100,251 research outputs found
PLACES'10: The 3rd Workshop on Programmng Language Approaches to concurrency and Communication-Centric Software
Paphos, Cyprus. March 201
Feeling Racial Pride in the Mode of Frederick Douglass
Drawing on Frederick Douglassās arguments about racial pride, I develop and defend an account of feeling racial pride that centers on resisting racialized oppression. Such pride is racially ecumenical in that it does not imply partiality towards oneās own racial group. I argue that it can both accurately represent its intentional object and be intrinsically and extrinsically valuable to experience. It follows, I argue, that there is, under certain conditions, a morally unproblematic, and plausibly valuable, kind of racial pride available to white people, though one that could hardly differ more from what is generally meant by āwhite pride.
Efficient and Reasonable Object-Oriented Concurrency
Making threaded programs safe and easy to reason about is one of the chief
difficulties in modern programming. This work provides an efficient execution
model for SCOOP, a concurrency approach that provides not only data race
freedom but also pre/postcondition reasoning guarantees between threads. The
extensions we propose influence both the underlying semantics to increase the
amount of concurrent execution that is possible, exclude certain classes of
deadlocks, and enable greater performance. These extensions are used as the
basis an efficient runtime and optimization pass that improve performance 15x
over a baseline implementation. This new implementation of SCOOP is also 2x
faster than other well-known safe concurrent languages. The measurements are
based on both coordination-intensive and data-manipulation-intensive benchmarks
designed to offer a mixture of workloads.Comment: Proceedings of the 10th Joint Meeting of the European Software
Engineering Conference and the ACM SIGSOFT Symposium on the Foundations of
Software Engineering (ESEC/FSE '15). ACM, 201
A Concurrent Language with a Uniform Treatment of Regions and Locks
A challenge for programming language research is to design and implement
multi-threaded low-level languages providing static guarantees for memory
safety and freedom from data races. Towards this goal, we present a concurrent
language employing safe region-based memory management and hierarchical locking
of regions. Both regions and locks are treated uniformly, and the language
supports ownership transfer, early deallocation of regions and early release of
locks in a safe manner
Fast and Precise Symbolic Analysis of Concurrency Bugs in Device Drivers
Ā© 2015 IEEE.Concurrency errors, such as data races, make device drivers notoriously hard to develop and debug without automated tool support. We present Whoop, a new automated approach that statically analyzes drivers for data races. Whoop is empowered by symbolic pairwise lockset analysis, a novel analysis that can soundly detect all potential races in a driver. Our analysis avoids reasoning about thread interleavings and thus scales well. Exploiting the race-freedom guarantees provided by Whoop, we achieve a sound partial-order reduction that significantly accelerates Corral, an industrial-strength bug-finder for concurrent programs. Using the combination of Whoop and Corral, we analyzed 16 drivers from the Linux 4.0 kernel, achieving 1.5 - 20Ć speedups over standalone Corral
Contract-Based General-Purpose GPU Programming
Using GPUs as general-purpose processors has revolutionized parallel
computing by offering, for a large and growing set of algorithms, massive
data-parallelization on desktop machines. An obstacle to widespread adoption,
however, is the difficulty of programming them and the low-level control of the
hardware required to achieve good performance. This paper suggests a
programming library, SafeGPU, that aims at striking a balance between
programmer productivity and performance, by making GPU data-parallel operations
accessible from within a classical object-oriented programming language. The
solution is integrated with the design-by-contract approach, which increases
confidence in functional program correctness by embedding executable program
specifications into the program text. We show that our library leads to modular
and maintainable code that is accessible to GPGPU non-experts, while providing
performance that is comparable with hand-written CUDA code. Furthermore,
runtime contract checking turns out to be feasible, as the contracts can be
executed on the GPU
Preventing Atomicity Violations with Contracts
Software developers are expected to protect concurrent accesses to shared
regions of memory with some mutual exclusion primitive that ensures atomicity
properties to a sequence of program statements. This approach prevents data
races but may fail to provide all necessary correctness properties.The
composition of correlated atomic operations without further synchronization may
cause atomicity violations. Atomic violations may be avoided by grouping the
correlated atomic regions in a single larger atomic scope. Concurrent programs
are particularly prone to atomicity violations when they use services provided
by third party packages or modules, since the programmer may fail to identify
which services are correlated. In this paper we propose to use contracts for
concurrency, where the developer of a module writes a set of contract terms
that specify which methods are correlated and must be executed in the same
atomic scope. These contracts are then used to verify the correctness of the
main program with respect to the usage of the module(s). If a contract is well
defined and complete, and the main program respects it, then the program is
safe from atomicity violations with respect to that module. We also propose a
static analysis based methodology to verify contracts for concurrency that we
applied to some real-world software packages. The bug we found in Tomcat 6.0
was immediately acknowledged and corrected by its development team
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