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Region Type Checking for Core-JavaChin, Wei Ngan, Qin, Shengchao, Rinard, Martin C. 01 1900 (has links)
Region-based memory management offers several important advantages over garbage-collected heap, including real-time performance, better data locality and efficient use of limited memory. The concept of regions was first introduced for a call-by-value functional language by Tofte and Talpin, and has since been advocated for imperative and object-oriented languages. Scope memory, a lexical variant of regions, is now a core feature in a recent proposal on Real-Time Specification for Java (RTSJ). In this paper, we propose a region-based memory management system for a core subset of Java. Our region type analysis can completely prevent dangling references and thus is ready to cater for the no-dangling requirement in RTSJ. Our system also supports modular compilation, which is an important feature for Java, but was missing in recent related work. / Singapore-MIT Alliance (SMA)
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Type-Safety Obligation Generation in RosettaKamath, Roshan 16 September 2002 (has links)
No description available.
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Language and tool support for multilingual programsLee, Byeongcheol 12 October 2011 (has links)
Programmers compose programs in multiple languages to combine the
advantages of innovations in new high-level programming languages with
decades of engineering effort in legacy libraries and systems. For
language inter-operation, language designers provide two classes of
multilingual programming interfaces: (1) foreign function interfaces
and (2) code generation interfaces. These interfaces embody the
semantic mismatch for developers and multilingual systems
builders. Their programming rules are difficult or impossible to
verify. As a direct consequence, multilingual programs are full of
bugs at interface boundaries, and debuggers cannot assist developers
across these lines.
This dissertation shows how to use composition of single language
systems and interposition to improve the safety of multilingual
programs. Our compositional approach is scalable by construction
because it does not require any changes to single-language systems,
and it leverages their engineering efforts. We show it is effective by
composing a variety of multilingual tools that help programmers
eliminate bugs. We present the first concise taxonomy and formal
description of multilingual programming interfaces and their
programming rules. We next compose three classes of multilingual
tools: (1) Dynamic bug checkers for foreign function interfaces. We
demonstrate a new approach for automatically generating a dynamic bug
checker by interposing on foreign function interfaces, and we show
that it finds bugs in real-world applications including Eclipse,
Subversion, and Java Gnome. (2) Multilingual debuggers for foreign
function interfaces. We introduce an intermediate agent that wraps all
the methods and functions at language boundaries. This intermediate
agent is sufficient to build all the essential debugging features used
in single-language debuggers. (3) Safe macros for code generation
interfaces. We design a safe macro language, called Marco, that
generates programs in any language and demonstrate it by implementing
checkers for SQL and C++ generators. To check the correctness of the
generated programs, Marco queries single-language compilers and
interpreters through code generation interfaces. Using their error
messages, Marco points out the errors in program generators.
In summary, this dissertation presents the first concise taxonomy and
formal specification of multilingual interfaces and, based on this
taxonomy, shows how to compose multilingual tools to improve safety
in multilingual programs. Our results show that our compositional
approach is scalable and effective for improving safety in real-world
multilingual programs. / text
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Interpret dynamického programovacího jazyka pro vědecké výpočty / Interpreter of a Dynamic Programming Language for Scientific ComputingOcelík, Tomáš January 2012 (has links)
The master's thesis deals with design of a dynamic reflective prototype-based language. First, basic principles of this language group are explained and well known representatives are described. Then languages for scientific computing are shortly discussed. Next section of the thesis describes in detail the proposed programming language, its grammar and semantics. Principles of type checking and inheritance are explained. Thesis also demonstrates implementation of basic control structures known from other languages. Next section shows design of virtual machine for the language described before. Section explains used computational model, organization of the object memory and internal representation of important structures of the designed language. Finally, dynamic type checking, compiler and compilation of typical structures to the virtual machine internal code are discussed.
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