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Networks of Workstations

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Networks of Workstations Prabhaker Mateti Wright State University Overview Parallel computers Concurrent computation Parallel Methods Message Passing Distributed ... – PowerPoint PPT presentation

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Title: Networks of Workstations


1
Networks of Workstations
  • Prabhaker Mateti
  • Wright State University

2
Overview
  • Parallel computers
  • Concurrent computation
  • Parallel Methods
  • Message Passing
  • Distributed Shared Memory
  • Programming Tools
  • Cluster configurations

3
Granularity of Parallelism
  • Fine-Grained Parallelism
  • Medium-Grained Parallelism
  • Coarse-Grained Parallelism
  • NOWs (Networks of Workstations)

4
Fine-Grained Machines
  • Tens of thousands of Processors
  • Processors
  • Slow (bit serial)
  • Small (K bits of RAM)
  • Distributed Memory
  • Interconnection Networks
  • Message Passing
  • Single Instruction Multiple Data (SIMD)

5
Sample Meshes
  • Massively Parallel Processor (MPP)
  • TMC CM-2 (Connection Machine)
  • MasPar MP-1/2

6
Medium-Grained Machines
  • Typical Configurations
  • Thousands of processors
  • Processors have power between coarse- and
    fine-grained
  • Either shared or distributed memory
  • Traditionally Research Machines
  • Single Code Multiple Data (SCMD)

7
Medium-Grained Machines
  • Ex Cray T3E
  • Processors
  • DEC Alpha EV5 (600 MFLOPS peak)
  • Max of 2048
  • Peak Performance 1.2 TFLOPS
  • 3-D Torus
  • Memory 64 MB - 2 GB per CPU

8
Coarse-Grained Machines
  • Typical Configurations
  • Hundreds of Processors
  • Processors
  • Powerful (fast CPUs)
  • Large (cache, vectors, multiple fast buses)
  • Memory Shared or Distributed-Shared
  • Multiple Instruction Multiple Data (MIMD)

9
Coarse-Grained Machines
  • SGI Origin 2000
  • PEs (MIPS R10000) Max of 128
  • Peak Performance 49 Gflops
  • Memory 256 GBytes
  • Crossbar switches for interconnect
  • HP/Convex Exemplar
  • PEs (HP PA-RISC 8000) Max of 64
  • Peak Performance 46 Gflops
  • Memory Max of 64 GBytes
  • Distributed crossbar switches for interconnect

10
Networks of Workstations
  • Exploit inexpensive Workstations/PCs
  • Commodity network
  • The NOW becomes a distributed memory
    multiprocessor
  • Workstations sendreceive messages
  • C and Fortran programs with PVM, MPI, etc.
    libraries
  • Programs developed on NOWs are portable to
    supercomputers for production runs

11
Parallel Computing
  • Concurrent Computing
  • Distributed Computing
  • Networked Computing
  • Parallel Computing

12
Definition of Parallel
  • S1 begins at time b1, ends at e1
  • S2 begins at time b2, ends at e2
  • S1 S2
  • Begins at min(b1, b2)
  • Ends at max(e1, e2)
  • Equiv to S2 S1

13
Data Dependency
  • x a b y c d
  • x a b y c d
  • y c d x a b
  • X depends on a and b, y depends on c and d
  • Assumed a, b, c, d were independent

14
Types of Parallelism
  • Result
  • Specialist
  • Agenda

15
Perfect Parallelism
  • Also called
  • Embarrassingly Parallel
  • Result parallel
  • Computations that can be subdivided into sets of
    independent tasks that require little or no
    communication
  • Monte Carlo simulations
  • F(x, y, z)

16
MW Model
  • Manager
  • Initiates computation
  • Tracks progress
  • Handles workers requests
  • Interfaces with user
  • Workers
  • Spawned and terminated by manager
  • Make requests to manager
  • Send results to manager

17
Reduction
  • Combine several sub-results into one
  • Reduce r1 r2 rn with op
  • Becomes r1 op r2 op op rn

18
Data Parallelism
  • Also called
  • Domain Decomposition
  • Specialist
  • Same operations performed on many data elements
    simultaneously
  • Matrix operations
  • Compiling several files

19
Control Parallelism
  • Different operations performed simultaneously on
    different processors
  • E.g., Simulating a chemical plant one processor
    simulates the preprocessing of chemicals, one
    simulates reactions in first batch, another
    simulates refining the products, etc.

20
Process communication
  • Shared Memory
  • Message Passing

21
Shared Memory
  • Process A writes to a memory location
  • Process B reads from that memory location
  • Synchronization is crucial
  • Excellent speed

22
Shared Memory
  • Needs hardware support
  • multi-ported memory
  • Atomic operations
  • Test-and-Set
  • Semaphores

23
Shared Memory Semantics Assumptions
  • Global time is available. Discrete increments.
  • Shared variable s, vi at ti, i0,
  • Process A s v1 at time t1
  • Assume no other assignment occurred after t1.
  • Process B reads s at time t and gets value v.

24
Shared Memory Semantics
  • Value of Shared Variable
  • v v1, if t gt t1
  • v v0, if t lt t1
  • v ??, if t t1
  • t t1 - discrete quantum
  • Next Update of Shared Variable
  • Occurs at t2
  • t2 t1 ?

25
Condition Variables and Semaphores
  • Semaphores
  • V(s) lt s s 1 gt
  • P(s) ltwhen s gt 0 do s s 1gt
  • Condition variables
  • C.wait()
  • C.signal()

26
Distributed Shared Memory
  • A common address space that all the computers in
    the cluster share.
  • Difficult to describe semantics.

27
Distributed Shared Memory Issues
  • Distributed
  • Spatially
  • LAN
  • WAN
  • No global time available

28
Messages
  • Messages are sequences of bytes moving between
    processes
  • The sender and receiver must agree on the type
    structure of values in the message
  • Marshalling of data

29
Message Passing
  • Process A sends a data buffer as a message to
    process B.
  • Process B waits for a message from A, and when it
    arrives copies it into its own local memory.
  • No memory shared between A and B.

30
Message Passing
  • Obviously,
  • Messages cannot be received before they are sent.
  • A receiver waits until there is a message.
  • Asynchronous
  • Sender never blocks, even if infinitely many
    messages are waiting to be received
  • Semi-asynchronous is a practical version of above
    with large but finite amount of buffering

31
Message Passing Point to Point
  • Q send(m, P)
  • Send message M to process P
  • P recv(x, Q)
  • Receive message from process P, and place it in
    variable x
  • The message data
  • Type of x must match that of m
  • As if x m

32
Broadcast
  • One sender, multiple receivers
  • Not all receivers may receive at the same time

33
Types of Sends
  • Synchronous
  • Asynchronous

34
Synchronous Message Passing
  • Sender blocks until receiver is ready to receive.
  • Cannot send messages to self.
  • No buffering.

35
Message Passing Speed
  • Speed not so good
  • Sender copies message into system buffers.
  • Message travels the network.
  • Receiver copies message from system buffers into
    local memory.
  • Special virtual memory techniques help.

36
Message Passing Programming
  • Less error-prone cf. shared memory

37
Message Passing Synchronization
  • Synchronous MP
  • Sender waits until receiver is ready.
  • No intermediary buffering

38
Barrier Synchronization
  • Processes wait until all arrive

39
Parallel Software Development
  • Algorithmic conversion by compilers

40
Development of DistributedParallel Programs
  • New code algorithms
  • Old programs rewritten
  • in new languages that have distributed and
    parallel primitives
  • With new libraries
  • Parallelize legacy code

41
Conversion of Legacy Software
  • Mechanical conversion by software tools
  • Reverse engineer its design, and re-code

42
Automatically parallelizing compilers
  • Compilers analyze programs and parallelize
    (usually loops).Easy to use, but with limited
    success

43
OpenMP on Networks of Workstations
  • The OpenMP is an API for shared memory
    architectures.
  • User-gives hints as directives to the compiler
  • http//www.openmp.org

44
Message Passing Libraries
  • Programmer is responsible for data distribution,
    synchronizations, and sending and receiving
    information
  • Parallel Virtual Machine (PVM)
  • Message Passing Interface (MPI)
  • BSP

45
BSP Bulk Synchronous Parallel model
  • Divides computation into supersteps
  • In each superstep a processor can work on local
    data and send messages.
  • At the end of the superstep, a barrier
    synchronization takes place and all processors
    receive the messages which were sent in the
    previous superstep
  • http//www.bsp-worldwide.org/

46
BSP Library
  • Small number of subroutines to implement
  • process creation,
  • remote data access, and
  • bulk synchronization.
  • Linked to C, Fortran, programs

47
Parallel Languages
  • Shared-memory languages
  • Parallel object-oriented languages
  • Parallel functional languages
  • Concurrent logic languages

48
Tuple Space Linda
  • ltv1, v2, , vkgt
  • Atomic Primitives
  • In (t)
  • Read (t)
  • Out (t)
  • Eval (t)
  • Host language e.g., JavaSpaces

49
Data Parallel Languages
  • Data is distributed over the processors as a
    arrays
  • Entire arrays are manipulated
  • A(1100) B(1100) C(1100)
  • Compiler generates parallel code
  • Fortran 90
  • High Performance Fortran (HPF)

50
Parallel Functional Languages
  • Erlang http//www.erlang.org/
  • SISAL http//www.llnl.gov/sisal/
  • PCN Argonne

51
Clusters

52
Buildings-Full of Workstations
  • Distributed OS have not taken a foot hold.
  • Powerful personal computers are ubiquitous.
  • Mostly idle more than 90 of the up-time?
  • 100 Mb/s LANs are common.
  • Windows and Linux are the top two OS in terms of
    installed base.

53
Cluster Configurations
  • NOW -- Networks of Workstations
  • COW -- Clusters of Dedicated Nodes
  • Clusters of Come-and-Go Nodes
  • Beowulf clusters

54
Beowulf
  • Collection of compute nodes
  • Full trust in each other
  • Login from one node into another without
    authentication
  • Shared file system subtree
  • Dedicated

55
Close Cluster Configuration
High Speed Network
High Speed Network
File Server node
compute node
compute node
compute node
compute node
compute node
compute node
compute node
compute node
Service Network
Front-end
Front-end
gateway node
gateway node
External Network
External Network
56
Open Cluster Configuration
High Speed Network
File Server node
compute node
compute node
compute node
compute node
compute node
compute node
compute node
compute node
Front-end
External Network
57
Interconnection Network
  • Most popular Fast Ethernet
  • Network topologies
  • Mesh
  • Torus
  • Switch v Hub

58
Software Components
  • Operating System
  • Linux, FreeBSD,
  • Parallel programming
  • PVM, MPI
  • Utilities,
  • Open source

59
Software Structure of PC Cluster
60
Single System View
  • Single system view
  • Common filesystem structure view from any node
  • Common accounts on all nodes
  • Single software installation point
  • Benefits
  • Easy to install and maintain system
  • Easy to use for users

61
Installation Steps
  • Install Operating system
  • Setup a Single System View
  • Shared filesystem
  • Common accounts
  • Single software installation point
  • Install parallel programming packages such as
    MPI, PVM, BSP
  • Install utilities, libraries, and applications

62
Linux Installation
  • Linux has many distributions Redhat, Caldera,
    SuSe, Debian,
  • Caldera is easy to install
  • All above upgrade with RPM package management
  • Mandrake and SuSe come with a very complete set
    of software

63
Clusters with Part Time Nodes
  • Cycle Stealing Running of jobs on a workstation
    that don't belong to the owner.
  • Definition of Idleness E.g., No keyboard and no
    mouse activity
  • Tools/Libraries
  • Condor
  • PVM
  • MPI

64
Migration of Jobs
  • Policies
  • Immediate-Eviction
  • Pause-and-Migrate
  • Technical Issues
  • Checkpointing Preserving the state of the
    process so it can be resumed.
  • Migrating from one architecture to another

65
Summary
  • Parallel
  • computers
  • computation
  • Parallel Methods
  • Communication primitives
  • Message Passing
  • Distributed Shared Memory
  • Programming Tools
  • Cluster configurations
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