s4-dsdb: use constant-time search for descriptor -> get_last_structural_class()
[Samba/id10ts.git] / lib / talloc / talloc.c
blob38e6f21854a643559a4cf653ce8f7125f0984651
1 /*
2 Samba Unix SMB/CIFS implementation.
4 Samba trivial allocation library - new interface
6 NOTE: Please read talloc_guide.txt for full documentation
8 Copyright (C) Andrew Tridgell 2004
9 Copyright (C) Stefan Metzmacher 2006
11 ** NOTE! The following LGPL license applies to the talloc
12 ** library. This does NOT imply that all of Samba is released
13 ** under the LGPL
15 This library is free software; you can redistribute it and/or
16 modify it under the terms of the GNU Lesser General Public
17 License as published by the Free Software Foundation; either
18 version 3 of the License, or (at your option) any later version.
20 This library is distributed in the hope that it will be useful,
21 but WITHOUT ANY WARRANTY; without even the implied warranty of
22 MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the GNU
23 Lesser General Public License for more details.
25 You should have received a copy of the GNU Lesser General Public
26 License along with this library; if not, see <http://www.gnu.org/licenses/>.
30 inspired by http://swapped.cc/halloc/
33 #include "replace.h"
34 #include "talloc.h"
36 #ifdef TALLOC_BUILD_VERSION_MAJOR
37 #if (TALLOC_VERSION_MAJOR != TALLOC_BUILD_VERSION_MAJOR)
38 #error "TALLOC_VERSION_MAJOR != TALLOC_BUILD_VERSION_MAJOR"
39 #endif
40 #endif
42 #ifdef TALLOC_BUILD_VERSION_MINOR
43 #if (TALLOC_VERSION_MINOR != TALLOC_BUILD_VERSION_MINOR)
44 #error "TALLOC_VERSION_MINOR != TALLOC_BUILD_VERSION_MINOR"
45 #endif
46 #endif
48 /* Special macros that are no-ops except when run under Valgrind on
49 * x86. They've moved a little bit from valgrind 1.0.4 to 1.9.4 */
50 #ifdef HAVE_VALGRIND_MEMCHECK_H
51 /* memcheck.h includes valgrind.h */
52 #include <valgrind/memcheck.h>
53 #elif defined(HAVE_VALGRIND_H)
54 #include <valgrind.h>
55 #endif
57 /* use this to force every realloc to change the pointer, to stress test
58 code that might not cope */
59 #define ALWAYS_REALLOC 0
62 #define MAX_TALLOC_SIZE 0x10000000
63 #define TALLOC_MAGIC_BASE 0xe814ec70
64 #define TALLOC_MAGIC ( \
65 TALLOC_MAGIC_BASE + \
66 (TALLOC_VERSION_MAJOR << 12) + \
67 (TALLOC_VERSION_MINOR << 4) \
70 #define TALLOC_FLAG_FREE 0x01
71 #define TALLOC_FLAG_LOOP 0x02
72 #define TALLOC_FLAG_POOL 0x04 /* This is a talloc pool */
73 #define TALLOC_FLAG_POOLMEM 0x08 /* This is allocated in a pool */
74 #define TALLOC_MAGIC_REFERENCE ((const char *)1)
76 /* by default we abort when given a bad pointer (such as when talloc_free() is called
77 on a pointer that came from malloc() */
78 #ifndef TALLOC_ABORT
79 #define TALLOC_ABORT(reason) abort()
80 #endif
82 #ifndef discard_const_p
83 #if defined(__intptr_t_defined) || defined(HAVE_INTPTR_T)
84 # define discard_const_p(type, ptr) ((type *)((intptr_t)(ptr)))
85 #else
86 # define discard_const_p(type, ptr) ((type *)(ptr))
87 #endif
88 #endif
90 /* these macros gain us a few percent of speed on gcc */
91 #if (__GNUC__ >= 3)
92 /* the strange !! is to ensure that __builtin_expect() takes either 0 or 1
93 as its first argument */
94 #ifndef likely
95 #define likely(x) __builtin_expect(!!(x), 1)
96 #endif
97 #ifndef unlikely
98 #define unlikely(x) __builtin_expect(!!(x), 0)
99 #endif
100 #else
101 #ifndef likely
102 #define likely(x) (x)
103 #endif
104 #ifndef unlikely
105 #define unlikely(x) (x)
106 #endif
107 #endif
109 /* this null_context is only used if talloc_enable_leak_report() or
110 talloc_enable_leak_report_full() is called, otherwise it remains
111 NULL
113 static void *null_context;
114 static void *autofree_context;
116 /* used to enable fill of memory on free, which can be useful for
117 * catching use after free errors when valgrind is too slow
119 static struct {
120 bool initialised;
121 bool enabled;
122 uint8_t fill_value;
123 } talloc_fill;
125 #define TALLOC_FILL_ENV "TALLOC_FREE_FILL"
128 * do not wipe the header, to allow the
129 * double-free logic to still work
131 #define TC_INVALIDATE_FULL_FILL_CHUNK(_tc) do { \
132 if (unlikely(talloc_fill.enabled)) { \
133 size_t _flen = (_tc)->size; \
134 char *_fptr = (char *)TC_PTR_FROM_CHUNK(_tc); \
135 memset(_fptr, talloc_fill.fill_value, _flen); \
137 } while (0)
139 #if defined(DEVELOPER) && defined(VALGRIND_MAKE_MEM_NOACCESS)
140 /* Mark the whole chunk as not accessable */
141 #define TC_INVALIDATE_FULL_VALGRIND_CHUNK(_tc) do { \
142 size_t _flen = TC_HDR_SIZE + (_tc)->size; \
143 char *_fptr = (char *)(_tc); \
144 VALGRIND_MAKE_MEM_NOACCESS(_fptr, _flen); \
145 } while(0)
146 #else
147 #define TC_INVALIDATE_FULL_VALGRIND_CHUNK(_tc) do { } while (0)
148 #endif
150 #define TC_INVALIDATE_FULL_CHUNK(_tc) do { \
151 TC_INVALIDATE_FULL_FILL_CHUNK(_tc); \
152 TC_INVALIDATE_FULL_VALGRIND_CHUNK(_tc); \
153 } while (0)
155 #define TC_INVALIDATE_SHRINK_FILL_CHUNK(_tc, _new_size) do { \
156 if (unlikely(talloc_fill.enabled)) { \
157 size_t _flen = (_tc)->size - (_new_size); \
158 char *_fptr = (char *)TC_PTR_FROM_CHUNK(_tc); \
159 _fptr += (_new_size); \
160 memset(_fptr, talloc_fill.fill_value, _flen); \
162 } while (0)
164 #if defined(DEVELOPER) && defined(VALGRIND_MAKE_MEM_NOACCESS)
165 /* Mark the unused bytes not accessable */
166 #define TC_INVALIDATE_SHRINK_VALGRIND_CHUNK(_tc, _new_size) do { \
167 size_t _flen = (_tc)->size - (_new_size); \
168 char *_fptr = (char *)TC_PTR_FROM_CHUNK(_tc); \
169 _fptr += (_new_size); \
170 VALGRIND_MAKE_MEM_NOACCESS(_fptr, _flen); \
171 } while (0)
172 #else
173 #define TC_INVALIDATE_SHRINK_VALGRIND_CHUNK(_tc, _new_size) do { } while (0)
174 #endif
176 #define TC_INVALIDATE_SHRINK_CHUNK(_tc, _new_size) do { \
177 TC_INVALIDATE_SHRINK_FILL_CHUNK(_tc, _new_size); \
178 TC_INVALIDATE_SHRINK_VALGRIND_CHUNK(_tc, _new_size); \
179 } while (0)
181 #define TC_UNDEFINE_SHRINK_FILL_CHUNK(_tc, _new_size) do { \
182 if (unlikely(talloc_fill.enabled)) { \
183 size_t _flen = (_tc)->size - (_new_size); \
184 char *_fptr = (char *)TC_PTR_FROM_CHUNK(_tc); \
185 _fptr += (_new_size); \
186 memset(_fptr, talloc_fill.fill_value, _flen); \
188 } while (0)
190 #if defined(DEVELOPER) && defined(VALGRIND_MAKE_MEM_UNDEFINED)
191 /* Mark the unused bytes as undefined */
192 #define TC_UNDEFINE_SHRINK_VALGRIND_CHUNK(_tc, _new_size) do { \
193 size_t _flen = (_tc)->size - (_new_size); \
194 char *_fptr = (char *)TC_PTR_FROM_CHUNK(_tc); \
195 _fptr += (_new_size); \
196 VALGRIND_MAKE_MEM_UNDEFINED(_fptr, _flen); \
197 } while (0)
198 #else
199 #define TC_UNDEFINE_SHRINK_VALGRIND_CHUNK(_tc, _new_size) do { } while (0)
200 #endif
202 #define TC_UNDEFINE_SHRINK_CHUNK(_tc, _new_size) do { \
203 TC_UNDEFINE_SHRINK_FILL_CHUNK(_tc, _new_size); \
204 TC_UNDEFINE_SHRINK_VALGRIND_CHUNK(_tc, _new_size); \
205 } while (0)
207 #if defined(DEVELOPER) && defined(VALGRIND_MAKE_MEM_UNDEFINED)
208 /* Mark the new bytes as undefined */
209 #define TC_UNDEFINE_GROW_VALGRIND_CHUNK(_tc, _new_size) do { \
210 size_t _old_used = TC_HDR_SIZE + (_tc)->size; \
211 size_t _new_used = TC_HDR_SIZE + (_new_size); \
212 size_t _flen = _new_used - _old_used; \
213 char *_fptr = _old_used + (char *)(_tc); \
214 VALGRIND_MAKE_MEM_UNDEFINED(_fptr, _flen); \
215 } while (0)
216 #else
217 #define TC_UNDEFINE_GROW_VALGRIND_CHUNK(_tc, _new_size) do { } while (0)
218 #endif
220 #define TC_UNDEFINE_GROW_CHUNK(_tc, _new_size) do { \
221 TC_UNDEFINE_GROW_VALGRIND_CHUNK(_tc, _new_size); \
222 } while (0)
224 struct talloc_reference_handle {
225 struct talloc_reference_handle *next, *prev;
226 void *ptr;
227 const char *location;
230 typedef int (*talloc_destructor_t)(void *);
232 struct talloc_chunk {
233 struct talloc_chunk *next, *prev;
234 struct talloc_chunk *parent, *child;
235 struct talloc_reference_handle *refs;
236 talloc_destructor_t destructor;
237 const char *name;
238 size_t size;
239 unsigned flags;
242 * "pool" has dual use:
244 * For the talloc pool itself (i.e. TALLOC_FLAG_POOL is set), "pool"
245 * marks the end of the currently allocated area.
247 * For members of the pool (i.e. TALLOC_FLAG_POOLMEM is set), "pool"
248 * is a pointer to the struct talloc_chunk of the pool that it was
249 * allocated from. This way children can quickly find the pool to chew
250 * from.
252 void *pool;
255 /* 16 byte alignment seems to keep everyone happy */
256 #define TC_ALIGN16(s) (((s)+15)&~15)
257 #define TC_HDR_SIZE TC_ALIGN16(sizeof(struct talloc_chunk))
258 #define TC_PTR_FROM_CHUNK(tc) ((void *)(TC_HDR_SIZE + (char*)tc))
260 _PUBLIC_ int talloc_version_major(void)
262 return TALLOC_VERSION_MAJOR;
265 _PUBLIC_ int talloc_version_minor(void)
267 return TALLOC_VERSION_MINOR;
270 static void (*talloc_log_fn)(const char *message);
272 _PUBLIC_ void talloc_set_log_fn(void (*log_fn)(const char *message))
274 talloc_log_fn = log_fn;
277 static void talloc_log(const char *fmt, ...) PRINTF_ATTRIBUTE(1,2);
278 static void talloc_log(const char *fmt, ...)
280 va_list ap;
281 char *message;
283 if (!talloc_log_fn) {
284 return;
287 va_start(ap, fmt);
288 message = talloc_vasprintf(NULL, fmt, ap);
289 va_end(ap);
291 talloc_log_fn(message);
292 talloc_free(message);
295 static void talloc_log_stderr(const char *message)
297 fprintf(stderr, "%s", message);
300 _PUBLIC_ void talloc_set_log_stderr(void)
302 talloc_set_log_fn(talloc_log_stderr);
305 static void (*talloc_abort_fn)(const char *reason);
307 _PUBLIC_ void talloc_set_abort_fn(void (*abort_fn)(const char *reason))
309 talloc_abort_fn = abort_fn;
312 static void talloc_abort(const char *reason)
314 talloc_log("%s\n", reason);
316 if (!talloc_abort_fn) {
317 TALLOC_ABORT(reason);
320 talloc_abort_fn(reason);
323 static void talloc_abort_magic(unsigned magic)
325 unsigned striped = magic - TALLOC_MAGIC_BASE;
326 unsigned major = (striped & 0xFFFFF000) >> 12;
327 unsigned minor = (striped & 0x00000FF0) >> 4;
328 talloc_log("Bad talloc magic[0x%08X/%u/%u] expected[0x%08X/%u/%u]\n",
329 magic, major, minor,
330 TALLOC_MAGIC, TALLOC_VERSION_MAJOR, TALLOC_VERSION_MINOR);
331 talloc_abort("Bad talloc magic value - wrong talloc version used/mixed");
334 static void talloc_abort_access_after_free(void)
336 talloc_abort("Bad talloc magic value - access after free");
339 static void talloc_abort_unknown_value(void)
341 talloc_abort("Bad talloc magic value - unknown value");
344 /* panic if we get a bad magic value */
345 static inline struct talloc_chunk *talloc_chunk_from_ptr(const void *ptr)
347 const char *pp = (const char *)ptr;
348 struct talloc_chunk *tc = discard_const_p(struct talloc_chunk, pp - TC_HDR_SIZE);
349 if (unlikely((tc->flags & (TALLOC_FLAG_FREE | ~0xF)) != TALLOC_MAGIC)) {
350 if ((tc->flags & (~0xFFF)) == TALLOC_MAGIC_BASE) {
351 talloc_abort_magic(tc->flags & (~0xF));
352 return NULL;
355 if (tc->flags & TALLOC_FLAG_FREE) {
356 talloc_log("talloc: access after free error - first free may be at %s\n", tc->name);
357 talloc_abort_access_after_free();
358 return NULL;
359 } else {
360 talloc_abort_unknown_value();
361 return NULL;
364 return tc;
367 /* hook into the front of the list */
368 #define _TLIST_ADD(list, p) \
369 do { \
370 if (!(list)) { \
371 (list) = (p); \
372 (p)->next = (p)->prev = NULL; \
373 } else { \
374 (list)->prev = (p); \
375 (p)->next = (list); \
376 (p)->prev = NULL; \
377 (list) = (p); \
379 } while (0)
381 /* remove an element from a list - element doesn't have to be in list. */
382 #define _TLIST_REMOVE(list, p) \
383 do { \
384 if ((p) == (list)) { \
385 (list) = (p)->next; \
386 if (list) (list)->prev = NULL; \
387 } else { \
388 if ((p)->prev) (p)->prev->next = (p)->next; \
389 if ((p)->next) (p)->next->prev = (p)->prev; \
391 if ((p) && ((p) != (list))) (p)->next = (p)->prev = NULL; \
392 } while (0)
396 return the parent chunk of a pointer
398 static inline struct talloc_chunk *talloc_parent_chunk(const void *ptr)
400 struct talloc_chunk *tc;
402 if (unlikely(ptr == NULL)) {
403 return NULL;
406 tc = talloc_chunk_from_ptr(ptr);
407 while (tc->prev) tc=tc->prev;
409 return tc->parent;
412 _PUBLIC_ void *talloc_parent(const void *ptr)
414 struct talloc_chunk *tc = talloc_parent_chunk(ptr);
415 return tc? TC_PTR_FROM_CHUNK(tc) : NULL;
419 find parents name
421 _PUBLIC_ const char *talloc_parent_name(const void *ptr)
423 struct talloc_chunk *tc = talloc_parent_chunk(ptr);
424 return tc? tc->name : NULL;
428 A pool carries an in-pool object count count in the first 16 bytes.
429 bytes. This is done to support talloc_steal() to a parent outside of the
430 pool. The count includes the pool itself, so a talloc_free() on a pool will
431 only destroy the pool if the count has dropped to zero. A talloc_free() of a
432 pool member will reduce the count, and eventually also call free(3) on the
433 pool memory.
435 The object count is not put into "struct talloc_chunk" because it is only
436 relevant for talloc pools and the alignment to 16 bytes would increase the
437 memory footprint of each talloc chunk by those 16 bytes.
440 #define TALLOC_POOL_HDR_SIZE 16
442 #define TC_POOL_SPACE_LEFT(_pool_tc) \
443 PTR_DIFF(TC_HDR_SIZE + (_pool_tc)->size + (char *)(_pool_tc), \
444 (_pool_tc)->pool)
446 #define TC_POOL_FIRST_CHUNK(_pool_tc) \
447 ((void *)(TC_HDR_SIZE + TALLOC_POOL_HDR_SIZE + (char *)(_pool_tc)))
449 #define TC_POOLMEM_CHUNK_SIZE(_tc) \
450 TC_ALIGN16(TC_HDR_SIZE + (_tc)->size)
452 #define TC_POOLMEM_NEXT_CHUNK(_tc) \
453 ((void *)(TC_POOLMEM_CHUNK_SIZE(tc) + (char*)(_tc)))
455 /* Mark the whole remaining pool as not accessable */
456 #define TC_INVALIDATE_FILL_POOL(_pool_tc) do { \
457 if (unlikely(talloc_fill.enabled)) { \
458 size_t _flen = TC_POOL_SPACE_LEFT(_pool_tc); \
459 char *_fptr = (char *)(_pool_tc)->pool; \
460 memset(_fptr, talloc_fill.fill_value, _flen); \
462 } while(0)
464 #if defined(DEVELOPER) && defined(VALGRIND_MAKE_MEM_NOACCESS)
465 /* Mark the whole remaining pool as not accessable */
466 #define TC_INVALIDATE_VALGRIND_POOL(_pool_tc) do { \
467 size_t _flen = TC_POOL_SPACE_LEFT(_pool_tc); \
468 char *_fptr = (char *)(_pool_tc)->pool; \
469 VALGRIND_MAKE_MEM_NOACCESS(_fptr, _flen); \
470 } while(0)
471 #else
472 #define TC_INVALIDATE_VALGRIND_POOL(_pool_tc) do { } while (0)
473 #endif
475 #define TC_INVALIDATE_POOL(_pool_tc) do { \
476 TC_INVALIDATE_FILL_POOL(_pool_tc); \
477 TC_INVALIDATE_VALGRIND_POOL(_pool_tc); \
478 } while (0)
480 static unsigned int *talloc_pool_objectcount(struct talloc_chunk *tc)
482 return (unsigned int *)((char *)tc + TC_HDR_SIZE);
486 Allocate from a pool
489 static struct talloc_chunk *talloc_alloc_pool(struct talloc_chunk *parent,
490 size_t size)
492 struct talloc_chunk *pool_ctx = NULL;
493 size_t space_left;
494 struct talloc_chunk *result;
495 size_t chunk_size;
497 if (parent == NULL) {
498 return NULL;
501 if (parent->flags & TALLOC_FLAG_POOL) {
502 pool_ctx = parent;
504 else if (parent->flags & TALLOC_FLAG_POOLMEM) {
505 pool_ctx = (struct talloc_chunk *)parent->pool;
508 if (pool_ctx == NULL) {
509 return NULL;
512 space_left = TC_POOL_SPACE_LEFT(pool_ctx);
515 * Align size to 16 bytes
517 chunk_size = TC_ALIGN16(size);
519 if (space_left < chunk_size) {
520 return NULL;
523 result = (struct talloc_chunk *)pool_ctx->pool;
525 #if defined(DEVELOPER) && defined(VALGRIND_MAKE_MEM_UNDEFINED)
526 VALGRIND_MAKE_MEM_UNDEFINED(result, size);
527 #endif
529 pool_ctx->pool = (void *)((char *)result + chunk_size);
531 result->flags = TALLOC_MAGIC | TALLOC_FLAG_POOLMEM;
532 result->pool = pool_ctx;
534 *talloc_pool_objectcount(pool_ctx) += 1;
536 return result;
540 Allocate a bit of memory as a child of an existing pointer
542 static inline void *__talloc(const void *context, size_t size)
544 struct talloc_chunk *tc = NULL;
546 if (unlikely(context == NULL)) {
547 context = null_context;
550 if (unlikely(size >= MAX_TALLOC_SIZE)) {
551 return NULL;
554 if (context != NULL) {
555 tc = talloc_alloc_pool(talloc_chunk_from_ptr(context),
556 TC_HDR_SIZE+size);
559 if (tc == NULL) {
560 tc = (struct talloc_chunk *)malloc(TC_HDR_SIZE+size);
561 if (unlikely(tc == NULL)) return NULL;
562 tc->flags = TALLOC_MAGIC;
563 tc->pool = NULL;
566 tc->size = size;
567 tc->destructor = NULL;
568 tc->child = NULL;
569 tc->name = NULL;
570 tc->refs = NULL;
572 if (likely(context)) {
573 struct talloc_chunk *parent = talloc_chunk_from_ptr(context);
575 if (parent->child) {
576 parent->child->parent = NULL;
577 tc->next = parent->child;
578 tc->next->prev = tc;
579 } else {
580 tc->next = NULL;
582 tc->parent = parent;
583 tc->prev = NULL;
584 parent->child = tc;
585 } else {
586 tc->next = tc->prev = tc->parent = NULL;
589 return TC_PTR_FROM_CHUNK(tc);
593 * Create a talloc pool
596 _PUBLIC_ void *talloc_pool(const void *context, size_t size)
598 void *result = __talloc(context, size + TALLOC_POOL_HDR_SIZE);
599 struct talloc_chunk *tc;
601 if (unlikely(result == NULL)) {
602 return NULL;
605 tc = talloc_chunk_from_ptr(result);
607 tc->flags |= TALLOC_FLAG_POOL;
608 tc->pool = TC_POOL_FIRST_CHUNK(tc);
610 *talloc_pool_objectcount(tc) = 1;
612 TC_INVALIDATE_POOL(tc);
614 return result;
618 setup a destructor to be called on free of a pointer
619 the destructor should return 0 on success, or -1 on failure.
620 if the destructor fails then the free is failed, and the memory can
621 be continued to be used
623 _PUBLIC_ void _talloc_set_destructor(const void *ptr, int (*destructor)(void *))
625 struct talloc_chunk *tc = talloc_chunk_from_ptr(ptr);
626 tc->destructor = destructor;
630 increase the reference count on a piece of memory.
632 _PUBLIC_ int talloc_increase_ref_count(const void *ptr)
634 if (unlikely(!talloc_reference(null_context, ptr))) {
635 return -1;
637 return 0;
641 helper for talloc_reference()
643 this is referenced by a function pointer and should not be inline
645 static int talloc_reference_destructor(struct talloc_reference_handle *handle)
647 struct talloc_chunk *ptr_tc = talloc_chunk_from_ptr(handle->ptr);
648 _TLIST_REMOVE(ptr_tc->refs, handle);
649 return 0;
653 more efficient way to add a name to a pointer - the name must point to a
654 true string constant
656 static inline void _talloc_set_name_const(const void *ptr, const char *name)
658 struct talloc_chunk *tc = talloc_chunk_from_ptr(ptr);
659 tc->name = name;
663 internal talloc_named_const()
665 static inline void *_talloc_named_const(const void *context, size_t size, const char *name)
667 void *ptr;
669 ptr = __talloc(context, size);
670 if (unlikely(ptr == NULL)) {
671 return NULL;
674 _talloc_set_name_const(ptr, name);
676 return ptr;
680 make a secondary reference to a pointer, hanging off the given context.
681 the pointer remains valid until both the original caller and this given
682 context are freed.
684 the major use for this is when two different structures need to reference the
685 same underlying data, and you want to be able to free the two instances separately,
686 and in either order
688 _PUBLIC_ void *_talloc_reference_loc(const void *context, const void *ptr, const char *location)
690 struct talloc_chunk *tc;
691 struct talloc_reference_handle *handle;
692 if (unlikely(ptr == NULL)) return NULL;
694 tc = talloc_chunk_from_ptr(ptr);
695 handle = (struct talloc_reference_handle *)_talloc_named_const(context,
696 sizeof(struct talloc_reference_handle),
697 TALLOC_MAGIC_REFERENCE);
698 if (unlikely(handle == NULL)) return NULL;
700 /* note that we hang the destructor off the handle, not the
701 main context as that allows the caller to still setup their
702 own destructor on the context if they want to */
703 talloc_set_destructor(handle, talloc_reference_destructor);
704 handle->ptr = discard_const_p(void, ptr);
705 handle->location = location;
706 _TLIST_ADD(tc->refs, handle);
707 return handle->ptr;
710 static void *_talloc_steal_internal(const void *new_ctx, const void *ptr);
712 static inline void _talloc_free_poolmem(struct talloc_chunk *tc,
713 const char *location)
715 struct talloc_chunk *pool;
716 void *next_tc;
717 unsigned int *pool_object_count;
719 pool = (struct talloc_chunk *)tc->pool;
720 next_tc = TC_POOLMEM_NEXT_CHUNK(tc);
722 tc->flags |= TALLOC_FLAG_FREE;
724 /* we mark the freed memory with where we called the free
725 * from. This means on a double free error we can report where
726 * the first free came from
728 tc->name = location;
730 TC_INVALIDATE_FULL_CHUNK(tc);
732 pool_object_count = talloc_pool_objectcount(pool);
734 if (unlikely(*pool_object_count == 0)) {
735 talloc_abort("Pool object count zero!");
736 return;
739 *pool_object_count -= 1;
741 if (unlikely(*pool_object_count == 1 && !(pool->flags & TALLOC_FLAG_FREE))) {
743 * if there is just one object left in the pool
744 * and pool->flags does not have TALLOC_FLAG_FREE,
745 * it means this is the pool itself and
746 * the rest is available for new objects
747 * again.
749 pool->pool = TC_POOL_FIRST_CHUNK(pool);
750 TC_INVALIDATE_POOL(pool);
751 } else if (unlikely(*pool_object_count == 0)) {
753 * we mark the freed memory with where we called the free
754 * from. This means on a double free error we can report where
755 * the first free came from
757 pool->name = location;
759 TC_INVALIDATE_FULL_CHUNK(pool);
760 free(pool);
761 } else if (pool->pool == next_tc) {
763 * if pool->pool still points to end of
764 * 'tc' (which is stored in the 'next_tc' variable),
765 * we can reclaim the memory of 'tc'.
767 pool->pool = tc;
771 static inline void _talloc_free_children_internal(struct talloc_chunk *tc,
772 void *ptr,
773 const char *location);
776 internal talloc_free call
778 static inline int _talloc_free_internal(void *ptr, const char *location)
780 struct talloc_chunk *tc;
782 if (unlikely(ptr == NULL)) {
783 return -1;
786 /* possibly initialised the talloc fill value */
787 if (unlikely(!talloc_fill.initialised)) {
788 const char *fill = getenv(TALLOC_FILL_ENV);
789 if (fill != NULL) {
790 talloc_fill.enabled = true;
791 talloc_fill.fill_value = strtoul(fill, NULL, 0);
793 talloc_fill.initialised = true;
796 tc = talloc_chunk_from_ptr(ptr);
798 if (unlikely(tc->refs)) {
799 int is_child;
800 /* check if this is a reference from a child or
801 * grandchild back to it's parent or grandparent
803 * in that case we need to remove the reference and
804 * call another instance of talloc_free() on the current
805 * pointer.
807 is_child = talloc_is_parent(tc->refs, ptr);
808 _talloc_free_internal(tc->refs, location);
809 if (is_child) {
810 return _talloc_free_internal(ptr, location);
812 return -1;
815 if (unlikely(tc->flags & TALLOC_FLAG_LOOP)) {
816 /* we have a free loop - stop looping */
817 return 0;
820 if (unlikely(tc->destructor)) {
821 talloc_destructor_t d = tc->destructor;
822 if (d == (talloc_destructor_t)-1) {
823 return -1;
825 tc->destructor = (talloc_destructor_t)-1;
826 if (d(ptr) == -1) {
827 tc->destructor = d;
828 return -1;
830 tc->destructor = NULL;
833 if (tc->parent) {
834 _TLIST_REMOVE(tc->parent->child, tc);
835 if (tc->parent->child) {
836 tc->parent->child->parent = tc->parent;
838 } else {
839 if (tc->prev) tc->prev->next = tc->next;
840 if (tc->next) tc->next->prev = tc->prev;
841 tc->prev = tc->next = NULL;
844 tc->flags |= TALLOC_FLAG_LOOP;
846 _talloc_free_children_internal(tc, ptr, location);
848 tc->flags |= TALLOC_FLAG_FREE;
850 /* we mark the freed memory with where we called the free
851 * from. This means on a double free error we can report where
852 * the first free came from
854 tc->name = location;
856 if (tc->flags & TALLOC_FLAG_POOL) {
857 unsigned int *pool_object_count;
859 pool_object_count = talloc_pool_objectcount(tc);
861 if (unlikely(*pool_object_count == 0)) {
862 talloc_abort("Pool object count zero!");
863 return 0;
866 *pool_object_count -= 1;
868 if (unlikely(*pool_object_count == 0)) {
869 TC_INVALIDATE_FULL_CHUNK(tc);
870 free(tc);
872 } else if (tc->flags & TALLOC_FLAG_POOLMEM) {
873 _talloc_free_poolmem(tc, location);
874 } else {
875 TC_INVALIDATE_FULL_CHUNK(tc);
876 free(tc);
878 return 0;
882 move a lump of memory from one talloc context to another return the
883 ptr on success, or NULL if it could not be transferred.
884 passing NULL as ptr will always return NULL with no side effects.
886 static void *_talloc_steal_internal(const void *new_ctx, const void *ptr)
888 struct talloc_chunk *tc, *new_tc;
890 if (unlikely(!ptr)) {
891 return NULL;
894 if (unlikely(new_ctx == NULL)) {
895 new_ctx = null_context;
898 tc = talloc_chunk_from_ptr(ptr);
900 if (unlikely(new_ctx == NULL)) {
901 if (tc->parent) {
902 _TLIST_REMOVE(tc->parent->child, tc);
903 if (tc->parent->child) {
904 tc->parent->child->parent = tc->parent;
906 } else {
907 if (tc->prev) tc->prev->next = tc->next;
908 if (tc->next) tc->next->prev = tc->prev;
911 tc->parent = tc->next = tc->prev = NULL;
912 return discard_const_p(void, ptr);
915 new_tc = talloc_chunk_from_ptr(new_ctx);
917 if (unlikely(tc == new_tc || tc->parent == new_tc)) {
918 return discard_const_p(void, ptr);
921 if (tc->parent) {
922 _TLIST_REMOVE(tc->parent->child, tc);
923 if (tc->parent->child) {
924 tc->parent->child->parent = tc->parent;
926 } else {
927 if (tc->prev) tc->prev->next = tc->next;
928 if (tc->next) tc->next->prev = tc->prev;
929 tc->prev = tc->next = NULL;
932 tc->parent = new_tc;
933 if (new_tc->child) new_tc->child->parent = NULL;
934 _TLIST_ADD(new_tc->child, tc);
936 return discard_const_p(void, ptr);
940 move a lump of memory from one talloc context to another return the
941 ptr on success, or NULL if it could not be transferred.
942 passing NULL as ptr will always return NULL with no side effects.
944 _PUBLIC_ void *_talloc_steal_loc(const void *new_ctx, const void *ptr, const char *location)
946 struct talloc_chunk *tc;
948 if (unlikely(ptr == NULL)) {
949 return NULL;
952 tc = talloc_chunk_from_ptr(ptr);
954 if (unlikely(tc->refs != NULL) && talloc_parent(ptr) != new_ctx) {
955 struct talloc_reference_handle *h;
957 talloc_log("WARNING: talloc_steal with references at %s\n",
958 location);
960 for (h=tc->refs; h; h=h->next) {
961 talloc_log("\treference at %s\n",
962 h->location);
966 #if 0
967 /* this test is probably too expensive to have on in the
968 normal build, but it useful for debugging */
969 if (talloc_is_parent(new_ctx, ptr)) {
970 talloc_log("WARNING: stealing into talloc child at %s\n", location);
972 #endif
974 return _talloc_steal_internal(new_ctx, ptr);
978 this is like a talloc_steal(), but you must supply the old
979 parent. This resolves the ambiguity in a talloc_steal() which is
980 called on a context that has more than one parent (via references)
982 The old parent can be either a reference or a parent
984 _PUBLIC_ void *talloc_reparent(const void *old_parent, const void *new_parent, const void *ptr)
986 struct talloc_chunk *tc;
987 struct talloc_reference_handle *h;
989 if (unlikely(ptr == NULL)) {
990 return NULL;
993 if (old_parent == talloc_parent(ptr)) {
994 return _talloc_steal_internal(new_parent, ptr);
997 tc = talloc_chunk_from_ptr(ptr);
998 for (h=tc->refs;h;h=h->next) {
999 if (talloc_parent(h) == old_parent) {
1000 if (_talloc_steal_internal(new_parent, h) != h) {
1001 return NULL;
1003 return discard_const_p(void, ptr);
1007 /* it wasn't a parent */
1008 return NULL;
1012 remove a secondary reference to a pointer. This undo's what
1013 talloc_reference() has done. The context and pointer arguments
1014 must match those given to a talloc_reference()
1016 static inline int talloc_unreference(const void *context, const void *ptr)
1018 struct talloc_chunk *tc = talloc_chunk_from_ptr(ptr);
1019 struct talloc_reference_handle *h;
1021 if (unlikely(context == NULL)) {
1022 context = null_context;
1025 for (h=tc->refs;h;h=h->next) {
1026 struct talloc_chunk *p = talloc_parent_chunk(h);
1027 if (p == NULL) {
1028 if (context == NULL) break;
1029 } else if (TC_PTR_FROM_CHUNK(p) == context) {
1030 break;
1033 if (h == NULL) {
1034 return -1;
1037 return _talloc_free_internal(h, __location__);
1041 remove a specific parent context from a pointer. This is a more
1042 controlled variant of talloc_free()
1044 _PUBLIC_ int talloc_unlink(const void *context, void *ptr)
1046 struct talloc_chunk *tc_p, *new_p, *tc_c;
1047 void *new_parent;
1049 if (ptr == NULL) {
1050 return -1;
1053 if (context == NULL) {
1054 context = null_context;
1057 if (talloc_unreference(context, ptr) == 0) {
1058 return 0;
1061 if (context != NULL) {
1062 tc_c = talloc_chunk_from_ptr(context);
1063 } else {
1064 tc_c = NULL;
1066 if (tc_c != talloc_parent_chunk(ptr)) {
1067 return -1;
1070 tc_p = talloc_chunk_from_ptr(ptr);
1072 if (tc_p->refs == NULL) {
1073 return _talloc_free_internal(ptr, __location__);
1076 new_p = talloc_parent_chunk(tc_p->refs);
1077 if (new_p) {
1078 new_parent = TC_PTR_FROM_CHUNK(new_p);
1079 } else {
1080 new_parent = NULL;
1083 if (talloc_unreference(new_parent, ptr) != 0) {
1084 return -1;
1087 _talloc_steal_internal(new_parent, ptr);
1089 return 0;
1093 add a name to an existing pointer - va_list version
1095 static inline const char *talloc_set_name_v(const void *ptr, const char *fmt, va_list ap) PRINTF_ATTRIBUTE(2,0);
1097 static inline const char *talloc_set_name_v(const void *ptr, const char *fmt, va_list ap)
1099 struct talloc_chunk *tc = talloc_chunk_from_ptr(ptr);
1100 tc->name = talloc_vasprintf(ptr, fmt, ap);
1101 if (likely(tc->name)) {
1102 _talloc_set_name_const(tc->name, ".name");
1104 return tc->name;
1108 add a name to an existing pointer
1110 _PUBLIC_ const char *talloc_set_name(const void *ptr, const char *fmt, ...)
1112 const char *name;
1113 va_list ap;
1114 va_start(ap, fmt);
1115 name = talloc_set_name_v(ptr, fmt, ap);
1116 va_end(ap);
1117 return name;
1122 create a named talloc pointer. Any talloc pointer can be named, and
1123 talloc_named() operates just like talloc() except that it allows you
1124 to name the pointer.
1126 _PUBLIC_ void *talloc_named(const void *context, size_t size, const char *fmt, ...)
1128 va_list ap;
1129 void *ptr;
1130 const char *name;
1132 ptr = __talloc(context, size);
1133 if (unlikely(ptr == NULL)) return NULL;
1135 va_start(ap, fmt);
1136 name = talloc_set_name_v(ptr, fmt, ap);
1137 va_end(ap);
1139 if (unlikely(name == NULL)) {
1140 _talloc_free_internal(ptr, __location__);
1141 return NULL;
1144 return ptr;
1148 return the name of a talloc ptr, or "UNNAMED"
1150 _PUBLIC_ const char *talloc_get_name(const void *ptr)
1152 struct talloc_chunk *tc = talloc_chunk_from_ptr(ptr);
1153 if (unlikely(tc->name == TALLOC_MAGIC_REFERENCE)) {
1154 return ".reference";
1156 if (likely(tc->name)) {
1157 return tc->name;
1159 return "UNNAMED";
1164 check if a pointer has the given name. If it does, return the pointer,
1165 otherwise return NULL
1167 _PUBLIC_ void *talloc_check_name(const void *ptr, const char *name)
1169 const char *pname;
1170 if (unlikely(ptr == NULL)) return NULL;
1171 pname = talloc_get_name(ptr);
1172 if (likely(pname == name || strcmp(pname, name) == 0)) {
1173 return discard_const_p(void, ptr);
1175 return NULL;
1178 static void talloc_abort_type_mismatch(const char *location,
1179 const char *name,
1180 const char *expected)
1182 const char *reason;
1184 reason = talloc_asprintf(NULL,
1185 "%s: Type mismatch: name[%s] expected[%s]",
1186 location,
1187 name?name:"NULL",
1188 expected);
1189 if (!reason) {
1190 reason = "Type mismatch";
1193 talloc_abort(reason);
1196 _PUBLIC_ void *_talloc_get_type_abort(const void *ptr, const char *name, const char *location)
1198 const char *pname;
1200 if (unlikely(ptr == NULL)) {
1201 talloc_abort_type_mismatch(location, NULL, name);
1202 return NULL;
1205 pname = talloc_get_name(ptr);
1206 if (likely(pname == name || strcmp(pname, name) == 0)) {
1207 return discard_const_p(void, ptr);
1210 talloc_abort_type_mismatch(location, pname, name);
1211 return NULL;
1215 this is for compatibility with older versions of talloc
1217 _PUBLIC_ void *talloc_init(const char *fmt, ...)
1219 va_list ap;
1220 void *ptr;
1221 const char *name;
1223 ptr = __talloc(NULL, 0);
1224 if (unlikely(ptr == NULL)) return NULL;
1226 va_start(ap, fmt);
1227 name = talloc_set_name_v(ptr, fmt, ap);
1228 va_end(ap);
1230 if (unlikely(name == NULL)) {
1231 _talloc_free_internal(ptr, __location__);
1232 return NULL;
1235 return ptr;
1238 static inline void _talloc_free_children_internal(struct talloc_chunk *tc,
1239 void *ptr,
1240 const char *location)
1242 while (tc->child) {
1243 /* we need to work out who will own an abandoned child
1244 if it cannot be freed. In priority order, the first
1245 choice is owner of any remaining reference to this
1246 pointer, the second choice is our parent, and the
1247 final choice is the null context. */
1248 void *child = TC_PTR_FROM_CHUNK(tc->child);
1249 const void *new_parent = null_context;
1250 if (unlikely(tc->child->refs)) {
1251 struct talloc_chunk *p = talloc_parent_chunk(tc->child->refs);
1252 if (p) new_parent = TC_PTR_FROM_CHUNK(p);
1254 if (unlikely(_talloc_free_internal(child, location) == -1)) {
1255 if (new_parent == null_context) {
1256 struct talloc_chunk *p = talloc_parent_chunk(ptr);
1257 if (p) new_parent = TC_PTR_FROM_CHUNK(p);
1259 _talloc_steal_internal(new_parent, child);
1265 this is a replacement for the Samba3 talloc_destroy_pool functionality. It
1266 should probably not be used in new code. It's in here to keep the talloc
1267 code consistent across Samba 3 and 4.
1269 _PUBLIC_ void talloc_free_children(void *ptr)
1271 struct talloc_chunk *tc_name = NULL;
1272 struct talloc_chunk *tc;
1274 if (unlikely(ptr == NULL)) {
1275 return;
1278 tc = talloc_chunk_from_ptr(ptr);
1280 /* we do not want to free the context name if it is a child .. */
1281 if (likely(tc->child)) {
1282 for (tc_name = tc->child; tc_name; tc_name = tc_name->next) {
1283 if (tc->name == TC_PTR_FROM_CHUNK(tc_name)) break;
1285 if (tc_name) {
1286 _TLIST_REMOVE(tc->child, tc_name);
1287 if (tc->child) {
1288 tc->child->parent = tc;
1293 _talloc_free_children_internal(tc, ptr, __location__);
1295 /* .. so we put it back after all other children have been freed */
1296 if (tc_name) {
1297 if (tc->child) {
1298 tc->child->parent = NULL;
1300 tc_name->parent = tc;
1301 _TLIST_ADD(tc->child, tc_name);
1306 Allocate a bit of memory as a child of an existing pointer
1308 _PUBLIC_ void *_talloc(const void *context, size_t size)
1310 return __talloc(context, size);
1314 externally callable talloc_set_name_const()
1316 _PUBLIC_ void talloc_set_name_const(const void *ptr, const char *name)
1318 _talloc_set_name_const(ptr, name);
1322 create a named talloc pointer. Any talloc pointer can be named, and
1323 talloc_named() operates just like talloc() except that it allows you
1324 to name the pointer.
1326 _PUBLIC_ void *talloc_named_const(const void *context, size_t size, const char *name)
1328 return _talloc_named_const(context, size, name);
1332 free a talloc pointer. This also frees all child pointers of this
1333 pointer recursively
1335 return 0 if the memory is actually freed, otherwise -1. The memory
1336 will not be freed if the ref_count is > 1 or the destructor (if
1337 any) returns non-zero
1339 _PUBLIC_ int _talloc_free(void *ptr, const char *location)
1341 struct talloc_chunk *tc;
1343 if (unlikely(ptr == NULL)) {
1344 return -1;
1347 tc = talloc_chunk_from_ptr(ptr);
1349 if (unlikely(tc->refs != NULL)) {
1350 struct talloc_reference_handle *h;
1352 if (talloc_parent(ptr) == null_context && tc->refs->next == NULL) {
1353 /* in this case we do know which parent should
1354 get this pointer, as there is really only
1355 one parent */
1356 return talloc_unlink(null_context, ptr);
1359 talloc_log("ERROR: talloc_free with references at %s\n",
1360 location);
1362 for (h=tc->refs; h; h=h->next) {
1363 talloc_log("\treference at %s\n",
1364 h->location);
1366 return -1;
1369 return _talloc_free_internal(ptr, location);
1375 A talloc version of realloc. The context argument is only used if
1376 ptr is NULL
1378 _PUBLIC_ void *_talloc_realloc(const void *context, void *ptr, size_t size, const char *name)
1380 struct talloc_chunk *tc;
1381 void *new_ptr;
1382 bool malloced = false;
1383 struct talloc_chunk *pool_tc = NULL;
1385 /* size zero is equivalent to free() */
1386 if (unlikely(size == 0)) {
1387 talloc_unlink(context, ptr);
1388 return NULL;
1391 if (unlikely(size >= MAX_TALLOC_SIZE)) {
1392 return NULL;
1395 /* realloc(NULL) is equivalent to malloc() */
1396 if (ptr == NULL) {
1397 return _talloc_named_const(context, size, name);
1400 tc = talloc_chunk_from_ptr(ptr);
1402 /* don't allow realloc on referenced pointers */
1403 if (unlikely(tc->refs)) {
1404 return NULL;
1407 /* don't let anybody try to realloc a talloc_pool */
1408 if (unlikely(tc->flags & TALLOC_FLAG_POOL)) {
1409 return NULL;
1412 /* don't let anybody try to realloc a talloc_pool */
1413 if (unlikely(tc->flags & TALLOC_FLAG_POOLMEM)) {
1414 pool_tc = (struct talloc_chunk *)tc->pool;
1417 #if (ALWAYS_REALLOC == 0)
1418 /* don't shrink if we have less than 1k to gain */
1419 if (size < tc->size) {
1420 if (pool_tc) {
1421 void *next_tc = TC_POOLMEM_NEXT_CHUNK(tc);
1422 TC_INVALIDATE_SHRINK_CHUNK(tc, size);
1423 tc->size = size;
1424 if (next_tc == pool_tc->pool) {
1425 pool_tc->pool = TC_POOLMEM_NEXT_CHUNK(tc);
1427 return ptr;
1428 } else if ((tc->size - size) < 1024) {
1430 * if we call TC_INVALIDATE_SHRINK_CHUNK() here
1431 * we would need to call TC_UNDEFINE_GROW_CHUNK()
1432 * after each realloc call, which slows down
1433 * testing a lot :-(.
1435 * That is why we only mark memory as undefined here.
1437 TC_UNDEFINE_SHRINK_CHUNK(tc, size);
1439 /* do not shrink if we have less than 1k to gain */
1440 tc->size = size;
1441 return ptr;
1443 } else if (tc->size == size) {
1445 * do not change the pointer if it is exactly
1446 * the same size.
1448 return ptr;
1450 #endif
1452 /* by resetting magic we catch users of the old memory */
1453 tc->flags |= TALLOC_FLAG_FREE;
1455 #if ALWAYS_REALLOC
1456 if (pool_tc) {
1457 new_ptr = talloc_alloc_pool(tc, size + TC_HDR_SIZE);
1458 *talloc_pool_objectcount(pool_tc) -= 1;
1460 if (new_ptr == NULL) {
1461 new_ptr = malloc(TC_HDR_SIZE+size);
1462 malloced = true;
1465 if (new_ptr) {
1466 memcpy(new_ptr, tc, MIN(tc->size,size) + TC_HDR_SIZE);
1467 TC_INVALIDATE_FULL_CHUNK(tc);
1469 } else {
1470 new_ptr = malloc(size + TC_HDR_SIZE);
1471 if (new_ptr) {
1472 memcpy(new_ptr, tc, MIN(tc->size, size) + TC_HDR_SIZE);
1473 free(tc);
1476 #else
1477 if (pool_tc) {
1478 void *next_tc = TC_POOLMEM_NEXT_CHUNK(tc);
1479 size_t old_chunk_size = TC_POOLMEM_CHUNK_SIZE(tc);
1480 size_t new_chunk_size = TC_ALIGN16(TC_HDR_SIZE + size);
1481 size_t space_needed;
1482 size_t space_left;
1483 unsigned int chunk_count = *talloc_pool_objectcount(pool_tc);
1485 if (!(pool_tc->flags & TALLOC_FLAG_FREE)) {
1486 chunk_count -= 1;
1489 if (chunk_count == 1) {
1491 * optimize for the case where 'tc' is the only
1492 * chunk in the pool.
1494 space_needed = new_chunk_size;
1495 space_left = pool_tc->size - TALLOC_POOL_HDR_SIZE;
1497 if (space_left >= space_needed) {
1498 size_t old_used = TC_HDR_SIZE + tc->size;
1499 size_t new_used = TC_HDR_SIZE + size;
1500 pool_tc->pool = TC_POOL_FIRST_CHUNK(pool_tc);
1501 #if defined(DEVELOPER) && defined(VALGRIND_MAKE_MEM_UNDEFINED)
1503 * we need to prepare the memmove into
1504 * the unaccessable area.
1507 size_t diff = PTR_DIFF(tc, pool_tc->pool);
1508 size_t flen = MIN(diff, old_used);
1509 char *fptr = (char *)pool_tc->pool;
1510 VALGRIND_MAKE_MEM_UNDEFINED(fptr, flen);
1512 #endif
1513 memmove(pool_tc->pool, tc, old_used);
1514 new_ptr = pool_tc->pool;
1516 tc = (struct talloc_chunk *)new_ptr;
1517 TC_UNDEFINE_GROW_CHUNK(tc, size);
1520 * first we do not align the pool pointer
1521 * because we want to invalidate the padding
1522 * too.
1524 pool_tc->pool = new_used + (char *)new_ptr;
1525 TC_INVALIDATE_POOL(pool_tc);
1527 /* now the aligned pointer */
1528 pool_tc->pool = new_chunk_size + (char *)new_ptr;
1529 goto got_new_ptr;
1532 next_tc = NULL;
1535 if (new_chunk_size == old_chunk_size) {
1536 TC_UNDEFINE_GROW_CHUNK(tc, size);
1537 tc->flags &= ~TALLOC_FLAG_FREE;
1538 tc->size = size;
1539 return ptr;
1542 if (next_tc == pool_tc->pool) {
1544 * optimize for the case where 'tc' is the last
1545 * chunk in the pool.
1547 space_needed = new_chunk_size - old_chunk_size;
1548 space_left = TC_POOL_SPACE_LEFT(pool_tc);
1550 if (space_left >= space_needed) {
1551 TC_UNDEFINE_GROW_CHUNK(tc, size);
1552 tc->flags &= ~TALLOC_FLAG_FREE;
1553 tc->size = size;
1554 pool_tc->pool = TC_POOLMEM_NEXT_CHUNK(tc);
1555 return ptr;
1559 new_ptr = talloc_alloc_pool(tc, size + TC_HDR_SIZE);
1561 if (new_ptr == NULL) {
1562 new_ptr = malloc(TC_HDR_SIZE+size);
1563 malloced = true;
1566 if (new_ptr) {
1567 memcpy(new_ptr, tc, MIN(tc->size,size) + TC_HDR_SIZE);
1569 _talloc_free_poolmem(tc, __location__ "_talloc_realloc");
1572 else {
1573 new_ptr = realloc(tc, size + TC_HDR_SIZE);
1575 got_new_ptr:
1576 #endif
1577 if (unlikely(!new_ptr)) {
1578 tc->flags &= ~TALLOC_FLAG_FREE;
1579 return NULL;
1582 tc = (struct talloc_chunk *)new_ptr;
1583 tc->flags &= ~TALLOC_FLAG_FREE;
1584 if (malloced) {
1585 tc->flags &= ~TALLOC_FLAG_POOLMEM;
1587 if (tc->parent) {
1588 tc->parent->child = tc;
1590 if (tc->child) {
1591 tc->child->parent = tc;
1594 if (tc->prev) {
1595 tc->prev->next = tc;
1597 if (tc->next) {
1598 tc->next->prev = tc;
1601 tc->size = size;
1602 _talloc_set_name_const(TC_PTR_FROM_CHUNK(tc), name);
1604 return TC_PTR_FROM_CHUNK(tc);
1608 a wrapper around talloc_steal() for situations where you are moving a pointer
1609 between two structures, and want the old pointer to be set to NULL
1611 _PUBLIC_ void *_talloc_move(const void *new_ctx, const void *_pptr)
1613 const void **pptr = discard_const_p(const void *,_pptr);
1614 void *ret = talloc_steal(new_ctx, discard_const_p(void, *pptr));
1615 (*pptr) = NULL;
1616 return ret;
1620 return the total size of a talloc pool (subtree)
1622 _PUBLIC_ size_t talloc_total_size(const void *ptr)
1624 size_t total = 0;
1625 struct talloc_chunk *c, *tc;
1627 if (ptr == NULL) {
1628 ptr = null_context;
1630 if (ptr == NULL) {
1631 return 0;
1634 tc = talloc_chunk_from_ptr(ptr);
1636 if (tc->flags & TALLOC_FLAG_LOOP) {
1637 return 0;
1640 tc->flags |= TALLOC_FLAG_LOOP;
1642 if (likely(tc->name != TALLOC_MAGIC_REFERENCE)) {
1643 total = tc->size;
1645 for (c=tc->child;c;c=c->next) {
1646 total += talloc_total_size(TC_PTR_FROM_CHUNK(c));
1649 tc->flags &= ~TALLOC_FLAG_LOOP;
1651 return total;
1655 return the total number of blocks in a talloc pool (subtree)
1657 _PUBLIC_ size_t talloc_total_blocks(const void *ptr)
1659 size_t total = 0;
1660 struct talloc_chunk *c, *tc;
1662 if (ptr == NULL) {
1663 ptr = null_context;
1665 if (ptr == NULL) {
1666 return 0;
1669 tc = talloc_chunk_from_ptr(ptr);
1671 if (tc->flags & TALLOC_FLAG_LOOP) {
1672 return 0;
1675 tc->flags |= TALLOC_FLAG_LOOP;
1677 total++;
1678 for (c=tc->child;c;c=c->next) {
1679 total += talloc_total_blocks(TC_PTR_FROM_CHUNK(c));
1682 tc->flags &= ~TALLOC_FLAG_LOOP;
1684 return total;
1688 return the number of external references to a pointer
1690 _PUBLIC_ size_t talloc_reference_count(const void *ptr)
1692 struct talloc_chunk *tc = talloc_chunk_from_ptr(ptr);
1693 struct talloc_reference_handle *h;
1694 size_t ret = 0;
1696 for (h=tc->refs;h;h=h->next) {
1697 ret++;
1699 return ret;
1703 report on memory usage by all children of a pointer, giving a full tree view
1705 _PUBLIC_ void talloc_report_depth_cb(const void *ptr, int depth, int max_depth,
1706 void (*callback)(const void *ptr,
1707 int depth, int max_depth,
1708 int is_ref,
1709 void *private_data),
1710 void *private_data)
1712 struct talloc_chunk *c, *tc;
1714 if (ptr == NULL) {
1715 ptr = null_context;
1717 if (ptr == NULL) return;
1719 tc = talloc_chunk_from_ptr(ptr);
1721 if (tc->flags & TALLOC_FLAG_LOOP) {
1722 return;
1725 callback(ptr, depth, max_depth, 0, private_data);
1727 if (max_depth >= 0 && depth >= max_depth) {
1728 return;
1731 tc->flags |= TALLOC_FLAG_LOOP;
1732 for (c=tc->child;c;c=c->next) {
1733 if (c->name == TALLOC_MAGIC_REFERENCE) {
1734 struct talloc_reference_handle *h = (struct talloc_reference_handle *)TC_PTR_FROM_CHUNK(c);
1735 callback(h->ptr, depth + 1, max_depth, 1, private_data);
1736 } else {
1737 talloc_report_depth_cb(TC_PTR_FROM_CHUNK(c), depth + 1, max_depth, callback, private_data);
1740 tc->flags &= ~TALLOC_FLAG_LOOP;
1743 static void talloc_report_depth_FILE_helper(const void *ptr, int depth, int max_depth, int is_ref, void *_f)
1745 const char *name = talloc_get_name(ptr);
1746 FILE *f = (FILE *)_f;
1748 if (is_ref) {
1749 fprintf(f, "%*sreference to: %s\n", depth*4, "", name);
1750 return;
1753 if (depth == 0) {
1754 fprintf(f,"%stalloc report on '%s' (total %6lu bytes in %3lu blocks)\n",
1755 (max_depth < 0 ? "full " :""), name,
1756 (unsigned long)talloc_total_size(ptr),
1757 (unsigned long)talloc_total_blocks(ptr));
1758 return;
1761 fprintf(f, "%*s%-30s contains %6lu bytes in %3lu blocks (ref %d) %p\n",
1762 depth*4, "",
1763 name,
1764 (unsigned long)talloc_total_size(ptr),
1765 (unsigned long)talloc_total_blocks(ptr),
1766 (int)talloc_reference_count(ptr), ptr);
1768 #if 0
1769 fprintf(f, "content: ");
1770 if (talloc_total_size(ptr)) {
1771 int tot = talloc_total_size(ptr);
1772 int i;
1774 for (i = 0; i < tot; i++) {
1775 if ((((char *)ptr)[i] > 31) && (((char *)ptr)[i] < 126)) {
1776 fprintf(f, "%c", ((char *)ptr)[i]);
1777 } else {
1778 fprintf(f, "~%02x", ((char *)ptr)[i]);
1782 fprintf(f, "\n");
1783 #endif
1787 report on memory usage by all children of a pointer, giving a full tree view
1789 _PUBLIC_ void talloc_report_depth_file(const void *ptr, int depth, int max_depth, FILE *f)
1791 if (f) {
1792 talloc_report_depth_cb(ptr, depth, max_depth, talloc_report_depth_FILE_helper, f);
1793 fflush(f);
1798 report on memory usage by all children of a pointer, giving a full tree view
1800 _PUBLIC_ void talloc_report_full(const void *ptr, FILE *f)
1802 talloc_report_depth_file(ptr, 0, -1, f);
1806 report on memory usage by all children of a pointer
1808 _PUBLIC_ void talloc_report(const void *ptr, FILE *f)
1810 talloc_report_depth_file(ptr, 0, 1, f);
1814 report on any memory hanging off the null context
1816 static void talloc_report_null(void)
1818 if (talloc_total_size(null_context) != 0) {
1819 talloc_report(null_context, stderr);
1824 report on any memory hanging off the null context
1826 static void talloc_report_null_full(void)
1828 if (talloc_total_size(null_context) != 0) {
1829 talloc_report_full(null_context, stderr);
1834 enable tracking of the NULL context
1836 _PUBLIC_ void talloc_enable_null_tracking(void)
1838 if (null_context == NULL) {
1839 null_context = _talloc_named_const(NULL, 0, "null_context");
1840 if (autofree_context != NULL) {
1841 talloc_reparent(NULL, null_context, autofree_context);
1847 enable tracking of the NULL context, not moving the autofree context
1848 into the NULL context. This is needed for the talloc testsuite
1850 _PUBLIC_ void talloc_enable_null_tracking_no_autofree(void)
1852 if (null_context == NULL) {
1853 null_context = _talloc_named_const(NULL, 0, "null_context");
1858 disable tracking of the NULL context
1860 _PUBLIC_ void talloc_disable_null_tracking(void)
1862 if (null_context != NULL) {
1863 /* we have to move any children onto the real NULL
1864 context */
1865 struct talloc_chunk *tc, *tc2;
1866 tc = talloc_chunk_from_ptr(null_context);
1867 for (tc2 = tc->child; tc2; tc2=tc2->next) {
1868 if (tc2->parent == tc) tc2->parent = NULL;
1869 if (tc2->prev == tc) tc2->prev = NULL;
1871 for (tc2 = tc->next; tc2; tc2=tc2->next) {
1872 if (tc2->parent == tc) tc2->parent = NULL;
1873 if (tc2->prev == tc) tc2->prev = NULL;
1875 tc->child = NULL;
1876 tc->next = NULL;
1878 talloc_free(null_context);
1879 null_context = NULL;
1883 enable leak reporting on exit
1885 _PUBLIC_ void talloc_enable_leak_report(void)
1887 talloc_enable_null_tracking();
1888 atexit(talloc_report_null);
1892 enable full leak reporting on exit
1894 _PUBLIC_ void talloc_enable_leak_report_full(void)
1896 talloc_enable_null_tracking();
1897 atexit(talloc_report_null_full);
1901 talloc and zero memory.
1903 _PUBLIC_ void *_talloc_zero(const void *ctx, size_t size, const char *name)
1905 void *p = _talloc_named_const(ctx, size, name);
1907 if (p) {
1908 memset(p, '\0', size);
1911 return p;
1915 memdup with a talloc.
1917 _PUBLIC_ void *_talloc_memdup(const void *t, const void *p, size_t size, const char *name)
1919 void *newp = _talloc_named_const(t, size, name);
1921 if (likely(newp)) {
1922 memcpy(newp, p, size);
1925 return newp;
1928 static inline char *__talloc_strlendup(const void *t, const char *p, size_t len)
1930 char *ret;
1932 ret = (char *)__talloc(t, len + 1);
1933 if (unlikely(!ret)) return NULL;
1935 memcpy(ret, p, len);
1936 ret[len] = 0;
1938 _talloc_set_name_const(ret, ret);
1939 return ret;
1943 strdup with a talloc
1945 _PUBLIC_ char *talloc_strdup(const void *t, const char *p)
1947 if (unlikely(!p)) return NULL;
1948 return __talloc_strlendup(t, p, strlen(p));
1952 strndup with a talloc
1954 _PUBLIC_ char *talloc_strndup(const void *t, const char *p, size_t n)
1956 if (unlikely(!p)) return NULL;
1957 return __talloc_strlendup(t, p, strnlen(p, n));
1960 static inline char *__talloc_strlendup_append(char *s, size_t slen,
1961 const char *a, size_t alen)
1963 char *ret;
1965 ret = talloc_realloc(NULL, s, char, slen + alen + 1);
1966 if (unlikely(!ret)) return NULL;
1968 /* append the string and the trailing \0 */
1969 memcpy(&ret[slen], a, alen);
1970 ret[slen+alen] = 0;
1972 _talloc_set_name_const(ret, ret);
1973 return ret;
1977 * Appends at the end of the string.
1979 _PUBLIC_ char *talloc_strdup_append(char *s, const char *a)
1981 if (unlikely(!s)) {
1982 return talloc_strdup(NULL, a);
1985 if (unlikely(!a)) {
1986 return s;
1989 return __talloc_strlendup_append(s, strlen(s), a, strlen(a));
1993 * Appends at the end of the talloc'ed buffer,
1994 * not the end of the string.
1996 _PUBLIC_ char *talloc_strdup_append_buffer(char *s, const char *a)
1998 size_t slen;
2000 if (unlikely(!s)) {
2001 return talloc_strdup(NULL, a);
2004 if (unlikely(!a)) {
2005 return s;
2008 slen = talloc_get_size(s);
2009 if (likely(slen > 0)) {
2010 slen--;
2013 return __talloc_strlendup_append(s, slen, a, strlen(a));
2017 * Appends at the end of the string.
2019 _PUBLIC_ char *talloc_strndup_append(char *s, const char *a, size_t n)
2021 if (unlikely(!s)) {
2022 return talloc_strdup(NULL, a);
2025 if (unlikely(!a)) {
2026 return s;
2029 return __talloc_strlendup_append(s, strlen(s), a, strnlen(a, n));
2033 * Appends at the end of the talloc'ed buffer,
2034 * not the end of the string.
2036 _PUBLIC_ char *talloc_strndup_append_buffer(char *s, const char *a, size_t n)
2038 size_t slen;
2040 if (unlikely(!s)) {
2041 return talloc_strdup(NULL, a);
2044 if (unlikely(!a)) {
2045 return s;
2048 slen = talloc_get_size(s);
2049 if (likely(slen > 0)) {
2050 slen--;
2053 return __talloc_strlendup_append(s, slen, a, strnlen(a, n));
2056 #ifndef HAVE_VA_COPY
2057 #ifdef HAVE___VA_COPY
2058 #define va_copy(dest, src) __va_copy(dest, src)
2059 #else
2060 #define va_copy(dest, src) (dest) = (src)
2061 #endif
2062 #endif
2064 _PUBLIC_ char *talloc_vasprintf(const void *t, const char *fmt, va_list ap)
2066 int len;
2067 char *ret;
2068 va_list ap2;
2069 char c;
2071 /* this call looks strange, but it makes it work on older solaris boxes */
2072 va_copy(ap2, ap);
2073 len = vsnprintf(&c, 1, fmt, ap2);
2074 va_end(ap2);
2075 if (unlikely(len < 0)) {
2076 return NULL;
2079 ret = (char *)__talloc(t, len+1);
2080 if (unlikely(!ret)) return NULL;
2082 va_copy(ap2, ap);
2083 vsnprintf(ret, len+1, fmt, ap2);
2084 va_end(ap2);
2086 _talloc_set_name_const(ret, ret);
2087 return ret;
2092 Perform string formatting, and return a pointer to newly allocated
2093 memory holding the result, inside a memory pool.
2095 _PUBLIC_ char *talloc_asprintf(const void *t, const char *fmt, ...)
2097 va_list ap;
2098 char *ret;
2100 va_start(ap, fmt);
2101 ret = talloc_vasprintf(t, fmt, ap);
2102 va_end(ap);
2103 return ret;
2106 static inline char *__talloc_vaslenprintf_append(char *s, size_t slen,
2107 const char *fmt, va_list ap)
2108 PRINTF_ATTRIBUTE(3,0);
2110 static inline char *__talloc_vaslenprintf_append(char *s, size_t slen,
2111 const char *fmt, va_list ap)
2113 ssize_t alen;
2114 va_list ap2;
2115 char c;
2117 va_copy(ap2, ap);
2118 alen = vsnprintf(&c, 1, fmt, ap2);
2119 va_end(ap2);
2121 if (alen <= 0) {
2122 /* Either the vsnprintf failed or the format resulted in
2123 * no characters being formatted. In the former case, we
2124 * ought to return NULL, in the latter we ought to return
2125 * the original string. Most current callers of this
2126 * function expect it to never return NULL.
2128 return s;
2131 s = talloc_realloc(NULL, s, char, slen + alen + 1);
2132 if (!s) return NULL;
2134 va_copy(ap2, ap);
2135 vsnprintf(s + slen, alen + 1, fmt, ap2);
2136 va_end(ap2);
2138 _talloc_set_name_const(s, s);
2139 return s;
2143 * Realloc @p s to append the formatted result of @p fmt and @p ap,
2144 * and return @p s, which may have moved. Good for gradually
2145 * accumulating output into a string buffer. Appends at the end
2146 * of the string.
2148 _PUBLIC_ char *talloc_vasprintf_append(char *s, const char *fmt, va_list ap)
2150 if (unlikely(!s)) {
2151 return talloc_vasprintf(NULL, fmt, ap);
2154 return __talloc_vaslenprintf_append(s, strlen(s), fmt, ap);
2158 * Realloc @p s to append the formatted result of @p fmt and @p ap,
2159 * and return @p s, which may have moved. Always appends at the
2160 * end of the talloc'ed buffer, not the end of the string.
2162 _PUBLIC_ char *talloc_vasprintf_append_buffer(char *s, const char *fmt, va_list ap)
2164 size_t slen;
2166 if (unlikely(!s)) {
2167 return talloc_vasprintf(NULL, fmt, ap);
2170 slen = talloc_get_size(s);
2171 if (likely(slen > 0)) {
2172 slen--;
2175 return __talloc_vaslenprintf_append(s, slen, fmt, ap);
2179 Realloc @p s to append the formatted result of @p fmt and return @p
2180 s, which may have moved. Good for gradually accumulating output
2181 into a string buffer.
2183 _PUBLIC_ char *talloc_asprintf_append(char *s, const char *fmt, ...)
2185 va_list ap;
2187 va_start(ap, fmt);
2188 s = talloc_vasprintf_append(s, fmt, ap);
2189 va_end(ap);
2190 return s;
2194 Realloc @p s to append the formatted result of @p fmt and return @p
2195 s, which may have moved. Good for gradually accumulating output
2196 into a buffer.
2198 _PUBLIC_ char *talloc_asprintf_append_buffer(char *s, const char *fmt, ...)
2200 va_list ap;
2202 va_start(ap, fmt);
2203 s = talloc_vasprintf_append_buffer(s, fmt, ap);
2204 va_end(ap);
2205 return s;
2209 alloc an array, checking for integer overflow in the array size
2211 _PUBLIC_ void *_talloc_array(const void *ctx, size_t el_size, unsigned count, const char *name)
2213 if (count >= MAX_TALLOC_SIZE/el_size) {
2214 return NULL;
2216 return _talloc_named_const(ctx, el_size * count, name);
2220 alloc an zero array, checking for integer overflow in the array size
2222 _PUBLIC_ void *_talloc_zero_array(const void *ctx, size_t el_size, unsigned count, const char *name)
2224 if (count >= MAX_TALLOC_SIZE/el_size) {
2225 return NULL;
2227 return _talloc_zero(ctx, el_size * count, name);
2231 realloc an array, checking for integer overflow in the array size
2233 _PUBLIC_ void *_talloc_realloc_array(const void *ctx, void *ptr, size_t el_size, unsigned count, const char *name)
2235 if (count >= MAX_TALLOC_SIZE/el_size) {
2236 return NULL;
2238 return _talloc_realloc(ctx, ptr, el_size * count, name);
2242 a function version of talloc_realloc(), so it can be passed as a function pointer
2243 to libraries that want a realloc function (a realloc function encapsulates
2244 all the basic capabilities of an allocation library, which is why this is useful)
2246 _PUBLIC_ void *talloc_realloc_fn(const void *context, void *ptr, size_t size)
2248 return _talloc_realloc(context, ptr, size, NULL);
2252 static int talloc_autofree_destructor(void *ptr)
2254 autofree_context = NULL;
2255 return 0;
2258 static void talloc_autofree(void)
2260 talloc_free(autofree_context);
2264 return a context which will be auto-freed on exit
2265 this is useful for reducing the noise in leak reports
2267 _PUBLIC_ void *talloc_autofree_context(void)
2269 if (autofree_context == NULL) {
2270 autofree_context = _talloc_named_const(NULL, 0, "autofree_context");
2271 talloc_set_destructor(autofree_context, talloc_autofree_destructor);
2272 atexit(talloc_autofree);
2274 return autofree_context;
2277 _PUBLIC_ size_t talloc_get_size(const void *context)
2279 struct talloc_chunk *tc;
2281 if (context == NULL) {
2282 context = null_context;
2284 if (context == NULL) {
2285 return 0;
2288 tc = talloc_chunk_from_ptr(context);
2290 return tc->size;
2294 find a parent of this context that has the given name, if any
2296 _PUBLIC_ void *talloc_find_parent_byname(const void *context, const char *name)
2298 struct talloc_chunk *tc;
2300 if (context == NULL) {
2301 return NULL;
2304 tc = talloc_chunk_from_ptr(context);
2305 while (tc) {
2306 if (tc->name && strcmp(tc->name, name) == 0) {
2307 return TC_PTR_FROM_CHUNK(tc);
2309 while (tc && tc->prev) tc = tc->prev;
2310 if (tc) {
2311 tc = tc->parent;
2314 return NULL;
2318 show the parentage of a context
2320 _PUBLIC_ void talloc_show_parents(const void *context, FILE *file)
2322 struct talloc_chunk *tc;
2324 if (context == NULL) {
2325 fprintf(file, "talloc no parents for NULL\n");
2326 return;
2329 tc = talloc_chunk_from_ptr(context);
2330 fprintf(file, "talloc parents of '%s'\n", talloc_get_name(context));
2331 while (tc) {
2332 fprintf(file, "\t'%s'\n", talloc_get_name(TC_PTR_FROM_CHUNK(tc)));
2333 while (tc && tc->prev) tc = tc->prev;
2334 if (tc) {
2335 tc = tc->parent;
2338 fflush(file);
2342 return 1 if ptr is a parent of context
2344 static int _talloc_is_parent(const void *context, const void *ptr, int depth)
2346 struct talloc_chunk *tc;
2348 if (context == NULL) {
2349 return 0;
2352 tc = talloc_chunk_from_ptr(context);
2353 while (tc && depth > 0) {
2354 if (TC_PTR_FROM_CHUNK(tc) == ptr) return 1;
2355 while (tc && tc->prev) tc = tc->prev;
2356 if (tc) {
2357 tc = tc->parent;
2358 depth--;
2361 return 0;
2365 return 1 if ptr is a parent of context
2367 _PUBLIC_ int talloc_is_parent(const void *context, const void *ptr)
2369 return _talloc_is_parent(context, ptr, TALLOC_MAX_DEPTH);