open_source / modbus

  #include <config.h>
  #include <errno.h>
  #include <limits.h>
  #include <stdio.h>
  #include <string.h>
  #include <stdlib.h>
  #include <stdarg.h>
  #include <time.h>
  #include <unistd.h>
  
  #include "modbus.h"
  #include "modbus-private.h"
  
  /* Internal use */
  #define MSG_LENGTH_UNDEFINED -1
  
  /* Max between RTU and TCP max adu length (so TCP) */
  #define MAX_MESSAGE_LENGTH 260
  
  /* 3 steps are used to parse the query */
  typedef enum 
  {
      _STEP_FUNCTION,
      _STEP_META,
      _STEP_DATA
  } _step_t;
  
  const char *modbus_strerror( int errnum ) 
  {
      switch (errnum) 
      {
          case EMBXILFUN:
              return "Illegal function";
          case EMBXILADD:
              return "Illegal data address";
          case EMBXILVAL:
              return "Illegal data value";
          case EMBXSFAIL:
              return "Slave device or server failure";
          case EMBXACK:
              return "Acknowledge";
          case EMBXSBUSY:
              return "Slave device or server is busy";
          case EMBXNACK:
              return "Negative acknowledge";
          case EMBXMEMPAR:
              return "Memory parity error";
          case EMBXGPATH:
              return "Gateway path unavailable";
          case EMBXGTAR:
              return "Target device failed to respond";
          case EMBBADCRC:
              return "Invalid CRC";
          case EMBBADDATA:
              return "Invalid data";
          case EMBBADEXC:
              return "Invalid exception code";
          case EMBMDATA:
              return "Too many data";
          case EMBBADSLAVE:
              return "Response not from requested slave";
          default:
              return strerror(errnum);
      }
  }
  
  void _error_print(modbus_t *ctx, const char *context)
  {
      if (ctx->debug) 
      {
          fprintf(stderr, "ERROR %s", modbus_strerror(errno));
          if (context != NULL) 
          {
              fprintf(stderr, ": %s\n", context);
          } 
          else 
          {
              fprintf(stderr, "\n");
          }
      }
  }
  
  static void _sleep_response_timeout(modbus_t *ctx)
  {
      /* Response timeout is always positive */
      /* usleep source code */
      struct timespec request, remaining;
      request.tv_sec = ctx->response_timeout.tv_sec;
      request.tv_nsec = ((long int)ctx->response_timeout.tv_usec) * 1000;
      while ( nanosleep( &request, &remaining ) == -1 && errno == EINTR ) 
      {
          request = remaining;
      }
  }
  
  int modbus_flush(modbus_t *ctx)
  {
      int rc;
  
      if (ctx == NULL) 
      {
          errno = EINVAL;
          return -1;
      }
  
      rc = ctx->backend->flush( ctx );
      if (rc != -1 && ctx->debug) 
      {
          /* Not all backends are able to return the number of bytes flushed */
          printf("Bytes flushed (%d)\n", rc);
      }
      return rc;
  }
  
  /* Computes the length of the expected response */
  static unsigned int compute_response_length_from_request(modbus_t *ctx, uint8_t *req)
  {
      int length;
      const int offset = ctx->backend->header_length;
  
      switch (req[offset]) 
      {
          case MODBUS_FC_READ_COILS:
          case MODBUS_FC_READ_DISCRETE_INPUTS: 
              /* Header + nb values (code from write_bits) */
              int nb = (req[offset + 3] << 8) | req[offset + 4];
              length = 2 + (nb / 8) + ((nb % 8) ? 1 : 0);
              break;
          case MODBUS_FC_WRITE_AND_READ_REGISTERS:
          case MODBUS_FC_READ_HOLDING_REGISTERS:
          case MODBUS_FC_READ_INPUT_REGISTERS:
              /* Header + 2 * nb values */
              length = 2 + 2 * (req[offset + 3] << 8 | req[offset + 4]);
              break;
          case MODBUS_FC_READ_EXCEPTION_STATUS:
              length = 3;
              break;
          case MODBUS_FC_REPORT_SLAVE_ID:
              /* The response is device specific (the header provides the
                 length) */
              return MSG_LENGTH_UNDEFINED;
          case MODBUS_FC_MASK_WRITE_REGISTER:
              length = 7;
              break;
          default:
              length = 5;
      }
  
      return offset + length + ctx->backend->checksum_length;
  }
  
  /* Sends a request/response */
  static int send_msg(modbus_t *ctx, uint8_t *msg, int msg_length)
  {
      int rc;
      int i;
  
      msg_length = ctx->backend->send_msg_pre(msg, msg_length);
  
      if (ctx->debug) 
      {
          for (i = 0; i < msg_length; i++)
          {
              printf("[%.2X]", msg[i]);
          }
          printf("\n");
      }
      
  	/* In recovery mode, the write command will be issued until to be
         successful! Disabled by default. */
      do 
      {
          rc = ctx->backend->send(ctx, msg, msg_length);
          if (rc == -1) 
          {
              _error_print(ctx, NULL);
              if (ctx->error_recovery & MODBUS_ERROR_RECOVERY_LINK) 
              {
                  int saved_errno = errno;
  
                  if ( (errno == EBADF || errno == ECONNRESET || errno == EPIPE)) 
                  {
                      modbus_close(ctx);
                      _sleep_response_timeout(ctx);
                      modbus_connect(ctx);
                  } 
                  else 
                  {
                      _sleep_response_timeout(ctx);
                      modbus_flush(ctx);
                  }
                  errno = saved_errno;
              }
          }
      } while ( (ctx->error_recovery & MODBUS_ERROR_RECOVERY_LINK) && rc == -1);
  
      if (rc > 0 && rc != msg_length) {
          errno = EMBBADDATA;
          return -1;
      }
  
      return rc;
  }
  
  int modbus_send_raw_request( modbus_t *ctx, uint8_t *raw_req, int raw_req_length )
  {
      sft_t sft;
      uint8_t req[MAX_MESSAGE_LENGTH];
      int req_length;
  
      if (ctx == NULL) 
      {
          errno = EINVAL;
          return -1;
      }
  
      if (raw_req_length < 2 || raw_req_length > (MODBUS_MAX_PDU_LENGTH + 1)) 
      {
          /* The raw request must contain function and slave at least and
             must not be longer than the maximum pdu length plus the slave
             address. */
          errno = EINVAL;
          return -1;
      }
  
      sft.slave = raw_req[0];
      sft.function = raw_req[1];
      /* The t_id is left to zero */
      sft.t_id = 0;
      /* This response function only set the header so it's convenient here */
      req_length = ctx->backend->build_response_basis(&sft, req);
  
      if( raw_req_length > 2 ) 
      {
          /* Copy data after function code */
          memcpy(req + req_length, raw_req + 2, raw_req_length - 2);
          req_length += raw_req_length - 2;
      }
  
      return send_msg(ctx, req, req_length);
  }
  
  /*
   *  ---------- Request     Indication ----------
   *  | Client | ---------------------->| Server |
   *  ---------- Confirmation  Response ----------
   */
  
  /* Computes the length to read after the function received */
  static uint8_t compute_meta_length_after_function( int function, msg_type_t msg_type )
  {
      int length;
  
      if (msg_type == MSG_INDICATION) 
      {
          if (function <= MODBUS_FC_WRITE_SINGLE_REGISTER) 
          {
              length = 4;
          } 
          else if (function == MODBUS_FC_WRITE_MULTIPLE_COILS || function == MODBUS_FC_WRITE_MULTIPLE_REGISTERS) 
          {
              length = 5;
          } 
          else if (function == MODBUS_FC_MASK_WRITE_REGISTER) 
          {
              length = 6;
          } 
          else if (function == MODBUS_FC_WRITE_AND_READ_REGISTERS) 
          {
              length = 9;
          } 
          else 
          {
              /* MODBUS_FC_READ_EXCEPTION_STATUS, MODBUS_FC_REPORT_SLAVE_ID */
              length = 0;
          }
      } 
      else 
      {
          /* MSG_CONFIRMATION */
          switch (function) 
          {
              case MODBUS_FC_WRITE_SINGLE_COIL:
              case MODBUS_FC_WRITE_SINGLE_REGISTER:
              case MODBUS_FC_WRITE_MULTIPLE_COILS:
              case MODBUS_FC_WRITE_MULTIPLE_REGISTERS:
                  length = 4;
                  break;
              case MODBUS_FC_MASK_WRITE_REGISTER:
                  length = 6;
                  break;
              default:
                  length = 1;
          }
      }
  
      return length;
  }
  
  /* Computes the length to read after the meta information (address, count, etc) */
  static int compute_data_length_after_meta(modbus_t *ctx, uint8_t *msg, msg_type_t msg_type)
  {
      int function = msg[ctx->backend->header_length];
      int length;
  
      if (msg_type == MSG_INDICATION) 
      {
          switch (function) 
          {
              case MODBUS_FC_WRITE_MULTIPLE_COILS:
              case MODBUS_FC_WRITE_MULTIPLE_REGISTERS:
                  length = msg[ctx->backend->header_length + 5];
                  break;
              case MODBUS_FC_WRITE_AND_READ_REGISTERS:
                  length = msg[ctx->backend->header_length + 9];
                  break;
              default:
                  length = 0;
          }
      } 
      else 
      {
          /* MSG_CONFIRMATION */
          if (function <= MODBUS_FC_READ_INPUT_REGISTERS ||
              function == MODBUS_FC_REPORT_SLAVE_ID ||
              function == MODBUS_FC_WRITE_AND_READ_REGISTERS) 
          {
              length = msg[ctx->backend->header_length + 1];
          } 
          else 
          {
              length = 0;
          }
      }
  
      length += ctx->backend->checksum_length;
  
      return length;
  }
  
  
  /* Waits a response from a modbus server or a request from a modbus client.
     This function blocks if there is no replies (3 timeouts).
  
     The function shall return the number of received characters and the received
     message in an array of uint8_t if successful. Otherwise it shall return -1
     and errno is set to one of the values defined below:
     - ECONNRESET
     - EMBBADDATA
     - EMBUNKEXC
     - ETIMEDOUT
     - read() or recv() error codes
  */
  
  int _modbus_receive_msg( modbus_t *ctx, uint8_t *msg, msg_type_t msg_type )
  {
      int rc;
      fd_set rset;
      struct timeval tv;
      struct timeval *p_tv;
      int length_to_read;
      int msg_length = 0;
      _step_t step;
  
      if (ctx->debug) 
      {
          if (msg_type == MSG_INDICATION) 
          {
              printf("Waiting for a indication...\n");
          } 
          else 
          {
              printf("Waiting for a confirmation...\n");
          }
      }
  
      /* Add a file descriptor to the set */
      FD_ZERO(&rset);
      FD_SET(ctx->s, &rset);
  
      /* We need to analyse the message step by step.  At the first step, we want
       * to reach the function code because all packets contain this
       * information. */
      step = _STEP_FUNCTION;
      length_to_read = ctx->backend->header_length + 1;
  
      if (msg_type == MSG_INDICATION) 
      {
          /* Wait for a message, we don't know when the message will be
           * received */
          p_tv = NULL;
      } 
      else 
      {
          tv.tv_sec = ctx->response_timeout.tv_sec;
          tv.tv_usec = ctx->response_timeout.tv_usec;
          p_tv = &tv;
      }
  
      while (length_to_read != 0) 
      {
          rc = ctx->backend->select(ctx, &rset, p_tv, length_to_read);
          if (rc == -1) 
          {
              _error_print(ctx, "select");
              if (ctx->error_recovery & MODBUS_ERROR_RECOVERY_LINK) 
              {
                  int saved_errno = errno;
  
                  if (errno == ETIMEDOUT) 
                  {
                      _sleep_response_timeout(ctx);
                      modbus_flush(ctx);
                  } 
                  else if (errno == EBADF) 
                  {
                      modbus_close(ctx);
                      modbus_connect(ctx);
                  }
                  errno = saved_errno;
              }
              return -1;
          }
  
          rc = ctx->backend->recv(ctx, msg + msg_length, length_to_read);
          if (rc == 0) 
          {
              errno = ECONNRESET;
              rc = -1;
          }
  
          if (rc == -1) 
          {
              _error_print(ctx, "read");
              if ((ctx->error_recovery & MODBUS_ERROR_RECOVERY_LINK) &&
                  (errno == ECONNRESET || errno == ECONNREFUSED ||
                   errno == EBADF)) 
              {
                  int saved_errno = errno;
                  modbus_close(ctx);
                  modbus_connect(ctx);
                  /* Could be removed by previous calls */
                  errno = saved_errno;
              }
              return -1;
          }
  
          /* Display the hex code of each character received */
          if (ctx->debug) 
          {
              int i;
              for (i=0; i < rc; i++)
                  printf("<%.2X>", msg[msg_length + i]);
          }
  
          /* Sums bytes received */
          msg_length += rc;
          /* Computes remaining bytes */
          length_to_read -= rc;
  
          if (length_to_read == 0) 
          {
              switch (step) 
              {
              case _STEP_FUNCTION:
                  /* Function code position */
                  length_to_read = compute_meta_length_after_function( msg[ctx->backend->header_length], msg_type);
                  if (length_to_read != 0) 
                  {
                      step = _STEP_META;
                      break;
                  } /* else switches straight to the next step */
              case _STEP_META:
                  length_to_read = compute_data_length_after_meta( ctx, msg, msg_type);
                  if ( (msg_length + length_to_read) > (int)ctx->backend->max_adu_length ) 
                  {
                      errno = EMBBADDATA;
                      _error_print(ctx, "too many data");
                      return -1;
                  }
                  step = _STEP_DATA;
                  break;
              default:
                  break;
              }
          }
  
          if (length_to_read > 0 &&
              (ctx->byte_timeout.tv_sec > 0 || ctx->byte_timeout.tv_usec > 0)) {
              /* If there is no character in the buffer, the allowed timeout
                 interval between two consecutive bytes is defined by
                 byte_timeout */
              tv.tv_sec = ctx->byte_timeout.tv_sec;
              tv.tv_usec = ctx->byte_timeout.tv_usec;
              p_tv = &tv;
          }
          /* else timeout isn't set again, the full response must be read before
             expiration of response timeout (for CONFIRMATION only) */
      }
  
      if (ctx->debug)
          printf("\n");
  
      return ctx->backend->check_integrity(ctx, msg, msg_length);
  }
  
  /* Receive the request from a modbus master */
  int modbus_receive(modbus_t *ctx, uint8_t *req)
  {
      if (ctx == NULL) {
          errno = EINVAL;
          return -1;
      }
  
      return ctx->backend->receive(ctx, req);
  }
  
  /* Receives the confirmation.
  
     The function shall store the read response in rsp and return the number of
     values (bits or words). Otherwise, its shall return -1 and errno is set.
  
     The function doesn't check the confirmation is the expected response to the
     initial request.
  */
  int modbus_receive_confirmation(modbus_t *ctx, uint8_t *rsp)
  {
      if (ctx == NULL) {
          errno = EINVAL;
          return -1;
      }
  
      return _modbus_receive_msg(ctx, rsp, MSG_CONFIRMATION);
  }
  
  static int check_confirmation(modbus_t *ctx, uint8_t *req,
                                uint8_t *rsp, int rsp_length)
  {
      int rc;
      int rsp_length_computed;
      const int offset = ctx->backend->header_length;
      const int function = rsp[offset];
  
      if (ctx->backend->pre_check_confirmation) {
          rc = ctx->backend->pre_check_confirmation(ctx, req, rsp, rsp_length);
          if (rc == -1) {
              if (ctx->error_recovery & MODBUS_ERROR_RECOVERY_PROTOCOL) {
                  _sleep_response_timeout(ctx);
                  modbus_flush(ctx);
              }
              return -1;
          }
      }
  
      rsp_length_computed = compute_response_length_from_request(ctx, req);
  
      /* Exception code */
      if (function >= 0x80) {
          if (rsp_length == (offset + 2 + (int)ctx->backend->checksum_length) &&
              req[offset] == (rsp[offset] - 0x80)) {
              /* Valid exception code received */
  
              int exception_code = rsp[offset + 1];
              if (exception_code < MODBUS_EXCEPTION_MAX) {
                  errno = MODBUS_ENOBASE + exception_code;
              } else {
                  errno = EMBBADEXC;
              }
              _error_print(ctx, NULL);
              return -1;
          } else {
              errno = EMBBADEXC;
              _error_print(ctx, NULL);
              return -1;
          }
      }
  
      /* Check length */
      if ((rsp_length == rsp_length_computed ||
           rsp_length_computed == MSG_LENGTH_UNDEFINED) &&
          function < 0x80) {
          int req_nb_value;
          int rsp_nb_value;
  
          /* Check function code */
          if (function != req[offset]) {
              if (ctx->debug) {
                  fprintf(stderr,
                          "Received function not corresponding to the request (0x%X != 0x%X)\n",
                          function, req[offset]);
              }
              if (ctx->error_recovery & MODBUS_ERROR_RECOVERY_PROTOCOL) {
                  _sleep_response_timeout(ctx);
                  modbus_flush(ctx);
              }
              errno = EMBBADDATA;
              return -1;
          }
  
          /* Check the number of values is corresponding to the request */
          switch (function) {
          case MODBUS_FC_READ_COILS:
          case MODBUS_FC_READ_DISCRETE_INPUTS:
              /* Read functions, 8 values in a byte (nb
               * of values in the request and byte count in
               * the response. */
              req_nb_value = (req[offset + 3] << 8) + req[offset + 4];
              req_nb_value = (req_nb_value / 8) + ((req_nb_value % 8) ? 1 : 0);
              rsp_nb_value = rsp[offset + 1];
              break;
          case MODBUS_FC_WRITE_AND_READ_REGISTERS:
          case MODBUS_FC_READ_HOLDING_REGISTERS:
          case MODBUS_FC_READ_INPUT_REGISTERS:
              /* Read functions 1 value = 2 bytes */
              req_nb_value = (req[offset + 3] << 8) + req[offset + 4];
              rsp_nb_value = (rsp[offset + 1] / 2);
              break;
          case MODBUS_FC_WRITE_MULTIPLE_COILS:
          case MODBUS_FC_WRITE_MULTIPLE_REGISTERS:
              /* N Write functions */
              req_nb_value = (req[offset + 3] << 8) + req[offset + 4];
              rsp_nb_value = (rsp[offset + 3] << 8) | rsp[offset + 4];
              break;
          case MODBUS_FC_REPORT_SLAVE_ID:
              /* Report slave ID (bytes received) */
              req_nb_value = rsp_nb_value = rsp[offset + 1];
              break;
          default:
              /* 1 Write functions & others */
              req_nb_value = rsp_nb_value = 1;
          }
  
          if (req_nb_value == rsp_nb_value) {
              rc = rsp_nb_value;
          } else {
              if (ctx->debug) {
                  fprintf(stderr,
                          "Quantity not corresponding to the request (%d != %d)\n",
                          rsp_nb_value, req_nb_value);
              }
  
              if (ctx->error_recovery & MODBUS_ERROR_RECOVERY_PROTOCOL) {
                  _sleep_response_timeout(ctx);
                  modbus_flush(ctx);
              }
  
              errno = EMBBADDATA;
              rc = -1;
          }
      } else {
          if (ctx->debug) {
              fprintf(stderr,
                      "Message length not corresponding to the computed length (%d != %d)\n",
                      rsp_length, rsp_length_computed);
          }
          if (ctx->error_recovery & MODBUS_ERROR_RECOVERY_PROTOCOL) {
              _sleep_response_timeout(ctx);
              modbus_flush(ctx);
          }
          errno = EMBBADDATA;
          rc = -1;
      }
  
      return rc;
  }
  
  static int response_io_status(uint8_t *tab_io_status,
                                int address, int nb,
                                uint8_t *rsp, int offset)
  {
      int shift = 0;
      /* Instead of byte (not allowed in Win32) */
      int one_byte = 0;
      int i;
  
      for (i = address; i < address + nb; i++) {
          one_byte |= tab_io_status[i] << shift;
          if (shift == 7) {
              /* Byte is full */
              rsp[offset++] = one_byte;
              one_byte = shift = 0;
          } else {
              shift++;
          }
      }
  
      if (shift != 0)
          rsp[offset++] = one_byte;
  
      return offset;
  }
  
  /* Build the exception response */
  static int response_exception(modbus_t *ctx, sft_t *sft,
                                int exception_code, uint8_t *rsp,
                                unsigned int to_flush,
                                const char* template, ...)
  {
      int rsp_length;
  
      /* Print debug message */
      if (ctx->debug) {
          va_list ap;
  
          va_start(ap, template);
          vfprintf(stderr, template, ap);
          va_end(ap);
      }
  
      /* Flush if required */
      if (to_flush) {
          _sleep_response_timeout(ctx);
          modbus_flush(ctx);
      }
  
      /* Build exception response */
      sft->function = sft->function + 0x80;
      rsp_length = ctx->backend->build_response_basis(sft, rsp);
      rsp[rsp_length++] = exception_code;
  
      return rsp_length;
  }
  
  /* Send a response to the received request.
     Analyses the request and constructs a response.
  
     If an error occurs, this function construct the response
     accordingly.
  */
  int modbus_reply(modbus_t *ctx, const uint8_t *req,
                   int req_length, modbus_mapping_t *mb_mapping)
  {
      int offset;
      int slave;
      int function;
      uint16_t address;
      uint8_t rsp[MAX_MESSAGE_LENGTH];
      int rsp_length = 0;
      sft_t sft;
  
      if (ctx == NULL) {
          errno = EINVAL;
          return -1;
      }
  
      offset = ctx->backend->header_length;
      slave = req[offset - 1];
      function = req[offset];
      address = (req[offset + 1] << 8) + req[offset + 2];
  
      sft.slave = slave;
      sft.function = function;
      sft.t_id = ctx->backend->prepare_response_tid(req, &req_length);
  
      /* Data are flushed on illegal number of values errors. */
      switch (function) {
      case MODBUS_FC_READ_COILS:
      case MODBUS_FC_READ_DISCRETE_INPUTS: {
          unsigned int is_input = (function == MODBUS_FC_READ_DISCRETE_INPUTS);
          int start_bits = is_input ? mb_mapping->start_input_bits : mb_mapping->start_bits;
          int nb_bits = is_input ? mb_mapping->nb_input_bits : mb_mapping->nb_bits;
          uint8_t *tab_bits = is_input ? mb_mapping->tab_input_bits : mb_mapping->tab_bits;
          const char * const name = is_input ? "read_input_bits" : "read_bits";
          int nb = (req[offset + 3] << 8) + req[offset + 4];
          /* The mapping can be shifted to reduce memory consumption and it
             doesn't always start at address zero. */
          int mapping_address = address - start_bits;
  
          if (nb < 1 || MODBUS_MAX_READ_BITS < nb) {
              rsp_length = response_exception(
                  ctx, &sft, MODBUS_EXCEPTION_ILLEGAL_DATA_VALUE, rsp, TRUE,
                  "Illegal nb of values %d in %s (max %d)\n",
                  nb, name, MODBUS_MAX_READ_BITS);
          } else if (mapping_address < 0 || (mapping_address + nb) > nb_bits) {
              rsp_length = response_exception(
                  ctx, &sft,
                  MODBUS_EXCEPTION_ILLEGAL_DATA_ADDRESS, rsp, FALSE,
                  "Illegal data address 0x%0X in %s\n",
                  mapping_address < 0 ? address : address + nb, name);
          } else {
              rsp_length = ctx->backend->build_response_basis(&sft, rsp);
              rsp[rsp_length++] = (nb / 8) + ((nb % 8) ? 1 : 0);
              rsp_length = response_io_status(tab_bits, mapping_address, nb,
                                              rsp, rsp_length);
          }
      }
          break;
      case MODBUS_FC_READ_HOLDING_REGISTERS:
      case MODBUS_FC_READ_INPUT_REGISTERS: {
          unsigned int is_input = (function == MODBUS_FC_READ_INPUT_REGISTERS);
          int start_registers = is_input ? mb_mapping->start_input_registers : mb_mapping->start_registers;
          int nb_registers = is_input ? mb_mapping->nb_input_registers : mb_mapping->nb_registers;
          uint16_t *tab_registers = is_input ? mb_mapping->tab_input_registers : mb_mapping->tab_registers;
          const char * const name = is_input ? "read_input_registers" : "read_registers";
          int nb = (req[offset + 3] << 8) + req[offset + 4];
          /* The mapping can be shifted to reduce memory consumption and it
             doesn't always start at address zero. */
          int mapping_address = address - start_registers;
  
          if (nb < 1 || MODBUS_MAX_READ_REGISTERS < nb) {
              rsp_length = response_exception(
                  ctx, &sft, MODBUS_EXCEPTION_ILLEGAL_DATA_VALUE, rsp, TRUE,
                  "Illegal nb of values %d in %s (max %d)\n",
                  nb, name, MODBUS_MAX_READ_REGISTERS);
          } else if (mapping_address < 0 || (mapping_address + nb) > nb_registers) {
              rsp_length = response_exception(
                  ctx, &sft, MODBUS_EXCEPTION_ILLEGAL_DATA_ADDRESS, rsp, FALSE,
                  "Illegal data address 0x%0X in %s\n",
                  mapping_address < 0 ? address : address + nb, name);
          } else {
              int i;
  
              rsp_length = ctx->backend->build_response_basis(&sft, rsp);
              rsp[rsp_length++] = nb << 1;
              for (i = mapping_address; i < mapping_address + nb; i++) {
                  rsp[rsp_length++] = tab_registers[i] >> 8;
                  rsp[rsp_length++] = tab_registers[i] & 0xFF;
              }
          }
      }
          break;
      case MODBUS_FC_WRITE_SINGLE_COIL: {
          int mapping_address = address - mb_mapping->start_bits;
  
          if (mapping_address < 0 || mapping_address >= mb_mapping->nb_bits) {
              rsp_length = response_exception(
                  ctx, &sft, MODBUS_EXCEPTION_ILLEGAL_DATA_ADDRESS, rsp, FALSE,
                  "Illegal data address 0x%0X in write_bit\n",
                  address);
          } else {
              int data = (req[offset + 3] << 8) + req[offset + 4];
  
              if (data == 0xFF00 || data == 0x0) {
                  mb_mapping->tab_bits[mapping_address] = data ? ON : OFF;
                  memcpy(rsp, req, req_length);
                  rsp_length = req_length;
              } else {
                  rsp_length = response_exception(
                      ctx, &sft,
                      MODBUS_EXCEPTION_ILLEGAL_DATA_VALUE, rsp, FALSE,
                      "Illegal data value 0x%0X in write_bit request at address %0X\n",
                      data, address);
              }
          }
      }
          break;
      case MODBUS_FC_WRITE_SINGLE_REGISTER: {
          int mapping_address = address - mb_mapping->start_registers;
  
          if (mapping_address < 0 || mapping_address >= mb_mapping->nb_registers) {
              rsp_length = response_exception(
                  ctx, &sft,
                  MODBUS_EXCEPTION_ILLEGAL_DATA_ADDRESS, rsp, FALSE,
                  "Illegal data address 0x%0X in write_register\n",
                  address);
          } else {
              int data = (req[offset + 3] << 8) + req[offset + 4];
  
              mb_mapping->tab_registers[mapping_address] = data;
              memcpy(rsp, req, req_length);
              rsp_length = req_length;
          }
      }
          break;
      case MODBUS_FC_WRITE_MULTIPLE_COILS: {
          int nb = (req[offset + 3] << 8) + req[offset + 4];
          int mapping_address = address - mb_mapping->start_bits;
  
          if (nb < 1 || MODBUS_MAX_WRITE_BITS < nb) {
              /* May be the indication has been truncated on reading because of
               * invalid address (eg. nb is 0 but the request contains values to
               * write) so it's necessary to flush. */
              rsp_length = response_exception(
                  ctx, &sft, MODBUS_EXCEPTION_ILLEGAL_DATA_VALUE, rsp, TRUE,
                  "Illegal number of values %d in write_bits (max %d)\n",
                  nb, MODBUS_MAX_WRITE_BITS);
          } else if (mapping_address < 0 ||
                     (mapping_address + nb) > mb_mapping->nb_bits) {
              rsp_length = response_exception(
                  ctx, &sft,
                  MODBUS_EXCEPTION_ILLEGAL_DATA_ADDRESS, rsp, FALSE,
                  "Illegal data address 0x%0X in write_bits\n",
                  mapping_address < 0 ? address : address + nb);
          } else {
              /* 6 = byte count */
              modbus_set_bits_from_bytes(mb_mapping->tab_bits, mapping_address, nb,
                                         &req[offset + 6]);
  
              rsp_length = ctx->backend->build_response_basis(&sft, rsp);
              /* 4 to copy the bit address (2) and the quantity of bits */
              memcpy(rsp + rsp_length, req + rsp_length, 4);
              rsp_length += 4;
          }
      }
          break;
      case MODBUS_FC_WRITE_MULTIPLE_REGISTERS: {
          int nb = (req[offset + 3] << 8) + req[offset + 4];
          int mapping_address = address - mb_mapping->start_registers;
  
          if (nb < 1 || MODBUS_MAX_WRITE_REGISTERS < nb) {
              rsp_length = response_exception(
                  ctx, &sft, MODBUS_EXCEPTION_ILLEGAL_DATA_VALUE, rsp, TRUE,
                  "Illegal number of values %d in write_registers (max %d)\n",
                  nb, MODBUS_MAX_WRITE_REGISTERS);
          } else if (mapping_address < 0 ||
                     (mapping_address + nb) > mb_mapping->nb_registers) {
              rsp_length = response_exception(
                  ctx, &sft, MODBUS_EXCEPTION_ILLEGAL_DATA_ADDRESS, rsp, FALSE,
                  "Illegal data address 0x%0X in write_registers\n",
                  mapping_address < 0 ? address : address + nb);
          } else {
              int i, j;
              for (i = mapping_address, j = 6; i < mapping_address + nb; i++, j += 2) {
                  /* 6 and 7 = first value */
                  mb_mapping->tab_registers[i] =
                      (req[offset + j] << 8) + req[offset + j + 1];
              }
  
              rsp_length = ctx->backend->build_response_basis(&sft, rsp);
              /* 4 to copy the address (2) and the no. of registers */
              memcpy(rsp + rsp_length, req + rsp_length, 4);
              rsp_length += 4;
          }
      }
          break;
      case MODBUS_FC_REPORT_SLAVE_ID: 
      {
          int str_len;
          int byte_count_pos;
  
          rsp_length = ctx->backend->build_response_basis(&sft, rsp);
          /* Skip byte count for now */
          byte_count_pos = rsp_length++;
          rsp[rsp_length++] = _REPORT_SLAVE_ID;
          /* Run indicator status to ON */
          rsp[rsp_length++] = 0xFF;
          str_len = 3 + strlen(MODBUS_VERSION_STRING);
          memcpy(rsp + rsp_length, "LMB" MODBUS_VERSION_STRING, str_len);
          rsp_length += str_len;
          rsp[byte_count_pos] = rsp_length - byte_count_pos - 1;
      }
          break;
      case MODBUS_FC_READ_EXCEPTION_STATUS:
          if (ctx->debug) {
              fprintf(stderr, "FIXME Not implemented\n");
          }
          errno = ENOPROTOOPT;
          return -1;
          break;
      case MODBUS_FC_MASK_WRITE_REGISTER: {
          int mapping_address = address - mb_mapping->start_registers;
  
          if (mapping_address < 0 || mapping_address >= mb_mapping->nb_registers) {
              rsp_length = response_exception(
                  ctx, &sft, MODBUS_EXCEPTION_ILLEGAL_DATA_ADDRESS, rsp, FALSE,
                  "Illegal data address 0x%0X in write_register\n",
                  address);
          } else {
              uint16_t data = mb_mapping->tab_registers[mapping_address];
              uint16_t and = (req[offset + 3] << 8) + req[offset + 4];
              uint16_t or = (req[offset + 5] << 8) + req[offset + 6];
  
              data = (data & and) | (or & (~and));
              mb_mapping->tab_registers[mapping_address] = data;
              memcpy(rsp, req, req_length);
              rsp_length = req_length;
          }
      }
          break;
      case MODBUS_FC_WRITE_AND_READ_REGISTERS: {
          int nb = (req[offset + 3] << 8) + req[offset + 4];
          uint16_t address_write = (req[offset + 5] << 8) + req[offset + 6];
          int nb_write = (req[offset + 7] << 8) + req[offset + 8];
          int nb_write_bytes = req[offset + 9];
          int mapping_address = address - mb_mapping->start_registers;
          int mapping_address_write = address_write - mb_mapping->start_registers;
  
          if (nb_write < 1 || MODBUS_MAX_WR_WRITE_REGISTERS < nb_write ||
              nb < 1 || MODBUS_MAX_WR_READ_REGISTERS < nb ||
              nb_write_bytes != nb_write * 2) {
              rsp_length = response_exception(
                  ctx, &sft, MODBUS_EXCEPTION_ILLEGAL_DATA_VALUE, rsp, TRUE,
                  "Illegal nb of values (W%d, R%d) in write_and_read_registers (max W%d, R%d)\n",
                  nb_write, nb, MODBUS_MAX_WR_WRITE_REGISTERS, MODBUS_MAX_WR_READ_REGISTERS);
          } else if (mapping_address < 0 ||
                     (mapping_address + nb) > mb_mapping->nb_registers ||
                     mapping_address < 0 ||
                     (mapping_address_write + nb_write) > mb_mapping->nb_registers) {
              rsp_length = response_exception(
                  ctx, &sft, MODBUS_EXCEPTION_ILLEGAL_DATA_ADDRESS, rsp, FALSE,
                  "Illegal data read address 0x%0X or write address 0x%0X write_and_read_registers\n",
                  mapping_address < 0 ? address : address + nb,
                  mapping_address_write < 0 ? address_write : address_write + nb_write);
          } else {
              int i, j;
              rsp_length = ctx->backend->build_response_basis(&sft, rsp);
              rsp[rsp_length++] = nb << 1;
  
              /* Write first.
                 10 and 11 are the offset of the first values to write */
              for (i = mapping_address_write, j = 10;
                   i < mapping_address_write + nb_write; i++, j += 2) {
                  mb_mapping->tab_registers[i] =
                      (req[offset + j] << 8) + req[offset + j + 1];
              }
  
              /* and read the data for the response */
              for (i = mapping_address; i < mapping_address + nb; i++) {
                  rsp[rsp_length++] = mb_mapping->tab_registers[i] >> 8;
                  rsp[rsp_length++] = mb_mapping->tab_registers[i] & 0xFF;
              }
          }
      }
          break;
  
      default:
          rsp_length = response_exception(
              ctx, &sft, MODBUS_EXCEPTION_ILLEGAL_FUNCTION, rsp, TRUE,
              "Unknown Modbus function code: 0x%0X\n", function);
          break;
      }
  
      /* Suppress any responses when the request was a broadcast */
      return (slave == MODBUS_BROADCAST_ADDRESS) ? 0 : send_msg(ctx, rsp, rsp_length);
  }
  
  int modbus_reply_exception(modbus_t *ctx, const uint8_t *req,
                             unsigned int exception_code)
  {
      int offset;
      int slave;
      int function;
      uint8_t rsp[MAX_MESSAGE_LENGTH];
      int rsp_length;
      int dummy_length = 99;
      sft_t sft;
  
      if (ctx == NULL) {
          errno = EINVAL;
          return -1;
      }
  
      offset = ctx->backend->header_length;
      slave = req[offset - 1];
      function = req[offset];
  
      sft.slave = slave;
      sft.function = function + 0x80;;
      sft.t_id = ctx->backend->prepare_response_tid(req, &dummy_length);
      rsp_length = ctx->backend->build_response_basis(&sft, rsp);
  
      /* Positive exception code */
      if (exception_code < MODBUS_EXCEPTION_MAX) {
          rsp[rsp_length++] = exception_code;
          return send_msg(ctx, rsp, rsp_length);
      } else {
          errno = EINVAL;
          return -1;
      }
  }
  
  /* Reads IO status */
  static int read_io_status(modbus_t *ctx, int function,
                            int addr, int nb, uint8_t *dest)
  {
      int rc;
      int req_length;
  
      uint8_t req[_MIN_REQ_LENGTH];
      uint8_t rsp[MAX_MESSAGE_LENGTH];
  
      req_length = ctx->backend->build_request_basis(ctx, function, addr, nb, req);
  
      rc = send_msg(ctx, req, req_length);
      if (rc > 0) {
          int i, temp, bit;
          int pos = 0;
          int offset;
          int offset_end;
  
          rc = _modbus_receive_msg(ctx, rsp, MSG_CONFIRMATION);
          if (rc == -1)
              return -1;
  
          rc = check_confirmation(ctx, req, rsp, rc);
          if (rc == -1)
              return -1;
  
          offset = ctx->backend->header_length + 2;
          offset_end = offset + rc;
          for (i = offset; i < offset_end; i++) {
              /* Shift reg hi_byte to temp */
              temp = rsp[i];
  
              for (bit = 0x01; (bit & 0xff) && (pos < nb);) {
                  dest[pos++] = (temp & bit) ? TRUE : FALSE;
                  bit = bit << 1;
              }
  
          }
      }
  
      return rc;
  }
  
  /* Reads the boolean status of bits and sets the array elements
     in the destination to TRUE or FALSE (single bits). */
  int modbus_read_bits(modbus_t *ctx, int addr, int nb, uint8_t *dest)
  {
      int rc;
  
      if (ctx == NULL) {
          errno = EINVAL;
          return -1;
      }
  
      if (nb > MODBUS_MAX_READ_BITS) {
          if (ctx->debug) {
              fprintf(stderr,
                      "ERROR Too many bits requested (%d > %d)\n",
                      nb, MODBUS_MAX_READ_BITS);
          }
          errno = EMBMDATA;
          return -1;
      }
  
      rc = read_io_status(ctx, MODBUS_FC_READ_COILS, addr, nb, dest);
  
      if (rc == -1)
          return -1;
      else
          return nb;
  }
  
  
  /* Same as modbus_read_bits but reads the remote device input table */
  int modbus_read_input_bits(modbus_t *ctx, int addr, int nb, uint8_t *dest)
  {
      int rc;
  
      if (ctx == NULL) {
          errno = EINVAL;
          return -1;
      }
  
      if (nb > MODBUS_MAX_READ_BITS) {
          if (ctx->debug) {
              fprintf(stderr,
                      "ERROR Too many discrete inputs requested (%d > %d)\n",
                      nb, MODBUS_MAX_READ_BITS);
          }
          errno = EMBMDATA;
          return -1;
      }
  
      rc = read_io_status(ctx, MODBUS_FC_READ_DISCRETE_INPUTS, addr, nb, dest);
  
      if (rc == -1)
          return -1;
      else
          return nb;
  }
  
  /* Reads the data from a remove device and put that data into an array */
  static int read_registers(modbus_t *ctx, int function, int addr, int nb, uint16_t *dest)
  {
      int rc;
      int req_length;
      uint8_t req[_MIN_REQ_LENGTH];
      uint8_t rsp[MAX_MESSAGE_LENGTH];
  
      if (nb > MODBUS_MAX_READ_REGISTERS)
      {
          if (ctx->debug)
          {
              fprintf(stderr,
                      "ERROR Too many registers requested (%d > %d)\n",
                      nb, MODBUS_MAX_READ_REGISTERS);
          }
          errno = EMBMDATA;
          return -1;
      }
  
      req_length = ctx->backend->build_request_basis(ctx, function, addr, nb, req);
  
      rc = send_msg(ctx, req, req_length);
      if (rc > 0)
      {
          int offset;
          int i;
  
          rc = _modbus_receive_msg(ctx, rsp, MSG_CONFIRMATION);
          if (rc == -1)
              return -1;
  
          rc = check_confirmation(ctx, req, rsp, rc);
          if (rc == -1)
              return -1;
  
          offset = ctx->backend->header_length;
  
          for (i = 0; i < rc; i++) {
              /* shift reg hi_byte to temp OR with lo_byte */
              dest[i] = (rsp[offset + 2 + (i << 1)] << 8) |
                  rsp[offset + 3 + (i << 1)];
          }
      }
  
      return rc;
  }
  
  /* Reads the holding registers of remote device and put the data into an
     array */
  int modbus_read_registers(modbus_t *ctx, int addr, int nb, uint16_t *dest)
  {
      int status;
  
      if (ctx == NULL) {
          errno = EINVAL;
          return -1;
      }
  
      if (nb > MODBUS_MAX_READ_REGISTERS)
      {
          if (ctx->debug)
          {
              fprintf(stderr,
                      "ERROR Too many registers requested (%d > %d)\n",
                      nb, MODBUS_MAX_READ_REGISTERS);
          }
          errno = EMBMDATA;
          return -1;
      }
  
      status = read_registers(ctx, MODBUS_FC_READ_HOLDING_REGISTERS,
                              addr, nb, dest);
      return status;
  }
  
  /* Reads the input registers of remote device and put the data into an array */
  int modbus_read_input_registers(modbus_t *ctx, int addr, int nb,
                                  uint16_t *dest)
  {
      int status;
  
      if (ctx == NULL) {
          errno = EINVAL;
          return -1;
      }
  
      if (nb > MODBUS_MAX_READ_REGISTERS) {
          fprintf(stderr,
                  "ERROR Too many input registers requested (%d > %d)\n",
                  nb, MODBUS_MAX_READ_REGISTERS);
          errno = EMBMDATA;
          return -1;
      }
  
      status = read_registers(ctx, MODBUS_FC_READ_INPUT_REGISTERS,
                              addr, nb, dest);
  
      return status;
  }
  
  /* Write a value to the specified register of the remote device.
     Used by write_bit and write_register */
  static int write_single(modbus_t *ctx, int function, int addr, int value)
  {
      int rc;
      int req_length;
      uint8_t req[_MIN_REQ_LENGTH];
  
      if (ctx == NULL) {
          errno = EINVAL;
          return -1;
      }
  
      req_length = ctx->backend->build_request_basis(ctx, function, addr, value, req);
  
      rc = send_msg(ctx, req, req_length);
      if (rc > 0) {
          /* Used by write_bit and write_register */
          uint8_t rsp[MAX_MESSAGE_LENGTH];
  
          rc = _modbus_receive_msg(ctx, rsp, MSG_CONFIRMATION);
          if (rc == -1)
              return -1;
  
          rc = check_confirmation(ctx, req, rsp, rc);
      }
  
      return rc;
  }
  
  /* Turns ON or OFF a single bit of the remote device */
  int modbus_write_bit(modbus_t *ctx, int addr, int status)
  {
      if (ctx == NULL) {
          errno = EINVAL;
          return -1;
      }
  
      return write_single(ctx, MODBUS_FC_WRITE_SINGLE_COIL, addr,
                          status ? 0xFF00 : 0);
  }
  
  /* Writes a value in one register of the remote device */
  int modbus_write_register(modbus_t *ctx, int addr, int value)
  {
      if (ctx == NULL) {
          errno = EINVAL;
          return -1;
      }
  
      return write_single(ctx, MODBUS_FC_WRITE_SINGLE_REGISTER, addr, value);
  }
  
  /* Write the bits of the array in the remote device */
  int modbus_write_bits(modbus_t *ctx, int addr, int nb, const uint8_t *src)
  {
      int rc;
      int i;
      int byte_count;
      int req_length;
      int bit_check = 0;
      int pos = 0;
      uint8_t req[MAX_MESSAGE_LENGTH];
  
      if (ctx == NULL) {
          errno = EINVAL;
          return -1;
      }
  
      if (nb > MODBUS_MAX_WRITE_BITS) {
          if (ctx->debug) {
              fprintf(stderr, "ERROR Writing too many bits (%d > %d)\n",
                      nb, MODBUS_MAX_WRITE_BITS);
          }
          errno = EMBMDATA;
          return -1;
      }
  
      req_length = ctx->backend->build_request_basis(ctx,
                                                     MODBUS_FC_WRITE_MULTIPLE_COILS,
                                                     addr, nb, req);
      byte_count = (nb / 8) + ((nb % 8) ? 1 : 0);
      req[req_length++] = byte_count;
  
      for (i = 0; i < byte_count; i++) {
          int bit;
  
          bit = 0x01;
          req[req_length] = 0;
  
          while ((bit & 0xFF) && (bit_check++ < nb)) {
              if (src[pos++])
                  req[req_length] |= bit;
              else
                  req[req_length] &=~ bit;
  
              bit = bit << 1;
          }
          req_length++;
      }
  
      rc = send_msg(ctx, req, req_length);
      if (rc > 0) {
          uint8_t rsp[MAX_MESSAGE_LENGTH];
  
          rc = _modbus_receive_msg(ctx, rsp, MSG_CONFIRMATION);
          if (rc == -1)
              return -1;
  
          rc = check_confirmation(ctx, req, rsp, rc);
      }
  
  
      return rc;
  }
  
  /* Write the values from the array to the registers of the remote device */
  int modbus_write_registers(modbus_t *ctx, int addr, int nb, const uint16_t *src)
  {
      int rc;
      int i;
      int req_length;
      int byte_count;
      uint8_t req[MAX_MESSAGE_LENGTH];
  
      if (ctx == NULL) {
          errno = EINVAL;
          return -1;
      }
  
      if (nb > MODBUS_MAX_WRITE_REGISTERS) {
          if (ctx->debug) {
              fprintf(stderr,
                      "ERROR Trying to write to too many registers (%d > %d)\n",
                      nb, MODBUS_MAX_WRITE_REGISTERS);
          }
          errno = EMBMDATA;
          return -1;
      }
  
      req_length = ctx->backend->build_request_basis(ctx,
                                                     MODBUS_FC_WRITE_MULTIPLE_REGISTERS,
                                                     addr, nb, req);
      byte_count = nb * 2;
      req[req_length++] = byte_count;
  
      for (i = 0; i < nb; i++) {
          req[req_length++] = src[i] >> 8;
          req[req_length++] = src[i] & 0x00FF;
      }
  
      rc = send_msg(ctx, req, req_length);
      if (rc > 0) {
          uint8_t rsp[MAX_MESSAGE_LENGTH];
  
          rc = _modbus_receive_msg(ctx, rsp, MSG_CONFIRMATION);
          if (rc == -1)
              return -1;
  
          rc = check_confirmation(ctx, req, rsp, rc);
      }
  
      return rc;
  }
  
  int modbus_mask_write_register(modbus_t *ctx, int addr, uint16_t and_mask, uint16_t or_mask)
  {
      int rc;
      int req_length;
      /* The request length can not exceed _MIN_REQ_LENGTH - 2 and 4 bytes to
       * store the masks. The ugly substraction is there to remove the 'nb' value
       * (2 bytes) which is not used. */
      uint8_t req[_MIN_REQ_LENGTH + 2];
  
      req_length = ctx->backend->build_request_basis(ctx,
                                                     MODBUS_FC_MASK_WRITE_REGISTER,
                                                     addr, 0, req);
  
      /* HACKISH, count is not used */
      req_length -= 2;
  
      req[req_length++] = and_mask >> 8;
      req[req_length++] = and_mask & 0x00ff;
      req[req_length++] = or_mask >> 8;
      req[req_length++] = or_mask & 0x00ff;
  
      rc = send_msg(ctx, req, req_length);
      if (rc > 0) {
          /* Used by write_bit and write_register */
          uint8_t rsp[MAX_MESSAGE_LENGTH];
  
          rc = _modbus_receive_msg(ctx, rsp, MSG_CONFIRMATION);
          if (rc == -1)
              return -1;
  
          rc = check_confirmation(ctx, req, rsp, rc);
      }
  
      return rc;
  }
  
  /* Write multiple registers from src array to remote device and read multiple
     registers from remote device to dest array. */
  int modbus_write_and_read_registers(modbus_t *ctx,
                                      int write_addr, int write_nb,
                                      const uint16_t *src,
                                      int read_addr, int read_nb,
                                      uint16_t *dest)
  
  {
      int rc;
      int req_length;
      int i;
      int byte_count;
      uint8_t req[MAX_MESSAGE_LENGTH];
      uint8_t rsp[MAX_MESSAGE_LENGTH];
  
      if (ctx == NULL) {
          errno = EINVAL;
          return -1;
      }
  
      if (write_nb > MODBUS_MAX_WR_WRITE_REGISTERS) {
          if (ctx->debug) {
              fprintf(stderr,
                      "ERROR Too many registers to write (%d > %d)\n",
                      write_nb, MODBUS_MAX_WR_WRITE_REGISTERS);
          }
          errno = EMBMDATA;
          return -1;
      }
  
      if (read_nb > MODBUS_MAX_WR_READ_REGISTERS) {
          if (ctx->debug) {
              fprintf(stderr,
                      "ERROR Too many registers requested (%d > %d)\n",
                      read_nb, MODBUS_MAX_WR_READ_REGISTERS);
          }
          errno = EMBMDATA;
          return -1;
      }
      req_length = ctx->backend->build_request_basis(ctx,
                                                     MODBUS_FC_WRITE_AND_READ_REGISTERS,
                                                     read_addr, read_nb, req);
  
      req[req_length++] = write_addr >> 8;
      req[req_length++] = write_addr & 0x00ff;
      req[req_length++] = write_nb >> 8;
      req[req_length++] = write_nb & 0x00ff;
      byte_count = write_nb * 2;
      req[req_length++] = byte_count;
  
      for (i = 0; i < write_nb; i++) {
          req[req_length++] = src[i] >> 8;
          req[req_length++] = src[i] & 0x00FF;
      }
  
      rc = send_msg(ctx, req, req_length);
      if (rc > 0) {
          int offset;
  
          rc = _modbus_receive_msg(ctx, rsp, MSG_CONFIRMATION);
          if (rc == -1)
              return -1;
  
          rc = check_confirmation(ctx, req, rsp, rc);
          if (rc == -1)
              return -1;
  
          offset = ctx->backend->header_length;
          for (i = 0; i < rc; i++) {
              /* shift reg hi_byte to temp OR with lo_byte */
              dest[i] = (rsp[offset + 2 + (i << 1)] << 8) |
                  rsp[offset + 3 + (i << 1)];
          }
      }
  
      return rc;
  }
  
  /* Send a request to get the slave ID of the device (only available in serial
     communication). */
  int modbus_report_slave_id(modbus_t *ctx, int max_dest, uint8_t *dest)
  {
      int rc;
      int req_length;
      uint8_t req[_MIN_REQ_LENGTH];
  
      if (ctx == NULL || max_dest <= 0) {
          errno = EINVAL;
          return -1;
      }
  
      req_length = ctx->backend->build_request_basis(ctx, MODBUS_FC_REPORT_SLAVE_ID,
                                                     0, 0, req);
  
      /* HACKISH, addr and count are not used */
      req_length -= 4;
  
      rc = send_msg(ctx, req, req_length);
      if (rc > 0) {
          int i;
          int offset;
          uint8_t rsp[MAX_MESSAGE_LENGTH];
  
          rc = _modbus_receive_msg(ctx, rsp, MSG_CONFIRMATION);
          if (rc == -1)
              return -1;
  
          rc = check_confirmation(ctx, req, rsp, rc);
          if (rc == -1)
              return -1;
  
          offset = ctx->backend->header_length + 2;
  
          /* Byte count, slave id, run indicator status and
             additional data. Truncate copy to max_dest. */
          for (i=0; i < rc && i < max_dest; i++) {
              dest[i] = rsp[offset + i];
          }
      }
  
      return rc;
  }
  
  void _modbus_init_common(modbus_t *ctx)
  {
      /* Slave and socket are initialized to -1 */
      ctx->slave = -1;
      ctx->s = -1;
  
      ctx->debug = FALSE;
      ctx->error_recovery = MODBUS_ERROR_RECOVERY_NONE;
  
      ctx->response_timeout.tv_sec = 0;
      ctx->response_timeout.tv_usec = _RESPONSE_TIMEOUT;
  
      ctx->byte_timeout.tv_sec = 0;
      ctx->byte_timeout.tv_usec = _BYTE_TIMEOUT;
  }
  
  /* Define the slave number */
  int modbus_set_slave(modbus_t *ctx, int slave)
  {
      if (ctx == NULL) {
          errno = EINVAL;
          return -1;
      }
  
      return ctx->backend->set_slave(ctx, slave);
  }
  
  int modbus_set_error_recovery(modbus_t *ctx,
                                modbus_error_recovery_mode error_recovery)
  {
      if (ctx == NULL) {
          errno = EINVAL;
          return -1;
      }
  
      /* The type of modbus_error_recovery_mode is unsigned enum */
      ctx->error_recovery = (uint8_t) error_recovery;
      return 0;
  }
  
  int modbus_set_socket(modbus_t *ctx, int s)
  {
      if (ctx == NULL) {
          errno = EINVAL;
          return -1;
      }
  
      ctx->s = s;
      return 0;
  }
  
  int modbus_get_socket(modbus_t *ctx)
  {
      if (ctx == NULL) {
          errno = EINVAL;
          return -1;
      }
  
      return ctx->s;
  }
  
  /* Get the timeout interval used to wait for a response */
  int modbus_get_response_timeout(modbus_t *ctx, uint32_t *to_sec, uint32_t *to_usec)
  {
      if (ctx == NULL) {
          errno = EINVAL;
          return -1;
      }
  
      *to_sec = ctx->response_timeout.tv_sec;
      *to_usec = ctx->response_timeout.tv_usec;
      return 0;
  }
  
  int modbus_set_response_timeout(modbus_t *ctx, uint32_t to_sec, uint32_t to_usec)
  {
      if (ctx == NULL ||
          (to_sec == 0 && to_usec == 0) || to_usec > 999999) {
          errno = EINVAL;
          return -1;
      }
  
      ctx->response_timeout.tv_sec = to_sec;
      ctx->response_timeout.tv_usec = to_usec;
      return 0;
  }
  
  /* Get the timeout interval between two consecutive bytes of a message */
  int modbus_get_byte_timeout(modbus_t *ctx, uint32_t *to_sec, uint32_t *to_usec)
  {
      if (ctx == NULL) {
          errno = EINVAL;
          return -1;
      }
  
      *to_sec = ctx->byte_timeout.tv_sec;
      *to_usec = ctx->byte_timeout.tv_usec;
      return 0;
  }
  
  int modbus_set_byte_timeout(modbus_t *ctx, uint32_t to_sec, uint32_t to_usec)
  {
      /* Byte timeout can be disabled when both values are zero */
      if (ctx == NULL || to_usec > 999999) {
          errno = EINVAL;
          return -1;
      }
  
      ctx->byte_timeout.tv_sec = to_sec;
      ctx->byte_timeout.tv_usec = to_usec;
      return 0;
  }
  
  int modbus_get_header_length(modbus_t *ctx)
  {
      if (ctx == NULL) {
          errno = EINVAL;
          return -1;
      }
  
      return ctx->backend->header_length;
  }
  
  int modbus_connect(modbus_t *ctx)
  {
      if (ctx == NULL) {
          errno = EINVAL;
          return -1;
      }
  
      return ctx->backend->connect(ctx);
  }
  
  void modbus_close(modbus_t *ctx)
  {
      if (ctx == NULL)
          return;
  
      ctx->backend->close(ctx);
  }
  
  void modbus_free(modbus_t *ctx)
  {
      if (ctx == NULL)
          return;
  
      ctx->backend->free(ctx);
  }
  
  int modbus_set_debug(modbus_t *ctx, int flag)
  {
      if (ctx == NULL) {
          errno = EINVAL;
          return -1;
      }
  
      ctx->debug = flag;
      return 0;
  }
  
  /* Allocates 4 arrays to store bits, input bits, registers and inputs
     registers. The pointers are stored in modbus_mapping structure.
  
     The modbus_mapping_new_ranges() function shall return the new allocated
     structure if successful. Otherwise it shall return NULL and set errno to
     ENOMEM. */
  modbus_mapping_t* modbus_mapping_new_start_address(
      unsigned int start_bits, unsigned int nb_bits,
      unsigned int start_input_bits, unsigned int nb_input_bits,
      unsigned int start_registers, unsigned int nb_registers,
      unsigned int start_input_registers, unsigned int nb_input_registers)
  {
      modbus_mapping_t *mb_mapping;
  
      mb_mapping = (modbus_mapping_t *)malloc(sizeof(modbus_mapping_t));
      if (mb_mapping == NULL) {
          return NULL;
      }
  
      /* 0X */
      mb_mapping->nb_bits = nb_bits;
      mb_mapping->start_bits = start_bits;
      if (nb_bits == 0) {
          mb_mapping->tab_bits = NULL;
      } else {
          /* Negative number raises a POSIX error */
          mb_mapping->tab_bits =
              (uint8_t *) malloc(nb_bits * sizeof(uint8_t));
          if (mb_mapping->tab_bits == NULL) {
              free(mb_mapping);
              return NULL;
          }
          memset(mb_mapping->tab_bits, 0, nb_bits * sizeof(uint8_t));
      }
  
      /* 1X */
      mb_mapping->nb_input_bits = nb_input_bits;
      mb_mapping->start_input_bits = start_input_bits;
      if (nb_input_bits == 0) {
          mb_mapping->tab_input_bits = NULL;
      } else {
          mb_mapping->tab_input_bits =
              (uint8_t *) malloc(nb_input_bits * sizeof(uint8_t));
          if (mb_mapping->tab_input_bits == NULL) {
              free(mb_mapping->tab_bits);
              free(mb_mapping);
              return NULL;
          }
          memset(mb_mapping->tab_input_bits, 0, nb_input_bits * sizeof(uint8_t));
      }
  
      /* 4X */
      mb_mapping->nb_registers = nb_registers;
      mb_mapping->start_registers = start_registers;
      if (nb_registers == 0) {
          mb_mapping->tab_registers = NULL;
      } else {
          mb_mapping->tab_registers =
              (uint16_t *) malloc(nb_registers * sizeof(uint16_t));
          if (mb_mapping->tab_registers == NULL) {
              free(mb_mapping->tab_input_bits);
              free(mb_mapping->tab_bits);
              free(mb_mapping);
              return NULL;
          }
          memset(mb_mapping->tab_registers, 0, nb_registers * sizeof(uint16_t));
      }
  
      /* 3X */
      mb_mapping->nb_input_registers = nb_input_registers;
      mb_mapping->start_input_registers = start_input_registers;
      if (nb_input_registers == 0) {
          mb_mapping->tab_input_registers = NULL;
      } else {
          mb_mapping->tab_input_registers =
              (uint16_t *) malloc(nb_input_registers * sizeof(uint16_t));
          if (mb_mapping->tab_input_registers == NULL) {
              free(mb_mapping->tab_registers);
              free(mb_mapping->tab_input_bits);
              free(mb_mapping->tab_bits);
              free(mb_mapping);
              return NULL;
          }
          memset(mb_mapping->tab_input_registers, 0,
                 nb_input_registers * sizeof(uint16_t));
      }
  
      return mb_mapping;
  }
  
  modbus_mapping_t* modbus_mapping_new(int nb_bits, int nb_input_bits,
                                       int nb_registers, int nb_input_registers)
  {
      return modbus_mapping_new_start_address(
          0, nb_bits, 0, nb_input_bits, 0, nb_registers, 0, nb_input_registers);
  }
  
  /* Frees the 4 arrays */
  void modbus_mapping_free(modbus_mapping_t *mb_mapping)
  {
      if (mb_mapping == NULL) {
          return;
      }
  
      free(mb_mapping->tab_input_registers);
      free(mb_mapping->tab_registers);
      free(mb_mapping->tab_input_bits);
      free(mb_mapping->tab_bits);
      free(mb_mapping);
  }
  
  #ifndef HAVE_STRLCPY
  /*
   * Function strlcpy was originally developed by
   * Todd C. Miller <Todd.Miller@courtesan.com> to simplify writing secure code.
   * See ftp://ftp.openbsd.org/pub/OpenBSD/src/lib/libc/string/strlcpy.3
   * for more information.
   *
   * Thank you Ulrich Drepper... not!
   *
   * Copy src to string dest of size dest_size.  At most dest_size-1 characters
   * will be copied.  Always NUL terminates (unless dest_size == 0).  Returns
   * strlen(src); if retval >= dest_size, truncation occurred.
   */
  size_t strlcpy(char *dest, const char *src, size_t dest_size)
  {
      register char *d = dest;
      register const char *s = src;
      register size_t n = dest_size;
  
      /* Copy as many bytes as will fit */
      if (n != 0 && --n != 0) {
          do {
              if ((*d++ = *s++) == 0)
                  break;
          } while (--n != 0);
      }
  
      /* Not enough room in dest, add NUL and traverse rest of src */
      if (n == 0) {
          if (dest_size != 0)
              *d = '\0'; /* NUL-terminate dest */
          while (*s++)
              ;
      }
  
      return (s - src - 1); /* count does not include NUL */
  }
  #endif