import ctypes
import re
import numpy as np
from numpy import ctypeslib
import os
import cv2
import multiprocessing as mp
from multiprocessing.sharedctypes import RawArray
from scipy.spatial.distance import euclidean
from tqdm import tqdm
IMG_DIR = "images"
RATIO = 10
def resize(im, tile_row, tile_col):
shape_row = im.shape[0]
shape_col = im.shape[1]
shrink_ratio = min(shape_row/tile_row, shape_col/tile_col)
resized = cv2.resize(im, (int(shape_col/shrink_ratio)+1, int(shape_row/shrink_ratio)+1), interpolation=cv2.INTER_CUBIC)
result = resized[:tile_row, :tile_col,:]
return result
def img_distance(im1, im2):
if im1.shape != im2.shape:
msg = "shapes are different {} {}".format(im1.shape, im2.shape)
raise Exception(msg)
array1 = im1.flatten()
array2 = im2.flatten()
dist = euclidean(array1, array2)
return dist
def load_all_images(tile_row, tile_col):
img_dir = IMG_DIR
filenames = os.listdir(img_dir)
result = []
print(len(filenames))
for filename in tqdm(filenames):
if not re.search(".jpg", filename, re.I):
continue
try:
filepath = os.path.join(img_dir, filename)
im = cv2.imread(filepath)
row = im.shape[0]
col = im.shape[1]
im = resize(im, tile_row, tile_col)
result.append(np.array(im))
except Exception as e:
msg = "error with {} - {}".format(filepath, str(e))
print(msg)
return np.array(result, dtype=np.uint8)
def find_closest_image(q, shared_tile_images, tile_images_shape, shared_result, img_shape, tile_row, tile_col):
tile_images_array = np.frombuffer(shared_tile_images, dtype=np.uint8)
tile_images = tile_images_array.reshape(tile_images_shape)
while True:
[row, col, im_roi] = q.get()
print(row)
min_dist = float("inf")
min_img = None
for im in tile_images:
dist = img_distance(im_roi, im)
if dist < min_dist:
min_dist = dist
min_img = im
im_res = np.frombuffer(shared_result, dtype=np.uint8).reshape(img_shape)
im_res[row:row+tile_row,col:col+tile_col,:] = min_img
q.task_done()
def get_tile_row_col(shape):
if shape[0] >= shape[1]:
return [120, 90]
else:
return [90, 120]
def generate_mosaic(infile, outfile):
img = cv2.imread(infile)
tile_row, tile_col = get_tile_row_col(img.shape)
img_shape = list(img.shape)
img_shape[0] = int(img_shape[0]/tile_row) * tile_row * RATIO
img_shape[1] = int(img_shape[1]/tile_col) * tile_col * RATIO
img = cv2.resize(img, (img_shape[1], img_shape[0]), interpolation=cv2.INTER_CUBIC)
print(img_shape)
im_res = np.zeros(img_shape, np.uint8)
tile_images = load_all_images(tile_row, tile_col)
shared_tile_images = mp.sharedctypes.RawArray(ctypes.c_ubyte, len(tile_images.flatten()))
tile_images_shape = tile_images.shape
np.copyto(np.frombuffer(shared_tile_images, dtype=np.uint8).reshape(tile_images_shape), tile_images)
shared_result = mp.sharedctypes.RawArray(ctypes.c_ubyte, len(im_res.flatten()))
q = mp.JoinableQueue()
for i in range(5):
p = mp.Process(target=find_closest_image,
args=(q, shared_tile_images, tile_images_shape, shared_result, img_shape, tile_row, tile_col),
daemon=True)
p.start()
print("started process")
for row in range(0, img_shape[0], tile_row):
for col in range(0, img_shape[1], tile_col):
roi = img[row:row+tile_row,col:col+tile_col,:]
q.put([row, col, roi])
q.join()
cv2.imwrite(outfile, np.frombuffer(shared_result, dtype=np.uint8).reshape(img_shape))
if __name__ == "__main__":
generate_mosaic("test.jpg", "out.jpg")
