public static void CalculatePiezometricHeadAtExit_CompleteInput_InputSetOnSubCalculator() { // Setup RoundedDouble assessmentLevel = new Random(21).NextRoundedDouble(); var validPipingCalculation = SemiProbabilisticPipingCalculationTestFactory.CreateCalculationWithValidInput <TestSemiProbabilisticPipingCalculation>( new TestHydraulicBoundaryLocation()); PipingInput input = validPipingCalculation.InputParameters; using (new PipingSubCalculatorFactoryConfig()) { // Call InputParameterCalculationService.CalculatePiezometricHeadAtExit( assessmentLevel, SemiProbabilisticPipingDesignVariableFactory.GetDampingFactorExit(input).GetDesignValue(), PipingDesignVariableFactory.GetPhreaticLevelExit(input).GetDesignValue()); // Assert var testFactory = (TestPipingSubCalculatorFactory)PipingSubCalculatorFactory.Instance; PiezoHeadCalculatorStub piezometricHeadAtExitCalculator = testFactory.LastCreatedPiezometricHeadAtExitCalculator; Assert.AreEqual(assessmentLevel.Value, piezometricHeadAtExitCalculator.HRiver); Assert.AreEqual(PipingDesignVariableFactory.GetPhreaticLevelExit(input).GetDesignValue(), piezometricHeadAtExitCalculator.PhiPolder, input.PhreaticLevelExit.GetAccuracy()); Assert.AreEqual(SemiProbabilisticPipingDesignVariableFactory.GetDampingFactorExit(input).GetDesignValue(), piezometricHeadAtExitCalculator.RExit, input.DampingFactorExit.GetAccuracy()); } }
public void Finish_ValidPipingCalculationAndRan_NotifyObserversOfPipingCalculation() { // Setup var mocks = new MockRepository(); var observer = mocks.StrictMock <IObserver>(); observer.Expect(o => o.UpdateObserver()); mocks.ReplayAll(); var validPipingCalculation = SemiProbabilisticPipingCalculationTestFactory.CreateCalculationWithValidInput <TestSemiProbabilisticPipingCalculation>( new TestHydraulicBoundaryLocation()); validPipingCalculation.Output = null; validPipingCalculation.Attach(observer); var activity = new SemiProbabilisticPipingCalculationActivity(validPipingCalculation, new GeneralPipingInput(), AssessmentSectionTestHelper.GetTestAssessmentLevel()); activity.Run(); // Call activity.Finish(); // Assert mocks.VerifyAll(); }
public static void CalculateEffectiveThicknessCoverageLayer_CompleteInput_InputSetOnSubCalculator() { // Setup var validPipingCalculation = SemiProbabilisticPipingCalculationTestFactory.CreateCalculationWithValidInput <TestSemiProbabilisticPipingCalculation>( new TestHydraulicBoundaryLocation()); PipingInput input = validPipingCalculation.InputParameters; var generalInput = new GeneralPipingInput(); using (new PipingSubCalculatorFactoryConfig()) { // Call PipingInput inputParameters = validPipingCalculation.InputParameters; InputParameterCalculationService.CalculateEffectiveThicknessCoverageLayer( generalInput.WaterVolumetricWeight, PipingDesignVariableFactory.GetPhreaticLevelExit(inputParameters).GetDesignValue(), inputParameters.ExitPointL, inputParameters.SurfaceLine, inputParameters.StochasticSoilProfile.SoilProfile); // Assert var testFactory = (TestPipingSubCalculatorFactory)PipingSubCalculatorFactory.Instance; EffectiveThicknessCalculatorStub effectiveThicknessCalculator = testFactory.LastCreatedEffectiveThicknessCalculator; Assert.AreEqual(input.ExitPointL.Value, effectiveThicknessCalculator.ExitPointXCoordinate); Assert.AreEqual(PipingDesignVariableFactory.GetPhreaticLevelExit(input).GetDesignValue(), effectiveThicknessCalculator.PhreaticLevel, input.PhreaticLevelExit.GetAccuracy()); AssertEqualSoilProfiles(input.StochasticSoilProfile.SoilProfile, effectiveThicknessCalculator.SoilProfile); AssertEqualSurfaceLines(input.SurfaceLine, effectiveThicknessCalculator.SurfaceLine); Assert.AreEqual(generalInput.WaterVolumetricWeight, effectiveThicknessCalculator.VolumicWeightOfWater); } }
public void Run_ValidPipingCalculation_PerformPipingValidationAndCalculationAndLogStartAndEnd() { // Setup var validPipingCalculation = SemiProbabilisticPipingCalculationTestFactory.CreateCalculationWithValidInput <TestSemiProbabilisticPipingCalculation>( new TestHydraulicBoundaryLocation()); var activity = new SemiProbabilisticPipingCalculationActivity(validPipingCalculation, new GeneralPipingInput(), AssessmentSectionTestHelper.GetTestAssessmentLevel()); // Call Action call = () => activity.Run(); // Assert TestHelper.AssertLogMessages(call, messages => { string[] msgs = messages.ToArray(); Assert.AreEqual(5, msgs.Length); Assert.AreEqual($"Uitvoeren van berekening '{validPipingCalculation.Name}' is gestart.", msgs[0]); CalculationServiceTestHelper.AssertValidationStartMessage(msgs[1]); CalculationServiceTestHelper.AssertValidationEndMessage(msgs[2]); CalculationServiceTestHelper.AssertCalculationStartMessage(msgs[3]); CalculationServiceTestHelper.AssertCalculationEndMessage(msgs[4]); }); Assert.AreEqual(ActivityState.Executed, activity.State); Assert.IsNotNull(validPipingCalculation.Output); }
public void GivenViewWithCalculationGroupData_WhenCalculationGroupUpdatedAndNotified_ThenMapDataUpdated() { // Given var failureMechanism = new PipingFailureMechanism(); PipingFailureMechanismView view = CreateView(failureMechanism, new AssessmentSectionStub()); IMapControl map = ((RiskeerMapControl)view.Controls[0]).MapControl; var surfaceLineA = new PipingSurfaceLine(string.Empty); surfaceLineA.SetGeometry(new[] { new Point3D(0.0, 0.0, 1.0), new Point3D(3.0, 0.0, 1.7) }); var surfaceLineB = new PipingSurfaceLine(string.Empty); surfaceLineB.SetGeometry(new[] { new Point3D(0.0, 0.0, 1.5), new Point3D(3.0, 0.0, 1.8) }); surfaceLineA.ReferenceLineIntersectionWorldPoint = new Point2D(1.3, 1.3); surfaceLineB.ReferenceLineIntersectionWorldPoint = new Point2D(1.5, 1.5); var calculationA = SemiProbabilisticPipingCalculationTestFactory.CreateCalculationWithValidInput <SemiProbabilisticPipingCalculationScenario>( new TestHydraulicBoundaryLocation()); var calculationB = ProbabilisticPipingCalculationTestFactory.CreateCalculationWithValidInput <ProbabilisticPipingCalculationScenario>( new TestHydraulicBoundaryLocation()); calculationA.InputParameters.SurfaceLine = surfaceLineA; calculationB.InputParameters.SurfaceLine = surfaceLineB; failureMechanism.CalculationsGroup.Children.Add(calculationA); failureMechanism.CalculationsGroup.Children.Add(calculationB); var probabilisticCalculationMapData = (MapLineData)map.Data.Collection.ElementAt(probabilisticCalculationsIndex); var semiProbabilisticCalculationMapData = (MapLineData)map.Data.Collection.ElementAt(semiProbabilisticCalculationsIndex); var mocks = new MockRepository(); IObserver[] observers = AttachMapDataObservers(mocks, map.Data.Collection); observers[semiProbabilisticCalculationObserverIndex].Expect(obs => obs.UpdateObserver()); observers[probabilisticCalculationObserverIndex].Expect(obs => obs.UpdateObserver()); mocks.ReplayAll(); // When failureMechanism.CalculationsGroup.Children.Add(calculationB); failureMechanism.CalculationsGroup.NotifyObservers(); // Then AssertSemiProbabilisticCalculationsMapData(failureMechanism.Calculations.OfType <SemiProbabilisticPipingCalculationScenario>(), semiProbabilisticCalculationMapData); AssertProbabilisticCalculationsMapData(failureMechanism.Calculations.OfType <ProbabilisticPipingCalculationScenario>(), probabilisticCalculationMapData); mocks.VerifyAll(); }
private static void AddSemiProbabilisticPipingCalculationScenario(AssessmentSection assessmentSection, HydraulicBoundaryLocation hydraulicBoundaryLocation) { var pipingCalculationScenario = SemiProbabilisticPipingCalculationTestFactory.CreateCalculationWithValidInput <SemiProbabilisticPipingCalculationScenario>( hydraulicBoundaryLocation); pipingCalculationScenario.InputParameters.UseAssessmentLevelManualInput = true; pipingCalculationScenario.InputParameters.AssessmentLevel = new Random(39).NextRoundedDouble(); assessmentSection.Piping.CalculationsGroup.Children.Add(pipingCalculationScenario); }
public void CreateSemiProbabilisticPipingCalculationActivity_WithValidCalculation_ReturnsActivityWithParametersSet() { // Setup var hydraulicBoundaryLocation = new TestHydraulicBoundaryLocation(); var assessmentSection = new AssessmentSectionStub { FailureMechanismContribution = { NormativeProbabilityType = NormativeProbabilityType.MaximumAllowableFloodingProbability } }; assessmentSection.SetHydraulicBoundaryLocationCalculations(new[] { hydraulicBoundaryLocation }); var random = new Random(39); HydraulicBoundaryLocationCalculation hydraulicBoundaryLocationCalculation = assessmentSection.WaterLevelCalculationsForMaximumAllowableFloodingProbability.Single(); hydraulicBoundaryLocationCalculation.Output = new TestHydraulicBoundaryLocationCalculationOutput(random.NextDouble()); var calculation = SemiProbabilisticPipingCalculationTestFactory.CreateCalculationWithValidInput <TestSemiProbabilisticPipingCalculation>( hydraulicBoundaryLocation); var generalPipingInput = new GeneralPipingInput(); // Call CalculatableActivity activity = PipingCalculationActivityFactory.CreateSemiProbabilisticPipingCalculationActivity(calculation, generalPipingInput, assessmentSection); // Assert Assert.IsInstanceOf <SemiProbabilisticPipingCalculationActivity>(activity); AssertSemiProbabilisticPipingCalculationActivity(activity, calculation, hydraulicBoundaryLocationCalculation); }
public static void CalculateEffectiveThicknessCoverageLayer_InvalidPipingCalculationWithOutput_ReturnsNaN() { // Setup var invalidPipingCalculation = SemiProbabilisticPipingCalculationTestFactory.CreateCalculationWithValidInput <TestSemiProbabilisticPipingCalculation>( new TestHydraulicBoundaryLocation()); // Make invalid by having surface line partially above soil profile: double highestLevelSurfaceLine = invalidPipingCalculation.InputParameters.SurfaceLine.Points.Max(p => p.Z); double soilProfileTop = highestLevelSurfaceLine - 0.5; double soilProfileBottom = soilProfileTop - 0.5; invalidPipingCalculation.InputParameters.StochasticSoilProfile = new PipingStochasticSoilProfile( 0.0, new PipingSoilProfile("A", soilProfileBottom, new[] { new PipingSoilLayer(soilProfileTop) { IsAquifer = true } }, SoilProfileType.SoilProfile1D)); var generalInput = new GeneralPipingInput(); // Call PipingInput input = invalidPipingCalculation.InputParameters; double result = InputParameterCalculationService.CalculateEffectiveThicknessCoverageLayer( generalInput.WaterVolumetricWeight, PipingDesignVariableFactory.GetPhreaticLevelExit(input).GetDesignValue(), input.ExitPointL, input.SurfaceLine, input.StochasticSoilProfile.SoilProfile); // Assert Assert.IsNaN(result); }
public void Constructor_WithAllData_DataUpdatedToCollectionOfFilledMapData() { // Setup PipingStochasticSoilModel stochasticSoilModel1 = PipingStochasticSoilModelTestFactory.CreatePipingStochasticSoilModel("name1", new[] { new Point2D(1.0, 2.0), new Point2D(1.1, 2.2) }); PipingStochasticSoilModel stochasticSoilModel2 = PipingStochasticSoilModelTestFactory.CreatePipingStochasticSoilModel("name2", new[] { new Point2D(3.0, 4.0), new Point2D(3.3, 4.4) }); var surfaceLineA = new PipingSurfaceLine("Line A"); surfaceLineA.SetGeometry(new[] { new Point3D(0.0, 0.0, 1.0), new Point3D(3.0, 0.0, 1.7) }); var surfaceLineB = new PipingSurfaceLine("Name B"); surfaceLineB.SetGeometry(new[] { new Point3D(0.0, 0.0, 1.5), new Point3D(3.0, 0.0, 1.8) }); surfaceLineA.ReferenceLineIntersectionWorldPoint = new Point2D(1.3, 1.3); surfaceLineB.ReferenceLineIntersectionWorldPoint = new Point2D(1.5, 1.5); var failureMechanism = new PipingFailureMechanism(); const string arbitraryFilePath = "path"; var geometryPoints = new[] { new Point2D(0.0, 0.0), new Point2D(2.0, 0.0), new Point2D(4.0, 4.0), new Point2D(6.0, 4.0) }; failureMechanism.SurfaceLines.AddRange(new[] { surfaceLineA, surfaceLineB }, arbitraryFilePath); FailureMechanismTestHelper.SetSections(failureMechanism, new[] { new FailureMechanismSection("A", geometryPoints.Take(2)), new FailureMechanismSection("B", geometryPoints.Skip(1).Take(2)), new FailureMechanismSection("C", geometryPoints.Skip(2).Take(2)) }); failureMechanism.StochasticSoilModels.AddRange(new[] { stochasticSoilModel1, stochasticSoilModel2 }, arbitraryFilePath); var hydraulicBoundaryLocation1 = new HydraulicBoundaryLocation(1, "test", 1.0, 2.0); var hydraulicBoundaryLocation2 = new HydraulicBoundaryLocation(2, "test", 3.0, 4.0); var calculationA = SemiProbabilisticPipingCalculationTestFactory.CreateCalculationWithValidInput <SemiProbabilisticPipingCalculationScenario>( hydraulicBoundaryLocation1); var calculationB = ProbabilisticPipingCalculationTestFactory.CreateCalculationWithValidInput <ProbabilisticPipingCalculationScenario>( hydraulicBoundaryLocation2); calculationA.InputParameters.SurfaceLine = surfaceLineA; calculationB.InputParameters.SurfaceLine = surfaceLineB; failureMechanism.CalculationsGroup.Children.Add(calculationA); failureMechanism.CalculationsGroup.Children.Add(calculationB); var referenceLine = new ReferenceLine(); referenceLine.SetGeometry(new[] { new Point2D(0.0, 3.0), new Point2D(3.0, 0.0) }); var assessmentSection = new AssessmentSectionStub { ReferenceLine = referenceLine }; assessmentSection.SetHydraulicBoundaryLocationCalculations(new[] { hydraulicBoundaryLocation1, hydraulicBoundaryLocation2 }); using (new AssemblyToolCalculatorFactoryConfig()) { // Call PipingFailureMechanismView view = CreateView(failureMechanism, assessmentSection); IMapControl map = ((RiskeerMapControl)view.Controls[0]).MapControl; // Assert MapDataCollection mapData = map.Data; Assert.IsInstanceOf <MapDataCollection>(mapData); List <MapData> mapDataList = mapData.Collection.ToList(); Assert.AreEqual(8, mapDataList.Count); MapDataTestHelper.AssertReferenceLineMapData(assessmentSection.ReferenceLine, mapDataList[referenceLineIndex]); AssertSurfaceLinesMapData(failureMechanism.SurfaceLines, mapDataList[surfaceLinesIndex]); IEnumerable <MapData> sectionsCollection = ((MapDataCollection)mapDataList[sectionsCollectionIndex]).Collection; MapDataTestHelper.AssertFailureMechanismSectionsMapData(failureMechanism.Sections, sectionsCollection.ElementAt(sectionsIndex)); MapDataTestHelper.AssertFailureMechanismSectionsStartPointMapData(failureMechanism.Sections, sectionsCollection.ElementAt(sectionsStartPointIndex)); MapDataTestHelper.AssertFailureMechanismSectionsEndPointMapData(failureMechanism.Sections, sectionsCollection.ElementAt(sectionsEndPointIndex)); MapDataTestHelper.AssertHydraulicBoundaryLocationsMapData(assessmentSection, mapDataList[hydraulicBoundaryLocationsIndex]); AssertStochasticSoilModelsMapData(failureMechanism.StochasticSoilModels, mapDataList[stochasticSoilModelsIndex]); AssertProbabilisticCalculationsMapData(failureMechanism.Calculations.OfType <ProbabilisticPipingCalculationScenario>(), mapDataList[probabilisticCalculationsIndex]); AssertSemiProbabilisticCalculationsMapData(failureMechanism.Calculations.OfType <SemiProbabilisticPipingCalculationScenario>(), mapDataList[semiProbabilisticCalculationsIndex]); var calculatorFactory = (TestAssemblyToolCalculatorFactory)AssemblyToolCalculatorFactory.Instance; FailureMechanismSectionAssemblyCalculatorStub calculator = calculatorFactory.LastCreatedFailureMechanismSectionAssemblyCalculator; MapDataTestHelper.AssertAssemblyMapData(failureMechanism, calculator.FailureMechanismSectionAssemblyResultOutput.AssemblyResult, mapDataList[assemblyResultsIndex]); } }
public void CreateCalculationActivitiesForFailureMechanism_WithValidCalculations_ReturnsPipingCalculationActivitiesWithParametersSet() { // Setup var assessmentSection = new AssessmentSectionStub { FailureMechanismContribution = { NormativeProbabilityType = NormativeProbabilityType.MaximumAllowableFloodingProbability } }; var hydraulicBoundaryLocation1 = new TestHydraulicBoundaryLocation(); var hydraulicBoundaryLocation2 = new TestHydraulicBoundaryLocation(); TestPipingFailureMechanism failureMechanism = TestPipingFailureMechanism.GetFailureMechanismWithSurfaceLinesAndStochasticSoilModels(); assessmentSection.SetHydraulicBoundaryLocationCalculations(new[] { hydraulicBoundaryLocation1, hydraulicBoundaryLocation2 }); assessmentSection.HydraulicBoundaryDatabase.FilePath = validHydraulicBoundaryDatabaseFilePath; HydraulicBoundaryDatabaseTestHelper.SetHydraulicBoundaryLocationConfigurationSettings(assessmentSection.HydraulicBoundaryDatabase); var random = new Random(39); HydraulicBoundaryLocationCalculation hydraulicBoundaryLocationCalculation1 = assessmentSection.WaterLevelCalculationsForMaximumAllowableFloodingProbability.First(); hydraulicBoundaryLocationCalculation1.Output = new TestHydraulicBoundaryLocationCalculationOutput(random.NextDouble()); HydraulicBoundaryLocationCalculation hydraulicBoundaryLocationCalculation2 = assessmentSection.WaterLevelCalculationsForMaximumAllowableFloodingProbability.ElementAt(1); hydraulicBoundaryLocationCalculation2.Output = new TestHydraulicBoundaryLocationCalculationOutput(random.NextDouble()); var calculation1 = SemiProbabilisticPipingCalculationTestFactory.CreateCalculationWithValidInput <TestSemiProbabilisticPipingCalculation>( hydraulicBoundaryLocation1); var calculation2 = ProbabilisticPipingCalculationTestFactory.CreateCalculationWithValidInput <TestProbabilisticPipingCalculation>( hydraulicBoundaryLocation1); var calculation3 = SemiProbabilisticPipingCalculationTestFactory.CreateCalculationWithValidInput <TestSemiProbabilisticPipingCalculation>( hydraulicBoundaryLocation2); var calculation4 = ProbabilisticPipingCalculationTestFactory.CreateCalculationWithValidInput <TestProbabilisticPipingCalculation>( hydraulicBoundaryLocation2); failureMechanism.CalculationsGroup.Children.AddRange(new IPipingCalculation <PipingInput>[] { calculation1, calculation2, calculation3, calculation4 }); // Call IEnumerable <CalculatableActivity> activities = PipingCalculationActivityFactory.CreateCalculationActivities( failureMechanism, assessmentSection); // Assert Assert.AreEqual(4, activities.Count()); CalculatableActivity activity1 = activities.ElementAt(0); Assert.IsInstanceOf <SemiProbabilisticPipingCalculationActivity>(activity1); AssertSemiProbabilisticPipingCalculationActivity(activity1, calculation1, hydraulicBoundaryLocationCalculation1); CalculatableActivity activity2 = activities.ElementAt(1); Assert.IsInstanceOf <ProbabilisticPipingCalculationActivity>(activity2); AssertProbabilisticPipingCalculationActivity(activity2, calculation2, hydraulicBoundaryLocation1); CalculatableActivity activity3 = activities.ElementAt(2); Assert.IsInstanceOf <SemiProbabilisticPipingCalculationActivity>(activity3); AssertSemiProbabilisticPipingCalculationActivity(activity3, calculation3, hydraulicBoundaryLocationCalculation2); CalculatableActivity activity4 = activities.ElementAt(3); Assert.IsInstanceOf <ProbabilisticPipingCalculationActivity>(activity4); AssertProbabilisticPipingCalculationActivity(activity4, calculation4, hydraulicBoundaryLocation2); }
public void ContextMenuStrip_ClickOnCalculateAllItem_ScheduleAllChildCalculations() { // Setup using (var treeViewControl = new TreeViewControl()) { var assessmentSection = new AssessmentSectionStub(); var hydraulicBoundaryLocation = new TestHydraulicBoundaryLocation(); TestPipingFailureMechanism failureMechanism = TestPipingFailureMechanism.GetFailureMechanismWithSurfaceLinesAndStochasticSoilModels(); assessmentSection.HydraulicBoundaryDatabase.FilePath = validHydraulicBoundaryDatabaseFilePath; HydraulicBoundaryDatabaseTestHelper.SetHydraulicBoundaryLocationConfigurationSettings(assessmentSection.HydraulicBoundaryDatabase); assessmentSection.SetHydraulicBoundaryLocationCalculations(new[] { hydraulicBoundaryLocation }, true); var calculationA = SemiProbabilisticPipingCalculationTestFactory.CreateCalculationWithValidInput <SemiProbabilisticPipingCalculationScenario>( hydraulicBoundaryLocation); var calculationB = SemiProbabilisticPipingCalculationTestFactory.CreateCalculationWithValidInput <SemiProbabilisticPipingCalculationScenario>( hydraulicBoundaryLocation); var calculationC = ProbabilisticPipingCalculationTestFactory.CreateCalculationWithValidInput <ProbabilisticPipingCalculationScenario>( hydraulicBoundaryLocation); var calculationD = ProbabilisticPipingCalculationTestFactory.CreateCalculationWithValidInput <ProbabilisticPipingCalculationScenario>( hydraulicBoundaryLocation); calculationA.Name = "A"; calculationB.Name = "B"; calculationC.Name = "C"; calculationD.Name = "D"; failureMechanism.CalculationsGroup.Children.Add(calculationA); failureMechanism.CalculationsGroup.Children.Add(calculationC); failureMechanism.CalculationsGroup.Children.Add(calculationB); failureMechanism.CalculationsGroup.Children.Add(calculationD); var context = new PipingFailureMechanismContext(failureMechanism, assessmentSection); var menuBuilder = new CustomItemsOnlyContextMenuBuilder(); IMainWindow mainWindow = MainWindowTestHelper.CreateMainWindowStub(mocks); var gui = mocks.Stub <IGui>(); gui.Stub(g => g.MainWindow).Return(mainWindow); gui.Stub(g => g.Get(context, treeViewControl)).Return(menuBuilder); var calculatorFactory = mocks.Stub <IHydraRingCalculatorFactory>(); calculatorFactory.Stub(cf => cf.CreatePipingCalculator(null)) .IgnoreArguments() .Return(new TestPipingCalculator()); mocks.ReplayAll(); plugin.Gui = gui; DialogBoxHandler = (name, wnd) => { // Expect an activity dialog which is automatically closed }; using (new PipingSubCalculatorFactoryConfig()) using (new HydraRingCalculatorFactoryConfig(calculatorFactory)) using (ContextMenuStrip contextMenu = info.ContextMenuStrip(context, null, treeViewControl)) { // Call void Call() => contextMenu.Items[contextMenuCalculateAllIndex].PerformClick(); // Assert TestHelper.AssertLogMessages(Call, messages => { string[] msgs = messages.ToArray(); Assert.AreEqual(28, msgs.Length); Assert.AreEqual("Uitvoeren van berekening 'A' is gestart.", msgs[0]); CalculationServiceTestHelper.AssertValidationStartMessage(msgs[1]); CalculationServiceTestHelper.AssertValidationEndMessage(msgs[2]); CalculationServiceTestHelper.AssertCalculationStartMessage(msgs[3]); CalculationServiceTestHelper.AssertCalculationEndMessage(msgs[4]); Assert.AreEqual("Uitvoeren van berekening 'A' is gelukt.", msgs[5]); Assert.AreEqual("Uitvoeren van berekening 'C' is gestart.", msgs[6]); CalculationServiceTestHelper.AssertValidationStartMessage(msgs[7]); CalculationServiceTestHelper.AssertValidationEndMessage(msgs[8]); CalculationServiceTestHelper.AssertCalculationStartMessage(msgs[9]); CalculationServiceTestHelper.AssertCalculationEndMessage(msgs[12]); Assert.AreEqual("Uitvoeren van berekening 'C' is gelukt.", msgs[13]); Assert.AreEqual("Uitvoeren van berekening 'B' is gestart.", msgs[14]); CalculationServiceTestHelper.AssertValidationStartMessage(msgs[15]); CalculationServiceTestHelper.AssertValidationEndMessage(msgs[16]); CalculationServiceTestHelper.AssertCalculationStartMessage(msgs[17]); CalculationServiceTestHelper.AssertCalculationEndMessage(msgs[18]); Assert.AreEqual("Uitvoeren van berekening 'B' is gelukt.", msgs[19]); Assert.AreEqual("Uitvoeren van berekening 'D' is gestart.", msgs[20]); CalculationServiceTestHelper.AssertValidationStartMessage(msgs[21]); CalculationServiceTestHelper.AssertValidationEndMessage(msgs[22]); CalculationServiceTestHelper.AssertCalculationStartMessage(msgs[23]); CalculationServiceTestHelper.AssertCalculationEndMessage(msgs[26]); Assert.AreEqual("Uitvoeren van berekening 'D' is gelukt.", msgs[27]); }); } } }
public void ContextMenuStrip_ClickOnValidateAllItem_ValidateAllChildCalculations() { // Setup using (var treeViewControl = new TreeViewControl()) { var assessmentSection = new AssessmentSectionStub(); var hydraulicBoundaryLocation = new TestHydraulicBoundaryLocation(); TestPipingFailureMechanism failureMechanism = TestPipingFailureMechanism.GetFailureMechanismWithSurfaceLinesAndStochasticSoilModels(); assessmentSection.HydraulicBoundaryDatabase.FilePath = validHydraulicBoundaryDatabaseFilePath; HydraulicBoundaryDatabaseTestHelper.SetHydraulicBoundaryLocationConfigurationSettings(assessmentSection.HydraulicBoundaryDatabase); assessmentSection.SetHydraulicBoundaryLocationCalculations(new[] { hydraulicBoundaryLocation }, true); var validSemiProbabilisticCalculation = SemiProbabilisticPipingCalculationTestFactory.CreateCalculationWithValidInput <SemiProbabilisticPipingCalculationScenario>( hydraulicBoundaryLocation); var invalidSemiProbabilisticCalculation = SemiProbabilisticPipingCalculationTestFactory.CreateCalculationWithInvalidInput <SemiProbabilisticPipingCalculationScenario>(); var validProbabilisticCalculation = ProbabilisticPipingCalculationTestFactory.CreateCalculationWithValidInput <ProbabilisticPipingCalculationScenario>( hydraulicBoundaryLocation); var invalidProbabilisticCalculation = ProbabilisticPipingCalculationTestFactory.CreateCalculationWithInvalidInput <ProbabilisticPipingCalculationScenario>(); failureMechanism.CalculationsGroup.Children.Add(validSemiProbabilisticCalculation); failureMechanism.CalculationsGroup.Children.Add(invalidProbabilisticCalculation); failureMechanism.CalculationsGroup.Children.Add(validProbabilisticCalculation); failureMechanism.CalculationsGroup.Children.Add(invalidSemiProbabilisticCalculation); var context = new PipingFailureMechanismContext(failureMechanism, assessmentSection); var menuBuilder = new CustomItemsOnlyContextMenuBuilder(); var gui = mocks.Stub <IGui>(); gui.Stub(g => g.Get(context, treeViewControl)).Return(menuBuilder); gui.Stub(cmp => cmp.MainWindow).Return(mocks.Stub <IMainWindow>()); mocks.ReplayAll(); plugin.Gui = gui; using (ContextMenuStrip contextMenu = info.ContextMenuStrip(context, null, treeViewControl)) { // Call void Call() => contextMenu.Items[contextMenuValidateAllIndex].PerformClick(); // Assert TestHelper.AssertLogMessages(Call, messages => { string[] msgs = messages.ToArray(); Assert.AreEqual(18, msgs.Length); CalculationServiceTestHelper.AssertValidationStartMessage(msgs[0]); CalculationServiceTestHelper.AssertValidationEndMessage(msgs[1]); CalculationServiceTestHelper.AssertValidationStartMessage(msgs[2]); CalculationServiceTestHelper.AssertValidationEndMessage(msgs[8]); CalculationServiceTestHelper.AssertValidationStartMessage(msgs[9]); CalculationServiceTestHelper.AssertValidationEndMessage(msgs[10]); CalculationServiceTestHelper.AssertValidationStartMessage(msgs[11]); CalculationServiceTestHelper.AssertValidationEndMessage(msgs[17]); }); } } }