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dnn_models.py
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dnn_models.py
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import numpy as np
import torch
import torch.nn.functional as F
import torch.nn as nn
import sys
from torch.autograd import Variable
import math
def flip(x, dim):
xsize = x.size()
dim = x.dim() + dim if dim < 0 else dim
x = x.contiguous()
x = x.view(-1, *xsize[dim:])
x = x.view(x.size(0), x.size(1), -1)[:, getattr(torch.arange(x.size(1)-1,
-1, -1), ('cpu','cuda')[x.is_cuda])().long(), :]
return x.view(xsize)
def sinc(band,t_right):
y_right= torch.sin(2*math.pi*band*t_right)/(2*math.pi*band*t_right)
y_left= flip(y_right,0)
y=torch.cat([y_left,Variable(torch.ones(1)).cuda(),y_right])
return y
class SincConv_fast(nn.Module):
"""Sinc-based convolution
Parameters
----------
in_channels : `int`
Number of input channels. Must be 1.
out_channels : `int`
Number of filters.
kernel_size : `int`
Filter length.
sample_rate : `int`, optional
Sample rate. Defaults to 16000.
Usage
-----
See `torch.nn.Conv1d`
Reference
---------
Mirco Ravanelli, Yoshua Bengio,
"Speaker Recognition from raw waveform with SincNet".
https://arxiv.org/abs/1808.00158
"""
@staticmethod
def to_mel(hz):
return 2595 * np.log10(1 + hz / 700)
@staticmethod
def to_hz(mel):
return 700 * (10 ** (mel / 2595) - 1)
def __init__(self, out_channels, kernel_size, sample_rate=16000, in_channels=1,
stride=1, padding=0, dilation=1, bias=False, groups=1, min_low_hz=50, min_band_hz=50):
super(SincConv_fast,self).__init__()
if in_channels != 1:
#msg = (f'SincConv only support one input channel '
# f'(here, in_channels = {in_channels:d}).')
msg = "SincConv only support one input channel (here, in_channels = {%i})" % (in_channels)
raise ValueError(msg)
self.out_channels = out_channels
self.kernel_size = kernel_size
# Forcing the filters to be odd (i.e, perfectly symmetrics)
if kernel_size%2==0:
self.kernel_size=self.kernel_size+1
self.stride = stride
self.padding = padding
self.dilation = dilation
if bias:
raise ValueError('SincConv does not support bias.')
if groups > 1:
raise ValueError('SincConv does not support groups.')
self.sample_rate = sample_rate
self.min_low_hz = min_low_hz
self.min_band_hz = min_band_hz
# initialize filterbanks such that they are equally spaced in Mel scale
low_hz = 30
high_hz = self.sample_rate / 2 - (self.min_low_hz + self.min_band_hz)
mel = np.linspace(self.to_mel(low_hz),
self.to_mel(high_hz),
self.out_channels + 1)
hz = self.to_hz(mel)
# filter lower frequency (out_channels, 1)
self.low_hz_ = nn.Parameter(torch.Tensor(hz[:-1]).view(-1, 1))
# filter frequency band (out_channels, 1)
self.band_hz_ = nn.Parameter(torch.Tensor(np.diff(hz)).view(-1, 1))
# Hamming window
#self.window_ = torch.hamming_window(self.kernel_size)
n_lin=torch.linspace(0, (self.kernel_size/2)-1, steps=int((self.kernel_size/2))) # computing only half of the window
self.window_=0.54-0.46*torch.cos(2*math.pi*n_lin/self.kernel_size);
# (1, kernel_size/2)
n = (self.kernel_size - 1) / 2.0
self.n_ = 2*math.pi*torch.arange(-n, 0).view(1, -1) / self.sample_rate # Due to symmetry, I only need half of the time axes
def forward(self, waveforms):
"""
Parameters
----------
waveforms : `torch.Tensor` (batch_size, 1, n_samples)
Batch of waveforms.
Returns
-------
features : `torch.Tensor` (batch_size, out_channels, n_samples_out)
Batch of sinc filters activations.
"""
self.n_ = self.n_.to(waveforms.device)
self.window_ = self.window_.to(waveforms.device)
low = self.min_low_hz + torch.abs(self.low_hz_)
high = torch.clamp(low + self.min_band_hz + torch.abs(self.band_hz_),self.min_low_hz,self.sample_rate/2)
band=(high-low)[:,0]
f_times_t_low = torch.matmul(low, self.n_)
f_times_t_high = torch.matmul(high, self.n_)
band_pass_left=((torch.sin(f_times_t_high)-torch.sin(f_times_t_low))/(self.n_/2))*self.window_ # Equivalent of Eq.4 of the reference paper (SPEAKER RECOGNITION FROM RAW WAVEFORM WITH SINCNET). I just have expanded the sinc and simplified the terms. This way I avoid several useless computations.
band_pass_center = 2*band.view(-1,1)
band_pass_right= torch.flip(band_pass_left,dims=[1])
band_pass=torch.cat([band_pass_left,band_pass_center,band_pass_right],dim=1)
band_pass = band_pass / (2*band[:,None])
self.filters = (band_pass).view(
self.out_channels, 1, self.kernel_size)
return F.conv1d(waveforms, self.filters, stride=self.stride,
padding=self.padding, dilation=self.dilation,
bias=None, groups=1)
class sinc_conv(nn.Module):
def __init__(self, N_filt,Filt_dim,fs):
super(sinc_conv,self).__init__()
# Mel Initialization of the filterbanks
low_freq_mel = 80
high_freq_mel = (2595 * np.log10(1 + (fs / 2) / 700)) # Convert Hz to Mel
mel_points = np.linspace(low_freq_mel, high_freq_mel, N_filt) # Equally spaced in Mel scale
f_cos = (700 * (10**(mel_points / 2595) - 1)) # Convert Mel to Hz
b1=np.roll(f_cos,1)
b2=np.roll(f_cos,-1)
b1[0]=30
b2[-1]=(fs/2)-100
self.freq_scale=fs*1.0
self.filt_b1 = nn.Parameter(torch.from_numpy(b1/self.freq_scale))
self.filt_band = nn.Parameter(torch.from_numpy((b2-b1)/self.freq_scale))
self.N_filt=N_filt
self.Filt_dim=Filt_dim
self.fs=fs
def forward(self, x):
filters=Variable(torch.zeros((self.N_filt,self.Filt_dim))).cuda()
N=self.Filt_dim
t_right=Variable(torch.linspace(1, (N-1)/2, steps=int((N-1)/2))/self.fs).cuda()
min_freq=50.0;
min_band=50.0;
filt_beg_freq=torch.abs(self.filt_b1)+min_freq/self.freq_scale
filt_end_freq=filt_beg_freq+(torch.abs(self.filt_band)+min_band/self.freq_scale)
n=torch.linspace(0, N, steps=N)
# Filter window (hamming)
window=0.54-0.46*torch.cos(2*math.pi*n/N);
window=Variable(window.float().cuda())
for i in range(self.N_filt):
low_pass1 = 2*filt_beg_freq[i].float()*sinc(filt_beg_freq[i].float()*self.freq_scale,t_right)
low_pass2 = 2*filt_end_freq[i].float()*sinc(filt_end_freq[i].float()*self.freq_scale,t_right)
band_pass=(low_pass2-low_pass1)
band_pass=band_pass/torch.max(band_pass)
filters[i,:]=band_pass.cuda()*window
out=F.conv1d(x, filters.view(self.N_filt,1,self.Filt_dim))
return out
def act_fun(act_type):
if act_type=="relu":
return nn.ReLU()
if act_type=="tanh":
return nn.Tanh()
if act_type=="sigmoid":
return nn.Sigmoid()
if act_type=="leaky_relu":
return nn.LeakyReLU(0.2)
if act_type=="elu":
return nn.ELU()
if act_type=="softmax":
return nn.LogSoftmax(dim=1)
if act_type=="linear":
return nn.LeakyReLU(1) # initializzed like this, but not used in forward!
class LayerNorm(nn.Module):
def __init__(self, features, eps=1e-6):
super(LayerNorm,self).__init__()
self.gamma = nn.Parameter(torch.ones(features))
self.beta = nn.Parameter(torch.zeros(features))
self.eps = eps
def forward(self, x):
mean = x.mean(-1, keepdim=True)
std = x.std(-1, keepdim=True)
return self.gamma * (x - mean) / (std + self.eps) + self.beta
class MLP(nn.Module):
def __init__(self, options):
super(MLP, self).__init__()
self.input_dim=int(options['input_dim'])
self.fc_lay=options['fc_lay']
self.fc_drop=options['fc_drop']
self.fc_use_batchnorm=options['fc_use_batchnorm']
self.fc_use_laynorm=options['fc_use_laynorm']
self.fc_use_laynorm_inp=options['fc_use_laynorm_inp']
self.fc_use_batchnorm_inp=options['fc_use_batchnorm_inp']
self.fc_act=options['fc_act']
self.wx = nn.ModuleList([])
self.bn = nn.ModuleList([])
self.ln = nn.ModuleList([])
self.act = nn.ModuleList([])
self.drop = nn.ModuleList([])
# input layer normalization
if self.fc_use_laynorm_inp:
self.ln0=LayerNorm(self.input_dim)
# input batch normalization
if self.fc_use_batchnorm_inp:
self.bn0=nn.BatchNorm1d([self.input_dim],momentum=0.05)
self.N_fc_lay=len(self.fc_lay)
current_input=self.input_dim
# Initialization of hidden layers
for i in range(self.N_fc_lay):
# dropout
self.drop.append(nn.Dropout(p=self.fc_drop[i]))
# activation
self.act.append(act_fun(self.fc_act[i]))
add_bias=True
# layer norm initialization
self.ln.append(LayerNorm(self.fc_lay[i]))
self.bn.append(nn.BatchNorm1d(self.fc_lay[i],momentum=0.05))
if self.fc_use_laynorm[i] or self.fc_use_batchnorm[i]:
add_bias=False
# Linear operations
self.wx.append(nn.Linear(current_input, self.fc_lay[i],bias=add_bias))
# weight initialization
self.wx[i].weight = torch.nn.Parameter(torch.Tensor(self.fc_lay[i],current_input).uniform_(-np.sqrt(0.01/(current_input+self.fc_lay[i])),np.sqrt(0.01/(current_input+self.fc_lay[i]))))
self.wx[i].bias = torch.nn.Parameter(torch.zeros(self.fc_lay[i]))
current_input=self.fc_lay[i]
def forward(self, x):
# Applying Layer/Batch Norm
if bool(self.fc_use_laynorm_inp):
x=self.ln0((x))
if bool(self.fc_use_batchnorm_inp):
x=self.bn0((x))
for i in range(self.N_fc_lay):
if self.fc_act[i]!='linear':
if self.fc_use_laynorm[i]:
x = self.drop[i](self.act[i](self.ln[i](self.wx[i](x))))
if self.fc_use_batchnorm[i]:
x = self.drop[i](self.act[i](self.bn[i](self.wx[i](x))))
if self.fc_use_batchnorm[i]==False and self.fc_use_laynorm[i]==False:
x = self.drop[i](self.act[i](self.wx[i](x)))
else:
if self.fc_use_laynorm[i]:
x = self.drop[i](self.ln[i](self.wx[i](x)))
if self.fc_use_batchnorm[i]:
x = self.drop[i](self.bn[i](self.wx[i](x)))
if self.fc_use_batchnorm[i]==False and self.fc_use_laynorm[i]==False:
x = self.drop[i](self.wx[i](x))
return x
class SincNet(nn.Module):
def __init__(self,options):
super(SincNet,self).__init__()
self.cnn_N_filt=options['cnn_N_filt']
self.cnn_len_filt=options['cnn_len_filt']
self.cnn_max_pool_len=options['cnn_max_pool_len']
self.cnn_act=options['cnn_act']
self.cnn_drop=options['cnn_drop']
self.cnn_use_laynorm=options['cnn_use_laynorm']
self.cnn_use_batchnorm=options['cnn_use_batchnorm']
self.cnn_use_laynorm_inp=options['cnn_use_laynorm_inp']
self.cnn_use_batchnorm_inp=options['cnn_use_batchnorm_inp']
self.input_dim=int(options['input_dim'])
self.fs=options['fs']
self.N_cnn_lay=len(options['cnn_N_filt'])
self.conv = nn.ModuleList([])
self.bn = nn.ModuleList([])
self.ln = nn.ModuleList([])
self.act = nn.ModuleList([])
self.drop = nn.ModuleList([])
if self.cnn_use_laynorm_inp:
self.ln0=LayerNorm(self.input_dim)
if self.cnn_use_batchnorm_inp:
self.bn0=nn.BatchNorm1d([self.input_dim],momentum=0.05)
current_input=self.input_dim
for i in range(self.N_cnn_lay):
N_filt=int(self.cnn_N_filt[i])
len_filt=int(self.cnn_len_filt[i])
# dropout
self.drop.append(nn.Dropout(p=self.cnn_drop[i]))
# activation
self.act.append(act_fun(self.cnn_act[i]))
# layer norm initialization
self.ln.append(LayerNorm([N_filt,int((current_input-self.cnn_len_filt[i]+1)/self.cnn_max_pool_len[i])]))
self.bn.append(nn.BatchNorm1d(N_filt,int((current_input-self.cnn_len_filt[i]+1)/self.cnn_max_pool_len[i]),momentum=0.05))
if i==0:
self.conv.append(SincConv_fast(self.cnn_N_filt[0],self.cnn_len_filt[0],self.fs))
else:
self.conv.append(nn.Conv1d(self.cnn_N_filt[i-1], self.cnn_N_filt[i], self.cnn_len_filt[i]))
current_input=int((current_input-self.cnn_len_filt[i]+1)/self.cnn_max_pool_len[i])
self.out_dim=current_input*N_filt
def forward(self, x):
batch=x.shape[0]
seq_len=x.shape[1]
if bool(self.cnn_use_laynorm_inp):
x=self.ln0((x))
if bool(self.cnn_use_batchnorm_inp):
x=self.bn0((x))
x=x.view(batch,1,seq_len)
for i in range(self.N_cnn_lay):
if self.cnn_use_laynorm[i]:
if i==0:
x = self.drop[i](self.act[i](self.ln[i](F.max_pool1d(torch.abs(self.conv[i](x)), self.cnn_max_pool_len[i]))))
else:
x = self.drop[i](self.act[i](self.ln[i](F.max_pool1d(self.conv[i](x), self.cnn_max_pool_len[i]))))
if self.cnn_use_batchnorm[i]:
x = self.drop[i](self.act[i](self.bn[i](F.max_pool1d(self.conv[i](x), self.cnn_max_pool_len[i]))))
if self.cnn_use_batchnorm[i]==False and self.cnn_use_laynorm[i]==False:
x = self.drop[i](self.act[i](F.max_pool1d(self.conv[i](x), self.cnn_max_pool_len[i])))
x = x.view(batch,-1)
return x