38,557 research outputs found
GraphX: Unifying Data-Parallel and Graph-Parallel Analytics
From social networks to language modeling, the growing scale and importance
of graph data has driven the development of numerous new graph-parallel systems
(e.g., Pregel, GraphLab). By restricting the computation that can be expressed
and introducing new techniques to partition and distribute the graph, these
systems can efficiently execute iterative graph algorithms orders of magnitude
faster than more general data-parallel systems. However, the same restrictions
that enable the performance gains also make it difficult to express many of the
important stages in a typical graph-analytics pipeline: constructing the graph,
modifying its structure, or expressing computation that spans multiple graphs.
As a consequence, existing graph analytics pipelines compose graph-parallel and
data-parallel systems using external storage systems, leading to extensive data
movement and complicated programming model.
To address these challenges we introduce GraphX, a distributed graph
computation framework that unifies graph-parallel and data-parallel
computation. GraphX provides a small, core set of graph-parallel operators
expressive enough to implement the Pregel and PowerGraph abstractions, yet
simple enough to be cast in relational algebra. GraphX uses a collection of
query optimization techniques such as automatic join rewrites to efficiently
implement these graph-parallel operators. We evaluate GraphX on real-world
graphs and workloads and demonstrate that GraphX achieves comparable
performance as specialized graph computation systems, while outperforming them
in end-to-end graph pipelines. Moreover, GraphX achieves a balance between
expressiveness, performance, and ease of use
Shared-Memory Parallel Maximal Clique Enumeration
We present shared-memory parallel methods for Maximal Clique Enumeration
(MCE) from a graph. MCE is a fundamental and well-studied graph analytics task,
and is a widely used primitive for identifying dense structures in a graph. Due
to its computationally intensive nature, parallel methods are imperative for
dealing with large graphs. However, surprisingly, there do not yet exist
scalable and parallel methods for MCE on a shared-memory parallel machine. In
this work, we present efficient shared-memory parallel algorithms for MCE, with
the following properties: (1) the parallel algorithms are provably
work-efficient relative to a state-of-the-art sequential algorithm (2) the
algorithms have a provably small parallel depth, showing that they can scale to
a large number of processors, and (3) our implementations on a multicore
machine shows a good speedup and scaling behavior with increasing number of
cores, and are substantially faster than prior shared-memory parallel
algorithms for MCE.Comment: 10 pages, 3 figures, proceedings of the 25th IEEE International
Conference on. High Performance Computing, Data, and Analytics (HiPC), 201
GraphBLAST: A High-Performance Linear Algebra-based Graph Framework on the GPU
High-performance implementations of graph algorithms are challenging to
implement on new parallel hardware such as GPUs because of three challenges:
(1) the difficulty of coming up with graph building blocks, (2) load imbalance
on parallel hardware, and (3) graph problems having low arithmetic intensity.
To address some of these challenges, GraphBLAS is an innovative, on-going
effort by the graph analytics community to propose building blocks based on
sparse linear algebra, which will allow graph algorithms to be expressed in a
performant, succinct, composable and portable manner. In this paper, we examine
the performance challenges of a linear-algebra-based approach to building graph
frameworks and describe new design principles for overcoming these bottlenecks.
Among the new design principles is exploiting input sparsity, which allows
users to write graph algorithms without specifying push and pull direction.
Exploiting output sparsity allows users to tell the backend which values of the
output in a single vectorized computation they do not want computed.
Load-balancing is an important feature for balancing work amongst parallel
workers. We describe the important load-balancing features for handling graphs
with different characteristics. The design principles described in this paper
have been implemented in "GraphBLAST", the first high-performance linear
algebra-based graph framework on NVIDIA GPUs that is open-source. The results
show that on a single GPU, GraphBLAST has on average at least an order of
magnitude speedup over previous GraphBLAS implementations SuiteSparse and GBTL,
comparable performance to the fastest GPU hardwired primitives and
shared-memory graph frameworks Ligra and Gunrock, and better performance than
any other GPU graph framework, while offering a simpler and more concise
programming model.Comment: 50 pages, 14 figures, 14 table
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