Your search keyword '"Itzhaky, Shachar"' showing total 10 results

1. Kotlin's Type System is (Also) Unsound

Author

Kinsbruner, Elad, Peleg, Hila, and Itzhaky, Shachar

Subjects

Computer Science - Programming Languages, Computer Science - Software Engineering

Abstract

Soundness of a type system is a fundemental property that guarantees that no operation that is not supported by a value will be performed on that value at run time. A type checker for a sound type system is expected to issue a warning on every type error. While soundness is a desirable property for many practical applications, in 2016, Amin and Tate presented the first unsoundness proof for two major industry languages: Java and Scala. This proof relied on use-site variance and implicit null values. We present an unsoundness proof for Kotlin, another emerging industry language, which relies on a previously unknown unsound combination of language features. Kotlin does not have implicit null values, meaning that the proof by Amin and Tate would not work for Kotlin. Our new proof, which is an infringing code snippet, utilizes Kotlin's \emph{declaration-site} variance specification and does not require implicit null values. We present this counterexample to soundness in full along with detailed explanations of every step. Finally, we present a thorough discussion on precisely which language features cause this issue, as well as how Kotlin's compiler can be patched to fix it.

Published

2024

2. Colored E-Graph: Equality Reasoning with Conditions

Author

Singher, Eytan and Itzhaky, Shachar

Subjects

Computer Science - Programming Languages

Abstract

E-graphs are a prominent data structure that has been increasing in popularity in recent years due to their expanding range of applications in various formal reasoning tasks. Often, they are used for equality saturation, a process of deriving consequences through repeatedly applying universally quantified equality formulas via term rewriting. They handle equality reasoning over a large spaces of terms, but are severely limited in their handling of case splitting and other types of logical cuts, especially when compared to other reasoning techniques such as sequent calculi and resolution. The main difficulty is when equality reasoning requires multiple inconsistent assumptions to reach a single conclusion. Ad-hoc solutions, such as duplicating the e-graph for each assumption, are available, but they are notably resource-intensive. We introduce a key observation is that each duplicate e-graph (with an added assumption) corresponds to coarsened congruence relation. Based on that, we present an extension to e-graphs, called Colored E-Graphs, as a way to represent all of the coarsened congruence relations in a single structure. A colored e-graph is a memory-efficient equivalent of multiple copies of an e-graph, with a much lower overhead. This is attained by sharing as much as possible between different cases, while carefully tracking which conclusion is true under which assumption. Support for multiple relations can be thought of as adding multiple "color-coded" layers on top of the original e-graph structure, leading to a large degree of sharing. In our implementation, we introduce optimizations to rebuilding and e-matching. We run experiments and demonstrate that our colored e-graphs can support hundreds of assumptions and millions of terms with space requirements that are an order of magnitude lower, and with similar time requirements.

Published

2023

3. Hyperproperty Verification as CHC Satisfiability

Author

Itzhaky, Shachar, Shoham, Sharon, and Vizel, Yakir

Subjects

Computer Science - Logic in Computer Science

Abstract

Hyperproperties govern the behavior of a system or systems across multiple executions, and are being recognized as an important extension of regular temporal properties. So far, such properties have resisted comprehensive treatment by modern software model-checking approaches such as IC3/PDR, due to the need to find not only an inductive invariant but also a \emph{total} alignment of different executions that facilitates simpler inductive invariants. We show how this treatment is achieved via a reduction from the verification problem of $\forall^k\exists^l$ properties to Constrained Horn Clauses. The approach is based on combining the inference of an alignment and inductive invariant in a single CHC encoding; and, for existential quantification over traces, incorporating also inference of a witness function for the existential choices, based on a game semantics with a sound-and-complete encoding to CHCs as well.

Published

2023

4. SMT Sampling via Model-Guided Approximation

Author

Peled, Matan, Rothenberg, Bat-Chen, and Itzhaky, Shachar

Subjects

Computer Science - Logic in Computer Science

Abstract

We investigate the domain of satisfiable formulas in satisfiability modulo theories (SMT), in particular, automatic generation of a multitude of satisfying assignments to such formulas. Despite the long and successful history of SMT in model checking and formal verification, this aspect is relatively under-explored. Prior work exists for generating such assignments, or samples, for Boolean formulas and for quantifier-free first-order formulas involving bit-vectors, arrays, and uninterpreted functions (QF_AUFBV). We propose a new approach that is suitable for a theory T of integer arithmetic and to T with arrays and uninterpreted functions. The approach involves reducing the general sampling problem to a simpler instance of sampling from a set of independent intervals, which can be done efficiently. Such reduction is carried out by expanding a single model - a seed - using top-down propagation of constraints along the original first-order formula.

Published

2022

5. Securing Access to Untrusted Services From TEEs with GateKeeper

Author

Orenbach, Meni, Raveh, Bar, Berkenstadt, Alon, Michalevsky, Yan, Itzhaky, Shachar, and Silberstein, Mark

Subjects

Computer Science - Cryptography and Security

Abstract

Applications running in Trusted Execution Environments (TEEs) commonly use untrusted external services such as host File System. Adversaries may maliciously alter the normal service behavior to trigger subtle application bugs that would have never occurred under correct service operation, causing data leaks and integrity violations. Unfortunately, existing manual protections are incomplete and ad-hoc, whereas formally-verified ones require special expertise. We introduce GateKeeper, a framework to develop mitigations and vulnerability checkers for such attacks by leveraging lightweight formal models of untrusted services. With the attack seen as a violation of a services' functional correctness, GateKeeper takes a novel approach to develop a comprehensive model of a service without requiring formal methods expertise. We harness available testing suites routinely used in service development to tighten the model to known correct service implementation. GateKeeper uses the resulting model to automatically generate (1) a correct-by-construction runtime service validator in C that is linked with a trusted application and guards each service invocation to conform to the model; and (2) a targeted model-driven vulnerability checker for analyzing black-box applications. We evaluate GateKeeper on Intel SGX enclaves. We develop comprehensive models of a POSIX file system and OS synchronization primitives while using thousands of existing test suites to tighten their models to the actual Linux implementations. We generate the validator and integrate it with Graphene-SGX, and successfully protect unmodified Memcached and SQLite with negligible overheads. The generated vulnerability checker detects novel vulnerabilities in the Graphene-SGX protection layer and production applications.

Published

2022

6. AmiGo: Computational Design of Amigurumi Crochet Patterns

Author

Edelstein, Michal, Peleg, Hila, Itzhaky, Shachar, and Ben-Chen, Mirela

Subjects

Computer Science - Graphics

Abstract

We propose an approach for generating crochet instructions (patterns) from an input 3D model. We focus on Amigurumi, which are knitted stuffed toys. Given a closed triangle mesh, and a single point specified by the user, we generate crochet instructions, which when knitted and stuffed result in a toy similar to the input geometry. Our approach relies on constructing the geometry and connectivity of a Crochet Graph, which is then translated into a crochet pattern. We segment the shape automatically into chrochetable components, which are connected using the join-as-you-go method, requiring no additional sewing. We demonstrate that our method is applicable to a large variety of shapes and geometries, and yields easily crochetable patterns., Comment: 11 pages, 10 figures, SCF 2022

Published

2022

7. Putting the Squeeze on Array Programs: Loop Verification via Inductive Rank Reduction

Author

Shalom, Oren Ish, Itzhaky, Shachar, Rinetzky, Noam, and Shoham, Sharon

Subjects

Computer Science - Programming Languages, Computer Science - Computational Complexity

Abstract

Automatic verification of array manipulating programs is a challenging problem because it often amounts to the inference of in ductive quantified loop invariants which, in some cases, may not even be firstorder expressible. In this paper, we suggest a novel verification tech nique that is based on induction on userdefined rank of program states as an alternative to loopinvariants. Our technique, dubbed inductive rank reduction, works in two steps. Firstly, we simplify the verification problem and prove that the program is correct when the input state con tains an input array of length B or less, using the length of the array as the rank of the state. Secondly, we employ a squeezing function g which converts a program state sigma with an array of length > B to a state g(sigma) containing an array of length minus 1 or less. We prove that when g satisfies certain natural conditions then if the program violates its specification on sigma then it does so also on g(sigma). The correctness of the program on inputs with arrays of arbitrary lengths follows by induction. We make our technique automatic for array programs whose length of execution is proportional to the length of the input arrays by (i) perform ing the first step using symbolic execution, (ii) verifying the conditions required of g using Z3, and (iii) providing a heuristic procedure for syn thesizing g. We implemented our technique and applied it successfully to several interesting arraymanipulating programs, including a bidirec tional summation program whose loop invariant cannot be expressed in firstorder logic while its specification is quantifier free.

Published

2021

8. Theory Exploration Powered By Deductive Synthesis

Author

Singher, Eytan and Itzhaky, Shachar

Subjects

Computer Science - Programming Languages, I.2.3, D.2.4, F.3.1

Abstract

Recent years have seen tremendous growth in the amount of verified software. Proofs for complex properties can now be achieved using higher-order theories and calculi. Complex properties lead to an ever-growing number of definitions and associated lemmas, which constitute an integral part of proof construction. Following this -- whether automatic or semi-automatic -- methods for computer-aided lemma discovery have emerged. In this work, we introduce a new symbolic technique for bottom-up lemma discovery, that is, the generation of a library of lemmas from a base set of inductive data types and recursive definitions. This is known as the theory exploration problem, and so far, solutions have been proposed based either on counter-example generation or the more prevalent random testing combined with first-order solvers. Our new approach, being purely deductive, eliminates the need for random testing as a filtering phase and for SMT solvers. Therefore it is amenable compositional reasoning and for the treatment of user-defined higher-order functions. Our implementation has shown to find more lemmas than prior art, while avoiding redundancy.

Published

2020

9. On the automated verification of web applications with embedded SQL

Author

Itzhaky, Shachar, Kotek, Tomer, Rinetzky, Noam, Sagiv, Mooly, Tamir, Orr, Veith, Helmut, and Zuleger, Florian

Subjects

Computer Science - Logic in Computer Science, 68P15, 68Q60, D.3.2, F.3.1

Abstract

A large number of web applications is based on a relational database together with a program, typically a script, that enables the user to interact with the database through embedded SQL queries and commands. In this paper, we introduce a method for formal automated verification of such systems which connects database theory to mainstream program analysis. We identify a fragment of SQL which captures the behavior of the queries in our case studies, is algorithmically decidable, and facilitates the construction of weakest preconditions. Thus, we can integrate the analysis of SQL queries into a program analysis tool chain. To this end, we implement a new decision procedure for the SQL fragment that we introduce. We demonstrate practical applicability of our results with three case studies, a web administrator, a simple firewall, and a conference management system., Comment: 25 pages

Published

2016

10. Liquid Information Flow Control

Author

Polikarpova, Nadia, Stefan, Deian, Yang, Jean, Itzhaky, Shachar, Hance, Travis, and Solar-Lezama, Armando

Subjects

Computer Science - Programming Languages

Abstract

We present Lifty, a domain-specific language for data-centric applications that manipulate sensitive data. A Lifty programmer annotates the sources of sensitive data with declarative security policies, and the language statically and automatically verifies that the application handles the data according to the policies. Moreover, if verification fails, Lifty suggests a provably correct repair, thereby easing the programmer burden of implementing policy enforcing code throughout the application. The main insight behind Lifty is to encode information flow control using liquid types, an expressive yet decidable type system. Liquid types enable fully automatic checking of complex, data dependent policies, and power our repair mechanism via type-driven error localization and patch synthesis. Our experience using Lifty to implement three case studies from the literature shows that (1) the Lifty policy language is sufficiently expressive to specify many real-world policies, (2) the Lifty type checker is able to verify secure programs and find leaks in insecure programs quickly, and (3) even if the programmer leaves out all policy enforcing code, the Lifty repair engine is able to patch all leaks automatically within a reasonable time.

Published

2016