/*************************************************************************** * Copyright (c) Jürgen Riegel (juergen.riegel@web.de) 2010 * * * * This file is part of the FreeCAD CAx development system. * * * * This library is free software; you can redistribute it and/or * * modify it under the terms of the GNU Library General Public * * License as published by the Free Software Foundation; either * * version 2 of the License, or (at your option) any later version. * * * * This library 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 library; see the file COPYING.LIB. If not, * * write to the Free Software Foundation, Inc., 59 Temple Place, * * Suite 330, Boston, MA 02111-1307, USA * * * ***************************************************************************/ #include "PreCompiled.h" #include #include "Constraint.h" #include "ConstraintPy.h" #include "ConstraintPy.cpp" #include using namespace Sketcher; PyObject *ConstraintPy::PyMake(struct _typeobject *, PyObject *, PyObject *) // Python wrapper { // create a new instance of ConstraintPy and the Twin object return new ConstraintPy(new Constraint); } // constructor method int ConstraintPy::PyInit(PyObject* args, PyObject* /*kwd*/) { if (PyArg_ParseTuple(args, "")) { return 0; } PyErr_Clear(); char *ConstraintType; int FirstIndex = Constraint::GeoUndef; int FirstPos = none; int SecondIndex= Constraint::GeoUndef; int SecondPos = none; int ThirdIndex = Constraint::GeoUndef; int ThirdPos = none; double Value = 0; int intArg1, intArg2, intArg3, intArg4, intArg5; // Note: In Python 2.x PyArg_ParseTuple prints a warning if a float is given but an integer is expected. // This means we must use a PyObject and check afterwards if it's a float or integer. PyObject* index_or_value; PyObject* oNumArg4; PyObject* oNumArg5; int any_index; // ConstraintType, GeoIndex if (PyArg_ParseTuple(args, "si", &ConstraintType, &FirstIndex)) { if (strcmp("Horizontal",ConstraintType) == 0) { this->getConstraintPtr()->Type = Horizontal; this->getConstraintPtr()->First = FirstIndex; return 0; } else if (strcmp("Vertical",ConstraintType) == 0) { this->getConstraintPtr()->Type = Vertical; this->getConstraintPtr()->First = FirstIndex; return 0; } } PyErr_Clear(); if (PyArg_ParseTuple(args, "siO", &ConstraintType, &FirstIndex, &index_or_value)) { // ConstraintType, GeoIndex1, GeoIndex2 if (PyInt_Check(index_or_value)) { SecondIndex = PyInt_AsLong(index_or_value); bool valid = false; if (strcmp("Tangent",ConstraintType) == 0) { this->getConstraintPtr()->Type = Tangent; valid = true; } else if (strcmp("Parallel",ConstraintType) == 0) { this->getConstraintPtr()->Type = Parallel; valid = true; } else if (strcmp("Perpendicular",ConstraintType) == 0) { this->getConstraintPtr()->Type = Perpendicular; valid = true; } else if (strcmp("Equal",ConstraintType) == 0) { this->getConstraintPtr()->Type = Equal; valid = true; } else if (strstr(ConstraintType,"InternalAlignment") != NULL) { this->getConstraintPtr()->Type = InternalAlignment; valid = true; if(strstr(ConstraintType,"EllipseMajorDiameter") != NULL) this->getConstraintPtr()->AlignmentType=EllipseMajorDiameter; else if(strstr(ConstraintType,"EllipseMinorDiameter") != NULL) this->getConstraintPtr()->AlignmentType=EllipseMinorDiameter; else { this->getConstraintPtr()->AlignmentType=Undef; valid = false; } } if (valid) { this->getConstraintPtr()->First = FirstIndex; this->getConstraintPtr()->Second = SecondIndex; return 0; } } // ConstraintType, GeoIndex, Value if (PyNumber_Check(index_or_value)) { // can be float or int Value = PyFloat_AsDouble(index_or_value); bool valid = false; if (strcmp("Distance",ConstraintType) == 0 ) { this->getConstraintPtr()->Type = Distance; valid = true; } else if (strcmp("Angle",ConstraintType) == 0 ) { if (PyObject_TypeCheck(index_or_value, &(Base::QuantityPy::Type))) { Base::Quantity q = *(static_cast(index_or_value)->getQuantityPtr()); if (q.getUnit() == Base::Unit::Angle) Value = q.getValueAs(Base::Quantity::Radian); } this->getConstraintPtr()->Type = Angle; valid = true; } else if (strcmp("DistanceX",ConstraintType) == 0) { this->getConstraintPtr()->Type = DistanceX; valid = true; } else if (strcmp("DistanceY",ConstraintType) == 0) { this->getConstraintPtr()->Type = DistanceY; valid = true; } else if (strcmp("Radius",ConstraintType) == 0) { this->getConstraintPtr()->Type = Radius; // set a value that is out of range of result of atan2 // this value is handled in ViewProviderSketch this->getConstraintPtr()->LabelPosition = 10; valid = true; } if (valid) { this->getConstraintPtr()->First = FirstIndex; this->getConstraintPtr()->Value = Value; return 0; } } } PyErr_Clear(); if (PyArg_ParseTuple(args, "siiO", &ConstraintType, &FirstIndex, &any_index, &index_or_value)) { // ConstraintType, GeoIndex1, PosIndex1, GeoIndex2 if (PyInt_Check(index_or_value)) { FirstPos = any_index; SecondIndex = PyInt_AsLong(index_or_value); bool valid = false; if (strcmp("Perpendicular", ConstraintType) == 0) { this->getConstraintPtr()->Type = Perpendicular; valid = true; } else if (strcmp("Tangent", ConstraintType) == 0) { this->getConstraintPtr()->Type = Tangent; valid = true; } else if (strcmp("PointOnObject", ConstraintType) == 0) { this->getConstraintPtr()->Type = PointOnObject; valid = true; } else if (strstr(ConstraintType,"InternalAlignment") != NULL) { this->getConstraintPtr()->Type = InternalAlignment; valid = true; if(strstr(ConstraintType,"EllipseFocus1") != NULL) this->getConstraintPtr()->AlignmentType=EllipseFocus1; else if(strstr(ConstraintType,"EllipseFocus2") != NULL) this->getConstraintPtr()->AlignmentType=EllipseFocus2; else { this->getConstraintPtr()->AlignmentType=Undef; valid = false; } } if (valid) { this->getConstraintPtr()->First = FirstIndex; this->getConstraintPtr()->FirstPos = (Sketcher::PointPos) FirstPos; this->getConstraintPtr()->Second = SecondIndex; return 0; } } // ConstraintType, GeoIndex1, GeoIndex2, Value // ConstraintType, GeoIndex, PosIndex, Value if (PyNumber_Check(index_or_value)) { // can be float or int SecondIndex = any_index; Value = PyFloat_AsDouble(index_or_value); //if (strcmp("Distance",ConstraintType) == 0) { // this->getConstraintPtr()->Type = Distance; // this->getConstraintPtr()->First = FirstIndex; // this->getConstraintPtr()->Second = SecondIndex; // this->getConstraintPtr()->Value = Value; // return 0; //} //else if (strcmp("Angle",ConstraintType) == 0) { if (PyObject_TypeCheck(index_or_value, &(Base::QuantityPy::Type))) { Base::Quantity q = *(static_cast(index_or_value)->getQuantityPtr()); if (q.getUnit() == Base::Unit::Angle) Value = q.getValueAs(Base::Quantity::Radian); } this->getConstraintPtr()->Type = Angle; this->getConstraintPtr()->First = FirstIndex; this->getConstraintPtr()->Second = SecondIndex; this->getConstraintPtr()->Value = Value; return 0; } else if (strcmp("DistanceX",ConstraintType) == 0) { FirstPos = SecondIndex; SecondIndex = -1; this->getConstraintPtr()->Type = DistanceX; this->getConstraintPtr()->First = FirstIndex; this->getConstraintPtr()->FirstPos = (Sketcher::PointPos) FirstPos; this->getConstraintPtr()->Value = Value; return 0; } else if (strcmp("DistanceY",ConstraintType) == 0) { FirstPos = SecondIndex; SecondIndex = -1; this->getConstraintPtr()->Type = DistanceY; this->getConstraintPtr()->First = FirstIndex; this->getConstraintPtr()->FirstPos = (Sketcher::PointPos) FirstPos; this->getConstraintPtr()->Value = Value; return 0; } } } PyErr_Clear(); if (PyArg_ParseTuple(args, "siiiO", &ConstraintType, &intArg1, &intArg2, &intArg3, &oNumArg4)) { // Value, ConstraintType, GeoIndex1, PosIndex1, GeoIndex2, PosIndex2 if (PyInt_Check(oNumArg4)) { intArg4 = PyInt_AsLong(oNumArg4); bool valid = false; if (strcmp("Coincident", ConstraintType) == 0) { this->getConstraintPtr()->Type = Coincident; valid = true; } else if (strcmp("Horizontal", ConstraintType) == 0) { this->getConstraintPtr()->Type = Horizontal; valid = true; } else if (strcmp("Vertical", ConstraintType) == 0) { this->getConstraintPtr()->Type = Vertical; valid = true; } else if (strcmp("Perpendicular", ConstraintType) == 0) { this->getConstraintPtr()->Type = Perpendicular; valid = true; } else if (strcmp("Tangent", ConstraintType) == 0) { this->getConstraintPtr()->Type = Tangent; valid = true; } else if (strcmp("TangentViaPoint", ConstraintType) == 0) { this->getConstraintPtr()->Type = Tangent; //valid = true;//non-standard assignment this->getConstraintPtr()->First = intArg1; this->getConstraintPtr()->FirstPos = Sketcher::none; this->getConstraintPtr()->Second = intArg2; this->getConstraintPtr()->SecondPos = Sketcher::none; this->getConstraintPtr()->Third = intArg3; this->getConstraintPtr()->ThirdPos = (Sketcher::PointPos) intArg4; return 0; } else if (strcmp("PerpendicularViaPoint", ConstraintType) == 0) { this->getConstraintPtr()->Type = Perpendicular; //valid = true;//non-standard assignment this->getConstraintPtr()->First = intArg1; this->getConstraintPtr()->FirstPos = Sketcher::none; this->getConstraintPtr()->Second = intArg2; this->getConstraintPtr()->SecondPos = Sketcher::none; this->getConstraintPtr()->Third = intArg3; this->getConstraintPtr()->ThirdPos = (Sketcher::PointPos) intArg4; return 0; } if (valid) { this->getConstraintPtr()->First = intArg1; this->getConstraintPtr()->FirstPos = (Sketcher::PointPos) intArg2; this->getConstraintPtr()->Second = intArg3; this->getConstraintPtr()->SecondPos = (Sketcher::PointPos) intArg4; return 0; } } // ConstraintType, GeoIndex1, PosIndex1, GeoIndex2, Value if (PyNumber_Check(oNumArg4)) { // can be float or int Value = PyFloat_AsDouble(oNumArg4); if (strcmp("Distance",ConstraintType) == 0 ) { this->getConstraintPtr()->Type = Distance; this->getConstraintPtr()->First = intArg1; this->getConstraintPtr()->FirstPos = (Sketcher::PointPos) intArg2; this->getConstraintPtr()->Second = intArg3; this->getConstraintPtr()->Value = Value; return 0; } } } PyErr_Clear(); if (PyArg_ParseTuple(args, "siiiiO", &ConstraintType, &intArg1, &intArg2, &intArg3, &intArg4, &oNumArg5)) { // ConstraintType, GeoIndex1, PosIndex1, GeoIndex2, PosIndex2, GeoIndex3 if (PyInt_Check(oNumArg5)) { intArg5 = PyInt_AsLong(oNumArg5); if (strcmp("Symmetric",ConstraintType) == 0 ) { this->getConstraintPtr()->Type = Symmetric; this->getConstraintPtr()->First = intArg1; this->getConstraintPtr()->FirstPos = (Sketcher::PointPos) intArg2; this->getConstraintPtr()->Second = intArg3; this->getConstraintPtr()->SecondPos = (Sketcher::PointPos) intArg4; this->getConstraintPtr()->Third = intArg5; return 0; } } // ConstraintType, GeoIndex1, PosIndex1, GeoIndex2, PosIndex2, Value if (PyNumber_Check(oNumArg5)) { // can be float or int Value = PyFloat_AsDouble(oNumArg5); bool valid=false; if (strcmp("Distance",ConstraintType) == 0 ) { this->getConstraintPtr()->Type = Distance; valid = true; } else if (strcmp("DistanceX",ConstraintType) == 0) { this->getConstraintPtr()->Type = DistanceX; valid = true; } else if (strcmp("DistanceY",ConstraintType) == 0) { this->getConstraintPtr()->Type = DistanceY; valid = true; } else if (strcmp("Angle",ConstraintType) == 0 ) { if (PyObject_TypeCheck(oNumArg5, &(Base::QuantityPy::Type))) { Base::Quantity q = *(static_cast(oNumArg5)->getQuantityPtr()); if (q.getUnit() == Base::Unit::Angle) Value = q.getValueAs(Base::Quantity::Radian); } this->getConstraintPtr()->Type = Angle; valid = true; } else if (strcmp("AngleViaPoint",ConstraintType) == 0 ) { if (PyObject_TypeCheck(oNumArg5, &(Base::QuantityPy::Type))) { Base::Quantity q = *(static_cast(oNumArg5)->getQuantityPtr()); if (q.getUnit() == Base::Unit::Angle) Value = q.getValueAs(Base::Quantity::Radian); } this->getConstraintPtr()->Type = Angle; //valid = true;//non-standard assignment this->getConstraintPtr()->First = intArg1; this->getConstraintPtr()->FirstPos = Sketcher::none; this->getConstraintPtr()->Second = intArg2; //let's goof up all the terminology =) this->getConstraintPtr()->SecondPos = Sketcher::none; this->getConstraintPtr()->Third = intArg3; this->getConstraintPtr()->ThirdPos = (Sketcher::PointPos) intArg4; this->getConstraintPtr()->Value = Value; return 0; } if (valid) { this->getConstraintPtr()->First = intArg1; this->getConstraintPtr()->FirstPos = (Sketcher::PointPos) intArg2; this->getConstraintPtr()->Second = intArg3; this->getConstraintPtr()->SecondPos = (Sketcher::PointPos) intArg4; this->getConstraintPtr()->Value = Value; return 0; } } } PyErr_Clear(); if (PyArg_ParseTuple(args, "siiiiiO", &ConstraintType, &FirstIndex, &FirstPos, &SecondIndex, &SecondPos, &ThirdIndex, &index_or_value)) { if (PyInt_Check(index_or_value)) { ThirdPos = PyInt_AsLong(index_or_value); // ConstraintType, GeoIndex1, PosIndex1, GeoIndex2, PosIndex2, GeoIndex3, PosIndex3 if (strcmp("Symmetric",ConstraintType) == 0 ) { this->getConstraintPtr()->Type = Symmetric; this->getConstraintPtr()->First = FirstIndex; this->getConstraintPtr()->FirstPos = (Sketcher::PointPos) FirstPos; this->getConstraintPtr()->Second = SecondIndex; this->getConstraintPtr()->SecondPos = (Sketcher::PointPos) SecondPos; this->getConstraintPtr()->Third = ThirdIndex; this->getConstraintPtr()->ThirdPos = (Sketcher::PointPos) ThirdPos; return 0; } } if (PyNumber_Check(index_or_value)) { // can be float or int Value = PyFloat_AsDouble(index_or_value); if (strcmp("SnellsLaw",ConstraintType) == 0 ) { this->getConstraintPtr()->Type = SnellsLaw; this->getConstraintPtr()->First = FirstIndex; this->getConstraintPtr()->FirstPos = (Sketcher::PointPos) FirstPos; this->getConstraintPtr()->Second = SecondIndex; this->getConstraintPtr()->SecondPos = (Sketcher::PointPos) SecondPos; this->getConstraintPtr()->Third = ThirdIndex; this->getConstraintPtr()->ThirdPos = none; this->getConstraintPtr()->Value = Value; return 0; } } } std::stringstream str; str << "Invalid parameters: "; Py::Tuple tuple(args); str << tuple.as_string() << std::endl; str << "Constraint constructor accepts:" << std::endl << "-- empty parameter list" << std::endl << "-- Constraint type and index" << std::endl; PyErr_SetString(PyExc_TypeError, str.str().c_str()); return -1; } // returns a string which represents the object e.g. when printed in python std::string ConstraintPy::representation(void) const { std::stringstream result; result << "getConstraintPtr()->Type) { case None : result << "'None'>";break; case DistanceX : result << "'DistanceX'>";break; case DistanceY : result << "'DistanceY'>";break; case Coincident : result << "'Coincident'>";break; case Horizontal : result << "'Horizontal' (" << getConstraintPtr()->First << ")>";break; case Vertical : result << "'Vertical' (" << getConstraintPtr()->First << ")>";break; case Parallel : result << "'Parallel'>";break; case Tangent : if (this->getConstraintPtr()->Third == Constraint::GeoUndef) result << "'Tangent'>"; else result << "'TangentViaPoint'>"; break; case Perpendicular : if (this->getConstraintPtr()->Third == Constraint::GeoUndef) result << "'Perpendicular'>"; else result << "'PerpendicularViaPoint'>"; break; case Distance : result << "'Distance'>";break; case Angle : if (this->getConstraintPtr()->Third == Constraint::GeoUndef) result << "'Angle'>"; else result << "'AngleViaPoint'>"; break; case Symmetric : result << "'Symmetric'>"; break; case SnellsLaw : result << "'SnellsLaw'>"; break; case InternalAlignment : switch(this->getConstraintPtr()->AlignmentType) { case Undef : result << "'InternalAlignment:Undef'>";break; case EllipseMajorDiameter : result << "'InternalAlignment:EllipseMajorDiameter'>";break; case EllipseMinorDiameter : result << "'InternalAlignment:EllipseMinorDiameter'>";break; case EllipseFocus1 : result << "'InternalAlignment:EllipseFocus1'>";break; case EllipseFocus2 : result << "'InternalAlignment:EllipseFocus2'>";break; default : result << "'InternalAlignment:?'>";break; } break; default : result << "'?'>";break; } return result.str(); } Py::Int ConstraintPy::getFirst(void) const { return Py::Int(this->getConstraintPtr()->First); } void ConstraintPy::setFirst(Py::Int arg) { this->getConstraintPtr()->First = arg; } Py::Int ConstraintPy::getSecond(void) const { return Py::Int(this->getConstraintPtr()->Second); } void ConstraintPy::setSecond(Py::Int arg) { this->getConstraintPtr()->Second = arg; } Py::String ConstraintPy::getName(void) const { return Py::String(this->getConstraintPtr()->Name); } void ConstraintPy::setName(Py::String arg) { this->getConstraintPtr()->Name = arg; } PyObject *ConstraintPy::getCustomAttributes(const char* /*attr*/) const { return 0; } int ConstraintPy::setCustomAttributes(const char* /*attr*/, PyObject* /*obj*/) { return 0; }