// ----------------------------------------------------------------------------- // // ----------------------------------------------------------------------------- void TestSyntheticBuilder() { MXADir::mkdir(m_OutputDirectory, true); Observer* observer = new Observer; int err = 0; // Create our Pipeline object FilterPipeline::Pointer pipeline = FilterPipeline::New(); VoxelDataContainer::Pointer m = VoxelDataContainer::New(); pipeline->setVoxelDataContainer(m); ShapeTypeArrayType::Pointer m_ShapeTypes = ShapeTypeArrayType::CreateArray(4, DREAM3D::EnsembleData::ShapeTypes); m_ShapeTypes->SetValue(0, DREAM3D::ShapeType::UnknownShapeType); m_ShapeTypes->SetValue(1, DREAM3D::ShapeType::EllipsoidShape); m_ShapeTypes->SetValue(2, DREAM3D::ShapeType::EllipsoidShape); m_ShapeTypes->SetValue(3, DREAM3D::ShapeType::EllipsoidShape); InitializeSyntheticVolume::Pointer init_volume = InitializeSyntheticVolume::New(); init_volume->setShapeTypes(m_ShapeTypes); init_volume->setInputFile(getH5StatsFile()); init_volume->setXVoxels(m_XPoints); init_volume->setYVoxels(m_YPoints); init_volume->setZVoxels(m_ZPoints); init_volume->setXRes(m_XResolution); init_volume->setYRes(m_YResolution); init_volume->setZRes(m_ZResolution); pipeline->pushBack(init_volume); PackPrimaryPhases::Pointer pack_grains = PackPrimaryPhases::New(); pack_grains->setPeriodicBoundaries(m_PeriodicBoundary); pack_grains->setNeighborhoodErrorWeight(m_NeighborhoodErrorWeight); #if PACK_GRAINS_ERROR_TXT_OUT MAKE_OUTPUT_FILE_PATH( errorFile, DREAM3D::SyntheticBuilder::ErrorFile) pack_grains->setErrorOutputFile(errorFile); #endif #if PACK_GRAINS_VTK_FILE_OUT MAKE_OUTPUT_FILE_PATH( vtkFile, DREAM3D::SyntheticBuilder::VtkFile) pack_grains->setVtkOutputFile(vtkFile); #endif pipeline->pushBack(pack_grains); AdjustVolume::Pointer adjust_grains = AdjustVolume::New(); pipeline->pushBack(adjust_grains); InsertPrecipitatePhases::Pointer place_precipitates = InsertPrecipitatePhases::New(); place_precipitates->setPeriodicBoundaries(m_PeriodicBoundary); pipeline->pushBack(place_precipitates); MatchCrystallography::Pointer match_crystallography = MatchCrystallography::New(); // pipeline->pushBack(match_crystallography); FieldDataCSVWriter::Pointer write_fielddata = FieldDataCSVWriter::New(); write_fielddata->setFieldDataFile(UnitTest::SyntheticBuilderTest::CsvFile); pipeline->pushBack(write_fielddata); DataContainerWriter::Pointer writer = DataContainerWriter::New(); writer->setOutputFile(UnitTest::SyntheticBuilderTest::OutputFile); pipeline->pushBack(writer); bool m_WriteVtkFile(true); bool m_WriteBinaryVTKFiles(true); bool m_WritePhaseId(true); bool m_WriteIPFColor(false); if(m_WriteVtkFile) { VtkRectilinearGridWriter::Pointer vtkWriter = VtkRectilinearGridWriter::New(); vtkWriter->setOutputFile(UnitTest::SyntheticBuilderTest::VtkOutputFile); vtkWriter->setWriteGrainIds(true); vtkWriter->setWritePhaseIds(m_WritePhaseId); // vtkWriter->setWriteGoodVoxels(m_WriteGoodVoxels); vtkWriter->setWriteIPFColors(m_WriteIPFColor); vtkWriter->setWriteBinaryFile(m_WriteBinaryVTKFiles); pipeline->pushBack(vtkWriter); } std::cout << "********* RUNNING PIPELINE **********************" << std::endl; m = VoxelDataContainer::New(); pipeline->setVoxelDataContainer(m); pipeline->run(); err = pipeline->getErrorCondition(); DREAM3D_REQUIRE_EQUAL(err, 0); DREAM3D_REQUIRE_EQUAL(false, pipeline->empty()); pipeline->clear(); DREAM3D_REQUIRE_EQUAL(0, pipeline->size()); DREAM3D_REQUIRE_EQUAL(true, pipeline->empty()); delete observer; }
void CropVolumePipeline::execute() { VoxelDataContainer* m = getVoxelDataContainer(); float m_MisorientationTolerance = 5.0f; float m_AlignMisorientationTolerance = 5.0f; float m_Zres = 4.0f; int m_MinAllowedGrainSize = 10; int m_MinNumNeighbors = 1; int m_PhaseNumberMinSize = 1; int m_NumIterations_Erode = 3; int NUM_OF_CROPS = getNumLinesinFile(m_InputFile); std::vector<int> m_Xmin(NUM_OF_CROPS+1, 0); std::vector<int> m_Ymin(NUM_OF_CROPS+1, 0); std::vector<int> m_Zmin(NUM_OF_CROPS+1, 0); std::vector<int> m_Xmax(NUM_OF_CROPS+1, 0); std::vector<int> m_Ymax(NUM_OF_CROPS+1, 0); std::vector<int> m_Zmax(NUM_OF_CROPS+1, 0); get_max_and_min_xyz_for_crop(m_Xmax, m_Ymax, m_Zmax, m_Xmin, m_Ymin, m_Zmin); /* int m_Zmin = 1 ; int m_Xmax = 495; int m_Ymax = 355; int m_Zmax = 163;*/ for (DimType i = 1; i < NUM_OF_CROPS+1; i++) { // Create our Pipeline object FilterPipeline::Pointer pipeline = FilterPipeline::New(); // updateProgressAndMessage(("Loading Slices"), 10); ReadH5Ebsd::Pointer read_h5ebsd = ReadH5Ebsd::New(); read_h5ebsd->setH5EbsdFile(getH5EbsdFile()); //read_h5ebsd->setRefFrameZDir(Ebsd::LowtoHigh); read_h5ebsd->setZStartIndex(getZStartIndex()); read_h5ebsd->setZEndIndex(getZEndIndex()); read_h5ebsd->setPTypes(getPhaseTypes()); read_h5ebsd->setQualityMetricFilters(getQualityMetricFilters()); read_h5ebsd->setVoxelDataContainer(m); read_h5ebsd->execute(); pipeline->pushBack(read_h5ebsd); ConvertEulerAngles::Pointer convert_euler = ConvertEulerAngles::New(); convert_euler->setConversionType(DREAM3D::EulerAngleConversionType::DegreesToRadians); convert_euler->setVoxelDataContainer(m); convert_euler->execute(); pipeline->pushBack(convert_euler); AlignSectionsMisorientation::Pointer align_sections = AlignSectionsMisorientation::New(); align_sections->setMisorientationTolerance(m_AlignMisorientationTolerance); align_sections->setVoxelDataContainer(m); align_sections->execute(); pipeline->pushBack(align_sections); CropVolume::Pointer crop_volume = CropVolume::New(); crop_volume->setXMin(m_Xmin[i]); crop_volume->setYMin(m_Ymin[i]); crop_volume->setZMin(m_Zmin[i]); crop_volume->setXMax(m_Xmax[i]); crop_volume->setYMax(m_Ymax[i]); crop_volume->setZMax(m_Zmax[i]); crop_volume->setRenumberGrains(false); crop_volume->setVoxelDataContainer(m); crop_volume->execute(); pipeline->pushBack(crop_volume); RegularizeZSpacing::Pointer regularize_z = RegularizeZSpacing::New(); regularize_z->setInputFile(getZ_spacingfile()); regularize_z->setZRes(m_Zres); regularize_z->setVoxelDataContainer(m); regularize_z->execute(); pipeline->pushBack(regularize_z); EBSDSegmentGrains::Pointer ebsdsegment_grains = EBSDSegmentGrains::New(); ebsdsegment_grains->setMisorientationTolerance(m_MisorientationTolerance); ebsdsegment_grains->setVoxelDataContainer(m); ebsdsegment_grains->execute(); pipeline->pushBack(ebsdsegment_grains); OpenCloseBadData::Pointer erode_dilate = OpenCloseBadData::New(); erode_dilate->setDirection(1); // 1 is erode. erode_dilate->setNumIterations(m_NumIterations_Erode); erode_dilate->setVoxelDataContainer(m); erode_dilate->execute(); pipeline->pushBack(erode_dilate); FindNeighbors::Pointer find_neighbors = FindNeighbors::New(); find_neighbors->setVoxelDataContainer(m); find_neighbors->execute(); pipeline->pushBack(find_neighbors); PerPhaseMinSize::Pointer min_size = PerPhaseMinSize::New(); min_size->setMinAllowedGrainSize(m_MinAllowedGrainSize); min_size->setPhaseNumber(m_PhaseNumberMinSize); min_size->setVoxelDataContainer(m); min_size->execute(); pipeline->pushBack(min_size); MinNeighbors::Pointer min_neighbors = MinNeighbors::New(); min_neighbors->setMinNumNeighbors(m_MinNumNeighbors); min_neighbors->setVoxelDataContainer(m); min_neighbors->execute(); pipeline->pushBack(min_neighbors); FindSizes::Pointer find_sizes = FindSizes::New(); //find_sizes->setDistributionType(DREAM3D::DistributionType::Beta); find_sizes->setVoxelDataContainer(m); find_sizes->execute(); pipeline->pushBack(find_sizes); FindShapes::Pointer find_shapes = FindShapes::New(); //find_shapes->setDistributionType(DREAM3D::DistributionType::Beta); find_shapes->setVoxelDataContainer(m); find_shapes->execute(); pipeline->pushBack(find_shapes); FieldDataCSVWriter::Pointer field_data_write_csv = FieldDataCSVWriter::New(); std::string field_csv = "D:/IN100_run1/DREAM3D_files/crop_line_"+ convertIntToString(i) +".csv"; field_data_write_csv->setFieldDataFile(field_csv); field_data_write_csv->setVoxelDataContainer(m); field_data_write_csv->execute(); pipeline->pushBack(field_data_write_csv); bool m_WriteVtkFile = true ; bool m_WriteBinaryVTKFiles= true ; bool m_WriteGrainID= true; bool m_WritePhaseId= true ; bool m_WriteIPFColor= true ; bool m_WriteGoodVoxels= true ; bool m_WriteGrainSizes = true ; bool m_WriteBandContrasts = true ; VtkRectilinearGridWriter::Pointer vtkWriter = VtkRectilinearGridWriter::New(); if(m_WriteVtkFile) { std::string vtk_file = "D:/IN100_run1/DREAM3D_files/crop_line_" + convertIntToString(i) + ".vtk"; vtkWriter->setOutputFile(vtk_file); vtkWriter->setWriteGrainIds(m_WriteGrainID); vtkWriter->setWritePhaseIds(m_WritePhaseId); vtkWriter->setWriteBandContrasts(m_WriteBandContrasts); vtkWriter->setWriteGoodVoxels(m_WriteGoodVoxels); vtkWriter->setWriteIPFColors(m_WriteIPFColor); vtkWriter->setWriteBinaryFile(m_WriteBinaryVTKFiles); vtkWriter->setWriteBinaryFile(m_WriteGrainSizes); vtkWriter->setVoxelDataContainer(m); vtkWriter->execute(); pipeline->pushBack(vtkWriter); } DataContainerWriter::Pointer writer = DataContainerWriter::New(); std::string dream_3d_file = "D:/IN100_run1/DREAM3D_files/crop_line_" + convertIntToString(i) + ".dream3d"; writer->setOutputFile(dream_3d_file); writer->setVoxelDataContainer(m); pipeline->pushBack(writer); writer->execute(); // std::cout << "********* RUNNING PIPELINE **********************" << std::endl; // // pipeline->run(); pipeline->clear(); //delete [] m; m->clearCellData(); m->clearEnsembleData(); m->clearFieldData(); } }
// ----------------------------------------------------------------------------- // // ----------------------------------------------------------------------------- void FilterParametersRWTest() { // Create our Pipeline object FilterPipeline::Pointer pipeline = FilterPipeline::New(); GenericFilter::Pointer filt = GenericFilter::New(); // Set something for each and every property so you have something to compare against. // You may want to make some constants for these values filt->setStlFilePrefix(StlFilePrefixTestValue); filt->setMaxIterations(MaxIterationsTestValue); filt->setMisorientationTolerance(MisorientationToleranceTestValue); filt->setInputFile(InputFileTestValue); filt->setInputPath(InputPathTestValue); filt->setOutputFile(OutputFileTestValue); filt->setOutputPath(OutputPathTestValue); filt->setWriteAlignmentShifts(WriteAlignmentShiftsTestValue); filt->setConversionType(ConversionTypeTestValue); filt->setSelectedCellArrayName(SelectedCellArrayNameTestValue); filt->setSelectedFieldArrayName(SelectedFieldArrayNameTestValue); filt->setSelectedEnsembleArrayName(SelectedEnsembleArrayNameTestValue); filt->setSurfaceMeshPointArrayName(SurfaceMeshPointArrayNameTestValue); filt->setSurfaceMeshFaceArrayName(SurfaceMeshFaceArrayNameTestValue); filt->setSurfaceMeshEdgeArrayName(SurfaceMeshEdgeArrayNameTestValue); filt->setSolidMeshPointArrayName(SolidMeshPointArrayNameTestValue); filt->setSolidMeshFaceArrayName(SolidMeshFaceArrayNameTestValue); filt->setSolidMeshEdgeArrayName(SolidMeshEdgeArrayNameTestValue); ComparisonInput_t comparison1; comparison1.arrayName = Comparison1InputArrayNameTestValue; comparison1.compOperator = Comparison1CompOperatorTestValue; comparison1.compValue = Comparison1CompValueTestValue; ComparisonInput_t comparison2; comparison2.arrayName = Comparison2InputArrayNameTestValue; comparison2.compOperator = Comparison2CompOperatorTestValue; comparison2.compValue = Comparison2CompValueTestValue; std::vector<ComparisonInput_t> comparisonVector; comparisonVector.push_back(comparison1); comparisonVector.push_back(comparison2); filt->setCellComparisonInputs(comparisonVector); AxisAngleInput_t axisAngles1; axisAngles1.angle = AxisAngles1AngleTestValue; axisAngles1.h = AxisAngles1HTestValue; axisAngles1.k = AxisAngles1KTestValue; axisAngles1.l = AxisAngles1LTestValue; AxisAngleInput_t axisAngles2; axisAngles2.angle = AxisAngles2AngleTestValue; axisAngles2.h = AxisAngles2HTestValue; axisAngles2.k = AxisAngles2KTestValue; axisAngles2.l = AxisAngles2LTestValue; std::vector<AxisAngleInput_t> axisAngleInputsVector; axisAngleInputsVector.push_back(axisAngles1); axisAngleInputsVector.push_back(axisAngles2); filt->setAxisAngleRotations(axisAngleInputsVector); DataContainerWriter::Pointer writer = DataContainerWriter::New(); writer->setOutputFile(UnitTest::FilterParametersRWTest::OutputFile); pipeline->pushBack(filt); pipeline->pushBack(writer); pipeline->execute(); int err = pipeline->getErrorCondition(); DREAM3D_REQUIRED(err, >= , 0) // We are done writing a file, now we need to read the file using raw HDF5 codes hid_t fid = H5Utilities::openFile(UnitTest::FilterParametersRWTest::OutputFile); DREAM3D_REQUIRED(fid, >, 0) H5FilterParametersReader::Pointer reader = H5FilterParametersReader::New(); hid_t pipelineGroupId = H5Gopen(fid, DREAM3D::HDF5::PipelineGroupName.c_str(), H5P_DEFAULT); reader->setGroupId(pipelineGroupId); err = reader->openFilterGroup( filt.get(), 0); // Open the HDF5 Group for this filter DREAM3D_REQUIRED(err, >=, 0) // This next line should read all the filter parameters into the filter. filt->readFilterParameters( reader.get(), 0); // Now one by one, compare each of the filter parameters that you have stored in some constant somewhere to the values that are now in the filt variable. // Use DREAM3D_REQUIRED() to make sure each one is what you think it is. DREAM3D_REQUIRED(StlFilePrefixTestValue, ==, filt->getStlFilePrefix() ) DREAM3D_REQUIRED(MaxIterationsTestValue, ==, filt->getMaxIterations() ) DREAM3D_REQUIRED(MisorientationToleranceTestValue, ==, filt->getMisorientationTolerance() ) DREAM3D_REQUIRED(InputFileTestValue, ==, filt->getInputFile() ) DREAM3D_REQUIRED(InputPathTestValue, ==, filt->getInputPath() ) DREAM3D_REQUIRED(OutputFileTestValue, ==, filt->getOutputFile() ) DREAM3D_REQUIRED(OutputPathTestValue, ==, filt->getOutputPath() ) DREAM3D_REQUIRED(WriteAlignmentShiftsTestValue, ==, filt->getWriteAlignmentShifts() ) DREAM3D_REQUIRED(ConversionTypeTestValue, ==, filt->getConversionType() ) DREAM3D_REQUIRED(SelectedCellArrayNameTestValue, ==, filt->getSelectedCellArrayName() ) DREAM3D_REQUIRED(SelectedFieldArrayNameTestValue, ==, filt->getSelectedFieldArrayName() ) DREAM3D_REQUIRED(SelectedEnsembleArrayNameTestValue, ==, filt->getSelectedEnsembleArrayName() ) DREAM3D_REQUIRED(SurfaceMeshPointArrayNameTestValue, ==, filt->getSurfaceMeshPointArrayName() ) DREAM3D_REQUIRED(SurfaceMeshFaceArrayNameTestValue, ==, filt->getSurfaceMeshFaceArrayName() ) DREAM3D_REQUIRED(SurfaceMeshEdgeArrayNameTestValue, ==, filt->getSurfaceMeshEdgeArrayName() ) DREAM3D_REQUIRED(SolidMeshPointArrayNameTestValue, ==, filt->getSolidMeshPointArrayName() ) DREAM3D_REQUIRED(SolidMeshFaceArrayNameTestValue, ==, filt->getSolidMeshFaceArrayName() ) DREAM3D_REQUIRED(SolidMeshEdgeArrayNameTestValue, ==, filt->getSolidMeshEdgeArrayName() ) // Test the CellComparisonInputs widget std::vector<ComparisonInput_t> comparisonVectorRead = filt->getCellComparisonInputs(); ComparisonInput_t comparison1Read = comparisonVectorRead[0]; ComparisonInput_t comparison2Read = comparisonVectorRead[1]; DREAM3D_REQUIRED(comparison1.arrayName, ==, comparison1Read.arrayName) DREAM3D_REQUIRED(comparison1.compOperator, ==, comparison1Read.compOperator) DREAM3D_REQUIRED(comparison1.compValue, ==, comparison1Read.compValue) DREAM3D_REQUIRED(comparison2.arrayName, ==, comparison2Read.arrayName) DREAM3D_REQUIRED(comparison2.compOperator, ==, comparison2Read.compOperator) DREAM3D_REQUIRED(comparison2.compValue, ==, comparison2Read.compValue) // Test the AxisAngleInput widget std::vector<AxisAngleInput_t> axisAngleVectorRead = filt->getAxisAngleRotations(); AxisAngleInput_t axisAngles1Read = axisAngleVectorRead[0]; AxisAngleInput_t axisAngles2Read = axisAngleVectorRead[1]; DREAM3D_REQUIRED(axisAngles1.angle, ==, axisAngles1Read.angle) DREAM3D_REQUIRED(axisAngles1.h, ==, axisAngles1Read.h) DREAM3D_REQUIRED(axisAngles1.k, ==, axisAngles1Read.k) DREAM3D_REQUIRED(axisAngles1.l, ==, axisAngles1Read.l) DREAM3D_REQUIRED(axisAngles2.angle, ==, axisAngles2Read.angle) DREAM3D_REQUIRED(axisAngles2.h, ==, axisAngles2Read.h) DREAM3D_REQUIRED(axisAngles2.k, ==, axisAngles2Read.k) DREAM3D_REQUIRED(axisAngles2.l, ==, axisAngles2Read.l) err = reader->closeFilterGroup(); // Close the HDF5 group for this filter DREAM3D_REQUIRED(err, >=, 0) H5Gclose(pipelineGroupId); // Closes the "Pipeline" group H5Fclose(fid); // Closes the file }