static void frag_fu_a(uint8_t *nal, int fragsize, int mtu,
Track *tr)
{
int start = 1, fraglen;
uint8_t fu_header, buf[mtu];
fnc_log(FNC_LOG_VERBOSE, "[h264] frags");
// p = data + index;
buf[0] = (nal[0] & 0xe0) | 28; // fu_indicator
fu_header = nal[0] & 0x1f;
nal++;
fragsize--;
while(fragsize>0) {
buf[1] = fu_header;
if (start) {
start = 0;
buf[1] = fu_header | (1<<7);
}
fraglen = MIN(mtu-2, fragsize);
if (fraglen == fragsize) {
buf[1] = fu_header | (1<<6);
}
memcpy(buf + 2, nal, fraglen);
fnc_log(FNC_LOG_VERBOSE, "[h264] Frag %d %d",buf[0], buf[1]);
mparser_buffer_write(tr,
tr->properties.pts,
tr->properties.dts,
tr->properties.frame_duration,
(fragsize<=fraglen),
buf, fraglen + 2);
fragsize -= fraglen;
nal += fraglen;
}
}
gint
unix_sock_bind(const gchar *host, gint port, L4_Proto l4)
{
struct sockaddr_in sin;
gint sock, err;
sock = socket(AF_INET, l4 == L4_TCP ? SOCK_STREAM : SOCK_DGRAM, 0);
if (sock < 0)
{
err = -errno;
fnc_log(FNC_LOG_ERR, "[FC] Create socket failed.");
return err;
}
memset(&sin, 0, sizeof(sin));
sin.sin_family = AF_INET;
sin.sin_port = htons(port);
sin.sin_addr.s_addr = host ? inet_addr(host) : INADDR_ANY;
if (bind(sock, (struct sockaddr*)&sin, sizeof(sin)))
{
err = -errno;
fnc_log(FNC_LOG_ERR, "[FC] Bind socket failed on port '%d'.", port);
close(sock);
return err;
}
return sock;
}
tsocket tcp_connect(unsigned short port, char *addr)
{
tsocket f;
int on=1;
int one = 1;/*used to set SO_KEEPALIVE*/
struct sockaddr_in s;
int v = 1;
if ((f = socket(AF_INET, SOCK_STREAM, IPPROTO_TCP))<0) {
fnc_log(FNC_LOG_ERR,"socket() error in tcp_connect.\n" );
return ERR_GENERIC;
}
setsockopt(f, SOL_SOCKET, SO_REUSEADDR, (char *) &v, sizeof(int));
s.sin_family = AF_INET;
s.sin_addr.s_addr = inet_addr(addr);//htonl(addr);
s.sin_port = htons(port);
// set to non-blocking
if (ioctl(f, FIONBIO, &on) < 0) {
fnc_log(FNC_LOG_ERR,"ioctl() error in tcp_connect.\n" );
return ERR_GENERIC;
}
if (connect(f,(struct sockaddr*)&s, sizeof(s)) < 0) {
fnc_log(FNC_LOG_ERR,"connect() error in tcp_connect.\n" );
return ERR_GENERIC;
}
if(setsockopt(f, SOL_SOCKET, SO_KEEPALIVE, &one, sizeof(one))<0){
fnc_log(FNC_LOG_ERR,"setsockopt() SO_KEEPALIVE error in tcp_connect.\n" );
return ERR_GENERIC;
}
return f;
}
static int simple_parse(Track *tr, uint8_t *data, size_t len)
{
int32_t offset = 0, rem = len;
if (DEFAULT_MTU >= len) {
mparser_buffer_write(tr,
tr->properties.pts,
tr->properties.dts,
tr->properties.frame_duration,
1,
data, len);
fnc_log(FNC_LOG_VERBOSE, "[simple] no frags");
} else {
do {
offset = len - rem;
mparser_buffer_write(tr,
tr->properties.pts,
tr->properties.dts,
tr->properties.frame_duration,
(rem <= DEFAULT_MTU),
data + offset, MIN(rem, DEFAULT_MTU));
rem -= DEFAULT_MTU;
fnc_log(FNC_LOG_VERBOSE, "[simple] frags");
} while (rem >= 0);
}
fnc_log(FNC_LOG_VERBOSE, "[simple] Frame completed");
return ERR_NOERROR;
}
int udp_open(unsigned short port,struct sockaddr *s_addr, tsocket *fd)
{
struct sockaddr_in s;
int on = 1; //,v=1;
if (!*fd) {
if ((*fd = socket(AF_INET, SOCK_DGRAM, 0)) < 0) {
fnc_log(FNC_LOG_ERR,"socket() error in udp_open.\n" );
return ERR_GENERIC;
}
// set to non-blocking
if (ioctl(*fd, FIONBIO, &on) < 0) {
fnc_log(FNC_LOG_ERR,"ioctl() error in udp_open.\n" );
return ERR_GENERIC;
}
}
s.sin_family = AF_INET;
s.sin_addr.s_addr = htonl(INADDR_ANY);
s.sin_port = htons(port);
if (bind (*fd, (struct sockaddr *)&s, sizeof (s))) {
fnc_log(FNC_LOG_ERR,"bind() error in udp_open.\n" );
return ERR_GENERIC;
}
*s_addr=*((struct sockaddr*)&s);
return ERR_NOERROR;
}
/**
* Drop privileges to the configured user
*
* This function takes care of changing the running group and user to
* those defined in @ref feng_srv::groupname and @ref
* feng_srv::username, defaulting to feng:feng.
*
* We do not drop privileges if we're running as non-root, as in that
* case we assume we have been given already only the limited set of
* privileges we need.
*/
static void feng_drop_privs()
{
const char *const wanted_group = feng_srv.groupname;
const char *const wanted_user = feng_srv.username;
if ( getuid() != 0 ) /* only if root */
return;
errno = 0;
if ( wanted_group != NULL ) {
struct group *gr = getgrnam(wanted_group);
if ( errno != 0 )
fnc_perror("getgrnam");
else if ( gr == NULL )
fnc_log(FNC_LOG_ERR, "%s: group %s not found", __func__, wanted_group);
else if ( setgid(gr->gr_gid) < 0 )
fnc_perror("setgid");
}
errno = 0;
if ( wanted_user != NULL ) {
struct passwd *pw = getpwnam(wanted_user);
if ( errno != 0 )
fnc_perror("getpwnam");
else if ( pw == NULL )
fnc_log(FNC_LOG_ERR, "%s: user %s not found", __func__, wanted_user);
else if ( setuid(pw->pw_uid) < 0 )
fnc_perror("setuid");
}
}
gint
set_fd_flags(gint fd, gint flgs)
{
gint old_flgs, err;
old_flgs = fcntl(fd, F_GETFL, 0);
if (G_UNLIKELY(old_flgs < 0))
{
err = -errno;
fnc_log(FNC_LOG_ERR,
"set_fd_flags()->fcntl(fd, F_GETFL, 0)"
);
return err;
}
old_flgs |= flgs;
if (fcntl(fd, F_SETFL, old_flgs) < 0)
{
err = -errno;
fnc_log(FNC_LOG_ERR,
"set_fd_flags()->fcntl(fd, F_SETFL, 0)"
);
return err;
}
return 0;
}
/**
* @brief Read data from a resource (unlocked)
*
* @param resouce The resource to read from
*
* @return The same return value as read_packet
*/
int r_read(Resource *resource)
{
int ret = RESOURCE_EOF;
g_mutex_lock(resource->lock);
if (!resource->eor)
switch( (ret = resource->demuxer->read_packet(resource)) ) {
case RESOURCE_OK:
break;
case RESOURCE_EOF:
fnc_log(FNC_LOG_INFO,
"r_read_unlocked: %s read_packet() end of file.",
resource->info->mrl);
resource->eor = true;
break;
default:
fnc_log(FNC_LOG_FATAL,
"r_read_unlocked: %s read_packet() error.",
resource->info->mrl);
break;
}
g_mutex_unlock(resource->lock);
return ret;
}
static char *encode_avc1_header(uint8_t *p, unsigned int len, int packet_mode)
{
int i, cnt, nalsize;
uint8_t *q = p;
char *sprop = NULL;
cnt = *(p+5) & 0x1f; // Number of sps
p += 6;
for (i = 0; i < cnt; i++) {
if (p > q + len)
goto err_alloc;
nalsize = RB16(p); //buf_size
p += 2;
fnc_log(FNC_LOG_VERBOSE, "[h264] nalsize %d", nalsize);
if (i == 0) {
gchar *out = g_strdup_printf("profile-level-id=%02x%02x%02x; "
"packetization-mode=%d; ",
p[0], p[1], p[2], packet_mode);
gchar *buf = g_base64_encode(p, nalsize);
sprop = g_strdup_printf("%ssprop-parameter-sets=%s", out, buf);
g_free(buf);
g_free(out);
} else {
gchar *buf = g_base64_encode(p, nalsize);
gchar *out = g_strdup_printf("%s,%s", sprop, buf);
g_free(sprop);
g_free(buf);
sprop = out;
}
p += nalsize;
}
// Decode pps from avcC
cnt = *(p++); // Number of pps
fnc_log(FNC_LOG_VERBOSE, "[h264] pps %d", cnt);
for (i = 0; i < cnt; i++) {
gchar *out, *buf;
if (p > q + len)
goto err_alloc;
nalsize = RB16(p);
p += 2;
fnc_log(FNC_LOG_VERBOSE, "[h264] nalsize %d", nalsize);
buf = g_base64_encode(p, nalsize);
out = g_strdup_printf("%s,%s",sprop, buf);
g_free(sprop);
g_free(buf);
sprop = out;
p += nalsize;
}
return sprop;
err_alloc:
if (sprop) g_free(sprop);
return NULL;
}
static void check_if_any_rtp_session_timedout(gpointer element,
gpointer user_data)
{
RTP_session *session = (RTP_session *)element;
time_t *last_packet_send_time = (time_t *)user_data;
time_t now = time(NULL);
/* Jmkn: get the last packet send time in all the session*/
if( last_packet_send_time != NULL &&
(session->last_packet_send_time > *last_packet_send_time)){
*last_packet_send_time = session->last_packet_send_time;
}
#if 0
/* Check if we didn't send any data for more then STREAM_BYE_TIMEOUT seconds
* this will happen if we are not receiving any more from live producer or
* if the stored stream ended.
*/
if ((session->track->properties.media_source == MS_live) &&
(now - session->last_packet_send_time) >= LIVE_STREAM_BYE_TIMEOUT) {
fnc_log(FNC_LOG_INFO, "[client] Soft stream timeout");
rtcp_send_sr(session, BYE);
}
/* If we were not able to serve any packet and the client ignored our BYE
* kick it by closing everything
*/
if (session->isBye != 0 &&
(now - session->last_packet_send_time) >= STREAM_TIMEOUT) {
fnc_log(FNC_LOG_INFO, "[client] Stream Timeout, client kicked off!");
ev_async_send(session->srv->loop, &session->client->ev_sig_disconnect);
}else{
#endif
/* send RTCP SDE */
rtcp_send_sr(session, SDES);
/* If we do not read RTCP report in 12 seconds .we will deal it as the client lost
connection,and end the child process.
*/
if(session->srv->srvconf.rtcp_heartbeat != 0 &&
session->last_rtcp_read_time != 0 &&
(now - session->last_rtcp_read_time)>=60)
{
fnc_log(FNC_LOG_INFO, "[client] Client Lost Connection\n");
ev_async_send(session->srv->loop, &session->client->ev_sig_disconnect);
}
#if 0
}
#endif
}
static __inline__ gboolean
rtsp_recv_rtp_packets(RTSP_client_session *rtsp_s, RTP_Session *rtp_s,
GEvent *ev)
{
gchar rtp_pkt[RTP_BUFFER_LEN];
gint rtp_size, err;
for (;;)
{
rtp_size = recvfrom(g_event_fd(ev), rtp_pkt, RTP_BUFFER_LEN,
MSG_DONTWAIT, NULL, NULL);
if (rtp_size > 0)
{
RTP_Frame fr;
err = rtp_parse_frame(rtp_s, rtp_pkt, rtp_size, &fr);
if (err == RTP_PKT_OK || err == RTP_PKT_AGAIN)
{
if (err == RTP_PKT_OK)
{
INVOKE_DAT_HOOK_FRA(rtsp_s, &fr, NULL);
}
continue;
}
fnc_log(FNC_LOG_ERR,
"[FC] Rtp parse failed, rtsp_s '%p', stop.", rtsp_s
);
g_event_remove_events_sync(ev, EV_READ|EV_WRITE);
break;
}
else
{
err = -errno;
if (err != -EAGAIN && err != -EINTR)
{
fnc_log(FNC_LOG_ERR,
"[FC] Rtp recv failed, rtsp_s '%p', err:'%d', stop.", rtsp_s, err
);
g_event_remove_events_sync(ev, EV_READ|EV_WRITE);
}
break;
}
}
return TRUE;
}
Track *add_track(Resource *r, char *name, MediaProperties *prop_hints)
{
Track *t;
t = g_slice_new0(Track);
t->lock = g_mutex_new();
t->parent = r;
t->name = name;
t->sdp_description = g_string_new("");
g_string_append_printf(t->sdp_description,
"a=control:%s\r\n",
name);
memcpy(&t->properties, prop_hints, sizeof(MediaProperties));
switch (t->properties.media_source) {
case STORED_SOURCE:
if ( !(t->parser = mparser_find(t->properties.encoding_name)) ) {
fnc_log(FNC_LOG_FATAL, "Could not find a valid parser\n");
goto error;
}
t->properties.media_type = t->parser->media_type;
break;
case LIVE_SOURCE:
break;
default:
g_assert_not_reached();
break;
}
if (t->parser && t->parser->init && t->parser->init(t) != 0) {
fnc_log(FNC_LOG_FATAL, "Could not initialize parser for %s\n",
t->properties.encoding_name);
goto error;
}
r->tracks = g_list_append(r->tracks, t);
return t;
error:
free_track(t, NULL);
return NULL;
}
char *alloc_path_name(char *base_path, char *file_path)
{
char *PathName;
char *p;
int len;
len = strlen(base_path);
PathName = malloc(len + strlen(file_path) + 2);
if (PathName==NULL) {
fnc_log(FNC_LOG_FATAL,"Out of memory in alloc_path_name()\n");
exit(-1);
}
p = base_path + len ;
if (len)
p--;
if ((*p == '/') && (*file_path == '/'))
sprintf(PathName, "%s%s", base_path, file_path + 1);
else if ((*p != '/') && (*file_path != '/'))
sprintf(PathName, "%s/%s", base_path, file_path);
else
sprintf(PathName, "%s%s", base_path, file_path);
return (PathName);
}
static __inline__ gint
get_new_udp_sock(gint *port)
{
struct sockaddr_in sin;
socklen_t len = sizeof(sin);
gint sock, err;
sock = unix_sock_bind(NULL, *port, L4_UDP);
if (sock < 0)
return sock;
if (!*port)
{
if (getsockname(sock, (struct sockaddr*)&sin, &len))
{
err = -errno;
fnc_log(FNC_LOG_ERR, "[FC] getsockname() failed.");
close(sock);
return err;
}
*port = ntohs(sin.sin_port);
}
return sock;
}
static void interleaved_read_tcp_cb( struct ev_loop *loop, ev_io *w,
int revents)
{
GByteArray *pkt;
uint16_t ne_n;
char buffer[RTSP_BUFFERSIZE + 1];
RTSP_interleaved_channel *intlvd = w->data;
RTSP_Client *rtsp = intlvd->local->data;
int n;
if ((n = Sock_read(intlvd->local, buffer,
RTSP_BUFFERSIZE, NULL, MSG_DONTWAIT)) < 0) {
fnc_log(FNC_LOG_WARN, "Error reading from local socket\n");
return;
}
ne_n = htons((uint16_t)n);
pkt = g_byte_array_sized_new(n+4);
g_byte_array_set_size(pkt, n+4);
pkt->data[0] = '$';
pkt->data[1] = (uint8_t)intlvd->channel;
memcpy(&pkt->data[2], &ne_n, sizeof(ne_n));
memcpy(&pkt->data[4], buffer, n);
g_queue_push_head(rtsp->out_queue, pkt);
ev_io_start(rtsp->srv->loop, &rtsp->ev_io_write);
}
/**
* @brief Resume (or start) an RTP session
*
* @param session_gen The session to resume or start
* @param range_gen Pointer tp @ref RTSP_Range to start with
*
* @todo This function should probably take care of starting eventual
* libev events when the scheduler is replaced.
*
* This function is used by the PLAY method of RTSP to start or resume
* a session; since a newly-created session starts as paused, this is
* the only method available.
*
* The use of a pointer to double rather than a double itself is to
* make it possible to pass this function straight to foreach
* functions from glib.
*
* @internal This function should only be called from g_slist_foreach.
*/
static void rtp_session_resume(gpointer session_gen, gpointer range_gen) {
RTP_session *session = (RTP_session*)session_gen;
RTSP_Range *range = (RTSP_Range*)range_gen;
fnc_log(FNC_LOG_VERBOSE, "Resuming session %p\n", session);
session->range = range;
session->start_seq = 1 + session->seq_no;
session->start_rtptime = g_random_int();
session->send_time = 0.0;
session->last_packet_send_time = time(NULL);
/* Create the new thread pool for the read requests */
session->fill_pool = g_thread_pool_new(rtp_session_fill_cb, session,
1, true, NULL);
/* Prefetch frames */
rtp_session_fill(session);
ev_periodic_set(&session->transport.rtp_writer,
range->playback_time - 0.05,
0, NULL);
ev_periodic_start(session->srv->loop, &session->transport.rtp_writer);
ev_io_start(session->srv->loop, &session->transport.rtcp_reader);
}
static void rtsp_client_free(RTSP_Client *client)
{
GString *outbuf = NULL;
close(client->sd);
g_free(client->local_host);
g_free(client->remote_host);
rtsp_session_free(client->session);
if ( client->channels )
g_hash_table_destroy(client->channels);
/* Remove the output queue */
if ( client->out_queue ) {
while( (outbuf = g_queue_pop_tail(client->out_queue)) )
g_string_free(outbuf, TRUE);
g_queue_free(client->out_queue);
}
if ( client->input ) /* not present on SCTP or HTTP transports */
g_byte_array_free(client->input, true);
g_slice_free(RFC822_Request, client->pending_request);
g_slice_free1(client->sa_len, client->peer_sa);
g_slice_free1(client->sa_len, client->local_sa);
g_slice_free(RTSP_Client, client);
fnc_log(FNC_LOG_INFO, "[client] Client removed");
}
/**
* @brief Send an interleaved RTCP packet down to the RTCP handler
*
* @param rtsp The RTSP client where the handler can be found
* @param channel The channel index where the package arrived
* @param data The pointer to the data to send
* @param len The length of the data to send
*
* This function is used to send data down to the actual RTCP handler
* after it has been received from an interleaved transport (TCP or
* SCTP alike).
*/
void interleaved_rtcp_send(RTSP_Client *rtsp, int channel,
void *data, size_t len)
{
RTSP_interleaved *intlvd = NULL;
GSList *intlvd_iter = g_slist_find_custom(rtsp->interleaved,
GINT_TO_POINTER(channel),
interleaved_rtcp_find_compare);
/* We have to check if the value returned by g_slist_find_custom
* is valid before derefencing it.
*/
if ( intlvd_iter == NULL ) {
fnc_log(FNC_LOG_DEBUG,
"Interleaved RTCP packet arrived for unknown channel (%d)... discarding.\n",
channel);
return;
}
intlvd = (RTSP_interleaved *)intlvd_iter->data;
/* We should be pretty sure this is not NULL */
g_assert(intlvd != NULL);
/* Write the actual data */
Sock_write(intlvd->rtcp.local, data, len, NULL, MSG_DONTWAIT | MSG_EOR);
}
static __inline__ RTP_Session *
rtp_session_new(RTSP_client_session *rtsp_s)
{
RTP_Session *rtp_s;
gint err;
rtp_s = g_new0(RTP_Session, 1);
rtp_s->ref_count = 1;
if (!rtsp_s->rtp_over_rtsp)
{
err = rtp_session_sock_init(rtp_s);
if (err)
{
fnc_log(FNC_LOG_ERR, "[FC] Init RTP sock failed, err:%d", err);
g_free(rtp_s);
return NULL;
}
}
else
{
rtp_s->interleaved = 1;
rtp_s->rtp_port = rtsp_session_get_interleaved(rtsp_s);
#ifdef CONFIG_RTCP_SUPPORT
rtp_s->rtcp_port = rtsp_session_get_interleaved(rtsp_s);
#endif
}
return rtp_s;
}
static void child_terminate_cb (struct ev_loop *loop, ev_child *w, int revents)
{
client_port_pair *client=NULL;
pid_t pid;
feng *srv=w->data;
//ev_child_stop (EV_A_ w);
//printf ("child process %d exited with status %x\n", w->rpid, w->rstatus);
pid = w->rpid;
client=get_client_list_item(pid);
if(client)
{
fnc_log(FNC_LOG_INFO,
"The child process (pid:%d) for rtsp connection (%s:%hu) terminated with status %x\n",
w->rpid,
client->host,
client->port,
w->rstatus);
reduce_client_list(client);
srv->connection_count--;
free_child_port(client);
}
}
gboolean interleaved_setup_transport(RTSP_Client *rtsp, RTP_transport *transport,
int rtp_ch, int rtcp_ch) {
RTSP_interleaved *intlvd = NULL;
Sock *sock_pair[2][2];
//unsigned buffer_size = 0;
// RTP local sockpair
if ( Sock_socketpair(sock_pair[0]) < 0) {
fnc_log(FNC_LOG_ERR,
"Cannot create AF_LOCAL socketpair for rtp\n");
return false;
}
// RTCP local sockpair
if ( Sock_socketpair(sock_pair[1]) < 0) {
fnc_log(FNC_LOG_ERR,
"Cannot create AF_LOCAL socketpair for rtcp\n");
Sock_close(sock_pair[0][0]);
Sock_close(sock_pair[0][1]);
return false;
}
intlvd = g_slice_new0(RTSP_interleaved);
transport->rtp_sock = sock_pair[0][0];
intlvd->rtp.local = sock_pair[0][1];
/* Jmkn: Not necessary to increase the buffer for socketpair,
* because we send a 1.4 Kbytes packet each time
*/
/*
buffer_size = increase_sock_buffer_to(transport->rtp_sock, SO_SNDBUF, RTP_BUF_SIZE);
fnc_log(FNC_LOG_VERBOSE,"[rtsp] Set rtp data socket send buffer size to %u", buffer_size);
*/
transport->rtcp_sock = sock_pair[1][0];
intlvd->rtcp.local = sock_pair[1][1];
// copy stream number in rtp_transport struct
transport->rtp_ch = intlvd->rtp.channel = rtp_ch;
transport->rtcp_ch = intlvd->rtcp.channel = rtcp_ch;
interleaved_setup_callbacks(rtsp, intlvd);
rtsp->interleaved = g_slist_prepend(rtsp->interleaved, intlvd);
return true;
}
int h264_parse(Track *tr, uint8_t *data, ssize_t len)
{
// double nal_time; // see page 9 and 7.4.1.2
size_t nalsize = 0, index = 0;
uint8_t *p, *q;
if (tr->h264.is_avc) {
const size_t nal_length_size = tr->h264.nal_length_size;
while (1) {
unsigned int i;
if(index >= len) break;
//get the nal size
nalsize = 0;
for(i = 0; i < nal_length_size; i++)
nalsize = (nalsize << 8) | data[index++];
if(nalsize <= 1 || nalsize > len) {
if(nalsize == 1) {
index++;
continue;
} else {
fnc_log(FNC_LOG_VERBOSE, "[h264] AVC: nal size %d", nalsize);
break;
}
}
if (DEFAULT_MTU >= nalsize) {
struct MParserBuffer *buffer = g_slice_new0(struct MParserBuffer);
buffer->timestamp = tr->pts;
buffer->delivery = tr->dts;
buffer->duration = tr->frame_duration;
buffer->marker = true;
buffer->data_size = nalsize;
buffer->data = g_memdup(data + index, buffer->data_size);
track_write(tr, buffer);
fnc_log(FNC_LOG_VERBOSE, "[h264] single NAL");
} else {
// single NAL, to be fragmented, FU-A;
frag_fu_a(data + index, nalsize, tr);
}
index += nalsize;
}
} else {
void rtsp_interleaved_receive(RTSP_Client *rtsp, int channel, uint8_t *data, size_t len)
{
RTP_session *rtp = NULL;
if ( (rtp = g_hash_table_lookup(rtsp->channels, GINT_TO_POINTER(channel))) == NULL )
fnc_log(FNC_LOG_INFO, "Received interleaved message for unknown channel %d", channel);
else /* we currently only support inbound RTCP; find a solution before supporting inbound RTP */
rtcp_handle(rtp, data, len);
}
static void frag_fu_a(uint8_t *nal, int fragsize, Track *tr)
{
int start = 1;
const uint8_t fu_indicator = (nal[0] & 0xe0) | 28;
const uint8_t fu_header = nal[0] & 0x1f;
fnc_log(FNC_LOG_VERBOSE, "[h264] frags");
nal++;
fragsize--;
while(fragsize>0) {
const size_t fraglen = MIN(DEFAULT_MTU-2, fragsize);
struct MParserBuffer *buffer = g_slice_new0(struct MParserBuffer);
buffer->timestamp = tr->pts;
buffer->delivery = tr->dts;
buffer->duration = tr->frame_duration;
buffer->data_size = fraglen + 2;
buffer->data = g_malloc(buffer->data_size);
buffer->data[0] = fu_indicator;
buffer->data[1] = fu_header;
if ( start ) {
buffer->data[1] |= (1<<7);
start = 0;
}
if (fraglen == fragsize) {
buffer->marker = true;
buffer->data[1] |= (1<<6);
}
memcpy(buffer->data + 2, nal, fraglen);
fnc_log(FNC_LOG_VERBOSE, "[h264] Frag %02x%02x", buffer->data[0], buffer->data[1]);
track_write(tr, buffer);
fragsize -= fraglen;
nal += fraglen;
}
}
/**
* @brief parse incoming RTCP packets
*/
static void rtcp_read_cb(ATTR_UNUSED struct ev_loop *loop,
ev_io *w,
ATTR_UNUSED int revents)
{
char buffer[RTP_DEFAULT_MTU*2] = { 0, }; //FIXME just a quick hack...
RTP_session *session = w->data;
int n = Sock_read(session->transport.rtcp_sock, buffer,
RTP_DEFAULT_MTU*2, NULL, 0);
fnc_log(FNC_LOG_INFO, "[RTCP] Read %d byte", n);
}
int send_reply(int err, char *addon, RTSP_buffer * rtsp)
{
unsigned int len;
char *b;
char *p;
int res;
char method[32];
char object[256];
char ver[32];
if (addon != NULL) {
len = 256 + strlen(addon);
} else {
len = 256;
}
b = (char *) malloc(len);
if (b == NULL) {
fnc_log(FNC_LOG_ERR,"send_reply(): memory allocation error.\n");
return ERR_ALLOC;
}
memset(b, 0, sizeof(b));
sprintf(b, "%s %d %s"RTSP_EL"CSeq: %d"RTSP_EL, RTSP_VER, err, get_stat(err), rtsp->rtsp_cseq);
//---patch coerenza con rfc in caso di errore
// strcat(b, "\r\n");
strcat(b, RTSP_EL);
res = bwrite(b, (unsigned short) strlen(b), rtsp);
free(b);
sscanf(rtsp->in_buffer, " %31s %255s %31s ", method, object, ver);
fnc_log(FNC_LOG_ERR,"%s %s %s %d - - ", method, object, ver, err);
if ((p=strstr(rtsp->in_buffer, HDR_USER_AGENT))!=NULL) {
char cut[strlen(p)];
strcpy(cut,p);
cut[strlen(cut)-1]='\0';
fnc_log(FNC_LOG_CLIENT,"%s",cut);
}
return res;
}
static __inline__ void
rtp_session_destroy_ssrc(RTP_Session *rtp_s)
{
if (rtp_s->ssrc != &rtp_s->rtp_ssrc_init)
{
fnc_log(FNC_LOG_ERR, "[FC] rtp ssrc sanity check failed!");
BUG();
}
return;
}
int send_options_reply(RTSP_buffer * rtsp, long cseq)
{
char r[1024];
sprintf(r, "%s %d %s"RTSP_EL"CSeq: %ld"RTSP_EL, RTSP_VER, 200, get_stat(200), cseq);
strcat(r, "Public: OPTIONS,DESCRIBE,SETUP,PLAY,PAUSE,TEARDOWN"RTSP_EL);
strcat(r, RTSP_EL);
bwrite(r, (unsigned short) strlen(r), rtsp);
fnc_log(FNC_LOG_CLIENT,"200 - - ");
return ERR_NOERROR;
}
static void
rtp_packet_send(RTP_session *session, MParserBuffer *buffer, time_t time_now)
{
gsize packet_size = sizeof(RTP_packet) + buffer->data_size;
RTP_packet *packet = g_malloc0(packet_size);
Track *tr = session->track;
guint32 timestamp = RTP_calc_rtptime(session,
tr->properties.clock_rate,
buffer);
packet->version = 2;
packet->padding = 0;
packet->extension = 0;
packet->csrc_len = 0;
packet->marker = buffer->marker & 0x1;
packet->payload = tr->properties.payload_type & 0x7f;
packet->seq_no = htons(++session->seq_no);
packet->timestamp = htonl(timestamp);
packet->ssrc = htonl(session->ssrc);
fnc_log(FNC_LOG_VERBOSE, "[RTP] Timestamp: %u", ntohl(timestamp));
memcpy(packet->data, buffer->data, buffer->data_size);
if (__rtp_pkt_send(session, &session->transport,
packet, packet_size) < 0)
{
fnc_log(FNC_LOG_DEBUG, "RTP Packet Lost\n");
}
else
{
session->last_timestamp = buffer->timestamp;
session->pkt_count++;
session->octet_count += buffer->data_size;
session->last_packet_send_time = time_now;//time(NULL);
}
g_free(packet);
}
static void command_environment(int argc, char **argv)
{
#ifndef CLEANUP_DESTRUCTOR
gchar *progname;
#endif
gchar *config_file = NULL;
gboolean quiet = FALSE, verbose = FALSE, lint = FALSE;
GOptionEntry optionsTable[] = {
{ "config", 'f', 0, G_OPTION_ARG_STRING, &config_file,
"specify configuration file", NULL },
{ "quiet", 'q', 0, G_OPTION_ARG_NONE, &quiet,
"show as little output as possible", NULL },
{ "verbose", 'v', 0, G_OPTION_ARG_NONE, &verbose,
"output to standard error (debug)", NULL },
{ "version", 'V', G_OPTION_FLAG_NO_ARG, G_OPTION_ARG_CALLBACK, show_version,
"print version information and exit", NULL },
{ "lint", 'l', 0, G_OPTION_ARG_NONE, &lint,
"check the configuration file for errors, then exit", NULL },
{ NULL, 0, 0, 0, NULL, NULL, NULL }
};
GError *error = NULL;
GOptionContext *context = g_option_context_new("");
g_option_context_add_main_entries(context, optionsTable, PACKAGE_TARNAME);
g_option_context_parse(context, &argc, &argv, &error);
g_option_context_free(context);
if ( error != NULL ) {
fnc_log(FNC_LOG_FATAL, "%s", error->message);
exit(1);
}
if (!quiet && !lint) fncheader();
config_file_parse(config_file, lint);
g_free(config_file);
/* if we're doing a verbose run, make sure to output
everything directly on standard error.
*/
if ( verbose ) {
feng_srv.log_level = FNC_LOG_INFO;
feng_srv.error_log = "stderr";
}
progname = g_path_get_basename(argv[0]);
fnc_log_init(progname);
}
