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asterisk/channels/chan_h323.c

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/*
* Asterisk -- An open source telephony toolkit.
*
* Copyright (C) 1999 - 2005
*
* OpenH323 Channel Driver for ASTERISK PBX.
* By Jeremy McNamara
* For The NuFone Network
*
* chan_h323 has been derived from code created by
* Michael Manousos and Mark Spencer
*
* 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 This file is part of the chan_h323 driver for Asterisk
*
* \author Jeremy McNamara
*
* \par See also
* \arg Config_h323
*
* \ingroup channel_drivers
*/
/*** MODULEINFO
<depend>openh323</depend>
<defaultenabled>no</defaultenabled>
***/
#ifdef __cplusplus
extern "C" {
#endif
#include "asterisk.h"
ASTERISK_FILE_VERSION(__FILE__, "$Revision$")
#ifdef __cplusplus
}
#endif
#include <sys/socket.h>
#include <sys/signal.h>
#include <sys/param.h>
#if defined(BSD)
#ifndef IPTOS_MINCOST
#define IPTOS_MINCOST 0x02
#endif
#endif
#include <arpa/inet.h>
#include <net/if.h>
#include <netinet/in.h>
#include <netinet/in_systm.h>
#include <netinet/ip.h>
#include <unistd.h>
#include <stdlib.h>
#include <netdb.h>
#include <stdio.h>
#include <string.h>
#include <errno.h>
#include <fcntl.h>
#ifdef __cplusplus
extern "C" {
#endif
#include "asterisk/lock.h"
#include "asterisk/logger.h"
#include "asterisk/channel.h"
#include "asterisk/config.h"
#include "asterisk/module.h"
#include "asterisk/musiconhold.h"
#include "asterisk/pbx.h"
#include "asterisk/options.h"
#include "asterisk/utils.h"
#include "asterisk/lock.h"
#include "asterisk/sched.h"
#include "asterisk/io.h"
#include "asterisk/rtp.h"
#include "asterisk/acl.h"
#include "asterisk/callerid.h"
#include "asterisk/cli.h"
#include "asterisk/dsp.h"
#include "asterisk/causes.h"
#include "asterisk/stringfields.h"
#include "asterisk/abstract_jb.h"
#include "asterisk/astobj.h"
#ifdef __cplusplus
}
#endif
#include "h323/chan_h323.h"
receive_digit_cb on_receive_digit;
on_rtp_cb on_external_rtp_create;
start_rtp_cb on_start_rtp_channel;
setup_incoming_cb on_incoming_call;
setup_outbound_cb on_outgoing_call;
chan_ringing_cb on_chan_ringing;
con_established_cb on_connection_established;
clear_con_cb on_connection_cleared;
answer_call_cb on_answer_call;
progress_cb on_progress;
rfc2833_cb on_set_rfc2833_payload;
hangup_cb on_hangup;
setcapabilities_cb on_setcapabilities;
setpeercapabilities_cb on_setpeercapabilities;
/* global debug flag */
int h323debug;
/*! Global jitterbuffer configuration - by default, jb is disabled */
static struct ast_jb_conf default_jbconf =
{
.flags = 0,
.max_size = -1,
.resync_threshold = -1,
.impl = ""
};
static struct ast_jb_conf global_jbconf;
/** Variables required by Asterisk */
static const char tdesc[] = "The NuFone Network's Open H.323 Channel Driver";
static const char config[] = "h323.conf";
static char default_context[AST_MAX_CONTEXT] = "default";
static struct sockaddr_in bindaddr;
#define GLOBAL_CAPABILITY (AST_FORMAT_G723_1 | AST_FORMAT_GSM | AST_FORMAT_ULAW | AST_FORMAT_ALAW | AST_FORMAT_G729A | AST_FORMAT_H261)
/** H.323 configuration values */
static int h323_signalling_port = 1720;
static char gatekeeper[100];
static int gatekeeper_disable = 1;
static int gatekeeper_discover = 0;
static int gkroute = 0;
/* Find user by alias (h.323 id) is default, alternative is the incomming call's source IP address*/
static int userbyalias = 1;
static int acceptAnonymous = 1;
static int tos = 0;
static char secret[50];
static unsigned int unique = 0;
static call_options_t global_options;
/** Private structure of a OpenH323 channel */
struct oh323_pvt {
ast_mutex_t lock; /* Channel private lock */
call_options_t options; /* Options to be used during call setup */
int alreadygone; /* Whether or not we've already been destroyed by our peer */
int needdestroy; /* if we need to be destroyed */
call_details_t cd; /* Call details */
struct ast_channel *owner; /* Who owns us */
struct sockaddr_in sa; /* Our peer */
struct sockaddr_in redirip; /* Where our RTP should be going if not to us */
int nonCodecCapability; /* non-audio capability */
int outgoing; /* Outgoing or incoming call? */
char exten[AST_MAX_EXTENSION]; /* Requested extension */
char context[AST_MAX_CONTEXT]; /* Context where to start */
char accountcode[256]; /* Account code */
char rdnis[80]; /* Referring DNIS, if available */
int amaflags; /* AMA Flags */
struct ast_rtp *rtp; /* RTP Session */
struct ast_dsp *vad; /* Used for in-band DTMF detection */
int nativeformats; /* Codec formats supported by a channel */
int needhangup; /* Send hangup when Asterisk is ready */
int hangupcause; /* Hangup cause from OpenH323 layer */
int newstate; /* Pending state change */
int newcontrol; /* Pending control to send */
int newdigit; /* Pending DTMF digit to send */
int newduration; /* Pending DTMF digit duration to send */
int pref_codec; /* Preferred codec */
int peercapability; /* Capabilities learned from peer */
int jointcapability; /* Common capabilities for local and remote side */
int dtmf_pt; /* Payload code used for RFC2833 messages */
int curDTMF; /* DTMF tone being generated to Asterisk side */
int DTMFsched; /* Scheduler descriptor for DTMF */
int update_rtp_info; /* Configuration of fd's array is pending */
int recvonly; /* Peer isn't wish to receive our voice stream */
int txDtmfDigit; /* DTMF digit being to send to H.323 side */
int noInbandDtmf; /* Inband DTMF processing by DSP isn't available */
int connection_established; /* Call got CONNECT message */
struct oh323_pvt *next; /* Next channel in list */
} *iflist = NULL;
static struct ast_user_list {
ASTOBJ_CONTAINER_COMPONENTS(struct oh323_user);
} userl;
static struct ast_peer_list {
ASTOBJ_CONTAINER_COMPONENTS(struct oh323_peer);
} peerl;
static struct ast_alias_list {
ASTOBJ_CONTAINER_COMPONENTS(struct oh323_alias);
} aliasl;
/** Asterisk RTP stuff */
static struct sched_context *sched;
static struct io_context *io;
/** Protect the interface list (oh323_pvt) */
AST_MUTEX_DEFINE_STATIC(iflock);
/* Protect the monitoring thread, so only one process can kill or start it, and not
when it's doing something critical. */
AST_MUTEX_DEFINE_STATIC(monlock);
/* Protect the H.323 capabilities list, to avoid more than one channel to set the capabilities simultaneaously in the h323 stack. */
AST_MUTEX_DEFINE_STATIC(caplock);
/* Protect the reload process */
AST_MUTEX_DEFINE_STATIC(h323_reload_lock);
static int h323_reloading = 0;
/* This is the thread for the monitor which checks for input on the channels
which are not currently in use. */
static pthread_t monitor_thread = AST_PTHREADT_NULL;
static int restart_monitor(void);
static int h323_do_reload(void);
static struct ast_channel *oh323_request(const char *type, int format, void *data, int *cause);
static int oh323_digit_begin(struct ast_channel *c, char digit);
static int oh323_digit_end(struct ast_channel *c, char digit);
static int oh323_call(struct ast_channel *c, char *dest, int timeout);
static int oh323_hangup(struct ast_channel *c);
static int oh323_answer(struct ast_channel *c);
static struct ast_frame *oh323_read(struct ast_channel *c);
static int oh323_write(struct ast_channel *c, struct ast_frame *frame);
static int oh323_indicate(struct ast_channel *c, int condition, const void *data, size_t datalen);
static int oh323_fixup(struct ast_channel *oldchan, struct ast_channel *newchan);
static const struct ast_channel_tech oh323_tech = {
.type = "H323",
.description = tdesc,
.capabilities = ((AST_FORMAT_MAX_AUDIO << 1) - 1),
.properties = AST_CHAN_TP_WANTSJITTER | AST_CHAN_TP_CREATESJITTER,
.requester = oh323_request,
.send_digit_begin = oh323_digit_begin,
.send_digit_end = oh323_digit_end,
.call = oh323_call,
.hangup = oh323_hangup,
.answer = oh323_answer,
.read = oh323_read,
.write = oh323_write,
.indicate = oh323_indicate,
.fixup = oh323_fixup,
/* disable, for now */
#if 0
.bridge = ast_rtp_bridge,
#endif
};
static const char* redirectingreason2str(int redirectingreason)
{
switch (redirectingreason) {
case 0:
return "UNKNOWN";
case 1:
return "BUSY";
case 2:
return "NO_REPLY";
case 0xF:
return "UNCONDITIONAL";
default:
return "NOREDIRECT";
}
}
static void oh323_destroy_alias(struct oh323_alias *alias)
{
if (h323debug)
ast_log(LOG_DEBUG, "Destroying alias '%s'\n", alias->name);
free(alias);
}
static void oh323_destroy_user(struct oh323_user *user)
{
if (h323debug)
ast_log(LOG_DEBUG, "Destroying user '%s'\n", user->name);
ast_free_ha(user->ha);
free(user);
}
static void oh323_destroy_peer(struct oh323_peer *peer)
{
if (h323debug)
ast_log(LOG_DEBUG, "Destroying peer '%s'\n", peer->name);
ast_free_ha(peer->ha);
free(peer);
}
static int oh323_simulate_dtmf_end(void *data)
{
struct oh323_pvt *pvt = data;
if (pvt) {
ast_mutex_lock(&pvt->lock);
/* Don't hold pvt lock while trying to lock the channel */
while(pvt->owner && ast_channel_trylock(pvt->owner)) {
ast_mutex_unlock(&pvt->lock);
usleep(1);
ast_mutex_lock(&pvt->lock);
}
if (pvt->owner) {
struct ast_frame f = {
.frametype = AST_FRAME_DTMF_END,
.subclass = pvt->curDTMF,
.samples = 0,
.src = "SIMULATE_DTMF_END",
};
ast_queue_frame(pvt->owner, &f);
ast_channel_unlock(pvt->owner);
}
pvt->DTMFsched = -1;
ast_mutex_unlock(&pvt->lock);
}
return 0;
}
/* Channel and private structures should be already locked */
static void __oh323_update_info(struct ast_channel *c, struct oh323_pvt *pvt)
{
if (c->nativeformats != pvt->nativeformats) {
if (h323debug)
ast_log(LOG_DEBUG, "Preparing %s for new native format\n", c->name);
c->nativeformats = pvt->nativeformats;
ast_set_read_format(c, c->readformat);
ast_set_write_format(c, c->writeformat);
}
if (pvt->needhangup) {
if (h323debug)
ast_log(LOG_DEBUG, "Process pending hangup for %s\n", c->name);
c->_softhangup |= AST_SOFTHANGUP_DEV;
c->hangupcause = pvt->hangupcause;
ast_queue_hangup(c);
pvt->needhangup = 0;
pvt->newstate = pvt->newcontrol = pvt->newdigit = pvt->DTMFsched = -1;
}
if (pvt->newstate >= 0) {
ast_setstate(c, pvt->newstate);
pvt->newstate = -1;
}
if (pvt->newcontrol >= 0) {
ast_queue_control(c, pvt->newcontrol);
pvt->newcontrol = -1;
}
if (pvt->newdigit >= 0) {
struct ast_frame f = {
.frametype = AST_FRAME_DTMF_END,
.subclass = pvt->newdigit,
.samples = pvt->newduration * 8,
.src = "UPDATE_INFO",
};
if (pvt->newdigit == ' ') { /* signalUpdate message */
f.subclass = pvt->curDTMF;
if (pvt->DTMFsched >= 0) {
ast_sched_del(sched, pvt->DTMFsched);
pvt->DTMFsched = -1;
}
} else { /* Regular input or signal message */
if (pvt->newduration) { /* This is a signal, signalUpdate follows */
f.frametype = AST_FRAME_DTMF_BEGIN;
if (pvt->DTMFsched >= 0)
ast_sched_del(sched, pvt->DTMFsched);
pvt->DTMFsched = ast_sched_add(sched, pvt->newduration, oh323_simulate_dtmf_end, pvt);
if (h323debug)
ast_log(LOG_DTMF, "Scheduled DTMF END simulation for %d ms, id=%d\n", pvt->newduration, pvt->DTMFsched);
}
pvt->curDTMF = pvt->newdigit;
}
ast_queue_frame(c, &f);
pvt->newdigit = -1;
}
if (pvt->update_rtp_info > 0) {
if (pvt->rtp) {
ast_jb_configure(c, &global_jbconf);
c->fds[0] = ast_rtp_fd(pvt->rtp);
c->fds[1] = ast_rtcp_fd(pvt->rtp);
ast_queue_frame(pvt->owner, &ast_null_frame); /* Tell Asterisk to apply changes */
}
pvt->update_rtp_info = -1;
}
}
/* Only channel structure should be locked */
static void oh323_update_info(struct ast_channel *c)
{
struct oh323_pvt *pvt = c->tech_pvt;
if (pvt) {
ast_mutex_lock(&pvt->lock);
__oh323_update_info(c, pvt);
ast_mutex_unlock(&pvt->lock);
}
}
static void cleanup_call_details(call_details_t *cd)
{
if (cd->call_token) {
free(cd->call_token);
cd->call_token = NULL;
}
if (cd->call_source_aliases) {
free(cd->call_source_aliases);
cd->call_source_aliases = NULL;
}
if (cd->call_dest_alias) {
free(cd->call_dest_alias);
cd->call_dest_alias = NULL;
}
if (cd->call_source_name) {
free(cd->call_source_name);
cd->call_source_name = NULL;
}
if (cd->call_source_e164) {
free(cd->call_source_e164);
cd->call_source_e164 = NULL;
}
if (cd->call_dest_e164) {
free(cd->call_dest_e164);
cd->call_dest_e164 = NULL;
}
if (cd->sourceIp) {
free(cd->sourceIp);
cd->sourceIp = NULL;
}
if (cd->redirect_number) {
free(cd->redirect_number);
cd->redirect_number = NULL;
}
}
static void __oh323_destroy(struct oh323_pvt *pvt)
{
struct oh323_pvt *cur, *prev = NULL;
if (pvt->DTMFsched >= 0) {
ast_sched_del(sched, pvt->DTMFsched);
pvt->DTMFsched = -1;
}
if (pvt->rtp) {
ast_rtp_destroy(pvt->rtp);
}
/* Free dsp used for in-band DTMF detection */
if (pvt->vad) {
ast_dsp_free(pvt->vad);
}
cleanup_call_details(&pvt->cd);
/* Unlink us from the owner if we have one */
if (pvt->owner) {
ast_channel_lock(pvt->owner);
if (h323debug)
ast_log(LOG_DEBUG, "Detaching from %s\n", pvt->owner->name);
pvt->owner->tech_pvt = NULL;
ast_channel_unlock(pvt->owner);
}
cur = iflist;
while(cur) {
if (cur == pvt) {
if (prev)
prev->next = cur->next;
else
iflist = cur->next;
break;
}
prev = cur;
cur = cur->next;
}
if (!cur) {
ast_log(LOG_WARNING, "%p is not in list?!?! \n", cur);
} else {
ast_mutex_unlock(&pvt->lock);
ast_mutex_destroy(&pvt->lock);
free(pvt);
}
}
static void oh323_destroy(struct oh323_pvt *pvt)
{
if (h323debug) {
ast_log(LOG_DEBUG, "Destroying channel %s\n", (pvt->owner ? pvt->owner->name : "<unknown>"));
}
ast_mutex_lock(&iflock);
ast_mutex_lock(&pvt->lock);
__oh323_destroy(pvt);
ast_mutex_unlock(&iflock);
}
static int oh323_digit_begin(struct ast_channel *c, char digit)
{
struct oh323_pvt *pvt = (struct oh323_pvt *) c->tech_pvt;
char *token;
if (!pvt) {
ast_log(LOG_ERROR, "No private structure?! This is bad\n");
return -1;
}
ast_mutex_lock(&pvt->lock);
if (pvt->rtp && (pvt->options.dtmfmode & H323_DTMF_RFC2833) && (pvt->dtmf_pt > 0)) {
/* out-of-band DTMF */
if (h323debug) {
ast_log(LOG_DTMF, "Begin sending out-of-band digit %c on %s\n", digit, c->name);
}
ast_rtp_senddigit_begin(pvt->rtp, digit);
ast_mutex_unlock(&pvt->lock);
} else if (pvt->txDtmfDigit != digit) {
/* in-band DTMF */
if (h323debug) {
ast_log(LOG_DTMF, "Begin sending inband digit %c on %s\n", digit, c->name);
}
pvt->txDtmfDigit = digit;
token = pvt->cd.call_token ? strdup(pvt->cd.call_token) : NULL;
ast_mutex_unlock(&pvt->lock);
h323_send_tone(token, digit);
if (token) {
free(token);
}
} else
ast_mutex_unlock(&pvt->lock);
oh323_update_info(c);
return 0;
}
/**
* Send (play) the specified digit to the channel.
*
*/
static int oh323_digit_end(struct ast_channel *c, char digit)
{
struct oh323_pvt *pvt = (struct oh323_pvt *) c->tech_pvt;
char *token;
if (!pvt) {
ast_log(LOG_ERROR, "No private structure?! This is bad\n");
return -1;
}
ast_mutex_lock(&pvt->lock);
if (pvt->rtp && (pvt->options.dtmfmode & H323_DTMF_RFC2833) && (pvt->dtmf_pt > 0)) {
/* out-of-band DTMF */
if (h323debug) {
ast_log(LOG_DTMF, "End sending out-of-band digit %c on %s\n", digit, c->name);
}
ast_rtp_senddigit_end(pvt->rtp, digit);
ast_mutex_unlock(&pvt->lock);
} else {
/* in-band DTMF */
if (h323debug) {
ast_log(LOG_DTMF, "End sending inband digit %c on %s\n", digit, c->name);
}
pvt->txDtmfDigit = ' ';
token = pvt->cd.call_token ? strdup(pvt->cd.call_token) : NULL;
ast_mutex_unlock(&pvt->lock);
h323_send_tone(token, ' ');
if (token) {
free(token);
}
}
oh323_update_info(c);
return 0;
}
/**
* Make a call over the specified channel to the specified
* destination.
* Returns -1 on error, 0 on success.
*/
static int oh323_call(struct ast_channel *c, char *dest, int timeout)
{
int res = 0;
struct oh323_pvt *pvt = (struct oh323_pvt *)c->tech_pvt;
const char *addr;
char called_addr[1024];
if (h323debug) {
ast_log(LOG_DEBUG, "Calling to %s on %s\n", dest, c->name);
}
if ((c->_state != AST_STATE_DOWN) && (c->_state != AST_STATE_RESERVED)) {
ast_log(LOG_WARNING, "Line is already in use (%s)\n", c->name);
return -1;
}
ast_mutex_lock(&pvt->lock);
if (!gatekeeper_disable) {
if (ast_strlen_zero(pvt->exten)) {
strncpy(called_addr, dest, sizeof(called_addr));
} else {
snprintf(called_addr, sizeof(called_addr), "%s@%s", pvt->exten, dest);
}
} else {
res = htons(pvt->sa.sin_port);
addr = ast_inet_ntoa(pvt->sa.sin_addr);
if (ast_strlen_zero(pvt->exten)) {
snprintf(called_addr, sizeof(called_addr), "%s:%d", addr, res);
} else {
snprintf(called_addr, sizeof(called_addr), "%s@%s:%d", pvt->exten, addr, res);
}
}
/* make sure null terminated */
called_addr[sizeof(called_addr) - 1] = '\0';
if (c->cid.cid_num)
strncpy(pvt->options.cid_num, c->cid.cid_num, sizeof(pvt->options.cid_num));
if (c->cid.cid_name)
strncpy(pvt->options.cid_name, c->cid.cid_name, sizeof(pvt->options.cid_name));
if (c->cid.cid_rdnis) {
strncpy(pvt->options.cid_rdnis, c->cid.cid_rdnis, sizeof(pvt->options.cid_rdnis));
}
if ((addr = pbx_builtin_getvar_helper(c, "PRIREDIRECTREASON"))) {
if (!strcasecmp(addr, "UNKNOWN"))
pvt->options.redirect_reason = 0;
else if (!strcasecmp(addr, "BUSY"))
pvt->options.redirect_reason = 1;
else if (!strcasecmp(addr, "NO_REPLY"))
pvt->options.redirect_reason = 2;
else if (!strcasecmp(addr, "UNCONDITIONAL"))
pvt->options.redirect_reason = 15;
else
pvt->options.redirect_reason = -1;
} else
pvt->options.redirect_reason = -1;
/* indicate that this is an outgoing call */
pvt->outgoing = 1;
if (h323debug)
ast_log(LOG_DEBUG, "Placing outgoing call to %s, %d\n", called_addr, pvt->options.dtmfcodec);
ast_mutex_unlock(&pvt->lock);
res = h323_make_call(called_addr, &(pvt->cd), &pvt->options);
if (res) {
ast_log(LOG_NOTICE, "h323_make_call failed(%s)\n", c->name);
return -1;
}
oh323_update_info(c);
return 0;
}
static int oh323_answer(struct ast_channel *c)
{
int res;
struct oh323_pvt *pvt = (struct oh323_pvt *) c->tech_pvt;
char *token;
if (h323debug)
ast_log(LOG_DEBUG, "Answering on %s\n", c->name);
ast_mutex_lock(&pvt->lock);
token = pvt->cd.call_token ? strdup(pvt->cd.call_token) : NULL;
ast_mutex_unlock(&pvt->lock);
res = h323_answering_call(token, 0);
if (token)
free(token);
oh323_update_info(c);
if (c->_state != AST_STATE_UP) {
ast_setstate(c, AST_STATE_UP);
}
return res;
}
static int oh323_hangup(struct ast_channel *c)
{
struct oh323_pvt *pvt = (struct oh323_pvt *) c->tech_pvt;
int q931cause = AST_CAUSE_NORMAL_CLEARING;
char *call_token;
if (h323debug)
ast_log(LOG_DEBUG, "Hanging up and scheduling destroy of call %s\n", c->name);
if (!c->tech_pvt) {
ast_log(LOG_WARNING, "Asked to hangup channel not connected\n");
return 0;
}
ast_mutex_lock(&pvt->lock);
/* Determine how to disconnect */
if (pvt->owner != c) {
ast_log(LOG_WARNING, "Huh? We aren't the owner?\n");
ast_mutex_unlock(&pvt->lock);
return 0;
}
pvt->owner = NULL;
c->tech_pvt = NULL;
if (c->hangupcause) {
q931cause = c->hangupcause;
} else {
const char *cause = pbx_builtin_getvar_helper(c, "DIALSTATUS");
if (cause) {
if (!strcmp(cause, "CONGESTION")) {
q931cause = AST_CAUSE_NORMAL_CIRCUIT_CONGESTION;
} else if (!strcmp(cause, "BUSY")) {
q931cause = AST_CAUSE_USER_BUSY;
} else if (!strcmp(cause, "CHANISUNVAIL")) {
q931cause = AST_CAUSE_REQUESTED_CHAN_UNAVAIL;
} else if (!strcmp(cause, "NOANSWER")) {
q931cause = AST_CAUSE_NO_ANSWER;
} else if (!strcmp(cause, "CANCEL")) {
q931cause = AST_CAUSE_CALL_REJECTED;
}
}
}
/* Start the process if it's not already started */
if (!pvt->alreadygone && !pvt->hangupcause) {
call_token = pvt->cd.call_token ? strdup(pvt->cd.call_token) : NULL;
if (call_token) {
/* Release lock to eliminate deadlock */
ast_mutex_unlock(&pvt->lock);
if (h323_clear_call(call_token, q931cause)) {
ast_log(LOG_WARNING, "ClearCall failed.\n");
}
free(call_token);
ast_mutex_lock(&pvt->lock);
}
}
pvt->needdestroy = 1;
ast_mutex_unlock(&pvt->lock);
/* Update usage counter */
ast_module_unref(ast_module_info->self);
return 0;
}
static struct ast_frame *oh323_rtp_read(struct oh323_pvt *pvt)
{
/* Retrieve audio/etc from channel. Assumes pvt->lock is already held. */
struct ast_frame *f;
/* Only apply it for the first packet, we just need the correct ip/port */
if (pvt->options.nat) {
ast_rtp_setnat(pvt->rtp, pvt->options.nat);
pvt->options.nat = 0;
}
f = ast_rtp_read(pvt->rtp);
/* Don't send RFC2833 if we're not supposed to */
if (f && (f->frametype == AST_FRAME_DTMF) && !(pvt->options.dtmfmode & H323_DTMF_RFC2833)) {
return &ast_null_frame;
}
if (pvt->owner) {
/* We already hold the channel lock */
if (f->frametype == AST_FRAME_VOICE) {
if (f->subclass != pvt->owner->nativeformats) {
/* Try to avoid deadlock */
if (ast_channel_trylock(pvt->owner)) {
ast_log(LOG_NOTICE, "Format changed but channel is locked. Ignoring frame...\n");
return &ast_null_frame;
}
if (h323debug)
ast_log(LOG_DEBUG, "Oooh, format changed to %d\n", f->subclass);
pvt->owner->nativeformats = f->subclass;
pvt->nativeformats = f->subclass;
ast_set_read_format(pvt->owner, pvt->owner->readformat);
ast_set_write_format(pvt->owner, pvt->owner->writeformat);
ast_channel_unlock(pvt->owner);
}
/* Do in-band DTMF detection */
if ((pvt->options.dtmfmode & H323_DTMF_INBAND) && pvt->vad) {
if ((pvt->nativeformats & (AST_FORMAT_SLINEAR | AST_FORMAT_ALAW | AST_FORMAT_ULAW))) {
if (!ast_channel_trylock(pvt->owner)) {
f = ast_dsp_process(pvt->owner, pvt->vad, f);
ast_channel_unlock(pvt->owner);
}
else
ast_log(LOG_NOTICE, "Unable to process inband DTMF while channel is locked\n");
} else if (pvt->nativeformats && !pvt->noInbandDtmf) {
ast_log(LOG_NOTICE, "Inband DTMF is not supported on codec %s. Use RFC2833\n", ast_getformatname(f->subclass));
pvt->noInbandDtmf = 1;
}
if (f &&(f->frametype == AST_FRAME_DTMF)) {
if (h323debug)
ast_log(LOG_DTMF, "Received in-band digit %c.\n", f->subclass);
}
}
}
}
return f;
}
static struct ast_frame *oh323_read(struct ast_channel *c)
{
struct ast_frame *fr;
struct oh323_pvt *pvt = (struct oh323_pvt *)c->tech_pvt;
ast_mutex_lock(&pvt->lock);
__oh323_update_info(c, pvt);
switch(c->fdno) {
case 0:
fr = oh323_rtp_read(pvt);
break;
case 1:
if (pvt->rtp)
fr = ast_rtcp_read(pvt->rtp);
else
fr = &ast_null_frame;
break;
default:
ast_log(LOG_ERROR, "Unable to handle fd %d on channel %s\n", c->fdno, c->name);
fr = &ast_null_frame;
break;
}
ast_mutex_unlock(&pvt->lock);
return fr;
}
static int oh323_write(struct ast_channel *c, struct ast_frame *frame)
{
struct oh323_pvt *pvt = (struct oh323_pvt *) c->tech_pvt;
int res = 0;
if (frame->frametype != AST_FRAME_VOICE) {
if (frame->frametype == AST_FRAME_IMAGE) {
return 0;
} else {
ast_log(LOG_WARNING, "Can't send %d type frames with H323 write\n", frame->frametype);
return 0;
}
} else {
if (!(frame->subclass & c->nativeformats)) {
ast_log(LOG_WARNING, "Asked to transmit frame type %d, while native formats is %d (read/write = %d/%d)\n",
frame->subclass, c->nativeformats, c->readformat, c->writeformat);
return 0;
}
}
if (pvt) {
ast_mutex_lock(&pvt->lock);
if (pvt->rtp && !pvt->recvonly)
res = ast_rtp_write(pvt->rtp, frame);
__oh323_update_info(c, pvt);
ast_mutex_unlock(&pvt->lock);
}
return res;
}
static int oh323_indicate(struct ast_channel *c, int condition, const void *data, size_t datalen)
{
struct oh323_pvt *pvt = (struct oh323_pvt *) c->tech_pvt;
char *token = (char *)NULL;
ast_mutex_lock(&pvt->lock);
token = (pvt->cd.call_token ? strdup(pvt->cd.call_token) : NULL);
ast_mutex_unlock(&pvt->lock);
if (h323debug)
ast_log(LOG_DEBUG, "OH323: Indicating %d on %s\n", condition, token);
switch(condition) {
case AST_CONTROL_RINGING:
if (c->_state == AST_STATE_RING || c->_state == AST_STATE_RINGING) {
h323_send_alerting(token);
break;
}
if (token)
free(token);
return -1;
case AST_CONTROL_PROGRESS:
if (c->_state != AST_STATE_UP) {
h323_send_progress(token);
break;
}
if (token)
free(token);
return -1;
case AST_CONTROL_BUSY:
if (c->_state != AST_STATE_UP) {
h323_answering_call(token, 1);
ast_mutex_lock(&pvt->lock);
pvt->alreadygone = 1;
ast_mutex_unlock(&pvt->lock);
ast_softhangup_nolock(c, AST_SOFTHANGUP_DEV);
break;
}
if (token)
free(token);
return -1;
case AST_CONTROL_CONGESTION:
if (c->_state != AST_STATE_UP) {
h323_answering_call(token, 1);
ast_mutex_lock(&pvt->lock);
pvt->alreadygone = 1;
ast_mutex_unlock(&pvt->lock);
ast_softhangup_nolock(c, AST_SOFTHANGUP_DEV);
break;
}
if (token)
free(token);
return -1;
case AST_CONTROL_HOLD:
ast_moh_start(c, data, NULL);
if (token)
free(token);
return 0;
case AST_CONTROL_UNHOLD:
ast_moh_stop(c);
if (token)
free(token);
return 0;
case AST_CONTROL_PROCEEDING:
case -1:
if (token)
free(token);
return -1;
default:
ast_log(LOG_WARNING, "Don't know how to indicate condition %d on %s\n", condition, token);
if (token)
free(token);
return -1;
}
if (h323debug)
ast_log(LOG_DEBUG, "OH323: Indicated %d on %s\n", condition, token);
if (token)
free(token);
oh323_update_info(c);
return -1;
}
static int oh323_fixup(struct ast_channel *oldchan, struct ast_channel *newchan)
{
struct oh323_pvt *pvt = (struct oh323_pvt *) newchan->tech_pvt;
ast_mutex_lock(&pvt->lock);
if (pvt->owner != oldchan) {
ast_log(LOG_WARNING, "old channel wasn't %p but was %p\n", oldchan, pvt->owner);
return -1;
}
pvt->owner = newchan;
ast_mutex_unlock(&pvt->lock);
return 0;
}
static int __oh323_rtp_create(struct oh323_pvt *pvt)
{
struct in_addr our_addr;
if (pvt->rtp)
return 0;
if (ast_find_ourip(&our_addr, bindaddr)) {
ast_mutex_unlock(&pvt->lock);
ast_log(LOG_ERROR, "Unable to locate local IP address for RTP stream\n");
return -1;
}
pvt->rtp = ast_rtp_new_with_bindaddr(sched, io, 1, 0, our_addr);
if (!pvt->rtp) {
ast_mutex_unlock(&pvt->lock);
ast_log(LOG_WARNING, "Unable to create RTP session: %s\n", strerror(errno));
return -1;
}
if (h323debug)
ast_log(LOG_DEBUG, "Created RTP channel\n");
ast_rtp_settos(pvt->rtp, tos);
if (h323debug)
ast_log(LOG_DEBUG, "Setting NAT on RTP to %d\n", pvt->options.nat);
ast_rtp_setnat(pvt->rtp, pvt->options.nat);
if (pvt->dtmf_pt > 0)
ast_rtp_set_rtpmap_type(pvt->rtp, pvt->dtmf_pt, "audio", "telephone-event", 0);
if (pvt->owner && !ast_channel_trylock(pvt->owner)) {
ast_jb_configure(pvt->owner, &global_jbconf);
pvt->owner->fds[0] = ast_rtp_fd(pvt->rtp);
pvt->owner->fds[1] = ast_rtcp_fd(pvt->rtp);
ast_queue_frame(pvt->owner, &ast_null_frame); /* Tell Asterisk to apply changes */
ast_channel_unlock(pvt->owner);
} else
pvt->update_rtp_info = 1;
return 0;
}
/* Private structure should be locked on a call */
static struct ast_channel *__oh323_new(struct oh323_pvt *pvt, int state, const char *host)
{
struct ast_channel *ch;
int fmt;
/* Don't hold a oh323_pvt lock while we allocate a chanel */
ast_mutex_unlock(&pvt->lock);
ch = ast_channel_alloc(1);
/* Update usage counter */
ast_module_ref(ast_module_info->self);
ast_mutex_lock(&pvt->lock);
if (ch) {
ch->tech = &oh323_tech;
ast_string_field_build(ch, name, "H323/%s", host);
if (!(fmt = pvt->jointcapability) && !(fmt = pvt->options.capability))
fmt = global_options.capability;
ch->nativeformats = ast_codec_choose(&pvt->options.prefs, fmt, 1)/* | (pvt->jointcapability & AST_FORMAT_VIDEO_MASK)*/;
pvt->nativeformats = ch->nativeformats;
fmt = ast_best_codec(ch->nativeformats);
ch->writeformat = fmt;
ch->rawwriteformat = fmt;
ch->readformat = fmt;
ch->rawreadformat = fmt;
#if 0
ch->fds[0] = ast_rtp_fd(pvt->rtp);
ch->fds[1] = ast_rtcp_fd(pvt->rtp);
#endif
#ifdef VIDEO_SUPPORT
if (pvt->vrtp) {
ch->fds[2] = ast_rtp_fd(pvt->vrtp);
ch->fds[3] = ast_rtcp_fd(pvt->vrtp);
}
#endif
#ifdef T38_SUPPORT
if (pvt->udptl) {
ch->fds[4] = ast_udptl_fd(pvt->udptl);
}
#endif
if (state == AST_STATE_RING) {
ch->rings = 1;
}
/* Allocate dsp for in-band DTMF support */
if (pvt->options.dtmfmode & H323_DTMF_INBAND) {
pvt->vad = ast_dsp_new();
ast_dsp_set_features(pvt->vad, DSP_FEATURE_DTMF_DETECT);
}
/* Register channel functions. */
ch->tech_pvt = pvt;
/* Set the owner of this channel */
pvt->owner = ch;
strncpy(ch->context, pvt->context, sizeof(ch->context) - 1);
strncpy(ch->exten, pvt->exten, sizeof(ch->exten) - 1);
ch->priority = 1;
if (!ast_strlen_zero(pvt->accountcode)) {
ast_string_field_set(ch, accountcode, pvt->accountcode);
}
if (pvt->amaflags) {
ch->amaflags = pvt->amaflags;
}
/* Don't use ast_set_callerid() here because it will
* generate a NewCallerID event before the NewChannel event */
if (!ast_strlen_zero(pvt->options.cid_num)) {
ch->cid.cid_num = ast_strdup(pvt->options.cid_num);
ch->cid.cid_ani = ast_strdup(pvt->options.cid_num);
} else {
ch->cid.cid_num = ast_strdup(pvt->cd.call_source_e164);
ch->cid.cid_ani = ast_strdup(pvt->cd.call_source_e164);
}
if (!ast_strlen_zero(pvt->options.cid_name))
ch->cid.cid_name = ast_strdup(pvt->options.cid_name);
else
ch->cid.cid_name = ast_strdup(pvt->cd.call_source_name);
if (pvt->cd.redirect_reason >= 0) {
ch->cid.cid_rdnis = ast_strdup(pvt->cd.redirect_number);
pbx_builtin_setvar_helper(ch, "PRIREDIRECTREASON", redirectingreason2str(pvt->cd.redirect_reason));
}
if (!ast_strlen_zero(pvt->exten) && strcmp(pvt->exten, "s")) {
ch->cid.cid_dnid = strdup(pvt->exten);
}
ast_setstate(ch, state);
#if 0
if (pvt->rtp)
ast_jb_configure(ch, &global_jbconf);
#endif
if (state != AST_STATE_DOWN) {
if (ast_pbx_start(ch)) {
ast_log(LOG_WARNING, "Unable to start PBX on %s\n", ch->name);
ast_hangup(ch);
ch = NULL;
}
}
} else {
ast_log(LOG_WARNING, "Unable to allocate channel structure\n");
}
return ch;
}
static struct oh323_pvt *oh323_alloc(int callid)
{
struct oh323_pvt *pvt;
pvt = (struct oh323_pvt *) malloc(sizeof(struct oh323_pvt));
if (!pvt) {
ast_log(LOG_ERROR, "Couldn't allocate private structure. This is bad\n");
return NULL;
}
memset(pvt, 0, sizeof(struct oh323_pvt));
pvt->cd.redirect_reason = -1;
#if 0
pvt->rtp = ast_rtp_new_with_bindaddr(sched, io, 1, 0,bindaddr.sin_addr);
if (!pvt->rtp) {
ast_log(LOG_WARNING, "Unable to create RTP session: %s\n", strerror(errno));
free(pvt);
return NULL;
}
ast_rtp_settos(pvt->rtp, tos);
#endif
/* Ensure the call token is allocated for outgoing call */
if (!callid) {
if ((pvt->cd).call_token == NULL) {
(pvt->cd).call_token = (char *)malloc(128);
}
if (!pvt->cd.call_token) {
ast_log(LOG_ERROR, "Not enough memory to alocate call token\n");
ast_rtp_destroy(pvt->rtp);
free(pvt);
return NULL;
}
memset((char *)(pvt->cd).call_token, 0, 128);
pvt->cd.call_reference = callid;
}
memcpy(&pvt->options, &global_options, sizeof(pvt->options));
pvt->jointcapability = pvt->options.capability;
if (pvt->options.dtmfmode & H323_DTMF_RFC2833) {
pvt->nonCodecCapability |= AST_RTP_DTMF;
} else {
pvt->nonCodecCapability &= ~AST_RTP_DTMF;
}
strncpy(pvt->context, default_context, sizeof(pvt->context) - 1);
pvt->newstate = pvt->newcontrol = pvt->newdigit = pvt->update_rtp_info = pvt->DTMFsched = -1;
ast_mutex_init(&pvt->lock);
/* Add to interface list */
ast_mutex_lock(&iflock);
pvt->next = iflist;
iflist = pvt;
ast_mutex_unlock(&iflock);
return pvt;
}
static struct oh323_pvt *find_call_locked(int call_reference, const char *token)
{
struct oh323_pvt *pvt;
ast_mutex_lock(&iflock);
pvt = iflist;
while(pvt) {
if (!pvt->needdestroy && ((signed int)pvt->cd.call_reference == call_reference)) {
/* Found the call */
if ((token != NULL) && (!strcmp(pvt->cd.call_token, token))) {
ast_mutex_lock(&pvt->lock);
ast_mutex_unlock(&iflock);
return pvt;
} else if (token == NULL) {
ast_log(LOG_WARNING, "Call Token is NULL\n");
ast_mutex_lock(&pvt->lock);
ast_mutex_unlock(&iflock);
return pvt;
}
}
pvt = pvt->next;
}
ast_mutex_unlock(&iflock);
return NULL;
}
static int update_state(struct oh323_pvt *pvt, int state, int signal)
{
if (!pvt)
return 0;
if (pvt->owner && !ast_channel_trylock(pvt->owner)) {
if (state >= 0)
ast_setstate(pvt->owner, state);
if (signal >= 0)
ast_queue_control(pvt->owner, signal);
ast_channel_unlock(pvt->owner);
return 1;
}
else {
if (state >= 0)
pvt->newstate = state;
if (signal >= 0)
pvt->newcontrol = signal;
return 0;
}
}
static struct oh323_alias *build_alias(const char *name, struct ast_variable *v, struct ast_variable *alt, int realtime)
{
struct oh323_alias *alias;
int found = 0;
alias = ASTOBJ_CONTAINER_FIND_UNLINK_FULL(&aliasl, name, name, 0, 0, strcasecmp);
if (alias)
found++;
else {
if (!(alias = (struct oh323_alias *)calloc(1, sizeof(*alias))))
return NULL;
ASTOBJ_INIT(alias);
}
if (!found && name)
strncpy(alias->name, name, sizeof(alias->name) - 1);
for (; v || ((v = alt) && !(alt = NULL)); v = v->next) {
if (!strcasecmp(v->name, "e164")) {
strncpy(alias->e164, v->value, sizeof(alias->e164) - 1);
} else if (!strcasecmp(v->name, "prefix")) {
strncpy(alias->prefix, v->value, sizeof(alias->prefix) - 1);
} else if (!strcasecmp(v->name, "context")) {
strncpy(alias->context, v->value, sizeof(alias->context) - 1);
} else if (!strcasecmp(v->name, "secret")) {
strncpy(alias->secret, v->value, sizeof(alias->secret) - 1);
} else {
if (strcasecmp(v->value, "h323")) {
ast_log(LOG_WARNING, "Keyword %s does not make sense in type=h323\n", v->name);
}
}
}
ASTOBJ_UNMARK(alias);
return alias;
}
static struct oh323_alias *realtime_alias(const char *alias)
{
struct ast_variable *var, *tmp;
struct oh323_alias *a;
var = ast_load_realtime("h323", "name", alias, NULL);
if (!var)
return NULL;
for (tmp = var; tmp; tmp = tmp->next) {
if (!strcasecmp(tmp->name, "type") &&
!(!strcasecmp(tmp->value, "alias") || !strcasecmp(tmp->value, "h323"))) {
ast_variables_destroy(var);
return NULL;
}
}
a = build_alias(alias, var, NULL, 1);
ast_variables_destroy(var);
return a;
}
#define DEPRECATED(_v, _new_opt) \
ast_log(LOG_WARNING, "Option %s found at line %d has beed deprecated. Use %s instead.\n", (_v)->name, (_v)->lineno, (_new_opt))
static int update_common_options(struct ast_variable *v, struct call_options *options)
{
int tmp;
if (!strcasecmp(v->name, "allow")) {
ast_parse_allow_disallow(&options->prefs, &options->capability, v->value, 1);
} else if (!strcasecmp(v->name, "disallow")) {
ast_parse_allow_disallow(&options->prefs, &options->capability, v->value, 0);
} else if (!strcasecmp(v->name, "dtmfmode")) {
if (!strcasecmp(v->value, "inband")) {
options->dtmfmode = H323_DTMF_INBAND;
} else if (!strcasecmp(v->value, "rfc2833")) {
options->dtmfmode = H323_DTMF_RFC2833;
} else {
ast_log(LOG_WARNING, "Unknown dtmf mode '%s', using rfc2833\n", v->value);
options->dtmfmode = H323_DTMF_RFC2833;
}
} else if (!strcasecmp(v->name, "dtmfcodec")) {
tmp = atoi(v->value);
if (tmp < 96)
ast_log(LOG_WARNING, "Invalid %s value %s at line %d\n", v->name, v->value, v->lineno);
else
options->dtmfcodec = tmp;
} else if (!strcasecmp(v->name, "bridge")) {
options->bridge = ast_true(v->value);
} else if (!strcasecmp(v->name, "nat")) {
options->nat = ast_true(v->value);
} else if (!strcasecmp(v->name, "noFastStart")) {
DEPRECATED(v, "fastStart");
options->fastStart = !ast_true(v->value);
} else if (!strcasecmp(v->name, "fastStart")) {
options->fastStart = ast_true(v->value);
} else if (!strcasecmp(v->name, "noH245Tunneling")) {
DEPRECATED(v, "h245Tunneling");
options->h245Tunneling = !ast_true(v->value);
} else if (!strcasecmp(v->name, "h245Tunneling")) {
options->h245Tunneling = ast_true(v->value);
} else if (!strcasecmp(v->name, "noSilenceSuppression")) {
DEPRECATED(v, "silenceSuppression");
options->silenceSuppression = !ast_true(v->value);
} else if (!strcasecmp(v->name, "silenceSuppression")) {
options->silenceSuppression = ast_true(v->value);
} else if (!strcasecmp(v->name, "progress_setup")) {
tmp = atoi(v->value);
if ((tmp != 0) && (tmp != 1) && (tmp != 3) && (tmp != 8)) {
ast_log(LOG_WARNING, "Invalid value %s for %s at line %d, assuming 0\n", v->value, v->name, v->lineno);
tmp = 0;
}
options->progress_setup = tmp;
} else if (!strcasecmp(v->name, "progress_alert")) {
tmp = atoi(v->value);
if ((tmp != 0) && (tmp != 1) && (tmp != 8)) {
ast_log(LOG_WARNING, "Invalid value %s for %s at line %d, assuming 0\n", v->value, v->name, v->lineno);
tmp = 0;
}
options->progress_alert = tmp;
} else if (!strcasecmp(v->name, "progress_audio")) {
options->progress_audio = ast_true(v->value);
} else if (!strcasecmp(v->name, "callerid")) {
ast_callerid_split(v->value, options->cid_name, sizeof(options->cid_name), options->cid_num, sizeof(options->cid_num));
} else if (!strcasecmp(v->name, "fullname")) {
ast_copy_string(options->cid_name, v->value, sizeof(options->cid_name));
} else if (!strcasecmp(v->name, "cid_number")) {
ast_copy_string(options->cid_num, v->value, sizeof(options->cid_num));
} else if (!strcasecmp(v->name, "tunneling")) {
if (!strcasecmp(v->value, "none"))
options->tunnelOptions = 0;
else if (!strcasecmp(v->value, "cisco"))
options->tunnelOptions |= H323_TUNNEL_CISCO;
else if (!strcasecmp(v->value, "qsig"))
options->tunnelOptions |= H323_TUNNEL_QSIG;
else
ast_log(LOG_WARNING, "Invalid value %s for %s at line %d\n", v->value, v->name, v->lineno);
} else
return 1;
return 0;
}
#undef DEPRECATED
static struct oh323_user *build_user(char *name, struct ast_variable *v, struct ast_variable *alt, int realtime)
{
struct oh323_user *user;
struct ast_ha *oldha;
int found = 0;
int format;
user = ASTOBJ_CONTAINER_FIND_UNLINK_FULL(&userl, name, name, 0, 0, strcmp);
if (user)
found++;
else {
if (!(user = (struct oh323_user *)calloc(1, sizeof(*user))))
return NULL;
ASTOBJ_INIT(user);
}
oldha = user->ha;
user->ha = (struct ast_ha *)NULL;
memcpy(&user->options, &global_options, sizeof(user->options));
/* Set default context */
strncpy(user->context, default_context, sizeof(user->context) - 1);
if (user && !found)
strncpy(user->name, name, sizeof(user->name) - 1);
#if 0 /* XXX Port channel variables functionality from chan_sip XXX */
if (user->chanvars) {
ast_variables_destroy(user->chanvars);
user->chanvars = NULL;
}
#endif
for (; v || ((v = alt) && !(alt = NULL)); v = v->next) {
if (!update_common_options(v, &user->options))
continue;
if (!strcasecmp(v->name, "context")) {
strncpy(user->context, v->value, sizeof(user->context) - 1);
} else if (!strcasecmp(v->name, "secret")) {
strncpy(user->secret, v->value, sizeof(user->secret) - 1);
} else if (!strcasecmp(v->name, "accountcode")) {
strncpy(user->accountcode, v->value, sizeof(user->accountcode) - 1);
} else if (!strcasecmp(v->name, "host")) {
if (!strcasecmp(v->value, "dynamic")) {
ast_log(LOG_ERROR, "A dynamic host on a type=user does not make any sense\n");
ASTOBJ_UNREF(user, oh323_destroy_user);
return NULL;
} else if (ast_get_ip(&user->addr, v->value)) {
ASTOBJ_UNREF(user, oh323_destroy_user);
return NULL;
}
/* Let us know we need to use ip authentication */
user->host = 1;
} else if (!strcasecmp(v->name, "amaflags")) {
format = ast_cdr_amaflags2int(v->value);
if (format < 0) {
ast_log(LOG_WARNING, "Invalid AMA Flags: %s at line %d\n", v->value, v->lineno);
} else {
user->amaflags = format;
}
} else if (!strcasecmp(v->name, "permit") ||
!strcasecmp(v->name, "deny")) {
user->ha = ast_append_ha(v->name, v->value, user->ha);
}
}
ASTOBJ_UNMARK(user);
ast_free_ha(oldha);
return user;
}
static struct oh323_user *realtime_user(const call_details_t *cd)
{
struct ast_variable *var, *tmp;
struct oh323_user *user;
char *username;
if (userbyalias)
var = ast_load_realtime("h323", "name", username = cd->call_source_aliases, NULL);
else {
username = (char *)NULL;
var = ast_load_realtime("h323", "host", cd->sourceIp, NULL);
}
if (!var)
return NULL;
for (tmp = var; tmp; tmp = tmp->next) {
if (!strcasecmp(tmp->name, "type") &&
!(!strcasecmp(tmp->value, "user") || !strcasecmp(tmp->value, "friend"))) {
ast_variables_destroy(var);
return NULL;
} else if (!username && !strcasecmp(tmp->name, "name"))
username = tmp->value;
}
if (!username) {
ast_log(LOG_WARNING, "Cannot determine user name for IP address %s\n", cd->sourceIp);
ast_variables_destroy(var);
return NULL;
}
user = build_user(username, var, NULL, 1);
ast_variables_destroy(var);
return user;
}
static struct oh323_peer *build_peer(const char *name, struct ast_variable *v, struct ast_variable *alt, int realtime)
{
struct oh323_peer *peer;
struct ast_ha *oldha;
int found = 0;
peer = ASTOBJ_CONTAINER_FIND_UNLINK_FULL(&peerl, name, name, 0, 0, strcmp);
if (peer)
found++;
else {
if (!(peer = (struct oh323_peer*)calloc(1, sizeof(*peer))))
return NULL;
ASTOBJ_INIT(peer);
}
oldha = peer->ha;
peer->ha = NULL;
memcpy(&peer->options, &global_options, sizeof(peer->options));
peer->addr.sin_port = htons(h323_signalling_port);
peer->addr.sin_family = AF_INET;
if (!found && name)
strncpy(peer->name, name, sizeof(peer->name) - 1);
#if 0 /* XXX Port channel variables functionality from chan_sip XXX */
if (peer->chanvars) {
ast_variables_destroy(peer->chanvars);
peer->chanvars = NULL;
}
#endif
/* Default settings for mailbox */
peer->mailbox[0] = '\0';
for (; v || ((v = alt) && !(alt = NULL)); v = v->next) {
if (!update_common_options(v, &peer->options))
continue;
if (!strcasecmp(v->name, "host")) {
if (!strcasecmp(v->value, "dynamic")) {
ast_log(LOG_ERROR, "Dynamic host configuration not implemented.\n");
ASTOBJ_UNREF(peer, oh323_destroy_peer);
return NULL;
}
if (ast_get_ip(&peer->addr, v->value)) {
ast_log(LOG_ERROR, "Could not determine IP for %s\n", v->value);
ASTOBJ_UNREF(peer, oh323_destroy_peer);
return NULL;
}
} else if (!strcasecmp(v->name, "port")) {
peer->addr.sin_port = htons(atoi(v->value));
} else if (!strcasecmp(v->name, "permit") ||
!strcasecmp(v->name, "deny")) {
peer->ha = ast_append_ha(v->name, v->value, peer->ha);
} else if (!strcasecmp(v->name, "mailbox")) {
ast_copy_string(peer->mailbox, v->value, sizeof(peer->mailbox));
}
}
ASTOBJ_UNMARK(peer);
ast_free_ha(oldha);
return peer;
}
static struct oh323_peer *realtime_peer(const char *peername, struct sockaddr_in *sin)
{
struct oh323_peer *peer;
struct ast_variable *var;
struct ast_variable *tmp;
const char *addr;
/* First check on peer name */
if (peername)
var = ast_load_realtime("h323", "name", peername, addr = NULL);
else if (sin) /* Then check on IP address for dynamic peers */
var = ast_load_realtime("h323", "host", addr = ast_inet_ntoa(sin->sin_addr), NULL);
else
return NULL;
if (!var)
return NULL;
for (tmp = var; tmp; tmp = tmp->next) {
/* If this is type=user, then skip this object. */
if (!strcasecmp(tmp->name, "type") &&
!(!strcasecmp(tmp->value, "peer") || !strcasecmp(tmp->value, "friend"))) {
ast_variables_destroy(var);
return NULL;
} else if (!peername && !strcasecmp(tmp->name, "name")) {
peername = tmp->value;
}
}
if (!peername) { /* Did not find peer in realtime */
ast_log(LOG_WARNING, "Cannot determine peer name for IP address %s\n", addr);
ast_variables_destroy(var);
return NULL;
}
/* Peer found in realtime, now build it in memory */
peer = build_peer(peername, var, NULL, 1);
ast_variables_destroy(var);
return peer;
}
static int oh323_addrcmp_str(struct in_addr inaddr, char *addr)
{
return strcmp(ast_inet_ntoa(inaddr), addr);
}
static struct oh323_user *find_user(const call_details_t *cd, int realtime)
{
struct oh323_user *u;
if (userbyalias)
u = ASTOBJ_CONTAINER_FIND(&userl, cd->call_source_aliases);
else
u = ASTOBJ_CONTAINER_FIND_FULL(&userl, cd->sourceIp, addr.sin_addr, 0, 0, oh323_addrcmp_str);
if (!u && realtime)
u = realtime_user(cd);
if (!u && h323debug)
ast_log(LOG_DEBUG, "Could not find user by name %s or address %s\n", cd->call_source_aliases, cd->sourceIp);
return u;
}
static int oh323_addrcmp(struct sockaddr_in addr, struct sockaddr_in *sin)
{
int res;
if (!sin)
res = -1;
else
res = inaddrcmp(&addr , sin);
return res;
}
static struct oh323_peer *find_peer(const char *peer, struct sockaddr_in *sin, int realtime)
{
struct oh323_peer *p;
if (peer)
p = ASTOBJ_CONTAINER_FIND(&peerl, peer);
else
p = ASTOBJ_CONTAINER_FIND_FULL(&peerl, sin, addr, 0, 0, oh323_addrcmp);
if (!p && realtime)
p = realtime_peer(peer, sin);
if (!p && h323debug)
ast_log(LOG_DEBUG, "Could not find peer by name %s or address %s\n", (peer ? peer : "<NONE>"), (sin ? ast_inet_ntoa(sin->sin_addr) : "<NONE>"));
return p;
}
static int create_addr(struct oh323_pvt *pvt, char *opeer)
{
struct hostent *hp;
struct ast_hostent ahp;
struct oh323_peer *p;
int portno;
int found = 0;
char *port;
char *hostn;
char peer[256] = "";
strncpy(peer, opeer, sizeof(peer) - 1);
port = strchr(peer, ':');
if (port) {
*port = '\0';
port++;
}
pvt->sa.sin_family = AF_INET;
p = find_peer(peer, NULL, 1);
if (p) {
found++;
memcpy(&pvt->options, &p->options, sizeof(pvt->options));
pvt->jointcapability = pvt->options.capability;
#if 0
if (pvt->rtp) {
if (h323debug)
ast_log(LOG_DEBUG, "Setting NAT on RTP to %d\n", pvt->options.nat);
ast_rtp_setnat(pvt->rtp, pvt->options.nat);
}
#endif
if (pvt->options.dtmfmode) {
if (pvt->options.dtmfmode & H323_DTMF_RFC2833) {
pvt->nonCodecCapability |= AST_RTP_DTMF;
} else {
pvt->nonCodecCapability &= ~AST_RTP_DTMF;
}
}
if (p->addr.sin_addr.s_addr) {
pvt->sa.sin_addr = p->addr.sin_addr;
pvt->sa.sin_port = p->addr.sin_port;
}
ASTOBJ_UNREF(p, oh323_destroy_peer);
}
if (!p && !found) {
hostn = peer;
if (port) {
portno = atoi(port);
} else {
portno = h323_signalling_port;
}
hp = ast_gethostbyname(hostn, &ahp);
if (hp) {
memcpy(&pvt->sa.sin_addr, hp->h_addr, sizeof(pvt->sa.sin_addr));
pvt->sa.sin_port = htons(portno);
/* Look peer by address */
p = find_peer(NULL, &pvt->sa, 1);
memcpy(&pvt->options, (p ? &p->options : &global_options), sizeof(pvt->options));
pvt->jointcapability = pvt->options.capability;
if (p) {
ASTOBJ_UNREF(p, oh323_destroy_peer);
}
#if 0
if (pvt->rtp) {
if (h323debug)
ast_log(LOG_DEBUG, "Setting NAT on RTP to %d\n", pvt->options.nat);
ast_rtp_setnat(pvt->rtp, pvt->options.nat);
}
#endif
if (pvt->options.dtmfmode) {
if (pvt->options.dtmfmode & H323_DTMF_RFC2833) {
pvt->nonCodecCapability |= AST_RTP_DTMF;
} else {
pvt->nonCodecCapability &= ~AST_RTP_DTMF;
}
}
return 0;
} else {
ast_log(LOG_WARNING, "No such host: %s\n", peer);
return -1;
}
} else if (!found) {
return -1;
} else {
return 0;
}
}
static struct ast_channel *oh323_request(const char *type, int format, void *data, int *cause)
{
int oldformat;
struct oh323_pvt *pvt;
struct ast_channel *tmpc = NULL;
char *dest = (char *)data;
char *ext, *host;
char *h323id = NULL;
char tmp[256], tmp1[256];
if (h323debug)
ast_log(LOG_DEBUG, "type=%s, format=%d, data=%s.\n", type, format, (char *)data);
pvt = oh323_alloc(0);
if (!pvt) {
ast_log(LOG_WARNING, "Unable to build pvt data for '%s'\n", (char *)data);
return NULL;
}
oldformat = format;
format &= ((AST_FORMAT_MAX_AUDIO << 1) - 1);
if (!format) {
ast_log(LOG_NOTICE, "Asked to get a channel of unsupported format '%d'\n", format);
oh323_destroy(pvt);
if (cause)
*cause = AST_CAUSE_INCOMPATIBLE_DESTINATION;
return NULL;
}
strncpy(tmp, dest, sizeof(tmp) - 1);
host = strchr(tmp, '@');
if (host) {
*host = '\0';
host++;
ext = tmp;
} else {
ext = strrchr(tmp, '/');
if (ext)
*ext++ = '\0';
host = tmp;
}
strtok_r(host, "/", &(h323id));
if (!ast_strlen_zero(h323id)) {
h323_set_id(h323id);
}
if (ext) {
strncpy(pvt->exten, ext, sizeof(pvt->exten) - 1);
}
if (h323debug)
ast_log(LOG_DEBUG, "Extension: %s Host: %s\n", pvt->exten, host);
if (gatekeeper_disable) {
if (create_addr(pvt, host)) {
oh323_destroy(pvt);
if (cause)
*cause = AST_CAUSE_DESTINATION_OUT_OF_ORDER;
return NULL;
}
}
else {
memcpy(&pvt->options, &global_options, sizeof(pvt->options));
pvt->jointcapability = pvt->options.capability;
#if 0
if (pvt->rtp) {
if (h323debug)
ast_log(LOG_DEBUG, "Setting NAT on RTP to %d\n", pvt->options.nat);
ast_rtp_setnat(pvt->rtp, pvt->options.nat);
}
#endif
if (pvt->options.dtmfmode) {
if (pvt->options.dtmfmode & H323_DTMF_RFC2833) {
pvt->nonCodecCapability |= AST_RTP_DTMF;
} else {
pvt->nonCodecCapability &= ~AST_RTP_DTMF;
}
}
}
ast_mutex_lock(&caplock);
/* Generate unique channel identifier */
snprintf(tmp1, sizeof(tmp1)-1, "%s-%u", host, ++unique);
tmp1[sizeof(tmp1)-1] = '\0';
ast_mutex_unlock(&caplock);
ast_mutex_lock(&pvt->lock);
tmpc = __oh323_new(pvt, AST_STATE_DOWN, tmp1);
ast_mutex_unlock(&pvt->lock);
if (!tmpc) {
oh323_destroy(pvt);
if (cause)
*cause = AST_CAUSE_NORMAL_TEMPORARY_FAILURE;
}
ast_update_use_count();
restart_monitor();
return tmpc;
}
/** Find a call by alias */
static struct oh323_alias *find_alias(const char *source_aliases, int realtime)
{
struct oh323_alias *a;
a = ASTOBJ_CONTAINER_FIND(&aliasl, source_aliases);
if (!a && realtime)
a = realtime_alias(source_aliases);
return a;
}
/**
* Callback for sending digits from H.323 up to asterisk
*
*/
static int receive_digit(unsigned call_reference, char digit, const char *token, int duration)
{
struct oh323_pvt *pvt;
int res;
pvt = find_call_locked(call_reference, token);
if (!pvt) {
ast_log(LOG_ERROR, "Received digit '%c' (%u ms) for call %s without private structure\n", digit, duration, token);
return -1;
}
if (h323debug)
ast_log(LOG_DTMF, "Received %s digit '%c' (%u ms) for call %s\n", (digit == ' ' ? "update for" : "new"), (digit == ' ' ? pvt->curDTMF : digit), duration, token);
if (pvt->owner && !ast_channel_trylock(pvt->owner)) {
if (digit == '!')
res = ast_queue_control(pvt->owner, AST_CONTROL_FLASH);
else {
struct ast_frame f = {
.frametype = AST_FRAME_DTMF_END,
.subclass = digit,
.samples = duration * 8,
.src = "SEND_DIGIT",
};
if (digit == ' ') { /* signalUpdate message */
f.subclass = pvt->curDTMF;
if (pvt->DTMFsched >= 0) {
ast_sched_del(sched, pvt->DTMFsched);
pvt->DTMFsched = -1;
}
} else { /* Regular input or signal message */
if (duration) { /* This is a signal, signalUpdate follows */
f.frametype = AST_FRAME_DTMF_BEGIN;
if (pvt->DTMFsched >= 0)
ast_sched_del(sched, pvt->DTMFsched);
pvt->DTMFsched = ast_sched_add(sched, duration, oh323_simulate_dtmf_end, pvt);
if (h323debug)
ast_log(LOG_DTMF, "Scheduled DTMF END simulation for %d ms, id=%d\n", duration, pvt->DTMFsched);
}
pvt->curDTMF = digit;
}
res = ast_queue_frame(pvt->owner, &f);
}
ast_channel_unlock(pvt->owner);
} else {
if (digit == '!')
pvt->newcontrol = AST_CONTROL_FLASH;
else {
pvt->newduration = duration;
pvt->newdigit = digit;
}
res = 0;
}
ast_mutex_unlock(&pvt->lock);
return res;
}
/**
* Callback function used to inform the H.323 stack of the local rtp ip/port details
*
* Returns the local RTP information
*/
static struct rtp_info *external_rtp_create(unsigned call_reference, const char * token)
{
struct oh323_pvt *pvt;
struct sockaddr_in us;
struct rtp_info *info;
info = (struct rtp_info *)malloc(sizeof(struct rtp_info));
if (!info) {
ast_log(LOG_ERROR, "Unable to allocated info structure, this is very bad\n");
return NULL;
}
pvt = find_call_locked(call_reference, token);
if (!pvt) {
free(info);
ast_log(LOG_ERROR, "Unable to find call %s(%d)\n", token, call_reference);
return NULL;
}
if (!pvt->rtp)
__oh323_rtp_create(pvt);
if (!pvt->rtp) {
ast_mutex_unlock(&pvt->lock);
free(info);
ast_log(LOG_ERROR, "No RTP stream is available for call %s (%d)", token, call_reference);
return NULL;
}
/* figure out our local RTP port and tell the H.323 stack about it */
ast_rtp_get_us(pvt->rtp, &us);
ast_mutex_unlock(&pvt->lock);
strncpy(info->addr, ast_inet_ntoa(us.sin_addr), sizeof(info->addr));
info->addr[sizeof(info->addr)-1] = '\0';
info->port = ntohs(us.sin_port);
if (h323debug)
ast_log(LOG_DEBUG, "Sending RTP 'US' %s:%d\n", info->addr, info->port);
return info;
}
/**
* Definition taken from rtp.c for rtpPayloadType because we need it here.
*/
struct rtpPayloadType {
int isAstFormat; /* whether the following code is an AST_FORMAT */
int code;
};
/**
* Call-back function passing remote ip/port information from H.323 to asterisk
*
* Returns nothing
*/
static void setup_rtp_connection(unsigned call_reference, const char *remoteIp, int remotePort, const char *token, int pt)
{
struct oh323_pvt *pvt;
struct sockaddr_in them;
struct rtpPayloadType rtptype;
int nativeformats_changed;
enum { NEED_NONE, NEED_HOLD, NEED_UNHOLD } rtp_change = NEED_NONE;
if (h323debug)
ast_log(LOG_DEBUG, "Setting up RTP connection for %s\n", token);
/* Find the call or allocate a private structure if call not found */
pvt = find_call_locked(call_reference, token);
if (!pvt) {
ast_log(LOG_ERROR, "Something is wrong: rtp\n");
return;
}
if (pvt->alreadygone) {
ast_mutex_unlock(&pvt->lock);
return;
}
if (!pvt->rtp)
__oh323_rtp_create(pvt);
them.sin_family = AF_INET;
/* only works for IPv4 */
them.sin_addr.s_addr = inet_addr(remoteIp);
them.sin_port = htons(remotePort);
if (them.sin_addr.s_addr) {
ast_rtp_set_peer(pvt->rtp, &them);
if (pvt->recvonly) {
pvt->recvonly = 0;
rtp_change = NEED_UNHOLD;
}
} else {
ast_rtp_stop(pvt->rtp);
if (!pvt->recvonly) {
pvt->recvonly = 1;
rtp_change = NEED_HOLD;
}
}
/* Change native format to reflect information taken from OLC/OLCAck */
nativeformats_changed = 0;
if (pt != 128 && pvt->rtp) { /* Payload type is invalid, so try to use previously decided */
rtptype = ast_rtp_lookup_pt(pvt->rtp, pt);
if (h323debug)
ast_log(LOG_DEBUG, "Native format is set to %d from %d by RTP payload type %d\n", rtptype.code, pvt->nativeformats, pt);
if (pvt->nativeformats != rtptype.code) {
pvt->nativeformats = rtptype.code;
nativeformats_changed = 1;
}
} else if (h323debug)
ast_log(LOG_NOTICE, "Payload type is unknown, formats isn't changed\n");
/* Don't try to lock the channel if nothing changed */
if (nativeformats_changed || pvt->options.progress_audio || (rtp_change != NEED_NONE)) {
if (pvt->owner && !ast_channel_trylock(pvt->owner)) {
/* Re-build translation path only if native format(s) has been changed */
if (pvt->owner->nativeformats != pvt->nativeformats) {
if (h323debug)
ast_log(LOG_DEBUG, "Native format changed to %d from %d, read format is %d, write format is %d\n", pvt->nativeformats, pvt->owner->nativeformats, pvt->owner->readformat, pvt->owner->writeformat);
pvt->owner->nativeformats = pvt->nativeformats;
ast_set_read_format(pvt->owner, pvt->owner->readformat);
ast_set_write_format(pvt->owner, pvt->owner->writeformat);
}
if (pvt->options.progress_audio)
ast_queue_control(pvt->owner, AST_CONTROL_PROGRESS);
switch (rtp_change) {
case NEED_HOLD:
ast_queue_control(pvt->owner, AST_CONTROL_HOLD);
break;
case NEED_UNHOLD:
ast_queue_control(pvt->owner, AST_CONTROL_UNHOLD);
break;
default:
break;
}
ast_channel_unlock(pvt->owner);
}
else {
if (pvt->options.progress_audio)
pvt->newcontrol = AST_CONTROL_PROGRESS;
else if (rtp_change == NEED_HOLD)
pvt->newcontrol = AST_CONTROL_HOLD;
else if (rtp_change == NEED_UNHOLD)
pvt->newcontrol = AST_CONTROL_UNHOLD;
if (h323debug)
ast_log(LOG_DEBUG, "RTP connection preparation for %s is pending...\n", token);
}
}
ast_mutex_unlock(&pvt->lock);
if (h323debug)
ast_log(LOG_DEBUG, "RTP connection prepared for %s\n", token);
return;
}
/**
* Call-back function to signal asterisk that the channel has been answered
* Returns nothing
*/
static void connection_made(unsigned call_reference, const char *token)
{
struct oh323_pvt *pvt;
if (h323debug)
ast_log(LOG_DEBUG, "Call %s answered\n", token);
pvt = find_call_locked(call_reference, token);
if (!pvt) {
ast_log(LOG_ERROR, "Something is wrong: connection\n");
return;
}
/* Inform asterisk about remote party connected only on outgoing calls */
if (!pvt->outgoing) {
ast_mutex_unlock(&pvt->lock);
return;
}
/* Do not send ANSWER message more than once */
if (!pvt->connection_established) {
pvt->connection_established = 1;
update_state(pvt, -1, AST_CONTROL_ANSWER);
}
ast_mutex_unlock(&pvt->lock);
return;
}
static int progress(unsigned call_reference, const char *token, int inband)
{
struct oh323_pvt *pvt;
if (h323debug)
ast_log(LOG_DEBUG, "Received ALERT/PROGRESS message for %s tones\n", (inband ? "inband" : "self-generated"));
pvt = find_call_locked(call_reference, token);
if (!pvt) {
ast_log(LOG_ERROR, "Private structure not found in progress.\n");
return -1;
}
if (!pvt->owner) {
ast_mutex_unlock(&pvt->lock);
ast_log(LOG_ERROR, "No Asterisk channel associated with private structure.\n");
return -1;
}
update_state(pvt, -1, (inband ? AST_CONTROL_PROGRESS : AST_CONTROL_RINGING));
ast_mutex_unlock(&pvt->lock);
return 0;
}
/**
* Call-back function for incoming calls
*
* Returns 1 on success
*/
static call_options_t *setup_incoming_call(call_details_t *cd)
{
struct oh323_pvt *pvt;
struct oh323_user *user = NULL;
struct oh323_alias *alias = NULL;
if (h323debug)
ast_log(LOG_DEBUG, "Setting up incoming call for %s\n", cd->call_token);
/* allocate the call*/
pvt = oh323_alloc(cd->call_reference);
if (!pvt) {
ast_log(LOG_ERROR, "Unable to allocate private structure, this is bad.\n");
cleanup_call_details(cd);
return NULL;
}
/* Populate the call details in the private structure */
memcpy(&pvt->cd, cd, sizeof(pvt->cd));
memcpy(&pvt->options, &global_options, sizeof(pvt->options));
pvt->jointcapability = pvt->options.capability;
if (h323debug) {
ast_verbose(VERBOSE_PREFIX_3 "Setting up Call\n");
ast_verbose(VERBOSE_PREFIX_3 " \tCall token: [%s]\n", pvt->cd.call_token);
ast_verbose(VERBOSE_PREFIX_3 " \tCalling party name: [%s]\n", pvt->cd.call_source_name);
ast_verbose(VERBOSE_PREFIX_3 " \tCalling party number: [%s]\n", pvt->cd.call_source_e164);
ast_verbose(VERBOSE_PREFIX_3 " \tCalled party name: [%s]\n", pvt->cd.call_dest_alias);
ast_verbose(VERBOSE_PREFIX_3 " \tCalled party number: [%s]\n", pvt->cd.call_dest_e164);
if (pvt->cd.redirect_reason >= 0)
ast_verbose(VERBOSE_PREFIX_3 " \tRedirecting party number: [%s] (reason %d)\n", pvt->cd.redirect_number, pvt->cd.redirect_reason);
ast_verbose(VERBOSE_PREFIX_3 " \tCalling party IP: [%s]\n", pvt->cd.sourceIp);
}
/* Decide if we are allowing Gatekeeper routed calls*/
if ((!strcasecmp(cd->sourceIp, gatekeeper)) && (gkroute == -1) && !gatekeeper_disable) {
if (!ast_strlen_zero(cd->call_dest_e164)) {
strncpy(pvt->exten, cd->call_dest_e164, sizeof(pvt->exten) - 1);
strncpy(pvt->context, default_context, sizeof(pvt->context) - 1);
} else {
alias = find_alias(cd->call_dest_alias, 1);
if (!alias) {
ast_log(LOG_ERROR, "Call for %s rejected, alias not found\n", cd->call_dest_alias);
oh323_destroy(pvt);
return NULL;
}
strncpy(pvt->exten, alias->name, sizeof(pvt->exten) - 1);
strncpy(pvt->context, alias->context, sizeof(pvt->context) - 1);
}
} else {
/* Either this call is not from the Gatekeeper
or we are not allowing gk routed calls */
user = find_user(cd, 1);
if (!user) {
if (!acceptAnonymous) {
ast_log(LOG_NOTICE, "Anonymous call from '%s@%s' rejected\n", pvt->cd.call_source_aliases, pvt->cd.sourceIp);
oh323_destroy(pvt);
return NULL;
}
if (ast_strlen_zero(default_context)) {
ast_log(LOG_ERROR, "Call from '%s@%s' rejected due to no default context\n", pvt->cd.call_source_aliases, pvt->cd.sourceIp);
oh323_destroy(pvt);
return NULL;
}
strncpy(pvt->context, default_context, sizeof(pvt->context) - 1);
if (!ast_strlen_zero(pvt->cd.call_dest_e164)) {
strncpy(pvt->exten, cd->call_dest_e164, sizeof(pvt->exten) - 1);
} else {
strncpy(pvt->exten, cd->call_dest_alias, sizeof(pvt->exten) - 1);
}
if (h323debug)
ast_log(LOG_DEBUG, "Sending %s@%s to context [%s] extension %s\n", cd->call_source_aliases, cd->sourceIp, pvt->context, pvt->exten);
} else {
if (user->host) {
if (strcasecmp(cd->sourceIp, ast_inet_ntoa(user->addr.sin_addr))) {
if (ast_strlen_zero(user->context)) {
if (ast_strlen_zero(default_context)) {
ast_log(LOG_ERROR, "Call from '%s' rejected due to non-matching IP address (%s) and no default context\n", user->name, cd->sourceIp);
oh323_destroy(pvt);
ASTOBJ_UNREF(user, oh323_destroy_user);
return NULL;
}
strncpy(pvt->context, default_context, sizeof(pvt->context) - 1);
} else {
strncpy(pvt->context, user->context, sizeof(pvt->context) - 1);
}
pvt->exten[0] = 'i';
pvt->exten[1] = '\0';
ast_log(LOG_ERROR, "Call from '%s' rejected due to non-matching IP address (%s)s\n", user->name, cd->sourceIp);
oh323_destroy(pvt);
ASTOBJ_UNREF(user, oh323_destroy_user);
return NULL; /* XXX: Hmmm... Why to setup context if we drop connection immediately??? */
}
}
strncpy(pvt->context, user->context, sizeof(pvt->context) - 1);
memcpy(&pvt->options, &user->options, sizeof(pvt->options));
pvt->jointcapability = pvt->options.capability;
if (!ast_strlen_zero(pvt->cd.call_dest_e164)) {
strncpy(pvt->exten, cd->call_dest_e164, sizeof(pvt->exten) - 1);
} else {
strncpy(pvt->exten, cd->call_dest_alias, sizeof(pvt->exten) - 1);
}
if (!ast_strlen_zero(user->accountcode)) {
strncpy(pvt->accountcode, user->accountcode, sizeof(pvt->accountcode) - 1);
}
if (user->amaflags) {
pvt->amaflags = user->amaflags;
}
ASTOBJ_UNREF(user, oh323_destroy_user);
}
}
return &pvt->options;
}
/**
* Call-back function to start PBX when OpenH323 ready to serve incoming call
*
* Returns 1 on success
*/
static int answer_call(unsigned call_reference, const char *token)
{
struct oh323_pvt *pvt;
struct ast_channel *c = NULL;
enum {ext_original, ext_s, ext_i, ext_notexists} try_exten;
char tmp_exten[sizeof(pvt->exten)];
if (h323debug)
ast_log(LOG_DEBUG, "Preparing Asterisk to answer for %s\n", token);
/* Find the call or allocate a private structure if call not found */
pvt = find_call_locked(call_reference, token);
if (!pvt) {
ast_log(LOG_ERROR, "Something is wrong: answer_call\n");
return 0;
}
/* Check if requested extension@context pair exists in the dialplan */
strncpy(tmp_exten, pvt->exten, sizeof(tmp_exten));
/* Try to find best extension in specified context */
if ((tmp_exten[0] != '\0') && (tmp_exten[1] == '\0')) {
if (tmp_exten[0] == 's')
try_exten = ext_s;
else if (tmp_exten[0] == 'i')
try_exten = ext_i;
else
try_exten = ext_original;
} else
try_exten = ext_original;
do {
if (ast_exists_extension(NULL, pvt->context, tmp_exten, 1, NULL))
break;
switch (try_exten) {
case ext_original:
tmp_exten[0] = 's';
tmp_exten[1] = '\0';
try_exten = ext_s;
break;
case ext_s:
tmp_exten[0] = 'i';
try_exten = ext_i;
break;
case ext_i:
try_exten = ext_notexists;
break;
default:
break;
}
} while (try_exten != ext_notexists);
/* Drop the call if we don't have <exten>, s and i extensions */
if (try_exten == ext_notexists) {
ast_log(LOG_NOTICE, "Dropping call because extensions '%s', 's' and 'i' doesn't exists in context [%s]\n", pvt->exten, pvt->context);
ast_mutex_unlock(&pvt->lock);
h323_clear_call(token, AST_CAUSE_UNALLOCATED);
return 0;
} else if ((try_exten != ext_original) && (strcmp(pvt->exten, tmp_exten) != 0)) {
if (h323debug)
ast_log(LOG_DEBUG, "Going to extension %s@%s because %s@%s isn't exists\n", tmp_exten, pvt->context, pvt->exten, pvt->context);
strncpy(pvt->exten, tmp_exten, sizeof(pvt->exten));
}
/* allocate a channel and tell asterisk about it */
c = __oh323_new(pvt, AST_STATE_RINGING, pvt->cd.call_token);
/* And release when done */
ast_mutex_unlock(&pvt->lock);
if (!c) {
ast_log(LOG_ERROR, "Couldn't create channel. This is bad\n");
return 0;
}
return 1;
}
/**
* Call-back function to establish an outgoing H.323 call
*
* Returns 1 on success
*/
static int setup_outgoing_call(call_details_t *cd)
{
/* Use argument here or free it immediately */
cleanup_call_details(cd);
return 1;
}
/**
* Call-back function to signal asterisk that the channel is ringing
* Returns nothing
*/
static void chan_ringing(unsigned call_reference, const char *token)
{
struct oh323_pvt *pvt;
if (h323debug)
ast_log(LOG_DEBUG, "Ringing on %s\n", token);
pvt = find_call_locked(call_reference, token);
if (!pvt) {
ast_log(LOG_ERROR, "Something is wrong: ringing\n");
return;
}
if (!pvt->owner) {
ast_mutex_unlock(&pvt->lock);
ast_log(LOG_ERROR, "Channel has no owner\n");
return;
}
update_state(pvt, AST_STATE_RINGING, AST_CONTROL_RINGING);
ast_mutex_unlock(&pvt->lock);
return;
}
/**
* Call-back function to cleanup communication
* Returns nothing,
*/
static void cleanup_connection(unsigned call_reference, const char *call_token)
{
struct oh323_pvt *pvt;
if (h323debug)
ast_log(LOG_DEBUG, "Cleaning connection to %s\n", call_token);
while (1) {
pvt = find_call_locked(call_reference, call_token);
if (!pvt) {
if (h323debug)
ast_log(LOG_DEBUG, "No connection for %s\n", call_token);
return;
}
if (!pvt->owner || !ast_channel_trylock(pvt->owner))
break;
#if 1
#ifdef DEBUG_THREADS
ast_log(LOG_NOTICE, "Avoiding H.323 destory deadlock on %s, locked at %ld/%d by %s (%s:%d)\n", call_token, pvt->owner->lock.thread[0], pvt->owner->lock.reentrancy, pvt->owner->lock.func[0], pvt->owner->lock.file[0], pvt->owner->lock.lineno[0]);
#else
ast_log(LOG_NOTICE, "Avoiding H.323 destory deadlock on %s\n", call_token);
#endif
#endif
ast_mutex_unlock(&pvt->lock);
usleep(1);
}
if (pvt->rtp) {
/* Immediately stop RTP */
ast_rtp_destroy(pvt->rtp);
pvt->rtp = NULL;
}
/* Free dsp used for in-band DTMF detection */
if (pvt->vad) {
ast_dsp_free(pvt->vad);
pvt->vad = NULL;
}
cleanup_call_details(&pvt->cd);
pvt->alreadygone = 1;
/* Send hangup */
if (pvt->owner) {
pvt->owner->_softhangup |= AST_SOFTHANGUP_DEV;
ast_queue_hangup(pvt->owner);
ast_channel_unlock(pvt->owner);
}
ast_mutex_unlock(&pvt->lock);
if (h323debug)
ast_log(LOG_DEBUG, "Connection to %s cleaned\n", call_token);
return;
}
static void hangup_connection(unsigned int call_reference, const char *token, int cause)
{
struct oh323_pvt *pvt;
if (h323debug) {
ast_log(LOG_DEBUG, "Hanging up connection to %s with cause %d\n", token, cause);
}
pvt = find_call_locked(call_reference, token);
if (!pvt) {
if (h323debug) {
ast_log(LOG_DEBUG, "Connection to %s already cleared\n", token);
}
return;
}
if (pvt->owner && !ast_channel_trylock(pvt->owner)) {
pvt->owner->_softhangup |= AST_SOFTHANGUP_DEV;
pvt->owner->hangupcause = pvt->hangupcause = cause;
ast_queue_hangup(pvt->owner);
ast_channel_unlock(pvt->owner);
}
else {
pvt->needhangup = 1;
pvt->hangupcause = cause;
if (h323debug)
ast_log(LOG_DEBUG, "Hangup for %s is pending\n", token);
}
ast_mutex_unlock(&pvt->lock);
}
static void set_dtmf_payload(unsigned call_reference, const char *token, int payload)
{
struct oh323_pvt *pvt;
if (h323debug)
ast_log(LOG_DEBUG, "Setting DTMF payload to %d on %s\n", payload, token);
pvt = find_call_locked(call_reference, token);
if (!pvt) {
return;
}
if (pvt->rtp) {
ast_rtp_set_rtpmap_type(pvt->rtp, payload, "audio", "telephone-event", 0);
}
pvt->dtmf_pt = payload;
ast_mutex_unlock(&pvt->lock);
if (h323debug)
ast_log(LOG_DEBUG, "DTMF payload on %s set to %d\n", token, payload);
}
static void set_peer_capabilities(unsigned call_reference, const char *token, int capabilities)
{
struct oh323_pvt *pvt;
if (h323debug)
ast_log(LOG_DEBUG, "Got remote capabilities from connection %s\n", token);
pvt = find_call_locked(call_reference, token);
if (!pvt)
return;
pvt->peercapability = capabilities;
pvt->jointcapability = pvt->options.capability & capabilities;
ast_mutex_unlock(&pvt->lock);
}
static void set_local_capabilities(unsigned call_reference, const char *token)
{
struct oh323_pvt *pvt;
int capability, dtmfmode, pref_codec;
struct ast_codec_pref prefs;
if (h323debug)
ast_log(LOG_DEBUG, "Setting capabilities for connection %s\n", token);
pvt = find_call_locked(call_reference, token);
if (!pvt)
return;
capability = (pvt->jointcapability) ? pvt->jointcapability : pvt->options.capability;
dtmfmode = pvt->options.dtmfmode;
prefs = pvt->options.prefs;
pref_codec = pvt->pref_codec;
ast_mutex_unlock(&pvt->lock);
h323_set_capabilities(token, capability, dtmfmode, &prefs, pref_codec);
if (h323debug)
ast_log(LOG_DEBUG, "Capabilities for connection %s is set\n", token);
}
static void *do_monitor(void *data)
{
int res;
int reloading;
struct oh323_pvt *oh323 = NULL;
for(;;) {
/* Check for a reload request */
ast_mutex_lock(&h323_reload_lock);
reloading = h323_reloading;
h323_reloading = 0;
ast_mutex_unlock(&h323_reload_lock);
if (reloading) {
if (option_verbose > 0) {
ast_verbose(VERBOSE_PREFIX_1 "Reloading H.323\n");
}
h323_do_reload();
}
/* Check for interfaces needing to be killed */
ast_mutex_lock(&iflock);
#if 1
do {
for (oh323 = iflist; oh323; oh323 = oh323->next) {
if (!ast_mutex_trylock(&oh323->lock)) {
if (oh323->needdestroy) {
__oh323_destroy(oh323);
break;
}
ast_mutex_unlock(&oh323->lock);
}
}
} while (/*oh323*/ 0);
#else
restartsearch:
oh323 = iflist;
while(oh323) {
if (!ast_mutex_trylock(&oh323->lock)) {
if (oh323->needdestroy) {
__oh323_destroy(oh323);
goto restartsearch;
}
ast_mutex_unlock(&oh323->lock);
oh323 = oh323->next;
}
}
#endif
ast_mutex_unlock(&iflock);
pthread_testcancel();
/* Wait for sched or io */
res = ast_sched_wait(sched);
if ((res < 0) || (res > 1000)) {
res = 1000;
}
/* Do not wait if some channel(s) is destroyed, probably, more available too */
if (oh323)
res = 1;
res = ast_io_wait(io, res);
pthread_testcancel();
ast_mutex_lock(&monlock);
if (res >= 0) {
ast_sched_runq(sched);
}
ast_mutex_unlock(&monlock);
}
/* Never reached */
return NULL;
}
static int restart_monitor(void)
{
pthread_attr_t attr;
/* If we're supposed to be stopped -- stay stopped */
if (ast_mutex_lock(&monlock)) {
ast_log(LOG_WARNING, "Unable to lock monitor\n");
return -1;
}
if (monitor_thread == AST_PTHREADT_STOP) {
ast_mutex_unlock(&monlock);
return 0;
}
if (monitor_thread == pthread_self()) {
ast_mutex_unlock(&monlock);
ast_log(LOG_WARNING, "Cannot kill myself\n");
return -1;
}
if (monitor_thread && (monitor_thread != AST_PTHREADT_NULL)) {
/* Wake up the thread */
pthread_kill(monitor_thread, SIGURG);
} else {
pthread_attr_init(&attr);
pthread_attr_setdetachstate(&attr, PTHREAD_CREATE_DETACHED);
/* Start a new monitor */
if (ast_pthread_create(&monitor_thread, &attr, do_monitor, NULL) < 0) {
monitor_thread = AST_PTHREADT_NULL;
ast_mutex_unlock(&monlock);
ast_log(LOG_ERROR, "Unable to start monitor thread.\n");
return -1;
}
}
ast_mutex_unlock(&monlock);
return 0;
}
static int h323_do_trace(int fd, int argc, char *argv[])
{
if (argc != 3) {
return RESULT_SHOWUSAGE;
}
h323_debug(1, atoi(argv[2]));
ast_cli(fd, "H.323 trace set to level %s\n", argv[2]);
return RESULT_SUCCESS;
}
static int h323_no_trace(int fd, int argc, char *argv[])
{
if (argc != 3) {
return RESULT_SHOWUSAGE;
}
h323_debug(0,0);
ast_cli(fd, "H.323 trace disabled\n");
return RESULT_SUCCESS;
}
static int h323_do_debug(int fd, int argc, char *argv[])
{
if (argc != 2) {
return RESULT_SHOWUSAGE;
}
h323debug = 1;
ast_cli(fd, "H.323 debug enabled\n");
return RESULT_SUCCESS;
}
static int h323_no_debug(int fd, int argc, char *argv[])
{
if (argc != 3) {
return RESULT_SHOWUSAGE;
}
h323debug = 0;
ast_cli(fd, "H.323 debug disabled\n");
return RESULT_SUCCESS;
}
static int h323_gk_cycle(int fd, int argc, char *argv[])
{
if (argc != 3) {
return RESULT_SHOWUSAGE;
}
h323_gk_urq();
/* Possibly register with a GK */
if (!gatekeeper_disable) {
if (h323_set_gk(gatekeeper_discover, gatekeeper, secret)) {
ast_log(LOG_ERROR, "Gatekeeper registration failed.\n");
}
}
return RESULT_SUCCESS;
}
static int h323_ep_hangup(int fd, int argc, char *argv[])
{
if (argc != 3) {
return RESULT_SHOWUSAGE;
}
if (h323_soft_hangup(argv[2])) {
ast_verbose(VERBOSE_PREFIX_3 "Hangup succeeded on %s\n", argv[2]);
} else {
ast_verbose(VERBOSE_PREFIX_3 "Hangup failed for %s\n", argv[2]);
}
return RESULT_SUCCESS;
}
static int h323_tokens_show(int fd, int argc, char *argv[])
{
if (argc != 3) {
return RESULT_SHOWUSAGE;
}
h323_show_tokens();
return RESULT_SUCCESS;
}
static char trace_usage[] =
"Usage: h.323 trace <level num>\n"
" Enables H.323 stack tracing for debugging purposes\n";
static char no_trace_usage[] =
"Usage: h.323 no trace\n"
" Disables H.323 stack tracing for debugging purposes\n";
static char debug_usage[] =
"Usage: h.323 debug\n"
" Enables H.323 debug output\n";
static char no_debug_usage[] =
"Usage: h.323 no debug\n"
" Disables H.323 debug output\n";
static char show_cycle_usage[] =
"Usage: h.323 gk cycle\n"
" Manually re-register with the Gatekeper (Currently Disabled)\n";
static char show_hangup_usage[] =
"Usage: h.323 hangup <token>\n"
" Manually try to hang up call identified by <token>\n";
static char show_tokens_usage[] =
"Usage: h.323 show tokens\n"
" Print out all active call tokens\n";
static char h323_reload_usage[] =
"Usage: h323 reload\n"
" Reloads H.323 configuration from h323.conf\n";
static struct ast_cli_entry cli_h323[] = {
{ { "h.323", "trace", NULL },
h323_do_trace, "Enable H.323 Stack Tracing",
trace_usage },
{ { "h.323", "no", "trace", NULL },
h323_no_trace, "Disable H.323 Stack Tracing",
no_trace_usage },
{ { "h.323", "debug", NULL },
h323_do_debug, "Enable H.323 debug",
debug_usage },
{ { "h.323", "no", "debug", NULL },
h323_no_debug, "Disable H.323 debug",
no_debug_usage },
{ { "h.323", "gk", "cycle", NULL },
h323_gk_cycle, "Manually re-register with the Gatekeper",
show_cycle_usage },
{ { "h.323", "hangup", NULL },
h323_ep_hangup, "Manually try to hang up a call",
show_hangup_usage },
{ { "h.323", "show", "tokens", NULL },
h323_tokens_show, "Show all active call tokens",
show_tokens_usage },
};
static int reload_config(int is_reload)
{
int format;
struct ast_config *cfg, *ucfg;
struct ast_variable *v;
struct oh323_peer *peer = NULL;
struct oh323_user *user = NULL;
struct oh323_alias *alias = NULL;
struct ast_hostent ahp; struct hostent *hp;
char *cat;
char *utype;
int is_user, is_peer, is_alias;
char _gatekeeper[100];
int gk_discover, gk_disable, gk_changed;
cfg = ast_config_load(config);
/* We *must* have a config file otherwise stop immediately */
if (!cfg) {
ast_log(LOG_NOTICE, "Unable to load config %s, H.323 disabled\n", config);
return 1;
}
/* fire up the H.323 Endpoint */
if (!h323_end_point_exist()) {
h323_end_point_create();
}
strncpy(_gatekeeper, gatekeeper, sizeof(_gatekeeper));
gk_discover = gatekeeper_discover;
gk_disable = gatekeeper_disable;
memset(&bindaddr, 0, sizeof(bindaddr));
memset(&global_options, 0, sizeof(global_options));
global_options.fastStart = 1;
global_options.h245Tunneling = 1;
global_options.dtmfcodec = 101;
global_options.dtmfmode = H323_DTMF_RFC2833;
global_options.capability = GLOBAL_CAPABILITY;
global_options.bridge = 1; /* Do native bridging by default */
strncpy(default_context, "default", sizeof(default_context) - 1);
h323_signalling_port = 1720;
gatekeeper_disable = 1;
gatekeeper_discover = 0;
gkroute = 0;
userbyalias = 1;
acceptAnonymous = 1;
tos = 0;
/* Copy the default jb config over global_jbconf */
memcpy(&global_jbconf, &default_jbconf, sizeof(struct ast_jb_conf));
/* Load configuration from users.conf */
ucfg = ast_config_load("users.conf");
if (ucfg) {
struct ast_variable *gen;
int genhas_h323;
char *has_h323;
genhas_h323 = ast_true(ast_variable_retrieve(ucfg, "general", "hash323"));
gen = ast_variable_browse(ucfg, "general");
for (cat = ast_category_browse(ucfg, NULL); cat; cat = ast_category_browse(ucfg, cat)) {
if (strcasecmp(cat, "general")) {
has_h323 = ast_variable_retrieve(ucfg, cat, "hash323");
if (ast_true(has_h323) || (!has_h323 && genhas_h323)) {
user = build_user(cat, gen, ast_variable_browse(ucfg, cat), 0);
if (user) {
ASTOBJ_CONTAINER_LINK(&userl, user);
ASTOBJ_UNREF(user, oh323_destroy_user);
}
}
}
}
ast_config_destroy(ucfg);
}
for (v = ast_variable_browse(cfg, "general"); v; v = v->next) {
/* handle jb conf */
if (!ast_jb_read_conf(&global_jbconf, v->name, v->value))
continue;
/* Create the interface list */
if (!strcasecmp(v->name, "port")) {
h323_signalling_port = (int)strtol(v->value, NULL, 10);
} else if (!strcasecmp(v->name, "bindaddr")) {
if (!(hp = ast_gethostbyname(v->value, &ahp))) {
ast_log(LOG_WARNING, "Invalid address: %s\n", v->value);
} else {
memcpy(&bindaddr.sin_addr, hp->h_addr, sizeof(bindaddr.sin_addr));
}
} else if (!strcasecmp(v->name, "tos")) {
if (sscanf(v->value, "%d", &format)) {
tos = format & 0xff;
} else if (!strcasecmp(v->value, "lowdelay")) {
tos = IPTOS_LOWDELAY;
} else if (!strcasecmp(v->value, "throughput")) {
tos = IPTOS_THROUGHPUT;
} else if (!strcasecmp(v->value, "reliability")) {
tos = IPTOS_RELIABILITY;
} else if (!strcasecmp(v->value, "mincost")) {
tos = IPTOS_MINCOST;
} else if (!strcasecmp(v->value, "none")) {
tos = 0;
} else {
ast_log(LOG_WARNING, "Invalid tos value at line %d, should be 'lowdelay', 'throughput', 'reliability', 'mincost', or 'none'\n", v->lineno);
}
} else if (!strcasecmp(v->name, "gatekeeper")) {
if (!strcasecmp(v->value, "DISABLE")) {
gatekeeper_disable = 1;
} else if (!strcasecmp(v->value, "DISCOVER")) {
gatekeeper_disable = 0;
gatekeeper_discover = 1;
} else {
gatekeeper_disable = 0;
strncpy(gatekeeper, v->value, sizeof(gatekeeper) - 1);
}
} else if (!strcasecmp(v->name, "secret")) {
strncpy(secret, v->value, sizeof(secret) - 1);
} else if (!strcasecmp(v->name, "AllowGKRouted")) {
gkroute = ast_true(v->value);
} else if (!strcasecmp(v->name, "context")) {
strncpy(default_context, v->value, sizeof(default_context) - 1);
ast_verbose(VERBOSE_PREFIX_2 "Setting default context to %s\n", default_context);
} else if (!strcasecmp(v->name, "UserByAlias")) {
userbyalias = ast_true(v->value);
} else if (!strcasecmp(v->name, "AcceptAnonymous")) {
acceptAnonymous = ast_true(v->value);
} else if (!update_common_options(v, &global_options)) {
/* dummy */
}
}
for (cat = ast_category_browse(cfg, NULL); cat; cat = ast_category_browse(cfg, cat)) {
if (strcasecmp(cat, "general")) {
utype = ast_variable_retrieve(cfg, cat, "type");
if (utype) {
is_user = is_peer = is_alias = 0;
if (!strcasecmp(utype, "user"))
is_user = 1;
else if (!strcasecmp(utype, "peer"))
is_peer = 1;
else if (!strcasecmp(utype, "friend"))
is_user = is_peer = 1;
else if (!strcasecmp(utype, "h323") || !strcasecmp(utype, "alias"))
is_alias = 1;
else {
ast_log(LOG_WARNING, "Unknown type '%s' for '%s' in %s\n", utype, cat, config);
continue;
}
if (is_user) {
user = build_user(cat, ast_variable_browse(cfg, cat), NULL, 0);
if (user) {
ASTOBJ_CONTAINER_LINK(&userl, user);
ASTOBJ_UNREF(user, oh323_destroy_user);
}
}
if (is_peer) {
peer = build_peer(cat, ast_variable_browse(cfg, cat), NULL, 0);
if (peer) {
ASTOBJ_CONTAINER_LINK(&peerl, peer);
ASTOBJ_UNREF(peer, oh323_destroy_peer);
}
}
if (is_alias) {
alias = build_alias(cat, ast_variable_browse(cfg, cat), NULL, 0);
if (alias) {
ASTOBJ_CONTAINER_LINK(&aliasl, alias);
ASTOBJ_UNREF(alias, oh323_destroy_alias);
}
}
} else {
ast_log(LOG_WARNING, "Section '%s' lacks type\n", cat);
}
}
}
ast_config_destroy(cfg);
/* Register our H.323 aliases if any*/
ASTOBJ_CONTAINER_WRLOCK(&aliasl);
ASTOBJ_CONTAINER_TRAVERSE(&aliasl, 1, do {
ASTOBJ_RDLOCK(iterator);
if (h323_set_alias(iterator)) {
ast_log(LOG_ERROR, "Alias %s rejected by endpoint\n", alias->name);
ASTOBJ_UNLOCK(iterator);
continue;
}
ASTOBJ_UNLOCK(iterator);
} while (0) );
ASTOBJ_CONTAINER_UNLOCK(&aliasl);
/* Don't touch GK if nothing changed because URQ will drop all existing calls */
gk_changed = 0;
if (gatekeeper_disable != gk_disable)
gk_changed = is_reload;
else if(!gatekeeper_disable && (gatekeeper_discover != gk_discover))
gk_changed = is_reload;
else if(!gatekeeper_disable && (strncmp(_gatekeeper, gatekeeper, sizeof(_gatekeeper)) != 0))
gk_changed = is_reload;
if (gk_changed) {
if(!gk_disable)
h323_gk_urq();
if (!gatekeeper_disable) {
if (h323_set_gk(gatekeeper_discover, gatekeeper, secret)) {
ast_log(LOG_ERROR, "Gatekeeper registration failed.\n");
gatekeeper_disable = 1;
}
}
}
return 0;
}
static void delete_users(void)
{
int pruned = 0;
/* Delete all users */
ASTOBJ_CONTAINER_WRLOCK(&userl);
ASTOBJ_CONTAINER_TRAVERSE(&userl, 1, do {
ASTOBJ_RDLOCK(iterator);
ASTOBJ_MARK(iterator);
++pruned;
ASTOBJ_UNLOCK(iterator);
} while (0) );
if (pruned) {
ASTOBJ_CONTAINER_PRUNE_MARKED(&userl, oh323_destroy_user);
}
ASTOBJ_CONTAINER_UNLOCK(&userl);
ASTOBJ_CONTAINER_WRLOCK(&peerl);
ASTOBJ_CONTAINER_TRAVERSE(&peerl, 1, do {
ASTOBJ_RDLOCK(iterator);
ASTOBJ_MARK(iterator);
ASTOBJ_UNLOCK(iterator);
} while (0) );
ASTOBJ_CONTAINER_UNLOCK(&peerl);
}
static void delete_aliases(void)
{
int pruned = 0;
/* Delete all aliases */
ASTOBJ_CONTAINER_WRLOCK(&aliasl);
ASTOBJ_CONTAINER_TRAVERSE(&aliasl, 1, do {
ASTOBJ_RDLOCK(iterator);
ASTOBJ_MARK(iterator);
++pruned;
ASTOBJ_UNLOCK(iterator);
} while (0) );
if (pruned) {
ASTOBJ_CONTAINER_PRUNE_MARKED(&aliasl, oh323_destroy_alias);
}
ASTOBJ_CONTAINER_UNLOCK(&aliasl);
}
static void prune_peers(void)
{
/* Prune peers who still are supposed to be deleted */
ASTOBJ_CONTAINER_PRUNE_MARKED(&peerl, oh323_destroy_peer);
}
static int h323_reload(int fd, int argc, char *argv[])
{
ast_mutex_lock(&h323_reload_lock);
if (h323_reloading) {
ast_verbose("Previous H.323 reload not yet done\n");
} else {
h323_reloading = 1;
}
ast_mutex_unlock(&h323_reload_lock);
restart_monitor();
return 0;
}
static int h323_do_reload(void)
{
delete_users();
delete_aliases();
prune_peers();
reload_config(1);
return 0;
}
static int reload(void)
{
return h323_reload(0, 0, NULL);
}
static struct ast_cli_entry cli_h323_reload =
{ { "h.323", "reload", NULL },
h323_reload, "Reload H.323 configuration",
h323_reload_usage
};
static enum ast_rtp_get_result oh323_get_rtp_peer(struct ast_channel *chan, struct ast_rtp **rtp)
{
struct oh323_pvt *pvt;
enum ast_rtp_get_result res = AST_RTP_GET_FAILED;
if (!(pvt = (struct oh323_pvt *)chan->tech_pvt))
return res;
ast_mutex_lock(&pvt->lock);
if (pvt->rtp && pvt->options.bridge) {
*rtp = pvt->rtp;
res = AST_RTP_TRY_NATIVE;
}
ast_mutex_unlock(&pvt->lock);
return res;
}
static enum ast_rtp_get_result oh323_get_vrtp_peer(struct ast_channel *chan, struct ast_rtp **rtp)
{
return AST_RTP_GET_FAILED;
}
static char *convertcap(int cap)
{
switch (cap) {
case AST_FORMAT_G723_1:
return "G.723";
case AST_FORMAT_GSM:
return "GSM";
case AST_FORMAT_ULAW:
return "ULAW";
case AST_FORMAT_ALAW:
return "ALAW";
case AST_FORMAT_ADPCM:
return "G.728";
case AST_FORMAT_G729A:
return "G.729";
case AST_FORMAT_SPEEX:
return "SPEEX";
case AST_FORMAT_ILBC:
return "ILBC";
default:
ast_log(LOG_NOTICE, "Don't know how to deal with mode %d\n", cap);
return NULL;
}
}
static int oh323_set_rtp_peer(struct ast_channel *chan, struct ast_rtp *rtp, struct ast_rtp *vrtp, int codecs, int nat_active)
{
/* XXX Deal with Video */
struct oh323_pvt *pvt;
struct sockaddr_in them;
struct sockaddr_in us;
char *mode;
if (!rtp) {
return 0;
}
mode = convertcap(chan->writeformat);
pvt = (struct oh323_pvt *) chan->tech_pvt;
if (!pvt) {
ast_log(LOG_ERROR, "No Private Structure, this is bad\n");
return -1;
}
ast_rtp_get_peer(rtp, &them);
ast_rtp_get_us(rtp, &us);
#if 0 /* Native bridge still isn't ready */
h323_native_bridge(pvt->cd.call_token, ast_inet_ntoa(them.sin_addr), mode);
#endif
return 0;
}
static struct ast_rtp_protocol oh323_rtp = {
.type = "H323",
.get_rtp_info = oh323_get_rtp_peer,
.get_vrtp_info = oh323_get_vrtp_peer,
.set_rtp_peer = oh323_set_rtp_peer,
};
static enum ast_module_load_result load_module(void)
{
int res;
h323debug = 0;
sched = sched_context_create();
if (!sched) {
ast_log(LOG_WARNING, "Unable to create schedule context\n");
return AST_MODULE_LOAD_FAILURE;
}
io = io_context_create();
if (!io) {
ast_log(LOG_WARNING, "Unable to create I/O context\n");
return AST_MODULE_LOAD_FAILURE;
}
ast_cli_register(&cli_h323_reload);
ASTOBJ_CONTAINER_INIT(&userl);
ASTOBJ_CONTAINER_INIT(&peerl);
ASTOBJ_CONTAINER_INIT(&aliasl);
res = reload_config(0);
if (res) {
return AST_MODULE_LOAD_DECLINE;
} else {
/* Make sure we can register our channel type */
if (ast_channel_register(&oh323_tech)) {
ast_log(LOG_ERROR, "Unable to register channel class 'H323'\n");
ast_cli_unregister(&cli_h323_reload);
h323_end_process();
io_context_destroy(io);
sched_context_destroy(sched);
ASTOBJ_CONTAINER_DESTROYALL(&userl, oh323_destroy_user);
ASTOBJ_CONTAINER_DESTROY(&userl);
ASTOBJ_CONTAINER_DESTROYALL(&peerl, oh323_destroy_peer);
ASTOBJ_CONTAINER_DESTROY(&peerl);
ASTOBJ_CONTAINER_DESTROYALL(&aliasl, oh323_destroy_alias);
ASTOBJ_CONTAINER_DESTROY(&aliasl);
return AST_MODULE_LOAD_FAILURE;
}
ast_cli_register_multiple(cli_h323, sizeof(cli_h323) / sizeof(struct ast_cli_entry));
ast_rtp_proto_register(&oh323_rtp);
/* Register our callback functions */
h323_callback_register(setup_incoming_call,
setup_outgoing_call,
external_rtp_create,
setup_rtp_connection,
cleanup_connection,
chan_ringing,
connection_made,
receive_digit,
answer_call,
progress,
set_dtmf_payload,
hangup_connection,
set_local_capabilities,
set_peer_capabilities);
/* start the h.323 listener */
if (h323_start_listener(h323_signalling_port, bindaddr)) {
ast_log(LOG_ERROR, "Unable to create H323 listener.\n");
ast_rtp_proto_unregister(&oh323_rtp);
ast_cli_unregister_multiple(cli_h323, sizeof(cli_h323) / sizeof(struct ast_cli_entry));
ast_cli_unregister(&cli_h323_reload);
h323_end_process();
io_context_destroy(io);
sched_context_destroy(sched);
ASTOBJ_CONTAINER_DESTROYALL(&userl, oh323_destroy_user);
ASTOBJ_CONTAINER_DESTROY(&userl);
ASTOBJ_CONTAINER_DESTROYALL(&peerl, oh323_destroy_peer);
ASTOBJ_CONTAINER_DESTROY(&peerl);
ASTOBJ_CONTAINER_DESTROYALL(&aliasl, oh323_destroy_alias);
ASTOBJ_CONTAINER_DESTROY(&aliasl);
return AST_MODULE_LOAD_FAILURE;
}
/* Possibly register with a GK */
if (!gatekeeper_disable) {
if (h323_set_gk(gatekeeper_discover, gatekeeper, secret)) {
ast_log(LOG_ERROR, "Gatekeeper registration failed.\n");
gatekeeper_disable = 1;
return AST_MODULE_LOAD_SUCCESS;
}
}
/* And start the monitor for the first time */
restart_monitor();
}
return res;
}
static int unload_module(void)
{
struct oh323_pvt *p, *pl;
/* unregister commands */
ast_cli_unregister_multiple(cli_h323, sizeof(cli_h323) / sizeof(struct ast_cli_entry));
ast_cli_unregister(&cli_h323_reload);
ast_channel_unregister(&oh323_tech);
ast_rtp_proto_unregister(&oh323_rtp);
if (!ast_mutex_lock(&iflock)) {
/* hangup all interfaces if they have an owner */
p = iflist;
while(p) {
if (p->owner) {
ast_softhangup(p->owner, AST_SOFTHANGUP_APPUNLOAD);
}
p = p->next;
}
iflist = NULL;
ast_mutex_unlock(&iflock);
} else {
ast_log(LOG_WARNING, "Unable to lock the interface list\n");
return -1;
}
if (!ast_mutex_lock(&monlock)) {
if ((monitor_thread != AST_PTHREADT_STOP) && (monitor_thread != AST_PTHREADT_NULL)) {
/* this causes a seg, anyone know why? */
if (monitor_thread != pthread_self())
pthread_cancel(monitor_thread);
pthread_kill(monitor_thread, SIGURG);
pthread_join(monitor_thread, NULL);
}
monitor_thread = AST_PTHREADT_STOP;
ast_mutex_unlock(&monlock);
} else {
ast_log(LOG_WARNING, "Unable to lock the monitor\n");
return -1;
}
if (!ast_mutex_lock(&iflock)) {
/* destroy all the interfaces and free their memory */
p = iflist;
while(p) {
pl = p;
p = p->next;
/* free associated memory */
ast_mutex_destroy(&pl->lock);
free(pl);
}
iflist = NULL;
ast_mutex_unlock(&iflock);
} else {
ast_log(LOG_WARNING, "Unable to lock the interface list\n");
return -1;
}
if (!gatekeeper_disable)
h323_gk_urq();
h323_end_process();
io_context_destroy(io);
sched_context_destroy(sched);
ASTOBJ_CONTAINER_DESTROYALL(&userl, oh323_destroy_user);
ASTOBJ_CONTAINER_DESTROY(&userl);
ASTOBJ_CONTAINER_DESTROYALL(&peerl, oh323_destroy_peer);
ASTOBJ_CONTAINER_DESTROY(&peerl);
ASTOBJ_CONTAINER_DESTROYALL(&aliasl, oh323_destroy_alias);
ASTOBJ_CONTAINER_DESTROY(&aliasl);
return 0;
}
AST_MODULE_INFO(ASTERISK_GPL_KEY, AST_MODFLAG_DEFAULT, "The NuFone Network's OpenH323 Channel Driver",
.load = load_module,
.unload = unload_module,
.reload = reload,
);
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