legacy code not needed anymore

processing/DADF5toDREAM3D.py

@@ -1,185 +0,0 @@
-#!/usr/bin/env python3
-
-import argparse
-import os
-from pathlib import Path
-
-import h5py
-import numpy as np
-
-import damask
-from damask import Rotation
-from damask import Orientation
-
-class AttributeManagerNullterm(h5py.AttributeManager):
-  """
-  Attribute management for DREAM.3D hdf5 files.
-
-  String attribute values are stored as fixed-length string with NULLTERM
-
-  References
-  ----------
-    https://stackoverflow.com/questions/38267076
-    https://stackoverflow.com/questions/52750232
-
-  """
-
-  def create(self, name, data, shape=None, dtype=None):
-    if isinstance(data,str):
-      tid = h5py.h5t.C_S1.copy()
-      tid.set_size(len(data + ' '))
-      super().create(name=name,data=data+' ',dtype = h5py.Datatype(tid))
-    else:
-      super().create(name=name,data=data,shape=shape,dtype=dtype)
-
-
-h5py._hl.attrs.AttributeManager = AttributeManagerNullterm # 'Monkey patch'
-
-
-# --------------------------------------------------------------------
-# Crystal structure specifications
-# --------------------------------------------------------------------
-Crystal_structures = {'fcc': 1,
-                      'bcc': 1,
-                      'hcp': 0,
-                      'bct': 7,
-                      'ort': 6} #TODO: is bct Tetragonal low/Tetragonal high?
-Phase_types = {'Primary': 0} #further additions to these can be done by looking at 'Create Ensemble Info' filter
-
-class DAMASKtoDREAM3D():
-    """
-    This class can convert the DAMASK data to DREAM3D compatible data. 
-    There can be various different types of ways DAMASK data can be represented. 
-    Therefore, there are multiple functions available for different purposes.
-    """
-    def __init__(self,job_file,geom_file,load_file):
-        """
-        Defining the common quantities for all the functions in this class.
-       
-        Parameters
-        ----------
-        job_file: str or pathlib.Path
-            Full path of the DAMASK results file.
-        geom_file : str
-          name of the geom file.
-        load_file : 
-          name of the load file.
-        """
-        self.job_file = Path(job_file).expanduser().absolute()
-        self.geom_file = geom_file   
-        self.load_file = load_file   
-
-    def DAMASKtoDREAM3D(self,dx,inc):
-        """
-        Creates a dream3D file from DAMASK output.
-        Without any regridding. 
-        Considers the original grid from DAMASK. 
-        
-        Parameters:
-        -----------
-        dx : float
-          The grid spacing.
-        inc: int
-          increment of interest for DREAM3D processing.
-        """
-        os.chdir(self.job_file.parents[0])
-        #--------------------------------------------------------------------------
-        #Build array of euler angles for each cell
-        #--------------------------------------------------------------------------
-        d = damask.Result(self.job_file)
-        inc_data = d.view(increments=inc)  # selecting only relevant data to reduce overload
-    
-        f = h5py.File(self.job_file,'r')
-        cells = f['geometry'].attrs['cells']
-        size = f['geometry'].attrs['size']
-        dx = size/cells
-    
-        O_dict = inc_data.get('O') 
-        
-        cell_orientation_array = np.zeros((np.prod(cells),3))
-    
-        phase_ID_array = np.zeros((np.prod(cells)),dtype=np.int32) #need to reshape it later
-    
-        for count,p in enumerate(d.phases):
-            phase_index = np.where(f['cell_to/phase']['label'] == f'{p}'.encode())[0]
-            if len(d.phases) > 1:
-                cell_orientation_array[phase_index,:] = Rotation(O_dict[p]).as_Euler_angles()
-            else:
-                cell_orientation_array[phase_index,:] = Rotation(O_dict).as_Euler_angles()
-            phase_ID_array[phase_index] = count + 1
-        
-        #--------------------------------------------------------------------------
-        job_file_no_ext = os.path.splitext(self.job_file)[0]
-        o = h5py.File(f'{job_file_no_ext}_increment{inc}.dream3D','w')
-        o.attrs['DADF5toDREAM3D'] = '1.0'
-        o.attrs['FileVersion']    = '7.0'
-    
-        for g in ['DataContainerBundles','Pipeline']: # empty groups (needed)
-          o.create_group(g)
-    
-        data_container_label = 'DataContainers/SyntheticVolumeDataContainer'        
-        cell_data_label      = data_container_label + '/CellData'
-    
-        # Data phases
-        o[cell_data_label + '/Phases'] = np.reshape(phase_ID_array, \
-                                                    tuple(np.flip(cells))+(1,))
-    
-        # Data eulers
-        orientation_data = cell_orientation_array.astype(np.float32)
-        o[cell_data_label + '/Eulers'] = orientation_data.reshape(tuple(np.flip(cells))+(3,))
-    
-        # Attributes to CellData group
-        o[cell_data_label].attrs['AttributeMatrixType'] = np.array([3],np.uint32)
-        o[cell_data_label].attrs['TupleDimensions']     = np.array(cells,np.uint64)
-    
-        # Common Attributes for groups in CellData
-        for group in ['/Phases','/Eulers']:
-          o[cell_data_label + group].attrs['DataArrayVersion']      = np.array([2],np.int32)
-          o[cell_data_label + group].attrs['Tuple Axis Dimensions'] = 'x={},y={},z={}'.format(*np.array(cells))
-        
-        # phase attributes
-        o[cell_data_label + '/Phases'].attrs['ComponentDimensions'] = np.array([1],np.uint64)
-        o[cell_data_label + '/Phases'].attrs['ObjectType']          = 'DataArray<int32_t>'
-        o[cell_data_label + '/Phases'].attrs['TupleDimensions']     = np.array(cells,np.uint64)
-        
-        # Eulers attributes
-        o[cell_data_label + '/Eulers'].attrs['ComponentDimensions'] = np.array([3],np.uint64)
-        o[cell_data_label + '/Eulers'].attrs['ObjectType']          = 'DataArray<float>'        
-        o[cell_data_label + '/Eulers'].attrs['TupleDimensions']     = np.array(cells,np.uint64)
-    
-        # Create EnsembleAttributeMatrix
-        ensemble_label = data_container_label + '/CellEnsembleData'
-    
-        # Data CrystalStructures
-        #o[ensemble_label + '/CrystalStructures'] = np.uint32(np.array([999,1]))
-        o[ensemble_label + '/CrystalStructures'] = np.uint32(np.array([999] + [1]*len(d.phases)))
-        # assuming only cubic crystal structures
-        # Damask can give the crystal structure info but need to look into dream3d which crystal structure corresponds to which number
-        o[ensemble_label + '/PhaseTypes']        = np.uint32(np.array([999] + [Phase_types['Primary']]*len(d.phases))).reshape((len(d.phases)+1,1))
-        # also assuming Primary phases
-        # there can be precipitates etc as well
-    
-        # Attributes Ensemble Matrix
-        o[ensemble_label].attrs['AttributeMatrixType'] = np.array([11],np.uint32)
-        o[ensemble_label].attrs['TupleDimensions']     = np.array([len(d.phases) + 1], np.uint64)
-    
-        # Attributes for data in Ensemble matrix
-        for group in ['CrystalStructures','PhaseTypes']: # 'PhaseName' not required MD: But would be nice to take the phase name mapping
-          o[ensemble_label+'/'+group].attrs['ComponentDimensions']   = np.array([1],np.uint64)
-          o[ensemble_label+'/'+group].attrs['Tuple Axis Dimensions'] = f'x={len(d.phases)+1}'
-          o[ensemble_label+'/'+group].attrs['DataArrayVersion']      = np.array([2],np.int32)
-          o[ensemble_label+'/'+group].attrs['ObjectType']            = 'DataArray<uint32_t>'
-          o[ensemble_label+'/'+group].attrs['TupleDimensions']       = np.array([len(d.phases) + 1],np.uint64)
-    
-        # Create geometry info
-        geom_label = data_container_label + '/_SIMPL_GEOMETRY'
-        
-        o[geom_label + '/DIMENSIONS'] = np.int64(np.array(cells))
-        o[geom_label + '/ORIGIN']     = np.float32(np.zeros(3))
-        o[geom_label + '/SPACING']    = np.float32(dx)
-            
-        o[geom_label].attrs['GeometryName']     = 'ImageGeometry'
-        o[geom_label].attrs['GeometryTypeName'] = 'ImageGeometry'
-        o[geom_label].attrs['GeometryType']          = np.array([0],np.uint32) 
-        o[geom_label].attrs['SpatialDimensionality'] = np.array([3],np.uint32) 
-        o[geom_label].attrs['UnitDimensionality']    = np.array([3],np.uint32)