##// END OF EJS Templates
Implements test execute() method...
Implements test execute() method For each iteration of the test, this method generates available operations according to states of the variables, and execute an operation that has been chosen randomly.

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TestAmdaResultParser.cpp
579 lines | 25.8 KiB | text/x-c | CppLexer
/ plugins / amda / tests / TestAmdaResultParser.cpp
#include "AmdaResultParser.h"
#include <Data/ScalarSeries.h>
#include <Data/SpectrogramSeries.h>
#include <Data/VectorSeries.h>
#include <QObject>
#include <QtTest>
namespace {
/// Path for the tests
const auto TESTS_RESOURCES_PATH
= QFileInfo{QString{AMDA_TESTS_RESOURCES_DIR}, "TestAmdaResultParser"}.absoluteFilePath();
QDateTime dateTime(int year, int month, int day, int hours, int minutes, int seconds)
{
return QDateTime{{year, month, day}, {hours, minutes, seconds}, Qt::UTC};
}
QString inputFilePath(const QString &inputFileName)
{
return QFileInfo{TESTS_RESOURCES_PATH, inputFileName}.absoluteFilePath();
}
template <typename T>
struct ExpectedResults {
ExpectedResults &setParsingOK(bool parsingOK)
{
m_ParsingOK = parsingOK;
return *this;
}
ExpectedResults &setXAxisUnit(Unit xAxisUnit)
{
m_XAxisUnit = std::move(xAxisUnit);
return *this;
}
ExpectedResults &setXAxisData(const QVector<QDateTime> &xAxisData)
{
m_XAxisData.clear();
// Converts QVector<QDateTime> to QVector<double>
std::transform(xAxisData.cbegin(), xAxisData.cend(), std::back_inserter(m_XAxisData),
[](const auto &dateTime) { return dateTime.toMSecsSinceEpoch() / 1000.; });
return *this;
}
ExpectedResults &setValuesUnit(Unit valuesUnit)
{
m_ValuesUnit = std::move(valuesUnit);
return *this;
}
ExpectedResults &setValuesData(QVector<double> valuesData)
{
m_ValuesData.clear();
m_ValuesData.push_back(std::move(valuesData));
return *this;
}
ExpectedResults &setValuesData(QVector<QVector<double> > valuesData)
{
m_ValuesData = std::move(valuesData);
return *this;
}
ExpectedResults &setYAxisEnabled(bool yAxisEnabled)
{
m_YAxisEnabled = yAxisEnabled;
return *this;
}
ExpectedResults &setYAxisUnit(Unit yAxisUnit)
{
m_YAxisUnit = std::move(yAxisUnit);
return *this;
}
ExpectedResults &setYAxisData(QVector<double> yAxisData)
{
m_YAxisData = std::move(yAxisData);
return *this;
}
/**
* Validates a DataSeries compared to the expected results
* @param results the DataSeries to validate
*/
void validate(std::shared_ptr<IDataSeries> results)
{
if (m_ParsingOK) {
auto dataSeries = dynamic_cast<T *>(results.get());
if (dataSeries == nullptr) {
// No unit detected, parsink ok but data is nullptr
// TODO, improve the test to verify that the data is null
return;
}
// Checks units
QVERIFY(dataSeries->xAxisUnit() == m_XAxisUnit);
QVERIFY(dataSeries->valuesUnit() == m_ValuesUnit);
auto verifyRange = [dataSeries](const auto &expectedData, const auto &equalFun) {
QVERIFY(std::equal(dataSeries->cbegin(), dataSeries->cend(), expectedData.cbegin(),
expectedData.cend(),
[&equalFun](const auto &dataSeriesIt, const auto &expectedX) {
return equalFun(dataSeriesIt, expectedX);
}));
};
// Checks x-axis data
verifyRange(m_XAxisData, [](const auto &seriesIt, const auto &value) {
return seriesIt.x() == value;
});
// Checks values data of each component
for (auto i = 0; i < m_ValuesData.size(); ++i) {
verifyRange(m_ValuesData.at(i), [i](const auto &seriesIt, const auto &value) {
auto itValue = seriesIt.value(i);
return (std::isnan(itValue) && std::isnan(value)) || seriesIt.value(i) == value;
});
}
// Checks y-axis (if defined)
auto yAxis = dataSeries->yAxis();
QCOMPARE(yAxis.isDefined(), m_YAxisEnabled);
if (m_YAxisEnabled) {
// Unit
QCOMPARE(yAxis.unit(), m_YAxisUnit);
// Data
QVERIFY(std::equal(yAxis.cbegin(), yAxis.cend(), m_YAxisData.cbegin(),
m_YAxisData.cend(), [](const auto &it, const auto &expectedVal) {
return it.first() == expectedVal;
}));
}
}
else {
QVERIFY(results == nullptr);
}
}
// Parsing was successfully completed
bool m_ParsingOK{false};
// Expected x-axis unit
Unit m_XAxisUnit{};
// Expected x-axis data
QVector<double> m_XAxisData{};
// Expected values unit
Unit m_ValuesUnit{};
// Expected values data
QVector<QVector<double> > m_ValuesData{};
// Expected data series has y-axis
bool m_YAxisEnabled{false};
// Expected y-axis unit (if axis defined)
Unit m_YAxisUnit{};
// Expected y-axis data (if axis defined)
QVector<double> m_YAxisData{};
};
} // namespace
Q_DECLARE_METATYPE(ExpectedResults<ScalarSeries>)
Q_DECLARE_METATYPE(ExpectedResults<SpectrogramSeries>)
Q_DECLARE_METATYPE(ExpectedResults<VectorSeries>)
class TestAmdaResultParser : public QObject {
Q_OBJECT
private:
template <typename T>
void testReadDataStructure()
{
// ////////////// //
// Test structure //
// ////////////// //
// Name of TXT file to read
QTest::addColumn<QString>("inputFileName");
// Expected results
QTest::addColumn<ExpectedResults<T> >("expectedResults");
}
template <typename T>
void testRead(AmdaResultParser::ValueType valueType)
{
QFETCH(QString, inputFileName);
QFETCH(ExpectedResults<T>, expectedResults);
// Parses file
auto filePath = inputFilePath(inputFileName);
auto results = AmdaResultParser::readTxt(filePath, valueType);
// ///////////////// //
// Validates results //
// ///////////////// //
expectedResults.validate(results);
}
private slots:
/// Input test data
/// @sa testReadScalarTxt()
void testReadScalarTxt_data();
/// Tests parsing scalar series of a TXT file
void testReadScalarTxt();
/// Input test data
/// @sa testReadSpectrogramTxt()
void testReadSpectrogramTxt_data();
/// Tests parsing spectrogram series of a TXT file
void testReadSpectrogramTxt();
/// Input test data
/// @sa testReadVectorTxt()
void testReadVectorTxt_data();
/// Tests parsing vector series of a TXT file
void testReadVectorTxt();
};
void TestAmdaResultParser::testReadScalarTxt_data()
{
testReadDataStructure<ScalarSeries>();
// ////////// //
// Test cases //
// ////////// //
// Valid files
QTest::newRow("Valid file")
<< QStringLiteral("ValidScalar1.txt")
<< ExpectedResults<ScalarSeries>{}
.setParsingOK(true)
.setXAxisUnit(Unit{"nT", true})
.setXAxisData({dateTime(2013, 9, 23, 9, 0, 30), dateTime(2013, 9, 23, 9, 1, 30),
dateTime(2013, 9, 23, 9, 2, 30), dateTime(2013, 9, 23, 9, 3, 30),
dateTime(2013, 9, 23, 9, 4, 30), dateTime(2013, 9, 23, 9, 5, 30),
dateTime(2013, 9, 23, 9, 6, 30), dateTime(2013, 9, 23, 9, 7, 30),
dateTime(2013, 9, 23, 9, 8, 30), dateTime(2013, 9, 23, 9, 9, 30)})
.setValuesData({-2.83950, -2.71850, -2.52150, -2.57633, -2.58050, -2.48325, -2.63025,
-2.55800, -2.43250, -2.42200});
QTest::newRow("Valid file (value of first line is invalid but it is converted to NaN")
<< QStringLiteral("WrongValue.txt")
<< ExpectedResults<ScalarSeries>{}
.setParsingOK(true)
.setXAxisUnit(Unit{"nT", true})
.setXAxisData({dateTime(2013, 9, 23, 9, 0, 30), dateTime(2013, 9, 23, 9, 1, 30),
dateTime(2013, 9, 23, 9, 2, 30)})
.setValuesData({std::numeric_limits<double>::quiet_NaN(), -2.71850, -2.52150});
QTest::newRow("Valid file that contains NaN values")
<< QStringLiteral("NaNValue.txt")
<< ExpectedResults<ScalarSeries>{}
.setParsingOK(true)
.setXAxisUnit(Unit{("nT"), true})
.setXAxisData({dateTime(2013, 9, 23, 9, 0, 30), dateTime(2013, 9, 23, 9, 1, 30),
dateTime(2013, 9, 23, 9, 2, 30)})
.setValuesData({std::numeric_limits<double>::quiet_NaN(), -2.71850, -2.52150});
// Valid files but with some invalid lines (wrong unit, wrong values, etc.)
QTest::newRow("No unit file")
<< QStringLiteral("NoUnit.txt")
<< ExpectedResults<ScalarSeries>{}.setParsingOK(true).setXAxisUnit(Unit{"", true});
QTest::newRow("Wrong unit file")
<< QStringLiteral("WrongUnit.txt")
<< ExpectedResults<ScalarSeries>{}
.setParsingOK(true)
.setXAxisUnit(Unit{"", true})
.setXAxisData({dateTime(2013, 9, 23, 9, 0, 30), dateTime(2013, 9, 23, 9, 1, 30),
dateTime(2013, 9, 23, 9, 2, 30)})
.setValuesData({-2.83950, -2.71850, -2.52150});
QTest::newRow("Wrong results file (date of first line is invalid")
<< QStringLiteral("WrongDate.txt")
<< ExpectedResults<ScalarSeries>{}
.setParsingOK(true)
.setXAxisUnit(Unit{"nT", true})
.setXAxisData({dateTime(2013, 9, 23, 9, 1, 30), dateTime(2013, 9, 23, 9, 2, 30)})
.setValuesData({-2.71850, -2.52150});
QTest::newRow("Wrong results file (too many values for first line")
<< QStringLiteral("TooManyValues.txt")
<< ExpectedResults<ScalarSeries>{}
.setParsingOK(true)
.setXAxisUnit(Unit{"nT", true})
.setXAxisData({dateTime(2013, 9, 23, 9, 1, 30), dateTime(2013, 9, 23, 9, 2, 30)})
.setValuesData({-2.71850, -2.52150});
QTest::newRow("Wrong results file (x of first line is NaN")
<< QStringLiteral("NaNX.txt")
<< ExpectedResults<ScalarSeries>{}
.setParsingOK(true)
.setXAxisUnit(Unit{"nT", true})
.setXAxisData({dateTime(2013, 9, 23, 9, 1, 30), dateTime(2013, 9, 23, 9, 2, 30)})
.setValuesData({-2.71850, -2.52150});
QTest::newRow("Invalid file type (vector)")
<< QStringLiteral("ValidVector1.txt")
<< ExpectedResults<ScalarSeries>{}.setParsingOK(true).setXAxisUnit(Unit{"nT", true});
// Invalid files
QTest::newRow("Invalid file (unexisting file)")
<< QStringLiteral("UnexistingFile.txt")
<< ExpectedResults<ScalarSeries>{}.setParsingOK(false);
QTest::newRow("Invalid file (file not found on server)")
<< QStringLiteral("FileNotFound.txt")
<< ExpectedResults<ScalarSeries>{}.setParsingOK(false);
}
void TestAmdaResultParser::testReadScalarTxt()
{
testRead<ScalarSeries>(AmdaResultParser::ValueType::SCALAR);
}
void TestAmdaResultParser::testReadSpectrogramTxt_data()
{
testReadDataStructure<SpectrogramSeries>();
// ////////// //
// Test cases //
// ////////// //
// Valid files
QTest::newRow("Valid file (three bands)")
<< QStringLiteral("spectro/ValidSpectrogram1.txt")
<< ExpectedResults<SpectrogramSeries>{}
.setParsingOK(true)
.setXAxisUnit(Unit{"t", true})
.setXAxisData({dateTime(2012, 11, 6, 9, 14, 35), dateTime(2012, 11, 6, 9, 16, 10),
dateTime(2012, 11, 6, 9, 17, 45), dateTime(2012, 11, 6, 9, 19, 20),
dateTime(2012, 11, 6, 9, 20, 55)})
.setYAxisEnabled(true)
.setYAxisUnit(Unit{"eV"})
.setYAxisData({5.75, 7.6, 10.05}) // middle of the intervals of each band
.setValuesUnit(Unit{"eV/(cm^2-s-sr-eV)"})
.setValuesData(QVector<QVector<double> >{
{16313.780, 12631.465, 8223.368, 27595.301, 12820.613},
{15405.838, 11957.925, 15026.249, 25617.533, 11179.109},
{8946.475, 18133.158, 10875.621, 24051.619, 19283.221}});
auto fourBandsResult
= ExpectedResults<SpectrogramSeries>{}
.setParsingOK(true)
.setXAxisUnit(Unit{"t", true})
.setXAxisData({dateTime(2012, 11, 6, 9, 14, 35), dateTime(2012, 11, 6, 9, 16, 10),
dateTime(2012, 11, 6, 9, 17, 45), dateTime(2012, 11, 6, 9, 19, 20),
dateTime(2012, 11, 6, 9, 20, 55)})
.setYAxisEnabled(true)
.setYAxisUnit(Unit{"eV"})
.setYAxisData({5.75, 7.6, 10.05, 13.}) // middle of the intervals of each band
.setValuesUnit(Unit{"eV/(cm^2-s-sr-eV)"})
.setValuesData(QVector<QVector<double> >{
{16313.780, 12631.465, 8223.368, 27595.301, 12820.613},
{15405.838, 11957.925, 15026.249, 25617.533, 11179.109},
{8946.475, 18133.158, 10875.621, 24051.619, 19283.221},
{20907.664, 32076.725, 13008.381, 13142.759, 23226.998}});
QTest::newRow("Valid file (four bands)") << QStringLiteral("spectro/ValidSpectrogram2.txt")
<< fourBandsResult;
QTest::newRow("Valid file (four unsorted bands)")
<< QStringLiteral("spectro/ValidSpectrogram3.txt")
<< fourBandsResult; // Bands and values are sorted
auto nan = std::numeric_limits<double>::quiet_NaN();
auto nanValuesResult
= ExpectedResults<SpectrogramSeries>{}
.setParsingOK(true)
.setXAxisUnit(Unit{"t", true})
.setXAxisData({dateTime(2012, 11, 6, 9, 14, 35), dateTime(2012, 11, 6, 9, 16, 10),
dateTime(2012, 11, 6, 9, 17, 45), dateTime(2012, 11, 6, 9, 19, 20),
dateTime(2012, 11, 6, 9, 20, 55)})
.setYAxisEnabled(true)
.setYAxisUnit(Unit{"eV"})
.setYAxisData({5.75, 7.6, 10.05, 13.}) // middle of the intervals of each band
.setValuesUnit(Unit{"eV/(cm^2-s-sr-eV)"})
.setValuesData(
QVector<QVector<double> >{{nan, 12631.465, 8223.368, 27595.301, 12820.613},
{15405.838, nan, nan, 25617.533, 11179.109},
{8946.475, 18133.158, 10875.621, 24051.619, 19283.221},
{nan, nan, nan, nan, nan}});
QTest::newRow("Valid file (containing NaN values)")
<< QStringLiteral("spectro/ValidSpectrogramNaNValues.txt") << nanValuesResult;
QTest::newRow("Valid file (containing fill values)")
<< QStringLiteral("spectro/ValidSpectrogramFillValues.txt")
<< nanValuesResult; // Fill values are replaced by NaN values in the data series
QTest::newRow("Valid file (containing data holes, resolution = 3 minutes)")
<< QStringLiteral("spectro/ValidSpectrogramDataHoles.txt")
<< ExpectedResults<SpectrogramSeries>{}
.setParsingOK(true)
.setXAxisUnit(Unit{"t", true})
.setXAxisData({dateTime(2011, 12, 10, 12, 10, 54), //
dateTime(2011, 12, 10, 12, 13, 54), // Data hole
dateTime(2011, 12, 10, 12, 16, 54), // Data hole
dateTime(2011, 12, 10, 12, 17, 23), //
dateTime(2011, 12, 10, 12, 20, 23), // Data hole
dateTime(2011, 12, 10, 12, 23, 23), // Data hole
dateTime(2011, 12, 10, 12, 23, 51), //
dateTime(2011, 12, 10, 12, 26, 51), // Data hole
dateTime(2011, 12, 10, 12, 29, 51), // Data hole
dateTime(2011, 12, 10, 12, 30, 19), //
dateTime(2011, 12, 10, 12, 33, 19), // Data hole
dateTime(2011, 12, 10, 12, 35, 04), //
dateTime(2011, 12, 10, 12, 36, 41), //
dateTime(2011, 12, 10, 12, 38, 18), //
dateTime(2011, 12, 10, 12, 39, 55)})
.setYAxisEnabled(true)
.setYAxisUnit(Unit{"eV"})
.setYAxisData({16485.85, 20996.1}) // middle of the intervals of each band
.setValuesUnit(Unit{"eV/(cm^2-s-sr-eV)"})
.setValuesData(QVector<QVector<double> >{{2577578.000, //
nan, // Data hole
nan, // Data hole
2314121.500, //
nan, // Data hole
nan, // Data hole
2063608.750, //
nan, // Data hole
nan, // Data hole
2234525.500, //
nan, // Data hole
1670215.250, //
1689243.250, //
1654617.125, //
1504983.750},
{2336016.000, //
nan, // Data hole
nan, // Data hole
1712093.125, //
nan, // Data hole
nan, // Data hole
1614491.625, //
nan, // Data hole
nan, // Data hole
1764516.500, //
nan, // Data hole
1688078.500, //
1743183.500, //
1733603.250, //
1708356.500}});
QTest::newRow(
"Valid file (containing data holes at the beginning and the end, resolution = 4 minutes)")
<< QStringLiteral("spectro/ValidSpectrogramDataHoles2.txt")
<< ExpectedResults<SpectrogramSeries>{}
.setParsingOK(true)
.setXAxisUnit(Unit{"t", true})
.setXAxisData({
dateTime(2011, 12, 10, 12, 2, 54), // Data hole
dateTime(2011, 12, 10, 12, 6, 54), // Data hole
dateTime(2011, 12, 10, 12, 10, 54), //
dateTime(2011, 12, 10, 12, 14, 54), // Data hole
dateTime(2011, 12, 10, 12, 17, 23), //
dateTime(2011, 12, 10, 12, 21, 23), // Data hole
dateTime(2011, 12, 10, 12, 23, 51), //
dateTime(2011, 12, 10, 12, 27, 51), // Data hole
dateTime(2011, 12, 10, 12, 30, 19), //
dateTime(2011, 12, 10, 12, 34, 19), // Data hole
dateTime(2011, 12, 10, 12, 35, 04), //
dateTime(2011, 12, 10, 12, 36, 41), //
dateTime(2011, 12, 10, 12, 38, 18), //
dateTime(2011, 12, 10, 12, 39, 55),
dateTime(2011, 12, 10, 12, 43, 55), // Data hole
dateTime(2011, 12, 10, 12, 47, 55), // Data hole
dateTime(2011, 12, 10, 12, 51, 55), // Data hole
dateTime(2011, 12, 10, 12, 55, 55), // Data hole
dateTime(2011, 12, 10, 12, 59, 55) // Data hole
})
.setYAxisEnabled(true)
.setYAxisUnit(Unit{"eV"})
.setYAxisData({16485.85, 20996.1}) // middle of the intervals of each band
.setValuesUnit(Unit{"eV/(cm^2-s-sr-eV)"})
.setValuesData(QVector<QVector<double> >{{
nan, // Data hole
nan, // Data hole
2577578.000, //
nan, // Data hole
2314121.500, //
nan, // Data hole
2063608.750, //
nan, // Data hole
2234525.500, //
nan, // Data hole
1670215.250, //
1689243.250, //
1654617.125, //
1504983.750, //
nan, // Data hole
nan, // Data hole
nan, // Data hole
nan, // Data hole
nan // Data hole
},
{
nan, // Data hole
nan, // Data hole
2336016.000, //
nan, // Data hole
1712093.125, //
nan, // Data hole
1614491.625, //
nan, // Data hole
1764516.500, //
nan, // Data hole
1688078.500, //
1743183.500, //
1733603.250, //
1708356.500, //
nan, // Data hole
nan, // Data hole
nan, // Data hole
nan, // Data hole
nan // Data hole
}});
// Invalid files
QTest::newRow("Invalid file (inconsistent bands)")
<< QStringLiteral("spectro/InvalidSpectrogramWrongBands.txt")
<< ExpectedResults<SpectrogramSeries>{}.setParsingOK(false);
}
void TestAmdaResultParser::testReadSpectrogramTxt()
{
testRead<SpectrogramSeries>(AmdaResultParser::ValueType::SPECTROGRAM);
}
void TestAmdaResultParser::testReadVectorTxt_data()
{
testReadDataStructure<VectorSeries>();
// ////////// //
// Test cases //
// ////////// //
// Valid files
QTest::newRow("Valid file")
<< QStringLiteral("ValidVector1.txt")
<< ExpectedResults<VectorSeries>{}
.setParsingOK(true)
.setXAxisUnit(Unit{"nT", true})
.setXAxisData({dateTime(2013, 7, 2, 9, 13, 50), dateTime(2013, 7, 2, 9, 14, 6),
dateTime(2013, 7, 2, 9, 14, 22), dateTime(2013, 7, 2, 9, 14, 38),
dateTime(2013, 7, 2, 9, 14, 54), dateTime(2013, 7, 2, 9, 15, 10),
dateTime(2013, 7, 2, 9, 15, 26), dateTime(2013, 7, 2, 9, 15, 42),
dateTime(2013, 7, 2, 9, 15, 58), dateTime(2013, 7, 2, 9, 16, 14)})
.setValuesData(
{{-0.332, -1.011, -1.457, -1.293, -1.217, -1.443, -1.278, -1.202, -1.22, -1.259},
{3.206, 2.999, 2.785, 2.736, 2.612, 2.564, 2.892, 2.862, 2.859, 2.764},
{0.058, 0.496, 1.018, 1.485, 1.662, 1.505, 1.168, 1.244, 1.15, 1.358}});
// Valid files but with some invalid lines (wrong unit, wrong values, etc.)
QTest::newRow("Invalid file type (scalar)")
<< QStringLiteral("ValidScalar1.txt")
<< ExpectedResults<VectorSeries>{}
.setParsingOK(true)
.setXAxisUnit(Unit{"nT", true})
.setXAxisData({})
.setValuesData(QVector<QVector<double> >{{}, {}, {}});
}
void TestAmdaResultParser::testReadVectorTxt()
{
testRead<VectorSeries>(AmdaResultParser::ValueType::VECTOR);
}
QTEST_MAIN(TestAmdaResultParser)
#include "TestAmdaResultParser.moc"