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monaural_source_separation.py
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monaural_source_separation.py
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#!/usr/bin/env python
# encoding: utf-8
"""
Author: Yuan-Ping Chen
Data: 2016/03/11
----------------------------------------------------------------------
Source separation: attenuate the accompaniments in order to emphasize
guitar solo.
----------------------------------------------------------------------
Args:
input_files: Audio files to be processed.
Only the wav files would be considered.
output_dir: Directory for storing the results.
Optional args:
Please refer to --help.
----------------------------------------------------------------------
Returns:
Guitar solo
Accompaniments
"""
import scipy.fftpack as fft
import numpy as np
from scipy.io import wavfile
from sys import float_info
import os, glob
def repet_ada(x,fs):
# Default adaptive parameters
par = [24,12,7]
# Default repeating period range
per = [0.8,min(8,par[0]/3.)]
# Analysis window length in seconds (audio stationary around 40 milliseconds)
alen = 0.040
# Analysis window length in samples (power of 2 for faster FFT)
N = 2**nextpow2(alen*fs)
# Analysis window (even N and 'periodic' Hamming for constant overlap-add)
win = np.hamming(N)
#win = np.reshape(win,(win.shape[0],1))
# Analysis step length (N/2 for constant overlap-add)
stp = N/2.
# Cutoff frequency in Hz for the dual high-pass filtering (e.g., singing voice rarely below 100 Hz)
cof = 100.
# Cutoff frequency in frequency bins for the dual high-pass filtering (DC component = bin 0)
cof = np.ceil(cof*(N-1)/fs)
# Number of samples
t = x.shape[0]
# Number of channels
try:
# multi channel files
k = x.shape[1]
except IndexError:
# catch mono files
k = 1
X = np.empty( (win.shape[0], int(np.ceil((N-stp+x.shape[0])/stp)), k), 'complex128')
if k>1:
# Loop over the channels
for i in range(k):
# Short-Time Fourier Transform (STFT) of channel i
X[:,:,i] = stft(x[:,i],win,stp)
else:
i = 0
X[:,:,i] = stft(x,win,stp)
# Magnitude spectrogram (with DC component and without mirrored frequencies)
V = abs(X[0:int(N/2+1),:,:])
# Repeating period in time frames (compensate for STFT zero-padding at the beginning)
per = map(lambda g: g*fs, per)
per = np.ceil((per+N/stp-1)/stp)
# per = np.ceil((per*fs+N/stp-1)/stp)
# Adaptive window length and step length in time frames
par[0] = round(par[0]*fs/stp)
par[1] = round(par[1]*fs/stp)
# Beat spectrogram of the mean power spectrograms
B = beat_spectrogram(np.mean(V**2,2),par[0],par[1])
# Repeating periods in time frames
P = repeating_periods(B,per)
y = np.zeros((t,k))
# Loop over the channels
for i in range(k):
# Repeating mask
Mi = repeating_mask(V[:,:,i],P,par[2])
# High-pass filtering of the (dual) non-repeating foreground
s = 1
e = 1+cof
Mi[int(s):int(e),:] = 1
# Mirror the frequencies
Mj = Mi[1:-1,:]
Mi = np.concatenate((Mi,Mj[::-1]),0)
# Estimated repeating background
yi = istft(Mi*X[:,:,i],win,stp)
# Truncate to the original length of the mixture
y[:,i] = yi[0:t]
if y.shape[1]==1:
# multi channel files
y = y.reshape(y.shape[0])
return y
"""
nextpow2(N) returns the first P such that 2.^P >= abs(N). It is
often useful for finding the nearest power of two sequence
length for FFT operations.
"""
def nextpow2(n):
m_f = np.log2(n)
m_i = np.ceil(m_f)
return m_i
"""
Short-Time Fourier Transform (STFT) using fft
X = stft(x,win,stp);
Input(s):
x: signal [t samples, 1]
win: analysis window [N samples, 1]
stp: analysis step
Output(s):
X: Short-Time Fourier Transform [N bins, m frames]
"""
def stft(x,win,stp):
# Number of samples
t = x.shape[0]
# Analysis window length
N = win.shape[0]
# Number of frames with zero-padding
m = np.ceil((N-stp+t)/stp)
# Zero-padding for constant overlap-add
x = np.r_[np.zeros(int(N-stp)), x, np.zeros(int(m*stp-t))]
X = np.zeros((N,int(m)),'complex128')
# Loop over the frames
for j in range(int(m)):
s = 0+stp*j
e = N+stp*j
# Windowing and fft
X[:,j] = fft.fft(x[int(s):int(e)]*win)
return X
"""
Inverse Short-Time Fourier Transform using ifft
x = istft(X,win,stp);
Input(s):
X: Short-Time Fourier Transform [N bins, m frames]
win: analysis window [N samples, 1]
stp: analysis step
Output(s):
x: signal [t samples, 1]
"""
def istft(X,win,stp):
# Number of frequency bins and time frames
N,m = X.shape
# Length with zero-padding
l = (m-1)*stp+N
x = np.zeros(int(l))
# Loop over the frames
for j in range(int(m)):
# Un-windowing and ifft (assuming constant overlap-add)
s = 0+stp*j
e = N+stp*j
x[int(s):int(e)] = x[int(s):int(e)]+np.real(fft.ifft(X[:,j]))
# Remove zero-padding at the beginning
x = x[0:int(l-(N-stp))]
# Remove zero-padding at the end
x = x[int(N-stp)::]
# Normalize constant overlap-add using win
x = x/np.sum(win[0:N:int(stp)])
return x
"""
Autocorrelation function using fft according to the WienerKhinchin theorem
C = acorr(X);
Input(s):
X: data matrix [n elements, m vectors]
Output(s):
C: autocorrelation matrix [n lags, m vectors]
"""
def acorr(X):
n,m = X.shape
# Zero-padding to twice the length for a proper autocorrelation
X = np.r_[X,np.zeros((n,m))]
# Power Spectral Density: PSD(X) = fft(X).*conj(fft(X))
X = abs(fft.fft(X,axis = 0))**2
# WienerKhinchin theorem: PSD(X) = fft(acorr(X))
C = abs(fft.ifft(X,axis = 0))
# Discard the symmetric part (lags n-1 to 1)
C = C[0:n,:]
# Unbiased autocorrelation (lags 0 to n-1)
T = np.arange(n,0,-1)
T = T.reshape(T.shape[0],1)
C = C/np.tile(T, [1,m])
return C
"""
Beat spectrum using the autocorrelation function
b = beat_spectrum(X);
Input(s):
X: spectrogram [n frequency bins, m time frames]
Output(s):
b: beat spectrum [1, m time lags]
"""
def beat_spectrum(X):
# Correlogram using acorr [m lags, n bins]
B = acorr(X.T)
g = B.dtype
# Mean along the frequency bins
b = np.mean(B,1)
return b
"""
Beat spectrogram using the beat_spectrum
B = beat_spectrogram(X,w,h);
Input(s):
X: spectrogram [n bins, m frames]
w: time window length
h: hop size
Output(s):
B: beat spectrogram [w lags, m frames] (lags from 0 to w-1)
"""
def beat_spectrogram(X,w,h):
# Number of frequency bins and time frames
n,m = X.shape
# Zero-padding to center windows
X = np.concatenate((np.zeros((n, int(np.ceil((w-1.)/2)) )), X, np.zeros((n, int(np.floor((w-1.)/2)) ))), 1)
B = np.zeros((int(w),m))
# Loop over the time frames (including the last one)
for j in range(0,m,int(h))+[m-1]:
# Beat spectrum of the windowed spectrogram centered on frame j
s = 0+j
e = w+j
B[:,j] = beat_spectrum(X[:,int(s):int(e)]).T
return B
"""
Repeating periods from the beat spectrogram
P = repeating_periods(B,r);
Input(s):
B: beat_spectrogram [l lags, m frames]
r: repeating period range in time frames [min lag, max lag]
Output(s):
P: repeating periods in time frames [1, m frames]
"""
def repeating_periods(B,r):
# Discard lags 0
B = B[1::,:]
# Beat spectrogram in the repeating period range
s = r[0]-1
e = r[1]
B = B[int(s):int(e),:]
# Maximum values in the repeating period range for all the frames
P = np.argmax(B,0)
# The repeating periods are estimated as the indices of the maximum values
P = P+r[0]
P = P.astype(int)
return P
"""
Repeating mask from the magnitude spectrogram and the repeating periods
M = repeating_mask(V,p,k);
Input(s):
V: magnitude spectrogram [n bins, m frames]
p: repeating periods in time frames [1, m frames]
k: order for the median filter
Output(s):
M: repeating (soft) mask in [0,1] [n bins, m frames]
"""
def repeating_mask(V,p,k):
# Number of frequency bins and time frames
n,m = V.shape
# Order vector centered in 0
k = np.arange(1,k+1)-int(np.ceil(k/2.))
W = np.zeros((n,m))
# Loop over the frames
for j in range(int(m)):
# Indices of the frames for the median filtering (e.g.: k=3 => i=[-1,0,1], k=4 => i=[-1,0,1,2])
i = j+k*p[j]
# Discard out-of-range indices
i = i[i>=0]
i = i[i<m]
# Median filter centered on frame j
W[:,j] = np.median(np.real(V[:,i.astype(int)]),1)
# For every time-frequency bins, we must have W <= V
W = np.minimum(V,W)
# Normalize W by V
eps = float_info.epsilon
M = (W+eps)/(V+eps)
return M
def parse_input_files(input_files, ext='.wav'):
"""
Collect all files by given extension and keywords.
:param agrs: class 'argparse.Namespace'.
:param ext: the string of file extension.
:returns: a list of stings of file name.
"""
from os.path import basename, isdir
import fnmatch
import glob
files = []
# check what we have (file/path)
if isdir(input_files):
# use all files with .raw.melody in the given path
files = fnmatch.filter(glob.glob(input_files+'/*'), '*'+ext)
else:
# file was given, append to list
if basename(input_files).find(ext)!=-1:
files.append(input_files)
print ' Input files: '
for f in files: print ' ', f
return files
def parser():
"""
Parses the command line arguments.
:param lgd: use local group delay weighting by default
:param threshold: default value for threshold
"""
import argparse
# define parser
p = argparse.ArgumentParser(
formatter_class=argparse.RawDescriptionHelpFormatter, description="""
REpeating Pattern Extraction Technique (REPET): adaptive REPET (thanks Antoine!)
REPET is a simple method for separating the repeating background
from the non-repeating foreground in an audio mixture.
REPET can be extended by locally modeling the repetitions.
Usage:
y = repet_ada(x,fs,per,par);
Input(s):
x: mixture data [t samples, k channels]
fs: sampling frequency in Hz
per: repeating period range (if two values)
or defined repeating period (if one value) in seconds
(default: [0.8,min(8,seg(1)/3)])
par: adaptive parameters (two values) (default: [24,12,7])
par(1): adaptive window length in seconds
par(2): adaptive step length in seconds
par(3): order for the median filter
Output(s):
y: repeating background [t samples, k channels]
(the corresponding non-repeating foreground is equal to x-y)
Example(s):
# Read some audio mixture
x, fs, nbits = scipy.io.wavfile.read('mixture.wav')
# Derives the repeating background using windows of 24 seconds, steps of 12 seconds, and order of 7
y = repet(x,fs,[0.8,8],[24,12,7])
# Write the repeating background
wavwrite(y,fs,nbits,'background.wav')
# Write the corresponding non-repeating foreground
wavwrite(x-y,fs,nbits,'foreground.wav')
See also http://music.eecs.northwestern.edu/research.php?project=repet
Author: Zafar Rafii ([email protected])
Update: September 2013
Copyright: Zafar Rafii and Bryan Pardo, Northwestern University
Reference(s):
[1]: Antoine Liutkus, Zafar Rafii, Roland Badeau, Bryan Pardo, and Gaël Richard.
"Adaptive Filtering for Music/Voice Separation Exploiting the Repeating Musical Structure,"
37th International Conference on Acoustics, Speech and Signal Processing,
Kyoto, Japan, March 25-30, 2012.
""")
# general options
p.add_argument('input_files', type=str, metavar='input_files',
help='files to be processed')
p.add_argument('output_dir', type=str, metavar='output_dir',
help='output directory.')
# version
p.add_argument('--version', action='version',
version='%(prog)spec 1.03 (2015-08-18)')
# parse arguments
args = p.parse_args()
# return args
return args
def main(args):
"""
Main adaptive Repeating Pattern Extraction Technique program.
:param args: parsed arguments
"""
print '====================================='
print 'Running monaural source separation...'
print '====================================='
# parse and list files to be processed
files = parse_input_files(args.input_files)
# create result directory
if not os.path.exists(args.output_dir): os.makedirs(args.output_dir)
print ' Output directory: ', '\n', ' ', args.output_dir
# processing
for f in files:
# parse file name and extension
ext = os.path.basename(f).split('.')[-1]
name = os.path.basename(f).split('.')[0]
# do the processing stuff
fs, x = wavfile.read(f)
# change data type int to float and normalization
x = x.astype(np.float)/np.max(x)
# execute main adaptive REPET function
y = repet_ada(x,fs)
z = x-y
z = z/(np.max(z)/2**15)
z = z.astype(np.int16)
wavfile.write(args.output_dir+os.sep+name+'_sep.wav',fs,z)
if __name__ == '__main__':
args = parser()
main(args)