Esempio n. 1
0
// Handle the FLOWGRAPH_ENABLE message.
// Returns TRUE if the message was handled, otherwise FALSE.
UtlBoolean MpFlowGraphBase::handleEnable(void)
{
   int            i;
   MpFlowGraphMsg msg(MpFlowGraphMsg::RESOURCE_ENABLE);
   MpResource*    pResource;

   // iterate over all resources
   // invoke the enable() method for each resource in the flow graph
   for (i=0; i < mResourceCnt; i++)
   {
      // iterate through the resources
      pResource = mUnsorted[i];

      // make each resource handle a RESOURCE_ENABLE message
      msg.setMsgDest(pResource);
      if (!pResource->handleMessage(msg))
      {
         assert(FALSE);
         return FALSE;
      }
   }

   return TRUE;
}
Esempio n. 2
0
// Handle the FLOWGRAPH_SET_SAMPLES_PER_SEC message.
// Returns TRUE if the message was handled, otherwise FALSE.
UtlBoolean MpFlowGraphBase::handleSetSamplesPerSec(int samplesPerSec)
{
   int            i;
   MpFlowGraphMsg msg(MpFlowGraphMsg::RESOURCE_SET_SAMPLES_PER_SEC,
                      NULL, NULL, NULL, samplesPerSec);
   MpResource*    pResource;

   // iterate over all resources
   for (i=0; i < mResourceCnt; i++)
   {
      pResource = mUnsorted[i];

      // make each resource handle a SET_SAMPLES_PER_SEC message
      msg.setMsgDest(pResource);
      if (!pResource->handleMessage(msg))
      {
         assert(FALSE);
         return FALSE;
      }
   }

   mSamplesPerSec = samplesPerSec;
   return TRUE;
}
Esempio n. 3
0
// Processes all of the messages currently queued for this flow graph.
// For now, this method always returns OS_SUCCESS.
OsStatus MpFlowGraphBase::processMessages(void)
{
   OsWriteLock     lock(mRWMutex);

   UtlBoolean       done;
   UtlBoolean       handled;
   static MpFlowGraphMsg* pStopMsg = NULL;
   MpResource*     pMsgDest;

   OsStatus        res;

   // First, we send ourselves a FLOWGRAPH_PROCESS_FRAME message.
   // This message serves as a "stopper" in the message queue.  When we
   // handle that message, we know that we have processed all of the messages
   // for the flowgraph (and its resources) that had arrived prior to the
   // start of this frame processing interval.

   if (NULL == pStopMsg) {
      pStopMsg = new MpFlowGraphMsg(MpFlowGraphMsg::FLOWGRAPH_PROCESS_FRAME);
      pStopMsg->setReusable(TRUE);
   }

   res = postMessage(*pStopMsg);
   assert(res == OS_SUCCESS);

   done = FALSE;
   while (!done)
   {
      // get the next message
      OsMsg* pMsg ;

      res = mMessages.receive(pMsg, OsTime::NO_WAIT);

      assert(res == OS_SUCCESS);

      if (pMsg->getMsgType() == OsMsg::MP_FLOWGRAPH_MSG)
      {
         MpFlowGraphMsg* pRcvdMsg = (MpFlowGraphMsg*) pMsg ;
         // determine if this message is intended for a resource in the
         // flow graph (as opposed to a message for the flow graph itself)
         pMsgDest = pRcvdMsg->getMsgDest();


         if (pMsgDest != NULL)
         {
            // deliver the message if the resource is still part of this graph
            if (pMsgDest->getFlowGraph() == this)
            {
               handled = pMsgDest->handleMessage(*pRcvdMsg);
               assert(handled);
            }
         }
         else
         {
            // since pMsgDest is NULL, this msg is intended for the flow graph
            switch (pRcvdMsg->getMsg())
            {
            case MpFlowGraphMsg::FLOWGRAPH_PROCESS_FRAME:
               done = TRUE;    // "stopper" message encountered -- we are done
               break;          //  processing messages for this frame interval

            default:
               handled = handleMessage(*pRcvdMsg);
               assert(handled);
               break;
            }
         }
         pRcvdMsg->releaseMsg();    // free the msg
      }
      else
      {
         handled = handleMessage(*pMsg);
         assert(handled);
         pMsg->releaseMsg() ;
      }

   }

   return OS_SUCCESS;
}