package geojson import ( "bytes" "strconv" "github.com/tidwall/tile38/geojson/geohash" ) // Polygon is a geojson object with the type "Polygon" type Polygon struct { Coordinates [][]Position BBox *BBox } func fillPolygon(coordinates [][]Position, bbox *BBox, b []byte, err error) (Polygon, []byte, error) { if err == nil { if len(coordinates) == 0 { err = errMustBeALinearRing } } if err == nil { for _, ps := range coordinates { if !isLinearRing(ps) { err = errMustBeALinearRing break } } } return Polygon{ Coordinates: coordinates, BBox: bbox, }, b, err } // CalculatedBBox is exterior bbox containing the object. func (g Polygon) CalculatedBBox() BBox { return level3CalculatedBBox(g.Coordinates, g.BBox, true) } // CalculatedPoint is a point representation of the object. func (g Polygon) CalculatedPoint() Position { return g.CalculatedBBox().center() } // Geohash converts the object to a geohash value. func (g Polygon) Geohash(precision int) (string, error) { p := g.CalculatedPoint() return geohash.Encode(p.Y, p.X, precision) } // PositionCount return the number of coordinates. func (g Polygon) PositionCount() int { return level3PositionCount(g.Coordinates, g.BBox) } // Weight returns the in-memory size of the object. func (g Polygon) Weight() int { return level3Weight(g.Coordinates, g.BBox) } // MarshalJSON allows the object to be encoded in json.Marshal calls. func (g Polygon) MarshalJSON() ([]byte, error) { return []byte(g.JSON()), nil } // JSON is the json representation of the object. This might not be exactly the same as the original. func (g Polygon) JSON() string { return level3JSON("Polygon", g.Coordinates, g.BBox) } // String returns a string representation of the object. This might be JSON or something else. func (g Polygon) String() string { return g.JSON() } // Bytes is the bytes representation of the object. func (g Polygon) Bytes() []byte { return level3Bytes(polygon, g.Coordinates, g.BBox) } func (g Polygon) bboxPtr() *BBox { return g.BBox } func (g Polygon) hasPositions() bool { if g.BBox != nil { return true } for _, c := range g.Coordinates { if len(c) > 0 { return true } } return false } // WithinBBox detects if the object is fully contained inside a bbox. func (g Polygon) WithinBBox(bbox BBox) bool { if g.BBox != nil { return rectBBox(g.CalculatedBBox()).InsideRect(rectBBox(bbox)) } if len(g.Coordinates) == 0 { return false } return polyPositions(g.Coordinates[0]).InsideRect(rectBBox(bbox)) } // IntersectsBBox detects if the object intersects a bbox. func (g Polygon) IntersectsBBox(bbox BBox) bool { if g.BBox != nil { return rectBBox(g.CalculatedBBox()).IntersectsRect(rectBBox(bbox)) } if len(g.Coordinates) == 0 { return false } return polyPositions(g.Coordinates[0]).IntersectsRect(rectBBox(bbox)) } // Within detects if the object is fully contained inside another object. func (g Polygon) Within(o Object) bool { return withinObjectShared(g, o, func(v Polygon) bool { if len(g.Coordinates) == 0 { return false } return polyPositions(g.Coordinates[0]).Inside(polyExteriorHoles(v.Coordinates)) }, func(v MultiPolygon) bool { if len(g.Coordinates) == 0 { return false } for _, c := range v.Coordinates { if !polyPositions(g.Coordinates[0]).Inside(polyExteriorHoles(c)) { return false } } return true }, ) } // Intersects detects if the object intersects another object. func (g Polygon) Intersects(o Object) bool { return intersectsObjectShared(g, o, func(v Polygon) bool { if len(g.Coordinates) == 0 { return false } return polyPositions(g.Coordinates[0]).Intersects(polyExteriorHoles(v.Coordinates)) }, func(v MultiPolygon) bool { if len(g.Coordinates) == 0 { return false } for _, c := range v.Coordinates { if polyPositions(g.Coordinates[0]).Intersects(polyExteriorHoles(c)) { return true } } return false }, ) } // Nearby detects if the object is nearby a position. func (g Polygon) Nearby(center Position, meters float64) bool { return nearbyObjectShared(g, center.X, center.Y, meters) } // KML outputs kml func (g Polygon) KML() string { var buf bytes.Buffer buf.WriteString(``) buf.WriteString(``) buf.WriteString(``) buf.WriteString(``) buf.WriteString(`1`) buf.WriteString(`relativeToGround`) for i, c := range g.Coordinates { if i == 0 { buf.WriteString(``) } else { buf.WriteString(``) } buf.WriteString(``) buf.WriteString(``) for _, c := range c { buf.WriteString("\n" + strconv.FormatFloat(c.X, 'f', -1, 64) + `,` + strconv.FormatFloat(c.Y, 'f', -1, 64) + `,` + strconv.FormatFloat(c.Z, 'f', -1, 64)) } if len(c) > 0 { buf.WriteString("\n") } buf.WriteString(``) buf.WriteString(``) if i == 0 { buf.WriteString(``) } else { buf.WriteString(``) } } buf.WriteString(``) buf.WriteString(``) buf.WriteString(``) return buf.String() } // IsBBoxDefined returns true if the object has a defined bbox. func (g Polygon) IsBBoxDefined() bool { return g.BBox != nil } // IsGeometry return true if the object is a geojson geometry object. false if it something else. func (g Polygon) IsGeometry() bool { return true }