Security Assessment of Dynamically Obfuscated Scan Chain Against Oracle-guided Attacks

Author:

Rahman M Sazadur1,Nahiyan Adib1,Rahman Fahim1,Fazzari Saverio2,Plaks Kenneth3,Farahmandi Farimah1,Forte Domenic1,Tehranipoor Mark1

Affiliation:

1. University of Florida, Gainesville, Florida, USA

2. Booz Allen Hamilton, Arlington, Virginia, USA

3. Defense Advanced Research Projects Agency, Arlington, Virginia, USA

Abstract

Logic locking has emerged as a promising solution to protect integrated circuits against piracy and tampering. However, the security provided by existing logic locking techniques is often thwarted by Boolean satisfiability (SAT)-based oracle-guided attacks. Criteria for successful SAT attacks on locked circuits include: (i) the circuit under attack is fully combinational, or (ii) the attacker has scan chain access. To address the threat posed by SAT-based attacks, we adopt the dynamically obfuscated scan chain (DOSC) architecture and illustrate its resiliency against the SAT attacks when inserted into the scan chain of an obfuscated design. We demonstrate, both mathematically and experimentally, that DOSC exponentially increases the resiliency against key extraction by SAT attack and its variants. Our results show that the mathematical estimation of attack complexity correlates to the experimental results with an accuracy of 95% or better. Along with the formal proof, we model DOSC architecture to its equivalent combinational circuit and perform SAT attack to evaluate its resiliency empirically. Our experiments demonstrate that SAT attack on DOSC-inserted benchmark circuits timeout at minimal test time overhead, and while DOSC requires less than 1% area and power overhead.

Funder

Defense Advanced Research Projects Agency

Publisher

Association for Computing Machinery (ACM)

Subject

Electrical and Electronic Engineering,Computer Graphics and Computer-Aided Design,Computer Science Applications

Reference64 articles.

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