/************************************************************************
* Function: TimerThreadInit
*
* Description:
* Initializes and starts timer thread.
*
* Parameters:
* timer - valid timer thread pointer.
* tp - valid thread pool to use. Must be
* started. Must be valid for lifetime
* of timer. Timer must be shutdown
* BEFORE thread pool.
* Return:
* 0 on success, nonzero on failure
* Returns error from ThreadPoolAddPersistent if failure.
************************************************************************/
int
TimerThreadInit( TimerThread * timer,
ThreadPool * tp )
{
int rc = 0;
ThreadPoolJob timerThreadWorker;
assert( timer != NULL );
assert( tp != NULL );
if( ( timer == NULL ) || ( tp == NULL ) ) {
return EINVAL;
}
rc += ithread_mutex_init( &timer->mutex, NULL );
assert( rc == 0 );
rc += ithread_mutex_lock( &timer->mutex );
assert( rc == 0 );
rc += ithread_cond_init( &timer->condition, NULL );
assert( rc == 0 );
rc += FreeListInit( &timer->freeEvents, sizeof( TimerEvent ), 100 );
assert( rc == 0 );
timer->shutdown = 0;
timer->tp = tp;
timer->lastEventId = 0;
rc += ListInit( &timer->eventQ, NULL, NULL );
assert( rc == 0 );
if( rc != 0 ) {
rc = EAGAIN;
} else {
TPJobInit( &timerThreadWorker, TimerThreadWorker, timer );
TPJobSetPriority( &timerThreadWorker, HIGH_PRIORITY );
rc = ThreadPoolAddPersistent( tp, &timerThreadWorker, NULL );
}
ithread_mutex_unlock( &timer->mutex );
if( rc != 0 ) {
ithread_cond_destroy( &timer->condition );
ithread_mutex_destroy( &timer->mutex );
FreeListDestroy( &timer->freeEvents );
ListDestroy( &timer->eventQ, 0 );
}
return rc;
}
int StartMiniServer(
/*! [in,out] Port on which the server listens for incoming IPv4
* connections. */
uint16_t *listen_port4,
/*! [in,out] Port on which the server listens for incoming IPv6
* connections. */
uint16_t *listen_port6)
{
int ret_code;
int count;
int max_count = 10000;
MiniServerSockArray *miniSocket;
ThreadPoolJob job;
memset(&job, 0, sizeof(job));
switch (gMServState) {
case MSERV_IDLE:
break;
default:
/* miniserver running. */
return UPNP_E_INTERNAL_ERROR;
}
miniSocket = (MiniServerSockArray *)malloc(
sizeof (MiniServerSockArray));
if (!miniSocket) {
return UPNP_E_OUTOF_MEMORY;
}
InitMiniServerSockArray(miniSocket);
#ifdef INTERNAL_WEB_SERVER
/* V4 and V6 http listeners. */
ret_code = get_miniserver_sockets(
miniSocket, *listen_port4, *listen_port6);
if (ret_code != UPNP_E_SUCCESS) {
free(miniSocket);
return ret_code;
}
#endif
/* Stop socket (To end miniserver processing). */
ret_code = get_miniserver_stopsock(miniSocket);
if (ret_code != UPNP_E_SUCCESS) {
sock_close(miniSocket->miniServerSock4);
sock_close(miniSocket->miniServerSock6);
free(miniSocket);
return ret_code;
}
/* SSDP socket for discovery/advertising. */
ret_code = get_ssdp_sockets(miniSocket);
if (ret_code != UPNP_E_SUCCESS) {
sock_close(miniSocket->miniServerSock4);
sock_close(miniSocket->miniServerSock6);
sock_close(miniSocket->miniServerStopSock);
free(miniSocket);
return ret_code;
}
TPJobInit(&job, (start_routine)RunMiniServer, (void *)miniSocket);
TPJobSetPriority(&job, MED_PRIORITY);
TPJobSetFreeFunction(&job, (free_routine)free);
ret_code = ThreadPoolAddPersistent(&gMiniServerThreadPool, &job, NULL);
if (ret_code < 0) {
sock_close(miniSocket->miniServerSock4);
sock_close(miniSocket->miniServerSock6);
sock_close(miniSocket->miniServerStopSock);
sock_close(miniSocket->ssdpSock4);
sock_close(miniSocket->ssdpSock6);
sock_close(miniSocket->ssdpSock6UlaGua);
#ifdef INCLUDE_CLIENT_APIS
sock_close(miniSocket->ssdpReqSock4);
sock_close(miniSocket->ssdpReqSock6);
#endif /* INCLUDE_CLIENT_APIS */
return UPNP_E_OUTOF_MEMORY;
}
/* Wait for miniserver to start. */
count = 0;
while (gMServState != (MiniServerState)MSERV_RUNNING && count < max_count) {
/* 0.05s */
usleep(50u * 1000u);
count++;
}
if (count >= max_count) {
/* Took it too long to start that thread. */
sock_close(miniSocket->miniServerSock4);
sock_close(miniSocket->miniServerSock6);
sock_close(miniSocket->miniServerStopSock);
sock_close(miniSocket->ssdpSock4);
sock_close(miniSocket->ssdpSock6);
sock_close(miniSocket->ssdpSock6UlaGua);
#ifdef INCLUDE_CLIENT_APIS
sock_close(miniSocket->ssdpReqSock4);
sock_close(miniSocket->ssdpReqSock6);
#endif /* INCLUDE_CLIENT_APIS */
return UPNP_E_INTERNAL_ERROR;
}
#ifdef INTERNAL_WEB_SERVER
*listen_port4 = miniSocket->miniServerPort4;
*listen_port6 = miniSocket->miniServerPort6;
#endif
return UPNP_E_SUCCESS;
}
/************************************************************************
* Function: StartMiniServer
*
* Parameters :
* unsigned short listen_port - Port on which the server listens for
* incoming connections
*
* Description:
* Initialize the sockets functionality for the
* Miniserver. Initialize a thread pool job to run the MiniServer
* and the job to the thread pool. If listen port is 0, port is
* dynamically picked
*
* Use timer mechanism to start the MiniServer, failure to meet the
* allowed delay aborts the attempt to launch the MiniServer.
*
* Return: int
* Actual port socket is bound to - On Success
* A negative number DLNA_E_XXX - On Error
************************************************************************/
int
StartMiniServer( unsigned short listen_port )
{
int success;
int count;
int max_count = 10000;
MiniServerSockArray *miniSocket;
ThreadPoolJob job;
if( gMServState != MSERV_IDLE ) {
return DLNA_E_INTERNAL_ERROR; // miniserver running
}
miniSocket =
( MiniServerSockArray * ) malloc( sizeof( MiniServerSockArray ) );
if( miniSocket == NULL )
return DLNA_E_OUTOF_MEMORY;
if( ( success = get_miniserver_sockets( miniSocket, listen_port ) )
!= DLNA_E_SUCCESS ) {
free( miniSocket );
return success;
}
if( ( success = get_ssdp_sockets( miniSocket ) ) != DLNA_E_SUCCESS ) {
shutdown( miniSocket->miniServerSock, SD_BOTH );
dlnaCloseSocket( miniSocket->miniServerSock );
shutdown( miniSocket->miniServerStopSock, SD_BOTH );
dlnaCloseSocket( miniSocket->miniServerStopSock );
free( miniSocket );
return success;
}
TPJobInit( &job, ( start_routine ) RunMiniServer,
( void * )miniSocket );
TPJobSetPriority( &job, MED_PRIORITY );
TPJobSetFreeFunction( &job, ( free_routine ) free );
success = ThreadPoolAddPersistent( &gMiniServerThreadPool, &job, NULL );
if( success < 0 ) {
shutdown( miniSocket->miniServerSock, SD_BOTH );
dlnaCloseSocket( miniSocket->miniServerSock );
shutdown( miniSocket->miniServerStopSock, SD_BOTH );
dlnaCloseSocket( miniSocket->miniServerStopSock );
shutdown( miniSocket->ssdpSock, SD_BOTH );
dlnaCloseSocket( miniSocket->ssdpSock );
#ifdef INCLUDE_CLIENT_APIS
shutdown( miniSocket->ssdpReqSock, SD_BOTH );
dlnaCloseSocket( miniSocket->ssdpReqSock );
#endif
return DLNA_E_OUTOF_MEMORY;
}
// wait for miniserver to start
count = 0;
while( gMServState != MSERV_RUNNING && count < max_count ) {
usleep( 50 * 1000 ); // 0.05s
count++;
}
// taking too long to start that thread
if( count >= max_count ) {
shutdown( miniSocket->miniServerSock, SD_BOTH );
dlnaCloseSocket( miniSocket->miniServerSock );
shutdown( miniSocket->miniServerStopSock, SD_BOTH );
dlnaCloseSocket( miniSocket->miniServerStopSock );
shutdown( miniSocket->ssdpSock, SD_BOTH );
dlnaCloseSocket( miniSocket->ssdpSock );
#ifdef INCLUDE_CLIENT_APIS
shutdown( miniSocket->ssdpReqSock, SD_BOTH );
dlnaCloseSocket( miniSocket->ssdpReqSock );
#endif
return DLNA_E_INTERNAL_ERROR;
}
return miniSocket->miniServerPort;
}
/****************************************************************************
* Function: TimerThreadWorker
*
* Description:
* Implements timer thread.
* Waits for next event to occur and schedules
* associated job into threadpool.
* Internal Only.
* Parameters:
* void * arg -> is cast to TimerThread *
*****************************************************************************/
static void *
TimerThreadWorker( void *arg )
{
TimerThread *timer = ( TimerThread * ) arg;
ListNode *head = NULL;
TimerEvent *nextEvent = NULL;
time_t currentTime = 0;
time_t nextEventTime = 0;
struct timespec timeToWait;
int tempId;
assert( timer != NULL );
ithread_mutex_lock( &timer->mutex );
while( 1 )
{
//mutex should always be locked at top of loop
//Check for shutdown
if( timer->shutdown )
{
timer->shutdown = 0;
ithread_cond_signal( &timer->condition );
ithread_mutex_unlock( &timer->mutex );
return NULL;
}
nextEvent = NULL;
//Get the next event if possible
if( timer->eventQ.size > 0 )
{
head = ListHead( &timer->eventQ );
nextEvent = ( TimerEvent * ) head->item;
nextEventTime = nextEvent->eventTime;
}
currentTime = time( NULL );
//If time has elapsed, schedule job
if( ( nextEvent != NULL ) && ( currentTime >= nextEventTime ) )
{
if( nextEvent->persistent ) {
ThreadPoolAddPersistent( timer->tp, &nextEvent->job,
&tempId );
} else {
ThreadPoolAdd( timer->tp, &nextEvent->job, &tempId );
}
ListDelNode( &timer->eventQ, head, 0 );
FreeTimerEvent( timer, nextEvent );
continue;
}
if( nextEvent != NULL ) {
timeToWait.tv_nsec = 0;
timeToWait.tv_sec = nextEvent->eventTime;
ithread_cond_timedwait( &timer->condition, &timer->mutex,
&timeToWait );
} else {
ithread_cond_wait( &timer->condition, &timer->mutex );
}
}
}
