/**************************************************************************** (c) SYSTEC electronic GmbH, D-07973 Greiz, August-Bebel-Str. 29 www.systec-electronic.com Project: openPOWERLINK Description: source file for NMT-Userspace-Module License: Redistribution and use in source and binary forms, with or without modification, are permitted provided that the following conditions are met: 1. Redistributions of source code must retain the above copyright notice, this list of conditions and the following disclaimer. 2. Redistributions in binary form must reproduce the above copyright notice, this list of conditions and the following disclaimer in the documentation and/or other materials provided with the distribution. 3. Neither the name of SYSTEC electronic GmbH nor the names of its contributors may be used to endorse or promote products derived from this software without prior written permission. For written permission, please contact info@systec-electronic.com. THIS SOFTWARE IS PROVIDED BY THE COPYRIGHT HOLDERS AND CONTRIBUTORS "AS IS" AND ANY EXPRESS OR IMPLIED WARRANTIES, INCLUDING, BUT NOT LIMITED TO, THE IMPLIED WARRANTIES OF MERCHANTABILITY AND FITNESS FOR A PARTICULAR PURPOSE ARE DISCLAIMED. IN NO EVENT SHALL THE COPYRIGHT HOLDERS OR CONTRIBUTORS BE LIABLE FOR ANY DIRECT, INDIRECT, INCIDENTAL, SPECIAL, EXEMPLARY, OR CONSEQUENTIAL DAMAGES (INCLUDING, BUT NOT LIMITED TO, PROCUREMENT OF SUBSTITUTE GOODS OR SERVICES; LOSS OF USE, DATA, OR PROFITS; OR BUSINESS INTERRUPTION) HOWEVER CAUSED AND ON ANY THEORY OF LIABILITY, WHETHER IN CONTRACT, STRICT LIABILITY, OR TORT (INCLUDING NEGLIGENCE OR OTHERWISE) ARISING IN ANY WAY OUT OF THE USE OF THIS SOFTWARE, EVEN IF ADVISED OF THE POSSIBILITY OF SUCH DAMAGE. Severability Clause: If a provision of this License is or becomes illegal, invalid or unenforceable in any jurisdiction, that shall not affect: 1. the validity or enforceability in that jurisdiction of any other provision of this License; or 2. the validity or enforceability in other jurisdictions of that or any other provision of this License. ------------------------------------------------------------------------- $RCSfile: EplNmtu.c,v $ $Author: D.Krueger $ $Revision: 1.8 $ $Date: 2008/11/10 17:17:42 $ $State: Exp $ Build Environment: GCC V3.4 ------------------------------------------------------------------------- Revision History: 2006/06/09 k.t.: start of the implementation ****************************************************************************/ #include "EplInc.h" #include "user/EplNmtu.h" #include "user/EplObdu.h" #include "user/EplTimeru.h" #if(((EPL_MODULE_INTEGRATION) & (EPL_MODULE_NMTK)) != 0) #include "kernel/EplNmtk.h" #endif #if(((EPL_MODULE_INTEGRATION) & (EPL_MODULE_NMTU)) != 0) /***************************************************************************/ /* */ /* */ /* G L O B A L D E F I N I T I O N S */ /* */ /* */ /***************************************************************************/ //--------------------------------------------------------------------------- // const defines //--------------------------------------------------------------------------- //--------------------------------------------------------------------------- // local types //--------------------------------------------------------------------------- typedef struct { tEplNmtuStateChangeCallback m_pfnNmtChangeCb; tEplTimerHdl m_TimerHdl; } tEplNmtuInstance; //--------------------------------------------------------------------------- // modul globale vars //--------------------------------------------------------------------------- static tEplNmtuInstance EplNmtuInstance_g; //--------------------------------------------------------------------------- // local function prototypes //--------------------------------------------------------------------------- //=========================================================================// // // // P U B L I C F U N C T I O N S // // // //=========================================================================// //--------------------------------------------------------------------------- // // Function: EplNmtuInit // // Description: init first instance of the module // // // // Parameters: // // // Returns: tEplKernel = errorcode // // // State: // //--------------------------------------------------------------------------- EPLDLLEXPORT tEplKernel PUBLIC EplNmtuInit() { tEplKernel Ret; Ret = EplNmtuAddInstance(); return Ret; } //--------------------------------------------------------------------------- // // Function: EplNmtuAddInstance // // Description: init other instances of the module // // // // Parameters: // // // Returns: tEplKernel = errorcode // // // State: // //--------------------------------------------------------------------------- EPLDLLEXPORT tEplKernel PUBLIC EplNmtuAddInstance() { tEplKernel Ret; Ret = kEplSuccessful; EplNmtuInstance_g.m_pfnNmtChangeCb = NULL; return Ret; } //--------------------------------------------------------------------------- // // Function: EplNmtuDelInstance // // Description: delete instance // // // // Parameters: // // // Returns: tEplKernel = errorcode // // // State: // //--------------------------------------------------------------------------- EPLDLLEXPORT tEplKernel PUBLIC EplNmtuDelInstance() { tEplKernel Ret; Ret = kEplSuccessful; EplNmtuInstance_g.m_pfnNmtChangeCb = NULL; // delete timer Ret = EplTimeruDeleteTimer(&EplNmtuInstance_g.m_TimerHdl); return Ret; } //--------------------------------------------------------------------------- // // Function: EplNmtuNmtEvent // // Description: sends the NMT-Event to the NMT-State-Maschine // // // // Parameters: NmtEvent_p = NMT-Event to send // // // Returns: tEplKernel = errorcode // // // State: // //--------------------------------------------------------------------------- EPLDLLEXPORT tEplKernel PUBLIC EplNmtuNmtEvent(tEplNmtEvent NmtEvent_p) { tEplKernel Ret; tEplEvent Event; Event.m_EventSink = kEplEventSinkNmtk; Event.m_NetTime.m_dwNanoSec = 0; Event.m_NetTime.m_dwSec = 0; Event.m_EventType = kEplEventTypeNmtEvent; Event.m_pArg = &NmtEvent_p; Event.m_uiSize = sizeof(NmtEvent_p); Ret = EplEventuPost(&Event); return Ret; } //--------------------------------------------------------------------------- // // Function: EplNmtuGetNmtState // // Description: returns the actuell NMT-State // // // // Parameters: // // // Returns: tEplNmtState = NMT-State // // // State: // //--------------------------------------------------------------------------- EPLDLLEXPORT tEplNmtState PUBLIC EplNmtuGetNmtState() { tEplNmtState NmtState; // $$$ call function of communication abstraction layer #if(((EPL_MODULE_INTEGRATION) & (EPL_MODULE_NMTK)) != 0) NmtState = EplNmtkGetNmtState(); #else NmtState = 0; #endif return NmtState; } //--------------------------------------------------------------------------- // // Function: EplNmtuProcessEvent // // Description: processes events from event queue // // // // Parameters: pEplEvent_p = pointer to event // // // Returns: tEplKernel = errorcode // // // State: // //--------------------------------------------------------------------------- EPLDLLEXPORT tEplKernel PUBLIC EplNmtuProcessEvent(tEplEvent * pEplEvent_p) { tEplKernel Ret; Ret = kEplSuccessful; // process event switch (pEplEvent_p->m_EventType) { // state change of NMT-Module case kEplEventTypeNmtStateChange: { tEplEventNmtStateChange *pNmtStateChange; // delete timer Ret = EplTimeruDeleteTimer(&EplNmtuInstance_g.m_TimerHdl); pNmtStateChange = (tEplEventNmtStateChange *) pEplEvent_p->m_pArg; // call cb-functions to inform higher layer if (EplNmtuInstance_g.m_pfnNmtChangeCb != NULL) { Ret = EplNmtuInstance_g. m_pfnNmtChangeCb(*pNmtStateChange); } if (Ret == kEplSuccessful) { // everything is OK, so switch to next state if necessary switch (pNmtStateChange->m_NewNmtState) { // EPL stack is not running case kEplNmtGsOff: break; // first init of the hardware case kEplNmtGsInitialising: { Ret = EplNmtuNmtEvent (kEplNmtEventEnterResetApp); break; } // init of the manufacturer-specific profile area and the // standardised device profile area case kEplNmtGsResetApplication: { Ret = EplNmtuNmtEvent (kEplNmtEventEnterResetCom); break; } // init of the communication profile area case kEplNmtGsResetCommunication: { Ret = EplNmtuNmtEvent (kEplNmtEventEnterResetConfig); break; } // build the configuration with infos from OD case kEplNmtGsResetConfiguration: { unsigned int uiNodeId; // get node ID from OD #if (((EPL_MODULE_INTEGRATION) & (EPL_MODULE_OBDU)) != 0) || (EPL_OBD_USE_KERNEL != FALSE) uiNodeId = EplObduGetNodeId (EPL_MCO_PTR_INSTANCE_PTR); #else uiNodeId = 0; #endif //check node ID if not should be master or slave if (uiNodeId == EPL_C_ADR_MN_DEF_NODE_ID) { // node shall be MN #if (((EPL_MODULE_INTEGRATION) & (EPL_MODULE_NMT_MN)) != 0) Ret = EplNmtuNmtEvent (kEplNmtEventEnterMsNotActive); #else TRACE0 ("EplNmtuProcess(): no MN functionality implemented\n"); #endif } else { // node shall be CN Ret = EplNmtuNmtEvent (kEplNmtEventEnterCsNotActive); } break; } //----------------------------------------------------------- // CN part of the state machine // node listens for EPL-Frames and check timeout case kEplNmtCsNotActive: { DWORD dwBuffer; tEplObdSize ObdSize; tEplTimerArg TimerArg; // create timer to switch automatically to BasicEthernet if no MN available in network // read NMT_CNBasicEthernetTimerout_U32 from OD ObdSize = sizeof(dwBuffer); #if (((EPL_MODULE_INTEGRATION) & (EPL_MODULE_OBDU)) != 0) || (EPL_OBD_USE_KERNEL != FALSE) Ret = EplObduReadEntry (EPL_MCO_PTR_INSTANCE_PTR_ 0x1F99, 0x00, &dwBuffer, &ObdSize); #else Ret = kEplObdIndexNotExist; #endif if (Ret != kEplSuccessful) { break; } if (dwBuffer != 0) { // BasicEthernet is enabled // convert us into ms dwBuffer = dwBuffer / 1000; if (dwBuffer == 0) { // timer was below one ms // set one ms dwBuffer = 1; } TimerArg.m_EventSink = kEplEventSinkNmtk; TimerArg.m_ulArg = (unsigned long) kEplNmtEventTimerBasicEthernet; Ret = EplTimeruModifyTimerMs (&EplNmtuInstance_g. m_TimerHdl, (unsigned long) dwBuffer, TimerArg); // potential error is forwarded to event queue which generates error event } break; } // node processes only async frames case kEplNmtCsPreOperational1: { break; } // node processes isochronous and asynchronous frames case kEplNmtCsPreOperational2: { Ret = EplNmtuNmtEvent (kEplNmtEventEnterReadyToOperate); break; } // node should be configured und application is ready case kEplNmtCsReadyToOperate: { break; } // normal work state case kEplNmtCsOperational: { break; } // node stopped by MN // -> only process asynchronous frames case kEplNmtCsStopped: { break; } // no EPL cycle // -> normal ethernet communication case kEplNmtCsBasicEthernet: { break; } //----------------------------------------------------------- // MN part of the state machine #if (((EPL_MODULE_INTEGRATION) & (EPL_MODULE_NMT_MN)) != 0) // node listens for EPL-Frames and check timeout case kEplNmtMsNotActive: { DWORD dwBuffer; tEplObdSize ObdSize; tEplTimerArg TimerArg; // create timer to switch automatically to BasicEthernet/PreOp1 if no other MN active in network // check NMT_StartUp_U32.Bit13 // read NMT_StartUp_U32 from OD ObdSize = sizeof(dwBuffer); #if (((EPL_MODULE_INTEGRATION) & (EPL_MODULE_OBDU)) != 0) || (EPL_OBD_USE_KERNEL != FALSE) Ret = EplObduReadEntry (EPL_MCO_PTR_INSTANCE_PTR_ 0x1F80, 0x00, &dwBuffer, &ObdSize); #else Ret = kEplObdIndexNotExist; #endif if (Ret != kEplSuccessful) { break; } if ((dwBuffer & EPL_NMTST_BASICETHERNET) == 0) { // NMT_StartUp_U32.Bit13 == 0 // new state PreOperational1 TimerArg.m_ulArg = (unsigned long) kEplNmtEventTimerMsPreOp1; } else { // NMT_StartUp_U32.Bit13 == 1 // new state BasicEthernet TimerArg.m_ulArg = (unsigned long) kEplNmtEventTimerBasicEthernet; } // read NMT_BootTime_REC.MNWaitNotAct_U32 from OD ObdSize = sizeof(dwBuffer); #if (((EPL_MODULE_INTEGRATION) & (EPL_MODULE_OBDU)) != 0) || (EPL_OBD_USE_KERNEL != FALSE) Ret = EplObduReadEntry (EPL_MCO_PTR_INSTANCE_PTR_ 0x1F89, 0x01, &dwBuffer, &ObdSize); #else Ret = kEplObdIndexNotExist; #endif if (Ret != kEplSuccessful) { break; } // convert us into ms dwBuffer = dwBuffer / 1000; if (dwBuffer == 0) { // timer was below one ms // set one ms dwBuffer = 1; } TimerArg.m_EventSink = kEplEventSinkNmtk; Ret = EplTimeruModifyTimerMs (&EplNmtuInstance_g. m_TimerHdl, (unsigned long)dwBuffer, TimerArg); // potential error is forwarded to event queue which generates error event break; } // node processes only async frames case kEplNmtMsPreOperational1: { DWORD dwBuffer = 0; tEplObdSize ObdSize; tEplTimerArg TimerArg; // create timer to switch automatically to PreOp2 if MN identified all mandatory CNs // read NMT_BootTime_REC.MNWaitPreOp1_U32 from OD ObdSize = sizeof(dwBuffer); #if (((EPL_MODULE_INTEGRATION) & (EPL_MODULE_OBDU)) != 0) || (EPL_OBD_USE_KERNEL != FALSE) Ret = EplObduReadEntry (EPL_MCO_PTR_INSTANCE_PTR_ 0x1F89, 0x03, &dwBuffer, &ObdSize); if (Ret != kEplSuccessful) { // ignore error, because this timeout is optional dwBuffer = 0; } #endif if (dwBuffer == 0) { // delay is deactivated // immediately post timer event Ret = EplNmtuNmtEvent (kEplNmtEventTimerMsPreOp2); break; } // convert us into ms dwBuffer = dwBuffer / 1000; if (dwBuffer == 0) { // timer was below one ms // set one ms dwBuffer = 1; } TimerArg.m_EventSink = kEplEventSinkNmtk; TimerArg.m_ulArg = (unsigned long) kEplNmtEventTimerMsPreOp2; Ret = EplTimeruModifyTimerMs (&EplNmtuInstance_g. m_TimerHdl, (unsigned long)dwBuffer, TimerArg); // potential error is forwarded to event queue which generates error event break; } // node processes isochronous and asynchronous frames case kEplNmtMsPreOperational2: { break; } // node should be configured und application is ready case kEplNmtMsReadyToOperate: { break; } // normal work state case kEplNmtMsOperational: { break; } // no EPL cycle // -> normal ethernet communication case kEplNmtMsBasicEthernet: { break; } #endif // (((EPL_MODULE_INTEGRATION) & (EPL_MODULE_NMT_MN)) != 0) default: { TRACE1 ("EplNmtuProcess(): unhandled NMT state 0x%X\n", pNmtStateChange-> m_NewNmtState); } } } else if (Ret == kEplReject) { // application wants to change NMT state itself // it's OK Ret = kEplSuccessful; } EPL_DBGLVL_NMTU_TRACE0 ("EplNmtuProcessEvent(): NMT-State-Maschine announce change of NMT State\n"); break; } default: { Ret = kEplNmtInvalidEvent; } } //Exit: return Ret; } //--------------------------------------------------------------------------- // // Function: EplNmtuRegisterStateChangeCb // // Description: register Callback-function go get informed about a // NMT-Change-State-Event // // // // Parameters: pfnEplNmtStateChangeCb_p = functionpointer // // // Returns: tEplKernel = errorcode // // // State: // //--------------------------------------------------------------------------- EPLDLLEXPORT tEplKernel PUBLIC EplNmtuRegisterStateChangeCb(tEplNmtuStateChangeCallback pfnEplNmtStateChangeCb_p) { tEplKernel Ret; Ret = kEplSuccessful; // save callback-function in modul global var EplNmtuInstance_g.m_pfnNmtChangeCb = pfnEplNmtStateChangeCb_p; return Ret; } //=========================================================================// // // // P R I V A T E F U N C T I O N S // // // //=========================================================================// //--------------------------------------------------------------------------- // // Function: // // Description: // // // // Parameters: // // // Returns: // // // State: // //--------------------------------------------------------------------------- #endif // #if(((EPL_MODULE_INTEGRATION) & (EPL_MODULE_NMTU)) != 0) // EOF