/* * FreeModbus Libary: A portable Modbus implementation for Modbus ASCII/RTU. * Copyright (c) 2006 Christian Walter * 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: mbfunccoils.c,v 1.8 2007/02/18 23:47:16 wolti Exp $ */ /* ----------------------- System includes ----------------------------------*/ #include "stdlib.h" #include "string.h" /* ----------------------- Platform includes --------------------------------*/ #include "port.h" /* ----------------------- Modbus includes ----------------------------------*/ #include "mb.h" #include "mbframe.h" #include "mbproto.h" #include "mbconfig.h" /* ----------------------- Defines ------------------------------------------*/ #define MB_PDU_FUNC_READ_ADDR_OFF ( MB_PDU_DATA_OFF ) #define MB_PDU_FUNC_READ_COILCNT_OFF ( MB_PDU_DATA_OFF + 2 ) #define MB_PDU_FUNC_READ_SIZE ( 4 ) #define MB_PDU_FUNC_READ_COILCNT_MAX ( 0x07D0 ) #define MB_PDU_FUNC_WRITE_ADDR_OFF ( MB_PDU_DATA_OFF ) #define MB_PDU_FUNC_WRITE_VALUE_OFF ( MB_PDU_DATA_OFF + 2 ) #define MB_PDU_FUNC_WRITE_SIZE ( 4 ) #define MB_PDU_FUNC_WRITE_MUL_ADDR_OFF ( MB_PDU_DATA_OFF ) #define MB_PDU_FUNC_WRITE_MUL_COILCNT_OFF ( MB_PDU_DATA_OFF + 2 ) #define MB_PDU_FUNC_WRITE_MUL_BYTECNT_OFF ( MB_PDU_DATA_OFF + 4 ) #define MB_PDU_FUNC_WRITE_MUL_VALUES_OFF ( MB_PDU_DATA_OFF + 5 ) #define MB_PDU_FUNC_WRITE_MUL_SIZE_MIN ( 5 ) #define MB_PDU_FUNC_WRITE_MUL_COILCNT_MAX ( 0x07B0 ) /* ----------------------- Static functions ---------------------------------*/ eMBException prveMBError2Exception( eMBErrorCode eErrorCode ); /* ----------------------- Start implementation -----------------------------*/ #if MB_FUNC_READ_COILS_ENABLED > 0 eMBException eMBFuncReadCoils( UCHAR * pucFrame, USHORT * usLen ) { USHORT usRegAddress; USHORT usCoilCount; UCHAR ucNBytes; UCHAR *pucFrameCur; eMBException eStatus = MB_EX_NONE; eMBErrorCode eRegStatus; if( *usLen == ( MB_PDU_FUNC_READ_SIZE + MB_PDU_SIZE_MIN ) ) { usRegAddress = ( USHORT )( pucFrame[MB_PDU_FUNC_READ_ADDR_OFF] << 8 ); usRegAddress |= ( USHORT )( pucFrame[MB_PDU_FUNC_READ_ADDR_OFF + 1] ); usRegAddress++; usCoilCount = ( USHORT )( pucFrame[MB_PDU_FUNC_READ_COILCNT_OFF] << 8 ); usCoilCount |= ( USHORT )( pucFrame[MB_PDU_FUNC_READ_COILCNT_OFF + 1] ); /* Check if the number of registers to read is valid. If not * return Modbus illegal data value exception. */ if( ( usCoilCount >= 1 ) && ( usCoilCount < MB_PDU_FUNC_READ_COILCNT_MAX ) ) { /* Set the current PDU data pointer to the beginning. */ pucFrameCur = &pucFrame[MB_PDU_FUNC_OFF]; *usLen = MB_PDU_FUNC_OFF; /* First byte contains the function code. */ *pucFrameCur++ = MB_FUNC_READ_COILS; *usLen += 1; /* Test if the quantity of coils is a multiple of 8. If not last * byte is only partially field with unused coils set to zero. */ if( ( usCoilCount & 0x0007 ) != 0 ) { ucNBytes = ( UCHAR )( usCoilCount / 8 + 1 ); } else { ucNBytes = ( UCHAR )( usCoilCount / 8 ); } *pucFrameCur++ = ucNBytes; *usLen += 1; eRegStatus = eMBRegCoilsCB( pucFrameCur, usRegAddress, usCoilCount, MB_REG_READ ); /* If an error occured convert it into a Modbus exception. */ if( eRegStatus != MB_ENOERR ) { eStatus = prveMBError2Exception( eRegStatus ); } else { /* The response contains the function code, the starting address * and the quantity of registers. We reuse the old values in the * buffer because they are still valid. */ *usLen += ucNBytes;; } } else { eStatus = MB_EX_ILLEGAL_DATA_VALUE; } } else { /* Can't be a valid read coil register request because the length * is incorrect. */ eStatus = MB_EX_ILLEGAL_DATA_VALUE; } return eStatus; } #endif #if MB_FUNC_WRITE_COIL_ENABLED > 0 eMBException eMBFuncWriteCoil( UCHAR * pucFrame, USHORT * usLen ) { USHORT usRegAddress; UCHAR ucBuf[2]; eMBException eStatus = MB_EX_NONE; eMBErrorCode eRegStatus; if( *usLen == ( MB_PDU_FUNC_WRITE_SIZE + MB_PDU_SIZE_MIN ) ) { usRegAddress = ( USHORT )( pucFrame[MB_PDU_FUNC_WRITE_ADDR_OFF] << 8 ); usRegAddress |= ( USHORT )( pucFrame[MB_PDU_FUNC_WRITE_ADDR_OFF + 1] ); usRegAddress++; if( ( pucFrame[MB_PDU_FUNC_WRITE_VALUE_OFF + 1] == 0x00 ) && ( ( pucFrame[MB_PDU_FUNC_WRITE_VALUE_OFF] == 0xFF ) || ( pucFrame[MB_PDU_FUNC_WRITE_VALUE_OFF] == 0x00 ) ) ) { ucBuf[1] = 0; if( pucFrame[MB_PDU_FUNC_WRITE_VALUE_OFF] == 0xFF ) { ucBuf[0] = 1; } else { ucBuf[0] = 0; } eRegStatus = eMBRegCoilsCB( &ucBuf[0], usRegAddress, 1, MB_REG_WRITE ); /* If an error occured convert it into a Modbus exception. */ if( eRegStatus != MB_ENOERR ) { eStatus = prveMBError2Exception( eRegStatus ); } } else { eStatus = MB_EX_ILLEGAL_DATA_VALUE; } } else { /* Can't be a valid write coil register request because the length * is incorrect. */ eStatus = MB_EX_ILLEGAL_DATA_VALUE; } return eStatus; } #endif #if MB_FUNC_WRITE_MULTIPLE_COILS_ENABLED > 0 eMBException eMBFuncWriteMultipleCoils( UCHAR * pucFrame, USHORT * usLen ) { USHORT usRegAddress; USHORT usCoilCnt; UCHAR ucByteCount; UCHAR ucByteCountVerify; eMBException eStatus = MB_EX_NONE; eMBErrorCode eRegStatus; if( *usLen > ( MB_PDU_FUNC_WRITE_SIZE + MB_PDU_SIZE_MIN ) ) { usRegAddress = ( USHORT )( pucFrame[MB_PDU_FUNC_WRITE_MUL_ADDR_OFF] << 8 ); usRegAddress |= ( USHORT )( pucFrame[MB_PDU_FUNC_WRITE_MUL_ADDR_OFF + 1] ); usRegAddress++; usCoilCnt = ( USHORT )( pucFrame[MB_PDU_FUNC_WRITE_MUL_COILCNT_OFF] << 8 ); usCoilCnt |= ( USHORT )( pucFrame[MB_PDU_FUNC_WRITE_MUL_COILCNT_OFF + 1] ); ucByteCount = pucFrame[MB_PDU_FUNC_WRITE_MUL_BYTECNT_OFF]; /* Compute the number of expected bytes in the request. */ if( ( usCoilCnt & 0x0007 ) != 0 ) { ucByteCountVerify = ( UCHAR )( usCoilCnt / 8 + 1 ); } else { ucByteCountVerify = ( UCHAR )( usCoilCnt / 8 ); } if( ( usCoilCnt >= 1 ) && ( usCoilCnt <= MB_PDU_FUNC_WRITE_MUL_COILCNT_MAX ) && ( ucByteCountVerify == ucByteCount ) ) { eRegStatus = eMBRegCoilsCB( &pucFrame[MB_PDU_FUNC_WRITE_MUL_VALUES_OFF], usRegAddress, usCoilCnt, MB_REG_WRITE ); /* If an error occured convert it into a Modbus exception. */ if( eRegStatus != MB_ENOERR ) { eStatus = prveMBError2Exception( eRegStatus ); } else { /* The response contains the function code, the starting address * and the quantity of registers. We reuse the old values in the * buffer because they are still valid. */ *usLen = MB_PDU_FUNC_WRITE_MUL_BYTECNT_OFF; } } else { eStatus = MB_EX_ILLEGAL_DATA_VALUE; } } else { /* Can't be a valid write coil register request because the length * is incorrect. */ eStatus = MB_EX_ILLEGAL_DATA_VALUE; } return eStatus; } #endif