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OML is a PyTorch-based framework to train and validate the models producing high-quality embeddings.

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OML is a PyTorch-based framework to train and validate the models producing high-quality embeddings.

FAQ

Why do I need OML?

You may think "If I need image embeddings I can simply train a vanilla classifier and take its penultimate layer". Well, it makes sense as a starting point. But there are several possible drawbacks:

  • If you want to use embeddings to perform searching you need to calculate some distance among them (for example, cosine or L2). Usually, you don't directly optimize these distances during the training in the classification setup. So, you can only hope that final embeddings will have the desired properties.

  • The second problem is the validation process. In the searching setup, you usually care how related your top-N outputs are to the query. The natural way to evaluate the model is to simulate searching requests to the reference set and apply one of the retrieval metrics. So, there is no guarantee that classification accuracy will correlate with these metrics.

  • Finally, you may want to implement a metric learning pipeline by yourself. There is a lot of work: to use triplet loss you need to form batches in a specific way, implement different kinds of triplets mining, tracking distances, etc. For the validation, you also need to implement retrieval metrics, which include effective embeddings accumulation during the epoch, covering corner cases, etc. It's even harder if you have several gpus and use DDP. You may also want to visualize your search requests by highlighting good and bad search results. Instead of doing it by yourself, you can simply use OML for your purposes.

What is the difference between Open Metric Learning and PyTorch Metric Learning?

PML is the popular library for Metric Learning, and it includes a rich collection of losses, miners, distances, and reducers; that is why we provide straightforward examples of using them with OML. Initially, we tried to use PML, but in the end, we came up with our library, which is more pipeline / recipes oriented. That is how OML differs from PML:

  • OML has Config API which allows training models by preparing a config and your data in the required format (it's like converting data into COCO format to train a detector from mmdetection).

  • OML focuses on end-to-end pipelines and practical use cases. It has config based examples on popular benchmarks close to real life (like photos of products of thousands ids). We found some good combinations of hyperparameters on these datasets, trained and published models and their configs. Thus, it makes OML more recipes oriented than PML, and its author confirms this saying that his library is a set of tools rather the recipes, moreover, the examples in PML are mostly for CIFAR and MNIST datasets.

  • OML has the Zoo of pretrained models that can be easily accessed from the code in the same way as in torchvision (when you type resnet50(pretrained=True)).

  • OML is integrated with PyTorch Lightning, so, we can use the power of its Trainer. This is especially helpful when we work with DDP, so, you compare our DDP example and the PMLs one. By the way, PML also has Trainers, but it's not in the examples and custom train / test functions are used instead.

We believe that having Config API, laconic examples, and Zoo of pretrained models sets the entry threshold to a really low value.

What is Metric Learning?

Metric Learning problem (also known as extreme classification problem) means a situation in which we have thousands of ids of some entities, but only a few samples for every entity. Often we assume that during the test stage (or production) we will deal with unseen entities which makes it impossible to apply the vanilla classification pipeline directly. In many cases obtained embeddings are used to perform search or matching procedures over them.

Here are a few examples of such tasks from the computer vision sphere:

  • Person/Animal Re-Identification
  • Face Recognition
  • Landmark Recognition
  • Searching engines for online shops and many others.

Glossary (Naming convention)

  • embedding - model's output (also known as features vector or descriptor).
  • query - a sample which is used as a request in the retrieval procedure.
  • gallery set - the set of entities to search items similar to query (also known as reference or index).
  • Sampler - an argument for DataLoader which is used to form batches
  • Miner - the object to form pairs or triplets after the batch was formed by Sampler. It's not necessary to form the combinations of samples only inside the current batch, thus, the memory bank may be a part of Miner.
  • Samples/Labels/Instances - as an example let's consider DeepFashion dataset. It includes thousands of fashion item ids (we name them labels) and several photos for each item id (we name the individual photo as instance or sample). All of the fashion item ids have their groups like "skirts", "jackets", "shorts" and so on (we name them categories). Note, we avoid using the term class to avoid misunderstanding.
  • training epoch - batch samplers which we use for combination-based losses usually have a length equal to [number of labels in training dataset] / [numbers of labels in one batch]. It means that we don't observe all of the available training samples in one epoch (as opposed to vanilla classification), instead, we observe all of the available labels.

How good may be a model trained with OML?

It may be comparable with the current (2022 year) SotA methods, for example, Hyp-ViT. (Few words about this approach: it's a ViT architecture trained with contrastive loss, but the embeddings were projected into some hyperbolic space. As the authors claimed, such a space is able to describe the nested structure of real-world data. So, the paper requires some heavy math to adapt the usual operations for the hyperbolical space.)

We trained the same architecture with triplet loss, fixing the rest of the parameters: training and test transformations, image size, and optimizer. See configs in Models Zoo. The trick was in heuristics in our miner and sampler:

  • Category Balance Sampler forms the batches limiting the number of categories C in it. For instance, when C = 1 it puts only jackets in one batch and only jeans into another one (just an example). It automatically makes the negative pairs harder: it's more meaningful for a model to realise why two jackets are different than to understand the same about a jacket and a t-shirt.

  • Hard Triplets Miner makes the task even harder keeping only the hardest triplets (with maximal positive and minimal negative distances).

Here are CMC@1 scores for 2 popular benchmarks. SOP dataset: Hyp-ViT — 85.9, ours — 86.6. DeepFashion dataset: Hyp-ViT — 92.5, ours — 92.1. Thus, utilising simple heuristics and avoiding heavy math we are able to perform on SotA level.

How does OML work under the hood?

Training part implies using losses, well-established for metric learning, such as the angular losses (like ArcFace) or the combinations based losses (like TripletLoss or ContrastiveLoss). The latter benefits from effective mining schemas of triplets/pairs, so we pay great attention to it. Thus, during the training we:

  1. Use DataLoader + Sampler to form batches (for example BalanceSampler)
  2. [Only for losses based on combinations] Use Miner to form effective pairs or triplets, including those which utilize a memory bank.
  3. Compute loss.

Validation part consists of several steps:

  1. Accumulating all of the embeddings (EmbeddingMetrics).
  2. Calculating distances between them with respect to query/gallery split.
  3. Applying some specific retrieval techniques like query reranking or score normalisation.
  4. Calculating retrieval metrics like CMC@k, Precision@k or MeanAveragePrecision@k.

What about Self-Supervised Learning?

Recent research in SSL definitely obtained great results. The problem is that these approaches required an enormous amount of computing to train the model. But in our framework, we consider the most common case when the average user has no more than a few GPUs.

At the same time, it would be unwise to ignore success in this sphere, so we still exploit it in two ways:

  • As a source of checkpoints that would be great to start training with. From publications and our experience, they are much better as initialisation than the default supervised model trained on ImageNet. Thus, we added the possibility to initialise your models using these pretrained checkpoints only by passing an argument in the config or the constructor.
  • As a source of inspiration. For example, we adapted the idea of a memory bank from MoCo for the TripletLoss.

Do I need to know other frameworks to use OML?

No, you don't. OML is a framework-agnostic. Despite we use PyTorch Lightning as a loop runner for the experiments, we also keep the possibility to run everything on pure PyTorch. Thus, only the tiny part of OML is Lightning-specific and we keep this logic separately from other code (see oml.lightning). Even when you use Lightning, you don't need to know it, since we provide ready to use Config API.

The possibility of using pure PyTorch and modular structure of the code leaves a room for utilizing OML with your favourite framework after the implementation of the necessary wrappers.

Can I use OML without any knowledge in DataScience?

Yes. To run the experiment with Config API you only need to write a converter to our format (it means preparing the .csv table with 5 predefined columns). That's it!

Probably we already have a suitable pre-trained model for your domain in our Models Zoo. In this case, you don't even need to train it.

Documentation

Documentation is available via the link.

Installation

OML is available in PyPI:

pip install -U open-metric-learning

You can also pull the prepared image from DockerHub...

docker pull omlteam/oml:gpu
docker pull omlteam/oml:cpu

...or build one by your own

make docker_build RUNTIME=cpu
make docker_build RUNTIME=gpu

Get started using Config API

Using configs is the best option if your dataset and pipeline are standard enough or if you are not experienced in Machine Learning or Python. You can find more details in the examples.

Get started using Python

The most flexible, but knowledge-requiring approach. You are not limited by our project structure and you can use only that part of the functionality which you need. You can start with fully working code snippets below that train and validate the model on a tiny dataset of figures.

Training

import torch
from tqdm import tqdm

from oml.datasets.base import DatasetWithLabels
from oml.losses.triplet import TripletLossWithMiner
from oml.miners.inbatch_all_tri import AllTripletsMiner
from oml.models.vit.vit import ViTExtractor
from oml.samplers.balance import BalanceSampler
from oml.utils.download_mock_dataset import download_mock_dataset

dataset_root = "mock_dataset/"
df_train, _ = download_mock_dataset(dataset_root)

model = ViTExtractor("vits16_dino", arch="vits16", normalise_features=False).train()
optimizer = torch.optim.SGD(model.parameters(), lr=1e-6)

train_dataset = DatasetWithLabels(df_train, dataset_root=dataset_root)
criterion = TripletLossWithMiner(margin=0.1, miner=AllTripletsMiner())
sampler = BalanceSampler(train_dataset.get_labels(), n_labels=2, n_instances=2)
train_loader = torch.utils.data.DataLoader(train_dataset, batch_sampler=sampler)

for batch in tqdm(train_loader):
    embeddings = model(batch["input_tensors"])
    loss = criterion(embeddings, batch["labels"])
    loss.backward()
    optimizer.step()
    optimizer.zero_grad()

Open In Colab

Validation

import torch
from tqdm import tqdm

from oml.datasets.base import DatasetQueryGallery
from oml.metrics.embeddings import EmbeddingMetrics
from oml.models.vit.vit import ViTExtractor
from oml.utils.download_mock_dataset import download_mock_dataset

dataset_root =  "mock_dataset/"
_, df_val = download_mock_dataset(dataset_root)

model = ViTExtractor("vits16_dino", arch="vits16", normalise_features=False).eval()

val_dataset = DatasetQueryGallery(df_val, dataset_root=dataset_root)

val_loader = torch.utils.data.DataLoader(val_dataset, batch_size=4)
calculator = EmbeddingMetrics()
calculator.setup(num_samples=len(val_dataset))

with torch.no_grad():
    for batch in tqdm(val_loader):
        batch["embeddings"] = model(batch["input_tensors"])
        calculator.update_data(batch)

metrics = calculator.compute_metrics()

Open In Colab

Training + Validation [Lightning]

import pytorch_lightning as pl
import torch

from oml.datasets.base import DatasetQueryGallery, DatasetWithLabels
from oml.lightning.modules.retrieval import RetrievalModule
from oml.lightning.callbacks.metric import MetricValCallback
from oml.losses.triplet import TripletLossWithMiner
from oml.metrics.embeddings import EmbeddingMetrics
from oml.miners.inbatch_all_tri import AllTripletsMiner
from oml.models.vit.vit import ViTExtractor
from oml.samplers.balance import BalanceSampler
from oml.utils.download_mock_dataset import download_mock_dataset

dataset_root =  "mock_dataset/"
df_train, df_val = download_mock_dataset(dataset_root)

# model
model = ViTExtractor("vits16_dino", arch="vits16", normalise_features=False)

# train
optimizer = torch.optim.SGD(model.parameters(), lr=1e-6)
train_dataset = DatasetWithLabels(df_train, dataset_root=dataset_root)
criterion = TripletLossWithMiner(margin=0.1, miner=AllTripletsMiner())
batch_sampler = BalanceSampler(train_dataset.get_labels(), n_labels=2, n_instances=3)
train_loader = torch.utils.data.DataLoader(train_dataset, batch_sampler=batch_sampler)

# val
val_dataset = DatasetQueryGallery(df_val, dataset_root=dataset_root)
val_loader = torch.utils.data.DataLoader(val_dataset, batch_size=4)
metric_callback = MetricValCallback(metric=EmbeddingMetrics())

# run
pl_model = RetrievalModule(model, criterion, optimizer)
trainer = pl.Trainer(max_epochs=1, callbacks=[metric_callback], num_sanity_val_steps=0)
trainer.fit(pl_model, train_dataloaders=train_loader, val_dataloaders=val_loader)

ㅤ ㅤ

If you want to train your model in the DDP regime (Distributed Data Parallel), you only need to slightly change only few lines of code in the example below.

Training + Validation [Lightning Distributed]

import pytorch_lightning as pl
import torch

from oml.datasets.base import DatasetQueryGallery, DatasetWithLabels
from oml.lightning.modules.retrieval import RetrievalModuleDDP
from oml.lightning.callbacks.metric import MetricValCallbackDDP
from oml.losses.triplet import TripletLossWithMiner
from oml.metrics.embeddings import EmbeddingMetricsDDP
from oml.miners.inbatch_all_tri import AllTripletsMiner
from oml.models.vit.vit import ViTExtractor
from oml.samplers.balance import BalanceSampler
from oml.utils.download_mock_dataset import download_mock_dataset

dataset_root = "mock_dataset/"
df_train, df_val = download_mock_dataset(dataset_root)

# model
model = ViTExtractor("vits16_dino", arch="vits16", normalise_features=False)

# train
optimizer = torch.optim.SGD(model.parameters(), lr=1e-6)
train_dataset = DatasetWithLabels(df_train, dataset_root=dataset_root)
criterion = TripletLossWithMiner(margin=0.1, miner=AllTripletsMiner())
batch_sampler = BalanceSampler(train_dataset.get_labels(), n_labels=2, n_instances=3)
train_loader = torch.utils.data.DataLoader(train_dataset, batch_sampler=batch_sampler)

# val
val_dataset = DatasetQueryGallery(df_val, dataset_root=dataset_root)
val_loader = torch.utils.data.DataLoader(val_dataset, batch_size=4)
metric_callback = MetricValCallbackDDP(metric=EmbeddingMetricsDDP())  # DDP specific

# run
pl_model = RetrievalModuleDDP(model=model, criterion=criterion, optimizer=optimizer,
                              loaders_train=train_loader, loaders_val=val_loader  # DDP specific
                              )

ddp_args = {"accelerator": "auto", "devices": 2, "strategy": pl.plugins.DDPPlugin(), "replace_sampler_ddp": False} # DDP specific
trainer = pl.Trainer(max_epochs=1, callbacks=[metric_callback], num_sanity_val_steps=0, **ddp_args)
trainer.fit(pl_model)  # we don't pass loaders to .fit() in DDP

Usage with PyTorch Metric Learning

You can easily access a lot of content from PyTorch Metric Learning with our library. You can see that the examples below are different from the basic ones only in a few lines of code:

Training with loss from PML

import torch
from tqdm import tqdm

from oml.datasets.base import DatasetWithLabels
from oml.losses.triplet import TripletLossWithMiner
from oml.miners.inbatch_all_tri import AllTripletsMiner
from oml.models.vit.vit import ViTExtractor
from oml.samplers.balance import BalanceSampler
from oml.utils.download_mock_dataset import download_mock_dataset

from pytorch_metric_learning import losses, distances, reducers, miners

dataset_root = "mock_dataset/"
df_train, _ = download_mock_dataset(dataset_root)

model = ViTExtractor("vits16_dino", arch="vits16", normalise_features=False).train()
optimizer = torch.optim.SGD(model.parameters(), lr=1e-6)

train_dataset = DatasetWithLabels(df_train, dataset_root=dataset_root)

# PML specific
# criterion = losses.TripletMarginLoss(margin=0.2, triplets_per_anchor="all")
criterion = losses.ArcFaceLoss(num_classes=df_train["label"].nunique(), embedding_size=model.feat_dim)  # for classification-like losses

sampler = BalanceSampler(train_dataset.get_labels(), n_labels=2, n_instances=2)
train_loader = torch.utils.data.DataLoader(train_dataset, batch_sampler=sampler)

for batch in tqdm(train_loader):
    embeddings = model(batch["input_tensors"])
    loss = criterion(embeddings, batch["labels"])
    loss.backward()
    optimizer.step()
    optimizer.zero_grad()

Open In Colab

Training with distance, reducer, miner and loss from PML

import torch
from tqdm import tqdm

from oml.datasets.base import DatasetWithLabels
from oml.losses.triplet import TripletLossWithMiner
from oml.miners.inbatch_all_tri import AllTripletsMiner
from oml.models.vit.vit import ViTExtractor
from oml.samplers.balance import BalanceSampler
from oml.utils.download_mock_dataset import download_mock_dataset

from pytorch_metric_learning import losses, distances, reducers, miners

dataset_root = "mock_dataset/"
df_train, _ = download_mock_dataset(dataset_root)

model = ViTExtractor("vits16_dino", arch="vits16", normalise_features=False).train()
optimizer = torch.optim.SGD(model.parameters(), lr=1e-6)

train_dataset = DatasetWithLabels(df_train, dataset_root=dataset_root)

# PML specific
distance = distances.LpDistance(p=2)
reducer = reducers.ThresholdReducer(low=0)
criterion = losses.TripletMarginLoss()
miner = miners.TripletMarginMiner(margin=0.2, distance=distance, type_of_triplets="all")

sampler = BalanceSampler(train_dataset.get_labels(), n_labels=2, n_instances=2)
train_loader = torch.utils.data.DataLoader(train_dataset, batch_sampler=sampler)

for batch in tqdm(train_loader):
    embeddings = model(batch["input_tensors"])
    loss = criterion(embeddings, batch["labels"], miner(embeddings, batch["labels"]))  # PML specific
    loss.backward()
    optimizer.step()
    optimizer.zero_grad()

Open In Colab

Note, during the validation process OpenMetricLearning computes L2 distances. Thus, when choosing a distance from PML, we recommend you to pick distances.LpDistance(p=2).

To use content from PyTorch Metric Learning with our Config API just follow the standard tutorial of adding custom loss.

Zoo

Below are the models trained with OML on 4 public datasets. For more details about the training process and configs, please, visit examples submodule and it's Readme. All metrics below were obtained on the images with the sizes of 224 x 224:

model cmc1 dataset weights configs transforms
ViTExtractor(weights="vits16_inshop", arch="vits16", ...) 0.921 DeepFashion Inshop link link link
ViTExtractor(weights="vits16_sop", arch="vits16", ...) 0.866 Stanford Online Products link link link
ViTExtractor(weights="vits16_cars", arch="vits16", ...) 0.907 CARS 196 link link link
ViTExtractor(weights="vits16_cub", arch="vits16", ...) 0.837 CUB 200 2011 link link link

We also provide an integration with the models pretrained by other researchers. All metrics below were obtained on the images with the sizes of 224 x 224:

model Stanford Online Products DeepFashion InShop CUB 200 2011 CARS 196 transforms
ViTCLIPExtractor("sber_vitb32_224", "vitb32_224") 0.547 0.514 0.448 0.618 link
ViTCLIPExtractor("sber_vitb16_224", "vitb16_224") 0.565 0.565 0.524 0.648 link
ViTCLIPExtractor("sber_vitl14_224", "vitl14_224") 0.512 0.555 0.606 0.707 link
ViTCLIPExtractor("openai_vitb32_224", "vitb32_224") 0.612 0.491 0.560 0.693 link
ViTCLIPExtractor("openai_vitb16_224", "vitb16_224") 0.648 0.606 0.665 0.767 link
ViTCLIPExtractor("openai_vitl14_224", "vitl14_224") 0.670 0.675 0.745 0.844 link
ViTExtractor("vits16_dino", "vits16") 0.629 0.456 0.693 0.313 link
ViTExtractor("vits8_dino", "vits8") 0.637 0.478 0.703 0.344 link
ViTExtractor("vitb16_dino", "vitb16") 0.636 0.464 0.626 0.340 link
ViTExtractor("vitb8_dino", "vitb8") 0.673 0.548 0.546 0.342 link
ResnetExtractor("resnet50_moco_v2", "resnet50") 0.491 0.310 0.244 0.155 link

You can specify the desired weights and architecture to automatically download pretrained checkpoint (by the analogue with torchvision.models):

import oml
from oml.models.vit.vit import ViTExtractor

# We are downloading vits16 pretrained on CARS dataset:
model = ViTExtractor(weights="vits16_cars", arch="vits16", normalise_features=False)

# You can also check other available pretrained models:
print(list(ViTExtractor.pretrained_models.keys()))

# To load checkpoint saved on a disk:
model_from_disk = ViTExtractor(weights=oml.const.CKPT_SAVE_ROOT / "vits16_cars.ckpt", arch="vits16", normalise_features=False)

Contributing guide

We welcome new contributors! Please, see our:

Extra materials

You can also read some extra materials related to OML:

Acknowledgments

The project was started in 2020 as a module for Catalyst library. I want to thank people who worked with me on that module: Julia Shenshina, Nikita Balagansky, Sergey Kolesnikov and others.

I would like to thank people who continue working on this pipeline when it became a separe project: Julia Shenshina, Misha Kindulov, Aleksei Tarasov and Verkhovtsev Leonid.

I also want to thank NewYorker, since the part of functionality was developed (and used) by its computer vision team led by me.

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