Binary analysis techniques from academic research have been introduced into the reverse engineering community as well as research labs that are equipped with lots of computing power. Some program analyses using these techniques have even begun to show up in hacker conferences. But significant limitations remain:
In this talk, we will present our solution to these limitations. We will explain the Cross-platform Binary Automated Symbolic-execution System (CBASS) that we developed and demonstrate one of its interactive applications: an IDA based Taint-enabled Reverse Engineering Environment (TREE). TREE can deliver program analysis techniques (taint analysis, dynamic slicing, symbolic execution and constraint solving) into the reverse engineer’s hands now. Binary analysis and its security applications have been extensively researched, mainly in the context of a single instruction set architecture (predominantly x86) and popular desktop operating systems (Linux or Windows). CBASS performs its binary analysis on a common Intermediate Representation (IR) rather than on the native Instruction Set Architecture (ISA) of any program. This thin layer allows our powerful analysis tools to work on cross-platform binary applications.
While CBASS supports both automated and interactive security applications, TREE supports a subset of these capabilities but from with an IDA Pro plug-in. TREE provides useful interactive visualizations of the results of on-demand binary analysis. Symbolic execution and concolic execution (concrete-symbolic execution) are fundamental techniques used in binary analysis; but they are plagued by the exponential path explosion problem. Solving this problem requires vigorous path pruning algorithms and highly parallel computing infrastructure (like clouds). Neither of these is typically available to a reverse engineer. TREE solves this problem by helping the reverse engineer prioritize path execution through an interactive and intuitive visual representation of the results of on-demand analysis of what inputs and instruction sequences led to the crash site or other suspicious path, leverage path constraints and SMT solver to negate tainted branch condition for a new, unexplored path. The details of the taint analysis, dynamic slicing and path constraint solving mechanisms are transparent to reverse engineer.
Utilizing the existing IDA Pro debugging infrastructure, TREE can automate trace generation from diversified target platforms, including kernel mode tracing for Windows. To our surprise, despite the fact that IDA Pro debugging API has been around for a long time, there has been no serious effort to automate trace collection for extensible binary analysis, particularly for kernel mode tracing. Our work has directly contributed to two bug fixes in the latest IDA Pro patches (IDA 6.4.130206). Our presentation will feature several case studies of using TREE to analyze real world vulnerabilities.