385 lines
8.5 KiB
Go
385 lines
8.5 KiB
Go
package runchart
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import (
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"github.com/sqshq/sampler/component"
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"github.com/sqshq/sampler/component/util"
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"github.com/sqshq/sampler/config"
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"github.com/sqshq/sampler/console"
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"github.com/sqshq/sampler/data"
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"image"
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"math"
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"strconv"
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"sync"
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"time"
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ui "github.com/gizak/termui/v3"
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)
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const (
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xAxisGridWidth = xAxisLabelsIndent + xAxisLabelsWidth
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xAxisLabelsHeight = 1
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xAxisLabelsWidth = 8
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xAxisLabelsIndent = 2
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yAxisLabelsHeight = 1
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yAxisLabelsIndent = 1
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historyReserveMin = 20
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xBrailleMultiplier = 2
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yBrailleMultiplier = 4
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)
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type Mode int
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const (
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ModeDefault Mode = 0
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ModePinpoint Mode = 1
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)
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const (
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CommandDisableSelection = "DISABLE_SELECTION"
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CommandMoveSelection = "MOVE_SELECTION"
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)
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type RunChart struct {
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*ui.Block
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*data.Consumer
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alert *data.Alert
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lines []TimeLine
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grid ChartGrid
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timescale time.Duration
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mutex *sync.Mutex
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mode Mode
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selection time.Time
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scale int
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legend Legend
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palette console.Palette
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}
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type TimePoint struct {
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value float64
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time time.Time
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coordinate int
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}
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type TimeLine struct {
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points []TimePoint
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extrema ValueExtrema
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color ui.Color
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label string
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selectionCoordinate int
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selectionPoint TimePoint
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}
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type TimeRange struct {
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max time.Time
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min time.Time
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}
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type ValueExtrema struct {
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max float64
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min float64
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}
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func NewRunChart(c config.RunChartConfig, palette console.Palette) *RunChart {
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chart := RunChart{
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Block: component.NewBlock(c.Title, true, palette),
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Consumer: data.NewConsumer(),
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lines: []TimeLine{},
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timescale: calculateTimescale(*c.RateMs),
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mutex: &sync.Mutex{},
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scale: *c.Scale,
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mode: ModeDefault,
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legend: Legend{Enabled: c.Legend.Enabled, Details: c.Legend.Details},
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palette: palette,
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}
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for _, i := range c.Items {
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chart.AddLine(*i.Label, *i.Color)
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}
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go func() {
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for {
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select {
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case sample := <-chart.SampleChannel:
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chart.consumeSample(sample)
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case alert := <-chart.AlertChannel:
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chart.alert = alert
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case command := <-chart.CommandChannel:
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switch command.Type {
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case CommandDisableSelection:
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chart.disableSelection()
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case CommandMoveSelection:
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chart.moveSelection(command.Value.(int))
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}
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}
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}
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}()
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return &chart
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}
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func (c *RunChart) newTimePoint(value float64) TimePoint {
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now := time.Now()
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return TimePoint{
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value: value,
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time: now,
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coordinate: c.calculateTimeCoordinate(now),
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}
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}
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func (c *RunChart) Draw(buffer *ui.Buffer) {
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c.mutex.Lock()
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c.Block.Draw(buffer)
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c.grid = c.newChartGrid()
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drawArea := image.Rect(
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c.Inner.Min.X+c.grid.minTimeWidth+1, c.Inner.Min.Y,
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c.Inner.Max.X, c.Inner.Max.Y-xAxisLabelsHeight-1,
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)
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c.renderAxes(buffer)
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c.renderLines(buffer, drawArea)
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c.renderLegend(buffer, drawArea)
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component.RenderAlert(c.alert, c.Rectangle, buffer)
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c.mutex.Unlock()
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}
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func (c *RunChart) AddLine(Label string, color ui.Color) {
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line := TimeLine{
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points: []TimePoint{},
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color: color,
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label: Label,
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extrema: ValueExtrema{max: -math.MaxFloat64, min: math.MaxFloat64},
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}
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c.lines = append(c.lines, line)
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}
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func (c *RunChart) consumeSample(sample *data.Sample) {
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float, err := strconv.ParseFloat(sample.Value, 64)
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if err != nil {
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c.AlertChannel <- &data.Alert{
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Title: "FAILED TO PARSE A NUMBER",
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Text: err.Error(),
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Color: sample.Color,
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}
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return
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}
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c.mutex.Lock()
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index := -1
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for i, line := range c.lines {
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if line.label == sample.Label {
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index = i
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}
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}
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line := c.lines[index]
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if float < line.extrema.min {
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line.extrema.min = float
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}
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if float > line.extrema.max {
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line.extrema.max = float
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}
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line.points = append(line.points, c.newTimePoint(float))
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c.lines[index] = line
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// perform cleanup once in a while
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if len(line.points)%100 == 0 {
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c.trimOutOfRangeValues()
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}
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c.mutex.Unlock()
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}
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func (c *RunChart) renderLines(buffer *ui.Buffer, drawArea image.Rectangle) {
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canvas := ui.NewCanvas()
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canvas.Rectangle = drawArea
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if len(c.lines) == 0 || len(c.lines[0].points) == 0 {
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return
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}
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selectionCoordinate := c.calculateTimeCoordinate(c.selection)
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selectionPoints := make(map[int]image.Point)
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probe := c.lines[0].points[0]
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delta := ui.AbsInt(c.calculateTimeCoordinate(probe.time) - probe.coordinate)
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for i, line := range c.lines {
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xPoint := make(map[int]image.Point)
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xOrder := make([]int, 0)
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// move selection on a delta, if it was instantiated after cursor move
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if line.selectionCoordinate != 0 {
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line.selectionCoordinate -= delta
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c.lines[i].selectionCoordinate = line.selectionCoordinate
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}
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for j, timePoint := range line.points {
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timePoint.coordinate -= delta
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line.points[j] = timePoint
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var y int
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if c.grid.valueExtrema.max == c.grid.valueExtrema.min {
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y = (drawArea.Dy() - 2) / 2
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} else {
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valuePerY := (c.grid.valueExtrema.max - c.grid.valueExtrema.min) / float64(drawArea.Dy()-2)
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y = int(float64(timePoint.value-c.grid.valueExtrema.min) / valuePerY)
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}
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point := image.Pt(timePoint.coordinate, drawArea.Max.Y-y-1)
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if _, exists := xPoint[point.X]; exists {
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continue
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}
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if !point.In(drawArea) {
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continue
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}
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if line.selectionCoordinate == 0 {
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// instantiate selection coordinate as the closest point to the cursor time
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if len(line.points) > j+1 && ui.AbsInt(timePoint.coordinate-selectionCoordinate) > ui.AbsInt(line.points[j+1].coordinate-selectionCoordinate) {
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selectionPoints[i] = point
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c.lines[i].selectionPoint = timePoint
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}
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} else if timePoint.coordinate == line.selectionCoordinate {
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selectionPoints[i] = point
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}
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xPoint[point.X] = point
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xOrder = append(xOrder, point.X)
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}
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for i, x := range xOrder {
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currentPoint := xPoint[x]
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var previousPoint image.Point
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if i == 0 {
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previousPoint = currentPoint
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} else {
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previousPoint = xPoint[xOrder[i-1]]
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}
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canvas.SetLine(
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braillePoint(previousPoint),
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braillePoint(currentPoint),
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line.color,
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)
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}
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}
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canvas.Draw(buffer)
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if c.mode == ModePinpoint {
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for lineIndex, point := range selectionPoints {
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buffer.SetCell(ui.NewCell(console.SymbolSelection, ui.NewStyle(c.lines[lineIndex].color)), point)
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if c.lines[lineIndex].selectionCoordinate == 0 {
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c.lines[lineIndex].selectionCoordinate = point.X
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}
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}
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}
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}
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func (c *RunChart) trimOutOfRangeValues() {
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minRangeTime := c.grid.timeRange.min.Add(-time.Minute * time.Duration(historyReserveMin))
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for i, item := range c.lines {
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lastOutOfRangeValueIndex := -1
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for j, point := range item.points {
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if point.time.Before(minRangeTime) {
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lastOutOfRangeValueIndex = j
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}
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}
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if lastOutOfRangeValueIndex > 0 {
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item.points = append(item.points[:0], item.points[lastOutOfRangeValueIndex+1:]...)
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c.lines[i] = item
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}
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}
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}
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func (c *RunChart) calculateTimeCoordinate(t time.Time) int {
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timeDeltaWithGridMaxTime := c.grid.timeRange.max.Sub(t).Nanoseconds()
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timeDeltaToPaddingRelation := float64(timeDeltaWithGridMaxTime) / float64(c.timescale.Nanoseconds())
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return c.grid.maxTimeWidth - int(math.Ceil(float64(xAxisGridWidth)*timeDeltaToPaddingRelation))
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}
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// TODO add boundaries for values in range
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func (c *RunChart) getMaxValueLength() int {
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maxValueLength := 0
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for _, line := range c.lines {
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for _, point := range line.points {
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l := len(util.FormatValue(point.value, c.scale))
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if l > maxValueLength {
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maxValueLength = l
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}
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}
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}
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return maxValueLength
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}
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func (c *RunChart) moveSelection(shift int) {
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if c.mode == ModeDefault {
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c.mode = ModePinpoint
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c.selection = getMidRangeTime(c.grid.timeRange)
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return
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} else {
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c.selection = c.selection.Add(c.grid.timePerPoint * time.Duration(shift))
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if c.selection.After(c.grid.timeRange.max) {
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c.selection = c.grid.timeRange.max
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} else if c.selection.Before(c.grid.timeRange.min) {
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c.selection = c.grid.timeRange.min
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}
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}
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for i := range c.lines {
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c.lines[i].selectionCoordinate = 0
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}
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}
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func (c *RunChart) disableSelection() {
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if c.mode == ModePinpoint {
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c.mode = ModeDefault
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return
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}
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}
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func getMidRangeTime(r TimeRange) time.Time {
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delta := r.max.Sub(r.min)
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return r.max.Add(-delta / 2)
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}
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// time duration between grid lines
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func calculateTimescale(rateMs int) time.Duration {
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multiplier := rateMs * xAxisGridWidth / 2
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timescale := time.Duration(time.Millisecond * time.Duration(multiplier)).Round(time.Second)
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if timescale.Seconds() == 0 {
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return time.Second
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} else {
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return timescale
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}
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}
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func braillePoint(point image.Point) image.Point {
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return image.Point{X: point.X * xBrailleMultiplier, Y: point.Y * yBrailleMultiplier}
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}
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