Tom Martins
/
Probleme_implementation_lwip2
test public
Fork of Probleme_implementation_lwip by
mb.cpp
- Committer:
- cam
- Date:
- 2010-04-15
- Revision:
- 0:0453a0a7e500
File content as of revision 0:0453a0a7e500:
/* * FreeModbus Libary: A portable Modbus implementation for Modbus ASCII/RTU. * Copyright (c) 2006 Christian Walter <wolti@sil.at> * All rights reserved. * * 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. The name of the author may not be used to endorse or promote products * derived from this software without specific prior written permission. * * THIS SOFTWARE IS PROVIDED BY THE AUTHOR ``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 AUTHOR 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. * * File: $Id: mb.c,v 1.27 2007/02/18 23:45:41 wolti Exp $ */ /* ----------------------- System includes ----------------------------------*/ #include "stdlib.h" #include "string.h" /* ----------------------- Platform includes --------------------------------*/ #include "port.h" /* ----------------------- Modbus includes ----------------------------------*/ #include "mb.h" #include "mbconfig.h" #include "mbframe.h" #include "mbproto.h" #include "mbfunc.h" #include "mbport.h" #if MB_RTU_ENABLED == 1 #include "mbrtu.h" #endif #if MB_ASCII_ENABLED == 1 #include "mbascii.h" #endif #if MB_TCP_ENABLED == 1 #include "mbtcp.h" #endif #ifndef MB_PORT_HAS_CLOSE #define MB_PORT_HAS_CLOSE 0 #endif /* ----------------------- Static variables ---------------------------------*/ static UCHAR ucMBAddress; static eMBMode eMBCurrentMode; static enum { STATE_ENABLED, STATE_DISABLED, STATE_NOT_INITIALIZED } eMBState = STATE_NOT_INITIALIZED; /* Functions pointer which are initialized in eMBInit( ). Depending on the * mode (RTU or ASCII) the are set to the correct implementations. */ static peMBFrameSend peMBFrameSendCur; static pvMBFrameStart pvMBFrameStartCur; static pvMBFrameStop pvMBFrameStopCur; static peMBFrameReceive peMBFrameReceiveCur; static pvMBFrameClose pvMBFrameCloseCur; /* Callback functions required by the porting layer. They are called when * an external event has happend which includes a timeout or the reception * or transmission of a character. */ BOOL( *pxMBFrameCBByteReceived ) ( void ); BOOL( *pxMBFrameCBTransmitterEmpty ) ( void ); BOOL( *pxMBPortCBTimerExpired ) ( void ); BOOL( *pxMBFrameCBReceiveFSMCur ) ( void ); BOOL( *pxMBFrameCBTransmitFSMCur ) ( void ); /* An array of Modbus functions handlers which associates Modbus function * codes with implementing functions. */ static xMBFunctionHandler xFuncHandlers[MB_FUNC_HANDLERS_MAX] = { #if MB_FUNC_OTHER_REP_SLAVEID_ENABLED > 0 {MB_FUNC_OTHER_REPORT_SLAVEID, eMBFuncReportSlaveID}, #endif #if MB_FUNC_READ_INPUT_ENABLED > 0 {MB_FUNC_READ_INPUT_REGISTER, eMBFuncReadInputRegister}, #endif #if MB_FUNC_READ_HOLDING_ENABLED > 0 {MB_FUNC_READ_HOLDING_REGISTER, eMBFuncReadHoldingRegister}, #endif #if MB_FUNC_WRITE_MULTIPLE_HOLDING_ENABLED > 0 {MB_FUNC_WRITE_MULTIPLE_REGISTERS, eMBFuncWriteMultipleHoldingRegister}, #endif #if MB_FUNC_WRITE_HOLDING_ENABLED > 0 {MB_FUNC_WRITE_REGISTER, eMBFuncWriteHoldingRegister}, #endif #if MB_FUNC_READWRITE_HOLDING_ENABLED > 0 {MB_FUNC_READWRITE_MULTIPLE_REGISTERS, eMBFuncReadWriteMultipleHoldingRegister}, #endif #if MB_FUNC_READ_COILS_ENABLED > 0 {MB_FUNC_READ_COILS, eMBFuncReadCoils}, #endif #if MB_FUNC_WRITE_COIL_ENABLED > 0 {MB_FUNC_WRITE_SINGLE_COIL, eMBFuncWriteCoil}, #endif #if MB_FUNC_WRITE_MULTIPLE_COILS_ENABLED > 0 {MB_FUNC_WRITE_MULTIPLE_COILS, eMBFuncWriteMultipleCoils}, #endif #if MB_FUNC_READ_DISCRETE_INPUTS_ENABLED > 0 {MB_FUNC_READ_DISCRETE_INPUTS, eMBFuncReadDiscreteInputs}, #endif }; /* ----------------------- Start implementation -----------------------------*/ eMBErrorCode eMBInit( eMBMode eMode, UCHAR ucSlaveAddress, UCHAR ucPort, ULONG ulBaudRate, eMBParity eParity ) { eMBErrorCode eStatus = MB_ENOERR; /* check preconditions */ if ( ( ucSlaveAddress == MB_ADDRESS_BROADCAST ) || ( ucSlaveAddress < MB_ADDRESS_MIN ) || ( ucSlaveAddress > MB_ADDRESS_MAX ) ) { eStatus = MB_EINVAL; } else { ucMBAddress = ucSlaveAddress; switch ( eMode ) { #if MB_RTU_ENABLED > 0 case MB_RTU: pvMBFrameStartCur = eMBRTUStart; pvMBFrameStopCur = eMBRTUStop; peMBFrameSendCur = eMBRTUSend; peMBFrameReceiveCur = eMBRTUReceive; pvMBFrameCloseCur = MB_PORT_HAS_CLOSE ? vMBPortClose : NULL; pxMBFrameCBByteReceived = xMBRTUReceiveFSM; pxMBFrameCBTransmitterEmpty = xMBRTUTransmitFSM; pxMBPortCBTimerExpired = xMBRTUTimerT35Expired; eStatus = eMBRTUInit( ucMBAddress, ucPort, ulBaudRate, eParity ); break; #endif #if MB_ASCII_ENABLED > 0 case MB_ASCII: pvMBFrameStartCur = eMBASCIIStart; pvMBFrameStopCur = eMBASCIIStop; peMBFrameSendCur = eMBASCIISend; peMBFrameReceiveCur = eMBASCIIReceive; pvMBFrameCloseCur = MB_PORT_HAS_CLOSE ? vMBPortClose : NULL; pxMBFrameCBByteReceived = xMBASCIIReceiveFSM; pxMBFrameCBTransmitterEmpty = xMBASCIITransmitFSM; pxMBPortCBTimerExpired = xMBASCIITimerT1SExpired; eStatus = eMBASCIIInit( ucMBAddress, ucPort, ulBaudRate, eParity ); break; #endif default: eStatus = MB_EINVAL; } if ( eStatus == MB_ENOERR ) { if ( !xMBPortEventInit( ) ) { /* port dependent event module initalization failed. */ eStatus = MB_EPORTERR; } else { eMBCurrentMode = eMode; eMBState = STATE_DISABLED; } } } return eStatus; } #if MB_TCP_ENABLED > 0 eMBErrorCode eMBTCPInit( USHORT ucTCPPort ) { eMBErrorCode eStatus = MB_ENOERR; if ( ( eStatus = eMBTCPDoInit( ucTCPPort ) ) != MB_ENOERR ) { eMBState = STATE_DISABLED; } else if ( !xMBPortEventInit( ) ) { /* Port dependent event module initalization failed. */ eStatus = MB_EPORTERR; } else { pvMBFrameStartCur = eMBTCPStart; pvMBFrameStopCur = eMBTCPStop; peMBFrameReceiveCur = eMBTCPReceive; peMBFrameSendCur = eMBTCPSend; pvMBFrameCloseCur = MB_PORT_HAS_CLOSE ? vMBTCPPortClose : NULL; ucMBAddress = MB_TCP_PSEUDO_ADDRESS; eMBCurrentMode = MB_TCP; eMBState = STATE_DISABLED; } return eStatus; } #endif eMBErrorCode eMBRegisterCB( UCHAR ucFunctionCode, pxMBFunctionHandler pxHandler ) { int i; eMBErrorCode eStatus; if ( ( 0 < ucFunctionCode ) && ( ucFunctionCode <= 127 ) ) { ENTER_CRITICAL_SECTION( ); if ( pxHandler != NULL ) { for ( i = 0; i < MB_FUNC_HANDLERS_MAX; i++ ) { if ( ( xFuncHandlers[i].pxHandler == NULL ) || ( xFuncHandlers[i].pxHandler == pxHandler ) ) { xFuncHandlers[i].ucFunctionCode = ucFunctionCode; xFuncHandlers[i].pxHandler = pxHandler; break; } } eStatus = ( i != MB_FUNC_HANDLERS_MAX ) ? MB_ENOERR : MB_ENORES; } else { for ( i = 0; i < MB_FUNC_HANDLERS_MAX; i++ ) { if ( xFuncHandlers[i].ucFunctionCode == ucFunctionCode ) { xFuncHandlers[i].ucFunctionCode = 0; xFuncHandlers[i].pxHandler = NULL; break; } } /* Remove can't fail. */ eStatus = MB_ENOERR; } EXIT_CRITICAL_SECTION( ); } else { eStatus = MB_EINVAL; } return eStatus; } eMBErrorCode eMBClose( void ) { eMBErrorCode eStatus = MB_ENOERR; if ( eMBState == STATE_DISABLED ) { if ( pvMBFrameCloseCur != NULL ) { pvMBFrameCloseCur( ); } } else { eStatus = MB_EILLSTATE; } return eStatus; } eMBErrorCode eMBEnable( void ) { eMBErrorCode eStatus = MB_ENOERR; if ( eMBState == STATE_DISABLED ) { /* Activate the protocol stack. */ pvMBFrameStartCur( ); eMBState = STATE_ENABLED; } else { eStatus = MB_EILLSTATE; } return eStatus; } eMBErrorCode eMBDisable( void ) { eMBErrorCode eStatus; if ( eMBState == STATE_ENABLED ) { pvMBFrameStopCur( ); eMBState = STATE_DISABLED; eStatus = MB_ENOERR; } else if ( eMBState == STATE_DISABLED ) { eStatus = MB_ENOERR; } else { eStatus = MB_EILLSTATE; } return eStatus; } eMBErrorCode eMBPoll( void ) { static UCHAR *ucMBFrame; static UCHAR ucRcvAddress; static UCHAR ucFunctionCode; static USHORT usLength; static eMBException eException; int i; eMBErrorCode eStatus = MB_ENOERR; eMBEventType eEvent; /* Check if the protocol stack is ready. */ if ( eMBState != STATE_ENABLED ) { return MB_EILLSTATE; } /* Check if there is a event available. If not return control to caller. * Otherwise we will handle the event. */ if ( xMBPortEventGet( &eEvent ) == TRUE ) { switch ( eEvent ) { case EV_READY: break; case EV_FRAME_RECEIVED: eStatus = peMBFrameReceiveCur( &ucRcvAddress, &ucMBFrame, &usLength ); if ( eStatus == MB_ENOERR ) { /* Check if the frame is for us. If not ignore the frame. */ if ( ( ucRcvAddress == ucMBAddress ) || ( ucRcvAddress == MB_ADDRESS_BROADCAST ) ) { ( void )xMBPortEventPost( EV_EXECUTE ); } } break; case EV_EXECUTE: ucFunctionCode = ucMBFrame[MB_PDU_FUNC_OFF]; eException = MB_EX_ILLEGAL_FUNCTION; for ( i = 0; i < MB_FUNC_HANDLERS_MAX; i++ ) { /* No more function handlers registered. Abort. */ if ( xFuncHandlers[i].ucFunctionCode == 0 ) { break; } else if ( xFuncHandlers[i].ucFunctionCode == ucFunctionCode ) { eException = xFuncHandlers[i].pxHandler( ucMBFrame, &usLength ); break; } } /* If the request was not sent to the broadcast address we * return a reply. */ if ( ucRcvAddress != MB_ADDRESS_BROADCAST ) { if ( eException != MB_EX_NONE ) { /* An exception occured. Build an error frame. */ usLength = 0; ucMBFrame[usLength++] = ( UCHAR )( ucFunctionCode | MB_FUNC_ERROR ); ucMBFrame[usLength++] = eException; } eStatus = peMBFrameSendCur( ucMBAddress, ucMBFrame, usLength ); } break; case EV_FRAME_SENT: break; } } return MB_ENOERR; }