Current Path : /usr/src/cddl/contrib/opensolaris/lib/libuutil/common/ |
FreeBSD hs32.drive.ne.jp 9.1-RELEASE FreeBSD 9.1-RELEASE #1: Wed Jan 14 12:18:08 JST 2015 root@hs32.drive.ne.jp:/sys/amd64/compile/hs32 amd64 |
Current File : //usr/src/cddl/contrib/opensolaris/lib/libuutil/common/uu_avl.c |
/* * CDDL HEADER START * * The contents of this file are subject to the terms of the * Common Development and Distribution License (the "License"). * You may not use this file except in compliance with the License. * * You can obtain a copy of the license at usr/src/OPENSOLARIS.LICENSE * or http://www.opensolaris.org/os/licensing. * See the License for the specific language governing permissions * and limitations under the License. * * When distributing Covered Code, include this CDDL HEADER in each * file and include the License file at usr/src/OPENSOLARIS.LICENSE. * If applicable, add the following below this CDDL HEADER, with the * fields enclosed by brackets "[]" replaced with your own identifying * information: Portions Copyright [yyyy] [name of copyright owner] * * CDDL HEADER END */ /* * Copyright 2008 Sun Microsystems, Inc. All rights reserved. * Use is subject to license terms. */ #pragma ident "%Z%%M% %I% %E% SMI" #include "libuutil_common.h" #include <stdlib.h> #include <string.h> #include <unistd.h> #include <sys/avl.h> static uu_avl_pool_t uu_null_apool = { &uu_null_apool, &uu_null_apool }; static pthread_mutex_t uu_apool_list_lock = PTHREAD_MUTEX_INITIALIZER; /* * The index mark change on every insert and delete, to catch stale * references. * * We leave the low bit alone, since the avl code uses it. */ #define INDEX_MAX (sizeof (uintptr_t) - 2) #define INDEX_NEXT(m) (((m) == INDEX_MAX)? 2 : ((m) + 2) & INDEX_MAX) #define INDEX_DECODE(i) ((i) & ~INDEX_MAX) #define INDEX_ENCODE(p, n) (((n) & ~INDEX_MAX) | (p)->ua_index) #define INDEX_VALID(p, i) (((i) & INDEX_MAX) == (p)->ua_index) #define INDEX_CHECK(i) (((i) & INDEX_MAX) != 0) /* * When an element is inactive (not in a tree), we keep a marked pointer to * its containing pool in its first word, and a NULL pointer in its second. * * On insert, we use these to verify that it comes from the correct pool. */ #define NODE_ARRAY(p, n) ((uintptr_t *)((uintptr_t)(n) + \ (pp)->uap_nodeoffset)) #define POOL_TO_MARKER(pp) (((uintptr_t)(pp) | 1)) #define DEAD_MARKER 0xc4 uu_avl_pool_t * uu_avl_pool_create(const char *name, size_t objsize, size_t nodeoffset, uu_compare_fn_t *compare_func, uint32_t flags) { uu_avl_pool_t *pp, *next, *prev; if (name == NULL || uu_check_name(name, UU_NAME_DOMAIN) == -1 || nodeoffset + sizeof (uu_avl_node_t) > objsize || compare_func == NULL) { uu_set_error(UU_ERROR_INVALID_ARGUMENT); return (NULL); } if (flags & ~UU_AVL_POOL_DEBUG) { uu_set_error(UU_ERROR_UNKNOWN_FLAG); return (NULL); } pp = uu_zalloc(sizeof (uu_avl_pool_t)); if (pp == NULL) { uu_set_error(UU_ERROR_NO_MEMORY); return (NULL); } (void) strlcpy(pp->uap_name, name, sizeof (pp->uap_name)); pp->uap_nodeoffset = nodeoffset; pp->uap_objsize = objsize; pp->uap_cmp = compare_func; if (flags & UU_AVL_POOL_DEBUG) pp->uap_debug = 1; pp->uap_last_index = 0; (void) pthread_mutex_init(&pp->uap_lock, NULL); pp->uap_null_avl.ua_next_enc = UU_PTR_ENCODE(&pp->uap_null_avl); pp->uap_null_avl.ua_prev_enc = UU_PTR_ENCODE(&pp->uap_null_avl); (void) pthread_mutex_lock(&uu_apool_list_lock); pp->uap_next = next = &uu_null_apool; pp->uap_prev = prev = next->uap_prev; next->uap_prev = pp; prev->uap_next = pp; (void) pthread_mutex_unlock(&uu_apool_list_lock); return (pp); } void uu_avl_pool_destroy(uu_avl_pool_t *pp) { if (pp->uap_debug) { if (pp->uap_null_avl.ua_next_enc != UU_PTR_ENCODE(&pp->uap_null_avl) || pp->uap_null_avl.ua_prev_enc != UU_PTR_ENCODE(&pp->uap_null_avl)) { uu_panic("uu_avl_pool_destroy: Pool \"%.*s\" (%p) has " "outstanding avls, or is corrupt.\n", (int)sizeof (pp->uap_name), pp->uap_name, (void *)pp); } } (void) pthread_mutex_lock(&uu_apool_list_lock); pp->uap_next->uap_prev = pp->uap_prev; pp->uap_prev->uap_next = pp->uap_next; (void) pthread_mutex_unlock(&uu_apool_list_lock); pp->uap_prev = NULL; pp->uap_next = NULL; uu_free(pp); } void uu_avl_node_init(void *base, uu_avl_node_t *np, uu_avl_pool_t *pp) { uintptr_t *na = (uintptr_t *)np; if (pp->uap_debug) { uintptr_t offset = (uintptr_t)np - (uintptr_t)base; if (offset + sizeof (*np) > pp->uap_objsize) { uu_panic("uu_avl_node_init(%p, %p, %p (\"%s\")): " "offset %ld doesn't fit in object (size %ld)\n", base, (void *)np, (void *)pp, pp->uap_name, (long)offset, (long)pp->uap_objsize); } if (offset != pp->uap_nodeoffset) { uu_panic("uu_avl_node_init(%p, %p, %p (\"%s\")): " "offset %ld doesn't match pool's offset (%ld)\n", base, (void *)np, (void *)pp, pp->uap_name, (long)offset, (long)pp->uap_objsize); } } na[0] = POOL_TO_MARKER(pp); na[1] = 0; } void uu_avl_node_fini(void *base, uu_avl_node_t *np, uu_avl_pool_t *pp) { uintptr_t *na = (uintptr_t *)np; if (pp->uap_debug) { if (na[0] == DEAD_MARKER && na[1] == DEAD_MARKER) { uu_panic("uu_avl_node_fini(%p, %p, %p (\"%s\")): " "node already finied\n", base, (void *)np, (void *)pp, pp->uap_name); } if (na[0] != POOL_TO_MARKER(pp) || na[1] != 0) { uu_panic("uu_avl_node_fini(%p, %p, %p (\"%s\")): " "node corrupt, in tree, or in different pool\n", base, (void *)np, (void *)pp, pp->uap_name); } } na[0] = DEAD_MARKER; na[1] = DEAD_MARKER; na[2] = DEAD_MARKER; } struct uu_avl_node_compare_info { uu_compare_fn_t *ac_compare; void *ac_private; void *ac_right; void *ac_found; }; static int uu_avl_node_compare(const void *l, const void *r) { struct uu_avl_node_compare_info *info = (struct uu_avl_node_compare_info *)l; int res = info->ac_compare(r, info->ac_right, info->ac_private); if (res == 0) { if (info->ac_found == NULL) info->ac_found = (void *)r; return (-1); } if (res < 0) return (1); return (-1); } uu_avl_t * uu_avl_create(uu_avl_pool_t *pp, void *parent, uint32_t flags) { uu_avl_t *ap, *next, *prev; if (flags & ~UU_AVL_DEBUG) { uu_set_error(UU_ERROR_UNKNOWN_FLAG); return (NULL); } ap = uu_zalloc(sizeof (*ap)); if (ap == NULL) { uu_set_error(UU_ERROR_NO_MEMORY); return (NULL); } ap->ua_pool = pp; ap->ua_parent_enc = UU_PTR_ENCODE(parent); ap->ua_debug = pp->uap_debug || (flags & UU_AVL_DEBUG); ap->ua_index = (pp->uap_last_index = INDEX_NEXT(pp->uap_last_index)); avl_create(&ap->ua_tree, &uu_avl_node_compare, pp->uap_objsize, pp->uap_nodeoffset); ap->ua_null_walk.uaw_next = &ap->ua_null_walk; ap->ua_null_walk.uaw_prev = &ap->ua_null_walk; (void) pthread_mutex_lock(&pp->uap_lock); next = &pp->uap_null_avl; prev = UU_PTR_DECODE(next->ua_prev_enc); ap->ua_next_enc = UU_PTR_ENCODE(next); ap->ua_prev_enc = UU_PTR_ENCODE(prev); next->ua_prev_enc = UU_PTR_ENCODE(ap); prev->ua_next_enc = UU_PTR_ENCODE(ap); (void) pthread_mutex_unlock(&pp->uap_lock); return (ap); } void uu_avl_destroy(uu_avl_t *ap) { uu_avl_pool_t *pp = ap->ua_pool; if (ap->ua_debug) { if (avl_numnodes(&ap->ua_tree) != 0) { uu_panic("uu_avl_destroy(%p): tree not empty\n", (void *)ap); } if (ap->ua_null_walk.uaw_next != &ap->ua_null_walk || ap->ua_null_walk.uaw_prev != &ap->ua_null_walk) { uu_panic("uu_avl_destroy(%p): outstanding walkers\n", (void *)ap); } } (void) pthread_mutex_lock(&pp->uap_lock); UU_AVL_PTR(ap->ua_next_enc)->ua_prev_enc = ap->ua_prev_enc; UU_AVL_PTR(ap->ua_prev_enc)->ua_next_enc = ap->ua_next_enc; (void) pthread_mutex_unlock(&pp->uap_lock); ap->ua_prev_enc = UU_PTR_ENCODE(NULL); ap->ua_next_enc = UU_PTR_ENCODE(NULL); ap->ua_pool = NULL; avl_destroy(&ap->ua_tree); uu_free(ap); } size_t uu_avl_numnodes(uu_avl_t *ap) { return (avl_numnodes(&ap->ua_tree)); } void * uu_avl_first(uu_avl_t *ap) { return (avl_first(&ap->ua_tree)); } void * uu_avl_last(uu_avl_t *ap) { return (avl_last(&ap->ua_tree)); } void * uu_avl_next(uu_avl_t *ap, void *node) { return (AVL_NEXT(&ap->ua_tree, node)); } void * uu_avl_prev(uu_avl_t *ap, void *node) { return (AVL_PREV(&ap->ua_tree, node)); } static void _avl_walk_init(uu_avl_walk_t *wp, uu_avl_t *ap, uint32_t flags) { uu_avl_walk_t *next, *prev; int robust = (flags & UU_WALK_ROBUST); int direction = (flags & UU_WALK_REVERSE)? -1 : 1; (void) memset(wp, 0, sizeof (*wp)); wp->uaw_avl = ap; wp->uaw_robust = robust; wp->uaw_dir = direction; if (direction > 0) wp->uaw_next_result = avl_first(&ap->ua_tree); else wp->uaw_next_result = avl_last(&ap->ua_tree); if (ap->ua_debug || robust) { wp->uaw_next = next = &ap->ua_null_walk; wp->uaw_prev = prev = next->uaw_prev; next->uaw_prev = wp; prev->uaw_next = wp; } } static void * _avl_walk_advance(uu_avl_walk_t *wp, uu_avl_t *ap) { void *np = wp->uaw_next_result; avl_tree_t *t = &ap->ua_tree; if (np == NULL) return (NULL); wp->uaw_next_result = (wp->uaw_dir > 0)? AVL_NEXT(t, np) : AVL_PREV(t, np); return (np); } static void _avl_walk_fini(uu_avl_walk_t *wp) { if (wp->uaw_next != NULL) { wp->uaw_next->uaw_prev = wp->uaw_prev; wp->uaw_prev->uaw_next = wp->uaw_next; wp->uaw_next = NULL; wp->uaw_prev = NULL; } wp->uaw_avl = NULL; wp->uaw_next_result = NULL; } uu_avl_walk_t * uu_avl_walk_start(uu_avl_t *ap, uint32_t flags) { uu_avl_walk_t *wp; if (flags & ~(UU_WALK_ROBUST | UU_WALK_REVERSE)) { uu_set_error(UU_ERROR_UNKNOWN_FLAG); return (NULL); } wp = uu_zalloc(sizeof (*wp)); if (wp == NULL) { uu_set_error(UU_ERROR_NO_MEMORY); return (NULL); } _avl_walk_init(wp, ap, flags); return (wp); } void * uu_avl_walk_next(uu_avl_walk_t *wp) { return (_avl_walk_advance(wp, wp->uaw_avl)); } void uu_avl_walk_end(uu_avl_walk_t *wp) { _avl_walk_fini(wp); uu_free(wp); } int uu_avl_walk(uu_avl_t *ap, uu_walk_fn_t *func, void *private, uint32_t flags) { void *e; uu_avl_walk_t my_walk; int status = UU_WALK_NEXT; if (flags & ~(UU_WALK_ROBUST | UU_WALK_REVERSE)) { uu_set_error(UU_ERROR_UNKNOWN_FLAG); return (-1); } _avl_walk_init(&my_walk, ap, flags); while (status == UU_WALK_NEXT && (e = _avl_walk_advance(&my_walk, ap)) != NULL) status = (*func)(e, private); _avl_walk_fini(&my_walk); if (status >= 0) return (0); uu_set_error(UU_ERROR_CALLBACK_FAILED); return (-1); } void uu_avl_remove(uu_avl_t *ap, void *elem) { uu_avl_walk_t *wp; uu_avl_pool_t *pp = ap->ua_pool; uintptr_t *na = NODE_ARRAY(pp, elem); if (ap->ua_debug) { /* * invalidate outstanding uu_avl_index_ts. */ ap->ua_index = INDEX_NEXT(ap->ua_index); } /* * Robust walkers most be advanced, if we are removing the node * they are currently using. In debug mode, non-robust walkers * are also on the walker list. */ for (wp = ap->ua_null_walk.uaw_next; wp != &ap->ua_null_walk; wp = wp->uaw_next) { if (wp->uaw_robust) { if (elem == wp->uaw_next_result) (void) _avl_walk_advance(wp, ap); } else if (wp->uaw_next_result != NULL) { uu_panic("uu_avl_remove(%p, %p): active non-robust " "walker\n", (void *)ap, elem); } } avl_remove(&ap->ua_tree, elem); na[0] = POOL_TO_MARKER(pp); na[1] = 0; } void * uu_avl_teardown(uu_avl_t *ap, void **cookie) { void *elem = avl_destroy_nodes(&ap->ua_tree, cookie); if (elem != NULL) { uu_avl_pool_t *pp = ap->ua_pool; uintptr_t *na = NODE_ARRAY(pp, elem); na[0] = POOL_TO_MARKER(pp); na[1] = 0; } return (elem); } void * uu_avl_find(uu_avl_t *ap, void *elem, void *private, uu_avl_index_t *out) { struct uu_avl_node_compare_info info; void *result; info.ac_compare = ap->ua_pool->uap_cmp; info.ac_private = private; info.ac_right = elem; info.ac_found = NULL; result = avl_find(&ap->ua_tree, &info, out); if (out != NULL) *out = INDEX_ENCODE(ap, *out); if (ap->ua_debug && result != NULL) uu_panic("uu_avl_find: internal error: avl_find succeeded\n"); return (info.ac_found); } void uu_avl_insert(uu_avl_t *ap, void *elem, uu_avl_index_t idx) { if (ap->ua_debug) { uu_avl_pool_t *pp = ap->ua_pool; uintptr_t *na = NODE_ARRAY(pp, elem); if (na[1] != 0) uu_panic("uu_avl_insert(%p, %p, %p): node already " "in tree, or corrupt\n", (void *)ap, elem, (void *)idx); if (na[0] == 0) uu_panic("uu_avl_insert(%p, %p, %p): node not " "initialized\n", (void *)ap, elem, (void *)idx); if (na[0] != POOL_TO_MARKER(pp)) uu_panic("uu_avl_insert(%p, %p, %p): node from " "other pool, or corrupt\n", (void *)ap, elem, (void *)idx); if (!INDEX_VALID(ap, idx)) uu_panic("uu_avl_insert(%p, %p, %p): %s\n", (void *)ap, elem, (void *)idx, INDEX_CHECK(idx)? "outdated index" : "invalid index"); /* * invalidate outstanding uu_avl_index_ts. */ ap->ua_index = INDEX_NEXT(ap->ua_index); } avl_insert(&ap->ua_tree, elem, INDEX_DECODE(idx)); } void * uu_avl_nearest_next(uu_avl_t *ap, uu_avl_index_t idx) { if (ap->ua_debug && !INDEX_VALID(ap, idx)) uu_panic("uu_avl_nearest_next(%p, %p): %s\n", (void *)ap, (void *)idx, INDEX_CHECK(idx)? "outdated index" : "invalid index"); return (avl_nearest(&ap->ua_tree, INDEX_DECODE(idx), AVL_AFTER)); } void * uu_avl_nearest_prev(uu_avl_t *ap, uu_avl_index_t idx) { if (ap->ua_debug && !INDEX_VALID(ap, idx)) uu_panic("uu_avl_nearest_prev(%p, %p): %s\n", (void *)ap, (void *)idx, INDEX_CHECK(idx)? "outdated index" : "invalid index"); return (avl_nearest(&ap->ua_tree, INDEX_DECODE(idx), AVL_BEFORE)); } /* * called from uu_lockup() and uu_release(), as part of our fork1()-safety. */ void uu_avl_lockup(void) { uu_avl_pool_t *pp; (void) pthread_mutex_lock(&uu_apool_list_lock); for (pp = uu_null_apool.uap_next; pp != &uu_null_apool; pp = pp->uap_next) (void) pthread_mutex_lock(&pp->uap_lock); } void uu_avl_release(void) { uu_avl_pool_t *pp; for (pp = uu_null_apool.uap_next; pp != &uu_null_apool; pp = pp->uap_next) (void) pthread_mutex_unlock(&pp->uap_lock); (void) pthread_mutex_unlock(&uu_apool_list_lock); }