training/rnn_train.py - platform/external/rnnoise - Git at Google

 #!/usr/bin/python

 from __future__ import print_function

 import keras
 from keras.models import Sequential
 from keras.models import Model
 from keras.layers import Input
 from keras.layers import Dense
 from keras.layers import LSTM
 from keras.layers import GRU
 from keras.layers import SimpleRNN
 from keras.layers import Dropout
 from keras.layers import concatenate
 from keras import losses
 from keras import regularizers
 from keras.constraints import min_max_norm
 import h5py

 from keras.constraints import Constraint
 from keras import backend as K
 import numpy as np

 #import tensorflow as tf
 #from keras.backend.tensorflow_backend import set_session
 #config = tf.ConfigProto()
 #config.gpu_options.per_process_gpu_memory_fraction = 0.42
 #set_session(tf.Session(config=config))


 def my_crossentropy(y_true, y_pred):
     return K.mean(2*K.abs(y_true-0.5) * K.binary_crossentropy(y_pred, y_true), axis=-1)

 def mymask(y_true):
     return K.minimum(y_true+1., 1.)

 def msse(y_true, y_pred):
     return K.mean(mymask(y_true) * K.square(K.sqrt(y_pred) - K.sqrt(y_true)), axis=-1)

 def mycost(y_true, y_pred):
     return K.mean(mymask(y_true) * (10*K.square(K.square(K.sqrt(y_pred) - K.sqrt(y_true))) + K.square(K.sqrt(y_pred) - K.sqrt(y_true)) + 0.01*K.binary_crossentropy(y_pred, y_true)), axis=-1)

 def my_accuracy(y_true, y_pred):
     return K.mean(2*K.abs(y_true-0.5) * K.equal(y_true, K.round(y_pred)), axis=-1)

 class WeightClip(Constraint):
     '''Clips the weights incident to each hidden unit to be inside a range
     '''
     def __init__(self, c=2):
         self.c = c

     def __call__(self, p):
         return K.clip(p, -self.c, self.c)

     def get_config(self):
         return {'name': self.__class__.__name__,
             'c': self.c}

 reg = 0.000001
 constraint = WeightClip(0.499)

 print('Build model...')
 main_input = Input(shape=(None, 42), name='main_input')
 tmp = Dense(24, activation='tanh', name='input_dense', kernel_constraint=constraint, bias_constraint=constraint)(main_input)
 vad_gru = GRU(24, activation='tanh', recurrent_activation='sigmoid', return_sequences=True, name='vad_gru', kernel_regularizer=regularizers.l2(reg), recurrent_regularizer=regularizers.l2(reg), kernel_constraint=constraint, recurrent_constraint=constraint, bias_constraint=constraint)(tmp)
 vad_output = Dense(1, activation='sigmoid', name='vad_output', kernel_constraint=constraint, bias_constraint=constraint)(vad_gru)
 noise_input = keras.layers.concatenate([tmp, vad_gru, main_input])
 noise_gru = GRU(48, activation='relu', recurrent_activation='sigmoid', return_sequences=True, name='noise_gru', kernel_regularizer=regularizers.l2(reg), recurrent_regularizer=regularizers.l2(reg), kernel_constraint=constraint, recurrent_constraint=constraint, bias_constraint=constraint)(noise_input)
 denoise_input = keras.layers.concatenate([vad_gru, noise_gru, main_input])

 denoise_gru = GRU(96, activation='tanh', recurrent_activation='sigmoid', return_sequences=True, name='denoise_gru', kernel_regularizer=regularizers.l2(reg), recurrent_regularizer=regularizers.l2(reg), kernel_constraint=constraint, recurrent_constraint=constraint, bias_constraint=constraint)(denoise_input)

 denoise_output = Dense(22, activation='sigmoid', name='denoise_output', kernel_constraint=constraint, bias_constraint=constraint)(denoise_gru)

 model = Model(inputs=main_input, outputs=[denoise_output, vad_output])

 model.compile(loss=[mycost, my_crossentropy],
               metrics=[msse],
               optimizer='adam', loss_weights=[10, 0.5])


 batch_size = 32

 print('Loading data...')
 with h5py.File('training.h5', 'r') as hf:
     all_data = hf['data'][:]
 print('done.')

 window_size = 2000

 nb_sequences = len(all_data)//window_size
 print(nb_sequences, ' sequences')
 x_train = all_data[:nb_sequences*window_size, :42]
 x_train = np.reshape(x_train, (nb_sequences, window_size, 42))

 y_train = np.copy(all_data[:nb_sequences*window_size, 42:64])
 y_train = np.reshape(y_train, (nb_sequences, window_size, 22))

 noise_train = np.copy(all_data[:nb_sequences*window_size, 64:86])
 noise_train = np.reshape(noise_train, (nb_sequences, window_size, 22))

 vad_train = np.copy(all_data[:nb_sequences*window_size, 86:87])
 vad_train = np.reshape(vad_train, (nb_sequences, window_size, 1))

 all_data = 0;
 #x_train = x_train.astype('float32')
 #y_train = y_train.astype('float32')

 print(len(x_train), 'train sequences. x shape =', x_train.shape, 'y shape = ', y_train.shape)

 print('Train...')
 model.fit(x_train, [y_train, vad_train],
           batch_size=batch_size,
           epochs=120,
           validation_split=0.1)
 model.save("weights.hdf5")
	#!/usr/bin/python

	from __future__ import print_function

	import keras
	from keras.models import Sequential
	from keras.models import Model
	from keras.layers import Input
	from keras.layers import Dense
	from keras.layers import LSTM
	from keras.layers import GRU
	from keras.layers import SimpleRNN
	from keras.layers import Dropout
	from keras.layers import concatenate
	from keras import losses
	from keras import regularizers
	from keras.constraints import min_max_norm
	import h5py

	from keras.constraints import Constraint
	from keras import backend as K
	import numpy as np

	#import tensorflow as tf
	#from keras.backend.tensorflow_backend import set_session
	#config = tf.ConfigProto()
	#config.gpu_options.per_process_gpu_memory_fraction = 0.42
	#set_session(tf.Session(config=config))


	def my_crossentropy(y_true, y_pred):
	return K.mean(2K.abs(y_true-0.5) K.binary_crossentropy(y_pred, y_true), axis=-1)

	def mymask(y_true):
	return K.minimum(y_true+1., 1.)

	def msse(y_true, y_pred):
	return K.mean(mymask(y_true) * K.square(K.sqrt(y_pred) - K.sqrt(y_true)), axis=-1)

	def mycost(y_true, y_pred):
	return K.mean(mymask(y_true) * (10K.square(K.square(K.sqrt(y_pred) - K.sqrt(y_true))) + K.square(K.sqrt(y_pred) - K.sqrt(y_true)) + 0.01K.binary_crossentropy(y_pred, y_true)), axis=-1)

	def my_accuracy(y_true, y_pred):
	return K.mean(2K.abs(y_true-0.5) K.equal(y_true, K.round(y_pred)), axis=-1)

	class WeightClip(Constraint):
	'''Clips the weights incident to each hidden unit to be inside a range
	'''
	def __init__(self, c=2):
	self.c = c

	def __call__(self, p):
	return K.clip(p, -self.c, self.c)

	def get_config(self):
	return {'name': self.__class__.__name__,
	'c': self.c}

	reg = 0.000001
	constraint = WeightClip(0.499)

	print('Build model...')
	main_input = Input(shape=(None, 42), name='main_input')
	tmp = Dense(24, activation='tanh', name='input_dense', kernel_constraint=constraint, bias_constraint=constraint)(main_input)
	vad_gru = GRU(24, activation='tanh', recurrent_activation='sigmoid', return_sequences=True, name='vad_gru', kernel_regularizer=regularizers.l2(reg), recurrent_regularizer=regularizers.l2(reg), kernel_constraint=constraint, recurrent_constraint=constraint, bias_constraint=constraint)(tmp)
	vad_output = Dense(1, activation='sigmoid', name='vad_output', kernel_constraint=constraint, bias_constraint=constraint)(vad_gru)
	noise_input = keras.layers.concatenate([tmp, vad_gru, main_input])
	noise_gru = GRU(48, activation='relu', recurrent_activation='sigmoid', return_sequences=True, name='noise_gru', kernel_regularizer=regularizers.l2(reg), recurrent_regularizer=regularizers.l2(reg), kernel_constraint=constraint, recurrent_constraint=constraint, bias_constraint=constraint)(noise_input)
	denoise_input = keras.layers.concatenate([vad_gru, noise_gru, main_input])

	denoise_gru = GRU(96, activation='tanh', recurrent_activation='sigmoid', return_sequences=True, name='denoise_gru', kernel_regularizer=regularizers.l2(reg), recurrent_regularizer=regularizers.l2(reg), kernel_constraint=constraint, recurrent_constraint=constraint, bias_constraint=constraint)(denoise_input)

	denoise_output = Dense(22, activation='sigmoid', name='denoise_output', kernel_constraint=constraint, bias_constraint=constraint)(denoise_gru)

	model = Model(inputs=main_input, outputs=[denoise_output, vad_output])

	model.compile(loss=[mycost, my_crossentropy],
	metrics=[msse],
	optimizer='adam', loss_weights=[10, 0.5])


	batch_size = 32

	print('Loading data...')
	with h5py.File('training.h5', 'r') as hf:
	all_data = hf['data'][:]
	print('done.')

	window_size = 2000

	nb_sequences = len(all_data)//window_size
	print(nb_sequences, ' sequences')
	x_train = all_data[:nb_sequences*window_size, :42]
	x_train = np.reshape(x_train, (nb_sequences, window_size, 42))

	y_train = np.copy(all_data[:nb_sequences*window_size, 42:64])
	y_train = np.reshape(y_train, (nb_sequences, window_size, 22))

	noise_train = np.copy(all_data[:nb_sequences*window_size, 64:86])
	noise_train = np.reshape(noise_train, (nb_sequences, window_size, 22))

	vad_train = np.copy(all_data[:nb_sequences*window_size, 86:87])
	vad_train = np.reshape(vad_train, (nb_sequences, window_size, 1))

	all_data = 0;
	#x_train = x_train.astype('float32')
	#y_train = y_train.astype('float32')

	print(len(x_train), 'train sequences. x shape =', x_train.shape, 'y shape = ', y_train.shape)

	print('Train...')
	model.fit(x_train, [y_train, vad_train],
	batch_size=batch_size,
	epochs=120,
	validation_split=0.1)
	model.save("weights.hdf5")