| /**************************************************************************** |
| |
| (c) SYSTEC electronic GmbH, D-07973 Greiz, August-Bebel-Str. 29 |
| www.systec-electronic.com |
| |
| Project: openPOWERLINK |
| |
| Description: source file for kernel DLL 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: EplDllk.c,v $ |
| |
| $Author: D.Krueger $ |
| |
| $Revision: 1.21 $ $Date: 2008/11/13 17:13:09 $ |
| |
| $State: Exp $ |
| |
| Build Environment: |
| GCC V3.4 |
| |
| ------------------------------------------------------------------------- |
| |
| Revision History: |
| |
| 2006/06/12 d.k.: start of the implementation, version 1.00 |
| |
| ****************************************************************************/ |
| |
| #include "kernel/EplDllk.h" |
| #include "kernel/EplDllkCal.h" |
| #include "kernel/EplEventk.h" |
| #include "kernel/EplNmtk.h" |
| #include "edrv.h" |
| #include "Benchmark.h" |
| |
| #if (((EPL_MODULE_INTEGRATION) & (EPL_MODULE_PDOK)) != 0) |
| #include "kernel/EplPdok.h" |
| #endif |
| |
| #if (((EPL_MODULE_INTEGRATION) & (EPL_MODULE_VETH)) != 0) |
| #include "kernel/VirtualEthernet.h" |
| #endif |
| |
| //#if EPL_TIMER_USE_HIGHRES != FALSE |
| #include "kernel/EplTimerHighResk.h" |
| //#endif |
| |
| #if(((EPL_MODULE_INTEGRATION) & (EPL_MODULE_DLLK)) != 0) |
| |
| #if(((EPL_MODULE_INTEGRATION) & (EPL_MODULE_NMTK)) == 0) |
| #error "EPL module DLLK needs EPL module NMTK!" |
| #endif |
| |
| #if (EPL_DLL_PRES_READY_AFTER_SOA != FALSE) && (EPL_DLL_PRES_READY_AFTER_SOC != FALSE) |
| #error "EPL module DLLK: select only one of EPL_DLL_PRES_READY_AFTER_SOA and EPL_DLL_PRES_READY_AFTER_SOC." |
| #endif |
| |
| #if ((EPL_DLL_PRES_READY_AFTER_SOA != FALSE) || (EPL_DLL_PRES_READY_AFTER_SOC != FALSE)) \ |
| && (((EPL_MODULE_INTEGRATION) & (EPL_MODULE_NMT_MN)) == 0) |
| #error "EPL module DLLK: currently, EPL_DLL_PRES_READY_AFTER_* is not supported if EPL_MODULE_NMT_MN is enabled." |
| #endif |
| |
| #if (EDRV_FAST_TXFRAMES == FALSE) && \ |
| ((EPL_DLL_PRES_READY_AFTER_SOA != FALSE) || (EPL_DLL_PRES_READY_AFTER_SOC != FALSE)) |
| #error "EPL module DLLK: EPL_DLL_PRES_READY_AFTER_* is enabled, but not EDRV_FAST_TXFRAMES." |
| #endif |
| |
| /***************************************************************************/ |
| /* */ |
| /* */ |
| /* G L O B A L D E F I N I T I O N S */ |
| /* */ |
| /* */ |
| /***************************************************************************/ |
| |
| //--------------------------------------------------------------------------- |
| // const defines |
| //--------------------------------------------------------------------------- |
| |
| // TracePoint support for realtime-debugging |
| #ifdef _DBG_TRACE_POINTS_ |
| void TgtDbgSignalTracePoint(u8 bTracePointNumber_p); |
| void TgtDbgPostTraceValue(u32 dwTraceValue_p); |
| #define TGT_DBG_SIGNAL_TRACE_POINT(p) TgtDbgSignalTracePoint(p) |
| #define TGT_DBG_POST_TRACE_VALUE(v) TgtDbgPostTraceValue(v) |
| #else |
| #define TGT_DBG_SIGNAL_TRACE_POINT(p) |
| #define TGT_DBG_POST_TRACE_VALUE(v) |
| #endif |
| #define EPL_DLLK_DBG_POST_TRACE_VALUE(Event_p, uiNodeId_p, wErrorCode_p) \ |
| TGT_DBG_POST_TRACE_VALUE((kEplEventSinkDllk << 28) | (Event_p << 24) \ |
| | (uiNodeId_p << 16) | wErrorCode_p) |
| |
| /***************************************************************************/ |
| /* */ |
| /* */ |
| /* C L A S S EplDllk */ |
| /* */ |
| /* */ |
| /***************************************************************************/ |
| // |
| // Description: |
| // |
| // |
| /***************************************************************************/ |
| |
| //=========================================================================// |
| // // |
| // P R I V A T E D E F I N I T I O N S // |
| // // |
| //=========================================================================// |
| |
| //--------------------------------------------------------------------------- |
| // const defines |
| //--------------------------------------------------------------------------- |
| |
| // defines for indexes of tEplDllInstance.m_pTxFrameInfo |
| #define EPL_DLLK_TXFRAME_IDENTRES 0 // IdentResponse on CN / MN |
| #define EPL_DLLK_TXFRAME_STATUSRES 1 // StatusResponse on CN / MN |
| #define EPL_DLLK_TXFRAME_NMTREQ 2 // NMT Request from FIFO on CN / MN |
| #define EPL_DLLK_TXFRAME_NONEPL 3 // non-EPL frame from FIFO on CN / MN |
| #define EPL_DLLK_TXFRAME_PRES 4 // PRes on CN / MN |
| #define EPL_DLLK_TXFRAME_SOC 5 // SoC on MN |
| #define EPL_DLLK_TXFRAME_SOA 6 // SoA on MN |
| #define EPL_DLLK_TXFRAME_PREQ 7 // PReq on MN |
| #if(((EPL_MODULE_INTEGRATION) & (EPL_MODULE_NMT_MN)) != 0) |
| #define EPL_DLLK_TXFRAME_COUNT (7 + EPL_D_NMT_MaxCNNumber_U8 + 2) // on MN: 7 + MaxPReq of regular CNs + 1 Diag + 1 Router |
| #else |
| #define EPL_DLLK_TXFRAME_COUNT 5 // on CN: 5 |
| #endif |
| |
| #define EPL_DLLK_BUFLEN_EMPTY 0 // buffer is empty |
| #define EPL_DLLK_BUFLEN_FILLING 1 // just the buffer is being filled |
| #define EPL_DLLK_BUFLEN_MIN 60 // minimum ethernet frame length |
| |
| //--------------------------------------------------------------------------- |
| // local types |
| //--------------------------------------------------------------------------- |
| |
| typedef enum { |
| kEplDllGsInit = 0x00, // MN/CN: initialisation (< PreOp2) |
| kEplDllCsWaitPreq = 0x01, // CN: wait for PReq frame |
| kEplDllCsWaitSoc = 0x02, // CN: wait for SoC frame |
| kEplDllCsWaitSoa = 0x03, // CN: wait for SoA frame |
| kEplDllMsNonCyclic = 0x04, // MN: reduced EPL cycle (PreOp1) |
| kEplDllMsWaitSocTrig = 0x05, // MN: wait for SoC trigger (cycle timer) |
| kEplDllMsWaitPreqTrig = 0x06, // MN: wait for (first) PReq trigger (WaitSoCPReq_U32) |
| kEplDllMsWaitPres = 0x07, // MN: wait for PRes frame from CN |
| kEplDllMsWaitSoaTrig = 0x08, // MN: wait for SoA trigger (PRes transmitted) |
| kEplDllMsWaitAsndTrig = 0x09, // MN: wait for ASnd trigger (SoA transmitted) |
| kEplDllMsWaitAsnd = 0x0A, // MN: wait for ASnd frame if SoA contained invitation |
| |
| } tEplDllState; |
| |
| typedef struct { |
| u8 m_be_abSrcMac[6]; |
| tEdrvTxBuffer *m_pTxBuffer; // Buffers for Tx-Frames |
| unsigned int m_uiMaxTxFrames; |
| u8 m_bFlag1; // Flag 1 with EN, EC for PRes, StatusRes |
| u8 m_bMnFlag1; // Flag 1 with EA, ER from PReq, SoA of MN |
| u8 m_bFlag2; // Flag 2 with PR and RS for PRes, StatusRes, IdentRes |
| tEplDllConfigParam m_DllConfigParam; |
| tEplDllIdentParam m_DllIdentParam; |
| tEplDllState m_DllState; |
| tEplDllkCbAsync m_pfnCbAsync; |
| tEplDllAsndFilter m_aAsndFilter[EPL_DLL_MAX_ASND_SERVICE_ID]; |
| |
| #if (((EPL_MODULE_INTEGRATION) & (EPL_MODULE_NMT_MN)) != 0) |
| tEplDllkNodeInfo *m_pFirstNodeInfo; |
| tEplDllkNodeInfo *m_pCurNodeInfo; |
| tEplDllkNodeInfo m_aNodeInfo[EPL_NMT_MAX_NODE_ID]; |
| tEplDllReqServiceId m_LastReqServiceId; |
| unsigned int m_uiLastTargetNodeId; |
| #endif |
| |
| #if EPL_TIMER_USE_HIGHRES != FALSE |
| tEplTimerHdl m_TimerHdlCycle; // used for EPL cycle monitoring on CN and generation on MN |
| #if (((EPL_MODULE_INTEGRATION) & (EPL_MODULE_NMT_MN)) != 0) |
| tEplTimerHdl m_TimerHdlResponse; // used for CN response monitoring |
| #endif //(((EPL_MODULE_INTEGRATION) & (EPL_MODULE_NMT_MN)) != 0) |
| #endif |
| |
| unsigned int m_uiCycleCount; // cycle counter (needed for multiplexed cycle support) |
| unsigned long long m_ullFrameTimeout; // frame timeout (cycle length + loss of frame tolerance) |
| |
| } tEplDllkInstance; |
| |
| //--------------------------------------------------------------------------- |
| // local vars |
| //--------------------------------------------------------------------------- |
| |
| // if no dynamic memory allocation shall be used |
| // define structures statically |
| static tEplDllkInstance EplDllkInstance_g; |
| |
| static tEdrvTxBuffer aEplDllkTxBuffer_l[EPL_DLLK_TXFRAME_COUNT]; |
| |
| //--------------------------------------------------------------------------- |
| // local function prototypes |
| //--------------------------------------------------------------------------- |
| |
| // change DLL state on event |
| static tEplKernel EplDllkChangeState(tEplNmtEvent NmtEvent_p, |
| tEplNmtState NmtState_p); |
| |
| // called from EdrvInterruptHandler() |
| static void EplDllkCbFrameReceived(tEdrvRxBuffer * pRxBuffer_p); |
| |
| // called from EdrvInterruptHandler() |
| static void EplDllkCbFrameTransmitted(tEdrvTxBuffer * pTxBuffer_p); |
| |
| // check frame and set missing information |
| static tEplKernel EplDllkCheckFrame(tEplFrame * pFrame_p, |
| unsigned int uiFrameSize_p); |
| |
| // called by high resolution timer module to monitor EPL cycle as CN |
| #if EPL_TIMER_USE_HIGHRES != FALSE |
| static tEplKernel EplDllkCbCnTimer(tEplTimerEventArg *pEventArg_p); |
| #endif |
| |
| #if (((EPL_MODULE_INTEGRATION) & (EPL_MODULE_NMT_MN)) != 0) |
| // MN: returns internal node info structure |
| static tEplDllkNodeInfo *EplDllkGetNodeInfo(unsigned int uiNodeId_p); |
| |
| // transmit SoA |
| static tEplKernel EplDllkMnSendSoa(tEplNmtState NmtState_p, |
| tEplDllState * pDllStateProposed_p, |
| BOOL fEnableInvitation_p); |
| |
| static tEplKernel EplDllkMnSendSoc(void); |
| |
| static tEplKernel EplDllkMnSendPreq(tEplNmtState NmtState_p, |
| tEplDllState * pDllStateProposed_p); |
| |
| static tEplKernel EplDllkAsyncFrameNotReceived(tEplDllReqServiceId |
| ReqServiceId_p, |
| unsigned int uiNodeId_p); |
| |
| static tEplKernel EplDllkCbMnTimerCycle(tEplTimerEventArg *pEventArg_p); |
| |
| static tEplKernel EplDllkCbMnTimerResponse(tEplTimerEventArg *pEventArg_p); |
| |
| #endif |
| |
| //=========================================================================// |
| // // |
| // P U B L I C F U N C T I O N S // |
| // // |
| //=========================================================================// |
| |
| //--------------------------------------------------------------------------- |
| // |
| // Function: EplDllkAddInstance() |
| // |
| // Description: add and initialize new instance of EPL stack |
| // |
| // Parameters: pInitParam_p = initialisation parameters like MAC address |
| // |
| // Returns: tEplKernel = error code |
| // |
| // |
| // State: |
| // |
| //--------------------------------------------------------------------------- |
| |
| tEplKernel EplDllkAddInstance(tEplDllkInitParam * pInitParam_p) |
| { |
| tEplKernel Ret = kEplSuccessful; |
| unsigned int uiIndex; |
| tEdrvInitParam EdrvInitParam; |
| |
| // reset instance structure |
| EPL_MEMSET(&EplDllkInstance_g, 0, sizeof(EplDllkInstance_g)); |
| |
| #if EPL_TIMER_USE_HIGHRES != FALSE |
| Ret = EplTimerHighReskInit(); |
| if (Ret != kEplSuccessful) { // error occured while initializing high resolution timer module |
| goto Exit; |
| } |
| #endif |
| |
| // if dynamic memory allocation available |
| // allocate instance structure |
| // allocate TPDO and RPDO table with default size |
| |
| // initialize and link pointers in instance structure to frame tables |
| EplDllkInstance_g.m_pTxBuffer = aEplDllkTxBuffer_l; |
| EplDllkInstance_g.m_uiMaxTxFrames = |
| sizeof(aEplDllkTxBuffer_l) / sizeof(tEdrvTxBuffer); |
| |
| // initialize state |
| EplDllkInstance_g.m_DllState = kEplDllGsInit; |
| |
| #if (((EPL_MODULE_INTEGRATION) & (EPL_MODULE_NMT_MN)) != 0) |
| // set up node info structure |
| for (uiIndex = 0; uiIndex < tabentries(EplDllkInstance_g.m_aNodeInfo); |
| uiIndex++) { |
| EplDllkInstance_g.m_aNodeInfo[uiIndex].m_uiNodeId = uiIndex + 1; |
| EplDllkInstance_g.m_aNodeInfo[uiIndex].m_wPresPayloadLimit = |
| 0xFFFF; |
| } |
| #endif |
| |
| // initialize Edrv |
| EPL_MEMCPY(EdrvInitParam.m_abMyMacAddr, pInitParam_p->m_be_abSrcMac, 6); |
| EdrvInitParam.m_pfnRxHandler = EplDllkCbFrameReceived; |
| EdrvInitParam.m_pfnTxHandler = EplDllkCbFrameTransmitted; |
| Ret = EdrvInit(&EdrvInitParam); |
| if (Ret != kEplSuccessful) { // error occured while initializing ethernet driver |
| goto Exit; |
| } |
| // copy local MAC address from Ethernet driver back to local instance structure |
| // because Ethernet driver may have read it from controller EEPROM |
| EPL_MEMCPY(EplDllkInstance_g.m_be_abSrcMac, EdrvInitParam.m_abMyMacAddr, |
| 6); |
| EPL_MEMCPY(pInitParam_p->m_be_abSrcMac, EdrvInitParam.m_abMyMacAddr, 6); |
| |
| // initialize TxBuffer array |
| for (uiIndex = 0; uiIndex < EplDllkInstance_g.m_uiMaxTxFrames; |
| uiIndex++) { |
| EplDllkInstance_g.m_pTxBuffer[uiIndex].m_pbBuffer = NULL; |
| } |
| |
| #if (((EPL_MODULE_INTEGRATION) & (EPL_MODULE_VETH)) != 0) |
| Ret = VEthAddInstance(pInitParam_p); |
| #endif |
| |
| Exit: |
| return Ret; |
| } |
| |
| //--------------------------------------------------------------------------- |
| // |
| // Function: EplDllkDelInstance() |
| // |
| // Description: deletes an instance of EPL stack |
| // |
| // Parameters: (none) |
| // |
| // Returns: tEplKernel = error code |
| // |
| // |
| // State: |
| // |
| //--------------------------------------------------------------------------- |
| |
| tEplKernel EplDllkDelInstance(void) |
| { |
| tEplKernel Ret = kEplSuccessful; |
| |
| // reset state |
| EplDllkInstance_g.m_DllState = kEplDllGsInit; |
| |
| #if EPL_TIMER_USE_HIGHRES != FALSE |
| Ret = EplTimerHighReskDelInstance(); |
| #endif |
| |
| #if (((EPL_MODULE_INTEGRATION) & (EPL_MODULE_VETH)) != 0) |
| Ret = VEthDelInstance(); |
| #endif |
| |
| Ret = EdrvShutdown(); |
| return Ret; |
| } |
| |
| //--------------------------------------------------------------------------- |
| // |
| // Function: EplDllkCreateTxFrame |
| // |
| // Description: creates the buffer for a Tx frame and registers it to the |
| // ethernet driver |
| // |
| // Parameters: puiHandle_p = OUT: handle to frame buffer |
| // ppFrame_p = OUT: pointer to pointer of EPL frame |
| // puiFrameSize_p = IN/OUT: pointer to size of frame |
| // returned size is always equal or larger than |
| // requested size, if that is not possible |
| // an error will be returned |
| // MsgType_p = EPL message type |
| // ServiceId_p = Service ID in case of ASnd frame, otherwise |
| // kEplDllAsndNotDefined |
| // |
| // Returns: tEplKernel = error code |
| // |
| // |
| // State: |
| // |
| //--------------------------------------------------------------------------- |
| |
| tEplKernel EplDllkCreateTxFrame(unsigned int *puiHandle_p, |
| tEplFrame ** ppFrame_p, |
| unsigned int *puiFrameSize_p, |
| tEplMsgType MsgType_p, |
| tEplDllAsndServiceId ServiceId_p) |
| { |
| tEplKernel Ret = kEplSuccessful; |
| tEplFrame *pTxFrame; |
| unsigned int uiHandle = EplDllkInstance_g.m_uiMaxTxFrames; |
| tEdrvTxBuffer *pTxBuffer = NULL; |
| |
| if (MsgType_p == kEplMsgTypeAsnd) { |
| // search for fixed Tx buffers |
| if (ServiceId_p == kEplDllAsndIdentResponse) { |
| uiHandle = EPL_DLLK_TXFRAME_IDENTRES; |
| } else if (ServiceId_p == kEplDllAsndStatusResponse) { |
| uiHandle = EPL_DLLK_TXFRAME_STATUSRES; |
| } else if ((ServiceId_p == kEplDllAsndNmtRequest) |
| || (ServiceId_p == kEplDllAsndNmtCommand)) { |
| uiHandle = EPL_DLLK_TXFRAME_NMTREQ; |
| } |
| |
| if (uiHandle >= EplDllkInstance_g.m_uiMaxTxFrames) { // look for free entry |
| uiHandle = EPL_DLLK_TXFRAME_PREQ; |
| pTxBuffer = &EplDllkInstance_g.m_pTxBuffer[uiHandle]; |
| for (; uiHandle < EplDllkInstance_g.m_uiMaxTxFrames; |
| uiHandle++, pTxBuffer++) { |
| if (pTxBuffer->m_pbBuffer == NULL) { // free entry found |
| break; |
| } |
| } |
| } |
| } else if (MsgType_p == kEplMsgTypeNonEpl) { |
| uiHandle = EPL_DLLK_TXFRAME_NONEPL; |
| } else if (MsgType_p == kEplMsgTypePres) { |
| uiHandle = EPL_DLLK_TXFRAME_PRES; |
| } else if (MsgType_p == kEplMsgTypeSoc) { |
| uiHandle = EPL_DLLK_TXFRAME_SOC; |
| } else if (MsgType_p == kEplMsgTypeSoa) { |
| uiHandle = EPL_DLLK_TXFRAME_SOA; |
| } else { // look for free entry |
| uiHandle = EPL_DLLK_TXFRAME_PREQ; |
| pTxBuffer = &EplDllkInstance_g.m_pTxBuffer[uiHandle]; |
| for (; uiHandle < EplDllkInstance_g.m_uiMaxTxFrames; |
| uiHandle++, pTxBuffer++) { |
| if (pTxBuffer->m_pbBuffer == NULL) { // free entry found |
| break; |
| } |
| } |
| if (pTxBuffer->m_pbBuffer != NULL) { |
| Ret = kEplEdrvNoFreeBufEntry; |
| goto Exit; |
| } |
| } |
| |
| // test if requested entry is free |
| pTxBuffer = &EplDllkInstance_g.m_pTxBuffer[uiHandle]; |
| if (pTxBuffer->m_pbBuffer != NULL) { // entry is not free |
| Ret = kEplEdrvNoFreeBufEntry; |
| goto Exit; |
| } |
| // setup Tx buffer |
| pTxBuffer->m_EplMsgType = MsgType_p; |
| pTxBuffer->m_uiMaxBufferLen = *puiFrameSize_p; |
| |
| Ret = EdrvAllocTxMsgBuffer(pTxBuffer); |
| if (Ret != kEplSuccessful) { // error occured while registering Tx frame |
| goto Exit; |
| } |
| // because buffer size may be larger than requested |
| // memorize real length of frame |
| pTxBuffer->m_uiTxMsgLen = *puiFrameSize_p; |
| |
| // fill whole frame with 0 |
| EPL_MEMSET(pTxBuffer->m_pbBuffer, 0, pTxBuffer->m_uiMaxBufferLen); |
| |
| pTxFrame = (tEplFrame *) pTxBuffer->m_pbBuffer; |
| |
| if (MsgType_p != kEplMsgTypeNonEpl) { // fill out Frame only if it is an EPL frame |
| // ethertype |
| AmiSetWordToBe(&pTxFrame->m_be_wEtherType, |
| EPL_C_DLL_ETHERTYPE_EPL); |
| // source node ID |
| AmiSetByteToLe(&pTxFrame->m_le_bSrcNodeId, |
| (u8) EplDllkInstance_g.m_DllConfigParam. |
| m_uiNodeId); |
| // source MAC address |
| EPL_MEMCPY(&pTxFrame->m_be_abSrcMac[0], |
| &EplDllkInstance_g.m_be_abSrcMac[0], 6); |
| switch (MsgType_p) { |
| case kEplMsgTypeAsnd: |
| // destination MAC address |
| AmiSetQword48ToBe(&pTxFrame->m_be_abDstMac[0], |
| EPL_C_DLL_MULTICAST_ASND); |
| // destination node ID |
| switch (ServiceId_p) { |
| case kEplDllAsndIdentResponse: |
| case kEplDllAsndStatusResponse: |
| { // IdentResponses and StatusResponses are Broadcast |
| AmiSetByteToLe(&pTxFrame-> |
| m_le_bDstNodeId, |
| (u8) |
| EPL_C_ADR_BROADCAST); |
| break; |
| } |
| |
| default: |
| break; |
| } |
| // ASnd Service ID |
| AmiSetByteToLe(&pTxFrame->m_Data.m_Asnd.m_le_bServiceId, |
| ServiceId_p); |
| break; |
| |
| case kEplMsgTypeSoc: |
| // destination MAC address |
| AmiSetQword48ToBe(&pTxFrame->m_be_abDstMac[0], |
| EPL_C_DLL_MULTICAST_SOC); |
| // destination node ID |
| AmiSetByteToLe(&pTxFrame->m_le_bDstNodeId, |
| (u8) EPL_C_ADR_BROADCAST); |
| // reset Flags |
| //AmiSetByteToLe(&pTxFrame->m_Data.m_Soc.m_le_bFlag1, (u8) 0); |
| //AmiSetByteToLe(&pTxFrame->m_Data.m_Soc.m_le_bFlag2, (u8) 0); |
| break; |
| |
| case kEplMsgTypeSoa: |
| // destination MAC address |
| AmiSetQword48ToBe(&pTxFrame->m_be_abDstMac[0], |
| EPL_C_DLL_MULTICAST_SOA); |
| // destination node ID |
| AmiSetByteToLe(&pTxFrame->m_le_bDstNodeId, |
| (u8) EPL_C_ADR_BROADCAST); |
| // reset Flags |
| //AmiSetByteToLe(&pTxFrame->m_Data.m_Soa.m_le_bFlag1, (u8) 0); |
| //AmiSetByteToLe(&pTxFrame->m_Data.m_Soa.m_le_bFlag2, (u8) 0); |
| // EPL profile version |
| AmiSetByteToLe(&pTxFrame->m_Data.m_Soa.m_le_bEplVersion, |
| (u8) EPL_SPEC_VERSION); |
| break; |
| |
| case kEplMsgTypePres: |
| // destination MAC address |
| AmiSetQword48ToBe(&pTxFrame->m_be_abDstMac[0], |
| EPL_C_DLL_MULTICAST_PRES); |
| // destination node ID |
| AmiSetByteToLe(&pTxFrame->m_le_bDstNodeId, |
| (u8) EPL_C_ADR_BROADCAST); |
| // reset Flags |
| //AmiSetByteToLe(&pTxFrame->m_Data.m_Pres.m_le_bFlag1, (u8) 0); |
| //AmiSetByteToLe(&pTxFrame->m_Data.m_Pres.m_le_bFlag2, (u8) 0); |
| // PDO size |
| //AmiSetWordToLe(&pTxFrame->m_Data.m_Pres.m_le_wSize, 0); |
| break; |
| |
| case kEplMsgTypePreq: |
| // reset Flags |
| //AmiSetByteToLe(&pTxFrame->m_Data.m_Preq.m_le_bFlag1, (u8) 0); |
| //AmiSetByteToLe(&pTxFrame->m_Data.m_Preq.m_le_bFlag2, (u8) 0); |
| // PDO size |
| //AmiSetWordToLe(&pTxFrame->m_Data.m_Preq.m_le_wSize, 0); |
| break; |
| |
| default: |
| break; |
| } |
| // EPL message type |
| AmiSetByteToLe(&pTxFrame->m_le_bMessageType, (u8) MsgType_p); |
| } |
| |
| *ppFrame_p = pTxFrame; |
| *puiFrameSize_p = pTxBuffer->m_uiMaxBufferLen; |
| *puiHandle_p = uiHandle; |
| |
| Exit: |
| return Ret; |
| } |
| |
| //--------------------------------------------------------------------------- |
| // |
| // Function: EplDllkDeleteTxFrame |
| // |
| // Description: deletes the buffer for a Tx frame and frees it in the |
| // ethernet driver |
| // |
| // Parameters: uiHandle_p = IN: handle to frame buffer |
| // |
| // Returns: tEplKernel = error code |
| // |
| // |
| // State: |
| // |
| //--------------------------------------------------------------------------- |
| |
| tEplKernel EplDllkDeleteTxFrame(unsigned int uiHandle_p) |
| { |
| tEplKernel Ret = kEplSuccessful; |
| tEdrvTxBuffer *pTxBuffer = NULL; |
| |
| if (uiHandle_p >= EplDllkInstance_g.m_uiMaxTxFrames) { // handle is not valid |
| Ret = kEplDllIllegalHdl; |
| goto Exit; |
| } |
| |
| pTxBuffer = &EplDllkInstance_g.m_pTxBuffer[uiHandle_p]; |
| |
| // mark buffer as free so that frame will not be send in future anymore |
| // $$$ d.k. What's up with running transmissions? |
| pTxBuffer->m_uiTxMsgLen = EPL_DLLK_BUFLEN_EMPTY; |
| pTxBuffer->m_pbBuffer = NULL; |
| |
| // delete Tx buffer |
| Ret = EdrvReleaseTxMsgBuffer(pTxBuffer); |
| if (Ret != kEplSuccessful) { // error occured while releasing Tx frame |
| goto Exit; |
| } |
| |
| Exit: |
| return Ret; |
| } |
| |
| //--------------------------------------------------------------------------- |
| // |
| // Function: EplDllkProcess |
| // |
| // Description: process the passed event |
| // |
| // Parameters: pEvent_p = event to be processed |
| // |
| // Returns: tEplKernel = error code |
| // |
| // |
| // State: |
| // |
| //--------------------------------------------------------------------------- |
| |
| tEplKernel EplDllkProcess(tEplEvent * pEvent_p) |
| { |
| tEplKernel Ret = kEplSuccessful; |
| tEplFrame *pTxFrame; |
| tEdrvTxBuffer *pTxBuffer; |
| unsigned int uiHandle; |
| unsigned int uiFrameSize; |
| u8 abMulticastMac[6]; |
| tEplDllAsyncReqPriority AsyncReqPriority; |
| unsigned int uiFrameCount; |
| tEplNmtState NmtState; |
| #if (((EPL_MODULE_INTEGRATION) & (EPL_MODULE_PDOK)) != 0) |
| tEplFrameInfo FrameInfo; |
| #endif |
| |
| switch (pEvent_p->m_EventType) { |
| case kEplEventTypeDllkCreate: |
| { |
| // $$$ reset ethernet driver |
| |
| NmtState = *((tEplNmtState *) pEvent_p->m_pArg); |
| |
| // initialize flags for PRes and StatusRes |
| EplDllkInstance_g.m_bFlag1 = EPL_FRAME_FLAG1_EC; |
| EplDllkInstance_g.m_bMnFlag1 = 0; |
| EplDllkInstance_g.m_bFlag2 = 0; |
| |
| #if (((EPL_MODULE_INTEGRATION) & (EPL_MODULE_NMT_MN)) != 0) |
| // initialize linked node list |
| EplDllkInstance_g.m_pFirstNodeInfo = NULL; |
| #endif |
| |
| // register TxFrames in Edrv |
| |
| // IdentResponse |
| uiFrameSize = EPL_C_DLL_MINSIZE_IDENTRES; |
| Ret = |
| EplDllkCreateTxFrame(&uiHandle, &pTxFrame, |
| &uiFrameSize, kEplMsgTypeAsnd, |
| kEplDllAsndIdentResponse); |
| if (Ret != kEplSuccessful) { // error occured while registering Tx frame |
| goto Exit; |
| } |
| // EPL profile version |
| AmiSetByteToLe(&pTxFrame->m_Data.m_Asnd.m_Payload. |
| m_IdentResponse.m_le_bEplProfileVersion, |
| (u8) EPL_SPEC_VERSION); |
| // FeatureFlags |
| AmiSetDwordToLe(&pTxFrame->m_Data.m_Asnd.m_Payload. |
| m_IdentResponse.m_le_dwFeatureFlags, |
| EplDllkInstance_g.m_DllConfigParam. |
| m_dwFeatureFlags); |
| // MTU |
| AmiSetWordToLe(&pTxFrame->m_Data.m_Asnd.m_Payload. |
| m_IdentResponse.m_le_wMtu, |
| (u16) EplDllkInstance_g. |
| m_DllConfigParam.m_uiAsyncMtu); |
| // PollInSize |
| AmiSetWordToLe(&pTxFrame->m_Data.m_Asnd.m_Payload. |
| m_IdentResponse.m_le_wPollInSize, |
| (u16) EplDllkInstance_g. |
| m_DllConfigParam. |
| m_uiPreqActPayloadLimit); |
| // PollOutSize |
| AmiSetWordToLe(&pTxFrame->m_Data.m_Asnd.m_Payload. |
| m_IdentResponse.m_le_wPollOutSize, |
| (u16) EplDllkInstance_g. |
| m_DllConfigParam. |
| m_uiPresActPayloadLimit); |
| // ResponseTime / PresMaxLatency |
| AmiSetDwordToLe(&pTxFrame->m_Data.m_Asnd.m_Payload. |
| m_IdentResponse.m_le_dwResponseTime, |
| EplDllkInstance_g.m_DllConfigParam. |
| m_dwPresMaxLatency); |
| // DeviceType |
| AmiSetDwordToLe(&pTxFrame->m_Data.m_Asnd.m_Payload. |
| m_IdentResponse.m_le_dwDeviceType, |
| EplDllkInstance_g.m_DllIdentParam. |
| m_dwDeviceType); |
| // VendorId |
| AmiSetDwordToLe(&pTxFrame->m_Data.m_Asnd.m_Payload. |
| m_IdentResponse.m_le_dwVendorId, |
| EplDllkInstance_g.m_DllIdentParam. |
| m_dwVendorId); |
| // ProductCode |
| AmiSetDwordToLe(&pTxFrame->m_Data.m_Asnd.m_Payload. |
| m_IdentResponse.m_le_dwProductCode, |
| EplDllkInstance_g.m_DllIdentParam. |
| m_dwProductCode); |
| // RevisionNumber |
| AmiSetDwordToLe(&pTxFrame->m_Data.m_Asnd.m_Payload. |
| m_IdentResponse.m_le_dwRevisionNumber, |
| EplDllkInstance_g.m_DllIdentParam. |
| m_dwRevisionNumber); |
| // SerialNumber |
| AmiSetDwordToLe(&pTxFrame->m_Data.m_Asnd.m_Payload. |
| m_IdentResponse.m_le_dwSerialNumber, |
| EplDllkInstance_g.m_DllIdentParam. |
| m_dwSerialNumber); |
| // VendorSpecificExt1 |
| AmiSetQword64ToLe(&pTxFrame->m_Data.m_Asnd.m_Payload. |
| m_IdentResponse. |
| m_le_qwVendorSpecificExt1, |
| EplDllkInstance_g.m_DllIdentParam. |
| m_qwVendorSpecificExt1); |
| // VerifyConfigurationDate |
| AmiSetDwordToLe(&pTxFrame->m_Data.m_Asnd.m_Payload. |
| m_IdentResponse. |
| m_le_dwVerifyConfigurationDate, |
| EplDllkInstance_g.m_DllIdentParam. |
| m_dwVerifyConfigurationDate); |
| // VerifyConfigurationTime |
| AmiSetDwordToLe(&pTxFrame->m_Data.m_Asnd.m_Payload. |
| m_IdentResponse. |
| m_le_dwVerifyConfigurationTime, |
| EplDllkInstance_g.m_DllIdentParam. |
| m_dwVerifyConfigurationTime); |
| // ApplicationSwDate |
| AmiSetDwordToLe(&pTxFrame->m_Data.m_Asnd.m_Payload. |
| m_IdentResponse. |
| m_le_dwApplicationSwDate, |
| EplDllkInstance_g.m_DllIdentParam. |
| m_dwApplicationSwDate); |
| // ApplicationSwTime |
| AmiSetDwordToLe(&pTxFrame->m_Data.m_Asnd.m_Payload. |
| m_IdentResponse. |
| m_le_dwApplicationSwTime, |
| EplDllkInstance_g.m_DllIdentParam. |
| m_dwApplicationSwTime); |
| // IPAddress |
| AmiSetDwordToLe(&pTxFrame->m_Data.m_Asnd.m_Payload. |
| m_IdentResponse.m_le_dwIpAddress, |
| EplDllkInstance_g.m_DllIdentParam. |
| m_dwIpAddress); |
| // SubnetMask |
| AmiSetDwordToLe(&pTxFrame->m_Data.m_Asnd.m_Payload. |
| m_IdentResponse.m_le_dwSubnetMask, |
| EplDllkInstance_g.m_DllIdentParam. |
| m_dwSubnetMask); |
| // DefaultGateway |
| AmiSetDwordToLe(&pTxFrame->m_Data.m_Asnd.m_Payload. |
| m_IdentResponse.m_le_dwDefaultGateway, |
| EplDllkInstance_g.m_DllIdentParam. |
| m_dwDefaultGateway); |
| // HostName |
| EPL_MEMCPY(&pTxFrame->m_Data.m_Asnd.m_Payload. |
| m_IdentResponse.m_le_sHostname[0], |
| &EplDllkInstance_g.m_DllIdentParam. |
| m_sHostname[0], |
| sizeof(EplDllkInstance_g.m_DllIdentParam. |
| m_sHostname)); |
| // VendorSpecificExt2 |
| EPL_MEMCPY(&pTxFrame->m_Data.m_Asnd.m_Payload. |
| m_IdentResponse.m_le_abVendorSpecificExt2[0], |
| &EplDllkInstance_g.m_DllIdentParam. |
| m_abVendorSpecificExt2[0], |
| sizeof(EplDllkInstance_g.m_DllIdentParam. |
| m_abVendorSpecificExt2)); |
| |
| // StatusResponse |
| uiFrameSize = EPL_C_DLL_MINSIZE_STATUSRES; |
| Ret = |
| EplDllkCreateTxFrame(&uiHandle, &pTxFrame, |
| &uiFrameSize, kEplMsgTypeAsnd, |
| kEplDllAsndStatusResponse); |
| if (Ret != kEplSuccessful) { // error occured while registering Tx frame |
| goto Exit; |
| } |
| // PRes $$$ maybe move this to PDO module |
| if ((EplDllkInstance_g.m_DllConfigParam.m_fAsyncOnly == |
| FALSE) |
| && (EplDllkInstance_g.m_DllConfigParam.m_uiPresActPayloadLimit >= 36)) { // it is not configured as async-only CN, |
| // so take part in isochronous phase and register PRes frame |
| uiFrameSize = |
| EplDllkInstance_g.m_DllConfigParam. |
| m_uiPresActPayloadLimit + 24; |
| Ret = |
| EplDllkCreateTxFrame(&uiHandle, &pTxFrame, |
| &uiFrameSize, |
| kEplMsgTypePres, |
| kEplDllAsndNotDefined); |
| if (Ret != kEplSuccessful) { // error occured while registering Tx frame |
| goto Exit; |
| } |
| #if (((EPL_MODULE_INTEGRATION) & (EPL_MODULE_PDOK)) != 0) |
| // initially encode TPDO -> inform PDO module |
| FrameInfo.m_pFrame = pTxFrame; |
| FrameInfo.m_uiFrameSize = uiFrameSize; |
| Ret = EplPdokCbPdoTransmitted(&FrameInfo); |
| #endif |
| // reset cycle counter |
| EplDllkInstance_g.m_uiCycleCount = 0; |
| } else { // it is an async-only CN |
| // fool EplDllkChangeState() to think that PRes was not expected |
| EplDllkInstance_g.m_uiCycleCount = 1; |
| } |
| |
| // NMT request |
| uiFrameSize = EPL_C_IP_MAX_MTU; |
| Ret = |
| EplDllkCreateTxFrame(&uiHandle, &pTxFrame, |
| &uiFrameSize, kEplMsgTypeAsnd, |
| kEplDllAsndNmtRequest); |
| if (Ret != kEplSuccessful) { // error occured while registering Tx frame |
| goto Exit; |
| } |
| // mark Tx buffer as empty |
| EplDllkInstance_g.m_pTxBuffer[uiHandle].m_uiTxMsgLen = |
| EPL_DLLK_BUFLEN_EMPTY; |
| |
| // non-EPL frame |
| uiFrameSize = EPL_C_IP_MAX_MTU; |
| Ret = |
| EplDllkCreateTxFrame(&uiHandle, &pTxFrame, |
| &uiFrameSize, |
| kEplMsgTypeNonEpl, |
| kEplDllAsndNotDefined); |
| if (Ret != kEplSuccessful) { // error occured while registering Tx frame |
| goto Exit; |
| } |
| // mark Tx buffer as empty |
| EplDllkInstance_g.m_pTxBuffer[uiHandle].m_uiTxMsgLen = |
| EPL_DLLK_BUFLEN_EMPTY; |
| |
| // register multicast MACs in ethernet driver |
| AmiSetQword48ToBe(&abMulticastMac[0], |
| EPL_C_DLL_MULTICAST_SOC); |
| Ret = EdrvDefineRxMacAddrEntry(abMulticastMac); |
| AmiSetQword48ToBe(&abMulticastMac[0], |
| EPL_C_DLL_MULTICAST_SOA); |
| Ret = EdrvDefineRxMacAddrEntry(abMulticastMac); |
| AmiSetQword48ToBe(&abMulticastMac[0], |
| EPL_C_DLL_MULTICAST_PRES); |
| Ret = EdrvDefineRxMacAddrEntry(abMulticastMac); |
| AmiSetQword48ToBe(&abMulticastMac[0], |
| EPL_C_DLL_MULTICAST_ASND); |
| Ret = EdrvDefineRxMacAddrEntry(abMulticastMac); |
| |
| #if (((EPL_MODULE_INTEGRATION) & (EPL_MODULE_NMT_MN)) != 0) |
| if (NmtState >= kEplNmtMsNotActive) { // local node is MN |
| unsigned int uiIndex; |
| |
| // SoC |
| uiFrameSize = EPL_C_DLL_MINSIZE_SOC; |
| Ret = |
| EplDllkCreateTxFrame(&uiHandle, &pTxFrame, |
| &uiFrameSize, |
| kEplMsgTypeSoc, |
| kEplDllAsndNotDefined); |
| if (Ret != kEplSuccessful) { // error occured while registering Tx frame |
| goto Exit; |
| } |
| // SoA |
| uiFrameSize = EPL_C_DLL_MINSIZE_SOA; |
| Ret = |
| EplDllkCreateTxFrame(&uiHandle, &pTxFrame, |
| &uiFrameSize, |
| kEplMsgTypeSoa, |
| kEplDllAsndNotDefined); |
| if (Ret != kEplSuccessful) { // error occured while registering Tx frame |
| goto Exit; |
| } |
| |
| for (uiIndex = 0; |
| uiIndex < |
| tabentries(EplDllkInstance_g.m_aNodeInfo); |
| uiIndex++) { |
| // EplDllkInstance_g.m_aNodeInfo[uiIndex].m_uiNodeId = uiIndex + 1; |
| EplDllkInstance_g.m_aNodeInfo[uiIndex]. |
| m_wPresPayloadLimit = |
| (u16) EplDllkInstance_g. |
| m_DllConfigParam. |
| m_uiIsochrRxMaxPayload; |
| } |
| |
| // calculate cycle length |
| EplDllkInstance_g.m_ullFrameTimeout = 1000LL |
| * |
| ((unsigned long long)EplDllkInstance_g. |
| m_DllConfigParam.m_dwCycleLen); |
| } |
| #endif //(((EPL_MODULE_INTEGRATION) & (EPL_MODULE_NMT_MN)) != 0) |
| |
| Ret = EplDllkCalAsyncClearBuffer(); |
| |
| break; |
| } |
| |
| case kEplEventTypeDllkDestroy: |
| { |
| // destroy all data structures |
| |
| NmtState = *((tEplNmtState *) pEvent_p->m_pArg); |
| |
| // delete Tx frames |
| Ret = EplDllkDeleteTxFrame(EPL_DLLK_TXFRAME_IDENTRES); |
| if (Ret != kEplSuccessful) { // error occured while deregistering Tx frame |
| goto Exit; |
| } |
| |
| Ret = EplDllkDeleteTxFrame(EPL_DLLK_TXFRAME_STATUSRES); |
| if (Ret != kEplSuccessful) { // error occured while deregistering Tx frame |
| goto Exit; |
| } |
| |
| Ret = EplDllkDeleteTxFrame(EPL_DLLK_TXFRAME_PRES); |
| if (Ret != kEplSuccessful) { // error occured while deregistering Tx frame |
| goto Exit; |
| } |
| |
| Ret = EplDllkDeleteTxFrame(EPL_DLLK_TXFRAME_NMTREQ); |
| if (Ret != kEplSuccessful) { // error occured while deregistering Tx frame |
| goto Exit; |
| } |
| |
| Ret = EplDllkDeleteTxFrame(EPL_DLLK_TXFRAME_NONEPL); |
| if (Ret != kEplSuccessful) { // error occured while deregistering Tx frame |
| goto Exit; |
| } |
| #if (((EPL_MODULE_INTEGRATION) & (EPL_MODULE_NMT_MN)) != 0) |
| if (NmtState >= kEplNmtMsNotActive) { // local node was MN |
| unsigned int uiIndex; |
| |
| Ret = |
| EplDllkDeleteTxFrame(EPL_DLLK_TXFRAME_SOC); |
| if (Ret != kEplSuccessful) { // error occured while deregistering Tx frame |
| goto Exit; |
| } |
| |
| Ret = |
| EplDllkDeleteTxFrame(EPL_DLLK_TXFRAME_SOA); |
| if (Ret != kEplSuccessful) { // error occured while deregistering Tx frame |
| goto Exit; |
| } |
| |
| for (uiIndex = 0; |
| uiIndex < |
| tabentries(EplDllkInstance_g.m_aNodeInfo); |
| uiIndex++) { |
| if (EplDllkInstance_g. |
| m_aNodeInfo[uiIndex]. |
| m_pPreqTxBuffer != NULL) { |
| uiHandle = |
| EplDllkInstance_g. |
| m_aNodeInfo[uiIndex]. |
| m_pPreqTxBuffer - |
| EplDllkInstance_g. |
| m_pTxBuffer; |
| EplDllkInstance_g. |
| m_aNodeInfo[uiIndex]. |
| m_pPreqTxBuffer = NULL; |
| Ret = |
| EplDllkDeleteTxFrame |
| (uiHandle); |
| if (Ret != kEplSuccessful) { // error occured while deregistering Tx frame |
| goto Exit; |
| } |
| |
| } |
| EplDllkInstance_g.m_aNodeInfo[uiIndex]. |
| m_wPresPayloadLimit = 0xFFFF; |
| } |
| } |
| #endif //(((EPL_MODULE_INTEGRATION) & (EPL_MODULE_NMT_MN)) != 0) |
| |
| // deregister multicast MACs in ethernet driver |
| AmiSetQword48ToBe(&abMulticastMac[0], |
| EPL_C_DLL_MULTICAST_SOC); |
| Ret = EdrvUndefineRxMacAddrEntry(abMulticastMac); |
| AmiSetQword48ToBe(&abMulticastMac[0], |
| EPL_C_DLL_MULTICAST_SOA); |
| Ret = EdrvUndefineRxMacAddrEntry(abMulticastMac); |
| AmiSetQword48ToBe(&abMulticastMac[0], |
| EPL_C_DLL_MULTICAST_PRES); |
| Ret = EdrvUndefineRxMacAddrEntry(abMulticastMac); |
| AmiSetQword48ToBe(&abMulticastMac[0], |
| EPL_C_DLL_MULTICAST_ASND); |
| Ret = EdrvUndefineRxMacAddrEntry(abMulticastMac); |
| |
| // delete timer |
| #if EPL_TIMER_USE_HIGHRES != FALSE |
| Ret = |
| EplTimerHighReskDeleteTimer(&EplDllkInstance_g. |
| m_TimerHdlCycle); |
| #endif |
| |
| break; |
| } |
| |
| case kEplEventTypeDllkFillTx: |
| { |
| // fill TxBuffer of specified priority with new frame if empty |
| |
| pTxFrame = NULL; |
| AsyncReqPriority = |
| *((tEplDllAsyncReqPriority *) pEvent_p->m_pArg); |
| switch (AsyncReqPriority) { |
| case kEplDllAsyncReqPrioNmt: // NMT request priority |
| { |
| pTxBuffer = |
| &EplDllkInstance_g. |
| m_pTxBuffer |
| [EPL_DLLK_TXFRAME_NMTREQ]; |
| if (pTxBuffer->m_pbBuffer != NULL) { // NmtRequest does exist |
| // check if frame is empty and not being filled |
| if (pTxBuffer->m_uiTxMsgLen == |
| EPL_DLLK_BUFLEN_EMPTY) { |
| // mark Tx buffer as filling is in process |
| pTxBuffer-> |
| m_uiTxMsgLen = |
| EPL_DLLK_BUFLEN_FILLING; |
| // set max buffer size as input parameter |
| uiFrameSize = |
| pTxBuffer-> |
| m_uiMaxBufferLen; |
| // copy frame from shared loop buffer to Tx buffer |
| Ret = |
| EplDllkCalAsyncGetTxFrame |
| (pTxBuffer-> |
| m_pbBuffer, |
| &uiFrameSize, |
| AsyncReqPriority); |
| if (Ret == |
| kEplSuccessful) { |
| pTxFrame = |
| (tEplFrame |
| *) |
| pTxBuffer-> |
| m_pbBuffer; |
| Ret = |
| EplDllkCheckFrame |
| (pTxFrame, |
| uiFrameSize); |
| |
| // set buffer valid |
| pTxBuffer-> |
| m_uiTxMsgLen |
| = |
| uiFrameSize; |
| } else if (Ret == kEplDllAsyncTxBufferEmpty) { // empty Tx buffer is not a real problem |
| // so just ignore it |
| Ret = |
| kEplSuccessful; |
| // mark Tx buffer as empty |
| pTxBuffer-> |
| m_uiTxMsgLen |
| = |
| EPL_DLLK_BUFLEN_EMPTY; |
| } |
| } |
| } |
| break; |
| } |
| |
| default: // generic priority |
| { |
| pTxBuffer = |
| &EplDllkInstance_g. |
| m_pTxBuffer |
| [EPL_DLLK_TXFRAME_NONEPL]; |
| if (pTxBuffer->m_pbBuffer != NULL) { // non-EPL frame does exist |
| // check if frame is empty and not being filled |
| if (pTxBuffer->m_uiTxMsgLen == |
| EPL_DLLK_BUFLEN_EMPTY) { |
| // mark Tx buffer as filling is in process |
| pTxBuffer-> |
| m_uiTxMsgLen = |
| EPL_DLLK_BUFLEN_FILLING; |
| // set max buffer size as input parameter |
| uiFrameSize = |
| pTxBuffer-> |
| m_uiMaxBufferLen; |
| // copy frame from shared loop buffer to Tx buffer |
| Ret = |
| EplDllkCalAsyncGetTxFrame |
| (pTxBuffer-> |
| m_pbBuffer, |
| &uiFrameSize, |
| AsyncReqPriority); |
| if (Ret == |
| kEplSuccessful) { |
| pTxFrame = |
| (tEplFrame |
| *) |
| pTxBuffer-> |
| m_pbBuffer; |
| Ret = |
| EplDllkCheckFrame |
| (pTxFrame, |
| uiFrameSize); |
| |
| // set buffer valid |
| pTxBuffer-> |
| m_uiTxMsgLen |
| = |
| uiFrameSize; |
| } else if (Ret == kEplDllAsyncTxBufferEmpty) { // empty Tx buffer is not a real problem |
| // so just ignore it |
| Ret = |
| kEplSuccessful; |
| // mark Tx buffer as empty |
| pTxBuffer-> |
| m_uiTxMsgLen |
| = |
| EPL_DLLK_BUFLEN_EMPTY; |
| } |
| } |
| } |
| break; |
| } |
| } |
| |
| NmtState = EplNmtkGetNmtState(); |
| |
| if ((NmtState == kEplNmtCsBasicEthernet) || (NmtState == kEplNmtMsBasicEthernet)) { // send frame immediately |
| if (pTxFrame != NULL) { // frame is present |
| // padding is done by Edrv or ethernet controller |
| Ret = EdrvSendTxMsg(pTxBuffer); |
| } else { // no frame moved to TxBuffer |
| // check if TxBuffers contain unsent frames |
| if (EplDllkInstance_g.m_pTxBuffer[EPL_DLLK_TXFRAME_NMTREQ].m_uiTxMsgLen > EPL_DLLK_BUFLEN_EMPTY) { // NMT request Tx buffer contains a frame |
| Ret = |
| EdrvSendTxMsg |
| (&EplDllkInstance_g. |
| m_pTxBuffer |
| [EPL_DLLK_TXFRAME_NMTREQ]); |
| } else if (EplDllkInstance_g.m_pTxBuffer[EPL_DLLK_TXFRAME_NONEPL].m_uiTxMsgLen > EPL_DLLK_BUFLEN_EMPTY) { // non-EPL Tx buffer contains a frame |
| Ret = |
| EdrvSendTxMsg |
| (&EplDllkInstance_g. |
| m_pTxBuffer |
| [EPL_DLLK_TXFRAME_NONEPL]); |
| } |
| if (Ret == kEplInvalidOperation) { // ignore error if caused by already active transmission |
| Ret = kEplSuccessful; |
| } |
| } |
| // reset PRes flag 2 |
| EplDllkInstance_g.m_bFlag2 = 0; |
| } else { |
| // update Flag 2 (PR, RS) |
| Ret = |
| EplDllkCalAsyncGetTxCount(&AsyncReqPriority, |
| &uiFrameCount); |
| if (AsyncReqPriority == kEplDllAsyncReqPrioNmt) { // non-empty FIFO with hightest priority is for NMT requests |
| if (EplDllkInstance_g.m_pTxBuffer[EPL_DLLK_TXFRAME_NMTREQ].m_uiTxMsgLen > EPL_DLLK_BUFLEN_EMPTY) { // NMT request Tx buffer contains a frame |
| // add one more frame |
| uiFrameCount++; |
| } |
| } else { // non-empty FIFO with highest priority is for generic frames |
| if (EplDllkInstance_g.m_pTxBuffer[EPL_DLLK_TXFRAME_NMTREQ].m_uiTxMsgLen > EPL_DLLK_BUFLEN_EMPTY) { // NMT request Tx buffer contains a frame |
| // use NMT request FIFO, because of higher priority |
| uiFrameCount = 1; |
| AsyncReqPriority = |
| kEplDllAsyncReqPrioNmt; |
| } else if (EplDllkInstance_g.m_pTxBuffer[EPL_DLLK_TXFRAME_NONEPL].m_uiTxMsgLen > EPL_DLLK_BUFLEN_EMPTY) { // non-EPL Tx buffer contains a frame |
| // use NMT request FIFO, because of higher priority |
| // add one more frame |
| uiFrameCount++; |
| } |
| } |
| |
| if (uiFrameCount > 7) { // limit frame request to send counter to 7 |
| uiFrameCount = 7; |
| } |
| if (uiFrameCount > 0) { |
| EplDllkInstance_g.m_bFlag2 = |
| (u8) (((AsyncReqPriority << |
| EPL_FRAME_FLAG2_PR_SHIFT) |
| & EPL_FRAME_FLAG2_PR) |
| | (uiFrameCount & |
| EPL_FRAME_FLAG2_RS)); |
| } else { |
| EplDllkInstance_g.m_bFlag2 = 0; |
| } |
| } |
| |
| break; |
| } |
| |
| #if (((EPL_MODULE_INTEGRATION) & (EPL_MODULE_NMT_MN)) != 0) |
| case kEplEventTypeDllkStartReducedCycle: |
| { |
| // start the reduced cycle by programming the cycle timer |
| // it is issued by NMT MN module, when PreOp1 is entered |
| |
| // clear the asynchronous queues |
| Ret = EplDllkCalAsyncClearQueues(); |
| |
| // reset cycle counter (everytime a SoA is triggerd in PreOp1 the counter is incremented |
| // and when it reaches EPL_C_DLL_PREOP1_START_CYCLES the SoA may contain invitations) |
| EplDllkInstance_g.m_uiCycleCount = 0; |
| |
| // remove any CN from isochronous phase |
| while (EplDllkInstance_g.m_pFirstNodeInfo != NULL) { |
| EplDllkDeleteNode(EplDllkInstance_g. |
| m_pFirstNodeInfo->m_uiNodeId); |
| } |
| |
| // change state to NonCyclic, |
| // hence EplDllkChangeState() will not ignore the next call |
| EplDllkInstance_g.m_DllState = kEplDllMsNonCyclic; |
| |
| #if EPL_TIMER_USE_HIGHRES != FALSE |
| if (EplDllkInstance_g.m_DllConfigParam. |
| m_dwAsyncSlotTimeout != 0) { |
| Ret = |
| EplTimerHighReskModifyTimerNs |
| (&EplDllkInstance_g.m_TimerHdlCycle, |
| EplDllkInstance_g.m_DllConfigParam. |
| m_dwAsyncSlotTimeout, |
| EplDllkCbMnTimerCycle, 0L, FALSE); |
| } |
| #endif |
| |
| break; |
| } |
| #endif |
| |
| #if EPL_DLL_PRES_READY_AFTER_SOA != FALSE |
| case kEplEventTypeDllkPresReady: |
| { |
| // post PRes to transmit FIFO |
| |
| NmtState = EplNmtkGetNmtState(); |
| |
| if (NmtState != kEplNmtCsBasicEthernet) { |
| // Does PRes exist? |
| if (EplDllkInstance_g.m_pTxBuffer[EPL_DLLK_TXFRAME_PRES].m_pbBuffer != NULL) { // PRes does exist |
| pTxFrame = |
| (tEplFrame *) EplDllkInstance_g. |
| m_pTxBuffer[EPL_DLLK_TXFRAME_PRES]. |
| m_pbBuffer; |
| // update frame (NMT state, RD, RS, PR, MS, EN flags) |
| if (NmtState < kEplNmtCsPreOperational2) { // NMT state is not PreOp2, ReadyToOp or Op |
| // fake NMT state PreOp2, because PRes will be sent only in PreOp2 or greater |
| NmtState = |
| kEplNmtCsPreOperational2; |
| } |
| AmiSetByteToLe(&pTxFrame->m_Data.m_Pres. |
| m_le_bNmtStatus, |
| (u8) NmtState); |
| AmiSetByteToLe(&pTxFrame->m_Data.m_Pres. |
| m_le_bFlag2, |
| EplDllkInstance_g. |
| m_bFlag2); |
| if (NmtState != kEplNmtCsOperational) { // mark PDO as invalid in NMT state Op |
| // $$$ reset only RD flag; set other flags appropriately |
| AmiSetByteToLe(&pTxFrame-> |
| m_Data.m_Pres. |
| m_le_bFlag1, 0); |
| } |
| // $$$ make function that updates Pres, StatusRes |
| // mark PRes frame as ready for transmission |
| Ret = |
| EdrvTxMsgReady(&EplDllkInstance_g. |
| m_pTxBuffer |
| [EPL_DLLK_TXFRAME_PRES]); |
| } |
| } |
| |
| break; |
| } |
| #endif |
| default: |
| { |
| ASSERTMSG(FALSE, |
| "EplDllkProcess(): unhandled event type!\n"); |
| } |
| } |
| |
| Exit: |
| return Ret; |
| } |
| |
| //--------------------------------------------------------------------------- |
| // |
| // Function: EplDllkConfig |
| // |
| // Description: configure parameters of DLL |
| // |
| // Parameters: pDllConfigParam_p = configuration parameters |
| // |
| // Returns: tEplKernel = error code |
| // |
| // |
| // State: |
| // |
| //--------------------------------------------------------------------------- |
| |
| tEplKernel EplDllkConfig(tEplDllConfigParam * pDllConfigParam_p) |
| { |
| tEplKernel Ret = kEplSuccessful; |
| |
| // d.k. check of NMT state disabled, because CycleLen is programmed at run time by MN without reset of CN |
| /*tEplNmtState NmtState; |
| |
| NmtState = EplNmtkGetNmtState(); |
| |
| if (NmtState > kEplNmtGsResetConfiguration) |
| { // only allowed in state DLL_GS_INIT |
| Ret = kEplInvalidOperation; |
| goto Exit; |
| } |
| */ |
| EPL_MEMCPY(&EplDllkInstance_g.m_DllConfigParam, pDllConfigParam_p, |
| (pDllConfigParam_p->m_uiSizeOfStruct < |
| sizeof(tEplDllConfigParam) ? pDllConfigParam_p-> |
| m_uiSizeOfStruct : sizeof(tEplDllConfigParam))); |
| |
| if ((EplDllkInstance_g.m_DllConfigParam.m_dwCycleLen != 0) |
| && (EplDllkInstance_g.m_DllConfigParam.m_dwLossOfFrameTolerance != 0)) { // monitor EPL cycle, calculate frame timeout |
| EplDllkInstance_g.m_ullFrameTimeout = (1000LL |
| * |
| ((unsigned long long) |
| EplDllkInstance_g. |
| m_DllConfigParam. |
| m_dwCycleLen)) |
| + |
| ((unsigned long long)EplDllkInstance_g.m_DllConfigParam. |
| m_dwLossOfFrameTolerance); |
| } else { |
| EplDllkInstance_g.m_ullFrameTimeout = 0LL; |
| } |
| |
| if (EplDllkInstance_g.m_DllConfigParam.m_fAsyncOnly != FALSE) { // it is configured as async-only CN |
| // disable multiplexed cycle, that m_uiCycleCount will not be incremented spuriously on SoC |
| EplDllkInstance_g.m_DllConfigParam.m_uiMultiplCycleCnt = 0; |
| } |
| //Exit: |
| return Ret; |
| } |
| |
| //--------------------------------------------------------------------------- |
| // |
| // Function: EplDllkSetIdentity |
| // |
| // Description: configure identity of local node for IdentResponse |
| // |
| // Parameters: pDllIdentParam_p = identity |
| // |
| // Returns: tEplKernel = error code |
| // |
| // |
| // State: |
| // |
| //--------------------------------------------------------------------------- |
| |
| tEplKernel EplDllkSetIdentity(tEplDllIdentParam * pDllIdentParam_p) |
| { |
| tEplKernel Ret = kEplSuccessful; |
| |
| EPL_MEMCPY(&EplDllkInstance_g.m_DllIdentParam, pDllIdentParam_p, |
| (pDllIdentParam_p->m_uiSizeOfStruct < |
| sizeof(tEplDllIdentParam) ? pDllIdentParam_p-> |
| m_uiSizeOfStruct : sizeof(tEplDllIdentParam))); |
| |
| // $$$ if IdentResponse frame exists update it |
| |
| return Ret; |
| } |
| |
| //--------------------------------------------------------------------------- |
| // |
| // Function: EplDllkRegAsyncHandler |
| // |
| // Description: registers handler for non-EPL frames |
| // |
| // Parameters: pfnDllkCbAsync_p = pointer to callback function |
| // |
| // Returns: tEplKernel = error code |
| // |
| // |
| // State: |
| // |
| //--------------------------------------------------------------------------- |
| |
| tEplKernel EplDllkRegAsyncHandler(tEplDllkCbAsync pfnDllkCbAsync_p) |
| { |
| tEplKernel Ret = kEplSuccessful; |
| |
| if (EplDllkInstance_g.m_pfnCbAsync == NULL) { // no handler registered yet |
| EplDllkInstance_g.m_pfnCbAsync = pfnDllkCbAsync_p; |
| } else { // handler already registered |
| Ret = kEplDllCbAsyncRegistered; |
| } |
| |
| return Ret; |
| } |
| |
| //--------------------------------------------------------------------------- |
| // |
| // Function: EplDllkDeregAsyncHandler |
| // |
| // Description: deregisters handler for non-EPL frames |
| // |
| // Parameters: pfnDllkCbAsync_p = pointer to callback function |
| // |
| // Returns: tEplKernel = error code |
| // |
| // |
| // State: |
| // |
| //--------------------------------------------------------------------------- |
| |
| tEplKernel EplDllkDeregAsyncHandler(tEplDllkCbAsync pfnDllkCbAsync_p) |
| { |
| tEplKernel Ret = kEplSuccessful; |
| |
| if (EplDllkInstance_g.m_pfnCbAsync == pfnDllkCbAsync_p) { // same handler is registered |
| // deregister it |
| EplDllkInstance_g.m_pfnCbAsync = NULL; |
| } else { // wrong handler or no handler registered |
| Ret = kEplDllCbAsyncRegistered; |
| } |
| |
| return Ret; |
| } |
| |
| //--------------------------------------------------------------------------- |
| // |
| // Function: EplDllkSetAsndServiceIdFilter() |
| // |
| // Description: sets the specified node ID filter for the specified |
| // AsndServiceId. It registers C_DLL_MULTICAST_ASND in ethernet |
| // driver if any AsndServiceId is open. |
| // |
| // Parameters: ServiceId_p = ASnd Service ID |
| // Filter_p = node ID filter |
| // |
| // Returns: tEplKernel = error code |
| // |
| // |
| // State: |
| // |
| //--------------------------------------------------------------------------- |
| |
| tEplKernel EplDllkSetAsndServiceIdFilter(tEplDllAsndServiceId ServiceId_p, |
| tEplDllAsndFilter Filter_p) |
| { |
| tEplKernel Ret = kEplSuccessful; |
| |
| if (ServiceId_p < tabentries(EplDllkInstance_g.m_aAsndFilter)) { |
| EplDllkInstance_g.m_aAsndFilter[ServiceId_p] = Filter_p; |
| } |
| |
| return Ret; |
| } |
| |
| #if (((EPL_MODULE_INTEGRATION) & (EPL_MODULE_NMT_MN)) != 0) |
| |
| //--------------------------------------------------------------------------- |
| // |
| // Function: EplDllkSetFlag1OfNode() |
| // |
| // Description: sets Flag1 (for PReq and SoA) of the specified node ID. |
| // |
| // Parameters: uiNodeId_p = node ID |
| // bSoaFlag1_p = flag1 |
| // |
| // Returns: tEplKernel = error code |
| // |
| // |
| // State: |
| // |
| //--------------------------------------------------------------------------- |
| |
| tEplKernel EplDllkSetFlag1OfNode(unsigned int uiNodeId_p, u8 bSoaFlag1_p) |
| { |
| tEplKernel Ret = kEplSuccessful; |
| tEplDllkNodeInfo *pNodeInfo; |
| |
| pNodeInfo = EplDllkGetNodeInfo(uiNodeId_p); |
| if (pNodeInfo == NULL) { // no node info structure available |
| Ret = kEplDllNoNodeInfo; |
| goto Exit; |
| } |
| // store flag1 in internal node info structure |
| pNodeInfo->m_bSoaFlag1 = bSoaFlag1_p; |
| |
| Exit: |
| return Ret; |
| } |
| |
| //--------------------------------------------------------------------------- |
| // |
| // Function: EplDllkGetFirstNodeInfo() |
| // |
| // Description: returns first info structure of first node in isochronous phase. |
| // It is only useful for ErrorHandlerk module. |
| // |
| // Parameters: ppNodeInfo_p = pointer to pointer of internal node info structure |
| // |
| // Returns: tEplKernel = error code |
| // |
| // |
| // State: |
| // |
| //--------------------------------------------------------------------------- |
| |
| tEplKernel EplDllkGetFirstNodeInfo(tEplDllkNodeInfo ** ppNodeInfo_p) |
| { |
| tEplKernel Ret = kEplSuccessful; |
| |
| *ppNodeInfo_p = EplDllkInstance_g.m_pFirstNodeInfo; |
| |
| return Ret; |
| } |
| |
| //--------------------------------------------------------------------------- |
| // |
| // Function: EplDllkAddNode() |
| // |
| // Description: adds the specified node to the isochronous phase. |
| // |
| // Parameters: pNodeInfo_p = pointer of node info structure |
| // |
| // Returns: tEplKernel = error code |
| // |
| // |
| // State: |
| // |
| //--------------------------------------------------------------------------- |
| |
| tEplKernel EplDllkAddNode(tEplDllNodeInfo * pNodeInfo_p) |
| { |
| tEplKernel Ret = kEplSuccessful; |
| tEplDllkNodeInfo *pIntNodeInfo; |
| tEplDllkNodeInfo **ppIntNodeInfo; |
| unsigned int uiHandle; |
| tEplFrame *pFrame; |
| unsigned int uiFrameSize; |
| |
| pIntNodeInfo = EplDllkGetNodeInfo(pNodeInfo_p->m_uiNodeId); |
| if (pIntNodeInfo == NULL) { // no node info structure available |
| Ret = kEplDllNoNodeInfo; |
| goto Exit; |
| } |
| |
| EPL_DLLK_DBG_POST_TRACE_VALUE(kEplEventTypeDllkAddNode, |
| pNodeInfo_p->m_uiNodeId, 0); |
| |
| // copy node configuration |
| pIntNodeInfo->m_dwPresTimeout = pNodeInfo_p->m_dwPresTimeout; |
| pIntNodeInfo->m_wPresPayloadLimit = pNodeInfo_p->m_wPresPayloadLimit; |
| |
| // $$$ d.k.: actually add node only if MN. On CN it is sufficient to update the node configuration |
| if (pNodeInfo_p->m_uiNodeId == EplDllkInstance_g.m_DllConfigParam.m_uiNodeId) { // we shall send PRes ourself |
| // insert our node at the end of the list |
| ppIntNodeInfo = &EplDllkInstance_g.m_pFirstNodeInfo; |
| while ((*ppIntNodeInfo != NULL) |
| && ((*ppIntNodeInfo)->m_pNextNodeInfo != NULL)) { |
| ppIntNodeInfo = &(*ppIntNodeInfo)->m_pNextNodeInfo; |
| } |
| if (*ppIntNodeInfo != NULL) { |
| if ((*ppIntNodeInfo)->m_uiNodeId == pNodeInfo_p->m_uiNodeId) { // node was already added to list |
| // $$$ d.k. maybe this should be an error |
| goto Exit; |
| } else { // add our node at the end of the list |
| ppIntNodeInfo = |
| &(*ppIntNodeInfo)->m_pNextNodeInfo; |
| } |
| } |
| // set "PReq"-TxBuffer to PRes-TxBuffer |
| pIntNodeInfo->m_pPreqTxBuffer = |
| &EplDllkInstance_g.m_pTxBuffer[EPL_DLLK_TXFRAME_PRES]; |
| } else { // normal CN shall be added to isochronous phase |
| // insert node into list in ascending order |
| ppIntNodeInfo = &EplDllkInstance_g.m_pFirstNodeInfo; |
| while ((*ppIntNodeInfo != NULL) |
| && ((*ppIntNodeInfo)->m_uiNodeId < |
| pNodeInfo_p->m_uiNodeId) |
| && ((*ppIntNodeInfo)->m_uiNodeId != |
| EplDllkInstance_g.m_DllConfigParam.m_uiNodeId)) { |
| ppIntNodeInfo = &(*ppIntNodeInfo)->m_pNextNodeInfo; |
| } |
| if ((*ppIntNodeInfo != NULL) && ((*ppIntNodeInfo)->m_uiNodeId == pNodeInfo_p->m_uiNodeId)) { // node was already added to list |
| // $$$ d.k. maybe this should be an error |
| goto Exit; |
| } |
| } |
| |
| // initialize elements of internal node info structure |
| pIntNodeInfo->m_bSoaFlag1 = 0; |
| pIntNodeInfo->m_fSoftDelete = FALSE; |
| pIntNodeInfo->m_NmtState = kEplNmtCsNotActive; |
| if (pIntNodeInfo->m_pPreqTxBuffer == NULL) { // create TxBuffer entry |
| uiFrameSize = pNodeInfo_p->m_wPreqPayloadLimit + 24; |
| Ret = |
| EplDllkCreateTxFrame(&uiHandle, &pFrame, &uiFrameSize, |
| kEplMsgTypePreq, |
| kEplDllAsndNotDefined); |
| if (Ret != kEplSuccessful) { |
| goto Exit; |
| } |
| pIntNodeInfo->m_pPreqTxBuffer = |
| &EplDllkInstance_g.m_pTxBuffer[uiHandle]; |
| AmiSetByteToLe(&pFrame->m_le_bDstNodeId, |
| (u8) pNodeInfo_p->m_uiNodeId); |
| |
| // set up destination MAC address |
| EPL_MEMCPY(pFrame->m_be_abDstMac, pIntNodeInfo->m_be_abMacAddr, |
| 6); |
| |
| #if (((EPL_MODULE_INTEGRATION) & (EPL_MODULE_PDOK)) != 0) |
| { |
| tEplFrameInfo FrameInfo; |
| |
| // initially encode TPDO -> inform PDO module |
| FrameInfo.m_pFrame = pFrame; |
| FrameInfo.m_uiFrameSize = uiFrameSize; |
| Ret = EplPdokCbPdoTransmitted(&FrameInfo); |
| } |
| #endif |
| } |
| pIntNodeInfo->m_ulDllErrorEvents = 0L; |
| // add node to list |
| pIntNodeInfo->m_pNextNodeInfo = *ppIntNodeInfo; |
| *ppIntNodeInfo = pIntNodeInfo; |
| |
| Exit: |
| return Ret; |
| } |
| |
| //--------------------------------------------------------------------------- |
| // |
| // Function: EplDllkDeleteNode() |
| // |
| // Description: removes the specified node from the isochronous phase. |
| // |
| // Parameters: uiNodeId_p = node ID |
| // |
| // Returns: tEplKernel = error code |
| // |
| // |
| // State: |
| // |
| //--------------------------------------------------------------------------- |
| |
| tEplKernel EplDllkDeleteNode(unsigned int uiNodeId_p) |
| { |
| tEplKernel Ret = kEplSuccessful; |
| tEplDllkNodeInfo *pIntNodeInfo; |
| tEplDllkNodeInfo **ppIntNodeInfo; |
| unsigned int uiHandle; |
| |
| pIntNodeInfo = EplDllkGetNodeInfo(uiNodeId_p); |
| if (pIntNodeInfo == NULL) { // no node info structure available |
| Ret = kEplDllNoNodeInfo; |
| goto Exit; |
| } |
| |
| EPL_DLLK_DBG_POST_TRACE_VALUE(kEplEventTypeDllkDelNode, uiNodeId_p, 0); |
| |
| // search node in whole list |
| ppIntNodeInfo = &EplDllkInstance_g.m_pFirstNodeInfo; |
| while ((*ppIntNodeInfo != NULL) |
| && ((*ppIntNodeInfo)->m_uiNodeId != uiNodeId_p)) { |
| ppIntNodeInfo = &(*ppIntNodeInfo)->m_pNextNodeInfo; |
| } |
| if ((*ppIntNodeInfo == NULL) || ((*ppIntNodeInfo)->m_uiNodeId != uiNodeId_p)) { // node was not found in list |
| // $$$ d.k. maybe this should be an error |
| goto Exit; |
| } |
| // remove node from list |
| *ppIntNodeInfo = pIntNodeInfo->m_pNextNodeInfo; |
| |
| if ((pIntNodeInfo->m_pPreqTxBuffer != NULL) |
| && (pIntNodeInfo->m_pPreqTxBuffer != &EplDllkInstance_g.m_pTxBuffer[EPL_DLLK_TXFRAME_PRES])) { // delete TxBuffer entry |
| uiHandle = |
| pIntNodeInfo->m_pPreqTxBuffer - |
| EplDllkInstance_g.m_pTxBuffer; |
| pIntNodeInfo->m_pPreqTxBuffer = NULL; |
| Ret = EplDllkDeleteTxFrame(uiHandle); |
| /* if (Ret != kEplSuccessful) |
| { |
| goto Exit; |
| }*/ |
| } |
| |
| Exit: |
| return Ret; |
| } |
| |
| //--------------------------------------------------------------------------- |
| // |
| // Function: EplDllkSoftDeleteNode() |
| // |
| // Description: removes the specified node not immediately from the isochronous phase. |
| // Instead the will be removed after error (late/loss PRes) without |
| // charging the error. |
| // |
| // Parameters: uiNodeId_p = node ID |
| // |
| // Returns: tEplKernel = error code |
| // |
| // |
| // State: |
| // |
| //--------------------------------------------------------------------------- |
| |
| tEplKernel EplDllkSoftDeleteNode(unsigned int uiNodeId_p) |
| { |
| tEplKernel Ret = kEplSuccessful; |
| tEplDllkNodeInfo *pIntNodeInfo; |
| |
| pIntNodeInfo = EplDllkGetNodeInfo(uiNodeId_p); |
| if (pIntNodeInfo == NULL) { // no node info structure available |
| Ret = kEplDllNoNodeInfo; |
| goto Exit; |
| } |
| |
| EPL_DLLK_DBG_POST_TRACE_VALUE(kEplEventTypeDllkSoftDelNode, |
| uiNodeId_p, 0); |
| |
| pIntNodeInfo->m_fSoftDelete = TRUE; |
| |
| Exit: |
| return Ret; |
| } |
| |
| #endif //(((EPL_MODULE_INTEGRATION) & (EPL_MODULE_NMT_MN)) != 0) |
| |
| //=========================================================================// |
| // // |
| // P R I V A T E F U N C T I O N S // |
| // // |
| //=========================================================================// |
| |
| //--------------------------------------------------------------------------- |
| // |
| // Function: EplDllkChangeState |
| // |
| // Description: change DLL state on event and diagnose some communication errors |
| // |
| // Parameters: NmtEvent_p = DLL event (wrapped in NMT event) |
| // |
| // Returns: tEplKernel = error code |
| // |
| // |
| // State: |
| // |
| //--------------------------------------------------------------------------- |
| |
| static tEplKernel EplDllkChangeState(tEplNmtEvent NmtEvent_p, |
| tEplNmtState NmtState_p) |
| { |
| tEplKernel Ret = kEplSuccessful; |
| tEplEvent Event; |
| tEplErrorHandlerkEvent DllEvent; |
| |
| DllEvent.m_ulDllErrorEvents = 0; |
| DllEvent.m_uiNodeId = 0; |
| DllEvent.m_NmtState = NmtState_p; |
| |
| switch (NmtState_p) { |
| case kEplNmtGsOff: |
| case kEplNmtGsInitialising: |
| case kEplNmtGsResetApplication: |
| case kEplNmtGsResetCommunication: |
| case kEplNmtGsResetConfiguration: |
| case kEplNmtCsBasicEthernet: |
| // enter DLL_GS_INIT |
| EplDllkInstance_g.m_DllState = kEplDllGsInit; |
| break; |
| |
| case kEplNmtCsNotActive: |
| case kEplNmtCsPreOperational1: |
| // reduced EPL cycle is active |
| if (NmtEvent_p == kEplNmtEventDllCeSoc) { // SoC received |
| // enter DLL_CS_WAIT_PREQ |
| EplDllkInstance_g.m_DllState = kEplDllCsWaitPreq; |
| } else { |
| // enter DLL_GS_INIT |
| EplDllkInstance_g.m_DllState = kEplDllGsInit; |
| } |
| break; |
| |
| case kEplNmtCsPreOperational2: |
| case kEplNmtCsReadyToOperate: |
| case kEplNmtCsOperational: |
| // full EPL cycle is active |
| |
| switch (EplDllkInstance_g.m_DllState) { |
| case kEplDllCsWaitPreq: |
| switch (NmtEvent_p) { |
| // DLL_CT2 |
| case kEplNmtEventDllCePreq: |
| // enter DLL_CS_WAIT_SOA |
| DllEvent.m_ulDllErrorEvents |= |
| EPL_DLL_ERR_CN_RECVD_PREQ; |
| EplDllkInstance_g.m_DllState = kEplDllCsWaitSoa; |
| break; |
| |
| // DLL_CT8 |
| case kEplNmtEventDllCeFrameTimeout: |
| if (NmtState_p == kEplNmtCsPreOperational2) { // ignore frame timeout in PreOp2, |
| // because the previously configured cycle len |
| // may be wrong. |
| // 2008/10/15 d.k. If it would not be ignored, |
| // we would go cyclically to PreOp1 and on next |
| // SoC back to PreOp2. |
| break; |
| } |
| // report DLL_CEV_LOSS_SOC and DLL_CEV_LOSS_SOA |
| DllEvent.m_ulDllErrorEvents |= |
| EPL_DLL_ERR_CN_LOSS_SOA | |
| EPL_DLL_ERR_CN_LOSS_SOC; |
| |
| // enter DLL_CS_WAIT_SOC |
| EplDllkInstance_g.m_DllState = kEplDllCsWaitSoc; |
| break; |
| |
| case kEplNmtEventDllCeSoa: |
| // check if multiplexed and PReq should have been received in this cycle |
| // and if >= NMT_CS_READY_TO_OPERATE |
| if ((EplDllkInstance_g.m_uiCycleCount == 0) |
| && (NmtState_p >= kEplNmtCsReadyToOperate)) { // report DLL_CEV_LOSS_OF_PREQ |
| DllEvent.m_ulDllErrorEvents |= |
| EPL_DLL_ERR_CN_LOSS_PREQ; |
| } |
| // enter DLL_CS_WAIT_SOC |
| EplDllkInstance_g.m_DllState = kEplDllCsWaitSoc; |
| break; |
| |
| // DLL_CT7 |
| case kEplNmtEventDllCeSoc: |
| case kEplNmtEventDllCeAsnd: |
| // report DLL_CEV_LOSS_SOA |
| DllEvent.m_ulDllErrorEvents |= |
| EPL_DLL_ERR_CN_LOSS_SOA; |
| |
| case kEplNmtEventDllCePres: |
| default: |
| // remain in this state |
| break; |
| } |
| break; |
| |
| case kEplDllCsWaitSoc: |
| switch (NmtEvent_p) { |
| // DLL_CT1 |
| case kEplNmtEventDllCeSoc: |
| // start of cycle and isochronous phase |
| // enter DLL_CS_WAIT_PREQ |
| EplDllkInstance_g.m_DllState = |
| kEplDllCsWaitPreq; |
| break; |
| |
| // DLL_CT4 |
| // case kEplNmtEventDllCePres: |
| case kEplNmtEventDllCeFrameTimeout: |
| if (NmtState_p == kEplNmtCsPreOperational2) { // ignore frame timeout in PreOp2, |
| // because the previously configured cycle len |
| // may be wrong. |
| // 2008/10/15 d.k. If it would not be ignored, |
| // we would go cyclically to PreOp1 and on next |
| // SoC back to PreOp2. |
| break; |
| } |
| // fall through |
| |
| case kEplNmtEventDllCePreq: |
| case kEplNmtEventDllCeSoa: |
| // report DLL_CEV_LOSS_SOC |
| DllEvent.m_ulDllErrorEvents |= |
| EPL_DLL_ERR_CN_LOSS_SOC; |
| |
| case kEplNmtEventDllCeAsnd: |
| default: |
| // remain in this state |
| break; |
| } |
| break; |
| |
| case kEplDllCsWaitSoa: |
| switch (NmtEvent_p) { |
| case kEplNmtEventDllCeFrameTimeout: |
| // DLL_CT3 |
| if (NmtState_p == kEplNmtCsPreOperational2) { // ignore frame timeout in PreOp2, |
| // because the previously configured cycle len |
| // may be wrong. |
| // 2008/10/15 d.k. If it would not be ignored, |
| // we would go cyclically to PreOp1 and on next |
| // SoC back to PreOp2. |
| break; |
| } |
| // fall through |
| |
| case kEplNmtEventDllCePreq: |
| // report DLL_CEV_LOSS_SOC and DLL_CEV_LOSS_SOA |
| DllEvent.m_ulDllErrorEvents |= |
| EPL_DLL_ERR_CN_LOSS_SOA | |
| EPL_DLL_ERR_CN_LOSS_SOC; |
| |
| case kEplNmtEventDllCeSoa: |
| // enter DLL_CS_WAIT_SOC |
| EplDllkInstance_g.m_DllState = kEplDllCsWaitSoc; |
| break; |
| |
| // DLL_CT9 |
| case kEplNmtEventDllCeSoc: |
| // report DLL_CEV_LOSS_SOA |
| DllEvent.m_ulDllErrorEvents |= |
| EPL_DLL_ERR_CN_LOSS_SOA; |
| |
| // enter DLL_CS_WAIT_PREQ |
| EplDllkInstance_g.m_DllState = |
| kEplDllCsWaitPreq; |
| break; |
| |
| // DLL_CT10 |
| case kEplNmtEventDllCeAsnd: |
| // report DLL_CEV_LOSS_SOA |
| DllEvent.m_ulDllErrorEvents |= |
| EPL_DLL_ERR_CN_LOSS_SOA; |
| |
| case kEplNmtEventDllCePres: |
| default: |
| // remain in this state |
| break; |
| } |
| break; |
| |
| case kEplDllGsInit: |
| // enter DLL_CS_WAIT_PREQ |
| EplDllkInstance_g.m_DllState = kEplDllCsWaitPreq; |
| break; |
| |
| default: |
| break; |
| } |
| break; |
| |
| case kEplNmtCsStopped: |
| // full EPL cycle is active, but without PReq/PRes |
| |
| switch (EplDllkInstance_g.m_DllState) { |
| case kEplDllCsWaitPreq: |
| switch (NmtEvent_p) { |
| // DLL_CT2 |
| case kEplNmtEventDllCePreq: |
| // enter DLL_CS_WAIT_SOA |
| EplDllkInstance_g.m_DllState = kEplDllCsWaitSoa; |
| break; |
| |
| // DLL_CT8 |
| case kEplNmtEventDllCeFrameTimeout: |
| // report DLL_CEV_LOSS_SOC and DLL_CEV_LOSS_SOA |
| DllEvent.m_ulDllErrorEvents |= |
| EPL_DLL_ERR_CN_LOSS_SOA | |
| EPL_DLL_ERR_CN_LOSS_SOC; |
| |
| case kEplNmtEventDllCeSoa: |
| // NMT_CS_STOPPED active |
| // it is Ok if no PReq was received |
| |
| // enter DLL_CS_WAIT_SOC |
| EplDllkInstance_g.m_DllState = kEplDllCsWaitSoc; |
| break; |
| |
| // DLL_CT7 |
| case kEplNmtEventDllCeSoc: |
| case kEplNmtEventDllCeAsnd: |
| // report DLL_CEV_LOSS_SOA |
| DllEvent.m_ulDllErrorEvents |= |
| EPL_DLL_ERR_CN_LOSS_SOA; |
| |
| case kEplNmtEventDllCePres: |
| default: |
| // remain in this state |
| break; |
| } |
| break; |
| |
| case kEplDllCsWaitSoc: |
| switch (NmtEvent_p) { |
| // DLL_CT1 |
| case kEplNmtEventDllCeSoc: |
| // start of cycle and isochronous phase |
| // enter DLL_CS_WAIT_SOA |
| EplDllkInstance_g.m_DllState = kEplDllCsWaitSoa; |
| break; |
| |
| // DLL_CT4 |
| // case kEplNmtEventDllCePres: |
| case kEplNmtEventDllCePreq: |
| case kEplNmtEventDllCeSoa: |
| case kEplNmtEventDllCeFrameTimeout: |
| // report DLL_CEV_LOSS_SOC |
| DllEvent.m_ulDllErrorEvents |= |
| EPL_DLL_ERR_CN_LOSS_SOC; |
| |
| case kEplNmtEventDllCeAsnd: |
| default: |
| // remain in this state |
| break; |
| } |
| break; |
| |
| case kEplDllCsWaitSoa: |
| switch (NmtEvent_p) { |
| // DLL_CT3 |
| case kEplNmtEventDllCeFrameTimeout: |
| // report DLL_CEV_LOSS_SOC and DLL_CEV_LOSS_SOA |
| DllEvent.m_ulDllErrorEvents |= |
| EPL_DLL_ERR_CN_LOSS_SOA | |
| EPL_DLL_ERR_CN_LOSS_SOC; |
| |
| case kEplNmtEventDllCeSoa: |
| // enter DLL_CS_WAIT_SOC |
| EplDllkInstance_g.m_DllState = kEplDllCsWaitSoc; |
| break; |
| |
| // DLL_CT9 |
| case kEplNmtEventDllCeSoc: |
| // report DLL_CEV_LOSS_SOA |
| DllEvent.m_ulDllErrorEvents |= |
| EPL_DLL_ERR_CN_LOSS_SOA; |
| // remain in DLL_CS_WAIT_SOA |
| break; |
| |
| // DLL_CT10 |
| case kEplNmtEventDllCeAsnd: |
| // report DLL_CEV_LOSS_SOA |
| DllEvent.m_ulDllErrorEvents |= |
| EPL_DLL_ERR_CN_LOSS_SOA; |
| |
| case kEplNmtEventDllCePreq: |
| // NMT_CS_STOPPED active and we do not expect any PReq |
| // so just ignore it |
| case kEplNmtEventDllCePres: |
| default: |
| // remain in this state |
| break; |
| } |
| break; |
| |
| case kEplDllGsInit: |
| default: |
| // enter DLL_CS_WAIT_PREQ |
| EplDllkInstance_g.m_DllState = kEplDllCsWaitSoa; |
| break; |
| } |
| break; |
| |
| #if (((EPL_MODULE_INTEGRATION) & (EPL_MODULE_NMT_MN)) != 0) |
| case kEplNmtMsNotActive: |
| case kEplNmtMsBasicEthernet: |
| break; |
| |
| case kEplNmtMsPreOperational1: |
| // reduced EPL cycle is active |
| if (EplDllkInstance_g.m_DllState != kEplDllMsNonCyclic) { // stop cycle timer |
| #if EPL_TIMER_USE_HIGHRES != FALSE |
| Ret = |
| EplTimerHighReskDeleteTimer(&EplDllkInstance_g. |
| m_TimerHdlCycle); |
| #endif |
| EplDllkInstance_g.m_DllState = kEplDllMsNonCyclic; |
| |
| // stop further processing, |
| // because it will be restarted by NMT MN module |
| break; |
| } |
| |
| switch (NmtEvent_p) { |
| case kEplNmtEventDllMeSocTrig: |
| case kEplNmtEventDllCeAsnd: |
| { // because of reduced EPL cycle SoA shall be triggered, not SoC |
| tEplDllState DummyDllState; |
| |
| Ret = |
| EplDllkAsyncFrameNotReceived |
| (EplDllkInstance_g.m_LastReqServiceId, |
| EplDllkInstance_g.m_uiLastTargetNodeId); |
| |
| // go ahead and send SoA |
| Ret = EplDllkMnSendSoa(NmtState_p, |
| &DummyDllState, |
| (EplDllkInstance_g. |
| m_uiCycleCount >= |
| EPL_C_DLL_PREOP1_START_CYCLES)); |
| // increment cycle counter to detect if EPL_C_DLL_PREOP1_START_CYCLES empty cycles are elapsed |
| EplDllkInstance_g.m_uiCycleCount++; |
| |
| // reprogram timer |
| #if EPL_TIMER_USE_HIGHRES != FALSE |
| if (EplDllkInstance_g.m_DllConfigParam. |
| m_dwAsyncSlotTimeout != 0) { |
| Ret = |
| EplTimerHighReskModifyTimerNs |
| (&EplDllkInstance_g.m_TimerHdlCycle, |
| EplDllkInstance_g.m_DllConfigParam. |
| m_dwAsyncSlotTimeout, |
| EplDllkCbMnTimerCycle, 0L, FALSE); |
| } |
| #endif |
| break; |
| } |
| |
| default: |
| break; |
| } |
| break; |
| |
| case kEplNmtMsPreOperational2: |
| case kEplNmtMsReadyToOperate: |
| case kEplNmtMsOperational: |
| // full EPL cycle is active |
| switch (NmtEvent_p) { |
| case kEplNmtEventDllMeSocTrig: |
| { |
| // update cycle counter |
| if (EplDllkInstance_g.m_DllConfigParam.m_uiMultiplCycleCnt > 0) { // multiplexed cycle active |
| EplDllkInstance_g.m_uiCycleCount = |
| (EplDllkInstance_g.m_uiCycleCount + |
| 1) % |
| EplDllkInstance_g.m_DllConfigParam. |
| m_uiMultiplCycleCnt; |
| // $$$ check multiplexed cycle restart |
| // -> toggle MC flag |
| // -> change node linked list |
| } else { // non-multiplexed cycle active |
| // start with first node in isochronous phase |
| EplDllkInstance_g.m_pCurNodeInfo = NULL; |
| } |
| |
| switch (EplDllkInstance_g.m_DllState) { |
| case kEplDllMsNonCyclic: |
| { // start continuous cycle timer |
| #if EPL_TIMER_USE_HIGHRES != FALSE |
| Ret = |
| EplTimerHighReskModifyTimerNs |
| (&EplDllkInstance_g. |
| m_TimerHdlCycle, |
| EplDllkInstance_g. |
| m_ullFrameTimeout, |
| EplDllkCbMnTimerCycle, 0L, |
| TRUE); |
| #endif |
| // continue with sending SoC |
| } |
| |
| case kEplDllMsWaitAsnd: |
| case kEplDllMsWaitSocTrig: |
| { // if m_LastReqServiceId is still valid, |
| // SoA was not correctly answered |
| // and user part has to be informed |
| Ret = |
| EplDllkAsyncFrameNotReceived |
| (EplDllkInstance_g. |
| m_LastReqServiceId, |
| EplDllkInstance_g. |
| m_uiLastTargetNodeId); |
| |
| // send SoC |
| Ret = EplDllkMnSendSoc(); |
| |
| // new DLL state |
| EplDllkInstance_g.m_DllState = |
| kEplDllMsWaitPreqTrig; |
| |
| // start WaitSoCPReq Timer |
| #if EPL_TIMER_USE_HIGHRES != FALSE |
| Ret = |
| EplTimerHighReskModifyTimerNs |
| (&EplDllkInstance_g. |
| m_TimerHdlResponse, |
| EplDllkInstance_g. |
| m_DllConfigParam. |
| m_dwWaitSocPreq, |
| EplDllkCbMnTimerResponse, |
| 0L, FALSE); |
| #endif |
| break; |
| } |
| |
| default: |
| { // wrong DLL state / cycle time exceeded |
| DllEvent.m_ulDllErrorEvents |= |
| EPL_DLL_ERR_MN_CYCTIMEEXCEED; |
| EplDllkInstance_g.m_DllState = |
| kEplDllMsWaitSocTrig; |
| break; |
| } |
| } |
| |
| break; |
| } |
| |
| case kEplNmtEventDllMePresTimeout: |
| { |
| |
| switch (EplDllkInstance_g.m_DllState) { |
| case kEplDllMsWaitPres: |
| { // PRes not received |
| |
| if (EplDllkInstance_g.m_pCurNodeInfo->m_fSoftDelete == FALSE) { // normal isochronous CN |
| DllEvent. |
| m_ulDllErrorEvents |
| |= |
| EPL_DLL_ERR_MN_CN_LOSS_PRES; |
| DllEvent.m_uiNodeId = |
| EplDllkInstance_g. |
| m_pCurNodeInfo-> |
| m_uiNodeId; |
| } else { // CN shall be deleted softly |
| Event.m_EventSink = |
| kEplEventSinkDllkCal; |
| Event.m_EventType = |
| kEplEventTypeDllkSoftDelNode; |
| // $$$ d.k. set Event.m_NetTime to current time |
| Event.m_uiSize = |
| sizeof(unsigned |
| int); |
| Event.m_pArg = |
| &EplDllkInstance_g. |
| m_pCurNodeInfo-> |
| m_uiNodeId; |
| Ret = |
| EplEventkPost |
| (&Event); |
| } |
| |
| // continue with sending next PReq |
| } |
| |
| case kEplDllMsWaitPreqTrig: |
| { |
| // send next PReq |
| Ret = |
| EplDllkMnSendPreq |
| (NmtState_p, |
| &EplDllkInstance_g. |
| m_DllState); |
| |
| break; |
| } |
| |
| default: |
| { // wrong DLL state |
| break; |
| } |
| } |
| |
| break; |
| } |
| |
| case kEplNmtEventDllCePres: |
| { |
| |
| switch (EplDllkInstance_g.m_DllState) { |
| case kEplDllMsWaitPres: |
| { // PRes received |
| // send next PReq |
| Ret = |
| EplDllkMnSendPreq |
| (NmtState_p, |
| &EplDllkInstance_g. |
| m_DllState); |
| |
| break; |
| } |
| |
| default: |
| { // wrong DLL state |
| break; |
| } |
| } |
| |
| break; |
| } |
| |
| case kEplNmtEventDllMeSoaTrig: |
| { |
| |
| switch (EplDllkInstance_g.m_DllState) { |
| case kEplDllMsWaitSoaTrig: |
| { // MN PRes sent |
| // send SoA |
| Ret = |
| EplDllkMnSendSoa(NmtState_p, |
| &EplDllkInstance_g. |
| m_DllState, |
| TRUE); |
| |
| break; |
| } |
| |
| default: |
| { // wrong DLL state |
| break; |
| } |
| } |
| |
| break; |
| } |
| |
| case kEplNmtEventDllCeAsnd: |
| { // ASnd has been received, but it may be not the requested one |
| /* |
| // report if SoA was correctly answered |
| Ret = EplDllkAsyncFrameNotReceived(EplDllkInstance_g.m_LastReqServiceId, |
| EplDllkInstance_g.m_uiLastTargetNodeId); |
| */ |
| if (EplDllkInstance_g.m_DllState == |
| kEplDllMsWaitAsnd) { |
| EplDllkInstance_g.m_DllState = |
| kEplDllMsWaitSocTrig; |
| } |
| break; |
| } |
| |
| default: |
| break; |
| } |
| break; |
| #endif //(((EPL_MODULE_INTEGRATION) & (EPL_MODULE_NMT_MN)) != 0) |
| |
| default: |
| break; |
| } |
| |
| if (DllEvent.m_ulDllErrorEvents != 0) { // error event set -> post it to error handler |
| Event.m_EventSink = kEplEventSinkErrk; |
| Event.m_EventType = kEplEventTypeDllError; |
| // $$$ d.k. set Event.m_NetTime to current time |
| Event.m_uiSize = sizeof(DllEvent); |
| Event.m_pArg = &DllEvent; |
| Ret = EplEventkPost(&Event); |
| } |
| |
| return Ret; |
| } |
| |
| //--------------------------------------------------------------------------- |
| // |
| // Function: EplDllkCbFrameReceived() |
| // |
| // Description: called from EdrvInterruptHandler() |
| // |
| // Parameters: pRxBuffer_p = receive buffer structure |
| // |
| // Returns: (none) |
| // |
| // |
| // State: |
| // |
| //--------------------------------------------------------------------------- |
| |
| static void EplDllkCbFrameReceived(tEdrvRxBuffer * pRxBuffer_p) |
| { |
| tEplKernel Ret = kEplSuccessful; |
| tEplNmtState NmtState; |
| tEplNmtEvent NmtEvent = kEplNmtEventNoEvent; |
| tEplEvent Event; |
| tEplFrame *pFrame; |
| tEplFrame *pTxFrame; |
| tEdrvTxBuffer *pTxBuffer = NULL; |
| tEplFrameInfo FrameInfo; |
| tEplMsgType MsgType; |
| tEplDllReqServiceId ReqServiceId; |
| unsigned int uiAsndServiceId; |
| unsigned int uiNodeId; |
| u8 bFlag1; |
| |
| BENCHMARK_MOD_02_SET(3); |
| NmtState = EplNmtkGetNmtState(); |
| |
| if (NmtState <= kEplNmtGsResetConfiguration) { |
| goto Exit; |
| } |
| |
| pFrame = (tEplFrame *) pRxBuffer_p->m_pbBuffer; |
| |
| #if EDRV_EARLY_RX_INT != FALSE |
| switch (pRxBuffer_p->m_BufferInFrame) { |
| case kEdrvBufferFirstInFrame: |
| { |
| MsgType = |
| (tEplMsgType) AmiGetByteFromLe(&pFrame-> |
| m_le_bMessageType); |
| if (MsgType == kEplMsgTypePreq) { |
| if (EplDllkInstance_g.m_DllState == kEplDllCsWaitPreq) { // PReq expected and actually received |
| // d.k.: The condition above is sufficent, because EPL cycle is active |
| // and no non-EPL frame shall be received in isochronous phase. |
| // start transmission PRes |
| // $$$ What if Tx buffer is invalid? |
| pTxBuffer = |
| &EplDllkInstance_g. |
| m_pTxBuffer[EPL_DLLK_TXFRAME_PRES]; |
| #if (EPL_DLL_PRES_READY_AFTER_SOA != FALSE) || (EPL_DLL_PRES_READY_AFTER_SOC != FALSE) |
| Ret = EdrvTxMsgStart(pTxBuffer); |
| #else |
| pTxFrame = |
| (tEplFrame *) pTxBuffer->m_pbBuffer; |
| // update frame (NMT state, RD, RS, PR, MS, EN flags) |
| AmiSetByteToLe(&pTxFrame->m_Data.m_Pres. |
| m_le_bNmtStatus, |
| (u8) NmtState); |
| AmiSetByteToLe(&pTxFrame->m_Data.m_Pres. |
| m_le_bFlag2, |
| EplDllkInstance_g. |
| m_bFlag2); |
| if (NmtState != kEplNmtCsOperational) { // mark PDO as invalid in NMT state Op |
| // $$$ reset only RD flag; set other flags appropriately |
| AmiSetByteToLe(&pTxFrame-> |
| m_Data.m_Pres. |
| m_le_bFlag1, 0); |
| } |
| // $$$ make function that updates Pres, StatusRes |
| // send PRes frame |
| Ret = EdrvSendTxMsg(pTxBuffer); |
| #endif |
| } |
| } |
| goto Exit; |
| } |
| |
| case kEdrvBufferMiddleInFrame: |
| { |
| goto Exit; |
| } |
| |
| case kEdrvBufferLastInFrame: |
| { |
| break; |
| } |
| } |
| #endif |
| |
| FrameInfo.m_pFrame = pFrame; |
| FrameInfo.m_uiFrameSize = pRxBuffer_p->m_uiRxMsgLen; |
| FrameInfo.m_NetTime.m_dwNanoSec = pRxBuffer_p->m_NetTime.m_dwNanoSec; |
| FrameInfo.m_NetTime.m_dwSec = pRxBuffer_p->m_NetTime.m_dwSec; |
| |
| if (AmiGetWordFromBe(&pFrame->m_be_wEtherType) != EPL_C_DLL_ETHERTYPE_EPL) { // non-EPL frame |
| //TRACE2("EplDllkCbFrameReceived: pfnCbAsync=0x%p SrcMAC=0x%llx\n", EplDllkInstance_g.m_pfnCbAsync, AmiGetQword48FromBe(pFrame->m_be_abSrcMac)); |
| if (EplDllkInstance_g.m_pfnCbAsync != NULL) { // handler for async frames is registered |
| EplDllkInstance_g.m_pfnCbAsync(&FrameInfo); |
| } |
| |
| goto Exit; |
| } |
| |
| MsgType = (tEplMsgType) AmiGetByteFromLe(&pFrame->m_le_bMessageType); |
| switch (MsgType) { |
| case kEplMsgTypePreq: |
| { |
| // PReq frame |
| // d.k.: (we assume that this PReq frame is intended for us and don't check DstNodeId) |
| if (AmiGetByteFromLe(&pFrame->m_le_bDstNodeId) != EplDllkInstance_g.m_DllConfigParam.m_uiNodeId) { // this PReq is not intended for us |
| goto Exit; |
| } |
| NmtEvent = kEplNmtEventDllCePreq; |
| |
| if (NmtState >= kEplNmtMsNotActive) { // MN is active -> wrong msg type |
| break; |
| } |
| #if EDRV_EARLY_RX_INT == FALSE |
| if (NmtState >= kEplNmtCsPreOperational2) { // respond to and process PReq frames only in PreOp2, ReadyToOp and Op |
| // Does PRes exist? |
| pTxBuffer = |
| &EplDllkInstance_g. |
| m_pTxBuffer[EPL_DLLK_TXFRAME_PRES]; |
| if (pTxBuffer->m_pbBuffer != NULL) { // PRes does exist |
| #if (EPL_DLL_PRES_READY_AFTER_SOA != FALSE) || (EPL_DLL_PRES_READY_AFTER_SOC != FALSE) |
| EdrvTxMsgStart(pTxBuffer); |
| #else |
| pTxFrame = |
| (tEplFrame *) pTxBuffer->m_pbBuffer; |
| // update frame (NMT state, RD, RS, PR, MS, EN flags) |
| AmiSetByteToLe(&pTxFrame->m_Data.m_Pres. |
| m_le_bNmtStatus, |
| (u8) NmtState); |
| AmiSetByteToLe(&pTxFrame->m_Data.m_Pres. |
| m_le_bFlag2, |
| EplDllkInstance_g. |
| m_bFlag2); |
| bFlag1 = |
| AmiGetByteFromLe(&pFrame->m_Data. |
| m_Preq. |
| m_le_bFlag1); |
| // save EA flag |
| EplDllkInstance_g.m_bMnFlag1 = |
| (EplDllkInstance_g. |
| m_bMnFlag1 & ~EPL_FRAME_FLAG1_EA) |
| | (bFlag1 & EPL_FRAME_FLAG1_EA); |
| // preserve MS flag |
| bFlag1 &= EPL_FRAME_FLAG1_MS; |
| // add EN flag from Error signaling module |
| bFlag1 |= |
| EplDllkInstance_g. |
| m_bFlag1 & EPL_FRAME_FLAG1_EN; |
| if (NmtState != kEplNmtCsOperational) { // mark PDO as invalid in NMT state Op |
| // reset only RD flag |
| AmiSetByteToLe(&pTxFrame-> |
| m_Data.m_Pres. |
| m_le_bFlag1, |
| bFlag1); |
| } else { // leave RD flag untouched |
| AmiSetByteToLe(&pTxFrame-> |
| m_Data.m_Pres. |
| m_le_bFlag1, |
| (AmiGetByteFromLe |
| (&pTxFrame-> |
| m_Data.m_Pres. |
| m_le_bFlag1) & |
| EPL_FRAME_FLAG1_RD) |
| | bFlag1); |
| } |
| // $$$ update EPL_DLL_PRES_READY_AFTER_* code |
| // send PRes frame |
| Ret = EdrvSendTxMsg(pTxBuffer); |
| if (Ret != kEplSuccessful) { |
| goto Exit; |
| } |
| #endif |
| } |
| #endif |
| // inform PDO module |
| #if (((EPL_MODULE_INTEGRATION) & (EPL_MODULE_PDOK)) != 0) |
| if (NmtState >= kEplNmtCsReadyToOperate) { // inform PDO module only in ReadyToOp and Op |
| if (NmtState != kEplNmtCsOperational) { |
| // reset RD flag and all other flags, but that does not matter, because they were processed above |
| AmiSetByteToLe(&pFrame->m_Data. |
| m_Preq. |
| m_le_bFlag1, 0); |
| } |
| // compares real frame size and PDO size |
| if ((unsigned |
| int)(AmiGetWordFromLe(&pFrame-> |
| m_Data. |
| m_Preq. |
| m_le_wSize) + |
| 24) |
| > FrameInfo.m_uiFrameSize) { // format error |
| tEplErrorHandlerkEvent DllEvent; |
| |
| DllEvent.m_ulDllErrorEvents = |
| EPL_DLL_ERR_INVALID_FORMAT; |
| DllEvent.m_uiNodeId = |
| AmiGetByteFromLe(&pFrame-> |
| m_le_bSrcNodeId); |
| DllEvent.m_NmtState = NmtState; |
| Event.m_EventSink = |
| kEplEventSinkErrk; |
| Event.m_EventType = |
| kEplEventTypeDllError; |
| Event.m_NetTime = |
| FrameInfo.m_NetTime; |
| Event.m_uiSize = |
| sizeof(DllEvent); |
| Event.m_pArg = &DllEvent; |
| Ret = EplEventkPost(&Event); |
| break; |
| } |
| // forward PReq frame as RPDO to PDO module |
| Ret = EplPdokCbPdoReceived(&FrameInfo); |
| |
| } |
| #if (EPL_DLL_PRES_READY_AFTER_SOC != FALSE) |
| if (pTxBuffer->m_pbBuffer != NULL) { // PRes does exist |
| // inform PDO module about PRes after PReq |
| FrameInfo.m_pFrame = |
| (tEplFrame *) pTxBuffer->m_pbBuffer; |
| FrameInfo.m_uiFrameSize = |
| pTxBuffer->m_uiMaxBufferLen; |
| Ret = |
| EplPdokCbPdoTransmitted(&FrameInfo); |
| } |
| #endif |
| #endif |
| |
| #if EDRV_EARLY_RX_INT == FALSE |
| // $$$ inform emergency protocol handling (error signaling module) about flags |
| } |
| #endif |
| |
| // reset cycle counter |
| EplDllkInstance_g.m_uiCycleCount = 0; |
| |
| break; |
| } |
| |
| case kEplMsgTypePres: |
| { |
| #if (((EPL_MODULE_INTEGRATION) & (EPL_MODULE_NMT_MN)) != 0) |
| tEplDllkNodeInfo *pIntNodeInfo; |
| tEplHeartbeatEvent HeartbeatEvent; |
| #endif |
| |
| // PRes frame |
| NmtEvent = kEplNmtEventDllCePres; |
| |
| uiNodeId = AmiGetByteFromLe(&pFrame->m_le_bSrcNodeId); |
| |
| if ((NmtState >= kEplNmtCsPreOperational2) |
| && (NmtState <= kEplNmtCsOperational)) { // process PRes frames only in PreOp2, ReadyToOp and Op of CN |
| |
| #if (((EPL_MODULE_INTEGRATION) & (EPL_MODULE_NMT_MN)) != 0) |
| pIntNodeInfo = EplDllkGetNodeInfo(uiNodeId); |
| if (pIntNodeInfo == NULL) { // no node info structure available |
| Ret = kEplDllNoNodeInfo; |
| goto Exit; |
| } |
| } else if (EplDllkInstance_g.m_DllState == kEplDllMsWaitPres) { // or process PRes frames in MsWaitPres |
| |
| pIntNodeInfo = EplDllkInstance_g.m_pCurNodeInfo; |
| if ((pIntNodeInfo == NULL) || (pIntNodeInfo->m_uiNodeId != uiNodeId)) { // ignore PRes, because it is from wrong CN |
| // $$$ maybe post event to NmtMn module |
| goto Exit; |
| } |
| // forward Flag2 to asynchronous scheduler |
| bFlag1 = |
| AmiGetByteFromLe(&pFrame->m_Data.m_Asnd. |
| m_Payload.m_StatusResponse. |
| m_le_bFlag2); |
| Ret = |
| EplDllkCalAsyncSetPendingRequests(uiNodeId, |
| ((tEplDllAsyncReqPriority) ((bFlag1 & EPL_FRAME_FLAG2_PR) >> EPL_FRAME_FLAG2_PR_SHIFT)), (bFlag1 & EPL_FRAME_FLAG2_RS)); |
| |
| #endif |
| } else { // ignore PRes, because it was received in wrong NMT state |
| // but execute EplDllkChangeState() and post event to NMT module |
| break; |
| } |
| |
| #if (((EPL_MODULE_INTEGRATION) & (EPL_MODULE_NMT_MN)) != 0) |
| { // check NMT state of CN |
| HeartbeatEvent.m_wErrorCode = EPL_E_NO_ERROR; |
| HeartbeatEvent.m_NmtState = |
| (tEplNmtState) (AmiGetByteFromLe |
| (&pFrame->m_Data.m_Pres. |
| m_le_bNmtStatus) | |
| EPL_NMT_TYPE_CS); |
| if (pIntNodeInfo->m_NmtState != HeartbeatEvent.m_NmtState) { // NMT state of CN has changed -> post event to NmtMnu module |
| if (pIntNodeInfo->m_fSoftDelete == FALSE) { // normal isochronous CN |
| HeartbeatEvent.m_uiNodeId = |
| uiNodeId; |
| Event.m_EventSink = |
| kEplEventSinkNmtMnu; |
| Event.m_EventType = |
| kEplEventTypeHeartbeat; |
| Event.m_uiSize = |
| sizeof(HeartbeatEvent); |
| Event.m_pArg = &HeartbeatEvent; |
| } else { // CN shall be deleted softly |
| Event.m_EventSink = |
| kEplEventSinkDllkCal; |
| Event.m_EventType = |
| kEplEventTypeDllkSoftDelNode; |
| Event.m_uiSize = |
| sizeof(unsigned int); |
| Event.m_pArg = |
| &pIntNodeInfo->m_uiNodeId; |
| } |
| Event.m_NetTime = FrameInfo.m_NetTime; |
| Ret = EplEventkPost(&Event); |
| |
| // save current NMT state of CN in internal node structure |
| pIntNodeInfo->m_NmtState = |
| HeartbeatEvent.m_NmtState; |
| } |
| } |
| #endif |
| |
| // inform PDO module |
| #if (((EPL_MODULE_INTEGRATION) & (EPL_MODULE_PDOK)) != 0) |
| if ((NmtState != kEplNmtCsPreOperational2) |
| && (NmtState != kEplNmtMsPreOperational2)) { // inform PDO module only in ReadyToOp and Op |
| // compare real frame size and PDO size? |
| if (((unsigned |
| int)(AmiGetWordFromLe(&pFrame->m_Data. |
| m_Pres.m_le_wSize) + |
| 24) |
| > FrameInfo.m_uiFrameSize) |
| #if (((EPL_MODULE_INTEGRATION) & (EPL_MODULE_NMT_MN)) != 0) |
| || |
| (AmiGetWordFromLe |
| (&pFrame->m_Data.m_Pres.m_le_wSize) > |
| pIntNodeInfo->m_wPresPayloadLimit) |
| #endif |
| ) { // format error |
| tEplErrorHandlerkEvent DllEvent; |
| |
| DllEvent.m_ulDllErrorEvents = |
| EPL_DLL_ERR_INVALID_FORMAT; |
| DllEvent.m_uiNodeId = uiNodeId; |
| DllEvent.m_NmtState = NmtState; |
| Event.m_EventSink = kEplEventSinkErrk; |
| Event.m_EventType = |
| kEplEventTypeDllError; |
| Event.m_NetTime = FrameInfo.m_NetTime; |
| Event.m_uiSize = sizeof(DllEvent); |
| Event.m_pArg = &DllEvent; |
| Ret = EplEventkPost(&Event); |
| break; |
| } |
| if ((NmtState != kEplNmtCsOperational) |
| && (NmtState != kEplNmtMsOperational)) { |
| // reset RD flag and all other flags, but that does not matter, because they were processed above |
| AmiSetByteToLe(&pFrame->m_Data.m_Pres. |
| m_le_bFlag1, 0); |
| } |
| Ret = EplPdokCbPdoReceived(&FrameInfo); |
| } |
| #endif |
| |
| break; |
| } |
| |
| case kEplMsgTypeSoc: |
| { |
| // SoC frame |
| NmtEvent = kEplNmtEventDllCeSoc; |
| |
| if (NmtState >= kEplNmtMsNotActive) { // MN is active -> wrong msg type |
| break; |
| } |
| #if EPL_DLL_PRES_READY_AFTER_SOC != FALSE |
| // post PRes to transmit FIFO of the ethernet controller, but don't start |
| // transmission over bus |
| pTxBuffer = |
| &EplDllkInstance_g. |
| m_pTxBuffer[EPL_DLLK_TXFRAME_PRES]; |
| // Does PRes exist? |
| if (pTxBuffer->m_pbBuffer != NULL) { // PRes does exist |
| pTxFrame = (tEplFrame *) pTxBuffer->m_pbBuffer; |
| // update frame (NMT state, RD, RS, PR, MS, EN flags) |
| if (NmtState < kEplNmtCsPreOperational2) { // NMT state is not PreOp2, ReadyToOp or Op |
| // fake NMT state PreOp2, because PRes will be sent only in PreOp2 or greater |
| NmtState = kEplNmtCsPreOperational2; |
| } |
| AmiSetByteToLe(&pTxFrame->m_Data.m_Pres. |
| m_le_bNmtStatus, |
| (u8) NmtState); |
| AmiSetByteToLe(&pTxFrame->m_Data.m_Pres. |
| m_le_bFlag2, |
| EplDllkInstance_g.m_bFlag2); |
| if (NmtState != kEplNmtCsOperational) { // mark PDO as invalid in NMT state Op |
| // $$$ reset only RD flag; set other flags appropriately |
| AmiSetByteToLe(&pTxFrame->m_Data.m_Pres. |
| m_le_bFlag1, 0); |
| } |
| // $$$ make function that updates Pres, StatusRes |
| // mark PRes frame as ready for transmission |
| Ret = EdrvTxMsgReady(pTxBuffer); |
| } |
| #endif |
| |
| if (NmtState >= kEplNmtCsPreOperational2) { // SoC frames only in PreOp2, ReadyToOp and Op |
| // trigger synchronous task |
| Event.m_EventSink = kEplEventSinkSync; |
| Event.m_EventType = kEplEventTypeSync; |
| Event.m_uiSize = 0; |
| Ret = EplEventkPost(&Event); |
| |
| // update cycle counter |
| if (EplDllkInstance_g.m_DllConfigParam.m_uiMultiplCycleCnt > 0) { // multiplexed cycle active |
| EplDllkInstance_g.m_uiCycleCount = |
| (EplDllkInstance_g.m_uiCycleCount + |
| 1) % |
| EplDllkInstance_g.m_DllConfigParam. |
| m_uiMultiplCycleCnt; |
| } |
| } |
| // reprogram timer |
| #if EPL_TIMER_USE_HIGHRES != FALSE |
| if (EplDllkInstance_g.m_ullFrameTimeout != 0) { |
| Ret = |
| EplTimerHighReskModifyTimerNs |
| (&EplDllkInstance_g.m_TimerHdlCycle, |
| EplDllkInstance_g.m_ullFrameTimeout, |
| EplDllkCbCnTimer, 0L, FALSE); |
| } |
| #endif |
| |
| break; |
| } |
| |
| case kEplMsgTypeSoa: |
| { |
| // SoA frame |
| NmtEvent = kEplNmtEventDllCeSoa; |
| |
| if (NmtState >= kEplNmtMsNotActive) { // MN is active -> wrong msg type |
| break; |
| } |
| |
| pTxFrame = NULL; |
| |
| if ((NmtState & EPL_NMT_SUPERSTATE_MASK) != EPL_NMT_CS_EPLMODE) { // do not respond, if NMT state is < PreOp1 (i.e. not EPL_MODE) |
| break; |
| } |
| // check TargetNodeId |
| uiNodeId = |
| AmiGetByteFromLe(&pFrame->m_Data.m_Soa. |
| m_le_bReqServiceTarget); |
| if (uiNodeId == EplDllkInstance_g.m_DllConfigParam.m_uiNodeId) { // local node is the target of the current request |
| |
| // check ServiceId |
| ReqServiceId = |
| (tEplDllReqServiceId) |
| AmiGetByteFromLe(&pFrame->m_Data.m_Soa. |
| m_le_bReqServiceId); |
| if (ReqServiceId == kEplDllReqServiceStatus) { // StatusRequest |
| if (EplDllkInstance_g.m_pTxBuffer[EPL_DLLK_TXFRAME_STATUSRES].m_pbBuffer != NULL) { // StatusRes does exist |
| |
| pTxFrame = |
| (tEplFrame *) |
| EplDllkInstance_g. |
| m_pTxBuffer |
| [EPL_DLLK_TXFRAME_STATUSRES]. |
| m_pbBuffer; |
| // update StatusRes frame (NMT state, EN, EC, RS, PR flags) |
| AmiSetByteToLe(&pTxFrame-> |
| m_Data.m_Asnd. |
| m_Payload. |
| m_StatusResponse. |
| m_le_bNmtStatus, |
| (u8) NmtState); |
| AmiSetByteToLe(&pTxFrame-> |
| m_Data.m_Asnd. |
| m_Payload. |
| m_StatusResponse. |
| m_le_bFlag1, |
| EplDllkInstance_g. |
| m_bFlag1); |
| AmiSetByteToLe(&pTxFrame-> |
| m_Data.m_Asnd. |
| m_Payload. |
| m_StatusResponse. |
| m_le_bFlag2, |
| EplDllkInstance_g. |
| m_bFlag2); |
| // send StatusRes |
| Ret = |
| EdrvSendTxMsg |
| (&EplDllkInstance_g. |
| m_pTxBuffer |
| [EPL_DLLK_TXFRAME_STATUSRES]); |
| if (Ret != kEplSuccessful) { |
| goto Exit; |
| } |
| TGT_DBG_SIGNAL_TRACE_POINT(8); |
| |
| // update error signaling |
| bFlag1 = |
| AmiGetByteFromLe(&pFrame-> |
| m_Data. |
| m_Soa. |
| m_le_bFlag1); |
| if (((bFlag1 ^ EplDllkInstance_g.m_bMnFlag1) & EPL_FRAME_FLAG1_ER) != 0) { // exception reset flag was changed by MN |
| // assume same state for EC in next cycle (clear all other bits) |
| if ((bFlag1 & |
| EPL_FRAME_FLAG1_ER) |
| != 0) { |
| // set EC and reset rest |
| EplDllkInstance_g. |
| m_bFlag1 = |
| EPL_FRAME_FLAG1_EC; |
| } else { |
| // reset complete flag 1 (including EC and EN) |
| EplDllkInstance_g. |
| m_bFlag1 = |
| 0; |
| } |
| } |
| // save flag 1 from MN for Status request response cycle |
| EplDllkInstance_g.m_bMnFlag1 = |
| bFlag1; |
| } |
| } else if (ReqServiceId == kEplDllReqServiceIdent) { // IdentRequest |
| if (EplDllkInstance_g.m_pTxBuffer[EPL_DLLK_TXFRAME_IDENTRES].m_pbBuffer != NULL) { // IdentRes does exist |
| pTxFrame = |
| (tEplFrame *) |
| EplDllkInstance_g. |
| m_pTxBuffer |
| [EPL_DLLK_TXFRAME_IDENTRES]. |
| m_pbBuffer; |
| // update IdentRes frame (NMT state, RS, PR flags) |
| AmiSetByteToLe(&pTxFrame-> |
| m_Data.m_Asnd. |
| m_Payload. |
| m_IdentResponse. |
| m_le_bNmtStatus, |
| (u8) NmtState); |
| AmiSetByteToLe(&pTxFrame-> |
| m_Data.m_Asnd. |
| m_Payload. |
| m_IdentResponse. |
| m_le_bFlag2, |
| EplDllkInstance_g. |
| m_bFlag2); |
| // send IdentRes |
| Ret = |
| EdrvSendTxMsg |
| (&EplDllkInstance_g. |
| m_pTxBuffer |
| [EPL_DLLK_TXFRAME_IDENTRES]); |
| if (Ret != kEplSuccessful) { |
| goto Exit; |
| } |
| TGT_DBG_SIGNAL_TRACE_POINT(7); |
| } |
| } else if (ReqServiceId == kEplDllReqServiceNmtRequest) { // NmtRequest |
| if (EplDllkInstance_g.m_pTxBuffer[EPL_DLLK_TXFRAME_NMTREQ].m_pbBuffer != NULL) { // NmtRequest does exist |
| // check if frame is not empty and not being filled |
| if (EplDllkInstance_g. |
| m_pTxBuffer |
| [EPL_DLLK_TXFRAME_NMTREQ]. |
| m_uiTxMsgLen > |
| EPL_DLLK_BUFLEN_FILLING) { |
| /*if (EplDllkInstance_g.m_pTxBuffer[EPL_DLLK_TXFRAME_NMTREQ].m_uiTxMsgLen < EPL_DLLK_BUFLEN_MIN) |
| { // pad frame |
| EplDllkInstance_g.m_pTxBuffer[EPL_DLLK_TXFRAME_NMTREQ].m_uiTxMsgLen = EPL_DLLK_BUFLEN_MIN; |
| } */ |
| // memorize transmission |
| pTxFrame = |
| (tEplFrame *) 1; |
| // send NmtRequest |
| Ret = |
| EdrvSendTxMsg |
| (&EplDllkInstance_g. |
| m_pTxBuffer |
| [EPL_DLLK_TXFRAME_NMTREQ]); |
| if (Ret != |
| kEplSuccessful) { |
| goto Exit; |
| } |
| |
| } |
| } |
| |
| } else if (ReqServiceId == kEplDllReqServiceUnspecified) { // unspecified invite |
| if (EplDllkInstance_g.m_pTxBuffer[EPL_DLLK_TXFRAME_NONEPL].m_pbBuffer != NULL) { // non-EPL frame does exist |
| // check if frame is not empty and not being filled |
| if (EplDllkInstance_g. |
| m_pTxBuffer |
| [EPL_DLLK_TXFRAME_NONEPL]. |
| m_uiTxMsgLen > |
| EPL_DLLK_BUFLEN_FILLING) { |
| /*if (EplDllkInstance_g.m_pTxBuffer[EPL_DLLK_TXFRAME_NMTREQ].m_uiTxMsgLen < EPL_DLLK_BUFLEN_MIN) |
| { // pad frame |
| EplDllkInstance_g.m_pTxBuffer[EPL_DLLK_TXFRAME_NMTREQ].m_uiTxMsgLen = EPL_DLLK_BUFLEN_MIN; |
| } */ |
| // memorize transmission |
| pTxFrame = |
| (tEplFrame *) 1; |
| // send non-EPL frame |
| Ret = |
| EdrvSendTxMsg |
| (&EplDllkInstance_g. |
| m_pTxBuffer |
| [EPL_DLLK_TXFRAME_NONEPL]); |
| if (Ret != |
| kEplSuccessful) { |
| goto Exit; |
| } |
| |
| } |
| } |
| |
| } else if (ReqServiceId == kEplDllReqServiceNo) { // no async service requested -> do nothing |
| } |
| } |
| #if EPL_DLL_PRES_READY_AFTER_SOA != FALSE |
| if (pTxFrame == NULL) { // signal process function readiness of PRes frame |
| Event.m_EventSink = kEplEventSinkDllk; |
| Event.m_EventType = kEplEventTypeDllkPresReady; |
| Event.m_uiSize = 0; |
| Event.m_pArg = NULL; |
| Ret = EplEventkPost(&Event); |
| } |
| #endif |
| |
| // inform PDO module |
| #if (((EPL_MODULE_INTEGRATION) & (EPL_MODULE_PDOK)) != 0) |
| // Ret = EplPdokCbSoa(&FrameInfo); |
| #endif |
| |
| // $$$ put SrcNodeId, NMT state and NetTime as HeartbeatEvent into eventqueue |
| |
| // $$$ inform emergency protocol handling about flags |
| break; |
| } |
| |
| case kEplMsgTypeAsnd: |
| { |
| // ASnd frame |
| NmtEvent = kEplNmtEventDllCeAsnd; |
| |
| // ASnd service registered? |
| uiAsndServiceId = |
| (unsigned int)AmiGetByteFromLe(&pFrame->m_Data. |
| m_Asnd. |
| m_le_bServiceId); |
| |
| #if (((EPL_MODULE_INTEGRATION) & (EPL_MODULE_NMT_MN)) != 0) |
| if ((EplDllkInstance_g.m_DllState >= kEplDllMsNonCyclic) |
| && |
| ((((tEplDllAsndServiceId) uiAsndServiceId) == |
| kEplDllAsndStatusResponse) |
| || (((tEplDllAsndServiceId) uiAsndServiceId) == kEplDllAsndIdentResponse))) { // StatusRes or IdentRes received |
| uiNodeId = |
| AmiGetByteFromLe(&pFrame->m_le_bSrcNodeId); |
| if ((EplDllkInstance_g.m_LastReqServiceId == |
| ((tEplDllReqServiceId) uiAsndServiceId)) |
| && (uiNodeId == EplDllkInstance_g.m_uiLastTargetNodeId)) { // mark request as responded |
| EplDllkInstance_g.m_LastReqServiceId = |
| kEplDllReqServiceNo; |
| } |
| if (((tEplDllAsndServiceId) uiAsndServiceId) == kEplDllAsndIdentResponse) { // memorize MAC address of CN for PReq |
| tEplDllkNodeInfo *pIntNodeInfo; |
| |
| pIntNodeInfo = |
| EplDllkGetNodeInfo(uiNodeId); |
| if (pIntNodeInfo == NULL) { // no node info structure available |
| Ret = kEplDllNoNodeInfo; |
| } else { |
| EPL_MEMCPY(pIntNodeInfo-> |
| m_be_abMacAddr, |
| pFrame-> |
| m_be_abSrcMac, 6); |
| } |
| } |
| // forward Flag2 to asynchronous scheduler |
| bFlag1 = |
| AmiGetByteFromLe(&pFrame->m_Data.m_Asnd. |
| m_Payload.m_StatusResponse. |
| m_le_bFlag2); |
| Ret = |
| EplDllkCalAsyncSetPendingRequests(uiNodeId, |
| ((tEplDllAsyncReqPriority) ((bFlag1 & EPL_FRAME_FLAG2_PR) >> EPL_FRAME_FLAG2_PR_SHIFT)), (bFlag1 & EPL_FRAME_FLAG2_RS)); |
| } |
| #endif |
| |
| if (uiAsndServiceId < EPL_DLL_MAX_ASND_SERVICE_ID) { // ASnd service ID is valid |
| if (EplDllkInstance_g.m_aAsndFilter[uiAsndServiceId] == kEplDllAsndFilterAny) { // ASnd service ID is registered |
| // forward frame via async receive FIFO to userspace |
| Ret = |
| EplDllkCalAsyncFrameReceived |
| (&FrameInfo); |
| } else if (EplDllkInstance_g.m_aAsndFilter[uiAsndServiceId] == kEplDllAsndFilterLocal) { // ASnd service ID is registered, but only local node ID or broadcasts |
| // shall be forwarded |
| uiNodeId = |
| AmiGetByteFromLe(&pFrame-> |
| m_le_bDstNodeId); |
| if ((uiNodeId == |
| EplDllkInstance_g.m_DllConfigParam. |
| m_uiNodeId) |
| || (uiNodeId == EPL_C_ADR_BROADCAST)) { // ASnd frame is intended for us |
| // forward frame via async receive FIFO to userspace |
| Ret = |
| EplDllkCalAsyncFrameReceived |
| (&FrameInfo); |
| } |
| } |
| } |
| break; |
| } |
| |
| default: |
| { |
| break; |
| } |
| } |
| |
| if (NmtEvent != kEplNmtEventNoEvent) { // event for DLL and NMT state machine generated |
| Ret = EplDllkChangeState(NmtEvent, NmtState); |
| if (Ret != kEplSuccessful) { |
| goto Exit; |
| } |
| |
| if ((NmtEvent != kEplNmtEventDllCeAsnd) |
| && ((NmtState <= kEplNmtCsPreOperational1) || (NmtEvent != kEplNmtEventDllCePres))) { // NMT state machine is not interested in ASnd frames and PRes frames when not CsNotActive or CsPreOp1 |
| // inform NMT module |
| Event.m_EventSink = kEplEventSinkNmtk; |
| Event.m_EventType = kEplEventTypeNmtEvent; |
| Event.m_uiSize = sizeof(NmtEvent); |
| Event.m_pArg = &NmtEvent; |
| Ret = EplEventkPost(&Event); |
| } |
| } |
| |
| Exit: |
| if (Ret != kEplSuccessful) { |
| u32 dwArg; |
| |
| BENCHMARK_MOD_02_TOGGLE(9); |
| |
| dwArg = EplDllkInstance_g.m_DllState | (NmtEvent << 8); |
| |
| // Error event for API layer |
| Ret = EplEventkPostError(kEplEventSourceDllk, |
| Ret, sizeof(dwArg), &dwArg); |
| } |
| BENCHMARK_MOD_02_RESET(3); |
| return; |
| } |
| |
| //--------------------------------------------------------------------------- |
| // |
| // Function: EplDllkCbFrameTransmitted() |
| // |
| // Description: called from EdrvInterruptHandler(). |
| // It signals |
| // |
| // Parameters: pRxBuffer_p = receive buffer structure |
| // |
| // Returns: (none) |
| // |
| // |
| // State: |
| // |
| //--------------------------------------------------------------------------- |
| |
| static void EplDllkCbFrameTransmitted(tEdrvTxBuffer * pTxBuffer_p) |
| { |
| tEplKernel Ret = kEplSuccessful; |
| tEplEvent Event; |
| tEplDllAsyncReqPriority Priority; |
| tEplNmtState NmtState; |
| |
| #if (((EPL_MODULE_INTEGRATION) & (EPL_MODULE_PDOK)) != 0) \ |
| && (EPL_DLL_PRES_READY_AFTER_SOC == FALSE) |
| tEplFrameInfo FrameInfo; |
| #endif |
| |
| NmtState = EplNmtkGetNmtState(); |
| |
| if (NmtState <= kEplNmtGsResetConfiguration) { |
| goto Exit; |
| } |
| |
| if ((pTxBuffer_p - EplDllkInstance_g.m_pTxBuffer) == EPL_DLLK_TXFRAME_NMTREQ) { // frame from NMT request FIFO sent |
| // mark Tx-buffer as empty |
| pTxBuffer_p->m_uiTxMsgLen = EPL_DLLK_BUFLEN_EMPTY; |
| |
| // post event to DLL |
| Priority = kEplDllAsyncReqPrioNmt; |
| Event.m_EventSink = kEplEventSinkDllk; |
| Event.m_EventType = kEplEventTypeDllkFillTx; |
| EPL_MEMSET(&Event.m_NetTime, 0x00, sizeof(Event.m_NetTime)); |
| Event.m_pArg = &Priority; |
| Event.m_uiSize = sizeof(Priority); |
| Ret = EplEventkPost(&Event); |
| } else if ((pTxBuffer_p - EplDllkInstance_g.m_pTxBuffer) == EPL_DLLK_TXFRAME_NONEPL) { // frame from generic priority FIFO sent |
| // mark Tx-buffer as empty |
| pTxBuffer_p->m_uiTxMsgLen = EPL_DLLK_BUFLEN_EMPTY; |
| |
| // post event to DLL |
| Priority = kEplDllAsyncReqPrioGeneric; |
| Event.m_EventSink = kEplEventSinkDllk; |
| Event.m_EventType = kEplEventTypeDllkFillTx; |
| EPL_MEMSET(&Event.m_NetTime, 0x00, sizeof(Event.m_NetTime)); |
| Event.m_pArg = &Priority; |
| Event.m_uiSize = sizeof(Priority); |
| Ret = EplEventkPost(&Event); |
| } |
| #if ((((EPL_MODULE_INTEGRATION) & (EPL_MODULE_PDOK)) != 0) \ |
| && (EPL_DLL_PRES_READY_AFTER_SOC == FALSE)) \ |
| || (((EPL_MODULE_INTEGRATION) & (EPL_MODULE_NMT_MN)) != 0) |
| else if ((pTxBuffer_p->m_EplMsgType == kEplMsgTypePreq) |
| || (pTxBuffer_p->m_EplMsgType == kEplMsgTypePres)) { // PRes resp. PReq frame sent |
| |
| #if ((((EPL_MODULE_INTEGRATION) & (EPL_MODULE_PDOK)) != 0) \ |
| && (EPL_DLL_PRES_READY_AFTER_SOC == FALSE)) |
| { |
| // inform PDO module |
| FrameInfo.m_pFrame = |
| (tEplFrame *) pTxBuffer_p->m_pbBuffer; |
| FrameInfo.m_uiFrameSize = pTxBuffer_p->m_uiMaxBufferLen; |
| Ret = EplPdokCbPdoTransmitted(&FrameInfo); |
| } |
| #endif |
| |
| #if (((EPL_MODULE_INTEGRATION) & (EPL_MODULE_NMT_MN)) != 0) |
| { |
| // if own Pres on MN, trigger SoA |
| if ((NmtState >= kEplNmtMsPreOperational2) |
| && (pTxBuffer_p == |
| &EplDllkInstance_g. |
| m_pTxBuffer[EPL_DLLK_TXFRAME_PRES])) { |
| Ret = |
| EplDllkChangeState(kEplNmtEventDllMeSoaTrig, |
| NmtState); |
| } |
| } |
| #endif |
| |
| #if EPL_DLL_PRES_READY_AFTER_SOA != FALSE |
| goto Exit; |
| #endif |
| } |
| #endif |
| #if (((EPL_MODULE_INTEGRATION) & (EPL_MODULE_NMT_MN)) != 0) |
| else if (pTxBuffer_p->m_EplMsgType == kEplMsgTypeSoa) { // SoA frame sent |
| tEplNmtEvent NmtEvent = kEplNmtEventDllMeSoaSent; |
| |
| // check if we are invited |
| if (EplDllkInstance_g.m_uiLastTargetNodeId == |
| EplDllkInstance_g.m_DllConfigParam.m_uiNodeId) { |
| tEplFrame *pTxFrame; |
| |
| if (EplDllkInstance_g.m_LastReqServiceId == kEplDllReqServiceStatus) { // StatusRequest |
| if (EplDllkInstance_g.m_pTxBuffer[EPL_DLLK_TXFRAME_STATUSRES].m_pbBuffer != NULL) { // StatusRes does exist |
| |
| pTxFrame = |
| (tEplFrame *) EplDllkInstance_g. |
| m_pTxBuffer |
| [EPL_DLLK_TXFRAME_STATUSRES]. |
| m_pbBuffer; |
| // update StatusRes frame (NMT state, EN, EC, RS, PR flags) |
| AmiSetByteToLe(&pTxFrame->m_Data.m_Asnd. |
| m_Payload. |
| m_StatusResponse. |
| m_le_bNmtStatus, |
| (u8) NmtState); |
| AmiSetByteToLe(&pTxFrame->m_Data.m_Asnd. |
| m_Payload. |
| m_StatusResponse. |
| m_le_bFlag1, |
| EplDllkInstance_g. |
| m_bFlag1); |
| AmiSetByteToLe(&pTxFrame->m_Data.m_Asnd. |
| m_Payload. |
| m_StatusResponse. |
| m_le_bFlag2, |
| EplDllkInstance_g. |
| m_bFlag2); |
| // send StatusRes |
| Ret = |
| EdrvSendTxMsg(&EplDllkInstance_g. |
| m_pTxBuffer |
| [EPL_DLLK_TXFRAME_STATUSRES]); |
| if (Ret != kEplSuccessful) { |
| goto Exit; |
| } |
| TGT_DBG_SIGNAL_TRACE_POINT(8); |
| |
| } |
| } else if (EplDllkInstance_g.m_LastReqServiceId == kEplDllReqServiceIdent) { // IdentRequest |
| if (EplDllkInstance_g.m_pTxBuffer[EPL_DLLK_TXFRAME_IDENTRES].m_pbBuffer != NULL) { // IdentRes does exist |
| pTxFrame = |
| (tEplFrame *) EplDllkInstance_g. |
| m_pTxBuffer |
| [EPL_DLLK_TXFRAME_IDENTRES]. |
| m_pbBuffer; |
| // update IdentRes frame (NMT state, RS, PR flags) |
| AmiSetByteToLe(&pTxFrame->m_Data.m_Asnd. |
| m_Payload. |
| m_IdentResponse. |
| m_le_bNmtStatus, |
| (u8) NmtState); |
| AmiSetByteToLe(&pTxFrame->m_Data.m_Asnd. |
| m_Payload. |
| m_IdentResponse. |
| m_le_bFlag2, |
| EplDllkInstance_g. |
| m_bFlag2); |
| // send IdentRes |
| Ret = |
| EdrvSendTxMsg(&EplDllkInstance_g. |
| m_pTxBuffer |
| [EPL_DLLK_TXFRAME_IDENTRES]); |
| if (Ret != kEplSuccessful) { |
| goto Exit; |
| } |
| TGT_DBG_SIGNAL_TRACE_POINT(7); |
| } |
| } else if (EplDllkInstance_g.m_LastReqServiceId == kEplDllReqServiceNmtRequest) { // NmtRequest |
| if (EplDllkInstance_g.m_pTxBuffer[EPL_DLLK_TXFRAME_NMTREQ].m_pbBuffer != NULL) { // NmtRequest does exist |
| // check if frame is not empty and not being filled |
| if (EplDllkInstance_g. |
| m_pTxBuffer |
| [EPL_DLLK_TXFRAME_NMTREQ]. |
| m_uiTxMsgLen > |
| EPL_DLLK_BUFLEN_FILLING) { |
| // check if this frame is a NMT command, |
| // then forward this frame back to NmtMnu module, |
| // because it needs the time, when this frame is |
| // actually sent, to start the timer for monitoring |
| // the NMT state change. |
| |
| pTxFrame = |
| (tEplFrame *) |
| EplDllkInstance_g. |
| m_pTxBuffer |
| [EPL_DLLK_TXFRAME_NMTREQ]. |
| m_pbBuffer; |
| if ((AmiGetByteFromLe |
| (&pTxFrame-> |
| m_le_bMessageType) |
| == (u8) kEplMsgTypeAsnd) |
| && |
| (AmiGetByteFromLe |
| (&pTxFrame->m_Data.m_Asnd. |
| m_le_bServiceId) |
| == (u8) kEplDllAsndNmtCommand)) { // post event directly to NmtMnu module |
| Event.m_EventSink = |
| kEplEventSinkNmtMnu; |
| Event.m_EventType = |
| kEplEventTypeNmtMnuNmtCmdSent; |
| Event.m_uiSize = |
| EplDllkInstance_g. |
| m_pTxBuffer |
| [EPL_DLLK_TXFRAME_NMTREQ]. |
| m_uiTxMsgLen; |
| Event.m_pArg = pTxFrame; |
| Ret = |
| EplEventkPost |
| (&Event); |
| |
| } |
| // send NmtRequest |
| Ret = |
| EdrvSendTxMsg |
| (&EplDllkInstance_g. |
| m_pTxBuffer |
| [EPL_DLLK_TXFRAME_NMTREQ]); |
| if (Ret != kEplSuccessful) { |
| goto Exit; |
| } |
| |
| } |
| } |
| |
| } else if (EplDllkInstance_g.m_LastReqServiceId == kEplDllReqServiceUnspecified) { // unspecified invite |
| if (EplDllkInstance_g.m_pTxBuffer[EPL_DLLK_TXFRAME_NONEPL].m_pbBuffer != NULL) { // non-EPL frame does exist |
| // check if frame is not empty and not being filled |
| if (EplDllkInstance_g. |
| m_pTxBuffer |
| [EPL_DLLK_TXFRAME_NONEPL]. |
| m_uiTxMsgLen > |
| EPL_DLLK_BUFLEN_FILLING) { |
| // send non-EPL frame |
| Ret = |
| EdrvSendTxMsg |
| (&EplDllkInstance_g. |
| m_pTxBuffer |
| [EPL_DLLK_TXFRAME_NONEPL]); |
| if (Ret != kEplSuccessful) { |
| goto Exit; |
| } |
| |
| } |
| } |
| } |
| // ASnd frame was sent, remove the request |
| EplDllkInstance_g.m_LastReqServiceId = |
| kEplDllReqServiceNo; |
| } |
| // forward event to ErrorHandler and PDO module |
| Event.m_EventSink = kEplEventSinkNmtk; |
| Event.m_EventType = kEplEventTypeNmtEvent; |
| Event.m_uiSize = sizeof(NmtEvent); |
| Event.m_pArg = &NmtEvent; |
| Ret = EplEventkPost(&Event); |
| if (Ret != kEplSuccessful) { |
| goto Exit; |
| } |
| } |
| #endif |
| |
| #if EPL_DLL_PRES_READY_AFTER_SOA != FALSE |
| else { // d.k.: Why that else? on CN it is entered on IdentRes and StatusRes |
| goto Exit; |
| } |
| |
| // signal process function readiness of PRes frame |
| Event.m_EventSink = kEplEventSinkDllk; |
| Event.m_EventType = kEplEventTypeDllkPresReady; |
| Event.m_uiSize = 0; |
| Event.m_pArg = NULL; |
| Ret = EplEventkPost(&Event); |
| |
| #endif |
| |
| Exit: |
| if (Ret != kEplSuccessful) { |
| u32 dwArg; |
| |
| BENCHMARK_MOD_02_TOGGLE(9); |
| |
| dwArg = |
| EplDllkInstance_g.m_DllState | (pTxBuffer_p-> |
| m_EplMsgType << 16); |
| |
| // Error event for API layer |
| Ret = EplEventkPostError(kEplEventSourceDllk, |
| Ret, sizeof(dwArg), &dwArg); |
| } |
| |
| return; |
| } |
| |
| //--------------------------------------------------------------------------- |
| // |
| // Function: EplDllkCheckFrame() |
| // |
| // Description: check frame and set missing information |
| // |
| // Parameters: pFrame_p = ethernet frame |
| // uiFrameSize_p = size of frame |
| // |
| // Returns: tEplKernel = error code |
| // |
| // |
| // State: |
| // |
| //--------------------------------------------------------------------------- |
| |
| static tEplKernel EplDllkCheckFrame(tEplFrame * pFrame_p, |
| unsigned int uiFrameSize_p) |
| { |
| tEplMsgType MsgType; |
| u16 wEtherType; |
| |
| // check frame |
| if (pFrame_p != NULL) { |
| // check SrcMAC |
| if (AmiGetQword48FromBe(pFrame_p->m_be_abSrcMac) == 0) { |
| // source MAC address |
| EPL_MEMCPY(&pFrame_p->m_be_abSrcMac[0], |
| &EplDllkInstance_g.m_be_abSrcMac[0], 6); |
| } |
| // check ethertype |
| wEtherType = AmiGetWordFromBe(&pFrame_p->m_be_wEtherType); |
| if (wEtherType == 0) { |
| // assume EPL frame |
| wEtherType = EPL_C_DLL_ETHERTYPE_EPL; |
| AmiSetWordToBe(&pFrame_p->m_be_wEtherType, wEtherType); |
| } |
| |
| if (wEtherType == EPL_C_DLL_ETHERTYPE_EPL) { |
| // source node ID |
| AmiSetByteToLe(&pFrame_p->m_le_bSrcNodeId, |
| (u8) EplDllkInstance_g. |
| m_DllConfigParam.m_uiNodeId); |
| |
| // check message type |
| MsgType = |
| AmiGetByteFromLe(&pFrame_p->m_le_bMessageType); |
| if (MsgType == 0) { |
| MsgType = kEplMsgTypeAsnd; |
| AmiSetByteToLe(&pFrame_p->m_le_bMessageType, |
| (u8) MsgType); |
| } |
| |
| if (MsgType == kEplMsgTypeAsnd) { |
| // destination MAC address |
| AmiSetQword48ToBe(&pFrame_p->m_be_abDstMac[0], |
| EPL_C_DLL_MULTICAST_ASND); |
| } |
| |
| } |
| } |
| |
| return kEplSuccessful; |
| } |
| |
| //--------------------------------------------------------------------------- |
| // |
| // Function: EplDllkCbCnTimer() |
| // |
| // Description: called by timer module. It monitors the EPL cycle when it is a CN. |
| // |
| // Parameters: pEventArg_p = timer event argument |
| // |
| // Returns: tEplKernel = error code |
| // |
| // |
| // State: |
| // |
| //--------------------------------------------------------------------------- |
| |
| #if EPL_TIMER_USE_HIGHRES != FALSE |
| static tEplKernel EplDllkCbCnTimer(tEplTimerEventArg *pEventArg_p) |
| { |
| tEplKernel Ret = kEplSuccessful; |
| tEplNmtState NmtState; |
| |
| #if EPL_TIMER_USE_HIGHRES != FALSE |
| if (pEventArg_p->m_TimerHdl != EplDllkInstance_g.m_TimerHdlCycle) { // zombie callback |
| // just exit |
| goto Exit; |
| } |
| #endif |
| |
| NmtState = EplNmtkGetNmtState(); |
| |
| if (NmtState <= kEplNmtGsResetConfiguration) { |
| goto Exit; |
| } |
| |
| Ret = EplDllkChangeState(kEplNmtEventDllCeFrameTimeout, NmtState); |
| if (Ret != kEplSuccessful) { |
| goto Exit; |
| } |
| // 2008/10/15 d.k. reprogramming of timer not necessary, |
| // because it will be programmed, when SoC is received. |
| /* |
| // reprogram timer |
| #if EPL_TIMER_USE_HIGHRES != FALSE |
| if ((NmtState > kEplNmtCsPreOperational1) |
| && (EplDllkInstance_g.m_ullFrameTimeout != 0)) |
| { |
| Ret = EplTimerHighReskModifyTimerNs(&EplDllkInstance_g.m_TimerHdlCycle, EplDllkInstance_g.m_ullFrameTimeout, EplDllkCbCnTimer, 0L, FALSE); |
| } |
| #endif |
| */ |
| |
| Exit: |
| if (Ret != kEplSuccessful) { |
| u32 dwArg; |
| |
| BENCHMARK_MOD_02_TOGGLE(9); |
| |
| dwArg = |
| EplDllkInstance_g. |
| m_DllState | (kEplNmtEventDllCeFrameTimeout << 8); |
| |
| // Error event for API layer |
| Ret = EplEventkPostError(kEplEventSourceDllk, |
| Ret, sizeof(dwArg), &dwArg); |
| } |
| |
| return Ret; |
| } |
| #endif |
| |
| #if (((EPL_MODULE_INTEGRATION) & (EPL_MODULE_NMT_MN)) != 0) |
| |
| //--------------------------------------------------------------------------- |
| // |
| // Function: EplDllkCbMnTimerCycle() |
| // |
| // Description: called by timer module. It triggers the SoC when it is a MN. |
| // |
| // Parameters: pEventArg_p = timer event argument |
| // |
| // Returns: tEplKernel = error code |
| // |
| // |
| // State: |
| // |
| //--------------------------------------------------------------------------- |
| |
| static tEplKernel EplDllkCbMnTimerCycle(tEplTimerEventArg *pEventArg_p) |
| { |
| tEplKernel Ret = kEplSuccessful; |
| tEplNmtState NmtState; |
| |
| #if EPL_TIMER_USE_HIGHRES != FALSE |
| if (pEventArg_p->m_TimerHdl != EplDllkInstance_g.m_TimerHdlCycle) { // zombie callback |
| // just exit |
| goto Exit; |
| } |
| #endif |
| |
| NmtState = EplNmtkGetNmtState(); |
| |
| if (NmtState <= kEplNmtGsResetConfiguration) { |
| goto Exit; |
| } |
| |
| Ret = EplDllkChangeState(kEplNmtEventDllMeSocTrig, NmtState); |
| |
| Exit: |
| if (Ret != kEplSuccessful) { |
| u32 dwArg; |
| |
| BENCHMARK_MOD_02_TOGGLE(9); |
| |
| dwArg = |
| EplDllkInstance_g. |
| m_DllState | (kEplNmtEventDllMeSocTrig << 8); |
| |
| // Error event for API layer |
| Ret = EplEventkPostError(kEplEventSourceDllk, |
| Ret, sizeof(dwArg), &dwArg); |
| } |
| |
| return Ret; |
| } |
| |
| //--------------------------------------------------------------------------- |
| // |
| // Function: EplDllkCbMnTimerResponse() |
| // |
| // Description: called by timer module. It monitors the PRes timeout. |
| // |
| // Parameters: pEventArg_p = timer event argument |
| // |
| // Returns: tEplKernel = error code |
| // |
| // |
| // State: |
| // |
| //--------------------------------------------------------------------------- |
| |
| static tEplKernel EplDllkCbMnTimerResponse(tEplTimerEventArg *pEventArg_p) |
| { |
| tEplKernel Ret = kEplSuccessful; |
| tEplNmtState NmtState; |
| |
| #if EPL_TIMER_USE_HIGHRES != FALSE |
| if (pEventArg_p->m_TimerHdl != EplDllkInstance_g.m_TimerHdlResponse) { // zombie callback |
| // just exit |
| goto Exit; |
| } |
| #endif |
| |
| NmtState = EplNmtkGetNmtState(); |
| |
| if (NmtState <= kEplNmtGsResetConfiguration) { |
| goto Exit; |
| } |
| |
| Ret = EplDllkChangeState(kEplNmtEventDllMePresTimeout, NmtState); |
| |
| Exit: |
| if (Ret != kEplSuccessful) { |
| u32 dwArg; |
| |
| BENCHMARK_MOD_02_TOGGLE(9); |
| |
| dwArg = |
| EplDllkInstance_g. |
| m_DllState | (kEplNmtEventDllMePresTimeout << 8); |
| |
| // Error event for API layer |
| Ret = EplEventkPostError(kEplEventSourceDllk, |
| Ret, sizeof(dwArg), &dwArg); |
| } |
| |
| return Ret; |
| } |
| |
| //--------------------------------------------------------------------------- |
| // |
| // Function: EplDllkGetNodeInfo() |
| // |
| // Description: returns node info structure of the specified node. |
| // |
| // Parameters: uiNodeId_p = node ID |
| // |
| // Returns: tEplDllkNodeInfo* = pointer to internal node info structure |
| // |
| // |
| // State: |
| // |
| //--------------------------------------------------------------------------- |
| |
| static tEplDllkNodeInfo *EplDllkGetNodeInfo(unsigned int uiNodeId_p) |
| { |
| // $$$ d.k.: use hash algorithm to retrieve the appropriate node info structure |
| // if size of array is less than 254. |
| uiNodeId_p--; // node ID starts at 1 but array at 0 |
| if (uiNodeId_p >= tabentries(EplDllkInstance_g.m_aNodeInfo)) { |
| return NULL; |
| } else { |
| return &EplDllkInstance_g.m_aNodeInfo[uiNodeId_p]; |
| } |
| } |
| |
| //--------------------------------------------------------------------------- |
| // |
| // Function: EplDllkMnSendSoa() |
| // |
| // Description: it updates and transmits the SoA. |
| // |
| // Parameters: NmtState_p = current NMT state |
| // pDllStateProposed_p = proposed DLL state |
| // fEnableInvitation_p = enable invitation for asynchronous phase |
| // it will be disabled for EPL_C_DLL_PREOP1_START_CYCLES SoAs |
| // |
| // Returns: tEplKernel = error code |
| // |
| // |
| // State: |
| // |
| //--------------------------------------------------------------------------- |
| |
| static tEplKernel EplDllkMnSendSoa(tEplNmtState NmtState_p, |
| tEplDllState * pDllStateProposed_p, |
| BOOL fEnableInvitation_p) |
| { |
| tEplKernel Ret = kEplSuccessful; |
| tEdrvTxBuffer *pTxBuffer = NULL; |
| tEplFrame *pTxFrame; |
| tEplDllkNodeInfo *pNodeInfo; |
| |
| *pDllStateProposed_p = kEplDllMsNonCyclic; |
| |
| pTxBuffer = &EplDllkInstance_g.m_pTxBuffer[EPL_DLLK_TXFRAME_SOA]; |
| if (pTxBuffer->m_pbBuffer != NULL) { // SoA does exist |
| pTxFrame = (tEplFrame *) pTxBuffer->m_pbBuffer; |
| |
| if (fEnableInvitation_p != FALSE) { // fetch target of asynchronous phase |
| if (EplDllkInstance_g.m_bFlag2 == 0) { // own queues are empty |
| EplDllkInstance_g.m_LastReqServiceId = |
| kEplDllReqServiceNo; |
| } else if (((tEplDllAsyncReqPriority) (EplDllkInstance_g.m_bFlag2 >> EPL_FRAME_FLAG2_PR_SHIFT)) == kEplDllAsyncReqPrioNmt) { // frames in own NMT request queue available |
| EplDllkInstance_g.m_LastReqServiceId = |
| kEplDllReqServiceNmtRequest; |
| } else { |
| EplDllkInstance_g.m_LastReqServiceId = |
| kEplDllReqServiceUnspecified; |
| } |
| Ret = |
| EplDllkCalAsyncGetSoaRequest(&EplDllkInstance_g. |
| m_LastReqServiceId, |
| &EplDllkInstance_g. |
| m_uiLastTargetNodeId); |
| if (Ret != kEplSuccessful) { |
| goto Exit; |
| } |
| if (EplDllkInstance_g.m_LastReqServiceId != kEplDllReqServiceNo) { // asynchronous phase will be assigned to one node |
| if (EplDllkInstance_g.m_uiLastTargetNodeId == EPL_C_ADR_INVALID) { // exchange invalid node ID with local node ID |
| EplDllkInstance_g.m_uiLastTargetNodeId = |
| EplDllkInstance_g.m_DllConfigParam. |
| m_uiNodeId; |
| // d.k. DLL state WaitAsndTrig is not helpful; |
| // so just step over to WaitSocTrig, |
| // because own ASnd is sent automatically in CbFrameTransmitted() after SoA. |
| //*pDllStateProposed_p = kEplDllMsWaitAsndTrig; |
| *pDllStateProposed_p = |
| kEplDllMsWaitSocTrig; |
| } else { // assignment to CN |
| *pDllStateProposed_p = |
| kEplDllMsWaitAsnd; |
| } |
| |
| pNodeInfo = |
| EplDllkGetNodeInfo(EplDllkInstance_g. |
| m_uiLastTargetNodeId); |
| if (pNodeInfo == NULL) { // no node info structure available |
| Ret = kEplDllNoNodeInfo; |
| goto Exit; |
| } |
| // update frame (EA, ER flags) |
| AmiSetByteToLe(&pTxFrame->m_Data.m_Soa. |
| m_le_bFlag1, |
| pNodeInfo-> |
| m_bSoaFlag1 & (EPL_FRAME_FLAG1_EA |
| | |
| EPL_FRAME_FLAG1_ER)); |
| } else { // no assignment of asynchronous phase |
| *pDllStateProposed_p = kEplDllMsWaitSocTrig; |
| EplDllkInstance_g.m_uiLastTargetNodeId = |
| EPL_C_ADR_INVALID; |
| } |
| |
| // update frame (target) |
| AmiSetByteToLe(&pTxFrame->m_Data.m_Soa. |
| m_le_bReqServiceId, |
| (u8) EplDllkInstance_g. |
| m_LastReqServiceId); |
| AmiSetByteToLe(&pTxFrame->m_Data.m_Soa. |
| m_le_bReqServiceTarget, |
| (u8) EplDllkInstance_g. |
| m_uiLastTargetNodeId); |
| |
| } else { // invite nobody |
| // update frame (target) |
| AmiSetByteToLe(&pTxFrame->m_Data.m_Soa. |
| m_le_bReqServiceId, (u8) 0); |
| AmiSetByteToLe(&pTxFrame->m_Data.m_Soa. |
| m_le_bReqServiceTarget, (u8) 0); |
| } |
| |
| // update frame (NMT state) |
| AmiSetByteToLe(&pTxFrame->m_Data.m_Soa.m_le_bNmtStatus, |
| (u8) NmtState_p); |
| |
| // send SoA frame |
| Ret = EdrvSendTxMsg(pTxBuffer); |
| } |
| |
| Exit: |
| return Ret; |
| } |
| |
| //--------------------------------------------------------------------------- |
| // |
| // Function: EplDllkMnSendSoc() |
| // |
| // Description: it updates and transmits the SoA. |
| // |
| // Parameters: (none) |
| // |
| // Returns: tEplKernel = error code |
| // |
| // |
| // State: |
| // |
| //--------------------------------------------------------------------------- |
| |
| static tEplKernel EplDllkMnSendSoc(void) |
| { |
| tEplKernel Ret = kEplSuccessful; |
| tEdrvTxBuffer *pTxBuffer = NULL; |
| tEplFrame *pTxFrame; |
| tEplEvent Event; |
| |
| pTxBuffer = &EplDllkInstance_g.m_pTxBuffer[EPL_DLLK_TXFRAME_SOC]; |
| if (pTxBuffer->m_pbBuffer != NULL) { // SoC does exist |
| pTxFrame = (tEplFrame *) pTxBuffer->m_pbBuffer; |
| |
| // $$$ update NetTime |
| |
| // send SoC frame |
| Ret = EdrvSendTxMsg(pTxBuffer); |
| if (Ret != kEplSuccessful) { |
| goto Exit; |
| } |
| // trigger synchronous task |
| Event.m_EventSink = kEplEventSinkSync; |
| Event.m_EventType = kEplEventTypeSync; |
| Event.m_uiSize = 0; |
| Ret = EplEventkPost(&Event); |
| } |
| |
| Exit: |
| return Ret; |
| } |
| |
| //--------------------------------------------------------------------------- |
| // |
| // Function: EplDllkMnSendPreq() |
| // |
| // Description: it updates and transmits the PReq for the next isochronous CN |
| // or own PRes if enabled. |
| // |
| // Parameters: NmtState_p = current NMT state |
| // pDllStateProposed_p = proposed DLL state |
| // |
| // Returns: tEplKernel = error code |
| // |
| // |
| // State: |
| // |
| //--------------------------------------------------------------------------- |
| |
| static tEplKernel EplDllkMnSendPreq(tEplNmtState NmtState_p, |
| tEplDllState * pDllStateProposed_p) |
| { |
| tEplKernel Ret = kEplSuccessful; |
| tEdrvTxBuffer *pTxBuffer = NULL; |
| tEplFrame *pTxFrame; |
| u8 bFlag1 = 0; |
| |
| if (EplDllkInstance_g.m_pCurNodeInfo == NULL) { // start with first isochronous CN |
| EplDllkInstance_g.m_pCurNodeInfo = |
| EplDllkInstance_g.m_pFirstNodeInfo; |
| } else { // iterate to next isochronous CN |
| EplDllkInstance_g.m_pCurNodeInfo = |
| EplDllkInstance_g.m_pCurNodeInfo->m_pNextNodeInfo; |
| } |
| |
| if (EplDllkInstance_g.m_pCurNodeInfo == NULL) { // last isochronous CN reached |
| Ret = EplDllkMnSendSoa(NmtState_p, pDllStateProposed_p, TRUE); |
| goto Exit; |
| } else { |
| pTxBuffer = EplDllkInstance_g.m_pCurNodeInfo->m_pPreqTxBuffer; |
| bFlag1 = |
| EplDllkInstance_g.m_pCurNodeInfo-> |
| m_bSoaFlag1 & EPL_FRAME_FLAG1_EA; |
| *pDllStateProposed_p = kEplDllMsWaitPres; |
| |
| // start PRes Timer |
| // $$$ d.k.: maybe move this call to CbFrameTransmitted(), because the time should run from there |
| #if EPL_TIMER_USE_HIGHRES != FALSE |
| Ret = |
| EplTimerHighReskModifyTimerNs(&EplDllkInstance_g. |
| m_TimerHdlResponse, |
| EplDllkInstance_g. |
| m_pCurNodeInfo-> |
| m_dwPresTimeout, |
| EplDllkCbMnTimerResponse, 0L, |
| FALSE); |
| #endif |
| } |
| |
| if (pTxBuffer == NULL) { // PReq does not exist |
| Ret = kEplDllTxBufNotReady; |
| goto Exit; |
| } |
| |
| pTxFrame = (tEplFrame *) pTxBuffer->m_pbBuffer; |
| |
| if (pTxFrame != NULL) { // PReq does exist |
| if (NmtState_p == kEplNmtMsOperational) { // leave RD flag untouched |
| bFlag1 |= |
| AmiGetByteFromLe(&pTxFrame->m_Data.m_Preq. |
| m_le_bFlag1) & EPL_FRAME_FLAG1_RD; |
| } |
| |
| if (pTxBuffer == &EplDllkInstance_g.m_pTxBuffer[EPL_DLLK_TXFRAME_PRES]) { // PRes of MN will be sent |
| // update NMT state |
| AmiSetByteToLe(&pTxFrame->m_Data.m_Pres.m_le_bNmtStatus, |
| (u8) NmtState_p); |
| *pDllStateProposed_p = kEplDllMsWaitSoaTrig; |
| } |
| // $$$ d.k. set EPL_FRAME_FLAG1_MS if necessary |
| // update frame (Flag1) |
| AmiSetByteToLe(&pTxFrame->m_Data.m_Preq.m_le_bFlag1, bFlag1); |
| |
| // calculate frame size from payload size |
| pTxBuffer->m_uiTxMsgLen = |
| AmiGetWordFromLe(&pTxFrame->m_Data.m_Preq.m_le_wSize) + 24; |
| |
| // send PReq frame |
| Ret = EdrvSendTxMsg(pTxBuffer); |
| } else { |
| Ret = kEplDllTxFrameInvalid; |
| } |
| |
| Exit: |
| return Ret; |
| } |
| |
| //--------------------------------------------------------------------------- |
| // |
| // Function: EplDllkAsyncFrameNotReceived() |
| // |
| // Description: passes empty ASnd frame to receive FIFO. |
| // It will be called only for frames with registered AsndServiceIds |
| // (only kEplDllAsndFilterAny). |
| // |
| // Parameters: none |
| // |
| // Returns: tEplKernel = error code |
| // |
| // |
| // State: |
| // |
| //--------------------------------------------------------------------------- |
| |
| static tEplKernel EplDllkAsyncFrameNotReceived(tEplDllReqServiceId |
| ReqServiceId_p, |
| unsigned int uiNodeId_p) |
| { |
| tEplKernel Ret = kEplSuccessful; |
| u8 abBuffer[18]; |
| tEplFrame *pFrame = (tEplFrame *) abBuffer; |
| tEplFrameInfo FrameInfo; |
| |
| // check if previous SoA invitation was not answered |
| switch (ReqServiceId_p) { |
| case kEplDllReqServiceIdent: |
| case kEplDllReqServiceStatus: |
| // ASnd service registered? |
| if (EplDllkInstance_g.m_aAsndFilter[ReqServiceId_p] == kEplDllAsndFilterAny) { // ASnd service ID is registered |
| AmiSetByteToLe(&pFrame->m_le_bSrcNodeId, |
| (u8) uiNodeId_p); |
| // EPL MsgType ASnd |
| AmiSetByteToLe(&pFrame->m_le_bMessageType, |
| (u8) kEplMsgTypeAsnd); |
| // ASnd Service ID |
| AmiSetByteToLe(&pFrame->m_Data.m_Asnd.m_le_bServiceId, |
| (u8) ReqServiceId_p); |
| // create frame info structure |
| FrameInfo.m_pFrame = pFrame; |
| FrameInfo.m_uiFrameSize = 18; // empty non existing ASnd frame |
| // forward frame via async receive FIFO to userspace |
| Ret = EplDllkCalAsyncFrameReceived(&FrameInfo); |
| } |
| break; |
| default: |
| // no invitation issued or it was successfully answered or it is uninteresting |
| break; |
| } |
| |
| return Ret; |
| } |
| |
| #endif //(((EPL_MODULE_INTEGRATION) & (EPL_MODULE_NMT_MN)) != 0) |
| |
| #endif // #if(((EPL_MODULE_INTEGRATION) & (EPL_MODULE_DLLK)) != 0) |
| // EOF |