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|
|
| # Marigold Computer Vision |
|
|
| **Marigold** is a diffusion-based [method](https://huggingface.co/papers/2312.02145) and a collection of [pipelines](../api/pipelines/marigold) designed for |
| dense computer vision tasks, including **monocular depth prediction**, **surface normals estimation**, and **intrinsic |
| image decomposition**. |
|
|
| This guide will walk you through using Marigold to generate fast and high-quality predictions for images and videos. |
|
|
| Each pipeline is tailored for a specific computer vision task, processing an input RGB image and generating a |
| corresponding prediction. |
| Currently, the following computer vision tasks are implemented: |
|
|
| | Pipeline | Recommended Model Checkpoints | Spaces (Interactive Apps) | Predicted Modalities | |
| |---------------------------------------------------------------------------------------------------------------------------------------------------|---------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------|:------------------------------------------------------------------------------------:|------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------| |
| | [MarigoldDepthPipeline](https://github.com/huggingface/diffusers/blob/main/src/diffusers/pipelines/marigold/pipeline_marigold_depth.py) | [prs-eth/marigold-depth-v1-1](https://huggingface.co/prs-eth/marigold-depth-v1-1) | [Depth Estimation](https://huggingface.co/spaces/prs-eth/marigold) | [Depth](https://en.wikipedia.org/wiki/Depth_map), [Disparity](https://en.wikipedia.org/wiki/Binocular_disparity) | |
| | [MarigoldNormalsPipeline](https://github.com/huggingface/diffusers/blob/main/src/diffusers/pipelines/marigold/pipeline_marigold_normals.py) | [prs-eth/marigold-normals-v1-1](https://huggingface.co/prs-eth/marigold-normals-v1-1) | [Surface Normals Estimation](https://huggingface.co/spaces/prs-eth/marigold-normals) | [Surface normals](https://en.wikipedia.org/wiki/Normal_mapping) | |
| | [MarigoldIntrinsicsPipeline](https://github.com/huggingface/diffusers/blob/main/src/diffusers/pipelines/marigold/pipeline_marigold_intrinsics.py) | [prs-eth/marigold-iid-appearance-v1-1](https://huggingface.co/prs-eth/marigold-iid-appearance-v1-1),<br>[prs-eth/marigold-iid-lighting-v1-1](https://huggingface.co/prs-eth/marigold-iid-lighting-v1-1) | [Intrinsic Image Decomposition](https://huggingface.co/spaces/prs-eth/marigold-iid) | [Albedo](https://en.wikipedia.org/wiki/Albedo), [Materials](https://www.n.aiq3d.com/wiki/roughnessmetalnessao-map), [Lighting](https://en.wikipedia.org/wiki/Diffuse_reflection) | |
|
|
| All original checkpoints are available under the [PRS-ETH](https://huggingface.co/prs-eth/) organization on Hugging Face. |
| They are designed for use with diffusers pipelines and the [original codebase](https://github.com/prs-eth/marigold), which can also be used to train |
| new model checkpoints. |
| The following is a summary of the recommended checkpoints, all of which produce reliable results with 1 to 4 steps. |
|
|
| | Checkpoint | Modality | Comment | |
| |-----------------------------------------------------------------------------------------------------|--------------|-------------------------------------------------------------------------------------------------------------------------------------------------------------------| |
| | [prs-eth/marigold-depth-v1-1](https://huggingface.co/prs-eth/marigold-depth-v1-1) | Depth | Affine-invariant depth prediction assigns each pixel a value between 0 (near plane) and 1 (far plane), with both planes determined by the model during inference. | |
| | [prs-eth/marigold-normals-v0-1](https://huggingface.co/prs-eth/marigold-normals-v0-1) | Normals | The surface normals predictions are unit-length 3D vectors in the screen space camera, with values in the range from -1 to 1. | |
| | [prs-eth/marigold-iid-appearance-v1-1](https://huggingface.co/prs-eth/marigold-iid-appearance-v1-1) | Intrinsics | InteriorVerse decomposition is comprised of Albedo and two BRDF material properties: Roughness and Metallicity. | |
| | [prs-eth/marigold-iid-lighting-v1-1](https://huggingface.co/prs-eth/marigold-iid-lighting-v1-1) | Intrinsics | HyperSim decomposition of an image \\(I\\) is comprised of Albedo \\(A\\), Diffuse shading \\(S\\), and Non-diffuse residual \\(R\\): \\(I = A*S+R\\). | |
| |
| The examples below are mostly given for depth prediction, but they can be universally applied to other supported |
| modalities. |
| We showcase the predictions using the same input image of Albert Einstein generated by Midjourney. |
| This makes it easier to compare visualizations of the predictions across various modalities and checkpoints. |
| |
| <div class="flex gap-4" style="justify-content: center; width: 100%;"> |
| <div style="flex: 1 1 50%; max-width: 50%;"> |
| <img class="rounded-xl" src="https://marigoldmonodepth.github.io/images/einstein.jpg"/> |
| <figcaption class="mt-1 text-center text-sm text-gray-500"> |
| Example input image for all Marigold pipelines |
| </figcaption> |
| </div> |
| </div> |
| |
| ## Depth Prediction |
| |
| To get a depth prediction, load the `prs-eth/marigold-depth-v1-1` checkpoint into [`MarigoldDepthPipeline`], |
| put the image through the pipeline, and save the predictions: |
| |
| ```python |
| import diffusers |
| import torch |
| |
| pipe = diffusers.MarigoldDepthPipeline.from_pretrained( |
| "prs-eth/marigold-depth-v1-1", variant="fp16", torch_dtype=torch.float16 |
| ).to("cuda") |
| |
| image = diffusers.utils.load_image("https://marigoldmonodepth.github.io/images/einstein.jpg") |
| |
| depth = pipe(image) |
| |
| vis = pipe.image_processor.visualize_depth(depth.prediction) |
| vis[0].save("einstein_depth.png") |
| |
| depth_16bit = pipe.image_processor.export_depth_to_16bit_png(depth.prediction) |
| depth_16bit[0].save("einstein_depth_16bit.png") |
| ``` |
| |
| The [`~pipelines.marigold.marigold_image_processing.MarigoldImageProcessor.visualize_depth`] function applies one of |
| [matplotlib's colormaps](https://matplotlib.org/stable/users/explain/colors/colormaps.html) (`Spectral` by default) to map the predicted pixel values from a single-channel `[0, 1]` |
| depth range into an RGB image. |
| With the `Spectral` colormap, pixels with near depth are painted red, and far pixels are blue. |
| The 16-bit PNG file stores the single channel values mapped linearly from the `[0, 1]` range into `[0, 65535]`. |
| Below are the raw and the visualized predictions. The darker and closer areas (mustache) are easier to distinguish in |
| the visualization. |
| |
| <div class="flex gap-4"> |
| <div style="flex: 1 1 50%; max-width: 50%;"> |
| <img class="rounded-xl" src="https://huggingface.co/datasets/huggingface/documentation-images/resolve/main/marigold/marigold_einstein_lcm_depth_16bit.png"/> |
| <figcaption class="mt-1 text-center text-sm text-gray-500"> |
| Predicted depth (16-bit PNG) |
| </figcaption> |
| </div> |
| <div style="flex: 1 1 50%; max-width: 50%;"> |
| <img class="rounded-xl" src="https://huggingface.co/datasets/huggingface/documentation-images/resolve/main/marigold/marigold_einstein_lcm_depth.png"/> |
| <figcaption class="mt-1 text-center text-sm text-gray-500"> |
| Predicted depth visualization (Spectral) |
| </figcaption> |
| </div> |
| </div> |
| |
| ## Surface Normals Estimation |
| |
| Load the `prs-eth/marigold-normals-v1-1` checkpoint into [`MarigoldNormalsPipeline`], put the image through the |
| pipeline, and save the predictions: |
| |
| ```python |
| import diffusers |
| import torch |
| |
| pipe = diffusers.MarigoldNormalsPipeline.from_pretrained( |
| "prs-eth/marigold-normals-v1-1", variant="fp16", torch_dtype=torch.float16 |
| ).to("cuda") |
| |
| image = diffusers.utils.load_image("https://marigoldmonodepth.github.io/images/einstein.jpg") |
| |
| normals = pipe(image) |
| |
| vis = pipe.image_processor.visualize_normals(normals.prediction) |
| vis[0].save("einstein_normals.png") |
| ``` |
| |
| The [`~pipelines.marigold.marigold_image_processing.MarigoldImageProcessor.visualize_normals`] maps the three-dimensional |
| prediction with pixel values in the range `[-1, 1]` into an RGB image. |
| The visualization function supports flipping surface normals axes to make the visualization compatible with other |
| choices of the frame of reference. |
| Conceptually, each pixel is painted according to the surface normal vector in the frame of reference, where `X` axis |
| points right, `Y` axis points up, and `Z` axis points at the viewer. |
| Below is the visualized prediction: |
| |
| <div class="flex gap-4" style="justify-content: center; width: 100%;"> |
| <div style="flex: 1 1 50%; max-width: 50%;"> |
| <img class="rounded-xl" src="https://huggingface.co/datasets/huggingface/documentation-images/resolve/main/marigold/marigold_einstein_lcm_normals.png"/> |
| <figcaption class="mt-1 text-center text-sm text-gray-500"> |
| Predicted surface normals visualization |
| </figcaption> |
| </div> |
| </div> |
| |
| In this example, the nose tip almost certainly has a point on the surface, in which the surface normal vector points |
| straight at the viewer, meaning that its coordinates are `[0, 0, 1]`. |
| This vector maps to the RGB `[128, 128, 255]`, which corresponds to the violet-blue color. |
| Similarly, a surface normal on the cheek in the right part of the image has a large `X` component, which increases the |
| red hue. |
| Points on the shoulders pointing up with a large `Y` promote green color. |
| |
| ## Intrinsic Image Decomposition |
| |
| Marigold provides two models for Intrinsic Image Decomposition (IID): "Appearance" and "Lighting". |
| Each model produces Albedo maps, derived from InteriorVerse and Hypersim annotations, respectively. |
| |
| - The "Appearance" model also estimates Material properties: Roughness and Metallicity. |
| - The "Lighting" model generates Diffuse Shading and Non-diffuse Residual. |
| |
| Here is the sample code saving predictions made by the "Appearance" model: |
| |
| ```python |
| import diffusers |
| import torch |
| |
| pipe = diffusers.MarigoldIntrinsicsPipeline.from_pretrained( |
| "prs-eth/marigold-iid-appearance-v1-1", variant="fp16", torch_dtype=torch.float16 |
| ).to("cuda") |
| |
| image = diffusers.utils.load_image("https://marigoldmonodepth.github.io/images/einstein.jpg") |
| |
| intrinsics = pipe(image) |
| |
| vis = pipe.image_processor.visualize_intrinsics(intrinsics.prediction, pipe.target_properties) |
| vis[0]["albedo"].save("einstein_albedo.png") |
| vis[0]["roughness"].save("einstein_roughness.png") |
| vis[0]["metallicity"].save("einstein_metallicity.png") |
| ``` |
| |
| Another example demonstrating the predictions made by the "Lighting" model: |
| |
| ```python |
| import diffusers |
| import torch |
| |
| pipe = diffusers.MarigoldIntrinsicsPipeline.from_pretrained( |
| "prs-eth/marigold-iid-lighting-v1-1", variant="fp16", torch_dtype=torch.float16 |
| ).to("cuda") |
| |
| image = diffusers.utils.load_image("https://marigoldmonodepth.github.io/images/einstein.jpg") |
| |
| intrinsics = pipe(image) |
| |
| vis = pipe.image_processor.visualize_intrinsics(intrinsics.prediction, pipe.target_properties) |
| vis[0]["albedo"].save("einstein_albedo.png") |
| vis[0]["shading"].save("einstein_shading.png") |
| vis[0]["residual"].save("einstein_residual.png") |
| ``` |
| |
| Both models share the same pipeline while supporting different decomposition types. |
| The exact decomposition parameterization (e.g., sRGB vs. linear space) is stored in the |
| `pipe.target_properties` dictionary, which is passed into the |
| [`~pipelines.marigold.marigold_image_processing.MarigoldImageProcessor.visualize_intrinsics`] function. |
| |
| Below are some examples showcasing the predicted decomposition outputs. |
| All modalities can be inspected in the |
| [Intrinsic Image Decomposition](https://huggingface.co/spaces/prs-eth/marigold-iid) Space. |
| |
| <div class="flex gap-4"> |
| <div style="flex: 1 1 50%; max-width: 50%;"> |
| <img class="rounded-xl" src="https://huggingface.co/datasets/huggingface/documentation-images/resolve/8c7986eaaab5eb9604eb88336311f46a7b0ff5ab/marigold/marigold_einstein_albedo.png"/> |
| <figcaption class="mt-1 text-center text-sm text-gray-500"> |
| Predicted albedo ("Appearance" model) |
| </figcaption> |
| </div> |
| <div style="flex: 1 1 50%; max-width: 50%;"> |
| <img class="rounded-xl" src="https://huggingface.co/datasets/huggingface/documentation-images/resolve/8c7986eaaab5eb9604eb88336311f46a7b0ff5ab/marigold/marigold_einstein_diffuse.png"/> |
| <figcaption class="mt-1 text-center text-sm text-gray-500"> |
| Predicted diffuse shading ("Lighting" model) |
| </figcaption> |
| </div> |
| </div> |
| |
| ## Speeding up inference |
| |
| The above quick start snippets are already optimized for quality and speed, loading the checkpoint, utilizing the |
| `fp16` variant of weights and computation, and performing the default number (4) of denoising diffusion steps. |
| The first step to accelerate inference, at the expense of prediction quality, is to reduce the denoising diffusion |
| steps to the minimum: |
| |
| ```diff |
| import diffusers |
| import torch |
| |
| pipe = diffusers.MarigoldDepthPipeline.from_pretrained( |
| "prs-eth/marigold-depth-v1-1", variant="fp16", torch_dtype=torch.float16 |
| ).to("cuda") |
| |
| image = diffusers.utils.load_image("https://marigoldmonodepth.github.io/images/einstein.jpg") |
| |
| - depth = pipe(image) |
| + depth = pipe(image, num_inference_steps=1) |
| ``` |
| |
| With this change, the `pipe` call completes in 280ms on RTX 3090 GPU. |
| Internally, the input image is first encoded using the Stable Diffusion VAE encoder, followed by a single denoising |
| step performed by the U-Net. |
| Finally, the prediction latent is decoded with the VAE decoder into pixel space. |
| In this setup, two out of three module calls are dedicated to converting between the pixel and latent spaces of the LDM. |
| Since Marigold's latent space is compatible with Stable Diffusion 2.0, inference can be accelerated by more than 3x, |
| reducing the call time to 85ms on an RTX 3090, by using a [lightweight replacement of the SD VAE](../api/models/autoencoder_tiny). |
| Note that using a lightweight VAE may slightly reduce the visual quality of the predictions. |
| |
| ```diff |
| import diffusers |
| import torch |
| |
| pipe = diffusers.MarigoldDepthPipeline.from_pretrained( |
| "prs-eth/marigold-depth-v1-1", variant="fp16", torch_dtype=torch.float16 |
| ).to("cuda") |
| |
| + pipe.vae = diffusers.AutoencoderTiny.from_pretrained( |
| + "madebyollin/taesd", torch_dtype=torch.float16 |
| + ).cuda() |
| |
| image = diffusers.utils.load_image("https://marigoldmonodepth.github.io/images/einstein.jpg") |
| |
| depth = pipe(image, num_inference_steps=1) |
| ``` |
| |
| So far, we have optimized the number of diffusion steps and model components. Self-attention operations account for a |
| significant portion of computations. |
| Speeding them up can be achieved by using a more efficient attention processor: |
| |
| ```diff |
| import diffusers |
| import torch |
| + from diffusers.models.attention_processor import AttnProcessor2_0 |
| |
| pipe = diffusers.MarigoldDepthPipeline.from_pretrained( |
| "prs-eth/marigold-depth-v1-1", variant="fp16", torch_dtype=torch.float16 |
| ).to("cuda") |
| |
| + pipe.vae.set_attn_processor(AttnProcessor2_0()) |
| + pipe.unet.set_attn_processor(AttnProcessor2_0()) |
| |
| image = diffusers.utils.load_image("https://marigoldmonodepth.github.io/images/einstein.jpg") |
| |
| depth = pipe(image, num_inference_steps=1) |
| ``` |
| |
| Finally, as suggested in [Optimizations](../optimization/fp16#torchcompile), enabling `torch.compile` can further enhance performance depending on |
| the target hardware. |
| However, compilation incurs a significant overhead during the first pipeline invocation, making it beneficial only when |
| the same pipeline instance is called repeatedly, such as within a loop. |
| |
| ```diff |
| import diffusers |
| import torch |
| from diffusers.models.attention_processor import AttnProcessor2_0 |
| |
| pipe = diffusers.MarigoldDepthPipeline.from_pretrained( |
| "prs-eth/marigold-depth-v1-1", variant="fp16", torch_dtype=torch.float16 |
| ).to("cuda") |
| |
| pipe.vae.set_attn_processor(AttnProcessor2_0()) |
| pipe.unet.set_attn_processor(AttnProcessor2_0()) |
| |
| + pipe.vae = torch.compile(pipe.vae, mode="reduce-overhead", fullgraph=True) |
| + pipe.unet = torch.compile(pipe.unet, mode="reduce-overhead", fullgraph=True) |
| |
| image = diffusers.utils.load_image("https://marigoldmonodepth.github.io/images/einstein.jpg") |
| |
| depth = pipe(image, num_inference_steps=1) |
| ``` |
| |
| ## Maximizing Precision and Ensembling |
| |
| Marigold pipelines have a built-in ensembling mechanism combining multiple predictions from different random latents. |
| This is a brute-force way of improving the precision of predictions, capitalizing on the generative nature of diffusion. |
| The ensembling path is activated automatically when the `ensemble_size` argument is set greater or equal than `3`. |
| When aiming for maximum precision, it makes sense to adjust `num_inference_steps` simultaneously with `ensemble_size`. |
| The recommended values vary across checkpoints but primarily depend on the scheduler type. |
| The effect of ensembling is particularly well-seen with surface normals: |
| |
| ```diff |
| import diffusers |
| |
| pipe = diffusers.MarigoldNormalsPipeline.from_pretrained("prs-eth/marigold-normals-v1-1").to("cuda") |
| |
| image = diffusers.utils.load_image("https://marigoldmonodepth.github.io/images/einstein.jpg") |
| |
| - depth = pipe(image) |
| + depth = pipe(image, num_inference_steps=10, ensemble_size=5) |
| |
| vis = pipe.image_processor.visualize_normals(depth.prediction) |
| vis[0].save("einstein_normals.png") |
| ``` |
| |
| <div class="flex gap-4"> |
| <div style="flex: 1 1 50%; max-width: 50%;"> |
| <img class="rounded-xl" src="https://huggingface.co/datasets/huggingface/documentation-images/resolve/main/marigold/marigold_einstein_lcm_normals.png"/> |
| <figcaption class="mt-1 text-center text-sm text-gray-500"> |
| Surface normals, no ensembling |
| </figcaption> |
| </div> |
| <div style="flex: 1 1 50%; max-width: 50%;"> |
| <img class="rounded-xl" src="https://huggingface.co/datasets/huggingface/documentation-images/resolve/main/marigold/marigold_einstein_normals.png"/> |
| <figcaption class="mt-1 text-center text-sm text-gray-500"> |
| Surface normals, with ensembling |
| </figcaption> |
| </div> |
| </div> |
| |
| As can be seen, all areas with fine-grained structurers, such as hair, got more conservative and on average more |
| correct predictions. |
| Such a result is more suitable for precision-sensitive downstream tasks, such as 3D reconstruction. |
| |
| ## Frame-by-frame Video Processing with Temporal Consistency |
| |
| Due to Marigold's generative nature, each prediction is unique and defined by the random noise sampled for the latent |
| initialization. |
| This becomes an obvious drawback compared to traditional end-to-end dense regression networks, as exemplified in the |
| following videos: |
| |
| <div class="flex gap-4"> |
| <div style="flex: 1 1 50%; max-width: 50%;"> |
| <img class="rounded-xl" src="https://huggingface.co/datasets/huggingface/documentation-images/resolve/main/marigold/marigold_obama.gif"/> |
| <figcaption class="mt-1 text-center text-sm text-gray-500">Input video</figcaption> |
| </div> |
| <div style="flex: 1 1 50%; max-width: 50%;"> |
| <img class="rounded-xl" src="https://huggingface.co/datasets/huggingface/documentation-images/resolve/main/marigold/marigold_obama_depth_independent.gif"/> |
| <figcaption class="mt-1 text-center text-sm text-gray-500">Marigold Depth applied to input video frames independently</figcaption> |
| </div> |
| </div> |
| |
| To address this issue, it is possible to pass `latents` argument to the pipelines, which defines the starting point of |
| diffusion. |
| Empirically, we found that a convex combination of the very same starting point noise latent and the latent |
| corresponding to the previous frame prediction give sufficiently smooth results, as implemented in the snippet below: |
| |
| ```python |
| import imageio |
| import diffusers |
| import torch |
| from diffusers.models.attention_processor import AttnProcessor2_0 |
| from PIL import Image |
| from tqdm import tqdm |
| |
| device = "cuda" |
| path_in = "https://huggingface.co/spaces/prs-eth/marigold-lcm/resolve/c7adb5427947d2680944f898cd91d386bf0d4924/files/video/obama.mp4" |
| path_out = "obama_depth.gif" |
| |
| pipe = diffusers.MarigoldDepthPipeline.from_pretrained( |
| "prs-eth/marigold-depth-v1-1", variant="fp16", torch_dtype=torch.float16 |
| ).to(device) |
| pipe.vae = diffusers.AutoencoderTiny.from_pretrained( |
| "madebyollin/taesd", torch_dtype=torch.float16 |
| ).to(device) |
| pipe.unet.set_attn_processor(AttnProcessor2_0()) |
| pipe.vae = torch.compile(pipe.vae, mode="reduce-overhead", fullgraph=True) |
| pipe.unet = torch.compile(pipe.unet, mode="reduce-overhead", fullgraph=True) |
| pipe.set_progress_bar_config(disable=True) |
| |
| with imageio.get_reader(path_in) as reader: |
| size = reader.get_meta_data()['size'] |
| last_frame_latent = None |
| latent_common = torch.randn( |
| (1, 4, 768 * size[1] // (8 * max(size)), 768 * size[0] // (8 * max(size))) |
| ).to(device=device, dtype=torch.float16) |
| |
| out = [] |
| for frame_id, frame in tqdm(enumerate(reader), desc="Processing Video"): |
| frame = Image.fromarray(frame) |
| latents = latent_common |
| if last_frame_latent is not None: |
| latents = 0.9 * latents + 0.1 * last_frame_latent |
| |
| depth = pipe( |
| frame, |
| num_inference_steps=1, |
| match_input_resolution=False, |
| latents=latents, |
| output_latent=True, |
| ) |
| last_frame_latent = depth.latent |
| out.append(pipe.image_processor.visualize_depth(depth.prediction)[0]) |
| |
| diffusers.utils.export_to_gif(out, path_out, fps=reader.get_meta_data()['fps']) |
| ``` |
| |
| Here, the diffusion process starts from the given computed latent. |
| The pipeline sets `output_latent=True` to access `out.latent` and computes its contribution to the next frame's latent |
| initialization. |
| The result is much more stable now: |
|
|
| <div class="flex gap-4"> |
| <div style="flex: 1 1 50%; max-width: 50%;"> |
| <img class="rounded-xl" src="https://huggingface.co/datasets/huggingface/documentation-images/resolve/main/marigold/marigold_obama_depth_independent.gif"/> |
| <figcaption class="mt-1 text-center text-sm text-gray-500">Marigold Depth applied to input video frames independently</figcaption> |
| </div> |
| <div style="flex: 1 1 50%; max-width: 50%;"> |
| <img class="rounded-xl" src="https://huggingface.co/datasets/huggingface/documentation-images/resolve/main/marigold/marigold_obama_depth_consistent.gif"/> |
| <figcaption class="mt-1 text-center text-sm text-gray-500">Marigold Depth with forced latents initialization</figcaption> |
| </div> |
| </div> |
| |
| ## Marigold for ControlNet |
|
|
| A very common application for depth prediction with diffusion models comes in conjunction with ControlNet. |
| Depth crispness plays a crucial role in obtaining high-quality results from ControlNet. |
| As seen in comparisons with other methods above, Marigold excels at that task. |
| The snippet below demonstrates how to load an image, compute depth, and pass it into ControlNet in a compatible format: |
|
|
| ```python |
| import torch |
| import diffusers |
| |
| device = "cuda" |
| generator = torch.Generator(device=device).manual_seed(2024) |
| image = diffusers.utils.load_image( |
| "https://huggingface.co/datasets/huggingface/documentation-images/resolve/main/diffusers/controlnet_depth_source.png" |
| ) |
| |
| pipe = diffusers.MarigoldDepthPipeline.from_pretrained( |
| "prs-eth/marigold-depth-v1-1", torch_dtype=torch.float16, variant="fp16" |
| ).to(device) |
| |
| depth_image = pipe(image, generator=generator).prediction |
| depth_image = pipe.image_processor.visualize_depth(depth_image, color_map="binary") |
| depth_image[0].save("motorcycle_controlnet_depth.png") |
| |
| controlnet = diffusers.ControlNetModel.from_pretrained( |
| "diffusers/controlnet-depth-sdxl-1.0", torch_dtype=torch.float16, variant="fp16" |
| ).to(device) |
| pipe = diffusers.StableDiffusionXLControlNetPipeline.from_pretrained( |
| "SG161222/RealVisXL_V4.0", torch_dtype=torch.float16, variant="fp16", controlnet=controlnet |
| ).to(device) |
| pipe.scheduler = diffusers.DPMSolverMultistepScheduler.from_config(pipe.scheduler.config, use_karras_sigmas=True) |
| |
| controlnet_out = pipe( |
| prompt="high quality photo of a sports bike, city", |
| negative_prompt="", |
| guidance_scale=6.5, |
| num_inference_steps=25, |
| image=depth_image, |
| controlnet_conditioning_scale=0.7, |
| control_guidance_end=0.7, |
| generator=generator, |
| ).images |
| controlnet_out[0].save("motorcycle_controlnet_out.png") |
| ``` |
|
|
| <div class="flex gap-4"> |
| <div style="flex: 1 1 33%; max-width: 33%;"> |
| <img class="rounded-xl" src="https://huggingface.co/datasets/huggingface/documentation-images/resolve/main/diffusers/controlnet_depth_source.png"/> |
| <figcaption class="mt-1 text-center text-sm text-gray-500"> |
| Input image |
| </figcaption> |
| </div> |
| <div style="flex: 1 1 33%; max-width: 33%;"> |
| <img class="rounded-xl" src="https://huggingface.co/datasets/huggingface/documentation-images/resolve/main/marigold/motorcycle_controlnet_depth.png"/> |
| <figcaption class="mt-1 text-center text-sm text-gray-500"> |
| Depth in the format compatible with ControlNet |
| </figcaption> |
| </div> |
| <div style="flex: 1 1 33%; max-width: 33%;"> |
| <img class="rounded-xl" src="https://huggingface.co/datasets/huggingface/documentation-images/resolve/main/marigold/motorcycle_controlnet_out.png"/> |
| <figcaption class="mt-1 text-center text-sm text-gray-500"> |
| ControlNet generation, conditioned on depth and prompt: "high quality photo of a sports bike, city" |
| </figcaption> |
| </div> |
| </div> |
| |
| ## Quantitative Evaluation |
|
|
| To evaluate Marigold quantitatively in standard leaderboards and benchmarks (such as NYU, KITTI, and other datasets), |
| follow the evaluation protocol outlined in the paper: load the full precision fp32 model and use appropriate values |
| for `num_inference_steps` and `ensemble_size`. |
| Optionally seed randomness to ensure reproducibility. |
| Maximizing `batch_size` will deliver maximum device utilization. |
|
|
| ```python |
| import diffusers |
| import torch |
| |
| device = "cuda" |
| seed = 2024 |
| |
| generator = torch.Generator(device=device).manual_seed(seed) |
| pipe = diffusers.MarigoldDepthPipeline.from_pretrained("prs-eth/marigold-depth-v1-1").to(device) |
| |
| image = diffusers.utils.load_image("https://marigoldmonodepth.github.io/images/einstein.jpg") |
| |
| depth = pipe( |
| image, |
| num_inference_steps=4, # set according to the evaluation protocol from the paper |
| ensemble_size=10, # set according to the evaluation protocol from the paper |
| generator=generator, |
| ) |
| |
| # evaluate metrics |
| ``` |
|
|
| ## Using Predictive Uncertainty |
|
|
| The ensembling mechanism built into Marigold pipelines combines multiple predictions obtained from different random |
| latents. |
| As a side effect, it can be used to quantify epistemic (model) uncertainty; simply specify `ensemble_size` greater |
| or equal than 3 and set `output_uncertainty=True`. |
| The resulting uncertainty will be available in the `uncertainty` field of the output. |
| It can be visualized as follows: |
|
|
| ```python |
| import diffusers |
| import torch |
| |
| pipe = diffusers.MarigoldDepthPipeline.from_pretrained( |
| "prs-eth/marigold-depth-v1-1", variant="fp16", torch_dtype=torch.float16 |
| ).to("cuda") |
| |
| image = diffusers.utils.load_image("https://marigoldmonodepth.github.io/images/einstein.jpg") |
| |
| depth = pipe( |
| image, |
| ensemble_size=10, # any number >= 3 |
| output_uncertainty=True, |
| ) |
| |
| uncertainty = pipe.image_processor.visualize_uncertainty(depth.uncertainty) |
| uncertainty[0].save("einstein_depth_uncertainty.png") |
| ``` |
|
|
| <div class="flex gap-4"> |
| <div style="flex: 1 1 33%; max-width: 33%;"> |
| <img class="rounded-xl" src="https://huggingface.co/datasets/huggingface/documentation-images/resolve/main/marigold/marigold_einstein_depth_uncertainty.png"/> |
| <figcaption class="mt-1 text-center text-sm text-gray-500"> |
| Depth uncertainty |
| </figcaption> |
| </div> |
| <div style="flex: 1 1 33%; max-width: 33%;"> |
| <img class="rounded-xl" src="https://huggingface.co/datasets/huggingface/documentation-images/resolve/main/marigold/marigold_einstein_normals_uncertainty.png"/> |
| <figcaption class="mt-1 text-center text-sm text-gray-500"> |
| Surface normals uncertainty |
| </figcaption> |
| </div> |
| <div style="flex: 1 1 33%; max-width: 33%;"> |
| <img class="rounded-xl" src="https://huggingface.co/datasets/huggingface/documentation-images/resolve/4f83035d84a24e5ec44fdda129b1d51eba12ce04/marigold/marigold_einstein_albedo_uncertainty.png"/> |
| <figcaption class="mt-1 text-center text-sm text-gray-500"> |
| Albedo uncertainty |
| </figcaption> |
| </div> |
| </div> |
| |
| The interpretation of uncertainty is easy: higher values (white) correspond to pixels, where the model struggles to |
| make consistent predictions. |
| - The depth model exhibits the most uncertainty around discontinuities, where object depth changes abruptly. |
| - The surface normals model is least confident in fine-grained structures like hair and in dark regions such as the |
| collar area. |
| - Albedo uncertainty is represented as an RGB image, as it captures uncertainty independently for each color channel, |
| unlike depth and surface normals. It is also higher in shaded regions and at discontinuities. |
|
|
| ## Conclusion |
|
|
| We hope Marigold proves valuable for your downstream tasks, whether as part of a broader generative workflow or for |
| perception-based applications like 3D reconstruction. |