AMiRo-OS

/*

AMiRo-OS is an operating system designed for the Autonomous Mini Robot (AMiRo) platform.

Copyright (C) 2016..2019  Thomas Schöpping et al.

This program is free software: you can redistribute it and/or modify

it under the terms of the GNU General Public License as published by

the Free Software Foundation, either version 3 of the License, or

(at your option) any later version.

This program is distributed in the hope that it will be useful,

but WITHOUT ANY WARRANTY; without even the implied warranty of

MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE.  See the

GNU General Public License for more details.

You should have received a copy of the GNU General Public License

along with this program.  If not, see <http://www.gnu.org/licenses/>.

*/

#include <ut_alld_ina219.h>

#if ((AMIROOS_CFG_TESTS_ENABLE == true) && defined(AMIROLLD_CFG_USE_INA219)) || defined(__DOXYGEN__)

#include <math.h>

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/* LOCAL DEFINITIONS                                                          */

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/* EXPORTED VARIABLES                                                         */

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/* LOCAL TYPES                                                                */

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/* LOCAL VARIABLES                                                            */

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/******************************************************************************/

/* LOCAL FUNCTIONS                                                            */

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/* EXPORTED FUNCTIONS                                                         */

/******************************************************************************/

aos_utresult_t utAlldIna219Func(BaseSequentialStream* stream, aos_unittest_t* ut)

{

  aosDbgCheck(ut->data != NULL && ((ut_ina219data_t*)(ut->data))->inad != NULL);

  // local variables

  aos_utresult_t result = {0, 0};

  uint32_t status;

  uint16_t data[6];

  uint16_t write_data = 0x1011;

  uint16_t new_data[6];

  uint16_t reset_data;

  uint16_t test_calib = 0;

  int16_t usensor_data = 0;

  uint16_t busready = 0;

  uint32_t power = 0;

  int32_t shunt;

  uint32_t bus;

  chprintf(stream, "read registers...\n");

  status = ina219_lld_read_register(((ut_ina219data_t*)ut->data)->inad, INA219_LLD_REGISTER_CONFIGURATION, data, 6, ((ut_ina219data_t*)ut->data)->timeout);

  if (status == APAL_STATUS_SUCCESS) {

    aosUtPassed(stream, &result);

  } else {

    aosUtFailed(stream, &result);

  }

  chprintf(stream, "write registers...\n");

  status = ina219_lld_write_register(((ut_ina219data_t*)ut->data)->inad, INA219_LLD_REGISTER_CONFIGURATION, &write_data, 1, ((ut_ina219data_t*)ut->data)->timeout);

  status |= ina219_lld_read_register(((ut_ina219data_t*)ut->data)->inad, INA219_LLD_REGISTER_CONFIGURATION, new_data, 6, ((ut_ina219data_t*)ut->data)->timeout);

  if (status == APAL_STATUS_SUCCESS && new_data[0] == write_data) {

    uint8_t errors = 0;

    for (uint8_t dataIdx = 1; dataIdx < 6; dataIdx++) {

      if (new_data[dataIdx] != data[dataIdx]) {

        ++errors;

      }

    }

    if (errors == 0) {

      aosUtPassed(stream, &result);

    } else {

      aosUtFailed(stream, &result);

    }

  } else {

    aosUtFailed(stream, &result);

  }

  chprintf(stream, "reset...\n");

  status = ina219_lld_reset(((ut_ina219data_t*)ut->data)->inad, ((ut_ina219data_t*)ut->data)->timeout);

  status |= ina219_lld_read_register(((ut_ina219data_t*)ut->data)->inad, INA219_LLD_REGISTER_CONFIGURATION, &reset_data, 1, ((ut_ina219data_t*)ut->data)->timeout);

  if (status == APAL_STATUS_SUCCESS && reset_data == 0x399F) {

    aosUtPassed(stream, &result);

  } else {

    chprintf(stream, "\tfailed\n");

    ++result.failed;

  }

  chprintf(stream, "read config...\n");

  ina219_lld_cfg_t ina_config;

  status = ina219_lld_read_config(((ut_ina219data_t*)ut->data)->inad, &ina_config, ((ut_ina219data_t*)ut->data)->timeout);

  if (status == APAL_STATUS_SUCCESS) {

    aosUtPassed(stream, &result);

  } else {

    aosUtFailed(stream, &result);

  }

  chprintf(stream, "write config...\n");

  ina_config.data = 0x7FFu;

  status = ina219_lld_write_config(((ut_ina219data_t*)ut->data)->inad, ina_config, ((ut_ina219data_t*)ut->data)->timeout);

  if (status == APAL_STATUS_SUCCESS) {

    aosUtPassed(stream, &result);

  } else {

    aosUtFailed(stream, &result);

  }

  chprintf(stream, "calibrate...\n");

  ina219_lld_calib_input_t calib_in;

  calib_in.shunt_resistance_0 = 0.1;

  calib_in.max_expected_current_A = 0.075;

  calib_in.current_lsb_uA = 10;

  calib_in.cfg_reg = ina_config;

  ina219_lld_calib_output_t calib_out;

  status = ina219_lld_calibration(((ut_ina219data_t*)ut->data)->inad, &calib_in, &calib_out);

  status |= ina219_lld_write_calibration(((ut_ina219data_t*)ut->data)->inad, calib_out.calibration & 0xFFFEu, ((ut_ina219data_t*)ut->data)->timeout);

  status |= ina219_lld_write_calibration(((ut_ina219data_t*)ut->data)->inad, 0xA000, ((ut_ina219data_t*)ut->data)->timeout);

  ina219_lld_cfg_t test_config;

  ((ut_ina219data_t*)ut->data)->inad->current_lsb_uA = 0xA;

  status |= ina219_lld_read_config(((ut_ina219data_t*)ut->data)->inad, &test_config, ((ut_ina219data_t*)ut->data)->timeout);

  status |= ina219_lld_read_calibration(((ut_ina219data_t*)ut->data)->inad, &test_calib, ((ut_ina219data_t*)ut->data)->timeout);

  while (!busready || power == 0) {

    aosThdMSleep(20);

    status |= ina219_lld_bus_conversion_ready(((ut_ina219data_t*)ut->data)->inad, &busready, ((ut_ina219data_t*)ut->data)->timeout);

    status |= ina219_lld_read_power(((ut_ina219data_t*)ut->data)->inad, &power, ((ut_ina219data_t*)ut->data)->timeout);

  }

  if (status == APAL_STATUS_SUCCESS) {

    aosUtPassed(stream, &result);

  } else {

    aosUtFailed(stream, &result);

  }

  chprintf(stream, "read shunt voltage...\n");

  status = ina219_lld_read_shunt_voltage(((ut_ina219data_t*)ut->data)->inad, &shunt, ((ut_ina219data_t*)ut->data)->timeout);

  chprintf(stream, "\t\tshunt voltage: %fV\n", (float)shunt/1000000.f);

  if (status == APAL_STATUS_SUCCESS) {

    aosUtPassed(stream, &result);

  } else {

    aosUtFailed(stream, &result);

  }

  chprintf(stream, "read bus voltage (%u%% tolerance)...\n", (uint8_t)(((ut_ina219data_t*)ut->data)->tolerance * 100.f + 0.5f));

  status = ina219_lld_read_bus_voltage(((ut_ina219data_t*)ut->data)->inad, &bus, ((ut_ina219data_t*)ut->data)->timeout);

  chprintf(stream, "\t\tbus voltage: %fV\n", (float)bus/1000000.f);

  if ((status == APAL_STATUS_SUCCESS) && (fabs(((float)bus/1000000.f) - ((ut_ina219data_t*)ut->data)->v_expected) < ((ut_ina219data_t*)ut->data)->v_expected * ((ut_ina219data_t*)ut->data)->tolerance)) {

    aosUtPassed(stream, &result);

  } else {

    aosUtFailed(stream, &result);

  }

  chprintf(stream, "read power...\n");

  status = ina219_lld_read_power(((ut_ina219data_t*)ut->data)->inad, &power, ((ut_ina219data_t*)ut->data)->timeout);

  chprintf(stream, "\t\tpower: %fW\n", (float)(power)/1000000.f);

  if (status == APAL_STATUS_SUCCESS) {

    aosUtPassed(stream, &result);

  } else {

    aosUtFailed(stream, &result);

  }

  chprintf(stream, "read current...\n");

  status = ina219_lld_read_current(((ut_ina219data_t*)ut->data)->inad, &usensor_data, ((ut_ina219data_t*)ut->data)->timeout);

  chprintf(stream, "\t\tcurrent: %fA\n", (float)(usensor_data)/1000000.f);

  if (status == APAL_STATUS_SUCCESS) {

    aosUtPassed(stream, &result);

  } else {

    aosUtFailed(stream, &result);

  }

  aosUtInfoMsg(stream, "driver object memory footprint: %u bytes\n", sizeof(INA219Driver));

  return result;

}

#endif /* (AMIROOS_CFG_TESTS_ENABLE == true) && defined(AMIROLLD_CFG_USE_INA219) */