Teaching Computer Science (CS) students how to comprehend and maintain legacy code bases is a critical challenge in software engineering education. While Generative AI (GenAI) assistants like GitHub Copilot improve task completion speed and correctness, their impact on code understanding remains unclear. We conducted a within-subject study with 15 graduate CS students completing feature implementation tasks with and without Copilot. Despite significant performance improvements, participants showed no overall comprehension improvement (p=0.59), revealing a \textit{comprehension-performance decoupling}. Further analysis uncovered a \textit{comprehension trade-off}: performance gains negatively correlated with reverse engineering comprehension (ρ=−0.57, p=0.026) but showed a positive trend with implementation comprehension (ρ=0.50, p=0.06). A follow-up behavioral analysis revealed that \textit{how} students used Copilot determined outcomes: Engaging in verification loops in which programmers actively reviewed generated code strongly predicted comprehension (p<0.001, r=0.96), with high-comprehension participants verifying code 4.7 times more frequently than low-comprehension participants. These findings suggest that GenAI tools do not inherently undermine comprehension; rather, passive consumption patterns do. This suggests a need to alter programming education to teach system-level verification skills, and the need to redesign educational GenAI tools to scaffold active cognitive engagement.
@article{arxiv.2511.02922,
title = {Code Comprehension with GitHub Copilot: Performance Gains, Comprehension Trade-offs, and Behavioral Predictors in Brownfield Programming},
author = {Yunhan Qiao and Md Istiak Hossain Shihab and Summit Haque and and Christopher Hundhausen},
journal= {arXiv preprint arXiv:2511.02922},
year = {2026}
}