Spelling suggestions: "subject:"haskell (computer program language)"" "subject:"haskell (coomputer program language)""
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Executable semantics for PLEXIL : simulating a task-scheduling language in Haskell /Strauss, Paul J. January 1900 (has links)
Thesis ()--Oregon State University, 2009. / Printout. Includes bibliographical references (leaves 87-89). Also available on the World Wide Web.
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A declarative debugger for Haskell /Pope, Bernard James. January 2006 (has links)
Thesis (Ph.D.)--University of Melbourne, Dept. of Computer Science and Software Engineering, 2007. / Typescript. Includes bibliographical references (leaves 253-264).
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Value recursion in monadic computations /Erkök, Levent, January 2002 (has links)
Thesis (Ph. D.)--OGI School of Science & Engineering at OHSU, 2002.
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Extensible Scheduling in a Haskell-based Operating SystemGraunke, Kenneth William 01 January 2010 (has links)
This thesis presents Lighthouse, an experimental branch of the Haskell-based House operating system which integrates Li et al.'s Lightweight Concurrency framework. First and foremost, it improves House's viability as a "real operating system" by providing a new extensible scheduler framework which makes it easy to experiment with different scheduling policies. In particular, Lighthouse extends Concurrent Haskell with thread priority and implements a priority-based scheduler which significantly improves system responsiveness when compared with GHC's normal round-robin scheduler. Even while doing this, it improves on House's claim of being "written in Haskell" by moving a whole subsystem out of the complex C-based runtime system and into Haskell itself. In addition, Lighthouse also includes an alternate, simpler implementation of Lightweight Concurrency which takes advantage of House's unique setting (running directly on uniprocessor x86 hardware). This experience sheds light on areas that need further attention before the system can truly be viable---primarily interactions between blackholing and interrupt handling. In particular, this thesis uncovers a potential case of self-deadlock and suggests potential solutions. Finally, this work offers further insight into the viability of using high-level languages such as Haskell for systems programming. Although laziness and blackholing present unique problems, many parts of the system are still much easier to express in Haskell than traditional languages such as C.
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Type Classes and Instance Chains: A Relational ApproachMorris, John Garrett 04 June 2013 (has links)
Type classes, first proposed during the design of the Haskell programming language, extend standard type systems to support overloaded functions. Since their introduction, type classes have been used to address a range of problems, from typing ordering and arithmetic operators to describing heterogeneous lists and limited subtyping. However, while type class programming is useful for a variety of practical problems, its wider use is limited by the inexpressiveness and hidden complexity of current mechanisms. We propose two improvements to existing class systems. First, we introduce several novel language features, instance chains and explicit failure, that increase the expressiveness of type classes while providing more direct expression of current idioms. To validate these features, we have built an implementation of these features, demonstrating their use in a practical setting and their integration with type reconstruction for a Hindley-Milner type system. Second, we define a set-based semantics for type classes that provides a sound basis for reasoning about type class systems, their implementations, and the meanings of programs that use them.
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