def measure(im, debug=False): gray = image.rgb2gray(im) size = cv.GetSize(im) total = float(size[0] * size[1]) edges = image.auto_edges(im) _, sat, val = image.split(image.rgb2hsv(im)) edges = image.auto_edges(im) l, u, v = tuple(map(image.equalize_hist, image.split(image.rgb2luv(im)))) u, v = tuple(map(image.gaussian, (u, v))) if debug: image.show(l, "1. L") image.show(u, "1. U") image.show(v, "1. V") la, ua, va, uva = tuple(map(image.cv2array, (l, u, v, image.And(l, u, v)))) test = image.new_from(gray) test2 = image.new_from(gray) cv.Xor(u, v, test) #cv.AbsDiff(u,v, test2) if debug: #cv.Threshold(test, test, 32, 255, cv.CV_THRESH_BINARY) image.show(test, "2. U Xor V") #image.show(test2, "TEST 2") #test = image.dilate(test) cv.Set(test, 0, image.dilate(edges)) #cv.Set(test, 0, image.invert(image.threshold(sat, threshold=8))) uv_score = cv.CountNonZero(test) / total if debug: image.show( test, "3. U Xor V - dilate(Edges) - invert(threshold(Saturation))") arr = image.cv2array(test) avg_mean, avg_std = arr.mean(), arr.std() score = uv_score, avg_std return test, score
def measure(im, debug=False): gray = image.rgb2gray(im) size = cv.GetSize(im) total = float(size[0] * size[1]) edges = image.auto_edges(im) _, sat, val = image.split(image.rgb2hsv(im)) edges = image.auto_edges(im) l,u,v = tuple(map(image.equalize_hist, image.split(image.rgb2luv(im)))) u,v = tuple(map(image.gaussian, (u,v))) if debug: image.show(l, "1. L") image.show(u, "1. U") image.show(v, "1. V") la,ua,va,uva = tuple(map(image.cv2array, (l,u,v, image.And(l,u,v)))) test = image.new_from(gray) test2 = image.new_from(gray) cv.Xor(u,v,test) #cv.AbsDiff(u,v, test2) if debug: #cv.Threshold(test, test, 32, 255, cv.CV_THRESH_BINARY) image.show(test, "2. U Xor V") #image.show(test2, "TEST 2") #test = image.dilate(test) cv.Set(test, 0, image.dilate(edges)) #cv.Set(test, 0, image.invert(image.threshold(sat, threshold=8))) uv_score = cv.CountNonZero(test) / total if debug: image.show(test, "3. U Xor V - dilate(Edges) - invert(threshold(Saturation))") arr = image.cv2array(test) avg_mean, avg_std = arr.mean(), arr.std() score = uv_score, avg_std return test, score
def get_focus_points(im, debug=False): edges = image.dilate(image.auto_edges(im)) #d = 1 #sobel = image.sobel(im, xorder=d, yorder=d) sobel = image.laplace(im) hsv = image.rgb2hsv(im) focused = image.And(sobel, edges) if im.nChannels == 3: hue, saturation, value = image.split(hsv) saturation = image.dilate(saturation) focused = image.And(focused, saturation) focused = image.threshold(image.dilate(focused), threshold=32) if debug: image.show(edges, "1. Edges") image.show(sobel, "2. Sobel") if im.nChannels == 3: image.show(saturation, "3. Saturation") return focused
def get_focus_points(im,debug=False): edges = image.dilate(image.auto_edges(im)) #d = 1 #sobel = image.sobel(im, xorder=d, yorder=d) sobel = image.laplace(im) hsv = image.rgb2hsv(im) focused = image.And(sobel, edges) if im.nChannels == 3: hue, saturation, value = image.split(hsv) saturation = image.dilate(saturation) focused = image.And(focused, saturation) focused = image.threshold(image.dilate(focused), threshold=32) if debug: image.show(edges, "1. Edges") image.show(sobel, "2. Sobel") if im.nChannels == 3: image.show(saturation, "3. Saturation") return focused
def measure(im, debug=False): gray = image.rgb2gray(im) size = cv.GetSize(im) total = float(size[0] * size[1]) edges = image.auto_edges(im) hue, sat, val = tuple( map(image.equalize_hist, image.split(image.rgb2hsv(im)))) l, u, v = tuple(map(image.equalize_hist, image.split(image.rgb2luv(im)))) values = [] if debug: image.show(l, "L") image.show(val, "Value") sat = image.threshold(val, 255 - 32) #image.And(val, sat) if debug: image.show(sat, "Thresh") #cv.And(val, l, val) cv.Sub(l, sat, l) cv.Set(l, 0, image.dilate(edges, iterations=3)) if debug: image.show(l, "L - Value") val = l g = Grid(cv.GetSize(val)) images = g.split_into(val, 16) arr = image.cv2array(val) avgmean, avgstd = arr.mean(), arr.std() for i in images: a = image.cv2array(i) mean, std = abs(a.mean() - avgmean), max(a.std(), 0) values.append((mean + std)) if debug: print values print "AVG", avgmean, avgstd image.show(val, "Result") return val, (avgmean, avgstd, len([v for v in values if v > avgstd * 2]))
def measure(im, debug=False): gray = image.rgb2gray(im) size = cv.GetSize(im) total = float(size[0] * size[1]) edges = image.auto_edges(im) hue, sat, val = tuple(map(image.equalize_hist, image.split(image.rgb2hsv(im)) )) l,u,v = tuple(map(image.equalize_hist, image.split(image.rgb2luv(im)))) values = [] if debug: image.show(l, "L") image.show(val, "Value") sat = image.threshold(val,255-32)#image.And(val, sat) if debug: image.show(sat, "Thresh") #cv.And(val, l, val) cv.Sub(l, sat, l) cv.Set(l, 0, image.dilate(edges, iterations=3)) if debug: image.show(l, "L - Value") val = l g = Grid(cv.GetSize(val)) images = g.split_into(val, 16) arr = image.cv2array(val) avgmean, avgstd = arr.mean(), arr.std() for i in images: a = image.cv2array(i) mean, std = abs(a.mean() - avgmean), max(a.std(), 0) values.append((mean+std)) if debug: print values print "AVG", avgmean, avgstd image.show(val, "Result") return val, (avgmean, avgstd, len([v for v in values if v > avgstd*2]))
def measure(im, debug=False): gray = image.rgb2gray(im) size = cv.GetSize(im) total = float(size[0] * size[1]) l = image.sub(gray, image.gaussian(gray, 5)) l2 = image.sub(gray, image.gaussian(gray, 9)) edges = image.dilate(image.auto_edges(im, percentage=0.2)) if debug: image.show(image.threshold(l, threshold=1), "Before Edge Removal (kernel=5)") image.show(image.threshold(l2, threshold=1), "Before Edge Removal (kernel=9)") cv.Set(l, 0, image.threshold(edges, threshold=1)) cv.Set(l2, 0, image.threshold(edges, threshold=1)) l = image.threshold(l, threshold=1) l2 = image.threshold(l2, threshold=1) if debug: image.show(image.threshold(edges, threshold=1), "Edges") image.show(l, "After Edge Removal (kernel=5)") image.show(l2, "After Edge Removal (kernel=9)") noise2 = image.new_from(gray) cv.EqualizeHist(gray, noise2) cv.AbsDiff(noise2, gray, noise2) cv.Set(noise2, 0, image.threshold(image.sobel(im, xorder=2, yorder=2), threshold=4)) diff = image.cv2array(noise2) if debug: image.show(noise2, "DIFF") print "M", diff.mean(), "S", diff.std() diff_stat = (diff.mean(), diff.std()) percent_noise = cv.CountNonZero(noise2) / total if debug: image.show(noise2, "NOISE2") # magical, I don't understand how this works _, sat, _ = image.split(image.rgb2hsv(im)) edges = image.auto_edges(im) l, u, v = tuple(map(image.equalize_hist, image.split(image.rgb2luv(im)))) u, v = tuple(map(image.gaussian, (u, v))) if debug: image.show(l, "1. L") image.show(u, "1. U") image.show(v, "1. V") la, ua, va, uva = tuple(map(image.cv2array, (l, u, v, image.And(l, u, v)))) test = image.new_from(gray) test2 = image.new_from(gray) cv.Xor(u, v, test) if debug: image.show(test, "2. U Xor V") cv.Set(test, 0, image.dilate(edges)) #cv.Set(test, 0, image.invert(image.threshold(sat, threshold=8))) uv_score = cv.CountNonZero(test) / total if debug: image.show( test, "3. U Xor V - dilate(Edges) - invert(threshold(Saturation))") g = Grid(size) images = map(image.cv2array, g.split_into(test, 6)) arr = image.cv2array(test) avg_mean, avg_std = arr.mean(), arr.std() #ms = [(a.mean(), a.std()) for a in images] #min_mean = min_std = 255 #max_mean = max_std = 0 #for m,s in ms: # min_mean = min(min_mean, m) # min_std = min(min_std, s) # max_mean = max(max_mean, m) # max_std = max(max_std, s) #if debug: # print min_mean, min_std # print avg_mean, avg_std # print max_mean, max_std # #score = uv_score, min_mean, avg_mean, avg_std, max_mean uv_score = uv_score, avg_std score = cv.CountNonZero(l) / total, cv.CountNonZero(l2) / total, \ diff_stat[0], diff_stat[1], uv_score return l, score
def measure(im, debug=False): size = cv.GetSize(im) npixels = size[0] * size[1] #print 'np', npixels focused = get_focus_points(im, debug) points = convert_to_points(focused) if debug: print "\t" + str( len(points)), '/', npixels, '=', len(points) / float(npixels) print "\tlen(points) =", len(points) image.show(focused, "4. Focused Points") saturation_score = 0 if not image.is_grayscale(im): edges = image.auto_edges(im) _, saturation, _ = image.split(image.rgb2hsv(im)) if debug: image.show(saturation, "5. Saturation") #saturation = image.laplace(image.gaussian(saturation, 3)) saturation = image.invert(saturation) mask = image.invert(image.threshold(im, threshold=16)) if debug: image.show(saturation, "5.3. Laplace of Saturation") cv.Set(saturation, 0, mask) cv.Set(saturation, 0, focused) if debug: image.show(mask, "5.6. Mask(focused AND invert(threshold(im, 16)))") image.show(saturation, "6. Set(<5.3>, 0, <5.6>)") saturation_score = cv.Sum(saturation)[0] / float(npixels * 255) print "\tSaturation Score:", saturation_score # light exposure h, s, v = image.split(image.rgb2hsv(im)) if debug: image.show(h, "7. Hue") image.show(s, "7. Saturation") image.show(v, "7. Value") diff = cv.CloneImage(v) cv.Set(diff, 0, image.threshold(s, threshold=16)) diff = image.dilate(diff, iterations=10) if debug: thres_s = image.threshold(s, threshold=16) image.show(thres_s, "8.3. Mask(threshold(<7.Saturation>, 16))") image.show(diff, "8.6. Dilate(Set(<7.Value>, 0, <8.3>), 10)") cdiff = cv.CountNonZero(diff) if cdiff > 0 and cdiff / float(npixels) > 0.01: test = cv.CloneImage(v) cv.Set(test, 0, image.invert(diff)) s = cv.Sum(test)[0] / float(cdiff * 255) if debug: print '\tLight Exposure Score:', s else: s = 0 if image.is_grayscale(im): return focused, (1, 1, 1, saturation_score, s) # we want to short circuit ASAP to avoid doing KMeans 50% of the image's pixels if len(points) > npixels / 2: return focused, (1, 1, 1, saturation_score, s) # we're so blurry we don't have any points! if len(points) < 1: return focused, (0, 0, 0, saturation_score, s) if debug: im2 = cv.CloneImage(im) focused_regions = image.new_from(im) cv.Set(focused_regions, 0) r = lambda x: random.randrange(1, x) groups = form_groups(points, estimated_size=min(max(int(len(points) / 1000), 2), 15)) #groups = form_groups(points, threshold=max(cv.GetSize(im))/16) #print 'groups', len(groups) hulls = draw_groups(groups, focused_regions) focused_regions = image.threshold(focused_regions, threshold=32, type=cv.CV_THRESH_TOZERO) min_area = npixels * 0.0005 densities = [h.points_per_pixel() for h in hulls if h.area() >= min_area] if debug: #image.show(focused, "Focused Points") image.show(focused_regions, "9. Focused Regions from <4>") cv.Sub( im2, image.gray2rgb( image.invert(image.threshold(focused_regions, threshold=1))), im2) image.show(im2, "10. threshold(<9>)") focused_regions = image.rgb2gray(focused_regions) densities = array(densities) c = cv.CountNonZero(focused_regions) c /= float(npixels) score = (c, densities.mean(), densities.std(), saturation_score, s) return focused, score
def measure(im, debug=False): size = cv.GetSize(im) npixels = size[0] * size[1] #print 'np', npixels focused = get_focus_points(im, debug) points = convert_to_points(focused) if debug: print "\t"+str(len(points)), '/', npixels, '=', len(points) / float(npixels) print "\tlen(points) =", len(points) image.show(focused, "4. Focused Points") saturation_score = 0 if not image.is_grayscale(im): edges = image.auto_edges(im) _, saturation, _ = image.split(image.rgb2hsv(im)) if debug: image.show(saturation, "5. Saturation") #saturation = image.laplace(image.gaussian(saturation, 3)) saturation = image.invert(saturation) mask = image.invert(image.threshold(im, threshold=16)) if debug: image.show(saturation, "5.3. Laplace of Saturation") cv.Set(saturation, 0, mask) cv.Set(saturation, 0, focused) if debug: image.show(mask, "5.6. Mask(focused AND invert(threshold(im, 16)))") image.show(saturation, "6. Set(<5.3>, 0, <5.6>)") saturation_score = cv.Sum(saturation)[0] / float(npixels * 255) print "\tSaturation Score:", saturation_score # light exposure h,s,v = image.split(image.rgb2hsv(im)) if debug: image.show(h, "7. Hue") image.show(s, "7. Saturation") image.show(v, "7. Value") diff = cv.CloneImage(v) cv.Set(diff, 0, image.threshold(s, threshold=16)) diff = image.dilate(diff, iterations=10) if debug: thres_s = image.threshold(s, threshold=16) image.show(thres_s, "8.3. Mask(threshold(<7.Saturation>, 16))") image.show(diff, "8.6. Dilate(Set(<7.Value>, 0, <8.3>), 10)") cdiff = cv.CountNonZero(diff) if cdiff > 0 and cdiff / float(npixels) > 0.01: test = cv.CloneImage(v) cv.Set(test, 0, image.invert(diff)) s = cv.Sum(test)[0] / float(cdiff * 255) if debug: print '\tLight Exposure Score:', s else: s = 0 if image.is_grayscale(im): return focused, (1, 1, 1, saturation_score, s) # we want to short circuit ASAP to avoid doing KMeans 50% of the image's pixels if len(points) > npixels/2: return focused, (1, 1, 1, saturation_score, s) # we're so blurry we don't have any points! if len(points) < 1: return focused, (0, 0, 0, saturation_score, s) if debug: im2 = cv.CloneImage(im) focused_regions = image.new_from(im) cv.Set(focused_regions, 0) r = lambda x: random.randrange(1, x) groups = form_groups(points, estimated_size=min(max(int(len(points) / 1000), 2), 15)) #groups = form_groups(points, threshold=max(cv.GetSize(im))/16) #print 'groups', len(groups) hulls = draw_groups(groups, focused_regions) focused_regions = image.threshold(focused_regions, threshold=32, type=cv.CV_THRESH_TOZERO) min_area = npixels * 0.0005 densities = [h.points_per_pixel() for h in hulls if h.area() >= min_area] if debug: #image.show(focused, "Focused Points") image.show(focused_regions, "9. Focused Regions from <4>") cv.Sub(im2, image.gray2rgb(image.invert(image.threshold(focused_regions, threshold=1))), im2) image.show(im2, "10. threshold(<9>)") focused_regions = image.rgb2gray(focused_regions) densities = array(densities) c = cv.CountNonZero(focused_regions) c /= float(npixels) score = (c, densities.mean(), densities.std(), saturation_score, s) return focused, score
def measure(im, debug=False): gray = image.rgb2gray(im) size = cv.GetSize(im) total = float(size[0] * size[1]) l = image.sub(gray, image.gaussian(gray, 5)) l2 = image.sub(gray, image.gaussian(gray, 9)) edges = image.dilate(image.auto_edges(im, percentage=0.2)) if debug: image.show(image.threshold(l, threshold=1), "Before Edge Removal (kernel=5)") image.show(image.threshold(l2, threshold=1), "Before Edge Removal (kernel=9)") cv.Set(l, 0, image.threshold(edges, threshold=1)) cv.Set(l2, 0, image.threshold(edges, threshold=1)) l = image.threshold(l, threshold=1) l2 = image.threshold(l2, threshold=1) if debug: image.show(image.threshold(edges, threshold=1), "Edges") image.show(l, "After Edge Removal (kernel=5)") image.show(l2, "After Edge Removal (kernel=9)") noise2 = image.new_from(gray) cv.EqualizeHist(gray, noise2) cv.AbsDiff(noise2, gray, noise2) cv.Set(noise2, 0, image.threshold(image.sobel(im, xorder=2, yorder=2), threshold=4)) diff = image.cv2array(noise2) if debug: image.show(noise2, "DIFF") print "M", diff.mean(), "S", diff.std() diff_stat = (diff.mean(), diff.std()) percent_noise = cv.CountNonZero(noise2) / total if debug: image.show(noise2, "NOISE2") # magical, I don't understand how this works _, sat, _ = image.split(image.rgb2hsv(im)) edges = image.auto_edges(im) l,u,v = tuple(map(image.equalize_hist, image.split(image.rgb2luv(im)))) u,v = tuple(map(image.gaussian, (u,v))) if debug: image.show(l, "1. L") image.show(u, "1. U") image.show(v, "1. V") la,ua,va,uva = tuple(map(image.cv2array, (l,u,v, image.And(l,u,v)))) test = image.new_from(gray) test2 = image.new_from(gray) cv.Xor(u,v,test) if debug: image.show(test, "2. U Xor V") cv.Set(test, 0, image.dilate(edges)) #cv.Set(test, 0, image.invert(image.threshold(sat, threshold=8))) uv_score = cv.CountNonZero(test) / total if debug: image.show(test, "3. U Xor V - dilate(Edges) - invert(threshold(Saturation))") g = Grid(size) images = map(image.cv2array, g.split_into(test, 6)) arr = image.cv2array(test) avg_mean, avg_std = arr.mean(), arr.std() #ms = [(a.mean(), a.std()) for a in images] #min_mean = min_std = 255 #max_mean = max_std = 0 #for m,s in ms: # min_mean = min(min_mean, m) # min_std = min(min_std, s) # max_mean = max(max_mean, m) # max_std = max(max_std, s) #if debug: # print min_mean, min_std # print avg_mean, avg_std # print max_mean, max_std # #score = uv_score, min_mean, avg_mean, avg_std, max_mean uv_score = uv_score, avg_std score = cv.CountNonZero(l) / total, cv.CountNonZero(l2) / total, \ diff_stat[0], diff_stat[1], uv_score return l, score