YCAyca/non_linear_filtering.py

## non_linear_filtering.py
import copy
import cv2
import numpy as np
from PIL import Image, ImageFilter
from enum import Enum


class Filter_Type(Enum):
    MIN = 1
    MAX = 2
    MEDIAN = 3

class Print_Mode(Enum):
    ON = 1
    OFF = 2

def padding(image, padding_size):
    pad_w = padding_size[0]
    pad_h = padding_size[1]

    h = len(image)

    for i in range(pad_w):
        for i in range(h):
            image[i].insert(0,0)
            image[i].append(0)

    length = len(image[0])
    pad_line = [0]*length


    for i in range(pad_h):
        image.insert(0,pad_line)
        image.append(pad_line)


def nonlinear_filtering(image, filter_size, padding_size=None, mode=Filter_Type.MIN, print_mode = Print_Mode.ON):
    h = len(image)
    w = len(image[0])

    """ Apply padding if a padding size is given as a tuple (padding_width, padding_height) """
    if padding_size != None:
       padding(image, padding_size)


    pad_w = padding_size[0]
    pad_h = padding_size[1]

    h_padded = h + pad_h*2
    w_padded = w + pad_w*2

    if print_mode == Print_Mode.ON:
        print("input image with size " + str((h,w)) + "and with padding size" + str(padding_size) + "\n")

        for i in range(w):
            for j in range(h):
                print(image[i][j], end=' ')
            print("\n")

    output_image = [[0 for _ in range(w_padded-filter_size[0]+1)] for _ in range(h_padded-filter_size[1]+1)]

    h2 = len(output_image)
    w2 = len(output_image[0])

    window_area = list()

    k = 0
    l = 0

    """ apply chosen filter to the input image and create output image"""

    for i in range(w_padded-filter_size[0]+1): # main border (traveling to left should stop before coming to border - filter_size)
        for j in range(h_padded-filter_size[1]+1):  # main border (traveling to botto should stop before coming to border - filter_size)
            for a in range(filter_size[0]): #each tour should be in size of given filter (if kernel is 3x3, we should stop and calculate the minimum,maximum or median after each 3 step to left)
                for b in range(filter_size[1]): #each tour should be in size of given filter (if kernel is 3x3, we should stop and calculate the  minimum,maximum or median after each 3 step to bottom)
                    window_area.append(image[i+a][j+b])
            if mode == Filter_Type.MIN:
                pixel = min(window_area)
            elif mode ==  Filter_Type.MAX:
                pixel = max(window_area)
            elif mode ==  Filter_Type.MEDIAN:
                window_area.sort()
                length = len(window_area)
                middle_pixel_index = int(length / 2)
                pixel = window_area[middle_pixel_index]
            output_image[k][l] = pixel
            l += 1
            if l >= w2:
                l = 0
                k += 1
            window_area.clear()

    """print the output image """

    if print_mode == Print_Mode.ON:
        print("output image with size " + str((h2,w2)) + " after " + str(mode).split('.')[1] +  " filtering \n")

        for i in range(w2):
            for j in range(h2):
                print(output_image[i][j], end=' ')
            print("\n")

    return output_image


""" Test with a 2D list """

def Test_2D_list():
    im1 = [[0,0,2,5,50,50,100,150,150],
       [0,10,12,25,15,10,5,200,204],
       [2,1,5,10,100,4,150,178,101],
       [12,10,15,20,101,2,1,5,12],
       [10,3,5,13,72,88,95,4,7],
       [15,0,3,90,102,90,100,101,10],
       [4,4,5,52,18,10,10,17,50],
       [50,50,15,45,100,15,22,1,8],
       [10,4,2,0,0,0,50,5,103]]


    filter_size = (3,3)

    input_image = copy.deepcopy(im1)
    output_image = nonlinear_filtering(input_image,filter_size, (1,1))

    input_image = copy.deepcopy(im1)
    nonlinear_filtering(input_image,filter_size, (1,1),Filter_Type.MAX)

    input_image = im1.copy()
    nonlinear_filtering(im1,filter_size,(1,1),Filter_Type.MEDIAN)


""" Test with a real image using opencv  to list conversion """

def Test_Image():
    im2 = cv2.imread("lena.png", cv2.IMREAD_GRAYSCALE)
    cv2.imshow("input_image", im2)
    cv2.waitKey(0) # Press a key, not x (cross) button on coming window
    w,h = im2.shape

    input_image = im2.tolist()
    output_image = np.array(nonlinear_filtering(input_image,(3,3), (1,1), Filter_Type.MIN, print_mode = Print_Mode.OFF), dtype=np.uint8)
    cv2.imshow("MIN output_image", output_image)
    cv2.waitKey(0) # Press a key, not x (cross) button on coming window

    input_image = im2.tolist()
    output_image = np.array(nonlinear_filtering(input_image,(3,3), (1,1), Filter_Type.MAX, print_mode = Print_Mode.OFF), dtype=np.uint8)
    cv2.imshow("MAX output_image", output_image)
    cv2.waitKey(0) # Press a key, not x (cross) button on coming window

    input_image = im2.tolist()
    output_image = np.array(nonlinear_filtering(input_image,(3,3), (1,1), Filter_Type.MEDIAN, print_mode = Print_Mode.OFF), dtype=np.uint8)
    cv2.imshow("MEDIAN output_image", output_image)
    cv2.waitKey(0) # Press a key, not x (cross) button on coming window

    cv2.destroyAllWindows()


""" Compare the same image with Python's PIL image """

def PIL_Comparison():
    im1 = Image.open("lena.png")

    # applying the min filter
    im2 = im1.filter(ImageFilter.MinFilter(size = 3))
    im2.show()

    # applying the max filter
    im2 = im1.filter(ImageFilter.MaxFilter(size = 3))
    im2.show()

    # applying the median filter
    im2 = im1.filter(ImageFilter.MedianFilter(size = 3))
    im2.show()

    # applying the median filter to a noisy image

    im1 = Image.open("noisy.jpeg")
    im2 = im1.filter(ImageFilter.MedianFilter(size = 3))
    im2.show()


Test_2D_list()
Test_Image()
PIL_Comparison()
	import copy
	import cv2
	import numpy as np
	from PIL import Image, ImageFilter
	from enum import Enum


	class Filter_Type(Enum):
	MIN = 1
	MAX = 2
	MEDIAN = 3

	class Print_Mode(Enum):
	ON = 1
	OFF = 2

	def padding(image, padding_size):
	pad_w = padding_size[0]
	pad_h = padding_size[1]

	h = len(image)

	for i in range(pad_w):
	for i in range(h):
	image[i].insert(0,0)
	image[i].append(0)

	length = len(image[0])
	pad_line = [0]*length


	for i in range(pad_h):
	image.insert(0,pad_line)
	image.append(pad_line)


	def nonlinear_filtering(image, filter_size, padding_size=None, mode=Filter_Type.MIN, print_mode = Print_Mode.ON):
	h = len(image)
	w = len(image[0])

	""" Apply padding if a padding size is given as a tuple (padding_width, padding_height) """
	if padding_size != None:
	padding(image, padding_size)


	pad_w = padding_size[0]
	pad_h = padding_size[1]

	h_padded = h + pad_h*2
	w_padded = w + pad_w*2

	if print_mode == Print_Mode.ON:
	print("input image with size " + str((h,w)) + "and with padding size" + str(padding_size) + "\n")

	for i in range(w):
	for j in range(h):
	print(image[i][j], end=' ')
	print("\n")

	output_image = [[0 for _ in range(w_padded-filter_size[0]+1)] for _ in range(h_padded-filter_size[1]+1)]

	h2 = len(output_image)
	w2 = len(output_image[0])

	window_area = list()

	k = 0
	l = 0

	""" apply chosen filter to the input image and create output image"""

	for i in range(w_padded-filter_size[0]+1): # main border (traveling to left should stop before coming to border - filter_size)
	for j in range(h_padded-filter_size[1]+1): # main border (traveling to botto should stop before coming to border - filter_size)
	for a in range(filter_size[0]): #each tour should be in size of given filter (if kernel is 3x3, we should stop and calculate the minimum,maximum or median after each 3 step to left)
	for b in range(filter_size[1]): #each tour should be in size of given filter (if kernel is 3x3, we should stop and calculate the minimum,maximum or median after each 3 step to bottom)
	window_area.append(image[i+a][j+b])
	if mode == Filter_Type.MIN:
	pixel = min(window_area)
	elif mode == Filter_Type.MAX:
	pixel = max(window_area)
	elif mode == Filter_Type.MEDIAN:
	window_area.sort()
	length = len(window_area)
	middle_pixel_index = int(length / 2)
	pixel = window_area[middle_pixel_index]
	output_image[k][l] = pixel
	l += 1
	if l >= w2:
	l = 0
	k += 1
	window_area.clear()

	"""print the output image """

	if print_mode == Print_Mode.ON:
	print("output image with size " + str((h2,w2)) + " after " + str(mode).split('.')[1] + " filtering \n")

	for i in range(w2):
	for j in range(h2):
	print(output_image[i][j], end=' ')
	print("\n")

	return output_image



	""" Test with a 2D list """

	def Test_2D_list():
	im1 = [[0,0,2,5,50,50,100,150,150],
	[0,10,12,25,15,10,5,200,204],
	[2,1,5,10,100,4,150,178,101],
	[12,10,15,20,101,2,1,5,12],
	[10,3,5,13,72,88,95,4,7],
	[15,0,3,90,102,90,100,101,10],
	[4,4,5,52,18,10,10,17,50],
	[50,50,15,45,100,15,22,1,8],
	[10,4,2,0,0,0,50,5,103]]


	filter_size = (3,3)

	input_image = copy.deepcopy(im1)
	output_image = nonlinear_filtering(input_image,filter_size, (1,1))

	input_image = copy.deepcopy(im1)
	nonlinear_filtering(input_image,filter_size, (1,1),Filter_Type.MAX)

	input_image = im1.copy()
	nonlinear_filtering(im1,filter_size,(1,1),Filter_Type.MEDIAN)


	""" Test with a real image using opencv to list conversion """

	def Test_Image():
	im2 = cv2.imread("lena.png", cv2.IMREAD_GRAYSCALE)
	cv2.imshow("input_image", im2)
	cv2.waitKey(0) # Press a key, not x (cross) button on coming window
	w,h = im2.shape

	input_image = im2.tolist()
	output_image = np.array(nonlinear_filtering(input_image,(3,3), (1,1), Filter_Type.MIN, print_mode = Print_Mode.OFF), dtype=np.uint8)
	cv2.imshow("MIN output_image", output_image)
	cv2.waitKey(0) # Press a key, not x (cross) button on coming window

	input_image = im2.tolist()
	output_image = np.array(nonlinear_filtering(input_image,(3,3), (1,1), Filter_Type.MAX, print_mode = Print_Mode.OFF), dtype=np.uint8)
	cv2.imshow("MAX output_image", output_image)
	cv2.waitKey(0) # Press a key, not x (cross) button on coming window

	input_image = im2.tolist()
	output_image = np.array(nonlinear_filtering(input_image,(3,3), (1,1), Filter_Type.MEDIAN, print_mode = Print_Mode.OFF), dtype=np.uint8)
	cv2.imshow("MEDIAN output_image", output_image)
	cv2.waitKey(0) # Press a key, not x (cross) button on coming window

	cv2.destroyAllWindows()


	""" Compare the same image with Python's PIL image """

	def PIL_Comparison():
	im1 = Image.open("lena.png")

	# applying the min filter
	im2 = im1.filter(ImageFilter.MinFilter(size = 3))
	im2.show()

	# applying the max filter
	im2 = im1.filter(ImageFilter.MaxFilter(size = 3))
	im2.show()

	# applying the median filter
	im2 = im1.filter(ImageFilter.MedianFilter(size = 3))
	im2.show()

	# applying the median filter to a noisy image

	im1 = Image.open("noisy.jpeg")
	im2 = im1.filter(ImageFilter.MedianFilter(size = 3))
	im2.show()



	Test_2D_list()
	Test_Image()
	PIL_Comparison()