Metadata-Version: 2.4
Name: stable-pretraining
Version: 0.1.4
Summary: Stable Pretraining Library for Self-Supervised Learning
License: MIT
Description-Content-Type: text/markdown
License-File: LICENSE
Requires-Dist: torch
Requires-Dist: torchvision
Requires-Dist: torchmetrics
Requires-Dist: lightning
Requires-Dist: hydra-core
Requires-Dist: omegaconf
Requires-Dist: loguru
Requires-Dist: tabulate
Requires-Dist: pandas
Requires-Dist: rich
Requires-Dist: requests-cache
Requires-Dist: prettytable
Requires-Dist: submitit
Requires-Dist: timm
Provides-Extra: vision
Requires-Dist: transformers; extra == "vision"
Requires-Dist: pillow>=11.3.0; extra == "vision"
Provides-Extra: tracking
Requires-Dist: wandb; extra == "tracking"
Provides-Extra: cluster
Requires-Dist: hydra-submitit-launcher; extra == "cluster"
Provides-Extra: visualization
Requires-Dist: matplotlib; extra == "visualization"
Provides-Extra: datasets
Requires-Dist: datasets; extra == "datasets"
Requires-Dist: pyarrow==20.0.0; extra == "datasets"
Requires-Dist: minari[hdf5]>=0.5.3; extra == "datasets"
Provides-Extra: extras
Requires-Dist: scikit-learn>=1.7.0; extra == "extras"
Requires-Dist: richuru; extra == "extras"
Provides-Extra: all
Requires-Dist: stable-pretraining[cluster,datasets,extras,tracking,vision,visualization]; extra == "all"
Provides-Extra: dev
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Requires-Dist: sphinxcontrib-bibtex; extra == "doc"
Requires-Dist: matplotlib; extra == "doc"
Requires-Dist: memory_profiler; extra == "doc"
Requires-Dist: myst-parser; extra == "doc"
Dynamic: license-file

# stable-pretraining

[![Documentation](https://img.shields.io/badge/Documentation-blue.svg)](https://rbalestr-lab.github.io/stable-pretraining.github.io/dev/)
[![Benchmarks](https://img.shields.io/badge/Benchmarks-blue.svg)](https://github.com/rbalestr-lab/stable-pretraining/tree/main/benchmarks)
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[![WandB](https://raw.githubusercontent.com/wandb/assets/main/wandb-github-badge-gradient.svg)](https://wandb.ai/site)



AI is moving beyond labels. Today's models learn through **self-supervision** and **multimodal alignment**, extracting knowledge from raw data to build general-purpose representations that work across tasks. These foundation models are then deployed at scale, often after finetuning, to solve tasks in zero or few shot.

`stable-pretraining` is a PyTorch framework built on top of Lightning for this new paradigm. What sets us apart is **real-time visibility into training quality** through extensive logging and monitoring. Our callback ecosystem (`OnlineProbe`, `OnlineKNN`, `RankMe`, and many more) provides insights into feature collapse, training dynamics, and downstream performance. Data flow as dictionaries through model components, metrics, and callbacks, making any intermediate value accessible and debuggable. With `stable-pretraining`: track everything, debug faster, iterate sooner.

Join our Discord: [https://discord.gg/8M6hT39X](https://discord.gg/adzpqWKM25)

## How?

To reach flexibility, scalability and stability, we rely on battle-tested third party libraries: `PyTorch`, `Lightning`, `HuggingFace`, `TorchMetrics` amongst a few others. Those dependencies allow us to focus on assembling everything into a powerful ML framework. ``stable-pretraining`` adopts a flexible and modular design for seamless integration of components from external libraries, including architectures, loss functions, evaluation metrics, and augmentations.

## Core Structure

`stable-pretraining` simplifies complex ML workflows into 4 intuitive components:

### 1 - Data
Your dataset must follow a dictionary-structured format where each sample is a dictionary with named fields (e.g., `{"image": ..., "label": ...}`). This ensures consistent behavior across all components. You have multiple options for creating datasets:

- **HuggingFace datasets** (if available on the Hub):
```python
import stable_pretraining as spt
train_dataset = spt.data.HFDataset(
    path="frgfm/imagenette",
    name="160px",
    split="train",
    transform=train_transform,
)
```

- **From PyTorch datasets**:
```python
train_dataset = spt.data.FromTorchDataset(
    torchvision_dataset,
    names=["image", "label"],  # Map tuple outputs to dictionary keys
    transform=train_transform,
)
```

- **Custom datasets**: Any dataset that returns dictionaries

```python
datamodule = spt.data.DataModule(train=train_dataloader, val=val_dataloader)
```

### 2 - Module
The key differentiator from PyTorch Lightning - **you only define the `forward` function**, not `training_step`! This unified approach computes losses and generates useful quantities that can be retrieved for monitoring and analysis:

```python
# Use the pre-built forward functions from stable_pretraining
from stable_pretraining import forward

# Simply use the appropriate forward for your method
module = spt.Module(
    backbone=backbone,
    projector=projector,
    forward=forward.simclr_forward,  # Or byol_forward, vicreg_forward, etc.
    simclr_loss=spt.losses.NTXEntLoss(temperature=0.5),
    optim={
        "optimizer": {"type": "Adam", "lr": 0.001},
        "scheduler": {"type": "CosineAnnealingLR"},
        "interval": "epoch"
    }
)
```

Or define your own custom forward:
```python
def forward(self, batch, stage):
    out = {}

    if isinstance(batch, list):
        # Multi-view training - batch is a list of view dicts
        embeddings = [self.backbone(view["image"]) for view in batch]
        out["embedding"] = torch.cat(embeddings, dim=0)

        if self.training:
            projections = [self.projector(emb) for emb in embeddings]
            out["loss"] = self.simclr_loss(projections[0], projections[1])
    else:
        # Single-view validation
        out["embedding"] = self.backbone(batch["image"])

    return out
```

**Key points:**
- The `forward` method defines both the loss and any quantities to monitor
- No need to override `training_step`, `validation_step`, etc.
- Return a dictionary with a `"loss"` key for training
- All model components are passed as kwargs to `spt.Module`

### 3 - Callbacks
Monitor and evaluate your models in real-time during training. Callbacks are key ingredients of `stable-pretraining`, providing rich insights without interrupting your training flow:

```python
# Monitor SSL representations with a linear probe
linear_probe = spt.callbacks.OnlineProbe(
    name="linear_probe",  # Useful for retrieving metrics and values in logging
    input="embedding",  # Which output from forward to monitor
    target="label",      # Ground truth from batch
    probe=torch.nn.Linear(512, 10),
    loss_fn=torch.nn.CrossEntropyLoss(),
    metrics={
        "top1": torchmetrics.classification.MulticlassAccuracy(10),
        "top5": torchmetrics.classification.MulticlassAccuracy(10, top_k=5),
    },
)

# Track representation quality with KNN evaluation
knn_probe = spt.callbacks.OnlineKNN(
    name="knn_probe",
    input="embedding",
    target="label",
    queue_length=20000,
    k=10,
)
```

Callbacks are powered by an intelligent queue management system that automatically shares memory between callbacks monitoring the same data thus eliminating redundant computations.

**Why callbacks matter:** Get real-time feedback on representation quality, catch issues like collapse early, and track multiple metrics simultaneously for deeper insights.

### 4 - Trainer
Orchestrate everything together with PyTorch Lightning's `Trainer`:

```python
trainer = pl.Trainer(
    max_epochs=10,
    num_sanity_val_steps=1,
    callbacks=[linear_probe, knn_probe, rankme],  # Your monitoring callbacks
    precision="16-mixed",
    logger=False,
    enable_checkpointing=False,
)
manager = spt.Manager(trainer=trainer, module=module, data=data)
manager()
```

Once configured, the `Manager` connects all components and handles the training loop with precise logging and monitoring (optional).

## Complete Example

<details>
<summary>SimCLR on CIFAR-10</summary>

This example demonstrates the key features of `stable-pretraining`: dictionary-structured data, unified forward function, and rich monitoring through callbacks.

```python
import lightning as pl
import torch
import torchmetrics
import torchvision
from torch import nn
from lightning.pytorch.loggers import WandbLogger

import stable_pretraining as spt
from stable_pretraining import forward
from stable_pretraining.data import transforms

# Define augmentations for SimCLR (creates 2 views of each image)
simclr_transform = transforms.MultiViewTransform(
    [
        transforms.Compose(
            transforms.RGB(),
            transforms.RandomResizedCrop((32, 32), scale=(0.2, 1.0)),
            transforms.RandomHorizontalFlip(p=0.5),
            transforms.ColorJitter(brightness=0.4, contrast=0.4, saturation=0.2, hue=0.1, p=0.8),
            transforms.RandomGrayscale(p=0.2),
            transforms.ToImage(**spt.data.static.CIFAR10),
        ),
        # Second view with slightly different augmentations
        transforms.Compose(
            transforms.RGB(),
            transforms.RandomResizedCrop((32, 32), scale=(0.08, 1.0)),
            transforms.RandomHorizontalFlip(p=0.5),
            transforms.ColorJitter(brightness=0.4, contrast=0.4, saturation=0.2, hue=0.1, p=0.8),
            transforms.RandomGrayscale(p=0.2),
            transforms.RandomSolarize(threshold=0.5, p=0.2),
            transforms.ToImage(**spt.data.static.CIFAR10),
        ),
    ]
)

# Load CIFAR-10 and wrap in dictionary format
cifar_train = torchvision.datasets.CIFAR10(root="./data", train=True, download=True)
cifar_val = torchvision.datasets.CIFAR10(root="./data", train=False, download=True)

train_dataset = spt.data.FromTorchDataset(
    cifar_train,
    names=["image", "label"],  # Convert tuple to dictionary
    transform=simclr_transform,
)

val_dataset = spt.data.FromTorchDataset(
    cifar_val,
    names=["image", "label"],
    transform=transforms.Compose(
        transforms.RGB(),
        transforms.Resize((32, 32)),
        transforms.ToImage(**spt.data.static.CIFAR10),
    ),
)

# Create dataloaders - MultiViewTransform handles the view creation
train_dataloader = torch.utils.data.DataLoader(
    dataset=train_dataset,
    batch_size=256,
    num_workers=8,
    drop_last=True,
    shuffle=True,  # Simple shuffle, no RepeatedRandomSampler needed
)

val_dataloader = torch.utils.data.DataLoader(
    dataset=val_dataset,
    batch_size=256,
    num_workers=10,
)

data = spt.data.DataModule(train=train_dataloader, val=val_dataloader)

# Build model components
backbone = spt.backbone.from_torchvision("resnet18", low_resolution=True)
backbone.fc = torch.nn.Identity()  # Remove classification head

projector = nn.Sequential(
    nn.Linear(512, 2048),
    nn.BatchNorm1d(2048),
    nn.ReLU(inplace=True),
    nn.Linear(2048, 2048),
    nn.BatchNorm1d(2048),
    nn.ReLU(inplace=True),
    nn.Linear(2048, 256),
)

# Create the module using the built-in SimCLR forward function
module = spt.Module(
    backbone=backbone,
    projector=projector,
    forward=forward.simclr_forward,  # Use the built-in forward function
    simclr_loss=spt.losses.NTXEntLoss(temperature=0.5),
    optim={
        "optimizer": {"type": "LARS", "lr": 5, "weight_decay": 1e-6},
        "scheduler": {"type": "LinearWarmupCosineAnnealing"},
        "interval": "epoch",
    },
)

# Add callbacks for monitoring performance during training
linear_probe = spt.callbacks.OnlineProbe(
    name="linear_probe",
    input="embedding",
    target="label",
    probe=torch.nn.Linear(512, 10),
    loss_fn=torch.nn.CrossEntropyLoss(),
    metrics={
        "top1": torchmetrics.classification.MulticlassAccuracy(10),
        "top5": torchmetrics.classification.MulticlassAccuracy(10, top_k=5),
    },
)

knn_probe = spt.callbacks.OnlineKNN(
    name="knn_probe",
    input="embedding",
    target="label",
    queue_length=20000,
    metrics={"accuracy": torchmetrics.classification.MulticlassAccuracy(10)},
    input_dim=512,
    k=10,
)

# Configure training
trainer = pl.Trainer(
    max_epochs=1000,
    callbacks=[knn_probe, linear_probe],  # Monitor SSL quality in real-time
    precision="16-mixed",
    logger=WandbLogger(project="cifar10-simclr"),
)

# Launch training
manager = spt.Manager(trainer=trainer, module=module, data=data)
manager()
```
</details>


## 🚀 Quick Start with `spt` CLI

The `spt` command launches training from YAML configuration files using Hydra.

**Note:** `spt` requires YAML configs. If you have Python-based configs, you can:
- Convert them to YAML format where each component uses `_target_` to specify the importable class/function
- See `examples/simclr_cifar10_config.yaml` for the structure and syntax

### Local Training

```bash
# Run with a config file
spt examples/simclr_cifar10_config.yaml

# With parameter overrides
spt examples/simclr_cifar10_config.yaml trainer.max_epochs=50 module.optim.lr=0.01

# Run from any directory - supports absolute and relative paths
spt ../configs/my_config.yaml
spt /path/to/config.yaml
```

### SLURM Cluster Training

For training on SLURM clusters, use the `-m` flag to enable multirun mode:

```bash
# Use the provided SLURM template (customize partition/QOS in the file)
spt examples/simclr_cifar10_slurm.yaml -m

# Override SLURM parameters via command line
spt examples/simclr_cifar10_slurm.yaml -m \
    hydra.launcher.partition=gpu \
    hydra.launcher.qos=normal \
    hydra.launcher.timeout_min=720
```

The SLURM template (`examples/simclr_cifar10_slurm.yaml`) includes placeholders for cluster-specific settings. Either modify the file directly or override values via command line.

## Installation

The library is not yet available on PyPI. You can install it from the source code, as follows.

1. <details><summary>conda (optional)</summary>

    First use your favorite environment manager and install your favorite pytorch version, we provide an example with conda
    ```
    wget https://repo.anaconda.com/miniconda/Miniconda3-latest-Linux-x86_64.sh
    bash Miniconda3-latest-Linux-x86_64.sh
    ```
    follow installation instructions... once completed, create your environment
    ```
    conda create -n my_env python=3.11
    ```
    with your environment name (here `my_env`) and your favorite Python version (here, `3.11`). Once completed, make sure to activate your environment (`conda activate my_env`) before proceeding to the next steps!
  </details>

2. Pytorch and our library (we recommend using `uv` for quicker package management):
    ```bash
    pip3 install uv
    uv pip install torch torchvision torchaudio
    uv pip install -e .  # Core dependencies only
    ```

    For optional features (vision models, experiment tracking, cluster support, etc.):
    ```bash
    uv pip install -e ".[vision,tracking]"  # Example: add vision models and wandb
    uv pip install -e ".[all]"  # Or install all optional dependencies
    ```
    See `pyproject.toml` for available dependency groups (`vision`, `tracking`, `cluster`, `visualization`, `datasets`, `extras`, `dev`, `doc`).

    If you do not want to use uv, simply remove it from the above commands.

3. API login (optional)
    ```
    wandb login
    huggingface-cli login
    ```
4. LATEX support in Matplotlib (optional)

    1.  <details>
        <summary>Install the LaTex font (Computer Modern)</summary>

        - we provide the ttf files [in the repo](assets/cm-unicode-0.7.0%202/) to make things simple
        - create your local folder (if not present) and copy the ttf files there
          - `mkdir -p ~/.local/share/fonts `
          - `cp assets/cm-unicode-0.7.0\ 2/*ttf ~/.local/share/fonts/`
        - refresh the font cache with `fc-cache -f -v`
        - validate that the fonts are listed in your system with `fc-list | grep cmu`
        - refresh matplotlib cache
          ```
          import shutil
          import matplotlib

          shutil.rmtree(matplotlib.get_cachedir())
          ```
        </details>


    2. <details>
        <summary>Install the Tex compiler (optional, if not available on your system)</summary>

        - install texlive locally following https://tug.org/texlive/quickinstall.html#running where you can use `-texdir your_path` to install to a local path (so you don't need sudo privileges)
        - follow the instructions at the end of the installation to edit the PATH variables. If in the above step you used `-texdir ~/texdir` then the path to add should be like `TEXDIR_PATH=/private/home/$USER/texdir/bin/x86_64-linux`. You can use your favorite method such as
          - `export PATH="$TEXDIR_PATH:$PATH"` for local session
          - adding `export PATH="$TEXDIR_PATH:$PATH"` to your `.bashrc`
          - run `conda env config vars set PATH="$TEXDIR_PATH:$PATH"` once for it to be set within your conda env
          - IMPORTANT: if the above is not done you will see an error akin to `! LaTeX Error: File type1ec.sty not found.`
        - make sure inside the conde environment that you point to the right binaries e.g. `whereis latex` and `whereis mktexfmt`
        - If at some point there is an error that the file `latex.fmt` is not found. You can generate it with
          - `pdftex -ini   -jobname=latex -progname=latex -translate-file=cp227.tcx *latex.ini`
          - or (unsure) `fmtutil-sys --all`
        </details>

    3. <details>
        <summary>rc config (optional)</summary>

        ```
        font.family: serif
        font.serif: cmr10
        font.sans-serif: cmss10
        font.monospace: cmtt10

        text.usetex: True
        text.latex.preamble: \usepackage{amssymb} \usepackage{amsmath} \usepackage{bm}

        xtick.labelsize: 14
        ytick.labelsize: 14
        legend.fontsize: 14
        axes.labelsize: 16
        axes.titlesize: 16
        axes.formatter.use_mathtext: True
        ```
        which can be written to a file, e.g., `~/.config/matplotlib/matplotlibrc` or set via `rc` in your script directly. See here for more details.
        </details>

    4. <details>
        <summary>Example of matplotlib script to run for a quick test (optional)</summary>

        ```
        from matplotlib import rc
        rc('font',**{'family':'sans-serif','sans-serif':['Helvetica']})
        rc('text', usetex=True)
        import numpy as np
        import matplotlib.pyplot as plt


        t = np.arange(0.0, 1.0 + 0.01, 0.01)
        s = np.cos(4 * np.pi * t) + 2

        plt.rc('text', usetex=True)
        plt.rc('font', family='serif')
        plt.plot(t, s)

        plt.xlabel(r'\textbf{time} (s)')
        plt.ylabel(r'\textit{voltage} (mV)',fontsize=16)
        plt.title(r"\TeX\ is Number "
                  r"$\displaystyle\sum_{n=1}^\infty\frac{-e^{i\pi}}{2^n}$!",
                  fontsize=16, color='gray')
        # Make room for the ridiculously large title.
        plt.subplots_adjust(top=0.8)

        plt.savefig('tex_demo')
        plt.show()
        ```
      </details>

## Ways You Can Contribute:

- If you'd like to contribute new features, bug fixes, or improvements to the documentation, please refer to our [contributing guide](https://rbalestr-lab.github.io/stable-pretraining.github.io/dev/contributing.html) for detailed instructions on how to get started.

- You can also contribute by adding new methods, datasets, or configurations that improve the current performance of a method in the [benchmark section](https://github.com/rbalestr-lab/stable-pretraining/tree/main/benchmarks).

## Contributors

Core contributors (in order of joining the project):
- [Randall Balestriero](https://github.com/RandallBalestriero)
- [Hugues Van Assel](https://github.com/huguesva)
- [Sami BuGhanem](https://github.com/sami-bg)
- [Lucas Maes](https://github.com/lucas-maes)
