Separating out the browser documentation doesn't make much sense now that we are only a browser. :^)
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SerenityOS Browser process architecture
NOTE: This document is partly aspirational, in that the state of the code does not yet fully reflect what's described here. Implementation is underway.
The SerenityOS web browser ("Browser") uses a multi-process architecture to improve stability and security in the face of arbitrary (and possibly hostile) web content.
Process overview
Every instance of the Browser application can have one or more tabs open. Each tab has a unique WebContent service process spawned on its behalf.
Two important aspects of web browsing are further separated from the WebContent process: network requests and image decoding, segregated to the RequestServer and ImageDecoder processes respectively.
All processes are aggressively sandboxed using the pledge()
and unveil()
mechanisms. Furthermore, all processes except Browser run as an unprivileged user, separate from the primary logged-in desktop user.
Process: WebContent
This process hosts the main HTML/CSS engine (LibWeb.) It also runs JavaScript (LibJS.) It gets input events from Browser and paints the web content into shared bitmaps. It can only communicate with the outside world via RequestServer.
Process: RequestServer
This process can use networking protocols (like HTTP or HTTPS) to request files from the outside world. Each WebContent process gets its own RequestServer to do uploading or downloading on its behalf.
For DNS lookups, RequestServer asks for help from the system's global LookupServer service, which handles all outgoing DNS requests.
Process: ImageDecoder
This process can decode images (PNG, JPEG, BMP, ICO, PBM, etc.) into bitmaps. Each image is decoded in a fresh ImageDecoder process. These are strongly sandboxed and can't do much except receive encoded bitmap data and return a bitmap to WebContent if decoding is successful.
How processes are spawned
To get a fresh WebContent process, anyone with the suitable file system permissions can spawn one by connecting to
the socket at /tmp/session/%sid/portal/webcontent
, with %sid
being the current login session id. This socket is managed
by SystemServer and will spawn a new instance of WebContent for every connection.
The same basic concept applies to RequestServer and ImageDecoder as well, except that those services are spawned by WebContent as needed, not by Browser.
Class overview
In the GUI application process, a OutOfProcessWebView
widget is placed somewhere in a window, and it takes care of spawning all of the helper processes, etc.
Internally, the OutOfProcessWebView
has a WebContentClient
object that implements the client side of the WebContent IPC protocol.
The WebContentClient
speaks to a WebContent::ConnectionFromClient
in the WebContent process. Internally, the WebContent::ConnectionFromClient
has a WebContent::PageHost
which hosts the LibWeb engine's main Web::Page
object.
Inside LibWeb, a Web::Page
has a main Web::Frame
, which may have subframes corresponding to <frame>
or <iframe>
HTML elements. Each Web::Frame
has a Web::Document
, which is the root node of the DOM tree.
Describing the LibWeb object model in detail is outside the scope of this document.