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

 // Copyright ©2015 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/lapack/lapack64"
 )

 var (
 	triDense *TriDense
 	_        Matrix            = triDense
 	_        Triangular        = triDense
 	_        RawTriangular     = triDense
 	_        MutableTriangular = triDense

 	_ NonZeroDoer    = triDense
 	_ RowNonZeroDoer = triDense
 	_ ColNonZeroDoer = triDense
 )

 const badTriCap = "mat: bad capacity for TriDense"

 // TriDense represents an upper or lower triangular matrix in dense storage
 // format.
 type TriDense struct {
 	mat blas64.Triangular
 	cap int
 }

 // Triangular represents a triangular matrix. Triangular matrices are always square.
 type Triangular interface {
 	Matrix
 	// Triangular 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
 }

 // A RawTriangular can return a view of itself as a BLAS Triangular matrix.
 type RawTriangular interface {
 	RawTriangular() blas64.Triangular
 }

 // A MutableTriangular can set elements of a triangular matrix.
 type MutableTriangular interface {
 	Triangular
 	SetTri(i, j int, v float64)
 }

 var (
 	_ Matrix           = TransposeTri{}
 	_ Triangular       = TransposeTri{}
 	_ UntransposeTrier = TransposeTri{}
 )

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

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

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

 // T performs an implicit transpose by returning the Triangular field.
 func (t TransposeTri) T() Matrix {
 	return t.Triangular
 }

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

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

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

 func (t TransposeTri) UntransposeTri() Triangular {
 	return t.Triangular
 }

 // NewTriDense creates a new Triangular matrix with n rows and columns. If data == nil,
 // a new slice is allocated for the backing slice. If len(data) == n*n, data is
 // used as the backing slice, and changes to the elements of the returned TriDense
 // will be reflected in data. If neither of these is true, NewTriDense will panic.
 //
 // The data must be arranged in row-major order, i.e. the (i*c + j)-th
 // element in the data slice is the {i, j}-th element in the matrix.
 // Only the values in the triangular portion corresponding to kind are used.
 func NewTriDense(n int, kind TriKind, data []float64) *TriDense {
 	if n < 0 {
 		panic("mat: negative dimension")
 	}
 	if data != nil && len(data) != n*n {
 		panic(ErrShape)
 	}
 	if data == nil {
 		data = make([]float64, n*n)
 	}
 	uplo := blas.Lower
 	if kind == Upper {
 		uplo = blas.Upper
 	}
 	return &TriDense{
 		mat: blas64.Triangular{
 			N:      n,
 			Stride: n,
 			Data:   data,
 			Uplo:   uplo,
 			Diag:   blas.NonUnit,
 		},
 		cap: n,
 	}
 }

 func (t *TriDense) Dims() (r, c int) {
 	return t.mat.N, t.mat.N
 }

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

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

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

 func isUpperUplo(u blas.Uplo) bool {
 	switch u {
 	case blas.Upper:
 		return true
 	case blas.Lower:
 		return false
 	default:
 		panic(badTriangle)
 	}
 }

 // asSymBlas returns the receiver restructured as a blas64.Symmetric with the
 // same backing memory. Panics if the receiver is unit.
 // This returns a blas64.Symmetric and not a *SymDense because SymDense can only
 // be upper triangular.
 func (t *TriDense) asSymBlas() blas64.Symmetric {
 	if t.mat.Diag == blas.Unit {
 		panic("mat: cannot convert unit TriDense into blas64.Symmetric")
 	}
 	return blas64.Symmetric{
 		N:      t.mat.N,
 		Stride: t.mat.Stride,
 		Data:   t.mat.Data,
 		Uplo:   t.mat.Uplo,
 	}
 }

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

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

 func (t *TriDense) RawTriangular() blas64.Triangular {
 	return t.mat
 }

 // 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 *TriDense) Reset() {
 	// N and Stride must be zeroed in unison.
 	t.mat.N, t.mat.Stride = 0, 0
 	// Defensively zero Uplo to ensure
 	// it is set correctly later.
 	t.mat.Uplo = 0
 	t.mat.Data = t.mat.Data[:0]
 }

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

 // 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 untransposeTri(a Triangular) (Triangular, bool) {
 	if ut, ok := a.(UntransposeTrier); ok {
 		return ut.UntransposeTri(), true
 	}
 	return a, false
 }

 // reuseAs resizes a zero receiver to an n×n triangular matrix with the given
 // orientation. If the receiver is non-zero, reuseAs checks that the receiver
 // is the correct size and orientation.
 func (t *TriDense) reuseAs(n int, kind TriKind) {
 	ul := blas.Lower
 	if kind == Upper {
 		ul = blas.Upper
 	}
 	if t.mat.N > t.cap {
 		panic(badTriCap)
 	}
 	if t.IsZero() {
 		t.mat = blas64.Triangular{
 			N:      n,
 			Stride: n,
 			Diag:   blas.NonUnit,
 			Data:   use(t.mat.Data, n*n),
 			Uplo:   ul,
 		}
 		t.cap = n
 		return
 	}
 	if t.mat.N != n {
 		panic(ErrShape)
 	}
 	if t.mat.Uplo != ul {
 		panic(ErrTriangle)
 	}
 }

 // isolatedWorkspace returns a new TriDense matrix w with the size of a and
 // returns a callback to defer which performs cleanup at the return of the call.
 // This should be used when a method receiver is the same pointer as an input argument.
 func (t *TriDense) isolatedWorkspace(a Triangular) (w *TriDense, restore func()) {
 	n, kind := a.Triangle()
 	if n == 0 {
 		panic("zero size")
 	}
 	w = getWorkspaceTri(n, kind, false)
 	return w, func() {
 		t.Copy(w)
 		putWorkspaceTri(w)
 	}
 }

 // Copy makes a copy of elements of a into the receiver. It is similar to the
 // built-in copy; it copies as much as the overlap between the two matrices and
 // returns the number of rows and columns it copied. Only elements within the
 // receiver's non-zero triangle are set.
 //
 // See the Copier interface for more information.
 func (t *TriDense) Copy(a Matrix) (r, c int) {
 	r, c = a.Dims()
 	r = min(r, t.mat.N)
 	c = min(c, t.mat.N)
 	if r == 0 || c == 0 {
 		return 0, 0
 	}

 	switch a := a.(type) {
 	case RawMatrixer:
 		amat := a.RawMatrix()
 		if t.isUpper() {
 			for i := 0; i < r; i++ {
 				copy(t.mat.Data[i*t.mat.Stride+i:i*t.mat.Stride+c], amat.Data[i*amat.Stride+i:i*amat.Stride+c])
 			}
 		} else {
 			for i := 0; i < r; i++ {
 				copy(t.mat.Data[i*t.mat.Stride:i*t.mat.Stride+i+1], amat.Data[i*amat.Stride:i*amat.Stride+i+1])
 			}
 		}
 	case RawTriangular:
 		amat := a.RawTriangular()
 		aIsUpper := isUpperUplo(amat.Uplo)
 		tIsUpper := t.isUpper()
 		switch {
 		case tIsUpper && aIsUpper:
 			for i := 0; i < r; i++ {
 				copy(t.mat.Data[i*t.mat.Stride+i:i*t.mat.Stride+c], amat.Data[i*amat.Stride+i:i*amat.Stride+c])
 			}
 		case !tIsUpper && !aIsUpper:
 			for i := 0; i < r; i++ {
 				copy(t.mat.Data[i*t.mat.Stride:i*t.mat.Stride+i+1], amat.Data[i*amat.Stride:i*amat.Stride+i+1])
 			}
 		default:
 			for i := 0; i < r; i++ {
 				t.set(i, i, amat.Data[i*amat.Stride+i])
 			}
 		}
 	default:
 		isUpper := t.isUpper()
 		for i := 0; i < r; i++ {
 			if isUpper {
 				for j := i; j < c; j++ {
 					t.set(i, j, a.At(i, j))
 				}
 			} else {
 				for j := 0; j <= i; j++ {
 					t.set(i, j, a.At(i, j))
 				}
 			}
 		}
 	}

 	return r, c
 }

 // InverseTri computes the inverse of the triangular matrix a, storing the result
 // into the receiver. If a is ill-conditioned, a Condition error will be returned.
 // Note that matrix inversion is numerically unstable, and should generally be
 // avoided where possible, for example by using the Solve routines.
 func (t *TriDense) InverseTri(a Triangular) error {
 	if rt, ok := a.(RawTriangular); ok {
 		t.checkOverlap(rt.RawTriangular())
 	}
 	n, _ := a.Triangle()
 	t.reuseAs(a.Triangle())
 	t.Copy(a)
 	work := getFloats(3*n, false)
 	iwork := getInts(n, false)
 	cond := lapack64.Trcon(CondNorm, t.mat, work, iwork)
 	putFloats(work)
 	putInts(iwork)
 	if math.IsInf(cond, 1) {
 		return Condition(cond)
 	}
 	ok := lapack64.Trtri(t.mat)
 	if !ok {
 		return Condition(math.Inf(1))
 	}
 	if cond > ConditionTolerance {
 		return Condition(cond)
 	}
 	return nil
 }

 // MulTri takes the product of triangular matrices a and b and places the result
 // in the receiver. The size of a and b must match, and they both must have the
 // same TriKind, or Mul will panic.
 func (t *TriDense) MulTri(a, b Triangular) {
 	n, kind := a.Triangle()
 	nb, kindb := b.Triangle()
 	if n != nb {
 		panic(ErrShape)
 	}
 	if kind != kindb {
 		panic(ErrTriangle)
 	}

 	aU, _ := untransposeTri(a)
 	bU, _ := untransposeTri(b)
 	t.reuseAs(n, kind)
 	var restore func()
 	if t == aU {
 		t, restore = t.isolatedWorkspace(aU)
 		defer restore()
 	} else if t == bU {
 		t, restore = t.isolatedWorkspace(bU)
 		defer restore()
 	}

 	// TODO(btracey): Improve the set of fast-paths.
 	if kind == Upper {
 		for i := 0; i < n; i++ {
 			for j := i; j < n; j++ {
 				var v float64
 				for k := i; k <= j; k++ {
 					v += a.At(i, k) * b.At(k, j)
 				}
 				t.SetTri(i, j, v)
 			}
 		}
 		return
 	}
 	for i := 0; i < n; i++ {
 		for j := 0; j <= i; j++ {
 			var v float64
 			for k := j; k <= i; k++ {
 				v += a.At(i, k) * b.At(k, j)
 			}
 			t.SetTri(i, j, v)
 		}
 	}
 }

 // copySymIntoTriangle copies a symmetric matrix into a TriDense
 func copySymIntoTriangle(t *TriDense, s Symmetric) {
 	n, upper := t.Triangle()
 	ns := s.Symmetric()
 	if n != ns {
 		panic("mat: triangle size mismatch")
 	}
 	ts := t.mat.Stride
 	if rs, ok := s.(RawSymmetricer); ok {
 		sd := rs.RawSymmetric()
 		ss := sd.Stride
 		if upper {
 			if sd.Uplo == blas.Upper {
 				for i := 0; i < n; i++ {
 					copy(t.mat.Data[i*ts+i:i*ts+n], sd.Data[i*ss+i:i*ss+n])
 				}
 				return
 			}
 			for i := 0; i < n; i++ {
 				for j := i; j < n; j++ {
 					t.mat.Data[i*ts+j] = sd.Data[j*ss+i]
 				}
 			}
 			return
 		}
 		if sd.Uplo == blas.Upper {
 			for i := 0; i < n; i++ {
 				for j := 0; j <= i; j++ {
 					t.mat.Data[i*ts+j] = sd.Data[j*ss+i]
 				}
 			}
 			return
 		}
 		for i := 0; i < n; i++ {
 			copy(t.mat.Data[i*ts:i*ts+i+1], sd.Data[i*ss:i*ss+i+1])
 		}
 		return
 	}
 	if upper {
 		for i := 0; i < n; i++ {
 			for j := i; j < n; j++ {
 				t.mat.Data[i*ts+j] = s.At(i, j)
 			}
 		}
 		return
 	}
 	for i := 0; i < n; i++ {
 		for j := 0; j <= i; j++ {
 			t.mat.Data[i*ts+j] = s.At(i, j)
 		}
 	}
 }

 // DoNonZero calls the function fn for each of the non-zero elements of t. The function fn
 // takes a row/column index and the element value of t at (i, j).
 func (t *TriDense) DoNonZero(fn func(i, j int, v float64)) {
 	if t.isUpper() {
 		for i := 0; i < t.mat.N; i++ {
 			for j := i; j < t.mat.N; j++ {
 				v := t.at(i, j)
 				if v != 0 {
 					fn(i, j, v)
 				}
 			}
 		}
 		return
 	}
 	for i := 0; i < t.mat.N; i++ {
 		for j := 0; j <= i; j++ {
 			v := t.at(i, j)
 			if v != 0 {
 				fn(i, j, v)
 			}
 		}
 	}
 }

 // DoRowNonZero calls the function fn for each of the non-zero elements of row i of t. The function fn
 // takes a row/column index and the element value of t at (i, j).
 func (t *TriDense) DoRowNonZero(i int, fn func(i, j int, v float64)) {
 	if i < 0 || t.mat.N <= i {
 		panic(ErrRowAccess)
 	}
 	if t.isUpper() {
 		for j := i; j < t.mat.N; j++ {
 			v := t.at(i, j)
 			if v != 0 {
 				fn(i, j, v)
 			}
 		}
 		return
 	}
 	for j := 0; j <= i; j++ {
 		v := t.at(i, j)
 		if v != 0 {
 			fn(i, j, v)
 		}
 	}
 }

 // DoColNonZero calls the function fn for each of the non-zero elements of column j of t. The function fn
 // takes a row/column index and the element value of t at (i, j).
 func (t *TriDense) DoColNonZero(j int, fn func(i, j int, v float64)) {
 	if j < 0 || t.mat.N <= j {
 		panic(ErrColAccess)
 	}
 	if t.isUpper() {
 		for i := 0; i <= j; i++ {
 			v := t.at(i, j)
 			if v != 0 {
 				fn(i, j, v)
 			}
 		}
 		return
 	}
 	for i := j; i < t.mat.N; i++ {
 		v := t.at(i, j)
 		if v != 0 {
 			fn(i, j, v)
 		}
 	}
 }
	// Copyright ©2015 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/lapack/lapack64"
	)

	var (
	triDense *TriDense
	_ Matrix = triDense
	_ Triangular = triDense
	_ RawTriangular = triDense
	_ MutableTriangular = triDense

	_ NonZeroDoer = triDense
	_ RowNonZeroDoer = triDense
	_ ColNonZeroDoer = triDense
	)

	const badTriCap = "mat: bad capacity for TriDense"

	// TriDense represents an upper or lower triangular matrix in dense storage
	// format.
	type TriDense struct {
	mat blas64.Triangular
	cap int
	}

	// Triangular represents a triangular matrix. Triangular matrices are always square.
	type Triangular interface {
	Matrix
	// Triangular 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
	}

	// A RawTriangular can return a view of itself as a BLAS Triangular matrix.
	type RawTriangular interface {
	RawTriangular() blas64.Triangular
	}

	// A MutableTriangular can set elements of a triangular matrix.
	type MutableTriangular interface {
	Triangular
	SetTri(i, j int, v float64)
	}

	var (
	_ Matrix = TransposeTri{}
	_ Triangular = TransposeTri{}
	_ UntransposeTrier = TransposeTri{}
	)

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

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

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

	// T performs an implicit transpose by returning the Triangular field.
	func (t TransposeTri) T() Matrix {
	return t.Triangular
	}

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

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

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

	func (t TransposeTri) UntransposeTri() Triangular {
	return t.Triangular
	}

	// NewTriDense creates a new Triangular matrix with n rows and columns. If data == nil,
	// a new slice is allocated for the backing slice. If len(data) == n*n, data is
	// used as the backing slice, and changes to the elements of the returned TriDense
	// will be reflected in data. If neither of these is true, NewTriDense will panic.
	//
	// The data must be arranged in row-major order, i.e. the (i*c + j)-th
	// element in the data slice is the {i, j}-th element in the matrix.
	// Only the values in the triangular portion corresponding to kind are used.
	func NewTriDense(n int, kind TriKind, data []float64) *TriDense {
	if n < 0 {
	panic("mat: negative dimension")
	}
	if data != nil && len(data) != n*n {
	panic(ErrShape)
	}
	if data == nil {
	data = make([]float64, n*n)
	}
	uplo := blas.Lower
	if kind == Upper {
	uplo = blas.Upper
	}
	return &TriDense{
	mat: blas64.Triangular{
	N: n,
	Stride: n,
	Data: data,
	Uplo: uplo,
	Diag: blas.NonUnit,
	},
	cap: n,
	}
	}

	func (t *TriDense) Dims() (r, c int) {
	return t.mat.N, t.mat.N
	}

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

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

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

	func isUpperUplo(u blas.Uplo) bool {
	switch u {
	case blas.Upper:
	return true
	case blas.Lower:
	return false
	default:
	panic(badTriangle)
	}
	}

	// asSymBlas returns the receiver restructured as a blas64.Symmetric with the
	// same backing memory. Panics if the receiver is unit.
	// This returns a blas64.Symmetric and not a *SymDense because SymDense can only
	// be upper triangular.
	func (t *TriDense) asSymBlas() blas64.Symmetric {
	if t.mat.Diag == blas.Unit {
	panic("mat: cannot convert unit TriDense into blas64.Symmetric")
	}
	return blas64.Symmetric{
	N: t.mat.N,
	Stride: t.mat.Stride,
	Data: t.mat.Data,
	Uplo: t.mat.Uplo,
	}
	}

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

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

	func (t *TriDense) RawTriangular() blas64.Triangular {
	return t.mat
	}

	// 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 *TriDense) Reset() {
	// N and Stride must be zeroed in unison.
	t.mat.N, t.mat.Stride = 0, 0
	// Defensively zero Uplo to ensure
	// it is set correctly later.
	t.mat.Uplo = 0
	t.mat.Data = t.mat.Data[:0]
	}

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

	// 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 untransposeTri(a Triangular) (Triangular, bool) {
	if ut, ok := a.(UntransposeTrier); ok {
	return ut.UntransposeTri(), true
	}
	return a, false
	}

	// reuseAs resizes a zero receiver to an n×n triangular matrix with the given
	// orientation. If the receiver is non-zero, reuseAs checks that the receiver
	// is the correct size and orientation.
	func (t *TriDense) reuseAs(n int, kind TriKind) {
	ul := blas.Lower
	if kind == Upper {
	ul = blas.Upper
	}
	if t.mat.N > t.cap {
	panic(badTriCap)
	}
	if t.IsZero() {
	t.mat = blas64.Triangular{
	N: n,
	Stride: n,
	Diag: blas.NonUnit,
	Data: use(t.mat.Data, n*n),
	Uplo: ul,
	}
	t.cap = n
	return
	}
	if t.mat.N != n {
	panic(ErrShape)
	}
	if t.mat.Uplo != ul {
	panic(ErrTriangle)
	}
	}

	// isolatedWorkspace returns a new TriDense matrix w with the size of a and
	// returns a callback to defer which performs cleanup at the return of the call.
	// This should be used when a method receiver is the same pointer as an input argument.
	func (t TriDense) isolatedWorkspace(a Triangular) (w TriDense, restore func()) {
	n, kind := a.Triangle()
	if n == 0 {
	panic("zero size")
	}
	w = getWorkspaceTri(n, kind, false)
	return w, func() {
	t.Copy(w)
	putWorkspaceTri(w)
	}
	}

	// Copy makes a copy of elements of a into the receiver. It is similar to the
	// built-in copy; it copies as much as the overlap between the two matrices and
	// returns the number of rows and columns it copied. Only elements within the
	// receiver's non-zero triangle are set.
	//
	// See the Copier interface for more information.
	func (t *TriDense) Copy(a Matrix) (r, c int) {
	r, c = a.Dims()
	r = min(r, t.mat.N)
	c = min(c, t.mat.N)
	if r == 0 \|\| c == 0 {
	return 0, 0
	}

	switch a := a.(type) {
	case RawMatrixer:
	amat := a.RawMatrix()
	if t.isUpper() {
	for i := 0; i < r; i++ {
	copy(t.mat.Data[it.mat.Stride+i:it.mat.Stride+c], amat.Data[iamat.Stride+i:iamat.Stride+c])
	}
	} else {
	for i := 0; i < r; i++ {
	copy(t.mat.Data[it.mat.Stride:it.mat.Stride+i+1], amat.Data[iamat.Stride:iamat.Stride+i+1])
	}
	}
	case RawTriangular:
	amat := a.RawTriangular()
	aIsUpper := isUpperUplo(amat.Uplo)
	tIsUpper := t.isUpper()
	switch {
	case tIsUpper && aIsUpper:
	for i := 0; i < r; i++ {
	copy(t.mat.Data[it.mat.Stride+i:it.mat.Stride+c], amat.Data[iamat.Stride+i:iamat.Stride+c])
	}
	case !tIsUpper && !aIsUpper:
	for i := 0; i < r; i++ {
	copy(t.mat.Data[it.mat.Stride:it.mat.Stride+i+1], amat.Data[iamat.Stride:iamat.Stride+i+1])
	}
	default:
	for i := 0; i < r; i++ {
	t.set(i, i, amat.Data[i*amat.Stride+i])
	}
	}
	default:
	isUpper := t.isUpper()
	for i := 0; i < r; i++ {
	if isUpper {
	for j := i; j < c; j++ {
	t.set(i, j, a.At(i, j))
	}
	} else {
	for j := 0; j <= i; j++ {
	t.set(i, j, a.At(i, j))
	}
	}
	}
	}

	return r, c
	}

	// InverseTri computes the inverse of the triangular matrix a, storing the result
	// into the receiver. If a is ill-conditioned, a Condition error will be returned.
	// Note that matrix inversion is numerically unstable, and should generally be
	// avoided where possible, for example by using the Solve routines.
	func (t *TriDense) InverseTri(a Triangular) error {
	if rt, ok := a.(RawTriangular); ok {
	t.checkOverlap(rt.RawTriangular())
	}
	n, _ := a.Triangle()
	t.reuseAs(a.Triangle())
	t.Copy(a)
	work := getFloats(3*n, false)
	iwork := getInts(n, false)
	cond := lapack64.Trcon(CondNorm, t.mat, work, iwork)
	putFloats(work)
	putInts(iwork)
	if math.IsInf(cond, 1) {
	return Condition(cond)
	}
	ok := lapack64.Trtri(t.mat)
	if !ok {
	return Condition(math.Inf(1))
	}
	if cond > ConditionTolerance {
	return Condition(cond)
	}
	return nil
	}

	// MulTri takes the product of triangular matrices a and b and places the result
	// in the receiver. The size of a and b must match, and they both must have the
	// same TriKind, or Mul will panic.
	func (t *TriDense) MulTri(a, b Triangular) {
	n, kind := a.Triangle()
	nb, kindb := b.Triangle()
	if n != nb {
	panic(ErrShape)
	}
	if kind != kindb {
	panic(ErrTriangle)
	}

	aU, _ := untransposeTri(a)
	bU, _ := untransposeTri(b)
	t.reuseAs(n, kind)
	var restore func()
	if t == aU {
	t, restore = t.isolatedWorkspace(aU)
	defer restore()
	} else if t == bU {
	t, restore = t.isolatedWorkspace(bU)
	defer restore()
	}

	// TODO(btracey): Improve the set of fast-paths.
	if kind == Upper {
	for i := 0; i < n; i++ {
	for j := i; j < n; j++ {
	var v float64
	for k := i; k <= j; k++ {
	v += a.At(i, k) * b.At(k, j)
	}
	t.SetTri(i, j, v)
	}
	}
	return
	}
	for i := 0; i < n; i++ {
	for j := 0; j <= i; j++ {
	var v float64
	for k := j; k <= i; k++ {
	v += a.At(i, k) * b.At(k, j)
	}
	t.SetTri(i, j, v)
	}
	}
	}

	// copySymIntoTriangle copies a symmetric matrix into a TriDense
	func copySymIntoTriangle(t *TriDense, s Symmetric) {
	n, upper := t.Triangle()
	ns := s.Symmetric()
	if n != ns {
	panic("mat: triangle size mismatch")
	}
	ts := t.mat.Stride
	if rs, ok := s.(RawSymmetricer); ok {
	sd := rs.RawSymmetric()
	ss := sd.Stride
	if upper {
	if sd.Uplo == blas.Upper {
	for i := 0; i < n; i++ {
	copy(t.mat.Data[its+i:its+n], sd.Data[iss+i:iss+n])
	}
	return
	}
	for i := 0; i < n; i++ {
	for j := i; j < n; j++ {
	t.mat.Data[its+j] = sd.Data[jss+i]
	}
	}
	return
	}
	if sd.Uplo == blas.Upper {
	for i := 0; i < n; i++ {
	for j := 0; j <= i; j++ {
	t.mat.Data[its+j] = sd.Data[jss+i]
	}
	}
	return
	}
	for i := 0; i < n; i++ {
	copy(t.mat.Data[its:its+i+1], sd.Data[iss:iss+i+1])
	}
	return
	}
	if upper {
	for i := 0; i < n; i++ {
	for j := i; j < n; j++ {
	t.mat.Data[i*ts+j] = s.At(i, j)
	}
	}
	return
	}
	for i := 0; i < n; i++ {
	for j := 0; j <= i; j++ {
	t.mat.Data[i*ts+j] = s.At(i, j)
	}
	}
	}

	// DoNonZero calls the function fn for each of the non-zero elements of t. The function fn
	// takes a row/column index and the element value of t at (i, j).
	func (t *TriDense) DoNonZero(fn func(i, j int, v float64)) {
	if t.isUpper() {
	for i := 0; i < t.mat.N; i++ {
	for j := i; j < t.mat.N; j++ {
	v := t.at(i, j)
	if v != 0 {
	fn(i, j, v)
	}
	}
	}
	return
	}
	for i := 0; i < t.mat.N; i++ {
	for j := 0; j <= i; j++ {
	v := t.at(i, j)
	if v != 0 {
	fn(i, j, v)
	}
	}
	}
	}

	// DoRowNonZero calls the function fn for each of the non-zero elements of row i of t. The function fn
	// takes a row/column index and the element value of t at (i, j).
	func (t *TriDense) DoRowNonZero(i int, fn func(i, j int, v float64)) {
	if i < 0 \|\| t.mat.N <= i {
	panic(ErrRowAccess)
	}
	if t.isUpper() {
	for j := i; j < t.mat.N; j++ {
	v := t.at(i, j)
	if v != 0 {
	fn(i, j, v)
	}
	}
	return
	}
	for j := 0; j <= i; j++ {
	v := t.at(i, j)
	if v != 0 {
	fn(i, j, v)
	}
	}
	}

	// DoColNonZero calls the function fn for each of the non-zero elements of column j of t. The function fn
	// takes a row/column index and the element value of t at (i, j).
	func (t *TriDense) DoColNonZero(j int, fn func(i, j int, v float64)) {
	if j < 0 \|\| t.mat.N <= j {
	panic(ErrColAccess)
	}
	if t.isUpper() {
	for i := 0; i <= j; i++ {
	v := t.at(i, j)
	if v != 0 {
	fn(i, j, v)
	}
	}
	return
	}
	for i := j; i < t.mat.N; i++ {
	v := t.at(i, j)
	if v != 0 {
	fn(i, j, v)
	}
	}
	}