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- import torch
- from typing import Tuple
- from typing import Union
- from funasr.modules.nets_utils import make_non_pad_mask
- from torch.nn import functional as F
- import math
- VAR2STD_EPSILON = 1e-12
- class StatisticPooling(torch.nn.Module):
- def __init__(self, pooling_dim: Union[int, Tuple] = 2, eps=1e-12):
- super(StatisticPooling, self).__init__()
- if isinstance(pooling_dim, int):
- pooling_dim = (pooling_dim, )
- self.pooling_dim = pooling_dim
- self.eps = eps
- def forward(self, xs_pad, ilens=None):
- # xs_pad in (Batch, Channel, Time, Frequency)
- if ilens is None:
- masks = torch.ones_like(xs_pad).to(xs_pad)
- else:
- masks = make_non_pad_mask(ilens, xs_pad, length_dim=2).to(xs_pad)
- mean = (torch.sum(xs_pad, dim=self.pooling_dim, keepdim=True) /
- torch.sum(masks, dim=self.pooling_dim, keepdim=True))
- squared_difference = torch.pow(xs_pad - mean, 2.0)
- variance = (torch.sum(squared_difference, dim=self.pooling_dim, keepdim=True) /
- torch.sum(masks, dim=self.pooling_dim, keepdim=True))
- for i in reversed(self.pooling_dim):
- mean, variance = torch.squeeze(mean, dim=i), torch.squeeze(variance, dim=i)
- mask = torch.less_equal(variance, self.eps).float()
- variance = (1.0 - mask) * variance + mask * self.eps
- stddev = torch.sqrt(variance)
- stat_pooling = torch.cat([mean, stddev], dim=1)
- return stat_pooling
- def convert_tf2torch(self, var_dict_tf, var_dict_torch):
- return {}
- def statistic_pooling(
- xs_pad: torch.Tensor,
- ilens: torch.Tensor = None,
- pooling_dim: Tuple = (2, 3)
- ) -> torch.Tensor:
- # xs_pad in (Batch, Channel, Time, Frequency)
- if ilens is None:
- seq_mask = torch.ones_like(xs_pad).to(xs_pad)
- else:
- seq_mask = make_non_pad_mask(ilens, xs_pad, length_dim=2).to(xs_pad)
- mean = (torch.sum(xs_pad, dim=pooling_dim, keepdim=True) /
- torch.sum(seq_mask, dim=pooling_dim, keepdim=True))
- squared_difference = torch.pow(xs_pad - mean, 2.0)
- variance = (torch.sum(squared_difference, dim=pooling_dim, keepdim=True) /
- torch.sum(seq_mask, dim=pooling_dim, keepdim=True))
- for i in reversed(pooling_dim):
- mean, variance = torch.squeeze(mean, dim=i), torch.squeeze(variance, dim=i)
- value_mask = torch.less_equal(variance, VAR2STD_EPSILON).float()
- variance = (1.0 - value_mask) * variance + value_mask * VAR2STD_EPSILON
- stddev = torch.sqrt(variance)
- stat_pooling = torch.cat([mean, stddev], dim=1)
- return stat_pooling
- def windowed_statistic_pooling(
- xs_pad: torch.Tensor,
- ilens: torch.Tensor = None,
- pooling_dim: Tuple = (2, 3),
- pooling_size: int = 20,
- pooling_stride: int = 1
- ) -> Tuple[torch.Tensor, int]:
- # xs_pad in (Batch, Channel, Time, Frequency)
- tt = xs_pad.shape[2]
- num_chunk = int(math.ceil(tt / pooling_stride))
- pad = pooling_size // 2
- if len(xs_pad.shape) == 4:
- features = F.pad(xs_pad, (0, 0, pad, pad), "reflect")
- else:
- features = F.pad(xs_pad, (pad, pad), "reflect")
- stat_list = []
- for i in range(num_chunk):
- # B x C
- st, ed = i*pooling_stride, i*pooling_stride+pooling_size
- stat = statistic_pooling(features[:, :, st: ed], pooling_dim=pooling_dim)
- stat_list.append(stat.unsqueeze(2))
- # B x C x T
- return torch.cat(stat_list, dim=2), ilens / pooling_stride
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