SANCTUARY - ARMing TrustZone with User-space Enclaves.

ARM TrustZone is one of the most widely deployed security architecture providing Trusted Execution Environments (TEEs). Unfortunately, its usage and potential benefits for application developers and end users are largely limited due to restricted deployment policies imposed by device vendors. Restriction is enforced since every Trusted App (TA) increases the TEE's attack surface: any vulnerable or malicious TA can compromise the system's security. Hence, deploying a TA requires mutual trust between device vendor and application developer, incurring high costs for both. Vendors work around this by offering interfaces to selected TEE functionalities, however, these are not sufficient to securely implement advanced mobile services like banking. Extensive discussion of Intel's SGX technology in academia and industry has unveiled the demand for an unrestricted use of TEEs, yet no comparable security architecture for mobile devices exists to this day. We propose SANCTUARY, the first security architecture which allows unconstrained use of TEEs in the TrustZone ecosystem without relying on virtualization. SANCTUARY enables execution of security-sensitive apps within strongly isolated compartments in TrustZone's normal world comparable to SGX's user-space enclaves. In particular, we leverage TrustZone's versatile Address-Space Controller available in current ARM System-on-Chip reference designs, to enforce two-way hardware-level isolation: (i) security-sensitive apps are shielded against a compromised normal-world OS, while (ii) the system is also protected from potentially malicious apps in isolated compartments. Moreover, moving security-sensitive apps from the TrustZone's secure world to isolated compartments minimizes the TEE's attack surface. Thus, mutual trust relationships between device vendors and developers become obsolete: the full potential of TEEs can be leveraged. We demonstrate practicality and real-world benefits of SANCTUARY by thoroughly evaluating our prototype on a HiKey 960 development board with microbenchmarks and a use case for one-time password generation in two-factor authentication.