upm/src/ds18b20/ds18b20.cxx

/*
 * Author: Jon Trulson <jtrulson@ics.com>
 * Copyright (c) 2016 Intel Corporation.
 *
 * Permission is hereby granted, free of charge, to any person obtaining
 * a copy of this software and associated documentation files (the
 * "Software"), to deal in the Software without restriction, including
 * without limitation the rights to use, copy, modify, merge, publish,
 * distribute, sublicense, and/or sell copies of the Software, and to
 * permit persons to whom the Software is furnished to do so, subject to
 * the following conditions:
 *
 * The above copyright notice and this permission notice shall be
 * included in all copies or substantial portions of the Software.
 *
 * THE SOFTWARE IS PROVIDED "AS IS", WITHOUT WARRANTY OF ANY KIND,
 * EXPRESS OR IMPLIED, INCLUDING BUT NOT LIMITED TO THE WARRANTIES OF
 * MERCHANTABILITY, FITNESS FOR A PARTICULAR PURPOSE AND
 * NONINFRINGEMENT. IN NO EVENT SHALL THE AUTHORS OR COPYRIGHT HOLDERS BE
 * LIABLE FOR ANY CLAIM, DAMAGES OR OTHER LIABILITY, WHETHER IN AN ACTION
 * OF CONTRACT, TORT OR OTHERWISE, ARISING FROM, OUT OF OR IN CONNECTION
 * WITH THE SOFTWARE OR THE USE OR OTHER DEALINGS IN THE SOFTWARE.
 */

#include <iostream>
#include <time.h>
#include <stdexcept>

#include "ds18b20.h"

using namespace upm;
using namespace std;

// conversion from celcius to fahrenheit
static float c2f(float c)
{
  return (c * (9.0 / 5.0) + 32.0);
}

DS18B20::DS18B20(int uart) :
  m_uart(uart)
{
  m_devicesFound = 0;

  // check basic access to the 1-wire bus (presence detect)
  mraa::Result rv;

  if ((rv = m_uart.reset()) != mraa::SUCCESS)
    {
      throw std::runtime_error(std::string(__FUNCTION__) +
                               ": reset() failed, no devices on bus?");
    }
}

DS18B20::~DS18B20()
{
}

void DS18B20::init()
{
  // iterate through the bus and build up a list of detected DS18B20
  // devices (only)

  // empty the map, in case this method has already been run once
  // before
  m_devicesFound = 0;
  m_deviceMap.clear();

  sensor_info_t sinfo;

  // defaults
  sinfo.temperature = 0.0;
  sinfo.resolution = RESOLUTION_12BITS;

  // start the search from scratch
  string id = m_uart.search(true);
  if (id.empty())
    {
      throw std::runtime_error(std::string(__FUNCTION__) +
                               ": no devices detected on bus");
    }

  while (!id.empty())
    {
      // The first byte (id[0]]) is the device type (family) code.  We
      // are only interested in the family code for these devices.

      if ((uint8_t)id[0] == DS18B20_FAMILY_CODE)
        {
          // we have a winner, add it to our map and continue searching

          sinfo.id = id;
          m_deviceMap[m_devicesFound] = sinfo;

          m_devicesFound++;
        }

      // continue search
      id = m_uart.search(false);
    }

  if (!m_devicesFound)
    {
      throw std::runtime_error(std::string(__FUNCTION__) +
                               ": no DS18B20 devices found on bus");
    }

  // iterate through the found devices and query their resolutions
  for (int i=0; i<m_devicesFound; i++)
    {
      // read only the first 5 bytes of the scratchpad
      static const int numScratch = 5;
      uint8_t scratch[numScratch];

      m_uart.command(CMD_READ_SCRATCHPAD, m_deviceMap[i].id);
      for (int j=0; j<numScratch; j++)
        scratch[j] = m_uart.readByte();

      // config byte, shift the resolution to bit 0
      scratch[4] >>= _CFG_RESOLUTION_SHIFT;

      switch (scratch[4] & _CFG_RESOLUTION_MASK)
        {
        case 0: m_deviceMap[i].resolution = RESOLUTION_9BITS; break;
        case 1: m_deviceMap[i].resolution = RESOLUTION_10BITS; break;
        case 2: m_deviceMap[i].resolution = RESOLUTION_11BITS; break;
        case 3: m_deviceMap[i].resolution = RESOLUTION_12BITS; break;
        }

      // reset the bus
      m_uart.reset();
    }
}

void DS18B20::update(int index)
{
  if (index >= m_devicesFound)
    {
      throw std::out_of_range(std::string(__FUNCTION__) +
                              ": device index out of range");
    }

  // should we update all of them?
  bool doAll = (index < 0) ? true : false;

  if (doAll)
    {
      // if we want to update all of them, we will first send the
      // convert command to all of them, then wait.  This will be
      // faster, timey-wimey wise, then converting, sleeping, and
      // reading each individual sensor.

      for (int i=0; i<m_devicesFound; i++)
        m_uart.command(CMD_CONVERT, m_deviceMap[i].id);
    }
  else
    m_uart.command(CMD_CONVERT, m_deviceMap[index].id);

  // wait for conversion(s) to finish
  usleep(750000); // 750ms max

  if (doAll)
    {
      for (int i=0; i<m_devicesFound; i++)
        m_deviceMap[i].temperature = readSingleTemp(i);
    }
  else
    m_deviceMap[index].temperature = readSingleTemp(index);
}

// utility function to read temp data from a single sensor
float DS18B20::readSingleTemp(int index)
{
  if (index < 0 || index >= m_devicesFound)
    {
      throw std::out_of_range(std::string(__FUNCTION__) +
                              ": device index out of range");
    }

  static const int numScratch = 9;
  uint8_t scratch[numScratch];

  // read the 9-byte scratchpad
  m_uart.command(CMD_READ_SCRATCHPAD, m_deviceMap[index].id);
  for (int i=0; i<numScratch; i++)
    scratch[i] = m_uart.readByte();

  // validate cksum -- if we get an error, we will warn and simply
  // return the current (previously read) temperature
  uint8_t crc = m_uart.crc8(scratch, 8);

  if (crc != scratch[8])
    {
      cerr << __FUNCTION__ << ": crc check failed for device "
           << index << ", returning previously measured temperature" << endl;
      return m_deviceMap[index].temperature;
    }

  // check the sign bit(s)
  bool negative = (scratch[1] & 0x80) ? true : false;

  // shift everything into position
  int16_t temp = (scratch[1] << 8) | scratch[0];

  // grab the fractional
  uint8_t frac = temp & 0x0f;

  // depending on the resolution, some frac bits should be ignored, so
  // we mask them off.  For 12bits, all bits are valid so we leve them
  // alone.

  switch (m_deviceMap[index].resolution)
    {
    case RESOLUTION_9BITS: frac &= 0x08; break;
    case RESOLUTION_10BITS: frac &= 0x0c; break;
    case RESOLUTION_11BITS: frac &= 0x0e; break;
    }

  // remove the fractional with extreme prejudice
  temp >>= 4;

  // compensate for sign
  if (negative)
    temp -= 65536; // 2^^16

  // convert
  return ( float(temp) + (float(frac) * 0.0625) );
}

float DS18B20::getTemperature(int index, bool fahrenheit)
{
  if (index < 0 || index >= m_devicesFound)
    {
      throw std::out_of_range(std::string(__FUNCTION__) +
                              ": device index out of range");
    }

  if (fahrenheit)
    return c2f(m_deviceMap[index].temperature);
  else
    return m_deviceMap[index].temperature;
}

void DS18B20::setResolution(int index, RESOLUTIONS_T res)
{
  if (index < 0 || index >= m_devicesFound)
    {
      throw std::out_of_range(std::string(__FUNCTION__) +
                              ": device index out of range");
    }

  static const int numScratch = 9;
  uint8_t scratch[numScratch];

  // read the 9-byte scratchpad
  m_uart.command(CMD_READ_SCRATCHPAD, m_deviceMap[index].id);
  for (int i=0; i<numScratch; i++)
    scratch[i] = m_uart.readByte();

  // resolution is stored in byte 4
  scratch[4] = ((scratch[4] & ~(_CFG_RESOLUTION_MASK << _CFG_RESOLUTION_SHIFT))
                | (res << _CFG_RESOLUTION_SHIFT));

  // now, write back, we only write 3 bytes (2-4), no cksum.
  m_uart.command(CMD_WRITE_SCRATCHPAD, m_deviceMap[index].id);
  for (int i=0; i<3; i++)
    m_uart.writeByte(scratch[i+2]);
}

void DS18B20::copyScratchPad(int index)
{
  if (index < 0 || index >= m_devicesFound)
    {
      throw std::out_of_range(std::string(__FUNCTION__) +
                              ": device index out of range");
    }

  // issue the command
  m_uart.command(CMD_COPY_SCRATCHPAD, m_deviceMap[index].id);

  sleep(1); // to be safe...
}

void DS18B20::recallEEPROM(int index)
{
  if (index < 0 || index >= m_devicesFound)
    {
      throw std::out_of_range(std::string(__FUNCTION__) +
                              ": device index out of range");
    }

  // issue the command
  m_uart.command(CMD_RECALL_EEPROM, m_deviceMap[index].id);

  // issue read timeslots until a '1' is read back, indicating completion
  while (!m_uart.writeBit(1))
    usleep(100);
}
ds18b20: Initial implementation This driver supports, and was tested with, a DS18B20 1-wire Temperature Sensor using external power. This device requires the use of a UART to provide access to a Dallas 1-wire bus, via a new facility supported by MRAA (once the relevant PR is accepted), using the UartOW access class. It is important to realize that the UART is only being used to access and control a Dallas 1-wire compliant bus, it is not actually a UART device. Multiple DS18B20 devices can be connected to this bus. This module will identify all such devices connected, and allow you to access them using an index starting at 0. Parasitic power is not currently supported due to the very tight 10us limit on switching a GPIO properly to supply power during certain operations. For this reason, you should use external power for your sensors. Setting the alarm values (Tl, Th) is also not supported, since this is only useful when doing a 1-wire device search looking for devices in an alarm state, a capability not yet supported in MRAA. In reality, this is trivial to handle yourself in your application. Signed-off-by: Jon Trulson <jtrulson@ics.com> Signed-off-by: Noel Eck <noel.eck@intel.com> 2016-01-26 16:45:05 -07:00			`/*`
			`* Author: Jon Trulson <jtrulson@ics.com>`
			`* Copyright (c) 2016 Intel Corporation.`
			`*`
			`* Permission is hereby granted, free of charge, to any person obtaining`
			`* a copy of this software and associated documentation files (the`
			`* "Software"), to deal in the Software without restriction, including`
			`* without limitation the rights to use, copy, modify, merge, publish,`
			`* distribute, sublicense, and/or sell copies of the Software, and to`
			`* permit persons to whom the Software is furnished to do so, subject to`
			`* the following conditions:`
			`*`
			`* The above copyright notice and this permission notice shall be`
			`* included in all copies or substantial portions of the Software.`
			`*`
			`* THE SOFTWARE IS PROVIDED "AS IS", WITHOUT WARRANTY OF ANY KIND,`
			`* EXPRESS OR IMPLIED, INCLUDING BUT NOT LIMITED TO THE WARRANTIES OF`
			`* MERCHANTABILITY, FITNESS FOR A PARTICULAR PURPOSE AND`
			`* NONINFRINGEMENT. IN NO EVENT SHALL THE AUTHORS OR COPYRIGHT HOLDERS BE`
			`* LIABLE FOR ANY CLAIM, DAMAGES OR OTHER LIABILITY, WHETHER IN AN ACTION`
			`* OF CONTRACT, TORT OR OTHERWISE, ARISING FROM, OUT OF OR IN CONNECTION`
			`* WITH THE SOFTWARE OR THE USE OR OTHER DEALINGS IN THE SOFTWARE.`
			`*/`

			`#include <iostream>`
			`#include <time.h>`
			`#include <stdexcept>`

			`#include "ds18b20.h"`

			`using namespace upm;`
			`using namespace std;`

			`// conversion from celcius to fahrenheit`
			`static float c2f(float c)`
			`{`
			`return (c * (9.0 / 5.0) + 32.0);`
			`}`

			`DS18B20::DS18B20(int uart) :`
			`m_uart(uart)`
			`{`
			`m_devicesFound = 0;`

			`// check basic access to the 1-wire bus (presence detect)`
			`mraa::Result rv;`

			`if ((rv = m_uart.reset()) != mraa::SUCCESS)`
			`{`
			`throw std::runtime_error(std::string(__FUNCTION__) +`
			`": reset() failed, no devices on bus?");`
			`}`
			`}`

			`DS18B20::~DS18B20()`
			`{`
			`}`

			`void DS18B20::init()`
			`{`
			`// iterate through the bus and build up a list of detected DS18B20`
			`// devices (only)`

			`// empty the map, in case this method has already been run once`
			`// before`
			`m_devicesFound = 0;`
			`m_deviceMap.clear();`

			`sensor_info_t sinfo;`

			`// defaults`
			`sinfo.temperature = 0.0;`
			`sinfo.resolution = RESOLUTION_12BITS;`

			`// start the search from scratch`
			`string id = m_uart.search(true);`
			`if (id.empty())`
			`{`
			`throw std::runtime_error(std::string(__FUNCTION__) +`
			`": no devices detected on bus");`
			`}`

			`while (!id.empty())`
			`{`
			`// The first byte (id[0]]) is the device type (family) code. We`
			`// are only interested in the family code for these devices.`

			`if ((uint8_t)id[0] == DS18B20_FAMILY_CODE)`
			`{`
			`// we have a winner, add it to our map and continue searching`

			`sinfo.id = id;`
			`m_deviceMap[m_devicesFound] = sinfo;`

			`m_devicesFound++;`
			`}`

			`// continue search`
			`id = m_uart.search(false);`
			`}`

			`if (!m_devicesFound)`
			`{`
			`throw std::runtime_error(std::string(__FUNCTION__) +`
			`": no DS18B20 devices found on bus");`
			`}`

			`// iterate through the found devices and query their resolutions`
			`for (int i=0; i<m_devicesFound; i++)`
			`{`
			`// read only the first 5 bytes of the scratchpad`
			`static const int numScratch = 5;`
			`uint8_t scratch[numScratch];`

			`m_uart.command(CMD_READ_SCRATCHPAD, m_deviceMap[i].id);`
			`for (int j=0; j<numScratch; j++)`
			`scratch[j] = m_uart.readByte();`

			`// config byte, shift the resolution to bit 0`
			`scratch[4] >>= _CFG_RESOLUTION_SHIFT;`

			`switch (scratch[4] & _CFG_RESOLUTION_MASK)`
			`{`
			`case 0: m_deviceMap[i].resolution = RESOLUTION_9BITS; break;`
			`case 1: m_deviceMap[i].resolution = RESOLUTION_10BITS; break;`
			`case 2: m_deviceMap[i].resolution = RESOLUTION_11BITS; break;`
			`case 3: m_deviceMap[i].resolution = RESOLUTION_12BITS; break;`
			`}`

			`// reset the bus`
			`m_uart.reset();`
			`}`
			`}`

			`void DS18B20::update(int index)`
			`{`
			`if (index >= m_devicesFound)`
			`{`
			`throw std::out_of_range(std::string(__FUNCTION__) +`
			`": device index out of range");`
			`}`

			`// should we update all of them?`
			`bool doAll = (index < 0) ? true : false;`

			`if (doAll)`
			`{`
			`// if we want to update all of them, we will first send the`
			`// convert command to all of them, then wait. This will be`
			`// faster, timey-wimey wise, then converting, sleeping, and`
			`// reading each individual sensor.`

			`for (int i=0; i<m_devicesFound; i++)`
			`m_uart.command(CMD_CONVERT, m_deviceMap[i].id);`
			`}`
			`else`
			`m_uart.command(CMD_CONVERT, m_deviceMap[index].id);`

			`// wait for conversion(s) to finish`
			`usleep(750000); // 750ms max`

			`if (doAll)`
			`{`
			`for (int i=0; i<m_devicesFound; i++)`
			`m_deviceMap[i].temperature = readSingleTemp(i);`
			`}`
			`else`
			`m_deviceMap[index].temperature = readSingleTemp(index);`
			`}`

			`// utility function to read temp data from a single sensor`
			`float DS18B20::readSingleTemp(int index)`
			`{`
			`if (index < 0 \|\| index >= m_devicesFound)`
			`{`
			`throw std::out_of_range(std::string(__FUNCTION__) +`
			`": device index out of range");`
			`}`

			`static const int numScratch = 9;`
			`uint8_t scratch[numScratch];`

			`// read the 9-byte scratchpad`
			`m_uart.command(CMD_READ_SCRATCHPAD, m_deviceMap[index].id);`
			`for (int i=0; i<numScratch; i++)`
			`scratch[i] = m_uart.readByte();`

			`// validate cksum -- if we get an error, we will warn and simply`
			`// return the current (previously read) temperature`
			`uint8_t crc = m_uart.crc8(scratch, 8);`

			`if (crc != scratch[8])`
			`{`
			`cerr << __FUNCTION__ << ": crc check failed for device "`
			`<< index << ", returning previously measured temperature" << endl;`
			`return m_deviceMap[index].temperature;`
			`}`

			`// check the sign bit(s)`
			`bool negative = (scratch[1] & 0x80) ? true : false;`

			`// shift everything into position`
			`int16_t temp = (scratch[1] << 8) \| scratch[0];`

			`// grab the fractional`
			`uint8_t frac = temp & 0x0f;`

			`// depending on the resolution, some frac bits should be ignored, so`
			`// we mask them off. For 12bits, all bits are valid so we leve them`
			`// alone.`

			`switch (m_deviceMap[index].resolution)`
			`{`
			`case RESOLUTION_9BITS: frac &= 0x08; break;`
			`case RESOLUTION_10BITS: frac &= 0x0c; break;`
			`case RESOLUTION_11BITS: frac &= 0x0e; break;`
			`}`

			`// remove the fractional with extreme prejudice`
			`temp >>= 4;`

			`// compensate for sign`
			`if (negative)`
			`temp -= 65536; // 2^^16`

			`// convert`
			`return ( float(temp) + (float(frac) * 0.0625) );`
			`}`

			`float DS18B20::getTemperature(int index, bool fahrenheit)`
			`{`
			`if (index < 0 \|\| index >= m_devicesFound)`
			`{`
			`throw std::out_of_range(std::string(__FUNCTION__) +`
			`": device index out of range");`
			`}`

			`if (fahrenheit)`
			`return c2f(m_deviceMap[index].temperature);`
			`else`
			`return m_deviceMap[index].temperature;`
			`}`

			`void DS18B20::setResolution(int index, RESOLUTIONS_T res)`
			`{`
			`if (index < 0 \|\| index >= m_devicesFound)`
			`{`
			`throw std::out_of_range(std::string(__FUNCTION__) +`
			`": device index out of range");`
			`}`

			`static const int numScratch = 9;`
			`uint8_t scratch[numScratch];`

			`// read the 9-byte scratchpad`
			`m_uart.command(CMD_READ_SCRATCHPAD, m_deviceMap[index].id);`
			`for (int i=0; i<numScratch; i++)`
			`scratch[i] = m_uart.readByte();`

			`// resolution is stored in byte 4`
			`scratch[4] = ((scratch[4] & ~(_CFG_RESOLUTION_MASK << _CFG_RESOLUTION_SHIFT))`
			`\| (res << _CFG_RESOLUTION_SHIFT));`

			`// now, write back, we only write 3 bytes (2-4), no cksum.`
			`m_uart.command(CMD_WRITE_SCRATCHPAD, m_deviceMap[index].id);`
			`for (int i=0; i<3; i++)`
			`m_uart.writeByte(scratch[i+2]);`
			`}`

			`void DS18B20::copyScratchPad(int index)`
			`{`
			`if (index < 0 \|\| index >= m_devicesFound)`
			`{`
			`throw std::out_of_range(std::string(__FUNCTION__) +`
			`": device index out of range");`
			`}`

			`// issue the command`
			`m_uart.command(CMD_COPY_SCRATCHPAD, m_deviceMap[index].id);`

			`sleep(1); // to be safe...`
			`}`

			`void DS18B20::recallEEPROM(int index)`
			`{`
			`if (index < 0 \|\| index >= m_devicesFound)`
			`{`
			`throw std::out_of_range(std::string(__FUNCTION__) +`
			`": device index out of range");`
			`}`

			`// issue the command`
			`m_uart.command(CMD_RECALL_EEPROM, m_deviceMap[index].id);`

			`// issue read timeslots until a '1' is read back, indicating completion`
			`while (!m_uart.writeBit(1))`
			`usleep(100);`
			`}`