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Chapter 8-2 : Multicomputers

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Title: Chapter 8-2 : Multicomputers

1
Chapter 8-2 Multicomputers

2
Multicomputers

Multiprocessors share the common memory
Multicomputers are tightly coupled CPUs with
memories of their own and do not share them
These systems are also known as cluster computers
and COWS (Clusters of Workstations)
The secret of high performance is the
interconnection network

3
Multiprocessor vs Multicomputer

4
Interconnection Topologies

Figure 8-16. Various interconnect topologies.
(a) A single switch (b) A ring (c) A grid or
mesh (d) A double torus (e) A cube (f) A 4D
hypercube
Note A diameter is defined as the longest path
between any two nodes

5
Switching Schemes

Store-and-forward packet switching messages are
broken into packets. Packets move from one switch
to another
This scheme has increasing latency (delay)
problem because of store-and-forwarding in
intermediate switches
Circuit switching a path is established from
the source to the destination. Once this path is
setup bits are pumped from source to destination
with no buffering in the intermediate switches
Circuit setup may need some time but then the
transfer is fast

6
User Level Communication Software

Multicomputers communicate through messages
Send(dest, mptr) send a message pointed by
mptr to a process identified by dest
Receive(addr, mptr) addr is usually CPU number
and a process or port number
Send calls can be blocked or nonblocked
Receive calls are always blocked. That is, the
receiving process has to wait if the message has
not been sent before

7
Blocking Calls

8
Nonblocking Calls

9
Remote Procedure Call

Figure 8-20. Steps in making a remote procedure
call.
The stubs are local procedures implementing the
interface between the client and the server
Parameter and result passing are done by messages

10
Distributed Shared Memory (1)

Figure 8-21. Various layers where shared memory
can be implemented (a) The hardware (b) The
operating system (c) User-level software

11
Distributed Shared Memory (2)

Figure 8-22. (a) Pages of the address space
distributed among four machines.
When a CPU references an address that is not
local, a trap occurs, and the DSM software
fetches the page containing the address and
restarts the faulting instruction

12
Distributed Shared Memory (3)

Figure 8-22. (b) Situation after CPU 0
references page 10 and the page is moved there.

13
Distributed Shared Memory (4)

14
Multicomputer Scheduling

On a multiprocessor, all processes reside on the
shared memory
On a multicomputer each node has its own memory
and its own set of processes
Scheduling within a node is easier but allocation
of processes to nodes is much more important
(load balancing)
The algorithms and heuristics for doing this
assignment are known as processor allocation
algorithms

15
Scheduling Algorithms

16
Virtualization

Virtualization is the virtual machine concept
introduced in Chapter 1 Introduction
VM technology allows a single computer to host
multiple virtual machines, each potentially
running a different operating system
Advantages
Failure in one VM does not automatically bring
down any others since VMs are isolated
Fewer machines to provide an environment for
different applications (instead of having one
server for each of the different apllications, a
server with VMs can do the job)
Ability to run different and probably older
versions of Oss needed by some appications

17
Virtualization Methods