264 lines
12 KiB
Python
264 lines
12 KiB
Python
# ***************************************************************************
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# * *
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# * Copyright (c) 2017 - Markus Hovorka <m.hovorka@live.de> *
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# * Copyright (c) 2017 - Bernd Hahnebach <bernd@bimstatik.org> *
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# * *
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# * This program is free software; you can redistribute it and/or modify *
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# * it under the terms of the GNU Lesser General Public License (LGPL) *
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# * as published by the Free Software Foundation; either version 2 of *
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# * the License, or (at your option) any later version. *
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# * for detail see the LICENCE text file. *
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# * *
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# * This program is distributed in the hope that it will be useful, *
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# * but WITHOUT ANY WARRANTY; without even the implied warranty of *
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# * MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the *
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# * GNU Library General Public License for more details. *
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# * *
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# * You should have received a copy of the GNU Library General Public *
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# * License along with this program; if not, write to the Free Software *
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# * Foundation, Inc., 59 Temple Place, Suite 330, Boston, MA 02111-1307 *
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# * USA *
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# * *
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# ***************************************************************************
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__title__ = "CalculiX Tasks"
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__author__ = "Markus Hovorka, Bernd Hahnebach"
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__url__ = "http://www.freecadweb.org"
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import os
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import subprocess
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import os.path
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import FreeCAD as App
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import FemUtils
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import importCcxFrdResults
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import importCcxDatResults
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from .. import run
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from .. import settings
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from . import writer
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_inputFileName = None
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class Check(run.Check):
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def run(self):
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self.pushStatus("Checking analysis...\n")
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self.checkMesh()
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self.checkMaterial()
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class Prepare(run.Prepare):
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def run(self):
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global _inputFileName
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self.pushStatus("Preparing input files...\n")
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c = _Container(self.analysis)
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w = writer.FemInputWriterCcx(
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self.analysis, self.solver, c.mesh, c.materials_linear,
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c.materials_nonlinear, c.fixed_constraints,
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c.displacement_constraints, c.contact_constraints,
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c.planerotation_constraints, c.transform_constraints,
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c.selfweight_constraints, c.force_constraints,
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c.pressure_constraints, c.temperature_constraints,
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c.heatflux_constraints, c.initialtemperature_constraints,
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c.beam_sections, c.shell_thicknesses, c.fluid_sections,
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self.solver.AnalysisType, self.directory)
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path = w.write_calculix_input_file()
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_inputFileName = os.path.splitext(os.path.basename(path))[0]
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class Solve(run.Solve):
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def run(self):
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self.pushStatus("Executing solver...\n")
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binary = settings.getBinary("Calculix")
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self._process = subprocess.Popen(
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[binary, "-i", _inputFileName],
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cwd=self.directory,
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stdout=subprocess.PIPE,
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stderr=subprocess.PIPE)
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self.signalAbort.add(self._process.terminate)
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output = self._observeSolver(self._process)
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self._process.communicate()
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self.signalAbort.remove(self._process.terminate)
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# if not self.aborted:
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# self._updateOutput(output)
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del output # get flake8 quiet
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def _observeSolver(self, process):
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output = ""
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line = process.stdout.readline()
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self.pushStatus(line)
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output += line
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line = process.stdout.readline()
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while line:
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line = "\n%s" % line.rstrip()
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self.pushStatus(line)
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output += line
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line = process.stdout.readline()
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return output
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class Results(run.Results):
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def run(self):
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prefs = App.ParamGet(
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"User parameter:BaseApp/Preferences/Mod/Fem/General")
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if not prefs.GetBool("KeepResultsOnReRun", False):
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self.purge_results()
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self.load_results_ccxfrd()
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self.load_results_ccxdat()
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def purge_results(self):
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for m in FemUtils.getMember(self.analysis, "Fem::FemResultObject"):
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if FemUtils.isOfType(m.Mesh, "FemMeshResult"):
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self.analysis.Document.removeObject(m.Mesh.Name)
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self.analysis.Document.removeObject(m.Name)
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App.ActiveDocument.recompute()
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def load_results_ccxfrd(self):
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frd_result_file = os.path.join(
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self.directory, _inputFileName + '.frd')
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if os.path.isfile(frd_result_file):
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result_name_prefix = 'CalculiX_' + self.solver.AnalysisType + '_'
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importCcxFrdResults.importFrd(
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frd_result_file, self.analysis, result_name_prefix)
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else:
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raise Exception(
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'FEM: No results found at {}!'.format(frd_result_file))
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def load_results_ccxdat(self):
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dat_result_file = os.path.join(
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self.directory, _inputFileName + '.dat')
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if os.path.isfile(dat_result_file):
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mode_frequencies = importCcxDatResults.import_dat(
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dat_result_file, self.analysis)
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else:
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raise Exception(
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'FEM: No .dat results found at {}!'.format(dat_result_file))
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if mode_frequencies:
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for m in FemUtils.getMember(self.analysis, "Fem::FemResultObject"):
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if m.Eigenmode > 0:
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for mf in mode_frequencies:
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if m.Eigenmode == mf['eigenmode']:
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m.EigenmodeFrequency = mf['frequency']
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class _Container(object):
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def __init__(self, analysis):
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self.mesh = None
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self.materials_linear = []
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self.materials_nonlinear = []
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self.fixed_constraints = []
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self.selfweight_constraints = []
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self.force_constraints = []
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self.pressure_constraints = []
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self.beam_sections = []
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self.fluid_sections = []
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self.shell_thicknesses = []
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self.displacement_constraints = []
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self.temperature_constraints = []
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self.heatflux_constraints = []
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self.initialtemperature_constraints = []
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self.planerotation_constraints = []
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self.contact_constraints = []
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self.transform_constraints = []
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for m in analysis.Member:
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if m.isDerivedFrom("Fem::FemMeshObject"):
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if not self.mesh:
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self.mesh = m
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else:
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raise Exception('FEM: Multiple mesh in analysis not yet supported!')
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elif m.isDerivedFrom("App::MaterialObjectPython"):
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material_linear_dict = {}
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material_linear_dict['Object'] = m
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self.materials_linear.append(material_linear_dict)
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elif hasattr(m, "Proxy") and m.Proxy.Type == "FemMaterialMechanicalNonlinear":
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material_nonlinear_dict = {}
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material_nonlinear_dict['Object'] = m
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self.materials_nonlinear.append(material_nonlinear_dict)
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elif m.isDerivedFrom("Fem::ConstraintFixed"):
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fixed_constraint_dict = {}
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fixed_constraint_dict['Object'] = m
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self.fixed_constraints.append(fixed_constraint_dict)
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elif hasattr(m, "Proxy") and m.Proxy.Type == "FemConstraintSelfWeight":
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selfweight_dict = {}
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selfweight_dict['Object'] = m
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self.selfweight_constraints.append(selfweight_dict)
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elif m.isDerivedFrom("Fem::ConstraintForce"):
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force_constraint_dict = {}
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force_constraint_dict['Object'] = m
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force_constraint_dict['RefShapeType'] = self.get_refshape_type(m)
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self.force_constraints.append(force_constraint_dict)
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elif m.isDerivedFrom("Fem::ConstraintPressure"):
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PressureObjectDict = {}
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PressureObjectDict['Object'] = m
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self.pressure_constraints.append(PressureObjectDict)
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elif m.isDerivedFrom("Fem::ConstraintDisplacement"):
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displacement_constraint_dict = {}
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displacement_constraint_dict['Object'] = m
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self.displacement_constraints.append(displacement_constraint_dict)
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elif m.isDerivedFrom("Fem::ConstraintTemperature"):
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temperature_constraint_dict = {}
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temperature_constraint_dict['Object'] = m
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self.temperature_constraints.append(temperature_constraint_dict)
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elif m.isDerivedFrom("Fem::ConstraintHeatflux"):
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heatflux_constraint_dict = {}
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heatflux_constraint_dict['Object'] = m
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self.heatflux_constraints.append(heatflux_constraint_dict)
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elif m.isDerivedFrom("Fem::ConstraintInitialTemperature"):
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initialtemperature_constraint_dict = {}
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initialtemperature_constraint_dict['Object'] = m
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self.initialtemperature_constraints.append(
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initialtemperature_constraint_dict)
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elif m.isDerivedFrom("Fem::ConstraintPlaneRotation"):
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planerotation_constraint_dict = {}
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planerotation_constraint_dict['Object'] = m
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self.planerotation_constraints.append(planerotation_constraint_dict)
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elif m.isDerivedFrom("Fem::ConstraintContact"):
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contact_constraint_dict = {}
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contact_constraint_dict['Object'] = m
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self.contact_constraints.append(contact_constraint_dict)
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elif m.isDerivedFrom("Fem::ConstraintTransform"):
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transform_constraint_dict = {}
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transform_constraint_dict['Object'] = m
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self.transform_constraints.append(transform_constraint_dict)
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elif hasattr(m, "Proxy") and m.Proxy.Type == "FemElementGeometry1D":
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beam_section_dict = {}
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beam_section_dict['Object'] = m
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self.beam_sections.append(beam_section_dict)
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elif hasattr(m, "Proxy") and m.Proxy.Type == "FemElementFluid1D":
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fluid_section_dict = {}
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fluid_section_dict['Object'] = m
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self.fluid_sections.append(fluid_section_dict)
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elif hasattr(m, "Proxy") and m.Proxy.Type == "FemElementGeometry2D":
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shell_thickness_dict = {}
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shell_thickness_dict['Object'] = m
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self.shell_thicknesses.append(shell_thickness_dict)
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def get_refshape_type(self, fem_doc_object):
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# returns the reference shape type
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# for force object:
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# in GUI defined frc_obj all frc_obj have at leas one ref_shape and ref_shape have all the same shape type
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# for material object:
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# in GUI defined material_obj could have no RefShape and RefShapes could be different type
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# we gone need the RefShapes to be the same type inside one fem_doc_object
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# TODO here: check if all RefShapes inside the object really have the same type
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import FemMeshTools
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if hasattr(fem_doc_object, 'References') and fem_doc_object.References:
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first_ref_obj = fem_doc_object.References[0]
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first_ref_shape = FemMeshTools.get_element(first_ref_obj[0], first_ref_obj[1][0])
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st = first_ref_shape.ShapeType
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print(fem_doc_object.Name + ' has ' + st + ' reference shapes.')
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return st
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else:
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print(fem_doc_object.Name + ' has empty References.')
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return ''
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