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Hitachi SR8000 Supercomputer LAPPEENRANTA UNIVERSITY OF TECHNOLOGY Department of Information Technology 010652000 Introduction to Parallel Computing Group.

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Presentation on theme: "Hitachi SR8000 Supercomputer LAPPEENRANTA UNIVERSITY OF TECHNOLOGY Department of Information Technology 010652000 Introduction to Parallel Computing Group."— Presentation transcript:

1 Hitachi SR8000 Supercomputer LAPPEENRANTA UNIVERSITY OF TECHNOLOGY Department of Information Technology 010652000 Introduction to Parallel Computing Group 2: Juha Huttunen, Tite 4 Olli Ryhänen, Tite 4

2 History of SR8000 Successor of Hitachi S-3800 vector super computer and SR2201 parallel computer.

3 Overview of system architecture Distributed-memory parallel computer with pseudo-vector SMP nodes.

4 Processing Unit IBM PowerPC CPU architecture with Hitachi’s extensions –64 bit PowerPC RISC processors –Available in speeds: 250MHz, 300MHz, 375MHz and 450MHz –Hitachi extensions Additional 128 floating-point registers (total of 160 FPRs) Fast hardware barrier synchronisation mechanism Pseudo Vector Processing (PVP)

5 160 Floating-Point registers 160 FP registers –FR0 – FR31 global part –FR32 – FR128 slide part FPR operations extended to handle slide part Inner Product of two arrays

6 Pseudo Vector Processing (PVP) Introduced in Hitachi SR2201 supercomputer Designed to solve memory bandwidth problems in RISC CPUs –Performance similar of vector processor –Non-blocking arithmetic execution –Reduce chances of cache misses Pipelined data loading –pre-fetch –pre-load

7 Pseudo Vector Processing (PVP) Performance effect of PVP

8 Node Structure Pseudo vector SMP-nodes –8 instruction processors (IP) for computation –1 system control processor (SP) for management –Co-operative Micro-processors in single Address Space (COMPAS) –Maximum number of nodes is 512 (4096 processors) Node types –Processing Nodes (PRN) –I/O Nodes (ION) –Supervisory Node (SVN) One per system

9 Node Partitioning/Grouping A physical node can belong to many logical partitions A node can belong to multiple node groups –Node groups are created dynamically by the master node

10 COMPAS Auto parallelization by the compiler Hardware support for fast fork/join sequences –Small start-up overhead –Cache coherency –Fast signalling between child and parent processes

11 COMPAS Performance effect of COMPAS

12 Interconnection Network Interconnection network –Multidimensional crossbar 1, 2 or 3-dimensional Maximum of 8 nodes/dimension –External connections via I/O nodes Ethernet, ATM, etc. Remote Direct Memory Access (RDMA) –Data transfer between nodes –Minimizes operating system overhead –Support in MPI and PVM libraries

13 RDMA

14 Overview of Architecture

15 Software on SR8000 Operating System –HI-UX with MPP (Massively Parallel Processing) features –Built-in maintenance tools –64 bit addressing with 32 bit code support –Single system for the whole computer Programming tools –Optimized F77, F90, Parallel Fortran, C and C++ compilers –MPI-2 (Message Parsing Interface) –PVM (Parallel Virtual Machine) –Variety of debugging tools (eg. Vampir and Totalview)

16 Hybrid Programming Model Supports several parallel programming methods –MPI + COMPAS Each node has one MPI process Pseudo vectorization by PVP Auto parallelization by COMPAS –MPI + OpenMP Each node has one MPI process Divided to threads between the 8 CPUs by OpenMP –MPI + MPP Each CPU has one MPI process (max 8 processes/node) –COMPAS Each node has one process Pseudo vectorization by PVP Auto parallelization by COMPAS

17 Hybrid Programming Model –OpenMP Each node has one process Divided to threads between the 8 CPUs by OpenMP –Scalar One application with a single thread on one CPU Can use the 9th CPU –ION Default model for commands like ’ls’, ’vi’ etc. Can use the 9th CPU

18 Hybrid Programming Model Performance Effects Parallel vector-matrix multiplication used as example

19 Performance Figures 10 places on the Top 500 list –Highest rankings 26 and 27 Theoretical maximum performance 7,3Tflop/s with 512 nodes Node performance depends on the model, from 8Gflop/s to 14,4Gflop/s depending on the CPU speed. Maximum memory capacity 8TB Latency from processor to various locations –To memory: 30 – 200 nanoseconds –To remote memory via RDMA feature: ~3-5 microseconds –MPI (without RDMA): ~6-20 microseconds –To disk: ~8 milliseconds –To tape: ~30 seconds

20 Scalability Highly scalable architecture –Fast interconnection network and modular node structure –Externally coupling 2 G1 frames performanceof 1709Gflop/s out of 2074Gflop/s was achieved (82% efficiency)

21 Leibniz-Rechenzentrum SR8000-F1 in Leibniz-Rechenzentrum (LRZ), Munich –German federal top-level compute server in Bavaria System information –168 nodes (1344 processors, 375 MHz) –1344GB of memory 8 GB/node 4 nodes with 16 GB –10TB of disk storage

22 Leibniz-Rechenzentrum Performance –Peak performance per CPU – 1,5 GFlop/s (per node 12 GFlop/s) –Total peak performance – 2016 GFlop/s (Linpack 1645 GFlop/s) –I/O bandwidth – to /home 600 MB/s, to /tmp 2,4GB/s –Expected efficiency (from LRZ benchmarks) >600 GFlop/s –Performance from main memory (most unfavourable case) >244 GFlop/s

23 Leibniz-Rechenzentrum –Unidirectional communication bandwidth: MPI without RDMA – 770 MB/s MPI without RDMA – 950 MB/s Hardware – 1000 MB/s –2*unidirectional bisection bandwidth MPI and RDMA – 2x79 = 158 GB/s Hardware – 2x84 = 168 GB/s


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