| Paradigm(s) | Multi-paradigm: scripting, object-oriented (prototype-based), imperative, functional |
|---|---|
| Appeared in | 1995 |
| Designed by | Brendan Eich |
| Developer | Netscape Communications Corporation, Mozilla Foundation |
| Stable release | 1.8.5 (March 22, 2011) |
| Typing discipline | dynamic, weak, duck |
| Major implementations | KJS, Rhino, SpiderMonkey, V8, WebKit, Carakan, Chakra |
| Influenced by | C, Java, Perl, Python, Scheme, Self |
| Influenced | ActionScript, CoffeeScript, Dart, JScript .NET, Objective-J, QML, TIScript, TypeScript |
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| Filename extension | .js |
|---|---|
| Internet media type | application/javascripttext/javascript (obsolete) |
| Uniform Type Identifier | com.netscape.javascript-source |
| Type of format | Scripting language |
| Part of a series on |
| JavaScript |
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JavaScript (JS) is an interpreted computer programming language. It was originally implemented as part of web browsers so that client-side scripts could interact with the user, control the browser, communicate asynchronously, and alter the document content that was displayed. Now though it has many uses involving popular game development and the creation of applications.
JavaScript is a prototype-based scripting language that is dynamic, weakly typed, and has first-class functions. Its syntax was influenced by the language C. JavaScript copies many names and naming conventions from Java, but the two languages are otherwise unrelated and have very different semantics. The key design principles within JavaScript are taken from the Self and Scheme programming languages. It is a multi-paradigm language, supporting object-oriented, imperative, and functional programming styles.
JavaScript's use in applications outside of web pages-for example, in PDF documents, site-specific browsers, and desktop widgets-is also significant. Newer and faster JavaScript VMs and frameworks built upon them (notably Node.js) have also increased the popularity of JavaScript for server-side web applications.
JavaScript was formalized in the ECMAScript language standard and is primarily used as part of a web browser (client-side JavaScript). This enables programmatic access to computational objects within a host environment.
JavaScript was originally developed in Netscape, by Brendan Eich. Battling with Microsoft over the Internet, Netscape considered their client-server solution as a distributed OS, running a portable version of Sun Microsystems' Java. Because Java was a competitor of C++ and aimed at professional programmers, Netscape also wanted a lightweight interpreted language that would complement Java by appealing to nonprofessional programmers, like Microsoft's Visual Basic (see JavaScript and Java).
Developed under the name Mocha, LiveScript was the official name for the language when it first shipped in beta releases of Netscape Navigator 2.0 in September 1995, but it was renamed JavaScript when it was deployed in the Netscape browser version 2.0B3.
The change of name from LiveScript to JavaScript roughly coincided with Netscape adding support for Java technology in its Netscape Navigator web browser. The final choice of name caused confusion, giving the impression that the language was a spin-off of the Java programming language, and the choice has been characterized by many as a marketing ploy by Netscape to give JavaScript the cachet of what was then the hot new web programming language.
Netscape introduced an implementation of the language for server-side scripting with Netscape Enterprise Server, first released in December, 1994 (soon after releasing JavaScript for browsers). Since the mid-2000s, there has been a proliferation of server-side JavaScript implementations. Node.js is one recent notable example of server-side JavaScript being used in real-world applications.
JavaScript very quickly gained widespread success as a client-side scripting language for web pages. Microsoft introduced JavaScript support in its own web browser, Internet Explorer, in version 3.0, released in August 1996.[not in citation given] Microsoft's webserver, Internet Information Server, introduced support for server-side scripting in JavaScript with release 3.0 (1996). Microsoft started to promote webpage scripting using the umbrella term Dynamic HTML.
Microsoft's JavaScript implementation was later renamed JScript to avoid trademark issues. JScript added new date methods to fix the Y2K-problematic methods in JavaScript, which were based on Java's java.util.Date class.
In November 1996, Netscape announced that it had submitted JavaScript to Ecma International for consideration as an industry standard, and subsequent work resulted in the standardized version named ECMAScript. In June 1997, Ecma International published the first edition of the ECMA-262 specification. A year later, in June 1998, some modifications were made to adapt it to the ISO/IEC-16262 standard, and the second edition was released. The third edition of ECMA-262 (published on December 1999) is the version most browsers currently use.
A fourth edition is under development and may include new features such as packages, namespaces and explicit definition of classes.
JavaScript has become one of the most popular programming languages on the web. Initially, however, many professional programmers denigrated the language because its target audience consisted of web authors and other such "amateurs", among other reasons. The advent of Ajax returned JavaScript to the spotlight and brought more professional programming attention. The result was a proliferation of comprehensive frameworks and libraries, improved JavaScript programming practices, and increased usage of JavaScript outside of web browsers, as seen by the proliferation of server-side JavaScript platforms.
In January 2009, the CommonJS project was founded with the goal of specifying a common standard library mainly for JavaScript development outside the browser.
Today, "JavaScript" is a trademark of Oracle Corporation. It is used under license for technology invented and implemented by Netscape Communications and current entities such as the Mozilla Foundation.
The following features are common to all conforming ECMAScript implementations, unless explicitly specified otherwise.
JavaScript supports much of the structured programming syntax from C (e.g., if statements, while loops, switch statements, etc.). One partial exception is scoping: C-style block scoping is not supported; instead, JavaScript has function scoping. JavaScript 1.7, however, supports block scoping with the let keyword. Like C, JavaScript makes a distinction between expressions and statements. One syntactic difference from C is automatic semicolon insertion, in which the semicolons that terminate statements can be omitted.
x could be bound to a number, then later rebound to a string. JavaScript supports various ways to test the type of an object, including duck typing.obj.x = 10 and obj['x'] = 10 are equivalent, the dot notation being syntactic sugar. Properties and their values can be added, changed, or deleted at run-time. Most properties of an object (and those on its prototype inheritance chain) can be enumerated using a for...in loop. JavaScript has a small number of built-in objects such as Function and Date.eval function that can execute statements provided as strings at run-time..call() and .bind(). A nested function is a function defined within another function. It is created each time the outer function is invoked. In addition, each created function forms a lexical closure: the lexical scope of the outer function, including any constants, local variables and argument values, becomes part of the internal state of each inner function object, even after execution of the outer function concludes.new will create an instance of a prototype, inheriting properties and methods from the constructor (including properties from the Object prototype). ECMAScript 5 offers the Object.create method, allowing explicit creation of an instance without automatically inheriting from the Object prototype (older environments can assign the prototype to null). The constructor's prototype property determines the object used for the new object's internal prototype. New methods can be added by modifying the prototype of the object used as a constructor. JavaScript's built-in constructors, such as Array or Object, also have prototypes that can be modified. While this is possible it is generally considered bad practice to modify the Object prototype as most objects in Javascript will inherit methods and properties from the Object prototype and may not expect those to be modified.this keyword is bound to that object for that invocation.<script> elements). (This is not a language feature per se, but it is common in most JavaScript implementations.)arguments object. Variadic functions can also be created by using the apply method.JavaScript is officially managed by Mozilla Foundation, and new language features are added periodically. However, only some JavaScript engines support these new features:
catch clauseslet keywordfunction(args) expr)As of 2011[update], the latest version of the language is JavaScript 1.8.5. It is a superset of ECMAScript (ECMA-262) Edition 3. Extensions to the language, including partial ECMAScript for XML (E4X) (ECMA-357) support and experimental features considered for inclusion into future ECMAScript editions, are documented here.
Variables in JavaScript can be defined using the var keyword:
var x; //defines the variable x, although no value is assigned to it by default var y = 2; //defines the variable y and assigns the value of 2 to it
Note the comments in the example above, both of which were preceded with two forward slashes.
There is no built-in I/O functionality in JavaScript; the runtime environment provides that. The ECMAScript specification in edition 5.1 mentions:
... indeed, there are no provisions in this specification for input of external data or output of computed results.
However, most runtime environments have a console object that can be used to print output. Here is a minimalist Hello World program:
console.log("Hello world!");
A simple recursive function:
function factorial(n) { if (n === 0) { return 1; } return n * factorial(n - 1); }
Anonymous function (or lambda) syntax and closure example:
var displayClosure = function() { var count = 0; return function () { return ++count; }; } var inc = displayClosure(); inc(); // returns 1 inc(); // returns 2 inc(); // returns 3
Variadic function demonstration (arguments is a special variable).
var sum = function() { var i, x = 0; for (i = 0; i < arguments.length; ++i) { x += arguments[i]; } return x; } sum(1, 2, 3); // returns 6
Immediately-invoked function expressions allow functions to pass around variables under their own closures.
var v; v = 1; var getValue = (function(v) { return function() {return v;}; }(v)); v = 2; getValue(); // 1
This sample code displays various JavaScript features.
/* Finds the lowest common multiple (LCM) of two numbers */ function LCMCalculator(x, y) { // constructor function var checkInt = function (x) { // inner function if (x % 1 !== 0) { throw new TypeError(x + " is not an integer"); // throw an exception } return x; }; this.a = checkInt(x) // ^ semicolons are optional this.b = checkInt(y); } // The prototype of object instances created by a constructor is // that constructor's "prototype" property. LCMCalculator.prototype = { // object literal constructor: LCMCalculator, // when reassigning a prototype, set the constructor property appropriately gcd: function () { // method that calculates the greatest common divisor // Euclidean algorithm: var a = Math.abs(this.a), b = Math.abs(this.b), t; if (a < b) { // swap variables t = b; b = a; a = t; } while (b !== 0) { t = b; b = a % b; a = t; } // Only need to calculate GCD once, so "redefine" this method. // (Actually not redefinition-it's defined on the instance itself, // so that this.gcd refers to this "redefinition" instead of LCMCalculator.prototype.gcd.) // Also, 'gcd' === "gcd", this['gcd'] === this.gcd this['gcd'] = function () { return a; }; return a; }, // Object property names can be specified by strings delimited by double (") or single (') quotes. "lcm" : function () { // Variable names don't collide with object properties, e.g. |lcm| is not |this.lcm|. // not using |this.a * this.b| to avoid FP precision issues var lcm = this.a / this.gcd() * this.b; // Only need to calculate lcm once, so "redefine" this method. this.lcm = function () { return lcm; }; return lcm; }, toString: function () { return "LCMCalculator: a = " + this.a + ", b = " + this.b; } }; // Define generic output function; this implementation only works for web browsers function output(x) { document.body.appendChild(document.createTextNode(x)); document.body.appendChild(document.createElement('br')); } // Note: Array's map() and forEach() are defined in JavaScript 1.6. // They are used here to demonstrate JavaScript's inherent functional nature. [[25, 55], [21, 56], [22, 58], [28, 56]].map(function (pair) { // array literal + mapping function return new LCMCalculator(pair[0], pair[1]); }).sort(function (a, b) { // sort with this comparative function return a.lcm() - b.lcm(); }).forEach(function (obj) { output(obj + ", gcd = " + obj.gcd() + ", lcm = " + obj.lcm()); });
The following output should be displayed in the browser window.
LCMCalculator: a = 28, b = 56, gcd = 28, lcm = 56 LCMCalculator: a = 21, b = 56, gcd = 7, lcm = 168 LCMCalculator: a = 25, b = 55, gcd = 5, lcm = 275 LCMCalculator: a = 22, b = 58, gcd = 2, lcm = 638
The most common use of JavaScript is to write functions that are embedded in or included from HTML pages and that interact with the Document Object Model (DOM) of the page. Some simple examples of this usage are:
Because JavaScript code can run locally in a user's browser (rather than on a remote server), the browser can respond to user actions quickly, making an application more responsive. Furthermore, JavaScript code can detect user actions which HTML alone cannot, such as individual keystrokes. Applications such as Gmail take advantage of this: much of the user-interface logic is written in JavaScript, and JavaScript dispatches requests for information (such as the content of an e-mail message) to the server. The wider trend of Ajax programming similarly exploits this strength.
A JavaScript engine (also known as JavaScript interpreter or JavaScript implementation) is an interpreter that interprets JavaScript source code and executes the script accordingly. The first JavaScript engine was created by Brendan Eich at Netscape Communications Corporation, for the Netscape Navigator web browser. The engine, code-named SpiderMonkey, is implemented in C. It has since been updated (in JavaScript 1.5) to conform to ECMA-262 Edition 3. The Rhino engine, created primarily by Norris Boyd (formerly of Netscape; now at Google) is a JavaScript implementation in Java. Rhino, like SpiderMonkey, is ECMA-262 Edition 3 compliant.
A web browser is by far the most common host environment for JavaScript. Web browsers typically create "host objects" to represent the Document Object Model (DOM) in JavaScript. The web server is another common host environment. A JavaScript webserver would typically expose host objects representing HTTP request and response objects, which a JavaScript program could then interrogate and manipulate to dynamically generate web pages.
Because JavaScript is the only language that the most popular browsers share support for, it has become a target language for many frameworks in other languages, even though JavaScript was never intended to be such a language. Despite the performance limitations inherent to its dynamic nature, the increasing speed of JavaScript engines has made the language a surprisingly feasible compilation target.
Below is a minimal example of a standards-conforming web page containing JavaScript (using HTML 5 syntax) and the DOM:
<!DOCTYPE html> <meta charset="utf-8"> <title>Minimal Example</title> <h1 id="header">This is JavaScript</h1> <script> document.body.appendChild(document.createTextNode('Hello World!')); var h1 = document.getElementById('header'); // holds a reference to the <h1> tag h1 = document.getElementsByTagName('h1')[0]; // accessing the same <h1> element </script> <noscript>Your browser either does not support JavaScript, or has it turned off.</noscript>
Because JavaScript runs in widely varying environments, an important part of testing and debugging is to test and verify that the JavaScript works across multiple browsers.
The DOM interfaces for manipulating web pages are not part of the ECMAScript standard, or of JavaScript itself. Officially, the DOM interfaces are defined by a separate standardization effort by the W3C; in practice, browser implementations differ from the standards and from each other, and not all browsers execute JavaScript.
To deal with these differences, JavaScript authors can attempt to write standards-compliant code which will also be executed correctly by most browsers; failing that, they can write code that checks for the presence of certain browser features and behaves differently if they are not available. In some cases, two browsers may both implement a feature but with different behavior, and authors may find it practical to detect what browser is running and change their script's behavior to match. Programmers may also use libraries or toolkits which take browser differences into account.
Furthermore, scripts may not work for some users. For example, a user may:
To support these users, web authors can try to create pages which degrade gracefully on user agents (browsers) which do not support the page's JavaScript. In particular, the page should remain usable albeit without the extra features that the JavaScript would have added. An alternative approach that many find preferable is to first author content using basic technologies that work in all browsers, then enhance the content for users that have JavaScript enabled. This is known as progressive enhancement.
Assuming that the user has not disabled its execution, client-side web JavaScript should be written to enhance the experiences of visitors with visual or physical disabilities, and certainly should avoid denying information to these visitors.
Screen readers, used by the blind and partially sighted, can be JavaScript-aware and so may access and read the page DOM after the script has altered it. The HTML should be as concise, navigable and semantically rich as possible whether the scripts have run or not. JavaScript should not be totally reliant on mouse-specific events so as to deny its benefits to users who either cannot use a mouse or who choose to favor the keyboard for whatever reason. Equally, although hyperlinks and webforms can be navigated and operated from the keyboard, accessible JavaScript should not require keyboard events either. There are device-independent events such as onfocus and onchange that are preferable in most cases.
JavaScript should not be used in a way that is confusing or disorienting to any web user. For example, using script to alter or disable the normal functionality of the browser, such as by changing the way the back-button or the refresh event work, is usually best avoided. Equally, triggering events that the user may not be aware of reduces the user's sense of control as do unexpected scripted changes to the page content.
Often the process of making a complex web page as accessible as possible becomes a nontrivial problem where issues become matters of debate and opinion, and where compromises are necessary in the end. However, user agents and assistive technologies are constantly evolving and new guidelines and relevant information are continually being published on the web.
JavaScript and the DOM provide the potential for malicious authors to deliver scripts to run on a client computer via the web. Browser authors contain this risk using two restrictions. First, scripts run in a sandbox in which they can only perform web-related actions, not general-purpose programming tasks like creating files. Second, scripts are constrained by the same origin policy: scripts from one web site do not have access to information such as usernames, passwords, or cookies sent to another site. Most JavaScript-related security bugs are breaches of either the same origin policy or the sandbox.
There are subsets of general JavaScript - ADsafe, Secure ECMA Script (SES) - that provide greater level of security, especially on code created by third parties (such as advertisements).
Content Security Policy is the main intended method of ensuring that only trusted code is executed on a web page.
A common JavaScript-related security problem is cross-site scripting, or XSS, a violation of the same-origin policy. XSS vulnerabilities occur when an attacker is able to cause a target web site, such as an online banking website, to include a malicious script in the webpage presented to a victim. The script in this example can then access the banking application with the privileges of the victim, potentially disclosing secret information or transferring money without the victim's authorization. A solution to XSS vulnerabilities is to use HTML escaping whenever displaying untrusted data.
Some browsers include partial protection against reflected XSS attacks, in which the attacker provides a URL including malicious script. However, even users of those browsers are vulnerable to other XSS attacks, such as those where the malicious code is stored in a database. Only correct design of Web applications on the server side can fully prevent XSS.
XSS vulnerabilities can also occur because of implementation mistakes by browser authors.
Another cross-site vulnerability is cross-site request forgery or CSRF. In CSRF, code on an attacker's site tricks the victim's browser into taking actions the user didn't intend at a target site (like transferring money at a bank). It works because, if the target site relies only on cookies to authenticate requests, then requests initiated by code on the attacker's site will carry the same legitimate login credentials as requests initiated by the user. In general, the solution to CSRF is to require an authentication value in a hidden form field, and not only in the cookies, to authenticate any request that might have lasting effects. Checking the HTTP Referrer header can also help.
"JavaScript hijacking" is a type of CSRF attack in which a <script> tag on an attacker's site exploits a page on the victim's site that returns private information such as JSON or JavaScript. Possible solutions include:
Developers of client-server applications must recognize that untrusted clients may be under the control of attackers. Thus any secret embedded in JavaScript could be extracted by a determined adversary, and the application author cannot assume that his JavaScript runs as intended, or at all. Some implications:
JavaScript provides an interface to a wide range of browser capabilities, some of which may have flaws such as buffer overflows. These flaws can allow attackers to write scripts which would run any code they wish on the user's system. This code is not by any means limited to another JavaScript application. For example, a buffer overrun exploit can allow an attacker to gain access to the operating system's API with superuser privileges.
These flaws have affected major browsers including Firefox, Internet Explorer, and Safari.
Plugins, such as video players, Adobe Flash, and the wide range of ActiveX controls enabled by default in Microsoft Internet Explorer, may also have flaws exploitable via JavaScript, and such flaws have been exploited in the past.
In Windows Vista, Microsoft has attempted to contain the risks of bugs such as buffer overflows by running the Internet Explorer process with limited privileges. Google Chrome similarly limits page renderers in its own "sandbox".
Web browsers are capable of running JavaScript outside of the sandbox, with the privileges necessary to, for example, create or delete files. Of course, such privileges aren't meant to be granted to code from the web.
Incorrectly granting privileges to JavaScript from the web has played a role in vulnerabilities in both Internet Explorer and Firefox. In Windows XP Service Pack 2, Microsoft demoted JScript's privileges in Internet Explorer.
Microsoft Windows allows JavaScript source files on a computer's hard drive to be launched as general-purpose, non-sandboxed programs. This makes JavaScript (like VBScript) a theoretically viable vector for a Trojan horse, although JavaScript Trojan horses are uncommon in practice. (See Windows Script Host.)
In addition to web browsers and servers, JavaScript interpreters are embedded in a number of tools. Each of these applications provides its own object model which provides access to the host environment, with the core JavaScript language remaining mostly the same in each application.
javax.script package, including a JavaScript implementation based on Mozilla Rhino. Thus, Java applications can host scripts that access the application's variables and objects, much like web browsers host scripts that access the browser's Document Object Model (DOM) for a webpage.QtScript module to interpret JavaScript, analogous to Java's javax.script package.MacOS object for interaction with the operating system and third-party applications.Within JavaScript, access to a debugger becomes invaluable when developing large, non-trivial programs. Because there can be implementation differences between the various browsers (particularly within the Document Object Model), it is useful to have access to a debugger for each of the browsers that a web application targets.
Script debuggers are available for Internet Explorer, Firefox, Safari, Google Chrome, and Opera.
Three debuggers are available for Internet Explorer: Microsoft Visual Studio is the richest of the three, closely followed by Microsoft Script Editor (a component of Microsoft Office), and finally the free Microsoft Script Debugger which is far more basic than the other two. The free Microsoft Visual Web Developer Express provides a limited version of the JavaScript debugging functionality in Microsoft Visual Studio. Internet Explorer has included developer tools since version 8 (reached by pressing the F12 key).
Web applications within Firefox can be debugged using the Firebug add-on, or the older Venkman debugger. Firefox also has a simpler built-in Error Console, which logs and evaluates JavaScript. It also logs CSS errors and warnings.
Opera includes a set of tools called Dragonfly.
WebKit's Web Inspector includes a JavaScript debugger used in Safari, along with a modified version in Google Chrome.
Some debugging aids are themselves written in JavaScript and built to run on the Web. An example is the program JSLint, developed by Douglas Crockford who has written extensively on the language. JSLint scans JavaScript code for conformance to a set of standards and guidelines.
The following table is based on a history compilation forum post, jQuery author's blog post, and Microsoft's JScript version information webpage.
| Version | Release date | Equivalent to | Netscape Navigator |
Mozilla Firefox |
Internet Explorer |
Opera | Safari | Google Chrome |
|---|---|---|---|---|---|---|---|---|
| 1.0 | March 1996 | 2.0 | 3.0 | |||||
| 1.1 | August 1996 | 3.0 | ||||||
| 1.2 | June 1997 | 4.0-4.05 | 3 | |||||
| 1.3 | October 1998 | ECMA-262 1st + 2nd edition | 4.06-4.7x | 4.0 | 5 | |||
| 1.4 | Netscape Server |
6 | ||||||
| 1.5 | November 2000 | ECMA-262 3rd edition | 6.0 | 1.0 | 5.5 (JScript 5.5), 6 (JScript 5.6), 7 (JScript 5.7), 8 (JScript 5.8) |
7.0 | 3.0-5 | 1.0-10.0.666 |
| 1.6 | November 2005 | 1.5 + array extras + array and string generics + E4X | 1.5 | |||||
| 1.7 | October 2006 | 1.6 + Pythonic generators + iterators + let | 2.0 | |||||
| 1.8 | June 2008 | 1.7 + generator expressions + expression closures | 3.0 | 11.50 | ||||
| 1.8.1 | 1.8 + native JSON support + minor updates | 3.5 | ||||||
| 1.8.2 | June 22, 2009 | 1.8.1 + minor updates | 3.6 | |||||
| 1.8.5 | July 27, 2010 | 1.8.2 + ECMAScript 5 compliance | 4 | 9 | 11.60 |
JSON, or JavaScript Object Notation, is a general-purpose data interchange format that is defined as a subset of JavaScript's literal syntax.
jQuery and Prototype are popular JavaScript libraries designed to simplify DOM-oriented client-side HTML scripting.
Mozilla browsers currently support LiveConnect, a feature that allows JavaScript and Java to intercommunicate on the web. However, Mozilla-specific support for LiveConnect is scheduled to be phased out in the future in favor of passing on the LiveConnect handling via NPAPI to the Java 1.6+ plug-in (not yet supported on the Mac as of March 2010[update]). Most browser inspection tools, such as Firebug in Firefox, include JavaScript interpreters that can act on the visible page's DOM.
As JavaScript is the most widely supported client-side language that can run within a web browser, it has become an intermediate language for other languages to target. This has included both newly-created languages and ports of existing languages. Some of these include:
A common misconception is that JavaScript is similar or closely related to Java. It is true that both have a C-like syntax, the C language being their most immediate common ancestor language. They are both object-oriented and typically sandboxed (when used inside a browser). In addition, JavaScript was designed with Java's syntax and standard library in mind. In particular, all Java keywords were reserved in original JavaScript, JavaScript's standard library follows Java's naming conventions, and JavaScript's Math and Date objects are based on classes from Java 1.0.
However, the similarities end there. Java has static typing; JavaScript's typing is dynamic (meaning a variable can hold an object of any type and cannot be restricted). JavaScript is weakly typed while Java is strongly typed. Java is loaded from compiled bytecode; JavaScript is loaded as human-readable source code. Java's objects are class-based; JavaScript's are prototype-based. JavaScript also has many functional programming features based on the Scheme language.
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