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asterisk/main/data.c

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/*
* Asterisk -- An open source telephony toolkit.
*
* Copyright (C) 2009, Eliel C. Sardanons (LU1ALY) <eliels@gmail.com>
*
* See http://www.asterisk.org for more information about
* the Asterisk project. Please do not directly contact
* any of the maintainers of this project for assistance;
* the project provides a web site, mailing lists and IRC
* channels for your use.
*
* This program is free software, distributed under the terms of
* the GNU General Public License Version 2. See the LICENSE file
* at the top of the source tree.
*/
/*! \file
*
* \brief Data retrieval API.
*
* \author Brett Bryant <brettbryant@gmail.com>
* \author Eliel C. Sardanons (LU1ALY) <eliels@gmail.com>
*/
#include "asterisk.h"
ASTERISK_FILE_VERSION(__FILE__, "$Revision$")
#include "asterisk/_private.h"
#include <regex.h>
#include "asterisk/module.h"
#include "asterisk/utils.h"
#include "asterisk/lock.h"
#include "asterisk/data.h"
#include "asterisk/astobj2.h"
#include "asterisk/xml.h"
#include "asterisk/cli.h"
#include "asterisk/term.h"
#include "asterisk/manager.h"
#include "asterisk/test.h"
#include "asterisk/frame.h"
/*** DOCUMENTATION
<manager name="DataGet" language="en_US">
<synopsis>
Retrieve the data api tree.
</synopsis>
<syntax>
<xi:include xpointer="xpointer(/docs/manager[@name='Login']/syntax/parameter[@name='ActionID'])" />
<parameter name="Path" required="true" />
<parameter name="Search" />
<parameter name="Filter" />
</syntax>
<description>
<para>Retrieve the data api tree.</para>
</description>
</manager>
***/
#define NUM_DATA_NODE_BUCKETS 59
#define NUM_DATA_RESULT_BUCKETS 59
#define NUM_DATA_SEARCH_BUCKETS 59
#define NUM_DATA_FILTER_BUCKETS 59
/*! \brief The last compatible version. */
static const uint32_t latest_handler_compatible_version = 0;
/*! \brief The last compatible version. */
static const uint32_t latest_query_compatible_version = 0;
/*! \brief Current handler structure version. */
static const uint32_t current_handler_version = AST_DATA_HANDLER_VERSION;
/*! \brief Current query structure version. */
static const uint32_t current_query_version = AST_DATA_QUERY_VERSION;
/*! \brief The data tree to be returned by the callbacks and
managed by functions local to this file. */
struct ast_data {
enum ast_data_type type;
/*! \brief The node content. */
union {
int32_t sint;
uint32_t uint;
double dbl;
unsigned int boolean;
char *str;
char character;
struct in_addr ipaddr;
void *ptr;
} payload;
/*! \brief The filter node that depends on the current node,
* this is used only when creating the result tree. */
const struct data_filter *filter;
/*! \brief The list of nodes inside this node. */
struct ao2_container *children;
/*! \brief The name of the node. */
char name[0];
};
/*! \brief Type of comparisons allow in the search string. */
enum data_search_comparison {
DATA_CMP_UNKNOWN,
DATA_CMP_EQ, /* = */
DATA_CMP_NEQ, /* != */
DATA_CMP_GT, /* > */
DATA_CMP_GE, /* >= */
DATA_CMP_LT, /* < */
DATA_CMP_LE /* <= */
};
/*! \brief The list of nodes with their search requirement. */
struct ast_data_search {
/*! \brief The value of the comparison. */
char *value;
/*! \brief The type of comparison. */
enum data_search_comparison cmp_type;
/*! \brief reference another node. */
struct ao2_container *children;
/*! \brief The name of the node we are trying to compare. */
char name[0];
};
struct data_filter;
/*! \brief The filter node. */
struct data_filter {
/*! \brief node childrens. */
struct ao2_container *children;
/*! \brief glob list */
AST_LIST_HEAD_NOLOCK(glob_list_t, data_filter) glob_list;
/*! \brief glob list entry */
AST_LIST_ENTRY(data_filter) list;
/*! \brief node name. */
char name[0];
};
/*! \brief A data container node pointing to the registered handler. */
struct data_provider {
/*! \brief node content handler. */
const struct ast_data_handler *handler;
/*! \brief Module providing this handler. */
struct ast_module *module;
/*! \brief children nodes. */
struct ao2_container *children;
/*! \brief Who registered this node. */
const char *registrar;
/*! \brief Node name. */
char name[0];
};
/*! \brief This structure is used by the iterator. */
struct ast_data_iterator {
/*! \brief The internal iterator. */
struct ao2_iterator internal_iterator;
/*! \brief The last returned node. */
struct ast_data *last;
/*! \brief The iterator pattern. */
const char *pattern;
/*! \brief The compiled patter. */
regex_t regex_pattern;
/*! \brief is a regular expression. */
unsigned int is_pattern:1;
};
struct {
/*! \brief The asterisk data main content structure. */
struct ao2_container *container;
/*! \brief asterisk data locking mechanism. */
ast_rwlock_t lock;
} root_data;
static void __data_result_print_cli(int fd, const struct ast_data *root, uint32_t depth);
/*!
* \internal
* \brief Common string hash function.
* \see ast_data_init
*/
static int data_provider_hash(const void *obj, const int flags)
{
const struct data_provider *node = obj;
return ast_str_case_hash(node->name);
}
/*!
* \internal
* \brief Compare two data_provider's.
* \see ast_data_init
*/
static int data_provider_cmp(void *obj1, void *obj2, int flags)
{
struct data_provider *node1 = obj1, *node2 = obj2;
return strcasecmp(node1->name, node2->name) ? 0 : CMP_MATCH;
}
/*!
* \internal
* \brief Common string hash function for data nodes
*/
static int data_result_hash(const void *obj, const int flags)
{
const struct ast_data *node = obj;
return ast_str_hash(node->name);
}
/*!
* \internal
* \brief Common string comparison function
*/
static int data_result_cmp(void *obj, void *arg, int flags)
{
struct ast_data *node1 = obj, *node2 = arg;
return strcasecmp(node1->name, node2->name) ? 0 : CMP_MATCH;
}
/*!
* \internal
* \brief Lock the data registered handlers structure for writing.
* \see data_unlock
*/
#define data_write_lock() ast_rwlock_wrlock(&root_data.lock)
/*!
* \internal
* \brief Lock the data registered handlers structure for reading.
* \see data_unlock
*/
#define data_read_lock() ast_rwlock_rdlock(&root_data.lock)
/*!
* \internal
* \brief Unlock the data registered handlers structure.
*/
#define data_unlock() ast_rwlock_unlock(&root_data.lock)
/*!
* \internal
* \brief Check if a version is compatible with the current core.
* \param[in] structure_version The current structure version.
* \param[in] latest_compatible The latest compatible version.
* \param[in] current The current Data API version.
* \retval 1 If the module is compatible.
* \retval 0 If the module is NOT compatible.
*/
static int data_structure_compatible(int structure_version, uint32_t latest_compatible,
uint32_t current)
{
if (structure_version >= latest_compatible && structure_version <= current) {
return 1;
}
ast_log(LOG_ERROR, "A module is not compatible with the"
"current data api version\n");
return 0;
}
/*!
* \internal
* \brief Get the next node name in a path (/node1/node2)
* Avoid null nodes like //node1//node2/node3.
* \param[in] path The path where we are going to search for the next node name.
* \retval The next node name we found inside the given path.
* \retval NULL if there are no more node names.
*/
static char *next_node_name(char **path)
{
char *res;
do {
res = strsep(path, "/");
} while (res && ast_strlen_zero(res));
return res;
}
/*!
* \internal
* \brief Release the memory allocated by a call to ao2_alloc.
*/
static void data_provider_destructor(void *obj)
{
struct data_provider *provider = obj;
ao2_ref(provider->children, -1);
}
/*!
* \internal
* \brief Create a new data node.
* \param[in] name The name of the node we are going to create.
* \param[in] handler The handler registered for this node.
* \param[in] registrar The name of the registrar.
* \retval NULL on error.
* \retval The allocated data node structure.
*/
static struct data_provider *data_provider_new(const char *name,
const struct ast_data_handler *handler, const char *registrar)
{
struct data_provider *node;
size_t namelen;
namelen = strlen(name) + 1;
node = ao2_alloc(sizeof(*node) + namelen, data_provider_destructor);
if (!node) {
return NULL;
}
node->handler = handler;
node->registrar = registrar;
strcpy(node->name, name);
/* initialize the childrens container. */
if (!(node->children = ao2_container_alloc(NUM_DATA_NODE_BUCKETS,
data_provider_hash, data_provider_cmp))) {
ao2_ref(node, -1);
return NULL;
}
return node;
}
/*!
* \internal
* \brief Add a child node named 'name' to the 'parent' node.
* \param[in] parent Where to add the child node.
* \param[in] name The name of the child node.
* \param[in] handler The handler structure.
* \param[in] registrar Who registered this node.
* \retval NULL on error.
* \retval A newly allocated child in parent.
*/
static struct data_provider *data_provider_add_child(struct ao2_container *parent,
const char *name, const struct ast_data_handler *handler, const char *registrar)
{
struct data_provider *child;
child = data_provider_new(name, handler, registrar);
if (!child) {
return NULL;
}
ao2_link(parent, child);
return child;
}
/*!
* \internal
* \brief Find a child node, based on his name.
* \param[in] parent Where to find the node.
* \param[in] name The node name to find.
* \param[in] registrar Also check if the node was being used by this registrar.
* \retval NULL if a node wasn't found.
* \retval The node found.
* \note Remember to decrement the ref count of the returned node after using it.
*/
static struct data_provider *data_provider_find(struct ao2_container *parent,
const char *name, const char *registrar)
{
struct data_provider *find_node, *found;
/* XXX avoid allocating a new data node for searching... */
find_node = data_provider_new(name, NULL, NULL);
if (!find_node) {
return NULL;
}
found = ao2_find(parent, find_node, OBJ_POINTER);
/* free the created node used for searching. */
ao2_ref(find_node, -1);
if (found && found->registrar && registrar) {
if (strcmp(found->registrar, registrar)) {
/* if the name doesn't match, do not return this node. */
ast_debug(1, "Registrar doesn't match, node was registered"
" by '%s' and we are searching for '%s'\n",
found->registrar, registrar);
ao2_ref(found, -1);
return NULL;
}
}
return found;
}
/*!
* \internal
* \brief Release a group of nodes.
* \param[in] parent The parent node.
* \param[in] path The path of nodes to release.
* \param[in] registrar Who registered this node.
* \retval <0 on error.
* \retval 0 on success.
* \see data_provider_create
*/
static int data_provider_release(struct ao2_container *parent, const char *path,
const char *registrar)
{
char *node_name, *rpath;
struct data_provider *child;
int ret = 0;
rpath = ast_strdupa(path);
node_name = next_node_name(&rpath);
if (!node_name) {
return -1;
}
child = data_provider_find(parent, node_name, registrar);
if (!child) {
return -1;
}
/* if this is not a terminal node. */
if (!child->handler && rpath) {
ret = data_provider_release(child->children, rpath, registrar);
}
/* if this node is empty, unlink it. */
if (!ret && !ao2_container_count(child->children)) {
ao2_unlink(parent, child);
}
ao2_ref(child, -1);
return ret;
}
/*!
* \internal
* \brief Release every node registered by 'registrar'.
* \param[in] parent The parent node.
* \param[in] registrar
* \see __ast_data_unregister
*/
static void data_provider_release_all(struct ao2_container *parent,
const char *registrar)
{
struct ao2_iterator i;
struct data_provider *node;
i = ao2_iterator_init(parent, 0);
while ((node = ao2_iterator_next(&i))) {
if (!node->handler) {
/* this is a non-terminal node, go inside it. */
data_provider_release_all(node->children, registrar);
if (!ao2_container_count(node->children)) {
/* if this node was left empty, unlink it. */
ao2_unlink(parent, node);
}
} else {
if (!strcmp(node->registrar, registrar)) {
/* if the registrars match, release it! */
ao2_unlink(parent, node);
}
}
ao2_ref(node, -1);
}
ao2_iterator_destroy(&i);
}
/*!
* \internal
* \brief Create the middle nodes for the specified path (asterisk/testnode1/childnode)
* \param[in] parent Where to add the middle nodes structure.
* \param[in] path The path of nodes to add.
* \param[in] registrar Who is trying to create this node provider.
* \retval NULL on error.
* \retval The created node.
* \see data_provider_release
*/
static struct data_provider *data_provider_create(struct ao2_container *parent,
const char *path, const char *registrar)
{
char *rpath, *node_name;
struct data_provider *child, *ret = NULL;
rpath = ast_strdupa(path);
node_name = next_node_name(&rpath);
if (!node_name) {
/* no more nodes to create. */
return NULL;
}
child = data_provider_find(parent, node_name, NULL);
if (!child) {
/* nodes without handler are non-terminal nodes. */
child = data_provider_add_child(parent, node_name, NULL, registrar);
}
if (rpath) {
ret = data_provider_create(child->children, rpath, registrar);
if (ret) {
ao2_ref(child, -1);
}
}
return ret ? ret : child;
}
int __ast_data_register(const char *path, const struct ast_data_handler *handler,
const char *registrar, struct ast_module *mod)
{
struct data_provider *node;
if (!path) {
return -1;
}
/* check if the handler structure is compatible. */
if (!data_structure_compatible(handler->version,
latest_handler_compatible_version,
current_handler_version)) {
return -1;
}
/* create the node structure for the registered handler. */
data_write_lock();
node = data_provider_create(root_data.container, path, registrar);
if (!node) {
ast_log(LOG_ERROR, "Unable to create the specified path (%s) "
"for '%s'.\n", path, registrar);
data_unlock();
return -1;
}
if (ao2_container_count(node->children) || node->handler) {
ast_log(LOG_ERROR, "The node '%s' was already registered. "
"We were unable to register '%s' for registrar '%s'.\n",
node->name, path, registrar);
ao2_ref(node, -1);
data_unlock();
return -1;
}
/* add handler to that node. */
node->handler = handler;
node->module = mod;
ao2_ref(node, -1);
data_unlock();
return 0;
}
int __ast_data_register_multiple(const struct ast_data_entry *data_entries,
size_t entries, const char *registrar, struct ast_module *mod)
{
int i, res;
for (i = 0; i < entries; i++) {
res = __ast_data_register(data_entries[i].path, data_entries[i].handler,
registrar, mod);
if (res) {
/* unregister all the already registered nodes, and make
* this an atomic action. */
while ((--i) >= 0) {
__ast_data_unregister(data_entries[i].path, registrar);
}
return -1;
}
}
return 0;
}
int __ast_data_unregister(const char *path, const char *registrar)
{
int ret = 0;
data_write_lock();
if (path) {
ret = data_provider_release(root_data.container, path, registrar);
} else {
data_provider_release_all(root_data.container, registrar);
}
data_unlock();
if (path && ret) {
ast_log(LOG_ERROR, "Unable to unregister '%s' for '%s'\n",
path, registrar);
}
return ret;
}
/*!
* \internal
* \brief Is a char used to specify a comparison?
* \param[in] a Character to evaluate.
* \retval 1 It is a char used to specify a comparison.
* \retval 0 It is NOT a char used to specify a comparison.
*/
static int data_search_comparison_char(char a)
{
switch (a) {
case '!':
case '=':
case '<':
case '>':
return 1;
}
return 0;
}
/*!
* \internal
* \brief Get the type of comparison.
*/
static enum data_search_comparison data_search_comparison_type(const char *comparison)
{
if (!strcmp(comparison, "=")) {
return DATA_CMP_EQ;
} else if (!strcmp(comparison, "!=")) {
return DATA_CMP_NEQ;
} else if (!strcmp(comparison, "<")) {
return DATA_CMP_LT;
} else if (!strcmp(comparison, ">")) {
return DATA_CMP_GT;
} else if (!strcmp(comparison, "<=")) {
return DATA_CMP_LE;
} else if (!strcmp(comparison, ">=")) {
return DATA_CMP_GE;
}
return DATA_CMP_UNKNOWN;
}
/*!
* \internal
* \brief Common string hash function for data nodes
*/
static int data_search_hash(const void *obj, const int flags)
{
const struct ast_data_search *node = obj;
return ast_str_hash(node->name);
}
/*!
* \internal
* \brief Common string comparison function
*/
static int data_search_cmp(void *obj, void *arg, int flags)
{
struct ast_data_search *node1 = obj, *node2 = arg;
return strcasecmp(node1->name, node2->name) ? 0 : CMP_MATCH;
}
/*!
* \internal
* \brief Destroy the ao2 search node.
*/
static void data_search_destructor(void *obj)
{
struct ast_data_search *node = obj;
if (node->value) {
ast_free(node->value);
}
ao2_ref(node->children, -1);
}
/*!
* \internal
* \brief Allocate a search node.
* \retval NULL on error.
* \retval non-NULL The allocated search node structure.
*/
static struct ast_data_search *data_search_alloc(const char *name)
{
struct ast_data_search *res;
size_t name_len = strlen(name) + 1;
res = ao2_alloc(sizeof(*res) + name_len, data_search_destructor);
if (!res) {
return NULL;
}
res->children = ao2_container_alloc(NUM_DATA_SEARCH_BUCKETS, data_search_hash,
data_search_cmp);
if (!res) {
ao2_ref(res, -1);
return NULL;
}
strcpy(res->name, name);
return res;
}
/*!
* \internal
* \brief Find a child node, based on his name.
* \param[in] parent Where to find the node.
* \param[in] name The node name to find.
* \retval NULL if a node wasn't found.
* \retval The node found.
* \note Remember to decrement the ref count of the returned node after using it.
*/
static struct ast_data_search *data_search_find(struct ao2_container *parent,
const char *name)
{
struct ast_data_search *find_node, *found;
find_node = data_search_alloc(name);
if (!find_node) {
return NULL;
}
found = ao2_find(parent, find_node, OBJ_POINTER);
/* free the created node used for searching. */
ao2_ref(find_node, -1);
return found;
}
/*!
* \internal
* \brief Add a child node named 'name' to the 'parent' node.
* \param[in] parent Where to add the child node.
* \param[in] name The name of the child node.
* \retval NULL on error.
* \retval A newly allocated child in parent.
*/
static struct ast_data_search *data_search_add_child(struct ao2_container *parent,
const char *name)
{
struct ast_data_search *child;
child = data_search_alloc(name);
if (!child) {
return NULL;
}
ao2_link(parent, child);
return child;
}
/*!
* \internal
* \brief Create the middle nodes for the specified path (asterisk/testnode1/childnode)
* \param[in] parent Where to add the middle nodes structure.
* \param[in] path The path of nodes to add.
* \retval NULL on error.
* \retval The created node.
*/
static struct ast_data_search *data_search_create(struct ao2_container *parent,
const char *path)
{
char *rpath, *node_name;
struct ast_data_search *child = NULL;
struct ao2_container *current = parent;
rpath = ast_strdupa(path);
node_name = next_node_name(&rpath);
while (node_name) {
child = data_search_find(current, node_name);
if (!child) {
child = data_search_add_child(current, node_name);
}
ao2_ref(child, -1);
current = child->children;
node_name = next_node_name(&rpath);
}
return child;
}
/*!
* \internal
* \brief Allocate a tree with the search string parsed.
* \param[in] search_string The search string.
* \retval NULL on error.
* \retval non-NULL A dynamically allocated search tree.
*/
static struct ast_data_search *data_search_generate(const char *search_string)
{
struct ast_str *name, *value, *comparison;
char *elements, *search_string_dup, *saveptr;
int i;
struct ast_data_search *root, *child;
enum data_search_comparison cmp_type;
size_t search_string_len;
if (!search_string) {
ast_log(LOG_ERROR, "You must pass a valid search string.\n");
return NULL;
}
search_string_len = strlen(search_string);
name = ast_str_create(search_string_len);
if (!name) {
return NULL;
}
value = ast_str_create(search_string_len);
if (!value) {
ast_free(name);
return NULL;
}
comparison = ast_str_create(search_string_len);
if (!comparison) {
ast_free(name);
ast_free(value);
return NULL;
}
search_string_dup = ast_strdupa(search_string);
/* Create the root node (just used as a container) */
root = data_search_alloc("/");
if (!root) {
ast_free(name);
ast_free(value);
ast_free(comparison);
return NULL;
}
for (elements = strtok_r(search_string_dup, ",", &saveptr); elements;
elements = strtok_r(NULL, ",", &saveptr)) {
/* Parse the name */
ast_str_reset(name);
for (i = 0; !data_search_comparison_char(elements[i]) &&
elements[i]; i++) {
ast_str_append(&name, 0, "%c", elements[i]);
}
/* check if the syntax is ok. */
if (!data_search_comparison_char(elements[i])) {
/* if this is the end of the string, then this is
* an error! */
ast_log(LOG_ERROR, "Invalid search string!\n");
continue;
}
/* parse the comparison string. */
ast_str_reset(comparison);
for (; data_search_comparison_char(elements[i]) && elements[i]; i++) {
ast_str_append(&comparison, 0, "%c", elements[i]);
}
/* parse the value string. */
ast_str_reset(value);
for (; elements[i]; i++) {
ast_str_append(&value, 0, "%c", elements[i]);
}
cmp_type = data_search_comparison_type(ast_str_buffer(comparison));
if (cmp_type == DATA_CMP_UNKNOWN) {
ast_log(LOG_ERROR, "Invalid comparison '%s'\n",
ast_str_buffer(comparison));
continue;
}
/* add this node to the tree. */
child = data_search_create(root->children, ast_str_buffer(name));
if (child) {
child->cmp_type = cmp_type;
child->value = ast_strdup(ast_str_buffer(value));
}
}
ast_free(name);
ast_free(value);
ast_free(comparison);
return root;
}
/*!
* \internal
* \brief Release the allocated memory for the search tree.
* \param[in] search The search tree root node.
*/
static void data_search_release(struct ast_data_search *search)
{
ao2_ref(search, -1);
}
/*!
* \internal
* \brief Based on the kind of comparison and the result in cmpval, return
* if it matches.
* \param[in] cmpval A result returned by a strcmp() for example.
* \param[in] comparison_type The kind of comparison (<,>,=,!=,...)
* \retval 1 If the comparison doesn't match.
* \retval 0 If the comparison matches.
*/
static inline int data_search_comparison_result(int cmpval,
enum data_search_comparison comparison_type)
{
switch (comparison_type) {
case DATA_CMP_GE:
if (cmpval >= 0) {
return 0;
}
break;
case DATA_CMP_LE:
if (cmpval <= 0) {
return 0;
}
break;
case DATA_CMP_EQ:
if (cmpval == 0) {
return 0;
}
break;
case DATA_CMP_NEQ:
if (cmpval != 0) {
return 0;
}
break;
case DATA_CMP_LT:
if (cmpval < 0) {
return 0;
}
break;
case DATA_CMP_GT:
if (cmpval > 0) {
return 0;
}
break;
case DATA_CMP_UNKNOWN:
break;
}
return 1;
}
/*!
* \internal
* \brief Get an internal node, from the search tree.
* \param[in] node A node container.
* \param[in] path The path to the needed internal node.
* \retval NULL if the internal node is not found.
* \retval non-NULL the internal node with path 'path'.
*/
static struct ast_data_search *data_search_get_node(const struct ast_data_search *node,
const char *path)
{
char *savepath, *node_name;
struct ast_data_search *child, *current = (struct ast_data_search *) node;
if (!node) {
return NULL;
}
savepath = ast_strdupa(path);
node_name = next_node_name(&savepath);
while (node_name) {
child = data_search_find(current->children, node_name);
if (current != node) {
ao2_ref(current, -1);
}
if (!child) {
return NULL;
};
current = child;
node_name = next_node_name(&savepath);
}
return current;
}
/*!
* \internal
* \brief Based on a search tree, evaluate the specified 'name' inside the tree with the
* current string value.
* .search = "somename=somestring"
* name = "somename"
* value is the current value of something and will be evaluated against "somestring".
* \param[in] root The root node pointer of the search tree.
* \param[in] name The name of the specific.
* \param[in] value The value to compare.
* \returns The strcmp return value.
*/
static int data_search_cmp_string(const struct ast_data_search *root, const char *name,
char *value)
{
struct ast_data_search *child;
enum data_search_comparison cmp_type;
int ret;
child = data_search_get_node(root, name);
if (!child) {
return 0;
}
ret = strcmp(value, child->value);
cmp_type = child->cmp_type;
ao2_ref(child, -1);
return data_search_comparison_result(ret, cmp_type);
}
/*!
* \internal
* \brief Based on a search tree, evaluate the specified 'name' inside the tree with the
* current pointer address value.
* .search = "something=0x32323232"
* name = "something"
* value is the current value of something and will be evaluated against "0x32323232".
* \param[in] root The root node pointer of the search tree.
* \param[in] name The name of the specific.
* \param[in] ptr The pointer address to compare.
* \returns The (value - current_value) result.
*/
static int data_search_cmp_ptr(const struct ast_data_search *root, const char *name,
void *ptr)
{
struct ast_data_search *child;
enum data_search_comparison cmp_type;
void *node_ptr;
child = data_search_get_node(root, name);
if (!child) {
return 0;
}
cmp_type = child->cmp_type;
if (sscanf(child->value, "%p", &node_ptr) <= 0) {
return 1;
}
ao2_ref(child, -1);
return data_search_comparison_result((node_ptr - ptr), cmp_type);
}
/*!
* \internal
* \brief Based on a search tree, evaluate the specified 'name' inside the tree with the
* current ipv4 address value.
* .search = "something=192.168.2.2"
* name = "something"
* value is the current value of something and will be evaluated against "192.168.2.2".
* \param[in] root The root node pointer of the search tree.
* \param[in] name The name of the specific.
* \param[in] addr The ipv4 address value to compare.
* \returns The (value - current_value) result.
*/
static int data_search_cmp_ipaddr(const struct ast_data_search *root, const char *name,
struct in_addr addr)
{
struct ast_data_search *child;
enum data_search_comparison cmp_type;
struct in_addr node_addr;
child = data_search_get_node(root, name);
if (!child) {
return 0;
}
cmp_type = child->cmp_type;
inet_aton(child->value, &node_addr);
ao2_ref(child, -1);
return data_search_comparison_result((node_addr.s_addr - addr.s_addr), cmp_type);
}
/*!
* \internal
* \brief Based on a search tree, evaluate the specified 'name' inside the tree with the
* current boolean value.
* .search = "something=true"
* name = "something"
* value is the current value of something and will be evaluated against "true".
* \param[in] root The root node pointer of the search tree.
* \param[in] name The name of the specific.
* \param[in] value The boolean value to compare.
* \returns The (value - current_value) result.
*/
static int data_search_cmp_bool(const struct ast_data_search *root, const char *name,
unsigned int value)
{
struct ast_data_search *child;
unsigned int node_value;
enum data_search_comparison cmp_type;
child = data_search_get_node(root, name);
if (!child) {
return 0;
}
node_value = abs(ast_true(child->value));
cmp_type = child->cmp_type;
ao2_ref(child, -1);
return data_search_comparison_result(value - node_value, cmp_type);
}
/*!
* \internal
* \brief Based on a search tree, evaluate the specified 'name' inside the tree with the
* current double value.
* .search = "something=222"
* name = "something"
* value is the current value of something and will be evaluated against "222".
* \param[in] root The root node pointer of the search tree.
* \param[in] name The name of the specific.
* \param[in] value The double value to compare.
* \returns The (value - current_value) result.
*/
static int data_search_cmp_dbl(const struct ast_data_search *root, const char *name,
double value)
{
struct ast_data_search *child;
double node_value;
enum data_search_comparison cmp_type;
child = data_search_get_node(root, name);
if (!child) {
return 0;
}
node_value = strtod(child->value, NULL);
cmp_type = child->cmp_type;
ao2_ref(child, -1);
return data_search_comparison_result(value - node_value, cmp_type);
}
/*!
* \internal
* \brief Based on a search tree, evaluate the specified 'name' inside the tree with the
* current unsigned integer value.
* .search = "something=10"
* name = "something"
* value is the current value of something and will be evaluated against "10".
* \param[in] root The root node pointer of the search tree.
* \param[in] name The name of the specific.
* \param[in] value The unsigned value to compare.
* \returns The strcmp return value.
*/
static int data_search_cmp_uint(const struct ast_data_search *root, const char *name,
unsigned int value)
{
struct ast_data_search *child;
unsigned int node_value;
enum data_search_comparison cmp_type;
child = data_search_get_node(root, name);
if (!child) {
return 0;
}
node_value = atoi(child->value);
cmp_type = child->cmp_type;
ao2_ref(child, -1);
return data_search_comparison_result(value - node_value, cmp_type);
}
/*!
* \internal
* \brief Based on a search tree, evaluate the specified 'name' inside the tree with the
* current signed integer value.
* .search = "something=10"
* name = "something"
* value is the current value of something and will be evaluated against "10".
* \param[in] root The root node pointer of the search tree.
* \param[in] name The name of the specific.
* \param[in] value The value to compare.
* \returns The strcmp return value.
*/
static int data_search_cmp_int(const struct ast_data_search *root, const char *name,
int value)
{
struct ast_data_search *child;
int node_value;
enum data_search_comparison cmp_type;
child = data_search_get_node(root, name);
if (!child) {
return 0;
}
node_value = atoi(child->value);
cmp_type = child->cmp_type;
ao2_ref(child, -1);
return data_search_comparison_result(value - node_value, cmp_type);
}
/*!
* \internal
* \brief Based on a search tree, evaluate the specified 'name' inside the tree with the
* current character value.
* .search = "something=c"
* name = "something"
* value is the current value of something and will be evaluated against "c".
* \param[in] root The root node pointer of the search tree.
* \param[in] name The name of the specific.
* \param[in] value The boolean value to compare.
* \returns The (value - current_value) result.
*/
static int data_search_cmp_char(const struct ast_data_search *root, const char *name,
char value)
{
struct ast_data_search *child;
char node_value;
enum data_search_comparison cmp_type;
child = data_search_get_node(root, name);
if (!child) {
return 0;
}
node_value = *(child->value);
cmp_type = child->cmp_type;
ao2_ref(child, -1);
return data_search_comparison_result(value - node_value, cmp_type);
}
/*!
* \internal
* \brief Get the member pointer, from a mapping structure, based on its name.
* \XXX We will need to improve performance here!!.
* \retval <0 if the member was not found.
* \retval >=0 The member position in the mapping structure.
*/
static inline int data_search_mapping_find(const struct ast_data_mapping_structure *map,
size_t mapping_len,
const char *member_name)
{
int i;
for (i = 0; i < mapping_len; i++) {
if (!strcmp(map[i].name, member_name)) {
return i;
}
}
return -1;
}
int __ast_data_search_cmp_structure(const struct ast_data_search *search,
const struct ast_data_mapping_structure *mapping, size_t mapping_len,
void *structure, const char *structure_name)
{
struct ao2_iterator i;
struct ast_data_search *node, *struct_children;
int member, notmatch = 0;
if (!search) {
return 0;
}
struct_children = data_search_get_node(search, structure_name);
if (!struct_children) {
return 0;
}
i = ao2_iterator_init(struct_children->children, 0);
while ((node = ao2_iterator_next(&i))) {
member = data_search_mapping_find(mapping, mapping_len, node->name);
if (member < 0) {
/* the structure member name doesn't match! */
ao2_ref(node, -1);
ao2_ref(struct_children, -1);
ao2_iterator_destroy(&i);
return 0;
}
notmatch = 0;
switch (mapping[member].type) {
case AST_DATA_PASSWORD:
notmatch = data_search_cmp_string(struct_children,
node->name,
mapping[member].get.AST_DATA_PASSWORD(structure));
break;
case AST_DATA_TIMESTAMP:
notmatch = data_search_cmp_uint(struct_children,
node->name,
mapping[member].get.AST_DATA_TIMESTAMP(structure));
break;
case AST_DATA_SECONDS:
notmatch = data_search_cmp_uint(struct_children,
node->name,
mapping[member].get.AST_DATA_SECONDS(structure));
break;
case AST_DATA_MILLISECONDS:
notmatch = data_search_cmp_uint(struct_children,
node->name,
mapping[member].get.AST_DATA_MILLISECONDS(structure));
break;
case AST_DATA_STRING:
notmatch = data_search_cmp_string(struct_children,
node->name,
mapping[member].get.AST_DATA_STRING(structure));
break;
case AST_DATA_CHARACTER:
notmatch = data_search_cmp_char(struct_children,
node->name,
mapping[member].get.AST_DATA_CHARACTER(structure));
break;
case AST_DATA_INTEGER:
notmatch = data_search_cmp_int(struct_children,
node->name,
mapping[member].get.AST_DATA_INTEGER(structure));
break;
case AST_DATA_BOOLEAN:
notmatch = data_search_cmp_bool(struct_children,
node->name,
mapping[member].get.AST_DATA_BOOLEAN(structure));
break;
case AST_DATA_UNSIGNED_INTEGER:
notmatch = data_search_cmp_uint(struct_children,
node->name,
mapping[member].get.AST_DATA_UNSIGNED_INTEGER(structure));
break;
case AST_DATA_DOUBLE:
notmatch = data_search_cmp_dbl(struct_children,
node->name,
mapping[member].get.AST_DATA_DOUBLE(structure));
break;
case AST_DATA_IPADDR:
notmatch = data_search_cmp_ipaddr(struct_children,
node->name,
mapping[member].get.AST_DATA_IPADDR(structure));
break;
case AST_DATA_POINTER:
notmatch = data_search_cmp_ptr(struct_children,
node->name,
mapping[member].get.AST_DATA_POINTER(structure));
break;
case AST_DATA_CONTAINER:
break;
}
ao2_ref(node, -1);
}
ao2_iterator_destroy(&i);
ao2_ref(struct_children, -1);
return notmatch;
}
/*!
* \internal
* \brief Release the memory allocated by a call to ao2_alloc.
*/
static void data_result_destructor(void *obj)
{
struct ast_data *root = obj;
switch (root->type) {
case AST_DATA_PASSWORD:
case AST_DATA_STRING:
ast_free(root->payload.str);
ao2_ref(root->children, -1);
break;
case AST_DATA_POINTER:
case AST_DATA_CHARACTER:
case AST_DATA_CONTAINER:
case AST_DATA_INTEGER:
case AST_DATA_TIMESTAMP:
case AST_DATA_SECONDS:
case AST_DATA_MILLISECONDS:
case AST_DATA_UNSIGNED_INTEGER:
case AST_DATA_DOUBLE:
case AST_DATA_BOOLEAN:
case AST_DATA_IPADDR:
ao2_ref(root->children, -1);
break;
}
}
static struct ast_data *data_result_create(const char *name)
{
struct ast_data *res;
size_t namelen;
namelen = ast_strlen_zero(name) ? 1 : strlen(name) + 1;
res = ao2_alloc(sizeof(*res) + namelen, data_result_destructor);
if (!res) {
return NULL;
}
strcpy(res->name, namelen ? name : "");
/* initialize the children container */
res->children = ao2_container_alloc(NUM_DATA_RESULT_BUCKETS, data_result_hash,
data_result_cmp);
if (!res->children) {
ao2_ref(res, -1);
return NULL;
}
/* set this node as a container. */
res->type = AST_DATA_CONTAINER;
return res;
}
/*!
* \internal
* \brief Find a child node, based on its name.
* \param[in] root The starting point.
* \param[in] name The child name.
* \retval NULL if the node wasn't found.
* \retval non-NULL the node we were looking for.
*/
static struct ast_data *data_result_find_child(struct ast_data *root, const char *name)
{
struct ast_data *found, *find_node;
find_node = data_result_create(name);
if (!find_node) {
return NULL;
}
found = ao2_find(root->children, find_node, OBJ_POINTER);
/* release the temporary created node used for searching. */
ao2_ref(find_node, -1);
return found;
}
int ast_data_search_match(const struct ast_data_search *search, struct ast_data *data)
{
struct ao2_iterator i, ii;
struct ast_data_search *s, *s_child;
struct ast_data *d_child;
int notmatch = 1;
if (!search) {
return 1;
}
s_child = data_search_find(search->children, data->name);
if (!s_child) {
/* nothing to compare */
ao2_ref(s_child, -1);
return 1;
}
i = ao2_iterator_init(s_child->children, 0);
while ((s = ao2_iterator_next(&i))) {
if (!ao2_container_count(s->children)) {
/* compare this search node with every data node */
d_child = data_result_find_child(data, s->name);
if (!d_child) {
ao2_ref(s, -1);
notmatch = 1;
continue;
}
switch (d_child->type) {
case AST_DATA_PASSWORD:
case AST_DATA_STRING:
notmatch = data_search_cmp_string(s_child, d_child->name,
d_child->payload.str);
break;
case AST_DATA_CHARACTER:
notmatch = data_search_cmp_char(s_child, d_child->name,
d_child->payload.character);
break;
case AST_DATA_INTEGER:
notmatch = data_search_cmp_int(s_child, d_child->name,
d_child->payload.sint);
break;
case AST_DATA_BOOLEAN:
notmatch = data_search_cmp_bool(s_child, d_child->name,
d_child->payload.boolean);
break;
case AST_DATA_UNSIGNED_INTEGER:
notmatch = data_search_cmp_uint(s_child, d_child->name,
d_child->payload.uint);
break;
case AST_DATA_TIMESTAMP:
case AST_DATA_SECONDS:
case AST_DATA_MILLISECONDS:
case AST_DATA_DOUBLE:
notmatch = data_search_cmp_uint(s_child, d_child->name,
d_child->payload.dbl);
break;
case AST_DATA_IPADDR:
notmatch = data_search_cmp_ipaddr(s_child, d_child->name,
d_child->payload.ipaddr);
break;
case AST_DATA_POINTER:
notmatch = data_search_cmp_ptr(s_child, d_child->name,
d_child->payload.ptr);
break;
case AST_DATA_CONTAINER:
break;
}
ao2_ref(d_child, -1);
} else {
ii = ao2_iterator_init(data->children, 0);
while ((d_child = ao2_iterator_next(&ii))) {
if (strcmp(d_child->name, s->name)) {
ao2_ref(d_child, -1);
continue;
}
if (!(notmatch = !ast_data_search_match(s_child, d_child))) {
/* do not continue if we have a match. */
ao2_ref(d_child, -1);
break;
}
ao2_ref(d_child, -1);
}
ao2_iterator_destroy(&ii);
}
ao2_ref(s, -1);
if (notmatch) {
/* do not continue if we don't have a match. */
break;
}
}
ao2_iterator_destroy(&i);
ao2_ref(s_child, -1);
return !notmatch;
}
/*!
* \internal
* \brief Get an internal node, from the result set.
* \param[in] node A node container.
* \param[in] path The path to the needed internal node.
* \retval NULL if the internal node is not found.
* \retval non-NULL the internal node with path 'path'.
*/
static struct ast_data *data_result_get_node(struct ast_data *node,
const char *path)
{
char *savepath, *node_name;
struct ast_data *child, *current = node;
savepath = ast_strdupa(path);
node_name = next_node_name(&savepath);
while (node_name) {
child = data_result_find_child(current, node_name);
if (current != node) {
ao2_ref(current, -1);
}
if (!child) {
return NULL;
}
current = child;
node_name = next_node_name(&savepath);
}
/* do not increment the refcount of the returned object. */
if (current != node) {
ao2_ref(current, -1);
}
return current;
}
/*!
* \internal
* \brief Add a child to the specified root node.
* \param[in] root The root node pointer.
* \param[in] child The child to add to the root node.
*/
static void data_result_add_child(struct ast_data *root, struct ast_data *child)
{
ao2_link(root->children, child);
}
/*!
* \internal
* \brief Common string hash function for data nodes
*/
static int data_filter_hash(const void *obj, const int flags)
{
const struct data_filter *node = obj;
return ast_str_hash(node->name);
}
/*!
* \internal
* \brief Common string comparison function
*/
static int data_filter_cmp(void *obj, void *arg, int flags)
{
struct data_filter *node1 = obj, *node2 = arg;
return strcasecmp(node1->name, node2->name) ? 0 : CMP_MATCH;
}
/*!
* \internal
* \brief Destroy a data filter tree.
* \param[in] obj Data filter list to be destroyed.
*/
static void data_filter_destructor(void *obj)
{
struct data_filter *filter = obj, *globres;
AST_LIST_TRAVERSE(&(filter->glob_list), globres, list) {
ao2_ref(globres, -1);
}
ao2_ref(filter->children, -1);
}
/*!
* \internal
* \brief Allocate a filter node.
* \retval NULL on error.
* \retval non-NULL The allocated search node structure.
*/
static struct data_filter *data_filter_alloc(const char *name)
{
char *globname, *token;
struct data_filter *res, *globfilter;
size_t name_len = strlen(name) + 1;
res = ao2_alloc(sizeof(*res) + name_len, data_filter_destructor);
if (!res) {
return NULL;
}
res->children = ao2_container_alloc(NUM_DATA_FILTER_BUCKETS, data_filter_hash,
data_filter_cmp);
if (!res) {
ao2_ref(res, -1);
return NULL;
}
strcpy(res->name, name);
if (strchr(res->name, '*')) {
globname = ast_strdupa(res->name);
while ((token = strsep(&globname, "*"))) {
globfilter = data_filter_alloc(token);
AST_LIST_INSERT_TAIL(&(res->glob_list), globfilter, list);
}
}
return res;
}
/*!
* \internal
* \brief Release a filter tree.
* \param[in] filter The filter tree root node.
*/
static void data_filter_release(struct data_filter *filter)
{
ao2_ref(filter, -1);
}
/*!
* \internal
* \brief Find a child node, based on his name.
* \param[in] parent Where to find the node.
* \param[in] name The node name to find.
* \retval NULL if a node wasn't found.
* \retval The node found.
* \note Remember to decrement the ref count of the returned node after using it.
*/
static struct data_filter *data_filter_find(struct ao2_container *parent,
const char *name)
{
int i, olend, orend, globfound;
size_t name_len = strlen(name), glob_len;
struct ao2_iterator iter;
struct data_filter *find_node, *found, *globres;
find_node = data_filter_alloc(name);
if (!find_node) {
return NULL;
}
found = ao2_find(parent, find_node, OBJ_POINTER);
/* free the created node used for searching. */
ao2_ref(find_node, -1);
if (found) {
return found;
}
iter = ao2_iterator_init(parent, 0);
while ((found = ao2_iterator_next(&iter))) {
if (!AST_LIST_EMPTY(&(found->glob_list))) {
i = 0;
globfound = 1;
olend = ast_strlen_zero(AST_LIST_FIRST(&(found->glob_list))->name);
orend = ast_strlen_zero(AST_LIST_LAST(&(found->glob_list))->name);
AST_LIST_TRAVERSE(&(found->glob_list), globres, list) {
if (!*globres->name) {
continue;
}
glob_len = strlen(globres->name);
if (!i && !olend) {
if (strncasecmp(name, globres->name, glob_len)) {
globfound = 0;
break;
}
i += glob_len;
continue;
}
for (globfound = 0; name_len - i >= glob_len; ++i) {
if (!strncasecmp(name + i, globres->name, glob_len)) {
globfound = 1;
i += glob_len;
break;
}
}
if (!globfound) {
break;
}
}
if (globfound && (i == name_len || orend)) {
ao2_iterator_destroy(&iter);
return found;
}
}
ao2_ref(found, -1);
}
ao2_iterator_destroy(&iter);
return NULL;
}
/*!
* \internal
* \brief Add a child to the specified node.
* \param[in] root The root node where to add the child.
* \param[in] name The name of the node to add.
* \note Remember to decrement the ref count after using the returned node.
*/
static struct data_filter *data_filter_add_child(struct ao2_container *root,
char *name)
{
struct data_filter *node;
node = data_filter_find(root, name);
if (node) {
return node;
}
node = data_filter_alloc(name);
if (!node) {
return NULL;
}
ao2_link(root, node);
return node;
}
/*!
* \internal
* \brief Add a node to a filter list from a path
* \param[in] Filter list to add the path onto.
* \param[in] The path to add into the filter list.
* \retval NULL on error.
* \retval non-NULL A tree with the wanted nodes.
*/
static int data_filter_add_nodes(struct ao2_container *root, char *path)
{
struct data_filter *node;
char *savepath, *saveptr, *token, *node_name;
int ret = 0;
if (!path) {
return 0;
}
savepath = ast_strdupa(path);
node_name = next_node_name(&savepath);
if (!node_name) {
return 0;
}
for (token = strtok_r(node_name, "|", &saveptr);
token; token = strtok_r(NULL, "|", &saveptr)) {
node = data_filter_add_child(root, token);
if (!node) {
continue;
}
data_filter_add_nodes(node->children, savepath);
ret = 1;
ao2_ref(node, -1);
}
return ret;
}
/*!
* \internal
* \brief Generate a filter list based on a filter string provided by the API user.
* \param[in] A filter string to create a filter from.
*/
static struct data_filter *data_filter_generate(const char *constfilter)
{
struct data_filter *filter = NULL;
char *strfilter, *token, *saveptr;
int node_added = 0;
if (!constfilter) {
return NULL;
}
strfilter = ast_strdupa(constfilter);
filter = data_filter_alloc("/");
if (!filter) {
return NULL;
}
for (token = strtok_r(strfilter, ",", &saveptr); token;
token = strtok_r(NULL, ",", &saveptr)) {
node_added = data_filter_add_nodes(filter->children, token);
}
if (!node_added) {
ao2_ref(filter, -1);
return NULL;
}
return filter;
}
/*!
* \internal
* \brief Generate all the tree from a specified provider.
* \param[in] query The query executed.
* \param[in] root_provider The provider specified in the path of the query.
* \param[in] parent_node_name The root node name.
* \retval NULL on error.
* \retval non-NULL The generated result tree.
*/
static struct ast_data *data_result_generate_node(const struct ast_data_query *query,
const struct data_provider *root_provider,
const char *parent_node_name,
const struct ast_data_search *search,
const struct data_filter *filter)
{
struct ast_data *generated, *node;
struct ao2_iterator i;
struct data_provider *provider;
struct ast_data_search *search_child = NULL;
struct data_filter *filter_child;
node = data_result_create(parent_node_name);
if (!node) {
ast_log(LOG_ERROR, "Unable to allocate '%s' node\n", parent_node_name);
return NULL;
}
if (root_provider->module) {
ast_module_ref(root_provider->module);
}
/* if this is a terminal node, just run the callback function. */
if (root_provider->handler && root_provider->handler->get) {
node->filter = filter;
root_provider->handler->get(search, node);
if (root_provider->module) {
ast_module_unref(root_provider->module);
}
return node;
}
if (root_provider->module) {
ast_module_unref(root_provider->module);
}
/* if this is not a terminal node, generate every child node. */
i = ao2_iterator_init(root_provider->children, 0);
while ((provider = ao2_iterator_next(&i))) {
filter_child = NULL;
generated = NULL;
/* get the internal search node. */
if (search) {
search_child = data_search_find(search->children, provider->name);
}
/* get the internal filter node. */
if (filter) {
filter_child = data_filter_find(filter->children, provider->name);
}
if (!filter || filter_child) {
/* only generate the internal node, if we have something to
* generate based on the filtering string. */
generated = data_result_generate_node(query, provider,
provider->name,
search_child, filter_child);
}
/* decrement the refcount of the internal search node. */
if (search_child) {
ao2_ref(search_child, -1);
}
/* decrement the refcount of the internal filter node. */
if (filter_child) {
ao2_ref(filter_child, -1);
}
if (generated) {
data_result_add_child(node, generated);
ao2_ref(generated, -1);
}
ao2_ref(provider, -1);
}
ao2_iterator_destroy(&i);
return node;
}
/*!
* \internal
* \brief Generate a result tree based on a query.
* \param[in] query The complete query structure.
* \param[in] search_path The path to retrieve.
* \retval NULL on error.
* \retval non-NULL The generated data result.
*/
static struct ast_data *data_result_generate(const struct ast_data_query *query,
const char *search_path)
{
char *node_name, *tmp_path;
struct data_provider *provider_child, *tmp_provider_child;
struct ast_data *result, *result_filtered;
struct ast_data_search *search = NULL, *search_child = NULL;
struct data_filter *filter = NULL, *filter_child = NULL;
if (!search_path) {
/* generate all the trees?. */
return NULL;
}
tmp_path = ast_strdupa(search_path);
/* start searching the root node name */
node_name = next_node_name(&tmp_path);
if (!node_name) {
return NULL;
}
provider_child = data_provider_find(root_data.container, node_name, NULL);
/* continue with the rest of the path. */
while (provider_child) {
node_name = next_node_name(&tmp_path);
if (!node_name) {
break;
}
tmp_provider_child = data_provider_find(provider_child->children,
node_name, NULL);
/* release the reference from this child */
ao2_ref(provider_child, -1);
provider_child = tmp_provider_child;
}
if (!provider_child) {
ast_log(LOG_ERROR, "Invalid path '%s', '%s' not found.\n",
tmp_path, node_name);
return NULL;
}
/* generate the search tree. */
if (query->search) {
search = data_search_generate(query->search);
if (search) {
search_child = data_search_find(search->children,
provider_child->name);
}
}
/* generate the filter tree. */
if (query->filter) {
filter = data_filter_generate(query->filter);
if (filter) {
filter_child = data_filter_find(filter->children,
provider_child->name);
}
}
result = data_result_generate_node(query, provider_child, provider_child->name,
search_child, filter_child);
/* release the requested provider. */
ao2_ref(provider_child, -1);
/* release the generated search tree. */
if (search_child) {
ao2_ref(search_child, -1);
}
if (filter_child) {
ao2_ref(filter_child, -1);
}
if (search) {
data_search_release(search);
}
result_filtered = result;
/* release the generated filter tree. */
if (filter) {
data_filter_release(filter);
}
return result_filtered;
}
struct ast_data *ast_data_get(const struct ast_data_query *query)
{
struct ast_data *res;
/* check compatibility */
if (!data_structure_compatible(query->version, latest_query_compatible_version,
current_query_version)) {
return NULL;
}
data_read_lock();
res = data_result_generate(query, query->path);
data_unlock();
if (!res) {
ast_log(LOG_ERROR, "Unable to get data from %s\n", query->path);
return NULL;
}
return res;
}
#ifdef HAVE_LIBXML2
/*!
* \internal
* \brief Helper function to move an ast_data tree to xml.
* \param[in] parent_data The initial ast_data node to be passed to xml.
* \param[out] parent_xml The root node to insert the xml.
*/
static void data_get_xml_add_child(struct ast_data *parent_data,
struct ast_xml_node *parent_xml)
{
struct ao2_iterator i;
struct ast_data *node;
struct ast_xml_node *child_xml;
char node_content[256];
i = ao2_iterator_init(parent_data->children, 0);
while ((node = ao2_iterator_next(&i))) {
child_xml = ast_xml_new_node(node->name);
if (!child_xml) {
ao2_ref(node, -1);
continue;
}
switch (node->type) {
case AST_DATA_CONTAINER:
data_get_xml_add_child(node, child_xml);
break;
case AST_DATA_PASSWORD:
ast_xml_set_text(child_xml, node->payload.str);
break;
case AST_DATA_TIMESTAMP:
snprintf(node_content, sizeof(node_content), "%d",
node->payload.uint);
ast_xml_set_text(child_xml, node_content);
break;
case AST_DATA_SECONDS:
snprintf(node_content, sizeof(node_content), "%d",
node->payload.uint);
ast_xml_set_text(child_xml, node_content);
break;
case AST_DATA_MILLISECONDS:
snprintf(node_content, sizeof(node_content), "%d",
node->payload.uint);
ast_xml_set_text(child_xml, node_content);
break;
case AST_DATA_STRING:
ast_xml_set_text(child_xml, node->payload.str);
break;
case AST_DATA_CHARACTER:
snprintf(node_content, sizeof(node_content), "%c",
node->payload.character);
ast_xml_set_text(child_xml, node_content);
break;
case AST_DATA_INTEGER:
snprintf(node_content, sizeof(node_content), "%d",
node->payload.sint);
ast_xml_set_text(child_xml, node_content);
break;
case AST_DATA_UNSIGNED_INTEGER:
snprintf(node_content, sizeof(node_content), "%u",
node->payload.uint);
ast_xml_set_text(child_xml, node_content);
break;
case AST_DATA_DOUBLE:
snprintf(node_content, sizeof(node_content), "%f",
node->payload.dbl);
ast_xml_set_text(child_xml, node_content);
break;
case AST_DATA_BOOLEAN:
if (node->payload.boolean) {
ast_xml_set_text(child_xml, "true");
} else {
ast_xml_set_text(child_xml, "false");
}
break;
case AST_DATA_POINTER:
snprintf(node_content, sizeof(node_content), "%p",
node->payload.ptr);
ast_xml_set_text(child_xml, node_content);
break;
case AST_DATA_IPADDR:
snprintf(node_content, sizeof(node_content), "%s",
ast_inet_ntoa(node->payload.ipaddr));
ast_xml_set_text(child_xml, node_content);
break;
}
ast_xml_add_child(parent_xml, child_xml);
ao2_ref(node, -1);
}
ao2_iterator_destroy(&i);
}
struct ast_xml_doc *ast_data_get_xml(const struct ast_data_query *query)
{
struct ast_xml_doc *doc;
struct ast_xml_node *root;
struct ast_data *res;
res = ast_data_get(query);
if (!res) {
return NULL;
}
doc = ast_xml_new();
if (!doc) {
return NULL;
}
root = ast_xml_new_node(res->name);
if (!root) {
ast_xml_close(doc);
}
ast_xml_set_root(doc, root);
data_get_xml_add_child(res, root);
ast_data_free(res);
return doc;
}
#endif
enum ast_data_type ast_data_retrieve_type(struct ast_data *node, const char *path)
{
struct ast_data *internal;
internal = data_result_get_node(node, path);
if (!internal) {
return -1;
}
return internal->type;
}
char *ast_data_retrieve_name(struct ast_data *node)
{
return node->name;
}
/*!
* \internal
* \brief Insert a child node inside a passed parent node.
* \param root Where we are going to insert the child node.
* \param name The name of the child node to add.
* \param type The type of content inside the child node.
* \param ptr The actual content of the child node.
* \retval NULL on error.
* \retval non-NULL The added child node pointer.
*/
static struct ast_data *__ast_data_add(struct ast_data *root, const char *name,
enum ast_data_type type, void *ptr)
{
struct ast_data *node;
struct data_filter *filter, *filter_child = NULL;
if (!root || !root->children) {
/* invalid data result node. */
return NULL;
}
/* check if we need to add this node, based on the filter. */
if (root->filter) {
filter = data_filter_find(root->filter->children, name);
if (!filter) {
return NULL;
}
ao2_ref(filter, -1);
}
node = data_result_create(name);
if (!node) {
return NULL;
}
node->type = type;
switch (type) {
case AST_DATA_BOOLEAN:
node->payload.boolean = *(unsigned int *) ptr;
break;
case AST_DATA_INTEGER:
node->payload.sint = *(int *) ptr;
break;
case AST_DATA_TIMESTAMP:
case AST_DATA_SECONDS:
case AST_DATA_MILLISECONDS:
case AST_DATA_UNSIGNED_INTEGER:
node->payload.uint = *(unsigned int *) ptr;
break;
case AST_DATA_DOUBLE:
node->payload.dbl = *(double *) ptr;
break;
case AST_DATA_PASSWORD:
case AST_DATA_STRING:
node->payload.str = (char *) ptr;
break;
case AST_DATA_CHARACTER:
node->payload.character = *(char *) ptr;
break;
case AST_DATA_POINTER:
node->payload.ptr = ptr;
break;
case AST_DATA_IPADDR:
node->payload.ipaddr = *(struct in_addr *) ptr;
break;
case AST_DATA_CONTAINER:
if (root->filter) {
filter_child = data_filter_find(root->filter->children, name);
if (filter_child) {
/* do not increment the refcount because it is not neccesary. */
ao2_ref(filter_child, -1);
}
}
node->filter = filter_child;
break;
default:
break;
}
data_result_add_child(root, node);
ao2_ref(node, -1);
return node;
}
struct ast_data *ast_data_add_node(struct ast_data *root, const char *name)
{
return __ast_data_add(root, name, AST_DATA_CONTAINER, NULL);
}
struct ast_data *ast_data_add_int(struct ast_data *root, const char *name, int value)
{
return __ast_data_add(root, name, AST_DATA_INTEGER, &value);
}
struct ast_data *ast_data_add_char(struct ast_data *root, const char *name, char value)
{
return __ast_data_add(root, name, AST_DATA_CHARACTER, &value);
}
struct ast_data *ast_data_add_uint(struct ast_data *root, const char *name,
unsigned int value)
{
return __ast_data_add(root, name, AST_DATA_UNSIGNED_INTEGER, &value);
}
struct ast_data *ast_data_add_dbl(struct ast_data *root, const char *childname,
double dbl)
{
return __ast_data_add(root, childname, AST_DATA_DOUBLE, &dbl);
}
struct ast_data *ast_data_add_bool(struct ast_data *root, const char *childname,
unsigned int boolean)
{
return __ast_data_add(root, childname, AST_DATA_BOOLEAN, &boolean);
}
struct ast_data *ast_data_add_ipaddr(struct ast_data *root, const char *childname,
struct in_addr addr)
{
return __ast_data_add(root, childname, AST_DATA_IPADDR, &addr);
}
struct ast_data *ast_data_add_ptr(struct ast_data *root, const char *childname,
void *ptr)
{
return __ast_data_add(root, childname, AST_DATA_POINTER, ptr);
}
struct ast_data *ast_data_add_timestamp(struct ast_data *root, const char *childname,
unsigned int timestamp)
{
return __ast_data_add(root, childname, AST_DATA_TIMESTAMP, &timestamp);
}
struct ast_data *ast_data_add_seconds(struct ast_data *root, const char *childname,
unsigned int seconds)
{
return __ast_data_add(root, childname, AST_DATA_SECONDS, &seconds);
}
struct ast_data *ast_data_add_milliseconds(struct ast_data *root, const char *childname,
unsigned int milliseconds)
{
return __ast_data_add(root, childname, AST_DATA_MILLISECONDS, &milliseconds);
}
struct ast_data *ast_data_add_password(struct ast_data *root, const char *childname,
const char *value)
{
char *name;
size_t namelen = 1 + (ast_strlen_zero(value) ? 0 : strlen(value));
struct ast_data *res;
if (!(name = ast_malloc(namelen))) {
return NULL;
}
strcpy(name, (ast_strlen_zero(value) ? "" : value));
res = __ast_data_add(root, childname, AST_DATA_PASSWORD, name);
if (!res) {
ast_free(name);
}
return res;
}
struct ast_data *ast_data_add_str(struct ast_data *root, const char *childname,
const char *value)
{
char *name;
size_t namelen = 1 + (ast_strlen_zero(value) ? 0 : strlen(value));
struct ast_data *res;
if (!(name = ast_malloc(namelen))) {
return NULL;
}
strcpy(name, (ast_strlen_zero(value) ? "" : value));
res = __ast_data_add(root, childname, AST_DATA_STRING, name);
if (!res) {
ast_free(name);
}
return res;
}
int __ast_data_add_structure(struct ast_data *root,
const struct ast_data_mapping_structure *mapping, size_t mapping_len,
void *structure)
{
int i;
for (i = 0; i < mapping_len; i++) {
switch (mapping[i].type) {
case AST_DATA_INTEGER:
ast_data_add_int(root, mapping[i].name,
mapping[i].get.AST_DATA_INTEGER(structure));
break;
case AST_DATA_UNSIGNED_INTEGER:
ast_data_add_uint(root, mapping[i].name,
mapping[i].get.AST_DATA_UNSIGNED_INTEGER(structure));
break;
case AST_DATA_DOUBLE:
ast_data_add_dbl(root, mapping[i].name,
mapping[i].get.AST_DATA_DOUBLE(structure));
break;
case AST_DATA_BOOLEAN:
ast_data_add_bool(root, mapping[i].name,
mapping[i].get.AST_DATA_BOOLEAN(structure));
break;
case AST_DATA_PASSWORD:
ast_data_add_password(root, mapping[i].name,
mapping[i].get.AST_DATA_PASSWORD(structure));
break;
case AST_DATA_TIMESTAMP:
ast_data_add_timestamp(root, mapping[i].name,
mapping[i].get.AST_DATA_TIMESTAMP(structure));
break;
case AST_DATA_SECONDS:
ast_data_add_seconds(root, mapping[i].name,
mapping[i].get.AST_DATA_SECONDS(structure));
break;
case AST_DATA_MILLISECONDS:
ast_data_add_milliseconds(root, mapping[i].name,
mapping[i].get.AST_DATA_MILLISECONDS(structure));
break;
case AST_DATA_STRING:
ast_data_add_str(root, mapping[i].name,
mapping[i].get.AST_DATA_STRING(structure));
break;
case AST_DATA_CHARACTER:
ast_data_add_char(root, mapping[i].name,
mapping[i].get.AST_DATA_CHARACTER(structure));
break;
case AST_DATA_CONTAINER:
break;
case AST_DATA_IPADDR:
ast_data_add_ipaddr(root, mapping[i].name,
mapping[i].get.AST_DATA_IPADDR(structure));
break;
case AST_DATA_POINTER:
ast_data_add_ptr(root, mapping[i].name,
mapping[i].get.AST_DATA_POINTER(structure));
break;
}
}
return 0;
}
void ast_data_remove_node(struct ast_data *root, struct ast_data *child)
{
ao2_unlink(root->children, child);
}
void ast_data_free(struct ast_data *root)
{
/* destroy it, this will destroy all the internal nodes. */
ao2_ref(root, -1);
}
struct ast_data_iterator *ast_data_iterator_init(struct ast_data *tree,
const char *elements)
{
struct ast_data_iterator *iterator;
struct ao2_iterator i;
struct ast_data *internal = tree;
char *path, *ptr = NULL;
/* tree is the node we want to use to iterate? or we are going
* to iterate thow an internal node? */
if (elements) {
path = ast_strdupa(elements);
ptr = strrchr(path, '/');
if (ptr) {
*ptr = '\0';
internal = data_result_get_node(tree, path);
if (!internal) {
return NULL;
}
}
}
iterator = ast_calloc(1, sizeof(*iterator));
if (!iterator) {
return NULL;
}
i = ao2_iterator_init(internal->children, 0);
iterator->pattern = (ptr ? strrchr(elements, '/') + 1 : elements);
/* is the last node a regular expression?, compile it! */
if (!regcomp(&(iterator->regex_pattern), iterator->pattern,
REG_EXTENDED | REG_NOSUB | REG_ICASE)) {
iterator->is_pattern = 1;
}
iterator->internal_iterator = i;
return iterator;
}
void ast_data_iterator_end(struct ast_data_iterator *iterator)
{
/* decrement the reference counter. */
if (iterator->last) {
ao2_ref(iterator->last, -1);
}
/* release the generated pattern. */
if (iterator->is_pattern) {
regfree(&(iterator->regex_pattern));
}
ao2_iterator_destroy(&(iterator->internal_iterator));
ast_free(iterator);
iterator = NULL;
}
struct ast_data *ast_data_iterator_next(struct ast_data_iterator *iterator)
{
struct ast_data *res;
if (iterator->last) {
/* release the last retrieved node reference. */
ao2_ref(iterator->last, -1);
}
while ((res = ao2_iterator_next(&iterator->internal_iterator))) {
/* if there is no node name pattern specified, return
* the next node. */
if (!iterator->pattern) {
break;
}
/* if the pattern is a regular expression, check if this node
* matches. */
if (iterator->is_pattern && !regexec(&(iterator->regex_pattern),
res->name, 0, NULL, 0)) {
break;
}
/* if there is a pattern specified, check if this node matches
* the wanted node names. */
if (!iterator->is_pattern && (iterator->pattern &&
!strcasecmp(res->name, iterator->pattern))) {
break;
}
ao2_ref(res, -1);
}
iterator->last = res;
return res;
}
int ast_data_retrieve(struct ast_data *tree, const char *path,
struct ast_data_retrieve *content)
{
struct ast_data *node;
if (!content) {
return -1;
}
node = data_result_get_node(tree, path);
if (!node) {
ast_log(LOG_ERROR, "Invalid internal node %s\n", path);
return -1;
}
content->type = node->type;
switch (node->type) {
case AST_DATA_STRING:
content->value.AST_DATA_STRING = node->payload.str;
break;
case AST_DATA_PASSWORD:
content->value.AST_DATA_PASSWORD = node->payload.str;
break;
case AST_DATA_TIMESTAMP:
content->value.AST_DATA_TIMESTAMP = node->payload.uint;
break;
case AST_DATA_SECONDS:
content->value.AST_DATA_SECONDS = node->payload.uint;
break;
case AST_DATA_MILLISECONDS:
content->value.AST_DATA_MILLISECONDS = node->payload.uint;
break;
case AST_DATA_CHARACTER:
content->value.AST_DATA_CHARACTER = node->payload.character;
break;
case AST_DATA_INTEGER:
content->value.AST_DATA_INTEGER = node->payload.sint;
break;
case AST_DATA_UNSIGNED_INTEGER:
content->value.AST_DATA_UNSIGNED_INTEGER = node->payload.uint;
break;
case AST_DATA_BOOLEAN:
content->value.AST_DATA_BOOLEAN = node->payload.boolean;
break;
case AST_DATA_IPADDR:
content->value.AST_DATA_IPADDR = node->payload.ipaddr;
break;
case AST_DATA_DOUBLE:
content->value.AST_DATA_DOUBLE = node->payload.dbl;
break;
case AST_DATA_CONTAINER:
break;
case AST_DATA_POINTER:
content->value.AST_DATA_POINTER = node->payload.ptr;
break;
}
return 0;
}
/*!
* \internal
* \brief One color for each node type.
*/
static const struct {
enum ast_data_type type;
int color;
} data_result_color[] = {
{ AST_DATA_STRING, COLOR_BLUE },
{ AST_DATA_PASSWORD, COLOR_BRBLUE },
{ AST_DATA_TIMESTAMP, COLOR_CYAN },
{ AST_DATA_SECONDS, COLOR_MAGENTA },
{ AST_DATA_MILLISECONDS, COLOR_BRMAGENTA },
{ AST_DATA_CHARACTER, COLOR_GRAY },
{ AST_DATA_INTEGER, COLOR_RED },
{ AST_DATA_UNSIGNED_INTEGER, COLOR_RED },
{ AST_DATA_DOUBLE, COLOR_RED },
{ AST_DATA_BOOLEAN, COLOR_BRRED },
{ AST_DATA_CONTAINER, COLOR_GREEN },
{ AST_DATA_IPADDR, COLOR_BROWN },
{ AST_DATA_POINTER, COLOR_YELLOW },
};
/*!
* \internal
* \brief Get the color configured for a specific node type.
* \param[in] type The node type.
* \returns The color specified for the passed type.
*/
static int data_result_get_color(enum ast_data_type type)
{
int i;
for (i = 0; i < ARRAY_LEN(data_result_color); i++) {
if (data_result_color[i].type == type) {
return data_result_color[i].color;
}
}
return COLOR_BLUE;
}
/*!
* \internal
* \brief Print a node to the CLI.
* \param[in] fd The CLI file descriptor.
* \param[in] node The node to print.
* \param[in] depth The actual node depth in the tree.
*/
static void data_result_print_cli_node(int fd, const struct ast_data *node, uint32_t depth)
{
int i;
struct ast_str *tabs, *output;
tabs = ast_str_create(depth * 10 + 1);
if (!tabs) {
return;
}
ast_str_reset(tabs);
for (i = 0; i < depth; i++) {
ast_str_append(&tabs, 0, " ");
}
output = ast_str_create(20);
if (!output) {
ast_free(tabs);
return;
}
ast_str_reset(output);
ast_term_color_code(&output, data_result_get_color(node->type), 0);
switch (node->type) {
case AST_DATA_POINTER:
ast_str_append(&output, 0, "%s%s: %p\n", ast_str_buffer(tabs),
node->name, node->payload.ptr);
break;
case AST_DATA_PASSWORD:
ast_str_append(&output, 0, "%s%s: \"%s\"\n",
ast_str_buffer(tabs),
node->name,
node->payload.str);
break;
case AST_DATA_STRING:
ast_str_append(&output, 0, "%s%s: \"%s\"\n",
ast_str_buffer(tabs),
node->name,
node->payload.str);
break;
case AST_DATA_CHARACTER:
ast_str_append(&output, 0, "%s%s: \'%c\'\n",
ast_str_buffer(tabs),
node->name,
node->payload.character);
break;
case AST_DATA_CONTAINER:
ast_str_append(&output, 0, "%s%s\n", ast_str_buffer(tabs),
node->name);
break;
case AST_DATA_TIMESTAMP:
ast_str_append(&output, 0, "%s%s: %d\n", ast_str_buffer(tabs),
node->name,
node->payload.uint);
break;
case AST_DATA_SECONDS:
ast_str_append(&output, 0, "%s%s: %d\n", ast_str_buffer(tabs),
node->name,
node->payload.uint);
break;
case AST_DATA_MILLISECONDS:
ast_str_append(&output, 0, "%s%s: %d\n", ast_str_buffer(tabs),
node->name,
node->payload.uint);
break;
case AST_DATA_INTEGER:
ast_str_append(&output, 0, "%s%s: %d\n", ast_str_buffer(tabs),
node->name,
node->payload.sint);
break;
case AST_DATA_UNSIGNED_INTEGER:
ast_str_append(&output, 0, "%s%s: %u\n", ast_str_buffer(tabs),
node->name,
node->payload.uint);
break;
case AST_DATA_DOUBLE:
ast_str_append(&output, 0, "%s%s: %lf\n", ast_str_buffer(tabs),
node->name,
node->payload.dbl);
break;
case AST_DATA_BOOLEAN:
ast_str_append(&output, 0, "%s%s: %s\n", ast_str_buffer(tabs),
node->name,
((node->payload.boolean) ? "True" : "False"));
break;
case AST_DATA_IPADDR:
ast_str_append(&output, 0, "%s%s: %s\n", ast_str_buffer(tabs),
node->name,
ast_inet_ntoa(node->payload.ipaddr));
break;
}
ast_free(tabs);
ast_term_color_code(&output, COLOR_WHITE, 0);
ast_cli(fd, "%s", ast_str_buffer(output));
ast_free(output);
if (node->type == AST_DATA_CONTAINER) {
__data_result_print_cli(fd, node, depth + 1);
}
}
/*!
* \internal
* \brief Print out an ast_data tree to the CLI.
* \param[in] fd The CLI file descriptor.
* \param[in] root The root node of the tree.
* \param[in] depth Actual depth.
*/
static void __data_result_print_cli(int fd, const struct ast_data *root, uint32_t depth)
{
struct ao2_iterator iter;
struct ast_data *node;
if (root->type == AST_DATA_CONTAINER) {
iter = ao2_iterator_init(root->children, 0);
while ((node = ao2_iterator_next(&iter))) {
data_result_print_cli_node(fd, node, depth + 1);
ao2_ref(node, -1);
}
ao2_iterator_destroy(&iter);
} else {
data_result_print_cli_node(fd, root, depth);
}
}
/*!
* \internal
* \brief
* \param[in] fd The CLI file descriptor.
* \param[in] root The root node of the tree.
*/
static void data_result_print_cli(int fd, const struct ast_data *root)
{
struct ast_str *output;
/* print the initial node. */
output = ast_str_create(30);
if (!output) {
return;
}
ast_term_color_code(&output, data_result_get_color(root->type), 0);
ast_str_append(&output, 0, "%s\n", root->name);
ast_term_color_code(&output, COLOR_WHITE, 0);
ast_cli(fd, "%s", ast_str_buffer(output));
ast_free(output);
__data_result_print_cli(fd, root, 0);
ast_cli(fd, "\n");
}
/*!
* \internal
* \brief Handle the CLI command "data get".
*/
static char *handle_cli_data_get(struct ast_cli_entry *e, int cmd,
struct ast_cli_args *a)
{
struct ast_data_query query = {
.version = AST_DATA_QUERY_VERSION
};
struct ast_data *tree;
switch (cmd) {
case CLI_INIT:
e->command = "data get";
e->usage = ""
"Usage: data get <path> [<search> [<filter>]]\n"
" Get the tree based on a path.\n";
return NULL;
case CLI_GENERATE:
return NULL;
}
if (a->argc < e->args + 1) {
return CLI_SHOWUSAGE;
}
query.path = (char *) a->argv[e->args];
if (a->argc > e->args + 1) {
query.search = (char *) a->argv[e->args + 1];
}
if (a->argc > e->args + 2) {
query.filter = (char *) a->argv[e->args + 2];
}
tree = ast_data_get(&query);
if (!tree) {
return CLI_FAILURE;
}
data_result_print_cli(a->fd, tree);
ast_data_free(tree);
return CLI_SUCCESS;
}
/*!
* \internal
* \brief Print the list of data providers.
* \param[in] fd The CLI file descriptor.
* \param[in] name The last node visited name.
* \param[in] container The childrens of the last node.
* \param[in] path The path to the current node.
*/
static void data_provider_print_cli(int fd, const char *name,
struct ao2_container *container, struct ast_str *path)
{
struct ao2_iterator i;
struct ast_str *current_path;
struct data_provider *provider;
current_path = ast_str_create(60);
if (!current_path) {
return;
}
ast_str_reset(current_path);
if (path) {
ast_str_set(&current_path, 0, "%s/%s", ast_str_buffer(path), name);
} else {
ast_str_set(&current_path, 0, "%s", name);
}
i = ao2_iterator_init(container, 0);
while ((provider = ao2_iterator_next(&i))) {
if (provider->handler) {
/* terminal node, print it. */
ast_cli(fd, "%s/%s (", ast_str_buffer(current_path),
provider->name);
if (provider->handler->get) {
ast_cli(fd, "get");
}
ast_cli(fd, ") [%s]\n", provider->registrar);
}
data_provider_print_cli(fd, provider->name, provider->children,
current_path);
ao2_ref(provider, -1);
}
ao2_iterator_destroy(&i);
ast_free(current_path);
}
/*!
* \internal
* \brief Handle CLI command "data show providers"
*/
static char *handle_cli_data_show_providers(struct ast_cli_entry *e, int cmd,
struct ast_cli_args *a)
{
switch (cmd) {
case CLI_INIT:
e->command = "data show providers";
e->usage = ""
"Usage: data show providers\n"
" Show the list of registered providers\n";
return NULL;
case CLI_GENERATE:
return NULL;
}
data_read_lock();
data_provider_print_cli(a->fd, "", root_data.container, NULL);
data_unlock();
return CLI_SUCCESS;
}
/*!
* \internal
* \brief Data API CLI commands.
*/
static struct ast_cli_entry cli_data[] = {
AST_CLI_DEFINE(handle_cli_data_get, "Data API get"),
AST_CLI_DEFINE(handle_cli_data_show_providers, "Show data providers")
};
/*!
* \internal
* \brief Output a tree to the AMI.
* \param[in] s AMI session.
* \param[in] name The root node name.
* \param[in] container The root container.
* \param[in] path The current path.
*/
static void data_result_manager_output(struct mansession *s, const char *name,
struct ao2_container *container, struct ast_str *path, int id)
{
struct ao2_iterator i;
struct ast_str *current_path;
struct ast_data *node;
int current_id = id;
current_path = ast_str_create(60);
if (!current_path) {
return;
}
ast_str_reset(current_path);
if (path) {
ast_str_set(&current_path, 0, "%s.%s", ast_str_buffer(path), name);
} else {
ast_str_set(&current_path, 0, "%s", name);
}
i = ao2_iterator_init(container, 0);
while ((node = ao2_iterator_next(&i))) {
/* terminal node, print it. */
if (node->type != AST_DATA_CONTAINER) {
astman_append(s, "%d-%s.%s", id, ast_str_buffer(current_path),
node->name);
}
switch (node->type) {
case AST_DATA_CONTAINER:
data_result_manager_output(s, node->name, node->children, current_path, ++current_id);
break;
case AST_DATA_INTEGER:
astman_append(s, ": %d\r\n", node->payload.sint);
break;
case AST_DATA_TIMESTAMP:
case AST_DATA_SECONDS:
case AST_DATA_MILLISECONDS:
case AST_DATA_UNSIGNED_INTEGER:
astman_append(s, ": %u\r\n", node->payload.uint);
break;
case AST_DATA_PASSWORD:
astman_append(s, ": %s\r\n", node->payload.str);
break;
case AST_DATA_STRING:
astman_append(s, ": %s\r\n", node->payload.str);
break;
case AST_DATA_CHARACTER:
astman_append(s, ": %c\r\n", node->payload.character);
break;
case AST_DATA_IPADDR:
astman_append(s, ": %s\r\n", ast_inet_ntoa(node->payload.ipaddr));
break;
case AST_DATA_POINTER:
break;
case AST_DATA_DOUBLE:
astman_append(s, ": %f\r\n", node->payload.dbl);
break;
case AST_DATA_BOOLEAN:
astman_append(s, ": %s\r\n",
(node->payload.boolean ? "True" : "False"));
break;
}
ao2_ref(node, -1);
}
ao2_iterator_destroy(&i);
ast_free(current_path);
}
/*!
* \internal
* \brief Implements the manager action: "DataGet".
*/
static int manager_data_get(struct mansession *s, const struct message *m)
{
const char *path = astman_get_header(m, "Path");
const char *search = astman_get_header(m, "Search");
const char *filter = astman_get_header(m, "Filter");
const char *id = astman_get_header(m, "ActionID");
struct ast_data *res;
struct ast_data_query query = {
.version = AST_DATA_QUERY_VERSION,
.path = (char *) path,
.search = (char *) search,
.filter = (char *) filter,
};
if (ast_strlen_zero(path)) {
astman_send_error(s, m, "'Path' parameter not specified");
return 0;
}
res = ast_data_get(&query);
if (!res) {
astman_send_error(s, m, "No data returned");
return 0;
}
astman_append(s, "Event: DataGet Tree\r\n");
if (!ast_strlen_zero(id)) {
astman_append(s, "ActionID: %s\r\n", id);
}
data_result_manager_output(s, res->name, res->children, NULL, 0);
astman_append(s, "\r\n");
ast_data_free(res);
return RESULT_SUCCESS;
}
int ast_data_add_codec(struct ast_data *root, const char *node_name, struct ast_format *format)
{
struct ast_data *codecs, *codec;
size_t fmlist_size;
const struct ast_format_list *fmlist;
int x;
codecs = ast_data_add_node(root, node_name);
if (!codecs) {
return -1;
}
fmlist = ast_format_list_get(&fmlist_size);
for (x = 0; x < fmlist_size; x++) {
if (ast_format_cmp(&fmlist[x].format, format) == AST_FORMAT_CMP_EQUAL) {
codec = ast_data_add_node(codecs, "codec");
if (!codec) {
ast_format_list_destroy(fmlist);
return -1;
}
ast_data_add_str(codec, "name", fmlist[x].name);
ast_data_add_int(codec, "samplespersecond", fmlist[x].samplespersecond);
ast_data_add_str(codec, "description", fmlist[x].desc);
ast_data_add_int(codec, "frame_length", fmlist[x].fr_len);
}
}
ast_format_list_destroy(fmlist);
return 0;
}
int ast_data_add_codecs(struct ast_data *root, const char *node_name, struct ast_format_cap *cap)
{
struct ast_data *codecs, *codec;
size_t fmlist_size;
const struct ast_format_list *fmlist;
int x;
codecs = ast_data_add_node(root, node_name);
if (!codecs) {
return -1;
}
fmlist = ast_format_list_get(&fmlist_size);
for (x = 0; x < fmlist_size; x++) {
if (ast_format_cap_iscompatible(cap, &fmlist[x].format)) {
codec = ast_data_add_node(codecs, "codec");
if (!codec) {
ast_format_list_destroy(fmlist);
return -1;
}
ast_data_add_str(codec, "name", fmlist[x].name);
ast_data_add_int(codec, "samplespersecond", fmlist[x].samplespersecond);
ast_data_add_str(codec, "description", fmlist[x].desc);
ast_data_add_int(codec, "frame_length", fmlist[x].fr_len);
}
}
ast_format_list_destroy(fmlist);
return 0;
}
#ifdef TEST_FRAMEWORK
/*!
* \internal
* \brief Structure used to test how to add a complete structure,
* and how to compare it.
*/
struct test_structure {
int a_int;
unsigned int b_bool:1;
char *c_str;
unsigned int a_uint;
};
/*!
* \internal
* \brief test_structure mapping.
*/
#define DATA_EXPORT_TEST_STRUCTURE(MEMBER) \
MEMBER(test_structure, a_int, AST_DATA_INTEGER) \
MEMBER(test_structure, b_bool, AST_DATA_BOOLEAN) \
MEMBER(test_structure, c_str, AST_DATA_STRING) \
MEMBER(test_structure, a_uint, AST_DATA_UNSIGNED_INTEGER)
AST_DATA_STRUCTURE(test_structure, DATA_EXPORT_TEST_STRUCTURE);
/*!
* \internal
* \brief Callback implementation.
*/
static int test_data_full_provider(const struct ast_data_search *search,
struct ast_data *root)
{
struct ast_data *test_structure;
struct test_structure local_test_structure = {
.a_int = 10,
.b_bool = 1,
.c_str = "test string",
.a_uint = 20
};
test_structure = ast_data_add_node(root, "test_structure");
if (!test_structure) {
ast_debug(1, "Internal data api error\n");
return 0;
}
/* add the complete structure. */
ast_data_add_structure(test_structure, test_structure, &local_test_structure);
if (!ast_data_search_match(search, test_structure)) {
ast_data_remove_node(root, test_structure);
}
return 0;
}
/*!
* \internal
* \brief Handler definition for the full provider.
*/
static const struct ast_data_handler full_provider = {
.version = AST_DATA_HANDLER_VERSION,
.get = test_data_full_provider
};
/*!
* \internal
* \brief Structure used to define multiple providers at once.
*/
static const struct ast_data_entry test_providers[] = {
AST_DATA_ENTRY("test/node1/node11/node111", &full_provider)
};
AST_TEST_DEFINE(test_data_get)
{
struct ast_data *res, *node;
struct ast_data_iterator *i;
struct ast_data_query query = {
.version = AST_DATA_QUERY_VERSION,
.path = "test/node1/node11/node111",
.search = "node111/test_structure/a_int=10",
.filter = "node111/test_structure/a*int"
};
switch (cmd) {
case TEST_INIT:
info->name = "data_test";
info->category = "/main/data/";
info->summary = "Data API unit test";
info->description =
"Tests whether data API get implementation works as expected.";
return AST_TEST_NOT_RUN;
case TEST_EXECUTE:
break;
}
ast_data_register_multiple_core(test_providers, ARRAY_LEN(test_providers));
res = ast_data_get(&query);
if (!res) {
ast_test_status_update(test, "Unable to get tree.");
ast_data_unregister("test/node1/node11/node111");
return AST_TEST_FAIL;
}
/* initiate the iterator and check for errors. */
i = ast_data_iterator_init(res, "test_structure/");
if (!i) {
ast_test_status_update(test, "Unable to initiate the iterator.");
ast_data_free(res);
ast_data_unregister("test/node1/node11/node111");
return AST_TEST_FAIL;
}
/* walk the returned nodes. */
while ((node = ast_data_iterator_next(i))) {
if (!strcmp(ast_data_retrieve_name(node), "a_int")) {
if (ast_data_retrieve_int(node, "/") != 10) {
ast_data_iterator_end(i);
ast_data_free(res);
ast_data_unregister("test/node1/node11/node111");
return AST_TEST_FAIL;
}
} else if (!strcmp(ast_data_retrieve_name(node), "a_uint")) {
if (ast_data_retrieve_uint(node, "/") != 20) {
ast_data_iterator_end(i);
ast_data_free(res);
ast_data_unregister("test/node1/node11/node111");
return AST_TEST_FAIL;
}
}
}
/* finish the iterator. */
ast_data_iterator_end(i);
ast_data_free(res);
ast_data_unregister("test/node1/node11/node111");
return AST_TEST_PASS;
}
#endif
int ast_data_init(void)
{
int res = 0;
ast_rwlock_init(&root_data.lock);
if (!(root_data.container = ao2_container_alloc(NUM_DATA_NODE_BUCKETS,
data_provider_hash, data_provider_cmp))) {
return -1;
}
res |= ast_cli_register_multiple(cli_data, ARRAY_LEN(cli_data));
res |= ast_manager_register_xml("DataGet", 0, manager_data_get);
#ifdef TEST_FRAMEWORK
AST_TEST_REGISTER(test_data_get);
#endif
return res;
}
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