Bernard Schmidt, Carlos Villarraga, J. Bormann, D. Stoffel, Markus Wedler, W. Kunz
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A computational model for SAT-based verification of hardware-dependent low-level embedded system software
This paper describes a method to generate a computational model for formal verification of hardware-dependent software in embedded systems. The computational model of the combined HW/SW system is a program netlist (PN) consisting of instruction cells connected in a directed acyclic graph that compactly represents all execution paths of the software. The model can be easily integrated into SAT-based verification environments such as those based on Bounded Model Checking (BMC). The proposed construction of the model, however, allows for an efficient reasoning of the SAT solver over entire execution paths. We demonstrate the efficiency of our approach by presenting experimental results from the formal verification of an industrial LIN (Local Interconnect Network) bus node, implemented as a software driver on a 32-bit RISC machine.