Rust is an emerging programming language that aims to prevent memory-safety bugs. However, the current design of Rust also brings side effects which may increase the risk of memory-safety issues. In particular, it employs OBRM (ownership-based resource management) and enforces automatic deallocation of unused resources without the garbage collector. It may therefore falsely deallocate reclaimed memory and lead to use-after-free or double-free issues. In this paper, we study the problem of invalid memory deallocation and propose SafeDrop, a static path-sensitive data-flow analysis approach to detect such bugs. Our approach analyzes each API of a Rust crate iteratively by traversing the control-flow graph and extracting all aliases of each data-flow. To guarantee precision and scalability, we leverage a modified Tarjan algorithm to achieve scalable path-sensitive analysis, and a cache-based strategy to achieve efficient inter-procedural analysis. Our experiment results show that our approach can successfully detect all existing CVEs of such issues with a limited number of false positives. The analysis overhead ranges from 1.0% to 110.7% in comparison with the original compilation time. We further apply our tool to several real-world Rust crates and find 8 Rust crates involved with invalid memory deallocation issues.
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