1,289 research outputs found
Tree Contraction, Connected Components, Minimum Spanning Trees: a GPU Path to Vertex Fitting
Standard parallel computing operations are considered in the context of algorithms for solving 3D graph problems which have applications, e.g., in vertex finding in HEP. Exploiting GPUs for tree-accumulation and graph algorithms is challenging: GPUs offer extreme computational power and high memory-access bandwidth, combined with a model of fine-grained parallelism perhaps not suiting the irregular distribution of linked representations of graph data structures. Achieving data-race free computations may demand serialization through atomic transactions, inevitably producing poor parallel performance. A Minimum Spanning Tree algorithm for GPUs is presented, its implementation discussed, and its efficiency evaluated on GPU and multicore architectures
CSR5: An Efficient Storage Format for Cross-Platform Sparse Matrix-Vector Multiplication
Sparse matrix-vector multiplication (SpMV) is a fundamental building block
for numerous applications. In this paper, we propose CSR5 (Compressed Sparse
Row 5), a new storage format, which offers high-throughput SpMV on various
platforms including CPUs, GPUs and Xeon Phi. First, the CSR5 format is
insensitive to the sparsity structure of the input matrix. Thus the single
format can support an SpMV algorithm that is efficient both for regular
matrices and for irregular matrices. Furthermore, we show that the overhead of
the format conversion from the CSR to the CSR5 can be as low as the cost of a
few SpMV operations. We compare the CSR5-based SpMV algorithm with 11
state-of-the-art formats and algorithms on four mainstream processors using 14
regular and 10 irregular matrices as a benchmark suite. For the 14 regular
matrices in the suite, we achieve comparable or better performance over the
previous work. For the 10 irregular matrices, the CSR5 obtains average
performance improvement of 17.6\%, 28.5\%, 173.0\% and 293.3\% (up to 213.3\%,
153.6\%, 405.1\% and 943.3\%) over the best existing work on dual-socket Intel
CPUs, an nVidia GPU, an AMD GPU and an Intel Xeon Phi, respectively. For
real-world applications such as a solver with only tens of iterations, the CSR5
format can be more practical because of its low-overhead for format conversion.
The source code of this work is downloadable at
https://github.com/bhSPARSE/Benchmark_SpMV_using_CSR5Comment: 12 pages, 10 figures, In Proceedings of the 29th ACM International
Conference on Supercomputing (ICS '15
Gunrock: A High-Performance Graph Processing Library on the GPU
For large-scale graph analytics on the GPU, the irregularity of data access
and control flow, and the complexity of programming GPUs have been two
significant challenges for developing a programmable high-performance graph
library. "Gunrock", our graph-processing system designed specifically for the
GPU, uses a high-level, bulk-synchronous, data-centric abstraction focused on
operations on a vertex or edge frontier. Gunrock achieves a balance between
performance and expressiveness by coupling high performance GPU computing
primitives and optimization strategies with a high-level programming model that
allows programmers to quickly develop new graph primitives with small code size
and minimal GPU programming knowledge. We evaluate Gunrock on five key graph
primitives and show that Gunrock has on average at least an order of magnitude
speedup over Boost and PowerGraph, comparable performance to the fastest GPU
hardwired primitives, and better performance than any other GPU high-level
graph library.Comment: 14 pages, accepted by PPoPP'16 (removed the text repetition in the
previous version v5
Gunrock: GPU Graph Analytics
For large-scale graph analytics on the GPU, the irregularity of data access
and control flow, and the complexity of programming GPUs, have presented two
significant challenges to developing a programmable high-performance graph
library. "Gunrock", our graph-processing system designed specifically for the
GPU, uses a high-level, bulk-synchronous, data-centric abstraction focused on
operations on a vertex or edge frontier. Gunrock achieves a balance between
performance and expressiveness by coupling high performance GPU computing
primitives and optimization strategies with a high-level programming model that
allows programmers to quickly develop new graph primitives with small code size
and minimal GPU programming knowledge. We characterize the performance of
various optimization strategies and evaluate Gunrock's overall performance on
different GPU architectures on a wide range of graph primitives that span from
traversal-based algorithms and ranking algorithms, to triangle counting and
bipartite-graph-based algorithms. The results show that on a single GPU,
Gunrock has on average at least an order of magnitude speedup over Boost and
PowerGraph, comparable performance to the fastest GPU hardwired primitives and
CPU shared-memory graph libraries such as Ligra and Galois, and better
performance than any other GPU high-level graph library.Comment: 52 pages, invited paper to ACM Transactions on Parallel Computing
(TOPC), an extended version of PPoPP'16 paper "Gunrock: A High-Performance
Graph Processing Library on the GPU
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