/* $OpenLDAP$ */ /* This work is part of OpenLDAP Software . * * Copyright 1998-2006 The OpenLDAP Foundation. * All rights reserved. * * Redistribution and use in source and binary forms, with or without * modification, are permitted only as authorized by the OpenLDAP * Public License. * * A copy of this license is available in file LICENSE in the * top-level directory of the distribution or, alternatively, at * . */ #include "portable.h" #include #include #include #include #include #include #include "ldap-int.h" #include "ldap_pvt_thread.h" /* Get the thread interface */ #include "ldap_queue.h" #define LDAP_THREAD_POOL_IMPLEMENTATION #include "ldap_thr_debug.h" /* May rename symbols defined below */ #ifndef LDAP_THREAD_HAVE_TPOOL typedef enum ldap_int_thread_pool_state_e { LDAP_INT_THREAD_POOL_RUNNING, LDAP_INT_THREAD_POOL_FINISHING, LDAP_INT_THREAD_POOL_STOPPING, LDAP_INT_THREAD_POOL_PAUSING } ldap_int_thread_pool_state_t; typedef struct ldap_int_thread_key_s { void *ltk_key; void *ltk_data; ldap_pvt_thread_pool_keyfree_t *ltk_free; } ldap_int_thread_key_t; /* Max number of thread-specific keys we store per thread. * We don't expect to use many... */ #define MAXKEYS 32 #define LDAP_MAXTHR 1024 /* must be a power of 2 */ typedef struct ldap_int_thread_userctx_s { ldap_pvt_thread_t ltu_id; ldap_int_thread_key_t ltu_key[MAXKEYS]; } ldap_int_thread_userctx_t; static ldap_pvt_thread_t tid_zero; static struct { ldap_pvt_thread_t id; ldap_int_thread_userctx_t *ctx; } thread_keys[LDAP_MAXTHR]; typedef struct ldap_int_thread_ctx_s { union { LDAP_STAILQ_ENTRY(ldap_int_thread_ctx_s) q; LDAP_SLIST_ENTRY(ldap_int_thread_ctx_s) l; LDAP_SLIST_ENTRY(ldap_int_thread_ctx_s) al; } ltc_next; ldap_pvt_thread_start_t *ltc_start_routine; void *ltc_arg; } ldap_int_thread_ctx_t; struct ldap_int_thread_pool_s { LDAP_STAILQ_ENTRY(ldap_int_thread_pool_s) ltp_next; ldap_pvt_thread_mutex_t ltp_mutex; ldap_pvt_thread_cond_t ltp_cond; ldap_pvt_thread_cond_t ltp_pcond; LDAP_STAILQ_HEAD(tcq, ldap_int_thread_ctx_s) ltp_pending_list; LDAP_SLIST_HEAD(tcl, ldap_int_thread_ctx_s) ltp_free_list; LDAP_SLIST_HEAD(tclq, ldap_int_thread_ctx_s) ltp_active_list; ldap_int_thread_pool_state_t ltp_state; long ltp_max_count; long ltp_max_pending; long ltp_pending_count; long ltp_active_count; long ltp_open_count; long ltp_starting; }; static LDAP_STAILQ_HEAD(tpq, ldap_int_thread_pool_s) ldap_int_thread_pool_list = LDAP_STAILQ_HEAD_INITIALIZER(ldap_int_thread_pool_list); static ldap_pvt_thread_mutex_t ldap_pvt_thread_pool_mutex; static void *ldap_int_thread_pool_wrapper( void *pool ); static ldap_pvt_thread_t ldap_int_main_tid; static ldap_int_thread_userctx_t ldap_int_main_thrctx; int ldap_int_thread_pool_startup ( void ) { ldap_int_main_tid = ldap_pvt_thread_self(); ldap_int_main_thrctx.ltu_id = ldap_int_main_tid; return ldap_pvt_thread_mutex_init(&ldap_pvt_thread_pool_mutex); } int ldap_int_thread_pool_shutdown ( void ) { struct ldap_int_thread_pool_s *pool; while ((pool = LDAP_STAILQ_FIRST(&ldap_int_thread_pool_list)) != NULL) { (ldap_pvt_thread_pool_destroy)(&pool, 0); /* ignore thr_debug macro */ } ldap_pvt_thread_mutex_destroy(&ldap_pvt_thread_pool_mutex); return(0); } typedef struct ldap_lazy_sem_t { ldap_pvt_thread_mutex_t ls_mutex; ldap_pvt_thread_cond_t ls_cond; int ls_sem_value; /* * when more than ls_lazy_count number of resources * becmoes available, the thread wating for the resources will * be waken up in order to prevent frequent blocking/waking-up */ unsigned int ls_lazy_count; /* * only one thread(listener) will wait on this semaphore * using a flag instead of a list */ int ls_wait; } ldap_lazy_sem_t; ldap_lazy_sem_t* thread_pool_sem = NULL; int ldap_lazy_sem_init( unsigned int value, unsigned int lazyness ) { thread_pool_sem = (ldap_lazy_sem_t*) LDAP_CALLOC(1, sizeof( ldap_lazy_sem_t )); if( thread_pool_sem == NULL ) return -1; ldap_pvt_thread_mutex_init( &thread_pool_sem->ls_mutex ); ldap_pvt_thread_cond_init( &thread_pool_sem->ls_cond ); thread_pool_sem->ls_sem_value = value; thread_pool_sem->ls_lazy_count = lazyness; thread_pool_sem->ls_wait = 0; return 0; } /* FIXME: move to some approprite header */ int ldap_lazy_sem_dec( ldap_lazy_sem_t* ls ); int ldap_lazy_sem_wait ( ldap_lazy_sem_t* ls ); /* * ldap_lazy_sem_wait is used if a caller is blockable(listener). * Otherwise use ldap_lazy_sem_dec (worker) */ int ldap_lazy_sem_op_submit( ldap_lazy_sem_t* ls ) { if ( ls == NULL ) return -1; /* only worker thread has its thread ctx */ if ( ldap_pvt_thread_pool_context() ) { /* worker thread */ return ldap_lazy_sem_dec( ls ); } else { /* listener */ return ldap_lazy_sem_wait( ls ); } } /* * test if given semaphore's count is zero. * If 0, the caller is blocked * If not, the count is decremented. */ int ldap_lazy_sem_wait ( ldap_lazy_sem_t* ls ) { ldap_pvt_thread_mutex_lock( &ls->ls_mutex ); lazy_sem_retry: if ( ls->ls_sem_value <= 0 ) { /* no more avaliable resources */ ls->ls_wait = 1; ldap_pvt_thread_cond_wait( &ls->ls_cond, &ls->ls_mutex ); goto lazy_sem_retry; } else { /* avaliable resources */ ls->ls_sem_value--; } ldap_pvt_thread_mutex_unlock( &ls->ls_mutex ); return 0; } /* * decrement the count without blocking * even when the count becomes less than or equal to 0 */ int ldap_lazy_sem_dec( ldap_lazy_sem_t* ls ) { ldap_pvt_thread_mutex_lock( &ls->ls_mutex ); ls->ls_sem_value--; ldap_pvt_thread_mutex_unlock( &ls->ls_mutex ); return 0; } /* * Increment the count by one and test if it is greater or * equal to lazyness. If it is, wake up a blocked thread. */ int ldap_lazy_sem_post( ldap_lazy_sem_t* ls ) { if( ls == NULL ) return (-1); ldap_pvt_thread_mutex_lock( &ls->ls_mutex ); ls->ls_sem_value++; if ( ls->ls_wait ) { if ( ls->ls_sem_value >= ls->ls_lazy_count ) { ls->ls_wait = 0; ldap_pvt_thread_cond_signal( &ls->ls_cond ); } } ldap_pvt_thread_mutex_unlock( &ls->ls_mutex ); return 0; } int ldap_pvt_thread_pool_init ( ldap_pvt_thread_pool_t *tpool, int max_threads, int max_pending ) { ldap_pvt_thread_pool_t pool; int rc; *tpool = NULL; pool = (ldap_pvt_thread_pool_t) LDAP_CALLOC(1, sizeof(struct ldap_int_thread_pool_s)); if (pool == NULL) return(-1); rc = ldap_pvt_thread_mutex_init(&pool->ltp_mutex); if (rc != 0) return(rc); rc = ldap_pvt_thread_cond_init(&pool->ltp_cond); if (rc != 0) return(rc); rc = ldap_pvt_thread_cond_init(&pool->ltp_pcond); if (rc != 0) return(rc); pool->ltp_state = LDAP_INT_THREAD_POOL_RUNNING; pool->ltp_max_count = max_threads; pool->ltp_max_pending = max_pending; LDAP_STAILQ_INIT(&pool->ltp_pending_list); LDAP_SLIST_INIT(&pool->ltp_free_list); LDAP_SLIST_INIT(&pool->ltp_active_list); ldap_pvt_thread_mutex_lock(&ldap_pvt_thread_pool_mutex); LDAP_STAILQ_INSERT_TAIL(&ldap_int_thread_pool_list, pool, ltp_next); ldap_pvt_thread_mutex_unlock(&ldap_pvt_thread_pool_mutex); #if 0 /* THIS WILL NOT WORK on some systems. If the process * forks after starting a thread, there is no guarantee * that the thread will survive the fork. For example, * slapd forks in order to daemonize, and does so after * calling ldap_pvt_thread_pool_init. On some systems, * this initial thread does not run in the child process, * but ltp_open_count == 1, so two things happen: * 1) the first client connection fails, and 2) when * slapd is kill'ed, it never terminates since it waits * for all worker threads to exit. */ /* start up one thread, just so there is one. no need to * lock the mutex right now, since no threads are running. */ pool->ltp_open_count++; ldap_pvt_thread_t thr; rc = ldap_pvt_thread_create( &thr, 1, ldap_int_thread_pool_wrapper, pool ); if( rc != 0) { /* couldn't start one? then don't start any */ ldap_pvt_thread_mutex_lock(&ldap_pvt_thread_pool_mutex); LDAP_STAILQ_REMOVE(ldap_int_thread_pool_list, pool, ldap_int_thread_pool_s, ltp_next); ldap_pvt_thread_mutex_unlock(&ldap_pvt_thread_pool_mutex); ldap_pvt_thread_cond_destroy(&pool->ltp_pcond); ldap_pvt_thread_cond_destroy(&pool->ltp_cond); ldap_pvt_thread_mutex_destroy(&pool->ltp_mutex); LDAP_FREE(pool); return(-1); } #endif *tpool = pool; return(0); } #define TID_HASH(tid, hash) do { unsigned i; \ unsigned char *ptr = (unsigned char *)&(tid); \ for (i=0, hash=0; iltp_mutex); if ((pool->ltp_state != LDAP_INT_THREAD_POOL_RUNNING && pool->ltp_state != LDAP_INT_THREAD_POOL_PAUSING) || (pool->ltp_max_pending > 0 && pool->ltp_pending_count >= pool->ltp_max_pending)) { ldap_pvt_thread_mutex_unlock(&pool->ltp_mutex); return(-1); } ctx = LDAP_SLIST_FIRST(&pool->ltp_free_list); if (ctx) { LDAP_SLIST_REMOVE_HEAD(&pool->ltp_free_list, ltc_next.l); } else { ctx = (ldap_int_thread_ctx_t *) LDAP_MALLOC( sizeof(ldap_int_thread_ctx_t)); if (ctx == NULL) { ldap_pvt_thread_mutex_unlock(&pool->ltp_mutex); return(-1); } } ctx->ltc_start_routine = start_routine; ctx->ltc_arg = arg; pool->ltp_pending_count++; LDAP_STAILQ_INSERT_TAIL(&pool->ltp_pending_list, ctx, ltc_next.q); if (pool->ltp_state == LDAP_INT_THREAD_POOL_PAUSING) { ldap_pvt_thread_mutex_unlock(&pool->ltp_mutex); return(0); } ldap_pvt_thread_cond_signal(&pool->ltp_cond); if (pool->ltp_open_count < pool->ltp_active_count + pool->ltp_pending_count && (pool->ltp_open_count < pool->ltp_max_count || pool->ltp_max_count <= 0 )) { pool->ltp_open_count++; pool->ltp_starting++; need_thread = 1; } ldap_pvt_thread_mutex_unlock(&pool->ltp_mutex); #ifdef LDAP_PVT_THREAD_POOL_SEM_LOAD_CONTROL ldap_lazy_sem_op_submit( thread_pool_sem ); #endif if (need_thread) { int rc; ldap_pvt_thread_mutex_lock(&pool->ltp_mutex); rc = ldap_pvt_thread_create( &thr, 1, ldap_int_thread_pool_wrapper, pool ); if (rc == 0) { int hash; pool->ltp_starting--; /* assign this thread ID to a key slot; start * at the thread ID itself (mod LDAP_MAXTHR) and * look for an empty slot. */ TID_HASH(thr, hash); for (rc = hash & (LDAP_MAXTHR-1); !ldap_pvt_thread_equal(thread_keys[rc].id, tid_zero); rc = (rc+1) & (LDAP_MAXTHR-1)); thread_keys[rc].id = thr; } else { /* couldn't create thread. back out of * ltp_open_count and check for even worse things. */ pool->ltp_open_count--; pool->ltp_starting--; if (pool->ltp_open_count == 0) { /* no open threads at all?!? */ ldap_int_thread_ctx_t *ptr; LDAP_STAILQ_FOREACH(ptr, &pool->ltp_pending_list, ltc_next.q) if (ptr == ctx) break; if (ptr == ctx) { /* no open threads, context not handled, so * back out of ltp_pending_count, free the context, * report the error. */ LDAP_STAILQ_REMOVE(&pool->ltp_pending_list, ctx, ldap_int_thread_ctx_s, ltc_next.q); pool->ltp_pending_count++; ldap_pvt_thread_mutex_unlock(&pool->ltp_mutex); LDAP_FREE(ctx); return(-1); } } /* there is another open thread, so this * context will be handled eventually. * continue on and signal that the context * is waiting. */ } ldap_pvt_thread_mutex_unlock(&pool->ltp_mutex); } return(0); } int ldap_pvt_thread_pool_maxthreads ( ldap_pvt_thread_pool_t *tpool, int max_threads ) { struct ldap_int_thread_pool_s *pool; if (tpool == NULL) return(-1); pool = *tpool; if (pool == NULL) return(-1); ldap_pvt_thread_mutex_lock(&pool->ltp_mutex); pool->ltp_max_count = max_threads; ldap_pvt_thread_mutex_unlock(&pool->ltp_mutex); return(0); } int ldap_pvt_thread_pool_query ( ldap_pvt_thread_pool_t *tpool, ldap_pvt_thread_pool_param_t param, void *value ) { struct ldap_int_thread_pool_s *pool; int count = -1; if ( tpool == NULL || value == NULL ) { return -1; } pool = *tpool; if ( pool == NULL ) { return 0; } ldap_pvt_thread_mutex_lock(&pool->ltp_mutex); switch ( param ) { case LDAP_PVT_THREAD_POOL_PARAM_MAX: count = pool->ltp_max_count; break; case LDAP_PVT_THREAD_POOL_PARAM_MAX_PENDING: count = pool->ltp_max_pending; break; case LDAP_PVT_THREAD_POOL_PARAM_OPEN: count = pool->ltp_open_count; break; case LDAP_PVT_THREAD_POOL_PARAM_STARTING: count = pool->ltp_starting; break; case LDAP_PVT_THREAD_POOL_PARAM_ACTIVE: count = pool->ltp_active_count; break; case LDAP_PVT_THREAD_POOL_PARAM_PENDING: count = pool->ltp_pending_count; break; case LDAP_PVT_THREAD_POOL_PARAM_BACKLOAD: count = pool->ltp_pending_count + pool->ltp_active_count; break; case LDAP_PVT_THREAD_POOL_PARAM_ACTIVE_MAX: break; case LDAP_PVT_THREAD_POOL_PARAM_PENDING_MAX: break; case LDAP_PVT_THREAD_POOL_PARAM_BACKLOAD_MAX: break; case LDAP_PVT_THREAD_POOL_PARAM_STATE: { static struct { char *name; ldap_int_thread_pool_state_t state; } str2state[] = { { "running", LDAP_INT_THREAD_POOL_RUNNING }, { "finishing", LDAP_INT_THREAD_POOL_FINISHING }, { "stopping", LDAP_INT_THREAD_POOL_STOPPING }, { "pausing", LDAP_INT_THREAD_POOL_PAUSING }, { NULL } }; int i; for ( i = 0; str2state[ i ].name != NULL; i++ ) { if ( str2state[ i ].state == pool->ltp_state ) { break; } } *((char **)value) = str2state[ i ].name; if ( str2state[ i ].name != NULL ) { count = -2; } } break; } ldap_pvt_thread_mutex_unlock( &pool->ltp_mutex ); if ( count > -1 ) { *((int *)value) = count; } return ( count == -1 ? -1 : 0 ); } /* * wrapper for ldap_pvt_thread_pool_query(), left around * for backwards compatibility */ int ldap_pvt_thread_pool_backload ( ldap_pvt_thread_pool_t *tpool ) { int rc, count; rc = ldap_pvt_thread_pool_query( tpool, LDAP_PVT_THREAD_POOL_PARAM_BACKLOAD, (void *)&count ); if ( rc == 0 ) { return count; } return rc; } int ldap_pvt_thread_pool_destroy ( ldap_pvt_thread_pool_t *tpool, int run_pending ) { struct ldap_int_thread_pool_s *pool, *pptr; ldap_int_thread_ctx_t *ctx; if (tpool == NULL) return(-1); pool = *tpool; if (pool == NULL) return(-1); ldap_pvt_thread_mutex_lock(&ldap_pvt_thread_pool_mutex); LDAP_STAILQ_FOREACH(pptr, &ldap_int_thread_pool_list, ltp_next) if (pptr == pool) break; if (pptr == pool) LDAP_STAILQ_REMOVE(&ldap_int_thread_pool_list, pool, ldap_int_thread_pool_s, ltp_next); ldap_pvt_thread_mutex_unlock(&ldap_pvt_thread_pool_mutex); if (pool != pptr) return(-1); ldap_pvt_thread_mutex_lock(&pool->ltp_mutex); pool->ltp_state = run_pending ? LDAP_INT_THREAD_POOL_FINISHING : LDAP_INT_THREAD_POOL_STOPPING; if ( pool->ltp_open_count ) { ldap_pvt_thread_cond_broadcast(&pool->ltp_cond); ldap_pvt_thread_cond_wait(&pool->ltp_cond, &pool->ltp_mutex); } ldap_pvt_thread_mutex_unlock(&pool->ltp_mutex); while ((ctx = LDAP_STAILQ_FIRST(&pool->ltp_pending_list)) != NULL) { LDAP_STAILQ_REMOVE_HEAD(&pool->ltp_pending_list, ltc_next.q); LDAP_FREE(ctx); } while ((ctx = LDAP_SLIST_FIRST(&pool->ltp_free_list)) != NULL) { LDAP_SLIST_REMOVE_HEAD(&pool->ltp_free_list, ltc_next.l); LDAP_FREE(ctx); } ldap_pvt_thread_cond_destroy(&pool->ltp_pcond); ldap_pvt_thread_cond_destroy(&pool->ltp_cond); ldap_pvt_thread_mutex_destroy(&pool->ltp_mutex); LDAP_FREE(pool); #ifdef LDAP_PVT_THREAD_POOL_SEM_LOAD_CONTROL if ( thread_pool_sem ) { LDAP_FREE( thread_pool_sem ); } #endif return(0); } static void * ldap_int_thread_pool_wrapper ( void *xpool ) { struct ldap_int_thread_pool_s *pool = xpool; ldap_int_thread_ctx_t *ctx; ldap_int_thread_userctx_t uctx; int i, keyslot, hash; if (pool == NULL) return NULL; for ( i=0; iltp_mutex); /* store pointer to our keys */ TID_HASH(uctx.ltu_id, hash); for (i = hash & (LDAP_MAXTHR-1); !ldap_pvt_thread_equal(thread_keys[i].id, uctx.ltu_id); i = (i+1) & (LDAP_MAXTHR-1)); thread_keys[i].ctx = &uctx; keyslot = i; while (pool->ltp_state != LDAP_INT_THREAD_POOL_STOPPING) { ctx = LDAP_STAILQ_FIRST(&pool->ltp_pending_list); if (ctx) { LDAP_STAILQ_REMOVE_HEAD(&pool->ltp_pending_list, ltc_next.q); } else { if (pool->ltp_state == LDAP_INT_THREAD_POOL_FINISHING) break; if (pool->ltp_max_count > 0 && pool->ltp_open_count > pool->ltp_max_count) { /* too many threads running (can happen if the * maximum threads value is set during ongoing * operation using ldap_pvt_thread_pool_maxthreads) * so let this thread die. */ break; } /* we could check an idle timer here, and let the * thread die if it has been inactive for a while. * only die if there are other open threads (i.e., * always have at least one thread open). the check * should be like this: * if (pool->ltp_open_count > 1 && pool->ltp_starting == 0) * check timer, leave thread (break;) * * Just use pthread_cond_timedwait if we want to * check idle time. */ if (pool->ltp_state == LDAP_INT_THREAD_POOL_RUNNING || pool->ltp_state == LDAP_INT_THREAD_POOL_PAUSING) { ldap_pvt_thread_cond_wait(&pool->ltp_cond, &pool->ltp_mutex); } continue; } pool->ltp_pending_count--; LDAP_SLIST_INSERT_HEAD(&pool->ltp_active_list, ctx, ltc_next.al); pool->ltp_active_count++; ldap_pvt_thread_mutex_unlock(&pool->ltp_mutex); ctx->ltc_start_routine(&uctx, ctx->ltc_arg); #ifdef LDAP_PVT_THREAD_POOL_SEM_LOAD_CONTROL ldap_lazy_sem_post( thread_pool_sem ); #endif ldap_pvt_thread_mutex_lock(&pool->ltp_mutex); LDAP_SLIST_REMOVE(&pool->ltp_active_list, ctx, ldap_int_thread_ctx_s, ltc_next.al); LDAP_SLIST_INSERT_HEAD(&pool->ltp_free_list, ctx, ltc_next.l); pool->ltp_active_count--; if (pool->ltp_state == LDAP_INT_THREAD_POOL_PAUSING) { if (pool->ltp_active_count < 2) { ldap_pvt_thread_cond_signal(&pool->ltp_pcond); } ldap_pvt_thread_cond_wait(&pool->ltp_cond, &pool->ltp_mutex); } } for ( i=0; iltp_open_count--; /* let pool_destroy know we're all done */ if (pool->ltp_open_count < 1) ldap_pvt_thread_cond_signal(&pool->ltp_cond); ldap_pvt_thread_mutex_unlock(&pool->ltp_mutex); ldap_pvt_thread_exit(NULL); return(NULL); } int ldap_pvt_thread_pool_pause ( ldap_pvt_thread_pool_t *tpool ) { struct ldap_int_thread_pool_s *pool; if (tpool == NULL) return(-1); pool = *tpool; if (pool == NULL) return(0); ldap_pvt_thread_mutex_lock(&pool->ltp_mutex); /* If someone else has already requested a pause, we have to wait */ while (pool->ltp_state == LDAP_INT_THREAD_POOL_PAUSING) { pool->ltp_pending_count++; pool->ltp_active_count--; ldap_pvt_thread_cond_wait(&pool->ltp_cond, &pool->ltp_mutex); pool->ltp_pending_count--; pool->ltp_active_count++; } /* Wait for everyone else to finish */ pool->ltp_state = LDAP_INT_THREAD_POOL_PAUSING; while (pool->ltp_active_count > 1) { ldap_pvt_thread_cond_wait(&pool->ltp_pcond, &pool->ltp_mutex); } ldap_pvt_thread_mutex_unlock(&pool->ltp_mutex); return(0); } int ldap_pvt_thread_pool_resume ( ldap_pvt_thread_pool_t *tpool ) { struct ldap_int_thread_pool_s *pool; if (tpool == NULL) return(-1); pool = *tpool; if (pool == NULL) return(0); ldap_pvt_thread_mutex_lock(&pool->ltp_mutex); pool->ltp_state = LDAP_INT_THREAD_POOL_RUNNING; ldap_pvt_thread_cond_broadcast(&pool->ltp_cond); ldap_pvt_thread_mutex_unlock(&pool->ltp_mutex); return(0); } int ldap_pvt_thread_pool_getkey( void *xctx, void *key, void **data, ldap_pvt_thread_pool_keyfree_t **kfree ) { ldap_int_thread_userctx_t *ctx = xctx; int i; if ( !ctx || !data ) return EINVAL; for ( i=0; iltu_key[i].ltk_key; i++ ) { if ( ctx->ltu_key[i].ltk_key == key ) { *data = ctx->ltu_key[i].ltk_data; if ( kfree ) *kfree = ctx->ltu_key[i].ltk_free; return 0; } } return ENOENT; } int ldap_pvt_thread_pool_setkey( void *xctx, void *key, void *data, ldap_pvt_thread_pool_keyfree_t *kfree ) { ldap_int_thread_userctx_t *ctx = xctx; int i; if ( !ctx || !key ) return EINVAL; for ( i=0; iltu_key[i].ltk_key || ctx->ltu_key[i].ltk_key == key ) { ctx->ltu_key[i].ltk_key = key; ctx->ltu_key[i].ltk_data = data; ctx->ltu_key[i].ltk_free = kfree; return 0; } } return ENOMEM; } /* Free all elements with this key, no matter which thread they're in. * May only be called while the pool is paused. */ void ldap_pvt_thread_pool_purgekey( void *key ) { int i, j; ldap_int_thread_userctx_t *ctx; for ( i=0; iltu_key[j].ltk_key == key ) { if (ctx->ltu_key[j].ltk_free) ctx->ltu_key[j].ltk_free( ctx->ltu_key[j].ltk_key, ctx->ltu_key[j].ltk_data ); ctx->ltu_key[j].ltk_key = NULL; ctx->ltu_key[j].ltk_free = NULL; break; } } } } } /* * This is necessary if the caller does not have access to the * thread context handle (for example, a slapd plugin calling * slapi_search_internal()). No doubt it is more efficient to * for the application to keep track of the thread context * handles itself. */ void *ldap_pvt_thread_pool_context( ) { ldap_pvt_thread_t tid; int i, hash; tid = ldap_pvt_thread_self(); if ( ldap_pvt_thread_equal( tid, ldap_int_main_tid )) return &ldap_int_main_thrctx; TID_HASH( tid, hash ); for (i = hash & (LDAP_MAXTHR-1); !ldap_pvt_thread_equal(thread_keys[i].id, tid_zero) && !ldap_pvt_thread_equal(thread_keys[i].id, tid); i = (i+1) & (LDAP_MAXTHR-1)); return thread_keys[i].ctx; } void ldap_pvt_thread_pool_context_reset( void *vctx ) { ldap_int_thread_userctx_t *ctx = vctx; int i; for ( i=0; iltu_key[i].ltk_key; i++) { if ( ctx->ltu_key[i].ltk_free ) ctx->ltu_key[i].ltk_free( ctx->ltu_key[i].ltk_key, ctx->ltu_key[i].ltk_data ); ctx->ltu_key[i].ltk_key = NULL; } } ldap_pvt_thread_t ldap_pvt_thread_pool_tid( void *vctx ) { ldap_int_thread_userctx_t *ctx = vctx; return ctx->ltu_id; } #endif /* LDAP_THREAD_HAVE_TPOOL */