package rtree

You can search for identifiers within the package.

in-package search v0.2.0

On This Page

Core Modules
Guide
1. Insertion
  1. Loading
2. Find

rtree
- Rtree
  - Envelope
  - Make
    
    Envelope
    
    Value
  - Maker
    
    Envelope
    
    Value
  - Rectangle
  - S
    
    Envelope
    
    Value
  - Value

Legend:
Library
Module
Module type
Parameter
Class
Class type

Rtree

An Rtree is a data-structure for indexing geospatial information. They are quite closely related to B-trees. They make it quicker to perform geospatial queries on data such as "what are all the items that are inside this area?".

This library provides in-memory Rtrees that are parameterised over both the envelope (minimal bounding box) and the values stored in the the rtree. Note that the values are tied to the envelope as you must provide a means of calculating an envelope from any value.

To this end you probably want to start with Rtree.Make and for must two-dimensional use cases the Rtree.Rectangle envelope it probably what you are looking for.

Core Modules

Guide

There are two key elements to an rtree. The type of envelopes used and the type of the values being store in the tree. These values must come with a function to calculate an envelope.

The core library comes with an implementation of envelopes as two-dimensional Rtree.Rectangle.

If you wanted to store lines in your rtree, one possible implementation might be the following.

module Line = struct
  type t = { p0 : float * float; p1 : float * float }

  let t =
    let open Repr in
    record "line" (fun p0 p1 -> { p0; p1 })
    |+ field "p0" (pair float float) (fun t -> t.p0)
    |+ field "p1" (pair float float) (fun t -> t.p1)
    |> sealr

  type envelope = Rtree.Rectangle.t

  let envelope { p0 = (x1, y1); p1 = (x2, y2) } =
    let x0 = Float.min x1 x2 in
    let x1 = Float.max x1 x2 in
    let y0 = Float.min y1 y2 in
    let y1 = Float.max y1 y2 in
    Rtree.Rectangle.v ~x0 ~y0 ~x1 ~y1
end

module R = Rtree.Make(Rtree.Rectangle)(Line)

Insertion

To insert into an rtree, you simply pass a value into a pre-existing rtree. You can create an empty rtree where you control the maximum node load size. This is essentially the branching factor in the tree. The correct value is hard to guess.

# let index = R.empty 8;;
val index : R.t = <abstr>
# let index = R.insert index Line.{ p0 = (1., 2.); p1 = (3., 3.) };;
val index : R.t = <abstr>
# let index = R.insert index Line.{ p0 = (4., 4.); p1 = (5., 5.) };;
val index : R.t = <abstr>

Loading

If you have a list of values to put into an rtree, then you are better off using the `load` function instead of folding and inserting. This uses the OMT algorithm and should give you a more optimised rtree layout.

let lines =
    Line.[
      { p0 = (0., 0.); p1 = (1., 1.) };
      { p0 = (1., 1.); p1 = (2., 2.) };
      { p0 = (2., 2.); p1 = (3., 3.) };
      { p0 = (3., 3.); p1 = (4., 4.) };
    ]
in
  R.load ~max_node_load:2 lines

Find

Finding values requires you to pass in a search envelope. A list of result, perhaps empty, will be returned.

# R.find index (Rtree.Rectangle.v ~x0:0. ~y0:0. ~x1:3. ~y1:3.);;
- : Line.t list = [{Line.p0 = (1., 2.); p1 = (3., 3.)}]
# R.find index (Rtree.Rectangle.v ~x0:0. ~y0:0. ~x1:5. ~y1:5.);;
- : Line.t list =
[{Line.p0 = (4., 4.); p1 = (5., 5.)}; {Line.p0 = (1., 2.); p1 = (3., 3.)}]