void StopWatcher::onDataPointComplete(const UUID &dataPoint) { ++m_nComplete; if (m_nComplete == m_stopNum) { AnalysisDriver driver = analysisDriver(); CurrentAnalysisVector currentAnalyses = driver.currentAnalyses(); ASSERT_FALSE(currentAnalyses.empty()); EXPECT_EQ(1u,currentAnalyses.size()); CurrentAnalysis currentAnalysis = currentAnalyses[0]; openstudio::Time start = openstudio::Time::currentTime(); driver.stop(currentAnalysis); m_stoppingTime = openstudio::Time::currentTime() - start; } }
TEST_F(AnalysisDriverFixture, DDACE_MonteCarlo_Continuous) { // RETRIEVE PROBLEM Problem problem = retrieveProblem("Continuous",true,false); // DEFINE SEED Model model = model::exampleModel(); openstudio::path p = toPath("./example.osm"); model.save(p,true); FileReference seedModel(p); // CREATE ANALYSIS DDACEAlgorithmOptions algOptions(DDACEAlgorithmType::random); Analysis analysis("DDACE Monte Carlo Sampling", problem, DDACEAlgorithm(algOptions), seedModel); // RUN ANALYSIS { ProjectDatabase database = getCleanDatabase("DDACEMonteCarlo_Continuous_NoSamples"); AnalysisDriver analysisDriver(database); AnalysisRunOptions runOptions = standardRunOptions(analysisDriver.database().path().parent_path()); CurrentAnalysis currentAnalysis = analysisDriver.run(analysis,runOptions); EXPECT_TRUE(analysisDriver.waitForFinished()); boost::optional<runmanager::JobErrors> jobErrors = currentAnalysis.dakotaJobErrors(); ASSERT_TRUE(jobErrors); EXPECT_FALSE(jobErrors->errors().empty()); // require specification of number of samples EXPECT_TRUE(analysisDriver.currentAnalyses().empty()); Table summary = currentAnalysis.analysis().summaryTable(); EXPECT_EQ(1u,summary.nRows()); // no points } { algOptions.setSamples(6); analysis = Analysis("DDACE MonteCarlo Sampling", problem, DDACEAlgorithm(algOptions), seedModel); ProjectDatabase database = getCleanDatabase("DDACEMonteCarlo_Continuous"); AnalysisDriver analysisDriver = AnalysisDriver(database); AnalysisRunOptions runOptions = standardRunOptions(analysisDriver.database().path().parent_path()); runOptions.setQueueSize(4); CurrentAnalysis currentAnalysis = analysisDriver.run(analysis,runOptions); EXPECT_TRUE(analysisDriver.waitForFinished()); boost::optional<runmanager::JobErrors> jobErrors = currentAnalysis.dakotaJobErrors(); ASSERT_TRUE(jobErrors); EXPECT_TRUE(jobErrors->errors().empty()); EXPECT_TRUE(analysisDriver.currentAnalyses().empty()); Table summary = currentAnalysis.analysis().summaryTable(); EXPECT_EQ(7u,summary.nRows()); // 6 points summary.save(analysisDriver.database().path().parent_path() / toPath("summary.csv")); BOOST_FOREACH(const DataPoint& dataPoint,analysis.dataPoints()) { EXPECT_TRUE(dataPoint.isComplete()); EXPECT_FALSE(dataPoint.failed()); // EXPECT_FALSE(dataPoint.responseValues().empty()); } } }
TEST_F(AnalysisDriverFixture, DDACE_MonteCarlo_MixedOsmIdf_ProjectDatabaseOpen) { // RETRIEVE PROBLEM Problem problem = retrieveProblem("MixedOsmIdf",false,false); // DEFINE SEED Model model = model::exampleModel(); openstudio::path p = toPath("./example.osm"); model.save(p,true); FileReference seedModel(p); // CREATE ANALYSIS DDACEAlgorithmOptions algOptions(DDACEAlgorithmType::oas); algOptions.setSamples(4); Analysis analysis("DDACE Monte Carlo Sampling", problem, DDACEAlgorithm(algOptions), seedModel); // RUN ANALYSIS { analysis = Analysis("DDACE Monte Carlo Sampling - MixedOsmIdf", problem, DDACEAlgorithm(algOptions), seedModel); ProjectDatabase database = getCleanDatabase("DDACEMonteCarlo_MixedOsmIdf"); AnalysisDriver analysisDriver = AnalysisDriver(database); AnalysisRunOptions runOptions = standardRunOptions(analysisDriver.database().path().parent_path()); CurrentAnalysis currentAnalysis = analysisDriver.run(analysis,runOptions); EXPECT_TRUE(analysisDriver.waitForFinished()); boost::optional<runmanager::JobErrors> jobErrors = currentAnalysis.dakotaJobErrors(); ASSERT_TRUE(jobErrors); EXPECT_TRUE(jobErrors->errors().empty()); EXPECT_TRUE(analysisDriver.currentAnalyses().empty()); Table summary = currentAnalysis.analysis().summaryTable(); EXPECT_EQ(5u,summary.nRows()); // 4 points summary.save(analysisDriver.database().path().parent_path() / toPath("summary.csv")); BOOST_FOREACH(const DataPoint& dataPoint,analysis.dataPoints()) { EXPECT_TRUE(dataPoint.isComplete()); EXPECT_FALSE(dataPoint.failed()); } } { project::OptionalProjectDatabase oDatabase = project::ProjectDatabase::open(toPath("AnalysisDriverFixtureData/DDACEMonteCarloMixedOsmIdf/DDACEMonteCarlo_MixedOsmIdf.osp")); ASSERT_TRUE(oDatabase); project::AnalysisRecordVector analysisRecords = project::AnalysisRecord::getAnalysisRecords(*oDatabase); EXPECT_EQ(1u,analysisRecords.size()); if (!analysisRecords.empty()) { EXPECT_NO_THROW(analysisRecords[0].analysis()); } } }
TEST_F(AnalysisDriverFixture, FSUDace_CVT_MixedOsmIdf) { // RETRIEVE PROBLEM Problem problem = retrieveProblem("MixedOsmIdf",false,false); // DEFINE SEED Model model = model::exampleModel(); openstudio::path p = toPath("./example.osm"); model.save(p,true); FileReference seedModel(p); // CREATE ANALYSIS FSUDaceAlgorithmOptions algOptions(FSUDaceAlgorithmType::cvt); algOptions.setSamples(3); Analysis analysis("FSUDace CVT", problem, FSUDaceAlgorithm(algOptions), seedModel); // RUN ANALYSIS analysis = Analysis("FSUDace CVT - MixedOsmIdf", problem, FSUDaceAlgorithm(algOptions), seedModel); ProjectDatabase database = getCleanDatabase("FSUDaceCVT_MixedOsmIdf"); AnalysisDriver analysisDriver = AnalysisDriver(database); AnalysisRunOptions runOptions = standardRunOptions(analysisDriver.database().path().parent_path()); CurrentAnalysis currentAnalysis = analysisDriver.run(analysis,runOptions); EXPECT_TRUE(analysisDriver.waitForFinished()); boost::optional<runmanager::JobErrors> jobErrors = currentAnalysis.dakotaJobErrors(); ASSERT_TRUE(jobErrors); EXPECT_TRUE(jobErrors->errors().empty()); EXPECT_TRUE(analysisDriver.currentAnalyses().empty()); Table summary = currentAnalysis.analysis().summaryTable(); // EXPECT_EQ(10u,summary.nRows()); // 9 points summary.save(analysisDriver.database().path().parent_path() / toPath("summary.csv")); BOOST_FOREACH(const DataPoint& dataPoint,analysis.dataPoints()) { EXPECT_TRUE(dataPoint.isComplete()); EXPECT_FALSE(dataPoint.failed()); } }
TEST_F(AnalysisDriverFixture, DDACE_LatinHypercube_UserScriptContinuous) { // RETRIEVE PROBLEM Problem problem = retrieveProblem("UserScriptContinuous",true,false); // DEFINE SEED Model model = model::exampleModel(); openstudio::path p = toPath("./example.osm"); model.save(p,true); FileReference seedModel(p); // CREATE ANALYSIS DDACEAlgorithmOptions algOptions(DDACEAlgorithmType::lhs); algOptions.setSamples(10); // RUN ANALYSIS Analysis analysis("DDACE Latin Hypercube Sampling - UserScriptContinuous", problem, DDACEAlgorithm(algOptions), seedModel); ProjectDatabase database = getCleanDatabase("DDACELatinHypercube_UserScriptContinuous"); AnalysisDriver analysisDriver = AnalysisDriver(database); AnalysisRunOptions runOptions = standardRunOptions(analysisDriver.database().path().parent_path()); CurrentAnalysis currentAnalysis = analysisDriver.run(analysis,runOptions); EXPECT_TRUE(analysisDriver.waitForFinished()); boost::optional<runmanager::JobErrors> jobErrors = currentAnalysis.dakotaJobErrors(); ASSERT_TRUE(jobErrors); EXPECT_TRUE(jobErrors->errors().empty()); EXPECT_TRUE(analysisDriver.currentAnalyses().empty()); Table summary = currentAnalysis.analysis().summaryTable(); EXPECT_EQ(11u,summary.nRows()); summary.save(analysisDriver.database().path().parent_path() / toPath("summary.csv")); BOOST_FOREACH(const DataPoint& dataPoint,analysis.dataPoints()) { EXPECT_TRUE(dataPoint.isComplete()); EXPECT_FALSE(dataPoint.failed()); } }
TEST_F(AnalysisDriverFixture, DesignOfExperiments_MeshAnalysis) { openstudio::path rubyLibDirPath = openstudio::toPath(rubyLibDir()); // GET SIMPLE PROJECT SimpleProject project = getCleanSimpleProject("DesignOfExperiments_MeshAnalysis"); Analysis analysis = project.analysis(); // SET PROBLEM Problem problem = retrieveProblem("MixedOsmIdf",false,false); analysis.setProblem(problem); // SET SEED Model model = model::exampleModel(); openstudio::path p = toPath("./example.osm"); model.save(p,true); FileReference seedModel(p); analysis.setSeed(seedModel); // SET ALGORITHM DesignOfExperimentsOptions algOptions(DesignOfExperimentsType::FullFactorial); DesignOfExperiments algorithm(algOptions); analysis.setAlgorithm(algorithm); // RUN ANALYSIS AnalysisDriver driver = project.analysisDriver(); AnalysisRunOptions runOptions = standardRunOptions(project.projectDir()); driver.run(analysis,runOptions); EXPECT_TRUE(driver.waitForFinished()); // CHECK RESULTS AnalysisRecord analysisRecord = project.analysisRecord(); EXPECT_EQ(4,analysisRecord.problemRecord().combinatorialSize(true).get()); EXPECT_EQ(4u, analysisRecord.dataPointRecords().size()); BOOST_FOREACH(const DataPointRecord& dataPointRecord, analysisRecord.dataPointRecords()) { EXPECT_TRUE(dataPointRecord.isComplete()); EXPECT_FALSE(dataPointRecord.failed()); } // get data points by perturbations and vice versa std::vector<DataPointRecord> testDataPoints; std::vector<QVariant> testVariableValues; // all data points are successful testDataPoints = analysisRecord.successfulDataPointRecords(); EXPECT_EQ(4u,testDataPoints.size()); // empty variableValues returns all data points testDataPoints = analysisRecord.getDataPointRecords(testVariableValues); EXPECT_EQ(4u, testDataPoints.size()); // find the baseline testVariableValues.clear(); testVariableValues.push_back(0); testVariableValues.push_back(QVariant(QVariant::Int)); // only one perturbation, null works too testVariableValues.push_back(0); ASSERT_TRUE(testVariableValues[1].isNull()); testDataPoints = analysisRecord.getDataPointRecords(testVariableValues); ASSERT_EQ(1u, testDataPoints.size()); // find model with improved wall and roof testVariableValues.clear(); testVariableValues.push_back(1); testVariableValues.push_back(0); testVariableValues.push_back(1); testDataPoints = analysisRecord.getDataPointRecords(testVariableValues); ASSERT_EQ(1u, testDataPoints.size()); DataPoint testDataPoint = testDataPoints[0].dataPoint(); std::vector<OptionalDiscretePerturbation> perturbations = analysis.problem().getDiscretePerturbations(testVariableValues); ASSERT_EQ(3u,perturbations.size()); ASSERT_TRUE(perturbations[0] && perturbations[1] && perturbations[2]); EXPECT_TRUE(perturbations[0]->uuid() == problem.variables()[0].cast<DiscreteVariable>().perturbations(false)[1].uuid()); EXPECT_TRUE(perturbations[1]->uuid() == problem.variables()[1].cast<DiscreteVariable>().perturbations(false)[0].uuid()); EXPECT_TRUE(perturbations[2]->uuid() == problem.variables()[2].cast<DiscreteVariable>().perturbations(false)[1].uuid()); EXPECT_TRUE(perturbations[0]->optionalCast<RubyPerturbation>()); EXPECT_TRUE(perturbations[1]->optionalCast<RubyPerturbation>()); EXPECT_TRUE(perturbations[2]->optionalCast<RubyPerturbation>()); // find models with improved wall testVariableValues.clear(); testVariableValues.push_back(1); testDataPoints = analysisRecord.getDataPointRecords(testVariableValues); ASSERT_EQ(2u, testDataPoints.size()); // infeasible testVariableValues.clear(); testVariableValues.push_back(0); testVariableValues.push_back(0); testVariableValues.push_back(0); testVariableValues.push_back(0); testDataPoints = analysisRecord.getDataPointRecords(testVariableValues); ASSERT_EQ(0u, testDataPoints.size()); }
TEST_F(AnalysisDriverFixture, DDACE_LatinHypercube_MixedOsmIdf_MoveProjectDatabase) { openstudio::path oldDir, newDir; { // GET SIMPLE PROJECT SimpleProject project = getCleanSimpleProject("DDACE_LatinHypercube_MixedOsmIdf"); Analysis analysis = project.analysis(); analysis.setName("DDACE Latin Hypercube Sampling - MixedOsmIdf"); // SET PROBLEM Problem problem = retrieveProblem("MixedOsmIdf",false,false); analysis.setProblem(problem); // SET SEED Model model = model::exampleModel(); openstudio::path p = toPath("./example.osm"); model.save(p,true); FileReference seedModel(p); analysis.setSeed(seedModel); // SET ALGORITHM DDACEAlgorithmOptions algOptions(DDACEAlgorithmType::lhs); algOptions.setSamples(12); // test reprinting results.out for copies of same point DDACEAlgorithm algorithm(algOptions); analysis.setAlgorithm(algorithm); // RUN ANALYSIS AnalysisDriver driver = project.analysisDriver(); AnalysisRunOptions runOptions = standardRunOptions(project.projectDir()); CurrentAnalysis currentAnalysis = driver.run(analysis,runOptions); EXPECT_TRUE(driver.waitForFinished()); boost::optional<runmanager::JobErrors> jobErrors = currentAnalysis.dakotaJobErrors(); ASSERT_TRUE(jobErrors); EXPECT_TRUE(jobErrors->errors().empty()); EXPECT_TRUE(driver.currentAnalyses().empty()); Table summary = analysis.summaryTable(); EXPECT_EQ(5u,summary.nRows()); // 4 points (all combinations) summary.save(project.projectDir() / toPath("summary.csv")); EXPECT_EQ(4u,analysis.dataPoints().size()); BOOST_FOREACH(const DataPoint& dataPoint,analysis.dataPoints()) { EXPECT_TRUE(dataPoint.isComplete()); EXPECT_FALSE(dataPoint.failed()); EXPECT_TRUE(dataPoint.workspace()); // should be able to load data from disk } oldDir = project.projectDir(); newDir = project.projectDir().parent_path() / toPath("DDACELatinHypercubeMixedOsmIdfCopy"); // Make copy of project boost::filesystem::remove_all(newDir); ASSERT_TRUE(project.saveAs(newDir)); } // Blow away old project. // TODO: Reinstate. This was failing on Windows and isn't absolutely necessary. // try { // boost::filesystem::remove_all(oldDir); // } // catch (std::exception& e) { // EXPECT_TRUE(false) << "Boost filesystem was unable to delete the old folder, because " << e.what(); // } // Open new project SimpleProject project = getSimpleProject("DDACE_LatinHypercube_MixedOsmIdf_Copy"); EXPECT_TRUE(project.projectDir() == newDir); EXPECT_EQ(toString(newDir),toString(project.projectDir())); // After move, should be able to retrieve results. EXPECT_FALSE(project.analysisIsLoaded()); Analysis analysis = project.analysis(); EXPECT_TRUE(project.analysisIsLoaded()); EXPECT_EQ(4u,analysis.dataPoints().size()); BOOST_FOREACH(const DataPoint& dataPoint,analysis.dataPoints()) { EXPECT_TRUE(dataPoint.isComplete()); EXPECT_FALSE(dataPoint.failed()); LOG(Debug,"Attempting to load workspace for data point at '" << dataPoint.directory() << "'."); if (dataPoint.idfInputData()) { LOG(Debug,"Says there should be input data at " << toString(dataPoint.idfInputData()->path())); } EXPECT_TRUE(dataPoint.workspace()); // should be able to load data from disk if (!dataPoint.workspace()) { LOG(Debug,"Unsuccessful.") } } // Should be able to blow away results and run again project.removeAllDataPoints(); EXPECT_EQ(0u,analysis.dataPoints().size()); EXPECT_FALSE(analysis.algorithm()->isComplete()); EXPECT_FALSE(analysis.algorithm()->failed()); EXPECT_EQ(-1,analysis.algorithm()->iter()); EXPECT_FALSE(analysis.algorithm()->cast<DakotaAlgorithm>().restartFileReference()); EXPECT_FALSE(analysis.algorithm()->cast<DakotaAlgorithm>().outFileReference()); AnalysisRunOptions runOptions = standardRunOptions(project.projectDir()); AnalysisDriver driver = project.analysisDriver(); CurrentAnalysis currentAnalysis = driver.run(analysis,runOptions); EXPECT_TRUE(driver.waitForFinished()); boost::optional<runmanager::JobErrors> jobErrors = currentAnalysis.dakotaJobErrors(); ASSERT_TRUE(jobErrors); EXPECT_TRUE(jobErrors->errors().empty()); EXPECT_TRUE(driver.currentAnalyses().empty()); Table summary = analysis.summaryTable(); EXPECT_EQ(5u,summary.nRows()); // 4 points (all combinations) summary.save(project.projectDir() / toPath("summary.csv")); BOOST_FOREACH(const DataPoint& dataPoint,analysis.dataPoints()) { EXPECT_TRUE(dataPoint.isComplete()); EXPECT_FALSE(dataPoint.failed()); EXPECT_TRUE(dataPoint.workspace()); // should be able to load data from disk } }
TEST_F(AnalysisDriverFixture, DDACE_LatinHypercube_Continuous) { { // GET SIMPLE PROJECT SimpleProject project = getCleanSimpleProject("DDACE_LatinHypercube_Continuous"); Analysis analysis = project.analysis(); // SET PROBLEM Problem problem = retrieveProblem("Continuous",true,false); analysis.setProblem(problem); // DEFINE SEED Model model = model::exampleModel(); openstudio::path p = toPath("./example.osm"); model.save(p,true); FileReference seedModel(p); analysis.setSeed(seedModel); // CREATE ANALYSIS DDACEAlgorithmOptions algOptions(DDACEAlgorithmType::lhs); DDACEAlgorithm algorithm(algOptions); analysis.setAlgorithm(algorithm); // RUN ANALYSIS AnalysisDriver driver = project.analysisDriver(); AnalysisRunOptions runOptions = standardRunOptions(project.projectDir()); CurrentAnalysis currentAnalysis = driver.run(analysis,runOptions); EXPECT_TRUE(driver.waitForFinished()); boost::optional<runmanager::JobErrors> jobErrors = currentAnalysis.dakotaJobErrors(); ASSERT_TRUE(jobErrors); EXPECT_FALSE(jobErrors->errors().empty()); // require specification of number of samples EXPECT_TRUE(driver.currentAnalyses().empty()); Table summary = currentAnalysis.analysis().summaryTable(); EXPECT_EQ(1u,summary.nRows()); // no points project.clearAllResults(); algOptions.setSamples(4); EXPECT_EQ(4,analysis.algorithm()->cast<DDACEAlgorithm>().ddaceAlgorithmOptions().samples()); currentAnalysis = driver.run(analysis,runOptions); EXPECT_TRUE(driver.waitForFinished()); jobErrors = currentAnalysis.dakotaJobErrors(); ASSERT_TRUE(jobErrors); EXPECT_TRUE(jobErrors->errors().empty()); EXPECT_TRUE(driver.currentAnalyses().empty()); summary = currentAnalysis.analysis().summaryTable(); EXPECT_EQ(5u,summary.nRows()); summary.save(project.projectDir() / toPath("summary.csv")); BOOST_FOREACH(const DataPoint& dataPoint,analysis.dataPoints()) { EXPECT_TRUE(dataPoint.isComplete()); EXPECT_FALSE(dataPoint.failed()); // EXPECT_FALSE(dataPoint.responseValues().empty()); } ASSERT_TRUE(analysis.algorithm()); EXPECT_TRUE(analysis.algorithm()->isComplete()); EXPECT_FALSE(analysis.algorithm()->failed()); { AnalysisRecord analysisRecord = project.analysisRecord(); Analysis analysisCopy = analysisRecord.analysis(); ASSERT_TRUE(analysisCopy.algorithm()); EXPECT_TRUE(analysisCopy.algorithm()->isComplete()); EXPECT_FALSE(analysisCopy.algorithm()->failed()); } } LOG(Info,"Restart from existing project."); // Get existing project SimpleProject project = getSimpleProject("DDACE_LatinHypercube_Continuous"); EXPECT_FALSE(project.analysisIsLoaded()); // make sure starting fresh Analysis analysis = project.analysis(); EXPECT_FALSE(analysis.isDirty()); // Add custom data point std::vector<QVariant> values; values.push_back(0.0); values.push_back(0.8); values.push_back(int(0)); OptionalDataPoint dataPoint = analysis.problem().createDataPoint(values); ASSERT_TRUE(dataPoint); analysis.addDataPoint(*dataPoint); EXPECT_EQ(1u,analysis.dataPointsToQueue().size()); ASSERT_TRUE(analysis.algorithm()); EXPECT_TRUE(analysis.algorithm()->isComplete()); EXPECT_FALSE(analysis.algorithm()->failed()); EXPECT_TRUE(analysis.isDirty()); EXPECT_FALSE(analysis.resultsAreInvalid()); EXPECT_FALSE(analysis.dataPointsAreInvalid()); // get last modified time of a file in a completed data point to make sure nothing is re-run DataPointVector completePoints = analysis.completeDataPoints(); ASSERT_FALSE(completePoints.empty()); OptionalFileReference inputFileRef = completePoints[0].osmInputData(); ASSERT_TRUE(inputFileRef); QFileInfo inputFileInfo(toQString(inputFileRef->path())); QDateTime inputFileModifiedTestTime = inputFileInfo.lastModified(); EXPECT_EQ(1u,analysis.dataPointsToQueue().size()); AnalysisDriver driver = project.analysisDriver(); CurrentAnalysis currentAnalysis = driver.run( analysis, standardRunOptions(project.projectDir())); EXPECT_TRUE(driver.waitForFinished()); boost::optional<runmanager::JobErrors> jobErrors = currentAnalysis.dakotaJobErrors(); EXPECT_FALSE(jobErrors); // should not try to re-run DakotaAlgorithm EXPECT_TRUE(driver.currentAnalyses().empty()); EXPECT_TRUE(analysis.dataPointsToQueue().empty()); Table summary = currentAnalysis.analysis().summaryTable(); EXPECT_EQ(6u,summary.nRows()); summary.save(project.projectDir() / toPath("summary_post_restart.csv")); // RunManager should not re-run any data points EXPECT_EQ(inputFileModifiedTestTime,inputFileInfo.lastModified()); }
TEST_F(AnalysisDriverFixture, DDACE_Grid_Continuous) { // RETRIEVE PROBLEM Problem problem = retrieveProblem("Continuous",true,false); // DEFINE SEED Model model = model::exampleModel(); openstudio::path p = toPath("./example.osm"); model.save(p,true); FileReference seedModel(p); // CREATE ANALYSIS DDACEAlgorithmOptions algOptions(DDACEAlgorithmType::grid); Analysis analysis("DDACE Grid Sampling", problem, DDACEAlgorithm(algOptions), seedModel); // RUN ANALYSIS { ProjectDatabase database = getCleanDatabase("DDACEGridSampling_NoSamples"); AnalysisDriver analysisDriver(database); AnalysisRunOptions runOptions = standardRunOptions(analysisDriver.database().path().parent_path()); runOptions.setQueueSize(4); CurrentAnalysis currentAnalysis = analysisDriver.run(analysis,runOptions); EXPECT_TRUE(analysisDriver.waitForFinished()); boost::optional<runmanager::JobErrors> jobErrors = currentAnalysis.dakotaJobErrors(); ASSERT_TRUE(jobErrors); EXPECT_FALSE(jobErrors->errors().empty()); // require specification of number of samples EXPECT_TRUE(analysisDriver.currentAnalyses().empty()); Table summary = currentAnalysis.analysis().summaryTable(); EXPECT_EQ(1u,summary.nRows()); // no points } // ETH@20120120 At first tried just using the same database, analysisdriver, etc., but // it did not go well. Restarting an initially failed Dakota analysis should be part of // enabling Dakota restart more generally. { // algorithm rounds samples up to next one that fits n**(problem.numVariables()) algOptions.setSamples(6); analysis = Analysis("DDACE Grid Sampling - Wrong Samples", problem, DDACEAlgorithm(algOptions), seedModel); ProjectDatabase database = getCleanDatabase("DDACEGridSampling_WrongSamples"); AnalysisDriver analysisDriver = AnalysisDriver(database); AnalysisRunOptions runOptions = standardRunOptions(analysisDriver.database().path().parent_path()); CurrentAnalysis currentAnalysis = analysisDriver.run(analysis,runOptions); EXPECT_TRUE(analysisDriver.waitForFinished()); boost::optional<runmanager::JobErrors> jobErrors = currentAnalysis.dakotaJobErrors(); ASSERT_TRUE(jobErrors); EXPECT_TRUE(jobErrors->errors().empty()); EXPECT_TRUE(analysisDriver.currentAnalyses().empty()); Table summary = currentAnalysis.analysis().summaryTable(); EXPECT_EQ(10u,summary.nRows()); // 9 points summary.save(analysisDriver.database().path().parent_path() / toPath("summary.csv")); BOOST_FOREACH(const DataPoint& dataPoint,analysis.dataPoints()) { EXPECT_TRUE(dataPoint.isComplete()); EXPECT_FALSE(dataPoint.failed()); // EXPECT_FALSE(dataPoint.responseValues().empty()); } } { // algorithm rounds samples up to next one that fits n**(problem.numVariables()) algOptions.setSamplesForGrid(2,problem); analysis = Analysis("DDACE Grid Sampling - Correct Samples", problem, DDACEAlgorithm(algOptions), seedModel); ProjectDatabase database = getCleanDatabase("DDACEGridSampling_CorrectSamples"); AnalysisDriver analysisDriver = AnalysisDriver(database); AnalysisRunOptions runOptions = standardRunOptions(analysisDriver.database().path().parent_path()); CurrentAnalysis currentAnalysis = analysisDriver.run(analysis,runOptions); EXPECT_TRUE(analysisDriver.waitForFinished()); boost::optional<runmanager::JobErrors> jobErrors = currentAnalysis.dakotaJobErrors(); ASSERT_TRUE(jobErrors); EXPECT_TRUE(jobErrors->errors().empty()); EXPECT_TRUE(analysisDriver.currentAnalyses().empty()); Table summary = currentAnalysis.analysis().summaryTable(); EXPECT_EQ(5u,summary.nRows()); // 4 points summary.save(analysisDriver.database().path().parent_path() / toPath("summary.csv")); BOOST_FOREACH(const DataPoint& dataPoint,analysis.dataPoints()) { EXPECT_TRUE(dataPoint.isComplete()); EXPECT_FALSE(dataPoint.failed()); // EXPECT_FALSE(dataPoint.responseValues().empty()); } } }
TEST_F(AnalysisDriverFixture, DDACE_OrthogonalArray_Continuous) { // RETRIEVE PROBLEM Problem problem = retrieveProblem("Continuous",true,false); // DEFINE SEED Model model = model::exampleModel(); openstudio::path p = toPath("./example.osm"); model.save(p,true); FileReference seedModel(p); // CREATE ANALYSIS DDACEAlgorithmOptions algOptions(DDACEAlgorithmType::oas); Analysis analysis("DDACE Orthogonal Array Sampling", problem, DDACEAlgorithm(algOptions), seedModel); // RUN ANALYSIS { ProjectDatabase database = getCleanDatabase("DDACEOrthogonalArray_NoSamples"); AnalysisDriver analysisDriver(database); AnalysisRunOptions runOptions = standardRunOptions(analysisDriver.database().path().parent_path()); CurrentAnalysis currentAnalysis = analysisDriver.run(analysis,runOptions); EXPECT_TRUE(analysisDriver.waitForFinished()); boost::optional<runmanager::JobErrors> jobErrors = currentAnalysis.dakotaJobErrors(); ASSERT_TRUE(jobErrors); EXPECT_FALSE(jobErrors->errors().empty()); // require specification of number of samples EXPECT_TRUE(analysisDriver.currentAnalyses().empty()); Table summary = currentAnalysis.analysis().summaryTable(); EXPECT_EQ(1u,summary.nRows()); // no points } { algOptions.setSamples(6); // symbols = 0 analysis = Analysis("DDACE Orthogonal Array Sampling - Wrong Samples", problem, DDACEAlgorithm(algOptions), seedModel); ProjectDatabase database = getCleanDatabase("DDACEOrthogonalArray_WrongSamples"); AnalysisDriver analysisDriver = AnalysisDriver(database); AnalysisRunOptions runOptions = standardRunOptions(analysisDriver.database().path().parent_path()); CurrentAnalysis currentAnalysis = analysisDriver.run(analysis,runOptions); EXPECT_TRUE(analysisDriver.waitForFinished()); boost::optional<runmanager::JobErrors> jobErrors = currentAnalysis.dakotaJobErrors(); ASSERT_TRUE(jobErrors); EXPECT_TRUE(jobErrors->errors().empty()); EXPECT_TRUE(analysisDriver.currentAnalyses().empty()); Table summary = currentAnalysis.analysis().summaryTable(); EXPECT_EQ(10u,summary.nRows()); // 9 points summary.save(analysisDriver.database().path().parent_path() / toPath("summary.csv")); BOOST_FOREACH(const DataPoint& dataPoint,analysis.dataPoints()) { EXPECT_TRUE(dataPoint.isComplete()); EXPECT_FALSE(dataPoint.failed()); // EXPECT_FALSE(dataPoint.responseValues().empty()); } } { bool ok = algOptions.setSamplesAndSymbolsForOrthogonalArray(6,1); EXPECT_FALSE(ok); ok = algOptions.setSamplesAndSymbolsForOrthogonalArray(2,2); // 2,3 not ok for no apparent reason EXPECT_TRUE(ok); ASSERT_TRUE(algOptions.symbols()); EXPECT_EQ(2,algOptions.symbols().get()); ASSERT_TRUE(algOptions.samples()); EXPECT_EQ(8,algOptions.samples().get()); analysis = Analysis("DDACE Orthogonal Array Sampling - Correct Samples", problem, DDACEAlgorithm(algOptions), seedModel); ProjectDatabase database = getCleanDatabase("DDACEOrthogonalArray_CorrectSamples"); AnalysisDriver analysisDriver = AnalysisDriver(database); AnalysisRunOptions runOptions = standardRunOptions(analysisDriver.database().path().parent_path()); CurrentAnalysis currentAnalysis = analysisDriver.run(analysis,runOptions); EXPECT_TRUE(analysisDriver.waitForFinished()); boost::optional<runmanager::JobErrors> jobErrors = currentAnalysis.dakotaJobErrors(); ASSERT_TRUE(jobErrors); EXPECT_TRUE(jobErrors->errors().empty()); EXPECT_TRUE(analysisDriver.currentAnalyses().empty()); Table summary = currentAnalysis.analysis().summaryTable(); EXPECT_EQ(9u,summary.nRows()); summary.save(analysisDriver.database().path().parent_path() / toPath("summary.csv")); BOOST_FOREACH(const DataPoint& dataPoint,analysis.dataPoints()) { EXPECT_TRUE(dataPoint.isComplete()); EXPECT_FALSE(dataPoint.failed()); } } }