k3s/vendor/gonum.org/v1/gonum/mat/triband.go

// Copyright ©2018 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 (
	"gonum.org/v1/gonum/blas"
	"gonum.org/v1/gonum/blas/blas64"
)

var (
	triBand TriBanded
	_       Banded     = triBand
	_       Triangular = triBand

	triBandDense *TriBandDense
	_            Matrix           = triBandDense
	_            Triangular       = triBandDense
	_            Banded           = triBandDense
	_            TriBanded        = triBandDense
	_            RawTriBander     = triBandDense
	_            MutableTriBanded = triBandDense
)

// TriBanded is a triangular band matrix interface type.
type TriBanded interface {
	Banded

	// Triangle returns the number of rows/columns in the matrix and its
	// orientation.
	Triangle() (n int, kind TriKind)

	// TTri is the equivalent of the T() method in the Matrix interface but
	// guarantees the transpose is of triangular type.
	TTri() Triangular

	// TriBand returns the number of rows/columns in the matrix, the
	// size of the bandwidth, and the orientation.
	TriBand() (n, k int, kind TriKind)

	// TTriBand is the equivalent of the T() method in the Matrix interface but
	// guarantees the transpose is of banded triangular type.
	TTriBand() TriBanded
}

// A RawTriBander can return a blas64.TriangularBand representation of the receiver.
// Changes to the blas64.TriangularBand.Data slice will be reflected in the original
// matrix, changes to the N, K, Stride, Uplo and Diag fields will not.
type RawTriBander interface {
	RawTriBand() blas64.TriangularBand
}

// MutableTriBanded is a triangular band matrix interface type that allows
// elements to be altered.
type MutableTriBanded interface {
	TriBanded
	SetTriBand(i, j int, v float64)
}

var (
	tTriBand TransposeTriBand
	_        Matrix               = tTriBand
	_        TriBanded            = tTriBand
	_        Untransposer         = tTriBand
	_        UntransposeTrier     = tTriBand
	_        UntransposeBander    = tTriBand
	_        UntransposeTriBander = tTriBand
)

// TransposeTriBand is a type for performing an implicit transpose of a TriBanded
// matrix. It implements the TriBanded interface, returning values from the
// transpose of the matrix within.
type TransposeTriBand struct {
	TriBanded TriBanded
}

// 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 TriBanded field.
func (t TransposeTriBand) At(i, j int) float64 {
	return t.TriBanded.At(j, i)
}

// Dims returns the dimensions of the transposed matrix. TriBanded matrices are
// square and thus this is the same size as the original TriBanded.
func (t TransposeTriBand) Dims() (r, c int) {
	c, r = t.TriBanded.Dims()
	return r, c
}

// T performs an implicit transpose by returning the TriBand field.
func (t TransposeTriBand) T() Matrix {
	return t.TriBanded
}

// Triangle returns the number of rows/columns in the matrix and its orientation.
func (t TransposeTriBand) Triangle() (int, TriKind) {
	n, upper := t.TriBanded.Triangle()
	return n, !upper
}

// TTri performs an implicit transpose by returning the TriBand field.
func (t TransposeTriBand) TTri() Triangular {
	return t.TriBanded
}

// Bandwidth returns the upper and lower bandwidths of the matrix.
func (t TransposeTriBand) Bandwidth() (kl, ku int) {
	kl, ku = t.TriBanded.Bandwidth()
	return ku, kl
}

// TBand performs an implicit transpose by returning the TriBand field.
func (t TransposeTriBand) TBand() Banded {
	return t.TriBanded
}

// TriBand returns the number of rows/columns in the matrix, the
// size of the bandwidth, and the orientation.
func (t TransposeTriBand) TriBand() (n, k int, kind TriKind) {
	n, k, kind = t.TriBanded.TriBand()
	return n, k, !kind
}

// TTriBand performs an implicit transpose by returning the TriBand field.
func (t TransposeTriBand) TTriBand() TriBanded {
	return t.TriBanded
}

// Untranspose returns the Triangular field.
func (t TransposeTriBand) Untranspose() Matrix {
	return t.TriBanded
}

// UntransposeTri returns the underlying Triangular matrix.
func (t TransposeTriBand) UntransposeTri() Triangular {
	return t.TriBanded
}

// UntransposeBand returns the underlying Banded matrix.
func (t TransposeTriBand) UntransposeBand() Banded {
	return t.TriBanded
}

// UntransposeTriBand returns the underlying TriBanded matrix.
func (t TransposeTriBand) UntransposeTriBand() TriBanded {
	return t.TriBanded
}

// TriBandDense represents a triangular band matrix in dense storage format.
type TriBandDense struct {
	mat blas64.TriangularBand
}

// NewTriBandDense creates a new triangular banded matrix with n rows and columns,
// k bands in the direction of the specified kind. If data == nil,
// a new slice is allocated for the backing slice. If len(data) == n*(k+1),
// data is used as the backing slice, and changes to the elements of the returned
// TriBandDense will be reflected in data. If neither of these is true, NewTriBandDense
// will panic. k must be at least zero and less than n, otherwise NewTriBandDense will panic.
//
// The data must be arranged in row-major order constructed by removing the zeros
// from the rows outside the band and aligning the diagonals. For example, if
// the upper-triangular banded matrix
//    1  2  3  0  0  0
//    0  4  5  6  0  0
//    0  0  7  8  9  0
//    0  0  0 10 11 12
//    0  0  0 0  13 14
//    0  0  0 0  0  15
// becomes (* entries are never accessed)
//     1  2  3
//     4  5  6
//     7  8  9
//    10 11 12
//    13 14  *
//    15  *  *
// which is passed to NewTriBandDense as []float64{1, 2, ..., 15, *, *, *}
// with k=2 and kind = mat.Upper.
// The lower triangular banded matrix
//    1  0  0  0  0  0
//    2  3  0  0  0  0
//    4  5  6  0  0  0
//    0  7  8  9  0  0
//    0  0 10 11 12  0
//    0  0  0 13 14 15
// becomes (* entries are never accessed)
//     *  *  1
//     *  2  3
//     4  5  6
//     7  8  9
//    10 11 12
//    13 14 15
// which is passed to NewTriBandDense as []float64{*, *, *, 1, 2, ..., 15}
// with k=2 and kind = mat.Lower.
// Only the values in the band portion of the matrix are used.
func NewTriBandDense(n, k int, kind TriKind, data []float64) *TriBandDense {
	if n <= 0 || k < 0 {
		if n == 0 {
			panic(ErrZeroLength)
		}
		panic("mat: negative dimension")
	}
	if k+1 > n {
		panic("mat: band out of range")
	}
	bc := k + 1
	if data != nil && len(data) != n*bc {
		panic(ErrShape)
	}
	if data == nil {
		data = make([]float64, n*bc)
	}
	uplo := blas.Lower
	if kind {
		uplo = blas.Upper
	}
	return &TriBandDense{
		mat: blas64.TriangularBand{
			Uplo:   uplo,
			Diag:   blas.NonUnit,
			N:      n,
			K:      k,
			Data:   data,
			Stride: bc,
		},
	}
}

// Dims returns the number of rows and columns in the matrix.
func (t *TriBandDense) Dims() (r, c int) {
	return t.mat.N, t.mat.N
}

// T performs an implicit transpose by returning the receiver inside a Transpose.
func (t *TriBandDense) T() Matrix {
	return Transpose{t}
}

// IsZero returns whether the receiver is zero-sized. Zero-sized matrices can be the
// receiver for size-restricted operations. TriBandDense matrices can be zeroed using Reset.
func (t *TriBandDense) IsZero() bool {
	// It must be the case that t.Dims() returns
	// zeros in this case. See comment in Reset().
	return t.mat.Stride == 0
}

// Reset zeros the dimensions of the matrix so that it can be reused as the
// receiver of a dimensionally restricted operation.
//
// See the Reseter interface for more information.
func (t *TriBandDense) Reset() {
	t.mat.N = 0
	t.mat.Stride = 0
	t.mat.K = 0
	t.mat.Data = t.mat.Data[:0]
}

// Zero sets all of the matrix elements to zero.
func (t *TriBandDense) Zero() {
	if t.isUpper() {
		for i := 0; i < t.mat.N; i++ {
			u := min(1+t.mat.K, t.mat.N-i)
			zero(t.mat.Data[i*t.mat.Stride : i*t.mat.Stride+u])
		}
		return
	}
	for i := 0; i < t.mat.N; i++ {
		l := max(0, t.mat.K-i)
		zero(t.mat.Data[i*t.mat.Stride+l : i*t.mat.Stride+t.mat.K+1])
	}
}

func (t *TriBandDense) isUpper() bool {
	return isUpperUplo(t.mat.Uplo)
}

func (t *TriBandDense) triKind() TriKind {
	return TriKind(isUpperUplo(t.mat.Uplo))
}

// Triangle returns the dimension of t and its orientation. The returned
// orientation is only valid when n is not zero.
func (t *TriBandDense) Triangle() (n int, kind TriKind) {
	return t.mat.N, t.triKind()
}

// TTri performs an implicit transpose by returning the receiver inside a TransposeTri.
func (t *TriBandDense) TTri() Triangular {
	return TransposeTri{t}
}

// Bandwidth returns the upper and lower bandwidths of the matrix.
func (t *TriBandDense) Bandwidth() (kl, ku int) {
	if t.isUpper() {
		return 0, t.mat.K
	}
	return t.mat.K, 0
}

// TBand performs an implicit transpose by returning the receiver inside a TransposeBand.
func (t *TriBandDense) TBand() Banded {
	return TransposeBand{t}
}

// TriBand returns the number of rows/columns in the matrix, the
// size of the bandwidth, and the orientation.
func (t *TriBandDense) TriBand() (n, k int, kind TriKind) {
	return t.mat.N, t.mat.K, TriKind(!t.IsZero()) && t.triKind()
}

// TTriBand performs an implicit transpose by returning the receiver inside a TransposeTriBand.
func (t *TriBandDense) TTriBand() TriBanded {
	return TransposeTriBand{t}
}

// RawTriBand returns the underlying blas64.TriangularBand used by the receiver.
// Changes to the blas64.TriangularBand.Data slice will be reflected in the original
// matrix, changes to the N, K, Stride, Uplo and Diag fields will not.
func (t *TriBandDense) RawTriBand() blas64.TriangularBand {
	return t.mat
}

// SetRawTriBand sets the underlying blas64.TriangularBand used by the receiver.
// Changes to elements in the receiver following the call will be reflected
// in the input.
//
// The supplied TriangularBand must not use blas.Unit storage format.
func (t *TriBandDense) SetRawTriBand(mat blas64.TriangularBand) {
	if mat.Diag == blas.Unit {
		panic("mat: cannot set TriBand with Unit storage")
	}
	t.mat = mat
}

// DiagView returns the diagonal as a matrix backed by the original data.
func (t *TriBandDense) DiagView() Diagonal {
	if t.mat.Diag == blas.Unit {
		panic("mat: cannot take view of Unit diagonal")
	}
	n := t.mat.N
	data := t.mat.Data
	if !t.isUpper() {
		data = data[t.mat.K:]
	}
	return &DiagDense{
		mat: blas64.Vector{
			N:    n,
			Inc:  t.mat.Stride,
			Data: data[:(n-1)*t.mat.Stride+1],
		},
	}
}
Update vendor 2019-08-30 18:33:25 +00:00			`// Copyright ©2018 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 (`
			`"gonum.org/v1/gonum/blas"`
			`"gonum.org/v1/gonum/blas/blas64"`
			`)`

			`var (`
			`triBand TriBanded`
			`_ Banded = triBand`
			`_ Triangular = triBand`

			`triBandDense *TriBandDense`
			`_ Matrix = triBandDense`
			`_ Triangular = triBandDense`
			`_ Banded = triBandDense`
			`_ TriBanded = triBandDense`
			`_ RawTriBander = triBandDense`
			`_ MutableTriBanded = triBandDense`
			`)`

			`// TriBanded is a triangular band matrix interface type.`
			`type TriBanded interface {`
			`Banded`

			`// Triangle returns the number of rows/columns in the matrix and its`
			`// orientation.`
			`Triangle() (n int, kind TriKind)`

			`// TTri is the equivalent of the T() method in the Matrix interface but`
			`// guarantees the transpose is of triangular type.`
			`TTri() Triangular`

			`// TriBand returns the number of rows/columns in the matrix, the`
			`// size of the bandwidth, and the orientation.`
			`TriBand() (n, k int, kind TriKind)`

			`// TTriBand is the equivalent of the T() method in the Matrix interface but`
			`// guarantees the transpose is of banded triangular type.`
			`TTriBand() TriBanded`
			`}`

			`// A RawTriBander can return a blas64.TriangularBand representation of the receiver.`
			`// Changes to the blas64.TriangularBand.Data slice will be reflected in the original`
			`// matrix, changes to the N, K, Stride, Uplo and Diag fields will not.`
			`type RawTriBander interface {`
			`RawTriBand() blas64.TriangularBand`
			`}`

			`// MutableTriBanded is a triangular band matrix interface type that allows`
			`// elements to be altered.`
			`type MutableTriBanded interface {`
			`TriBanded`
			`SetTriBand(i, j int, v float64)`
			`}`

			`var (`
			`tTriBand TransposeTriBand`
			`_ Matrix = tTriBand`
			`_ TriBanded = tTriBand`
			`_ Untransposer = tTriBand`
			`_ UntransposeTrier = tTriBand`
			`_ UntransposeBander = tTriBand`
			`_ UntransposeTriBander = tTriBand`
			`)`

			`// TransposeTriBand is a type for performing an implicit transpose of a TriBanded`
			`// matrix. It implements the TriBanded interface, returning values from the`
			`// transpose of the matrix within.`
			`type TransposeTriBand struct {`
			`TriBanded TriBanded`
			`}`

			`// 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 TriBanded field.`
			`func (t TransposeTriBand) At(i, j int) float64 {`
			`return t.TriBanded.At(j, i)`
			`}`

			`// Dims returns the dimensions of the transposed matrix. TriBanded matrices are`
			`// square and thus this is the same size as the original TriBanded.`
			`func (t TransposeTriBand) Dims() (r, c int) {`
			`c, r = t.TriBanded.Dims()`
			`return r, c`
			`}`

			`// T performs an implicit transpose by returning the TriBand field.`
			`func (t TransposeTriBand) T() Matrix {`
			`return t.TriBanded`
			`}`

			`// Triangle returns the number of rows/columns in the matrix and its orientation.`
			`func (t TransposeTriBand) Triangle() (int, TriKind) {`
			`n, upper := t.TriBanded.Triangle()`
			`return n, !upper`
			`}`

			`// TTri performs an implicit transpose by returning the TriBand field.`
			`func (t TransposeTriBand) TTri() Triangular {`
			`return t.TriBanded`
			`}`

			`// Bandwidth returns the upper and lower bandwidths of the matrix.`
			`func (t TransposeTriBand) Bandwidth() (kl, ku int) {`
			`kl, ku = t.TriBanded.Bandwidth()`
			`return ku, kl`
			`}`

			`// TBand performs an implicit transpose by returning the TriBand field.`
			`func (t TransposeTriBand) TBand() Banded {`
			`return t.TriBanded`
			`}`

			`// TriBand returns the number of rows/columns in the matrix, the`
			`// size of the bandwidth, and the orientation.`
			`func (t TransposeTriBand) TriBand() (n, k int, kind TriKind) {`
			`n, k, kind = t.TriBanded.TriBand()`
			`return n, k, !kind`
			`}`

			`// TTriBand performs an implicit transpose by returning the TriBand field.`
			`func (t TransposeTriBand) TTriBand() TriBanded {`
			`return t.TriBanded`
			`}`

			`// Untranspose returns the Triangular field.`
			`func (t TransposeTriBand) Untranspose() Matrix {`
			`return t.TriBanded`
			`}`

			`// UntransposeTri returns the underlying Triangular matrix.`
			`func (t TransposeTriBand) UntransposeTri() Triangular {`
			`return t.TriBanded`
			`}`

			`// UntransposeBand returns the underlying Banded matrix.`
			`func (t TransposeTriBand) UntransposeBand() Banded {`
			`return t.TriBanded`
			`}`

			`// UntransposeTriBand returns the underlying TriBanded matrix.`
			`func (t TransposeTriBand) UntransposeTriBand() TriBanded {`
			`return t.TriBanded`
			`}`

			`// TriBandDense represents a triangular band matrix in dense storage format.`
			`type TriBandDense struct {`
			`mat blas64.TriangularBand`
			`}`

			`// NewTriBandDense creates a new triangular banded matrix with n rows and columns,`
			`// k bands in the direction of the specified kind. If data == nil,`
			`// a new slice is allocated for the backing slice. If len(data) == n*(k+1),`
			`// data is used as the backing slice, and changes to the elements of the returned`
			`// TriBandDense will be reflected in data. If neither of these is true, NewTriBandDense`
			`// will panic. k must be at least zero and less than n, otherwise NewTriBandDense will panic.`
			`//`
			`// The data must be arranged in row-major order constructed by removing the zeros`
			`// from the rows outside the band and aligning the diagonals. For example, if`
			`// the upper-triangular banded matrix`
			`// 1 2 3 0 0 0`
			`// 0 4 5 6 0 0`
			`// 0 0 7 8 9 0`
			`// 0 0 0 10 11 12`
			`// 0 0 0 0 13 14`
			`// 0 0 0 0 0 15`
			`// becomes (* entries are never accessed)`
			`// 1 2 3`
			`// 4 5 6`
			`// 7 8 9`
			`// 10 11 12`
			`// 13 14 *`
			`// 15 * *`
			`// which is passed to NewTriBandDense as []float64{1, 2, ..., 15, , , *}`
			`// with k=2 and kind = mat.Upper.`
			`// The lower triangular banded matrix`
			`// 1 0 0 0 0 0`
			`// 2 3 0 0 0 0`
			`// 4 5 6 0 0 0`
			`// 0 7 8 9 0 0`
			`// 0 0 10 11 12 0`
			`// 0 0 0 13 14 15`
			`// becomes (* entries are never accessed)`
			`// * * 1`
			`// * 2 3`
			`// 4 5 6`
			`// 7 8 9`
			`// 10 11 12`
			`// 13 14 15`
			`// which is passed to NewTriBandDense as []float64{, , *, 1, 2, ..., 15}`
			`// with k=2 and kind = mat.Lower.`
			`// Only the values in the band portion of the matrix are used.`
			`func NewTriBandDense(n, k int, kind TriKind, data []float64) *TriBandDense {`
			`if n <= 0 \|\| k < 0 {`
			`if n == 0 {`
			`panic(ErrZeroLength)`
			`}`
			`panic("mat: negative dimension")`
			`}`
			`if k+1 > n {`
			`panic("mat: band out of range")`
			`}`
			`bc := k + 1`
			`if data != nil && len(data) != n*bc {`
			`panic(ErrShape)`
			`}`
			`if data == nil {`
			`data = make([]float64, n*bc)`
			`}`
			`uplo := blas.Lower`
			`if kind {`
			`uplo = blas.Upper`
			`}`
			`return &TriBandDense{`
			`mat: blas64.TriangularBand{`
			`Uplo: uplo,`
			`Diag: blas.NonUnit,`
			`N: n,`
			`K: k,`
			`Data: data,`
			`Stride: bc,`
			`},`
			`}`
			`}`

			`// Dims returns the number of rows and columns in the matrix.`
			`func (t *TriBandDense) Dims() (r, c int) {`
			`return t.mat.N, t.mat.N`
			`}`

			`// T performs an implicit transpose by returning the receiver inside a Transpose.`
			`func (t *TriBandDense) T() Matrix {`
			`return Transpose{t}`
			`}`

			`// IsZero returns whether the receiver is zero-sized. Zero-sized matrices can be the`
			`// receiver for size-restricted operations. TriBandDense matrices can be zeroed using Reset.`
			`func (t *TriBandDense) IsZero() bool {`
			`// It must be the case that t.Dims() returns`
			`// zeros in this case. See comment in Reset().`
			`return t.mat.Stride == 0`
			`}`

			`// Reset zeros the dimensions of the matrix so that it can be reused as the`
			`// receiver of a dimensionally restricted operation.`
			`//`
			`// See the Reseter interface for more information.`
			`func (t *TriBandDense) Reset() {`
			`t.mat.N = 0`
			`t.mat.Stride = 0`
			`t.mat.K = 0`
			`t.mat.Data = t.mat.Data[:0]`
			`}`

			`// Zero sets all of the matrix elements to zero.`
			`func (t *TriBandDense) Zero() {`
			`if t.isUpper() {`
			`for i := 0; i < t.mat.N; i++ {`
			`u := min(1+t.mat.K, t.mat.N-i)`
			`zero(t.mat.Data[it.mat.Stride : it.mat.Stride+u])`
			`}`
			`return`
			`}`
			`for i := 0; i < t.mat.N; i++ {`
			`l := max(0, t.mat.K-i)`
			`zero(t.mat.Data[it.mat.Stride+l : it.mat.Stride+t.mat.K+1])`
			`}`
			`}`

			`func (t *TriBandDense) isUpper() bool {`
			`return isUpperUplo(t.mat.Uplo)`
			`}`

			`func (t *TriBandDense) triKind() TriKind {`
			`return TriKind(isUpperUplo(t.mat.Uplo))`
			`}`

			`// Triangle returns the dimension of t and its orientation. The returned`
			`// orientation is only valid when n is not zero.`
			`func (t *TriBandDense) Triangle() (n int, kind TriKind) {`
			`return t.mat.N, t.triKind()`
			`}`

			`// TTri performs an implicit transpose by returning the receiver inside a TransposeTri.`
			`func (t *TriBandDense) TTri() Triangular {`
			`return TransposeTri{t}`
			`}`

			`// Bandwidth returns the upper and lower bandwidths of the matrix.`
			`func (t *TriBandDense) Bandwidth() (kl, ku int) {`
			`if t.isUpper() {`
			`return 0, t.mat.K`
			`}`
			`return t.mat.K, 0`
			`}`

			`// TBand performs an implicit transpose by returning the receiver inside a TransposeBand.`
			`func (t *TriBandDense) TBand() Banded {`
			`return TransposeBand{t}`
			`}`

			`// TriBand returns the number of rows/columns in the matrix, the`
			`// size of the bandwidth, and the orientation.`
			`func (t *TriBandDense) TriBand() (n, k int, kind TriKind) {`
			`return t.mat.N, t.mat.K, TriKind(!t.IsZero()) && t.triKind()`
			`}`

			`// TTriBand performs an implicit transpose by returning the receiver inside a TransposeTriBand.`
			`func (t *TriBandDense) TTriBand() TriBanded {`
			`return TransposeTriBand{t}`
			`}`

			`// RawTriBand returns the underlying blas64.TriangularBand used by the receiver.`
			`// Changes to the blas64.TriangularBand.Data slice will be reflected in the original`
			`// matrix, changes to the N, K, Stride, Uplo and Diag fields will not.`
			`func (t *TriBandDense) RawTriBand() blas64.TriangularBand {`
			`return t.mat`
			`}`

			`// SetRawTriBand sets the underlying blas64.TriangularBand used by the receiver.`
			`// Changes to elements in the receiver following the call will be reflected`
			`// in the input.`
			`//`
			`// The supplied TriangularBand must not use blas.Unit storage format.`
			`func (t *TriBandDense) SetRawTriBand(mat blas64.TriangularBand) {`
			`if mat.Diag == blas.Unit {`
			`panic("mat: cannot set TriBand with Unit storage")`
			`}`
			`t.mat = mat`
			`}`

			`// DiagView returns the diagonal as a matrix backed by the original data.`
			`func (t *TriBandDense) DiagView() Diagonal {`
			`if t.mat.Diag == blas.Unit {`
			`panic("mat: cannot take view of Unit diagonal")`
			`}`
			`n := t.mat.N`
			`data := t.mat.Data`
			`if !t.isUpper() {`
			`data = data[t.mat.K:]`
			`}`
			`return &DiagDense{`
			`mat: blas64.Vector{`
			`N: n,`
			`Inc: t.mat.Stride,`
			`Data: data[:(n-1)*t.mat.Stride+1],`
			`},`
			`}`
			`}`