Compositional Exemplars for In-context Learning

This repository contains the source code for CEIL, which is an in-context example retriever proposed in our paper “Compositional Exemplars for In-context Learning”, Besides, this repo also implements several learning-free (e.g., Random, BM25, TopK-BERT, TopK-DPP) and learning-based retrievers (e.g., EPR).

Instead of independently retrieving each exemplar (or in-context example), CEIL models the full exemplar sets by learning its joint probability with a conditional DPP, which is further trained to align with the LM score through a contrastive loss. For a given test input during inference, the optimal exemplar set is obtained by the learned DPP retriever through MAP inference. The black-box LM is frozen during the whole procedure.

Contents

• Setup
• Usage
• Modules
• Add a New Task
• Citation

Setup

All required packages can be found in requirements.txt. You can install them in a new environment with

conda create -n icl python=3.7
conda activate icl

git clone [email protected]:HKUNLP/icl-ceil.git
#[Optional] If you want to experiment on Break dataset with LF-EM evaluation metric, you have to clone recursively with the following commands to include third-party dependencies:
#git clone --recurse-submodules [email protected]:HKUNLP/HKUNLP.git

# The following line to be replaced depending on your cuda version.
pip install torch==1.10.1+cu113 -f https://download.pytorch.org/whl/torch_stable.html

cd icl-ceil
pip install -r requirements.txt
# if you don't want to use API from openai, just comment out the `openai` package in `requirements.txt`.

Setup WandB for tracking the training status for EPR and CEIL in scripts/run_epr.sh and scripts/run_dpp_epr.sh:

export WANDB_API_KEY=YOUR_WANDB_API_KEY
export WANDB_PROJECT=YOUR_PROJECT_NAME
export WANDB_ENTITY=YOUR_TEAM_NAME

Usage

Given an index dataset (by default the training set) and an test dataset (by default the validation set), we include scripts to run six in-context example retrievers under scripts/:

• run_random.sh: random retrieve;
• run_bm25.sh: sparse retrieve with BM25;
• run_dense.sh: dense retrieve with BERT encoder;
• run_dense_dpp.sh: dense retrieve with BERT encoder, considering diversity between examples;
• run_epr.sh: the learning-based retriever trained to retrieve a better singleton in-context example (Rubin et al., 2022);
• run_ceil.sh: our proposed learning-based retriever. You need to run run_epr.sh first to get an initialization for training CEIL.

The config files and detailed explanation of each argument can be found in configs/.

Modules

1. bm25_retriever.py: retrieve examples from training set with bm25, saved json will have additional field:
   • ctxs: a single in-context example sequence which can be directly used in inferencer. This is a idx list and each idx specifies the position of an example in the index (e.g., training set).
   • ctxs_candidates: multiple in-context example sequences which can be used to train a dense retriever by further running scorer and retriever_trainer. This is a list of idx list.
2. dense_retriever.py: similar as bm25_retriever but retrieve examples with embed model, which is specified in configs/dense_retriever.yaml.
3. scorer.py: scoring each candidate in ctxs_candidates and reranking ctxs_candidates based on the scores to create a training data.
4. retriever_trainer.py: train a dense retriever based on the ordered ctxs_candidates by contrastive learning.
5. inferencer.py: in-context learning inference with pre-retrieved in-context examples (i.e., ctxs) and report the final metric.

When using a local huggingface model as inferencer LM, both scorer and inferencer use accelerate to run on multiple GPUs in parallel. For API-based inferencer, we also support multiprocessing api calls. For example, you can input multiple (say n) OpenAI authenticated keys in openai_keys.txt, and we will create n processes to run the inference.

For each task, a dataset_wrapper is needed, which defines the q (input or question) and a (output or answer) fields. Besides, qa and gen_a fields are used to define the format of each in-context example and the whole prompt.

For classification tasks, an additional field is choices, which pre-defines the description for each class. During answer generation for classification tasks, we select the class description that has the lowest LM perplexity.

Add a New Task

Change the task by modify task_name argument, and the current available tasks are sst5, mrpc, qnli, mnli, cmsqa, swag, webqs, geoquery, nl2bash, mtop, break, smcalflow. It's easy to add a new task with this repo. You can take the following steps:

1. (Optional) Define a dataset script under src/hf_datasets if the dataset is not available in Huggingface Datasets.
2. Create a file under src/dataset_readers/dataset_wrapper, and define several interfaces of getting question (task input), answer (task output) and prompt, which will be used by different dataset_readers (e.g., base_dsr, inference_dsr).
3. (Optional) Define the task metric under src/metrics if you have ground-truth outputs for your test dataset.

Citation

If you find our work helpful, please cite us:

@article{ye2023ceil,
      title={Compositional Exemplars for In-context Learning}, 
      author={Jiacheng Ye, Zhiyong Wu, Jiangtao Feng, Tao Yu, Lingpeng Kong},
      year={2023},
      eprint={2302.05698},
      archivePrefix={arXiv},
      primaryClass={cs.CL}
}