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High Resolution Aerospace Applications using the NASA Columbia Supercomputer

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Title: High Resolution Aerospace Applications using the NASA Columbia Supercomputer


1
High Resolution Aerospace Applications using the
NASA Columbia Supercomputer
  • Dimitri J. Mavriplis
  • University of Wyoming
  • Michael J. Aftosmis
  • NASA Ames Research Center
  • Marsha Berger
  • Courant Institute, NYU

2
Computational Aerospace Design and Analysis
  • Computational Fluid Dynamics (CFD) Successes
  • Preliminary design estimates for various
    conditions
  • Accurate prediction at cruise conditions (no flow
    separation)

3
Computational Aerospace Design and Analysis
  • Computational Fluid Dynamics (CFD) Successes
  • Preliminary design estimates for various
    conditions
  • Accurate prediction at cruise conditions (no flow
    separation)
  • CFD Shortcomings
  • Poor predictive ability at off-design conditions
  • Complex geometry, flow separation
  • High accuracy requirements
  • Drag coefficient to 10-4 (i.e. wind tunnels)
  • Production runs with 109 grid points (vs 107
    today) should become commonplace (NIA
    Congressional Report, 2005)

4
Computational Aerospace Design and Analysis
  • Computational Fluid Dynamics (CFD) Successes
  • Preliminary design estimates for various
    conditions
  • Accurate prediction at cruise conditions (no flow
    separation)
  • CFD Shortcomings
  • Poor predictive ability at off-design conditions
  • Complex geometry, flow separation
  • High accuracy requirements
  • Drag coefficient to 10-4 (i.e. wind tunnels)
  • Production runs with 109 grid points (vs 107
    today) should become commonplace (NIA
    Congressional Report, 2005)
  • Drive towards Simulation based Design
  • Design Optimization (20 100 Analyses)
  • Flight envelope simulation (103 106 Analyses)
  • Unsteady Simulations
  • Aeroelastics
  • Digital Flight (simulation of maneuvering vehicle)

5
MOTIVATION
  • CFD computational requirements in aerospace
    vehicle design are essentially insatiable for the
    foreseeable future
  • Addressable through hardware and software
    (algorithmic) advances
  • Recently installed NASA Columbia Supercomputer
    provides quantum leap in agencys/stakeholders
    computing capability
  • Demonstrate advances in state-of-the-art using 2
    production codes on Columbia
  • Cart3D (NASA Ames, NYU)
  • Lower Fidelity, rapid turnaround anaysis
  • NSU3D (ICASE/NASA Langley, U. Wyoming)
  • Higher Fidelity, analysis and design

6
Cart3D Cartesian Mesh Inviscid Flow Simulation
Package
  • Unprecedented level of automation
  • Inviscid analysis package
  • Surface modeling, mesh generation, data
    extraction
  • Insensitive to geometric complexity
  • Aimed at
  • Aerodynamic database generation
  • Parametric studies
  • Preliminary design
  • Wide dissemination
  • NASA, DoD, DOE, Intel Agencies
  • US Aerospace industry, commercial and general
    aviation

Mesh Generation
Domain Decomposition
Flow solution
Parametric Analysis
7
Multigrid Scheme Fast O(N) Convergence
8
  • Space-Filling-Curve based partitioner and mesh
    coarsener
  • Each subdomain has own local grid hierarchy
  • Good (not perfect) nesting favor load balance
    at each level
  • Restrict use of OpenMP constructs - Use MPI-like
    architecture
  • Exchange via structure copy (OpenMP),
    send/receive (MPI)

Each subdomain resides in processor local memory
Cart3D Solver programming paradigm
Explicit subdomain communication
9
Flight-Envelope Data-Base Generation (parametric
analysis)
  • Configuration space
  • Vary geometric parameters
  • Control surface deflection
  • Shape optimization
  • Requires remeshing
  • Wind-Space Parameters
  • Vary wind vector
  • Mach, aincidence, bsideslip
  • No remeshing
  • Completely Automated
  • Hierarchical Job launching, scheduling
  • Data retrieval

10
Aerodynamic Database Generation
Parametric Analysis
11
Flight-Envelope Data-Base Generation (parametric
analysis)
  • Configuration space
  • Vary geometric parameters
  • Control surface deflection
  • Shape optimization
  • Requires remeshing
  • Wind-Space Parameters
  • Vary wind vector
  • Mach, aincidence, bsideslip
  • No remeshing
  • Completely Automated
  • Hierarchical Job launching, scheduling
  • Data retrieval

12
 Wind-Space M8 0.2-6.0, a -530, b
030  P has dimensions (38 x 25 x 5)  2900
simulations
Liquid glide-back booster - Crank delta
wing, canards, tail Wind-space only
Database Generation
parametric Analysis Wind-Space
13
 Wind-Space M8 0.2-6.0, a -530, b
030  P has dimensions (38 x 25 x 5)  2900
simulations
Liquid glide-back booster - Crank delta
wing, canards, tail Wind-space only
  • Typically smaller resolution runs
  • 32-64 cpus each
  • Farmed out simultaneously (PBS)
  • 2900 simulations

14
 Wind-Space M8 0.2-6.0, a -530, b
030  P has dimensions (38 x 25 x 5)  2900
simulations
Liquid glide-back booster - Crank delta
wing, canards, tail Wind-space only
  • Need for higher resolution simulations
  • - Selected data-base points
  • - General drive to higher accuracy
  • Good large cpu count scalability important

15
NSU3D Unstructured Navier-Stokes Solver
  • High fidelity viscous analysis
  • Resolves thin boundary layer to wall
  • O(10-6) normal spacing
  • Stiff discrete equations to solve
  • Suite of turbulence models available
  • High accuracy objective 0.01 Cd
  • 50-100 times cost of inviscid analysis (Cart3D)
  • Unstructured mixed element grids for complex
    geometries
  • VGRID NASA Langley
  • Production use in commercial, general aviation
    industry
  • Extension to Design Optimization and Unsteady
    Simulations

16
Agglomeration Multigrid
  • Agglomeration Multigrid solvers for unstructured
    meshes
  • Coarse level meshes constructed by agglomerating
    fine grid cells/equations

17
Agglomeration Multigrid
  • Automated Graph-Based Coarsening Algorithm
  • Coarse Levels are Graphs
  • Coarse Level Operator by Galerkin Projection
  • Grid independent convergence rates (order of
    magnitude improvement)

18
Anisotropy Induced Stiffness
  • Convergence rates for RANS (viscous) problems
    much slower then inviscid flows
  • Mainly due to grid stretching
  • Thin boundary and wake regions
  • Mixed element (prism-tet) grids
  • Use directional solver to relieve stiffness
  • Line solver in anisotropic regions

19
Method of Solution
  • Line-implicit solver

20
Parallelization through Domain Decomposition
  • Intersected edges resolved by ghost vertices
  • Generates communication between original and
    ghost vertex
  • Handled using MPI and/or OpenMP (Hybrid
    implementation)
  • Local reordering within partition for
    cache-locality
  • Multigrid levels partitioned independently
  • Match levels using greedy algorithm
  • Optimize intra-grid communication vs inter-grid
    communication

21
Partitioning
  • (Block) Tridiagonal Lines solver inherently
    sequential
  • Contract graph along implicit lines
  • Weight edges and vertices
  • Partition contracted graph
  • Decontract graph
  • Guaranteed lines never broken
  • Possible small increase in imbalance/cut edges

22
Partitioning Example
  • 32-way partition of 30,562 point 2D grid
  • Unweighted partition 2.6 edges cut, 2.7 lines
    cut
  • Weighted partition 3.2 edges cut, 0 lines cut

23
Hybrid MPI-OMP (NSU3D)
  • MPI master gathers/scatters to OMP threads
  • OMP local thread-to-thread communication occurs
    during MPI Irecv wait time (attempt to overlap)

24
Simulation Strategy
  • NSU3D Isolated high resolution analyses and
    design optimization
  • Cart3D Rapid flight envelope data-base fill-in
  • Examine performance of each code individually on
    Columbia
  • Both codes use customized multigrid solvers
  • Domain-decomposition based parallelism
  • Extensive cache-locality reordering optimization
  • 1.3 to 1.6 Gflops on 1.6GHz Itanium2 cpu (pfmon
    utility)
  • NSU3D Hybrid MPI/OpenMP
  • Cart3D MPI or OpenMP (exclusively)

25
NASA Columbia Supercluster
  • 20 SGI Atix Nodes
  • 512 Itanium2 cpus each
  • 1 Tbyte memory each
  • 1.5Ghz / 1.6Ghz
  • Total 10,240 cpus
  • 3 Interconnects
  • SGI NUMAlink (shared memory in node)
  • Infiniband (across nodes)
  • 10Gig Ethernet (File I/O)
  • Subsystems
  • 8 Nodes Double density Altix 3700BX2
  • 4 Nodes NUMAlink4 interconnect between nodes
  • BX2 Nodes, 1.6GHz cpus

26
NASA Columbia Subsystems
  • 4 Node Altix 3700 BX2
  • 2048 cpus, 1.6GHz, 4 Tbytes RAM
  • NUMAlink4 between all cpus (6.4Gbytes/s)
  • MPI, SHMEM, MLP across all cpus
  • OpenMP (OMP) within a node
  • Infiniband using MPI across all cpus
  • Limited to 1524 mpi processes
  • 8 Node Altix 3700BX2
  • 4096 cpus, 1.6 GHz / 1.5 GHz, 8 Tbytes RAM
  • Infiniband using MPI required for cross-node
    communication
  • Hardware limitation 2048 MPI connections
  • Requires hybrid MPI/OMP to access all cpus
  • 2 OMP threads running under each MPI process
  • Overall well balanced machine
  • 1Gbyte/sec I/O on each node

27
Cart3D Solver Performance
  • Test problem
  • Full Space Shuttle Launch Vehicle
  • Mach 2.6,
  • AoA 2.09 deg
  • Mesh 25 M cells

28
Cart3D Solver Performance
Pressure Contours
  • Test problem
  • Full Space Shuttle Launch Vehicle
  • Mach 2.6,
  • AoA 2.09 deg
  • Mesh 25 M cells

29
Cart3D Solver Performance
Compare OpenMP and MPI
  • Pure OpenMP restricted to single 512 cpu node
  • Ran from 32-504 cpus (node c18)
  • Perfect speed-up assumed on 32 cpus
  • OpenMP show slight beak at 128 cpus due to change
    in global addressing scheme - MPI unaffected (no
    global addressing)
  • MPI achieves 0.75 TFLOP/s on 496 cpus

30
Cart3D Solver Performance
Single Mesh vs Multigrid
  • Used NUMAlink on c17-c20
  • MPI only, from 32-2016 cpus
  • Reducing multigrid de-emphasizes communication
  • Single-grid scalability 1900 on 2016 cpus
  • Coarsest mesh in 4 level multigrid has 16
    cells/partition
  • 4 Level multigrid shows parallel speedups of 1585
    on 2016 cpus

31
Cart3D Solver Performance
Compare NUMAlink Infiniband
  • MPI only, from 32-2016 cpus, 4 Level multigrid
  • 32-496 cpus run on 1 node - (no interconnect)
  • 508-1000 cpus run on 2 nodes
  • 1000-2016 cpus on 4 nodes
  • IB lags due to decrease in delivered bandwidth
  • Delivered bandwidth drops again when going from 2
    to 4 nodes
  • NUMAlink on 2016 cpus achieves over 2.4 TFLOP/s

32
NSU3D TEST CASE
  • Wing-Body Configuration
  • 72 million grid points
  • Transonic Flow
  • Mach0.75, Incidence 0 degrees, Reynolds
    number3,000,000

33
NSU3D Scalability
G F L O P S
  • 72M pt grid
  • Assume perfect speedup on 128 cpus
  • Good scalability up to 2008 using NUMAlink
  • Superlinear !
  • Multigrid slowdown due to coarse grid
    communication
  • 3TFlops on 2008 cpus

34
NSU3D Scalability
  • Best convergence with 6 level multigrid scheme
  • Importance of fastest overall solution strategy
  • 5 level Multigrid
  • 10 minutes wall clock time for steady-state
    solution on 72M pt grid

35
NUMAlink vs. Infiniband (IB)
  • IB required for gt 2048 cpus
  • Hybrid MPI/OMP required due to MPI limitation
    under IB
  • Slight drop-off using IB
  • Additional penalty with increasing OMP Threads
  • (locally) sequential nature during mpi to mpi
    communication

128 cpu run split across 4 hosts
36
NUMAlink vs. Infiniband (IB)
Single Grid (no multigrid)
  • 2 OMP required for IB on 2048
  • Excellent scalability for single grid solver (non
    multigrid)

37
NUMAlink vs. Infiniband (IB)
6 level multigrid
  • 2 OMP required for IB on 2048
  • Dramatic drop-off for 6 level multigrid

38
NUMAlink vs. Infiniband(IB)
5 level multigrid
  • 2 OMP required for IB on 2048
  • Dramatic drop-off for 5 level multigrid

39
NUMAlink vs. Infiniband(IB)
4 level multigrid
  • 2 OMP required for IB on 2048
  • Dramatic drop-off for 4 level multigrid

40
NUMAlink vs. Infiniband(IB)
3 level multigrid
  • 2 OMP required for IB on 2048
  • Dramatic drop-off for 3 level multigrid

41
NUMAlink vs. Infiniband(IB)
2 level multigrid
  • 2 OMP required for IB on 2048
  • Dramatic drop-off for 2 level multigrid

42
NUMAlink vs. Infiniband(IB)
2nd coarse grid level alone ( lt 1M pts)
  • Similar slowdowns with NUMALINK and Infiniband

43
NUMAlink vs. Infiniband(IB)
  • Inconsistent NUMAlink/Infiniband performance
  • Multigrid IB drop-off not due to coarse grid
    level communication
  • Due to inter-grid communication
  • Not bandwidth related
  • More non-local communication pattern
  • Sensitive to system ENV variable settings
  • Addressable through
  • More local fine to coarse partitioning
  • Multi-level communication strategy

44
Single Grid Performance up to 4016 cpus
First real world application on Columbia using gt
2048 cpus
  • 1 OMP possible for IB on 2008 (8 hosts)
  • 2 OMP required for IB on 4016 (8 hosts)
  • Good scalability up to 4016
  • 5.2 Tflops at 4016

45
Inhomogeneous CPU Set
  • 1.5GHz (6Mbyte L3) cpus vs 1.6GHz (9Mbyte L3)
    cpus
  • Responsible for part of slowdown

46
Concluding Remarks
  • NASAs Columbia Supercomputer enabling advances
    in state-of-the-art for aerospace computing
    applications
  • 100M grid point solutions (turbulent flow) in 15
    minutes
  • Design Optimization overnight (20-100 analyses)
  • Rapid flight envelope data-base generation
  • Time dependent maneuvering solutions
  • Digital Flight

47
Conclusions
  • Much higher resolution analyses possible
  • 72M pts on 4016 cpus? only 18,000 points per cpu
  • 109 Grid points feasible on 2000 cpus
  • Should become routine in future
  • Approximately 4 hour turnaround on Columbia
  • Other bottlenecks must be addressed
  • I/O Files 35 Gbytes for 72M pts -- 400Gbytes for
    109pts
  • Other sequential pre/post processing (i.e. grid
    generation)
  • Requires rethinking entire process
  • On demand parallel grid refinement and load
    balancing
  • Obviates large input files
  • Requires link to CAD database from parallel
    machine

48
Conclusions
  • Columbia Supercomputer Architecture validated on
    real world applications (2 production codes)
  • NUMAlink provides best performance but currently
    limited to 2048 cpus
  • Infiniband practical for very large applications
  • Requires hybrid MPI/OMP communication
  • Issues remain concerning communication patterns
  • Bandwidth adequate for current and larger
    applications
  • Large applications on 8,000 to 10,240 cpus using
    IB and OMP 4 should be feasible and achieve
    12Tflops
  • Special thanks to Bob Ciotti (NASA), Bron
    Nelson (SGI)
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