/* Test the mthreads library. When the library is compiled with -DMDEBUG, you * have to compile this test with -DMDEBUG as well or it won't link. MDEBUG * lets you check the internal integrity of the library. */ #include #include #define thread_t mthread_thread_t #define mutex_t mthread_mutex_t #define cond_t mthread_cond_t #define once_t mthread_once_t #define attr_t mthread_attr_t #define MAX_ERROR 5 #include "common.c" PUBLIC int errct; PRIVATE int count, condition_met; PRIVATE int th_a, th_b, th_c, th_d, th_e, th_f, th_g, th_h; PRIVATE int mutex_a_step, mutex_b_step, mutex_c_step; PRIVATE mutex_t mu[3]; PRIVATE cond_t condition; PRIVATE mutex_t *count_mutex, *condition_mutex; PRIVATE once_t once; #define VERIFY_MUTEX(a,b,c,esub,eno) do { \ if (mutex_a_step != a) { \ printf("Expected %d %d %d, got: %d %d %d\n", \ a, b, c, mutex_a_step, mutex_b_step, mutex_c_step); \ err(esub, eno); \ } else if (mutex_b_step != b) err(esub, eno); \ else if (mutex_c_step != c) err(esub, eno); \ } while(0) #define ROUNDS 14 #define THRESH1 3 #define THRESH2 8 #define MEG 1024*1024 #define MAGIC 0xb4a3f1c2 FORWARD _PROTOTYPE( void thread_a, (void *arg) ); FORWARD _PROTOTYPE( void thread_b, (void *arg) ); FORWARD _PROTOTYPE( void thread_c, (void *arg) ); FORWARD _PROTOTYPE( void thread_d, (void *arg) ); FORWARD _PROTOTYPE( void thread_e, (void) ); FORWARD _PROTOTYPE( void thread_f, (void *arg) ); FORWARD _PROTOTYPE( void thread_g, (void *arg) ); FORWARD _PROTOTYPE( void thread_h, (void *arg) ); FORWARD _PROTOTYPE( void test_scheduling, (void) ); FORWARD _PROTOTYPE( void test_mutex, (void) ); FORWARD _PROTOTYPE( void test_condition, (void) ); FORWARD _PROTOTYPE( void test_attributes, (void) ); FORWARD _PROTOTYPE( void err, (int subtest, int error) ); /*===========================================================================* * thread_a * *===========================================================================*/ PRIVATE void thread_a(void *arg) { th_a++; } /*===========================================================================* * thread_b * *===========================================================================*/ PRIVATE void thread_b(void *arg) { th_b++; if (mthread_once(&once, thread_e) != 0) err(10, 1); } /*===========================================================================* * thread_c * *===========================================================================*/ PRIVATE void thread_c(void *arg) { th_c++; } /*===========================================================================* * thread_d * *===========================================================================*/ PRIVATE void thread_d(void *arg) { th_d++; mthread_exit(NULL); /* Thread wants to stop running */ } /*===========================================================================* * thread_e * *===========================================================================*/ PRIVATE void thread_e(void) { th_e++; } /*===========================================================================* * thread_f * *===========================================================================*/ PRIVATE void thread_f(void *arg) { if (mthread_mutex_lock(condition_mutex) != 0) err(12, 1); th_f++; if (mthread_cond_signal(&condition) != 0) err(12, 2); if (mthread_mutex_unlock(condition_mutex) != 0) err(12, 3); } /*===========================================================================* * thread_g * *===========================================================================*/ PRIVATE void thread_g(void *arg) { char bigarray[MTHREAD_STACK_MIN + 1]; if (mthread_mutex_lock(condition_mutex) != 0) err(13, 1); memset(bigarray, '\0', MTHREAD_STACK_MIN + 1); /* Actually allocate it */ th_g++; if (mthread_cond_signal(&condition) != 0) err(13, 2); if (mthread_mutex_unlock(condition_mutex) != 0) err(13, 3); } /*===========================================================================* * thread_h * *===========================================================================*/ PRIVATE void thread_h(void *arg) { char bigarray[2 * MEG]; int reply; if (mthread_mutex_lock(condition_mutex) != 0) err(14, 1); memset(bigarray, '\0', 2 * MEG); /* Actually allocate it */ th_h++; if (mthread_cond_signal(&condition) != 0) err(14, 2); if (mthread_mutex_unlock(condition_mutex) != 0) err(14, 3); reply = *((int *) arg); mthread_exit((void *) reply); } /*===========================================================================* * err * *===========================================================================*/ PRIVATE void err(int sub, int error) { /* As we're running with multiple threads, they might all clobber the * subtest variable. This wrapper prevents that from happening. */ subtest = sub; e(error); } /*===========================================================================* * test_scheduling * *===========================================================================*/ PRIVATE void test_scheduling(void) { int i; thread_t t[7]; #ifdef MDEBUG mthread_verify(); #endif th_a = th_b = th_c = th_d = th_e = 0; if (mthread_create(&t[0], NULL, thread_a, NULL) != 0) err(1, 1); if (mthread_create(&t[1], NULL, thread_a, NULL) != 0) err(1, 2); if (mthread_create(&t[2], NULL, thread_a, NULL) != 0) err(1, 3); if (mthread_create(&t[3], NULL, thread_d, NULL) != 0) err(1, 4); if (mthread_once(&once, thread_e) != 0) err(1, 5); mthread_yield(); if (mthread_create(&t[4], NULL, thread_c, NULL) != 0) err(1, 6); mthread_yield(); if (mthread_create(&t[5], NULL, thread_b, NULL) != 0) err(1, 7); if (mthread_create(&t[6], NULL, thread_a, NULL) != 0) err(1, 8); mthread_yield(); mthread_yield(); if (mthread_once(&once, thread_e) != 0) err(1, 9); if (mthread_once(&once, thread_e) != 0) err(1, 10); if (th_a != 4) err(1, 11); if (th_b != 1) err(1, 12); if (th_c != 1) err(1, 13); if (th_d != 1) err(1, 14); if (th_e != 1) err(1, 15); for (i = 0; i < (sizeof(t) / sizeof(thread_t)); i++) { if (mthread_join(t[i], NULL) != 0) err(1, 16); if (mthread_join(t[i], NULL) == 0) err(1, 17); /*Shouldn't work twice*/ } #ifdef MDEBUG mthread_verify(); #endif if (mthread_create(NULL, NULL, NULL, NULL) == 0) err(1, 18); mthread_yield(); #ifdef MDEBUG mthread_verify(); #endif if (mthread_create(&t[6], NULL, NULL, NULL) == 0) err(1, 19); mthread_yield(); #ifdef MDEBUG mthread_verify(); #endif if (mthread_join(0xc0ffee, NULL) == 0) err(1, 20); mthread_yield(); mthread_yield(); #ifdef MDEBUG mthread_verify(); #endif } /*===========================================================================* * mutex_a * *===========================================================================*/ PRIVATE void mutex_a(void *arg) { mutex_t *mu = (mutex_t *) arg; mutex_t mu2; VERIFY_MUTEX(0, 0, 0, 3, 1); if (mthread_mutex_lock(&mu[0]) != 0) err(3, 2); /* Trying to acquire lock again should fail with EDEADLK */ if (mthread_mutex_lock(&mu[0]) != EDEADLK) err(3, 2); #ifdef MTHREAD_STRICT /* Try to acquire lock on uninitialized mutex; should fail with EINVAL */ /* Note: this check only works when libmthread is compiled with * MTHREAD_STRICT turned on. In POSIX this situation is a MAY fail if... */ if (mthread_mutex_lock(&mu2) != EINVAL) { err(3, 4); mthread_mutex_unlock(&mu2); } if (mthread_mutex_trylock(&mu2) != EINVAL) { err(3, 6); mthread_mutex_unlock(&mu2); } #endif if (mthread_mutex_trylock(&mu[1]) != 0) err(3, 8); mutex_a_step = 1; mthread_yield(); VERIFY_MUTEX(1, 0, 0, 3, 9); if (mthread_mutex_trylock(&mu[2]) != EBUSY) err(3, 10); if (mthread_mutex_lock(&mu[2]) != 0) err(3, 12); /* Transfer control to main * loop. */ VERIFY_MUTEX(1, 0, 0, 3, 13); if (mthread_mutex_unlock(&mu[0]) != 0) err(3, 14); mutex_a_step = 2; mthread_yield(); VERIFY_MUTEX(2, 1, 0, 3, 15); if (mthread_mutex_unlock(&mu[1]) != 0) err(3, 16); mutex_a_step = 3; /* Try with faulty memory locations */ if (mthread_mutex_lock(NULL) == 0) err(3, 17); if (mthread_mutex_trylock(NULL) == 0) err(3, 18); if (mthread_mutex_unlock(NULL) == 0) err(3, 19); if (mthread_mutex_unlock(&mu[2]) != 0) err(3, 20); } /*===========================================================================* * mutex_b * *===========================================================================*/ PRIVATE void mutex_b(void *arg) { mutex_t *mu = (mutex_t *) arg; /* At this point mutex_a thread should have acquired a lock on mu[0]. We * should not be able to unlock it on behalf of that thread. */ VERIFY_MUTEX(1, 0, 0, 4, 1); if (mthread_mutex_unlock(&mu[0]) != EPERM) err(4, 2); /* Probing mu[0] to lock it should tell us it's locked */ if (mthread_mutex_trylock(&mu[0]) != EBUSY) err(4, 4); if (mthread_mutex_lock(&mu[0]) != 0) err(4, 5); mutex_b_step = 1; VERIFY_MUTEX(2, 1, 0, 4, 6); if (mthread_mutex_lock(&mu[1]) != 0) err(4, 6); mutex_b_step = 2; VERIFY_MUTEX(3, 2, 2, 4, 7); mthread_yield(); VERIFY_MUTEX(3, 2, 2, 4, 8); if (mthread_mutex_unlock(&mu[0]) != 0) err(4, 7); mutex_b_step = 3; mthread_yield(); if (mthread_mutex_unlock(&mu[1]) != 0) err(4, 8); mutex_b_step = 4; } /*===========================================================================* * mutex_c * *===========================================================================*/ PRIVATE void mutex_c(void *arg) { mutex_t *mu = (mutex_t *) arg; VERIFY_MUTEX(1, 0, 0, 5, 1); if (mthread_mutex_lock(&mu[1]) != 0) err(5, 2); mutex_c_step = 1; VERIFY_MUTEX(3, 1, 1, 5, 3); mthread_yield(); VERIFY_MUTEX(3, 1, 1, 5, 4); if (mthread_mutex_unlock(&mu[1]) != 0) err(5, 5); mutex_c_step = 2; if (mthread_mutex_lock(&mu[0]) != 0) err(5, 6); mutex_c_step = 3; VERIFY_MUTEX(3, 3, 3, 5, 7); mthread_yield(); VERIFY_MUTEX(3, 4, 3, 5, 8); if (mthread_mutex_unlock(&mu[0]) != 0) err(5, 9); mutex_c_step = 4; } /*===========================================================================* * test_mutex * *===========================================================================*/ PRIVATE void test_mutex(void) { int i; thread_t t[3]; #ifdef MDEBUG mthread_verify(); #endif if (mthread_mutex_init(&mu[0], NULL) != 0) err(2, 1); if (mthread_mutex_init(&mu[1], NULL) != 0) err(2, 2); if (mthread_mutex_init(&mu[2], NULL) != 0) err(2, 3); if (mthread_create(&t[0], NULL, mutex_a, (void *) mu) != 0) err(2, 3); if (mthread_create(&t[1], NULL, mutex_b, (void *) mu) != 0) err(2, 4); if (mthread_create(&t[2], NULL, mutex_c, (void *) mu) != 0) err(2, 5); if (mthread_mutex_lock(&mu[2]) != 0) err(2, 6); mthread_yield_all(); /* Should result in a RUNNABLE mutex_a, and a blocked * on mutex mutex_b and mutex_c. */ VERIFY_MUTEX(1, 0, 0, 2, 7); /* err(2, 7) */ if (mthread_mutex_unlock(&mu[2]) != 0) err(2, 8); mthread_yield(); /* Should schedule mutex_a to release the lock on the * mu[0] mutex. Consequently allowing mutex_b and mutex_c * to acquire locks on the mutexes and exit. */ VERIFY_MUTEX(2, 0, 0, 2, 9); for (i = 0; i < (sizeof(t) / sizeof(thread_t)); i++) if (mthread_join(t[i], NULL) != 0) err(2, 10); if (mthread_mutex_destroy(&mu[0]) != 0) err(2, 11); if (mthread_mutex_destroy(&mu[1]) != 0) err(2, 12); if (mthread_mutex_destroy(&mu[2]) != 0) err(2, 13); #ifdef MDEBUG mthread_verify(); #endif } /*===========================================================================* * cond_a * *===========================================================================*/ PRIVATE void cond_a(void *arg) { cond_t c; int did_count = 0; while(1) { if (mthread_mutex_lock(condition_mutex) != 0) err(6, 1); while (count >= THRESH1 && count <= THRESH2) { if (mthread_cond_wait(&condition, condition_mutex) != 0) err(6, 2); } if (mthread_mutex_unlock(condition_mutex) != 0) err(6, 3); mthread_yield(); if (mthread_mutex_lock(count_mutex) != 0) err(6, 4); count++; did_count++; if (mthread_mutex_unlock(count_mutex) != 0) err(6, 5); if (count >= ROUNDS) break; } if (!(did_count <= count - (THRESH2 - THRESH1 + 1))) err(6, 6); /* Try faulty addresses */ if (mthread_mutex_lock(condition_mutex) != 0) err(6, 7); /* Condition c is not initialized, so whatever we do with it should fail. */ if (mthread_cond_wait(&c, condition_mutex) == 0) err(6, 8); if (mthread_cond_wait(NULL, condition_mutex) == 0) err(6, 9); if (mthread_cond_signal(&c) == 0) err(6, 10); if (mthread_mutex_unlock(condition_mutex) != 0) err(6, 11); /* Try again with an unlocked mutex */ if (mthread_cond_wait(&c, condition_mutex) == 0) err(6, 12); if (mthread_cond_signal(&c) == 0) err(6, 13); /* And again with an unlocked mutex, but initialized c */ if (mthread_cond_init(&c, NULL) != 0) err(6, 14); if (mthread_cond_wait(&c, condition_mutex) == 0) err(6, 15); if (mthread_cond_signal(&c) != 0) err(6, 16);/*c.f., 6.10 this should work!*/ if (mthread_cond_destroy(&c) != 0) err(6, 17); } /*===========================================================================* * cond_b * *===========================================================================*/ PRIVATE void cond_b(void *arg) { int did_count = 0; while(1) { if (mthread_mutex_lock(condition_mutex) != 0) err(7, 1); if (count < THRESH1 || count > THRESH2) if (mthread_cond_signal(&condition) != 0) err(7, 2); if (mthread_mutex_unlock(condition_mutex) != 0) err(7, 3); mthread_yield(); if (mthread_mutex_lock(count_mutex) != 0) err(7, 4); count++; did_count++; if (mthread_mutex_unlock(count_mutex) != 0) err(7, 5); if (count >= ROUNDS) break; } if (!(did_count >= count - (THRESH2 - THRESH1 + 1))) err(7, 6); } /*===========================================================================* * cond_broadcast * *===========================================================================*/ PRIVATE void cond_broadcast(void *arg) { int rounds = 0; if (mthread_mutex_lock(condition_mutex) != 0) err(9, 1); while(!condition_met) if (mthread_cond_wait(&condition, condition_mutex) != 0) err(9, 2); if (mthread_mutex_unlock(condition_mutex) != 0) err(9, 3); if (mthread_mutex_lock(count_mutex) != 0) err(9, 4); count++; if (mthread_mutex_unlock(count_mutex) != 0) err(9, 5); } /*===========================================================================* * test_condition * *===========================================================================*/ PRIVATE void test_condition(void) { #define NTHREADS 10 int i, r; thread_t t[2], s[NTHREADS]; count_mutex = &mu[0]; condition_mutex = &mu[1]; /* Test simple condition variable behavior: Two threads increase a counter. * At some point one thread waits for a condition and the other thread * signals the condition. Consequently, one thread increased the counter a * few times less than other thread. Although the difference is 'random', * there is a guaranteed minimum difference that we can measure. */ #ifdef MDEBUG mthread_verify(); #endif if (mthread_mutex_init(count_mutex, NULL) != 0) err(8, 1); if (mthread_mutex_init(condition_mutex, NULL) != 0) err(8, 2); if (mthread_cond_init(&condition, NULL) != 0) err(8, 3); count = 0; if (mthread_create(&t[0], NULL, cond_a, NULL) != 0) err(8, 4); if (mthread_create(&t[1], NULL, cond_b, NULL) != 0) err(8, 5); for (i = 0; i < (sizeof(t) / sizeof(thread_t)); i++) if (mthread_join(t[i], NULL) != 0) err(8, 6); if (mthread_mutex_destroy(count_mutex) != 0) err(8, 7); if (mthread_mutex_destroy(condition_mutex) != 0) err(8, 8); if (mthread_cond_destroy(&condition) != 0) err(8, 9); #ifdef MTHREAD_STRICT /* Let's try to destroy it again. Should fails as it's uninitialized. */ /* Note: this only works when libmthread is compiled with MTHREAD_STRICT. In * POSIX this situation is a MAY fail if... */ if (mthread_cond_destroy(&condition) == 0) err(8, 10); #endif #ifdef MDEBUG mthread_verify(); #endif /* Test signal broadcasting: spawn N threads that will increase a counter * after a condition has been signaled. The counter must equal N. */ if (mthread_mutex_init(count_mutex, NULL) != 0) err(8, 11); if (mthread_mutex_init(condition_mutex, NULL) != 0) err(8, 12); if (mthread_cond_init(&condition, NULL) != 0) err(8, 13); condition_met = count = 0; for (i = 0; i < NTHREADS; i++) if (mthread_create(&s[i], NULL, cond_broadcast, NULL) != 0) err(8, 14); /* Allow other threads to block on the condition variable. If we don't yield, * the threads will only start running when we call mthread_join below. In * that case the while loop in cond_broadcast will never evaluate to true. */ mthread_yield(); if (mthread_mutex_lock(condition_mutex) != 0) err(8, 15); condition_met = 1; if (mthread_cond_broadcast(&condition) != 0) err(8, 16); if (mthread_mutex_unlock(condition_mutex) != 0) err(8, 17); for (i = 0; i < (sizeof(s) / sizeof(thread_t)); i++) if (mthread_join(s[i], NULL) != 0) err(8, 18); if (count != NTHREADS) err(8, 19); if (mthread_mutex_destroy(count_mutex) != 0) err(8, 20); if (mthread_mutex_destroy(condition_mutex) != 0) err(8, 21); if (mthread_cond_destroy(&condition) != 0) err(8, 22); #ifdef MTHREAD_STRICT /* Again, destroying the condition variable twice shouldn't work */ /* See previous note about MTHREAD_STRICT */ if (mthread_cond_destroy(&condition) == 0) err(8, 23); #endif #ifdef MDEBUG mthread_verify(); #endif } /*===========================================================================* * test_attributes * *===========================================================================*/ PRIVATE void test_attributes(void) { attr_t tattr; thread_t tid; int detachstate = -1, status = 0; int i, no_ints, stack_untouched = 1; void *stackaddr, *newstackaddr; int *stackp; size_t stacksize, newstacksize; #ifdef MDEBUG mthread_verify(); #endif /* Initialize thread attribute and try to read the default values */ if (mthread_attr_init(&tattr) != 0) err(11, 1); if (mthread_attr_getdetachstate(&tattr, &detachstate) != 0) err(11, 2); if (detachstate != MTHREAD_CREATE_JOINABLE) err(11, 3); if (mthread_attr_getstack(&tattr, &stackaddr, &stacksize) != 0) err(11, 4); if (stackaddr != NULL) err(11, 5); if (stacksize != (size_t) 0) err(11, 6); /* Modify the attribute ... */ /* Try bogus detach state value */ if (mthread_attr_setdetachstate(&tattr, 0xc0ffee) == 0) err(11, 7); if (mthread_attr_setdetachstate(&tattr, MTHREAD_CREATE_DETACHED) != 0) err(11, 8); newstacksize = (size_t) MEG; if ((newstackaddr = malloc(newstacksize)) == NULL) err(11, 9); if (mthread_attr_setstack(&tattr, newstackaddr, newstacksize) != 0) err(11, 10); /* ... and read back the new values. */ if (mthread_attr_getdetachstate(&tattr, &detachstate) != 0) err(11, 11); if (detachstate != MTHREAD_CREATE_DETACHED) err(11, 12); if (mthread_attr_getstack(&tattr, &stackaddr, &stacksize) != 0) err(11, 13); if (stackaddr != newstackaddr) err(11, 14); if (stacksize != newstacksize) err(11, 15); if (mthread_attr_destroy(&tattr) != 0) err(11, 16); /* Freeing the stack. Note that this is only possible because it wasn't * actually used yet by a thread. If it was, mthread would clean it up after * usage and this free would do something undefined. */ free(newstackaddr); /* Try to allocate too small a stack; it should fail and the attribute * values should remain as is. */ newstacksize = MTHREAD_STACK_MIN - 1; stackaddr = NULL; stacksize = 0; if (mthread_attr_init(&tattr) != 0) err(11, 17); if ((newstackaddr = malloc(newstacksize)) == NULL) err(11, 18); if (mthread_attr_setstack(&tattr, newstackaddr, newstacksize) != EINVAL) err(11, 19); if (mthread_attr_getstack(&tattr, &stackaddr, &stacksize) != 0) err(11, 21); if (stackaddr == newstackaddr) err(11, 22); if (stacksize == newstacksize) err(11, 23); if (mthread_attr_destroy(&tattr) != 0) err(11, 24); /* Again, freeing because we can. Shouldn't do it if it was actually used. */ free(newstackaddr); /* Tell attribute to let the system allocate a stack for the thread and only * dictate how big that stack should be (2 megabyte, not actually allocated * yet). */ if (mthread_attr_init(&tattr) != 0) err(11, 25); if (mthread_attr_setstack(&tattr, NULL /* System allocated */, 2*MEG) != 0) err(11, 26); if (mthread_attr_getstack(&tattr, &stackaddr, &stacksize) != 0) err(11, 27); if (stackaddr != NULL) err(11, 28); if (stacksize != 2*MEG) err(11, 29); /* Use set/getstacksize to set and retrieve new stack sizes */ stacksize = 0; if (mthread_attr_getstacksize(&tattr, &stacksize) != 0) err(11, 30); if (stacksize != 2*MEG) err(11, 31); newstacksize = MEG; if (mthread_attr_setstacksize(&tattr, newstacksize) != 0) err(11, 32); if (mthread_attr_getstacksize(&tattr, &stacksize) != 0) err(11, 33); if (stacksize != newstacksize) err(11, 34); if (mthread_attr_destroy(&tattr) != 0) err(11, 35); /* Perform same tests, but also actually use them in a thread */ if (mthread_attr_init(&tattr) != 0) err(11, 36); if (mthread_attr_setdetachstate(&tattr, MTHREAD_CREATE_DETACHED) != 0) err(11, 37); condition_mutex = &mu[0]; if (mthread_mutex_init(condition_mutex, NULL) != 0) err(11, 38); if (mthread_cond_init(&condition, NULL) != 0) err(11, 39); if (mthread_mutex_lock(condition_mutex) != 0) err(11, 40); if (mthread_create(&tid, &tattr, thread_f, NULL) != 0) err(11, 41); /* Wait for thread_f to finish */ if (mthread_cond_wait(&condition, condition_mutex) != 0) err(11, 42); if (mthread_mutex_unlock(condition_mutex) != 0) err(11, 43); if (th_f != 1) err(11, 44); /* Joining a detached thread should fail */ if (mthread_join(tid, NULL) == 0) err(11, 45); if (mthread_attr_destroy(&tattr) != 0) err(11, 46); /* Try telling the attribute how large the stack should be */ if (mthread_attr_init(&tattr) != 0) err(11, 47); if (mthread_attr_setstack(&tattr, NULL, 2 * MTHREAD_STACK_MIN) != 0) err(11, 48); if (mthread_mutex_lock(condition_mutex) != 0) err(11, 49); if (mthread_create(&tid, &tattr, thread_g, NULL) != 0) err(11, 50); /* Wait for thread_g to finish */ if (mthread_cond_wait(&condition, condition_mutex) != 0) err(11, 51); if (mthread_mutex_unlock(condition_mutex) != 0) err(11, 52); if (th_g != 1) err(11, 53); if (mthread_attr_setdetachstate(&tattr, MTHREAD_CREATE_DETACHED) != 0) err(11, 54); /* Shouldn't affect the join below, as thread is already * running as joinable. If this attribute should be * modified after thread creation, use mthread_detach(). */ if (mthread_join(tid, NULL) != 0) err(11, 55); if (mthread_attr_destroy(&tattr) != 0) err(11, 56); /* Try telling the attribute how large the stack should be and where it is * located. */ if (mthread_attr_init(&tattr) != 0) err(11, 57); stacksize = 3 * MEG; /* Make sure this test is meaningful. We have to verify that we actually * use a custom stack. So we're going to allocate an array on the stack in * thread_h that should at least be bigger than the default stack size * allocated by the system. */ if (2 * MEG <= MTHREAD_STACK_MIN) err(11, 58); if ((stackaddr = malloc(stacksize)) == NULL) err(11, 59); /* Fill stack with pattern. We assume that the beginning of the stack * should be overwritten with something and that the end should remain * untouched. The thread will zero-fill around two-thirds of the stack with * zeroes, so we can check if that's true. */ stackp = stackaddr; no_ints = stacksize / sizeof(int); for (i = 0; i < no_ints ; i++) stackp[i] = MAGIC; if (mthread_attr_setstack(&tattr, stackaddr, stacksize) != 0) err(11, 60); if (mthread_mutex_lock(condition_mutex) != 0) err(11, 61); if (mthread_create(&tid, &tattr, thread_h, (void *) &stacksize) != 0) err(11, 62); /* Wait for thread h to finish */ if (mthread_cond_wait(&condition, condition_mutex) != 0) err(11, 63); if (th_h != 1) err(11, 64); if (mthread_mutex_unlock(condition_mutex) != 0) err(11, 65); /* Verify stack hypothesis; we assume a stack is used from the top and grows * downwards. At this point the stack should still exist, because we haven't * 'joined' yet. After joining, the stack is cleaned up and this test becomes * useless. */ #if (_MINIX_CHIP == _CHIP_INTEL) if (stackp[0] != MAGIC) err(11, 66); /* End of the stack */ for (i = no_ints - 1 - 16; i < no_ints; i++) if (stackp[i] != MAGIC) stack_untouched = 0; if (stack_untouched) err(11, 67); /* Beginning of the stack */ if (stackp[no_ints / 2] != 0) err(11, 68);/*Zero half way through the stack*/ #else #error "Unsupported chip for this test" #endif if (mthread_join(tid, (void *) &status) != 0) err(11, 69); if (status != stacksize) err(11, 70); if (mthread_attr_destroy(&tattr) != 0) err(11, 71); if (mthread_mutex_destroy(condition_mutex) != 0) err(11, 72); if (mthread_cond_destroy(&condition) != 0) err(11, 73); #ifdef MDEBUG mthread_verify(); #endif } /*===========================================================================* * main * *===========================================================================*/ int main(void) { errct = 0; th_a = th_b = th_c = th_d = th_e = th_f = th_g = th_h = 0; mutex_a_step = mutex_b_step = mutex_c_step = 0; once = MTHREAD_ONCE_INIT; start(59); mthread_init(); test_scheduling(); test_mutex(); test_condition(); test_attributes(); quit(); }