937 lines
39 KiB
Python
937 lines
39 KiB
Python
import copy
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import multiprocessing as mp
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from functools import partial
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from os import path
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import warnings
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import numpy as np
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import pandas as pd
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import h5py
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from scipy import ndimage,spatial
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from . import environment
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from . import VTK
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from . import util
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from . import grid_filters
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from . import Rotation
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class Geom:
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"""Geometry definition for grid solvers."""
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def __init__(self,material,size,origin=[0.0,0.0,0.0],comments=[]):
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"""
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New geometry definition from array of materials, size, and origin.
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Parameters
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----------
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material : numpy.ndarray
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Material index array (3D).
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size : list or numpy.ndarray
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Physical size of the geometry in meter.
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origin : list or numpy.ndarray, optional
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Physical origin of the geometry in meter.
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comments : list of str, optional
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Comment lines.
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"""
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self.material = material
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self.size = size
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self.origin = origin
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self.comments = comments
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def __repr__(self):
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"""Basic information on geometry definition."""
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return util.srepr([
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f'cells a b c: {util.srepr(self.cells, " x ")}',
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f'size x y z: {util.srepr(self.size, " x ")}',
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f'origin x y z: {util.srepr(self.origin," ")}',
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f'# materials: {self.N_materials}',
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f'max material: {np.nanmax(self.material)}',
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])
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def __copy__(self):
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"""Copy geometry."""
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return copy.deepcopy(self)
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def copy(self):
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"""Copy geometry."""
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return self.__copy__()
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def diff(self,other):
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"""
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Report property differences of self relative to other.
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Parameters
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----------
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other : Geom
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Geometry to compare self against.
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"""
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message = []
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if np.any(other.cells != self.cells):
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message.append(util.deemph(f'cells a b c: {util.srepr(other.cells," x ")}'))
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message.append(util.emph( f'cells a b c: {util.srepr( self.cells," x ")}'))
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if not np.allclose(other.size,self.size):
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message.append(util.deemph(f'size x y z: {util.srepr(other.size," x ")}'))
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message.append(util.emph( f'size x y z: {util.srepr( self.size," x ")}'))
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if not np.allclose(other.origin,self.origin):
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message.append(util.deemph(f'origin x y z: {util.srepr(other.origin," ")}'))
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message.append(util.emph( f'origin x y z: {util.srepr( self.origin," ")}'))
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if other.N_materials != self.N_materials:
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message.append(util.deemph(f'# materials: {other.N_materials}'))
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message.append(util.emph( f'# materials: { self.N_materials}'))
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if np.nanmax(other.material) != np.nanmax(self.material):
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message.append(util.deemph(f'max material: {np.nanmax(other.material)}'))
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message.append(util.emph( f'max material: {np.nanmax( self.material)}'))
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return util.return_message(message)
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@property
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def material(self):
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"""Material indices."""
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return self._material
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@material.setter
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def material(self,material):
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if len(material.shape) != 3:
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raise ValueError(f'Invalid material shape {material.shape}.')
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elif material.dtype not in np.sctypes['float'] + np.sctypes['int']:
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raise TypeError(f'Invalid material data type {material.dtype}.')
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else:
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self._material = np.copy(material)
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if self.material.dtype in np.sctypes['float'] and \
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np.all(self.material == self.material.astype(int).astype(float)):
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self._material = self.material.astype(int)
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@property
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def size(self):
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"""Physical size of geometry in meter."""
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return self._size
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@size.setter
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def size(self,size):
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if len(size) != 3 or any(np.array(size) <= 0):
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raise ValueError(f'Invalid size {size}.')
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else:
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self._size = np.array(size)
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@property
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def origin(self):
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"""Coordinates of geometry origin in meter."""
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return self._origin
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@origin.setter
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def origin(self,origin):
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if len(origin) != 3:
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raise ValueError(f'Invalid origin {origin}.')
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else:
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self._origin = np.array(origin)
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@property
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def comments(self):
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"""Comments/history of geometry."""
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return self._comments
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@comments.setter
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def comments(self,comments):
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self._comments = [str(c) for c in comments] if isinstance(comments,list) else [str(comments)]
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@property
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def cells(self):
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"""Number of cells in x,y,z direction."""
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return np.asarray(self.material.shape)
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@property
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def N_materials(self):
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"""Number of (unique) material indices within geometry."""
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return np.unique(self.material).size
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@staticmethod
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def load(fname):
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"""
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Load from VTK rectilinear grid file.
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Parameters
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----------
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fname : str or or pathlib.Path
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Geometry file to read.
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Valid extension is .vtr, which will be appended if not given.
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"""
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v = VTK.load(fname if str(fname).endswith('.vtr') else str(fname)+'.vtr')
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comments = v.get_comments()
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cells = np.array(v.vtk_data.GetDimensions())-1
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bbox = np.array(v.vtk_data.GetBounds()).reshape(3,2).T
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return Geom(material = v.get('material').reshape(cells,order='F'),
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size = bbox[1] - bbox[0],
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origin = bbox[0],
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comments=comments)
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@staticmethod
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def load_ASCII(fname):
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"""
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Load from geom file.
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Storing geometry files in ASCII format is deprecated.
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This function will be removed in a future version of DAMASK.
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Parameters
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----------
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fname : str, pathlib.Path, or file handle
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Geometry file to read.
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"""
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warnings.warn('Support for ASCII-based geom format will be removed in DAMASK 3.1.0', DeprecationWarning)
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try:
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f = open(fname)
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except TypeError:
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f = fname
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f.seek(0)
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try:
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header_length,keyword = f.readline().split()[:2]
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header_length = int(header_length)
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except ValueError:
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header_length,keyword = (-1, 'invalid')
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if not keyword.startswith('head') or header_length < 3:
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raise TypeError('Header length information missing or invalid')
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comments = []
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content = f.readlines()
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for i,line in enumerate(content[:header_length]):
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items = line.split('#')[0].lower().strip().split()
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key = items[0] if items else ''
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if key == 'grid':
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cells = np.array([ int(dict(zip(items[1::2],items[2::2]))[i]) for i in ['a','b','c']])
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elif key == 'size':
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size = np.array([float(dict(zip(items[1::2],items[2::2]))[i]) for i in ['x','y','z']])
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elif key == 'origin':
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origin = np.array([float(dict(zip(items[1::2],items[2::2]))[i]) for i in ['x','y','z']])
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else:
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comments.append(line.strip())
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material = np.empty(cells.prod()) # initialize as flat array
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i = 0
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for line in content[header_length:]:
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items = line.split('#')[0].split()
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if len(items) == 3:
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if items[1].lower() == 'of':
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items = np.ones(int(items[0]))*float(items[2])
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elif items[1].lower() == 'to':
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items = np.linspace(int(items[0]),int(items[2]),
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abs(int(items[2])-int(items[0]))+1,dtype=float)
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else: items = list(map(float,items))
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else: items = list(map(float,items))
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material[i:i+len(items)] = items
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i += len(items)
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if i != cells.prod():
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raise TypeError(f'Invalid file: expected {cells.prod()} entries, found {i}')
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if not np.any(np.mod(material,1) != 0.0): # no float present
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material = material.astype('int') - (1 if material.min() > 0 else 0)
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return Geom(material.reshape(cells,order='F'),size,origin,comments)
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@staticmethod
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def load_DREAM3D(fname,base_group,point_data=None,material='FeatureIds'):
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"""
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Load from DREAM.3D file.
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Parameters
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----------
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fname : str
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Filename of the DREAM.3D file
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base_group : str
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Name of the group (folder) below 'DataContainers',
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for example 'SyntheticVolumeDataContainer'.
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point_data : str, optional
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Name of the group (folder) containing the pointwise material data,
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for example 'CellData'. Defaults to None, in which case points are consecutively numbered.
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material : str, optional
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Name of the dataset containing the material ID.
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Defaults to 'FeatureIds'.
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"""
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root_dir ='DataContainers'
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f = h5py.File(fname, 'r')
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g = path.join(root_dir,base_group,'_SIMPL_GEOMETRY')
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cells = f[path.join(g,'DIMENSIONS')][()]
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size = f[path.join(g,'SPACING')][()] * cells
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origin = f[path.join(g,'ORIGIN')][()]
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ma = np.arange(cells.prod(),dtype=int) \
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if point_data is None else \
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np.reshape(f[path.join(root_dir,base_group,point_data,material)],cells.prod())
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return Geom(ma.reshape(cells,order='F'),size,origin,util.execution_stamp('Geom','load_DREAM3D'))
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@staticmethod
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def from_table(table,coordinates,labels):
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"""
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Generate grid from ASCII table.
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Parameters
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----------
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table : damask.Table
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Table that contains material information.
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coordinates : str
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Label of the vector column containing the spatial coordinates.
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Need to be ordered (1./x fast, 3./z slow).
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labels : str or list of str
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Label(s) of the columns containing the material definition.
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Each unique combintation of values results in one material ID.
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"""
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cells,size,origin = grid_filters.cellSizeOrigin_coordinates0_point(table.get(coordinates))
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labels_ = [labels] if isinstance(labels,str) else labels
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unique,unique_inverse = np.unique(np.hstack([table.get(l) for l in labels_]),return_inverse=True,axis=0)
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ma = np.arange(cells.prod()) if len(unique) == cells.prod() else \
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np.arange(unique.size)[np.argsort(pd.unique(unique_inverse))][unique_inverse]
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return Geom(ma.reshape(cells,order='F'),size,origin,util.execution_stamp('Geom','from_table'))
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@staticmethod
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def _find_closest_seed(seeds, weights, point):
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return np.argmin(np.sum((np.broadcast_to(point,(len(seeds),3))-seeds)**2,axis=1) - weights)
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@staticmethod
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def from_Laguerre_tessellation(cells,size,seeds,weights,material=None,periodic=True):
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"""
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Generate grid from Laguerre tessellation.
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Parameters
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----------
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cells : int numpy.ndarray of shape (3)
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Number of cells in x,y,z direction.
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size : list or numpy.ndarray of shape (3)
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Physical size of the geometry in meter.
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seeds : numpy.ndarray of shape (:,3)
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Position of the seed points in meter. All points need to lay within the box.
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weights : numpy.ndarray of shape (seeds.shape[0])
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Weights of the seeds. Setting all weights to 1.0 gives a standard Voronoi tessellation.
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material : numpy.ndarray of shape (seeds.shape[0]), optional
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Material ID of the seeds.
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Defaults to None, in which case materials are consecutively numbered.
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periodic : Boolean, optional
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Perform a periodic tessellation. Defaults to True.
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"""
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if periodic:
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weights_p = np.tile(weights,27) # Laguerre weights (1,2,3,1,2,3,...,1,2,3)
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seeds_p = np.vstack((seeds -np.array([size[0],0.,0.]),seeds, seeds +np.array([size[0],0.,0.])))
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seeds_p = np.vstack((seeds_p-np.array([0.,size[1],0.]),seeds_p,seeds_p+np.array([0.,size[1],0.])))
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seeds_p = np.vstack((seeds_p-np.array([0.,0.,size[2]]),seeds_p,seeds_p+np.array([0.,0.,size[2]])))
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coords = grid_filters.coordinates0_point(cells*3,size*3,-size).reshape(-1,3)
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else:
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weights_p = weights
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seeds_p = seeds
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coords = grid_filters.coordinates0_point(cells,size).reshape(-1,3)
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pool = mp.Pool(processes = int(environment.options['DAMASK_NUM_THREADS']))
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result = pool.map_async(partial(Geom._find_closest_seed,seeds_p,weights_p), [coord for coord in coords])
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pool.close()
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pool.join()
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material_ = np.array(result.get())
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if periodic:
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material_ = material_.reshape(cells*3)
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material_ = material_[cells[0]:cells[0]*2,cells[1]:cells[1]*2,cells[2]:cells[2]*2]%seeds.shape[0]
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else:
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material_ = material_.reshape(cells)
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return Geom(material = material_ if material is None else material[material_],
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size = size,
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comments = util.execution_stamp('Geom','from_Laguerre_tessellation'),
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)
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@staticmethod
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def from_Voronoi_tessellation(cells,size,seeds,material=None,periodic=True):
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"""
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Generate grid from Voronoi tessellation.
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Parameters
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----------
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cells : int numpy.ndarray of shape (3)
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Number of cells in x,y,z direction.
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size : list or numpy.ndarray of shape (3)
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Physical size of the geometry in meter.
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seeds : numpy.ndarray of shape (:,3)
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Position of the seed points in meter. All points need to lay within the box.
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material : numpy.ndarray of shape (seeds.shape[0]), optional
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Material ID of the seeds.
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Defaults to None, in which case materials are consecutively numbered.
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periodic : Boolean, optional
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Perform a periodic tessellation. Defaults to True.
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"""
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coords = grid_filters.coordinates0_point(cells,size).reshape(-1,3)
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KDTree = spatial.cKDTree(seeds,boxsize=size) if periodic else spatial.cKDTree(seeds)
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devNull,material_ = KDTree.query(coords)
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return Geom(material = (material_ if material is None else material[material_]).reshape(cells),
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size = size,
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comments = util.execution_stamp('Geom','from_Voronoi_tessellation'),
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)
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_minimal_surface = \
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{'Schwarz P': lambda x,y,z: np.cos(x) + np.cos(y) + np.cos(z),
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'Double Primitive': lambda x,y,z: ( 0.5 * (np.cos(x)*np.cos(y) + np.cos(y)*np.cos(z) + np.cos(z)*np.cos(x))
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+ 0.2 * (np.cos(2*x) + np.cos(2*y) + np.cos(2*z)) ),
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'Schwarz D': lambda x,y,z: ( np.sin(x)*np.sin(y)*np.sin(z)
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+ np.sin(x)*np.cos(y)*np.cos(z)
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+ np.cos(x)*np.cos(y)*np.sin(z)
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+ np.cos(x)*np.sin(y)*np.cos(z) ),
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'Complementary D': lambda x,y,z: ( np.cos(3*x+y)*np.cos(z) - np.sin(3*x-y)*np.sin(z) + np.cos(x+3*y)*np.cos(z)
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+ np.sin(x-3*y)*np.sin(z) + np.cos(x-y)*np.cos(3*z) - np.sin(x+y)*np.sin(3*z) ),
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'Double Diamond': lambda x,y,z: 0.5 * (np.sin(x)*np.sin(y)
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+ np.sin(y)*np.sin(z)
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+ np.sin(z)*np.sin(x)
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+ np.cos(x) * np.cos(y) * np.cos(z) ),
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'Dprime': lambda x,y,z: 0.5 * ( np.cos(x)*np.cos(y)*np.cos(z)
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+ np.cos(x)*np.sin(y)*np.sin(z)
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+ np.sin(x)*np.cos(y)*np.sin(z)
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+ np.sin(x)*np.sin(y)*np.cos(z)
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- np.sin(2*x)*np.sin(2*y)
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- np.sin(2*y)*np.sin(2*z)
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- np.sin(2*z)*np.sin(2*x) ) - 0.2,
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'Gyroid': lambda x,y,z: np.cos(x)*np.sin(y) + np.cos(y)*np.sin(z) + np.cos(z)*np.sin(x),
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'Gprime': lambda x,y,z : ( np.sin(2*x)*np.cos(y)*np.sin(z)
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+ np.sin(2*y)*np.cos(z)*np.sin(x)
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+ np.sin(2*z)*np.cos(x)*np.sin(y) ) + 0.32,
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'Karcher K': lambda x,y,z: ( 0.3 * ( np.cos(x) + np.cos(y) + np.cos(z)
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+ np.cos(x)*np.cos(y) + np.cos(y)*np.cos(z) + np.cos(z)*np.cos(x) )
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- 0.4 * ( np.cos(2*x) + np.cos(2*y) + np.cos(2*z) ) ) + 0.2,
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'Lidinoid': lambda x,y,z: 0.5 * ( np.sin(2*x)*np.cos(y)*np.sin(z)
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+ np.sin(2*y)*np.cos(z)*np.sin(x)
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+ np.sin(2*z)*np.cos(x)*np.sin(y)
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- np.cos(2*x)*np.cos(2*y)
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- np.cos(2*y)*np.cos(2*z)
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- np.cos(2*z)*np.cos(2*x) ) + 0.15,
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'Neovius': lambda x,y,z: ( 3 * (np.cos(x)+np.cos(y)+np.cos(z))
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+ 4 * np.cos(x)*np.cos(y)*np.cos(z) ),
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'Fisher-Koch S': lambda x,y,z: ( np.cos(2*x)*np.sin( y)*np.cos( z)
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+ np.cos( x)*np.cos(2*y)*np.sin( z)
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+ np.sin( x)*np.cos( y)*np.cos(2*z) ),
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}
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@staticmethod
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def from_minimal_surface(cells,size,surface,threshold=0.0,periods=1,materials=(0,1)):
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"""
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Generate grid from definition of triply periodic minimal surface.
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Parameters
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----------
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cells : int numpy.ndarray of shape (3)
|
||
Number of cells in x,y,z direction.
|
||
size : list or numpy.ndarray of shape (3)
|
||
Physical size of the geometry in meter.
|
||
surface : str
|
||
Type of the minimal surface. See notes for details.
|
||
threshold : float, optional.
|
||
Threshold of the minimal surface. Defaults to 0.0.
|
||
periods : integer, optional.
|
||
Number of periods per unit cell. Defaults to 1.
|
||
materials : (int, int), optional
|
||
Material IDs. Defaults to (1,2).
|
||
|
||
Notes
|
||
-----
|
||
The following triply-periodic minimal surfaces are implemented:
|
||
- Schwarz P
|
||
- Double Primitive
|
||
- Schwarz D
|
||
- Complementary D
|
||
- Double Diamond
|
||
- Dprime
|
||
- Gyroid
|
||
- Gprime
|
||
- Karcher K
|
||
- Lidinoid
|
||
- Neovius
|
||
- Fisher-Koch S
|
||
|
||
References
|
||
----------
|
||
Sébastien B G Blanquer, Maike Werner, Markus Hannula, Shahriar Sharifi,
|
||
Guillaume P R Lajoinie, David Eglin, Jari Hyttinen, André A Poot, and Dirk W Grijpma
|
||
Surface curvature in triply-periodic minimal surface architectures as
|
||
a distinct design parameter in preparing advanced tissue engineering scaffolds
|
||
https://doi.org/10.1088/1758-5090/aa6553
|
||
|
||
Meinhard Wohlgemuth, Nataliya Yufa, James Hoffman, and Edwin L. Thomas
|
||
Triply Periodic Bicontinuous Cubic Microdomain Morphologies by Symmetries
|
||
https://doi.org/10.1021/ma0019499
|
||
|
||
Meng-Ting Hsieh, Lorenzo Valdevit
|
||
Minisurf – A minimal surface generator for finite element modeling and additive manufacturing
|
||
https://doi.org/10.1016/j.simpa.2020.100026
|
||
|
||
"""
|
||
x,y,z = np.meshgrid(periods*2.0*np.pi*(np.arange(cells[0])+0.5)/cells[0],
|
||
periods*2.0*np.pi*(np.arange(cells[1])+0.5)/cells[1],
|
||
periods*2.0*np.pi*(np.arange(cells[2])+0.5)/cells[2],
|
||
indexing='ij',sparse=True)
|
||
return Geom(material = np.where(threshold < Geom._minimal_surface[surface](x,y,z),materials[1],materials[0]),
|
||
size = size,
|
||
comments = util.execution_stamp('Geom','from_minimal_surface'),
|
||
)
|
||
|
||
|
||
def save(self,fname,compress=True):
|
||
"""
|
||
Save as VTK rectilinear grid file.
|
||
|
||
Parameters
|
||
----------
|
||
fname : str or pathlib.Path
|
||
Filename to write. Valid extension is .vtr, it will be appended if not given.
|
||
compress : bool, optional
|
||
Compress with zlib algorithm. Defaults to True.
|
||
|
||
"""
|
||
v = VTK.from_rectilinear_grid(self.cells,self.size,self.origin)
|
||
v.add(self.material.flatten(order='F'),'material')
|
||
v.add_comments(self.comments)
|
||
|
||
v.save(fname if str(fname).endswith('.vtr') else str(fname)+'.vtr',parallel=False,compress=compress)
|
||
|
||
|
||
def save_ASCII(self,fname):
|
||
"""
|
||
Save as geom file.
|
||
|
||
Storing geometry files in ASCII format is deprecated.
|
||
This function will be removed in a future version of DAMASK.
|
||
|
||
Parameters
|
||
----------
|
||
fname : str or file handle
|
||
Geometry file to write with extension '.geom'.
|
||
compress : bool, optional
|
||
Compress geometry with 'x of y' and 'a to b'.
|
||
|
||
"""
|
||
warnings.warn('Support for ASCII-based geom format will be removed in DAMASK 3.1.0', DeprecationWarning)
|
||
header = [f'{len(self.comments)+4} header'] + self.comments \
|
||
+ ['grid a {} b {} c {}'.format(*self.cells),
|
||
'size x {} y {} z {}'.format(*self.size),
|
||
'origin x {} y {} z {}'.format(*self.origin),
|
||
'homogenization 1',
|
||
]
|
||
|
||
format_string = '%g' if self.material.dtype in np.sctypes['float'] else \
|
||
'%{}i'.format(1+int(np.floor(np.log10(np.nanmax(self.material)))))
|
||
np.savetxt(fname,
|
||
self.material.reshape([self.cells[0],np.prod(self.cells[1:])],order='F').T,
|
||
header='\n'.join(header), fmt=format_string, comments='')
|
||
|
||
|
||
def show(self):
|
||
"""Show on screen."""
|
||
VTK.from_rectilinear_grid(self.cells,self.size,self.origin).show()
|
||
|
||
|
||
def add_primitive(self,dimension,center,exponent,
|
||
fill=None,R=Rotation(),inverse=False,periodic=True):
|
||
"""
|
||
Insert a primitive geometric object at a given position.
|
||
|
||
Parameters
|
||
----------
|
||
dimension : int or float numpy.ndarray of shape (3)
|
||
Dimension (diameter/side length) of the primitive. If given as
|
||
integers, cell centers are addressed.
|
||
If given as floats, coordinates are addressed.
|
||
center : int or float numpy.ndarray of shape (3)
|
||
Center of the primitive. If given as integers, cell centers are addressed.
|
||
If given as floats, coordinates in space are addressed.
|
||
exponent : numpy.ndarray of shape (3) or float
|
||
Exponents for the three axes.
|
||
0 gives octahedron (ǀxǀ^(2^0) + ǀyǀ^(2^0) + ǀzǀ^(2^0) < 1)
|
||
1 gives sphere (ǀxǀ^(2^1) + ǀyǀ^(2^1) + ǀzǀ^(2^1) < 1)
|
||
fill : int, optional
|
||
Fill value for primitive. Defaults to material.max()+1.
|
||
R : damask.Rotation, optional
|
||
Rotation of primitive. Defaults to no rotation.
|
||
inverse : Boolean, optional
|
||
Retain original materials within primitive and fill outside.
|
||
Defaults to False.
|
||
periodic : Boolean, optional
|
||
Repeat primitive over boundaries. Defaults to True.
|
||
|
||
"""
|
||
# radius and center
|
||
r = np.array(dimension)/2.0*self.size/self.cells if np.array(dimension).dtype in np.sctypes['int'] else \
|
||
np.array(dimension)/2.0
|
||
c = (np.array(center) + .5)*self.size/self.cells if np.array(center).dtype in np.sctypes['int'] else \
|
||
(np.array(center) - self.origin)
|
||
|
||
coords = grid_filters.coordinates0_point(self.cells,self.size,
|
||
-(0.5*(self.size + (self.size/self.cells
|
||
if np.array(center).dtype in np.sctypes['int'] else
|
||
0)) if periodic else c))
|
||
coords_rot = R.broadcast_to(tuple(self.cells))@coords
|
||
|
||
with np.errstate(all='ignore'):
|
||
mask = np.sum(np.power(coords_rot/r,2.0**np.array(exponent)),axis=-1) > 1.0
|
||
|
||
if periodic: # translate back to center
|
||
mask = np.roll(mask,((c/self.size-0.5)*self.cells).round().astype(int),(0,1,2))
|
||
|
||
return Geom(material = np.where(np.logical_not(mask) if inverse else mask,
|
||
self.material,
|
||
np.nanmax(self.material)+1 if fill is None else fill),
|
||
size = self.size,
|
||
origin = self.origin,
|
||
comments = self.comments+[util.execution_stamp('Geom','add_primitive')],
|
||
)
|
||
|
||
|
||
def mirror(self,directions,reflect=False):
|
||
"""
|
||
Mirror geometry along given directions.
|
||
|
||
Parameters
|
||
----------
|
||
directions : iterable containing str
|
||
Direction(s) along which the geometry is mirrored.
|
||
Valid entries are 'x', 'y', 'z'.
|
||
reflect : bool, optional
|
||
Reflect (include) outermost layers. Defaults to False.
|
||
|
||
"""
|
||
valid = ['x','y','z']
|
||
if not set(directions).issubset(valid):
|
||
raise ValueError(f'Invalid direction {set(directions).difference(valid)} specified.')
|
||
|
||
limits = [None,None] if reflect else [-2,0]
|
||
mat = self.material.copy()
|
||
|
||
if 'x' in directions:
|
||
mat = np.concatenate([mat,mat[limits[0]:limits[1]:-1,:,:]],0)
|
||
if 'y' in directions:
|
||
mat = np.concatenate([mat,mat[:,limits[0]:limits[1]:-1,:]],1)
|
||
if 'z' in directions:
|
||
mat = np.concatenate([mat,mat[:,:,limits[0]:limits[1]:-1]],2)
|
||
|
||
return Geom(material = mat,
|
||
size = self.size/self.cells*np.asarray(mat.shape),
|
||
origin = self.origin,
|
||
comments = self.comments+[util.execution_stamp('Geom','mirror')],
|
||
)
|
||
|
||
|
||
def flip(self,directions):
|
||
"""
|
||
Flip geometry along given directions.
|
||
|
||
Parameters
|
||
----------
|
||
directions : iterable containing str
|
||
Direction(s) along which the geometry is flipped.
|
||
Valid entries are 'x', 'y', 'z'.
|
||
|
||
"""
|
||
valid = ['x','y','z']
|
||
if not set(directions).issubset(valid):
|
||
raise ValueError(f'Invalid direction {set(directions).difference(valid)} specified.')
|
||
|
||
mat = np.flip(self.material, (valid.index(d) for d in directions if d in valid))
|
||
|
||
return Geom(material = mat,
|
||
size = self.size,
|
||
origin = self.origin,
|
||
comments = self.comments+[util.execution_stamp('Geom','flip')],
|
||
)
|
||
|
||
|
||
def scale(self,cells,periodic=True):
|
||
"""
|
||
Scale geometry to new cells.
|
||
|
||
Parameters
|
||
----------
|
||
cells : numpy.ndarray of shape (3)
|
||
Number of cells in x,y,z direction.
|
||
periodic : Boolean, optional
|
||
Assume geometry to be periodic. Defaults to True.
|
||
|
||
"""
|
||
return Geom(material = ndimage.interpolation.zoom(
|
||
self.material,
|
||
cells/self.cells,
|
||
output=self.material.dtype,
|
||
order=0,
|
||
mode=('wrap' if periodic else 'nearest'),
|
||
prefilter=False
|
||
),
|
||
size = self.size,
|
||
origin = self.origin,
|
||
comments = self.comments+[util.execution_stamp('Geom','scale')],
|
||
)
|
||
|
||
|
||
def clean(self,stencil=3,selection=None,periodic=True):
|
||
"""
|
||
Smooth geometry by selecting most frequent material index within given stencil at each location.
|
||
|
||
Parameters
|
||
----------
|
||
stencil : int, optional
|
||
Size of smoothing stencil.
|
||
selection : list, optional
|
||
Field values that can be altered. Defaults to all.
|
||
periodic : Boolean, optional
|
||
Assume geometry to be periodic. Defaults to True.
|
||
|
||
"""
|
||
def mostFrequent(arr,selection=None):
|
||
me = arr[arr.size//2]
|
||
if selection is None or me in selection:
|
||
unique, inverse = np.unique(arr, return_inverse=True)
|
||
return unique[np.argmax(np.bincount(inverse))]
|
||
else:
|
||
return me
|
||
|
||
return Geom(material = ndimage.filters.generic_filter(
|
||
self.material,
|
||
mostFrequent,
|
||
size=(stencil if selection is None else stencil//2*2+1,)*3,
|
||
mode=('wrap' if periodic else 'nearest'),
|
||
extra_keywords=dict(selection=selection),
|
||
).astype(self.material.dtype),
|
||
size = self.size,
|
||
origin = self.origin,
|
||
comments = self.comments+[util.execution_stamp('Geom','clean')],
|
||
)
|
||
|
||
|
||
def renumber(self):
|
||
"""Renumber sorted material indices as 0,...,N-1."""
|
||
_,renumbered = np.unique(self.material,return_inverse=True)
|
||
|
||
return Geom(material = renumbered.reshape(self.cells),
|
||
size = self.size,
|
||
origin = self.origin,
|
||
comments = self.comments+[util.execution_stamp('Geom','renumber')],
|
||
)
|
||
|
||
|
||
def rotate(self,R,fill=None):
|
||
"""
|
||
Rotate geometry (pad if required).
|
||
|
||
Parameters
|
||
----------
|
||
R : damask.Rotation
|
||
Rotation to apply to the geometry.
|
||
fill : int or float, optional
|
||
Material index to fill the corners. Defaults to material.max() + 1.
|
||
|
||
"""
|
||
if fill is None: fill = np.nanmax(self.material) + 1
|
||
dtype = float if np.isnan(fill) or int(fill) != fill or self.material.dtype==np.float else int
|
||
|
||
Eulers = R.as_Euler_angles(degrees=True)
|
||
material_in = self.material.copy()
|
||
|
||
# These rotations are always applied in the reference coordinate system, i.e. (z,x,z) not (z,x',z'')
|
||
# see https://www.cs.utexas.edu/~theshark/courses/cs354/lectures/cs354-14.pdf
|
||
for angle,axes in zip(Eulers[::-1], [(0,1),(1,2),(0,1)]):
|
||
material_out = ndimage.rotate(material_in,angle,axes,order=0,
|
||
prefilter=False,output=dtype,cval=fill)
|
||
if np.prod(material_in.shape) == np.prod(material_out.shape):
|
||
# avoid scipy interpolation errors for rotations close to multiples of 90°
|
||
material_in = np.rot90(material_in,k=np.rint(angle/90.).astype(int),axes=axes)
|
||
else:
|
||
material_in = material_out
|
||
|
||
origin = self.origin-(np.asarray(material_in.shape)-self.cells)*.5 * self.size/self.cells
|
||
|
||
return Geom(material = material_in,
|
||
size = self.size/self.cells*np.asarray(material_in.shape),
|
||
origin = origin,
|
||
comments = self.comments+[util.execution_stamp('Geom','rotate')],
|
||
)
|
||
|
||
|
||
def canvas(self,cells=None,offset=None,fill=None):
|
||
"""
|
||
Crop or enlarge/pad geometry.
|
||
|
||
Parameters
|
||
----------
|
||
cells : numpy.ndarray of shape (3)
|
||
Number of cells x,y,z direction.
|
||
offset : numpy.ndarray of shape (3)
|
||
Offset (measured in cells) from old to new geometry [0,0,0].
|
||
fill : int or float, optional
|
||
Material index to fill the background. Defaults to material.max() + 1.
|
||
|
||
"""
|
||
if offset is None: offset = 0
|
||
if fill is None: fill = np.nanmax(self.material) + 1
|
||
dtype = float if int(fill) != fill or self.material.dtype in np.sctypes['float'] else int
|
||
|
||
canvas = np.full(self.cells if cells is None else cells,fill,dtype)
|
||
|
||
LL = np.clip( offset, 0,np.minimum(self.cells, cells+offset))
|
||
UR = np.clip( offset+cells, 0,np.minimum(self.cells, cells+offset))
|
||
ll = np.clip(-offset, 0,np.minimum( cells,self.cells-offset))
|
||
ur = np.clip(-offset+self.cells,0,np.minimum( cells,self.cells-offset))
|
||
|
||
canvas[ll[0]:ur[0],ll[1]:ur[1],ll[2]:ur[2]] = self.material[LL[0]:UR[0],LL[1]:UR[1],LL[2]:UR[2]]
|
||
|
||
return Geom(material = canvas,
|
||
size = self.size/self.cells*np.asarray(canvas.shape),
|
||
origin = self.origin+offset*self.size/self.cells,
|
||
comments = self.comments+[util.execution_stamp('Geom','canvas')],
|
||
)
|
||
|
||
|
||
def substitute(self,from_material,to_material):
|
||
"""
|
||
Substitute material indices.
|
||
|
||
Parameters
|
||
----------
|
||
from_material : iterable of ints
|
||
Material indices to be substituted.
|
||
to_material : iterable of ints
|
||
New material indices.
|
||
|
||
"""
|
||
def mp(entry,mapper):
|
||
return mapper[entry] if entry in mapper else entry
|
||
|
||
mp = np.vectorize(mp)
|
||
mapper = dict(zip(from_material,to_material))
|
||
|
||
return Geom(material = mp(self.material,mapper).reshape(self.cells),
|
||
size = self.size,
|
||
origin = self.origin,
|
||
comments = self.comments+[util.execution_stamp('Geom','substitute')],
|
||
)
|
||
|
||
|
||
def sort(self):
|
||
"""Sort material indices such that min(material) is located at (0,0,0)."""
|
||
a = self.material.flatten(order='F')
|
||
from_ma = pd.unique(a)
|
||
sort_idx = np.argsort(from_ma)
|
||
ma = np.unique(a)[sort_idx][np.searchsorted(from_ma,a,sorter = sort_idx)]
|
||
|
||
return Geom(material = ma.reshape(self.cells,order='F'),
|
||
size = self.size,
|
||
origin = self.origin,
|
||
comments = self.comments+[util.execution_stamp('Geom','sort')],
|
||
)
|
||
|
||
|
||
def vicinity_offset(self,vicinity=1,offset=None,trigger=[],periodic=True):
|
||
"""
|
||
Offset material index of points in the vicinity of xxx.
|
||
|
||
Different from themselves (or listed as triggers) within a given (cubic) vicinity,
|
||
i.e. within the region close to a grain/phase boundary.
|
||
ToDo: use include/exclude as in seeds.from_geom
|
||
|
||
Parameters
|
||
----------
|
||
vicinity : int, optional
|
||
Voxel distance checked for presence of other materials.
|
||
Defaults to 1.
|
||
offset : int, optional
|
||
Offset (positive or negative) to tag material indices,
|
||
defaults to material.max()+1.
|
||
trigger : list of ints, optional
|
||
List of material indices that trigger a change.
|
||
Defaults to [], meaning that any different neighbor triggers a change.
|
||
periodic : Boolean, optional
|
||
Assume geometry to be periodic. Defaults to True.
|
||
|
||
"""
|
||
def tainted_neighborhood(stencil,trigger):
|
||
|
||
me = stencil[stencil.shape[0]//2]
|
||
return np.any(stencil != me
|
||
if len(trigger) == 0 else
|
||
np.in1d(stencil,np.array(list(set(trigger) - {me}))))
|
||
|
||
offset_ = np.nanmax(self.material)+1 if offset is None else offset
|
||
mask = ndimage.filters.generic_filter(self.material,
|
||
tainted_neighborhood,
|
||
size=1+2*vicinity,
|
||
mode='wrap' if periodic else 'nearest',
|
||
extra_keywords={'trigger':trigger})
|
||
|
||
return Geom(material = np.where(mask, self.material + offset_,self.material),
|
||
size = self.size,
|
||
origin = self.origin,
|
||
comments = self.comments+[util.execution_stamp('Geom','vicinity_offset')],
|
||
)
|
||
|
||
|
||
def get_grain_boundaries(self,periodic=True,directions='xyz'):
|
||
"""
|
||
Create VTK unstructured grid containing grain boundaries.
|
||
|
||
Parameters
|
||
----------
|
||
periodic : bool, optional
|
||
Show boundaries across periodicity. Defaults to True.
|
||
directions : iterable containing str, optional
|
||
Direction(s) along which the geometry is mirrored.
|
||
Valid entries are 'x', 'y', 'z'. Defaults to 'xyz'.
|
||
|
||
"""
|
||
valid = ['x','y','z']
|
||
if not set(directions).issubset(valid):
|
||
raise ValueError(f'Invalid direction {set(directions).difference(valid)} specified.')
|
||
|
||
o = [[0, self.cells[0]+1, np.prod(self.cells[:2]+1)+self.cells[0]+1, np.prod(self.cells[:2]+1)],
|
||
[0, np.prod(self.cells[:2]+1), np.prod(self.cells[:2]+1)+1, 1],
|
||
[0, 1, self.cells[0]+1+1, self.cells[0]+1]] # offset for connectivity
|
||
|
||
connectivity = []
|
||
for i,d in enumerate(['x','y','z']):
|
||
if d not in directions: continue
|
||
mask = self.material != np.roll(self.material,1,i)
|
||
for j in [0,1,2]:
|
||
mask = np.concatenate((mask,np.take(mask,[0],j)*(i==j)),j)
|
||
if i == 0 and not periodic: mask[0,:,:] = mask[-1,:,:] = False
|
||
if i == 1 and not periodic: mask[:,0,:] = mask[:,-1,:] = False
|
||
if i == 2 and not periodic: mask[:,:,0] = mask[:,:,-1] = False
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||
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||
base_nodes = np.argwhere(mask.flatten(order='F')).reshape(-1,1)
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||
connectivity.append(np.block([base_nodes + o[i][k] for k in range(4)]))
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||
|
||
coords = grid_filters.coordinates0_node(self.cells,self.size,self.origin).reshape(-1,3,order='F')
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return VTK.from_unstructured_grid(coords,np.vstack(connectivity),'QUAD')
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