Example #1
0
 def insert(self, cover_image):
     # Image to array
     cover_array = np.asarray(cover_image)
     # Blue component
     blue_cover_array = cover_array[:, :, 2]
     blue_cover_array.setflags(write=1)
     # Dividing in 32x32 blocks
     blocks32x32 = BlocksImage(blue_cover_array, 32, 32)
     # Touring each block 32x32
     for num_block in range(blocks32x32.max_num_blocks()):
         # Copying block 32x32
         blocksCopy32x32 = deepcopy(blocks32x32.get_block(num_block))
         # Dividing in 16x16 blocks
         blocksCopy16x16 = BlocksImage(blocksCopy32x32, 16, 16)
         # Get first block
         first_block = blocksCopy16x16.get_block(0)
         # Pariar
         for i in range(16):
             for y in range(16):
                 if (first_block[i, y] % 2) == 1:
                     first_block[i, y] -= 1
         # Hash of blocksCopy32x32 pareado
         blocksHash = utils.sha256Binary(blocksCopy32x32.tolist())
         # Insert data
         for i in range(16):
             for y in range(16):
                 first_block[i, y] += int(blocksHash[16 * i + y])
         # Update block
         blocks32x32.set_block(blocksCopy32x32, num_block)
     watermarked_image = Image.fromarray(cover_array)
     return watermarked_image
Example #2
0
 def extractFromComponent(self, component_cover_array):
     # Dividing in 32x32 blocks
     blocks32x32 = BlocksImage(component_cover_array, 32, 32)
     # Touring each block 32x32
     modifiedBlocks = []
     for num_block in range(blocks32x32.max_num_blocks()):
         # Copying block 32x32
         blockCopy32x32 = deepcopy(blocks32x32.get_block(num_block))
         # Dividing in 16x16 blocks
         blocksCopy16x16 = BlocksImage(blockCopy32x32, 16, 16)
         # Get first block
         first_block = blocksCopy16x16.get_block(0)
         # Watermark
         w = ''
         # Pariar
         for i in range(16):
             for y in range(16):
                 if (first_block[i, y] % 2) == 1:
                     first_block[i, y] -= 1
                     w += '1'
                 else:
                     w += '0'
         # Hash of blocksCopy32x32 pareado
         blocksHash = utils.sha256Binary(blockCopy32x32.tolist())
         if w != blocksHash:
             modifiedBlocks.append(num_block)
     return modifiedBlocks
Example #3
0
def main():
    try:
        # Load cover image
        root = Tk()
        root.filename = filedialog.askopenfilename(
            initialdir="static/",
            title="Select file",
            filetypes=(("png files", "*.jpg"), ("jpg files", "*.png"),
                       ("all files", "*.*")))
        cover_image = Image.open(root.filename).convert('RGB')
        # Creando path para almacebar los bloques de esta imagen
        b_path = 'static/' + root.filename.split('/')[-1][:-4] + '/'
        try:
            os.stat(b_path)
        except Exception as e:
            os.mkdir(b_path)
        root.destroy()

    except Exception as e:
        root.destroy()
        print("Error: ", e)
        print("The image file was not loaded")

    # Instance a la clase Bloque
    cover_array = np.asarray(cover_image)
    blocks = BlocksImage(cover_array)
    random_blocks = [i for i in range(blocks.max_num_blocks())]
    random.shuffle(random_blocks)
    for i in range(blocks.max_num_blocks()):
        print("Block #: ", random_blocks[i] + 1)
        block_array = blocks.get_block(random_blocks[i] + 1)
        # Save block image
        block_image = Image.fromarray(block_array, 'RGB')
        block_path = b_path + str(i) + '.png'
        block_image.save(block_path)
        # Clasificacion del block
        clasificador = clasificar(block_path)
        print(clasificador)
        class_path = b_path + str(clasificador['c']) + '_' + str(
            clasificador['delta']) + '/'
        if len(clases) == 0:
            # Add como clase 1
            os.mkdir(class_path)
            clases['1'] = [clasificador['c'], clasificador['delta']]
            block_image = Image.open(block_path).save(class_path + str(i) +
                                                      '.png')
        elif is_in_clases([clasificador['c'], clasificador['delta']]):
            # Add a la clase correspondiente
            block_image = Image.open(block_path).save(class_path + str(i) +
                                                      '.png')
        else:
            # Add clase
            clases[len(clases) +
                   1] = [clasificador['c'], clasificador['delta']]
            os.mkdir(class_path)
            block_image = Image.open(block_path).save(class_path + str(i) +
                                                      '.png')
        print("Clases: ", clases)
Example #4
0
    def extract(self, watermarked_image):

        print("...Proceso de extraccion...")

        # Instancias necesarias
        itools = ImageTools()

        print("Convirtiendo a YCbCr")
        # Convirtiendo a modelo de color YCbCr
        watermarked_ycbcr_array = itools.rgb2ycbcr(watermarked_image)

        # Tomando componente Y
        watermarked_array = watermarked_ycbcr_array[:, :, 0]

        bt_of_watermarked_Y = BlocksImage(watermarked_array)

        extract = []

        print("Extrayendo")
        # Recorrer todos los bloques de la imagen
        for i in range(self.len_watermark_list):
            block = bt_of_watermarked_Y.get_block(self.pos[i])
            # Valores de coeficiente y delta optimo para el bloque
            (c, delta) = self.clasificar(self.pos[i], watermarked_image)
            dqkt_block = DqKT().dqkt2(np.array(block, dtype=np.float32))
            
            negative = False
            
            (px, py) = self.get_indice(c)           
            if dqkt_block[px, py] < 0:
                negative = True
            
            C1 = (2*delta*round(abs(dqkt_block[px, py])/(2.0*delta)) + delta/2.0) - abs(dqkt_block[px, py])
            
            C0 = (2*delta*round(abs(dqkt_block[px, py])/(2.0*delta)) - delta/2.0) - abs(dqkt_block[px, py])

            if negative:
                C1 *= -1
                C0 *= -1
            if C0 < C1:
                extract.append(0)
            else:
                extract.append(1)

        wh = int(math.sqrt(self.len_watermark_list))
        extract_image = Image.new("1", (wh, wh), 255)
        array_extract_image1 = misc.fromimage(extract_image)

        for i in range(wh):
            for y in range(wh):
                if extract[wh*i+y] == 0:
                    array_extract_image1[i, y] = 0
        
        watermark_extracted = misc.toimage(array_extract_image1)
        for i in range(10):
            watermark_extracted = DAT().dat2(watermark_extracted)
        
        return watermark_extracted
Example #5
0
    def insert(self, cover_image):
        
        print("...Proceso de insercion...")

        # Instancias necesarias
        itools = ImageTools()

        print("Convirtiendo a YCbCr")
        # Convirtiendo a modelo de color YCbCr
        cover_ycbcr_array = itools.rgb2ycbcr(cover_image)

        # Obteniendo componente Y
        cover_array = cover_ycbcr_array[:, :, 0]

        # Objeto de la clase Bloque
        bt_of_cover = BlocksImage(cover_array)

        # Generando bloques a marcar
        print("Generando bloques a marcar")
        self.generar(bt_of_cover.max_num_blocks())

        print("Marcando")
        # Marcar los self.len_watermark_list bloques
        for i in range(self.len_watermark_list):
            block = bt_of_cover.get_block(self.pos[i])

            # Calculando DCT
            dct_block = DCT().dct2(block)

            c = self.c
            delta = self.delta

            # negative = False
            (px, py) = self.get_indice(c)
            # if dct_block[px, py] < 0:
            #     negative = True

            if self.watermark_list[i % self.len_watermark_list] == 0:
                # Bit a insertar 0
                dct_block[px, py] = 2*delta*round(abs(dct_block[px, py])/(2.0*delta)) - delta/2.0
            else:
                # Bit a insertar 1
                dct_block[px, py] = 2*delta*round(abs(dct_block[px, py])/(2.0*delta)) + delta/2.0

            # if negative:
            #     dct_block[px, py] *= -1

            idct_block = DCT().idct2(dct_block)
            
            bt_of_cover.set_block(idct_block, self.pos[i])

        print("Convirtiendo a RGB")
        image_rgb_array = itools.ycbcr2rgb(cover_ycbcr_array)

        return Image.fromarray(image_rgb_array)
Example #6
0
    def extract(self, watermarked_image):
        # Instancias necesarias
        itools = ImageTools()

        # Convirtiendo a modelo de color YCbCr
        watermarked_ycbcr_array = itools.rgb2ycbcr(watermarked_image)

        # Tomando componente Y
        watermarked_array = watermarked_ycbcr_array[:, :, 0]

        # Wavelet Transform
        LL, [LH, HL, HH] = pywt.dwt2(watermarked_array, 'haar')

        colums = len(LL[0])

        extract = []

        # Extracting
        # Dividiendo LL en bloques de 8x8
        bt_of_LL = BlocksImage(LL)

        for i in range(bt_of_LL.max_num_blocks()):
            # Cuantificado
            QLL = utils.quantification(bt_of_LL.get_block(i), self.Q)
            # replaced directly by the resulting Q-LL
            bt_of_LL.set_block(QLL, i)

        for i in range(self.len_watermark_list):
            # Extrayendo
            px = self.pos[i] // colums
            py = self.pos[i] - (px * colums)
            extract.append(abs(round((HH[px, py] - LL[px, py]) / self.k)))

        # for i in range(self.len_watermark_list + 1):
        #     # Marcado
        #     if i > 0:
        #         px = i // colums
        #         py = i - (px * colums)
        #         extract.append(abs(round((HH[px, py] - LL[px, py])/self.k)))

        wh = int(math.sqrt(self.len_watermark_list))
        extract_image1 = Image.new("L", (wh, wh), 255)
        array_extract_image = misc.fromimage(extract_image1)

        for i in range(wh):
            for y in range(wh):
                if extract[wh * i + y] == 0:
                    array_extract_image[i, y] = 0

        watermark_extracted = misc.toimage(array_extract_image)

        return watermark_extracted
Example #7
0
 def extract(self, watermarked_image):
     import cv2
     # To array
     watermarked_array = np.asarray(watermarked_image)
     # Blue component
     blue_watermarked_array = watermarked_array[:, :, 2]
     blue_watermarked_array.setflags(write=1)
     blue_watermarked_array_noise = blue_watermarked_array.copy()
     # Dividing in 32x32 blocks
     blocks32x32 = BlocksImage(blue_watermarked_array_noise, 32, 32)
     # Touring each block 32x32
     modifiedBlocks = []
     for num_block in range(blocks32x32.max_num_blocks()):
         # Copying block 32x32
         blockCopy32x32 = deepcopy(blocks32x32.get_block(num_block))
         # Dividing in 16x16 blocks
         blocksCopy16x16 = BlocksImage(blockCopy32x32, 16, 16)
         # Get first block
         first_block = blocksCopy16x16.get_block(0)
         # Watermark
         w = ''
         # Pariar
         for i in range(16):
             for y in range(16):
                 if (first_block[i, y] % 2) == 1:
                     first_block[i, y] -= 1
                     w += '1'
                 else:
                     w += '0'
         # Hash of blocksCopy32x32 pareado
         blocksHash = utils.sha256Binary(blockCopy32x32.tolist())
         if w != blocksHash:
             modifiedBlocks.append(num_block)
     print(modifiedBlocks)
     for item in modifiedBlocks:
         coord = blocks32x32.get_coord(item)
         cv2.rectangle(watermarked_array, (coord[1], coord[0]),
                       (coord[3], coord[2]), (0, 255, 0), 1)
     return Image.fromarray(watermarked_array)
Example #8
0
 def insertInComponent(self, component_cover_array):
     # Dividing in 32x32 blocks
     blocks32x32 = BlocksImage(component_cover_array, 32, 32)
     # Touring each block 32x32
     for num_block in range(blocks32x32.max_num_blocks()):
         # Copying block 32x32
         blocksCopy32x32 = deepcopy(blocks32x32.get_block(num_block))
         # Dividing in 16x16 blocks
         blocksCopy16x16 = BlocksImage(blocksCopy32x32, 16, 16)
         # Get first block
         first_block = blocksCopy16x16.get_block(0)
         # Pariar
         for i in range(16):
             for y in range(16):
                 if (first_block[i, y] % 2) == 1:
                     first_block[i, y] -= 1
         # Hash of blocksCopy32x32 pareado
         blocksHash = utils.sha256Binary(blocksCopy32x32.tolist())
         # Insert data
         for i in range(16):
             for y in range(16):
                 first_block[i, y] += int(blocksHash[16*i + y])
         # Update block
         blocks32x32.set_block(blocksCopy32x32, num_block)
Example #9
0
 def clasificar(self, num_block, cover_image):
     # Instancia necesaria
     clasification = Clasification()
     bt_of_rgb_cover = BlocksImage(misc.fromimage(cover_image))
     # Predict
     p = clasification.predict(bt_of_rgb_cover.get_block(num_block))
     if p == 1:
         return (17, 90)
     elif p == 4:
         return (19, 60)
     elif p == 5:
         return (20, 130)
     elif p == 7:
         return (28, 94)
     elif p == 8:
         return (34, 130)
     else:
         return (19, 130)
Example #10
0
def sprint(path):
    cover_image = Image.open(path).convert('RGB')
    # Creando path para almacenar los bloques de esta imagen
    b_path = 'static/' + path.split('/')[-1][:-4] + '/'
    try:
        os.stat(b_path)
    except Exception:
        os.mkdir(b_path)

    # Instance a la clase Bloque
    cover_array = np.asarray(cover_image)
    blocks = BlocksImage(cover_array)
    random_blocks = [i for i in range(blocks.max_num_blocks())]
    random.shuffle(random_blocks)
    for i in range(blocks.max_num_blocks()):
        block_array = blocks.get_block(random_blocks[i])
        # Save block image
        block_image = Image.fromarray(block_array, 'RGB')
        block_path = b_path + str(random_blocks[i]) + '.png'
        try:
            os.stat(block_path)
            print("Ya existe: ", block_path)
        except Exception:
            block_image.save(block_path)
            # Clasificacion del block
            clasificador = clasificar(block_path)
            # print(clasificador)
            class_path = b_path + str(clasificador['c']) + '_' + str(
                clasificador['delta']) + '/'

            try:
                os.stat(class_path)
            except Exception:
                os.mkdir(class_path)

            Image.open(block_path).save(class_path + str(random_blocks[i]) +
                                        '.png')
Example #11
0
    def insert(self, cover_image):
        
        print("...Proceso de insercion...")

        # Instancias necesarias
        itools = ImageTools()

        print("Convirtiendo a YCbCr")
        # Convirtiendo a modelo de color YCbCr
        cover_ycbcr_array = itools.rgb2ycbcr(cover_image)

        # Obteniendo componente Y
        cover_array = cover_ycbcr_array[:, :, 0]

        # Objeto de la clase Bloque
        bt_of_cover = BlocksImage(cover_array)

        # Generando bloques a marcar
        print("Generando bloques a marcar")
        self.generar(bt_of_cover.max_num_blocks())

        print("Marcando")
        # Marcar los self.len_watermark_list bloques
        for i in range(self.len_watermark_list):
            block = bt_of_cover.get_block(self.pos[i])

            # Valores de coeficiente y delta optimo para el bloque
            (c, delta) = self.clasificar(self.pos[i], cover_image) 

            # Calculando Krawchout Transform
            dqkt_block = DqKT().dqkt2(block)

            negative = False
            (px, py) = self.get_indice(c)
            if dqkt_block[px, py] < 0:
                negative = True

            if self.watermark_list[i % self.len_watermark_list] == 0:
                # Bit a insertar 0
                dqkt_block[px, py] = 2*delta*round(abs(dqkt_block[px, py])/(2.0*delta)) + delta/2.0
            else:
                # Bit a insertar 1
                dqkt_block[px, py] = 2*delta*round(abs(dqkt_block[px, py])/(2.0*delta)) - delta/2.0

            if negative:
                dqkt_block[px, py] *= -1
            idqkt_block = DqKT().idqkt2(dqkt_block)
            inv = idqkt_block
            for x in range(8):
                for y in range(8):
                    if (inv[x, y] - int(inv[x, y])) < 0.5:
                        inv[x, y] = int(inv[x, y])
                    else:
                        inv[x, y] = int(inv[x, y]) + 1
                    if inv[x, y] > 255:
                        inv[x, y] = 255
                    if inv[x, y] < 0:
                        inv[x, y] = 0
            bt_of_cover.set_block(idqkt_block, self.pos[i])

        print("Convirtiendo a RGB")
        image_rgb_array = itools.ycbcr2rgb(cover_ycbcr_array)

        return Image.fromarray(image_rgb_array)
Example #12
0
    def insert(self, cover_image):
        # Instancia
        itools = ImageTools()

        print("Convirtiendo a YCbCr")
        # Convirtiendo a modelo de color YCbCr
        cover_ycbcr_array = itools.rgb2ycbcr(cover_image)

        # Obteniendo componente Y
        cover_array = cover_ycbcr_array[:, :, 0]

        print("DWT")
        # DWT
        LL, [LH, HL, HH] = pywt.dwt2(cover_array, 'haar')

        # Generando posiciones a utilizar
        self.generar(LL.size)

        # Dividiendo LL en bloques de 8x8
        bt_of_LL = BlocksImage(LL)
        bt_of_HH = BlocksImage(HH)

        print("Re-asignando subbanda HH")
        for i in range(bt_of_LL.max_num_blocks()):
            # Cuantificado
            QLL = utils.quantification(bt_of_LL.get_block(i), self.Q)
            # replaced directly by the resulting Q-LL
            bt_of_HH.set_block(QLL, i)

        QWLL = np.copy(HH)
        # QWLL = np.full_like(HH)

        print("Modificando LL")
        for i in range(self.len_watermark_list):
            colums = len(LL[0])
            # Marcado
            px = self.pos[i] // colums
            py = self.pos[i] - (px * colums)
            QWLL[px, py] = HH[px, py] + self.watermark_list[i] / 255 * self.k

        # print("Modificando LL")
        # for i in range(self.len_watermark_list + 1):
        #     colums = len(LL[0])
        #     # Marcado
        #     if i > 0:
        #         px = i // colums
        #         py = i - (px * colums)
        #         LL[px, py] += self.watermark_list[i-1]/255 * self.k

        bt_of_QWLL = BlocksImage(QWLL)
        for i in range(bt_of_LL.max_num_blocks()):
            # Descuantificando
            UQWLL = utils.unquantification(bt_of_QWLL.get_block(i), self.Q)
            # replaced directly by the resulting Q-LL
            bt_of_LL.set_block(UQWLL, i)

        # Inverse transform
        print("IDWT")
        cover_ycbcr_array[:, :, 0] = pywt.idwt2((LL, (LH, HL, HH)), 'haar')

        print("Convirtiendo a RGB")
        image_rgb_array = itools.ycbcr2rgb(cover_ycbcr_array)

        return Image.fromarray(image_rgb_array)
Example #13
0
    def extract(self, watermarked_image):

        c = self.c
        delta = self.delta

        print("...Proceso de extraccion...")

        # Instancias necesarias
        itools = ImageTools()

        print("Convirtiendo a YCbCr")
        # Convirtiendo a modelo de color YCbCr
        watermarked_ycbcr_array = itools.rgb2ycbcr(watermarked_image)

        # Tomando componente Y
        watermarked_array = watermarked_ycbcr_array[:, :, 0]

        bt_of_watermarked_Y = BlocksImage(watermarked_array)

        extract = []

        print("Extrayendo")
        # Recorrer todos los bloques de la imagen
        for i in range(self.len_watermark_list):
            block = bt_of_watermarked_Y.get_block(self.pos[i])
            
            dct_block = DCT().dct2(block)
            
            negative = False
            
            (px, py) = self.get_indice(c)           
            if dct_block[px, py] < 0:
                negative = True
            
            C1 = (2*delta*round(abs(dct_block[px, py])/(2.0*delta)) + delta/2.0) - abs(dct_block[px, py])
            
            C0 = (2*delta*round(abs(dct_block[px, py])/(2.0*delta)) - delta/2.0) - abs(dct_block[px, py])

            if negative:
                C1 *= -1
                C0 *= -1

            if (dct_block[px, py] - C0) < (dct_block[px, py] - C1):
                extract.append(0)
            else:
                extract.append(1)

        wh = int(math.sqrt(self.len_watermark_list))
        extract_image = Image.new("1", (wh, wh), 255)
        array_extract_image1 = misc.fromimage(extract_image)

        for i in range(wh):
            for y in range(wh):
                if extract[wh*i+y] == 0:
                    array_extract_image1[i, y] = 0
        
        # myqr1 = MyQR62()
        
        watermark_extracted = misc.toimage(array_extract_image1)
        for i in range(10):
            watermark_extracted = DAT().dat2(watermark_extracted)
        
        # # Utilizacion de caracteristica de QR code
        
        # array = misc.fromimage(watermark_extracted)
        # watermark_extracted = misc.toimage(
        #     myqr1.get_resconstructed(array))

        # b = BlocksImage(misc.fromimage(watermark_extracted), 2, 2)
        # for m in range(b.max_num_blocks()):
        #     b.set_color(m)
        # watermark_extracted = misc.toimage(b.get())
        
        return watermark_extracted