GY-63_MS5611/libraries/Temperature/test/unit_test_001.cpp
2022-01-09 11:07:58 +01:00

177 lines
5.6 KiB
C++

//
// FILE: unit_test_001.cpp
// AUTHOR: Rob Tillaart
// DATE: 2021-01-01
// PURPOSE: unit tests for the temperature library
// https://github.com/RobTillaart/Temperature
// https://github.com/Arduino-CI/arduino_ci/blob/master/REFERENCE.md
//
// supported assertions
// ----------------------------
// assertEqual(expected, actual); // a == b
// assertNotEqual(unwanted, actual); // a != b
// assertComparativeEquivalent(expected, actual); // abs(a - b) == 0 or (!(a > b) && !(a < b))
// assertComparativeNotEquivalent(unwanted, actual); // abs(a - b) > 0 or ((a > b) || (a < b))
// assertLess(upperBound, actual); // a < b
// assertMore(lowerBound, actual); // a > b
// assertLessOrEqual(upperBound, actual); // a <= b
// assertMoreOrEqual(lowerBound, actual); // a >= b
// assertTrue(actual);
// assertFalse(actual);
// assertNull(actual);
// // special cases for floats
// assertEqualFloat(expected, actual, epsilon); // fabs(a - b) <= epsilon
// assertNotEqualFloat(unwanted, actual, epsilon); // fabs(a - b) >= epsilon
// assertInfinity(actual); // isinf(a)
// assertNotInfinity(actual); // !isinf(a)
// assertNAN(arg); // isnan(a)
// assertNotNAN(arg); // !isnan(a)
#include <ArduinoUnitTests.h>
#include "Arduino.h"
#include "temperature.h"
unittest_setup()
{
fprintf(stderr, "TEMPERATURE_VERSION: %s\n", (char *) TEMPERATURE_VERSION);
}
unittest_teardown()
{
}
unittest(test_conversion)
{
assertEqualFloat(-40, Fahrenheit(-40), 0.001);
assertEqualFloat(-40, Celsius(-40), 0.001);
assertEqualFloat(273.15, Kelvin(0), 0.001);
}
unittest(test_dewpoint)
{
assertEqualFloat(9.27985, dewPoint(20, 50), 0.001);
assertEqualFloat(9.25489, dewPointFast(20, 50), 0.001);
assertEqualFloat(21.2829, humidex(20, 10), 0.001);
}
unittest(test_heatIndex)
{
// Fahrenheit
assertEqualFloat(14.050, heatIndex(20, 50), 0.001);
assertEqualFloat(66.850, heatIndex(68, 50), 0.001);
// Celsius
assertEqualFloat(19.361, heatIndexC(20, 50), 0.001);
}
unittest(test_heatIndex_2)
{
// Fahrenheit reference points
assertEqualFloat( 77, heatIndex(80, 00), 1);
assertEqualFloat( 78, heatIndex(80, 10), 1);
assertEqualFloat( 80, heatIndex(80, 40), 1);
assertEqualFloat( 82, heatIndex(80, 60), 1);
assertEqualFloat( 86, heatIndex(80, 90), 1);
assertEqualFloat( 89, heatIndex(80, 100), 1);
fprintf(stderr, "\n");
assertEqualFloat( 84, heatIndex(90, 00), 1);
assertEqualFloat( 85, heatIndex(90, 10), 1);
assertEqualFloat( 91, heatIndex(90, 40), 1);
assertEqualFloat(100, heatIndex(90, 60), 1);
assertEqualFloat(122, heatIndex(90, 90), 1);
assertEqualFloat(132, heatIndex(90, 100), 1);
fprintf(stderr, "\n");
assertEqualFloat( 91, heatIndex(100, 00), 1);
assertEqualFloat( 94, heatIndex(100, 10), 1);
assertEqualFloat(109, heatIndex(100, 40), 1);
assertEqualFloat(129, heatIndex(100, 60), 1);
assertEqualFloat(176, heatIndex(100, 90), 1);
assertEqualFloat(195, heatIndex(100, 100), 1);
fprintf(stderr, "\n");
assertEqualFloat( 99, heatIndex(110, 00), 1);
assertEqualFloat(104, heatIndex(110, 10), 1);
assertEqualFloat(136, heatIndex(110, 40), 1);
assertEqualFloat(171, heatIndex(110, 60), 1);
assertEqualFloat(247, heatIndex(110, 90), 1);
assertEqualFloat(278, heatIndex(110, 100), 1);
}
unittest(test_windChill)
{
assertEqualFloat(107.108, WindChill_F_mph (100, 10, true), 0.001);
assertEqualFloat(40.8862, WindChill_C_kmph(37, 10, true), 0.001);
assertEqualFloat(41.9713, WindChill_C_mps (37, 10, true), 0.001);
assertEqualFloat(166.99, WindChill_F_mph (100, 10, false), 0.001);
assertEqualFloat(69.1205, WindChill_C_kmph(37, 10, false), 0.001);
assertEqualFloat(154.934, WindChill_C_mps (37, 10, false), 0.001);
}
unittest(test_converter)
{
temperatureConverter TC;
fprintf(stderr, "\n 0°C\n");
TC.setCelsius(0);
assertEqualFloat( 273.15, TC.getKelvin(), 0.01);
assertEqualFloat( 0.00, TC.getCelsius(), 0.01);
assertEqualFloat( 32.00, TC.getFahrenheit(), 0.01);
assertEqualFloat( 0.00, TC.getReamur(), 0.01);
assertEqualFloat( 491.67, TC.getRankine(), 0.01);
assertEqualFloat(-100.00, TC.getDelisle(), 0.01);
assertEqualFloat( 0.00, TC.getNewton(), 0.01);
assertEqualFloat( 7.50, TC.getRomer(), 0.01);
fprintf(stderr, "\n 100°C\n");
TC.setCelsius(100);
assertEqualFloat( 373.15, TC.getKelvin(), 0.01);
assertEqualFloat( 100.00, TC.getCelsius(), 0.01);
assertEqualFloat( 212.00, TC.getFahrenheit(), 0.01);
assertEqualFloat( 80.00, TC.getReamur(), 0.01);
assertEqualFloat( 671.67, TC.getRankine(), 0.01);
assertEqualFloat( 50.00, TC.getDelisle(), 0.01);
assertEqualFloat( 33.00, TC.getNewton(), 0.01);
assertEqualFloat( 60.00, TC.getRomer(), 0.01);
}
unittest(test_set_get)
{
temperatureConverter TC;
fprintf(stderr, "\n 42°C\n");
TC.setKelvin(42);
assertEqualFloat( 42.00, TC.getKelvin(), 0.01);
TC.setCelsius(42);
assertEqualFloat( 42.00, TC.getCelsius(), 0.01);
TC.setFahrenheit(42);
assertEqualFloat( 42.00, TC.getFahrenheit(), 0.01);
TC.setReamur(42);
assertEqualFloat( 42.00, TC.getReamur(), 0.01);
TC.setRankine(42);
assertEqualFloat( 42.00, TC.getRankine(), 0.01);
TC.setDelisle(42);
assertEqualFloat( 42.00, TC.getDelisle(), 0.01);
TC.setNewton(42);
assertEqualFloat( 42.00, TC.getNewton(), 0.01);
TC.setRomer(42);
assertEqualFloat( 42.00, TC.getRomer(), 0.01);
}
unittest_main()
// --------