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review.jami.net / pjproject / e8df45f381f0043c435281d267c624d98d934e5f / . / pjnath / src / pjturn-srv / allocation.c
blob: 725863ce8b9dd496fe6ddca7e7b7f1371ec5a0e4 [file] [log] [blame]
/* $Id$ */
/*
* Copyright (C) 2003-2007 Benny Prijono <benny@prijono.org>
*
* This program is free software; you can redistribute it and/or modify
* it under the terms of the GNU General Public License as published by
* the Free Software Foundation; either version 2 of the License, or
* (at your option) any later version.
*
* This program 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 General Public License for more details.
*
* You should have received a copy of the GNU General Public License
* along with this program; if not, write to the Free Software
* Foundation, Inc., 59 Temple Place, Suite 330, Boston, MA 02111-1307 USA
*/
#include "turn.h"
#define THIS_FILE "allocation.c"
enum {
TIMER_ID_NONE,
TIMER_ID_TIMEOUT,
TIMER_ID_DESTROY
};
#define DESTROY_DELAY {0, 500}
#define PEER_TABLE_SIZE 32
/* ChannelData header */
typedef struct channel_data_hdr
{
pj_uint16_t ch_number;
pj_uint16_t length;
} channel_data_hdr;
/* Prototypes */
static pj_status_t create_relay(pjturn_allocation *alloc,
const pjturn_allocation_req *req);
static void on_rx_from_peer(pj_ioqueue_key_t *key,
pj_ioqueue_op_key_t *op_key,
pj_ssize_t bytes_read);
static void destroy_relay(pjturn_relay_res *relay);
static pj_status_t stun_on_send_msg(pj_stun_session *sess,
const void *pkt,
pj_size_t pkt_size,
const pj_sockaddr_t *dst_addr,
unsigned addr_len);
static pj_status_t stun_on_rx_request(pj_stun_session *sess,
const pj_uint8_t *pkt,
unsigned pkt_len,
const pj_stun_msg *msg,
const pj_sockaddr_t *src_addr,
unsigned src_addr_len);
static pj_status_t stun_on_rx_indication(pj_stun_session *sess,
const pj_uint8_t *pkt,
unsigned pkt_len,
const pj_stun_msg *msg,
const pj_sockaddr_t *src_addr,
unsigned src_addr_len);
/* Log allocation error */
static void alloc_err(pjturn_allocation *alloc, const char *title,
pj_status_t status)
{
char errmsg[PJ_ERR_MSG_SIZE];
pj_strerror(status, errmsg, sizeof(errmsg));
PJ_LOG(4,(alloc->obj_name, "%s for client %s: %s",
title, alloc->info, errmsg));
}
/*
* Create new allocation.
*/
PJ_DEF(pj_status_t) pjturn_allocation_create(pjturn_listener *listener,
const pj_sockaddr_t *src_addr,
unsigned src_addr_len,
const pj_stun_msg *msg,
const pjturn_allocation_req *req,
pjturn_allocation **p_alloc)
{
pjturn_srv *srv = listener->server;
pj_pool_t *pool;
pjturn_allocation *alloc;
pj_stun_session_cb sess_cb;
char relay_info[80];
pj_status_t status;
pool = pj_pool_create(srv->core.pf, "alloc%p", 1000, 1000, NULL);
/* Init allocation structure */
alloc = PJ_POOL_ZALLOC_T(pool, pjturn_allocation);
alloc->pool = pool;
alloc->obj_name = pool->obj_name;
alloc->listener = listener;
alloc->clt_sock = PJ_INVALID_SOCKET;
alloc->relay.tp.sock = PJ_INVALID_SOCKET;
alloc->bandwidth = req->bandwidth;
alloc->hkey.tp_type = listener->tp_type;
pj_memcpy(&alloc->hkey.clt_addr, src_addr, src_addr_len);
status = pj_lock_create_recursive_mutex(pool, alloc->obj_name,
&alloc->lock);
if (status != PJ_SUCCESS) {
pjturn_allocation_destroy(alloc);
return status;
}
/* Create peer hash table */
alloc->peer_table = pj_hash_create(pool, PEER_TABLE_SIZE);
/* Create channel hash table */
alloc->ch_table = pj_hash_create(pool, PEER_TABLE_SIZE);
/* Print info */
pj_ansi_strcpy(alloc->info, pjturn_tp_type_name(listener->tp_type));
alloc->info[3] = ':';
pj_sockaddr_print(src_addr, alloc->info+4, sizeof(alloc->info)-4, 3);
/* Create STUN session to handle STUN communication with client */
pj_bzero(&sess_cb, sizeof(sess_cb));
sess_cb.on_send_msg = &stun_on_send_msg;
sess_cb.on_rx_request = &stun_on_rx_request;
sess_cb.on_rx_indication = &stun_on_rx_indication;
status = pj_stun_session_create(&srv->core.stun_cfg, alloc->obj_name,
&sess_cb, PJ_FALSE, &alloc->sess);
if (status != PJ_SUCCESS) {
pjturn_allocation_destroy(alloc);
return status;
}
/* Attach to STUN session */
pj_stun_session_set_user_data(alloc->sess, alloc);
/* Create the relay resource */
status = pjturn_allocation_create_relay(srv, alloc, msg, req,
&alloc->relay);
if (status != PJ_SUCCESS) {
pjturn_allocation_destroy(alloc);
return status;
}
/* Register this allocation */
pjturn_srv_register_allocation(srv, alloc);
pj_sockaddr_print(&alloc->relay.hkey.addr, relay_info,
sizeof(relay_info), 3);
PJ_LOG(4,(alloc->obj_name, "Client %s created, relay addr=%s:%s",
alloc->info, pjturn_tp_type_name(req->tp_type), relay_info));
/* Success */
*p_alloc = alloc;
return PJ_SUCCESS;
}
/*
* Destroy allocation.
*/
PJ_DECL(void) pjturn_allocation_destroy(pjturn_allocation *alloc)
{
pj_pool_t *pool;
/* Unregister this allocation */
pjturn_srv_unregister_allocation(alloc->listener->server, alloc);
/* Destroy relay */
destroy_relay(&alloc->relay);
/* Must lock only after destroying relay otherwise deadlock */
if (alloc->lock) {
pj_lock_acquire(alloc->lock);
}
/* Destroy STUN session */
if (alloc->sess) {
pj_stun_session_destroy(alloc->sess);
alloc->sess = NULL;
}
/* Destroy lock */
if (alloc->lock) {
pj_lock_release(alloc->lock);
pj_lock_destroy(alloc->lock);
alloc->lock = NULL;
}
/* Destroy pool */
pool = alloc->pool;
if (pool) {
alloc->pool = NULL;
pj_pool_release(pool);
}
}
/* Destroy relay resource */
static void destroy_relay(pjturn_relay_res *relay)
{
if (relay->timer.id) {
pj_timer_heap_cancel(relay->allocation->listener->server->core.timer_heap,
&relay->timer);
relay->timer.id = PJ_FALSE;
}
if (relay->tp.key) {
pj_ioqueue_unregister(relay->tp.key);
relay->tp.key = NULL;
relay->tp.sock = PJ_INVALID_SOCKET;
} else if (relay->tp.sock != PJ_INVALID_SOCKET) {
pj_sock_close(relay->tp.sock);
relay->tp.sock = PJ_INVALID_SOCKET;
}
/* Mark as shutdown */
relay->lifetime = 0;
}
/* Initiate shutdown sequence for this allocation */
static void alloc_shutdown(pjturn_allocation *alloc)
{
pj_time_val destroy_delay = DESTROY_DELAY;
/* Work with existing schedule */
if (alloc->relay.timer.id == TIMER_ID_TIMEOUT) {
/* Cancel existing timer */
pj_timer_heap_cancel(alloc->listener->server->core.timer_heap,
&alloc->relay.timer);
alloc->relay.timer.id = TIMER_ID_NONE;
} else if (alloc->relay.timer.id == TIMER_ID_DESTROY) {
/* We've been scheduled to be destroyed, ignore this
* shutdown request.
*/
return;
}
pj_assert(alloc->relay.timer.id == TIMER_ID_NONE);
/* Shutdown relay socket */
destroy_relay(&alloc->relay);
/* Don't unregister from hash table because we still need to
* handle REFRESH retransmission.
*/
/* Schedule destroy timer */
alloc->relay.timer.id = TIMER_ID_DESTROY;
pj_timer_heap_schedule(alloc->listener->server->core.timer_heap,
&alloc->relay.timer, &destroy_delay);
}
/* Reschedule timeout using current lifetime setting */
static pj_status_t resched_timeout(pjturn_allocation *alloc)
{
pj_time_val delay;
pj_status_t status;
pj_gettimeofday(&alloc->relay.expiry);
alloc->relay.expiry.sec += alloc->relay.lifetime;
pj_assert(alloc->relay.timer.id != TIMER_ID_DESTROY);
if (alloc->relay.timer.id != 0) {
pj_timer_heap_cancel(alloc->listener->server->core.timer_heap,
&alloc->relay.timer);
alloc->relay.timer.id = TIMER_ID_NONE;
}
delay.sec = alloc->relay.lifetime;
delay.msec = 0;
alloc->relay.timer.id = TIMER_ID_TIMEOUT;
status = pj_timer_heap_schedule(alloc->listener->server->core.timer_heap,
&alloc->relay.timer, &delay);
if (status != PJ_SUCCESS) {
alloc->relay.timer.id = TIMER_ID_NONE;
return status;
}
return PJ_SUCCESS;
}
/* Timer timeout callback */
static void relay_timeout_cb(pj_timer_heap_t *heap, pj_timer_entry *e)
{
pjturn_relay_res *rel;
pjturn_allocation *alloc;
rel = (pjturn_relay_res*) e->user_data;
alloc = rel->allocation;
if (e->id == TIMER_ID_TIMEOUT) {
e->id = TIMER_ID_NONE;
PJ_LOG(4,(alloc->obj_name,
"Client %s refresh timed-out, shutting down..",
alloc->info));
alloc_shutdown(alloc);
} else if (e->id == TIMER_ID_DESTROY) {
e->id = TIMER_ID_NONE;
PJ_LOG(4,(alloc->obj_name, "Client %s destroying..",
alloc->info));
pjturn_allocation_destroy(alloc);
}
}
/*
* Create relay.
*/
PJ_DEF(pj_status_t) pjturn_allocation_create_relay(pjturn_srv *srv,
pjturn_allocation *alloc,
const pj_stun_msg *msg,
const pjturn_allocation_req *req,
pjturn_relay_res *relay)
{
enum { RETRY = 40 };
pj_pool_t *pool = alloc->pool;
int retry, retry_max, sock_type;
pj_ioqueue_callback icb;
int af, namelen;
pj_stun_string_attr *sa;
pj_status_t status;
pj_bzero(relay, sizeof(*relay));
relay->allocation = alloc;
relay->tp.sock = PJ_INVALID_SOCKET;
/* TODO: get the requested address family from somewhere */
af = alloc->listener->addr.addr.sa_family;
/* Save realm */
sa = (pj_stun_string_attr*)
pj_stun_msg_find_attr(msg, PJ_STUN_ATTR_REALM, 0);
PJ_ASSERT_RETURN(sa, PJ_EINVALIDOP);
pj_strdup(pool, &relay->realm, &sa->value);
/* Save username */
sa = (pj_stun_string_attr*)
pj_stun_msg_find_attr(msg, PJ_STUN_ATTR_USERNAME, 0);
PJ_ASSERT_RETURN(sa, PJ_EINVALIDOP);
pj_strdup(pool, &relay->user, &sa->value);
/* Lifetime and timeout */
relay->lifetime = req->lifetime;
pj_timer_entry_init(&relay->timer, TIMER_ID_NONE, relay,
&relay_timeout_cb);
resched_timeout(alloc);
/* Transport type */
relay->hkey.tp_type = req->tp_type;
/* Create the socket */
if (req->tp_type == PJTURN_TP_UDP) {
sock_type = pj_SOCK_DGRAM();
} else if (req->tp_type == PJTURN_TP_TCP) {
sock_type = pj_SOCK_STREAM();
} else {
pj_assert(!"Unknown transport");
return PJ_EINVALIDOP;
}
status = pj_sock_socket(af, sock_type, 0, &relay->tp.sock);
if (status != PJ_SUCCESS) {
pj_bzero(relay, sizeof(*relay));
return status;
}
/* Find suitable port for this allocation */
if (req->rpp_port) {
retry_max = 1;
} else {
retry_max = RETRY;
}
for (retry=0; retry<retry_max; ++retry) {
pj_uint16_t port;
pj_sockaddr bound_addr;
pj_lock_acquire(srv->core.lock);
if (req->rpp_port) {
port = (pj_uint16_t) req->rpp_port;
} else if (req->tp_type == PJTURN_TP_UDP) {
port = (pj_uint16_t) srv->ports.next_udp++;
if (srv->ports.next_udp > srv->ports.max_udp)
srv->ports.next_udp = srv->ports.min_udp;
} else if (req->tp_type == PJTURN_TP_TCP) {
port = (pj_uint16_t) srv->ports.next_tcp++;
if (srv->ports.next_tcp > srv->ports.max_tcp)
srv->ports.next_tcp = srv->ports.min_tcp;
} else {
pj_assert(!"Invalid transport");
}
pj_lock_release(srv->core.lock);
pj_sockaddr_init(af, &bound_addr, NULL, port);
status = pj_sock_bind(relay->tp.sock, &bound_addr,
pj_sockaddr_get_len(&bound_addr));
if (status == PJ_SUCCESS)
break;
}
if (status != PJ_SUCCESS) {
/* Unable to allocate port */
PJ_LOG(4,(THIS_FILE, "bind() failed: err %d",
status));
pj_sock_close(relay->tp.sock);
relay->tp.sock = PJ_INVALID_SOCKET;
return status;
}
/* Init relay key */
namelen = sizeof(relay->hkey.addr);
status = pj_sock_getsockname(relay->tp.sock, &relay->hkey.addr, &namelen);
if (status != PJ_SUCCESS) {
PJ_LOG(4,(THIS_FILE, "pj_sock_getsockname() failed: err %d",
status));
pj_sock_close(relay->tp.sock);
relay->tp.sock = PJ_INVALID_SOCKET;
return status;
}
if (!pj_sockaddr_has_addr(&relay->hkey.addr)) {
pj_sockaddr_copy_addr(&relay->hkey.addr, &alloc->listener->addr);
}
/* Init ioqueue */
pj_bzero(&icb, sizeof(icb));
icb.on_read_complete = &on_rx_from_peer;
status = pj_ioqueue_register_sock(pool, srv->core.ioqueue, relay->tp.sock,
relay, &icb, &relay->tp.key);
if (status != PJ_SUCCESS) {
PJ_LOG(4,(THIS_FILE, "pj_ioqueue_register_sock() failed: err %d",
status));
pj_sock_close(relay->tp.sock);
relay->tp.sock = PJ_INVALID_SOCKET;
return status;
}
/* Kick off pending read operation */
pj_ioqueue_op_key_init(&relay->tp.read_key, sizeof(relay->tp.read_key));
on_rx_from_peer(relay->tp.key, &relay->tp.read_key, 0);
/* Done */
return PJ_SUCCESS;
}
/* Create and send error response */
static void send_reply_err(pjturn_allocation *alloc,
const pj_stun_msg *req,
pj_bool_t cache,
int code, const char *errmsg)
{
pj_status_t status;
pj_str_t reason;
pj_stun_tx_data *tdata;
status = pj_stun_session_create_res(alloc->sess, req,
code, (errmsg?pj_cstr(&reason,errmsg):NULL),
&tdata);
if (status != PJ_SUCCESS) {
alloc_err(alloc, "Error creating STUN error response", status);
return;
}
status = pj_stun_session_send_msg(alloc->sess, cache,
&alloc->hkey.clt_addr,
pj_sockaddr_get_len(&alloc->hkey.clt_addr),
tdata);
if (status != PJ_SUCCESS) {
alloc_err(alloc, "Error sending STUN error response", status);
return;
}
}
/* Create and send successful response */
static void send_reply_ok(pjturn_allocation *alloc,
const pj_stun_msg *req)
{
pj_status_t status;
unsigned interval;
pj_stun_tx_data *tdata;
status = pj_stun_session_create_res(alloc->sess, req, 0, NULL, &tdata);
if (status != PJ_SUCCESS) {
alloc_err(alloc, "Error creating STUN success response", status);
return;
}
/* Calculate time to expiration */
if (alloc->relay.lifetime != 0) {
pj_time_val now;
pj_gettimeofday(&now);
interval = alloc->relay.expiry.sec - now.sec;
} else {
interval = 0;
}
/* Add LIFETIME. */
pj_stun_msg_add_uint_attr(tdata->pool, tdata->msg,
PJ_STUN_ATTR_LIFETIME, interval);
/* Add BANDWIDTH */
pj_stun_msg_add_uint_attr(tdata->pool, tdata->msg,
PJ_STUN_ATTR_BANDWIDTH,
alloc->bandwidth);
status = pj_stun_session_send_msg(alloc->sess, PJ_TRUE,
&alloc->hkey.clt_addr,
pj_sockaddr_get_len(&alloc->hkey.clt_addr),
tdata);
if (status != PJ_SUCCESS) {
alloc_err(alloc, "Error sending STUN success response", status);
return;
}
}
/* Create new permission */
static pjturn_permission *create_permission(pjturn_allocation *alloc,
const pj_sockaddr_t *peer_addr,
unsigned addr_len)
{
pjturn_permission *perm;
perm = PJ_POOL_ZALLOC_T(alloc->pool, pjturn_permission);
pj_memcpy(&perm->hkey.peer_addr, peer_addr, addr_len);
if (alloc->listener->tp_type == PJTURN_TP_UDP) {
perm->sock = alloc->listener->sock;
} else {
pj_assert(!"TCP is not supported yet");
return NULL;
}
perm->allocation = alloc;
perm->channel = PJTURN_INVALID_CHANNEL;
pj_gettimeofday(&perm->expiry);
perm->expiry.sec += PJTURN_PERM_TIMEOUT;
return perm;
}
/* Check if a permission isn't expired. Return NULL if expired. */
static pjturn_permission *check_permission_expiry(pjturn_permission *perm)
{
pjturn_allocation *alloc = perm->allocation;
pj_time_val now;
pj_gettimeofday(&now);
if (PJ_TIME_VAL_LT(perm->expiry, now)) {
/* Permission has not expired */
return perm;
}
/* Remove from permission hash table */
pj_hash_set(NULL, alloc->peer_table, &perm->hkey, sizeof(perm->hkey),
0, NULL);
/* Remove from channel hash table, if assigned a channel number */
if (perm->channel != PJTURN_INVALID_CHANNEL) {
pj_hash_set(NULL, alloc->ch_table, &perm->channel,
sizeof(perm->channel), 0, NULL);
}
return NULL;
}
/* Lookup permission in hash table by the peer address */
static pjturn_permission*
lookup_permission_by_addr(pjturn_allocation *alloc,
const pj_sockaddr_t *peer_addr,
unsigned addr_len)
{
pjturn_permission_key key;
pjturn_permission *perm;
pj_bzero(&key, sizeof(key));
pj_memcpy(&key, peer_addr, addr_len);
/* Lookup in peer hash table */
perm = (pjturn_permission*) pj_hash_get(alloc->peer_table, &key,
sizeof(key), NULL);
return check_permission_expiry(perm);
}
/* Lookup permission in hash table by the channel number */
static pjturn_permission*
lookup_permission_by_chnum(pjturn_allocation *alloc,
unsigned chnum)
{
pj_uint16_t chnum16 = (pj_uint16_t)chnum;
pjturn_permission *perm;
/* Lookup in peer hash table */
perm = (pjturn_permission*) pj_hash_get(alloc->peer_table, &chnum16,
sizeof(chnum16), NULL);
return check_permission_expiry(perm);
}
/* Update permission because of data from client to peer.
* Return PJ_TRUE is permission is found.
*/
static pj_bool_t refresh_permission(pjturn_permission *perm)
{
pj_gettimeofday(&perm->expiry);
if (perm->channel == PJTURN_INVALID_CHANNEL)
perm->expiry.sec += PJTURN_PERM_TIMEOUT;
else
perm->expiry.sec += PJTURN_CHANNEL_TIMEOUT;
return PJ_TRUE;
}
/*
* Handle incoming packet from client.
*/
PJ_DEF(void) pjturn_allocation_on_rx_client_pkt( pjturn_allocation *alloc,
pjturn_pkt *pkt)
{
pj_bool_t is_stun;
pj_status_t status;
/* Quickly check if this is STUN message */
is_stun = ((*((pj_uint8_t*)pkt->pkt) & 0xC0) == 0);
if (is_stun) {
/*
* This could be an incoming STUN requests or indications.
* Pass this through to the STUN session, which will call
* our stun_on_rx_request() or stun_on_rx_indication()
* callbacks.
*/
unsigned options = PJ_STUN_CHECK_PACKET;
if (pkt->listener->tp_type == PJTURN_TP_UDP)
options |= PJ_STUN_IS_DATAGRAM;
status = pj_stun_session_on_rx_pkt(alloc->sess, pkt->pkt, pkt->len,
options, NULL,
&pkt->src.clt_addr,
pkt->src_addr_len);
if (status != PJ_SUCCESS) {
alloc_err(alloc, "Error handling STUN packet", status);
return;
}
} else {
/*
* This is not a STUN packet, must be ChannelData packet.
*/
channel_data_hdr *cd = (channel_data_hdr*)pkt->pkt;
pjturn_permission *perm;
pj_ssize_t len;
/* For UDP check the packet length */
if (alloc->listener->tp_type == PJTURN_TP_UDP) {
if (pkt->len < pj_ntohs(cd->length)+sizeof(*cd)) {
PJ_LOG(4,(alloc->obj_name,
"ChannelData from %s discarded: UDP size error",
alloc->info));
return;
}
} else {
pj_assert(!"Unsupported transport");
return;
}
perm = lookup_permission_by_chnum(alloc, pj_ntohs(cd->ch_number));
if (!perm) {
/* Discard */
PJ_LOG(4,(alloc->obj_name,
"ChannelData from %s discarded: not found",
alloc->info));
return;
}
/* Relay the data */
len = pj_ntohs(cd->length);
pj_sock_sendto(alloc->relay.tp.sock, cd+1, &len, 0,
&perm->hkey.peer_addr,
pj_sockaddr_get_len(&perm->hkey.peer_addr));
/* Refresh permission */
refresh_permission(perm);
}
}
/*
* Handle incoming packet from peer. This function is called by
* on_rx_from_peer().
*/
static void on_rx_peer_pkt(pjturn_allocation *alloc,
pjturn_relay_res *rel,
char *pkt, pj_size_t len,
const pj_sockaddr *src_addr)
{
pjturn_permission *perm;
/* Lookup permission */
perm = lookup_permission_by_addr(alloc, src_addr,
pj_sockaddr_get_len(src_addr));
if (perm == NULL) {
/* No permission, discard data */
return;
}
/* Send Data Indication or ChannelData, depends on whether
* this permission is attached to a channel number.
*/
if (perm->channel != PJTURN_INVALID_CHANNEL) {
/* Send ChannelData */
channel_data_hdr *cd = (channel_data_hdr*)rel->tp.tx_pkt;
if (len > PJTURN_MAX_PKT_LEN) {
char peer_addr[80];
pj_sockaddr_print(src_addr, peer_addr, sizeof(peer_addr), 3);
PJ_LOG(1,(alloc->obj_name, "Client %s: discarded data from %s "
"because it's too long (%d bytes)",
alloc->info, peer_addr, len));
return;
}
/* Init header */
cd->ch_number = pj_htons(perm->channel);
cd->length = pj_htons((pj_uint16_t)len);
/* Copy data */
pj_memcpy(rel->tp.rx_pkt+sizeof(channel_data_hdr), pkt, len);
/* Send to client */
pjturn_listener_sendto(alloc->listener, rel->tp.tx_pkt,
len+sizeof(channel_data_hdr), 0,
&alloc->hkey.clt_addr,
pj_sockaddr_get_len(&alloc->hkey.clt_addr));
} else {
/* Send Data Indication */
pj_stun_tx_data *tdata;
pj_status_t status;
status = pj_stun_session_create_ind(alloc->sess,
PJ_STUN_DATA_INDICATION, &tdata);
if (status != PJ_SUCCESS) {
alloc_err(alloc, "Error creating Data indication", status);
return;
}
}
}
/*
* ioqueue notification on RX packets from the relay socket.
*/
static void on_rx_from_peer(pj_ioqueue_key_t *key,
pj_ioqueue_op_key_t *op_key,
pj_ssize_t bytes_read)
{
pjturn_relay_res *rel;
pj_status_t status;
rel = (pjturn_relay_res*) pj_ioqueue_get_user_data(key);
do {
if (bytes_read > 0) {
on_rx_peer_pkt(rel->allocation, rel, rel->tp.rx_pkt,
bytes_read, &rel->tp.src_addr);
}
/* Read next packet */
bytes_read = sizeof(rel->tp.rx_pkt);
rel->tp.src_addr_len = sizeof(rel->tp.src_addr);
status = pj_ioqueue_recvfrom(key, op_key,
rel->tp.rx_pkt, &bytes_read, 0,
&rel->tp.src_addr,
&rel->tp.src_addr_len);
if (status != PJ_EPENDING && status != PJ_SUCCESS)
bytes_read = -status;
} while (status != PJ_EPENDING && status != PJ_ECANCELLED);
}
/*
* Callback notification from STUN session when it wants to send
* a STUN message towards the client.
*/
static pj_status_t stun_on_send_msg(pj_stun_session *sess,
const void *pkt,
pj_size_t pkt_size,
const pj_sockaddr_t *dst_addr,
unsigned addr_len)
{
pjturn_allocation *alloc;
alloc = (pjturn_allocation*) pj_stun_session_get_user_data(sess);
return pjturn_listener_sendto(alloc->listener, pkt, pkt_size, 0,
dst_addr, addr_len);
}
/*
* Callback notification from STUN session when it receives STUN
* requests. This callback was trigger by STUN incoming message
* processing in pjturn_allocation_on_rx_client_pkt().
*/
static pj_status_t stun_on_rx_request(pj_stun_session *sess,
const pj_uint8_t *pkt,
unsigned pkt_len,
const pj_stun_msg *msg,
const pj_sockaddr_t *src_addr,
unsigned src_addr_len)
{
pjturn_allocation *alloc;
alloc = (pjturn_allocation*) pj_stun_session_get_user_data(sess);
/* Refuse to serve any request if we've been shutdown */
if (alloc->relay.lifetime == 0) {
send_reply_err(alloc, msg, PJ_TRUE,
PJ_STUN_SC_ALLOCATION_MISMATCH, NULL);
return PJ_SUCCESS;
}
if (msg->hdr.type == PJ_STUN_REFRESH_REQUEST) {
/*
* Handle REFRESH request
*/
pj_stun_lifetime_attr *lifetime;
pj_stun_bandwidth_attr *bandwidth;
/* Get LIFETIME attribute */
lifetime = (pj_stun_lifetime_attr*)
pj_stun_msg_find_attr(msg, PJ_STUN_ATTR_LIFETIME, 0);
/* Get BANDWIDTH attribute */
bandwidth = (pj_stun_bandwidth_attr*)
pj_stun_msg_find_attr(msg, PJ_STUN_ATTR_BANDWIDTH, 0);
if (lifetime && lifetime->value==0) {
/*
* This is deallocation request.
*/
alloc->relay.lifetime = 0;
/* Respond first */
send_reply_ok(alloc, msg);
/* Shutdown allocation */
PJ_LOG(4,(alloc->obj_name,
"Client %s request to dealloc, shutting down",
alloc->info));
alloc_shutdown(alloc);
} else {
/*
* This is a refresh request.
*/
/* Update lifetime */
if (lifetime) {
alloc->relay.lifetime = lifetime->value;
}
/* Update bandwidth */
// TODO:
/* Update expiration timer */
resched_timeout(alloc);
/* Send reply */
send_reply_ok(alloc, msg);
}
} else if (msg->hdr.type == PJ_STUN_CHANNEL_BIND_REQUEST) {
/*
* ChannelBind request.
*/
pj_stun_channel_number_attr *ch_attr;
pj_stun_peer_addr_attr *peer_attr;
pjturn_permission *p1, *p2;
ch_attr = (pj_stun_channel_number_attr*)
pj_stun_msg_find_attr(msg, PJ_STUN_ATTR_CHANNEL_NUMBER, 0);
peer_attr = (pj_stun_peer_addr_attr*)
pj_stun_msg_find_attr(msg, PJ_STUN_ATTR_PEER_ADDR, 0);
if (!ch_attr || !peer_attr) {
send_reply_err(alloc, msg, PJ_TRUE, PJ_STUN_SC_BAD_REQUEST, NULL);
return PJ_SUCCESS;
}
/* Find permission with the channel number */
p1 = lookup_permission_by_chnum(alloc, PJ_STUN_GET_CH_NB(ch_attr->value));
/* If permission is found, this is supposed to be a channel bind
* refresh. Make sure it's for the same peer.
*/
if (p1) {
if (pj_sockaddr_cmp(&p1->hkey.peer_addr, &peer_attr->sockaddr)) {
/* Address mismatch. Send 400 */
send_reply_err(alloc, msg, PJ_TRUE,
PJ_STUN_SC_BAD_REQUEST,
"Peer address mismatch");
return PJ_SUCCESS;
}
/* Refresh permission */
refresh_permission(p1);
/* Done */
return PJ_SUCCESS;
}
/* If permission is not found, create a new one. Make sure the peer
* has not alreadyy assigned with a channel number.
*/
p2 = lookup_permission_by_addr(alloc, &peer_attr->sockaddr,
pj_sockaddr_get_len(&peer_attr->sockaddr));
if (p2 && p2->channel != PJTURN_INVALID_CHANNEL) {
send_reply_err(alloc, msg, PJ_TRUE, PJ_STUN_SC_BAD_REQUEST,
"Peer address already assigned a channel number");
return PJ_SUCCESS;
}
/* Create permission if it doesn't exist */
if (!p2) {
p2 = create_permission(alloc, &peer_attr->sockaddr,
pj_sockaddr_get_len(&peer_attr->sockaddr));
if (!p2)
return PJ_SUCCESS;
}
/* Assign channel number to permission */
p2->channel = PJ_STUN_GET_CH_NB(ch_attr->value);
/* Update */
refresh_permission(p2);
/* Reply */
send_reply_ok(alloc, msg);
return PJ_SUCCESS;
} else if (msg->hdr.type == PJ_STUN_ALLOCATE_REQUEST) {
/* Respond with 437 (section 6.3 turn-07) */
send_reply_err(alloc, msg, PJ_TRUE, PJ_STUN_SC_ALLOCATION_MISMATCH, NULL);
} else {
/* Respond with Bad Request? */
send_reply_err(alloc, msg, PJ_TRUE, PJ_STUN_SC_BAD_REQUEST, NULL);
}
return PJ_SUCCESS;
}
/*
* Callback notification from STUN session when it receives STUN
* indications. This callback was trigger by STUN incoming message
* processing in pjturn_allocation_on_rx_client_pkt().
*/
static pj_status_t stun_on_rx_indication(pj_stun_session *sess,
const pj_uint8_t *pkt,
unsigned pkt_len,
const pj_stun_msg *msg,
const pj_sockaddr_t *src_addr,
unsigned src_addr_len)
{
pj_stun_peer_addr_attr *peer_attr;
pj_stun_data_attr *data_attr;
pjturn_allocation *alloc;
pjturn_permission *perm;
alloc = (pjturn_allocation*) pj_stun_session_get_user_data(sess);
/* Only expect Send Indication */
if (msg->hdr.type != PJ_STUN_SEND_INDICATION) {
/* Ignore */
return PJ_SUCCESS;
}
/* Get PEER-ADDRESS attribute */
peer_attr = (pj_stun_peer_addr_attr*)
pj_stun_msg_find_attr(msg, PJ_STUN_ATTR_PEER_ADDR, 0);
/* MUST have PEER-ADDRESS attribute */
if (!peer_attr)
return PJ_SUCCESS;
/* Get DATA attribute */
data_attr = (pj_stun_data_attr*)
pj_stun_msg_find_attr(msg, PJ_STUN_ATTR_DATA, 0);
/* Create/update/refresh the permission */
perm = lookup_permission_by_addr(alloc, &peer_attr->sockaddr,
pj_sockaddr_get_len(&peer_attr->sockaddr));
if (perm == NULL) {
perm = create_permission(alloc, &peer_attr->sockaddr,
pj_sockaddr_get_len(&peer_attr->sockaddr));
}
refresh_permission(perm);
/* Return if we don't have data */
if (data_attr == NULL)
return PJ_SUCCESS;
/* Relay the data to client */
if (alloc->hkey.tp_type == PJTURN_TP_UDP) {
pj_ssize_t len = data_attr->length;
pj_sock_sendto(alloc->listener->sock, data_attr->data,
&len, 0, &peer_attr->sockaddr,
pj_sockaddr_get_len(&peer_attr->sockaddr));
} else {
pj_assert(!"TCP is not supported");
}
return PJ_SUCCESS;
}