Quickstart 🤗 Transformers

Let’s build a federated learning system using Hugging Face Transformers and Flower!

We will leverage Hugging Face to federate the training of language models over multiple clients using Flower. More specifically, we will fine-tune a pre-trained Transformer model (distilBERT) for sequence classification over a dataset of IMDB ratings. The end goal is to detect if a movie rating is positive or negative.

Dependencies

To follow along this tutorial you will need to install the following packages: datasets, evaluate, flwr, torch, and transformers. This can be done using pip:

$ pip install datasets evaluate flwr torch transformers

Standard Hugging Face workflow

Handling the data

To fetch the IMDB dataset, we will use Hugging Face’s datasets library. We then need to tokenize the data and create PyTorch dataloaders, this is all done in the load_data function:

import random
import torch
from datasets import load_dataset
from torch.utils.data import DataLoader
from transformers import AutoTokenizer, DataCollatorWithPadding

DEVICE = torch.device("cuda:0" if torch.cuda.is_available() else "cpu")
CHECKPOINT = "distilbert-base-uncased"

def load_data():
    """Load IMDB data (training and eval)"""
    raw_datasets = load_dataset("imdb")
    raw_datasets = raw_datasets.shuffle(seed=42)
    # remove unnecessary data split
    del raw_datasets["unsupervised"]
    tokenizer = AutoTokenizer.from_pretrained(CHECKPOINT)
    def tokenize_function(examples):
        return tokenizer(examples["text"], truncation=True)
    # We will take a small sample in order to reduce the compute time, this is optional
    train_population = random.sample(range(len(raw_datasets["train"])), 100)
    test_population = random.sample(range(len(raw_datasets["test"])), 100)
    tokenized_datasets = raw_datasets.map(tokenize_function, batched=True)
    tokenized_datasets["train"] = tokenized_datasets["train"].select(train_population)
    tokenized_datasets["test"] = tokenized_datasets["test"].select(test_population)
    tokenized_datasets = tokenized_datasets.remove_columns("text")
    tokenized_datasets = tokenized_datasets.rename_column("label", "labels")
    data_collator = DataCollatorWithPadding(tokenizer=tokenizer)
    trainloader = DataLoader(
        tokenized_datasets["train"],
        shuffle=True,
        batch_size=32,
        collate_fn=data_collator,
    )
    testloader = DataLoader(
        tokenized_datasets["test"], batch_size=32, collate_fn=data_collator
    )
    return trainloader, testloader

Training and testing the model

Once we have a way of creating our trainloader and testloader, we can take care of the training and testing. This is very similar to any PyTorch training or testing loop:

from evaluate import load as load_metric
from transformers import AdamW

def train(net, trainloader, epochs):
    optimizer = AdamW(net.parameters(), lr=5e-5)
    net.train()
    for _ in range(epochs):
        for batch in trainloader:
            batch = {k: v.to(DEVICE) for k, v in batch.items()}
            outputs = net(**batch)
            loss = outputs.loss
            loss.backward()
            optimizer.step()
            optimizer.zero_grad()
def test(net, testloader):
    metric = load_metric("accuracy")
    loss = 0
    net.eval()
    for batch in testloader:
        batch = {k: v.to(DEVICE) for k, v in batch.items()}
        with torch.no_grad():
            outputs = net(**batch)
        logits = outputs.logits
        loss += outputs.loss.item()
        predictions = torch.argmax(logits, dim=-1)
        metric.add_batch(predictions=predictions, references=batch["labels"])
    loss /= len(testloader.dataset)
    accuracy = metric.compute()["accuracy"]
    return loss, accuracy

Creating the model itself

To create the model itself, we will just load the pre-trained distillBERT model using Hugging Face’s AutoModelForSequenceClassification :

from transformers import AutoModelForSequenceClassification

net = AutoModelForSequenceClassification.from_pretrained(
        CHECKPOINT, num_labels=2
    ).to(DEVICE)

Federating the example

Creating the IMDBClient

To federate our example to multiple clients, we first need to write our Flower client class (inheriting from flwr.client.NumPyClient). This is very easy, as our model is a standard PyTorch model:

from collections import OrderedDict
import flwr as fl

class IMDBClient(fl.client.NumPyClient):
        def get_parameters(self, config):
            return [val.cpu().numpy() for _, val in net.state_dict().items()]
        def set_parameters(self, parameters):
            params_dict = zip(net.state_dict().keys(), parameters)
            state_dict = OrderedDict({k: torch.Tensor(v) for k, v in params_dict})
            net.load_state_dict(state_dict, strict=True)
        def fit(self, parameters, config):
            self.set_parameters(parameters)
            print("Training Started...")
            train(net, trainloader, epochs=1)
            print("Training Finished.")
            return self.get_parameters(config={}), len(trainloader), {}
        def evaluate(self, parameters, config):
            self.set_parameters(parameters)
            loss, accuracy = test(net, testloader)
            return float(loss), len(testloader), {"accuracy": float(accuracy)}

The get_parameters function lets the server get the client’s parameters. Inversely, the set_parameters function allows the server to send its parameters to the client. Finally, the fit function trains the model locally for the client, and the evaluate function tests the model locally and returns the relevant metrics.

Starting the server

Now that we have a way to instantiate clients, we need to create our server in order to aggregate the results. Using Flower, this can be done very easily by first choosing a strategy (here, we are using FedAvg, which will define the global weights as the average of all the clients’ weights at each round) and then using the flwr.server.start_server function:

def weighted_average(metrics):
    accuracies = [num_examples * m["accuracy"] for num_examples, m in metrics]
    losses = [num_examples * m["loss"] for num_examples, m in metrics]
    examples = [num_examples for num_examples, _ in metrics]
    return {"accuracy": sum(accuracies) / sum(examples), "loss": sum(losses) / sum(examples)}

# Define strategy
strategy = fl.server.strategy.FedAvg(
    fraction_fit=1.0,
    fraction_evaluate=1.0,
    evaluate_metrics_aggregation_fn=weighted_average,
)

# Start server
fl.server.start_server(
    server_address="0.0.0.0:8080",
    config=fl.server.ServerConfig(num_rounds=3),
    strategy=strategy,
)

The weighted_average function is there to provide a way to aggregate the metrics distributed amongst the clients (basically this allows us to display a nice average accuracy and loss for every round).

Putting everything together

We can now start client instances using:

fl.client.start_numpy_client(
    server_address="127.0.0.1:8080",
    client=IMDBClient()
)

And they will be able to connect to the server and start the federated training.

If you want to check out everything put together, you should check out the full code example: [https://github.com/adap/flower/tree/main/examples/quickstart_huggingface](https://github.com/adap/flower/tree/main/examples/quickstart_huggingface).

Of course, this is a very basic example, and a lot can be added or modified, it was just to showcase how simply we could federate a Hugging Face workflow using Flower.

Note that in this example we used PyTorch, but we could have very well used TensorFlow.