Normalized Cut and Nyström Approximation
Project description
🌐Documentation | 🤗HuggingFace Demo
NCUT: Nyström Normalized Cut
Normalized Cut, aka. spectral clustering, is a graphical method to analyze data grouping in the affinity eigenvector space. It has been widely used for unsupervised segmentation in the 2000s.
Nyström Normalized Cut, is a new approximation algorithm developed for large-scale graph cuts, a large-graph of million nodes can be processed in under 10s (cpu) or 2s (gpu).
https://github.com/user-attachments/assets/f0d40b1f-b8a5-4077-ab5f-e405f3ffb70f
Installation
1. Install PyTorch
conda install pytorch torchvision torchaudio pytorch-cuda=11.8 -c pytorch -c nvidia
2. Install ncut-pytorch
pip install ncut-pytorch
Trouble Shooting
In case of pip install failed, please try install the build dependencies
Option A:
sudo apt-get update && sudo apt-get install build-essential cargo rustc -y
Option B:
conda install rust -c conda-forge
Option C:
curl --proto '=https' --tlsv1.2 -sSf https://sh.rustup.rs | sh && . "$HOME/.cargo/env"
Quick Start
Minimal example on how to run NCUT:
import torch
from ncut_pytorch import NCUT, rgb_from_tsne_3d
model_features = torch.rand(20, 64, 64, 768) # (B, H, W, C)
inp = model_features.reshape(-1, 768) # flatten
eigvectors, eigvalues = NCUT(num_eig=100, device='cuda:0').fit_transform(inp)
tsne_x3d, tsne_rgb = rgb_from_tsne_3d(eigvectors, device='cuda:0')
eigvectors = eigvectors.reshape(20, 64, 64, 100) # (B, H, W, num_eig)
tsne_rgb = tsne_rgb.reshape(20, 64, 64, 3) # (B, H, W, 3)
Load Feature Extractor Model
Any backbone model works as plug-in feature extractor. We have implemented some backbone models, here is a list of available models:
from ncut_pytorch.backbone import list_models
print(list_models())
[
'SAM2(sam2_hiera_t)', 'SAM2(sam2_hiera_s)', 'SAM2(sam2_hiera_b+)', 'SAM2(sam2_hiera_l)',
'SAM(sam_vit_b)', 'SAM(sam_vit_l)', 'SAM(sam_vit_h)', 'MobileSAM(TinyViT)',
'DiNOv2reg(dinov2_vits14_reg)', 'DiNOv2reg(dinov2_vitb14_reg)', 'DiNOv2reg(dinov2_vitl14_reg)', 'DiNOv2reg(dinov2_vitg14_reg)',
'DiNOv2(dinov2_vits14)', 'DiNOv2(dinov2_vitb14)', 'DiNOv2(dinov2_vitl14)', 'DiNOv2(dinov2_vitg14)',
'DiNO(dino_vits8_896)', 'DiNO(dino_vitb8_896)', 'DiNO(dino_vits8_672)', 'DiNO(dino_vitb8_672)', 'DiNO(dino_vits8_448)', 'DiNO(dino_vitb8_448)', 'DiNO(dino_vits16_448)', 'DiNO(dino_vitb16_448)',
'Diffusion(stabilityai/stable-diffusion-2)', 'Diffusion(CompVis/stable-diffusion-v1-4)', 'Diffusion(stabilityai/stable-diffusion-3-medium-diffusers)',
'CLIP(ViT-B-16/openai)', 'CLIP(ViT-L-14/openai)', 'CLIP(ViT-H-14/openai)', 'CLIP(ViT-B-16/laion2b_s34b_b88k)',
'CLIP(convnext_base_w_320/laion_aesthetic_s13b_b82k)', 'CLIP(convnext_large_d_320/laion2b_s29b_b131k_ft_soup)', 'CLIP(convnext_xxlarge/laion2b_s34b_b82k_augreg_soup)',
'CLIP(eva02_base_patch14_448/mim_in22k_ft_in1k)', "CLIP(eva02_large_patch14_448/mim_m38m_ft_in22k_in1k)",
'MAE(vit_base)', 'MAE(vit_large)', 'MAE(vit_huge)',
'ImageNet(vit_base)'
]
Image model example:
import torch
from ncut_pytorch import NCUT, rgb_from_tsne_3d
from ncut_pytorch.backbone import load_model, extract_features
model = load_model(model_name="SAM(sam_vit_b)")
images = torch.rand(20, 3, 1024, 1024)
model_features = extract_features(images, model, node_type='attn', layer=6)
# model_features = model(images)['attn'][6] # this also works
inp = model_features.reshape(-1, 768) # flatten
eigvectors, eigvalues = NCUT(num_eig=100, device='cuda:0').fit_transform(inp)
tsne_x3d, tsne_rgb = rgb_from_tsne_3d(eigvectors, device='cuda:0')
eigvectors = eigvectors.reshape(20, 64, 64, 100) # (B, H, W, num_eig)
tsne_rgb = tsne_rgb.reshape(20, 64, 64, 3) # (B, H, W, 3)
Text model example:
import os
from ncut_pytorch import NCUT, rgb_from_tsne_3d
from ncut_pytorch.backbone_text import load_text_model
os.environ['HF_ACCESS_TOKEN'] = "your_huggingface_token"
llama = load_text_model("meta-llama/Meta-Llama-3.1-8B").cuda()
output_dict = llama("The quick white fox jumps over the lazy cat.")
model_features = output_dict['block'][31].squeeze(0) # 32nd block output
token_texts = output_dict['token_texts']
eigvectors, eigvalues = NCUT(num_eig=5, device='cuda:0').fit_transform(model_features)
tsne_x3d, tsne_rgb = rgb_from_tsne_3d(eigvectors, device='cuda:0')
# eigvectors.shape[0] == tsne_rgb.shape[0] == len(token_texts)
paper in prep, Yang 2024
AlignedCut: Visual Concepts Discovery on Brain-Guided Universal Feature Space, Huzheng Yang, James Gee*, Jianbo Shi*,2024
Normalized Cuts and Image Segmentation, Jianbo Shi and Jitendra Malik, 2000
Release history Release notifications | RSS feed
Download files
Download the file for your platform. If you're not sure which to choose, learn more about installing packages.
Source Distribution
Built Distribution
Filter files by name, interpreter, ABI, and platform.
If you're not sure about the file name format, learn more about wheel file names.
Copy a direct link to the current filters
File details
Details for the file ncut_pytorch-1.13.1.tar.gz.
File metadata
- Download URL: ncut_pytorch-1.13.1.tar.gz
- Upload date:
- Size: 42.8 kB
- Tags: Source
- Uploaded using Trusted Publishing? No
- Uploaded via: twine/6.1.0 CPython/3.11.10
File hashes
| Algorithm | Hash digest | |
|---|---|---|
| SHA256 |
8370013b842785df6f0c5a975f0842bf27b3b4acf12affe20ddb6d53721f25b4
|
|
| MD5 |
19497eb475dc2ddea079b3488b382aca
|
|
| BLAKE2b-256 |
4e40f2d9f081d864056a7eeed80d343001385f817633b4349316dd63225e536a
|
File details
Details for the file ncut_pytorch-1.13.1-py3-none-any.whl.
File metadata
- Download URL: ncut_pytorch-1.13.1-py3-none-any.whl
- Upload date:
- Size: 41.4 kB
- Tags: Python 3
- Uploaded using Trusted Publishing? No
- Uploaded via: twine/6.1.0 CPython/3.11.10
File hashes
| Algorithm | Hash digest | |
|---|---|---|
| SHA256 |
aff3677f018a623c008372a5a57ea1001ba5adc5d164ec302492a4489d4b5587
|
|
| MD5 |
101f1de7a499c7855ba2e9ea9d193f47
|
|
| BLAKE2b-256 |
5366c1b3229ada8b0585093f1f0dacc330bfa1a069629a448abf4589edd1c122
|
