GY-63_MS5611/libraries/HX711_MP/HX711_MP.cpp

//
//    FILE: HX711_MP.cpp
//  AUTHOR: Rob Tillaart
// VERSION: 0.1.1
// PURPOSE: Library for load cells for UNO
//     URL: https://github.com/RobTillaart/HX711_MP
//     URL: https://github.com/RobTillaart/HX711


#include "HX711_MP.h"


HX711_MP::HX711_MP(uint8_t size)
{
  _size = size;
  if (_size >= HX711_MP_MAX_SIZE)
  {
    _size = HX711_MP_MAX_SIZE;
  }
  else if (_size <  2)
  {
    _size = 2;   //  hard coded minimum!!
  }
  reset();
}


HX711_MP::~HX711_MP() {}


void HX711_MP::begin(uint8_t dataPin, uint8_t clockPin)
{
  _dataPin  = dataPin;
  _clockPin = clockPin;

  pinMode(_dataPin, INPUT);
  pinMode(_clockPin, OUTPUT);
  digitalWrite(_clockPin, LOW);

  reset();
}


void HX711_MP::reset()
{
  power_down();
  power_up();
  _gain     = HX711_CHANNEL_A_GAIN_128;
  _lastRead = 0;
  _mode     = HX711_AVERAGE_MODE;
}


bool HX711_MP::is_ready()
{
  return digitalRead(_dataPin) == LOW;
}


void HX711_MP::wait_ready(uint32_t ms)
{
  while (!is_ready())
  {
    delay(ms);
  }
}


bool HX711_MP::wait_ready_retry(uint8_t retries, uint32_t ms)
{
  while (retries--)
  {
    if (is_ready()) return true;
    delay(ms);
  }
  return false;
}


bool HX711_MP::wait_ready_timeout(uint32_t timeout, uint32_t ms)
{
  uint32_t start = millis();
  while (millis() - start < timeout)
  {
    if (is_ready()) return true;
    delay(ms);
  }
  return false;
}


///////////////////////////////////////////////////////////////
//
//  READ
//
//  From datasheet page 4
//  When output data is not ready for retrieval,
//       digital output pin DOUT is HIGH.
//  Serial clock input PD_SCK should be LOW.
//  When DOUT goes to LOW, it indicates data is ready for retrieval.
float HX711_MP::read()
{
  //  this BLOCKING wait takes most time...
  while (digitalRead(_dataPin) == HIGH) yield();

  union
  {
    long value = 0;
    uint8_t data[4];
  } v;

  //  blocking part ...
  noInterrupts();

  //  Pulse the clock pin 24 times to read the data.
  //  v.data[2] = shiftIn(_dataPin, _clockPin, MSBFIRST);
  //  v.data[1] = shiftIn(_dataPin, _clockPin, MSBFIRST);
  //  v.data[0] = shiftIn(_dataPin, _clockPin, MSBFIRST);
  v.data[2] = _shiftIn();
  v.data[1] = _shiftIn();
  v.data[0] = _shiftIn();

  //  TABLE 3 page 4 datasheet
  //
  //  CLOCK      CHANNEL      GAIN      m
  //  ------------------------------------
  //   25           A         128       1    //  default
  //   26           B          32       2
  //   27           A          64       3
  //
  //  only default 128 verified,
  //  selection goes through the set_gain(gain)
  //
  uint8_t m = 1;
  if      (_gain == HX711_CHANNEL_A_GAIN_128) m = 1;
  else if (_gain == HX711_CHANNEL_A_GAIN_64)  m = 3;
  else if (_gain == HX711_CHANNEL_B_GAIN_32)  m = 2;

  while (m > 0)
  {
    //  delayMicroSeconds(1) needed for fast processors?
    digitalWrite(_clockPin, HIGH);
    digitalWrite(_clockPin, LOW);
    m--;
  }

  interrupts();
  //  yield();

  //  SIGN extend
  if (v.data[2] & 0x80) v.data[3] = 0xFF;

  _lastRead = millis();
  return 1.0 * v.value;
}


float HX711_MP::read_average(uint8_t times)
{
  if (times < 1) times = 1;
  float sum = 0;
  for (uint8_t i = 0; i < times; i++)
  {
    sum += read();
    yield();
  }
  return sum / times;
}


float HX711_MP::read_median(uint8_t times)
{
  if (times > 15) times = 15;
  if (times < 3)  times = 3;
  float samples[15];
  for (uint8_t i = 0; i < times; i++)
  {
    samples[i] = read();
    yield();
  }
  _insertSort(samples, times);
  if (times & 0x01) return samples[times/2];
  return (samples[times/2] + samples[times/2 + 1]) / 2;
}


float HX711_MP::read_medavg(uint8_t times)
{
  if (times > 15) times = 15;
  if (times < 3)  times = 3;
  float samples[15];
  for (uint8_t i = 0; i < times; i++)
  {
    samples[i] = read();
    yield();
  }
  _insertSort(samples, times);
  float sum = 0;
  // iterate over 1/4 to 3/4 of the array
  uint8_t count = 0;
  uint8_t first = (times + 2) / 4;
  uint8_t last  = times - first - 1;
  for (uint8_t i = first; i <= last; i++)  //  !! include last one too
  {
    sum += samples[i];
    count++;
  }
  return sum / count;
}


float HX711_MP::read_runavg(uint8_t times, float alpha)
{
  if (times < 1)  times = 1;
  if (alpha < 0)  alpha = 0;
  if (alpha > 1)  alpha = 1;
  float val = read();
  for (uint8_t i = 1; i < times; i++)
  {
    val += alpha * (read() - val);
    yield();
  }
  return val;
}


float HX711_MP::get_value(uint8_t times)
{
  float raw;
  switch(_mode)
  {
    case HX711_RAW_MODE:
      raw = read();
      break;
    case HX711_RUNAVG_MODE:
      raw = read_runavg(times);
      break;
    case HX711_MEDAVG_MODE:
      raw = read_medavg(times);
      break;
    case HX711_MEDIAN_MODE:
      raw = read_median(times);
      break;
    case HX711_AVERAGE_MODE:
    default:
      raw = read_average(times);
      break;
  }
  return raw;
}


float HX711_MP::get_units(uint8_t times)
{
  return _multiMap(get_value(times));
}


///////////////////////////////////////////////////////////////
//
//  GAIN
//
//  note: if parameter gain == 0xFF40 some compilers
//  will map that to 0x40 == HX711_CHANNEL_A_GAIN_64;
//  solution: use uint32_t or larger parameters everywhere.
//  note that changing gain/channel may take up to 400 ms (page 3)
bool HX711_MP::set_gain(uint8_t gain, bool forced)
{
  if ( (not forced) && (_gain == gain)) return true;
  switch(gain)
  {
    case HX711_CHANNEL_B_GAIN_32:
    case HX711_CHANNEL_A_GAIN_64:
    case HX711_CHANNEL_A_GAIN_128:
      _gain = gain;
      read();     //  next user read() is from right channel / gain
      return true;
  }
  return false;   //  unchanged, but incorrect value.
}


uint8_t HX711_MP::get_gain()
{
  return _gain;
}


///////////////////////////////////////////////////////////////
//
//  CALIBRATION
//
bool HX711_MP::setCalibrate(uint8_t index, float raw, float weight)
{
  if (index >= _size) return false;
  _in[index]  = raw;
  _out[index] = weight;
  return true;
}


uint8_t HX711_MP::getCalibrateSize()
{
  return _size;
}


float HX711_MP::getCalibrateRaw(uint8_t index)
{
  if (index >= _size) return 0;  //  NaN
  return _in[index];
}


float HX711_MP::adjustCalibrateRaw(uint8_t index, float amount)
{
  if (index >= _size) return 0;  //  NaN
  _in[index] += amount;
  return _in[index];
}


float HX711_MP::getCalibrateWeight(uint8_t index)
{
  if (index >= _size) return 0;  //  NaN
  return _out[index];
}


///////////////////////////////////////////////////////////////
//
//  POWER MANAGEMENT
//
void HX711_MP::power_down()
{
  // at least 60 us HIGH
  digitalWrite(_clockPin, HIGH);
  delayMicroseconds(64);
}


void HX711_MP::power_up()
{
  digitalWrite(_clockPin, LOW);
}


///////////////////////////////////////////////////////////////
//
//  PRIVATE
//
void HX711_MP::_insertSort(float * array, uint8_t size)
{
  uint8_t t, z;
  float temp;
  for (t = 1; t < size; t++)
  {
    z = t;
    temp = array[z];
    while( (z > 0) && (temp < array[z - 1] ))
    {
      array[z] = array[z - 1];
      z--;
    }
    array[z] = temp;
    yield();
  }
}


//  MSB_FIRST optimized shiftIn
//  see datasheet page 5 for timing
uint8_t HX711_MP::_shiftIn()
{
  // local variables are faster.
  uint8_t clk   = _clockPin;
  uint8_t data  = _dataPin;
  uint8_t value = 0;
  uint8_t mask  = 0x80;
  while (mask > 0)
  {
    digitalWrite(clk, HIGH);
    delayMicroseconds(1);   //  T2  >= 0.2 us
    if (digitalRead(data) == HIGH)
    {
      value |= mask;
    }
    digitalWrite(clk, LOW);
    delayMicroseconds(1);   //  keep duty cycle ~50%
    mask >>= 1;
  }
  return value;
}


float HX711_MP::_multiMap(float val)
{
    //  take care the value is within range
    //  val = constrain(val, _in[0], _in[_size-1]);
    if (val <= _in[0])       return _out[0];
    if (val >= _in[_size-1]) return _out[_size-1];

    //  search right interval
    uint8_t pos = 1;  //  _in[0] already tested
    while(val > _in[pos]) pos++;

    //  this will handle all exact "points" in the _in array
    if (val == _in[pos]) return _out[pos];

    //  interpolate in the right segment for the rest
    return (val - _in[pos-1]) * (_out[pos] - _out[pos-1]) / (_in[pos] - _in[pos-1]) + _out[pos-1];
}


//  -- END OF FILE --
0.1.0 HX711_MP 2023-03-11 05:28:34 -05:00			`//`
			`// FILE: HX711_MP.cpp`
			`// AUTHOR: Rob Tillaart`
0.1.1 HX711_MP 2023-11-05 04:10:09 -05:00			`// VERSION: 0.1.1`
0.1.0 HX711_MP 2023-03-11 05:28:34 -05:00			`// PURPOSE: Library for load cells for UNO`
			`// URL: https://github.com/RobTillaart/HX711_MP`
			`// URL: https://github.com/RobTillaart/HX711`


			`#include "HX711_MP.h"`


			`HX711_MP::HX711_MP(uint8_t size)`
			`{`
			`_size = size;`
			`if (_size >= HX711_MP_MAX_SIZE)`
			`{`
			`_size = HX711_MP_MAX_SIZE;`
			`}`
0.1.1 HX711_MP 2023-11-05 04:10:09 -05:00			`else if (_size < 2)`
0.1.0 HX711_MP 2023-03-11 05:28:34 -05:00			`{`
			`_size = 2; // hard coded minimum!!`
			`}`
			`reset();`
			`}`


			`HX711_MP::~HX711_MP() {}`


			`void HX711_MP::begin(uint8_t dataPin, uint8_t clockPin)`
			`{`
			`_dataPin = dataPin;`
			`_clockPin = clockPin;`

			`pinMode(_dataPin, INPUT);`
			`pinMode(_clockPin, OUTPUT);`
			`digitalWrite(_clockPin, LOW);`

			`reset();`
			`}`


			`void HX711_MP::reset()`
			`{`
			`power_down();`
			`power_up();`
			`_gain = HX711_CHANNEL_A_GAIN_128;`
			`_lastRead = 0;`
			`_mode = HX711_AVERAGE_MODE;`
			`}`


			`bool HX711_MP::is_ready()`
			`{`
			`return digitalRead(_dataPin) == LOW;`
			`}`


			`void HX711_MP::wait_ready(uint32_t ms)`
			`{`
			`while (!is_ready())`
			`{`
			`delay(ms);`
			`}`
			`}`


			`bool HX711_MP::wait_ready_retry(uint8_t retries, uint32_t ms)`
			`{`
			`while (retries--)`
			`{`
			`if (is_ready()) return true;`
			`delay(ms);`
			`}`
			`return false;`
			`}`


			`bool HX711_MP::wait_ready_timeout(uint32_t timeout, uint32_t ms)`
			`{`
			`uint32_t start = millis();`
			`while (millis() - start < timeout)`
			`{`
			`if (is_ready()) return true;`
			`delay(ms);`
			`}`
			`return false;`
			`}`


			`///////////////////////////////////////////////////////////////`
			`//`
			`// READ`
			`//`
			`// From datasheet page 4`
			`// When output data is not ready for retrieval,`
			`// digital output pin DOUT is HIGH.`
			`// Serial clock input PD_SCK should be LOW.`
			`// When DOUT goes to LOW, it indicates data is ready for retrieval.`
			`float HX711_MP::read()`
			`{`
			`// this BLOCKING wait takes most time...`
			`while (digitalRead(_dataPin) == HIGH) yield();`

			`union`
			`{`
			`long value = 0;`
			`uint8_t data[4];`
			`} v;`

			`// blocking part ...`
			`noInterrupts();`

			`// Pulse the clock pin 24 times to read the data.`
			`// v.data[2] = shiftIn(_dataPin, _clockPin, MSBFIRST);`
			`// v.data[1] = shiftIn(_dataPin, _clockPin, MSBFIRST);`
			`// v.data[0] = shiftIn(_dataPin, _clockPin, MSBFIRST);`
			`v.data[2] = _shiftIn();`
			`v.data[1] = _shiftIn();`
			`v.data[0] = _shiftIn();`

			`// TABLE 3 page 4 datasheet`
			`//`
			`// CLOCK CHANNEL GAIN m`
			`// ------------------------------------`
			`// 25 A 128 1 // default`
			`// 26 B 32 2`
			`// 27 A 64 3`
			`//`
			`// only default 128 verified,`
			`// selection goes through the set_gain(gain)`
			`//`
			`uint8_t m = 1;`
			`if (_gain == HX711_CHANNEL_A_GAIN_128) m = 1;`
			`else if (_gain == HX711_CHANNEL_A_GAIN_64) m = 3;`
			`else if (_gain == HX711_CHANNEL_B_GAIN_32) m = 2;`

			`while (m > 0)`
			`{`
			`// delayMicroSeconds(1) needed for fast processors?`
			`digitalWrite(_clockPin, HIGH);`
			`digitalWrite(_clockPin, LOW);`
			`m--;`
			`}`

			`interrupts();`
			`// yield();`

			`// SIGN extend`
			`if (v.data[2] & 0x80) v.data[3] = 0xFF;`

			`_lastRead = millis();`
			`return 1.0 * v.value;`
			`}`


			`float HX711_MP::read_average(uint8_t times)`
			`{`
			`if (times < 1) times = 1;`
			`float sum = 0;`
			`for (uint8_t i = 0; i < times; i++)`
			`{`
			`sum += read();`
			`yield();`
			`}`
			`return sum / times;`
			`}`


			`float HX711_MP::read_median(uint8_t times)`
			`{`
			`if (times > 15) times = 15;`
			`if (times < 3) times = 3;`
			`float samples[15];`
			`for (uint8_t i = 0; i < times; i++)`
			`{`
			`samples[i] = read();`
			`yield();`
			`}`
			`_insertSort(samples, times);`
			`if (times & 0x01) return samples[times/2];`
			`return (samples[times/2] + samples[times/2 + 1]) / 2;`
			`}`


			`float HX711_MP::read_medavg(uint8_t times)`
			`{`
			`if (times > 15) times = 15;`
			`if (times < 3) times = 3;`
			`float samples[15];`
			`for (uint8_t i = 0; i < times; i++)`
			`{`
			`samples[i] = read();`
			`yield();`
			`}`
			`_insertSort(samples, times);`
			`float sum = 0;`
			`// iterate over 1/4 to 3/4 of the array`
			`uint8_t count = 0;`
			`uint8_t first = (times + 2) / 4;`
			`uint8_t last = times - first - 1;`
			`for (uint8_t i = first; i <= last; i++) // !! include last one too`
			`{`
			`sum += samples[i];`
			`count++;`
			`}`
			`return sum / count;`
			`}`


			`float HX711_MP::read_runavg(uint8_t times, float alpha)`
			`{`
			`if (times < 1) times = 1;`
			`if (alpha < 0) alpha = 0;`
			`if (alpha > 1) alpha = 1;`
			`float val = read();`
			`for (uint8_t i = 1; i < times; i++)`
			`{`
			`val += alpha * (read() - val);`
			`yield();`
			`}`
			`return val;`
			`}`


			`float HX711_MP::get_value(uint8_t times)`
			`{`
			`float raw;`
			`switch(_mode)`
			`{`
			`case HX711_RAW_MODE:`
			`raw = read();`
			`break;`
			`case HX711_RUNAVG_MODE:`
			`raw = read_runavg(times);`
			`break;`
			`case HX711_MEDAVG_MODE:`
			`raw = read_medavg(times);`
			`break;`
			`case HX711_MEDIAN_MODE:`
			`raw = read_median(times);`
			`break;`
			`case HX711_AVERAGE_MODE:`
			`default:`
			`raw = read_average(times);`
			`break;`
			`}`
			`return raw;`
			`}`


			`float HX711_MP::get_units(uint8_t times)`
			`{`
			`return _multiMap(get_value(times));`
			`}`


			`///////////////////////////////////////////////////////////////`
			`//`
			`// GAIN`
			`//`
			`// note: if parameter gain == 0xFF40 some compilers`
			`// will map that to 0x40 == HX711_CHANNEL_A_GAIN_64;`
			`// solution: use uint32_t or larger parameters everywhere.`
			`// note that changing gain/channel may take up to 400 ms (page 3)`
			`bool HX711_MP::set_gain(uint8_t gain, bool forced)`
			`{`
			`if ( (not forced) && (_gain == gain)) return true;`
			`switch(gain)`
			`{`
			`case HX711_CHANNEL_B_GAIN_32:`
			`case HX711_CHANNEL_A_GAIN_64:`
			`case HX711_CHANNEL_A_GAIN_128:`
			`_gain = gain;`
			`read(); // next user read() is from right channel / gain`
			`return true;`
			`}`
			`return false; // unchanged, but incorrect value.`
			`}`


			`uint8_t HX711_MP::get_gain()`
			`{`
			`return _gain;`
			`}`


			`///////////////////////////////////////////////////////////////`
			`//`
			`// CALIBRATION`
			`//`
			`bool HX711_MP::setCalibrate(uint8_t index, float raw, float weight)`
			`{`
			`if (index >= _size) return false;`
			`_in[index] = raw;`
			`_out[index] = weight;`
			`return true;`
			`}`


			`uint8_t HX711_MP::getCalibrateSize()`
			`{`
			`return _size;`
			`}`


			`float HX711_MP::getCalibrateRaw(uint8_t index)`
			`{`
			`if (index >= _size) return 0; // NaN`
			`return _in[index];`
			`}`


			`float HX711_MP::adjustCalibrateRaw(uint8_t index, float amount)`
			`{`
			`if (index >= _size) return 0; // NaN`
			`_in[index] += amount;`
			`return _in[index];`
			`}`


			`float HX711_MP::getCalibrateWeight(uint8_t index)`
			`{`
			`if (index >= _size) return 0; // NaN`
			`return _out[index];`
			`}`


			`///////////////////////////////////////////////////////////////`
			`//`
			`// POWER MANAGEMENT`
			`//`
			`void HX711_MP::power_down()`
			`{`
			`// at least 60 us HIGH`
			`digitalWrite(_clockPin, HIGH);`
			`delayMicroseconds(64);`
			`}`


			`void HX711_MP::power_up()`
			`{`
			`digitalWrite(_clockPin, LOW);`
			`}`


			`///////////////////////////////////////////////////////////////`
			`//`
			`// PRIVATE`
			`//`
			`void HX711_MP::_insertSort(float * array, uint8_t size)`
			`{`
			`uint8_t t, z;`
			`float temp;`
			`for (t = 1; t < size; t++)`
			`{`
			`z = t;`
			`temp = array[z];`
			`while( (z > 0) && (temp < array[z - 1] ))`
			`{`
			`array[z] = array[z - 1];`
			`z--;`
			`}`
			`array[z] = temp;`
			`yield();`
			`}`
			`}`


			`// MSB_FIRST optimized shiftIn`
			`// see datasheet page 5 for timing`
			`uint8_t HX711_MP::_shiftIn()`
			`{`
			`// local variables are faster.`
			`uint8_t clk = _clockPin;`
			`uint8_t data = _dataPin;`
			`uint8_t value = 0;`
			`uint8_t mask = 0x80;`
			`while (mask > 0)`
			`{`
			`digitalWrite(clk, HIGH);`
			`delayMicroseconds(1); // T2 >= 0.2 us`
			`if (digitalRead(data) == HIGH)`
			`{`
			`value \|= mask;`
			`}`
			`digitalWrite(clk, LOW);`
			`delayMicroseconds(1); // keep duty cycle ~50%`
			`mask >>= 1;`
			`}`
			`return value;`
			`}`


			`float HX711_MP::_multiMap(float val)`
			`{`
			`// take care the value is within range`
			`// val = constrain(val, _in[0], _in[_size-1]);`
			`if (val <= _in[0]) return _out[0];`
			`if (val >= _in[_size-1]) return _out[_size-1];`

			`// search right interval`
			`uint8_t pos = 1; // _in[0] already tested`
			`while(val > _in[pos]) pos++;`

			`// this will handle all exact "points" in the _in array`
			`if (val == _in[pos]) return _out[pos];`

			`// interpolate in the right segment for the rest`
			`return (val - _in[pos-1]) * (_out[pos] - _out[pos-1]) / (_in[pos] - _in[pos-1]) + _out[pos-1];`
			`}`



			`// -- END OF FILE --`