final"]:
+ if cache is not None and is_final:
tail_hidden = torch.zeros((batch_size, 1, hidden_size), device=hidden.device)
tail_alphas = torch.tensor([[self.tail_threshold]], device=alphas.device)
tail_alphas = torch.tile(tail_alphas, (batch_size, 1))
@@ -274,7 +280,7 @@
max_token_len = max(token_length)
if max_token_len == 0:
- return hidden, torch.stack(token_length, 0)
+ return hidden, torch.stack(token_length, 0), None, None
list_ls = []
for b in range(batch_size):
pad_frames = torch.zeros((max_token_len - token_length[b], hidden_size), device=alphas.device)
@@ -288,7 +294,7 @@
cache["cif_alphas"] = torch.unsqueeze(cache["cif_alphas"], axis=0)
cache["cif_hidden"] = torch.stack(cache_hiddens, axis=0)
cache["cif_hidden"] = torch.unsqueeze(cache["cif_hidden"], axis=0)
- return torch.stack(list_ls, 0), torch.stack(token_length, 0)
+ return torch.stack(list_ls, 0), torch.stack(token_length, 0), None, None
def tail_process_fn(self, hidden, alphas, token_num=None, mask=None):
@@ -422,7 +428,7 @@
return var_dict_torch_update
-class mae_loss(nn.Module):
+class mae_loss(torch.nn.Module):
def __init__(self, normalize_length=False):
super(mae_loss, self).__init__()
@@ -505,372 +511,3 @@
fires = torch.stack(list_fires, 1)
return fires
-
-class CifPredictorV3(nn.Module):
- def __init__(self,
- idim,
- l_order,
- r_order,
- threshold=1.0,
- dropout=0.1,
- smooth_factor=1.0,
- noise_threshold=0,
- tail_threshold=0.0,
- tf2torch_tensor_name_prefix_torch="predictor",
- tf2torch_tensor_name_prefix_tf="seq2seq/cif",
- smooth_factor2=1.0,
- noise_threshold2=0,
- upsample_times=5,
- upsample_type="cnn",
- use_cif1_cnn=True,
- tail_mask=True,
- ):
- super(CifPredictorV3, self).__init__()
-
- self.pad = nn.ConstantPad1d((l_order, r_order), 0)
- self.cif_conv1d = nn.Conv1d(idim, idim, l_order + r_order + 1)
- self.cif_output = nn.Linear(idim, 1)
- self.dropout = torch.nn.Dropout(p=dropout)
- self.threshold = threshold
- self.smooth_factor = smooth_factor
- self.noise_threshold = noise_threshold
- self.tail_threshold = tail_threshold
- self.tf2torch_tensor_name_prefix_torch = tf2torch_tensor_name_prefix_torch
- self.tf2torch_tensor_name_prefix_tf = tf2torch_tensor_name_prefix_tf
-
- self.upsample_times = upsample_times
- self.upsample_type = upsample_type
- self.use_cif1_cnn = use_cif1_cnn
- if self.upsample_type == 'cnn':
- self.upsample_cnn = nn.ConvTranspose1d(idim, idim, self.upsample_times, self.upsample_times)
- self.cif_output2 = nn.Linear(idim, 1)
- elif self.upsample_type == 'cnn_blstm':
- self.upsample_cnn = nn.ConvTranspose1d(idim, idim, self.upsample_times, self.upsample_times)
- self.blstm = nn.LSTM(idim, idim, 1, bias=True, batch_first=True, dropout=0.0, bidirectional=True)
- self.cif_output2 = nn.Linear(idim*2, 1)
- elif self.upsample_type == 'cnn_attn':
- self.upsample_cnn = nn.ConvTranspose1d(idim, idim, self.upsample_times, self.upsample_times)
- from funasr.models.encoder.transformer_encoder import EncoderLayer as TransformerEncoderLayer
- from funasr.models.transformer.attention import MultiHeadedAttention
- from funasr.models.transformer.positionwise_feed_forward import PositionwiseFeedForward
- positionwise_layer_args = (
- idim,
- idim*2,
- 0.1,
- )
- self.self_attn = TransformerEncoderLayer(
- idim,
- MultiHeadedAttention(
- 4, idim, 0.1
- ),
- PositionwiseFeedForward(*positionwise_layer_args),
- 0.1,
- True, #normalize_before,
- False, #concat_after,
- )
- self.cif_output2 = nn.Linear(idim, 1)
- self.smooth_factor2 = smooth_factor2
- self.noise_threshold2 = noise_threshold2
-
- def forward(self, hidden, target_label=None, mask=None, ignore_id=-1, mask_chunk_predictor=None,
- target_label_length=None):
- h = hidden
- context = h.transpose(1, 2)
- queries = self.pad(context)
- output = torch.relu(self.cif_conv1d(queries))
-
- # alphas2 is an extra head for timestamp prediction
- if not self.use_cif1_cnn:
- _output = context
- else:
- _output = output
- if self.upsample_type == 'cnn':
- output2 = self.upsample_cnn(_output)
- output2 = output2.transpose(1,2)
- elif self.upsample_type == 'cnn_blstm':
- output2 = self.upsample_cnn(_output)
- output2 = output2.transpose(1,2)
- output2, (_, _) = self.blstm(output2)
- elif self.upsample_type == 'cnn_attn':
- output2 = self.upsample_cnn(_output)
- output2 = output2.transpose(1,2)
- output2, _ = self.self_attn(output2, mask)
- # import pdb; pdb.set_trace()
- alphas2 = torch.sigmoid(self.cif_output2(output2))
- alphas2 = torch.nn.functional.relu(alphas2 * self.smooth_factor2 - self.noise_threshold2)
- # repeat the mask in T demension to match the upsampled length
- if mask is not None:
- mask2 = mask.repeat(1, self.upsample_times, 1).transpose(-1, -2).reshape(alphas2.shape[0], -1)
- mask2 = mask2.unsqueeze(-1)
- alphas2 = alphas2 * mask2
- alphas2 = alphas2.squeeze(-1)
- token_num2 = alphas2.sum(-1)
-
- output = output.transpose(1, 2)
-
- output = self.cif_output(output)
- alphas = torch.sigmoid(output)
- alphas = torch.nn.functional.relu(alphas * self.smooth_factor - self.noise_threshold)
- if mask is not None:
- mask = mask.transpose(-1, -2).float()
- alphas = alphas * mask
- if mask_chunk_predictor is not None:
- alphas = alphas * mask_chunk_predictor
- alphas = alphas.squeeze(-1)
- mask = mask.squeeze(-1)
- if target_label_length is not None:
- target_length = target_label_length
- elif target_label is not None:
- target_length = (target_label != ignore_id).float().sum(-1)
- else:
- target_length = None
- token_num = alphas.sum(-1)
-
- if target_length is not None:
- alphas *= (target_length / token_num)[:, None].repeat(1, alphas.size(1))
- elif self.tail_threshold > 0.0:
- hidden, alphas, token_num = self.tail_process_fn(hidden, alphas, token_num, mask=mask)
-
- acoustic_embeds, cif_peak = cif(hidden, alphas, self.threshold)
- if target_length is None and self.tail_threshold > 0.0:
- token_num_int = torch.max(token_num).type(torch.int32).item()
- acoustic_embeds = acoustic_embeds[:, :token_num_int, :]
- return acoustic_embeds, token_num, alphas, cif_peak, token_num2
-
- def get_upsample_timestamp(self, hidden, mask=None, token_num=None):
- h = hidden
- b = hidden.shape[0]
- context = h.transpose(1, 2)
- queries = self.pad(context)
- output = torch.relu(self.cif_conv1d(queries))
-
- # alphas2 is an extra head for timestamp prediction
- if not self.use_cif1_cnn:
- _output = context
- else:
- _output = output
- if self.upsample_type == 'cnn':
- output2 = self.upsample_cnn(_output)
- output2 = output2.transpose(1,2)
- elif self.upsample_type == 'cnn_blstm':
- output2 = self.upsample_cnn(_output)
- output2 = output2.transpose(1,2)
- output2, (_, _) = self.blstm(output2)
- elif self.upsample_type == 'cnn_attn':
- output2 = self.upsample_cnn(_output)
- output2 = output2.transpose(1,2)
- output2, _ = self.self_attn(output2, mask)
- alphas2 = torch.sigmoid(self.cif_output2(output2))
- alphas2 = torch.nn.functional.relu(alphas2 * self.smooth_factor2 - self.noise_threshold2)
- # repeat the mask in T demension to match the upsampled length
- if mask is not None:
- mask2 = mask.repeat(1, self.upsample_times, 1).transpose(-1, -2).reshape(alphas2.shape[0], -1)
- mask2 = mask2.unsqueeze(-1)
- alphas2 = alphas2 * mask2
- alphas2 = alphas2.squeeze(-1)
- _token_num = alphas2.sum(-1)
- if token_num is not None:
- alphas2 *= (token_num / _token_num)[:, None].repeat(1, alphas2.size(1))
- # re-downsample
- ds_alphas = alphas2.reshape(b, -1, self.upsample_times).sum(-1)
- ds_cif_peak = cif_wo_hidden(ds_alphas, self.threshold - 1e-4)
- # upsampled alphas and cif_peak
- us_alphas = alphas2
- us_cif_peak = cif_wo_hidden(us_alphas, self.threshold - 1e-4)
- return ds_alphas, ds_cif_peak, us_alphas, us_cif_peak
-
- def tail_process_fn(self, hidden, alphas, token_num=None, mask=None):
- b, t, d = hidden.size()
- tail_threshold = self.tail_threshold
- if mask is not None:
- zeros_t = torch.zeros((b, 1), dtype=torch.float32, device=alphas.device)
- ones_t = torch.ones_like(zeros_t)
- mask_1 = torch.cat([mask, zeros_t], dim=1)
- mask_2 = torch.cat([ones_t, mask], dim=1)
- mask = mask_2 - mask_1
- tail_threshold = mask * tail_threshold
- alphas = torch.cat([alphas, zeros_t], dim=1)
- alphas = torch.add(alphas, tail_threshold)
- else:
- tail_threshold = torch.tensor([tail_threshold], dtype=alphas.dtype).to(alphas.device)
- tail_threshold = torch.reshape(tail_threshold, (1, 1))
- alphas = torch.cat([alphas, tail_threshold], dim=1)
- zeros = torch.zeros((b, 1, d), dtype=hidden.dtype).to(hidden.device)
- hidden = torch.cat([hidden, zeros], dim=1)
- token_num = alphas.sum(dim=-1)
- token_num_floor = torch.floor(token_num)
-
- return hidden, alphas, token_num_floor
-
- def gen_frame_alignments(self,
- alphas: torch.Tensor = None,
- encoder_sequence_length: torch.Tensor = None):
- batch_size, maximum_length = alphas.size()
- int_type = torch.int32
-
- is_training = self.training
- if is_training:
- token_num = torch.round(torch.sum(alphas, dim=1)).type(int_type)
- else:
- token_num = torch.floor(torch.sum(alphas, dim=1)).type(int_type)
-
- max_token_num = torch.max(token_num).item()
-
- alphas_cumsum = torch.cumsum(alphas, dim=1)
- alphas_cumsum = torch.floor(alphas_cumsum).type(int_type)
- alphas_cumsum = alphas_cumsum[:, None, :].repeat(1, max_token_num, 1)
-
- index = torch.ones([batch_size, max_token_num], dtype=int_type)
- index = torch.cumsum(index, dim=1)
- index = index[:, :, None].repeat(1, 1, maximum_length).to(alphas_cumsum.device)
-
- index_div = torch.floor(torch.true_divide(alphas_cumsum, index)).type(int_type)
- index_div_bool_zeros = index_div.eq(0)
- index_div_bool_zeros_count = torch.sum(index_div_bool_zeros, dim=-1) + 1
- index_div_bool_zeros_count = torch.clamp(index_div_bool_zeros_count, 0, encoder_sequence_length.max())
- token_num_mask = (~make_pad_mask(token_num, maxlen=max_token_num)).to(token_num.device)
- index_div_bool_zeros_count *= token_num_mask
-
- index_div_bool_zeros_count_tile = index_div_bool_zeros_count[:, :, None].repeat(1, 1, maximum_length)
- ones = torch.ones_like(index_div_bool_zeros_count_tile)
- zeros = torch.zeros_like(index_div_bool_zeros_count_tile)
- ones = torch.cumsum(ones, dim=2)
- cond = index_div_bool_zeros_count_tile == ones
- index_div_bool_zeros_count_tile = torch.where(cond, zeros, ones)
-
- index_div_bool_zeros_count_tile_bool = index_div_bool_zeros_count_tile.type(torch.bool)
- index_div_bool_zeros_count_tile = 1 - index_div_bool_zeros_count_tile_bool.type(int_type)
- index_div_bool_zeros_count_tile_out = torch.sum(index_div_bool_zeros_count_tile, dim=1)
- index_div_bool_zeros_count_tile_out = index_div_bool_zeros_count_tile_out.type(int_type)
- predictor_mask = (~make_pad_mask(encoder_sequence_length, maxlen=encoder_sequence_length.max())).type(
- int_type).to(encoder_sequence_length.device)
- index_div_bool_zeros_count_tile_out = index_div_bool_zeros_count_tile_out * predictor_mask
-
- predictor_alignments = index_div_bool_zeros_count_tile_out
- predictor_alignments_length = predictor_alignments.sum(-1).type(encoder_sequence_length.dtype)
- return predictor_alignments.detach(), predictor_alignments_length.detach()
-
-class BATPredictor(nn.Module):
- def __init__(self, idim, l_order, r_order, threshold=1.0, dropout=0.1, smooth_factor=1.0, noise_threshold=0, return_accum=False):
- super(BATPredictor, self).__init__()
-
- self.pad = nn.ConstantPad1d((l_order, r_order), 0)
- self.cif_conv1d = nn.Conv1d(idim, idim, l_order + r_order + 1, groups=idim)
- self.cif_output = nn.Linear(idim, 1)
- self.dropout = torch.nn.Dropout(p=dropout)
- self.threshold = threshold
- self.smooth_factor = smooth_factor
- self.noise_threshold = noise_threshold
- self.return_accum = return_accum
-
- def cif(
- self,
- input: Tensor,
- alpha: Tensor,
- beta: float = 1.0,
- return_accum: bool = False,
- ) -> Tuple[Tensor, Tensor, Tensor, Tensor]:
- B, S, C = input.size()
- assert tuple(alpha.size()) == (B, S), f"{alpha.size()} != {(B, S)}"
-
- dtype = alpha.dtype
- alpha = alpha.float()
-
- alpha_sum = alpha.sum(1)
- feat_lengths = (alpha_sum / beta).floor().long()
- T = feat_lengths.max()
-
- # aggregate and integrate
- csum = alpha.cumsum(-1)
- with torch.no_grad():
- # indices used for scattering
- right_idx = (csum / beta).floor().long().clip(max=T)
- left_idx = right_idx.roll(1, dims=1)
- left_idx[:, 0] = 0
-
- # count # of fires from each source
- fire_num = right_idx - left_idx
- extra_weights = (fire_num - 1).clip(min=0)
- # The extra entry in last dim is for
- output = input.new_zeros((B, T + 1, C))
- source_range = torch.arange(1, 1 + S).unsqueeze(0).type_as(input)
- zero = alpha.new_zeros((1,))
-
- # right scatter
- fire_mask = fire_num > 0
- right_weight = torch.where(
- fire_mask,
- csum - right_idx.type_as(alpha) * beta,
- zero
- ).type_as(input)
- # assert right_weight.ge(0).all(), f"{right_weight} should be non-negative."
- output.scatter_add_(
- 1,
- right_idx.unsqueeze(-1).expand(-1, -1, C),
- right_weight.unsqueeze(-1) * input
- )
-
- # left scatter
- left_weight = (
- alpha - right_weight - extra_weights.type_as(alpha) * beta
- ).type_as(input)
- output.scatter_add_(
- 1,
- left_idx.unsqueeze(-1).expand(-1, -1, C),
- left_weight.unsqueeze(-1) * input
- )
-
- # extra scatters
- if extra_weights.ge(0).any():
- extra_steps = extra_weights.max().item()
- tgt_idx = left_idx
- src_feats = input * beta
- for _ in range(extra_steps):
- tgt_idx = (tgt_idx + 1).clip(max=T)
- # (B, S, 1)
- src_mask = (extra_weights > 0)
- output.scatter_add_(
- 1,
- tgt_idx.unsqueeze(-1).expand(-1, -1, C),
- src_feats * src_mask.unsqueeze(2)
- )
- extra_weights -= 1
-
- output = output[:, :T, :]
-
- if return_accum:
- return output, csum
- else:
- return output, alpha
-
- def forward(self, hidden, target_label=None, mask=None, ignore_id=-1, mask_chunk_predictor=None, target_label_length=None):
- h = hidden
- context = h.transpose(1, 2)
- queries = self.pad(context)
- memory = self.cif_conv1d(queries)
- output = memory + context
- output = self.dropout(output)
- output = output.transpose(1, 2)
- output = torch.relu(output)
- output = self.cif_output(output)
- alphas = torch.sigmoid(output)
- alphas = torch.nn.functional.relu(alphas*self.smooth_factor - self.noise_threshold)
- if mask is not None:
- alphas = alphas * mask.transpose(-1, -2).float()
- if mask_chunk_predictor is not None:
- alphas = alphas * mask_chunk_predictor
- alphas = alphas.squeeze(-1)
- if target_label_length is not None:
- target_length = target_label_length
- elif target_label is not None:
- target_length = (target_label != ignore_id).float().sum(-1)
- # logging.info("target_length: {}".format(target_length))
- else:
- target_length = None
- token_num = alphas.sum(-1)
- if target_length is not None:
- # length_noise = torch.rand(alphas.size(0), device=alphas.device) - 0.5
- # target_length = length_noise + target_length
- alphas *= ((target_length + 1e-4) / token_num)[:, None].repeat(1, alphas.size(1))
- acoustic_embeds, cif_peak = self.cif(hidden, alphas, self.threshold, self.return_accum)
- return acoustic_embeds, token_num, alphas, cif_peak
--
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