benchseries/chart.go - perf - Git at Google

 // Copyright 2022 The Go 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 benchseries

 import (
 	"fmt"
 	"image/color"
 	"math"
 	"os"
 	"path/filepath"
 	"sort"
 	"strings"

 	"gonum.org/v1/plot/vg/draw"
 	"gonum.org/v1/plot/vg/vgimg"

 	//	"gonum.org/v1/plot/vg/vgpdf"
 	//	"gonum.org/v1/plot/vg/vgsvg"

 	"gonum.org/v1/plot"
 	"gonum.org/v1/plot/plotter"
 	"gonum.org/v1/plot/vg"
 )

 type ChartOptions int

 type Point struct {
 	numHash, denHash string
 	values           plotter.Values
 	changes          []float64
 	changeBVID       []benchValID
 }

 // because there are holes in that data, the benchmark index can be larger than the valueIndex
 type benchValID struct {
 	benchIndex, valueIndex int
 }

 const pointRad = 5

 func Chart(cs []*ComparisonSeries, pngDir, pdfDir, svgDir string, logScale bool, threshold float64, boring bool) {

 	doDir := func(s string) {
 		if s != "" {
 			os.MkdirAll(s, 0777)
 		}
 	}
 	doDir(pngDir)
 	doDir(pdfDir)
 	doDir(svgDir)

 	for _, g := range cs {

 		var allValues []float64

 		// When boring runs are omitted, this is where the interesting parts go.
 		selectedPoints := []*Point{}

 		// select a subset of the points, inserting "..." whenever there is a gap.
 		for i, s := range g.Series {

 			values := make(plotter.Values, 0, len(g.Benchmarks))
 			changes := make([]float64, 0, len(g.Benchmarks))
 			changeBenches := make([]benchValID, 0, len(g.Benchmarks)) // which benchmarks changed?
 			for j := range g.Benchmarks {
 				sum := g.Summaries[i][j]
 				if sum.Defined() {
 					ch := math.NaN()
 					v := sum.Center
 					if math.IsInf(v, 0) {
 						continue
 					}
 					if i > 0 {
 						psum := g.Summaries[i-1][j]
 						if psum.Defined() {
 							ch = psum.HeurOverlap(sum, threshold)
 						}
 					}
 					changes = append(changes, ch)
 					changeBenches = append(changeBenches, benchValID{j, len(values)})
 					values = append(values, v)
 					allValues = append(allValues, v)
 				}
 			}
 			hp := g.HashPairs[s]
 			selectedPoints = append(selectedPoints, &Point{numHash: hp.NumHash, denHash: hp.DenHash, values: values, changes: changes, changeBVID: changeBenches})
 		}

 		// Want lines that grab most of the data; it's outliers we worry about
 		sort.Float64s(allValues)
 		lav := len(allValues)
 		const Nth = 25
 		lapNth := (lav + (Nth / 2)) / Nth
 		minLine := allValues[lapNth]
 		maxLine := allValues[lav-lapNth-1]

 		pl := plot.New()

 		pl.Title.Text = g.Unit
 		pl.Title.TextStyle.Font.Size = 40
 		pl.Y.Label.Text = "tip measure / baseline measure"

 		if logScale {
 			pl.Y.Scale = plot.LogScale{}
 			// TODO perhaps these are not the best lines for a log scale.
 			pl.Y.Tick.Marker = ratioLines(minLine, maxLine, allValues[0], allValues[lav-1])

 		} else {
 			pl.Y.Tick.Marker = ratioLines(minLine, maxLine, allValues[0], allValues[lav-1])
 		}
 		pl.Y.Tick.Label.Font.Size = 20

 		grid := plotter.NewGrid()
 		grid.Vertical.Color = nil
 		pl.Add(grid)

 		w := vg.Points(10)

 		var nominalX []string
 		var boxes []plot.Plotter
 		for i, sp := range selectedPoints {

 			perm := absSortedPermFor(sp.changes)
 			rmsChange := norm(sp.changes, 2)
 			sp.changes = permute(sp.changes, perm)
 			l := len(sp.changes)
 			movers := make(map[int]bool)
 			moves := []directedColor{}
 			for k := 1; k <= 5; k++ {
 				if l-k < 0 {
 					break
 				}
 				ch := sp.changes[l-k]
 				c := math.Abs(ch)
 				noteMove := func(clr color.Color) {
 					index := sp.changeBVID[perm[l-k]].valueIndex
 					bi := sp.changeBVID[perm[l-k]].benchIndex
 					prevIndex := -1
 					for _, psp := range selectedPoints[i-1].changeBVID {
 						if psp.benchIndex == bi {
 							prevIndex = psp.valueIndex
 						}
 					}
 					// it should not be the case that a move was recorded, yet there was no match for prevIndex
 					movers[index] = true
 					moves = append(moves, directedColor{prev: selectedPoints[i-1].values.Value(prevIndex), index: index, change: ch, clr: clr})
 				}
 				if c >= 100 {
 					noteMove(green(0xff))
 				} else if c > 5 {
 					noteMove(red(0xff))
 				} else if c > 4 {
 					noteMove(purple(0xff))
 				} else if c > 3 {
 					noteMove(blue(0xff))
 				} else {
 					break
 				}

 			}

 			p := sp.values
 			b, err := MyNewBoxPlot(w, float64(i), p, moves, movers)
 			if err != nil {
 				panic(err)
 			}
 			b.bp.BoxStyle.Color = color.Black
 			b.bp.GlyphStyle.Radius = pointRad

 			boxes = append(boxes, b)

 			if rmsChange > 6 {
 				b.bp.BoxStyle.Color = red(0xff)
 				b.bp.FillColor = red(0x50)
 			} else if rmsChange > 4 {
 				b.bp.BoxStyle.Color = purple(0xFF)
 				b.bp.FillColor = purple(0x50)
 			} else if percentile(sp.changes, 1) > 4 {
 				b.bp.BoxStyle.Color = blue(0xff)
 				b.bp.FillColor = blue(0x50)
 			}
 			label := sp.numHash + "/" + sp.denHash

 			nominalX = append(nominalX, label)
 		}
 		pl.Add(boxes...)
 		pl.NominalX(nominalX...)

 		pl.X.Tick.Width = vg.Points(0.5)
 		pl.X.Tick.Length = vg.Points(8)

 		pl.X.Tick.Label.Rotation = -math.Pi / 8
 		pl.X.Tick.Label.YAlign = draw.YTop
 		pl.X.Tick.Label.XAlign = draw.XLeft
 		pl.X.Tick.Label.Font.Size = 15

 		// Force the unit ratio onto the graph to ensure there is a scale.
 		if pl.Y.Min > 1 {
 			pl.Y.Min = 1
 		}
 		if pl.Y.Max < 1 {
 			pl.Y.Max = 1
 		}

 		// Heuristic width and height
 		width := 1.5 * float64(2+len(selectedPoints))
 		height := width / 3
 		if pl.Y.Max > 1 && pl.Y.Max-1 > 2*(math.Max(maxLine, minLine)-1) ||
 			pl.Y.Min < 1 && 1-pl.Y.Min > 2*(1-math.Min(maxLine, minLine)) {
 			height = height * 1.5
 		}
 		if height < 5 {
 			height = 5
 		}
 		dpi := 300

 		// // Override heuristics if demanded
 		// if *flagWidth != 0 {
 		// 	width = *flagWidth
 		// }
 		// if *flagHeight != 0 {
 		// 	height = *flagHeight
 		// }

 		// Scale down dpi to conform to twitter limits
 		initialWidth := float64(dpi) * width / 2.54
 		if initialWidth > 8190 {
 			dpi = int(math.Trunc(float64(dpi) * 8190 / initialWidth))
 		}
 		//fmt.Printf("%s: W=%f, H=%f, DPI=%d, PYM=%f, PYm=%f, Ml=%f, ml=%f\n", filename, width, height, dpi,
 		//	p.Y.Max, p.Y.Min, maxLine, minLine)

 		filename := strings.ReplaceAll(g.Unit, "/", "-per-")

 		do := func(dir, sfx string, can vg.CanvasWriterTo) {
 			file := filepath.Join(dir, filename) + "." + sfx
 			f, err := os.Create(file)
 			if err != nil {
 				panic(err)
 			}

 			pl.Draw(draw.New(can))
 			_, err = can.WriteTo(f)
 			if err != nil {
 				panic(err)
 			}
 			f.Close()
 		}

 		if pngDir != "" {
 			do(pngDir, "png", vgimg.PngCanvas{Canvas: vgimg.NewWith(vgimg.UseWH(vg.Length(width)*vg.Centimeter, vg.Length(height)*vg.Centimeter),
 				vgimg.UseDPI(dpi), vgimg.UseBackgroundColor(color.White))})
 		}
 		// if pdfDir != "" {
 		// 	do(pdfDir, "pdf", vgpdf.Canvas{Canvas: vgimg.NewWith(vgimg.UseWH(vg.Length(width)*vg.Centimeter, vg.Length(height)*vg.Centimeter),
 		// 		vgimg.UseDPI(dpi), vgimg.UseBackgroundColor(color.White))})
 		// }
 		// if svgDir != "" {
 		// 	do(svgDir, "svg", vgsvg.Canvas{Canvas: vgimg.NewWith(vgimg.UseWH(vg.Length(width)*vg.Centimeter, vg.Length(height)*vg.Centimeter),
 		// 		vgimg.UseDPI(dpi), vgimg.UseBackgroundColor(color.White))})
 		// }
 		// Other formats, including default PNG
 		//if err := p.Save(20*vg.Inch, 5*vg.Inch, filepath.Join(dir, filename)+".png"); err != nil {
 		//	panic(err)
 		//}
 		//if err := p.Save(20*vg.Inch, 5*vg.Inch, filepath.Join(dir, filename)+".svg"); err != nil {
 		//	panic(err)
 		//}
 		//if err := p.Save(20*vg.Inch, 5*vg.Inch, filepath.Join(dir, filename)+".pdf"); err != nil {
 		//	panic(err)
 		//}
 	}
 }

 func red(alpha uint8) color.Color {
 	return color.NRGBA{0xFF, 0, 0, alpha}
 }
 func green(alpha uint8) color.Color {
 	return color.NRGBA{0, 0xFF, 0, alpha}
 }
 func blue(alpha uint8) color.Color {
 	return color.NRGBA{0, 0, 0xFF, alpha}
 }
 func purple(alpha uint8) color.Color {
 	return color.NRGBA{0x99, 0, 0xFF, alpha}
 }

 type directedColor struct {
 	prev   float64
 	index  int
 	change float64
 	clr    color.Color
 }

 type MyBoxPlot struct {
 	bp     *plotter.BoxPlot
 	movers map[int]bool
 	moves  []directedColor
 }

 func MyNewBoxPlot(w vg.Length, loc float64, values plotter.Valuer, moves []directedColor, movers map[int]bool) (*MyBoxPlot, error) {
 	b, err := plotter.NewBoxPlot(w, loc, values)
 	if err != nil {
 		return nil, err
 	}
 	return &MyBoxPlot{bp: b, moves: moves, movers: movers}, nil
 }

 // Plot draws the BoxPlot on Canvas c and Plot plt.
 func (p *MyBoxPlot) Plot(c draw.Canvas, plt *plot.Plot) {
 	b := p.bp

 	trX, trY := plt.Transforms(&c)
 	x := trX(b.Location)
 	px := trX(b.Location - 1)
 	if !c.ContainsX(x) {
 		return
 	}
 	x += b.Offset
 	px += b.Offset

 	med := trY(b.Median)
 	q1 := trY(b.Quartile1)
 	q3 := trY(b.Quartile3)
 	aLow := trY(b.AdjLow)
 	aHigh := trY(b.AdjHigh)

 	pts := []vg.Point{
 		{X: x - b.Width/2, Y: q1},
 		{X: x - b.Width/2, Y: q3},
 		{X: x + b.Width/2, Y: q3},
 		{X: x + b.Width/2, Y: q1},
 		{X: x - b.Width/2 - b.BoxStyle.Width/2, Y: q1},
 	}
 	box := c.ClipLinesY(pts)
 	if b.FillColor != nil {
 		c.FillPolygon(b.FillColor, c.ClipPolygonY(pts))
 	}
 	c.StrokeLines(b.BoxStyle, box...)

 	medLine := c.ClipLinesY([]vg.Point{
 		{X: x - b.Width/2, Y: med},
 		{X: x + b.Width/2, Y: med},
 	})
 	c.StrokeLines(b.MedianStyle, medLine...)

 	cap := b.CapWidth / 2
 	whisks := c.ClipLinesY(
 		[]vg.Point{{X: x, Y: q3}, {X: x, Y: aHigh}},
 		[]vg.Point{{X: x - cap, Y: aHigh}, {X: x + cap, Y: aHigh}},
 		[]vg.Point{{X: x, Y: q1}, {X: x, Y: aLow}},
 		[]vg.Point{{X: x - cap, Y: aLow}, {X: x + cap, Y: aLow}},
 	)
 	c.StrokeLines(b.WhiskerStyle, whisks...)

 	for _, out := range b.Outside {
 		y := trY(b.Value(out))
 		if c.ContainsY(y) {
 			c.DrawGlyphNoClip(b.GlyphStyle, vg.Point{X: x, Y: y})
 		}
 	}

 	for _, dc := range p.moves {
 		clr := dc.clr
 		y := trY(b.Value(dc.index))
 		py := trY(dc.prev)
 		if c.ContainsY(y) && c.ContainsY(py) {
 			c.SetLineStyle(draw.LineStyle{Color: clr, Width: vg.Points(1)})
 			p := make(vg.Path, 0, 3)
 			p.Move(vg.Point{X: px, Y: py})
 			p.Line(vg.Point{X: x, Y: y})
 			c.Stroke(p)
 		}
 	}
 }

 func (b *MyBoxPlot) DataRange() (float64, float64, float64, float64) { return b.bp.DataRange() }
 func (b *MyBoxPlot) GlyphBoxes(plt *plot.Plot) []plot.GlyphBox       { return b.bp.GlyphBoxes(plt) }
 func (b *MyBoxPlot) OutsideLabels(labels plotter.Labeller) (*plotter.Labels, error) {
 	return b.bp.OutsideLabels(labels)
 }

 const (
 	cosπover4 = vg.Length(.707106781202420)
 	sinπover6 = vg.Length(.500000000025921)
 	cosπover6 = vg.Length(.866025403769473)
 )

 // CrossGlyph is a glyph that draws a big X.
 // this version draws a heavier X.
 type CrossGlyph struct{}

 // DrawGlyph implements the Glyph interface.
 func (CrossGlyph) DrawGlyph(c *draw.Canvas, sty draw.GlyphStyle, pt vg.Point) {
 	c.SetLineStyle(draw.LineStyle{Color: sty.Color, Width: vg.Points(1)})
 	r := sty.Radius * cosπover4
 	p := make(vg.Path, 0, 2)
 	p.Move(vg.Point{X: pt.X - r, Y: pt.Y - r})
 	p.Line(vg.Point{X: pt.X + r, Y: pt.Y + r})
 	c.Stroke(p)
 	p = p[:0]
 	p.Move(vg.Point{X: pt.X - r, Y: pt.Y + r})
 	p.Line(vg.Point{X: pt.X + r, Y: pt.Y - r})
 	c.Stroke(p)
 }

 type TriDown struct{}

 // DrawGlyph implements the Glyph interface.
 func (TriDown) DrawGlyph(c *draw.Canvas, sty draw.GlyphStyle, pt vg.Point) {
 	c.SetLineStyle(draw.LineStyle{Color: sty.Color, Width: vg.Points(1)})
 	r := sty.Radius * cosπover4
 	p := make(vg.Path, 0, 3)
 	p.Move(vg.Point{X: pt.X - r, Y: pt.Y + r})
 	p.Line(vg.Point{X: pt.X, Y: pt.Y - r})
 	c.Stroke(p)
 	p = p[:0]
 	p.Move(vg.Point{X: pt.X + r, Y: pt.Y + r})
 	p.Line(vg.Point{X: pt.X, Y: pt.Y - r})
 	c.Stroke(p)
 	p = p[:0]
 	p.Move(vg.Point{X: pt.X - r, Y: pt.Y})
 	p.Line(vg.Point{X: pt.X + r, Y: pt.Y})
 	c.Stroke(p)
 }

 type TriUp struct{}

 // DrawGlyph implements the Glyph interface.
 func (TriUp) DrawGlyph(c *draw.Canvas, sty draw.GlyphStyle, pt vg.Point) {
 	c.SetLineStyle(draw.LineStyle{Color: sty.Color, Width: vg.Points(1)})
 	r := sty.Radius * cosπover4
 	p := make(vg.Path, 0, 3)
 	p.Move(vg.Point{X: pt.X - r, Y: pt.Y - r})
 	p.Line(vg.Point{X: pt.X, Y: pt.Y + r})
 	c.Stroke(p)
 	p = p[:0]
 	p.Move(vg.Point{X: pt.X + r, Y: pt.Y - r})
 	p.Line(vg.Point{X: pt.X, Y: pt.Y + r})
 	c.Stroke(p)
 	p = p[:0]
 	p.Move(vg.Point{X: pt.X - r, Y: pt.Y})
 	p.Line(vg.Point{X: pt.X + r, Y: pt.Y})
 	c.Stroke(p)
 }

 type Lines struct {
 	ticks []plot.Tick
 }

 // roundish finds a roundish fraction less than x, and the number of digits for formatting.
 // x is distance from 1.0, so 1 +/- roundish(x) gives a good location for a grid line.
 func roundish(x float64) (float64, int) {
 	if !(x > 0) { // catch NaN also.
 		panic(fmt.Sprintf("Roundish(%.9g <= 0)", x))
 	}
 	if x >= 1 {
 		return math.Trunc(x), 0
 	}
 	if x >= 0.5 {
 		return 0.5, 1
 	}
 	if x >= 0.25 {
 		return 0.25, 2
 	}
 	if x >= 0.2 {
 		return 0.2, 1
 	}
 	if x >= 0.1 {
 		return 0.1, 1
 	}
 	x, n := roundish(x * 10)
 	return x / 10, n + 1
 }

 func reverseTicks(ticks []plot.Tick) []plot.Tick {
 	l := len(ticks)
 	for i := 0; i < l/2; i++ {
 		ticks[i], ticks[l-i-1] = ticks[l-i-1], ticks[i]
 	}
 	return ticks
 }

 func ratioLines(low, high, min, max float64) Lines {
 	if high <= 1 {
 		if low == 1 {
 			// TODO this is a degenerate case
 			return Lines{ticks: []plot.Tick{one}}
 		}

 		step, k := roundish(1 - low)
 		var ticks []plot.Tick
 		for t := 1.0; t > min; t -= step {
 			ticks = append(ticks, tick(t, k))
 		}

 		return Lines{ticks: reverseTicks(ticks)}
 	} else if low >= 1 {

 		step, k := roundish(high - 1)
 		k++ // for 1.frac
 		var ticks []plot.Tick
 		for t := 1.0; t < max; t += step {
 			ticks = append(ticks, tick(t, k))
 		}

 		return Lines{ticks: ticks}
 	}
 	rmin, kmin := roundish(1 - low)
 	rmax, k := roundish(high - 1)
 	if rmax < rmin {
 		rmax = rmin
 		k = kmin
 	}
 	k++ // for 1.frac

 	step := rmax
 	var ticks []plot.Tick
 	for t := 1.0; t > min; t -= step {
 		ticks = append(ticks, tick(t, k))
 	}
 	ticks = reverseTicks(ticks)
 	for t := 1.0 + step; t < max; t += step {
 		ticks = append(ticks, tick(t, k))
 	}

 	return Lines{ticks: ticks}
 }

 func tick(x float64, k int) plot.Tick {
 	return plot.Tick{Value: x, Label: fmt.Sprintf("%.[2]*[1]g", x, k)}
 }

 var one = plot.Tick{
 	Value: 1.0, Label: "1.0",
 }

 func (u Lines) Ticks(min, max float64) []plot.Tick {
 	return u.ticks
 }
	// Copyright 2022 The Go 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 benchseries

	import (
	"fmt"
	"image/color"
	"math"
	"os"
	"path/filepath"
	"sort"
	"strings"

	"gonum.org/v1/plot/vg/draw"
	"gonum.org/v1/plot/vg/vgimg"

	// "gonum.org/v1/plot/vg/vgpdf"
	// "gonum.org/v1/plot/vg/vgsvg"

	"gonum.org/v1/plot"
	"gonum.org/v1/plot/plotter"
	"gonum.org/v1/plot/vg"
	)

	type ChartOptions int

	type Point struct {
	numHash, denHash string
	values plotter.Values
	changes []float64
	changeBVID []benchValID
	}

	// because there are holes in that data, the benchmark index can be larger than the valueIndex
	type benchValID struct {
	benchIndex, valueIndex int
	}

	const pointRad = 5

	func Chart(cs []*ComparisonSeries, pngDir, pdfDir, svgDir string, logScale bool, threshold float64, boring bool) {

	doDir := func(s string) {
	if s != "" {
	os.MkdirAll(s, 0777)
	}
	}
	doDir(pngDir)
	doDir(pdfDir)
	doDir(svgDir)

	for _, g := range cs {

	var allValues []float64

	// When boring runs are omitted, this is where the interesting parts go.
	selectedPoints := []*Point{}

	// select a subset of the points, inserting "..." whenever there is a gap.
	for i, s := range g.Series {

	values := make(plotter.Values, 0, len(g.Benchmarks))
	changes := make([]float64, 0, len(g.Benchmarks))
	changeBenches := make([]benchValID, 0, len(g.Benchmarks)) // which benchmarks changed?
	for j := range g.Benchmarks {
	sum := g.Summaries[i][j]
	if sum.Defined() {
	ch := math.NaN()
	v := sum.Center
	if math.IsInf(v, 0) {
	continue
	}
	if i > 0 {
	psum := g.Summaries[i-1][j]
	if psum.Defined() {
	ch = psum.HeurOverlap(sum, threshold)
	}
	}
	changes = append(changes, ch)
	changeBenches = append(changeBenches, benchValID{j, len(values)})
	values = append(values, v)
	allValues = append(allValues, v)
	}
	}
	hp := g.HashPairs[s]
	selectedPoints = append(selectedPoints, &Point{numHash: hp.NumHash, denHash: hp.DenHash, values: values, changes: changes, changeBVID: changeBenches})
	}

	// Want lines that grab most of the data; it's outliers we worry about
	sort.Float64s(allValues)
	lav := len(allValues)
	const Nth = 25
	lapNth := (lav + (Nth / 2)) / Nth
	minLine := allValues[lapNth]
	maxLine := allValues[lav-lapNth-1]

	pl := plot.New()

	pl.Title.Text = g.Unit
	pl.Title.TextStyle.Font.Size = 40
	pl.Y.Label.Text = "tip measure / baseline measure"

	if logScale {
	pl.Y.Scale = plot.LogScale{}
	// TODO perhaps these are not the best lines for a log scale.
	pl.Y.Tick.Marker = ratioLines(minLine, maxLine, allValues[0], allValues[lav-1])

	} else {
	pl.Y.Tick.Marker = ratioLines(minLine, maxLine, allValues[0], allValues[lav-1])
	}
	pl.Y.Tick.Label.Font.Size = 20

	grid := plotter.NewGrid()
	grid.Vertical.Color = nil
	pl.Add(grid)

	w := vg.Points(10)

	var nominalX []string
	var boxes []plot.Plotter
	for i, sp := range selectedPoints {

	perm := absSortedPermFor(sp.changes)
	rmsChange := norm(sp.changes, 2)
	sp.changes = permute(sp.changes, perm)
	l := len(sp.changes)
	movers := make(map[int]bool)
	moves := []directedColor{}
	for k := 1; k <= 5; k++ {
	if l-k < 0 {
	break
	}
	ch := sp.changes[l-k]
	c := math.Abs(ch)
	noteMove := func(clr color.Color) {
	index := sp.changeBVID[perm[l-k]].valueIndex
	bi := sp.changeBVID[perm[l-k]].benchIndex
	prevIndex := -1
	for _, psp := range selectedPoints[i-1].changeBVID {
	if psp.benchIndex == bi {
	prevIndex = psp.valueIndex
	}
	}
	// it should not be the case that a move was recorded, yet there was no match for prevIndex
	movers[index] = true
	moves = append(moves, directedColor{prev: selectedPoints[i-1].values.Value(prevIndex), index: index, change: ch, clr: clr})
	}
	if c >= 100 {
	noteMove(green(0xff))
	} else if c > 5 {
	noteMove(red(0xff))
	} else if c > 4 {
	noteMove(purple(0xff))
	} else if c > 3 {
	noteMove(blue(0xff))
	} else {
	break
	}

	}

	p := sp.values
	b, err := MyNewBoxPlot(w, float64(i), p, moves, movers)
	if err != nil {
	panic(err)
	}
	b.bp.BoxStyle.Color = color.Black
	b.bp.GlyphStyle.Radius = pointRad

	boxes = append(boxes, b)

	if rmsChange > 6 {
	b.bp.BoxStyle.Color = red(0xff)
	b.bp.FillColor = red(0x50)
	} else if rmsChange > 4 {
	b.bp.BoxStyle.Color = purple(0xFF)
	b.bp.FillColor = purple(0x50)
	} else if percentile(sp.changes, 1) > 4 {
	b.bp.BoxStyle.Color = blue(0xff)
	b.bp.FillColor = blue(0x50)
	}
	label := sp.numHash + "/" + sp.denHash

	nominalX = append(nominalX, label)
	}
	pl.Add(boxes...)
	pl.NominalX(nominalX...)

	pl.X.Tick.Width = vg.Points(0.5)
	pl.X.Tick.Length = vg.Points(8)

	pl.X.Tick.Label.Rotation = -math.Pi / 8
	pl.X.Tick.Label.YAlign = draw.YTop
	pl.X.Tick.Label.XAlign = draw.XLeft
	pl.X.Tick.Label.Font.Size = 15

	// Force the unit ratio onto the graph to ensure there is a scale.
	if pl.Y.Min > 1 {
	pl.Y.Min = 1
	}
	if pl.Y.Max < 1 {
	pl.Y.Max = 1
	}

	// Heuristic width and height
	width := 1.5 * float64(2+len(selectedPoints))
	height := width / 3
	if pl.Y.Max > 1 && pl.Y.Max-1 > 2*(math.Max(maxLine, minLine)-1) \|\|
	pl.Y.Min < 1 && 1-pl.Y.Min > 2*(1-math.Min(maxLine, minLine)) {
	height = height * 1.5
	}
	if height < 5 {
	height = 5
	}
	dpi := 300

	// // Override heuristics if demanded
	// if *flagWidth != 0 {
	// width = *flagWidth
	// }
	// if *flagHeight != 0 {
	// height = *flagHeight
	// }

	// Scale down dpi to conform to twitter limits
	initialWidth := float64(dpi) * width / 2.54
	if initialWidth > 8190 {
	dpi = int(math.Trunc(float64(dpi) * 8190 / initialWidth))
	}
	//fmt.Printf("%s: W=%f, H=%f, DPI=%d, PYM=%f, PYm=%f, Ml=%f, ml=%f\n", filename, width, height, dpi,
	// p.Y.Max, p.Y.Min, maxLine, minLine)

	filename := strings.ReplaceAll(g.Unit, "/", "-per-")

	do := func(dir, sfx string, can vg.CanvasWriterTo) {
	file := filepath.Join(dir, filename) + "." + sfx
	f, err := os.Create(file)
	if err != nil {
	panic(err)
	}

	pl.Draw(draw.New(can))
	_, err = can.WriteTo(f)
	if err != nil {
	panic(err)
	}
	f.Close()
	}

	if pngDir != "" {
	do(pngDir, "png", vgimg.PngCanvas{Canvas: vgimg.NewWith(vgimg.UseWH(vg.Length(width)vg.Centimeter, vg.Length(height)vg.Centimeter),
	vgimg.UseDPI(dpi), vgimg.UseBackgroundColor(color.White))})
	}
	// if pdfDir != "" {
	// do(pdfDir, "pdf", vgpdf.Canvas{Canvas: vgimg.NewWith(vgimg.UseWH(vg.Length(width)vg.Centimeter, vg.Length(height)vg.Centimeter),
	// vgimg.UseDPI(dpi), vgimg.UseBackgroundColor(color.White))})
	// }
	// if svgDir != "" {
	// do(svgDir, "svg", vgsvg.Canvas{Canvas: vgimg.NewWith(vgimg.UseWH(vg.Length(width)vg.Centimeter, vg.Length(height)vg.Centimeter),
	// vgimg.UseDPI(dpi), vgimg.UseBackgroundColor(color.White))})
	// }
	// Other formats, including default PNG
	//if err := p.Save(20vg.Inch, 5vg.Inch, filepath.Join(dir, filename)+".png"); err != nil {
	// panic(err)
	//}
	//if err := p.Save(20vg.Inch, 5vg.Inch, filepath.Join(dir, filename)+".svg"); err != nil {
	// panic(err)
	//}
	//if err := p.Save(20vg.Inch, 5vg.Inch, filepath.Join(dir, filename)+".pdf"); err != nil {
	// panic(err)
	//}
	}
	}

	func red(alpha uint8) color.Color {
	return color.NRGBA{0xFF, 0, 0, alpha}
	}
	func green(alpha uint8) color.Color {
	return color.NRGBA{0, 0xFF, 0, alpha}
	}
	func blue(alpha uint8) color.Color {
	return color.NRGBA{0, 0, 0xFF, alpha}
	}
	func purple(alpha uint8) color.Color {
	return color.NRGBA{0x99, 0, 0xFF, alpha}
	}

	type directedColor struct {
	prev float64
	index int
	change float64
	clr color.Color
	}

	type MyBoxPlot struct {
	bp *plotter.BoxPlot
	movers map[int]bool
	moves []directedColor
	}

	func MyNewBoxPlot(w vg.Length, loc float64, values plotter.Valuer, moves []directedColor, movers map[int]bool) (*MyBoxPlot, error) {
	b, err := plotter.NewBoxPlot(w, loc, values)
	if err != nil {
	return nil, err
	}
	return &MyBoxPlot{bp: b, moves: moves, movers: movers}, nil
	}

	// Plot draws the BoxPlot on Canvas c and Plot plt.
	func (p MyBoxPlot) Plot(c draw.Canvas, plt plot.Plot) {
	b := p.bp

	trX, trY := plt.Transforms(&c)
	x := trX(b.Location)
	px := trX(b.Location - 1)
	if !c.ContainsX(x) {
	return
	}
	x += b.Offset
	px += b.Offset

	med := trY(b.Median)
	q1 := trY(b.Quartile1)
	q3 := trY(b.Quartile3)
	aLow := trY(b.AdjLow)
	aHigh := trY(b.AdjHigh)

	pts := []vg.Point{
	{X: x - b.Width/2, Y: q1},
	{X: x - b.Width/2, Y: q3},
	{X: x + b.Width/2, Y: q3},
	{X: x + b.Width/2, Y: q1},
	{X: x - b.Width/2 - b.BoxStyle.Width/2, Y: q1},
	}
	box := c.ClipLinesY(pts)
	if b.FillColor != nil {
	c.FillPolygon(b.FillColor, c.ClipPolygonY(pts))
	}
	c.StrokeLines(b.BoxStyle, box...)

	medLine := c.ClipLinesY([]vg.Point{
	{X: x - b.Width/2, Y: med},
	{X: x + b.Width/2, Y: med},
	})
	c.StrokeLines(b.MedianStyle, medLine...)

	cap := b.CapWidth / 2
	whisks := c.ClipLinesY(
	[]vg.Point{{X: x, Y: q3}, {X: x, Y: aHigh}},
	[]vg.Point{{X: x - cap, Y: aHigh}, {X: x + cap, Y: aHigh}},
	[]vg.Point{{X: x, Y: q1}, {X: x, Y: aLow}},
	[]vg.Point{{X: x - cap, Y: aLow}, {X: x + cap, Y: aLow}},
	)
	c.StrokeLines(b.WhiskerStyle, whisks...)

	for _, out := range b.Outside {
	y := trY(b.Value(out))
	if c.ContainsY(y) {
	c.DrawGlyphNoClip(b.GlyphStyle, vg.Point{X: x, Y: y})
	}
	}

	for _, dc := range p.moves {
	clr := dc.clr
	y := trY(b.Value(dc.index))
	py := trY(dc.prev)
	if c.ContainsY(y) && c.ContainsY(py) {
	c.SetLineStyle(draw.LineStyle{Color: clr, Width: vg.Points(1)})
	p := make(vg.Path, 0, 3)
	p.Move(vg.Point{X: px, Y: py})
	p.Line(vg.Point{X: x, Y: y})
	c.Stroke(p)
	}
	}
	}

	func (b *MyBoxPlot) DataRange() (float64, float64, float64, float64) { return b.bp.DataRange() }
	func (b MyBoxPlot) GlyphBoxes(plt plot.Plot) []plot.GlyphBox { return b.bp.GlyphBoxes(plt) }
	func (b MyBoxPlot) OutsideLabels(labels plotter.Labeller) (plotter.Labels, error) {
	return b.bp.OutsideLabels(labels)
	}

	const (
	cosπover4 = vg.Length(.707106781202420)
	sinπover6 = vg.Length(.500000000025921)
	cosπover6 = vg.Length(.866025403769473)
	)

	// CrossGlyph is a glyph that draws a big X.
	// this version draws a heavier X.
	type CrossGlyph struct{}

	// DrawGlyph implements the Glyph interface.
	func (CrossGlyph) DrawGlyph(c *draw.Canvas, sty draw.GlyphStyle, pt vg.Point) {
	c.SetLineStyle(draw.LineStyle{Color: sty.Color, Width: vg.Points(1)})
	r := sty.Radius * cosπover4
	p := make(vg.Path, 0, 2)
	p.Move(vg.Point{X: pt.X - r, Y: pt.Y - r})
	p.Line(vg.Point{X: pt.X + r, Y: pt.Y + r})
	c.Stroke(p)
	p = p[:0]
	p.Move(vg.Point{X: pt.X - r, Y: pt.Y + r})
	p.Line(vg.Point{X: pt.X + r, Y: pt.Y - r})
	c.Stroke(p)
	}

	type TriDown struct{}

	// DrawGlyph implements the Glyph interface.
	func (TriDown) DrawGlyph(c *draw.Canvas, sty draw.GlyphStyle, pt vg.Point) {
	c.SetLineStyle(draw.LineStyle{Color: sty.Color, Width: vg.Points(1)})
	r := sty.Radius * cosπover4
	p := make(vg.Path, 0, 3)
	p.Move(vg.Point{X: pt.X - r, Y: pt.Y + r})
	p.Line(vg.Point{X: pt.X, Y: pt.Y - r})
	c.Stroke(p)
	p = p[:0]
	p.Move(vg.Point{X: pt.X + r, Y: pt.Y + r})
	p.Line(vg.Point{X: pt.X, Y: pt.Y - r})
	c.Stroke(p)
	p = p[:0]
	p.Move(vg.Point{X: pt.X - r, Y: pt.Y})
	p.Line(vg.Point{X: pt.X + r, Y: pt.Y})
	c.Stroke(p)
	}

	type TriUp struct{}

	// DrawGlyph implements the Glyph interface.
	func (TriUp) DrawGlyph(c *draw.Canvas, sty draw.GlyphStyle, pt vg.Point) {
	c.SetLineStyle(draw.LineStyle{Color: sty.Color, Width: vg.Points(1)})
	r := sty.Radius * cosπover4
	p := make(vg.Path, 0, 3)
	p.Move(vg.Point{X: pt.X - r, Y: pt.Y - r})
	p.Line(vg.Point{X: pt.X, Y: pt.Y + r})
	c.Stroke(p)
	p = p[:0]
	p.Move(vg.Point{X: pt.X + r, Y: pt.Y - r})
	p.Line(vg.Point{X: pt.X, Y: pt.Y + r})
	c.Stroke(p)
	p = p[:0]
	p.Move(vg.Point{X: pt.X - r, Y: pt.Y})
	p.Line(vg.Point{X: pt.X + r, Y: pt.Y})
	c.Stroke(p)
	}

	type Lines struct {
	ticks []plot.Tick
	}

	// roundish finds a roundish fraction less than x, and the number of digits for formatting.
	// x is distance from 1.0, so 1 +/- roundish(x) gives a good location for a grid line.
	func roundish(x float64) (float64, int) {
	if !(x > 0) { // catch NaN also.
	panic(fmt.Sprintf("Roundish(%.9g <= 0)", x))
	}
	if x >= 1 {
	return math.Trunc(x), 0
	}
	if x >= 0.5 {
	return 0.5, 1
	}
	if x >= 0.25 {
	return 0.25, 2
	}
	if x >= 0.2 {
	return 0.2, 1
	}
	if x >= 0.1 {
	return 0.1, 1
	}
	x, n := roundish(x * 10)
	return x / 10, n + 1
	}

	func reverseTicks(ticks []plot.Tick) []plot.Tick {
	l := len(ticks)
	for i := 0; i < l/2; i++ {
	ticks[i], ticks[l-i-1] = ticks[l-i-1], ticks[i]
	}
	return ticks
	}

	func ratioLines(low, high, min, max float64) Lines {
	if high <= 1 {
	if low == 1 {
	// TODO this is a degenerate case
	return Lines{ticks: []plot.Tick{one}}
	}

	step, k := roundish(1 - low)
	var ticks []plot.Tick
	for t := 1.0; t > min; t -= step {
	ticks = append(ticks, tick(t, k))
	}

	return Lines{ticks: reverseTicks(ticks)}
	} else if low >= 1 {

	step, k := roundish(high - 1)
	k++ // for 1.frac
	var ticks []plot.Tick
	for t := 1.0; t < max; t += step {
	ticks = append(ticks, tick(t, k))
	}

	return Lines{ticks: ticks}
	}
	rmin, kmin := roundish(1 - low)
	rmax, k := roundish(high - 1)
	if rmax < rmin {
	rmax = rmin
	k = kmin
	}
	k++ // for 1.frac

	step := rmax
	var ticks []plot.Tick
	for t := 1.0; t > min; t -= step {
	ticks = append(ticks, tick(t, k))
	}
	ticks = reverseTicks(ticks)
	for t := 1.0 + step; t < max; t += step {
	ticks = append(ticks, tick(t, k))
	}

	return Lines{ticks: ticks}
	}

	func tick(x float64, k int) plot.Tick {
	return plot.Tick{Value: x, Label: fmt.Sprintf("%.[2]*[1]g", x, k)}
	}

	var one = plot.Tick{
	Value: 1.0, Label: "1.0",
	}

	func (u Lines) Ticks(min, max float64) []plot.Tick {
	return u.ticks
	}