242 lines
9.8 KiB
Python
242 lines
9.8 KiB
Python
# This file is modified based on `evaluate_hr.py` from [RobustVideoMatting](https://github.com/PeterL1n/RobustVideoMatting)
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# Changes:
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# - Adapted for CRGNN dataset
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# - Supported metrics: pha_mad, pha_mse, pha_grad, pha_dtssd
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"""
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HR (High-Resolution) evaluation. We found using numpy is very slow for high resolution, so we moved it to PyTorch using CUDA.
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Note, the script only does evaluation. You will need to first inference yourself and save the results to disk
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Expected directory format for both prediction and ground-truth is:
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crgnn
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├── video1
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├── pha
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├── 0000.png
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├── video2
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├── pha
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├── 0000.png
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Prediction must have the exact file structure and file name as the ground-truth,
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except for the file extension.
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Example usage:
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python evaluation/eval_crgnn.py \
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--pred-dir ./data/results/crgnn \
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--true-dir ./data/crgnn/alpha
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An excel sheet with evaluation results will be written to "PATH_TO_PREDICTIONS/crgnn.xlsx"
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"""
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import argparse
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import os
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import cv2
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import kornia
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import numpy as np
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import xlsxwriter
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import torch
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from concurrent.futures import ThreadPoolExecutor
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from tqdm import tqdm
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class Evaluator:
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def __init__(self):
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self.parse_args()
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self.init_metrics()
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self.evaluate()
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self.write_excel()
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def parse_args(self):
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parser = argparse.ArgumentParser()
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parser.add_argument('--pred-dir', type=str, required=True)
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parser.add_argument('--true-dir', type=str, required=True)
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parser.add_argument('--num-workers', type=int, default=48)
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parser.add_argument('--metrics', type=str, nargs='+', default=[
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'pha_mad', 'pha_mse', 'pha_grad', 'pha_dtssd'])
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self.args = parser.parse_args()
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def init_metrics(self):
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self.mad = MetricMAD()
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self.mse = MetricMSE()
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self.grad = MetricGRAD()
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self.dtssd = MetricDTSSD()
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def evaluate(self):
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tasks = []
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position = 0
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with ThreadPoolExecutor(max_workers=self.args.num_workers) as executor:
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for video_folder in sorted(os.listdir(self.args.pred_dir)):
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pred_video_path = os.path.join(self.args.pred_dir, video_folder)
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true_video_path = os.path.join(self.args.true_dir, video_folder)
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if os.path.isdir(pred_video_path) and os.path.isdir(true_video_path):
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future = executor.submit(self.evaluate_worker, video_folder, position)
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tasks.append((video_folder, future))
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position += 1
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self.results = [(video_folder, future.result()) for video_folder, future in tasks]
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def write_excel(self):
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workbook = xlsxwriter.Workbook(os.path.join(self.args.pred_dir, f'{os.path.basename(self.args.pred_dir)}.xlsx'))
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summarysheet = workbook.add_worksheet('summary')
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metricsheets = [workbook.add_worksheet(metric) for metric in self.results[0][-1].keys()]
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for i, metric in enumerate(self.results[0][-1].keys()):
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summarysheet.write(i, 0, metric)
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summarysheet.write(i, 1, f'={metric}!B2')
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for row, (video_folder, metrics) in enumerate(self.results):
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for metricsheet, metric in zip(metricsheets, metrics.values()):
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# Write the header
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if row == 0:
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metricsheet.write(1, 0, 'Average')
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metricsheet.write(1, 1, f'=AVERAGE(C2:ZZ2)')
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for col in range(len(metric)):
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metricsheet.write(0, col + 2, col)
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colname = xlsxwriter.utility.xl_col_to_name(col + 2)
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metricsheet.write(1, col + 2, f'=AVERAGE({colname}3:{colname}9999)')
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metricsheet.write(row + 2, 0, video_folder)
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metricsheet.write_row(row + 2, 1, metric)
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workbook.close()
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def evaluate_worker(self, video_folder, position):
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pred_pha_dir = os.path.join(self.args.pred_dir, video_folder, 'pha')
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true_pha_dir = os.path.join(self.args.true_dir, video_folder)
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# Get sorted filenames from both directories
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pred_framenames = sorted([f for f in os.listdir(pred_pha_dir) if os.path.isfile(os.path.join(pred_pha_dir, f))])
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true_framenames = sorted([f for f in os.listdir(true_pha_dir) if os.path.isfile(os.path.join(true_pha_dir, f))])
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# true-dir contains frames at every 10 frames (frame 1, 11, 21, ...)
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# pred-dir contains all frames (frame 0, 1, 2, 3, ...)
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# Match: true frame i (which is video frame i*10) corresponds to pred frame i*10
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num_true_frames = len(true_framenames)
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num_pred_frames = len(pred_framenames)
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if num_true_frames == 0:
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print(f'Warning: {video_folder} has no true frames')
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return {metric_name : [] for metric_name in self.args.metrics}
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print(f'Info: {video_folder} has {num_pred_frames} pred frames and {num_true_frames} true frames (every 10 frames)')
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print(f' First few pred files: {pred_framenames[:5]}')
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print(f' First few true files: {true_framenames[:5]}')
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metrics = {metric_name : [] for metric_name in self.args.metrics}
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pred_pha_tm1 = None
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true_pha_tm1 = None
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for true_idx in tqdm(range(num_true_frames), desc=video_folder, position=position, dynamic_ncols=True):
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# true frame at index true_idx corresponds to video frame true_idx * 10
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# pred frame at index pred_idx = true_idx * 10
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pred_idx = true_idx * 10
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if pred_idx >= num_pred_frames:
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print(f'Warning: {video_folder} true frame {true_idx} (video frame {pred_idx}) exceeds pred frames ({num_pred_frames})')
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break
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pred_pha_path = os.path.join(pred_pha_dir, pred_framenames[pred_idx])
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true_pha_path = os.path.join(true_pha_dir, true_framenames[true_idx])
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# Print the matched pair
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print(f' [{video_folder}] Pair {true_idx}: pred[{pred_idx}]="{pred_framenames[pred_idx]}" <-> true[{true_idx}]="{true_framenames[true_idx]}"')
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pred_pha = cv2.imread(pred_pha_path, cv2.IMREAD_GRAYSCALE)
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true_pha = cv2.imread(true_pha_path, cv2.IMREAD_GRAYSCALE)
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if pred_pha is None or true_pha is None:
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print(f'Warning: Failed to read image at true_idx {true_idx} (pred_idx {pred_idx}) in {video_folder}')
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continue
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true_pha = torch.from_numpy(true_pha).cuda(non_blocking=True).float().div_(255)
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pred_pha = torch.from_numpy(pred_pha).cuda(non_blocking=True).float().div_(255)
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if 'pha_mad' in self.args.metrics:
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metrics['pha_mad'].append(self.mad(pred_pha, true_pha))
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if 'pha_mse' in self.args.metrics:
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metrics['pha_mse'].append(self.mse(pred_pha, true_pha))
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if 'pha_grad' in self.args.metrics:
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metrics['pha_grad'].append(self.grad(pred_pha, true_pha))
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if 'pha_conn' in self.args.metrics:
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metrics['pha_conn'].append(self.conn(pred_pha, true_pha))
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if 'pha_dtssd' in self.args.metrics:
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if true_idx == 0:
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metrics['pha_dtssd'].append(0)
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else:
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metrics['pha_dtssd'].append(self.dtssd(pred_pha, pred_pha_tm1, true_pha, true_pha_tm1))
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pred_pha_tm1 = pred_pha
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true_pha_tm1 = true_pha
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return metrics
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class MetricMAD:
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def __call__(self, pred, true):
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return (pred - true).abs_().mean() * 1e3
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class MetricMSE:
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def __call__(self, pred, true):
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return ((pred - true) ** 2).mean() * 1e3
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class MetricGRAD:
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def __init__(self, sigma=1.4):
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self.filter_x, self.filter_y = self.gauss_filter(sigma)
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self.filter_x = torch.from_numpy(self.filter_x).unsqueeze(0).cuda()
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self.filter_y = torch.from_numpy(self.filter_y).unsqueeze(0).cuda()
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def __call__(self, pred, true):
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true_grad = self.gauss_gradient(true)
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pred_grad = self.gauss_gradient(pred)
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return ((true_grad - pred_grad) ** 2).sum() / 1000
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def gauss_gradient(self, img):
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img_filtered_x = kornia.filters.filter2d(img[None, None, :, :], self.filter_x, border_type='replicate')[0, 0]
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img_filtered_y = kornia.filters.filter2d(img[None, None, :, :], self.filter_y, border_type='replicate')[0, 0]
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return (img_filtered_x**2 + img_filtered_y**2).sqrt()
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@staticmethod
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def gauss_filter(sigma, epsilon=1e-2):
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half_size = np.ceil(sigma * np.sqrt(-2 * np.log(np.sqrt(2 * np.pi) * sigma * epsilon)))
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size = int(2 * half_size + 1)
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# create filter in x axis
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filter_x = np.zeros((size, size))
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for i in range(size):
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for j in range(size):
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filter_x[i, j] = MetricGRAD.gaussian(i - half_size, sigma) * MetricGRAD.dgaussian(
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j - half_size, sigma)
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# normalize filter
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norm = np.sqrt((filter_x**2).sum())
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filter_x = filter_x / norm
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filter_y = np.transpose(filter_x)
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return filter_x, filter_y
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@staticmethod
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def gaussian(x, sigma):
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return np.exp(-x**2 / (2 * sigma**2)) / (sigma * np.sqrt(2 * np.pi))
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@staticmethod
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def dgaussian(x, sigma):
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return -x * MetricGRAD.gaussian(x, sigma) / sigma**2
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class MetricDTSSD:
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def __call__(self, pred_t, pred_tm1, true_t, true_tm1):
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dtSSD = ((pred_t - pred_tm1) - (true_t - true_tm1)) ** 2
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dtSSD = dtSSD.sum() / true_t.numel()
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dtSSD = dtSSD.sqrt()
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return dtSSD * 1e2
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if __name__ == '__main__':
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Evaluator() |