Hu Chunming / FFNvDecoder

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3rdparty/jrtplib-3.11.2/examples/example5.cpp 4.63 KB
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3d2ab595   Hu Chunming   支持gb28181 
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  /*
     This is a modified version of example1.cpp to illustrate the use of a memory
     manager.
  */
  
  #include "rtpsession.h"
  #include "rtppacket.h"
  #include "rtpudpv4transmitter.h"
  #include "rtpipv4address.h"
  #include "rtpsessionparams.h"
  #include "rtperrors.h"
  #include "rtpmemorymanager.h"
  #include <stdlib.h>
  #include <stdio.h>
  #include <iostream>
  #include <string>
  
  using namespace jrtplib;
  
  //
  // This function checks if there was a RTP error. If so, it displays an error
  // message and exists.
  //
  
  void checkerror(int rtperr)
  {
  	if (rtperr < 0)
  	{
  		std::cout << "ERROR: " << RTPGetErrorString(rtperr) << std::endl;
  		exit(-1);
  	}
  }
  
  //
  // The main routine
  //
  
  #ifdef RTP_SUPPORT_THREAD
  
  using namespace jthread;
  
  class MyMemoryManager : public RTPMemoryManager
  {
  public:
  	MyMemoryManager() 
  	{ 
  		mutex.Init();
  		alloccount = 0; 
  		freecount = 0; 
  	}
  	~MyMemoryManager() 
  	{ 
  		std::cout << "alloc: " << alloccount << " free: " << freecount << std::endl; 
  	}
  	void *AllocateBuffer(size_t numbytes, int memtype)
  	{
  		mutex.Lock();
  		void *buf = malloc(numbytes);
  		std::cout << "Allocated " << numbytes << " bytes at location " << buf << " (memtype = " << memtype << ")" << std::endl;
  		alloccount++;
  		mutex.Unlock();
  		return buf;
  	}
  
  	void FreeBuffer(void *p)
  	{
  		mutex.Lock();
  		std::cout << "Freeing block " << p << std::endl;
  		freecount++;
  		free(p);
  		mutex.Unlock();
  	}
  private:
  	int alloccount,freecount;
  	JMutex mutex;
  };
  
  #else
  
  class MyMemoryManager : public RTPMemoryManager
  {
  public:
  	MyMemoryManager() 
  	{ 
  		alloccount = 0; 
  		freecount = 0; 
  	}
  	~MyMemoryManager() 
  	{ 
  		std::cout << "alloc: " << alloccount << " free: " << freecount << std::endl; 
  	}
  	void *AllocateBuffer(size_t numbytes, int memtype)
  	{
  		void *buf = malloc(numbytes);
  		std::cout << "Allocated " << numbytes << " bytes at location " << buf << " (memtype = " << memtype << ")" << std::endl;
  		alloccount++;
  		return buf;
  	}
  
  	void FreeBuffer(void *p)
  	{
  		std::cout << "Freeing block " << p << std::endl;
  		freecount++;
  		free(p);
  	}
  private:
  	int alloccount,freecount;
  };
  
  #endif // RTP_SUPPORT_THREAD
  
  int main(void)
  {
  #ifdef RTP_SOCKETTYPE_WINSOCK
  	WSADATA dat;
  	WSAStartup(MAKEWORD(2,2),&dat);
  #endif // RTP_SOCKETTYPE_WINSOCK
  	
  	MyMemoryManager mgr;
  	RTPSession sess(0, &mgr);
  	uint16_t portbase,destport;
  	uint32_t destip;
  	std::string ipstr;
  	int status,i,num;
  
          // First, we'll ask for the necessary information
  		
  	std::cout << "Enter local portbase:" << std::endl;
  	std::cin >> portbase;
  	std::cout << std::endl;
  	
  	std::cout << "Enter the destination IP address" << std::endl;
  	std::cin >> ipstr;
  	destip = inet_addr(ipstr.c_str());
  	if (destip == INADDR_NONE)
  	{
  		std::cerr << "Bad IP address specified" << std::endl;
  		return -1;
  	}
  	
  	// The inet_addr function returns a value in network byte order, but
  	// we need the IP address in host byte order, so we use a call to
  	// ntohl
  	destip = ntohl(destip);
  	
  	std::cout << "Enter the destination port" << std::endl;
  	std::cin >> destport;
  	
  	std::cout << std::endl;
  	std::cout << "Number of packets you wish to be sent:" << std::endl;
  	std::cin >> num;
  	
  	// Now, we'll create a RTP session, set the destination, send some
  	// packets and poll for incoming data.
  	
  	RTPUDPv4TransmissionParams transparams;
  	RTPSessionParams sessparams;
  	
  	// IMPORTANT: The local timestamp unit MUST be set, otherwise
  	//            RTCP Sender Report info will be calculated wrong
  	// In this case, we'll be sending 10 samples each second, so we'll
  	// put the timestamp unit to (1.0/10.0)
  	sessparams.SetOwnTimestampUnit(1.0/10.0);		
  	
  	sessparams.SetAcceptOwnPackets(true);
  	transparams.SetPortbase(portbase);
  	status = sess.Create(sessparams,&transparams);	
  	checkerror(status);
  	
  	RTPIPv4Address addr(destip,destport);
  	
  	status = sess.AddDestination(addr);
  	checkerror(status);
  	
  	for (i = 1 ; i <= num ; i++)
  	{
  		printf("\nSending packet %d/%d\n",i,num);
  		
  		// send the packet
  		status = sess.SendPacket((void *)"1234567890",10,0,false,10);
  		checkerror(status);
  		
  		sess.BeginDataAccess();
  		
  		// check incoming packets
  		if (sess.GotoFirstSourceWithData())
  		{
  			do
  			{
  				RTPPacket *pack;
  				
  				while ((pack = sess.GetNextPacket()) != NULL)
  				{
  					// You can examine the data here
  					printf("Got packet !\n");
  					
  					// we don't longer need the packet, so
  					// we'll delete it
  					sess.DeletePacket(pack);
  				}
  			} while (sess.GotoNextSourceWithData());
  		}
  		
  		sess.EndDataAccess();
  
  #ifndef RTP_SUPPORT_THREAD
  		status = sess.Poll();
  		checkerror(status);
  #endif // RTP_SUPPORT_THREAD
  		
  		RTPTime::Wait(RTPTime(1,0));
  	}
  	
  	sess.BYEDestroy(RTPTime(10,0),0,0);
  
  #ifdef RTP_SOCKETTYPE_WINSOCK
  	WSACleanup();
  #endif // RTP_SOCKETTYPE_WINSOCK
  	return 0;
  }