retronetworking
/
freeswitch
13
0
Fork 0
Code Pull Requests Releases Activity
freeswitch/libs/sofia-sip/libsofia-sip-ua/su/su_kqueue_port.c

653 lines
17 KiB
C
Raw Blame History

/*
* This file is part of the Sofia-SIP package
*
* Copyright (C) 2005 Nokia Corporation.
*
* Contact: Pekka Pessi <pekka.pessi@nokia.com>
*
* This library is free software; you can redistribute it and/or
* modify it under the terms of the GNU Lesser General Public License
* as published by the Free Software Foundation; either version 2.1 of
* the License, or (at your option) any later version.
*
* This library is distributed in the hope that it will be useful, but
* WITHOUT ANY WARRANTY; without even the implied warranty of
* MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the GNU
* Lesser General Public License for more details.
*
* You should have received a copy of the GNU Lesser General Public
* License along with this library; if not, write to the Free Software
* Foundation, Inc., 51 Franklin St, Fifth Floor, Boston, MA
* 02110-1301 USA
*
*/
/**@ingroup su_wait
* @CFILE su_kqueue_port.c
*
* Port implementation using kqueue()
*
* @author Martti Mela <Martti.Mela@nokia.com>
* @author Pekka Pessi <Pekka.Pessi@nokia.com>
*
* @date Created: Sun Feb 18 19:55:37 EET 2007 mela
*/
#include "config.h"
#include "sofia-sip/su.h"
#define su_port_s su_kqueue_port_s
#include "su_port.h"
#if HAVE_KQUEUE
#include "sofia-sip/su_alloc.h"
#include <sys/event.h>
/* INT_TO_UDATA() macros from https://github.com/libevent/libevent */
/* Some platforms apparently define the udata field of struct kevent as
* intptr_t, whereas others define it as void*. There doesn't seem to be an
* easy way to tell them apart via autoconf, so we need to use OS macros. */
#if defined(HAVE_INTTYPES_H) && !defined(__OpenBSD__) && !defined(__FreeBSD__) && !defined(__darwin__) && !defined(__APPLE__) && !defined(__DragonFly__)
#define INT_TO_UDATA(x) ((intptr_t)(x))
#else
#define INT_TO_UDATA(x) ((void*)(intptr_t)(x))
#endif
#define SU_ENABLE_MULTISHOT_KQUEUE 1
#include <stdlib.h>
#include <assert.h>
#include <stdarg.h>
#include <stdio.h>
#include <string.h>
#include <limits.h>
#include <errno.h>
/** Port based on kqueue(). */
struct su_kqueue_port_s {
su_socket_port_t sup_base[1];
#define sup_home sup_base->sup_base->sup_base->sup_home
/** kqueue fd */
int sup_kqueue;
unsigned sup_multishot; /**< Multishot operation? */
unsigned sup_registers; /** Counter incremented by
su_port_register() or
su_port_unregister()
*/
int sup_n_registrations;
int sup_max_index; /**< Indexes are equal or smaller than this */
int sup_size_indices; /**< Size of allocated index table */
#define INDEX_MAX (0x7fffffff)
/** Structure containing registration data */
struct su_register {
struct su_register *ser_next; /* Next in free list */
su_wakeup_f ser_cb;
su_wakeup_arg_t*ser_arg;
su_root_t *ser_root;
int ser_id; /** registration identifier */
su_wait_t ser_wait[1];
} **sup_indices;
};
static void su_kqueue_port_decref(su_port_t *, int blocking, char const *who);
static int su_kqueue_port_register(su_port_t *self,
su_root_t *root,
su_wait_t *wait,
su_wakeup_f callback,
su_wakeup_arg_t *arg,
int priority);
static int su_kqueue_port_unregister(su_port_t *port,
su_root_t *root,
su_wait_t *wait,
su_wakeup_f callback,
su_wakeup_arg_t *arg);
static int su_kqueue_port_deregister(su_port_t *self, int i);
static int su_kqueue_port_unregister_all(su_port_t *self, su_root_t *root);
static int su_kqueue_port_eventmask(su_port_t *self,
int index,
int socket,
int events);
static int su_kqueue_port_multishot(su_port_t *self, int multishot);
static int su_kqueue_port_wait_events(su_port_t *self, su_duration_t tout);
static char const *su_kqueue_port_name(su_port_t const *self);
su_port_vtable_t const su_kqueue_port_vtable[1] =
{{
/* su_vtable_size: */ sizeof su_kqueue_port_vtable,
su_pthread_port_lock,
su_pthread_port_unlock,
su_base_port_incref,
su_kqueue_port_decref,
su_base_port_gsource,
su_base_port_send,
su_kqueue_port_register,
su_kqueue_port_unregister,
su_kqueue_port_deregister,
su_kqueue_port_unregister_all,
su_kqueue_port_eventmask,
su_base_port_run,
su_base_port_break,
su_base_port_step,
su_pthread_port_thread,
su_base_port_add_prepoll,
su_base_port_remove_prepoll,
su_base_port_timers,
su_kqueue_port_multishot,
su_kqueue_port_wait_events,
su_base_port_getmsgs,
su_base_port_getmsgs_from,
su_kqueue_port_name,
su_base_port_start_shared,
su_pthread_port_wait,
su_pthread_port_execute,
su_base_port_deferrable,
su_base_port_max_defer,
su_socket_port_wakeup,
su_base_port_is_running,
}};
static char const *su_kqueue_port_name(su_port_t const *self)
{
return "kqueue";
}
static void su_kqueue_port_deinit(void *arg)
{
su_port_t *self = arg;
SU_DEBUG_9(("%s(%p) called\n", "su_kqueue_port_deinit", (void *)self));
su_socket_port_deinit(self->sup_base);
close(self->sup_kqueue);
}
static void su_kqueue_port_decref(su_port_t *self, int blocking, char const *who)
{
su_base_port_decref(self, blocking, who);
}
/** @internal
*
* Register a @c su_wait_t object. The wait object, a callback function and
* an argument pointer is stored in the port object. The callback function
* will be called when the wait object is signaled.
*
* Please note if identical wait objects are inserted, only first one is
* ever signalled.
*
* @param self pointer to port
* @param root pointer to root object
* @param waits pointer to wait object
* @param callback callback function pointer
* @param arg argument given to callback function when it is invoked
* @param priority relative priority of the wait object
* (0 is normal, 1 important, 2 realtime)
*
* @return
* Positive index of the wait object,
* or -1 upon an error.
*/
int su_kqueue_port_register(su_port_t *self,
su_root_t *root,
su_wait_t *wait,
su_wakeup_f callback,
su_wakeup_arg_t *arg,
int priority)
{
int i, j, n;
struct su_register *ser;
struct su_register **indices = self->sup_indices;
struct kevent ev[1];
int flags;
assert(su_port_own_thread(self));
n = self->sup_size_indices;
if (n >= SU_WAIT_MAX)
return su_seterrno(ENOMEM);
ser = indices[0];
if (!ser) {
su_home_t *h = su_port_home(self);
i = self->sup_max_index, j = i == 0 ? 15 : i + 16;
if (j >= self->sup_size_indices) {
/* Reallocate index table */
n = n < 1024 ? 2 * n : n + 1024;
indices = su_realloc(h, indices, n * sizeof(indices[0]));
if (!indices)
return -1;
self->sup_indices = indices;
self->sup_size_indices = n;
}
/* Allocate registrations */
ser = su_zalloc(h, (j - i) * (sizeof *ser));
if (!ser)
return -1;
indices[0] = ser;
for (i++; i <= j; i++) {
ser->ser_id = i;
ser->ser_next = i < j ? ser + 1 : NULL;
indices[i] = ser++;
}
self->sup_max_index = j;
ser = indices[0];
}
i = ser->ser_id;
flags = (wait->events & SU_WAIT_IN) ? EV_ADD : EV_ADD | EV_DISABLE;
EV_SET(ev, wait->fd, EVFILT_READ, flags, 0, 0, INT_TO_UDATA(i));
if (kevent(self->sup_kqueue, ev, 1, NULL, 0, NULL) == -1) {
SU_DEBUG_0(("kevent((%u, %s, %u, %p)) failed: %s\n",
wait->fd, "EVFILT_READ", flags, (void *)(intptr_t)i, strerror(errno)));
return -1;
}
flags = (wait->events & SU_WAIT_OUT) ? EV_ADD : EV_ADD | EV_DISABLE;
EV_SET(ev, wait->fd, EVFILT_WRITE, flags, 0, 0, INT_TO_UDATA(i));
if (kevent(self->sup_kqueue, ev, 1, NULL, 0, NULL) == -1) {
int error = errno;
SU_DEBUG_0(("kevent((%u, %s, %u, %p)) failed: %s\n",
wait->fd, "EVFILT_WRITE", flags, (void *)(intptr_t)i, strerror(error)));
EV_SET(ev, wait->fd, EVFILT_READ, EV_DELETE, 0, 0, INT_TO_UDATA(i));
kevent(self->sup_kqueue, ev, 1, NULL, 0, NULL);
errno = error;
return -1;
}
indices[0] = ser->ser_next;
ser->ser_next = NULL;
*ser->ser_wait = *wait;
ser->ser_cb = callback;
ser->ser_arg = arg;
ser->ser_root = root;
self->sup_registers++;
self->sup_n_registrations++;
return i; /* return index */
}
/** Deregister a su_wait_t object. */
static int su_kqueue_port_deregister0(su_port_t *self, int i, int destroy_wait)
{
struct su_register **indices = self->sup_indices;
struct su_register *ser;
struct kevent ev[1];
su_wait_t *wait;
ser = self->sup_indices[i];
if (ser == NULL || ser->ser_cb == NULL) {
su_seterrno(ENOENT);
return -1;
}
assert(ser->ser_id == i);
wait = ser->ser_wait;
EV_SET(ev, wait->fd, EVFILT_READ, EV_DELETE, 0, 0, INT_TO_UDATA(i));
if (kevent(self->sup_kqueue, ev, 1, NULL, 0, NULL) == -1) {
SU_DEBUG_0(("remove kevent((%u, %s, %s, %p)) failed: %s\n",
wait->fd, "EVFILT_READ", "EV_DELETE", (void *)(intptr_t)i,
strerror(errno)));
}
EV_SET(ev, wait->fd, EVFILT_WRITE, EV_DELETE, 0, 0, INT_TO_UDATA(i));
if (kevent(self->sup_kqueue, ev, 1, NULL, 0, NULL) == -1) {
SU_DEBUG_0(("remove kevent((%u, %s, %s, %p)) failed: %s\n",
wait->fd, "EVFILT_WRITE", "EV_DELETE", (void *)(intptr_t)i,
strerror(errno)));
}
if (destroy_wait)
su_wait_destroy(wait);
memset(ser, 0, sizeof *ser);
ser->ser_id = i;
ser->ser_next = indices[0], indices[0] = ser;
self->sup_n_registrations--;
self->sup_registers++;
return i;
}
/** Unregister a su_wait_t object.
*
* The function su_kqueue_port_unregister() unregisters a su_wait_t object. The
* wait object, a callback function and a argument are removed from the
* port object.
*
* @param self - pointer to port object
* @param root - pointer to root object
* @param wait - pointer to wait object
* @param callback - callback function pointer (may be NULL)
* @param arg - argument given to callback function when it is invoked
* (may be NULL)
*
* @deprecated Use su_kqueue_port_deregister() instead.
*
* @return Nonzero index of the wait object, or -1 upon an error.
*/
int su_kqueue_port_unregister(su_port_t *self,
su_root_t *root,
su_wait_t *wait,
su_wakeup_f callback, /* XXX - ignored */
su_wakeup_arg_t *arg)
{
int i, I;
struct su_register *ser;
assert(self);
assert(su_port_own_thread(self));
I = self->sup_max_index;
for (i = 1; i <= I; i++) {
ser = self->sup_indices[i];
if (ser->ser_cb &&
arg == ser->ser_arg &&
SU_WAIT_CMP(wait[0], ser->ser_wait[0]) == 0)
return su_kqueue_port_deregister0(self, ser->ser_id, 0);
}
su_seterrno(ENOENT);
return -1;
}
/** Deregister a su_wait_t object.
*
* Deregisters a registration by index. The wait object, a callback
* function and a argument are removed from the port object. The wait
* object is destroyed.
*
* @param self - pointer to port object
* @param i - registration index
*
* @return Index of the wait object, or -1 upon an error.
*/
int su_kqueue_port_deregister(su_port_t *self, int i)
{
struct su_register *ser;
if (i <= 0 || i > self->sup_max_index)
return su_seterrno(EBADF);
ser = self->sup_indices[i];
if (!ser->ser_cb)
return su_seterrno(EBADF);
return su_kqueue_port_deregister0(self, i, 1);
}
/** @internal
* Unregister all su_wait_t objects belonging to a root.
*
* The function su_kqueue_port_unregister_all() unregisters all su_wait_t objects
* and destroys all queued timers associated with given root object.
*
* @param self - pointer to port object
* @param root - pointer to root object
*
* @return Number of wait objects removed.
*/
int su_kqueue_port_unregister_all(su_port_t *self,
su_root_t *root)
{
int i, I, n;
struct su_register *ser;
assert(self); assert(root);
assert(su_port_own_thread(self));
I = self->sup_max_index;
for (i = 1, n = 0; i <= I; i++) {
ser = self->sup_indices[i];
if (ser->ser_root != root)
continue;
su_kqueue_port_deregister0(self, ser->ser_id, 0);
n++;
}
return n;
}
/**Set mask for a registered event. @internal
*
* The function su_kqueue_port_eventmask() sets the mask describing events
* that can signal the registered callback.
*
* @param port pointer to port object
* @param index registration index
* @param socket socket
* @param events new event mask
*
* @retval 0 when successful,
* @retval -1 upon an error.
*/
int su_kqueue_port_eventmask(su_port_t *self, int index, int socket, int events)
{
struct su_register *ser;
struct kevent ev[1];
su_wait_t *wait;
int flags;
if (index <= 0 || index > self->sup_max_index)
return su_seterrno(EBADF);
ser = self->sup_indices[index];
if (!ser->ser_cb)
return su_seterrno(EBADF);
wait = ser->ser_wait;
assert(socket == wait->fd);
wait->events = events;
flags = (wait->events & SU_WAIT_IN) ? EV_ADD | EV_ENABLE : EV_ADD | EV_DISABLE;
EV_SET(ev, wait->fd, EVFILT_READ, flags, 0, 0, INT_TO_UDATA(index));
if (kevent(self->sup_kqueue, ev, 1, NULL, 0, NULL) == -1) {
SU_DEBUG_0(("modify kevent((%u, %s, %s, %p)) failed: %s\n",
wait->fd, "EVFILT_READ",
(events & SU_WAIT_IN) ? "EV_ENABLE" : "EV_DISABLE",
(void *)(intptr_t)index, strerror(errno)));
}
flags = (wait->events & SU_WAIT_OUT) ? EV_ADD | EV_ENABLE : EV_ADD | EV_DISABLE;
EV_SET(ev, wait->fd, EVFILT_WRITE, flags, 0, 0, INT_TO_UDATA(index));
if (kevent(self->sup_kqueue, ev, 1, NULL, 0, NULL) == -1) {
SU_DEBUG_0(("modify kevent((%u, %s, %s, %p)) failed: %s\n",
wait->fd, "EVFILT_WRITE",
(events & SU_WAIT_OUT) ? "EV_ENABLE" : "EV_DISABLE",
(void *)(intptr_t)index, strerror(errno)));
}
return 0;
}
/** @internal Enable multishot mode.
*
* Enables, disables or queries the multishot mode for the port. The
* multishot mode determines how the events are scheduled by port. If
* multishot mode is enabled, port serves all the sockets that have received
* network events. If it is disabled, only first socket event is served.
*
* @param self pointer to port object
* @param multishot multishot mode (0 => disables, 1 => enables, -1 => query)
*
* @retval 0 multishot mode is disabled
* @retval 1 multishot mode is enabled
* @retval -1 an error occurred
*/
static
int su_kqueue_port_multishot(su_port_t *self, int multishot)
{
if (multishot < 0)
return self->sup_multishot;
else if (multishot == 0 || multishot == 1)
return self->sup_multishot = multishot;
else
return (errno = EINVAL), -1;
}
/** @internal
* Wait (kqueue()) for wait objects in port.
*
* @param self pointer to port
* @param tout timeout in milliseconds
*
* @return number of events handled
*/
static
int su_kqueue_port_wait_events(su_port_t *self, su_duration_t tout)
{
int j, n, events = 0, index;
unsigned version = self->sup_registers;
int const M = 4;
struct kevent ev[M];
struct timespec ts;
ts.tv_sec = tout / 1000;
ts.tv_nsec = tout % 1000 * 1000000;
n = kevent(self->sup_kqueue, NULL, 0,
ev, self->sup_multishot ? M : 1,
tout < SU_DURATION_MAX ? &ts : NULL);
assert(n <= M);
for (j = 0; j < n; j++) {
struct su_register *ser;
su_root_magic_t *magic;
index = (int)(intptr_t)ev[j].udata;
if (index <= 0 || self->sup_max_index < index)
continue;
ser = self->sup_indices[index];
magic = ser->ser_root ? su_root_magic(ser->ser_root) : NULL;
ser->ser_wait->revents =
(ser->ser_wait->events | SU_WAIT_HUP) &
(
((ev[j].filter == EVFILT_READ) ? SU_WAIT_IN : 0) |
((ev[j].filter == EVFILT_WRITE) ? SU_WAIT_OUT : 0) |
((ev[j].flags & EV_EOF) ? SU_WAIT_HUP : 0)
);
if (ser->ser_wait->revents) {
ser->ser_cb(magic, ser->ser_wait, ser->ser_arg);
events++;
if (version != self->sup_registers)
/* Callback function used su_register()/su_deregister() */
return events;
}
}
return n;
}
/** Create a port using kqueue() (or poll()/select(), if kqueue() fails).
*/
su_port_t *su_kqueue_port_create(void)
{
su_port_t *self = NULL;
int kq = kqueue();
if (kq < 0) {
#if HAVE_POLL
return su_poll_port_create();
#else
return su_select_port_create();
#endif
}
self = su_home_new(sizeof *self);
if (!self)
goto failed;
if (su_home_destructor(su_port_home(self), su_kqueue_port_deinit) < 0)
goto failed;
self->sup_kqueue = kq, kq = -1;
self->sup_indices = su_zalloc(su_port_home(self),
(sizeof self->sup_indices[0]) *
(self->sup_size_indices = 64));
if (!self->sup_indices)
goto failed;
if (su_socket_port_init(self->sup_base, su_kqueue_port_vtable) < 0)
goto failed;
self->sup_multishot = SU_ENABLE_MULTISHOT_KQUEUE;
return self;
failed:
if (kq != -1)
close(kq);
su_home_unref(su_port_home(self));
return NULL;
}
int su_kqueue_clone_start(su_root_t *parent,
su_clone_r return_clone,
su_root_magic_t *magic,
su_root_init_f init,
su_root_deinit_f deinit)
{
return su_pthreaded_port_start(su_kqueue_port_create,
parent, return_clone, magic, init, deinit);
}
#else
su_port_t *su_kqueue_port_create(void)
{
return su_default_port_create();
}
int su_kqueue_clone_start(su_root_t *parent,
su_clone_r return_clone,
su_root_magic_t *magic,
su_root_init_f init,
su_root_deinit_f deinit)
{
return su_default_clone_start(parent, return_clone, magic, init, deinit);
}
#endif /* HAVE_KQUEUE */
View Git Blame Copy Permalink