blaz-kranjc/visually_encode.py

## visually_encode.py
#!/usr/bin/env python2
# Implementation of visual encryption generator from
# http://www.datagenetics.com/blog/november32013/index.html
#
# The input files are three png images and should be placed in the same directory.
# The names are hardcoded:
# in1.png, in2.png : input images that are used on the encoded images
# hidden.png : input image that is shown when encoded images are overlayed

import numpy as np
import matplotlib.image as mpimg
import random

# When a pixel is considered black
GRAY_CUTOFF = 0.5
# Enlargement factor for output encoded images
ENLARGE_FACTOR = 5

RGB_WHITE = np.array([1, 1, 1, 0])
RGB_BLACK = np.array([0, 0, 0, 1])

def loadImage(filename):

    return mpimg.imread(filename)

def saveImage(imageArray, filename):

    mpimg.imsave(filename, imageArray)

def encode(in1, in2, hidden):

    # Sizes of all inputs should match, we don't care about the alpha
    if not (in1.shape[0] == in2.shape[0] == hidden.shape[0] and
            in1.shape[1] == in2.shape[1] == hidden.shape[1]):
        raise RuntimeError("Shapes of the images do not match")
    (xsize, ysize) = (in1.shape[0], in1.shape[1])

    outshape = (2*xsize*ENLARGE_FACTOR, 2*ysize*ENLARGE_FACTOR, len(RGB_WHITE))
    out1 = np.empty(outshape)
    out2 = np.empty(outshape)

    def getBW(i, j, array):
        norm = np.linalg.norm(array[i,j][1:3])
        return norm < GRAY_CUTOFF

    def setElements(i, j, enc):
        def setElemArray(x, y, enc, arr):
            for i in xrange(2):
                for j in xrange(2):
                    for e_i1 in xrange(ENLARGE_FACTOR):
                        for e_i2 in xrange(ENLARGE_FACTOR):
                            arr[x*2*ENLARGE_FACTOR+i*ENLARGE_FACTOR+e_i1,y*2*ENLARGE_FACTOR+j*ENLARGE_FACTOR+e_i2] = RGB_BLACK if enc[i,j] else RGB_WHITE

        setElemArray(i, j, enc[0], out1)
        setElemArray(i, j, enc[1], out2)

    def generateEncoding(h, i1, i2):
        blockSize = (2, 2)
        def generateRandomPixels(N):
            if N > 4:
                raise Exception("Programming error: generateRandomPixels should be called with N < 4!")
            availablePositions = range(4)
            out = []
            for i in range(N):
                rnd = random.choice(availablePositions)
                availablePositions.remove(rnd)
                out.append(rnd)
            return out

        def BBB():
            [rnd1, rnd2] = generateRandomPixels(2)
            (e1, e2) = (np.ones(4), np.ones(4))
            e1[rnd1] = e2[rnd2] = 0
            return (np.reshape(e1, blockSize), np.reshape(e2, blockSize))

        def BBW():
            [rnd1, rnd2, rnd3] = generateRandomPixels(3)
            (e1, e2) = (np.ones(4), np.ones(4))
            e1[rnd1] = e2[rnd2] = e2[rnd3] = 0
            return (np.reshape(e1, blockSize), np.reshape(e2, blockSize))

        def BWB():
            (e1, e2) = BBW()
            return (e2, e1)

        def BWW():
            [rnd1, rnd2] = generateRandomPixels(2)
            e1 = np.ones(4)
            e1[rnd1] = e1[rnd2] = 0
            e2 = np.ones(4) - e1
            return (np.reshape(e1, blockSize), np.reshape(e2, blockSize))

        def WBB():
            [rnd] = generateRandomPixels(1)
            (e1, e2) = (np.ones(4), np.ones(4))
            e1[rnd] = e2[rnd] = 0
            return (np.reshape(e1, blockSize), np.reshape(e2, blockSize))

        def WBW():
            [rnd1, rnd2] = generateRandomPixels(2)
            (e1, e2) = (np.ones(4), np.ones(4))
            e1[rnd1] = e2[rnd1] = e2[rnd2] = 0
            return (np.reshape(e1, blockSize), np.reshape(e2, blockSize))

        def WWB():
            (e1, e2) = WBW()
            return (e2, e1)

        def WWW():
            [rnd1, rnd2, rnd3] = generateRandomPixels(3)
            (e1, e2) = (np.ones(4), np.ones(4))
            e1[rnd1] = e2[rnd1] = e1[rnd2] = e2[rnd3] = 0
            return (np.reshape(e1, blockSize), np.reshape(e2, blockSize))

        if h:
            if i1:
                if i2:
                    return BBB()
                else:
                    return BBW()
            else:
                if i2:
                    return BWB()
                else:
                    return BWW()
        else:
            if i1:
                if i2:
                    return WBB()
                else:
                    return WBW()
            else:
                if i2:
                    return WWB()
                else:
                    return WWW()


    for i in xrange(xsize):
        for j in xrange(ysize):
            enc = generateEncoding(getBW(i,j,hidden), getBW(i,j,in1), getBW(i,j,in2))
            setElements(i, j, enc)

    return (out1, out2)

if __name__ == "__main__":
    hidden = loadImage("hidden.png")
    in1 = loadImage("in1.png")
    in2 = loadImage("in2.png")

    (out1, out2) = encode(in1, in2, hidden)

    saveImage(out1, "out1.png")
    saveImage(out2, "out2.png")
	#!/usr/bin/env python2
	# Implementation of visual encryption generator from
	# http://www.datagenetics.com/blog/november32013/index.html
	#
	# The input files are three png images and should be placed in the same directory.
	# The names are hardcoded:
	# in1.png, in2.png : input images that are used on the encoded images
	# hidden.png : input image that is shown when encoded images are overlayed

	import numpy as np
	import matplotlib.image as mpimg
	import random

	# When a pixel is considered black
	GRAY_CUTOFF = 0.5
	# Enlargement factor for output encoded images
	ENLARGE_FACTOR = 5

	RGB_WHITE = np.array([1, 1, 1, 0])
	RGB_BLACK = np.array([0, 0, 0, 1])

	def loadImage(filename):

	return mpimg.imread(filename)

	def saveImage(imageArray, filename):

	mpimg.imsave(filename, imageArray)

	def encode(in1, in2, hidden):

	# Sizes of all inputs should match, we don't care about the alpha
	if not (in1.shape[0] == in2.shape[0] == hidden.shape[0] and
	in1.shape[1] == in2.shape[1] == hidden.shape[1]):
	raise RuntimeError("Shapes of the images do not match")
	(xsize, ysize) = (in1.shape[0], in1.shape[1])

	outshape = (2xsizeENLARGE_FACTOR, 2ysizeENLARGE_FACTOR, len(RGB_WHITE))
	out1 = np.empty(outshape)
	out2 = np.empty(outshape)

	def getBW(i, j, array):
	norm = np.linalg.norm(array[i,j][1:3])
	return norm < GRAY_CUTOFF

	def setElements(i, j, enc):
	def setElemArray(x, y, enc, arr):
	for i in xrange(2):
	for j in xrange(2):
	for e_i1 in xrange(ENLARGE_FACTOR):
	for e_i2 in xrange(ENLARGE_FACTOR):
	arr[x2ENLARGE_FACTOR+iENLARGE_FACTOR+e_i1,y2ENLARGE_FACTOR+jENLARGE_FACTOR+e_i2] = RGB_BLACK if enc[i,j] else RGB_WHITE

	setElemArray(i, j, enc[0], out1)
	setElemArray(i, j, enc[1], out2)

	def generateEncoding(h, i1, i2):
	blockSize = (2, 2)
	def generateRandomPixels(N):
	if N > 4:
	raise Exception("Programming error: generateRandomPixels should be called with N < 4!")
	availablePositions = range(4)
	out = []
	for i in range(N):
	rnd = random.choice(availablePositions)
	availablePositions.remove(rnd)
	out.append(rnd)
	return out

	def BBB():
	[rnd1, rnd2] = generateRandomPixels(2)
	(e1, e2) = (np.ones(4), np.ones(4))
	e1[rnd1] = e2[rnd2] = 0
	return (np.reshape(e1, blockSize), np.reshape(e2, blockSize))

	def BBW():
	[rnd1, rnd2, rnd3] = generateRandomPixels(3)
	(e1, e2) = (np.ones(4), np.ones(4))
	e1[rnd1] = e2[rnd2] = e2[rnd3] = 0
	return (np.reshape(e1, blockSize), np.reshape(e2, blockSize))

	def BWB():
	(e1, e2) = BBW()
	return (e2, e1)

	def BWW():
	[rnd1, rnd2] = generateRandomPixels(2)
	e1 = np.ones(4)
	e1[rnd1] = e1[rnd2] = 0
	e2 = np.ones(4) - e1
	return (np.reshape(e1, blockSize), np.reshape(e2, blockSize))

	def WBB():
	[rnd] = generateRandomPixels(1)
	(e1, e2) = (np.ones(4), np.ones(4))
	e1[rnd] = e2[rnd] = 0
	return (np.reshape(e1, blockSize), np.reshape(e2, blockSize))

	def WBW():
	[rnd1, rnd2] = generateRandomPixels(2)
	(e1, e2) = (np.ones(4), np.ones(4))
	e1[rnd1] = e2[rnd1] = e2[rnd2] = 0
	return (np.reshape(e1, blockSize), np.reshape(e2, blockSize))

	def WWB():
	(e1, e2) = WBW()
	return (e2, e1)

	def WWW():
	[rnd1, rnd2, rnd3] = generateRandomPixels(3)
	(e1, e2) = (np.ones(4), np.ones(4))
	e1[rnd1] = e2[rnd1] = e1[rnd2] = e2[rnd3] = 0
	return (np.reshape(e1, blockSize), np.reshape(e2, blockSize))

	if h:
	if i1:
	if i2:
	return BBB()
	else:
	return BBW()
	else:
	if i2:
	return BWB()
	else:
	return BWW()
	else:
	if i1:
	if i2:
	return WBB()
	else:
	return WBW()
	else:
	if i2:
	return WWB()
	else:
	return WWW()


	for i in xrange(xsize):
	for j in xrange(ysize):
	enc = generateEncoding(getBW(i,j,hidden), getBW(i,j,in1), getBW(i,j,in2))
	setElements(i, j, enc)

	return (out1, out2)

	if __name__ == "__main__":
	hidden = loadImage("hidden.png")
	in1 = loadImage("in1.png")
	in2 = loadImage("in2.png")

	(out1, out2) = encode(in1, in2, hidden)

	saveImage(out1, "out1.png")
	saveImage(out2, "out2.png")