As researchers have reached the practical limits of processor performance improvements by frequency scaling, it is clear that the future of computing lies in the effective utilization of parallel and multi-core architectures. Since this significant change in computing is well underway, it is vital for HEP programmers to understand the scalability of their software on modern hardware and the opportunities for potential improvements. This work aims to quantify the benefit of new mainstream architectures to the HEP community through practical benchmarking on recent hardware solutions, including the usage of parallelized HEP applications
In the coming years, HEP data processing will need to exploit parallelism on present and future hard...
As of 2009, HEP-SPEC06 (HS06) is the benchmark adopted by the WLCG community to describe the computi...
As of 2009, HEP-SPEC06 (HS06) is the benchmark adopted by the WLCG community to describe the computi...
As the mainstream computing world has shifted from multi-core to many-core platforms, the situation ...
As Moore's Law continues to deliver more and more transistors, the mainstream processor industry is ...
As the mainstream computing world has shifted from multi-core to many-core platforms, the situation ...
Abstract. Virtualization technologies such as Xen can be used in order to satisfy the disparate and ...
The HEPiX Benchmarking Working Group has developed a framework to benchmark the performance of a com...
As Moore's Law drives the silicon industry towards higher transistor counts, processor designs are b...
This paper summarizes the five years of CERN openlab's efforts focused on the Intel Xeon Phi co-proc...
The benchmarking and accounting of CPU resources in WLCG has been based on the HEP-SPEC06 (HS06) sui...
HEPSPEC-06(HS06) is a decade old suite used to benchmark CPU resources for WLCG. Its adoption spans ...
In pursuit of ever increasing performance, more and more processor architectures have become multico...
In the coming years, HEP data processing will need to exploit parallelism on present and future hard...
Today's world of scientific software for High Energy Physics (HEP) is powered by x86 code, while the...
In the coming years, HEP data processing will need to exploit parallelism on present and future hard...
As of 2009, HEP-SPEC06 (HS06) is the benchmark adopted by the WLCG community to describe the computi...
As of 2009, HEP-SPEC06 (HS06) is the benchmark adopted by the WLCG community to describe the computi...
As the mainstream computing world has shifted from multi-core to many-core platforms, the situation ...
As Moore's Law continues to deliver more and more transistors, the mainstream processor industry is ...
As the mainstream computing world has shifted from multi-core to many-core platforms, the situation ...
Abstract. Virtualization technologies such as Xen can be used in order to satisfy the disparate and ...
The HEPiX Benchmarking Working Group has developed a framework to benchmark the performance of a com...
As Moore's Law drives the silicon industry towards higher transistor counts, processor designs are b...
This paper summarizes the five years of CERN openlab's efforts focused on the Intel Xeon Phi co-proc...
The benchmarking and accounting of CPU resources in WLCG has been based on the HEP-SPEC06 (HS06) sui...
HEPSPEC-06(HS06) is a decade old suite used to benchmark CPU resources for WLCG. Its adoption spans ...
In pursuit of ever increasing performance, more and more processor architectures have become multico...
In the coming years, HEP data processing will need to exploit parallelism on present and future hard...
Today's world of scientific software for High Energy Physics (HEP) is powered by x86 code, while the...
In the coming years, HEP data processing will need to exploit parallelism on present and future hard...
As of 2009, HEP-SPEC06 (HS06) is the benchmark adopted by the WLCG community to describe the computi...
As of 2009, HEP-SPEC06 (HS06) is the benchmark adopted by the WLCG community to describe the computi...