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1 Lecture 24: Multiprocessors Today’s topics:  Directory-based cache coherence protocol  Synchronization  Consistency  Writing parallel programs Reminder:

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Presentation on theme: "1 Lecture 24: Multiprocessors Today’s topics:  Directory-based cache coherence protocol  Synchronization  Consistency  Writing parallel programs Reminder:"— Presentation transcript:

1 1 Lecture 24: Multiprocessors Today’s topics:  Directory-based cache coherence protocol  Synchronization  Consistency  Writing parallel programs Reminder:  Assignment 9 will be posted later today, due in a week  Next Tuesday: recap lecture  Next Thursday: guest lecture by Al Davis on future technologies

2 2 Snooping-Based Protocols Three states for a block: invalid, shared, modified A write is placed on the bus and sharers invalidate themselves The protocols are referred to as MSI, MESI, etc. Processor Caches Processor Caches Processor Caches Processor Caches Main Memory I/O System

3 3 Example P1 reads X: not found in cache-1, request sent on bus, memory responds, X is placed in cache-1 in shared state P2 reads X: not found in cache-2, request sent on bus, everyone snoops this request, cache-1does nothing because this is just a read request, memory responds, X is placed in cache-2 in shared state P1 Cache-1 P2 Cache-2 Main Memory P1 writes X: cache-1 has data in shared state (shared only provides read perms), request sent on bus, cache-2 snoops and then invalidates its copy of X, cache-1 moves its state to modified P2 reads X: cache-2 has data in invalid state, request sent on bus, cache-1 snoops and realizes it has the only valid copy, so it downgrades itself to shared state and responds with data, X is placed in cache-2 in shared state

4 4 Cache Coherence Protocols Directory-based: A single location (directory) keeps track of the sharing status of a block of memory Snooping: Every cache block is accompanied by the sharing status of that block – all cache controllers monitor the shared bus so they can update the sharing status of the block, if necessary  Write-invalidate: a processor gains exclusive access of a block before writing by invalidating all other copies  Write-update: when a processor writes, it updates other shared copies of that block

5 5 Coherence in Distributed Memory Multiprocs Distributed memory systems are typically larger  bus-based snooping may not work well Option 1: software-based mechanisms – message-passing systems or software-controlled cache coherence Option 2: hardware-based mechanisms – directory-based cache coherence

6 6 Distributed Memory Multiprocessors Processor & Caches MemoryI/O Processor & Caches MemoryI/O Processor & Caches MemoryI/O Processor & Caches MemoryI/O Interconnection network Directory

7 7 Directory-Based Cache Coherence The physical memory is distributed among all processors The directory is also distributed along with the corresponding memory The physical address is enough to determine the location of memory The (many) processing nodes are connected with a scalable interconnect (not a bus) – hence, messages are no longer broadcast, but routed from sender to receiver – since the processing nodes can no longer snoop, the directory keeps track of sharing state

8 8 Cache Block States What are the different states a block of memory can have within the directory? Note that we need information for each cache so that invalidate messages can be sent The directory now serves as the arbitrator: if multiple write attempts happen simultaneously, the directory determines the ordering

9 9 Directory-Based Example Processor & Caches MemoryI/O Processor & Caches MemoryI/O Processor & Caches MemoryI/O Interconnection network Directory X Directory Y A: Rd X B: Rd X C: Rd X A: Wr X C: Wr X B: Rd X A: Rd X A: Rd Y B: Wr X B: Rd Y B: Wr X B: Wr Y

10 10 Directory Actions If block is in uncached state:  Read miss: send data, make block shared  Write miss: send data, make block exclusive If block is in shared state:  Read miss: send data, add node to sharers list  Write miss: send data, invalidate sharers, make excl If block is in exclusive state:  Read miss: ask owner for data, write to memory, send data, make shared, add node to sharers list  Data write back: write to memory, make uncached  Write miss: ask owner for data, write to memory, send data, update identity of new owner, remain exclusive

11 11 Constructing Locks Applications have phases (consisting of many instructions) that must be executed atomically, without other parallel processes modifying the data A lock surrounding the data/code ensures that only one program can be in a critical section at a time The hardware must provide some basic primitives that allows us to construct locks with different properties Bank balance $1000 Rd $1000 Add $100 Wr $1100 Rd $1000 Add $200 Wr $1200 Parallel (unlocked) banking transactions

12 12 Synchronization The simplest hardware primitive that greatly facilitates synchronization implementations (locks, barriers, etc.) is an atomic read-modify-write Atomic exchange: swap contents of register and memory Special case of atomic exchange: test & set: transfer memory location into register and write 1 into memory (if memory has 0, lock is free) lock: t&s register, location bnz register, lock CS st location, #0 When multiple parallel threads execute this code, only one will be able to enter CS

13 13 Coherence Vs. Consistency Recall that coherence guarantees (i) write propagation (a write will eventually be seen by other processors), and (ii) write serialization (all processors see writes to the same location in the same order) The consistency model defines the ordering of writes and reads to different memory locations – the hardware guarantees a certain consistency model and the programmer attempts to write correct programs with those assumptions

14 14 Consistency Example Consider a multiprocessor with bus-based snooping cache coherence and a write buffer between CPU and cache Initially A = B = 0 P1 P2 A  1 B  1 … … if (B == 0) if (A == 0) Crit.Section Crit.Section The programmer expected the above code to implement a lock – because of write buffering, both processors can enter the critical section The consistency model lets the programmer know what assumptions they can make about the hardware’s reordering capabilities

15 15 Sequential Consistency A multiprocessor is sequentially consistent if the result of the execution is achieveable by maintaining program order within a processor and interleaving accesses by different processors in an arbitrary fashion The multiprocessor in the previous example is not sequentially consistent Can implement sequential consistency by requiring the following: program order, write serialization, everyone has seen an update before a value is read – very intuitive for the programmer, but extremely slow

16 16 Shared-Memory Vs. Message-Passing Shared-memory: Well-understood programming model Communication is implicit and hardware handles protection Hardware-controlled caching Message-passing: No cache coherence  simpler hardware Explicit communication  easier for the programmer to restructure code Software-controlled caching Sender can initiate data transfer

17 17 Ocean Kernel Procedure Solve(A) begin diff = done = 0; while (!done) do diff = 0; for i  1 to n do for j  1 to n do temp = A[i,j]; A[i,j]  0.2 * (A[i,j] + neighbors); diff += abs(A[i,j] – temp); end for if (diff < TOL) then done = 1; end while end procedure

18 18 Shared Address Space Model int n, nprocs; float **A, diff; LOCKDEC(diff_lock); BARDEC(bar1); main() begin read(n); read(nprocs); A  G_MALLOC(); initialize (A); CREATE (nprocs,Solve,A); WAIT_FOR_END (nprocs); end main procedure Solve(A) int i, j, pid, done=0; float temp, mydiff=0; int mymin = 1 + (pid * n/procs); int mymax = mymin + n/nprocs -1; while (!done) do mydiff = diff = 0; BARRIER(bar1,nprocs); for i  mymin to mymax for j  1 to n do … endfor LOCK(diff_lock); diff += mydiff; UNLOCK(diff_lock); BARRIER (bar1, nprocs); if (diff < TOL) then done = 1; BARRIER (bar1, nprocs); endwhile

19 19 Message Passing Model main() read(n); read(nprocs); CREATE (nprocs-1, Solve); Solve(); WAIT_FOR_END (nprocs-1); procedure Solve() int i, j, pid, nn = n/nprocs, done=0; float temp, tempdiff, mydiff = 0; myA  malloc(…) initialize(myA); while (!done) do mydiff = 0; if (pid != 0) SEND(&myA[1,0], n, pid-1, ROW); if (pid != nprocs-1) SEND(&myA[nn,0], n, pid+1, ROW); if (pid != 0) RECEIVE(&myA[0,0], n, pid-1, ROW); if (pid != nprocs-1) RECEIVE(&myA[nn+1,0], n, pid+1, ROW); for i  1 to nn do for j  1 to n do … endfor if (pid != 0) SEND(mydiff, 1, 0, DIFF); RECEIVE(done, 1, 0, DONE); else for i  1 to nprocs-1 do RECEIVE(tempdiff, 1, *, DIFF); mydiff += tempdiff; endfor if (mydiff < TOL) done = 1; for i  1 to nprocs-1 do SEND(done, 1, I, DONE); endfor endif endwhile

20 20 Title Bullet

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