Many-core processor architectures require scalable solutions that reflect the locality and power constraints of future generations of technology. This paper presents a CMP architecture that supports automatic mapping and dynamic scheduling of threads leaving the binary code devoid of any explicit communication. The thrust of this approach is to produce binary code that is divorced from implementation parameters, yet, which still gives good performance over future generations of CMPs. A key component of this abstract processor architecture is the memory system. This paper evaluates the memory architectures, which must maintain performance across a range of targets
Abstract—By integrating multiple cores in a single chip, Chip Multiprocessors (CMP) provide an attra...
grantor: University of TorontoDynamically-scheduled processors challenge hardware and soft...
PARSEC is a reference application suite used in industry and academia to assess new Chip Multiproces...
Moving threads is a theoretically interesting approach for mapping the computation of an application...
Due to inherent non-scalability of superscalar processors, processor manufacturers have switched to ...
This paper proposes the concept of performance balancing, and reports its performance impact on a Ch...
The continued decrease in transistor size and the increasing delay of wires relative to transistor s...
Abstract — In this paper we study the OS services requirect to efficiently manage on-chip memories i...
Modern CMPs are designed to exploit both instruction-level parallelism within processors and threadl...
On the road to computer systems able to support the requirements of exascale applications, Chip Mult...
© 2012 IEEE. Personal use of this material is permitted. Permission from IEEE must be obtained for a...
We propose and evaluate a multi-thread memory scheduler that targets high performance CMPs. The prop...
Moving threads is a new kind of approach for multicore processor architectures. Traditionally, each ...
Future chip multiprocessors (CMPs) will be expected to deliver robust performance in the face of man...
Chip-level multiprocessors (CMP) have multiple processing cores (Cores) and generally have their cac...
Abstract—By integrating multiple cores in a single chip, Chip Multiprocessors (CMP) provide an attra...
grantor: University of TorontoDynamically-scheduled processors challenge hardware and soft...
PARSEC is a reference application suite used in industry and academia to assess new Chip Multiproces...
Moving threads is a theoretically interesting approach for mapping the computation of an application...
Due to inherent non-scalability of superscalar processors, processor manufacturers have switched to ...
This paper proposes the concept of performance balancing, and reports its performance impact on a Ch...
The continued decrease in transistor size and the increasing delay of wires relative to transistor s...
Abstract — In this paper we study the OS services requirect to efficiently manage on-chip memories i...
Modern CMPs are designed to exploit both instruction-level parallelism within processors and threadl...
On the road to computer systems able to support the requirements of exascale applications, Chip Mult...
© 2012 IEEE. Personal use of this material is permitted. Permission from IEEE must be obtained for a...
We propose and evaluate a multi-thread memory scheduler that targets high performance CMPs. The prop...
Moving threads is a new kind of approach for multicore processor architectures. Traditionally, each ...
Future chip multiprocessors (CMPs) will be expected to deliver robust performance in the face of man...
Chip-level multiprocessors (CMP) have multiple processing cores (Cores) and generally have their cac...
Abstract—By integrating multiple cores in a single chip, Chip Multiprocessors (CMP) provide an attra...
grantor: University of TorontoDynamically-scheduled processors challenge hardware and soft...
PARSEC is a reference application suite used in industry and academia to assess new Chip Multiproces...