Parametric flows: Automated behavior equivalencing for symbolic analysis of races in CUDA programs

Li, Guodong; Gopalakrishnan, Ganesh

doi:10.1109/sc.2012.94

Cited by 18 publications

(24 citation statements)

References 19 publications

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“…First, we assume the absence of data races (checking for races using tools such as [30] is future work). Second, we have manually verified that there are no schedule-dependent reduction operations (automation of these checks is future work).…”

Section: Results For Parallel Benchmarksmentioning

confidence: 99%

Efficient search for inputs causing high floating-point errors

Chiang

Gopalakrishnan

Rakamarić

et al. 2014

Proceedings of the 19th ACM SIGPLAN Symposium on Principles and Practice of Parallel Programming

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Tools for floating-point error estimation are fundamental to program understanding and optimization. In this paper, we focus on tools for determining the input settings to a floating point routine that maximizes its result error. Such tools can help support activities such as precision allocation, performance optimization, and auto-tuning. We benchmark current abstraction-based precision analysis methods, and show that they often do not work at scale, or generate highly pessimistic error estimates, often caused by non-linear operators or complex input constraints that define the set of legal inputs. We show that while concrete-testing-based error estimation methods based on maintaining shadow values at higher precision can search out higher error-inducing inputs, suitable heuristic search guidance is key to finding higher errors. We develop a heuristic search algorithm called Binary Guided Random Testing (BGRT). In 45 of the 48 total benchmarks, including many real-world routines, BGRT returns higher guaranteed errors. We also evaluate BGRT against two other heuristic search methods called ILS and PSO, obtaining better results.

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Section: Results For Parallel Benchmarksmentioning

confidence: 99%

Efficient search for inputs causing high floating-point errors

Chiang

Gopalakrishnan

Rakamarić

et al. 2014

Proceedings of the 19th ACM SIGPLAN Symposium on Principles and Practice of Parallel Programming

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“…In addition to detecting subtle concurrency bugs, CD proves to be a light-weight and tailorable approximation to more complete (but also more expensive) algorithms such as DPOR. Our future work will include exploiting thread symmetry [18] and informing concolic verification through static analysis.…”

Section: Discussion Related Work and Conclusionmentioning

confidence: 99%

“…In particular, one such technique that enables scalability to a large number of threads is described in our recent work [18].…”

Section: Cudamentioning

confidence: 99%

Formal Analysis of GPU Programs with Atomics via Conflict-Directed Delay-Bounding

Chiang

Gopalakrishnan

et al. 2013

Lecture Notes in Computer Science

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Abstract. GPU based computing has made significant strides in recent years. Unfortunately, GPU program optimizations can introduce subtle concurrency errors, and so incisive formal bug-hunting methods are essential. This paper presents a new formal bug-hunting method for GPU programs that combine barriers and atomics. We present an algorithm called conflict-directed delay-bounded scheduling algorithm (CD) that exploits the occurrence of conflicts among atomic synchronization commands to trigger the generation of alternate schedules; these alternate schedules are executed in a delay-bounded manner. We formally describe CD, and present two correctness checking methods, one based on final state comparison, and the other on user assertions. We evaluate our implementation on realistic GPU benchmarks, with encouraging results.

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“…This allows for precise defect checking, but limits scalability. A recent extension to GKLEE by Li et al [2012a] uses the notion of parametric flows to soundly restrict defect checking to consider only certain pairs of threads. This is similar to the two-thread abstraction employed by GPUVerify and PUG, and leads to scalability improvements over standard GKLEE, at the expense of a loss in precision for kernels that exhibit inter-thread communication (GPUVerify and PUG also suffer from this loss in precision, as discussed under Incompleteness of the Two-Thread Reduction in Section 4.1).…”

Section: Related Workmentioning

confidence: 99%

The Design and Implementation of a Verification Technique for GPU Kernels

Betts

Chong

Donaldson

et al. 2015

ACM Trans. Program. Lang. Syst.

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We present a technique for the formal verification of GPU kernels, addressing two classes of correctness properties: data races and barrier divergence. Our approach is founded on a novel formal operational semantics for GPU kernels termed synchronous, delayed visibility (SDV) semantics, which captures the execution of a GPU kernel by multiple groups of threads. The SDV semantics provides operational definitions for barrier divergence and for both inter-and intra-group data races. We build on the semantics to develop a method for reducing the task of verifying a massively parallel GPU kernel to that of verifying a sequential program. This completely avoids the need to reason about thread interleavings, and allows existing techniques for sequential program verification to be leveraged. We describe an efficient encoding of data race detection and propose a method for automatically inferring the loop invariants that are required for verification. We have implemented these techniques as a practical verification tool, GPUVerify, that can be applied directly to OpenCL and CUDA source code. We evaluate GPUVerify with respect to a set of 162 kernels drawn from public and commercial sources. Our evaluation demonstrates that GPUVerify is capable of efficient, automatic verification of a large number of real-world kernels.

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Parametric flows: Automated behavior equivalencing for symbolic analysis of races in CUDA programs

Cited by 18 publications

References 19 publications

Efficient search for inputs causing high floating-point errors

Efficient search for inputs causing high floating-point errors

Formal Analysis of GPU Programs with Atomics via Conflict-Directed Delay-Bounding

The Design and Implementation of a Verification Technique for GPU Kernels

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