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gen.py
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gen.py
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# -*- coding: utf-8 -*-
# Author: Ankush Gupta
# Date: 2015
"""
Entry-point for generating synthetic text images, as described in:
@InProceedings{Gupta16,
author = "Gupta, A. and Vedaldi, A. and Zisserman, A.",
title = "Synthetic Data for Text Localisation in Natural Images",
booktitle = "IEEE Conference on Computer Vision and Pattern Recognition",
year = "2016",
}
"""
import numpy as np
import h5py
import os, sys, traceback
import os.path as osp
from synthgen import *
from common import *
import wget, tarfile
import cv2 as cv
import time
## Define some configuration variables:
NUM_IMG = -1 # no. of images to use for generation (-1 to use all available):
INSTANCE_PER_IMAGE = 1 # no. of times to use the same image
SECS_PER_IMG = 5 #max time per image in seconds
# path to the data-file, containing image, depth and segmentation:
DATA_PATH = 'data'
DB_FNAME = osp.join(DATA_PATH,'dset.h5')
# url of the data (google-drive public file):
DATA_URL = 'http://www.robots.ox.ac.uk/~ankush/data.tar.gz'
OUT_FILE = 'results/SynthText_cartoon_viz.h5'
def get_data():
"""
Download the image,depth and segmentation data:
Returns, the h5 database.
"""
if not osp.exists(DB_FNAME):
try:
colorprint(Color.BLUE,'\tdownloading data (56 M) from: '+DATA_URL,bold=True)
print
sys.stdout.flush()
out_fname = 'data.tar.gz'
wget.download(DATA_URL,out=out_fname)
tar = tarfile.open(out_fname)
tar.extractall()
tar.close()
os.remove(out_fname)
colorprint(Color.BLUE,'\n\tdata saved at:'+DB_FNAME,bold=True)
sys.stdout.flush()
except:
print colorize(Color.RED,'Data not found and have problems downloading.',bold=True)
sys.stdout.flush()
sys.exit(-1)
# open the h5 file and return:
return h5py.File(DB_FNAME,'r')
def add_res_to_db(imgname,res,db):
"""
Add the synthetically generated text image instance
and other metadata to the dataset.
"""
ninstance = len(res)
for i in xrange(ninstance):
print colorize(Color.GREEN,'added into the db %s '%res[i]['txt'])
dname = "%s_%d"%(imgname, i)
db['data'].create_dataset(dname,data=res[i]['img'])
db['data'][dname].attrs['charBB'] = res[i]['charBB']
db['data'][dname].attrs['wordBB'] = res[i]['wordBB']
print 'type of res[i][\'txt\'] ',type(res[i]['txt'])
#db['data'][dname].attrs['txt'] = res[i]['txt']
db['data'][dname].attrs.create('txt', res[i]['txt'], dtype=h5py.special_dtype(vlen=unicode))
print 'type of db ',type(db['data'][dname].attrs['txt'])
print colorize(Color.GREEN,'successfully added')
print res[i]['txt']
print res[i]['img'].shape
print 'charBB',res[i]['charBB'].shape
print 'charBB',res[i]['charBB']
print 'wordBB',res[i]['wordBB'].shape
print 'wordBB',res[i]['wordBB']
'''
img = Image.fromarray(res[i]['img'])
hsv_img=np.array(rgb2hsv(img))
print 'hsv_img_shape',hsv_img.shape
print 'hsv_img',hsv_img
H=hsv_img[:,:,2]
print 'H_channel',H.shape,H
#img = Image.fromarray(db['data'][dname][:])
'''
def rgb2hsv(image):
return image.convert('HSV')
def rgb2gray(image):
rgb=np.array(image)
r, g, b = rgb[:,:,0], rgb[:,:,1], rgb[:,:,2]
gray = 0.2989 * r + 0.5870 * g + 0.1140 * b
return gray
def main(viz=False):
# open databases:
print colorize(Color.BLUE,'getting data..',bold=True)
db = get_data()
print colorize(Color.BLUE,'\t-> done',bold=True)
# open the output h5 file:
out_db = h5py.File(OUT_FILE,'w')
out_db.create_group('/data')
print colorize(Color.GREEN,'Storing the output in: '+OUT_FILE, bold=True)
# get the names of the image files in the dataset:
imnames = sorted(db['image'].keys())
N = len(imnames)
global NUM_IMG
if NUM_IMG < 0:
NUM_IMG = N
start_idx,end_idx = 0,min(NUM_IMG, N)
RV3 = RendererV3(DATA_PATH,max_time=SECS_PER_IMG)
for i in xrange(start_idx,end_idx):
t1=time.time()
imname = imnames[i]
try:
# get the image:
img = Image.fromarray(db['image'][imname][:])
# get the pre-computed depth:
# there are 2 estimates of depth (represented as 2 "channels")
# here we are using the second one (in some cases it might be
# useful to use the other one):
img_resize=img.resize(db['depth'][imname].shape)
depth = db['depth'][imname][:].T
print 'depth shape,img shape',depth.shape,np.array(img).shape
print 'depth info',depth
print 'depth max min',np.max(depth),np.min(depth)
#depth = depth[:,:,1]
#modify the depth with HSV H_channel
#img_resize=img.resize(depth.shape)
hsv_img=np.array(rgb2hsv(img_resize))
print 'hsv_img_shape',hsv_img.shape
#print 'hsv_img',hsv_img
H=hsv_img[:,:,2]
H=H.T
H=H.astype('float32')
print 'H_channel',H.shape,H
print 'H_max min',np.max(H),np.min(H)
print 'scale',np.max(depth)/np.max(H)
#depth= (np.max(depth)/np.max(H))*H
#depth= H
#print np.isnan(H).any()
#print np.isinf(H).any()
#print np.isnan(depth).any()
#print np.isinf(depth).any()
print 'depth shape',depth.shape
#print 'depth info',depth
print 'depth max min',np.max(depth),np.min(depth)
gray=np.array(rgb2gray(img_resize))
#print 'gray',gray.shape,gray
depth= (np.max(depth)/np.max(gray))*gray.astype('float32')
#add more blur
#mean blur
kernel = np.ones((5,5),np.float32)/25
gray = cv2.filter2D(gray,-1,kernel)
#print 'gray',gray.shape,gray
# get segmentation:
seg = db['seg'][imname][:].astype('float32')
area = db['seg'][imname].attrs['area']
label = db['seg'][imname].attrs['label']
print 'seg info',seg.shape,area.shape,label.shape
# re-size uniformly:
sz = depth.shape[:2][::-1]
img = np.array(img.resize(sz,Image.ANTIALIAS))
seg = np.array(Image.fromarray(seg).resize(sz,Image.NEAREST))
print colorize(Color.RED,'%d of %d'%(i,end_idx-1), bold=True)
res = RV3.render_text(img,depth,seg,area,label,
ninstance=INSTANCE_PER_IMAGE,viz=viz)
t2=time.time()
for ct in range(5):
if len(res) > 0:
# non-empty : successful in placing text:
add_res_to_db(imname,res,out_db)
break
else:
res = RV3.render_text(img,depth,seg,area,label,
ninstance=INSTANCE_PER_IMAGE,viz=viz)
# visualize the output:
print 'time consume in each pic',t2-t1
if viz:
if 'q' in raw_input(colorize(Color.RED,'continue? (enter to continue, q to exit): ',True)):
break
except:
traceback.print_exc()
print colorize(Color.GREEN,'>>>> CONTINUING....', bold=True)
continue
db.close()
out_db.close()
if __name__=='__main__':
import argparse
parser = argparse.ArgumentParser(description='Genereate Synthetic Scene-Text Images')
parser.add_argument('--viz',action='store_true',dest='viz',default=False,help='flag for turning on visualizations')
args = parser.parse_args()
main(args.viz)