unsupported/Eigen/CXX11/src/TensorSymmetry/StaticSymmetry.h - eigen/fuchsia - Git at Google

 // This file is part of Eigen, a lightweight C++ template library
 // for linear algebra.
 //
 // Copyright (C) 2013 Christian Seiler <christian@iwakd.de>
 //
 // This Source Code Form is subject to the terms of the Mozilla
 // Public License v. 2.0. If a copy of the MPL was not distributed
 // with this file, You can obtain one at http://mozilla.org/MPL/2.0/.

 #ifndef EIGEN_CXX11_TENSORSYMMETRY_STATICSYMMETRY_H
 #define EIGEN_CXX11_TENSORSYMMETRY_STATICSYMMETRY_H

 namespace Eigen {

 namespace internal {

 template<typename list> struct tensor_static_symgroup_permutate;

 template<int... nn>
 struct tensor_static_symgroup_permutate<numeric_list<int, nn...>>
 {
   constexpr static std::size_t N = sizeof...(nn);

   template<typename T>
   constexpr static inline std::array<T, N> run(const std::array<T, N>& indices)
   {
     return {{indices[nn]...}};
   }
 };

 template<typename indices_, int flags_>
 struct tensor_static_symgroup_element
 {
   typedef indices_ indices;
   constexpr static int flags = flags_;
 };

 template<typename Gen, int N>
 struct tensor_static_symgroup_element_ctor
 {
   typedef tensor_static_symgroup_element<
     typename gen_numeric_list_swapped_pair<int, N, Gen::One, Gen::Two>::type,
     Gen::Flags
   > type;
 };

 template<int N>
 struct tensor_static_symgroup_identity_ctor
 {
   typedef tensor_static_symgroup_element<
     typename gen_numeric_list<int, N>::type,
     0
   > type;
 };

 template<typename iib>
 struct tensor_static_symgroup_multiply_helper
 {
   template<int... iia>
   constexpr static inline numeric_list<int, get<iia, iib>::value...> helper(numeric_list<int, iia...>) {
     return numeric_list<int, get<iia, iib>::value...>();
   }
 };

 template<typename A, typename B>
 struct tensor_static_symgroup_multiply
 {
   private:
     typedef typename A::indices iia;
     typedef typename B::indices iib;
     constexpr static int ffa = A::flags;
     constexpr static int ffb = B::flags;

   public:
     static_assert(iia::count == iib::count, "Cannot multiply symmetry elements with different number of indices.");

     typedef tensor_static_symgroup_element<
       decltype(tensor_static_symgroup_multiply_helper<iib>::helper(iia())),
       ffa ^ ffb
     > type;
 };

 template<typename A, typename B>
 struct tensor_static_symgroup_equality
 {
     typedef typename A::indices iia;
     typedef typename B::indices iib;
     constexpr static int ffa = A::flags;
     constexpr static int ffb = B::flags;
     static_assert(iia::count == iib::count, "Cannot compare symmetry elements with different number of indices.");

     constexpr static bool value = is_same<iia, iib>::value;

   private:
     /* this should be zero if they are identical, or else the tensor
      * will be forced to be pure real, pure imaginary or even pure zero
      */
     constexpr static int flags_cmp_ = ffa ^ ffb;

     /* either they are not equal, then we don't care whether the flags
      * match, or they are equal, and then we have to check
      */
     constexpr static bool is_zero      = value && flags_cmp_ == NegationFlag;
     constexpr static bool is_real      = value && flags_cmp_ == ConjugationFlag;
     constexpr static bool is_imag      = value && flags_cmp_ == (NegationFlag | ConjugationFlag);

   public:
     constexpr static int global_flags =
       (is_real ? GlobalRealFlag : 0) |
       (is_imag ? GlobalImagFlag : 0) |
       (is_zero ? GlobalZeroFlag : 0);
 };

 template<std::size_t NumIndices, typename... Gen>
 struct tensor_static_symgroup
 {
   typedef StaticSGroup<Gen...> type;
   constexpr static std::size_t size = type::static_size;
 };

 template<typename Index, std::size_t N, int... ii, int... jj>
 constexpr static inline std::array<Index, N> tensor_static_symgroup_index_permute(std::array<Index, N> idx, internal::numeric_list<int, ii...>, internal::numeric_list<int, jj...>)
 {
   return {{ idx[ii]..., idx[jj]... }};
 }

 template<typename Index, int... ii>
 static inline std::vector<Index> tensor_static_symgroup_index_permute(std::vector<Index> idx, internal::numeric_list<int, ii...>)
 {
   std::vector<Index> result{{ idx[ii]... }};
   std::size_t target_size = idx.size();
   for (std::size_t i = result.size(); i < target_size; i++)
     result.push_back(idx[i]);
   return result;
 }

 template<typename T> struct tensor_static_symgroup_do_apply;

 template<typename first, typename... next>
 struct tensor_static_symgroup_do_apply<internal::type_list<first, next...>>
 {
   template<typename Op, typename RV, std::size_t SGNumIndices, typename Index, std::size_t NumIndices, typename... Args>
   static inline RV run(const std::array<Index, NumIndices>& idx, RV initial, Args&&... args)
   {
     static_assert(NumIndices >= SGNumIndices, "Can only apply symmetry group to objects that have at least the required amount of indices.");
     typedef typename internal::gen_numeric_list<int, NumIndices - SGNumIndices, SGNumIndices>::type remaining_indices;
     initial = Op::run(tensor_static_symgroup_index_permute(idx, typename first::indices(), remaining_indices()), first::flags, initial, std::forward<Args>(args)...);
     return tensor_static_symgroup_do_apply<internal::type_list<next...>>::template run<Op, RV, SGNumIndices>(idx, initial, args...);
   }

   template<typename Op, typename RV, std::size_t SGNumIndices, typename Index, typename... Args>
   static inline RV run(const std::vector<Index>& idx, RV initial, Args&&... args)
   {
     eigen_assert(idx.size() >= SGNumIndices && "Can only apply symmetry group to objects that have at least the required amount of indices.");
     initial = Op::run(tensor_static_symgroup_index_permute(idx, typename first::indices()), first::flags, initial, std::forward<Args>(args)...);
     return tensor_static_symgroup_do_apply<internal::type_list<next...>>::template run<Op, RV, SGNumIndices>(idx, initial, args...);
   }
 };

 template<EIGEN_TPL_PP_SPEC_HACK_DEF(typename, empty)>
 struct tensor_static_symgroup_do_apply<internal::type_list<EIGEN_TPL_PP_SPEC_HACK_USE(empty)>>
 {
   template<typename Op, typename RV, std::size_t SGNumIndices, typename Index, std::size_t NumIndices, typename... Args>
   static inline RV run(const std::array<Index, NumIndices>&, RV initial, Args&&...)
   {
     // do nothing
     return initial;
   }

   template<typename Op, typename RV, std::size_t SGNumIndices, typename Index, typename... Args>
   static inline RV run(const std::vector<Index>&, RV initial, Args&&...)
   {
     // do nothing
     return initial;
   }
 };

 } // end namespace internal

 template<typename... Gen>
 class StaticSGroup
 {
     constexpr static std::size_t NumIndices = internal::tensor_symmetry_num_indices<Gen...>::value;
     typedef internal::group_theory::enumerate_group_elements<
       internal::tensor_static_symgroup_multiply,
       internal::tensor_static_symgroup_equality,
       typename internal::tensor_static_symgroup_identity_ctor<NumIndices>::type,
       internal::type_list<typename internal::tensor_static_symgroup_element_ctor<Gen, NumIndices>::type...>
     > group_elements;
     typedef typename group_elements::type ge;
   public:
     constexpr inline StaticSGroup() {}
     constexpr inline StaticSGroup(const StaticSGroup<Gen...>&) {}
     constexpr inline StaticSGroup(StaticSGroup<Gen...>&&) {}

     template<typename Op, typename RV, typename Index, std::size_t N, typename... Args>
     static inline RV apply(const std::array<Index, N>& idx, RV initial, Args&&... args)
     {
       return internal::tensor_static_symgroup_do_apply<ge>::template run<Op, RV, NumIndices>(idx, initial, args...);
     }

     template<typename Op, typename RV, typename Index, typename... Args>
     static inline RV apply(const std::vector<Index>& idx, RV initial, Args&&... args)
     {
       eigen_assert(idx.size() == NumIndices);
       return internal::tensor_static_symgroup_do_apply<ge>::template run<Op, RV, NumIndices>(idx, initial, args...);
     }

     constexpr static std::size_t static_size = ge::count;

     constexpr static inline std::size_t size() {
       return ge::count;
     }
     constexpr static inline int globalFlags() { return group_elements::global_flags; }

     template<typename Tensor_, typename... IndexTypes>
     inline internal::tensor_symmetry_value_setter<Tensor_, StaticSGroup<Gen...>> operator()(Tensor_& tensor, typename Tensor_::Index firstIndex, IndexTypes... otherIndices) const
     {
       static_assert(sizeof...(otherIndices) + 1 == Tensor_::NumIndices, "Number of indices used to access a tensor coefficient must be equal to the rank of the tensor.");
       return operator()(tensor, std::array<typename Tensor_::Index, Tensor_::NumIndices>{{firstIndex, otherIndices...}});
     }

     template<typename Tensor_>
     inline internal::tensor_symmetry_value_setter<Tensor_, StaticSGroup<Gen...>> operator()(Tensor_& tensor, std::array<typename Tensor_::Index, Tensor_::NumIndices> const& indices) const
     {
       return internal::tensor_symmetry_value_setter<Tensor_, StaticSGroup<Gen...>>(tensor, *this, indices);
     }
 };

 } // end namespace Eigen

 #endif // EIGEN_CXX11_TENSORSYMMETRY_STATICSYMMETRY_H

 /*
  * kate: space-indent on; indent-width 2; mixedindent off; indent-mode cstyle;
  */
	// This file is part of Eigen, a lightweight C++ template library
	// for linear algebra.
	//
	// Copyright (C) 2013 Christian Seiler <christian@iwakd.de>
	//
	// This Source Code Form is subject to the terms of the Mozilla
	// Public License v. 2.0. If a copy of the MPL was not distributed
	// with this file, You can obtain one at http://mozilla.org/MPL/2.0/.

	#ifndef EIGEN_CXX11_TENSORSYMMETRY_STATICSYMMETRY_H
	#define EIGEN_CXX11_TENSORSYMMETRY_STATICSYMMETRY_H

	namespace Eigen {

	namespace internal {

	template<typename list> struct tensor_static_symgroup_permutate;

	template<int... nn>
	struct tensor_static_symgroup_permutate<numeric_list<int, nn...>>
	{
	constexpr static std::size_t N = sizeof...(nn);

	template<typename T>
	constexpr static inline std::array<T, N> run(const std::array<T, N>& indices)
	{
	return {{indices[nn]...}};
	}
	};

	template<typename indices_, int flags_>
	struct tensor_static_symgroup_element
	{
	typedef indices_ indices;
	constexpr static int flags = flags_;
	};

	template<typename Gen, int N>
	struct tensor_static_symgroup_element_ctor
	{
	typedef tensor_static_symgroup_element<
	typename gen_numeric_list_swapped_pair<int, N, Gen::One, Gen::Two>::type,
	Gen::Flags
	> type;
	};

	template<int N>
	struct tensor_static_symgroup_identity_ctor
	{
	typedef tensor_static_symgroup_element<
	typename gen_numeric_list<int, N>::type,
	0
	> type;
	};

	template<typename iib>
	struct tensor_static_symgroup_multiply_helper
	{
	template<int... iia>
	constexpr static inline numeric_list<int, get<iia, iib>::value...> helper(numeric_list<int, iia...>) {
	return numeric_list<int, get<iia, iib>::value...>();
	}
	};

	template<typename A, typename B>
	struct tensor_static_symgroup_multiply
	{
	private:
	typedef typename A::indices iia;
	typedef typename B::indices iib;
	constexpr static int ffa = A::flags;
	constexpr static int ffb = B::flags;

	public:
	static_assert(iia::count == iib::count, "Cannot multiply symmetry elements with different number of indices.");

	typedef tensor_static_symgroup_element<
	decltype(tensor_static_symgroup_multiply_helper<iib>::helper(iia())),
	ffa ^ ffb
	> type;
	};

	template<typename A, typename B>
	struct tensor_static_symgroup_equality
	{
	typedef typename A::indices iia;
	typedef typename B::indices iib;
	constexpr static int ffa = A::flags;
	constexpr static int ffb = B::flags;
	static_assert(iia::count == iib::count, "Cannot compare symmetry elements with different number of indices.");

	constexpr static bool value = is_same<iia, iib>::value;

	private:
	/* this should be zero if they are identical, or else the tensor
	* will be forced to be pure real, pure imaginary or even pure zero
	*/
	constexpr static int flags_cmp_ = ffa ^ ffb;

	/* either they are not equal, then we don't care whether the flags
	* match, or they are equal, and then we have to check
	*/
	constexpr static bool is_zero = value && flags_cmp_ == NegationFlag;
	constexpr static bool is_real = value && flags_cmp_ == ConjugationFlag;
	constexpr static bool is_imag = value && flags_cmp_ == (NegationFlag \| ConjugationFlag);

	public:
	constexpr static int global_flags =
	(is_real ? GlobalRealFlag : 0) \|
	(is_imag ? GlobalImagFlag : 0) \|
	(is_zero ? GlobalZeroFlag : 0);
	};

	template<std::size_t NumIndices, typename... Gen>
	struct tensor_static_symgroup
	{
	typedef StaticSGroup<Gen...> type;
	constexpr static std::size_t size = type::static_size;
	};

	template<typename Index, std::size_t N, int... ii, int... jj>
	constexpr static inline std::array<Index, N> tensor_static_symgroup_index_permute(std::array<Index, N> idx, internal::numeric_list<int, ii...>, internal::numeric_list<int, jj...>)
	{
	return {{ idx[ii]..., idx[jj]... }};
	}

	template<typename Index, int... ii>
	static inline std::vector<Index> tensor_static_symgroup_index_permute(std::vector<Index> idx, internal::numeric_list<int, ii...>)
	{
	std::vector<Index> result{{ idx[ii]... }};
	std::size_t target_size = idx.size();
	for (std::size_t i = result.size(); i < target_size; i++)
	result.push_back(idx[i]);
	return result;
	}

	template<typename T> struct tensor_static_symgroup_do_apply;

	template<typename first, typename... next>
	struct tensor_static_symgroup_do_apply<internal::type_list<first, next...>>
	{
	template<typename Op, typename RV, std::size_t SGNumIndices, typename Index, std::size_t NumIndices, typename... Args>
	static inline RV run(const std::array<Index, NumIndices>& idx, RV initial, Args&&... args)
	{
	static_assert(NumIndices >= SGNumIndices, "Can only apply symmetry group to objects that have at least the required amount of indices.");
	typedef typename internal::gen_numeric_list<int, NumIndices - SGNumIndices, SGNumIndices>::type remaining_indices;
	initial = Op::run(tensor_static_symgroup_index_permute(idx, typename first::indices(), remaining_indices()), first::flags, initial, std::forward<Args>(args)...);
	return tensor_static_symgroup_do_apply<internal::type_list<next...>>::template run<Op, RV, SGNumIndices>(idx, initial, args...);
	}

	template<typename Op, typename RV, std::size_t SGNumIndices, typename Index, typename... Args>
	static inline RV run(const std::vector<Index>& idx, RV initial, Args&&... args)
	{
	eigen_assert(idx.size() >= SGNumIndices && "Can only apply symmetry group to objects that have at least the required amount of indices.");
	initial = Op::run(tensor_static_symgroup_index_permute(idx, typename first::indices()), first::flags, initial, std::forward<Args>(args)...);
	return tensor_static_symgroup_do_apply<internal::type_list<next...>>::template run<Op, RV, SGNumIndices>(idx, initial, args...);
	}
	};

	template<EIGEN_TPL_PP_SPEC_HACK_DEF(typename, empty)>
	struct tensor_static_symgroup_do_apply<internal::type_list<EIGEN_TPL_PP_SPEC_HACK_USE(empty)>>
	{
	template<typename Op, typename RV, std::size_t SGNumIndices, typename Index, std::size_t NumIndices, typename... Args>
	static inline RV run(const std::array<Index, NumIndices>&, RV initial, Args&&...)
	{
	// do nothing
	return initial;
	}

	template<typename Op, typename RV, std::size_t SGNumIndices, typename Index, typename... Args>
	static inline RV run(const std::vector<Index>&, RV initial, Args&&...)
	{
	// do nothing
	return initial;
	}
	};

	} // end namespace internal

	template<typename... Gen>
	class StaticSGroup
	{
	constexpr static std::size_t NumIndices = internal::tensor_symmetry_num_indices<Gen...>::value;
	typedef internal::group_theory::enumerate_group_elements<
	internal::tensor_static_symgroup_multiply,
	internal::tensor_static_symgroup_equality,
	typename internal::tensor_static_symgroup_identity_ctor<NumIndices>::type,
	internal::type_list<typename internal::tensor_static_symgroup_element_ctor<Gen, NumIndices>::type...>
	> group_elements;
	typedef typename group_elements::type ge;
	public:
	constexpr inline StaticSGroup() {}
	constexpr inline StaticSGroup(const StaticSGroup<Gen...>&) {}
	constexpr inline StaticSGroup(StaticSGroup<Gen...>&&) {}

	template<typename Op, typename RV, typename Index, std::size_t N, typename... Args>
	static inline RV apply(const std::array<Index, N>& idx, RV initial, Args&&... args)
	{
	return internal::tensor_static_symgroup_do_apply<ge>::template run<Op, RV, NumIndices>(idx, initial, args...);
	}

	template<typename Op, typename RV, typename Index, typename... Args>
	static inline RV apply(const std::vector<Index>& idx, RV initial, Args&&... args)
	{
	eigen_assert(idx.size() == NumIndices);
	return internal::tensor_static_symgroup_do_apply<ge>::template run<Op, RV, NumIndices>(idx, initial, args...);
	}

	constexpr static std::size_t static_size = ge::count;

	constexpr static inline std::size_t size() {
	return ge::count;
	}
	constexpr static inline int globalFlags() { return group_elements::global_flags; }

	template<typename Tensor_, typename... IndexTypes>
	inline internal::tensor_symmetry_value_setter<Tensor_, StaticSGroup<Gen...>> operator()(Tensor_& tensor, typename Tensor_::Index firstIndex, IndexTypes... otherIndices) const
	{
	static_assert(sizeof...(otherIndices) + 1 == Tensor_::NumIndices, "Number of indices used to access a tensor coefficient must be equal to the rank of the tensor.");
	return operator()(tensor, std::array<typename Tensor_::Index, Tensor_::NumIndices>{{firstIndex, otherIndices...}});
	}

	template<typename Tensor_>
	inline internal::tensor_symmetry_value_setter<Tensor_, StaticSGroup<Gen...>> operator()(Tensor_& tensor, std::array<typename Tensor_::Index, Tensor_::NumIndices> const& indices) const
	{
	return internal::tensor_symmetry_value_setter<Tensor_, StaticSGroup<Gen...>>(tensor, *this, indices);
	}
	};

	} // end namespace Eigen

	#endif // EIGEN_CXX11_TENSORSYMMETRY_STATICSYMMETRY_H

	/*
	* kate: space-indent on; indent-width 2; mixedindent off; indent-mode cstyle;
	*/