mat/dense_arithmetic.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"

 	"gonum.org/v1/gonum/blas"
 	"gonum.org/v1/gonum/blas/blas64"
 	"gonum.org/v1/gonum/lapack/lapack64"
 )

 // Add adds a and b element-wise, placing the result in the receiver. Add
 // will panic if the two matrices do not have the same shape.
 func (m *Dense) Add(a, b Matrix) {
 	ar, ac := a.Dims()
 	br, bc := b.Dims()
 	if ar != br || ac != bc {
 		panic(ErrShape)
 	}

 	aU, _ := untranspose(a)
 	bU, _ := untranspose(b)
 	m.reuseAs(ar, ac)

 	if arm, ok := a.(RawMatrixer); ok {
 		if brm, ok := b.(RawMatrixer); ok {
 			amat, bmat := arm.RawMatrix(), brm.RawMatrix()
 			if m != aU {
 				m.checkOverlap(amat)
 			}
 			if m != bU {
 				m.checkOverlap(bmat)
 			}
 			for ja, jb, jm := 0, 0, 0; ja < ar*amat.Stride; ja, jb, jm = ja+amat.Stride, jb+bmat.Stride, jm+m.mat.Stride {
 				for i, v := range amat.Data[ja : ja+ac] {
 					m.mat.Data[i+jm] = v + bmat.Data[i+jb]
 				}
 			}
 			return
 		}
 	}

 	m.checkOverlapMatrix(aU)
 	m.checkOverlapMatrix(bU)
 	var restore func()
 	if m == aU {
 		m, restore = m.isolatedWorkspace(aU)
 		defer restore()
 	} else if m == bU {
 		m, restore = m.isolatedWorkspace(bU)
 		defer restore()
 	}

 	for r := 0; r < ar; r++ {
 		for c := 0; c < ac; c++ {
 			m.set(r, c, a.At(r, c)+b.At(r, c))
 		}
 	}
 }

 // Sub subtracts the matrix b from a, placing the result in the receiver. Sub
 // will panic if the two matrices do not have the same shape.
 func (m *Dense) Sub(a, b Matrix) {
 	ar, ac := a.Dims()
 	br, bc := b.Dims()
 	if ar != br || ac != bc {
 		panic(ErrShape)
 	}

 	aU, _ := untranspose(a)
 	bU, _ := untranspose(b)
 	m.reuseAs(ar, ac)

 	if arm, ok := a.(RawMatrixer); ok {
 		if brm, ok := b.(RawMatrixer); ok {
 			amat, bmat := arm.RawMatrix(), brm.RawMatrix()
 			if m != aU {
 				m.checkOverlap(amat)
 			}
 			if m != bU {
 				m.checkOverlap(bmat)
 			}
 			for ja, jb, jm := 0, 0, 0; ja < ar*amat.Stride; ja, jb, jm = ja+amat.Stride, jb+bmat.Stride, jm+m.mat.Stride {
 				for i, v := range amat.Data[ja : ja+ac] {
 					m.mat.Data[i+jm] = v - bmat.Data[i+jb]
 				}
 			}
 			return
 		}
 	}

 	m.checkOverlapMatrix(aU)
 	m.checkOverlapMatrix(bU)
 	var restore func()
 	if m == aU {
 		m, restore = m.isolatedWorkspace(aU)
 		defer restore()
 	} else if m == bU {
 		m, restore = m.isolatedWorkspace(bU)
 		defer restore()
 	}

 	for r := 0; r < ar; r++ {
 		for c := 0; c < ac; c++ {
 			m.set(r, c, a.At(r, c)-b.At(r, c))
 		}
 	}
 }

 // MulElem performs element-wise multiplication of a and b, placing the result
 // in the receiver. MulElem will panic if the two matrices do not have the same
 // shape.
 func (m *Dense) MulElem(a, b Matrix) {
 	ar, ac := a.Dims()
 	br, bc := b.Dims()
 	if ar != br || ac != bc {
 		panic(ErrShape)
 	}

 	aU, _ := untranspose(a)
 	bU, _ := untranspose(b)
 	m.reuseAs(ar, ac)

 	if arm, ok := a.(RawMatrixer); ok {
 		if brm, ok := b.(RawMatrixer); ok {
 			amat, bmat := arm.RawMatrix(), brm.RawMatrix()
 			if m != aU {
 				m.checkOverlap(amat)
 			}
 			if m != bU {
 				m.checkOverlap(bmat)
 			}
 			for ja, jb, jm := 0, 0, 0; ja < ar*amat.Stride; ja, jb, jm = ja+amat.Stride, jb+bmat.Stride, jm+m.mat.Stride {
 				for i, v := range amat.Data[ja : ja+ac] {
 					m.mat.Data[i+jm] = v * bmat.Data[i+jb]
 				}
 			}
 			return
 		}
 	}

 	m.checkOverlapMatrix(aU)
 	m.checkOverlapMatrix(bU)
 	var restore func()
 	if m == aU {
 		m, restore = m.isolatedWorkspace(aU)
 		defer restore()
 	} else if m == bU {
 		m, restore = m.isolatedWorkspace(bU)
 		defer restore()
 	}

 	for r := 0; r < ar; r++ {
 		for c := 0; c < ac; c++ {
 			m.set(r, c, a.At(r, c)*b.At(r, c))
 		}
 	}
 }

 // DivElem performs element-wise division of a by b, placing the result
 // in the receiver. DivElem will panic if the two matrices do not have the same
 // shape.
 func (m *Dense) DivElem(a, b Matrix) {
 	ar, ac := a.Dims()
 	br, bc := b.Dims()
 	if ar != br || ac != bc {
 		panic(ErrShape)
 	}

 	aU, _ := untranspose(a)
 	bU, _ := untranspose(b)
 	m.reuseAs(ar, ac)

 	if arm, ok := a.(RawMatrixer); ok {
 		if brm, ok := b.(RawMatrixer); ok {
 			amat, bmat := arm.RawMatrix(), brm.RawMatrix()
 			if m != aU {
 				m.checkOverlap(amat)
 			}
 			if m != bU {
 				m.checkOverlap(bmat)
 			}
 			for ja, jb, jm := 0, 0, 0; ja < ar*amat.Stride; ja, jb, jm = ja+amat.Stride, jb+bmat.Stride, jm+m.mat.Stride {
 				for i, v := range amat.Data[ja : ja+ac] {
 					m.mat.Data[i+jm] = v / bmat.Data[i+jb]
 				}
 			}
 			return
 		}
 	}

 	m.checkOverlapMatrix(aU)
 	m.checkOverlapMatrix(bU)
 	var restore func()
 	if m == aU {
 		m, restore = m.isolatedWorkspace(aU)
 		defer restore()
 	} else if m == bU {
 		m, restore = m.isolatedWorkspace(bU)
 		defer restore()
 	}

 	for r := 0; r < ar; r++ {
 		for c := 0; c < ac; c++ {
 			m.set(r, c, a.At(r, c)/b.At(r, c))
 		}
 	}
 }

 // Inverse computes the inverse of the 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 (m *Dense) Inverse(a Matrix) error {
 	// TODO(btracey): Special case for RawTriangular, etc.
 	r, c := a.Dims()
 	if r != c {
 		panic(ErrSquare)
 	}
 	m.reuseAs(a.Dims())
 	aU, aTrans := untranspose(a)
 	switch rm := aU.(type) {
 	case RawMatrixer:
 		if m != aU || aTrans {
 			if m == aU || m.checkOverlap(rm.RawMatrix()) {
 				tmp := getWorkspace(r, c, false)
 				tmp.Copy(a)
 				m.Copy(tmp)
 				putWorkspace(tmp)
 				break
 			}
 			m.Copy(a)
 		}
 	default:
 		m.Copy(a)
 	}
 	ipiv := getInts(r, false)
 	defer putInts(ipiv)
 	ok := lapack64.Getrf(m.mat, ipiv)
 	if !ok {
 		return Condition(math.Inf(1))
 	}
 	work := getFloats(4*r, false) // must be at least 4*r for cond.
 	lapack64.Getri(m.mat, ipiv, work, -1)
 	if int(work[0]) > 4*r {
 		l := int(work[0])
 		putFloats(work)
 		work = getFloats(l, false)
 	} else {
 		work = work[:4*r]
 	}
 	defer putFloats(work)
 	lapack64.Getri(m.mat, ipiv, work, len(work))
 	norm := lapack64.Lange(CondNorm, m.mat, work)
 	rcond := lapack64.Gecon(CondNorm, m.mat, norm, work, ipiv) // reuse ipiv
 	if rcond == 0 {
 		return Condition(math.Inf(1))
 	}
 	cond := 1 / rcond
 	if cond > ConditionTolerance {
 		return Condition(cond)
 	}
 	return nil
 }

 // Mul takes the matrix product of a and b, placing the result in the receiver.
 // If the number of columns in a does not equal the number of rows in b, Mul will panic.
 func (m *Dense) Mul(a, b Matrix) {
 	ar, ac := a.Dims()
 	br, bc := b.Dims()

 	if ac != br {
 		panic(ErrShape)
 	}

 	aU, aTrans := untranspose(a)
 	bU, bTrans := untranspose(b)
 	m.reuseAs(ar, bc)
 	var restore func()
 	if m == aU {
 		m, restore = m.isolatedWorkspace(aU)
 		defer restore()
 	} else if m == bU {
 		m, restore = m.isolatedWorkspace(bU)
 		defer restore()
 	}
 	aT := blas.NoTrans
 	if aTrans {
 		aT = blas.Trans
 	}
 	bT := blas.NoTrans
 	if bTrans {
 		bT = blas.Trans
 	}

 	// Some of the cases do not have a transpose option, so create
 	// temporary memory.
 	// C = A^T * B = (B^T * A)^T
 	// C^T = B^T * A.
 	if aUrm, ok := aU.(RawMatrixer); ok {
 		amat := aUrm.RawMatrix()
 		if restore == nil {
 			m.checkOverlap(amat)
 		}
 		if bUrm, ok := bU.(RawMatrixer); ok {
 			bmat := bUrm.RawMatrix()
 			if restore == nil {
 				m.checkOverlap(bmat)
 			}
 			blas64.Gemm(aT, bT, 1, amat, bmat, 0, m.mat)
 			return
 		}
 		if bU, ok := bU.(RawSymmetricer); ok {
 			bmat := bU.RawSymmetric()
 			if aTrans {
 				c := getWorkspace(ac, ar, false)
 				blas64.Symm(blas.Left, 1, bmat, amat, 0, c.mat)
 				strictCopy(m, c.T())
 				putWorkspace(c)
 				return
 			}
 			blas64.Symm(blas.Right, 1, bmat, amat, 0, m.mat)
 			return
 		}
 		if bU, ok := bU.(RawTriangular); ok {
 			// Trmm updates in place, so copy aU first.
 			bmat := bU.RawTriangular()
 			if aTrans {
 				c := getWorkspace(ac, ar, false)
 				var tmp Dense
 				tmp.SetRawMatrix(amat)
 				c.Copy(&tmp)
 				bT := blas.Trans
 				if bTrans {
 					bT = blas.NoTrans
 				}
 				blas64.Trmm(blas.Left, bT, 1, bmat, c.mat)
 				strictCopy(m, c.T())
 				putWorkspace(c)
 				return
 			}
 			m.Copy(a)
 			blas64.Trmm(blas.Right, bT, 1, bmat, m.mat)
 			return
 		}
 		if bU, ok := bU.(*VecDense); ok {
 			m.checkOverlap(bU.asGeneral())
 			bvec := bU.RawVector()
 			if bTrans {
 				// {ar,1} x {1,bc}, which is not a vector.
 				// Instead, construct B as a General.
 				bmat := blas64.General{
 					Rows:   bc,
 					Cols:   1,
 					Stride: bvec.Inc,
 					Data:   bvec.Data,
 				}
 				blas64.Gemm(aT, bT, 1, amat, bmat, 0, m.mat)
 				return
 			}
 			cvec := blas64.Vector{
 				Inc:  m.mat.Stride,
 				Data: m.mat.Data,
 			}
 			blas64.Gemv(aT, 1, amat, bvec, 0, cvec)
 			return
 		}
 	}
 	if bUrm, ok := bU.(RawMatrixer); ok {
 		bmat := bUrm.RawMatrix()
 		if restore == nil {
 			m.checkOverlap(bmat)
 		}
 		if aU, ok := aU.(RawSymmetricer); ok {
 			amat := aU.RawSymmetric()
 			if bTrans {
 				c := getWorkspace(bc, br, false)
 				blas64.Symm(blas.Right, 1, amat, bmat, 0, c.mat)
 				strictCopy(m, c.T())
 				putWorkspace(c)
 				return
 			}
 			blas64.Symm(blas.Left, 1, amat, bmat, 0, m.mat)
 			return
 		}
 		if aU, ok := aU.(RawTriangular); ok {
 			// Trmm updates in place, so copy bU first.
 			amat := aU.RawTriangular()
 			if bTrans {
 				c := getWorkspace(bc, br, false)
 				var tmp Dense
 				tmp.SetRawMatrix(bmat)
 				c.Copy(&tmp)
 				aT := blas.Trans
 				if aTrans {
 					aT = blas.NoTrans
 				}
 				blas64.Trmm(blas.Right, aT, 1, amat, c.mat)
 				strictCopy(m, c.T())
 				putWorkspace(c)
 				return
 			}
 			m.Copy(b)
 			blas64.Trmm(blas.Left, aT, 1, amat, m.mat)
 			return
 		}
 		if aU, ok := aU.(*VecDense); ok {
 			m.checkOverlap(aU.asGeneral())
 			avec := aU.RawVector()
 			if aTrans {
 				// {1,ac} x {ac, bc}
 				// Transpose B so that the vector is on the right.
 				cvec := blas64.Vector{
 					Inc:  1,
 					Data: m.mat.Data,
 				}
 				bT := blas.Trans
 				if bTrans {
 					bT = blas.NoTrans
 				}
 				blas64.Gemv(bT, 1, bmat, avec, 0, cvec)
 				return
 			}
 			// {ar,1} x {1,bc} which is not a vector result.
 			// Instead, construct A as a General.
 			amat := blas64.General{
 				Rows:   ar,
 				Cols:   1,
 				Stride: avec.Inc,
 				Data:   avec.Data,
 			}
 			blas64.Gemm(aT, bT, 1, amat, bmat, 0, m.mat)
 			return
 		}
 	}

 	m.checkOverlapMatrix(aU)
 	m.checkOverlapMatrix(bU)
 	row := getFloats(ac, false)
 	defer putFloats(row)
 	for r := 0; r < ar; r++ {
 		for i := range row {
 			row[i] = a.At(r, i)
 		}
 		for c := 0; c < bc; c++ {
 			var v float64
 			for i, e := range row {
 				v += e * b.At(i, c)
 			}
 			m.mat.Data[r*m.mat.Stride+c] = v
 		}
 	}
 }

 // strictCopy copies a into m panicking if the shape of a and m differ.
 func strictCopy(m *Dense, a Matrix) {
 	r, c := m.Copy(a)
 	if r != m.mat.Rows || c != m.mat.Cols {
 		// Panic with a string since this
 		// is not a user-facing panic.
 		panic(ErrShape.Error())
 	}
 }

 // Exp calculates the exponential of the matrix a, e^a, placing the result
 // in the receiver. Exp will panic with matrix.ErrShape if a is not square.
 func (m *Dense) Exp(a Matrix) {
 	// The implementation used here is from Functions of Matrices: Theory and Computation
 	// Chapter 10, Algorithm 10.20. https://doi.org/10.1137/1.9780898717778.ch10

 	r, c := a.Dims()
 	if r != c {
 		panic(ErrShape)
 	}

 	m.reuseAs(r, r)
 	if r == 1 {
 		m.mat.Data[0] = math.Exp(a.At(0, 0))
 		return
 	}

 	pade := []struct {
 		theta float64
 		b     []float64
 	}{
 		{theta: 0.015, b: []float64{
 			120, 60, 12, 1,
 		}},
 		{theta: 0.25, b: []float64{
 			30240, 15120, 3360, 420, 30, 1,
 		}},
 		{theta: 0.95, b: []float64{
 			17297280, 8648640, 1995840, 277200, 25200, 1512, 56, 1,
 		}},
 		{theta: 2.1, b: []float64{
 			17643225600, 8821612800, 2075673600, 302702400, 30270240, 2162160, 110880, 3960, 90, 1,
 		}},
 	}

 	a1 := m
 	a1.Copy(a)
 	v := getWorkspace(r, r, true)
 	vraw := v.RawMatrix()
 	n := r * r
 	vvec := blas64.Vector{N: n, Inc: 1, Data: vraw.Data}
 	defer putWorkspace(v)

 	u := getWorkspace(r, r, true)
 	uraw := u.RawMatrix()
 	uvec := blas64.Vector{N: n, Inc: 1, Data: uraw.Data}
 	defer putWorkspace(u)

 	a2 := getWorkspace(r, r, false)
 	defer putWorkspace(a2)

 	n1 := Norm(a, 1)
 	for i, t := range pade {
 		if n1 > t.theta {
 			continue
 		}

 		// This loop only executes once, so
 		// this is not as horrible as it looks.
 		p := getWorkspace(r, r, true)
 		praw := p.RawMatrix()
 		pvec := blas64.Vector{N: n, Inc: 1, Data: praw.Data}
 		defer putWorkspace(p)

 		for k := 0; k < r; k++ {
 			p.set(k, k, 1)
 			v.set(k, k, t.b[0])
 			u.set(k, k, t.b[1])
 		}

 		a2.Mul(a1, a1)
 		for j := 0; j <= i; j++ {
 			p.Mul(p, a2)
 			blas64.Axpy(t.b[2*j+2], pvec, vvec)
 			blas64.Axpy(t.b[2*j+3], pvec, uvec)
 		}
 		u.Mul(a1, u)

 		// Use p as a workspace here and
 		// rename u for the second call's
 		// receiver.
 		vmu, vpu := u, p
 		vpu.Add(v, u)
 		vmu.Sub(v, u)

 		m.Solve(vmu, vpu)
 		return
 	}

 	// Remaining Padé table line.
 	const theta13 = 5.4
 	b := [...]float64{
 		64764752532480000, 32382376266240000, 7771770303897600, 1187353796428800,
 		129060195264000, 10559470521600, 670442572800, 33522128640,
 		1323241920, 40840800, 960960, 16380, 182, 1,
 	}

 	s := math.Log2(n1 / theta13)
 	if s >= 0 {
 		s = math.Ceil(s)
 		a1.Scale(1/math.Pow(2, s), a1)
 	}
 	a2.Mul(a1, a1)

 	i := getWorkspace(r, r, true)
 	for j := 0; j < r; j++ {
 		i.set(j, j, 1)
 	}
 	iraw := i.RawMatrix()
 	ivec := blas64.Vector{N: n, Inc: 1, Data: iraw.Data}
 	defer putWorkspace(i)

 	a2raw := a2.RawMatrix()
 	a2vec := blas64.Vector{N: n, Inc: 1, Data: a2raw.Data}

 	a4 := getWorkspace(r, r, false)
 	a4raw := a4.RawMatrix()
 	a4vec := blas64.Vector{N: n, Inc: 1, Data: a4raw.Data}
 	defer putWorkspace(a4)
 	a4.Mul(a2, a2)

 	a6 := getWorkspace(r, r, false)
 	a6raw := a6.RawMatrix()
 	a6vec := blas64.Vector{N: n, Inc: 1, Data: a6raw.Data}
 	defer putWorkspace(a6)
 	a6.Mul(a2, a4)

 	// V = A_6(b_12*A_6 + b_10*A_4 + b_8*A_2) + b_6*A_6 + b_4*A_4 + b_2*A_2 +b_0*I
 	blas64.Axpy(b[12], a6vec, vvec)
 	blas64.Axpy(b[10], a4vec, vvec)
 	blas64.Axpy(b[8], a2vec, vvec)
 	v.Mul(v, a6)
 	blas64.Axpy(b[6], a6vec, vvec)
 	blas64.Axpy(b[4], a4vec, vvec)
 	blas64.Axpy(b[2], a2vec, vvec)
 	blas64.Axpy(b[0], ivec, vvec)

 	// U = A(A_6(b_13*A_6 + b_11*A_4 + b_9*A_2) + b_7*A_6 + b_5*A_4 + b_2*A_3 +b_1*I)
 	blas64.Axpy(b[13], a6vec, uvec)
 	blas64.Axpy(b[11], a4vec, uvec)
 	blas64.Axpy(b[9], a2vec, uvec)
 	u.Mul(u, a6)
 	blas64.Axpy(b[7], a6vec, uvec)
 	blas64.Axpy(b[5], a4vec, uvec)
 	blas64.Axpy(b[3], a2vec, uvec)
 	blas64.Axpy(b[1], ivec, uvec)
 	u.Mul(u, a1)

 	// Use i as a workspace here and
 	// rename u for the second call's
 	// receiver.
 	vmu, vpu := u, i
 	vpu.Add(v, u)
 	vmu.Sub(v, u)

 	m.Solve(vmu, vpu)

 	for ; s > 0; s-- {
 		m.Mul(m, m)
 	}
 }

 // Pow calculates the integral power of the matrix a to n, placing the result
 // in the receiver. Pow will panic if n is negative or if a is not square.
 func (m *Dense) Pow(a Matrix, n int) {
 	if n < 0 {
 		panic("matrix: illegal power")
 	}
 	r, c := a.Dims()
 	if r != c {
 		panic(ErrShape)
 	}

 	m.reuseAs(r, c)

 	// Take possible fast paths.
 	switch n {
 	case 0:
 		for i := 0; i < r; i++ {
 			zero(m.mat.Data[i*m.mat.Stride : i*m.mat.Stride+c])
 			m.mat.Data[i*m.mat.Stride+i] = 1
 		}
 		return
 	case 1:
 		m.Copy(a)
 		return
 	case 2:
 		m.Mul(a, a)
 		return
 	}

 	// Perform iterative exponentiation by squaring in work space.
 	w := getWorkspace(r, r, false)
 	w.Copy(a)
 	s := getWorkspace(r, r, false)
 	s.Copy(a)
 	x := getWorkspace(r, r, false)
 	for n--; n > 0; n >>= 1 {
 		if n&1 != 0 {
 			x.Mul(w, s)
 			w, x = x, w
 		}
 		if n != 1 {
 			x.Mul(s, s)
 			s, x = x, s
 		}
 	}
 	m.Copy(w)
 	putWorkspace(w)
 	putWorkspace(s)
 	putWorkspace(x)
 }

 // Scale multiplies the elements of a by f, placing the result in the receiver.
 //
 // See the Scaler interface for more information.
 func (m *Dense) Scale(f float64, a Matrix) {
 	ar, ac := a.Dims()

 	m.reuseAs(ar, ac)

 	aU, aTrans := untranspose(a)
 	if rm, ok := aU.(RawMatrixer); ok {
 		amat := rm.RawMatrix()
 		if m == aU || m.checkOverlap(amat) {
 			var restore func()
 			m, restore = m.isolatedWorkspace(a)
 			defer restore()
 		}
 		if !aTrans {
 			for ja, jm := 0, 0; ja < ar*amat.Stride; ja, jm = ja+amat.Stride, jm+m.mat.Stride {
 				for i, v := range amat.Data[ja : ja+ac] {
 					m.mat.Data[i+jm] = v * f
 				}
 			}
 		} else {
 			for ja, jm := 0, 0; ja < ac*amat.Stride; ja, jm = ja+amat.Stride, jm+1 {
 				for i, v := range amat.Data[ja : ja+ar] {
 					m.mat.Data[i*m.mat.Stride+jm] = v * f
 				}
 			}
 		}
 		return
 	}

 	m.checkOverlapMatrix(a)
 	for r := 0; r < ar; r++ {
 		for c := 0; c < ac; c++ {
 			m.set(r, c, f*a.At(r, c))
 		}
 	}
 }

 // Apply applies the function fn to each of the elements of a, placing the
 // resulting matrix in the receiver. The function fn takes a row/column
 // index and element value and returns some function of that tuple.
 func (m *Dense) Apply(fn func(i, j int, v float64) float64, a Matrix) {
 	ar, ac := a.Dims()

 	m.reuseAs(ar, ac)

 	aU, aTrans := untranspose(a)
 	if rm, ok := aU.(RawMatrixer); ok {
 		amat := rm.RawMatrix()
 		if m == aU || m.checkOverlap(amat) {
 			var restore func()
 			m, restore = m.isolatedWorkspace(a)
 			defer restore()
 		}
 		if !aTrans {
 			for j, ja, jm := 0, 0, 0; ja < ar*amat.Stride; j, ja, jm = j+1, ja+amat.Stride, jm+m.mat.Stride {
 				for i, v := range amat.Data[ja : ja+ac] {
 					m.mat.Data[i+jm] = fn(j, i, v)
 				}
 			}
 		} else {
 			for j, ja, jm := 0, 0, 0; ja < ac*amat.Stride; j, ja, jm = j+1, ja+amat.Stride, jm+1 {
 				for i, v := range amat.Data[ja : ja+ar] {
 					m.mat.Data[i*m.mat.Stride+jm] = fn(i, j, v)
 				}
 			}
 		}
 		return
 	}

 	m.checkOverlapMatrix(a)
 	for r := 0; r < ar; r++ {
 		for c := 0; c < ac; c++ {
 			m.set(r, c, fn(r, c, a.At(r, c)))
 		}
 	}
 }

 // RankOne performs a rank-one update to the matrix a and stores the result
 // in the receiver. If a is zero, see Outer.
 //  m = a + alpha * x * y'
 func (m *Dense) RankOne(a Matrix, alpha float64, x, y Vector) {
 	ar, ac := a.Dims()
 	xr, xc := x.Dims()
 	if xr != ar || xc != 1 {
 		panic(ErrShape)
 	}
 	yr, yc := y.Dims()
 	if yr != ac || yc != 1 {
 		panic(ErrShape)
 	}

 	if a != m {
 		aU, _ := untranspose(a)
 		if rm, ok := aU.(RawMatrixer); ok {
 			m.checkOverlap(rm.RawMatrix())
 		}
 	}

 	var xmat, ymat blas64.Vector
 	fast := true
 	xU, _ := untranspose(x)
 	if rv, ok := xU.(RawVectorer); ok {
 		xmat = rv.RawVector()
 		m.checkOverlap((&VecDense{mat: xmat}).asGeneral())
 	} else {
 		fast = false
 	}
 	yU, _ := untranspose(y)
 	if rv, ok := yU.(RawVectorer); ok {
 		ymat = rv.RawVector()
 		m.checkOverlap((&VecDense{mat: ymat}).asGeneral())
 	} else {
 		fast = false
 	}

 	if fast {
 		if m != a {
 			m.reuseAs(ar, ac)
 			m.Copy(a)
 		}
 		blas64.Ger(alpha, xmat, ymat, m.mat)
 		return
 	}

 	m.reuseAs(ar, ac)
 	for i := 0; i < ar; i++ {
 		for j := 0; j < ac; j++ {
 			m.set(i, j, a.At(i, j)+alpha*x.AtVec(i)*y.AtVec(j))
 		}
 	}
 }

 // Outer calculates the outer product of the column vectors x and y,
 // and stores the result in the receiver.
 //  m = alpha * x * y'
 // In order to update an existing matrix, see RankOne.
 func (m *Dense) Outer(alpha float64, x, y Vector) {
 	xr, xc := x.Dims()
 	if xc != 1 {
 		panic(ErrShape)
 	}
 	yr, yc := y.Dims()
 	if yc != 1 {
 		panic(ErrShape)
 	}

 	r := xr
 	c := yr

 	// Copied from reuseAs with use replaced by useZeroed
 	// and a final zero of the matrix elements if we pass
 	// the shape checks.
 	// TODO(kortschak): Factor out into reuseZeroedAs if
 	// we find another case that needs it.
 	if m.mat.Rows > m.capRows || m.mat.Cols > m.capCols {
 		// Panic as a string, not a mat.Error.
 		panic("mat: caps not correctly set")
 	}
 	if m.IsZero() {
 		m.mat = blas64.General{
 			Rows:   r,
 			Cols:   c,
 			Stride: c,
 			Data:   useZeroed(m.mat.Data, r*c),
 		}
 		m.capRows = r
 		m.capCols = c
 	} else if r != m.mat.Rows || c != m.mat.Cols {
 		panic(ErrShape)
 	}

 	var xmat, ymat blas64.Vector
 	fast := true
 	xU, _ := untranspose(x)
 	if rv, ok := xU.(RawVectorer); ok {
 		xmat = rv.RawVector()
 		m.checkOverlap((&VecDense{mat: xmat}).asGeneral())

 	} else {
 		fast = false
 	}
 	yU, _ := untranspose(y)
 	if rv, ok := yU.(RawVectorer); ok {
 		ymat = rv.RawVector()
 		m.checkOverlap((&VecDense{mat: ymat}).asGeneral())
 	} else {
 		fast = false
 	}

 	if fast {
 		for i := 0; i < r; i++ {
 			zero(m.mat.Data[i*m.mat.Stride : i*m.mat.Stride+c])
 		}
 		blas64.Ger(alpha, xmat, ymat, m.mat)
 		return
 	}

 	for i := 0; i < r; i++ {
 		for j := 0; j < c; j++ {
 			m.set(i, j, alpha*x.AtVec(i)*y.AtVec(j))
 		}
 	}
 }
	// 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/lapack/lapack64"
	)

	// Add adds a and b element-wise, placing the result in the receiver. Add
	// will panic if the two matrices do not have the same shape.
	func (m *Dense) Add(a, b Matrix) {
	ar, ac := a.Dims()
	br, bc := b.Dims()
	if ar != br \|\| ac != bc {
	panic(ErrShape)
	}

	aU, _ := untranspose(a)
	bU, _ := untranspose(b)
	m.reuseAs(ar, ac)

	if arm, ok := a.(RawMatrixer); ok {
	if brm, ok := b.(RawMatrixer); ok {
	amat, bmat := arm.RawMatrix(), brm.RawMatrix()
	if m != aU {
	m.checkOverlap(amat)
	}
	if m != bU {
	m.checkOverlap(bmat)
	}
	for ja, jb, jm := 0, 0, 0; ja < ar*amat.Stride; ja, jb, jm = ja+amat.Stride, jb+bmat.Stride, jm+m.mat.Stride {
	for i, v := range amat.Data[ja : ja+ac] {
	m.mat.Data[i+jm] = v + bmat.Data[i+jb]
	}
	}
	return
	}
	}

	m.checkOverlapMatrix(aU)
	m.checkOverlapMatrix(bU)
	var restore func()
	if m == aU {
	m, restore = m.isolatedWorkspace(aU)
	defer restore()
	} else if m == bU {
	m, restore = m.isolatedWorkspace(bU)
	defer restore()
	}

	for r := 0; r < ar; r++ {
	for c := 0; c < ac; c++ {
	m.set(r, c, a.At(r, c)+b.At(r, c))
	}
	}
	}

	// Sub subtracts the matrix b from a, placing the result in the receiver. Sub
	// will panic if the two matrices do not have the same shape.
	func (m *Dense) Sub(a, b Matrix) {
	ar, ac := a.Dims()
	br, bc := b.Dims()
	if ar != br \|\| ac != bc {
	panic(ErrShape)
	}

	aU, _ := untranspose(a)
	bU, _ := untranspose(b)
	m.reuseAs(ar, ac)

	if arm, ok := a.(RawMatrixer); ok {
	if brm, ok := b.(RawMatrixer); ok {
	amat, bmat := arm.RawMatrix(), brm.RawMatrix()
	if m != aU {
	m.checkOverlap(amat)
	}
	if m != bU {
	m.checkOverlap(bmat)
	}
	for ja, jb, jm := 0, 0, 0; ja < ar*amat.Stride; ja, jb, jm = ja+amat.Stride, jb+bmat.Stride, jm+m.mat.Stride {
	for i, v := range amat.Data[ja : ja+ac] {
	m.mat.Data[i+jm] = v - bmat.Data[i+jb]
	}
	}
	return
	}
	}

	m.checkOverlapMatrix(aU)
	m.checkOverlapMatrix(bU)
	var restore func()
	if m == aU {
	m, restore = m.isolatedWorkspace(aU)
	defer restore()
	} else if m == bU {
	m, restore = m.isolatedWorkspace(bU)
	defer restore()
	}

	for r := 0; r < ar; r++ {
	for c := 0; c < ac; c++ {
	m.set(r, c, a.At(r, c)-b.At(r, c))
	}
	}
	}

	// MulElem performs element-wise multiplication of a and b, placing the result
	// in the receiver. MulElem will panic if the two matrices do not have the same
	// shape.
	func (m *Dense) MulElem(a, b Matrix) {
	ar, ac := a.Dims()
	br, bc := b.Dims()
	if ar != br \|\| ac != bc {
	panic(ErrShape)
	}

	aU, _ := untranspose(a)
	bU, _ := untranspose(b)
	m.reuseAs(ar, ac)

	if arm, ok := a.(RawMatrixer); ok {
	if brm, ok := b.(RawMatrixer); ok {
	amat, bmat := arm.RawMatrix(), brm.RawMatrix()
	if m != aU {
	m.checkOverlap(amat)
	}
	if m != bU {
	m.checkOverlap(bmat)
	}
	for ja, jb, jm := 0, 0, 0; ja < ar*amat.Stride; ja, jb, jm = ja+amat.Stride, jb+bmat.Stride, jm+m.mat.Stride {
	for i, v := range amat.Data[ja : ja+ac] {
	m.mat.Data[i+jm] = v * bmat.Data[i+jb]
	}
	}
	return
	}
	}

	m.checkOverlapMatrix(aU)
	m.checkOverlapMatrix(bU)
	var restore func()
	if m == aU {
	m, restore = m.isolatedWorkspace(aU)
	defer restore()
	} else if m == bU {
	m, restore = m.isolatedWorkspace(bU)
	defer restore()
	}

	for r := 0; r < ar; r++ {
	for c := 0; c < ac; c++ {
	m.set(r, c, a.At(r, c)*b.At(r, c))
	}
	}
	}

	// DivElem performs element-wise division of a by b, placing the result
	// in the receiver. DivElem will panic if the two matrices do not have the same
	// shape.
	func (m *Dense) DivElem(a, b Matrix) {
	ar, ac := a.Dims()
	br, bc := b.Dims()
	if ar != br \|\| ac != bc {
	panic(ErrShape)
	}

	aU, _ := untranspose(a)
	bU, _ := untranspose(b)
	m.reuseAs(ar, ac)

	if arm, ok := a.(RawMatrixer); ok {
	if brm, ok := b.(RawMatrixer); ok {
	amat, bmat := arm.RawMatrix(), brm.RawMatrix()
	if m != aU {
	m.checkOverlap(amat)
	}
	if m != bU {
	m.checkOverlap(bmat)
	}
	for ja, jb, jm := 0, 0, 0; ja < ar*amat.Stride; ja, jb, jm = ja+amat.Stride, jb+bmat.Stride, jm+m.mat.Stride {
	for i, v := range amat.Data[ja : ja+ac] {
	m.mat.Data[i+jm] = v / bmat.Data[i+jb]
	}
	}
	return
	}
	}

	m.checkOverlapMatrix(aU)
	m.checkOverlapMatrix(bU)
	var restore func()
	if m == aU {
	m, restore = m.isolatedWorkspace(aU)
	defer restore()
	} else if m == bU {
	m, restore = m.isolatedWorkspace(bU)
	defer restore()
	}

	for r := 0; r < ar; r++ {
	for c := 0; c < ac; c++ {
	m.set(r, c, a.At(r, c)/b.At(r, c))
	}
	}
	}

	// Inverse computes the inverse of the 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 (m *Dense) Inverse(a Matrix) error {
	// TODO(btracey): Special case for RawTriangular, etc.
	r, c := a.Dims()
	if r != c {
	panic(ErrSquare)
	}
	m.reuseAs(a.Dims())
	aU, aTrans := untranspose(a)
	switch rm := aU.(type) {
	case RawMatrixer:
	if m != aU \|\| aTrans {
	if m == aU \|\| m.checkOverlap(rm.RawMatrix()) {
	tmp := getWorkspace(r, c, false)
	tmp.Copy(a)
	m.Copy(tmp)
	putWorkspace(tmp)
	break
	}
	m.Copy(a)
	}
	default:
	m.Copy(a)
	}
	ipiv := getInts(r, false)
	defer putInts(ipiv)
	ok := lapack64.Getrf(m.mat, ipiv)
	if !ok {
	return Condition(math.Inf(1))
	}
	work := getFloats(4r, false) // must be at least 4r for cond.
	lapack64.Getri(m.mat, ipiv, work, -1)
	if int(work[0]) > 4*r {
	l := int(work[0])
	putFloats(work)
	work = getFloats(l, false)
	} else {
	work = work[:4*r]
	}
	defer putFloats(work)
	lapack64.Getri(m.mat, ipiv, work, len(work))
	norm := lapack64.Lange(CondNorm, m.mat, work)
	rcond := lapack64.Gecon(CondNorm, m.mat, norm, work, ipiv) // reuse ipiv
	if rcond == 0 {
	return Condition(math.Inf(1))
	}
	cond := 1 / rcond
	if cond > ConditionTolerance {
	return Condition(cond)
	}
	return nil
	}

	// Mul takes the matrix product of a and b, placing the result in the receiver.
	// If the number of columns in a does not equal the number of rows in b, Mul will panic.
	func (m *Dense) Mul(a, b Matrix) {
	ar, ac := a.Dims()
	br, bc := b.Dims()

	if ac != br {
	panic(ErrShape)
	}

	aU, aTrans := untranspose(a)
	bU, bTrans := untranspose(b)
	m.reuseAs(ar, bc)
	var restore func()
	if m == aU {
	m, restore = m.isolatedWorkspace(aU)
	defer restore()
	} else if m == bU {
	m, restore = m.isolatedWorkspace(bU)
	defer restore()
	}
	aT := blas.NoTrans
	if aTrans {
	aT = blas.Trans
	}
	bT := blas.NoTrans
	if bTrans {
	bT = blas.Trans
	}

	// Some of the cases do not have a transpose option, so create
	// temporary memory.
	// C = A^T * B = (B^T * A)^T
	// C^T = B^T * A.
	if aUrm, ok := aU.(RawMatrixer); ok {
	amat := aUrm.RawMatrix()
	if restore == nil {
	m.checkOverlap(amat)
	}
	if bUrm, ok := bU.(RawMatrixer); ok {
	bmat := bUrm.RawMatrix()
	if restore == nil {
	m.checkOverlap(bmat)
	}
	blas64.Gemm(aT, bT, 1, amat, bmat, 0, m.mat)
	return
	}
	if bU, ok := bU.(RawSymmetricer); ok {
	bmat := bU.RawSymmetric()
	if aTrans {
	c := getWorkspace(ac, ar, false)
	blas64.Symm(blas.Left, 1, bmat, amat, 0, c.mat)
	strictCopy(m, c.T())
	putWorkspace(c)
	return
	}
	blas64.Symm(blas.Right, 1, bmat, amat, 0, m.mat)
	return
	}
	if bU, ok := bU.(RawTriangular); ok {
	// Trmm updates in place, so copy aU first.
	bmat := bU.RawTriangular()
	if aTrans {
	c := getWorkspace(ac, ar, false)
	var tmp Dense
	tmp.SetRawMatrix(amat)
	c.Copy(&tmp)
	bT := blas.Trans
	if bTrans {
	bT = blas.NoTrans
	}
	blas64.Trmm(blas.Left, bT, 1, bmat, c.mat)
	strictCopy(m, c.T())
	putWorkspace(c)
	return
	}
	m.Copy(a)
	blas64.Trmm(blas.Right, bT, 1, bmat, m.mat)
	return
	}
	if bU, ok := bU.(*VecDense); ok {
	m.checkOverlap(bU.asGeneral())
	bvec := bU.RawVector()
	if bTrans {
	// {ar,1} x {1,bc}, which is not a vector.
	// Instead, construct B as a General.
	bmat := blas64.General{
	Rows: bc,
	Cols: 1,
	Stride: bvec.Inc,
	Data: bvec.Data,
	}
	blas64.Gemm(aT, bT, 1, amat, bmat, 0, m.mat)
	return
	}
	cvec := blas64.Vector{
	Inc: m.mat.Stride,
	Data: m.mat.Data,
	}
	blas64.Gemv(aT, 1, amat, bvec, 0, cvec)
	return
	}
	}
	if bUrm, ok := bU.(RawMatrixer); ok {
	bmat := bUrm.RawMatrix()
	if restore == nil {
	m.checkOverlap(bmat)
	}
	if aU, ok := aU.(RawSymmetricer); ok {
	amat := aU.RawSymmetric()
	if bTrans {
	c := getWorkspace(bc, br, false)
	blas64.Symm(blas.Right, 1, amat, bmat, 0, c.mat)
	strictCopy(m, c.T())
	putWorkspace(c)
	return
	}
	blas64.Symm(blas.Left, 1, amat, bmat, 0, m.mat)
	return
	}
	if aU, ok := aU.(RawTriangular); ok {
	// Trmm updates in place, so copy bU first.
	amat := aU.RawTriangular()
	if bTrans {
	c := getWorkspace(bc, br, false)
	var tmp Dense
	tmp.SetRawMatrix(bmat)
	c.Copy(&tmp)
	aT := blas.Trans
	if aTrans {
	aT = blas.NoTrans
	}
	blas64.Trmm(blas.Right, aT, 1, amat, c.mat)
	strictCopy(m, c.T())
	putWorkspace(c)
	return
	}
	m.Copy(b)
	blas64.Trmm(blas.Left, aT, 1, amat, m.mat)
	return
	}
	if aU, ok := aU.(*VecDense); ok {
	m.checkOverlap(aU.asGeneral())
	avec := aU.RawVector()
	if aTrans {
	// {1,ac} x {ac, bc}
	// Transpose B so that the vector is on the right.
	cvec := blas64.Vector{
	Inc: 1,
	Data: m.mat.Data,
	}
	bT := blas.Trans
	if bTrans {
	bT = blas.NoTrans
	}
	blas64.Gemv(bT, 1, bmat, avec, 0, cvec)
	return
	}
	// {ar,1} x {1,bc} which is not a vector result.
	// Instead, construct A as a General.
	amat := blas64.General{
	Rows: ar,
	Cols: 1,
	Stride: avec.Inc,
	Data: avec.Data,
	}
	blas64.Gemm(aT, bT, 1, amat, bmat, 0, m.mat)
	return
	}
	}

	m.checkOverlapMatrix(aU)
	m.checkOverlapMatrix(bU)
	row := getFloats(ac, false)
	defer putFloats(row)
	for r := 0; r < ar; r++ {
	for i := range row {
	row[i] = a.At(r, i)
	}
	for c := 0; c < bc; c++ {
	var v float64
	for i, e := range row {
	v += e * b.At(i, c)
	}
	m.mat.Data[r*m.mat.Stride+c] = v
	}
	}
	}

	// strictCopy copies a into m panicking if the shape of a and m differ.
	func strictCopy(m *Dense, a Matrix) {
	r, c := m.Copy(a)
	if r != m.mat.Rows \|\| c != m.mat.Cols {
	// Panic with a string since this
	// is not a user-facing panic.
	panic(ErrShape.Error())
	}
	}

	// Exp calculates the exponential of the matrix a, e^a, placing the result
	// in the receiver. Exp will panic with matrix.ErrShape if a is not square.
	func (m *Dense) Exp(a Matrix) {
	// The implementation used here is from Functions of Matrices: Theory and Computation
	// Chapter 10, Algorithm 10.20. https://doi.org/10.1137/1.9780898717778.ch10

	r, c := a.Dims()
	if r != c {
	panic(ErrShape)
	}

	m.reuseAs(r, r)
	if r == 1 {
	m.mat.Data[0] = math.Exp(a.At(0, 0))
	return
	}

	pade := []struct {
	theta float64
	b []float64
	}{
	{theta: 0.015, b: []float64{
	120, 60, 12, 1,
	}},
	{theta: 0.25, b: []float64{
	30240, 15120, 3360, 420, 30, 1,
	}},
	{theta: 0.95, b: []float64{
	17297280, 8648640, 1995840, 277200, 25200, 1512, 56, 1,
	}},
	{theta: 2.1, b: []float64{
	17643225600, 8821612800, 2075673600, 302702400, 30270240, 2162160, 110880, 3960, 90, 1,
	}},
	}

	a1 := m
	a1.Copy(a)
	v := getWorkspace(r, r, true)
	vraw := v.RawMatrix()
	n := r * r
	vvec := blas64.Vector{N: n, Inc: 1, Data: vraw.Data}
	defer putWorkspace(v)

	u := getWorkspace(r, r, true)
	uraw := u.RawMatrix()
	uvec := blas64.Vector{N: n, Inc: 1, Data: uraw.Data}
	defer putWorkspace(u)

	a2 := getWorkspace(r, r, false)
	defer putWorkspace(a2)

	n1 := Norm(a, 1)
	for i, t := range pade {
	if n1 > t.theta {
	continue
	}

	// This loop only executes once, so
	// this is not as horrible as it looks.
	p := getWorkspace(r, r, true)
	praw := p.RawMatrix()
	pvec := blas64.Vector{N: n, Inc: 1, Data: praw.Data}
	defer putWorkspace(p)

	for k := 0; k < r; k++ {
	p.set(k, k, 1)
	v.set(k, k, t.b[0])
	u.set(k, k, t.b[1])
	}

	a2.Mul(a1, a1)
	for j := 0; j <= i; j++ {
	p.Mul(p, a2)
	blas64.Axpy(t.b[2*j+2], pvec, vvec)
	blas64.Axpy(t.b[2*j+3], pvec, uvec)
	}
	u.Mul(a1, u)

	// Use p as a workspace here and
	// rename u for the second call's
	// receiver.
	vmu, vpu := u, p
	vpu.Add(v, u)
	vmu.Sub(v, u)

	m.Solve(vmu, vpu)
	return
	}

	// Remaining Padé table line.
	const theta13 = 5.4
	b := [...]float64{
	64764752532480000, 32382376266240000, 7771770303897600, 1187353796428800,
	129060195264000, 10559470521600, 670442572800, 33522128640,
	1323241920, 40840800, 960960, 16380, 182, 1,
	}

	s := math.Log2(n1 / theta13)
	if s >= 0 {
	s = math.Ceil(s)
	a1.Scale(1/math.Pow(2, s), a1)
	}
	a2.Mul(a1, a1)

	i := getWorkspace(r, r, true)
	for j := 0; j < r; j++ {
	i.set(j, j, 1)
	}
	iraw := i.RawMatrix()
	ivec := blas64.Vector{N: n, Inc: 1, Data: iraw.Data}
	defer putWorkspace(i)

	a2raw := a2.RawMatrix()
	a2vec := blas64.Vector{N: n, Inc: 1, Data: a2raw.Data}

	a4 := getWorkspace(r, r, false)
	a4raw := a4.RawMatrix()
	a4vec := blas64.Vector{N: n, Inc: 1, Data: a4raw.Data}
	defer putWorkspace(a4)
	a4.Mul(a2, a2)

	a6 := getWorkspace(r, r, false)
	a6raw := a6.RawMatrix()
	a6vec := blas64.Vector{N: n, Inc: 1, Data: a6raw.Data}
	defer putWorkspace(a6)
	a6.Mul(a2, a4)

	// V = A_6(b_12A_6 + b_10A_4 + b_8A_2) + b_6A_6 + b_4A_4 + b_2A_2 +b_0*I
	blas64.Axpy(b[12], a6vec, vvec)
	blas64.Axpy(b[10], a4vec, vvec)
	blas64.Axpy(b[8], a2vec, vvec)
	v.Mul(v, a6)
	blas64.Axpy(b[6], a6vec, vvec)
	blas64.Axpy(b[4], a4vec, vvec)
	blas64.Axpy(b[2], a2vec, vvec)
	blas64.Axpy(b[0], ivec, vvec)

	// U = A(A_6(b_13A_6 + b_11A_4 + b_9A_2) + b_7A_6 + b_5A_4 + b_2A_3 +b_1*I)
	blas64.Axpy(b[13], a6vec, uvec)
	blas64.Axpy(b[11], a4vec, uvec)
	blas64.Axpy(b[9], a2vec, uvec)
	u.Mul(u, a6)
	blas64.Axpy(b[7], a6vec, uvec)
	blas64.Axpy(b[5], a4vec, uvec)
	blas64.Axpy(b[3], a2vec, uvec)
	blas64.Axpy(b[1], ivec, uvec)
	u.Mul(u, a1)

	// Use i as a workspace here and
	// rename u for the second call's
	// receiver.
	vmu, vpu := u, i
	vpu.Add(v, u)
	vmu.Sub(v, u)

	m.Solve(vmu, vpu)

	for ; s > 0; s-- {
	m.Mul(m, m)
	}
	}

	// Pow calculates the integral power of the matrix a to n, placing the result
	// in the receiver. Pow will panic if n is negative or if a is not square.
	func (m *Dense) Pow(a Matrix, n int) {
	if n < 0 {
	panic("matrix: illegal power")
	}
	r, c := a.Dims()
	if r != c {
	panic(ErrShape)
	}

	m.reuseAs(r, c)

	// Take possible fast paths.
	switch n {
	case 0:
	for i := 0; i < r; i++ {
	zero(m.mat.Data[im.mat.Stride : im.mat.Stride+c])
	m.mat.Data[i*m.mat.Stride+i] = 1
	}
	return
	case 1:
	m.Copy(a)
	return
	case 2:
	m.Mul(a, a)
	return
	}

	// Perform iterative exponentiation by squaring in work space.
	w := getWorkspace(r, r, false)
	w.Copy(a)
	s := getWorkspace(r, r, false)
	s.Copy(a)
	x := getWorkspace(r, r, false)
	for n--; n > 0; n >>= 1 {
	if n&1 != 0 {
	x.Mul(w, s)
	w, x = x, w
	}
	if n != 1 {
	x.Mul(s, s)
	s, x = x, s
	}
	}
	m.Copy(w)
	putWorkspace(w)
	putWorkspace(s)
	putWorkspace(x)
	}

	// Scale multiplies the elements of a by f, placing the result in the receiver.
	//
	// See the Scaler interface for more information.
	func (m *Dense) Scale(f float64, a Matrix) {
	ar, ac := a.Dims()

	m.reuseAs(ar, ac)

	aU, aTrans := untranspose(a)
	if rm, ok := aU.(RawMatrixer); ok {
	amat := rm.RawMatrix()
	if m == aU \|\| m.checkOverlap(amat) {
	var restore func()
	m, restore = m.isolatedWorkspace(a)
	defer restore()
	}
	if !aTrans {
	for ja, jm := 0, 0; ja < ar*amat.Stride; ja, jm = ja+amat.Stride, jm+m.mat.Stride {
	for i, v := range amat.Data[ja : ja+ac] {
	m.mat.Data[i+jm] = v * f
	}
	}
	} else {
	for ja, jm := 0, 0; ja < ac*amat.Stride; ja, jm = ja+amat.Stride, jm+1 {
	for i, v := range amat.Data[ja : ja+ar] {
	m.mat.Data[im.mat.Stride+jm] = v f
	}
	}
	}
	return
	}

	m.checkOverlapMatrix(a)
	for r := 0; r < ar; r++ {
	for c := 0; c < ac; c++ {
	m.set(r, c, f*a.At(r, c))
	}
	}
	}

	// Apply applies the function fn to each of the elements of a, placing the
	// resulting matrix in the receiver. The function fn takes a row/column
	// index and element value and returns some function of that tuple.
	func (m *Dense) Apply(fn func(i, j int, v float64) float64, a Matrix) {
	ar, ac := a.Dims()

	m.reuseAs(ar, ac)

	aU, aTrans := untranspose(a)
	if rm, ok := aU.(RawMatrixer); ok {
	amat := rm.RawMatrix()
	if m == aU \|\| m.checkOverlap(amat) {
	var restore func()
	m, restore = m.isolatedWorkspace(a)
	defer restore()
	}
	if !aTrans {
	for j, ja, jm := 0, 0, 0; ja < ar*amat.Stride; j, ja, jm = j+1, ja+amat.Stride, jm+m.mat.Stride {
	for i, v := range amat.Data[ja : ja+ac] {
	m.mat.Data[i+jm] = fn(j, i, v)
	}
	}
	} else {
	for j, ja, jm := 0, 0, 0; ja < ac*amat.Stride; j, ja, jm = j+1, ja+amat.Stride, jm+1 {
	for i, v := range amat.Data[ja : ja+ar] {
	m.mat.Data[i*m.mat.Stride+jm] = fn(i, j, v)
	}
	}
	}
	return
	}

	m.checkOverlapMatrix(a)
	for r := 0; r < ar; r++ {
	for c := 0; c < ac; c++ {
	m.set(r, c, fn(r, c, a.At(r, c)))
	}
	}
	}

	// RankOne performs a rank-one update to the matrix a and stores the result
	// in the receiver. If a is zero, see Outer.
	// m = a + alpha * x * y'
	func (m *Dense) RankOne(a Matrix, alpha float64, x, y Vector) {
	ar, ac := a.Dims()
	xr, xc := x.Dims()
	if xr != ar \|\| xc != 1 {
	panic(ErrShape)
	}
	yr, yc := y.Dims()
	if yr != ac \|\| yc != 1 {
	panic(ErrShape)
	}

	if a != m {
	aU, _ := untranspose(a)
	if rm, ok := aU.(RawMatrixer); ok {
	m.checkOverlap(rm.RawMatrix())
	}
	}

	var xmat, ymat blas64.Vector
	fast := true
	xU, _ := untranspose(x)
	if rv, ok := xU.(RawVectorer); ok {
	xmat = rv.RawVector()
	m.checkOverlap((&VecDense{mat: xmat}).asGeneral())
	} else {
	fast = false
	}
	yU, _ := untranspose(y)
	if rv, ok := yU.(RawVectorer); ok {
	ymat = rv.RawVector()
	m.checkOverlap((&VecDense{mat: ymat}).asGeneral())
	} else {
	fast = false
	}

	if fast {
	if m != a {
	m.reuseAs(ar, ac)
	m.Copy(a)
	}
	blas64.Ger(alpha, xmat, ymat, m.mat)
	return
	}

	m.reuseAs(ar, ac)
	for i := 0; i < ar; i++ {
	for j := 0; j < ac; j++ {
	m.set(i, j, a.At(i, j)+alphax.AtVec(i)y.AtVec(j))
	}
	}
	}

	// Outer calculates the outer product of the column vectors x and y,
	// and stores the result in the receiver.
	// m = alpha * x * y'
	// In order to update an existing matrix, see RankOne.
	func (m *Dense) Outer(alpha float64, x, y Vector) {
	xr, xc := x.Dims()
	if xc != 1 {
	panic(ErrShape)
	}
	yr, yc := y.Dims()
	if yc != 1 {
	panic(ErrShape)
	}

	r := xr
	c := yr

	// Copied from reuseAs with use replaced by useZeroed
	// and a final zero of the matrix elements if we pass
	// the shape checks.
	// TODO(kortschak): Factor out into reuseZeroedAs if
	// we find another case that needs it.
	if m.mat.Rows > m.capRows \|\| m.mat.Cols > m.capCols {
	// Panic as a string, not a mat.Error.
	panic("mat: caps not correctly set")
	}
	if m.IsZero() {
	m.mat = blas64.General{
	Rows: r,
	Cols: c,
	Stride: c,
	Data: useZeroed(m.mat.Data, r*c),
	}
	m.capRows = r
	m.capCols = c
	} else if r != m.mat.Rows \|\| c != m.mat.Cols {
	panic(ErrShape)
	}

	var xmat, ymat blas64.Vector
	fast := true
	xU, _ := untranspose(x)
	if rv, ok := xU.(RawVectorer); ok {
	xmat = rv.RawVector()
	m.checkOverlap((&VecDense{mat: xmat}).asGeneral())

	} else {
	fast = false
	}
	yU, _ := untranspose(y)
	if rv, ok := yU.(RawVectorer); ok {
	ymat = rv.RawVector()
	m.checkOverlap((&VecDense{mat: ymat}).asGeneral())
	} else {
	fast = false
	}

	if fast {
	for i := 0; i < r; i++ {
	zero(m.mat.Data[im.mat.Stride : im.mat.Stride+c])
	}
	blas64.Ger(alpha, xmat, ymat, m.mat)
	return
	}

	for i := 0; i < r; i++ {
	for j := 0; j < c; j++ {
	m.set(i, j, alphax.AtVec(i)y.AtVec(j))
	}
	}
	}