/* * Copyright (c) 2010 Kungliga Tekniska Högskolan * (Royal Institute of Technology, Stockholm, Sweden). * All rights reserved. * * Portions Copyright (c) 2010 Apple Inc. All rights reserved. * * Redistribution and use in source and binary forms, with or without * modification, are permitted provided that the following conditions * are met: * * 1. Redistributions of source code must retain the above copyright * notice, this list of conditions and the following disclaimer. * * 2. Redistributions in binary form must reproduce the above copyright * notice, this list of conditions and the following disclaimer in the * documentation and/or other materials provided with the distribution. * * 3. Neither the name of the Institute nor the names of its contributors * may be used to endorse or promote products derived from this software * without specific prior written permission. * * THIS SOFTWARE IS PROVIDED BY THE INSTITUTE AND CONTRIBUTORS ``AS IS'' AND * ANY EXPRESS OR IMPLIED WARRANTIES, INCLUDING, BUT NOT LIMITED TO, THE * IMPLIED WARRANTIES OF MERCHANTABILITY AND FITNESS FOR A PARTICULAR PURPOSE * ARE DISCLAIMED. IN NO EVENT SHALL THE INSTITUTE OR CONTRIBUTORS BE LIABLE * FOR ANY DIRECT, INDIRECT, INCIDENTAL, SPECIAL, EXEMPLARY, OR CONSEQUENTIAL * DAMAGES (INCLUDING, BUT NOT LIMITED TO, PROCUREMENT OF SUBSTITUTE GOODS * OR SERVICES; LOSS OF USE, DATA, OR PROFITS; OR BUSINESS INTERRUPTION) * HOWEVER CAUSED AND ON ANY THEORY OF LIABILITY, WHETHER IN CONTRACT, STRICT * LIABILITY, OR TORT (INCLUDING NEGLIGENCE OR OTHERWISE) ARISING IN ANY WAY * OUT OF THE USE OF THIS SOFTWARE, EVEN IF ADVISED OF THE POSSIBILITY OF * SUCH DAMAGE. */ #include "baselocl.h" #include "heimbase-atomics.h" #include static heim_base_atomic(uint32_t) tidglobal = HEIM_TID_USER; struct heim_base { heim_const_type_t isa; heim_base_atomic(uint32_t) ref_cnt; HEIM_TAILQ_ENTRY(heim_base) autorel; heim_auto_release_t autorelpool; uintptr_t isaextra[3]; }; /* specialized version of base */ struct heim_base_mem { heim_const_type_t isa; heim_base_atomic(uint32_t) ref_cnt; HEIM_TAILQ_ENTRY(heim_base) autorel; heim_auto_release_t autorelpool; const char *name; void (HEIM_CALLCONV *dealloc)(void *); uintptr_t isaextra[1]; }; #define PTR2BASE(ptr) (((struct heim_base *)ptr) - 1) #define BASE2PTR(ptr) ((void *)(((struct heim_base *)ptr) + 1)) HEIMDAL_MUTEX * HEIM_CALLCONV heim_base_mutex(void) { static HEIMDAL_MUTEX _heim_base_mutex = HEIMDAL_MUTEX_INITIALIZER; return &_heim_base_mutex; } /* * Auto release structure */ struct heim_auto_release { HEIM_TAILQ_HEAD(, heim_base) pool; HEIMDAL_MUTEX pool_mutex; struct heim_auto_release *parent; }; /** * Retain object (i.e., take a reference) * * @param object to be released, NULL is ok * * @return the same object as passed in */ heim_object_t heim_retain(heim_object_t ptr) { struct heim_base *p; if (ptr == NULL || heim_base_is_tagged(ptr)) return ptr; p = PTR2BASE(ptr); if (heim_base_atomic_load(&p->ref_cnt) == UINT32_MAX) return ptr; if ((heim_base_atomic_inc_32(&p->ref_cnt) - 1) == 0) heim_abort("resurection"); return ptr; } /** * Release object, free if reference count reaches zero * * @param object to be released */ void heim_release(void *ptr) { heim_base_atomic(uint32_t) old; struct heim_base *p; if (ptr == NULL || heim_base_is_tagged(ptr)) return; p = PTR2BASE(ptr); if (heim_base_atomic_load(&p->ref_cnt) == UINT32_MAX) return; old = heim_base_atomic_dec_32(&p->ref_cnt) + 1; if (old > 1) return; if (old == 1) { heim_auto_release_t ar = p->autorelpool; /* remove from autorel pool list */ if (ar) { p->autorelpool = NULL; HEIMDAL_MUTEX_lock(&ar->pool_mutex); HEIM_TAILQ_REMOVE(&ar->pool, p, autorel); HEIMDAL_MUTEX_unlock(&ar->pool_mutex); } if (p->isa->dealloc) p->isa->dealloc(ptr); free(p); } else heim_abort("over release"); } /** * If used require wrapped in autorelease pool */ heim_string_t heim_description(heim_object_t ptr) { struct heim_base *p = PTR2BASE(ptr); if (p->isa->desc == NULL) return heim_auto_release(heim_string_ref_create(p->isa->name, NULL)); return heim_auto_release(p->isa->desc(ptr)); } void _heim_make_permanent(heim_object_t ptr) { struct heim_base *p = PTR2BASE(ptr); heim_base_atomic_store(&p->ref_cnt, UINT32_MAX); } static heim_type_t tagged_isa[9] = { &_heim_number_object, &_heim_null_object, &_heim_bool_object, NULL, NULL, NULL, NULL, NULL, NULL }; heim_const_type_t _heim_get_isa(heim_object_t ptr) { struct heim_base *p; if (heim_base_is_tagged(ptr)) { if (heim_base_is_tagged_object(ptr)) return tagged_isa[heim_base_tagged_object_tid(ptr)]; heim_abort("not a supported tagged type"); } p = PTR2BASE(ptr); return p->isa; } /** * Get type ID of object * * @param object object to get type id of * * @return type id of object */ heim_tid_t heim_get_tid(heim_object_t ptr) { heim_const_type_t isa = _heim_get_isa(ptr); return isa->tid; } /** * Get hash value of object * * @param object object to get hash value for * * @return a hash value */ uintptr_t heim_get_hash(heim_object_t ptr) { heim_const_type_t isa = _heim_get_isa(ptr); if (isa->hash) return isa->hash(ptr); return (uintptr_t)ptr; } /** * Compare two objects, returns 0 if equal, can use used for qsort() * and friends. * * @param a first object to compare * @param b first object to compare * * @return 0 if objects are equal */ int heim_cmp(heim_object_t a, heim_object_t b) { heim_tid_t ta, tb; heim_const_type_t isa; ta = heim_get_tid(a); tb = heim_get_tid(b); if (ta != tb) return ta - tb; isa = _heim_get_isa(a); if (isa->cmp) return isa->cmp(a, b); return (uintptr_t)a - (uintptr_t)b; } /* * Private - allocates an memory object */ static void HEIM_CALLCONV memory_dealloc(void *ptr) { if (ptr) { struct heim_base_mem *p = (struct heim_base_mem *)PTR2BASE(ptr); if (p->dealloc) p->dealloc(ptr); } } static const struct heim_type_data memory_object = { HEIM_TID_MEMORY, "memory-object", NULL, memory_dealloc, NULL, NULL, NULL, NULL }; /** * Allocate memory for an object of anonymous type * * @param size size of object to be allocated * @param name name of ad-hoc type * @param dealloc destructor function * * Objects allocated with this interface do not serialize. * * @return allocated object */ void * heim_alloc(size_t size, const char *name, heim_type_dealloc dealloc) { /* XXX use posix_memalign */ struct heim_base_mem *p = calloc(1, size + sizeof(*p)); if (p == NULL) return NULL; p->isa = &memory_object; p->ref_cnt = 1; p->name = name; p->dealloc = dealloc; return BASE2PTR(p); } heim_type_t _heim_create_type(const char *name, heim_type_init init, heim_type_dealloc dealloc, heim_type_copy copy, heim_type_cmp cmp, heim_type_hash hash, heim_type_description desc) { heim_type_t type; type = calloc(1, sizeof(*type)); if (type == NULL) return NULL; type->tid = heim_base_atomic_inc_32(&tidglobal); type->name = name; type->init = init; type->dealloc = dealloc; type->copy = copy; type->cmp = cmp; type->hash = hash; type->desc = desc; return type; } heim_object_t _heim_alloc_object(heim_const_type_t type, size_t size) { /* XXX should use posix_memalign */ struct heim_base *p = calloc(1, size + sizeof(*p)); if (p == NULL) return NULL; p->isa = type; p->ref_cnt = 1; return BASE2PTR(p); } void * _heim_get_isaextra(heim_object_t ptr, size_t idx) { struct heim_base *p; heim_assert(ptr != NULL, "internal error"); p = (struct heim_base *)PTR2BASE(ptr); if (p->isa == &memory_object) return NULL; heim_assert(idx < 3, "invalid private heim_base extra data index"); return &p->isaextra[idx]; } heim_tid_t _heim_type_get_tid(heim_type_t type) { return type->tid; } #if !defined(WIN32) && !defined(HAVE_DISPATCH_DISPATCH_H) && defined(ENABLE_PTHREAD_SUPPORT) static pthread_once_t once_arg_key_once = PTHREAD_ONCE_INIT; static pthread_key_t once_arg_key; static void once_arg_key_once_init(void) { errno = pthread_key_create(&once_arg_key, NULL); if (errno != 0) { fprintf(stderr, "Error: pthread_key_create() failed, cannot continue: %s\n", strerror(errno)); abort(); } } struct once_callback { void (*fn)(void *); void *data; }; static void once_callback_caller(void) { struct once_callback *once_callback = pthread_getspecific(once_arg_key); if (once_callback == NULL) { fprintf(stderr, "Error: pthread_once() calls callback on " "different thread?! Cannot continue.\n"); abort(); } once_callback->fn(once_callback->data); } #endif /** * Call func once and only once * * @param once pointer to a heim_base_once_t * @param ctx context passed to func * @param func function to be called */ void heim_base_once_f(heim_base_once_t *once, void *ctx, void (*func)(void *)) { #if defined(WIN32) /* * With a libroken wrapper for some CAS function and a libroken yield() * wrapper we could make this the default implementation when we have * neither Grand Central nor POSX threads. * * We could also adapt the double-checked lock pattern with CAS * providing the necessary memory barriers in the absence of * portable explicit memory barrier APIs. */ /* * We use CAS operations in large part to provide implied memory * barriers. * * State 0 means that func() has never executed. * State 1 means that func() is executing. * State 2 means that func() has completed execution. */ if (InterlockedCompareExchange(once, 1L, 0L) == 0L) { /* State is now 1 */ (*func)(ctx); (void)InterlockedExchange(once, 2L); /* State is now 2 */ } else { /* * The InterlockedCompareExchange is being used to fetch * the current state under a full memory barrier. As long * as the current state is 1 continue to spin. */ while (InterlockedCompareExchange(once, 2L, 0L) == 1L) SwitchToThread(); } #elif defined(HAVE_DISPATCH_DISPATCH_H) dispatch_once_f(once, ctx, func); #elif defined(ENABLE_PTHREAD_SUPPORT) struct once_callback once_callback; once_callback.fn = func; once_callback.data = ctx; errno = pthread_once(&once_arg_key_once, once_arg_key_once_init); if (errno != 0) { fprintf(stderr, "Error: pthread_once() failed, cannot continue: %s\n", strerror(errno)); abort(); } errno = pthread_setspecific(once_arg_key, &once_callback); if (errno != 0) { fprintf(stderr, "Error: pthread_setspecific() failed, cannot continue: %s\n", strerror(errno)); abort(); } errno = pthread_once(once, once_callback_caller); if (errno != 0) { fprintf(stderr, "Error: pthread_once() failed, cannot continue: %s\n", strerror(errno)); abort(); } #else static HEIMDAL_MUTEX mutex = HEIMDAL_MUTEX_INITIALIZER; HEIMDAL_MUTEX_lock(&mutex); if (*once == 0) { *once = 1; HEIMDAL_MUTEX_unlock(&mutex); func(ctx); HEIMDAL_MUTEX_lock(&mutex); *once = 2; HEIMDAL_MUTEX_unlock(&mutex); } else if (*once == 2) { HEIMDAL_MUTEX_unlock(&mutex); } else { HEIMDAL_MUTEX_unlock(&mutex); while (1) { struct timeval tv = { 0, 1000 }; select(0, NULL, NULL, NULL, &tv); HEIMDAL_MUTEX_lock(&mutex); if (*once == 2) break; HEIMDAL_MUTEX_unlock(&mutex); } HEIMDAL_MUTEX_unlock(&mutex); } #endif } /** * Abort and log the failure (using syslog) */ void heim_abort(const char *fmt, ...) HEIMDAL_NORETURN_ATTRIBUTE HEIMDAL_PRINTF_ATTRIBUTE((__printf__, 1, 2)) { va_list ap; va_start(ap, fmt); heim_abortv(fmt, ap); va_end(ap); } /** * Abort and log the failure (using syslog) */ void heim_abortv(const char *fmt, va_list ap) HEIMDAL_NORETURN_ATTRIBUTE HEIMDAL_PRINTF_ATTRIBUTE((__printf__, 1, 0)) { static char str[1024]; vsnprintf(str, sizeof(str), fmt, ap); syslog(LOG_ERR, "heim_abort: %s", str); abort(); } /* * */ static int ar_created = 0; static HEIMDAL_thread_key ar_key; struct ar_tls { struct heim_auto_release *head; struct heim_auto_release *current; HEIMDAL_MUTEX tls_mutex; }; static void ar_tls_delete(void *ptr) { struct ar_tls *tls = ptr; heim_auto_release_t next = NULL; if (tls == NULL) return; for (; tls->current != NULL; tls->current = next) { next = tls->current->parent; heim_release(tls->current); } free(tls); } static void init_ar_tls(void *ptr) { int ret; HEIMDAL_key_create(&ar_key, ar_tls_delete, ret); if (ret == 0) ar_created = 1; } static struct ar_tls * autorel_tls(void) { static heim_base_once_t once = HEIM_BASE_ONCE_INIT; struct ar_tls *arp; int ret; heim_base_once_f(&once, NULL, init_ar_tls); if (!ar_created) return NULL; arp = HEIMDAL_getspecific(ar_key); if (arp == NULL) { arp = calloc(1, sizeof(*arp)); if (arp == NULL) return NULL; HEIMDAL_setspecific(ar_key, arp, ret); if (ret) { free(arp); return NULL; } } return arp; } static void HEIM_CALLCONV autorel_dealloc(void *ptr) { heim_auto_release_t ar = ptr; struct ar_tls *tls; tls = autorel_tls(); if (tls == NULL) heim_abort("autorelease pool released on thread w/o autorelease inited"); heim_auto_release_drain(ar); if (!HEIM_TAILQ_EMPTY(&ar->pool)) heim_abort("pool not empty after draining"); HEIMDAL_MUTEX_lock(&tls->tls_mutex); if (tls->current != ptr) heim_abort("autorelease not releaseing top pool"); tls->current = ar->parent; HEIMDAL_MUTEX_unlock(&tls->tls_mutex); } static int autorel_cmp(void *a, void *b) { return (a == b); } static uintptr_t autorel_hash(void *ptr) { return (uintptr_t)ptr; } static struct heim_type_data _heim_autorel_object = { HEIM_TID_AUTORELEASE, "autorelease-pool", NULL, autorel_dealloc, NULL, autorel_cmp, autorel_hash, NULL }; /** * Create thread-specific object auto-release pool * * Objects placed on the per-thread auto-release pool (with * heim_auto_release()) can be released in one fell swoop by calling * heim_auto_release_drain(). */ heim_auto_release_t heim_auto_release_create(void) { struct ar_tls *tls = autorel_tls(); heim_auto_release_t ar; if (tls == NULL) heim_abort("Failed to create/get autorelease head"); ar = _heim_alloc_object(&_heim_autorel_object, sizeof(struct heim_auto_release)); if (ar) { HEIMDAL_MUTEX_lock(&tls->tls_mutex); if (tls->head == NULL) tls->head = ar; ar->parent = tls->current; tls->current = ar; HEIMDAL_MUTEX_unlock(&tls->tls_mutex); } return ar; } /** * Place the current object on the thread's auto-release pool * * @param ptr object */ heim_object_t heim_auto_release(heim_object_t ptr) { struct heim_base *p; struct ar_tls *tls; heim_auto_release_t ar; if (ptr == NULL || heim_base_is_tagged(ptr)) return ptr; p = PTR2BASE(ptr); tls = autorel_tls(); /* drop from old pool */ if ((ar = p->autorelpool) != NULL) { HEIMDAL_MUTEX_lock(&ar->pool_mutex); HEIM_TAILQ_REMOVE(&ar->pool, p, autorel); p->autorelpool = NULL; HEIMDAL_MUTEX_unlock(&ar->pool_mutex); } if (tls == NULL || (ar = tls->current) == NULL) heim_abort("no auto relase pool in place, would leak"); HEIMDAL_MUTEX_lock(&ar->pool_mutex); HEIM_TAILQ_INSERT_HEAD(&ar->pool, p, autorel); p->autorelpool = ar; HEIMDAL_MUTEX_unlock(&ar->pool_mutex); return ptr; } /** * Release all objects on the given auto-release pool */ void heim_auto_release_drain(heim_auto_release_t autorel) { heim_object_t obj; /* release all elements on the tail queue */ HEIMDAL_MUTEX_lock(&autorel->pool_mutex); while(!HEIM_TAILQ_EMPTY(&autorel->pool)) { obj = HEIM_TAILQ_FIRST(&autorel->pool); HEIMDAL_MUTEX_unlock(&autorel->pool_mutex); heim_release(BASE2PTR(obj)); HEIMDAL_MUTEX_lock(&autorel->pool_mutex); } HEIMDAL_MUTEX_unlock(&autorel->pool_mutex); } /* * Helper for heim_path_vget() and heim_path_delete(). On success * outputs the node named by the path and the parent node and key * (useful for heim_path_delete()). */ static heim_object_t heim_path_vget2(heim_object_t ptr, heim_object_t *parent, heim_object_t *key, heim_error_t *error, va_list ap) { heim_object_t path_element; heim_object_t node, next_node; heim_tid_t node_type; *parent = NULL; *key = NULL; if (ptr == NULL) return NULL; for (node = ptr; node != NULL; ) { path_element = va_arg(ap, heim_object_t); if (path_element == NULL) { *parent = node; *key = path_element; return node; } node_type = heim_get_tid(node); switch (node_type) { case HEIM_TID_ARRAY: case HEIM_TID_DICT: case HEIM_TID_DB: break; default: if (node == ptr) heim_abort("heim_path_get() only operates on container types"); return NULL; } if (node_type == HEIM_TID_DICT) { next_node = heim_dict_get_value(node, path_element); } else if (node_type == HEIM_TID_DB) { next_node = _heim_db_get_value(node, NULL, path_element, NULL); } else { int idx = -1; /* node_type == HEIM_TID_ARRAY */ if (heim_get_tid(path_element) == HEIM_TID_NUMBER) idx = heim_number_get_int(path_element); if (idx < 0) { if (error) *error = heim_error_create(EINVAL, "heim_path_get() path elements " "for array nodes must be " "numeric and positive"); return NULL; } next_node = heim_array_get_value(node, idx); } node = next_node; } return NULL; } /** * Get a node in a heim_object tree by path * * @param ptr tree * @param error error (output) * @param ap NULL-terminated va_list of heim_object_ts that form a path * * @return object (not retained) if found * * @addtogroup heimbase */ heim_object_t heim_path_vget(heim_object_t ptr, heim_error_t *error, va_list ap) { heim_object_t p, k; return heim_path_vget2(ptr, &p, &k, error, ap); } /** * Get a node in a tree by path, with retained reference * * @param ptr tree * @param error error (output) * @param ap NULL-terminated va_list of heim_object_ts that form a path * * @return retained object if found * * @addtogroup heimbase */ heim_object_t heim_path_vcopy(heim_object_t ptr, heim_error_t *error, va_list ap) { heim_object_t p, k; return heim_retain(heim_path_vget2(ptr, &p, &k, error, ap)); } /** * Get a node in a tree by path * * @param ptr tree * @param error error (output) * @param ... NULL-terminated va_list of heim_object_ts that form a path * * @return object (not retained) if found * * @addtogroup heimbase */ heim_object_t heim_path_get(heim_object_t ptr, heim_error_t *error, ...) { heim_object_t o; heim_object_t p, k; va_list ap; if (ptr == NULL) return NULL; va_start(ap, error); o = heim_path_vget2(ptr, &p, &k, error, ap); va_end(ap); return o; } /** * Get a node in a tree by path, with retained reference * * @param ptr tree * @param error error (output) * @param ... NULL-terminated va_list of heim_object_ts that form a path * * @return retained object if found * * @addtogroup heimbase */ heim_object_t heim_path_copy(heim_object_t ptr, heim_error_t *error, ...) { heim_object_t o; heim_object_t p, k; va_list ap; if (ptr == NULL) return NULL; va_start(ap, error); o = heim_retain(heim_path_vget2(ptr, &p, &k, error, ap)); va_end(ap); return o; } /** * Create a path in a heim_object_t tree * * @param ptr the tree * @param size the size of the heim_dict_t nodes to be created * @param leaf leaf node to be added, if any * @param error error (output) * @param ap NULL-terminated of path component objects * * Create a path of heim_dict_t interior nodes in a given heim_object_t * tree, as necessary, and set/replace a leaf, if given (if leaf is NULL * then the leaf is not deleted). * * @return 0 on success, else a system error * * @addtogroup heimbase */ int heim_path_vcreate(heim_object_t ptr, size_t size, heim_object_t leaf, heim_error_t *error, va_list ap) { heim_object_t path_element = va_arg(ap, heim_object_t); heim_object_t next_path_element = NULL; heim_object_t node = ptr; heim_object_t next_node = NULL; heim_tid_t node_type; int ret = 0; if (ptr == NULL) heim_abort("heim_path_vcreate() does not create root nodes"); while (path_element != NULL) { int idx = -1; next_path_element = va_arg(ap, heim_object_t); node_type = heim_get_tid(node); if (node_type == HEIM_TID_DICT) { next_node = heim_dict_get_value(node, path_element); } else if (node_type == HEIM_TID_ARRAY) { if (heim_get_tid(path_element) == HEIM_TID_NUMBER) idx = heim_number_get_int(path_element); if (idx < 0) { if (error) *error = heim_error_create(EINVAL, "heim_path() path elements for " "array nodes must be numeric " "and positive"); return EINVAL; } if (idx < heim_array_get_length(node)) { next_node = heim_array_get_value(node, idx); } else if (idx == heim_array_get_length(node)) { next_node = NULL; } else { if (error) *error = heim_error_create(EINVAL, "Index for array in path is too large"); return EINVAL; } } else if (node_type == HEIM_TID_DB && next_path_element != NULL) { if (error) *error = heim_error_create(EINVAL, "Interior node is a DB"); return EINVAL; } if (next_path_element == NULL) break; /* Create missing interior node */ if (next_node == NULL) { heim_dict_t new_node; new_node = heim_dict_create(size); /* no arrays or DBs, just dicts */ if (new_node == NULL) { ret = ENOMEM; goto err; } if (node_type == HEIM_TID_DICT) { ret = heim_dict_set_value(node, path_element, new_node); next_node = heim_dict_get_value(node, path_element); } else if (node_type == HEIM_TID_ARRAY && heim_number_get_int(path_element) <= heim_array_get_length(node)) { ret = heim_array_insert_value(node, heim_number_get_int(path_element), new_node); next_node = heim_array_get_value(node, idx); } else { ret = EINVAL; if (error) *error = heim_error_create(ret, "Node in path not a " "container"); } heim_release(new_node); if (ret) goto err; } path_element = next_path_element; node = next_node; next_node = NULL; } if (path_element == NULL) goto err; /* Add the leaf */ if (leaf != NULL) { if (node_type == HEIM_TID_DICT) ret = heim_dict_set_value(node, path_element, leaf); else ret = heim_array_insert_value(node, heim_number_get_int(path_element), leaf); } return ret; err: if (error && !*error) { if (ret == ENOMEM) *error = heim_error_create_enomem(); else *error = heim_error_create(ret, "Could not set " "dict value"); } return ret; } /** * Create a path in a heim_object_t tree * * @param ptr the tree * @param size the size of the heim_dict_t nodes to be created * @param leaf leaf node to be added, if any * @param error error (output) * @param ... NULL-terminated list of path component objects * * Create a path of heim_dict_t interior nodes in a given heim_object_t * tree, as necessary, and set/replace a leaf, if given (if leaf is NULL * then the leaf is not deleted). * * @return 0 on success, else a system error * * @addtogroup heimbase */ int heim_path_create(heim_object_t ptr, size_t size, heim_object_t leaf, heim_error_t *error, ...) { va_list ap; int ret; va_start(ap, error); ret = heim_path_vcreate(ptr, size, leaf, error, ap); va_end(ap); return ret; } /** * Delete leaf node named by a path in a heim_object_t tree * * @param ptr the tree * @param error error (output) * @param ap NULL-terminated list of path component objects * * @addtogroup heimbase */ void heim_path_vdelete(heim_object_t ptr, heim_error_t *error, va_list ap) { heim_object_t parent, key, child; child = heim_path_vget2(ptr, &parent, &key, error, ap); if (child != NULL) { if (heim_get_tid(parent) == HEIM_TID_DICT) heim_dict_delete_key(parent, key); else if (heim_get_tid(parent) == HEIM_TID_DB) heim_db_delete_key(parent, NULL, key, error); else if (heim_get_tid(parent) == HEIM_TID_ARRAY) heim_array_delete_value(parent, heim_number_get_int(key)); heim_release(child); } } /** * Delete leaf node named by a path in a heim_object_t tree * * @param ptr the tree * @param error error (output) * @param ap NULL-terminated list of path component objects * * @addtogroup heimbase */ void heim_path_delete(heim_object_t ptr, heim_error_t *error, ...) { va_list ap; va_start(ap, error); heim_path_vdelete(ptr, error, ap); va_end(ap); return; }