Measuring The Impact Of Programming Language Distribution
This addresses the limited language coverage in code model benchmarks, benefiting researchers and practitioners in AI and software engineering, though it is incremental as it builds on existing evaluation methods.
The paper tackles the problem of evaluating neural code models across diverse programming languages by introducing the BabelCode framework and a translation dataset, finding that training on a balanced language corpus improves average pass@k by 12.34% overall and 66.48% for low-resource languages, with a 12.94% cost to high-resource languages.
Current benchmarks for evaluating neural code models focus on only a small subset of programming languages, excluding many popular languages such as Go or Rust. To ameliorate this issue, we present the BabelCode framework for execution-based evaluation of any benchmark in any language. BabelCode enables new investigations into the qualitative performance of models' memory, runtime, and individual test case results. Additionally, we present a new code translation dataset called Translating Python Programming Puzzles (TP3) from the Python Programming Puzzles (Schuster et al. 2021) benchmark that involves translating expert-level python functions to any language. With both BabelCode and the TP3 benchmark, we investigate if balancing the distributions of 14 languages in a training dataset improves a large language model's performance on low-resource languages. Training a model on a balanced corpus results in, on average, 12.34% higher $pass@k$ across all tasks and languages compared to the baseline. We find that this strategy achieves 66.48% better $pass@k$ on low-resource languages at the cost of only a 12.94% decrease to high-resource languages. In our three translation tasks, this strategy yields, on average, 30.77% better low-resource $pass@k$ while having 19.58% worse high-resource $pass@k$.