xbps/lib/portableproplib/prop_array.c
Juan RP 6256b34ccc Some changes that will appear in 0.5.0:
* Add proplib-0.4.1 source and use it in XBPS. This is to avoid
   an external dependency, so that we depend on the features of the
   internal library. This also means that proplib is not required anymore.

 * Added support to read/write gzip compressed plists by default, thanks
   to proplib-0.4 that gained new functionality.

That means that from now, XBPS will be able to write compressed gzip
plist files for all metadata related work. This will vastly reduce
bandwidth required for fetching remote repo's pkg index file and
binary packages.

--HG--
extra : convert_revision : xtraeme%40gmail.com-20100420122238-zcb85rudt9p34e10
2010-04-20 14:22:38 +02:00

1045 lines
24 KiB
C

/* $NetBSD: prop_array.c,v 1.20 2008/08/11 05:54:21 christos Exp $ */
/*-
* Copyright (c) 2010 Juan Romero Pardines (zlib/gzip support).
* 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.
*
* THIS SOFTWARE IS PROVIDED BY THE AUTHOR ``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 AUTHOR 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.
*/
/*-
* 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"
#include <errno.h>
#include <zlib.h>
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 = 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 = 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");
}
/*
* 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), false);
if (rv == false)
save_errno = errno;
_PROP_FREE(xml, M_TEMP);
if (rv == false)
errno = save_errno;
return (rv);
}
/*
* prop_array_externalize_to_zfile ---
* Externalize an array to the specified file, and on the fly
* compressing the result with gzip (via zlib).
*/
bool
prop_array_externalize_to_zfile(prop_array_t array, const char *fname)
{
char *xml;
bool rv;
int save_errno = 0;
xml = prop_array_externalize(array);
if (xml == NULL)
return false;
rv = _prop_object_externalize_write_file(fname, xml, strlen(xml), true);
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);
}
#define _READ_CHUNK 512
/*
* prop_array_internalize_from_zfile ---
* Internalize an array from a compressed gzip file.
*/
prop_array_t
prop_array_internalize_from_zfile(const char *fname)
{
struct _prop_object_internalize_mapped_file *mf;
prop_array_t array;
z_stream strm;
unsigned char out[_READ_CHUNK];
char *uncomp_xml = NULL;
size_t have;
ssize_t totalsize = 0;
int rv = 0;
mf = _prop_object_internalize_map_file(fname);
if (mf == NULL)
return NULL;
/* Decompress the mmap'ed buffer with zlib */
strm.zalloc = Z_NULL;
strm.zfree = Z_NULL;
strm.opaque = Z_NULL;
strm.avail_in = 0;
strm.next_in = Z_NULL;
/* 15+16 to use gzip method */
if (inflateInit2(&strm, 15+16) != Z_OK) {
_prop_object_internalize_unmap_file(mf);
return NULL;
}
strm.avail_in = mf->poimf_mapsize;
strm.next_in = mf->poimf_xml;
/* Output buffer (decompressed) */
uncomp_xml = _PROP_MALLOC(_READ_CHUNK, M_TEMP);
if (uncomp_xml == NULL) {
_prop_object_internalize_unmap_file(mf);
(void)inflateEnd(&strm);
return NULL;
}
/* Inflate the input buffer and copy into 'dest' */
do {
strm.avail_out = _READ_CHUNK;
strm.next_out = out;
rv = inflate(&strm, Z_NO_FLUSH);
switch (rv) {
case Z_DATA_ERROR:
/*
* Wrong compressed data or uncompressed, try
* normal method as last resort.
*/
(void)inflateEnd(&strm);
_PROP_FREE(uncomp_xml, M_TEMP);
array = prop_array_internalize(mf->poimf_xml);
_prop_object_internalize_unmap_file(mf);
return array;
case Z_STREAM_ERROR:
case Z_NEED_DICT:
case Z_MEM_ERROR:
(void)inflateEnd(&strm);
_PROP_FREE(uncomp_xml, M_TEMP);
_prop_object_internalize_unmap_file(mf);
errno = rv;
return NULL;
}
have = _READ_CHUNK - strm.avail_out;
totalsize += have;
uncomp_xml = _PROP_REALLOC(uncomp_xml, totalsize, M_TEMP);
memcpy(uncomp_xml + totalsize - have, out, have);
} while (strm.avail_out == 0);
/* we are done */
(void)inflateEnd(&strm);
array = prop_array_internalize(uncomp_xml);
_PROP_FREE(uncomp_xml, M_TEMP);
_prop_object_internalize_unmap_file(mf);
return array;
}