// // ******************************************************************** // * License and Disclaimer * // * * // * The Geant4 software is copyright of the Copyright Holders of * // * the Geant4 Collaboration. It is provided under the terms and * // * conditions of the Geant4 Software License, included in the file * // * LICENSE and available at http://cern.ch/geant4/license . These * // * include a list of copyright holders. * // * * // * Neither the authors of this software system, nor their employing * // * institutes,nor the agencies providing financial support for this * // * work make any representation or warranty, express or implied, * // * regarding this software system or assume any liability for its * // * use. Please see the license in the file LICENSE and URL above * // * for the full disclaimer and the limitation of liability. * // * * // * This code implementation is the result of the scientific and * // * technical work of the GEANT4 collaboration. * // * By using, copying, modifying or distributing the software (or * // * any work based on the software) you agree to acknowledge its * // * use in resulting scientific publications, and indicate your * // * acceptance of all terms of the Geant4 Software license. * // ******************************************************************** // // $Id: pyG4ThreeVector.cc,v 1.5 2006/06/29 15:33:24 gunter Exp $ // $Name: geant4-09-04-beta-01 $ // ==================================================================== // pyG4ThreeVector.cc // // 2005 Q // ==================================================================== #include #include "G4ThreeVector.hh" #include "G4RotationMatrix.hh" using namespace boost::python; using namespace CLHEP; typedef G4ThreeVector XXX; // ... // ==================================================================== // thin wrappers // ==================================================================== namespace pyG4ThreeVector { G4double(XXX::*f1_theta)() const= &XXX::theta; G4double(XXX::*f2_theta)(const XXX&) const = &XXX::theta; G4double(XXX::*f1_cosTheta)() const= &XXX::cosTheta; G4double(XXX::*f2_cosTheta)(const XXX&) const = &XXX::cosTheta; G4double(XXX::*f1_cos2Theta)() const= &XXX::cos2Theta; G4double(XXX::*f2_cos2Theta)(const XXX&) const = &XXX::cos2Theta; G4double(XXX::*f1_perp2)() const= &XXX::perp2; G4double(XXX::*f2_perp2)(const XXX&) const = &XXX::perp2; G4double(XXX::*f1_perp)() const= &XXX::perp; G4double(XXX::*f2_perp)(const XXX&) const = &XXX::perp; G4double(XXX::*f1_angle)() const= &XXX::angle; G4double(XXX::*f2_angle)(const XXX&) const = &XXX::angle; G4double(XXX::*f1_eta)() const= &XXX::eta; G4double(XXX::*f2_eta)(const XXX&) const = &XXX::eta; XXX(XXX::*f1_project)() const= &XXX::project; XXX(XXX::*f2_project)(const XXX&) const = &XXX::project; XXX(XXX::*f1_perpPart)() const= &XXX::perpPart; XXX(XXX::*f2_perpPart)(const XXX&) const = &XXX::perpPart; G4double(XXX::*f1_rapidity)() const= &XXX::rapidity; G4double(XXX::*f2_rapidity)(const XXX&) const = &XXX::rapidity; G4double(XXX::*f1_polarAngle)(const XXX&) const= &XXX::polarAngle; G4double(XXX::*f2_polarAngle)(const XXX&, const XXX&) const = &XXX::polarAngle; G4double(XXX::*f1_azimAngle)(const XXX&) const= &XXX::azimAngle; G4double(XXX::*f2_azimAngle)(const XXX&, const XXX&) const = &XXX::azimAngle; XXX&(XXX::*f1_rotate)(G4double, const XXX&)= &XXX::rotate; XXX&(XXX::*f2_rotate)(const XXX&, G4double)= &XXX::rotate; XXX&(XXX::*f3_rotate)(const HepAxisAngle&)= &XXX::rotate; XXX&(XXX::*f4_rotate)(const HepEulerAngles&)= &XXX::rotate; XXX&(XXX::*f5_rotate)(G4double, G4double, G4double)= &XXX::rotate; BOOST_PYTHON_MEMBER_FUNCTION_OVERLOADS(f_isNear, isNear, 1, 2); BOOST_PYTHON_MEMBER_FUNCTION_OVERLOADS(f_isParallel, isParallel, 1, 2); BOOST_PYTHON_MEMBER_FUNCTION_OVERLOADS(f_isOrthogonal, isOrthogonal, 1, 2); }; using namespace pyG4ThreeVector; // ==================================================================== // module definition // ==================================================================== void export_G4ThreeVector() { class_("G4ThreeVector", "general 3-vector") // constructors .def(init()) .def(init()) .def(init()) .def(init()) // property .add_property("x", &XXX::x, &XXX::setX) .add_property("y", &XXX::y, &XXX::setY) .add_property("z", &XXX::z, &XXX::setZ) // methods .def("set", &XXX::set) .def("phi", &XXX::phi) .def("mag", &XXX::mag) .def("mag2", &XXX::mag2) .def("setPhi", &XXX::setPhi) .def("setTheta", &XXX::setTheta) .def("setMag", &XXX::setMag) .def("setPerp", &XXX::setPerp) .def("setCylTheta", &XXX::setCylTheta) .def("howNear", &XXX::howNear) .def("deltaR", &XXX::deltaR) .def("unit", &XXX::unit) .def("orthogonal", &XXX::orthogonal) .def("dot", &XXX::dot) .def("cross", &XXX::cross) .def("pseudoRapidity", &XXX::pseudoRapidity) .def("setEta", &XXX::setEta) .def("setCylEta",&XXX::setCylEta) .def("setRThetaPhi", &XXX::setRThetaPhi) .def("setREtaPhi", &XXX::setREtaPhi) .def("setRhoPhiZ", &XXX::setRhoPhiZ) .def("setRhoPhiEta", &XXX::setRhoPhiEta) .def("getX", &XXX::getX) .def("getY", &XXX::getY) .def("getZ", &XXX::getZ) .def("getR", &XXX::getR) .def("getTheta", &XXX::getTheta) .def("getPhi", &XXX::getPhi) .def("r", &XXX::r) .def("rho", &XXX::rho) .def("getRho", &XXX::getRho) .def("getEta", &XXX::getEta) .def("setR", &XXX::setR) .def("setRho", &XXX::setRho) .def("compare", &XXX::compare) .def("diff2", &XXX::diff2) .def("setTolerance", &XXX::setTolerance) .staticmethod("setTolerance") .def("getTolerance", &XXX::getTolerance) .staticmethod("getTolerance") .def("isNear", &XXX::isNear, f_isNear()) .def("isParallel", &XXX::isParallel, f_isParallel()) .def("isOrthogonal", &XXX::isOrthogonal, f_isOrthogonal()) .def("howParallel", &XXX::howParallel) .def("howOrthogonal", &XXX::howOrthogonal) .def("beta", &XXX::beta) .def("gamma", &XXX::gamma) .def("deltaPhi", &XXX::deltaPhi) .def("coLinearRapidity", &XXX::coLinearRapidity) .def("theta", f1_theta) .def("theta", f2_theta) .def("cosTheta", f1_cosTheta) .def("cosTheta", f2_cosTheta) .def("cos2Theta", f1_cos2Theta) .def("cos2Theta", f2_cos2Theta) .def("perp2", f1_perp2) .def("perp2", f2_perp2) .def("angle", f1_angle) .def("angle", f2_angle) .def("eta", f1_eta) .def("eta", f2_eta) .def("project", f1_project) .def("project", f2_project) .def("perpPart", f1_perpPart) .def("perpPart", f2_perpPart) .def("rapidity", f1_rapidity) .def("rapidity", f2_rapidity) .def("polarAngle",f1_polarAngle) .def("polarAngle",f2_polarAngle) .def("azimAngle", f1_azimAngle) .def("azimAngle", f2_azimAngle) .def("rotateX", &XXX::rotateX, return_value_policy()) .def("rotateY", &XXX::rotateY, return_value_policy()) .def("rotateZ", &XXX::rotateZ, return_value_policy()) .def("rotateUz", &XXX::rotateUz, return_value_policy()) .def("transform",&XXX::transform, return_value_policy()) .def("rotate", f1_rotate, return_value_policy()) .def("rotate", f2_rotate, return_value_policy()) .def("rotate", f5_rotate, return_value_policy()) // operators .def(self_ns::str(self)) .def(self == self) .def(self != self) .def(self += self) .def(self -= self) .def(self - self) .def(self + self) .def(self * self) .def(self * G4double()) .def(self / G4double()) .def(G4double() * self) .def(self *= G4double()) .def(self /= G4double()) .def(self > self) .def(self < self) .def(self >= self) .def(self <= self) ; }