Visible to the public Biblio

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Fu, Y., Tong, S., Guo, X., Cheng, L., Zhang, Y., Feng, D..  2020.  Improving the Effectiveness of Grey-box Fuzzing By Extracting Program Information. 2020 IEEE 19th International Conference on Trust, Security and Privacy in Computing and Communications (TrustCom). :434–441.
Fuzzing has been widely adopted as an effective techniques to detect vulnerabilities in softwares. However, existing fuzzers suffer from the problems of generating excessive test inputs that either cannot pass input validation or are ineffective in exploring unvisited regions in the program under test (PUT). To tackle these problems, we propose a greybox fuzzer called MuFuzzer based on AFL, which incorporates two heuristics that optimize seed selection and automatically extract input formatting information from the PUT to increase the chance of generating valid test inputs, respectively. In particular, the first heuristic collects the branch coverage and execution information during a fuzz session, and utilizes such information to guide fuzzing tools in selecting seeds that are fast to execute, small in size, and more importantly, more likely to explore new behaviors of the PUT for subsequent fuzzing activities. The second heuristic automatically identifies string comparison operations that the PUT uses for input validation, and establishes a dictionary with string constants from these operations to help fuzzers generate test inputs that have higher chances to pass input validation. We have evaluated the performance of MuFuzzer, in terms of code coverage and bug detection, using a set of realistic programs and the LAVA-M test bench. Experiment results demonstrate that MuFuzzer is able to achieve higher code coverage and better or comparative bug detection performance than state-of-the-art fuzzers.
Vastel, A., Rudametkin, W., Rouvoy, R..  2018.  FP -TESTER : Automated Testing of Browser Fingerprint Resilience. 2018 IEEE European Symposium on Security and Privacy Workshops (EuroS PW). :103-107.
Despite recent regulations and growing user awareness, undesired browser tracking is increasing. In addition to cookies, browser fingerprinting is a stateless technique that exploits a device's configuration for tracking purposes. In particular, browser fingerprinting builds on attributes made available from Javascript and HTTP headers to create a unique and stable fingerprint. For example, browser plugins have been heavily exploited by state-of-the-art browser fingerprinters as a rich source of entropy. However, as browser vendors abandon plugins in favor of extensions, fingerprinters will adapt. We present FP-TESTER, an approach to automatically test the effectiveness of browser fingerprinting countermeasure extensions. We implement a testing toolkit to be used by developers to reduce browser fingerprintability. While countermeasures aim to hinder tracking by changing or blocking attributes, they may easily introduce subtle side-effects that make browsers more identifiable, rendering the extensions counterproductive. FP-TESTER reports on the side-effects introduced by the countermeasure, as well as how they impact tracking duration from a fingerprinter's point-of-view. To the best of our knowledge, FP-TESTER is the first tool to assist developers in fighting browser fingerprinting and reducing the exposure of end-users to such privacy leaks.
Fehlmann, Thomas, Kranich, Eberhard.  2017.  Autonomous Real-time Software & Systems Testing. Proceedings of the 27th International Workshop on Software Measurement and 12th International Conference on Software Process and Product Measurement. :54–63.

For the Internet of Things (IoT), for safety in automotive, or for data protection, to be legally compliant requires testing the impact of any actions before allowing them to occur. However, system boundaries change at runtime. When adding a new, previously unknown device to an IoT orchestra, or when an autonomous car meets another, or with truck platooning, the original base system expands and needs being tested before it can do decisions with the potential of affecting harm to humans. This paper explains the theory and outlines the implementation approach a framework for autonomous real-time testing of a software-based system while in operation, with an example from IoT.

Appelt, D., Panichella, A., Briand, L..  2017.  Automatically Repairing Web Application Firewalls Based on Successful SQL Injection Attacks. 2017 IEEE 28th International Symposium on Software Reliability Engineering (ISSRE). :339–350.

Testing and fixing Web Application Firewalls (WAFs) are two relevant and complementary challenges for security analysts. Automated testing helps to cost-effectively detect vulnerabilities in a WAF by generating effective test cases, i.e., attacks. Once vulnerabilities have been identified, the WAF needs to be fixed by augmenting its rule set to filter attacks without blocking legitimate requests. However, existing research suggests that rule sets are very difficult to understand and too complex to be manually fixed. In this paper, we formalise the problem of fixing vulnerable WAFs as a combinatorial optimisation problem. To solve it, we propose an automated approach that combines machine learning with multi-objective genetic algorithms. Given a set of legitimate requests and bypassing SQL injection attacks, our approach automatically infers regular expressions that, when added to the WAF's rule set, prevent many attacks while letting legitimate requests go through. Our empirical evaluation based on both open-source and proprietary WAFs shows that the generated filter rules are effective at blocking previously identified and successful SQL injection attacks (recall between 54.6% and 98.3%), while triggering in most cases no or few false positives (false positive rate between 0% and 2%).

Yaneva, Vanya, Rajan, Ajitha, Dubach, Christophe.  2017.  Compiler-Assisted Test Acceleration on GPUs for Embedded Software. Proceedings of the 26th ACM SIGSOFT International Symposium on Software Testing and Analysis. :35–45.

Embedded software is found everywhere from our highly visible mobile devices to the confines of our car in the form of smart sensors. Embedded software companies are under huge pressure to produce safe applications that limit risks, and testing is absolutely critical to alleviate concerns regarding safety and user privacy. This requires using large test suites throughout the development process, increasing time-to-market and ultimately hindering competitivity. Speeding up test execution is, therefore, of paramount importance for embedded software developers. This is traditionally achieved by running, in parallel, multiple tests on large-scale clusters of computers. However, this approach is costly in terms of infrastructure maintenance and energy consumed, and is at times inconvenient as developers have to wait for their tests to be scheduled on a shared resource. We propose to look at exploiting GPUs (Graphics Processing Units) for running embedded software testing. GPUs are readily available in most computers and offer tremendous amounts of parallelism, making them an ideal target for embedded software testing. In this paper, we demonstrate, for the first time, how test executions of embedded C programs can be automatically performed on a GPU, without involving the end user. We take a compiler-assisted approach which automatically compiles the C program into GPU kernels for parallel execution of the input tests. Using this technique, we achieve an average speedup of 16× when compared to CPU execution of input tests across nine programs from an industry standard embedded benchmark suite.