mirror of https://github.com/tidwall/tile38.git
264 lines
6.0 KiB
Go
264 lines
6.0 KiB
Go
package geojson
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import (
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"bytes"
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"strconv"
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"math"
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"github.com/tidwall/tile38/geojson/poly"
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)
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// BBox is a bounding box
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type BBox struct {
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Min Position
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Max Position
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}
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// New2DBBox creates a new bounding box
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func New2DBBox(minX, minY, maxX, maxY float64) BBox {
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return BBox{Min: Position{X: minX, Y: minY, Z: 0}, Max: Position{X: maxX, Y: maxY, Z: 0}}
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}
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func fillBBox(m map[string]interface{}) (*BBox, error) {
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var bbox *BBox
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var ok bool
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switch v := m["bbox"].(type) {
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default:
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return nil, errBBoxInvalidType
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case nil:
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case []interface{}:
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if !(len(v) == 4 || len(v) == 6) {
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return nil, errBBoxInvalidNumberOfValues
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}
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bbox = &BBox{}
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if bbox.Min.X, ok = v[0].(float64); !ok {
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return nil, errBBoxInvalidValue
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}
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if bbox.Min.Y, ok = v[1].(float64); !ok {
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return nil, errBBoxInvalidValue
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}
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i := 2
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if len(v) == 6 {
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if bbox.Min.Z, ok = v[2].(float64); !ok {
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return nil, errBBoxInvalidValue
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}
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i = 3
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} else {
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bbox.Min.Z = nilz
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}
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if bbox.Max.X, ok = v[i+0].(float64); !ok {
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return nil, errBBoxInvalidValue
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}
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if bbox.Max.Y, ok = v[i+1].(float64); !ok {
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return nil, errBBoxInvalidValue
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}
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if len(v) == 6 {
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if bbox.Max.Z, ok = v[i+2].(float64); !ok {
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return nil, errBBoxInvalidValue
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}
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} else {
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bbox.Max.Z = nilz
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}
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}
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return bbox, nil
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}
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func (b *BBox) isCordZDefined() bool {
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return b != nil && (b.Min.Z != nilz || b.Max.Z != nilz)
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}
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func (b *BBox) write(buf *bytes.Buffer) {
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if b == nil {
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return
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}
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hasZ := b.Min.Z != nilz && b.Max.Z != nilz
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buf.WriteString(`,"bbox":[`)
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buf.WriteString(strconv.FormatFloat(b.Min.X, 'f', -1, 64))
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buf.WriteByte(',')
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buf.WriteString(strconv.FormatFloat(b.Min.Y, 'f', -1, 64))
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if hasZ {
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buf.WriteByte(',')
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buf.WriteString(strconv.FormatFloat(b.Min.Z, 'f', -1, 64))
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}
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buf.WriteByte(',')
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buf.WriteString(strconv.FormatFloat(b.Max.X, 'f', -1, 64))
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buf.WriteByte(',')
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buf.WriteString(strconv.FormatFloat(b.Max.Y, 'f', -1, 64))
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if hasZ {
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buf.WriteByte(',')
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buf.WriteString(strconv.FormatFloat(b.Max.Z, 'f', -1, 64))
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}
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buf.WriteByte(']')
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}
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func (b BBox) center() Position {
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return Position{
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(b.Max.X-b.Min.X)/2 + b.Min.X,
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(b.Max.Y-b.Min.Y)/2 + b.Min.Y,
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0,
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}
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}
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func (b BBox) union(bbox BBox) BBox {
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if bbox.Min.X < b.Min.X {
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b.Min.X = bbox.Min.X
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}
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if bbox.Min.Y < b.Min.Y {
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b.Min.Y = bbox.Min.Y
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}
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if bbox.Max.X > b.Max.X {
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b.Max.X = bbox.Max.X
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}
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if bbox.Max.Y > b.Max.Y {
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b.Max.Y = bbox.Max.Y
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}
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return b
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}
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func (b BBox) exterior() []Position {
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return []Position{
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{b.Min.X, b.Min.Y, 0},
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{b.Min.X, b.Max.Y, 0},
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{b.Max.X, b.Max.Y, 0},
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{b.Max.X, b.Min.Y, 0},
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{b.Min.X, b.Min.Y, 0},
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}
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}
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func rectBBox(bbox BBox) poly.Rect {
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return poly.Rect{
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Min: poly.Point{X: bbox.Min.X, Y: bbox.Min.Y, Z: 0},
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Max: poly.Point{X: bbox.Max.X, Y: bbox.Max.Y, Z: 0},
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}
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}
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// ExternalJSON is the simple json representation of the bounding box used for external applications.
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func (b BBox) ExternalJSON() string {
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sw, ne := b.Min, b.Max
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sw.Z, ne.Z = 0, 0
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return `{"sw":` + sw.ExternalJSON() + `,"ne":` + ne.ExternalJSON() + `}`
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}
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// Sparse returns back an evenly distributed number of sub bboxs.
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func (b BBox) Sparse(amount byte) []BBox {
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if amount == 0 {
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return []BBox{b}
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}
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var bboxes []BBox
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split := 1 << amount
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var xsize, ysize float64
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if b.Max.X < b.Min.X {
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// crosses the prime meridian
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xsize = (b.Min.X - b.Max.X) / float64(split)
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} else {
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xsize = (b.Max.X - b.Min.X) / float64(split)
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}
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if b.Max.Y < b.Min.Y {
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// crosses the equator
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ysize = (b.Min.Y - b.Max.Y) / float64(split)
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} else {
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ysize = (b.Max.Y - b.Min.Y) / float64(split)
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}
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for y := b.Min.Y; y < b.Max.Y; y += ysize {
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for x := b.Min.X; x < b.Max.X; x += xsize {
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bboxes = append(bboxes, BBox{
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Min: Position{X: x, Y: y, Z: b.Min.Z},
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Max: Position{X: x + xsize, Y: y + ysize, Z: b.Max.Z},
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})
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}
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}
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return bboxes
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}
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// BBoxesFromCenter calculates the bounding box surrounding a circle.
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func BBoxesFromCenter(lat, lon, meters float64) (outer BBox) {
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outer.Min.Y, outer.Min.X, outer.Max.Y, outer.Max.X = BBoxBounds(lat, lon, meters)
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if outer.Min.X == outer.Max.X {
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switch outer.Min.X {
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case -180:
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outer.Max.X = 180
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case 180:
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outer.Min.X = -180
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}
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}
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return outer
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}
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func BBoxBounds(lat, lon, meters float64) (latMin, lonMin, latMax, lonMax float64) {
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// see http://janmatuschek.de/LatitudeLongitudeBoundingCoordinates#Latitude
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lat = toRadians(lat)
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lon = toRadians(lon)
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r := meters / earthRadius // angular radius
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latMin = lat - r
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latMax = lat + r
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latT := math.Asin(math.Sin(lat) / math.Cos(r))
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lonΔ := math.Acos(( math.Cos(r) - math.Sin(latT) * math.Sin(lat)) / (math.Cos(latT) * math.Cos(lat) ))
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lonMin = lon - lonΔ
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lonMax = lon + lonΔ
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// Adjust for north poll
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if latMax > math.Pi/2 {
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lonMin = -math.Pi
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latMax = math.Pi/2
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lonMax = math.Pi
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}
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// Adjust for south poll
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if latMin < -math.Pi/2 {
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latMin = -math.Pi/2
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lonMin = -math.Pi
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lonMax = math.Pi
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}
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// Adjust for wraparound. Remove this if the commented-out condition below this block is added.
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if lonMin < -math.Pi || lonMax > math.Pi {
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lonMin = -math.Pi
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lonMax = math.Pi
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}
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/*
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// Consider splitting area into two bboxes, using the below checks, and erasing above block for performance. See http://janmatuschek.de/LatitudeLongitudeBoundingCoordinates#PolesAnd180thMeridian
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// Adjust for wraparound if minimum longitude is less than -180 degrees.
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if lonMin < -math.Pi {
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// box 1:
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latMin = latMin
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latMax = latMax
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lonMin += 2*math.Pi
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lonMax = math.Pi
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// box 2:
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latMin = latMin
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latMax = latMax
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lonMin = -math.Pi
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lonMax = lonMax
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}
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// Adjust for wraparound if maximum longitude is greater than 180 degrees.
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if lonMax > math.Pi {
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// box 1:
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latMin = latMin
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latMax = latMax
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lonMin = lonMin
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lonMax = -math.Pi
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// box 2:
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latMin = latMin
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latMax = latMax
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lonMin = -math.Pi
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lonMax -= 2*math.Pi
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}
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*/
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lonMin = math.Mod(lonMin+3*math.Pi, 2*math.Pi) - math.Pi // normalise to -180..+180°
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lonMax = math.Mod(lonMax+3*math.Pi, 2*math.Pi) - math.Pi
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return toDegrees(latMin), toDegrees(lonMin), toDegrees(latMax), toDegrees(lonMax)
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}
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