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ops.py
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ops.py
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import tensorflow as tf
import tensorflow.compat.v1.layers as layers
import numpy as np
import random as rr
import math as mt
import cv2
from scipy import misc
def instance_norm(input, name="instance_norm"):
with tf.compat.v1.variable_scope(name):
depth = input.get_shape()[3]
scale = tf.compat.v1.get_variable("scale", [depth], initializer=tf.compat.v1.random_normal_initializer(1.0, 0.02, dtype=tf.float32))
offset = tf.compat.v1.get_variable("offset", [depth], initializer=tf.compat.v1.constant_initializer(0.0))
mean, variance = tf.nn.moments(x=input, axes=[1,2], keepdims=True)
epsilon = 1e-5
inv = tf.math.rsqrt(variance + epsilon)
normalized = (input-mean)*inv
return scale*normalized + offset
def make_sq_mask(size, m_size, batch_size):
start_x = rr.randint(0, size - m_size-1)
start_y = rr.randint(0, size - m_size-1)
temp = np.ones([batch_size, size, size, 3])
temp[:, start_x:start_x + m_size, start_y:start_y + m_size, 0:3] *= 0
return temp, start_x, start_y
def softmax(input):
k = tf.exp(input - 3)
k = tf.reduce_sum(input_tensor=k, axis=3, keepdims=True)
# k = k - num * tf.ones_like(k)
ouput = tf.exp(input - 3) / k
return ouput
def reduce_var(x, axis=None, keepdims=False):
"""Variance of a tensor, alongside the specified axis.
# Arguments
x: A tensor or variable.
axis: An integer, the axis to compute the variance.
keepdims: A boolean, whether to keep the dimensions or not.
If `keepdims` is `False`, the rank of the tensor is reduced
by 1. If `keepdims` is `True`,
the reduced dimension is retained with length 1.
# Returns
A tensor with the variance of elements of `x`.
"""
m = tf.reduce_mean(input_tensor=x, axis=axis, keepdims=True)
devs_squared = tf.square(x - m)
return tf.reduce_mean(input_tensor=devs_squared, axis=axis, keepdims=keepdims)
def reduce_std(x, axis=None, keepdims=False):
"""Standard deviation of a tensor, alongside the specified axis.
# Arguments
x: A tensor or variable.
axis: An integer, the axis to compute the standard deviation.
keepdims: A boolean, whether to keep the dimensions or not.
If `keepdims` is `False`, the rank of the tensor is reduced
by 1. If `keepdims` is `True`,
the reduced dimension is retained with length 1.
# Returns
A tensor with the standard deviation of elements of `x`.
"""
return tf.sqrt(reduce_var(x, axis=axis, keepdims=keepdims))
def l2_norm(v, eps=1e-12):
return v / (tf.reduce_sum(input_tensor=v ** 2) ** 0.5 + eps)
def ff_mask(size, b_zise, maxLen, maxWid, maxAng, maxNum, maxVer, minLen = 20, minWid = 15, minVer = 5):
mask = np.ones((b_zise, size, size, 3))
num = rr.randint(3, maxNum)
for i in range(num):
startX = rr.randint(0, size)
startY = rr.randint(0, size)
numVer = rr.randint(minVer, maxVer)
width = rr.randint(minWid, maxWid)
for j in range(numVer):
angle = rr.uniform(-maxAng, maxAng)
length = rr.randint(minLen, maxLen)
endX = min(size-1, max(0, int(startX + length * mt.sin(angle))))
endY = min(size-1, max(0, int(startY + length * mt.cos(angle))))
if endX >= startX:
lowx = startX
highx = endX
else:
lowx = endX
highx = startX
if endY >= startY:
lowy = startY
highy = endY
else:
lowy = endY
highy = startY
if abs(startY-endY) + abs(startX - endX) != 0:
wlx = max(0, lowx-int(abs(width * mt.cos(angle))))
whx = min(size - 1, highx+1 + int(abs(width * mt.cos(angle))))
wly = max(0, lowy - int(abs(width * mt.sin(angle))))
why = min(size - 1, highy+1 + int(abs(width * mt.sin(angle))))
for x in range(wlx, whx):
for y in range(wly, why):
d = abs((endY-startY)*x - (endX -startX)*y - endY*startX + startY*endX) / mt.sqrt((startY-endY)**2 + (startX -endX)**2)
if d <= width:
mask[:, x, y, :] = 0
wlx = max(0, lowx-width)
whx = min(size - 1, highx+width+1)
wly = max(0, lowy - width)
why = min(size - 1, highy + width + 1)
for x2 in range(wlx, whx):
for y2 in range(wly, why):
d1 = (startX - x2) ** 2 + (startY - y2) ** 2
d2 = (endX - x2) ** 2 + (endY - y2) ** 2
if np.sqrt(d1) <= width:
mask[:, x2, y2, :] = 0
if np.sqrt(d2) <= width:
mask[:, x2, y2, :] = 0
startX = endX
startY = endY
return mask
def ff_mask_batch(size, b_size, maxLen, maxWid, maxAng, maxNum, maxVer, minLen = 20, minWid = 15, minVer = 5):
mask = None
temp = ff_mask(size, 1, maxLen, maxWid, maxAng, maxNum, maxVer, minLen=minLen, minWid=minWid, minVer=minVer)
temp = temp[0]
for ib in range(b_size):
if ib == 0:
mask = np.expand_dims(temp, 0)
else:
mask = np.concatenate((mask, np.expand_dims(temp, 0)), 0)
temp = cv2.rotate(temp, cv2.ROTATE_90_CLOCKWISE)
if ib == 3:
temp = cv2.flip(temp, 0)
return mask
def spectral_norm(w, name, iteration=1):
w_shape = w.shape.as_list()
w = tf.reshape(w, [-1, w_shape[-1]])
u = tf.compat.v1.get_variable(name+"u", [1, w_shape[-1]], initializer=tf.compat.v1.truncated_normal_initializer(), trainable=False)
u_hat = u
v_hat = None
for i in range(iteration):
"""
power iteration
Usually iteration = 1 will be enough
"""
v_ = tf.matmul(u_hat, tf.transpose(a=w))
v_hat = l2_norm(v_)
u_ = tf.matmul(v_hat, w)
u_hat = l2_norm(u_)
sigma = tf.matmul(tf.matmul(v_hat, w), tf.transpose(a=u_hat))
w_norm = w / sigma
with tf.control_dependencies([u.assign(u_hat)]):
w_norm = tf.reshape(w_norm, w_shape)
return w_norm
def convolution_SN(tensor, output_dim, kernel_size, stride, name):
_, h, w, c = [i for i in tensor.get_shape()]
w = tf.compat.v1.get_variable(name=name + 'w', shape=[kernel_size, kernel_size, c, output_dim], initializer=tf.compat.v1.keras.initializers.glorot_normal())
b = tf.compat.v1.get_variable(name=name + 'b', shape=[output_dim], initializer=tf.compat.v1.constant_initializer(0.0))
output = tf.nn.conv2d(input=tensor, filters=spectral_norm(w, name=name + 'w'), strides=[1, stride, stride, 1], padding='SAME') + b
return output
def dense_SN(tensor, output_dim, name):
_, h, w, c = [i for i in tensor.get_shape()]
w = tf.compat.v1.get_variable(name=name + 'w', shape=[h, w, c, output_dim], initializer=tf.compat.v1.keras.initializers.glorot_normal())
b = tf.compat.v1.get_variable(name=name + 'b', shape=[output_dim], initializer=tf.compat.v1.constant_initializer(0.0))
output = tf.nn.conv2d(input=tensor, filters=spectral_norm(w, name=name + 'w'), strides=[1, 1, 1, 1], padding='VALID') + b
return output
def dense_RED_SN(tensor, name):
sn_w = None
_, h, w, c = [i for i in tensor.get_shape()]
h = int(h)
w = int(w)
c = int(c)
weight = tf.compat.v1.get_variable(name=name + '_w', shape=[h*w, 1, c, 1], initializer=tf.compat.v1.keras.initializers.glorot_normal())
b = tf.compat.v1.get_variable(name=name + '_b', shape=[1, h, w, 1], initializer=tf.compat.v1.constant_initializer(0.0))
for it in range(h*w):
w_pixel = weight[it:it+1, :, :, :]
sn_w_pixel = spectral_norm(w_pixel, name=name + 'w_%d' %it)
if it == 0:
sn_w = sn_w_pixel
else:
sn_w = tf.concat([sn_w, sn_w_pixel], axis=0)
w_rs = tf.reshape(sn_w, [h, w, c, 1])
w_rs_t = tf.transpose(a=w_rs, perm=[3, 0, 1, 2])
output_RED = tf.reduce_sum(input_tensor=tensor*w_rs_t + b, axis=3, keepdims=True)
return output_RED