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INetwork.py
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INetwork.py
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from __future__ import print_function
from __future__ import division
from __future__ import absolute_import
# from scipy.misc import imread, imresize, imsave, fromimage, toimage
from utils import imread, imresize, imsave, fromimage, toimage
from scipy.optimize import fmin_l_bfgs_b
import numpy as np
import time
import argparse
import warnings
from keras.models import Model
from keras.layers import Input
from keras.layers.convolutional import Convolution2D, AveragePooling2D, MaxPooling2D
from keras import backend as K
from keras.utils.data_utils import get_file
from keras.utils.layer_utils import convert_all_kernels_in_model
"""
Neural Style Transfer with Keras 2.0.5
Based on:
https://github.com/keras-team/keras-io/blob/master/examples/generative/neural_style_transfer.py
Contains few improvements suggested in the paper Improving the Neural Algorithm of Artistic Style
(http://arxiv.org/abs/1605.04603).
-----------------------------------------------------------------------------------------------------------------------
"""
THEANO_WEIGHTS_PATH_NO_TOP = 'https://github.com/fchollet/deep-learning-models/releases/download/v0.1/vgg16_weights_th_dim_ordering_th_kernels_notop.h5'
TF_WEIGHTS_PATH_NO_TOP = 'https://github.com/fchollet/deep-learning-models/releases/download/v0.1/vgg16_weights_tf_dim_ordering_tf_kernels_notop.h5'
TH_19_WEIGHTS_PATH_NO_TOP = 'https://github.com/fchollet/deep-learning-models/releases/download/v0.1/vgg19_weights_th_dim_ordering_th_kernels_notop.h5'
TF_19_WEIGHTS_PATH_NO_TOP = 'https://github.com/fchollet/deep-learning-models/releases/download/v0.1/vgg19_weights_tf_dim_ordering_tf_kernels_notop.h5'
parser = argparse.ArgumentParser(description='Neural style transfer with Keras.')
parser.add_argument('base_image_path', metavar='base', type=str,
help='Path to the image to transform.')
parser.add_argument('syle_image_paths', metavar='ref', nargs='+', type=str,
help='Path to the style reference image.')
parser.add_argument('result_prefix', metavar='res_prefix', type=str,
help='Prefix for the saved results.')
parser.add_argument("--style_masks", type=str, default=None, nargs='+',
help='Masks for style images')
parser.add_argument("--content_mask", type=str, default=None,
help='Masks for the content image')
parser.add_argument("--color_mask", type=str, default=None,
help='Mask for color preservation')
parser.add_argument("--image_size", dest="img_size", default=400, type=int,
help='Minimum image size')
parser.add_argument("--content_weight", dest="content_weight", default=0.025, type=float,
help="Weight of content")
parser.add_argument("--style_weight", dest="style_weight", nargs='+', default=[1], type=float,
help="Weight of style, can be multiple for multiple styles")
parser.add_argument("--style_scale", dest="style_scale", default=1.0, type=float,
help="Scale the weighing of the style")
parser.add_argument("--total_variation_weight", dest="tv_weight", default=8.5e-5, type=float,
help="Total Variation weight")
parser.add_argument("--num_iter", dest="num_iter", default=10, type=int,
help="Number of iterations")
parser.add_argument("--model", default="vgg16", type=str,
help="Choices are 'vgg16' and 'vgg19'")
parser.add_argument("--content_loss_type", default=0, type=int,
help='Can be one of 0, 1 or 2. Readme contains the required information of each mode.')
parser.add_argument("--rescale_image", dest="rescale_image", default="False", type=str,
help="Rescale image after execution to original dimentions")
parser.add_argument("--rescale_method", dest="rescale_method", default="bilinear", type=str,
help="Rescale image algorithm")
parser.add_argument("--maintain_aspect_ratio", dest="maintain_aspect_ratio", default="True", type=str,
help="Maintain aspect ratio of loaded images")
parser.add_argument("--content_layer", dest="content_layer", default="conv5_2", type=str,
help="Content layer used for content loss.")
parser.add_argument("--init_image", dest="init_image", default="content", type=str,
help="Initial image used to generate the final image. Options are 'content', 'noise', or 'gray'")
parser.add_argument("--pool_type", dest="pool", default="max", type=str,
help='Pooling type. Can be "ave" for average pooling or "max" for max pooling')
parser.add_argument('--preserve_color', dest='color', default="False", type=str,
help='Preserve original color in image')
parser.add_argument('--min_improvement', default=0.0, type=float,
help='Defines minimum improvement required to continue script')
def str_to_bool(v):
return v.lower() in ("true", "yes", "t", "1")
''' Arguments '''
args = parser.parse_args()
base_image_path = args.base_image_path
style_reference_image_paths = args.syle_image_paths
result_prefix = args.result_prefix
style_image_paths = []
for style_image_path in style_reference_image_paths:
style_image_paths.append(style_image_path)
style_masks_present = args.style_masks is not None
mask_paths = []
if style_masks_present:
for mask_path in args.style_masks:
mask_paths.append(mask_path)
if style_masks_present:
assert len(style_image_paths) == len(mask_paths), "Wrong number of style masks provided.\n" \
"Number of style images = %d, \n" \
"Number of style mask paths = %d." % \
(len(style_image_paths), len(style_masks_present))
content_mask_present = args.content_mask is not None
content_mask_path = args.content_mask
color_mask_present = args.color_mask is not None
rescale_image = str_to_bool(args.rescale_image)
maintain_aspect_ratio = str_to_bool(args.maintain_aspect_ratio)
preserve_color = str_to_bool(args.color)
# these are the weights of the different loss components
content_weight = args.content_weight
total_variation_weight = args.tv_weight
style_weights = []
if len(style_image_paths) != len(args.style_weight):
print("Mismatch in number of style images provided and number of style weights provided. \n"
"Found %d style images and %d style weights. \n"
"Equally distributing weights to all other styles." % (len(style_image_paths), len(args.style_weight)))
weight_sum = sum(args.style_weight) * args.style_scale
count = len(style_image_paths)
for i in range(len(style_image_paths)):
style_weights.append(weight_sum / count)
else:
for style_weight in args.style_weight:
style_weights.append(style_weight * args.style_scale)
# Decide pooling function
pooltype = str(args.pool).lower()
assert pooltype in ["ave", "max"], 'Pooling argument is wrong. Needs to be either "ave" or "max".'
pooltype = 1 if pooltype == "ave" else 0
read_mode = "gray" if args.init_image == "gray" else "color"
# dimensions of the generated picture.
img_width = img_height = 0
img_WIDTH = img_HEIGHT = 0
aspect_ratio = 0
assert args.content_loss_type in [0, 1, 2], "Content Loss Type must be one of 0, 1 or 2"
# util function to open, resize and format pictures into appropriate tensors
def preprocess_image(image_path, load_dims=False, read_mode="color"):
global img_width, img_height, img_WIDTH, img_HEIGHT, aspect_ratio
mode = "RGB" if read_mode == "color" else "L"
img = imread(image_path, mode=mode) # Prevents crashes due to PNG images (ARGB)
if mode == "L":
# Expand the 1 channel grayscale to 3 channel grayscale image
temp = np.zeros(img.shape + (3,), dtype=np.uint8)
temp[:, :, 0] = img
temp[:, :, 1] = img.copy()
temp[:, :, 2] = img.copy()
img = temp
if load_dims:
img_WIDTH = img.shape[0]
img_HEIGHT = img.shape[1]
aspect_ratio = float(img_HEIGHT) / img_WIDTH
img_width = args.img_size
if maintain_aspect_ratio:
img_height = int(img_width * aspect_ratio)
else:
img_height = args.img_size
img = imresize(img, (img_width, img_height)).astype('float32')
# RGB -> BGR
img = img[:, :, ::-1]
img[:, :, 0] -= 103.939
img[:, :, 1] -= 116.779
img[:, :, 2] -= 123.68
if K.image_data_format() == "channels_first":
img = img.transpose((2, 0, 1)).astype('float32')
img = np.expand_dims(img, axis=0)
return img
# util function to convert a tensor into a valid image
def deprocess_image(x):
if K.image_data_format() == "channels_first":
x = x.reshape((3, img_width, img_height))
x = x.transpose((1, 2, 0))
else:
x = x.reshape((img_width, img_height, 3))
x[:, :, 0] += 103.939
x[:, :, 1] += 116.779
x[:, :, 2] += 123.68
# BGR -> RGB
x = x[:, :, ::-1]
x = np.clip(x, 0, 255).astype('uint8')
return x
# util function to preserve image color
def original_color_transform(content, generated, mask=None):
generated = fromimage(toimage(generated, mode='RGB'), mode='YCbCr') # Convert to YCbCr color space
if mask is None:
generated[:, :, 1:] = content[:, :, 1:] # Generated CbCr = Content CbCr
else:
width, height, channels = generated.shape
for i in range(width):
for j in range(height):
if mask[i, j] == 1:
generated[i, j, 1:] = content[i, j, 1:]
generated = fromimage(toimage(generated, mode='YCbCr'), mode='RGB') # Convert to RGB color space
return generated
def load_mask(mask_path, shape, return_mask_img=False):
if K.image_data_format() == "channels_first":
_, channels, width, height = shape
else:
_, width, height, channels = shape
mask = imread(mask_path, mode="L") # Grayscale mask load
mask = imresize(mask, (width, height)).astype('float32')
# Perform binarization of mask
mask[mask <= 127] = 0
mask[mask > 128] = 255
max = np.amax(mask)
mask /= max
if return_mask_img: return mask
mask_shape = shape[1:]
mask_tensor = np.empty(mask_shape)
for i in range(channels):
if K.image_data_format() == "channels_first":
mask_tensor[i, :, :] = mask
else:
mask_tensor[:, :, i] = mask
return mask_tensor
def pooling_func(x):
if pooltype == 1:
return AveragePooling2D((2, 2), strides=(2, 2))(x)
else:
return MaxPooling2D((2, 2), strides=(2, 2))(x)
# get tensor representations of our images
base_image = K.variable(preprocess_image(base_image_path, True, read_mode=read_mode))
style_reference_images = []
for style_path in style_image_paths:
style_reference_images.append(K.variable(preprocess_image(style_path)))
# this will contain our generated image
if K.image_data_format() == "channels_first":
combination_image = K.placeholder((1, 3, img_width, img_height))
else:
combination_image = K.placeholder((1, img_width, img_height, 3))
image_tensors = [base_image]
for style_image_tensor in style_reference_images:
image_tensors.append(style_image_tensor)
image_tensors.append(combination_image)
nb_tensors = len(image_tensors)
nb_style_images = nb_tensors - 2 # Content and Output image not considered
# combine the various images into a single Keras tensor
input_tensor = K.concatenate(image_tensors, axis=0)
if K.image_data_format() == "channels_first":
shape = (nb_tensors, 3, img_width, img_height)
else:
shape = (nb_tensors, img_width, img_height, 3)
ip = Input(tensor=input_tensor, batch_shape=shape)
# build the VGG16 network with our 3 images as input
x = Convolution2D(64, (3, 3), activation='relu', name='conv1_1', padding='same')(ip)
x = Convolution2D(64, (3, 3), activation='relu', name='conv1_2', padding='same')(x)
x = pooling_func(x)
x = Convolution2D(128, (3, 3), activation='relu', name='conv2_1', padding='same')(x)
x = Convolution2D(128, (3, 3), activation='relu', name='conv2_2', padding='same')(x)
x = pooling_func(x)
x = Convolution2D(256, (3, 3), activation='relu', name='conv3_1', padding='same')(x)
x = Convolution2D(256, (3, 3), activation='relu', name='conv3_2', padding='same')(x)
x = Convolution2D(256, (3, 3), activation='relu', name='conv3_3', padding='same')(x)
if args.model == "vgg19":
x = Convolution2D(256, (3, 3), activation='relu', name='conv3_4', padding='same')(x)
x = pooling_func(x)
x = Convolution2D(512, (3, 3), activation='relu', name='conv4_1', padding='same')(x)
x = Convolution2D(512, (3, 3), activation='relu', name='conv4_2', padding='same')(x)
x = Convolution2D(512, (3, 3), activation='relu', name='conv4_3', padding='same')(x)
if args.model == "vgg19":
x = Convolution2D(512, (3, 3), activation='relu', name='conv4_4', padding='same')(x)
x = pooling_func(x)
x = Convolution2D(512, (3, 3), activation='relu', name='conv5_1', padding='same')(x)
x = Convolution2D(512, (3, 3), activation='relu', name='conv5_2', padding='same')(x)
x = Convolution2D(512, (3, 3), activation='relu', name='conv5_3', padding='same')(x)
if args.model == "vgg19":
x = Convolution2D(512, (3, 3), activation='relu', name='conv5_4', padding='same')(x)
x = pooling_func(x)
model = Model(ip, x)
if K.image_data_format() == "channels_first":
if args.model == "vgg19":
weights = get_file('vgg19_weights_th_dim_ordering_th_kernels_notop.h5', TH_19_WEIGHTS_PATH_NO_TOP, cache_subdir='models')
else:
weights = get_file('vgg16_weights_th_dim_ordering_th_kernels_notop.h5', THEANO_WEIGHTS_PATH_NO_TOP, cache_subdir='models')
else:
if args.model == "vgg19":
weights = get_file('vgg19_weights_tf_dim_ordering_tf_kernels_notop.h5', TF_19_WEIGHTS_PATH_NO_TOP, cache_subdir='models')
else:
weights = get_file('vgg16_weights_tf_dim_ordering_tf_kernels_notop.h5', TF_WEIGHTS_PATH_NO_TOP, cache_subdir='models')
model.load_weights(weights)
if K.backend() == 'tensorflow' and K.image_data_format() == "channels_first":
warnings.warn('You are using the TensorFlow backend, yet you '
'are using the Theano '
'image dimension ordering convention '
'(`image_dim_ordering="th"`). '
'For best performance, set '
'`image_dim_ordering="tf"` in '
'your Keras config '
'at ~/.keras/keras.json.')
convert_all_kernels_in_model(model)
print('Model loaded.')
# get the symbolic outputs of each "key" layer (we gave them unique names).
outputs_dict = dict([(layer.name, layer.output) for layer in model.layers])
shape_dict = dict([(layer.name, layer.output_shape) for layer in model.layers])
# compute the neural style loss
# first we need to define 4 util functions
# Improvement 1
# the gram matrix of an image tensor (feature-wise outer product) using shifted activations
def gram_matrix(x):
assert K.ndim(x) == 3
if K.image_data_format() == "channels_first":
features = K.batch_flatten(x)
else:
features = K.batch_flatten(K.permute_dimensions(x, (2, 0, 1)))
gram = K.dot(features - 1, K.transpose(features - 1))
return gram
# the "style loss" is designed to maintain
# the style of the reference image in the generated image.
# It is based on the gram matrices (which capture style) of
# feature maps from the style reference image
# and from the generated image
def style_loss(style, combination, mask_path=None, nb_channels=None):
assert K.ndim(style) == 3
assert K.ndim(combination) == 3
if content_mask_path is not None:
content_mask = K.variable(load_mask(content_mask_path, nb_channels))
combination = combination * K.stop_gradient(content_mask)
del content_mask
if mask_path is not None:
style_mask = K.variable(load_mask(mask_path, nb_channels))
style = style * K.stop_gradient(style_mask)
if content_mask_path is None:
combination = combination * K.stop_gradient(style_mask)
del style_mask
S = gram_matrix(style)
C = gram_matrix(combination)
channels = 3
size = img_width * img_height
return K.sum(K.square(S - C)) / (4. * (channels ** 2) * (size ** 2))
# an auxiliary loss function
# designed to maintain the "content" of the
# base image in the generated image
def content_loss(base, combination):
channel_dim = 0 if K.image_data_format() == "channels_first" else -1
try:
channels = K.int_shape(base)[channel_dim]
except TypeError:
channels = K.shape(base)[channel_dim]
size = img_width * img_height
if args.content_loss_type == 1:
multiplier = 1. / (2. * (channels ** 0.5) * (size ** 0.5))
elif args.content_loss_type == 2:
multiplier = 1. / (channels * size)
else:
multiplier = 1.
return multiplier * K.sum(K.square(combination - base))
# the 3rd loss function, total variation loss,
# designed to keep the generated image locally coherent
def total_variation_loss(x):
assert K.ndim(x) == 4
if K.image_data_format() == "channels_first":
a = K.square(x[:, :, :img_width - 1, :img_height - 1] - x[:, :, 1:, :img_height - 1])
b = K.square(x[:, :, :img_width - 1, :img_height - 1] - x[:, :, :img_width - 1, 1:])
else:
a = K.square(x[:, :img_width - 1, :img_height - 1, :] - x[:, 1:, :img_height - 1, :])
b = K.square(x[:, :img_width - 1, :img_height - 1, :] - x[:, :img_width - 1, 1:, :])
return K.sum(K.pow(a + b, 1.25))
if args.model == "vgg19":
feature_layers = ['conv1_1', 'conv1_2', 'conv2_1', 'conv2_2', 'conv3_1', 'conv3_2', 'conv3_3', 'conv3_4',
'conv4_1', 'conv4_2', 'conv4_3', 'conv4_4', 'conv5_1', 'conv5_2', 'conv5_3', 'conv5_4']
else:
feature_layers = ['conv1_1', 'conv1_2', 'conv2_1', 'conv2_2', 'conv3_1', 'conv3_2', 'conv3_3',
'conv4_1', 'conv4_2', 'conv4_3', 'conv5_1', 'conv5_2', 'conv5_3']
# combine these loss functions into a single scalar
loss = K.variable(0.)
layer_features = outputs_dict[args.content_layer]
base_image_features = layer_features[0, :, :, :]
combination_features = layer_features[nb_tensors - 1, :, :, :]
loss = loss + content_weight * content_loss(base_image_features,
combination_features)
# Improvement 2
# Use all layers for style feature extraction and reconstruction
nb_layers = len(feature_layers) - 1
style_masks = []
if style_masks_present:
style_masks = mask_paths # If mask present, pass dictionary of masks to style loss
else:
style_masks = [None for _ in range(nb_style_images)] # If masks not present, pass None to the style loss
channel_index = 1 if K.image_data_format() == "channels_first" else -1
# Improvement 3 : Chained Inference without blurring
for i in range(len(feature_layers) - 1):
layer_features = outputs_dict[feature_layers[i]]
shape = shape_dict[feature_layers[i]]
combination_features = layer_features[nb_tensors - 1, :, :, :]
style_reference_features = layer_features[1:nb_tensors - 1, :, :, :]
sl1 = []
for j in range(nb_style_images):
sl1.append(style_loss(style_reference_features[j], combination_features, style_masks[j], shape))
layer_features = outputs_dict[feature_layers[i + 1]]
shape = shape_dict[feature_layers[i + 1]]
combination_features = layer_features[nb_tensors - 1, :, :, :]
style_reference_features = layer_features[1:nb_tensors - 1, :, :, :]
sl2 = []
for j in range(nb_style_images):
sl2.append(style_loss(style_reference_features[j], combination_features, style_masks[j], shape))
for j in range(nb_style_images):
sl = sl1[j] - sl2[j]
# Improvement 4
# Geometric weighted scaling of style loss
loss = loss + (style_weights[j] / (2 ** (nb_layers - (i + 1)))) * sl
loss = loss + total_variation_weight * total_variation_loss(combination_image)
# get the gradients of the generated image wrt the loss
grads = K.gradients(loss, combination_image)
outputs = [loss]
if type(grads) in {list, tuple}:
outputs += grads
else:
outputs.append(grads)
f_outputs = K.function([combination_image], outputs)
def eval_loss_and_grads(x):
if K.image_data_format() == "channels_first":
x = x.reshape((1, 3, img_width, img_height))
else:
x = x.reshape((1, img_width, img_height, 3))
outs = f_outputs([x])
loss_value = outs[0]
if len(outs[1:]) == 1:
grad_values = outs[1].flatten().astype('float64')
else:
grad_values = np.array(outs[1:]).flatten().astype('float64')
return loss_value, grad_values
# this Evaluator class makes it possible
# to compute loss and gradients in one pass
# while retrieving them via two separate functions,
# "loss" and "grads". This is done because scipy.optimize
# requires separate functions for loss and gradients,
# but computing them separately would be inefficient.
class Evaluator(object):
def __init__(self):
self.loss_value = None
self.grads_values = None
def loss(self, x):
assert self.loss_value is None
loss_value, grad_values = eval_loss_and_grads(x)
self.loss_value = loss_value
self.grad_values = grad_values
return self.loss_value
def grads(self, x):
assert self.loss_value is not None
grad_values = np.copy(self.grad_values)
self.loss_value = None
self.grad_values = None
return grad_values
evaluator = Evaluator()
# run scipy-based optimization (L-BFGS) over the pixels of the generated image
# so as to minimize the neural style loss
if "content" in args.init_image or "gray" in args.init_image:
x = preprocess_image(base_image_path, True, read_mode=read_mode)
elif "noise" in args.init_image:
x = np.random.uniform(0, 255, (1, img_width, img_height, 3)) - 128.
if K.image_data_format() == "channels_first":
x = x.transpose((0, 3, 1, 2))
else:
print("Using initial image : ", args.init_image)
x = preprocess_image(args.init_image, read_mode=read_mode)
# We require original image if we are to preserve color in YCbCr mode
if preserve_color:
content = imread(base_image_path, mode="YCbCr")
content = imresize(content, (img_width, img_height))
if color_mask_present:
if K.image_data_format() == "channels_first":
color_mask_shape = (None, None, img_width, img_height)
else:
color_mask_shape = (None, img_width, img_height, None)
color_mask = load_mask(args.color_mask, color_mask_shape, return_mask_img=True)
else:
color_mask = None
else:
color_mask = None
num_iter = args.num_iter
prev_min_val = -1
improvement_threshold = float(args.min_improvement)
for i in range(num_iter):
print("Starting iteration %d of %d" % ((i + 1), num_iter))
start_time = time.time()
x, min_val, info = fmin_l_bfgs_b(evaluator.loss, x.flatten(), fprime=evaluator.grads, maxfun=20)
if prev_min_val == -1:
prev_min_val = min_val
improvement = (prev_min_val - min_val) / prev_min_val * 100
print("Current loss value:", min_val, " Improvement : %0.3f" % improvement, "%")
prev_min_val = min_val
# save current generated image
img = deprocess_image(x.copy())
if preserve_color and content is not None:
img = original_color_transform(content, img, mask=color_mask)
if not rescale_image:
img_ht = int(img_width * aspect_ratio)
print("Rescaling Image to (%d, %d)" % (img_width, img_ht))
img = imresize(img, (img_width, img_ht), interp=args.rescale_method)
if rescale_image:
print("Rescaling Image to (%d, %d)" % (img_WIDTH, img_HEIGHT))
img = imresize(img, (img_WIDTH, img_HEIGHT), interp=args.rescale_method)
fname = result_prefix + "_at_iteration_%d.png" % (i + 1)
imsave(fname, img)
end_time = time.time()
print("Image saved as", fname)
print("Iteration %d completed in %ds" % (i + 1, end_time - start_time))
if improvement_threshold is not 0.0:
if improvement < improvement_threshold and improvement is not 0.0:
print("Improvement (%f) is less than improvement threshold (%f). Early stopping script." %
(improvement, improvement_threshold))
exit()