mirror of https://github.com/k3s-io/k3s
234 lines
5.7 KiB
Go
234 lines
5.7 KiB
Go
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// Copyright ©2017 The Gonum Authors. All rights reserved.
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// Use of this source code is governed by a BSD-style
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// license that can be found in the LICENSE file.
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package mat
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import (
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"errors"
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"gonum.org/v1/gonum/blas/blas64"
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)
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// HOGSVD is a type for creating and using the Higher Order Generalized Singular Value
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// Decomposition (HOGSVD) of a set of matrices.
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//
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// The factorization is a linear transformation of the data sets from the given
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// variable×sample spaces to reduced and diagonalized "eigenvariable"×"eigensample"
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// spaces.
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type HOGSVD struct {
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n int
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v *Dense
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b []Dense
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err error
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}
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// succFact returns whether the receiver contains a successful factorization.
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func (gsvd *HOGSVD) succFact() bool {
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return gsvd.n != 0
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}
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// Factorize computes the higher order generalized singular value decomposition (HOGSVD)
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// of the n input r_i×c column tall matrices in m. HOGSV extends the GSVD case from 2 to n
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// input matrices.
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//
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// M_0 = U_0 * Σ_0 * V^T
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// M_1 = U_1 * Σ_1 * V^T
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// .
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// .
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// .
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// M_{n-1} = U_{n-1} * Σ_{n-1} * V^T
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//
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// where U_i are r_i×c matrices of singular vectors, Σ are c×c matrices singular values, and V
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// is a c×c matrix of singular vectors.
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//
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// Factorize returns whether the decomposition succeeded. If the decomposition
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// failed, routines that require a successful factorization will panic.
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func (gsvd *HOGSVD) Factorize(m ...Matrix) (ok bool) {
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// Factorize performs the HOGSVD factorisation
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// essentially as described by Ponnapalli et al.
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// https://doi.org/10.1371/journal.pone.0028072
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if len(m) < 2 {
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panic("hogsvd: too few matrices")
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}
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gsvd.n = 0
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r, c := m[0].Dims()
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a := make([]Cholesky, len(m))
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var ts SymDense
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for i, d := range m {
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rd, cd := d.Dims()
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if rd < cd {
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gsvd.err = ErrShape
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return false
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}
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if rd > r {
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r = rd
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}
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if cd != c {
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panic(ErrShape)
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}
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ts.Reset()
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ts.SymOuterK(1, d.T())
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ok = a[i].Factorize(&ts)
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if !ok {
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gsvd.err = errors.New("hogsvd: cholesky decomposition failed")
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return false
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}
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}
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s := getWorkspace(c, c, true)
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defer putWorkspace(s)
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sij := getWorkspace(c, c, false)
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defer putWorkspace(sij)
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for i, ai := range a {
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for _, aj := range a[i+1:] {
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gsvd.err = ai.SolveCholTo(sij, &aj)
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if gsvd.err != nil {
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return false
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}
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s.Add(s, sij)
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gsvd.err = aj.SolveCholTo(sij, &ai)
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if gsvd.err != nil {
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return false
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}
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s.Add(s, sij)
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}
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}
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s.Scale(1/float64(len(m)*(len(m)-1)), s)
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var eig Eigen
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ok = eig.Factorize(s.T(), EigenRight)
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if !ok {
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gsvd.err = errors.New("hogsvd: eigen decomposition failed")
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return false
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}
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vc := eig.VectorsTo(nil)
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// vc is guaranteed to have real eigenvalues.
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rc, cc := vc.Dims()
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v := NewDense(rc, cc, nil)
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for i := 0; i < rc; i++ {
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for j := 0; j < cc; j++ {
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a := vc.At(i, j)
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v.set(i, j, real(a))
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}
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}
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// Rescale the columns of v by their Frobenius norms.
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// Work done in cv is reflected in v.
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var cv VecDense
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for j := 0; j < c; j++ {
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cv.ColViewOf(v, j)
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cv.ScaleVec(1/blas64.Nrm2(cv.mat), &cv)
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}
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b := make([]Dense, len(m))
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biT := getWorkspace(c, r, false)
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defer putWorkspace(biT)
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for i, d := range m {
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// All calls to reset will leave a zeroed
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// matrix with capacity to store the result
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// without additional allocation.
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biT.Reset()
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gsvd.err = biT.Solve(v, d.T())
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if gsvd.err != nil {
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return false
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}
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b[i].Clone(biT.T())
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}
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gsvd.n = len(m)
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gsvd.v = v
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gsvd.b = b
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return true
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}
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// Err returns the reason for a factorization failure.
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func (gsvd *HOGSVD) Err() error {
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return gsvd.err
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}
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// Len returns the number of matrices that have been factorized. If Len returns
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// zero, the factorization was not successful.
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func (gsvd *HOGSVD) Len() int {
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return gsvd.n
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}
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// UTo extracts the matrix U_n from the singular value decomposition, storing
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// the result in-place into dst. U_n is size r×c.
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// If dst is nil, a new matrix is allocated. The resulting U matrix is returned.
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//
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// UTo will panic if the receiver does not contain a successful factorization.
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func (gsvd *HOGSVD) UTo(dst *Dense, n int) *Dense {
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if !gsvd.succFact() {
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panic(badFact)
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}
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if n < 0 || gsvd.n <= n {
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panic("hogsvd: invalid index")
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}
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if dst == nil {
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r, c := gsvd.b[n].Dims()
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dst = NewDense(r, c, nil)
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} else {
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dst.reuseAs(gsvd.b[n].Dims())
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}
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dst.Copy(&gsvd.b[n])
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var v VecDense
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for j, f := range gsvd.Values(nil, n) {
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v.ColViewOf(dst, j)
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v.ScaleVec(1/f, &v)
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}
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return dst
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}
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// Values returns the nth set of singular values of the factorized system.
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// If the input slice is non-nil, the values will be stored in-place into the slice.
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// In this case, the slice must have length c, and Values will panic with
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// matrix.ErrSliceLengthMismatch otherwise. If the input slice is nil,
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// a new slice of the appropriate length will be allocated and returned.
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//
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// Values will panic if the receiver does not contain a successful factorization.
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func (gsvd *HOGSVD) Values(s []float64, n int) []float64 {
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if !gsvd.succFact() {
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panic(badFact)
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}
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if n < 0 || gsvd.n <= n {
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panic("hogsvd: invalid index")
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}
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_, c := gsvd.b[n].Dims()
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if s == nil {
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s = make([]float64, c)
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} else if len(s) != c {
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panic(ErrSliceLengthMismatch)
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}
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var v VecDense
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for j := 0; j < c; j++ {
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v.ColViewOf(&gsvd.b[n], j)
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s[j] = blas64.Nrm2(v.mat)
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}
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return s
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}
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// VTo extracts the matrix V from the singular value decomposition, storing
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// the result in-place into dst. V is size c×c.
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// If dst is nil, a new matrix is allocated. The resulting V matrix is returned.
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//
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// VTo will panic if the receiver does not contain a successful factorization.
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func (gsvd *HOGSVD) VTo(dst *Dense) *Dense {
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if !gsvd.succFact() {
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panic(badFact)
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}
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if dst == nil {
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r, c := gsvd.v.Dims()
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dst = NewDense(r, c, nil)
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} else {
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dst.reuseAs(gsvd.v.Dims())
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}
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dst.Copy(gsvd.v)
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return dst
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}
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