Efficient and provable local capability revocation using uninitialized capabilities-Reference-Cited by-同舟云学术

Efficient and provable local capability revocation using uninitialized capabilities

Published:2021-01-04 Issue:POPL Volume:5 Page:1-30
ISSN:2475-1421
Container-title:Proceedings of the ACM on Programming Languages
language:en
Short-container-title:Proc. ACM Program. Lang.

Author:

Georges Aïna Linn¹^ORCID,Guéneau Armaël¹,Van Strydonck Thomas²,Timany Amin¹^ORCID,Trieu Alix¹^ORCID,Huyghebaert Sander³,Devriese Dominique³^ORCID,Birkedal Lars¹^ORCID

Affiliation:

1. Aarhus University, Denmark

2. KU Leuven, Belgium

3. Vrije Universiteit Brussel, Belgium

Abstract

Capability machines are a special form of CPUs that offer fine-grained privilege separation using a form of authority-carrying values known as capabilities. The CHERI capability machine offers local capabilities, which could be used as a cheap but restricted form of capability revocation. Unfortunately, local capability revocation is unrealistic in practice because large amounts of stack memory need to be cleared as a security precaution. In this paper, we address this shortcoming by introducing uninitialized capabilities : a new form of capabilities that represent read/write authority to a block of memory without exposing the memory’s initial contents. We provide a mechanically verified program logic for reasoning about programs on a capability machine with the new feature and we formalize and prove capability safety in the form of a universal contract for untrusted code. We use uninitialized capabilities for making a previously-proposed secure calling convention efficient and prove its security using the program logic. Finally, we report on a proof-of-concept implementation of uninitialized capabilities on the CHERI capability machine.

Funder

Villum Fonden

Natur og Univers, Det Frie Forskningsråd

Fonds Wetenschappelijk Onderzoek

Publisher

Association for Computing Machinery (ACM)

Subject

Safety, Risk, Reliability and Quality,Software

Link

https://dl.acm.org/doi/pdf/10.1145/3434287

Reference42 articles.

1. State-dependent representation independence

2. Alasdair Armstrong Thomas Bauereiss Brian Campbell Shaked Flur Jon French Kathryn E. Gray Gabriel Kerneis Neel Krishnaswami Prashanth Mundkur Robert Norton-Wright Christopher Pulte Alastair Reid Peter Sewell Ian Stark and Mark Wassell. 2013-2019. The Sail Instruction-Set Architecture (ISA) specification language. Alasdair Armstrong Thomas Bauereiss Brian Campbell Shaked Flur Jon French Kathryn E. Gray Gabriel Kerneis Neel Krishnaswami Prashanth Mundkur Robert Norton-Wright Christopher Pulte Alastair Reid Peter Sewell Ian Stark and Mark Wassell. 2013-2019. The Sail Instruction-Set Architecture (ISA) specification language.

3. Lars Birkedal and Aleš Bizjak. 2017. Lecture Notes on Iris: Higher-Order Concurrent Separation Logic. http://irisproject.org/tutorial-pdfs /iris-lecture-notes.pdf. ( 2017 ). Lars Birkedal and Aleš Bizjak. 2017. Lecture Notes on Iris: Higher-Order Concurrent Separation Logic. http://irisproject.org/tutorial-pdfs /iris-lecture-notes.pdf. ( 2017 ).

4. Step-indexed kripke models over recursive worlds

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