#include #include #define KZT_SUBSYSTEM_RWLOCK 0x0700 #define KZT_RWLOCK_NAME "rwlock" #define KZT_RWLOCK_DESC "Kernel RW Lock Tests" #define KZT_RWLOCK_TEST1_ID 0x0701 #define KZT_RWLOCK_TEST1_NAME "rwtest1" #define KZT_RWLOCK_TEST1_DESC "Multiple Readers One Writer" #define KZT_RWLOCK_TEST2_ID 0x0702 #define KZT_RWLOCK_TEST2_NAME "rwtest2" #define KZT_RWLOCK_TEST2_DESC "Multiple Writers" #define KZT_RWLOCK_TEST3_ID 0x0703 #define KZT_RWLOCK_TEST3_NAME "rwtest3" #define KZT_RWLOCK_TEST3_DESC "Owner Verification" #define KZT_RWLOCK_TEST4_ID 0x0704 #define KZT_RWLOCK_TEST4_NAME "rwtest4" #define KZT_RWLOCK_TEST4_DESC "Trylock Test" #define KZT_RWLOCK_TEST5_ID 0x0705 #define KZT_RWLOCK_TEST5_NAME "rwtest5" #define KZT_RWLOCK_TEST5_DESC "Write Downgrade Test" #define KZT_RWLOCK_TEST6_ID 0x0706 #define KZT_RWLOCK_TEST6_NAME "rwtest6" #define KZT_RWLOCK_TEST6_DESC "Read Upgrade Test" #define KZT_RWLOCK_TEST_MAGIC 0x115599DDUL #define KZT_RWLOCK_TEST_NAME "rwlock_test" #define KZT_RWLOCK_TEST_COUNT 8 #define KZT_RWLOCK_RELEASE_INIT 0 #define KZT_RWLOCK_RELEASE_WRITERS 1 #define KZT_RWLOCK_RELEASE_READERS 2 typedef struct rw_priv { unsigned long rw_magic; struct file *rw_file; krwlock_t rwl; spinlock_t rw_priv_lock; wait_queue_head_t rw_waitq; atomic_t rw_completed; atomic_t rw_acquired; atomic_t rw_waiters; atomic_t rw_release; } rw_priv_t; typedef struct rw_thr { int rwt_id; const char *rwt_name; rw_priv_t *rwt_rwp; int rwt_rc; } rw_thr_t; static inline void kzt_rwlock_sleep(signed long delay) { set_current_state(TASK_INTERRUPTIBLE); schedule_timeout(delay); } #define kzt_rwlock_lock_and_test(lock,test) \ ({ \ int ret = 0; \ \ spin_lock(lock); \ ret = (test) ? 1 : 0; \ spin_unlock(lock); \ ret; \ }) void kzt_init_rw_priv(rw_priv_t *rwv, struct file *file) { rwv->rw_magic = KZT_RWLOCK_TEST_MAGIC; rwv->rw_file = file; spin_lock_init(&rwv->rw_priv_lock); init_waitqueue_head(&rwv->rw_waitq); atomic_set(&rwv->rw_completed, 0); atomic_set(&rwv->rw_acquired, 0); atomic_set(&rwv->rw_waiters, 0); atomic_set(&rwv->rw_release, KZT_RWLOCK_RELEASE_INIT); /* Initialize the read/write lock */ rw_init(&rwv->rwl, KZT_RWLOCK_TEST_NAME, RW_DEFAULT, NULL); } int kzt_rwlock_test1_writer_thread(void *arg) { rw_thr_t *rwt = (rw_thr_t *)arg; rw_priv_t *rwv = rwt->rwt_rwp; uint8_t rnd = 0; char name[16]; ASSERT(rwv->rw_magic == KZT_RWLOCK_TEST_MAGIC); snprintf(name, sizeof(name), "%s%d", KZT_RWLOCK_TEST_NAME, rwt->rwt_id); daemonize(name); get_random_bytes((void *)&rnd, 1); kzt_rwlock_sleep(rnd * HZ / 1000); spin_lock(&rwv->rw_priv_lock); kzt_vprint(rwv->rw_file, rwt->rwt_name, "%s writer thread trying to acquire rwlock with " "%d holding lock and %d waiting\n", name, atomic_read(&rwv->rw_acquired), atomic_read(&rwv->rw_waiters)); atomic_inc(&rwv->rw_waiters); spin_unlock(&rwv->rw_priv_lock); /* Take the semaphore for writing * release it when we are told to */ rw_enter(&rwv->rwl, RW_WRITER); spin_lock(&rwv->rw_priv_lock); atomic_dec(&rwv->rw_waiters); atomic_inc(&rwv->rw_acquired); kzt_vprint(rwv->rw_file, rwt->rwt_name, "%s writer thread acquired rwlock with " "%d holding lock and %d waiting\n", name, atomic_read(&rwv->rw_acquired), atomic_read(&rwv->rw_waiters)); spin_unlock(&rwv->rw_priv_lock); /* Wait here until the control thread * says we can release the write lock */ wait_event_interruptible(rwv->rw_waitq, kzt_rwlock_lock_and_test(&rwv->rw_priv_lock, atomic_read(&rwv->rw_release) == KZT_RWLOCK_RELEASE_WRITERS)); spin_lock(&rwv->rw_priv_lock); atomic_inc(&rwv->rw_completed); atomic_dec(&rwv->rw_acquired); kzt_vprint(rwv->rw_file, rwt->rwt_name, "%s writer thread dropped rwlock with " "%d holding lock and %d waiting\n", name, atomic_read(&rwv->rw_acquired), atomic_read(&rwv->rw_waiters)); spin_unlock(&rwv->rw_priv_lock); /* Release the semaphore */ rw_exit(&rwv->rwl); return 0; } int kzt_rwlock_test1_reader_thread(void *arg) { rw_thr_t *rwt = (rw_thr_t *)arg; rw_priv_t *rwv = rwt->rwt_rwp; uint8_t rnd = 0; char name[16]; ASSERT(rwv->rw_magic == KZT_RWLOCK_TEST_MAGIC); snprintf(name, sizeof(name), "%s%d", KZT_RWLOCK_TEST_NAME, rwt->rwt_id); daemonize(name); get_random_bytes((void *)&rnd, 1); kzt_rwlock_sleep(rnd * HZ / 1000); /* Don't try and and take the semaphore until * someone else has already acquired it */ wait_event_interruptible(rwv->rw_waitq, kzt_rwlock_lock_and_test(&rwv->rw_priv_lock, atomic_read(&rwv->rw_acquired) > 0)); spin_lock(&rwv->rw_priv_lock); kzt_vprint(rwv->rw_file, rwt->rwt_name, "%s reader thread trying to acquire rwlock with " "%d holding lock and %d waiting\n", name, atomic_read(&rwv->rw_acquired), atomic_read(&rwv->rw_waiters)); atomic_inc(&rwv->rw_waiters); spin_unlock(&rwv->rw_priv_lock); /* Take the semaphore for reading * release it when we are told to */ rw_enter(&rwv->rwl, RW_READER); spin_lock(&rwv->rw_priv_lock); atomic_dec(&rwv->rw_waiters); atomic_inc(&rwv->rw_acquired); kzt_vprint(rwv->rw_file, rwt->rwt_name, "%s reader thread acquired rwlock with " "%d holding lock and %d waiting\n", name, atomic_read(&rwv->rw_acquired), atomic_read(&rwv->rw_waiters)); spin_unlock(&rwv->rw_priv_lock); /* Wait here until the control thread * says we can release the read lock */ wait_event_interruptible(rwv->rw_waitq, kzt_rwlock_lock_and_test(&rwv->rw_priv_lock, atomic_read(&rwv->rw_release) == KZT_RWLOCK_RELEASE_READERS)); spin_lock(&rwv->rw_priv_lock); atomic_inc(&rwv->rw_completed); atomic_dec(&rwv->rw_acquired); kzt_vprint(rwv->rw_file, rwt->rwt_name, "%s reader thread dropped rwlock with " "%d holding lock and %d waiting\n", name, atomic_read(&rwv->rw_acquired), atomic_read(&rwv->rw_waiters)); spin_unlock(&rwv->rw_priv_lock); /* Release the semaphore */ rw_exit(&rwv->rwl); return 0; } static int kzt_rwlock_test1(struct file *file, void *arg) { int i, count = 0, rc = 0; long pids[KZT_RWLOCK_TEST_COUNT]; rw_thr_t rwt[KZT_RWLOCK_TEST_COUNT]; rw_priv_t rwv; /* Initialize private data * including the rwlock */ kzt_init_rw_priv(&rwv, file); /* Create some threads, the exact number isn't important just as * long as we know how many we managed to create and should expect. */ for (i = 0; i < KZT_RWLOCK_TEST_COUNT; i++) { rwt[i].rwt_rwp = &rwv; rwt[i].rwt_id = i; rwt[i].rwt_name = KZT_RWLOCK_TEST1_NAME; rwt[i].rwt_rc = 0; /* The first thread will be a writer */ if (i == 0) { pids[i] = kernel_thread(kzt_rwlock_test1_writer_thread, &rwt[i], 0); } else { pids[i] = kernel_thread(kzt_rwlock_test1_reader_thread, &rwt[i], 0); } if (pids[i] >= 0) { count++; } } /* Once the writer has the lock, release the readers */ while (kzt_rwlock_lock_and_test(&rwv.rw_priv_lock, atomic_read(&rwv.rw_acquired) <= 0)) { kzt_rwlock_sleep(1 * HZ); } wake_up_interruptible(&rwv.rw_waitq); /* Ensure that there is only 1 writer and all readers are waiting */ while (kzt_rwlock_lock_and_test(&rwv.rw_priv_lock, atomic_read(&rwv.rw_acquired) != 1 || atomic_read(&rwv.rw_waiters) != KZT_RWLOCK_TEST_COUNT - 1)) { kzt_rwlock_sleep(1 * HZ); } /* Relase the writer */ spin_lock(&rwv.rw_priv_lock); atomic_set(&rwv.rw_release, KZT_RWLOCK_RELEASE_WRITERS); spin_unlock(&rwv.rw_priv_lock); wake_up_interruptible(&rwv.rw_waitq); /* Now ensure that there are multiple reader threads holding the lock */ while (kzt_rwlock_lock_and_test(&rwv.rw_priv_lock, atomic_read(&rwv.rw_acquired) <= 1)) { kzt_rwlock_sleep(1 * HZ); } /* Release the readers */ spin_lock(&rwv.rw_priv_lock); atomic_set(&rwv.rw_release, KZT_RWLOCK_RELEASE_READERS); spin_unlock(&rwv.rw_priv_lock); wake_up_interruptible(&rwv.rw_waitq); /* Wait for the test to complete */ while (kzt_rwlock_lock_and_test(&rwv.rw_priv_lock, atomic_read(&rwv.rw_acquired) != 0 || atomic_read(&rwv.rw_waiters) != 0)) { kzt_rwlock_sleep(1 * HZ); } rw_destroy(&rwv.rwl); return rc; } int kzt_rwlock_test2_writer_thread(void *arg) { rw_thr_t *rwt = (rw_thr_t *)arg; rw_priv_t *rwv = rwt->rwt_rwp; uint8_t rnd = 0; char name[16]; ASSERT(rwv->rw_magic == KZT_RWLOCK_TEST_MAGIC); snprintf(name, sizeof(name), "%s%d", KZT_RWLOCK_TEST_NAME, rwt->rwt_id); daemonize(name); get_random_bytes((void *)&rnd, 1); kzt_rwlock_sleep(rnd * HZ / 1000); /* Here just increment the waiters count even if we are not * exactly about to call rw_enter(). Not really a big deal * since more than likely will be true when we simulate work * later on */ spin_lock(&rwv->rw_priv_lock); kzt_vprint(rwv->rw_file, rwt->rwt_name, "%s writer thread trying to acquire rwlock with " "%d holding lock and %d waiting\n", name, atomic_read(&rwv->rw_acquired), atomic_read(&rwv->rw_waiters)); atomic_inc(&rwv->rw_waiters); spin_unlock(&rwv->rw_priv_lock); /* Wait here until the control thread * says we can acquire the write lock */ wait_event_interruptible(rwv->rw_waitq, kzt_rwlock_lock_and_test(&rwv->rw_priv_lock, atomic_read(&rwv->rw_release) == KZT_RWLOCK_RELEASE_WRITERS)); /* Take the semaphore for writing */ rw_enter(&rwv->rwl, RW_WRITER); spin_lock(&rwv->rw_priv_lock); atomic_dec(&rwv->rw_waiters); atomic_inc(&rwv->rw_acquired); kzt_vprint(rwv->rw_file, rwt->rwt_name, "%s writer thread acquired rwlock with " "%d holding lock and %d waiting\n", name, atomic_read(&rwv->rw_acquired), atomic_read(&rwv->rw_waiters)); spin_unlock(&rwv->rw_priv_lock); /* Give up the processor for a bit to simulate * doing some work while taking the write lock */ kzt_rwlock_sleep(rnd * HZ / 1000); /* Ensure that we are the only one writing */ if (atomic_read(&rwv->rw_acquired) > 1) { rwt->rwt_rc = 1; } else { rwt->rwt_rc = 0; } spin_lock(&rwv->rw_priv_lock); atomic_inc(&rwv->rw_completed); atomic_dec(&rwv->rw_acquired); kzt_vprint(rwv->rw_file, rwt->rwt_name, "%s writer thread dropped rwlock with " "%d holding lock and %d waiting\n", name, atomic_read(&rwv->rw_acquired), atomic_read(&rwv->rw_waiters)); spin_unlock(&rwv->rw_priv_lock); rw_exit(&rwv->rwl); return 0; } static int kzt_rwlock_test2(struct file *file, void *arg) { int i, count = 0, rc = 0; long pids[KZT_RWLOCK_TEST_COUNT]; rw_thr_t rwt[KZT_RWLOCK_TEST_COUNT]; rw_priv_t rwv; /* Initialize private data * including the rwlock */ kzt_init_rw_priv(&rwv, file); /* Create some threads, the exact number isn't important just as * long as we know how many we managed to create and should expect. */ for (i = 0; i < KZT_RWLOCK_TEST_COUNT; i++) { rwt[i].rwt_rwp = &rwv; rwt[i].rwt_id = i; rwt[i].rwt_name = KZT_RWLOCK_TEST2_NAME; rwt[i].rwt_rc = 0; /* The first thread will be a writer */ pids[i] = kernel_thread(kzt_rwlock_test2_writer_thread, &rwt[i], 0); if (pids[i] >= 0) { count++; } } /* Wait for writers to get queued up */ while (kzt_rwlock_lock_and_test(&rwv.rw_priv_lock, atomic_read(&rwv.rw_waiters) < KZT_RWLOCK_TEST_COUNT)) { kzt_rwlock_sleep(1 * HZ); } /* Relase the writers */ spin_lock(&rwv.rw_priv_lock); atomic_set(&rwv.rw_release, KZT_RWLOCK_RELEASE_WRITERS); spin_unlock(&rwv.rw_priv_lock); wake_up_interruptible(&rwv.rw_waitq); /* Wait for the test to complete */ while (kzt_rwlock_lock_and_test(&rwv.rw_priv_lock, atomic_read(&rwv.rw_acquired) != 0 || atomic_read(&rwv.rw_waiters) != 0)) { kzt_rwlock_sleep(1 * HZ); } /* If any of the write threads ever acquired the lock * while another thread had it, make sure we return * an error */ for (i = 0; i < KZT_RWLOCK_TEST_COUNT; i++) { if (rwt[i].rwt_rc) { rc++; } } rw_destroy(&rwv.rwl); return rc; } static int kzt_rwlock_test3(struct file *file, void *arg) { kthread_t *owner; rw_priv_t rwv; int rc = 0; /* Initialize private data * including the rwlock */ kzt_init_rw_priv(&rwv, file); /* Take the rwlock for writing */ rw_enter(&rwv.rwl, RW_WRITER); owner = rw_owner(&rwv.rwl); if (current != owner) { kzt_vprint(file, KZT_RWLOCK_TEST3_NAME, "rwlock should " "be owned by pid %d but is owned by pid %d\n", current->pid, owner ? owner->pid : -1); rc = -EINVAL; goto out; } /* Release the rwlock */ rw_exit(&rwv.rwl); owner = rw_owner(&rwv.rwl); if (owner) { kzt_vprint(file, KZT_RWLOCK_TEST3_NAME, "rwlock should not " "be owned but is owned by pid %d\n", owner->pid); rc = -EINVAL; goto out; } /* Take the rwlock for reading. * Should not have an owner */ rw_enter(&rwv.rwl, RW_READER); owner = rw_owner(&rwv.rwl); if (owner) { kzt_vprint(file, KZT_RWLOCK_TEST3_NAME, "rwlock should not " "be owned but is owned by pid %d\n", owner->pid); /* Release the rwlock */ rw_exit(&rwv.rwl); rc = -EINVAL; goto out; } /* Release the rwlock */ rw_exit(&rwv.rwl); out: rw_destroy(&rwv.rwl); return rc; } int kzt_rwlock_test4_reader_thread(void *arg) { rw_thr_t *rwt = (rw_thr_t *)arg; rw_priv_t *rwv = rwt->rwt_rwp; uint8_t rnd = 0; char name[16]; ASSERT(rwv->rw_magic == KZT_RWLOCK_TEST_MAGIC); snprintf(name, sizeof(name), "%s%d", KZT_RWLOCK_TEST_NAME, rwt->rwt_id); daemonize(name); get_random_bytes((void *)&rnd, 1); kzt_rwlock_sleep(rnd * HZ / 1000); /* Don't try and and take the semaphore until * someone else has already acquired it */ wait_event_interruptible(rwv->rw_waitq, kzt_rwlock_lock_and_test(&rwv->rw_priv_lock, atomic_read(&rwv->rw_acquired) > 0)); spin_lock(&rwv->rw_priv_lock); kzt_vprint(rwv->rw_file, rwt->rwt_name, "%s reader thread trying to acquire rwlock with " "%d holding lock and %d waiting\n", name, atomic_read(&rwv->rw_acquired), atomic_read(&rwv->rw_waiters)); spin_unlock(&rwv->rw_priv_lock); /* Take the semaphore for reading * release it when we are told to */ rwt->rwt_rc = rw_tryenter(&rwv->rwl, RW_READER); /* Here we acquired the lock this is a * failure since the writer should be * holding the lock */ if (rwt->rwt_rc == 1) { spin_lock(&rwv->rw_priv_lock); atomic_inc(&rwv->rw_acquired); kzt_vprint(rwv->rw_file, rwt->rwt_name, "%s reader thread acquired rwlock with " "%d holding lock and %d waiting\n", name, atomic_read(&rwv->rw_acquired), atomic_read(&rwv->rw_waiters)); spin_unlock(&rwv->rw_priv_lock); spin_lock(&rwv->rw_priv_lock); atomic_dec(&rwv->rw_acquired); kzt_vprint(rwv->rw_file, rwt->rwt_name, "%s reader thread dropped rwlock with " "%d holding lock and %d waiting\n", name, atomic_read(&rwv->rw_acquired), atomic_read(&rwv->rw_waiters)); spin_unlock(&rwv->rw_priv_lock); /* Release the semaphore */ rw_exit(&rwv->rwl); } /* Here we know we didn't block and didn't * acquire the rwlock for reading */ else { spin_lock(&rwv->rw_priv_lock); atomic_inc(&rwv->rw_completed); kzt_vprint(rwv->rw_file, rwt->rwt_name, "%s reader thread could not acquire rwlock with " "%d holding lock and %d waiting\n", name, atomic_read(&rwv->rw_acquired), atomic_read(&rwv->rw_waiters)); spin_unlock(&rwv->rw_priv_lock); } return 0; } static int kzt_rwlock_test4(struct file *file, void *arg) { int i, count = 0, rc = 0; long pids[KZT_RWLOCK_TEST_COUNT]; rw_thr_t rwt[KZT_RWLOCK_TEST_COUNT]; rw_priv_t rwv; /* Initialize private data * including the rwlock */ kzt_init_rw_priv(&rwv, file); /* Create some threads, the exact number isn't important just as * long as we know how many we managed to create and should expect. */ for (i = 0; i < KZT_RWLOCK_TEST_COUNT; i++) { rwt[i].rwt_rwp = &rwv; rwt[i].rwt_id = i; rwt[i].rwt_name = KZT_RWLOCK_TEST4_NAME; rwt[i].rwt_rc = 0; /* The first thread will be a writer */ if (i == 0) { /* We can reuse the test1 writer thread here */ pids[i] = kernel_thread(kzt_rwlock_test1_writer_thread, &rwt[i], 0); } else { pids[i] = kernel_thread(kzt_rwlock_test4_reader_thread, &rwt[i], 0); } if (pids[i] >= 0) { count++; } } /* Once the writer has the lock, release the readers */ while (kzt_rwlock_lock_and_test(&rwv.rw_priv_lock, atomic_read(&rwv.rw_acquired) <= 0)) { kzt_rwlock_sleep(1 * HZ); } wake_up_interruptible(&rwv.rw_waitq); /* Make sure that the reader threads complete */ while (kzt_rwlock_lock_and_test(&rwv.rw_priv_lock, atomic_read(&rwv.rw_completed) != KZT_RWLOCK_TEST_COUNT - 1)) { kzt_rwlock_sleep(1 * HZ); } /* Release the writer */ spin_lock(&rwv.rw_priv_lock); atomic_set(&rwv.rw_release, KZT_RWLOCK_RELEASE_WRITERS); spin_unlock(&rwv.rw_priv_lock); wake_up_interruptible(&rwv.rw_waitq); /* Wait for the test to complete */ while (kzt_rwlock_lock_and_test(&rwv.rw_priv_lock, atomic_read(&rwv.rw_acquired) != 0 || atomic_read(&rwv.rw_waiters) != 0)) { kzt_rwlock_sleep(1 * HZ); } /* If any of the reader threads ever acquired the lock * while another thread had it, make sure we return * an error since the rw_tryenter() should have failed */ for (i = 0; i < KZT_RWLOCK_TEST_COUNT; i++) { if (rwt[i].rwt_rc) { rc++; } } rw_destroy(&rwv.rwl); return rc; } static int kzt_rwlock_test5(struct file *file, void *arg) { kthread_t *owner; rw_priv_t rwv; int rc = 0; /* Initialize private data * including the rwlock */ kzt_init_rw_priv(&rwv, file); /* Take the rwlock for writing */ rw_enter(&rwv.rwl, RW_WRITER); owner = rw_owner(&rwv.rwl); if (current != owner) { kzt_vprint(file, KZT_RWLOCK_TEST5_NAME, "rwlock should " "be owned by pid %d but is owned by pid %d\n", current->pid, owner ? owner->pid : -1); rc = -EINVAL; goto out; } /* Make sure that the downgrade * worked properly */ rw_downgrade(&rwv.rwl); owner = rw_owner(&rwv.rwl); if (owner) { kzt_vprint(file, KZT_RWLOCK_TEST5_NAME, "rwlock should not " "be owned but is owned by pid %d\n", owner->pid); /* Release the rwlock */ rw_exit(&rwv.rwl); rc = -EINVAL; goto out; } /* Release the rwlock */ rw_exit(&rwv.rwl); out: rw_destroy(&rwv.rwl); return rc; } static int kzt_rwlock_test6(struct file *file, void *arg) { kthread_t *owner; rw_priv_t rwv; int rc = 0; /* Initialize private data * including the rwlock */ kzt_init_rw_priv(&rwv, file); /* Take the rwlock for reading */ rw_enter(&rwv.rwl, RW_READER); owner = rw_owner(&rwv.rwl); if (owner) { kzt_vprint(file, KZT_RWLOCK_TEST6_NAME, "rwlock should not " "be owned but is owned by pid %d\n", owner->pid); rc = -EINVAL; goto out; } /* Make sure that the upgrade * worked properly */ rc = !rw_tryupgrade(&rwv.rwl); owner = rw_owner(&rwv.rwl); if (rc || current != owner) { kzt_vprint(file, KZT_RWLOCK_TEST6_NAME, "rwlock should " "be owned by pid %d but is owned by pid %d " "trylock rc %d\n", current->pid, owner ? owner->pid : -1, rc); rc = -EINVAL; goto out; } /* Release the rwlock */ rw_exit(&rwv.rwl); out: rw_destroy(&rwv.rwl); return rc; } kzt_subsystem_t * kzt_rwlock_init(void) { kzt_subsystem_t *sub; sub = kmalloc(sizeof(*sub), GFP_KERNEL); if (sub == NULL) return NULL; memset(sub, 0, sizeof(*sub)); strncpy(sub->desc.name, KZT_RWLOCK_NAME, KZT_NAME_SIZE); strncpy(sub->desc.desc, KZT_RWLOCK_DESC, KZT_DESC_SIZE); INIT_LIST_HEAD(&sub->subsystem_list); INIT_LIST_HEAD(&sub->test_list); spin_lock_init(&sub->test_lock); sub->desc.id = KZT_SUBSYSTEM_RWLOCK; KZT_TEST_INIT(sub, KZT_RWLOCK_TEST1_NAME, KZT_RWLOCK_TEST1_DESC, KZT_RWLOCK_TEST1_ID, kzt_rwlock_test1); KZT_TEST_INIT(sub, KZT_RWLOCK_TEST2_NAME, KZT_RWLOCK_TEST2_DESC, KZT_RWLOCK_TEST2_ID, kzt_rwlock_test2); KZT_TEST_INIT(sub, KZT_RWLOCK_TEST3_NAME, KZT_RWLOCK_TEST3_DESC, KZT_RWLOCK_TEST3_ID, kzt_rwlock_test3); KZT_TEST_INIT(sub, KZT_RWLOCK_TEST4_NAME, KZT_RWLOCK_TEST4_DESC, KZT_RWLOCK_TEST4_ID, kzt_rwlock_test4); KZT_TEST_INIT(sub, KZT_RWLOCK_TEST5_NAME, KZT_RWLOCK_TEST5_DESC, KZT_RWLOCK_TEST5_ID, kzt_rwlock_test5); KZT_TEST_INIT(sub, KZT_RWLOCK_TEST6_NAME, KZT_RWLOCK_TEST6_DESC, KZT_RWLOCK_TEST6_ID, kzt_rwlock_test6); return sub; } void kzt_rwlock_fini(kzt_subsystem_t *sub) { ASSERT(sub); KZT_TEST_FINI(sub, KZT_RWLOCK_TEST6_ID); KZT_TEST_FINI(sub, KZT_RWLOCK_TEST5_ID); KZT_TEST_FINI(sub, KZT_RWLOCK_TEST4_ID); KZT_TEST_FINI(sub, KZT_RWLOCK_TEST3_ID); KZT_TEST_FINI(sub, KZT_RWLOCK_TEST2_ID); KZT_TEST_FINI(sub, KZT_RWLOCK_TEST1_ID); kfree(sub); } int kzt_rwlock_id(void) { return KZT_SUBSYSTEM_RWLOCK; }