asterisk/main/taskprocessor.c

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2023-05-25 18:45:57 +00:00
/*
* Asterisk -- An open source telephony toolkit.
*
* Copyright (C) 2007-2013, Digium, Inc.
*
* Dwayne M. Hubbard <dhubbard@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 Maintain a container of uniquely-named taskprocessor threads that can be shared across modules.
*
* \author Dwayne Hubbard <dhubbard@digium.com>
*/
/*** MODULEINFO
<support_level>core</support_level>
***/
#include "asterisk.h"
#include "asterisk/_private.h"
#include "asterisk/module.h"
#include "asterisk/time.h"
#include "asterisk/astobj2.h"
#include "asterisk/cli.h"
#include "asterisk/taskprocessor.h"
#include "asterisk/sem.h"
/*!
* \brief tps_task structure is queued to a taskprocessor
*
* tps_tasks are processed in FIFO order and freed by the taskprocessing
* thread after the task handler returns. The callback function that is assigned
* to the execute() function pointer is responsible for releasing datap resources if necessary.
*/
struct tps_task {
/*! \brief The execute() task callback function pointer */
union {
int (*execute)(void *datap);
int (*execute_local)(struct ast_taskprocessor_local *local);
} callback;
/*! \brief The data pointer for the task execute() function */
void *datap;
/*! \brief AST_LIST_ENTRY overhead */
AST_LIST_ENTRY(tps_task) list;
unsigned int wants_local:1;
};
/*! \brief tps_taskprocessor_stats maintain statistics for a taskprocessor. */
struct tps_taskprocessor_stats {
/*! \brief This is the maximum number of tasks queued at any one time */
unsigned long max_qsize;
/*! \brief This is the current number of tasks processed */
unsigned long _tasks_processed_count;
};
/*! \brief A ast_taskprocessor structure is a singleton by name */
struct ast_taskprocessor {
/*! \brief Taskprocessor statistics */
struct tps_taskprocessor_stats stats;
void *local_data;
/*! \brief Taskprocessor current queue size */
long tps_queue_size;
/*! \brief Taskprocessor low water clear alert level */
long tps_queue_low;
/*! \brief Taskprocessor high water alert trigger level */
long tps_queue_high;
/*! \brief Taskprocessor queue */
AST_LIST_HEAD_NOLOCK(tps_queue, tps_task) tps_queue;
struct ast_taskprocessor_listener *listener;
/*! Current thread executing the tasks */
pthread_t thread;
/*! Indicates if the taskprocessor is currently executing a task */
unsigned int executing:1;
/*! Indicates that a high water warning has been issued on this task processor */
unsigned int high_water_warned:1;
/*! Indicates that a high water alert is active on this taskprocessor */
unsigned int high_water_alert:1;
/*! Indicates if the taskprocessor is currently suspended */
unsigned int suspended:1;
/*! \brief Anything before the first '/' in the name (if there is one) */
char *subsystem;
/*! \brief Friendly name of the taskprocessor.
* Subsystem is appended after the name's NULL terminator.
*/
char name[0];
};
/*!
* \brief A listener for taskprocessors
*
* \since 12.0.0
*
* When a taskprocessor's state changes, the listener
* is notified of the change. This allows for tasks
* to be addressed in whatever way is appropriate for
* the module using the taskprocessor.
*/
struct ast_taskprocessor_listener {
/*! The callbacks the taskprocessor calls into to notify of state changes */
const struct ast_taskprocessor_listener_callbacks *callbacks;
/*! The taskprocessor that the listener is listening to */
struct ast_taskprocessor *tps;
/*! Data private to the listener */
void *user_data;
};
/*!
* Keep track of which subsystems are in alert
* and how many of their taskprocessors are overloaded.
*/
struct subsystem_alert {
unsigned int alert_count;
char subsystem[0];
};
static AST_VECTOR_RW(subsystem_alert_vector, struct subsystem_alert *) overloaded_subsystems;
#ifdef LOW_MEMORY
#define TPS_MAX_BUCKETS 61
#else
/*! \brief Number of buckets in the tps_singletons container. */
#define TPS_MAX_BUCKETS 1567
#endif
/*! \brief tps_singletons is the astobj2 container for taskprocessor singletons */
static struct ao2_container *tps_singletons;
/*! \brief CLI <example>taskprocessor ping &lt;blah&gt;</example> operation requires a ping condition */
static ast_cond_t cli_ping_cond;
/*! \brief CLI <example>taskprocessor ping &lt;blah&gt;</example> operation requires a ping condition lock */
AST_MUTEX_DEFINE_STATIC(cli_ping_cond_lock);
/*! \brief The astobj2 hash callback for taskprocessors */
static int tps_hash_cb(const void *obj, const int flags);
/*! \brief The astobj2 compare callback for taskprocessors */
static int tps_cmp_cb(void *obj, void *arg, int flags);
/*! \brief CLI <example>taskprocessor ping &lt;blah&gt;</example> handler function */
static int tps_ping_handler(void *datap);
static char *cli_tps_ping(struct ast_cli_entry *e, int cmd, struct ast_cli_args *a);
static char *cli_tps_report(struct ast_cli_entry *e, int cmd, struct ast_cli_args *a);
static char *cli_subsystem_alert_report(struct ast_cli_entry *e, int cmd, struct ast_cli_args *a);
static char *cli_tps_reset_stats(struct ast_cli_entry *e, int cmd, struct ast_cli_args *a);
static char *cli_tps_reset_stats_all(struct ast_cli_entry *e, int cmd, struct ast_cli_args *a);
static int tps_sort_cb(const void *obj_left, const void *obj_right, int flags);
static struct ast_cli_entry taskprocessor_clis[] = {
AST_CLI_DEFINE(cli_tps_ping, "Ping a named task processor"),
AST_CLI_DEFINE(cli_tps_report, "List instantiated task processors and statistics"),
AST_CLI_DEFINE(cli_subsystem_alert_report, "List task processor subsystems in alert"),
AST_CLI_DEFINE(cli_tps_reset_stats, "Reset a named task processor's stats"),
AST_CLI_DEFINE(cli_tps_reset_stats_all, "Reset all task processors' stats"),
};
struct default_taskprocessor_listener_pvt {
pthread_t poll_thread;
int dead;
struct ast_sem sem;
};
static void default_listener_pvt_destroy(struct default_taskprocessor_listener_pvt *pvt)
{
ast_assert(pvt->dead);
ast_sem_destroy(&pvt->sem);
ast_free(pvt);
}
static void default_listener_pvt_dtor(struct ast_taskprocessor_listener *listener)
{
struct default_taskprocessor_listener_pvt *pvt = listener->user_data;
default_listener_pvt_destroy(pvt);
listener->user_data = NULL;
}
/*!
* \brief Function that processes tasks in the taskprocessor
* \internal
*/
static void *default_tps_processing_function(void *data)
{
struct ast_taskprocessor_listener *listener = data;
struct ast_taskprocessor *tps = listener->tps;
struct default_taskprocessor_listener_pvt *pvt = listener->user_data;
int sem_value;
int res;
while (!pvt->dead) {
res = ast_sem_wait(&pvt->sem);
if (res != 0 && errno != EINTR) {
ast_log(LOG_ERROR, "ast_sem_wait(): %s\n",
strerror(errno));
/* Just give up */
break;
}
ast_taskprocessor_execute(tps);
}
/* No posting to a dead taskprocessor! */
res = ast_sem_getvalue(&pvt->sem, &sem_value);
ast_assert(res == 0 && sem_value == 0);
/* Free the shutdown reference (see default_listener_shutdown) */
ao2_t_ref(listener->tps, -1, "tps-shutdown");
return NULL;
}
static int default_listener_start(struct ast_taskprocessor_listener *listener)
{
struct default_taskprocessor_listener_pvt *pvt = listener->user_data;
if (ast_pthread_create(&pvt->poll_thread, NULL, default_tps_processing_function, listener)) {
return -1;
}
return 0;
}
static void default_task_pushed(struct ast_taskprocessor_listener *listener, int was_empty)
{
struct default_taskprocessor_listener_pvt *pvt = listener->user_data;
if (ast_sem_post(&pvt->sem) != 0) {
ast_log(LOG_ERROR, "Failed to notify of enqueued task: %s\n",
strerror(errno));
}
}
static int default_listener_die(void *data)
{
struct default_taskprocessor_listener_pvt *pvt = data;
pvt->dead = 1;
return 0;
}
static void default_listener_shutdown(struct ast_taskprocessor_listener *listener)
{
struct default_taskprocessor_listener_pvt *pvt = listener->user_data;
int res;
/* Hold a reference during shutdown */
ao2_t_ref(listener->tps, +1, "tps-shutdown");
if (ast_taskprocessor_push(listener->tps, default_listener_die, pvt)) {
/* This will cause the thread to exit early without completing tasks already
* in the queue. This is probably the least bad option in this situation. */
default_listener_die(pvt);
}
ast_assert(pvt->poll_thread != AST_PTHREADT_NULL);
if (pthread_equal(pthread_self(), pvt->poll_thread)) {
res = pthread_detach(pvt->poll_thread);
if (res != 0) {
ast_log(LOG_ERROR, "pthread_detach(): %s\n", strerror(errno));
}
} else {
res = pthread_join(pvt->poll_thread, NULL);
if (res != 0) {
ast_log(LOG_ERROR, "pthread_join(): %s\n", strerror(errno));
}
}
pvt->poll_thread = AST_PTHREADT_NULL;
}
static const struct ast_taskprocessor_listener_callbacks default_listener_callbacks = {
.start = default_listener_start,
.task_pushed = default_task_pushed,
.shutdown = default_listener_shutdown,
.dtor = default_listener_pvt_dtor,
};
/*! \brief How many seconds to wait for running taskprocessors to finish on shutdown. */
#define AST_TASKPROCESSOR_SHUTDOWN_MAX_WAIT 10
/*!
* \internal
* \brief Clean up resources on Asterisk shutdown
*/
static void tps_shutdown(void)
{
int objcount;
int tries;
struct ao2_container *sorted_tps;
struct ast_taskprocessor *tps;
struct ao2_iterator iter;
struct timespec delay = {1, 0};
/* During shutdown there may still be taskprocessor threads running and those
* tasprocessors reference tps_singletons. When those taskprocessors finish
* they will call ast_taskprocessor_unreference, creating a race condition which
* can result in tps_singletons being referenced after being deleted. To try and
* avoid this we check the container count and if greater than zero, give the
* running taskprocessors a chance to finish */
objcount = ao2_container_count(tps_singletons);
if (objcount > 0) {
ast_log(LOG_DEBUG,
"waiting for taskprocessor shutdown, %d tps object(s) still allocated.\n",
objcount);
/* give the running taskprocessors a chance to finish, up to
* AST_TASKPROCESSOR_SHUTDOWN_MAX_WAIT seconds */
for (tries = 0; tries < AST_TASKPROCESSOR_SHUTDOWN_MAX_WAIT; tries++) {
while (nanosleep(&delay, &delay));
objcount = ao2_container_count(tps_singletons);
/* if count is 0, we are done waiting */
if (objcount == 0) {
break;
}
delay.tv_sec = 1;
delay.tv_nsec = 0;
ast_log(LOG_DEBUG,
"waiting for taskprocessor shutdown, %d tps object(s) still allocated.\n",
objcount);
}
}
/* rather than try forever, risk an assertion on shutdown. This probably indicates
* a taskprocessor was not cleaned up somewhere */
if (objcount > 0) {
ast_log(LOG_ERROR,
"Asertion may occur, the following taskprocessors are still runing:\n");
sorted_tps = ao2_container_alloc_rbtree(AO2_ALLOC_OPT_LOCK_NOLOCK, 0, tps_sort_cb,
NULL);
if (!sorted_tps || ao2_container_dup(sorted_tps, tps_singletons, 0)) {
ast_log(LOG_ERROR, "unable to get sorted list of taskprocessors");
}
else {
iter = ao2_iterator_init(sorted_tps, AO2_ITERATOR_UNLINK);
while ((tps = ao2_iterator_next(&iter))) {
ast_log(LOG_ERROR, "taskprocessor '%s'\n", tps->name);
}
}
ao2_cleanup(sorted_tps);
}
else {
ast_log(LOG_DEBUG,
"All waiting taskprocessors cleared!\n");
}
ast_cli_unregister_multiple(taskprocessor_clis, ARRAY_LEN(taskprocessor_clis));
AST_VECTOR_CALLBACK_VOID(&overloaded_subsystems, ast_free);
AST_VECTOR_RW_FREE(&overloaded_subsystems);
ao2_t_ref(tps_singletons, -1, "Unref tps_singletons in shutdown");
tps_singletons = NULL;
}
/* initialize the taskprocessor container and register CLI operations */
int ast_tps_init(void)
{
tps_singletons = ao2_container_alloc_hash(AO2_ALLOC_OPT_LOCK_MUTEX, 0,
TPS_MAX_BUCKETS, tps_hash_cb, NULL, tps_cmp_cb);
if (!tps_singletons) {
ast_log(LOG_ERROR, "taskprocessor container failed to initialize!\n");
return -1;
}
if (AST_VECTOR_RW_INIT(&overloaded_subsystems, 10)) {
ao2_ref(tps_singletons, -1);
ast_log(LOG_ERROR, "taskprocessor subsystems vector failed to initialize!\n");
return -1;
}
ast_cond_init(&cli_ping_cond, NULL);
ast_cli_register_multiple(taskprocessor_clis, ARRAY_LEN(taskprocessor_clis));
ast_register_cleanup(tps_shutdown);
return 0;
}
/* allocate resources for the task */
static struct tps_task *tps_task_alloc(int (*task_exe)(void *datap), void *datap)
{
struct tps_task *t;
if (!task_exe) {
ast_log(LOG_ERROR, "task_exe is NULL!\n");
return NULL;
}
t = ast_calloc(1, sizeof(*t));
if (!t) {
ast_log(LOG_ERROR, "failed to allocate task!\n");
return NULL;
}
t->callback.execute = task_exe;
t->datap = datap;
return t;
}
static struct tps_task *tps_task_alloc_local(int (*task_exe)(struct ast_taskprocessor_local *local), void *datap)
{
struct tps_task *t;
if (!task_exe) {
ast_log(LOG_ERROR, "task_exe is NULL!\n");
return NULL;
}
t = ast_calloc(1, sizeof(*t));
if (!t) {
ast_log(LOG_ERROR, "failed to allocate task!\n");
return NULL;
}
t->callback.execute_local = task_exe;
t->datap = datap;
t->wants_local = 1;
return t;
}
/* release task resources */
static void *tps_task_free(struct tps_task *task)
{
ast_free(task);
return NULL;
}
/* Taskprocessor tab completion.
*
* The caller of this function is responsible for argument
* position checks prior to calling.
*/
static char *tps_taskprocessor_tab_complete(struct ast_cli_args *a)
{
int tklen;
struct ast_taskprocessor *p;
struct ao2_iterator i;
tklen = strlen(a->word);
i = ao2_iterator_init(tps_singletons, 0);
while ((p = ao2_iterator_next(&i))) {
if (!strncasecmp(a->word, p->name, tklen)) {
if (ast_cli_completion_add(ast_strdup(p->name))) {
ast_taskprocessor_unreference(p);
break;
}
}
ast_taskprocessor_unreference(p);
}
ao2_iterator_destroy(&i);
return NULL;
}
/* ping task handling function */
static int tps_ping_handler(void *datap)
{
ast_mutex_lock(&cli_ping_cond_lock);
ast_cond_signal(&cli_ping_cond);
ast_mutex_unlock(&cli_ping_cond_lock);
return 0;
}
/* ping the specified taskprocessor and display the ping time on the CLI */
static char *cli_tps_ping(struct ast_cli_entry *e, int cmd, struct ast_cli_args *a)
{
struct timeval begin, end, delta;
const char *name;
struct timeval when;
struct timespec ts;
struct ast_taskprocessor *tps;
switch (cmd) {
case CLI_INIT:
e->command = "core ping taskprocessor";
e->usage =
"Usage: core ping taskprocessor <taskprocessor>\n"
" Displays the time required for a task to be processed\n";
return NULL;
case CLI_GENERATE:
if (a->pos == 3) {
return tps_taskprocessor_tab_complete(a);
} else {
return NULL;
}
}
if (a->argc != 4)
return CLI_SHOWUSAGE;
name = a->argv[3];
if (!(tps = ast_taskprocessor_get(name, TPS_REF_IF_EXISTS))) {
ast_cli(a->fd, "\nping failed: %s not found\n\n", name);
return CLI_SUCCESS;
}
ast_cli(a->fd, "\npinging %s ...", name);
/*
* Wait up to 5 seconds for a ping reply.
*
* On a very busy system it could take awhile to get a
* ping response from some taskprocessors.
*/
begin = ast_tvnow();
when = ast_tvadd(begin, ast_samp2tv(5000, 1000));
ts.tv_sec = when.tv_sec;
ts.tv_nsec = when.tv_usec * 1000;
ast_mutex_lock(&cli_ping_cond_lock);
if (ast_taskprocessor_push(tps, tps_ping_handler, 0) < 0) {
ast_mutex_unlock(&cli_ping_cond_lock);
ast_cli(a->fd, "\nping failed: could not push task to %s\n\n", name);
ast_taskprocessor_unreference(tps);
return CLI_FAILURE;
}
ast_cond_timedwait(&cli_ping_cond, &cli_ping_cond_lock, &ts);
ast_mutex_unlock(&cli_ping_cond_lock);
end = ast_tvnow();
delta = ast_tvsub(end, begin);
ast_cli(a->fd, "\n\t%24s ping time: %.1ld.%.6ld sec\n\n", name, (long)delta.tv_sec, (long int)delta.tv_usec);
ast_taskprocessor_unreference(tps);
return CLI_SUCCESS;
}
/*!
* \internal
* \brief Taskprocessor ao2 container sort function.
* \since 13.8.0
*
* \param obj_left pointer to the (user-defined part) of an object.
* \param obj_right pointer to the (user-defined part) of an object.
* \param flags flags from ao2_callback()
* OBJ_SEARCH_OBJECT - if set, 'obj_right', is an object.
* OBJ_SEARCH_KEY - if set, 'obj_right', is a search key item that is not an object.
* OBJ_SEARCH_PARTIAL_KEY - if set, 'obj_right', is a partial search key item that is not an object.
*
* \retval negative if obj_left < obj_right
* \retval 0 if obj_left == obj_right
* \retval positive if obj_left > obj_right
*/
static int tps_sort_cb(const void *obj_left, const void *obj_right, int flags)
{
const struct ast_taskprocessor *tps_left = obj_left;
const struct ast_taskprocessor *tps_right = obj_right;
const char *right_key = obj_right;
int cmp;
switch (flags & OBJ_SEARCH_MASK) {
default:
case OBJ_SEARCH_OBJECT:
right_key = tps_right->name;
/* Fall through */
case OBJ_SEARCH_KEY:
cmp = strcasecmp(tps_left->name, right_key);
break;
case OBJ_SEARCH_PARTIAL_KEY:
cmp = strncasecmp(tps_left->name, right_key, strlen(right_key));
break;
}
return cmp;
}
#define FMT_HEADERS "%-70s %10s %10s %10s %10s %10s\n"
#define FMT_FIELDS "%-70s %10lu %10lu %10lu %10lu %10lu\n"
/*!
* \internal
* \brief Print taskprocessor information to CLI.
* \since 13.30.0
*
* \param fd the file descriptor
* \param tps the taskprocessor
*/
static void tps_report_taskprocessor_list_helper(int fd, struct ast_taskprocessor *tps)
{
ast_cli(fd, FMT_FIELDS, tps->name, tps->stats._tasks_processed_count,
tps->tps_queue_size, tps->stats.max_qsize, tps->tps_queue_low,
tps->tps_queue_high);
}
/*!
* \internal
* \brief Prints an optionally narrowed down list of taskprocessors to the CLI.
* \since 13.30.0
*
* \param fd the file descriptor
* \param like the string we are matching on
*
* \return number of taskprocessors on success
* \retval 0 otherwise
*/
static int tps_report_taskprocessor_list(int fd, const char *like)
{
int tps_count = 0;
int word_len;
struct ao2_container *sorted_tps;
struct ast_taskprocessor *tps;
struct ao2_iterator iter;
sorted_tps = ao2_container_alloc_rbtree(AO2_ALLOC_OPT_LOCK_NOLOCK, 0, tps_sort_cb,
NULL);
if (!sorted_tps
|| ao2_container_dup(sorted_tps, tps_singletons, 0)) {
ast_debug(1, "Failed to retrieve sorted taskprocessors\n");
ao2_cleanup(sorted_tps);
return 0;
}
word_len = strlen(like);
iter = ao2_iterator_init(sorted_tps, AO2_ITERATOR_UNLINK);
while ((tps = ao2_iterator_next(&iter))) {
if (like) {
if (!strncasecmp(like, tps->name, word_len)) {
tps_report_taskprocessor_list_helper(fd, tps);
tps_count++;
}
} else {
tps_report_taskprocessor_list_helper(fd, tps);
tps_count++;
}
ast_taskprocessor_unreference(tps);
}
ao2_iterator_destroy(&iter);
ao2_ref(sorted_tps, -1);
return tps_count;
}
static char *cli_tps_report(struct ast_cli_entry *e, int cmd, struct ast_cli_args *a)
{
const char *like;
switch (cmd) {
case CLI_INIT:
e->command = "core show taskprocessors [like]";
e->usage =
"Usage: core show taskprocessors [like keyword]\n"
" Shows a list of instantiated task processors and their statistics\n";
return NULL;
case CLI_GENERATE:
if (a->pos == e->args) {
return tps_taskprocessor_tab_complete(a);
} else {
return NULL;
}
}
if (a->argc == e->args - 1) {
like = "";
} else if (a->argc == e->args + 1 && !strcasecmp(a->argv[e->args-1], "like")) {
like = a->argv[e->args];
} else {
return CLI_SHOWUSAGE;
}
ast_cli(a->fd, "\n" FMT_HEADERS, "Processor", "Processed", "In Queue", "Max Depth", "Low water", "High water");
ast_cli(a->fd, "\n%d taskprocessors\n\n", tps_report_taskprocessor_list(a->fd, like));
return CLI_SUCCESS;
}
/* hash callback for astobj2 */
static int tps_hash_cb(const void *obj, const int flags)
{
const struct ast_taskprocessor *tps = obj;
const char *name = flags & OBJ_KEY ? obj : tps->name;
return ast_str_case_hash(name);
}
/* compare callback for astobj2 */
static int tps_cmp_cb(void *obj, void *arg, int flags)
{
struct ast_taskprocessor *lhs = obj, *rhs = arg;
const char *rhsname = flags & OBJ_KEY ? arg : rhs->name;
return !strcasecmp(lhs->name, rhsname) ? CMP_MATCH | CMP_STOP : 0;
}
static int subsystem_match(struct subsystem_alert *alert, const char *subsystem)
{
return !strcmp(alert->subsystem, subsystem);
}
static int subsystem_cmp(struct subsystem_alert *a, struct subsystem_alert *b)
{
return strcmp(a->subsystem, b->subsystem);
}
unsigned int ast_taskprocessor_get_subsystem_alert(const char *subsystem)
{
struct subsystem_alert *alert;
unsigned int count = 0;
int idx;
AST_VECTOR_RW_RDLOCK(&overloaded_subsystems);
idx = AST_VECTOR_GET_INDEX(&overloaded_subsystems, subsystem, subsystem_match);
if (idx >= 0) {
alert = AST_VECTOR_GET(&overloaded_subsystems, idx);
count = alert->alert_count;
}
AST_VECTOR_RW_UNLOCK(&overloaded_subsystems);
return count;
}
static void subsystem_alert_increment(const char *subsystem)
{
struct subsystem_alert *alert;
int idx;
if (ast_strlen_zero(subsystem)) {
return;
}
AST_VECTOR_RW_WRLOCK(&overloaded_subsystems);
idx = AST_VECTOR_GET_INDEX(&overloaded_subsystems, subsystem, subsystem_match);
if (idx >= 0) {
alert = AST_VECTOR_GET(&overloaded_subsystems, idx);
alert->alert_count++;
AST_VECTOR_RW_UNLOCK(&overloaded_subsystems);
return;
}
alert = ast_malloc(sizeof(*alert) + strlen(subsystem) + 1);
if (!alert) {
AST_VECTOR_RW_UNLOCK(&overloaded_subsystems);
return;
}
alert->alert_count = 1;
strcpy(alert->subsystem, subsystem); /* Safe */
if (AST_VECTOR_APPEND(&overloaded_subsystems, alert)) {
ast_free(alert);
}
AST_VECTOR_RW_UNLOCK(&overloaded_subsystems);
}
static void subsystem_alert_decrement(const char *subsystem)
{
struct subsystem_alert *alert;
int idx;
if (ast_strlen_zero(subsystem)) {
return;
}
AST_VECTOR_RW_WRLOCK(&overloaded_subsystems);
idx = AST_VECTOR_GET_INDEX(&overloaded_subsystems, subsystem, subsystem_match);
if (idx < 0) {
ast_log(LOG_ERROR,
"Can't decrement alert count for subsystem '%s' as it wasn't in alert\n", subsystem);
AST_VECTOR_RW_UNLOCK(&overloaded_subsystems);
return;
}
alert = AST_VECTOR_GET(&overloaded_subsystems, idx);
alert->alert_count--;
if (alert->alert_count <= 0) {
AST_VECTOR_REMOVE(&overloaded_subsystems, idx, 0);
ast_free(alert);
}
AST_VECTOR_RW_UNLOCK(&overloaded_subsystems);
}
static void subsystem_copy(struct subsystem_alert *alert,
struct subsystem_alert_vector *vector)
{
struct subsystem_alert *alert_copy;
alert_copy = ast_malloc(sizeof(*alert_copy) + strlen(alert->subsystem) + 1);
if (!alert_copy) {
return;
}
alert_copy->alert_count = alert->alert_count;
strcpy(alert_copy->subsystem, alert->subsystem); /* Safe */
if (AST_VECTOR_ADD_SORTED(vector, alert_copy, subsystem_cmp)) {
ast_free(alert_copy);
}
}
static char *cli_subsystem_alert_report(struct ast_cli_entry *e, int cmd, struct ast_cli_args *a)
{
struct subsystem_alert_vector sorted_subsystems;
int i;
#define FMT_HEADERS_SUBSYSTEM "%-32s %12s\n"
#define FMT_FIELDS_SUBSYSTEM "%-32s %12u\n"
switch (cmd) {
case CLI_INIT:
e->command = "core show taskprocessor alerted subsystems";
e->usage =
"Usage: core show taskprocessor alerted subsystems\n"
" Shows a list of task processor subsystems that are currently alerted\n";
return NULL;
case CLI_GENERATE:
return NULL;
}
if (a->argc != e->args) {
return CLI_SHOWUSAGE;
}
if (AST_VECTOR_INIT(&sorted_subsystems, AST_VECTOR_SIZE(&overloaded_subsystems))) {
return CLI_FAILURE;
}
AST_VECTOR_RW_RDLOCK(&overloaded_subsystems);
for (i = 0; i < AST_VECTOR_SIZE(&overloaded_subsystems); i++) {
subsystem_copy(AST_VECTOR_GET(&overloaded_subsystems, i), &sorted_subsystems);
}
AST_VECTOR_RW_UNLOCK(&overloaded_subsystems);
ast_cli(a->fd, "\n" FMT_HEADERS_SUBSYSTEM, "Subsystem", "Alert Count");
for (i = 0; i < AST_VECTOR_SIZE(&sorted_subsystems); i++) {
struct subsystem_alert *alert = AST_VECTOR_GET(&sorted_subsystems, i);
ast_cli(a->fd, FMT_FIELDS_SUBSYSTEM, alert->subsystem, alert->alert_count);
}
ast_cli(a->fd, "\n%zu subsystems\n\n", AST_VECTOR_SIZE(&sorted_subsystems));
AST_VECTOR_CALLBACK_VOID(&sorted_subsystems, ast_free);
AST_VECTOR_FREE(&sorted_subsystems);
return CLI_SUCCESS;
}
/*! Count of the number of taskprocessors in high water alert. */
static unsigned int tps_alert_count;
/*! Access protection for tps_alert_count */
AST_RWLOCK_DEFINE_STATIC(tps_alert_lock);
/*!
* \internal
* \brief Add a delta to tps_alert_count with protection.
* \since 13.10.0
*
* \param tps Taskprocessor updating queue water mark alert trigger.
* \param delta The amount to add to tps_alert_count.
*/
static void tps_alert_add(struct ast_taskprocessor *tps, int delta)
{
unsigned int old;
ast_rwlock_wrlock(&tps_alert_lock);
old = tps_alert_count;
tps_alert_count += delta;
if (DEBUG_ATLEAST(3)
/* and tps_alert_count becomes zero or non-zero */
&& !old != !tps_alert_count) {
ast_log(LOG_DEBUG, "Taskprocessor '%s' %s the high water alert.\n",
tps->name, tps_alert_count ? "triggered" : "cleared");
}
if (tps->subsystem[0] != '\0') {
if (delta > 0) {
subsystem_alert_increment(tps->subsystem);
} else {
subsystem_alert_decrement(tps->subsystem);
}
}
ast_rwlock_unlock(&tps_alert_lock);
}
unsigned int ast_taskprocessor_alert_get(void)
{
unsigned int count;
ast_rwlock_rdlock(&tps_alert_lock);
count = tps_alert_count;
ast_rwlock_unlock(&tps_alert_lock);
return count;
}
int ast_taskprocessor_alert_set_levels(struct ast_taskprocessor *tps, long low_water, long high_water)
{
if (!tps || high_water < 0 || high_water < low_water) {
return -1;
}
if (low_water < 0) {
/* Set low water level to 90% of high water level */
low_water = (high_water * 9) / 10;
}
ao2_lock(tps);
tps->tps_queue_low = low_water;
tps->tps_queue_high = high_water;
if (tps->high_water_alert) {
if (!tps->tps_queue_size || tps->tps_queue_size < low_water) {
/* Update water mark alert immediately */
tps->high_water_alert = 0;
tps_alert_add(tps, -1);
}
} else {
if (high_water < tps->tps_queue_size) {
/* Update water mark alert immediately */
tps->high_water_alert = 1;
tps_alert_add(tps, +1);
}
}
ao2_unlock(tps);
return 0;
}
/* destroy the taskprocessor */
static void tps_taskprocessor_dtor(void *tps)
{
struct ast_taskprocessor *t = tps;
struct tps_task *task;
while ((task = AST_LIST_REMOVE_HEAD(&t->tps_queue, list))) {
tps_task_free(task);
}
t->tps_queue_size = 0;
if (t->high_water_alert) {
t->high_water_alert = 0;
tps_alert_add(t, -1);
}
ao2_cleanup(t->listener);
t->listener = NULL;
}
/* pop the front task and return it */
static struct tps_task *tps_taskprocessor_pop(struct ast_taskprocessor *tps)
{
struct tps_task *task;
if ((task = AST_LIST_REMOVE_HEAD(&tps->tps_queue, list))) {
--tps->tps_queue_size;
if (tps->high_water_alert && tps->tps_queue_size <= tps->tps_queue_low) {
tps->high_water_alert = 0;
tps_alert_add(tps, -1);
}
}
return task;
}
long ast_taskprocessor_size(struct ast_taskprocessor *tps)
{
return (tps) ? tps->tps_queue_size : -1;
}
/* taskprocessor name accessor */
const char *ast_taskprocessor_name(struct ast_taskprocessor *tps)
{
if (!tps) {
ast_log(LOG_ERROR, "no taskprocessor specified!\n");
return NULL;
}
return tps->name;
}
static void listener_shutdown(struct ast_taskprocessor_listener *listener)
{
listener->callbacks->shutdown(listener);
ao2_ref(listener->tps, -1);
}
static void taskprocessor_listener_dtor(void *obj)
{
struct ast_taskprocessor_listener *listener = obj;
if (listener->callbacks->dtor) {
listener->callbacks->dtor(listener);
}
}
struct ast_taskprocessor_listener *ast_taskprocessor_listener_alloc(const struct ast_taskprocessor_listener_callbacks *callbacks, void *user_data)
{
struct ast_taskprocessor_listener *listener;
listener = ao2_alloc(sizeof(*listener), taskprocessor_listener_dtor);
if (!listener) {
return NULL;
}
listener->callbacks = callbacks;
listener->user_data = user_data;
return listener;
}
struct ast_taskprocessor *ast_taskprocessor_listener_get_tps(const struct ast_taskprocessor_listener *listener)
{
ao2_ref(listener->tps, +1);
return listener->tps;
}
void *ast_taskprocessor_listener_get_user_data(const struct ast_taskprocessor_listener *listener)
{
return listener->user_data;
}
static void *default_listener_pvt_alloc(void)
{
struct default_taskprocessor_listener_pvt *pvt;
pvt = ast_calloc(1, sizeof(*pvt));
if (!pvt) {
return NULL;
}
pvt->poll_thread = AST_PTHREADT_NULL;
if (ast_sem_init(&pvt->sem, 0, 0) != 0) {
ast_log(LOG_ERROR, "ast_sem_init(): %s\n", strerror(errno));
ast_free(pvt);
return NULL;
}
return pvt;
}
/*!
* \internal
* \brief Allocate a task processor structure
*
* \param name Name of the task processor.
* \param listener Listener to associate with the task processor.
*
* \return The newly allocated task processor.
*
* \pre tps_singletons must be locked by the caller.
*/
static struct ast_taskprocessor *__allocate_taskprocessor(const char *name, struct ast_taskprocessor_listener *listener)
{
struct ast_taskprocessor *p;
char *subsystem_separator;
size_t subsystem_length = 0;
size_t name_length;
name_length = strlen(name);
subsystem_separator = strchr(name, '/');
if (subsystem_separator) {
subsystem_length = subsystem_separator - name;
}
p = ao2_alloc(sizeof(*p) + name_length + subsystem_length + 2, tps_taskprocessor_dtor);
if (!p) {
ast_log(LOG_WARNING, "failed to create taskprocessor '%s'\n", name);
return NULL;
}
/* Set default congestion water level alert triggers. */
p->tps_queue_low = (AST_TASKPROCESSOR_HIGH_WATER_LEVEL * 9) / 10;
p->tps_queue_high = AST_TASKPROCESSOR_HIGH_WATER_LEVEL;
strcpy(p->name, name); /* Safe */
p->subsystem = p->name + name_length + 1;
ast_copy_string(p->subsystem, name, subsystem_length + 1);
ao2_ref(listener, +1);
p->listener = listener;
p->thread = AST_PTHREADT_NULL;
ao2_ref(p, +1);
listener->tps = p;
if (!(ao2_link_flags(tps_singletons, p, OBJ_NOLOCK))) {
ast_log(LOG_ERROR, "Failed to add taskprocessor '%s' to container\n", p->name);
listener->tps = NULL;
ao2_ref(p, -2);
return NULL;
}
return p;
}
static struct ast_taskprocessor *__start_taskprocessor(struct ast_taskprocessor *p)
{
if (p && p->listener->callbacks->start(p->listener)) {
ast_log(LOG_ERROR, "Unable to start taskprocessor listener for taskprocessor %s\n",
p->name);
ast_taskprocessor_unreference(p);
return NULL;
}
return p;
}
/* Provide a reference to a taskprocessor. Create the taskprocessor if necessary, but don't
* create the taskprocessor if we were told via ast_tps_options to return a reference only
* if it already exists */
struct ast_taskprocessor *ast_taskprocessor_get(const char *name, enum ast_tps_options create)
{
struct ast_taskprocessor *p;
struct ast_taskprocessor_listener *listener;
struct default_taskprocessor_listener_pvt *pvt;
if (ast_strlen_zero(name)) {
ast_log(LOG_ERROR, "requesting a nameless taskprocessor!!!\n");
return NULL;
}
ao2_lock(tps_singletons);
p = ao2_find(tps_singletons, name, OBJ_KEY | OBJ_NOLOCK);
if (p || (create & TPS_REF_IF_EXISTS)) {
/* calling function does not want a new taskprocessor to be created if it doesn't already exist */
ao2_unlock(tps_singletons);
return p;
}
/* Create a new taskprocessor. Start by creating a default listener */
pvt = default_listener_pvt_alloc();
if (!pvt) {
ao2_unlock(tps_singletons);
return NULL;
}
listener = ast_taskprocessor_listener_alloc(&default_listener_callbacks, pvt);
if (!listener) {
ao2_unlock(tps_singletons);
default_listener_pvt_destroy(pvt);
return NULL;
}
p = __allocate_taskprocessor(name, listener);
ao2_unlock(tps_singletons);
p = __start_taskprocessor(p);
ao2_ref(listener, -1);
return p;
}
struct ast_taskprocessor *ast_taskprocessor_create_with_listener(const char *name, struct ast_taskprocessor_listener *listener)
{
struct ast_taskprocessor *p;
ao2_lock(tps_singletons);
p = ao2_find(tps_singletons, name, OBJ_KEY | OBJ_NOLOCK);
if (p) {
ao2_unlock(tps_singletons);
ast_taskprocessor_unreference(p);
return NULL;
}
p = __allocate_taskprocessor(name, listener);
ao2_unlock(tps_singletons);
return __start_taskprocessor(p);
}
void ast_taskprocessor_set_local(struct ast_taskprocessor *tps,
void *local_data)
{
SCOPED_AO2LOCK(lock, tps);
tps->local_data = local_data;
}
/* decrement the taskprocessor reference count and unlink from the container if necessary */
void *ast_taskprocessor_unreference(struct ast_taskprocessor *tps)
{
if (!tps) {
return NULL;
}
/* To prevent another thread from finding and getting a reference to this
* taskprocessor we hold the singletons lock. If we didn't do this then
* they may acquire it and find that the listener has been shut down.
*/
ao2_lock(tps_singletons);
if (ao2_ref(tps, -1) > 3) {
ao2_unlock(tps_singletons);
return NULL;
}
/* If we're down to 3 references, then those must be:
* 1. The reference we just got rid of
* 2. The container
* 3. The listener
*/
ao2_unlink_flags(tps_singletons, tps, OBJ_NOLOCK);
ao2_unlock(tps_singletons);
listener_shutdown(tps->listener);
return NULL;
}
/* push the task into the taskprocessor queue */
static int taskprocessor_push(struct ast_taskprocessor *tps, struct tps_task *t)
{
int previous_size;
int was_empty;
if (!tps) {
ast_log(LOG_ERROR, "tps is NULL!\n");
return -1;
}
if (!t) {
ast_log(LOG_ERROR, "t is NULL!\n");
return -1;
}
ao2_lock(tps);
AST_LIST_INSERT_TAIL(&tps->tps_queue, t, list);
previous_size = tps->tps_queue_size++;
if (tps->tps_queue_high <= tps->tps_queue_size) {
if (!tps->high_water_alert) {
ast_log(LOG_WARNING, "The '%s' task processor queue reached %ld scheduled tasks%s.\n",
tps->name, tps->tps_queue_size, tps->high_water_warned ? " again" : "");
tps->high_water_warned = 1;
tps->high_water_alert = 1;
tps_alert_add(tps, +1);
}
}
/* The currently executing task counts as still in queue */
was_empty = tps->executing ? 0 : previous_size == 0;
ao2_unlock(tps);
tps->listener->callbacks->task_pushed(tps->listener, was_empty);
return 0;
}
int ast_taskprocessor_push(struct ast_taskprocessor *tps, int (*task_exe)(void *datap), void *datap)
{
return taskprocessor_push(tps, tps_task_alloc(task_exe, datap));
}
int ast_taskprocessor_push_local(struct ast_taskprocessor *tps, int (*task_exe)(struct ast_taskprocessor_local *datap), void *datap)
{
return taskprocessor_push(tps, tps_task_alloc_local(task_exe, datap));
}
int ast_taskprocessor_suspend(struct ast_taskprocessor *tps)
{
if (tps) {
ao2_lock(tps);
tps->suspended = 1;
ao2_unlock(tps);
return 0;
}
return -1;
}
int ast_taskprocessor_unsuspend(struct ast_taskprocessor *tps)
{
if (tps) {
ao2_lock(tps);
tps->suspended = 0;
ao2_unlock(tps);
return 0;
}
return -1;
}
int ast_taskprocessor_is_suspended(struct ast_taskprocessor *tps)
{
return tps ? tps->suspended : -1;
}
int ast_taskprocessor_execute(struct ast_taskprocessor *tps)
{
struct ast_taskprocessor_local local;
struct tps_task *t;
long size;
ao2_lock(tps);
t = tps_taskprocessor_pop(tps);
if (!t) {
ao2_unlock(tps);
return 0;
}
tps->thread = pthread_self();
tps->executing = 1;
if (t->wants_local) {
local.local_data = tps->local_data;
local.data = t->datap;
}
ao2_unlock(tps);
if (t->wants_local) {
t->callback.execute_local(&local);
} else {
t->callback.execute(t->datap);
}
tps_task_free(t);
ao2_lock(tps);
tps->thread = AST_PTHREADT_NULL;
/* We need to check size in the same critical section where we reset the
* executing bit. Avoids a race condition where a task is pushed right
* after we pop an empty stack.
*/
tps->executing = 0;
size = ast_taskprocessor_size(tps);
/* Update the stats */
++tps->stats._tasks_processed_count;
/* Include the task we just executed as part of the queue size. */
if (size >= tps->stats.max_qsize) {
tps->stats.max_qsize = size + 1;
}
ao2_unlock(tps);
/* If we executed a task, check for the transition to empty */
if (size == 0 && tps->listener->callbacks->emptied) {
tps->listener->callbacks->emptied(tps->listener);
}
return size > 0;
}
int ast_taskprocessor_is_task(struct ast_taskprocessor *tps)
{
int is_task;
ao2_lock(tps);
is_task = pthread_equal(tps->thread, pthread_self());
ao2_unlock(tps);
return is_task;
}
unsigned int ast_taskprocessor_seq_num(void)
{
static int seq_num;
return (unsigned int) ast_atomic_fetchadd_int(&seq_num, +1);
}
#define SEQ_STR_SIZE (1 + 8 + 1) /* Dash plus 8 hex digits plus null terminator */
void ast_taskprocessor_name_append(char *buf, unsigned int size, const char *name)
{
int final_size = strlen(name) + SEQ_STR_SIZE;
ast_assert(buf != NULL && name != NULL);
ast_assert(final_size <= size);
snprintf(buf, final_size, "%s-%08x", name, ast_taskprocessor_seq_num());
}
void ast_taskprocessor_build_name(char *buf, unsigned int size, const char *format, ...)
{
va_list ap;
int user_size;
ast_assert(buf != NULL);
ast_assert(SEQ_STR_SIZE <= size);
va_start(ap, format);
user_size = vsnprintf(buf, size - (SEQ_STR_SIZE - 1), format, ap);
va_end(ap);
if (user_size < 0) {
/*
* Wow! We got an output error to a memory buffer.
* Assume no user part of name written.
*/
user_size = 0;
} else if (size < user_size + SEQ_STR_SIZE) {
/* Truncate user part of name to make sequence number fit. */
user_size = size - SEQ_STR_SIZE;
}
/* Append sequence number to end of user name. */
snprintf(buf + user_size, SEQ_STR_SIZE, "-%08x", ast_taskprocessor_seq_num());
}
static void tps_reset_stats(struct ast_taskprocessor *tps)
{
ao2_lock(tps);
tps->stats._tasks_processed_count = 0;
tps->stats.max_qsize = 0;
ao2_unlock(tps);
}
static char *cli_tps_reset_stats(struct ast_cli_entry *e, int cmd, struct ast_cli_args *a)
{
const char *name;
struct ast_taskprocessor *tps;
switch (cmd) {
case CLI_INIT:
e->command = "core reset taskprocessor";
e->usage =
"Usage: core reset taskprocessor <taskprocessor>\n"
" Resets stats for the specified taskprocessor\n";
return NULL;
case CLI_GENERATE:
return tps_taskprocessor_tab_complete(a);
}
if (a->argc != 4) {
return CLI_SHOWUSAGE;
}
name = a->argv[3];
if (!(tps = ast_taskprocessor_get(name, TPS_REF_IF_EXISTS))) {
ast_cli(a->fd, "\nReset failed: %s not found\n\n", name);
return CLI_SUCCESS;
}
ast_cli(a->fd, "\nResetting %s\n\n", name);
tps_reset_stats(tps);
ast_taskprocessor_unreference(tps);
return CLI_SUCCESS;
}
static char *cli_tps_reset_stats_all(struct ast_cli_entry *e, int cmd, struct ast_cli_args *a)
{
struct ast_taskprocessor *tps;
struct ao2_iterator iter;
switch (cmd) {
case CLI_INIT:
e->command = "core reset taskprocessors";
e->usage =
"Usage: core reset taskprocessors\n"
" Resets stats for all taskprocessors\n";
return NULL;
case CLI_GENERATE:
return NULL;
}
if (a->argc != e->args) {
return CLI_SHOWUSAGE;
}
ast_cli(a->fd, "\nResetting stats for all taskprocessors\n\n");
iter = ao2_iterator_init(tps_singletons, 0);
while ((tps = ao2_iterator_next(&iter))) {
tps_reset_stats(tps);
ast_taskprocessor_unreference(tps);
}
ao2_iterator_destroy(&iter);
return CLI_SUCCESS;
}