Migrating SGX Enclaves with Persistent State

Fritz Alder; Arseny Kurnikov; Andrew Paverd; N. Asokan

doi:10.1109/DSN.2018.00031

Migrating SGX Enclaves with Persistent State

Fritz Alder, Arseny Kurnikov, Andrew Paverd, N. Asokan

Research output: Chapter in Book/Report/Conference proceeding › Conference article in proceedings › Scientific › peer-review

Abstract

Hardware-supported security mechanisms like Intel Software Guard Extensions (SGX) provide strong security guarantees, which are particularly relevant in cloud settings. However, their reliance on physical hardware conflicts with cloud practices, like migration of VMs between physical platforms. For instance, the SGX trusted execution environment (enclave) is bound to a single physical CPU. Although prior work has proposed an effective mechanism to migrate an enclave's data memory, it overlooks the migration of persistent state, including sealed data and monotonic counters; the former risks data loss whilst the latter undermines the SGX security guarantees. We show how this can be exploited to mount attacks, and then propose an improved enclave migration approach guaranteeing the consistency of persistent state. Our software-only approach enables migratable sealed data and monotonic counters, maintains all SGX security guarantees, minimizes developer effort, and incurs negligible performance overhead.

Original language	English
Title of host publication	48th Annual IEEE/IFIP International Conference on Dependable Systems and Networks (DSN)
Publisher	IEEE
Pages	195-206
ISBN (Electronic)	978-1-5386-5595-5
DOIs	https://doi.org/10.1109/DSN.2018.00031
Publication status	Published - 23 Jul 2018
MoE publication type	A4 Conference publication
Event	Annual IEEE/IFIP International Conference on Dependable Systems and Networks - Luxembourg, Luxembourg Duration: 25 Jun 2018 → 28 Jun 2018 Conference number: 48

Conference

Conference	Annual IEEE/IFIP International Conference on Dependable Systems and Networks
Abbreviated title	DSN
Country/Territory	Luxembourg
City	Luxembourg
Period	25/06/2018 → 28/06/2018

Access to Document

10.1109/DSN.2018.00031

https://arxiv.org/pdf/1803.11021.pdf

CloSer: Cloud-assisted Security Services
Asokan, N. (Principal investigator)
01/09/2016 → 31/08/2018
Project: Business Finland: Other research funding

Cite this

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title = "Migrating SGX Enclaves with Persistent State",

abstract = "Hardware-supported security mechanisms like Intel Software Guard Extensions (SGX) provide strong security guarantees, which are particularly relevant in cloud settings. However, their reliance on physical hardware conflicts with cloud practices, like migration of VMs between physical platforms. For instance, the SGX trusted execution environment (enclave) is bound to a single physical CPU. Although prior work has proposed an effective mechanism to migrate an enclave's data memory, it overlooks the migration of persistent state, including sealed data and monotonic counters; the former risks data loss whilst the latter undermines the SGX security guarantees. We show how this can be exploited to mount attacks, and then propose an improved enclave migration approach guaranteeing the consistency of persistent state. Our software-only approach enables migratable sealed data and monotonic counters, maintains all SGX security guarantees, minimizes developer effort, and incurs negligible performance overhead.",

author = "Fritz Alder and Arseny Kurnikov and Andrew Paverd and N. Asokan",

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booktitle = "48th Annual IEEE/IFIP International Conference on Dependable Systems and Networks (DSN)",

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AU - Kurnikov, Arseny

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AU - Asokan, N.

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PY - 2018/7/23

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N2 - Hardware-supported security mechanisms like Intel Software Guard Extensions (SGX) provide strong security guarantees, which are particularly relevant in cloud settings. However, their reliance on physical hardware conflicts with cloud practices, like migration of VMs between physical platforms. For instance, the SGX trusted execution environment (enclave) is bound to a single physical CPU. Although prior work has proposed an effective mechanism to migrate an enclave's data memory, it overlooks the migration of persistent state, including sealed data and monotonic counters; the former risks data loss whilst the latter undermines the SGX security guarantees. We show how this can be exploited to mount attacks, and then propose an improved enclave migration approach guaranteeing the consistency of persistent state. Our software-only approach enables migratable sealed data and monotonic counters, maintains all SGX security guarantees, minimizes developer effort, and incurs negligible performance overhead.

AB - Hardware-supported security mechanisms like Intel Software Guard Extensions (SGX) provide strong security guarantees, which are particularly relevant in cloud settings. However, their reliance on physical hardware conflicts with cloud practices, like migration of VMs between physical platforms. For instance, the SGX trusted execution environment (enclave) is bound to a single physical CPU. Although prior work has proposed an effective mechanism to migrate an enclave's data memory, it overlooks the migration of persistent state, including sealed data and monotonic counters; the former risks data loss whilst the latter undermines the SGX security guarantees. We show how this can be exploited to mount attacks, and then propose an improved enclave migration approach guaranteeing the consistency of persistent state. Our software-only approach enables migratable sealed data and monotonic counters, maintains all SGX security guarantees, minimizes developer effort, and incurs negligible performance overhead.

U2 - 10.1109/DSN.2018.00031

DO - 10.1109/DSN.2018.00031

M3 - Conference article in proceedings

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EP - 206

BT - 48th Annual IEEE/IFIP International Conference on Dependable Systems and Networks (DSN)

PB - IEEE

T2 - Annual IEEE/IFIP International Conference on Dependable Systems and Networks

Y2 - 25 June 2018 through 28 June 2018

ER -

Migrating SGX Enclaves with Persistent State

Abstract

Conference

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Projects

CloSer: Cloud-assisted Security Services

Cite this