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#ifndef Magnum_SceneGraph_MatrixTransformation3D_h
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#define Magnum_SceneGraph_MatrixTransformation3D_h
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/*
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This file is part of Magnum.
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Copyright © 2010, 2011, 2012, 2013, 2014, 2015, 2016, 2017, 2018, 2019,
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2020, 2021 Vladimír Vondruš <mosra@centrum.cz>
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Permission is hereby granted, free of charge, to any person obtaining a
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copy of this software and associated documentation files (the "Software"),
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to deal in the Software without restriction, including without limitation
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the rights to use, copy, modify, merge, publish, distribute, sublicense,
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and/or sell copies of the Software, and to permit persons to whom the
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Software is furnished to do so, subject to the following conditions:
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The above copyright notice and this permission notice shall be included
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in all copies or substantial portions of the Software.
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THE SOFTWARE IS PROVIDED "AS IS", WITHOUT WARRANTY OF ANY KIND, EXPRESS OR
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IMPLIED, INCLUDING BUT NOT LIMITED TO THE WARRANTIES OF MERCHANTABILITY,
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FITNESS FOR A PARTICULAR PURPOSE AND NONINFRINGEMENT. IN NO EVENT SHALL
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THE AUTHORS OR COPYRIGHT HOLDERS BE LIABLE FOR ANY CLAIM, DAMAGES OR OTHER
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LIABILITY, WHETHER IN AN ACTION OF CONTRACT, TORT OR OTHERWISE, ARISING
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FROM, OUT OF OR IN CONNECTION WITH THE SOFTWARE OR THE USE OR OTHER
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DEALINGS IN THE SOFTWARE.
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*/
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/** @file
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* @brief Class @ref Magnum::SceneGraph::BasicMatrixTransformation3D, typedef @ref Magnum::SceneGraph::MatrixTransformation3D
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*/
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#include "Magnum/Math/Matrix4.h"
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#include "Magnum/SceneGraph/AbstractTranslationRotationScaling3D.h"
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#include "Magnum/SceneGraph/Object.h"
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namespace Magnum { namespace SceneGraph {
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/**
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@brief Three-dimensional transformation implemented using matrices
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Uses @ref Math::Matrix4 as underlying transformation type.
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@see @ref scenegraph, @ref MatrixTransformation3D,
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@ref BasicRigidMatrixTransformation3D, @ref BasicMatrixTransformation2D
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*/
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template<class T> class BasicMatrixTransformation3D: public AbstractBasicTranslationRotationScaling3D<T> {
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public:
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/** @brief Underlying transformation type */
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typedef Math::Matrix4<T> DataType;
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/** @brief Object transformation */
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Math::Matrix4<T> transformation() const { return _transformation; }
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/**
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* @brief Set transformation
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* @return Reference to self (for method chaining)
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*/
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Object<BasicMatrixTransformation3D<T>>& setTransformation(const Math::Matrix4<T>& transformation) {
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/* Setting transformation is forbidden for the scene */
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/** @todo Assert for this? */
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/** @todo Do this in some common code so we don't need to include Object? */
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if(!static_cast<Object<BasicMatrixTransformation3D<T>>*>(this)->isScene()) {
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_transformation = transformation;
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static_cast<Object<BasicMatrixTransformation3D<T>>*>(this)->setDirty();
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}
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return static_cast<Object<BasicMatrixTransformation3D<T>>&>(*this);
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}
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SceneGraph: don't use virtual calls when setting transformations.
Until now, all calls to e.g. `Object::translate()` were virtual, which
is _very_ bad for performance. The virtual call is only needed when
setting the transformation via some interface, e.g.
`AbstractTranslationRotation3D`, as the caller doesn't know which
transformation implementation is used.
Now all public-facing transformation methods are inline non-virtual
functions, which are in most cases calling directly the transformation
implementation. In `Abstract*` transformation interfaces these functions
call private virtual `do*()` implementations, which are (re)implemented
in subclasses, but aren't used anywhere except when transforming
directly through the `Abstract*` interfaces. This should have good
impact on performance when doing many transformations in every frame
(although I can't verify it anywhere, as I don't have any significantly
large animated demo). Except of course when doing it through the virtual
interfaces.
As the public-facing transformation methods are now non-virtual, there
are now no "covariant return" issues and they can now return proper
`Object<*Transformation*>` type instead of just `*Transformation*`,
which makes full non-WTF method chaining possible:
Object2D* obj2;
obj2->translate({0.5f, -1.0f}) // Transformation method
->setParentKeepTransformation(obj1); // Object method
Or even this:
Object2D* obj = (new Object2D)->rotate(-15.0_degf);
13 years ago
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/** @copydoc AbstractTranslationRotationScaling3D::resetTransformation() */
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Object<BasicMatrixTransformation3D<T>>& resetTransformation() {
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return setTransformation({});
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}
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/**
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* @brief Transform the object
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* @return Reference to self (for method chaining)
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*
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* @see @ref transformLocal()
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*/
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Object<BasicMatrixTransformation3D<T>>& transform(const Math::Matrix4<T>& transformation) {
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return setTransformation(transformation*_transformation);
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}
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/**
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* @brief Transform the object as a local transformation
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*
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* Similar to the above, except that the transformation is applied
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* before all others.
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*/
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Object<BasicMatrixTransformation3D<T>>& transformLocal(const Math::Matrix4<T>& transformation) {
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return setTransformation(_transformation*transformation);
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}
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/**
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* @brief Translate the object
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* @return Reference to self (for method chaining)
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*
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* Same as calling @ref transform() with @ref Math::Matrix4::translation().
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* @see @ref translateLocal(), @ref Math::Vector3::xAxis(),
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* @ref Math::Vector3::yAxis(), @ref Math::Vector3::zAxis()
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*/
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Object<BasicMatrixTransformation3D<T>>& translate(const Math::Vector3<T>& vector) {
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return transform(Math::Matrix4<T>::translation(vector));
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}
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/**
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* @brief Translate the object as a local transformation
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*
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* Similar to the above, except that the transformation is applied
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* before all others. Same as calling @ref transformLocal() with
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* @ref Math::Matrix4::translation().
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*/
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Object<BasicMatrixTransformation3D<T>>& translateLocal(const Math::Vector3<T>& vector) {
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return transformLocal(Math::Matrix4<T>::translation(vector));
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}
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/**
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* @brief Rotate the object using a quaternion
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* @param quaternion Normalized quaternion
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* @return Reference to self (for method chaining)
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* @m_since{2020,06}
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*
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* Expects that the quaternion is normalized.
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* @see @ref rotate(Math::Rad<T>, const Math::Vector3<T>&),
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* @ref rotateLocal(const Math::Quaternion<T>&), @ref rotateX(),
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* @ref rotateY(), @ref rotateZ()
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*/
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Object<BasicMatrixTransformation3D<T>>& rotate(const Math::Quaternion<T>& quaternion);
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/**
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* @brief Rotate the object using a quaternion as a local transformation
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* @m_since{2020,06}
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*
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* Similar to the above, except that the transformation is applied
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* before all others.
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*/
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Object<BasicMatrixTransformation3D<T>>& rotateLocal(const Math::Quaternion<T>& quaternion);
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/**
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* @brief Rotate the object
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* @param angle Angle (counterclockwise)
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* @param normalizedAxis Normalized rotation axis
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* @return Reference to self (for method chaining)
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*
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* Same as calling @ref transform() with @ref Math::Matrix4::rotation().
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* @see @ref rotate(const Math::Quaternion<T>&), @ref rotateLocal(),
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* @ref rotateX(), @ref rotateY(), @ref rotateZ(),
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* @ref Math::Vector3::xAxis(), @ref Math::Vector3::yAxis(),
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* @ref Math::Vector3::zAxis()
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*/
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Object<BasicMatrixTransformation3D<T>>& rotate(Math::Rad<T> angle, const Math::Vector3<T>& normalizedAxis) {
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return transform(Math::Matrix4<T>::rotation(angle, normalizedAxis));
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}
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/**
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* @brief Rotate the object as a local transformation
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*
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* Similar to the above, except that the transformation is applied
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* before all others. Same as calling @ref transformLocal() with
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* @ref Math::Matrix4::rotation().
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*/
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Object<BasicMatrixTransformation3D<T>>& rotateLocal(Math::Rad<T> angle, const Math::Vector3<T>& normalizedAxis) {
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return transformLocal(Math::Matrix4<T>::rotation(angle, normalizedAxis));
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}
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/**
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* @brief Rotate the object around X axis
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* @param angle Angle (counterclockwise)
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* @return Reference to self (for method chaining)
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*
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* Same as calling @ref transform() with @ref Math::Matrix4::rotationX().
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* @see @ref rotateXLocal()
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*/
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Object<BasicMatrixTransformation3D<T>>& rotateX(Math::Rad<T> angle) {
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return transform(Math::Matrix4<T>::rotationX(angle));
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}
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/**
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* @brief Rotate the object around X axis as a local transformation
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*
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* Similar to the above, except that the transformation is applied
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* before all others. Same as calling @ref transformLocal() with
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* @ref Math::Matrix4::rotationX().
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*/
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Object<BasicMatrixTransformation3D<T>>& rotateXLocal(Math::Rad<T> angle) {
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return transformLocal(Math::Matrix4<T>::rotationX(angle));
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}
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/**
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* @brief Rotate the object around Y axis
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* @param angle Angle (counterclockwise)
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* @return Reference to self (for method chaining)
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*
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* Same as calling @ref transform() with @ref Math::Matrix4::rotationY().
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* @see @ref rotateYLocal()
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*/
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Object<BasicMatrixTransformation3D<T>>& rotateY(Math::Rad<T> angle) {
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return transform(Math::Matrix4<T>::rotationY(angle));
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}
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/**
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* @brief Rotate the object around Y axis as a local transformation
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*
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* Similar to the above, except that the transformation is applied
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* before all others. Same as calling @ref transformLocal() with
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* @ref Math::Matrix4::rotationY().
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*/
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Object<BasicMatrixTransformation3D<T>>& rotateYLocal(Math::Rad<T> angle) {
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return transformLocal(Math::Matrix4<T>::rotationY(angle));
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}
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/**
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* @brief Rotate the object around Z axis
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* @param angle Angle (counterclockwise)
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* @return Reference to self (for method chaining)
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*
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* Same as calling @ref transform() with @ref Math::Matrix4::rotationZ().
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* @see @ref rotateZLocal()
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*/
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Object<BasicMatrixTransformation3D<T>>& rotateZ(Math::Rad<T> angle) {
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return transform(Math::Matrix4<T>::rotationZ(angle));
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}
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/**
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* @brief Rotate the object around Z axis as a local transformation
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*
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* Similar to the above, except that the transformation is applied
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* before all others. Same as calling @ref transformLocal() with
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* @ref Math::Matrix4::rotationZ().
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*/
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Object<BasicMatrixTransformation3D<T>>& rotateZLocal(Math::Rad<T> angle) {
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return transformLocal(Math::Matrix4<T>::rotationZ(angle));
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}
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/**
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* @brief Scale the object
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* @return Reference to self (for method chaining)
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*
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* Same as calling @ref transform() with @ref Math::Matrix4::scaling().
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* @see @ref scaleLocal(), @ref Math::Vector3::xScale(),
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* @ref Math::Vector3::yScale(), @ref Math::Vector3::zScale()
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*/
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Object<BasicMatrixTransformation3D<T>>& scale(const Math::Vector3<T>& vector) {
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return transform(Math::Matrix4<T>::scaling(vector));
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}
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/**
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* @brief Scale the object as a local transformation
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*
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* Similar to the above, except that the transformation is applied
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* before all others. Same as calling @ref transformLocal() with
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* @ref Math::Matrix4::scaling().
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*/
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Object<BasicMatrixTransformation3D<T>>& scaleLocal(const Math::Vector3<T>& vector) {
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return transformLocal(Math::Matrix4<T>::scaling(vector));
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}
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/**
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* @brief Reflect the object
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* @param normal Normal of the plane through which to reflect
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* (normalized)
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* @return Reference to self (for method chaining)
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*
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* Same as calling @ref transform() with @ref Math::Matrix4::reflection().
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* @see @ref reflectLocal()
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*/
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Object<BasicMatrixTransformation3D<T>>& reflect(const Math::Vector3<T>& normal) {
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return transform(Math::Matrix4<T>::reflection(normal));
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}
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/**
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* @brief Reflect the object as a local transformation
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*
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* Similar to the above, except that the transformation is applied
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* before all others. Same as calling @ref transformLocal() with
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* @ref Math::Matrix4::reflection().
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*/
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Object<BasicMatrixTransformation3D<T>>& reflectLocal(const Math::Vector3<T>& normal) {
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return transformLocal(Math::Matrix4<T>::reflection(normal));
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}
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protected:
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/* Allow construction only from Object */
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explicit BasicMatrixTransformation3D() = default;
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private:
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SceneGraph: don't use virtual calls when setting transformations.
Until now, all calls to e.g. `Object::translate()` were virtual, which
is _very_ bad for performance. The virtual call is only needed when
setting the transformation via some interface, e.g.
`AbstractTranslationRotation3D`, as the caller doesn't know which
transformation implementation is used.
Now all public-facing transformation methods are inline non-virtual
functions, which are in most cases calling directly the transformation
implementation. In `Abstract*` transformation interfaces these functions
call private virtual `do*()` implementations, which are (re)implemented
in subclasses, but aren't used anywhere except when transforming
directly through the `Abstract*` interfaces. This should have good
impact on performance when doing many transformations in every frame
(although I can't verify it anywhere, as I don't have any significantly
large animated demo). Except of course when doing it through the virtual
interfaces.
As the public-facing transformation methods are now non-virtual, there
are now no "covariant return" issues and they can now return proper
`Object<*Transformation*>` type instead of just `*Transformation*`,
which makes full non-WTF method chaining possible:
Object2D* obj2;
obj2->translate({0.5f, -1.0f}) // Transformation method
->setParentKeepTransformation(obj1); // Object method
Or even this:
Object2D* obj = (new Object2D)->rotate(-15.0_degf);
13 years ago
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|
|
void doResetTransformation() override final { resetTransformation(); }
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void doTranslate(const Math::Vector3<T>& vector) override final { translate(vector); }
|
|
|
|
|
void doTranslateLocal(const Math::Vector3<T>& vector) override final { translateLocal(vector); }
|
SceneGraph: don't use virtual calls when setting transformations.
Until now, all calls to e.g. `Object::translate()` were virtual, which
is _very_ bad for performance. The virtual call is only needed when
setting the transformation via some interface, e.g.
`AbstractTranslationRotation3D`, as the caller doesn't know which
transformation implementation is used.
Now all public-facing transformation methods are inline non-virtual
functions, which are in most cases calling directly the transformation
implementation. In `Abstract*` transformation interfaces these functions
call private virtual `do*()` implementations, which are (re)implemented
in subclasses, but aren't used anywhere except when transforming
directly through the `Abstract*` interfaces. This should have good
impact on performance when doing many transformations in every frame
(although I can't verify it anywhere, as I don't have any significantly
large animated demo). Except of course when doing it through the virtual
interfaces.
As the public-facing transformation methods are now non-virtual, there
are now no "covariant return" issues and they can now return proper
`Object<*Transformation*>` type instead of just `*Transformation*`,
which makes full non-WTF method chaining possible:
Object2D* obj2;
obj2->translate({0.5f, -1.0f}) // Transformation method
->setParentKeepTransformation(obj1); // Object method
Or even this:
Object2D* obj = (new Object2D)->rotate(-15.0_degf);
13 years ago
|
|
|
|
|
|
|
|
void doRotate(const Math::Quaternion<T>& quaternion) override final {
|
|
|
|
|
rotate(quaternion);
|
|
|
|
|
}
|
|
|
|
|
void doRotateLocal(const Math::Quaternion<T>& quaternion) override final {
|
|
|
|
|
rotateLocal(quaternion);
|
|
|
|
|
}
|
|
|
|
|
|
|
|
|
|
void doRotate(Math::Rad<T> angle, const Math::Vector3<T>& normalizedAxis) override final {
|
|
|
|
|
rotate(angle, normalizedAxis);
|
SceneGraph: don't use virtual calls when setting transformations.
Until now, all calls to e.g. `Object::translate()` were virtual, which
is _very_ bad for performance. The virtual call is only needed when
setting the transformation via some interface, e.g.
`AbstractTranslationRotation3D`, as the caller doesn't know which
transformation implementation is used.
Now all public-facing transformation methods are inline non-virtual
functions, which are in most cases calling directly the transformation
implementation. In `Abstract*` transformation interfaces these functions
call private virtual `do*()` implementations, which are (re)implemented
in subclasses, but aren't used anywhere except when transforming
directly through the `Abstract*` interfaces. This should have good
impact on performance when doing many transformations in every frame
(although I can't verify it anywhere, as I don't have any significantly
large animated demo). Except of course when doing it through the virtual
interfaces.
As the public-facing transformation methods are now non-virtual, there
are now no "covariant return" issues and they can now return proper
`Object<*Transformation*>` type instead of just `*Transformation*`,
which makes full non-WTF method chaining possible:
Object2D* obj2;
obj2->translate({0.5f, -1.0f}) // Transformation method
->setParentKeepTransformation(obj1); // Object method
Or even this:
Object2D* obj = (new Object2D)->rotate(-15.0_degf);
13 years ago
|
|
|
}
|
|
|
|
|
void doRotateLocal(Math::Rad<T> angle, const Math::Vector3<T>& normalizedAxis) override final {
|
|
|
|
|
rotateLocal(angle, normalizedAxis);
|
SceneGraph: don't use virtual calls when setting transformations.
Until now, all calls to e.g. `Object::translate()` were virtual, which
is _very_ bad for performance. The virtual call is only needed when
setting the transformation via some interface, e.g.
`AbstractTranslationRotation3D`, as the caller doesn't know which
transformation implementation is used.
Now all public-facing transformation methods are inline non-virtual
functions, which are in most cases calling directly the transformation
implementation. In `Abstract*` transformation interfaces these functions
call private virtual `do*()` implementations, which are (re)implemented
in subclasses, but aren't used anywhere except when transforming
directly through the `Abstract*` interfaces. This should have good
impact on performance when doing many transformations in every frame
(although I can't verify it anywhere, as I don't have any significantly
large animated demo). Except of course when doing it through the virtual
interfaces.
As the public-facing transformation methods are now non-virtual, there
are now no "covariant return" issues and they can now return proper
`Object<*Transformation*>` type instead of just `*Transformation*`,
which makes full non-WTF method chaining possible:
Object2D* obj2;
obj2->translate({0.5f, -1.0f}) // Transformation method
->setParentKeepTransformation(obj1); // Object method
Or even this:
Object2D* obj = (new Object2D)->rotate(-15.0_degf);
13 years ago
|
|
|
}
|
|
|
|
|
|
|
|
|
|
void doRotateX(Math::Rad<T> angle) override final { rotateX(angle); }
|
|
|
|
|
void doRotateXLocal(Math::Rad<T> angle) override final { rotateXLocal(angle); }
|
SceneGraph: don't use virtual calls when setting transformations.
Until now, all calls to e.g. `Object::translate()` were virtual, which
is _very_ bad for performance. The virtual call is only needed when
setting the transformation via some interface, e.g.
`AbstractTranslationRotation3D`, as the caller doesn't know which
transformation implementation is used.
Now all public-facing transformation methods are inline non-virtual
functions, which are in most cases calling directly the transformation
implementation. In `Abstract*` transformation interfaces these functions
call private virtual `do*()` implementations, which are (re)implemented
in subclasses, but aren't used anywhere except when transforming
directly through the `Abstract*` interfaces. This should have good
impact on performance when doing many transformations in every frame
(although I can't verify it anywhere, as I don't have any significantly
large animated demo). Except of course when doing it through the virtual
interfaces.
As the public-facing transformation methods are now non-virtual, there
are now no "covariant return" issues and they can now return proper
`Object<*Transformation*>` type instead of just `*Transformation*`,
which makes full non-WTF method chaining possible:
Object2D* obj2;
obj2->translate({0.5f, -1.0f}) // Transformation method
->setParentKeepTransformation(obj1); // Object method
Or even this:
Object2D* obj = (new Object2D)->rotate(-15.0_degf);
13 years ago
|
|
|
|
|
|
|
|
void doRotateY(Math::Rad<T> angle) override final { rotateY(angle); }
|
|
|
|
|
void doRotateYLocal(Math::Rad<T> angle) override final { rotateYLocal(angle); }
|
SceneGraph: don't use virtual calls when setting transformations.
Until now, all calls to e.g. `Object::translate()` were virtual, which
is _very_ bad for performance. The virtual call is only needed when
setting the transformation via some interface, e.g.
`AbstractTranslationRotation3D`, as the caller doesn't know which
transformation implementation is used.
Now all public-facing transformation methods are inline non-virtual
functions, which are in most cases calling directly the transformation
implementation. In `Abstract*` transformation interfaces these functions
call private virtual `do*()` implementations, which are (re)implemented
in subclasses, but aren't used anywhere except when transforming
directly through the `Abstract*` interfaces. This should have good
impact on performance when doing many transformations in every frame
(although I can't verify it anywhere, as I don't have any significantly
large animated demo). Except of course when doing it through the virtual
interfaces.
As the public-facing transformation methods are now non-virtual, there
are now no "covariant return" issues and they can now return proper
`Object<*Transformation*>` type instead of just `*Transformation*`,
which makes full non-WTF method chaining possible:
Object2D* obj2;
obj2->translate({0.5f, -1.0f}) // Transformation method
->setParentKeepTransformation(obj1); // Object method
Or even this:
Object2D* obj = (new Object2D)->rotate(-15.0_degf);
13 years ago
|
|
|
|
|
|
|
|
void doRotateZ(Math::Rad<T> angle) override final { rotateZ(angle); }
|
|
|
|
|
void doRotateZLocal(Math::Rad<T> angle) override final { rotateZLocal(angle); }
|
|
|
|
|
|
|
|
|
|
void doScale(const Math::Vector3<T>& vector) override final { scale(vector); }
|
|
|
|
|
void doScaleLocal(const Math::Vector3<T>& vector) override final { scaleLocal(vector); }
|
SceneGraph: don't use virtual calls when setting transformations.
Until now, all calls to e.g. `Object::translate()` were virtual, which
is _very_ bad for performance. The virtual call is only needed when
setting the transformation via some interface, e.g.
`AbstractTranslationRotation3D`, as the caller doesn't know which
transformation implementation is used.
Now all public-facing transformation methods are inline non-virtual
functions, which are in most cases calling directly the transformation
implementation. In `Abstract*` transformation interfaces these functions
call private virtual `do*()` implementations, which are (re)implemented
in subclasses, but aren't used anywhere except when transforming
directly through the `Abstract*` interfaces. This should have good
impact on performance when doing many transformations in every frame
(although I can't verify it anywhere, as I don't have any significantly
large animated demo). Except of course when doing it through the virtual
interfaces.
As the public-facing transformation methods are now non-virtual, there
are now no "covariant return" issues and they can now return proper
`Object<*Transformation*>` type instead of just `*Transformation*`,
which makes full non-WTF method chaining possible:
Object2D* obj2;
obj2->translate({0.5f, -1.0f}) // Transformation method
->setParentKeepTransformation(obj1); // Object method
Or even this:
Object2D* obj = (new Object2D)->rotate(-15.0_degf);
13 years ago
|
|
|
|
|
|
|
|
Math::Matrix4<T> _transformation;
|
|
|
|
|
};
|
|
|
|
|
|
|
|
|
|
/**
|
|
|
|
|
@brief Three-dimensional transformation for float scenes implemented using matrices
|
|
|
|
|
|
|
|
|
|
@see @ref MatrixTransformation2D
|
|
|
|
|
*/
|
|
|
|
|
typedef BasicMatrixTransformation3D<Float> MatrixTransformation3D;
|
|
|
|
|
|
|
|
|
|
namespace Implementation {
|
|
|
|
|
|
|
|
|
|
template<class T> struct Transformation<BasicMatrixTransformation3D<T>> {
|
|
|
|
|
constexpr static Math::Matrix4<T> fromMatrix(const Math::Matrix4<T>& matrix) {
|
|
|
|
|
return matrix;
|
|
|
|
|
}
|
|
|
|
|
|
|
|
|
|
constexpr static Math::Matrix4<T> toMatrix(const Math::Matrix4<T>& transformation) {
|
|
|
|
|
return transformation;
|
|
|
|
|
}
|
|
|
|
|
|
|
|
|
|
static Math::Matrix4<T> compose(const Math::Matrix4<T>& parent, const Math::Matrix4<T>& child) {
|
|
|
|
|
return parent*child;
|
|
|
|
|
}
|
|
|
|
|
|
|
|
|
|
static Math::Matrix4<T> inverted(const Math::Matrix4<T>& transformation) {
|
|
|
|
|
return transformation.inverted();
|
|
|
|
|
}
|
|
|
|
|
};
|
|
|
|
|
|
|
|
|
|
}
|
|
|
|
|
|
|
|
|
|
#if defined(CORRADE_TARGET_WINDOWS) && !(defined(CORRADE_TARGET_MINGW) && !defined(CORRADE_TARGET_CLANG))
|
|
|
|
|
extern template class MAGNUM_SCENEGRAPH_EXPORT BasicMatrixTransformation3D<Float>;
|
|
|
|
|
extern template class MAGNUM_SCENEGRAPH_EXPORT Object<BasicMatrixTransformation3D<Float>>;
|
|
|
|
|
#endif
|
|
|
|
|
|
|
|
|
|
}}
|
|
|
|
|
|
|
|
|
|
#endif
|
