Jun Furuse scite author profile

Jun Furuse

5Publications

13Citation Statements Received

51Citation Statements Given

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Kyoto University

Publications

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Structuring of Sekisui Heim Automated Parts Pickup System (HAPPS) to Process Indivisual Floor Plans

Furuse¹,

Katano²

2006

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Sekisui Heim residential houses (herein "Heim") are made of factory-produced modules called "Units" which can be combined to complete any house plan. All "Units" to compose a house are unique and have different parts in different combinations. It is an important process to select and pick up about 30,000 parts correctly for each house, out of about 300,000 listed parts and feed them to the production line in time of work. In this paper, the writer will introduce to you how to pick up the parts constituting Heim units, and certain technical points of the "HAPPS" (Heim Automated Part Pickup System) which has materialized such method. In the end, the writer will touch on the efficiency and accuracy of such part pickup method.

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Helmholtz: A Verifier for Tezos Smart Contracts Based on Refinement Types

et al. 2022

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A smart contract is a program executed on a blockchain, based on which many cryptocurrencies are implemented, and is being used for automating transactions. Due to the large amount of money that smart contracts deal with, there is a surging demand for a method that can statically and formally verify them. This article describes our type-based static verification tool Helmholtz for Michelson, which is a statically typed stack-based language for writing smart contracts that are executed on the blockchain platform Tezos. Helmholtz is designed on top of our extension of Michelson’s type system with refinement types. Helmholtz takes a Michelson program annotated with a user-defined specification written in the form of a refinement type as input; it then typechecks the program against the specification based on the refinement type system, discharging the generated verification conditions with the SMT solver Z3. We briefly introduce our refinement type system for the core calculus Mini-Michelson of Michelson, which incorporates the characteristic features such as compound datatypes (e.g., lists and pairs), higher-order functions, and invocation of another contract. Helmholtz successfully verifies several practical Michelson programs, including one that transfers money to an account and that checks a digital signature.

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Verification of a Merkle Patricia Tree Library Using F*

Sato¹,

Banno²,

Furuse³

et al. 2021

Preprint

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A Merkle tree is a data structure for representing a key-value store as a tree. Each node of a Merkle tree is equipped with a hash value computed from those of their descendants. A Merkle tree is often used for representing a state of a blockchain system such as Ethereum and Tezos since it can be used for efficiently auditing the state in a trustless manner. Due to the safety-critical nature of blockchains, ensuring the correctness of their implementation is paramount.We show our formally verified implementation of the core part of Plebeia using F ★ , a programming language to implement a formally verified functional program. Plebeia, which is implemented in OCaml, is a library to manipulate an extension of Merkle trees (called Plebeia trees). It is being implemented as a part of the storage system of the Tezos blockchain system. To this end, we gradually ported Plebeia to F ★ ; the OCaml code extracted from the modules ported to F ★ is linked with the unverified part of Plebeia. By this gradual porting process, we can obtain a working code from our partially verified implementation of Plebeia; we confirmed that the binary passes all the unit tests of Plebeia.More specifically, we verified the following properties on the implementation of Plebeia: (1) Each treemanipulating function preserves the invariants on the data structure of a Plebeia tree and satisfies the functional requirements as a nested key-value store; (2) Each function for serializing/deserializing a Plebeia tree to/from the low-level storage is implemented correctly; and (3) The hash function for a Plebeia tree is relatively collision-resistant with respect to the cryptographic safety of the blake2b hash function. During porting Plebeia to F ★ , we found a bug in an old version of Plebeia, which was overlooked by the tests bundled with the original implementation. To the best of our knowledge, this is the first work that verifies a production-level implementation of a Merkle-tree library by F ★ .

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Helmholtz: A Verifier for Tezos Smart Contracts Based on Refinement Types

Nishida

Saito

Chen

et al. 2021

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A smart contract is a program executed on a blockchain, based on which many cryptocurrencies are implemented, and is being used for automating transactions. Due to the large amount of money that smart contracts deal with, there is a surging demand for a method that can statically and formally verify them.This tool paper describes our type-based static verification tool Helmholtz for Michelson, which is a statically typed stack-based language for writing smart contracts that are executed on the blockchain platform Tezos. Helmholtz is designed on top of our extension of Michelson’s type system with refinement types. Helmholtz takes a Michelson program annotated with a user-defined specification written in the form of a refinement type as input; it then typechecks the program against the specification based on the refinement type system, discharging the generated verification conditions with the SMT solver Z3. We briefly introduce our refinement type system for the core calculus Mini-Michelson of Michelson, which incorporates the characteristic features such as compound datatypes (e.g., lists and pairs), higher-order functions, and invocation of another contract. Helmholtz successfully verifies several practical Michelson programs, including one that transfers money to an account and that checks a digital signature.

show abstract

HELMHOLTZ: A Verifier for Tezos Smart Contracts Based on Refinement Types

Nishida¹,

Saito²,

Chen³

et al. 2021

Preprint

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Jun Furuse

Structuring of Sekisui Heim Automated Parts Pickup System (HAPPS) to Process Indivisual Floor Plans

Helmholtz: A Verifier for Tezos Smart Contracts Based on Refinement Types

Verification of a Merkle Patricia Tree Library Using F*

Helmholtz: A Verifier for Tezos Smart Contracts Based on Refinement Types

HELMHOLTZ: A Verifier for Tezos Smart Contracts Based on Refinement Types

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