# 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. import argparse import os, sys from ppocr.utils.utility import initial_logger logger = initial_logger() from paddle.fluid.core import PaddleTensor from paddle.fluid.core import AnalysisConfig from paddle.fluid.core import create_paddle_predictor import cv2 import numpy as np import json from PIL import Image, ImageDraw, ImageFont import math def parse_args(): def str2bool(v): return v.lower() in ("true", "t", "1") parser = argparse.ArgumentParser() #params for prediction engine parser.add_argument("--use_gpu", type=str2bool, default=True) parser.add_argument("--ir_optim", type=str2bool, default=True) parser.add_argument("--use_tensorrt", type=str2bool, default=False) parser.add_argument("--gpu_mem", type=int, default=8000) #params for text detector parser.add_argument("--image_dir", type=str) parser.add_argument("--det_algorithm", type=str, default='DB') parser.add_argument("--det_model_dir", type=str) parser.add_argument("--det_max_side_len", type=float, default=960) #DB parmas parser.add_argument("--det_db_thresh", type=float, default=0.3) parser.add_argument("--det_db_box_thresh", type=float, default=0.5) parser.add_argument("--det_db_unclip_ratio", type=float, default=2.0) #EAST parmas parser.add_argument("--det_east_score_thresh", type=float, default=0.8) parser.add_argument("--det_east_cover_thresh", type=float, default=0.1) parser.add_argument("--det_east_nms_thresh", type=float, default=0.2) #SAST parmas parser.add_argument("--det_sast_score_thresh", type=float, default=0.5) parser.add_argument("--det_sast_nms_thresh", type=float, default=0.2) parser.add_argument("--det_sast_polygon", type=bool, default=False) #params for text recognizer parser.add_argument("--rec_algorithm", type=str, default='CRNN') parser.add_argument("--rec_model_dir", type=str) parser.add_argument("--rec_image_shape", type=str, default="3, 32, 320") parser.add_argument("--rec_char_type", type=str, default='ch') parser.add_argument("--rec_batch_num", type=int, default=30) parser.add_argument("--max_text_length", type=int, default=25) parser.add_argument( "--rec_char_dict_path", type=str, default="./ppocr/utils/ppocr_keys_v1.txt") parser.add_argument("--use_space_char", type=bool, default=True) parser.add_argument("--enable_mkldnn", type=bool, default=False) parser.add_argument("--use_zero_copy_run", type=bool, default=False) return parser.parse_args() def create_predictor(args, mode): if mode == "det": model_dir = args.det_model_dir else: model_dir = args.rec_model_dir if model_dir is None: logger.info("not find {} model file path {}".format(mode, model_dir)) sys.exit(0) model_file_path = model_dir + "/model" params_file_path = model_dir + "/params" if not os.path.exists(model_file_path): logger.info("not find model file path {}".format(model_file_path)) sys.exit(0) if not os.path.exists(params_file_path): logger.info("not find params file path {}".format(params_file_path)) sys.exit(0) config = AnalysisConfig(model_file_path, params_file_path) if args.use_gpu: config.enable_use_gpu(args.gpu_mem, 0) else: config.disable_gpu() config.set_cpu_math_library_num_threads(6) if args.enable_mkldnn: config.enable_mkldnn() #config.enable_memory_optim() config.disable_glog_info() if args.use_zero_copy_run: config.delete_pass("conv_transpose_eltwiseadd_bn_fuse_pass") config.switch_use_feed_fetch_ops(False) else: config.switch_use_feed_fetch_ops(True) predictor = create_paddle_predictor(config) input_names = predictor.get_input_names() input_tensor = predictor.get_input_tensor(input_names[0]) output_names = predictor.get_output_names() output_tensors = [] for output_name in output_names: output_tensor = predictor.get_output_tensor(output_name) output_tensors.append(output_tensor) return predictor, input_tensor, output_tensors def draw_text_det_res(dt_boxes, img_path): src_im = cv2.imread(img_path) for box in dt_boxes: box = np.array(box).astype(np.int32).reshape(-1, 2) cv2.polylines(src_im, [box], True, color=(255, 255, 0), thickness=2) return src_im def resize_img(img, input_size=600): """ resize img and limit the longest side of the image to input_size """ img = np.array(img) im_shape = img.shape im_size_max = np.max(im_shape[0:2]) im_scale = float(input_size) / float(im_size_max) im = cv2.resize(img, None, None, fx=im_scale, fy=im_scale) return im def draw_ocr(image, boxes, txts, scores, draw_txt=True, drop_score=0.5): """ Visualize the results of OCR detection and recognition args: image(Image|array): RGB image boxes(list): boxes with shape(N, 4, 2) txts(list): the texts scores(list): txxs corresponding scores draw_txt(bool): whether draw text or not drop_score(float): only scores greater than drop_threshold will be visualized return(array): the visualized img """ if scores is None: scores = [1] * len(boxes) for (box, score) in zip(boxes, scores): if score < drop_score or math.isnan(score): continue box = np.reshape(np.array(box), [-1, 1, 2]).astype(np.int64) image = cv2.polylines(np.array(image), [box], True, (255, 0, 0), 2) if draw_txt: img = np.array(resize_img(image, input_size=600)) txt_img = text_visual( txts, scores, img_h=img.shape[0], img_w=600, threshold=drop_score) img = np.concatenate([np.array(img), np.array(txt_img)], axis=1) return img return image def draw_ocr_box_txt(image, boxes, txts): h, w = image.height, image.width img_left = image.copy() img_right = Image.new('RGB', (w, h), (255, 255, 255)) import random random.seed(0) draw_left = ImageDraw.Draw(img_left) draw_right = ImageDraw.Draw(img_right) for (box, txt) in zip(boxes, txts): color = (random.randint(0, 255), random.randint(0, 255), random.randint(0, 255)) draw_left.polygon(box, fill=color) draw_right.polygon( [ box[0][0], box[0][1], box[1][0], box[1][1], box[2][0], box[2][1], box[3][0], box[3][1] ], outline=color) box_height = math.sqrt((box[0][0] - box[3][0])**2 + (box[0][1] - box[3][ 1])**2) box_width = math.sqrt((box[0][0] - box[1][0])**2 + (box[0][1] - box[1][ 1])**2) if box_height > 2 * box_width: font_size = max(int(box_width * 0.9), 10) font = ImageFont.truetype( "./doc/simfang.ttf", font_size, encoding="utf-8") cur_y = box[0][1] for c in txt: char_size = font.getsize(c) draw_right.text( (box[0][0] + 3, cur_y), c, fill=(0, 0, 0), font=font) cur_y += char_size[1] else: font_size = max(int(box_height * 0.8), 10) font = ImageFont.truetype( "./doc/simfang.ttf", font_size, encoding="utf-8") draw_right.text( [box[0][0], box[0][1]], txt, fill=(0, 0, 0), font=font) img_left = Image.blend(image, img_left, 0.5) img_show = Image.new('RGB', (w * 2, h), (255, 255, 255)) img_show.paste(img_left, (0, 0, w, h)) img_show.paste(img_right, (w, 0, w * 2, h)) return np.array(img_show) def str_count(s): """ Count the number of Chinese characters, a single English character and a single number equal to half the length of Chinese characters. args: s(string): the input of string return(int): the number of Chinese characters """ import string count_zh = count_pu = 0 s_len = len(s) en_dg_count = 0 for c in s: if c in string.ascii_letters or c.isdigit() or c.isspace(): en_dg_count += 1 elif c.isalpha(): count_zh += 1 else: count_pu += 1 return s_len - math.ceil(en_dg_count / 2) def text_visual(texts, scores, img_h=400, img_w=600, threshold=0.): """ create new blank img and draw txt on it args: texts(list): the text will be draw scores(list|None): corresponding score of each txt img_h(int): the height of blank img img_w(int): the width of blank img return(array): """ if scores is not None: assert len(texts) == len( scores), "The number of txts and corresponding scores must match" def create_blank_img(): blank_img = np.ones(shape=[img_h, img_w], dtype=np.int8) * 255 blank_img[:, img_w - 1:] = 0 blank_img = Image.fromarray(blank_img).convert("RGB") draw_txt = ImageDraw.Draw(blank_img) return blank_img, draw_txt blank_img, draw_txt = create_blank_img() font_size = 20 txt_color = (0, 0, 0) font = ImageFont.truetype("./doc/simfang.ttf", font_size, encoding="utf-8") gap = font_size + 5 txt_img_list = [] count, index = 1, 0 for idx, txt in enumerate(texts): index += 1 if scores[idx] < threshold or math.isnan(scores[idx]): index -= 1 continue first_line = True while str_count(txt) >= img_w // font_size - 4: tmp = txt txt = tmp[:img_w // font_size - 4] if first_line: new_txt = str(index) + ': ' + txt first_line = False else: new_txt = ' ' + txt draw_txt.text((0, gap * count), new_txt, txt_color, font=font) txt = tmp[img_w // font_size - 4:] if count >= img_h // gap - 1: txt_img_list.append(np.array(blank_img)) blank_img, draw_txt = create_blank_img() count = 0 count += 1 if first_line: new_txt = str(index) + ': ' + txt + ' ' + '%.3f' % (scores[idx]) else: new_txt = " " + txt + " " + '%.3f' % (scores[idx]) draw_txt.text((0, gap * count), new_txt, txt_color, font=font) # whether add new blank img or not if count >= img_h // gap - 1 and idx + 1 < len(texts): txt_img_list.append(np.array(blank_img)) blank_img, draw_txt = create_blank_img() count = 0 count += 1 txt_img_list.append(np.array(blank_img)) if len(txt_img_list) == 1: blank_img = np.array(txt_img_list[0]) else: blank_img = np.concatenate(txt_img_list, axis=1) return np.array(blank_img) def base64_to_cv2(b64str): import base64 data = base64.b64decode(b64str.encode('utf8')) data = np.fromstring(data, np.uint8) data = cv2.imdecode(data, cv2.IMREAD_COLOR) return data def draw_boxes(image, boxes, scores=None, drop_score=0.5): if scores is None: scores = [1] * len(boxes) for (box, score) in zip(boxes, scores): if score < drop_score: continue box = np.reshape(np.array(box), [-1, 1, 2]).astype(np.int64) image = cv2.polylines(np.array(image), [box], True, (255, 0, 0), 2) return image if __name__ == '__main__': test_img = "./doc/test_v2" predict_txt = "./doc/predict.txt" f = open(predict_txt, 'r') data = f.readlines() img_path, anno = data[0].strip().split('\t') img_name = os.path.basename(img_path) img_path = os.path.join(test_img, img_name) image = Image.open(img_path) data = json.loads(anno) boxes, txts, scores = [], [], [] for dic in data: boxes.append(dic['points']) txts.append(dic['transcription']) scores.append(round(dic['scores'], 3)) new_img = draw_ocr(image, boxes, txts, scores, draw_txt=True) cv2.imwrite(img_name, new_img)