spatial/kdtree/points.go - third_party/github.com/gonum/gonum - Git at Google

 // Copyright ©2019 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 kdtree

 import "math"

 var (
 	_ Interface  = Points(nil)
 	_ Comparable = Point(nil)
 )

 // Point represents a point in a k-d space that satisfies the Comparable interface.
 type Point []float64

 // Compare returns the signed distance of p from the plane passing through c and
 // perpendicular to the dimension d. The concrete type of c must be Point.
 func (p Point) Compare(c Comparable, d Dim) float64 { q := c.(Point); return p[d] - q[d] }

 // Dims returns the number of dimensions described by the receiver.
 func (p Point) Dims() int { return len(p) }

 // Distance returns the squared Euclidean distance between c and the receiver. The
 // concrete type of c must be Point.
 func (p Point) Distance(c Comparable) float64 {
 	q := c.(Point)
 	var sum float64
 	for dim, c := range p {
 		d := c - q[dim]
 		sum += d * d
 	}
 	return sum
 }

 // Extend returns a bounding box that has been extended to include the receiver.
 func (p Point) Extend(b *Bounding) *Bounding {
 	if b == nil {
 		b = &Bounding{append(Point(nil), p...), append(Point(nil), p...)}
 	}
 	min := b.Min.(Point)
 	max := b.Max.(Point)
 	for d, v := range p {
 		min[d] = math.Min(min[d], v)
 		max[d] = math.Max(max[d], v)
 	}
 	*b = Bounding{Min: min, Max: max}
 	return b
 }

 // Points is a collection of point values that satisfies the Interface.
 type Points []Point

 func (p Points) Bounds() *Bounding {
 	if p.Len() == 0 {
 		return nil
 	}
 	min := append(Point(nil), p[0]...)
 	max := append(Point(nil), p[0]...)
 	for _, e := range p[1:] {
 		for d, v := range e {
 			min[d] = math.Min(min[d], v)
 			max[d] = math.Max(max[d], v)
 		}
 	}
 	return &Bounding{Min: min, Max: max}
 }
 func (p Points) Index(i int) Comparable         { return p[i] }
 func (p Points) Len() int                       { return len(p) }
 func (p Points) Pivot(d Dim) int                { return Plane{Points: p, Dim: d}.Pivot() }
 func (p Points) Slice(start, end int) Interface { return p[start:end] }

 // Plane is a wrapping type that allows a Points type be pivoted on a dimension.
 // The Pivot method of Plane uses MedianOfRandoms sampling at most 100 elements
 // to find a pivot element.
 type Plane struct {
 	Dim
 	Points
 }

 // randoms is the maximum number of random values to sample for calculation of
 // median of random elements.
 const randoms = 100

 func (p Plane) Less(i, j int) bool              { return p.Points[i][p.Dim] < p.Points[j][p.Dim] }
 func (p Plane) Pivot() int                      { return Partition(p, MedianOfRandoms(p, randoms)) }
 func (p Plane) Slice(start, end int) SortSlicer { p.Points = p.Points[start:end]; return p }
 func (p Plane) Swap(i, j int)                   { p.Points[i], p.Points[j] = p.Points[j], p.Points[i] }
	// Copyright ©2019 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 kdtree

	import "math"

	var (
	_ Interface = Points(nil)
	_ Comparable = Point(nil)
	)

	// Point represents a point in a k-d space that satisfies the Comparable interface.
	type Point []float64

	// Compare returns the signed distance of p from the plane passing through c and
	// perpendicular to the dimension d. The concrete type of c must be Point.
	func (p Point) Compare(c Comparable, d Dim) float64 { q := c.(Point); return p[d] - q[d] }

	// Dims returns the number of dimensions described by the receiver.
	func (p Point) Dims() int { return len(p) }

	// Distance returns the squared Euclidean distance between c and the receiver. The
	// concrete type of c must be Point.
	func (p Point) Distance(c Comparable) float64 {
	q := c.(Point)
	var sum float64
	for dim, c := range p {
	d := c - q[dim]
	sum += d * d
	}
	return sum
	}

	// Extend returns a bounding box that has been extended to include the receiver.
	func (p Point) Extend(b Bounding) Bounding {
	if b == nil {
	b = &Bounding{append(Point(nil), p...), append(Point(nil), p...)}
	}
	min := b.Min.(Point)
	max := b.Max.(Point)
	for d, v := range p {
	min[d] = math.Min(min[d], v)
	max[d] = math.Max(max[d], v)
	}
	*b = Bounding{Min: min, Max: max}
	return b
	}

	// Points is a collection of point values that satisfies the Interface.
	type Points []Point

	func (p Points) Bounds() *Bounding {
	if p.Len() == 0 {
	return nil
	}
	min := append(Point(nil), p[0]...)
	max := append(Point(nil), p[0]...)
	for _, e := range p[1:] {
	for d, v := range e {
	min[d] = math.Min(min[d], v)
	max[d] = math.Max(max[d], v)
	}
	}
	return &Bounding{Min: min, Max: max}
	}
	func (p Points) Index(i int) Comparable { return p[i] }
	func (p Points) Len() int { return len(p) }
	func (p Points) Pivot(d Dim) int { return Plane{Points: p, Dim: d}.Pivot() }
	func (p Points) Slice(start, end int) Interface { return p[start:end] }

	// Plane is a wrapping type that allows a Points type be pivoted on a dimension.
	// The Pivot method of Plane uses MedianOfRandoms sampling at most 100 elements
	// to find a pivot element.
	type Plane struct {
	Dim
	Points
	}

	// randoms is the maximum number of random values to sample for calculation of
	// median of random elements.
	const randoms = 100

	func (p Plane) Less(i, j int) bool { return p.Points[i][p.Dim] < p.Points[j][p.Dim] }
	func (p Plane) Pivot() int { return Partition(p, MedianOfRandoms(p, randoms)) }
	func (p Plane) Slice(start, end int) SortSlicer { p.Points = p.Points[start:end]; return p }
	func (p Plane) Swap(i, j int) { p.Points[i], p.Points[j] = p.Points[j], p.Points[i] }