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| # 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 numpy as np | |
| import imageio | |
| import torch | |
| from matplotlib import cm | |
| import torch.nn.functional as F | |
| import torchvision.transforms as transforms | |
| import matplotlib.pyplot as plt | |
| from PIL import Image, ImageDraw | |
| # import av | |
| # import decord | |
| import torchvision | |
| from einops import rearrange | |
| def read_video_from_path(path): | |
| # try: | |
| # reader = imageio.get_reader(path) | |
| # except Exception as e: | |
| # print("Error opening video file: ", e) | |
| # return None | |
| # frames = [] | |
| # for i, im in enumerate(reader): | |
| # frames.append(np.array(im)) | |
| # return np.stack(frames) | |
| # # read videe using decord | |
| # video = decord.VideoReader(path) | |
| # frames = video.get_batch(range(len(video))) | |
| # frames = [frame.asnumpy() for frame in frames] | |
| # return np.stack(frames) | |
| # read video using torchvision | |
| vframes, aframes, info = torchvision.io.read_video(filename=path, pts_unit='sec', output_format='THWC') | |
| vframes = vframes.numpy() | |
| return vframes | |
| def draw_circle(rgb, coord, radius, color=(255, 0, 0), visible=True): | |
| # Create a draw object | |
| draw = ImageDraw.Draw(rgb) | |
| # Calculate the bounding box of the circle | |
| left_up_point = (coord[0] - radius, coord[1] - radius) | |
| right_down_point = (coord[0] + radius, coord[1] + radius) | |
| # Draw the circle | |
| draw.ellipse( | |
| [left_up_point, right_down_point], | |
| fill=tuple(color) if visible else None, | |
| outline=tuple(color), | |
| ) | |
| return rgb | |
| def draw_line(rgb, coord_y, coord_x, color, linewidth): | |
| draw = ImageDraw.Draw(rgb) | |
| draw.line( | |
| (coord_y[0], coord_y[1], coord_x[0], coord_x[1]), | |
| fill=tuple(color), | |
| width=linewidth, | |
| ) | |
| return rgb | |
| def add_weighted(rgb, alpha, original, beta, gamma): | |
| return (rgb * alpha + original * beta + gamma).astype("uint8") | |
| class Visualizer: | |
| def __init__( | |
| self, | |
| save_dir: str = "./results", | |
| grayscale: bool = False, | |
| pad_value: int = 0, | |
| fps: int = 10, | |
| mode: str = "rainbow", # 'cool', 'optical_flow' | |
| linewidth: int = 2, | |
| show_first_frame: int = 10, | |
| tracks_leave_trace: int = 0, # -1 for infinite | |
| ): | |
| self.mode = mode | |
| self.save_dir = save_dir | |
| if mode == "rainbow": | |
| self.color_map = cm.get_cmap("gist_rainbow") | |
| elif mode == "cool": | |
| self.color_map = cm.get_cmap(mode) | |
| self.show_first_frame = show_first_frame | |
| self.grayscale = grayscale | |
| self.tracks_leave_trace = tracks_leave_trace | |
| self.pad_value = pad_value | |
| self.linewidth = linewidth | |
| self.fps = fps | |
| def visualize( | |
| self, | |
| video: torch.Tensor, # (B,T,C,H,W) | |
| tracks: torch.Tensor, # (B,T,N,2) | |
| visibility: torch.Tensor = None, # (B, T, N, 1) bool | |
| gt_tracks: torch.Tensor = None, # (B,T,N,2) | |
| segm_mask: torch.Tensor = None, # (B,1,H,W) | |
| filename: str = "video", | |
| writer=None, # tensorboard Summary Writer, used for visualization during training | |
| step: int = 0, | |
| query_frame: int = 0, | |
| save_video: bool = True, | |
| compensate_for_camera_motion: bool = False, | |
| ): | |
| if compensate_for_camera_motion: | |
| assert segm_mask is not None | |
| if segm_mask is not None: | |
| coords = tracks[0, query_frame].round().long() | |
| segm_mask = segm_mask[0, query_frame][coords[:, 1], coords[:, 0]].long() | |
| video = F.pad( | |
| video, | |
| (self.pad_value, self.pad_value, self.pad_value, self.pad_value), | |
| "constant", | |
| 255, | |
| ) | |
| tracks = tracks + self.pad_value | |
| if self.grayscale: | |
| transform = transforms.Grayscale() | |
| video = transform(video) | |
| video = video.repeat(1, 1, 3, 1, 1) | |
| res_video = self.draw_tracks_on_video( | |
| video=video, | |
| tracks=tracks, | |
| visibility=visibility, | |
| segm_mask=segm_mask, | |
| gt_tracks=gt_tracks, | |
| query_frame=query_frame, | |
| compensate_for_camera_motion=compensate_for_camera_motion, | |
| ) | |
| if save_video: | |
| self.save_video(res_video, filename=filename, writer=writer, step=step) | |
| return res_video | |
| def save_video(self, video, filename, writer=None, step=0): | |
| if writer is not None: | |
| writer.add_video( | |
| filename, | |
| video.to(torch.uint8), | |
| global_step=step, | |
| fps=self.fps, | |
| ) | |
| else: | |
| os.makedirs(self.save_dir, exist_ok=True) | |
| # Prepare the video file path | |
| save_path = os.path.join(self.save_dir, f"{filename}.mp4") | |
| # save video using torchvision | |
| assert video.shape[0] == 1 | |
| video = rearrange(video[0], 'T C H W -> T H W C') | |
| torchvision.io.write_video(save_path, video, fps=self.fps) | |
| # wide_list = list(video.unbind(1)) | |
| # wide_list = [wide[0].permute(1, 2, 0).cpu().numpy() for wide in wide_list] | |
| # # Create a writer object | |
| # video_writer = imageio.get_writer(save_path, fps=self.fps) | |
| # # Write frames to the video file | |
| # for frame in wide_list[2:-1]: | |
| # video_writer.append_data(frame) | |
| # video_writer.close() | |
| # # pyav | |
| # container = av.open(save_path, mode="w") | |
| # stream = container.add_stream("h264", rate=self.fps) | |
| # for frame in wide_list[2:-1]: | |
| # frame = Image.fromarray(frame) | |
| # frame = np.array(frame) | |
| # frame = av.VideoFrame.from_ndarray(frame, format="rgb24") | |
| # for packet in stream.encode(frame): | |
| # container.mux(packet) | |
| print(f"Video saved to {save_path}") | |
| def draw_tracks_on_video( | |
| self, | |
| video: torch.Tensor, | |
| tracks: torch.Tensor, | |
| visibility: torch.Tensor = None, | |
| segm_mask: torch.Tensor = None, | |
| gt_tracks=None, | |
| query_frame: int = 0, | |
| compensate_for_camera_motion=False, | |
| ): | |
| B, T, C, H, W = video.shape | |
| _, _, N, D = tracks.shape | |
| assert D == 2 | |
| assert C == 3 | |
| video = video[0].permute(0, 2, 3, 1).byte().detach().cpu().numpy() # S, H, W, C | |
| tracks = tracks[0].long().detach().cpu().numpy() # S, N, 2 | |
| if gt_tracks is not None: | |
| gt_tracks = gt_tracks[0].detach().cpu().numpy() | |
| res_video = [] | |
| # process input video | |
| for rgb in video: | |
| res_video.append(rgb.copy()) | |
| vector_colors = np.zeros((T, N, 3)) | |
| # define vector colors | |
| if self.mode == "optical_flow": | |
| import flow_vis | |
| vector_colors = flow_vis.flow_to_color(tracks - tracks[query_frame][None]) | |
| elif segm_mask is None: | |
| if self.mode == "rainbow": | |
| y_min, y_max = ( | |
| tracks[query_frame, :, 1].min(), | |
| tracks[query_frame, :, 1].max(), | |
| ) | |
| norm = plt.Normalize(y_min, y_max) | |
| for n in range(N): | |
| color = self.color_map(norm(tracks[query_frame, n, 1])) | |
| color = np.array(color[:3])[None] * 255 | |
| vector_colors[:, n] = np.repeat(color, T, axis=0) | |
| else: | |
| # color changes with time | |
| for t in range(T): | |
| color = np.array(self.color_map(t / T)[:3])[None] * 255 | |
| vector_colors[t] = np.repeat(color, N, axis=0) | |
| else: | |
| if self.mode == "rainbow": | |
| vector_colors[:, segm_mask <= 0, :] = 255 | |
| y_min, y_max = ( | |
| tracks[0, segm_mask > 0, 1].min(), | |
| tracks[0, segm_mask > 0, 1].max(), | |
| ) | |
| norm = plt.Normalize(y_min, y_max) | |
| for n in range(N): | |
| if segm_mask[n] > 0: | |
| color = self.color_map(norm(tracks[0, n, 1])) | |
| color = np.array(color[:3])[None] * 255 | |
| vector_colors[:, n] = np.repeat(color, T, axis=0) | |
| else: | |
| # color changes with segm class | |
| segm_mask = segm_mask.cpu() | |
| color = np.zeros((segm_mask.shape[0], 3), dtype=np.float32) | |
| color[segm_mask > 0] = np.array(self.color_map(1.0)[:3]) * 255.0 | |
| color[segm_mask <= 0] = np.array(self.color_map(0.0)[:3]) * 255.0 | |
| vector_colors = np.repeat(color[None], T, axis=0) | |
| # draw tracks | |
| if self.tracks_leave_trace != 0: | |
| for t in range(query_frame + 1, T): | |
| first_ind = ( | |
| max(0, t - self.tracks_leave_trace) if self.tracks_leave_trace >= 0 else 0 | |
| ) | |
| curr_tracks = tracks[first_ind : t + 1] | |
| curr_colors = vector_colors[first_ind : t + 1] | |
| if compensate_for_camera_motion: | |
| diff = ( | |
| tracks[first_ind : t + 1, segm_mask <= 0] | |
| - tracks[t : t + 1, segm_mask <= 0] | |
| ).mean(1)[:, None] | |
| curr_tracks = curr_tracks - diff | |
| curr_tracks = curr_tracks[:, segm_mask > 0] | |
| curr_colors = curr_colors[:, segm_mask > 0] | |
| res_video[t] = self._draw_pred_tracks( | |
| res_video[t], | |
| curr_tracks, | |
| curr_colors, | |
| ) | |
| if gt_tracks is not None: | |
| res_video[t] = self._draw_gt_tracks(res_video[t], gt_tracks[first_ind : t + 1]) | |
| # draw points | |
| for t in range(query_frame, T): | |
| img = Image.fromarray(np.uint8(res_video[t])) | |
| for i in range(N): | |
| coord = (tracks[t, i, 0], tracks[t, i, 1]) | |
| visibile = True | |
| if visibility is not None: | |
| visibile = visibility[0, t, i] | |
| if coord[0] != 0 and coord[1] != 0: | |
| if not compensate_for_camera_motion or ( | |
| compensate_for_camera_motion and segm_mask[i] > 0 | |
| ): | |
| img = draw_circle( | |
| img, | |
| coord=coord, | |
| radius=int(self.linewidth * 2), | |
| color=vector_colors[t, i].astype(int), | |
| visible=visibile, | |
| ) | |
| res_video[t] = np.array(img) | |
| # construct the final rgb sequence | |
| if self.show_first_frame > 0: | |
| res_video = [res_video[0]] * self.show_first_frame + res_video[1:] | |
| return torch.from_numpy(np.stack(res_video)).permute(0, 3, 1, 2)[None].byte() | |
| def _draw_pred_tracks( | |
| self, | |
| rgb: np.ndarray, # H x W x 3 | |
| tracks: np.ndarray, # T x 2 | |
| vector_colors: np.ndarray, | |
| alpha: float = 0.5, | |
| ): | |
| T, N, _ = tracks.shape | |
| rgb = Image.fromarray(np.uint8(rgb)) | |
| for s in range(T - 1): | |
| vector_color = vector_colors[s] | |
| original = rgb.copy() | |
| alpha = (s / T) ** 2 | |
| for i in range(N): | |
| coord_y = (int(tracks[s, i, 0]), int(tracks[s, i, 1])) | |
| coord_x = (int(tracks[s + 1, i, 0]), int(tracks[s + 1, i, 1])) | |
| if coord_y[0] != 0 and coord_y[1] != 0: | |
| rgb = draw_line( | |
| rgb, | |
| coord_y, | |
| coord_x, | |
| vector_color[i].astype(int), | |
| self.linewidth, | |
| ) | |
| if self.tracks_leave_trace > 0: | |
| rgb = Image.fromarray( | |
| np.uint8(add_weighted(np.array(rgb), alpha, np.array(original), 1 - alpha, 0)) | |
| ) | |
| rgb = np.array(rgb) | |
| return rgb | |
| def _draw_gt_tracks( | |
| self, | |
| rgb: np.ndarray, # H x W x 3, | |
| gt_tracks: np.ndarray, # T x 2 | |
| ): | |
| T, N, _ = gt_tracks.shape | |
| color = np.array((211, 0, 0)) | |
| rgb = Image.fromarray(np.uint8(rgb)) | |
| for t in range(T): | |
| for i in range(N): | |
| gt_tracks = gt_tracks[t][i] | |
| # draw a red cross | |
| if gt_tracks[0] > 0 and gt_tracks[1] > 0: | |
| length = self.linewidth * 3 | |
| coord_y = (int(gt_tracks[0]) + length, int(gt_tracks[1]) + length) | |
| coord_x = (int(gt_tracks[0]) - length, int(gt_tracks[1]) - length) | |
| rgb = draw_line( | |
| rgb, | |
| coord_y, | |
| coord_x, | |
| color, | |
| self.linewidth, | |
| ) | |
| coord_y = (int(gt_tracks[0]) - length, int(gt_tracks[1]) + length) | |
| coord_x = (int(gt_tracks[0]) + length, int(gt_tracks[1]) - length) | |
| rgb = draw_line( | |
| rgb, | |
| coord_y, | |
| coord_x, | |
| color, | |
| self.linewidth, | |
| ) | |
| rgb = np.array(rgb) | |
| return rgb | |