mat/lq.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 (
 	"math"

 	"gonum.org/v1/gonum/blas"
 	"gonum.org/v1/gonum/blas/blas64"
 	"gonum.org/v1/gonum/lapack"
 	"gonum.org/v1/gonum/lapack/lapack64"
 )

 const badLQ = "mat: invalid LQ factorization"

 // LQ is a type for creating and using the LQ factorization of a matrix.
 type LQ struct {
 	lq   *Dense
 	tau  []float64
 	cond float64
 }

 func (lq *LQ) updateCond(norm lapack.MatrixNorm) {
 	// Since A = L*Q, and Q is orthogonal, we get for the condition number κ
 	//  κ(A) := |A| |A^-1| = |L*Q| |(L*Q)^-1| = |L| |Qᵀ * L^-1|
 	//        = |L| |L^-1| = κ(L),
 	// where we used that fact that Q^-1 = Qᵀ. However, this assumes that
 	// the matrix norm is invariant under orthogonal transformations which
 	// is not the case for CondNorm. Hopefully the error is negligible: κ
 	// is only a qualitative measure anyway.
 	m := lq.lq.mat.Rows
 	work := getFloats(3*m, false)
 	iwork := getInts(m, false)
 	l := lq.lq.asTriDense(m, blas.NonUnit, blas.Lower)
 	v := lapack64.Trcon(norm, l.mat, work, iwork)
 	lq.cond = 1 / v
 	putFloats(work)
 	putInts(iwork)
 }

 // Factorize computes the LQ factorization of an m×n matrix a where m <= n. The LQ
 // factorization always exists even if A is singular.
 //
 // The LQ decomposition is a factorization of the matrix A such that A = L * Q.
 // The matrix Q is an orthonormal n×n matrix, and L is an m×n lower triangular matrix.
 // L and Q can be extracted using the LTo and QTo methods.
 func (lq *LQ) Factorize(a Matrix) {
 	lq.factorize(a, CondNorm)
 }

 func (lq *LQ) factorize(a Matrix, norm lapack.MatrixNorm) {
 	m, n := a.Dims()
 	if m > n {
 		panic(ErrShape)
 	}
 	k := min(m, n)
 	if lq.lq == nil {
 		lq.lq = &Dense{}
 	}
 	lq.lq.CloneFrom(a)
 	work := []float64{0}
 	lq.tau = make([]float64, k)
 	lapack64.Gelqf(lq.lq.mat, lq.tau, work, -1)
 	work = getFloats(int(work[0]), false)
 	lapack64.Gelqf(lq.lq.mat, lq.tau, work, len(work))
 	putFloats(work)
 	lq.updateCond(norm)
 }

 // isValid returns whether the receiver contains a factorization.
 func (lq *LQ) isValid() bool {
 	return lq.lq != nil && !lq.lq.IsEmpty()
 }

 // Cond returns the condition number for the factorized matrix.
 // Cond will panic if the receiver does not contain a factorization.
 func (lq *LQ) Cond() float64 {
 	if !lq.isValid() {
 		panic(badLQ)
 	}
 	return lq.cond
 }

 // TODO(btracey): Add in the "Reduced" forms for extracting the m×m orthogonal
 // and upper triangular matrices.

 // LTo extracts the m×n lower trapezoidal matrix from a LQ decomposition.
 //
 // If dst is empty, LTo will resize dst to be r×c. When dst is
 // non-empty, LTo will panic if dst is not r×c. LTo will also panic
 // if the receiver does not contain a successful factorization.
 func (lq *LQ) LTo(dst *Dense) {
 	if !lq.isValid() {
 		panic(badLQ)
 	}

 	r, c := lq.lq.Dims()
 	if dst.IsEmpty() {
 		dst.ReuseAs(r, c)
 	} else {
 		r2, c2 := dst.Dims()
 		if r != r2 || c != c2 {
 			panic(ErrShape)
 		}
 	}

 	// Disguise the LQ as a lower triangular.
 	t := &TriDense{
 		mat: blas64.Triangular{
 			N:      r,
 			Stride: lq.lq.mat.Stride,
 			Data:   lq.lq.mat.Data,
 			Uplo:   blas.Lower,
 			Diag:   blas.NonUnit,
 		},
 		cap: lq.lq.capCols,
 	}
 	dst.Copy(t)

 	if r == c {
 		return
 	}
 	// Zero right of the triangular.
 	for i := 0; i < r; i++ {
 		zero(dst.mat.Data[i*dst.mat.Stride+r : i*dst.mat.Stride+c])
 	}
 }

 // QTo extracts the n×n orthonormal matrix Q from an LQ decomposition.
 //
 // If dst is empty, QTo will resize dst to be c×c. When dst is
 // non-empty, QTo will panic if dst is not c×c. QTo will also panic
 // if the receiver does not contain a successful factorization.
 func (lq *LQ) QTo(dst *Dense) {
 	if !lq.isValid() {
 		panic(badLQ)
 	}

 	_, c := lq.lq.Dims()
 	if dst.IsEmpty() {
 		dst.ReuseAs(c, c)
 	} else {
 		r2, c2 := dst.Dims()
 		if c != r2 || c != c2 {
 			panic(ErrShape)
 		}
 		dst.Zero()
 	}
 	q := dst.mat

 	// Set Q = I.
 	ldq := q.Stride
 	for i := 0; i < c; i++ {
 		q.Data[i*ldq+i] = 1
 	}

 	// Construct Q from the elementary reflectors.
 	work := []float64{0}
 	lapack64.Ormlq(blas.Left, blas.NoTrans, lq.lq.mat, lq.tau, q, work, -1)
 	work = getFloats(int(work[0]), false)
 	lapack64.Ormlq(blas.Left, blas.NoTrans, lq.lq.mat, lq.tau, q, work, len(work))
 	putFloats(work)
 }

 // SolveTo finds a minimum-norm solution to a system of linear equations defined
 // by the matrices A and b, where A is an m×n matrix represented in its LQ factorized
 // form. If A is singular or near-singular a Condition error is returned.
 // See the documentation for Condition for more information.
 //
 // The minimization problem solved depends on the input parameters.
 //  If trans == false, find the minimum norm solution of A * X = B.
 //  If trans == true, find X such that ||A*X - B||_2 is minimized.
 // The solution matrix, X, is stored in place into dst.
 // SolveTo will panic if the receiver does not contain a factorization.
 func (lq *LQ) SolveTo(dst *Dense, trans bool, b Matrix) error {
 	if !lq.isValid() {
 		panic(badLQ)
 	}

 	r, c := lq.lq.Dims()
 	br, bc := b.Dims()

 	// The LQ solve algorithm stores the result in-place into the right hand side.
 	// The storage for the answer must be large enough to hold both b and x.
 	// However, this method's receiver must be the size of x. Copy b, and then
 	// copy the result into x at the end.
 	if trans {
 		if c != br {
 			panic(ErrShape)
 		}
 		dst.reuseAsNonZeroed(r, bc)
 	} else {
 		if r != br {
 			panic(ErrShape)
 		}
 		dst.reuseAsNonZeroed(c, bc)
 	}
 	// Do not need to worry about overlap between x and b because w has its own
 	// independent storage.
 	w := getWorkspace(max(r, c), bc, false)
 	w.Copy(b)
 	t := lq.lq.asTriDense(lq.lq.mat.Rows, blas.NonUnit, blas.Lower).mat
 	if trans {
 		work := []float64{0}
 		lapack64.Ormlq(blas.Left, blas.NoTrans, lq.lq.mat, lq.tau, w.mat, work, -1)
 		work = getFloats(int(work[0]), false)
 		lapack64.Ormlq(blas.Left, blas.NoTrans, lq.lq.mat, lq.tau, w.mat, work, len(work))
 		putFloats(work)

 		ok := lapack64.Trtrs(blas.Trans, t, w.mat)
 		if !ok {
 			return Condition(math.Inf(1))
 		}
 	} else {
 		ok := lapack64.Trtrs(blas.NoTrans, t, w.mat)
 		if !ok {
 			return Condition(math.Inf(1))
 		}
 		for i := r; i < c; i++ {
 			zero(w.mat.Data[i*w.mat.Stride : i*w.mat.Stride+bc])
 		}
 		work := []float64{0}
 		lapack64.Ormlq(blas.Left, blas.Trans, lq.lq.mat, lq.tau, w.mat, work, -1)
 		work = getFloats(int(work[0]), false)
 		lapack64.Ormlq(blas.Left, blas.Trans, lq.lq.mat, lq.tau, w.mat, work, len(work))
 		putFloats(work)
 	}
 	// x was set above to be the correct size for the result.
 	dst.Copy(w)
 	putWorkspace(w)
 	if lq.cond > ConditionTolerance {
 		return Condition(lq.cond)
 	}
 	return nil
 }

 // SolveVecTo finds a minimum-norm solution to a system of linear equations.
 // See LQ.SolveTo for the full documentation.
 // SolveToVec will panic if the receiver does not contain a factorization.
 func (lq *LQ) SolveVecTo(dst *VecDense, trans bool, b Vector) error {
 	if !lq.isValid() {
 		panic(badLQ)
 	}

 	r, c := lq.lq.Dims()
 	if _, bc := b.Dims(); bc != 1 {
 		panic(ErrShape)
 	}

 	// The Solve implementation is non-trivial, so rather than duplicate the code,
 	// instead recast the VecDenses as Dense and call the matrix code.
 	bm := Matrix(b)
 	if rv, ok := b.(RawVectorer); ok {
 		bmat := rv.RawVector()
 		if dst != b {
 			dst.checkOverlap(bmat)
 		}
 		b := VecDense{mat: bmat}
 		bm = b.asDense()
 	}
 	if trans {
 		dst.reuseAsNonZeroed(r)
 	} else {
 		dst.reuseAsNonZeroed(c)
 	}
 	return lq.SolveTo(dst.asDense(), trans, bm)
 }
	// 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 (
	"math"

	"gonum.org/v1/gonum/blas"
	"gonum.org/v1/gonum/blas/blas64"
	"gonum.org/v1/gonum/lapack"
	"gonum.org/v1/gonum/lapack/lapack64"
	)

	const badLQ = "mat: invalid LQ factorization"

	// LQ is a type for creating and using the LQ factorization of a matrix.
	type LQ struct {
	lq *Dense
	tau []float64
	cond float64
	}

	func (lq *LQ) updateCond(norm lapack.MatrixNorm) {
	// Since A = L*Q, and Q is orthogonal, we get for the condition number κ
	// κ(A) := \|A\| \|A^-1\| = \|LQ\| \|(LQ)^-1\| = \|L\| \|Qᵀ * L^-1\|
	// = \|L\| \|L^-1\| = κ(L),
	// where we used that fact that Q^-1 = Qᵀ. However, this assumes that
	// the matrix norm is invariant under orthogonal transformations which
	// is not the case for CondNorm. Hopefully the error is negligible: κ
	// is only a qualitative measure anyway.
	m := lq.lq.mat.Rows
	work := getFloats(3*m, false)
	iwork := getInts(m, false)
	l := lq.lq.asTriDense(m, blas.NonUnit, blas.Lower)
	v := lapack64.Trcon(norm, l.mat, work, iwork)
	lq.cond = 1 / v
	putFloats(work)
	putInts(iwork)
	}

	// Factorize computes the LQ factorization of an m×n matrix a where m <= n. The LQ
	// factorization always exists even if A is singular.
	//
	// The LQ decomposition is a factorization of the matrix A such that A = L * Q.
	// The matrix Q is an orthonormal n×n matrix, and L is an m×n lower triangular matrix.
	// L and Q can be extracted using the LTo and QTo methods.
	func (lq *LQ) Factorize(a Matrix) {
	lq.factorize(a, CondNorm)
	}

	func (lq *LQ) factorize(a Matrix, norm lapack.MatrixNorm) {
	m, n := a.Dims()
	if m > n {
	panic(ErrShape)
	}
	k := min(m, n)
	if lq.lq == nil {
	lq.lq = &Dense{}
	}
	lq.lq.CloneFrom(a)
	work := []float64{0}
	lq.tau = make([]float64, k)
	lapack64.Gelqf(lq.lq.mat, lq.tau, work, -1)
	work = getFloats(int(work[0]), false)
	lapack64.Gelqf(lq.lq.mat, lq.tau, work, len(work))
	putFloats(work)
	lq.updateCond(norm)
	}

	// isValid returns whether the receiver contains a factorization.
	func (lq *LQ) isValid() bool {
	return lq.lq != nil && !lq.lq.IsEmpty()
	}

	// Cond returns the condition number for the factorized matrix.
	// Cond will panic if the receiver does not contain a factorization.
	func (lq *LQ) Cond() float64 {
	if !lq.isValid() {
	panic(badLQ)
	}
	return lq.cond
	}

	// TODO(btracey): Add in the "Reduced" forms for extracting the m×m orthogonal
	// and upper triangular matrices.

	// LTo extracts the m×n lower trapezoidal matrix from a LQ decomposition.
	//
	// If dst is empty, LTo will resize dst to be r×c. When dst is
	// non-empty, LTo will panic if dst is not r×c. LTo will also panic
	// if the receiver does not contain a successful factorization.
	func (lq LQ) LTo(dst Dense) {
	if !lq.isValid() {
	panic(badLQ)
	}

	r, c := lq.lq.Dims()
	if dst.IsEmpty() {
	dst.ReuseAs(r, c)
	} else {
	r2, c2 := dst.Dims()
	if r != r2 \|\| c != c2 {
	panic(ErrShape)
	}
	}

	// Disguise the LQ as a lower triangular.
	t := &TriDense{
	mat: blas64.Triangular{
	N: r,
	Stride: lq.lq.mat.Stride,
	Data: lq.lq.mat.Data,
	Uplo: blas.Lower,
	Diag: blas.NonUnit,
	},
	cap: lq.lq.capCols,
	}
	dst.Copy(t)

	if r == c {
	return
	}
	// Zero right of the triangular.
	for i := 0; i < r; i++ {
	zero(dst.mat.Data[idst.mat.Stride+r : idst.mat.Stride+c])
	}
	}

	// QTo extracts the n×n orthonormal matrix Q from an LQ decomposition.
	//
	// If dst is empty, QTo will resize dst to be c×c. When dst is
	// non-empty, QTo will panic if dst is not c×c. QTo will also panic
	// if the receiver does not contain a successful factorization.
	func (lq LQ) QTo(dst Dense) {
	if !lq.isValid() {
	panic(badLQ)
	}

	_, c := lq.lq.Dims()
	if dst.IsEmpty() {
	dst.ReuseAs(c, c)
	} else {
	r2, c2 := dst.Dims()
	if c != r2 \|\| c != c2 {
	panic(ErrShape)
	}
	dst.Zero()
	}
	q := dst.mat

	// Set Q = I.
	ldq := q.Stride
	for i := 0; i < c; i++ {
	q.Data[i*ldq+i] = 1
	}

	// Construct Q from the elementary reflectors.
	work := []float64{0}
	lapack64.Ormlq(blas.Left, blas.NoTrans, lq.lq.mat, lq.tau, q, work, -1)
	work = getFloats(int(work[0]), false)
	lapack64.Ormlq(blas.Left, blas.NoTrans, lq.lq.mat, lq.tau, q, work, len(work))
	putFloats(work)
	}

	// SolveTo finds a minimum-norm solution to a system of linear equations defined
	// by the matrices A and b, where A is an m×n matrix represented in its LQ factorized
	// form. If A is singular or near-singular a Condition error is returned.
	// See the documentation for Condition for more information.
	//
	// The minimization problem solved depends on the input parameters.
	// If trans == false, find the minimum norm solution of A * X = B.
	// If trans == true, find X such that \|\|A*X - B\|\|_2 is minimized.
	// The solution matrix, X, is stored in place into dst.
	// SolveTo will panic if the receiver does not contain a factorization.
	func (lq LQ) SolveTo(dst Dense, trans bool, b Matrix) error {
	if !lq.isValid() {
	panic(badLQ)
	}

	r, c := lq.lq.Dims()
	br, bc := b.Dims()

	// The LQ solve algorithm stores the result in-place into the right hand side.
	// The storage for the answer must be large enough to hold both b and x.
	// However, this method's receiver must be the size of x. Copy b, and then
	// copy the result into x at the end.
	if trans {
	if c != br {
	panic(ErrShape)
	}
	dst.reuseAsNonZeroed(r, bc)
	} else {
	if r != br {
	panic(ErrShape)
	}
	dst.reuseAsNonZeroed(c, bc)
	}
	// Do not need to worry about overlap between x and b because w has its own
	// independent storage.
	w := getWorkspace(max(r, c), bc, false)
	w.Copy(b)
	t := lq.lq.asTriDense(lq.lq.mat.Rows, blas.NonUnit, blas.Lower).mat
	if trans {
	work := []float64{0}
	lapack64.Ormlq(blas.Left, blas.NoTrans, lq.lq.mat, lq.tau, w.mat, work, -1)
	work = getFloats(int(work[0]), false)
	lapack64.Ormlq(blas.Left, blas.NoTrans, lq.lq.mat, lq.tau, w.mat, work, len(work))
	putFloats(work)

	ok := lapack64.Trtrs(blas.Trans, t, w.mat)
	if !ok {
	return Condition(math.Inf(1))
	}
	} else {
	ok := lapack64.Trtrs(blas.NoTrans, t, w.mat)
	if !ok {
	return Condition(math.Inf(1))
	}
	for i := r; i < c; i++ {
	zero(w.mat.Data[iw.mat.Stride : iw.mat.Stride+bc])
	}
	work := []float64{0}
	lapack64.Ormlq(blas.Left, blas.Trans, lq.lq.mat, lq.tau, w.mat, work, -1)
	work = getFloats(int(work[0]), false)
	lapack64.Ormlq(blas.Left, blas.Trans, lq.lq.mat, lq.tau, w.mat, work, len(work))
	putFloats(work)
	}
	// x was set above to be the correct size for the result.
	dst.Copy(w)
	putWorkspace(w)
	if lq.cond > ConditionTolerance {
	return Condition(lq.cond)
	}
	return nil
	}

	// SolveVecTo finds a minimum-norm solution to a system of linear equations.
	// See LQ.SolveTo for the full documentation.
	// SolveToVec will panic if the receiver does not contain a factorization.
	func (lq LQ) SolveVecTo(dst VecDense, trans bool, b Vector) error {
	if !lq.isValid() {
	panic(badLQ)
	}

	r, c := lq.lq.Dims()
	if _, bc := b.Dims(); bc != 1 {
	panic(ErrShape)
	}

	// The Solve implementation is non-trivial, so rather than duplicate the code,
	// instead recast the VecDenses as Dense and call the matrix code.
	bm := Matrix(b)
	if rv, ok := b.(RawVectorer); ok {
	bmat := rv.RawVector()
	if dst != b {
	dst.checkOverlap(bmat)
	}
	b := VecDense{mat: bmat}
	bm = b.asDense()
	}
	if trans {
	dst.reuseAsNonZeroed(r)
	} else {
	dst.reuseAsNonZeroed(c)
	}
	return lq.SolveTo(dst.asDense(), trans, bm)
	}