address.map(Function.prototype.call, String.prototype.trim);

Recently my friend sent me a very interesting JS snippet, which he found in one open-source library:

1 addressParts . map ( Function . prototype . call , String . prototype . trim );

At first, I laughed and thought “nice try”. Second thought was that map accepts only one argument, and I went to MDN docs, where I realized that you can pass context as a second argument. At this point I was really puzzled, and after running my confusion increased to the limit – it worked as expected!

I’ve spent at least half an hour playing with it, and it was an interesting example how magical JavaScript can be, even after years spent writing it. Feel free to figure it out by yourself, and if you want to check out my understanding, keep reading!

So, how does it work? Let’s start with super naive implementation (which is actually shorter and easier to read :)):

1 addressParts . map ( str => str . trim ());

But as it is clear, we strive here to avoid creating new functions, so let’s move on. Function.prototype.call is a function in prototype of all javascript functions, and it invokes function, using first argument as this argument, passing rest arguments as parameters of function invokation. To illustrate:

1 2 3 4 5 6 7 8 // this function has `Function` in prototype chain // so `call` is available function multiply ( x , y ) { return x * y ; } multiply . call ( null , 3 , 5 ); // 15 multiply ( 3 , 5 ); // same, 15

Typical usage of the second argument can be the following – imagine you have a class-based react component, and you want to render list of buttons:

1 2 3 4 5 6 7 8 9 10 11 12 13 14 15 16 17 18 19 class ExampleComponent extends Component { renderButton ({ title , name }) { // without proper `this` it will fail const { isActive } = this . props ; return ( < Button key = { title } title = { title } > { name } < /Button > ); } render () { const { buttons } = this . props ; // without second param our function won't be able // to access `this` inside const buttonsMarkup = buttons . map ( this . renderButton , this ); } }

However, from my experience, it is not that common to use this second argument, usually class properties or decorators are used to avoid binding all the time.

There is one similar method – Function.prototype.apply, which works the same, except that the second argument should be an array, which will be transformed to a normal list of arguments, separated by comma. So, let’s see how we can use it to calculate maximum:

1 2 3 4 5 6 7 8 9 Math . max ( 1 , 2 , 3 ); // if we know all numbers upfront // we can call it like that Math . max ([ 1 , 2 , 3 ]); // won't work! Math . max . apply ( null , [ 1 , 2 , 3 ]); // will work! // however, ES2015 array destructuring works as well: Math . max (...[ 1 , 2 , 3 ]);

Now, let’s try to recreate a call which will solve our problem. We want to trim the string, and it is a method in String.prototype , so we call it using . notation (however, strings are primitives, but when we call methods, they are converted to objects internally). Let’s go back to our console:

1 2 3 4 5 6 7 8 9 10 11 12 13 14 15 16 // let's try to imagine how trim method is implemented // on String.prototype String . prototype . trim = function () { // string itself is contained inside `this`! const str = this ; // this is a very naive implementation return str . replace ( / ( ^ \s + ) | (\s +$ ) /g , '' ); }; // let's try to use `.call` method to invoke `trim` " aa " . trim . call ( thisArg ); // but `this` is our string itself! // so, next two calls are equivalent: " aa " . trim . call ( " aa " ); String . prototype . trim . call ( " aa " );

We are now one step closer, but still not yet there to understand our initial snippet:

1 addressParts . map ( Function . prototype . call , String . prototype . trim );

Let’s try to implement Function.prototype.call itself:

1 2 3 4 5 6 7 Function . prototype . call = function ( thisArg , ... args ) { // `this` in our case is actually our function! const fn = this ; // also, pretty naive implementation return fn . bind ( thisArg )(... args ); };

So, now we can put all pieces together. When we declare function inside the .map , we pass Function.prototype.call with bound String.prototype.trim as this context, and then we invoke this function on each element in the collection, passing each string as thisArg to the call . It means that String.prototype.trim will be invoked using string as this context! We already found that it will work, using our example:

1 String . prototype . trim . call ( " aa " ); // "aa"

Problem solved! However, I think it is not the best example how one should write such a code in JavaScript, and instead just pass a simple anonymous function: