go-chart/linear_regression_series.go

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package chart
// LinearRegressionSeries is a series that plots the n-nearest neighbors
// linear regression for the values.
type LinearRegressionSeries struct {
Name string
Style Style
YAxis YAxisType
Window int
Offset int
InnerSeries ValueProvider
m float64
b float64
avgx float64
stddevx float64
}
// GetName returns the name of the time series.
func (lrs LinearRegressionSeries) GetName() string {
return lrs.Name
}
// GetStyle returns the line style.
func (lrs LinearRegressionSeries) GetStyle() Style {
return lrs.Style
}
// GetYAxis returns which YAxis the series draws on.
func (lrs LinearRegressionSeries) GetYAxis() YAxisType {
return lrs.YAxis
}
// Len returns the number of elements in the series.
func (lrs LinearRegressionSeries) Len() int {
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return MinInt(lrs.GetWindow(), lrs.InnerSeries.Len()-lrs.GetOffset())
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}
// GetWindow returns the window size.
func (lrs LinearRegressionSeries) GetWindow() int {
if lrs.Window == 0 {
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return lrs.InnerSeries.Len()
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}
return lrs.Window
}
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// GetEndIndex returns the effective window end.
func (lrs LinearRegressionSeries) GetEndIndex() int {
return MinInt(lrs.GetOffset()+(lrs.Len()), (lrs.InnerSeries.Len() - 1))
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}
// GetOffset returns the data offset.
func (lrs LinearRegressionSeries) GetOffset() int {
if lrs.Offset == 0 {
return 0
}
return lrs.Offset
}
// GetValue gets a value at a given index.
func (lrs *LinearRegressionSeries) GetValue(index int) (x, y float64) {
if lrs.InnerSeries == nil {
return
}
if lrs.m == 0 && lrs.b == 0 {
lrs.computeCoefficients()
}
offset := lrs.GetOffset()
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effectiveIndex := MinInt(index+offset, lrs.InnerSeries.Len())
x, y = lrs.InnerSeries.GetValue(effectiveIndex)
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y = (lrs.m * lrs.normalize(x)) + lrs.b
return
}
// GetLastValue computes the last moving average value but walking back window size samples,
// and recomputing the last moving average chunk.
func (lrs *LinearRegressionSeries) GetLastValue() (x, y float64) {
if lrs.InnerSeries == nil {
return
}
if lrs.m == 0 && lrs.b == 0 {
lrs.computeCoefficients()
}
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endIndex := lrs.GetEndIndex()
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x, y = lrs.InnerSeries.GetValue(endIndex)
y = (lrs.m * lrs.normalize(x)) + lrs.b
return
}
func (lrs *LinearRegressionSeries) normalize(xvalue float64) float64 {
return (xvalue - lrs.avgx) / lrs.stddevx
}
// computeCoefficients computes the `m` and `b` terms in the linear formula given by `y = mx+b`.
func (lrs *LinearRegressionSeries) computeCoefficients() {
startIndex := lrs.GetOffset()
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endIndex := lrs.GetEndIndex()
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p := float64(endIndex - startIndex)
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xvalues := NewRingBufferWithCapacity(lrs.Len())
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for index := startIndex; index < endIndex; index++ {
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x, _ := lrs.InnerSeries.GetValue(index)
xvalues.Enqueue(x)
}
lrs.avgx = xvalues.Average()
lrs.stddevx = xvalues.StdDev()
var sumx, sumy, sumxx, sumxy float64
for index := startIndex; index < endIndex; index++ {
x, y := lrs.InnerSeries.GetValue(index)
x = lrs.normalize(x)
sumx += x
sumy += y
sumxx += x * x
sumxy += x * y
}
lrs.m = (p*sumxy - sumx*sumy) / (p*sumxx - sumx*sumx)
lrs.b = (sumy / p) - (lrs.m * sumx / p)
}
// Render renders the series.
func (lrs *LinearRegressionSeries) Render(r Renderer, canvasBox Box, xrange, yrange Range, defaults Style) {
style := lrs.Style.InheritFrom(defaults)
DrawLineSeries(r, canvasBox, xrange, yrange, style, lrs)
}