Macro Unfold Box/fr

Description
La macro permet de déplier les surfaces d'un objet de n'importe quelle forme et la dessiner sur une page.

Installation
Copiez le fichier de la macro dans le répertoire :
 * Linux & Mac  : $home/.Freecad/Mod/unfoldBox.
 * Windows : C:\Program Files\FreeCAD0.13

Ajouter les templates : A3_Landscape_Empty.svg A3_Landscape.svg  A4_Landscape_Empty.svg  A4_Landscape.svg

Cf Macro for unfolding box surfaces

Options

 * Échelle manuelle ou automatique
 * Format de Page : A3 / A4, cartouche (cf FreeCAD modèles)
 * Groupe les dessins dans la même page si possible.
 * Attache ou non les bords de la pièce.

Utilisation

 * 1) Sélectionnez un volume créé avec par exemple Part::Loft tool
 * 2) Développe la forme dans le plan de la forme (cf Draft menu)
 * 3) Sélectionnez la surface
 * 4) Exécuter la macro

Script
Macro_unfoldBox.py
 * 1) *  Copyright (c) 2013 - DoNovae/Herve BAILLY          *
 * 2) *  This program is free software; you can redistribute it and/or modify  *
 * 3) *  it under the terms of the GNU Lesser General Public License (LGPL)    *
 * 4) *  as published by the Free Software Foundation; either version 2 of     *
 * 5) *  the License, or (at your option) any later version.                   *
 * 6) *  for detail see the LICENCE text file.                                 *
 * 7) *  This program is distributed in the hope that it will be useful,       *
 * 8) *  but WITHOUT ANY WARRANTY; without even the implied warranty of        *
 * 9) *  MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE.  See the         *
 * 10) *  GNU Library General Public License for more details.                  *
 * 11) *  You should have received a copy of the GNU Library General Public     *
 * 12) *  License along with this program; if not, write to the Free Software   *
 * 13) *  Foundation, Inc., 59 Temple Place, Suite 330, Boston, MA  02111-1307  *
 * 14) *  USA                                                                   *
 * 1) *  You should have received a copy of the GNU Library General Public     *
 * 2) *  License along with this program; if not, write to the Free Software   *
 * 3) *  Foundation, Inc., 59 Temple Place, Suite 330, Boston, MA  02111-1307  *
 * 4) *  USA                                                                   *
 * 1) *  USA                                                                   *

import FreeCAD, FreeCADGui , Part, Draft, math, Drawing , PyQt4, os from PyQt4 import QtGui,QtCore from FreeCAD import Base fields_l = [] unroll_l = []
 * 1) Macro unfoldBox
 * 2)     Unroll of a ruled surface
 * 1)     Unroll of a ruled surface


 * 1) Functions
 * 1) Functions
 * 1) Functions

def errorDialog(msg): diag = QtGui.QMessageBox(QtGui.QMessageBox.Critical,u"Error Message",msg ) diag.setWindowFlags(PyQt4.QtCore.Qt.WindowStaysOnTopHint) diag.exec_
 * 1) Function errorDialog
 * 1) Function errorDialog

def proceed: QtGui.qApp.setOverrideCursor(QtCore.Qt.WaitCursor)
 * 1) Function proceed
 * 1) Function proceed

FreeCAD.Console.PrintMessage("===========================================\n") FreeCAD.Console.PrintMessage("unfoldBox: start.\n") try: file_name = fields_l[0].text scale   = float(fields_l[1].text) scale_auto = scale_check.isChecked a3 = a3_check.isChecked cartridge = cartridge_check.isChecked onedrawing = onedrawing_check.isChecked sewed = sewed_check.isChecked FreeCAD.Console.PrintMessage("unfoldBox.file_name: "+file_name+"\n") FreeCAD.Console.PrintMessage("unfoldBox.scale: "+str(scale)+"\n") FreeCAD.Console.PrintMessage("unfoldBox.scale_check: "+str(scale_auto)+"\n") FreeCAD.Console.PrintMessage("unfoldBox.a3_check: "+str(a3)+"\n") FreeCAD.Console.PrintMessage("unfoldBox.cartridge: "+str(cartridge)+"\n") FreeCAD.Console.PrintMessage("unfoldBox.onedrawing: "+str(onedrawing)+"\n") FreeCAD.Console.PrintMessage("unfoldBox.sewed: "+str(sewed)+"\n") except: msg="unfoldBox: wrong inputs...\n" FreeCAD.Console.PrintError(msg) errorDialog(msg)

QtGui.qApp.restoreOverrideCursor DialogBox.hide #  # Get selection #  sel=FreeCADGui.Selection.getSelection faceid=0 objnames_l=[] tree_l=[] grp=FreeCAD.activeDocument.addObject("App::DocumentObjectGroup", str(file_name)) for objid in range( sel.__len__ ): obj=Draft.clone(sel[objid]) grp.addObject(obj) objnames_l.append( [ obj, sel[objid].Name ] )

unfold=unfoldBox if sewed : objnames_l=unfold.done(objnames_l) grp.addObject(objnames_l[0][0]) else: for objid in range( objnames_l.__len__ ): unfold.moveXY(objnames_l[objid][0])

id=0 while objnames_l.__len__ > 0: draw=Drawing2d( scale, scale_auto, a3 , cartridge , onedrawing , FreeCAD.activeDocument.Name , "Page"+str(id) ) objnames_l=draw.all( objnames_l ) id=id+1 FreeCAD.Console.PrintMessage("unfoldBox: obj_l= "+str(objnames_l.__len__)+"\n")

FreeCAD.Console.PrintMessage("unfoldBox: end.\n") FreeCAD.Console.PrintMessage("===========================================\n")

def close: DialogBox.hide
 * 1) Function close
 * 1) Function close

class unfoldBox: ##################################### # Function __init__ ##################################### def __init__(self): FreeCAD.Console.PrintMessage("unfoldBox.unfoldBox\n") self.LIMIT=0.0001
 * 1) Class unfoldBox
 * 1) Class unfoldBox

##################################### # Function done ##################################### def done(self,objnames_l): tree_l=self.makeTree(objnames_l) for id in range( objnames_l.__len__ ): face=objnames_l[id] self.moveXY(face[0]) self.sew( objnames_l, tree_l ) return self.fusion(objnames_l)

##################################### # Function makeTree ##################################### def makeTree(self,objnames_l): #    # Initialisation of tree_l #    tree_l=[] for k in range( objnames_l.__len__ ): facek=objnames_l[k][0] facek_l=[] for i in range( facek.Shape.Edges.__len__ ): if False and type(facek.Shape.Edges[i].Curve).__name__ != 'GeomLineSegment': facek_l.append([-1,-1]) else: #	    # Search face link to the ith edge #	    vki0=facek.Shape.Edges[i].Curve.StartPoint vki1=facek.Shape.Edges[i].Curve.EndPoint found=False for l in range( k+1, objnames_l.__len__ ): facel=objnames_l[l][0] for j in range( facel.Shape.Edges.__len__ ): vlj0=facel.Shape.Edges[j].Curve.StartPoint vlj1=facel.Shape.Edges[j].Curve.EndPoint if vki0.__eq__(vlj0) and vki1.__eq__(vlj1): arelinked=False isfacek=False isfacel=False for kk in range( k-1 ): for ii in range( tree_l[kk].__len__ ): if tree_l[kk][ii][0]==k: isfacek=True if tree_l[kk][ii][0]==l: isfacel=True if isfacek and isfacel: arelinked=True break if not arelinked: facek_l.append([l,j]) found=True break if found: break if not found: facek_l.append([-1,-1]) tree_l.append(facek_l) return tree_l

##################################### # Function sew ##################################### def sew( self,objnames_l, tree_l ): placed_l=[] for k in range( tree_l.__len__ ): iskplaced=False for p in range( placed_l.__len__ ): if placed_l[p] == k:           iskplaced=True if not iskplaced:placed_l.append(k) facek=tree_l[k] objk=objnames_l[k][0] for i in range( facek.__len__ ): edgeki=facek[i] l=edgeki[0] j=edgeki[1] islplaced=False for p in range( placed_l.__len__ ): if placed_l[p] == l: 	       islplaced=True break if not islplaced: placed_l.append(l) if l >= 0 and not ( islplaced and iskplaced ): iskplaced=True # 	  # Move facel.edgelj to facek.edgeki #         objl=objnames_l[l][0] vki0=objk.Shape.Edges[i].Curve.StartPoint vki1=objk.Shape.Edges[i].Curve.EndPoint vlj0=objl.Shape.Edges[j].Curve.StartPoint vlj1=objl.Shape.Edges[j].Curve.EndPoint vk=vki1.sub(vki0) vl=vlj1.sub(vlj0) alpk=vk.getAngle(vl)*180/math.pi	 alpl=vl.getAngle(vk)*180/math.pi          self.isPlanZ(objk) if islplaced: Draft.move( objk, vlj0.sub(vki0) ) else: Draft.move( objl, vki0.sub(vlj0) ) self.isPlanZ(objk)

if math.fabs( vk.dot(FreeCAD.Base.Vector(-vl.y,vl.x,0))) > self.LIMIT: if islplaced: Draft.rotate( objk, -alpl , vlj0 , self.vecto( vl , vk )) else: Draft.rotate( objl, -alpk , vki0 , self.vecto( vk , vl )) elif vk.dot(vl)<0: if islplaced: Draft.rotate( objk, 180 , vlj0 , self.vecto( vl , FreeCAD.Base.Vector(-vl.y,vl.x,0) )) else: Draft.rotate( objl, 180 , vki0 , self.vecto( vk , FreeCAD.Base.Vector(-vk.y,vk.x,0))) #	 # Verifications #         vki0=objk.Shape.Edges[i].Curve.StartPoint vki1=objk.Shape.Edges[i].Curve.EndPoint vlj0=objl.Shape.Edges[j].Curve.StartPoint vlj1=objl.Shape.Edges[j].Curve.EndPoint vk=vki1.sub(vki0) vl=vlj1.sub(vlj0) self.isPlanZ(objk)

#	 # Flip or not #         L=max(objl.Shape.BoundBox.XMax,objk.Shape.BoundBox.XMax) - min( objl.Shape.BoundBox.XMin,objk.Shape.BoundBox.XMin) W=max(objl.Shape.BoundBox.YMax,objk.Shape.BoundBox.YMax) - min( objl.Shape.BoundBox.YMin,objk.Shape.BoundBox.YMin) S1=L*W if islplaced: dum=0 Draft.rotate( objk, 180 , vlj0 ,vl) else: dum=0 Draft.rotate( objl, 180 , vki0 ,vk) L=max(objl.Shape.BoundBox.XMax,objk.Shape.BoundBox.XMax) - min( objl.Shape.BoundBox.XMin,objk.Shape.BoundBox.XMin) W=max(objl.Shape.BoundBox.YMax,objk.Shape.BoundBox.YMax) - min( objl.Shape.BoundBox.YMin,objk.Shape.BoundBox.YMin) S2=L*W if (S2<=S1): if islplaced: dum=0 Draft.rotate( objk, 180 , vlj0 ,vl) else: dum=0 Draft.rotate( objl, 180 , vki0 ,vk) self.isPlanZ(objk)

##################################### # Function isPlanZ ##################################### def isPlanZ(self,obj): L=obj.Shape.BoundBox.XMax - obj.Shape.BoundBox.XMin W=obj.Shape.BoundBox.YMax - obj.Shape.BoundBox.YMin H=obj.Shape.BoundBox.ZMax - obj.Shape.BoundBox.ZMin if H < self.LIMIT: return True else: return False

##################################### # Function fusion ##################################### def fusion(self,objnames_l): #    # Init #    obj_l=[] objna_l=[] obj0=objnames_l[0][0];name=objnames_l[0][1] objfuse=FreeCAD.activeDocument.addObject("Part::MultiFuse","Unfolding") for k in range( objnames_l.__len__ ): objk=objnames_l[k][0] obj_l.append(objk) objfuse.Shapes=obj_l FreeCAD.activeDocument.recompute objna_l.append([objfuse,name]) return objna_l

##################################### # Function get2Vectors ##################################### def get2Vectors(self,shape): v0=FreeCAD.Base.Vector(0,0,0) v1=FreeCAD.Base.Vector(0,0,0)

edges= shape.Edges for id in range( edges.__len__-1): va=edges[id].Curve.EndPoint.sub(edges[id].Curve.StartPoint) vb=edges[id+1].Curve.EndPoint.sub(edges[id+1].Curve.StartPoint) if vb.sub(va).Length > v1.sub(v0).Length: v0=self.vect_copy(va);v1=self.vect_copy(vb) #FreeCAD.Console.PrintMessage("unfoldBox.get2Vectors: v0= {:s}, v1= {:s}\n".format(str(v0),str(v1))) return [ v0, v1 ]

##################################### # Function vecto #  - vect1,2: #  - return abs(sin) angle between #    2 vectors ##################################### def vecto( self,vect1, vect2 ): v= FreeCAD.Base.Vector(0,0,0) v.x=vect1.y*vect2.z-vect1.z*vect2.y    v.y=vect1.z*vect2.x-vect1.x*vect2.z     v.z=vect1.x*vect2.y-vect1.y*vect2.x     return v

##################################### # Function vect_copy #  - vect: #  - return copy of vector ##################################### def vect_copy( self,vect): v= vect.add( FreeCAD.Base.Vector(0,0,0) ) return v

##################################### # Function movexy ##################################### def moveXY( self,obj ): #    # Move to origin #    Draft.move( obj, FreeCAD.Base.Vector( -obj.Shape.BoundBox.XMin , -obj.Shape.BoundBox.YMin , -obj.Shape.BoundBox.ZMin )) #    # Find 2 vectors defining the plan of surface #    tab=self.get2Vectors( obj.Shape ) v0=tab[0];v1=tab[1] norm=self.vecto(v0,v1) norm.normalize #FreeCAD.Console.PrintMessage("unfoldBox.moveXY: norm= {:s}\n".format(str(norm)))

#    # Rotate #    if math.fabs(norm.x) < self.LIMIT and math.fabs(norm.y) < self.LIMIT: dum=0 elif math.fabs(norm.x) < self.LIMIT and math.fabs(norm.z) < self.LIMIT: Draft.rotate( obj, 90 , FreeCAD.Base.Vector(0,0,0) , FreeCAD.Base.Vector(1,0,0) ) elif math.fabs(norm.y) < self.LIMIT and math.fabs(norm.z) < self.LIMIT: Draft.rotate( obj, 90 , FreeCAD.Base.Vector(0,0,0) , FreeCAD.Base.Vector(0,1,0) ) else: #	# Rotate following the angle to the normal direction of the plan #       oz= FreeCAD.Base.Vector(0,0,1) alp=oz.getAngle(norm)*180/math.pi       #FreeCAD.Console.PrintMessage("unfoldBox.moveXY: alp= "+str(alp)+"\n") #FreeCAD.Console.PrintMessage("unfoldBox.moveXY: vecto= {:s}\n".format(str(self.vecto(oz,norm)))) Draft.rotate( obj, -alp , FreeCAD.Base.Vector(0,0,0) , self.vecto( oz, norm )) #    # Move to z=0 #    Draft.move( obj, FreeCAD.Base.Vector( 0 , 0 , -obj.Shape.BoundBox.ZMin )) L=obj.Shape.BoundBox.XMax - obj.Shape.BoundBox.XMin W=obj.Shape.BoundBox.YMax - obj.Shape.BoundBox.YMin H=obj.Shape.BoundBox.ZMax - obj.Shape.BoundBox.ZMin

class Drawing2d: ##################################### # Function __init__ #    - Scale #    - scale_auto #    - a3  #     - cartridge #    - onedrawing ##################################### def __init__( self,  scale, scale_auto , a3 , cartridge , onedrawing , drawing_name , page_name ): self.TopX_H=0 self.TopY_H=0 self.TopX_V=0 self.TopY_V=0 self.TopX_Hmax=0 self.TopY_Hmax=0 self.TopX_Vmax=0 self.TopY_Vmax=0 self.a3=a3 self.pts_nbr=100 self.scale=scale self.scale_auto=scale_auto self.cartridge=cartridge self.onedrawing=onedrawing if self.a3: self.L=420 self.H=297 self.marge=6 else: self.L=297 self.H=210 self.marge=6 self.page_name=page_name self.drawing_name=drawing_name
 * 1) Class Drawing2d
 * 1) Class Drawing2d

##################################### # Function newPage ##################################### def newPage( self ): freecad_dir=os.getenv('HOME')+"/.FreeCAD/Mod/unfoldBox" page = FreeCAD.activeDocument.addObject('Drawing::FeaturePage', self.page_name ) if self.a3: if self.cartridge: page.Template = freecad_dir+'/A3_Landscape.svg' else: page.Template = freecad_dir+'/A3_Landscape_Empty.svg' else: if self.cartridge: page.Template = freecad_dir+'/A4_Landscape.svg' else: page.Template = freecad_dir+'/A4_Landscape_Empty.svg' return page

##################################### # Function all ##################################### def all( self, objnames_l ): obj_l=[] for objid in range( objnames_l.__len__ ): if objid == 0 or not self.onedrawing: page = self.newPage obj_l.extend( self.done( objid, objnames_l[objid] )) return obj_l

##################################### # Function done ##################################### def done( self, id, objname ): #   # Init #   obj_l=[] obj=objname[0] objname=objname[1] xmax=obj.Shape.BoundBox.XMax-obj.Shape.BoundBox.XMin ymax=obj.Shape.BoundBox.YMax-obj.Shape.BoundBox.YMin if ymax > xmax : Draft.rotate( obj, 90 ) Draft.move( obj, FreeCAD.Base.Vector( -obj.Shape.BoundBox.XMin , -obj.Shape.BoundBox.YMin , 0)) xmax=obj.Shape.BoundBox.XMax-obj.Shape.BoundBox.XMin ymax=obj.Shape.BoundBox.YMax-obj.Shape.BoundBox.YMin

scale=min((self.L-4*self.marge)/xmax,(self.H-4*self.marge)/ymax)

if ( not self.scale_auto ) or ( self.onedrawing ) : scale=self.scale

if id == 0 or not self.onedrawing: #     # Init #     FreeCAD.Console.PrintMessage("Dawing2d: init\n") self.TopX_H=self.marge*2 self.TopY_H=self.marge*2 TopX=self.TopX_H TopY=self.TopY_H self.TopX_H=self.TopX_H + xmax * scale + self.marge self.TopY_H=self.TopY_H self.TopX_Hmax=max( self.TopX_Hmax, self.TopX_H ) self.TopY_Hmax=max( self.TopY_Hmax, self.TopY_H + ymax*scale+self.marge ) self.TopX_Vmax=max( self.TopX_Vmax, self.TopX_Hmax ) self.TopX_V=max(self.TopX_Vmax,self.TopX_V) self.TopY_V=self.marge*2 elif self.onedrawing: if self.TopX_H + xmax * scale < self.L : if self.TopY_H + ymax * scale + self.marge*2 < self.H : #	  # H Add at right on same horizontal line #          FreeCAD.Console.PrintMessage("Dawing2d: horizontal\n") TopX=self.TopX_H TopY=self.TopY_H self.TopX_H=self.TopX_H + xmax * scale + self.marge self.TopX_Hmax=max( self.TopX_Hmax, self.TopX_H ) self.TopY_Hmax=max( self.TopY_Hmax, self.TopY_H + ymax*scale+self.marge ) self.TopX_Vmax=max( self.TopX_Hmax, self.TopX_Vmax ) self.TopX_Vmax=max( self.TopX_Vmax, self.TopX_Hmax ) self.TopX_V=max(self.TopX_Vmax,self.TopX_V) else: #	  # V Add at right on same horizontal line #          FreeCAD.Console.PrintMessage("Dawing2d: vertival\n") if self.TopX_V + ymax * scale +2* self.marge < self.L and self.TopY_V + xmax * scale + 2*self.marge < self.H : Draft.rotate( obj, 90 ) Draft.move( obj, FreeCAD.Base.Vector( -obj.BoundBox.XMin , -obj.BoundBox.YMin , 0)) self.TopX_V=max(self.TopX_Vmax, self.TopX_V) TopX=self.TopX_V TopY=self.TopY_V self.TopX_V = self.TopX_V + ymax * scale + self.marge self.TopY_Vmax=max( self.TopY_Vmax, self.TopY_V + xmax * scale + self.marge ) else: obj_l.append( [ obj, name ] ) return obj_l

else: #	# H Carriage return #       if ( self.TopY_Hmax + ymax * scale + self.marge*2 < self.H ): FreeCAD.Console.PrintMessage("Dawing2d: carriage return: "+str(self.TopY_H + ymax * scale )+" > "+str(self.H)+"\n") TopX=self.marge*2 TopY=self.TopY_Hmax self.TopX_H=TopX + xmax * scale + self.marge self.TopY_H=TopY self.TopX_Hmax=max( self.TopX_Hmax, self.TopX_H ) self.TopY_Hmax=self.TopY_Hmax + ymax*scale+self.marge self.TopX_Vmax=max( self.TopX_Vmax, self.TopX_Hmax ) self.TopX_V=max(self.TopX_Vmax,self.TopX_V) else: #	  # V Add at right on same horizontal line #          FreeCAD.Console.PrintMessage("Dawing2d: vertival: "+str(self.TopX_V)+", "+str(self.TopX_Vmax)+"\n") if self.TopX_V + ymax * scale + 2*self.marge < self.L and self.TopY_V + xmax * scale + 2*self.marge < self.H : Draft.rotate( obj, 90 ) Draft.move( obj, FreeCAD.Base.Vector( -obj.BoundBox.XMin , -obj.BoundBox.YMin , 0)) TopX=self.TopX_V TopY=self.TopY_V self.TopX_V = self.TopX_V + ymax * scale + self.marge self.TopY_Vmax=max( self.TopY_Vmax, self.TopY_V + xmax * scale + self.marge ) else: obj_l.append( [ obj, name ] ) return obj_l

page=FreeCAD.activeDocument.getObject(self.page_name )

Text=FreeCAD.activeDocument.addObject('Drawing::FeatureViewAnnotation', objname+"_txt") Text.Text=objname Text.X=TopX+xmax/2*scale Text.Y=TopY+ymax/2*scale Text.Scale=1

TopView = FreeCAD.activeDocument.addObject('Drawing::FeatureViewPart','TopView') TopView.Source = obj TopView.Direction = (0.0,0.0,1) TopView.Rotation = 0 TopView.X = TopX TopView.Y = TopY TopView.ShowHiddenLines = True TopView.Scale = scale page.addObject(TopView) page.addObject(Text) FreeCAD.activeDocument.recompute return obj_l

fields = "Group Name", "Unfolding" fields.append(["Scale","1" ])
 * 1) Dialog Box
 * 1) Dialog Box
 * 1) Dialog Box

DialogBox = QtGui.QDialog DialogBox.resize(250,250) DialogBox.setWindowTitle("unfoldBox") la = QtGui.QVBoxLayout(DialogBox)

for id in range(len( fields )): la.addWidget(QtGui.QLabel( fields[ id ][ 0 ] )) fields_l.append( QtGui.QLineEdit( fields[ id ][ 1 ] )) la.addWidget( fields_l[ id ] )
 * 1) Input fields
 * 1) Input fields

scale_check = QtGui.QCheckBox( DialogBox ) scale_check.setObjectName("checkBox") scale_check.setChecked(True) la.addWidget(QtGui.QLabel("Scale auto")) la.addWidget(scale_check)

a3_check = QtGui.QCheckBox( DialogBox ) a3_check.setObjectName("checkBox") la.addWidget(QtGui.QLabel("A3 Format")) a3_check.setChecked(False) la.addWidget(a3_check)

cartridge_check = QtGui.QCheckBox( DialogBox ) cartridge_check.setObjectName("checkBox") la.addWidget(QtGui.QLabel("Cartridge")) cartridge_check.setChecked(False) la.addWidget(cartridge_check)

onedrawing_check = QtGui.QCheckBox( DialogBox ) onedrawing_check.setObjectName("checkBox") la.addWidget(QtGui.QLabel("Group drawings in page")) onedrawing_check.setChecked(True) la.addWidget(onedrawing_check)

sewed_check = QtGui.QCheckBox( DialogBox ) sewed_check.setObjectName("checkBox") la.addWidget(QtGui.QLabel("Sewed surfaces")) sewed_check.setChecked(True) la.addWidget(sewed_check)

box = QtGui.QDialogButtonBox(DialogBox)

box = QtGui.QDialogButtonBox(DialogBox) box.setOrientation(QtCore.Qt.Horizontal) box.setStandardButtons(QtGui.QDialogButtonBox.Cancel|QtGui.QDialogButtonBox.Ok) la.addWidget(box)

QtCore.QObject.connect(box, QtCore.SIGNAL("accepted"), proceed ) QtCore.QObject.connect(box, QtCore.SIGNAL("rejected"), close ) QtCore.QMetaObject.connectSlotsByName(DialogBox) DialogBox.show