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SemanticExtractor.py
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SemanticExtractor.py
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"""
@author: Tae-Hyun Oh (http://taehyunoh.com, [email protected])
@date: Jul 29, 2018
@description: This is a part of the semantic feature extraction implementation used in
[Semantic Soft Segmentation (Aksoy et al., 2018)] (project page: http://people.inf.ethz.ch/aksoyy/sss/).
This code is modified from the implementation by DrSleep (https://github.com/DrSleep/tensorflow-deeplab-resnet)
This code is for protyping research ideas; thus, please use this code only for non-commercial purpose only.
"""
from __future__ import print_function
import argparse
from datetime import datetime
import os
import sys
import time
import scipy.io as sio
from glob import glob
import tensorflow as tf
import numpy as np
import pdb
import cv2
from parse_opt import get_arguments
from deeplab_resnet import HyperColumn_Deeplabv2, read_data_list
from sklearn.decomposition import PCA
from save_features import *
from filter_image import *
IMG_MEAN = np.array((104.00698793,116.66876762,122.67891434), dtype=np.float32)
#######################################################
'''
Helper functions
'''
def load_dir_structs(dataset_path):
# Get list of subdirs
# types = ('*.jpg', '*.png') # jpg is not supported yet by read_img()
types = ('*.jpg',)
curflist= []
for files in types:
curflist.extend(glob(os.path.join(dataset_path, files)))
return curflist
def read_img(t_imgfname, input_size, img_mean): # optional pre-processing arguments
"""Read one image and its corresponding mask with optional pre-processing.
Args:
input_queue: tf queue with paths to the image and its mask.
input_size: a tuple with (height, width) values.
If not given, return images of original size.
random_scale: whether to randomly scale the images prior
to random crop.
random_mirror: whether to randomly mirror the images prior
to random crop.
ignore_label: index of label to ignore during the training.
img_mean: vector of mean colour values.
Returns:
Two tensors: the decoded image and its mask.
"""
img_contents = tf.read_file(t_imgfname)
#img = tf.image.decode_image(img_contents, channels=3)
img = tf.image.decode_png(img_contents, channels=3)
img_r, img_g, img_b = tf.split(axis=2, num_or_size_splits=3, value=img)
img = tf.cast(tf.concat(axis=2, values=[img_b, img_g, img_r]), dtype=tf.float32)
# Extract mean.
img -= img_mean
if input_size is not None:
h, w = input_size
# Randomly scale the images and labels.
newshape = tf.squeeze(tf.stack([h, w]), squeeze_dims=[1])
img2 = tf.image.resize_images(img, newshape)
else:
img2 = tf.image.resize_images(img, tf.shape(img)[0:2,]*2)
return img2, img
def SaveFeatures(h,w,data,path=''):
data = data[:,:3]
col_min = np.min(data, axis=0)
col_max = np.max(data, axis=0)
image = np.zeros((h*w,3))
image[:,0] = (data[:,0] - col_min[0]) / (col_max[0]-col_min[0])
image[:,1] = (data[:,1] - col_min[1]) / (col_max[1]-col_min[1])
image[:,2] = (data[:,2] - col_min[2]) / (col_max[0]-col_min[2])
image = image.reshape(h,w,3)*255
#cv2.imshow("feature_image", image)
#cv2.waitKey(0)
cv2.imwrite(path,image)
#######################################################
'''
Original Main function
'''
'''
if __name__ == "__main__":
args = get_arguments()
# Set up tf session and initialize variables.
config = tf.ConfigProto()
config.gpu_options.allow_growth = True
with tf.Session(config=config) as sess:
model = HyperColumn_Deeplabv2(sess, args)
# Load variables if the checkpoint is provided.
model.load(args.snapshot_dir)
local_imgflist = load_dir_structs(args.data_dir)
save_folder = os.path.join(args.data_dir, args.feat_dir)
if not os.path.exists(save_folder):
os.mkdir(save_folder)
for i in range(len(local_imgflist)):
if os.path.splitext(local_imgflist[i])[1] == '':
continue
print('{} Processing {}'.format(i, local_imgflist[i]))
padsize = 50
# the following read_img() calls could lead to a memory leakage-like issue or at least very slow. (need to be fixed later)
_, ori_img = read_img(local_imgflist[i], input_size = None, img_mean = IMG_MEAN)
pad_img = tf.pad(ori_img, [[padsize,padsize], [padsize,padsize], [0,0]], mode='REFLECT')
cur_embed = model.test(pad_img.eval())
cur_embed = np.squeeze(cur_embed)
curfname = os.path.split(os.path.splitext(local_imgflist[i])[0])[1]
cur_svpath = os.path.join(save_folder, curfname + '.mat')
print(cur_svpath)
img_h = cur_embed.shape[0]-2*padsize
img_w = cur_embed.shape[1]-2*padsize
res = cur_embed[padsize:(cur_embed.shape[0]-padsize),padsize:(cur_embed.shape[1]-padsize),:]
#image guild filter
img_path = local_imgflist[i]
res = np.clip(res,-5,5)
gray_img =cv2.imread(img_path)
gray_img = cv2.cvtColor(gray_img,cv2.COLOR_RGB2GRAY)
res = FilterImage(res, gray_img)
res = res.reshape(-1,128)
pca = PCA(n_components=3)
reduced = pca.fit_transform(res)
normal_reduced = (reduced-reduced.min(axis=0))/(reduced.max(axis=0)-reduced.min(axis=0))
save_data_path = os.path.join(save_folder, curfname + '_feat.data')
save_feat_vis_path = os.path.join(save_folder, curfname + '_feat.png')
print("Save feature file...")
normal_reduced.astype('double').tofile(save_data_path)
SaveFeatures(img_h, img_w,normal_reduced,save_feat_vis_path)
print('Finish to Processing ' + img_path + "\n")
'''
if __name__ == "__main__":
args = get_arguments()
data_dir = "./image2/"
imgNames = ["ball.jpg"]
# Set up tf session and initialize variables.
config = tf.ConfigProto()
config.gpu_options.allow_growth = True
with tf.Session(config=config) as sess:
model = HyperColumn_Deeplabv2(sess, args)
# Load variables if the checkpoint is provided.
model.load(args.snapshot_dir)
save_folder = os.path.join(args.data_dir, args.feat_dir)
if not os.path.exists(save_folder):
os.mkdir(save_folder)
for i in range(len(imgNames)):
img_path = data_dir + imgNames[i]
if os.path.splitext(img_path)[1] == '':
continue
print('Processing ' + img_path)
padsize = 50
# the following read_img() calls could lead to a memory leakage-like issue or at least very slow. (need to be fixed later)
_, ori_img = read_img(img_path, input_size = None, img_mean = IMG_MEAN)
pad_img = tf.pad(ori_img, [[padsize,padsize], [padsize,padsize], [0,0]], mode='REFLECT')
cur_embed = model.test(pad_img.eval())
cur_embed = np.squeeze(cur_embed)
curfname = os.path.split(os.path.splitext(img_path)[0])[1]
cur_svpath = os.path.join(save_folder, curfname + '.mat')
img_h = cur_embed.shape[0]-2*padsize
img_w = cur_embed.shape[1]-2*padsize
res = cur_embed[padsize:(cur_embed.shape[0]-padsize),padsize:(cur_embed.shape[1]-padsize),:]
#image guild filter
res = np.clip(res,-5,5)
gray_img = cv2.imread(img_path)
gray_img = cv2.cvtColor(gray_img,cv2.COLOR_RGB2GRAY)
res = FilterImage(res, gray_img)
save_feat_vis_path1 = os.path.join(save_folder, curfname + '_gray.png')
cv2.imwrite(save_feat_vis_path1,gray_img)
res = res.reshape(-1,128)
pca = PCA(n_components=3)
reduced = pca.fit_transform(res)
normal_reduced = (reduced-reduced.min(axis=0))/(reduced.max(axis=0)-reduced.min(axis=0))
save_data_path = os.path.join(save_folder, curfname + '_feat.data')
save_feat_vis_path = os.path.join(save_folder, curfname + '_feat.png')
print("Save feature file...")
normal_reduced.astype('double').tofile(save_data_path)
SaveFeatures(img_h, img_w,normal_reduced,save_feat_vis_path)
print('Finish to Processing ' + img_path + "\n")