/usr/include/vtk-7.1/vtkDoubleDispatcher.h is in libvtk7-dev 7.1.1+dfsg1-2.
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Program: Visualization Toolkit
Module: vtkDoubleDispatcher.h
Copyright (c) Ken Martin, Will Schroeder, Bill Lorensen
All rights reserved.
See Copyright.txt or http://www.kitware.com/Copyright.htm for details.
This software is distributed WITHOUT ANY WARRANTY; without even
the implied warranty of MERCHANTABILITY or FITNESS FOR A PARTICULAR
PURPOSE. See the above copyright notice for more information.
=========================================================================*/
////////////////////////////////////////////////////////////////////////////////
// The Loki Library
// Copyright (c) 2001 by Andrei Alexandrescu
// This code accompanies the book:
// Alexandrescu, Andrei. "Modern C++ Design: Generic Programming and Design
// Patterns Applied". Copyright (c) 2001. Addison-Wesley.
// Permission to use, copy, modify, distribute and sell this software for any
// purpose is hereby granted without fee, provided that the above copyright
// notice appear in all copies and that both that copyright notice and this
// permission notice appear in supporting documentation.
// The author or Addison-Wesley Longman make no representations about the
// suitability of this software for any purpose. It is provided "as is"
// without express or implied warranty.
////////////////////////////////////////////////////////////////////////////////
/**
* @class vtkDoubleDispatcher
* @brief Dispatch to functor based on two pointer types.
*
* vtkDoubleDispatcher is a class that allows calling a functor based
* on the derived types of two pointers. This form of dynamic dispatching
* allows the conversion of runtime polymorphism to a compile time polymorphism.
* For example it can be used as a replacement for the vtkTemplateMacro when
* you want to know multiple parameter types, or need to call a specialized implementation
* for a subset
*
* Note: By default the return type is void.
*
* The functors that are passed around can contain state, and are allowed
* to be const or non const. If you are using a functor that does have state,
* make sure your copy constructor is correct.
*
* \code
* struct functor{
* template<typename T,typename U>
* void operator()(T& t,U& u) const
* {
*
* }
* };
*
* Here is an example of using the double dispatcher.
* \code
* vtkDoubleDispatcher<vtkObject,vtkObject,vtkPoints*> dispatcher;
* dispatcher.Add<vtkPoints,vtkDoubleArray>(makePointsWrapperFunctor());
* dispatcher.Add<vtkPoints,vtkPoints>(straightCopyFunctor());
* dispatcher.Go(ptr1,ptr2); //this will return a vtkPoints pointer
* \endcode
*
*
* @sa
* vtkDispatcher
*/
#ifndef vtkDoubleDispatcher_h
#define vtkDoubleDispatcher_h
#include "vtkDispatcher_Private.h" //needed for Functor,CastingPolicy,TypeInfo
#include <map> //Required for the storage of template params to runtime params
template
<
class BaseLhs,
class BaseRhs = BaseLhs,
typename ReturnType = void,
template <class, class> class CastingPolicy = vtkDispatcherCommon::vtkCaster
>
class vtkDoubleDispatcher
{
public:
/**
* Add in a functor that is mapped to the combination of the
* two template parameters passed in. When instances of the two parameters
* are passed in on the Go method we will call the functor and pass along
* the given parameters.
* Note: This copies the functor so pass stateful functors by pointer.
* \code
* vtkDoubleDispatcher<vtkDataModel,vtkCell> dispatcher;
* dispatcher.Add<vtkImageData,vtkVoxel>(exampleFunctor());
* dispatcher.Add<vtkImageData,vtkVoxel>(&exampleFunctorWithState);
* \endcode
*/
template <class SomeLhs, class SomeRhs, class Functor>
void Add(Functor fun) { this->AddInternal<SomeLhs,SomeRhs>(fun, 1); }
/**
* Remove a functor that is bound to the given parameter types. Will
* return true if we did remove a functor.
*/
template <class SomeLhs, class SomeRhs>
bool Remove() { return DoRemove(typeid(SomeLhs), typeid(SomeRhs)); }
/**
* Given two pointers of objects that derive from the BaseLhs and BaseRhs
* we find the matching functor that was added, and call it passing along
* the given parameters. It should be noted that the functor will be called
* with the parameters being the derived type that Functor was registered with.
* Note: This will only find exact matches. So if you add functor to find
* vtkDataArray,vtkDataArray, it will not be called if passed with
* vtkDoubleArray,vtkDoubleArray.
* \code
* vtkDoubleDispatcher<vtkDataArray,vtkDataArray> dispatcher;
* dispatcher.Add(vtkFloatArray,vtkFloatArray>(floatFunctor())
* dispatcher.Add(vtkFloatArray,vtkDoubleArray>(mixedTypeFunctor())
* dispatcher.Go( dataArray1, dataArray2);
* \endcode
*/
ReturnType Go(BaseLhs* lhs, BaseRhs* rhs);
protected:
typedef vtkDispatcherCommon::TypeInfo TypeInfo;
typedef vtkDoubleDispatcherPrivate::Functor<ReturnType,BaseLhs,BaseRhs>
MappedType;
void DoAddFunctor(TypeInfo lhs,TypeInfo rhs, MappedType fun);
bool DoRemove(TypeInfo lhs, TypeInfo rhs);
typedef std::pair<TypeInfo,TypeInfo> KeyType;
typedef std::map<KeyType, MappedType > MapType;
MapType FunctorMap;
private:
template <class SomeLhs, class SomeRhs, class Functor>
void AddInternal(const Functor& fun, long);
template <class SomeLhs, class SomeRhs, class Functor>
void AddInternal(Functor* fun, int);
};
//We are making all these method non-inline to reduce compile time overhead
//----------------------------------------------------------------------------
template<class BaseLhs, class BaseRhs, typename ReturnType,
template <class, class> class CastingPolicy>
template <class SomeLhs, class SomeRhs, class Functor>
void vtkDoubleDispatcher<BaseLhs,BaseRhs,ReturnType,CastingPolicy>
::AddInternal(const Functor& fun, long)
{
typedef vtkDoubleDispatcherPrivate::FunctorDoubleDispatcherHelper<
BaseLhs, BaseRhs,
SomeLhs, SomeRhs,
ReturnType,
CastingPolicy<SomeLhs, BaseLhs>,
CastingPolicy<SomeRhs, BaseRhs>,
Functor> Adapter;
Adapter ada(fun);
MappedType mt(ada);
DoAddFunctor(typeid(SomeLhs), typeid(SomeRhs),mt);
}
//----------------------------------------------------------------------------
template<class BaseLhs, class BaseRhs, typename ReturnType,
template <class, class> class CastingPolicy>
template <class SomeLhs, class SomeRhs, class Functor>
void vtkDoubleDispatcher<BaseLhs,BaseRhs,ReturnType,CastingPolicy>
::AddInternal(Functor* fun, int)
{
typedef vtkDoubleDispatcherPrivate::FunctorRefDispatcherHelper<
BaseLhs, BaseRhs,
SomeLhs, SomeRhs,
ReturnType,
CastingPolicy<SomeLhs, BaseLhs>,
CastingPolicy<SomeRhs, BaseRhs>,
Functor> Adapter;
Adapter ada(*fun);
MappedType mt(ada);
DoAddFunctor(typeid(SomeLhs), typeid(SomeRhs),mt);
}
//----------------------------------------------------------------------------
template<class BaseLhs, class BaseRhs, typename ReturnType,
template <class, class> class CastingPolicy>
void vtkDoubleDispatcher<BaseLhs,BaseRhs,ReturnType,CastingPolicy>
::DoAddFunctor(TypeInfo lhs, TypeInfo rhs, MappedType fun)
{
FunctorMap[KeyType(lhs, rhs)] = fun;
}
//----------------------------------------------------------------------------
template <class BaseLhs, class BaseRhs, typename ReturnType,
template <class, class> class CastingPolicy>
bool vtkDoubleDispatcher<BaseLhs,BaseRhs,ReturnType,CastingPolicy>
::DoRemove(TypeInfo lhs, TypeInfo rhs)
{
return FunctorMap.erase(KeyType(lhs, rhs)) == 1;
}
//----------------------------------------------------------------------------
template <class BaseLhs, class BaseRhs, typename ReturnType,
template <class, class> class CastingPolicy>
ReturnType vtkDoubleDispatcher<BaseLhs,BaseRhs,ReturnType,CastingPolicy>
::Go(BaseLhs* lhs, BaseRhs* rhs)
{
typename MapType::key_type k(typeid(*lhs),typeid(*rhs));
typename MapType::iterator i = FunctorMap.find(k);
if (i == FunctorMap.end())
{
//we don't want to throw exceptions so we have two options.
//we can return the default, or make a lightweight struct for return value
return ReturnType();
}
return (i->second)(*lhs,*rhs);
}
#endif // vtkDoubleDispatcher_h
// VTK-HeaderTest-Exclude: vtkDoubleDispatcher.h
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