Code, Models, and Data for the ACL 2019 paper "Scoring Sentence Singletons and Pairs for Abstractive Summarization"
Our data consists of > 1 million sentence fusion instances, of the form:
Input: one or two articles sentences
Output: the summary sentence formed by compressing/fusing the input sentences
Our data is derived from existing summarization datasets: CNN/Daily Mail, XSum, and DUC-04.
We provide instructions on generating the data for CNN/DailyMail. Email the authors at loganlebanoff@knights.ucf.edu if you are interested in our data for XSum and DUC-04.
To generate the CNN/DailyMail data, follow the following steps:
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Download the zip files from https://github.com/JafferWilson/Process-Data-of-CNN-DailyMail. Unzip and place
cnn_stories_tokenized/
anddm_stories_tokenized/
inside the./data/cnn_dm_unprocessed/
directory. -
Run the following command to extract the articles and summaries from the CNN/DailyMail data. This will create the
articles.tsv
andsummaries.tsv
files.python create_cnndm_dataset.py
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Run the following command to run our heuristic, which decides which article sentences were used to create each of the summary sentences. This will create the
highlights.tsv
andpretty_html.html
files.python highlight_heuristic.py --dataset_name=cnn_dm
Four files will appear in the newly-created ./data/cnn_dm_processed directory. Each of the .tsv files will have the same number of lines.
-
articles.tsv
- 1 article per line, tab-separated list of sentences. Each sentence is tokenized, where each token is separated by a space (" ").
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summaries.tsv
- 1 summary per line, tab-separated list of sentences. Each sentence is tokenized, where each token is separated by a space (" ").
-
highlights.tsv
- 1 set of fusion examples per line, tab-separated list of fusion examples. The number of fusion examples corresponds to the same number of summary sentences in the same line in summaries.tsv. Each fusion example is either 0, 1, or 2 source indices (separated by ",") representing which sentences from the article were fused together to form the summary sentence.
-
pretty_html.html
- Examples highlighting which sentences were fused together to form summary sentences
Follow the steps in "Generating the data," but you may skip steps 1 and 2. Instead, you must generate the two files "article.tsv" and "summaries.tsv" (format is described above after step 3). After you have created those two files, then run step 3.
Summary outputs and models: https://www.dropbox.com/sh/g34aj101oauwlx3/AAA9dNhGlgVDQFiQrAqfMaKIa/Scoring%20Sentence%20Singletons%20and%20Pairs%20for%20Abstractive%20Summarization?dl=0
It includes the following (only for CNN/DailyMail):
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BERT-Extr summaries (see paper for more details)
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BERT-Abs w/ PG summaries (see paper for more details)
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Content Selection model (corresponds to BERT-Extr)
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Sentence Fusion model (The sentence fusion model reads from a file
logs/cnn_dm_bert_both/ssi.pkl
which contains the sentence singletons/pairs that were chosen by the content selection model.)
-
Convert the line-by-line data from the Data section to TF examples, which are used by the rest of the code.
python convert_data.py --dataset_name=cnn_dm
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Additionally, convert data to a .tsv format to be input to BERT.
python preprocess_for_bert_fine_tuning.py --dataset_name=cnn_dm python preprocess_for_bert_article.py --dataset_name=cnn_dm python bert/extract_features.py --dataset_name=cnn_dm --layers=-1,-2,-3,-4 --max_seq_length=400 --batch_size=1
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Download the pre-trained BERT-Base Uncased model from (https://storage.googleapis.com/bert_models/2018_10_18/uncased_L-12_H-768_A-12.zip), unzip, and place in the
pretrained_bert_model/
directory. -
Train the BERT model to predict whether a given sentence singleton/pair is likely to create a summary sentence or not.
cd bert/ python run_classifier.py --task_name=merge --do_train --do_eval --dataset_name=cnn_dm --num_train_epochs=1000.0 cd ..
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Following a similar training procedure to See et al. (https://github.com/abisee/pointer-generator#run-training), train the Pointer-Generator model on sentence singletons/pairs.
python run_summarization.py --mode=train --dataset_name=cnn_dm --dataset_split=train --exp_name=cnn_dm --max_enc_steps=100 --min_dec_steps=10 --max_dec_steps=30 --single_pass=False --batch_size=128 --num_iterations=10000000 --by_instance
You can perform concurrent evaluation alongside the training process.
python run_summarization.py --mode=eval --dataset_name=cnn_dm --dataset_split=val --exp_name=cnn_dm --max_enc_steps=100 --min_dec_steps=10 --max_dec_steps=30 --single_pass=False --batch_size=128 --num_iterations=10000000 --by_instance
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Once the evaluation loss begins to increase, stop training and evaluation. Then run the following command to restore the model with the lowest evaluation loss.
python run_summarization.py --mode=train --dataset_name=cnn_dm --dataset_split=train --exp_name=cnn_dm --max_enc_steps=100 --min_dec_steps=10 --max_dec_steps=30 --single_pass=False --batch_size=128 --num_iterations=10000000 --by_instance --restore_best_model
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Run BERT on test examples. This gives a score for every possible sentence in the article and every possible pair of sentences.
cd bert/ python run_classifier.py --task_name=merge --do_predict=true --dataset_name=cnn_dm cd ..
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Consolidate the scores generated from BERT to create an extractive summary. This also generates a file
ssi.pkl
which contains the sentence singletons/pairs that were selected by BERT.python bert_scores_to_summaries.py --dataset_name=cnn_dm
- Run the Pointer-Generator model on the sentence singletons/pairs chosen by BERT in the previous step. The PG model will compress sentence singletons and fuse together sentence pairs.
python sentence_fusion.py --dataset_name=cnn_dm --use_bert=True