#ifndef _SPARC64_SEMAPHORE_H #define _SPARC64_SEMAPHORE_H /* These are actually reasonable on the V9. * * See asm-ppc/semaphore.h for implementation commentary, * only sparc64 specific issues are commented here. */ #ifdef __KERNEL__ #include #include #include #include struct semaphore { atomic_t count; wait_queue_head_t wait; }; #define __SEMAPHORE_INITIALIZER(name, count) \ { ATOMIC_INIT(count), \ __WAIT_QUEUE_HEAD_INITIALIZER((name).wait) } #define __MUTEX_INITIALIZER(name) \ __SEMAPHORE_INITIALIZER(name, 1) #define __DECLARE_SEMAPHORE_GENERIC(name, count) \ struct semaphore name = __SEMAPHORE_INITIALIZER(name,count) #define DECLARE_MUTEX(name) __DECLARE_SEMAPHORE_GENERIC(name, 1) #define DECLARE_MUTEX_LOCKED(name) __DECLARE_SEMAPHORE_GENERIC(name, 0) static inline void sema_init (struct semaphore *sem, int val) { atomic_set(&sem->count, val); init_waitqueue_head(&sem->wait); } static inline void init_MUTEX (struct semaphore *sem) { sema_init(sem, 1); } static inline void init_MUTEX_LOCKED (struct semaphore *sem) { sema_init(sem, 0); } extern void __down(struct semaphore * sem); extern int __down_interruptible(struct semaphore * sem); extern void __up(struct semaphore * sem); static __inline__ void down(struct semaphore * sem) { /* This atomically does: * old_val = sem->count; * new_val = sem->count - 1; * sem->count = new_val; * if (old_val < 1) * __down(sem); * * The (old_val < 1) test is equivalent to * the more straightforward (new_val < 0), * but it is easier to test the former because * of how the CAS instruction works. */ __asm__ __volatile__("\n" " ! down sem(%0)\n" "1: lduw [%0], %%g5\n" " sub %%g5, 1, %%g7\n" " cas [%0], %%g5, %%g7\n" " cmp %%g5, %%g7\n" " bne,pn %%icc, 1b\n" " cmp %%g7, 1\n" " bl,pn %%icc, 3f\n" " membar #StoreLoad | #StoreStore\n" "2:\n" " .subsection 2\n" "3: mov %0, %%g5\n" " save %%sp, -160, %%sp\n" " mov %%g1, %%l1\n" " mov %%g2, %%l2\n" " mov %%g3, %%l3\n" " call %1\n" " mov %%g5, %%o0\n" " mov %%l1, %%g1\n" " mov %%l2, %%g2\n" " ba,pt %%xcc, 2b\n" " restore %%l3, %%g0, %%g3\n" " .previous\n" : : "r" (sem), "i" (__down) : "g5", "g7", "memory", "cc"); } static __inline__ int down_interruptible(struct semaphore *sem) { int ret = 0; /* This atomically does: * old_val = sem->count; * new_val = sem->count - 1; * sem->count = new_val; * if (old_val < 1) * ret = __down_interruptible(sem); * * The (old_val < 1) test is equivalent to * the more straightforward (new_val < 0), * but it is easier to test the former because * of how the CAS instruction works. */ __asm__ __volatile__("\n" " ! down_interruptible sem(%2) ret(%0)\n" "1: lduw [%2], %%g5\n" " sub %%g5, 1, %%g7\n" " cas [%2], %%g5, %%g7\n" " cmp %%g5, %%g7\n" " bne,pn %%icc, 1b\n" " cmp %%g7, 1\n" " bl,pn %%icc, 3f\n" " membar #StoreLoad | #StoreStore\n" "2:\n" " .subsection 2\n" "3: mov %2, %%g5\n" " save %%sp, -160, %%sp\n" " mov %%g1, %%l1\n" " mov %%g2, %%l2\n" " mov %%g3, %%l3\n" " call %3\n" " mov %%g5, %%o0\n" " mov %%l1, %%g1\n" " mov %%l2, %%g2\n" " mov %%l3, %%g3\n" " ba,pt %%xcc, 2b\n" " restore %%o0, %%g0, %0\n" " .previous\n" : "=r" (ret) : "0" (ret), "r" (sem), "i" (__down_interruptible) : "g5", "g7", "memory", "cc"); return ret; } static __inline__ int down_trylock(struct semaphore *sem) { int ret; /* This atomically does: * old_val = sem->count; * new_val = sem->count - 1; * if (old_val < 1) { * ret = 1; * } else { * sem->count = new_val; * ret = 0; * } * * The (old_val < 1) test is equivalent to * the more straightforward (new_val < 0), * but it is easier to test the former because * of how the CAS instruction works. */ __asm__ __volatile__("\n" " ! down_trylock sem(%1) ret(%0)\n" "1: lduw [%1], %%g5\n" " sub %%g5, 1, %%g7\n" " cmp %%g5, 1\n" " bl,pn %%icc, 2f\n" " mov 1, %0\n" " cas [%1], %%g5, %%g7\n" " cmp %%g5, %%g7\n" " bne,pn %%icc, 1b\n" " mov 0, %0\n" " membar #StoreLoad | #StoreStore\n" "2:\n" : "=&r" (ret) : "r" (sem) : "g5", "g7", "memory", "cc"); return ret; } static __inline__ void up(struct semaphore * sem) { /* This atomically does: * old_val = sem->count; * new_val = sem->count + 1; * sem->count = new_val; * if (old_val < 0) * __up(sem); * * The (old_val < 0) test is equivalent to * the more straightforward (new_val <= 0), * but it is easier to test the former because * of how the CAS instruction works. */ __asm__ __volatile__("\n" " ! up sem(%0)\n" " membar #StoreLoad | #LoadLoad\n" "1: lduw [%0], %%g5\n" " add %%g5, 1, %%g7\n" " cas [%0], %%g5, %%g7\n" " cmp %%g5, %%g7\n" " bne,pn %%icc, 1b\n" " addcc %%g7, 1, %%g0\n" " ble,pn %%icc, 3f\n" " membar #StoreLoad | #StoreStore\n" "2:\n" " .subsection 2\n" "3: mov %0, %%g5\n" " save %%sp, -160, %%sp\n" " mov %%g1, %%l1\n" " mov %%g2, %%l2\n" " mov %%g3, %%l3\n" " call %1\n" " mov %%g5, %%o0\n" " mov %%l1, %%g1\n" " mov %%l2, %%g2\n" " ba,pt %%xcc, 2b\n" " restore %%l3, %%g0, %%g3\n" " .previous\n" : : "r" (sem), "i" (__up) : "g5", "g7", "memory", "cc"); } static inline int sem_getcount(struct semaphore *sem) { return atomic_read(&sem->count); } #endif /* __KERNEL__ */ #endif /* !(_SPARC64_SEMAPHORE_H) */