Specified the "analyze" script as the "normalize" script. Can be used for multiple processes.

At the point where the straightened image needs to be centered onto an idealized blank sheet.
2022-11-10 18:06:47 -05:00 · 2022-11-10 18:06:47 -05:00 · ca6d7d7d0b
parent 602b6dc26c
commit ca6d7d7d0b
2 changed files with 386 additions and 212 deletions
--- a/fourcell/analyze.py
+++ b/fourcell/analyze.py
@ -1,212 +0,0 @@
 import sys
 import cv2
 import numpy as np
 import math
 def image_resize(image, width = None, height = None, inter = cv2.INTER_AREA):
    dim = None
    (h, w) = image.shape[:2]
    if width is None and height is None:
        return image
    if width is None:
        r = height / float(h)
        dim = (int(w * r), height)
    else:
        r = width / float(w)
        dim = (width, int(h * r))
    resized = cv2.resize(image, dim, interpolation = inter)
    return resized
 def display (image) :
 	resized = image_resize(image, 800, 800)
 	cv2.imshow('img', resized)
 	while True:
 		key = cv2.waitKey(0)
 		if key == 27:
 			cv2.destroyAllWindows()
 			break
 	exit(0)
 def get_center (contour) : 
 	M = cv2.moments(contour)
 	cX = int(M["m10"] / M["m00"])
 	cY = int(M["m01"] / M["m00"])
 	return cX, cY
 def draw_line (image, hps, a, b) :
 	print(f'{a} -> {b}')
 	lA = (hps[a-1]['x'], hps[a-1]['y'])
 	lB = (hps[b-1]['x'], hps[b-1]['y'])
 	cv2.line(image, lA, lB, [0, 255, 0], 10)
 	return (lA, lB)
 def horiz_angle (line) :
 	deltaY = line[1][1] - line[0][1] #P2_y - P1_y
 	deltaX = line[1][0] - line[0][0] #P2_x - P1_x
 	angleInDegrees = math.degrees(math.atan2(deltaY, deltaX))
 	print(angleInDegrees)
 	return angleInDegrees
 def verts_angle (line) :
 	deltaY = line[1][1] - line[0][1] #P2_y - P1_y
 	deltaX = line[1][0] - line[0][0] #P2_x - P1_x
 	angleInDegrees = - (math.atan2(deltaX, deltaY) * 180 / math.pi)
 	print(angleInDegrees)
 	return angleInDegrees
 if len(sys.argv) < 2:
 	print('Please provide path to image for analysis')
 	exit(1)
 if len(sys.argv) < 3:
 	print('Please provide path to template file to create')
 	exit(2)
 scanImage = sys.argv[-2]
 templateFile = sys.argv[-1]
 print(f'Analyzing {scanImage} and creating {templateFile}')
 orig = cv2.imread(scanImage)
 img = orig.copy()
 height, width = img.shape[:2]
 orientation = height > width
 pageDim = (11, 8.5)
 if not orientation :
 	pageDim = (8.5, 11)
 pageRatio = pageDim[1] / pageDim[0]
 left=-1
 right=-1
 top=-1
 bottom=-1
 if orientation :
 	left = width * 0.2
 	right = width * 0.8
 else :
 	top = height * 0.2
 	bottom = height * 0.8
 gray = cv2.cvtColor(img, cv2.COLOR_BGR2GRAY)
 blur = cv2.medianBlur(gray, 31)
 ret, thresh = cv2.threshold(blur, 200, 255, cv2.THRESH_BINARY)
 canny = cv2.Canny(thresh, 75, 200)
 contours, hierarchy = cv2.findContours(canny, cv2.RETR_TREE, cv2.CHAIN_APPROX_NONE)
 contourList = []
 areaList = []
 for contour in contours:
 	approx = cv2.approxPolyDP(contour, 0.03 * cv2.arcLength(contour, True), True)
 	if cv2.isContourConvex(approx) :
 		cX, cY = get_center(contour)
 		if (orientation and ( cX < left or cX > right) ) or ( not orientation and ( cY < top or cY > bottom)) :
 			area = cv2.contourArea(contour)
 			areaList.append(area)
 			contourList.append(contour)
 maxArea=0
 maxIndex=0
 #reduce to lambda
 for i in range(len(areaList)) :
 	area = areaList[i]
 	if area > maxArea:
 		maxArea = area
 		maxIndex = i
 count = 0
 holePunches = []
 centersStr = []
 areaRange = 0
 topLeft = None
 minDist = 1000000
 # pretty good
 # add position constraint
 while count < 6 :
 	areaRange+=1
 	for i in range(len(areaList)) :
 		area = areaList[i]
 		if area == maxArea or area * ((100 + areaRange) / 100) > maxArea  :
 			cX, cY = get_center(contourList[i])
 			strC = f'{cX},{cY}'
 			if strC in centersStr :
 				continue
 			centersStr.append(strC)
 			print(f'{cX},{cY}')
 			#cv2.circle(img, (cX, cY), 40, (255, 0, 0), -1)
 			hp = {
 				'x' : cX,
 				'y' : cY,
 				'contour' : contourList[i],
 				'dist' : math.dist((cX, cY), (0, 0)),
 				'order': -1
 			}
 			if hp['dist'] < minDist :
 				minDist = hp['dist']
 				topLeft = hp
 			holePunches.append(hp)
 			count+=1
 for hp in holePunches :
 	hp['dist'] = math.dist( (topLeft['x'], topLeft['y']), (hp['x'], hp['y']) )
 holePunches = sorted(holePunches, key = lambda hp: hp['dist'])
 i = 0
 for hp in holePunches :
 	hp['order'] = i 
 	cv2.putText(img, str(i + 1), (hp['x'], hp['y']), cv2.FONT_HERSHEY_SIMPLEX, 20, (0, 0, 255), 5, cv2.LINE_AA, False)
 	i+=1
 verts = []
 horiz = []
 #across top
 horiz.append(horiz_angle(draw_line(img, holePunches, 1, 3)))
 #across bottom
 horiz.append(horiz_angle(draw_line(img, holePunches, 4, 6)))
 #middle
 horiz.append(horiz_angle(draw_line(img, holePunches, 2, 5)))
 #top left
 verts.append(verts_angle(draw_line(img, holePunches, 1, 2)))
 #long left
 verts.append(verts_angle(draw_line(img, holePunches, 1, 4)))
 #top right
 verts.append(verts_angle(draw_line(img, holePunches, 3, 5)))
 #long right
 verts.append(verts_angle(draw_line(img, holePunches, 3, 6)))
 #bottom left
 verts.append(verts_angle(draw_line(img, holePunches, 2, 4)))
 #bottom right
 verts.append(verts_angle(draw_line(img, holePunches, 5, 6)))
 #for v in verts :
 	#print(v)
 #for h in horiz :
 #	print(h)
 #	horiz_angle(h)
 print(f'Found hole punches within {areaRange}% of largest')
 #print(holePunches)
 #cv2.drawContours(img, list(map(lambda hp : hp['contour'], holePunches)), -1, (0, 255, 0), 20)
 #cv2.circle(img, (topLeft['x'], topLeft['y']), 50, (0, 0, 255), -1)
 display(img)
--- a/fourcell/normalize.py
+++ b/fourcell/normalize.py
@ -0,0 +1,386 @@
 import sys
 import cv2
 import numpy as np
 import math
 def image_resize(image, width = None, height = None, inter = cv2.INTER_AREA):
    dim = None
    (h, w) = image.shape[:2]
    if width is None and height is None:
        return image
    if width is None:
        r = height / float(h)
        dim = (int(w * r), height)
    else:
        r = width / float(w)
        dim = (width, int(h * r))
    resized = cv2.resize(image, dim, interpolation = inter)
    return resized
 def display (image) :
 	resized = image_resize(image, 800, 800)
 	cv2.imshow('img', resized)
 	while True:
 		key = cv2.waitKey(0)
 		if key == 27:
 			cv2.destroyAllWindows()
 			break
 	exit(0)
 def get_center (contour) : 
 	M = cv2.moments(contour)
 	cX = int(M["m10"] / M["m00"])
 	cY = int(M["m01"] / M["m00"])
 	return cX, cY
 def draw_line (image, hps, a, b) :
 	print(f'{a} -> {b}')
 	lA = (hps[a-1]['x'], hps[a-1]['y'])
 	lB = (hps[b-1]['x'], hps[b-1]['y'])
 	cv2.line(image, lA, lB, [0, 255, 0], 10)
 	return (lA, lB)
 def horiz_angle (line, rotate = 0) :
 	deltaY = line[1][1] - line[0][1] #P2_y - P1_y
 	deltaX = line[1][0] - line[0][0] #P2_x - P1_x
 	angleInDegrees = normalize_angle(math.degrees(math.atan2(deltaY, deltaX) + rotate))
 	return angleInDegrees
 def verts_angle (line) :
 	angleInDegrees = normalize_angle(horiz_angle(line, math.pi/2))
 	return angleInDegrees
 def is_close (point, points) :
 	for pt in points :
 		if math.dist(point, pt) < 100 :
 			return True
 	return False
 def normalize_angle (num, lower=0.0, upper=360.0, b=False):
    """Normalize number to range [lower, upper) or [lower, upper].
    Parameters
    ----------
    num : float
        The number to be normalized.
    lower : float
        Lower limit of range. Default is 0.0.
    upper : float
        Upper limit of range. Default is 360.0.
    b : bool
        Type of normalization. See notes.
    Returns
    -------
    n : float
        A number in the range [lower, upper) or [lower, upper].
    Raises
    ------
    ValueError
      If lower >= upper.
    Notes
    -----
    If the keyword `b == False`, the default, then the normalization
    is done in the following way. Consider the numbers to be arranged
    in a circle, with the lower and upper marks sitting on top of each
    other. Moving past one limit, takes the number into the beginning
    of the other end. For example, if range is [0 - 360), then 361
    becomes 1. Negative numbers move from higher to lower
    numbers. So, -1 normalized to [0 - 360) becomes 359.
    If the keyword `b == True` then the given number is considered to
    "bounce" between the two limits. So, -91 normalized to [-90, 90],
    becomes -89, instead of 89. In this case the range is [lower,
    upper]. This code is based on the function `fmt_delta` of `TPM`.
    Range must be symmetric about 0 or lower == 0.
    Examples
    --------
    >>> normalize(-270,-180,180)
    90
    >>> import math
    >>> math.degrees(normalize(-2*math.pi,-math.pi,math.pi))
    0.0
    >>> normalize(181,-180,180)
    -179
    >>> normalize(-180,0,360)
    180
    >>> normalize(36,0,24)
    12
    >>> normalize(368.5,-180,180)
    8.5
    >>> normalize(-100, -90, 90, b=True)
    -80.0
    >>> normalize(100, -90, 90, b=True)
    80.0
    >>> normalize(181, -90, 90, b=True)
    -1.0
    >>> normalize(270, -90, 90, b=True)
    -90.0
    """
    # abs(num + upper) and abs(num - lower) are needed, instead of
    # abs(num), since the lower and upper limits need not be 0. We need
    # to add half size of the range, so that the final result is lower +
    # <value> or upper - <value>, respectively.
    res = num
    if not b:
        if lower >= upper:
            raise ValueError("Invalid lower and upper limits: (%s, %s)" %
                             (lower, upper))
        res = num
        if num > upper or num == lower:
            num = lower + abs(num + upper) % (abs(lower) + abs(upper))
        if num < lower or num == upper:
            num = upper - abs(num - lower) % (abs(lower) + abs(upper))
        res = lower if res == upper else num
    else:
        total_length = abs(lower) + abs(upper)
        if num < -total_length:
            num += math.ceil(num / (-2 * total_length)) * 2 * total_length
        if num > total_length:
            num -= math.floor(num / (2 * total_length)) * 2 * total_length
        if num > upper:
            num = total_length - num
        if num < lower:
            num = -total_length - num
        res = num * 1.0  # Make all numbers float, to be consistent
    return res
 def mean (lst):
    return sum(lst) / len(lst)
 def find_hole_punches (img) :
 	left=-1
 	right=-1
 	top=-1
 	bottom=-1
 	if orientation :
 		left = width * 0.2
 		right = width * 0.8
 	else :
 		top = height * 0.2
 		bottom = height * 0.8
 	gray = cv2.cvtColor(img, cv2.COLOR_BGR2GRAY)
 	blur = cv2.medianBlur(gray, 31)
 	ret, thresh = cv2.threshold(blur, 200, 255, cv2.THRESH_BINARY)
 	canny = cv2.Canny(thresh, 75, 200)
 	contours, hierarchy = cv2.findContours(canny, cv2.RETR_TREE, cv2.CHAIN_APPROX_NONE)
 	contourList = []
 	areaList = []
 	for contour in contours:
 		approx = cv2.approxPolyDP(contour, 0.03 * cv2.arcLength(contour, True), True)
 		if cv2.isContourConvex(approx) :
 			cX, cY = get_center(contour)
 			if (orientation and ( cX < left or cX > right) ) or ( not orientation and ( cY < top or cY > bottom)) :
 				area = cv2.contourArea(contour)
 				areaList.append(area)
 				contourList.append(contour)
 	maxArea=0
 	maxIndex=0
 	#reduce to lambda
 	for i in range(len(areaList)) :
 		area = areaList[i]
 		if area > maxArea:
 			maxArea = area
 			maxIndex = i
 	count = 0
 	holePunches = []
 	centers = []
 	areaRange = 0
 	topLeft = None
 	minDist = 1000000
 	# pretty good
 	# add position constraint
 	while count < 6 :
 		areaRange+=1
 		for i in range(len(areaList)) :
 			area = areaList[i]
 			if area == maxArea or area * ((100 + areaRange) / 100) > maxArea  :
 				cX, cY = get_center(contourList[i])
 				if is_close((cX, cY), centers) :
 					continue
 				centers.append((cX, cY))
 				print(f'{cX},{cY}')
 				hp = {
 					'x' : cX,
 					'y' : cY,
 					'contour' : contourList[i],
 					'dist' : math.dist((cX, cY), (0, 0)),
 					'order': -1
 				}
 				if hp['dist'] < minDist :
 					minDist = hp['dist']
 					topLeft = hp
 				holePunches.append(hp)
 				count+=1
 	for hp in holePunches :
 		hp['dist'] = math.dist( (topLeft['x'], topLeft['y']), (hp['x'], hp['y']) )
 	print(f'Hole punches: {len(holePunches)}')
 	print(f'Found hole punches within {areaRange}% of largest')
 	if len(holePunches) != 6:
 		print(f'Wrong number of hole punches, exiting...')
 		exit(4)
 	holePunches = sorted(holePunches, key = lambda hp: hp['dist'])
 	i = 0
 	for hp in holePunches :
 		hp['order'] = i 
 		#cv2.putText(img, str(i + 1), (hp['x'], hp['y']), cv2.FONT_HERSHEY_SIMPLEX, 20, (0, 0, 255), 5, cv2.LINE_AA, False)
 		i+=1
 	return holePunches
 def correct_rotation (img, original, holePunches) :
 	horizLines = [
 		(3, 1),
 		(6, 4),
 		(5, 2)
 	]
 	vertsLines = [
 		(1, 2),
 		(1, 4), #double long left
 		(1, 4), #
 		(3, 5),
 		(3, 6), #double long right
 		(3, 6),  #
 		(2, 4),
 		(5, 6)
 	]
 	rotations = []
 	for h in horizLines :
 		line = draw_line(img, holePunches, h[0], h[1])
 		angle = horiz_angle(line)
 		print(angle)
 		rotations.append(angle)
 	for v in vertsLines :
 		line = draw_line(img, holePunches, v[0], v[1])
 		angle = verts_angle(line)
 		print(angle)
 		rotations.append(angle)
 	correctionRotation = mean(rotations) - 180
 	print(f'Mean rotation: {correctionRotation}')
 	(cX, cY) = (width // 2, height // 2)
 	M = cv2.getRotationMatrix2D((cX, cY), correctionRotation, 1.0)
 	#create rotation of original
 	return cv2.warpAffine(original, M, (width, height))
 def create_blank (w, h, rgb_color = (255, 255, 255)) :
 	blank = np.zeros([h, w, 3], dtype=np.uint8)
 	color = tuple(reversed(rgb_color))
 	blank[:] = color
 	return blank
 def place (bottom, top, x, y) :
 	return bottom.paste(top, (x, y))
 def get_mean_rect (holePunches) :
 	left = 0
 	right = 0
 	top = 0
 	bottom = 0
 	for hp in holePunches :
 		if hp['order'] == 0 :
 			left += float(hp['x'])
 			top += float(hp['y'])
 		elif hp['order'] == 2 :
 			right += float(hp['y'])
 			top += float(hp['y'])
 		elif hp['order'] == 3 :
 			left += float(hp['x'])
 			bottom += float(hp['y'])
 		elif hp['order'] == 5 :
 			right += float(hp['x'])
 			bottom += float(hp['y'])
 	x = round((right / 2.0) - (left / 2.0))
 	y = round((bottom / 2.0) - (top / 2.0))
 	return (x, y)
 def center_within (larger, smaller) :
 	w1 = larger[0]
 	h1 = larger[1]
 	w2 = smaller[0]
 	h2 = smaller[1]
 	x = ((w1 - w2) / 2)
 	y = ((h1 - h2) / 2)
 	return (x, y)
 if len(sys.argv) < 2:
 	print('Please provide path of scan to normalize')
 	exit(1)
 if len(sys.argv) < 3:
 	print('Please provide path to output file')
 	exit(2)
 scanImage = sys.argv[-2]
 normalImage = sys.argv[-1]
 pageDim = (11, 8.5)
 pageRatio = pageDim[1] / pageDim[0]
 print(f'Normalizing {scanImage} as {normalImage}')
 original = cv2.imread(scanImage)
 img = original.copy()
 height, width = img.shape[:2]
 orientation = height > width
 if not orientation :
 	print(f'Scan is not in portrait mode, exiting...')
 	exit(3)
 normalHeight = round(float(width) / pageRatio)
 holePunches = find_hole_punches(img)
 rotated = correct_rotation(img, original, holePunches)
 holePunches = find_hole_punches(rotated)
 blank = create_blank(width, normalHeight)
 tl = None
 for hp in holePunches :
 	if tl is None :
 		tl = hp
 	print(f'{hp["order"] + 1} {hp["x"]},{hp["y"]}')
 print(f'Normal dimensions: {width},{normalHeight}')
 # the mean rectangle is the average width and height
 # determined by the four corner hole punches
 meanRect = get_mean_rect(holePunches)
 print(f'Mean rectangle: {meanRect[0]},{meanRect[1]}')
 # offset is the position within the new normal image
 # the top left hole punch should be centered to
 offset = center_within((width, normalHeight), meanRect)
 print(f'Offset: {offset[0]},{offset[1]}')
 #normal = place(blank, rotated, 0, 0)
 #display(normal)