static char *
pseudo_serialno_from_addr(char *name)
{
int sd, rc, errnum;
char buf[128];
struct hostent *hp;
struct xarpreq ar;
if (name == NULL)
return (NULL);
memset(&ar, 0, sizeof (ar));
hp = getipnodebyname(name, AF_INET6, AI_ADDRCONFIG, &errnum);
if (hp != NULL) {
struct sockaddr_in6 *sin6 = (struct sockaddr_in6 *)&ar.xarp_pa;
sin6->sin6_family = AF_INET6;
(void) memcpy(&sin6->sin6_addr, hp->h_addr_list[0],
hp->h_length);
} else {
struct sockaddr_in *sin = (struct sockaddr_in *)&ar.xarp_pa;
sin->sin_family = AF_INET;
sin->sin_addr.s_addr = inet_addr(name);
}
sd = socket(AF_INET, SOCK_DGRAM, 0);
ar.xarp_ha.sdl_family = AF_LINK;
rc = ioctl(sd, SIOCGXARP, (caddr_t)&ar);
close(sd);
if (ar.xarp_flags & ATF_COM) { /* use the MAC address */
uchar_t *ea = (uchar_t *)LLADDR(&ar.xarp_ha);
addr_to_string("LLADDR-", ea, ar.xarp_ha.sdl_alen,
buf, sizeof (buf));
} else if (hp != NULL) { /* use the IPv6 address */
addr_to_string("IPV6ADDR-", (uchar_t *)&hp->h_addr_list[0],
hp->h_length, buf, sizeof (buf));
} else { /* use the IPv4 address */
struct sockaddr_in *sin = (struct sockaddr_in *)&ar.xarp_pa;
addr_to_string("IPV4ADDR-", (uchar_t *)&sin->sin_addr.s_addr, 4,
buf, sizeof (buf));
}
return (strdup(buf));
}
void _hna_global_del_orig(struct hna_global_entry *hna_global_entry,
char *message)
{
char hna_str[ETH_STR_LEN], orig_str[ETH_STR_LEN];
addr_to_string(orig_str, hna_global_entry->orig_node->orig);
addr_to_string(hna_str, hna_global_entry->addr);
debug_log(LOG_TYPE_ROUTES, "Deleting global hna entry %s (via %s): %s \n", hna_str, orig_str, message);
hash_remove(hna_global_hash, hna_global_entry->addr);
kfree(hna_global_entry);
}
QString StunClient::getStunAddress(QByteArray resp, uint16_t attr_type)
{
stun_buffer buf;
u08bits addr_buff[STUN_BUFFER_SIZE] = {0};
buf.len = resp.length();
memcpy(buf.buf, resp.data(), resp.length());
uint16_t t_attr_type;
const u08bits *attr_value;
int attr_len;
ioa_addr stun_addr;
stun_attr_ref raw_attr = stun_attr_get_first_str(buf.buf, buf.len);
for ( ; raw_attr ; raw_attr = stun_attr_get_next_str(buf.buf, buf.len, raw_attr)) {
t_attr_type = stun_attr_get_type(raw_attr);
attr_value = stun_attr_get_value(raw_attr);
attr_len = stun_attr_get_len(raw_attr);
if (t_attr_type == attr_type) {
stun_attr_get_addr_str(buf.buf, buf.len, raw_attr, &stun_addr, NULL);
addr_to_string(&stun_addr, (u08bits*)addr_buff);
break;
}
}
return QString((char*)addr_buff);
}
static int create_server_listener(tls_listener_relay_server_type* server) {
FUNCSTART;
if(!server) return -1;
evutil_socket_t tls_listen_fd = -1;
tls_listen_fd = socket(server->addr.ss.ss_family, SOCK_STREAM, 0);
if (tls_listen_fd < 0) {
perror("socket");
return -1;
}
if(sock_bind_to_device(tls_listen_fd, (unsigned char*)server->ifname)<0) {
TURN_LOG_FUNC(TURN_LOG_LEVEL_INFO,"Cannot bind listener socket to device %s\n",server->ifname);
}
if(addr_bind(tls_listen_fd,&server->addr)<0) {
perror("Cannot bind local socket to addr");
char saddr[129];
addr_to_string(&server->addr,(u08bits*)saddr);
TURN_LOG_FUNC(TURN_LOG_LEVEL_INFO,"Cannot bind TCP/TLS listener socket to addr %s\n",saddr);
socket_closesocket(tls_listen_fd);
return -1;
}
socket_tcp_set_keepalive(tls_listen_fd);
socket_set_nonblocking(tls_listen_fd);
server->l = evconnlistener_new(server->e->event_base,
server_input_handler, server,
LEV_OPT_CLOSE_ON_FREE | LEV_OPT_REUSEABLE,
1024, tls_listen_fd);
if(!(server->l)) {
TURN_LOG_FUNC(TURN_LOG_LEVEL_INFO,"Cannot create TLS listener\n");
socket_closesocket(tls_listen_fd);
return -1;
}
if(addr_get_from_sock(tls_listen_fd, &(server->addr))) {
perror("Cannot get local socket addr");
socket_closesocket(tls_listen_fd);
return -1;
}
if(!no_tcp && !no_tls)
addr_debug_print(server->verbose, &server->addr,"TCP/TLS listener opened on ");
else if(!no_tls)
addr_debug_print(server->verbose, &server->addr,"TLS listener opened on ");
else if(!no_tcp)
addr_debug_print(server->verbose, &server->addr,"TCP listener opened on ");
FUNCEND;
return 0;
}
/*
* Send the gossip to connected peers.
*/
void send_gossip()
{
int size = 256;
char *payload = (char *) malloc(size);
char *g;
int index = 0;
struct file_info *fi;
for(fi=file_info;fi!=NULL;fi=fi->next)
{
char *addr = addr_to_string(fi->addr);
printf("Checking %s type = %d outgoing status = %d\n", addr, fi->type,fi->u.fi_outgoing.status);
if(fi->type == FI_INCOMING || (fi->type == FI_OUTGOING && fi->status == FI_KNOWN && fi->u.fi_outgoing.status == FI_CONNECTED))
{
printf("Address extracted - %s\n", addr);
if(strlen(addr) + index > size)
{
size *= 2;
payload = realloc(payload, size);
}
if (index == 0) {
strcpy(payload, ";");
sprintf(payload, "%s%s", payload, addr);
}
else {
sprintf(payload, "%s;%s", payload, addr);
}
printf("Gossip Payload = %s\n", payload);
index += strlen(addr) + 1;
}
free(addr);
}
payload[index++] = '\n';
payload[index++] = '\0';
char *my_addr_str = (char *) addr_to_string(my_addr);
gossip_gen++;
g = (char *) malloc(sizeof(char)*(strlen(payload) + strlen(my_addr_str) + 4 + 4));
printf ("payload length = %d, my_addr length = %d\n", strlen(payload), strlen(my_addr_str));
memset(g, 0, strlen(payload) + strlen(my_addr_str) + 8);
sprintf(g, "G%s/%d/%s", my_addr_str, gossip_gen, payload);
printf("Gossip created - %s\n", g);
printf("DONE\n");
file_broadcast(g, strlen(g), NULL);
free(my_addr_str);
}
static int create_server_socket(dtls_listener_relay_server_type* server) {
FUNCSTART;
if(!server) return -1;
clean_server(server);
ioa_socket_raw udp_listen_fd = -1;
udp_listen_fd = socket(server->addr.ss.ss_family, SOCK_DGRAM, 0);
if (udp_listen_fd < 0) {
perror("socket");
return -1;
}
server->udp_listen_s = create_ioa_socket_from_fd(server->e, udp_listen_fd, NULL, UDP_SOCKET, LISTENER_SOCKET, NULL, &(server->addr));
server->udp_listen_s->listener_server = server;
set_sock_buf_size(udp_listen_fd,UR_SERVER_SOCK_BUF_SIZE);
if(sock_bind_to_device(udp_listen_fd, (unsigned char*)server->ifname)<0) {
TURN_LOG_FUNC(TURN_LOG_LEVEL_INFO,"Cannot bind listener socket to device %s\n",server->ifname);
}
if(addr_bind(udp_listen_fd,&server->addr)<0) {
perror("Cannot bind local socket to addr");
char saddr[129];
addr_to_string(&server->addr,(u08bits*)saddr);
TURN_LOG_FUNC(TURN_LOG_LEVEL_INFO,"Cannot bind UDP/DTLS listener socket to addr %s\n",saddr);
return -1;
}
server->udp_listen_ev = event_new(server->e->event_base,udp_listen_fd,
EV_READ|EV_PERSIST,udp_server_input_handler,server);
event_add(server->udp_listen_ev,NULL);
if(addr_get_from_sock(udp_listen_fd, &(server->addr))) {
perror("Cannot get local socket addr");
return -1;
}
if(!no_udp && !no_dtls)
addr_debug_print(server->verbose, &server->addr,"UDP/DTLS listener opened on ");
else if(!no_dtls)
addr_debug_print(server->verbose, &server->addr,"DTLS listener opened on ");
else if(!no_udp)
addr_debug_print(server->verbose, &server->addr,"UDP listener opened on ");
FUNCEND;
return 0;
}
int tcpopen(_addr *addr) {
int sockid;
if ((sockid = socket(struct_pf(addr), SOCK_STREAM, IPPROTO_TCP)) < 0)
throw PException("Could not create TCP socket");
if (connect(sockid, (sockaddr *)addr, struct_len(addr)) < 0) {
closesocket(sockid);
std::string txt = addr_to_string(addr, false);
throw PException(true, "Could not connect TCP socket to dst addr=%s", txt.c_str());
}
return sockid;
}
static void print_pcap_addrs(pcap_addr_t *addr) {
char addrbuf[1024];
for(; addr; addr = addr->next) {
if(addr->netmask)
printf(" %s/%d ",
addr_to_string(addr->addr, addrbuf, sizeof addrbuf),
netmask_to_string(addr->netmask));
else
printf(" %s ",
addr_to_string(addr->addr, addrbuf, sizeof addrbuf));
if(addr->broadaddr)
printf("brd %s",
addr_to_string(addr->broadaddr, addrbuf, sizeof addrbuf));
if(addr->dstaddr)
printf("dst %s",
addr_to_string(addr->dstaddr, addrbuf, sizeof addrbuf));
puts("");
}
}
static void hna_local_del(struct hna_local_entry *hna_local_entry,
char *message)
{
char hna_str[ETH_STR_LEN];
addr_to_string(hna_str, hna_local_entry->addr);
debug_log(LOG_TYPE_ROUTES, "Deleting local hna entry (%s): %s \n",
hna_str, message);
hash_remove(hna_local_hash, hna_local_entry->addr);
_hna_local_del(hna_local_entry);
}
int get_name_from_addr (struct qsockaddr *addr, char *name)
{
struct hostent *hostentry;
hostentry = gethostbyaddr ((char *)&((struct sockaddr_in *)addr)->sin_addr, sizeof(struct in_addr), AF_INET);
if (hostentry)
{
Q_strncpy (name, (char *)hostentry->h_name, NET_NAMELEN - 1);
return 0;
}
Q_strcpy (name, addr_to_string (addr));
return 0;
}
/* Broadcast to all connections except fi.
*/
void file_broadcast(char *buf, int size, struct file_info *fi){
printf("In send broadcast\n");
struct file_info *fi2;
for (fi2 = file_info; fi2 != 0; fi2 = fi2->next) {
char * fi2_addr = addr_to_string(fi2->addr);
//printf("Checking %s type = %d outgoing status = %d\n", fi2_addr, fi2->type, fi2->u.fi_outgoing.status);
if (fi2->type == FI_FREE || fi2 == fi) {
//printf("C1\n");
continue;
}
if (fi2->type == FI_OUTGOING && fi2->u.fi_outgoing.status == FI_CONNECTING) {
//printf("C2\n");
continue;
}
if (fi2->type == FI_OUTGOING || fi2->type == FI_INCOMING) {
//printf("Sending broadcast\n");
file_info_send(fi2, buf, size);
}
}
//printf("C3\n");
}
int datagram_recv(struct datagram *d, char *data, int length, char *addr, int *port, int timeout)
{
int result;
struct sockaddr_in iaddr;
SOCKLEN_T iaddr_length;
fd_set fds;
struct timeval tm;
while(1) {
tm.tv_sec = timeout / 1000000;
tm.tv_usec = timeout % 1000000;
FD_ZERO(&fds);
FD_SET(d->fd, &fds);
result = select(d->fd + 1, &fds, 0, 0, &tm);
if(result > 0) {
if(FD_ISSET(d->fd, &fds))
break;
} else if(result < 0 && errno_is_temporary(errno)) {
continue;
} else {
return -1;
}
}
iaddr_length = sizeof(iaddr);
result = recvfrom(d->fd, data, length, 0, (struct sockaddr *) &iaddr, &iaddr_length);
if(result < 0)
return result;
addr_to_string(&iaddr.sin_addr, addr);
*port = ntohs(iaddr.sin_port);
return result;
}
/*
* evaluate the RAF frame
*/
int ess_raf_received_pack(struct s_smc *smc, SMbuf *mb, struct smt_header *sm,
int fs)
{
void *p ; /* universal pointer */
struct smt_p_0016 *cmd ; /* para: command for the ESS */
SMbuf *db ;
u_long msg_res_type ; /* recource type */
u_long payload, overhead ;
int local ;
int i ;
/*
* Message Processing Code
*/
local = ((fs & L_INDICATOR) != 0) ;
/*
* get the resource type
*/
if (!(p = (void *) sm_to_para(smc,sm,SMT_P0015))) {
DB_ESS("ESS: RAF frame error, parameter type not found\n",0,0) ;
return fs;
}
msg_res_type = ((struct smt_p_0015 *)p)->res_type ;
/*
* get the pointer to the ESS command
*/
if (!(cmd = (struct smt_p_0016 *) sm_to_para(smc,sm,SMT_P0016))) {
/*
* error in frame: para ESS command was not found
*/
DB_ESS("ESS: RAF frame error, parameter command not found\n",0,0);
return fs;
}
DB_ESSN(2,"fc %x ft %x\n",sm->smt_class,sm->smt_type) ;
DB_ESSN(2,"ver %x tran %lx\n",sm->smt_version,sm->smt_tid) ;
DB_ESSN(2,"stn_id %s\n",addr_to_string(&sm->smt_source),0) ;
DB_ESSN(2,"infolen %x res %x\n",sm->smt_len, msg_res_type) ;
DB_ESSN(2,"sbacmd %x\n",cmd->sba_cmd,0) ;
/*
* evaluate the ESS command
*/
switch (cmd->sba_cmd) {
/*
* Process an ESS Allocation Request
*/
case REQUEST_ALLOCATION :
/*
* check for an RAF Request (Allocation Request)
*/
if (sm->smt_type == SMT_REQUEST) {
/*
* process the Allocation request only if the frame is
* local and no static allocation is used
*/
if (!local || smc->mib.fddiESSPayload)
return fs;
p = (void *) sm_to_para(smc,sm,SMT_P0019) ;
for (i = 0; i < 5; i++) {
if (((struct smt_p_0019 *)p)->alloc_addr.a[i]) {
return fs;
}
}
/*
* Note: The Application should send a LAN_LOC_FRAME.
* The ESS do not send the Frame to the network!
*/
smc->ess.alloc_trans_id = sm->smt_tid ;
DB_ESS("ESS: save Alloc Req Trans ID %lx\n",sm->smt_tid,0);
p = (void *) sm_to_para(smc,sm,SMT_P320F) ;
((struct smt_p_320f *)p)->mib_payload =
smc->mib.a[PATH0].fddiPATHSbaPayload ;
p = (void *) sm_to_para(smc,sm,SMT_P3210) ;
((struct smt_p_3210 *)p)->mib_overhead =
smc->mib.a[PATH0].fddiPATHSbaOverhead ;
sm->smt_dest = smt_sba_da ;
if (smc->ess.local_sba_active)
return fs | I_INDICATOR;
if (!(db = smt_get_mbuf(smc)))
return fs;
db->sm_len = mb->sm_len ;
db->sm_off = mb->sm_off ;
memcpy(((char *)(db->sm_data+db->sm_off)),(char *)sm,
(int)db->sm_len) ;
dump_smt(smc,
(struct smt_header *)(db->sm_data+db->sm_off),
"RAF") ;
smt_send_frame(smc,db,FC_SMT_INFO,0) ;
return fs;
}
/*
* The RAF frame is an Allocation Response !
* check the parameters
*/
if (smt_check_para(smc,sm,plist_raf_alc_res)) {
DB_ESS("ESS: RAF with para problem, ignoring\n",0,0) ;
return fs;
}
/*
* VERIFY THE FRAME IS WELL BUILT:
*
* 1. path index = primary ring only
* 2. resource type = sync bw only
* 3. trans action id = alloc_trans_id
* 4. reason code = success
*
* If any are violated, discard the RAF frame
*/
if ((((struct smt_p_320b *)sm_to_para(smc,sm,SMT_P320B))->path_index
!= PRIMARY_RING) ||
(msg_res_type != SYNC_BW) ||
(((struct smt_p_reason *)sm_to_para(smc,sm,SMT_P0012))->rdf_reason
!= SMT_RDF_SUCCESS) ||
(sm->smt_tid != smc->ess.alloc_trans_id)) {
DB_ESS("ESS: Allocation Response not accepted\n",0,0) ;
return fs;
}
/*
* Extract message parameters
*/
p = (void *) sm_to_para(smc,sm,SMT_P320F) ;
if (!p) {
printk(KERN_ERR "ESS: sm_to_para failed");
return fs;
}
payload = ((struct smt_p_320f *)p)->mib_payload ;
p = (void *) sm_to_para(smc,sm,SMT_P3210) ;
if (!p) {
printk(KERN_ERR "ESS: sm_to_para failed");
return fs;
}
overhead = ((struct smt_p_3210 *)p)->mib_overhead ;
DB_ESSN(2,"payload= %lx overhead= %lx\n",payload,overhead) ;
/*
* process the bandwidth allocation
*/
(void)process_bw_alloc(smc,(long)payload,(long)overhead) ;
return fs;
/* end of Process Allocation Request */
/*
* Process an ESS Change Request
*/
case CHANGE_ALLOCATION :
/*
* except only replies
*/
if (sm->smt_type != SMT_REQUEST) {
DB_ESS("ESS: Do not process Change Responses\n",0,0) ;
return fs;
}
/*
* check the para for the Change Request
*/
if (smt_check_para(smc,sm,plist_raf_chg_req)) {
DB_ESS("ESS: RAF with para problem, ignoring\n",0,0) ;
return fs;
}
/*
* Verify the path index and resource
* type are correct. If any of
* these are false, don't process this
* change request frame.
*/
if ((((struct smt_p_320b *)sm_to_para(smc,sm,SMT_P320B))->path_index
!= PRIMARY_RING) || (msg_res_type != SYNC_BW)) {
DB_ESS("ESS: RAF frame with para problem, ignoring\n",0,0) ;
return fs;
}
/*
* Extract message queue parameters
*/
p = (void *) sm_to_para(smc,sm,SMT_P320F) ;
payload = ((struct smt_p_320f *)p)->mib_payload ;
p = (void *) sm_to_para(smc,sm,SMT_P3210) ;
overhead = ((struct smt_p_3210 *)p)->mib_overhead ;
DB_ESSN(2,"ESS: Change Request from %s\n",
addr_to_string(&sm->smt_source),0) ;
DB_ESSN(2,"payload= %lx overhead= %lx\n",payload,overhead) ;
/*
* process the bandwidth allocation
*/
if(!process_bw_alloc(smc,(long)payload,(long)overhead))
return fs;
/*
* send an RAF Change Reply
*/
ess_send_response(smc,sm,CHANGE_ALLOCATION) ;
return fs;
/* end of Process Change Request */
/*
* Process Report Response
*/
case REPORT_ALLOCATION :
/*
* except only requests
*/
if (sm->smt_type != SMT_REQUEST) {
DB_ESS("ESS: Do not process a Report Reply\n",0,0) ;
return fs;
}
DB_ESSN(2,"ESS: Report Request from %s\n",
addr_to_string(&(sm->smt_source)),0) ;
/*
* verify that the resource type is sync bw only
*/
if (msg_res_type != SYNC_BW) {
DB_ESS("ESS: ignoring RAF with para problem\n",0,0) ;
return fs;
}
/*
* send an RAF Change Reply
*/
ess_send_response(smc,sm,REPORT_ALLOCATION) ;
return fs;
/* end of Process Report Request */
default:
/*
* error in frame
*/
DB_ESS("ESS: ignoring RAF with bad sba_cmd\n",0,0) ;
break ;
}
return fs;
}
void updateGraph()
{
if(dist) {
free(dist);
dist = NULL;
}
if(prev) {
free(prev);
prev = NULL;
}
if(graph) {
free(graph);
graph = NULL;
}
int r= 0, s=0;
dist = (int *) malloc(nl_nsites(nl) * sizeof(int));
prev = (int *) malloc(nl_nsites(nl) * sizeof(int));
graph = (int *) malloc(sizeof(int) * (nl_nsites(nl)) * (nl_nsites(nl)));
for(r=0;r<nl_nsites(nl);r++)
{
dist[r] = INFINITY;
prev[r] = UNDEFINED;
for(s=0;s<nl_nsites(nl);s++)
{
graph[INDEX(r, s, nl_nsites(nl))] = 0;
}
}
struct gossip *g = gossip;
while(g != NULL)
{
int len = strlen(gossip_latest(g));
char *lat = (char *) malloc(sizeof(char) * (len+1));
strcpy(lat, gossip_latest(g));
char *addr = lat;
char *ctr = index(addr, '/');
*ctr++ = 0;
char *payload = index(ctr, '/');
*payload++ = 0;
char *token = strtok(payload, ";");
while (token)
{
//printf("Address = %s\n", addr);
//printf("Token = %s\n", token);
set_dist(nl, graph, nl_nsites(nl), addr, token, 1);
token = strtok(NULL, ";");
}
g = gossip_next(g);
free(lat);
}
char *my_addr_str = addr_to_string(my_addr);
int my_index = nl_index(nl, my_addr_str);
// update connections of immediate neighbours
struct file_info *f = file_info;
while (f) {
char *addr = addr_to_string(f->addr);
if(strcmp(addr,my_addr_str ) != 0 && (f->type == FI_INCOMING || (f->type == FI_OUTGOING && f->status == FI_KNOWN && f->u.fi_outgoing.status == FI_CONNECTED)))
{
set_dist(nl, graph, nl_nsites(nl), addr, my_addr_str, 1);
}
f = f->next;
free(addr);
}
free(my_addr_str);
// call graph on updated graph
dijkstra(graph, nl_nsites(nl), my_index, dist, prev);
printf("PRINTING GRAPH\n");
for(r=0;r<nl_nsites(nl);r++)
{
for(s=0;s<nl_nsites(nl);s++)
{
printf("%d ", graph[INDEX(r, s, nl_nsites(nl))]);
}
printf("\n");
}
printf("\nPRINTING DISTANCE\n");
for(r=0;r<nl_nsites(nl);r++)
{
printf("Distance to Site [%d] %s = %d\n", r, nl_name(nl,r), dist[r]);
}
printf("\nPRINTING PREV\n");
for(r=0;r<nl_nsites(nl);r++)
{
printf("Previous to Site [%d] %s = %d\n", r, nl_name(nl,r), prev[r]);
}
}
void hna_local_add(uint8_t *addr)
{
struct hna_local_entry *hna_local_entry;
struct hna_global_entry *hna_global_entry;
struct hashtable_t *swaphash;
char hna_str[ETH_STR_LEN];
unsigned long flags;
spin_lock_irqsave(&hna_local_hash_lock, flags);
hna_local_entry =
((struct hna_local_entry *)hash_find(hna_local_hash, addr));
spin_unlock_irqrestore(&hna_local_hash_lock, flags);
if (hna_local_entry != NULL) {
hna_local_entry->last_seen = jiffies;
return;
}
addr_to_string(hna_str, addr);
/* only announce as many hosts as possible in the batman-packet and
space in batman_packet->num_hna That also should give a limit to
MAC-flooding. */
if ((num_hna + 1 > (ETH_DATA_LEN - BAT_PACKET_LEN) / ETH_ALEN) ||
(num_hna + 1 > 255)) {
debug_log(LOG_TYPE_ROUTES, "Can't add new local hna entry (%s): number of local hna entries exceeds packet size \n", hna_str);
return;
}
debug_log(LOG_TYPE_ROUTES, "Creating new local hna entry: %s \n",
hna_str);
hna_local_entry = kmalloc(sizeof(struct hna_local_entry), GFP_ATOMIC);
if (!hna_local_entry)
return;
memcpy(hna_local_entry->addr, addr, ETH_ALEN);
hna_local_entry->last_seen = jiffies;
/* the batman interface mac address should never be purged */
if (compare_orig(addr, soft_device->dev_addr))
hna_local_entry->never_purge = 1;
else
hna_local_entry->never_purge = 0;
spin_lock_irqsave(&hna_local_hash_lock, flags);
hash_add(hna_local_hash, hna_local_entry);
num_hna++;
atomic_set(&hna_local_changed, 1);
if (hna_local_hash->elements * 4 > hna_local_hash->size) {
swaphash = hash_resize(hna_local_hash,
hna_local_hash->size * 2);
if (swaphash == NULL)
debug_log(LOG_TYPE_CRIT, "Couldn't resize local hna hash table \n");
else
hna_local_hash = swaphash;
}
spin_unlock_irqrestore(&hna_local_hash_lock, flags);
/* remove address from global hash if present */
spin_lock_irqsave(&hna_global_hash_lock, flags);
hna_global_entry =
((struct hna_global_entry *)hash_find(hna_global_hash, addr));
if (hna_global_entry != NULL)
_hna_global_del_orig(hna_global_entry, "local hna received");
spin_unlock_irqrestore(&hna_global_hash_lock, flags);
}
void StunClient::processResponse(QByteArray resp, QString peer_addr)
{
u08bits rbuf[STUN_BUFFER_SIZE];
size_t rlen = 0;
stun_buffer buf;
QString mapped_addr;
u08bits addr_buff[STUN_BUFFER_SIZE] = {0};
rlen = resp.length();
memcpy(rbuf, resp.data(), resp.length());
buf.len = resp.length();
memcpy(buf.buf, resp.data(), resp.length());
if (!stun_is_command_message(&buf)) {
qDebug()<<resp.length()<<("The response is not a STUN message")<<peer_addr;
// should be a relayed raw UDP packet to peerA
emit packetReceived(resp, peer_addr);
return;
}
u16bits stun_method;
u16bits stun_msg_type;
stun_method = stun_get_method_str(buf.buf, buf.len);
stun_msg_type = stun_get_msg_type_str(buf.buf, buf.len);
qDebug()<<"method:"<<stun_method<<getMethodName(stun_method)<<",msg type:"<<stun_msg_type;
if (stun_method == STUN_METHOD_BINDING) {
} else {
this->debugStunResponse(resp);
}
// channel data
if (stun_is_indication(&buf)) {
u16bits chan_no;
size_t blen = 0;
qDebug()<<"indication data:"<<buf.len;
stun_attr_ref t_attr = stun_attr_get_first_by_type(&buf, STUN_ATTRIBUTE_DATA);
const u08bits *t_value = stun_attr_get_value(t_attr);
blen = stun_attr_get_len(t_attr);
QString xor_peer_addr = getStunAddress(resp, STUN_ATTRIBUTE_XOR_PEER_ADDRESS);
qDebug()<<"is chan msg:"<<stun_is_channel_message_str(t_value, &blen, &chan_no, 0);
qDebug()<<"chan no:"<<chan_no<<blen<<xor_peer_addr;
emit this->packetReceived(QByteArray((char*)t_value + 4, blen - 4), xor_peer_addr);
return;
}
if (!stun_is_response(&buf)) {
qDebug()<<resp.length()<<("The response is not a reponse message\n");
return;
}
if (!stun_is_success_response(&buf)) {
int err_code = 0;
u08bits err_msg[1025] = "\0";
size_t err_msg_size = sizeof(err_msg);
if (stun_is_error_response(&buf, &err_code, err_msg, err_msg_size)) {
printf("The response is an error %d (%s)\n", err_code, (char*) err_msg);
} else {
printf("The response is an unrecognized error\n");
}
// test unauth
u08bits realm[128] = {0};
u08bits nonce[256] = {0};
if (stun_is_challenge_response_str(buf.buf, buf.len, &err_code, err_msg, err_msg_size, realm, nonce)) {
qDebug()<<err_code;
qDebug()<<err_code<<(char*)err_msg<<(char*)realm<<(char*)nonce;
m_realm = QByteArray((char*)realm);
m_nonce = QByteArray((char*)nonce);
if (stun_method == STUN_METHOD_ALLOCATE) {
this->allocate((char*)realm, (char*)nonce);
}
if (stun_method == STUN_METHOD_CHANNEL_BIND) {
QThread::msleep(100);
this->channelBind(m_peer_addr);
}
}
if (err_code == 437) {
assert(err_code != 437); // allocate mismatch
}
if (err_code == 438) {
assert(err_code != 438); // stale nonce
}
if (err_code == 486) {
assert(err_code != 486); // allocate quota reached
}
return;
}
if (stun_is_binding_response(&buf)) {
ioa_addr reflexive_addr;
addr_set_any(&reflexive_addr);
if (stun_attr_get_first_addr(&buf, STUN_ATTRIBUTE_XOR_MAPPED_ADDRESS, &reflexive_addr, NULL) >= 0) {
stun_attr_ref sar = stun_attr_get_first_by_type_str(buf.buf, buf.len, STUN_ATTRIBUTE_OTHER_ADDRESS);
if (sar) {
// *rfc5780 = 1;
printf("\n========================================\n");
// printf("RFC 5780 response %d\n",++counter);
ioa_addr other_addr;
stun_attr_get_addr_str((u08bits *) buf.buf, (size_t) buf.len, sar, &other_addr, NULL);
sar = stun_attr_get_first_by_type_str(buf.buf, buf.len, STUN_ATTRIBUTE_RESPONSE_ORIGIN);
if (sar) {
ioa_addr response_origin;
stun_attr_get_addr_str((u08bits *) buf.buf, (size_t) buf.len, sar, &response_origin, NULL);
addr_debug_print(1, &response_origin, "Response origin: ");
}
addr_debug_print(1, &other_addr, "Other addr: ");
}
addr_debug_print(1, &reflexive_addr, "UDP reflexive addr");
addr_to_string(&reflexive_addr, addr_buff);
} else {
printf("Cannot read the response\n");
}
// emit got addr
if (strlen((char*)addr_buff) > 0) {
mapped_addr = QString((char*)addr_buff);
emit this->mappedAddressRecieved(mapped_addr);
}
return;
} // end bind resp
if (stun_method == STUN_METHOD_ALLOCATE) {
m_relayed_addr = this->getStunAddress(resp, STUN_ATTRIBUTE_XOR_RELAYED_ADDRESS);
this->saveAllocatePuples(m_realm, m_nonce);
emit this->allocateDone(m_relayed_addr);
if (!m_channel_refresh_timer) {
m_channel_refresh_timer = new QTimer();
QObject::connect(m_channel_refresh_timer, &QTimer::timeout, this, &StunClient::onRefreshTimeout);
}
if (!m_channel_refresh_timer->isActive()) {
m_channel_refresh_timer->start(m_channel_refresh_timeout);
}
}
if (stun_method == STUN_METHOD_CREATE_PERMISSION) {
if (!m_permission_keepalive_timer) {
emit this->createPermissionDone();
}
if (!m_permission_keepalive_timer) {
m_permission_keepalive_timer = new QTimer();
QObject::connect(m_permission_keepalive_timer, &QTimer::timeout, this, &StunClient::onPermKATimeout);
}
if (!m_permission_keepalive_timer->isActive()) {
m_permission_keepalive_timer->start(m_permission_keepalive_timeout);
}
}
if (stun_method == STUN_METHOD_CHANNEL_BIND) {
emit this->channelBindDone(m_relayed_addr);
}
if (stun_method == STUN_METHOD_REFRESH) {
qDebug()<<"refresh responsed.";
}
}
void hna_global_add_orig(struct orig_node *orig_node,
unsigned char *hna_buff, int hna_buff_len)
{
struct hna_global_entry *hna_global_entry;
struct hna_local_entry *hna_local_entry;
struct hashtable_t *swaphash;
char hna_str[ETH_STR_LEN], orig_str[ETH_STR_LEN];
int hna_buff_count = 0;
unsigned long flags;
unsigned char *hna_ptr;
addr_to_string(orig_str, orig_node->orig);
while ((hna_buff_count + 1) * ETH_ALEN <= hna_buff_len) {
spin_lock_irqsave(&hna_global_hash_lock, flags);
hna_ptr = hna_buff + (hna_buff_count * ETH_ALEN);
hna_global_entry = (struct hna_global_entry *)
hash_find(hna_global_hash, hna_ptr);
if (hna_global_entry == NULL) {
spin_unlock_irqrestore(&hna_global_hash_lock, flags);
hna_global_entry =
kmalloc(sizeof(struct hna_global_entry),
GFP_ATOMIC);
if (!hna_global_entry)
break;
memcpy(hna_global_entry->addr, hna_ptr, ETH_ALEN);
addr_to_string(hna_str, hna_global_entry->addr);
debug_log(LOG_TYPE_ROUTES, "Creating new global hna entry: %s (via %s)\n", hna_str, orig_str);
spin_lock_irqsave(&hna_global_hash_lock, flags);
hash_add(hna_global_hash, hna_global_entry);
}
hna_global_entry->orig_node = orig_node;
spin_unlock_irqrestore(&hna_global_hash_lock, flags);
/* remove address from local hash if present */
spin_lock_irqsave(&hna_local_hash_lock, flags);
hna_ptr = hna_buff + (hna_buff_count * ETH_ALEN);
hna_local_entry = (struct hna_local_entry *)
hash_find(hna_local_hash, hna_ptr);
if (hna_local_entry != NULL)
hna_local_del(hna_local_entry, "global hna received");
spin_unlock_irqrestore(&hna_local_hash_lock, flags);
hna_buff_count++;
}
orig_node->hna_buff_len = hna_buff_len;
if (orig_node->hna_buff_len > 0) {
orig_node->hna_buff = kmalloc(orig_node->hna_buff_len,
GFP_ATOMIC);
memcpy(orig_node->hna_buff, hna_buff, orig_node->hna_buff_len);
} else {
orig_node->hna_buff = NULL;
}
spin_lock_irqsave(&hna_global_hash_lock, flags);
if (hna_global_hash->elements * 4 > hna_global_hash->size) {
swaphash = hash_resize(hna_global_hash,
hna_global_hash->size * 2);
if (swaphash == NULL)
debug_log(LOG_TYPE_CRIT, "Couldn't resize global hna hash table \n");
else
hna_global_hash = swaphash;
}
spin_unlock_irqrestore(&hna_global_hash_lock, flags);
}
void StunClient::debugStunResponse(QByteArray resp)
{
u08bits rbuf[STUN_BUFFER_SIZE];
size_t rlen = 0;
stun_buffer buf;
u08bits addr_buff[STUN_BUFFER_SIZE] = {0};
rlen = resp.length();
memcpy(rbuf, resp.data(), resp.length());
buf.len = resp.length();
memcpy(buf.buf, resp.data(), resp.length());
if (!stun_is_command_message(&buf)) {
qDebug()<<resp.length()<<("The response is not a STUN message\n");
return;
}
if (!stun_is_response(&buf)) {
qDebug()<<resp.length()<<("The response is not a reponse message\n");
// return;
}
u16bits stun_method;
u16bits stun_msg_type;
stun_method = stun_get_method_str(buf.buf, buf.len);
stun_msg_type = stun_get_msg_type_str(buf.buf, buf.len);
qDebug()<<"method:"<<stun_method<<getMethodName(stun_method)<<",msg type:"<<stun_msg_type;
int attr_type;
const u08bits *attr_value;
int attr_len;
char relayed_addr_str[32] = {0};
char mapped_addr_str[32] = {0};
char addr_str[32] = {0};
ioa_addr relayed_addr;
ioa_addr mapped_addr;
ioa_addr stun_addr;
uint32_t lifetime = 0;
uint32_t bandwidth = 0;
stun_attr_ref raw_attr = stun_attr_get_first_str(buf.buf, buf.len);
for ( ; raw_attr ; raw_attr = stun_attr_get_next_str(buf.buf, buf.len, raw_attr)) {
attr_type = stun_attr_get_type(raw_attr);
attr_value = stun_attr_get_value(raw_attr);
attr_len = stun_attr_get_len(raw_attr);
switch (attr_type) {
case STUN_ATTRIBUTE_SOFTWARE:
qDebug()<<"attr software:"<<QByteArray((char*)attr_value, attr_len);
break;
case STUN_ATTRIBUTE_XOR_MAPPED_ADDRESS:
stun_attr_get_addr_str(buf.buf, buf.len, raw_attr, &mapped_addr, NULL);
addr_to_string(&mapped_addr, (u08bits*)mapped_addr_str);
qDebug()<<"mapped addr:"<<mapped_addr_str;
break;
case STUN_ATTRIBUTE_XOR_RELAYED_ADDRESS:
stun_attr_get_addr_str(buf.buf, buf.len, raw_attr, &relayed_addr, NULL);
addr_to_string(&relayed_addr, (u08bits*)relayed_addr_str);
qDebug()<<"relayed addr:"<<relayed_addr_str;
break;
case STUN_ATTRIBUTE_MESSAGE_INTEGRITY:
qDebug()<<"message integrity:"<<attr_len<<QByteArray((char*)attr_value, attr_len).toHex();
break;
case STUN_ATTRIBUTE_LIFETIME:
memcpy(&lifetime, attr_value, attr_len);
lifetime = nswap32(lifetime);
qDebug()<<"lifetime:"<<lifetime;
break;
case STUN_ATTRIBUTE_BANDWIDTH:
memcpy(&bandwidth, attr_value, attr_len);
bandwidth = nswap32(bandwidth);
qDebug()<<"bandwidth:"<<bandwidth;
break;
case STUN_ATTRIBUTE_XOR_PEER_ADDRESS:
stun_attr_get_addr_str(buf.buf, buf.len, raw_attr, &stun_addr, NULL);
addr_to_string(&stun_addr, (u08bits*)addr_str);
qDebug()<<"xor peer addr:"<<addr_str;
break;
case STUN_ATTRIBUTE_DATA:
qDebug()<<"attr data len:"<<attr_len<<QString(QByteArray((char*)attr_value + 4, attr_len - 4)).left(50)<<"...";
break;
default:
qDebug()<<"unkown attr:"<<attr_type<<attr_len;
break;
}
}
}
static int turn_create_permission(int verbose, app_ur_conn_info *clnet_info,
ioa_addr *peer_addr, int addrnum)
{
if(no_permissions || (addrnum<1))
return 0;
char saddr[129]="\0";
if (verbose) {
addr_to_string(peer_addr,(u08bits*)saddr);
}
stun_buffer request_message, response_message;
beg_cp:
{
int cp_sent = 0;
stun_init_request(STUN_METHOD_CREATE_PERMISSION, &request_message);
{
int addrindex;
for(addrindex=0;addrindex<addrnum;++addrindex) {
stun_attr_add_addr(&request_message, STUN_ATTRIBUTE_XOR_PEER_ADDRESS, peer_addr+addrindex);
}
}
add_origin(&request_message);
if(add_integrity(clnet_info, &request_message)<0) return -1;
stun_attr_add_fingerprint_str(request_message.buf,(size_t*)&(request_message.len));
while (!cp_sent) {
int len = send_buffer(clnet_info, &request_message, 0,0);
if (len > 0) {
if (verbose) {
TURN_LOG_FUNC(TURN_LOG_LEVEL_INFO, "create perm sent: %s\n",saddr);
}
cp_sent = 1;
} else {
perror("send");
exit(1);
}
}
}
////////////<<==create permission send
if(not_rare_event()) return 0;
////////create permission response==>>
{
int cp_received = 0;
while (!cp_received) {
int len = recv_buffer(clnet_info, &response_message, 1, 0, NULL, &request_message);
if (len > 0) {
if (verbose) {
TURN_LOG_FUNC(TURN_LOG_LEVEL_INFO,
"cp response received: \n");
}
int err_code = 0;
u08bits err_msg[129];
if (stun_is_success_response(&response_message)) {
cp_received = 1;
if(clnet_info->nonce[0]) {
if(check_integrity(clnet_info, &response_message)<0)
return -1;
}
if (verbose) {
TURN_LOG_FUNC(TURN_LOG_LEVEL_INFO, "success\n");
}
} else if (stun_is_challenge_response_str(response_message.buf, (size_t)response_message.len,
&err_code,err_msg,sizeof(err_msg),
clnet_info->realm,clnet_info->nonce,
clnet_info->server_name, &(clnet_info->oauth))) {
goto beg_cp;
} else if (stun_is_error_response(&response_message, &err_code,err_msg,sizeof(err_msg))) {
cp_received = 1;
TURN_LOG_FUNC(TURN_LOG_LEVEL_INFO, "create permission error %d (%s)\n",
err_code,(char*)err_msg);
return -1;
} else {
TURN_LOG_FUNC(TURN_LOG_LEVEL_INFO, "unknown create permission response\n");
/* Try again ? */
}
} else {
perror("recv");
exit(-1);
}
}
}
return 0;
}
int ess_raf_received_pack(struct s_smc *smc, SMbuf *mb, struct smt_header *sm,
int fs)
{
void *p ;
struct smt_p_0016 *cmd ;
SMbuf *db ;
u_long msg_res_type ;
u_long payload, overhead ;
int local ;
int i ;
local = ((fs & L_INDICATOR) != 0) ;
if (!(p = (void *) sm_to_para(smc,sm,SMT_P0015))) {
DB_ESS("ESS: RAF frame error, parameter type not found\n",0,0) ;
return fs;
}
msg_res_type = ((struct smt_p_0015 *)p)->res_type ;
if (!(cmd = (struct smt_p_0016 *) sm_to_para(smc,sm,SMT_P0016))) {
DB_ESS("ESS: RAF frame error, parameter command not found\n",0,0);
return fs;
}
DB_ESSN(2,"fc %x ft %x\n",sm->smt_class,sm->smt_type) ;
DB_ESSN(2,"ver %x tran %lx\n",sm->smt_version,sm->smt_tid) ;
DB_ESSN(2,"stn_id %s\n",addr_to_string(&sm->smt_source),0) ;
DB_ESSN(2,"infolen %x res %x\n",sm->smt_len, msg_res_type) ;
DB_ESSN(2,"sbacmd %x\n",cmd->sba_cmd,0) ;
switch (cmd->sba_cmd) {
case REQUEST_ALLOCATION :
if (sm->smt_type == SMT_REQUEST) {
if (!local || smc->mib.fddiESSPayload)
return fs;
p = (void *) sm_to_para(smc,sm,SMT_P0019) ;
for (i = 0; i < 5; i++) {
if (((struct smt_p_0019 *)p)->alloc_addr.a[i]) {
return fs;
}
}
smc->ess.alloc_trans_id = sm->smt_tid ;
DB_ESS("ESS: save Alloc Req Trans ID %lx\n",sm->smt_tid,0);
p = (void *) sm_to_para(smc,sm,SMT_P320F) ;
((struct smt_p_320f *)p)->mib_payload =
smc->mib.a[PATH0].fddiPATHSbaPayload ;
p = (void *) sm_to_para(smc,sm,SMT_P3210) ;
((struct smt_p_3210 *)p)->mib_overhead =
smc->mib.a[PATH0].fddiPATHSbaOverhead ;
sm->smt_dest = smt_sba_da ;
if (smc->ess.local_sba_active)
return fs | I_INDICATOR;
if (!(db = smt_get_mbuf(smc)))
return fs;
db->sm_len = mb->sm_len ;
db->sm_off = mb->sm_off ;
memcpy(((char *)(db->sm_data+db->sm_off)),(char *)sm,
(int)db->sm_len) ;
dump_smt(smc,
(struct smt_header *)(db->sm_data+db->sm_off),
"RAF") ;
smt_send_frame(smc,db,FC_SMT_INFO,0) ;
return fs;
}
if (smt_check_para(smc,sm,plist_raf_alc_res)) {
DB_ESS("ESS: RAF with para problem, ignoring\n",0,0) ;
return fs;
}
if ((((struct smt_p_320b *)sm_to_para(smc,sm,SMT_P320B))->path_index
!= PRIMARY_RING) ||
(msg_res_type != SYNC_BW) ||
(((struct smt_p_reason *)sm_to_para(smc,sm,SMT_P0012))->rdf_reason
!= SMT_RDF_SUCCESS) ||
(sm->smt_tid != smc->ess.alloc_trans_id)) {
DB_ESS("ESS: Allocation Response not accepted\n",0,0) ;
return fs;
}
p = (void *) sm_to_para(smc,sm,SMT_P320F) ;
if (!p) {
printk(KERN_ERR "ESS: sm_to_para failed");
return fs;
}
payload = ((struct smt_p_320f *)p)->mib_payload ;
p = (void *) sm_to_para(smc,sm,SMT_P3210) ;
if (!p) {
printk(KERN_ERR "ESS: sm_to_para failed");
return fs;
}
overhead = ((struct smt_p_3210 *)p)->mib_overhead ;
DB_ESSN(2,"payload= %lx overhead= %lx\n",payload,overhead) ;
(void)process_bw_alloc(smc,(long)payload,(long)overhead) ;
return fs;
case CHANGE_ALLOCATION :
if (sm->smt_type != SMT_REQUEST) {
DB_ESS("ESS: Do not process Change Responses\n",0,0) ;
return fs;
}
if (smt_check_para(smc,sm,plist_raf_chg_req)) {
DB_ESS("ESS: RAF with para problem, ignoring\n",0,0) ;
return fs;
}
if ((((struct smt_p_320b *)sm_to_para(smc,sm,SMT_P320B))->path_index
!= PRIMARY_RING) || (msg_res_type != SYNC_BW)) {
DB_ESS("ESS: RAF frame with para problem, ignoring\n",0,0) ;
return fs;
}
p = (void *) sm_to_para(smc,sm,SMT_P320F) ;
payload = ((struct smt_p_320f *)p)->mib_payload ;
p = (void *) sm_to_para(smc,sm,SMT_P3210) ;
overhead = ((struct smt_p_3210 *)p)->mib_overhead ;
DB_ESSN(2,"ESS: Change Request from %s\n",
addr_to_string(&sm->smt_source),0) ;
DB_ESSN(2,"payload= %lx overhead= %lx\n",payload,overhead) ;
if(!process_bw_alloc(smc,(long)payload,(long)overhead))
return fs;
ess_send_response(smc,sm,CHANGE_ALLOCATION) ;
return fs;
case REPORT_ALLOCATION :
if (sm->smt_type != SMT_REQUEST) {
DB_ESS("ESS: Do not process a Report Reply\n",0,0) ;
return fs;
}
DB_ESSN(2,"ESS: Report Request from %s\n",
addr_to_string(&(sm->smt_source)),0) ;
if (msg_res_type != SYNC_BW) {
DB_ESS("ESS: ignoring RAF with para problem\n",0,0) ;
return fs;
}
ess_send_response(smc,sm,REPORT_ALLOCATION) ;
return fs;
default:
DB_ESS("ESS: ignoring RAF with bad sba_cmd\n",0,0) ;
break ;
}
return fs;
}
glibtop_open_files_entry *
glibtop_get_proc_open_files_s (glibtop *server, glibtop_proc_open_files *buf, pid_t pid)
{
#if __FreeBSD_version > 800018 || (__FreeBSD_version < 800000 && __FreeBSD_version >= 700104)
struct kinfo_file *freep, *kif;
#ifndef HAVE_KINFO_GETFILE
int name[4];
size_t len;
#else
int cnt;
#endif
ssize_t i;
#else
char *output;
#endif
GArray *entries;
memset(buf, 0, sizeof (glibtop_proc_open_files));
#if __FreeBSD_version > 800018 || (__FreeBSD_version < 800000 && __FreeBSD_version >= 700104)
#ifndef HAVE_KINFO_GETFILE
name[0] = CTL_KERN;
name[1] = KERN_PROC;
name[2] = KERN_PROC_FILEDESC;
name[3] = pid;
if (sysctl(name, 4, NULL, &len, NULL, 0) < 0)
return NULL;
freep = kif = g_malloc(len);
if (sysctl(name, 4, kif, &len, NULL, 0) < 0) {
g_free(freep);
return NULL;
}
#else
freep = kinfo_getfile(pid, &cnt);
#endif
entries = g_array_new(FALSE, FALSE, sizeof(glibtop_open_files_entry));
#ifndef HAVE_KINFO_GETFILE
for (i = 0; i < len / sizeof(*kif); i++, kif++) {
glibtop_open_files_entry entry = {0};
if (kif->kf_structsize != sizeof(*kif))
continue;
#else
for (i = 0; i < cnt; i++) {
glibtop_open_files_entry entry = {0};
kif = &freep[i];
#endif
if (kif->kf_fd < 0)
continue;
if (kif->kf_type == KF_TYPE_SOCKET) {
if (kif->kf_sock_domain == AF_LOCAL) {
struct sockaddr_un *sun;
entry.type = GLIBTOP_FILE_TYPE_LOCALSOCKET;
sun = (struct sockaddr_un *)&kif->kf_sa_local;
if (sun->sun_path[0]) {
char *addrstr;
addrstr = addr_to_string(&kif->kf_sa_local);
g_strlcpy(entry.info.localsock.name,
addrstr,
sizeof(entry.info.localsock.name));
g_free(addrstr);
} else {
char *addrstr;
addrstr = addr_to_string(&kif->kf_sa_peer);
g_strlcpy(entry.info.localsock.name,
addrstr,
sizeof(entry.info.localsock.name));
g_free(addrstr);
}
} else if (kif->kf_sock_domain == AF_INET ||
kif->kf_sock_domain == AF_INET6) {
char *addrstr;
if (kif->kf_sock_domain == AF_INET)
entry.type = GLIBTOP_FILE_TYPE_INETSOCKET;
else
entry.type = GLIBTOP_FILE_TYPE_INET6SOCKET;
addrstr = addr_to_string(&kif->kf_sa_peer);
g_strlcpy(entry.info.sock.dest_host,
addrstr,
sizeof(entry.info.sock.dest_host));
g_free(addrstr);
entry.info.sock.dest_port = addr_to_port(&kif->kf_sa_peer);
}
} else if (kif->kf_type == KF_TYPE_PIPE) {
entry.type = GLIBTOP_FILE_TYPE_PIPE;
} else if (kif->kf_type == KF_TYPE_VNODE) {
entry.type = GLIBTOP_FILE_TYPE_FILE;
g_strlcpy(entry.info.file.name, kif->kf_path,
sizeof(entry.info.file.name));
} else
continue;
entry.fd = kif->kf_fd;
g_array_append_val(entries, entry);
}
g_free(freep);
#else
output = execute_lsof(pid);
if (output == NULL) return NULL;
entries = parse_output(output);
g_free(output);
#endif
buf->flags = _glibtop_sysdeps_proc_open_files;
buf->number = entries->len;
buf->size = sizeof(glibtop_open_files_entry);
buf->total = buf->number * buf->size;
return (glibtop_open_files_entry*)g_array_free(entries, FALSE);
}
static int create_server_socket(dtls_listener_relay_server_type* server, int report_creation) {
FUNCSTART;
if(!server) return -1;
clean_server(server);
{
ioa_socket_raw udp_listen_fd = -1;
udp_listen_fd = socket(server->addr.ss.sa_family, CLIENT_DGRAM_SOCKET_TYPE, CLIENT_DGRAM_SOCKET_PROTOCOL);
if (udp_listen_fd < 0) {
perror("socket");
return -1;
}
server->udp_listen_s = create_ioa_socket_from_fd(server->e, udp_listen_fd, NULL, UDP_SOCKET, LISTENER_SOCKET, NULL, &(server->addr));
set_sock_buf_size(udp_listen_fd,UR_SERVER_SOCK_BUF_SIZE);
if(sock_bind_to_device(udp_listen_fd, (unsigned char*)server->ifname)<0) {
TURN_LOG_FUNC(TURN_LOG_LEVEL_INFO,"Cannot bind listener socket to device %s\n",server->ifname);
}
set_raw_socket_ttl_options(udp_listen_fd, server->addr.ss.sa_family);
set_raw_socket_tos_options(udp_listen_fd, server->addr.ss.sa_family);
{
const int max_binding_time = 60;
int addr_bind_cycle = 0;
retry_addr_bind:
if(addr_bind(udp_listen_fd,&server->addr,1,1,UDP_SOCKET)<0) {
perror("Cannot bind local socket to addr");
char saddr[129];
addr_to_string(&server->addr,(u08bits*)saddr);
TURN_LOG_FUNC(TURN_LOG_LEVEL_WARNING,"Cannot bind DTLS/UDP listener socket to addr %s\n",saddr);
if(addr_bind_cycle++<max_binding_time) {
TURN_LOG_FUNC(TURN_LOG_LEVEL_INFO,"Trying to bind DTLS/UDP listener socket to addr %s, again...\n",saddr);
sleep(1);
goto retry_addr_bind;
}
TURN_LOG_FUNC(TURN_LOG_LEVEL_ERROR,"Fatal final failure: cannot bind DTLS/UDP listener socket to addr %s\n",saddr);
exit(-1);
}
}
server->udp_listen_ev = event_new(server->e->event_base,udp_listen_fd,
EV_READ|EV_PERSIST,udp_server_input_handler,
server);
event_add(server->udp_listen_ev,NULL);
}
if(report_creation) {
if(!turn_params.no_udp && !turn_params.no_dtls)
addr_debug_print(server->verbose, &server->addr,"DTLS/UDP listener opened on");
else if(!turn_params.no_dtls)
addr_debug_print(server->verbose, &server->addr,"DTLS listener opened on");
else if(!turn_params.no_udp)
addr_debug_print(server->verbose, &server->addr,"UDP listener opened on");
}
FUNCEND;
return 0;
}
static int create_new_connected_udp_socket(
dtls_listener_relay_server_type* server, ioa_socket_handle s)
{
evutil_socket_t udp_fd = socket(s->local_addr.ss.sa_family, CLIENT_DGRAM_SOCKET_TYPE, CLIENT_DGRAM_SOCKET_PROTOCOL);
if (udp_fd < 0) {
perror("socket");
TURN_LOG_FUNC(TURN_LOG_LEVEL_ERROR, "%s: Cannot allocate new socket\n",
__FUNCTION__);
return -1;
}
if (sock_bind_to_device(udp_fd, (unsigned char*) (s->e->relay_ifname))
< 0) {
TURN_LOG_FUNC(TURN_LOG_LEVEL_ERROR,
"Cannot bind udp server socket to device %s\n",
(char*) (s->e->relay_ifname));
}
ioa_socket_handle ret = (ioa_socket*) turn_malloc(sizeof(ioa_socket));
if (!ret) {
TURN_LOG_FUNC(TURN_LOG_LEVEL_ERROR,
"%s: Cannot allocate new socket structure\n", __FUNCTION__);
close(udp_fd);
return -1;
}
ns_bzero(ret, sizeof(ioa_socket));
ret->magic = SOCKET_MAGIC;
ret->fd = udp_fd;
ret->family = s->family;
ret->st = s->st;
ret->sat = CLIENT_SOCKET;
ret->local_addr_known = 1;
addr_cpy(&(ret->local_addr), &(s->local_addr));
if (addr_bind(udp_fd,&(s->local_addr),1,1,UDP_SOCKET) < 0) {
TURN_LOG_FUNC(TURN_LOG_LEVEL_ERROR,
"Cannot bind new detached udp server socket to local addr\n");
IOA_CLOSE_SOCKET(ret);
return -1;
}
ret->bound = 1;
{
int connect_err = 0;
if (addr_connect(udp_fd, &(server->sm.m.sm.nd.src_addr), &connect_err) < 0) {
char sl[129];
char sr[129];
addr_to_string(&(ret->local_addr),(u08bits*)sl);
addr_to_string(&(server->sm.m.sm.nd.src_addr),(u08bits*)sr);
TURN_LOG_FUNC(TURN_LOG_LEVEL_ERROR,
"Cannot connect new detached udp client socket from local addr %s to remote addr %s\n",sl,sr);
IOA_CLOSE_SOCKET(ret);
return -1;
}
}
ret->connected = 1;
addr_cpy(&(ret->remote_addr), &(server->sm.m.sm.nd.src_addr));
set_socket_options(ret);
ret->current_ttl = s->current_ttl;
ret->default_ttl = s->default_ttl;
ret->current_tos = s->current_tos;
ret->default_tos = s->default_tos;
#if DTLS_SUPPORTED
if (!turn_params.no_dtls
&& is_dtls_handshake_message(
ioa_network_buffer_data(server->sm.m.sm.nd.nbh),
(int) ioa_network_buffer_get_size(
server->sm.m.sm.nd.nbh))) {
SSL* connecting_ssl = NULL;
BIO *wbio = NULL;
struct timeval timeout;
/* Create BIO */
wbio = BIO_new_dgram(ret->fd, BIO_NOCLOSE);
(void) BIO_dgram_set_peer(wbio, (struct sockaddr*) &(server->sm.m.sm.nd.src_addr));
BIO_ctrl(wbio, BIO_CTRL_DGRAM_SET_CONNECTED, 0, &(server->sm.m.sm.nd.src_addr));
/* Set and activate timeouts */
timeout.tv_sec = DTLS_MAX_RECV_TIMEOUT;
timeout.tv_usec = 0;
BIO_ctrl(wbio, BIO_CTRL_DGRAM_SET_RECV_TIMEOUT, 0, &timeout);
#if DTLSv1_2_SUPPORTED
if(get_dtls_version(ioa_network_buffer_data(server->sm.m.sm.nd.nbh),
(int)ioa_network_buffer_get_size(server->sm.m.sm.nd.nbh)) == 1) {
connecting_ssl = SSL_NEW(server->dtls_ctx_v1_2);
} else {
connecting_ssl = SSL_NEW(server->dtls_ctx);
}
#else
{
connecting_ssl = SSL_NEW(server->dtls_ctx);
}
#endif
SSL_set_accept_state(connecting_ssl);
SSL_set_bio(connecting_ssl, NULL, wbio);
SSL_set_options(connecting_ssl, SSL_OP_COOKIE_EXCHANGE);
SSL_set_max_cert_list(connecting_ssl, 655350);
int rc = ssl_read(ret->fd, connecting_ssl, server->sm.m.sm.nd.nbh,
server->verbose);
if (rc < 0) {
if (!(SSL_get_shutdown(connecting_ssl) & SSL_SENT_SHUTDOWN)) {
SSL_set_shutdown(connecting_ssl, SSL_RECEIVED_SHUTDOWN);
SSL_shutdown(connecting_ssl);
}
SSL_FREE(connecting_ssl);
IOA_CLOSE_SOCKET(ret);
return -1;
}
addr_debug_print(server->verbose, &(server->sm.m.sm.nd.src_addr),
"Accepted DTLS connection from");
ret->ssl = connecting_ssl;
ioa_network_buffer_delete(server->e, server->sm.m.sm.nd.nbh);
server->sm.m.sm.nd.nbh = NULL;
ret->st = DTLS_SOCKET;
}
#endif
server->sm.m.sm.s = ret;
return server->connect_cb(server->e, &(server->sm));
}
/* Received a H(ello) message of the form H<addr>:<port>. This is the first message
* that's sent over a TCP connection (in both directions) so the peers can identify
* one another. The port is the server port of the endpoint rather than the
* connection's port.
*
* Sometimes accidentally peers try to connect to one another at the same time.
* This code kills one of the connections.
*/
void hello_received(struct file_info *fi, char *addr_port){
char *p = index(addr_port, ':');
if (p == 0) {
fprintf(stderr, "do_hello: format is H<addr>:<port>\n");
return;
}
*p++ = 0;
struct sockaddr_in addr;
if (addr_get(&addr, addr_port, atoi(p)) < 0) {
return;
}
*--p = ':';
printf("Got hello from %s:%d on socket %d\n", inet_ntoa(addr.sin_addr), ntohs(addr.sin_port), fi->fd);
/* If a connection breaks and is re-established, a duplicate hello message is likely
* to arrive, but we can ignore it as we already know the peer.
*/
if (fi->status == FI_KNOWN) {
fprintf(stderr, "Duplicate hello (ignoring)\n");
if (addr_cmp(addr, fi->addr) != 0) {
fprintf(stderr, "do_hello: address has changed???\n");
}
return;
}
/* It is possible to set up a connection to self. We deal with it by ignoring the
* Hello message but keeping the connection established.
*/
if (addr_cmp(addr, my_addr) == 0) {
fprintf(stderr, "Got hello from self??? (ignoring)\n");
return;
}
/* Search the connections to see if there is already a connection to this peer.
*/
struct file_info *fi2;
for (fi2 = file_info; fi2 != 0; fi2 = fi2->next) {
if (fi2->type == FI_FREE || fi2->status != FI_KNOWN) {
continue;
}
if (addr_cmp(fi2->addr, addr) != 0) {
continue;
}
/* Found another connection. We're going to keep just one. First see if
* this is actually an existing connection. It may have broken.
*/
if (fi2->fd == -1) {
printf("Found a defunct connection---dropping that one\n");
if (fi2->type == FI_OUTGOING) {
fi->type = FI_OUTGOING;
fi->u.fi_outgoing = fi2->u.fi_outgoing;
}
fi2->type = FI_FREE;
return;
}
/* Of the two, we keep the "lowest one". We identify a connection by the lowest
* endpoint address.
*/
struct sockaddr_in mine, other;
get_id(fi->fd, &mine);
get_id(fi2->fd, &other);
if (addr_cmp(mine, other) < 0) {
/* We keep mine.
*/
printf("duplicate connection -- keep mine\n");
if (fi2->type == FI_OUTGOING) {
fi->type = FI_OUTGOING;
fi->u.fi_outgoing = fi2->u.fi_outgoing;
}
close(fi2->fd);
fi2->type = FI_FREE;
}
else {
printf("duplicate connection -- keep other\n");
/* The other one wins.
*/
if (fi->type == FI_OUTGOING) {
fi2->type = FI_OUTGOING;
fi2->u.fi_outgoing = fi->u.fi_outgoing;
}
close(fi->fd);
fi->type = FI_FREE;
return;
}
}
/* No other connection. Keep this one.
*/
printf("New Connection\n");
fi->addr = addr;
fi->status = FI_KNOWN;
if(!nl)
{
nl = (struct node_list *) nl_create();
char *my_addr_str = addr_to_string(my_addr);
nl_add(nl, my_addr_str);
free(my_addr_str);
}
char *addr_str = addr_to_string(addr);
nl_add(nl, addr_str);
free(addr_str);
updateGraph();
send_gossip();
}
void send_handler(struct file_info *fi, char *msg)
{
printf ("SEND HANDLER CALLED\n");
if(isalpha(*msg))
{
printf("Incorrect send command\n");
return;
}
int len = strlen(msg);
char *ctr = index(msg, '/');
*ctr++ = 0;
char *payload = rindex(ctr, '/');
*payload++ = 0;
char *my_addr_str = addr_to_string(my_addr);
if(strcmp(msg, my_addr_str) == 0)
{
printf("%s\n", payload);
free(my_addr_str);
return;
}
else
{
int ttl = atoi(ctr);
if(ttl == 0)
{
//free(msg);
free(my_addr_str);
return;
}
int dest_index = nl_index(nl, msg);
if (dest_index == -1) {
//free(msg);
free(my_addr_str);
return;
}
int my_index = nl_index(nl, my_addr_str);
while (prev[dest_index] != my_index) {
dest_index = prev[dest_index];
//Node disconnected
if(dest_index == -1)
{
free(my_addr_str);
return;
}
}
// send to the dest_index
char *dest_addr = nl_name(nl, dest_index);
ttl--;
char *str = (char *) malloc(len);
sprintf(str, "S%s/%d/%s\n",msg, ttl, payload);
struct file_info *f = file_info;
while(f)
{
char *f_addr_str = addr_to_string(f->addr);
if(strcmp(dest_addr, f_addr_str) == 0 &&
(f->type == FI_INCOMING || (f->type == FI_OUTGOING && f->status == FI_KNOWN
&& f->u.fi_outgoing.status == FI_CONNECTED)))
break;
f = f->next;
//free(f_addr_str);
//free(myaddr);
}
if (f) {
printf("%s\n", addr_to_string(f->addr));
file_info_send(f, str, strlen(str));
}
else
printf("f not found\n");
}
free(my_addr_str);
}
static int reopen_server_socket(dtls_listener_relay_server_type* server)
{
if(!server)
return 0;
FUNCSTART;
EVENT_DEL(server->udp_listen_ev);
if(server->udp_listen_s->fd>=0) {
socket_closesocket(server->udp_listen_s->fd);
server->udp_listen_s->fd = -1;
}
if (!(server->udp_listen_s)) {
return create_server_socket(server);
}
ioa_socket_raw udp_listen_fd = socket(server->addr.ss.ss_family, SOCK_DGRAM, 0);
if (udp_listen_fd < 0) {
perror("socket");
FUNCEND;
return -1;
}
server->udp_listen_s->fd = udp_listen_fd;
/* some UDP sessions may fail due to the race condition here */
set_socket_options(server->udp_listen_s);
set_sock_buf_size(udp_listen_fd, UR_SERVER_SOCK_BUF_SIZE);
if (sock_bind_to_device(udp_listen_fd, (unsigned char*) server->ifname) < 0) {
TURN_LOG_FUNC(TURN_LOG_LEVEL_INFO,
"Cannot bind listener socket to device %s\n",
server->ifname);
}
if(addr_bind(udp_listen_fd,&server->addr)<0) {
perror("Cannot bind local socket to addr");
char saddr[129];
addr_to_string(&server->addr,(u08bits*)saddr);
TURN_LOG_FUNC(TURN_LOG_LEVEL_INFO,"Cannot bind listener socket to addr %s\n",saddr);
return -1;
}
server->udp_listen_ev = event_new(server->e->event_base, udp_listen_fd,
EV_READ | EV_PERSIST, udp_server_input_handler, server);
event_add(server->udp_listen_ev, NULL );
if (!no_udp && !no_dtls)
addr_debug_print(server->verbose, &server->addr,
"UDP/DTLS listener opened on ");
else if (!no_dtls)
addr_debug_print(server->verbose, &server->addr,
"DTLS listener opened on ");
else if (!no_udp)
addr_debug_print(server->verbose, &server->addr,
"UDP listener opened on ");
FUNCEND;
return 0;
}
static char *reds_stream_get_remote_address(RedsStream *stream)
{
return addr_to_string("%s;%s", &stream->priv->info->paddr_ext,
stream->priv->info->plen_ext);
}
/* Activity on a socket: input, output, or error...
*/
static void message_handler(struct file_info *fi, int events){
printf("Message handler called\n");
char buf[512];
if (events & (POLLERR | POLLHUP)) {
double time;
int error;
socklen_t len = sizeof(error);
if (getsockopt(fi->fd, SOL_SOCKET, SO_ERROR, &error, &len) < 0) {
perror("getsockopt");
}
switch (error) {
case 0:
printf("Lost connection on socket %d\n", fi->fd);
time = timer_now() + 1;
break;
default:
printf("Error '%s' on socket %d\n", strerror(error), fi->fd);
time = timer_now() + 5;
}
close(fi->fd);
/* Start a timer to reconnect.
*/
if (fi->type == FI_OUTGOING) {
timer_start(time, timer_reconnect, fi->uid);
fi->fd = -1;
fi->u.fi_outgoing.status = FI_CONNECTING;
}
else {
fi->type = FI_FREE;
}
char *my_addr_str = addr_to_string(my_addr);
char *fi_addr_str = addr_to_string(fi->addr);
set_dist(nl, graph, nl_nsites(nl), fi_addr_str, my_addr_str, 0);
updateGraph();
send_gossip();
free (my_addr_str);
free (fi_addr_str);
return;
}
if (events & POLLOUT) {
int n = send(fi->fd, fi->output_buffer, fi->amount_to_send, 0);
if (n < 0) {
perror("send");
}
if (n > 0) {
if (n == fi->amount_to_send) {
fi->amount_to_send = 0;
}
else {
memmove(&fi->output_buffer[n], fi->output_buffer, fi->amount_to_send - n);
fi->amount_to_send -= n;
}
}
}
if (events & POLLIN) {
add_input(fi);
}
if (events & ~(POLLIN|POLLOUT|POLLERR|POLLHUP)) {
printf("message_handler: unknown events\n");
fi->events = 0;
}
}
static RList *r_debug_desc_native_list (int pid) {
// TODO: windows
#if __APPLE__
return xnu_desc_list (pid);
#elif __WINDOWS__
return win_desc_list(pid);
#elif __KFBSD__
RList *ret = NULL;
int perm, type, mib[4];
size_t len;
char *buf, *bp, *eb, *str, path[1024];
RDebugDesc *desc;
struct kinfo_file *kve;
len = 0;
mib[0] = CTL_KERN;
mib[1] = KERN_PROC;
mib[2] = KERN_PROC_FILEDESC;
mib[3] = pid;
if (sysctl (mib, 4, NULL, &len, NULL, 0) != 0) return NULL;
len = len * 4 / 3;
buf = malloc(len);
if (buf == NULL) return (NULL);
if (sysctl (mib, 4, buf, &len, NULL, 0) != 0) {
free (buf);
return NULL;
}
bp = buf;
eb = buf + len;
ret = r_list_new ();
if (!ret) {
free (buf);
return NULL;
}
ret->free = (RListFree) r_debug_desc_free;
while (bp < eb) {
kve = (struct kinfo_file *)(uintptr_t)bp;
bp += kve->kf_structsize;
if (kve->kf_fd < 0) continue; // Skip root and cwd. We need it ??
str = kve->kf_path;
switch (kve->kf_type) {
case KF_TYPE_VNODE: type = 'v'; break;
case KF_TYPE_SOCKET:
type = 's';
if (kve->kf_sock_domain == AF_LOCAL) {
struct sockaddr_un *sun =
(struct sockaddr_un *)&kve->kf_sa_local;
if (sun->sun_path[0] != 0)
addr_to_string (&kve->kf_sa_local, path, sizeof(path));
else
addr_to_string (&kve->kf_sa_peer, path, sizeof(path));
} else {
addr_to_string (&kve->kf_sa_local, path, sizeof(path));
strcat (path, " ");
addr_to_string (&kve->kf_sa_peer, path + strlen (path),
sizeof (path));
}
str = path;
break;
case KF_TYPE_PIPE: type = 'p'; break;
case KF_TYPE_FIFO: type = 'f'; break;
case KF_TYPE_KQUEUE: type = 'k'; break;
case KF_TYPE_CRYPTO: type = 'c'; break;
case KF_TYPE_MQUEUE: type = 'm'; break;
case KF_TYPE_SHM: type = 'h'; break;
case KF_TYPE_PTS: type = 't'; break;
case KF_TYPE_SEM: type = 'e'; break;
case KF_TYPE_NONE:
case KF_TYPE_UNKNOWN:
default: type = '-'; break;
}
perm = (kve->kf_flags & KF_FLAG_READ)?R_IO_READ:0;
perm |= (kve->kf_flags & KF_FLAG_WRITE)?R_IO_WRITE:0;
desc = r_debug_desc_new (kve->kf_fd, str, perm, type,
kve->kf_offset);
if (desc == NULL) break;
r_list_append (ret, desc);
}
free (buf);
return ret;
#elif __linux__
return linux_desc_list (pid);
#else
#warning list filedescriptors not supported for this platform
return NULL;
#endif
}
static int handle_udp_packet(dtls_listener_relay_server_type *server,
struct message_to_relay *sm,
ioa_engine_handle ioa_eng, turn_turnserver *ts)
{
int verbose = ioa_eng->verbose;
ioa_socket_handle s = sm->m.sm.s;
ur_addr_map_value_type mvt = 0;
ur_addr_map *amap = server->children_ss;
ioa_socket_handle chs = NULL;
if ((ur_addr_map_get(amap, &(sm->m.sm.nd.src_addr), &mvt) > 0) && mvt) {
chs = (ioa_socket_handle) mvt;
}
if (chs && !ioa_socket_tobeclosed(chs)
&& (chs->sockets_container == amap)
&& (chs->magic == SOCKET_MAGIC)) {
s = chs;
sm->m.sm.s = s;
if(s->ssl) {
int read_len = (int)ioa_network_buffer_get_size(sm->m.sm.nd.nbh);
int sslret = ssl_read(s->fd, s->ssl, (s08bits*)ioa_network_buffer_data(sm->m.sm.nd.nbh),
(int)ioa_network_buffer_get_capacity(),
verbose, &read_len);
if(sslret < 0) {
ioa_network_buffer_delete(ioa_eng, sm->m.sm.nd.nbh);
sm->m.sm.nd.nbh = NULL;
ts_ur_super_session *ss = (ts_ur_super_session *) s->session;
if (ss) {
turn_turnserver *server = (turn_turnserver *) ss->server;
if (server) {
shutdown_client_connection(server, ss);
}
} else {
close_ioa_socket(s);
}
ur_addr_map_del(amap, &(sm->m.sm.nd.src_addr), NULL);
sm->m.sm.s = NULL;
s = NULL;
chs = NULL;
} else if(read_len>0) {
ioa_network_buffer_set_size(sm->m.sm.nd.nbh,(size_t)read_len);
} else {
ioa_network_buffer_delete(ioa_eng, sm->m.sm.nd.nbh);
sm->m.sm.nd.nbh = NULL;
}
}
if (s && s->read_cb && sm->m.sm.nd.nbh) {
s->e = ioa_eng;
s->read_cb(s, IOA_EV_READ, &(sm->m.sm.nd), s->read_ctx);
ioa_network_buffer_delete(ioa_eng, sm->m.sm.nd.nbh);
sm->m.sm.nd.nbh = NULL;
if (ioa_socket_tobeclosed(s)) {
ts_ur_super_session *ss = (ts_ur_super_session *) s->session;
if (ss) {
turn_turnserver *server = (turn_turnserver *) ss->server;
if (server) {
shutdown_client_connection(server, ss);
}
}
}
}
} else {
if (chs && ioa_socket_tobeclosed(chs)) {
TURN_LOG_FUNC(TURN_LOG_LEVEL_ERROR,
"%s: socket to be closed\n", __FUNCTION__);
{
u08bits saddr[129];
u08bits rsaddr[129];
long thrid = 0;
#if !defined(TURN_NO_THREADS)
thrid = (long) pthread_self();
#endif
addr_to_string(get_local_addr_from_ioa_socket(chs),saddr);
addr_to_string(get_remote_addr_from_ioa_socket(chs),rsaddr);
TURN_LOG_FUNC(TURN_LOG_LEVEL_INFO,
"%s: thrid=0x%lx: Amap = 0x%lx, socket container=0x%lx, local addr %s, remote addr %s, s=0x%lx, done=%d, tbc=%d\n",
__FUNCTION__, thrid, (long) amap,
(long) (chs->sockets_container), (char*) saddr,
(char*) rsaddr, (long) s, (int) (chs->done),
(int) (chs->tobeclosed));
}
}
if (chs && (chs->magic != SOCKET_MAGIC)) {
TURN_LOG_FUNC(TURN_LOG_LEVEL_ERROR,
"%s: wrong socket magic\n", __FUNCTION__);
}
if (chs && (chs->sockets_container != amap)) {
TURN_LOG_FUNC(TURN_LOG_LEVEL_ERROR,
"%s: wrong socket container\n", __FUNCTION__);
{
u08bits saddr[129];
u08bits rsaddr[129];
long thrid = 0;
#if !defined(TURN_NO_THREADS)
thrid = (long) pthread_self();
#endif
addr_to_string(get_local_addr_from_ioa_socket(chs),saddr);
addr_to_string(get_remote_addr_from_ioa_socket(chs),rsaddr);
TURN_LOG_FUNC(TURN_LOG_LEVEL_INFO,
"%s: thrid=0x%lx: Amap = 0x%lx, socket container=0x%lx, local addr %s, remote addr %s, s=0x%lx, done=%d, tbc=%d, st=%d, sat=%d\n",
__FUNCTION__, thrid, (long) amap,
(long) (chs->sockets_container), (char*) saddr,
(char*) rsaddr, (long) chs, (int) (chs->done),
(int) (chs->tobeclosed), (int) (chs->st),
(int) (chs->sat));
}
}
chs = NULL;
#if !defined(TURN_NO_DTLS)
if (!no_dtls &&
is_dtls_handshake_message(ioa_network_buffer_data(sm->m.sm.nd.nbh),
(int)ioa_network_buffer_get_size(sm->m.sm.nd.nbh))) {
chs = dtls_server_input_handler(server,
ioa_network_buffer_data(sm->m.sm.nd.nbh),
(int)ioa_network_buffer_get_size(sm->m.sm.nd.nbh));
ioa_network_buffer_delete(server->e, sm->m.sm.nd.nbh);
sm->m.sm.nd.nbh = NULL;
}
#endif
if(!chs) {
chs = create_ioa_socket_from_fd(ioa_eng, s->fd, s,
UDP_SOCKET, CLIENT_SOCKET, &(sm->m.sm.nd.src_addr),
get_local_addr_from_ioa_socket(s));
}
s = chs;
sm->m.sm.s = s;
if (s) {
if(verbose) {
u08bits saddr[129];
u08bits rsaddr[129];
addr_to_string(get_local_addr_from_ioa_socket(s),saddr);
addr_to_string(get_remote_addr_from_ioa_socket(s),rsaddr);
TURN_LOG_FUNC(TURN_LOG_LEVEL_INFO,
"%s: New UDP endpoint: local addr %s, remote addr %s\n",
__FUNCTION__, (char*) saddr,(char*) rsaddr);
}
s->e = ioa_eng;
add_socket_to_map(s, amap);
open_client_connection_session(ts, &(sm->m.sm));
}
}
return 0;
}
