# ifndef Magnum_SceneGraph_DualComplexTransformation_h
# define Magnum_SceneGraph_DualComplexTransformation_h
/*
This file is part of Magnum .
Copyright © 2010 , 2011 , 2012 , 2013 , 2014
Vladimír Vondruš < mosra @ centrum . cz >
Permission is hereby granted , free of charge , to any person obtaining a
copy of this software and associated documentation files ( the " Software " ) ,
to deal in the Software without restriction , including without limitation
the rights to use , copy , modify , merge , publish , distribute , sublicense ,
and / or sell copies of the Software , and to permit persons to whom the
Software is furnished to do so , subject to the following conditions :
The above copyright notice and this permission notice shall be included
in all copies or substantial portions of the Software .
THE SOFTWARE IS PROVIDED " AS IS " , WITHOUT WARRANTY OF ANY KIND , EXPRESS OR
IMPLIED , INCLUDING BUT NOT LIMITED TO THE WARRANTIES OF MERCHANTABILITY ,
FITNESS FOR A PARTICULAR PURPOSE AND NONINFRINGEMENT . IN NO EVENT SHALL
THE AUTHORS OR COPYRIGHT HOLDERS BE LIABLE FOR ANY CLAIM , DAMAGES OR OTHER
LIABILITY , WHETHER IN AN ACTION OF CONTRACT , TORT OR OTHERWISE , ARISING
FROM , OUT OF OR IN CONNECTION WITH THE SOFTWARE OR THE USE OR OTHER
DEALINGS IN THE SOFTWARE .
*/
/** @file
* @ brief Class @ ref Magnum : : SceneGraph : : BasicDualComplexTransformation , typedef @ ref Magnum : : SceneGraph : : DualComplexTransformation
*/
# include "Magnum/Math/DualComplex.h"
# include "Magnum/SceneGraph/AbstractTranslationRotation2D.h"
# include "Magnum/SceneGraph/Object.h"
namespace Magnum { namespace SceneGraph {
/**
@ brief Two - dimensional transformation implemented using dual complex numbers
This class allows only rigid transformation ( i . e . only rotation and
translation ) . Uses @ ref Math : : DualComplex as underlying transformation type .
@ see @ ref DualComplexTransformation , @ ref scenegraph ,
@ ref BasicDualQuaternionTransformation
*/
template < class T > class BasicDualComplexTransformation : public AbstractBasicTranslationRotation2D < T > {
public :
/** @brief Underlying transformation type */
typedef Math : : DualComplex < T > DataType ;
/** @brief Object transformation */
Math : : DualComplex < T > transformation ( ) const { return _transformation ; }
/**
* @ brief Set transformation
* @ return Reference to self ( for method chaining )
*
* Expects that the dual complex number is normalized .
* @ see @ ref Math : : DualComplex : : isNormalized ( )
*/
Object < BasicDualComplexTransformation < T > > & setTransformation ( const Math : : DualComplex < T > & transformation ) {
CORRADE_ASSERT ( transformation . isNormalized ( ) ,
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
" SceneGraph::DualComplexTransformation::setTransformation(): the dual complex number is not normalized " ,
static_cast < Object < BasicDualComplexTransformation < T > > & > ( * this ) ) ;
return setTransformationInternal ( transformation ) ;
}
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
/** @copydoc AbstractTranslationRotationScaling2D::resetTransformation() */
Object < BasicDualComplexTransformation < T > > & resetTransformation ( ) {
return setTransformationInternal ( { } ) ;
}
/**
* @ brief Normalize rotation part
* @ return Reference to self ( for method chaining )
*
* Normalizes the rotation part to prevent rounding errors when rotating
* the object subsequently .
* @ see @ ref Math : : DualComplex : : normalized ( )
*/
Object < BasicDualComplexTransformation < T > > & normalizeRotation ( ) {
return setTransformationInternal ( _transformation . normalized ( ) ) ;
}
/**
* @ brief Transform object
* @ return Reference to self ( for method chaining )
*
* Expects that the dual complex number is normalized .
* @ see @ ref transformLocal ( ) , @ ref Math : : DualComplex : : isNormalized ( )
*/
Object < BasicDualComplexTransformation < T > > & transform ( const Math : : DualComplex < T > & transformation ) {
CORRADE_ASSERT ( transformation . isNormalized ( ) ,
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
" SceneGraph::DualComplexTransformation::transform(): the dual complex number is not normalized " ,
static_cast < Object < BasicDualComplexTransformation < T > > & > ( * this ) ) ;
return transformInternal ( transformation ) ;
}
/**
* @ brief Transform object as a local transformation
*
* Similar to the above , except that the transformation is applied
* before all others .
*/
Object < BasicDualComplexTransformation < T > > & transformLocal ( const Math : : DualComplex < T > & transformation ) {
CORRADE_ASSERT ( transformation . isNormalized ( ) ,
" SceneGraph::DualComplexTransformation::transformLocal(): the dual complex number is not normalized " ,
static_cast < Object < BasicDualComplexTransformation < T > > & > ( * this ) ) ;
return transformLocalInternal ( transformation ) ;
}
# ifdef MAGNUM_BUILD_DEPRECATED
/**
* @ copybrief transform ( )
* @ deprecated Use @ ref Magnum : : SceneGraph : : DualComplexTransformation : : transform ( ) " transform() "
* or @ ref Magnum : : SceneGraph : : DualComplexTransformation : : transformLocal ( ) " transformLocal() "
* instead .
*/
CORRADE_DEPRECATED ( " use transform() or transformLocal() instead " ) Object < BasicDualComplexTransformation < T > > & transform ( const Math : : DualComplex < T > & transformation , TransformationType type ) {
return type = = TransformationType : : Global ? transform ( transformation ) : transformLocal ( transformation ) ;
}
# endif
/**
* @ brief Translate object
* @ return Reference to self ( for method chaining )
*
* Same as calling @ ref transform ( ) with @ ref Math : : DualComplex : : translation ( ) .
* @ see @ ref translateLocal ( ) , @ ref Math : : Vector2 : : xAxis ( ) ,
* @ ref Math : : Vector2 : : yAxis ( )
*/
Object < BasicDualComplexTransformation < T > > & translate ( const Math : : Vector2 < T > & vector ) {
return transformInternal ( Math : : DualComplex < T > : : translation ( vector ) ) ;
}
/**
* @ brief Translate object as a local transformation
*
* Similar to the above , except that the transformation is applied
* before all others . Same as calling @ ref transformLocal ( ) with
* @ ref Math : : DualComplex : : translation ( ) .
*/
Object < BasicDualComplexTransformation < T > > & translateLocal ( const Math : : Vector2 < T > & vector ) {
return transformLocalInternal ( Math : : DualComplex < T > : : translation ( vector ) ) ;
}
# ifdef MAGNUM_BUILD_DEPRECATED
/**
* @ copybrief translate ( )
* @ deprecated Use @ ref Magnum : : SceneGraph : : DualComplexTransformation : : translate ( ) " translate() "
* or @ ref Magnum : : SceneGraph : : DualComplexTransformation : : translateLocal ( ) " translateLocal() "
* instead .
*/
CORRADE_DEPRECATED ( " use translate() or translateLocal() instead " ) Object < BasicDualComplexTransformation < T > > & translate ( const Math : : Vector2 < T > & vector , TransformationType type ) {
return type = = TransformationType : : Global ? translate ( vector ) : translateLocal ( vector ) ;
}
# endif
/**
* @ brief Rotate object
* @ param angle Angle ( counterclockwise )
* @ return Reference to self ( for method chaining )
*
* Same as calling @ ref transform ( ) with @ ref Math : : DualComplex : : rotation ( ) .
* @ see @ ref rotateLocal ( ) , @ ref normalizeRotation ( )
*/
Object < BasicDualComplexTransformation < T > > & rotate ( Math : : Rad < T > angle ) {
return transformInternal ( Math : : DualComplex < T > : : rotation ( angle ) ) ;
}
/**
* @ brief Rotate object as a local transformation
*
* Similar to the above , except that the transformation is applied
* before all others .
*/
Object < BasicDualComplexTransformation < T > > & rotateLocal ( Math : : Rad < T > angle ) {
return transformLocalInternal ( Math : : DualComplex < T > : : rotation ( angle ) ) ;
}
# ifdef MAGNUM_BUILD_DEPRECATED
/**
* @ copybrief rotate ( )
* @ deprecated Use @ ref Magnum : : SceneGraph : : DualComplexTransformation : : rotate ( ) " rotate() "
* or @ ref Magnum : : SceneGraph : : DualComplexTransformation : : rotateLocal ( ) " rotateLocal() "
* instead .
*/
CORRADE_DEPRECATED ( " use rotate() or rotateLocal() instead " ) Object < BasicDualComplexTransformation < T > > & rotate ( Math : : Rad < T > angle , TransformationType type ) {
return type = = TransformationType : : Global ? rotate ( angle ) : rotateLocal ( angle ) ;
}
# endif
protected :
/* Allow construction only from Object */
explicit BasicDualComplexTransformation ( ) = default ;
private :
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 doResetTransformation ( ) override final { resetTransformation ( ) ; }
void doTranslate ( const Math : : Vector2 < T > & vector ) override final {
translate ( 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 doTranslateLocal ( const Math : : Vector2 < 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 ( Math : : Rad < T > angle ) override final { rotate ( angle ) ; }
void doRotateLocal ( Math : : Rad < T > angle ) override final { rotateLocal ( angle ) ; }
/* No assertions fired, for internal use */
Object < BasicDualComplexTransformation < T > > & setTransformationInternal ( const Math : : DualComplex < T > & transformation ) {
/* Setting transformation is forbidden for the scene */
/** @todo Assert for this? */
/** @todo Do this in some common code so we don't need to include Object? */
if ( ! static_cast < Object < BasicDualComplexTransformation < T > > * > ( this ) - > isScene ( ) ) {
_transformation = transformation ;
static_cast < Object < BasicDualComplexTransformation < T > > * > ( this ) - > setDirty ( ) ;
}
return static_cast < Object < BasicDualComplexTransformation < T > > & > ( * this ) ;
}
/* No assertions fired, for internal use */
Object < BasicDualComplexTransformation < T > > & transformInternal ( const Math : : DualComplex < T > & transformation ) {
return setTransformationInternal ( transformation * _transformation ) ;
}
Object < BasicDualComplexTransformation < T > > & transformLocalInternal ( const Math : : DualComplex < T > & transformation ) {
return setTransformationInternal ( _transformation * transformation ) ;
}
Math : : DualComplex < T > _transformation ;
} ;
/**
@ brief Two - dimensional transformation for float scenes implemented using dual complex numbers
@ see @ ref DualQuaternionTransformation
*/
typedef BasicDualComplexTransformation < Float > DualComplexTransformation ;
namespace Implementation {
template < class T > struct Transformation < BasicDualComplexTransformation < T > > {
static Math : : DualComplex < T > fromMatrix ( const Math : : Matrix3 < T > & matrix ) {
return Math : : DualComplex < T > : : fromMatrix ( matrix ) ;
}
constexpr static Math : : Matrix3 < T > toMatrix ( const Math : : DualComplex < T > & transformation ) {
return transformation . toMatrix ( ) ;
}
static Math : : DualComplex < T > compose ( const Math : : DualComplex < T > & parent , const Math : : DualComplex < T > & child ) {
return parent * child ;
}
static Math : : DualComplex < T > inverted ( const Math : : DualComplex < T > & transformation ) {
return transformation . invertedNormalized ( ) ;
}
} ;
}
# if defined(CORRADE_TARGET_WINDOWS) && !defined(__MINGW32__)
extern template class MAGNUM_SCENEGRAPH_EXPORT Object < BasicDualComplexTransformation < Float > > ;
# endif
} }
# endif
