mat/diagonal.go - third_party/github.com/gonum/gonum - Git at Google

 // 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 (
 	diagDense *DiagDense
 	_         Matrix          = diagDense
 	_         Diagonal        = diagDense
 	_         MutableDiagonal = diagDense
 	_         Triangular      = diagDense
 	_         TriBanded       = diagDense
 	_         Symmetric       = diagDense
 	_         SymBanded       = diagDense
 	_         Banded          = diagDense
 	_         RawBander       = diagDense
 	_         RawSymBander    = diagDense

 	diag Diagonal
 	_    Matrix     = diag
 	_    Diagonal   = diag
 	_    Triangular = diag
 	_    TriBanded  = diag
 	_    Symmetric  = diag
 	_    SymBanded  = diag
 	_    Banded     = diag
 )

 // Diagonal represents a diagonal matrix, that is a square matrix that only
 // has non-zero terms on the diagonal.
 type Diagonal interface {
 	Matrix
 	// Diag returns the number of rows/columns in the matrix.
 	Diag() int

 	// Bandwidth and TBand are included in the Diagonal interface
 	// to allow the use of Diagonal types in banded functions.
 	// Bandwidth will always return (0, 0).
 	Bandwidth() (kl, ku int)
 	TBand() Banded

 	// Triangle and TTri are included in the Diagonal interface
 	// to allow the use of Diagonal types in triangular functions.
 	Triangle() (int, TriKind)
 	TTri() Triangular

 	// Symmetric and SymBand are included in the Diagonal interface
 	// to allow the use of Diagonal types in symmetric and banded symmetric
 	// functions respectively.
 	Symmetric() int
 	SymBand() (n, k int)

 	// TriBand and TTriBand are included in the Diagonal interface
 	// to allow the use of Diagonal types in triangular banded functions.
 	TriBand() (n, k int, kind TriKind)
 	TTriBand() TriBanded
 }

 // MutableDiagonal is a Diagonal matrix whose elements can be set.
 type MutableDiagonal interface {
 	Diagonal
 	SetDiag(i int, v float64)
 }

 // DiagDense represents a diagonal matrix in dense storage format.
 type DiagDense struct {
 	mat blas64.Vector
 }

 // NewDiagDense creates a new Diagonal matrix with n rows and n columns.
 // The length of data must be n or data must be nil, otherwise NewDiagDense
 // will panic. NewDiagDense will panic if n is zero.
 func NewDiagDense(n int, data []float64) *DiagDense {
 	if n <= 0 {
 		if n == 0 {
 			panic(ErrZeroLength)
 		}
 		panic("mat: negative dimension")
 	}
 	if data == nil {
 		data = make([]float64, n)
 	}
 	if len(data) != n {
 		panic(ErrShape)
 	}
 	return &DiagDense{
 		mat: blas64.Vector{N: n, Data: data, Inc: 1},
 	}
 }

 // Diag returns the dimension of the receiver.
 func (d *DiagDense) Diag() int {
 	return d.mat.N
 }

 // Dims returns the dimensions of the matrix.
 func (d *DiagDense) Dims() (r, c int) {
 	return d.mat.N, d.mat.N
 }

 // T returns the transpose of the matrix.
 func (d *DiagDense) T() Matrix {
 	return d
 }

 // TTri returns the transpose of the matrix. Note that Diagonal matrices are
 // Upper by default.
 func (d *DiagDense) TTri() Triangular {
 	return TransposeTri{d}
 }

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

 // TTriBand performs an implicit transpose by returning the receiver inside a
 // TransposeTriBand. Note that Diagonal matrices are Upper by default.
 func (d *DiagDense) TTriBand() TriBanded {
 	return TransposeTriBand{d}
 }

 // Bandwidth returns the upper and lower bandwidths of the matrix.
 // These values are always zero for diagonal matrices.
 func (d *DiagDense) Bandwidth() (kl, ku int) {
 	return 0, 0
 }

 // Symmetric implements the Symmetric interface.
 func (d *DiagDense) Symmetric() int {
 	return d.mat.N
 }

 // SymBand returns the number of rows/columns in the matrix, and the size of
 // the bandwidth.
 func (d *DiagDense) SymBand() (n, k int) {
 	return d.mat.N, 0
 }

 // Triangle implements the Triangular interface.
 func (d *DiagDense) Triangle() (int, TriKind) {
 	return d.mat.N, Upper
 }

 // TriBand returns the number of rows/columns in the matrix, the
 // size of the bandwidth, and the orientation. Note that Diagonal matrices are
 // Upper by default.
 func (d *DiagDense) TriBand() (n, k int, kind TriKind) {
 	return d.mat.N, 0, Upper
 }

 // Reset zeros the length 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 (d *DiagDense) Reset() {
 	// No change of Inc or n to 0 may be
 	// made unless both are set to 0.
 	d.mat.Inc = 0
 	d.mat.N = 0
 	d.mat.Data = d.mat.Data[:0]
 }

 // DiagView returns the diagonal as a matrix backed by the original data.
 func (d *DiagDense) DiagView() Diagonal {
 	return d
 }

 // DiagFrom copies the diagonal of m into the receiver. The receiver must
 // be min(r, c) long or zero. Otherwise DiagFrom will panic.
 func (d *DiagDense) DiagFrom(m Matrix) {
 	n := min(m.Dims())
 	d.reuseAs(n)

 	var vec blas64.Vector
 	switch r := m.(type) {
 	case *DiagDense:
 		vec = r.mat
 	case RawBander:
 		mat := r.RawBand()
 		vec = blas64.Vector{
 			N:    n,
 			Inc:  mat.Stride,
 			Data: mat.Data[mat.KL : (n-1)*mat.Stride+mat.KL+1],
 		}
 	case RawMatrixer:
 		mat := r.RawMatrix()
 		vec = blas64.Vector{
 			N:    n,
 			Inc:  mat.Stride + 1,
 			Data: mat.Data[:(n-1)*mat.Stride+n],
 		}
 	case RawSymBander:
 		mat := r.RawSymBand()
 		vec = blas64.Vector{
 			N:    n,
 			Inc:  mat.Stride,
 			Data: mat.Data[:(n-1)*mat.Stride+1],
 		}
 	case RawSymmetricer:
 		mat := r.RawSymmetric()
 		vec = blas64.Vector{
 			N:    n,
 			Inc:  mat.Stride + 1,
 			Data: mat.Data[:(n-1)*mat.Stride+n],
 		}
 	case RawTriBander:
 		mat := r.RawTriBand()
 		data := mat.Data
 		if mat.Uplo == blas.Lower {
 			data = data[mat.K:]
 		}
 		vec = blas64.Vector{
 			N:    n,
 			Inc:  mat.Stride,
 			Data: data[:(n-1)*mat.Stride+1],
 		}
 	case RawTriangular:
 		mat := r.RawTriangular()
 		if mat.Diag == blas.Unit {
 			for i := 0; i < n; i += d.mat.Inc {
 				d.mat.Data[i] = 1
 			}
 			return
 		}
 		vec = blas64.Vector{
 			N:    n,
 			Inc:  mat.Stride + 1,
 			Data: mat.Data[:(n-1)*mat.Stride+n],
 		}
 	case RawVectorer:
 		d.mat.Data[0] = r.RawVector().Data[0]
 		return
 	default:
 		for i := 0; i < n; i++ {
 			d.setDiag(i, m.At(i, i))
 		}
 		return
 	}
 	blas64.Copy(vec, d.mat)
 }

 // RawBand returns the underlying data used by the receiver represented
 // as a blas64.Band.
 // Changes to elements in the receiver following the call will be reflected
 // in returned blas64.Band.
 func (d *DiagDense) RawBand() blas64.Band {
 	return blas64.Band{
 		Rows:   d.mat.N,
 		Cols:   d.mat.N,
 		KL:     0,
 		KU:     0,
 		Stride: d.mat.Inc,
 		Data:   d.mat.Data,
 	}
 }

 // RawSymBand returns the underlying data used by the receiver represented
 // as a blas64.SymmetricBand.
 // Changes to elements in the receiver following the call will be reflected
 // in returned blas64.Band.
 func (d *DiagDense) RawSymBand() blas64.SymmetricBand {
 	return blas64.SymmetricBand{
 		N:      d.mat.N,
 		K:      0,
 		Stride: d.mat.Inc,
 		Uplo:   blas.Upper,
 		Data:   d.mat.Data,
 	}
 }

 // reuseAs resizes an empty diagonal to a r×r diagonal,
 // or checks that a non-empty matrix is r×r.
 func (d *DiagDense) reuseAs(r int) {
 	if r == 0 {
 		panic(ErrZeroLength)
 	}
 	if d.IsZero() {
 		d.mat = blas64.Vector{
 			Inc:  1,
 			Data: use(d.mat.Data, r),
 		}
 		d.mat.N = r
 		return
 	}
 	if r != d.mat.N {
 		panic(ErrShape)
 	}
 }

 // IsZero returns whether the receiver is zero-sized. Zero-sized vectors can be the
 // receiver for size-restricted operations. DiagDenses can be zeroed using Reset.
 func (d *DiagDense) IsZero() bool {
 	// It must be the case that d.Dims() returns
 	// zeros in this case. See comment in Reset().
 	return d.mat.Inc == 0
 }
	// 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 (
	diagDense *DiagDense
	_ Matrix = diagDense
	_ Diagonal = diagDense
	_ MutableDiagonal = diagDense
	_ Triangular = diagDense
	_ TriBanded = diagDense
	_ Symmetric = diagDense
	_ SymBanded = diagDense
	_ Banded = diagDense
	_ RawBander = diagDense
	_ RawSymBander = diagDense

	diag Diagonal
	_ Matrix = diag
	_ Diagonal = diag
	_ Triangular = diag
	_ TriBanded = diag
	_ Symmetric = diag
	_ SymBanded = diag
	_ Banded = diag
	)

	// Diagonal represents a diagonal matrix, that is a square matrix that only
	// has non-zero terms on the diagonal.
	type Diagonal interface {
	Matrix
	// Diag returns the number of rows/columns in the matrix.
	Diag() int

	// Bandwidth and TBand are included in the Diagonal interface
	// to allow the use of Diagonal types in banded functions.
	// Bandwidth will always return (0, 0).
	Bandwidth() (kl, ku int)
	TBand() Banded

	// Triangle and TTri are included in the Diagonal interface
	// to allow the use of Diagonal types in triangular functions.
	Triangle() (int, TriKind)
	TTri() Triangular

	// Symmetric and SymBand are included in the Diagonal interface
	// to allow the use of Diagonal types in symmetric and banded symmetric
	// functions respectively.
	Symmetric() int
	SymBand() (n, k int)

	// TriBand and TTriBand are included in the Diagonal interface
	// to allow the use of Diagonal types in triangular banded functions.
	TriBand() (n, k int, kind TriKind)
	TTriBand() TriBanded
	}

	// MutableDiagonal is a Diagonal matrix whose elements can be set.
	type MutableDiagonal interface {
	Diagonal
	SetDiag(i int, v float64)
	}

	// DiagDense represents a diagonal matrix in dense storage format.
	type DiagDense struct {
	mat blas64.Vector
	}

	// NewDiagDense creates a new Diagonal matrix with n rows and n columns.
	// The length of data must be n or data must be nil, otherwise NewDiagDense
	// will panic. NewDiagDense will panic if n is zero.
	func NewDiagDense(n int, data []float64) *DiagDense {
	if n <= 0 {
	if n == 0 {
	panic(ErrZeroLength)
	}
	panic("mat: negative dimension")
	}
	if data == nil {
	data = make([]float64, n)
	}
	if len(data) != n {
	panic(ErrShape)
	}
	return &DiagDense{
	mat: blas64.Vector{N: n, Data: data, Inc: 1},
	}
	}

	// Diag returns the dimension of the receiver.
	func (d *DiagDense) Diag() int {
	return d.mat.N
	}

	// Dims returns the dimensions of the matrix.
	func (d *DiagDense) Dims() (r, c int) {
	return d.mat.N, d.mat.N
	}

	// T returns the transpose of the matrix.
	func (d *DiagDense) T() Matrix {
	return d
	}

	// TTri returns the transpose of the matrix. Note that Diagonal matrices are
	// Upper by default.
	func (d *DiagDense) TTri() Triangular {
	return TransposeTri{d}
	}

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

	// TTriBand performs an implicit transpose by returning the receiver inside a
	// TransposeTriBand. Note that Diagonal matrices are Upper by default.
	func (d *DiagDense) TTriBand() TriBanded {
	return TransposeTriBand{d}
	}

	// Bandwidth returns the upper and lower bandwidths of the matrix.
	// These values are always zero for diagonal matrices.
	func (d *DiagDense) Bandwidth() (kl, ku int) {
	return 0, 0
	}

	// Symmetric implements the Symmetric interface.
	func (d *DiagDense) Symmetric() int {
	return d.mat.N
	}

	// SymBand returns the number of rows/columns in the matrix, and the size of
	// the bandwidth.
	func (d *DiagDense) SymBand() (n, k int) {
	return d.mat.N, 0
	}

	// Triangle implements the Triangular interface.
	func (d *DiagDense) Triangle() (int, TriKind) {
	return d.mat.N, Upper
	}

	// TriBand returns the number of rows/columns in the matrix, the
	// size of the bandwidth, and the orientation. Note that Diagonal matrices are
	// Upper by default.
	func (d *DiagDense) TriBand() (n, k int, kind TriKind) {
	return d.mat.N, 0, Upper
	}

	// Reset zeros the length 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 (d *DiagDense) Reset() {
	// No change of Inc or n to 0 may be
	// made unless both are set to 0.
	d.mat.Inc = 0
	d.mat.N = 0
	d.mat.Data = d.mat.Data[:0]
	}

	// DiagView returns the diagonal as a matrix backed by the original data.
	func (d *DiagDense) DiagView() Diagonal {
	return d
	}

	// DiagFrom copies the diagonal of m into the receiver. The receiver must
	// be min(r, c) long or zero. Otherwise DiagFrom will panic.
	func (d *DiagDense) DiagFrom(m Matrix) {
	n := min(m.Dims())
	d.reuseAs(n)

	var vec blas64.Vector
	switch r := m.(type) {
	case *DiagDense:
	vec = r.mat
	case RawBander:
	mat := r.RawBand()
	vec = blas64.Vector{
	N: n,
	Inc: mat.Stride,
	Data: mat.Data[mat.KL : (n-1)*mat.Stride+mat.KL+1],
	}
	case RawMatrixer:
	mat := r.RawMatrix()
	vec = blas64.Vector{
	N: n,
	Inc: mat.Stride + 1,
	Data: mat.Data[:(n-1)*mat.Stride+n],
	}
	case RawSymBander:
	mat := r.RawSymBand()
	vec = blas64.Vector{
	N: n,
	Inc: mat.Stride,
	Data: mat.Data[:(n-1)*mat.Stride+1],
	}
	case RawSymmetricer:
	mat := r.RawSymmetric()
	vec = blas64.Vector{
	N: n,
	Inc: mat.Stride + 1,
	Data: mat.Data[:(n-1)*mat.Stride+n],
	}
	case RawTriBander:
	mat := r.RawTriBand()
	data := mat.Data
	if mat.Uplo == blas.Lower {
	data = data[mat.K:]
	}
	vec = blas64.Vector{
	N: n,
	Inc: mat.Stride,
	Data: data[:(n-1)*mat.Stride+1],
	}
	case RawTriangular:
	mat := r.RawTriangular()
	if mat.Diag == blas.Unit {
	for i := 0; i < n; i += d.mat.Inc {
	d.mat.Data[i] = 1
	}
	return
	}
	vec = blas64.Vector{
	N: n,
	Inc: mat.Stride + 1,
	Data: mat.Data[:(n-1)*mat.Stride+n],
	}
	case RawVectorer:
	d.mat.Data[0] = r.RawVector().Data[0]
	return
	default:
	for i := 0; i < n; i++ {
	d.setDiag(i, m.At(i, i))
	}
	return
	}
	blas64.Copy(vec, d.mat)
	}

	// RawBand returns the underlying data used by the receiver represented
	// as a blas64.Band.
	// Changes to elements in the receiver following the call will be reflected
	// in returned blas64.Band.
	func (d *DiagDense) RawBand() blas64.Band {
	return blas64.Band{
	Rows: d.mat.N,
	Cols: d.mat.N,
	KL: 0,
	KU: 0,
	Stride: d.mat.Inc,
	Data: d.mat.Data,
	}
	}

	// RawSymBand returns the underlying data used by the receiver represented
	// as a blas64.SymmetricBand.
	// Changes to elements in the receiver following the call will be reflected
	// in returned blas64.Band.
	func (d *DiagDense) RawSymBand() blas64.SymmetricBand {
	return blas64.SymmetricBand{
	N: d.mat.N,
	K: 0,
	Stride: d.mat.Inc,
	Uplo: blas.Upper,
	Data: d.mat.Data,
	}
	}

	// reuseAs resizes an empty diagonal to a r×r diagonal,
	// or checks that a non-empty matrix is r×r.
	func (d *DiagDense) reuseAs(r int) {
	if r == 0 {
	panic(ErrZeroLength)
	}
	if d.IsZero() {
	d.mat = blas64.Vector{
	Inc: 1,
	Data: use(d.mat.Data, r),
	}
	d.mat.N = r
	return
	}
	if r != d.mat.N {
	panic(ErrShape)
	}
	}

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