A list of funny and tricky JavaScript examples
JavaScript is a great language. It has a simple syntax, large ecosystem and, what is most important, a great community.
At the same time, we all know that JavaScript is quite a funny language with tricky parts. Some of them can quickly turn our everyday job into hell, and some of them can make us laugh out loud.
The original idea for WTFJS belongs to Brian Leroux. This list is highly inspired by his talk βWTFJSβ at dotJS 2012:
You can install this handbook using npm
. Just run:
$ npm install -g wtfjs
You should be able to run wtfjs
at the command line now. This will open the manual in your selected $PAGER
. Otherwise, you may continue reading on here.
The source is available here: https://github.com/denysdovhan/wtfjs
Currently, there are these translations of wtfjs:
- πͺπ» Motivation
- βπ» Notation
- π Examples
[]
is equal![]
true
is not equal![]
, but not equal[]
too- true is false
- baNaNa
NaN
is not aNaN
- It's a fail
[]
is truthy, but nottrue
null
is falsy, but notfalse
document.all
is an object, but it is undefined- Minimal value is greater than zero
- function is not a function
- Adding arrays
- Trailing commas in array
- Array equality is a monster
undefined
andNumber
parseInt
is a bad guy- Math with
true
andfalse
- HTML comments are valid in JavaScript
NaN
isnota number[]
andnull
are objects- Magically increasing numbers
- Precision of
0.1 + 0.2
- Patching numbers
- Comparison of three numbers
- Funny math
- Addition of RegExps
- Strings aren't instances of
String
- Calling functions with backticks
- Call call call
- A
constructor
property - Object as a key of object's property
- Accessing prototypes with
__proto__
`${{Object}}`
- Destructuring with default values
- Dots and spreading
- Labels
- Nested labels
- Insidious
try..catch
- Is this multiple inheritance?
- A generator which yields itself
- A class of class
- Non-coercible objects
- Tricky arrow functions
- Arrow functions can not be a constructor
arguments
and arrow functions- Tricky return
- Chaining assignments on object
- Accessing object properties with arrays
- Null and Relational Operators
Number.toFixed()
display different numbersMath.max()
less thanMath.min()
- Comparing
null
to0
- Same variable redeclaration
- Default behavior Array.prototype.sort()
- π Other resources
- π License
Just for fun
β βJust for Fun: The Story of an Accidental Revolutionaryβ, Linus Torvalds
The primary goal of this list is to collect some crazy examples and explain how they work, if possible. Just because it's fun to learn something that we didn't know before.
If you are a beginner, you can use these notes to get a deeper dive into JavaScript. I hope these notes will motivate you to spend more time reading the specification.
If you are a professional developer, you can consider these examples as a great reference for all of the quirks and unexpected edges of our beloved JavaScript.
In any case, just read this. You're probably going to find something new.
// ->
is used to show the result of an expression. For example:
1 + 1; // -> 2
// >
means the result of console.log
or another output. For example:
console.log("hello, world!"); // > hello, world!
//
is just a comment used for explanations. Example:
// Assigning a function to foo constant
const foo = function() {};
Array is equal not array:
[] == ![]; // -> true
The abstract equality operator converts both sides to numbers to compare them, and both sides become the number 0
for different reasons. Arrays are truthy, so on the right, the opposite of a truthy value is false
, which is then coerced to 0
. On the left, however, an empty array is coerced to a number without becoming a boolean first, and empty arrays are coerced to 0
, despite being truthy.
Here is how this expression simplifies:
+[] == +![];
0 == +false;
0 == 0;
true;
See also []
is truthy, but not true
.
Array is not equal true
, but not Array is not equal true
too;
Array is equal false
, not Array is equal false
too:
true == []; // -> false
true == ![]; // -> false
false == []; // -> true
false == ![]; // -> true
true == []; // -> false
true == ![]; // -> false
// According to the specification
true == []; // -> false
toNumber(true); // -> 1
toNumber([]); // -> 0
1 == 0; // -> false
true == ![]; // -> false
![]; // -> false
true == false; // -> false
false == []; // -> true
false == ![]; // -> true
// According to the specification
false == []; // -> true
toNumber(false); // -> 0
toNumber([]); // -> 0
0 == 0; // -> true
false == ![]; // -> false
![]; // -> false
false == false; // -> true
!!"false" == !!"true"; // -> true
!!"false" === !!"true"; // -> true
Consider this step-by-step:
// true is 'truthy' and represented by value 1 (number), 'true' in string form is NaN.
true == "true"; // -> false
false == "false"; // -> false
// 'false' is not the empty string, so it's a truthy value
!!"false"; // -> true
!!"true"; // -> true
"b" + "a" + +"a" + "a"; // -> 'baNaNa'
This is an old-school joke in JavaScript, but remastered. Here's the original one:
"foo" + +"bar"; // -> 'fooNaN'
The expression is evaluated as 'foo' + (+'bar')
, which converts 'bar'
to not a number.
NaN === NaN; // -> false
The specification strictly defines the logic behind this behavior:
- If
Type(x)
is different fromType(y)
, return false.- If
Type(x)
is Number, then
- If
x
is NaN, return false.- If
y
is NaN, return false.- β¦ β¦ β¦
Following the definition of NaN
from the IEEE:
Four mutually exclusive relations are possible: less than, equal, greater than, and unordered. The last case arises when at least one operand is NaN. Every NaN shall compare unordered with everything, including itself.
β βWhat is the rationale for all comparisons returning false for IEEE754 NaN values?β at StackOverflow
You would not believe, but β¦
(![] + [])[+[]] +
(![] + [])[+!+[]] +
([![]] + [][[]])[+!+[] + [+[]]] +
(![] + [])[!+[] + !+[]];
// -> 'fail'
By breaking that mass of symbols into pieces, we notice that the following pattern occurs often:
![] + []; // -> 'false'
![]; // -> false
So we try adding []
to false
. But due to a number of internal function calls (binary + Operator
-> ToPrimitive
-> [[DefaultValue]]
) we end up converting the right operand to a string:
![] + [].toString(); // 'false'
Thinking of a string as an array we can access its first character via [0]
:
"false"[0]; // -> 'f'
The rest is obvious, but the i
is tricky. The i
in fail
is grabbed by generating the string 'falseundefined'
and grabbing the element on index ['10']
An array is a truthy value, however, it's not equal to true
.
!![] // -> true
[] == true // -> false
Here are links to the corresponding sections in the ECMA-262 specification:
Despite the fact that null
is a falsy value, it's not equal to false
.
!!null; // -> false
null == false; // -> false
At the same time, other falsy values, like 0
or ''
are equal to false
.
0 == false; // -> true
"" == false; // -> true
The explanation is the same as for previous example. Here's the corresponding link:
β οΈ This is part of the Browser API and won't work in a Node.js environmentβ οΈ
Despite the fact that document.all
is an array-like object and it gives access to the DOM nodes in the page, it responds to the typeof
function as undefined
.
document.all instanceof Object; // -> true
typeof document.all; // -> 'undefined'
At the same time, document.all
is not equal to undefined
.
document.all === undefined; // -> false
document.all === null; // -> false
But at the same time:
document.all == null; // -> true
document.all
used to be a way to access DOM elements, in particular with old versions of IE. While it has never been a standard it was broadly used in the old age JS code. When the standard progressed with new APIs (such asdocument.getElementById
) this API call became obsolete and the standard committee had to decide what to do with it. Because of its broad use they decided to keep the API but introduce a willful violation of the JavaScript specification. The reason why it responds tofalse
when using the Strict Equality Comparison withundefined
whiletrue
when using the Abstract Equality Comparison is due to the willful violation of the specification that explicitly allows that.β βObsolete features - document.allβ at WhatWG - HTML spec β βChapter 4 - ToBoolean - Falsy valuesβ at YDKJS - Types & Grammar
Number.MIN_VALUE
is the smallest number, which is greater than zero:
Number.MIN_VALUE > 0; // -> true
Number.MIN_VALUE
is5e-324
, i.e. the smallest positive number that can be represented within float precision, i.e. that's as close as you can get to zero. It defines the best resolution that floats can give you.Now the overall smallest value is
Number.NEGATIVE_INFINITY
although it's not really numeric in a strict sense.β βWhy is
0
less thanNumber.MIN_VALUE
in JavaScript?β at StackOverflow
β οΈ A bug present in V8 v5.5 or lower (Node.js <=7)β οΈ
All of you know about the annoying undefined is not a function, but what about this?
// Declare a class which extends null
class Foo extends null {}
// -> [Function: Foo]
new Foo() instanceof null;
// > TypeError: function is not a function
// > at β¦ β¦ β¦
This is not a part of the specification. It's just a bug that has now been fixed, so there shouldn't be a problem with it in the future.
What if you try to add two arrays?
[1, 2, 3] + [4, 5, 6]; // -> '1,2,34,5,6'
The concatenation happens. Step-by-step, it looks like this:
[1, 2, 3] +
[4, 5, 6][
// call toString()
(1, 2, 3)
].toString() +
[4, 5, 6].toString();
// concatenation
"1,2,3" + "4,5,6";
// ->
("1,2,34,5,6");
You've created an array with 4 empty elements. Despite all, you'll get an array with three elements, because of trailing commas:
let a = [, , ,];
a.length; // -> 3
a.toString(); // -> ',,'
Trailing commas (sometimes called "final commas") can be useful when adding new elements, parameters, or properties to JavaScript code. If you want to add a new property, you can simply add a new line without modifying the previously last line if that line already uses a trailing comma. This makes version-control diffs cleaner and editing code might be less troublesome.
β Trailing commas at MDN
Array equality is a monster in JS, as you can see below:
[] == '' // -> true
[] == 0 // -> true
[''] == '' // -> true
[0] == 0 // -> true
[0] == '' // -> false
[''] == 0 // -> true
[null] == '' // true
[null] == 0 // true
[undefined] == '' // true
[undefined] == 0 // true
[[]] == 0 // true
[[]] == '' // true
[[[[[[]]]]]] == '' // true
[[[[[[]]]]]] == 0 // true
[[[[[[ null ]]]]]] == 0 // true
[[[[[[ null ]]]]]] == '' // true
[[[[[[ undefined ]]]]]] == 0 // true
[[[[[[ undefined ]]]]]] == '' // true
You should watch very carefully for the above examples! The behaviour is described in section 7.2.13 Abstract Equality Comparison of the specification.
If we don't pass any arguments into the Number
constructor, we'll get 0
. The value undefined
is assigned to formal arguments when there are no actual arguments, so you might expect that Number
without arguments takes undefined
as a value of its parameter. However, when we pass undefined
, we will get NaN
.
Number(); // -> 0
Number(undefined); // -> NaN
According to the specification:
- If no arguments were passed to this function's invocation, let
n
be+0
. - Else, let
n
be ?ToNumber(value)
. - In case of
undefined
,ToNumber(undefined)
should returnNaN
.
Here's the corresponding section:
parseInt
is famous by its quirks:
parseInt("f*ck"); // -> NaN
parseInt("f*ck", 16); // -> 15
π‘ Explanation: This happens because parseInt
will continue parsing character-by-character until it hits a character it doesn't know. The f
in 'f*ck'
is the hexadecimal digit 15
.
Parsing Infinity
to integer is somethingβ¦
//
parseInt("Infinity", 10); // -> NaN
// ...
parseInt("Infinity", 18); // -> NaN...
parseInt("Infinity", 19); // -> 18
// ...
parseInt("Infinity", 23); // -> 18...
parseInt("Infinity", 24); // -> 151176378
// ...
parseInt("Infinity", 29); // -> 385849803
parseInt("Infinity", 30); // -> 13693557269
// ...
parseInt("Infinity", 34); // -> 28872273981
parseInt("Infinity", 35); // -> 1201203301724
parseInt("Infinity", 36); // -> 1461559270678...
parseInt("Infinity", 37); // -> NaN
Be careful with parsing null
too:
parseInt(null, 24); // -> 23
π‘ Explanation:
It's converting
null
to the string"null"
and trying to convert it. For radixes 0 through 23, there are no numerals it can convert, so it returns NaN. At 24,"n"
, the 14th letter, is added to the numeral system. At 31,"u"
, the 21st letter, is added and the entire string can be decoded. At 37 on there is no longer any valid numeral set that can be generated andNaN
is returned.β βparseInt(null, 24) === 23β¦ wait, what?β at StackOverflow
Don't forget about octals:
parseInt("06"); // 6
parseInt("08"); // 8 if support ECMAScript 5
parseInt("08"); // 0 if not support ECMAScript 5
π‘ Explanation: If the input string begins with "0", radix is eight (octal) or 10 (decimal). Exactly which radix is chosen is implementation-dependent. ECMAScript 5 specifies that 10 (decimal) is used, but not all browsers support this yet. For this reason always specify a radix when using parseInt
.
parseInt
always convert input to string:
parseInt({ toString: () => 2, valueOf: () => 1 }); // -> 2
Number({ toString: () => 2, valueOf: () => 1 }); // -> 1
Be careful while parsing floating point values
parseInt(0.000001); // -> 0
parseInt(0.0000001); // -> 1
parseInt(1 / 1999999); // -> 5
π‘ Explanation: ParseInt
takes a string argument and returns an integer of the specified radix. ParseInt
also strips anything after and including the first non-digit in the string parameter. 0.000001
is converted to a string "0.000001"
and the parseInt
returns 0
. When 0.0000001
is converted to a string it is treated as "1e-7"
and hence parseInt
returns 1
. 1/1999999
is interpreted as 5.00000250000125e-7
and parseInt
returns 5
.
Let's do some math:
true +
true(
// -> 2
true + true
) *
(true + true) -
true; // -> 3
Hmmmβ¦ π€
We can coerce values to numbers with the Number
constructor. It's quite obvious that true
will be coerced to 1
:
Number(true); // -> 1
The unary plus operator attempts to convert its value into a number. It can convert string representations of integers and floats, as well as the non-string values true
, false
, and null
. If it cannot parse a particular value, it will evaluate to NaN
. That means we can coerce true
to 1
easier:
+true; // -> 1
When you're performing addition or multiplication, the ToNumber
method is invoked. According to the specification, this method returns:
If
argument
is true, return 1. Ifargument
is false, return +0.
That's why we can add boolean values as regular numbers and get correct results.
Corresponding sections:
You will be impressed, but <!--
(which is known as HTML comment) is a valid comment in JavaScript.
// valid comment
<!-- valid comment too
Impressed? HTML-like comments were intended to allow browsers that didn't understand the <script>
tag to degrade gracefully. These browsers, e.g. Netscape 1.x are no longer popular. So there is really no point in putting HTML comments in your script tags anymore.
Since Node.js is based on the V8 engine, HTML-like comments are supported by the Node.js runtime too. Moreover, they're a part of the specification:
Type of NaN
is a 'number'
:
typeof NaN; // -> 'number'
Explanations of how typeof
and instanceof
operators work:
typeof []; // -> 'object'
typeof null; // -> 'object'
// however
null instanceof Object; // false
The behavior of typeof
operator is defined in this section of the specification:
According to the specification, the typeof
operator returns a string according to Table 35: typeof
Operator Results. For null
, ordinary, standard exotic and non-standard exotic objects, which do not implement [[Call]]
, it returns the string "object"
.
However, you can check the type of an object by using the toString
method.
Object.prototype.toString.call([]);
// -> '[object Array]'
Object.prototype.toString.call(new Date());
// -> '[object Date]'
Object.prototype.toString.call(null);
// -> '[object Null]'
999999999999999; // -> 999999999999999
9999999999999999; // -> 10000000000000000
10000000000000000; // -> 10000000000000000
10000000000000000 + 1; // -> 10000000000000000
10000000000000000 + 1.1; // -> 10000000000000002
This is caused by IEEE 754-2008 standard for Binary Floating-Point Arithmetic. At this scale, it rounds to the nearest even number. Read more:
- 6.1.6 The Number Type
- IEEE 754 on Wikipedia
A well-known joke. An addition of 0.1
and 0.2
is deadly precise:
0.1 +
0.2(
// -> 0.30000000000000004
0.1 + 0.2
) ===
0.3; // -> false
The answer for the βIs floating point math broken?β question on StackOverflow:
The constants
0.2
and0.3
in your program will also be approximations to their true values. It happens that the closestdouble
to0.2
is larger than the rational number0.2
but that the closestdouble
to0.3
is smaller than the rational number0.3
. The sum of0.1
and0.2
winds up being larger than the rational number0.3
and hence disagreeing with the constant in your code.
This problem is so known that there is even a website called 0.30000000000000004.com. It occurs in every language that uses floating-point math, not just JavaScript.
You can add your own methods to wrapper objects like Number
or String
.
Number.prototype.isOne = function() {
return Number(this) === 1;
};
(1.0).isOne(); // -> true
(1).isOne(); // -> true
(2.0)
.isOne()(
// -> false
7
)
.isOne(); // -> false
Obviously, you can extend the Number
object like any other object in JavaScript. However, it's not recommended if the behavior of the defined method is not a part of the specification. Here is the list of Number
's properties:
1 < 2 < 3; // -> true
3 > 2 > 1; // -> false
Why does this work that way? Well, the problem is in the first part of an expression. Here's how it works:
1 < 2 < 3; // 1 < 2 -> true
true < 3; // true -> 1
1 < 3; // -> true
3 > 2 > 1; // 3 > 2 -> true
true > 1; // true -> 1
1 > 1; // -> false
We can fix this with Greater than or equal operator (>=
):
3 > 2 >= 1; // true
Read more about Relational operators in the specification:
Often the results of arithmetic operations in JavaScript might be quite unexpected. Consider these examples:
3 - 1 // -> 2
3 + 1 // -> 4
'3' - 1 // -> 2
'3' + 1 // -> '31'
'' + '' // -> ''
[] + [] // -> ''
{} + [] // -> 0
[] + {} // -> '[object Object]'
{} + {} // -> '[object Object][object Object]'
'222' - -'111' // -> 333
[4] * [4] // -> 16
[] * [] // -> 0
[4, 4] * [4, 4] // NaN
What's happening in the first four examples? Here's a small table to understand addition in JavaScript:
Number + Number -> addition
Boolean + Number -> addition
Boolean + Boolean -> addition
Number + String -> concatenation
String + Boolean -> concatenation
String + String -> concatenation
What about other examples? A ToPrimitive
and ToString
methods are being implicitly called for []
and {}
before addition. Read more about evaluation process in the specification:
- 12.8.3 The Addition Operator (
+
) - 7.1.1 ToPrimitive(
input
[,PreferredType
]) - 7.1.12 ToString(
argument
)
Did you know you can add numbers like this?
// Patch a toString method
RegExp.prototype.toString =
function() {
return this.source;
} /
7 /
-/5/; // -> 2
"str"; // -> 'str'
typeof "str"; // -> 'string'
"str" instanceof String; // -> false
The String
constructor returns a string:
typeof String("str"); // -> 'string'
String("str"); // -> 'str'
String("str") == "str"; // -> true
Let's try with a new
:
new String("str") == "str"; // -> true
typeof new String("str"); // -> 'object'
Object? What's that?
new String("str"); // -> [String: 'str']
More information about the String constructor in the specification:
Let's declare a function which logs all params into the console:
function f(...args) {
return args;
}
No doubt, you know you can call this function like this:
f(1, 2, 3); // -> [ 1, 2, 3 ]
But did you know you can call any function with backticks?
f`true is ${true}, false is ${false}, array is ${[1, 2, 3]}`;
// -> [ [ 'true is ', ', false is ', ', array is ', '' ],
// -> true,
// -> false,
// -> [ 1, 2, 3 ] ]
Well, this is not magic at all if you're familiar with Tagged template literals. In the example above, f
function is a tag for template literal. Tags before template literal allow you to parse template literals with a function. The first argument of a tag function contains an array of string values. The remaining arguments are related to the expressions. Example:
function template(strings, ...keys) {
// do something with strings and keysβ¦
}
This is the magic behind famous library called π styled-components, which is popular in the React community.
Link to the specification:
Found by @cramforce
console.log.call.call.call.call.call.apply(a => a, [1, 2]);
Attention, it could break your mind! Try to reproduce this code in your head: we're applying the call
method using the apply
method. Read more:
- 19.2.3.3 Function.prototype.call(
thisArg
, ...args
) - **19.2.3.1 ** Function.prototype.apply(
thisArg
,argArray
)
const c = "constructor";
c[c][c]('console.log("WTF?")')(); // > WTF?
Let's consider this example step-by-step:
// Declare a new constant which is a string 'constructor'
const c = "constructor";
// c is a string
c; // -> 'constructor'
// Getting a constructor of string
c[c]; // -> [Function: String]
// Getting a constructor of constructor
c[c][c]; // -> [Function: Function]
// Call the Function constructor and pass
// the body of new function as an argument
c[c][c]('console.log("WTF?")'); // -> [Function: anonymous]
// And then call this anonymous function
// The result is console-logging a string 'WTF?'
c[c][c]('console.log("WTF?")')(); // > WTF?
An Object.prototype.constructor
returns a reference to the Object
constructor function that created the instance object. In case with strings it is String
, in case with numbers it is Number
and so on.
{ [{}]: {} } // -> { '[object Object]': {} }
Why does this work so? Here we're using a Computed property name. When you pass an object between those brackets, it coerces object to a string, so we get the property key '[object Object]'
and the value {}
.
We can make "brackets hell" like this:
({ [{}]: { [{}]: {} } }[{}][{}]); // -> {}
// structure:
// {
// '[object Object]': {
// '[object Object]': {}
// }
// }
Read more about object literals here:
As we know, primitives don't have prototypes. However, if we try to get a value of __proto__
for primitives, we would get this:
(1).__proto__.__proto__.__proto__; // -> null
This happens because when something doesn't have a prototype, it will be wrapped into a wrapper object using the ToObject
method. So, step-by-step:
(1)
.__proto__(
// -> [Number: 0]
1
)
.__proto__.__proto__(
// -> {}
1
).__proto__.__proto__.__proto__; // -> null
Here is more information about __proto__
:
What is the result of the expression below?
`${{ Object }}`;
The answer is:
// -> '[object Object]'
We defined an object with a property Object
using Shorthand property notation:
{
Object: Object;
}
Then we've passed this object to the template literal, so the toString
method calls for that object. That's why we get the string '[object Object]'
.
Consider this example:
let x,
{ x: y = 1 } = { x };
y;
The example above is a great task for an interview. What the value of y
? The answer is:
// -> 1
let x,
{ x: y = 1 } = { x };
y;
// β β β β
// 1 3 2 4
With the example above:
- We declare
x
with no value, so it'sundefined
. - Then we pack the value of
x
into the object propertyx
. - Then we extract the value of
x
using destructuring and want to assign it toy
. If the value is not defined, then we're going to use1
as the default value. - Return the value of
y
.
- Object initializer at MDN
Interesting examples could be composed with spreading of arrays. Consider this:
[...[..."..."]].length; // -> 3
Why 3
? When we use the spread operator, the @@iterator
method is called, and the returned iterator is used to obtain the values to be iterated. The default iterator for string spreads a string into characters. After spreading, we pack these characters into an array. Then we spread this array again and pack it back to an array.
A '...'
string consists with three .
characters, so the length of resulting array is 3
.
Now, step-by-step:
[...'...'] // -> [ '.', '.', '.' ]
[...[...'...']] // -> [ '.', '.', '.' ]
[...[...'...']].length // -> 3
Obviously, we can spread and wrap the elements of an array as many times as we want:
[...'...'] // -> [ '.', '.', '.' ]
[...[...'...']] // -> [ '.', '.', '.' ]
[...[...[...'...']]] // -> [ '.', '.', '.' ]
[...[...[...[...'...']]]] // -> [ '.', '.', '.' ]
// and so on β¦
Not many programmers know about labels in JavaScript. They are kind of interesting:
foo: {
console.log("first");
break foo;
console.log("second");
}
// > first
// -> undefined
The labeled statement is used with break
or continue
statements. You can use a label to identify a loop, and then use the break
or continue
statements to indicate whether a program should interrupt the loop or continue its execution.
In the example above, we identify a label foo
. After that console.log('first');
executes and then we interrupt the execution.
Read more about labels in JavaScript:
a: b: c: d: e: f: g: 1, 2, 3, 4, 5; // -> 5
Similar to previous examples, follow these links:
What will this expression return? 2
or 3
?
(() => {
try {
return 2;
} finally {
return 3;
}
})();
The answer is 3
. Surprised?
Take a look at the example below:
new class F extends (String, Array) {}(); // -> F []
Is this a multiple inheritance? Nope.
The interesting part is the value of the extends
clause ((String, Array)
). The grouping operator always returns its last argument, so (String, Array)
is actually just Array
. That means we've just created a class which extends Array
.
Consider this example of a generator which yields itself:
(function* f() {
yield f;
})().next();
// -> { value: [GeneratorFunction: f], done: false }
As you can see, the returned value is an object with its value
equal to f
. In that case, we can do something like this:
(function* f() {
yield f;
})()
.next()
.value()
.next()(
// -> { value: [GeneratorFunction: f], done: false }
// and again
function* f() {
yield f;
}
)()
.next()
.value()
.next()
.value()
.next()(
// -> { value: [GeneratorFunction: f], done: false }
// and again
function* f() {
yield f;
}
)()
.next()
.value()
.next()
.value()
.next()
.value()
.next();
// -> { value: [GeneratorFunction: f], done: false }
// and so on
// β¦
To understand why this works that way, read these sections of the specification:
Consider this obfuscated syntax playing:
typeof new class {
class() {}
}(); // -> 'object'
It seems like we're declaring a class inside of class. Should be an error, however, we get the string 'object'
.
Since ECMAScript 5 era, keywords are allowed as property names. So think about it as this simple object example:
const foo = {
class: function() {}
};
And ES6 standardized shorthand method definitions. Also, classes can be anonymous. So if we drop : function
part, we're going to get:
class {
class() {}
}
The result of a default class is always a simple object. And its typeof should return 'object'
.
Read more here:
With well-known symbols, there's a way to get rid of type coercion. Take a look:
function nonCoercible(val) {
if (val == null) {
throw TypeError("nonCoercible should not be called with null or undefined");
}
const res = Object(val);
res[Symbol.toPrimitive] = () => {
throw TypeError("Trying to coerce non-coercible object");
};
return res;
}
Now we can use this like this:
// objects
const foo = nonCoercible({ foo: "foo" });
foo * 10; // -> TypeError: Trying to coerce non-coercible object
foo + "evil"; // -> TypeError: Trying to coerce non-coercible object
// strings
const bar = nonCoercible("bar");
bar + "1"; // -> TypeError: Trying to coerce non-coercible object
bar.toString() + 1; // -> bar1
bar === "bar"; // -> false
bar.toString() === "bar"; // -> true
bar == "bar"; // -> TypeError: Trying to coerce non-coercible object
// numbers
const baz = nonCoercible(1);
baz == 1; // -> TypeError: Trying to coerce non-coercible object
baz === 1; // -> false
baz.valueOf() === 1; // -> true
Consider the example below:
let f = () => 10;
f(); // -> 10
Okay, fine, but what about this:
let f = () => {};
f(); // -> undefined
You might expect {}
instead of undefined
. This is because the curly braces are part of the syntax of the arrow functions, so f
will return undefined. It is however possible to return the {}
object directly from an arrow function, by enclosing the return value with brackets.
let f = () => ({});
f(); // -> {}
Consider the example below:
let f = function() {
this.a = 1;
};
new f(); // -> { 'a': 1 }
Now, try do to the same with an arrow function:
let f = () => {
this.a = 1;
};
new f(); // -> TypeError: f is not a constructor
Arrow functions cannot be used as constructors and will throw an error when used with new. Because has a lexical this
, and do not have a prototype
property, so it would not make much sense.
Consider the example below:
let f = function() {
return arguments;
};
f("a"); // -> { '0': 'a' }
Now, try do to the same with an arrow function:
let f = () => arguments;
f("a"); // -> Uncaught ReferenceError: arguments is not defined
Arrow functions are a lightweight version of regular functions with a focus on being short and lexical this
. At the same time arrow functions do not provide a binding for the arguments
object. As a valid alternative use the rest parameters
to achieve the same result:
let f = (...args) => args;
f("a");
- Arrow functions at MDN.
return
statement is also tricky. Consider this:
(function() {
return
{
b: 10;
}
})(); // -> undefined
return
and the returned expression must be in the same line:
(function() {
return {
b: 10
};
})(); // -> { b: 10 }
This is because of a concept called Automatic Semicolon Insertion, which automagically inserts semicolons after most newlines. In the first example, there is a semicolon inserted between the return
statement and the object literal, so the function returns undefined
and the object literal is never evaluated.
var foo = {n: 1};
var bar = foo;
foo.x = foo = {n: 2};
foo.x // -> undefined
foo // -> {n: 2}
bar // -> {n: 1, x: {n: 2}}
From right to left, {n: 2}
is assigned to foo, and the result of this assignment {n: 2}
is assigned to foo.x, that's why bar is {n: 1, x: {n: 2}}
as bar is a reference to foo. But why foo.x is undefined while bar.x is not ?
Foo and bar references the same object {n: 1}
, and lvalues are resolved before assignations. foo = {n: 2}
is creating a new object, and so foo is updated to reference that new object. The trick here is foo in foo.x = ...
as a lvalue was resolved beforehand and still reference the old foo = {n: 1}
object and update it by adding the x value. After that chain assignments, bar still reference the old foo object, but foo reference the new {n: 2}
object, where x is not existing.
It's equivalent to:
var foo = {n: 1};
var bar = foo;
foo = {n: 2} // -> {n: 2}
bar.x = foo // -> {n: 1, x: {n: 2}}
// bar.x point to the address of the new foo object
// it's not equivalent to: bar.x = {n: 2}
var obj = { property: 1 };
var array = ["property"];
obj[array]; // -> 1
What about pseudo-multidimensional arrays?
var map = {};
var x = 1;
var y = 2;
var z = 3;
map[[x, y, z]] = true;
map[[x + 10, y, z]] = true;
map["1,2,3"]; // -> true
map["11,2,3"]; // -> true
The brackets []
operator converts the passed expression using toString
. Converting a one-element array to a string is akin to converting the contained element to the string:
["property"].toString(); // -> 'property'
null > 0; // false
null == 0; // false
null >= 0; // true
Long story short, if null
is less than 0
is false
, then null >= 0
is true
. Read in-depth explanation for this here.
Number.toFixed()
can behave a bit strange in different browsers. Check out this example:
(0.7875).toFixed(3);
// Firefox: -> 0.787
// Chrome: -> 0.787
// IE11: -> 0.788
(0.7876).toFixed(3);
// Firefox: -> 0.788
// Chrome: -> 0.788
// IE11: -> 0.788
While your first instinct may be that IE11 is correct and Firefox/Chrome are wrong, the reality is that Firefox/Chrome are more directly obeying standards for numbers (IEEE-754 Floating Point), while IE11 is minutely disobeying them in (what is probably) an effort to give clearer results.
You can see why this occurs with a few quick tests:
// Confirm the odd result of rounding a 5 down
(0.7875).toFixed(3); // -> 0.787
// It looks like it's just a 5 when you expand to the
// limits of 64-bit (double-precision) float accuracy
(0.7875).toFixed(14); // -> 0.78750000000000
// But what if you go beyond the limit?
(0.7875).toFixed(20); // -> 0.78749999999999997780
Floating point numbers are not stored as a list of decimal digits internally, but through a more complicated methodology that produces tiny inaccuracies that are usually rounded away by toString and similar calls, but are actually present internally.
In this case, that "5" on the end was actually an extremely tiny fraction below a true 5. Rounding it at any reasonable length will render it as a 5... but it is actually not a 5 internally.
IE11, however, will report the value input with only zeros appended to the end even in the toFixed(20) case, as it seems to be forcibly rounding the value to reduce the troubles from hardware limits.
See for reference NOTE 2
on the ECMA-262 definition for toFixed
.
Math.min(1, 4, 7, 2); // -> 1
Math.max(1, 4, 7, 2); // -> 7
Math.min(); // -> Infinity
Math.max(); // -> -Infinity
Math.min() > Math.max(); // -> true
- Why is Math.max() less than Math.min()? by Charlie Harvey
The following expressions seem to introduce a contradiction:
null == 0; // -> false
null > 0; // -> false
null >= 0; // -> true
How can null
be neither equal to nor greater than 0
, if null >= 0
is actually true
? (This also works with less than in the same way.)
The way these three expressions are evaluated are all different and are responsible for producing this unexpected behavior.
First, the abstract equality comparison null == 0
. Normally, if this operator can't compare the values on either side properly, it converts both to numbers and compares the numbers. Then, you might expect the following behavior:
// This is not what happens
(null == 0 + null) == +0;
0 == 0;
true;
However, according to a close reading of the spec, the number conversion doesn't actually happen on a side that is null
or undefined
. Therefore, if you have null
on one side of the equal sign, the other side must be null
or undefined
for the expression to return true
. Since this is not the case, false
is returned.
Next, the relational comparison null > 0
. The algorithm here, unlike that of the abstract equality operator, will convert null
to a number. Therefore, we get this behavior:
null > 0
+null = +0
0 > 0
false
Finally, the relational comparison null >= 0
. You could argue that this expression should be the result of null > 0 || null == 0
; if this were the case, then the above results would mean that this would also be false
. However, the >=
operator in fact works in a very different way, which is basically to take the opposite of the <
operator. Because our example with the greater than operator above also holds for the less than operator, that means this expression is actually evaluated like so:
null >= 0;
!(null < 0);
!(+null < +0);
!(0 < 0);
!false;
true;
JS allows to redeclare variables:
a;
a;
// This is also valid
a, a;
Works also in strict mode:
var a, a, a;
var a;
var a;
All definitions are merged into one definition.
Imagine that you need to sort an array of numbers.
[ 10, 1, 3 ].sort() // -> [ 1, 10, 3 ]
The default sort order is built upon converting the elements into strings, then comparing their sequences of UTF-16 code units values.
Pass comparefn
if you try to sort anything but string.
[ 10, 1, 3 ].sort((a, b) => a - b) // -> [ 1, 3, 10 ]
- wtfjs.com β a collection of those very special irregularities, inconsistencies and just plain painfully unintuitive moments for the language of the web.
- Wat β A lightning talk by Gary Bernhardt from CodeMash 2012
- What the... JavaScript? β Kyle Simpsons talk for Forward 2 attempts to βpull out the crazyβ from JavaScript. He wants to help you produce cleaner, more elegant, more readable code, then inspire people to contribute to the open source community.
Β© Denys Dovhan