ray.train.huggingface.TransformersTrainer
ray.train.huggingface.TransformersTrainer#
- class ray.train.huggingface.TransformersTrainer(*args, **kwargs)[source]#
Bases:
ray.train.torch.torch_trainer.TorchTrainerA Trainer for data parallel HuggingFace Transformers on PyTorch training.
This Trainer runs the
transformers.Trainer.train()method on multiple Ray Actors. The training is carried out in a distributed fashion through PyTorch DDP. These actors already have the necessary torch process group already configured for distributed PyTorch training. If you have PyTorch >= 1.12.0 installed, you can also run FSDP training by specifying thefsdpargument inTrainingArguments. DeepSpeed is also supported - see GPT-J-6B Fine-Tuning with Ray AIR and DeepSpeed. For more information on configuring FSDP or DeepSpeed, refer to Hugging Face documentation.The training function ran on every Actor will first run the specified
trainer_init_per_workerfunction to obtain an instantiatedtransformers.Trainerobject. Thetrainer_init_per_workerfunction will have access to preprocessed train and evaluation datasets.If the
datasetsdict contains a training dataset (denoted by the “train” key), then it will be split into multiple dataset shards, with each Actor training on a single shard. All the other datasets will not be split.Please note that if you use a custom
transformers.Trainersubclass, theget_train_dataloadermethod will be wrapped around to disable sharding bytransformers.IterableDatasetShard, as the dataset will already be sharded on the Ray AIR side.You can also provide
datasets.Datasetobject or other dataset objects allowed bytransformers.Trainerdirectly in thetrainer_init_per_workerfunction, without specifying thedatasetsdict. It is recommended to initialize those objects inside the function, as otherwise they will be serialized and passed to the function, which may lead to long runtime and memory issues with large amounts of data. In this case, the training dataset will be split automatically by Transformers.HuggingFace loggers will be automatically disabled, and the
local_rankargument inTrainingArgumentswill be automatically set. Please note that if you want to use CPU training, you will need to set theno_cudaargument inTrainingArgumentsmanually - otherwise, an exception (segfault) may be thrown.This Trainer requires
transformers>=4.19.0package. It is tested withtransformers==4.19.1.Example
# Based on # huggingface/notebooks/examples/language_modeling_from_scratch.ipynb # Hugging Face imports from datasets import load_dataset import transformers from transformers import AutoConfig, AutoModelForCausalLM, AutoTokenizer import ray from ray.train.huggingface import TransformersTrainer from ray.train import ScalingConfig # If using GPUs, set this to True. use_gpu = True model_checkpoint = "gpt2" tokenizer_checkpoint = "sgugger/gpt2-like-tokenizer" block_size = 128 datasets = load_dataset("wikitext", "wikitext-2-raw-v1") tokenizer = AutoTokenizer.from_pretrained(tokenizer_checkpoint) def tokenize_function(examples): return tokenizer(examples["text"]) tokenized_datasets = datasets.map( tokenize_function, batched=True, num_proc=1, remove_columns=["text"] ) def group_texts(examples): # Concatenate all texts. concatenated_examples = { k: sum(examples[k], []) for k in examples.keys() } total_length = len(concatenated_examples[list(examples.keys())[0]]) # We drop the small remainder, we could add padding if the model # supported it. # instead of this drop, you can customize this part to your needs. total_length = (total_length // block_size) * block_size # Split by chunks of max_len. result = { k: [ t[i : i + block_size] for i in range(0, total_length, block_size) ] for k, t in concatenated_examples.items() } result["labels"] = result["input_ids"].copy() return result lm_datasets = tokenized_datasets.map( group_texts, batched=True, batch_size=1000, num_proc=1, ) ray_train_ds = ray.data.from_huggingface(lm_datasets["train"]) ray_evaluation_ds = ray.data.from_huggingface( lm_datasets["validation"] ) def trainer_init_per_worker(train_dataset, eval_dataset, **config): model_config = AutoConfig.from_pretrained(model_checkpoint) model = AutoModelForCausalLM.from_config(model_config) args = transformers.TrainingArguments( output_dir=f"{model_checkpoint}-wikitext2", evaluation_strategy="epoch", save_strategy="epoch", logging_strategy="epoch", learning_rate=2e-5, weight_decay=0.01, no_cuda=(not use_gpu), # Take a small subset for doctest max_steps=100, ) return transformers.Trainer( model=model, args=args, train_dataset=train_dataset, eval_dataset=eval_dataset, ) scaling_config = ScalingConfig(num_workers=4, use_gpu=use_gpu) trainer = TransformersTrainer( trainer_init_per_worker=trainer_init_per_worker, scaling_config=scaling_config, datasets={"train": ray_train_ds, "evaluation": ray_evaluation_ds}, ) result = trainer.fit()
- Parameters
trainer_init_per_worker – The function that returns an instantiated
transformers.Trainerobject and takes in the following arguments: trainTorch.Dataset, optional evaluationTorch.Datasetand config as kwargs. The Torch Datasets are automatically created by converting the Ray Datasets internally before they are passed into the function.trainer_init_config – Configurations to pass into
trainer_init_per_workeras kwargs.torch_config – Configuration for setting up the PyTorch backend. If set to None, use the default configuration. This replaces the
backend_configarg ofDataParallelTrainer. Same as inTorchTrainer.scaling_config – Configuration for how to scale data parallel training.
dataset_config – Configuration for dataset ingest.
run_config – Configuration for the execution of the training run.
datasets – Any Ray Datasets to use for training. Use the key “train” to denote which dataset is the training dataset and key “evaluation” to denote the evaluation dataset. Can only contain a training dataset and up to one extra dataset to be used for evaluation. If a
preprocessoris provided and has not already been fit, it will be fit on the training dataset. All datasets will be transformed by thepreprocessorif one is provided.preprocessor – A ray.data.Preprocessor to preprocess the provided datasets.
resume_from_checkpoint – A checkpoint to resume training from.
PublicAPI (alpha): This API is in alpha and may change before becoming stable.
Methods
Converts self to a
tune.Trainableclass.can_restore(path)Checks whether a given directory contains a restorable Train experiment.
fit()Runs training.
Returns a copy of this Trainer's final dataset configs.
restore(path[, trainer_init_per_worker, ...])Restores a TransformersTrainer from a previously interrupted/failed run.
setup()Called during fit() to perform initial setup on the Trainer.