libdune-functions-doc/doxygen/a00119_source.html

// -*- tab-width: 4; indent-tabs-mode: nil; c-basic-offset: 2 -*-

// vi: set et ts=4 sw=2 sts=2:

#ifndef DUNE_FUNCTIONS_COMMON_UTILITY_HH

#define DUNE_FUNCTIONS_COMMON_UTILITY_HH


#include <utility>

#include <type_traits>


#include <dune/common/overloadset.hh>

#include <dune/common/indices.hh>


#include <dune/functions/common/functionconcepts.hh>


namespace Dune {

namespace Functions {


template<class F, class size_type, size_type firstValue, class... Args>

auto forwardAsStaticInteger(std::integer_sequence<size_type, firstValue> values, const size_type& i, F&& f, Args&&... args)

  ->decltype(f(std::integral_constant<size_type, firstValue>(), std::forward<Args>(args)...))

{

  return f(std::integral_constant<size_type, firstValue>(), std::forward<Args>(args)...);

}


template<class F, class size_type, size_type firstValue, size_type secondValue, size_type... otherValues, class... Args>

auto forwardAsStaticInteger(std::integer_sequence<size_type, firstValue, secondValue, otherValues...> values, const size_type i, F&& f, Args&&... args)

  ->decltype(f(std::integral_constant<size_type, firstValue>(), std::forward<Args>(args)...))

{

  if (i==firstValue)

    return f(std::integral_constant<size_type, firstValue>(), std::forward<Args>(args)...);

  return forwardAsStaticInteger(std::integer_sequence<size_type, secondValue, otherValues...>(), i, std::forward<F>(f), std::forward<Args>(args)...);

}


template<std::size_t end, class F, class size_type, class... Args>

auto forwardAsStaticIndex(const size_type& i, F&& f, Args&&... args)

  ->decltype(f(Dune::Indices::_0, std::forward<Args>(args)...))

{

  return forwardAsStaticInteger(std::make_index_sequence<end>{}, i, std::forward<F>(f), std::forward<Args>(args)...);

}


namespace Imp {


  template<template<class...> class T, class List>

  struct ExpandTupleHelper

  {};


  template<template<class...> class T, template<class...> class ListType, class... Args>

  struct ExpandTupleHelper<T, ListType<Args...>>

  {

    using Type = T<Args...>;

  };


} // end namespace Imp


template<template<class...> class T, class ArgTuple>

using ExpandTuple = typename Imp::ExpandTupleHelper<T, ArgTuple>::Type;


namespace Imp {


  template<template<class...> class T, class... Tuple>

  struct TransformTupleHelper

  {};


  template<template<class...> class T, class... Args1>

  struct TransformTupleHelper<T, typename std::tuple<Args1...>>

  {

    using Type = std::tuple<T<Args1>...>;

  };


  template<template<class...> class T, class... Args1, class... Args2>

  struct TransformTupleHelper<T, typename std::tuple<Args1...>, typename std::tuple<Args2...>>

  {

    using Type = std::tuple<T<Args1, Args2>...>;

  };


} // end namespace Imp


template<template<class...> class F, class... Tuples>

using TransformTuple = typename Imp::TransformTupleHelper<F, Tuples...>::Type;


namespace Imp {


  template<class F, class... T, std::size_t... k>

  auto transformTupleHelper(F&& f, const std::tuple<T...>& tuple, std::index_sequence<k...>)

    -> decltype(std::make_tuple(f(std::get<k>(tuple))...))

  {

    return std::make_tuple(f(std::get<k>(tuple))...);

  }


  template<class F, class... T1, class...T2, std::size_t... k>

  auto transformTupleHelper(F&& f, const std::tuple<T1...>& tuple1, const std::tuple<T2...>& tuple2, std::index_sequence<k...>)

    -> decltype(std::make_tuple(f(std::get<k>(tuple1), std::get<k>(tuple2))...))

  {

    return std::make_tuple(f(std::get<k>(tuple1), std::get<k>(tuple2))...);

  }


} // end namespace Imp


template<class F, class... T>

auto transformTuple(F&& f, const std::tuple<T...>& tuple)

  -> decltype(Imp::transformTupleHelper(std::forward<F>(f), tuple, std::index_sequence_for<T...>{}))

{

  return Imp::transformTupleHelper(std::forward<F>(f), tuple, std::index_sequence_for<T...>{});

}


template<class F, class... T1, class... T2>

auto transformTuple(F&& f, const std::tuple<T1...>& tuple1, const std::tuple<T2...>& tuple2)

  -> decltype(Imp::transformTupleHelper(std::forward<F>(f), tuple1, tuple2, std::index_sequence_for<T1...>{}))

{

  return Imp::transformTupleHelper(std::forward<F>(f), tuple1, tuple2, std::index_sequence_for<T1...>{});

}


namespace Imp {


  template<class IntegerSequence>

  struct IntegerSequenceTupleHelper

  {};


  template<class I, I... k>

  struct IntegerSequenceTupleHelper<std::integer_sequence<I, k...>>

  {

    using Type = std::tuple<std::integral_constant<I, k>...>;

  };


} // end namespace Imp


template<class IntegerSequence>

using IntegerSequenceTuple= typename Imp::IntegerSequenceTupleHelper<IntegerSequence>::Type;


template<class... T>

struct LastType

{

  using type = typename std::tuple_element<sizeof...(T)-1, std::tuple<T...>>::type;

};


namespace Imp {


template<class T, class I>

struct RotateHelper;


template<class... T, std::size_t... I>

struct RotateHelper<std::tuple<T...>, std::index_sequence<I...> >

{

  using type = typename std::tuple<typename LastType<T...>::type, typename std::tuple_element<I,std::tuple<T...>>::type...>;

};


} // end namespace Imp


template<class... T>

struct RotateTuple

{

  using type = typename Imp::RotateHelper<std::tuple<T...>, std::make_index_sequence<sizeof...(T)-1>>::type;

};


template<class Expression>

auto callableCheck(Expression f)

{

  return [f](auto&&... args){

    return Functions::Concept::isCallable(f, std::forward<decltype(args)>(args)...);

  };

}


template<class Check>

auto negatePredicate(Check check)

{

  return [check](auto&&... args){

    auto negate = overload(

        [](std::true_type) { return std::false_type{};},

        [](std::false_type) { return std::true_type{};},

        [](bool v) { return not v;});

    return negate(check(std::forward<decltype(args)>(args)...));

  };

}


namespace Impl {


  // Wrapper to capture values in a lambda for perfect forwarding.

  // This captures value types by value and reference types by reference.

  template <typename T>

  struct ForwardCaptureWrapper;


  template <typename T>

  struct ForwardCaptureWrapper

  {

    template <typename TT>

    ForwardCaptureWrapper(TT&& t) : t_{std::forward<TT>(t)} {}


    auto forward() const { return std::move(t_); }


    T t_;

  };


  template <typename T>

  struct ForwardCaptureWrapper<T&>

  {

    ForwardCaptureWrapper(T& t) : t_{t} {}


    T& forward() const { return t_; };


    T& t_;

  };


  template <typename T>

  struct ForwardCaptureWrapper<const T&>

  {

    ForwardCaptureWrapper(const T& t) : t_{t} {}


    const T& forward() const { return t_; };


    const T& t_;

  };


} // end namespace Dune::Functions::Impl


template <class T>

auto forwardCapture(T&& t)

{

    return Impl::ForwardCaptureWrapper<T>(std::forward<T>(t));

}


} // namespace Dune::Functions

} // namespace Dune


#endif // DUNE_FUNCTIONS_COMMON_UTILITY_HH

functionconcepts.hh

Dune::Functions::ExpandTuple
typename Imp::ExpandTupleHelper< T, ArgTuple >::Type ExpandTuple
Expand tuple arguments as template arguments.
Definition: utility.hh:94

Dune::Functions::TransformTuple
typename Imp::TransformTupleHelper< F, Tuples... >::Type TransformTuple
Transform tuple types argument using type-functor.
Definition: utility.hh:131

Dune::Functions::Concept::isCallable
static constexpr auto isCallable()
Check if f is callable with given argument list.
Definition: functionconcepts.hh:47

Dune::Functions::transformTuple
auto transformTuple(F &&f, const std::tuple< T... > &tuple) -> decltype(Imp::transformTupleHelper(std::forward< F >(f), tuple, std::index_sequence_for< T... >{}))
Transform tuple value using a functor.
Definition: utility.hh:165

Dune::Functions::callableCheck
auto callableCheck(Expression f)
Create a predicate for checking validity of expressions.
Definition: utility.hh:279

Dune::Functions::forwardAsStaticIndex
auto forwardAsStaticIndex(const size_type &i, F &&f, Args &&... args) -> decltype(f(Dune::Indices::_0, std::forward< Args >(args)...))
Transform dynamic index to static index_constant.
Definition: utility.hh:60

Dune::Functions::negatePredicate
auto negatePredicate(Check check)
Negate given predicate.
Definition: utility.hh:304

Dune
Definition: polynomial.hh:10

Dune::Functions::forwardCapture
auto forwardCapture(T &&t)
Create a capture object for perfect forwarding.
Definition: utility.hh:372

Dune::Functions::forwardAsStaticInteger
auto forwardAsStaticInteger(std::integer_sequence< size_type, firstValue > values, const size_type &i, F &&f, Args &&... args) -> decltype(f(std::integral_constant< size_type, firstValue >(), std::forward< Args >(args)...))
Definition: utility.hh:21

Dune::Functions::IntegerSequenceTuple
typename Imp::IntegerSequenceTupleHelper< IntegerSequence >::Type IntegerSequenceTuple
Transform integer_sequence<I,k...> to tuple<integral_constant<I,k>...>
Definition: utility.hh:211

Dune::Functions::LastType
Get last entry of type list.
Definition: utility.hh:222

Dune::Functions::LastType::type
typename std::tuple_element< sizeof...(T) -1, std::tuple< T... > >::type type
Definition: utility.hh:223

Dune::Functions::RotateTuple
Rotate type list by one, such that last entry is moved to first position.
Definition: utility.hh:251

Dune::Functions::RotateTuple::type
typename Imp::RotateHelper< std::tuple< T... >, std::make_index_sequence< sizeof...(T) -1 > >::type type
Definition: utility.hh:252