tile38/vendor/github.com/tidwall/geojson/geometry/quadtree.go

256 lines
5.5 KiB
Go

package geometry
import "encoding/binary"
const qMaxItems = 16
const qMaxDepth = 16
type qNode struct {
split bool
items []uint32
quads [4]*qNode
}
func (n *qNode) insert(series *baseSeries, bounds, rect Rect, item, depth int) {
if depth == qMaxDepth {
// limit depth and insert now
n.items = append(n.items, uint32(item))
} else if n.split {
// qnode is split so try to insert into a quad
q := n.chooseQuad(bounds, rect)
if q == -1 {
// insert into overflow
n.items = append(n.items, uint32(item))
} else {
// insert into quad
qbounds := quadBounds(bounds, q)
if n.quads[q] == nil {
n.quads[q] = new(qNode)
}
n.quads[q].insert(series, qbounds, rect, item, depth+1)
}
} else if len(n.items) == qMaxItems {
// split qnode, keep current items in place
var nitems []uint32
for i := 0; i < len(n.items); i++ {
iitem := n.items[i]
irect := series.SegmentAt(int(iitem)).Rect()
q := n.chooseQuad(bounds, irect)
if q == -1 {
nitems = append(nitems, iitem)
} else {
qbounds := quadBounds(bounds, q)
if n.quads[q] == nil {
n.quads[q] = new(qNode)
}
n.quads[q].insert(series, qbounds, irect, int(iitem), depth+1)
}
}
n.items = nitems
n.split = true
n.insert(series, bounds, rect, item, depth)
} else {
n.items = append(n.items, uint32(item))
}
}
func (n *qNode) chooseQuad(bounds, rect Rect) int {
mid := Point{
X: (bounds.Min.X + bounds.Max.X) / 2,
Y: (bounds.Min.Y + bounds.Max.Y) / 2,
}
if rect.Max.X < mid.X {
if rect.Max.Y < mid.Y {
return 2
}
if rect.Min.Y < mid.Y {
return -1
}
return 0
}
if rect.Min.X < mid.X {
return -1
}
if rect.Max.Y < mid.Y {
return 3
}
if rect.Min.Y < mid.Y {
return -1
}
return 1
}
func quadBounds(bounds Rect, q int) (qbounds Rect) {
switch q {
case 0:
qbounds.Min.X = bounds.Min.X
qbounds.Min.Y = (bounds.Min.Y + bounds.Max.Y) / 2
qbounds.Max.X = (bounds.Min.X + bounds.Max.X) / 2
qbounds.Max.Y = bounds.Max.Y
case 1:
qbounds.Min.X = (bounds.Min.X + bounds.Max.X) / 2
qbounds.Min.Y = (bounds.Min.Y + bounds.Max.Y) / 2
qbounds.Max.X = bounds.Max.X
qbounds.Max.Y = bounds.Max.Y
case 2:
qbounds.Min.X = bounds.Min.X
qbounds.Min.Y = bounds.Min.Y
qbounds.Max.X = (bounds.Min.X + bounds.Max.X) / 2
qbounds.Max.Y = (bounds.Min.Y + bounds.Max.Y) / 2
case 3:
qbounds.Min.X = (bounds.Min.X + bounds.Max.X) / 2
qbounds.Min.Y = bounds.Min.Y
qbounds.Max.X = bounds.Max.X
qbounds.Max.Y = (bounds.Min.Y + bounds.Max.Y) / 2
}
return
}
func (n *qNode) search(
series *baseSeries,
bounds, rect Rect,
iter func(seg Segment, item int) bool,
) bool {
for _, item := range n.items {
seg := series.SegmentAt(int(item))
irect := seg.Rect()
if irect.IntersectsRect(rect) {
if !iter(seg, int(item)) {
return false
}
}
}
if n.split {
for q := 0; q < 4; q++ {
if n.quads[q] != nil {
qbounds := quadBounds(bounds, q)
if qbounds.IntersectsRect(rect) {
if !n.quads[q].search(series, qbounds, rect, iter) {
return false
}
}
}
}
}
return true
}
func numBytes(n uint32) byte {
if n <= 0xFF {
return 1
}
if n <= 0xFFFF {
return 2
}
return 4
}
func appendNum(dst []byte, num uint32, ibytes byte) []byte {
switch ibytes {
case 1:
dst = append(dst, byte(num))
case 2:
dst = append(dst, 0, 0)
binary.LittleEndian.PutUint16(dst[len(dst)-2:], uint16(num))
default:
dst = append(dst, 0, 0, 0, 0)
binary.LittleEndian.PutUint32(dst[len(dst)-4:], uint32(num))
}
return dst
}
func readNum(data []byte, ibytes byte) uint32 {
switch ibytes {
case 1:
return uint32(data[0])
case 2:
return uint32(binary.LittleEndian.Uint16(data))
default:
return binary.LittleEndian.Uint32(data)
}
}
func (n *qNode) compress(dst []byte, bounds Rect) []byte {
ibytes := numBytes(uint32(len(n.items)))
for i := 0; i < len(n.items); i++ {
ibytes2 := numBytes(n.items[i])
if ibytes2 > ibytes {
ibytes = ibytes2
}
}
dst = append(dst, ibytes)
dst = appendNum(dst, uint32(len(n.items)), ibytes)
for i := 0; i < len(n.items); i++ {
dst = appendNum(dst, n.items[i], ibytes)
}
if !n.split {
dst = append(dst, 0)
return dst
}
// store the quads
dst = append(dst, 1)
// first make the address space
var mark [4]int
for q := 0; q < 4; q++ {
if n.quads[q] == nil {
// no quad, no address
dst = append(dst, 0)
} else {
// yes quad, plus addres
dst = append(dst, 1)
mark[q] = len(dst)
dst = append(dst, 0, 0, 0, 0)
}
}
// next add each quad
for q := 0; q < 4; q++ {
if n.quads[q] != nil {
binary.LittleEndian.PutUint32(dst[mark[q]:], uint32(len(dst)))
dst = n.quads[q].compress(dst, quadBounds(bounds, q))
}
}
return dst
}
func qCompressSearch(
data []byte,
addr int,
series *baseSeries,
bounds, rect Rect,
iter func(seg Segment, item int) bool,
) bool {
ibytes := data[addr]
addr++
nItems := int(readNum(data[addr:], ibytes))
addr += int(ibytes)
for i := 0; i < nItems; i++ {
item := int(readNum(data[addr:], ibytes))
addr += int(ibytes)
seg := series.SegmentAt(int(item))
irect := seg.Rect()
if irect.IntersectsRect(rect) {
if !iter(seg, int(item)) {
return false
}
}
}
split := data[addr] == 1
addr++
if split {
for q := 0; q < 4; q++ {
use := data[addr] == 1
addr++
if !use {
continue
}
naddr := int(binary.LittleEndian.Uint32(data[addr:]))
addr += 4
qbounds := quadBounds(bounds, q)
if qbounds.IntersectsRect(rect) {
if !qCompressSearch(data, naddr, series, qbounds, rect, iter) {
return false
}
}
}
}
return true
}