# *************************************************************************** # * Copyright (c) 2015 Qingfeng Xia * # * Copyright (c) 2016 Bernd Hahnebach * # * Copyright (c) 2024 PMcB * # * Copyright (c) 2025 PMcB * # * * # * This file is part of the FreeCAD CAx development system. * # * * # * This program is free software; you can redistribute it and/or modify * # * it under the terms of the GNU Lesser General Public License (LGPL) * # * as published by the Free Software Foundation; either version 2 of * # * the License, or (at your option) any later version. * # * for detail see the LICENCE text file. * # * * # * This program is distributed in the hope that it will be useful, * # * but WITHOUT ANY WARRANTY; without even the implied warranty of * # * MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the * # * GNU Library General Public License for more details. * # * * # * You should have received a copy of the GNU Library General Public * # * License along with this program; if not, write to the Free Software * # * Foundation, Inc., 59 Temple Place, Suite 330, Boston, MA 02111-1307 * # * USA * # * * # *************************************************************************** __title__ = "FreeCAD result mechanical task panel" __author__ = "Qingfeng Xia, Bernd Hahnebach" __url__ = "https://www.freecad.org" ## @package view_result_mechanical # \ingroup FEM # \brief task panel for mechanical ResultObjectPython import CreateLabels import inspect, sys try: import matplotlib matplotlib.use("Qt5Agg") except Exception: print("Failed to set matplotlib backend to Qt5Agg") import matplotlib.pyplot as plt import numpy as np import time, math from PySide import QtCore from PySide import QtGui from PySide.QtCore import Qt from PySide.QtGui import QApplication import FreeCAD import FreeCADGui import femresult.resulttools as resulttools translate = FreeCAD.Qt.translate class _TaskPanel: """ The task panel for the post-processing """ def __init__(self, obj): self.result_obj = obj self.mesh_obj = self.result_obj.Mesh # task panel should be started by use of setEdit of view provider # in view provider checks: Mesh, active analysis and # if Mesh and result are in active analysis # activate the result mesh object self.mesh_obj.ViewObject.show() ui_path = FreeCAD.getHomePath() + "Mod/Fem/Resources/ui/" self.result_widget = FreeCADGui.PySideUic.loadUi(ui_path + "ResultShow.ui") self.info_widget = FreeCADGui.PySideUic.loadUi(ui_path + "ResultHints.ui") self.form = [self.result_widget, self.info_widget] self.results_name = "No Contour Data" self.animate_inc = 1 self.startAnimate = False self.animateText = [] self.slider_max = False self.recurlim = min(200, sys.getrecursionlimit() / 2) self.fem_prefs = FreeCAD.ParamGet("User parameter:BaseApp/Preferences/Mod/Fem/General") self.restore_result_settings_in_dialog = self.fem_prefs.GetBool("RestoreResultDialog", True) # Connect Signals and Slots # result type radio buttons # TODO: move to combo box, to be independent from result types and result types count QtCore.QObject.connect( self.result_widget.rb_none, QtCore.SIGNAL("toggled(bool)"), self.none_selected, ) QtCore.QObject.connect( self.result_widget.rb_abs_displacement, QtCore.SIGNAL("toggled(bool)"), self.abs_displacement_selected, ) QtCore.QObject.connect( self.result_widget.rb_x_displacement, QtCore.SIGNAL("toggled(bool)"), self.x_displacement_selected, ) QtCore.QObject.connect( self.result_widget.rb_y_displacement, QtCore.SIGNAL("toggled(bool)"), self.y_displacement_selected, ) QtCore.QObject.connect( self.result_widget.rb_z_displacement, QtCore.SIGNAL("toggled(bool)"), self.z_displacement_selected, ) QtCore.QObject.connect( self.result_widget.rb_temperature, QtCore.SIGNAL("toggled(bool)"), self.temperature_selected, ) QtCore.QObject.connect( self.result_widget.rb_vm_stress, QtCore.SIGNAL("toggled(bool)"), self.vm_stress_selected, ) QtCore.QObject.connect( self.result_widget.rb_maxprin, QtCore.SIGNAL("toggled(bool)"), self.max_prin_selected, ) QtCore.QObject.connect( self.result_widget.rb_minprin, QtCore.SIGNAL("toggled(bool)"), self.min_prin_selected, ) QtCore.QObject.connect( self.result_widget.rb_max_shear_stress, QtCore.SIGNAL("toggled(bool)"), self.max_shear_selected, ) QtCore.QObject.connect( self.result_widget.rb_massflowrate, QtCore.SIGNAL("toggled(bool)"), self.massflowrate_selected, ) QtCore.QObject.connect( self.result_widget.rb_networkpressure, QtCore.SIGNAL("toggled(bool)"), self.networkpressure_selected, ) QtCore.QObject.connect( self.result_widget.rb_peeq, QtCore.SIGNAL("toggled(bool)"), self.peeq_selected, ) # stats self.result_widget.show_histogram.clicked.connect(self.show_histogram_clicked) # animate QtCore.QObject.connect( self.result_widget.hsb_displacement_factor, QtCore.SIGNAL("valueChanged(int)"), lambda dummy="", name="scale": self.value_changed(self, dummy, name), ) QtCore.QObject.connect( self.result_widget.sb_displacement_factor, QtCore.SIGNAL("valueChanged(double)"), lambda dummy="", name="factor": self.value_changed(self, dummy, name), ) QtCore.QObject.connect( self.result_widget.startButton, QtCore.SIGNAL("clicked()"), lambda dummy="", name="startButton": self.value_changed(self, dummy, name), ) # displacement QtCore.QObject.connect( self.result_widget.cb_show_displacement, QtCore.SIGNAL("clicked(bool)"), self.show_displacement, ) QtCore.QObject.connect( self.result_widget.hsb_displacement_factor, QtCore.SIGNAL("valueChanged(int)"), self.hsb_disp_factor_changed, ) self.result_widget.sb_displacement_factor.valueChanged.connect(self.sb_disp_factor_changed) self.result_widget.sb_displacement_factor_max.valueChanged.connect( self.sb_disp_factor_max_changed ) # user defined equation self.result_widget.user_def_eq.textChanged.connect(self.user_defined_text) QtCore.QObject.connect( self.result_widget.calculate, QtCore.SIGNAL("clicked()"), self.calculate ) self.update() if self.restore_result_settings_in_dialog: self.restore_result_dialog() else: self.restore_initial_result_dialog() # initialize scale factor for show displacement scale_factor = get_displacement_scale_factor(self.result_obj) self.result_widget.sb_displacement_factor_max.setValue(10.0 * scale_factor) self.result_widget.sb_displacement_factor.setValue(scale_factor) def restore_result_dialog(self): try: rt = FreeCAD.FEM_dialog["results_type"] if rt == "None": self.result_widget.rb_none.setChecked(True) self.none_selected(True) elif rt == "Uabs": self.result_widget.rb_abs_displacement.setChecked(True) self.abs_displacement_selected(True) elif rt == "U1": self.result_widget.rb_x_displacement.setChecked(True) self.x_displacement_selected(True) elif rt == "U2": self.result_widget.rb_y_displacement.setChecked(True) self.y_displacement_selected(True) elif rt == "U3": self.result_widget.rb_z_displacement.setChecked(True) self.z_displacement_selected(True) elif rt == "Temp": self.result_widget.rb_temperature.setChecked(True) self.temperature_selected(True) elif rt == "Sabs": self.result_widget.rb_vm_stress.setChecked(True) self.vm_stress_selected(True) elif rt == "MaxPrin": self.result_widget.rb_maxprin.setChecked(True) self.max_prin_selected(True) elif rt == "MinPrin": self.result_widget.rb_minprin.setChecked(True) self.min_prin_selected(True) elif rt == "MaxShear": self.result_widget.rb_max_shear_stress.setChecked(True) self.max_shear_selected(True) elif rt == "MFlow": self.result_widget.rb_massflowrate.setChecked(True) self.massflowrate_selected(True) elif rt == "NPress": self.result_widget.rb_networkpressure.setChecked(True) self.networkpressure_selected(True) elif rt == "Peeq": self.result_widget.rb_peeq.setChecked(True) self.peeq_selected(True) sd = FreeCAD.FEM_dialog["show_disp"] self.result_widget.cb_show_displacement.setChecked(sd) self.show_displacement(sd) df = FreeCAD.FEM_dialog["disp_factor"] dfm = FreeCAD.FEM_dialog["disp_factor_max"] self.result_widget.hsb_displacement_factor.setMaximum(dfm) self.result_widget.hsb_displacement_factor.setValue(df) self.result_widget.sb_displacement_factor_max.setValue(dfm) self.result_widget.sb_displacement_factor.setValue(df) # animate self.startAnimate = False if FreeCAD.FEM_dialog["animate"][0] != -1: self.result_widget.steps.setValue(FreeCAD.FEM_dialog["animate"][0]) self.result_widget.loops.setValue(FreeCAD.FEM_dialog["animate"][1]) self.result_widget.framerate.setValue(FreeCAD.FEM_dialog["animate"][2]) if FreeCAD.FEM_dialog["animate"][3]: self.result_widget.rb_full_cycle.setChecked(True) else: self.result_widget.rb_half_cycle.setChecked(True) self.result_widget.sb_displacement_factor.setValue(FreeCAD.FEM_dialog["animate"][4]) except Exception: self.restore_initial_result_dialog() def restore_initial_result_dialog(self): # initialize FreeCAD.FEM_dialog and set standard values # the FEM result mechanical task panel restore values # are saved in a dictionary which is an attribute of FreeCAD # the name is FEM_dialog # in python console after result task panel has been opened once # FreeCAD.FEM_dialog or FreeCAD.__dir__() # This is not smart at all IMHO (Bernd) # It was added with commit 3a7772d # https://github.com/FreeCAD/FreeCAD/commit/3a7772d FreeCAD.FEM_dialog = { "results_type": "None", "show_disp": True, # False, "disp_factor": 5.0, "disp_factor_max": 100.0, "animate": [-1, -1, -1, -1, -1, -1, -1], # steps, loops, rate, cycle type } self.result_widget.sb_displacement_factor_max.setValue(100.0) # init non standard values def getStandardButtons(self): return QtGui.QDialogButtonBox.Close def get_result_stats(self, type_name): return resulttools.get_stats(self.result_obj, type_name) def none_selected(self, state): self.set_label(self.result_obj.Label, "No Contours") FreeCAD.FEM_dialog["results_type"] = "None" self.set_result_stats("mm", 0.0, 0.0) self.reset_mesh_color() if len(plt.get_fignums()) > 0: plt.close() # if an analysis has different result types and one has # stress and the other not the restore result dialog # could trigger stress selected for a result object # which has not stress # see https://forum.freecad.org/viewtopic.php?f=18&t=39162 # check if the results len is not 0 on any selected method def abs_displacement_selected(self, state): if len(self.result_obj.DisplacementLengths) > 0: self.result_selected( "Uabs", self.result_obj.DisplacementLengths, "mm", translate("FEM", "Displacement magnitude"), ) else: self.result_widget.rb_none.setChecked(True) self.none_selected(True) def x_displacement_selected(self, state): if len(self.result_obj.DisplacementVectors) > 0: res_disp_u1 = self.get_scalar_disp_list(self.result_obj.DisplacementVectors, 0) self.result_selected("U1", res_disp_u1, "mm", translate("FEM", "Displacement X")) else: self.result_widget.rb_none.setChecked(True) self.none_selected(True) def y_displacement_selected(self, state): if len(self.result_obj.DisplacementVectors) > 0: res_disp_u2 = self.get_scalar_disp_list(self.result_obj.DisplacementVectors, 1) self.result_selected("U2", res_disp_u2, "mm", translate("FEM", "Displacement Y")) else: self.result_widget.rb_none.setChecked(True) self.none_selected(True) def z_displacement_selected(self, state): if len(self.result_obj.DisplacementVectors) > 0: res_disp_u3 = self.get_scalar_disp_list(self.result_obj.DisplacementVectors, 2) self.result_selected("U3", res_disp_u3, "mm", translate("FEM", "Displacement Z")) else: self.result_widget.rb_none.setChecked(True) self.none_selected(True) def vm_stress_selected(self, state): if len(self.result_obj.vonMises) > 0: self.result_selected( "Sabs", self.result_obj.vonMises, "MPa", translate("FEM", "von Mises stress"), ) else: self.result_widget.rb_none.setChecked(True) self.none_selected(True) def max_shear_selected(self, state): if len(self.result_obj.MaxShear) > 0: self.result_selected( "MaxShear", self.result_obj.MaxShear, "MPa", translate("FEM", "Maximum shear stress (Tresca)"), ) else: self.result_widget.rb_none.setChecked(True) self.none_selected(True) def max_prin_selected(self, state): if len(self.result_obj.PrincipalMax) > 0: self.result_selected( "MaxPrin", self.result_obj.PrincipalMax, "MPa", translate("FEM", "Maximum principal stress"), ) else: self.result_widget.rb_none.setChecked(True) self.none_selected(True) def temperature_selected(self, state): if len(self.result_obj.Temperature) > 0: self.result_selected( "Temp", self.result_obj.Temperature, "K", translate("FEM", "Temperature"), ) else: self.result_widget.rb_none.setChecked(True) self.none_selected(True) def massflowrate_selected(self, state): if len(self.result_obj.MassFlowRate) > 0: self.result_selected( "MFlow", self.result_obj.MassFlowRate, "kg/s", translate("FEM", "Mass flow rate"), ) else: self.result_widget.rb_none.setChecked(True) self.none_selected(True) def networkpressure_selected(self, state): if len(self.result_obj.NetworkPressure) > 0: self.result_selected( "NPress", self.result_obj.NetworkPressure, "MPa", translate("FEM", "Network pressure"), ) else: self.result_widget.rb_none.setChecked(True) self.none_selected(True) def min_prin_selected(self, state): if len(self.result_obj.PrincipalMin) > 0: self.result_selected( "MinPrin", self.result_obj.PrincipalMin, "MPa", translate("FEM", "Minimum principal stress"), ) else: self.result_widget.rb_none.setChecked(True) self.none_selected(True) def peeq_selected(self, state): if len(self.result_obj.Peeq) > 0: self.result_selected( "Peeq", self.result_obj.Peeq, "", translate("FEM", "Equivalent plastic strain"), ) else: self.result_widget.rb_none.setChecked(True) self.none_selected(True) def show_histogram_clicked(self): if len(plt.get_fignums()) > 0: plt.show() else: # if the plot was closed and subsequently the Histogram button was pressed again # we have valid settings, but must restore the dialog to refill the plot content # see https://github.com/FreeCAD/FreeCAD/issues/6975 if FreeCAD.FEM_dialog["results_type"] != "None": self.restore_result_dialog() if len(plt.get_fignums()) > 0: plt.show() else: QtGui.QMessageBox.information( None, self.result_obj.Label + " - " + translate("FEM", "Information"), translate( "FEM", "No histogram available.\nPlease select a result type first.", ), ) def user_defined_text(self, equation): FreeCAD.FEM_dialog["results_type"] = "user" self.result_widget.user_def_eq.toPlainText() def calculate(self): # Convert existing result values to numpy array # scalars P1 = np.array(self.result_obj.PrincipalMax) P2 = np.array(self.result_obj.PrincipalMed) P3 = np.array(self.result_obj.PrincipalMin) MS = np.array(self.result_obj.MaxShear) vM = np.array(self.result_obj.vonMises) Peeq = np.array(self.result_obj.Peeq) T = np.array(self.result_obj.Temperature) MF = np.array(self.result_obj.MassFlowRate) NP = np.array(self.result_obj.NetworkPressure) sxx = np.array(self.result_obj.NodeStressXX) syy = np.array(self.result_obj.NodeStressYY) szz = np.array(self.result_obj.NodeStressZZ) sxy = np.array(self.result_obj.NodeStressXY) sxz = np.array(self.result_obj.NodeStressXZ) syz = np.array(self.result_obj.NodeStressYZ) exx = np.array(self.result_obj.NodeStrainXX) eyy = np.array(self.result_obj.NodeStrainYY) ezz = np.array(self.result_obj.NodeStrainZZ) exy = np.array(self.result_obj.NodeStrainXY) exz = np.array(self.result_obj.NodeStrainXZ) eyz = np.array(self.result_obj.NodeStrainYZ) rx = np.array(self.result_obj.ReinforcementRatio_x) ry = np.array(self.result_obj.ReinforcementRatio_y) rz = np.array(self.result_obj.ReinforcementRatio_z) mc = np.array(self.result_obj.MohrCoulomb) # vectors dispvectors = np.array(self.result_obj.DisplacementVectors) x = np.array(dispvectors[:, 0]) y = np.array(dispvectors[:, 1]) z = np.array(dispvectors[:, 2]) s1x, s1y, s1z = np.array([]), np.array([]), np.array([]) s2x, s2y, s2z = np.array([]), np.array([]), np.array([]) s3x, s3y, s3z = np.array([]), np.array([]), np.array([]) # If PSxVector is empty all UserDefined equation does not work if self.result_obj.PS1Vector: ps1vector = np.array(self.result_obj.PS1Vector) s1x = np.array(ps1vector[:, 0]) s1y = np.array(ps1vector[:, 1]) s1z = np.array(ps1vector[:, 2]) if self.result_obj.PS2Vector: ps2vector = np.array(self.result_obj.PS2Vector) s2x = np.array(ps2vector[:, 0]) s2y = np.array(ps2vector[:, 1]) s2z = np.array(ps2vector[:, 2]) if self.result_obj.PS3Vector: ps3vector = np.array(self.result_obj.PS3Vector) s3x = np.array(ps3vector[:, 0]) s3y = np.array(ps3vector[:, 1]) s3z = np.array(ps3vector[:, 2]) FreeCAD.FEM_dialog["results_type"] = "None" self.update() self.restore_result_dialog() userdefined_eq = self.result_widget.user_def_eq.toPlainText() # Get equation to be used self.results_name = "User Defined: " + userdefined_eq # https://forum.freecad.org/viewtopic.php?f=18&t=42425&start=10#p368774 ff # https://github.com/FreeCAD/FreeCAD/pull/3020 from ply import lex from ply import yacc import femtools.tokrules as tokrules identifiers = [ "x", "y", "z", "T", "vM", "Peeq", "P1", "P2", "P3", "sxx", "syy", "szz", "sxy", "sxz", "syz", "exx", "eyy", "ezz", "exy", "exz", "eyz", "MS", "MF", "NP", "rx", "ry", "rz", "mc", "s1x", "s1y", "s1z", "s2x", "s2y", "s2z", "s3x", "s3y", "s3z", ] tokrules.names = {} for i in identifiers: tokrules.names[i] = locals()[i] lexer = lex.lex(module=tokrules) yacc.parse(input=f"UserDefinedFormula={userdefined_eq}", lexer=lexer) UserDefinedFormula = tokrules.names["UserDefinedFormula"].tolist() tokrules.names = {} # UserDefinedFormula = eval(userdefined_eq).tolist() if UserDefinedFormula: self.result_obj.UserDefined = UserDefinedFormula minm = min(UserDefinedFormula) maxm = max(UserDefinedFormula) self.update_colors_stats(UserDefinedFormula, "", minm, maxm) # finally we must recompute the result_obj self.result_obj.Document.recompute() def get_scalar_disp_list(self, vector_list, axis): # list is needed, as zib-object is not subscriptable in py3 d = list(zip(*self.result_obj.DisplacementVectors)) scalar_list = list(d[axis]) return scalar_list def result_selected(self, res_type, res_values, res_unit, res_title): self.results_name = res_title FreeCAD.FEM_dialog["results_type"] = res_type (minm, maxm) = self.get_result_stats(res_type) self.update_colors_stats(res_values, res_unit, minm, maxm) if len(plt.get_fignums()) > 0: plt.close() plt.ioff() # disable interactive mode so we have full control when plot is shown plt.figure(res_title) plt.hist(res_values, bins=50, alpha=0.5, facecolor="blue") plt.xlabel(res_unit) plt.title(translate("FEM", "Histogram of {}").format(res_title)) plt.ylabel(translate("FEM", "Nodes")) plt.grid(True) fig_manager = plt.get_current_fig_manager() # Lines below tells Qt that plot widget/dialog should be kept on top of its parent, # its parent being defined as FC main window # "Tool" type also is non modal, and dialog doesn't add a tab in the OS task bar # See Qt::WindowFlags for more details fig_manager.window.setParent(FreeCADGui.getMainWindow()) fig_manager.window.setWindowFlag(QtCore.Qt.Tool) def update_colors_stats(self, res_values, res_unit, minm, maxm): self.set_label(self.result_obj.Label, self.results_name) QApplication.setOverrideCursor(Qt.WaitCursor) if self.suitable_results: self.mesh_obj.ViewObject.setNodeColorByScalars(self.result_obj.NodeNumbers, res_values) self.set_result_stats(res_unit, minm, maxm) QtGui.QApplication.restoreOverrideCursor() def set_result_stats(self, unit, minm, maxm): self.result_widget.le_min.setProperty("unit", unit) self.result_widget.le_min.setProperty("rawText", f"{minm:.6} {unit}") self.result_widget.le_max.setProperty("unit", unit) self.result_widget.le_max.setProperty("rawText", f"{maxm:.6} {unit}") def update_displacement(self, factor=None): if factor is None: if FreeCAD.FEM_dialog["show_disp"]: factor = self.result_widget.sb_displacement_factor.value() else: factor = 0.0 self.mesh_obj.ViewObject.applyDisplacement(factor) def show_displacement(self, checked): QApplication.setOverrideCursor(Qt.WaitCursor) FreeCAD.FEM_dialog["show_disp"] = checked if "result_obj" in FreeCAD.FEM_dialog: if FreeCAD.FEM_dialog["result_obj"] != self.result_obj: self.update_displacement() FreeCAD.FEM_dialog["result_obj"] = self.result_obj if self.suitable_results: self.mesh_obj.ViewObject.setNodeDisplacementByVectors( self.result_obj.NodeNumbers, self.result_obj.DisplacementVectors ) self.update_displacement() QtGui.QApplication.restoreOverrideCursor() def hsb_disp_factor_changed(self, value): self.result_widget.sb_displacement_factor.setValue( value / 100.0 * self.result_widget.sb_displacement_factor_max.value() ) self.update_displacement() def sb_disp_factor_max_changed(self, value): self.slider_max = True FreeCAD.FEM_dialog["disp_factor_max"] = value if value < self.result_widget.sb_displacement_factor.value(): self.result_widget.sb_displacement_factor.setValue(value) if value == 0.0: self.result_widget.hsb_displacement_factor.setValue(0) else: self.result_widget.hsb_displacement_factor.setValue( round(self.result_widget.sb_displacement_factor.value() / value * 100.0) ) self.slider_max = False def sb_disp_factor_changed(self, value): # this bit of code causes: # RecursionError: maximum recursion depth exceeded # so check on the depth and don't exceed recurlim if len(inspect.stack(0)) < self.recurlim: FreeCAD.FEM_dialog["disp_factor"] = value if value > self.result_widget.sb_displacement_factor_max.value(): self.result_widget.sb_displacement_factor.setValue( self.result_widget.sb_displacement_factor_max.value() ) if self.result_widget.sb_displacement_factor_max.value() == 0.0: self.result_widget.hsb_displacement_factor.setValue(0.0) else: self.result_widget.hsb_displacement_factor.setValue( round(value / self.result_widget.sb_displacement_factor_max.value() * 100.0) ) def disable_empty_result_buttons(self): """disable radio buttons if result does not exists in result object""" """assignments DisplacementLengths --> rb_abs_displacement DisplacementVectors --> rb_x_displacement, rb_y_displacement, rb_z_displacement Temperature --> rb_temperature vonMises --> rb_vm_stress PrincipalMax --> rb_maxprin PrincipalMin --> rb_minprin MaxShear --> rb_max_shear_stress MassFlowRate --> rb_massflowrate NetworkPressure --> rb_networkpressure Peeq --> rb_peeq""" if len(self.result_obj.DisplacementLengths) == 0: self.result_widget.rb_abs_displacement.setEnabled(0) if len(self.result_obj.DisplacementVectors) == 0: self.result_widget.rb_x_displacement.setEnabled(0) self.result_widget.rb_y_displacement.setEnabled(0) self.result_widget.rb_z_displacement.setEnabled(0) if len(self.result_obj.Temperature) == 0: self.result_widget.rb_temperature.setEnabled(0) if len(self.result_obj.vonMises) == 0: self.result_widget.rb_vm_stress.setEnabled(0) if len(self.result_obj.PrincipalMax) == 0: self.result_widget.rb_maxprin.setEnabled(0) if len(self.result_obj.PrincipalMin) == 0: self.result_widget.rb_minprin.setEnabled(0) if len(self.result_obj.MaxShear) == 0: self.result_widget.rb_max_shear_stress.setEnabled(0) if len(self.result_obj.MassFlowRate) == 0: self.result_widget.rb_massflowrate.setEnabled(0) if len(self.result_obj.NetworkPressure) == 0: self.result_widget.rb_networkpressure.setEnabled(0) if len(self.result_obj.Peeq) == 0: self.result_widget.rb_peeq.setEnabled(0) def update(self): self.reset_result_mesh() self.suitable_results = False self.disable_empty_result_buttons() if self.mesh_obj.FemMesh.NodeCount == 0: the_error_messagetext = ( "FEM: there are no nodes in result mesh, there will be nothing to show." ) error_message = translate("FEM", the_error_messagetext) + "\n" FreeCAD.Console.PrintError(error_message) QtGui.QMessageBox.critical( None, translate("FEM", "Result mesh is empty"), error_message ) elif self.mesh_obj.FemMesh.NodeCount == len(self.result_obj.NodeNumbers): self.suitable_results = True hide_parts_constraints() else: if not self.mesh_obj.FemMesh.VolumeCount: the_error_messagetext = ( "FEM: Graphical bending stress output " "for beam or shell FEM Meshes not yet supported." ) error_message = translate("FEM", the_error_messagetext) + "\n" FreeCAD.Console.PrintError(error_message) QtGui.QMessageBox.critical( None, translate("FEM", "No result object"), error_message ) else: the_error_messagetext = ( "FEM: Result node numbers are not equal to FEM Mesh NodeCount." ) error_message = translate("FEM", the_error_messagetext) + "\n" FreeCAD.Console.PrintError(error_message) QtGui.QMessageBox.critical( None, translate("FEM", "No result object"), error_message ) def reset_mesh_color(self): self.mesh_obj.ViewObject.NodeColor = {} self.mesh_obj.ViewObject.ElementColor = {} self.mesh_obj.ViewObject.resetNodeColor() def reset_result_mesh(self): self.mesh_obj.ViewObject.resetNodeDisplacement() self.reset_mesh_color() def reject(self): self.reset_result_mesh() plt.close() # if the tasks panel is called from Command obj is not in edit mode # thus reset edit does not close the dialog, maybe don't call but set in edit instead FreeCADGui.Control.closeDialog() FreeCADGui.ActiveDocument.resetEdit() if len(self.animateText) > 0: for a in self.animateText: a.hide() self.animateText = [] self.startAnimate = False FreeCAD.FEM_dialog["animate"][0] = self.result_widget.steps.value() FreeCAD.FEM_dialog["animate"][1] = self.result_widget.loops.value() FreeCAD.FEM_dialog["animate"][2] = self.result_widget.framerate.value() FreeCAD.FEM_dialog["animate"][3] = self.result_widget.rb_full_cycle.isChecked() try: FreeCAD.FEM_dialog["animate"][4] = self.result_widget.sb_displacement_factor.value() except: FreeCAD.FEM_dialog["animate"][4] = 1 # animation start def animate_displacement(self): if "result_obj" in FreeCAD.FEM_dialog: if FreeCAD.FEM_dialog["result_obj"] != self.result_obj: self.update_displacement() self.result_widget.cb_show_displacement.setChecked(True) FreeCAD.FEM_dialog["result_obj"] = self.result_obj if self.suitable_results: self.mesh_obj.ViewObject.setNodeDisplacementByVectors( self.result_obj.NodeNumbers, self.result_obj.DisplacementVectors ) self.result_widget.startButton.setText("Stop Animation") frame_rate = 10 self.hsb_displacement_factor = self.result_widget.sb_displacement_factor.value() frame_rate = self.result_widget.framerate.value() steps_per_cycle = int(self.result_widget.steps.value()) number_cycles = int(self.result_widget.loops.value()) sinc = inc = math.pi / steps_per_cycle * 2.0 self.set_label(self.result_obj.Label, self.results_name) done = False # for lo in range(0, number_cycles): loops = max(1, number_cycles) * steps_per_cycle + 1 st = 0 for loop in range(0, loops): if self.result_widget.rb_half_cycle.isChecked(): if number_cycles > 0: # 0 -> 1 -> 0, repeated inc = sinc / 2 else: inc = sinc / 4 # full cycle if self.result_widget.rb_full_cycle.isChecked(): self.mesh_obj.ViewObject.applyDisplacement( math.sin(st * inc) * self.hsb_displacement_factor ) elif self.result_widget.rb_half_cycle.isChecked(): # half cycle if number_cycles > 0: # 0 -> 1 -> 0, repeated self.mesh_obj.ViewObject.applyDisplacement( abs(math.sin(st * inc)) * self.hsb_displacement_factor ) elif number_cycles <= 0: # 0 -> 1, once self.mesh_obj.ViewObject.applyDisplacement( abs(math.sin(st * inc)) * self.hsb_displacement_factor ) else: print("No cycle type selected") FreeCADGui.updateGui() if not self.startAnimate: done = True break time.sleep(1.0 / frame_rate) # modify the time here st += 1 # if done: # break try: self.result_widget.startButton.setText("Start Animation") except: pass QtGui.QApplication.restoreOverrideCursor() self.startAnimate = False def value_changed(self, dummy, value, myType): # the only actions are: if myType == "startButton": if not self.startAnimate: self.startAnimate = True self.animate_displacement() else: self.startAnimate = False # # this is taken care of in the "ui" # # set the scale - scroll bar - Show # elif myType == "scale" and not self.slider_max: # if self.animate_inc == 0: # if self.result_widget.hsb_displacement_factor.value() > 1: # self.result_widget.sb_displacement_factor.setValue( # self.result_widget.hsb_displacement_factor.value() # ) # self.animate_inc = 1 - self.animate_inc # # set the factor - spin - Factor # elif myType == "factor" and not self.slider_max: # if self.animate_inc == 0: # self.result_widget.hsb_displacement_factor.setValue( # int(self.result_widget.sb_displacement_factor.value()) # ) # self.animate_inc = 1 - self.animate_inc else: pass try: self.hsb_displacement_factor = self.result_widget.sb_displacement_factor.value() except: pass return def set_label(self, result_name, mesh_data): if len(self.animateText) == 0: self.animateText.append(CreateLabels.createLabel((-0.98, 0.90, 0), result_name)) self.animateText.append(CreateLabels.createLabel((-0.98, 0.70, 0), mesh_data)) else: self.animateText[1].set_text(mesh_data) pass # animation end # helper def hide_parts_constraints(): from FemGui import getActiveAnalysis fem_prefs = FreeCAD.ParamGet("User parameter:BaseApp/Preferences/Mod/Fem/General") hide_constraints = fem_prefs.GetBool("HideConstraint", False) if hide_constraints: for o in FreeCAD.ActiveDocument.Objects: if o.isDerivedFrom("Fem::FemAnalysis"): for acnstrmesh in getActiveAnalysis().Group: if "Constraint" in acnstrmesh.TypeId: acnstrmesh.ViewObject.Visibility = False break def get_displacement_scale_factor(res_obj): node_items = res_obj.Mesh.FemMesh.Nodes.items() displacements = res_obj.DisplacementVectors # use standard scale if there are no displacements in result object if len(displacements) == 0: return 1 x_max, y_max, z_max = map(max, zip(*displacements)) positions = [] # list of node vectors for k, v in node_items: positions.append(v) p_x_max, p_y_max, p_z_max = map(max, zip(*positions)) p_x_min, p_y_min, p_z_min = map(min, zip(*positions)) x_span = abs(p_x_max - p_x_min) y_span = abs(p_y_max - p_y_min) z_span = abs(p_z_max - p_z_min) span = max(x_span, y_span, z_span) max_disp = max(x_max, y_max, z_max) if max_disp == 0.0: return 0.0 # avoid float division by zero # FIXME - add max_allowed_disp to Preferences max_allowed_disp = 0.01 * span scale = max_allowed_disp / max_disp return scale