/*
* %CopyrightBegin%
*
* Copyright Ericsson AB 2004-2011. All Rights Reserved.
*
* Licensed under the Apache License, Version 2.0 (the "License");
* you may not use this file except in compliance with the License.
* You may obtain a copy of the License at
*
* http://www.apache.org/licenses/LICENSE-2.0
*
* Unless required by applicable law or agreed to in writing, software
* distributed under the License is distributed on an "AS IS" BASIS,
* WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied.
* See the License for the specific language governing permissions and
* limitations under the License.
*
* %CopyrightEnd%
*/
/*
* Description: Test suite for the ethread thread library.
* Author: Rickard Green
*/
#define ETHR_NO_SUPP_THR_LIB_NOT_FATAL
#include "ethread.h"
#include "erl_misc_utils.h"
#include <stdio.h>
#include <stdarg.h>
#include <string.h>
#ifndef __WIN32__
#include <unistd.h>
#endif
#include <limits.h>
/*
* Auxiliary functions
*/
#define PRINT_VA_LIST(FRMT) \
do { \
if (FRMT && FRMT != '\0') { \
va_list args; \
va_start(args, FRMT); \
vfprintf(stderr, FRMT, args); \
va_end(args); \
} \
} while (0)
#define ASSERT(B) \
do { \
if (!(B)) \
fail("%s:%d: Assertion \"%s\" failed!",__FILE__,__LINE__,#B); \
} while (0)
#define ASSERT_PRINT(B, PRNT) \
do { \
if (!(B)) { \
print PRNT; \
fail("%s:%d: Assertion \"%s\" failed!",__FILE__,__LINE__,#B); \
} \
} while (0)
#define ASSERT_EQ(VAR, VAL, FSTR) \
do { \
if ((VAR) != (VAL)) { \
print("%s=" FSTR "\n", #VAR, (VAR)); \
fail("%s:%d: Assertion \"%s == " FSTR "\" failed!", \
__FILE__, __LINE__, #VAR, (VAL)); \
} \
} while (0)
#ifdef __WIN32_
#define EOL "\r\n"
#else
#define EOL "\n"
#endif
static void
print_eol(void)
{
fprintf(stderr, EOL);
fflush(stderr);
}
static void print_line(char *frmt,...)
{
PRINT_VA_LIST(frmt);
print_eol();
}
#if 0 /* Currently not used; silence annoying warning... */
static void print(char *frmt,...)
{
PRINT_VA_LIST(frmt);
}
#endif
static void fail(char *frmt,...)
{
char *abrt_env;
print_eol();
fprintf(stderr, "ETHR-TEST-FAILURE");
PRINT_VA_LIST(frmt);
print_eol();
abrt_env = getenv("ERL_ABORT_ON_FAILURE");
if (abrt_env && strcmp("true", abrt_env) == 0)
abort();
else
exit(1);
}
static void skip(char *frmt,...)
{
print_eol();
fprintf(stderr, "ETHR-TEST-SKIP");
PRINT_VA_LIST(frmt);
print_eol();
exit(0);
}
static void succeed(char *frmt,...)
{
print_eol();
fprintf(stderr, "ETHR-TEST-SUCCESS");
PRINT_VA_LIST(frmt);
print_eol();
exit(0);
}
static void
do_sleep(unsigned secs)
{
while (erts_milli_sleep(secs*1000) != 0);
}
#define WAIT_UNTIL_INTERVAL 10
#define WAIT_UNTIL_LIM(TEST, LIM) \
do { \
int ms__ = (LIM)*1000; \
while (!(TEST)) { \
while (erts_milli_sleep(WAIT_UNTIL_INTERVAL) != 0); \
ms__ -= WAIT_UNTIL_INTERVAL; \
if (ms__ <= 0) \
break; \
} \
} while (0)
static void
send_my_pid(void)
{
#ifndef __WIN32__
int pid = (int) getpid();
fprintf(stderr, EOL "ETHR-TEST-PID%d" EOL, pid);
#endif
}
/*
* The test-cases
*/
#ifndef ETHR_NO_THREAD_LIB
/*
* The create join thread test case.
*
* Tests ethr_thr_create and ethr_thr_join.
*/
#define CJTT_NO_THREADS 64
ethr_tid cjtt_tids[CJTT_NO_THREADS + 1];
int cjtt_ix[CJTT_NO_THREADS + 1];
int cjtt_res[CJTT_NO_THREADS + 1];
void *cjtt_thread(void *vpix)
{
int ix = *((int *) vpix);
cjtt_res[ix] = ix;
return (void *) &cjtt_res[ix];
}
static void
create_join_thread_test(void)
{
int i, res;
for (i = 1; i <= CJTT_NO_THREADS; i++) {
cjtt_ix[i] = i;
cjtt_res[i] = 0;
}
for (i = 1; i <= CJTT_NO_THREADS; i++) {
res = ethr_thr_create(&cjtt_tids[i],
cjtt_thread,
(void *) &cjtt_ix[i],
NULL);
ASSERT(res == 0);
}
for (i = 1; i <= CJTT_NO_THREADS; i++) {
void *tres;
res = ethr_thr_join(cjtt_tids[i], &tres);
ASSERT(res == 0);
ASSERT(tres == &cjtt_res[i]);
ASSERT(cjtt_res[i] == i);
}
}
/*
* The eq tid test case.
*
* Tests ethr_equal_tids.
*/
#define ETT_THREADS 100000
static ethr_tid ett_tids[3];
static ethr_mutex ett_mutex;
static ethr_cond ett_cond;
static int ett_terminate;
static void *
ett_thread(void *my_tid)
{
ASSERT(!ethr_equal_tids(ethr_self(), ett_tids[0]));
ASSERT(ethr_equal_tids(ethr_self(), *((ethr_tid *) my_tid)));
return NULL;
}
static void *
ett_thread2(void *unused)
{
int res;
ethr_mutex_lock(&ett_mutex);
while (!ett_terminate) {
res = ethr_cond_wait(&ett_cond, &ett_mutex);
ASSERT(res == 0);
}
ethr_mutex_unlock(&ett_mutex);
return NULL;
}
static void
equal_tids_test(void)
{
int res, i;
res = ethr_mutex_init(&ett_mutex);
ASSERT(res == 0);
res = ethr_cond_init(&ett_cond);
ASSERT(res == 0);
ett_tids[0] = ethr_self();
res = ethr_thr_create(&ett_tids[1], ett_thread, (void *) &ett_tids[1], NULL);
ASSERT(res == 0);
ASSERT(ethr_equal_tids(ethr_self(), ett_tids[0]));
ASSERT(!ethr_equal_tids(ethr_self(), ett_tids[1]));
res = ethr_thr_join(ett_tids[1], NULL);
res = ethr_thr_create(&ett_tids[2], ett_thread, (void *) &ett_tids[2], NULL);
ASSERT(res == 0);
ASSERT(ethr_equal_tids(ethr_self(), ett_tids[0]));
ASSERT(!ethr_equal_tids(ethr_self(), ett_tids[1]));
ASSERT(!ethr_equal_tids(ethr_self(), ett_tids[2]));
#if 0
/* This fails on some linux platforms. Until we decides if a tid
* is allowed to be reused right away or not, we disable the test.
*/
ASSERT(!ethr_equal_tids(ett_tids[1], ett_tids[2]));
#endif
res = ethr_thr_join(ett_tids[2], NULL);
ASSERT(res == 0);
/* Second part of test */
ett_terminate = 0;
res = ethr_thr_create(&ett_tids[1], ett_thread2, NULL, NULL);
ASSERT(res == 0);
ASSERT(!ethr_equal_tids(ett_tids[0], ett_tids[1]));
for (i = 0; i < ETT_THREADS; i++) {
res = ethr_thr_create(&ett_tids[2], ett_thread, (void*)&ett_tids[2], NULL);
ASSERT(res == 0);
ASSERT(!ethr_equal_tids(ett_tids[0], ett_tids[2]));
ASSERT(!ethr_equal_tids(ett_tids[1], ett_tids[2]));
res = ethr_thr_join(ett_tids[2], NULL);
ASSERT(res == 0);
}
ethr_mutex_lock(&ett_mutex);
ett_terminate = 1;
ethr_cond_signal(&ett_cond);
ethr_mutex_unlock(&ett_mutex);
res = ethr_thr_join(ett_tids[1], NULL);
ASSERT(res == 0);
res = ethr_cond_destroy(&ett_cond);
ASSERT(res == 0);
res = ethr_mutex_destroy(&ett_mutex);
ASSERT(res == 0);
}
/*
* The mutex test case.
*
* Tests mutexes.
*/
static ethr_mutex mt_mutex;
static int mt_data;
void *
mt_thread(void *unused)
{
print_line("Aux thread tries to lock mutex");
ethr_mutex_lock(&mt_mutex);
print_line("Aux thread locked mutex");
ASSERT(mt_data == 0);
mt_data = 1;
print_line("Aux thread wrote");
print_line("Aux thread goes to sleep for 1 second");
do_sleep(1);
print_line("Aux thread woke up");
ASSERT(mt_data == 1);
ethr_mutex_unlock(&mt_mutex);
print_line("Aux thread unlocked mutex");
return NULL;
}
static void
mutex_test(void)
{
int res;
ethr_tid tid;
print_line("Trying to initialize mutex");
res = ethr_mutex_init(&mt_mutex);
ASSERT(res == 0);
print_line("Initialized mutex");
mt_data = 0;
print_line("Main thread tries to lock mutex");
ethr_mutex_lock(&mt_mutex);
print_line("Main thread locked mutex");
ASSERT(mt_data == 0);
print_line("Main thread about to create aux thread");
res = ethr_thr_create(&tid, mt_thread, NULL, NULL);
ASSERT(res == 0);
print_line("Main thread created aux thread");
print_line("Main thread goes to sleep for 1 second");
do_sleep(1);
print_line("Main thread woke up");
ASSERT(mt_data == 0);
ethr_mutex_unlock(&mt_mutex);
print_line("Main thread unlocked mutex");
print_line("Main thread goes to sleep for 1 second");
do_sleep(1);
print_line("Main thread woke up");
print_line("Main thread tries to lock mutex");
ethr_mutex_lock(&mt_mutex);
print_line("Main thread locked mutex");
ASSERT(mt_data == 1);
print_line("Main thread goes to sleep for 1 second");
do_sleep(1);
print_line("Main thread woke up");
ASSERT(mt_data == 1);
ethr_mutex_unlock(&mt_mutex);
print_line("Main thread unlocked mutex");
res = ethr_thr_join(tid, NULL);
ASSERT(res == 0);
print_line("Main thread joined aux thread");
res = ethr_mutex_destroy(&mt_mutex);
ASSERT(res == 0);
print_line("Main thread destroyed mutex");
}
/*
* The try lock mutex test case.
*
* Tests try lock mutex operation.
*/
static ethr_mutex tlmt_mtx1;
static ethr_mutex tlmt_mtx2;
static ethr_cond tlmt_cnd2;
static int tlmt_mtx1_locked;
static int tlmt_mtx1_do_unlock;
static void *
tlmt_thread(void *unused)
{
int res;
ethr_mutex_lock(&tlmt_mtx1);
ethr_mutex_lock(&tlmt_mtx2);
tlmt_mtx1_locked = 1;
ethr_cond_signal(&tlmt_cnd2);
while (!tlmt_mtx1_do_unlock) {
res = ethr_cond_wait(&tlmt_cnd2, &tlmt_mtx2);
ASSERT(res == 0 || res == EINTR);
}
ethr_mutex_unlock(&tlmt_mtx2);
ethr_mutex_unlock(&tlmt_mtx1);
ethr_mutex_lock(&tlmt_mtx2);
tlmt_mtx1_locked = 0;
ethr_cond_signal(&tlmt_cnd2);
ethr_mutex_unlock(&tlmt_mtx2);
return NULL;
}
static void
try_lock_mutex_test(void)
{
int i, res;
ethr_tid tid;
res = ethr_mutex_init(&tlmt_mtx1);
ASSERT(res == 0);
res = ethr_mutex_init(&tlmt_mtx2);
ASSERT(res == 0);
res = ethr_cond_init(&tlmt_cnd2);
ASSERT(res == 0);
tlmt_mtx1_locked = 0;
tlmt_mtx1_do_unlock = 0;
res = ethr_thr_create(&tid, tlmt_thread, NULL, NULL);
ASSERT(res == 0);
ethr_mutex_lock(&tlmt_mtx2);
while (!tlmt_mtx1_locked) {
res = ethr_cond_wait(&tlmt_cnd2, &tlmt_mtx2);
ASSERT(res == 0 || res == EINTR);
}
ethr_mutex_unlock(&tlmt_mtx2);
for (i = 0; i < 10; i++) {
res = ethr_mutex_trylock(&tlmt_mtx1);
ASSERT(res == EBUSY);
}
ethr_mutex_lock(&tlmt_mtx2);
tlmt_mtx1_do_unlock = 1;
ethr_cond_signal(&tlmt_cnd2);
while (tlmt_mtx1_locked) {
res = ethr_cond_wait(&tlmt_cnd2, &tlmt_mtx2);
ASSERT(res == 0 || res == EINTR);
}
ethr_mutex_unlock(&tlmt_mtx2);
res = ethr_mutex_trylock(&tlmt_mtx1);
ASSERT(res == 0);
ethr_mutex_unlock(&tlmt_mtx1);
res = ethr_thr_join(tid, NULL);
ASSERT(res == 0);
res = ethr_mutex_destroy(&tlmt_mtx1);
ASSERT(res == 0);
res = ethr_mutex_destroy(&tlmt_mtx2);
ASSERT(res == 0);
res = ethr_cond_destroy(&tlmt_cnd2);
ASSERT(res == 0);
}
/*
* The cond wait test case.
*
* Tests ethr_cond_wait with ethr_cond_signal and ethr_cond_broadcast.
*/
static ethr_mutex cwt_mutex;
static ethr_cond cwt_cond;
static int cwt_counter;
void *
cwt_thread(void *unused)
{
int res;
ethr_mutex_lock(&cwt_mutex);
do {
res = ethr_cond_wait(&cwt_cond, &cwt_mutex);
} while (res == EINTR);
ASSERT(res == 0);
cwt_counter++;
ethr_mutex_unlock(&cwt_mutex);
return NULL;
}
static void
cond_wait_test(void)
{
ethr_tid tid1, tid2;
int res;
res = ethr_mutex_init(&cwt_mutex);
ASSERT(res == 0);
res = ethr_cond_init(&cwt_cond);
ASSERT(res == 0);
/* Wake with signal */
cwt_counter = 0;
res = ethr_thr_create(&tid1, cwt_thread, NULL, NULL);
ASSERT(res == 0);
res = ethr_thr_create(&tid2, cwt_thread, NULL, NULL);
ASSERT(res == 0);
do_sleep(1); /* Make sure threads waits on cond var */
ethr_mutex_lock(&cwt_mutex);
ethr_cond_signal(&cwt_cond); /* Wake one thread */
do_sleep(1); /* Make sure awakened thread waits on mutex */
ASSERT(cwt_counter == 0);
ethr_mutex_unlock(&cwt_mutex);
do_sleep(1); /* Let awakened thread proceed */
ethr_mutex_lock(&cwt_mutex);
ASSERT(cwt_counter == 1);
ethr_cond_signal(&cwt_cond); /* Wake the other thread */
do_sleep(1); /* Make sure awakened thread waits on mutex */
ASSERT(cwt_counter == 1);
ethr_mutex_unlock(&cwt_mutex);
do_sleep(1); /* Let awakened thread proceed */
ethr_mutex_lock(&cwt_mutex);
ASSERT(cwt_counter == 2);
ethr_mutex_unlock(&cwt_mutex);
res = ethr_thr_join(tid1, NULL);
ASSERT(res == 0);
res = ethr_thr_join(tid2, NULL);
ASSERT(res == 0);
/* Wake with broadcast */
cwt_counter = 0;
res = ethr_thr_create(&tid1, cwt_thread, NULL, NULL);
ASSERT(res == 0);
res = ethr_thr_create(&tid2, cwt_thread, NULL, NULL);
ASSERT(res == 0);
do_sleep(1); /* Make sure threads waits on cond var */
ethr_mutex_lock(&cwt_mutex);
ethr_cond_broadcast(&cwt_cond); /* Wake the threads */
do_sleep(1); /* Make sure awakened threads wait on mutex */
ASSERT(cwt_counter == 0);
ethr_mutex_unlock(&cwt_mutex);
do_sleep(1); /* Let awakened threads proceed */
ethr_mutex_lock(&cwt_mutex);
ASSERT(cwt_counter == 2);
ethr_mutex_unlock(&cwt_mutex);
res = ethr_thr_join(tid1, NULL);
ASSERT(res == 0);
res = ethr_thr_join(tid2, NULL);
ASSERT(res == 0);
res = ethr_mutex_destroy(&cwt_mutex);
ASSERT(res == 0);
res = ethr_cond_destroy(&cwt_cond);
ASSERT(res == 0);
}
/*
* The broadcast test case.
*
* Tests that a ethr_cond_broadcast really wakes up all waiting threads.
*/
#define BCT_THREADS 64
#define BCT_NO_OF_WAITS 100
static int bct_woken = 0;
static int bct_waiting = 0;
static int bct_done = 0;
static ethr_mutex bct_mutex;
static ethr_cond bct_cond;
static ethr_cond bct_cntrl_cond;
static void *
bct_thread(void *unused)
{
int res;
ethr_mutex_lock(&bct_mutex);
while (!bct_done) {
bct_waiting++;
if (bct_waiting == BCT_THREADS)
ethr_cond_signal(&bct_cntrl_cond);
do {
res = ethr_cond_wait(&bct_cond, &bct_mutex);
} while (res == EINTR);
ASSERT(res == 0);
bct_woken++;
if (bct_woken == BCT_THREADS)
ethr_cond_signal(&bct_cntrl_cond);
}
ethr_mutex_unlock(&bct_mutex);
return NULL;
}
static void
broadcast_test(void)
{
int res, i;
ethr_tid tid[BCT_THREADS];
res = ethr_mutex_init(&bct_mutex);
ASSERT(res == 0);
res = ethr_cond_init(&bct_cntrl_cond);
ASSERT(res == 0);
res = ethr_cond_init(&bct_cond);
ASSERT(res == 0);
for (i = 0; i < BCT_THREADS; i++) {
res = ethr_thr_create(&tid[i], bct_thread, NULL, NULL);
ASSERT(res == 0);
}
ethr_mutex_lock(&bct_mutex);
for (i = 0; i < BCT_NO_OF_WAITS; i++) {
while (bct_waiting != BCT_THREADS) {
res = ethr_cond_wait(&bct_cntrl_cond, &bct_mutex);
ASSERT(res == 0 || res == EINTR);
}
bct_waiting = 0;
bct_woken = 0;
/* Wake all threads */
ethr_cond_broadcast(&bct_cond);
while (bct_woken != BCT_THREADS) {
res = ethr_cond_wait(&bct_cntrl_cond, &bct_mutex);
ASSERT(res == 0 || res == EINTR);
}
}
bct_done = 1;
/* Wake all threads */
ethr_cond_broadcast(&bct_cond);
ethr_mutex_unlock(&bct_mutex);
for (i = 0; i < BCT_THREADS; i++) {
res = ethr_thr_join(tid[i], NULL);
ASSERT(res == 0);
}
res = ethr_mutex_destroy(&bct_mutex);
ASSERT(res == 0);
res = ethr_cond_destroy(&bct_cntrl_cond);
ASSERT(res == 0);
res = ethr_cond_destroy(&bct_cond);
ASSERT(res == 0);
}
/*
* The detached thread test case.
*
* Tests detached threads.
*/
#define DT_THREADS (50*1024)
#define DT_BATCH_SIZE 64
static ethr_mutex dt_mutex;
static ethr_cond dt_cond;
static int dt_count;
static int dt_limit;
static void *
dt_thread(void *unused)
{
ethr_mutex_lock(&dt_mutex);
dt_count++;
if (dt_count >= dt_limit)
ethr_cond_signal(&dt_cond);
ethr_mutex_unlock(&dt_mutex);
return NULL;
}
static void
detached_thread_test(void)
{
ethr_thr_opts thr_opts = ETHR_THR_OPTS_DEFAULT_INITER;
ethr_tid tid[DT_BATCH_SIZE];
int i, j, res;
res = ethr_mutex_init(&dt_mutex);
ASSERT(res == 0);
res = ethr_cond_init(&dt_cond);
ASSERT(res == 0);
thr_opts.detached = 1;
dt_count = 0;
dt_limit = 0;
for (i = 0; i < DT_THREADS/DT_BATCH_SIZE; i++) {
dt_limit += DT_BATCH_SIZE;
for (j = 0; j < DT_BATCH_SIZE; j++) {
res = ethr_thr_create(&tid[j], dt_thread, NULL, &thr_opts);
ASSERT(res == 0);
}
ethr_mutex_lock(&dt_mutex);
while (dt_count < dt_limit) {
res = ethr_cond_wait(&dt_cond, &dt_mutex);
ASSERT(res == 0 || res == EINTR);
}
ethr_mutex_unlock(&dt_mutex);
print_line("dt_count = %d", dt_count);
}
do_sleep(1);
}
/*
* The max threads test case.
*
* Tests
*/
#define MTT_TIMES 10
#define MTT_HARD_LIMIT (80000)
static int mtt_terminate;
static ethr_mutex mtt_mutex;
static ethr_cond mtt_cond;
static char mtt_string[22*MTT_TIMES]; /* 22 is enough for ", %d" */
void *mtt_thread(void *unused)
{
int res;
ethr_mutex_lock(&mtt_mutex);
while (!mtt_terminate) {
res = ethr_cond_wait(&mtt_cond, &mtt_mutex);
ASSERT(res == 0 || res == EINTR);
}
ethr_mutex_unlock(&mtt_mutex);
return NULL;
}
static int
mtt_create_join_threads(void)
{
int no_tids = 100, ix = 0, res = 0, no_threads;
ethr_tid *tids;
mtt_terminate = 0;
tids = (ethr_tid *) malloc(sizeof(ethr_tid)*no_tids);
ASSERT(tids);
print_line("Beginning to create threads");
while (1) {
if (ix >= no_tids) {
no_tids += 100;
if (no_tids > MTT_HARD_LIMIT) {
print_line("Hit the hard limit on number of threads (%d)!",
MTT_HARD_LIMIT);
break;
}
tids = (ethr_tid *) realloc((void *)tids, sizeof(ethr_tid)*no_tids);
ASSERT(tids);
}
res = ethr_thr_create(&tids[ix], mtt_thread, NULL, NULL);
if (res != 0) {
break;
}
ix++;
}
no_threads = ix;
print_line("%d = ethr_thr_create()", res);
print_line("Number of created threads: %d", no_threads);
ethr_mutex_lock(&mtt_mutex);
mtt_terminate = 1;
ethr_cond_broadcast(&mtt_cond);
ethr_mutex_unlock(&mtt_mutex);
while (ix) {
res = ethr_thr_join(tids[--ix], NULL);
ASSERT(res == 0);
}
print_line("All created threads terminated");
free((void *) tids);
return no_threads;
}
static void
max_threads_test(void)
{
int no_threads[MTT_TIMES], i, up, down, eq, res;
char *str;
res = ethr_mutex_init(&mtt_mutex);
ASSERT(res == 0);
res = ethr_cond_init(&mtt_cond);
ASSERT(res == 0);
for (i = 0; i < MTT_TIMES; i++) {
no_threads[i] = mtt_create_join_threads();
}
str = &mtt_string[0];
eq = up = down = 0;
for (i = 0; i < MTT_TIMES; i++) {
if (i == 0) {
str += sprintf(str, "%d", no_threads[i]);
continue;
}
str += sprintf(str, ", %d", no_threads[i]);
if (no_threads[i] < no_threads[i-1])
down++;
else if (no_threads[i] > no_threads[i-1])
up++;
else
eq++;
}
print_line("Max created threads: %s", mtt_string);
/* We fail if the no of threads we are able to create constantly decrease */
ASSERT(!down || up || eq);
succeed("Max created threads: %s", mtt_string);
}
/*
* The tsd test case.
*
* Tests thread specific data.
*/
#define TT_THREADS 10
static ethr_tsd_key tt_key;
static void *
tt_thread(void *arg)
{
int res = ethr_tsd_set(tt_key, arg);
ASSERT(res == 0);
return ethr_tsd_get(tt_key);
}
static void
tsd_test(void)
{
void *tres;
int i, res;
ethr_tid tid[TT_THREADS];
int values[TT_THREADS];
res = ethr_tsd_key_create(&tt_key,"tsd_test");
ASSERT(res == 0);
for (i = 1; i < TT_THREADS; i++) {
res = ethr_thr_create(&tid[i], tt_thread, (void *) &values[i], NULL);
ASSERT(res == 0);
}
tres = tt_thread((void *) &values[0]);
ASSERT(tres == (void *) &values[0]);
for (i = 1; i < TT_THREADS; i++) {
res = ethr_thr_join(tid[i], &tres);
ASSERT(res == 0);
ASSERT(tres == (void *) &values[i]);
}
res = ethr_tsd_key_delete(tt_key);
ASSERT(res == 0);
}
/*
* The spinlock test case.
*
* Tests spinlocks.
*/
static ethr_spinlock_t st_spinlock;
static int st_data;
void *
st_thread(void *unused)
{
print_line("Aux thread tries to lock spinlock");
ethr_spin_lock(&st_spinlock);
print_line("Aux thread locked spinlock");
ASSERT(st_data == 0);
st_data = 1;
print_line("Aux thread wrote");
print_line("Aux thread goes to sleep for 1 second");
do_sleep(1);
print_line("Aux thread woke up");
ASSERT(st_data == 1);
ethr_spin_unlock(&st_spinlock);
print_line("Aux thread unlocked spinlock");
return NULL;
}
static void
spinlock_test(void)
{
int res;
ethr_tid tid;
print_line("Trying to initialize spinlock");
res = ethr_spinlock_init(&st_spinlock);
ASSERT(res == 0);
print_line("Initialized spinlock");
st_data = 0;
print_line("Main thread tries to lock spinlock");
ethr_spin_lock(&st_spinlock);
print_line("Main thread locked spinlock");
ASSERT(st_data == 0);
print_line("Main thread about to create aux thread");
res = ethr_thr_create(&tid, st_thread, NULL, NULL);
ASSERT(res == 0);
print_line("Main thread created aux thread");
print_line("Main thread goes to sleep for 1 second");
do_sleep(1);
print_line("Main thread woke up");
ASSERT(st_data == 0);
ethr_spin_unlock(&st_spinlock);
print_line("Main thread unlocked spinlock");
print_line("Main thread goes to sleep for 1 second");
do_sleep(1);
print_line("Main thread woke up");
print_line("Main thread tries to lock spinlock");
ethr_spin_lock(&st_spinlock);
print_line("Main thread locked spinlock");
ASSERT(st_data == 1);
print_line("Main thread goes to sleep for 1 second");
do_sleep(1);
print_line("Main thread woke up");
ASSERT(st_data == 1);
ethr_spin_unlock(&st_spinlock);
print_line("Main thread unlocked spinlock");
res = ethr_thr_join(tid, NULL);
ASSERT(res == 0);
print_line("Main thread joined aux thread");
res = ethr_spinlock_destroy(&st_spinlock);
ASSERT(res == 0);
print_line("Main thread destroyed spinlock");
}
/*
* The rwspinlock test case.
*
* Tests rwspinlocks.
*/
static ethr_rwlock_t rwst_rwspinlock;
static int rwst_data;
void *
rwst_thread(void *unused)
{
int data;
print_line("Aux thread tries to read lock rwspinlock");
ethr_read_lock(&rwst_rwspinlock);
print_line("Aux thread read locked rwspinlock");
ASSERT(rwst_data == 4711);
print_line("Aux thread tries to read unlock rwspinlock");
ethr_read_unlock(&rwst_rwspinlock);
print_line("Aux thread read unlocked rwspinlock");
print_line("Aux thread tries to write lock rwspinlock");
ethr_write_lock(&rwst_rwspinlock);
print_line("Aux thread write locked rwspinlock");
data = ++rwst_data;
print_line("Aux thread wrote");
print_line("Aux thread goes to sleep for 1 second");
do_sleep(1);
print_line("Aux thread woke up");
ASSERT(rwst_data == data);
++rwst_data;
print_line("Aux thread tries to write unlock rwspinlock");
ethr_write_unlock(&rwst_rwspinlock);
print_line("Aux thread write unlocked rwspinlock");
return NULL;
}
static void
rwspinlock_test(void)
{
int data;
int res;
ethr_tid tid;
print_line("Trying to initialize rwspinlock");
res = ethr_rwlock_init(&rwst_rwspinlock);
ASSERT(res == 0);
print_line("Initialized rwspinlock");
rwst_data = 4711;
print_line("Main thread tries to read lock rwspinlock");
ethr_read_lock(&rwst_rwspinlock);
print_line("Main thread read locked rwspinlock");
ASSERT(rwst_data == 4711);
print_line("Main thread about to create aux thread");
res = ethr_thr_create(&tid, rwst_thread, NULL, NULL);
ASSERT(res == 0);
print_line("Main thread created aux thread");
print_line("Main thread goes to sleep for 1 second");
do_sleep(1);
print_line("Main thread woke up");
ASSERT(rwst_data == 4711);
print_line("Main thread tries to read unlock rwspinlock");
ethr_read_unlock(&rwst_rwspinlock);
print_line("Main thread read unlocked rwspinlock");
print_line("Main thread tries to write lock rwspinlock");
ethr_write_lock(&rwst_rwspinlock);
print_line("Main thread write locked rwspinlock");
data = ++rwst_data;
print_line("Main thread goes to sleep for 1 second");
do_sleep(1);
print_line("Main thread woke up");
ASSERT(rwst_data == data);
++rwst_data;
print_line("Main thread tries to write unlock rwspinlock");
ethr_write_unlock(&rwst_rwspinlock);
print_line("Main thread write unlocked rwspinlock");
res = ethr_thr_join(tid, NULL);
ASSERT(res == 0);
print_line("Main thread joined aux thread");
res = ethr_rwlock_destroy(&rwst_rwspinlock);
ASSERT(res == 0);
print_line("Main thread destroyed rwspinlock");
}
/*
* The rwmutex test case.
*
* Tests rwmutexes.
*/
static ethr_rwmutex rwmt_rwmutex;
static int rwmt_data;
void *
rwmt_thread(void *unused)
{
int data;
print_line("Aux thread tries to read lock rwmutex");
ethr_rwmutex_rlock(&rwmt_rwmutex);
print_line("Aux thread read locked rwmutex");
ASSERT(rwmt_data == 4711);
print_line("Aux thread tries to read unlock rwmutex");
ethr_rwmutex_runlock(&rwmt_rwmutex);
print_line("Aux thread read unlocked rwmutex");
print_line("Aux thread tries to write lock rwmutex");
ethr_rwmutex_rwlock(&rwmt_rwmutex);
print_line("Aux thread write locked rwmutex");
data = ++rwmt_data;
print_line("Aux thread wrote");
print_line("Aux thread goes to sleep for 1 second");
do_sleep(1);
print_line("Aux thread woke up");
ASSERT(rwmt_data == data);
++rwmt_data;
print_line("Aux thread tries to write unlock rwmutex");
ethr_rwmutex_rwunlock(&rwmt_rwmutex);
print_line("Aux thread write unlocked rwmutex");
return NULL;
}
static void
rwmutex_test(void)
{
int data;
int res;
ethr_tid tid;
print_line("Trying to initialize rwmutex");
res = ethr_rwmutex_init(&rwmt_rwmutex);
ASSERT(res == 0);
print_line("Initialized rwmutex");
rwmt_data = 4711;
print_line("Main thread tries to read lock rwmutex");
ethr_rwmutex_rlock(&rwmt_rwmutex);
print_line("Main thread read locked rwmutex");
ASSERT(rwmt_data == 4711);
print_line("Main thread about to create aux thread");
res = ethr_thr_create(&tid, rwmt_thread, NULL, NULL);
ASSERT(res == 0);
print_line("Main thread created aux thread");
print_line("Main thread goes to sleep for 1 second");
do_sleep(1);
print_line("Main thread woke up");
ASSERT(rwmt_data == 4711);
print_line("Main thread tries to read unlock rwmutex");
ethr_rwmutex_runlock(&rwmt_rwmutex);
print_line("Main thread read unlocked rwmutex");
print_line("Main thread tries to write lock rwmutex");
ethr_rwmutex_rwlock(&rwmt_rwmutex);
print_line("Main thread write locked rwmutex");
data = ++rwmt_data;
print_line("Main thread goes to sleep for 1 second");
do_sleep(1);
print_line("Main thread woke up");
ASSERT(rwmt_data == data);
++rwmt_data;
print_line("Main thread tries to write unlock rwmutex");
ethr_rwmutex_rwunlock(&rwmt_rwmutex);
print_line("Main thread write unlocked rwmutex");
res = ethr_thr_join(tid, NULL);
ASSERT(res == 0);
print_line("Main thread joined aux thread");
res = ethr_rwmutex_destroy(&rwmt_rwmutex);
ASSERT(res == 0);
print_line("Main thread destroyed rwmutex");
}
/*
* The atomic test case.
*
* Tests atomics.
*/
#define AT_AINT32_MAX 0x7fffffff
#define AT_AINT32_MIN 0x80000000
#define AT_THREADS 4
#define AT_ITER 10000
long at_set_val, at_rm_val, at_max_val;
static ethr_atomic_t at_ready;
static ethr_atomic_t at_go;
static ethr_atomic_t at_done;
static ethr_atomic_t at_data;
#define AT_TEST_INIT(T, A, B) \
do { \
ethr_ ## A ## _init ## B(&A, 17); \
ASSERT(ethr_ ## A ## _read ## B(&A) == 17); \
} while (0)
#define AT_TEST_SET(T, A, B) \
do { \
ethr_ ## A ## _set ## B(&A, 4711); \
ASSERT(ethr_ ## A ## _read ## B(&A) == 4711); \
} while (0)
#define AT_TEST_XCHG(T, A, B) \
do { \
ethr_ ## A ## _set ## B(&A, 4711); \
ASSERT(ethr_ ## A ## _xchg ## B(&A, 17) == 4711); \
ASSERT(ethr_ ## A ## _read ## B(&A) == 17); \
} while (0)
#define AT_TEST_CMPXCHG(T, A, B) \
do { \
ethr_ ## A ## _set ## B(&A, 4711); \
ASSERT(ethr_ ## A ## _cmpxchg ## B(&A, 17, 33) == 4711); \
ASSERT(ethr_ ## A ## _read ## B(&A) == 4711); \
ASSERT(ethr_ ## A ## _cmpxchg ## B(&A, 17, 4711) == 4711); \
ASSERT(ethr_ ## A ## _read ## B(&A) == 17); \
} while (0)
#define AT_TEST_ADD_READ(T, A, B) \
do { \
T var_ = AT_AINT32_MAX; \
var_ += 4711; \
ethr_ ## A ## _set ## B(&A, AT_AINT32_MAX); \
ASSERT(ethr_ ## A ## _add_read ## B(&A, 4711) == var_); \
ASSERT(ethr_ ## A ## _read ## B(&A) == var_); \
var_ = AT_AINT32_MIN; \
var_ -= 4711; \
ethr_ ## A ## _set ## B(&A, AT_AINT32_MIN); \
ASSERT(ethr_ ## A ## _add_read ## B(&A, -4711) == var_); \
ASSERT(ethr_ ## A ## _read ## B(&A) == var_); \
ethr_ ## A ## _set ## B(&A, 4711); \
ASSERT(ethr_ ## A ## _add_read ## B(&A, 10) == 4721); \
ASSERT(ethr_ ## A ## _read ## B(&A) == 4721); \
} while (0)
#define AT_TEST_ADD(T, A, B) \
do { \
T var_ = AT_AINT32_MAX; \
var_ += 4711; \
ethr_ ## A ## _set ## B(&A, AT_AINT32_MAX); \
ethr_ ## A ## _add ## B(&A, 4711); \
ASSERT(ethr_ ## A ## _read ## B(&A) == var_); \
var_ = AT_AINT32_MIN; \
var_ -= 4711; \
ethr_ ## A ## _set ## B(&A, AT_AINT32_MIN); \
ethr_ ## A ## _add ## B(&A, -4711); \
ASSERT(ethr_ ## A ## _read ## B(&A) == var_); \
ethr_ ## A ## _set ## B(&A, 11); \
ethr_ ## A ## _add ## B(&A, 4700); \
ASSERT(ethr_ ## A ## _read ## B(&A) == 4711); \
} while (0)
#define AT_TEST_INC_READ(T, A, B) \
do { \
T var_ = AT_AINT32_MAX; \
var_++; \
ethr_ ## A ## _set ## B(&A, AT_AINT32_MAX); \
ASSERT(ethr_ ## A ## _inc_read ## B(&A) == var_); \
ASSERT(ethr_ ## A ## _read ## B(&A) == var_); \
ethr_ ## A ## _set ## B(&A, 4710); \
ASSERT(ethr_ ## A ## _inc_read ## B(&A) == 4711); \
ASSERT(ethr_ ## A ## _read ## B(&A) == 4711); \
} while (0)
#define AT_TEST_DEC_READ(T, A, B) \
do { \
T var_ = AT_AINT32_MIN; \
var_--; \
ethr_ ## A ## _set ## B(&A, AT_AINT32_MIN); \
ASSERT(ethr_ ## A ## _dec_read ## B(&A) == var_); \
ASSERT(ethr_ ## A ## _read ## B(&A) == var_); \
ethr_ ## A ## _set ## B(&A, 17); \
ASSERT(ethr_ ## A ## _dec_read ## B(&A) == 16); \
ASSERT(ethr_ ## A ## _read ## B(&A) == 16); \
} while (0)
#define AT_TEST_INC(T, A, B) \
do { \
T var_ = AT_AINT32_MAX; \
var_++; \
ethr_ ## A ## _set ## B(&A, AT_AINT32_MAX); \
ethr_ ## A ## _inc ## B(&A); \
ASSERT(ethr_ ## A ## _read ## B(&A) == var_); \
ethr_ ## A ## _set ## B(&A, 4710); \
ethr_ ## A ## _inc ## B(&A); \
ASSERT(ethr_ ## A ## _read ## B(&A) == 4711); \
} while (0)
#define AT_TEST_DEC(T, A, B) \
do { \
T var_ = AT_AINT32_MIN; \
var_--; \
ethr_ ## A ## _set ## B(&A, AT_AINT32_MIN); \
ethr_ ## A ## _dec ## B(&A); \
ASSERT(ethr_ ## A ## _read ## B(&A) == var_); \
ethr_ ## A ## _set ## B(&A, 17); \
ethr_ ## A ## _dec ## B(&A); \
ASSERT(ethr_ ## A ## _read ## B(&A) == 16); \
} while (0)
#define AT_TEST_READ_BAND(T, A, B) \
do { \
ethr_ ## A ## _set ## B(&A, 0x13131313); \
ASSERT(ethr_ ## A ## _read_band ## B(&A, 0x31313131) == 0x13131313); \
ASSERT(ethr_ ## A ## _read ## B(&A) == 0x11111111); \
} while (0)
#define AT_TEST_READ_BOR(T, A, B) \
do { \
ethr_ ## A ## _set ## B(&A, 0x11111111); \
ASSERT(ethr_ ## A ## _read_bor ## B(&A, 0x23232323) == 0x11111111); \
ASSERT(ethr_ ## A ## _read ## B(&A) == 0x33333333); \
} while (0)
static void
atomic_basic_test(void)
{
/*
* Verify that each op does what it is expected
* to do for at least one input.
*/
ethr_atomic32_t atomic32;
ethr_atomic_t atomic;
print_line("AT_AINT32_MAX=%d",AT_AINT32_MAX);
print_line("AT_AINT32_MIN=%d",AT_AINT32_MIN);
AT_TEST_INIT(ethr_sint32_t, atomic32, );
AT_TEST_SET(ethr_sint32_t, atomic32, );
AT_TEST_XCHG(ethr_sint32_t, atomic32, );
AT_TEST_CMPXCHG(ethr_sint32_t, atomic32, );
AT_TEST_ADD_READ(ethr_sint32_t, atomic32, );
AT_TEST_ADD(ethr_sint32_t, atomic32, );
AT_TEST_INC_READ(ethr_sint32_t, atomic32, );
AT_TEST_DEC_READ(ethr_sint32_t, atomic32, );
AT_TEST_INC(ethr_sint32_t, atomic32, );
AT_TEST_DEC(ethr_sint32_t, atomic32, );
AT_TEST_READ_BAND(ethr_sint32_t, atomic32, );
AT_TEST_READ_BOR(ethr_sint32_t, atomic32, );
AT_TEST_INIT(ethr_sint32_t, atomic32, _acqb);
AT_TEST_SET(ethr_sint32_t, atomic32, _acqb);
AT_TEST_XCHG(ethr_sint32_t, atomic32, _acqb);
AT_TEST_CMPXCHG(ethr_sint32_t, atomic32, _acqb);
AT_TEST_ADD_READ(ethr_sint32_t, atomic32, _acqb);
AT_TEST_ADD(ethr_sint32_t, atomic32, _acqb);
AT_TEST_INC_READ(ethr_sint32_t, atomic32, _acqb);
AT_TEST_DEC_READ(ethr_sint32_t, atomic32, _acqb);
AT_TEST_INC(ethr_sint32_t, atomic32, _acqb);
AT_TEST_DEC(ethr_sint32_t, atomic32, _acqb);
AT_TEST_READ_BAND(ethr_sint32_t, atomic32, _acqb);
AT_TEST_READ_BOR(ethr_sint32_t, atomic32, _acqb);
AT_TEST_INIT(ethr_sint32_t, atomic32, _relb);
AT_TEST_SET(ethr_sint32_t, atomic32, _relb);
AT_TEST_XCHG(ethr_sint32_t, atomic32, _relb);
AT_TEST_CMPXCHG(ethr_sint32_t, atomic32, _relb);
AT_TEST_ADD_READ(ethr_sint32_t, atomic32, _relb);
AT_TEST_ADD(ethr_sint32_t, atomic32, _relb);
AT_TEST_INC_READ(ethr_sint32_t, atomic32, _relb);
AT_TEST_DEC_READ(ethr_sint32_t, atomic32, _relb);
AT_TEST_INC(ethr_sint32_t, atomic32, _relb);
AT_TEST_DEC(ethr_sint32_t, atomic32, _relb);
AT_TEST_READ_BAND(ethr_sint32_t, atomic32, _relb);
AT_TEST_READ_BOR(ethr_sint32_t, atomic32, _relb);
AT_TEST_INIT(ethr_sint32_t, atomic32, _rb);
AT_TEST_SET(ethr_sint32_t, atomic32, _rb);
AT_TEST_XCHG(ethr_sint32_t, atomic32, _rb);
AT_TEST_CMPXCHG(ethr_sint32_t, atomic32, _rb);
AT_TEST_ADD_READ(ethr_sint32_t, atomic32, _rb);
AT_TEST_ADD(ethr_sint32_t, atomic32, _rb);
AT_TEST_INC_READ(ethr_sint32_t, atomic32, _rb);
AT_TEST_DEC_READ(ethr_sint32_t, atomic32, _rb);
AT_TEST_INC(ethr_sint32_t, atomic32, _rb);
AT_TEST_DEC(ethr_sint32_t, atomic32, _rb);
AT_TEST_READ_BAND(ethr_sint32_t, atomic32, _rb);
AT_TEST_READ_BOR(ethr_sint32_t, atomic32, _rb);
AT_TEST_INIT(ethr_sint32_t, atomic32, _wb);
AT_TEST_SET(ethr_sint32_t, atomic32, _wb);
AT_TEST_XCHG(ethr_sint32_t, atomic32, _wb);
AT_TEST_CMPXCHG(ethr_sint32_t, atomic32, _wb);
AT_TEST_ADD_READ(ethr_sint32_t, atomic32, _wb);
AT_TEST_ADD(ethr_sint32_t, atomic32, _wb);
AT_TEST_INC_READ(ethr_sint32_t, atomic32, _wb);
AT_TEST_DEC_READ(ethr_sint32_t, atomic32, _wb);
AT_TEST_INC(ethr_sint32_t, atomic32, _wb);
AT_TEST_DEC(ethr_sint32_t, atomic32, _wb);
AT_TEST_READ_BAND(ethr_sint32_t, atomic32, _wb);
AT_TEST_READ_BOR(ethr_sint32_t, atomic32, _wb);
AT_TEST_INIT(ethr_sint32_t, atomic32, _mb);
AT_TEST_SET(ethr_sint32_t, atomic32, _mb);
AT_TEST_XCHG(ethr_sint32_t, atomic32, _mb);
AT_TEST_CMPXCHG(ethr_sint32_t, atomic32, _mb);
AT_TEST_ADD_READ(ethr_sint32_t, atomic32, _mb);
AT_TEST_ADD(ethr_sint32_t, atomic32, _mb);
AT_TEST_INC_READ(ethr_sint32_t, atomic32, _mb);
AT_TEST_DEC_READ(ethr_sint32_t, atomic32, _mb);
AT_TEST_INC(ethr_sint32_t, atomic32, _mb);
AT_TEST_DEC(ethr_sint32_t, atomic32, _mb);
AT_TEST_READ_BAND(ethr_sint32_t, atomic32, _mb);
AT_TEST_READ_BOR(ethr_sint32_t, atomic32, _mb);
AT_TEST_INIT(ethr_sint_t, atomic, );
AT_TEST_SET(ethr_sint_t, atomic, );
AT_TEST_XCHG(ethr_sint_t, atomic, );
AT_TEST_CMPXCHG(ethr_sint_t, atomic, );
AT_TEST_ADD_READ(ethr_sint_t, atomic, );
AT_TEST_ADD(ethr_sint_t, atomic, );
AT_TEST_INC_READ(ethr_sint_t, atomic, );
AT_TEST_DEC_READ(ethr_sint_t, atomic, );
AT_TEST_INC(ethr_sint_t, atomic, );
AT_TEST_DEC(ethr_sint_t, atomic, );
AT_TEST_READ_BAND(ethr_sint_t, atomic, );
AT_TEST_READ_BOR(ethr_sint_t, atomic, );
AT_TEST_INIT(ethr_sint_t, atomic, _acqb);
AT_TEST_SET(ethr_sint_t, atomic, _acqb);
AT_TEST_XCHG(ethr_sint_t, atomic, _acqb);
AT_TEST_CMPXCHG(ethr_sint_t, atomic, _acqb);
AT_TEST_ADD_READ(ethr_sint_t, atomic, _acqb);
AT_TEST_ADD(ethr_sint_t, atomic, _acqb);
AT_TEST_INC_READ(ethr_sint_t, atomic, _acqb);
AT_TEST_DEC_READ(ethr_sint_t, atomic, _acqb);
AT_TEST_INC(ethr_sint_t, atomic, _acqb);
AT_TEST_DEC(ethr_sint_t, atomic, _acqb);
AT_TEST_READ_BAND(ethr_sint_t, atomic, _acqb);
AT_TEST_READ_BOR(ethr_sint_t, atomic, _acqb);
AT_TEST_INIT(ethr_sint_t, atomic, _relb);
AT_TEST_SET(ethr_sint_t, atomic, _relb);
AT_TEST_XCHG(ethr_sint_t, atomic, _relb);
AT_TEST_CMPXCHG(ethr_sint_t, atomic, _relb);
AT_TEST_ADD_READ(ethr_sint_t, atomic, _relb);
AT_TEST_ADD(ethr_sint_t, atomic, _relb);
AT_TEST_INC_READ(ethr_sint_t, atomic, _relb);
AT_TEST_DEC_READ(ethr_sint_t, atomic, _relb);
AT_TEST_INC(ethr_sint_t, atomic, _relb);
AT_TEST_DEC(ethr_sint_t, atomic, _relb);
AT_TEST_READ_BAND(ethr_sint_t, atomic, _relb);
AT_TEST_READ_BOR(ethr_sint_t, atomic, _relb);
AT_TEST_INIT(ethr_sint_t, atomic, _rb);
AT_TEST_SET(ethr_sint_t, atomic, _rb);
AT_TEST_XCHG(ethr_sint_t, atomic, _rb);
AT_TEST_CMPXCHG(ethr_sint_t, atomic, _rb);
AT_TEST_ADD_READ(ethr_sint_t, atomic, _rb);
AT_TEST_ADD(ethr_sint_t, atomic, _rb);
AT_TEST_INC_READ(ethr_sint_t, atomic, _rb);
AT_TEST_DEC_READ(ethr_sint_t, atomic, _rb);
AT_TEST_INC(ethr_sint_t, atomic, _rb);
AT_TEST_DEC(ethr_sint_t, atomic, _rb);
AT_TEST_READ_BAND(ethr_sint_t, atomic, _rb);
AT_TEST_READ_BOR(ethr_sint_t, atomic, _rb);
AT_TEST_INIT(ethr_sint_t, atomic, _wb);
AT_TEST_SET(ethr_sint_t, atomic, _wb);
AT_TEST_XCHG(ethr_sint_t, atomic, _wb);
AT_TEST_CMPXCHG(ethr_sint_t, atomic, _wb);
AT_TEST_ADD_READ(ethr_sint_t, atomic, _wb);
AT_TEST_ADD(ethr_sint_t, atomic, _wb);
AT_TEST_INC_READ(ethr_sint_t, atomic, _wb);
AT_TEST_DEC_READ(ethr_sint_t, atomic, _wb);
AT_TEST_INC(ethr_sint_t, atomic, _wb);
AT_TEST_DEC(ethr_sint_t, atomic, _wb);
AT_TEST_READ_BAND(ethr_sint_t, atomic, _wb);
AT_TEST_READ_BOR(ethr_sint_t, atomic, _wb);
AT_TEST_INIT(ethr_sint_t, atomic, _mb);
AT_TEST_SET(ethr_sint_t, atomic, _mb);
AT_TEST_XCHG(ethr_sint_t, atomic, _mb);
AT_TEST_CMPXCHG(ethr_sint_t, atomic, _mb);
AT_TEST_ADD_READ(ethr_sint_t, atomic, _mb);
AT_TEST_ADD(ethr_sint_t, atomic, _mb);
AT_TEST_INC_READ(ethr_sint_t, atomic, _mb);
AT_TEST_DEC_READ(ethr_sint_t, atomic, _mb);
AT_TEST_INC(ethr_sint_t, atomic, _mb);
AT_TEST_DEC(ethr_sint_t, atomic, _mb);
AT_TEST_READ_BAND(ethr_sint_t, atomic, _mb);
AT_TEST_READ_BOR(ethr_sint_t, atomic, _mb);
/* Double word */
{
ethr_dw_atomic_t dw_atomic;
ethr_dw_sint_t dw0, dw1;
dw0.sint[0] = 4711;
dw0.sint[1] = 4712;
/* init */
ethr_dw_atomic_init(&dw_atomic, &dw0);
ethr_dw_atomic_read(&dw_atomic, &dw1);
ETHR_ASSERT(dw1.sint[0] == 4711);
ETHR_ASSERT(dw1.sint[1] == 4712);
/* set */
dw0.sint[0] = 42;
dw0.sint[1] = ~((ethr_sint_t) 0);
ethr_dw_atomic_set(&dw_atomic, &dw0);
ethr_dw_atomic_read(&dw_atomic, &dw1);
ASSERT(dw1.sint[0] == 42);
ASSERT(dw1.sint[1] == ~((ethr_sint_t) 0));
/* cmpxchg */
dw0.sint[0] = 17;
dw0.sint[1] = 18;
dw1.sint[0] = 19;
dw1.sint[1] = 20;
ASSERT(!ethr_dw_atomic_cmpxchg(&dw_atomic, &dw1, &dw0));
ethr_dw_atomic_read(&dw_atomic, &dw0);
ASSERT(dw0.sint[0] == 42);
ASSERT(dw0.sint[1] == ~((ethr_sint_t) 0));
ASSERT(ethr_dw_atomic_cmpxchg(&dw_atomic, &dw1, &dw0));
ethr_dw_atomic_read(&dw_atomic, &dw0);
ASSERT(dw0.sint[0] == 19);
ASSERT(dw0.sint[1] == 20);
}
}
#define AT_DW_MIN 12
#define AT_DW_MAX 42
#define AT_DW_THREADS (AT_DW_MAX - AT_DW_MIN + 1)
#define AT_DW_LOOPS 200000
#define AT_DW_R_LOOPS 10
ethr_dw_atomic_t at_dw_atomic;
void
at_dw_valid(ethr_dw_sint_t *dw)
{
int i;
char c;
char *cp;
ASSERT(dw->sint[0] == dw->sint[1]);
cp = (char *) &dw->sint[0];
c = cp[0];
ASSERT(AT_DW_MIN <= c && c <= AT_DW_MAX);
for (i = 0; i < sizeof(ethr_sint_t); i++)
ASSERT(c == cp[i]);
}
void *
at_dw_thr(void *vval)
{
int l, r;
ethr_sint_t val = (ethr_sint_t) vval;
ethr_dw_sint_t dw;
ethr_dw_sint_t my_dw;
my_dw.sint[0] = val;
my_dw.sint[1] = val;
ethr_dw_atomic_set(&at_dw_atomic, &my_dw);
for (l = 0; l < AT_DW_LOOPS; l++) {
for (r = 0; r < AT_DW_R_LOOPS; r++) {
ethr_dw_atomic_read(&at_dw_atomic, &dw);
at_dw_valid(&dw);
}
ethr_dw_atomic_set(&at_dw_atomic, &my_dw);
for (r = 0; r < AT_DW_R_LOOPS; r++) {
ethr_dw_atomic_read(&at_dw_atomic, &dw);
at_dw_valid(&dw);
}
dw.sint[0] = 0;
dw.sint[1] = 0;
while (1) {
if (ethr_dw_atomic_cmpxchg(&at_dw_atomic, &my_dw, &dw))
break;
}
}
}
static void
dw_atomic_massage_test(void)
{
int i, res;
ethr_tid tid[AT_DW_THREADS];
ethr_thr_opts thr_opts = ETHR_THR_OPTS_DEFAULT_INITER;
ethr_dw_sint_t dw;
dw.sint[0] = dw.sint[1] = 0;
ethr_dw_atomic_init(&at_dw_atomic, &dw);
for (i = AT_DW_MIN; i <= AT_DW_MAX; i++) {
ethr_sint_t val;
memset(&val, i, sizeof(ethr_sint_t));
res = ethr_thr_create(&tid[i-AT_DW_MIN], at_dw_thr, (void *) val, &thr_opts);
ASSERT(res == 0);
}
for (i = AT_DW_MIN; i <= AT_DW_MAX; i++) {
res = ethr_thr_join(tid[i-AT_DW_MIN], NULL);
ASSERT(res == 0);
}
}
void *
at_thread(void *unused)
{
int i;
long val, go;
val = ethr_atomic_inc_read(&at_ready);
ASSERT(val > 0);
ASSERT(val <= AT_THREADS);
do {
go = ethr_atomic_read(&at_go);
} while (!go);
for (i = 0; i < AT_ITER; i++) {
val = ethr_atomic_read_bor(&at_data, at_set_val);
ASSERT(val >= (i == 0 ? 0 : at_set_val) + (long) 4711);
ASSERT(val <= at_max_val);
val = ethr_atomic_read_band(&at_data, ~at_rm_val);
ASSERT(val >= at_set_val + (long) 4711);
ASSERT(val <= at_max_val);
val = ethr_atomic_read(&at_data);
ASSERT(val >= at_set_val + (long) 4711);
ASSERT(val <= at_max_val);
val = ethr_atomic_inc_read(&at_data);
ASSERT(val > at_set_val + (long) 4711);
ASSERT(val <= at_max_val);
val = ethr_atomic_dec_read(&at_data);
ASSERT(val >= at_set_val + (long) 4711);
ASSERT(val <= at_max_val);
ethr_atomic_inc(&at_data);
ethr_atomic_dec(&at_data);
val = ethr_atomic_add_read(&at_data, (long) 4711);
ASSERT(val >= at_set_val + (long) 2*4711);
ASSERT(val <= at_max_val);
ethr_atomic_add(&at_data, (long) -4711);
ASSERT(val >= at_set_val + (long) 4711);
ASSERT(val <= at_max_val);
}
ethr_atomic_inc(&at_done);
return NULL;
}
static void
atomic_test(void)
{
long data_init, data_final, val;
int res, i;
ethr_tid tid[AT_THREADS];
ethr_thr_opts thr_opts = ETHR_THR_OPTS_DEFAULT_INITER;
atomic_basic_test();
#if ETHR_SIZEOF_PTR > 4
at_rm_val = ((long) 1) << 57;
at_set_val = ((long) 1) << 60;
#else
at_rm_val = ((long) 1) << 27;
at_set_val = ((long) 1) << 30;
#endif
at_max_val = at_set_val + at_rm_val + ((long) AT_THREADS + 1) * 4711;
data_init = at_rm_val + (long) 4711;
data_final = at_set_val + (long) 4711;
thr_opts.detached = 1;
print_line("Initializing");
ethr_atomic_init(&at_ready, 0);
ethr_atomic_init(&at_go, 0);
ethr_atomic_init(&at_done, data_init);
ethr_atomic_init(&at_data, data_init);
val = ethr_atomic_read(&at_data);
ASSERT(val == data_init);
ethr_atomic_set(&at_done, 0);
val = ethr_atomic_read(&at_done);
ASSERT(val == 0);
print_line("Creating threads");
for (i = 0; i < AT_THREADS; i++) {
res = ethr_thr_create(&tid[i], at_thread, NULL, &thr_opts);
ASSERT(res == 0);
}
print_line("Waiting for threads to ready up");
do {
val = ethr_atomic_read(&at_ready);
ASSERT(val >= 0);
ASSERT(val <= AT_THREADS);
} while (val != AT_THREADS);
print_line("Letting threads loose");
val = ethr_atomic_xchg(&at_go, 17);
ASSERT(val == 0);
val = ethr_atomic_read(&at_go);
ASSERT(val == 17);
print_line("Waiting for threads to finish");
do {
val = ethr_atomic_read(&at_done);
ASSERT(val >= 0);
ASSERT(val <= AT_THREADS);
} while (val != AT_THREADS);
print_line("Checking result");
val = ethr_atomic_read(&at_data);
ASSERT(res == 0);
ASSERT(val == data_final);
print_line("Result ok");
}
#endif /* #ifndef ETHR_NO_THREAD_LIB */
/* * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * *
* The dispatcher *
\* */
int
main(int argc, char *argv[])
{
if (argc < 2)
fail("To few arguments for test case");
#ifndef ETHR_NO_THREAD_LIB
{
char *testcase;
send_my_pid();
testcase = argv[1];
if (ethr_init(NULL) != 0 || ethr_late_init(NULL) != 0)
fail("Failed to initialize the ethread library");
if (strcmp(testcase, "create_join_thread") == 0)
create_join_thread_test();
else if (strcmp(testcase, "equal_tids") == 0)
equal_tids_test();
else if (strcmp(testcase, "mutex") == 0)
mutex_test();
else if (strcmp(testcase, "try_lock_mutex") == 0)
try_lock_mutex_test();
else if (strcmp(testcase, "cond_wait") == 0)
cond_wait_test();
else if (strcmp(testcase, "broadcast") == 0)
broadcast_test();
else if (strcmp(testcase, "detached_thread") == 0)
detached_thread_test();
else if (strcmp(testcase, "max_threads") == 0)
max_threads_test();
else if (strcmp(testcase, "tsd") == 0)
tsd_test();
else if (strcmp(testcase, "spinlock") == 0)
spinlock_test();
else if (strcmp(testcase, "rwspinlock") == 0)
rwspinlock_test();
else if (strcmp(testcase, "rwmutex") == 0)
rwmutex_test();
else if (strcmp(testcase, "atomic") == 0)
atomic_test();
else if (strcmp(testcase, "dw_atomic_massage") == 0)
dw_atomic_massage_test();
else
skip("Test case \"%s\" not implemented yet", testcase);
succeed(NULL);
}
#else /* #ifndef ETHR_NO_THREAD_LIB */
skip("No ethread library to test");
#endif /* #ifndef ETHR_NO_THREAD_LIB */
return 0;
}