mirror of https://github.com/tidwall/tile38.git
260 lines
6.2 KiB
Go
260 lines
6.2 KiB
Go
package geojson
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import (
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"math"
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"strconv"
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"github.com/tidwall/geojson/geo"
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"github.com/tidwall/geojson/geometry"
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)
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// Circle ...
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type Circle struct {
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object Object
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center geometry.Point
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meters float64
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haversine float64
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steps int
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km bool
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extra *extra
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}
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// NewCircle returns an circle object
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func NewCircle(center geometry.Point, meters float64, steps int) *Circle {
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if steps < 3 {
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steps = 3
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}
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g := new(Circle)
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g.center = center
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g.meters = meters
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g.steps = steps
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if meters > 0 {
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meters = geo.NormalizeDistance(meters)
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g.haversine = geo.DistanceToHaversine(meters)
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}
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return g
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}
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// AppendJSON ...
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func (g *Circle) AppendJSON(dst []byte) []byte {
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dst = append(dst, `{"type":"Feature","geometry":`...)
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dst = append(dst, `{"type":"Point","coordinates":[`...)
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dst = strconv.AppendFloat(dst, g.center.X, 'f', -1, 64)
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dst = append(dst, ',')
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dst = strconv.AppendFloat(dst, g.center.Y, 'f', -1, 64)
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dst = append(dst, `]},"properties":{"type":"Circle","radius":`...)
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dst = strconv.AppendFloat(dst, g.meters, 'f', -1, 64)
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dst = append(dst, `,"radius_units":"m"}}`...)
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return dst
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}
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// JSON ...
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func (g *Circle) JSON() string {
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return string(g.AppendJSON(nil))
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}
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// MarshalJSON ...
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func (g *Circle) MarshalJSON() ([]byte, error) {
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return g.AppendJSON(nil), nil
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}
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// String ...
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func (g *Circle) String() string {
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return string(g.AppendJSON(nil))
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}
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// Meters returns the circle's radius
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func (g *Circle) Meters() float64 {
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return g.meters
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}
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// Center returns the circle's center point
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func (g *Circle) Center() geometry.Point {
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return g.center
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}
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// Haversine returns the haversine corresponding to circle's radius
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func (g *Circle) Haversine() float64 {
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return g.haversine
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}
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// HaversineTo returns the haversine from a given point to circle's center
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func (g *Circle) HaversineTo(p geometry.Point) float64 {
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return geo.Haversine(p.Y, p.X, g.center.Y, g.center.X)
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}
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// Within returns true if circle is contained inside object
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func (g *Circle) Within(obj Object) bool {
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return obj.Contains(g)
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}
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// containsPoint returns true if circle contains a given point
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func (g *Circle) containsPoint(p geometry.Point) bool {
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h := geo.Haversine(p.Y, p.X, g.center.Y, g.center.X)
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return h <= g.haversine
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}
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// Contains returns true if the circle contains other object
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func (g *Circle) Contains(obj Object) bool {
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switch other := obj.(type) {
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case *Point:
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return g.containsPoint(other.Center())
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case *Circle:
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return other.Distance(g) < (other.meters + g.meters)
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case *LineString:
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for i := 0; i < other.base.NumPoints(); i++ {
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if !g.containsPoint(other.base.PointAt(i)) {
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return false
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}
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}
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return true
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case Collection:
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for _, p := range other.Children() {
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if !g.Contains(p) {
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return false
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}
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}
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return true
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default:
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// No simple cases, so using polygon approximation.
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return g.getObject().Contains(other)
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}
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}
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// intersectsSegment returns true if the circle intersects a given segment
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func (g *Circle) intersectsSegment(seg geometry.Segment) bool {
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start, end := seg.A, seg.B
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// These are faster checks.
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// If they succeed there's no need do complicate things.
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if g.containsPoint(start) || g.containsPoint(end) {
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return true
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}
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// Distance between start and end
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l := geo.DistanceTo(start.Y, start.X, end.Y, end.X)
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// Unit direction vector
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dx := (end.X - start.X) / l
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dy := (end.Y - start.Y) / l
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// Point of the line closest to the center
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t := dx*(g.center.X-start.X) + dy*(g.center.Y-start.Y)
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px := t*dx + start.X
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py := t*dy + start.Y
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if px < start.X || px > end.X || py < start.Y || py > end.Y {
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// closest point is outside the segment
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return false
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}
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// Distance from the closest point to the center
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return g.containsPoint(geometry.Point{X: px, Y: py})
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}
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// Intersects returns true the circle intersects other object
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func (g *Circle) Intersects(obj Object) bool {
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switch other := obj.(type) {
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case *Point:
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return g.containsPoint(other.Center())
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case *Circle:
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return other.Distance(g) <= (other.meters + g.meters)
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case *LineString:
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for i := 0; i < other.base.NumSegments(); i++ {
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if g.intersectsSegment(other.base.SegmentAt(i)) {
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return true
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}
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}
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return false
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case Collection:
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for _, p := range other.Children() {
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if g.Intersects(p) {
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return true
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}
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}
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return false
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default:
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// No simple cases, so using polygon approximation.
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return g.getObject().Intersects(obj)
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}
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}
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// Empty ...
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func (g *Circle) Empty() bool {
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return false
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}
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// Valid ...
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func (g *Circle) Valid() bool {
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return g.getObject().Valid()
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}
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// ForEach ...
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func (g *Circle) ForEach(iter func(geom Object) bool) bool {
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return iter(g)
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}
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// NumPoints ...
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func (g *Circle) NumPoints() int {
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// should this be g.steps?
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return 1
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}
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// Distance ...
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func (g *Circle) Distance(other Object) float64 {
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return g.getObject().Distance(other)
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}
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// Rect ...
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func (g *Circle) Rect() geometry.Rect {
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return g.getObject().Rect()
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}
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// Spatial ...
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func (g *Circle) Spatial() Spatial {
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return g.getObject().Spatial()
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}
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func (g *Circle) getObject() Object {
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if g.object != nil {
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return g.object
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}
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return makeCircleObject(g.center, g.meters, g.steps)
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}
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func makeCircleObject(center geometry.Point, meters float64, steps int) Object {
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if meters <= 0 {
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return NewPoint(center)
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}
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meters = geo.NormalizeDistance(meters)
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points := make([]geometry.Point, 0, steps+1)
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// calc the four corners
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maxY, _ := geo.DestinationPoint(center.Y, center.X, meters, 0)
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_, maxX := geo.DestinationPoint(center.Y, center.X, meters, 90)
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minY, _ := geo.DestinationPoint(center.Y, center.X, meters, 180)
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_, minX := geo.DestinationPoint(center.Y, center.X, meters, 270)
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// TODO: detect of pole and antimeridian crossing and generate a
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// valid multigeometry
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// use the half width of the lat and lon
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lons := (maxX - minX) / 2
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lats := (maxY - minY) / 2
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// generate the
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for th := 0.0; th <= 360.0; th += 360.0 / float64(steps) {
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radians := (math.Pi / 180) * th
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x := center.X + lats*math.Cos(radians)
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y := center.Y + lons*math.Sin(radians)
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points = append(points, geometry.Point{X: x, Y: y})
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}
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// add last connecting point, make a total of steps+1
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points = append(points, points[0])
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return NewPolygon(
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geometry.NewPoly(points, nil, &geometry.IndexOptions{
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Kind: geometry.None,
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}),
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)
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}
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