/* Unix SMB/CIFS implementation. trivial database library Copyright (C) Anton Blanchard 2001 ** NOTE! The following LGPL license applies to the tdb ** library. This does NOT imply that all of Samba is released ** under the LGPL This library is free software; you can redistribute it and/or modify it under the terms of the GNU Lesser General Public License as published by the Free Software Foundation; either version 2 of the License, or (at your option) any later version. This library is distributed in the hope that it will be useful, but WITHOUT ANY WARRANTY; without even the implied warranty of MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the GNU Lesser General Public License for more details. You should have received a copy of the GNU Lesser General Public License along with this library; if not, write to the Free Software Foundation, Inc., 59 Temple Place, Suite 330, Boston, MA 02111-1307 USA */ #if HAVE_CONFIG_H #include #endif #if STANDALONE #include #include #include #include #include #include #include #include #include #include "tdb.h" #include "spinlock.h" #define DEBUG #else #include "includes.h" #endif #ifdef USE_SPINLOCKS /* * ARCH SPECIFIC */ #if defined(SPARC_SPINLOCKS) static inline int __spin_trylock(spinlock_t *lock) { unsigned int result; asm volatile("ldstub [%1], %0" : "=r" (result) : "r" (lock) : "memory"); return (result == 0) ? 0 : EBUSY; } static inline void __spin_unlock(spinlock_t *lock) { asm volatile("":::"memory"); *lock = 0; } static inline void __spin_lock_init(spinlock_t *lock) { *lock = 0; } static inline int __spin_is_locked(spinlock_t *lock) { return (*lock != 0); } #elif defined(POWERPC_SPINLOCKS) static inline int __spin_trylock(spinlock_t *lock) { unsigned int result; __asm__ __volatile__( "1: lwarx %0,0,%1\n\ cmpwi 0,%0,0\n\ li %0,0\n\ bne- 2f\n\ li %0,1\n\ stwcx. %0,0,%1\n\ bne- 1b\n\ isync\n\ 2:" : "=&r"(result) : "r"(lock) : "cr0", "memory"); return (result == 1) ? 0 : EBUSY; } static inline void __spin_unlock(spinlock_t *lock) { asm volatile("eieio":::"memory"); *lock = 0; } static inline void __spin_lock_init(spinlock_t *lock) { *lock = 0; } static inline int __spin_is_locked(spinlock_t *lock) { return (*lock != 0); } #elif defined(INTEL_SPINLOCKS) static inline int __spin_trylock(spinlock_t *lock) { int oldval; asm volatile("xchgl %0,%1" : "=r" (oldval), "=m" (*lock) : "0" (0) : "memory"); return oldval > 0 ? 0 : EBUSY; } static inline void __spin_unlock(spinlock_t *lock) { asm volatile("":::"memory"); *lock = 1; } static inline void __spin_lock_init(spinlock_t *lock) { *lock = 1; } static inline int __spin_is_locked(spinlock_t *lock) { return (*lock != 1); } #elif defined(MIPS_SPINLOCKS) static inline unsigned int load_linked(unsigned long addr) { unsigned int res; __asm__ __volatile__("ll\t%0,(%1)" : "=r" (res) : "r" (addr)); return res; } static inline unsigned int store_conditional(unsigned long addr, unsigned int value) { unsigned int res; __asm__ __volatile__("sc\t%0,(%2)" : "=r" (res) : "0" (value), "r" (addr)); return res; } static inline int __spin_trylock(spinlock_t *lock) { unsigned int mw; do { mw = load_linked(lock); if (mw) return EBUSY; } while (!store_conditional(lock, 1)); asm volatile("":::"memory"); return 0; } static inline void __spin_unlock(spinlock_t *lock) { asm volatile("":::"memory"); *lock = 0; } static inline void __spin_lock_init(spinlock_t *lock) { *lock = 0; } static inline int __spin_is_locked(spinlock_t *lock) { return (*lock != 0); } #else #error Need to implement spinlock code in spinlock.c #endif /* * OS SPECIFIC */ static void yield_cpu(void) { struct timespec tm; #ifdef USE_SCHED_YIELD sched_yield(); #else /* Linux will busy loop for delays < 2ms on real time tasks */ tm.tv_sec = 0; tm.tv_nsec = 2000000L + 1; nanosleep(&tm, NULL); #endif } static int this_is_smp(void) { return 0; } /* * GENERIC */ static int smp_machine = 0; static inline void __spin_lock(spinlock_t *lock) { int ntries = 0; while(__spin_trylock(lock)) { while(__spin_is_locked(lock)) { if (smp_machine && ntries++ < MAX_BUSY_LOOPS) continue; yield_cpu(); } } } static void __read_lock(tdb_rwlock_t *rwlock) { int ntries = 0; while(1) { __spin_lock(&rwlock->lock); if (!(rwlock->count & RWLOCK_BIAS)) { rwlock->count++; __spin_unlock(&rwlock->lock); return; } __spin_unlock(&rwlock->lock); while(rwlock->count & RWLOCK_BIAS) { if (smp_machine && ntries++ < MAX_BUSY_LOOPS) continue; yield_cpu(); } } } static void __write_lock(tdb_rwlock_t *rwlock) { int ntries = 0; while(1) { __spin_lock(&rwlock->lock); if (rwlock->count == 0) { rwlock->count |= RWLOCK_BIAS; __spin_unlock(&rwlock->lock); return; } __spin_unlock(&rwlock->lock); while(rwlock->count != 0) { if (smp_machine && ntries++ < MAX_BUSY_LOOPS) continue; yield_cpu(); } } } static void __write_unlock(tdb_rwlock_t *rwlock) { __spin_lock(&rwlock->lock); #ifdef DEBUG if (!(rwlock->count & RWLOCK_BIAS)) fprintf(stderr, "bug: write_unlock\n"); #endif rwlock->count &= ~RWLOCK_BIAS; __spin_unlock(&rwlock->lock); } static void __read_unlock(tdb_rwlock_t *rwlock) { __spin_lock(&rwlock->lock); #ifdef DEBUG if (!rwlock->count) fprintf(stderr, "bug: read_unlock\n"); if (rwlock->count & RWLOCK_BIAS) fprintf(stderr, "bug: read_unlock\n"); #endif rwlock->count--; __spin_unlock(&rwlock->lock); } /* TDB SPECIFIC */ /* lock a list in the database. list -1 is the alloc list */ int tdb_spinlock(TDB_CONTEXT *tdb, int list, int rw_type) { tdb_rwlock_t *rwlocks; if (!tdb->map_ptr) return -1; rwlocks = (tdb_rwlock_t *)((char *)tdb->map_ptr + tdb->header.rwlocks); switch(rw_type) { case F_RDLCK: __read_lock(&rwlocks[list+1]); break; case F_WRLCK: __write_lock(&rwlocks[list+1]); break; default: return TDB_ERRCODE(TDB_ERR_LOCK, -1); } return 0; } /* unlock the database. */ int tdb_spinunlock(TDB_CONTEXT *tdb, int list, int rw_type) { tdb_rwlock_t *rwlocks; if (!tdb->map_ptr) return -1; rwlocks = (tdb_rwlock_t *)((char *)tdb->map_ptr + tdb->header.rwlocks); switch(rw_type) { case F_RDLCK: __read_unlock(&rwlocks[list+1]); break; case F_WRLCK: __write_unlock(&rwlocks[list+1]); break; default: return TDB_ERRCODE(TDB_ERR_LOCK, -1); } return 0; } int tdb_create_rwlocks(int fd, unsigned int hash_size) { unsigned size, i; tdb_rwlock_t *rwlocks; size = TDB_SPINLOCK_SIZE(hash_size); rwlocks = malloc(size); if (!rwlocks) return -1; for(i = 0; i < hash_size+1; i++) { __spin_lock_init(&rwlocks[i].lock); rwlocks[i].count = 0; } /* Write it out (appending to end) */ if (write(fd, rwlocks, size) != size) { free(rwlocks); return -1; } smp_machine = this_is_smp(); free(rwlocks); return 0; } int tdb_clear_spinlocks(TDB_CONTEXT *tdb) { tdb_rwlock_t *rwlocks; unsigned i; if (tdb->header.rwlocks == 0) return 0; if (!tdb->map_ptr) return -1; /* We're mmapped here */ rwlocks = (tdb_rwlock_t *)((char *)tdb->map_ptr + tdb->header.rwlocks); for(i = 0; i < tdb->header.hash_size+1; i++) { __spin_lock_init(&rwlocks[i].lock); rwlocks[i].count = 0; } return 0; } #else int tdb_create_rwlocks(int fd, unsigned int hash_size) { return 0; } int tdb_spinlock(TDB_CONTEXT *tdb, int list, int rw_type) { return -1; } int tdb_spinunlock(TDB_CONTEXT *tdb, int list, int rw_type) { return -1; } /* Non-spinlock version: remove spinlock pointer */ int tdb_clear_spinlocks(TDB_CONTEXT *tdb) { tdb_off off = (tdb_off)((char *)&tdb->header.rwlocks - (char *)&tdb->header); tdb->header.rwlocks = 0; if (lseek(tdb->fd, off, SEEK_SET) != off || write(tdb->fd, (void *)&tdb->header.rwlocks, sizeof(tdb->header.rwlocks)) != sizeof(tdb->header.rwlocks)) return -1; return 0; } #endif