unsupported/test/splines.cpp - mirror - Git at Google

 // This file is part of Eigen, a lightweight C++ template library
 // for linear algebra.
 //
 // Copyright (C) 2010-2011 Hauke Heibel <heibel@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/.

 #include "main.h"

 #include <unsupported/Eigen/Splines>

 namespace Eigen {

 // lets do some explicit instantiations and thus
 // force the compilation of all spline functions...
 template class Spline<double, 2, Dynamic>;
 template class Spline<double, 3, Dynamic>;

 template class Spline<double, 2, 2>;
 template class Spline<double, 2, 3>;
 template class Spline<double, 2, 4>;
 template class Spline<double, 2, 5>;

 template class Spline<float, 2, Dynamic>;
 template class Spline<float, 3, Dynamic>;

 template class Spline<float, 3, 2>;
 template class Spline<float, 3, 3>;
 template class Spline<float, 3, 4>;
 template class Spline<float, 3, 5>;

 }  // namespace Eigen

 Spline<double, 2, Dynamic> closed_spline2d() {
   RowVectorXd knots(12);
   knots << 0, 0, 0, 0, 0.867193179093898, 1.660330955342408, 2.605084834823134, 3.484154586374428, 4.252699478956276,
       4.252699478956276, 4.252699478956276, 4.252699478956276;

   MatrixXd ctrls(8, 2);
   ctrls << -0.370967741935484, 0.236842105263158, -0.231401860693277, 0.442245185027632, 0.344361228532831,
       0.773369994120753, 0.828990216203802, 0.106550882647595, 0.407270163678382, -1.043452922172848,
       -0.488467813584053, -0.390098582530090, -0.494657189446427, 0.054804824897884, -0.370967741935484,
       0.236842105263158;
   ctrls.transposeInPlace();

   return Spline<double, 2, Dynamic>(knots, ctrls);
 }

 /* create a reference spline */
 Spline<double, 3, Dynamic> spline3d() {
   RowVectorXd knots(11);
   knots << 0, 0, 0, 0.118997681558377, 0.162611735194631, 0.498364051982143, 0.655098003973841, 0.679702676853675,
       1.000000000000000, 1.000000000000000, 1.000000000000000;

   MatrixXd ctrls(8, 3);
   ctrls << 0.959743958516081, 0.340385726666133, 0.585267750979777, 0.223811939491137, 0.751267059305653,
       0.255095115459269, 0.505957051665142, 0.699076722656686, 0.890903252535799, 0.959291425205444, 0.547215529963803,
       0.138624442828679, 0.149294005559057, 0.257508254123736, 0.840717255983663, 0.254282178971531, 0.814284826068816,
       0.243524968724989, 0.929263623187228, 0.349983765984809, 0.196595250431208, 0.251083857976031, 0.616044676146639,
       0.473288848902729;
   ctrls.transposeInPlace();

   return Spline<double, 3, Dynamic>(knots, ctrls);
 }

 /* compares evaluations against known results */
 void eval_spline3d() {
   Spline3d spline = spline3d();

   RowVectorXd u(10);
   u << 0.351659507062997, 0.830828627896291, 0.585264091152724, 0.549723608291140, 0.917193663829810, 0.285839018820374,
       0.757200229110721, 0.753729094278495, 0.380445846975357, 0.567821640725221;

   MatrixXd pts(10, 3);
   pts << 0.707620811535916, 0.510258911240815, 0.417485437023409, 0.603422256426978, 0.529498282727551,
       0.270351549348981, 0.228364197569334, 0.423745615677815, 0.637687289287490, 0.275556796335168, 0.350856706427970,
       0.684295784598905, 0.514519311047655, 0.525077224890754, 0.351628308305896, 0.724152914315666, 0.574461155457304,
       0.469860285484058, 0.529365063753288, 0.613328702656816, 0.237837040141739, 0.522469395136878, 0.619099658652895,
       0.237139665242069, 0.677357023849552, 0.480655768435853, 0.422227610314397, 0.247046593173758, 0.380604672404750,
       0.670065791405019;
   pts.transposeInPlace();

   for (int i = 0; i < u.size(); ++i) {
     Vector3d pt = spline(u(i));
     VERIFY((pt - pts.col(i)).norm() < 1e-14);
   }
 }

 /* compares evaluations on corner cases */
 void eval_spline3d_onbrks() {
   Spline3d spline = spline3d();

   RowVectorXd u = spline.knots();

   MatrixXd pts(11, 3);
   pts << 0.959743958516081, 0.340385726666133, 0.585267750979777, 0.959743958516081, 0.340385726666133,
       0.585267750979777, 0.959743958516081, 0.340385726666133, 0.585267750979777, 0.430282980289940, 0.713074680056118,
       0.720373307943349, 0.558074875553060, 0.681617921034459, 0.804417124839942, 0.407076008291750, 0.349707710518163,
       0.617275937419545, 0.240037008286602, 0.738739390398014, 0.324554153129411, 0.302434111480572, 0.781162443963899,
       0.240177089094644, 0.251083857976031, 0.616044676146639, 0.473288848902729, 0.251083857976031, 0.616044676146639,
       0.473288848902729, 0.251083857976031, 0.616044676146639, 0.473288848902729;
   pts.transposeInPlace();

   for (int i = 0; i < u.size(); ++i) {
     Vector3d pt = spline(u(i));
     VERIFY((pt - pts.col(i)).norm() < 1e-14);
   }
 }

 void eval_closed_spline2d() {
   Spline2d spline = closed_spline2d();

   RowVectorXd u(12);
   u << 0, 0.332457030395796, 0.356467130532952, 0.453562180176215, 0.648017921874804, 0.973770235555003,
       1.882577647219307, 2.289408593930498, 3.511951429883045, 3.884149321369450, 4.236261590369414, 4.252699478956276;

   MatrixXd pts(12, 2);
   pts << -0.370967741935484, 0.236842105263158, -0.152576775123250, 0.448975001279334, -0.133417538277668,
       0.461615613865667, -0.053199060826740, 0.507630360006299, 0.114249591147281, 0.570414135097409, 0.377810316891987,
       0.560497102875315, 0.665052120135908, -0.157557441109611, 0.516006487053228, -0.559763292174825,
       -0.379486035348887, -0.331959640488223, -0.462034726249078, -0.039105670080824, -0.378730600917982,
       0.225127015099919, -0.370967741935484, 0.236842105263158;
   pts.transposeInPlace();

   for (int i = 0; i < u.size(); ++i) {
     Vector2d pt = spline(u(i));
     VERIFY((pt - pts.col(i)).norm() < 1e-14);
   }
 }

 void check_global_interpolation2d() {
   typedef Spline2d::PointType PointType;
   typedef Spline2d::KnotVectorType KnotVectorType;
   typedef Spline2d::ControlPointVectorType ControlPointVectorType;

   ControlPointVectorType points = ControlPointVectorType::Random(2, 100);

   KnotVectorType chord_lengths;  // knot parameters
   Eigen::ChordLengths(points, chord_lengths);

   // interpolation without knot parameters
   {
     const Spline2d spline = SplineFitting<Spline2d>::Interpolate(points, 3);

     for (Eigen::DenseIndex i = 0; i < points.cols(); ++i) {
       PointType pt = spline(chord_lengths(i));
       PointType ref = points.col(i);
       VERIFY((pt - ref).matrix().norm() < 1e-14);
     }
   }

   // interpolation with given knot parameters
   {
     const Spline2d spline = SplineFitting<Spline2d>::Interpolate(points, 3, chord_lengths);

     for (Eigen::DenseIndex i = 0; i < points.cols(); ++i) {
       PointType pt = spline(chord_lengths(i));
       PointType ref = points.col(i);
       VERIFY((pt - ref).matrix().norm() < 1e-14);
     }
   }
 }

 void check_global_interpolation_with_derivatives2d() {
   typedef Spline2d::PointType PointType;
   typedef Spline2d::KnotVectorType KnotVectorType;

   const Eigen::DenseIndex numPoints = 100;
   const unsigned int dimension = 2;
   const unsigned int degree = 3;

   ArrayXXd points = ArrayXXd::Random(dimension, numPoints);

   KnotVectorType knots;
   Eigen::ChordLengths(points, knots);

   ArrayXXd derivatives = ArrayXXd::Random(dimension, numPoints);
   VectorXd derivativeIndices(numPoints);

   for (Eigen::DenseIndex i = 0; i < numPoints; ++i) derivativeIndices(i) = static_cast<double>(i);

   const Spline2d spline =
       SplineFitting<Spline2d>::InterpolateWithDerivatives(points, derivatives, derivativeIndices, degree);

   for (Eigen::DenseIndex i = 0; i < points.cols(); ++i) {
     PointType point = spline(knots(i));
     PointType referencePoint = points.col(i);
     VERIFY_IS_APPROX(point, referencePoint);
     PointType derivative = spline.derivatives(knots(i), 1).col(1);
     PointType referenceDerivative = derivatives.col(i);
     VERIFY_IS_APPROX(derivative, referenceDerivative);
   }
 }

 EIGEN_DECLARE_TEST(splines) {
   for (int i = 0; i < g_repeat; ++i) {
     CALL_SUBTEST(eval_spline3d());
     CALL_SUBTEST(eval_spline3d_onbrks());
     CALL_SUBTEST(eval_closed_spline2d());
     CALL_SUBTEST(check_global_interpolation2d());
     CALL_SUBTEST(check_global_interpolation_with_derivatives2d());
   }
 }
	// This file is part of Eigen, a lightweight C++ template library
	// for linear algebra.
	//
	// Copyright (C) 2010-2011 Hauke Heibel <heibel@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/.

	#include "main.h"

	#include <unsupported/Eigen/Splines>

	namespace Eigen {

	// lets do some explicit instantiations and thus
	// force the compilation of all spline functions...
	template class Spline<double, 2, Dynamic>;
	template class Spline<double, 3, Dynamic>;

	template class Spline<double, 2, 2>;
	template class Spline<double, 2, 3>;
	template class Spline<double, 2, 4>;
	template class Spline<double, 2, 5>;

	template class Spline<float, 2, Dynamic>;
	template class Spline<float, 3, Dynamic>;

	template class Spline<float, 3, 2>;
	template class Spline<float, 3, 3>;
	template class Spline<float, 3, 4>;
	template class Spline<float, 3, 5>;

	} // namespace Eigen

	Spline<double, 2, Dynamic> closed_spline2d() {
	RowVectorXd knots(12);
	knots << 0, 0, 0, 0, 0.867193179093898, 1.660330955342408, 2.605084834823134, 3.484154586374428, 4.252699478956276,
	4.252699478956276, 4.252699478956276, 4.252699478956276;

	MatrixXd ctrls(8, 2);
	ctrls << -0.370967741935484, 0.236842105263158, -0.231401860693277, 0.442245185027632, 0.344361228532831,
	0.773369994120753, 0.828990216203802, 0.106550882647595, 0.407270163678382, -1.043452922172848,
	-0.488467813584053, -0.390098582530090, -0.494657189446427, 0.054804824897884, -0.370967741935484,
	0.236842105263158;
	ctrls.transposeInPlace();

	return Spline<double, 2, Dynamic>(knots, ctrls);
	}

	/* create a reference spline */
	Spline<double, 3, Dynamic> spline3d() {
	RowVectorXd knots(11);
	knots << 0, 0, 0, 0.118997681558377, 0.162611735194631, 0.498364051982143, 0.655098003973841, 0.679702676853675,
	1.000000000000000, 1.000000000000000, 1.000000000000000;

	MatrixXd ctrls(8, 3);
	ctrls << 0.959743958516081, 0.340385726666133, 0.585267750979777, 0.223811939491137, 0.751267059305653,
	0.255095115459269, 0.505957051665142, 0.699076722656686, 0.890903252535799, 0.959291425205444, 0.547215529963803,
	0.138624442828679, 0.149294005559057, 0.257508254123736, 0.840717255983663, 0.254282178971531, 0.814284826068816,
	0.243524968724989, 0.929263623187228, 0.349983765984809, 0.196595250431208, 0.251083857976031, 0.616044676146639,
	0.473288848902729;
	ctrls.transposeInPlace();

	return Spline<double, 3, Dynamic>(knots, ctrls);
	}

	/* compares evaluations against known results */
	void eval_spline3d() {
	Spline3d spline = spline3d();

	RowVectorXd u(10);
	u << 0.351659507062997, 0.830828627896291, 0.585264091152724, 0.549723608291140, 0.917193663829810, 0.285839018820374,
	0.757200229110721, 0.753729094278495, 0.380445846975357, 0.567821640725221;

	MatrixXd pts(10, 3);
	pts << 0.707620811535916, 0.510258911240815, 0.417485437023409, 0.603422256426978, 0.529498282727551,
	0.270351549348981, 0.228364197569334, 0.423745615677815, 0.637687289287490, 0.275556796335168, 0.350856706427970,
	0.684295784598905, 0.514519311047655, 0.525077224890754, 0.351628308305896, 0.724152914315666, 0.574461155457304,
	0.469860285484058, 0.529365063753288, 0.613328702656816, 0.237837040141739, 0.522469395136878, 0.619099658652895,
	0.237139665242069, 0.677357023849552, 0.480655768435853, 0.422227610314397, 0.247046593173758, 0.380604672404750,
	0.670065791405019;
	pts.transposeInPlace();

	for (int i = 0; i < u.size(); ++i) {
	Vector3d pt = spline(u(i));
	VERIFY((pt - pts.col(i)).norm() < 1e-14);
	}
	}

	/* compares evaluations on corner cases */
	void eval_spline3d_onbrks() {
	Spline3d spline = spline3d();

	RowVectorXd u = spline.knots();

	MatrixXd pts(11, 3);
	pts << 0.959743958516081, 0.340385726666133, 0.585267750979777, 0.959743958516081, 0.340385726666133,
	0.585267750979777, 0.959743958516081, 0.340385726666133, 0.585267750979777, 0.430282980289940, 0.713074680056118,
	0.720373307943349, 0.558074875553060, 0.681617921034459, 0.804417124839942, 0.407076008291750, 0.349707710518163,
	0.617275937419545, 0.240037008286602, 0.738739390398014, 0.324554153129411, 0.302434111480572, 0.781162443963899,
	0.240177089094644, 0.251083857976031, 0.616044676146639, 0.473288848902729, 0.251083857976031, 0.616044676146639,
	0.473288848902729, 0.251083857976031, 0.616044676146639, 0.473288848902729;
	pts.transposeInPlace();

	for (int i = 0; i < u.size(); ++i) {
	Vector3d pt = spline(u(i));
	VERIFY((pt - pts.col(i)).norm() < 1e-14);
	}
	}

	void eval_closed_spline2d() {
	Spline2d spline = closed_spline2d();

	RowVectorXd u(12);
	u << 0, 0.332457030395796, 0.356467130532952, 0.453562180176215, 0.648017921874804, 0.973770235555003,
	1.882577647219307, 2.289408593930498, 3.511951429883045, 3.884149321369450, 4.236261590369414, 4.252699478956276;

	MatrixXd pts(12, 2);
	pts << -0.370967741935484, 0.236842105263158, -0.152576775123250, 0.448975001279334, -0.133417538277668,
	0.461615613865667, -0.053199060826740, 0.507630360006299, 0.114249591147281, 0.570414135097409, 0.377810316891987,
	0.560497102875315, 0.665052120135908, -0.157557441109611, 0.516006487053228, -0.559763292174825,
	-0.379486035348887, -0.331959640488223, -0.462034726249078, -0.039105670080824, -0.378730600917982,
	0.225127015099919, -0.370967741935484, 0.236842105263158;
	pts.transposeInPlace();

	for (int i = 0; i < u.size(); ++i) {
	Vector2d pt = spline(u(i));
	VERIFY((pt - pts.col(i)).norm() < 1e-14);
	}
	}

	void check_global_interpolation2d() {
	typedef Spline2d::PointType PointType;
	typedef Spline2d::KnotVectorType KnotVectorType;
	typedef Spline2d::ControlPointVectorType ControlPointVectorType;

	ControlPointVectorType points = ControlPointVectorType::Random(2, 100);

	KnotVectorType chord_lengths; // knot parameters
	Eigen::ChordLengths(points, chord_lengths);

	// interpolation without knot parameters
	{
	const Spline2d spline = SplineFitting<Spline2d>::Interpolate(points, 3);

	for (Eigen::DenseIndex i = 0; i < points.cols(); ++i) {
	PointType pt = spline(chord_lengths(i));
	PointType ref = points.col(i);
	VERIFY((pt - ref).matrix().norm() < 1e-14);
	}
	}

	// interpolation with given knot parameters
	{
	const Spline2d spline = SplineFitting<Spline2d>::Interpolate(points, 3, chord_lengths);

	for (Eigen::DenseIndex i = 0; i < points.cols(); ++i) {
	PointType pt = spline(chord_lengths(i));
	PointType ref = points.col(i);
	VERIFY((pt - ref).matrix().norm() < 1e-14);
	}
	}
	}

	void check_global_interpolation_with_derivatives2d() {
	typedef Spline2d::PointType PointType;
	typedef Spline2d::KnotVectorType KnotVectorType;

	const Eigen::DenseIndex numPoints = 100;
	const unsigned int dimension = 2;
	const unsigned int degree = 3;

	ArrayXXd points = ArrayXXd::Random(dimension, numPoints);

	KnotVectorType knots;
	Eigen::ChordLengths(points, knots);

	ArrayXXd derivatives = ArrayXXd::Random(dimension, numPoints);
	VectorXd derivativeIndices(numPoints);

	for (Eigen::DenseIndex i = 0; i < numPoints; ++i) derivativeIndices(i) = static_cast<double>(i);

	const Spline2d spline =
	SplineFitting<Spline2d>::InterpolateWithDerivatives(points, derivatives, derivativeIndices, degree);

	for (Eigen::DenseIndex i = 0; i < points.cols(); ++i) {
	PointType point = spline(knots(i));
	PointType referencePoint = points.col(i);
	VERIFY_IS_APPROX(point, referencePoint);
	PointType derivative = spline.derivatives(knots(i), 1).col(1);
	PointType referenceDerivative = derivatives.col(i);
	VERIFY_IS_APPROX(derivative, referenceDerivative);
	}
	}

	EIGEN_DECLARE_TEST(splines) {
	for (int i = 0; i < g_repeat; ++i) {
	CALL_SUBTEST(eval_spline3d());
	CALL_SUBTEST(eval_spline3d_onbrks());
	CALL_SUBTEST(eval_closed_spline2d());
	CALL_SUBTEST(check_global_interpolation2d());
	CALL_SUBTEST(check_global_interpolation_with_derivatives2d());
	}
	}