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kdtree.go
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kdtree.go
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package bkdtree
import (
"math/rand"
"sort"
)
type U64Slice []uint64
func (a U64Slice) Len() int { return len(a) }
func (a U64Slice) Swap(i, j int) { a[i], a[j] = a[j], a[i] }
func (a U64Slice) Less(i, j int) bool { return a[i] < a[j] }
type KdTreeNode interface {
intersect(visitor IntersectVisitor, numDims int)
insert(point Point, numDims int)
erase(point Point, numDims int) bool
}
type KdTreeIntraNode struct {
splitDim int
splitValues []uint64
children []KdTreeNode
}
type KdTreeLeafNode struct {
points []Point
}
type IntersectVisitor interface {
GetLowPoint() Point
GetHighPoint() Point
VisitPoint(point Point)
}
type IntersectCollector struct {
LowPoint Point
HighPoint Point
Points []Point
}
func (d *IntersectCollector) GetLowPoint() Point { return d.LowPoint }
func (d *IntersectCollector) GetHighPoint() Point { return d.HighPoint }
func (d *IntersectCollector) VisitPoint(point Point) { d.Points = append(d.Points, point) }
type KdTree struct {
root KdTreeNode
NumDims int
leafCap int // limit of points a leaf node can hold
intraCap int // limit of children of a intra node can hold
}
func NewKdTree(points []Point, numDims, leafCap, intraCap int) (kd *KdTree) {
if len(points) == 0 || numDims <= 0 ||
leafCap <= 0 || leafCap >= int(^uint16(0)) || intraCap <= 2 || intraCap >= int(^uint16(0)) {
return
}
kd = &KdTree{
root: createKdTree(points, 0, numDims, leafCap, intraCap),
NumDims: numDims,
leafCap: leafCap,
intraCap: intraCap,
}
return
}
func createKdTree(points []Point, depth, numDims, leafCap, intraCap int) KdTreeNode {
if len(points) == 0 {
return nil
}
if len(points) <= leafCap {
pointsCopy := make([]Point, len(points))
copy(pointsCopy, points)
ret := &KdTreeLeafNode{
points: pointsCopy,
}
return ret
}
splitDim := depth % numDims
numStrips := (len(points) + leafCap - 1) / leafCap
if numStrips > intraCap {
numStrips = intraCap
}
pam := PointArrayMem{
points: points,
byDim: splitDim,
}
splitValues, splitPoses := SplitPoints(&pam, numStrips)
children := make([]KdTreeNode, 0, numStrips)
for strip := 0; strip < numStrips; strip++ {
posBegin := 0
if strip != 0 {
posBegin = splitPoses[strip-1]
}
posEnd := len(points)
if strip != numStrips-1 {
posEnd = splitPoses[strip]
}
child := createKdTree(points[posBegin:posEnd], depth+1, numDims, leafCap, intraCap)
children = append(children, child)
}
ret := &KdTreeIntraNode{
splitDim: splitDim,
splitValues: splitValues,
children: children,
}
return ret
}
func (n *KdTreeIntraNode) intersect(visitor IntersectVisitor, numDims int) {
lowVal := visitor.GetLowPoint().Vals[n.splitDim]
highVal := visitor.GetHighPoint().Vals[n.splitDim]
numSplits := len(n.splitValues)
//calculate children[begin:end) need to visit
end := sort.Search(numSplits, func(i int) bool { return n.splitValues[i] > highVal })
begin := sort.Search(end, func(i int) bool { return n.splitValues[i] >= lowVal })
end++
for strip := begin; strip < end; strip++ {
n.children[strip].intersect(visitor, numDims)
}
}
func (n *KdTreeLeafNode) intersect(visitor IntersectVisitor, numDims int) {
lowPoint := visitor.GetLowPoint()
highPoint := visitor.GetHighPoint()
for _, point := range n.points {
isInside := point.Inside(lowPoint, highPoint)
if isInside {
visitor.VisitPoint(point)
}
}
}
func (t *KdTree) Intersect(visitor IntersectVisitor) {
t.root.intersect(visitor, t.NumDims)
}
func (n *KdTreeIntraNode) insert(point Point, numDims int) {
lowVal := point.Vals[n.splitDim]
highVal := lowVal
numSplits := len(n.splitValues)
//calculate children[begin:end) need to visit
end := sort.Search(numSplits, func(i int) bool { return n.splitValues[i] > highVal })
begin := sort.Search(end, func(i int) bool { return n.splitValues[i] >= lowVal })
end++
//if multiple strips could cover the point, select one randomly.
strip := begin + rand.Intn(end-begin)
n.children[strip].insert(point, numDims)
}
func (n *KdTreeLeafNode) insert(point Point, numDims int) {
//append blindly, no rebalance
n.points = append(n.points, point)
}
func (t *KdTree) Insert(point Point) {
t.root.insert(point, t.NumDims)
}
func (n *KdTreeIntraNode) erase(point Point, numDims int) (found bool) {
lowVal := point.Vals[n.splitDim]
highVal := lowVal
numSplits := len(n.splitValues)
//calculate children[begin:end) need to visit
end := sort.Search(numSplits, func(i int) bool { return n.splitValues[i] > highVal })
begin := sort.Search(end, func(i int) bool { return n.splitValues[i] >= lowVal })
end++
//if multiple strips could cover the point, iterate them. And stop iteration if found at middle way.
for strip := begin; strip < end; strip++ {
found = n.children[strip].erase(point, numDims)
if found {
break
}
}
return
}
func (n *KdTreeLeafNode) erase(point Point, numDims int) (found bool) {
found = false
idx := len(n.points)
for i, point2 := range n.points {
//assumes each point's userData is unique
if point.Equal(point2) {
idx = i
break
}
}
if idx < len(n.points) {
n.points = append(n.points[:idx], n.points[idx+1:]...)
found = true
}
return
}
func (t *KdTree) Erase(point Point) {
t.root.erase(point, t.NumDims)
}