Recently the latest generation of Blue Gene machines became available. In this paper we introduce general metrics to characterize the performance of applications and apply it to a diverse set of applications running on Blue Gene/Q. The applications range from regular, floating-point bound to irregular event-simulator like types. We argue that the proposed metrics are suitable to characterize the performance for a larger set of computational science applications running on today's massively-parallel systems. They therefore do not only allow to assess usability of the Blue Gene/Q architecture for the considered (types of) applications. They also provide more general information on application requirements and valuable input for evaluating the...
Applications may have unintended performance problems in spite of compiler optimizations, because of...
Abstract—As detailed in recent reports, HPC architectures will continue to change over the next deca...
Abstract—The power consumption of state of the art supercom-puters, because of their complexity and ...
High performance computers currently under construction, such as IBM's Blue Gene/L, consisting of l...
Caltech's Jet Propulsion Laboratory (JPL) and Center for Advanced Computer Architecture (CACR) are c...
With the increasing scale and complexity of large computing systems the effort of performance optimi...
Abstract. The Blue Gene/Q (BG/Q) system is the third generation in the IBM Blue Gene line of massive...
We present a performance prediction environment for large scale computers such as the Blue Gene mach...
Applications on todays massively parallel supercom-puters rely on performance analysis tools to guid...
International audienceGyrokinetic simulations lead to huge computational needs. Up to now, the semi-...
Using modern graphics processing units for no-graphics high performance computing is motivated by th...
A common approach to studying future computer systems is to build simulators that accurately model t...
Computational science and engineering application programs are typically large, complex, and dynamic...
Abstract—In addition to pushing what is possible computa-tionally, state-of-the-art supercomputers a...
Using modern graphics processing units for no-graphics high performance computing is motivated by th...
Applications may have unintended performance problems in spite of compiler optimizations, because of...
Abstract—As detailed in recent reports, HPC architectures will continue to change over the next deca...
Abstract—The power consumption of state of the art supercom-puters, because of their complexity and ...
High performance computers currently under construction, such as IBM's Blue Gene/L, consisting of l...
Caltech's Jet Propulsion Laboratory (JPL) and Center for Advanced Computer Architecture (CACR) are c...
With the increasing scale and complexity of large computing systems the effort of performance optimi...
Abstract. The Blue Gene/Q (BG/Q) system is the third generation in the IBM Blue Gene line of massive...
We present a performance prediction environment for large scale computers such as the Blue Gene mach...
Applications on todays massively parallel supercom-puters rely on performance analysis tools to guid...
International audienceGyrokinetic simulations lead to huge computational needs. Up to now, the semi-...
Using modern graphics processing units for no-graphics high performance computing is motivated by th...
A common approach to studying future computer systems is to build simulators that accurately model t...
Computational science and engineering application programs are typically large, complex, and dynamic...
Abstract—In addition to pushing what is possible computa-tionally, state-of-the-art supercomputers a...
Using modern graphics processing units for no-graphics high performance computing is motivated by th...
Applications may have unintended performance problems in spite of compiler optimizations, because of...
Abstract—As detailed in recent reports, HPC architectures will continue to change over the next deca...
Abstract—The power consumption of state of the art supercom-puters, because of their complexity and ...