unsupported/test/NNLS.cpp - eigen - Git at Google

 // This file is part of Eigen, a lightweight C++ template library
 // for linear algebra.
 //
 // Copyright (C) Essex Edwards <essex.edwards@gmail.com>
 //
 // 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/.

 #define EIGEN_RUNTIME_NO_MALLOC

 #include "main.h"
 #include <unsupported/Eigen/NNLS>

 /// Check that 'x' solves the NNLS optimization problem `min ||A*x-b|| s.t. 0 <= x`.
 /// The \p tolerance parameter is the absolute tolerance on the gradient, A'*(A*x-b).
 template <typename MatrixType, typename VectorB, typename VectorX, typename Scalar>
 static void verify_nnls_optimality(const MatrixType &A, const VectorB &b, const VectorX &x, const Scalar tolerance) {
   // The NNLS optimality conditions are:
   //
   // * 0 = A'*A*x - A'*b - lambda
   // * 0 <= x[i] \forall i
   // * 0 <= lambda[i] \forall i
   // * 0 = x[i]*lambda[i] \forall i
   //
   // we don't know lambda, but by assuming the first optimality condition is true,
   // we can derive it and then check the others conditions.
   const VectorX lambda = A.transpose() * (A * x - b);

   // NNLS solutions are EXACTLY not negative.
   VERIFY_LE(0, x.minCoeff());

   // Exact lambda would be non-negative, but computed lambda might leak a little
   VERIFY_LE(-tolerance, lambda.minCoeff());

   // x[i]*lambda[i] == 0 <~~> (x[i]==0) || (lambda[i] is small)
   VERIFY(((x.array() == Scalar(0)) || (lambda.array() <= tolerance)).all());
 }

 template <typename MatrixType, typename VectorB, typename VectorX>
 static void test_nnls_known_solution(const MatrixType &A, const VectorB &b, const VectorX &x_expected) {
   using Scalar = typename MatrixType::Scalar;

   using std::sqrt;
   const Scalar tolerance = sqrt(Eigen::GenericNumTraits<Scalar>::epsilon());
   Index max_iter = 5 * A.cols();  // A heuristic guess.
   NNLS<MatrixType> nnls(A, max_iter, tolerance);
   const VectorX x = nnls.solve(b);

   VERIFY_IS_EQUAL(nnls.info(), ComputationInfo::Success);
   VERIFY_IS_APPROX(x, x_expected);
   verify_nnls_optimality(A, b, x, tolerance);
 }

 template <typename MatrixType>
 static void test_nnls_random_problem() {
   //
   // SETUP
   //

   Index cols = MatrixType::ColsAtCompileTime;
   if (cols == Dynamic) cols = internal::random<Index>(1, EIGEN_TEST_MAX_SIZE);
   Index rows = MatrixType::RowsAtCompileTime;
   if (rows == Dynamic) rows = internal::random<Index>(cols, EIGEN_TEST_MAX_SIZE);
   VERIFY_LE(cols, rows);  // To have a unique LS solution: cols <= rows.

   // Make some sort of random test problem from a wide range of scales and condition numbers.
   using std::pow;
   using Scalar = typename MatrixType::Scalar;
   const Scalar sqrtConditionNumber = pow(Scalar(10), internal::random<Scalar>(Scalar(0), Scalar(2)));
   const Scalar scaleA = pow(Scalar(10), internal::random<Scalar>(Scalar(-3), Scalar(3)));
   const Scalar minSingularValue = scaleA / sqrtConditionNumber;
   const Scalar maxSingularValue = scaleA * sqrtConditionNumber;
   MatrixType A(rows, cols);
   generateRandomMatrixSvs(setupRangeSvs<Matrix<Scalar, Dynamic, 1>>(cols, minSingularValue, maxSingularValue), rows,
                           cols, A);

   // Make a random RHS also with a random scaling.
   using VectorB = decltype(A.col(0).eval());
   const Scalar scaleB = pow(Scalar(10), internal::random<Scalar>(Scalar(-3), Scalar(3)));
   const VectorB b = scaleB * VectorB::Random(A.rows());

   //
   // ACT
   //

   using Scalar = typename MatrixType::Scalar;
   using std::sqrt;
   const Scalar tolerance =
       sqrt(Eigen::GenericNumTraits<Scalar>::epsilon()) * b.cwiseAbs().maxCoeff() * A.cwiseAbs().maxCoeff();
   Index max_iter = 5 * A.cols();  // A heuristic guess.
   NNLS<MatrixType> nnls(A, max_iter, tolerance);
   const typename NNLS<MatrixType>::SolutionVectorType &x = nnls.solve(b);

   //
   // VERIFY
   //

   // In fact, NNLS can fail on some problems, but they are rare in practice.
   VERIFY_IS_EQUAL(nnls.info(), ComputationInfo::Success);
   verify_nnls_optimality(A, b, x, tolerance);
 }

 static void test_nnls_handles_zero_rhs() {
   //
   // SETUP
   //
   const Index cols = internal::random<Index>(1, EIGEN_TEST_MAX_SIZE);
   const Index rows = internal::random<Index>(cols, EIGEN_TEST_MAX_SIZE);
   const MatrixXd A = MatrixXd::Random(rows, cols);
   const VectorXd b = VectorXd::Zero(rows);

   //
   // ACT
   //
   NNLS<MatrixXd> nnls(A);
   const VectorXd x = nnls.solve(b);

   //
   // VERIFY
   //
   VERIFY_IS_EQUAL(nnls.info(), ComputationInfo::Success);
   VERIFY_LE(nnls.iterations(), 1);  // 0 or 1 would be be fine for an edge case like this.
   VERIFY_IS_EQUAL(x, VectorXd::Zero(cols));
 }

 static void test_nnls_handles_Mx0_matrix() {
   //
   // SETUP
   //
   const Index rows = internal::random<Index>(1, EIGEN_TEST_MAX_SIZE);
   const MatrixXd A(rows, 0);
   const VectorXd b = VectorXd::Random(rows);

   //
   // ACT
   //
   NNLS<MatrixXd> nnls(A);
   const VectorXd x = nnls.solve(b);

   //
   // VERIFY
   //
   VERIFY_IS_EQUAL(nnls.info(), ComputationInfo::Success);
   VERIFY_LE(nnls.iterations(), 0);
   VERIFY_IS_EQUAL(x.size(), 0);
 }

 static void test_nnls_handles_0x0_matrix() {
   //
   // SETUP
   //
   const MatrixXd A(0, 0);
   const VectorXd b(0);

   //
   // ACT
   //
   NNLS<MatrixXd> nnls(A);
   const VectorXd x = nnls.solve(b);

   //
   // VERIFY
   //
   VERIFY_IS_EQUAL(nnls.info(), ComputationInfo::Success);
   VERIFY_LE(nnls.iterations(), 0);
   VERIFY_IS_EQUAL(x.size(), 0);
 }

 static void test_nnls_handles_dependent_columns() {
   //
   // SETUP
   //
   const Index rank = internal::random<Index>(1, EIGEN_TEST_MAX_SIZE / 2);
   const Index cols = 2 * rank;
   const Index rows = internal::random<Index>(cols, EIGEN_TEST_MAX_SIZE);
   const MatrixXd A = MatrixXd::Random(rows, rank) * MatrixXd::Random(rank, cols);
   const VectorXd b = VectorXd::Random(rows);

   //
   // ACT
   //
   const double tolerance = 1e-8;
   NNLS<MatrixXd> nnls(A);
   const VectorXd &x = nnls.solve(b);

   //
   // VERIFY
   //
   // What should happen when the input 'A' has dependent columns?
   // We might still succeed. Or we might not converge.
   // Either outcome is fine. If Success is indicated,
   // then 'x' must actually be a solution vector.

   if (nnls.info() == ComputationInfo::Success) {
     verify_nnls_optimality(A, b, x, tolerance);
   }
 }

 static void test_nnls_handles_wide_matrix() {
   //
   // SETUP
   //
   const Index cols = internal::random<Index>(2, EIGEN_TEST_MAX_SIZE);
   const Index rows = internal::random<Index>(2, cols - 1);
   const MatrixXd A = MatrixXd::Random(rows, cols);
   const VectorXd b = VectorXd::Random(rows);

   //
   // ACT
   //
   const double tolerance = 1e-8;
   NNLS<MatrixXd> nnls(A);
   const VectorXd &x = nnls.solve(b);

   //
   // VERIFY
   //
   // What should happen when the input 'A' is wide?
   // The unconstrained least-squares problem has infinitely many solutions.
   // Subject the the non-negativity constraints,
   // the solution might actually be unique (e.g. it is [0,0,..,0]).
   // So, NNLS might succeed or it might fail.
   // Either outcome is fine. If Success is indicated,
   // then 'x' must actually be a solution vector.

   if (nnls.info() == ComputationInfo::Success) {
     verify_nnls_optimality(A, b, x, tolerance);
   }
 }

 // 4x2 problem, unconstrained solution positive
 static void test_nnls_known_1() {
   Matrix<double, 4, 2> A(4, 2);
   Matrix<double, 4, 1> b(4);
   Matrix<double, 2, 1> x(2);
   A << 1, 1, 2, 4, 3, 9, 4, 16;
   b << 0.6, 2.2, 4.8, 8.4;
   x << 0.1, 0.5;

   return test_nnls_known_solution(A, b, x);
 }

 // 4x3 problem, unconstrained solution positive
 static void test_nnls_known_2() {
   Matrix<double, 4, 3> A(4, 3);
   Matrix<double, 4, 1> b(4);
   Matrix<double, 3, 1> x(3);

   A << 1, 1, 1, 2, 4, 8, 3, 9, 27, 4, 16, 64;
   b << 0.73, 3.24, 8.31, 16.72;
   x << 0.1, 0.5, 0.13;

   test_nnls_known_solution(A, b, x);
 }

 // Simple 4x4 problem, unconstrained solution non-negative
 static void test_nnls_known_3() {
   Matrix<double, 4, 4> A(4, 4);
   Matrix<double, 4, 1> b(4);
   Matrix<double, 4, 1> x(4);

   A << 1, 1, 1, 1, 2, 4, 8, 16, 3, 9, 27, 81, 4, 16, 64, 256;
   b << 0.73, 3.24, 8.31, 16.72;
   x << 0.1, 0.5, 0.13, 0;

   test_nnls_known_solution(A, b, x);
 }

 // Simple 4x3 problem, unconstrained solution non-negative
 static void test_nnls_known_4() {
   Matrix<double, 4, 3> A(4, 3);
   Matrix<double, 4, 1> b(4);
   Matrix<double, 3, 1> x(3);

   A << 1, 1, 1, 2, 4, 8, 3, 9, 27, 4, 16, 64;
   b << 0.23, 1.24, 3.81, 8.72;
   x << 0.1, 0, 0.13;

   test_nnls_known_solution(A, b, x);
 }

 // Simple 4x3 problem, unconstrained solution indefinite
 static void test_nnls_known_5() {
   Matrix<double, 4, 3> A(4, 3);
   Matrix<double, 4, 1> b(4);
   Matrix<double, 3, 1> x(3);

   A << 1, 1, 1, 2, 4, 8, 3, 9, 27, 4, 16, 64;
   b << 0.13, 0.84, 2.91, 7.12;
   // Solution obtained by original nnls() implementation in Fortran
   x << 0.0, 0.0, 0.1106544;

   test_nnls_known_solution(A, b, x);
 }

 static void test_nnls_small_reference_problems() {
   test_nnls_known_1();
   test_nnls_known_2();
   test_nnls_known_3();
   test_nnls_known_4();
   test_nnls_known_5();
 }

 static void test_nnls_with_half_precision() {
   // The random matrix generation tools don't work with `half`,
   // so here's a simpler setup mostly just to check that NNLS compiles & runs with custom scalar types.

   using Mat = Matrix<half, 8, 2>;
   using VecB = Matrix<half, 8, 1>;
   using VecX = Matrix<half, 2, 1>;
   Mat A = Mat::Random();  // full-column rank with high probability.
   VecB b = VecB::Random();

   NNLS<Mat> nnls(A, 20, half(1e-2f));
   const VecX x = nnls.solve(b);

   VERIFY_IS_EQUAL(nnls.info(), ComputationInfo::Success);
   verify_nnls_optimality(A, b, x, half(1e-1));
 }

 static void test_nnls_special_case_solves_in_zero_iterations() {
   // The particular NNLS algorithm that is implemented starts with all variables
   // in the active set.
   // This test builds a system where all constraints are active at the solution,
   // so that initial guess is already correct.
   //
   // If the implementation changes to another algorithm that does not have this property,
   // then this test will need to change (e.g. starting from all constraints inactive,
   // or using ADMM, or an interior point solver).

   const Index n = 10;
   const Index m = 3 * n;
   const VectorXd b = VectorXd::Random(m);
   // With high probability, this is full column rank, which we need for uniqueness.
   MatrixXd A = MatrixXd::Random(m, n);
   // Make every column of `A` such that adding it to the active set only /increases/ the objective,
   // this ensuring the NNLS solution is all zeros.
   const VectorXd alignment = -(A.transpose() * b).cwiseSign();
   A = A * alignment.asDiagonal();

   NNLS<MatrixXd> nnls(A);
   nnls.solve(b);

   VERIFY_IS_EQUAL(nnls.info(), ComputationInfo::Success);
   VERIFY(nnls.iterations() == 0);
 }

 static void test_nnls_special_case_solves_in_n_iterations() {
   // The particular NNLS algorithm that is implemented starts with all variables
   // in the active set and then adds one variable to the inactive set each iteration.
   // This test builds a system where all variables are inactive at the solution,
   // so it should take 'n' iterations to get there.
   //
   // If the implementation changes to another algorithm that does not have this property,
   // then this test will need to change (e.g. starting from all constraints inactive,
   // or using ADMM, or an interior point solver).

   const Index n = 10;
   const Index m = 3 * n;
   // With high probability, this is full column rank, which we need for uniqueness.
   const MatrixXd A = MatrixXd::Random(m, n);
   const VectorXd x = VectorXd::Random(n).cwiseAbs().array() + 1;  // all positive.
   const VectorXd b = A * x;

   NNLS<MatrixXd> nnls(A);
   nnls.solve(b);

   VERIFY_IS_EQUAL(nnls.info(), ComputationInfo::Success);
   VERIFY(nnls.iterations() == n);
 }

 static void test_nnls_returns_NoConvergence_when_maxIterations_is_too_low() {
   // Using the special case that takes `n` iterations,
   // from `test_nnls_special_case_solves_in_n_iterations`,
   // we can set max iterations too low and that should cause the solve to fail.

   const Index n = 10;
   const Index m = 3 * n;
   // With high probability, this is full column rank, which we need for uniqueness.
   const MatrixXd A = MatrixXd::Random(m, n);
   const VectorXd x = VectorXd::Random(n).cwiseAbs().array() + 1;  // all positive.
   const VectorXd b = A * x;

   NNLS<MatrixXd> nnls(A);
   const Index max_iters = n - 1;
   nnls.setMaxIterations(max_iters);
   nnls.solve(b);

   VERIFY_IS_EQUAL(nnls.info(), ComputationInfo::NoConvergence);
   VERIFY(nnls.iterations() == max_iters);
 }

 static void test_nnls_default_maxIterations_is_twice_column_count() {
   const Index cols = internal::random<Index>(1, EIGEN_TEST_MAX_SIZE);
   const Index rows = internal::random<Index>(cols, EIGEN_TEST_MAX_SIZE);
   const MatrixXd A = MatrixXd::Random(rows, cols);

   NNLS<MatrixXd> nnls(A);

   VERIFY_IS_EQUAL(nnls.maxIterations(), 2 * cols);
 }

 static void test_nnls_does_not_allocate_during_solve() {
   const Index cols = internal::random<Index>(1, EIGEN_TEST_MAX_SIZE);
   const Index rows = internal::random<Index>(cols, EIGEN_TEST_MAX_SIZE);
   const MatrixXd A = MatrixXd::Random(rows, cols);
   const VectorXd b = VectorXd::Random(rows);

   NNLS<MatrixXd> nnls(A);

   internal::set_is_malloc_allowed(false);
   nnls.solve(b);
   internal::set_is_malloc_allowed(true);
 }

 static void test_nnls_repeated_calls_to_compute_and_solve() {
   const Index cols2 = internal::random<Index>(1, EIGEN_TEST_MAX_SIZE);
   const Index rows2 = internal::random<Index>(cols2, EIGEN_TEST_MAX_SIZE);
   const MatrixXd A2 = MatrixXd::Random(rows2, cols2);
   const VectorXd b2 = VectorXd::Random(rows2);

   NNLS<MatrixXd> nnls;

   for (int i = 0; i < 4; ++i) {
     const Index cols = internal::random<Index>(1, EIGEN_TEST_MAX_SIZE);
     const Index rows = internal::random<Index>(cols, EIGEN_TEST_MAX_SIZE);
     const MatrixXd A = MatrixXd::Random(rows, cols);

     nnls.compute(A);
     VERIFY_IS_EQUAL(nnls.info(), ComputationInfo::Success);

     for (int j = 0; j < 3; ++j) {
       const VectorXd b = VectorXd::Random(rows);
       const VectorXd x = nnls.solve(b);
       VERIFY_IS_EQUAL(nnls.info(), ComputationInfo::Success);
       verify_nnls_optimality(A, b, x, 1e-4);
     }
   }
 }

 EIGEN_DECLARE_TEST(NNLS) {
   // Small matrices with known solutions:
   CALL_SUBTEST_1(test_nnls_small_reference_problems());
   CALL_SUBTEST_1(test_nnls_handles_Mx0_matrix());
   CALL_SUBTEST_1(test_nnls_handles_0x0_matrix());

   for (int i = 0; i < g_repeat; i++) {
     // Essential NNLS properties, across different types.
     CALL_SUBTEST_2(test_nnls_random_problem<MatrixXf>());
     CALL_SUBTEST_3(test_nnls_random_problem<MatrixXd>());
     using MatFixed = Matrix<double, 12, 5>;
     CALL_SUBTEST_4(test_nnls_random_problem<MatFixed>());
     CALL_SUBTEST_5(test_nnls_with_half_precision());

     // Robustness tests:
     CALL_SUBTEST_6(test_nnls_handles_zero_rhs());
     CALL_SUBTEST_6(test_nnls_handles_dependent_columns());
     CALL_SUBTEST_6(test_nnls_handles_wide_matrix());

     // Properties specific to the implementation,
     // not NNLS in general.
     CALL_SUBTEST_7(test_nnls_special_case_solves_in_zero_iterations());
     CALL_SUBTEST_7(test_nnls_special_case_solves_in_n_iterations());
     CALL_SUBTEST_7(test_nnls_returns_NoConvergence_when_maxIterations_is_too_low());
     CALL_SUBTEST_7(test_nnls_default_maxIterations_is_twice_column_count());
     CALL_SUBTEST_8(test_nnls_repeated_calls_to_compute_and_solve());

     // This test fails. It hits allocations in HouseholderSequence.h
     // test_nnls_does_not_allocate_during_solve();
   }
 }
	// This file is part of Eigen, a lightweight C++ template library
	// for linear algebra.
	//
	// Copyright (C) Essex Edwards <essex.edwards@gmail.com>
	//
	// 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/.

	#define EIGEN_RUNTIME_NO_MALLOC

	#include "main.h"
	#include <unsupported/Eigen/NNLS>

	/// Check that 'x' solves the NNLS optimization problem `min \|\|A*x-b\|\| s.t. 0 <= x`.
	/// The \p tolerance parameter is the absolute tolerance on the gradient, A'(Ax-b).
	template <typename MatrixType, typename VectorB, typename VectorX, typename Scalar>
	static void verify_nnls_optimality(const MatrixType &A, const VectorB &b, const VectorX &x, const Scalar tolerance) {
	// The NNLS optimality conditions are:
	//
	// * 0 = A'Ax - A'*b - lambda
	// * 0 <= x[i] \forall i
	// * 0 <= lambda[i] \forall i
	// * 0 = x[i]*lambda[i] \forall i
	//
	// we don't know lambda, but by assuming the first optimality condition is true,
	// we can derive it and then check the others conditions.
	const VectorX lambda = A.transpose() * (A * x - b);

	// NNLS solutions are EXACTLY not negative.
	VERIFY_LE(0, x.minCoeff());

	// Exact lambda would be non-negative, but computed lambda might leak a little
	VERIFY_LE(-tolerance, lambda.minCoeff());

	// x[i]*lambda[i] == 0 <~~> (x[i]==0) \|\| (lambda[i] is small)
	VERIFY(((x.array() == Scalar(0)) \|\| (lambda.array() <= tolerance)).all());
	}

	template <typename MatrixType, typename VectorB, typename VectorX>
	static void test_nnls_known_solution(const MatrixType &A, const VectorB &b, const VectorX &x_expected) {
	using Scalar = typename MatrixType::Scalar;

	using std::sqrt;
	const Scalar tolerance = sqrt(Eigen::GenericNumTraits<Scalar>::epsilon());
	Index max_iter = 5 * A.cols(); // A heuristic guess.
	NNLS<MatrixType> nnls(A, max_iter, tolerance);
	const VectorX x = nnls.solve(b);

	VERIFY_IS_EQUAL(nnls.info(), ComputationInfo::Success);
	VERIFY_IS_APPROX(x, x_expected);
	verify_nnls_optimality(A, b, x, tolerance);
	}

	template <typename MatrixType>
	static void test_nnls_random_problem() {
	//
	// SETUP
	//

	Index cols = MatrixType::ColsAtCompileTime;
	if (cols == Dynamic) cols = internal::random<Index>(1, EIGEN_TEST_MAX_SIZE);
	Index rows = MatrixType::RowsAtCompileTime;
	if (rows == Dynamic) rows = internal::random<Index>(cols, EIGEN_TEST_MAX_SIZE);
	VERIFY_LE(cols, rows); // To have a unique LS solution: cols <= rows.

	// Make some sort of random test problem from a wide range of scales and condition numbers.
	using std::pow;
	using Scalar = typename MatrixType::Scalar;
	const Scalar sqrtConditionNumber = pow(Scalar(10), internal::random<Scalar>(Scalar(0), Scalar(2)));
	const Scalar scaleA = pow(Scalar(10), internal::random<Scalar>(Scalar(-3), Scalar(3)));
	const Scalar minSingularValue = scaleA / sqrtConditionNumber;
	const Scalar maxSingularValue = scaleA * sqrtConditionNumber;
	MatrixType A(rows, cols);
	generateRandomMatrixSvs(setupRangeSvs<Matrix<Scalar, Dynamic, 1>>(cols, minSingularValue, maxSingularValue), rows,
	cols, A);

	// Make a random RHS also with a random scaling.
	using VectorB = decltype(A.col(0).eval());
	const Scalar scaleB = pow(Scalar(10), internal::random<Scalar>(Scalar(-3), Scalar(3)));
	const VectorB b = scaleB * VectorB::Random(A.rows());

	//
	// ACT
	//

	using Scalar = typename MatrixType::Scalar;
	using std::sqrt;
	const Scalar tolerance =
	sqrt(Eigen::GenericNumTraits<Scalar>::epsilon()) * b.cwiseAbs().maxCoeff() * A.cwiseAbs().maxCoeff();
	Index max_iter = 5 * A.cols(); // A heuristic guess.
	NNLS<MatrixType> nnls(A, max_iter, tolerance);
	const typename NNLS<MatrixType>::SolutionVectorType &x = nnls.solve(b);

	//
	// VERIFY
	//

	// In fact, NNLS can fail on some problems, but they are rare in practice.
	VERIFY_IS_EQUAL(nnls.info(), ComputationInfo::Success);
	verify_nnls_optimality(A, b, x, tolerance);
	}

	static void test_nnls_handles_zero_rhs() {
	//
	// SETUP
	//
	const Index cols = internal::random<Index>(1, EIGEN_TEST_MAX_SIZE);
	const Index rows = internal::random<Index>(cols, EIGEN_TEST_MAX_SIZE);
	const MatrixXd A = MatrixXd::Random(rows, cols);
	const VectorXd b = VectorXd::Zero(rows);

	//
	// ACT
	//
	NNLS<MatrixXd> nnls(A);
	const VectorXd x = nnls.solve(b);

	//
	// VERIFY
	//
	VERIFY_IS_EQUAL(nnls.info(), ComputationInfo::Success);
	VERIFY_LE(nnls.iterations(), 1); // 0 or 1 would be be fine for an edge case like this.
	VERIFY_IS_EQUAL(x, VectorXd::Zero(cols));
	}

	static void test_nnls_handles_Mx0_matrix() {
	//
	// SETUP
	//
	const Index rows = internal::random<Index>(1, EIGEN_TEST_MAX_SIZE);
	const MatrixXd A(rows, 0);
	const VectorXd b = VectorXd::Random(rows);

	//
	// ACT
	//
	NNLS<MatrixXd> nnls(A);
	const VectorXd x = nnls.solve(b);

	//
	// VERIFY
	//
	VERIFY_IS_EQUAL(nnls.info(), ComputationInfo::Success);
	VERIFY_LE(nnls.iterations(), 0);
	VERIFY_IS_EQUAL(x.size(), 0);
	}

	static void test_nnls_handles_0x0_matrix() {
	//
	// SETUP
	//
	const MatrixXd A(0, 0);
	const VectorXd b(0);

	//
	// ACT
	//
	NNLS<MatrixXd> nnls(A);
	const VectorXd x = nnls.solve(b);

	//
	// VERIFY
	//
	VERIFY_IS_EQUAL(nnls.info(), ComputationInfo::Success);
	VERIFY_LE(nnls.iterations(), 0);
	VERIFY_IS_EQUAL(x.size(), 0);
	}

	static void test_nnls_handles_dependent_columns() {
	//
	// SETUP
	//
	const Index rank = internal::random<Index>(1, EIGEN_TEST_MAX_SIZE / 2);
	const Index cols = 2 * rank;
	const Index rows = internal::random<Index>(cols, EIGEN_TEST_MAX_SIZE);
	const MatrixXd A = MatrixXd::Random(rows, rank) * MatrixXd::Random(rank, cols);
	const VectorXd b = VectorXd::Random(rows);

	//
	// ACT
	//
	const double tolerance = 1e-8;
	NNLS<MatrixXd> nnls(A);
	const VectorXd &x = nnls.solve(b);

	//
	// VERIFY
	//
	// What should happen when the input 'A' has dependent columns?
	// We might still succeed. Or we might not converge.
	// Either outcome is fine. If Success is indicated,
	// then 'x' must actually be a solution vector.

	if (nnls.info() == ComputationInfo::Success) {
	verify_nnls_optimality(A, b, x, tolerance);
	}
	}

	static void test_nnls_handles_wide_matrix() {
	//
	// SETUP
	//
	const Index cols = internal::random<Index>(2, EIGEN_TEST_MAX_SIZE);
	const Index rows = internal::random<Index>(2, cols - 1);
	const MatrixXd A = MatrixXd::Random(rows, cols);
	const VectorXd b = VectorXd::Random(rows);

	//
	// ACT
	//
	const double tolerance = 1e-8;
	NNLS<MatrixXd> nnls(A);
	const VectorXd &x = nnls.solve(b);

	//
	// VERIFY
	//
	// What should happen when the input 'A' is wide?
	// The unconstrained least-squares problem has infinitely many solutions.
	// Subject the the non-negativity constraints,
	// the solution might actually be unique (e.g. it is [0,0,..,0]).
	// So, NNLS might succeed or it might fail.
	// Either outcome is fine. If Success is indicated,
	// then 'x' must actually be a solution vector.

	if (nnls.info() == ComputationInfo::Success) {
	verify_nnls_optimality(A, b, x, tolerance);
	}
	}

	// 4x2 problem, unconstrained solution positive
	static void test_nnls_known_1() {
	Matrix<double, 4, 2> A(4, 2);
	Matrix<double, 4, 1> b(4);
	Matrix<double, 2, 1> x(2);
	A << 1, 1, 2, 4, 3, 9, 4, 16;
	b << 0.6, 2.2, 4.8, 8.4;
	x << 0.1, 0.5;

	return test_nnls_known_solution(A, b, x);
	}

	// 4x3 problem, unconstrained solution positive
	static void test_nnls_known_2() {
	Matrix<double, 4, 3> A(4, 3);
	Matrix<double, 4, 1> b(4);
	Matrix<double, 3, 1> x(3);

	A << 1, 1, 1, 2, 4, 8, 3, 9, 27, 4, 16, 64;
	b << 0.73, 3.24, 8.31, 16.72;
	x << 0.1, 0.5, 0.13;

	test_nnls_known_solution(A, b, x);
	}

	// Simple 4x4 problem, unconstrained solution non-negative
	static void test_nnls_known_3() {
	Matrix<double, 4, 4> A(4, 4);
	Matrix<double, 4, 1> b(4);
	Matrix<double, 4, 1> x(4);

	A << 1, 1, 1, 1, 2, 4, 8, 16, 3, 9, 27, 81, 4, 16, 64, 256;
	b << 0.73, 3.24, 8.31, 16.72;
	x << 0.1, 0.5, 0.13, 0;

	test_nnls_known_solution(A, b, x);
	}

	// Simple 4x3 problem, unconstrained solution non-negative
	static void test_nnls_known_4() {
	Matrix<double, 4, 3> A(4, 3);
	Matrix<double, 4, 1> b(4);
	Matrix<double, 3, 1> x(3);

	A << 1, 1, 1, 2, 4, 8, 3, 9, 27, 4, 16, 64;
	b << 0.23, 1.24, 3.81, 8.72;
	x << 0.1, 0, 0.13;

	test_nnls_known_solution(A, b, x);
	}

	// Simple 4x3 problem, unconstrained solution indefinite
	static void test_nnls_known_5() {
	Matrix<double, 4, 3> A(4, 3);
	Matrix<double, 4, 1> b(4);
	Matrix<double, 3, 1> x(3);

	A << 1, 1, 1, 2, 4, 8, 3, 9, 27, 4, 16, 64;
	b << 0.13, 0.84, 2.91, 7.12;
	// Solution obtained by original nnls() implementation in Fortran
	x << 0.0, 0.0, 0.1106544;

	test_nnls_known_solution(A, b, x);
	}

	static void test_nnls_small_reference_problems() {
	test_nnls_known_1();
	test_nnls_known_2();
	test_nnls_known_3();
	test_nnls_known_4();
	test_nnls_known_5();
	}

	static void test_nnls_with_half_precision() {
	// The random matrix generation tools don't work with `half`,
	// so here's a simpler setup mostly just to check that NNLS compiles & runs with custom scalar types.

	using Mat = Matrix<half, 8, 2>;
	using VecB = Matrix<half, 8, 1>;
	using VecX = Matrix<half, 2, 1>;
	Mat A = Mat::Random(); // full-column rank with high probability.
	VecB b = VecB::Random();

	NNLS<Mat> nnls(A, 20, half(1e-2f));
	const VecX x = nnls.solve(b);

	VERIFY_IS_EQUAL(nnls.info(), ComputationInfo::Success);
	verify_nnls_optimality(A, b, x, half(1e-1));
	}

	static void test_nnls_special_case_solves_in_zero_iterations() {
	// The particular NNLS algorithm that is implemented starts with all variables
	// in the active set.
	// This test builds a system where all constraints are active at the solution,
	// so that initial guess is already correct.
	//
	// If the implementation changes to another algorithm that does not have this property,
	// then this test will need to change (e.g. starting from all constraints inactive,
	// or using ADMM, or an interior point solver).

	const Index n = 10;
	const Index m = 3 * n;
	const VectorXd b = VectorXd::Random(m);
	// With high probability, this is full column rank, which we need for uniqueness.
	MatrixXd A = MatrixXd::Random(m, n);
	// Make every column of `A` such that adding it to the active set only /increases/ the objective,
	// this ensuring the NNLS solution is all zeros.
	const VectorXd alignment = -(A.transpose() * b).cwiseSign();
	A = A * alignment.asDiagonal();

	NNLS<MatrixXd> nnls(A);
	nnls.solve(b);

	VERIFY_IS_EQUAL(nnls.info(), ComputationInfo::Success);
	VERIFY(nnls.iterations() == 0);
	}

	static void test_nnls_special_case_solves_in_n_iterations() {
	// The particular NNLS algorithm that is implemented starts with all variables
	// in the active set and then adds one variable to the inactive set each iteration.
	// This test builds a system where all variables are inactive at the solution,
	// so it should take 'n' iterations to get there.
	//
	// If the implementation changes to another algorithm that does not have this property,
	// then this test will need to change (e.g. starting from all constraints inactive,
	// or using ADMM, or an interior point solver).

	const Index n = 10;
	const Index m = 3 * n;
	// With high probability, this is full column rank, which we need for uniqueness.
	const MatrixXd A = MatrixXd::Random(m, n);
	const VectorXd x = VectorXd::Random(n).cwiseAbs().array() + 1; // all positive.
	const VectorXd b = A * x;

	NNLS<MatrixXd> nnls(A);
	nnls.solve(b);

	VERIFY_IS_EQUAL(nnls.info(), ComputationInfo::Success);
	VERIFY(nnls.iterations() == n);
	}

	static void test_nnls_returns_NoConvergence_when_maxIterations_is_too_low() {
	// Using the special case that takes `n` iterations,
	// from `test_nnls_special_case_solves_in_n_iterations`,
	// we can set max iterations too low and that should cause the solve to fail.

	const Index n = 10;
	const Index m = 3 * n;
	// With high probability, this is full column rank, which we need for uniqueness.
	const MatrixXd A = MatrixXd::Random(m, n);
	const VectorXd x = VectorXd::Random(n).cwiseAbs().array() + 1; // all positive.
	const VectorXd b = A * x;

	NNLS<MatrixXd> nnls(A);
	const Index max_iters = n - 1;
	nnls.setMaxIterations(max_iters);
	nnls.solve(b);

	VERIFY_IS_EQUAL(nnls.info(), ComputationInfo::NoConvergence);
	VERIFY(nnls.iterations() == max_iters);
	}

	static void test_nnls_default_maxIterations_is_twice_column_count() {
	const Index cols = internal::random<Index>(1, EIGEN_TEST_MAX_SIZE);
	const Index rows = internal::random<Index>(cols, EIGEN_TEST_MAX_SIZE);
	const MatrixXd A = MatrixXd::Random(rows, cols);

	NNLS<MatrixXd> nnls(A);

	VERIFY_IS_EQUAL(nnls.maxIterations(), 2 * cols);
	}

	static void test_nnls_does_not_allocate_during_solve() {
	const Index cols = internal::random<Index>(1, EIGEN_TEST_MAX_SIZE);
	const Index rows = internal::random<Index>(cols, EIGEN_TEST_MAX_SIZE);
	const MatrixXd A = MatrixXd::Random(rows, cols);
	const VectorXd b = VectorXd::Random(rows);

	NNLS<MatrixXd> nnls(A);

	internal::set_is_malloc_allowed(false);
	nnls.solve(b);
	internal::set_is_malloc_allowed(true);
	}

	static void test_nnls_repeated_calls_to_compute_and_solve() {
	const Index cols2 = internal::random<Index>(1, EIGEN_TEST_MAX_SIZE);
	const Index rows2 = internal::random<Index>(cols2, EIGEN_TEST_MAX_SIZE);
	const MatrixXd A2 = MatrixXd::Random(rows2, cols2);
	const VectorXd b2 = VectorXd::Random(rows2);

	NNLS<MatrixXd> nnls;

	for (int i = 0; i < 4; ++i) {
	const Index cols = internal::random<Index>(1, EIGEN_TEST_MAX_SIZE);
	const Index rows = internal::random<Index>(cols, EIGEN_TEST_MAX_SIZE);
	const MatrixXd A = MatrixXd::Random(rows, cols);

	nnls.compute(A);
	VERIFY_IS_EQUAL(nnls.info(), ComputationInfo::Success);

	for (int j = 0; j < 3; ++j) {
	const VectorXd b = VectorXd::Random(rows);
	const VectorXd x = nnls.solve(b);
	VERIFY_IS_EQUAL(nnls.info(), ComputationInfo::Success);
	verify_nnls_optimality(A, b, x, 1e-4);
	}
	}
	}

	EIGEN_DECLARE_TEST(NNLS) {
	// Small matrices with known solutions:
	CALL_SUBTEST_1(test_nnls_small_reference_problems());
	CALL_SUBTEST_1(test_nnls_handles_Mx0_matrix());
	CALL_SUBTEST_1(test_nnls_handles_0x0_matrix());

	for (int i = 0; i < g_repeat; i++) {
	// Essential NNLS properties, across different types.
	CALL_SUBTEST_2(test_nnls_random_problem<MatrixXf>());
	CALL_SUBTEST_3(test_nnls_random_problem<MatrixXd>());
	using MatFixed = Matrix<double, 12, 5>;
	CALL_SUBTEST_4(test_nnls_random_problem<MatFixed>());
	CALL_SUBTEST_5(test_nnls_with_half_precision());

	// Robustness tests:
	CALL_SUBTEST_6(test_nnls_handles_zero_rhs());
	CALL_SUBTEST_6(test_nnls_handles_dependent_columns());
	CALL_SUBTEST_6(test_nnls_handles_wide_matrix());

	// Properties specific to the implementation,
	// not NNLS in general.
	CALL_SUBTEST_7(test_nnls_special_case_solves_in_zero_iterations());
	CALL_SUBTEST_7(test_nnls_special_case_solves_in_n_iterations());
	CALL_SUBTEST_7(test_nnls_returns_NoConvergence_when_maxIterations_is_too_low());
	CALL_SUBTEST_7(test_nnls_default_maxIterations_is_twice_column_count());
	CALL_SUBTEST_8(test_nnls_repeated_calls_to_compute_and_solve());

	// This test fails. It hits allocations in HouseholderSequence.h
	// test_nnls_does_not_allocate_during_solve();
	}
	}