11,107 research outputs found
The structured phase of concurrency
This extended abstract summarizes the state-of-the-art solution to the structuring problem for models that describe existing real world or envisioned processes. Special attention is devoted to models that allow for the true concurrency semantics. Given a model of a process, the structuring problem deals with answering the question of whether there exists another model that describes the process and is solely composed of structured patterns, such as sequence, selection, option for simultaneous execution, and iteration. Methods and techniques for structuring developed by academia as well as products and standards proposed by industry are discussed. Expectations and recommendations on the future advancements of the structuring problem are suggested
Graphical modelling language for spycifying concurrency based on CSP
Introduced in this (shortened) paper is a graphical modelling language for specifying concurrency in software designs. The language notations are derived from CSP and the resulting designs form CSP diagrams. The notations reflect both data-flow and control-flow aspects of concurrent software architectures. These designs can automatically be described by CSP algebraic expressions that can be used for formal analysis. The designer does not have to be aware of the underlying mathematics. The techniques and rules presented provide guidance to the development of concurrent software architectures. One can detect and reason about compositional conflicts (errors in design), potential deadlocks (errors at run-time), and priority inversion problems (performance burden) at a high level of abstraction. The CSP diagram collaborates with objectoriented modelling languages and structured methods
A Programming Language for Web Service Development
There is now widespread acceptance of Web services and service-oriented architectures. But despite the agreement on key Web services standards there remain many challenges. Programming environments based on WSDL support go some way to facilitating Web service development. However Web services fundamentally rely on XML and Schema, not on contemporary programming language type systems such as those of Java or .NET. Moreover, Web services are based on a messaging paradigm and hence bring forward the traditional problems of messaging systems including concurrency control and message correlation. It is easy to write simple synchronous Web services using traditional programming languages; however more realistic scenarios are surprisingly difficult to implement. To alleviate these issues we propose a programming language which directly supports Web service development. The language leverages XQuery for native XML processing, supports implicit message correlation and has high level join calculus-style concurrency control. We illustrate the features of the language through a motivating example
Virtual Machine Support for Many-Core Architectures: Decoupling Abstract from Concrete Concurrency Models
The upcoming many-core architectures require software developers to exploit
concurrency to utilize available computational power. Today's high-level
language virtual machines (VMs), which are a cornerstone of software
development, do not provide sufficient abstraction for concurrency concepts. We
analyze concrete and abstract concurrency models and identify the challenges
they impose for VMs. To provide sufficient concurrency support in VMs, we
propose to integrate concurrency operations into VM instruction sets.
Since there will always be VMs optimized for special purposes, our goal is to
develop a methodology to design instruction sets with concurrency support.
Therefore, we also propose a list of trade-offs that have to be investigated to
advise the design of such instruction sets.
As a first experiment, we implemented one instruction set extension for
shared memory and one for non-shared memory concurrency. From our experimental
results, we derived a list of requirements for a full-grown experimental
environment for further research
Lock-free Concurrent Data Structures
Concurrent data structures are the data sharing side of parallel programming.
Data structures give the means to the program to store data, but also provide
operations to the program to access and manipulate these data. These operations
are implemented through algorithms that have to be efficient. In the sequential
setting, data structures are crucially important for the performance of the
respective computation. In the parallel programming setting, their importance
becomes more crucial because of the increased use of data and resource sharing
for utilizing parallelism.
The first and main goal of this chapter is to provide a sufficient background
and intuition to help the interested reader to navigate in the complex research
area of lock-free data structures. The second goal is to offer the programmer
familiarity to the subject that will allow her to use truly concurrent methods.Comment: To appear in "Programming Multi-core and Many-core Computing
Systems", eds. S. Pllana and F. Xhafa, Wiley Series on Parallel and
Distributed Computin
Specifying and Executing Optimizations for Parallel Programs
Compiler optimizations, usually expressed as rewrites on program graphs, are
a core part of all modern compilers. However, even production compilers have
bugs, and these bugs are difficult to detect and resolve. The problem only
becomes more complex when compiling parallel programs; from the choice of graph
representation to the possibility of race conditions, optimization designers
have a range of factors to consider that do not appear when dealing with
single-threaded programs. In this paper we present PTRANS, a domain-specific
language for formal specification of compiler transformations, and describe its
executable semantics. The fundamental approach of PTRANS is to describe program
transformations as rewrites on control flow graphs with temporal logic side
conditions. The syntax of PTRANS allows cleaner, more comprehensible
specification of program optimizations; its executable semantics allows these
specifications to act as prototypes for the optimizations themselves, so that
candidate optimizations can be tested and refined before going on to include
them in a compiler. We demonstrate the use of PTRANS to state, test, and refine
the specification of a redundant store elimination optimization on parallel
programs.Comment: In Proceedings GRAPHITE 2014, arXiv:1407.767
A Type-Safe Model of Adaptive Object Groups
Services are autonomous, self-describing, technology-neutral software units
that can be described, published, discovered, and composed into software
applications at runtime. Designing software services and composing services in
order to form applications or composite services requires abstractions beyond
those found in typical object-oriented programming languages. This paper
explores service-oriented abstractions such as service adaptation, discovery,
and querying in an object-oriented setting. We develop a formal model of
adaptive object-oriented groups which offer services to their environment.
These groups fit directly into the object-oriented paradigm in the sense that
they can be dynamically created, they have an identity, and they can receive
method calls. In contrast to objects, groups are not used for structuring code.
A group exports its services through interfaces and relies on objects to
implement these services. Objects may join or leave different groups. Groups
may dynamically export new interfaces, they support service discovery, and they
can be queried at runtime for the interfaces they support. We define an
operational semantics and a static type system for this model of adaptive
object groups, and show that well-typed programs do not cause
method-not-understood errors at runtime.Comment: In Proceedings FOCLASA 2012, arXiv:1208.432
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