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Zero
| # Copyright (c) Meta Platforms, Inc. and affiliates. | |
| # All rights reserved. | |
| # | |
| # This source code is licensed under the license found in the | |
| # LICENSE file in the root directory of this source tree. | |
| import os | |
| import warnings | |
| from typing import Optional, Sequence | |
| import torch | |
| import numpy as np | |
| import cv2 | |
| import mmcv | |
| import torchvision | |
| import torchvision.transforms as transforms | |
| import mmengine | |
| import mmengine.fileio as fileio | |
| from mmengine.hooks import Hook | |
| from mmengine.runner import Runner | |
| from mmengine.visualization import Visualizer | |
| from matplotlib import pyplot as plt | |
| from mmpose.registry import HOOKS | |
| from mmpose.structures import PoseDataSample, merge_data_samples | |
| from mmpose.registry import VISUALIZERS | |
| from mmengine.structures import InstanceData | |
| class GeneralPoseVisualizationHook(Hook): | |
| """ | |
| """ | |
| def __init__( | |
| self, | |
| enable: bool = False, | |
| interval: int = 50, | |
| kpt_thr: float = 0.3, | |
| show: bool = False, | |
| wait_time: float = 0., | |
| max_vis_samples: int = 16, | |
| scale: int = 4, | |
| line_width: int = 4, | |
| radius: int = 4, | |
| out_dir: Optional[str] = None, | |
| backend_args: Optional[dict] = None, | |
| ): | |
| self._visualizer: Visualizer = Visualizer.get_current_instance() | |
| self.interval = interval | |
| self.kpt_thr = kpt_thr | |
| self.show = show | |
| if self.show: | |
| # No need to think about vis backends. | |
| self._visualizer._vis_backends = {} | |
| warnings.warn('The show is True, it means that only ' | |
| 'the prediction results are visualized ' | |
| 'without storing data, so vis_backends ' | |
| 'needs to be excluded.') | |
| self.wait_time = wait_time | |
| self.enable = enable | |
| self.out_dir = out_dir | |
| self._test_index = 0 | |
| self.backend_args = backend_args | |
| self.max_vis_samples = max_vis_samples | |
| self.scale = scale | |
| self.init_visualizer = False | |
| self._visualizer.line_width = line_width | |
| self._visualizer.radius = radius | |
| return | |
| def after_train_iter(self, runner: Runner, batch_idx: int, data_batch: dict, | |
| outputs: Sequence[PoseDataSample]) -> None: | |
| """Run after every ``self.interval`` validation iterations. | |
| Args: | |
| runner (:obj:`Runner`): The runner of the validation process. | |
| batch_idx (int): The index of the current batch in the val loop. | |
| data_batch (dict): Data from dataloader. | |
| outputs (Sequence[:obj:`PoseDataSample`]): Outputs from model. | |
| """ | |
| if self.enable is False: | |
| return | |
| # ## check if the rank is 0 | |
| if not runner.rank == 0: | |
| return | |
| # There is no guarantee that the same batch of images | |
| # is visualized for each evaluation. | |
| total_curr_iter = runner.iter | |
| if total_curr_iter % self.interval != 0: | |
| return | |
| ## we divide by 255 to be compatible with the visualization functions | |
| image = torch.cat([input.unsqueeze(dim=0)/255 for input in data_batch['inputs']], dim=0) ## B x 3 x H x W, not normalized in BGR format | |
| output = outputs['vis_preds'].detach() ## B x 17 x H x W | |
| batch_size = min(self.max_vis_samples, len(image)) | |
| if self.init_visualizer == False: | |
| self._visualizer.set_dataset_meta(runner.train_dataloader.dataset.metainfo) ## this sets the skeleton and skeleton links colors | |
| self.init_visualizer = True | |
| image = image[:batch_size] | |
| output = output[:batch_size] | |
| target = [] | |
| for i in range(batch_size): | |
| target.append(data_batch['data_samples'][i].get('gt_fields').get('heatmaps').unsqueeze(dim=0)) | |
| target = torch.cat(target, dim=0) | |
| target_weight = [] | |
| for i in range(batch_size): | |
| target_weight.append(data_batch['data_samples'][i].get('gt_instance_labels').get('keypoints_visible').unsqueeze(dim=0)) | |
| target_weight = torch.cat(target_weight, dim=0) | |
| ##------------------------------------ | |
| vis_dir = os.path.join(runner.work_dir, 'vis_data') | |
| if not os.path.exists(vis_dir): | |
| os.makedirs(vis_dir, exist_ok=True) | |
| prefix = os.path.join(vis_dir, 'train') | |
| suffix = str(total_curr_iter).zfill(6) | |
| original_image = image | |
| self.save_batch_heatmaps(original_image, target, '{}_{}_hm_gt.jpg'.format(prefix, suffix), normalize=False, scale=self.scale, is_rgb=False) | |
| self.save_batch_heatmaps(original_image, output, '{}_{}_hm_pred.jpg'.format(prefix, suffix), normalize=False, scale=self.scale, is_rgb=False) | |
| self.save_batch_image_with_joints(255*original_image, target, target_weight, '{}_{}_gt.jpg'.format(prefix, suffix), scale=self.scale, is_rgb=False) | |
| self.save_batch_image_with_joints(255*original_image, output, torch.ones_like(target_weight), '{}_{}_pred.jpg'.format(prefix, suffix), scale=self.scale, is_rgb=False) | |
| return | |
| def save_batch_heatmaps(self, batch_image, batch_heatmaps, file_name, normalize=True, scale=4, is_rgb=True, max_num_joints=17): | |
| ''' | |
| batch_image: [batch_size, channel, height, width] | |
| batch_heatmaps: ['batch_size, num_joints, height, width] | |
| file_name: saved file name | |
| ''' | |
| ## normalize image | |
| if normalize: | |
| batch_image = batch_image.clone() | |
| min_val = float(batch_image.min()) | |
| max_val = float(batch_image.max()) | |
| batch_image.add_(-min_val).div_(max_val - min_val + 1e-5) | |
| ## check if type of batch_heatmaps is numpy.ndarray | |
| if isinstance(batch_heatmaps, np.ndarray): | |
| preds, maxvals = get_max_preds(batch_heatmaps) | |
| batch_heatmaps = torch.from_numpy(batch_heatmaps) | |
| else: | |
| preds, maxvals = get_max_preds(batch_heatmaps.detach().cpu().numpy()) | |
| preds = preds*scale ## scale to original image size | |
| batch_size = batch_heatmaps.size(0) | |
| num_joints = batch_heatmaps.size(1) | |
| heatmap_height = int(batch_heatmaps.size(2)*scale) | |
| heatmap_width = int(batch_heatmaps.size(3)*scale) | |
| num_joints = min(max_num_joints, num_joints) | |
| grid_image = np.zeros((batch_size*heatmap_height, | |
| (num_joints+1)*heatmap_width, | |
| 3), | |
| dtype=np.uint8) | |
| body_joint_order = range(max_num_joints) | |
| for i in range(batch_size): | |
| image = batch_image[i].mul(255)\ | |
| .clamp(0, 255)\ | |
| .byte()\ | |
| .permute(1, 2, 0)\ | |
| .cpu().numpy() | |
| heatmaps = batch_heatmaps[i].mul(255)\ | |
| .clamp(0, 255)\ | |
| .byte()\ | |
| .cpu().numpy() | |
| if is_rgb == True: | |
| image = cv2.cvtColor(image, cv2.COLOR_RGB2BGR) | |
| resized_image = cv2.resize(image, (int(heatmap_width), int(heatmap_height))) | |
| height_begin = heatmap_height * i | |
| height_end = heatmap_height * (i + 1) | |
| for j in range(num_joints): | |
| joint_index = body_joint_order[j] | |
| cv2.circle(resized_image, | |
| (int(preds[i][joint_index][0]), int(preds[i][joint_index][1])), | |
| 1, [0, 0, 255], 1) | |
| heatmap = heatmaps[joint_index, :, :] | |
| colored_heatmap = cv2.applyColorMap(heatmap, cv2.COLORMAP_JET) | |
| colored_heatmap = cv2.resize(colored_heatmap, (int(heatmap_width), int(heatmap_height))) | |
| masked_image = colored_heatmap*0.7 + resized_image*0.3 | |
| cv2.circle(masked_image, | |
| (int(preds[i][joint_index][0]), int(preds[i][joint_index][1])), | |
| 1, [0, 0, 255], 1) | |
| width_begin = heatmap_width * (j+1) | |
| width_end = heatmap_width * (j+2) | |
| grid_image[height_begin:height_end, width_begin:width_end, :] = \ | |
| masked_image | |
| grid_image[height_begin:height_end, 0:heatmap_width, :] = resized_image | |
| cv2.imwrite(file_name, grid_image) | |
| return | |
| def save_batch_image_with_joints(self, batch_image, batch_heatmaps, batch_target_weight, file_name, dataset_info=None, is_rgb=True, scale=4, nrow=8, padding=2): | |
| ''' | |
| batch_image: [batch_size, channel, height, width] | |
| batch_joints: [batch_size, num_joints, 3], | |
| batch_joints_vis: [batch_size, num_joints, 1], | |
| } | |
| ''' | |
| B, C, H, W = batch_image.size() | |
| num_joints = batch_heatmaps.size(1) | |
| ## check if type of batch_heatmaps is numpy.ndarray | |
| if isinstance(batch_heatmaps, np.ndarray): | |
| batch_joints, batch_scores = get_max_preds(batch_heatmaps) | |
| else: | |
| batch_joints, batch_scores = get_max_preds(batch_heatmaps.detach().cpu().numpy()) | |
| batch_joints = batch_joints*scale ## 4 is the ratio of output heatmap and input image | |
| if isinstance(batch_joints, torch.Tensor): | |
| batch_joints = batch_joints.cpu().numpy() | |
| if isinstance(batch_target_weight, torch.Tensor): | |
| batch_target_weight = batch_target_weight.cpu().numpy() | |
| batch_target_weight = batch_target_weight.reshape(B, num_joints) ## B x 17 | |
| grid = [] | |
| for i in range(B): | |
| image = batch_image[i].permute(1, 2, 0).cpu().numpy() #image_size x image_size x BGR. if is_rgb is False. | |
| image = image.copy() | |
| kps = batch_joints[i] | |
| kps_vis = batch_target_weight[i] | |
| kps_score = batch_scores[i].reshape(-1) | |
| if is_rgb == False: | |
| image = cv2.cvtColor(image, cv2.COLOR_BGR2RGB) # convert bgr to rgb image | |
| instances = InstanceData(metainfo=dict(keypoints=[kps], keypoints_visible=[kps_vis], keypoint_scores=[kps_score])) | |
| kp_vis_image = self._visualizer._draw_instances_kpts(image, instances=instances) ## H, W, C, rgb image | |
| kp_vis_image = cv2.cvtColor(kp_vis_image, cv2.COLOR_RGB2BGR) ## convert rgb to bgr image | |
| kp_vis_image = kp_vis_image.transpose((2, 0, 1)).astype(np.float32) | |
| kp_vis_image = torch.from_numpy(kp_vis_image.copy()) | |
| grid.append(kp_vis_image) | |
| grid = torchvision.utils.make_grid(grid, nrow, padding) | |
| ndarr = grid.byte().permute(1, 2, 0).cpu().numpy() | |
| cv2.imwrite(file_name, ndarr) | |
| return | |
| ###------------------helpers----------------------- | |
| ###------------------------------------------------------ | |
| def batch_unnormalize_image(images, mean=[123.675, 116.28, 103.53], std=[58.395, 57.12, 57.375]): | |
| normalize = transforms.Normalize(mean=mean, std=std) | |
| images[:, 0, :, :] = (images[:, 0, :, :]*normalize.std[0]) + normalize.mean[0] | |
| images[:, 1, :, :] = (images[:, 1, :, :]*normalize.std[1]) + normalize.mean[1] | |
| images[:, 2, :, :] = (images[:, 2, :, :]*normalize.std[2]) + normalize.mean[2] | |
| return images | |
| def get_max_preds(batch_heatmaps): | |
| ''' | |
| get predictions from score maps | |
| heatmaps: numpy.ndarray([batch_size, num_joints, height, width]) | |
| ''' | |
| assert isinstance(batch_heatmaps, np.ndarray), \ | |
| 'batch_heatmaps should be numpy.ndarray' | |
| assert batch_heatmaps.ndim == 4, 'batch_images should be 4-ndim' | |
| batch_size = batch_heatmaps.shape[0] | |
| num_joints = batch_heatmaps.shape[1] | |
| width = batch_heatmaps.shape[3] | |
| heatmaps_reshaped = batch_heatmaps.reshape((batch_size, num_joints, -1)) | |
| idx = np.argmax(heatmaps_reshaped, 2) ## B x 17 | |
| maxvals = np.amax(heatmaps_reshaped, 2) ## B x 17 | |
| maxvals = maxvals.reshape((batch_size, num_joints, 1)) ## B x 17 x 1 | |
| idx = idx.reshape((batch_size, num_joints, 1)) ## B x 17 x 1 | |
| preds = np.tile(idx, (1, 1, 2)).astype(np.float32) ## B x 17 x 2, like repeat in pytorch | |
| preds[:, :, 0] = (preds[:, :, 0]) % width | |
| preds[:, :, 1] = np.floor((preds[:, :, 1]) / width) | |
| pred_mask = np.tile(np.greater(maxvals, 0.0), (1, 1, 2)) | |
| pred_mask = pred_mask.astype(np.float32) | |
| preds *= pred_mask | |
| return preds, maxvals | |
| # ------------------------------------------------------------------------------------ | |