ELECTRA: Pre-training Text Encoders as Discriminators Rather Than Generators

Overview

ELECTRA

Introduction

ELECTRA is a method for self-supervised language representation learning. It can be used to pre-train transformer networks using relatively little compute. ELECTRA models are trained to distinguish "real" input tokens vs "fake" input tokens generated by another neural network, similar to the discriminator of a GAN. At small scale, ELECTRA achieves strong results even when trained on a single GPU. At large scale, ELECTRA achieves state-of-the-art results on the SQuAD 2.0 dataset.

For a detailed description and experimental results, please refer to our ICLR 2020 paper ELECTRA: Pre-training Text Encoders as Discriminators Rather Than Generators.

This repository contains code to pre-train ELECTRA, including small ELECTRA models on a single GPU. It also supports fine-tuning ELECTRA on downstream tasks including classification tasks (e.g,. GLUE), QA tasks (e.g., SQuAD), and sequence tagging tasks (e.g., text chunking).

This repository also contains code for Electric, a version of ELECTRA inspired by energy-based models. Electric provides a more principled view of ELECTRA as a "negative sampling" cloze model. It can also efficiently produce pseudo-likelihood scores for text, which can be used to re-rank the outputs of speech recognition or machine translation systems. For details on Electric, please refer to out EMNLP 2020 paper Pre-Training Transformers as Energy-Based Cloze Models.

Released Models

We are initially releasing three pre-trained models:

Model Layers Hidden Size Params GLUE score (test set) Download
ELECTRA-Small 12 256 14M 77.4 link
ELECTRA-Base 12 768 110M 82.7 link
ELECTRA-Large 24 1024 335M 85.2 link

The models were trained on uncased English text. They correspond to ELECTRA-Small++, ELECTRA-Base++, ELECTRA-1.75M in our paper. We hope to release other models, such as multilingual models, in the future.

On GLUE, ELECTRA-Large scores slightly better than ALBERT/XLNET, ELECTRA-Base scores better than BERT-Large, and ELECTRA-Small scores slightly worst than TinyBERT (but uses no distillation). See the expected results section below for detailed performance numbers.

Requirements

Pre-training

Use build_pretraining_dataset.py to create a pre-training dataset from a dump of raw text. It has the following arguments:

  • --corpus-dir: A directory containing raw text files to turn into ELECTRA examples. A text file can contain multiple documents with empty lines separating them.
  • --vocab-file: File defining the wordpiece vocabulary.
  • --output-dir: Where to write out ELECTRA examples.
  • --max-seq-length: The number of tokens per example (128 by default).
  • --num-processes: If >1 parallelize across multiple processes (1 by default).
  • --blanks-separate-docs: Whether blank lines indicate document boundaries (True by default).
  • --do-lower-case/--no-lower-case: Whether to lower case the input text (True by default).

Use run_pretraining.py to pre-train an ELECTRA model. It has the following arguments:

  • --data-dir: a directory where pre-training data, model weights, etc. are stored. By default, the training loads examples from <data-dir>/pretrain_tfrecords and a vocabulary from <data-dir>/vocab.txt.
  • --model-name: a name for the model being trained. Model weights will be saved in <data-dir>/models/<model-name> by default.
  • --hparams (optional): a JSON dict or path to a JSON file containing model hyperparameters, data paths, etc. See configure_pretraining.py for the supported hyperparameters.

If training is halted, re-running the run_pretraining.py with the same arguments will continue the training where it left off.

You can continue pre-training from the released ELECTRA checkpoints by

  1. Setting the model-name to point to a downloaded model (e.g., --model-name electra_small if you downloaded weights to $DATA_DIR/electra_small).
  2. Setting num_train_steps by (for example) adding "num_train_steps": 4010000 to the --hparams. This will continue training the small model for 10000 more steps (it has already been trained for 4e6 steps).
  3. Increase the learning rate to account for the linear learning rate decay. For example, to start with a learning rate of 2e-4 you should set the learning_rate hparam to 2e-4 * (4e6 + 10000) / 10000.
  4. For ELECTRA-Small, you also need to specifiy "generator_hidden_size": 1.0 in the hparams because we did not use a small generator for that model.

Quickstart: Pre-train a small ELECTRA model.

These instructions pre-train a small ELECTRA model (12 layers, 256 hidden size). Unfortunately, the data we used in the paper is not publicly available, so we will use the OpenWebTextCorpus released by Aaron Gokaslan and Vanya Cohen instead. The fully-trained model (~4 days on a v100 GPU) should perform roughly in between GPT and BERT-Base in terms of GLUE performance. By default the model is trained on length-128 sequences, so it is not suitable for running on question answering. See the "expected results" section below for more details on model performance.

Setup

  1. Place a vocabulary file in $DATA_DIR/vocab.txt. Our ELECTRA models all used the exact same vocabulary as English uncased BERT, which you can download here.
  2. Download the OpenWebText corpus (12G) and extract it (i.e., run tar xf openwebtext.tar.xz). Place it in $DATA_DIR/openwebtext.
  3. Run python3 build_openwebtext_pretraining_dataset.py --data-dir $DATA_DIR --num-processes 5. It pre-processes/tokenizes the data and outputs examples as tfrecord files under $DATA_DIR/pretrain_tfrecords. The tfrecords require roughly 30G of disk space.

Pre-training the model.

Run python3 run_pretraining.py --data-dir $DATA_DIR --model-name electra_small_owt to train a small ELECTRA model for 1 million steps on the data. This takes slightly over 4 days on a Tesla V100 GPU. However, the model should achieve decent results after 200k steps (10 hours of training on the v100 GPU).

To customize the training, add --hparams '{"hparam1": value1, "hparam2": value2, ...}' to the run command. --hparams can also be a path to a .json file containing the hyperparameters. Some particularly useful options:

  • "debug": true trains a tiny ELECTRA model for a few steps.
  • "model_size": one of "small", "base", or "large": determines the size of the model
  • "electra_objective": false trains a model with masked language modeling instead of replaced token detection (essentially BERT with dynamic masking and no next-sentence prediction).
  • "num_train_steps": n controls how long the model is pre-trained for.
  • "pretrain_tfrecords": <paths> determines where the pre-training data is located. Note you need to specify the specific files not just the directory (e.g., <data-dir>/pretrain_tf_records/pretrain_data.tfrecord*)
  • "vocab_file": <path> and "vocab_size": n can be used to set a custom wordpiece vocabulary.
  • "learning_rate": lr, "train_batch_size": n, etc. can be used to change training hyperparameters
  • "model_hparam_overrides": {"hidden_size": n, "num_hidden_layers": m}, etc. can be used to changed the hyperparameters for the underlying transformer (the "model_size" flag sets the default values).

See configure_pretraining.py for the full set of supported hyperparameters.

Evaluating the pre-trained model.

To evaluate the model on a downstream task, see the below finetuning instructions. To evaluate the generator/discriminator on the openwebtext data run python3 run_pretraining.py --data-dir $DATA_DIR --model-name electra_small_owt --hparams '{"do_train": false, "do_eval": true}'. This will print out eval metrics such as the accuracy of the generator and discriminator, and also writing the metrics out to data-dir/model-name/results.

Fine-tuning

Use run_finetuning.py to fine-tune and evaluate an ELECTRA model on a downstream NLP task. It expects three arguments:

  • --data-dir: a directory where data, model weights, etc. are stored. By default, the script loads finetuning data from <data-dir>/finetuning_data/<task-name> and a vocabulary from <data-dir>/vocab.txt.
  • --model-name: a name of the pre-trained model: the pre-trained weights should exist in data-dir/models/model-name.
  • --hparams: a JSON dict containing model hyperparameters, data paths, etc. (e.g., --hparams '{"task_names": ["rte"], "model_size": "base", "learning_rate": 1e-4, ...}'). See configure_pretraining.py for the supported hyperparameters. Instead of a dict, this can also be a path to a .json file containing the hyperparameters. You must specify the "task_names" and "model_size" (see examples below).

Eval metrics will be saved in data-dir/model-name/results and model weights will be saved in data-dir/model-name/finetuning_models by default. Evaluation is done on the dev set by default. To customize the training, add --hparams '{"hparam1": value1, "hparam2": value2, ...}' to the run command. Some particularly useful options:

  • "debug": true fine-tunes a tiny ELECTRA model for a few steps.
  • "task_names": ["task_name"]: specifies the tasks to train on. A list because the codebase nominally supports multi-task learning, (although be warned this has not been thoroughly tested).
  • "model_size": one of "small", "base", or "large": determines the size of the model; you must set this to the same size as the pre-trained model.
  • "do_train" and "do_eval": train and/or evaluate a model (both are set to true by default). For using "do_eval": true with "do_train": false, you need to specify the init_checkpoint, e.g., python3 run_finetuning.py --data-dir $DATA_DIR --model-name electra_base --hparams '{"model_size": "base", "task_names": ["mnli"], "do_train": false, "do_eval": true, "init_checkpoint": "<data-dir>/models/electra_base/finetuning_models/mnli_model_1"}'
  • "num_trials": n: If >1, does multiple fine-tuning/evaluation runs with different random seeds.
  • "learning_rate": lr, "train_batch_size": n, etc. can be used to change training hyperparameters.
  • "model_hparam_overrides": {"hidden_size": n, "num_hidden_layers": m}, etc. can be used to changed the hyperparameters for the underlying transformer (the "model_size" flag sets the default values).

Setup

Get a pre-trained ELECTRA model either by training your own (see pre-training instructions above), or downloading the release ELECTRA weights and unziping them under $DATA_DIR/models (e.g., you should have a directory$DATA_DIR/models/electra_large if you are using the large model).

Finetune ELECTRA on a GLUE task

Download the GLUE data by running this script. Set up the data by running mv CoLA cola && mv MNLI mnli && mv MRPC mrpc && mv QNLI qnli && mv QQP qqp && mv RTE rte && mv SST-2 sst && mv STS-B sts && mv diagnostic/diagnostic.tsv mnli && mkdir -p $DATA_DIR/finetuning_data && mv * $DATA_DIR/finetuning_data.

Then run run_finetuning.py. For example, to fine-tune ELECTRA-Base on MNLI

python3 run_finetuning.py --data-dir $DATA_DIR --model-name electra_base --hparams '{"model_size": "base", "task_names": ["mnli"]}'

Or fine-tune a small model pre-trained using the above instructions on CoLA.

python3 run_finetuning.py --data-dir $DATA_DIR --model-name electra_small_owt --hparams '{"model_size": "small", "task_names": ["cola"]}'

Finetune ELECTRA on question answering

The code supports SQuAD 1.1 and 2.0, as well as datasets in the 2019 MRQA shared task

  • Squad 1.1: Download the train and dev datasets and move them under $DATA_DIR/finetuning_data/squadv1/(train|dev).json
  • Squad 2.0: Download the datasets from the SQuAD Website and move them under $DATA_DIR/finetuning_data/squad/(train|dev).json
  • MRQA tasks: Download the data from here. Move the data to $DATA_DIR/finetuning_data/(newsqa|naturalqs|triviaqa|searchqa)/(train|dev).jsonl.

Then run (for example)

python3 run_finetuning.py --data-dir $DATA_DIR --model-name electra_base --hparams '{"model_size": "base", "task_names": ["squad"]}'

This repository uses the official evaluation code released by the SQuAD authors and the MRQA shared task to compute metrics

Finetune ELECTRA on sequence tagging

Download the CoNLL-2000 text chunking dataset from here and put it under $DATA_DIR/finetuning_data/chunk/(train|dev).txt. Then run

python3 run_finetuning.py --data-dir $DATA_DIR --model-name electra_base --hparams '{"model_size": "base", "task_names": ["chunk"]}'

Adding a new task

The easiest way to run on a new task is to implement a new finetune.task.Task, add it to finetune.task_builder.py, and then use run_finetuning.py as normal. For classification/qa/sequence tagging, you can inherit from a finetune.classification.classification_tasks.ClassificationTask, finetune.qa.qa_tasks.QATask, or finetune.tagging.tagging_tasks.TaggingTask. For preprocessing data, we use the same tokenizer as BERT.

Expected Results

Here are expected results for ELECTRA on various tasks (test set for chunking, dev set for the other tasks). Note that variance in fine-tuning can be quite large, so for some tasks you may see big fluctuations in scores when fine-tuning from the same checkpoint multiple times. The below scores show median performance over a large number of random seeds. ELECTRA-Small/Base/Large are our released models. ELECTRA-Small-OWT is the OpenWebText-trained model from above (it performs a bit worse than ELECTRA-Small due to being trained for less time and on a smaller dataset).

CoLA SST MRPC STS QQP MNLI QNLI RTE SQuAD 1.1 SQuAD 2.0 Chunking
Metrics MCC Acc Acc Spearman Acc Acc Acc Acc EM EM F1
ELECTRA-Large 69.1 96.9 90.8 92.6 92.4 90.9 95.0 88.0 89.7 88.1 97.2
ELECTRA-Base 67.7 95.1 89.5 91.2 91.5 88.8 93.2 82.7 86.8 80.5 97.1
ELECTRA-Small 57.0 91.2 88.0 87.5 89.0 81.3 88.4 66.7 75.8 70.1 96.5
ELECTRA-Small-OWT 56.8 88.3 87.4 86.8 88.3 78.9 87.9 68.5 -- -- --

See here for losses / training curves of the models during pre-training.

Electric

To train Electric, use the same pre-training script and command as ELECTRA. Pass "electra_objective": false and "electric_objective": true to the hyperparameters. We plan to release pre-trained Electric models soon!

Citation

If you use this code for your publication, please cite the original paper:

@inproceedings{clark2020electra,
  title = {{ELECTRA}: Pre-training Text Encoders as Discriminators Rather Than Generators},
  author = {Kevin Clark and Minh-Thang Luong and Quoc V. Le and Christopher D. Manning},
  booktitle = {ICLR},
  year = {2020},
  url = {https://openreview.net/pdf?id=r1xMH1BtvB}
}

If you use the code for Electric, please cite the Electric paper:

@inproceedings{clark2020electric,
  title = {Pre-Training Transformers as Energy-Based Cloze Models},
  author = {Kevin Clark and Minh-Thang Luong and Quoc V. Le and Christopher D. Manning},
  booktitle = {EMNLP},
  year = {2020},
  url = {https://www.aclweb.org/anthology/2020.emnlp-main.20.pdf}
}

Contact Info

For help or issues using ELECTRA, please submit a GitHub issue.

For personal communication related to ELECTRA, please contact Kevin Clark ([email protected]).

Owner
Google Research
Google Research
中文問句產生器;使用台達電閱讀理解資料集(DRCD)

Transformer QG on DRCD The inputs of the model refers to we integrate C and A into a new C' in the following form. C' = [c1, c2, ..., [HL], a1, ..., a

Philip 1 Oct 22, 2021
Türkçe küfürlü içerikleri bulan bir yapay zeka kütüphanesi / An ML library for profanity detection in Turkish sentences

"Kötü söz sahibine aittir." -Anonim Nedir? sinkaf uygunsuz yorumların bulunmasını sağlayan bir python kütüphanesidir. Farkı nedir? Diğer algoritmalard

KaraGoz 4 Feb 18, 2022
Signature remover is a NLP based solution which removes email signatures from the rest of the text.

Signature Remover Signature remover is a NLP based solution which removes email signatures from the rest of the text. It helps to enchance data conten

Forges Alterway 8 Jan 06, 2023
Script to download some free japanese lessons in portuguse from NHK

Nihongo_nhk This is a script to download some free japanese lessons in portuguese from NHK. It can be executed by installing the packages with: pip in

Matheus Alves 2 Jan 06, 2022
🕹 An esoteric language designed so that the program looks like the transcript of a Pokémon battle

PokéBattle is an esoteric language designed so that the program looks like the transcript of a Pokémon battle. Original inspiration and specification

Eduardo Correia 9 Jan 11, 2022
Shared, streaming Python dict

UltraDict Sychronized, streaming Python dictionary that uses shared memory as a backend Warning: This is an early hack. There are only few unit tests

Ronny Rentner 192 Dec 23, 2022
💬 Open source machine learning framework to automate text- and voice-based conversations: NLU, dialogue management, connect to Slack, Facebook, and more - Create chatbots and voice assistants

Rasa Open Source Rasa is an open source machine learning framework to automate text-and voice-based conversations. With Rasa, you can build contextual

Rasa 15.3k Jan 03, 2023
An assignment on creating a minimalist neural network toolkit for CS11-747

minnn by Graham Neubig, Zhisong Zhang, and Divyansh Kaushik This is an exercise in developing a minimalist neural network toolkit for NLP, part of Car

Graham Neubig 63 Dec 29, 2022
A simple recipe for training and inferencing Transformer architecture for Multi-Task Learning on custom datasets. You can find two approaches for achieving this in this repo.

multitask-learning-transformers A simple recipe for training and inferencing Transformer architecture for Multi-Task Learning on custom datasets. You

Shahrukh Khan 48 Jan 02, 2023
Library of deep learning models and datasets designed to make deep learning more accessible and accelerate ML research.

Tensor2Tensor Tensor2Tensor, or T2T for short, is a library of deep learning models and datasets designed to make deep learning more accessible and ac

12.9k Jan 07, 2023
Script to generate VAD dataset used in Asteroid recipe

About the dataset LibriVAD is an open source dataset for voice activity detection in noisy environments. It is derived from LibriSpeech signals (clean

11 Sep 15, 2022
Prompt tuning toolkit for GPT-2 and GPT-Neo

mkultra mkultra is a prompt tuning toolkit for GPT-2 and GPT-Neo. Prompt tuning injects a string of 20-100 special tokens into the context in order to

61 Jan 01, 2023
A text file containing 479k English words for all your dictionary/word-based projects e.g: auto-completion / autosuggestion

List Of English Words A text file containing over 466k English words. While searching for a list of english words (for an auto-complete tutorial) I fo

dwyl 8.5k Jan 03, 2023
Grapheme-to-phoneme (G2P) conversion is the process of generating pronunciation for words based on their written form.

Neural G2P to portuguese language Grapheme-to-phoneme (G2P) conversion is the process of generating pronunciation for words based on their written for

fluz 11 Nov 16, 2022
ChainKnowledgeGraph, 产业链知识图谱包括A股上市公司、行业和产品共3类实体

ChainKnowledgeGraph, 产业链知识图谱包括A股上市公司、行业和产品共3类实体,包括上市公司所属行业关系、行业上级关系、产品上游原材料关系、产品下游产品关系、公司主营产品、产品小类共6大类。 上市公司4,654家,行业511个,产品95,559条、上游材料56,824条,上级行业480条,下游产品390条,产品小类52,937条,所属行业3,946条。

liuhuanyong 415 Jan 06, 2023
Indonesia spellchecker with python

indonesia-spellchecker Ganti kata yang terdapat pada file teks.txt untuk diperiksa kebenaran kata. Run on local machine python3 main.py

Rahmat Agung Julians 1 Sep 14, 2022
Full Spectrum Bioinformatics - a free online text designed to introduce key topics in Bioinformatics using the Python

Full Spectrum Bioinformatics is a free online text designed to introduce key topics in Bioinformatics using the Python programming language. The text is written in interactive Jupyter Notebooks, whic

Jesse Zaneveld 33 Dec 28, 2022
This github repo is for Neurips 2021 paper, NORESQA A Framework for Speech Quality Assessment using Non-Matching References.

NORESQA: Speech Quality Assessment using Non-Matching References This is a Pytorch implementation for using NORESQA. It contains minimal code to predi

Meta Research 36 Dec 08, 2022
spaCy-wrap: For Wrapping fine-tuned transformers in spaCy pipelines

spaCy-wrap: For Wrapping fine-tuned transformers in spaCy pipelines spaCy-wrap is minimal library intended for wrapping fine-tuned transformers from t

Kenneth Enevoldsen 32 Dec 29, 2022
Modeling cumulative cases of Covid-19 in the US during the Covid 19 Delta wave using Bayesian methods.

Introduction The goal of this analysis is to find a model that fits the observed cumulative cases of COVID-19 in the US, starting in Mid-July 2021 and

Alexander Keeney 1 Jan 05, 2022