Session
FOSDEM 2021 Schedule
Hardware-Aided Trusted Computing

Hardwared Based CPU Undervolting on The Cheap

Stealing Your Secrets for $30
D.hardware.trusted
ZITAI CHEN
Previous work such as Plundervolt has shown that software-based undervolting can induce faults into Intel SGX enclaves and break their security guarantees. However, Intel has addressed this issue with microcode updates. We later discovered that there is a physical connection on the motherboard which allows us to control the voltage and conduct fault injection. In this talk, we will present a low-cost device: Voltpillager, which use this physical connection to break the guarantees provided by SGX again.
On a standard motherboard, there is a separate Voltage Regulator (VR) chip that generates and controls the CPU voltage. Our tool, VoltPillager, uses this to connect to the (unprotected) interface of the VR and control that voltage. Based on this, we then mount fault-injection attacks that breach confidentiality and integrity of Intel SGX enclaves, and present proof-of-concept key-recovery attacks against cryptographic algorithms running inside SGX. Our results may require a rethink of the widely assumed SGX adversarial model, where a cloud provider hosting SGX machines is assumed to be untrusted but has physical access to the hardware.

Additional information

Type devroom

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