DAMASK_EICMD/processing/pre/seeds_fromRandom.py

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#!/usr/bin/env python
# -*- coding: UTF-8 no BOM -*-
import os,sys,string,math,random
import numpy as np
import damask
from optparse import OptionParser,OptionGroup
from scipy import spatial
scriptID = string.replace('$Id$','\n','\\n')
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scriptName = os.path.splitext(scriptID.split()[1])[0]
# --------------------------------------------------------------------
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# MAIN
# --------------------------------------------------------------------
parser = OptionParser(option_class=damask.extendableOption, usage='%prog [options]', description = """
Distribute given number of points randomly within the three-dimensional cube [0.0,0.0,0.0]--[1.0,1.0,1.0].
Reports positions with random crystal orientations in seeds file format to STDOUT.
""", version = scriptID)
parser.add_option('-N', dest='N', type='int', metavar='int', \
help='number of seed points to distribute [%default]')
parser.add_option('-g','--grid', dest='grid', type='int', nargs=3, metavar='int int int', \
help='min a,b,c grid of hexahedral box %default')
parser.add_option('-r', '--rnd', dest='randomSeed', type='int', metavar='int', \
help='seed of random number generator [%default]')
parser.add_option('-w', '--weights', dest='weights', action='store_true',
help = 'assign random weigts (Gaussian Distribution) to seed points for laguerre tessellation [%default]')
parser.add_option('-m', '--microstructure', dest='microstructure', type='int',
help='first microstructure index [%default]', metavar='int')
parser.add_option('-s','--selective', dest='selective', action='store_true',
help = 'selective picking of seed points from random seed points [%default]')
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group = OptionGroup(parser, "Laguerre Tessellation Options",
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"Parameters determining shape of weight distribution of seed points "
)
group.add_option('--mean', dest='mean', type='float', metavar='float', \
help='mean of Gaussian Distribution for weights [%default]')
group.add_option('--sigma', dest='sigma', type='float', metavar='float', \
help='standard deviation of Gaussian Distribution for weights [%default]')
parser.add_option_group(group)
group = OptionGroup(parser, "Selective Seeding Options",
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"More uniform distribution of seed points using Mitchell\'s Best Candidate Algorithm"
)
group.add_option('--distance', dest='bestDistance', type='float', metavar='float', \
help='minimum distance to the next neighbor [%default]')
group.add_option('--numCandidates', dest='numCandidates', type='int', metavar='int', \
help='maximum number of point to consider for initial random points generation [%default]')
parser.add_option_group(group)
parser.set_defaults(randomSeed = None)
parser.set_defaults(grid = (16,16,16))
parser.set_defaults(N = 20)
parser.set_defaults(weights=False)
parser.set_defaults(mean = 0.0)
parser.set_defaults(sigma = 1.0)
parser.set_defaults(microstructure = 1)
parser.set_defaults(selective = False)
parser.set_defaults(bestDistance = 0.2)
parser.set_defaults(numCandidates = 10)
(options,filename) = parser.parse_args()
options.grid = np.array(options.grid)
labels = "1_coords\t2_coords\t3_coords\tphi1\tPhi\tphi2\tmicrostructure"
# ------------------------------------------ Functions Definitions ---------------------------------
def kdtree_search(xyz, point) :
dist, index = spatial.cKDTree(xyz).query(np.array(point))
return dist
def generatePoint() :
return np.array([random.uniform(0,options.grid[0]/max(options.grid)), \
random.uniform(0,options.grid[1]/max(options.grid)), \
random.uniform(0,options.grid[2]/max(options.grid))])
# ------------------------------------------ setup file handle -------------------------------------
if filename == []:
file = {'output':sys.stdout, 'croak':sys.stderr}
else:
file = {'output':open(filename[0],'w'), 'croak':sys.stderr}
gridSize = options.grid.prod()
if gridSize == 0:
file['croak'].write('zero grid dimension for %s.\n'%(', '.join([['a','b','c'][x] for x in np.where(options.grid == 0)[0]])))
sys.exit()
if options.N > gridSize:
file['croak'].write('accommodating only %i seeds on grid.\n'%gridSize)
options.N = gridSize
randomSeed = int(os.urandom(4).encode('hex'), 16) if options.randomSeed == None else options.randomSeed
np.random.seed(randomSeed) # init random generators
random.seed(randomSeed)
grainEuler = np.random.rand(3,options.N) # create random Euler triplets
grainEuler[0,:] *= 360.0 # phi_1 is uniformly distributed
grainEuler[1,:] = np.arccos(2*grainEuler[1,:]-1)*180.0/math.pi # cos(Phi) is uniformly distributed
grainEuler[2,:] *= 360.0 # phi_2 is uniformly distributed
microstructure=np.arange(options.microstructure,options.microstructure+options.N).reshape(1,options.N)
if options.selective == False :
seedpoints = -np.ones(options.N,dtype='int') # init grid positions of seed points
if options.N * 1024 < gridSize: # heuristic limit for random search
i = 0
while i < options.N: # until all (unique) points determined
p = np.random.randint(gridSize) # pick a location
if p not in seedpoints: # not yet taken?
seedpoints[i] = p # take it
i += 1 # advance stepper
else:
seedpoints = np.array(random.sample(range(gridSize),options.N)) # create random permutation of all grid positions and choose first N
seeds = np.zeros((3,options.N),float) # init seed positions
seeds[0,:] = (np.mod(seedpoints ,options.grid[0])\
+np.random.random())/options.grid[0]
seeds[1,:] = (np.mod(seedpoints// options.grid[0] ,options.grid[1])\
+np.random.random())/options.grid[1]
seeds[2,:] = (np.mod(seedpoints//(options.grid[1]*options.grid[0]),options.grid[2])\
+np.random.random())/options.grid[2]
table = np.transpose(np.concatenate((seeds,grainEuler,microstructure),axis = 0))
else :
samples = generatePoint().reshape(1,3)
while samples.shape[0] < options.N :
bestDistance = options.bestDistance
for i in xrange(options.numCandidates) :
c = generatePoint()
d = kdtree_search(samples, c)
if (d > bestDistance) :
bestDistance = d
bestCandidate = c
if kdtree_search(samples,bestCandidate) != 0.0 :
samples = np.append(samples,bestCandidate.reshape(1,3),axis=0)
else :
continue
table = np.transpose(np.concatenate((samples.T,grainEuler,microstructure),axis = 0))
if options.weights :
weight = np.random.normal(loc=options.mean, scale=options.sigma, size=options.N)
weight /= np.sum(weight)
table = np.append(table, weight.reshape(options.N,1), axis=1)
labels += "\tweight"
# -------------------------------------- Write Data --------------------------------------------------
header = ["5\theader",
scriptID + " " + " ".join(sys.argv[1:]),
"grid\ta {}\tb {}\tc {}".format(options.grid[0],options.grid[1],options.grid[2]),
"microstructures\t{}".format(options.N),
"randomSeed\t{}".format(randomSeed),
"%s"%labels,
]
for line in header:
file['output'].write(line+"\n")
np.savetxt(file['output'], table, fmt='%10.6f', delimiter='\t')