Question answering
Question answering tasks return an answer given a question. If you’ve ever asked a virtual assistant like Alexa, Siri or Google what the weather is, then you’ve used a question answering model before. There are two common types of question answering tasks:
- Extractive: extract the answer from the given context.
- Abstractive: generate an answer from the context that correctly answers the question.
This guide will show you how to:
- Finetune DistilBERT on the SQuAD dataset for extractive question answering.
- Use your finetuned model for inference.
See the question answering task page for more information about other forms of question answering and their associated models, datasets, and metrics.
Before you begin, make sure you have all the necessary libraries installed:
pip install transformers datasets evaluate
We encourage you to login to your Hugging Face account so you can upload and share your model with the community. When prompted, enter your token to login:
>>> from huggingface_hub import notebook_login
>>> notebook_login()
Load SQuAD dataset
Start by loading a smaller subset of the SQuAD dataset from the 🤗 Datasets library. This’ll give you a chance to experiment and make sure everythings works before spending more time training on the full dataset.
>>> from datasets import load_dataset
>>> squad = load_dataset("squad", split="train[:5000]")
Split the dataset’s train
split into a train and test set with the train_test_split method:
>>> squad = squad.train_test_split(test_size=0.2)
Then take a look at an example:
>>> squad["train"][0]
{'answers': {'answer_start': [515], 'text': ['Saint Bernadette Soubirous']},
'context': 'Architecturally, the school has a Catholic character. Atop the Main Building\'s gold dome is a golden statue of the Virgin Mary. Immediately in front of the Main Building and facing it, is a copper statue of Christ with arms upraised with the legend "Venite Ad Me Omnes". Next to the Main Building is the Basilica of the Sacred Heart. Immediately behind the basilica is the Grotto, a Marian place of prayer and reflection. It is a replica of the grotto at Lourdes, France where the Virgin Mary reputedly appeared to Saint Bernadette Soubirous in 1858. At the end of the main drive (and in a direct line that connects through 3 statues and the Gold Dome), is a simple, modern stone statue of Mary.',
'id': '5733be284776f41900661182',
'question': 'To whom did the Virgin Mary allegedly appear in 1858 in Lourdes France?',
'title': 'University_of_Notre_Dame'
}
There are several important fields here:
answers
: the starting location of the answer token and the answer text.context
: background information from which the model needs to extract the answer.question
: the question a model should answer.
Preprocess
The next step is to load a DistilBERT tokenizer to process the question
and context
fields:
>>> from transformers import AutoTokenizer
>>> tokenizer = AutoTokenizer.from_pretrained("distilbert-base-uncased")
There are a few preprocessing steps particular to question answering tasks you should be aware of:
- Some examples in a dataset may have a very long
context
that exceeds the maximum input length of the model. To deal with longer sequences, truncate only thecontext
by settingtruncation="only_second"
. - Next, map the start and end positions of the answer to the original
context
by settingreturn_offset_mapping=True
. - With the mapping in hand, now you can find the start and end tokens of the answer. Use the sequence_ids method to
find which part of the offset corresponds to the
question
and which corresponds to thecontext
.
Here is how you can create a function to truncate and map the start and end tokens of the answer
to the context
:
>>> def preprocess_function(examples):
... questions = [q.strip() for q in examples["question"]]
... inputs = tokenizer(
... questions,
... examples["context"],
... max_length=384,
... truncation="only_second",
... return_offsets_mapping=True,
... padding="max_length",
... )
... offset_mapping = inputs.pop("offset_mapping")
... answers = examples["answers"]
... start_positions = []
... end_positions = []
... for i, offset in enumerate(offset_mapping):
... answer = answers[i]
... start_char = answer["answer_start"][0]
... end_char = answer["answer_start"][0] + len(answer["text"][0])
... sequence_ids = inputs.sequence_ids(i)
... # Find the start and end of the context
... idx = 0
... while sequence_ids[idx] != 1:
... idx += 1
... context_start = idx
... while sequence_ids[idx] == 1:
... idx += 1
... context_end = idx - 1
... # If the answer is not fully inside the context, label it (0, 0)
... if offset[context_start][0] > end_char or offset[context_end][1] < start_char:
... start_positions.append(0)
... end_positions.append(0)
... else:
... # Otherwise it's the start and end token positions
... idx = context_start
... while idx <= context_end and offset[idx][0] <= start_char:
... idx += 1
... start_positions.append(idx - 1)
... idx = context_end
... while idx >= context_start and offset[idx][1] >= end_char:
... idx -= 1
... end_positions.append(idx + 1)
... inputs["start_positions"] = start_positions
... inputs["end_positions"] = end_positions
... return inputs
To apply the preprocessing function over the entire dataset, use 🤗 Datasets map function. You can speed up the map
function by setting batched=True
to process multiple elements of the dataset at once. Remove any columns you don’t need:
>>> tokenized_squad = squad.map(preprocess_function, batched=True, remove_columns=squad["train"].column_names)
Now create a batch of examples using DefaultDataCollator. Unlike other data collators in 🤗 Transformers, the DefaultDataCollator does not apply any additional preprocessing such as padding.
>>> from transformers import DefaultDataCollator
>>> data_collator = DefaultDataCollator()
>>> from transformers import DefaultDataCollator
>>> data_collator = DefaultDataCollator(return_tensors="tf")
Train
If you aren’t familiar with finetuning a model with the Trainer, take a look at the basic tutorial here!
>>> from transformers import AutoModelForQuestionAnswering, TrainingArguments, Trainer
>>> model = AutoModelForQuestionAnswering.from_pretrained("distilbert-base-uncased")
At this point, only three steps remain:
- Define your training hyperparameters in TrainingArguments. The only required parameter is
output_dir
which specifies where to save your model. You’ll push this model to the Hub by settingpush_to_hub=True
(you need to be signed in to Hugging Face to upload your model). - Pass the training arguments to Trainer along with the model, dataset, tokenizer, and data collator.
- Call train() to finetune your model.
>>> training_args = TrainingArguments(
... output_dir="my_awesome_qa_model",
... evaluation_strategy="epoch",
... learning_rate=2e-5,
... per_device_train_batch_size=16,
... per_device_eval_batch_size=16,
... num_train_epochs=3,
... weight_decay=0.01,
... push_to_hub=True,
... )
>>> trainer = Trainer(
... model=model,
... args=training_args,
... train_dataset=tokenized_squad["train"],
... eval_dataset=tokenized_squad["test"],
... tokenizer=tokenizer,
... data_collator=data_collator,
... )
>>> trainer.train()
Once training is completed, share your model to the Hub with the push_to_hub() method so everyone can use your model:
>>> trainer.push_to_hub()
If you aren’t familiar with finetuning a model with Keras, take a look at the basic tutorial here!
>>> from transformers import create_optimizer
>>> batch_size = 16
>>> num_epochs = 2
>>> total_train_steps = (len(tokenized_squad["train"]) // batch_size) * num_epochs
>>> optimizer, schedule = create_optimizer(
... init_lr=2e-5,
... num_warmup_steps=0,
... num_train_steps=total_train_steps,
... )
Then you can load DistilBERT with TFAutoModelForQuestionAnswering:
>>> from transformers import TFAutoModelForQuestionAnswering
>>> model = TFAutoModelForQuestionAnswering("distilbert-base-uncased")
Convert your datasets to the tf.data.Dataset
format with prepare_tf_dataset():
>>> tf_train_set = model.prepare_tf_dataset(
... tokenized_squad["train"],
... shuffle=True,
... batch_size=16,
... collate_fn=data_collator,
... )
>>> tf_validation_set = model.prepare_tf_dataset(
... tokenized_squad["test"],
... shuffle=False,
... batch_size=16,
... collate_fn=data_collator,
... )
Configure the model for training with compile
:
>>> import tensorflow as tf
>>> model.compile(optimizer=optimizer)
The last thing to setup before you start training is to provide a way to push your model to the Hub. This can be done by specifying where to push your model and tokenizer in the PushToHubCallback:
>>> from transformers.keras_callbacks import PushToHubCallback
>>> callback = PushToHubCallback(
... output_dir="my_awesome_qa_model",
... tokenizer=tokenizer,
... )
Finally, you’re ready to start training your model! Call fit
with your training and validation datasets, the number of epochs, and your callback to finetune the model:
>>> model.fit(x=tf_train_set, validation_data=tf_validation_set, epochs=3, callbacks=[callback])
Once training is completed, your model is automatically uploaded to the Hub so everyone can use it!
For a more in-depth example of how to finetune a model for question answering, take a look at the corresponding PyTorch notebook or TensorFlow notebook.
Evaluate
Evaluation for question answering requires a significant amount of postprocessing. To avoid taking up too much of your time, this guide skips the evaluation step. The Trainer still calculates the evaluation loss during training so you’re not completely in the dark about your model’s performance.
If have more time and you’re interested in how to evaluate your model for question answering, take a look at the Question answering chapter from the 🤗 Hugging Face Course!
Inference
Great, now that you’ve finetuned a model, you can use it for inference!
Come up with a question and some context you’d like the model to predict:
>>> question = "How many programming languages does BLOOM support?"
>>> context = "BLOOM has 176 billion parameters and can generate text in 46 languages natural languages and 13 programming languages."
The simplest way to try out your finetuned model for inference is to use it in a pipeline(). Instantiate a pipeline
for question answering with your model, and pass your text to it:
>>> from transformers import pipeline
>>> question_answerer = pipeline("question-answering", model="my_awesome_qa_model")
>>> question_answerer(question=question, context=context)
{'score': 0.2058267742395401,
'start': 10,
'end': 95,
'answer': '176 billion parameters and can generate text in 46 languages natural languages and 13'}
You can also manually replicate the results of the pipeline
if you’d like:
Tokenize the text and return PyTorch tensors:
>>> from transformers import AutoTokenizer
>>> tokenizer = AutoTokenizer.from_pretrained("my_awesome_qa_model")
>>> inputs = tokenizer(question, context, return_tensors="pt")
Pass your inputs to the model and return the logits
:
>>> from transformers import AutoModelForQuestionAnswering
>>> model = AutoModelForQuestionAnswering.from_pretrained("my_awesome_qa_model")
>>> with torch.no_grad():
... outputs = model(**inputs)
Get the highest probability from the model output for the start and end positions:
>>> answer_start_index = outputs.start_logits.argmax()
>>> answer_end_index = outputs.end_logits.argmax()
Decode the predicted tokens to get the answer:
>>> predict_answer_tokens = inputs.input_ids[0, answer_start_index : answer_end_index + 1]
>>> tokenizer.decode(predict_answer_tokens)
'176 billion parameters and can generate text in 46 languages natural languages and 13'
Tokenize the text and return TensorFlow tensors:
>>> from transformers import AutoTokenizer
>>> tokenizer = AutoTokenizer.from_pretrained("my_awesome_qa_model")
>>> inputs = tokenizer(question, text, return_tensors="tf")
Pass your inputs to the model and return the logits
:
>>> from transformers import TFAutoModelForQuestionAnswering
>>> model = TFAutoModelForQuestionAnswering.from_pretrained("my_awesome_qa_model")
>>> outputs = model(**inputs)
Get the highest probability from the model output for the start and end positions:
>>> answer_start_index = int(tf.math.argmax(outputs.start_logits, axis=-1)[0])
>>> answer_end_index = int(tf.math.argmax(outputs.end_logits, axis=-1)[0])
Decode the predicted tokens to get the answer:
>>> predict_answer_tokens = inputs.input_ids[0, answer_start_index : answer_end_index + 1]
>>> tokenizer.decode(predict_answer_tokens)
'176 billion parameters and can generate text in 46 languages natural languages and 13'