• Source: Abstract state machine

In computer science, an abstract state machine (ASM) is a state machine operating on states that are arbitrary data structures (structure in the sense of mathematical logic, that is a nonempty set together with a number of functions (operations) and relations over the set).




Overview


The ASM Method is a practical and scientifically well-founded systems engineering method that bridges the gap between the two ends of system development:

the human understanding and formulation of real-world problems (requirements capture by accurate high-level modeling at the level of abstraction determined by the given application domain)
the deployment of their algorithmic solutions by code-executing machines on changing platforms (definition of design decisions, system and implementation details).
The method builds upon three basic concepts:

ASM: a precise form of pseudo-code, generalizing Finite State Machines to operate over arbitrary data structures
ground model: a rigorous form of blueprints, serving as an authoritative reference model for the design
refinement: a most general scheme for stepwise instantiations of model abstractions to concrete system elements, providing controllable links between the more and more detailed descriptions at the successive stages of system development.
In the original conception of ASMs, a single agent executes a program in a sequence of steps, possibly interacting with its environment. This notion was extended to capture distributed computations, in which multiple agents execute their programs concurrently.
Since ASMs model algorithms at arbitrary levels of abstraction, they can provide high-level, low-level and mid-level views of a hardware or software design. ASM specifications often consist of a series of ASM models, starting with an abstract ground model and proceeding to greater levels of detail in successive refinements or coarsenings.
Due to the algorithmic and mathematical nature of these three concepts, ASM models and their properties of interest can be analyzed using any rigorous form of verification (by reasoning) or validation (by experimentation, testing model executions).




History


The concept of ASMs is due to Yuri Gurevich, who first proposed it in the mid-1980s as a way of improving on Turing's thesis that every algorithm is simulated by an appropriate Turing machine. He formulated the ASM Thesis: every algorithm, no matter how abstract, is step-for-step emulated by an appropriate ASM. In 2000, Gurevich axiomatized the notion of sequential algorithms, and proved the ASM thesis for them. Roughly stated, the axioms are as follows:

states are structures,
the state transition involves only a bounded part of the state, and
everything is invariant under isomorphisms of structures. (Structures can be viewed as algebras, which explains the original name evolving algebras for ASMs.)
The axiomatization and characterization of sequential algorithms have been extended to parallel and interactive algorithms.
In the 1990s, through a community effort, the ASM method was developed, using ASMs for the formal specification and analysis (verification and validation) of computer hardware and software. Comprehensive ASM specifications of programming languages (including Prolog, C, and Java) and design languages (UML and SDL) have been developed.
A detailed historical account can be found elsewhere.
A number of software tools for ASM execution and analysis are available.




Publications






= Books

=
AsmBook: Egon Börger, Robert Stärk. Abstract State Machines: A Method for High-Level System Design and Analysis
JBook: R.Stärk, J.Schmid, E.Börger. Java and the Java Virtual Machine: Definition, Verification, Validation
Proceedings/Journal Issues (since 2000)
2008: Springer LNCS 5238 Abstract State Machines, B and Z
2007: J.UCS Special Issue with Selected Papers from ASM'07
2006: Springer LNCS 5115 Rigorous Methods for Software Construction and Analysis, ASM and B Dagstuhl Seminar
2005: Fundamenta Informatica Special Issue with Selected Papers from ASM'05 (electronic proceedings)
2004: Springer LNCS 3052 Abstract State Machines 2004
2003: Springer LNCS 2589 Abstract State Machines 2003: Advances in Theory and Practice
2003: TCS special Issue with Selected Papers from ASM'03
2002: Dagstuhl Seminar Report Theory and Applications of Abstract State Machines
2001: J.UCS 7.11 Special Issue with Selected Papers from ASM'01
2000: Springer LNCS 1912 Abstract State Machines: Theory and Applications
Comparative case studies with ASM contributions
Steam-Boiler Control: Specification Case Study, Springer LNCS 1165
Production Cell: Software Development Case Study, ASM model
Railcrossing: Formal Methods for Real-Time Computing, ASM model
Light Control: Requirements Engineering Case Study, Dagstuhl Seminar
Invoicing: Requirements Capture Case Study




= Behavioral models for industrial standards

=
OMG for BPMN (version 2006): Springer LNCS 5316
OASIS for BPEL: IJBPMI 1.4 (2006)
ECMA for C#: "A high-level modular definition of the semantics of C♯" doi:10.1016/j.tcs.2004.11.008
ITU-T for SDL-2000: formal semantics of SDL-2000 and Formal Definition of SDL-2000 - Compiling and Running SDL Specifications as ASM Models
IEEE for VHDL93: E.Boerger, U.Glaesser, W.Mueller. Formal Definition of an Abstract VHDL'93 Simulator by EA-Machines. In: Carlos Delgado Kloos and Peter T.~Breuer (Eds.), Formal Semantics for VHDL, pp. 107–139, Kluwer Academic Publishers, 1995
ISO for Prolog: "A mathematical definition of full Prolog" doi:10.1016/0167-6423(95)00006-E




Tools


(in historical order since 2000)

The ASM Workbench
ASMETA, the Abstract State Machine Metamodel and its tool set
AsmL
CoreASM, available at CoreASM, an extensible ASM execution engine
AsmGofer on Archive.org
The XASM open source project on SourceForge




Bibliography


Y. Gurevich, Evolving Algebras 1993: Lipari Guide, E. Börger (ed.), Specification and Validation Methods, Oxford University Press, 1995, 9-36. (ISBN 0-19-853854-5)
Y. Gurevich, Sequential Abstract State Machines capture Sequential Algorithms, ACM Transactions on Computational Logic 1(1) (July 2000), 77–111.
R. Stärk, J. Schmid and E. Börger, Java and the Java Virtual Machine: Definition, Verification, Validation, Springer-Verlag, 2001. (ISBN 3-540-42088-6)
E. Börger and R. Stärk, Abstract State Machines: A Method for High-Level System Design and Analysis, Springer-Verlag, 2003. (ISBN 3-540-00702-4)
E. Börger and A. Raschke, Modeling Companion for Software Practitioners, Springer-Verlag, 2018. (ISBN 978-3-662-56639-8, doi:10.1007/978-3-662-56641-1)




References






External links


Abstract State Machines
AsmCenter Archived 2019-09-13 at the Wayback Machine
The TASM toolset: specification, simulation, and formal verification of real-time systems

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