MANGO: exploring Manycore Architectures for Next-GeneratiOn HPC systems

Objectif

MANGO targets to achieve extreme resource efficiency in future QoS-sensitive HPC through ambitious cross-boundary architecture exploration for performance/power/predictability (PPP) based on the definition of new-generation high-performance, power-efficient, heterogeneous architectures with native mechanisms for isolation and quality-of-service, and an innovative two-phase passive cooling system. Its disruptive approach will involve many interrelated mechanisms at various architectural levels, including heterogeneous computing cores, memory architectures, interconnects, run-time resource management, power monitoring and cooling, to the programming models. The system architecture will be inherently heterogeneous as an enabler for efficiency and application-based customization, where general-purpose compute nodes (GN) are intertwined with heterogeneous acceleration nodes (HN), linked by an across-boundary homogeneous interconnect. It will provide guarantees for predictability, bandwidth and latency for the whole HN node infrastructure, allowing dynamic adaptation to applications. MANGO will develop a toolset for PPP and explore holistic pro-active thermal and power management for energy optimization including chip, board and rack cooling levels, creating a hitherto inexistent link between HW and SW effects at all layers. Project will build an effective large-scale emulation platform. The architecture will be validated through noticeable examples of application with QoS and high-performance requirements.

Ultimately, the combined interplay of the multi-level innovative solutions brought by MANGO will result in a new positioning in the PPP space, ensuring sustainable performance as high as 100 PFLOPS for the realistic levels of power consumption (<15MWatt) delivered to QoS-sensitive applications in large-scale capacity computing scenarios providing essential building blocks at the architectural level enabling the full realization of the ETP4HPC strategic research agenda

Champ scientifique

• sciences naturellesinformatique et science de l'informationlogiciel
• ingénierie et technologiegénie mécaniqueingénierie thermodynamique
• ingénierie et technologiegénie mécaniquegénie automobilegénie aérospatialtechnologie satellitaire
• ingénierie et technologieingénierie médicaleimagerie diagnostique
• ingénierie et technologiegénie électrique, génie électronique, génie de l’informationingénierie de l’informationtélécommunication

Mots‑clés

• Real-time HPC
• power-performance-predictability
• capacity computing
• partitionability
• reconfigurability

Programme(s)

• H2020-EU.1.2. - EXCELLENT SCIENCE - Future and Emerging Technologies (FET) Main Programme
• H2020-EU.1.2.2. - FET Proactive

Thème(s)

• FETHPC-1-2014 - HPC Core Technologies, Programming Environments and Algorithms for Extreme Parallelism and Extreme Data Applications

Appel à propositions

H2020-FETHPC-2014

Régime de financement

Coordinateur

Participants (9)