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378 lines
10 KiB
378 lines
10 KiB
#include <windows.h>
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#include <stdio.h>
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#include <stdlib.h>
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//
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// - hStartOfRace is a manual reset event that is signalled when
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// all of the threads are supposed to cut loose and begin working
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//
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// - hEndOfRace is a manual reset event that is signalled once the end time
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// has been retrieved and it is ok for the threads to exit
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//
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HANDLE hStartOfRace;
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HANDLE hEndOfRace;
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#define MAX_THREADS 32
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//
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// - ThreadReadyDoneEvents are an array of autoclearing events. The threads
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// initially signal these events once they have reached their start routines
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// and are ready to being processing. Once they are done processing, they
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// signal thier event to indicate that they are done processing.
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//
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// - ThreadHandles are an array of thread handles to the worker threads. The
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// main thread waits on these to know when all of the threads have exited.
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//
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HANDLE ThreadReadyDoneEvents[MAX_THREADS];
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HANDLE ThreadHandles[MAX_THREADS];
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//
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// Each thread has a THREAD_WORK structure. This contains the address
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// of the cells that this thread is responsible for, and the number of
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// cells it is supposed to process.
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//
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typedef struct _THREAD_WORK {
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PDWORD CellVector;
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DWORD NumberOfCells;
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DWORD RecalcResult;
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} THREAD_WORK, *PTHREAD_WORK;
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THREAD_WORK ThreadWork[MAX_THREADS];
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#define ONE_MB (1024*1024)
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DWORD Mb = 4;
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DWORD NumberOfThreads = 1;
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DWORD ExpectedRecalcValue;
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DWORD ActualRecalcValue;
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DWORD ContentionValue;
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BOOL fMemoryContention;
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DWORD WorkerThread(PVOID ThreadIndex);
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int __cdecl
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main(
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int argc,
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char *argv[],
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char *envp[]
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)
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{
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DWORD StartTicks, EndTicks;
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DWORD i;
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BOOL fShowUsage;
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char c, *p, *whocares;
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PDWORD CellVector;
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DWORD NumberOfDwords;
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DWORD DwordsPerThread;
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DWORD ThreadId;
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LPSTR Answer;
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fShowUsage = FALSE;
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fMemoryContention = FALSE;
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if (argc <= 1) {
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goto showUsage;
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}
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while (--argc) {
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p = *++argv;
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if (*p == '/' || *p == '-') {
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while (c = *++p)
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switch (toupper( c )) {
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case '?':
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fShowUsage = TRUE;
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goto showUsage;
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break;
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case 'M':
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if (!argc--) {
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fShowUsage = TRUE;
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goto showUsage;
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}
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argv++;
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Mb = strtoul(*argv,&whocares,10);
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break;
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case 'C':
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fMemoryContention = TRUE;
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break;
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case 'T':
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if (!argc--) {
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fShowUsage = TRUE;
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goto showUsage;
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}
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argv++;
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NumberOfThreads = strtoul(*argv,&whocares,10);
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if ( NumberOfThreads > MAX_THREADS ) {
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fShowUsage = TRUE;
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goto showUsage;
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}
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break;
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default:
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fprintf( stderr, "MTBNCH: Invalid switch - /%c\n", c );
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goto showUsage;
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break;
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}
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}
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}
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showUsage:
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if ( fShowUsage ) {
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fprintf(stderr,"usage: MTBNCH\n" );
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fprintf(stderr," [-?] display this message\n" );
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fprintf(stderr," [-t n] use n threads for benchmark (less than 32)\n" );
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fprintf(stderr," [-m n] use an n Mb spreadsheet size (default 4)\n" );
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fprintf(stderr," [-c] cause memory contention on each loop iteration\n" );
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ExitProcess(1);
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}
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//
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// Prepare the race events. These are manual reset events.
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//
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hStartOfRace = CreateEvent(NULL,TRUE,FALSE,NULL);
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hEndOfRace = CreateEvent(NULL,TRUE,FALSE,NULL);
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if ( !hStartOfRace || !hEndOfRace ) {
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fprintf(stderr,"MTBNCH: Race Event Creation Failed\n");
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ExitProcess(1);
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}
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//
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// Prepare the ready done events. These are auto clearing events
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//
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for(i=0; i<NumberOfThreads; i++ ) {
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ThreadReadyDoneEvents[i] = CreateEvent(NULL,FALSE,FALSE,NULL);
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if ( !ThreadReadyDoneEvents[i] ) {
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fprintf(stderr,"MTBNCH: Ready Done Event Creation Failed %d\n",GetLastError());
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ExitProcess(1);
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}
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}
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//
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// Allocate and initialize the CellVector
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//
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CellVector = (PDWORD)VirtualAlloc(NULL,Mb*ONE_MB,MEM_COMMIT,PAGE_READWRITE);
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if ( !CellVector ) {
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fprintf(stderr,"MTBNCH: Cell Vector Allocation Failed %d\n",GetLastError());
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ExitProcess(1);
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}
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NumberOfDwords = (Mb*ONE_MB) / sizeof(DWORD);
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DwordsPerThread = NumberOfDwords / NumberOfThreads;
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//
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// Initialize the Cell Vector
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//
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for(i=0, ExpectedRecalcValue; i<NumberOfDwords; i++ ){
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ExpectedRecalcValue += i;
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CellVector[i] = i;
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}
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//
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// Partition the work to the worker threads
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//
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for(i=0; i<NumberOfThreads; i++ ){
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ThreadWork[i].CellVector = &CellVector[i*DwordsPerThread];
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ThreadWork[i].NumberOfCells = DwordsPerThread;
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NumberOfDwords -= DwordsPerThread;
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//
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// If we have a remainder, give the remaining work to the last thread
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//
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if ( NumberOfDwords < DwordsPerThread ) {
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ThreadWork[i].NumberOfCells += NumberOfDwords;
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}
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}
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//
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// Create the worker threads
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//
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for(i=0; i<NumberOfThreads; i++ ) {
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ThreadHandles[i] = CreateThread(
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NULL,
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0,
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WorkerThread,
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(PVOID)i,
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0,
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&ThreadId
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);
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if ( !ThreadHandles[i] ) {
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fprintf(stderr,"MTBNCH: Worker Thread Creation Failed %d\n",GetLastError());
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ExitProcess(1);
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}
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}
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//
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// All of the worker threads will signal thier ready done event
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// when they are idle and ready to proceed. Once all events have been
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// set, then setting the hStartOfRaceEvent will begin the recalc
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//
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i = WaitForMultipleObjects(
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NumberOfThreads,
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ThreadReadyDoneEvents,
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TRUE,
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INFINITE
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);
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if ( i == WAIT_FAILED ) {
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fprintf(stderr,"MTBNCH: Wait for threads to stabalize Failed %d\n",GetLastError());
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ExitProcess(1);
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}
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//
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// Everthing is set to begin the recalc operation
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//
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StartTicks = GetTickCount();
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if ( !SetEvent(hStartOfRace) ) {
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fprintf(stderr,"MTBNCH: SetEvent(hStartOfRace) Failed %d\n",GetLastError());
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ExitProcess(1);
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}
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//
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// Now just wait for the recalc to complete
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//
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i = WaitForMultipleObjects(
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NumberOfThreads,
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ThreadReadyDoneEvents,
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TRUE,
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INFINITE
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);
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if ( i == WAIT_FAILED ) {
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fprintf(stderr,"MTBNCH: Wait for threads to complete Failed %d\n",GetLastError());
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ExitProcess(1);
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}
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//
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// Now pick up the individual recalc values
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//
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for(i=0, ActualRecalcValue = 0; i<NumberOfThreads; i++ ){
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ActualRecalcValue += ThreadWork[i].RecalcResult;
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}
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EndTicks = GetTickCount();
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if ( fMemoryContention ) {
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if ( ContentionValue == (Mb*ONE_MB) / sizeof(DWORD) ) {
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if ( ActualRecalcValue == ExpectedRecalcValue ) {
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Answer = "Correct";
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}
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else {
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Answer = "Recalc Failure";
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}
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}
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else {
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Answer = "Contention Failure";
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}
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}
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else {
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if ( ActualRecalcValue == ExpectedRecalcValue ) {
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Answer = "Correct";
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}
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else {
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Answer = "Recalc Failure";
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}
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}
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fprintf(stdout,"MTBNCH: %d Thread Recalc complete in %dms, Answer = %s\n",
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NumberOfThreads,
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EndTicks-StartTicks,
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Answer
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);
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ExitProcess(2);
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}
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//
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// The worker threads perform the recalc operation on their
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// assigned cells. They begin by setting their ready done event
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// to indicate that they are ready to begin the recalc. Then they
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// wait until the hStartOfRace event is signaled. Once this occurs, they
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// do their part of the recalc and when done they signal their ready done
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// event and then wait on the hEndOfRaceEvent
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//
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DWORD
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WorkerThread(
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PVOID ThreadIndex
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)
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{
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DWORD Me;
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PDWORD MyCellVectorBase;
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PDWORD CurrentCellVector;
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DWORD MyRecalcValue;
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DWORD MyNumberOfCells;
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DWORD i;
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BOOL MemoryContention;
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Me = (DWORD)ThreadIndex;
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MyRecalcValue = 0;
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MyCellVectorBase = ThreadWork[Me].CellVector;
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MyNumberOfCells = ThreadWork[Me].NumberOfCells;
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MemoryContention = fMemoryContention;
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//
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// Signal that I am ready to go
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//
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if ( !SetEvent(ThreadReadyDoneEvents[Me]) ) {
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fprintf(stderr,"MTBNCH: (1) SetEvent(ThreadReadyDoneEvent[%d]) Failed %d\n",Me,GetLastError());
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ExitProcess(1);
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}
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//
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// Wait for the master to release us to do the recalc
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//
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i = WaitForSingleObject(hStartOfRace,INFINITE);
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if ( i == WAIT_FAILED ) {
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fprintf(stderr,"MTBNCH: Thread %d Wait for start of recalc Failed %d\n",Me,GetLastError());
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ExitProcess(1);
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}
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//
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// perform the recalc operation
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//
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for (i=0, CurrentCellVector = MyCellVectorBase; i<MyNumberOfCells; i++ ) {
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MyRecalcValue += *CurrentCellVector++;
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if ( MemoryContention ) {
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InterlockedIncrement(&ContentionValue);
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}
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}
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ThreadWork[Me].RecalcResult = MyRecalcValue;
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//
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// Signal that I am done and then wait for further instructions
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//
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if ( !SetEvent(ThreadReadyDoneEvents[Me]) ) {
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fprintf(stderr,"MTBNCH: (2) SetEvent(ThreadReadyDoneEvent[%d]) Failed %d\n",Me,GetLastError());
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ExitProcess(1);
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}
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i = WaitForSingleObject(hEndOfRace,INFINITE);
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if ( i == WAIT_FAILED ) {
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fprintf(stderr,"MTBNCH: Thread %d Wait for end of recalc Failed %d\n",Me,GetLastError());
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ExitProcess(1);
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}
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return MyRecalcValue;
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}
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