Ira Rosen scite author profile

Most implementations of the Single Instruction Multiple Data (SIMD) model available today require that data elements be packed in vector registers. Operations on disjoint vector elements are not supported directly and require explicit data reorganization manipulations. Computations on non-contiguous and especially interleaved data appear in important applications, which can greatly benefit from SIMD instructions once the data is reorganized properly. Vectorizing such computations efficiently is therefore an ambitious challenge for both programmers and vectorizing compilers. We demonstrate an automatic compilation scheme that supports effective vectorization in the presence of interleaved data with constant strides that are powers of 2, facilitating data reorganization. We demonstrate how our vectorization scheme applies to dominant SIMD architectures, and present experimental results on a wide range of key kernels, showing speedups in execution time up to 3.7 for interleaving levels (stride) as high as 8.

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Polyhedral-Model Guided Loop-Nest Auto-Vectorization

Trifunovic

Nuzman²,

Cohen³

et al. 2009

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Optimizing compilers apply numerous interdependent optimizations, leading to the notoriously difficult phase-ordering problem-that of deciding which transformations to apply and in which order. Fortunately, new infrastructures such as the polyhedral compilation framework host a variety of transformations, facilitating the efficient exploration and configuration of multiple transformation sequences. Many powerful optimizations, however, remain external to the polyhedral framework, including vectorization. The low-level, target-specific aspects of vectorization for fine-grain SIMD has so far excluded it from being part of the polyhedral framework. In this paper we examine the interactions between loop transformations of the polyhedral framework and subsequent vectorization. We model the performance impact of the different loop transformations and vectorization strategies, and then show how this cost model can be integrated seamlessly into the polyhedral representation. This predictive modelling facilitates efficient exploration and educated decision making to best apply various polyhedral loop transformations while considering the subsequent effects of different vectorization schemes. Our work demonstrates the feasibility and benefit of tuning the polyhedral model in the context of vectorization. Experimental results confirm that our model has accurate predictions, providing speedups of over 2.0x on average over traditional innermost-loop vectorization on PowerPC970 and Cell-SPU SIMD platforms.

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Auto-vectorization of interleaved data for SIMD

2006

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Speculatively vectorized bytecode

Rohou

Dyshel

Nuzman

et al. 2011

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ACOTES Project: Advanced Compiler Technologies for Embedded Streaming

Munk

Ayguadé

Bastoul

et al. 2010

Int J Parallel Prog

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Streaming applications are built of data-driven, computational components, consuming and producing unbounded data streams. Streaming oriented systems have become dominant in a wide range of domains, including embedded applications and DSPs. However, programming efficiently for streaming architectures is a challenging task, having to carefully partition the computation and map it to processes H. Munk (B) · Z. Chamski · P. Dumont · M. Duranton NXP Semiconductors, Eindhoven, The Netherlands e-mail: munkharm@xs4all.nl 123Int J Parallel Prog in a way that best matches the underlying streaming architecture, taking into account the distributed resources (memory, processing, real-time requirements) and communication overheads (processing and delay). These challenges have led to a number of suggested solutions, whose goal is to improve the programmer's productivity in developing applications that process massive streams of data on programmable, parallel embedded architectures. StreamIt is one such example. Another more recent approach is that developed by the ACOTES project (Advanced Compiler Technologies for Embedded Streaming). The ACOTES approach for streaming applications consists of compiler-assisted mapping of streaming tasks to highly parallel systems in order to maximize cost-effectiveness, both in terms of energy and in terms of design effort. The analysis and transformation techniques automate large parts of the partitioning and mapping process, based on the properties of the application domain, on the quantitative information about the target systems, and on programmer directives. This paper presents the outcomes of the ACOTES project, a 3-year collaborative work of industrial (NXP, ST, IBM, Silicon Hive, NOKIA) and academic (UPC, INRIA, MINES ParisTech) partners, and advocates the use of Advanced Compiler Technologies that we developed to support Embedded Streaming.

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Ira Rosen

Auto-vectorization of interleaved data for SIMD

Polyhedral-Model Guided Loop-Nest Auto-Vectorization

Auto-vectorization of interleaved data for SIMD

Speculatively vectorized bytecode

ACOTES Project: Advanced Compiler Technologies for Embedded Streaming

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