Paper: ARES: An Automated Evaluation Framework for Retrieval-Augmented Generation Systems

To implement ARES for scoring your RAG system and comparing to other RAG configurations, you need three components: ​

• A human preference validation set of annotated query, document, and answer triples for the evaluation criteria (e.g. context relevance, answer faithfulness, and/or answer relevance). There should be at least 50 examples but several hundred examples is ideal.
• A set of few-shot examples for scoring context relevance, answer faithfulness, and/or answer relevance in your system
• A much larger set of unlabeled query-document-answer triples outputted by your RAG system for scoring

The ARES training pipeline is three steps: ​

1. Generate synthetic queries and answers from in-domain passages
2. Prepare LLM judges for scoring RAG system by fine-tuning on synthetically-generated training data
3. Deploy the prepared LLM judges to evaluate your RAG system across key performance metrics

Note: We also allow users to skip Steps #1 and #2 deploying a zero/few-shot LLM-as-a-Judge ​

​ To install the necessary dependencies, run the following commands: ​

conda create -n llm_judge python=3.10 --yes
conda activate llm_judge
pip install -r requirements.txt

​ Additionally, you will need to initialize an OpenAI API key with the following command:

export OPENAI_API_KEY=<your key here>

​

​ To generate synthetic training data, use LLM-as-a-Judge_Adaptation/Generate_Synthetic_Queries_and_Answers.py. Replace items in the following command with your dataset and configuration: ​

python LLM-as-a-Judge_Adaptation/Generate_Synthetic_Queries_and_Answers.py \
       --document_filepath <document_filepath> \
       --few_shot_prompt_filename <few_shot_prompt_filename> \
       --synthetic_queries_filename <synthetic_queries_filename> \
       --documents_sampled 10000

Example:

python LLM-as-a-Judge_Adaptation/Generate_Synthetic_Queries_and_Answers.py \
       --document_filepath example_files/document_filepath.tsv \
       --few_shot_prompt_filename example_files/few_shot_prompt_filename.tsv \
       --synthetic_queries_filename output/synthetic_queries_1.tsv \
       --documents_sampled 10000

This script will output a filepath to the generated synthetic queries for the next step. ​

Note: For examples files for document_filepath and few_shot_prompt_filename, please see example_files. ​

​ With the generated file under synthetic_queries_filename from the previous step, use LLM-as-a-Judge_Adaptation/General_Binary_Classifier.py to train your LLM-as-a-Judge with the following command: ​

python General_Binary_Classifier.py \
       --classification_dataset <synthetic queries file> \
       --test_set_selection <test_set_selection> \
       --label_column Context_Relevance_Label \
       --num_epochs 10 \
       --patience_value 3 \
       --learning_rate 5e-6

For document_filepath, put the filepath of the synthetic queries generated in the previous step. For test_set_selection, put the filepath of the human annotated examples of your dataset; it should be formatted like the file example_files/evaluation_datasets.tsv.

This script will output a model checkpoint path for the next step.

​ With the outputted model checkpoint from Step #2, you can now score your RAG system's configurations using ARES with following command in folder RAG_Automatic_Evaluation/: ​

python LLMJudge_RAG_Compared_Scoring.py \
       --alpha 0.05 \
       --num_trials 1000 \
       --evaluation_datasets <evaluation_datasets as list> \
       --checkpoints <checkpoints as list> \
       --labels <label columns as list> \
       --GPT_scoring <True or False> \
       --gold_label_path <gold_label_path>
       --swap_human_labels_for_gpt_labels False

​ For evaluation_datasets, we expect a list of filepaths to query-passage-answer TSVs for each RAG configuration you wish to score.

If you want to use few-shot GPT scoring, switch GPT_scoring to True. You can leave the checkpoints list as blank and specify the GPT model with the tag --gpt_model <model selected>. ​

Note: For examples files of evaluation_datasets and gold_label_path, please see example_files/evaluation_datasets.tsv for formatting.

We include synthetic datasets for key experimental results in synthetic_datasets. The few-shot prompts used for generation and evaluation are included in datasets. We also include instructions for fine-tuning LLM judges in the paper itself. Please reach out to [email protected] if you have any further questions.

To cite our work, please use the following Bibtex:

@misc{saadfalcon2023ares,
      title={ARES: An Automated Evaluation Framework for Retrieval-Augmented Generation Systems}, 
      author={Jon Saad-Falcon and Omar Khattab and Christopher Potts and Matei Zaharia},
      year={2023},
      eprint={2311.09476},
      archivePrefix={arXiv},
      primaryClass={cs.CL}
}

Machine requirements

• Over ~100 GB of available disk space
• GPU
  • Should work: A100 (e.g. Standard_NC24ads_A100_v4 on Azure)
  • Does not work:
    • Tested on 2023-12-17 with both Standard_NC6s_v3 and Standard_NC12s_v3, and ran into this error: torch.cuda.OutOfMemoryError: CUDA out of memory. Tried to allocate 160.00 MiB (GPU 0; 15.77 GiB total capacity; 15.12 GiB already allocated; 95.44 MiB free; 15.12 GiB reserved in total by PyTorch)

Machine setup

For example, on an Azure VM running Linux (ubuntu 20.04), you will need to do the following:

• Install conda
  • First set of commands (can copy-paste multiple lines)
    • wget https://repo.anaconda.com/miniconda/Miniconda3-latest-Linux-x86_64.sh
    • chmod +x Miniconda3-latest-Linux-x86_64.sh
    • ./Miniconda3-latest-Linux-x86_64.sh -b
  • Second set of commands (can copy-paste multiple lines)
    • export PATH="~/miniconda3/bin:$PATH"
    • conda init
• Install gcc
  • sudo apt-get -y update
  • sudo apt-get -y upgrade
  • sudo apt-get -y install build-essential
  • sudo apt-get -y install libpcre3-dev
• Install NVIDIA drivers
  • sudo apt install ubuntu-drivers-common -y
  • sudo ubuntu-drivers autoinstall
  • sudo reboot
  • SSH in again and confirm the installation was successful by running nvidia-smi
• cd to ARES folder and follow the rest of the README