/* Mutex and recursive_lock code */ /* ** Copyright 2001-2002, Travis Geiselbrecht. All rights reserved. ** Distributed under the terms of the NewOS License. */ #include #include #include #include #include int recursive_lock_get_recursion(recursive_lock *lock) { thread_id thid = thread_get_current_thread_id(); if (lock->holder == thid) return lock->recursion; return -1; } status_t recursive_lock_init(recursive_lock *lock, const char *name) { if (lock == NULL) return B_BAD_VALUE; if (name == NULL) name = "recursive lock"; lock->holder = -1; lock->recursion = 0; lock->sem = create_sem(1, name); if (lock->sem >= B_OK) { //set_sem_owner(lock->sem, B_SYSTEM_TEAM); return B_OK; } return lock->sem; } void recursive_lock_destroy(recursive_lock *lock) { if (lock == NULL) return; delete_sem(lock->sem); lock->sem = -1; } bool recursive_lock_lock(recursive_lock *lock) { thread_id thid = thread_get_current_thread_id(); bool retval = false; if (!kernel_startup && !are_interrupts_enabled()) panic("recursive_lock_lock: called with interrupts disabled for lock %p, sem %#lx\n", lock, lock->sem); if (thid != lock->holder) { acquire_sem(lock->sem); lock->holder = thid; retval = true; } lock->recursion++; return retval; } bool recursive_lock_unlock(recursive_lock *lock) { thread_id thid = thread_get_current_thread_id(); bool retval = false; if (thid != lock->holder) panic("recursive_lock %p unlocked by non-holder thread!\n", lock); if (--lock->recursion == 0) { lock->holder = -1; release_sem(lock->sem); retval = true; } return retval; } // #pragma mark - status_t mutex_init(mutex *m, const char *name) { if (m == NULL) return EINVAL; if (name == NULL) name = "mutex_sem"; m->holder = -1; m->sem = create_sem(1, name); if (m->sem >= B_OK) { //set_sem_owner(m->sem, B_SYSTEM_TEAM); return B_OK; } return m->sem; } void mutex_destroy(mutex *mutex) { if (mutex == NULL) return; if (mutex->sem >= 0) { delete_sem(mutex->sem); mutex->sem = -1; } mutex->holder = -1; } void mutex_lock(mutex *mutex) { thread_id me = thread_get_current_thread_id(); if (!kernel_startup && !are_interrupts_enabled()) panic("mutex_lock: called with interrupts disabled for mutex %p, sem %#lx\n", mutex, mutex->sem); if (me == mutex->holder) panic("mutex_lock failure: mutex %p (sem = 0x%lx) acquired twice by thread 0x%lx\n", mutex, mutex->sem, me); acquire_sem(mutex->sem); mutex->holder = me; } void mutex_unlock(mutex *mutex) { thread_id me = thread_get_current_thread_id(); if (me != mutex->holder) panic("mutex_unlock failure: thread 0x%lx is trying to release mutex %p (current holder 0x%lx)\n", me, mutex, mutex->holder); mutex->holder = -1; release_sem(mutex->sem); } // #pragma mark - status_t benaphore_init(benaphore *ben, const char *name) { if (ben == NULL || name == NULL) return B_BAD_VALUE; ben->count = 1; ben->sem = create_sem(0, name); if (ben->sem >= B_OK) { set_sem_owner(ben->sem, B_SYSTEM_TEAM); return B_OK; } return ben->sem; } void benaphore_destroy(benaphore *ben) { delete_sem(ben->sem); ben->sem = -1; } // #pragma mark - status_t rw_lock_init(rw_lock *lock, const char *name) { if (lock == NULL) return B_BAD_VALUE; if (name == NULL) name = "r/w lock"; lock->sem = create_sem(RW_MAX_READERS, name); if (lock->sem >= B_OK) { set_sem_owner(lock->sem, B_SYSTEM_TEAM); return B_OK; } return lock->sem; } void rw_lock_destroy(rw_lock *lock) { if (lock == NULL) return; delete_sem(lock->sem); } status_t rw_lock_read_lock(rw_lock *lock) { return acquire_sem(lock->sem); } status_t rw_lock_read_unlock(rw_lock *lock) { return release_sem(lock->sem); } status_t rw_lock_write_lock(rw_lock *lock) { return acquire_sem_etc(lock->sem, RW_MAX_READERS, 0, 0); } status_t rw_lock_write_unlock(rw_lock *lock) { release_sem_etc(lock->sem, RW_MAX_READERS, 0); }