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gerrit.opencord.org / freeDiameter-old / 13d9601bf947af3286764506368fc3d04672bfde / . / tests / testfifo.c
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/*********************************************************************************************************
* Software License Agreement (BSD License) *
* Author: Sebastien Decugis <sdecugis@freediameter.net> *
* *
* Copyright (c) 2013, WIDE Project and NICT *
* All rights reserved. *
* *
* Redistribution and use of this software in source and binary forms, with or without modification, are *
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* *
* * Redistributions of source code must retain the above *
* copyright notice, this list of conditions and the *
* following disclaimer. *
* *
* * Redistributions in binary form must reproduce the above *
* copyright notice, this list of conditions and the *
* following disclaimer in the documentation and/or other *
* materials provided with the distribution. *
* *
* * Neither the name of the WIDE Project or NICT nor the *
* names of its contributors may be used to endorse or *
* promote products derived from this software without *
* specific prior written permission of WIDE Project and *
* NICT. *
* *
* THIS SOFTWARE IS PROVIDED BY THE COPYRIGHT HOLDERS AND CONTRIBUTORS "AS IS" AND ANY EXPRESS OR IMPLIED *
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*********************************************************************************************************/
#include "tests.h"
#include <unistd.h>
#include <limits.h>
/* Wrapper for pthread_barrier stuff on Mac OS X */
#ifndef HAVE_PTHREAD_BAR
#define PTHREAD_BARRIER_SERIAL_THREAD 1
typedef struct {
int count;
int entered;
int serial;
pthread_mutex_t mutex;
pthread_cond_t cond;
} pthread_barrier_t;
int pthread_barrier_init(pthread_barrier_t * barrier, int * barrier_attr, int count)
{
memset(barrier, 0, sizeof(pthread_barrier_t));
barrier->count = count;
pthread_mutex_init(&barrier->mutex, NULL);
pthread_cond_init(&barrier->cond, NULL);
return 0;
}
int pthread_barrier_destroy(pthread_barrier_t * barrier)
{
pthread_mutex_destroy(&barrier->mutex);
pthread_cond_destroy(&barrier->cond);
return 0;
}
int pthread_barrier_wait(pthread_barrier_t * barrier)
{
int ret = 0;
int serial;
pthread_mutex_lock(&barrier->mutex);
serial = barrier->serial;
/* first thread gets the special value */
if (barrier->entered++ == 0)
ret = PTHREAD_BARRIER_SERIAL_THREAD;
/* Count was achieved? */
if (barrier->entered == barrier->count) {
/* Ok, increase serial, reset number of threads, and signal everyone */
barrier->entered = 0;
barrier->serial++;
pthread_cond_broadcast(&barrier->cond);
} else {
do {
pthread_cond_wait(&barrier->cond, &barrier->mutex);
} while (barrier->serial == serial);
/* this protects against spurious wakes */
}
pthread_mutex_unlock(&barrier->mutex);
return 0;
}
#endif /* HAVE_PTHREAD_BAR */
/* Structure for testing threshold function */
static struct thrh_test {
struct fifo * queue; /* pointer to the queue */
int h_calls; /* number of calls of h_cb */
int l_calls; /* number of calls of l_cb */
} thrh_td;
/* Callbacks for threasholds test */
void thrh_cb_h(struct fifo *queue, void **data)
{
if (thrh_td.h_calls == thrh_td.l_calls) {
CHECK( NULL, *data );
*data = &thrh_td;
} else {
CHECK( *data, &thrh_td );
}
CHECK( queue, thrh_td.queue );
/* Update the count */
thrh_td.h_calls ++;
}
void thrh_cb_l(struct fifo *queue, void **data)
{
CHECK( 1, data ? 1 : 0 );
CHECK( *data, &thrh_td );
/* Check the queue parameter is correct */
CHECK( queue, thrh_td.queue );
/* Update the count */
thrh_td.l_calls ++;
/* Cleanup the data ptr if needed */
if (thrh_td.l_calls == thrh_td.h_calls)
*data = NULL;
/* done */
}
/* Structure that is passed to the test function */
struct test_data {
struct fifo * queue; /* pointer to the queue */
pthread_barrier_t * bar; /* if not NULL, barrier to synchronize before getting messages */
struct timespec * ts; /* if not NULL, use a timedget instead of a get */
int nbr; /* number of messages to retrieve from the queue */
};
/* The test function, to be threaded */
static void * test_fct(void * data)
{
int ret = 0, i;
struct msg * msg = NULL;
struct test_data * td = (struct test_data *) data;
if (td->bar != NULL) {
ret = pthread_barrier_wait(td->bar);
if (ret != PTHREAD_BARRIER_SERIAL_THREAD) {
CHECK( 0, ret);
} else {
CHECK( PTHREAD_BARRIER_SERIAL_THREAD, ret); /* just for the traces */
}
}
for (i=0; i< td->nbr; i++) {
if (td->ts != NULL) {
CHECK( 0, fd_fifo_timedget(td->queue, &msg, td->ts) );
} else {
CHECK( 0, fd_fifo_get(td->queue, &msg) );
}
}
return NULL;
}
/* The test function, to be threaded */
static int iter = 0;
static void * test_fct2(void * data)
{
int i;
int * item;
struct test_data * td = (struct test_data *) data;
for (i=0; i< td->nbr; i++) {
item = malloc(sizeof(int));
CHECK( 1, item ? 1 : 0 );
*item = i;
CHECK( 0, fd_fifo_post(td->queue, &item) );
iter++;
}
return NULL;
}
/* Main test routine */
int main(int argc, char *argv[])
{
struct timespec ts;
struct msg * msg1 = NULL;
struct msg * msg2 = NULL;
struct msg * msg3 = NULL;
/* First, initialize the daemon modules */
INIT_FD();
/* Prolog: create the messages */
{
struct dict_object * acr_model = NULL;
struct dict_object * cer_model = NULL;
struct dict_object * dwr_model = NULL;
CHECK( 0, fd_dict_search ( fd_g_config->cnf_dict, DICT_COMMAND, CMD_BY_NAME, "Accounting-Request", &acr_model, ENOENT ) );
CHECK( 0, fd_dict_search ( fd_g_config->cnf_dict, DICT_COMMAND, CMD_BY_NAME, "Capabilities-Exchange-Request", &cer_model, ENOENT ) );
CHECK( 0, fd_dict_search ( fd_g_config->cnf_dict, DICT_COMMAND, CMD_BY_NAME, "Device-Watchdog-Request", &dwr_model, ENOENT ) );
CHECK( 0, fd_msg_new ( acr_model, 0, &msg1 ) );
CHECK( 0, fd_msg_new ( cer_model, 0, &msg2 ) );
CHECK( 0, fd_msg_new ( dwr_model, 0, &msg3 ) );
}
/* Basic operation */
{
struct fifo * queue = NULL;
struct msg * msg = NULL;
int max;
long long count;
/* Create the queue */
CHECK( 0, fd_fifo_new(&queue, 0) );
/* Check the count is 0 */
CHECK( 0, fd_fifo_length(queue) );
/* Now enqueue */
msg = msg1;
CHECK( 0, fd_fifo_post(queue, &msg) );
msg = msg2;
CHECK( 0, fd_fifo_post(queue, &msg) );
msg = msg3;
CHECK( 0, fd_fifo_post(queue, &msg) );
/* Check the count is 3 */
CHECK( 3, fd_fifo_length(queue) );
/* Retrieve the first message using fd_fifo_get */
CHECK( 0, fd_fifo_get(queue, &msg) );
CHECK( msg1, msg);
CHECK( 2, fd_fifo_length(queue) );
/* Retrieve the second message using fd_fifo_timedget */
CHECK(0, clock_gettime(CLOCK_REALTIME, &ts));
ts.tv_sec += 1; /* Set the timeout to 1 second */
CHECK( 0, fd_fifo_timedget(queue, &msg, &ts) );
CHECK( msg2, msg);
CHECK( 1, fd_fifo_length(queue) );
/* Retrieve the third message using meq_tryget */
CHECK( 0, fd_fifo_tryget(queue, &msg) );
CHECK( msg3, msg);
CHECK( 0, fd_fifo_length(queue) );
/* Check that another meq_tryget does not block */
CHECK( EWOULDBLOCK, fd_fifo_tryget(queue, &msg) );
CHECK( 0, fd_fifo_length(queue) );
/* Check the timedget actually timesout */
CHECK(0, clock_gettime(CLOCK_REALTIME, &ts));
ts.tv_nsec += 1000000; /* 1 millisecond */
if (ts.tv_nsec >= 1000000000L) {
ts.tv_nsec -= 1000000000L;
ts.tv_sec += 1;
}
CHECK( ETIMEDOUT, fd_fifo_timedget(queue, &msg, &ts) );
CHECK( 0, fd_fifo_length(queue) );
/* Post & get another message */
msg = msg1;
CHECK( 0, fd_fifo_post(queue, &msg) );
CHECK( 0, fd_fifo_timedget(queue, &msg, &ts) );
CHECK( msg1, msg);
/* Check some statistics */
CHECK( 0, fd_fifo_getstats(queue, NULL, NULL, &max, &count, NULL, NULL, NULL) );
CHECK( 3, max );
CHECK( 4, count );
/* We're done for basic tests */
CHECK( 0, fd_fifo_del(&queue) );
}
/* Test robustness, ensure no messages are lost */
{
#define NBR_MSG 200
#define NBR_THREADS 60
struct fifo *queue = NULL;
pthread_barrier_t bar;
struct test_data td_1;
struct test_data td_2;
struct msg *msgs[NBR_MSG * NBR_THREADS * 2], *msg;
pthread_t thr [NBR_THREADS * 2];
struct dict_object *dwr_model = NULL;
int i;
int nbr_threads;
#ifdef _POSIX_THREAD_THREADS_MAX
nbr_threads = _POSIX_THREAD_THREADS_MAX;
#else /* _POSIX_THREAD_THREADS_MAX */
nbr_threads = sysconf(_SC_THREAD_THREADS_MAX);
#endif /* _POSIX_THREAD_THREADS_MAX */
if ((nbr_threads <= 0) || (nbr_threads > NBR_THREADS * 2)) {
nbr_threads = NBR_THREADS;
} else {
TRACE_DEBUG(INFO, "Local limit on number of threads: %d", nbr_threads);
/* The local limit is below NBR_THREADS */
nbr_threads = (nbr_threads / 2) - 1;
/* Ensure we create at least a few threads! */
CHECK( 1, nbr_threads >= 10 ? 1 : 0 );
}
/* Create the queue */
CHECK( 0, fd_fifo_new(&queue, 0) );
/* Create the barrier */
CHECK( 0, pthread_barrier_init(&bar, NULL, nbr_threads * 2 + 1) );
/* Initialize the ts */
CHECK(0, clock_gettime(CLOCK_REALTIME, &ts));
ts.tv_sec += 20; /* Set the timeout to 20 second */
/* Create the messages */
CHECK( 0, fd_dict_search ( fd_g_config->cnf_dict, DICT_COMMAND, CMD_BY_NAME, "Device-Watchdog-Request", &dwr_model, ENOENT ) );
for (i = 0; i < NBR_MSG * nbr_threads * 2; i++) {
CHECK( 0, fd_msg_new ( dwr_model, 0, &msgs[i] ) );
}
/* Initialize the test data structures */
td_1.queue = queue;
td_1.bar = &bar;
td_1.ts = &ts;
td_1.nbr = NBR_MSG;
td_2.queue = queue;
td_2.bar = &bar;
td_2.ts = NULL;
td_2.nbr = NBR_MSG;
/* Create the threads */
for (i=0; i < nbr_threads * 2; i++) {
CHECK( 0, pthread_create( &thr[i], NULL, test_fct, (i & 1) ? &td_1 : &td_2 ) );
}
/* Synchronize everyone */
{
int ret = pthread_barrier_wait(&bar);
if (ret != PTHREAD_BARRIER_SERIAL_THREAD) {
CHECK( 0, ret);
} else {
CHECK( PTHREAD_BARRIER_SERIAL_THREAD, ret); /* for trace only */
}
}
/* Now post all the messages */
for (i=0; i < NBR_MSG * nbr_threads * 2; i++) {
msg = msgs[i];
CHECK( 0, fd_fifo_post(queue, &msg) );
}
/* Join all threads. This blocks if messages are lost... */
for (i=0; i < nbr_threads * 2; i++) {
CHECK( 0, pthread_join( thr[i], NULL ) );
}
/* Check the count of the queue is back to 0 */
CHECK( 0, fd_fifo_length(queue) );
/* Destroy this queue and the messages */
CHECK( 0, fd_fifo_del(&queue) );
for (i=0; i < NBR_MSG * nbr_threads * 2; i++) {
CHECK( 0, fd_msg_free( msgs[i] ) );
}
}
/* Test thread cancelation */
{
struct fifo *queue = NULL;
pthread_barrier_t bar;
struct test_data td;
pthread_t th;
/* Create the queue */
CHECK( 0, fd_fifo_new(&queue, 0) );
/* Create the barrier */
CHECK( 0, pthread_barrier_init(&bar, NULL, 2) );
/* Initialize the ts */
CHECK(0, clock_gettime(CLOCK_REALTIME, &ts));
ts.tv_sec += 10; /* Set the timeout to 10 second */
/* Initialize the test data structures */
td.queue = queue;
td.bar = &bar;
td.ts = &ts;
td.nbr = 1;
/* Create the thread */
CHECK( 0, pthread_create( &th, NULL, test_fct, &td ) );
/* Wait for the thread to be running */
{
int ret = pthread_barrier_wait(&bar);
if (ret != PTHREAD_BARRIER_SERIAL_THREAD) {
CHECK( 0, ret);
} else {
CHECK( PTHREAD_BARRIER_SERIAL_THREAD, ret );
}
}
/* Now cancel the thread */
CHECK( 0, pthread_cancel( th ) );
/* Join it */
CHECK( 0, pthread_join( th, NULL ) );
/* Do the same with the other function */
td.ts = NULL;
/* Create the thread */
CHECK( 0, pthread_create( &th, NULL, test_fct, &td ) );
/* Wait for the thread to be running */
{
int ret = pthread_barrier_wait(&bar);
if (ret != PTHREAD_BARRIER_SERIAL_THREAD) {
CHECK( 0, ret);
} else {
CHECK( PTHREAD_BARRIER_SERIAL_THREAD, ret );
}
}
/* Now cancel the thread */
CHECK( 0, pthread_cancel( th ) );
/* Join it */
CHECK( 0, pthread_join( th, NULL ) );
/* Destroy the queue */
CHECK( 0, fd_fifo_del(&queue) );
}
/* Test the threashold function */
{
struct fifo * queue = NULL;
int i;
struct msg * msg = NULL;
/* Create the queue */
CHECK( 0, fd_fifo_new(&queue, 0) );
/* Prepare the test data */
memset(&thrh_td, 0, sizeof(thrh_td));
thrh_td.queue = queue;
/* Set the thresholds for the queue */
CHECK( 0, fd_fifo_setthrhd ( queue, NULL, 6, thrh_cb_h, 4, thrh_cb_l ) );
/* Post 5 messages, no cb must be called. */
for (i=0; i<5; i++) {
msg = msg1;
CHECK( 0, fd_fifo_post(queue, &msg) );
} /* 5 msg in queue */
CHECK( 0, thrh_td.h_calls );
CHECK( 0, thrh_td.l_calls );
/* Get all these messages, and check again */
for (i=0; i<5; i++) {
CHECK( 0, fd_fifo_get(queue, &msg) );
} /* 0 msg in queue */
CHECK( 0, thrh_td.h_calls );
CHECK( 0, thrh_td.l_calls );
/* Now, post 6 messages, the high threashold */
for (i=0; i<6; i++) {
msg = msg1;
CHECK( 0, fd_fifo_post(queue, &msg) );
} /* 6 msg in queue */
CHECK( 1, thrh_td.h_calls );
CHECK( 0, thrh_td.l_calls );
/* Remove 2 messages, to reach the low threshold */
for (i=0; i<2; i++) {
CHECK( 0, fd_fifo_get(queue, &msg) );
} /* 4 msg in queue */
CHECK( 1, thrh_td.h_calls );
CHECK( 1, thrh_td.l_calls );
/* Come again at the high threshold */
for (i=0; i<2; i++) {
msg = msg1;
CHECK( 0, fd_fifo_post(queue, &msg) );
} /* 6 msg in queue */
CHECK( 2, thrh_td.h_calls );
CHECK( 1, thrh_td.l_calls );
/* Suppose the queue continues to grow */
for (i=0; i<6; i++) {
msg = msg1;
CHECK( 0, fd_fifo_post(queue, &msg) );
} /* 12 msg in queue */
CHECK( 3, thrh_td.h_calls );
CHECK( 1, thrh_td.l_calls );
for (i=0; i<5; i++) {
msg = msg1;
CHECK( 0, fd_fifo_post(queue, &msg) );
} /* 17 msg in queue */
CHECK( 3, thrh_td.h_calls );
CHECK( 1, thrh_td.l_calls );
/* Now the queue goes back to 0 messages */
for (i=0; i<17; i++) {
CHECK( 0, fd_fifo_get(queue, &msg) );
} /* 0 msg in queue */
CHECK( 3, thrh_td.h_calls );
CHECK( 3, thrh_td.l_calls );
/* We're done for this test */
CHECK( 0, fd_fifo_del(&queue) );
}
/* Test max queue limit */
{
struct fifo *queue = NULL;
struct test_data td;
pthread_t th;
int * item, i;
/* Create the queue */
CHECK( 0, fd_fifo_new(&queue, 10) );
/* Initialize the test data structures */
td.queue = queue;
td.nbr = 15;
CHECK( 0, pthread_create( &th, NULL, test_fct2, &td ) );
usleep(100000); /* 100 millisec */
CHECK( 10, iter );
CHECK( 0, fd_fifo_tryget(queue, &item) );
CHECK( 0, *item);
free(item);
usleep(100000); /* 100 millisec */
CHECK( 11, iter );
for (i=1; i<4; i++) {
CHECK( 0, fd_fifo_get(queue, &item) );
CHECK( i, *item);
free(item);
}
usleep(100000); /* 100 millisec */
CHECK( 14, iter );
for (; i < td.nbr; i++) {
CHECK( 0, fd_fifo_tryget(queue, &item) );
CHECK( i, *item);
free(item);
}
CHECK( 0, pthread_join( th, NULL ) );
CHECK( 15, iter );
}
/* Delete the messages */
CHECK( 0, fd_msg_free( msg1 ) );
CHECK( 0, fd_msg_free( msg2 ) );
CHECK( 0, fd_msg_free( msg3 ) );
/* That's all for the tests yet */
PASSTEST();
}