SuperGLUE

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Presented by

Shikhar Sakhuja

Introduction

Natural Language Processing (NLP) has seen immense improvements over the past two years. The improvements offered by RNN-based model such as ELMo [2], and Transformer [1] based models such as OpenAI GPT [3] and BERT[4], have revolutionized the field. These models render GLUE [5], the standard benchmark for NLP tasks, ineffective. The GLUE benchmark was released over a year ago and assessed NLP models using a single-number metric that summarized performance over some diverse tasks. However, the transformer-based models outperform the non-expert humans in several tasks. With transformer-based models achieving near-perfect scores on almost all tasks in GLUE and outperforming humans in some, there is a need for a new benchmark that involves harder and even more diverse language tasks. The authors release SuperGLUE as a new benchmark that has a more rigorous set of language understanding tasks.

Related Work

There have been several benchmarks attempting to standardize the field of language understanding tasks. SentEval [6] evaluated fixed-size sentence embeddings for tasks. DecaNLP [7] converts tasks into a general question-answering format. GLUE offers a much more flexible and extensible benchmark since it imposes no restrictions on model architectures or parameter sharing.

GLUE has been the gold standard for language understanding tests since its release. In fact, the benchmark has promoted growth in language models with all the transformer-based models started with attempting to achieve high scores on GLUE. Original GPT and BERT models scored 72.8 and 80.2 on GLUE. The latest GPT and BERT models, however, far outperform these benchmarks and strike a need for a more robust and difficult benchmark.

Motivation

Transformer based NLP models allow NLP models to train using transfer learning which was previously only seen in Computer Vision tasks and was notoriously difficult for language because of the discrete nature of words. Transfer Learning in NLP allows models to be trained over terabytes of language data in a self-supervised fashion. These models can then be finetuned for downstream tasks such as sentiment classification and fake news detection. The fine-tuned models beat many of the human labelers who weren’t experts in the domain. Thus, it creates a need for a newer, more robust baseline that can stay relevant with the rapid improvements in the field of NLP.

Figure 1: Transformer-based models outperforming humans in GLUE tasks.

Improvements to GLUE

SuperGLUE follows the design principles of GLUE but seeks to improve on its predecessor in many ways:

More challenging tasks: SuperGLUE contains the two hardest tasks in GLUE and open tasks that are difficult to current NLP approaches.

More diverse task formats: SuperGLUE expands GLUE task formats to include coreference resolution and question answering.

Comprehensive human baselines: Human performance estimates are provided for all benchmark tasks.

Improved code support: SuperGLUE is build around the widely used tools including PyTorch and AllenNLP.

Refined usage rules: SuperGLUE leaderboard ensures fair competition and full credit to creators.

Design Process

SuperGLUE is designed to be widely applicable to many different NLP tasks. That being said, in designing SuperGLUE, certain criteria needed to be established to determine whether a NLP task can be completed. The authors specified six such requirements, which are listed below.

  1. Task substance: Tasks should test a system's reasoning and understanding of English text.
  2. Task difficulty: Tasks should be solvable by those who graduated from an English postsecondary institution.
  3. Evaluability: Tasks are required to have an automated performance metric that aligns to human judgements of the output quality.
  4. Public data: Tasks need to have existing public data for training with a preference for an additional private test set.
  5. Task format: Preference for tasks with simpler input and output formats to steer users of the benchmark away from tasks specific architectures.
  6. License: Task data must be under a license that allows the redistribution and use for research.

To select tasks that would be included in the benchmarks, the authors put a public request for NLP tasks and received many. From this, they filtered the tasks according to the criteria above as well as eliminating any tasks that could not be used due to licensing issues or other problems.

SuperGLUE Tasks

SuperGLUE has 8 language understanding tasks. They test a model’s understanding of texts in English. The tasks are built to be equivalent to the capabilities of most college-educated English speakers and are beyond the capabilities of most state-of-the-art systems today.

BoolQ (Boolean Questions [9]): QA task consisting of short passage and related questions to the passage as either a yes or a no answer.

CB (CommitmentBank [10]): Corpus of text where sentences have embedded clauses and sentences are written with the goal of keeping the clause accurate.

COPA (Choice of plausible Alternatives [11]): Reasoning tasks in which given a sentence the system must be able to choose the cause or effect of the sentence from two potential choices.

MultiRC (Multi-Sentence Reading Comprehension [12]): QA task in which given a passage and potential answers, the model should label the answers as true or false.

ReCoRD (Reading Comprehension with Commonsense Reasoning Dataset [13]): A multiple-choice, question answering task, where given a passage with a masked entity, the model should be able to predict the masked out entity from the choices.

RTE (Recognizing Textual Entailment [14]): Classifying whether a text can be plausibly inferred from a given passage.

WiC (Word in Context [15]): Identifying whether a polysemous word used in multiple sentences is being used with the same sense across sentences or not.

WSC (Winograd Schema Challenge, [16]): A conference resolution task where sentences include pronouns and noun phrases from the sentence. The goal is to identify the correct reference to a noun phrase corresponding to the pronoun.

The above table briefly corresponds to the different tasks included in SuperGLUE. In the above table, WSD stands for word sense disambiguation, NLI is natural language inference, coref. is coreference resolution, and QA is question answering.


Scoring

With GLUE, they seek to give a sense of aggregate system performance over all tasks by averaging scores of all tasks. Lacking a fair criterion with which to weight the contributions of each task to the overall score, they opt for the simple approach of weighing each task equally, and for tasks with multiple metrics, first averaging those metrics to get a task score.

Model Analysis

SuperGLUE includes two tasks for analyzing linguistic knowledge and gender bias in models. To analyze linguistic and world knowledge, submissions to SuperGLUE are required to include predictions of sentence pair relation (entailment, not_entailment) on the resulting set for RTE task. As for gender bias, SuperGLUE includes a diagnostic dataset Winogender, which measures gender bias in co-reference resolution systems. A poor bias score indicates gender bias, however, a good score does not necessarily mean a model is unbiased. This is one limitation of the dataset.

Results

Table 1 offers a summary of the results from SuperGLUE across different models. CBOW baselines are generally close to roughly chance performance. BERT, on the other hand, increased the SuperGLUE score by 25 points and had the highest improvement on most tasks, especially MultiRCC, ReCoRD, and RTE. WSC is trickier for BERT, potentially owing to the small dataset size.

BERT++[8] increases BERT’s performance even further. However, achieving the goal of the benchmark, the best model/score still lags behind compared to human performance. The human results for WiC, MltiRC, RTE, and ReCoRD were already available on [15], [12], [17], and [13] respectively. However, for the remaining tasks, the authors employed crowdworkers to reannotate a sample of each test set according to the methods used in [17]. The large gaps should be relatively tricky for models to close in on. The biggest margin is for WSC with 35 points and CV, RTE, BoolQ, WiC all have 10 point margins.


Table 1: Baseline performance on SuperGLUE tasks.

Conclusion

SuperGLUE fills the gap that GLUE has created owing to its inability to keep up with the SOTA in NLP. The new language tasks that the benchmark offers are built to be more robust and difficult to solve for NLP models. With the difference in model accuracy being around 10-35 points across all tasks, SuperGLUE is definitely going to be around for some time before the models catch up to it, as well. Overall, this is a significant contribution to improve general-purpose natural language understanding.

Critique

This is quite a fascinating read where the authors of the gold-standard benchmark have essentially conceded to the progress in NLP. Bowman’s team resorting to creating a new benchmark altogether to keep up with the rapid pace of increase in NLP makes me wonder if these benchmarks are inherently flawed. Applying the idea of Wittgenstein’s Ruler, are we measuring the performance of models using the benchmark, or the quality of benchmarks using the models?

I’m curious how long SuperGLUE would stay relevant owing to advances in NLP. GPT-3, released in June 2020, has outperformed GPT-2 and BERT by a huge margin, given the 100x increase in parameters (175B Parameters over ~600GB for GPT-3, compared to 1.5B parameters over 40GB for GPT-2). In October 2020, a new deep learning technique (Pattern Exploiting Training) managed to train a Transformer NLP model with 223M parameters (roughly 0.01% parameters of GPT-3) and outperformed GPT-3 by 3 points on SuperGLUE. With the field improving so rapidly, I think superGLUE is nothing but a bandaid for the benchmarking tasks that will turn obsolete in no time.

References

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[3] Alec Radford, Karthik Narasimhan, Tim Salimans, and Ilya Sutskever. Improving language understanding by generative pre-training, 2018. Unpublished ms. available through a link at https://blog.openai.com/language-unsupervised/.

[4] Jacob Devlin, Ming-Wei Chang, Kenton Lee, and Kristina Toutanova. BERT: Pre-training of deep bidirectional transformers for language understanding. In Proceedings of the Conference of the North American Chapter of the Association for Computational Linguistics: Human Language Technologies (NAACL-HLT). Association for Computational Linguistics, 2019. URL https: //arxiv.org/abs/1810.04805.

[5] Alex Wang, Amanpreet Singh, Julian Michael, Felix Hill, Omer Levy, and Samuel R. Bowman. GLUE: A multi-task benchmark and analysis platform for natural language understanding. In International Conference on Learning Representations, 2019a. URL https://openreview.net/forum?id=rJ4km2R5t7.

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[13] Sheng Zhang, Xiaodong Liu, Jingjing Liu, Jianfeng Gao, Kevin Duh, and Benjamin Van Durme. ReCoRD: Bridging the gap between human and machine commonsense reading comprehension. arXiv preprint 1810.12885, 2018.

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[17] Nikita Nangia and Samuel R. Bowman. Human vs. Muppet: A conservative estimate of human performance on the GLUE benchmark. In Proceedings of the Association of Computational Linguistics (ACL). Association for Computational Linguistics, 2019. URL https://woollysocks.github.io/assets/GLUE_Human_Baseline.pdf.