def __init__(self,
x_mag_spec_batch,
lengths_batch,
y_mag_spec_batch=None,
theta_x_batch=None,
theta_y_batch=None,
behavior='train'):
'''
behavior = 'train/validation/infer'
'''
if behavior != self.infer:
assert(y_mag_spec_batch is not None)
assert(theta_x_batch is not None)
assert(theta_y_batch is not None)
self._log_bias = tf.get_variable('logbias', [1], trainable=FLAGS.PARAM.LOG_BIAS_TRAINABLE,
initializer=tf.constant_initializer(FLAGS.PARAM.INIT_LOG_BIAS))
self._real_logbias = self._log_bias + FLAGS.PARAM.MIN_LOG_BIAS
self._x_mag_spec = x_mag_spec_batch
self._norm_x_mag_spec = norm_mag_spec(self._x_mag_spec, FLAGS.PARAM.MAG_NORM_MAX)
self._norm_x_logmag_spec = norm_logmag_spec(self._x_mag_spec, FLAGS.PARAM.MAG_NORM_MAX, self._log_bias, FLAGS.PARAM.MIN_LOG_BIAS)
self._y_mag_spec = y_mag_spec_batch
self._norm_y_mag_spec = norm_mag_spec(self._y_mag_spec, FLAGS.PARAM.MAG_NORM_MAX)
self._norm_y_logmag_spec = norm_logmag_spec(self._y_mag_spec, FLAGS.PARAM.MAG_NORM_MAX, self._log_bias, FLAGS.PARAM.MIN_LOG_BIAS)
self._lengths = lengths_batch
self._batch_size = tf.shape(self._lengths)[0]
self._x_theta = theta_x_batch
self._y_theta = theta_y_batch
self._model_type = FLAGS.PARAM.MODEL_TYPE
if FLAGS.PARAM.INPUT_TYPE == 'mag':
self.net_input = self._norm_x_mag_spec
elif FLAGS.PARAM.INPUT_TYPE == 'logmag':
self.net_input = self._norm_x_logmag_spec
if FLAGS.PARAM.LABEL_TYPE == 'mag':
self._y_labels = self._norm_y_mag_spec
elif FLAGS.PARAM.LABEL_TYPE == 'logmag':
self._y_labels = self._norm_y_logmag_spec
outputs = self.net_input
lstm_attn_cell = lstm_cell
if behavior != self.infer and FLAGS.PARAM.KEEP_PROB < 1.0:
def lstm_attn_cell(n_units, n_proj, act):
return tf.contrib.rnn.DropoutWrapper(lstm_cell(n_units, n_proj, act),
output_keep_prob=FLAGS.PARAM.KEEP_PROB)
GRU_attn_cell = GRU_cell
if behavior != self.infer and FLAGS.PARAM.KEEP_PROB < 1.0:
def GRU_attn_cell(n_units, act):
return tf.contrib.rnn.DropoutWrapper(GRU_cell(n_units, act),
output_keep_prob=FLAGS.PARAM.KEEP_PROB)
if FLAGS.PARAM.MODEL_TYPE.upper() == 'BLSTM':
with tf.variable_scope('BLSTM'):
lstm_fw_cell = tf.contrib.rnn.MultiRNNCell(
[lstm_attn_cell(FLAGS.PARAM.RNN_SIZE,
FLAGS.PARAM.LSTM_num_proj,
FLAGS.PARAM.LSTM_ACTIVATION) for _ in range(FLAGS.PARAM.RNN_LAYER)], state_is_tuple=True)
lstm_bw_cell = tf.contrib.rnn.MultiRNNCell(
[lstm_attn_cell(FLAGS.PARAM.RNN_SIZE,
FLAGS.PARAM.LSTM_num_proj,
FLAGS.PARAM.LSTM_ACTIVATION) for _ in range(FLAGS.PARAM.RNN_LAYER)], state_is_tuple=True)
fw_cell = lstm_fw_cell._cells
bw_cell = lstm_bw_cell._cells
result = rnn.stack_bidirectional_dynamic_rnn(
cells_fw=fw_cell,
cells_bw=bw_cell,
inputs=outputs,
dtype=tf.float32,
sequence_length=self._lengths)
outputs, fw_final_states, bw_final_states = result
if FLAGS.PARAM.MODEL_TYPE.upper() == 'BGRU':
with tf.variable_scope('BGRU'):
gru_fw_cell = tf.contrib.rnn.MultiRNNCell(
[GRU_attn_cell(FLAGS.PARAM.RNN_SIZE,
FLAGS.PARAM.LSTM_ACTIVATION) for _ in range(FLAGS.PARAM.RNN_LAYER)], state_is_tuple=True)
gru_bw_cell = tf.contrib.rnn.MultiRNNCell(
[GRU_attn_cell(FLAGS.PARAM.RNN_SIZE,
FLAGS.PARAM.LSTM_ACTIVATION) for _ in range(FLAGS.PARAM.RNN_LAYER)], state_is_tuple=True)
fw_cell = gru_fw_cell._cells
bw_cell = gru_bw_cell._cells
result = rnn.stack_bidirectional_dynamic_rnn(
cells_fw=fw_cell,
cells_bw=bw_cell,
inputs=outputs,
dtype=tf.float32,
sequence_length=self._lengths)
outputs, fw_final_states, bw_final_states = result
# region full connection get mask
# calcu rnn output size
in_size = FLAGS.PARAM.RNN_SIZE
mask = None
if self._model_type.upper()[0] == 'B': # bidirection
rnn_output_num = FLAGS.PARAM.RNN_SIZE*2
if FLAGS.PARAM.MODEL_TYPE == 'BLSTM' and (not (FLAGS.PARAM.LSTM_num_proj is None)):
rnn_output_num = 2*FLAGS.PARAM.LSTM_num_proj
in_size = rnn_output_num
outputs = tf.reshape(outputs, [-1, in_size])
out_size = FLAGS.PARAM.OUTPUT_SIZE
with tf.variable_scope('fullconnectOut'):
weights = tf.get_variable('weights1', [in_size, out_size],
initializer=tf.random_normal_initializer(stddev=0.01))
biases = tf.get_variable('biases1', [out_size],
initializer=tf.constant_initializer(0.0))
mask = tf.nn.relu(tf.matmul(outputs, weights) + biases)
self._mask = tf.reshape(
mask, [self._batch_size, -1, FLAGS.PARAM.OUTPUT_SIZE])
# endregion
outputs = tf.reshape(outputs, [self._batch_size, -1, in_size])
# region Apply Noise Threshold Function on Mask
if FLAGS.PARAM.THRESHOLD_FUNC is not None:
# use noise threshold
if FLAGS.PARAM.THRESHOLD_POS == FLAGS.PARAM.THRESHOLD_ON_MASK:
self._mask, self._threshold = threshold_feature(self._mask, outputs,
self._batch_size, in_size)
elif FLAGS.PARAM.THRESHOLD_POS == FLAGS.PARAM.THRESHOLD_ON_SPEC:
pass
else:
print('Threshold position error!')
exit(-1)
# endregion
# region prepare y_estimation and y_labels
if FLAGS.PARAM.TRAINING_MASK_POSITION == 'mag':
self._y_estimation = self._mask*self._norm_x_mag_spec
elif FLAGS.PARAM.TRAINING_MASK_POSITION == 'logmag':
self._y_estimation = self._mask*self._norm_x_logmag_spec
if FLAGS.PARAM.MASK_TYPE == 'PSM':
self._y_labels *= tf.cos(self._x_theta-self._y_theta)
elif FLAGS.PARAM.MASK_TYPE == 'IRM':
pass
else:
tf.logging.error('Mask type error.')
exit(-1)
# region Apply Noise Threshold Function on Spec(log or mag)
if FLAGS.PARAM.THRESHOLD_FUNC is not None:
# use noise threshold
if FLAGS.PARAM.THRESHOLD_POS == FLAGS.PARAM.THRESHOLD_ON_MASK:
pass
elif FLAGS.PARAM.THRESHOLD_POS == FLAGS.PARAM.THRESHOLD_ON_SPEC:
self._y_estimation, self._threshold = threshold_feature(self._y_estimation, outputs,
self._batch_size, in_size)
# endregion
# region get infer spec
if FLAGS.PARAM.DECODING_MASK_POSITION != FLAGS.PARAM.TRAINING_MASK_POSITION:
print('Error, DECODING_MASK_POSITION should be equal to TRAINING_MASK_POSITION when use thresohold model.')
if FLAGS.PARAM.DECODING_MASK_POSITION == 'mag':
self._y_mag_estimation = rm_norm_mag_spec(self._y_estimation, FLAGS.PARAM.MAG_NORM_MAX)
elif FLAGS.PARAM.DECODING_MASK_POSITION == 'logmag':
self._y_mag_estimation = rm_norm_logmag_spec(self._y_estimation,
FLAGS.PARAM.MAG_NORM_MAX,
self._log_bias, FLAGS.PARAM.MIN_LOG_BIAS)
'''
_y_mag_estimation is estimated mag_spec
_y_estimation is loss_targe, mag_sepec or logmag_spec
'''
# endregion
if FLAGS.PARAM.TRAINING_MASK_POSITION != FLAGS.PARAM.LABEL_TYPE:
if FLAGS.PARAM.LABEL_TYPE == 'mag':
self._y_estimation = normedLogmag2normedMag(self._y_estimation, FLAGS.PARAM.MAG_NORM_MAX,
self._log_bias, FLAGS.PARAM.MIN_LOG_BIAS)
elif FLAGS.PARAM.LABEL_TYPE == 'logmag':
self._y_estimation = normedMag2normedLogmag(self._y_estimation, FLAGS.PARAM.MAG_NORM_MAX,
self._log_bias, FLAGS.PARAM.MIN_LOG_BIAS)
# endregion
self.saver = tf.train.Saver(tf.trainable_variables(), max_to_keep=30)
if behavior == self.infer:
return
# region get LOSS
if FLAGS.PARAM.LOSS_FUNC_FOR_MAG_SPEC == 'SPEC_MSE': # log_mag and mag MSE
self._loss = loss.reduce_sum_frame_batchsize_MSE(self._y_estimation,self._y_labels)
elif FLAGS.PARAM.LOSS_FUNC_FOR_MAG_SPEC == 'MFCC_SPEC_MSE':
self._loss1, self._loss2 = loss.balanced_MFCC_AND_SPEC_MSE(self._y_estimation, self._y_labels,
self._y_mag_estimation, self._y_mag_spec)
self._loss = FLAGS.PARAM.SPEC_LOSS_COEF*self._loss1 + FLAGS.PARAM.MFCC_LOSS_COEF*self._loss2
elif FLAGS.PARAM.LOSS_FUNC_FOR_MAG_SPEC == 'MEL_MAG_MSE':
self._loss1, self._loss2 = loss.balanced_MEL_AND_SPEC_MSE(self._y_estimation, self._y_labels,
self._y_mag_estimation, self._y_mag_spec)
self._loss = FLAGS.PARAM.SPEC_LOSS_COEF*self._loss1 + FLAGS.PARAM.MEL_LOSS_COEF*self._loss2
elif FLAGS.PARAM.LOSS_FUNC_FOR_MAG_SPEC == "SPEC_MSE_LOWF_EN":
self._loss = loss.reduce_sum_frame_batchsize_MSE(self._y_estimation, self._y_labels)
elif FLAGS.PARAM.LOSS_FUNC_FOR_MAG_SPEC == "FAIR_SPEC_MSE":
self._loss = loss.fair_reduce_sum_frame_batchsize_MSE(self._y_estimation, self._y_labels)
elif FLAGS.PARAM.LOSS_FUNC_FOR_MAG_SPEC == "SPEC_MSE_FLEXIBLE_POW_C":
self._loss = loss.reduce_sum_frame_batchsize_MSE_EmphasizeLowerValue(self._y_estimation,
self._y_labels,
FLAGS.PARAM.POW_COEF)
else:
print('Loss type error.')
exit(-1)
# endregion
if behavior == self.validation:
'''
val model cannot train.
'''
return
self._lr = tf.Variable(0.0, trainable=False)
tvars = tf.trainable_variables()
grads, _ = tf.clip_by_global_norm(tf.gradients(self.loss, tvars),
FLAGS.PARAM.CLIP_NORM)
optimizer = tf.train.AdamOptimizer(self.lr)
#optimizer = tf.train.GradientDescentOptimizer(self.lr)
self._train_op = optimizer.apply_gradients(zip(grads, tvars))
self._new_lr = tf.placeholder(
tf.float32, shape=[], name='new_learning_rate')
self._lr_update = tf.assign(self._lr, self._new_lr)
def __init__(self,
x_mag_spec_batch,
lengths_batch,
y_mag_spec_batch=None,
theta_x_batch=None,
theta_y_batch=None,
behavior='train'):
'''
behavior = 'train/validation/infer'
'''
assert (theta_x_batch is not None)
if behavior != self.infer:
assert (y_mag_spec_batch is not None)
assert (theta_y_batch is not None)
self._x_mag_spec = x_mag_spec_batch
self._norm_x_mag_spec = norm_mag_spec(self._x_mag_spec,
FLAGS.PARAM.MAG_NORM_MAX)
self._y_mag_spec = y_mag_spec_batch
self._norm_y_mag_spec = norm_mag_spec(self._y_mag_spec,
FLAGS.PARAM.MAG_NORM_MAX)
self._lengths = lengths_batch
self._batch_size = tf.shape(self._lengths)[0]
self._x_theta = theta_x_batch
self._y_theta = theta_y_batch
# self._norm_x_theta = self._x_theta/(2.0*FLAGS.PARAM.PI)+0.5
# self._norm_y_theta = self._y_theta/(2.0*FLAGS.PARAM.PI)+0.5
self._model_type = FLAGS.PARAM.MODEL_TYPE
self.net_input = tf.concat([self._norm_x_mag_spec, self._x_theta],
axis=-1)
self._y_mag_labels = self._norm_y_mag_spec
# self._y_theta_labels = self._norm_y_theta
self._y_theta_labels = self._y_theta
outputs = self.net_input
lstm_attn_cell = lstm_cell
if behavior != self.infer and FLAGS.PARAM.KEEP_PROB < 1.0:
def lstm_attn_cell(n_units, n_proj, act):
return tf.contrib.rnn.DropoutWrapper(
lstm_cell(n_units, n_proj, act),
output_keep_prob=FLAGS.PARAM.KEEP_PROB)
GRU_attn_cell = GRU_cell
if behavior != self.infer and FLAGS.PARAM.KEEP_PROB < 1.0:
def GRU_attn_cell(n_units, act):
return tf.contrib.rnn.DropoutWrapper(
GRU_cell(n_units, act),
output_keep_prob=FLAGS.PARAM.KEEP_PROB)
with tf.variable_scope("BiRNN"):
if FLAGS.PARAM.MODEL_TYPE.upper() == 'BLSTM':
with tf.variable_scope('BLSTM'):
lstm_fw_cell = tf.contrib.rnn.MultiRNNCell(
[
lstm_attn_cell(FLAGS.PARAM.RNN_SIZE,
FLAGS.PARAM.LSTM_num_proj,
FLAGS.PARAM.LSTM_ACTIVATION)
for _ in range(FLAGS.PARAM.RNN_LAYER)
],
state_is_tuple=True)
lstm_bw_cell = tf.contrib.rnn.MultiRNNCell(
[
lstm_attn_cell(FLAGS.PARAM.RNN_SIZE,
FLAGS.PARAM.LSTM_num_proj,
FLAGS.PARAM.LSTM_ACTIVATION)
for _ in range(FLAGS.PARAM.RNN_LAYER)
],
state_is_tuple=True)
fw_cell = lstm_fw_cell._cells
bw_cell = lstm_bw_cell._cells
if FLAGS.PARAM.MODEL_TYPE.upper() == 'BGRU':
with tf.variable_scope('BGRU'):
gru_fw_cell = tf.contrib.rnn.MultiRNNCell(
[
GRU_attn_cell(FLAGS.PARAM.RNN_SIZE,
FLAGS.PARAM.LSTM_ACTIVATION)
for _ in range(FLAGS.PARAM.RNN_LAYER)
],
state_is_tuple=True)
gru_bw_cell = tf.contrib.rnn.MultiRNNCell(
[
GRU_attn_cell(FLAGS.PARAM.RNN_SIZE,
FLAGS.PARAM.LSTM_ACTIVATION)
for _ in range(FLAGS.PARAM.RNN_LAYER)
],
state_is_tuple=True)
fw_cell = gru_fw_cell._cells
bw_cell = gru_bw_cell._cells
result = rnn.stack_bidirectional_dynamic_rnn(
cells_fw=fw_cell,
cells_bw=bw_cell,
inputs=outputs,
dtype=tf.float32,
sequence_length=self._lengths)
outputs, fw_final_states, bw_final_states = result
# region full connection get mask
# calcu rnn output size
in_size = FLAGS.PARAM.RNN_SIZE
if self._model_type.upper()[0] == 'B': # bidirection
rnn_output_num = FLAGS.PARAM.RNN_SIZE * 2
if FLAGS.PARAM.MODEL_TYPE == 'BLSTM' and (
not (FLAGS.PARAM.LSTM_num_proj is None)):
rnn_output_num = 2 * FLAGS.PARAM.LSTM_num_proj
in_size = rnn_output_num
outputs = tf.reshape(outputs, [-1, in_size])
out_size = FLAGS.PARAM.OUTPUT_SIZE
with tf.variable_scope('fullconnectOut1'):
out1_dense1 = tf.layers.Dense(out_size, activation='tanh')
out1_dense2 = tf.layers.Dense(
out_size // 2,
activation='relu' if FLAGS.PARAM.ReLU_MASK else None,
bias_initializer=tf.constant_initializer(
FLAGS.PARAM.INIT_MASK_VAL))
self._mask1 = out1_dense2(out1_dense1(outputs))
with tf.variable_scope('fullconnectOut2'):
out2_dense1 = tf.layers.Dense(out_size, activation='tanh')
out2_dense2 = tf.layers.Dense(
out_size // 2,
activation='relu' if FLAGS.PARAM.ReLU_MASK else None,
bias_initializer=tf.constant_initializer(
FLAGS.PARAM.INIT_MASK_VAL))
self._mask2 = out2_dense2(out2_dense1(outputs))
self._mask1 = tf.reshape(
self._mask1, [self._batch_size, -1, FLAGS.PARAM.OUTPUT_SIZE // 2])
self._mask2 = tf.reshape(
self._mask2, [self._batch_size, -1, FLAGS.PARAM.OUTPUT_SIZE // 2])
self._mask = tf.concat([self._mask1, self._mask2], axis=-1)
# endregion
# mask type
if FLAGS.PARAM.MASK_TYPE == 'PSM':
self._y_mag_labels *= tf.cos(self._x_theta - self._y_theta)
elif FLAGS.PARAM.MASK_TYPE == 'fixPSM':
self._y_mag_labels *= (1.0 +
tf.cos(self._x_theta - self._y_theta)) * 0.5
elif FLAGS.PARAM.MASK_TYPE == 'AcutePM':
self._y_mag_labels *= tf.nn.relu(
tf.cos(self._x_theta - self._y_theta))
elif FLAGS.PARAM.MASK_TYPE == 'IRM':
pass
else:
tf.logging.error('Mask type error.')
exit(-1)
# region get infer spec
# self._y_est = self._mask*self.net_input # est->estimation
# self._norm_y_mag_est = tf.slice(self._y_est,[0,0,0],[-1,-1,FLAGS.PARAM.FFT_DOT])
# self._norm_y_theta_est = tf.slice(self._y_est,[0,0,FLAGS.PARAM.FFT_DOT],[-1,-1,-1])
self._norm_y_mag_est = self._mask1 * self._norm_x_mag_spec
self._norm_y_theta_est = self._mask2 * self._x_theta
self._y_mag_est = rm_norm_mag_spec(self._norm_y_mag_est,
FLAGS.PARAM.MAG_NORM_MAX)
# self._y_theta_est = (self._norm_y_theta_est-0.5)*2.0*FLAGS.PARAM.PI
self._y_theta_est = self._norm_y_theta_est
# endregion
self.saver = tf.train.Saver(tf.trainable_variables(), max_to_keep=30)
if behavior == self.infer:
return
# region get LOSS
if FLAGS.PARAM.LOSS_FUNC_FOR_MAG_SPEC == 'SPEC_MSE': # log_mag and mag MSE
self._mag_loss = loss.reduce_sum_frame_batchsize_MSE(
self._norm_y_mag_est, self._y_mag_labels)
elif FLAGS.PARAM.LOSS_FUNC_FOR_MAG_SPEC == "RELATED_MSE":
self._mag_loss = loss.relative_reduce_sum_frame_batchsize_MSE(
self._norm_y_mag_est, self._y_mag_labels,
FLAGS.PARAM.RELATED_MSE_IGNORE_TH)
elif FLAGS.PARAM.LOSS_FUNC_FOR_MAG_SPEC == "AUTO_RELATED_MSE":
self._mag_loss = loss.auto_ingore_relative_reduce_sum_frame_batchsize_MSE(
self._norm_y_mag_est, self._y_mag_labels,
FLAGS.PARAM.AUTO_RELATED_MSE_AXIS_FIT_DEG)
elif FLAGS.PARAM.LOSS_FUNC_FOR_MAG_SPEC == "AUTO_RELATED_MSE_USE_COS":
self._mag_loss = loss.cos_auto_ingore_relative_reduce_sum_frame_batchsize_MSE(
self._norm_y_mag_est, self._y_mag_labels,
FLAGS.PARAM.COS_AUTO_RELATED_MSE_W)
else:
tf.logging.error('Magnitude_Loss type error.')
exit(-1)
if FLAGS.PARAM.LOSS_FUNC_FOR_PHASE_SPEC == 'COS':
self._phase_loss = tf.reduce_sum(
tf.reduce_mean(
tf.pow(
tf.abs(1.0 - tf.cos(self._y_theta_est -
self._y_theta_labels)),
FLAGS.PARAM.PHASE_LOSS_INDEX), 1))
elif FLAGS.PARAM.LOSS_FUNC_FOR_PHASE_SPEC == 'MAG_WEIGHTED_COS':
self._phase_loss = loss.magnitude_weighted_cos_deltaTheta(
self._y_theta_est,
self._y_theta_labels,
self._norm_y_mag_spec,
index_=FLAGS.PARAM.PHASE_LOSS_INDEX)
elif FLAGS.PARAM.LOSS_FUNC_FOR_PHASE_SPEC == 'MIXMAG_WEIGHTED_COS':
self._phase_loss = loss.magnitude_weighted_cos_deltaTheta(
self._y_theta_est,
self._y_theta_labels,
self._norm_x_mag_spec,
index_=FLAGS.PARAM.PHASE_LOSS_INDEX)
elif FLAGS.PARAM.LOSS_FUNC_FOR_PHASE_SPEC == 'ABSOLUTE':
self._phase_loss = tf.reduce_sum(
tf.reduce_mean(
tf.pow(tf.abs(self._y_theta_est - self._y_theta_labels),
FLAGS.PARAM.PHASE_LOSS_INDEX), 1))
elif FLAGS.PARAM.LOSS_FUNC_FOR_PHASE_SPEC == 'MAG_WEIGHTED_ABSOLUTE':
self._phase_loss = tf.reduce_sum(
tf.reduce_mean(
tf.pow(
tf.abs(self._y_theta_est - self._y_theta_labels) *
self._norm_y_mag_spec * 10.0,
FLAGS.PARAM.PHASE_LOSS_INDEX), 1))
elif FLAGS.PARAM.LOSS_FUNC_FOR_PHASE_SPEC == 'MIXMAG_WEIGHTED_ABSOLUTE':
self._phase_loss = tf.reduce_sum(
tf.reduce_mean(
tf.pow(
tf.abs(self._y_theta_est - self._y_theta_labels) *
self._norm_x_mag_spec * 10.0,
FLAGS.PARAM.PHASE_LOSS_INDEX), 1))
else:
tf.logging.error('Phase_Loss type error.')
exit(-1)
self._loss = self._mag_loss + self._phase_loss
# endregion
if behavior == self.validation:
'''
val model cannot train.
'''
return
self._lr = tf.Variable(0.0, trainable=False)
tvars = tf.trainable_variables()
grads, _ = tf.clip_by_global_norm(tf.gradients(self.loss, tvars),
FLAGS.PARAM.CLIP_NORM)
optimizer = tf.train.AdamOptimizer(self.lr)
#optimizer = tf.train.GradientDescentOptimizer(self.lr)
self._train_op = optimizer.apply_gradients(zip(grads, tvars))
self._new_lr = tf.placeholder(tf.float32,
shape=[],
name='new_learning_rate')
self._lr_update = tf.assign(self._lr, self._new_lr)
def __init__(self,
x_mag_spec_batch,
lengths_batch,
y_mag_spec_batch=None,
theta_x_batch=None,
theta_y_batch=None,
behavior='train'):
'''
behavior = 'train/validation/infer'
'''
if behavior != self.infer:
assert (y_mag_spec_batch is not None)
assert (theta_x_batch is not None)
assert (theta_y_batch is not None)
self._x_mag_spec = x_mag_spec_batch
self._norm_x_mag_spec = norm_mag_spec(self._x_mag_spec,
FLAGS.PARAM.MAG_NORM_MAX)
self._y_mag_spec = y_mag_spec_batch
self._norm_y_mag_spec = norm_mag_spec(self._y_mag_spec,
FLAGS.PARAM.MAG_NORM_MAX)
self._lengths = lengths_batch
self._batch_size = tf.shape(self._lengths)[0]
self._x_theta = theta_x_batch
self._y_theta = theta_y_batch
self._model_type = FLAGS.PARAM.MODEL_TYPE
if FLAGS.PARAM.INPUT_TYPE == 'mag':
self.logbias_net_input = self._norm_x_mag_spec
elif FLAGS.PARAM.INPUT_TYPE == 'logmag':
tf.logging.error(
"Training_In_Turn_Model: NNET input must be magnitude spectrum."
)
exit(-1)
# region training dropout
lstm_attn_cell = lstm_cell
if behavior != self.infer and FLAGS.PARAM.KEEP_PROB < 1.0:
def lstm_attn_cell(n_units, n_proj, act):
return tf.contrib.rnn.DropoutWrapper(
lstm_cell(n_units, n_proj, act),
output_keep_prob=FLAGS.PARAM.KEEP_PROB)
GRU_attn_cell = GRU_cell
if behavior != self.infer and FLAGS.PARAM.KEEP_PROB < 1.0:
def GRU_attn_cell(n_units, act):
return tf.contrib.rnn.DropoutWrapper(
GRU_cell(n_units, act),
output_keep_prob=FLAGS.PARAM.KEEP_PROB)
# endregion
# region logbias net
with tf.variable_scope('logbias_net'):
logbias_net_outputs = self.logbias_net_input
if FLAGS.PARAM.MODEL_TYPE.upper() == 'BLSTM':
with tf.variable_scope('BLSTM_logbias'):
lstm_fw_cell = tf.contrib.rnn.MultiRNNCell(
[
lstm_attn_cell(FLAGS.PARAM.RNN_SIZE_LOGBIAS,
FLAGS.PARAM.LSTM_num_proj_LOGBIAS,
FLAGS.PARAM.LSTM_ACTIVATION_LOGBIAS)
for _ in range(FLAGS.PARAM.RNN_LAYER_LOGBIAS)
],
state_is_tuple=True)
lstm_bw_cell = tf.contrib.rnn.MultiRNNCell(
[
lstm_attn_cell(FLAGS.PARAM.RNN_SIZE_LOGBIAS,
FLAGS.PARAM.LSTM_num_proj_LOGBIAS,
FLAGS.PARAM.LSTM_ACTIVATION_LOGBIAS)
for _ in range(FLAGS.PARAM.RNN_LAYER_LOGBIAS)
],
state_is_tuple=True)
fw_cell_logbiasnet = lstm_fw_cell._cells
bw_cell_logbiasnet = lstm_bw_cell._cells
if FLAGS.PARAM.MODEL_TYPE.upper() == 'BGRU':
with tf.variable_scope('BGRU_logbias'):
gru_fw_cell = tf.contrib.rnn.MultiRNNCell(
[
GRU_attn_cell(FLAGS.PARAM.RNN_SIZE_LOGBIAS,
FLAGS.PARAM.LSTM_ACTIVATION_LOGBIAS)
for _ in range(FLAGS.PARAM.RNN_LAYER_LOGBIAS)
],
state_is_tuple=True)
gru_bw_cell = tf.contrib.rnn.MultiRNNCell(
[
GRU_attn_cell(FLAGS.PARAM.RNN_SIZE_LOGBIAS,
FLAGS.PARAM.LSTM_ACTIVATION_LOGBIAS)
for _ in range(FLAGS.PARAM.RNN_LAYER_LOGBIAS)
],
state_is_tuple=True)
fw_cell_logbiasnet = gru_fw_cell._cells
bw_cell_logbiasnet = gru_bw_cell._cells
# dynamic rnn
result = rnn.stack_bidirectional_dynamic_rnn(
cells_fw=fw_cell_logbiasnet,
cells_bw=bw_cell_logbiasnet,
inputs=logbias_net_outputs,
dtype=tf.float32,
sequence_length=self._lengths)
logbias_net_outputs, fw_final_states, bw_final_states = result
logbias_biRnn_out_size = FLAGS.PARAM.RNN_SIZE_LOGBIAS * 2
# attend_fea = sum_attention_v2(logbias_net_outputs,self._batch_size,logbias_biRnn_out_size)
# print(np.shape(fw_final_states),np.shape(bw_final_states),np.shape(logbias_net_outputs))
# attend_fea = sum_attention_with_final_state(logbias_net_outputs,
# tf.concat(-1, [fw_final_states,
# bw_final_states]),
# logbias_biRnn_out_size, 1024)
attend_fea = sum_attention(logbias_net_outputs,
logbias_biRnn_out_size, 1024)
with tf.variable_scope('fullconnectSuitableLogbias'):
weights_logbias_fc = tf.get_variable(
'weights_logbias_fc', [logbias_biRnn_out_size, 1],
initializer=tf.random_normal_initializer(stddev=0.01))
biases_logbias_fc = tf.get_variable(
'biases_logbias_fc', [1],
initializer=tf.constant_initializer(0.0))
logbias_net_out = tf.expand_dims(
tf.matmul(attend_fea, weights_logbias_fc) +
biases_logbias_fc,
axis=-1) # [batch,1,1]
self._log_bias = tf.nn.relu(logbias_net_out +
FLAGS.PARAM.INIT_LOG_BIAS)
self._real_logbias = tf.add(self._log_bias,
FLAGS.PARAM.MIN_LOG_BIAS)
# endregion
self._norm_x_logmag_spec = norm_logmag_spec(self._x_mag_spec,
FLAGS.PARAM.MAG_NORM_MAX,
self._log_bias,
FLAGS.PARAM.MIN_LOG_BIAS)
self._norm_y_logmag_spec = norm_logmag_spec(self._y_mag_spec,
FLAGS.PARAM.MAG_NORM_MAX,
self._log_bias,
FLAGS.PARAM.MIN_LOG_BIAS)
# region mask net
with tf.variable_scope('mask_net'):
mask_net_outputs = self._norm_x_logmag_spec
if FLAGS.PARAM.MODEL_TYPE.upper() == 'BLSTM':
with tf.variable_scope('BLSTM_mask'):
lstm_fw_cell = tf.contrib.rnn.MultiRNNCell(
[
lstm_attn_cell(FLAGS.PARAM.RNN_SIZE_MASK,
FLAGS.PARAM.LSTM_num_proj_MASK,
FLAGS.PARAM.LSTM_ACTIVATION_MASK)
for _ in range(FLAGS.PARAM.RNN_LAYER_MASK)
],
state_is_tuple=True)
lstm_bw_cell = tf.contrib.rnn.MultiRNNCell(
[
lstm_attn_cell(FLAGS.PARAM.RNN_SIZE_MASK,
FLAGS.PARAM.LSTM_num_proj_MASK,
FLAGS.PARAM.LSTM_ACTIVATION_MASK)
for _ in range(FLAGS.PARAM.RNN_LAYER_MASK)
],
state_is_tuple=True)
fw_cell_masknet = lstm_fw_cell._cells
bw_cell_masknet = lstm_bw_cell._cells
if FLAGS.PARAM.MODEL_TYPE.upper() == 'BGRU':
with tf.variable_scope('BGRU_mask'):
gru_fw_cell = tf.contrib.rnn.MultiRNNCell(
[
GRU_attn_cell(FLAGS.PARAM.RNN_SIZE,
FLAGS.PARAM.LSTM_ACTIVATION)
for _ in range(FLAGS.PARAM.RNN_LAYER)
],
state_is_tuple=True)
gru_bw_cell = tf.contrib.rnn.MultiRNNCell(
[
GRU_attn_cell(FLAGS.PARAM.RNN_SIZE,
FLAGS.PARAM.LSTM_ACTIVATION)
for _ in range(FLAGS.PARAM.RNN_LAYER)
],
state_is_tuple=True)
fw_cell_masknet = gru_fw_cell._cells
bw_cell_masknet = gru_bw_cell._cells
# dynamic rnn
result = rnn.stack_bidirectional_dynamic_rnn(
cells_fw=fw_cell_masknet,
cells_bw=bw_cell_masknet,
inputs=mask_net_outputs,
dtype=tf.float32,
sequence_length=self._lengths)
mask_net_outputs, fw_final_states, bw_final_states = result
mask_biRnn_output_size = FLAGS.PARAM.RNN_SIZE_MASK * 2
flatten_outputs = tf.reshape(mask_net_outputs,
[-1, mask_biRnn_output_size])
out_size = FLAGS.PARAM.OUTPUT_SIZE
with tf.variable_scope('fullconnectMask'):
weights = tf.get_variable(
'weights1', [mask_biRnn_output_size, out_size],
initializer=tf.random_normal_initializer(stddev=0.01))
biases = tf.get_variable(
'biases1', [out_size],
initializer=tf.constant_initializer(0.0))
mask = tf.nn.relu(tf.matmul(flatten_outputs, weights) + biases)
self._mask = tf.reshape(
mask, [self._batch_size, -1, FLAGS.PARAM.OUTPUT_SIZE])
# endregion
# region prepare y_estimation and y_labels
self._y_mag_labels = self._norm_y_mag_spec
self._y_logmag_labels = self._norm_y_logmag_spec
if FLAGS.PARAM.TRAINING_MASK_POSITION == 'mag':
self._y_normed_mag_estimation = self._mask * self._norm_x_mag_spec
self._y_normed_logmag_estimation = normedMag2normedLogmag(
self._y_normed_mag_estimation, FLAGS.PARAM.MAG_NORM_MAX,
self._log_bias, FLAGS.PARAM.MIN_LOG_BIAS)
elif FLAGS.PARAM.TRAINING_MASK_POSITION == 'logmag':
self._y_normed_logmag_estimation = self._mask * self._norm_x_logmag_spec
self._y_normed_mag_estimation = normedLogmag2normedMag(
self._y_normed_logmag_estimation, FLAGS.PARAM.MAG_NORM_MAX,
self._log_bias, FLAGS.PARAM.MIN_LOG_BIAS)
if FLAGS.PARAM.MASK_TYPE == 'PSM':
self._y_mag_labels *= tf.cos(self._x_theta - self._y_theta)
self._y_logmag_labels *= tf.cos(self._x_theta - self._y_theta)
elif FLAGS.PARAM.MASK_TYPE == 'IRM':
pass
else:
tf.logging.error('Mask type error.')
exit(-1)
# region get infer spec
if FLAGS.PARAM.DECODING_MASK_POSITION != FLAGS.PARAM.TRAINING_MASK_POSITION:
print(
'Error, DECODING_MASK_POSITION should be equal to TRAINING_MASK_POSITION when use training_in_turn_model.'
)
if FLAGS.PARAM.DECODING_MASK_POSITION == 'mag':
self._y_mag_estimation = rm_norm_mag_spec(
self._y_normed_mag_estimation, FLAGS.PARAM.MAG_NORM_MAX)
elif FLAGS.PARAM.DECODING_MASK_POSITION == 'logmag':
self._y_mag_estimation = rm_norm_logmag_spec(
self._y_normed_logmag_estimation, FLAGS.PARAM.MAG_NORM_MAX,
self._log_bias, FLAGS.PARAM.MIN_LOG_BIAS)
'''
_y_mag_estimation is estimated mag_spec
'''
# endregion
# endregion
self.saver = tf.train.Saver(tf.trainable_variables(), max_to_keep=30)
if behavior == self.infer:
return
# region get LOSS
if FLAGS.PARAM.LOSS_FUNC_FOR_MAG_SPEC == 'SPEC_MSE': # log_mag and mag MSE
self._logbiasnet_loss = loss.relative_reduce_sum_frame_batchsize_MSE(
self._y_normed_mag_estimation, self._y_mag_labels, 1e-6)
self._masknet_loss = loss.reduce_sum_frame_batchsize_MSE(
self._y_normed_logmag_estimation, self._y_logmag_labels)
elif FLAGS.PARAM.LOSS_FUNC_FOR_MAG_SPEC == "SPEC_MSE_FLEXIBLE_POW_C":
self._logbiasnet_loss = loss.reduce_sum_frame_batchsize_MSE_EmphasizeLowerValue(
self._y_normed_mag_estimation, self._y_mag_labels,
FLAGS.PARAM.POW_COEF)
self._masknet_loss = loss.reduce_sum_frame_batchsize_MSE_EmphasizeLowerValue(
self._y_normed_logmag_estimation, self._y_logmag_labels,
FLAGS.PARAM.POW_COEF)
else:
print('Loss type error.')
exit(-1)
# endregion
if behavior == self.validation:
'''
val model cannot train.
'''
return
self._lr_logbiasnet = tf.Variable(0.0, trainable=False)
self._lr_masknet = tf.Variable(0.0, trainable=False)
tvars = tf.trainable_variables()
logbias_vars = [var for var in tvars if 'logbias_net' in var.name]
mask_vars = [var for var in tvars if 'mask_net' in var.name]
logbiasnet_grads, _ = tf.clip_by_global_norm(
tf.gradients(self._logbiasnet_loss, logbias_vars),
FLAGS.PARAM.CLIP_NORM)
masknet_grads, _ = tf.clip_by_global_norm(
tf.gradients(self._masknet_loss, mask_vars), FLAGS.PARAM.CLIP_NORM)
optimizer_logbiasnet = tf.train.AdamOptimizer(self.lr_logbiasnet)
optimizer_masknet = tf.train.AdamOptimizer(self.lr_masknet)
#optimizer = tf.train.GradientDescentOptimizer(self.lr)
# all_grads = [grad for grad in logbiasnet_grads]
# for grad in masknet_grads:
# all_grads.append(grad)
# all_vars = [var for var in logbias_vars]
# for var in mask_vars:
# all_vars.append(var)
train_logbiasnet = optimizer_logbiasnet.apply_gradients(
zip(logbiasnet_grads, logbias_vars))
train_masknet = optimizer_masknet.apply_gradients(
zip(masknet_grads, mask_vars))
if FLAGS.PARAM.TRAIN_TYPE == 'BOTH':
self._train_op = [train_logbiasnet, train_masknet]
elif FLAGS.PARAM.TRAIN_TYPE == 'LOGBIASNET':
self._train_op = train_logbiasnet
elif FLAGS.PARAM.TRAIN_TYPE == 'MASKNET':
self._train_op = train_masknet
self._new_lr_logbiasnet = tf.placeholder(tf.float32,
shape=[],
name='new_learning_rate1')
self._new_lr_masknet = tf.placeholder(tf.float32,
shape=[],
name='new_learning_rate2')
self._lr_update = [
tf.assign(self._lr_logbiasnet, self._new_lr_logbiasnet),
tf.assign(self._lr_masknet, self._new_lr_masknet)
]
def __init__(self,
x_mag_spec_batch,
lengths_batch,
y_mag_spec_batch=None,
theta_x_batch=None,
theta_y_batch=None,
behavior='train'):
'''
behavior = 'train/validation/infer'
'''
if behavior != self.infer:
assert (y_mag_spec_batch is not None)
assert (theta_x_batch is not None)
assert (theta_y_batch is not None)
self._log_bias = tf.get_variable(
'logbias', [1],
trainable=FLAGS.PARAM.LOG_BIAS_TRAINABLE,
initializer=tf.constant_initializer(FLAGS.PARAM.INIT_LOG_BIAS))
self._real_logbias = self._log_bias + FLAGS.PARAM.MIN_LOG_BIAS
self._x_mag_spec = x_mag_spec_batch
self._norm_x_mag_spec = norm_mag_spec(self._x_mag_spec,
FLAGS.PARAM.MAG_NORM_MAX)
self._norm_x_logmag_spec = norm_logmag_spec(self._x_mag_spec,
FLAGS.PARAM.MAG_NORM_MAX,
self._log_bias,
FLAGS.PARAM.MIN_LOG_BIAS)
self._y_mag_spec = y_mag_spec_batch
self._norm_y_mag_spec = norm_mag_spec(self._y_mag_spec,
FLAGS.PARAM.MAG_NORM_MAX)
self._norm_y_logmag_spec = norm_logmag_spec(self._y_mag_spec,
FLAGS.PARAM.MAG_NORM_MAX,
self._log_bias,
FLAGS.PARAM.MIN_LOG_BIAS)
self._lengths = lengths_batch
self._batch_size = tf.shape(self._lengths)[0]
self._x_theta = theta_x_batch
self._y_theta = theta_y_batch
self._model_type = FLAGS.PARAM.MODEL_TYPE
if FLAGS.PARAM.INPUT_TYPE == 'mag':
self.net_input = self._norm_x_mag_spec
elif FLAGS.PARAM.INPUT_TYPE == 'logmag':
self.net_input = self._norm_x_logmag_spec
if FLAGS.PARAM.LABEL_TYPE == 'mag':
self._y_labels = self._norm_y_mag_spec
elif FLAGS.PARAM.LABEL_TYPE == 'logmag':
self._y_labels = self._norm_y_logmag_spec
outputs = self.net_input
if FLAGS.PARAM.INPUT_BN:
with tf.variable_scope('Batch_Norm_Layer'):
if_BRN = (FLAGS.PARAM.MVN_TYPE == 'BRN')
if FLAGS.PARAM.SELF_BN:
outputs = tf.layers.batch_normalization(outputs,
training=True,
renorm=if_BRN)
else:
outputs = tf.layers.batch_normalization(
outputs,
training=(behavior == self.train
or behavior == self.validation),
renorm=if_BRN)
lstm_attn_cell = lstm_cell
if behavior != self.infer and FLAGS.PARAM.KEEP_PROB < 1.0:
def lstm_attn_cell(n_units, n_proj, act):
return tf.contrib.rnn.DropoutWrapper(
lstm_cell(n_units, n_proj, act),
output_keep_prob=FLAGS.PARAM.KEEP_PROB)
GRU_attn_cell = GRU_cell
if behavior != self.infer and FLAGS.PARAM.KEEP_PROB < 1.0:
def GRU_attn_cell(n_units, act):
return tf.contrib.rnn.DropoutWrapper(
GRU_cell(n_units, act),
output_keep_prob=FLAGS.PARAM.KEEP_PROB)
if FLAGS.PARAM.MODEL_TYPE.upper() == 'BLSTM':
with tf.variable_scope('BLSTM'):
lstm_fw_cell = tf.contrib.rnn.MultiRNNCell([
lstm_attn_cell(FLAGS.PARAM.RNN_SIZE,
FLAGS.PARAM.LSTM_num_proj,
FLAGS.PARAM.LSTM_ACTIVATION)
for _ in range(FLAGS.PARAM.RNN_LAYER)
],
state_is_tuple=True)
lstm_bw_cell = tf.contrib.rnn.MultiRNNCell([
lstm_attn_cell(FLAGS.PARAM.RNN_SIZE,
FLAGS.PARAM.LSTM_num_proj,
FLAGS.PARAM.LSTM_ACTIVATION)
for _ in range(FLAGS.PARAM.RNN_LAYER)
],
state_is_tuple=True)
fw_cell = lstm_fw_cell._cells
bw_cell = lstm_bw_cell._cells
result = rnn.stack_bidirectional_dynamic_rnn(
cells_fw=fw_cell,
cells_bw=bw_cell,
inputs=outputs,
dtype=tf.float32,
sequence_length=self._lengths)
outputs, fw_final_states, bw_final_states = result
if FLAGS.PARAM.MODEL_TYPE.upper() == 'BGRU':
with tf.variable_scope('BGRU'):
gru_fw_cell = tf.contrib.rnn.MultiRNNCell([
GRU_attn_cell(FLAGS.PARAM.RNN_SIZE,
FLAGS.PARAM.LSTM_ACTIVATION)
for _ in range(FLAGS.PARAM.RNN_LAYER)
],
state_is_tuple=True)
gru_bw_cell = tf.contrib.rnn.MultiRNNCell([
GRU_attn_cell(FLAGS.PARAM.RNN_SIZE,
FLAGS.PARAM.LSTM_ACTIVATION)
for _ in range(FLAGS.PARAM.RNN_LAYER)
],
state_is_tuple=True)
fw_cell = gru_fw_cell._cells
bw_cell = gru_bw_cell._cells
result = rnn.stack_bidirectional_dynamic_rnn(
cells_fw=fw_cell,
cells_bw=bw_cell,
inputs=outputs,
dtype=tf.float32,
sequence_length=self._lengths)
outputs, fw_final_states, bw_final_states = result
self.fw_final_state = fw_final_states
self.bw_final_state = bw_final_states
# print(fw_final_states[0][0].get_shape().as_list())
# print(np.shape(fw_final_states),np.shape(bw_final_states))
# region full connection get mask
# calcu rnn output size
in_size = FLAGS.PARAM.RNN_SIZE
mask = None
if self._model_type.upper()[0] == 'B': # bidirection
rnn_output_num = FLAGS.PARAM.RNN_SIZE * 2
if FLAGS.PARAM.MODEL_TYPE == 'BLSTM' and (
not (FLAGS.PARAM.LSTM_num_proj is None)):
rnn_output_num = 2 * FLAGS.PARAM.LSTM_num_proj
in_size = rnn_output_num
outputs = tf.reshape(outputs, [-1, in_size])
out_size = FLAGS.PARAM.OUTPUT_SIZE
with tf.variable_scope('fullconnectOut'):
weights = tf.get_variable(
'weights1', [in_size, out_size],
initializer=tf.random_normal_initializer(stddev=0.01))
biases = tf.get_variable('biases1', [out_size],
initializer=tf.constant_initializer(
FLAGS.PARAM.INIT_MASK_VAL))
if FLAGS.PARAM.TIME_NOSOFTMAX_ATTENTION:
with tf.variable_scope('fullconnectCoef'):
weights_coef = tf.get_variable(
'weights_coef', [in_size, 1],
initializer=tf.random_normal_initializer(mean=1.0,
stddev=0.01))
biases_coef = tf.get_variable(
'biases_coef', [1],
initializer=tf.constant_initializer(0.0))
raw_mask = tf.reshape(
tf.matmul(outputs, weights) + biases,
[self._batch_size, -1, FLAGS.PARAM.OUTPUT_SIZE
]) # [batch,time,fre]
batch_coef_vec = tf.nn.relu(
tf.reshape(
tf.matmul(outputs, weights_coef) + biases_coef,
[self._batch_size, -1])) # [batch, time]
mask = tf.multiply(
raw_mask, tf.reshape(batch_coef_vec,
[self._batch_size, -1, 1]))
else:
if FLAGS.PARAM.POST_BN:
linear_out = tf.matmul(outputs, weights)
with tf.variable_scope('POST_Batch_Norm_Layer'):
if_BRN = (FLAGS.PARAM.MVN_TYPE == 'BRN')
if FLAGS.PARAM.SELF_BN:
linear_out = tf.layers.batch_normalization(
linear_out, training=True, renorm=if_BRN)
else:
linear_out = tf.layers.batch_normalization(
linear_out,
training=(behavior == self.train
or behavior == self.validation),
renorm=if_BRN)
weights2 = tf.get_variable(
'weights1', [out_size, out_size],
initializer=tf.random_normal_initializer(stddev=0.01))
biases2 = tf.get_variable(
'biases1', [out_size],
initializer=tf.constant_initializer(
FLAGS.PARAM.INIT_MASK_VAL))
linear_out = tf.matmul(linear_out, weights2) + biases2
else:
linear_out = tf.matmul(outputs, weights) + biases
mask = linear_out
if FLAGS.PARAM.ReLU_MASK:
mask = tf.nn.relu(linear_out)
# endregion
self._mask = tf.reshape(
mask, [self._batch_size, -1, FLAGS.PARAM.OUTPUT_SIZE])
if FLAGS.PARAM.TRAINING_MASK_POSITION == 'mag':
self._y_estimation = self._mask * (self._norm_x_mag_spec +
FLAGS.PARAM.SPEC_EST_BIAS)
elif FLAGS.PARAM.TRAINING_MASK_POSITION == 'logmag':
self._y_estimation = self._mask * (self._norm_x_logmag_spec +
FLAGS.PARAM.SPEC_EST_BIAS)
# region get infer spec
if FLAGS.PARAM.DECODING_MASK_POSITION == 'mag':
self._y_mag_estimation = rm_norm_mag_spec(
self._mask *
(self._norm_x_mag_spec + FLAGS.PARAM.SPEC_EST_BIAS),
FLAGS.PARAM.MAG_NORM_MAX)
elif FLAGS.PARAM.DECODING_MASK_POSITION == 'logmag':
self._y_mag_estimation = rm_norm_logmag_spec(
self._mask *
(self._norm_x_logmag_spec + FLAGS.PARAM.SPEC_EST_BIAS),
FLAGS.PARAM.MAG_NORM_MAX, self._log_bias,
FLAGS.PARAM.MIN_LOG_BIAS)
'''
_y_mag_estimation is estimated mag_spec
_y_estimation is loss_targe, mag_sepec or logmag_spec
'''
# endregion
# region prepare y_estimation
if FLAGS.PARAM.TRAINING_MASK_POSITION != FLAGS.PARAM.LABEL_TYPE:
if FLAGS.PARAM.LABEL_TYPE == 'mag':
self._y_estimation = normedLogmag2normedMag(
self._y_estimation, FLAGS.PARAM.MAG_NORM_MAX,
self._log_bias, FLAGS.PARAM.MIN_LOG_BIAS)
elif FLAGS.PARAM.LABEL_TYPE == 'logmag':
self._y_estimation = normedMag2normedLogmag(
self._y_estimation, FLAGS.PARAM.MAG_NORM_MAX,
self._log_bias, FLAGS.PARAM.MIN_LOG_BIAS)
# endregion
# region CBHG
if FLAGS.PARAM.USE_CBHG_POST_PROCESSING:
cbhg_kernels = 8 # All kernel sizes from 1 to cbhg_kernels will be used in the convolution bank of CBHG to act as "K-grams"
cbhg_conv_channels = 128 # Channels of the convolution bank
cbhg_pool_size = 2 # pooling size of the CBHG
cbhg_projection = 256 # projection channels of the CBHG (1st projection, 2nd is automatically set to num_mels)
cbhg_projection_kernel_size = 3 # kernel_size of the CBHG projections
cbhg_highwaynet_layers = 4 # Number of HighwayNet layers
cbhg_highway_units = 128 # Number of units used in HighwayNet fully connected layers
cbhg_rnn_units = 128 # Number of GRU units used in bidirectional RNN of CBHG block. CBHG output is 2x rnn_units in shape
batch_norm_position = 'before'
# is_training = True
is_training = bool(behavior == self.train)
post_cbhg = CBHG(cbhg_kernels,
cbhg_conv_channels,
cbhg_pool_size,
[cbhg_projection, FLAGS.PARAM.OUTPUT_SIZE],
cbhg_projection_kernel_size,
cbhg_highwaynet_layers,
cbhg_highway_units,
cbhg_rnn_units,
batch_norm_position,
is_training,
name='CBHG_postnet')
#[batch_size, decoder_steps(mel_frames), cbhg_channels]
self._cbhg_inputs_y_est = self._y_estimation
cbhg_outputs = post_cbhg(self._y_estimation, None)
frame_projector = FrameProjection(FLAGS.PARAM.OUTPUT_SIZE,
scope='CBHG_proj_to_spec')
self._y_estimation = frame_projector(cbhg_outputs)
if FLAGS.PARAM.DECODING_MASK_POSITION != FLAGS.PARAM.TRAINING_MASK_POSITION:
print(
'DECODING_MASK_POSITION must be equal to TRAINING_MASK_POSITION when use CBHG post processing.'
)
exit(-1)
if FLAGS.PARAM.DECODING_MASK_POSITION == 'mag':
self._y_mag_estimation = rm_norm_mag_spec(
self._y_estimation, FLAGS.PARAM.MAG_NORM_MAX)
elif FLAGS.PARAM.DECODING_MASK_POSITION == 'logmag':
self._y_mag_estimation = rm_norm_logmag_spec(
self._y_estimation, FLAGS.PARAM.MAG_NORM_MAX,
self._log_bias, FLAGS.PARAM.MIN_LOG_BIAS)
# endregion
self.saver = tf.train.Saver(tf.trainable_variables(), max_to_keep=30)
if behavior == self.infer:
return
# region get labels LOSS
# Labels
if FLAGS.PARAM.MASK_TYPE == 'PSM':
self._y_labels *= tf.cos(self._x_theta - self._y_theta)
elif FLAGS.PARAM.MASK_TYPE == 'fixPSM':
self._y_labels *= (1.0 +
tf.cos(self._x_theta - self._y_theta)) * 0.5
elif FLAGS.PARAM.MASK_TYPE == 'AcutePM':
self._y_labels *= tf.nn.relu(tf.cos(self._x_theta - self._y_theta))
elif FLAGS.PARAM.MASK_TYPE == 'PowFixPSM':
self._y_labels *= tf.pow(
tf.abs((1.0 + tf.cos(self._x_theta - self._y_theta)) * 0.5),
FLAGS.PARAM.POW_FIX_PSM_COEF)
elif FLAGS.PARAM.MASK_TYPE == 'IRM':
pass
else:
tf.logging.error('Mask type error.')
exit(-1)
# LOSS
if FLAGS.PARAM.LOSS_FUNC_FOR_MAG_SPEC == 'SPEC_MSE': # log_mag and mag MSE
self._loss = loss.reduce_sum_frame_batchsize_MSE(
self._y_estimation, self._y_labels)
if FLAGS.PARAM.USE_CBHG_POST_PROCESSING:
if FLAGS.PARAM.DOUBLE_LOSS:
self._loss = FLAGS.PARAM.CBHG_LOSS_COEF1 * loss.reduce_sum_frame_batchsize_MSE(
self._cbhg_inputs_y_est, self._y_labels
) + FLAGS.PARAM.CBHG_LOSS_COEF2 * self._loss
elif FLAGS.PARAM.LOSS_FUNC_FOR_MAG_SPEC == 'MFCC_SPEC_MSE':
self._loss1, self._loss2 = loss.balanced_MFCC_AND_SPEC_MSE(
self._y_estimation, self._y_labels, self._y_mag_estimation,
self._y_mag_spec)
self._loss = FLAGS.PARAM.SPEC_LOSS_COEF * self._loss1 + FLAGS.PARAM.MFCC_LOSS_COEF * self._loss2
elif FLAGS.PARAM.LOSS_FUNC_FOR_MAG_SPEC == 'MEL_MAG_MSE':
self._loss1, self._loss2 = loss.balanced_MEL_AND_SPEC_MSE(
self._y_estimation, self._y_labels, self._y_mag_estimation,
self._y_mag_spec)
self._loss = FLAGS.PARAM.SPEC_LOSS_COEF * self._loss1 + FLAGS.PARAM.MEL_LOSS_COEF * self._loss2
elif FLAGS.PARAM.LOSS_FUNC_FOR_MAG_SPEC == "SPEC_MSE_LOWF_EN":
self._loss = loss.reduce_sum_frame_batchsize_MSE(
self._y_estimation, self._y_labels)
elif FLAGS.PARAM.LOSS_FUNC_FOR_MAG_SPEC == "FAIR_SPEC_MSE":
self._loss = loss.fair_reduce_sum_frame_batchsize_MSE(
self._y_estimation, self._y_labels)
elif FLAGS.PARAM.LOSS_FUNC_FOR_MAG_SPEC == "SPEC_MSE_FLEXIBLE_POW_C":
self._loss = loss.reduce_sum_frame_batchsize_MSE_EmphasizeLowerValue(
self._y_estimation, self._y_labels, FLAGS.PARAM.POW_COEF)
elif FLAGS.PARAM.LOSS_FUNC_FOR_MAG_SPEC == "RELATED_MSE":
self._loss = loss.relative_reduce_sum_frame_batchsize_MSE(
self._y_estimation, self._y_labels,
FLAGS.PARAM.RELATED_MSE_IGNORE_TH)
elif FLAGS.PARAM.LOSS_FUNC_FOR_MAG_SPEC == "AUTO_RELATED_MSE":
self._loss = loss.auto_ingore_relative_reduce_sum_frame_batchsize_MSE(
self._y_estimation, self._y_labels,
FLAGS.PARAM.AUTO_RELATED_MSE_AXIS_FIT_DEG)
elif FLAGS.PARAM.LOSS_FUNC_FOR_MAG_SPEC == "AUTO_RELATED_MSE2":
self._loss = loss.auto_ingore_relative_reduce_sum_frame_batchsize_MSE_v2(
self._y_estimation,
self._y_labels,
FLAGS.PARAM.AUTO_RELATED_MSE_AXIS_FIT_DEG,
FLAGS.PARAM.LINEAR_BROKER,
)
elif FLAGS.PARAM.LOSS_FUNC_FOR_MAG_SPEC == "AUTO_RELATED_MSE3":
self._loss = loss.auto_ingore_relative_reduce_sum_frame_batchsize_MSE_v3(
self._y_estimation, self._y_labels,
FLAGS.PARAM.AUTO_RELATIVE_LOSS3_A,
FLAGS.PARAM.AUTO_RELATIVE_LOSS3_B,
FLAGS.PARAM.AUTO_RELATIVE_LOSS3_C1,
FLAGS.PARAM.AUTO_RELATIVE_LOSS3_C2)
elif FLAGS.PARAM.LOSS_FUNC_FOR_MAG_SPEC == "AUTO_RELATED_MSE4":
self._loss = loss.auto_ingore_relative_reduce_sum_frame_batchsize_MSE_v4(
self._y_estimation, self._y_labels,
FLAGS.PARAM.AUTO_RELATED_MSE_AXIS_FIT_DEG)
elif FLAGS.PARAM.LOSS_FUNC_FOR_MAG_SPEC == "AUTO_RELATED_MSE5":
self._loss = loss.auto_ingore_relative_reduce_sum_frame_batchsize_MSE_v5(
self._y_estimation, self._y_labels)
elif FLAGS.PARAM.LOSS_FUNC_FOR_MAG_SPEC == "AUTO_RELATED_MSE6":
self._loss = loss.auto_ingore_relative_reduce_sum_frame_batchsize_MSE_v6(
self._y_estimation, self._y_labels,
FLAGS.PARAM.AUTO_RELATIVE_LOSS6_A,
FLAGS.PARAM.AUTO_RELATIVE_LOSS6_B,
FLAGS.PARAM.AUTO_RELATIVE_LOSS6_C1,
FLAGS.PARAM.AUTO_RELATIVE_LOSS6_C2)
elif FLAGS.PARAM.LOSS_FUNC_FOR_MAG_SPEC == "AUTO_RELATED_MSE7":
self._loss = loss.auto_ingore_relative_reduce_sum_frame_batchsize_MSE_v7(
self._y_estimation, self._y_labels,
FLAGS.PARAM.AUTO_RELATIVE_LOSS7_A1,
FLAGS.PARAM.AUTO_RELATIVE_LOSS7_A2,
FLAGS.PARAM.AUTO_RELATIVE_LOSS7_B,
FLAGS.PARAM.AUTO_RELATIVE_LOSS7_C1,
FLAGS.PARAM.AUTO_RELATIVE_LOSS7_C2)
elif FLAGS.PARAM.LOSS_FUNC_FOR_MAG_SPEC == "AUTO_RELATED_MSE8":
self._loss = loss.auto_ingore_relative_reduce_sum_frame_batchsize_MSE_v8(
self._y_estimation, self._y_labels,
FLAGS.PARAM.AUTO_RELATIVE_LOSS8_A,
FLAGS.PARAM.AUTO_RELATIVE_LOSS8_B,
FLAGS.PARAM.AUTO_RELATIVE_LOSS8_C1,
FLAGS.PARAM.AUTO_RELATIVE_LOSS8_C2)
elif FLAGS.PARAM.LOSS_FUNC_FOR_MAG_SPEC == "AUTO_RELATED_MSE_USE_COS":
self._loss = loss.cos_auto_ingore_relative_reduce_sum_frame_batchsize_MSE(
self._y_estimation, self._y_labels,
FLAGS.PARAM.COS_AUTO_RELATED_MSE_W)
elif FLAGS.PARAM.LOSS_FUNC_FOR_MAG_SPEC == 'MEL_AUTO_RELATED_MSE':
# type(y_estimation) = FLAGS.PARAM.LABEL_TYPE
self._loss = loss.MEL_AUTO_RELATIVE_MSE(
self._y_estimation, self._norm_y_mag_spec, FLAGS.PARAM.MEL_NUM,
FLAGS.PARAM.AUTO_RELATED_MSE_AXIS_FIT_DEG)
else:
print('Loss type error.')
exit(-1)
# endregion
if behavior == self.validation:
'''
val model cannot train.
'''
return
self._lr = tf.Variable(0.0, trainable=False) #TODO
tvars = tf.trainable_variables()
grads, _ = tf.clip_by_global_norm(tf.gradients(self.loss, tvars),
FLAGS.PARAM.CLIP_NORM)
optimizer = tf.train.AdamOptimizer(self.lr)
#optimizer = tf.train.GradientDescentOptimizer(self.lr)
self._train_op = optimizer.apply_gradients(zip(grads, tvars))
self._new_lr = tf.placeholder(tf.float32,
shape=[],
name='new_learning_rate')
self._lr_update = tf.assign(self._lr, self._new_lr)
def __init__(self,
x_mag_spec_batch,
lengths_batch,
y_mag_spec_batch=None,
theta_x_batch=None,
theta_y_batch=None,
behavior='train'):
'''
behavior = 'train/validation/infer'
'''
if behavior != self.infer:
assert (y_mag_spec_batch is not None)
assert (theta_x_batch is not None)
assert (theta_y_batch is not None)
self._log_bias = tf.get_variable(
'logbias', [1],
trainable=FLAGS.PARAM.LOG_BIAS_TRAINABLE,
initializer=tf.constant_initializer(FLAGS.PARAM.INIT_LOG_BIAS))
self._real_logbias = self._log_bias + FLAGS.PARAM.MIN_LOG_BIAS
self._x_mag_spec = x_mag_spec_batch
self._norm_x_mag_spec = norm_mag_spec(self._x_mag_spec,
FLAGS.PARAM.MAG_NORM_MAX)
self._norm_x_logmag_spec = norm_logmag_spec(self._x_mag_spec,
FLAGS.PARAM.MAG_NORM_MAX,
self._log_bias,
FLAGS.PARAM.MIN_LOG_BIAS)
self._y_mag_spec = y_mag_spec_batch
self._norm_y_mag_spec = norm_mag_spec(self._y_mag_spec,
FLAGS.PARAM.MAG_NORM_MAX)
self._norm_y_logmag_spec = norm_logmag_spec(self._y_mag_spec,
FLAGS.PARAM.MAG_NORM_MAX,
self._log_bias,
FLAGS.PARAM.MIN_LOG_BIAS)
self._lengths = lengths_batch
self._batch_size = tf.shape(self._lengths)[0]
self._x_theta = theta_x_batch
self._y_theta = theta_y_batch
self._model_type = FLAGS.PARAM.MODEL_TYPE
if FLAGS.PARAM.INPUT_TYPE == 'mag':
self.net_input = self._norm_x_mag_spec
elif FLAGS.PARAM.INPUT_TYPE == 'logmag':
self.net_input = self._norm_x_logmag_spec
if FLAGS.PARAM.LABEL_TYPE == 'mag':
self._y_labels = self._norm_y_mag_spec
elif FLAGS.PARAM.LABEL_TYPE == 'logmag':
self._y_labels = self._norm_y_logmag_spec
outputs = self.net_input # [batch, time, ...]
if FLAGS.PARAM.OUTPUTS_LATER_SHIFT_FRAMES > 0:
padding_zeros = tf.zeros([
self._batch_size, FLAGS.PARAM.OUTPUTS_LATER_SHIFT_FRAMES,
tf.shape(outputs)[-1]
])
outputs = tf.concat([outputs, padding_zeros], -2)
if FLAGS.PARAM.MODEL_TYPE.upper() in [
"BGRU", "BLSTM", "UNIGRU", "UNILSTM"
]:
# in: outputs [batch, time, ...]
# out: outputs [batch, time, ...], insize: shape(outputs)[-1]
lstm_attn_cell = lstm_cell
if behavior != self.infer and FLAGS.PARAM.KEEP_PROB < 1.0:
def lstm_attn_cell(n_units, n_proj, act):
return tf.contrib.rnn.DropoutWrapper(
lstm_cell(n_units, n_proj, act),
output_keep_prob=FLAGS.PARAM.KEEP_PROB)
GRU_attn_cell = GRU_cell
if behavior != self.infer and FLAGS.PARAM.KEEP_PROB < 1.0:
def GRU_attn_cell(n_units, act):
return tf.contrib.rnn.DropoutWrapper(
GRU_cell(n_units, act),
output_keep_prob=FLAGS.PARAM.KEEP_PROB)
if FLAGS.PARAM.MODEL_TYPE.upper() == 'UNIGRU':
with tf.variable_scope('UNI_GRU'):
gru_cell = tf.contrib.rnn.MultiRNNCell([
GRU_attn_cell(FLAGS.PARAM.RNN_SIZE,
FLAGS.PARAM.LSTM_ACTIVATION)
for _ in range(FLAGS.PARAM.RNN_LAYER)
],
state_is_tuple=True)
# _cell = gru_cell._cells
result = tf.nn.dynamic_rnn(
gru_cell,
outputs,
dtype=tf.float32,
sequence_length=self._lengths,
)
outputs, final_states = result
if FLAGS.PARAM.MODEL_TYPE.upper() == 'UNILSTM':
with tf.variable_scope('UNI_LSTM'):
lstm_cells__t = tf.contrib.rnn.MultiRNNCell(
[
lstm_attn_cell(FLAGS.PARAM.RNN_SIZE,
FLAGS.PARAM.LSTM_num_proj,
FLAGS.PARAM.LSTM_ACTIVATION)
for _ in range(FLAGS.PARAM.RNN_LAYER)
],
state_is_tuple=True)
# _cell = lstm_cell._cells
result = tf.nn.dynamic_rnn(
lstm_cells__t,
outputs,
dtype=tf.float32,
sequence_length=self._lengths,
)
outputs, final_states = result
if FLAGS.PARAM.MODEL_TYPE.upper() == 'BLSTM':
with tf.variable_scope('BLSTM'):
lstm_fw_cell = tf.contrib.rnn.MultiRNNCell(
[
lstm_attn_cell(FLAGS.PARAM.RNN_SIZE,
FLAGS.PARAM.LSTM_num_proj,
FLAGS.PARAM.LSTM_ACTIVATION)
for _ in range(FLAGS.PARAM.RNN_LAYER)
],
state_is_tuple=True)
lstm_bw_cell = tf.contrib.rnn.MultiRNNCell(
[
lstm_attn_cell(FLAGS.PARAM.RNN_SIZE,
FLAGS.PARAM.LSTM_num_proj,
FLAGS.PARAM.LSTM_ACTIVATION)
for _ in range(FLAGS.PARAM.RNN_LAYER)
],
state_is_tuple=True)
fw_cell = lstm_fw_cell._cells
bw_cell = lstm_bw_cell._cells
result = rnn.stack_bidirectional_dynamic_rnn(
cells_fw=fw_cell,
cells_bw=bw_cell,
inputs=outputs,
dtype=tf.float32,
sequence_length=self._lengths)
outputs, fw_final_states, bw_final_states = result
if FLAGS.PARAM.MODEL_TYPE.upper() == 'BGRU':
with tf.variable_scope('BGRU'):
gru_fw_cell = tf.contrib.rnn.MultiRNNCell(
[
GRU_attn_cell(FLAGS.PARAM.RNN_SIZE,
FLAGS.PARAM.LSTM_ACTIVATION)
for _ in range(FLAGS.PARAM.RNN_LAYER)
],
state_is_tuple=True)
gru_bw_cell = tf.contrib.rnn.MultiRNNCell(
[
GRU_attn_cell(FLAGS.PARAM.RNN_SIZE,
FLAGS.PARAM.LSTM_ACTIVATION)
for _ in range(FLAGS.PARAM.RNN_LAYER)
],
state_is_tuple=True)
fw_cell = gru_fw_cell._cells
bw_cell = gru_bw_cell._cells
result = rnn.stack_bidirectional_dynamic_rnn(
cells_fw=fw_cell,
cells_bw=bw_cell,
inputs=outputs,
dtype=tf.float32,
sequence_length=self._lengths)
outputs, fw_final_states, bw_final_states = result
# self.fw_final_state = fw_final_states
# self.bw_final_state = bw_final_states
# print(fw_final_states[0][0].get_shape().as_list())
# print(np.shape(fw_final_states),np.shape(bw_final_states))
# calcu rnn output size
in_size = FLAGS.PARAM.RNN_SIZE
mask = None
if self._model_type.upper()[0] == 'B': # bidirection
rnn_output_num = FLAGS.PARAM.RNN_SIZE * 2
if FLAGS.PARAM.MODEL_TYPE == 'BLSTM' and (
not (FLAGS.PARAM.LSTM_num_proj is None)):
rnn_output_num = 2 * FLAGS.PARAM.LSTM_num_proj
in_size = rnn_output_num
elif FLAGS.PARAM.MODEL_TYPE.upper() == 'TRANSFORMER':
# in: outputs [batch, time, ...]
# out: outputs [batch, time, ...], insize: shape(outputs)[-1]
is_training = (behavior == self.train)
n_self_att_blocks = FLAGS.PARAM.n_self_att_blocks
d_model = FLAGS.PARAM.RNN_SIZE
num_att_heads = FLAGS.PARAM.num_att_heads
d_positionwise_FC = FLAGS.PARAM.d_positionwise_FC
with tf.variable_scope("transformer", reuse=tf.AUTO_REUSE):
# inputs embedding
trans = outputs
trans *= FLAGS.PARAM.FFT_DOT**0.5 # scale
trans += transformer_utils.positional_encoding(
trans, 2000) # TODO fixed length?
trans = tf.layers.dropout(trans,
1.0 - FLAGS.PARAM.KEEP_PROB,
training=is_training)
trans = tf.layers.dense(trans, d_model, use_bias=False)
## Blocks,
for i in range(n_self_att_blocks):
with tf.variable_scope("blocks_{}".format(i),
reuse=tf.AUTO_REUSE):
# self-attention
trans = transformer_utils.multihead_attention(
queries=trans,
keys=trans,
values=trans,
d_model=d_model,
KV_lengths=self.lengths,
Q_lengths=self.lengths,
num_heads=num_att_heads,
dropout_rate=1.0 - FLAGS.PARAM.KEEP_PROB,
training=is_training,
causality=False)
# position-wise feedforward
trans = transformer_utils.positionwise_FC(
trans, num_units=[d_positionwise_FC, d_model])
outputs = trans # [batch, time_src, d_model]
in_size = d_model
else:
raise ValueError('Unknown model type %s.' % FLAGS.PARAM.MODEL_TYPE)
if FLAGS.PARAM.OUTPUTS_LATER_SHIFT_FRAMES > 0:
outputs = tf.slice(outputs,
[0, FLAGS.PARAM.OUTPUTS_LATER_SHIFT_FRAMES, 0],
[-1, -1, -1])
if FLAGS.PARAM.POST_1D_CNN:
outputs = tf.layers.conv1d(outputs,
filters=in_size,
use_bias=True,
kernel_size=FLAGS.PARAM.CNN_1D_WIDTH,
padding="same",
reuse=tf.AUTO_REUSE)
# region full connection get mask
outputs = tf.reshape(outputs, [-1, in_size])
out_size = FLAGS.PARAM.OUTPUT_SIZE
with tf.variable_scope('fullconnectOut'):
weights = tf.get_variable(
'weights1', [in_size, out_size],
initializer=tf.random_normal_initializer(stddev=0.01))
biases = tf.get_variable('biases1', [out_size],
initializer=tf.constant_initializer(
FLAGS.PARAM.INIT_MASK_VAL))
linear_out = tf.matmul(outputs, weights) + biases
mask = linear_out
if FLAGS.PARAM.ReLU_MASK:
mask = tf.nn.relu(linear_out)
# endregion full connection
self._mask = tf.reshape(
mask, [self._batch_size, -1, FLAGS.PARAM.OUTPUT_SIZE])
if FLAGS.PARAM.TRAINING_MASK_POSITION == 'mag':
self._y_estimation = self._mask * (self._norm_x_mag_spec +
FLAGS.PARAM.SPEC_EST_BIAS)
elif FLAGS.PARAM.TRAINING_MASK_POSITION == 'logmag':
self._y_estimation = self._mask * (self._norm_x_logmag_spec +
FLAGS.PARAM.SPEC_EST_BIAS)
# region get infer spec
if FLAGS.PARAM.DECODING_MASK_POSITION == 'mag':
self._y_mag_estimation = rm_norm_mag_spec(
self._mask *
(self._norm_x_mag_spec + FLAGS.PARAM.SPEC_EST_BIAS),
FLAGS.PARAM.MAG_NORM_MAX)
elif FLAGS.PARAM.DECODING_MASK_POSITION == 'logmag':
self._y_mag_estimation = rm_norm_logmag_spec(
self._mask *
(self._norm_x_logmag_spec + FLAGS.PARAM.SPEC_EST_BIAS),
FLAGS.PARAM.MAG_NORM_MAX, self._log_bias,
FLAGS.PARAM.MIN_LOG_BIAS)
'''
_y_mag_estimation is estimated mag_spec
_y_estimation is loss_targe, mag_sepec or logmag_spec
'''
# endregion
# region prepare y_estimation
if FLAGS.PARAM.TRAINING_MASK_POSITION != FLAGS.PARAM.LABEL_TYPE:
if FLAGS.PARAM.LABEL_TYPE == 'mag':
self._y_estimation = normedLogmag2normedMag(
self._y_estimation, FLAGS.PARAM.MAG_NORM_MAX,
self._log_bias, FLAGS.PARAM.MIN_LOG_BIAS)
elif FLAGS.PARAM.LABEL_TYPE == 'logmag':
self._y_estimation = normedMag2normedLogmag(
self._y_estimation, FLAGS.PARAM.MAG_NORM_MAX,
self._log_bias, FLAGS.PARAM.MIN_LOG_BIAS)
# endregion
# region CBHG
if FLAGS.PARAM.USE_CBHG_POST_PROCESSING:
cbhg_kernels = 8 # All kernel sizes from 1 to cbhg_kernels will be used in the convolution bank of CBHG to act as "K-grams"
cbhg_conv_channels = 128 # Channels of the convolution bank
cbhg_pool_size = 2 # pooling size of the CBHG
cbhg_projection = 256 # projection channels of the CBHG (1st projection, 2nd is automatically set to num_mels)
cbhg_projection_kernel_size = 3 # kernel_size of the CBHG projections
cbhg_highwaynet_layers = 4 # Number of HighwayNet layers
cbhg_highway_units = 128 # Number of units used in HighwayNet fully connected layers
cbhg_rnn_units = 128 # Number of GRU units used in bidirectional RNN of CBHG block. CBHG output is 2x rnn_units in shape
batch_norm_position = 'before'
# is_training = True
is_training = bool(behavior == self.train)
post_cbhg = CBHG(cbhg_kernels,
cbhg_conv_channels,
cbhg_pool_size,
[cbhg_projection, FLAGS.PARAM.OUTPUT_SIZE],
cbhg_projection_kernel_size,
cbhg_highwaynet_layers,
cbhg_highway_units,
cbhg_rnn_units,
batch_norm_position,
is_training,
name='CBHG_postnet')
#[batch_size, decoder_steps(mel_frames), cbhg_channels]
self._cbhg_inputs_y_est = self._y_estimation
cbhg_outputs = post_cbhg(self._y_estimation, None)
frame_projector = FrameProjection(FLAGS.PARAM.OUTPUT_SIZE,
scope='CBHG_proj_to_spec')
self._y_estimation = frame_projector(cbhg_outputs)
if FLAGS.PARAM.DECODING_MASK_POSITION != FLAGS.PARAM.TRAINING_MASK_POSITION:
print(
'DECODING_MASK_POSITION must be equal to TRAINING_MASK_POSITION when use CBHG post processing.'
)
exit(-1)
if FLAGS.PARAM.DECODING_MASK_POSITION == 'mag':
self._y_mag_estimation = rm_norm_mag_spec(
self._y_estimation, FLAGS.PARAM.MAG_NORM_MAX)
elif FLAGS.PARAM.DECODING_MASK_POSITION == 'logmag':
self._y_mag_estimation = rm_norm_logmag_spec(
self._y_estimation, FLAGS.PARAM.MAG_NORM_MAX,
self._log_bias, FLAGS.PARAM.MIN_LOG_BIAS)
# endregion
self.saver = tf.train.Saver(tf.trainable_variables(), max_to_keep=30)
if behavior == self.infer:
return
# region get labels LOSS
# Labels
if FLAGS.PARAM.MASK_TYPE == 'PSM':
self._y_labels *= tf.cos(self._x_theta - self._y_theta)
elif FLAGS.PARAM.MASK_TYPE == 'fixPSM':
self._y_labels *= (1.0 +
tf.cos(self._x_theta - self._y_theta)) * 0.5
elif FLAGS.PARAM.MASK_TYPE == 'AcutePM':
self._y_labels *= tf.nn.relu(tf.cos(self._x_theta - self._y_theta))
elif FLAGS.PARAM.MASK_TYPE == 'PowFixPSM':
self._y_labels *= tf.pow(
tf.abs((1.0 + tf.cos(self._x_theta - self._y_theta)) * 0.5),
FLAGS.PARAM.POW_FIX_PSM_COEF)
elif FLAGS.PARAM.MASK_TYPE == 'IRM':
pass
else:
tf.logging.error('Mask type error.')
exit(-1)
# LOSS
if FLAGS.PARAM.LOSS_FUNC_FOR_MAG_SPEC == 'SPEC_MSE': # log_mag and mag MSE
self._loss = loss.reduce_sum_frame_batchsize_MSE(
self._y_estimation, self._y_labels)
if FLAGS.PARAM.USE_CBHG_POST_PROCESSING:
if FLAGS.PARAM.DOUBLE_LOSS:
self._loss = FLAGS.PARAM.CBHG_LOSS_COEF1 * loss.reduce_sum_frame_batchsize_MSE(
self._cbhg_inputs_y_est, self._y_labels
) + FLAGS.PARAM.CBHG_LOSS_COEF2 * self._loss
elif FLAGS.PARAM.LOSS_FUNC_FOR_MAG_SPEC == 'MFCC_SPEC_MSE':
self._loss1, self._loss2 = loss.balanced_MFCC_AND_SPEC_MSE(
self._y_estimation, self._y_labels, self._y_mag_estimation,
self._y_mag_spec)
self._loss = FLAGS.PARAM.SPEC_LOSS_COEF * self._loss1 + FLAGS.PARAM.MFCC_LOSS_COEF * self._loss2
elif FLAGS.PARAM.LOSS_FUNC_FOR_MAG_SPEC == 'MEL_MAG_MSE':
self._loss1, self._loss2 = loss.balanced_MEL_AND_SPEC_MSE(
self._y_estimation, self._y_labels, self._y_mag_estimation,
self._y_mag_spec)
self._loss = FLAGS.PARAM.SPEC_LOSS_COEF * self._loss1 + FLAGS.PARAM.MEL_LOSS_COEF * self._loss2
elif FLAGS.PARAM.LOSS_FUNC_FOR_MAG_SPEC == "SPEC_MSE_LOWF_EN":
self._loss = loss.reduce_sum_frame_batchsize_MSE(
self._y_estimation, self._y_labels)
elif FLAGS.PARAM.LOSS_FUNC_FOR_MAG_SPEC == "FAIR_SPEC_MSE":
self._loss = loss.fair_reduce_sum_frame_batchsize_MSE(
self._y_estimation, self._y_labels)
elif FLAGS.PARAM.LOSS_FUNC_FOR_MAG_SPEC == "SPEC_MSE_FLEXIBLE_POW_C":
self._loss = loss.reduce_sum_frame_batchsize_MSE_EmphasizeLowerValue(
self._y_estimation, self._y_labels, FLAGS.PARAM.POW_COEF)
elif FLAGS.PARAM.LOSS_FUNC_FOR_MAG_SPEC == "RELATED_MSE":
self._loss = loss.relative_reduce_sum_frame_batchsize_MSE(
self._y_estimation, self._y_labels,
FLAGS.PARAM.RELATED_MSE_IGNORE_TH)
elif FLAGS.PARAM.LOSS_FUNC_FOR_MAG_SPEC == "AUTO_RELATED_MSE":
self._loss = loss.auto_ingore_relative_reduce_sum_frame_batchsize_MSE(
self._y_estimation, self._y_labels,
FLAGS.PARAM.AUTO_RELATED_MSE_AXIS_FIT_DEG)
elif FLAGS.PARAM.LOSS_FUNC_FOR_MAG_SPEC == "AUTO_RELATED_MSE2":
self._loss = loss.auto_ingore_relative_reduce_sum_frame_batchsize_MSE_v2(
self._y_estimation,
self._y_labels,
FLAGS.PARAM.AUTO_RELATED_MSE_AXIS_FIT_DEG,
FLAGS.PARAM.LINEAR_BROKER,
)
elif FLAGS.PARAM.LOSS_FUNC_FOR_MAG_SPEC == "AUTO_RELATED_MSE3":
self._loss = loss.auto_ingore_relative_reduce_sum_frame_batchsize_MSE_v3(
self._y_estimation, self._y_labels,
FLAGS.PARAM.AUTO_RELATIVE_LOSS3_A,
FLAGS.PARAM.AUTO_RELATIVE_LOSS3_B,
FLAGS.PARAM.AUTO_RELATIVE_LOSS3_C1,
FLAGS.PARAM.AUTO_RELATIVE_LOSS3_C2)
elif FLAGS.PARAM.LOSS_FUNC_FOR_MAG_SPEC == "AUTO_RELATED_MSE4":
self._loss = loss.auto_ingore_relative_reduce_sum_frame_batchsize_MSE_v4(
self._y_estimation, self._y_labels,
FLAGS.PARAM.AUTO_RELATED_MSE_AXIS_FIT_DEG)
elif FLAGS.PARAM.LOSS_FUNC_FOR_MAG_SPEC == "AUTO_RELATED_MSE5":
self._loss = loss.auto_ingore_relative_reduce_sum_frame_batchsize_MSE_v5(
self._y_estimation, self._y_labels)
elif FLAGS.PARAM.LOSS_FUNC_FOR_MAG_SPEC == "AUTO_RELATED_MSE6":
self._loss = loss.auto_ingore_relative_reduce_sum_frame_batchsize_MSE_v6(
self._y_estimation, self._y_labels,
FLAGS.PARAM.AUTO_RELATIVE_LOSS6_A,
FLAGS.PARAM.AUTO_RELATIVE_LOSS6_B,
FLAGS.PARAM.AUTO_RELATIVE_LOSS6_C1,
FLAGS.PARAM.AUTO_RELATIVE_LOSS6_C2)
elif FLAGS.PARAM.LOSS_FUNC_FOR_MAG_SPEC == "AUTO_RELATED_MSE7":
self._loss = loss.auto_ingore_relative_reduce_sum_frame_batchsize_MSE_v7(
self._y_estimation, self._y_labels,
FLAGS.PARAM.AUTO_RELATIVE_LOSS7_A1,
FLAGS.PARAM.AUTO_RELATIVE_LOSS7_A2,
FLAGS.PARAM.AUTO_RELATIVE_LOSS7_B,
FLAGS.PARAM.AUTO_RELATIVE_LOSS7_C1,
FLAGS.PARAM.AUTO_RELATIVE_LOSS7_C2)
elif FLAGS.PARAM.LOSS_FUNC_FOR_MAG_SPEC == "AUTO_RELATED_MSE8":
self._loss = loss.auto_ingore_relative_reduce_sum_frame_batchsize_MSE_v8(
self._y_estimation, self._y_labels,
FLAGS.PARAM.AUTO_RELATIVE_LOSS8_A,
FLAGS.PARAM.AUTO_RELATIVE_LOSS8_B,
FLAGS.PARAM.AUTO_RELATIVE_LOSS8_C1,
FLAGS.PARAM.AUTO_RELATIVE_LOSS8_C2)
elif FLAGS.PARAM.LOSS_FUNC_FOR_MAG_SPEC == "AUTO_RELATED_MSE_USE_COS":
self._loss = loss.cos_auto_ingore_relative_reduce_sum_frame_batchsize_MSE(
self._y_estimation, self._y_labels,
FLAGS.PARAM.COS_AUTO_RELATED_MSE_W)
elif FLAGS.PARAM.LOSS_FUNC_FOR_MAG_SPEC == 'MEL_AUTO_RELATED_MSE':
# type(y_estimation) = FLAGS.PARAM.LABEL_TYPE
self._loss = loss.MEL_AUTO_RELATIVE_MSE(
self._y_estimation, self._norm_y_mag_spec, FLAGS.PARAM.MEL_NUM,
FLAGS.PARAM.AUTO_RELATED_MSE_AXIS_FIT_DEG)
else:
print('Loss type error.')
exit(-1)
# endregion
if behavior == self.validation:
'''
val model cannot train.
'''
return
self._lr = tf.Variable(0.0, trainable=False) # TODO
tvars = tf.trainable_variables()
grads, _ = tf.clip_by_global_norm(tf.gradients(self.loss, tvars),
FLAGS.PARAM.CLIP_NORM)
optimizer = tf.train.AdamOptimizer(self.lr)
#optimizer = tf.train.GradientDescentOptimizer(self.lr)
self._train_op = optimizer.apply_gradients(zip(grads, tvars))
self._new_lr = tf.placeholder(tf.float32,
shape=[],
name='new_learning_rate')
self._lr_update = tf.assign(self._lr, self._new_lr)
