Fable parser for TypeScript declaration files.
Install it with yarn or npm. With yarn it is:
yarn global add ts2fable
With npm it is:
npm install -g ts2fable
Run the ts2fable
command on a TypeScript file and also specify the F# output file. The F# namespace in taken from the output filename. In this example, it is Yargs
.
yarn add @types/yargs --dev
ts2fable node_modules/@types/yargs/index.d.ts src/Yargs.fs
You can also use --export
(or -e
) option to collect from multiple tsfiles
In below sample: All the related ts files in npm packages uifabric and office-ui-fabric-react will be compiled to OfficeReact.fs
as a bundle
ts2fable node_modules/office-ui-fabric-react/lib/index.d.ts test-compile/OfficeReact.fs -e uifabric office-ui-fabric-react
You can find more information about how to interact with JavaScript from F# here. Please note the parser is not perfect and some tweaking by hand may be needed. Please submit bugs as issues on GitHub.
You can also try an in-browser version here
The online version will be updated automatically when commits is merged
Succesfull builds on the master branch are uploaded and tagged as next
. You can help us test these builds by installing them with:
yarn global add ts2fable@next
or build directly from source:
git clone https://github.com/fable-compiler/ts2fable
cd ts2fable
- Compile:
- Windows:
./fake.cmd build
- Linux:
./fake.sh build
- Windows:
- Run:
node -require esm ./build/cli/ts2fable.js Path/to/Declaration.d.ts Path/to/Output.fs
- or:
npm ts2fable Path/to/Declaration.d.ts Path/to/Output.fs
-require esm
is needed, because fable outputs code with ES modules.
If you want to run ts2fable directly without esm (ECMAScript module loader):
- build:
./fake.cmd build -t Cli.BuildRelease
- call:
node ./dist/ts2fable.js ...
./test
: Mocha tests- Run:
./fake.cmd build -t RunTest
- Watch:
./fake.cmd build -t WatchAndRunTest
functionTests.fs
: Test ts2fable functionsfsFileTests.fs
: Test file translation using small snippets and compare output against expected results or content
- Run:
./test-compile
: Translate actual TypeScript declaration files with ts2fable into F#. Then compile with F# compiler to ensure they are valid F#.- Run:
./fake.cmd build -t BuildTestCompile
- Setup for translation of .ts files:
./build.fsx
> TargetRunCliOnTestCompile
- Setup for .NET compilation:
./test-compile/test-compile.fsproj
- Run:
Run both test suites: ./fake.cmd build -t CliTest
Debug Test:
- In VS Code:
Ctrl+Shift+P
> Run Task > WatchTest - Add your test to
./test/fsFileTests.fs
and prefix with mochaonly
(See below sample)
Sample Test:
only "duplicated variable exports" <| fun _ ->
let tsPaths = ["node_modules/reactxp/dist/web/ReactXP.d.ts"]
let fsPath = "test-compile/ReactXP.fs"
testFsFiles tsPaths fsPath <| fun fsFiles ->
fsFiles
|> getTopVariables
|> List.countBy(fun vb -> vb.Name)
|> List.forall(fun (_,l) -> l = 1)
|> equal true
- Press F5 (or launch
Run Mocha Tests
) to debug this test
- Start with:
./fake.cmd run -t WebApp.Watch
- Launch in Browser:
localhost:8080
Some JavaScript/TypeScript features have no direct translation to F#. Here is a list of common workarounds adopted by the parser to solve these problems:
- Erased unions: TypeScript union types work differently from F# and its only purpose is to specify the types allowed for a function argument. In F# they are translated as erased unions: they're checked at compiled time but they'll be removed from the generated JS code.
type CanvasRenderingContext2D =
abstract fillStyle: U3<string, CanvasGradient, CanvasPattern> with get, set
let ctx: CanvasRenderingContext2D = failwith "dummy"
ctx.fillStyle <- U3.Case1 "#FF0000"
- Constructor functions: In JS any function can become a constructor just by
calling it with the
new
keyword. In the parsed files, interfaces with this capability will have aCreate
method attached:
type CanvasRenderingContext2DType =
abstract prototype: CanvasRenderingContext2D with get, set
[<Emit("new $0($1...)")>] abstract Create: unit -> CanvasRenderingContext2D
- Callable interfaces: In the same way, JS functions are just objects which
means applying arguments directly to any object is legal in JS. To convey, the
parser attaches an
Invoke
method to callable interfaces:
type Express =
inherit Application
abstract version: string with get, set
abstract application: obj with get, set
[<Emit("$0($1...)")>] abstract Invoke: unit -> Application