smbinterp/interp/grid/gmsh.py

import pickle

from   itertools   import combinations
from   collections import defaultdict

import numpy as np
from   scipy.spatial import KDTree

from   interp.grid         import grid
from   interp.grid.simplex import face
from   interp.tools        import exact_func

class gmsh_grid(grid):
  THREE_NODE_TRIANGLE = 2

  def __init__(self, filename):
    """
      construct an interp.grid.grid-compliant grid
      object out of a 2D gmsh file
    """

    gmsh_file = open(filename, 'r')


    gmsh_file.readline() # $MeshFormat
    format = gmsh_file.readline()
    gmsh_file.readline() # $EndMeshFormat

    gmsh_file.readline() # $Nodes

    node_count = int(gmsh_file.readline())

    self.verts = np.empty((node_count, 3))
    self.q     = np.empty(node_count)

    for i in xrange(node_count):
      cur_line = gmsh_file.readline()
      (index, x,y,z) = cur_line.split()
      index = int(index) - 1

      self.verts[i][0] = float(x)
      self.verts[i][1] = float(y)
      self.verts[i][2] = float(z)
      self.q[i] = exact_func(self.verts[i])


    grid.__init__(self)
    self.tree = KDTree(self.verts)
    gmsh_file.readline() # $EndNodes
    gmsh_file.readline() # $Elements

    # temporary dict used to compute face connectivity
    neighbors = {}

    element_count = int(gmsh_file.readline())
    for i in xrange(element_count):
      cur_line = gmsh_file.readline()
      cur_line = cur_line.split()
      cur_face_index, node_type, rest = (int(cur_line[0]),
                                         int(cur_line[1]),
                                         [int(j) for j in  cur_line[2:]])

      if(node_type == gmsh_grid.THREE_NODE_TRIANGLE):
        points_for_cur_face = [i-1 for i in rest[rest[0]+1:]]

        cur_face = face(cur_face_index)

        for cur_point in points_for_cur_face:
          self.faces_for_vert[cur_point].append(cur_face)

        cur_face.verts       = points_for_cur_face

        self.faces[cur_face_index] = cur_face
        edges = [tuple(sorted(i)) for i in combinations(points_for_cur_face, 2)]

        # edge is two verts
        for edge in edges:
          if edge in neighbors:
            neighbors[edge].append(cur_face_index)
          else:
            neighbors[edge] = [cur_face_index]

    for k,v in neighbors.iteritems():
      if len(v) > 1:
        self.faces[v[0]].add_neighbor(self.faces[v[1]])
        self.faces[v[1]].add_neighbor(self.faces[v[0]])

  def dump_to_blender_files(self, pfile = '/tmp/points.p', ffile = '/tmp/faces.p'):
    pickle.dump([(p[0], p[1], p[2]) for p in self.verts],   open(pfile, 'w'))
    pickle.dump([f.verts for f in self.faces.itervalues()], open(ffile, 'w'))

class gmsh_grid3D(grid):
  FOUR_NODE_TET = 4

  def __init__(self, filename):
    """
      construct an interp.grid.grid-compliant grid
      object out of a 3D gmsh file
    """

    gmsh_file = open(filename, 'r')


    gmsh_file.readline() # $MeshFormat
    format = gmsh_file.readline()
    gmsh_file.readline() # $EndMeshFormat

    gmsh_file.readline() # $Nodes

    node_count = int(gmsh_file.readline())

    self.verts = np.empty((node_count, 3))
    self.q     = np.empty(node_count)

    for i in xrange(node_count):
      cur_line = gmsh_file.readline()
      (index, x,y,z) = cur_line.split()
      index = int(index) - 1

      self.verts[i][0] = float(x)
      self.verts[i][1] = float(y)
      self.verts[i][2] = float(z)
      self.q[i] = exact_func(self.verts[i])


    grid.__init__(self)
    self.tree = KDTree(self.verts)
    gmsh_file.readline() # $EndNodes
    gmsh_file.readline() # $Elements

    # temporary dict used to compute face connectivity
    neighbors = {}

    element_count = int(gmsh_file.readline())
    for i in xrange(element_count):
      cur_line = gmsh_file.readline()
      cur_line = cur_line.split()
      cur_face_index, node_type, rest = (int(cur_line[0]),
                                         int(cur_line[1]),
                                         [int(j) for j in  cur_line[2:]])

      if(node_type == gmsh_grid3D.FOUR_NODE_TET):
        points_for_cur_face = [i-1 for i in rest[rest[0]+1:]]

        cur_face = face(cur_face_index)

        for cur_point in points_for_cur_face:
          self.faces_for_vert[cur_point].append(cur_face)

        cur_face.verts       = points_for_cur_face

        self.faces[cur_face_index] = cur_face
        edges = [tuple(sorted(i)) for i in combinations(points_for_cur_face, 3)]

        # edge is two verts
        for edge in edges:
          if edge in neighbors:
            neighbors[edge].append(cur_face_index)
          else:
            neighbors[edge] = [cur_face_index]

    for k,v in neighbors.iteritems():
      if len(v) > 1:
        self.faces[v[0]].add_neighbor(self.faces[v[1]])
        self.faces[v[1]].add_neighbor(self.faces[v[0]])

  def dump_to_blender_files(self, pfile = '/tmp/points.p', ffile = '/tmp/faces.p'):
    pickle.dump([(p[0], p[1], p[2]) for p in self.verts],   open(pfile, 'w'))
    pickle.dump([f.verts for f in self.faces.itervalues()], open(ffile, 'w'))
created a distince gmsh 2D plugin 2010-10-23 15:57:44 -07:00			`import pickle`

			`from itertools import combinations`
			`from collections import defaultdict`

			`import numpy as np`
			`from scipy.spatial import KDTree`

			`from interp.grid import grid`
			`from interp.grid.simplex import face`
			`from interp.tools import exact_func`

			`class gmsh_grid(grid):`
			`THREE_NODE_TRIANGLE = 2`

			`def __init__(self, filename):`
			`"""`
			`construct an interp.grid.grid-compliant grid`
			`object out of a 2D gmsh file`
			`"""`

			`gmsh_file = open(filename, 'r')`


			`gmsh_file.readline() # $MeshFormat`
			`format = gmsh_file.readline()`
			`gmsh_file.readline() # $EndMeshFormat`

			`gmsh_file.readline() # $Nodes`

			`node_count = int(gmsh_file.readline())`

			`self.verts = np.empty((node_count, 3))`
			`self.q = np.empty(node_count)`

			`for i in xrange(node_count):`
			`cur_line = gmsh_file.readline()`
			`(index, x,y,z) = cur_line.split()`
			`index = int(index) - 1`

			`self.verts[i][0] = float(x)`
			`self.verts[i][1] = float(y)`
			`self.verts[i][2] = float(z)`
			`self.q[i] = exact_func(self.verts[i])`


			`grid.__init__(self)`
the gmsh grid object now instantiates its own KDTree 2010-10-29 11:41:39 -07:00			`self.tree = KDTree(self.verts)`
created a distince gmsh 2D plugin 2010-10-23 15:57:44 -07:00			`gmsh_file.readline() # $EndNodes`
			`gmsh_file.readline() # $Elements`

			`# temporary dict used to compute face connectivity`
			`neighbors = {}`

			`element_count = int(gmsh_file.readline())`
			`for i in xrange(element_count):`
			`cur_line = gmsh_file.readline()`
			`cur_line = cur_line.split()`
			`cur_face_index, node_type, rest = (int(cur_line[0]),`
			`int(cur_line[1]),`
			`[int(j) for j in cur_line[2:]])`

			`if(node_type == gmsh_grid.THREE_NODE_TRIANGLE):`
			`points_for_cur_face = [i-1 for i in rest[rest[0]+1:]]`

			`cur_face = face(cur_face_index)`

			`for cur_point in points_for_cur_face:`
			`self.faces_for_vert[cur_point].append(cur_face)`

			`cur_face.verts = points_for_cur_face`

			`self.faces[cur_face_index] = cur_face`
			`edges = [tuple(sorted(i)) for i in combinations(points_for_cur_face, 2)]`

			`# edge is two verts`
			`for edge in edges:`
			`if edge in neighbors:`
			`neighbors[edge].append(cur_face_index)`
			`else:`
			`neighbors[edge] = [cur_face_index]`

			`for k,v in neighbors.iteritems():`
			`if len(v) > 1:`
			`self.faces[v[0]].add_neighbor(self.faces[v[1]])`
			`self.faces[v[1]].add_neighbor(self.faces[v[0]])`

			`def dump_to_blender_files(self, pfile = '/tmp/points.p', ffile = '/tmp/faces.p'):`
			`pickle.dump([(p[0], p[1], p[2]) for p in self.verts], open(pfile, 'w'))`
			`pickle.dump([f.verts for f in self.faces.itervalues()], open(ffile, 'w'))`
starting to implement 3D test case by brute force, very ugly 2010-11-01 14:53:37 -07:00
			`class gmsh_grid3D(grid):`
			`FOUR_NODE_TET = 4`

			`def __init__(self, filename):`
			`"""`
			`construct an interp.grid.grid-compliant grid`
			`object out of a 3D gmsh file`
			`"""`

			`gmsh_file = open(filename, 'r')`


			`gmsh_file.readline() # $MeshFormat`
			`format = gmsh_file.readline()`
			`gmsh_file.readline() # $EndMeshFormat`

			`gmsh_file.readline() # $Nodes`

			`node_count = int(gmsh_file.readline())`

			`self.verts = np.empty((node_count, 3))`
			`self.q = np.empty(node_count)`

			`for i in xrange(node_count):`
			`cur_line = gmsh_file.readline()`
			`(index, x,y,z) = cur_line.split()`
			`index = int(index) - 1`

			`self.verts[i][0] = float(x)`
			`self.verts[i][1] = float(y)`
			`self.verts[i][2] = float(z)`
			`self.q[i] = exact_func(self.verts[i])`


			`grid.__init__(self)`
			`self.tree = KDTree(self.verts)`
			`gmsh_file.readline() # $EndNodes`
			`gmsh_file.readline() # $Elements`

			`# temporary dict used to compute face connectivity`
			`neighbors = {}`

			`element_count = int(gmsh_file.readline())`
			`for i in xrange(element_count):`
			`cur_line = gmsh_file.readline()`
			`cur_line = cur_line.split()`
			`cur_face_index, node_type, rest = (int(cur_line[0]),`
			`int(cur_line[1]),`
			`[int(j) for j in cur_line[2:]])`

			`if(node_type == gmsh_grid3D.FOUR_NODE_TET):`
			`points_for_cur_face = [i-1 for i in rest[rest[0]+1:]]`

			`cur_face = face(cur_face_index)`

			`for cur_point in points_for_cur_face:`
			`self.faces_for_vert[cur_point].append(cur_face)`

			`cur_face.verts = points_for_cur_face`

			`self.faces[cur_face_index] = cur_face`
			`edges = [tuple(sorted(i)) for i in combinations(points_for_cur_face, 3)]`

			`# edge is two verts`
			`for edge in edges:`
			`if edge in neighbors:`
			`neighbors[edge].append(cur_face_index)`
			`else:`
			`neighbors[edge] = [cur_face_index]`

			`for k,v in neighbors.iteritems():`
			`if len(v) > 1:`
			`self.faces[v[0]].add_neighbor(self.faces[v[1]])`
			`self.faces[v[1]].add_neighbor(self.faces[v[0]])`

			`def dump_to_blender_files(self, pfile = '/tmp/points.p', ffile = '/tmp/faces.p'):`
			`pickle.dump([(p[0], p[1], p[2]) for p in self.verts], open(pfile, 'w'))`
			`pickle.dump([f.verts for f in self.faces.itervalues()], open(ffile, 'w'))`