unsupported/Eigen/CXX11/src/TensorSymmetry/DynamicSymmetry.h - eigen - 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_DYNAMICSYMMETRY_H
 #define EIGEN_CXX11_TENSORSYMMETRY_DYNAMICSYMMETRY_H

 namespace Eigen {

 class DynamicSGroup
 {
   public:
     inline explicit DynamicSGroup() : m_numIndices(1), m_elements(), m_generators(), m_globalFlags(0) { m_elements.push_back(ge(Generator(0, 0, 0))); }
     inline DynamicSGroup(const DynamicSGroup& o) : m_numIndices(o.m_numIndices), m_elements(o.m_elements), m_generators(o.m_generators), m_globalFlags(o.m_globalFlags) { }
     inline DynamicSGroup(DynamicSGroup&& o) : m_numIndices(o.m_numIndices), m_elements(), m_generators(o.m_generators), m_globalFlags(o.m_globalFlags) { std::swap(m_elements, o.m_elements); }
     inline DynamicSGroup& operator=(const DynamicSGroup& o) { m_numIndices = o.m_numIndices; m_elements = o.m_elements; m_generators = o.m_generators; m_globalFlags = o.m_globalFlags; return *this; }
     inline DynamicSGroup& operator=(DynamicSGroup&& o) { m_numIndices = o.m_numIndices; std::swap(m_elements, o.m_elements); m_generators = o.m_generators; m_globalFlags = o.m_globalFlags; return *this; }

     void add(int one, int two, int flags = 0);

     template<typename Gen_>
     inline void add(Gen_) { add(Gen_::One, Gen_::Two, Gen_::Flags); }
     inline void addSymmetry(int one, int two) { add(one, two, 0); }
     inline void addAntiSymmetry(int one, int two) { add(one, two, NegationFlag); }
     inline void addHermiticity(int one, int two) { add(one, two, ConjugationFlag); }
     inline void addAntiHermiticity(int one, int two) { add(one, two, NegationFlag | ConjugationFlag); }

     template<typename Op, typename RV, typename Index, std::size_t N, typename... Args>
     inline RV apply(const std::array<Index, N>& idx, RV initial, Args&&... args) const
     {
       eigen_assert(N >= m_numIndices && "Can only apply symmetry group to objects that have at least the required amount of indices.");
       for (std::size_t i = 0; i < size(); i++)
         initial = Op::run(h_permute(i, idx, typename internal::gen_numeric_list<int, N>::type()), m_elements[i].flags, initial, std::forward<Args>(args)...);
       return initial;
     }

     template<typename Op, typename RV, typename Index, typename... Args>
     inline RV apply(const std::vector<Index>& idx, RV initial, Args&&... args) const
     {
       eigen_assert(idx.size() >= m_numIndices && "Can only apply symmetry group to objects that have at least the required amount of indices.");
       for (std::size_t i = 0; i < size(); i++)
         initial = Op::run(h_permute(i, idx), m_elements[i].flags, initial, std::forward<Args>(args)...);
       return initial;
     }

     inline int globalFlags() const { return m_globalFlags; }
     inline std::size_t size() const { return m_elements.size(); }

     template<typename Tensor_, typename... IndexTypes>
     inline internal::tensor_symmetry_value_setter<Tensor_, DynamicSGroup> 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_, DynamicSGroup> operator()(Tensor_& tensor, std::array<typename Tensor_::Index, Tensor_::NumIndices> const& indices) const
     {
       return internal::tensor_symmetry_value_setter<Tensor_, DynamicSGroup>(tensor, *this, indices);
     }
   private:
     struct GroupElement {
       std::vector<int> representation;
       int flags;
       bool isId() const
       {
         for (std::size_t i = 0; i < representation.size(); i++)
           if (i != (size_t)representation[i])
             return false;
         return true;
       }
     };
     struct Generator {
       int one;
       int two;
       int flags;
       constexpr inline Generator(int one_, int two_, int flags_) : one(one_), two(two_), flags(flags_) {}
     };

     std::size_t m_numIndices;
     std::vector<GroupElement> m_elements;
     std::vector<Generator> m_generators;
     int m_globalFlags;

     template<typename Index, std::size_t N, int... n>
     inline std::array<Index, N> h_permute(std::size_t which, const std::array<Index, N>& idx, internal::numeric_list<int, n...>) const
     {
       return std::array<Index, N>{{ idx[n >= m_numIndices ? n : m_elements[which].representation[n]]... }};
     }

     template<typename Index>
     inline std::vector<Index> h_permute(std::size_t which, std::vector<Index> idx) const
     {
       std::vector<Index> result;
       result.reserve(idx.size());
       for (auto k : m_elements[which].representation)
         result.push_back(idx[k]);
       for (std::size_t i = m_numIndices; i < idx.size(); i++)
         result.push_back(idx[i]);
       return result;
     }

     inline GroupElement ge(Generator const& g) const
     {
       GroupElement result;
       result.representation.reserve(m_numIndices);
       result.flags = g.flags;
       for (std::size_t k = 0; k < m_numIndices; k++) {
         if (k == (std::size_t)g.one)
           result.representation.push_back(g.two);
         else if (k == (std::size_t)g.two)
           result.representation.push_back(g.one);
         else
           result.representation.push_back(int(k));
       }
       return result;
     }

     GroupElement mul(GroupElement, GroupElement) const;
     inline GroupElement mul(Generator g1, GroupElement g2) const
     {
       return mul(ge(g1), g2);
     }

     inline GroupElement mul(GroupElement g1, Generator g2) const
     {
       return mul(g1, ge(g2));
     }

     inline GroupElement mul(Generator g1, Generator g2) const
     {
       return mul(ge(g1), ge(g2));
     }

     inline int findElement(GroupElement e) const
     {
       for (auto ee : m_elements) {
         if (ee.representation == e.representation)
           return ee.flags ^ e.flags;
       }
       return -1;
     }

     void updateGlobalFlags(int flagDiffOfSameGenerator);
 };

 // dynamic symmetry group that auto-adds the template parameters in the constructor
 template<typename... Gen>
 class DynamicSGroupFromTemplateArgs : public DynamicSGroup
 {
   public:
     inline DynamicSGroupFromTemplateArgs() : DynamicSGroup()
     {
       add_all(internal::type_list<Gen...>());
     }
     inline DynamicSGroupFromTemplateArgs(DynamicSGroupFromTemplateArgs const& other) : DynamicSGroup(other) { }
     inline DynamicSGroupFromTemplateArgs(DynamicSGroupFromTemplateArgs&& other) : DynamicSGroup(other) { }
     inline DynamicSGroupFromTemplateArgs<Gen...>& operator=(const DynamicSGroupFromTemplateArgs<Gen...>& o) { DynamicSGroup::operator=(o); return *this; }
     inline DynamicSGroupFromTemplateArgs<Gen...>& operator=(DynamicSGroupFromTemplateArgs<Gen...>&& o) { DynamicSGroup::operator=(o); return *this; }

   private:
     template<typename Gen1, typename... GenNext>
     inline void add_all(internal::type_list<Gen1, GenNext...>)
     {
       add(Gen1());
       add_all(internal::type_list<GenNext...>());
     }

     inline void add_all(internal::type_list<>)
     {
     }
 };

 inline DynamicSGroup::GroupElement DynamicSGroup::mul(GroupElement g1, GroupElement g2) const
 {
   eigen_internal_assert(g1.representation.size() == m_numIndices);
   eigen_internal_assert(g2.representation.size() == m_numIndices);

   GroupElement result;
   result.representation.reserve(m_numIndices);
   for (std::size_t i = 0; i < m_numIndices; i++) {
     int v = g2.representation[g1.representation[i]];
     eigen_assert(v >= 0);
     result.representation.push_back(v);
   }
   result.flags = g1.flags ^ g2.flags;
   return result;
 }

 inline void DynamicSGroup::add(int one, int two, int flags)
 {
   eigen_assert(one >= 0);
   eigen_assert(two >= 0);
   eigen_assert(one != two);

   if ((std::size_t)one >= m_numIndices || (std::size_t)two >= m_numIndices) {
     std::size_t newNumIndices = (one > two) ? one : two + 1;
     for (auto& gelem : m_elements) {
       gelem.representation.reserve(newNumIndices);
       for (std::size_t i = m_numIndices; i < newNumIndices; i++)
         gelem.representation.push_back(i);
     }
     m_numIndices = newNumIndices;
   }

   Generator g{one, two, flags};
   GroupElement e = ge(g);

   /* special case for first generator */
   if (m_elements.size() == 1) {
     while (!e.isId()) {
       m_elements.push_back(e);
       e = mul(e, g);
     }

     if (e.flags > 0)
       updateGlobalFlags(e.flags);

     // only add in case we didn't have identity
     if (m_elements.size() > 1)
       m_generators.push_back(g);
     return;
   }

   int p = findElement(e);
   if (p >= 0) {
     updateGlobalFlags(p);
     return;
   }

   std::size_t coset_order = m_elements.size();
   m_elements.push_back(e);
   for (std::size_t i = 1; i < coset_order; i++)
     m_elements.push_back(mul(m_elements[i], e));
   m_generators.push_back(g);

   std::size_t coset_rep = coset_order;
   do {
     for (auto g : m_generators) {
       e = mul(m_elements[coset_rep], g);
       p = findElement(e);
       if (p < 0) {
         // element not yet in group
         m_elements.push_back(e);
         for (std::size_t i = 1; i < coset_order; i++)
           m_elements.push_back(mul(m_elements[i], e));
       } else if (p > 0) {
         updateGlobalFlags(p);
       }
     }
     coset_rep += coset_order;
   } while (coset_rep < m_elements.size());
 }

 inline void DynamicSGroup::updateGlobalFlags(int flagDiffOfSameGenerator)
 {
     switch (flagDiffOfSameGenerator) {
       case 0:
       default:
         // nothing happened
         break;
       case NegationFlag:
         // every element is it's own negative => whole tensor is zero
         m_globalFlags |= GlobalZeroFlag;
         break;
       case ConjugationFlag:
         // every element is it's own conjugate => whole tensor is real
         m_globalFlags |= GlobalRealFlag;
         break;
       case (NegationFlag | ConjugationFlag):
         // every element is it's own negative conjugate => whole tensor is imaginary
         m_globalFlags |= GlobalImagFlag;
         break;
       /* NOTE:
        *   since GlobalZeroFlag == GlobalRealFlag | GlobalImagFlag, if one generator
        *   causes the tensor to be real and the next one to be imaginary, this will
        *   trivially give the correct result
        */
     }
 }

 } // end namespace Eigen

 #endif // EIGEN_CXX11_TENSORSYMMETRY_DYNAMICSYMMETRY_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_DYNAMICSYMMETRY_H
	#define EIGEN_CXX11_TENSORSYMMETRY_DYNAMICSYMMETRY_H

	namespace Eigen {

	class DynamicSGroup
	{
	public:
	inline explicit DynamicSGroup() : m_numIndices(1), m_elements(), m_generators(), m_globalFlags(0) { m_elements.push_back(ge(Generator(0, 0, 0))); }
	inline DynamicSGroup(const DynamicSGroup& o) : m_numIndices(o.m_numIndices), m_elements(o.m_elements), m_generators(o.m_generators), m_globalFlags(o.m_globalFlags) { }
	inline DynamicSGroup(DynamicSGroup&& o) : m_numIndices(o.m_numIndices), m_elements(), m_generators(o.m_generators), m_globalFlags(o.m_globalFlags) { std::swap(m_elements, o.m_elements); }
	inline DynamicSGroup& operator=(const DynamicSGroup& o) { m_numIndices = o.m_numIndices; m_elements = o.m_elements; m_generators = o.m_generators; m_globalFlags = o.m_globalFlags; return *this; }
	inline DynamicSGroup& operator=(DynamicSGroup&& o) { m_numIndices = o.m_numIndices; std::swap(m_elements, o.m_elements); m_generators = o.m_generators; m_globalFlags = o.m_globalFlags; return *this; }

	void add(int one, int two, int flags = 0);

	template<typename Gen_>
	inline void add(Gen_) { add(Gen_::One, Gen_::Two, Gen_::Flags); }
	inline void addSymmetry(int one, int two) { add(one, two, 0); }
	inline void addAntiSymmetry(int one, int two) { add(one, two, NegationFlag); }
	inline void addHermiticity(int one, int two) { add(one, two, ConjugationFlag); }
	inline void addAntiHermiticity(int one, int two) { add(one, two, NegationFlag \| ConjugationFlag); }

	template<typename Op, typename RV, typename Index, std::size_t N, typename... Args>
	inline RV apply(const std::array<Index, N>& idx, RV initial, Args&&... args) const
	{
	eigen_assert(N >= m_numIndices && "Can only apply symmetry group to objects that have at least the required amount of indices.");
	for (std::size_t i = 0; i < size(); i++)
	initial = Op::run(h_permute(i, idx, typename internal::gen_numeric_list<int, N>::type()), m_elements[i].flags, initial, std::forward<Args>(args)...);
	return initial;
	}

	template<typename Op, typename RV, typename Index, typename... Args>
	inline RV apply(const std::vector<Index>& idx, RV initial, Args&&... args) const
	{
	eigen_assert(idx.size() >= m_numIndices && "Can only apply symmetry group to objects that have at least the required amount of indices.");
	for (std::size_t i = 0; i < size(); i++)
	initial = Op::run(h_permute(i, idx), m_elements[i].flags, initial, std::forward<Args>(args)...);
	return initial;
	}

	inline int globalFlags() const { return m_globalFlags; }
	inline std::size_t size() const { return m_elements.size(); }

	template<typename Tensor_, typename... IndexTypes>
	inline internal::tensor_symmetry_value_setter<Tensor_, DynamicSGroup> 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_, DynamicSGroup> operator()(Tensor_& tensor, std::array<typename Tensor_::Index, Tensor_::NumIndices> const& indices) const
	{
	return internal::tensor_symmetry_value_setter<Tensor_, DynamicSGroup>(tensor, *this, indices);
	}
	private:
	struct GroupElement {
	std::vector<int> representation;
	int flags;
	bool isId() const
	{
	for (std::size_t i = 0; i < representation.size(); i++)
	if (i != (size_t)representation[i])
	return false;
	return true;
	}
	};
	struct Generator {
	int one;
	int two;
	int flags;
	constexpr inline Generator(int one_, int two_, int flags_) : one(one_), two(two_), flags(flags_) {}
	};

	std::size_t m_numIndices;
	std::vector<GroupElement> m_elements;
	std::vector<Generator> m_generators;
	int m_globalFlags;

	template<typename Index, std::size_t N, int... n>
	inline std::array<Index, N> h_permute(std::size_t which, const std::array<Index, N>& idx, internal::numeric_list<int, n...>) const
	{
	return std::array<Index, N>{{ idx[n >= m_numIndices ? n : m_elements[which].representation[n]]... }};
	}

	template<typename Index>
	inline std::vector<Index> h_permute(std::size_t which, std::vector<Index> idx) const
	{
	std::vector<Index> result;
	result.reserve(idx.size());
	for (auto k : m_elements[which].representation)
	result.push_back(idx[k]);
	for (std::size_t i = m_numIndices; i < idx.size(); i++)
	result.push_back(idx[i]);
	return result;
	}

	inline GroupElement ge(Generator const& g) const
	{
	GroupElement result;
	result.representation.reserve(m_numIndices);
	result.flags = g.flags;
	for (std::size_t k = 0; k < m_numIndices; k++) {
	if (k == (std::size_t)g.one)
	result.representation.push_back(g.two);
	else if (k == (std::size_t)g.two)
	result.representation.push_back(g.one);
	else
	result.representation.push_back(int(k));
	}
	return result;
	}

	GroupElement mul(GroupElement, GroupElement) const;
	inline GroupElement mul(Generator g1, GroupElement g2) const
	{
	return mul(ge(g1), g2);
	}

	inline GroupElement mul(GroupElement g1, Generator g2) const
	{
	return mul(g1, ge(g2));
	}

	inline GroupElement mul(Generator g1, Generator g2) const
	{
	return mul(ge(g1), ge(g2));
	}

	inline int findElement(GroupElement e) const
	{
	for (auto ee : m_elements) {
	if (ee.representation == e.representation)
	return ee.flags ^ e.flags;
	}
	return -1;
	}

	void updateGlobalFlags(int flagDiffOfSameGenerator);
	};

	// dynamic symmetry group that auto-adds the template parameters in the constructor
	template<typename... Gen>
	class DynamicSGroupFromTemplateArgs : public DynamicSGroup
	{
	public:
	inline DynamicSGroupFromTemplateArgs() : DynamicSGroup()
	{
	add_all(internal::type_list<Gen...>());
	}
	inline DynamicSGroupFromTemplateArgs(DynamicSGroupFromTemplateArgs const& other) : DynamicSGroup(other) { }
	inline DynamicSGroupFromTemplateArgs(DynamicSGroupFromTemplateArgs&& other) : DynamicSGroup(other) { }
	inline DynamicSGroupFromTemplateArgs<Gen...>& operator=(const DynamicSGroupFromTemplateArgs<Gen...>& o) { DynamicSGroup::operator=(o); return *this; }
	inline DynamicSGroupFromTemplateArgs<Gen...>& operator=(DynamicSGroupFromTemplateArgs<Gen...>&& o) { DynamicSGroup::operator=(o); return *this; }

	private:
	template<typename Gen1, typename... GenNext>
	inline void add_all(internal::type_list<Gen1, GenNext...>)
	{
	add(Gen1());
	add_all(internal::type_list<GenNext...>());
	}

	inline void add_all(internal::type_list<>)
	{
	}
	};

	inline DynamicSGroup::GroupElement DynamicSGroup::mul(GroupElement g1, GroupElement g2) const
	{
	eigen_internal_assert(g1.representation.size() == m_numIndices);
	eigen_internal_assert(g2.representation.size() == m_numIndices);

	GroupElement result;
	result.representation.reserve(m_numIndices);
	for (std::size_t i = 0; i < m_numIndices; i++) {
	int v = g2.representation[g1.representation[i]];
	eigen_assert(v >= 0);
	result.representation.push_back(v);
	}
	result.flags = g1.flags ^ g2.flags;
	return result;
	}

	inline void DynamicSGroup::add(int one, int two, int flags)
	{
	eigen_assert(one >= 0);
	eigen_assert(two >= 0);
	eigen_assert(one != two);

	if ((std::size_t)one >= m_numIndices \|\| (std::size_t)two >= m_numIndices) {
	std::size_t newNumIndices = (one > two) ? one : two + 1;
	for (auto& gelem : m_elements) {
	gelem.representation.reserve(newNumIndices);
	for (std::size_t i = m_numIndices; i < newNumIndices; i++)
	gelem.representation.push_back(i);
	}
	m_numIndices = newNumIndices;
	}

	Generator g{one, two, flags};
	GroupElement e = ge(g);

	/* special case for first generator */
	if (m_elements.size() == 1) {
	while (!e.isId()) {
	m_elements.push_back(e);
	e = mul(e, g);
	}

	if (e.flags > 0)
	updateGlobalFlags(e.flags);

	// only add in case we didn't have identity
	if (m_elements.size() > 1)
	m_generators.push_back(g);
	return;
	}

	int p = findElement(e);
	if (p >= 0) {
	updateGlobalFlags(p);
	return;
	}

	std::size_t coset_order = m_elements.size();
	m_elements.push_back(e);
	for (std::size_t i = 1; i < coset_order; i++)
	m_elements.push_back(mul(m_elements[i], e));
	m_generators.push_back(g);

	std::size_t coset_rep = coset_order;
	do {
	for (auto g : m_generators) {
	e = mul(m_elements[coset_rep], g);
	p = findElement(e);
	if (p < 0) {
	// element not yet in group
	m_elements.push_back(e);
	for (std::size_t i = 1; i < coset_order; i++)
	m_elements.push_back(mul(m_elements[i], e));
	} else if (p > 0) {
	updateGlobalFlags(p);
	}
	}
	coset_rep += coset_order;
	} while (coset_rep < m_elements.size());
	}

	inline void DynamicSGroup::updateGlobalFlags(int flagDiffOfSameGenerator)
	{
	switch (flagDiffOfSameGenerator) {
	case 0:
	default:
	// nothing happened
	break;
	case NegationFlag:
	// every element is it's own negative => whole tensor is zero
	m_globalFlags \|= GlobalZeroFlag;
	break;
	case ConjugationFlag:
	// every element is it's own conjugate => whole tensor is real
	m_globalFlags \|= GlobalRealFlag;
	break;
	case (NegationFlag \| ConjugationFlag):
	// every element is it's own negative conjugate => whole tensor is imaginary
	m_globalFlags \|= GlobalImagFlag;
	break;
	/* NOTE:
	* since GlobalZeroFlag == GlobalRealFlag \| GlobalImagFlag, if one generator
	* causes the tensor to be real and the next one to be imaginary, this will
	* trivially give the correct result
	*/
	}
	}

	} // end namespace Eigen

	#endif // EIGEN_CXX11_TENSORSYMMETRY_DYNAMICSYMMETRY_H

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