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layers.py
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# layers.py ---
#
# Filename: layers.py
# Description: Special layers not included in tensorflow
# Author: Kwang Moo Yi
# Maintainer: Kwang Moo Yi
# Created: Thu Jun 29 12:23:35 2017 (+0200)
# Version:
# Package-Requires: ()
# URL:
# Doc URL:
# Keywords:
# Compatibility:
#
#
# Commentary:
#
#
#
#
# Change Log:
#
#
#
# Copyright (C), EPFL Computer Vision Lab.
# Code:
import numpy as np
import tensorflow as tf
import tensorflow.contrib.layers as tcl
from six.moves import xrange
from utils import get_tensor_shape, get_W_b_conv2d, get_W_b_fc
def leaky_relu(x, alpha=0.2):
return tf.maximum(tf.minimum(0.0, alpha * x), x)
def relu(x):
return tf.nn.relu(x)
def batch_norm(x, training, data_format="NHWC"):
# return tcl.batch_norm(x, center=True, scale=True, is_training=training, data_format=data_format)
if data_format == "NHWC":
axis = -1
else:
axis = 1
return tf.layers.batch_normalization(x, training=training, trainable=False, axis=axis)
def norm_spatial_subtractive(inputs, sub_kernel, data_format="NHWC"):
"""Performs the spatial subtractive normalization
Parameters
----------
inputs: tensorflow 4D tensor, NHWC format
input to the network
sub_kernel: numpy.ndarray, 2D matrix
the subtractive normalization kernel
"""
raise NotImplementedError(
"This function is buggy! don't use before extensive debugging!")
# ----------
# Normalize kernel.
# Note that unlike Torch, we don't divide the kernel here. We divide
# when it is fed to the convolution, since we use it to generate the
# coefficient map.
kernel = sub_kernel.astype("float32")
norm_kernel = (kernel / np.sum(kernel))
# ----------
# Compute the adjustment coef.
# This allows our mean computation to compensate for the border area,
# where you have less terms adding up. Torch used convolution with a
# ``one'' image, but since we do not want the library to depend on
# other libraries with convolutions, we do it manually here.
input_shape = get_tensor_shape(inputs)
assert len(input_shape) == 4
if data_format == "NHWC":
coef = np.ones(input_shape[1:3], dtype="float32")
else:
coef = np.ones(input_shape[2:], dtype="float32")
pad_x = norm_kernel.shape[1] // 2
pad_y = norm_kernel.shape[0] // 2
# Corners
# for the top-left corner
tl_cumsum_coef = np.cumsum(np.cumsum(
norm_kernel[::-1, ::-1], axis=0), axis=1)[::1, ::1]
coef[:pad_y + 1, :pad_x + 1] = tl_cumsum_coef[pad_y:, pad_x:]
# for the top-right corner
tr_cumsum_coef = np.cumsum(np.cumsum(
norm_kernel[::-1, ::1], axis=0), axis=1)[::1, ::-1]
coef[:pad_y + 1, -pad_x - 1:] = tr_cumsum_coef[pad_y:, :pad_x + 1]
# for the bottom-left corner
bl_cumsum_coef = np.cumsum(np.cumsum(
norm_kernel[::1, ::-1], axis=0), axis=1)[::-1, ::1]
coef[-pad_y - 1:, :pad_x + 1] = bl_cumsum_coef[:pad_y + 1, pad_x:]
# for the bottom-right corner
br_cumsum_coef = np.cumsum(np.cumsum(
norm_kernel[::1, ::1], axis=0), axis=1)[::-1, ::-1]
coef[-pad_y - 1:, -pad_x - 1:] = br_cumsum_coef[:pad_y + 1, :pad_x + 1]
# Sides
tb_slice = slice(pad_y + 1, -pad_y - 1)
# for the left side
fill_value = tl_cumsum_coef[-1, pad_x:]
coef[tb_slice, :pad_x + 1] = fill_value.reshape([1, -1])
# for the right side
fill_value = br_cumsum_coef[0, :pad_x + 1]
coef[tb_slice, -pad_x - 1:] = fill_value.reshape([1, -1])
lr_slice = slice(pad_x + 1, -pad_x - 1)
# for the top side
fill_value = tl_cumsum_coef[pad_y:, -1]
coef[:pad_y + 1, lr_slice] = fill_value.reshape([-1, 1])
# for the right side
fill_value = br_cumsum_coef[:pad_y + 1, 0]
coef[-pad_y - 1:, lr_slice] = fill_value.reshape([-1, 1])
# # code for validation of above
# img = np.ones_like(input, dtype='float32')
# import cv2
# coef_cv2 = cv2.filter2D(img, -1, norm_kernel,
# borderType=cv2.BORDER_CONSTANT)
# ----------
# Extract convolutional mean
# Make filter a c01 filter by repeating. Note that we normalized above
# with the number of repetitions we are going to do.
if data_format == "NHWC":
norm_kernel = np.tile(norm_kernel, [input_shape[-1], 1, 1])
else:
norm_kernel = np.tile(norm_kernel, [input_shape[1], 1, 1])
# Re-normlize the kernel so that the sum is one.
norm_kernel /= np.sum(norm_kernel)
# add another axis in from to make oc01 filter, where o is the number
# of output dimensions (in our case, 1!)
norm_kernel = norm_kernel[np.newaxis, ...]
# # To pad with zeros, half the size of the kernel (only for 01 dims)
# border_mode = tuple(s // 2 for s in norm_kernel.shape[2:])
# Convolve the mean filter. Results in shape of (batch_size,
# input_shape[1], input_shape[2], 1).
# For tensorflow, the kernel shape is 01co, which is different.... why?!
conv_mean = tf.nn.conv2d(
inputs,
norm_kernel.astype("float32").transpose(2, 3, 1, 0),
strides=[1, 1, 1, 1],
padding="SAME",
data_format=data_format,
)
# ----------
# Adjust convolutional mean with precomputed coef
# This is to prevent border values being too small.
if data_format == "NHWC":
coef = coef[None][..., None].astype("float32")
else:
coef = coef[None, None].astype("float32")
adj_mean = conv_mean / coef
# # Make second dimension broadcastable as we are going to
# # subtract for all channels.
# adj_mean = T.addbroadcast(adj_mean, 1)
# ----------
# Subtract mean
sub_normalized = inputs - adj_mean
# # line for debugging
# test = theano.function(inputs=[input], outputs=[sub_normalized])
return sub_normalized
def pool_l2(inputs, ksize, stride, padding, data_format="NHWC"):
"""L2 pooling, NHWC"""
if data_format == "NHWC":
ksizes = [1, ksize, ksize, 1]
strides = [1, stride, stride, 1]
else:
ksizes = [1, 1, ksize, ksize]
strides = [1, 1, stride, stride]
scaler = tf.cast(ksize * ksize, tf.float32)
return tf.sqrt(
scaler * # Multiply since we want to sum
tf.nn.avg_pool(
tf.square(inputs),
ksize=ksizes,
strides=strides,
padding=padding,
data_format=data_format,
))
def pool_max(inputs, ksize, stride, padding, data_format="NHWC"):
"""max pooling, NHWC"""
if data_format == "NHWC":
ksizes = [1, ksize, ksize, 1]
strides = [1, stride, stride, 1]
else:
ksizes = [1, 1, ksize, ksize]
strides = [1, 1, stride, stride]
return tf.nn.max_pool(
inputs,
ksize=ksizes,
strides=strides,
padding=padding,
data_format=data_format,
)
def pool_avg(inputs, ksize, stride, padding, data_format="NHWC"):
"""max pooling, NHWC"""
if data_format == "NHWC":
ksizes = [1, ksize, ksize, 1]
strides = [1, stride, stride, 1]
else:
ksizes = [1, 1, ksize, ksize]
strides = [1, 1, stride, stride]
return tf.nn.avg_pool(
inputs,
ksize=ksizes,
strides=strides,
padding=padding,
data_format=data_format,
)
def conv_2d(inputs, ksize, nchannel, stride, padding, data_format="NHWC"):
"""conv 2d, NHWC"""
if data_format == "NHWC":
fanin = get_tensor_shape(inputs)[-1]
strides = [1, stride, stride, 1]
else:
fanin = get_tensor_shape(inputs)[1]
strides = [1, 1, stride, stride]
W, b = get_W_b_conv2d(ksize=ksize, fanin=fanin, fanout=nchannel)
conv = tf.nn.conv2d(
inputs, W, strides=strides,
padding=padding, data_format=data_format)
return tf.nn.bias_add(conv, b, data_format=data_format)
def conv_2d_trans(inputs, ksize, nchannel, stride, padding, data_format="NHWC"):
"""conv 2d, transposed, NHWC"""
assert(padding == "VALID")
inshp = tf.shape(inputs)
if data_format == "NHWC":
fanin = get_tensor_shape(inputs)[-1]
strides = [1, stride, stride, 1]
output_shape = tf.stack(
[inshp[0],
inshp[1] * int(stride), # + max(ksize - stride, 0),
inshp[2] * int(stride), # + max(ksize - stride, 0),
nchannel])
else:
fanin = get_tensor_shape(inputs)[1]
strides = [1, 1, stride, stride]
output_shape = tf.stack(
[inshp[0],
nchannel,
inshp[2] * int(stride), # + max(ksize - stride, 0),
inshp[3] * int(stride), # + max(ksize - stride, 0)
])
with tf.variable_scope("W"):
W, _ = get_W_b_conv2d(ksize=ksize, fanin=nchannel, fanout=fanin)
with tf.variable_scope("b"):
_, b = get_W_b_conv2d(ksize=ksize, fanin=fanin, fanout=nchannel)
deconv2dres = tf.nn.conv2d_transpose(
inputs, W, output_shape, strides=strides, padding=padding,
data_format=data_format)
deconv2dres = tf.reshape(deconv2dres, output_shape)
return tf.nn.bias_add(deconv2dres, b, data_format=data_format)
def fc(inputs, fanout):
"""fully connected, NC """
inshp = get_tensor_shape(inputs)
fanin = np.prod(inshp[1:])
# Flatten input if needed
if len(inshp) > 2:
inputs = tf.reshape(inputs, (inshp[0], fanin))
W, b = get_W_b_fc(fanin=fanin, fanout=fanout)
mul = tf.matmul(inputs, W)
return tf.nn.bias_add(mul, b)
def ghh(inputs, num_in_sum, num_in_max, data_format="NHWC"):
"""GHH layer
LATER: Make it more efficient
"""
# Assert NHWC
assert data_format == "NHWC"
# Check validity
inshp = get_tensor_shape(inputs)
num_channels = inshp[-1]
pool_axis = len(inshp) - 1
assert (num_channels % (num_in_sum * num_in_max)) == 0
# Abuse cur_in
cur_in = inputs
# # Okay the maxpooling and avgpooling functions do not like weird
# # pooling. Just reshape to avoid this issue.
# inshp = get_tensor_shape(inputs)
# numout = int(inshp[1] / (num_in_sum * num_in_max))
# cur_in = tf.reshape(cur_in, [
# inshp[0], numout, num_in_sum, num_in_max, inshp[2], inshp[3]
# ])
# Reshaping does not work for undecided input sizes. use split instead
cur_ins_to_max = tf.split(
cur_in, num_channels // num_in_max, axis=pool_axis)
# Do max and concat them back
cur_in = tf.concat([
tf.reduce_max(cur_ins, axis=pool_axis, keep_dims=True) for
cur_ins in cur_ins_to_max
], axis=pool_axis)
# Create delta
delta = (1.0 - 2.0 * (np.arange(num_in_sum) % 2)).astype("float32")
delta = tf.reshape(delta, [1] * (len(inshp) - 1) + [num_in_sum])
# Again, split into multiple pieces
cur_ins_to_sum = tf.split(
cur_in, num_channels // (num_in_max * num_in_sum),
axis=pool_axis)
# Do delta multiplication, sum, and concat them back
cur_in = tf.concat([
tf.reduce_sum(cur_ins * delta, axis=pool_axis, keep_dims=True) for
cur_ins in cur_ins_to_sum
], axis=pool_axis)
return cur_in
def crop_and_concat(x1, x2):
""" Crop x1 as size x2 and concat """
x1_shape = tf.shape(x1)
x2_shape = tf.shape(x2)
# x1_shape = [_s if _s is not None else -
# 1 for _s in x1.get_shape().as_list()]
# x2_shape = [_s if _s is not None else -
# 1 for _s in x2.get_shape().as_list()]
# offsets for the top left corner of the crop
offsets = [0,
(x1_shape[1] - x2_shape[1]) // 2,
(x1_shape[2] - x2_shape[2]) // 2,
0]
size = [-1, x2_shape[1], x2_shape[2], -1]
x1_crop = tf.slice(x1, offsets, size)
# return tf.concat(3, [x1_crop, x2])
return tf.concat([x1_crop, x2], axis=3)
def conv2d_unet(x, n_class, is_training, layers=3, features_root=16,
filter_size=4, pool_size=2, max_features=512,
pool_method="stride", padding="VALID",
last_activation_fn=None, init_stddev=0.02,
data_format="NHWC"):
"""
Creates a new convolutional unet for the given parametrization.
:param x: input tensor, shape [?,nx,ny,channels]
:param channels: number of channels in the input image
:param n_class: number of output labels
:param layers: number of layers in the net
:param features_root: number of features in the first layer
:param filter_size: size of the convolution filter
:param pool_size: size of the max pooling operation
:param summaries: Flag if summaries should be created
"""
in_node = x
if pool_method == "stride":
stride = 2
else:
raise NotImplementedError("TODO")
dw_convs = {}
# Initial convolution (no residual here, no activation)
with tf.variable_scope("initconv"):
in_node = conv_2d(
in_node, ksize=filter_size,
nchannel=features_root,
stride=1,
padding=padding,
data_format=data_format,
)
# in_node = batch_norm(in_node, is_training)
# in_node = tf.nn.relu(in_node)
print("Input---")
print("output shape = {}".format(in_node.get_shape()))
# Original input as -1 dw_h_conv layer
dw_convs[-1] = in_node
# layer n with have num_features[n] channels as output
num_features = {}
for layer in xrange(-1, layers):
num_features[layer] = int(
min(max_features, 2**(layer + 1) * features_root))
# num_features[layers - 1] = num_features[layers - 2]
# down layers
print("Conv down---")
with tf.variable_scope("convdown"):
for layer in range(0, layers):
with tf.variable_scope("level" + str(layer)):
features_out = num_features[layer]
# Bn-relu-conv
in_node = batch_norm(in_node, is_training)
in_node = tf.nn.relu(in_node)
# Conv with strides instead of pooling!
# in_node = conv_2d(
# in_node, ksize=stride,
# nchannel=features_out,
# stride=stride,
# padding=padding,
# data_format=data_format,
# )
in_node = conv_2d(
in_node, ksize=stride,
nchannel=features_out,
stride=1,
padding=padding,
data_format=data_format,
)
in_node = pool_avg(
in_node,
ksize=2,
stride=2,
padding=padding,
data_format=data_format,
)
dw_convs[layer] = in_node
print("output shape = {}".format(dw_convs[layer].get_shape()))
in_node = dw_convs[layers - 1]
# up layers
print("Conv up---")
with tf.variable_scope("convup"):
# from layers -2 to -1
for layer in range(layers - 2, -2, -1):
# print(layer)
with tf.variable_scope("level" + str(layer)):
# features_in = num_features[layer + 1]
features_out = num_features[layer]
# # Unpool if necessary
# if pool_method != "stride":
# with tf.variable_scope("unpool"):
# in_node = conv_2d_trans(
# in_node, ksize=filter_size,
# nchannel=features_in,
# stride=stride,
# padding=padding,
# data_format=data_format,
# )
# Perform deconv
with tf.variable_scope("deconv"):
in_node = batch_norm(in_node, is_training)
in_node = tf.nn.relu(in_node)
in_node = conv_2d_trans(
in_node, ksize=filter_size,
nchannel=features_out,
stride=stride,
padding=padding,
data_format=data_format,
)
# Bring in skip connections
in_node = crop_and_concat(
dw_convs[layer], in_node)
# mark that the features_in is now doubled
# features_in = num_features[layer + 1] + num_features[layer]
# Convolve with skip connections
with tf.variable_scope("conv"):
in_node = batch_norm(in_node, is_training)
in_node = tf.nn.relu(in_node)
in_node = conv_2d(
in_node, ksize=filter_size,
nchannel=features_out,
stride=1,
padding=padding,
data_format=data_format,
)
print("output shape = {}".format(in_node.get_shape()))
# Final convolution (no activation, no residual)
with tf.variable_scope("lastconv"):
# Do a batch normalization before the final, just as we did for input
with tf.variable_scope("last-pre-bn"):
in_node = batch_norm(in_node, is_training)
# Then do the proper thing
in_node = conv_2d(
in_node, ksize=1,
nchannel=n_class,
stride=1,
padding=padding,
data_format=data_format,
)
print("output shape = {}".format(in_node.get_shape()))
output_map = in_node
return output_map
#
# layers.py ends here