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PyTorch implementation for "Matching the Blanks: Distributional Similarity for Relation Learning" paper

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BERT(S) for Relation Extraction

Overview

A PyTorch implementation of the models for the paper "Matching the Blanks: Distributional Similarity for Relation Learning" published in ACL 2019.
Note: This is not an official repo for the paper.
Additional models for relation extraction, implemented here based on the paper's methodology:

Requirements

Requirements: Python (3.6+), PyTorch (1.2.0), Spacy (2.1.8)
Pre-trained BERT(S) model courtesy of HuggingFace.co (https://huggingface.co)

Training by matching the blanks (MTB)

Run main_pretraining.py with arguments below. Pre-training data can be any .txt continuous text file.
We use Spacy NLP to grab pairwise entities (within a window size of 40 tokens length) from the text to form relation statements for pre-training. Entities recognition are based on NER and dependency tree parsing of objects/subjects.
The pre-training data (cnn.txt) that I've used can be downloaded here.

Note: Pre-training can take a long time, depending on available GPU. It is possible to directly fine-tune on the relation-extraction task and still get reasonable results, following the section below.

main_pretraining.py [-h] 
	[--pretrain_data TRAIN_PATH] 
	[--batch_size BATCH_SIZE]
	[--freeze FREEZE]  
	[--gradient_acc_steps GRADIENT_ACC_STEPS]
	[--max_norm MAX_NORM]
	[--fp16 FP_16]  
	[--num_epochs NUM_EPOCHS]
	[--lr LR]
	[--model_no MODEL_NO (0: BERT ; 1: ALBERT)]

Fine-tuning on SemEval2010 Task 8

Run main_task.py with arguments below. Requires SemEval2010 Task 8 dataset, available here.

main_task.py [-h] 
	[--train_data TRAIN_DATA]
	[--test_data TEST_DATA]
	[--use_pretrained_blanks USE_PRETRAINED_BLANKS]
	[--num_classes NUM_CLASSES] 
	[--batch_size BATCH_SIZE]
	[--gradient_acc_steps GRADIENT_ACC_STEPS]
	[--max_norm MAX_NORM]
	[--fp16 FP_16]  
	[--num_epochs NUM_EPOCHS]
	[--lr LR]
	[--model_no MODEL_NO (0: BERT ; 1: ALBERT)]
	[--train TRAIN]
	[--infer INFER]

Inference (--infer=1)

To infer a sentence, you can annotate entity1 & entity2 of interest within the sentence with their respective entities tags [E1], [E2]. Example:

Type input sentence ('quit' or 'exit' to terminate):
The surprise [E1]visit[/E1] caused a [E2]frenzy[/E2] on the already chaotic trading floor.

Sentence:  The surprise [E1]visit[/E1] caused a [E2]frenzy[/E2] on the already chaotic trading floor.
Predicted:  Cause-Effect(e1,e2) 
from src.tasks.infer import infer_from_trained

inferer = infer_from_trained(args, detect_entities=False)
test = "The surprise [E1]visit[/E1] caused a [E2]frenzy[/E2] on the already chaotic trading floor."
inferer.infer_sentence(test, detect_entities=False)
Sentence:  The surprise [E1]visit[/E1] caused a [E2]frenzy[/E2] on the already chaotic trading floor.
Predicted:  Cause-Effect(e1,e2) 

The script can also automatically detect potential entities in an input sentence, in which case all possible relation combinations are inferred:

inferer = infer_from_trained(args, detect_entities=True)
test2 = "After eating the chicken, he developed a sore throat the next morning."
inferer.infer_sentence(test2, detect_entities=True)
Sentence:  [E2]After eating the chicken[/E2] , [E1]he[/E1] developed a sore throat the next morning .
Predicted:  Other 

Sentence:  After eating the chicken , [E1]he[/E1] developed [E2]a sore throat[/E2] the next morning .
Predicted:  Other 

Sentence:  [E1]After eating the chicken[/E1] , [E2]he[/E2] developed a sore throat the next morning .
Predicted:  Other 

Sentence:  [E1]After eating the chicken[/E1] , he developed [E2]a sore throat[/E2] the next morning .
Predicted:  Other 

Sentence:  After eating the chicken , [E2]he[/E2] developed [E1]a sore throat[/E1] the next morning .
Predicted:  Other 

Sentence:  [E2]After eating the chicken[/E2] , he developed [E1]a sore throat[/E1] the next morning .
Predicted:  Cause-Effect(e2,e1) 

Benchmark Results

SemEval2010 Task 8

  1. Base architecture: BERT base uncased (12-layer, 768-hidden, 12-heads, 110M parameters)

Without MTB pre-training: F1 results when trained on 100 % training data:

  1. Base architecture: ALBERT base uncased (12 repeating layers, 128 embedding, 768-hidden, 12-heads, 11M parameters)

Without MTB pre-training: F1 results when trained on 100 % training data:

To add

  • inference & results on benchmarks (SemEval2010 Task 8) with MTB pre-training
  • felrel task

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PyTorch implementation for "Matching the Blanks: Distributional Similarity for Relation Learning" paper

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