import numpy as np import cv2 import random from typing import List, Tuple, Union def hex2bgr(hex): gmask = 254 << 8 rmask = 254 b = hex >> 16 g = (hex & gmask) >> 8 r = hex & rmask return np.stack([b, g, r]).transpose() def union_area(bboxa, bboxb): x1 = max(bboxa[0], bboxb[0]) y1 = max(bboxa[1], bboxb[1]) x2 = min(bboxa[2], bboxb[2]) y2 = min(bboxa[3], bboxb[3]) if y2 < y1 or x2 < x1: return -1 return (y2 - y1) * (x2 - x1) def get_yololabel_strings(clslist, labellist): content = '' for cls, xywh in zip(clslist, labellist): content += str(int(cls)) + ' ' + ' '.join([str(e) for e in xywh]) + '\n' if len(content) != 0: content = content[:-1] return content # 4 points bbox to 8 points polygon def xywh2xyxypoly(xywh, to_int=True): xyxypoly = np.tile(xywh[:, [0, 1]], 4) xyxypoly[:, [2, 4]] += xywh[:, [2]] xyxypoly[:, [5, 7]] += xywh[:, [3]] if to_int: xyxypoly = xyxypoly.astype(np.int64) return xyxypoly def xyxy2yolo(xyxy, w: int, h: int): if xyxy == [] or xyxy == np.array([]) or len(xyxy) == 0: return None if isinstance(xyxy, list): xyxy = np.array(xyxy) if len(xyxy.shape) == 1: xyxy = np.array([xyxy]) yolo = np.copy(xyxy).astype(np.float64) yolo[:, [0, 2]] = yolo[:, [0, 2]] / w yolo[:, [1, 3]] = yolo[:, [1, 3]] / h yolo[:, [2, 3]] -= yolo[:, [0, 1]] yolo[:, [0, 1]] += yolo[:, [2, 3]] / 2 return yolo def yolo_xywh2xyxy(xywh: np.array, w: int, h: int, to_int=True): if xywh is None: return None if len(xywh) == 0: return None if len(xywh.shape) == 1: xywh = np.array([xywh]) xywh[:, [0, 2]] *= w xywh[:, [1, 3]] *= h xywh[:, [0, 1]] -= xywh[:, [2, 3]] / 2 xywh[:, [2, 3]] += xywh[:, [0, 1]] if to_int: xywh = xywh.astype(np.int64) return xywh def rotate_polygons(center, polygons, rotation, new_center=None, to_int=True): if new_center is None: new_center = center rotation = np.deg2rad(rotation) s, c = np.sin(rotation), np.cos(rotation) polygons = polygons.astype(np.float32) polygons[:, 1::2] -= center[1] polygons[:, ::2] -= center[0] rotated = np.copy(polygons) rotated[:, 1::2] = polygons[:, 1::2] * c - polygons[:, ::2] * s rotated[:, ::2] = polygons[:, 1::2] * s + polygons[:, ::2] * c rotated[:, 1::2] += new_center[1] rotated[:, ::2] += new_center[0] if to_int: return rotated.astype(np.int64) return rotated def letterbox(im, new_shape=(640, 640), color=(0, 0, 0), auto=False, scaleFill=False, scaleup=True, stride=128): # Resize and pad image while meeting stride-multiple constraints shape = im.shape[:2] # current shape [height, width] if not isinstance(new_shape, tuple): new_shape = (new_shape, new_shape) # Scale ratio (new / old) r = min(new_shape[0] / shape[0], new_shape[1] / shape[1]) if not scaleup: # only scale down, do not scale up (for better val mAP) r = min(r, 1.0) # Compute padding ratio = r, r # width, height ratios new_unpad = int(round(shape[1] * r)), int(round(shape[0] * r)) dw, dh = new_shape[1] - new_unpad[0], new_shape[0] - new_unpad[1] # wh padding if auto: # minimum rectangle dw, dh = np.mod(dw, stride), np.mod(dh, stride) # wh padding elif scaleFill: # stretch dw, dh = 0.0, 0.0 new_unpad = (new_shape[1], new_shape[0]) ratio = new_shape[1] / shape[1], new_shape[0] / shape[0] # width, height ratios # dw /= 2 # divide padding into 2 sides # dh /= 2 dh, dw = int(dh), int(dw) if shape[::-1] != new_unpad: # resize im = cv2.resize(im, new_unpad, interpolation=cv2.INTER_LINEAR) top, bottom = int(round(dh - 0.1)), int(round(dh + 0.1)) left, right = int(round(dw - 0.1)), int(round(dw + 0.1)) im = cv2.copyMakeBorder(im, 0, dh, 0, dw, cv2.BORDER_CONSTANT, value=color) # add border return im, ratio, (dw, dh) def resize_keepasp(im, new_shape=640, scaleup=True, interpolation=cv2.INTER_LINEAR, stride=None): shape = im.shape[:2] # current shape [height, width] if new_shape is not None: if not isinstance(new_shape, tuple): new_shape = (new_shape, new_shape) else: new_shape = shape # Scale ratio (new / old) r = min(new_shape[0] / shape[0], new_shape[1] / shape[1]) if not scaleup: # only scale down, do not scale up (for better val mAP) r = min(r, 1.0) new_unpad = int(round(shape[1] * r)), int(round(shape[0] * r)) if stride is not None: h, w = new_unpad if h % stride != 0 : new_h = (stride - (h % stride)) + h else : new_h = h if w % stride != 0 : new_w = (stride - (w % stride)) + w else : new_w = w new_unpad = (new_h, new_w) if shape[::-1] != new_unpad: # resize im = cv2.resize(im, new_unpad, interpolation=interpolation) return im def expand_textwindow(img_size, xyxy, expand_r=8, shrink=False): im_h, im_w = img_size[:2] x1, y1 , x2, y2 = xyxy w = x2 - x1 h = y2 - y1 paddings = int(round((max(h, w) * 0.25 + min(h, w) * 0.75) / expand_r)) if shrink: paddings *= -1 x1, y1 = max(0, x1 - paddings), max(0, y1 - paddings) x2, y2 = min(im_w-1, x2+paddings), min(im_h-1, y2+paddings) return [x1, y1, x2, y2] def enlarge_window(rect, im_w, im_h, ratio=2.5, aspect_ratio=1.0) -> List: assert ratio > 1.0 x1, y1, x2, y2 = rect w = x2 - x1 h = y2 - y1 if w <= 0 or h <= 0: return [0, 0, 0, 0] # https://numpy.org/doc/stable/reference/generated/numpy.roots.html coeff = [aspect_ratio, w+h*aspect_ratio, (1-ratio)*w*h] roots = np.roots(coeff) roots.sort() delta = int(round(roots[-1] / 2 )) delta_w = int(delta * aspect_ratio) delta_w = min(x1, im_w - x2, delta_w) delta = min(y1, im_h - y2, delta) rect = np.array([x1-delta_w, y1-delta, x2+delta_w, y2+delta], dtype=np.int64) rect[::2] = np.clip(rect[::2], 0, im_w) rect[1::2] = np.clip(rect[1::2], 0, im_h) return rect.tolist() def draw_connected_labels(num_labels, labels, stats, centroids, names="draw_connected_labels", skip_background=True): labdraw = np.zeros((labels.shape[0], labels.shape[1], 3), dtype=np.uint8) max_ind = 0 if isinstance(num_labels, int): num_labels = range(num_labels) # for ind, lab in enumerate((range(num_labels))): for lab in num_labels: if skip_background and lab == 0: continue randcolor = (random.randint(0,255), random.randint(0,255), random.randint(0,255)) labdraw[np.where(labels==lab)] = randcolor maxr, minr = 0.5, 0.001 maxw, maxh = stats[max_ind][2] * maxr, stats[max_ind][3] * maxr minarea = labdraw.shape[0] * labdraw.shape[1] * minr stat = stats[lab] bboxarea = stat[2] * stat[3] if stat[2] < maxw and stat[3] < maxh and bboxarea > minarea: pix = np.zeros((labels.shape[0], labels.shape[1]), dtype=np.uint8) pix[np.where(labels==lab)] = 255 rect = cv2.minAreaRect(cv2.findNonZero(pix)) box = np.int0(cv2.boxPoints(rect)) labdraw = cv2.drawContours(labdraw, [box], 0, randcolor, 2) labdraw = cv2.circle(labdraw, (int(centroids[lab][0]),int(centroids[lab][1])), radius=5, color=(random.randint(0,255), random.randint(0,255), random.randint(0,255)), thickness=-1) cv2.imshow(names, labdraw) return labdraw def rotate_image(mat: np.ndarray, angle: float) -> np.ndarray: """ Rotates an image (angle in degrees) and expands image to avoid cropping # https://stackoverflow.com/questions/43892506/opencv-python-rotate-image-without-cropping-sides """ height, width = mat.shape[:2] # image shape has 3 dimensions image_center = (width/2, height/2) # getRotationMatrix2D needs coordinates in reverse order (width, height) compared to shape rotation_mat = cv2.getRotationMatrix2D(image_center, angle, 1.) # rotation calculates the cos and sin, taking absolutes of those. abs_cos = abs(rotation_mat[0,0]) abs_sin = abs(rotation_mat[0,1]) # find the new width and height bounds bound_w = int(height * abs_sin + width * abs_cos) bound_h = int(height * abs_cos + width * abs_sin) # subtract old image center (bringing image back to origo) and adding the new image center coordinates rotation_mat[0, 2] += bound_w/2 - image_center[0] rotation_mat[1, 2] += bound_h/2 - image_center[1] # rotate image with the new bounds and translated rotation matrix rotated_mat = cv2.warpAffine(mat, rotation_mat, (bound_w, bound_h)) return rotated_mat def color_difference(rgb1: List, rgb2: List) -> float: # https://en.wikipedia.org/wiki/Color_difference#CIE76 color1 = np.array(rgb1, dtype=np.uint8).reshape(1, 1, 3) color2 = np.array(rgb2, dtype=np.uint8).reshape(1, 1, 3) diff = cv2.cvtColor(color1, cv2.COLOR_RGB2LAB).astype(np.float64) - cv2.cvtColor(color2, cv2.COLOR_RGB2LAB).astype(np.float64) diff[..., 0] *= 0.392 diff = np.linalg.norm(diff, axis=2) return diff.item() def extract_ballon_region(img: np.ndarray, ballon_rect: List, show_process=False, enlarge_ratio=2.0, cal_region_rect=False) -> Tuple[np.ndarray, int, List]: WHITE = (255, 255, 255) BLACK = (0, 0, 0) x1, y1, x2, y2 = ballon_rect[0], ballon_rect[1], \ ballon_rect[2] + ballon_rect[0], ballon_rect[3] + ballon_rect[1] if enlarge_ratio > 1: x1, y1, x2, y2 = enlarge_window([x1, y1, x2, y2], img.shape[1], img.shape[0], enlarge_ratio, aspect_ratio=ballon_rect[3] / ballon_rect[2]) img = img[y1:y2, x1:x2].copy() kernel = np.ones((3,3),np.uint8) orih, oriw = img.shape[0], img.shape[1] scaleR = 1 if orih > 300 and oriw > 300: scaleR = 0.6 elif orih < 120 or oriw < 120: scaleR = 1.4 if scaleR != 1: h, w = img.shape[0], img.shape[1] orimg = np.copy(img) img = cv2.resize(img, (int(w*scaleR), int(h*scaleR)), interpolation=cv2.INTER_AREA) h, w = img.shape[0], img.shape[1] img_area = h * w cpimg = cv2.GaussianBlur(img,(3,3),cv2.BORDER_DEFAULT) detected_edges = cv2.Canny(cpimg, 70, 140, L2gradient=True, apertureSize=3) cv2.rectangle(detected_edges, (0, 0), (w-1, h-1), WHITE, 1, cv2.LINE_8) cons, hiers = cv2.findContours(detected_edges, cv2.RETR_CCOMP, cv2.CHAIN_APPROX_NONE) cv2.rectangle(detected_edges, (0, 0), (w-1, h-1), BLACK, 1, cv2.LINE_8) ballon_mask, outer_index = np.zeros((h, w), np.uint8), -1 min_retval = np.inf mask = np.zeros((h, w), np.uint8) difres = 10 seedpnt = (int(w/2), int(h/2)) for ii in range(len(cons)): rect = cv2.boundingRect(cons[ii]) if rect[2]*rect[3] < img_area*0.4: continue mask = cv2.drawContours(mask, cons, ii, (255), 2) cpmask = np.copy(mask) cv2.rectangle(mask, (0, 0), (w-1, h-1), WHITE, 1, cv2.LINE_8) retval, _, _, rect = cv2.floodFill(cpmask, mask=None, seedPoint=seedpnt, flags=4, newVal=(127), loDiff=(difres, difres, difres), upDiff=(difres, difres, difres)) if retval <= img_area * 0.3: mask = cv2.drawContours(mask, cons, ii, (0), 2) if retval < min_retval and retval > img_area * 0.3: min_retval = retval ballon_mask = cpmask ballon_mask = 127 - ballon_mask ballon_mask = cv2.dilate(ballon_mask, kernel,iterations = 1) ballon_area, _, _, rect = cv2.floodFill(ballon_mask, mask=None, seedPoint=seedpnt, flags=4, newVal=(30), loDiff=(difres, difres, difres), upDiff=(difres, difres, difres)) ballon_mask = 30 - ballon_mask retval, ballon_mask = cv2.threshold(ballon_mask, 1, 255, cv2.THRESH_BINARY) ballon_mask = cv2.bitwise_not(ballon_mask, ballon_mask) box_kernel = int(np.sqrt(ballon_area) / 30) if box_kernel > 1: box_kernel = np.ones((box_kernel,box_kernel),np.uint8) ballon_mask = cv2.dilate(ballon_mask, box_kernel, iterations = 1) ballon_mask = cv2.erode(ballon_mask, box_kernel, iterations = 1) if scaleR != 1: img = orimg ballon_mask = cv2.resize(ballon_mask, (oriw, orih)) if show_process: cv2.imshow('ballon_mask', ballon_mask) cv2.imshow('img', img) cv2.waitKey(0) if cal_region_rect: return ballon_mask, (ballon_mask > 0).sum(), [x1, y1, x2, y2], cv2.boundingRect(ballon_mask) return ballon_mask, (ballon_mask > 0).sum(), [x1, y1, x2, y2] def square_pad_resize(img: np.ndarray, tgt_size: int): h, w = img.shape[:2] pad_h, pad_w = 0, 0 # make square image if w < h: pad_w = h - w w += pad_w elif h < w: pad_h = w - h h += pad_h pad_size = tgt_size - h if pad_size > 0: pad_h += pad_size pad_w += pad_size if pad_h > 0 or pad_w > 0: img = cv2.copyMakeBorder(img, 0, pad_h, 0, pad_w, cv2.BORDER_CONSTANT) down_scale_ratio = tgt_size / img.shape[0] assert down_scale_ratio <= 1 if down_scale_ratio < 1: img = cv2.resize(img, (tgt_size, tgt_size), interpolation=cv2.INTER_AREA) return img, down_scale_ratio, pad_h, pad_w def get_block_mask(xywh: List, mask_array: np.ndarray, angle: int): x, y, w, h = xywh im_h, im_w = mask_array.shape[:2] if angle != 0: cx, cy = x + int(round(w / 2)), y + int(round(h / 2)) poly = xywh2xyxypoly(np.array([[x, y, w, h]])) poly = rotate_polygons([cx, cy], poly, -angle) x1, x2 = np.min(poly[..., ::2]), np.max(poly[..., ::2]) y1, y2 = np.min(poly[..., 1::2]), np.max(poly[..., 1::2]) if x2 < 0 or x2 - x1 < 2 or x1 >= im_w - 1 \ or y2 < 0 or y2 - y1 < 2 or y1 >= im_h - 1: return None, None else: poly[..., ::2] -= cx - int((x2 - x1) / 2) poly[..., 1::2] -= cy - int((y2 - y1) / 2) itmsk = np.zeros((y2 - y1, x2 - x1), np.uint8) cv2.fillPoly(itmsk, poly.reshape(-1, 4, 2), color=(255)) px1, px2, py1, py2 = 0, itmsk.shape[1], 0, itmsk.shape[0] if x1 < 0: px1 = -x1 x1 = 0 if x2 > im_w: px2 = im_w - x2 x2 = im_w if y1 < 0: py1 = -y1 y1 = 0 if y2 > im_h: py2 = im_h - y2 y2 = im_h itmsk = itmsk[py1: py2, px1: px2] msk = cv2.bitwise_and(mask_array[y1: y2, x1: x2], itmsk) else: x1, y1, x2, y2 = x, y, x+w, y+h if x2 < 0 or x2 - x1 < 2 or x1 >= im_w - 1 \ or y2 < 0 or y2 - y1 < 2 or y1 >= im_h - 1: return None, None else: if x1 < 0: x1 = 0 if x2 > im_w: x2 = im_w if y1 < 0: y1 = 0 if y2 > im_h: y2 = im_h msk = mask_array[y1: y2, x1: x2] return msk, [x1, y1, x2, y2]