title: What happens when... url: https://github.com/alex/what-happens-when/blob/master/README.rst hash_url: 46f440a287ca07d71b0fd3e7915a9a0c

What happens when...

This repository is an attempt to answer the age old interview question "What happens when you type google.com into your browser's address box and press enter?"

Except instead of the usual story, we're going to try to answer this question in as much detail as possible. No skipping out on anything.

This is a collaborative process, so dig in and try to help out! There are tons of details missing, just waiting for you to add them! So send us a pull request, please!

This is all licensed under the terms of the Creative Commons Zero license.

Read this in 简体中文 (simplified Chinese) and 한국어 (Korean). NOTE: these have not been reviewed by the alex/what-happens-when maintainers.

Table of Contents

The "g" key is pressed

The following sections explain the physical keyboard actions and the OS interrupts. When you press the key "g" the browser receives the event and the auto-complete functions kick in. Depending on your browser's algorithm and if you are in private/incognito mode or not various suggestions will be presented to you in the dropbox below the URL bar. Most of these algorithms sort and prioritize results based on search history, bookmarks, cookies, and popular searches from the internet as a whole. As you are typing "google.com" many blocks of code run and the suggestions will be refined with each key press. It may even suggest "google.com" before you finish typing it.

The "enter" key bottoms out

To pick a zero point, let's choose the Enter key on the keyboard hitting the bottom of its range. At this point, an electrical circuit specific to the enter key is closed (either directly or capacitively). This allows a small amount of current to flow into the logic circuitry of the keyboard, which scans the state of each key switch, debounces the electrical noise of the rapid intermittent closure of the switch, and converts it to a keycode integer, in this case 13. The keyboard controller then encodes the keycode for transport to the computer. This is now almost universally over a Universal Serial Bus (USB) or Bluetooth connection, but historically has been over PS/2 or ADB connections.

In the case of the USB keyboard:

In the case of Virtual Keyboard (as in touch screen devices):

Interrupt fires [NOT for USB keyboards]

The keyboard sends signals on its interrupt request line (IRQ), which is mapped to an interrupt vector (integer) by the interrupt controller. The CPU uses the Interrupt Descriptor Table (IDT) to map the interrupt vectors to functions (interrupt handlers) which are supplied by the kernel. When an interrupt arrives, the CPU indexes the IDT with the interrupt vector and runs the appropriate handler. Thus, the kernel is entered.

(On Windows) A WM_KEYDOWN message is sent to the app

The HID transport passes the key down event to the KBDHID.sys driver which converts the HID usage into a scancode. In this case the scan code is VK_RETURN (0x0D). The KBDHID.sys driver interfaces with the KBDCLASS.sys (keyboard class driver). This driver is responsible for handling all keyboard and keypad input in a secure manner. It then calls into Win32K.sys (after potentially passing the message through 3rd party keyboard filters that are installed). This all happens in kernel mode.

Win32K.sys figures out what window is the active window through the GetForegroundWindow() API. This API provides the window handle of the browser's address box. The main Windows "message pump" then calls SendMessage(hWnd, WM_KEYDOWN, VK_RETURN, lParam). lParam is a bitmask that indicates further information about the keypress: repeat count (0 in this case), the actual scan code (can be OEM dependent, but generally wouldn't be for VK_RETURN), whether extended keys (e.g. alt, shift, ctrl) were also pressed (they weren't), and some other state.

The Windows SendMessage API is a straightforward function that adds the message to a queue for the particular window handle (hWnd). Later, the main message processing function (called a WindowProc) assigned to the hWnd is called in order to process each message in the queue.

The window (hWnd) that is active is actually an edit control and the WindowProc in this case has a message handler for WM_KEYDOWN messages. This code looks within the 3rd parameter that was passed to SendMessage (wParam) and, because it is VK_RETURN knows the user has hit the ENTER key.

(On OS X) A KeyDown NSEvent is sent to the app

The interrupt signal triggers an interrupt event in the I/O Kit kext keyboard driver. The driver translates the signal into a key code which is passed to the OS X WindowServer process. Resultantly, the WindowServer dispatches an event to any appropriate (e.g. active or listening) applications through their Mach port where it is placed into an event queue. Events can then be read from this queue by threads with sufficient privileges calling the mach_ipc_dispatch function. This most commonly occurs through, and is handled by, an NSApplication main event loop, via an NSEvent of NSEventType KeyDown.

(On GNU/Linux) the Xorg server listens for keycodes

When a graphical X server is used, X will use the generic event driver evdev to acquire the keypress. A re-mapping of keycodes to scancodes is made with X server specific keymaps and rules. When the scancode mapping of the key pressed is complete, the X server sends the character to the window manager (DWM, metacity, i3, etc), so the window manager in turn sends the character to the focused window. The graphical API of the window that receives the character prints the appropriate font symbol in the appropriate focused field.

Parse URL

Is it a URL or a search term?

When no protocol or valid domain name is given the browser proceeds to feed the text given in the address box to the browser's default web search engine. In many cases the URL has a special piece of text appended to it to tell the search engine that it came from a particular browser's URL bar.

Convert non-ASCII Unicode characters in hostname

Check HSTS list

DNS lookup

ARP process

In order to send an ARP (Address Resolution Protocol) broadcast the network stack library needs the target IP address to look up. It also needs to know the MAC address of the interface it will use to send out the ARP broadcast.

The ARP cache is first checked for an ARP entry for our target IP. If it is in the cache, the library function returns the result: Target IP = MAC.

If the entry is not in the ARP cache:

ARP Request:

Sender MAC: interface:mac:address:here
Sender IP: interface.ip.goes.here
Target MAC: FF:FF:FF:FF:FF:FF (Broadcast)
Target IP: target.ip.goes.here

Depending on what type of hardware is between the computer and the router:

Directly connected:

Hub:

Switch:

ARP Reply:

Sender MAC: target:mac:address:here
Sender IP: target.ip.goes.here
Target MAC: interface:mac:address:here
Target IP: interface.ip.goes.here

Now that the network library has the IP address of either our DNS server or the default gateway it can resume its DNS process:

Opening of a socket

Once the browser receives the IP address of the destination server, it takes that and the given port number from the URL (the HTTP protocol defaults to port 80, and HTTPS to port 443), and makes a call to the system library function named socket and requests a TCP socket stream - AF_INET/AF_INET6 and SOCK_STREAM.

At this point the packet is ready to be transmitted through either:

For most home or small business Internet connections the packet will pass from your computer, possibly through a local network, and then through a modem (MOdulator/DEModulator) which converts digital 1's and 0's into an analog signal suitable for transmission over telephone, cable, or wireless telephony connections. On the other end of the connection is another modem which converts the analog signal back into digital data to be processed by the next network node where the from and to addresses would be analyzed further.

Most larger businesses and some newer residential connections will have fiber or direct Ethernet connections in which case the data remains digital and is passed directly to the next network node for processing.

Eventually, the packet will reach the router managing the local subnet. From there, it will continue to travel to the autonomous system's (AS) border routers, other ASes, and finally to the destination server. Each router along the way extracts the destination address from the IP header and routes it to the appropriate next hop. The time to live (TTL) field in the IP header is decremented by one for each router that passes. The packet will be dropped if the TTL field reaches zero or if the current router has no space in its queue (perhaps due to network congestion).

This send and receive happens multiple times following the TCP connection flow:

TLS handshake

HTTP protocol

If the web browser used was written by Google, instead of sending an HTTP request to retrieve the page, it will send a request to try and negotiate with the server an "upgrade" from HTTP to the SPDY protocol.

If the client is using the HTTP protocol and does not support SPDY, it sends a request to the server of the form:

GET / HTTP/1.1
Host: google.com
Connection: close
[other headers]

where [other headers] refers to a series of colon-separated key-value pairs formatted as per the HTTP specification and separated by single new lines. (This assumes the web browser being used doesn't have any bugs violating the HTTP spec. This also assumes that the web browser is using HTTP/1.1, otherwise it may not include the Host header in the request and the version specified in the GET request will either be HTTP/1.0 or HTTP/0.9.)

HTTP/1.1 defines the "close" connection option for the sender to signal that the connection will be closed after completion of the response. For example,

Connection: close

HTTP/1.1 applications that do not support persistent connections MUST include the "close" connection option in every message.

After sending the request and headers, the web browser sends a single blank newline to the server indicating that the content of the request is done.

The server responds with a response code denoting the status of the request and responds with a response of the form:

200 OK
[response headers]

Followed by a single newline, and then sends a payload of the HTML content of www.google.com. The server may then either close the connection, or if headers sent by the client requested it, keep the connection open to be reused for further requests.

If the HTTP headers sent by the web browser included sufficient information for the web server to determine if the version of the file cached by the web browser has been unmodified since the last retrieval (ie. if the web browser included an ETag header), it may instead respond with a request of the form:

304 Not Modified
[response headers]

and no payload, and the web browser instead retrieves the HTML from its cache.

After parsing the HTML, the web browser (and server) repeats this process for every resource (image, CSS, favicon.ico, etc) referenced by the HTML page, except instead of GET / HTTP/1.1 the request will be GET /$(URL relative to www.google.com) HTTP/1.1.

If the HTML referenced a resource on a different domain than www.google.com, the web browser goes back to the steps involved in resolving the other domain, and follows all steps up to this point for that domain. The Host header in the request will be set to the appropriate server name instead of google.com.

HTTP Server Request Handle

The HTTPD (HTTP Daemon) server is the one handling the requests/responses on the server side. The most common HTTPD servers are Apache or nginx for Linux and IIS for Windows.

Behind the scenes of the Browser

Once the server supplies the resources (HTML, CSS, JS, images, etc.) to the browser it undergoes the below process:

Browser

The browser's functionality is to present the web resource you choose, by requesting it from the server and displaying it in the browser window. The resource is usually an HTML document, but may also be a PDF, image, or some other type of content. The location of the resource is specified by the user using a URI (Uniform Resource Identifier).

The way the browser interprets and displays HTML files is specified in the HTML and CSS specifications. These specifications are maintained by the W3C (World Wide Web Consortium) organization, which is the standards organization for the web.

Browser user interfaces have a lot in common with each other. Among the common user interface elements are:

Browser High Level Structure

The components of the browsers are:

HTML parsing

The rendering engine starts getting the contents of the requested document from the networking layer. This will usually be done in 8kB chunks.

The primary job of HTML parser to parse the HTML markup into a parse tree.

The output tree (the "parse tree") is a tree of DOM element and attribute nodes. DOM is short for Document Object Model. It is the object presentation of the HTML document and the interface of HTML elements to the outside world like JavaScript. The root of the tree is the "Document" object. Prior of any manipulation via scripting, the DOM has an almost one-to-one relation to the markup.

The parsing algorithm

HTML cannot be parsed using the regular top-down or bottom-up parsers.

The reasons are:

Unable to use the regular parsing techniques, the browser utilizes a custom parser for parsing HTML. The parsing algorithm is described in detail by the HTML5 specification.

The algorithm consists of two stages: tokenization and tree construction.

Actions when the parsing is finished

The browser begins fetching external resources linked to the page (CSS, images, JavaScript files, etc.).

At this stage the browser marks the document as interactive and starts parsing scripts that are in "deferred" mode: those that should be executed after the document is parsed. The document state is set to "complete" and a "load" event is fired.

Note there is never an "Invalid Syntax" error on an HTML page. Browsers fix any invalid content and go on.

CSS interpretation

Page Rendering

GPU Rendering

Window Server

Post-rendering and user-induced execution

After rendering has completed, the browser executes JavaScript code as a result of some timing mechanism (such as a Google Doodle animation) or user interaction (typing a query into the search box and receiving suggestions). Plugins such as Flash or Java may execute as well, although not at this time on the Google homepage. Scripts can cause additional network requests to be performed, as well as modify the page or its layout, causing another round of page rendering and painting.