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ops.py
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ops.py
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from __future__ import print_function
import tensorflow as tf
from tensorflow.contrib.layers import batch_norm, fully_connected, flatten
from tensorflow.contrib.layers import xavier_initializer
from contextlib import contextmanager
import numpy as np
def gaussian_noise_layer(input_layer, std):
noise = tf.random_normal(shape=input_layer.get_shape().as_list(),
mean=0.0,
stddev=std,
dtype=tf.float32)
return input_layer + noise
def sample_random_walk(batch_size, dim):
rw = np.zeros((batch_size, dim))
rw[:, 0] = np.random.randn(batch_size)
for b in range(batch_size):
for di in range(1, dim):
rw[b, di] = rw[b, di - 1] + np.random.randn(1)
# normalize to m=0 std=1
mean = np.mean(rw, axis=1).reshape((-1, 1))
std = np.std(rw, axis=1).reshape((-1, 1))
rw = (rw - mean) / std
return rw
def scalar_summary(name, x):
try:
summ = tf.summary.scalar(name, x)
except AttributeError:
summ = tf.scalar_summary(name, x)
return summ
def histogram_summary(name, x):
try:
summ = tf.summary.histogram(name, x)
except AttributeError:
summ = tf.histogram_summary(name, x)
return summ
def tensor_summary(name, x):
try:
summ = tf.summary.tensor_summary(name, x)
except AttributeError:
summ = tf.tensor_summary(name, x)
return summ
def audio_summary(name, x, sampling_rate=16e3):
try:
summ = tf.summary.audio(name, x, sampling_rate)
except AttributeError:
summ = tf.audio_summary(name, x, sampling_rate)
return summ
def minmax_normalize(x, x_min, x_max, o_min=-1., o_max=1.):
return (o_max - o_min)/(x_max - x_min) * (x - x_max) + o_max
def minmax_denormalize(x, x_min, x_max, o_min=-1., o_max=1.):
return minmax_normalize(x, o_min, o_max, x_min, x_max)
def downconv(x, output_dim, kwidth=5, pool=2, init=None, uniform=False,
bias_init=None, name='downconv'):
""" Downsampled convolution 1d """
x2d = tf.expand_dims(x, 2)
w_init = init
if w_init is None:
w_init = xavier_initializer(uniform=uniform)
with tf.variable_scope(name):
W = tf.get_variable('W', [kwidth, 1, x.get_shape()[-1], output_dim],
initializer=w_init)
conv = tf.nn.conv2d(x2d, W, strides=[1, pool, 1, 1], padding='SAME')
if bias_init is not None:
b = tf.get_variable('b', [output_dim],
initializer=bias_init)
conv = tf.reshape(tf.nn.bias_add(conv, b), conv.get_shape())
else:
conv = tf.reshape(conv, conv.get_shape())
# reshape back to 1d
conv = tf.reshape(conv, conv.get_shape().as_list()[:2] +
[conv.get_shape().as_list()[-1]])
return conv
# https://github.com/carpedm20/lstm-char-cnn-tensorflow/blob/master/models/ops.py
def highway(input_, size, layer_size=1, bias=-2, f=tf.nn.relu, name='hw'):
"""Highway Network (cf. http://arxiv.org/abs/1505.00387).
t = sigmoid(Wy + b)
z = t * g(Wy + b) + (1 - t) * y
where g is nonlinearity, t is transform gate, and (1 - t) is carry gate.
"""
output = input_
for idx in xrange(layer_size):
lin_scope = '{}_output_lin_{}'.format(name, idx)
output = f(tf.nn.rnn_cell._linear(output, size, 0, scope=lin_scope))
transform_scope = '{}_transform_lin_{}'.format(name, idx)
transform_gate = tf.sigmoid(
tf.nn.rnn_cell._linear(input_, size, 0, scope=transform_scope) + bias)
carry_gate = 1. - transform_gate
output = transform_gate * output + carry_gate * input_
return output
def leakyrelu(x, alpha=0.3, name='lrelu'):
return tf.maximum(x, alpha * x, name=name)
def prelu(x, name='prelu', ref=False):
in_shape = x.get_shape().as_list()
with tf.variable_scope(name):
# make one alpha per feature
alpha = tf.get_variable('alpha', in_shape[-1],
initializer=tf.constant_initializer(0.),
dtype=tf.float32)
pos = tf.nn.relu(x)
neg = alpha * (x - tf.abs(x)) * .5
if ref:
# return ref to alpha vector
return pos + neg, alpha
else:
return pos + neg
def conv1d(x, kwidth=5, num_kernels=1, init=None, uniform=False, bias_init=None,
name='conv1d', padding='SAME'):
input_shape = x.get_shape()
in_channels = input_shape[-1]
assert len(input_shape) >= 3
w_init = init
if w_init is None:
w_init = xavier_initializer(uniform=uniform)
with tf.variable_scope(name):
# filter shape: [kwidth, in_channels, num_kernels]
W = tf.get_variable('W', [kwidth, in_channels, num_kernels],
initializer=w_init
)
conv = tf.nn.conv1d(x, W, stride=1, padding=padding)
if bias_init is not None:
b = tf.get_variable('b', [num_kernels],
initializer=tf.constant_initializer(bias_init))
conv = conv + b
return conv
def time_to_batch(value, dilation, name=None):
with tf.name_scope('time_to_batch'):
shape = tf.shape(value)
pad_elements = dilation - 1 - (shape[1] + dilation - 1) % dilation
padded = tf.pad(value, [[0, 0], [0, pad_elements], [0, 0]])
reshaped = tf.reshape(padded, [-1, dilation, shape[2]])
transposed = tf.transpose(reshaped, perm=[1, 0, 2])
return tf.reshape(transposed, [shape[0] * dilation, -1, shape[2]])
# https://github.com/ibab/tensorflow-wavenet/blob/master/wavenet/ops.py
def batch_to_time(value, dilation, name=None):
with tf.name_scope('batch_to_time'):
shape = tf.shape(value)
prepared = tf.reshape(value, [dilation, -1, shape[2]])
transposed = tf.transpose(prepared, perm=[1, 0, 2])
return tf.reshape(transposed,
[tf.div(shape[0], dilation), -1, shape[2]])
def atrous_conv1d(value, dilation, kwidth=3, num_kernels=1,
name='atrous_conv1d', bias_init=None, stddev=0.02):
input_shape = value.get_shape().as_list()
in_channels = input_shape[-1]
assert len(input_shape) >= 3
with tf.variable_scope(name):
weights_init = tf.truncated_normal_initializer(stddev=0.02)
# filter shape: [kwidth, in_channels, output_channels]
filter_ = tf.get_variable('w', [kwidth, in_channels, num_kernels],
initializer=weights_init,
)
padding = [[0, 0], [(kwidth/2) * dilation, (kwidth/2) * dilation],
[0, 0]]
padded = tf.pad(value, padding, mode='SYMMETRIC')
if dilation > 1:
transformed = time_to_batch(padded, dilation)
conv = tf.nn.conv1d(transformed, filter_, stride=1, padding='SAME')
restored = batch_to_time(conv, dilation)
else:
restored = tf.nn.conv1d(padded, filter_, stride=1, padding='SAME')
# Remove excess elements at the end.
result = tf.slice(restored,
[0, 0, 0],
[-1, input_shape[1], num_kernels])
if bias_init is not None:
b = tf.get_variable('b', [num_kernels],
initializer=tf.constant_initializer(bias_init))
result = tf.add(result, b)
return result
def residual_block(input_, dilation, kwidth, num_kernels=1,
bias_init=None, stddev=0.02, do_skip=True,
name='residual_block'):
print('input shape to residual block: ', input_.get_shape())
with tf.variable_scope(name):
h_a = atrous_conv1d(input_, dilation, kwidth, num_kernels,
bias_init=bias_init, stddev=stddev)
h = tf.tanh(h_a)
# apply gated activation
z_a = atrous_conv1d(input_, dilation, kwidth, num_kernels,
name='conv_gate', bias_init=bias_init,
stddev=stddev)
z = tf.nn.sigmoid(z_a)
print('gate shape: ', z.get_shape())
# element-wise apply the gate
gated_h = tf.mul(z, h)
print('gated h shape: ', gated_h.get_shape())
#make res connection
h_ = conv1d(gated_h, kwidth=1, num_kernels=1,
init=tf.truncated_normal_initializer(stddev=stddev),
name='residual_conv1')
res = h_ + input_
print('residual result: ', res.get_shape())
if do_skip:
#make skip connection
skip = conv1d(gated_h, kwidth=1, num_kernels=1,
init=tf.truncated_normal_initializer(stddev=stddev),
name='skip_conv1')
return res, skip
else:
return res
# Code from keras backend
# https://github.com/fchollet/keras/blob/master/keras/backend/tensorflow_backend.py
def repeat_elements(x, rep, axis):
"""Repeats the elements of a tensor along an axis, like `np.repeat`.
If `x` has shape `(s1, s2, s3)` and `axis` is `1`, the output
will have shape `(s1, s2 * rep, s3)`.
# Arguments
x: Tensor or variable.
rep: Python integer, number of times to repeat.
axis: Axis along which to repeat.
# Raises
ValueError: In case `x.shape[axis]` is undefined.
# Returns
A tensor.
"""
x_shape = x.get_shape().as_list()
if x_shape[axis] is None:
raise ValueError('Axis ' + str(axis) + ' of input tensor '
'should have a defined dimension, but is None. '
'Full tensor shape: ' + str(tuple(x_shape)) + '. '
'Typically you need to pass a fully-defined '
'`input_shape` argument to your first layer.')
# slices along the repeat axis
splits = tf.split(split_dim=axis, num_split=x_shape[axis], value=x)
# repeat each slice the given number of reps
x_rep = [s for s in splits for _ in range(rep)]
return tf.concat(axis, x_rep)
def nn_deconv(x, kwidth=5, dilation=2, init=None, uniform=False,
bias_init=None, name='nn_deconv1d'):
# first compute nearest neighbour interpolated x
interp_x = repeat_elements(x, dilation, 1)
# run a convolution over the interpolated fmap
dec = conv1d(interp_x, kwidth=5, num_kernels=1, init=init, uniform=uniform,
bias_init=bias_init, name=name, padding='SAME')
return dec
def deconv(x, output_shape, kwidth=5, dilation=2, init=None, uniform=False,
bias_init=None, name='deconv1d'):
input_shape = x.get_shape()
in_channels = input_shape[-1]
out_channels = output_shape[-1]
assert len(input_shape) >= 3
# reshape the tensor to use 2d operators
x2d = tf.expand_dims(x, 2)
o2d = output_shape[:2] + [1] + [output_shape[-1]]
w_init = init
if w_init is None:
w_init = xavier_initializer(uniform=uniform)
with tf.variable_scope(name):
# filter shape: [kwidth, output_channels, in_channels]
W = tf.get_variable('W', [kwidth, 1, out_channels, in_channels],
initializer=w_init
)
try:
deconv = tf.nn.conv2d_transpose(x2d, W, output_shape=o2d,
strides=[1, dilation, 1, 1])
except AttributeError:
# support for versions of TF before 0.7.0
# based on https://github.com/carpedm20/DCGAN-tensorflow
deconv = tf.nn.deconv2d(x2d, W, output_shape=o2d,
strides=[1, dilation, 1, 1])
if bias_init is not None:
b = tf.get_variable('b', [out_channels],
initializer=tf.constant_initializer(0.))
deconv = tf.reshape(tf.nn.bias_add(deconv, b), deconv.get_shape())
else:
deconv = tf.reshape(deconv, deconv.get_shape())
# reshape back to 1d
deconv = tf.reshape(deconv, output_shape)
return deconv
def conv2d(input_, output_dim, k_h, k_w, stddev=0.05, name="conv2d", with_w=False):
with tf.variable_scope(name):
w = tf.get_variable('w', [k_h, k_w, input_.get_shape()[-1], output_dim],
initializer=tf.truncated_normal_initializer(stddev=stddev))
conv = tf.nn.conv2d(input_, w, strides=[1, 1, 1, 1], padding='VALID')
if with_w:
return conv, w
else:
return conv
# https://github.com/openai/improved-gan/blob/master/imagenet/ops.py
@contextmanager
def variables_on_gpu0():
old_fn = tf.get_variable
def new_fn(*args, **kwargs):
with tf.device("/gpu:0"):
return old_fn(*args, **kwargs)
tf.get_variable = new_fn
yield
tf.get_variable = old_fn
def average_gradients(tower_grads):
""" Calculate the average gradient for each shared variable across towers.
Note that this function provides a sync point across al towers.
Args:
tower_grads: List of lists of (gradient, variable) tuples. The outer
list is over individual gradients. The inner list is over the gradient
calculation for each tower.
Returns:
List of pairs of (gradient, variable) where the gradient has been
averaged across all towers.
"""
average_grads = []
for grad_and_vars in zip(*tower_grads):
# each grad is ((grad0_gpu0, var0_gpu0), ..., (grad0_gpuN, var0_gpuN))
grads = []
for g, _ in grad_and_vars:
# Add 0 dim to gradients to represent tower
expanded_g = tf.expand_dims(g, 0)
# Append on a 'tower' dimension that we will average over below
grads.append(expanded_g)
# Build the tensor and average along tower dimension
grad = tf.concat(0, grads)
grad = tf.reduce_mean(grad, 0)
# The Variables are redundant because they are shared across towers
# just return first tower's pointer to the Variable
v = grad_and_vars[0][1]
grad_and_var = (grad, v)
average_grads.append(grad_and_var)
return average_grads