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import gradio as gr |
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""" |
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Optical Flow: Predicting movement with the RAFT model |
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Optical flow is the task of predicting movement between two images, usually two |
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consecutive frames of a video. Optical flow models take two images as input, and |
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predict a flow: the flow indicates the displacement of every single pixel in the |
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first image, and maps it to its corresponding pixel in the second image. Flows |
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are (2, H, W)-dimensional tensors, where the first axis corresponds to the |
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predicted horizontal and vertical displacements. |
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The following example illustrates how torchvision can be used to predict flows |
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using our implementation of the RAFT model. We will also see how to convert the |
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predicted flows to RGB images for visualization. |
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""" |
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import cv2 |
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import numpy as np |
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import os |
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import sys |
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import torch |
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import matplotlib.pyplot as plt |
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import torchvision.transforms.functional as F |
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from torchvision.io import read_video |
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from torchvision.models.optical_flow import Raft_Large_Weights |
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from torchvision.models.optical_flow import raft_large |
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from torchvision.io import write_jpeg |
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import tempfile |
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from pathlib import Path |
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from urllib.request import urlretrieve |
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import tensorflow as tf |
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def write_flo(flow, filename): |
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""" |
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Write optical flow in Middlebury .flo format |
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:param flow: optical flow map |
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:param filename: optical flow file path to be saved |
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:return: None |
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from https://github.com/liruoteng/OpticalFlowToolkit/ |
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""" |
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flow = flow.cpu().data.numpy() |
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flow = flow.astype(np.float32) |
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f = open(filename, 'wb') |
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magic = np.array([202021.25], dtype=np.float32) |
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(height, width) = flow.shape[0:2] |
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w = np.array([width], dtype=np.int32) |
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h = np.array([height], dtype=np.int32) |
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magic.tofile(f) |
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w.tofile(f) |
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h.tofile(f) |
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flow.tofile(f) |
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f.close() |
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def warp_image(im, flow): |
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print(f"IMAGE: {im}") |
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im = im.cpu().data.numpy() |
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im = im.astype(np.float32) |
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print(f"IMAGE AP: {im}") |
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print(f"FLOW AV: {flow}") |
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flow = flow.cpu().data.numpy() |
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flow = flow.astype(np.float32) |
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print(f"FLOW AP: {flow}") |
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h, w = flow.shape[:2] |
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flow[:,:,0] += np.arange(w) |
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flow[:,:,1] += np.arange(h)[:,np.newaxis] |
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prevImg = cv2.remap(im, flow, None, cv2.INTER_LINEAR) |
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def infer(): |
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video_url = "https://download.pytorch.org/tutorial/pexelscom_pavel_danilyuk_basketball_hd.mp4" |
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video_path = Path(tempfile.mkdtemp()) / "basketball.mp4" |
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_ = urlretrieve(video_url, video_path) |
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frames, _, _ = read_video(str(video_path), output_format="TCHW") |
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img1_batch = torch.stack([frames[100]]) |
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img2_batch = torch.stack([frames[101]]) |
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weights = Raft_Large_Weights.DEFAULT |
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transforms = weights.transforms() |
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def preprocess(img1_batch, img2_batch): |
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img1_batch = F.resize(img1_batch, size=[520, 960]) |
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img2_batch = F.resize(img2_batch, size=[520, 960]) |
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return transforms(img1_batch, img2_batch) |
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img1_batch, img2_batch = preprocess(img1_batch, img2_batch) |
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print(f"shape = {img1_batch.shape}, dtype = {img1_batch.dtype}") |
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device = "cuda" if torch.cuda.is_available() else "cpu" |
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model = raft_large(weights=Raft_Large_Weights.DEFAULT, progress=False).to(device) |
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model = model.eval() |
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list_of_flows = model(img1_batch.to(device), img2_batch.to(device)) |
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print(f"type = {type(list_of_flows)}") |
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print(f"length = {len(list_of_flows)} = number of iterations of the model") |
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predicted_flows = list_of_flows[-1] |
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print(f"dtype = {predicted_flows.dtype}") |
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print(f"shape = {predicted_flows.shape} = (N, 2, H, W)") |
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print(f"min = {predicted_flows.min()}, max = {predicted_flows.max()}") |
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from torchvision.utils import flow_to_image |
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predicted_flow = list_of_flows[-1][0] |
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flow_img = flow_to_image(predicted_flow).to("cpu") |
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write_jpeg(flow_img, f"predicted_flow.jpg") |
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flo_file = write_flo(predicted_flow, "flofile.flo") |
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res = warp_image(img1_batch, predicted_flow) |
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im = Image.fromarray(res) |
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im.save('output.jpg') |
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return "done", "predicted_flow.jpg", ["flofile.flo"] |
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gr.Interface(fn=infer, inputs=[], outputs=[gr.Textbox(), gr.Image(), gr.Files()]).launch() |