lapack/lapack.go - third_party/github.com/gonum/gonum - Git at Google

 // Copyright ©2015 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 lapack

 import "gonum.org/v1/gonum/blas"

 // Complex128 defines the public complex128 LAPACK API supported by gonum/lapack.
 type Complex128 interface{}

 // Float64 defines the public float64 LAPACK API supported by gonum/lapack.
 type Float64 interface {
 	Dgecon(norm MatrixNorm, n int, a []float64, lda int, anorm float64, work []float64, iwork []int) float64
 	Dgeev(jobvl LeftEVJob, jobvr RightEVJob, n int, a []float64, lda int, wr, wi []float64, vl []float64, ldvl int, vr []float64, ldvr int, work []float64, lwork int) (first int)
 	Dgels(trans blas.Transpose, m, n, nrhs int, a []float64, lda int, b []float64, ldb int, work []float64, lwork int) bool
 	Dgelqf(m, n int, a []float64, lda int, tau, work []float64, lwork int)
 	Dgeqrf(m, n int, a []float64, lda int, tau, work []float64, lwork int)
 	Dgesvd(jobU, jobVT SVDJob, m, n int, a []float64, lda int, s, u []float64, ldu int, vt []float64, ldvt int, work []float64, lwork int) (ok bool)
 	Dgetrf(m, n int, a []float64, lda int, ipiv []int) (ok bool)
 	Dgetri(n int, a []float64, lda int, ipiv []int, work []float64, lwork int) (ok bool)
 	Dgetrs(trans blas.Transpose, n, nrhs int, a []float64, lda int, ipiv []int, b []float64, ldb int)
 	Dggsvd3(jobU, jobV, jobQ GSVDJob, m, n, p int, a []float64, lda int, b []float64, ldb int, alpha, beta, u []float64, ldu int, v []float64, ldv int, q []float64, ldq int, work []float64, lwork int, iwork []int) (k, l int, ok bool)
 	Dlantr(norm MatrixNorm, uplo blas.Uplo, diag blas.Diag, m, n int, a []float64, lda int, work []float64) float64
 	Dlange(norm MatrixNorm, m, n int, a []float64, lda int, work []float64) float64
 	Dlansy(norm MatrixNorm, uplo blas.Uplo, n int, a []float64, lda int, work []float64) float64
 	Dlapmt(forward bool, m, n int, x []float64, ldx int, k []int)
 	Dormqr(side blas.Side, trans blas.Transpose, m, n, k int, a []float64, lda int, tau, c []float64, ldc int, work []float64, lwork int)
 	Dormlq(side blas.Side, trans blas.Transpose, m, n, k int, a []float64, lda int, tau, c []float64, ldc int, work []float64, lwork int)
 	Dpocon(uplo blas.Uplo, n int, a []float64, lda int, anorm float64, work []float64, iwork []int) float64
 	Dpotrf(ul blas.Uplo, n int, a []float64, lda int) (ok bool)
 	Dpotrs(ul blas.Uplo, n, nrhs int, a []float64, lda int, b []float64, ldb int)
 	Dsyev(jobz EVJob, uplo blas.Uplo, n int, a []float64, lda int, w, work []float64, lwork int) (ok bool)
 	Dtrcon(norm MatrixNorm, uplo blas.Uplo, diag blas.Diag, n int, a []float64, lda int, work []float64, iwork []int) float64
 	Dtrtri(uplo blas.Uplo, diag blas.Diag, n int, a []float64, lda int) (ok bool)
 	Dtrtrs(uplo blas.Uplo, trans blas.Transpose, diag blas.Diag, n, nrhs int, a []float64, lda int, b []float64, ldb int) (ok bool)
 }

 // Direct specifies the direction of the multiplication for the Householder matrix.
 type Direct byte

 const (
 	Forward  Direct = 'F' // Reflectors are right-multiplied, H_0 * H_1 * ... * H_{k-1}.
 	Backward Direct = 'B' // Reflectors are left-multiplied, H_{k-1} * ... * H_1 * H_0.
 )

 // Sort is the sorting order.
 type Sort byte

 const (
 	SortIncreasing Sort = 'I'
 	SortDecreasing Sort = 'D'
 )

 // StoreV indicates the storage direction of elementary reflectors.
 type StoreV byte

 const (
 	ColumnWise StoreV = 'C' // Reflector stored in a column of the matrix.
 	RowWise    StoreV = 'R' // Reflector stored in a row of the matrix.
 )

 // MatrixNorm represents the kind of matrix norm to compute.
 type MatrixNorm byte

 const (
 	MaxAbs       MatrixNorm = 'M' // max(abs(A(i,j)))
 	MaxColumnSum MatrixNorm = 'O' // Maximum absolute column sum (one norm)
 	MaxRowSum    MatrixNorm = 'I' // Maximum absolute row sum (infinity norm)
 	Frobenius    MatrixNorm = 'F' // Frobenius norm (sqrt of sum of squares)
 )

 // MatrixType represents the kind of matrix represented in the data.
 type MatrixType byte

 const (
 	General  MatrixType = 'G' // A general dense matrix.
 	UpperTri MatrixType = 'U' // An upper triangular matrix.
 	LowerTri MatrixType = 'L' // A lower triangular matrix.
 )

 // Pivot specifies the pivot type for plane rotations.
 type Pivot byte

 const (
 	Variable Pivot = 'V'
 	Top      Pivot = 'T'
 	Bottom   Pivot = 'B'
 )

 // ApplyOrtho specifies which orthogonal matrix is applied in Dormbr.
 type ApplyOrtho byte

 const (
 	ApplyP ApplyOrtho = 'P' // Apply P or P^T.
 	ApplyQ ApplyOrtho = 'Q' // Apply Q or Q^T.
 )

 // GenOrtho specifies which orthogonal matrix is generated in Dorgbr.
 type GenOrtho byte

 const (
 	GeneratePT GenOrtho = 'P' // Generate P^T.
 	GenerateQ  GenOrtho = 'Q' // Generate Q.
 )

 // SVDJob specifies the singular vector computation type for SVD.
 type SVDJob byte

 const (
 	SVDAll       SVDJob = 'A' // Compute all columns of the orthogonal matrix U or V.
 	SVDStore     SVDJob = 'S' // Compute the singular vectors and store them in the orthogonal matrix U or V.
 	SVDOverwrite SVDJob = 'O' // Compute the singular vectors and overwrite them on the input matrix A.
 	SVDNone      SVDJob = 'N' // Do not compute singular vectors.
 )

 // GSVDJob specifies the singular vector computation type for Generalized SVD.
 type GSVDJob byte

 const (
 	GSVDU    GSVDJob = 'U' // Compute orthogonal matrix U.
 	GSVDV    GSVDJob = 'V' // Compute orthogonal matrix V.
 	GSVDQ    GSVDJob = 'Q' // Compute orthogonal matrix Q.
 	GSVDUnit GSVDJob = 'I' // Use unit-initialized matrix.
 	GSVDNone GSVDJob = 'N' // Do not compute orthogonal matrix.
 )

 // EVComp specifies how eigenvectors are computed in Dsteqr.
 type EVComp byte

 const (
 	EVOrig     EVComp = 'V' // Compute eigenvectors of the original symmetric matrix.
 	EVTridiag  EVComp = 'I' // Compute eigenvectors of the tridiagonal matrix.
 	EVCompNone EVComp = 'N' // Do not compute eigenvectors.
 )

 // EVJob specifies whether eigenvectors are computed in Dsyev.
 type EVJob byte

 const (
 	EVCompute EVJob = 'V' // Compute eigenvectors.
 	EVNone    EVJob = 'N' // Do not compute eigenvectors.
 )

 // LeftEVJob specifies whether left eigenvectors are computed in Dgeev.
 type LeftEVJob byte

 const (
 	LeftEVCompute LeftEVJob = 'V' // Compute left eigenvectors.
 	LeftEVNone    LeftEVJob = 'N' // Do not compute left eigenvectors.
 )

 // RightEVJob specifies whether right eigenvectors are computed in Dgeev.
 type RightEVJob byte

 const (
 	RightEVCompute RightEVJob = 'V' // Compute right eigenvectors.
 	RightEVNone    RightEVJob = 'N' // Do not compute right eigenvectors.
 )

 // BalanceJob specifies matrix balancing operation.
 type BalanceJob byte

 const (
 	Permute      BalanceJob = 'P'
 	Scale        BalanceJob = 'S'
 	PermuteScale BalanceJob = 'B'
 	BalanceNone  BalanceJob = 'N'
 )

 // SchurJob specifies whether the Schur form is computed in Dhseqr.
 type SchurJob byte

 const (
 	EigenvaluesOnly     SchurJob = 'E'
 	EigenvaluesAndSchur SchurJob = 'S'
 )

 // SchurComp specifies whether and how the Schur vectors are computed in Dhseqr.
 type SchurComp byte

 const (
 	SchurOrig SchurComp = 'V' // Compute Schur vectors of the original matrix.
 	SchurHess SchurComp = 'I' // Compute Schur vectors of the upper Hessenberg matrix.
 	SchurNone SchurComp = 'N' // Do not compute Schur vectors.
 )

 // UpdateSchurComp specifies whether the matrix of Schur vectors is updated in Dtrexc.
 type UpdateSchurComp byte

 const (
 	UpdateSchur     UpdateSchurComp = 'V' // Update the matrix of Schur vectors.
 	UpdateSchurNone UpdateSchurComp = 'N' // Do not update the matrix of Schur vectors.
 )

 // EVSide specifies what eigenvectors are computed in Dtrevc3.
 type EVSide byte

 const (
 	EVRight EVSide = 'R' // Compute only right eigenvectors.
 	EVLeft  EVSide = 'L' // Compute only left eigenvectors.
 	EVBoth  EVSide = 'B' // Compute both right and left eigenvectors.
 )

 // EVHowMany specifies which eigenvectors are computed in Dtrevc3 and how.
 type EVHowMany byte

 const (
 	EVAll      EVHowMany = 'A' // Compute all right and/or left eigenvectors.
 	EVAllMulQ  EVHowMany = 'B' // Compute all right and/or left eigenvectors multiplied by an input matrix.
 	EVSelected EVHowMany = 'S' // Compute selected right and/or left eigenvectors.
 )
	// Copyright ©2015 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 lapack

	import "gonum.org/v1/gonum/blas"

	// Complex128 defines the public complex128 LAPACK API supported by gonum/lapack.
	type Complex128 interface{}

	// Float64 defines the public float64 LAPACK API supported by gonum/lapack.
	type Float64 interface {
	Dgecon(norm MatrixNorm, n int, a []float64, lda int, anorm float64, work []float64, iwork []int) float64
	Dgeev(jobvl LeftEVJob, jobvr RightEVJob, n int, a []float64, lda int, wr, wi []float64, vl []float64, ldvl int, vr []float64, ldvr int, work []float64, lwork int) (first int)
	Dgels(trans blas.Transpose, m, n, nrhs int, a []float64, lda int, b []float64, ldb int, work []float64, lwork int) bool
	Dgelqf(m, n int, a []float64, lda int, tau, work []float64, lwork int)
	Dgeqrf(m, n int, a []float64, lda int, tau, work []float64, lwork int)
	Dgesvd(jobU, jobVT SVDJob, m, n int, a []float64, lda int, s, u []float64, ldu int, vt []float64, ldvt int, work []float64, lwork int) (ok bool)
	Dgetrf(m, n int, a []float64, lda int, ipiv []int) (ok bool)
	Dgetri(n int, a []float64, lda int, ipiv []int, work []float64, lwork int) (ok bool)
	Dgetrs(trans blas.Transpose, n, nrhs int, a []float64, lda int, ipiv []int, b []float64, ldb int)
	Dggsvd3(jobU, jobV, jobQ GSVDJob, m, n, p int, a []float64, lda int, b []float64, ldb int, alpha, beta, u []float64, ldu int, v []float64, ldv int, q []float64, ldq int, work []float64, lwork int, iwork []int) (k, l int, ok bool)
	Dlantr(norm MatrixNorm, uplo blas.Uplo, diag blas.Diag, m, n int, a []float64, lda int, work []float64) float64
	Dlange(norm MatrixNorm, m, n int, a []float64, lda int, work []float64) float64
	Dlansy(norm MatrixNorm, uplo blas.Uplo, n int, a []float64, lda int, work []float64) float64
	Dlapmt(forward bool, m, n int, x []float64, ldx int, k []int)
	Dormqr(side blas.Side, trans blas.Transpose, m, n, k int, a []float64, lda int, tau, c []float64, ldc int, work []float64, lwork int)
	Dormlq(side blas.Side, trans blas.Transpose, m, n, k int, a []float64, lda int, tau, c []float64, ldc int, work []float64, lwork int)
	Dpocon(uplo blas.Uplo, n int, a []float64, lda int, anorm float64, work []float64, iwork []int) float64
	Dpotrf(ul blas.Uplo, n int, a []float64, lda int) (ok bool)
	Dpotrs(ul blas.Uplo, n, nrhs int, a []float64, lda int, b []float64, ldb int)
	Dsyev(jobz EVJob, uplo blas.Uplo, n int, a []float64, lda int, w, work []float64, lwork int) (ok bool)
	Dtrcon(norm MatrixNorm, uplo blas.Uplo, diag blas.Diag, n int, a []float64, lda int, work []float64, iwork []int) float64
	Dtrtri(uplo blas.Uplo, diag blas.Diag, n int, a []float64, lda int) (ok bool)
	Dtrtrs(uplo blas.Uplo, trans blas.Transpose, diag blas.Diag, n, nrhs int, a []float64, lda int, b []float64, ldb int) (ok bool)
	}

	// Direct specifies the direction of the multiplication for the Householder matrix.
	type Direct byte

	const (
	Forward Direct = 'F' // Reflectors are right-multiplied, H_0 * H_1 * ... * H_{k-1}.
	Backward Direct = 'B' // Reflectors are left-multiplied, H_{k-1} * ... * H_1 * H_0.
	)

	// Sort is the sorting order.
	type Sort byte

	const (
	SortIncreasing Sort = 'I'
	SortDecreasing Sort = 'D'
	)

	// StoreV indicates the storage direction of elementary reflectors.
	type StoreV byte

	const (
	ColumnWise StoreV = 'C' // Reflector stored in a column of the matrix.
	RowWise StoreV = 'R' // Reflector stored in a row of the matrix.
	)

	// MatrixNorm represents the kind of matrix norm to compute.
	type MatrixNorm byte

	const (
	MaxAbs MatrixNorm = 'M' // max(abs(A(i,j)))
	MaxColumnSum MatrixNorm = 'O' // Maximum absolute column sum (one norm)
	MaxRowSum MatrixNorm = 'I' // Maximum absolute row sum (infinity norm)
	Frobenius MatrixNorm = 'F' // Frobenius norm (sqrt of sum of squares)
	)

	// MatrixType represents the kind of matrix represented in the data.
	type MatrixType byte

	const (
	General MatrixType = 'G' // A general dense matrix.
	UpperTri MatrixType = 'U' // An upper triangular matrix.
	LowerTri MatrixType = 'L' // A lower triangular matrix.
	)

	// Pivot specifies the pivot type for plane rotations.
	type Pivot byte

	const (
	Variable Pivot = 'V'
	Top Pivot = 'T'
	Bottom Pivot = 'B'
	)

	// ApplyOrtho specifies which orthogonal matrix is applied in Dormbr.
	type ApplyOrtho byte

	const (
	ApplyP ApplyOrtho = 'P' // Apply P or P^T.
	ApplyQ ApplyOrtho = 'Q' // Apply Q or Q^T.
	)

	// GenOrtho specifies which orthogonal matrix is generated in Dorgbr.
	type GenOrtho byte

	const (
	GeneratePT GenOrtho = 'P' // Generate P^T.
	GenerateQ GenOrtho = 'Q' // Generate Q.
	)

	// SVDJob specifies the singular vector computation type for SVD.
	type SVDJob byte

	const (
	SVDAll SVDJob = 'A' // Compute all columns of the orthogonal matrix U or V.
	SVDStore SVDJob = 'S' // Compute the singular vectors and store them in the orthogonal matrix U or V.
	SVDOverwrite SVDJob = 'O' // Compute the singular vectors and overwrite them on the input matrix A.
	SVDNone SVDJob = 'N' // Do not compute singular vectors.
	)

	// GSVDJob specifies the singular vector computation type for Generalized SVD.
	type GSVDJob byte

	const (
	GSVDU GSVDJob = 'U' // Compute orthogonal matrix U.
	GSVDV GSVDJob = 'V' // Compute orthogonal matrix V.
	GSVDQ GSVDJob = 'Q' // Compute orthogonal matrix Q.
	GSVDUnit GSVDJob = 'I' // Use unit-initialized matrix.
	GSVDNone GSVDJob = 'N' // Do not compute orthogonal matrix.
	)

	// EVComp specifies how eigenvectors are computed in Dsteqr.
	type EVComp byte

	const (
	EVOrig EVComp = 'V' // Compute eigenvectors of the original symmetric matrix.
	EVTridiag EVComp = 'I' // Compute eigenvectors of the tridiagonal matrix.
	EVCompNone EVComp = 'N' // Do not compute eigenvectors.
	)

	// EVJob specifies whether eigenvectors are computed in Dsyev.
	type EVJob byte

	const (
	EVCompute EVJob = 'V' // Compute eigenvectors.
	EVNone EVJob = 'N' // Do not compute eigenvectors.
	)

	// LeftEVJob specifies whether left eigenvectors are computed in Dgeev.
	type LeftEVJob byte

	const (
	LeftEVCompute LeftEVJob = 'V' // Compute left eigenvectors.
	LeftEVNone LeftEVJob = 'N' // Do not compute left eigenvectors.
	)

	// RightEVJob specifies whether right eigenvectors are computed in Dgeev.
	type RightEVJob byte

	const (
	RightEVCompute RightEVJob = 'V' // Compute right eigenvectors.
	RightEVNone RightEVJob = 'N' // Do not compute right eigenvectors.
	)

	// BalanceJob specifies matrix balancing operation.
	type BalanceJob byte

	const (
	Permute BalanceJob = 'P'
	Scale BalanceJob = 'S'
	PermuteScale BalanceJob = 'B'
	BalanceNone BalanceJob = 'N'
	)

	// SchurJob specifies whether the Schur form is computed in Dhseqr.
	type SchurJob byte

	const (
	EigenvaluesOnly SchurJob = 'E'
	EigenvaluesAndSchur SchurJob = 'S'
	)

	// SchurComp specifies whether and how the Schur vectors are computed in Dhseqr.
	type SchurComp byte

	const (
	SchurOrig SchurComp = 'V' // Compute Schur vectors of the original matrix.
	SchurHess SchurComp = 'I' // Compute Schur vectors of the upper Hessenberg matrix.
	SchurNone SchurComp = 'N' // Do not compute Schur vectors.
	)

	// UpdateSchurComp specifies whether the matrix of Schur vectors is updated in Dtrexc.
	type UpdateSchurComp byte

	const (
	UpdateSchur UpdateSchurComp = 'V' // Update the matrix of Schur vectors.
	UpdateSchurNone UpdateSchurComp = 'N' // Do not update the matrix of Schur vectors.
	)

	// EVSide specifies what eigenvectors are computed in Dtrevc3.
	type EVSide byte

	const (
	EVRight EVSide = 'R' // Compute only right eigenvectors.
	EVLeft EVSide = 'L' // Compute only left eigenvectors.
	EVBoth EVSide = 'B' // Compute both right and left eigenvectors.
	)

	// EVHowMany specifies which eigenvectors are computed in Dtrevc3 and how.
	type EVHowMany byte

	const (
	EVAll EVHowMany = 'A' // Compute all right and/or left eigenvectors.
	EVAllMulQ EVHowMany = 'B' // Compute all right and/or left eigenvectors multiplied by an input matrix.
	EVSelected EVHowMany = 'S' // Compute selected right and/or left eigenvectors.
	)