pycad/py_src/gmsh.py

# -*- coding: utf-8 -*-

########################################################
#
# Copyright (c) 2003-2010 by University of Queensland
# Earth Systems Science Computational Center (ESSCC)
# http://www.uq.edu.au/esscc
#
# Primary Business: Queensland, Australia
# Licensed under the Open Software License version 3.0
# http://www.opensource.org/licenses/osl-3.0.php
#
########################################################

__copyright__="""Copyright (c) 2003-2010 by University of Queensland
Earth Systems Science Computational Center (ESSCC)
http://www.uq.edu.au/esscc
Primary Business: Queensland, Australia"""
__license__="""Licensed under the Open Software License version 3.0
http://www.opensource.org/licenses/osl-3.0.php"""
__url__="https://launchpad.net/escript-finley"

"""
mesh generation using gmsh

:var __author__: name of author
:var __copyright__: copyrights
:var __license__: licence agreement
:var __url__: url entry point on documentation
:var __version__: version
:var __date__: date of the version
"""

__author__="Lutz Gross, l.gross@uq.edu.au"

import design
import tempfile
import os
from primitives import Point, Spline, BezierCurve, BSpline, Line, Arc, CurveLoop, RuledSurface, PlaneSurface, SurfaceLoop, Volume, PropertySet, Ellipse
from esys.escript import getMPIWorldMax, getMPIRankWorld
from transformations import DEG

class Design(design.Design):
    """
    Design for gmsh.
    """
    DELAUNAY="iso"
    NETGEN="netgen"
    TETGEN="tetgen"

    def __init__(self,dim=3,element_size=1.,order=1,keep_files=False):
       """
       Initializes the gmsh design.

       :param dim: spatial dimension
       :param element_size: global element size
       :param order: element order
       :param keep_files: flag to keep work files
       """
       design.Design.__init__(self,dim=dim,element_size=element_size,order=order,keep_files=keep_files)
       self.setScriptFileName()
       self.setMeshFileName()
       self.setOptions()
       self.setFileFormat(self.GMSH)

    def setScriptFileName(self,name=None):
       """
       Sets the filename for the gmsh input script. If no name is given a name
       with extension I{geo} is generated.
       """
       if name == None:
           tmp_f_id=tempfile.mkstemp(suffix=".geo")
           self.__scriptname=tmp_f_id[1]
           os.close(tmp_f_id[0])
       else:
           self.__scriptname=name
           self.setKeepFilesOn()

    def getScriptFileName(self):
       """
       Returns the name of the gmsh script file.
       """
       return self.__scriptname

    def getMeshFileName(self):
       """
       Returns the name of the gmsh mesh file.
       """
       return self.__mshname

    def setOptions(self,algorithm=None,optimize_quality=True,smoothing=1, curvature_based_element_size=False):
        """
        Sets options for the mesh generator.
        """
        if curvature_based_element_size:
              print "information: gmsh does not support curvature based element size anymore. Option ignored."
        if algorithm==None: algorithm=self.DELAUNAY
        self.__algo=algorithm
        self.__optimize_quality=optimize_quality
        self.__smoothing=smoothing

    def __del__(self):
        """
        Cleans up.
        """
        if not self.keepFiles() :
            os.unlink(self.getScriptFileName())
            os.unlink(self.getMeshFileName())

    def getCommandString(self):
        """
        Returns the gmsh command line.
        """
        if self.__optimize_quality:
              opt="-optimize "
        else:
              opt=""

        exe="gmsh -format %s -%s -algo %s -smooth %s %s-v 3 -order %s -o %s %%s" % (
                self.getFileFormat(), 
                self.getDim(), self.__algo, self.__smoothing, opt,
                self.getElementOrder(), self.getMeshFileName())
        return exe
    def getScriptHandler(self):
        """
        Returns a handler to the script file to generate the geometry.
        In the current implementation a script file name is returned.
        """
        if getMPIRankWorld() == 0:
            open(self.getScriptFileName(),"w").write(self.getScriptString())
        return self.getScriptFileName()

    def getMeshHandler(self):
        """
        Returns a handle to a mesh meshing the design. In the current
        implementation a mesh file name in gmsh format is returned.
        """
        cmd = self.getCommandString()%self.getScriptHandler()
        if getMPIRankWorld() == 0:
            ret = os.system(cmd) / 256
        else:
            ret=0
        ret=getMPIWorldMax(ret)
        if ret > 0: raise RuntimeError, "Could not build mesh: %s"%cmd
        return self.getMeshFileName()

        
    def getScriptString(self):
        """
        Returns the gmsh script to generate the mesh.
        """
        h=self.getElementSize()
        out='// generated by esys.pycad\nGeneral.Terminal = 1;\n'
        for prim in self.getAllPrimitives():
           p=prim.getUnderlyingPrimitive()
           if isinstance(p, Point):
               c=p.getCoordinates()
               out+="Point(%s) = {%s , %s, %s , %s };\n"%(p.getID(),c[0],c[1],c[2], p.getLocalScale()*h)

           elif isinstance(p, Spline):
               out+="Spline(%s) = {%s};\n"%(p.getID(),self.__mkArgs(p.getControlPoints()))+self.__mkTransfiniteLine(p)

           elif isinstance(p, BezierCurve):
               out+="Bezier(%s) = {%s};\n"%(p.getID(),self.__mkArgs(p.getControlPoints()))+self.__mkTransfiniteLine(p)

           elif isinstance(p, BSpline):
               out+="BSpline(%s) = {%s};\n"%(p.getID(),self.__mkArgs(p.getControlPoints()))+self.__mkTransfiniteLine(p)

           elif isinstance(p, Line):
               out+="Line(%s) = {%s, %s};\n"%(p.getID(),p.getStartPoint().getDirectedID(),p.getEndPoint().getDirectedID())+self.__mkTransfiniteLine(p)

           elif isinstance(p, Arc):
              out+="Circle(%s) = {%s, %s, %s};\n"%(p.getID(),p.getStartPoint().getDirectedID(),p.getCenterPoint().getDirectedID(),p.getEndPoint().getDirectedID())+self.__mkTransfiniteLine(p)

           elif isinstance(p, Ellipse):
              out+="Ellipse(%s) = {%s, %s, %s, %s};\n"%(p.getID(),p.getStartPoint().getDirectedID(),p.getCenterPoint().getDirectedID(),p.getPointOnMainAxis().getDirectedID(), p.getEndPoint().getDirectedID())+self.__mkTransfiniteLine(p)

           elif isinstance(p, CurveLoop):
               out+="Line Loop(%s) = {%s};\n"%(p.getID(),self.__mkArgs(p.getCurves()))

           elif isinstance(p, RuledSurface):
               out+="Ruled Surface(%s) = {%s};\n"%(p.getID(),p.getBoundaryLoop().getDirectedID())+self.__mkTransfiniteSurface(p)

           elif isinstance(p, PlaneSurface):
               line=self.__mkArgs(p.getHoles())
               if len(line)>0:
                 out+="Plane Surface(%s) = {%s, %s};\n"%(p.getID(),p.getBoundaryLoop().getDirectedID(), line)+self.__mkTransfiniteSurface(p)
               else:
                 out+="Plane Surface(%s) = {%s};\n"%(p.getID(),p.getBoundaryLoop().getDirectedID())+self.__mkTransfiniteSurface(p)

           elif isinstance(p, SurfaceLoop):
               out+="Surface Loop(%s) = {%s};\n"%(p.getID(),self.__mkArgs(p.getSurfaces()))

           elif isinstance(p, Volume):
               line=self.__mkArgs(p.getHoles())
               if len(line)>0:
                 out+="Volume(%s) = {%s, %s};\n"%(p.getID(),p.getSurfaceLoop().getDirectedID(), line)+self.__mkTransfiniteVolume(p)
               else:
                 out+="Volume(%s) = {%s};\n"%(p.getID(),p.getSurfaceLoop().getDirectedID())+self.__mkTransfiniteVolume(p)

           elif isinstance(p, PropertySet):
               if p.getNumItems()>0:
                  dim=p.getDim()
                  line="Physical "
                  if dim==0:
                      line+="Point"
                  elif dim==1:
                      line+="Line"
                  elif dim==2:
                      line+="Surface"
                  else:
                      line+="Volume"
                  out+=line+"(" + str(p.getID()) + ") = {"+self.__mkArgs(p.getItems(),useAbs=True)+"};\n"

           else:
               raise TypeError("unable to pass %s object to gmsh."%str(type(p)))
        return out


    def __mkArgs(self,args, useAbs=False):
        line=""
        for i in args:
            id = i.getDirectedID()
            if useAbs: id=abs(id)
            if len(line)>0:
                line+=", %s"%id
            else:
                line="%s"%id
        return line

    def __mkTransfiniteLine(self,p):
          s=p.getElementDistribution()
          if not s == None:
              if s[2]:
                  out="Transfinite Line{%d} = %d Using Bump %s;\n"%(p.getID(),s[0],s[1])
              else:
                  out="Transfinite Line{%d} = %d Using Progression %s;\n"%(p.getID(),s[0],s[1])
          else:
               out=""
          return out
    def __mkTransfiniteSurface(self,p):
         out=""
         o=p.getRecombination()
         s=p.getTransfiniteMeshing()
         if not s == None:
             out2=""
             if not s[0] == None:
               for q in s[0]:
                  if len(out2)==0:
                      out2="%s"%q.getID()
                  else:
                      out2="%s,%s"%(out2,q.getID())
             if s[1] == None:
                out+="Transfinite Surface{%s} = {%s};\n"%(p.getID(),out2)
             else:
                out+="Transfinite Surface{%s} = {%s} %s;\n"%(p.getID(),out2,s[1])
         if not o == None:
           out+="Recombine Surface {%s} = %s;\n"%(p.getID(),o/DEG)
         return out
    def __mkTransfiniteVolume(self,p):
         out=""
         s=p.getTransfiniteMeshing()
         if not s == None:
             if len(s)>0:
            out2=""
                for q in s[0]:
            if len(out2)==0:
                out2="%s"%q.getID()
            else:
                 out2="%s,%s"%(out2,q.getID())
            out+="Transfinite Volume{%s} = {%s};\n"%(p.getID(),out2)
         else:
            out+="Transfinite Volume{%s};\n"%(p.getID(),)
         return out
     
1	# -- coding: utf-8 --
2
3	########################################################
4	#
5	# Copyright (c) 2003-2010 by University of Queensland
6	# Earth Systems Science Computational Center (ESSCC)
7	# http://www.uq.edu.au/esscc
8	#
9	# Primary Business: Queensland, Australia
10	# Licensed under the Open Software License version 3.0
11	# http://www.opensource.org/licenses/osl-3.0.php
12	#
13	########################################################
14
15	__copyright__="""Copyright (c) 2003-2010 by University of Queensland
16	Earth Systems Science Computational Center (ESSCC)
17	http://www.uq.edu.au/esscc
18	Primary Business: Queensland, Australia"""
19	__license__="""Licensed under the Open Software License version 3.0
20	http://www.opensource.org/licenses/osl-3.0.php"""
21	__url__="https://launchpad.net/escript-finley"
22
23	"""
24	mesh generation using gmsh
25
26	:var __author__: name of author
27	:var __copyright__: copyrights
28	:var __license__: licence agreement
29	:var __url__: url entry point on documentation
30	:var __version__: version
31	:var __date__: date of the version
32	"""
33
34	__author__="Lutz Gross, l.gross@uq.edu.au"
35
36	import design
37	import tempfile
38	import os
39	from primitives import Point, Spline, BezierCurve, BSpline, Line, Arc, CurveLoop, RuledSurface, PlaneSurface, SurfaceLoop, Volume, PropertySet, Ellipse
40	from esys.escript import getMPIWorldMax, getMPIRankWorld
41	from transformations import DEG
42
43	class Design(design.Design):
44	"""
45	Design for gmsh.
46	"""
47	DELAUNAY="iso"
48	NETGEN="netgen"
49	TETGEN="tetgen"
50
51	def __init__(self,dim=3,element_size=1.,order=1,keep_files=False):
52	"""
53	Initializes the gmsh design.
54
55	:param dim: spatial dimension
56	:param element_size: global element size
57	:param order: element order
58	:param keep_files: flag to keep work files
59	"""
60	design.Design.__init__(self,dim=dim,element_size=element_size,order=order,keep_files=keep_files)
61	self.setScriptFileName()
62	self.setMeshFileName()
63	self.setOptions()
64	self.setFileFormat(self.GMSH)
65
66	def setScriptFileName(self,name=None):
67	"""
68	Sets the filename for the gmsh input script. If no name is given a name
69	with extension I{geo} is generated.
70	"""
71	if name == None:
72	tmp_f_id=tempfile.mkstemp(suffix=".geo")
73	self.__scriptname=tmp_f_id[1]
74	os.close(tmp_f_id[0])
75	else:
76	self.__scriptname=name
77	self.setKeepFilesOn()
78
79	def getScriptFileName(self):
80	"""
81	Returns the name of the gmsh script file.
82	"""
83	return self.__scriptname
84
85	def getMeshFileName(self):
86	"""
87	Returns the name of the gmsh mesh file.
88	"""
89	return self.__mshname
90
91	def setOptions(self,algorithm=None,optimize_quality=True,smoothing=1, curvature_based_element_size=False):
92	"""
93	Sets options for the mesh generator.
94	"""
95	if curvature_based_element_size:
96	print "information: gmsh does not support curvature based element size anymore. Option ignored."
97	if algorithm==None: algorithm=self.DELAUNAY
98	self.__algo=algorithm
99	self.__optimize_quality=optimize_quality
100	self.__smoothing=smoothing
101
102	def __del__(self):
103	"""
104	Cleans up.
105	"""
106	if not self.keepFiles() :
107	os.unlink(self.getScriptFileName())
108	os.unlink(self.getMeshFileName())
109
110	def getCommandString(self):
111	"""
112	Returns the gmsh command line.
113	"""
114	if self.__optimize_quality:
115	opt="-optimize "
116	else:
117	opt=""
118
119	exe="gmsh -format %s -%s -algo %s -smooth %s %s-v 3 -order %s -o %s %%s" % (
120	self.getFileFormat(),
121	self.getDim(), self.__algo, self.__smoothing, opt,
122	self.getElementOrder(), self.getMeshFileName())
123	return exe
124	def getScriptHandler(self):
125	"""
126	Returns a handler to the script file to generate the geometry.
127	In the current implementation a script file name is returned.
128	"""
129	if getMPIRankWorld() == 0:
130	open(self.getScriptFileName(),"w").write(self.getScriptString())
131	return self.getScriptFileName()
132
133	def getMeshHandler(self):
134	"""
135	Returns a handle to a mesh meshing the design. In the current
136	implementation a mesh file name in gmsh format is returned.
137	"""
138	cmd = self.getCommandString()%self.getScriptHandler()
139	if getMPIRankWorld() == 0:
140	ret = os.system(cmd) / 256
141	else:
142	ret=0
143	ret=getMPIWorldMax(ret)
144	if ret > 0: raise RuntimeError, "Could not build mesh: %s"%cmd
145	return self.getMeshFileName()
146
147
148	def getScriptString(self):
149	"""
150	Returns the gmsh script to generate the mesh.
151	"""
152	h=self.getElementSize()
153	out='// generated by esys.pycad\nGeneral.Terminal = 1;\n'
154	for prim in self.getAllPrimitives():
155	p=prim.getUnderlyingPrimitive()
156	if isinstance(p, Point):
157	c=p.getCoordinates()
158	out+="Point(%s) = {%s , %s, %s , %s };\n"%(p.getID(),c[0],c[1],c[2], p.getLocalScale()*h)
159
160	elif isinstance(p, Spline):
161	out+="Spline(%s) = {%s};\n"%(p.getID(),self.__mkArgs(p.getControlPoints()))+self.__mkTransfiniteLine(p)
162
163	elif isinstance(p, BezierCurve):
164	out+="Bezier(%s) = {%s};\n"%(p.getID(),self.__mkArgs(p.getControlPoints()))+self.__mkTransfiniteLine(p)
165
166	elif isinstance(p, BSpline):
167	out+="BSpline(%s) = {%s};\n"%(p.getID(),self.__mkArgs(p.getControlPoints()))+self.__mkTransfiniteLine(p)
168
169	elif isinstance(p, Line):
170	out+="Line(%s) = {%s, %s};\n"%(p.getID(),p.getStartPoint().getDirectedID(),p.getEndPoint().getDirectedID())+self.__mkTransfiniteLine(p)
171
172	elif isinstance(p, Arc):
173	out+="Circle(%s) = {%s, %s, %s};\n"%(p.getID(),p.getStartPoint().getDirectedID(),p.getCenterPoint().getDirectedID(),p.getEndPoint().getDirectedID())+self.__mkTransfiniteLine(p)
174
175	elif isinstance(p, Ellipse):
176	out+="Ellipse(%s) = {%s, %s, %s, %s};\n"%(p.getID(),p.getStartPoint().getDirectedID(),p.getCenterPoint().getDirectedID(),p.getPointOnMainAxis().getDirectedID(), p.getEndPoint().getDirectedID())+self.__mkTransfiniteLine(p)
177
178	elif isinstance(p, CurveLoop):
179	out+="Line Loop(%s) = {%s};\n"%(p.getID(),self.__mkArgs(p.getCurves()))
180
181	elif isinstance(p, RuledSurface):
182	out+="Ruled Surface(%s) = {%s};\n"%(p.getID(),p.getBoundaryLoop().getDirectedID())+self.__mkTransfiniteSurface(p)
183
184	elif isinstance(p, PlaneSurface):
185	line=self.__mkArgs(p.getHoles())
186	if len(line)>0:
187	out+="Plane Surface(%s) = {%s, %s};\n"%(p.getID(),p.getBoundaryLoop().getDirectedID(), line)+self.__mkTransfiniteSurface(p)
188	else:
189	out+="Plane Surface(%s) = {%s};\n"%(p.getID(),p.getBoundaryLoop().getDirectedID())+self.__mkTransfiniteSurface(p)
190
191	elif isinstance(p, SurfaceLoop):
192	out+="Surface Loop(%s) = {%s};\n"%(p.getID(),self.__mkArgs(p.getSurfaces()))
193
194	elif isinstance(p, Volume):
195	line=self.__mkArgs(p.getHoles())
196	if len(line)>0:
197	out+="Volume(%s) = {%s, %s};\n"%(p.getID(),p.getSurfaceLoop().getDirectedID(), line)+self.__mkTransfiniteVolume(p)
198	else:
199	out+="Volume(%s) = {%s};\n"%(p.getID(),p.getSurfaceLoop().getDirectedID())+self.__mkTransfiniteVolume(p)
200
201	elif isinstance(p, PropertySet):
202	if p.getNumItems()>0:
203	dim=p.getDim()
204	line="Physical "
205	if dim==0:
206	line+="Point"
207	elif dim==1:
208	line+="Line"
209	elif dim==2:
210	line+="Surface"
211	else:
212	line+="Volume"
213	out+=line+"(" + str(p.getID()) + ") = {"+self.__mkArgs(p.getItems(),useAbs=True)+"};\n"
214
215	else:
216	raise TypeError("unable to pass %s object to gmsh."%str(type(p)))
217	return out
218
219
220	def __mkArgs(self,args, useAbs=False):
221	line=""
222	for i in args:
223	id = i.getDirectedID()
224	if useAbs: id=abs(id)
225	if len(line)>0:
226	line+=", %s"%id
227	else:
228	line="%s"%id
229	return line
230
231	def __mkTransfiniteLine(self,p):
232	s=p.getElementDistribution()
233	if not s == None:
234	if s[2]:
235	out="Transfinite Line{%d} = %d Using Bump %s;\n"%(p.getID(),s[0],s[1])
236	else:
237	out="Transfinite Line{%d} = %d Using Progression %s;\n"%(p.getID(),s[0],s[1])
238	else:
239	out=""
240	return out
241	def __mkTransfiniteSurface(self,p):
242	out=""
243	o=p.getRecombination()
244	s=p.getTransfiniteMeshing()
245	if not s == None:
246	out2=""
247	if not s[0] == None:
248	for q in s[0]:
249	if len(out2)==0:
250	out2="%s"%q.getID()
251	else:
252	out2="%s,%s"%(out2,q.getID())
253	if s[1] == None:
254	out+="Transfinite Surface{%s} = {%s};\n"%(p.getID(),out2)
255	else:
256	out+="Transfinite Surface{%s} = {%s} %s;\n"%(p.getID(),out2,s[1])
257	if not o == None:
258	out+="Recombine Surface {%s} = %s;\n"%(p.getID(),o/DEG)
259	return out
260	def __mkTransfiniteVolume(self,p):
261	out=""
262	s=p.getTransfiniteMeshing()
263	if not s == None:
264	if len(s)>0:
265	out2=""
266	for q in s[0]:
267	if len(out2)==0:
268	out2="%s"%q.getID()
269	else:
270	out2="%s,%s"%(out2,q.getID())
271	out+="Transfinite Volume{%s} = {%s};\n"%(p.getID(),out2)
272	else:
273	out+="Transfinite Volume{%s};\n"%(p.getID(),)
274	return out
275