Williams - PowerPoint PPT Presentation

1 / 10
About This Presentation
Title:

Williams

Description:

A Linux-based Software Environment for the Reconfigurable Scalable ... Embedded Linux No MMU - uClinux Provides easy path to high level development for ... – PowerPoint PPT presentation

Number of Views:83
Avg rating:3.0/5.0
Slides: 11
Provided by: Kev76
Learn more at: http://klabs.org
Category:

less

Transcript and Presenter's Notes

Title: Williams


1
A Linux-based Software Environment for the
Reconfigurable Scalable Computing Project
  • John A. Williams1 (jwilliams_at_itee.uq.edu.au)
  • Neil W. Bergmann1 (n.bergmann_at_itee.uq.edu.au)
  • Robert F. Hodson2 (robert.f.hodson_at_nasa.gov)
  • 1 The University Of Queensland, Australia
  • 2 NASA Langley Research Center

2
RSC Platform Architectural Overview
  • Collection of one or more modular stacks of
    computing elements
  • RPM is core reconfigurable component hosting
    reconfigurable FPGA fabric

3
RSC Embedded Processing
  • Primary target microprocessor is the MicroBlazeTM
    soft processor.
  • Design mitigated with XTMR tool (or manually)
  • Embedded Linux
  • No MMU -gt uClinux
  • Provides easy path to high level development for
    instrument applications (C, sockets, file
    systems, etc)
  • Development environment similar (if not
    identical) to typical Linux desktop

4
RSC Software Environment
  • Why Linux?
  • Path for existing applications onto RSC
  • Standard platform improves design efficiency
  • Application development/debug
  • Multiprocessing/clustering
  • Software infrastructure
  • Interoperability
  • Networking
  • File systems
  • Desktop application prototyping
  • Linux is the C runtime D. Jeff Dionne

5
Software Multiprocessing Model
  • Message Passing Interface (MPI, MPI2)
  • Standardised protocol for message passing
    parallel computation
  • Strong uptake in terrestrial cluster computing
    community
  • Supports distributed (networked) clusters as well
    as shared memory machines
  • MPI on MicroBlaze and uClinux
  • Based on Argonne National Labs MPICH2
    implementation
  • Start with MPICH on Linux TCP/IP stack
  • Migrate to higher performance implementation as
    RSC network architecture evolves

6
Hardware Multiprocessing Model
  • Reconfigurable Processing Module (RPM)
  • Application FPGA logic capacity (after TMR)
  • Two CPUs, support HW, system interconnect
  • Custom processing HW and IO cores
  • 512MB shared EDAC DRAM
  • Multiprocessing options
  • SMP Linux
  • Dual UP Linux (shared memory)
  • UP Linux custom coprocessor
  • UP Linux I/O processor

7
Hardware Multiprocessing Model
Application FPGA (Xilinx)
CPU0
CPU1
Timer / INTC/
Caches
Timer / INTC/
Bus I/F
On-Chip Peripheral Bus
On-Chip Peripheral Bus
I/O core(s)
I/O core(s)
Custom core
Custom core
Custom core
Custom core
SLiP I/F
Interface FPGA (Actel)
On Chip Bus (Wishbone)
PCI I/F
3.3V PCI 33MHz 32/64 bit
8
Status and outlook
  • OS and multiprocessing prototyping
  • COTS FPGA eval board
  • Insight-Memec V4LX25 comms module
  • Dual ethernet, uart
  • 64MB DDR
  • UP Linux reference design completed
  • SMP feasibility study underway
  • Dual UP Linux
  • Dual MicroBlaze HW system built
  • Dual kernel bringup underway
  • MPICH2 port in progress
  • MPICH libraries integrated into uClinux build
  • Preliminary port of cluster process manager
    daemon

9
Status and outlook
  • COTS prototype cluster
  • 4 x dual CPU subsystems

10
Research questions
  • Impact of TMR on performance
  • How to represent custom HW in an MPI cluster
  • Coprocessor to CPU nodes?
  • Fully fledged MPI nodes / peers?
  • Application of standard Linux technologies for
    reliability and survivability
  • RAID ramdisks
  • Cluster node failover
  • Performance modeling and analysis
  • Rob Jones, RSC Co-I
Write a Comment
User Comments (0)
About PowerShow.com