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A spatial analysis library written in Swift for native iOS, macOS, tvOS, watchOS, and Linux applications, ported from Turf.js.
Turf for Swift is experimental and its public API is subject to change. Please use with care and open issues for any problems you see or missing features that should be added.
Turf requires Xcode 9.x and supports the following minimum deployment targets:
- iOS 10.0 and above
- macOS 10.12 (Sierra) and above
- tvOS 10.0 and above
- watchOS 3.0 and above
Alternatively, you can incorporate Turf into a command line tool without Xcode on any platform that Swift supports, including Linux.
If your project is written in Objective-C, you’ll need to write a compatibility layer between turf-swift and your Objective-C code. If your project is written in Objective-C++, you may be able to use spatial-algorithms as an alternative to Turf.
Although a stable release of this library is not yet available, prereleases are available for installation using any of the popular Swift dependency managers.
To install Turf using CocoaPods:
- Specify the following dependency in your Podfile:
pod 'Turf', '~> 1.0'
- Run
pod repo updateif you haven’t lately. - Run
pod installand open the resulting Xcode workspace. - Add
import Turfto any Swift file in your application target.
To install Turf using Carthage:
- Add the following dependency to your Cartfile:
github "mapbox/turf-swift" ~> 1.0 - Run
carthage bootstrap. - Follow the rest of Carthage’s integration instructions. Your application target’s Embedded Frameworks should include Turf.framework.
- Add
import Turfto any Swift file in your application target.
To install Turf using the Swift Package Manager, add the following package to the dependencies in your Package.swift file:
.package(url: "https://github.com/mapbox/turf-swift.git", from: "1.0.0")Then import Turf in any Swift file in your module.
This work-in-progress port of Turf.js contains the following functionality:
| Turf.js | Turf-swift |
|---|---|
| turf-along | LineString.coordinateFromStart(distance:) |
| turf-area | Polygon.area |
| turf-bezier-spline | LineString.bezier(resolution:sharpness:) |
| turf-boolean-point-in-polygon | Polygon.contains(_:ignoreBoundary:) |
| turf-destination | CLLocationCoordinate2D.coordinate(at:facing:)RadianCoordinate2D.coordinate(at:facing:) |
| turf-distance | CLLocationCoordinate2D.distance(to:)RadianCoordinate2D.distance(to:) |
| turf-helpers#polygon | Polygon(_:) |
| turf-helpers#lineString | LineString(_:) |
| turf-helpers#degreesToRadians | CLLocationDegrees.toRadians() |
| turf-helpers#radiansToDegrees | CLLocationDegrees.toDegrees() |
| turf-helpers#convertLength turf-helpers#convertArea |
Measurement.converted(to:) |
| turf-length | LineString.distance(from:to:) |
| turf-line-intersect | intersection(_:_:) |
| turf-line-slice | LineString.sliced(from:to:) |
| turf-line-slice-along | LineString.trimmed(from:distance:) |
| turf-midpoint | mid(_:_:) |
| turf-nearest-point-on-line | LineString.closestCoordinate(to:) |
| — | CLLocationCoordinate2D.direction(to:)RadianCoordinate2D.direction(to:) |
| — | CLLocationDirection.difference(from:) |
| — | CLLocationDirection.wrap(min:max:) |
| turf-polygon-to-line | LineString(_:)MultiLineString(_:)FeatureCollection(_:) |
turf-swift also contains an experimental GeoJSON encoder/decoder with support for Codable.
// Decode unknown GeoJSON type
let geojson = try! GeoJSON.parse(data)
// Decode known GeoJSON type
let geojson = try! GeoJSON.parse(FeatureCollection.self, from: data)
// Initialize a PointFeature and encode as GeoJSON
let coordinate = CLLocationCoordinate2D(latitude: 0, longitude: 1)
let point = Point(coordinate)
let pointFeature = Feature(geometry: .point(point))
let data = try! JSONEncoder().encode(pointFeature)
let json = String(data: data, encoding: .utf8)
print(json)
/*
{
"type": "Feature",
"geometry": {
"type": "Point",
"coordinates": [
1,
0
]
}
}
*/