smbinterp/lib/grid.py

160 lines
3.6 KiB
Python
Executable File

#!/usr/bin/python
import sys
import re
import numpy as np
import scipy.spatial
from tools import exact_func
from smcqdelaunay import *
class face(object):
def __init__(self, name):
self.name = name
self.verts = []
self.neighbors = []
def add_vert(self, v):
self.verts.append(v)
def add_neighbor(self, n):
self.neighbors.append(n)
def __str__(self):
neighbors = [i.name for i in self.neighbors]
return '%s: points: %s neighbors: [%s]' %\
(
self.name,
self.verts,
", ".join(neighbors)
)
class grid(object):
def __init__(self, points, q):
"""
this thing eats two pre-constructed arrays of stuff:
points = array of arrays (2 for 2D, 3 for 3D)
q = array (1D) of important values
"""
self.points = np.array(points)
self.q = np.array(q)
self.faces = {}
def construct_connectivity(self, s):
facet_re = re.compile(r'''
-\s+(?P<facet>f\d+).*?
vertices:\s(?P<verts>.*?)\n.*?
neighboring\s facets:\s+(?P<neigh>[\sf\d]*)
''', re.S|re.X)
vert_re = re.compile(r'''
(p\d+)
''', re.S|re.X)
rajoutter = []
for matcher in facet_re.finditer(s):
d = matcher.groupdict()
facet_name = d['facet']
verticies = d['verts']
neighbors = d['neigh']
cur_face = face(facet_name)
self.faces[facet_name] = cur_face
for v in vert_re.findall(verticies):
cur_face.add_vert(int(v[1:]))
nghbrs = [(facet_name, i) for i in neighbors.split()]
rajoutter.extend(nghbrs)
for rel in rajoutter:
if rel[1] in self.faces:
self.faces[rel[0]].add_neighbor(self.faces[rel[1]])
def for_qhull_generator(self):
"""
this returns a generator that should be fed into qdelaunay
"""
yield '2';
yield '%d' % len(self.points)
for p in self.points:
yield "%f %f" % (p[0], p[1])
def for_qhull(self):
"""
this returns a single string that should be fed into qdelaunay
"""
r = '2\n'
r += '%d\n' % len(self.points)
for p in self.points:
r += "%f %f\n" % (p[0], p[1])
return r
def __str__(self):
r = ''
assert( len(self.points) == len(self.q) )
for c, i in enumerate(zip(self.points, self.q)):
r += "%d %r: %0.4f\n" % (c,i[0], i[1])
if self.faces:
for v in self.faces.itervalues():
r += "%s\n" % v
return r
class simple_rect_grid(grid):
def __init__(self, xres = 5, yres = 5):
xmin = -1.0
xmax = 1.0
xspan = xmax - xmin
xdel = xspan / float(xres - 1)
ymin = -1.0
ymay = 1.0
yspan = ymay - ymin
ydel = yspan / float(yres - 1)
points = []
q = []
for x in xrange(xres):
cur_x = xmin + (x * xdel)
for y in xrange(yres):
cur_y = ymin + (y * ydel)
points.append([cur_x, cur_y])
q.append(exact_func(cur_x, cur_y))
grid.__init__(self, points, q)
class simple_random_grid(simple_rect_grid):
def __init__(self, num_points = 10):
points = []
q = []
r = np.random
for i in xrange(num_points):
cur_x = r.rand()
cur_y = r.rand()
points.append([cur_x, cur_y])
q.append(exact_func(cur_x, cur_y))
grid.__init__(self, points, q)
self.points = np.array(self.points)
self.q = np.array(self.q)
if __name__ == '__main__':
try:
resolution = int(sys.argv[1])
except:
resolution = 10
g = simple_rect_grid(resolution, resolution)
print g.for_qhull()