/lightly

A python library for self-supervised learning on images.

Primary LanguagePythonMIT LicenseMIT

LightlySSL self-supervised learning Logo

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LightlySSL is a computer vision framework for self-supervised learning.

For a commercial version with more features, including Docker support and pretraining models for embedding, classification, detection, and segmentation tasks with a single command, please contact sales@lightly.ai.

We've also built a whole platform on top, with additional features for active learning and data curation. If you're interested in the Lightly Worker Solution to easily process millions of samples and run powerful algorithms on your data, check out lightly.ai. It's free to get started!

Features

This self-supervised learning framework offers the following features:

  • Modular framework, which exposes low-level building blocks such as loss functions and model heads.
  • Easy to use and written in a PyTorch-like style.
  • Supports custom backbone models for self-supervised pre-training.
  • Support for distributed training using PyTorch Lightning.

Supported Models

You can find sample code for all the supported models here. We provide PyTorch, PyTorch Lightning, and PyTorch Lightning distributed examples for all models to kickstart your project.

Models:

Model Year Paper Docs Colab (PyTorch) Colab (PyTorch Lightning)
AIM 2024 paper docs Open In Colab Open In Colab
Barlow Twins 2021 paper docs Open In Colab Open In Colab
BYOL 2020 paper docs Open In Colab Open In Colab
DCL & DCLW 2021 paper docs Open In Colab Open In Colab
DenseCL 2021 paper docs Open In Colab Open In Colab
DINO 2021 paper docs Open In Colab Open In Colab
MAE 2021 paper docs Open In Colab Open In Colab
MSN 2022 paper docs Open In Colab Open In Colab
MoCo 2019 paper docs Open In Colab Open In Colab
NNCLR 2021 paper docs Open In Colab Open In Colab
PMSN 2022 paper docs Open In Colab Open In Colab
SimCLR 2020 paper docs Open In Colab Open In Colab
SimMIM 2022 paper docs Open In Colab Open In Colab
SimSiam 2021 paper docs Open In Colab Open In Colab
SwaV 2020 paper docs Open In Colab Open In Colab
VICReg 2021 paper docs Open In Colab Open In Colab

Tutorials

Want to jump to the tutorials and see Lightly in action?

Community and partner projects:

Quick Start

Lightly requires Python 3.7+. We recommend installing Lightly in a Linux or OSX environment. Python 3.13 is not yet supported, as PyTorch itself lacks Python 3.13 compatibility.

Dependencies

Due to the modular nature of the Lightly package some modules can be used with older versions of dependencies. However, to use all features as of today lightly requires the following dependencies:

Lightly is compatible with PyTorch and PyTorch Lightning v2.0+!

Installation

You can install Lightly and its dependencies from PyPI with:

pip3 install lightly

We strongly recommend installing Lightly in a dedicated virtualenv to avoid conflicts with your system packages.

Lightly in Action

With Lightly, you can use the latest self-supervised learning methods in a modular way using the full power of PyTorch. Experiment with various backbones, models, and loss functions. The framework has been designed to be easy to use from the ground up. Find more examples in our docs.

import torch
import torchvision

from lightly import loss
from lightly import transforms
from lightly.data import LightlyDataset
from lightly.models.modules import heads


# Create a PyTorch module for the SimCLR model.
class SimCLR(torch.nn.Module):
    def __init__(self, backbone):
        super().__init__()
        self.backbone = backbone
        self.projection_head = heads.SimCLRProjectionHead(
            input_dim=512,  # Resnet18 features have 512 dimensions.
            hidden_dim=512,
            output_dim=128,
        )

    def forward(self, x):
        features = self.backbone(x).flatten(start_dim=1)
        z = self.projection_head(features)
        return z


# Use a resnet backbone from torchvision.
backbone = torchvision.models.resnet18()
# Ignore the classification head as we only want the features.
backbone.fc = torch.nn.Identity()

# Build the SimCLR model.
model = SimCLR(backbone)

# Prepare transform that creates multiple random views for every image.
transform = transforms.SimCLRTransform(input_size=32, cj_prob=0.5)


# Create a dataset from your image folder.
dataset = LightlyDataset(input_dir="./my/cute/cats/dataset/", transform=transform)

# Build a PyTorch dataloader.
dataloader = torch.utils.data.DataLoader(
    dataset,  # Pass the dataset to the dataloader.
    batch_size=128,  # A large batch size helps with the learning.
    shuffle=True,  # Shuffling is important!
)

# Lightly exposes building blocks such as loss functions.
criterion = loss.NTXentLoss(temperature=0.5)

# Get a PyTorch optimizer.
optimizer = torch.optim.SGD(model.parameters(), lr=0.1, weight_decay=1e-6)

# Train the model.
for epoch in range(10):
    for (view0, view1), targets, filenames in dataloader:
        z0 = model(view0)
        z1 = model(view1)
        loss = criterion(z0, z1)
        loss.backward()
        optimizer.step()
        optimizer.zero_grad()
        print(f"loss: {loss.item():.5f}")

You can easily use another model like SimSiam by swapping the model and the loss function.

# PyTorch module for the SimSiam model.
class SimSiam(torch.nn.Module):
    def __init__(self, backbone):
        super().__init__()
        self.backbone = backbone
        self.projection_head = heads.SimSiamProjectionHead(512, 512, 128)
        self.prediction_head = heads.SimSiamPredictionHead(128, 64, 128)

    def forward(self, x):
        features = self.backbone(x).flatten(start_dim=1)
        z = self.projection_head(features)
        p = self.prediction_head(z)
        z = z.detach()
        return z, p


model = SimSiam(backbone)

# Use the SimSiam loss function.
criterion = loss.NegativeCosineSimilarity()

You can find a more complete example for SimSiam here.

Use PyTorch Lightning to train the model:

from pytorch_lightning import LightningModule, Trainer

class SimCLR(LightningModule):
    def __init__(self):
        super().__init__()
        resnet = torchvision.models.resnet18()
        resnet.fc = torch.nn.Identity()
        self.backbone = resnet
        self.projection_head = heads.SimCLRProjectionHead(512, 512, 128)
        self.criterion = loss.NTXentLoss()

    def forward(self, x):
        features = self.backbone(x).flatten(start_dim=1)
        z = self.projection_head(features)
        return z

    def training_step(self, batch, batch_index):
        (view0, view1), _, _ = batch
        z0 = self.forward(view0)
        z1 = self.forward(view1)
        loss = self.criterion(z0, z1)
        return loss

    def configure_optimizers(self):
        optim = torch.optim.SGD(self.parameters(), lr=0.06)
        return optim


model = SimCLR()
trainer = Trainer(max_epochs=10, devices=1, accelerator="gpu")
trainer.fit(model, dataloader)

See our docs for a full PyTorch Lightning example.

Or train the model on 4 GPUs:

# Use distributed version of loss functions.
criterion = loss.NTXentLoss(gather_distributed=True)

trainer = Trainer(
    max_epochs=10,
    devices=4,
    accelerator="gpu",
    strategy="ddp",
    sync_batchnorm=True,
    use_distributed_sampler=True,  # or replace_sampler_ddp=True for PyTorch Lightning <2.0
)
trainer.fit(model, dataloader)

We provide multi-GPU training examples with distributed gather and synchronized BatchNorm. Have a look at our docs regarding distributed training.

Benchmarks

Implemented models and their performance on various datasets. Hyperparameters are not tuned for maximum accuracy. For detailed results and more information about the benchmarks click here.

ImageNet1k

ImageNet1k benchmarks

Note: Evaluation settings are based on these papers:

See the benchmarking scripts for details.

Model Backbone Batch Size Epochs Linear Top1 Finetune Top1 kNN Top1 Tensorboard Checkpoint
BarlowTwins Res50 256 100 62.9 72.6 45.6 link link
BYOL Res50 256 100 62.5 74.5 46.0 link link
DINO Res50 128 100 68.2 72.5 49.9 link link
MAE ViT-B/16 256 100 46.0 81.3 11.2 link link
MoCoV2 Res50 256 100 61.5 74.3 41.8 link link
SimCLR* Res50 256 100 63.2 73.9 44.8 link link
SimCLR* + DCL Res50 256 100 65.1 73.5 49.6 link link
SimCLR* + DCLW Res50 256 100 64.5 73.2 48.5 link link
SwAV Res50 256 100 67.2 75.4 49.5 link link
TiCo Res50 256 100 49.7 72.7 26.6 link link
VICReg Res50 256 100 63.0 73.7 46.3 link link

*We use square root learning rate scaling instead of linear scaling as it yields better results for smaller batch sizes. See Appendix B.1 in the SimCLR paper.

ImageNet100

ImageNet100 benchmarks detailed results

Imagenette

Imagenette benchmarks detailed results

CIFAR-10

CIFAR-10 benchmarks detailed results

Terminology

Below you can see a schematic overview of the different concepts in the package. The terms in bold are explained in more detail in our documentation.

Overview of the Lightly pip package

Next Steps

Head to the documentation and see the things you can achieve with Lightly!

Development

To install dev dependencies (for example to contribute to the framework) you can use the following command:

pip3 install -e ".[dev]"

For more information about how to contribute have a look here.

Running Tests

Unit tests are within the tests directory and we recommend running them using pytest. There are two test configurations available. By default, only a subset will be run:

make test-fast

To run all tests (including the slow ones) you can use the following command:

make test

To test a specific file or directory use:

pytest <path to file or directory>

Code Formatting

To format code with black and isort run:

make format

Further Reading

Self-Supervised Learning:

FAQ

  • Why should I care about self-supervised learning? Aren't pre-trained models from ImageNet much better for transfer learning?

    • Self-supervised learning has become increasingly popular among scientists over the last years because the learned representations perform extraordinarily well on downstream tasks. This means that they capture the important information in an image better than other types of pre-trained models. By training a self-supervised model on your dataset, you can make sure that the representations have all the necessary information about your images.
  • How can I contribute?

    • Create an issue if you encounter bugs or have ideas for features we should implement. You can also add your own code by forking this repository and creating a PR. More details about how to contribute with code is in our contribution guide.
  • Is this framework for free?

    • Yes, this framework is completely free to use and we provide the source code. We believe that we need to make training deep learning models more data efficient to achieve widespread adoption. One step to achieve this goal is by leveraging self-supervised learning. The company behind Lightly is committed to keep this framework open-source.
  • If this framework is free, how is the company behind Lightly making money?

    • Training self-supervised models is only one part of our solution. The company behind Lightly focuses on processing and analyzing embeddings created by self-supervised models. By building, what we call a self-supervised active learning loop we help companies understand and work with their data more efficiently. As the Lightly Solution is a freemium product, you can try it out for free. However, we will charge for some features.
    • In any case this framework will always be free to use, even for commercial purposes.

Lightly in Research

Company behind this Open Source Framework

Lightly is a spin-off from ETH Zurich that helps companies build efficient active learning pipelines to select the most relevant data for their models.

You can find out more about the company and it's services by following the links below:

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