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Fine-tune BERT for Text Classification on AWS Trainium

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Fine-tune BERT for Text Classification on AWS Trainium

There is a notebook version of that tutorial here.

This tutorial will help you to get started with AWS Trainium and Hugging Face Transformers. It will cover how to set up a Trainium instance on AWS, load & fine-tune a transformers model for text-classification

You will learn how to:

  1. Setup AWS environment
  2. Load and process the dataset
  3. Fine-tune BERT using Hugging Face Transformers and Optimum Neuron

Before we can start, make sure you have a Hugging Face Account to save artifacts and experiments.

Quick intro: AWS Trainium

AWS Trainium (Trn1) is a purpose-built EC2 for deep learning (DL) training workloads. Trainium is the successor of AWS Inferentia focused on high-performance training workloads claiming up to 50% cost-to-train savings over comparable GPU-based instances.

Trainium has been optimized for training natural language processing, computer vision, and recommender models used. The accelerator supports a wide range of data types, including FP32, TF32, BF16, FP16, UINT8, and configurable FP8.

The biggest Trainium instance, the trn1.32xlarge comes with over 500GB of memory, making it easy to fine-tune ~10B parameter models on a single instance. Below you will find an overview of the available instance types. More details here:

instance size accelerators accelerator memory vCPU CPU Memory price per hour
trn1.2xlarge 1 32 8 32 $1.34
trn1.32xlarge 16 512 128 512 $21.50
trn1n.32xlarge (2x bandwidth) 16 512 128 512 $24.78

Now we know what Trainium offers, let’s get started. 🚀

Note: This tutorial was created on a trn1.2xlarge AWS EC2 Instance.

1. Setup AWS environment

In this example, we will use the trn1.2xlarge instance on AWS with 1 Accelerator, including two Neuron Cores and the Hugging Face Neuron Deep Learning AMI.

This blog post doesn’t cover how to create the instance in detail. You can check out my previous blog about “Setting up AWS Trainium for Hugging Face Transformers”, which includes a step-by-step guide on setting up the environment.

Once the instance is up and running, we can ssh into it. But instead of developing inside a terminal we want to use a Jupyter environment, which we can use for preparing our dataset and launching the training. For this, we need to add a port for forwarding in the ssh command, which will tunnel our localhost traffic to the Trainium instance.

PUBLIC_DNS="" # IP address, e.g. ec2-3-80-....
KEY_PATH="" # local path to key, e.g. ssh/trn.pem

ssh -L 8080:localhost:8080 -i ${KEY_NAME}.pem ubuntu@$PUBLIC_DNS

We can now start our jupyter server.

python -m notebook --allow-root --port=8080

You should see a familiar jupyter output with a URL to the notebook.

http://localhost:8080/?token=8c1739aff1755bd7958c4cfccc8d08cb5da5234f61f129a9

We can click on it, and a jupyter environment opens in our local browser.

jupyter.webp

We are going to use the Jupyter environment only for preparing the dataset and then torchrun for launching our training script on both neuron cores for distributed training. Lets create a new notebook and get started.

2. Load and process the dataset

We are training a Text Classification model on the emotion dataset to keep the example straightforward. The emotion is a dataset of English Twitter messages with six basic emotions: anger, fear, joy, love, sadness, and surprise.

We will use the load_dataset() method from the 🤗 Datasets library to load the emotion.

from datasets import load_dataset

# Dataset id from huggingface.co/dataset
dataset_id = "philschmid/emotion"

# Load raw dataset
raw_dataset = load_dataset(dataset_id)

print(f"Train dataset size: {len(raw_dataset['train'])}")
print(f"Test dataset size: {len(raw_dataset['test'])}")

# Train dataset size: 16000
# Test dataset size: 2000

Let’s check out an example of the dataset.

from random import randrange

random_id = randrange(len(raw_dataset['train']))
raw_dataset['train'][random_id]
# {'text': 'i feel isolated and alone in my trade', 'label': 0}

We must convert our “Natural Language” to token IDs to train our model. This is done by a Tokenizer, which tokenizes the inputs (including converting the tokens to their corresponding IDs in the pre-trained vocabulary). if you want to learn more about this, out chapter 6 of the Hugging Face Course.

Our Neuron Accelerator expects a fixed shape of inputs. We need to truncate or pad all samples to the same length.

from transformers import AutoTokenizer
import os
# Model id to load the tokenizer
model_id = "bert-base-uncased"
save_dataset_path = "lm_dataset"
# Load Tokenizer
tokenizer = AutoTokenizer.from_pretrained(model_id)

# Tokenize helper function
def tokenize(batch):
    return tokenizer(batch['text'], padding='max_length', truncation=True,return_tensors="pt")

# Tokenize dataset
raw_dataset =  raw_dataset.rename_column("label", "labels") # to match Trainer
tokenized_dataset = raw_dataset.map(tokenize, batched=True, remove_columns=["text"])
tokenized_dataset = tokenized_dataset.with_format("torch")

# save dataset to disk
tokenized_dataset["train"].save_to_disk(os.path.join(save_dataset_path,"train"))
tokenized_dataset["test"].save_to_disk(os.path.join(save_dataset_path,"eval"))

3. Fine-tune BERT using Hugging Face Transformers

Normally you would use the Trainer and TrainingArguments to fine-tune PyTorch-based transformer models.

But together with AWS, we have developed a NeuronTrainer to improve performance, robustness, and safety when training on Trainium or Inferentia2 instances. The NeuronTrainer also comes with a model cache, which allows us to use precompiled models and configuration from Hugging Face Hub to skip the compilation step, which would be needed at the beginning of training. This can reduce the training time by ~3x.

The NeuronTrainer is part of the optimum-neuron library and can be used as a 1-to-1 replacement for the Trainer. You only have to adjust the import in your training script.

- from transformers import Trainer, TrainingArguments
+ from optimum.neuron import NeuronTrainer as Trainer
+ from optimum.neuron import NeuronTrainingArguments as TrainingArguments

We prepared a simple train.py training script based on the “Getting started with Pytorch 2.0 and Hugging Face Transformers” blog post with the NeuronTrainer. Below is an excerpt

from transformers import TrainingArguments
from optimum.neuron import NeuronTrainer as Trainer

def parse_args():
	...

def training_function(args):

    # load dataset from disk and tokenizer
    train_dataset = load_from_disk(os.path.join(args.dataset_path, "train"))
		...

    # Download the model from huggingface.co/models
    model = AutoModelForSequenceClassification.from_pretrained(
        args.model_id, num_labels=num_labels, label2id=label2id, id2label=id2label
    )

    training_args = TrainingArguments(
			...
    )

    # Create Trainer instance
    trainer = Trainer(
        model=model,
        args=training_args,
        train_dataset=train_dataset,
        eval_dataset=eval_dataset,
        compute_metrics=compute_metrics,
    )

    # Start training
    trainer.train()

We can load the training script into our environment using the wget command or manually copy it into the notebook from here.

!wget https://raw.githubusercontent.com/huggingface/optimum-neuron/main/notebooks/text-classification/scripts/train.py

We will use torchrun to launch our training script on both neuron cores for distributed training. torchrun is a tool that automatically distributes a PyTorch model across multiple accelerators. We can pass the number of accelerators as nproc_per_node arguments alongside our hyperparameters.

We’ll use the following command to launch training:

!torchrun --nproc_per_node=2 train.py \
 --model_id bert-base-uncased \
 --dataset_path lm_dataset \
 --lr 5e-5 \
 --per_device_train_batch_size 16 \
 --bf16 True \
 --epochs 3

Note: If you see bad, bad accuracy, you might want to deactivate bf16 for now.

After 9 minutes the training was completed and achieved an excellent f1 score of 0.914.

***** train metrics *****
  epoch                    =        3.0
  train_runtime            =    0:08:30
  train_samples            =      16000
  train_samples_per_second =     96.337

***** eval metrics *****
  eval_f1                  =      0.914
  eval_runtime             =    0:00:08

Last but not least, terminate the EC2 instance to avoid unnecessary charges. Looking at the price-performance, our training only cost 20ct (1.34$/h * 0.15h = 0.20$)