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import math |
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from typing import Dict, Union |
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|
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import matplotlib |
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import numpy as np |
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import torch |
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from PIL import Image |
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from scipy.optimize import minimize |
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from torch.utils.data import DataLoader, TensorDataset |
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from tqdm.auto import tqdm |
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from transformers import CLIPTextModel, CLIPTokenizer |
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|
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from diffusers import ( |
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AutoencoderKL, |
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DDIMScheduler, |
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DiffusionPipeline, |
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UNet2DConditionModel, |
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) |
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from diffusers.utils import BaseOutput, check_min_version |
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check_min_version("0.26.0") |
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|
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class MarigoldDepthOutput(BaseOutput): |
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""" |
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Output class for Marigold monocular depth prediction pipeline. |
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|
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Args: |
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depth_np (`np.ndarray`): |
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Predicted depth map, with depth values in the range of [0, 1]. |
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depth_colored (`PIL.Image.Image`): |
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Colorized depth map, with the shape of [3, H, W] and values in [0, 1]. |
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uncertainty (`None` or `np.ndarray`): |
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Uncalibrated uncertainty(MAD, median absolute deviation) coming from ensembling. |
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""" |
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|
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depth_np: np.ndarray |
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depth_colored: Image.Image |
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uncertainty: Union[None, np.ndarray] |
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class MarigoldPipeline(DiffusionPipeline): |
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""" |
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Pipeline for monocular depth estimation using Marigold: https://marigoldmonodepth.github.io. |
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This model inherits from [`DiffusionPipeline`]. Check the superclass documentation for the generic methods the |
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library implements for all the pipelines (such as downloading or saving, running on a particular device, etc.) |
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|
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Args: |
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unet (`UNet2DConditionModel`): |
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Conditional U-Net to denoise the depth latent, conditioned on image latent. |
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vae (`AutoencoderKL`): |
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Variational Auto-Encoder (VAE) Model to encode and decode images and depth maps |
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to and from latent representations. |
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scheduler (`DDIMScheduler`): |
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A scheduler to be used in combination with `unet` to denoise the encoded image latents. |
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text_encoder (`CLIPTextModel`): |
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Text-encoder, for empty text embedding. |
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tokenizer (`CLIPTokenizer`): |
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CLIP tokenizer. |
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""" |
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|
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rgb_latent_scale_factor = 0.18215 |
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depth_latent_scale_factor = 0.18215 |
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|
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def __init__( |
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self, |
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unet: UNet2DConditionModel, |
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vae: AutoencoderKL, |
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scheduler: DDIMScheduler, |
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text_encoder: CLIPTextModel, |
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tokenizer: CLIPTokenizer, |
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): |
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super().__init__() |
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|
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self.register_modules( |
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unet=unet, |
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vae=vae, |
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scheduler=scheduler, |
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text_encoder=text_encoder, |
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tokenizer=tokenizer, |
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) |
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|
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self.empty_text_embed = None |
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|
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@torch.no_grad() |
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def __call__( |
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self, |
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input_image: Image, |
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denoising_steps: int = 10, |
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ensemble_size: int = 10, |
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processing_res: int = 768, |
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match_input_res: bool = True, |
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batch_size: int = 0, |
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color_map: str = "Spectral", |
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show_progress_bar: bool = True, |
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ensemble_kwargs: Dict = None, |
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) -> MarigoldDepthOutput: |
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""" |
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Function invoked when calling the pipeline. |
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|
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Args: |
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input_image (`Image`): |
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Input RGB (or gray-scale) image. |
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processing_res (`int`, *optional*, defaults to `768`): |
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Maximum resolution of processing. |
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If set to 0: will not resize at all. |
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match_input_res (`bool`, *optional*, defaults to `True`): |
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Resize depth prediction to match input resolution. |
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Only valid if `limit_input_res` is not None. |
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denoising_steps (`int`, *optional*, defaults to `10`): |
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Number of diffusion denoising steps (DDIM) during inference. |
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ensemble_size (`int`, *optional*, defaults to `10`): |
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Number of predictions to be ensembled. |
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batch_size (`int`, *optional*, defaults to `0`): |
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Inference batch size, no bigger than `num_ensemble`. |
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If set to 0, the script will automatically decide the proper batch size. |
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show_progress_bar (`bool`, *optional*, defaults to `True`): |
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Display a progress bar of diffusion denoising. |
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color_map (`str`, *optional*, defaults to `"Spectral"`): |
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Colormap used to colorize the depth map. |
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ensemble_kwargs (`dict`, *optional*, defaults to `None`): |
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Arguments for detailed ensembling settings. |
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Returns: |
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`MarigoldDepthOutput`: Output class for Marigold monocular depth prediction pipeline, including: |
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- **depth_np** (`np.ndarray`) Predicted depth map, with depth values in the range of [0, 1] |
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- **depth_colored** (`PIL.Image.Image`) Colorized depth map, with the shape of [3, H, W] and values in [0, 1] |
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- **uncertainty** (`None` or `np.ndarray`) Uncalibrated uncertainty(MAD, median absolute deviation) |
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coming from ensembling. None if `ensemble_size = 1` |
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""" |
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device = self.device |
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input_size = input_image.size |
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|
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if not match_input_res: |
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assert processing_res is not None, "Value error: `resize_output_back` is only valid with " |
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assert processing_res >= 0 |
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assert denoising_steps >= 1 |
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assert ensemble_size >= 1 |
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if processing_res > 0: |
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input_image = self.resize_max_res(input_image, max_edge_resolution=processing_res) |
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input_image = input_image.convert("RGB") |
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image = np.asarray(input_image) |
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rgb = np.transpose(image, (2, 0, 1)) |
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rgb_norm = rgb / 255.0 |
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rgb_norm = torch.from_numpy(rgb_norm).to(self.dtype) |
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rgb_norm = rgb_norm.to(device) |
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assert rgb_norm.min() >= 0.0 and rgb_norm.max() <= 1.0 |
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duplicated_rgb = torch.stack([rgb_norm] * ensemble_size) |
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single_rgb_dataset = TensorDataset(duplicated_rgb) |
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if batch_size > 0: |
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_bs = batch_size |
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else: |
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_bs = self._find_batch_size( |
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ensemble_size=ensemble_size, |
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input_res=max(rgb_norm.shape[1:]), |
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dtype=self.dtype, |
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) |
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single_rgb_loader = DataLoader(single_rgb_dataset, batch_size=_bs, shuffle=False) |
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depth_pred_ls = [] |
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if show_progress_bar: |
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iterable = tqdm(single_rgb_loader, desc=" " * 2 + "Inference batches", leave=False) |
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else: |
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iterable = single_rgb_loader |
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for batch in iterable: |
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(batched_img,) = batch |
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depth_pred_raw = self.single_infer( |
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rgb_in=batched_img, |
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num_inference_steps=denoising_steps, |
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show_pbar=show_progress_bar, |
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) |
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depth_pred_ls.append(depth_pred_raw.detach().clone()) |
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depth_preds = torch.concat(depth_pred_ls, axis=0).squeeze() |
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torch.cuda.empty_cache() |
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if ensemble_size > 1: |
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depth_pred, pred_uncert = self.ensemble_depths(depth_preds, **(ensemble_kwargs or {})) |
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else: |
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depth_pred = depth_preds |
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pred_uncert = None |
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min_d = torch.min(depth_pred) |
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max_d = torch.max(depth_pred) |
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depth_pred = (depth_pred - min_d) / (max_d - min_d) |
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depth_pred = depth_pred.cpu().numpy().astype(np.float32) |
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if match_input_res: |
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pred_img = Image.fromarray(depth_pred) |
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pred_img = pred_img.resize(input_size) |
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depth_pred = np.asarray(pred_img) |
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depth_pred = depth_pred.clip(0, 1) |
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depth_colored = self.colorize_depth_maps( |
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depth_pred, 0, 1, cmap=color_map |
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).squeeze() |
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depth_colored = (depth_colored * 255).astype(np.uint8) |
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depth_colored_hwc = self.chw2hwc(depth_colored) |
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depth_colored_img = Image.fromarray(depth_colored_hwc) |
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return MarigoldDepthOutput( |
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depth_np=depth_pred, |
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depth_colored=depth_colored_img, |
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uncertainty=pred_uncert, |
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) |
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|
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def _encode_empty_text(self): |
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""" |
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Encode text embedding for empty prompt. |
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""" |
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prompt = "" |
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text_inputs = self.tokenizer( |
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prompt, |
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padding="do_not_pad", |
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max_length=self.tokenizer.model_max_length, |
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truncation=True, |
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return_tensors="pt", |
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) |
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text_input_ids = text_inputs.input_ids.to(self.text_encoder.device) |
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self.empty_text_embed = self.text_encoder(text_input_ids)[0].to(self.dtype) |
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|
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@torch.no_grad() |
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def single_infer(self, rgb_in: torch.Tensor, num_inference_steps: int, show_pbar: bool) -> torch.Tensor: |
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""" |
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Perform an individual depth prediction without ensembling. |
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|
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Args: |
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rgb_in (`torch.Tensor`): |
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Input RGB image. |
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num_inference_steps (`int`): |
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Number of diffusion denoisign steps (DDIM) during inference. |
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show_pbar (`bool`): |
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Display a progress bar of diffusion denoising. |
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Returns: |
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`torch.Tensor`: Predicted depth map. |
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""" |
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device = rgb_in.device |
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self.scheduler.set_timesteps(num_inference_steps, device=device) |
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timesteps = self.scheduler.timesteps |
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rgb_latent = self._encode_rgb(rgb_in) |
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depth_latent = torch.randn(rgb_latent.shape, device=device, dtype=self.dtype) |
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|
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if self.empty_text_embed is None: |
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self._encode_empty_text() |
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batch_empty_text_embed = self.empty_text_embed.repeat((rgb_latent.shape[0], 1, 1)) |
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if show_pbar: |
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iterable = tqdm( |
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enumerate(timesteps), |
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total=len(timesteps), |
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leave=False, |
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desc=" " * 4 + "Diffusion denoising", |
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) |
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else: |
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iterable = enumerate(timesteps) |
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|
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for i, t in iterable: |
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unet_input = torch.cat([rgb_latent, depth_latent], dim=1) |
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|
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noise_pred = self.unet(unet_input, t, encoder_hidden_states=batch_empty_text_embed).sample |
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depth_latent = self.scheduler.step(noise_pred, t, depth_latent).prev_sample |
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torch.cuda.empty_cache() |
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depth = self._decode_depth(depth_latent) |
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|
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depth = torch.clip(depth, -1.0, 1.0) |
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|
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depth = (depth + 1.0) / 2.0 |
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return depth |
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|
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def _encode_rgb(self, rgb_in: torch.Tensor) -> torch.Tensor: |
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""" |
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Encode RGB image into latent. |
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|
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Args: |
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rgb_in (`torch.Tensor`): |
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Input RGB image to be encoded. |
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|
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Returns: |
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`torch.Tensor`: Image latent. |
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""" |
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|
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h = self.vae.encoder(rgb_in) |
|
moments = self.vae.quant_conv(h) |
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mean, logvar = torch.chunk(moments, 2, dim=1) |
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|
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rgb_latent = mean * self.rgb_latent_scale_factor |
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return rgb_latent |
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|
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def _decode_depth(self, depth_latent: torch.Tensor) -> torch.Tensor: |
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""" |
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Decode depth latent into depth map. |
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|
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Args: |
|
depth_latent (`torch.Tensor`): |
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Depth latent to be decoded. |
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|
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Returns: |
|
`torch.Tensor`: Decoded depth map. |
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""" |
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|
|
depth_latent = depth_latent / self.depth_latent_scale_factor |
|
|
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z = self.vae.post_quant_conv(depth_latent) |
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stacked = self.vae.decoder(z) |
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|
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depth_mean = stacked.mean(dim=1, keepdim=True) |
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return depth_mean |
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|
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@staticmethod |
|
def resize_max_res(img: Image.Image, max_edge_resolution: int) -> Image.Image: |
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""" |
|
Resize image to limit maximum edge length while keeping aspect ratio. |
|
|
|
Args: |
|
img (`Image.Image`): |
|
Image to be resized. |
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max_edge_resolution (`int`): |
|
Maximum edge length (pixel). |
|
|
|
Returns: |
|
`Image.Image`: Resized image. |
|
""" |
|
original_width, original_height = img.size |
|
downscale_factor = min(max_edge_resolution / original_width, max_edge_resolution / original_height) |
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|
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new_width = int(original_width * downscale_factor) |
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new_height = int(original_height * downscale_factor) |
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|
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resized_img = img.resize((new_width, new_height)) |
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return resized_img |
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|
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@staticmethod |
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def colorize_depth_maps(depth_map, min_depth, max_depth, cmap="Spectral", valid_mask=None): |
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""" |
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Colorize depth maps. |
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""" |
|
assert len(depth_map.shape) >= 2, "Invalid dimension" |
|
|
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if isinstance(depth_map, torch.Tensor): |
|
depth = depth_map.detach().clone().squeeze().numpy() |
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elif isinstance(depth_map, np.ndarray): |
|
depth = depth_map.copy().squeeze() |
|
|
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if depth.ndim < 3: |
|
depth = depth[np.newaxis, :, :] |
|
|
|
|
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cm = matplotlib.colormaps[cmap] |
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depth = ((depth - min_depth) / (max_depth - min_depth)).clip(0, 1) |
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img_colored_np = cm(depth, bytes=False)[:, :, :, 0:3] |
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img_colored_np = np.rollaxis(img_colored_np, 3, 1) |
|
|
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if valid_mask is not None: |
|
if isinstance(depth_map, torch.Tensor): |
|
valid_mask = valid_mask.detach().numpy() |
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valid_mask = valid_mask.squeeze() |
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if valid_mask.ndim < 3: |
|
valid_mask = valid_mask[np.newaxis, np.newaxis, :, :] |
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else: |
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valid_mask = valid_mask[:, np.newaxis, :, :] |
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valid_mask = np.repeat(valid_mask, 3, axis=1) |
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img_colored_np[~valid_mask] = 0 |
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|
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if isinstance(depth_map, torch.Tensor): |
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img_colored = torch.from_numpy(img_colored_np).float() |
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elif isinstance(depth_map, np.ndarray): |
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img_colored = img_colored_np |
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|
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return img_colored |
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|
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@staticmethod |
|
def chw2hwc(chw): |
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assert 3 == len(chw.shape) |
|
if isinstance(chw, torch.Tensor): |
|
hwc = torch.permute(chw, (1, 2, 0)) |
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elif isinstance(chw, np.ndarray): |
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hwc = np.moveaxis(chw, 0, -1) |
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return hwc |
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|
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@staticmethod |
|
def _find_batch_size(ensemble_size: int, input_res: int, dtype: torch.dtype) -> int: |
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""" |
|
Automatically search for suitable operating batch size. |
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|
|
Args: |
|
ensemble_size (`int`): |
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Number of predictions to be ensembled. |
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input_res (`int`): |
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Operating resolution of the input image. |
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|
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Returns: |
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`int`: Operating batch size. |
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""" |
|
|
|
bs_search_table = [ |
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|
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{"res": 768, "total_vram": 79, "bs": 35, "dtype": torch.float32}, |
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{"res": 1024, "total_vram": 79, "bs": 20, "dtype": torch.float32}, |
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|
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{"res": 768, "total_vram": 39, "bs": 15, "dtype": torch.float32}, |
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{"res": 1024, "total_vram": 39, "bs": 8, "dtype": torch.float32}, |
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{"res": 768, "total_vram": 39, "bs": 30, "dtype": torch.float16}, |
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{"res": 1024, "total_vram": 39, "bs": 15, "dtype": torch.float16}, |
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|
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{"res": 512, "total_vram": 23, "bs": 20, "dtype": torch.float32}, |
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{"res": 768, "total_vram": 23, "bs": 7, "dtype": torch.float32}, |
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{"res": 1024, "total_vram": 23, "bs": 3, "dtype": torch.float32}, |
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{"res": 512, "total_vram": 23, "bs": 40, "dtype": torch.float16}, |
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{"res": 768, "total_vram": 23, "bs": 18, "dtype": torch.float16}, |
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{"res": 1024, "total_vram": 23, "bs": 10, "dtype": torch.float16}, |
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|
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{"res": 512, "total_vram": 10, "bs": 5, "dtype": torch.float32}, |
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{"res": 768, "total_vram": 10, "bs": 2, "dtype": torch.float32}, |
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{"res": 512, "total_vram": 10, "bs": 10, "dtype": torch.float16}, |
|
{"res": 768, "total_vram": 10, "bs": 5, "dtype": torch.float16}, |
|
{"res": 1024, "total_vram": 10, "bs": 3, "dtype": torch.float16}, |
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] |
|
|
|
if not torch.cuda.is_available(): |
|
return 1 |
|
|
|
total_vram = torch.cuda.mem_get_info()[1] / 1024.0**3 |
|
filtered_bs_search_table = [s for s in bs_search_table if s["dtype"] == dtype] |
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for settings in sorted( |
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filtered_bs_search_table, |
|
key=lambda k: (k["res"], -k["total_vram"]), |
|
): |
|
if input_res <= settings["res"] and total_vram >= settings["total_vram"]: |
|
bs = settings["bs"] |
|
if bs > ensemble_size: |
|
bs = ensemble_size |
|
elif bs > math.ceil(ensemble_size / 2) and bs < ensemble_size: |
|
bs = math.ceil(ensemble_size / 2) |
|
return bs |
|
|
|
return 1 |
|
|
|
@staticmethod |
|
def ensemble_depths( |
|
input_images: torch.Tensor, |
|
regularizer_strength: float = 0.02, |
|
max_iter: int = 2, |
|
tol: float = 1e-3, |
|
reduction: str = "median", |
|
max_res: int = None, |
|
): |
|
""" |
|
To ensemble multiple affine-invariant depth images (up to scale and shift), |
|
by aligning estimating the scale and shift |
|
""" |
|
|
|
def inter_distances(tensors: torch.Tensor): |
|
""" |
|
To calculate the distance between each two depth maps. |
|
""" |
|
distances = [] |
|
for i, j in torch.combinations(torch.arange(tensors.shape[0])): |
|
arr1 = tensors[i : i + 1] |
|
arr2 = tensors[j : j + 1] |
|
distances.append(arr1 - arr2) |
|
dist = torch.concatenate(distances, dim=0) |
|
return dist |
|
|
|
device = input_images.device |
|
dtype = input_images.dtype |
|
np_dtype = np.float32 |
|
|
|
original_input = input_images.clone() |
|
n_img = input_images.shape[0] |
|
ori_shape = input_images.shape |
|
|
|
if max_res is not None: |
|
scale_factor = torch.min(max_res / torch.tensor(ori_shape[-2:])) |
|
if scale_factor < 1: |
|
downscaler = torch.nn.Upsample(scale_factor=scale_factor, mode="nearest") |
|
input_images = downscaler(torch.from_numpy(input_images)).numpy() |
|
|
|
|
|
_min = np.min(input_images.reshape((n_img, -1)).cpu().numpy(), axis=1) |
|
_max = np.max(input_images.reshape((n_img, -1)).cpu().numpy(), axis=1) |
|
s_init = 1.0 / (_max - _min).reshape((-1, 1, 1)) |
|
t_init = (-1 * s_init.flatten() * _min.flatten()).reshape((-1, 1, 1)) |
|
x = np.concatenate([s_init, t_init]).reshape(-1).astype(np_dtype) |
|
|
|
input_images = input_images.to(device) |
|
|
|
|
|
def closure(x): |
|
l = len(x) |
|
s = x[: int(l / 2)] |
|
t = x[int(l / 2) :] |
|
s = torch.from_numpy(s).to(dtype=dtype).to(device) |
|
t = torch.from_numpy(t).to(dtype=dtype).to(device) |
|
|
|
transformed_arrays = input_images * s.view((-1, 1, 1)) + t.view((-1, 1, 1)) |
|
dists = inter_distances(transformed_arrays) |
|
sqrt_dist = torch.sqrt(torch.mean(dists**2)) |
|
|
|
if "mean" == reduction: |
|
pred = torch.mean(transformed_arrays, dim=0) |
|
elif "median" == reduction: |
|
pred = torch.median(transformed_arrays, dim=0).values |
|
else: |
|
raise ValueError |
|
|
|
near_err = torch.sqrt((0 - torch.min(pred)) ** 2) |
|
far_err = torch.sqrt((1 - torch.max(pred)) ** 2) |
|
|
|
err = sqrt_dist + (near_err + far_err) * regularizer_strength |
|
err = err.detach().cpu().numpy().astype(np_dtype) |
|
return err |
|
|
|
res = minimize( |
|
closure, |
|
x, |
|
method="BFGS", |
|
tol=tol, |
|
options={"maxiter": max_iter, "disp": False}, |
|
) |
|
x = res.x |
|
l = len(x) |
|
s = x[: int(l / 2)] |
|
t = x[int(l / 2) :] |
|
|
|
|
|
s = torch.from_numpy(s).to(dtype=dtype).to(device) |
|
t = torch.from_numpy(t).to(dtype=dtype).to(device) |
|
transformed_arrays = original_input * s.view(-1, 1, 1) + t.view(-1, 1, 1) |
|
if "mean" == reduction: |
|
aligned_images = torch.mean(transformed_arrays, dim=0) |
|
std = torch.std(transformed_arrays, dim=0) |
|
uncertainty = std |
|
elif "median" == reduction: |
|
aligned_images = torch.median(transformed_arrays, dim=0).values |
|
|
|
abs_dev = torch.abs(transformed_arrays - aligned_images) |
|
mad = torch.median(abs_dev, dim=0).values |
|
uncertainty = mad |
|
else: |
|
raise ValueError(f"Unknown reduction method: {reduction}") |
|
|
|
|
|
_min = torch.min(aligned_images) |
|
_max = torch.max(aligned_images) |
|
aligned_images = (aligned_images - _min) / (_max - _min) |
|
uncertainty /= _max - _min |
|
|
|
return aligned_images, uncertainty |
|
|