minix/common/lib/libprop/prop_array.c

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2011-12-22 17:42:19 +01:00
/* $NetBSD: prop_array.c,v 1.20 2008/08/11 05:54:21 christos Exp $ */
/*-
* Copyright (c) 2006, 2007 The NetBSD Foundation, Inc.
* All rights reserved.
*
* This code is derived from software contributed to The NetBSD Foundation
* by Jason R. Thorpe.
*
* 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.
*
* THIS SOFTWARE IS PROVIDED BY THE NETBSD FOUNDATION, INC. 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 FOUNDATION 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 <prop/prop_array.h>
#include "prop_object_impl.h"
#if !defined(_KERNEL) && !defined(_STANDALONE)
#include <errno.h>
#endif
struct _prop_array {
struct _prop_object pa_obj;
_PROP_RWLOCK_DECL(pa_rwlock)
prop_object_t * pa_array;
unsigned int pa_capacity;
unsigned int pa_count;
int pa_flags;
uint32_t pa_version;
};
#define PA_F_IMMUTABLE 0x01 /* array is immutable */
_PROP_POOL_INIT(_prop_array_pool, sizeof(struct _prop_array), "proparay")
_PROP_MALLOC_DEFINE(M_PROP_ARRAY, "prop array",
"property array container object")
static _prop_object_free_rv_t
_prop_array_free(prop_stack_t, prop_object_t *);
static void _prop_array_emergency_free(prop_object_t);
static bool _prop_array_externalize(
struct _prop_object_externalize_context *,
void *);
static _prop_object_equals_rv_t
_prop_array_equals(prop_object_t, prop_object_t,
void **, void **,
prop_object_t *, prop_object_t *);
static void _prop_array_equals_finish(prop_object_t, prop_object_t);
static prop_object_iterator_t
_prop_array_iterator_locked(prop_array_t);
static prop_object_t
_prop_array_iterator_next_object_locked(void *);
static void _prop_array_iterator_reset_locked(void *);
static const struct _prop_object_type _prop_object_type_array = {
.pot_type = PROP_TYPE_ARRAY,
.pot_free = _prop_array_free,
.pot_emergency_free = _prop_array_emergency_free,
.pot_extern = _prop_array_externalize,
.pot_equals = _prop_array_equals,
.pot_equals_finish = _prop_array_equals_finish,
};
#define prop_object_is_array(x) \
((x) != NULL && (x)->pa_obj.po_type == &_prop_object_type_array)
#define prop_array_is_immutable(x) (((x)->pa_flags & PA_F_IMMUTABLE) != 0)
struct _prop_array_iterator {
struct _prop_object_iterator pai_base;
unsigned int pai_index;
};
#define EXPAND_STEP 16
static _prop_object_free_rv_t
_prop_array_free(prop_stack_t stack, prop_object_t *obj)
{
prop_array_t pa = *obj;
prop_object_t po;
_PROP_ASSERT(pa->pa_count <= pa->pa_capacity);
_PROP_ASSERT((pa->pa_capacity == 0 && pa->pa_array == NULL) ||
(pa->pa_capacity != 0 && pa->pa_array != NULL));
/* The easy case is an empty array, just free and return. */
if (pa->pa_count == 0) {
if (pa->pa_array != NULL)
_PROP_FREE(pa->pa_array, M_PROP_ARRAY);
_PROP_RWLOCK_DESTROY(pa->pa_rwlock);
_PROP_POOL_PUT(_prop_array_pool, pa);
return (_PROP_OBJECT_FREE_DONE);
}
po = pa->pa_array[pa->pa_count - 1];
_PROP_ASSERT(po != NULL);
if (stack == NULL) {
/*
* If we are in emergency release mode,
* just let caller recurse down.
*/
*obj = po;
return (_PROP_OBJECT_FREE_FAILED);
}
/* Otherwise, try to push the current object on the stack. */
if (!_prop_stack_push(stack, pa, NULL, NULL, NULL)) {
/* Push failed, entering emergency release mode. */
return (_PROP_OBJECT_FREE_FAILED);
}
/* Object pushed on stack, caller will release it. */
--pa->pa_count;
*obj = po;
return (_PROP_OBJECT_FREE_RECURSE);
}
static void
_prop_array_emergency_free(prop_object_t obj)
{
prop_array_t pa = obj;
_PROP_ASSERT(pa->pa_count != 0);
--pa->pa_count;
}
static bool
_prop_array_externalize(struct _prop_object_externalize_context *ctx,
void *v)
{
prop_array_t pa = v;
struct _prop_object *po;
prop_object_iterator_t pi;
unsigned int i;
bool rv = false;
_PROP_RWLOCK_RDLOCK(pa->pa_rwlock);
if (pa->pa_count == 0) {
_PROP_RWLOCK_UNLOCK(pa->pa_rwlock);
return (_prop_object_externalize_empty_tag(ctx, "array"));
}
/* XXXJRT Hint "count" for the internalize step? */
if (_prop_object_externalize_start_tag(ctx, "array") == false ||
_prop_object_externalize_append_char(ctx, '\n') == false)
goto out;
pi = _prop_array_iterator_locked(pa);
if (pi == NULL)
goto out;
ctx->poec_depth++;
_PROP_ASSERT(ctx->poec_depth != 0);
while ((po = _prop_array_iterator_next_object_locked(pi)) != NULL) {
if ((*po->po_type->pot_extern)(ctx, po) == false) {
prop_object_iterator_release(pi);
goto out;
}
}
prop_object_iterator_release(pi);
ctx->poec_depth--;
for (i = 0; i < ctx->poec_depth; i++) {
if (_prop_object_externalize_append_char(ctx, '\t') == false)
goto out;
}
if (_prop_object_externalize_end_tag(ctx, "array") == false)
goto out;
rv = true;
out:
_PROP_RWLOCK_UNLOCK(pa->pa_rwlock);
return (rv);
}
/* ARGSUSED */
static _prop_object_equals_rv_t
_prop_array_equals(prop_object_t v1, prop_object_t v2,
void **stored_pointer1, void **stored_pointer2,
prop_object_t *next_obj1, prop_object_t *next_obj2)
{
prop_array_t array1 = v1;
prop_array_t array2 = v2;
uintptr_t idx;
_prop_object_equals_rv_t rv = _PROP_OBJECT_EQUALS_FALSE;
if (array1 == array2)
return (_PROP_OBJECT_EQUALS_TRUE);
_PROP_ASSERT(*stored_pointer1 == *stored_pointer2);
idx = (uintptr_t)*stored_pointer1;
/* For the first iteration, lock the objects. */
if (idx == 0) {
if ((uintptr_t)array1 < (uintptr_t)array2) {
_PROP_RWLOCK_RDLOCK(array1->pa_rwlock);
_PROP_RWLOCK_RDLOCK(array2->pa_rwlock);
} else {
_PROP_RWLOCK_RDLOCK(array2->pa_rwlock);
_PROP_RWLOCK_RDLOCK(array1->pa_rwlock);
}
}
if (array1->pa_count != array2->pa_count)
goto out;
if (idx == array1->pa_count) {
rv = _PROP_OBJECT_EQUALS_TRUE;
goto out;
}
_PROP_ASSERT(idx < array1->pa_count);
*stored_pointer1 = (void *)(idx + 1);
*stored_pointer2 = (void *)(idx + 1);
*next_obj1 = array1->pa_array[idx];
*next_obj2 = array2->pa_array[idx];
return (_PROP_OBJECT_EQUALS_RECURSE);
out:
_PROP_RWLOCK_UNLOCK(array1->pa_rwlock);
_PROP_RWLOCK_UNLOCK(array2->pa_rwlock);
return (rv);
}
static void
_prop_array_equals_finish(prop_object_t v1, prop_object_t v2)
{
_PROP_RWLOCK_UNLOCK(((prop_array_t)v1)->pa_rwlock);
_PROP_RWLOCK_UNLOCK(((prop_array_t)v2)->pa_rwlock);
}
static prop_array_t
_prop_array_alloc(unsigned int capacity)
{
prop_array_t pa;
prop_object_t *array;
if (capacity != 0) {
array = _PROP_CALLOC(capacity * sizeof(prop_object_t),
M_PROP_ARRAY);
if (array == NULL)
return (NULL);
} else
array = NULL;
pa = _PROP_POOL_GET(_prop_array_pool);
if (pa != NULL) {
_prop_object_init(&pa->pa_obj, &_prop_object_type_array);
pa->pa_obj.po_type = &_prop_object_type_array;
_PROP_RWLOCK_INIT(pa->pa_rwlock);
pa->pa_array = array;
pa->pa_capacity = capacity;
pa->pa_count = 0;
pa->pa_flags = 0;
pa->pa_version = 0;
} else if (array != NULL)
_PROP_FREE(array, M_PROP_ARRAY);
return (pa);
}
static bool
_prop_array_expand(prop_array_t pa, unsigned int capacity)
{
prop_object_t *array, *oarray;
/*
* Array must be WRITE-LOCKED.
*/
oarray = pa->pa_array;
array = _PROP_CALLOC(capacity * sizeof(*array), M_PROP_ARRAY);
if (array == NULL)
return (false);
if (oarray != NULL)
memcpy(array, oarray, pa->pa_capacity * sizeof(*array));
pa->pa_array = array;
pa->pa_capacity = capacity;
if (oarray != NULL)
_PROP_FREE(oarray, M_PROP_ARRAY);
return (true);
}
static prop_object_t
_prop_array_iterator_next_object_locked(void *v)
{
struct _prop_array_iterator *pai = v;
prop_array_t pa = pai->pai_base.pi_obj;
prop_object_t po = NULL;
_PROP_ASSERT(prop_object_is_array(pa));
if (pa->pa_version != pai->pai_base.pi_version)
goto out; /* array changed during iteration */
_PROP_ASSERT(pai->pai_index <= pa->pa_count);
if (pai->pai_index == pa->pa_count)
goto out; /* we've iterated all objects */
po = pa->pa_array[pai->pai_index];
pai->pai_index++;
out:
return (po);
}
static prop_object_t
_prop_array_iterator_next_object(void *v)
{
struct _prop_array_iterator *pai = v;
prop_array_t pa __unused = pai->pai_base.pi_obj;
prop_object_t po;
_PROP_ASSERT(prop_object_is_array(pa));
_PROP_RWLOCK_RDLOCK(pa->pa_rwlock);
po = _prop_array_iterator_next_object_locked(pai);
_PROP_RWLOCK_UNLOCK(pa->pa_rwlock);
return (po);
}
static void
_prop_array_iterator_reset_locked(void *v)
{
struct _prop_array_iterator *pai = v;
prop_array_t pa = pai->pai_base.pi_obj;
_PROP_ASSERT(prop_object_is_array(pa));
pai->pai_index = 0;
pai->pai_base.pi_version = pa->pa_version;
}
static void
_prop_array_iterator_reset(void *v)
{
struct _prop_array_iterator *pai = v;
prop_array_t pa __unused = pai->pai_base.pi_obj;
_PROP_ASSERT(prop_object_is_array(pa));
_PROP_RWLOCK_RDLOCK(pa->pa_rwlock);
_prop_array_iterator_reset_locked(pai);
_PROP_RWLOCK_UNLOCK(pa->pa_rwlock);
}
/*
* prop_array_create --
* Create an empty array.
*/
prop_array_t
prop_array_create(void)
{
return (_prop_array_alloc(0));
}
/*
* prop_array_create_with_capacity --
* Create an array with the capacity to store N objects.
*/
prop_array_t
prop_array_create_with_capacity(unsigned int capacity)
{
return (_prop_array_alloc(capacity));
}
/*
* prop_array_copy --
* Copy an array. The new array has an initial capacity equal to
* the number of objects stored in the original array. The new
* array contains references to the original array's objects, not
* copies of those objects (i.e. a shallow copy).
*/
prop_array_t
prop_array_copy(prop_array_t opa)
{
prop_array_t pa;
prop_object_t po;
unsigned int idx;
if (! prop_object_is_array(opa))
return (NULL);
_PROP_RWLOCK_RDLOCK(opa->pa_rwlock);
pa = _prop_array_alloc(opa->pa_count);
if (pa != NULL) {
for (idx = 0; idx < opa->pa_count; idx++) {
po = opa->pa_array[idx];
prop_object_retain(po);
pa->pa_array[idx] = po;
}
pa->pa_count = opa->pa_count;
pa->pa_flags = opa->pa_flags;
}
_PROP_RWLOCK_UNLOCK(opa->pa_rwlock);
return (pa);
}
/*
* prop_array_copy_mutable --
* Like prop_array_copy(), but the resulting array is mutable.
*/
prop_array_t
prop_array_copy_mutable(prop_array_t opa)
{
prop_array_t pa;
pa = prop_array_copy(opa);
if (pa != NULL)
pa->pa_flags &= ~PA_F_IMMUTABLE;
return (pa);
}
/*
* prop_array_capacity --
* Return the capacity of the array.
*/
unsigned int
prop_array_capacity(prop_array_t pa)
{
unsigned int rv;
if (! prop_object_is_array(pa))
return (0);
_PROP_RWLOCK_RDLOCK(pa->pa_rwlock);
rv = pa->pa_capacity;
_PROP_RWLOCK_UNLOCK(pa->pa_rwlock);
return (rv);
}
/*
* prop_array_count --
* Return the number of objects stored in the array.
*/
unsigned int
prop_array_count(prop_array_t pa)
{
unsigned int rv;
if (! prop_object_is_array(pa))
return (0);
_PROP_RWLOCK_RDLOCK(pa->pa_rwlock);
rv = pa->pa_count;
_PROP_RWLOCK_UNLOCK(pa->pa_rwlock);
return (rv);
}
/*
* prop_array_ensure_capacity --
* Ensure that the array has the capacity to store the specified
* total number of objects (inluding the objects already stored
* in the array).
*/
bool
prop_array_ensure_capacity(prop_array_t pa, unsigned int capacity)
{
bool rv;
if (! prop_object_is_array(pa))
return (false);
_PROP_RWLOCK_WRLOCK(pa->pa_rwlock);
if (capacity > pa->pa_capacity)
rv = _prop_array_expand(pa, capacity);
else
rv = true;
_PROP_RWLOCK_UNLOCK(pa->pa_rwlock);
return (rv);
}
static prop_object_iterator_t
_prop_array_iterator_locked(prop_array_t pa)
{
struct _prop_array_iterator *pai;
if (! prop_object_is_array(pa))
return (NULL);
pai = _PROP_CALLOC(sizeof(*pai), M_TEMP);
if (pai == NULL)
return (NULL);
pai->pai_base.pi_next_object = _prop_array_iterator_next_object;
pai->pai_base.pi_reset = _prop_array_iterator_reset;
prop_object_retain(pa);
pai->pai_base.pi_obj = pa;
_prop_array_iterator_reset_locked(pai);
return (&pai->pai_base);
}
/*
* prop_array_iterator --
* Return an iterator for the array. The array is retained by
* the iterator.
*/
prop_object_iterator_t
prop_array_iterator(prop_array_t pa)
{
prop_object_iterator_t pi;
_PROP_RWLOCK_RDLOCK(pa->pa_rwlock);
pi = _prop_array_iterator_locked(pa);
_PROP_RWLOCK_UNLOCK(pa->pa_rwlock);
return (pi);
}
/*
* prop_array_make_immutable --
* Make the array immutable.
*/
void
prop_array_make_immutable(prop_array_t pa)
{
_PROP_RWLOCK_WRLOCK(pa->pa_rwlock);
if (prop_array_is_immutable(pa) == false)
pa->pa_flags |= PA_F_IMMUTABLE;
_PROP_RWLOCK_UNLOCK(pa->pa_rwlock);
}
/*
* prop_array_mutable --
* Returns true if the array is mutable.
*/
bool
prop_array_mutable(prop_array_t pa)
{
bool rv;
_PROP_RWLOCK_RDLOCK(pa->pa_rwlock);
rv = prop_array_is_immutable(pa) == false;
_PROP_RWLOCK_UNLOCK(pa->pa_rwlock);
return (rv);
}
/*
* prop_array_get --
* Return the object stored at the specified array index.
*/
prop_object_t
prop_array_get(prop_array_t pa, unsigned int idx)
{
prop_object_t po = NULL;
if (! prop_object_is_array(pa))
return (NULL);
_PROP_RWLOCK_RDLOCK(pa->pa_rwlock);
if (idx >= pa->pa_count)
goto out;
po = pa->pa_array[idx];
_PROP_ASSERT(po != NULL);
out:
_PROP_RWLOCK_UNLOCK(pa->pa_rwlock);
return (po);
}
static bool
_prop_array_add(prop_array_t pa, prop_object_t po)
{
/*
* Array must be WRITE-LOCKED.
*/
_PROP_ASSERT(pa->pa_count <= pa->pa_capacity);
if (prop_array_is_immutable(pa) ||
(pa->pa_count == pa->pa_capacity &&
_prop_array_expand(pa, pa->pa_capacity + EXPAND_STEP) == false))
return (false);
prop_object_retain(po);
pa->pa_array[pa->pa_count++] = po;
pa->pa_version++;
return (true);
}
/*
* prop_array_set --
* Store a reference to an object at the specified array index.
* This method is not allowed to create holes in the array; the
* caller must either be setting the object just beyond the existing
* count or replacing an already existing object reference.
*/
bool
prop_array_set(prop_array_t pa, unsigned int idx, prop_object_t po)
{
prop_object_t opo;
bool rv = false;
if (! prop_object_is_array(pa))
return (false);
_PROP_RWLOCK_WRLOCK(pa->pa_rwlock);
if (prop_array_is_immutable(pa))
goto out;
if (idx == pa->pa_count) {
rv = _prop_array_add(pa, po);
goto out;
}
_PROP_ASSERT(idx < pa->pa_count);
opo = pa->pa_array[idx];
_PROP_ASSERT(opo != NULL);
prop_object_retain(po);
pa->pa_array[idx] = po;
pa->pa_version++;
prop_object_release(opo);
rv = true;
out:
_PROP_RWLOCK_UNLOCK(pa->pa_rwlock);
return (rv);
}
/*
* prop_array_add --
* Add a reference to an object to the specified array, appending
* to the end and growing the array's capacity, if necessary.
*/
bool
prop_array_add(prop_array_t pa, prop_object_t po)
{
bool rv;
if (! prop_object_is_array(pa))
return (false);
_PROP_RWLOCK_WRLOCK(pa->pa_rwlock);
rv = _prop_array_add(pa, po);
_PROP_RWLOCK_UNLOCK(pa->pa_rwlock);
return (rv);
}
/*
* prop_array_remove --
* Remove the reference to an object from an array at the specified
* index. The array will be compacted following the removal.
*/
void
prop_array_remove(prop_array_t pa, unsigned int idx)
{
prop_object_t po;
if (! prop_object_is_array(pa))
return;
_PROP_RWLOCK_WRLOCK(pa->pa_rwlock);
_PROP_ASSERT(idx < pa->pa_count);
/* XXX Should this be a _PROP_ASSERT()? */
if (prop_array_is_immutable(pa)) {
_PROP_RWLOCK_UNLOCK(pa->pa_rwlock);
return;
}
po = pa->pa_array[idx];
_PROP_ASSERT(po != NULL);
for (++idx; idx < pa->pa_count; idx++)
pa->pa_array[idx - 1] = pa->pa_array[idx];
pa->pa_count--;
pa->pa_version++;
_PROP_RWLOCK_UNLOCK(pa->pa_rwlock);
prop_object_release(po);
}
/*
* prop_array_equals --
* Return true if the two arrays are equivalent. Note we do a
* by-value comparison of the objects in the array.
*/
bool
prop_array_equals(prop_array_t array1, prop_array_t array2)
{
if (!prop_object_is_array(array1) || !prop_object_is_array(array2))
return (false);
return (prop_object_equals(array1, array2));
}
/*
* prop_array_externalize --
* Externalize an array, return a NUL-terminated buffer
* containing the XML-style representation. The buffer is allocated
* with the M_TEMP memory type.
*/
char *
prop_array_externalize(prop_array_t pa)
{
struct _prop_object_externalize_context *ctx;
char *cp;
ctx = _prop_object_externalize_context_alloc();
if (ctx == NULL)
return (NULL);
if (_prop_object_externalize_header(ctx) == false ||
(*pa->pa_obj.po_type->pot_extern)(ctx, pa) == false ||
_prop_object_externalize_footer(ctx) == false) {
/* We are responsible for releasing the buffer. */
_PROP_FREE(ctx->poec_buf, M_TEMP);
_prop_object_externalize_context_free(ctx);
return (NULL);
}
cp = ctx->poec_buf;
_prop_object_externalize_context_free(ctx);
return (cp);
}
/*
* _prop_array_internalize --
* Parse an <array>...</array> and return the object created from the
* external representation.
*/
static bool _prop_array_internalize_body(prop_stack_t, prop_object_t *,
struct _prop_object_internalize_context *);
bool
_prop_array_internalize(prop_stack_t stack, prop_object_t *obj,
struct _prop_object_internalize_context *ctx)
{
/* We don't currently understand any attributes. */
if (ctx->poic_tagattr != NULL)
return (true);
*obj = prop_array_create();
/*
* We are done if the create failed or no child elements exist.
*/
if (*obj == NULL || ctx->poic_is_empty_element)
return (true);
/*
* Opening tag is found, now continue to the first element.
*/
return (_prop_array_internalize_body(stack, obj, ctx));
}
static bool
_prop_array_internalize_continue(prop_stack_t stack,
prop_object_t *obj,
struct _prop_object_internalize_context *ctx,
void *data, prop_object_t child)
{
prop_array_t array;
_PROP_ASSERT(data == NULL);
if (child == NULL)
goto bad; /* Element could not be parsed. */
array = *obj;
if (prop_array_add(array, child) == false) {
prop_object_release(child);
goto bad;
}
prop_object_release(child);
/*
* Current element is processed and added, look for next.
*/
return (_prop_array_internalize_body(stack, obj, ctx));
bad:
prop_object_release(*obj);
*obj = NULL;
return (true);
}
static bool
_prop_array_internalize_body(prop_stack_t stack, prop_object_t *obj,
struct _prop_object_internalize_context *ctx)
{
prop_array_t array = *obj;
_PROP_ASSERT(array != NULL);
/* Fetch the next tag. */
if (_prop_object_internalize_find_tag(ctx, NULL,
_PROP_TAG_TYPE_EITHER) == false)
goto bad;
/* Check to see if this is the end of the array. */
if (_PROP_TAG_MATCH(ctx, "array") &&
ctx->poic_tag_type == _PROP_TAG_TYPE_END) {
/* It is, so don't iterate any further. */
return (true);
}
if (_prop_stack_push(stack, array,
_prop_array_internalize_continue, NULL, NULL))
return (false);
bad:
prop_object_release(array);
*obj = NULL;
return (true);
}
/*
* prop_array_internalize --
* Create an array by parsing the XML-style representation.
*/
prop_array_t
prop_array_internalize(const char *xml)
{
return _prop_generic_internalize(xml, "array");
}
#if !defined(_KERNEL) && !defined(_STANDALONE)
/*
* prop_array_externalize_to_file --
* Externalize an array to the specified file.
*/
bool
prop_array_externalize_to_file(prop_array_t array, const char *fname)
{
char *xml;
bool rv;
int save_errno = 0; /* XXXGCC -Wuninitialized [mips, ...] */
xml = prop_array_externalize(array);
if (xml == NULL)
return (false);
rv = _prop_object_externalize_write_file(fname, xml, strlen(xml));
if (rv == false)
save_errno = errno;
_PROP_FREE(xml, M_TEMP);
if (rv == false)
errno = save_errno;
return (rv);
}
/*
* prop_array_internalize_from_file --
* Internalize an array from a file.
*/
prop_array_t
prop_array_internalize_from_file(const char *fname)
{
struct _prop_object_internalize_mapped_file *mf;
prop_array_t array;
mf = _prop_object_internalize_map_file(fname);
if (mf == NULL)
return (NULL);
array = prop_array_internalize(mf->poimf_xml);
_prop_object_internalize_unmap_file(mf);
return (array);
}
#endif /* _KERNEL && !_STANDALONE */