Inspect: a runtime model checker for multithreaded C programs

technical reportWe present Inspect, a runtime model checker for revealing concurrency bugs in multithreaded C programs. Inspect instruments a given program at all global interaction points, and with the help of a new scheduler, examines all relevant thread interleavings under dynamic partial order reduction (DPOR). While the ideas behind Inspect are well known, there hasn't been a previously reported effort in which these ideas are applied to multithreaded C programs. We report on our engineering efforts to endow Inspect with (i) automatic source program instrumentation, (ii) practical DPOR implementation, and (iii) optimizations such as using locksets to compute more precise co-enabled relation. Our initial experience shows that such a tool can, indeed, be very effective for obtaining a handle on the notorious complexity of thread programmin

Partial Redundancy Elimination for Multi-threaded Programs

Multi-threaded programs have many applications which are widely used such as operating systems. Analyzing multi-threaded programs differs from sequential ones; the main feature is that many threads execute at the same time. The effect of all other running threads must be taken in account. Partial redundancy elimination is among the most powerful compiler optimizations: it performs loop-invariant code motion and common subexpression elimination. We present a type system with optimization component which performs partial redundancy elimination for multi-threaded programs.Comment: 7 page

Improving Quality of Software with Foreign Function Interfaces using Static Analysis

A Foreign Function Interface (FFI) is a mechanism that allows software written in one host programming language to directly use another foreign programming language by invoking function calls across language boundaries. Today\u27s software development often utilizes FFIs to reuse software components. Examples of such systems are the Java Development Kit (JDK), Android mobile OS, and Python packages in the Fedora LINUX operating systems. The use of FFIs, however, requires extreme care and can introduce undesired side effects that degrade software quality. In this thesis, we aim to improve several quality aspects of software composed of FFIs by applying static analysis. The thesis investigates several particular characteristics of FFIs and studies software bugs caused by the misuse of FFIs. We choose two FFIs, the Java Native Interface (JNI) and the Python/C interface, as the main subjects of this dissertation. To reduce software security vulnerabilities introduced by the JNI, we first propose definitions of new patterns of bugs caused by the improper exception handlings between Java and C. We then present the design and implement a bug finding system to uncover these bugs. To ensure software safety and reliability in multithreaded environment, we present a novel and efficient system that ensures atomicity in the JNI. Finally, to improve software performance and reliability, we design and develop a framework for finding errors in memory management in programs written with the Python/C interface. The framework is built by applying affine abstraction and affine analysis of reference-counts of Python objects. This dissertation offers a comprehensive study of FFIs and software composed of FFIs. The research findings make several contributions to the studies of static analysis and to the improvement of software quality

Eliminating read barriers through procrastination and cleanliness

Managed languages use read barriers to interpret forwarding pointers introduced to keep track of copied objects. For example, in a split-heap managed runtime for a multicore environment, an object initially allocated on a local heap may be copied to a shared heap if it becomes the source of a store operation whose target location resides on the shared heap. As part of the copy operation, a forwarding pointer may be established to allow existing references to the local object to reference the copied version. In this paper, we consider the design of a managed runtime that avoids the need for read barriers. Our design is premised on the availability of a sufficient degree of concurrency to stall operations that would otherwise necessitate the copy. Stalled actions are deferred until the next local collection, avoiding exposing forwarding pointers to the mutator. In certain important cases, procrastination is unnecessary- lightweight runtime techniques can sometimes be used to allow objects to be eagerly copied when their set of incoming references is known, or when it can be determined that having multiple copies would not violate program semantics. Experimental results over a range of parallel benchmarks on a number of different architectural platforms including an 864 core Azul Vega 3, and a 48 core Intel SCC, indicate that our approach leads to notable performance gains (20- 32 % on average) without incurring any additional complexity