optimize/morethuente.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 optimize

 import "math"

 // MoreThuente is a Linesearcher that finds steps that satisfy both the
 // sufficient decrease and curvature conditions (the strong Wolfe conditions).
 //
 // References:
 //  - More, J.J. and D.J. Thuente: Line Search Algorithms with Guaranteed Sufficient
 //    Decrease. ACM Transactions on Mathematical Software 20(3) (1994), 286-307
 type MoreThuente struct {
 	// DecreaseFactor is the constant factor in the sufficient decrease
 	// (Armijo) condition.
 	// It must be in the interval [0, 1). The default value is 0.
 	DecreaseFactor float64
 	// CurvatureFactor is the constant factor in the Wolfe conditions. Smaller
 	// values result in a more exact line search.
 	// A set value must be in the interval (0, 1). If it is zero, it will be
 	// defaulted to 0.9.
 	CurvatureFactor float64
 	// StepTolerance sets the minimum acceptable width for the linesearch
 	// interval. If the relative interval length is less than this value,
 	// ErrLinesearcherFailure is returned.
 	// It must be non-negative. If it is zero, it will be defaulted to 1e-10.
 	StepTolerance float64

 	// MinimumStep is the minimum step that the linesearcher will take.
 	// It must be non-negative and less than MaximumStep. Defaults to no
 	// minimum (a value of 0).
 	MinimumStep float64
 	// MaximumStep is the maximum step that the linesearcher will take.
 	// It must be greater than MinimumStep. If it is zero, it will be defaulted
 	// to 1e20.
 	MaximumStep float64

 	bracketed bool    // Indicates if a minimum has been bracketed.
 	fInit     float64 // Function value at step = 0.
 	gInit     float64 // Derivative value at step = 0.

 	// When stage is 1, the algorithm updates the interval given by x and y
 	// so that it contains a minimizer of the modified function
 	//  psi(step) = f(step) - f(0) - DecreaseFactor * step * f'(0).
 	// When stage is 2, the interval is updated so that it contains a minimizer
 	// of f.
 	stage int

 	step         float64    // Current step.
 	lower, upper float64    // Lower and upper bounds on the next step.
 	x            float64    // Endpoint of the interval with a lower function value.
 	fx, gx       float64    // Data at x.
 	y            float64    // The other endpoint.
 	fy, gy       float64    // Data at y.
 	width        [2]float64 // Width of the interval at two previous iterations.
 }

 const (
 	mtMinGrowthFactor float64 = 1.1
 	mtMaxGrowthFactor float64 = 4
 )

 func (mt *MoreThuente) Init(f, g float64, step float64) Operation {
 	// Based on the original Fortran code that is available, for example, from
 	//  http://ftp.mcs.anl.gov/pub/MINPACK-2/csrch/
 	// as part of
 	//  MINPACK-2 Project. November 1993.
 	//  Argonne National Laboratory and University of Minnesota.
 	//  Brett M. Averick, Richard G. Carter, and Jorge J. Moré.

 	if g >= 0 {
 		panic("morethuente: initial derivative is non-negative")
 	}
 	if step <= 0 {
 		panic("morethuente: invalid initial step")
 	}

 	if mt.CurvatureFactor == 0 {
 		mt.CurvatureFactor = 0.9
 	}
 	if mt.StepTolerance == 0 {
 		mt.StepTolerance = 1e-10
 	}
 	if mt.MaximumStep == 0 {
 		mt.MaximumStep = 1e20
 	}

 	if mt.MinimumStep < 0 {
 		panic("morethuente: minimum step is negative")
 	}
 	if mt.MaximumStep <= mt.MinimumStep {
 		panic("morethuente: maximum step is not greater than minimum step")
 	}
 	if mt.DecreaseFactor < 0 || mt.DecreaseFactor >= 1 {
 		panic("morethuente: invalid decrease factor")
 	}
 	if mt.CurvatureFactor <= 0 || mt.CurvatureFactor >= 1 {
 		panic("morethuente: invalid curvature factor")
 	}
 	if mt.StepTolerance <= 0 {
 		panic("morethuente: step tolerance is not positive")
 	}

 	if step < mt.MinimumStep {
 		step = mt.MinimumStep
 	}
 	if step > mt.MaximumStep {
 		step = mt.MaximumStep
 	}

 	mt.bracketed = false
 	mt.stage = 1
 	mt.fInit = f
 	mt.gInit = g

 	mt.x, mt.fx, mt.gx = 0, f, g
 	mt.y, mt.fy, mt.gy = 0, f, g

 	mt.lower = 0
 	mt.upper = step + mtMaxGrowthFactor*step

 	mt.width[0] = mt.MaximumStep - mt.MinimumStep
 	mt.width[1] = 2 * mt.width[0]

 	mt.step = step
 	return FuncEvaluation | GradEvaluation
 }

 func (mt *MoreThuente) Iterate(f, g float64) (Operation, float64, error) {
 	if mt.stage == 0 {
 		panic("morethuente: Init has not been called")
 	}

 	gTest := mt.DecreaseFactor * mt.gInit
 	fTest := mt.fInit + mt.step*gTest

 	if mt.bracketed {
 		if mt.step <= mt.lower || mt.step >= mt.upper || mt.upper-mt.lower <= mt.StepTolerance*mt.upper {
 			// step contains the best step found (see below).
 			return NoOperation, mt.step, ErrLinesearcherFailure
 		}
 	}
 	if mt.step == mt.MaximumStep && f <= fTest && g <= gTest {
 		return NoOperation, mt.step, ErrLinesearcherBound
 	}
 	if mt.step == mt.MinimumStep && (f > fTest || g >= gTest) {
 		return NoOperation, mt.step, ErrLinesearcherFailure
 	}

 	// Test for convergence.
 	if f <= fTest && math.Abs(g) <= mt.CurvatureFactor*(-mt.gInit) {
 		mt.stage = 0
 		return MajorIteration, mt.step, nil
 	}

 	if mt.stage == 1 && f <= fTest && g >= 0 {
 		mt.stage = 2
 	}

 	if mt.stage == 1 && f <= mt.fx && f > fTest {
 		// Lower function value but the decrease is not sufficient .

 		// Compute values and derivatives of the modified function at step, x, y.
 		fm := f - mt.step*gTest
 		fxm := mt.fx - mt.x*gTest
 		fym := mt.fy - mt.y*gTest
 		gm := g - gTest
 		gxm := mt.gx - gTest
 		gym := mt.gy - gTest
 		// Update x, y and step.
 		mt.nextStep(fxm, gxm, fym, gym, fm, gm)
 		// Recover values and derivates of the non-modified function at x and y.
 		mt.fx = fxm + mt.x*gTest
 		mt.fy = fym + mt.y*gTest
 		mt.gx = gxm + gTest
 		mt.gy = gym + gTest
 	} else {
 		// Update x, y and step.
 		mt.nextStep(mt.fx, mt.gx, mt.fy, mt.gy, f, g)
 	}

 	if mt.bracketed {
 		// Monitor the length of the bracketing interval. If the interval has
 		// not been reduced sufficiently after two steps, use bisection to
 		// force its length to zero.
 		width := mt.y - mt.x
 		if math.Abs(width) >= 2.0/3*mt.width[1] {
 			mt.step = mt.x + 0.5*width
 		}
 		mt.width[0], mt.width[1] = math.Abs(width), mt.width[0]
 	}

 	if mt.bracketed {
 		mt.lower = math.Min(mt.x, mt.y)
 		mt.upper = math.Max(mt.x, mt.y)
 	} else {
 		mt.lower = mt.step + mtMinGrowthFactor*(mt.step-mt.x)
 		mt.upper = mt.step + mtMaxGrowthFactor*(mt.step-mt.x)
 	}

 	// Force the step to be in [MinimumStep, MaximumStep].
 	mt.step = math.Max(mt.MinimumStep, math.Min(mt.step, mt.MaximumStep))

 	if mt.bracketed {
 		if mt.step <= mt.lower || mt.step >= mt.upper || mt.upper-mt.lower <= mt.StepTolerance*mt.upper {
 			// If further progress is not possible, set step to the best step
 			// obtained during the search.
 			mt.step = mt.x
 		}
 	}

 	return FuncEvaluation | GradEvaluation, mt.step, nil
 }

 // nextStep computes the next safeguarded step and updates the interval that
 // contains a step that satisfies the sufficient decrease and curvature
 // conditions.
 func (mt *MoreThuente) nextStep(fx, gx, fy, gy, f, g float64) {
 	x := mt.x
 	y := mt.y
 	step := mt.step

 	gNeg := g < 0
 	if gx < 0 {
 		gNeg = !gNeg
 	}

 	var next float64
 	var bracketed bool
 	switch {
 	case f > fx:
 		// A higher function value. The minimum is bracketed between x and step.
 		// We want the next step to be closer to x because the function value
 		// there is lower.

 		theta := 3*(fx-f)/(step-x) + gx + g
 		s := math.Max(math.Abs(gx), math.Abs(g))
 		s = math.Max(s, math.Abs(theta))
 		gamma := s * math.Sqrt((theta/s)*(theta/s)-(gx/s)*(g/s))
 		if step < x {
 			gamma *= -1
 		}
 		p := gamma - gx + theta
 		q := gamma - gx + gamma + g
 		r := p / q
 		stpc := x + r*(step-x)
 		stpq := x + gx/((fx-f)/(step-x)+gx)/2*(step-x)

 		if math.Abs(stpc-x) < math.Abs(stpq-x) {
 			// The cubic step is closer to x than the quadratic step.
 			// Take the cubic step.
 			next = stpc
 		} else {
 			// If f is much larger than fx, then the quadratic step may be too
 			// close to x. Therefore heuristically take the average of the
 			// cubic and quadratic steps.
 			next = stpc + (stpq-stpc)/2
 		}
 		bracketed = true

 	case gNeg:
 		// A lower function value and derivatives of opposite sign. The minimum
 		// is bracketed between x and step. If we choose a step that is far
 		// from step, the next iteration will also likely fall in this case.

 		theta := 3*(fx-f)/(step-x) + gx + g
 		s := math.Max(math.Abs(gx), math.Abs(g))
 		s = math.Max(s, math.Abs(theta))
 		gamma := s * math.Sqrt((theta/s)*(theta/s)-(gx/s)*(g/s))
 		if step > x {
 			gamma *= -1
 		}
 		p := gamma - g + theta
 		q := gamma - g + gamma + gx
 		r := p / q
 		stpc := step + r*(x-step)
 		stpq := step + g/(g-gx)*(x-step)

 		if math.Abs(stpc-step) > math.Abs(stpq-step) {
 			// The cubic step is farther from x than the quadratic step.
 			// Take the cubic step.
 			next = stpc
 		} else {
 			// Take the quadratic step.
 			next = stpq
 		}
 		bracketed = true

 	case math.Abs(g) < math.Abs(gx):
 		// A lower function value, derivatives of the same sign, and the
 		// magnitude of the derivative decreases. Extrapolate function values
 		// at x and step so that the next step lies between step and y.

 		theta := 3*(fx-f)/(step-x) + gx + g
 		s := math.Max(math.Abs(gx), math.Abs(g))
 		s = math.Max(s, math.Abs(theta))
 		gamma := s * math.Sqrt(math.Max(0, (theta/s)*(theta/s)-(gx/s)*(g/s)))
 		if step > x {
 			gamma *= -1
 		}
 		p := gamma - g + theta
 		q := gamma + gx - g + gamma
 		r := p / q
 		var stpc float64
 		switch {
 		case r < 0 && gamma != 0:
 			stpc = step + r*(x-step)
 		case step > x:
 			stpc = mt.upper
 		default:
 			stpc = mt.lower
 		}
 		stpq := step + g/(g-gx)*(x-step)

 		if mt.bracketed {
 			// We are extrapolating so be cautious and take the step that
 			// is closer to step.
 			if math.Abs(stpc-step) < math.Abs(stpq-step) {
 				next = stpc
 			} else {
 				next = stpq
 			}
 			// Modify next if it is close to or beyond y.
 			if step > x {
 				next = math.Min(step+2.0/3*(y-step), next)
 			} else {
 				next = math.Max(step+2.0/3*(y-step), next)
 			}
 		} else {
 			// Minimum has not been bracketed so take the larger step...
 			if math.Abs(stpc-step) > math.Abs(stpq-step) {
 				next = stpc
 			} else {
 				next = stpq
 			}
 			// ...but within reason.
 			next = math.Max(mt.lower, math.Min(next, mt.upper))
 		}

 	default:
 		// A lower function value, derivatives of the same sign, and the
 		// magnitude of the derivative does not decrease. The function seems to
 		// decrease rapidly in the direction of the step.

 		switch {
 		case mt.bracketed:
 			theta := 3*(f-fy)/(y-step) + gy + g
 			s := math.Max(math.Abs(gy), math.Abs(g))
 			s = math.Max(s, math.Abs(theta))
 			gamma := s * math.Sqrt((theta/s)*(theta/s)-(gy/s)*(g/s))
 			if step > y {
 				gamma *= -1
 			}
 			p := gamma - g + theta
 			q := gamma - g + gamma + gy
 			r := p / q
 			next = step + r*(y-step)
 		case step > x:
 			next = mt.upper
 		default:
 			next = mt.lower
 		}
 	}

 	if f > fx {
 		// x is still the best step.
 		mt.y = step
 		mt.fy = f
 		mt.gy = g
 	} else {
 		// step is the new best step.
 		if gNeg {
 			mt.y = x
 			mt.fy = fx
 			mt.gy = gx
 		}
 		mt.x = step
 		mt.fx = f
 		mt.gx = g
 	}
 	mt.bracketed = bracketed
 	mt.step = next
 }
	// 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 optimize

	import "math"

	// MoreThuente is a Linesearcher that finds steps that satisfy both the
	// sufficient decrease and curvature conditions (the strong Wolfe conditions).
	//
	// References:
	// - More, J.J. and D.J. Thuente: Line Search Algorithms with Guaranteed Sufficient
	// Decrease. ACM Transactions on Mathematical Software 20(3) (1994), 286-307
	type MoreThuente struct {
	// DecreaseFactor is the constant factor in the sufficient decrease
	// (Armijo) condition.
	// It must be in the interval [0, 1). The default value is 0.
	DecreaseFactor float64
	// CurvatureFactor is the constant factor in the Wolfe conditions. Smaller
	// values result in a more exact line search.
	// A set value must be in the interval (0, 1). If it is zero, it will be
	// defaulted to 0.9.
	CurvatureFactor float64
	// StepTolerance sets the minimum acceptable width for the linesearch
	// interval. If the relative interval length is less than this value,
	// ErrLinesearcherFailure is returned.
	// It must be non-negative. If it is zero, it will be defaulted to 1e-10.
	StepTolerance float64

	// MinimumStep is the minimum step that the linesearcher will take.
	// It must be non-negative and less than MaximumStep. Defaults to no
	// minimum (a value of 0).
	MinimumStep float64
	// MaximumStep is the maximum step that the linesearcher will take.
	// It must be greater than MinimumStep. If it is zero, it will be defaulted
	// to 1e20.
	MaximumStep float64

	bracketed bool // Indicates if a minimum has been bracketed.
	fInit float64 // Function value at step = 0.
	gInit float64 // Derivative value at step = 0.

	// When stage is 1, the algorithm updates the interval given by x and y
	// so that it contains a minimizer of the modified function
	// psi(step) = f(step) - f(0) - DecreaseFactor * step * f'(0).
	// When stage is 2, the interval is updated so that it contains a minimizer
	// of f.
	stage int

	step float64 // Current step.
	lower, upper float64 // Lower and upper bounds on the next step.
	x float64 // Endpoint of the interval with a lower function value.
	fx, gx float64 // Data at x.
	y float64 // The other endpoint.
	fy, gy float64 // Data at y.
	width [2]float64 // Width of the interval at two previous iterations.
	}

	const (
	mtMinGrowthFactor float64 = 1.1
	mtMaxGrowthFactor float64 = 4
	)

	func (mt *MoreThuente) Init(f, g float64, step float64) Operation {
	// Based on the original Fortran code that is available, for example, from
	// http://ftp.mcs.anl.gov/pub/MINPACK-2/csrch/
	// as part of
	// MINPACK-2 Project. November 1993.
	// Argonne National Laboratory and University of Minnesota.
	// Brett M. Averick, Richard G. Carter, and Jorge J. Moré.

	if g >= 0 {
	panic("morethuente: initial derivative is non-negative")
	}
	if step <= 0 {
	panic("morethuente: invalid initial step")
	}

	if mt.CurvatureFactor == 0 {
	mt.CurvatureFactor = 0.9
	}
	if mt.StepTolerance == 0 {
	mt.StepTolerance = 1e-10
	}
	if mt.MaximumStep == 0 {
	mt.MaximumStep = 1e20
	}

	if mt.MinimumStep < 0 {
	panic("morethuente: minimum step is negative")
	}
	if mt.MaximumStep <= mt.MinimumStep {
	panic("morethuente: maximum step is not greater than minimum step")
	}
	if mt.DecreaseFactor < 0 \|\| mt.DecreaseFactor >= 1 {
	panic("morethuente: invalid decrease factor")
	}
	if mt.CurvatureFactor <= 0 \|\| mt.CurvatureFactor >= 1 {
	panic("morethuente: invalid curvature factor")
	}
	if mt.StepTolerance <= 0 {
	panic("morethuente: step tolerance is not positive")
	}

	if step < mt.MinimumStep {
	step = mt.MinimumStep
	}
	if step > mt.MaximumStep {
	step = mt.MaximumStep
	}

	mt.bracketed = false
	mt.stage = 1
	mt.fInit = f
	mt.gInit = g

	mt.x, mt.fx, mt.gx = 0, f, g
	mt.y, mt.fy, mt.gy = 0, f, g

	mt.lower = 0
	mt.upper = step + mtMaxGrowthFactor*step

	mt.width[0] = mt.MaximumStep - mt.MinimumStep
	mt.width[1] = 2 * mt.width[0]

	mt.step = step
	return FuncEvaluation \| GradEvaluation
	}

	func (mt *MoreThuente) Iterate(f, g float64) (Operation, float64, error) {
	if mt.stage == 0 {
	panic("morethuente: Init has not been called")
	}

	gTest := mt.DecreaseFactor * mt.gInit
	fTest := mt.fInit + mt.step*gTest

	if mt.bracketed {
	if mt.step <= mt.lower \|\| mt.step >= mt.upper \|\| mt.upper-mt.lower <= mt.StepTolerance*mt.upper {
	// step contains the best step found (see below).
	return NoOperation, mt.step, ErrLinesearcherFailure
	}
	}
	if mt.step == mt.MaximumStep && f <= fTest && g <= gTest {
	return NoOperation, mt.step, ErrLinesearcherBound
	}
	if mt.step == mt.MinimumStep && (f > fTest \|\| g >= gTest) {
	return NoOperation, mt.step, ErrLinesearcherFailure
	}

	// Test for convergence.
	if f <= fTest && math.Abs(g) <= mt.CurvatureFactor*(-mt.gInit) {
	mt.stage = 0
	return MajorIteration, mt.step, nil
	}

	if mt.stage == 1 && f <= fTest && g >= 0 {
	mt.stage = 2
	}

	if mt.stage == 1 && f <= mt.fx && f > fTest {
	// Lower function value but the decrease is not sufficient .

	// Compute values and derivatives of the modified function at step, x, y.
	fm := f - mt.step*gTest
	fxm := mt.fx - mt.x*gTest
	fym := mt.fy - mt.y*gTest
	gm := g - gTest
	gxm := mt.gx - gTest
	gym := mt.gy - gTest
	// Update x, y and step.
	mt.nextStep(fxm, gxm, fym, gym, fm, gm)
	// Recover values and derivates of the non-modified function at x and y.
	mt.fx = fxm + mt.x*gTest
	mt.fy = fym + mt.y*gTest
	mt.gx = gxm + gTest
	mt.gy = gym + gTest
	} else {
	// Update x, y and step.
	mt.nextStep(mt.fx, mt.gx, mt.fy, mt.gy, f, g)
	}

	if mt.bracketed {
	// Monitor the length of the bracketing interval. If the interval has
	// not been reduced sufficiently after two steps, use bisection to
	// force its length to zero.
	width := mt.y - mt.x
	if math.Abs(width) >= 2.0/3*mt.width[1] {
	mt.step = mt.x + 0.5*width
	}
	mt.width[0], mt.width[1] = math.Abs(width), mt.width[0]
	}

	if mt.bracketed {
	mt.lower = math.Min(mt.x, mt.y)
	mt.upper = math.Max(mt.x, mt.y)
	} else {
	mt.lower = mt.step + mtMinGrowthFactor*(mt.step-mt.x)
	mt.upper = mt.step + mtMaxGrowthFactor*(mt.step-mt.x)
	}

	// Force the step to be in [MinimumStep, MaximumStep].
	mt.step = math.Max(mt.MinimumStep, math.Min(mt.step, mt.MaximumStep))

	if mt.bracketed {
	if mt.step <= mt.lower \|\| mt.step >= mt.upper \|\| mt.upper-mt.lower <= mt.StepTolerance*mt.upper {
	// If further progress is not possible, set step to the best step
	// obtained during the search.
	mt.step = mt.x
	}
	}

	return FuncEvaluation \| GradEvaluation, mt.step, nil
	}

	// nextStep computes the next safeguarded step and updates the interval that
	// contains a step that satisfies the sufficient decrease and curvature
	// conditions.
	func (mt *MoreThuente) nextStep(fx, gx, fy, gy, f, g float64) {
	x := mt.x
	y := mt.y
	step := mt.step

	gNeg := g < 0
	if gx < 0 {
	gNeg = !gNeg
	}

	var next float64
	var bracketed bool
	switch {
	case f > fx:
	// A higher function value. The minimum is bracketed between x and step.
	// We want the next step to be closer to x because the function value
	// there is lower.

	theta := 3*(fx-f)/(step-x) + gx + g
	s := math.Max(math.Abs(gx), math.Abs(g))
	s = math.Max(s, math.Abs(theta))
	gamma := s * math.Sqrt((theta/s)(theta/s)-(gx/s)(g/s))
	if step < x {
	gamma *= -1
	}
	p := gamma - gx + theta
	q := gamma - gx + gamma + g
	r := p / q
	stpc := x + r*(step-x)
	stpq := x + gx/((fx-f)/(step-x)+gx)/2*(step-x)

	if math.Abs(stpc-x) < math.Abs(stpq-x) {
	// The cubic step is closer to x than the quadratic step.
	// Take the cubic step.
	next = stpc
	} else {
	// If f is much larger than fx, then the quadratic step may be too
	// close to x. Therefore heuristically take the average of the
	// cubic and quadratic steps.
	next = stpc + (stpq-stpc)/2
	}
	bracketed = true

	case gNeg:
	// A lower function value and derivatives of opposite sign. The minimum
	// is bracketed between x and step. If we choose a step that is far
	// from step, the next iteration will also likely fall in this case.

	theta := 3*(fx-f)/(step-x) + gx + g
	s := math.Max(math.Abs(gx), math.Abs(g))
	s = math.Max(s, math.Abs(theta))
	gamma := s * math.Sqrt((theta/s)(theta/s)-(gx/s)(g/s))
	if step > x {
	gamma *= -1
	}
	p := gamma - g + theta
	q := gamma - g + gamma + gx
	r := p / q
	stpc := step + r*(x-step)
	stpq := step + g/(g-gx)*(x-step)

	if math.Abs(stpc-step) > math.Abs(stpq-step) {
	// The cubic step is farther from x than the quadratic step.
	// Take the cubic step.
	next = stpc
	} else {
	// Take the quadratic step.
	next = stpq
	}
	bracketed = true

	case math.Abs(g) < math.Abs(gx):
	// A lower function value, derivatives of the same sign, and the
	// magnitude of the derivative decreases. Extrapolate function values
	// at x and step so that the next step lies between step and y.

	theta := 3*(fx-f)/(step-x) + gx + g
	s := math.Max(math.Abs(gx), math.Abs(g))
	s = math.Max(s, math.Abs(theta))
	gamma := s * math.Sqrt(math.Max(0, (theta/s)(theta/s)-(gx/s)(g/s)))
	if step > x {
	gamma *= -1
	}
	p := gamma - g + theta
	q := gamma + gx - g + gamma
	r := p / q
	var stpc float64
	switch {
	case r < 0 && gamma != 0:
	stpc = step + r*(x-step)
	case step > x:
	stpc = mt.upper
	default:
	stpc = mt.lower
	}
	stpq := step + g/(g-gx)*(x-step)

	if mt.bracketed {
	// We are extrapolating so be cautious and take the step that
	// is closer to step.
	if math.Abs(stpc-step) < math.Abs(stpq-step) {
	next = stpc
	} else {
	next = stpq
	}
	// Modify next if it is close to or beyond y.
	if step > x {
	next = math.Min(step+2.0/3*(y-step), next)
	} else {
	next = math.Max(step+2.0/3*(y-step), next)
	}
	} else {
	// Minimum has not been bracketed so take the larger step...
	if math.Abs(stpc-step) > math.Abs(stpq-step) {
	next = stpc
	} else {
	next = stpq
	}
	// ...but within reason.
	next = math.Max(mt.lower, math.Min(next, mt.upper))
	}

	default:
	// A lower function value, derivatives of the same sign, and the
	// magnitude of the derivative does not decrease. The function seems to
	// decrease rapidly in the direction of the step.

	switch {
	case mt.bracketed:
	theta := 3*(f-fy)/(y-step) + gy + g
	s := math.Max(math.Abs(gy), math.Abs(g))
	s = math.Max(s, math.Abs(theta))
	gamma := s * math.Sqrt((theta/s)(theta/s)-(gy/s)(g/s))
	if step > y {
	gamma *= -1
	}
	p := gamma - g + theta
	q := gamma - g + gamma + gy
	r := p / q
	next = step + r*(y-step)
	case step > x:
	next = mt.upper
	default:
	next = mt.lower
	}
	}

	if f > fx {
	// x is still the best step.
	mt.y = step
	mt.fy = f
	mt.gy = g
	} else {
	// step is the new best step.
	if gNeg {
	mt.y = x
	mt.fy = fx
	mt.gy = gx
	}
	mt.x = step
	mt.fx = f
	mt.gx = g
	}
	mt.bracketed = bracketed
	mt.step = next
	}