asterisk/res/stasis/control.c

1719 lines
44 KiB
C
Raw Normal View History

2023-05-25 18:45:57 +00:00
/*
* Asterisk -- An open source telephony toolkit.
*
* Copyright (C) 2013, Digium, Inc.
*
* David M. Lee, II <dlee@digium.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 Stasis application control support.
*
* \author David M. Lee, II <dlee@digium.com>
*/
#include "asterisk.h"
#include "asterisk/stasis_channels.h"
#include "asterisk/stasis_app.h"
#include "command.h"
#include "control.h"
#include "app.h"
#include "asterisk/dial.h"
#include "asterisk/bridge.h"
#include "asterisk/bridge_after.h"
#include "asterisk/bridge_basic.h"
#include "asterisk/bridge_features.h"
#include "asterisk/frame.h"
#include "asterisk/pbx.h"
#include "asterisk/musiconhold.h"
#include "asterisk/app.h"
AST_LIST_HEAD(app_control_rules, stasis_app_control_rule);
/*!
* \brief Indicates if the Stasis app internals are being shut down
*/
static int shutting_down;
struct stasis_app_control {
ast_cond_t wait_cond;
/*! Queue of commands to dispatch on the channel */
struct ao2_container *command_queue;
/*!
* The associated channel.
* Be very careful with the threading associated w/ manipulating
* the channel.
*/
struct ast_channel *channel;
/*!
* When a channel is in a bridge, the bridge that it is in.
*/
struct ast_bridge *bridge;
/*!
* Bridge features which should be applied to the channel when it enters the next bridge. These only apply to the next bridge and will be emptied thereafter.
*/
struct ast_bridge_features *bridge_features;
/*!
* Holding place for channel's PBX while imparted to a bridge.
*/
struct ast_pbx *pbx;
/*!
* A list of rules to check before adding a channel to a bridge.
*/
struct app_control_rules add_rules;
/*!
* A list of rules to check before removing a channel from a bridge.
*/
struct app_control_rules remove_rules;
/*!
* Silence generator, when silence is being generated.
*/
struct ast_silence_generator *silgen;
/*!
* The app for which this control is currently controlling.
* This can change through the use of the /channels/{channelId}/move
* command.
*/
struct stasis_app *app;
/*!
* The name of the next Stasis application to move to.
*/
char *next_app;
/*!
* The list of arguments to pass to StasisStart when moving to another app.
*/
AST_VECTOR(, char *) next_app_args;
/*!
* When set, /c app_stasis should exit and continue in the dialplan.
*/
unsigned int is_done:1;
};
static void control_dtor(void *obj)
{
struct stasis_app_control *control = obj;
ao2_cleanup(control->command_queue);
ast_channel_cleanup(control->channel);
ao2_cleanup(control->app);
control_move_cleanup(control);
ast_cond_destroy(&control->wait_cond);
AST_LIST_HEAD_DESTROY(&control->add_rules);
AST_LIST_HEAD_DESTROY(&control->remove_rules);
ast_bridge_features_destroy(control->bridge_features);
}
struct stasis_app_control *control_create(struct ast_channel *channel, struct stasis_app *app)
{
struct stasis_app_control *control;
int res;
control = ao2_alloc(sizeof(*control), control_dtor);
if (!control) {
return NULL;
}
AST_LIST_HEAD_INIT(&control->add_rules);
AST_LIST_HEAD_INIT(&control->remove_rules);
res = ast_cond_init(&control->wait_cond, NULL);
if (res != 0) {
ast_log(LOG_ERROR, "Error initializing ast_cond_t: %s\n",
strerror(errno));
ao2_ref(control, -1);
return NULL;
}
control->app = ao2_bump(app);
ast_channel_ref(channel);
control->channel = channel;
control->command_queue = ao2_container_alloc_list(
AO2_ALLOC_OPT_LOCK_MUTEX, 0, NULL, NULL);
if (!control->command_queue) {
ao2_ref(control, -1);
return NULL;
}
control->next_app = NULL;
AST_VECTOR_INIT(&control->next_app_args, 0);
return control;
}
static void app_control_register_rule(
struct stasis_app_control *control,
struct app_control_rules *list, struct stasis_app_control_rule *obj)
{
ao2_lock(control->command_queue);
AST_LIST_INSERT_TAIL(list, obj, next);
ao2_unlock(control->command_queue);
}
static void app_control_unregister_rule(
struct stasis_app_control *control,
struct app_control_rules *list, struct stasis_app_control_rule *obj)
{
struct stasis_app_control_rule *rule;
ao2_lock(control->command_queue);
AST_RWLIST_TRAVERSE_SAFE_BEGIN(list, rule, next) {
if (rule == obj) {
AST_RWLIST_REMOVE_CURRENT(next);
break;
}
}
AST_RWLIST_TRAVERSE_SAFE_END;
ao2_unlock(control->command_queue);
}
/*!
* \internal
* \brief Checks to make sure each rule in the given list passes.
*
* \details Loops over a list of rules checking for rejections or failures.
* If one rule fails its resulting error code is returned.
*
* \note Command queue should be locked before calling this function.
*
* \param control The stasis application control
* \param list The list of rules to check
*
* \retval 0 if all rules pass
* \retval non-zero error code if a rule fails
*/
static enum stasis_app_control_channel_result app_control_check_rules(
const struct stasis_app_control *control,
struct app_control_rules *list)
{
int res = 0;
struct stasis_app_control_rule *rule;
AST_LIST_TRAVERSE(list, rule, next) {
if ((res = rule->check_rule(control))) {
return res;
}
}
return res;
}
void stasis_app_control_register_add_rule(
struct stasis_app_control *control,
struct stasis_app_control_rule *rule)
{
return app_control_register_rule(control, &control->add_rules, rule);
}
void stasis_app_control_unregister_add_rule(
struct stasis_app_control *control,
struct stasis_app_control_rule *rule)
{
app_control_unregister_rule(control, &control->add_rules, rule);
}
void stasis_app_control_register_remove_rule(
struct stasis_app_control *control,
struct stasis_app_control_rule *rule)
{
return app_control_register_rule(control, &control->remove_rules, rule);
}
void stasis_app_control_unregister_remove_rule(
struct stasis_app_control *control,
struct stasis_app_control_rule *rule)
{
app_control_unregister_rule(control, &control->remove_rules, rule);
}
static int app_control_can_add_channel_to_bridge(
struct stasis_app_control *control)
{
return app_control_check_rules(control, &control->add_rules);
}
static int app_control_can_remove_channel_from_bridge(
struct stasis_app_control *control)
{
return app_control_check_rules(control, &control->remove_rules);
}
static int noop_cb(struct stasis_app_control *control,
struct ast_channel *chan, void *data)
{
return 0;
}
/*! Callback type to see if the command can execute
note: command_queue is locked during callback */
typedef int (*app_command_can_exec_cb)(struct stasis_app_control *control);
static struct stasis_app_command *exec_command_on_condition(
struct stasis_app_control *control, stasis_app_command_cb command_fn,
void *data, command_data_destructor_fn data_destructor,
app_command_can_exec_cb can_exec_fn)
{
int retval;
struct stasis_app_command *command;
command_fn = command_fn ? : noop_cb;
command = command_create(command_fn, data, data_destructor);
if (!command) {
return NULL;
}
ao2_lock(control->command_queue);
if (control->is_done) {
ao2_unlock(control->command_queue);
ao2_ref(command, -1);
return NULL;
}
if (can_exec_fn && (retval = can_exec_fn(control))) {
ao2_unlock(control->command_queue);
command_complete(command, retval);
return command;
}
ao2_link_flags(control->command_queue, command, OBJ_NOLOCK);
ast_cond_signal(&control->wait_cond);
ao2_unlock(control->command_queue);
return command;
}
static struct stasis_app_command *exec_command(
struct stasis_app_control *control, stasis_app_command_cb command_fn,
void *data, command_data_destructor_fn data_destructor)
{
return exec_command_on_condition(control, command_fn, data, data_destructor, NULL);
}
static int app_control_add_role(struct stasis_app_control *control,
struct ast_channel *chan, void *data)
{
char *role = data;
return ast_channel_add_bridge_role(chan, role);
}
int stasis_app_control_add_role(struct stasis_app_control *control, const char *role)
{
char *role_dup;
role_dup = ast_strdup(role);
if (!role_dup) {
return -1;
}
stasis_app_send_command_async(control, app_control_add_role, role_dup, ast_free_ptr);
return 0;
}
static int app_control_clear_roles(struct stasis_app_control *control,
struct ast_channel *chan, void *data)
{
ast_channel_clear_bridge_roles(chan);
return 0;
}
void stasis_app_control_clear_roles(struct stasis_app_control *control)
{
stasis_app_send_command_async(control, app_control_clear_roles, NULL, NULL);
}
int control_command_count(struct stasis_app_control *control)
{
return ao2_container_count(control->command_queue);
}
int control_is_done(struct stasis_app_control *control)
{
/* Called from stasis_app_exec thread; no lock needed */
return control->is_done;
}
void control_mark_done(struct stasis_app_control *control)
{
/* Locking necessary to sync with other threads adding commands to the queue. */
ao2_lock(control->command_queue);
control->is_done = 1;
ao2_unlock(control->command_queue);
}
struct stasis_app_control_continue_data {
char context[AST_MAX_CONTEXT];
char extension[AST_MAX_EXTENSION];
int priority;
};
static int app_control_continue(struct stasis_app_control *control,
struct ast_channel *chan, void *data)
{
struct stasis_app_control_continue_data *continue_data = data;
ast_assert(control->channel != NULL);
/* If we're in a Stasis bridge, depart it before going back to the
* dialplan */
if (stasis_app_get_bridge(control)) {
ast_bridge_depart(control->channel);
}
/* Called from stasis_app_exec thread; no lock needed */
ast_explicit_goto(control->channel, continue_data->context, continue_data->extension, continue_data->priority);
control_mark_done(control);
return 0;
}
int stasis_app_control_continue(struct stasis_app_control *control, const char *context, const char *extension, int priority)
{
struct stasis_app_control_continue_data *continue_data;
if (!(continue_data = ast_calloc(1, sizeof(*continue_data)))) {
return -1;
}
ast_copy_string(continue_data->context, S_OR(context, ""), sizeof(continue_data->context));
ast_copy_string(continue_data->extension, S_OR(extension, ""), sizeof(continue_data->extension));
if (priority > 0) {
continue_data->priority = priority;
} else {
continue_data->priority = -1;
}
stasis_app_send_command_async(control, app_control_continue, continue_data, ast_free_ptr);
return 0;
}
struct stasis_app_control_move_data {
char *app_name;
char *app_args;
};
static int app_control_move(struct stasis_app_control *control,
struct ast_channel *chan, void *data)
{
struct stasis_app_control_move_data *move_data = data;
control->next_app = ast_strdup(move_data->app_name);
if (!control->next_app) {
ast_log(LOG_ERROR, "Allocation failed for next app\n");
return -1;
}
if (move_data->app_args) {
char *token;
while ((token = strtok_r(move_data->app_args, ",", &move_data->app_args))) {
int res;
char *arg;
if (!(arg = ast_strdup(token))) {
ast_log(LOG_ERROR, "Allocation failed for next app arg\n");
control_move_cleanup(control);
return -1;
}
res = AST_VECTOR_APPEND(&control->next_app_args, arg);
if (res) {
ast_log(LOG_ERROR, "Failed to append arg to next app args\n");
ast_free(arg);
control_move_cleanup(control);
return -1;
}
}
}
return 0;
}
int stasis_app_control_move(struct stasis_app_control *control, const char *app_name, const char *app_args)
{
struct stasis_app_control_move_data *move_data;
size_t size;
size = sizeof(*move_data) + strlen(app_name) + 1;
if (app_args) {
/* Application arguments are optional */
size += strlen(app_args) + 1;
}
if (!(move_data = ast_calloc(1, size))) {
return -1;
}
move_data->app_name = (char *)move_data + sizeof(*move_data);
strcpy(move_data->app_name, app_name); /* Safe */
if (app_args) {
move_data->app_args = move_data->app_name + strlen(app_name) + 1;
strcpy(move_data->app_args, app_args); /* Safe */
} else {
move_data->app_args = NULL;
}
stasis_app_send_command_async(control, app_control_move, move_data, ast_free_ptr);
return 0;
}
static int app_control_redirect(struct stasis_app_control *control,
struct ast_channel *chan, void *data)
{
char *endpoint = data;
int res;
ast_assert(control->channel != NULL);
ast_assert(endpoint != NULL);
res = ast_transfer(control->channel, endpoint);
if (!res) {
ast_log(LOG_NOTICE, "Unsupported transfer requested on channel '%s'\n",
ast_channel_name(control->channel));
return 0;
}
return 0;
}
int stasis_app_control_redirect(struct stasis_app_control *control, const char *endpoint)
{
char *endpoint_data = ast_strdup(endpoint);
if (!endpoint_data) {
return -1;
}
stasis_app_send_command_async(control, app_control_redirect, endpoint_data, ast_free_ptr);
return 0;
}
struct stasis_app_control_dtmf_data {
int before;
int between;
unsigned int duration;
int after;
char dtmf[];
};
static void dtmf_in_bridge(struct ast_channel *chan, struct stasis_app_control_dtmf_data *dtmf_data)
{
if (dtmf_data->before) {
usleep(dtmf_data->before * 1000);
}
ast_dtmf_stream_external(chan, dtmf_data->dtmf, dtmf_data->between, dtmf_data->duration);
if (dtmf_data->after) {
usleep(dtmf_data->after * 1000);
}
}
static void dtmf_no_bridge(struct ast_channel *chan, struct stasis_app_control_dtmf_data *dtmf_data)
{
if (dtmf_data->before) {
ast_safe_sleep(chan, dtmf_data->before);
}
ast_dtmf_stream(chan, NULL, dtmf_data->dtmf, dtmf_data->between, dtmf_data->duration);
if (dtmf_data->after) {
ast_safe_sleep(chan, dtmf_data->after);
}
}
static int app_control_dtmf(struct stasis_app_control *control,
struct ast_channel *chan, void *data)
{
struct stasis_app_control_dtmf_data *dtmf_data = data;
if (ast_channel_state(chan) != AST_STATE_UP) {
ast_indicate(chan, AST_CONTROL_PROGRESS);
}
if (stasis_app_get_bridge(control)) {
dtmf_in_bridge(chan, dtmf_data);
} else {
dtmf_no_bridge(chan, dtmf_data);
}
return 0;
}
int stasis_app_control_dtmf(struct stasis_app_control *control, const char *dtmf, int before, int between, unsigned int duration, int after)
{
struct stasis_app_control_dtmf_data *dtmf_data;
if (!(dtmf_data = ast_calloc(1, sizeof(*dtmf_data) + strlen(dtmf) + 1))) {
return -1;
}
dtmf_data->before = before;
dtmf_data->between = between;
dtmf_data->duration = duration;
dtmf_data->after = after;
strcpy(dtmf_data->dtmf, dtmf);
stasis_app_send_command_async(control, app_control_dtmf, dtmf_data, ast_free_ptr);
return 0;
}
static int app_control_ring(struct stasis_app_control *control,
struct ast_channel *chan, void *data)
{
ast_indicate(control->channel, AST_CONTROL_RINGING);
return 0;
}
int stasis_app_control_ring(struct stasis_app_control *control)
{
stasis_app_send_command_async(control, app_control_ring, NULL, NULL);
return 0;
}
static int app_control_ring_stop(struct stasis_app_control *control,
struct ast_channel *chan, void *data)
{
ast_indicate(control->channel, -1);
return 0;
}
int stasis_app_control_ring_stop(struct stasis_app_control *control)
{
stasis_app_send_command_async(control, app_control_ring_stop, NULL, NULL);
return 0;
}
struct stasis_app_control_mute_data {
enum ast_frame_type frametype;
unsigned int direction;
};
static int app_control_mute(struct stasis_app_control *control,
struct ast_channel *chan, void *data)
{
struct stasis_app_control_mute_data *mute_data = data;
ast_channel_lock(chan);
ast_channel_suppress(control->channel, mute_data->direction, mute_data->frametype);
ast_channel_unlock(chan);
return 0;
}
int stasis_app_control_mute(struct stasis_app_control *control, unsigned int direction, enum ast_frame_type frametype)
{
struct stasis_app_control_mute_data *mute_data;
if (!(mute_data = ast_calloc(1, sizeof(*mute_data)))) {
return -1;
}
mute_data->direction = direction;
mute_data->frametype = frametype;
stasis_app_send_command_async(control, app_control_mute, mute_data, ast_free_ptr);
return 0;
}
static int app_control_unmute(struct stasis_app_control *control,
struct ast_channel *chan, void *data)
{
struct stasis_app_control_mute_data *mute_data = data;
ast_channel_lock(chan);
ast_channel_unsuppress(control->channel, mute_data->direction, mute_data->frametype);
ast_channel_unlock(chan);
return 0;
}
int stasis_app_control_unmute(struct stasis_app_control *control, unsigned int direction, enum ast_frame_type frametype)
{
struct stasis_app_control_mute_data *mute_data;
if (!(mute_data = ast_calloc(1, sizeof(*mute_data)))) {
return -1;
}
mute_data->direction = direction;
mute_data->frametype = frametype;
stasis_app_send_command_async(control, app_control_unmute, mute_data, ast_free_ptr);
return 0;
}
/*!
* \brief structure for queuing ARI channel variable setting
*
* It may seem weird to define this custom structure given that we already have
* ast_var_t and ast_variable defined elsewhere. The problem with those is that
* they are not tolerant of NULL channel variable value pointers. In fact, in both
* cases, the best they could do is to have a zero-length variable value. However,
* when un-setting a channel variable, it is important to pass a NULL value, not
* a zero-length string.
*/
struct chanvar {
/*! Name of variable to set/unset */
char *name;
/*! Value of variable to set. If unsetting, this will be NULL */
char *value;
};
static void free_chanvar(void *data)
{
struct chanvar *var = data;
ast_free(var->name);
ast_free(var->value);
ast_free(var);
}
static int app_control_set_channel_var(struct stasis_app_control *control,
struct ast_channel *chan, void *data)
{
struct chanvar *var = data;
pbx_builtin_setvar_helper(control->channel, var->name, var->value);
return 0;
}
int stasis_app_control_set_channel_var(struct stasis_app_control *control, const char *variable, const char *value)
{
struct chanvar *var;
var = ast_calloc(1, sizeof(*var));
if (!var) {
return -1;
}
var->name = ast_strdup(variable);
if (!var->name) {
free_chanvar(var);
return -1;
}
/* It's kosher for value to be NULL. It means the variable is being unset */
if (value) {
var->value = ast_strdup(value);
if (!var->value) {
free_chanvar(var);
return -1;
}
}
stasis_app_send_command_async(control, app_control_set_channel_var, var, free_chanvar);
return 0;
}
static int app_control_hold(struct stasis_app_control *control,
struct ast_channel *chan, void *data)
{
ast_indicate(control->channel, AST_CONTROL_HOLD);
return 0;
}
void stasis_app_control_hold(struct stasis_app_control *control)
{
stasis_app_send_command_async(control, app_control_hold, NULL, NULL);
}
static int app_control_unhold(struct stasis_app_control *control,
struct ast_channel *chan, void *data)
{
ast_indicate(control->channel, AST_CONTROL_UNHOLD);
return 0;
}
void stasis_app_control_unhold(struct stasis_app_control *control)
{
stasis_app_send_command_async(control, app_control_unhold, NULL, NULL);
}
static int app_control_moh_start(struct stasis_app_control *control,
struct ast_channel *chan, void *data)
{
char *moh_class = data;
if (ast_channel_state(chan) != AST_STATE_UP) {
ast_indicate(chan, AST_CONTROL_PROGRESS);
}
ast_moh_start(chan, moh_class, NULL);
return 0;
}
void stasis_app_control_moh_start(struct stasis_app_control *control, const char *moh_class)
{
char *data = NULL;
if (!ast_strlen_zero(moh_class)) {
data = ast_strdup(moh_class);
}
stasis_app_send_command_async(control, app_control_moh_start, data, ast_free_ptr);
}
static int app_control_moh_stop(struct stasis_app_control *control,
struct ast_channel *chan, void *data)
{
ast_moh_stop(chan);
return 0;
}
void stasis_app_control_moh_stop(struct stasis_app_control *control)
{
stasis_app_send_command_async(control, app_control_moh_stop, NULL, NULL);
}
static int app_control_silence_start(struct stasis_app_control *control,
struct ast_channel *chan, void *data)
{
if (ast_channel_state(chan) != AST_STATE_UP) {
ast_indicate(chan, AST_CONTROL_PROGRESS);
}
if (control->silgen) {
/* We have a silence generator, but it may have been implicitly
* disabled by media actions (music on hold, playing media,
* etc.) Just stop it and restart a new one.
*/
ast_channel_stop_silence_generator(
control->channel, control->silgen);
}
ast_debug(3, "%s: Starting silence generator\n",
stasis_app_control_get_channel_id(control));
control->silgen = ast_channel_start_silence_generator(control->channel);
if (!control->silgen) {
ast_log(LOG_WARNING,
"%s: Failed to start silence generator.\n",
stasis_app_control_get_channel_id(control));
}
return 0;
}
void stasis_app_control_silence_start(struct stasis_app_control *control)
{
stasis_app_send_command_async(control, app_control_silence_start, NULL, NULL);
}
void control_silence_stop_now(struct stasis_app_control *control)
{
if (control->silgen) {
ast_debug(3, "%s: Stopping silence generator\n",
stasis_app_control_get_channel_id(control));
ast_channel_stop_silence_generator(
control->channel, control->silgen);
control->silgen = NULL;
}
}
static int app_control_silence_stop(struct stasis_app_control *control,
struct ast_channel *chan, void *data)
{
control_silence_stop_now(control);
return 0;
}
void stasis_app_control_silence_stop(struct stasis_app_control *control)
{
stasis_app_send_command_async(control, app_control_silence_stop, NULL, NULL);
}
struct ast_channel_snapshot *stasis_app_control_get_snapshot(
const struct stasis_app_control *control)
{
return ast_channel_snapshot_get_latest(stasis_app_control_get_channel_id(control));
}
static int app_send_command_on_condition(struct stasis_app_control *control,
stasis_app_command_cb command_fn, void *data,
command_data_destructor_fn data_destructor,
app_command_can_exec_cb can_exec_fn)
{
int ret;
struct stasis_app_command *command;
if (control == NULL || control->is_done) {
/* If exec_command_on_condition fails, it calls the data_destructor.
* In order to provide consistent behavior, we'll also call the data_destructor
* on this error path. This way, callers never have to call the
* data_destructor themselves.
*/
if (data_destructor) {
data_destructor(data);
}
return -1;
}
command = exec_command_on_condition(
control, command_fn, data, data_destructor, can_exec_fn);
if (!command) {
return -1;
}
ret = command_join(command);
ao2_ref(command, -1);
return ret;
}
int stasis_app_send_command(struct stasis_app_control *control,
stasis_app_command_cb command_fn, void *data, command_data_destructor_fn data_destructor)
{
return app_send_command_on_condition(control, command_fn, data, data_destructor, NULL);
}
int stasis_app_send_command_async(struct stasis_app_control *control,
stasis_app_command_cb command_fn, void *data,
command_data_destructor_fn data_destructor)
{
struct stasis_app_command *command;
if (control == NULL || control->is_done) {
/* If exec_command fails, it calls the data_destructor. In order to
* provide consistent behavior, we'll also call the data_destructor
* on this error path. This way, callers never have to call the
* data_destructor themselves.
*/
if (data_destructor) {
data_destructor(data);
}
return -1;
}
command = exec_command(control, command_fn, data, data_destructor);
if (!command) {
return -1;
}
ao2_ref(command, -1);
return 0;
}
struct ast_bridge *stasis_app_get_bridge(struct stasis_app_control *control)
{
struct ast_bridge *ret;
if (!control) {
return NULL;
}
ao2_lock(control);
ret = control->bridge;
ao2_unlock(control);
return ret;
}
/*!
* \brief Singleton dial bridge
*
* The dial bridge is a holding bridge used to hold all
* outbound dialed channels that are not in any "real" ARI-created
* bridge. The dial bridge is invisible, meaning that it does not
* show up in channel snapshots, AMI or ARI output, and no events
* get raised for it.
*
* This is used to keep dialed channels confined to the bridging system
* and unify the threading model used for dialing outbound channels.
*/
static struct ast_bridge *dial_bridge;
AST_MUTEX_DEFINE_STATIC(dial_bridge_lock);
/*!
* \brief Retrieve a reference to the dial bridge.
*
* If the dial bridge has not been created yet, it will
* be created, otherwise, a reference to the existing bridge
* will be returned.
*
* The caller will need to unreference the dial bridge once
* they are finished with it.
*
* \retval NULL Unable to find/create the dial bridge
* \retval non-NULL A reference to the dial bridge
*/
static struct ast_bridge *get_dial_bridge(void)
{
struct ast_bridge *ret_bridge = NULL;
ast_mutex_lock(&dial_bridge_lock);
if (shutting_down) {
goto end;
}
if (dial_bridge) {
ret_bridge = ao2_bump(dial_bridge);
goto end;
}
dial_bridge = stasis_app_bridge_create_invisible("holding", "dial_bridge", NULL);
if (!dial_bridge) {
goto end;
}
ret_bridge = ao2_bump(dial_bridge);
end:
ast_mutex_unlock(&dial_bridge_lock);
return ret_bridge;
}
static int bridge_channel_depart(struct stasis_app_control *control,
struct ast_channel *chan, void *data);
/*!
* \brief after bridge callback for the dial bridge
*
* The only purpose of this callback is to ensure that the control structure's
* bridge pointer is NULLed
*/
static void dial_bridge_after_cb(struct ast_channel *chan, void *data)
{
struct stasis_app_control *control = data;
struct ast_bridge_channel *bridge_channel;
ast_channel_lock(chan);
bridge_channel = ast_channel_get_bridge_channel(chan);
ast_channel_unlock(chan);
ast_debug(3, "Channel: <%s> Reason: %d\n", ast_channel_name(control->channel), ast_channel_hangupcause(chan));
stasis_app_send_command_async(control, bridge_channel_depart, bridge_channel, __ao2_cleanup);
control->bridge = NULL;
}
static void dial_bridge_after_cb_failed(enum ast_bridge_after_cb_reason reason, void *data)
{
struct stasis_app_control *control = data;
ast_debug(3, "Channel: <%s> Reason: %d\n", ast_channel_name(control->channel), reason);
dial_bridge_after_cb(control->channel, data);
}
/*!
* \brief Add a channel to the singleton dial bridge.
*
* \param control The Stasis control structure
* \param chan The channel to add to the bridge
* \retval -1 Failed
* \retval 0 Success
*/
static int add_to_dial_bridge(struct stasis_app_control *control, struct ast_channel *chan)
{
struct ast_bridge *bridge;
bridge = get_dial_bridge();
if (!bridge) {
return -1;
}
control->bridge = bridge;
ast_bridge_set_after_callback(chan, dial_bridge_after_cb, dial_bridge_after_cb_failed, control);
if (ast_bridge_impart(bridge, chan, NULL, NULL, AST_BRIDGE_IMPART_CHAN_DEPARTABLE)) {
control->bridge = NULL;
ao2_ref(bridge, -1);
return -1;
}
ao2_ref(bridge, -1);
return 0;
}
/*!
* \brief Depart a channel from a bridge, and potentially add it back to the dial bridge
*
* \param control Take a guess
* \param chan Take another guess
*/
static int depart_channel(struct stasis_app_control *control, struct ast_channel *chan)
{
ast_bridge_depart(chan);
/* Channels which have a PBX are not ones that have been created and dialed from ARI. They
* have externally come in from the dialplan, and thus should not be placed into the dial
* bridge. Only channels which are created and dialed in ARI should go into the dial bridge.
*/
if (!ast_check_hangup(chan) && ast_channel_state(chan) != AST_STATE_UP && !ast_channel_pbx(chan)) {
/* Channel is still being dialed, so put it back in the dialing bridge */
add_to_dial_bridge(control, chan);
}
return 0;
}
static int bridge_channel_depart(struct stasis_app_control *control,
struct ast_channel *chan, void *data)
{
struct ast_bridge_channel *bridge_channel;
ast_channel_lock(chan);
bridge_channel = ast_channel_internal_bridge_channel(chan);
ast_channel_unlock(chan);
if (bridge_channel != data) {
ast_debug(3, "%s: Channel is no longer in departable state\n",
ast_channel_uniqueid(chan));
return -1;
}
ast_debug(3, "%s: Channel departing bridge\n",
ast_channel_uniqueid(chan));
depart_channel(control, chan);
return 0;
}
static void internal_bridge_after_cb(struct ast_channel *chan, void *data,
enum ast_bridge_after_cb_reason reason)
{
struct stasis_app_control *control = data;
struct ast_bridge_channel *bridge_channel;
ao2_lock(control);
ast_debug(3, "%s, %s: %s\n",
ast_channel_uniqueid(chan), control->bridge ? control->bridge->uniqueid : "unknown",
ast_bridge_after_cb_reason_string(reason));
if (reason == AST_BRIDGE_AFTER_CB_REASON_IMPART_FAILED) {
/* The impart actually failed so control->bridge isn't valid. */
control->bridge = NULL;
}
ast_assert(chan == control->channel);
/* Restore the channel's PBX */
ast_channel_pbx_set(control->channel, control->pbx);
control->pbx = NULL;
if (control->bridge) {
app_unsubscribe_bridge(control->app, control->bridge);
/* No longer in the bridge */
control->bridge = NULL;
/* Get the bridge channel so we don't depart from the wrong bridge */
ast_channel_lock(chan);
bridge_channel = ast_channel_get_bridge_channel(chan);
ast_channel_unlock(chan);
/* Depart this channel from the bridge using the command queue if possible */
stasis_app_send_command_async(control, bridge_channel_depart, bridge_channel, __ao2_cleanup);
}
if (stasis_app_channel_is_stasis_end_published(chan)) {
/* The channel has had a StasisEnd published on it, but until now had remained in
* the bridging system. This means that the channel moved from a Stasis bridge to a
* non-Stasis bridge and is now exiting the bridging system. Because of this, the
* channel needs to exit the Stasis application and go to wherever the non-Stasis
* bridge has directed it to go. If the non-Stasis bridge has not set up an after
* bridge destination, then the channel should be hung up.
*/
int hangup_flag;
hangup_flag = ast_bridge_setup_after_goto(chan) ? AST_SOFTHANGUP_DEV : AST_SOFTHANGUP_ASYNCGOTO;
ast_channel_lock(chan);
ast_softhangup_nolock(chan, hangup_flag);
ast_channel_unlock(chan);
}
ao2_unlock(control);
}
static void bridge_after_cb(struct ast_channel *chan, void *data)
{
struct stasis_app_control *control = data;
internal_bridge_after_cb(control->channel, data, AST_BRIDGE_AFTER_CB_REASON_DEPART);
}
static void bridge_after_cb_failed(enum ast_bridge_after_cb_reason reason,
void *data)
{
struct stasis_app_control *control = data;
internal_bridge_after_cb(control->channel, data, reason);
ast_debug(3, " reason: %s\n",
ast_bridge_after_cb_reason_string(reason));
}
/*!
* \brief Dial timeout datastore
*
* A datastore is used because a channel may change
* bridges during the course of a dial attempt. This
* may be because the channel changes from the dial bridge
* to a standard bridge, or it may move between standard
* bridges. In order to keep the dial timeout, we need
* to keep the timeout information local to the channel.
* That is what this datastore is for
*/
struct ast_datastore_info timeout_datastore = {
.type = "ARI dial timeout",
};
static int hangup_channel(struct stasis_app_control *control,
struct ast_channel *chan, void *data)
{
ast_softhangup(chan, AST_SOFTHANGUP_EXPLICIT);
return 0;
}
/*!
* \brief Dial timeout
*
* This is a bridge interval hook callback. The interval hook triggering
* means that the dial timeout has been reached. If the channel has not
* been answered by the time this callback is called, then the channel
* is hung up
*
* \param bridge_channel Bridge channel on which interval hook has been called
* \param ignore Ignored
* \return -1 (i.e. remove the interval hook)
*/
static int bridge_timeout(struct ast_bridge_channel *bridge_channel, void *ignore)
{
struct ast_datastore *datastore;
RAII_VAR(struct stasis_app_control *, control, NULL, ao2_cleanup);
control = stasis_app_control_find_by_channel(bridge_channel->chan);
ast_channel_lock(bridge_channel->chan);
if (ast_channel_state(bridge_channel->chan) != AST_STATE_UP) {
/* Don't bother removing the datastore because it will happen when the channel is hung up */
ast_channel_unlock(bridge_channel->chan);
stasis_app_send_command_async(control, hangup_channel, NULL, NULL);
return -1;
}
datastore = ast_channel_datastore_find(bridge_channel->chan, &timeout_datastore, NULL);
if (!datastore) {
ast_channel_unlock(bridge_channel->chan);
return -1;
}
ast_channel_datastore_remove(bridge_channel->chan, datastore);
ast_channel_unlock(bridge_channel->chan);
ast_datastore_free(datastore);
return -1;
}
/*!
* \brief Set a dial timeout interval hook on the channel.
*
* The absolute time that the timeout should occur is stored on
* a datastore on the channel. This time is converted into a relative
* number of milliseconds in the future. Then an interval hook is set
* to trigger in that number of milliseconds.
*
* \pre chan is locked
*
* \param chan The channel on which to set the interval hook
*/
static void set_interval_hook(struct ast_channel *chan)
{
struct ast_datastore *datastore;
struct timeval *hangup_time;
int64_t ms;
struct ast_bridge_channel *bridge_channel;
datastore = ast_channel_datastore_find(chan, &timeout_datastore, NULL);
if (!datastore) {
return;
}
hangup_time = datastore->data;
ms = ast_tvdiff_ms(*hangup_time, ast_tvnow());
bridge_channel = ast_channel_get_bridge_channel(chan);
if (!bridge_channel) {
return;
}
if (ast_bridge_interval_hook(bridge_channel->features, 0, ms > 0 ? ms : 1,
bridge_timeout, NULL, NULL, 0)) {
ao2_ref(bridge_channel, -1);
return;
}
ast_queue_frame(bridge_channel->chan, &ast_null_frame);
ao2_ref(bridge_channel, -1);
}
int control_swap_channel_in_bridge(struct stasis_app_control *control, struct ast_bridge *bridge, struct ast_channel *chan, struct ast_channel *swap)
{
int res;
struct ast_bridge_features *features;
int flags = AST_BRIDGE_IMPART_CHAN_DEPARTABLE;
if (!control || !bridge) {
return -1;
}
ast_debug(3, "%s: Adding to bridge %s\n",
stasis_app_control_get_channel_id(control),
bridge->uniqueid);
ast_assert(chan != NULL);
/* Depart whatever Stasis bridge we're currently in. */
if (stasis_app_get_bridge(control)) {
/* Note that it looks like there's a race condition here, since
* we don't have control locked. But this happens from the
* control callback thread, so there won't be any other
* concurrent attempts to bridge.
*/
ast_bridge_depart(chan);
}
res = ast_bridge_set_after_callback(chan, bridge_after_cb,
bridge_after_cb_failed, control);
if (res != 0) {
ast_log(LOG_ERROR, "Error setting after-bridge callback\n");
return -1;
}
ao2_lock(control);
/* Ensure the controlling application is subscribed early enough
* to receive the ChannelEnteredBridge message. This works in concert
* with the subscription handled in the Stasis application execution
* loop */
app_subscribe_bridge(control->app, bridge);
/* Save off the channel's PBX */
ast_assert(control->pbx == NULL);
if (!control->pbx) {
control->pbx = ast_channel_pbx(chan);
ast_channel_pbx_set(chan, NULL);
}
/* Pull bridge features from the control */
features = control->bridge_features;
control->bridge_features = NULL;
if (features && features->inhibit_colp) {
flags |= AST_BRIDGE_IMPART_INHIBIT_JOIN_COLP;
}
ast_assert(stasis_app_get_bridge(control) == NULL);
/* We need to set control->bridge here since bridge_after_cb may be run
* before ast_bridge_impart returns. bridge_after_cb gets a reason
* code so it can tell if the bridge is actually valid or not.
*/
control->bridge = bridge;
/* We can't be holding the control lock while impart is running
* or we could create a deadlock with bridge_after_cb which also
* tries to lock control.
*/
ao2_unlock(control);
res = ast_bridge_impart(bridge,
chan,
swap,
features, /* features */
flags);
if (res != 0) {
/* ast_bridge_impart failed before it could spawn the depart
* thread. The callbacks aren't called in this case.
* The impart could still fail even if ast_bridge_impart returned
* ok but that's handled by bridge_after_cb.
*/
ast_log(LOG_ERROR, "Error adding channel to bridge\n");
ao2_lock(control);
ast_channel_pbx_set(chan, control->pbx);
control->pbx = NULL;
control->bridge = NULL;
ao2_unlock(control);
} else {
ast_channel_lock(chan);
set_interval_hook(chan);
ast_channel_unlock(chan);
}
return res;
}
int control_add_channel_to_bridge(struct stasis_app_control *control, struct ast_channel *chan, void *data)
{
return control_swap_channel_in_bridge(control, data, chan, NULL);
}
int stasis_app_control_add_channel_to_bridge(
struct stasis_app_control *control, struct ast_bridge *bridge)
{
ast_debug(3, "%s: Sending channel add_to_bridge command\n",
stasis_app_control_get_channel_id(control));
return app_send_command_on_condition(
control, control_add_channel_to_bridge, bridge, NULL,
app_control_can_add_channel_to_bridge);
}
static int app_control_remove_channel_from_bridge(
struct stasis_app_control *control,
struct ast_channel *chan, void *data)
{
struct ast_bridge *bridge = data;
if (!control) {
return -1;
}
/* We should only depart from our own bridge */
ast_debug(3, "%s: Departing bridge %s\n",
stasis_app_control_get_channel_id(control),
bridge->uniqueid);
if (bridge != stasis_app_get_bridge(control)) {
ast_log(LOG_WARNING, "%s: Not in bridge %s; not removing\n",
stasis_app_control_get_channel_id(control),
bridge->uniqueid);
return -1;
}
depart_channel(control, chan);
return 0;
}
int stasis_app_control_remove_channel_from_bridge(
struct stasis_app_control *control, struct ast_bridge *bridge)
{
ast_debug(3, "%s: Sending channel remove_from_bridge command\n",
stasis_app_control_get_channel_id(control));
return app_send_command_on_condition(
control, app_control_remove_channel_from_bridge, bridge, NULL,
app_control_can_remove_channel_from_bridge);
}
const char *stasis_app_control_get_channel_id(
const struct stasis_app_control *control)
{
return ast_channel_uniqueid(control->channel);
}
void stasis_app_control_publish(
struct stasis_app_control *control, struct stasis_message *message)
{
if (!control || !control->channel || !message) {
return;
}
stasis_publish(ast_channel_topic(control->channel), message);
}
int stasis_app_control_queue_control(struct stasis_app_control *control,
enum ast_control_frame_type frame_type)
{
return ast_queue_control(control->channel, frame_type);
}
int stasis_app_control_bridge_features_init(
struct stasis_app_control *control)
{
struct ast_bridge_features *features;
features = ast_bridge_features_new();
if (!features) {
return 1;
}
control->bridge_features = features;
return 0;
}
void stasis_app_control_absorb_dtmf_in_bridge(
struct stasis_app_control *control, int absorb)
{
control->bridge_features->dtmf_passthrough = !absorb;
}
void stasis_app_control_mute_in_bridge(
struct stasis_app_control *control, int mute)
{
control->bridge_features->mute = mute;
}
void stasis_app_control_inhibit_colp_in_bridge(
struct stasis_app_control *control, int inhibit_colp)
{
control->bridge_features->inhibit_colp = inhibit_colp;
}
void control_flush_queue(struct stasis_app_control *control)
{
struct ao2_iterator iter;
struct stasis_app_command *command;
iter = ao2_iterator_init(control->command_queue, AO2_ITERATOR_UNLINK);
while ((command = ao2_iterator_next(&iter))) {
command_complete(command, -1);
ao2_ref(command, -1);
}
ao2_iterator_destroy(&iter);
}
int control_dispatch_all(struct stasis_app_control *control,
struct ast_channel *chan)
{
int count = 0;
struct ao2_iterator iter;
struct stasis_app_command *command;
ast_assert(control->channel == chan);
iter = ao2_iterator_init(control->command_queue, AO2_ITERATOR_UNLINK);
while ((command = ao2_iterator_next(&iter))) {
command_invoke(command, control, chan);
ao2_ref(command, -1);
++count;
}
ao2_iterator_destroy(&iter);
return count;
}
void control_wait(struct stasis_app_control *control)
{
if (!control) {
return;
}
ast_assert(control->command_queue != NULL);
ao2_lock(control->command_queue);
while (ao2_container_count(control->command_queue) == 0) {
int res = ast_cond_wait(&control->wait_cond,
ao2_object_get_lockaddr(control->command_queue));
if (res < 0) {
ast_log(LOG_ERROR, "Error waiting on command queue\n");
break;
}
}
ao2_unlock(control->command_queue);
}
int control_prestart_dispatch_all(struct stasis_app_control *control,
struct ast_channel *chan)
{
struct ao2_container *command_queue;
int count = 0;
struct ao2_iterator iter;
struct stasis_app_command *command;
ast_channel_lock(chan);
command_queue = command_prestart_get_container(chan);
ast_channel_unlock(chan);
if (!command_queue) {
return 0;
}
iter = ao2_iterator_init(command_queue, AO2_ITERATOR_UNLINK);
while ((command = ao2_iterator_next(&iter))) {
command_invoke(command, control, chan);
ao2_cleanup(command);
++count;
}
ao2_iterator_destroy(&iter);
ao2_cleanup(command_queue);
return count;
}
struct stasis_app *control_app(struct stasis_app_control *control)
{
return control->app;
}
struct control_dial_args {
unsigned int timeout;
char dialstring[0];
};
static struct control_dial_args *control_dial_args_alloc(const char *dialstring,
unsigned int timeout)
{
struct control_dial_args *args;
args = ast_malloc(sizeof(*args) + strlen(dialstring) + 1);
if (!args) {
return NULL;
}
args->timeout = timeout;
/* Safe */
strcpy(args->dialstring, dialstring);
return args;
}
static void control_dial_args_destroy(void *data)
{
struct control_dial_args *args = data;
ast_free(args);
}
/*!
* \brief Set dial timeout on a channel to be dialed.
*
* \param chan The channel on which to set the dial timeout
* \param timeout The timeout in seconds
*/
static int set_timeout(struct ast_channel *chan, unsigned int timeout)
{
struct ast_datastore *datastore;
struct timeval *hangup_time;
hangup_time = ast_malloc(sizeof(struct timeval));
datastore = ast_datastore_alloc(&timeout_datastore, NULL);
if (!datastore) {
return -1;
}
*hangup_time = ast_tvadd(ast_tvnow(), ast_samp2tv(timeout, 1));
datastore->data = hangup_time;
ast_channel_lock(chan);
ast_channel_datastore_add(chan, datastore);
if (ast_channel_is_bridged(chan)) {
set_interval_hook(chan);
}
ast_channel_unlock(chan);
return 0;
}
static int app_control_dial(struct stasis_app_control *control,
struct ast_channel *chan, void *data)
{
struct control_dial_args *args = data;
int bridged;
ast_channel_lock(chan);
bridged = ast_channel_is_bridged(chan);
ast_channel_unlock(chan);
if (!bridged && add_to_dial_bridge(control, chan)) {
return -1;
}
if (args->timeout && set_timeout(chan, args->timeout)) {
return -1;
}
if (ast_call(chan, args->dialstring, 0)) {
/* If call fails normally this channel would then just be normally hung up and destroyed.
* In this case though the channel is being handled by the ARI control thread and dial
* bridge which needs to be notified that the channel should be hung up. To do this we
* queue a soft hangup which will cause each to wake up, see that the channel has been
* hung up, and then destroy it.
*/
int hangup_flag;
hangup_flag = ast_bridge_setup_after_goto(chan) ? AST_SOFTHANGUP_DEV : AST_SOFTHANGUP_ASYNCGOTO;
ast_channel_lock(chan);
ast_softhangup_nolock(chan, hangup_flag);
ast_channel_unlock(chan);
return -1;
}
ast_channel_publish_dial(NULL, chan, args->dialstring, NULL);
return 0;
}
int stasis_app_control_dial(struct stasis_app_control *control,
const char *dialstring, unsigned int timeout)
{
struct control_dial_args *args;
args = control_dial_args_alloc(dialstring, timeout);
if (!args) {
return -1;
}
return stasis_app_send_command_async(control, app_control_dial,
args, control_dial_args_destroy);
}
void stasis_app_control_shutdown(void)
{
ast_mutex_lock(&dial_bridge_lock);
shutting_down = 1;
if (dial_bridge) {
ast_bridge_destroy(dial_bridge, 0);
dial_bridge = NULL;
}
ast_mutex_unlock(&dial_bridge_lock);
}
void control_set_app(struct stasis_app_control *control, struct stasis_app *app)
{
ao2_cleanup(control->app);
control->app = ao2_bump(app);
}
char *control_next_app(struct stasis_app_control *control)
{
return control->next_app;
}
void control_move_cleanup(struct stasis_app_control *control)
{
ast_free(control->next_app);
control->next_app = NULL;
AST_VECTOR_RESET(&control->next_app_args, ast_free_ptr);
}
char **control_next_app_args(struct stasis_app_control *control)
{
return AST_VECTOR_STEAL_ELEMENTS(&control->next_app_args);
}
int control_next_app_args_size(struct stasis_app_control *control)
{
return AST_VECTOR_SIZE(&control->next_app_args);
}