// Copies a vector X to a vector Y (Y := X). // // ARGUMENTS // X float or complex matrix // Y float or complex matrix. Must have the same type as X. // // OPTIONS // n integer. If n<0, the default value of n is used. // The default value is given by 1+(len(x)-offsetx-1)/incx or 0 // if len(x) > offsetx+1 // incx nonzero integer // incy nonzero integer // offsetx nonnegative integer // offsety nonnegative integer; // func Copy(X, Y matrix.Matrix, opts ...linalg.Option) (err error) { ind := linalg.GetIndexOpts(opts...) err = check_level1_func(ind, fcopy, X, Y) if err != nil { return } if ind.Nx == 0 { return } sameType := matrix.EqualTypes(X, Y) if !sameType { err = onError("arrays not same type") return } switch X.(type) { case *matrix.ComplexMatrix: Xa := X.(*matrix.ComplexMatrix).ComplexArray() Ya := Y.(*matrix.ComplexMatrix).ComplexArray() zcopy(ind.Nx, Xa[ind.OffsetX:], ind.IncX, Ya[ind.OffsetY:], ind.IncY) case *matrix.FloatMatrix: Xa := X.(*matrix.FloatMatrix).FloatArray() Ya := Y.(*matrix.FloatMatrix).FloatArray() dcopy(ind.Nx, Xa[ind.OffsetX:], ind.IncX, Ya[ind.OffsetY:], ind.IncY) default: err = onError("not implemented for parameter types") } return }
// Returns Y = X^H*Y for real or complex X, Y. // // ARGUMENTS // X float or complex matrix // Y float or complex matrix. Must have the same type as X. // // OPTIONS // n integer. If n<0, the default value of n is used. // The default value is equal to nx = 1+(len(x)-offsetx-1)/incx or 0 if // len(x) > offsetx+1. If the default value is used, it must be equal to // ny = 1+(len(y)-offsetx-1)/|incy| or 0 if len(y) > offsety+1 // incx nonzero integer [default=1] // incy nonzero integer [default=1] // offsetx nonnegative integer [default=0] // offsety nonnegative integer [default=0] // func Dot(X, Y matrix.Matrix, opts ...linalg.Option) (v matrix.Scalar) { v = matrix.FScalar(math.NaN()) //cv = cmplx.NaN() ind := linalg.GetIndexOpts(opts...) err := check_level1_func(ind, fdot, X, Y) if err != nil { return } if ind.Nx == 0 { return matrix.FScalar(0.0) } sameType := matrix.EqualTypes(X, Y) if !sameType { err = onError("arrays not of same type") return } switch X.(type) { case *matrix.ComplexMatrix: Xa := X.(*matrix.ComplexMatrix).ComplexArray() Ya := Y.(*matrix.ComplexMatrix).ComplexArray() v = matrix.CScalar(zdotc(ind.Nx, Xa[ind.OffsetX:], ind.IncX, Ya[ind.OffsetY:], ind.IncY)) case *matrix.FloatMatrix: Xa := X.(*matrix.FloatMatrix).FloatArray() Ya := Y.(*matrix.FloatMatrix).FloatArray() v = matrix.FScalar(ddot(ind.Nx, Xa[ind.OffsetX:], ind.IncX, Ya[ind.OffsetY:], ind.IncY)) //default: // err = onError("not implemented for parameter types", ) } return }
/* General matrix-matrix product. (L3) PURPOSE Computes C := alpha*A*B + beta*C if transA = PNoTrans and transB = PNoTrans. C := alpha*A^T*B + beta*C if transA = PTrans and transB = PNoTrans. C := alpha*A^H*B + beta*C if transA = PConjTrans and transB = PNoTrans. C := alpha*A*B^T + beta*C if transA = PNoTrans and transB = PTrans. C := alpha*A^T*B^T + beta*C if transA = PTrans and transB = PTrans. C := alpha*A^H*B^T + beta*C if transA = PConjTrans and transB = PTrans. C := alpha*A*B^H + beta*C if transA = PNoTrans and transB = PConjTrans. C := alpha*A^T*B^H + beta*C if transA = PTrans and transB = PConjTrans. C := alpha*A^H*B^H + beta*C if transA = PConjTrans and transB = PConjTrans. The number of rows of the matrix product is m. The number of columns is n. The inner dimension is k. If k=0, this reduces to C := beta*C. ARGUMENTS A float or complex matrix, m*k B float or complex matrix, k*n C float or complex matrix, m*n alpha number (float or complex singleton matrix) beta number (float or complex singleton matrix) OPTIONS transA PNoTrans, PTrans or PConjTrans transB PNoTrans, PTrans or PConjTrans m integer. If negative, the default value is used. The default value is m = A.Rows of if transA != PNoTrans m = A.Cols. n integer. If negative, the default value is used. The default value is n = (transB == PNoTrans) ? B.Cols : B.Rows. k integer. If negative, the default value is used. The default value is k=A.Cols or if transA != PNoTrans) k = A.Rows, transA=PNoTrans. If the default value is used it should also be equal to (transB == PNoTrans) ? B.Rows : B.Cols. ldA nonnegative integer. ldA >= max(1,m) of if transA != NoTrans max(1,k). If zero, the default value is used. ldB nonnegative integer. ldB >= max(1,k) or if transB != NoTrans max(1,n). If zero, the default value is used. ldC nonnegative integer. ldC >= max(1,m). If zero, the default value is used. offsetA nonnegative integer offsetB nonnegative integer offsetC nonnegative integer; */ func Gemm(A, B, C matrix.Matrix, alpha, beta matrix.Scalar, opts ...linalg.Option) (err error) { params, e := linalg.GetParameters(opts...) if e != nil { err = e return } ind := linalg.GetIndexOpts(opts...) err = check_level3_func(ind, fgemm, A, B, C, params) if err != nil { return } if ind.M == 0 || ind.N == 0 { return } if !matrix.EqualTypes(A, B, C) { return onError("Parameters not of same type") } switch A.(type) { case *matrix.FloatMatrix: Aa := A.(*matrix.FloatMatrix).FloatArray() Ba := B.(*matrix.FloatMatrix).FloatArray() Ca := C.(*matrix.FloatMatrix).FloatArray() aval := alpha.Float() bval := beta.Float() if math.IsNaN(aval) || math.IsNaN(bval) { return onError("alpha or beta not a number") } transB := linalg.ParamString(params.TransB) transA := linalg.ParamString(params.TransA) dgemm(transA, transB, ind.M, ind.N, ind.K, aval, Aa[ind.OffsetA:], ind.LDa, Ba[ind.OffsetB:], ind.LDb, bval, Ca[ind.OffsetC:], ind.LDc) case *matrix.ComplexMatrix: Aa := A.(*matrix.ComplexMatrix).ComplexArray() Ba := B.(*matrix.ComplexMatrix).ComplexArray() Ca := C.(*matrix.ComplexMatrix).ComplexArray() aval := alpha.Complex() if cmplx.IsNaN(aval) { return onError("alpha not a number") } bval := beta.Complex() if cmplx.IsNaN(bval) { return onError("beta not a number") } transB := linalg.ParamString(params.TransB) transA := linalg.ParamString(params.TransA) zgemm(transA, transB, ind.M, ind.N, ind.K, aval, Aa[ind.OffsetA:], ind.LDa, Ba[ind.OffsetB:], ind.LDb, bval, Ca[ind.OffsetC:], ind.LDc) default: return onError("Unknown type, not implemented") } return }
/* LU factorization of a real or complex tridiagonal matrix. PURPOSE Factors an n by n real or complex tridiagonal matrix A as A = P*L*U. A is specified by its lower diagonal dl, diagonal d, and upper diagonal du. On exit dl, d, du, du2 and ipiv contain the details of the factorization. ARGUMENTS. DL float or complex matrix D float or complex matrix. Must have the same type as DL. DU float or complex matrix. Must have the same type as DL. DU2 float or complex matrix of length at least n-2. Must have the same type as DL. ipiv int vector of length at least n OPTIONS n nonnegative integer. If negative, the default value is used. offsetdl nonnegative integer offsetd nonnegative integer offsetdu nonnegative integer */ func Gtrrf(DL, D, DU, DU2 matrix.Matrix, ipiv []int32, opts ...linalg.Option) error { ind := linalg.GetIndexOpts(opts...) if ind.OffsetD < 0 { return onError("Gttrf: offset D") } if ind.N < 0 { ind.N = D.NumElements() - ind.OffsetD } if ind.N < 0 { return onError("Gttrf: size D") } if ind.N == 0 { return nil } if ind.OffsetDL < 0 { return onError("Gttrf: offset DL") } sizeDL := DL.NumElements() if sizeDL < ind.OffsetDL+ind.N-1 { return onError("Gttrf: sizeDL") } if ind.OffsetDU < 0 { return onError("Gttrf: offset DU") } sizeDU := DU.NumElements() if sizeDU < ind.OffsetDU+ind.N-1 { return onError("Gttrf: sizeDU") } sizeDU2 := DU2.NumElements() if sizeDU2 < ind.N-2 { return onError("Gttrf: sizeDU2") } if len(ipiv) < ind.N { return onError("Gttrf: size ipiv") } info := -1 if !matrix.EqualTypes(DL, D, DU, DU2) { return onError("Gttrf: arguments not same type") } switch DL.(type) { case *matrix.FloatMatrix: DLa := DL.(*matrix.FloatMatrix).FloatArray() Da := D.(*matrix.FloatMatrix).FloatArray() DUa := DU.(*matrix.FloatMatrix).FloatArray() DU2a := DU2.(*matrix.FloatMatrix).FloatArray() info = dgttrf(ind.N, DLa[ind.OffsetDL:], Da[ind.OffsetD:], DUa[ind.OffsetDU:], DU2a, ipiv) case *matrix.ComplexMatrix: return onError("Gttrf: complex not yet implemented") } if info != 0 { return onError(fmt.Sprintf("Gttrf lapack error: %d", info)) } return nil }
/* Solves a general real or complex set of linear equations. PURPOSE Solves A*X=B with A m by n real or complex. ARGUMENTS. A float or complex matrix B float or complex matrix. Must have the same type as A. OPTIONS: trans m nonnegative integer. If negative, the default value is used. n nonnegative integer. If negative, the default value is used. nrhs nonnegative integer. If negative, the default value is used. ldA positive integer. ldA >= max(1,n). If zero, the default value is used. ldB positive integer. ldB >= max(1,n). If zero, the default value is used. */ func Gels(A, B matrix.Matrix, opts ...linalg.Option) error { pars, _ := linalg.GetParameters(opts...) ind := linalg.GetIndexOpts(opts...) arows := ind.LDa brows := ind.LDb if ind.M < 0 { ind.M = A.Rows() } if ind.N < 0 { ind.N = A.Cols() } if ind.Nrhs < 0 { ind.Nrhs = B.Cols() } if ind.M == 0 || ind.N == 0 || ind.Nrhs == 0 { return nil } if ind.LDa == 0 { ind.LDa = max(1, A.LeadingIndex()) arows = max(1, A.Rows()) } if ind.LDa < max(1, ind.M) { return onError("Gesv: ldA") } if ind.LDb == 0 { ind.LDb = max(1, B.LeadingIndex()) brows = max(1, B.Rows()) } if ind.LDb < max(ind.M, ind.N) { return onError("Gesv: ldB") } if !matrix.EqualTypes(A, B) { return onError("Gesv: arguments not of same type") } _, _ = arows, brows // todo!! something info := -1 trans := linalg.ParamString(pars.Trans) switch A.(type) { case *matrix.FloatMatrix: Aa := A.(*matrix.FloatMatrix).FloatArray() Ba := B.(*matrix.FloatMatrix).FloatArray() info = dgels(trans, ind.M, ind.N, ind.Nrhs, Aa[ind.OffsetA:], ind.LDa, Ba[ind.OffsetB:], ind.LDb) case *matrix.ComplexMatrix: Aa := A.(*matrix.ComplexMatrix).ComplexArray() Ba := B.(*matrix.ComplexMatrix).ComplexArray() info = zgels(trans, ind.M, ind.N, ind.Nrhs, Aa[ind.OffsetA:], ind.LDa, Ba[ind.OffsetB:], ind.LDb) } if info != 0 { return onError(fmt.Sprintf("Gels: lapack error: %d", info)) } return nil }
/* Computes selected eigenvalues and eigenvectors of a real symmetric matrix (RRR driver). PURPOSE Computes selected eigenvalues/vectors of a real symmetric n by n matrix A. If range is PRangeAll, all eigenvalues are computed. If range is PRangeV all eigenvalues in the interval (vlimit[0],vlimit[1]] are computed. If range is PRangeI, all eigenvalues ilimit[0] through ilimit[1] are computed (sorted in ascending order with 1 <= ilimit[0] <= ilimit[1] <= n). If jobz is PJobNo, only the eigenvalues are returned in W. If jobz is PJobV, the eigenvectors are also returned in Z. On exit, the content of A is destroyed. Syevr is usually the fastest of the four eigenvalue routines. ARGUMENTS A float matrix W float matrix of length at least n. On exit, contains the computed eigenvalues in ascending order. Z float matrix or nil. Only required when jobz = PJobV. If range is PRangeAll or PRangeV, Z must have at least n columns. If range is PRangeI, Z must have at least iu-il+1 columns. On exit the first m columns of Z contain the computed (normalized) eigenvectors. abstol double. Absolute error tolerance for eigenvalues. If nonpositive, the LAPACK default value is used. vlmit []float or nil. Only required when range is PRangeV. ilimit []int or nil. Only required when range is PRangeI. OPTIONS jobz PJobNo or PJobV range PRangeAll, PRangeV or PRangeI uplo PLower or PUpper n integer. If negative, the default value is used. ldA nonnegative integer. ldA >= max(1,n). If zero, the default value is used. ldZ nonnegative integer. ldZ >= 1 if jobz is 'N' and ldZ >= max(1,n) if jobz is PJobV. The default value is 1 if jobz is PJobNo and max(1,Z.Rows) if jobz =PJboV. If zero, the default value is used. offsetA nonnegative integer offsetW nonnegative integer offsetZ nonnegative integer m the number of eigenvalues computed */ func Syevr(A, W, Z matrix.Matrix, abstol float64, vlimit []float64, ilimit []int, opts ...linalg.Option) error { if !matrix.EqualTypes(A, W, Z) { return onError("Syevr: arguments not of same type") } switch A.(type) { case *matrix.FloatMatrix: Am := A.(*matrix.FloatMatrix) Wm := W.(*matrix.FloatMatrix) Zm := Z.(*matrix.FloatMatrix) return SyevrFloat(Am, Wm, Zm, abstol, vlimit, ilimit, opts...) } return onError("Syevr: unknown types") }
/* Eigenvalue decomposition of a real symmetric matrix (divide-and-conquer driver). PURPOSE Returns eigenvalues/vectors of a real symmetric nxn matrix A. On exit, W contains the eigenvalues in ascending order. If jobz is PJobV, the (normalized) eigenvectors are also computed and returned in A. If jobz is PJobNo, only the eigenvalues are computed, and the content of A is destroyed. ARGUMENTS A float matrix W float matrix of length at least n. On exit, contains the computed eigenvalues in ascending order. OPTIONS jobz PJobNo or PJobV uplo PLower or PUpper n integer. If negative, the default value is used. ldA nonnegative integer. ldA >= max(1,n). If zero, the default value is used. offsetA nonnegative integer offsetB nonnegative integer; */ func Syevd(A, W matrix.Matrix, opts ...linalg.Option) error { if !matrix.EqualTypes(A, W) { return onError("Syevd: arguments not of same type") } switch A.(type) { case *matrix.FloatMatrix: Am := A.(*matrix.FloatMatrix) Wm := W.(*matrix.FloatMatrix) return SyevdFloat(Am, Wm, opts...) case *matrix.ComplexMatrix: return onError("Syevd: not a complex function") } return onError("Syevd: unknown types") }
/* Rank-k update of symmetric matrix. (L3) Herk(A, C, alpha, beta, uplo=PLower, trans=PNoTrans, n=-1, k=-1, ldA=max(1,A.Rows), ldC=max(1,C.Rows), offsetA=0, offsetB=0) Computes C := alpha*A*A^T + beta*C, if trans is PNoTrans C := alpha*A^T*A + beta*C, if trans is PTrans C is symmetric (real or complex) of order n. The inner dimension of the matrix product is k. If k=0 this is interpreted as C := beta*C. ARGUMENTS A float or complex matrix. C float or complex matrix. Must have the same type as A. alpha number (float or complex singleton matrix). Complex alpha is only allowed if A is complex. beta number (float or complex singleton matrix). Complex beta is only allowed if A is complex. OPTIONS uplo PLower or PUpper trans PNoTrans or PTrans n integer. If negative, the default value is used. The default value is n = A.Rows or if trans == PNoTrans n = A.Cols. k integer. If negative, the default value is used. The default value is k = A.Cols, or if trans == PNoTrans k = A.Rows. ldA nonnegative integer. ldA >= max(1,n) or if trans != PNoTrans ldA >= max(1,k). If zero, the default value is used. ldC nonnegative integer. ldC >= max(1,n). If zero, the default value is used. offsetA nonnegative integer offsetC nonnegative integer; */ func Herk(A, C matrix.Matrix, alpha, beta matrix.Scalar, opts ...linalg.Option) (err error) { params, e := linalg.GetParameters(opts...) if e != nil { err = e return } ind := linalg.GetIndexOpts(opts...) err = check_level3_func(ind, fsyrk, A, nil, C, params) if e != nil || err != nil { return } if !matrix.EqualTypes(A, C) { return onError("Parameters not of same type") } switch A.(type) { case *matrix.FloatMatrix: Aa := A.(*matrix.FloatMatrix).FloatArray() Ca := C.(*matrix.FloatMatrix).FloatArray() aval := alpha.Float() bval := beta.Float() if math.IsNaN(aval) || math.IsNaN(bval) { return onError("alpha or beta not a number") } uplo := linalg.ParamString(params.Uplo) trans := linalg.ParamString(params.Trans) dsyrk(uplo, trans, ind.N, ind.K, aval, Aa[ind.OffsetA:], ind.LDa, bval, Ca[ind.OffsetC:], ind.LDc) case *matrix.ComplexMatrix: Aa := A.(*matrix.ComplexMatrix).ComplexArray() Ca := C.(*matrix.ComplexMatrix).ComplexArray() aval := alpha.Complex() if cmplx.IsNaN(aval) { return onError("alpha not a real or complex number") } bval := beta.Float() if math.IsNaN(bval) { return onError("beta not a real number") } uplo := linalg.ParamString(params.Uplo) trans := linalg.ParamString(params.Trans) zherk(uplo, trans, ind.N, ind.K, aval, Aa[ind.OffsetA:], ind.LDa, bval, Ca[ind.OffsetC:], ind.LDc) default: return onError("Unknown type, not implemented") } return }
/* Solves a real or complex set of linear equations with a banded coefficient matrix. PURPOSE Solves A*X = B A an n by n real or complex band matrix with kl subdiagonals and ku superdiagonals. If ipiv is provided, then on entry the kl+ku+1 diagonals of the matrix are stored in rows kl+1 to 2*kl+ku+1 of A, in the BLAS format for general band matrices. On exit, A and ipiv contain the details of the factorization. If ipiv is not provided, then on entry the diagonals of the matrix are stored in rows 1 to kl+ku+1 of A, and Gbsv() does not return the factorization and does not modify A. On exit B is replaced with solution X. ARGUMENTS. A float or complex banded matrix B float or complex matrix. Must have the same type as A. kl nonnegative integer ipiv int array of length at least n OPTIONS ku nonnegative integer. If negative, the default value is used. The default value is A.Rows-kl-1 if ipiv is not provided, and A.Rows-2*kl-1 otherwise. n nonnegative integer. If negative, the default value is used. nrhs nonnegative integer. If negative, the default value is used. ldA positive integer. ldA >= kl+ku+1 if ipiv is not provided and ldA >= 2*kl+ku+1 if ipiv is provided. If zero, the default value is used. ldB positive integer. ldB >= max(1,n). If zero, the default default value is used. offsetA nonnegative integer offsetB nonnegative integer; */ func Gbsv(A, B matrix.Matrix, ipiv []int32, kl int, opts ...linalg.Option) error { if !matrix.EqualTypes(A, B) { return onError("Gbsv: not same type") } switch A.(type) { case *matrix.FloatMatrix: Am := A.(*matrix.FloatMatrix) Bm := B.(*matrix.FloatMatrix) return GbsvFloat(Am, Bm, ipiv, kl, opts...) case *matrix.ComplexMatrix: Am := A.(*matrix.ComplexMatrix) Bm := B.(*matrix.ComplexMatrix) return GbsvComplex(Am, Bm, ipiv, kl, opts...) } return onError("Gbsv: unknown types types!") }
/* Solves a real symmetric or complex Hermitian positive definite set of linear equations. PURPOSE Solves A*X = B with A n by n, real symmetric or complex Hermitian, and positive definite, and B n by nrhs. On exit, if uplo is PLower, the lower triangular part of A is replaced by L. If uplo is PUpper, the upper triangular part is replaced by L^H. B is replaced by the solution. ARGUMENTS. A float or complex matrix B float or complex matrix. Must have the same type as A. OPTIONS uplo PLower or PUpper n nonnegative integer. If negative, the default value is used. nrhs nonnegative integer. If negative, the default value is used. ldA positive integer. ldA >= max(1,n). If zero, the default value is used. ldB positive integer. ldB >= max(1,n). If zero, the default value is used. offsetA nonnegative integer offsetB nonnegative integer */ func Posv(A, B matrix.Matrix, opts ...linalg.Option) error { if !matrix.EqualTypes(A, B) { return onError("Posv: arguments not same type") } switch A.(type) { case *matrix.FloatMatrix: Am := A.(*matrix.FloatMatrix) Bm := B.(*matrix.FloatMatrix) return PosvFloat(Am, Bm, opts...) case *matrix.ComplexMatrix: Am := A.(*matrix.ComplexMatrix) Bm := B.(*matrix.ComplexMatrix) return PosvComplex(Am, Bm, opts...) } return onError("Posv: unknown types") }
/* Computes selected eigenvalues and eigenvectors of a real symmetric matrix (expert driver). PURPOSE Computes selected eigenvalues/vectors of a real symmetric n by n matrix A. If range is OptRangeAll, all eigenvalues are computed. If range is OptRangeValue, all eigenvalues in the interval (vlimit[0],vlimit[1]] are computed. If range is OptRangeInt, all eigenvalues il through iu are computed (sorted in ascending order with 1 <= il <= iu <= n). If jobz is OptJobNo, only the eigenvalues are returned in W. If jobz is OptJobValue, the eigenvectors are also returned in Z. On exit, the content of A is destroyed. ARGUMENTS A float matrix W float matrix of length at least n. On exit, contains the computed eigenvalues in ascending order. Z float matrix. Only required when jobz is PJobValue. If range is PRangeAll or PRangeValue, Z must have at least n columns. If range is PRangeInt, Z must have at least iu-il+1 columns. On exit the first m columns of Z contain the computed (normalized) eigenvectors. vlimit []float64 or nul. Only required when range is PRangeValue ilimit []int or nil. Only required when range is PRangeInt. abstol double. Absolute error tolerance for eigenvalues. If nonpositive, the LAPACK default value is used. OPTIONS jobz linalg.OptJobNo or linalg.OptJobValue range linalg.OptRangeAll, linalg.OptRangeValue or linalg.OptRangeInt uplo linalg.OptLower or linalg.OptUpper n integer. If negative, the default value is used. m the number of eigenvalues computed; ldA nonnegative integer. ldA >= max(1,n). If zero, the default value is used. ldZ nonnegative integer. ldZ >= 1 if jobz is PJobNo and ldZ >= max(1,n) if jobz is PJobValue. The default value is 1 if jobz is PJobNo and max(1,Z.size[0]) if jobz =PJobValue. If zero, the default value is used. offsetA nonnegative integer offsetW nonnegative integer offsetZ nonnegative integer */ func Syevx(A, W, Z matrix.Matrix, abstol float64, vlimit []float64, ilimit []int, opts ...linalg.Option) error { if !matrix.EqualTypes(A, W, Z) { return onError("Syevx: not same type") } switch A.(type) { case *matrix.FloatMatrix: Am := A.(*matrix.FloatMatrix) Wm := W.(*matrix.FloatMatrix) var Zm *matrix.FloatMatrix = nil if Z != nil { Zm = Z.(*matrix.FloatMatrix) } return SyevrFloat(Am, Wm, Zm, abstol, vlimit, ilimit, opts...) } return onError("Syevr: unknown types") }
/* Solution of a triangular system of equations with multiple righthand sides. (L3) Trsm(A, B, alpha, side=PLeft, uplo=PLower, transA=PNoTrans, diag=PNonUnit, m=-1, n=-1, ldA=max(1,A.Rows), ldB=max(1,B.Rows), offsetA=0, offsetB=0) Computes B := alpha*A^{-1}*B if transA is PNoTrans and side = PLeft B := alpha*B*A^{-1} if transA is PNoTrans and side = PRight B := alpha*A^{-T}*B if transA is PTrans and side = PLeft B := alpha*B*A^{-T} if transA is PTrans and side = PRight B := alpha*A^{-H}*B if transA is PConjTrans and side = PLeft B := alpha*B*A^{-H} if transA is PConjTrans and side = PRight B is m by n and A is triangular. The code does not verify whether A is nonsingular. ARGUMENTS A float or complex matrix. B float or complex matrix. Must have the same type as A. alpha number (float or complex). Complex alpha is only allowed if A is complex. OPTIONS side PLeft or PRight uplo PLower or PUpper transA PNoTrans or PTrans diag PNonUnit or PUnit m integer. If negative, the default value is used. The default value is m = A.Rows or if side == PRight m = B.Rows If the default value is used and side is PLeft, m must be equal to A.Cols. n integer. If negative, the default value is used. The default value is n = B.Cols or if side )= PRight n = A.Rows. If the default value is used and side is PRight, n must be equal to A.Cols. ldA nonnegative integer. ldA >= max(1,m) of if side == PRight lda >= max(1,n). If zero, the default value is used. ldB nonnegative integer. ldB >= max(1,m). If zero, the default value is used. offsetA nonnegative integer offsetB nonnegative integer */ func Trsm(A, B matrix.Matrix, alpha matrix.Scalar, opts ...linalg.Option) (err error) { params, e := linalg.GetParameters(opts...) if e != nil { err = e return } ind := linalg.GetIndexOpts(opts...) err = check_level3_func(ind, ftrsm, A, B, nil, params) if err != nil { return } if !matrix.EqualTypes(A, B) { return onError("Parameters not of same type") } switch A.(type) { case *matrix.FloatMatrix: Aa := A.(*matrix.FloatMatrix).FloatArray() Ba := B.(*matrix.FloatMatrix).FloatArray() aval := alpha.Float() if math.IsNaN(aval) { return onError("alpha or beta not a number") } uplo := linalg.ParamString(params.Uplo) transA := linalg.ParamString(params.TransA) side := linalg.ParamString(params.Side) diag := linalg.ParamString(params.Diag) dtrsm(side, uplo, transA, diag, ind.M, ind.N, aval, Aa[ind.OffsetA:], ind.LDa, Ba[ind.OffsetB:], ind.LDb) case *matrix.ComplexMatrix: Aa := A.(*matrix.ComplexMatrix).ComplexArray() Ba := B.(*matrix.ComplexMatrix).ComplexArray() aval := alpha.Complex() if cmplx.IsNaN(aval) { return onError("alpha not a number") } uplo := linalg.ParamString(params.Uplo) transA := linalg.ParamString(params.TransA) side := linalg.ParamString(params.Side) diag := linalg.ParamString(params.Diag) ztrsm(side, uplo, transA, diag, ind.M, ind.N, aval, Aa[ind.OffsetA:], ind.LDa, Ba[ind.OffsetB:], ind.LDb) default: return onError("Unknown type, not implemented") } return }
/* QR factorization. PURPOSE QR factorization of an m by n real or complex matrix A: A = Q*R = [Q1 Q2] * [R1; 0] if m >= n A = Q*R = Q * [R1 R2] if m <= n, where Q is m by m and orthogonal/unitary and R is m by n with R1 upper triangular. On exit, R is stored in the upper triangular part of A. Q is stored as a product of k=min(m,n) elementary reflectors. The parameters of the reflectors are stored in the first k entries of tau and in the lower triangular part of the first k columns of A. ARGUMENTS A float or complex matrix tau float or complex matrix of length at least min(m,n). Must have the same type as A. m integer. If negative, the default value is used. n integer. If negative, the default value is used. ldA nonnegative integer. ldA >= max(1,m). If zero, the default value is used. offsetA nonnegative integer */ func Geqrf(A, tau matrix.Matrix, opts ...linalg.Option) error { ind := linalg.GetIndexOpts(opts...) arows := ind.LDa if ind.N < 0 { ind.N = A.Cols() } if ind.M < 0 { ind.M = A.Rows() } if ind.N == 0 || ind.M == 0 { return nil } if ind.LDa == 0 { ind.LDa = max(1, A.LeadingIndex()) arows = max(1, A.Rows()) } if ind.LDa < max(1, ind.M) { return onError("Geqrf: ldA") } if ind.OffsetA < 0 { return onError("Geqrf: offsetA") } if A.NumElements() < ind.OffsetA+ind.K*arows { return onError("Geqrf: sizeA") } if tau.NumElements() < min(ind.M, ind.N) { return onError("Geqrf: sizeTau") } if !matrix.EqualTypes(A, tau) { return onError("Geqrf: arguments not of same type") } info := -1 switch A.(type) { case *matrix.FloatMatrix: Aa := A.(*matrix.FloatMatrix).FloatArray() taua := tau.(*matrix.FloatMatrix).FloatArray() info = dgeqrf(ind.M, ind.N, Aa[ind.OffsetA:], ind.LDa, taua) case *matrix.ComplexMatrix: return onError("Geqrf: complex not yet implemented") } if info != 0 { return onError(fmt.Sprintf("Geqrf lapack error: %d", info)) } return nil }
/* Singular value decomposition of a real or complex matrix. PURPOSE Computes singular values and, optionally, singular vectors of a real or complex m by n matrix A. The argument jobu controls how many left singular vectors are computed: PJobNo : no left singular vectors are computed. PJobAll: all left singular vectors are computed and returned as columns of U. PJobS : the first min(m,n) left singular vectors are computed and returned as columns of U. PJobO : the first min(m,n) left singular vectors are computed and returned as columns of A. The argument jobvt controls how many right singular vectors are computed: PJobNo : no right singular vectors are computed. PJobAll: all right singular vectors are computed and returned as rows of Vt. PJobS : the first min(m,n) right singular vectors are computed and returned as rows of Vt. PJobO : the first min(m,n) right singular vectors are computed and returned as rows of A. Note that the (conjugate) transposes of the right singular vectors are returned in Vt or A. On exit (in all cases), the contents of A are destroyed. ARGUMENTS A float or complex matrix S float matrix of length at least min(m,n). On exit, contains the computed singular values in descending order. jobu PJobNo, PJobAll, PJobS or PJobO jobvt PJobNo, PJobAll, PJobS or PJobO U float or complex matrix. Must have the same type as A. Not referenced if jobu is PJobNo or PJobO. If jobu is PJobAll, a matrix with at least m columns. If jobu is PJobS, a matrix with at least min(m,n) columns. On exit (with jobu PJobAll or PJobS), the columns of U contain the computed left singular vectors. Vt float or complex matrix. Must have the same type as A. Not referenced if jobvt is PJobNo or PJobO. If jobvt is PJobAll or PJobS, a matrix with at least n columns. On exit (with jobvt PJobAll or PJobS), the rows of Vt contain the computed right singular vectors, or, in the complex case, their complex conjugates. m integer. If negative, the default value is used. n integer. If negative, the default value is used. ldA nonnegative integer. ldA >= max(1,m). If zero, the default value is used. ldU nonnegative integer. ldU >= 1 if jobu is PJobNo or PJobO ldU >= max(1,m) if jobu is PJobAll or PJobS. The default value is max(1,U.Rows) if jobu is PJobAll or PJobS, and 1 otherwise. If zero, the default value is used. ldVt nonnegative integer. ldVt >= 1 if jobvt is PJobNo or PJobO. ldVt >= max(1,n) if jobvt is PJobAll. ldVt >= max(1,min(m,n)) if ldVt is PJobS. The default value is max(1,Vt.Rows) if jobvt is PJobAll or PJobS, and 1 otherwise. If zero, the default value is used. offsetA nonnegative integer offsetS nonnegative integer offsetU nonnegative integer offsetVt nonnegative integer */ func Gesvd(A, S, U, Vt matrix.Matrix, opts ...linalg.Option) error { if !matrix.EqualTypes(A, S, U, Vt) { return onError("Gesvd: arguments not of same type") } switch A.(type) { case *matrix.FloatMatrix: Am := A.(*matrix.FloatMatrix) Sm := S.(*matrix.FloatMatrix) Um := U.(*matrix.FloatMatrix) Vm := Vt.(*matrix.FloatMatrix) return GesvdFloat(Am, Sm, Um, Vm, opts...) case *matrix.ComplexMatrix: Am := A.(*matrix.ComplexMatrix) Sm := S.(*matrix.ComplexMatrix) Um := U.(*matrix.ComplexMatrix) Vm := Vt.(*matrix.ComplexMatrix) return GesvdComplex(Am, Sm, Um, Vm, opts...) } return onError("Gesvd: unknown parameter types") }
// Constant times a vector plus a vector (Y := alpha*X+Y). // // ARGUMENTS // X float or complex matrix // Y float or complex matrix. Must have the same type as X. // alpha number (float or complex singleton matrix). Complex alpha is only // allowed if x is complex. // // OPTIONS // n integer. If n<0, the default value of n is used. // The default value is equal to 1+(len(x)-offsetx-1)/incx // or 0 if len(x) >= offsetx+1 // incx nonzero integer // incy nonzero integer // offsetx nonnegative integer // offsety nonnegative integer; // func Axpy(X, Y matrix.Matrix, alpha matrix.Scalar, opts ...linalg.Option) (err error) { ind := linalg.GetIndexOpts(opts...) err = check_level1_func(ind, faxpy, X, Y) if err != nil { return } if ind.Nx == 0 { return } sameType := matrix.EqualTypes(X, Y) if !sameType { err = onError("arrays not same type") return } switch X.(type) { case *matrix.ComplexMatrix: Xa := X.(*matrix.ComplexMatrix).ComplexArray() Ya := Y.(*matrix.ComplexMatrix).ComplexArray() aval := alpha.Complex() if cmplx.IsNaN(aval) { return onError("alpha not complex value") } zaxpy(ind.Nx, aval, Xa[ind.OffsetX:], ind.IncX, Ya[ind.OffsetY:], ind.IncY) case *matrix.FloatMatrix: Xa := X.(*matrix.FloatMatrix).FloatArray() Ya := Y.(*matrix.FloatMatrix).FloatArray() aval := alpha.Float() if math.IsNaN(aval) { return onError("alpha not float value") } daxpy(ind.Nx, aval, Xa[ind.OffsetX:], ind.IncX, Ya[ind.OffsetY:], ind.IncY) default: err = onError("not implemented for parameter types") } return }
/* Solves a general real or complex set of linear equations. PURPOSE Solves A*X=B with A n by n real or complex. If ipiv is provided, then on exit A is overwritten with the details of the LU factorization, and ipiv contains the permutation matrix. If ipiv is not provided, then gesv() does not return the factorization and does not modify A. On exit B is replaced with the solution X. ARGUMENTS. A float or complex matrix B float or complex matrix. Must have the same type as A. ipiv int vector of length at least n OPTIONS: n nonnegative integer. If negative, the default value is used. nrhs nonnegative integer. If negative, the default value is used. ldA positive integer. ldA >= max(1,n). If zero, the default value is used. ldB positive integer. ldB >= max(1,n). If zero, the default value is used. offsetA nonnegative integer offsetA nonnegative integer; */ func Gesv(A, B matrix.Matrix, ipiv []int32, opts ...linalg.Option) error { //pars, err := linalg.GetParameters(opts...) ind := linalg.GetIndexOpts(opts...) arows := ind.LDa brows := ind.LDb if ind.N < 0 { ind.N = A.Rows() if ind.N != A.Cols() { return onError("Gesv: A not square") } } if ind.Nrhs < 0 { ind.Nrhs = B.Cols() } if ind.N == 0 || ind.Nrhs == 0 { return nil } if ind.LDa == 0 { ind.LDa = max(1, A.LeadingIndex()) arows = max(1, A.Rows()) } if ind.LDa < max(1, ind.N) { return onError("Gesv: ldA") } if ind.LDb == 0 { ind.LDb = max(1, B.LeadingIndex()) brows = max(1, B.Rows()) } if ind.LDb < max(1, ind.N) { return onError("Gesv: ldB") } if ind.OffsetA < 0 { return onError("Gesv: offsetA") } if ind.OffsetB < 0 { return onError("Gesv: offsetB") } sizeA := A.NumElements() if sizeA < ind.OffsetA+(ind.N-1)*arows+ind.N { return onError("Gesv: sizeA") } sizeB := B.NumElements() if sizeB < ind.OffsetB+(ind.Nrhs-1)*brows+ind.N { return onError("Gesv: sizeB") } if ipiv != nil && len(ipiv) < ind.N { return onError("Gesv: size ipiv") } if !matrix.EqualTypes(A, B) { return onError("Gesv: arguments not of same type") } info := -1 if ipiv == nil { ipiv = make([]int32, ind.N) // Do not overwrite A. A = A.MakeCopy() } switch A.(type) { case *matrix.FloatMatrix: Aa := A.(*matrix.FloatMatrix).FloatArray() Aa = Aa[ind.OffsetA:] // Ensure there are sufficient elements in A. Aa = Aa[:ind.LDa*ind.LDb] Ba := B.(*matrix.FloatMatrix).FloatArray() Ba = Ba[ind.OffsetB:] info = dgesv(ind.N, ind.Nrhs, Aa, ind.LDa, ipiv, Ba, ind.LDb) case *matrix.ComplexMatrix: Aa := A.(*matrix.ComplexMatrix).ComplexArray() Aa = Aa[ind.OffsetA:] // Ensure there are sufficient elements in A. Aa = Aa[:ind.LDa*ind.LDb] Ba := B.(*matrix.ComplexMatrix).ComplexArray() Ba = Ba[ind.OffsetB:] info = zgesv(ind.N, ind.Nrhs, Aa, ind.LDa, ipiv, Ba, ind.LDb) } if info != 0 { return onError(fmt.Sprintf("Gesv: lapack error: %d", info)) } return nil }
/* Solves a real or complex tridiagonal set of linear equations, given the LU factorization computed by gttrf(). PURPOSE solves A*X=B, if trans is PNoTrans solves A^T*X=B, if trans is PTrans solves A^H*X=B, if trans is PConjTrans On entry, DL, D, DU, DU2 and ipiv contain the LU factorization of an n by n tridiagonal matrix A as computed by gttrf(). On exit B is replaced by the solution X. ARGUMENTS. DL float or complex matrix D float or complex matrix. Must have the same type as dl. DU float or complex matrix. Must have the same type as dl. DU2 float or complex matrix. Must have the same type as dl. B float or complex matrix. Must have the same type oas dl. ipiv int vector OPTIONS trans PNoTrans, PTrans, PConjTrans n nonnegative integer. If negative, the default value is used. nrhs nonnegative integer. If negative, the default value is used. ldB positive integer, ldB >= max(1,n). If zero, the default value is used. offsetdl nonnegative integer offsetd nonnegative integer offsetdu nonnegative integer offsetB nonnegative integer */ func Gtrrs(DL, D, DU, DU2, B matrix.Matrix, ipiv []int32, opts ...linalg.Option) error { pars, err := linalg.GetParameters(opts...) if err != nil { return err } ind := linalg.GetIndexOpts(opts...) brows := ind.LDb if ind.OffsetD < 0 { return onError("Gttrs: offset D") } if ind.N < 0 { ind.N = D.NumElements() - ind.OffsetD } if ind.N < 0 { return onError("Gttrs: size D") } if ind.N == 0 { return nil } if ind.OffsetDL < 0 { return onError("Gttrs: offset DL") } sizeDL := DL.NumElements() if sizeDL < ind.OffsetDL+ind.N-1 { return onError("Gttrs: sizeDL") } if ind.OffsetDU < 0 { return onError("Gttrs: offset DU") } sizeDU := DU.NumElements() if sizeDU < ind.OffsetDU+ind.N-1 { return onError("Gttrs: sizeDU") } sizeDU2 := DU2.NumElements() if sizeDU2 < ind.N-2 { return onError("Gttrs: sizeDU2") } if ind.Nrhs < 0 { ind.Nrhs = B.Cols() } if ind.Nrhs == 0 { return nil } if ind.LDb == 0 { ind.LDb = max(1, B.LeadingIndex()) brows = max(1, B.Rows()) } if ind.LDb < max(1, ind.N) { return onError("Gttrs: ldB") } if ind.OffsetB < 0 { return onError("Gttrs: offset B") } sizeB := B.NumElements() if sizeB < ind.OffsetB+(ind.Nrhs-1)*brows+ind.N { return onError("Gttrs: sizeB") } if len(ipiv) < ind.N { return onError("Gttrs: size ipiv") } if !matrix.EqualTypes(DL, D, DU, DU2, B) { return onError("Gttrs: matrix types") } var info int = -1 switch DL.(type) { case *matrix.FloatMatrix: DLa := DL.(*matrix.FloatMatrix).FloatArray() Da := D.(*matrix.FloatMatrix).FloatArray() DUa := DU.(*matrix.FloatMatrix).FloatArray() DU2a := DU2.(*matrix.FloatMatrix).FloatArray() Ba := B.(*matrix.FloatMatrix).FloatArray() trans := linalg.ParamString(pars.Trans) info = dgttrs(trans, ind.N, ind.Nrhs, DLa[ind.OffsetDL:], Da[ind.OffsetD:], DUa[ind.OffsetDU:], DU2a, ipiv, Ba[ind.OffsetB:], ind.LDb) case *matrix.ComplexMatrix: return onError("Gttrs: complex valued not yet implemented") } if info != 0 { return onError(fmt.Sprintf("Gttrs lapack error: %d", info)) } return nil }
/* Solves a real or complex set of linear equations with a banded coefficient matrix, given the LU factorization computed by gbtrf() or gbsv(). PURPOSE Solves linear equations A*X = B, if trans is PNoTrans A^T*X = B, if trans is PTrans A^H*X = B, if trans is PConjTrans On entry, A and ipiv contain the LU factorization of an n by n band matrix A as computed by Getrf() or Gbsv(). On exit B is replaced by the solution X. ARGUMENTS A float or complex matrix B float or complex matrix. Must have the same type as A. ipiv int vector kl nonnegative integer OPTIONS trans PNoTrans, PTrans or PConjTrans n nonnegative integer. If negative, the default value is used. ku nonnegative integer. If negative, the default value is used. nrhs nonnegative integer. If negative, the default value is used. ldA positive integer, ldA >= 2*kl+ku+1. If zero, the default value is used. ldB positive integer, ldB >= max(1,n). If zero, the default value is used. offsetA nonnegative integer offsetB nonnegative integer; */ func Gbtrs(A, B matrix.Matrix, ipiv []int32, KL int, opts ...linalg.Option) error { pars, err := linalg.GetParameters(opts...) if err != nil { return err } ind := linalg.GetIndexOpts(opts...) ind.Kl = KL arows := ind.LDa brows := ind.LDb if ind.Kl < 0 { return onError("Gbtrs: invalid kl") } if ind.N < 0 { ind.N = A.Rows() } if ind.Nrhs < 0 { ind.Nrhs = A.Cols() } if ind.N == 0 || ind.Nrhs == 0 { return nil } if ind.Ku < 0 { ind.Ku = A.Rows() - 2*ind.Kl - 1 } if ind.Ku < 0 { return onError("Gbtrs: invalid ku") } if ind.LDa == 0 { ind.LDa = max(1, A.LeadingIndex()) arows = max(1, A.Rows()) } if ind.LDa < 2*ind.Kl+ind.Ku+1 { return onError("Gbtrs: ldA") } if ind.OffsetA < 0 { return onError("Gbtrs: offsetA") } sizeA := A.NumElements() if sizeA < ind.OffsetA+(ind.N-1)*arows+2*ind.Kl+ind.Ku+1 { return onError("Gbtrs: sizeA") } if ind.LDb == 0 { ind.LDb = max(1, B.LeadingIndex()) brows = max(1, B.Rows()) } if ind.OffsetB < 0 { return onError("Gbtrs: offsetB") } sizeB := B.NumElements() if sizeB < ind.OffsetB+(ind.Nrhs-1)*brows+ind.N { return onError("Gbtrs: sizeB") } if ipiv != nil && len(ipiv) < ind.N { return onError("Gbtrs: size ipiv") } if !matrix.EqualTypes(A, B) { return onError("Gbtrs: arguments not of same type") } info := -1 switch A.(type) { case *matrix.FloatMatrix: Aa := A.(*matrix.FloatMatrix).FloatArray() Ba := B.(*matrix.FloatMatrix).FloatArray() trans := linalg.ParamString(pars.Trans) info = dgbtrs(trans, ind.N, ind.Kl, ind.Ku, ind.Nrhs, Aa[ind.OffsetA:], ind.LDa, ipiv, Ba[ind.OffsetB:], ind.LDb) case *matrix.ComplexMatrix: return onError("Gbtrs: complex not yet implemented") } if info != 0 { return onError(fmt.Sprintf("Gbtrs lapack error: %d", info)) } return nil }
/* Solves a real or complex symmetric set of linear equations, given the LDL^T factorization computed by sytrf() or sysv(). PURPOSE Solves A*X = B where A is real or complex symmetric and n by n, and B is n by nrhs. On entry, A and ipiv contain the factorization of A as returned by Sytrf() or Sysv(). On exit, B is replaced by the solution. ARGUMENTS A float or complex matrix B float or complex matrix. Must have the same type as A. ipiv int vector OPTIONS uplo PLower or PUpper n nonnegative integer. If negative, the default value is used. nrhs nonnegative integer. If negative, the default value is used. ldA positive integer. ldA >= max(1,n). If zero, the default value is used. ldB nonnegative integer. ldB >= max(1,n). If zero, the default value is used. offsetA nonnegative integer offsetB nonnegative integer; */ func Sytrs(A, B matrix.Matrix, ipiv []int32, opts ...linalg.Option) error { pars, err := linalg.GetParameters(opts...) if err != nil { return err } ind := linalg.GetIndexOpts(opts...) arows := ind.LDa brows := ind.LDb if ind.N < 0 { ind.N = A.Rows() if ind.N != A.Cols() { return onError("Sytrs: A not square") } } if ind.Nrhs < 0 { ind.Nrhs = B.Cols() } if ind.N == 0 || ind.Nrhs == 0 { return nil } if ind.LDa == 0 { ind.LDa = max(1, A.LeadingIndex()) arows = max(1, A.Rows()) } if ind.LDa < max(1, ind.N) { return onError("Sytrs: ldA") } if ind.LDb == 0 { ind.LDb = max(1, B.LeadingIndex()) brows = max(1, B.Rows()) } if ind.LDb < max(1, ind.N) { return onError("Sytrs: ldB") } if ind.OffsetA < 0 { return onError("Sytrs: offsetA") } sizeA := A.NumElements() if sizeA < ind.OffsetA+(ind.N-1)*arows+ind.N { return onError("Sytrs: sizeA") } if ind.OffsetB < 0 { return onError("Sytrs: offsetB") } sizeB := B.NumElements() if sizeB < ind.OffsetB+(ind.Nrhs-1)*brows+ind.N { return onError("Sytrs: sizeB") } if ipiv != nil && len(ipiv) < ind.N { return onError("Sytrs: size ipiv") } if !matrix.EqualTypes(A, B) { return onError("Sytrs: arguments not of same type") } info := -1 switch A.(type) { case *matrix.FloatMatrix: Aa := A.(*matrix.FloatMatrix).FloatArray() Ba := B.(*matrix.FloatMatrix).FloatArray() uplo := linalg.ParamString(pars.Uplo) info = dsytrs(uplo, ind.N, ind.Nrhs, Aa[ind.OffsetA:], ind.LDa, ipiv, Ba[ind.OffsetB:], ind.LDb) case *matrix.ComplexMatrix: return onError("Sytrs: complex not yet implemented") } if info != 0 { return onError(fmt.Sprintf("Sytrs lapack error: %d", info)) } return nil }
/* Product with a real orthogonal matrix. PURPOSE Computes C := Q*C if side = PLeft and trans = PNoTrans C := Q^T*C if side = PLeft and trans = PTrans C := C*Q if side = PRight and trans = PNoTrans C := C*Q^T if side = PRight and trans = PTrans C is m by n and Q is a square orthogonal matrix computed by geqrf. Q is defined as a product of k elementary reflectors, stored as the first k columns of A and the first k entries of tau. ARGUMENTS A float matrix tau float matrix of length at least k C float matrix OPTIONS side PLeft or PRight trans PNoTrans or PTrans m integer. If negative, the default value is used. n integer. If negative, the default value is used. k integer. k <= m if side = PRight and k <= n if side = PLeft. If negative, the default value is used. ldA nonnegative integer. ldA >= max(1,m) if side = PLeft and ldA >= max(1,n) if side = PRight. If zero, the default value is used. ldC nonnegative integer. ldC >= max(1,m). If zero, the default value is used. offsetA nonnegative integer offsetB nonnegative integer */ func Ormqr(A, tau, C matrix.Matrix, opts ...linalg.Option) error { pars, err := linalg.GetParameters(opts...) if err != nil { return err } ind := linalg.GetIndexOpts(opts...) arows := ind.LDa crows := ind.LDc if ind.N < 0 { ind.N = C.Cols() } if ind.M < 0 { ind.M = C.Rows() } if ind.K < 0 { ind.K = tau.NumElements() } if ind.N == 0 || ind.M == 0 || ind.K == 0 { return nil } if ind.LDa == 0 { ind.LDa = max(1, A.LeadingIndex()) arows = max(1, A.Rows()) } if ind.LDc == 0 { ind.LDc = max(1, C.LeadingIndex()) crows = max(1, C.Rows()) } switch pars.Side { case linalg.PLeft: if ind.K > ind.M { onError("Ormqf: K") } if ind.LDa < max(1, ind.M) { return onError("Ormqf: ldA") } case linalg.PRight: if ind.K > ind.N { onError("Ormqf: K") } if ind.LDa < max(1, ind.N) { return onError("Ormqf: ldA") } } if ind.OffsetA < 0 { return onError("Ormqf: offsetA") } if A.NumElements() < ind.OffsetA+ind.K*arows { return onError("Ormqf: sizeA") } if ind.OffsetC < 0 { return onError("Ormqf: offsetC") } if C.NumElements() < ind.OffsetC+(ind.N-1)*crows+ind.M { return onError("Ormqf: sizeC") } if tau.NumElements() < ind.K { return onError("Ormqf: sizeTau") } if !matrix.EqualTypes(A, C, tau) { return onError("Ormqf: arguments not of same type") } info := -1 side := linalg.ParamString(pars.Side) trans := linalg.ParamString(pars.Trans) switch A.(type) { case *matrix.FloatMatrix: Aa := A.(*matrix.FloatMatrix).FloatArray() Ca := C.(*matrix.FloatMatrix).FloatArray() taua := tau.(*matrix.FloatMatrix).FloatArray() info = dormqr(side, trans, ind.M, ind.N, ind.K, Aa[ind.OffsetA:], ind.LDa, taua, Ca[ind.OffsetC:], ind.LDc) case *matrix.ComplexMatrix: return onError("Ormqf: complex not implemented yet") } if info != 0 { return onError(fmt.Sprintf("Ormqr: lapack error %d", info)) } return nil }