int ARSTREAM2_H264_NaluFifoPushFreeItem(ARSTREAM2_H264_NaluFifo_t *fifo, ARSTREAM2_H264_NaluFifoItem_t *item)
{
if ((!fifo) || (!item))
{
ARSAL_PRINT(ARSAL_PRINT_ERROR, ARSTREAM2_H264_TAG, "Invalid pointer");
return -1;
}
ARSAL_Mutex_Lock(&(fifo->mutex));
if (fifo->free)
{
fifo->free->prev = item;
item->next = fifo->free;
}
else
{
item->next = NULL;
}
fifo->free = item;
item->prev = NULL;
ARSAL_Mutex_Unlock(&(fifo->mutex));
return 0;
}
eARNETWORK_ERROR ARNETWORK_RingBuffer_PopFrontWithSize(ARNETWORK_RingBuffer_t *ringBuffer, uint8_t *dataPop, int dataSize)
{
/* -- Pop the oldest data -- */
/* local declarations */
uint8_t *buffer = NULL;
eARNETWORK_ERROR error = ARNETWORK_OK;
ARSAL_Mutex_Lock(&(ringBuffer->mutex));
if (!ARNETWORK_RingBuffer_IsEmptyUnlocked(ringBuffer))
{
if(dataPop != NULL)
{
/* get the address of the front data */
buffer = ringBuffer->dataBuffer + (ringBuffer->indexOutput % (ringBuffer->numberOfCell * ringBuffer->cellSize));
memcpy(dataPop, buffer, dataSize);
}
/* No else: the data popped is not returned */
(ringBuffer->indexOutput) += ringBuffer->cellSize;
ARNETWORK_RingBuffer_NormalizeIndexes(ringBuffer);
}
else
{
error = ARNETWORK_ERROR_BUFFER_EMPTY;
}
ARSAL_Mutex_Unlock(&(ringBuffer->mutex));
return error;
}
float ARSTREAM_Reader_GetEstimatedEfficiency (ARSTREAM_Reader_t *reader)
{
if (reader == NULL)
{
return -1.0f;
}
float retVal = 1.0f;
uint32_t totalPackets = 0;
uint32_t usefulPackets = 0;
int i;
ARSAL_Mutex_Lock (&(reader->ackPacketMutex));
for (i = 0; i < ARSTREAM_READER_EFFICIENCY_AVERAGE_NB_FRAMES; i++)
{
totalPackets += reader->efficiency_nbTotal [i];
usefulPackets += reader->efficiency_nbUseful [i];
}
ARSAL_Mutex_Unlock (&(reader->ackPacketMutex));
if (totalPackets == 0)
{
retVal = 0.0f; // We didn't receive anything yet ... not really efficient
}
else if (usefulPackets > totalPackets)
{
retVal = 1.0f; // If this happens, it means that we have a big problem
ARSAL_PRINT (ARSAL_PRINT_ERROR, ARSTREAM_READER_TAG, "Computed efficiency is greater that 1.0 ...");
}
else
{
retVal = (1.f * usefulPackets) / (1.f * totalPackets);
}
return retVal;
}
int ARSTREAM2_H264_AuFifoAddQueue(ARSTREAM2_H264_AuFifo_t *fifo, ARSTREAM2_H264_AuFifoQueue_t *queue)
{
if ((!fifo) || (!queue))
{
ARSAL_PRINT(ARSAL_PRINT_ERROR, ARSTREAM2_H264_TAG, "Invalid pointer");
return -1;
}
int mutexRet = ARSAL_Mutex_Init(&(queue->mutex));
if (mutexRet != 0)
{
ARSAL_PRINT(ARSAL_PRINT_ERROR, ARSTREAM2_H264_TAG, "Mutex creation failed (%d)", mutexRet);
return -1;
}
ARSAL_Mutex_Lock(&(fifo->mutex));
queue->count = 0;
queue->head = NULL;
queue->tail = NULL;
queue->prev = NULL;
queue->next = fifo->queue;
if (queue->next)
{
queue->next->prev = queue;
}
fifo->queue = queue;
fifo->queueCount++;
ARSAL_Mutex_Unlock(&(fifo->mutex));
return 0;
}
int ARSTREAM2_H264_AuFifoPushFreeItem(ARSTREAM2_H264_AuFifo_t *fifo, ARSTREAM2_H264_AuFifoItem_t *item)
{
if ((!fifo) || (!item))
{
ARSAL_PRINT(ARSAL_PRINT_ERROR, ARSTREAM2_H264_TAG, "Invalid pointer");
return -1;
}
int ret = ARSTREAM2_H264_AuNaluFifoFlush(&item->au);
if (ret != 0)
{
ARSAL_PRINT(ARSAL_PRINT_ERROR, ARSTREAM2_H264_TAG, "ARSTREAM2_H264_AuNaluFifoFlush() failed (%d)", ret);
return -1;
}
ARSAL_Mutex_Lock(&(fifo->mutex));
if (fifo->itemFree)
{
fifo->itemFree->prev = item;
item->next = fifo->itemFree;
}
else
{
item->next = NULL;
}
fifo->itemFree = item;
item->prev = NULL;
ARSAL_Mutex_Unlock(&(fifo->mutex));
return 0;
}
eARNETWORK_ERROR ARNETWORK_RingBuffer_Front(ARNETWORK_RingBuffer_t *ringBuffer, uint8_t *frontData)
{
/* -- Return a pointer on the front data -- */
/* local declarations */
eARNETWORK_ERROR error = ARNETWORK_OK;
uint8_t *buffer = NULL;
ARSAL_Mutex_Lock(&(ringBuffer->mutex));
/* get the address of the front data */
buffer = ringBuffer->dataBuffer + (ringBuffer->indexOutput % (ringBuffer->numberOfCell * ringBuffer->cellSize));
if( !ARNETWORK_RingBuffer_IsEmptyUnlocked(ringBuffer) )
{
memcpy(frontData, buffer, ringBuffer->cellSize);
}
else
{
error = ARNETWORK_ERROR_BUFFER_EMPTY;
}
ARSAL_Mutex_Unlock(&(ringBuffer->mutex));
return error;
}
ARSTREAM2_H264_AuFifoItem_t* ARSTREAM2_H264_AuFifoPopFreeItem(ARSTREAM2_H264_AuFifo_t *fifo)
{
if (!fifo)
{
ARSAL_PRINT(ARSAL_PRINT_ERROR, ARSTREAM2_H264_TAG, "Invalid pointer");
return NULL;
}
ARSAL_Mutex_Lock(&(fifo->mutex));
if (fifo->itemFree)
{
ARSTREAM2_H264_AuFifoItem_t* cur = fifo->itemFree;
fifo->itemFree = cur->next;
if (cur->next) cur->next->prev = NULL;
cur->prev = NULL;
cur->next = NULL;
ARSAL_Mutex_Unlock(&(fifo->mutex));
return cur;
}
else
{
ARSAL_PRINT(ARSAL_PRINT_ERROR, ARSTREAM2_H264_TAG, "AU FIFO is full");
ARSAL_Mutex_Unlock(&(fifo->mutex));
return NULL;
}
}
void ARNETWORK_RingBuffer_DataPrint(ARNETWORK_RingBuffer_t *ringBuffer)
{
/* -- Print the contents of the ring buffer -- */
/* local declarations */
uint8_t *byteIterator = NULL;
unsigned int cellIndex = 0;
unsigned int byteIndex = 0;
ARSAL_Mutex_Lock(&(ringBuffer->mutex));
/* for all cell of the ringBuffer */
for (cellIndex = ringBuffer->indexOutput ; cellIndex < ringBuffer->indexInput ; cellIndex += ringBuffer->cellSize )
{
byteIterator = ringBuffer->dataBuffer + (cellIndex % (ringBuffer->numberOfCell * ringBuffer->cellSize) );
ARSAL_PRINT(ARSAL_PRINT_WARNING, ARNETWORK_RINGBUFFER_TAG," - 0x: ");
/* for all byte of the cell */
for(byteIndex = 0 ; byteIndex < ringBuffer->cellSize ; ++byteIndex)
{
ARSAL_PRINT(ARSAL_PRINT_WARNING, ARNETWORK_RINGBUFFER_TAG,"%2x | ",*((uint8_t*)byteIterator));
++byteIterator;
}
ARSAL_PRINT(ARSAL_PRINT_WARNING, ARNETWORK_RINGBUFFER_TAG,"\n");
}
ARSAL_Mutex_Unlock(&(ringBuffer->mutex));
}
int ARSTREAM2_H264_AuFifoEnqueueItem(ARSTREAM2_H264_AuFifoQueue_t *queue, ARSTREAM2_H264_AuFifoItem_t *item)
{
if ((!queue) || (!item))
{
ARSAL_PRINT(ARSAL_PRINT_ERROR, ARSTREAM2_H264_TAG, "Invalid pointer");
return -1;
}
ARSAL_Mutex_Lock(&(queue->mutex));
item->next = NULL;
if (queue->tail)
{
queue->tail->next = item;
item->prev = queue->tail;
}
else
{
item->prev = NULL;
}
queue->tail = item;
if (!queue->head)
{
queue->head = item;
}
queue->count++;
ARSAL_Mutex_Unlock(&(queue->mutex));
return 0;
}
ARSTREAM2_H264_AuFifoBuffer_t* ARSTREAM2_H264_AuFifoGetBuffer(ARSTREAM2_H264_AuFifo_t *fifo)
{
if (!fifo)
{
ARSAL_PRINT(ARSAL_PRINT_ERROR, ARSTREAM2_H264_TAG, "Invalid pointer");
return NULL;
}
ARSAL_Mutex_Lock(&(fifo->mutex));
if (fifo->bufferFree)
{
ARSTREAM2_H264_AuFifoBuffer_t* cur = fifo->bufferFree;
fifo->bufferFree = cur->next;
if (cur->next) cur->next->prev = NULL;
cur->prev = NULL;
cur->next = NULL;
cur->refCount = 1;
ARSAL_Mutex_Unlock(&(fifo->mutex));
return cur;
}
else
{
ARSAL_Mutex_Unlock(&(fifo->mutex));
ARSAL_PRINT(ARSAL_PRINT_ERROR, ARSTREAM2_H264_TAG, "No free buffer in pool");
return NULL;
}
}
void* ARSTREAM_Reader_RunAckThread (void *ARSTREAM_Reader_t_Param)
{
ARSTREAM_NetworkHeaders_AckPacket_t sendPacket = {0};
ARSTREAM_Reader_t *reader = (ARSTREAM_Reader_t *)ARSTREAM_Reader_t_Param;
memset(&sendPacket, 0, sizeof(sendPacket));
ARSAL_PRINT (ARSAL_PRINT_DEBUG, ARSTREAM_READER_TAG, "Ack sender thread running");
reader->ackThreadStarted = 1;
while (reader->threadsShouldStop == 0)
{
int isPeriodicAck = 0;
ARSAL_Mutex_Lock (&(reader->ackSendMutex));
if (reader->maxAckInterval <= 0)
{
ARSAL_Cond_Wait (&(reader->ackSendCond), &(reader->ackSendMutex));
}
else
{
int retval = ARSAL_Cond_Timedwait (&(reader->ackSendCond), &(reader->ackSendMutex), reader->maxAckInterval);
if (retval == -1 && errno == ETIMEDOUT)
{
isPeriodicAck = 1;
}
}
ARSAL_Mutex_Unlock (&(reader->ackSendMutex));
/* Only send an ACK if the maxAckInterval value allows it. */
if ((reader->maxAckInterval > 0) ||
((reader->maxAckInterval == 0) && (isPeriodicAck == 0)))
{
ARSAL_Mutex_Lock (&(reader->ackPacketMutex));
sendPacket.frameNumber = htods (reader->ackPacket.frameNumber);
sendPacket.highPacketsAck = htodll (reader->ackPacket.highPacketsAck);
sendPacket.lowPacketsAck = htodll (reader->ackPacket.lowPacketsAck);
ARSAL_Mutex_Unlock (&(reader->ackPacketMutex));
ARNETWORK_Manager_SendData (reader->manager, reader->ackBufferID, (uint8_t *)&sendPacket, sizeof (sendPacket), NULL, ARSTREAM_Reader_NetworkCallback, 1);
}
}
ARSAL_PRINT (ARSAL_PRINT_DEBUG, ARSTREAM_READER_TAG, "Ack sender thread ended");
reader->ackThreadStarted = 0;
return (void *)0;
}
void ARNETWORK_Sender_GotPingAck (ARNETWORK_Sender_t *senderPtr, struct timespec *startTime, struct timespec *endTime)
{
ARSAL_Mutex_Lock (&(senderPtr->pingMutex));
if ((senderPtr->isPingRunning == 1) &&
(ARSAL_Time_TimespecEquals (startTime, &(senderPtr->pingStartTime))))
{
senderPtr->lastPingValue = ARSAL_Time_ComputeTimespecMsTimeDiff (startTime, endTime);
senderPtr->isPingRunning = 0;
}
ARSAL_Mutex_Unlock (&(senderPtr->pingMutex));
}
int ARNETWORK_RingBuffer_GetFreeCellNumber(ARNETWORK_RingBuffer_t *ringBuffer)
{
int numberOfFreeCell = -1;
ARSAL_Mutex_Lock(&(ringBuffer->mutex));
numberOfFreeCell = ringBuffer->numberOfCell - ( (ringBuffer->indexInput - ringBuffer->indexOutput) / ringBuffer->cellSize );
ARSAL_Mutex_Unlock(&(ringBuffer->mutex));
return numberOfFreeCell;
}
int ARNETWORK_RingBuffer_IsEmpty(ARNETWORK_RingBuffer_t *ringBuffer)
{
int isEmpty = 0;
ARSAL_Mutex_Lock(&(ringBuffer->mutex));
isEmpty = (ringBuffer->indexInput == ringBuffer->indexOutput) ? 1 : 0;
ARSAL_Mutex_Unlock(&(ringBuffer->mutex));
return isEmpty;
}
void ARSTREAM_Reader_StopReader (ARSTREAM_Reader_t *reader)
{
if (reader != NULL)
{
reader->threadsShouldStop = 1;
/* Force unblock the ACK thread to allow it to shutdown quickly.
* This is necessary if maxAckInterval is set to -1, 0 or a large value.
* If maxAckInterval >= 0, an ACK packet will be sent as a side-effect. */
if (reader->ackThreadStarted == 1)
{
ARSAL_Mutex_Lock (&(reader->ackSendMutex));
ARSAL_Cond_Signal (&(reader->ackSendCond));
ARSAL_Mutex_Unlock (&(reader->ackSendMutex));
}
}
}
int ARSTREAM2_H264_AuFifoBufferAddRef(ARSTREAM2_H264_AuFifo_t *fifo, ARSTREAM2_H264_AuFifoBuffer_t *buffer)
{
if (!buffer)
{
ARSAL_PRINT(ARSAL_PRINT_ERROR, ARSTREAM2_H264_TAG, "Invalid pointer");
return -1;
}
ARSAL_Mutex_Lock(&(fifo->mutex));
buffer->refCount++;
ARSAL_Mutex_Unlock(&(fifo->mutex));
return 0;
}
int ARSAL_Sem_Getvalue(ARSAL_Sem_t *sem, int *value)
{
int result = -1;
if (NULL == sem || NULL == *sem || NULL == value)
{
errno = EINVAL;
return result;
}
/* No else. */
#if __SAL_USE_POSIX_SEM
result = sem_getvalue((sem_t *)*sem, value);
#else
/*
* Custom getvalue algo:
* Lock mutex
* Read counter to *value
* Unlock mutex
*/
ARSAL_Sem_CustomImpl_t *psem = (ARSAL_Sem_CustomImpl_t *)*sem;
int unlockRes = 0;
result = ARSAL_Mutex_Lock (&(psem->lock));
ARSAL_SEM_ERRNO_TRANSFORM (result);
if (0 == result)
{
*value = psem->count;
}
/* No else. */
unlockRes = ARSAL_Mutex_Unlock (&(psem->lock));
if (0 != unlockRes)
{
result = -1;
errno = unlockRes;
}
/* No else. */
#endif
return result;
}
eARCONTROLLER_ERROR ARCONTROLLER_Network_Resume (ARCONTROLLER_Network_t *networkController)
{
// -- Resumes the Network Controller --
eARCONTROLLER_ERROR error = ARCONTROLLER_OK;
// Check parameters
if (networkController == NULL)
{
error = ARCONTROLLER_ERROR_BAD_PARAMETER;
}
// No Else: the checking parameters sets error to ARNETWORK_ERROR_BAD_PARAMETER and stop the processing
if (error == ARCONTROLLER_OK)
{
if (ARSAL_Mutex_Lock (&(networkController->mutex)) != 0)
{
error = ARCONTROLLER_ERROR_MUTEX;
}
}
if (error == ARCONTROLLER_OK)
{
switch (networkController->state)
{
case ARCONTROLLER_NETWORK_STATE_PAUSE:
networkController->state = ARCONTROLLER_NETWORK_STATE_RUNNING;
break;
case ARCONTROLLER_NETWORK_STATE_RUNNING:
ARSAL_PRINT(ARSAL_PRINT_WARNING, ARCONTROLLER_NETWORK_TAG, "Nothing to do ; Network controller state : %d ", networkController->state);
break;
case ARCONTROLLER_NETWORK_STATE_STOPPED:
error = ARCONTROLLER_ERROR_STATE;
break;
default:
ARSAL_PRINT(ARSAL_PRINT_ERROR, ARCONTROLLER_NETWORK_TAG, "State : %d not known", networkController->state);
break;
}
ARSAL_Mutex_Unlock (&(networkController->mutex));
}
return error;
}
eARCONTROLLER_ERROR ARCONTROLLER_Network_SetVideoReceiveCallback (ARCONTROLLER_Network_t *networkController, ARCONTROLLER_Stream_DecoderConfigCallback_t decoderConfigCallback, ARCONTROLLER_Stream_DidReceiveFrameCallback_t receiveFrameCallback, ARCONTROLLER_Stream_TimeoutFrameCallback_t timeoutFrameCallback, void *customData)
{
// -- Set Video Receive Callback --
eARCONTROLLER_ERROR error = ARCONTROLLER_OK;
int locked = 0;
// Check parameters
if (networkController == NULL)
{
error = ARCONTROLLER_ERROR_BAD_PARAMETER;
}
// No Else: the checking parameters sets error to ARNETWORK_ERROR_BAD_PARAMETER and stop the processing
if (error == ARCONTROLLER_OK)
{
if (ARSAL_Mutex_Lock (&(networkController->mutex)) != 0)
{
error = ARCONTROLLER_ERROR_MUTEX;
}
else
{
locked = 1;
}
}
if (error == ARCONTROLLER_OK)
{
if (networkController->videoController != NULL)
{
error = ARCONTROLLER_Stream_SetReceiveFrameCallback (networkController->videoController, decoderConfigCallback, receiveFrameCallback, timeoutFrameCallback, customData);
}
else
{
error = ARCONTROLLER_ERROR_NO_VIDEO;
}
}
if (locked)
{
ARSAL_Mutex_Unlock (&(networkController->mutex));
}
return error;
}
void ARNETWORK_RingBuffer_Print(ARNETWORK_RingBuffer_t *ringBuffer)
{
/* -- Print the state of the ring buffer -- */
ARSAL_Mutex_Lock(&(ringBuffer->mutex));
ARSAL_PRINT(ARSAL_PRINT_WARNING, ARNETWORK_RINGBUFFER_TAG," pointer dataBuffer :%p \n",ringBuffer->dataBuffer);
ARSAL_PRINT(ARSAL_PRINT_WARNING, ARNETWORK_RINGBUFFER_TAG," numberOfCell :%d \n",ringBuffer->numberOfCell);
ARSAL_PRINT(ARSAL_PRINT_WARNING, ARNETWORK_RINGBUFFER_TAG," cellSize :%d \n",ringBuffer->cellSize);
ARSAL_PRINT(ARSAL_PRINT_WARNING, ARNETWORK_RINGBUFFER_TAG," indexOutput :%d \n",ringBuffer->indexOutput);
ARSAL_PRINT(ARSAL_PRINT_WARNING, ARNETWORK_RINGBUFFER_TAG," indexInput :%d \n",ringBuffer->indexInput);
ARSAL_PRINT(ARSAL_PRINT_WARNING, ARNETWORK_RINGBUFFER_TAG," overwriting :%d \n",ringBuffer->isOverwriting);
ARSAL_PRINT(ARSAL_PRINT_WARNING, ARNETWORK_RINGBUFFER_TAG," data : \n");
ARSAL_Mutex_Unlock(&(ringBuffer->mutex));
ARNETWORK_RingBuffer_DataPrint(ringBuffer);
}
int ARNETWORK_Sender_GetPing (ARNETWORK_Sender_t *senderPtr)
{
int retVal = -1;
ARSAL_Mutex_Lock (&(senderPtr->pingMutex));
if (senderPtr->isPingRunning == 1)
{
struct timespec now;
ARSAL_Time_GetTime(&now);
retVal = ARSAL_Time_ComputeTimespecMsTimeDiff (&(senderPtr->pingStartTime), &now);
}
if ((senderPtr->lastPingValue > retVal) ||
(senderPtr->lastPingValue == -1))
{
retVal = senderPtr->lastPingValue;
}
ARSAL_Mutex_Unlock (&(senderPtr->pingMutex));
return retVal;
}
eARCONTROLLER_ERROR ARCONTROLLER_Network_SetVideoStreamMP4Compliant (ARCONTROLLER_Network_t *networkController, int isMP4Compliant)
{
// -- Set video stream compliant with the mp4 format --
eARCONTROLLER_ERROR error = ARCONTROLLER_OK;
int locked = 0;
// Check parameters
if (networkController == NULL)
{
error = ARCONTROLLER_ERROR_BAD_PARAMETER;
}
// No Else: the checking parameters sets error to ARCONTROLLER_ERROR_BAD_PARAMETER and stop the processing
if (error == ARCONTROLLER_OK)
{
if (ARSAL_Mutex_Lock (&(networkController->mutex)) != 0)
{
error = ARCONTROLLER_ERROR_MUTEX;
}
else
{
locked = 1;
}
}
if (error == ARCONTROLLER_OK)
{
// Check if the device has video
if (networkController->hasVideo)
{
error = ARCONTROLLER_Stream_SetMP4Compliant (networkController->videoController, isMP4Compliant);
}
//NO else ; device has not video
}
// No else: skipped by an error
if (locked)
{
ARSAL_Mutex_Unlock (&(networkController->mutex));
}
return error;
}
eARCONTROLLER_ERROR ARCONTROLLER_Network_StartVideoStream (ARCONTROLLER_Network_t *networkController)
{
// -- Start Video stream --
eARCONTROLLER_ERROR error = ARCONTROLLER_OK;
int locked = 0;
// Check parameters
if (networkController == NULL)
{
error = ARCONTROLLER_ERROR_BAD_PARAMETER;
}
// No Else: the checking parameters sets error to ARNETWORK_ERROR_BAD_PARAMETER and stop the processing
if (error == ARCONTROLLER_OK)
{
if (ARSAL_Mutex_Lock (&(networkController->mutex)) != 0)
{
error = ARCONTROLLER_ERROR_MUTEX;
}
else
{
locked = 1;
}
}
if (error == ARCONTROLLER_OK)
{
// Check if the device has video
if (networkController->hasVideo)
{
error = ARCONTROLLER_Stream_Start (networkController->videoController, networkController->networkManager);
}
//NO else ; device has not video
}
// No else: skipped by an error
if (locked)
{
ARSAL_Mutex_Unlock (&(networkController->mutex));
}
return error;
}
eARNETWORK_ERROR ARNETWORK_RingBuffer_PushBackWithSize(ARNETWORK_RingBuffer_t *ringBuffer, const uint8_t *newData, int dataSize, uint8_t **dataCopy)
{
/* -- Add the new data at the back of the ring buffer with specification of the data size -- */
/* local declarations */
int error = ARNETWORK_OK;
uint8_t* buffer = NULL;
ARSAL_Mutex_Lock(&(ringBuffer->mutex));
/* check if the has enough free cell or the buffer is overwriting */
if ((ARNETWORK_RingBuffer_GetFreeCellNumberUnlocked(ringBuffer)) || (ringBuffer->isOverwriting))
{
if (!ARNETWORK_RingBuffer_GetFreeCellNumberUnlocked(ringBuffer))
{
(ringBuffer->indexOutput) += ringBuffer->cellSize;
}
/* No else: the ringBuffer is not full */
buffer = ringBuffer->dataBuffer + ( ringBuffer->indexInput % (ringBuffer->numberOfCell * ringBuffer->cellSize) );
memcpy(buffer, newData, dataSize);
/* return the pointer on the data copy in the ring buffer */
if(dataCopy != NULL)
{
*dataCopy = buffer;
}
/* No else: data are not returned */
ringBuffer->indexInput += ringBuffer->cellSize;
ARNETWORK_RingBuffer_NormalizeIndexes(ringBuffer);
}
else
{
error = ARNETWORK_ERROR_BUFFER_SIZE;
}
ARSAL_Mutex_Unlock(&(ringBuffer->mutex));
return error;
}
ARSTREAM2_H264_AuFifoItem_t* ARSTREAM2_H264_AuFifoDequeueItem(ARSTREAM2_H264_AuFifoQueue_t *queue)
{
ARSTREAM2_H264_AuFifoItem_t* cur;
if (!queue)
{
ARSAL_PRINT(ARSAL_PRINT_ERROR, ARSTREAM2_H264_TAG, "Invalid pointer");
return NULL;
}
ARSAL_Mutex_Lock(&(queue->mutex));
if ((!queue->head) || (!queue->count))
{
ARSAL_Mutex_Unlock(&(queue->mutex));
//ARSAL_PRINT(ARSAL_PRINT_VERBOSE, ARSTREAM2_H264_TAG, "FIFO is empty");
return NULL;
}
cur = queue->head;
if (cur->next)
{
cur->next->prev = NULL;
queue->head = cur->next;
queue->count--;
}
else
{
queue->head = NULL;
queue->count = 0;
queue->tail = NULL;
}
cur->prev = NULL;
cur->next = NULL;
ARSAL_Mutex_Unlock(&(queue->mutex));
return cur;
}
ARSTREAM2_H264_NaluFifoItem_t* ARSTREAM2_H264_NaluFifoDequeueItem(ARSTREAM2_H264_NaluFifo_t *fifo)
{
ARSTREAM2_H264_NaluFifoItem_t* cur;
if (!fifo)
{
ARSAL_PRINT(ARSAL_PRINT_ERROR, ARSTREAM2_H264_TAG, "Invalid pointer");
return NULL;
}
ARSAL_Mutex_Lock(&(fifo->mutex));
if ((!fifo->head) || (!fifo->count))
{
ARSAL_Mutex_Unlock(&(fifo->mutex));
//ARSAL_PRINT(ARSAL_PRINT_VERBOSE, ARSTREAM2_H264_TAG, "NALU FIFO is empty");
return NULL;
}
cur = fifo->head;
if (cur->next)
{
cur->next->prev = NULL;
fifo->head = cur->next;
fifo->count--;
}
else
{
fifo->head = NULL;
fifo->count = 0;
fifo->tail = NULL;
}
cur->prev = NULL;
cur->next = NULL;
ARSAL_Mutex_Unlock(&(fifo->mutex));
return cur;
}
int ARSTREAM2_H264_NaluFifoEnqueueItem(ARSTREAM2_H264_NaluFifo_t *fifo, ARSTREAM2_H264_NaluFifoItem_t *item)
{
if ((!fifo) || (!item))
{
ARSAL_PRINT(ARSAL_PRINT_ERROR, ARSTREAM2_H264_TAG, "Invalid pointer");
return -1;
}
ARSAL_Mutex_Lock(&(fifo->mutex));
if (fifo->count >= fifo->size)
{
ARSAL_Mutex_Unlock(&(fifo->mutex));
ARSAL_PRINT(ARSAL_PRINT_ERROR, ARSTREAM2_H264_TAG, "NALU FIFO is full");
return -2;
}
item->next = NULL;
if (fifo->tail)
{
fifo->tail->next = item;
item->prev = fifo->tail;
}
else
{
item->prev = NULL;
}
fifo->tail = item;
if (!fifo->head)
{
fifo->head = item;
}
fifo->count++;
ARSAL_Mutex_Unlock(&(fifo->mutex));
return 0;
}
int ARSTREAM2_H264_AuFifoUnrefBuffer(ARSTREAM2_H264_AuFifo_t *fifo, ARSTREAM2_H264_AuFifoBuffer_t *buffer)
{
if ((!fifo) || (!buffer))
{
ARSAL_PRINT(ARSAL_PRINT_ERROR, ARSTREAM2_H264_TAG, "Invalid pointer");
return -1;
}
ARSAL_Mutex_Lock(&(fifo->mutex));
if (buffer->refCount != 0)
{
buffer->refCount--;
}
else
{
ARSAL_PRINT(ARSAL_PRINT_WARNING, ARSTREAM2_H264_TAG, "FIXME! Ref count is already null, this should not happen!");
}
if (buffer->refCount == 0)
{
if (fifo->bufferFree)
{
fifo->bufferFree->prev = buffer;
buffer->next = fifo->bufferFree;
}
else
{
buffer->next = NULL;
}
fifo->bufferFree = buffer;
buffer->prev = NULL;
}
ARSAL_Mutex_Unlock(&(fifo->mutex));
return 0;
}
int ARSTREAM2_H264_AuFifoRemoveQueue(ARSTREAM2_H264_AuFifo_t *fifo, ARSTREAM2_H264_AuFifoQueue_t *queue)
{
if ((!fifo) || (!queue))
{
ARSAL_PRINT(ARSAL_PRINT_ERROR, ARSTREAM2_H264_TAG, "Invalid pointer");
return -1;
}
ARSAL_Mutex_Lock(&(fifo->mutex));
if (queue->prev)
{
queue->prev->next = queue->next;
}
if (queue->next)
{
queue->next->prev = queue->prev;
}
if ((!queue->prev) && (!queue->next))
{
fifo->queue = NULL;
}
fifo->queueCount--;
queue->prev = NULL;
queue->next = NULL;
queue->count = 0;
queue->head = NULL;
queue->tail = NULL;
ARSAL_Mutex_Unlock(&(fifo->mutex));
ARSAL_Mutex_Destroy(&(queue->mutex));
return 0;
}
void* ARSTREAM_Reader_RunDataThread (void *ARSTREAM_Reader_t_Param)
{
uint8_t *recvData = NULL;
int recvSize;
uint16_t previousFNum = UINT16_MAX;
int skipCurrentFrame = 0;
int packetWasAlreadyAck = 0;
ARSTREAM_Reader_t *reader = (ARSTREAM_Reader_t *)ARSTREAM_Reader_t_Param;
ARSTREAM_NetworkHeaders_DataHeader_t *header = NULL;
int recvDataLen = reader->maxFragmentSize + sizeof (ARSTREAM_NetworkHeaders_DataHeader_t);
/* Parameters check */
if (reader == NULL)
{
ARSAL_PRINT (ARSAL_PRINT_ERROR, ARSTREAM_READER_TAG, "Error while starting %s, bad parameters", __FUNCTION__);
return (void *)0;
}
/* Alloc and check */
recvData = malloc (recvDataLen);
if (recvData == NULL)
{
ARSAL_PRINT (ARSAL_PRINT_ERROR, ARSTREAM_READER_TAG, "Error while starting %s, can not alloc memory", __FUNCTION__);
return (void *)0;
}
header = (ARSTREAM_NetworkHeaders_DataHeader_t *)recvData;
ARSAL_PRINT (ARSAL_PRINT_DEBUG, ARSTREAM_READER_TAG, "Stream reader thread running");
reader->dataThreadStarted = 1;
while (reader->threadsShouldStop == 0)
{
eARNETWORK_ERROR err = ARNETWORK_Manager_ReadDataWithTimeout (reader->manager, reader->dataBufferID, recvData, recvDataLen, &recvSize, ARSTREAM_READER_DATAREAD_TIMEOUT_MS);
if (ARNETWORK_OK != err)
{
if (ARNETWORK_ERROR_BUFFER_EMPTY != err)
{
ARSAL_PRINT (ARSAL_PRINT_ERROR, ARSTREAM_READER_TAG, "Error while reading stream data: %s", ARNETWORK_Error_ToString (err));
}
}
else
{
int cpIndex, cpSize, endIndex;
ARSAL_Mutex_Lock (&(reader->ackPacketMutex));
if (header->frameNumber != reader->ackPacket.frameNumber)
{
reader->efficiency_index ++;
reader->efficiency_index %= ARSTREAM_READER_EFFICIENCY_AVERAGE_NB_FRAMES;
reader->efficiency_nbTotal [reader->efficiency_index] = 0;
reader->efficiency_nbUseful [reader->efficiency_index] = 0;
skipCurrentFrame = 0;
reader->currentFrameSize = 0;
reader->ackPacket.frameNumber = header->frameNumber;
#ifdef DEBUG
uint32_t nackPackets = ARSTREAM_NetworkHeaders_AckPacketCountNotSet (&(reader->ackPacket), header->fragmentsPerFrame);
if (nackPackets != 0)
{
ARSAL_PRINT (ARSAL_PRINT_DEBUG, ARSTREAM_READER_TAG, "Dropping a frame (missing %d fragments)", nackPackets);
}
#endif
ARSTREAM_NetworkHeaders_AckPacketResetUpTo (&(reader->ackPacket), header->fragmentsPerFrame);
}
packetWasAlreadyAck = ARSTREAM_NetworkHeaders_AckPacketFlagIsSet (&(reader->ackPacket), header->fragmentNumber);
ARSTREAM_NetworkHeaders_AckPacketSetFlag (&(reader->ackPacket), header->fragmentNumber);
reader->efficiency_nbTotal [reader->efficiency_index] ++;
if (packetWasAlreadyAck == 0)
{
reader->efficiency_nbUseful [reader->efficiency_index] ++;
}
ARSAL_Mutex_Unlock (&(reader->ackPacketMutex));
ARSAL_Mutex_Lock (&(reader->ackSendMutex));
ARSAL_Cond_Signal (&(reader->ackSendCond));
ARSAL_Mutex_Unlock (&(reader->ackSendMutex));
cpIndex = reader->maxFragmentSize * header->fragmentNumber;
cpSize = recvSize - sizeof (ARSTREAM_NetworkHeaders_DataHeader_t);
endIndex = cpIndex + cpSize;
while ((endIndex > reader->currentFrameBufferSize) &&
(skipCurrentFrame == 0) &&
(packetWasAlreadyAck == 0))
{
uint32_t nextFrameBufferSize = reader->maxFragmentSize * header->fragmentsPerFrame;
uint32_t dummy;
uint8_t *nextFrameBuffer = reader->callback (ARSTREAM_READER_CAUSE_FRAME_TOO_SMALL, reader->currentFrameBuffer, reader->currentFrameSize, 0, 0, &nextFrameBufferSize, reader->custom);
if (nextFrameBufferSize >= reader->currentFrameSize && nextFrameBufferSize > 0)
{
memcpy (nextFrameBuffer, reader->currentFrameBuffer, reader->currentFrameSize);
}
else
{
skipCurrentFrame = 1;
}
//TODO: Add "SKIP_FRAME"
reader->callback (ARSTREAM_READER_CAUSE_COPY_COMPLETE, reader->currentFrameBuffer, reader->currentFrameSize, 0, skipCurrentFrame, &dummy, reader->custom);
reader->currentFrameBuffer = nextFrameBuffer;
reader->currentFrameBufferSize = nextFrameBufferSize;
}
if (skipCurrentFrame == 0)
{
if (packetWasAlreadyAck == 0)
{
memcpy (&(reader->currentFrameBuffer)[cpIndex], &recvData[sizeof (ARSTREAM_NetworkHeaders_DataHeader_t)], recvSize - sizeof (ARSTREAM_NetworkHeaders_DataHeader_t));
}
if (endIndex > reader->currentFrameSize)
{
reader->currentFrameSize = endIndex;
}
ARSAL_Mutex_Lock (&(reader->ackPacketMutex));
if (ARSTREAM_NetworkHeaders_AckPacketAllFlagsSet (&(reader->ackPacket), header->fragmentsPerFrame))
{
if (header->frameNumber != previousFNum)
{
int nbMissedFrame = 0;
int isFlushFrame = ((header->frameFlags & ARSTREAM_NETWORK_HEADERS_FLAG_FLUSH_FRAME) != 0) ? 1 : 0;
ARSAL_PRINT (ARSAL_PRINT_DEBUG, ARSTREAM_READER_TAG, "Ack all in frame %d (isFlush : %d)", header->frameNumber, isFlushFrame);
if (header->frameNumber != previousFNum + 1)
{
nbMissedFrame = header->frameNumber - previousFNum - 1;
ARSAL_PRINT (ARSAL_PRINT_DEBUG, ARSTREAM_READER_TAG, "Missed %d frames !", nbMissedFrame);
}
previousFNum = header->frameNumber;
skipCurrentFrame = 1;
reader->currentFrameBuffer = reader->callback (ARSTREAM_READER_CAUSE_FRAME_COMPLETE, reader->currentFrameBuffer, reader->currentFrameSize, nbMissedFrame, isFlushFrame, &(reader->currentFrameBufferSize), reader->custom);
}
}
ARSAL_Mutex_Unlock (&(reader->ackPacketMutex));
}
}
}
free (recvData);
reader->callback (ARSTREAM_READER_CAUSE_CANCEL, reader->currentFrameBuffer, reader->currentFrameSize, 0, 0, &(reader->currentFrameBufferSize), reader->custom);
ARSAL_PRINT (ARSAL_PRINT_DEBUG, ARSTREAM_READER_TAG, "Stream reader thread ended");
reader->dataThreadStarted = 0;
return (void *)0;
}
