mat/eigen_test.go - third_party/github.com/gonum/gonum - Git at Google

 // Copyright ©2013 The Gonum Authors. All rights reserved.
 // Use of this source code is governed by a BSD-style
 // license that can be found in the LICENSE file.

 package mat

 import (
 	"sort"
 	"testing"

 	"golang.org/x/exp/rand"

 	"gonum.org/v1/gonum/floats"
 )

 func TestEigen(t *testing.T) {
 	t.Parallel()
 	for i, test := range []struct {
 		a *Dense

 		values []complex128
 		left   *CDense
 		right  *CDense
 	}{
 		{
 			a: NewDense(3, 3, []float64{
 				1, 0, 0,
 				0, 1, 0,
 				0, 0, 1,
 			}),
 			values: []complex128{1, 1, 1},
 			left: NewCDense(3, 3, []complex128{
 				1, 0, 0,
 				0, 1, 0,
 				0, 0, 1,
 			}),
 			right: NewCDense(3, 3, []complex128{
 				1, 0, 0,
 				0, 1, 0,
 				0, 0, 1,
 			}),
 		},
 		{
 			// Values compared with numpy.
 			a: NewDense(4, 4, []float64{
 				0.9025, 0.025, 0.475, 0.0475,
 				0.0475, 0.475, 0.475, 0.0025,
 				0.0475, 0.025, 0.025, 0.9025,
 				0.0025, 0.475, 0.025, 0.0475,
 			}),
 			values: []complex128{1, 0.7300317046114154, -0.1400158523057075 + 0.452854925738716i, -0.1400158523057075 - 0.452854925738716i},
 			left: NewCDense(4, 4, []complex128{
 				0.5, -0.3135167160788314, 0.0205812178013689 - 0.0045809393001271i, 0.0205812178013689 + 0.0045809393001271i,
 				0.5, 0.7842199280224774, -0.3755102695419336 + 0.2924634904103882i, -0.3755102695419336 - 0.2924634904103882i,
 				0.5, 0.3320220078078358, -0.1605261632278496 - 0.3881393645202528i, -0.1605261632278496 + 0.3881393645202528i,
 				0.5, 0.4200806584012395, 0.7723935249234153, 0.7723935249234153,
 			}),
 			right: NewCDense(4, 4, []complex128{
 				0.9476399565969628, -0.8637347682162745, -0.2688989440320280 - 0.1282234938321029i, -0.2688989440320280 + 0.1282234938321029i,
 				0.2394935907064427, 0.3457075153704627, -0.3621360383713332 - 0.2583198964498771i, -0.3621360383713332 + 0.2583198964498771i,
 				0.1692743801716332, 0.2706851011641580, 0.7426369401030960, 0.7426369401030960,
 				0.1263626404003607, 0.2473421516816520, -0.1116019576997347 + 0.3865433902819795i, -0.1116019576997347 - 0.3865433902819795i,
 			}),
 		},
 	} {
 		var e1, e2, e3, e4 Eigen
 		ok := e1.Factorize(test.a, EigenBoth)
 		if !ok {
 			panic("bad factorization")
 		}
 		e2.Factorize(test.a, EigenRight)
 		e3.Factorize(test.a, EigenLeft)
 		e4.Factorize(test.a, EigenNone)

 		v1 := e1.Values(nil)
 		if !cmplxEqualTol(v1, test.values, 1e-14) {
 			t.Errorf("eigenvalue mismatch. Case %v", i)
 		}
 		var left CDense
 		e1.LeftVectorsTo(&left)
 		if !CEqualApprox(&left, test.left, 1e-14) {
 			t.Errorf("left eigenvector mismatch. Case %v", i)
 		}
 		var right CDense
 		e1.VectorsTo(&right)
 		if !CEqualApprox(&right, test.right, 1e-14) {
 			t.Errorf("right eigenvector mismatch. Case %v", i)
 		}

 		// Check that the eigenvectors and values are the same in all combinations.
 		if !cmplxEqual(v1, e2.Values(nil)) {
 			t.Errorf("eigenvector mismatch. Case %v", i)
 		}
 		if !cmplxEqual(v1, e3.Values(nil)) {
 			t.Errorf("eigenvector mismatch. Case %v", i)
 		}
 		if !cmplxEqual(v1, e4.Values(nil)) {
 			t.Errorf("eigenvector mismatch. Case %v", i)
 		}
 		var right2 CDense
 		e2.VectorsTo(&right2)
 		if !CEqual(&right, &right2) {
 			t.Errorf("right eigenvector mismatch. Case %v", i)
 		}
 		var left3 CDense
 		e3.LeftVectorsTo(&left3)
 		if !CEqual(&left, &left3) {
 			t.Errorf("left eigenvector mismatch. Case %v", i)
 		}

 		// TODO(btracey): Also add in a test for correctness when #308 is
 		// resolved and we have a CMat.Mul().
 	}
 }

 func cmplxEqual(v1, v2 []complex128) bool {
 	for i, v := range v1 {
 		if v != v2[i] {
 			return false
 		}
 	}
 	return true
 }

 func cmplxEqualTol(v1, v2 []complex128, tol float64) bool {
 	for i, v := range v1 {
 		if !cEqualWithinAbsOrRel(v, v2[i], tol, tol) {
 			return false
 		}
 	}
 	return true
 }

 func TestSymEigen(t *testing.T) {
 	t.Parallel()
 	// Hand coded tests with results from lapack.
 	for _, test := range []struct {
 		mat *SymDense

 		values  []float64
 		vectors *Dense
 	}{
 		{
 			mat:    NewSymDense(3, []float64{8, 2, 4, 2, 6, 10, 4, 10, 5}),
 			values: []float64{-4.707679201365891, 6.294580208480216, 17.413098992885672},
 			vectors: NewDense(3, 3, []float64{
 				-0.127343483135656, -0.902414161226903, -0.411621572466779,
 				-0.664177720955769, 0.385801900032553, -0.640331827193739,
 				0.736648893495999, 0.191847792659746, -0.648492738712395,
 			}),
 		},
 	} {
 		var es EigenSym
 		ok := es.Factorize(test.mat, true)
 		if !ok {
 			t.Errorf("bad factorization")
 		}
 		if !floats.EqualApprox(test.values, es.values, 1e-14) {
 			t.Errorf("Eigenvalue mismatch")
 		}
 		if !EqualApprox(test.vectors, es.vectors, 1e-14) {
 			t.Errorf("Eigenvector mismatch")
 		}

 		var es2 EigenSym
 		es2.Factorize(test.mat, false)
 		if !floats.EqualApprox(es2.values, es.values, 1e-14) {
 			t.Errorf("Eigenvalue mismatch when no vectors computed")
 		}
 	}

 	// Randomized tests
 	rnd := rand.New(rand.NewSource(1))
 	for _, n := range []int{3, 5, 10, 70} {
 		for cas := 0; cas < 10; cas++ {
 			a := make([]float64, n*n)
 			for i := range a {
 				a[i] = rnd.NormFloat64()
 			}
 			s := NewSymDense(n, a)
 			var es EigenSym
 			ok := es.Factorize(s, true)
 			if !ok {
 				t.Errorf("Bad test")
 			}

 			// Check that the eigenvectors are orthonormal.
 			if !isOrthonormal(es.vectors, 1e-8) {
 				t.Errorf("Eigenvectors not orthonormal")
 			}

 			// Check that the eigenvalues are actually eigenvalues.
 			for i := 0; i < n; i++ {
 				v := NewVecDense(n, Col(nil, i, es.vectors))
 				var m VecDense
 				m.MulVec(s, v)

 				var scal VecDense
 				scal.ScaleVec(es.values[i], v)

 				if !EqualApprox(&m, &scal, 1e-8) {
 					t.Errorf("Eigenvalue does not match")
 				}
 			}

 			// Check that the eigenvalues are in ascending order.
 			if !sort.Float64sAreSorted(es.values) {
 				t.Errorf("Eigenvalues not ascending")
 			}
 		}
 	}
 }
	// Copyright ©2013 The Gonum Authors. All rights reserved.
	// Use of this source code is governed by a BSD-style
	// license that can be found in the LICENSE file.

	package mat

	import (
	"sort"
	"testing"

	"golang.org/x/exp/rand"

	"gonum.org/v1/gonum/floats"
	)

	func TestEigen(t *testing.T) {
	t.Parallel()
	for i, test := range []struct {
	a *Dense

	values []complex128
	left *CDense
	right *CDense
	}{
	{
	a: NewDense(3, 3, []float64{
	1, 0, 0,
	0, 1, 0,
	0, 0, 1,
	}),
	values: []complex128{1, 1, 1},
	left: NewCDense(3, 3, []complex128{
	1, 0, 0,
	0, 1, 0,
	0, 0, 1,
	}),
	right: NewCDense(3, 3, []complex128{
	1, 0, 0,
	0, 1, 0,
	0, 0, 1,
	}),
	},
	{
	// Values compared with numpy.
	a: NewDense(4, 4, []float64{
	0.9025, 0.025, 0.475, 0.0475,
	0.0475, 0.475, 0.475, 0.0025,
	0.0475, 0.025, 0.025, 0.9025,
	0.0025, 0.475, 0.025, 0.0475,
	}),
	values: []complex128{1, 0.7300317046114154, -0.1400158523057075 + 0.452854925738716i, -0.1400158523057075 - 0.452854925738716i},
	left: NewCDense(4, 4, []complex128{
	0.5, -0.3135167160788314, 0.0205812178013689 - 0.0045809393001271i, 0.0205812178013689 + 0.0045809393001271i,
	0.5, 0.7842199280224774, -0.3755102695419336 + 0.2924634904103882i, -0.3755102695419336 - 0.2924634904103882i,
	0.5, 0.3320220078078358, -0.1605261632278496 - 0.3881393645202528i, -0.1605261632278496 + 0.3881393645202528i,
	0.5, 0.4200806584012395, 0.7723935249234153, 0.7723935249234153,
	}),
	right: NewCDense(4, 4, []complex128{
	0.9476399565969628, -0.8637347682162745, -0.2688989440320280 - 0.1282234938321029i, -0.2688989440320280 + 0.1282234938321029i,
	0.2394935907064427, 0.3457075153704627, -0.3621360383713332 - 0.2583198964498771i, -0.3621360383713332 + 0.2583198964498771i,
	0.1692743801716332, 0.2706851011641580, 0.7426369401030960, 0.7426369401030960,
	0.1263626404003607, 0.2473421516816520, -0.1116019576997347 + 0.3865433902819795i, -0.1116019576997347 - 0.3865433902819795i,
	}),
	},
	} {
	var e1, e2, e3, e4 Eigen
	ok := e1.Factorize(test.a, EigenBoth)
	if !ok {
	panic("bad factorization")
	}
	e2.Factorize(test.a, EigenRight)
	e3.Factorize(test.a, EigenLeft)
	e4.Factorize(test.a, EigenNone)

	v1 := e1.Values(nil)
	if !cmplxEqualTol(v1, test.values, 1e-14) {
	t.Errorf("eigenvalue mismatch. Case %v", i)
	}
	var left CDense
	e1.LeftVectorsTo(&left)
	if !CEqualApprox(&left, test.left, 1e-14) {
	t.Errorf("left eigenvector mismatch. Case %v", i)
	}
	var right CDense
	e1.VectorsTo(&right)
	if !CEqualApprox(&right, test.right, 1e-14) {
	t.Errorf("right eigenvector mismatch. Case %v", i)
	}

	// Check that the eigenvectors and values are the same in all combinations.
	if !cmplxEqual(v1, e2.Values(nil)) {
	t.Errorf("eigenvector mismatch. Case %v", i)
	}
	if !cmplxEqual(v1, e3.Values(nil)) {
	t.Errorf("eigenvector mismatch. Case %v", i)
	}
	if !cmplxEqual(v1, e4.Values(nil)) {
	t.Errorf("eigenvector mismatch. Case %v", i)
	}
	var right2 CDense
	e2.VectorsTo(&right2)
	if !CEqual(&right, &right2) {
	t.Errorf("right eigenvector mismatch. Case %v", i)
	}
	var left3 CDense
	e3.LeftVectorsTo(&left3)
	if !CEqual(&left, &left3) {
	t.Errorf("left eigenvector mismatch. Case %v", i)
	}

	// TODO(btracey): Also add in a test for correctness when #308 is
	// resolved and we have a CMat.Mul().
	}
	}

	func cmplxEqual(v1, v2 []complex128) bool {
	for i, v := range v1 {
	if v != v2[i] {
	return false
	}
	}
	return true
	}

	func cmplxEqualTol(v1, v2 []complex128, tol float64) bool {
	for i, v := range v1 {
	if !cEqualWithinAbsOrRel(v, v2[i], tol, tol) {
	return false
	}
	}
	return true
	}

	func TestSymEigen(t *testing.T) {
	t.Parallel()
	// Hand coded tests with results from lapack.
	for _, test := range []struct {
	mat *SymDense

	values []float64
	vectors *Dense
	}{
	{
	mat: NewSymDense(3, []float64{8, 2, 4, 2, 6, 10, 4, 10, 5}),
	values: []float64{-4.707679201365891, 6.294580208480216, 17.413098992885672},
	vectors: NewDense(3, 3, []float64{
	-0.127343483135656, -0.902414161226903, -0.411621572466779,
	-0.664177720955769, 0.385801900032553, -0.640331827193739,
	0.736648893495999, 0.191847792659746, -0.648492738712395,
	}),
	},
	} {
	var es EigenSym
	ok := es.Factorize(test.mat, true)
	if !ok {
	t.Errorf("bad factorization")
	}
	if !floats.EqualApprox(test.values, es.values, 1e-14) {
	t.Errorf("Eigenvalue mismatch")
	}
	if !EqualApprox(test.vectors, es.vectors, 1e-14) {
	t.Errorf("Eigenvector mismatch")
	}

	var es2 EigenSym
	es2.Factorize(test.mat, false)
	if !floats.EqualApprox(es2.values, es.values, 1e-14) {
	t.Errorf("Eigenvalue mismatch when no vectors computed")
	}
	}

	// Randomized tests
	rnd := rand.New(rand.NewSource(1))
	for _, n := range []int{3, 5, 10, 70} {
	for cas := 0; cas < 10; cas++ {
	a := make([]float64, n*n)
	for i := range a {
	a[i] = rnd.NormFloat64()
	}
	s := NewSymDense(n, a)
	var es EigenSym
	ok := es.Factorize(s, true)
	if !ok {
	t.Errorf("Bad test")
	}

	// Check that the eigenvectors are orthonormal.
	if !isOrthonormal(es.vectors, 1e-8) {
	t.Errorf("Eigenvectors not orthonormal")
	}

	// Check that the eigenvalues are actually eigenvalues.
	for i := 0; i < n; i++ {
	v := NewVecDense(n, Col(nil, i, es.vectors))
	var m VecDense
	m.MulVec(s, v)

	var scal VecDense
	scal.ScaleVec(es.values[i], v)

	if !EqualApprox(&m, &scal, 1e-8) {
	t.Errorf("Eigenvalue does not match")
	}
	}

	// Check that the eigenvalues are in ascending order.
	if !sort.Float64sAreSorted(es.values) {
	t.Errorf("Eigenvalues not ascending")
	}
	}
	}
	}