// 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/floats" "gonum.org/v1/gonum/lapack" "gonum.org/v1/gonum/lapack/lapack64" ) // Matrix is the basic matrix interface type. type Matrix interface { // Dims returns the dimensions of a Matrix. Dims() (r, c int) // At returns the value of a matrix element at row i, column j. // It will panic if i or j are out of bounds for the matrix. At(i, j int) float64 // T returns the transpose of the Matrix. Whether T returns a copy of the // underlying data is implementation dependent. // This method may be implemented using the Transpose type, which // provides an implicit matrix transpose. T() Matrix } // allMatrix represents the extra set of methods that all mat Matrix types // should satisfy. This is used to enforce compile-time consistency between the // Dense types, especially helpful when adding new features. type allMatrix interface { Reseter IsEmpty() bool Zero() } // denseMatrix represents the extra set of methods that all Dense Matrix types // should satisfy. This is used to enforce compile-time consistency between the // Dense types, especially helpful when adding new features. type denseMatrix interface { DiagView() Diagonal Tracer } var ( _ Matrix = Transpose{} _ Untransposer = Transpose{} ) // Transpose is a type for performing an implicit matrix transpose. It implements // the Matrix interface, returning values from the transpose of the matrix within. type Transpose struct { Matrix Matrix } // At returns the value of the element at row i and column j of the transposed // matrix, that is, row j and column i of the Matrix field. func (t Transpose) At(i, j int) float64 { return t.Matrix.At(j, i) } // Dims returns the dimensions of the transposed matrix. The number of rows returned // is the number of columns in the Matrix field, and the number of columns is // the number of rows in the Matrix field. func (t Transpose) Dims() (r, c int) { c, r = t.Matrix.Dims() return r, c } // T performs an implicit transpose by returning the Matrix field. func (t Transpose) T() Matrix { return t.Matrix } // Untranspose returns the Matrix field. func (t Transpose) Untranspose() Matrix { return t.Matrix } // Untransposer is a type that can undo an implicit transpose. type Untransposer interface { // Note: This interface is needed to unify all of the Transpose types. In // the mat methods, we need to test if the Matrix has been implicitly // transposed. If this is checked by testing for the specific Transpose type // then the behavior will be different if the user uses T() or TTri() for a // triangular matrix. // Untranspose returns the underlying Matrix stored for the implicit transpose. Untranspose() Matrix } // UntransposeBander is a type that can undo an implicit band transpose. type UntransposeBander interface { // Untranspose returns the underlying Banded stored for the implicit transpose. UntransposeBand() Banded } // UntransposeTrier is a type that can undo an implicit triangular transpose. type UntransposeTrier interface { // Untranspose returns the underlying Triangular stored for the implicit transpose. UntransposeTri() Triangular } // UntransposeTriBander is a type that can undo an implicit triangular banded // transpose. type UntransposeTriBander interface { // Untranspose returns the underlying Triangular stored for the implicit transpose. UntransposeTriBand() TriBanded } // Mutable is a matrix interface type that allows elements to be altered. type Mutable interface { // Set alters the matrix element at row i, column j to v. // It will panic if i or j are out of bounds for the matrix. Set(i, j int, v float64) Matrix } // A RowViewer can return a Vector reflecting a row that is backed by the matrix // data. The Vector returned will have length equal to the number of columns. type RowViewer interface { RowView(i int) Vector } // A RawRowViewer can return a slice of float64 reflecting a row that is backed by the matrix // data. type RawRowViewer interface { RawRowView(i int) []float64 } // A ColViewer can return a Vector reflecting a column that is backed by the matrix // data. The Vector returned will have length equal to the number of rows. type ColViewer interface { ColView(j int) Vector } // A RawColViewer can return a slice of float64 reflecting a column that is backed by the matrix // data. type RawColViewer interface { RawColView(j int) []float64 } // A ClonerFrom can make a copy of a into the receiver, overwriting the previous value of the // receiver. The clone operation does not make any restriction on shape and will not cause // shadowing. type ClonerFrom interface { CloneFrom(a Matrix) } // A Reseter can reset the matrix so that it can be reused as the receiver of a dimensionally // restricted operation. This is commonly used when the matrix is being used as a workspace // or temporary matrix. // // If the matrix is a view, using Reset may result in data corruption in elements outside // the view. Similarly, if the matrix shares backing data with another variable, using // Reset may lead to unexpected changes in data values. type Reseter interface { Reset() } // A Copier can make a copy of elements of a into the receiver. The submatrix copied // starts at row and column 0 and has dimensions equal to the minimum dimensions of // the two matrices. The number of row and columns copied is returned. // Copy will copy from a source that aliases the receiver unless the source is transposed; // an aliasing transpose copy will panic with the exception for a special case when // the source data has a unitary increment or stride. type Copier interface { Copy(a Matrix) (r, c int) } // A Grower can grow the size of the represented matrix by the given number of rows and columns. // Growing beyond the size given by the Caps method will result in the allocation of a new // matrix and copying of the elements. If Grow is called with negative increments it will // panic with ErrIndexOutOfRange. type Grower interface { Caps() (r, c int) Grow(r, c int) Matrix } // A BandWidther represents a banded matrix and can return the left and right half-bandwidths, k1 and // k2. type BandWidther interface { BandWidth() (k1, k2 int) } // A RawMatrixSetter can set the underlying blas64.General used by the receiver. There is no restriction // on the shape of the receiver. Changes to the receiver's elements will be reflected in the blas64.General.Data. type RawMatrixSetter interface { SetRawMatrix(a blas64.General) } // A RawMatrixer can return a blas64.General representation of the receiver. Changes to the blas64.General.Data // slice will be reflected in the original matrix, changes to the Rows, Cols and Stride fields will not. type RawMatrixer interface { RawMatrix() blas64.General } // A RawVectorer can return a blas64.Vector representation of the receiver. Changes to the blas64.Vector.Data // slice will be reflected in the original matrix, changes to the Inc field will not. type RawVectorer interface { RawVector() blas64.Vector } // A NonZeroDoer can call a function for each non-zero element of the receiver. // The parameters of the function are the element indices and its value. type NonZeroDoer interface { DoNonZero(func(i, j int, v float64)) } // A RowNonZeroDoer can call a function for each non-zero element of a row of the receiver. // The parameters of the function are the element indices and its value. type RowNonZeroDoer interface { DoRowNonZero(i int, fn func(i, j int, v float64)) } // A ColNonZeroDoer can call a function for each non-zero element of a column of the receiver. // The parameters of the function are the element indices and its value. type ColNonZeroDoer interface { DoColNonZero(j int, fn func(i, j int, v float64)) } // untranspose untransposes a matrix if applicable. If a is an Untransposer, then // untranspose returns the underlying matrix and true. If it is not, then it returns // the input matrix and false. func untranspose(a Matrix) (Matrix, bool) { if ut, ok := a.(Untransposer); ok { return ut.Untranspose(), true } return a, false } // untransposeExtract returns an untransposed matrix in a built-in matrix type. // // The untransposed matrix is returned unaltered if it is a built-in matrix type. // Otherwise, if it implements a Raw method, an appropriate built-in type value // is returned holding the raw matrix value of the input. If neither of these // is possible, the untransposed matrix is returned. func untransposeExtract(a Matrix) (Matrix, bool) { ut, trans := untranspose(a) switch m := ut.(type) { case *DiagDense, *SymBandDense, *TriBandDense, *BandDense, *TriDense, *SymDense, *Dense: return m, trans // TODO(btracey): Add here if we ever have an equivalent of RawDiagDense. case RawSymBander: rsb := m.RawSymBand() if rsb.Uplo != blas.Upper { return ut, trans } var sb SymBandDense sb.SetRawSymBand(rsb) return &sb, trans case RawTriBander: rtb := m.RawTriBand() if rtb.Diag == blas.Unit { return ut, trans } var tb TriBandDense tb.SetRawTriBand(rtb) return &tb, trans case RawBander: var b BandDense b.SetRawBand(m.RawBand()) return &b, trans case RawTriangular: rt := m.RawTriangular() if rt.Diag == blas.Unit { return ut, trans } var t TriDense t.SetRawTriangular(rt) return &t, trans case RawSymmetricer: rs := m.RawSymmetric() if rs.Uplo != blas.Upper { return ut, trans } var s SymDense s.SetRawSymmetric(rs) return &s, trans case RawMatrixer: var d Dense d.SetRawMatrix(m.RawMatrix()) return &d, trans default: return ut, trans } } // TODO(btracey): Consider adding CopyCol/CopyRow if the behavior seems useful. // TODO(btracey): Add in fast paths to Row/Col for the other concrete types // (TriDense, etc.) as well as relevant interfaces (RowColer, RawRowViewer, etc.) // Col copies the elements in the jth column of the matrix into the slice dst. // The length of the provided slice must equal the number of rows, unless the // slice is nil in which case a new slice is first allocated. func Col(dst []float64, j int, a Matrix) []float64 { r, c := a.Dims() if j < 0 || j >= c { panic(ErrColAccess) } if dst == nil { dst = make([]float64, r) } else { if len(dst) != r { panic(ErrColLength) } } aU, aTrans := untranspose(a) if rm, ok := aU.(RawMatrixer); ok { m := rm.RawMatrix() if aTrans { copy(dst, m.Data[j*m.Stride:j*m.Stride+m.Cols]) return dst } blas64.Copy(blas64.Vector{N: r, Inc: m.Stride, Data: m.Data[j:]}, blas64.Vector{N: r, Inc: 1, Data: dst}, ) return dst } for i := 0; i < r; i++ { dst[i] = a.At(i, j) } return dst } // Row copies the elements in the ith row of the matrix into the slice dst. // The length of the provided slice must equal the number of columns, unless the // slice is nil in which case a new slice is first allocated. func Row(dst []float64, i int, a Matrix) []float64 { r, c := a.Dims() if i < 0 || i >= r { panic(ErrColAccess) } if dst == nil { dst = make([]float64, c) } else { if len(dst) != c { panic(ErrRowLength) } } aU, aTrans := untranspose(a) if rm, ok := aU.(RawMatrixer); ok { m := rm.RawMatrix() if aTrans { blas64.Copy(blas64.Vector{N: c, Inc: m.Stride, Data: m.Data[i:]}, blas64.Vector{N: c, Inc: 1, Data: dst}, ) return dst } copy(dst, m.Data[i*m.Stride:i*m.Stride+m.Cols]) return dst } for j := 0; j < c; j++ { dst[j] = a.At(i, j) } return dst } // Cond returns the condition number of the given matrix under the given norm. // The condition number must be based on the 1-norm, 2-norm or ∞-norm. // Cond will panic with matrix.ErrShape if the matrix has zero size. // // BUG(btracey): The computation of the 1-norm and ∞-norm for non-square matrices // is innacurate, although is typically the right order of magnitude. See // https://github.com/xianyi/OpenBLAS/issues/636. While the value returned will // change with the resolution of this bug, the result from Cond will match the // condition number used internally. func Cond(a Matrix, norm float64) float64 { m, n := a.Dims() if m == 0 || n == 0 { panic(ErrShape) } var lnorm lapack.MatrixNorm switch norm { default: panic("mat: bad norm value") case 1: lnorm = lapack.MaxColumnSum case 2: var svd SVD ok := svd.Factorize(a, SVDNone) if !ok { return math.Inf(1) } return svd.Cond() case math.Inf(1): lnorm = lapack.MaxRowSum } if m == n { // Use the LU decomposition to compute the condition number. var lu LU lu.factorize(a, lnorm) return lu.Cond() } if m > n { // Use the QR factorization to compute the condition number. var qr QR qr.factorize(a, lnorm) return qr.Cond() } // Use the LQ factorization to compute the condition number. var lq LQ lq.factorize(a, lnorm) return lq.Cond() } // Det returns the determinant of the matrix a. In many expressions using LogDet // will be more numerically stable. func Det(a Matrix) float64 { det, sign := LogDet(a) return math.Exp(det) * sign } // Dot returns the sum of the element-wise product of a and b. // Dot panics if the matrix sizes are unequal. func Dot(a, b Vector) float64 { la := a.Len() lb := b.Len() if la != lb { panic(ErrShape) } if arv, ok := a.(RawVectorer); ok { if brv, ok := b.(RawVectorer); ok { return blas64.Dot(arv.RawVector(), brv.RawVector()) } } var sum float64 for i := 0; i < la; i++ { sum += a.At(i, 0) * b.At(i, 0) } return sum } // Equal returns whether the matrices a and b have the same size // and are element-wise equal. func Equal(a, b Matrix) bool { ar, ac := a.Dims() br, bc := b.Dims() if ar != br || ac != bc { return false } aU, aTrans := untranspose(a) bU, bTrans := untranspose(b) if rma, ok := aU.(RawMatrixer); ok { if rmb, ok := bU.(RawMatrixer); ok { ra := rma.RawMatrix() rb := rmb.RawMatrix() if aTrans == bTrans { for i := 0; i < ra.Rows; i++ { for j := 0; j < ra.Cols; j++ { if ra.Data[i*ra.Stride+j] != rb.Data[i*rb.Stride+j] { return false } } } return true } for i := 0; i < ra.Rows; i++ { for j := 0; j < ra.Cols; j++ { if ra.Data[i*ra.Stride+j] != rb.Data[j*rb.Stride+i] { return false } } } return true } } if rma, ok := aU.(RawSymmetricer); ok { if rmb, ok := bU.(RawSymmetricer); ok { ra := rma.RawSymmetric() rb := rmb.RawSymmetric() // Symmetric matrices are always upper and equal to their transpose. for i := 0; i < ra.N; i++ { for j := i; j < ra.N; j++ { if ra.Data[i*ra.Stride+j] != rb.Data[i*rb.Stride+j] { return false } } } return true } } if ra, ok := aU.(*VecDense); ok { if rb, ok := bU.(*VecDense); ok { // If the raw vectors are the same length they must either both be // transposed or both not transposed (or have length 1). for i := 0; i < ra.mat.N; i++ { if ra.mat.Data[i*ra.mat.Inc] != rb.mat.Data[i*rb.mat.Inc] { return false } } return true } } for i := 0; i < ar; i++ { for j := 0; j < ac; j++ { if a.At(i, j) != b.At(i, j) { return false } } } return true } // EqualApprox returns whether the matrices a and b have the same size and contain all equal // elements with tolerance for element-wise equality specified by epsilon. Matrices // with non-equal shapes are not equal. func EqualApprox(a, b Matrix, epsilon float64) bool { ar, ac := a.Dims() br, bc := b.Dims() if ar != br || ac != bc { return false } aU, aTrans := untranspose(a) bU, bTrans := untranspose(b) if rma, ok := aU.(RawMatrixer); ok { if rmb, ok := bU.(RawMatrixer); ok { ra := rma.RawMatrix() rb := rmb.RawMatrix() if aTrans == bTrans { for i := 0; i < ra.Rows; i++ { for j := 0; j < ra.Cols; j++ { if !floats.EqualWithinAbsOrRel(ra.Data[i*ra.Stride+j], rb.Data[i*rb.Stride+j], epsilon, epsilon) { return false } } } return true } for i := 0; i < ra.Rows; i++ { for j := 0; j < ra.Cols; j++ { if !floats.EqualWithinAbsOrRel(ra.Data[i*ra.Stride+j], rb.Data[j*rb.Stride+i], epsilon, epsilon) { return false } } } return true } } if rma, ok := aU.(RawSymmetricer); ok { if rmb, ok := bU.(RawSymmetricer); ok { ra := rma.RawSymmetric() rb := rmb.RawSymmetric() // Symmetric matrices are always upper and equal to their transpose. for i := 0; i < ra.N; i++ { for j := i; j < ra.N; j++ { if !floats.EqualWithinAbsOrRel(ra.Data[i*ra.Stride+j], rb.Data[i*rb.Stride+j], epsilon, epsilon) { return false } } } return true } } if ra, ok := aU.(*VecDense); ok { if rb, ok := bU.(*VecDense); ok { // If the raw vectors are the same length they must either both be // transposed or both not transposed (or have length 1). for i := 0; i < ra.mat.N; i++ { if !floats.EqualWithinAbsOrRel(ra.mat.Data[i*ra.mat.Inc], rb.mat.Data[i*rb.mat.Inc], epsilon, epsilon) { return false } } return true } } for i := 0; i < ar; i++ { for j := 0; j < ac; j++ { if !floats.EqualWithinAbsOrRel(a.At(i, j), b.At(i, j), epsilon, epsilon) { return false } } } return true } // LogDet returns the log of the determinant and the sign of the determinant // for the matrix that has been factorized. Numerical stability in product and // division expressions is generally improved by working in log space. func LogDet(a Matrix) (det float64, sign float64) { // TODO(btracey): Add specialized routines for TriDense, etc. var lu LU lu.Factorize(a) return lu.LogDet() } // Max returns the largest element value of the matrix A. // Max will panic with matrix.ErrShape if the matrix has zero size. func Max(a Matrix) float64 { r, c := a.Dims() if r == 0 || c == 0 { panic(ErrShape) } // Max(A) = Max(Aᵀ) aU, _ := untranspose(a) switch m := aU.(type) { case RawMatrixer: rm := m.RawMatrix() max := math.Inf(-1) for i := 0; i < rm.Rows; i++ { for _, v := range rm.Data[i*rm.Stride : i*rm.Stride+rm.Cols] { if v > max { max = v } } } return max case RawTriangular: rm := m.RawTriangular() // The max of a triangular is at least 0 unless the size is 1. if rm.N == 1 { return rm.Data[0] } max := 0.0 if rm.Uplo == blas.Upper { for i := 0; i < rm.N; i++ { for _, v := range rm.Data[i*rm.Stride+i : i*rm.Stride+rm.N] { if v > max { max = v } } } return max } for i := 0; i < rm.N; i++ { for _, v := range rm.Data[i*rm.Stride : i*rm.Stride+i+1] { if v > max { max = v } } } return max case RawSymmetricer: rm := m.RawSymmetric() if rm.Uplo != blas.Upper { panic(badSymTriangle) } max := math.Inf(-1) for i := 0; i < rm.N; i++ { for _, v := range rm.Data[i*rm.Stride+i : i*rm.Stride+rm.N] { if v > max { max = v } } } return max default: r, c := aU.Dims() max := math.Inf(-1) for i := 0; i < r; i++ { for j := 0; j < c; j++ { v := aU.At(i, j) if v > max { max = v } } } return max } } // Min returns the smallest element value of the matrix A. // Min will panic with matrix.ErrShape if the matrix has zero size. func Min(a Matrix) float64 { r, c := a.Dims() if r == 0 || c == 0 { panic(ErrShape) } // Min(A) = Min(Aᵀ) aU, _ := untranspose(a) switch m := aU.(type) { case RawMatrixer: rm := m.RawMatrix() min := math.Inf(1) for i := 0; i < rm.Rows; i++ { for _, v := range rm.Data[i*rm.Stride : i*rm.Stride+rm.Cols] { if v < min { min = v } } } return min case RawTriangular: rm := m.RawTriangular() // The min of a triangular is at most 0 unless the size is 1. if rm.N == 1 { return rm.Data[0] } min := 0.0 if rm.Uplo == blas.Upper { for i := 0; i < rm.N; i++ { for _, v := range rm.Data[i*rm.Stride+i : i*rm.Stride+rm.N] { if v < min { min = v } } } return min } for i := 0; i < rm.N; i++ { for _, v := range rm.Data[i*rm.Stride : i*rm.Stride+i+1] { if v < min { min = v } } } return min case RawSymmetricer: rm := m.RawSymmetric() if rm.Uplo != blas.Upper { panic(badSymTriangle) } min := math.Inf(1) for i := 0; i < rm.N; i++ { for _, v := range rm.Data[i*rm.Stride+i : i*rm.Stride+rm.N] { if v < min { min = v } } } return min default: r, c := aU.Dims() min := math.Inf(1) for i := 0; i < r; i++ { for j := 0; j < c; j++ { v := aU.At(i, j) if v < min { min = v } } } return min } } // Norm returns the specified (induced) norm of the matrix a. See // https://en.wikipedia.org/wiki/Matrix_norm for the definition of an induced norm. // // Valid norms are: // 1 - The maximum absolute column sum // 2 - Frobenius norm, the square root of the sum of the squares of the elements. // Inf - The maximum absolute row sum. // Norm will panic with ErrNormOrder if an illegal norm order is specified and // with matrix.ErrShape if the matrix has zero size. func Norm(a Matrix, norm float64) float64 { r, c := a.Dims() if r == 0 || c == 0 { panic(ErrShape) } aU, aTrans := untranspose(a) var work []float64 switch rma := aU.(type) { case RawMatrixer: rm := rma.RawMatrix() n := normLapack(norm, aTrans) if n == lapack.MaxColumnSum { work = getFloats(rm.Cols, false) defer putFloats(work) } return lapack64.Lange(n, rm, work) case RawTriangular: rm := rma.RawTriangular() n := normLapack(norm, aTrans) if n == lapack.MaxRowSum || n == lapack.MaxColumnSum { work = getFloats(rm.N, false) defer putFloats(work) } return lapack64.Lantr(n, rm, work) case RawSymmetricer: rm := rma.RawSymmetric() n := normLapack(norm, aTrans) if n == lapack.MaxRowSum || n == lapack.MaxColumnSum { work = getFloats(rm.N, false) defer putFloats(work) } return lapack64.Lansy(n, rm, work) case *VecDense: rv := rma.RawVector() switch norm { default: panic(ErrNormOrder) case 1: if aTrans { imax := blas64.Iamax(rv) return math.Abs(rma.At(imax, 0)) } return blas64.Asum(rv) case 2: return blas64.Nrm2(rv) case math.Inf(1): if aTrans { return blas64.Asum(rv) } imax := blas64.Iamax(rv) return math.Abs(rma.At(imax, 0)) } } switch norm { default: panic(ErrNormOrder) case 1: var max float64 for j := 0; j < c; j++ { var sum float64 for i := 0; i < r; i++ { sum += math.Abs(a.At(i, j)) } if sum > max { max = sum } } return max case 2: var sum float64 for i := 0; i < r; i++ { for j := 0; j < c; j++ { v := a.At(i, j) sum += v * v } } return math.Sqrt(sum) case math.Inf(1): var max float64 for i := 0; i < r; i++ { var sum float64 for j := 0; j < c; j++ { sum += math.Abs(a.At(i, j)) } if sum > max { max = sum } } return max } } // normLapack converts the float64 norm input in Norm to a lapack.MatrixNorm. func normLapack(norm float64, aTrans bool) lapack.MatrixNorm { switch norm { case 1: n := lapack.MaxColumnSum if aTrans { n = lapack.MaxRowSum } return n case 2: return lapack.Frobenius case math.Inf(1): n := lapack.MaxRowSum if aTrans { n = lapack.MaxColumnSum } return n default: panic(ErrNormOrder) } } // Sum returns the sum of the elements of the matrix. func Sum(a Matrix) float64 { var sum float64 aU, _ := untranspose(a) switch rma := aU.(type) { case RawSymmetricer: rm := rma.RawSymmetric() for i := 0; i < rm.N; i++ { // Diagonals count once while off-diagonals count twice. sum += rm.Data[i*rm.Stride+i] var s float64 for _, v := range rm.Data[i*rm.Stride+i+1 : i*rm.Stride+rm.N] { s += v } sum += 2 * s } return sum case RawTriangular: rm := rma.RawTriangular() var startIdx, endIdx int for i := 0; i < rm.N; i++ { // Start and end index for this triangle-row. switch rm.Uplo { case blas.Upper: startIdx = i endIdx = rm.N case blas.Lower: startIdx = 0 endIdx = i + 1 default: panic(badTriangle) } for _, v := range rm.Data[i*rm.Stride+startIdx : i*rm.Stride+endIdx] { sum += v } } return sum case RawMatrixer: rm := rma.RawMatrix() for i := 0; i < rm.Rows; i++ { for _, v := range rm.Data[i*rm.Stride : i*rm.Stride+rm.Cols] { sum += v } } return sum case *VecDense: rm := rma.RawVector() for i := 0; i < rm.N; i++ { sum += rm.Data[i*rm.Inc] } return sum default: r, c := a.Dims() for i := 0; i < r; i++ { for j := 0; j < c; j++ { sum += a.At(i, j) } } return sum } } // A Tracer can compute the trace of the matrix. Trace must panic if the // matrix is not square. type Tracer interface { Trace() float64 } // Trace returns the trace of the matrix. Trace will panic if the // matrix is not square. func Trace(a Matrix) float64 { m, _ := untransposeExtract(a) if t, ok := m.(Tracer); ok { return t.Trace() } r, c := a.Dims() if r != c { panic(ErrSquare) } var v float64 for i := 0; i < r; i++ { v += a.At(i, i) } return v } func min(a, b int) int { if a < b { return a } return b } func max(a, b int) int { if a > b { return a } return b } // use returns a float64 slice with l elements, using f if it // has the necessary capacity, otherwise creating a new slice. func use(f []float64, l int) []float64 { if l <= cap(f) { return f[:l] } return make([]float64, l) } // useZeroed returns a float64 slice with l elements, using f if it // has the necessary capacity, otherwise creating a new slice. The // elements of the returned slice are guaranteed to be zero. func useZeroed(f []float64, l int) []float64 { if l <= cap(f) { f = f[:l] zero(f) return f } return make([]float64, l) } // zero zeros the given slice's elements. func zero(f []float64) { for i := range f { f[i] = 0 } } // useInt returns an int slice with l elements, using i if it // has the necessary capacity, otherwise creating a new slice. func useInt(i []int, l int) []int { if l <= cap(i) { return i[:l] } return make([]int, l) }