5,129 research outputs found
The role of concurrency in an evolutionary view of programming abstractions
In this paper we examine how concurrency has been embodied in mainstream
programming languages. In particular, we rely on the evolutionary talking
borrowed from biology to discuss major historical landmarks and crucial
concepts that shaped the development of programming languages. We examine the
general development process, occasionally deepening into some language, trying
to uncover evolutionary lineages related to specific programming traits. We
mainly focus on concurrency, discussing the different abstraction levels
involved in present-day concurrent programming and emphasizing the fact that
they correspond to different levels of explanation. We then comment on the role
of theoretical research on the quest for suitable programming abstractions,
recalling the importance of changing the working framework and the way of
looking every so often. This paper is not meant to be a survey of modern
mainstream programming languages: it would be very incomplete in that sense. It
aims instead at pointing out a number of remarks and connect them under an
evolutionary perspective, in order to grasp a unifying, but not simplistic,
view of the programming languages development process
Compositional Reasoning for Explicit Resource Management in Channel-Based Concurrency
We define a pi-calculus variant with a costed semantics where channels are
treated as resources that must explicitly be allocated before they are used and
can be deallocated when no longer required. We use a substructural type system
tracking permission transfer to construct coinductive proof techniques for
comparing behaviour and resource usage efficiency of concurrent processes. We
establish full abstraction results between our coinductive definitions and a
contextual behavioural preorder describing a notion of process efficiency
w.r.t. its management of resources. We also justify these definitions and
respective proof techniques through numerous examples and a case study
comparing two concurrent implementations of an extensible buffer.Comment: 51 pages, 7 figure
CPL: A Core Language for Cloud Computing -- Technical Report
Running distributed applications in the cloud involves deployment. That is,
distribution and configuration of application services and middleware
infrastructure. The considerable complexity of these tasks resulted in the
emergence of declarative JSON-based domain-specific deployment languages to
develop deployment programs. However, existing deployment programs unsafely
compose artifacts written in different languages, leading to bugs that are hard
to detect before run time. Furthermore, deployment languages do not provide
extension points for custom implementations of existing cloud services such as
application-specific load balancing policies.
To address these shortcomings, we propose CPL (Cloud Platform Language), a
statically-typed core language for programming both distributed applications as
well as their deployment on a cloud platform. In CPL, application services and
deployment programs interact through statically typed, extensible interfaces,
and an application can trigger further deployment at run time. We provide a
formal semantics of CPL and demonstrate that it enables type-safe, composable
and extensible libraries of service combinators, such as load balancing and
fault tolerance.Comment: Technical report accompanying the MODULARITY '16 submissio
Abstract State Machines 1988-1998: Commented ASM Bibliography
An annotated bibliography of papers which deal with or use Abstract State
Machines (ASMs), as of January 1998.Comment: Also maintained as a BibTeX file at http://www.eecs.umich.edu/gasm
Polymonadic Programming
Monads are a popular tool for the working functional programmer to structure
effectful computations. This paper presents polymonads, a generalization of
monads. Polymonads give the familiar monadic bind the more general type forall
a,b. L a -> (a -> M b) -> N b, to compose computations with three different
kinds of effects, rather than just one. Polymonads subsume monads and
parameterized monads, and can express other constructions, including precise
type-and-effect systems and information flow tracking; more generally,
polymonads correspond to Tate's productoid semantic model. We show how to equip
a core language (called lambda-PM) with syntactic support for programming with
polymonads. Type inference and elaboration in lambda-PM allows programmers to
write polymonadic code directly in an ML-like syntax--our algorithms compute
principal types and produce elaborated programs wherein the binds appear
explicitly. Furthermore, we prove that the elaboration is coherent: no matter
which (type-correct) binds are chosen, the elaborated program's semantics will
be the same. Pleasingly, the inferred types are easy to read: the polymonad
laws justify (sometimes dramatic) simplifications, but with no effect on a
type's generality.Comment: In Proceedings MSFP 2014, arXiv:1406.153
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