package rtree import "github.com/tidwall/tile38/index/rtreebase" // Item is an rtree item type Item interface { Rect() (minX, minY, minZ, maxX, maxY, maxZ float64) } // Rect is a rectangle type Rect struct { MinX, MinY, MinZ, MaxX, MaxY, MaxZ float64 } // Rect returns the rectangle func (item *Rect) Rect() (minX, minY, minZ, maxX, maxY, maxZ float64) { return item.MinX, item.MinY, item.MinZ, item.MaxX, item.MaxY, item.MaxZ } // RTree is an implementation of an rtree type RTree struct { tr *rtreebase.RTree } // New creates a new RTree func New() *RTree { return &RTree{ tr: rtreebase.New(), } } // Insert inserts item into rtree func (tr *RTree) Insert(item Item) { minX, minY, _, maxX, maxY, _ := item.Rect() tr.tr.Insert([2]float64{minX, minY}, [2]float64{maxX, maxY}, item) } // Remove removes item from rtree func (tr *RTree) Remove(item Item) { minX, minY, _, maxX, maxY, _ := item.Rect() tr.tr.Remove([2]float64{minX, minY}, [2]float64{maxX, maxY}, item) } // Search finds all items in bounding box. func (tr *RTree) Search(minX, minY, minZ, maxX, maxY, maxZ float64, iterator func(data interface{}) bool) { // start := time.Now() // var count int tr.tr.Search([2]float64{minX, minY}, [2]float64{maxX, maxY}, func(data interface{}) bool { // count++ return iterator(data) }) // dur := time.Since(start) // fmt.Printf("%s %d\n", dur, count) } // Count return the number of items in rtree. func (tr *RTree) Count() int { return tr.tr.Count() } // RemoveAll removes all items from rtree. func (tr *RTree) RemoveAll() { tr.tr = rtreebase.New() } // Bounds returns the bounds of the R-tree func (tr *RTree) Bounds() (minX, minY, maxX, maxY float64) { min, max := tr.tr.Bounds() return min[0], min[1], max[0], max[1] } // NearestNeighbors gets the closest Spatials to the Point. func (tr *RTree) NearestNeighbors(x, y float64, iter func(item interface{}, dist float64) bool) bool { return tr.tr.KNN([2]float64{x, y}, [2]float64{x, y}, true, func(item interface{}, dist float64) bool { return iter(item, dist) }) }