#!/usr/bin/env python import sys,os,pwd,math,re,string,msc_tools from optparse import OptionParser sys.path.append(msc_tools.MSC_TOOLS().library_paths(sys.argv[0],'../../')) try: from py_mentat import * except: print('error: no valid Mentat release found') sys.exit(-1) def outMentat(cmd,locals): if cmd[0:3] == '(!)': exec(cmd[3:]) elif cmd[0:3] == '(?)': cmd = eval(cmd[3:]) py_send(cmd) else: py_send(cmd) return def outStdout(cmd,locals): if cmd[0:3] == '(!)': exec(cmd[3:]) elif cmd[0:3] == '(?)': cmd = eval(cmd[3:]) print cmd else: print cmd return def output(cmds,locals,dest): for cmd in cmds: if isinstance(cmd,list): output(cmd,locals,dest) else: {\ 'Mentat': outMentat,\ 'Stdout': outStdout,\ }[dest](cmd,locals) return def servoLink(): cmds = [] base = ['x','y','z'] box = {'min': {'x': float(sys.maxint),'y': float(sys.maxint),'z': float(sys.maxint)}, 'max': {'x':-float(sys.maxint),'y':-float(sys.maxint),'z':-float(sys.maxint)}, 'delta': {'x':0,'y':0,'z':0}, } Nnodes = py_get_int("nnodes()") NodeCoords = [{'x':py_get_float("node_x(%i)"%(node)), 'y':py_get_float("node_y(%i)"%(node)), 'z':py_get_float("node_z(%i)"%(node)),} for node in range(1,1+Nnodes)] for node in range(Nnodes): # find the bounding box for coord in base: # check each direction in turn box['min'][coord] = min(box['min'][coord],NodeCoords[node][coord]) box['max'][coord] = max(box['max'][coord],NodeCoords[node][coord]) for coord in base: # calc the dimension of the bounding box box['delta'][coord] = box['max'][coord] - box['min'][coord] baseNode = {} linkNodes = [] for node in range(Nnodes): # loop over all nodes pos = {} key = {} maxFlag = {'x': False, 'y': False, 'z': False} Nmax = 0 Nmin = 0 for coord in base: # for each direction key[coord] = "%.8e"%NodeCoords[node][coord] # translate position to string if (key[coord] == "%.8e"%box['min'][coord]): # compare to min of bounding box (i.e. is on outer face?) Nmin += 1 # count outer (back) face membership elif (key[coord] == "%.8e"%box['max'][coord]): # compare to max of bounding box (i.e. is on outer face?) Nmax += 1 # count outer (front) face memebership maxFlag[coord] = True # remember face membership (for linked nodes) if Nmin > 0 and Nmin > Nmax: # node is on more back than font faces # prepare for any non-existing entries in the data structure if key['x'] not in baseNode.keys(): baseNode[key['x']] = {} if key['y'] not in baseNode[key['x']].keys(): baseNode[key['x']][key['y']] = {} if key['z'] not in baseNode[key['x']][key['y']].keys(): baseNode[key['x']][key['y']][key['z']] = 0 baseNode[key['x']][key['y']][key['z']] = node+1 # remember the base node id elif Nmax > 0 and Nmax >= Nmin: # node is on at least as many front than back faces linkNodes.append({'id': node+1,'coord': NodeCoords[node], 'onFaces': Nmax,'faceMember': maxFlag}) baseCorner = baseNode["%.8e"%box['min']['x']]["%.8e"%box['min']['y']]["%.8e"%box['min']['z']] # detect ultimate base node for node in linkNodes: # loop over all linked nodes linkCoord = [node['coord']] # start list of control node coords with my coords for dir in base: # check for each direction if node['faceMember'][dir]: # me on this front face linkCoord[0][dir] = box['min'][dir] # project me onto rear face along dir linkCoord.append({'x':box['min']['x'],'y':box['min']['y'],'z':box['min']['z'],}) # append base corner linkCoord[-1][dir] = box['max'][dir] # stretch it to corresponding control leg of "dir" nLinks = len(linkCoord) for dof in [1,2,3]: cmds.append([ "*new_link *link_class servo", "*link_class servo *tied_node %i"%node['id'], "*link_class servo *tied_dof %i"%dof, "*servo_nterms %i"%(1+nLinks), ]) for i in range(nLinks): cmds.append([ "*link_class servo *servo_ret_node %i %i"%(i+1,baseNode["%.8e"%linkCoord[i]['x']]["%.8e"%linkCoord[i]['y']]["%.8e"%linkCoord[i]['z']]), "*link_class servo *servo_ret_dof %i %i"%(i+1,dof), "*link_class servo *servo_ret_coef %i 1"%(i+1), ]) cmds.append([ "*link_class servo *servo_ret_node %i %i"%(1+nLinks,baseCorner), "*link_class servo *servo_ret_dof %i %i"%(1+nLinks,dof), "*link_class servo *servo_ret_coef %i -%i"%(1+nLinks,nLinks-1), ]) cmds.append([ "*select_nodes", ["%i"%node['id'] for node in linkNodes], "#", ]) return cmds # ----------------------- MAIN ------------------------------- parser = OptionParser(usage='%prog [options]', description = """ Set up servo linking to achieve periodic boundary conditions for a regular hexahedral mesh presently opened in MSC.Mentat """ + string.replace('$Id$','\n','\\n') ) parser.add_option("-p", "--port", type="int",\ dest="port",\ help="Mentat connection port [%default]") parser.add_option("-v", "--verbose", action="store_true",\ dest="verbose",\ help="write Mentat command stream also to stdout [%default]") parser.set_defaults(port = 40007) parser.set_defaults(verbose = False) (options, args) = parser.parse_args() outputLocals = {} print 'waiting to connect...' py_connect('',options.port) output([\ '*remove_all_servos', '*sweep_all', '*renumber_nodes', '*set_links off', ],outputLocals,'Mentat') # script depends on consecutive numbering of nodes cmds = servoLink() print 'connected...' output(cmds,outputLocals,'Mentat') output([\ '*set_links on', '*draw', ],outputLocals,'Mentat') # script depends on consecutive numbering of nodes py_disconnect() if options.verbose: output(cmds,outputLocals,'Stdout')