42,093 research outputs found
PADS: Practical Attestation for Highly Dynamic Swarm Topologies
Remote attestation protocols are widely used to detect device configuration
(e.g., software and/or data) compromise in Internet of Things (IoT) scenarios.
Unfortunately, the performances of such protocols are unsatisfactory when
dealing with thousands of smart devices. Recently, researchers are focusing on
addressing this limitation. The approach is to run attestation in a collective
way, with the goal of reducing computation and communication. Despite these
advances, current solutions for attestation are still unsatisfactory because of
their complex management and strict assumptions concerning the topology (e.g.,
being time invariant or maintaining a fixed topology). In this paper, we
propose PADS, a secure, efficient, and practical protocol for attesting
potentially large networks of smart devices with unstructured or dynamic
topologies. PADS builds upon the recent concept of non-interactive attestation,
by reducing the collective attestation problem into a minimum consensus one. We
compare PADS with a state-of-the art collective attestation protocol and
validate it by using realistic simulations that show practicality and
efficiency. The results confirm the suitability of PADS for low-end devices,
and highly unstructured networks.Comment: Submitted to ESORICS 201
LO-FAT: Low-Overhead Control Flow ATtestation in Hardware
Attacks targeting software on embedded systems are becoming increasingly
prevalent. Remote attestation is a mechanism that allows establishing trust in
embedded devices. However, existing attestation schemes are either static and
cannot detect control-flow attacks, or require instrumentation of software
incurring high performance overheads. To overcome these limitations, we present
LO-FAT, the first practical hardware-based approach to control-flow
attestation. By leveraging existing processor hardware features and
commonly-used IP blocks, our approach enables efficient control-flow
attestation without requiring software instrumentation. We show that our
proof-of-concept implementation based on a RISC-V SoC incurs no processor
stalls and requires reasonable area overhead.Comment: Authors' pre-print version to appear in DAC 2017 proceeding
RADIS: Remote Attestation of Distributed IoT Services
Remote attestation is a security technique through which a remote trusted
party (i.e., Verifier) checks the trustworthiness of a potentially untrusted
device (i.e., Prover). In the Internet of Things (IoT) systems, the existing
remote attestation protocols propose various approaches to detect the modified
software and physical tampering attacks. However, in an interoperable IoT
system, in which IoT devices interact autonomously among themselves, an
additional problem arises: a compromised IoT service can influence the genuine
operation of other invoked service, without changing the software of the
latter. In this paper, we propose a protocol for Remote Attestation of
Distributed IoT Services (RADIS), which verifies the trustworthiness of
distributed IoT services. Instead of attesting the complete memory content of
the entire interoperable IoT devices, RADIS attests only the services involved
in performing a certain functionality. RADIS relies on a control-flow
attestation technique to detect IoT services that perform an unexpected
operation due to their interactions with a malicious remote service. Our
experiments show the effectiveness of our protocol in validating the integrity
status of a distributed IoT service.Comment: 21 pages, 10 figures, 2 table
C-FLAT: Control-FLow ATtestation for Embedded Systems Software
Remote attestation is a crucial security service particularly relevant to
increasingly popular IoT (and other embedded) devices. It allows a trusted
party (verifier) to learn the state of a remote, and potentially
malware-infected, device (prover). Most existing approaches are static in
nature and only check whether benign software is initially loaded on the
prover. However, they are vulnerable to run-time attacks that hijack the
application's control or data flow, e.g., via return-oriented programming or
data-oriented exploits. As a concrete step towards more comprehensive run-time
remote attestation, we present the design and implementation of Control- FLow
ATtestation (C-FLAT) that enables remote attestation of an application's
control-flow path, without requiring the source code. We describe a full
prototype implementation of C-FLAT on Raspberry Pi using its ARM TrustZone
hardware security extensions. We evaluate C-FLAT's performance using a
real-world embedded (cyber-physical) application, and demonstrate its efficacy
against control-flow hijacking attacks.Comment: Extended version of article to appear in CCS '16 Proceedings of the
23rd ACM Conference on Computer and Communications Securit
Remote attestation mechanism for embedded devices based on physical unclonable functions
Remote attestation mechanisms are well studied in the high-end computing environments; however, the same is not true for embedded devices-especially for smart cards. With ever changing landscape of smart card technology and advancements towards a true multi-application platform, verifying the current state of the smart card is significant to the overall security of such proposals. The initiatives proposed by GlobalPlatform Consumer Centric Model (GP-CCM) and User Centric Smart Card Ownership Model (UCOM) enables a user to download any application as she desire-depending upon the authorisation of the application provider. Before an application provider issues an application to a smart card, verifying the current state of the smart card is crucial to the security of the respective application. In this paper, we analyse the rationale behind the remote attestation mechanism for smart cards, and the fundamental features that such a mechanism should possess. We also study the applicability of Physical Unclonable Functions (PUFs) for the remote attestation mechanism and propose two algorithms to achieve the stated features of remote attestation. The proposed algorithms are implemented in a test environment to evaluate their performance. © 2013 The authors and IOS Press. All rights reserved
Integrity Attestation For Cloud
A system and a method for integrity verification in a cloud through an attestation service is disclosed. The system includes an application (app) or platform including an integrity attestation service in the cloud connected to data centers and servers of the service provider. The method includes collecting integrity measurements for an app or platform during run time by combining multiple integrity statements to derive a final attestation verdict about the overall trust level and attest an app or platform to be in the well-known security state. Another attestation service may be used to verify the attestation claim and decide a cloud policy suitable for their operation. The attestation service extends the basic attestation and sealing infrastructure per a single node to support system-level attestation and sealing on the cloud scale. This is accomplished without revealing the specifics of software stack and hardware configurations of the nodes in the data center
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