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The pipeline API

Just like the transformers Python library, Transformers.js provides users with a simple way to leverage the power of transformers. The pipeline() function is the easiest and fastest way to use a pretrained model for inference.

For the full list of available tasks/pipelines, check out this table.

The basics

Start by creating an instance of pipeline() and specifying a task you want to use it for. For example, to create a sentiment analysis pipeline, you can do:

import { pipeline } from '@xenova/transformers';

let classifier = await pipeline('sentiment-analysis');

When running for the first time, the pipeline will download and cache the default pretrained model associated with the task. This can take a while, but subsequent calls will be much faster.

By default, models will be downloaded from the Model Database Hub and stored in browser cache, but there are ways to specify custom models and cache locations. For more information see here.

You can now use the classifier on your target text by calling it as a function:

let result = await classifier('I love transformers!');
// [{'label': 'POSITIVE', 'score': 0.9998}]

If you have multiple inputs, you can pass them as an array:

let result = await classifier(['I love transformers!', 'I hate transformers!']);
// [{'label': 'POSITIVE', 'score': 0.9998}, {'label': 'NEGATIVE', 'score': 0.9982}]

You can also specify a different model to use for the pipeline by passing it as the second argument to the pipeline() function. For example, to use a different model for sentiment analysis (like one trained to predict sentiment of a review as a number of stars between 1 and 5), you can do:

let reviewer = await pipeline('sentiment-analysis', 'Xenova/bert-base-multilingual-uncased-sentiment');

let result = await reviewer('The Shawshank Redemption is a true masterpiece of cinema.');
// [{label: '5 stars', score: 0.8167929649353027}]

Transformers.js supports loading any model hosted on the Model Database Hub, provided it has ONNX weights (located in a subfolder called onnx). For more information on how to convert your PyTorch, TensorFlow, or JAX model to ONNX, see the conversion section.

The pipeline() function is a great way to quickly use a pretrained model for inference, as it takes care of all the preprocessing and postprocessing for you. For example, if you want to perform Automatic Speech Recognition (ASR) using OpenAI’s Whisper model, you can do:

// Allocate a pipeline for Automatic Speech Recognition
let transcriber = await pipeline('automatic-speech-recognition', 'Xenova/whisper-small.en');

// Transcribe an audio file, loaded from a URL.
let result = await transcriber('https://huggingface.co/datasets/Narsil/asr_dummy/resolve/main/mlk.flac');
// {text: ' I have a dream that one day this nation will rise up and live out the true meaning of its creed.'}

Pipeline options

Loading

We offer a variety of options to control how models are loaded from the Model Database Hub (or locally). By default, the quantized version of the model is used, which is smaller and faster, but usually less accurate. To override this behaviour (i.e., use the unquantized model), you can use a custom PretrainedOptions object as the third parameter to the pipeline function:

// Allocation a pipeline for feature extraction, using the unquantized model
const pipe = await pipeline('feature-extraction', 'Xenova/all-MiniLM-L6-v2', {
    quantized: false,
});

You can also specify which revision of the model to use, by passing a revision parameter. Since the Model Database Hub uses a git-based versioning system, you can use any valid git revision specifier (e.g., branch name or commit hash)

let transcriber = await pipeline('automatic-speech-recognition', 'Xenova/whisper-tiny.en', {
    revision: 'output_attentions',
});

For the full list of options, check out the PretrainedOptions documentation.

Running

Many pipelines have additional options that you can specify. For example, when using a model that does multilingual translation, you can specify the source and target languages like this:
// Allocation a pipeline for translation
let translator = await pipeline('translation', 'Xenova/nllb-200-distilled-600M');

// Translate from English to Greek
let result = await translator('I like to walk my dog.', {
    src_lang: 'eng_Latn',
    tgt_lang: 'ell_Grek'
});
// [ { translation_text: 'Μου αρέσει να περπατάω το σκυλί μου.' } ]

// Translate back to English
let result2 = await translator(result[0].translation_text, {
    src_lang: 'ell_Grek',
    tgt_lang: 'eng_Latn'
});
// [ { translation_text: 'I like to walk my dog.' } ]

When using models that support auto-regressive generation, you can specify generation parameters like the number of new tokens, sampling methods, temperature, repetition penalty, and much more. For a full list of available parameters, see to the GenerationConfig class.

For example, to generate a poem using LaMini-Flan-T5-783M, you can do:

// Allocate a pipeline for text2text-generation
let poet = await pipeline('text2text-generation', 'Xenova/LaMini-Flan-T5-783M');
let result = await poet('Write me a love poem about cheese.', {
    max_new_tokens: 200,
    temperature: 0.9,
    repetition_penalty: 2.0,
    no_repeat_ngram_size: 3,

    // top_k: 20,
    // do_sample: true,
});

which outputs:

Cheese, oh cheese! You're the perfect comfort food.
Your texture so smooth and creamy you can never get old.
With every bite it melts in your mouth like buttery delights
that make me feel right at home with this sweet treat of mine. 

From classic to bold flavor combinations,
I love how versatile you are as an ingredient too?
Cheddar is my go-to for any occasion or mood; 
It adds depth and richness without being overpowering its taste buds alone

For more information on the available options for each pipeline, refer to the API Reference. If you would like more control over the inference process, you can use the AutoModel, AutoTokenizer, or AutoProcessor classes instead.

Available tasks

Tasks

Natural Language Processing

Task ID Description Supported?
Conversational conversational Generating conversational text that is relevant, coherent and knowledgable given a prompt.
Fill-Mask fill-mask Masking some of the words in a sentence and predicting which words should replace those masks. (docs)
(models)
Question Answering question-answering Retrieve the answer to a question from a given text. (docs)
(models)
Sentence Similarity sentence-similarity Determining how similar two texts are. (docs)
(models)
Summarization summarization Producing a shorter version of a document while preserving its important information. (docs)
(models)
Table Question Answering table-question-answering Answering a question about information from a given table.
Text Classification text-classification or sentiment-analysis Assigning a label or class to a given text. (docs)
(models)
Text Generation text-generation Producing new text by predicting the next word in a sequence. (docs)
(models)
Text-to-text Generation text2text-generation Converting one text sequence into another text sequence. (docs)
(models)
Token Classification token-classification or ner Assigning a label to each token in a text. (docs)
(models)
Translation translation Converting text from one language to another. (docs)
(models)
Zero-Shot Classification zero-shot-classification Classifying text into classes that are unseen during training. (docs)
(models)

Vision

Task ID Description Supported?
Depth Estimation depth-estimation Predicting the depth of objects present in an image.
Image Classification image-classification Assigning a label or class to an entire image. (docs)
(models)
Image Segmentation image-segmentation Divides an image into segments where each pixel is mapped to an object. This task has multiple variants such as instance segmentation, panoptic segmentation and semantic segmentation. (docs)
(models)
Image-to-Image image-to-image Transforming a source image to match the characteristics of a target image or a target image domain.
Mask Generation mask-generation Generate masks for the objects in an image.
Object Detection object-detection Identify objects of certain defined classes within an image. (docs)
(models)
Video Classification n/a Assigning a label or class to an entire video.
Unconditional Image Generation n/a Generating images with no condition in any context (like a prompt text or another image).

Audio

Task ID Description Supported?
Audio Classification audio-classification Assigning a label or class to a given audio. (docs)
(models)
Audio-to-Audio n/a Generating audio from an input audio source.
Automatic Speech Recognition automatic-speech-recognition Transcribing a given audio into text. (docs)
(models)
Text-to-Speech n/a Generating natural-sounding speech given text input.

Tabular

Task ID Description Supported?
Tabular Classification n/a Classifying a target category (a group) based on set of attributes.
Tabular Regression n/a Predicting a numerical value given a set of attributes.

Multimodal

Task ID Description Supported?
Document Question Answering document-question-answering Answering questions on document images.
Feature Extraction feature-extraction Transforming raw data into numerical features that can be processed while preserving the information in the original dataset. (docs)
(models)
Image-to-Text image-to-text Output text from a given image. (docs)
(models)
Text-to-Image text-to-image Generates images from input text.
Visual Question Answering visual-question-answering Answering open-ended questions based on an image.
Zero-Shot Image Classification zero-shot-image-classification Classifying images into classes that are unseen during training. (docs)
(models)

Reinforcement Learning

Task ID Description Supported?
Reinforcement Learning n/a Learning from actions by interacting with an environment through trial and error and receiving rewards (negative or positive) as feedback.