# Copyright (c) 2020 PaddlePaddle Authors. All Rights Reserved. # # Licensed under the Apache License, Version 2.0 (the "License"); # you may not use this file except in compliance with the License. # You may obtain a copy of the License at # # http://www.apache.org/licenses/LICENSE-2.0 # # Unless required by applicable law or agreed to in writing, software # distributed under the License is distributed on an "AS IS" BASIS, # WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied. # See the License for the specific language governing permissions and # limitations under the License. from __future__ import absolute_import from __future__ import division from __future__ import print_function import cv2 import os import numpy as np import base64 import sys from . import functional as F from PIL import Image, ImageDraw from shapely.geometry import Polygon import pyclipper import json _cv2_interpolation_to_str = {cv2.INTER_LINEAR: "cv2.INTER_LINEAR", None: "None"} py_version = sys.version_info[0] if py_version == 2: import urllib else: import urllib.request as urllib def generate_colormap(num_classes): color_map = num_classes * [0, 0, 0] for i in range(0, num_classes): j = 0 lab = i while lab: color_map[i * 3] |= (((lab >> 0) & 1) << (7 - j)) color_map[i * 3 + 1] |= (((lab >> 1) & 1) << (7 - j)) color_map[i * 3 + 2] |= (((lab >> 2) & 1) << (7 - j)) j += 1 lab >>= 3 color_map = [color_map[i:i + 3] for i in range(0, len(color_map), 3)] return color_map class DBPostProcess(object): """ The post process for Differentiable Binarization (DB). """ def __init__(self, params): self.thresh = params['thresh'] self.box_thresh = params['box_thresh'] self.max_candidates = params['max_candidates'] self.unclip_ratio = params['unclip_ratio'] self.min_size = 3 def boxes_from_bitmap(self, pred, _bitmap, dest_width, dest_height): ''' _bitmap: single map with shape (1, H, W), whose values are binarized as {0, 1} ''' bitmap = _bitmap height, width = bitmap.shape outs = cv2.findContours((bitmap * 255).astype(np.uint8), cv2.RETR_LIST, cv2.CHAIN_APPROX_SIMPLE) if len(outs) == 3: img, contours, _ = outs[0], outs[1], outs[2] elif len(outs) == 2: contours, _ = outs[0], outs[1] num_contours = min(len(contours), self.max_candidates) boxes = np.zeros((num_contours, 4, 2), dtype=np.int16) scores = np.zeros((num_contours, ), dtype=np.float32) for index in range(num_contours): contour = contours[index] points, sside = self.get_mini_boxes(contour) if sside < self.min_size: continue points = np.array(points) score = self.box_score_fast(pred, points.reshape(-1, 2)) if self.box_thresh > score: continue box = self.unclip(points).reshape(-1, 1, 2) box, sside = self.get_mini_boxes(box) if sside < self.min_size + 2: continue box = np.array(box) if not isinstance(dest_width, int): dest_width = dest_width.item() dest_height = dest_height.item() box[:, 0] = np.clip( np.round(box[:, 0] / width * dest_width), 0, dest_width) box[:, 1] = np.clip( np.round(box[:, 1] / height * dest_height), 0, dest_height) boxes[index, :, :] = box.astype(np.int16) scores[index] = score return boxes, scores def unclip(self, box): unclip_ratio = self.unclip_ratio poly = Polygon(box) distance = poly.area * unclip_ratio / poly.length offset = pyclipper.PyclipperOffset() offset.AddPath(box, pyclipper.JT_ROUND, pyclipper.ET_CLOSEDPOLYGON) expanded = np.array(offset.Execute(distance)) return expanded def get_mini_boxes(self, contour): bounding_box = cv2.minAreaRect(contour) points = sorted(list(cv2.boxPoints(bounding_box)), key=lambda x: x[0]) index_1, index_2, index_3, index_4 = 0, 1, 2, 3 if points[1][1] > points[0][1]: index_1 = 0 index_4 = 1 else: index_1 = 1 index_4 = 0 if points[3][1] > points[2][1]: index_2 = 2 index_3 = 3 else: index_2 = 3 index_3 = 2 box = [ points[index_1], points[index_2], points[index_3], points[index_4] ] return box, min(bounding_box[1]) def box_score_fast(self, bitmap, _box): h, w = bitmap.shape[:2] box = _box.copy() xmin = np.clip(np.floor(box[:, 0].min()).astype(np.int32), 0, w - 1) xmax = np.clip(np.ceil(box[:, 0].max()).astype(np.int32), 0, w - 1) ymin = np.clip(np.floor(box[:, 1].min()).astype(np.int32), 0, h - 1) ymax = np.clip(np.ceil(box[:, 1].max()).astype(np.int32), 0, h - 1) mask = np.zeros((ymax - ymin + 1, xmax - xmin + 1), dtype=np.uint8) box[:, 0] = box[:, 0] - xmin box[:, 1] = box[:, 1] - ymin cv2.fillPoly(mask, box.reshape(1, -1, 2).astype(np.int32), 1) return cv2.mean(bitmap[ymin:ymax + 1, xmin:xmax + 1], mask)[0] def __call__(self, pred, ratio_list): pred = pred[:, 0, :, :] segmentation = pred > self.thresh boxes_batch = [] for batch_index in range(pred.shape[0]): height, width = pred.shape[-2:] tmp_boxes, tmp_scores = self.boxes_from_bitmap( pred[batch_index], segmentation[batch_index], width, height) boxes = [] for k in range(len(tmp_boxes)): if tmp_scores[k] > self.box_thresh: boxes.append(tmp_boxes[k]) if len(boxes) > 0: boxes = np.array(boxes) ratio_h, ratio_w = ratio_list[batch_index] boxes[:, :, 0] = boxes[:, :, 0] / ratio_w boxes[:, :, 1] = boxes[:, :, 1] / ratio_h boxes_batch.append(boxes) return boxes_batch def __repr__(self): return self.__class__.__name__ + \ " thresh: {1}, box_thresh: {2}, max_candidates: {3}, unclip_ratio: {4}, min_size: {5}".format( self.thresh, self.box_thresh, self.max_candidates, self.unclip_ratio, self.min_size) class FilterBoxes(object): def __init__(self, width, height): self.filter_width = width self.filter_height = height def order_points_clockwise(self, pts): """ reference from: https://github.com/jrosebr1/imutils/blob/master/imutils/perspective.py # sort the points based on their x-coordinates """ xSorted = pts[np.argsort(pts[:, 0]), :] # grab the left-most and right-most points from the sorted # x-roodinate points leftMost = xSorted[:2, :] rightMost = xSorted[2:, :] # now, sort the left-most coordinates according to their # y-coordinates so we can grab the top-left and bottom-left # points, respectively leftMost = leftMost[np.argsort(leftMost[:, 1]), :] (tl, bl) = leftMost rightMost = rightMost[np.argsort(rightMost[:, 1]), :] (tr, br) = rightMost rect = np.array([tl, tr, br, bl], dtype="float32") return rect def clip_det_res(self, points, img_height, img_width): for pno in range(4): points[pno, 0] = int(min(max(points[pno, 0], 0), img_width - 1)) points[pno, 1] = int(min(max(points[pno, 1], 0), img_height - 1)) return points def __call__(self, dt_boxes, image_shape): img_height, img_width = image_shape[0:2] dt_boxes_new = [] for box in dt_boxes: box = self.order_points_clockwise(box) box = self.clip_det_res(box, img_height, img_width) rect_width = int(np.linalg.norm(box[0] - box[1])) rect_height = int(np.linalg.norm(box[0] - box[3])) if rect_width <= self.filter_width or \ rect_height <= self.filter_height: continue dt_boxes_new.append(box) dt_boxes = np.array(dt_boxes_new) return dt_boxes def __repr__(self): return self.__class__.__name__ + " filter_width: {1}, filter_height: {2}".format( self.filter_width, self.filter_height) class SegPostprocess(object): def __init__(self, class_num): self.class_num = class_num def __call__(self, image_with_result): if "filename" not in image_with_result: raise ("filename should be specified in postprocess") img_name = image_with_result["filename"] ori_img = cv2.imread(img_name, -1) ori_shape = ori_img.shape mask = None for key in image_with_result: if ".lod" in key or "filename" in key: continue mask = image_with_result[key] if mask is None: raise ("segment mask should be specified in postprocess") mask = mask.astype("uint8") mask_png = mask.reshape((512, 512, 1)) #score_png = mask_png[:, :, np.newaxis] score_png = mask_png score_png = np.concatenate([score_png] * 3, axis=2) color_map = generate_colormap(self.class_num) for i in range(score_png.shape[0]): for j in range(score_png.shape[1]): score_png[i, j] = color_map[score_png[i, j, 0]] ext_pos = img_name.rfind(".") img_name_fix = img_name[:ext_pos] + "_" + img_name[ext_pos + 1:] mask_save_name = img_name_fix + "_mask.png" cv2.imwrite(mask_save_name, mask_png, [cv2.CV_8UC1]) vis_result_name = img_name_fix + "_result.png" result_png = score_png result_png = cv2.resize( result_png, (ori_shape[1], ori_shape[0]), fx=0, fy=0, interpolation=cv2.INTER_CUBIC) cv2.imwrite(vis_result_name, result_png, [cv2.CV_8UC1]) class RCNNPostprocess(object): def __init__(self, label_file, output_dir, resize_shape=None): self.output_dir = output_dir self.label_file = label_file self.label_list = [] self.resize_shape = resize_shape with open(label_file) as fin: for line in fin: self.label_list.append(line.strip()) self.clsid2catid = {i: i for i in range(len(self.label_list))} self.catid2name = {i: name for i, name in enumerate(self.label_list)} def _offset_to_lengths(self, lod): offset = lod[0] lengths = [offset[i + 1] - offset[i] for i in range(len(offset) - 1)] return [lengths] def _bbox2out(self, results, clsid2catid, is_bbox_normalized=False): xywh_res = [] for t in results: bboxes = t['bbox'][0] lengths = t['bbox'][1][0] if bboxes.shape == (1, 1) or bboxes is None: continue k = 0 for i in range(len(lengths)): num = lengths[i] for j in range(num): dt = bboxes[k] clsid, score, xmin, ymin, xmax, ymax = dt.tolist() catid = (clsid2catid[int(clsid)]) if is_bbox_normalized: xmin, ymin, xmax, ymax = \ self.clip_bbox([xmin, ymin, xmax, ymax]) w = xmax - xmin h = ymax - ymin im_shape = t['im_shape'].tolist() im_height, im_width = int(im_shape[0]), int(im_shape[1]) xmin *= im_width ymin *= im_height w *= im_width h *= im_height else: w = xmax - xmin + 1 h = ymax - ymin + 1 bbox = [xmin, ymin, w, h] coco_res = { 'category_id': catid, 'bbox': bbox, 'score': score } xywh_res.append(coco_res) k += 1 return xywh_res def _get_bbox_result(self, fetch_map, fetch_name, clsid2catid): result = {} is_bbox_normalized = False output = fetch_map[fetch_name] lod = [fetch_map[fetch_name + '.lod']] lengths = self._offset_to_lengths(lod) np_data = np.array(output) result['bbox'] = (np_data, lengths) result['im_id'] = np.array([[0]]) bbox_results = self._bbox2out([result], clsid2catid, is_bbox_normalized) return bbox_results def color_map(self, num_classes): color_map = num_classes * [0, 0, 0] for i in range(0, num_classes): j = 0 lab = i while lab: color_map[i * 3] |= (((lab >> 0) & 1) << (7 - j)) color_map[i * 3 + 1] |= (((lab >> 1) & 1) << (7 - j)) color_map[i * 3 + 2] |= (((lab >> 2) & 1) << (7 - j)) j += 1 lab >>= 3 color_map = np.array(color_map).reshape(-1, 3) return color_map def draw_bbox(self, image, catid2name, bboxes, threshold, color_list): """ draw bbox on image """ draw = ImageDraw.Draw(image) for dt in np.array(bboxes): catid, bbox, score = dt['category_id'], dt['bbox'], dt['score'] if score < threshold: continue xmin, ymin, w, h = bbox xmax = xmin + w ymax = ymin + h img_w, img_h = image.size if self.resize_shape is not None: xmin = xmin * img_w / self.resize_shape[0] xmax = xmax * img_w / self.resize_shape[0] ymin = ymin * img_h / self.resize_shape[1] ymax = ymax * img_h / self.resize_shape[1] color = tuple(color_list[catid]) # draw bbox draw.line( [(xmin, ymin), (xmin, ymax), (xmax, ymax), (xmax, ymin), (xmin, ymin)], width=2, fill=color) # draw label text = "{} {:.2f}".format(catid2name[catid], score) tw, th = draw.textsize(text) draw.rectangle( [(xmin + 1, ymin - th), (xmin + tw + 1, ymin)], fill=color) draw.text((xmin + 1, ymin - th), text, fill=(255, 255, 255)) return image def visualize(self, infer_img, bbox_results, catid2name, num_classes): image = Image.open(infer_img).convert('RGB') color_list = self.color_map(num_classes) image = self.draw_bbox(image, self.catid2name, bbox_results, 0.5, color_list) image_path = os.path.split(infer_img)[-1] if not os.path.exists(self.output_dir): os.makedirs(self.output_dir) out_path = os.path.join(self.output_dir, image_path) image.save(out_path, quality=95) def __call__(self, image_with_bbox, visualize=True): fetch_name = "" for key in image_with_bbox: if key == "image": continue if ".lod" in key or "im_shape" in key: continue fetch_name = key bbox_result = self._get_bbox_result(image_with_bbox, fetch_name, self.clsid2catid) if os.path.isdir(self.output_dir) is False: os.mkdir(self.output_dir) if visualize is False: return bbox_result self.visualize(image_with_bbox["image"], bbox_result, self.catid2name, len(self.label_list)) if os.path.isdir(self.output_dir) is False: os.mkdir(self.output_dir) bbox_file = os.path.join(self.output_dir, 'bbox.json') with open(bbox_file, 'w') as f: json.dump(bbox_result, f, indent=4) return bbox_result def __repr__(self): return self.__class__.__name__ + "label_file: {1}, output_dir: {2}".format( self.label_file, self.output_dir) class BlazeFacePostprocess(RCNNPostprocess): def clip_bbox(self, bbox, im_size=None): h = 1. if im_size is None else im_size[0] w = 1. if im_size is None else im_size[1] xmin = max(min(bbox[0], w), 0.) ymin = max(min(bbox[1], h), 0.) xmax = max(min(bbox[2], w), 0.) ymax = max(min(bbox[3], h), 0.) return xmin, ymin, xmax, ymax def _get_bbox_result(self, fetch_map, fetch_name, clsid2catid): result = {} is_bbox_normalized = True #for blaze face, set true here output = fetch_map[fetch_name] lod = [fetch_map[fetch_name + '.lod']] lengths = self._offset_to_lengths(lod) np_data = np.array(output) result['bbox'] = (np_data, lengths) result['im_id'] = np.array([[0]]) result["im_shape"] = np.array(fetch_map["im_shape"]).astype(np.int32) bbox_results = self._bbox2out([result], clsid2catid, is_bbox_normalized) return bbox_results class Sequential(object): """ Args: sequence (sequence of ``Transform`` objects): list of transforms to chain. This API references some of the design pattern of torchvision Users can simply use this API in training as well Example: >>> image_reader.Sequnece([ >>> transforms.CenterCrop(10), >>> ]) """ def __init__(self, transforms): self.transforms = transforms def __call__(self, img): for t in self.transforms: img = t(img) return img def __repr__(self): format_string_ = self.__class__.__name__ + '(' for t in self.transforms: format_string_ += '\n' format_string_ += ' {0}'.format(t) format_string_ += '\n)' return format_string_ class RGB2BGR(object): def __init__(self): pass def __call__(self, img): return img[:, :, ::-1] def __repr__(self): return self.__class__.__name__ + "()" class BGR2RGB(object): def __init__(self): pass def __call__(self, img): return img[:, :, ::-1] def __repr__(self): return self.__class__.__name__ + "()" class String2Image(object): def __init__(self): pass def __call__(self, img_buffer): data = np.fromstring(img_buffer, np.uint8) img = cv2.imdecode(data, cv2.IMREAD_COLOR) return img def __repr__(self): return self.__class__.__name__ + "()" class File2Image(object): def __init__(self): pass def __call__(self, img_path): if py_version == 2: fin = open(img_path) else: fin = open(img_path, "rb") sample = fin.read() data = np.fromstring(sample, np.uint8) img = cv2.imdecode(data, cv2.IMREAD_COLOR) ''' img = cv2.imread(img_path, -1) channels = img.shape[2] ori_h = img.shape[0] ori_w = img.shape[1] ''' return img def __repr__(self): return self.__class__.__name__ + "()" class URL2Image(object): def __init__(self): pass def __call__(self, img_url): resp = urllib.urlopen(img_url) sample = resp.read() data = np.fromstring(sample, np.uint8) img = cv2.imdecode(data, cv2.IMREAD_COLOR) return img def __repr__(self): return self.__class__.__name__ + "()" class Base64ToImage(object): def __init__(self): pass def __call__(self, img_base64): sample = base64.b64decode(img_base64) data = np.fromstring(sample, np.uint8) img = cv2.imdecode(data, cv2.IMREAD_COLOR) return img def __repr__(self): return self.__class__.__name__ + "()" class Div(object): """ divide by some float number """ def __init__(self, value): self.value = value def __call__(self, img): """ Args: img (numpy array): (int8 numpy array) Returns: img (numpy array): (float32 numpy array) """ img = img.astype('float32') / self.value return img def __repr__(self): return self.__class__.__name__ + "({})".format(self.value) class Normalize(object): """Normalize a tensor image with mean and standard deviation. Given mean: ``(M1,...,Mn)`` and std: ``(S1,..,Sn)`` for ``n`` channels, this transform will normalize each channel of the input ``torch.*Tensor`` i.e. ``output[channel] = (input[channel] - mean[channel]) / std[channel]`` .. note:: This transform acts out of place, i.e., it does not mutate the input tensor. Args: mean (sequence): Sequence of means for each channel. std (sequence): Sequence of standard deviations for each channel. """ def __init__(self, mean, std, channel_first=False): self.mean = mean self.std = std self.channel_first = channel_first def __call__(self, img): """ Args: img (numpy array): (C, H, W) to be normalized. Returns: Tensor: Normalized Tensor image. """ return F.normalize(img, self.mean, self.std, self.channel_first) def __repr__(self): return self.__class__.__name__ + '(mean={0}, std={1})'.format(self.mean, self.std) class Lambda(object): """Apply a user-defined lambda as a transform. Very shame to just copy from https://github.com/pytorch/vision/blob/master/torchvision/transforms/transforms.py#L301 Args: lambd (function): Lambda/function to be used for transform. """ def __init__(self, lambd): assert callable(lambd), repr(type(lambd) .__name__) + " object is not callable" self.lambd = lambd def __call__(self, img): return self.lambd(img) def __repr__(self): return self.__class__.__name__ + '()' class CenterCrop(object): """Crops the given Image at the center. Args: size (sequence or int): Desired output size of the crop. If size is an int instead of sequence like (h, w), a square crop (size, size) is made. """ def __init__(self, size): self.size = size def __call__(self, img): """ Args: img (numpy array): Image to be cropped. Returns: numpy array Image: Cropped image. """ return F.crop(img, self.size, True) def __repr__(self): return self.__class__.__name__ + '(size={0})'.format(self.size) class Resize(object): """Resize the input numpy array Image to the given size. Args: size (sequence or int): Desired output size. If size is a sequence like (w, h), output size will be matched to this. If size is an int, smaller edge of the image will be matched to this number. i.e, if height > width, then image will be rescaled to (size * height / width, size) interpolation (int, optional): Desired interpolation. Default is ``None`` """ def __init__(self, size, max_size=2147483647, interpolation=None): self.size = size self.max_size = max_size self.interpolation = interpolation def __call__(self, img): return F.resize(img, self.size, self.max_size, self.interpolation) def __repr__(self): return self.__class__.__name__ + '(size={0}, max_size={1}, interpolation={2})'.format( self.size, self.max_size, _cv2_interpolation_to_str[self.interpolation]) class ResizeByFactor(object): """Resize the input numpy array Image to a size multiple of factor which is usually required by a network Args: factor (int): Resize factor. make width and height multiple factor of the value of factor. Default is 32 max_side_len (int): max size of width and height. if width or height is larger than max_side_len, just resize the width or the height. Default is 2400 """ def __init__(self, factor=32, max_side_len=2400): self.factor = factor self.max_side_len = max_side_len def __call__(self, img): h, w, _ = img.shape resize_w = w resize_h = h if max(resize_h, resize_w) > self.max_side_len: if resize_h > resize_w: ratio = float(self.max_side_len) / resize_h else: ratio = float(self.max_side_len) / resize_w else: ratio = 1. resize_h = int(resize_h * ratio) resize_w = int(resize_w * ratio) if resize_h % self.factor == 0: resize_h = resize_h elif resize_h // self.factor <= 1: resize_h = self.factor else: resize_h = (resize_h // 32 - 1) * 32 if resize_w % self.factor == 0: resize_w = resize_w elif resize_w // self.factor <= 1: resize_w = self.factor else: resize_w = (resize_w // self.factor - 1) * self.factor try: if int(resize_w) <= 0 or int(resize_h) <= 0: return None, (None, None) im = cv2.resize(img, (int(resize_w), int(resize_h))) except: print(resize_w, resize_h) sys.exit(0) return im def __repr__(self): return self.__class__.__name__ + '(factor={0}, max_side_len={1})'.format( self.factor, self.max_side_len) class PadStride(object): def __init__(self, stride): self.coarsest_stride = stride def __call__(self, img): coarsest_stride = self.coarsest_stride if coarsest_stride == 0: return img im_c, im_h, im_w = img.shape pad_h = int(np.ceil(float(im_h) / coarsest_stride) * coarsest_stride) pad_w = int(np.ceil(float(im_w) / coarsest_stride) * coarsest_stride) padding_im = np.zeros((im_c, pad_h, pad_w), dtype=np.float32) padding_im[:, :im_h, :im_w] = img im_info = {} im_info['resize_shape'] = padding_im.shape[1:] return padding_im class Transpose(object): def __init__(self, transpose_target): self.transpose_target = transpose_target def __call__(self, img): return F.transpose(img, self.transpose_target) return img def __repr__(self): format_string = self.__class__.__name__ + \ "({})".format(self.transpose_target) return format_string class SortedBoxes(object): """ Sorted bounding boxes from Detection """ def __init__(self): pass def __call__(self, dt_boxes): num_boxes = dt_boxes.shape[0] sorted_boxes = sorted(dt_boxes, key=lambda x: (x[0][1], x[0][0])) _boxes = list(sorted_boxes) for i in range(num_boxes - 1): if abs(_boxes[i+1][0][1] - _boxes[i][0][1]) < 10 and \ (_boxes[i + 1][0][0] < _boxes[i][0][0]): tmp = _boxes[i] _boxes[i] = _boxes[i + 1] _boxes[i + 1] = tmp return _boxes class GetRotateCropImage(object): """ Rotate and Crop image from OCR Det output """ def __init__(self): pass def __call__(self, img, points): img_height, img_width = img.shape[0:2] left = int(np.min(points[:, 0])) right = int(np.max(points[:, 0])) top = int(np.min(points[:, 1])) bottom = int(np.max(points[:, 1])) img_crop = img[top:bottom, left:right, :].copy() points[:, 0] = points[:, 0] - left points[:, 1] = points[:, 1] - top img_crop_width = int(np.linalg.norm(points[0] - points[1])) img_crop_height = int(np.linalg.norm(points[0] - points[3])) pts_std = np.float32([[0, 0], [img_crop_width, 0], \ [img_crop_width, img_crop_height], [0, img_crop_height]]) M = cv2.getPerspectiveTransform(points, pts_std) dst_img = cv2.warpPerspective( img_crop, M, (img_crop_width, img_crop_height), borderMode=cv2.BORDER_REPLICATE) dst_img_height, dst_img_width = dst_img.shape[0:2] if dst_img_height * 1.0 / dst_img_width >= 1.5: dst_img = np.rot90(dst_img) return dst_img class ImageReader(): def __init__(self, image_shape=[3, 224, 224], image_mean=[0.485, 0.456, 0.406], image_std=[0.229, 0.224, 0.225], resize_short_size=256, interpolation=None, crop_center=True): self.image_mean = image_mean self.image_std = image_std self.image_shape = image_shape self.resize_short_size = resize_short_size self.interpolation = interpolation self.crop_center = crop_center def resize_short(self, img, target_size, interpolation=None): """resize image Args: img: image data target_size: resize short target size interpolation: interpolation mode Returns: resized image data """ percent = float(target_size) / min(img.shape[0], img.shape[1]) resized_width = int(round(img.shape[1] * percent)) resized_height = int(round(img.shape[0] * percent)) if interpolation: resized = cv2.resize( img, (resized_width, resized_height), interpolation=interpolation) else: resized = cv2.resize(img, (resized_width, resized_height)) return resized def crop_image(self, img, target_size, center): """crop image Args: img: images data target_size: crop target size center: crop mode Returns: img: cropped image data """ height, width = img.shape[:2] size = target_size if center == True: w_start = (width - size) // 2 h_start = (height - size) // 2 else: w_start = np.random.randint(0, width - size + 1) h_start = np.random.randint(0, height - size + 1) w_end = w_start + size h_end = h_start + size img = img[h_start:h_end, w_start:w_end, :] return img def process_image(self, sample): """ process_image """ mean = self.image_mean std = self.image_std crop_size = self.image_shape[1] data = np.fromstring(sample, np.uint8) img = cv2.imdecode(data, cv2.IMREAD_COLOR) if img is None: print("img is None, pass it.") return None if crop_size > 0: target_size = self.resize_short_size img = self.resize_short( img, target_size, interpolation=self.interpolation) img = self.crop_image( img, target_size=crop_size, center=self.crop_center) img = img[:, :, ::-1] img = img.astype('float32').transpose((2, 0, 1)) / 255 img_mean = np.array(mean).reshape((3, 1, 1)) img_std = np.array(std).reshape((3, 1, 1)) img -= img_mean img /= img_std return img