DDevelopment & Design

Kotlin Type-Inference Puzzler

Kotlin takes Type-Inference to the next level (at least in comparison to Java) which is great, but there’re scenarios, in which it can backfire on us.

The Riddle

fun foo(int: Int?) = {
    println(int)
}

fun main(args: Array<String>) {
    listOf(42).forEach { foo(it) }
}

And the question is: what does the puzzler() method print and why it’s not 42? Assume that the main() method gets executed.

The answer can be found at the very end of the article.

Explanation

In Kotlin, we’ve got not only a local variable type inference (which is also coming to Java) but also the return value type inference when writing single-expression methods.

Which means that if we write a method:

fun foo() : String  {
    return "42"
}

We can rewrite it using the single-expression method syntax and ignore the explicit type declaration and the return keyword:

fun foo() = "42"

So, if we have a method:

fun foo(int: Int?) : Unit {
    println(int)
    return Unit
}

we could get rid of the return type declaration, as well as the explicit return statement by leveraging single-expression method syntax, right? but we already know that the following doesn’t work:

fun foo(int: Int?) = {
    println(int)
}

The devil’s in the details but everything becomes crystal clear if we specify the return type explicitly:

fun foo(int: Int?) : () -> Unit = {
    println(int)
}

If we look closely, it can be seen that we mixed two approaches here and actually defined a method that doesn’t return Unit but a () -> Unit itself – which is simply an action that doesn’t accept any parameters and doesn’t return anything – which is semantically equivalent to returning a java.lang.Runnable instance.

This is because Kotlin utilizes curly braces not only for defining classes/methods but also for defining Lambda Expressions and { println(42) } is a valid Lambda Expression declaration:

val foo: () -> Unit = { println(42) }

So, our original example is simply a Higher-Order Function accepting an Int parameter and returning a function that prints it – when we return it in the forEach() the return value just gets ignored.

So, if we want to fix our example, we have two ways to go.

Explicitly call invoke() on the returned function:

listOf(42)
  .forEach { foo(it).invoke() }

or simply define the method properly by removing the “=” sign:

fun foo(int: Int?) {
    println(int)
}

or by leveraging the single-expression method syntax:

fun foo(int: Int?) = println(int)

That’s why I encourage my fellow team members to declare return types explicitly.

Code snippets can be found on GitHub.

Answer

The method prints nothing.

— Previous article

Karaf configuration as Groovy file

Next article —

MapStruct mapper injection in OSGi Blueprint

You May Also Like
DDevelopment & Design

Clojure web development – state of the art

It’s now more than a year that I’m getting familiar with Clojure and the more I dive into it, the more it becomes the language. Once you defeat the “parentheses fear”, everything else just makes the difference: tooling, community, good engineering practices. So it’s now time for me to convince others. In this post I’ll try to walktrough a simple web application from scratch to show key tools and libraries used to develop with Clojure in late 2015.

Note for Clojurians: This material is rather elementary and may be useful for you if you already know Clojure a bit but never did anything bigger than hello world application.

Note for Java developers: This material shows how to replace Spring, Angular, grunt, live-reload with a bunch of Clojure tools and libraries and a bit of code.

The repo with final code and individual steps is here.

Bootstrap

I think all agreed that component is the industry standard for managing lifecycle of Clojure applications. If you are a Java developer you may think of it as a Spring (DI) replacement - you declare dependencies between “components” which are resolved on “system” startup. So you just say “my component needs a repository/database pool” and component library “injects” it for you.

To keep things simple I like to start with duct web app template. It’s a nice starter component application following the 12-factor philosophy. So let’s start with it:

lein new duct clojure-web-app +example

The +example parameter tells duct to create an example endpoint with HTTP routes - this would be helpful. To finish bootstraping run lein setup inside clojure-web-app directory.

Ok, let’s dive into the code. Component and injection related code should be in system.clj file:

(defn new-system [config]
  (let [config (meta-merge base-config config)]
    (-> (component/system-map
         :app  (handler-component (:app config))
         :http (jetty-server (:http config))
         :example (endpoint-component example-endpoint))
        (component/system-using
         {:http [:app]
          :app  [:example]
          :example []}))))

In the first section you instantiate components without dependencies, which are resolved in the second section. So in this example, “http” component (server) requires “app” (application abstraction), which in turn is injected with “example” (actual routes). If your component needs others, you just can get then by names (precisely: by Clojure keywords).

To start the system you must fire a REPL - interactive environment running within context of your application:

lein repl

After seeing prompt type (go). Application should start, you can visit http://localhost:3000 to see some example page.

A huge benefit of using component approach is that you get fully reloadable application. When you change literally anything - configuration, endpoints, implementation, you can just type (reset) in REPL and your application is up-to-date with the code. It’s a feature of the language, no JRebel, Spring-reloaded needed.

Adding REST endpoint

Ok, in the next step let’s add some basic REST endpoint returning JSON. We need to add 2 dependencies in project.clj file:

:dependencies
 ...
  [ring/ring-json "0.3.1"]
  [cheshire "5.1.1"]

Ring-json adds support for JSON for your routes (in ring it’s called middleware) and cheshire is Clojure JSON parser (like Jackson in Java). Modifying project dependencies if one of the few tasks that require restarting the REPL, so hit CTRL-C and type lein repl again.

To configure JSON middleware we have to add wrap-json-body and wrap-json-response just before wrap-defaults in system.clj:

(:require 
 ...
 [ring.middleware.json :refer [wrap-json-body wrap-json-response]])

(def base-config
   {:app {:middleware [[wrap-not-found :not-found]
                      [wrap-json-body {:keywords? true}]
                      [wrap-json-response]
                      [wrap-defaults :defaults]]

And finally, in endpoint/example.clj we must add some route with JSON response:

(:require 
 ...
 [ring.util.response :refer [response]]))

(defn example-endpoint [config]
  (routes
    (GET "/hello" [] (response {:hello "world"}))
    ...

Reload app with (reset) in REPL and test new route with curl:

curl -v http://localhost:3000/hello

< HTTP/1.1 200 OK
< Date: Tue, 15 Sep 2015 21:17:37 GMT
< Content-Type: application/json; charset=utf-8
< Set-Cookie: ring-session=37c337fb-6bbc-4e65-a060-1997718d03e0;Path=/;HttpOnly
< X-XSS-Protection: 1; mode=block
< X-Frame-Options: SAMEORIGIN
< X-Content-Type-Options: nosniff
< Content-Length: 151
* Server Jetty(9.2.10.v20150310) is not blacklisted
< Server: Jetty(9.2.10.v20150310)
<
* Connection #0 to host localhost left intact
{"hello": "world"}

It works! In case of any problems you can find working version in this commit.

Adding frontend with figwheel

Coding backend in Clojure is great, but what about the frontend? As you may already know, Clojure could be compiled not only to JVM bytecode, but also to Javascript. This may sound familiar if you used e.g. Coffescript. But ClojureScript philosophy is not only to provide some syntax sugar, but improve your development cycle with great tooling and fully interactive development. Let’s see how to achieve it.

The best way to introduce ClojureScript to a project is figweel. First let’s add fighweel plugin and configuration to project.clj:

:plugins
   ...
   [lein-figwheel "0.3.9"]

And cljsbuild configuration:

:cljsbuild
    {:builds [{:id "dev"
               :source-paths ["src-cljs"]
               :figwheel true
               :compiler {:main       "clojure-web-app.core"
                          :asset-path "js/out"
                          :output-to  "resources/public/js/clojure-web-app.js"
                          :output-dir "resources/public/js/out"}}]}

In short this tells ClojureScript compiler to take sources from src-cljs with figweel support and but resulting JavaScript into resources/public/js/clojure-web-app.js file. So we need to include this file in a simple HTML page:

<!DOCTYPE html>
<head>
</head>
<body>
  <div id="main">
  </div>
  <script src="js/clojure-web-app.js" type="text/javascript"></script>
</body>
</html>

To serve this static file we need to change some defaults and add corresponding route. In system.clj change api-defaults to site-defaults both in require section and base-config function. In example.clj add following route:

(GET "/" [] (io/resource "public/index.html")

Again (reset) in REPL window should reload everything.

But where is our ClojureScript source file? Let’s create file core.cljs in src-cljs/clojure-web-app directory:

(ns ^:figwheel-always clojure-web-app.core)

(enable-console-print!)

(println "hello from clojurescript")

Open another terminal and run lein fighweel. It should compile ClojureScript and print ‘Prompt will show when figwheel connects to your application’. Open http://localhost:3000. Fighweel window should prompt:

To quit, type: :cljs/quit
cljs.user=>

Type (js/alert "hello"). Boom! If everything worked you should see and alert in your browser. Open developers console in your browser. You should see hello from clojurescript printed on the console. Change it in core.cljs to (println "fighweel rocks") and save the file. Without reloading the page your should see updated message. Figweel rocks! Again, in case of any problems, refer to this commit.

In the next post I’ll show how to fetch data from MongoDB, serve it with REST to the broser and write ReactJs/Om components to render it. Stay tuned!

DDevelopment & Design

Using Eclipse snippets for faster JUnit test creation (with Mockito!)

I'm using this snippet to create a template of new unit test method supporting BDD mockito tests. This is a good example for adding static imports to a class from snippets.@${testType:newType(org.junit.Test)}public void should${testname}() { ${staticIm...I'm using this snippet to create a template of new unit test method supporting BDD mockito tests. This is a good example for adding static imports to a class from snippets.@${testType:newType(org.junit.Test)}public void should${testname}() { ${staticIm...