unsupported/doc/examples/PolynomialSolver1.cpp - eigen - Git at Google

 #include <unsupported/Eigen/Polynomials>
 #include <vector>
 #include <iostream>

 using namespace Eigen;
 using namespace std;

 int main() {
   typedef Matrix<double, 5, 1> Vector5d;

   Vector5d roots = Vector5d::Random();
   cout << "Roots: " << roots.transpose() << endl;
   Eigen::Matrix<double, 6, 1> polynomial;
   roots_to_monicPolynomial(roots, polynomial);

   PolynomialSolver<double, 5> psolve(polynomial);
   cout << "Complex roots: " << psolve.roots().transpose() << endl;

   std::vector<double> realRoots;
   psolve.realRoots(realRoots);
   Map<Vector5d> mapRR(&realRoots[0]);
   cout << "Real roots: " << mapRR.transpose() << endl;

   cout << endl;
   cout << "Illustration of the convergence problem with the QR algorithm: " << endl;
   cout << "---------------------------------------------------------------" << endl;
   Eigen::Matrix<float, 7, 1> hardCase_polynomial;
   hardCase_polynomial << -0.957, 0.9219, 0.3516, 0.9453, -0.4023, -0.5508, -0.03125;
   cout << "Hard case polynomial defined by floats: " << hardCase_polynomial.transpose() << endl;
   PolynomialSolver<float, 6> psolvef(hardCase_polynomial);
   cout << "Complex roots: " << psolvef.roots().transpose() << endl;
   Eigen::Matrix<float, 6, 1> evals;
   for (int i = 0; i < 6; ++i) {
     evals[i] = std::abs(poly_eval(hardCase_polynomial, psolvef.roots()[i]));
   }
   cout << "Norms of the evaluations of the polynomial at the roots: " << evals.transpose() << endl << endl;

   cout << "Using double's almost always solves the problem for small degrees: " << endl;
   cout << "-------------------------------------------------------------------" << endl;
   PolynomialSolver<double, 6> psolve6d(hardCase_polynomial.cast<double>());
   cout << "Complex roots: " << psolve6d.roots().transpose() << endl;
   for (int i = 0; i < 6; ++i) {
     std::complex<float> castedRoot(psolve6d.roots()[i].real(), psolve6d.roots()[i].imag());
     evals[i] = std::abs(poly_eval(hardCase_polynomial, castedRoot));
   }
   cout << "Norms of the evaluations of the polynomial at the roots: " << evals.transpose() << endl << endl;

   cout.precision(10);
   cout << "The last root in float then in double: " << psolvef.roots()[5] << "\t" << psolve6d.roots()[5] << endl;
   std::complex<float> castedRoot(psolve6d.roots()[5].real(), psolve6d.roots()[5].imag());
   cout << "Norm of the difference: " << std::abs(psolvef.roots()[5] - castedRoot) << endl;
 }
	#include <unsupported/Eigen/Polynomials>
	#include <vector>
	#include <iostream>

	using namespace Eigen;
	using namespace std;

	int main() {
	typedef Matrix<double, 5, 1> Vector5d;

	Vector5d roots = Vector5d::Random();
	cout << "Roots: " << roots.transpose() << endl;
	Eigen::Matrix<double, 6, 1> polynomial;
	roots_to_monicPolynomial(roots, polynomial);

	PolynomialSolver<double, 5> psolve(polynomial);
	cout << "Complex roots: " << psolve.roots().transpose() << endl;

	std::vector<double> realRoots;
	psolve.realRoots(realRoots);
	Map<Vector5d> mapRR(&realRoots[0]);
	cout << "Real roots: " << mapRR.transpose() << endl;

	cout << endl;
	cout << "Illustration of the convergence problem with the QR algorithm: " << endl;
	cout << "---------------------------------------------------------------" << endl;
	Eigen::Matrix<float, 7, 1> hardCase_polynomial;
	hardCase_polynomial << -0.957, 0.9219, 0.3516, 0.9453, -0.4023, -0.5508, -0.03125;
	cout << "Hard case polynomial defined by floats: " << hardCase_polynomial.transpose() << endl;
	PolynomialSolver<float, 6> psolvef(hardCase_polynomial);
	cout << "Complex roots: " << psolvef.roots().transpose() << endl;
	Eigen::Matrix<float, 6, 1> evals;
	for (int i = 0; i < 6; ++i) {
	evals[i] = std::abs(poly_eval(hardCase_polynomial, psolvef.roots()[i]));
	}
	cout << "Norms of the evaluations of the polynomial at the roots: " << evals.transpose() << endl << endl;

	cout << "Using double's almost always solves the problem for small degrees: " << endl;
	cout << "-------------------------------------------------------------------" << endl;
	PolynomialSolver<double, 6> psolve6d(hardCase_polynomial.cast<double>());
	cout << "Complex roots: " << psolve6d.roots().transpose() << endl;
	for (int i = 0; i < 6; ++i) {
	std::complex<float> castedRoot(psolve6d.roots()[i].real(), psolve6d.roots()[i].imag());
	evals[i] = std::abs(poly_eval(hardCase_polynomial, castedRoot));
	}
	cout << "Norms of the evaluations of the polynomial at the roots: " << evals.transpose() << endl << endl;

	cout.precision(10);
	cout << "The last root in float then in double: " << psolvef.roots()[5] << "\t" << psolve6d.roots()[5] << endl;
	std::complex<float> castedRoot(psolve6d.roots()[5].real(), psolve6d.roots()[5].imag());
	cout << "Norm of the difference: " << std::abs(psolvef.roots()[5] - castedRoot) << endl;
	}