cml
/
libcm
Beobachten 1
Favorisieren 0
Fork 0
Code Issues 0 Pull-Requests 0 Releases 0 Wiki Aktivität
libcm is a C development framework with an emphasis on audio signal processing applications.
Du kannst nicht mehr als 25 Themen auswählen Themen müssen mit entweder einem Buchstaben oder einer Ziffer beginnen. Sie können Bindestriche („-“) enthalten und bis zu 35 Zeichen lang sein.
6 Commits
1 Branch
Struktur: f1e70ee42a
Branches Tags
${ item.name }
Erstelle Branch ${ searchTerm }
von „f1e70ee42a“
${ noResults }
libcm/cmUdpPort.c

cmUdpPort.c 14KB
Verlauf Originalformat

123456789101112131415161718192021222324252627282930313233343536373839404142434445464748495051525354555657585960616263646566676869707172737475767778798081828384858687888990919293949596979899100101102103104105106107108109110111112113114115116117118119120121122123124125126127128129130131132133134135136137138139140141142143144145146147148149150151152153154155156157158159160161162163164165166167168169170171172173174175176177178179180181182183184185186187188189190191192193194195196197198199200201202203204205206207208209210211212213214215216217218219220221222223224225226227228229230231232233234235236237238239240241242243244245246247248249250251252253254255256257258259260261262263264265266267268269270271272273274275276277278279280281282283284285286287288289290291292293294295296297298299300301302303304305306307308309310311312313314315316317318319320321322323324325326327328329330331332333334335336337338339340341342343344345346347348349350351352353354355356357358359360361362363364365366367368369370371372373374375376377378379380381382383384385386387388389390391392393394395396397398399400401402403404405406407408409410411412413414415416417418419420421422423424425426427428429430431432433434435436437438439440441442443444445446447448449450451452453454455456457458459460461462463464465466467468469470471472473474475476477478479480481482483484485486487488489490491492493494495496497498499500501502503504505506507508509510511512513514515516517518519520521522523524525526527528529530531532533534535536537538539540541542543544545546547 
  1. #include "cmPrefix.h"

  2. #include "cmGlobal.h"

  3. #include "cmRpt.h"

  4. #include "cmErr.h"

  5. #include "cmCtx.h"

  6. #include "cmMem.h"

  7. #include "cmMallocDebug.h"

  8. #include "cmThread.h"

  9. 

  10. #include <sys/socket.h> 

  11. #include <netinet/in.h>	

  12. #include <arpa/inet.h>	

  13. #include <fcntl.h>		

  14. #include <unistd.h>  // close

  15. 

  16. #include "cmUdpPort.h"

  17. 

  18. #define cmUdp_SYS_ERR (-1)

  19. #define cmUdp_NULL_SOCK (-1)

  20. 

  21. enum

  22. {

  23.   kIsConnectedUdpFl = 0x01,

  24.   kIsBlockingUdpFl  = 0x02,

  25.   kQueueingUdpFl    = 0x04

  26. };

  27. 

  28. 

  29. typedef struct 

  30. {

  31.   cmErr_t         err;

  32.   int             sockH;

  33.   cmUdpCallback_t cbFunc;

  34.   void*           cbArg;

  35.   unsigned        timeOutMs;

  36.   unsigned        flags;

  37.   cmThreadH_t     thH;

  38.   cmTs1p1cH_t     qH;

  39.   unsigned        recvBufByteCnt;

  40.   char*           tempBuf;

  41.   unsigned        timeOutCnt;

  42.   unsigned        recvCnt;

  43.   unsigned        queCbCnt;

  44.   unsigned        errCnt;

  45. } cmUdp_t;

  46. 

  47. cmUdpH_t cmUdpNullHandle = cmSTATIC_NULL_HANDLE;

  48. 

  49. #define _cmUdpClear_errno() errno = 0

  50. 

  51. cmUdp_t* _cmUdpHandleToPtr( cmUdpH_t h )

  52. {

  53.   cmUdp_t* p = (cmUdp_t*)h.h;

  54.   assert(p != NULL);

  55.   return p;

  56. }

  57. 

  58. cmUdpRC_t _cmUdpFinal( cmUdp_t* p )

  59. {

  60.   cmUdpRC_t rc = kOkUdpRC;

  61. 

  62.   if( cmThreadIsValid(p->thH) )

  63.     if( cmThreadDestroy(&p->thH) != kOkThRC )

  64.       return cmErrMsg(&p->err,kThreadFailUdpRC,"Listener thread destroy failed.");

  65. 

  66.   if( cmTs1p1cIsValid(p->qH) )

  67.     if( cmTs1p1cDestroy(&p->qH) != kOkThRC )

  68.       cmErrMsg(&p->err,kQueueFailUdpRC,"Receive data queue destroy failed.");

  69. 

  70.   cmMemPtrFree(&p->tempBuf);

  71. 

  72.   // close the socket		

  73. 	if( p->sockH != cmUdp_NULL_SOCK )

  74. 	{

  75.     _cmUdpClear_errno();

  76. 		if( close(p->sockH) != 0 )

  77. 			cmErrSysMsg(&p->err,kSockCloseFailUdpRC,errno,"The socket close failed." );

  78. 			

  79. 		p->sockH = cmUdp_NULL_SOCK;		

  80. 	}

  81. 

  82. 

  83.   return rc;

  84. }

  85. 

  86. cmUdpRC_t _cmUdpFree( cmUdp_t* p )

  87. {

  88.   cmUdpRC_t rc;

  89.   if((rc = _cmUdpFinal(p)) != kOkUdpRC )

  90.     return rc;

  91. 

  92.   cmMemFree(p);

  93.   return rc;  

  94. }

  95. 

  96. cmUdpRC_t _cmUdpInitAddr( cmUdp_t* p, const char* addrStr, cmUdpPort_t portNumber, struct sockaddr_in* retAddrPtr )

  97. {

  98. 	memset(retAddrPtr,0,sizeof(struct sockaddr_in));

  99. 	

  100. 	if( addrStr == NULL )

  101. 		retAddrPtr->sin_addr.s_addr 	= htonl(INADDR_ANY);

  102. 	else

  103. 	{

  104.     _cmUdpClear_errno();

  105. 

  106. 		if(inet_pton(AF_INET,addrStr,&retAddrPtr->sin_addr) == 0 )

  107.       //if(( retAddrPtr->sin_addr.s_addr 	= inet_addr(addrStr)) == INADDR_NONE )

  108. 			return cmErrSysMsg(&p->err,kPtoNFailUdpRC,errno, "The network address string '%s' could not be converted to a netword address structure.",cmStringNullGuard(addrStr) );

  109. 	}

  110. 	

  111. 	//retAddrPtr->sin_len 			= sizeof(struct sockaddr_in);

  112. 	retAddrPtr->sin_family 		= AF_INET;

  113. 	retAddrPtr->sin_port 			= htons(portNumber);

  114. 	

  115. 	return kOkUdpRC;	

  116. }

  117. 

  118. cmUdpRC_t _cmUdpConnect( cmUdp_t* p, const char* remoteAddr, cmUdpPort_t remotePort )

  119. {

  120.   struct sockaddr_in addr;

  121.   cmUdpRC_t          rc;

  122. 

  123.   // create the remote address		

  124.   if((rc = _cmUdpInitAddr(p, remoteAddr, remotePort,  &addr )) != kOkUdpRC )

  125.     return rc;

  126. 		

  127.   _cmUdpClear_errno();

  128. 

  129.   // ... and connect this socket to the remote address/port

  130.   if( connect(p->sockH, (struct sockaddr*)&addr, sizeof(addr)) == cmUdp_SYS_ERR )

  131.     return cmErrSysMsg(&p->err,kSockConnectFailUdpRC, errno, "Socket connect failed." );

  132. 

  133.   p->flags = cmSetFlag(p->flags,kIsConnectedUdpFl);

  134. 

  135.   return rc;

  136. }

  137. 

  138. cmUdpRC_t cmUdpAlloc( cmCtx_t* ctx, cmUdpH_t* hp )

  139. {

  140.   cmUdpRC_t rc;

  141. 

  142.   if((rc = cmUdpFree(hp)) != kOkUdpRC )

  143.     return rc;

  144. 

  145.   cmUdp_t* p = cmMemAllocZ(cmUdp_t,1);

  146. 

  147.   cmErrSetup(&p->err,&ctx->rpt,"UDP Port");

  148. 

  149.   p->sockH = cmUdp_NULL_SOCK;

  150. 

  151.   hp->h = p;

  152. 

  153.   return rc;

  154. }

  155. 

  156. cmUdpRC_t cmUdpFree( cmUdpH_t* hp )

  157. {

  158.   cmUdpRC_t rc = kOkUdpRC;

  159.    

  160.   if( hp == NULL || cmUdpIsValid(*hp)==false)

  161.     return rc;

  162. 

  163.   cmUdp_t* p = _cmUdpHandleToPtr(*hp);

  164. 

  165.   if((rc = _cmUdpFree(p)) != kOkUdpRC )

  166.     return rc;

  167. 

  168.   hp->h = NULL;

  169.     

  170.   return rc;

  171. }

  172. 

  173. 

  174. 

  175. cmUdpRC_t cmUdpInit( 

  176.   cmUdpH_t       h, 

  177.   cmUdpPort_t     port,

  178.   unsigned        flags,

  179.   cmUdpCallback_t cbFunc, 

  180.   void*           cbArg,

  181.   const char*     remoteAddr,

  182.   cmUdpPort_t     remotePort,

  183.   unsigned        recvBufByteCnt,

  184.   unsigned        timeOutMs )

  185. {

  186.   cmUdpRC_t rc;

  187. 

  188.   struct sockaddr_in 	addr;

  189. 

  190.   cmUdp_t* p = _cmUdpHandleToPtr(h);

  191. 

  192.   if((rc = _cmUdpFinal(p)) != kOkUdpRC )

  193.     return rc;

  194. 

  195.   _cmUdpClear_errno();

  196. 

  197.   // get a handle to the socket

  198.   if(( p->sockH = socket( AF_INET, SOCK_DGRAM, IPPROTO_UDP ) ) == cmUdp_SYS_ERR )

  199.     return cmErrSysMsg(&p->err, kSockCreateFailUdpRC, errno, "Socket create failed." );	 

  200. 	

  201.   // create the local address		

  202.   if((rc = _cmUdpInitAddr(p, NULL, port,  &addr )) != kOkUdpRC )

  203.     goto errLabel;

  204. 			

  205.   // bind the socket to a local address/port	

  206.   if( (bind( p->sockH, (struct sockaddr*)&addr, sizeof(addr))) == cmUdp_SYS_ERR )

  207.   {

  208.     rc = cmErrSysMsg(&p->err,kSockBindFailUdpRC,errno,"Socket bind failed." );

  209.     goto errLabel;

  210.   }

  211. 

  212.   // if a remote addr was given connect this socket to it

  213.   if( remoteAddr != NULL )

  214.     if((rc = _cmUdpConnect(p,remoteAddr,remotePort)) != kOkUdpRC )

  215.       goto errLabel;

  216. 

  217.   // if this socket should block

  218.   if( cmIsFlag(flags,kBlockingUdpFl) )

  219.   {

  220.     struct timeval 		timeOut;

  221.     

  222.     // set the socket time out 

  223.     timeOut.tv_sec 	= timeOutMs/1000;

  224.     timeOut.tv_usec = (timeOutMs - (timeOut.tv_sec * 1000)) * 1000;

  225. 		

  226.     if( setsockopt( p->sockH, SOL_SOCKET, SO_RCVTIMEO, &timeOut, sizeof(timeOut) ) == cmUdp_SYS_ERR )

  227.     {

  228.       rc = cmErrSysMsg(&p->err,kSockOptSetFailUdpRC,errno, "Attempt to set the socket timeout failed." );

  229.       goto errLabel;

  230.     }

  231. 

  232.     p->flags = cmSetFlag(p->flags,kIsBlockingUdpFl);

  233. 

  234.   }

  235.   else

  236.   {

  237. 

  238.     int opts;

  239. 		

  240.     // get the socket options flags

  241.     if( (opts = fcntl(p->sockH,F_GETFL)) < 0 )

  242.     {

  243.       rc = cmErrSysMsg(&p->err,kSockOptSetFailUdpRC,errno, "Attempt to get the socket options flags failed." );

  244.       goto errLabel;

  245.     }

  246. 	    

  247.     opts = (opts | O_NONBLOCK);

  248. 		

  249.     // set the socket options flags

  250.     if(fcntl(p->sockH,F_SETFL,opts) < 0) 

  251.     {

  252.       rc = cmErrSysMsg(&p->err,kSockOptSetFailUdpRC,errno, "Attempt to set the socket to non-blocking failed." );

  253.       goto errLabel;

  254.     }	    

  255. 

  256.   }

  257. 

  258.   if( recvBufByteCnt != 0 )

  259.     p->tempBuf = cmMemAlloc(char,recvBufByteCnt );

  260. 

  261.   p->timeOutMs      = timeOutMs;

  262.   p->cbFunc         = cbFunc;

  263.   p->cbArg          = cbArg;

  264.   p->recvBufByteCnt = recvBufByteCnt;

  265.   p->timeOutCnt     = 0;

  266.   p->recvCnt        = 0;

  267.   p->queCbCnt       = 0;

  268.   p->errCnt         = 0;

  269. 

  270.   if( cmIsFlag(flags,kNoQueueUdpFl) == false )

  271.     p->flags = cmSetFlag(p->flags,kQueueingUdpFl);

  272. 

  273.  errLabel:

  274.   if( rc != kOkUdpRC )

  275.     _cmUdpFree(p);

  276. 

  277.   return rc;

  278. }

  279. 

  280. cmUdpRC_t cmUdpFinal( cmUdpH_t h )

  281. {

  282.   cmUdp_t* p = _cmUdpHandleToPtr(h);

  283.   return _cmUdpFinal(p);

  284. }

  285. 

  286. bool      cmUdpIsValid( cmUdpH_t h )

  287. { return h.h != NULL; }

  288. 

  289. 

  290. cmUdpRC_t cmUdpConnect( cmUdpH_t h, const char* remoteAddr, cmUdpPort_t remotePort )

  291. {

  292.   cmUdp_t* p = _cmUdpHandleToPtr(h);

  293.   return _cmUdpConnect(p,remoteAddr,remotePort);

  294. }

  295. 

  296. cmUdpRC_t cmUdpSend(    cmUdpH_t h, const char* data, unsigned dataByteCnt )

  297. {

  298.   cmUdp_t* p = _cmUdpHandleToPtr(h);

  299. 

  300.   _cmUdpClear_errno();

  301. 

  302.   if( cmIsFlag(p->flags,kIsConnectedUdpFl) == false )

  303.     return cmErrMsg(&p->err,kNotConnectedUdpRC,"cmUdpSend() only works with connected sockets.");

  304. 

  305.   if( send( p->sockH, data, dataByteCnt, 0 ) == cmUdp_SYS_ERR )

  306.     return cmErrSysMsg(&p->err,kSockSendFailUdpRC,errno,"Send failed.");

  307. 

  308.   return kOkUdpRC;

  309. }

  310. 

  311. cmUdpRC_t cmUdpSendTo(  cmUdpH_t h, const char* data, unsigned dataByteCnt, const struct sockaddr_in* remoteAddr )

  312. {

  313.   cmUdp_t* p = _cmUdpHandleToPtr(h);

  314.   

  315.   _cmUdpClear_errno();

  316.    

  317.   if( sendto(p->sockH, data, dataByteCnt, 0, (struct sockaddr*)remoteAddr, sizeof(*remoteAddr)) == cmUdp_SYS_ERR )

  318.     return cmErrSysMsg(&p->err,kSockSendFailUdpRC,errno,"SendTo failed.");

  319. 

  320.   return kOkUdpRC;

  321. }

  322. 

  323. cmUdpRC_t cmUdpSend2(  cmUdpH_t h, const char* data, unsigned dataByteCnt, const char* remoteAddr, cmUdpPort_t remotePort )

  324. {

  325.   cmUdpRC_t rc;

  326.   cmUdp_t* p = _cmUdpHandleToPtr(h);

  327.   struct sockaddr_in addr;

  328. 

  329.   if((rc = _cmUdpInitAddr(p,remoteAddr,remotePort,&addr)) != kOkUdpRC )

  330.     return rc;

  331.   

  332.   return cmUdpSendTo( h, data, dataByteCnt, &addr );

  333. }

  334. 

  335. cmUdpRC_t cmUdpRecv(    cmUdpH_t h, char* data, unsigned dataByteCnt, struct sockaddr_in* fromAddr, unsigned* recvByteCntPtr )

  336. {

  337.   cmUdp_t*  p                = _cmUdpHandleToPtr(h);

  338.   cmUdpRC_t rc               = kOkUdpRC;

  339.   ssize_t   retVal           = 0;

  340. 	socklen_t sizeOfRemoteAddr = fromAddr==NULL ? 0 : sizeof(struct sockaddr_in);

  341. 	

  342.   _cmUdpClear_errno();

  343. 

  344.   if( recvByteCntPtr != NULL )

  345.     *recvByteCntPtr = 0;

  346. 	

  347. 	if((retVal = recvfrom(p->sockH, data, dataByteCnt, 0, (struct sockaddr*)fromAddr, &sizeOfRemoteAddr )) == cmUdp_SYS_ERR )

  348.     return cmErrSysMsg(&p->err,kSockRecvFailUdpRC,errno,"recvFrom() failed.");

  349. 	

  350.   if( recvByteCntPtr != NULL )

  351.     *recvByteCntPtr = retVal;

  352. 

  353.   return rc;

  354. }

  355. 

  356. bool _cmUdpThreadCb(void* param)

  357. {

  358.   cmUdp_t*              p = (cmUdp_t*)param;

  359. 	fd_set                rdSet;

  360. 	struct timeval        timeOut;

  361. 

  362.   // setup the select() call

  363.   FD_ZERO(&rdSet);

  364.   FD_SET(p->sockH, &rdSet );

  365. 		

  366.   timeOut.tv_sec 	= p->timeOutMs/1000;

  367.   timeOut.tv_usec = (p->timeOutMs - (timeOut.tv_sec * 1000)) * 1000;

  368. 	

  369.   // NOTE; select() takes the highest socket value plus one of all the sockets in all the sets.

  370. 		

  371.   switch( select(p->sockH+1,&rdSet,NULL,NULL,&timeOut) )

  372.   {

  373.     case -1: 	// error

  374.       if( errno != EINTR )

  375.         cmErrSysMsg(&p->err,kSockSelectFailUdpRC,errno,"Select failed.");

  376.       ++p->errCnt;

  377.       break;

  378. 			

  379.     case 0: 	// select() timed out	

  380.       ++p->timeOutCnt;

  381.       break;

  382. 			

  383.     case 1: 	// (> 0) count of ready descripters

  384.       if( FD_ISSET(p->sockH,&rdSet) )

  385.       {

  386.         struct	sockaddr_in remoteAddr;

  387.         socklen_t           addrByteCnt = sizeof(remoteAddr);

  388.         ssize_t             retByteCnt;

  389. 

  390.         _cmUdpClear_errno();

  391. 

  392.         ++p->recvCnt;

  393. 

  394.         // recv the incoming msg into p->tempBuf[]

  395.         if(( retByteCnt = recvfrom( p->sockH, p->tempBuf, p->recvBufByteCnt, 0, (struct sockaddr*)&remoteAddr, &addrByteCnt )) == cmUdp_SYS_ERR )

  396.           cmErrSysMsg(&p->err,kSockRecvFailUdpRC,errno,"recvfrom() failed.");

  397.         else

  398.         {

  399.           // check for overflow

  400.           if( retByteCnt == p->recvBufByteCnt )

  401.             cmErrMsg(&p->err,kRecvBufOverflowUdpRC,"The receive buffer requires more than %i bytes.",p->recvBufByteCnt);

  402.           else

  403.           {

  404.             // if queueing is enabled

  405.             if( cmIsFlag(p->flags,kQueueingUdpFl ) )

  406.             {

  407.               // enqueue the msg - with the source address appended after the data

  408.               const void*    msgPtrArray[]     = { p->tempBuf, &remoteAddr, p->tempBuf };

  409.               unsigned msgByteCntArray[] = { retByteCnt, sizeof(remoteAddr)  };

  410.               if( cmTs1p1cEnqueueSegMsg( p->qH, msgPtrArray, msgByteCntArray, 2 ) != kOkThRC )

  411.                 cmErrMsg(&p->err,kQueueFailUdpRC,"A received msg containing %i bytes was not queued.",retByteCnt);

  412.             }

  413.             else // if queueing is not enabled - transmit the data directly via the callback

  414.               if( p->cbFunc != NULL )

  415.               {

  416.                 p->cbFunc(p->cbArg,p->tempBuf,retByteCnt,&remoteAddr);

  417.               }

  418.           }

  419.         }					

  420.       }	

  421.       break;

  422. 			

  423.     default:

  424.       { assert(0); }

  425.   } // switch

  426. 

  427. 

  428.   return true;

  429. }

  430. 

  431. cmRC_t _cmUdpQueueCb(void* userCbPtr, unsigned msgByteCnt, const void* msgDataPtr )

  432. {

  433.   cmUdp_t* p = (cmUdp_t*)userCbPtr;

  434. 

  435.   if( p->cbFunc != NULL )

  436.   {

  437.     struct sockaddr_in addr;

  438. 

  439.     assert( msgByteCnt >= sizeof(addr));

  440. 

  441.     const char* dataPtr = (const char*)msgDataPtr;

  442. 

  443.     // the address of the data source is apppended to the data bytes.

  444.     const char* addrPtr = dataPtr + msgByteCnt - sizeof(addr);

  445.     memcpy(&addr,addrPtr,sizeof(addr));  

  446. 

  447.     // make the receive callback

  448.     p->cbFunc(p->cbArg,dataPtr,msgByteCnt-sizeof(addr),&addr);

  449. 

  450.     ++p->queCbCnt;

  451.   }

  452. 

  453.   return cmOkRC;

  454. }

  455. 

  456. cmUdpRC_t cmUdpEnableListen( cmUdpH_t h, bool enableFl )

  457. {

  458.   cmUdp_t* p = _cmUdpHandleToPtr(h);

  459. 

  460.   if( cmThreadIsValid(p->thH) == false && enableFl == true)

  461.   {

  462.     if(cmThreadCreate(&p->thH,_cmUdpThreadCb,p,p->err.rpt) != kOkThRC )

  463.       return cmErrMsg(&p->err,kThreadFailUdpRC,"Listener thread create failed.");

  464. 

  465.     if(cmTs1p1cCreate(&p->qH,p->recvBufByteCnt,_cmUdpQueueCb,p,p->err.rpt) != kOkThRC )

  466.       return cmErrMsg(&p->err,kQueueFailUdpRC,"Listener data queue create failed.");

  467.   }

  468. 

  469.   if( cmThreadIsValid(p->thH) )

  470.     if( cmThreadPause( p->thH, enableFl ? 0 : kPauseThFl ) != kOkThRC )

  471.       return cmErrMsg(&p->err,kThreadFailUdpRC,"The listener thread failed to %s.", enableFl ? "pause" : "un-pause" );

  472. 

  473.   return kOkUdpRC;    

  474. }

  475. 

  476. bool      cmUdpIsQueueEnabled( cmUdpH_t h )

  477. {

  478.   cmUdp_t* p = _cmUdpHandleToPtr(h);

  479.   return cmIsFlag(p->flags,kQueueingUdpFl);

  480. }

  481. 

  482. void      cmUdpQueueEnable( cmUdpH_t h, bool enableFl )

  483. {

  484.   cmUdp_t* p = _cmUdpHandleToPtr(h);

  485.   p->flags = cmSetFlag(p->flags,kQueueingUdpFl);

  486. }

  487. 

  488. 

  489. unsigned  cmUdpAvailDataByteCount( cmUdpH_t h )

  490. {

  491.   cmUdp_t* p = _cmUdpHandleToPtr(h);

  492.   return cmTs1p1cIsValid(p->qH) ? cmTs1p1cDequeueMsgByteCount( p->qH ) : 0;

  493. }

  494. 

  495. cmUdpRC_t cmUdpGetAvailData( cmUdpH_t h, char* data, unsigned* dataByteCntPtr, struct sockaddr_in* fromAddr )

  496. {

  497.   cmUdp_t* p = _cmUdpHandleToPtr(h);

  498. 

  499.   unsigned availByteCnt;

  500.     

  501.   // if a received msg is queued

  502.   if( (availByteCnt = cmTs1p1cAvailByteCount(p->qH)) > 0 )

  503.   {

  504.     // all msg's must have at least a source address

  505.     assert( availByteCnt >= sizeof(*fromAddr) );

  506. 

  507.     // get the size of the return buffer (or 0 if there is no return buffer)

  508.     unsigned dataByteCnt = (data != NULL && dataByteCntPtr != NULL) ? *dataByteCntPtr : 0;

  509. 

  510.     if( dataByteCnt == 0 )

  511.       data = NULL;

  512. 

  513.     // dequeue the msg - if data==NULL then the data will be returned by

  514.     // a call to the callback function provided in cmUdpAlloc().

  515.     if( cmTs1p1cDequeueMsg(p->qH, data, dataByteCnt ) != kOkThRC )

  516.       return cmErrMsg(&p->err,kQueueFailUdpRC,"Data dequeue failed.");

  517.       

  518.     // if a return buffer was given

  519.     if( data != NULL )

  520.     {

  521.       assert( dataByteCntPtr != NULL );

  522.         

  523.       // the source address is appended to the end of the data 

  524.       const char* addrPtr = data + availByteCnt - sizeof(*fromAddr);

  525. 

  526.       // copy out the source address

  527.       if( fromAddr != NULL )

  528.         memcpy(fromAddr,addrPtr,sizeof(*fromAddr));

  529. 

  530.       // subtract the address size from the total msg size

  531.       *dataByteCntPtr = availByteCnt - sizeof(*fromAddr);

  532.     }

  533.   }

  534.   return kOkUdpRC;

  535. }

  536. 

  537. void      cmUdpReport( cmUdpH_t h, cmRpt_t* rpt )

  538. {

  539.   cmUdp_t* p = _cmUdpHandleToPtr(h);  

  540.   cmRptPrintf(rpt,"time-out:%i recv:%i queue cb:%i\n",p->timeOutCnt,p->recvCnt,p->queCbCnt);

  541. }

  542. 

  543. cmUdpRC_t cmUdpInitAddr( cmUdpH_t h, const char* addrStr, cmUdpPort_t portNumber, struct sockaddr_in* retAddrPtr )

  544. {

  545.   cmUdp_t* p = _cmUdpHandleToPtr(h);

  546.   return _cmUdpInitAddr(p,addrStr,portNumber,retAddrPtr);

  547. }