Verification of Certifying Computations

Alkassar, Eyad; Böhme, Sascha; Mehlhorn, Kurt; Rizkallah, Christine

doi:10.1007/978-3-642-22110-1_7

Cited by 12 publications

(11 citation statements)

References 18 publications

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“…When a successful formal verification of complex and large software systems at code level is desired, we believe a combination of both interactive and auto-active specification and verification approaches is promising -similar to verification of certifying algorithms using VCC, together with Isabelle/HOL as shown in [1]. Using this combination, auto-active tools would allow for efficient verification of sourcecode level properties closer to the hardware, the resulting functional properties of the code abstracting from implementation details -whereas interactive verification systems may be used to verify complex system properties on a suitable, user-defined abstraction of the system.…”

Section: Resultsmentioning

confidence: 99%

Lessons Learned From Microkernel Verification — Specification is the New Bottleneck

Baumann

Beckert

Blasum³

et al. 2012

Electron. Proc. Theor. Comput. Sci.

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Software verification tools have become a lot more powerful in recent years. Even verification of large, complex systems is feasible, as demonstrated in the L4.verified and Verisoft XT projects. Still, functional verification of large software systems is rare – for reasons beyond the large scale of verification effort needed due to the size alone. In this paper we report on lessons learned for verification of large software systems based on the experience gained in microkernel verification in the Verisoft XT project. We discuss a number of issues that impede widespread introduction of formal verification in the software life-cycle process

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Section: Resultsmentioning

confidence: 99%

Lessons Learned From Microkernel Verification — Specification is the New Bottleneck

Baumann

Beckert

Blasum³

et al. 2012

Electron. Proc. Theor. Comput. Sci.

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“…ϕ(x) ∧ W(x, y, w) −→ ψ(x, y). (1) In contrast to algorithms that work on abstract sets X, Y , and W , the implementing programs operate on concrete representations of abstract objects. We use X, Y , and W for the set of representations of objects in X, Y , and W , respectively, and assume the mappings i X : X → X, i Y : Y → Y , and i W : W → W .…”

Section: Outline Of Methodologymentioning

confidence: 99%

“…It took several months to develop the framework and complete the first example as described in [1]. For this paper, we have reworked the framework, thereby strengthening and simplifying it at the same time.…”

Section: Vccmentioning

confidence: 99%

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A Framework for the Verification of Certifying Computations

et al. 2013

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Formal verification of complex algorithms is challenging. Verifying their implementations goes beyond the state of the art of current automatic verification tools and usually involves intricate mathematical theorems. Certifying algorithms compute in addition to each output a witness certifying that the output is correct.A checker for such a witness is usually much simpler than the original algorithmyet it is all the user has to trust. The verification of checkers is feasible with current tools and leads to computations that can be completely trusted. We describe a framework to seamlessly verify certifying computations. We use the automatic verifier VCC for establishing the correctness of the checker and the interactive theorem prover Isabelle/HOL for high-level mathematical properties of algorithms. We demonstrate the effectiveness of our approach by presenting the verification of typical examples of the industrial-level and widespread algorithmic library LEDA.

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“…Literature offers numerous certifying algorithms [19], [20], [27], [4], [6], [15], [13], [12], [18], [23], [11], [22], [3], [10], [2], [1], [24], [9]. A theory of certifying algorithms and further reading is given in [19].…”

Section: Related Workmentioning

confidence: 99%

On a Verification Framework for Certifying Distributed Algorithms: Distributed Checking and Consistency

Völlinger

Akili

2018

Formal Techniques for Distributed Objects, Components, and Systems

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A major problem in software engineering is assuring the correctness of a distributed system. A certifying distributed algorithm (CDA) computes for its input-output pair (i, o) an additional witness w -a formal argument for the correctness of (i, o). Each CDA features a witness predicate such that if the witness predicate holds for a triple (i, o, w), the input-output pair (i, o) is correct. An accompanying checker algorithm decides the witness predicate. Consequently, a user of a CDA does not have to trust the CDA but its checker algorithm. Usually, a checker is simpler and its verification is feasible. To sum up, the idea of a CDA is to adapt the underlying algorithm of a program at design-time such that it verifies its own output at runtime. While certifying sequential algorithms are well-established, there are open questions on how to apply certification to distributed algorithms. In this paper, we discuss distributed checking of a distributed witness; one challenge is that all parts of a distributed witness have to be consistent with each other. Furthermore, we present a method for formal instance verification (i.e. obtaining a machine-checked proof that a particular input-output pair is correct), and implement the method in a framework for the theorem prover Coq.

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Verification of Certifying Computations

Cited by 12 publications

References 18 publications

Lessons Learned From Microkernel Verification — Specification is the New Bottleneck

Lessons Learned From Microkernel Verification — Specification is the New Bottleneck

A Framework for the Verification of Certifying Computations

On a Verification Framework for Certifying Distributed Algorithms: Distributed Checking and Consistency

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