Exception Handling In JavaScript

The syntax of JavaScript is the set of rules that define a correctly structured JavaScript program.

The examples below make use of the log function of the console object present in most browsers for standard text output.

The JavaScript standard library lacks an official standard text output function (with the exception of document.write). Given that JavaScript is mainly used for client-side scripting within modern web browsers, and that almost all Web browsers provide the alert function, alert can also be used, but is not commonly used.

Origins

Brendan Eich summarized the ancestry of the syntax in the first paragraph of the JavaScript 1.1 specification as follows:

Basics

Case sensitivity

JavaScript is case sensitive. It is common to start the name of a constructor with a capitalised letter, and the name of a function or variable with a lower-case letter.

Example:

var a = 5;
console.log(a); // 5
console.log(A); // throws a ReferenceError: A is not defined

Whitespace and semicolons

Unlike in C, whitespace in JavaScript source can directly impact semantics. Semicolons end statements in JavaScript. Because of automatic semicolon insertion (ASI), some statements that are well formed when a newline is parsed will be considered complete, as if a semicolon were inserted just prior to the newline. Some authorities advise supplying statement-terminating semicolons explicitly, because it may lessen unintended effects of the automatic semicolon insertion.

There are two issues: five tokens can either begin a statement or be the extension of a complete statement; and five restricted productions, where line breaks are not allowed in certain positions, potentially yielding incorrect parsing.

The five problematic tokens are the open parenthesis "(", open bracket " /", plus "+", and minus "-". Of these, the open parenthesis is common in the /code>", slash "/", plus "+", and minus "-". Of these, the open parenthesis is common in the immediately-invoked function expression pattern, and open bracket occurs sometimes, while others are quite rare. An example:

a = b + c
(d + e).foo()

// Treated as:
// a = b + c(d + e).foo();

with the suggestion that the preceding statement be terminated with a semicolon.

Some suggest instead the use of ''leading'' semicolons on lines starting with '(' or '[', so the line is not accidentally joined with the previous one. This is known as a defensive semicolon, and is particularly recommended, because code may otherwise become ambiguous when it is rearranged. For example:

a = b + c
;(d + e).foo()

// Treated as:
// a = b + c;
// (d + e).foo();

Initial semicolons are also sometimes used at the start of JavaScript libraries, in case they are appended to another library that omits a trailing semicolon, as this can result in ambiguity of the initial statement.

The five restricted productions are return, throw, break, continue, and post-increment/decrement. In all cases, inserting semicolons does not fix the problem, but makes the parsed syntax clear, making the error easier to detect. return and throw take an optional value, while break and continue take an optional label. In all cases, the advice is to keep the value or label on the same line as the statement. This most often shows up in the return statement, where one might return a large object literal, which might be accidentally placed starting on a new line. For post-increment/decrement, there is potential ambiguity with pre-increment/decrement, and again it is recommended to simply keep these on the same line.

return
a + b;

// Returns undefined. Treated as:
// return;
// a + b;
// Should be written as:
// return a + b;

Comments

Comment (computer programming)">Comment syntax is the same as in C++, Swift (programming language), Swift and many other languages.

// a short, one-line comment

/* this is a long, multi-line comment
about my script. May it one day
be great. */

/* Comments /* may not be nested */ Syntax error */

Variables

Variables in standard JavaScript have no type attached, so any value (each ''value'' has a type) can be stored in any variable. Starting with ES6, the 6th version of the language, variables could be declared with var for function scoped variables, and let or const which are for block level variables. Before ES6, variables could only be declared with a var statement. Values assigned to variables declared with const cannot be changed, but its properties can. A variable's identifier must start with a letter, underscore (_), or dollar sign ($), while subsequent characters can also be digits (0-9). JavaScript is case sensitive, so the uppercase characters "A" through "Z" are different from the lowercase characters "a" through "z".

Starting with JavaScript 1.5, ISO 8859-1 or Unicode letters (or \uXXXX Unicode escape sequences) can be used in identifiers. In certain JavaScript implementations, the at sign (@) can be used in an identifier, but this is contrary to the specifications and not supported in newer implementations.

Scoping and hoisting

Variables declared with var are lexically scoped at a function level, while ones with let or const have a block level scope. Since declarations are processed before any code is executed, a variable can be assigned to and used prior to being declared in the code. This is referred to as ', and it is equivalent to variables being forward declared at the top of the function or block.

With var, let, and const statements, only the declaration is hoisted; assignments are not hoisted. Thus a statement in the middle of the function is equivalent to a declaration statement at the top of the function, and an assignment statement at that point in the middle of the function. This means that values cannot be accessed before they are declared; forward reference is not possible. With var a variable's value is undefined until it is initialized. Variables declared with let or const cannot be accessed until they have been initialized, so referencing such variables before will cause an error.

Function declarations, which declare a variable and assign a function to it, are similar to variable statements, but in addition to hoisting the declaration, they also hoist the assignment – as if the entire statement appeared at the top of the containing function – and thus forward reference is also possible: the location of a function statement within an enclosing function is irrelevant. This is different from a function expression being assigned to a variable in a var, let, or const statement.

So, for example,

var func = function() // declaration is hoisted only
function func() // declaration and assignment are hoisted

Block scoping can be produced by wrapping the entire block in a function and then executing it – this is known as the immediately-invoked function expression pattern – or by declaring the variable using the let keyword.

Declaration and assignment

Variables declared outside a scope are global. If a variable is declared in a higher scope, it can be accessed by child scopes.

When JavaScript tries to resolve an identifier, it looks in the local scope. If this identifier is not found, it looks in the next outer scope, and so on along the ''scope chain'' until it reaches the ''global scope'' where global variables reside. If it is still not found, JavaScript will raise a ReferenceError exception.

When assigning an identifier, JavaScript goes through exactly the same process to retrieve this identifier, except that if it is not found in the ''global scope'', it will create the "variable" in the scope where it was created. As a consequence, a variable never declared will be global, if assigned. Declaring a variable (with the keyword var) in the ''global scope'' (i.e. outside of any function body (or block in the case of let/const)), assigning a never declared identifier or adding a property to the ''global object'' (usually ''window'') will also create a new global variable.

Note that JavaScript's ''strict mode'' forbids the assignment of an undeclared variable, which avoids global namespace pollution.

Examples

Here are some examples of variable declarations and scope:

var x1 = 0; // A global variable, because it is not in any function
let x2 = 0; // Also global, this time because it is not in any block

function f()

f();

console.log(z); // This line will raise a ReferenceError exception, because the value of z is no longer available

for (let i = 0; i < 10; i++) console.log(i);
console.log(i); // throws a ReferenceError: i is not defined

for (const i = 0; i < 10; i++) console.log(i); // throws a TypeError: Assignment to constant variable

for (const i of ,2,3 console.log(i); //will not raise an exception. i is not reassigned but recreated in every iteration

const pi; // throws a SyntaxError: Missing initializer in const declaration

Primitive data types

The JavaScript language provides six primitive data types:

* Undefined
* Number
* BigInt
* String
* Boolean
* Symbol

Some of the primitive data types also provide a set of named values that represent the extents of the type boundaries. These named values are described within the appropriate sections below.

Undefined

The value of "undefined" is assigned to all uninitialized variables, and is also returned when checking for object properties that do not exist. In a Boolean context, the undefined value is considered a false value.

Note: undefined is considered a genuine primitive type. Unless explicitly converted, the undefined value may behave unexpectedly in comparison to other types that evaluate to false in a logical context.

var test; // variable declared, but not defined, ...
// ... set to value of undefined
var testObj = ;
console.log(test); // test variable exists, but value not ...
// ... defined, displays undefined
console.log(testObj.myProp); // testObj exists, property does not, ...
// ... displays undefined
console.log(undefined

null); // unenforced type during check, displays true
console.log(undefined

null); // enforce type during check, displays false

Note: There is no built-in language literal for undefined. Thus is not a foolproof way to check whether a variable is undefined, because in versions before ECMAScript 5, it is legal for someone to write . A more robust approach is to compare using .

Functions like this won't work as expected:

function isUndefined(x) // like this...
function isUndefined(x) // ... or that second one
function isUndefined(x) // ... or that third one

Here, calling isUndefined(my_var) raises a if is an unknown identifier, whereas doesn't.

Number

Numbers are represented in binary as IEEE-754 floating point doubles. Although this format provides an accuracy of nearly 16 significant digits, it cannot always exactly represent real numbers, including fractions.

This becomes an issue when comparing or formatting numbers. For example:

console.log(0.2 + 0.1

0.3); // displays false
console.log(0.94 - 0.01); // displays 0.9299999999999999

As a result, a routine such as the method should be used to round numbers whenever they ar
formatted for output

Numbers may be specified in any of these notations:

345; // an "integer", although there is only one numeric type in JavaScript
34.5; // a floating-point number
3.45e2; // another floating-point, equivalent to 345
0b1011; // a binary integer equal to 11
0o377; // an octal integer equal to 255
0xFF; // a hexadecimal integer equal to 255, digits represented by the ...
// ... letters A-F may be upper or lowercase

There's also a numeric separator, (the underscore), introduced in ES2021:

// Note: Wikipedia syntax doesn't support numeric separators yet
1_000_000_000; // Used with big numbers
1_000_000.5; // Support with decimals
1_000e1_000; // Support with exponents

// Support with binary, octals and hex
0b0000_0000_0101_1011;
0o0001_3520_0237_1327;
0xFFFF_FFFF_FFFF_FFFE;

// But you can't use them next to a non-digit number part, or at the start or end
_12; // Variable is not defined (the underscore makes it a variable identifier)
12_; // Syntax error (cannot be at the end of numbers)
12_.0; // Syntax error (doesn't make sense to put a separator next to the decimal point)
12._0; // Syntax error
12e_6; // Syntax error (next to "e", a non-digit. Doesn't make sense to put a separator at the start)
1000____0000; // Syntax error (next to "_", a non-digit. Only 1 separator at a time is allowed

The extents +∞, −∞ and NaN (Not a Number) of the number type may be obtained by two program expressions:

Infinity; // positive infinity (negative obtained with -Infinity for instance)
NaN; // The Not-A-Number value, also returned as a failure in ...
// ... string-to-number conversions

Infinity and NaN are numbers:

typeof Infinity; // returns "number"
typeof NaN; // returns "number"

These three special values correspond and behave as the IEEE-754 describes them.

The Number constructor (used as a function), or a unary + or -, may be used to perform explicit numeric conversion:

var myString = "123.456";
var myNumber1 = Number(myString);
var myNumber2 = +myString;

When used as a constructor, a numeric ''wrapper'' object is created (though it is of little use):

myNumericWrapper = new Number(123.456);

However, NaN is not equal to itself:

const nan = NaN;
console.log(NaN

NaN); // false
console.log(NaN

NaN); // false
console.log(NaN !

NaN); // true
console.log(nan !

nan); // true

// You can use the isNaN methods to check for NaN
console.log(isNaN("converted to NaN")); // true
console.log(isNaN(NaN)); // true
console.log(Number.isNaN("not converted")); // false
console.log(Number.isNaN(NaN)); // true

BigInt

BigInts can be used for arbitrarily large integers. Especially whole numbers larger than 2⁵³ - 1, which is the largest number JavaScript can reliably represent with the Number primitive and represented by the Number.MAX_SAFE_INTEGER constant.

When dividing BigInts, the results are truncated.

String

A string in JavaScript is a sequence of characters. In JavaScript, strings can be created directly (as literals) by placing the series of characters between double (") or single (') quotes. Such strings must be written on a single line, but may include escaped newline characters (such as \n). The JavaScript standard allows the backquote character (`, a.k.a. grave accent or backtick) to quote multiline literal strings, but this is supported only on certain browsers as of 2016: Firefox and Chrome, but not Internet Explorer 11.

var greeting = "Hello, World!";
var anotherGreeting = 'Greetings, people of Earth.';

Individual characters within a string can be accessed using the method (provided by ). This is the preferred way when accessing individual characters within a string, because it also works in non-modern browsers:

var h = greeting.charAt(0);

In modern browsers, individual characters within a string can be accessed (as strings with only a single character) through the same notation as arrays:

var h = greeting

However, JavaScript strings are immutable:

greeting = "H"; // Fails.

Applying the equality operator ("

") to two strings returns true, if the strings have the same contents, which means: of the same length and containing the same sequence of characters (case is significant for alphabets). Thus:

var x = "World";
var compare1 = ("Hello, " +x

"Hello, World"); // Here compare1 contains true.
var compare2 = ("Hello, " +x

"hello, World"); // Here compare2 contains ...
// ... false since the ...
// ... first characters ...
// ... of both operands ...
// ... are not of the same case.

Quotes of the same type cannot be nested unless they are escaped.

var x = '"Hello, World!" he said.'; // Just fine.
var x = ""Hello, World!" he said."; // Not good.
var x = "\"Hello, World!\" he said."; // Works by escaping " with \"

The constructor creates a string object (an object wrapping a string):

var greeting = new String("Hello, World!");

These objects have a method returning the primitive string wrapped within them:

var s = new String("Hello !");
typeof s; // Is 'object'.
typeof s.valueOf(); // Is 'string'.

Equality between two objects does not behave as with string primitives:

var s1 = new String("Hello !");
var s2 = new String("Hello !");
s1

s2; // Is false, because they are two distinct objects.
s1.valueOf()

s2.valueOf(); // Is true.

Boolean

JavaScript provides a Boolean data type with and literals. The operator returns the string for these primitive types. When used in a logical context, , , , , , and the empty string () evaluate as due to automatic type conversion. All other values (the complement of the previous list) evaluate as , including the strings , and any object.

Type conversion

Automatic type coercion by the equality comparison operators (

and !=) can be avoided by using the type checked comparison operators (

and !

).

When type conversion is required, JavaScript converts , , , or operands as follows:
;: The string is converted to a number value. JavaScript attempts to convert the string numeric literal to a Number type value. First, a mathematical value is derived from the string numeric literal. Next, this value is rounded to nearest Number type value.
;: If one of the operands is a Boolean, the Boolean operand is converted to 1 if it is , or to 0 if it is .
;: If an object is compared with a number or string, JavaScript attempts to return the default value for the object. An object is converted to a primitive String or Number value, using the or methods of the object. If this fails, a runtime error is generated.

Douglas Crockford advocates the terms "truthy" and "falsy" to describe how values of various types behave when evaluated in a logical context, especially in regard to edge cases.
The binary logical operators returned a Boolean value in early versions of JavaScript, but now they return one of the operands instead. The left–operand is returned, if it can be evaluated as : , in the case of conjunction: (a && b), or , in the case of disjunction: (a , , b); otherwise the right–operand is returned. Automatic type coercion by the comparison operators may differ for cases of mixed Boolean and number-compatible operands (including strings that can be evaluated as a number, or objects that can be evaluated as such a string), because the Boolean operand will be compared as a numeric value. This may be unexpected. An expression can be explicitly cast to a Boolean primitive by doubling the logical negation operator: (), using the function, or using the conditional operator: (c ? t : f).

// Automatic type coercion
console.log(true

2 ); // false... true → 1 !

2 ← 2
console.log(false

2 ); // false... false → 0 !

2 ← 2
console.log(true

1 ); // true.... true → 1

1 ← 1
console.log(false

0 ); // true.... false → 0

0 ← 0
console.log(true

"2"); // false... true → 1 !

2 ← "2"
console.log(false

"2"); // false... false → 0 !

2 ← "2"
console.log(true

"1"); // true.... true → 1

1 ← "1"
console.log(false

"0"); // true.... false → 0

0 ← "0"
console.log(false

"" ); // true.... false → 0

0 ← ""
console.log(false

NaN); // false... false → 0 !

NaN

console.log(NaN

NaN); // false...... NaN is not equivalent to anything, including NaN.

// Type checked comparison (no conversion of types and values)
console.log(true

1); // false...... data types do not match

// Explicit type coercion
console.log(true

!!2); // true.... data types and values match
console.log(true

!!0); // false... data types match, but values differ
console.log( 1 ? true : false); // true.... only ±0 and NaN are "falsy" numbers
console.log("0" ? true : false); // true.... only the empty string is "falsy"
console.log(Boolean()); // true.... all objects are "truthy"

The new operator can be used to create an object wrapper for a Boolean primitive. However, the operator does not return for the object wrapper, it returns . Because all objects evaluate as , a method such as , or , must be used to retrieve the wrapped value. For explicit coercion to the Boolean type, Mozilla recommends that the function (without ) be used in preference to the Boolean object.

var b = new Boolean(false); // Object false
var t = Boolean(b); // Boolean true
var f = Boolean(b.valueOf()); // Boolean false
var n = new Boolean(b); // Not recommended
n = new Boolean(b.valueOf()); // Preferred

if (0 , , -0 , , "" , , null , , undefined , , b.valueOf() , , !new Boolean() , , !t) else if ([] && && b && typeof b

"object" && b.toString()

"false")

Symbol

New in ECMAScript6. A ''Symbol'' is a unique and immutable identifier.

Example:

var x = Symbol(1);
var y = Symbol(1);
x

y; // => false

var symbolObject = ;
var normalObject = ;

// since x and y are unique,
// they can be used as unique keys in an object
symbolObject = 1;
symbolObject = 2;

symbolObject // => 1
symbolObject // => 2

// as compared to normal numeric keys
normalObject = 1;
normalObject = 2; // overrides the value of 1

normalObject // => 2

// changing the value of x does not change the key stored in the object
x = Symbol(3);
symbolObject // => undefined

// changing x back just creates another unique Symbol
x = Symbol(1);
symbolObject // => undefined

There are also ''well known symbols''.

One of which is Symbol.iterator; if something implements Symbol.iterator, it's iterable:

let x = , 2, 3, 4 // x is an Array
x ymbol.iterator

Array.prototype ymbol.iterator // and Arrays are iterable

const xIterator = x ymbol.iterator); // The ymbol.iteratorfunction should provide an iterator for x
xIterator.next(); //
xIterator.next(); //
xIterator.next(); //
xIterator.next(); //
xIterator.next(); //
xIterator.next(); //

// for..of loops automatically iterate values
for (const value of x)

// Sets are also iterable:
ymbol.iteratorin Set.prototype; // true

for (const value of new Set( apple', 'orange')

Native objects

The JavaScript language provides a handful of native objects. JavaScript native objects are considered part of the JavaScript specification. JavaScript environment notwithstanding, this set of objects should always be available.

Array

An Array is a JavaScript object prototyped from the Array constructor specifically designed to store data values indexed by integer keys. Arrays, unlike the basic Object type, are prototyped with methods and properties to aid the programmer in routine tasks (for example, join, slice, and push).

As in the C family, arrays use a zero-based indexing scheme: A value that is inserted into an empty array by means of the push method occupies the 0th index of the array.

var myArray = []; // Point the variable myArray to a newly ...
// ... created, empty Array
myArray.push("hello World"); // Fill the next empty index, in this case 0
console.log(myArray ; // Equivalent to console.log("hello World");

Arrays have a length property that is guaranteed to always be larger than the largest integer index used in the array. It is automatically updated, if one creates a property with an even larger index. Writing a smaller number to the length property will remove larger indices.

Elements of Arrays may be accessed using normal object property access notation:

myArray // the 2nd item in myArray
myArray 1"

The above two are equivalent. It's not possible to use the "dot"-notation or strings with alternative representations of the number:

myArray.1; // syntax error
myArray 01" // not the same as myArray

Declaration of an array can use either an Array literal or the Array constructor:

let myArray;

// Array literals
myArray = , 2 // length of 2
myArray = , 2, // same array - You can also have an extra comma at the end

// It's also possible to not fill in parts of the array
myArray = , 1, /* hole */, /* hole */, 4, 5 // length of 6
myArray = , 1, /* hole */, /* hole */, 4, 5, // same array
myArray = , 1, /* hole */, /* hole */, 4, 5, /* hole */, // length of 7

// With the constructor
myArray = new Array(0, 1, 2, 3, 4, 5); // length of 6
myArray = new Array(365); // an empty array with length 365

Arrays are implemented so that only the defined elements use memory; they are "sparse arrays". Setting and only uses space for these two elements, just like any other object. The length of the array will still be reported as 58. The maximum length of an array is 4,294,967,295 which corresponds to 32-bit binary number (11111111111111111111111111111111)₂.

One can use the object declaration literal to create objects that behave much like associative arrays in other languages:

dog = ;
dog color" // results in "brown"
dog.color; // also results in "brown"

One can use the object and array declaration literals to quickly create arrays that are associative, multidimensional, or both. (Technically, JavaScript does not support multidimensional arrays, but one can mimic them with arrays-of-arrays.)

cats =

cats "size"]; // results in "large"

dogs = ;
dogs spot""size"]; // results in "small"
dogs.rover.color; // results in "brown"

Date

A Date object stores a signed millisecond count with zero representing 1970-01-01 00:00:00 UT and a range of ±10⁸ days. There are several ways of providing arguments to the Date constructor. Note that months are zero-based.

new Date(); // create a new Date instance representing the current time/date.
new Date(2010, 2, 1); // create a new Date instance representing 2010-Mar-01 00:00:00
new Date(2010, 2, 1, 14, 25, 30); // create a new Date instance representing 2010-Mar-01 14:25:30
new Date("2010-3-1 14:25:30"); // create a new Date instance from a String.

Methods to extract fields are provided, as well as a useful toString:

var d = new Date(2010, 2, 1, 14, 25, 30); // 2010-Mar-01 14:25:30;

// Displays '2010-3-1 14:25:30':
console.log(d.getFullYear() + '-' + (d.getMonth() + 1) + '-' + d.getDate() + ' '
+ d.getHours() + ':' + d.getMinutes() + ':' + d.getSeconds());

// Built-in toString returns something like 'Mon Mar 01 2010 14:25:30 GMT-0500 (EST)':
console.log(d);

Error

Custom error messages can be created using the Error class:

throw new Error("Something went wrong.");

These can be caught by try...catch...finally blocks as described in the section on #Exception_handling, exception handling.

Math

The object contains various math-related constants (for example, ) and functions (for example, cosine). (Note that the object has no constructor, unlike or . All its methods are "static", that is "class" methods.) All the trigonometric functions use angles expressed in radians, not degrees or grads.

Regular expression

/expression/.test(string); // returns Boolean
"string".search(/expression/); // returns position Number
"string".replace(/expression/, replacement);

// Here are some examples
if (/Tom/.test("My name is Tom")) console.log("Hello Tom!");
console.log("My name is Tom".search(/Tom/)); //

11 (letters before Tom)
console.log("My name is Tom".replace(/Tom/, "John")); //

"My name is John"

Character classes

// \d - digit
// \D - non digit
// \s - space
// \S - non space
// \w - word char
// \W - non word
// - one of
// - one not of
// - - range

if (/\d/.test('0')) console.log('Digit');
if (/ -9.test('6')) console.log('Digit');
if (/ 3579.test('1')) console.log('Odd number');
if (/\S\S\s\S\S\S\S/.test('My name')) console.log('Format OK');
if (/\w\w\w/.test('Tom')) console.log('Hello Tom');
if (/ -zA-Z.test('B')) console.log('Letter');

Character matching

// A...Z a...z 0...9 - alphanumeric
// \u0000...\uFFFF - Unicode hexadecimal
// \x00...\xFF - ASCII hexadecimal
// \t - tab
// \n - new line
// \r - CR
// . - any character
// , - OR

if (/T.m/.test('Tom')) console.log ('Hi Tom, Tam or Tim');
if (/A, B/.test("A")) console.log ('A or B');

Repeaters

// ? - 0 or 1 match
// * - 0 or more
// + - 1 or more
// - exactly n
// - n or more
// - n or less
// - range n to m

if (/ab?c/.test("ac")) console.log("OK"); // match: "ac", "abc"
if (/ab*c/.test("ac")) console.log("OK"); // match: "ac", "abc", "abbc", "abbbc" etc.
if (/ab+c/.test("abc")) console.log("OK"); // match: "abc", "abbc", "abbbc" etc.
if (/abc/.test("abbbc")) console.log("OK"); // match: "abbbc"
if (/abc/.test("abbbc")) console.log("OK"); // match: "abbbc", "abbbbc", "abbbbbc" etc.
if (/abc/.test("abc")) console.log("OK"); // match: "abc", "abbc", "abbbc"

Anchors

// ^ - string starts with
// $ - string ends with

if (/^My/.test("My name is Tom")) console.log ("Hi!");
if (/Tom$/.test("My name is Tom")) console.log ("Hi Tom!");

Subexpression

// ( ) - groups characters

if (/water(mark)?/.test("watermark")) console.log("Here is water!"); // match: "water", "watermark",
if (/(Tom), (John)/.test("John")) console.log("Hi Tom or John!");

Flags

// /g - global
// /i - ignore upper/lower case
// /m - allow matches to span multiple lines

console.log("hi tom!".replace(/Tom/i, "John")); //

"hi John!"
console.log("ratatam".replace(/ta/, "tu")); //

"ratutam"
console.log("ratatam".replace(/ta/g, "tu")); //

"ratutum"

Advanced methods

my_array = my_string.split(my_delimiter);
// example
my_array = "dog,cat,cow".split(","); // my_array

dog","cat","cow"

my_array = my_string.match(my_expression);
// example
my_array = "We start at 11:30, 12:15 and 16:45".match(/\d\d:\d\d/g); // my_array

11:30","12:15","16:45"

Capturing groups

var myRe = /(\d-\d-\d) (\d:\d:\d)/;
var results = myRe.exec("The date and time are 2009-09-08 09:37:08.");
if (results) else console.log("Did not find a valid date!");

Function

Every function in JavaScript is an instance of the Function constructor:

// x, y is the argument. 'return x + y' is the function body, which is the last in the argument list.
var add = new Function('x', 'y', 'return x + y');
add(1, 2); // => 3

The add function above may also be defined using a function expression:

var add = function(x, y) ;
add(1, 2); // => 3

In ES6, arrow function syntax was added, allowing functions that return a value to be more concise. They also retain the this of the global object instead of inheriting it from where it was called / what it was called on, unlike the function() expression.

var add = (x, y) => ;
// values can also be implicitly returned (i.e. no return statement is needed)
var addImplicit = (x, y) => x + y;

add(1, 2); // => 3
addImplicit(1, 2) // => 3

For functions that need to be hoisted, there is a separate expression:

function add(x, y)
add(1, 2); // => 3

Hoisting allows you to use the function before it is "declared":

add(1, 2); // => 3, not a ReferenceError
function add(x, y)

A function instance has properties and methods.

function subtract(x, y)

console.log(subtract.length); // => 2, arity of the function (number of arguments)
console.log(subtract.toString());

/*
"function subtract(x, y) "
*/

Operators

The '+' operator is overloaded: it is used for string concatenation and arithmetic addition. This may cause problems when inadvertently mixing strings and numbers. As a unary operator, it can convert a numeric string to a number.

// Concatenate 2 strings
console.log('He' + 'llo'); // displays Hello

// Add two numbers
console.log(2 + 6); // displays 8

// Adding a number and a string results in concatenation (from left to right)
console.log(2 + '2'); // displays 22
console.log('$' + 3 + 4); // displays $34, but $7 may have been expected
console.log('$' + (3 + 4)); // displays $7
console.log(3 + 4 + '7'); // displays 77, numbers stay numbers until a string is added

// Convert a string to a number using the unary plus
console.log(+'2'

2); // displays true
console.log(+'Hello'); // displays NaN

Similarly, the '*' operator is overloaded: it can convert a string into a number.

console.log(2 + '6'*1); // displays 8
console.log(3*'7'); // 21
console.log('3'*'7'); // 21
console.log('hello'*'world'); // displays NaN

Arithmetic

JavaScript supports the following binary arithmetic operators:

JavaScript supports the following unary arithmetic operators:

var x = 1;
console.log(++x); // x becomes 2; displays 2
console.log(x++); // displays 2; x becomes 3
console.log(x); // x is 3; displays 3
console.log(x--); // displays 3; x becomes 2
console.log(x); // displays 2; x is 2
console.log(--x); // x becomes 1; displays 1

The modulo operator displays the remainder after division by the modulus. If negative numbers are involved, the returned value depends on the operand.

var x = 17;
console.log(x%5); // displays 2
console.log(x%6); // displays 5
console.log(-x%5); // displays -2
console.log(-x%-5); // displays -2
console.log(x%-5); // displays 2

To always return a non-negative number, re-add the modulus and apply the modulo operator again:

var x = 17;
console.log((-x%5+5)%5); // displays 3

You could also do:

var x = 17;
console.log(Math.abs(-x%5)); // also 3

Assignment

Assignment of primitive types

var x = 9;
x += 1;
console.log(x); // displays: 10
x *= 30;
console.log(x); // displays: 300
x /= 6;
console.log(x); // displays: 50
x -= 3;
console.log(x); // displays: 47
x %= 7;
console.log(x); // displays: 5

Assignment of object types

/**
* To learn JavaScript objects...
*/
var object_1 = ; // assign reference of newly created object to object_1
var object_2 = ;
var object_3 = object_2; // object_3 references the same object as object_2 does

object_3.a = 2;
message(); // displays 1 2 2

object_2 = object_1; // object_2 now references the same object as object_1
// object_3 still references what object_2 referenced before
message(); // displays 1 1 2

object_2.a = 7; // modifies object_1
message(); // displays 7 7 2

object_3.a = 5; // object_3 doesn't change object_2
message(); // displays 7 7 5

object_3 = object_2;
object_3.a=4; // object_3 changes object_1 and object_2
message(); // displays 4 4 4

/**
* Prints the console.log message
*/
function message()

Destructuring assignment

In Mozilla's JavaScript, since version 1.7, destructuring assignment allows the assignment of parts of data structures to several variables at once. The left hand side of an assignment is a pattern that resembles an arbitrarily nested object/array literal containing l-lvalues at its leaves that are to receive the substructures of the assigned value.

var a, b, c, d, e;
, b, c= , 4, 5
console.log(a + ',' + b + ',' + c); // displays: 3,4,5
e = ;
var arr = [];
() = e;
console.log(a + ',' + b + ',' + arr); // displays: 5,6,Baz,,,Content
[a, b] = [b, a]; // swap contents of a and b
console.log(a + ',' + b); // displays: 6,5

, b, c= , 4, 5 // permutations
, b, c= , c, a
console.log(a + ',' + b + ',' + c); // displays: 4,5,3

Spread/rest operator

The ECMAScript 2015 standard introduces the "..." operator, for the related concepts of "spread syntax" and "rest parameters"

Spread syntax provides another way to destructure arrays. It indicates that the elements in a specified array should be used as the parameters in a function call or the items in an array literal.

In other words, "..." transforms " ..foo/code>" into " oo[0 foo[1">.html" ;"title="oo[0">oo[0 foo[1 foo[2">">oo[0<_a>_foo[1.html" ;"title=".html" ;"title="oo[0">oo[0 foo[1">.html" ;"title="oo[0">oo[0 foo[1 foo[2", and "this.bar(...foo);" into "this.bar(foo foo foo[2]);".


var a = , 2, 3, 4

// It can be used multiple times in the same expression
var b = ..a, ...a // b = , 2, 3, 4, 1, 2, 3, 4

// It can be combined with non-spread items.
var c = , 6, ...a, 7, 9 // c = , 6, 1, 2, 3, 4, 7, 9

// For comparison, doing this without the spread operator
// creates a nested array.
var d = , a // d = 1, 2, 3, 4 , 2, 3, 4

// It works the same with function calls
function foo(arg1, arg2, arg3)

// You can use it even if it passes more parameters than the function will use
foo(...a); // "1:2:3" → foo(a a a a ;

// You can mix it with non-spread parameters
foo(5, ...a, 6); // "5:1:2" → foo(5, a a a a 6);

// For comparison, doing this without the spread operator
// assigns the array to arg1, and nothing to the other parameters.
foo(a); // "1,2,3,4:undefined:undefined"


When ... is used in a function ''declaration'', it indicates a rest parameter. The rest parameter must be the final named parameter in the function's parameter list. It will be assigned an Array containing any arguments passed to the function in excess of the other named parameters. In other words, it gets "the rest" of the arguments passed to the function (hence the name).


function foo(a, b, ...c)

foo(1, 2, 3, 4, 5); // "3" → c = , 4, 5foo('a', 'b'); // "0" → c = []


Rest parameters are similar to Javascript's arguments object, which is an array-like object that contains all of the parameters (named and unnamed) in the current function call. Unlike arguments, however, rest parameters are true Array objects, so methods such as .slice() and .sort() can be used on them directly.

The ... operator can only be used with Array objects. (However, there is a proposal to extend it to Objects in a future ECMAScript standard.)


Comparison

Variables referencing objects are equal or identical only if they reference the same object:


var obj1 = ;
var obj2 = ;
var obj3 = obj1;
console.log(obj1

obj2); //false
console.log(obj3

obj1); //true
console.log(obj3

obj1); //true

See also String.


Logical

JavaScript provides four logical operators:
* unary negation (NOT = !a)
* binary disjunction (OR = a , , b) and conjunction (AND = a && b)
* ternary conditional (c ? t : f)

In the context of a logical operation, any expression evaluates to true except the following:
* Strings: "", '',
* Numbers: 0, -0, NaN,
* Special: null, undefined,
* Boolean: false.

The Boolean function can be used to explicitly convert to a primitive of type Boolean:

// Only empty strings return false
console.log(Boolean("")

false);
console.log(Boolean("false")

true);
console.log(Boolean("0")

true);

// Only zero and NaN return false
console.log(Boolean(NaN)

false);
console.log(Boolean(0)

false);
console.log(Boolean(-0)

false); // equivalent to -1*0
console.log(Boolean(-2)

true);

// All objects return true
console.log(Boolean(this)

true);
console.log(Boolean()

true);
console.log(Boolean([])

true);

// These types return false
console.log(Boolean(null)

false);
console.log(Boolean(undefined)

false); // equivalent to Boolean()

The NOT operator evaluates its operand as a Boolean and returns the negation. Using the operator twice in a row, as a double negative, explicitly converts an expression to a primitive of type Boolean:


console.log( !0

Boolean(!0));
console.log(Boolean(!0)

!!1);
console.log(!!1

Boolean(1));
console.log(!!0

Boolean(0));
console.log(Boolean(0)

!1);
console.log(!1

Boolean(!1));
console.log(!""

Boolean(!""));
console.log(Boolean(!"")

!!"s");
console.log(!!"s"

Boolean("s"));
console.log(!!""

Boolean(""));
console.log(Boolean("")

!"s");
console.log(!"s"

Boolean(!"s"));

The ternary operator can also be used for explicit conversion:


console.log([]

false); console.log([] ? true : false); // “truthy”, but the comparison uses [].toString()
console.log(

false); console.log( true : false); // toString()

"0"
console.log("0"

false); console.log("0"? true : false); // "0" → 0 ... (0

0) ... 0 ← false
console.log(

true); console.log( true : false); // toString()

"1"
console.log("1"

true); console.log("1"? true : false); // "1" → 1 ... (1

1) ... 1 ← true
console.log( != true); console.log( true : false); // toString()

"2"
console.log("2" != true); console.log("2"? true : false); // "2" → 2 ... (2 != 1) ... 1 ← true

Expressions that use features such as post–incrementation (i++) have an anticipated side effect. JavaScript provides short-circuit evaluation of expressions; the right operand is only executed if the left operand does not suffice to determine the value of the expression.


console.log(a , , b); // When a is true, there is no reason to evaluate b.
console.log(a && b); // When a is false, there is no reason to evaluate b.
console.log(c ? t : f); // When c is true, there is no reason to evaluate f.


In early versions of JavaScript and JScript, the binary logical operators returned a Boolean value (like most C-derived programming languages). However, all contemporary implementations return one of their operands instead:


console.log(a , , b); // if a is true, return a, otherwise return b
console.log(a && b); // if a is false, return a, otherwise return b


Programmers who are more familiar with the behavior in C might find this feature surprising, but it allows for a more concise expression of patterns like null coalescing:


var s = t , , "(default)"; // assigns t, or the default value, if t is null, empty, etc.



Logical assignment

Bitwise

JavaScript supports the following binary bitwise operators:

Examples:


x=11 & 6;
console.log(x); // 2


JavaScript supports the following unary bitwise operator:

Bitwise Assignment

JavaScript supports the following binary assignment operators:

Examples:


x=7;
console.log(x); // 7
x<<=3;
console.log(x); // 7->14->28->56



String

Examples:


str = "ab" + "cd"; // "abcd"
str += "e"; // "abcde"

str2 = "2" + 2; // "22", not "4" or 4.



??

Control structures

Compound statements

A pair of curly brackets and an enclosed sequence of statements constitute a compound statement, which can be used wherever a statement can be used.

If ... else

if (expr) else if (expr2) else

Conditional (ternary) operator

The conditional operator creates an expression that evaluates as one of two expressions depending on a condition. This is similar to the ''if'' statement that selects one of two statements to execute depending on a condition. I.e., the conditional operator is to expressions what ''if'' is to statements.

result = condition ? expression : alternative;

is the same as:

if (condition) else

Unlike the ''if'' statement, the conditional operator cannot omit its "else-branch".

Switch statement

The syntax of the JavaScript switch statement is as follows:

switch (expr)

* break; is optional; however, it is usually needed, since otherwise code execution will continue to the body of the next case block. This ''fall through'' behavior can be used when the same set of statements apply in several cases, effectively creating a disjunction between those cases.
* Add a break statement to the end of the last case as a precautionary measure, in case additional cases are added later.
* String literal values can also be used for the case values.
* Expressions can be used instead of values.
* The default case (optional) is executed when the expression does not match any other specified cases.
* Braces are required.

For loop

The syntax of the JavaScript for loop is as follows:

for (initial; condition; loop statement)

or

for (initial; condition; loop statement(iteration)) // one statement

For ... in loop

The syntax of the JavaScript for ... in loop is as follows:

for (var property_name in some_object)

* Iterates through all enumerable properties of an object.
* Iterates through all used indices of array including all user-defined properties of array object, if any. Thus it may be better to use a traditional for loop with a numeric index when iterating over arrays.
* There are differences between the various Web browsers with regard to which properties will be reflected with the for...in loop statement. In theory, this is controlled by an internal state property defined by the ECMAscript standard called "DontEnum", but in practice, each browser returns a slightly different set of properties during introspection. It is useful to test for a given property using . Thus, adding a method to the array prototype with may cause for ... in loops to loop over the method's name.

While loop

The syntax of the JavaScript while loop is as follows:

while (condition)

Do ... while loop

The syntax of the JavaScript do ... while loop is as follows:

do while (condition);

With

The with statement adds all of the given object's properties and methods into the following block's scope, letting them be referenced as if they were local variables.

with (document) ;

* Note the absence of before each invocation.

The semantics are similar to the with statement of Pascal.

Because the availability of with statements hinders program performance and is believed to reduce code clarity (since any given variable could actually be a property from an enclosing ), this statement is not allowed in ''strict mode''.

Labels

JavaScript supports nested labels in most implementations. Loops or blocks can be labelled for the break statement, and loops for continue. Although goto is a reserved word,ECMA-262, Edition 3, 7.5.3 Future Reserved Words goto is not implemented in JavaScript.

loop1: for (var a = 0; a < 10; ++a) //end of loop1
block1:
goto block1; // Parse error.

Functions

A function is a block with a (possibly empty) parameter list that is normally given a name. A function may use local variables. If you exit the function without a return statement, the value is returned.

function gcd(number1, number2)
console.log(gcd(60, 40)); // 20

//In the absence of parentheses following the identifier 'gcd' on the RHS of the assignment below,
//'gcd' returns a reference to the function itself without invoking it.
let mygcd = gcd; // mygcd and gcd reference the same function.
console.log(mygcd(60, 40)); // 20

Functions are first class objects and may be assigned to other variables.

The number of arguments given when calling a function may not necessarily correspond to the number of arguments in the function definition; a named argument in the definition that does not have a matching argument in the call will have the value (that can be implicitly cast to false). Within the function, the arguments may also be accessed through the object; this provides access to all arguments using indices (e.g. ), including those beyond the number of named arguments. (While the arguments list has a .length property, it is ''not'' an instance of ; it does not have methods such as , , etc.)

function add7(x, y) ;
add7(3); // 11
add7(3, 4); // 9

Primitive values (number, boolean, string) are passed by value. For objects, it is the reference to the object that is passed.

var obj1 = ;
var obj2 = ;
function foo(p)
foo(obj1, 3); // Does not affect obj1 at all. 3 is additional parameter
console.log(obj1.a + " " + obj2.b); // writes 1 3

Functions can be declared inside other functions, and access the outer function's local variables. Furthermore, they implement full closures by remembering the outer function's local variables even after the outer function has exited.

let t = "Top";
let bar, baz;
function foo()
foo();
baz("baz arg");
bar(); // "baz arg" (not "foo var") even though foo() has exited.
console.log(t); // Top

Async/await

Objects

For convenience, types are normally subdivided into ''primitives'' and ''objects''. Objects are entities that have an identity (they are only equal to themselves) and that map property names to values ("slots" in prototype-based programming terminology). Objects may be thought of as associative arrays or hashes, and are often implemented using these data structures. However, objects have additional features, such as a prototype chain, which ordinary associative arrays do not have.

JavaScript has several kinds of built-in objects, namely Array, Boolean, Date, Function, Math, Number, Object, RegExp and String. Other objects are "host objects", defined not by the language, but by the runtime environment. For example, in a browser, typical host objects belong to the DOM (window, form, links, etc.).

Creating objects

Objects can be created using a constructor or an object literal. The constructor can use either a built-in Object function or a custom function. It is a convention that constructor functions are given a name that starts with a capital letter:

// Constructor
var anObject = new Object();

// Object literal
var objectA = ;
var objectA2 = ; // A != A2, s create new objects as copies.
var objectB = ;

// Custom constructor (see below)

Object literals and array literals allow one to easily create flexible data structures:

var myStructure = ;

This is the basis for JSON, which is a simple notation that uses JavaScript-like syntax for data exchange.

Methods

A method is simply a function that has been assigned to a property name of an object. Unlike many object-oriented languages, there is no distinction between a function definition and a method definition in object-related JavaScript. Rather, the distinction occurs during function calling; a function can be called as a method.

When called as a method, the standard local variable ' is just automatically set to the object instance to the left of the "". (There are also ' and ' methods that can set ' explicitly—some packages such as jQuery do unusual things with '.)

In the example below, Foo is being used as a constructor. There is nothing special about a constructor - it is just a plain function that initialises an object. When used with the ' keyword, as is the norm, ' is set to a newly created blank object.

Note that in the example below, Foo is simply assigning values to slots, some of which are functions. Thus it can assign different functions to different instances. There is no prototyping in this example.

function px()

function Foo(yz)

var foo1 = new Foo(1);
var foo2 = new Foo(0);
foo2.prefix = "b-";

console.log("foo1/2 " + foo1.pyz() + foo2.pyz());
// foo1/2 a-Y b-Z

foo1.m3 = px; // Assigns the function itself, not its evaluated result, i.e. not px()
var baz = ;
baz.m4 = px; // No need for a constructor to make an object.

console.log("m1/m3/m4 " + foo1.m1() + foo1.m3() + baz.m4());
// m1/m3/m4 a-X a-X c-X

foo1.m2(); // Throws an exception, because foo1.m2 doesn't exist.

Constructors

Constructor functions simply assign values to slots of a newly created object. The values may be data or other functions.

Example: Manipulating an object:

function MyObject(attributeA, attributeB)

MyObject.staticC = "blue"; // On MyObject Function, not object
console.log(MyObject.staticC); // blue

object = new MyObject('red', 1000);

console.log(object.attributeA); // red
console.log(object attributeB"; // 1000

console.log(object.staticC); // undefined
object.attributeC = new Date(); // add a new property

delete object.attributeB; // remove a property of object
console.log(object.attributeB); // undefined

The constructor itself is referenced in the object's prototype's ''constructor'' slot. So,

function Foo()
// Use of 'new' sets prototype slots (for example,
// x = new Foo() would set x's prototype to Foo.prototype,
// and Foo.prototype has a constructor slot pointing back to Foo).
x = new Foo();
// The above is almost equivalent to
y = ;
y.constructor = Foo;
y.constructor();
// Except
x.constructor

y.constructor // true
x instanceof Foo // true
y instanceof Foo // false
// y's prototype is Object.prototype, not
// Foo.prototype, since it was initialised with
// instead of new Foo.
// Even though Foo is set to y's constructor slot,
// this is ignored by instanceof - only y's prototype's
// constructor slot is considered.

Functions are objects themselves, which can be used to produce an effect similar to "static properties" (using C++/Java terminology) as shown below. (The function object also has a special prototype property, as discussed in the "Inheritance" section below.)

Object deletion is rarely used as the scripting engine will garbage collect objects that are no longer being referenced.

Inheritance

JavaScript supports inheritance hierarchies through prototyping in the manner of Self.

In the following example, the class inherits from the class.
When is created as , the reference to the base instance of is copied to .

Derive does not contain a value for , so it is retrieved from ''when is accessed''. This is made clear by changing the value of , which is reflected in the value of .

Some implementations allow the prototype to be accessed or set explicitly using the slot as shown below.

function Base()

function Derived()

base = new Base();
Derived.prototype = base; // Must be before new Derived()
Derived.prototype.constructor = Derived; // Required to make `instanceof` work

d = new Derived(); // Copies Derived.prototype to d instance's hidden prototype slot.
d instanceof Derived; // true
d instanceof Base; // true

base.aBaseFunction = function()

d.anOverride(); // Derived::anOverride()
d.aBaseFunction(); // Base::aNEWBaseFunction()
console.log(d.aBaseFunction

Derived.prototype.aBaseFunction); // true

console.log(d.__proto__

base); // true in Mozilla-based implementations and false in many others.

The following shows clearly how references to prototypes are ''copied'' on instance creation, but that changes to a prototype can affect all instances that refer to it.

function m1()
function m2()
function m3()

function Base()

Base.prototype.m = m2;
bar = new Base();
console.log("bar.m " + bar.m()); // bar.m Two

function Top()
t = new Top();

foo = new Base();
Base.prototype = t;
// No effect on foo, the *reference* to t is copied.
console.log("foo.m " + foo.m()); // foo.m Two

baz = new Base();
console.log("baz.m " + baz.m()); // baz.m Three

t.m = m1; // Does affect baz, and any other derived classes.
console.log("baz.m1 " + baz.m()); // baz.m1 One

In practice many variations of these themes are used, and it can be both powerful and confusing.

Exception handling

JavaScript includes a try ... catch ... finally exception handling statement to handle run-time errors.

The try ... catch ... finally statement catches exceptions resulting from an error or a throw statement. Its syntax is as follows:

try catch(errorValue) finally

Initially, the statements within the try block execute. If an exception is thrown, the script's control flow immediately transfers to the statements in the catch block, with the exception available as the error argument. Otherwise the catch block is skipped. The catch block can , if it does not want to handle a specific error.

In any case the statements in the finally block are always executed. This can be used to free resources, although memory is automatically garbage collected.

Either the catch or the finally clause may be omitted. The catch argument is required.

The Mozilla implementation allows for multiple catch statements, as an extension to the ECMAScript standard. They follow a syntax similar to that used in Java:

try
catch (e if e

"InvalidNameException")
catch (e if e

"InvalidIdException")
catch (e if e

"InvalidEmailException")
catch (e)

In a browser, the event is more commonly used to trap exceptions.

onerror = function (errorValue, url, lineNr) ;

Native functions and methods

eval (expression)

Evaluates the first parameter as an expression, which can include assignment statements. Variables local to functions can be referenced by the expression. However, represents a major security risk, as it allows a bad actor to execute arbitrary code, so its use is discouraged.

> (function foo() )();
val 9
undefined

See also

* Comparison of JavaScript-based source code editors
* JavaScript

References

Further reading

* Danny Goodman: ''JavaScript Bible'', Wiley, John & Sons, .
* David Flanagan, Paula Ferguson: ''JavaScript: The Definitive Guide'', O'Reilly & Associates, .
* Thomas A. Powell, Fritz Schneider: ''JavaScript: The Complete Reference'', McGraw-Hill Companies, .
* Axel Rauschmayer: ''Speaking JavaScript: An In-Depth Guide for Programmers'', 460 pages, O'Reilly Media, 25 February 2014, .
free online edition

* Emily Vander Veer: ''JavaScript For Dummies, 4th Edition'', Wiley, .

External links

A re-introduction to JavaScript - Mozilla Developer Center

JavaScript Loops
* ECMAScript standard references


Interactive JavaScript Lessons - example-based

JavaScript on About.com: lessons and explanation

JavaScript Training
* Mozilla Developer Center Core References for JavaScript version
1.5
an


Mozilla JavaScript Language Documentation

{{DEFAULTSORT:Javascript Syntax
syntax
Programming language syntax