import torch from diffusers.image_processor import VaeImageProcessor from torch.nn import functional as F import cv2 from util.utils import * from util.rife.pytorch_msssim import ssim_matlab import numpy as np import logging import skvideo.io from util.rife.RIFE_HDv3 import Model logger = logging.getLogger(__name__) device = "cuda" if torch.cuda.is_available() else "cpu" def pad_image(img, scale): _, _, h, w = img.shape tmp = max(32, int(32 / scale)) ph = ((h - 1) // tmp + 1) * tmp pw = ((w - 1) // tmp + 1) * tmp padding = (0, 0, pw - w, ph - h) return F.pad(img, padding) def make_inference(model, I0, I1, upscale_amount, n): middle = model.inference(I0, I1, upscale_amount) if n == 1: return [middle] first_half = make_inference(model, I0, middle, upscale_amount, n=n // 2) second_half = make_inference(model, middle, I1, upscale_amount, n=n // 2) if n % 2: return [*first_half, middle, *second_half] else: return [*first_half, *second_half] @torch.inference_mode() def ssim_interpolation_rife(model, samples, exp=1, upscale_amount=1, output_device="cpu"): print(f"samples dtype:{samples.dtype}") print(f"samples shape:{samples.shape}") output = [] pbar = ProgressBar(samples.shape[0], desc="frame interpolating") for b in range(samples.shape[0]): frame = samples[b : b + 1] _, _, h, w = frame.shape I0 = samples[b : b + 1] I1 = samples[b + 1 : b + 2] if b + 2 < samples.shape[0] else samples[-1:] I0 = I0.to(torch.float) I1 = I1.to(torch.float) I0_small = F.interpolate(I0, (32, 32), mode="bilinear", align_corners=False) I1_small = F.interpolate(I1, (32, 32), mode="bilinear", align_corners=False) ssim = ssim_matlab(I0_small[:, :3], I1_small[:, :3]) if ssim > 0.996: I1 = make_inference(model, I0, I1, upscale_amount, 1) I1 = I1[0] frame = I1 tmp_output = [] if ssim < 0.2: for _ in range((2**exp) - 1): tmp_output.append(I0) else: tmp_output = make_inference(model, I0, I1, upscale_amount, 2**exp - 1) if exp else [] frame = F.interpolate(frame, size=(h, w)) output.append(frame.to(output_device)) for tmp_frame in tmp_output: tmp_frame = F.interpolate(tmp_frame, size=(h, w)) output.append(tmp_frame.to(output_device)) pbar.update(1) return output def load_rife_model(model_path): model = Model() model.load_model(model_path, -1) model.eval() return model # Create a generator that yields each frame, similar to cv2.VideoCapture def frame_generator(video_capture): while True: ret, frame = video_capture.read() if not ret: break yield frame video_capture.release() def rife_inference_with_path(model, video_path): video_capture = cv2.VideoCapture(video_path) tot_frame = video_capture.get(cv2.CAP_PROP_FRAME_COUNT) pt_frame_data = [] pt_frame = skvideo.io.vreader(video_path) for frame in pt_frame: pt_frame_data.append( torch.from_numpy(np.transpose(frame, (2, 0, 1))).to("cpu", non_blocking=True).float() / 255.0 ) pt_frame = torch.from_numpy(np.stack(pt_frame_data)) pt_frame = pt_frame.to(device) pbar = ProgressBar(tot_frame, desc="RIFE inference") frames = ssim_interpolation_rife(model, pt_frame) pt_image = torch.stack([frames[i].squeeze(0) for i in range(len(frames))]) image_np = VaeImageProcessor.pt_to_numpy(pt_image) # (to [49, 512, 480, 3]) image_pil = VaeImageProcessor.numpy_to_pil(image_np) video_path = save_video(image_pil, fps=16) if pbar: pbar.update(1) return video_path def rife_inference_with_latents(model, latents): rife_results = [] latents = latents.to(device) for i in range(latents.size(0)): # [f, c, w, h] latent = latents[i] frames = ssim_interpolation_rife(model, latent) pt_image = torch.stack([frames[i].squeeze(0) for i in range(len(frames))]) # (to [f, c, w, h]) rife_results.append(pt_image) return torch.stack(rife_results)