test/sparse_ref.cpp - mirror - Git at Google

 // This file is part of Eigen, a lightweight C++ template library
 // for linear algebra.
 //
 // Copyright (C) 2015 Gael Guennebaud <gael.guennebaud@inria.fr>
 //
 // 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/.
 // SPDX-License-Identifier: MPL-2.0

 // This unit test cannot be easily written to work with EIGEN_DEFAULT_TO_ROW_MAJOR
 #ifdef EIGEN_DEFAULT_TO_ROW_MAJOR
 #undef EIGEN_DEFAULT_TO_ROW_MAJOR
 #endif

 static long int nb_temporaries;

 inline void on_temporary_creation() {
   // here's a great place to set a breakpoint when debugging failures in this test!
   nb_temporaries++;
 }

 #define EIGEN_SPARSE_CREATE_TEMPORARY_PLUGIN \
   { on_temporary_creation(); }

 #include "main.h"
 #include <Eigen/SparseCore>

 #define VERIFY_EVALUATION_COUNT(XPR, N)                                                   \
   {                                                                                       \
     nb_temporaries = 0;                                                                   \
     CALL_SUBTEST(XPR);                                                                    \
     if (nb_temporaries != N) std::cerr << "nb_temporaries == " << nb_temporaries << "\n"; \
     VERIFY((#XPR) && nb_temporaries == N);                                                \
   }

 template <typename PlainObjectType>
 void check_const_correctness(const PlainObjectType &) {
   // verify that ref-to-const don't have LvalueBit
   typedef std::add_const_t<PlainObjectType> ConstPlainObjectType;
   VERIFY(!(internal::traits<Ref<ConstPlainObjectType>>::Flags & LvalueBit));
   VERIFY(!(internal::traits<Ref<ConstPlainObjectType, Aligned>>::Flags & LvalueBit));
   VERIFY(!(Ref<ConstPlainObjectType>::Flags & LvalueBit));
   VERIFY(!(Ref<ConstPlainObjectType, Aligned>::Flags & LvalueBit));
 }

 template <typename B>
 EIGEN_DONT_INLINE void call_ref_1(Ref<SparseMatrix<float>> a, const B &b) {
   VERIFY_IS_EQUAL(a.toDense(), b.toDense());
 }

 template <typename B>
 EIGEN_DONT_INLINE void call_ref_2(const Ref<const SparseMatrix<float>> &a, const B &b) {
   VERIFY_IS_EQUAL(a.toDense(), b.toDense());
 }

 template <typename B>
 EIGEN_DONT_INLINE void call_ref_rm_1(Ref<SparseMatrix<float, RowMajor>> a, const B &b) {
   VERIFY_IS_EQUAL(a.toDense(), b.toDense());
 }

 template <typename B>
 EIGEN_DONT_INLINE void call_ref_rm_2(const Ref<const SparseMatrix<float, RowMajor>> &a, const B &b) {
   VERIFY_IS_EQUAL(a.toDense(), b.toDense());
 }

 template <typename B>
 EIGEN_DONT_INLINE void call_ref_3(const Ref<const SparseMatrix<float>, StandardCompressedFormat> &a, const B &b) {
   VERIFY(a.isCompressed());
   VERIFY_IS_EQUAL(a.toDense(), b.toDense());
 }

 template <typename B>
 EIGEN_DONT_INLINE void call_ref_4(Ref<SparseVector<float>> a, const B &b) {
   VERIFY_IS_EQUAL(a.toDense(), b.toDense());
 }

 template <typename B>
 EIGEN_DONT_INLINE void call_ref_5(const Ref<const SparseVector<float>> &a, const B &b) {
   VERIFY_IS_EQUAL(a.toDense(), b.toDense());
 }

 template <typename T>
 typename T::Map make_map(T &xpr) {
   return typename T::Map(xpr.rows(), xpr.cols(), xpr.nonZeros(), xpr.outerIndexPtr(), xpr.innerIndexPtr(),
                          xpr.valuePtr(), xpr.innerNonZeroPtr());
 }

 template <typename T>
 auto innerpanel(T &xpr, Index start, Index size)
     -> std::enable_if_t<(T::Flags & RowMajorBit) == RowMajorBit, decltype(xpr.middleRows(start, size))> {
   return xpr.middleRows(start, size);
 }

 template <typename T>
 auto innerpanel(T &xpr, Index start, Index size)
     -> std::enable_if_t<(T::Flags & RowMajorBit) == 0, decltype(xpr.middleCols(start, size))> {
   return xpr.middleCols(start, size);
 }

 template <typename T>
 auto innervector(T &xpr, Index index)
     -> std::enable_if_t<(T::Flags & RowMajorBit) == RowMajorBit, decltype(xpr.row(index))> {
   return xpr.row(index);
 }

 template <typename T>
 auto innervector(T &xpr, Index index) -> std::enable_if_t<(T::Flags & RowMajorBit) == 0, decltype(xpr.col(index))> {
   return xpr.col(index);
 }

 template <typename XprType, typename ExpectedType>
 void verify_coeffs(const XprType &xpr, const ExpectedType &expected) {
   auto coeffs = xpr.coeffs();
   VERIFY_IS_EQUAL(coeffs.size(), expected.size());
   for (Index i = 0; i < expected.size(); ++i) VERIFY_IS_EQUAL(coeffs[i], expected[i]);
 }

 template <int Options>
 void init_diag(SparseMatrix<float, Options> &m) {
   m.resize(4, 4);
   m.insert(0, 0) = 10.f;
   m.insert(1, 1) = 20.f;
   m.insert(2, 2) = 30.f;
   m.insert(3, 3) = 40.f;
   m.makeCompressed();
 }

 template <typename MatrixType>
 std::enable_if_t<(MatrixType::Flags & RowMajorBit) == 0> init_noncompressed_inner_panel(MatrixType &m) {
   m.resize(4, 4);
   m.reserve(VectorXi::Constant(4, 2));
   m.insert(1, 1) = 11.f;
   m.insert(2, 1) = 12.f;
   m.insert(0, 2) = 20.f;
   m.insert(2, 2) = 30.f;
   m.insert(3, 3) = 40.f;
 }

 template <typename MatrixType>
 std::enable_if_t<(MatrixType::Flags & RowMajorBit) == RowMajorBit> init_noncompressed_inner_panel(MatrixType &m) {
   m.resize(4, 4);
   m.reserve(VectorXi::Constant(4, 2));
   m.insert(1, 1) = 11.f;
   m.insert(1, 2) = 12.f;
   m.insert(2, 0) = 20.f;
   m.insert(2, 2) = 30.f;
   m.insert(3, 3) = 40.f;
 }

 template <typename MatrixType, typename Init, typename Verify>
 void verify_ref_and_map(const Init &init, const Verify &verify) {
   {
     MatrixType matrix;
     init(matrix);
     Ref<MatrixType> ref(matrix);
     verify(ref, matrix, 0);
   }

   {
     MatrixType matrix;
     init(matrix);
     auto map = make_map(matrix);
     verify(map, matrix, 1);
   }
 }

 template <typename XprType, typename MatrixType>
 void verify_slice_coeffs(XprType &xpr, MatrixType &storage, int variant) {
   Array<float, 2, 1> expected;
   expected << 20.f, 30.f;

   Ref<MatrixType> middle(innerpanel(xpr, 1, 2));
   Ref<const MatrixType> const_middle(innerpanel(xpr, 1, 2));
   const float updated0 = 210.f + 10.f * variant;
   const float updated1 = 310.f + 10.f * variant;

   verify_coeffs(middle, expected);
   verify_coeffs(const_middle, expected);
   auto coeffs = middle.coeffs();
   coeffs[0] = updated0;
   coeffs[1] = updated1;
   VERIFY_IS_EQUAL(storage.coeff(0, 0), 10.f);
   VERIFY_IS_EQUAL(storage.coeff(1, 1), updated0);
   VERIFY_IS_EQUAL(storage.coeff(2, 2), updated1);
 }

 template <typename MatrixType, typename XprType>
 float innerpanel_coeff(const XprType &xpr, Index outer, Index inner) {
   if ((MatrixType::Flags & RowMajorBit) == RowMajorBit) return xpr.coeff(outer, inner);
   return xpr.coeff(inner, outer);
 }

 template <typename MatrixType, typename XprType>
 void set_innerpanel_coeff(XprType &xpr, Index outer, Index inner, float value) {
   if ((MatrixType::Flags & RowMajorBit) == RowMajorBit)
     xpr.coeffRef(outer, inner) = value;
   else
     xpr.coeffRef(inner, outer) = value;
 }

 template <typename MatrixType>
 float storage_innerpanel_coeff(const MatrixType &storage, Index outer, Index inner) {
   if ((MatrixType::Flags & RowMajorBit) == RowMajorBit) return storage.coeff(outer + 1, inner);
   return storage.coeff(inner, outer + 1);
 }

 template <typename MatrixType>
 float storage_innervector_coeff(const MatrixType &storage, Index outer, Index inner) {
   if ((MatrixType::Flags & RowMajorBit) == RowMajorBit) return storage.coeff(outer, inner);
   return storage.coeff(inner, outer);
 }

 template <typename XprType, typename MatrixType>
 void verify_noncompressed_middle_binding(XprType &xpr, MatrixType &storage, int variant) {
   struct Entry {
     Index outer;
     Index inner;
     float value;
   };

   Ref<MatrixType> middle(innerpanel(xpr, 1, 2));
   Ref<const MatrixType> const_middle(innerpanel(xpr, 1, 2));
   const float updated0 = 111.f + variant;
   const float updated1 = 121.f + variant;
   const Entry expected[] = {{0, 1, 11.f}, {0, 2, 12.f}, {1, 0, 20.f}, {1, 2, 30.f}};

   VERIFY(!middle.isCompressed());
   VERIFY_IS_EQUAL(middle.nonZeros(), 4);
   VERIFY(!const_middle.isCompressed());
   VERIFY_IS_EQUAL(const_middle.nonZeros(), 4);
   for (const auto &entry : expected) {
     VERIFY_IS_EQUAL(innerpanel_coeff<MatrixType>(middle, entry.outer, entry.inner), entry.value);
     VERIFY_IS_EQUAL(innerpanel_coeff<MatrixType>(const_middle, entry.outer, entry.inner), entry.value);
   }

   set_innerpanel_coeff<MatrixType>(middle, 0, 1, updated0);
   set_innerpanel_coeff<MatrixType>(middle, 1, 0, updated1);
   VERIFY_IS_EQUAL(storage_innerpanel_coeff(storage, 0, 1), updated0);
   VERIFY_IS_EQUAL(storage_innerpanel_coeff(storage, 1, 0), updated1);
 }

 template <typename XprType, typename MatrixType>
 void verify_noncompressed_inner_vector_binding(XprType &xpr, MatrixType &storage, int variant) {
   Array<float, 2, 1> expected;
   expected << 20.f, 30.f;

   Ref<SparseVector<float>> inner(innervector(xpr, 2));
   Ref<const SparseVector<float>> const_inner(innervector(xpr, 2));
   const float updated0 = 211.f + variant;
   const float updated1 = 221.f + variant;

   VERIFY(inner.isCompressed());
   VERIFY_IS_EQUAL(inner.rows(), 4);
   VERIFY_IS_EQUAL(inner.cols(), 1);
   VERIFY_IS_EQUAL(inner.nonZeros(), 2);
   VERIFY(const_inner.isCompressed());
   VERIFY_IS_EQUAL(const_inner.rows(), 4);
   VERIFY_IS_EQUAL(const_inner.cols(), 1);
   VERIFY_IS_EQUAL(const_inner.nonZeros(), 2);
   verify_coeffs(inner, expected);
   verify_coeffs(const_inner, expected);

   auto coeffs = inner.coeffs();
   coeffs[0] = updated0;
   coeffs[1] = updated1;
   VERIFY_IS_EQUAL(storage_innervector_coeff(storage, 2, 0), updated0);
   VERIFY_IS_EQUAL(storage_innervector_coeff(storage, 2, 2), updated1);
 }

 void check_ref_slice_coeffs() {
   verify_ref_and_map<SparseMatrix<float>>(
       [](SparseMatrix<float> &matrix) { init_diag(matrix); },
       [](auto &xpr, auto &matrix, int variant) { verify_slice_coeffs(xpr, matrix, variant); });
   verify_ref_and_map<SparseMatrix<float, RowMajor>>(
       [](SparseMatrix<float, RowMajor> &matrix) { init_diag(matrix); },
       [](auto &xpr, auto &matrix, int variant) { verify_slice_coeffs(xpr, matrix, variant); });
 }

 void check_noncompressed_ref_slices() {
   verify_ref_and_map<SparseMatrix<float>>(
       [](SparseMatrix<float> &matrix) { init_noncompressed_inner_panel(matrix); },
       [](auto &xpr, auto &matrix, int variant) { verify_noncompressed_middle_binding(xpr, matrix, variant); });
   verify_ref_and_map<SparseMatrix<float, RowMajor>>(
       [](SparseMatrix<float, RowMajor> &matrix) { init_noncompressed_inner_panel(matrix); },
       [](auto &xpr, auto &matrix, int variant) { verify_noncompressed_middle_binding(xpr, matrix, variant); });
 }

 void check_noncompressed_ref_inner_vectors() {
   verify_ref_and_map<SparseMatrix<float>>(
       [](SparseMatrix<float> &matrix) { init_noncompressed_inner_panel(matrix); },
       [](auto &xpr, auto &matrix, int variant) { verify_noncompressed_inner_vector_binding(xpr, matrix, variant); });
   verify_ref_and_map<SparseMatrix<float, RowMajor>>(
       [](SparseMatrix<float, RowMajor> &matrix) { init_noncompressed_inner_panel(matrix); },
       [](auto &xpr, auto &matrix, int variant) { verify_noncompressed_inner_vector_binding(xpr, matrix, variant); });
 }

 void call_ref() {
   SparseMatrix<float> A = MatrixXf::Random(10, 10).sparseView(0.5, 1);
   SparseMatrix<float, RowMajor> B = MatrixXf::Random(10, 10).sparseView(0.5, 1);
   SparseMatrix<float> C = MatrixXf::Random(10, 10).sparseView(0.5, 1);
   C.reserve(VectorXi::Constant(C.outerSize(), 2));
   const SparseMatrix<float> &Ac(A);
   SparseVector<float> vc = VectorXf::Random(10).sparseView(0.5, 1);
   SparseVector<float, RowMajor> vr = VectorXf::Random(10).sparseView(0.5, 1);
   SparseMatrix<float> AA = A * A;

   VERIFY_EVALUATION_COUNT(call_ref_1(A, A), 0);
   //   VERIFY_EVALUATION_COUNT( call_ref_1(Ac, Ac),  0); // does not compile on purpose
   VERIFY_EVALUATION_COUNT(call_ref_2(A, A), 0);
   VERIFY_EVALUATION_COUNT(call_ref_3(A, A), 0);
   VERIFY_EVALUATION_COUNT(call_ref_2(A.transpose(), A.transpose()), 1);
   VERIFY_EVALUATION_COUNT(call_ref_3(A.transpose(), A.transpose()), 1);
   VERIFY_EVALUATION_COUNT(call_ref_2(Ac, Ac), 0);
   VERIFY_EVALUATION_COUNT(call_ref_3(Ac, Ac), 0);
   VERIFY_EVALUATION_COUNT(call_ref_2(A + A, 2 * Ac), 1);
   VERIFY_EVALUATION_COUNT(call_ref_3(A + A, 2 * Ac), 1);
   VERIFY_EVALUATION_COUNT(call_ref_2(B, B), 1);
   VERIFY_EVALUATION_COUNT(call_ref_3(B, B), 1);
   VERIFY_EVALUATION_COUNT(call_ref_2(B.transpose(), B.transpose()), 0);
   VERIFY_EVALUATION_COUNT(call_ref_3(B.transpose(), B.transpose()), 0);
   VERIFY_EVALUATION_COUNT(call_ref_2(A * A, AA), 3);
   VERIFY_EVALUATION_COUNT(call_ref_3(A * A, AA), 3);

   VERIFY(!C.isCompressed());
   VERIFY_EVALUATION_COUNT(call_ref_3(C, C), 1);

   Ref<SparseMatrix<float>> Ar(A);
   VERIFY_IS_APPROX(Ar + Ar, A + A);
   VERIFY_EVALUATION_COUNT(call_ref_1(Ar, A), 0);
   VERIFY_EVALUATION_COUNT(call_ref_2(Ar, A), 0);
   VERIFY_EVALUATION_COUNT(call_ref_1(Ar.middleCols(1, 3), A.middleCols(1, 3)), 0);
   VERIFY_EVALUATION_COUNT(call_ref_2(Ar.middleCols(1, 3), A.middleCols(1, 3)), 0);
   VERIFY_EVALUATION_COUNT(call_ref_4(Ar.col(2), A.col(2)), 0);
   VERIFY_EVALUATION_COUNT(call_ref_5(Ar.col(2), A.col(2)), 0);

   Ref<SparseMatrix<float, RowMajor>> Br(B);
   VERIFY_EVALUATION_COUNT(call_ref_1(Br.transpose(), Br.transpose()), 0);
   VERIFY_EVALUATION_COUNT(call_ref_2(Br, Br), 1);
   VERIFY_EVALUATION_COUNT(call_ref_2(Br.transpose(), Br.transpose()), 0);
   VERIFY_EVALUATION_COUNT(call_ref_rm_1(Br.middleRows(1, 3), B.middleRows(1, 3)), 0);
   VERIFY_EVALUATION_COUNT(call_ref_rm_2(Br.middleRows(1, 3), B.middleRows(1, 3)), 0);
   VERIFY_EVALUATION_COUNT(call_ref_4(Br.row(2), B.row(2).transpose()), 0);
   VERIFY_EVALUATION_COUNT(call_ref_5(Br.row(2), B.row(2).transpose()), 0);

   auto Am = make_map(A);
   VERIFY_EVALUATION_COUNT(call_ref_1(Am.middleCols(1, 3), A.middleCols(1, 3)), 0);
   VERIFY_EVALUATION_COUNT(call_ref_2(Am.middleCols(1, 3), A.middleCols(1, 3)), 0);
   VERIFY_EVALUATION_COUNT(call_ref_4(Am.col(2), A.col(2)), 0);
   VERIFY_EVALUATION_COUNT(call_ref_5(Am.col(2), A.col(2)), 0);

   auto Bm = make_map(B);
   VERIFY_EVALUATION_COUNT(call_ref_rm_1(Bm.middleRows(1, 3), B.middleRows(1, 3)), 0);
   VERIFY_EVALUATION_COUNT(call_ref_rm_2(Bm.middleRows(1, 3), B.middleRows(1, 3)), 0);
   VERIFY_EVALUATION_COUNT(call_ref_4(Bm.row(2), B.row(2).transpose()), 0);
   VERIFY_EVALUATION_COUNT(call_ref_5(Bm.row(2), B.row(2).transpose()), 0);

   Ref<const SparseMatrix<float>> Arc(A);
   //   VERIFY_EVALUATION_COUNT( call_ref_1(Arc, Arc),  0); // does not compile on purpose
   VERIFY_EVALUATION_COUNT(call_ref_2(Arc, Arc), 0);

   VERIFY_EVALUATION_COUNT(call_ref_2(A.middleCols(1, 3), A.middleCols(1, 3)), 0);

   VERIFY_EVALUATION_COUNT(call_ref_2(A.col(2), A.col(2)), 0);
   VERIFY_EVALUATION_COUNT(call_ref_2(vc, vc), 0);
   VERIFY_EVALUATION_COUNT(call_ref_2(vr.transpose(), vr.transpose()), 0);
   VERIFY_EVALUATION_COUNT(call_ref_2(vr, vr.transpose()), 0);

   VERIFY_EVALUATION_COUNT(call_ref_2(A.block(1, 1, 3, 3), A.block(1, 1, 3, 3)),
                           1);  // should be 0 (allocate starts/nnz only)

   VERIFY_EVALUATION_COUNT(call_ref_4(vc, vc), 0);
   VERIFY_EVALUATION_COUNT(call_ref_4(vr, vr.transpose()), 0);
   VERIFY_EVALUATION_COUNT(call_ref_5(vc, vc), 0);
   VERIFY_EVALUATION_COUNT(call_ref_5(vr, vr.transpose()), 0);
   VERIFY_EVALUATION_COUNT(call_ref_4(A.col(2), A.col(2)), 0);
   VERIFY_EVALUATION_COUNT(call_ref_5(A.col(2), A.col(2)), 0);
   // VERIFY_EVALUATION_COUNT( call_ref_4(A.row(2), A.row(2).transpose()),  1); // does not compile on purpose
   VERIFY_EVALUATION_COUNT(call_ref_5(A.row(2), A.row(2).transpose()), 1);
 }

 EIGEN_DECLARE_TEST(sparse_ref) {
   for (int i = 0; i < g_repeat; i++) {
     CALL_SUBTEST_1(check_const_correctness(SparseMatrix<float>()));
     CALL_SUBTEST_1(check_const_correctness(SparseMatrix<double, RowMajor>()));
     CALL_SUBTEST_2(call_ref());
     CALL_SUBTEST_4(check_ref_slice_coeffs());
     CALL_SUBTEST_4(check_noncompressed_ref_slices());
     CALL_SUBTEST_4(check_noncompressed_ref_inner_vectors());

     CALL_SUBTEST_3(check_const_correctness(SparseVector<float>()));
     CALL_SUBTEST_3(check_const_correctness(SparseVector<double, RowMajor>()));
   }
 }
	// This file is part of Eigen, a lightweight C++ template library
	// for linear algebra.
	//
	// Copyright (C) 2015 Gael Guennebaud <gael.guennebaud@inria.fr>
	//
	// 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/.
	// SPDX-License-Identifier: MPL-2.0

	// This unit test cannot be easily written to work with EIGEN_DEFAULT_TO_ROW_MAJOR
	#ifdef EIGEN_DEFAULT_TO_ROW_MAJOR
	#undef EIGEN_DEFAULT_TO_ROW_MAJOR
	#endif

	static long int nb_temporaries;

	inline void on_temporary_creation() {
	// here's a great place to set a breakpoint when debugging failures in this test!
	nb_temporaries++;
	}

	#define EIGEN_SPARSE_CREATE_TEMPORARY_PLUGIN \
	{ on_temporary_creation(); }

	#include "main.h"
	#include <Eigen/SparseCore>

	#define VERIFY_EVALUATION_COUNT(XPR, N) \
	{ \
	nb_temporaries = 0; \
	CALL_SUBTEST(XPR); \
	if (nb_temporaries != N) std::cerr << "nb_temporaries == " << nb_temporaries << "\n"; \
	VERIFY((#XPR) && nb_temporaries == N); \
	}

	template <typename PlainObjectType>
	void check_const_correctness(const PlainObjectType &) {
	// verify that ref-to-const don't have LvalueBit
	typedef std::add_const_t<PlainObjectType> ConstPlainObjectType;
	VERIFY(!(internal::traits<Ref<ConstPlainObjectType>>::Flags & LvalueBit));
	VERIFY(!(internal::traits<Ref<ConstPlainObjectType, Aligned>>::Flags & LvalueBit));
	VERIFY(!(Ref<ConstPlainObjectType>::Flags & LvalueBit));
	VERIFY(!(Ref<ConstPlainObjectType, Aligned>::Flags & LvalueBit));
	}

	template <typename B>
	EIGEN_DONT_INLINE void call_ref_1(Ref<SparseMatrix<float>> a, const B &b) {
	VERIFY_IS_EQUAL(a.toDense(), b.toDense());
	}

	template <typename B>
	EIGEN_DONT_INLINE void call_ref_2(const Ref<const SparseMatrix<float>> &a, const B &b) {
	VERIFY_IS_EQUAL(a.toDense(), b.toDense());
	}

	template <typename B>
	EIGEN_DONT_INLINE void call_ref_rm_1(Ref<SparseMatrix<float, RowMajor>> a, const B &b) {
	VERIFY_IS_EQUAL(a.toDense(), b.toDense());
	}

	template <typename B>
	EIGEN_DONT_INLINE void call_ref_rm_2(const Ref<const SparseMatrix<float, RowMajor>> &a, const B &b) {
	VERIFY_IS_EQUAL(a.toDense(), b.toDense());
	}

	template <typename B>
	EIGEN_DONT_INLINE void call_ref_3(const Ref<const SparseMatrix<float>, StandardCompressedFormat> &a, const B &b) {
	VERIFY(a.isCompressed());
	VERIFY_IS_EQUAL(a.toDense(), b.toDense());
	}

	template <typename B>
	EIGEN_DONT_INLINE void call_ref_4(Ref<SparseVector<float>> a, const B &b) {
	VERIFY_IS_EQUAL(a.toDense(), b.toDense());
	}

	template <typename B>
	EIGEN_DONT_INLINE void call_ref_5(const Ref<const SparseVector<float>> &a, const B &b) {
	VERIFY_IS_EQUAL(a.toDense(), b.toDense());
	}

	template <typename T>
	typename T::Map make_map(T &xpr) {
	return typename T::Map(xpr.rows(), xpr.cols(), xpr.nonZeros(), xpr.outerIndexPtr(), xpr.innerIndexPtr(),
	xpr.valuePtr(), xpr.innerNonZeroPtr());
	}

	template <typename T>
	auto innerpanel(T &xpr, Index start, Index size)
	-> std::enable_if_t<(T::Flags & RowMajorBit) == RowMajorBit, decltype(xpr.middleRows(start, size))> {
	return xpr.middleRows(start, size);
	}

	template <typename T>
	auto innerpanel(T &xpr, Index start, Index size)
	-> std::enable_if_t<(T::Flags & RowMajorBit) == 0, decltype(xpr.middleCols(start, size))> {
	return xpr.middleCols(start, size);
	}

	template <typename T>
	auto innervector(T &xpr, Index index)
	-> std::enable_if_t<(T::Flags & RowMajorBit) == RowMajorBit, decltype(xpr.row(index))> {
	return xpr.row(index);
	}

	template <typename T>
	auto innervector(T &xpr, Index index) -> std::enable_if_t<(T::Flags & RowMajorBit) == 0, decltype(xpr.col(index))> {
	return xpr.col(index);
	}

	template <typename XprType, typename ExpectedType>
	void verify_coeffs(const XprType &xpr, const ExpectedType &expected) {
	auto coeffs = xpr.coeffs();
	VERIFY_IS_EQUAL(coeffs.size(), expected.size());
	for (Index i = 0; i < expected.size(); ++i) VERIFY_IS_EQUAL(coeffs[i], expected[i]);
	}

	template <int Options>
	void init_diag(SparseMatrix<float, Options> &m) {
	m.resize(4, 4);
	m.insert(0, 0) = 10.f;
	m.insert(1, 1) = 20.f;
	m.insert(2, 2) = 30.f;
	m.insert(3, 3) = 40.f;
	m.makeCompressed();
	}

	template <typename MatrixType>
	std::enable_if_t<(MatrixType::Flags & RowMajorBit) == 0> init_noncompressed_inner_panel(MatrixType &m) {
	m.resize(4, 4);
	m.reserve(VectorXi::Constant(4, 2));
	m.insert(1, 1) = 11.f;
	m.insert(2, 1) = 12.f;
	m.insert(0, 2) = 20.f;
	m.insert(2, 2) = 30.f;
	m.insert(3, 3) = 40.f;
	}

	template <typename MatrixType>
	std::enable_if_t<(MatrixType::Flags & RowMajorBit) == RowMajorBit> init_noncompressed_inner_panel(MatrixType &m) {
	m.resize(4, 4);
	m.reserve(VectorXi::Constant(4, 2));
	m.insert(1, 1) = 11.f;
	m.insert(1, 2) = 12.f;
	m.insert(2, 0) = 20.f;
	m.insert(2, 2) = 30.f;
	m.insert(3, 3) = 40.f;
	}

	template <typename MatrixType, typename Init, typename Verify>
	void verify_ref_and_map(const Init &init, const Verify &verify) {
	{
	MatrixType matrix;
	init(matrix);
	Ref<MatrixType> ref(matrix);
	verify(ref, matrix, 0);
	}

	{
	MatrixType matrix;
	init(matrix);
	auto map = make_map(matrix);
	verify(map, matrix, 1);
	}
	}

	template <typename XprType, typename MatrixType>
	void verify_slice_coeffs(XprType &xpr, MatrixType &storage, int variant) {
	Array<float, 2, 1> expected;
	expected << 20.f, 30.f;

	Ref<MatrixType> middle(innerpanel(xpr, 1, 2));
	Ref<const MatrixType> const_middle(innerpanel(xpr, 1, 2));
	const float updated0 = 210.f + 10.f * variant;
	const float updated1 = 310.f + 10.f * variant;

	verify_coeffs(middle, expected);
	verify_coeffs(const_middle, expected);
	auto coeffs = middle.coeffs();
	coeffs[0] = updated0;
	coeffs[1] = updated1;
	VERIFY_IS_EQUAL(storage.coeff(0, 0), 10.f);
	VERIFY_IS_EQUAL(storage.coeff(1, 1), updated0);
	VERIFY_IS_EQUAL(storage.coeff(2, 2), updated1);
	}

	template <typename MatrixType, typename XprType>
	float innerpanel_coeff(const XprType &xpr, Index outer, Index inner) {
	if ((MatrixType::Flags & RowMajorBit) == RowMajorBit) return xpr.coeff(outer, inner);
	return xpr.coeff(inner, outer);
	}

	template <typename MatrixType, typename XprType>
	void set_innerpanel_coeff(XprType &xpr, Index outer, Index inner, float value) {
	if ((MatrixType::Flags & RowMajorBit) == RowMajorBit)
	xpr.coeffRef(outer, inner) = value;
	else
	xpr.coeffRef(inner, outer) = value;
	}

	template <typename MatrixType>
	float storage_innerpanel_coeff(const MatrixType &storage, Index outer, Index inner) {
	if ((MatrixType::Flags & RowMajorBit) == RowMajorBit) return storage.coeff(outer + 1, inner);
	return storage.coeff(inner, outer + 1);
	}

	template <typename MatrixType>
	float storage_innervector_coeff(const MatrixType &storage, Index outer, Index inner) {
	if ((MatrixType::Flags & RowMajorBit) == RowMajorBit) return storage.coeff(outer, inner);
	return storage.coeff(inner, outer);
	}

	template <typename XprType, typename MatrixType>
	void verify_noncompressed_middle_binding(XprType &xpr, MatrixType &storage, int variant) {
	struct Entry {
	Index outer;
	Index inner;
	float value;
	};

	Ref<MatrixType> middle(innerpanel(xpr, 1, 2));
	Ref<const MatrixType> const_middle(innerpanel(xpr, 1, 2));
	const float updated0 = 111.f + variant;
	const float updated1 = 121.f + variant;
	const Entry expected[] = {{0, 1, 11.f}, {0, 2, 12.f}, {1, 0, 20.f}, {1, 2, 30.f}};

	VERIFY(!middle.isCompressed());
	VERIFY_IS_EQUAL(middle.nonZeros(), 4);
	VERIFY(!const_middle.isCompressed());
	VERIFY_IS_EQUAL(const_middle.nonZeros(), 4);
	for (const auto &entry : expected) {
	VERIFY_IS_EQUAL(innerpanel_coeff<MatrixType>(middle, entry.outer, entry.inner), entry.value);
	VERIFY_IS_EQUAL(innerpanel_coeff<MatrixType>(const_middle, entry.outer, entry.inner), entry.value);
	}

	set_innerpanel_coeff<MatrixType>(middle, 0, 1, updated0);
	set_innerpanel_coeff<MatrixType>(middle, 1, 0, updated1);
	VERIFY_IS_EQUAL(storage_innerpanel_coeff(storage, 0, 1), updated0);
	VERIFY_IS_EQUAL(storage_innerpanel_coeff(storage, 1, 0), updated1);
	}

	template <typename XprType, typename MatrixType>
	void verify_noncompressed_inner_vector_binding(XprType &xpr, MatrixType &storage, int variant) {
	Array<float, 2, 1> expected;
	expected << 20.f, 30.f;

	Ref<SparseVector<float>> inner(innervector(xpr, 2));
	Ref<const SparseVector<float>> const_inner(innervector(xpr, 2));
	const float updated0 = 211.f + variant;
	const float updated1 = 221.f + variant;

	VERIFY(inner.isCompressed());
	VERIFY_IS_EQUAL(inner.rows(), 4);
	VERIFY_IS_EQUAL(inner.cols(), 1);
	VERIFY_IS_EQUAL(inner.nonZeros(), 2);
	VERIFY(const_inner.isCompressed());
	VERIFY_IS_EQUAL(const_inner.rows(), 4);
	VERIFY_IS_EQUAL(const_inner.cols(), 1);
	VERIFY_IS_EQUAL(const_inner.nonZeros(), 2);
	verify_coeffs(inner, expected);
	verify_coeffs(const_inner, expected);

	auto coeffs = inner.coeffs();
	coeffs[0] = updated0;
	coeffs[1] = updated1;
	VERIFY_IS_EQUAL(storage_innervector_coeff(storage, 2, 0), updated0);
	VERIFY_IS_EQUAL(storage_innervector_coeff(storage, 2, 2), updated1);
	}

	void check_ref_slice_coeffs() {
	verify_ref_and_map<SparseMatrix<float>>(
	[](SparseMatrix<float> &matrix) { init_diag(matrix); },
	[](auto &xpr, auto &matrix, int variant) { verify_slice_coeffs(xpr, matrix, variant); });
	verify_ref_and_map<SparseMatrix<float, RowMajor>>(
	[](SparseMatrix<float, RowMajor> &matrix) { init_diag(matrix); },
	[](auto &xpr, auto &matrix, int variant) { verify_slice_coeffs(xpr, matrix, variant); });
	}

	void check_noncompressed_ref_slices() {
	verify_ref_and_map<SparseMatrix<float>>(
	[](SparseMatrix<float> &matrix) { init_noncompressed_inner_panel(matrix); },
	[](auto &xpr, auto &matrix, int variant) { verify_noncompressed_middle_binding(xpr, matrix, variant); });
	verify_ref_and_map<SparseMatrix<float, RowMajor>>(
	[](SparseMatrix<float, RowMajor> &matrix) { init_noncompressed_inner_panel(matrix); },
	[](auto &xpr, auto &matrix, int variant) { verify_noncompressed_middle_binding(xpr, matrix, variant); });
	}

	void check_noncompressed_ref_inner_vectors() {
	verify_ref_and_map<SparseMatrix<float>>(
	[](SparseMatrix<float> &matrix) { init_noncompressed_inner_panel(matrix); },
	[](auto &xpr, auto &matrix, int variant) { verify_noncompressed_inner_vector_binding(xpr, matrix, variant); });
	verify_ref_and_map<SparseMatrix<float, RowMajor>>(
	[](SparseMatrix<float, RowMajor> &matrix) { init_noncompressed_inner_panel(matrix); },
	[](auto &xpr, auto &matrix, int variant) { verify_noncompressed_inner_vector_binding(xpr, matrix, variant); });
	}

	void call_ref() {
	SparseMatrix<float> A = MatrixXf::Random(10, 10).sparseView(0.5, 1);
	SparseMatrix<float, RowMajor> B = MatrixXf::Random(10, 10).sparseView(0.5, 1);
	SparseMatrix<float> C = MatrixXf::Random(10, 10).sparseView(0.5, 1);
	C.reserve(VectorXi::Constant(C.outerSize(), 2));
	const SparseMatrix<float> &Ac(A);
	SparseVector<float> vc = VectorXf::Random(10).sparseView(0.5, 1);
	SparseVector<float, RowMajor> vr = VectorXf::Random(10).sparseView(0.5, 1);
	SparseMatrix<float> AA = A * A;

	VERIFY_EVALUATION_COUNT(call_ref_1(A, A), 0);
	// VERIFY_EVALUATION_COUNT( call_ref_1(Ac, Ac), 0); // does not compile on purpose
	VERIFY_EVALUATION_COUNT(call_ref_2(A, A), 0);
	VERIFY_EVALUATION_COUNT(call_ref_3(A, A), 0);
	VERIFY_EVALUATION_COUNT(call_ref_2(A.transpose(), A.transpose()), 1);
	VERIFY_EVALUATION_COUNT(call_ref_3(A.transpose(), A.transpose()), 1);
	VERIFY_EVALUATION_COUNT(call_ref_2(Ac, Ac), 0);
	VERIFY_EVALUATION_COUNT(call_ref_3(Ac, Ac), 0);
	VERIFY_EVALUATION_COUNT(call_ref_2(A + A, 2 * Ac), 1);
	VERIFY_EVALUATION_COUNT(call_ref_3(A + A, 2 * Ac), 1);
	VERIFY_EVALUATION_COUNT(call_ref_2(B, B), 1);
	VERIFY_EVALUATION_COUNT(call_ref_3(B, B), 1);
	VERIFY_EVALUATION_COUNT(call_ref_2(B.transpose(), B.transpose()), 0);
	VERIFY_EVALUATION_COUNT(call_ref_3(B.transpose(), B.transpose()), 0);
	VERIFY_EVALUATION_COUNT(call_ref_2(A * A, AA), 3);
	VERIFY_EVALUATION_COUNT(call_ref_3(A * A, AA), 3);

	VERIFY(!C.isCompressed());
	VERIFY_EVALUATION_COUNT(call_ref_3(C, C), 1);

	Ref<SparseMatrix<float>> Ar(A);
	VERIFY_IS_APPROX(Ar + Ar, A + A);
	VERIFY_EVALUATION_COUNT(call_ref_1(Ar, A), 0);
	VERIFY_EVALUATION_COUNT(call_ref_2(Ar, A), 0);
	VERIFY_EVALUATION_COUNT(call_ref_1(Ar.middleCols(1, 3), A.middleCols(1, 3)), 0);
	VERIFY_EVALUATION_COUNT(call_ref_2(Ar.middleCols(1, 3), A.middleCols(1, 3)), 0);
	VERIFY_EVALUATION_COUNT(call_ref_4(Ar.col(2), A.col(2)), 0);
	VERIFY_EVALUATION_COUNT(call_ref_5(Ar.col(2), A.col(2)), 0);

	Ref<SparseMatrix<float, RowMajor>> Br(B);
	VERIFY_EVALUATION_COUNT(call_ref_1(Br.transpose(), Br.transpose()), 0);
	VERIFY_EVALUATION_COUNT(call_ref_2(Br, Br), 1);
	VERIFY_EVALUATION_COUNT(call_ref_2(Br.transpose(), Br.transpose()), 0);
	VERIFY_EVALUATION_COUNT(call_ref_rm_1(Br.middleRows(1, 3), B.middleRows(1, 3)), 0);
	VERIFY_EVALUATION_COUNT(call_ref_rm_2(Br.middleRows(1, 3), B.middleRows(1, 3)), 0);
	VERIFY_EVALUATION_COUNT(call_ref_4(Br.row(2), B.row(2).transpose()), 0);
	VERIFY_EVALUATION_COUNT(call_ref_5(Br.row(2), B.row(2).transpose()), 0);

	auto Am = make_map(A);
	VERIFY_EVALUATION_COUNT(call_ref_1(Am.middleCols(1, 3), A.middleCols(1, 3)), 0);
	VERIFY_EVALUATION_COUNT(call_ref_2(Am.middleCols(1, 3), A.middleCols(1, 3)), 0);
	VERIFY_EVALUATION_COUNT(call_ref_4(Am.col(2), A.col(2)), 0);
	VERIFY_EVALUATION_COUNT(call_ref_5(Am.col(2), A.col(2)), 0);

	auto Bm = make_map(B);
	VERIFY_EVALUATION_COUNT(call_ref_rm_1(Bm.middleRows(1, 3), B.middleRows(1, 3)), 0);
	VERIFY_EVALUATION_COUNT(call_ref_rm_2(Bm.middleRows(1, 3), B.middleRows(1, 3)), 0);
	VERIFY_EVALUATION_COUNT(call_ref_4(Bm.row(2), B.row(2).transpose()), 0);
	VERIFY_EVALUATION_COUNT(call_ref_5(Bm.row(2), B.row(2).transpose()), 0);

	Ref<const SparseMatrix<float>> Arc(A);
	// VERIFY_EVALUATION_COUNT( call_ref_1(Arc, Arc), 0); // does not compile on purpose
	VERIFY_EVALUATION_COUNT(call_ref_2(Arc, Arc), 0);

	VERIFY_EVALUATION_COUNT(call_ref_2(A.middleCols(1, 3), A.middleCols(1, 3)), 0);

	VERIFY_EVALUATION_COUNT(call_ref_2(A.col(2), A.col(2)), 0);
	VERIFY_EVALUATION_COUNT(call_ref_2(vc, vc), 0);
	VERIFY_EVALUATION_COUNT(call_ref_2(vr.transpose(), vr.transpose()), 0);
	VERIFY_EVALUATION_COUNT(call_ref_2(vr, vr.transpose()), 0);

	VERIFY_EVALUATION_COUNT(call_ref_2(A.block(1, 1, 3, 3), A.block(1, 1, 3, 3)),
	1); // should be 0 (allocate starts/nnz only)

	VERIFY_EVALUATION_COUNT(call_ref_4(vc, vc), 0);
	VERIFY_EVALUATION_COUNT(call_ref_4(vr, vr.transpose()), 0);
	VERIFY_EVALUATION_COUNT(call_ref_5(vc, vc), 0);
	VERIFY_EVALUATION_COUNT(call_ref_5(vr, vr.transpose()), 0);
	VERIFY_EVALUATION_COUNT(call_ref_4(A.col(2), A.col(2)), 0);
	VERIFY_EVALUATION_COUNT(call_ref_5(A.col(2), A.col(2)), 0);
	// VERIFY_EVALUATION_COUNT( call_ref_4(A.row(2), A.row(2).transpose()), 1); // does not compile on purpose
	VERIFY_EVALUATION_COUNT(call_ref_5(A.row(2), A.row(2).transpose()), 1);
	}

	EIGEN_DECLARE_TEST(sparse_ref) {
	for (int i = 0; i < g_repeat; i++) {
	CALL_SUBTEST_1(check_const_correctness(SparseMatrix<float>()));
	CALL_SUBTEST_1(check_const_correctness(SparseMatrix<double, RowMajor>()));
	CALL_SUBTEST_2(call_ref());
	CALL_SUBTEST_4(check_ref_slice_coeffs());
	CALL_SUBTEST_4(check_noncompressed_ref_slices());
	CALL_SUBTEST_4(check_noncompressed_ref_inner_vectors());

	CALL_SUBTEST_3(check_const_correctness(SparseVector<float>()));
	CALL_SUBTEST_3(check_const_correctness(SparseVector<double, RowMajor>()));
	}
	}