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# Copyright (c) 2022 PaddlePaddle Authors. All Rights Reserved.
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#
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# Licensed under the Apache License, Version 2.0 (the "License");
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# you may not use this file except in compliance with the License.
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# You may obtain a copy of the License at
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#
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# http://www.apache.org/licenses/LICENSE-2.0
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#
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# Unless required by applicable law or agreed to in writing, software
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# distributed under the License is distributed on an "AS IS" BASIS,
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# WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied.
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# See the License for the specific language governing permissions and
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# limitations under the License.
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import sys
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import os
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import time
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import math
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import chardet
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import json
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import numpy as np
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from . import logging
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import platform
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import paddlers
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def seconds_to_hms(seconds):
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h = math.floor(seconds / 3600)
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m = math.floor((seconds - h * 3600) / 60)
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s = int(seconds - h * 3600 - m * 60)
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hms_str = "{}:{}:{}".format(h, m, s)
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return hms_str
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def get_encoding(path):
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f = open(path, 'rb')
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data = f.read()
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file_encoding = chardet.detect(data).get('encoding')
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f.close()
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return file_encoding
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def get_single_card_bs(batch_size):
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card_num = paddlers.env_info['num']
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place = paddlers.env_info['place']
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if batch_size % card_num == 0:
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return int(batch_size // card_num)
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elif batch_size == 1:
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# Evaluation of detection task only supports single card with batch size 1
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return batch_size
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else:
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raise Exception("Please support correct batch_size, \
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which can be divided by available cards({}) in {}"
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.format(card_num, place))
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def dict2str(dict_input):
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out = ''
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for k, v in dict_input.items():
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try:
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v = '{:8.6f}'.format(float(v))
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except:
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pass
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out = out + '{}={}, '.format(k, v)
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return out.strip(', ')
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def path_normalization(path):
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win_sep = "\\"
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other_sep = "/"
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if platform.system() == "Windows":
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path = win_sep.join(path.split(other_sep))
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else:
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path = other_sep.join(path.split(win_sep))
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return path
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def is_pic(img_name):
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valid_suffix = ['JPEG', 'jpeg', 'JPG', 'jpg', 'BMP', 'bmp', 'PNG', 'png', 'tiff']
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suffix = img_name.split('.')[-1]
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if suffix not in valid_suffix:
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return False
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return True
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class MyEncoder(json.JSONEncoder):
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def default(self, obj):
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if isinstance(obj, np.integer):
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return int(obj)
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elif isinstance(obj, np.floating):
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return float(obj)
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elif isinstance(obj, np.ndarray):
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return obj.tolist()
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else:
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return super(MyEncoder, self).default(obj)
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class EarlyStop:
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def __init__(self, patience, thresh):
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self.patience = patience
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self.counter = 0
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self.score = None
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self.max = 0
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self.thresh = thresh
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if patience < 1:
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raise Exception("Argument patience should be a positive integer.")
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def __call__(self, current_score):
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if self.score is None:
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self.score = current_score
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return False
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elif current_score > self.max:
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self.counter = 0
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self.score = current_score
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self.max = current_score
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return False
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else:
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if (abs(self.score - current_score) < self.thresh or
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current_score < self.score):
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self.counter += 1
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self.score = current_score
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logging.debug("EarlyStopping: %i / %i" %
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(self.counter, self.patience))
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if self.counter >= self.patience:
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logging.info("EarlyStopping: Stop training")
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return True
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return False
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else:
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self.counter = 0
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self.score = current_score
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return False
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class DisablePrint(object):
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def __enter__(self):
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self._original_stdout = sys.stdout
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sys.stdout = open(os.devnull, 'w')
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def __exit__(self, exc_type, exc_val, exc_tb):
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sys.stdout.close()
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sys.stdout = self._original_stdout
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class Times(object):
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def __init__(self):
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self.time = 0.
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# start time
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self.st = 0.
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# end time
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self.et = 0.
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def start(self):
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self.st = time.time()
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def end(self, iter_num=1, accumulative=True):
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self.et = time.time()
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if accumulative:
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self.time += (self.et - self.st) / iter_num
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else:
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self.time = (self.et - self.st) / iter_num
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def reset(self):
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self.time = 0.
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self.st = 0.
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self.et = 0.
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def value(self):
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return round(self.time, 4)
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class Timer(Times):
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def __init__(self):
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super(Timer, self).__init__()
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self.preprocess_time_s = Times()
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self.inference_time_s = Times()
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self.postprocess_time_s = Times()
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self.img_num = 0
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self.repeats = 0
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def info(self, average=False):
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total_time = self.preprocess_time_s.value(
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) * self.img_num + self.inference_time_s.value(
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) + self.postprocess_time_s.value() * self.img_num
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total_time = round(total_time, 4)
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print("------------------ Inference Time Info ----------------------")
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print("total_time(ms): {}, img_num: {}, batch_size: {}".format(
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total_time * 1000, self.img_num, self.img_num))
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preprocess_time = round(
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self.preprocess_time_s.value() / self.repeats,
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4) if average else self.preprocess_time_s.value()
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postprocess_time = round(
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self.postprocess_time_s.value() / self.repeats,
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4) if average else self.postprocess_time_s.value()
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inference_time = round(self.inference_time_s.value() / self.repeats,
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4) if average else self.inference_time_s.value()
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average_latency = total_time / self.repeats
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print("average latency time(ms): {:.2f}, QPS: {:2f}".format(
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average_latency * 1000, 1 / average_latency))
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print("preprocess_time_per_im(ms): {:.2f}, "
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"inference_time_per_batch(ms): {:.2f}, "
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"postprocess_time_per_im(ms): {:.2f}".format(
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preprocess_time * 1000, inference_time * 1000,
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postprocess_time * 1000))
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def report(self, average=False):
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dic = {}
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dic['preprocess_time_s'] = round(
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self.preprocess_time_s.value() / self.repeats,
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4) if average else self.preprocess_time_s.value()
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dic['postprocess_time_s'] = round(
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self.postprocess_time_s.value() / self.repeats,
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4) if average else self.postprocess_time_s.value()
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dic['inference_time_s'] = round(
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self.inference_time_s.value() / self.repeats,
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4) if average else self.inference_time_s.value()
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dic['img_num'] = self.img_num
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total_time = self.preprocess_time_s.value(
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) + self.inference_time_s.value() + self.postprocess_time_s.value()
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dic['total_time_s'] = round(total_time, 4)
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dic['batch_size'] = self.img_num / self.repeats
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return dic
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def reset(self):
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self.preprocess_time_s.reset()
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self.inference_time_s.reset()
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self.postprocess_time_s.reset()
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self.img_num = 0
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self.repeats = 0
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