S function hangs in line while (Wire.available() < 6)

Question

Alberto Prud'homme 2016년 4월 27일

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https://kr.mathworks.com/matlabcentral/answers/281386-s-function-hangs-in-line-while-wire-available-6

pruebalis3.zip

Hello;

I'm trying to implement a S-function block with the code of arduino to read a IMU sensor. I have the code in c++ and when I send it to the Arduino it works fine, but when I insert to the S-function block during the debug didn't receive any error, but when I turn on the Arduino it hangs.

By testing I found that the program debug in the line: mag.read(); (from the wrapper file)

Following the instruction I found that the program hangs in these lines:

#if defined(MATLAB_MEX_FILE)
#include "tmwtypes.h"
#include "simstruc_types.h"
#else
#include "rtwtypes.h"
#endif
/* %%%-SFUNWIZ_wrapper_includes_Changes_BEGIN --- EDIT HERE TO _END */
# ifndef MATLAB_MEX_FILE
# include <Arduino.h>
# include "Wire.h"
# include "Wire.cpp"
# include "LIS3MDL.h"
# include "LIS3MDL.cpp"
# endif
/* %%%-SFUNWIZ_wrapper_includes_Changes_END --- EDIT HERE TO _BEGIN */
#define y_width 1
/*
 * Create external references here.  
 *
 */
/* %%%-SFUNWIZ_wrapper_externs_Changes_BEGIN --- EDIT HERE TO _END */
/* extern double func(double a); */
/* %%%-SFUNWIZ_wrapper_externs_Changes_END --- EDIT HERE TO _BEGIN */
/*
 * Output functions
 *
 */
extern "C" void lis3_Outputs_wrapper(real_T *y0,
      const real_T *xD)
{
/* %%%-SFUNWIZ_wrapper_Outputs_Changes_BEGIN --- EDIT HERE TO _END */
if (xD[0] == 1){
      # ifndef MATLAB_MEX_FILE
      LIS3MDL mag;
      char report[80];
      mag.read();
      snprintf(report, sizeof(report), "M: %6d %6d %6d",
      mag.m.x, mag.m.y, mag.m.z);
      Serial.println(report);
      # endif
}
/* %%%-SFUNWIZ_wrapper_Outputs_Changes_END --- EDIT HERE TO _BEGIN */
}
/*
  * Updates function
  *
  */
extern "C" void lis3_Update_wrapper(real_T *y0,
      real_T *xD)
{
  /* %%%-SFUNWIZ_wrapper_Update_Changes_BEGIN --- EDIT HERE TO _END */
if (xD[0] != 1){
      # ifndef MATLAB_MEX_FILE
        LIS3MDL mag;
        Serial.begin(9600);
        Wire.begin();
         if (!mag.init())
        {
          Serial.println("Failed to detect and initialize magnetometer!");
          while (1);
        }
        mag.enableDefault();
      # endif    
      xD[0] = 1;
  }
  /* %%%-SFUNWIZ_wrapper_Update_Changes_END --- EDIT HERE TO _BEGIN */
  }

In the While instruction the value of while (Wire.available() < 6) always send a 1, so never pass from the while.

I can't found the origin of the problem, and it's harder to find because the code works fine directly from the INO and the C++ code.

#include <LIS3MDL.h>
#include <Wire.h>
#include <math.h>
// Defines ////////////////////////////////////////////////////////////////
// The Arduino two-wire interface uses a 7-bit number for the address,
// and sets the last bit correctly based on reads and writes
#define LIS3MDL_SA1_HIGH_ADDRESS  0b0011110
#define LIS3MDL_SA1_LOW_ADDRESS   0b0011100
#define TEST_REG_ERROR -1
#define LIS3MDL_WHO_ID  0x3D
// Constructors ////////////////////////////////////////////////////////////////
LIS3MDL::LIS3MDL(void)
{
  _device = device_auto;
    io_timeout = 0;  // 0 = no timeout
    did_timeout = false;
  }
// Public Methods //////////////////////////////////////////////////////////////
// Did a timeout occur in read() since the last call to timeoutOccurred()?
bool LIS3MDL::timeoutOccurred()
{
  bool tmp = did_timeout;
  did_timeout = false;
  return tmp;
}
void LIS3MDL::setTimeout(uint16_t timeout)
{
  io_timeout = timeout;
}
uint16_t LIS3MDL::getTimeout()
{
  return io_timeout;
}
bool LIS3MDL::init(deviceType device, sa1State sa1)
{
  // perform auto-detection unless device type and SA1 state were both specified
  if (device == device_auto || sa1 == sa1_auto)
  {
    // check for LIS3MDL if device is unidentified or was specified to be this type
    if (device == device_auto || device == device_LIS3MDL)
    {
      // check SA1 high address unless SA1 was specified to be low
      if (sa1 != sa1_low && testReg(LIS3MDL_SA1_HIGH_ADDRESS, WHO_AM_I) == LIS3MDL_WHO_ID)
      {
        sa1 = sa1_high;
        if (device == device_auto) { device = device_LIS3MDL; }
      }
      // check SA1 low address unless SA1 was specified to be high
      else if (sa1 != sa1_high && testReg(LIS3MDL_SA1_LOW_ADDRESS, WHO_AM_I) == LIS3MDL_WHO_ID)
      {
        sa1 = sa1_low;
        if (device == device_auto) { device = device_LIS3MDL; }
      }
    }
      // make sure device and SA1 were successfully detected; otherwise, indicate failure
      if (device == device_auto || sa1 == sa1_auto)
      {
        return false;
      }
    }
    _device = device;
    switch (device)
    {
      case device_LIS3MDL:
        address = (sa1 == sa1_high) ? LIS3MDL_SA1_HIGH_ADDRESS : LIS3MDL_SA1_LOW_ADDRESS;
        break;
    }
    return true;
  }
/*
Enables the LIS3MDL's magnetometer. Also:
- Selects ultra-high-performance mode for all axes
- Sets ODR (output data rate) to default power-on value of 10 Hz
- Sets magnetometer full scale (gain) to default power-on value of +/- 4 gauss
- Enables continuous conversion mode
Note that this function will also reset other settings controlled by
the registers it writes to.
*/
void LIS3MDL::enableDefault(void)
{
  if (_device == device_LIS3MDL)
  {
    // 0x70 = 0b01110000
    // OM = 11 (ultra-high-performance mode for X and Y); DO = 100 (10 Hz ODR)
    writeReg(CTRL_REG1, 0x70);
      // 0x00 = 0b00000000
      // FS = 00 (+/- 4 gauss full scale)
      writeReg(CTRL_REG2, 0x00);
      // 0x00 = 0b00000000
      // MD = 00 (continuous-conversion mode)
      writeReg(CTRL_REG3, 0x00);
      // 0x0C = 0b00001100
      // OMZ = 11 (ultra-high-performance mode for Z)
      writeReg(CTRL_REG4, 0x0C);
    }
  }
// Writes a mag register
void LIS3MDL::writeReg(uint8_t reg, uint8_t value)
{
  Wire.beginTransmission(address);
  Wire.write(reg);
  Wire.write(value);
  last_status = Wire.endTransmission();
}
// Reads a mag register
uint8_t LIS3MDL::readReg(uint8_t reg)
{
  uint8_t value;
    Wire.beginTransmission(address);
    Wire.write(reg);
    last_status = Wire.endTransmission();
    Wire.requestFrom(address, (uint8_t)1);
    value = Wire.read();
    Wire.endTransmission();
    return value;
  }
// Reads the 3 mag channels and stores them in vector m
void LIS3MDL::read()
{    
  Wire.beginTransmission(address);
  // assert MSB to enable subaddress updating
  Wire.write(OUT_X_L | 0x80);
  Wire.endTransmission();
  Wire.requestFrom(address, (uint8_t)6);
    uint16_t millis_start = millis();
    while (Wire.available() < 6)
    {    
      if (io_timeout > 0 && ((uint16_t)millis() - millis_start) > io_timeout)
      {
        did_timeout = true;
        return;
      }
    }
    uint8_t xlm = Wire.read();
    uint8_t xhm = Wire.read();
    uint8_t ylm = Wire.read();
    uint8_t yhm = Wire.read();
    uint8_t zlm = Wire.read();
    uint8_t zhm = Wire.read();
    // combine high and low bytes
    m.x = (int16_t)(xhm << 8 | xlm);
    m.y = (int16_t)(yhm << 8 | ylm);
    m.z = (int16_t)(zhm << 8 | zlm);
}
void LIS3MDL::vector_normalize(vector<float> *a)
{
  float mag = sqrt(vector_dot(a, a));
  a->x /= mag;
  a->y /= mag;
  a->z /= mag;
}
// Private Methods //////////////////////////////////////////////////////////////
int16_t LIS3MDL::testReg(uint8_t address, regAddr reg)
{
  Wire.beginTransmission(address);
  Wire.write((uint8_t)reg);
  if (Wire.endTransmission() != 0)
  {
    return TEST_REG_ERROR;
  }
    Wire.requestFrom(address, (uint8_t)1);
    if (Wire.available())
    {
      return Wire.read();
    }
    else
    {
      return TEST_REG_ERROR;
    }
  }