package geojson import ( "bytes" "encoding/binary" "github.com/tidwall/gjson" "github.com/tidwall/tile38/geojson/geohash" ) // Feature is a geojson object with the type "Feature" type Feature struct { Geometry Object BBox *BBox idprops string // raw id and properties seperated by a '\0' } func fillFeatureMap(json string) (Feature, error) { var g Feature v := gjson.Get(json, "geometry") switch v.Type { default: return g, errInvalidGeometryMember case gjson.Null: return g, errGeometryMemberRequired case gjson.JSON: var err error g.Geometry, err = objectMap(v.Raw, feat) if err != nil { return g, err } } var err error g.BBox, err = fillBBox(json) if err != nil { return g, err } var propsExists bool props := gjson.Get(json, "properties") switch props.Type { default: return g, errInvalidPropertiesMember case gjson.Null: case gjson.JSON: propsExists = true } id := gjson.Get(json, "id") if id.Exists() || propsExists { g.idprops = makeCompositeRaw(id.Raw, props.Raw) } return g, err } // Geohash converts the object to a geohash value. func (g Feature) Geohash(precision int) (string, error) { p := g.CalculatedPoint() return geohash.Encode(p.Y, p.X, precision) } // CalculatedPoint is a point representation of the object. func (g Feature) CalculatedPoint() Position { return g.CalculatedBBox().center() } // CalculatedBBox is exterior bbox containing the object. func (g Feature) CalculatedBBox() BBox { if g.BBox != nil { return *g.BBox } return g.Geometry.CalculatedBBox() } // PositionCount return the number of coordinates. func (g Feature) PositionCount() int { res := g.Geometry.PositionCount() if g.BBox != nil { return 2 + res } return res } // Weight returns the in-memory size of the object. func (g Feature) Weight() int { res := g.PositionCount() * sizeofPosition res += len(g.idprops) return res } // MarshalJSON allows the object to be encoded in json.Marshal calls. func (g Feature) MarshalJSON() ([]byte, error) { return []byte(g.JSON()), nil } func (g Feature) getRaw() (id, props string) { if len(g.idprops) == 0 { return "", "" } switch g.idprops[0] { default: lnp := int(g.idprops[0]) + 1 return g.idprops[1:lnp], g.idprops[lnp:] case 255: lnp := int(binary.LittleEndian.Uint64([]byte(g.idprops[1:9]))) + 9 return g.idprops[9:lnp], g.idprops[lnp:] } } func makeCompositeRaw(idRaw, propsRaw string) string { idRaw = stripWhitespace(idRaw) propsRaw = stripWhitespace(propsRaw) if len(idRaw) == 0 && len(propsRaw) == 0 { return "" } var raw []byte if len(idRaw) > 0xFF-1 { raw = make([]byte, len(idRaw)+len(propsRaw)+9) raw[0] = 0xFF binary.LittleEndian.PutUint64(raw[1:9], uint64(len(idRaw))) copy(raw[9:], idRaw) copy(raw[len(idRaw)+9:], propsRaw) } else { raw = make([]byte, len(idRaw)+len(propsRaw)+1) raw[0] = byte(len(idRaw)) copy(raw[1:], idRaw) copy(raw[len(idRaw)+1:], propsRaw) } return string(raw) } // JSON is the json representation of the object. This might not be exactly the same as the original. func (g Feature) JSON() string { var buf bytes.Buffer buf.WriteString(`{"type":"Feature","geometry":`) buf.WriteString(g.Geometry.JSON()) g.BBox.write(&buf) idRaw, propsRaw := g.getRaw() if propsRaw != "" { buf.WriteString(`,"properties":`) buf.WriteString(propsRaw) } if idRaw != "" { buf.WriteString(`,"id":`) buf.WriteString(idRaw) } buf.WriteByte('}') return buf.String() } // String returns a string representation of the object. This might be JSON or something else. func (g Feature) String() string { return g.JSON() } // Bytes is the bytes representation of the object. func (g Feature) Bytes() []byte { return []byte(g.JSON()) } func (g Feature) bboxPtr() *BBox { return g.BBox } func (g Feature) hasPositions() bool { if g.BBox != nil { return true } return g.Geometry.hasPositions() } // WithinBBox detects if the object is fully contained inside a bbox. func (g Feature) WithinBBox(bbox BBox) bool { if g.BBox != nil { return rectBBox(g.CalculatedBBox()).InsideRect(rectBBox(bbox)) } return g.Geometry.WithinBBox(bbox) } // IntersectsBBox detects if the object intersects a bbox. func (g Feature) IntersectsBBox(bbox BBox) bool { if g.BBox != nil { return rectBBox(g.CalculatedBBox()).IntersectsRect(rectBBox(bbox)) } return g.Geometry.IntersectsBBox(bbox) } // Within detects if the object is fully contained inside another object. func (g Feature) Within(o Object) bool { return withinObjectShared(g, o, func(v Polygon) bool { return g.Geometry.Within(o) }, func(v MultiPolygon) bool { return g.Geometry.Within(o) }, ) } // Intersects detects if the object intersects another object. func (g Feature) Intersects(o Object) bool { return intersectsObjectShared(g, o, func(v Polygon) bool { return g.Geometry.Intersects(o) }, func(v MultiPolygon) bool { return g.Geometry.Intersects(o) }, ) } // Nearby detects if the object is nearby a position. func (g Feature) Nearby(center Position, meters float64) bool { return nearbyObjectShared(g, center.X, center.Y, meters) } // IsBBoxDefined returns true if the object has a defined bbox. func (g Feature) IsBBoxDefined() bool { return g.BBox != nil } // IsGeometry return true if the object is a geojson geometry object. false if it something else. func (g Feature) IsGeometry() bool { return true }