openstudio::TimeSeries ScheduleVariableInterval_Impl::timeSeries() const
{
unsigned numExtensibleGroups = this->numExtensibleGroups();
if (numExtensibleGroups == 0){
return TimeSeries(Date(MonthOfYear::Jan, 1), 0, Vector(), "");
}
DateTimeVector dateTimes;
Vector values(numExtensibleGroups);
unsigned i = 0;
for (const ModelExtensibleGroup& group : castVector<ModelExtensibleGroup>(extensibleGroups()))
{
OptionalInt month = group.getInt(0);
OptionalInt day = group.getInt(1);
OptionalInt hour = group.getInt(2);
OptionalInt minute = group.getInt(3);
OptionalDouble x = group.getDouble(4);
OS_ASSERT(month);
OS_ASSERT(day);
OS_ASSERT(hour);
OS_ASSERT(minute);
OS_ASSERT(x);
dateTimes.push_back(DateTime(Date(MonthOfYear(*month), *day), Time(0, *hour, *minute)));
values[i] = *x;
++i;
}
TimeSeries result(dateTimes, values, "");
result.setOutOfRangeValue(this->outOfRangeValue());
return result;
}
TEST(Filetypes, EpwFile_International_Data)
{
try{
path p = resourcesPath() / toPath("utilities/Filetypes/CHN_Guangdong.Shaoguan.590820_CSWD.epw");
EpwFile epwFile(p,true);
EXPECT_EQ(p, epwFile.path());
EXPECT_EQ("B68C068B", epwFile.checksum());
EXPECT_EQ("Shaoguan", epwFile.city());
EXPECT_EQ("Guangdong", epwFile.stateProvinceRegion());
EXPECT_EQ("CHN", epwFile.country());
EXPECT_EQ("CSWD", epwFile.dataSource());
EXPECT_EQ("590820", epwFile.wmoNumber());
EXPECT_EQ(24.68, epwFile.latitude());
EXPECT_EQ(113.6, epwFile.longitude());
EXPECT_EQ(8, epwFile.timeZone());
EXPECT_EQ(61, epwFile.elevation());
EXPECT_EQ(Time(0,1,0,0), epwFile.timeStep());
EXPECT_EQ(DayOfWeek(DayOfWeek::Sunday), epwFile.startDayOfWeek());
EXPECT_EQ(Date(MonthOfYear::Jan, 1), epwFile.startDate());
EXPECT_EQ(Date(MonthOfYear::Dec, 31), epwFile.endDate());
// Up to here, everything should be the same as the first test. Now ask for the data
std::vector<EpwDataPoint> data = epwFile.data();
EXPECT_EQ(8760,data.size());
// The last data point check
EXPECT_EQ(14.7,data[8759].dryBulbTemperature().get());
EXPECT_EQ(101100,data[8759].atmosphericStationPressure().get());
// Try out the alternate access functions, dew point temperature should be -1C
EXPECT_EQ(11.7,data[8759].fieldByName("Dew Point Temperature").get());
EXPECT_EQ(11.7,data[8759].field(EpwDataField("Dew Point Temperature")).get());
// The last data point should not have a liquid precipitation depth
EXPECT_FALSE(data[8759].fieldByName("Liquid Precipitation Depth"));
// Get a time series
boost::optional<openstudio::TimeSeries> series = epwFile.getTimeSeries("Wind Speed");
ASSERT_TRUE(series);
ASSERT_EQ(8760,series->values().size());
DateTimeVector seriesTimes = series->dateTimes();
ASSERT_EQ(8760,seriesTimes.size());
// Check the times in the data and the time series
DateTime current(Date(1,1,1999),Time(0,1)); // Use 1999 to avoid leap years
Time delta(0,1);
for(unsigned i=0;i<8760;i++) {
// This is a lot more complicated that it probably should be to avoid the year being a problem
DateTime datatime = data[i].dateTime();
EXPECT_EQ(datatime.date().monthOfYear(), current.date().monthOfYear());
EXPECT_EQ(datatime.date().dayOfMonth(), current.date().dayOfMonth());
EXPECT_EQ(datatime.time().hours(), current.time().hours());
EXPECT_EQ(datatime.time().minutes(), current.time().minutes());
DateTime seriestime = seriesTimes[i];
EXPECT_EQ(seriestime.date().monthOfYear(), current.date().monthOfYear());
EXPECT_EQ(seriestime.date().dayOfMonth(), current.date().dayOfMonth());
EXPECT_EQ(seriestime.time().hours(), current.time().hours());
EXPECT_EQ(seriestime.time().minutes(), current.time().minutes());
current += delta;
}
// No need to redo the original tests here since the data should have been loaded in the constructor
}catch(...){
ASSERT_TRUE(false);
}
}
TEST(Filetypes, EpwFile_IWEC_Data)
{
try {
path p = resourcesPath() / toPath("utilities/Filetypes/TUN_Tunis.607150_IWEC.epw");
EpwFile epwFile(p, true);
EXPECT_EQ(p, epwFile.path());
EXPECT_EQ("FEAB878E", epwFile.checksum());
EXPECT_EQ("TUNIS", epwFile.city());
EXPECT_EQ("-", epwFile.stateProvinceRegion());
EXPECT_EQ("TUN", epwFile.country());
EXPECT_EQ("IWEC Data", epwFile.dataSource());
EXPECT_EQ("607150", epwFile.wmoNumber());
EXPECT_EQ(36.83, epwFile.latitude());
EXPECT_EQ(10.23, epwFile.longitude());
EXPECT_EQ(1, epwFile.timeZone());
EXPECT_EQ(4, epwFile.elevation());
EXPECT_EQ(Time(0, 1, 0, 0), epwFile.timeStep());
EXPECT_EQ(DayOfWeek(DayOfWeek::Sunday), epwFile.startDayOfWeek());
EXPECT_EQ(Date(MonthOfYear::Jan, 1), epwFile.startDate());
EXPECT_EQ(Date(MonthOfYear::Dec, 31), epwFile.endDate());
// Up to here, everything should be the same as the first test. Now ask for the data
std::vector<EpwDataPoint> data = epwFile.data();
EXPECT_EQ(8760, data.size());
// The last data point check
EXPECT_EQ(11.3, data[8759].dryBulbTemperature().get());
EXPECT_EQ(102400, data[8759].atmosphericStationPressure().get());
// Try out the alternate access functions
EXPECT_EQ(9.8, data[8759].getFieldByName("Dew Point Temperature").get());
EXPECT_EQ(9.8, data[8759].getField(EpwDataField("Dew Point Temperature")).get());
// Get a time series
boost::optional<openstudio::TimeSeries> series = epwFile.getTimeSeries("Wind Speed");
ASSERT_TRUE(series);
ASSERT_EQ(8760, series->values().size());
DateTimeVector seriesTimes = series->dateTimes();
ASSERT_EQ(8760, seriesTimes.size());
// Check the times in the data and the time series
DateTime current(Date(1, 1, 1999), Time(0, 1)); // Use 1999 to avoid leap years
Time delta(0, 1);
for (unsigned i = 0; i<8760; i++) {
// This is a lot more complicated that it probably should be to avoid the year being a problem
DateTime datatime = data[i].dateTime();
EXPECT_EQ(datatime.date().monthOfYear(), current.date().monthOfYear());
EXPECT_EQ(datatime.date().dayOfMonth(), current.date().dayOfMonth());
EXPECT_EQ(datatime.time().hours(), current.time().hours());
EXPECT_EQ(datatime.time().minutes(), current.time().minutes());
DateTime seriestime = seriesTimes[i];
EXPECT_EQ(seriestime.date().monthOfYear(), current.date().monthOfYear());
EXPECT_EQ(seriestime.date().dayOfMonth(), current.date().dayOfMonth());
EXPECT_EQ(seriestime.time().hours(), current.time().hours());
EXPECT_EQ(seriestime.time().minutes(), current.time().minutes());
current += delta;
}
// No need to redo the original tests here since the data should have been loaded in the constructor
}
catch (...) {
ASSERT_TRUE(false);
}
}
TEST_F(DataFixture,TimeSeries_AddSubtractSameTimePeriod)
{
std::string units = "W";
Date startDate(Date(MonthOfYear(MonthOfYear::Feb),21));
DateTime startDateTime(startDate, Time(0,1,0,0));
// interval
Time interval = Time(0,1,0,0);
Vector intervalValues(3);
intervalValues(0) = 0;
intervalValues(1) = 1;
intervalValues(2) = 2;
TimeSeries intervalTimeSeries(startDateTime, interval, intervalValues, units);
ASSERT_TRUE(!intervalTimeSeries.values().empty());
// detailed
DateTimeVector dateTimes;
dateTimes.push_back(startDateTime + Time(0,0,0,0));
dateTimes.push_back(startDateTime + Time(0,0,30,0));
dateTimes.push_back(startDateTime + Time(0,1,0,0));
dateTimes.push_back(startDateTime + Time(0,1,30,0));
dateTimes.push_back(startDateTime + Time(0,2,0,0));
Vector detailedValues(5);
detailedValues(0) = 0.0; // 1:00
detailedValues(1) = 0.5; // 1:30
detailedValues(2) = 1.0; // 2:00
detailedValues(3) = 1.5; // 2:30
detailedValues(4) = 2.0; // 3:00
TimeSeries detailedTimeSeries(dateTimes, detailedValues, units);
ASSERT_TRUE(!detailedTimeSeries.values().empty());
// sum and difference
TimeSeries sum = intervalTimeSeries + detailedTimeSeries;
TimeSeries diff1 = intervalTimeSeries - detailedTimeSeries;
TimeSeries diff2 = detailedTimeSeries - intervalTimeSeries;
ASSERT_TRUE(!sum.values().empty());
ASSERT_TRUE(!diff1.values().empty());
ASSERT_TRUE(!diff2.values().empty());
// EXPECT_EQ((unsigned)5, sum.dateTimes().size());
// EXPECT_EQ((unsigned)5, diff1.dateTimes().size());
// EXPECT_EQ((unsigned)5, diff2.dateTimes().size());
EXPECT_EQ((unsigned)5, sum.daysFromFirstReport().size());
EXPECT_EQ((unsigned)5, diff1.daysFromFirstReport().size());
EXPECT_EQ((unsigned)5, diff2.daysFromFirstReport().size());
// EXPECT_EQ(startDateTime, sum.dateTimes().front());
// EXPECT_EQ(startDateTime, diff1.dateTimes().front());
// EXPECT_EQ(startDateTime, diff2.dateTimes().front());
EXPECT_EQ(startDateTime, sum.firstReportDateTime());
EXPECT_EQ(startDateTime, diff1.firstReportDateTime());
EXPECT_EQ(startDateTime, diff2.firstReportDateTime());
DateTime endDateTime = startDateTime + Time(0,2,0,0);
// EXPECT_EQ(endDateTime, sum.dateTimes().back());
// EXPECT_EQ(endDateTime, diff1.dateTimes().back());
// EXPECT_EQ(endDateTime, diff2.dateTimes().back());
EXPECT_EQ(endDateTime, sum.firstReportDateTime() + Time(sum.daysFromFirstReport(sum.daysFromFirstReport().size()-1)));
EXPECT_EQ(endDateTime, diff1.firstReportDateTime() + Time(diff1.daysFromFirstReport(diff1.daysFromFirstReport().size()-1)));
EXPECT_EQ(endDateTime, diff2.firstReportDateTime() + Time(diff2.daysFromFirstReport(diff2.daysFromFirstReport().size()-1)));
// 1:00
EXPECT_EQ(0, sum.value(Time(0,0,0,0)));
EXPECT_EQ(0, diff1.value(Time(0,0,0,0)));
EXPECT_EQ(0, diff2.value(Time(0,0,0,0)));
// 1:30
EXPECT_EQ(1.5, sum.value(Time(0,0,30,0)));
EXPECT_EQ(0.5, diff1.value(Time(0,0,30,0)));
EXPECT_EQ(-0.5, diff2.value(Time(0,0,30,0)));
// 2:00
EXPECT_EQ(2, sum.value(Time(0,1,0,0)));
EXPECT_EQ(0.0, diff1.value(Time(0,1,0,0)));
EXPECT_EQ(0.0, diff2.value(Time(0,1,0,0)));
// 2:30
EXPECT_EQ(3.5, sum.value(Time(0,1,30,0)));
EXPECT_EQ(0.5, diff1.value(Time(0,1,30,0)));
EXPECT_EQ(-0.5, diff2.value(Time(0,1,30,0)));
// Test helper function for summing a vector.
TimeSeriesVector sumAndDiffs;
sumAndDiffs.push_back(sum);
sumAndDiffs.push_back(diff1);
sumAndDiffs.push_back(diff2);
TimeSeries ans = openstudio::sum(sumAndDiffs);
EXPECT_FALSE(ans.values().empty());
// 1:00
EXPECT_DOUBLE_EQ(0, ans.value(Time(0,0,0,0)));
// 1:30
EXPECT_DOUBLE_EQ(1.5, ans.value(Time(0,0,30,0)));
// 2:00
EXPECT_DOUBLE_EQ(2.0, ans.value(Time(0,1,0,0)));
// 2:30
EXPECT_DOUBLE_EQ(3.5, ans.value(Time(0,1,30,0)));
// Test multiplication and division with a scalar
sumAndDiffs.push_back(sum/2.0);
sumAndDiffs.push_back(3.0*diff1);
ans = openstudio::sum(sumAndDiffs);
EXPECT_FALSE(ans.values().empty());
// 1:00
EXPECT_DOUBLE_EQ(0, ans.value(Time(0,0,0,0)));
// 1:30
EXPECT_DOUBLE_EQ(3.75, ans.value(Time(0,0,30,0)));
// 2:00
EXPECT_DOUBLE_EQ(3.0, ans.value(Time(0,1,0,0)));
// 2:30
EXPECT_DOUBLE_EQ(6.75, ans.value(Time(0,1,30,0)));
}
TEST_F(DataFixture,TimeSeries_DetailedConstructor)
{
std::string units = "W";
Date startDate(Date(MonthOfYear(MonthOfYear::Feb),21));
DateTime startDateTime(startDate, Time(0,1,0,0));
// fill vector with 3 hours of data
Vector values(3);
DateTimeVector dateTimes;
for (unsigned i = 0; i < 3; ++i){
values(i) = i;
dateTimes.push_back(startDateTime + Time(0,i,0,0));
}
unsigned numValues = values.size();
// create detailed timeSeries
TimeSeries timeSeries(dateTimes, values, units);
ASSERT_TRUE(!timeSeries.values().empty());
// check interval
EXPECT_FALSE(timeSeries.intervalLength());
// check start date and time
// DateTime firstDateTime = timeSeries.dateTimes().front();
DateTime firstDateTime = timeSeries.firstReportDateTime();
EXPECT_EQ(DateTime(Date(MonthOfYear(MonthOfYear::Feb), 21), Time(0,1,0,0)), firstDateTime);
// check end date and time
// DateTime endDateTime = timeSeries.dateTimes().back();
DateTime endDateTime = timeSeries.firstReportDateTime() + Time(timeSeries.daysFromFirstReport(timeSeries.daysFromFirstReport().size()-1));
EXPECT_EQ(DateTime(Date(MonthOfYear(MonthOfYear::Feb), 21), Time(0,3,0,0)), endDateTime);
// check out of range
timeSeries.setOutOfRangeValue(-99);
EXPECT_EQ(-99, timeSeries.value(startDateTime + Time(0,0,-61,0))); // out of range
EXPECT_EQ(-99, timeSeries.value(startDateTime + Time(0,0,-60,0))); // out of range
EXPECT_EQ(-99, timeSeries.value(startDateTime + Time(0,0,-59,0))); // out of range
EXPECT_EQ(-99, timeSeries.value(startDateTime + Time(0,0,-1,0))); // out of range
EXPECT_EQ(0, timeSeries.value(startDateTime)); // in range
EXPECT_EQ(2, timeSeries.value(endDateTime)); // in range
EXPECT_EQ(-99, timeSeries.value(endDateTime + Time(0,1,0,0))); // out of range
// check values
for (unsigned i = 0; i < numValues; ++i){
double numPeriods = (double)i;
Time interval(0,1,0,0);
double lastPeriodEnd = (numPeriods-1.0)*interval.totalDays();
double periodBegin = (numPeriods-0.99)*interval.totalDays();
double periodMiddle = (numPeriods-0.5)*interval.totalDays();
double periodEnd = (numPeriods)*interval.totalDays();
if (i > 0){
EXPECT_EQ(numPeriods-1, timeSeries.value(lastPeriodEnd));
EXPECT_EQ(numPeriods, timeSeries.value(periodBegin));
EXPECT_EQ(numPeriods, timeSeries.value(periodMiddle));
}
EXPECT_EQ(numPeriods, timeSeries.value(periodEnd));
}
}
TEST(Filetypes, EpwFile_Data)
{
try{
path p = resourcesPath() / toPath("runmanager/USA_CO_Golden-NREL.724666_TMY3.epw");
EpwFile epwFile(p);
EXPECT_EQ(p, epwFile.path());
EXPECT_EQ("F188656D", epwFile.checksum());
EXPECT_EQ("Denver Centennial Golden Nr", epwFile.city());
EXPECT_EQ("CO", epwFile.stateProvinceRegion());
EXPECT_EQ("USA", epwFile.country());
EXPECT_EQ("TMY3", epwFile.dataSource());
EXPECT_EQ("724666", epwFile.wmoNumber());
EXPECT_EQ(39.74, epwFile.latitude());
EXPECT_EQ(-105.18, epwFile.longitude());
EXPECT_EQ(-7, epwFile.timeZone());
EXPECT_EQ(1829, epwFile.elevation());
EXPECT_EQ(Time(0,1,0,0), epwFile.timeStep());
EXPECT_EQ(DayOfWeek(DayOfWeek::Sunday), epwFile.startDayOfWeek());
EXPECT_EQ(Date(MonthOfYear::Jan, 1), epwFile.startDate());
EXPECT_EQ(Date(MonthOfYear::Dec, 31), epwFile.endDate());
// Up to here, everything should be the same as the first test. Now ask for the data
std::vector<EpwDataPoint> data = epwFile.data();
EXPECT_EQ(8760,data.size());
// The last data point should be on 12/31/1996, with a dry bulb temp of 4C and presure 81100
EXPECT_EQ(4.0,data[8759].dryBulbTemperature().get());
EXPECT_EQ(81100,data[8759].atmosphericStationPressure().get());
// Try out the alternate access functions, dew point temperature should be -1C
EXPECT_EQ(-1.0,data[8759].fieldByName("Dew Point Temperature").get());
EXPECT_EQ(-1.0,data[8759].field(EpwDataField("Dew Point Temperature")).get());
// The last data point should not have a liquid precipitation depth
EXPECT_FALSE(data[8759].fieldByName("Liquid Precipitation Depth"));
// Get a time series
boost::optional<openstudio::TimeSeries> series = epwFile.getTimeSeries("Wind Speed");
ASSERT_TRUE(series);
ASSERT_EQ(8760,series->values().size());
DateTimeVector seriesTimes = series->dateTimes();
ASSERT_EQ(8760,seriesTimes.size());
// Check the times in the data and the time series
DateTime current(Date(1,1,1999),Time(0,1)); // Use 1999 to avoid leap years
Time delta(0,1);
for(unsigned i=0;i<8760;i++) {
// This is a lot more complicated that it probably should be to avoid the year being a problem
DateTime datatime = data[i].dateTime();
EXPECT_EQ(datatime.date().monthOfYear(), current.date().monthOfYear());
EXPECT_EQ(datatime.date().dayOfMonth(), current.date().dayOfMonth());
EXPECT_EQ(datatime.time().hours(), current.time().hours());
EXPECT_EQ(datatime.time().minutes(), current.time().minutes());
DateTime seriestime = seriesTimes[i];
EXPECT_EQ(seriestime.date().monthOfYear(), current.date().monthOfYear());
EXPECT_EQ(seriestime.date().dayOfMonth(), current.date().dayOfMonth());
EXPECT_EQ(seriestime.time().hours(), current.time().hours());
EXPECT_EQ(seriestime.time().minutes(), current.time().minutes());
current += delta;
}
// We should redo the original tests because we have reparsed the entire file
EXPECT_EQ(p, epwFile.path());
EXPECT_EQ("F188656D", epwFile.checksum());
EXPECT_EQ("Denver Centennial Golden Nr", epwFile.city());
EXPECT_EQ("CO", epwFile.stateProvinceRegion());
EXPECT_EQ("USA", epwFile.country());
EXPECT_EQ("TMY3", epwFile.dataSource());
EXPECT_EQ("724666", epwFile.wmoNumber());
EXPECT_EQ(39.74, epwFile.latitude());
EXPECT_EQ(-105.18, epwFile.longitude());
EXPECT_EQ(-7, epwFile.timeZone());
EXPECT_EQ(1829, epwFile.elevation());
EXPECT_EQ(Time(0,1,0,0), epwFile.timeStep());
EXPECT_EQ(DayOfWeek(DayOfWeek::Sunday), epwFile.startDayOfWeek());
EXPECT_EQ(Date(MonthOfYear::Jan, 1), epwFile.startDate());
EXPECT_EQ(Date(MonthOfYear::Dec, 31), epwFile.endDate());
}catch(...){
ASSERT_TRUE(false);
}
}
TEST_F(DataFixture,TimeSeries_DetailedConstructor_WrapAroundDates)
{
std::string units = "W";
Date startDate(MonthOfYear(MonthOfYear::Jan),1);
// fill vector with 365 days of data
Vector values(365);
DateTimeVector dateTimes;
for (unsigned i = 0; i < 365; ++i){
values(i) = i;
dateTimes.push_back(startDate + Time(i+1,0,0,0));
}
unsigned numValues = values.size();
ASSERT_EQ(365u, numValues);
ASSERT_EQ(365u, dateTimes.size());
EXPECT_EQ(DateTime(Date(MonthOfYear(MonthOfYear::Jan), 1), Time(1,0,0,0)), dateTimes[0].date());
EXPECT_EQ(DateTime(Date(MonthOfYear(MonthOfYear::Dec), 31), Time(1,0,0,0)), dateTimes[364].date());
// create detailed timeSeries
TimeSeries timeSeries(dateTimes, values, units);
ASSERT_EQ(365u, timeSeries.values().size());
// check interval
EXPECT_FALSE(timeSeries.intervalLength());
// check start date and time
DateTime firstDateTime = timeSeries.firstReportDateTime();
EXPECT_EQ(DateTime(Date(MonthOfYear(MonthOfYear::Jan), 1), Time(1,0,0,0)), firstDateTime);
// check values
for (unsigned i = 0; i < numValues; ++i){
DateTime dateTime = dateTimes[i];
EXPECT_EQ(i, timeSeries.value(dateTime)) << dateTime;
}
Vector test = timeSeries.values(DateTime(Date(MonthOfYear(MonthOfYear::Apr), 1), Time(1,0,0,0)), DateTime(Date(MonthOfYear(MonthOfYear::Apr), 30), Time(1,0,0,0)));
ASSERT_EQ(30, test.size());
for (unsigned i = 0; i < 30; ++i){
EXPECT_EQ(i + 90, test[i]);
}
// now rearrange date times to make a wrap around year
Vector wrappedValues(365);
DateTimeVector wrappedDateTimes;
unsigned j = 0;
for (unsigned i = 100; i < 365; ++i, ++j){
wrappedValues[j] = values[i];
wrappedDateTimes.push_back(dateTimes[i]);
}
for (unsigned i = 0; i < 100; ++i, ++j){
wrappedValues[j] = values[i];
wrappedDateTimes.push_back(dateTimes[i]);
}
ASSERT_EQ(365u, wrappedValues.size());
ASSERT_EQ(365u, wrappedDateTimes.size());
EXPECT_EQ(100, wrappedValues[0]);
EXPECT_EQ(99, wrappedValues[364]);
EXPECT_EQ(DateTime(Date(MonthOfYear(MonthOfYear::Apr), 11), Time(1,0,0,0)), wrappedDateTimes[0].date());
EXPECT_EQ(DateTime(Date(MonthOfYear(MonthOfYear::Apr), 10), Time(1,0,0,0)), wrappedDateTimes[364].date());
// create detailed timeSeries
TimeSeries wrappedTimeSeries(wrappedDateTimes, wrappedValues, units);
ASSERT_EQ(365u, wrappedTimeSeries.values().size());
// check interval
EXPECT_FALSE(wrappedTimeSeries.intervalLength());
// check start date and time
firstDateTime = wrappedTimeSeries.firstReportDateTime();
EXPECT_EQ(DateTime(Date(MonthOfYear(MonthOfYear::Apr), 11), Time(1,0,0,0)), firstDateTime);
// check values
for (unsigned i = 0; i < numValues; ++i){
DateTime dateTime = dateTimes[i];
EXPECT_EQ(i, wrappedTimeSeries.value(dateTime)) << dateTime;
}
test = timeSeries.values(DateTime(Date(MonthOfYear(MonthOfYear::Apr), 1), Time(1,0,0,0)), DateTime(Date(MonthOfYear(MonthOfYear::Apr), 30), Time(1,0,0,0)));
ASSERT_EQ(30, test.size());
for (unsigned i = 0; i < 30; ++i){
EXPECT_EQ(i + 90, test[i]);
}
}
