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| import matplotlib.pyplot as plt | |
| import numpy as np | |
| import torch | |
| def imshow(ims, ax=None, t=0, vmin=None, vmax=None, title=None, cmap=None, fontsize=20): | |
| if ax is None: | |
| fig, ax = plt.subplots(1,1) | |
| with torch.no_grad(): | |
| im = ims[t].float().cpu().numpy().transpose((1,2,0)) | |
| if (vmin is not None) and (vmax is not None): | |
| im =ax.imshow(im, vmin=vmin, vmax=vmax, cmap=(cmap or 'viridis')) | |
| else: | |
| im =ax.imshow(im) | |
| if title is not None: | |
| ax.set_title(title, fontsize=fontsize) | |
| return (im, ax) | |
| def make_colorwheel(): | |
| """ | |
| Generates a color wheel for optical flow visualization as presented in: | |
| Baker et al. "A Database and Evaluation Methodology for Optical Flow" (ICCV, 2007) | |
| URL: http://vision.middlebury.edu/flow/flowEval-iccv07.pdf | |
| Code follows the original C++ source code of Daniel Scharstein. | |
| Code follows the the Matlab source code of Deqing Sun. | |
| Returns: | |
| np.ndarray: Color wheel | |
| """ | |
| RY = 15 | |
| YG = 6 | |
| GC = 4 | |
| CB = 11 | |
| BM = 13 | |
| MR = 6 | |
| ncols = RY + YG + GC + CB + BM + MR | |
| colorwheel = np.zeros((ncols, 3)) | |
| col = 0 | |
| # RY | |
| colorwheel[0:RY, 0] = 255 | |
| colorwheel[0:RY, 1] = np.floor(255*np.arange(0,RY)/RY) | |
| col = col+RY | |
| # YG | |
| colorwheel[col:col+YG, 0] = 255 - np.floor(255*np.arange(0,YG)/YG) | |
| colorwheel[col:col+YG, 1] = 255 | |
| col = col+YG | |
| # GC | |
| colorwheel[col:col+GC, 1] = 255 | |
| colorwheel[col:col+GC, 2] = np.floor(255*np.arange(0,GC)/GC) | |
| col = col+GC | |
| # CB | |
| colorwheel[col:col+CB, 1] = 255 - np.floor(255*np.arange(CB)/CB) | |
| colorwheel[col:col+CB, 2] = 255 | |
| col = col+CB | |
| # BM | |
| colorwheel[col:col+BM, 2] = 255 | |
| colorwheel[col:col+BM, 0] = np.floor(255*np.arange(0,BM)/BM) | |
| col = col+BM | |
| # MR | |
| colorwheel[col:col+MR, 2] = 255 - np.floor(255*np.arange(MR)/MR) | |
| colorwheel[col:col+MR, 0] = 255 | |
| return colorwheel | |
| def flow_uv_to_colors(u, v, convert_to_bgr=False): | |
| """ | |
| Applies the flow color wheel to (possibly clipped) flow components u and v. | |
| According to the C++ source code of Daniel Scharstein | |
| According to the Matlab source code of Deqing Sun | |
| Args: | |
| u (np.ndarray): Input horizontal flow of shape [H,W] | |
| v (np.ndarray): Input vertical flow of shape [H,W] | |
| convert_to_bgr (bool, optional): Convert output image to BGR. Defaults to False. | |
| Returns: | |
| np.ndarray: Flow visualization image of shape [H,W,3] | |
| """ | |
| flow_image = np.zeros((u.shape[0], u.shape[1], 3), np.uint8) | |
| colorwheel = make_colorwheel() # shape [55x3] | |
| ncols = colorwheel.shape[0] | |
| rad = np.sqrt(np.square(u) + np.square(v)) | |
| a = np.arctan2(-v, -u)/np.pi | |
| fk = (a+1) / 2*(ncols-1) | |
| k0 = np.floor(fk).astype(np.int32) | |
| k1 = k0 + 1 | |
| k1[k1 == ncols] = 0 | |
| f = fk - k0 | |
| for i in range(colorwheel.shape[1]): | |
| tmp = colorwheel[:,i] | |
| col0 = tmp[k0] / 255.0 | |
| col1 = tmp[k1] / 255.0 | |
| col = (1-f)*col0 + f*col1 | |
| idx = (rad <= 1) | |
| col[idx] = 1 - rad[idx] * (1-col[idx]) | |
| col[~idx] = col[~idx] * 0.75 # out of range | |
| # Note the 2-i => BGR instead of RGB | |
| ch_idx = 2-i if convert_to_bgr else i | |
| flow_image[:,:,ch_idx] = np.floor(255 * col) | |
| return flow_image | |
| def flow_to_image(flow_uv, clip_flow=None, convert_to_bgr=False): | |
| """ | |
| Expects a two dimensional flow image of shape. | |
| Args: | |
| flow_uv (np.ndarray): Flow UV image of shape [H,W,2] | |
| clip_flow (float, optional): Clip maximum of flow values. Defaults to None. | |
| convert_to_bgr (bool, optional): Convert output image to BGR. Defaults to False. | |
| Returns: | |
| np.ndarray: Flow visualization image of shape [H,W,3] | |
| """ | |
| assert flow_uv.ndim == 3, 'input flow must have three dimensions' | |
| assert flow_uv.shape[2] == 2, 'input flow must have shape [H,W,2]' | |
| if clip_flow is not None: | |
| flow_uv = np.clip(flow_uv, 0, clip_flow) | |
| u = flow_uv[:,:,0] | |
| v = flow_uv[:,:,1] | |
| rad = np.sqrt(np.square(u) + np.square(v)) | |
| rad_max = np.max(rad) | |
| epsilon = 1e-5 | |
| u = u / (rad_max + epsilon) | |
| v = v / (rad_max + epsilon) | |
| return flow_uv_to_colors(u, v, convert_to_bgr) | |
| from decord import VideoReader, cpu | |
| from PIL import Image | |
| from torchvision import transforms | |
| def get_video(video_name, num_frames=2, delta_time=4, frame=None): | |
| decord_vr = VideoReader(video_name, num_threads=1, ctx=cpu(0)) | |
| max_end_ind = len(decord_vr) - num_frames*delta_time - 1 | |
| start_frame = frame if frame is not None else rng.randint(1, max_end_ind) | |
| print("fps", decord_vr.get_avg_fps()) | |
| print("start frame = %d" % start_frame) | |
| frame_id_list = list(range(start_frame, start_frame + num_frames*delta_time, delta_time)) | |
| video_data = decord_vr.get_batch(frame_id_list).asnumpy() | |
| video_data = [Image.fromarray(video_data[t]).convert('RGB') for t, _ in enumerate(frame_id_list)] | |
| return (torch.stack([transforms.ToTensor()(im) for im in video_data], 0), start_frame) | |