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

 // 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"
 	"math/cmplx"

 	"gonum.org/v1/gonum/blas/cblas128"
 	"gonum.org/v1/gonum/floats/scalar"
 )

 // CMatrix is the basic matrix interface type for complex matrices.
 type CMatrix 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) complex128

 	// H returns the conjugate transpose of the Matrix. Whether H
 	// returns a copy of the underlying data is implementation dependent.
 	// This method may be implemented using the Conjugate type, which
 	// provides an implicit matrix conjugate transpose.
 	H() CMatrix
 }

 // A RawCMatrixer can return a cblas128.General representation of the receiver. Changes to the cblas128.General.Data
 // slice will be reflected in the original matrix, changes to the Rows, Cols and Stride fields will not.
 type RawCMatrixer interface {
 	RawCMatrix() cblas128.General
 }

 var (
 	_ CMatrix      = Conjugate{}
 	_ Unconjugator = Conjugate{}
 )

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

 // At returns the value of the element at row i and column j of the conjugate
 // transposed matrix, that is, row j and column i of the Matrix field.
 func (t Conjugate) At(i, j int) complex128 {
 	z := t.CMatrix.At(j, i)
 	return cmplx.Conj(z)
 }

 // 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 Conjugate) Dims() (r, c int) {
 	c, r = t.CMatrix.Dims()
 	return r, c
 }

 // H performs an implicit conjugate transpose by returning the Matrix field.
 func (t Conjugate) H() CMatrix {
 	return t.CMatrix
 }

 // Unconjugate returns the Matrix field.
 func (t Conjugate) Unconjugate() CMatrix {
 	return t.CMatrix
 }

 // Unconjugator is a type that can undo an implicit conjugate transpose.
 type Unconjugator interface {
 	// Note: This interface is needed to unify all of the Conjugate types. In
 	// the cmat128 methods, we need to test if the Matrix has been implicitly
 	// transposed. If this is checked by testing for the specific Conjugate type
 	// then the behavior will be different if the user uses H() or HTri() for a
 	// triangular matrix.

 	// Unconjugate returns the underlying Matrix stored for the implicit
 	// conjugate transpose.
 	Unconjugate() CMatrix
 }

 // useC returns a complex128 slice with l elements, using c if it
 // has the necessary capacity, otherwise creating a new slice.
 func useC(c []complex128, l int) []complex128 {
 	if l <= cap(c) {
 		return c[:l]
 	}
 	return make([]complex128, l)
 }

 // useZeroedC returns a complex128 slice with l elements, using c if it
 // has the necessary capacity, otherwise creating a new slice. The
 // elements of the returned slice are guaranteed to be zero.
 func useZeroedC(c []complex128, l int) []complex128 {
 	if l <= cap(c) {
 		c = c[:l]
 		zeroC(c)
 		return c
 	}
 	return make([]complex128, l)
 }

 // zeroC zeros the given slice's elements.
 func zeroC(c []complex128) {
 	for i := range c {
 		c[i] = 0
 	}
 }

 // unconjugate unconjugates a matrix if applicable. If a is an Unconjugator, then
 // unconjugate returns the underlying matrix and true. If it is not, then it returns
 // the input matrix and false.
 func unconjugate(a CMatrix) (CMatrix, bool) {
 	if ut, ok := a.(Unconjugator); ok {
 		return ut.Unconjugate(), true
 	}
 	return a, false
 }

 // CEqual returns whether the matrices a and b have the same size
 // and are element-wise equal.
 func CEqual(a, b CMatrix) bool {
 	ar, ac := a.Dims()
 	br, bc := b.Dims()
 	if ar != br || ac != bc {
 		return false
 	}
 	// TODO(btracey): Add in fast-paths.
 	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
 }

 // CEqualApprox 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 CEqualApprox(a, b CMatrix, epsilon float64) bool {
 	// TODO(btracey):
 	ar, ac := a.Dims()
 	br, bc := b.Dims()
 	if ar != br || ac != bc {
 		return false
 	}
 	for i := 0; i < ar; i++ {
 		for j := 0; j < ac; j++ {
 			if !cEqualWithinAbsOrRel(a.At(i, j), b.At(i, j), epsilon, epsilon) {
 				return false
 			}
 		}
 	}
 	return true
 }

 // TODO(btracey): Move these into a cmplxs if/when we have one.

 func cEqualWithinAbsOrRel(a, b complex128, absTol, relTol float64) bool {
 	if cEqualWithinAbs(a, b, absTol) {
 		return true
 	}
 	return cEqualWithinRel(a, b, relTol)
 }

 // cEqualWithinAbs returns true if a and b have an absolute
 // difference of less than tol.
 func cEqualWithinAbs(a, b complex128, tol float64) bool {
 	return a == b || cmplx.Abs(a-b) <= tol
 }

 const minNormalFloat64 = 2.2250738585072014e-308

 // cEqualWithinRel returns true if the difference between a and b
 // is not greater than tol times the greater value.
 func cEqualWithinRel(a, b complex128, tol float64) bool {
 	if a == b {
 		return true
 	}
 	if cmplx.IsNaN(a) || cmplx.IsNaN(b) {
 		return false
 	}
 	// Cannot play the same trick as in floats/scalar because there are multiple
 	// possible infinities.
 	if cmplx.IsInf(a) {
 		if !cmplx.IsInf(b) {
 			return false
 		}
 		ra := real(a)
 		if math.IsInf(ra, 0) {
 			if ra == real(b) {
 				return scalar.EqualWithinRel(imag(a), imag(b), tol)
 			}
 			return false
 		}
 		if imag(a) == imag(b) {
 			return scalar.EqualWithinRel(ra, real(b), tol)
 		}
 		return false
 	}
 	if cmplx.IsInf(b) {
 		return false
 	}

 	delta := cmplx.Abs(a - b)
 	if delta <= minNormalFloat64 {
 		return delta <= tol*minNormalFloat64
 	}
 	return delta/math.Max(cmplx.Abs(a), cmplx.Abs(b)) <= tol
 }
	// 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"
	"math/cmplx"

	"gonum.org/v1/gonum/blas/cblas128"
	"gonum.org/v1/gonum/floats/scalar"
	)

	// CMatrix is the basic matrix interface type for complex matrices.
	type CMatrix 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) complex128

	// H returns the conjugate transpose of the Matrix. Whether H
	// returns a copy of the underlying data is implementation dependent.
	// This method may be implemented using the Conjugate type, which
	// provides an implicit matrix conjugate transpose.
	H() CMatrix
	}

	// A RawCMatrixer can return a cblas128.General representation of the receiver. Changes to the cblas128.General.Data
	// slice will be reflected in the original matrix, changes to the Rows, Cols and Stride fields will not.
	type RawCMatrixer interface {
	RawCMatrix() cblas128.General
	}

	var (
	_ CMatrix = Conjugate{}
	_ Unconjugator = Conjugate{}
	)

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

	// At returns the value of the element at row i and column j of the conjugate
	// transposed matrix, that is, row j and column i of the Matrix field.
	func (t Conjugate) At(i, j int) complex128 {
	z := t.CMatrix.At(j, i)
	return cmplx.Conj(z)
	}

	// 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 Conjugate) Dims() (r, c int) {
	c, r = t.CMatrix.Dims()
	return r, c
	}

	// H performs an implicit conjugate transpose by returning the Matrix field.
	func (t Conjugate) H() CMatrix {
	return t.CMatrix
	}

	// Unconjugate returns the Matrix field.
	func (t Conjugate) Unconjugate() CMatrix {
	return t.CMatrix
	}

	// Unconjugator is a type that can undo an implicit conjugate transpose.
	type Unconjugator interface {
	// Note: This interface is needed to unify all of the Conjugate types. In
	// the cmat128 methods, we need to test if the Matrix has been implicitly
	// transposed. If this is checked by testing for the specific Conjugate type
	// then the behavior will be different if the user uses H() or HTri() for a
	// triangular matrix.

	// Unconjugate returns the underlying Matrix stored for the implicit
	// conjugate transpose.
	Unconjugate() CMatrix
	}

	// useC returns a complex128 slice with l elements, using c if it
	// has the necessary capacity, otherwise creating a new slice.
	func useC(c []complex128, l int) []complex128 {
	if l <= cap(c) {
	return c[:l]
	}
	return make([]complex128, l)
	}

	// useZeroedC returns a complex128 slice with l elements, using c if it
	// has the necessary capacity, otherwise creating a new slice. The
	// elements of the returned slice are guaranteed to be zero.
	func useZeroedC(c []complex128, l int) []complex128 {
	if l <= cap(c) {
	c = c[:l]
	zeroC(c)
	return c
	}
	return make([]complex128, l)
	}

	// zeroC zeros the given slice's elements.
	func zeroC(c []complex128) {
	for i := range c {
	c[i] = 0
	}
	}

	// unconjugate unconjugates a matrix if applicable. If a is an Unconjugator, then
	// unconjugate returns the underlying matrix and true. If it is not, then it returns
	// the input matrix and false.
	func unconjugate(a CMatrix) (CMatrix, bool) {
	if ut, ok := a.(Unconjugator); ok {
	return ut.Unconjugate(), true
	}
	return a, false
	}

	// CEqual returns whether the matrices a and b have the same size
	// and are element-wise equal.
	func CEqual(a, b CMatrix) bool {
	ar, ac := a.Dims()
	br, bc := b.Dims()
	if ar != br \|\| ac != bc {
	return false
	}
	// TODO(btracey): Add in fast-paths.
	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
	}

	// CEqualApprox 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 CEqualApprox(a, b CMatrix, epsilon float64) bool {
	// TODO(btracey):
	ar, ac := a.Dims()
	br, bc := b.Dims()
	if ar != br \|\| ac != bc {
	return false
	}
	for i := 0; i < ar; i++ {
	for j := 0; j < ac; j++ {
	if !cEqualWithinAbsOrRel(a.At(i, j), b.At(i, j), epsilon, epsilon) {
	return false
	}
	}
	}
	return true
	}

	// TODO(btracey): Move these into a cmplxs if/when we have one.

	func cEqualWithinAbsOrRel(a, b complex128, absTol, relTol float64) bool {
	if cEqualWithinAbs(a, b, absTol) {
	return true
	}
	return cEqualWithinRel(a, b, relTol)
	}

	// cEqualWithinAbs returns true if a and b have an absolute
	// difference of less than tol.
	func cEqualWithinAbs(a, b complex128, tol float64) bool {
	return a == b \|\| cmplx.Abs(a-b) <= tol
	}

	const minNormalFloat64 = 2.2250738585072014e-308

	// cEqualWithinRel returns true if the difference between a and b
	// is not greater than tol times the greater value.
	func cEqualWithinRel(a, b complex128, tol float64) bool {
	if a == b {
	return true
	}
	if cmplx.IsNaN(a) \|\| cmplx.IsNaN(b) {
	return false
	}
	// Cannot play the same trick as in floats/scalar because there are multiple
	// possible infinities.
	if cmplx.IsInf(a) {
	if !cmplx.IsInf(b) {
	return false
	}
	ra := real(a)
	if math.IsInf(ra, 0) {
	if ra == real(b) {
	return scalar.EqualWithinRel(imag(a), imag(b), tol)
	}
	return false
	}
	if imag(a) == imag(b) {
	return scalar.EqualWithinRel(ra, real(b), tol)
	}
	return false
	}
	if cmplx.IsInf(b) {
	return false
	}

	delta := cmplx.Abs(a - b)
	if delta <= minNormalFloat64 {
	return delta <= tol*minNormalFloat64
	}
	return delta/math.Max(cmplx.Abs(a), cmplx.Abs(b)) <= tol
	}