190 lines
4.4 KiB
C
190 lines
4.4 KiB
C
/*
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* rwlock7.c
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*
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* Hammer on a bunch of rwlocks to test robustness and fairness.
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* Printed stats should be roughly even for each thread.
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*/
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#include "test.h"
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#include <sys/time.h>
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#include <sys/timeb.h>
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#ifdef __GNUC__
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#include <stdlib.h>
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#endif
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#define THREADS 5
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#define DATASIZE 15
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#define ITERATIONS 1000000
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#define rand_r( _seed ) \
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( _seed == _seed? rand() : rand() )
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/*
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* Keep statistics for each thread.
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*/
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typedef struct thread_tag {
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int thread_num;
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pthread_t thread_id;
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int updates;
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int reads;
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int interval;
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} thread_t;
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/*
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* Read-write lock and shared data
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*/
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typedef struct data_tag {
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pthread_rwlock_t lock;
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int data;
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int updates;
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} data_t;
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static thread_t threads[THREADS];
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static data_t data[DATASIZE];
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/*
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* Thread start routine that uses read-write locks
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*/
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void *thread_routine (void *arg)
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{
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thread_t *self = (thread_t*)arg;
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int repeats = 0;
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int iteration;
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int element = 0;
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for (iteration = 0; iteration < ITERATIONS; iteration++)
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{
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if (iteration % (ITERATIONS / 10) == 0)
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{
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putchar('.');
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fflush(stdout);
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}
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/*
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* Each "self->interval" iterations, perform an
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* update operation (write lock instead of read
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* lock).
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*/
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if ((iteration % self->interval) == 0)
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{
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assert(pthread_rwlock_wrlock (&data[element].lock) == 0);
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data[element].data = self->thread_num;
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data[element].updates++;
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self->updates++;
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assert(pthread_rwlock_unlock (&data[element].lock) == 0);
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} else {
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/*
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* Look at the current data element to see whether
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* the current thread last updated it. Count the
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* times, to report later.
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*/
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assert(pthread_rwlock_rdlock (&data[element].lock) == 0);
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self->reads++;
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if (data[element].data == self->thread_num)
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{
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repeats++;
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}
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assert(pthread_rwlock_unlock (&data[element].lock) == 0);
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}
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element++;
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if (element >= DATASIZE)
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{
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element = 0;
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}
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}
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if (repeats > 0)
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{
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printf ("\nThread %d found unchanged elements %d times",
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self->thread_num, repeats);
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fflush(stdout);
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}
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return NULL;
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}
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int
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main (int argc, char *argv[])
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{
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int count;
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int data_count;
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int thread_updates = 0;
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int data_updates = 0;
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int seed = 1;
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struct timeb currSysTime1;
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struct timeb currSysTime2;
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/*
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* Initialize the shared data.
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*/
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for (data_count = 0; data_count < DATASIZE; data_count++)
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{
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data[data_count].data = 0;
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data[data_count].updates = 0;
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assert(pthread_rwlock_init (&data[data_count].lock, NULL) == 0);
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}
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ftime(&currSysTime1);
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/*
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* Create THREADS threads to access shared data.
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*/
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for (count = 0; count < THREADS; count++)
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{
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threads[count].thread_num = count;
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threads[count].updates = 0;
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threads[count].reads = 0;
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threads[count].interval = rand_r (&seed) % 71;
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assert(pthread_create (&threads[count].thread_id,
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NULL, thread_routine, (void*)&threads[count]) == 0);
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}
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/*
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* Wait for all threads to complete, and collect
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* statistics.
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*/
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for (count = 0; count < THREADS; count++)
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{
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assert(pthread_join (threads[count].thread_id, NULL) == 0);
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thread_updates += threads[count].updates;
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printf ("%02d: interval %d, updates %d, reads %d\n",
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count, threads[count].interval,
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threads[count].updates, threads[count].reads);
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}
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putchar('\n');
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fflush(stdout);
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/*
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* Collect statistics for the data.
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*/
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for (data_count = 0; data_count < DATASIZE; data_count++)
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{
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data_updates += data[data_count].updates;
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printf ("data %02d: value %d, %d updates\n",
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data_count, data[data_count].data, data[data_count].updates);
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assert(pthread_rwlock_destroy (&data[data_count].lock) == 0);
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}
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printf ("%d thread updates, %d data updates\n",
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thread_updates, data_updates);
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ftime(&currSysTime2);
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printf( "\nstart: %ld/%d, stop: %ld/%d, duration:%ld\n",
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currSysTime1.time,currSysTime1.millitm,
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currSysTime2.time,currSysTime2.millitm,
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(currSysTime2.time*1000+currSysTime2.millitm) -
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(currSysTime1.time*1000+currSysTime1.millitm));
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return 0;
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}
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