//------------------------------------------------------------------------------
tOplkError target_init(void)
{
tOplkError Ret = kErrorOk;
sigset_t mask;
/*
* We have to block the real time signals used by the timer modules so
* that they are able to wait on them using sigwaitinfo!
*/
sigemptyset(&mask);
sigaddset(&mask, SIGRTMIN);
sigaddset(&mask, SIGRTMIN + 1);
pthread_sigmask(SIG_BLOCK, &mask, NULL);
/* Enabling ftrace for debugging */
FTRACE_OPEN();
FTRACE_ENABLE(TRUE);
return Ret;
}
//---------------------------------------------------------------------------
//
// Function: main
//
// Description: main function of demo application
//
// Parameters:
//
// Returns:
//---------------------------------------------------------------------------
int main (int argc, char **argv)
{
tEplKernel EplRet = kEplSuccessful;
static tEplApiInitParam EplApiInitParam;
char* sHostname = HOSTNAME;
char cKey = 0;
#ifdef CONFIG_POWERLINK_USERSTACK
// variables for Pcap
char sErr_Msg[ PCAP_ERRBUF_SIZE ];
char devName[128];
pcap_if_t * alldevs;
pcap_if_t * seldev;
int i = 0;
int inum;
#endif
int opt;
#if (TARGET_SYSTEM == _LINUX_)
/* get command line parameters */
while ((opt = getopt(argc, argv, "c:l:")) != -1)
{
switch (opt)
{
case 'c':
uiCycleLen_g = strtoul(optarg, NULL, 10);
break;
case 'l':
pLogFile_g = optarg;
break;
default: /* '?' */
fprintf (stderr, "Usage: %s [-c CYCLE_TIME] [-l LOGFILE]\n", argv[0]);
goto Exit;
}
}
#endif
#ifdef CONFIG_POWERLINK_USERSTACK
#if (TARGET_SYSTEM == _LINUX_)
struct sched_param schedParam;
/* adjust process priority */
if (nice (-20) == -1) // push nice level in case we have no RTPreempt
{
EPL_DBGLVL_ERROR_TRACE("%s() couldn't set nice value! (%s)\n", __func__, strerror(errno));
}
schedParam.__sched_priority = MAIN_THREAD_PRIORITY;
if (pthread_setschedparam(pthread_self(), SCHED_RR, &schedParam) != 0)
{
EPL_DBGLVL_ERROR_TRACE("%s() couldn't set thread scheduling parameters! %d\n",
__func__, schedParam.__sched_priority);
}
/* Initialize target specific stuff */
EplTgtInit();
#elif (TARGET_SYSTEM == _WIN32_)
// activate realtime priority class
SetPriorityClass(GetCurrentProcess(), REALTIME_PRIORITY_CLASS);
// lower the priority of this thread
SetThreadPriority(GetCurrentThread(), THREAD_PRIORITY_IDLE);
#endif // (TARGET_SYSTEM == _WIN32_)
#endif // CONFIG_POWERLINK_USERSTACK
#if (TARGET_SYSTEM == _LINUX_)
#ifdef SET_CPU_AFFINITY
{
/* binds all openPOWERLINK threads to the second CPU core */
cpu_set_t affinity;
CPU_ZERO(&affinity);
CPU_SET(1, &affinity);
sched_setaffinity(0, sizeof(cpu_set_t), &affinity);
}
#endif
#endif
/* Enabling ftrace for debugging */
FTRACE_OPEN();
FTRACE_ENABLE(TRUE);
/*
EPL_DBGLVL_ALWAYS_TRACE("%s(): Main Thread Id:%ld\n", __func__,
syscall(SYS_gettid));
*/
printf("----------------------------------------------------\n");
printf("openPOWERLINK console MN DEMO application\n");
printf("----------------------------------------------------\n");
EPL_MEMSET(&EplApiInitParam, 0, sizeof (EplApiInitParam));
EplApiInitParam.m_uiSizeOfStruct = sizeof (EplApiInitParam);
#ifdef CONFIG_POWERLINK_USERSTACK
/* Retrieve the device list on the local machine */
if (pcap_findalldevs(&alldevs, sErr_Msg) == -1)
{
fprintf(stderr, "Error in pcap_findalldevs: %s\n", sErr_Msg);
EplRet = kEplNoResource;
goto Exit;
}
PRINTF("--------------------------------------------------\n");
PRINTF("List of Ethernet Cards Found in this System: \n");
PRINTF("--------------------------------------------------\n");
/* Print the list */
for (seldev = alldevs; seldev != NULL; seldev = seldev->next)
{
PRINTF("%d. ", ++i);
if (seldev->description)
{
PRINTF("%s\n %s\n", seldev->description, seldev->name);
}
else
{
PRINTF("%s\n", seldev->name);
}
}
if (i == 0)
{
PRINTF("\nNo interfaces found! Make sure pcap library is installed.\n");
EplRet = kEplNoResource;
goto Exit;
}
PRINTF("--------------------------------------------------\n");
PRINTF("Select the interface to be used for POWERLINK (1-%d):",i);
if (scanf("%d", &inum) == EOF)
{
pcap_freealldevs(alldevs);
EplRet = kEplNoResource;
goto Exit;
}
PRINTF("--------------------------------------------------\n");
if ((inum < 1) || (inum > i))
{
PRINTF("\nInterface number out of range.\n");
/* Free the device list */
pcap_freealldevs(alldevs);
EplRet = kEplNoResource;
goto Exit;
}
/* Jump to the selected adapter */
for (seldev = alldevs, i = 0;
i < (inum - 1);
seldev = seldev->next, i++)
{ // do nothing
}
strncpy(devName, seldev->name, 127);
// pass selected device name to Edrv
EplApiInitParam.m_HwParam.m_pszDevName = devName;
#endif
EplApiInitParam.m_uiNodeId = uiNodeId_g = NODEID;
EplApiInitParam.m_dwIpAddress = (0xFFFFFF00 & IP_ADDR) | EplApiInitParam.m_uiNodeId;
/* write 00:00:00:00:00:00 to MAC address, so that the driver uses the real hardware address */
EPL_MEMCPY(EplApiInitParam.m_abMacAddress, abMacAddr, sizeof (EplApiInitParam.m_abMacAddress));
EplApiInitParam.m_fAsyncOnly = FALSE;
EplApiInitParam.m_dwFeatureFlags = -1;
EplApiInitParam.m_dwCycleLen = uiCycleLen_g; // required for error detection
EplApiInitParam.m_uiIsochrTxMaxPayload = 256; // const
EplApiInitParam.m_uiIsochrRxMaxPayload = 256; // const
EplApiInitParam.m_dwPresMaxLatency = 50000; // const; only required for IdentRes
EplApiInitParam.m_uiPreqActPayloadLimit = 36; // required for initialisation (+28 bytes)
EplApiInitParam.m_uiPresActPayloadLimit = 36; // required for initialisation of Pres frame (+28 bytes)
EplApiInitParam.m_dwAsndMaxLatency = 150000; // const; only required for IdentRes
EplApiInitParam.m_uiMultiplCycleCnt = 0; // required for error detection
EplApiInitParam.m_uiAsyncMtu = 1500; // required to set up max frame size
EplApiInitParam.m_uiPrescaler = 2; // required for sync
EplApiInitParam.m_dwLossOfFrameTolerance = 500000;
EplApiInitParam.m_dwAsyncSlotTimeout = 3000000;
EplApiInitParam.m_dwWaitSocPreq = 150000;
EplApiInitParam.m_dwDeviceType = -1; // NMT_DeviceType_U32
EplApiInitParam.m_dwVendorId = -1; // NMT_IdentityObject_REC.VendorId_U32
EplApiInitParam.m_dwProductCode = -1; // NMT_IdentityObject_REC.ProductCode_U32
EplApiInitParam.m_dwRevisionNumber = -1; // NMT_IdentityObject_REC.RevisionNo_U32
EplApiInitParam.m_dwSerialNumber = -1; // NMT_IdentityObject_REC.SerialNo_U32
EplApiInitParam.m_dwSubnetMask = SUBNET_MASK;
EplApiInitParam.m_dwDefaultGateway = 0;
EPL_MEMCPY(EplApiInitParam.m_sHostname, sHostname, sizeof(EplApiInitParam.m_sHostname));
EplApiInitParam.m_uiSyncNodeId = EPL_C_ADR_SYNC_ON_SOA;
EplApiInitParam.m_fSyncOnPrcNode = FALSE;
// set callback functions
EplApiInitParam.m_pfnCbEvent = AppCbEvent;
#ifdef CONFIG_POWERLINK_USERSTACK
EplApiInitParam.m_pfnObdInitRam = EplObdInitRam;
EplApiInitParam.m_pfnCbSync = AppCbSync;
#else
EplApiInitParam.m_pfnCbSync = NULL;
#endif
printf("\n\nHello, I'm a Userspace POWERLINK node running as %s!\n (build: %s / %s)\n\n",
(uiNodeId_g == EPL_C_ADR_MN_DEF_NODE_ID ?
"Managing Node" : "Controlled Node"),
__DATE__, __TIME__);
// initialize POWERLINK stack
printf ("Initializing openPOWERLINK stack...\n");
EplRet = EplApiInitialize(&EplApiInitParam);
if(EplRet != kEplSuccessful)
{
printf("EplApiInitialize() failed (Error:0x%x!\n", EplRet);
goto Exit;
}
// initialize application
printf ("Initializing openPOWERLINK application...\n");
EplRet = AppInit();
if(EplRet != kEplSuccessful)
{
printf("ApiInit() failed!\n");
goto Exit;
}
#ifdef CONFIG_POWERLINK_USERSTACK
/* At this point, we don't need any more the device list. Free it */
pcap_freealldevs(alldevs);
EplRet = EplApiSetCdcFilename(pszCdcFilename_g);
if(EplRet != kEplSuccessful)
{
goto Exit;
}
#else
// create event thread
if (pthread_create(&eventThreadId, NULL,
&powerlinkEventThread, NULL) != 0)
{
goto Exit;
}
// create sync thread
if (pthread_create(&syncThreadId, NULL,
&powerlinkSyncThread, NULL) != 0)
{
goto Exit;
}
#endif
printf("Initializing process image...\n");
printf("Size of input process image: %ld\n", sizeof(AppProcessImageIn_g));
printf("Size of output process image: %ld\n", sizeof (AppProcessImageOut_g));
AppProcessImageCopyJob_g.m_fNonBlocking = FALSE;
AppProcessImageCopyJob_g.m_uiPriority = 0;
AppProcessImageCopyJob_g.m_In.m_pPart = &AppProcessImageIn_g;
AppProcessImageCopyJob_g.m_In.m_uiOffset = 0;
AppProcessImageCopyJob_g.m_In.m_uiSize = sizeof (AppProcessImageIn_g);
AppProcessImageCopyJob_g.m_Out.m_pPart = &AppProcessImageOut_g;
AppProcessImageCopyJob_g.m_Out.m_uiOffset = 0;
AppProcessImageCopyJob_g.m_Out.m_uiSize = sizeof (AppProcessImageOut_g);
EplRet = EplApiProcessImageAlloc(sizeof (AppProcessImageIn_g), sizeof (AppProcessImageOut_g), 2, 2);
if (EplRet != kEplSuccessful)
{
goto Exit;
}
EplRet = EplApiProcessImageSetup();
if (EplRet != kEplSuccessful)
{
goto Exit;
}
// start processing
EplRet = EplApiExecNmtCommand(kEplNmtEventSwReset);
if (EplRet != kEplSuccessful)
{
goto ExitShutdown;
}
printf("\n-------------------------------\n");
printf("Press Esc to leave the program\n");
printf("Press r to reset the node\n");
printf("-------------------------------\n\n");
// wait for key hit
while (cKey != 0x1B)
{
if( EplTgtKbhit() )
{
cKey = (BYTE) EplTgtGetch();
switch (cKey)
{
case 'r':
{
EplRet = EplApiExecNmtCommand(kEplNmtEventSwReset);
if (EplRet != kEplSuccessful)
{
goto ExitShutdown;
}
break;
}
case 'c':
{
EplRet = EplApiExecNmtCommand(kEplNmtEventNmtCycleError);
if (EplRet != kEplSuccessful)
{
goto ExitShutdown;
}
break;
}
default:
{
break;
}
}
}
EplTgtMilliSleep( 1500 );
}
FTRACE_ENABLE(FALSE);
ExitShutdown:
// halt the NMT state machine
// so the processing of POWERLINK frames stops
EplRet = EplApiExecNmtCommand(kEplNmtEventSwitchOff);
// delete process image
EplRet = EplApiProcessImageFree();
// delete instance for all modules
EplRet = EplApiShutdown();
Exit:
PRINTF("main(): returns 0x%X\n", EplRet);
#if (TARGET_SYSTEM == _WIN32_)
PRINTF("Press Enter to quit!\n");
EplTgtGetch();
#endif
return EplRet;
}