A Syntactic Approach to Foundational Proof-Carrying Code

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	Similar Articles Articles by Nadeem A. Hamid Articles by Zhong Shao Articles by Valery Trifonov Articles by Stefan Monnier Articles by Zhaozhong Ni

17th Annual IEEE Symposium on Logic in Computer Science (LICS'02)

Copenhagen, Denmark

July 22-July 25

ISBN: 0-7695-1483-9

	ASCII Text	x
	Nadeem A. Hamid, Zhong Shao, Valery Trifonov, Stefan Monnier, Zhaozhong Ni, "A Syntactic Approach to Foundational Proof-Carrying Code," Logic in Computer Science, Symposium on, pp. 89, 17th Annual IEEE Symposium on Logic in Computer Science (LICS'02), 2002.

	BibTex	x
	@article{ 10.1109/LICS.2002.1029819, author = {Nadeem A. Hamid and Zhong Shao and Valery Trifonov and Stefan Monnier and Zhaozhong Ni}, title = {A Syntactic Approach to Foundational Proof-Carrying Code}, journal ={Logic in Computer Science, Symposium on}, volume = {0}, year = {2002}, issn = {1043-6871}, pages = {89}, doi = {http://doi.ieeecomputersociety.org/10.1109/LICS.2002.1029819}, publisher = {IEEE Computer Society}, address = {Los Alamitos, CA, USA}, }

	RefWorks Procite/RefMan/Endnote	x
	TY - CONF JO - Logic in Computer Science, Symposium on TI - A Syntactic Approach to Foundational Proof-Carrying Code SN - 1043-6871 SP EP A1 - Nadeem A. Hamid, A1 - Zhong Shao, A1 - Valery Trifonov, A1 - Stefan Monnier, A1 - Zhaozhong Ni, PY - 2002 KW - null VL - 0 JA - Logic in Computer Science, Symposium on ER -

Nadeem A. Hamid, Yale University

Zhong Shao, Yale University

Valery Trifonov, Yale University

Stefan Monnier, Yale University

Zhaozhong Ni, Yale University

DOI Bookmark: http://doi.ieeecomputersociety.org/10.1109/LICS.2002.1029819

Proof-Carrying Code (PCC) is a general framework for verifying the safety properties of machine-language programs. PCC proofs are usually written in a logic extended with language-specific typing rules. In Foundational Proof-Carrying Code (FPCC), on the other hand, proofs are constructed and verified using strictly the foundations of mathematical logic, with no type-specific axioms. FPCC is more flexible and secure because it is not tied to any particular type system and it has a smaller trusted base.

Foundational proofs, however, are much harder to construct. Previous efforts on FPCC all required building so-phisticated semantic models for types. In this paper, we present a syntactic approach to FPCC that avoids the difficulties of previous work. Under our new scheme, the foundational proof for a typed machine program simply consists of the typing derivation plus the formalized syntactic soundness proof for the underlying type system. We give a translation from a typed assembly language into FPCC and demonstrate the advantages of our new system via an implementation in the Coq proof assistant.

Citation:

Nadeem A. Hamid, Zhong Shao, Valery Trifonov, Stefan Monnier, Zhaozhong Ni, "A Syntactic Approach to Foundational Proof-Carrying Code," lics, pp.89, 17th Annual IEEE Symposium on Logic in Computer Science (LICS'02), 2002

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