Add how to hack guide, first version
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Hacking i3: How To
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==================
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Michael Stapelberg <michael+i3@stapelberg.de>
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March 2009
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This document is intended to be the first thing you read before looking and/or touching
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i3’s source code. It should contain all important information to help you understand
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why things are like they are. If it does not mention something you find necessary, please
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do not hesitate to contact me.
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== Window Managers
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A window manager is not necessarily needed to run X, but it is usually used in combination
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to facilitate some things. The window manager's job is to take care of the placement of
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windows, to provide the user some mechanisms to change the position/size of windows and
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to communicate with clients to a certain extent (for example handle fullscreen requests
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of clients such as MPlayer).
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There are no different contexts in which X11 clients run, so a window manager is just another
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client, like all other X11 applications. However, it handles some events which normal clients
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usually don’t handle.
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In the case of i3, the tasks (and order of them) are the following:
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. Grab the key bindings (events will be sent upon keypress/keyrelease)
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. Iterate through all existing windows (if the window manager is not started as the first
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client of X) and manage them (= reparent them, create window decorations)
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. When new windows are created, manage them
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. Handle the client’s _WM_STATE property, but only the _WM_STATE_FULLSCREEN
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. Handle the client’s WM_NAME property
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. Handle the client’s size hints to display them proportionally
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. Handle enter notifications (focus follows mouse)
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. Handle button (as in mouse buttons) presses for focus/raise on click
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. Handle expose events to re-draw own windows such as decorations
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. React to the user’s commands: Change focus, Move windows, Switch workspaces,
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Change the layout mode of a container (default/stacking), Start a new application,
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Restart the window manager
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In the following chapters, each of these tasks and their implementation details will be discussed.
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== Files
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include/data.h::
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Contains data definitions used by nearly all files. You really need to read this first.
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include/*.h::
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Contains forward definitions for all public functions.
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src/commands.c::
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Parsing commands
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src/config.c::
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Parses the configuration file
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src/debug.c::
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Contains debugging functions to print unhandled X events
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src/handlers.c::
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Contains all handlers for all kind of X events
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src/layout.c::
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Renders your layout (screens, workspaces, containers)
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src/mainx.c::
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Initializes the window manager
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src/table.c::
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Manages the most important internal data structure, the design table.
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src/util.c::
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Contains useful functions which are not really dependant on anything.
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src/xcb.c::
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Contains wrappers to use xcb more easily.
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src/xinerama.c::
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(Re-)initializes the available screens and converts them to virtual screens (see below).
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== Data structures
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See include/data.h for documented data structures.
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=== Virtual screens
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A virtual screen (type i3Screen) is generated from the connected screens obtained
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through Xinerama. The difference to the raw Xinerama monitors as seen when using xrandr(1)
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is that it falls back to the lowest common resolution of the logical screens.
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For example, if your notebook has 1280x800 and you connect a video projector with
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1024x768, set up in clone mode (xrandr --output VGA --mode 1024x768 --same-as LVDS),
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i3 will have one virtual screen.
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However, if you configure it using xrandr --output VGA --mode 1024x768 --right-of LVDS,
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i3 will generate two virtual screens. For each virtual screen, a new workspace will be
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assigned. New workspaces are created on the screen you are currently on.
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== List/queue macros
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i3 makes heavy use of the list macros defined in BSD operating systems. To ensure
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that the operating system on which i3 is compiled has all the awaited features,
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i3 comes with include/queue.h. On BSD systems, you can use man queue(3). On Linux,
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you have to use google.
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The lists used are SLISTs (single linked lists) and CIRCLEQ (circular queues).
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Usually, only forward traversal is necessary, so an SLIST works fine. However,
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for the windows inside a container, a CIRCLEQ is necessary to go from the currently
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selected window to the window above/below.
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== Naming conventions
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There is a row of standard variables used in many events. The following names should be
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chosen for those:
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* "conn" is the xcb_connection_t
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* "event" is the event of the particular type
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* "container" names a container
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* "client" names a client, for example when using a CIRCLEQ_FOREACH
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== Startup (src/mainx.c)
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* Establish the xcb connection
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* Check for XKB extension on the separate X connection
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* Check for Xinerama screens
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* Grab the keycodes for which bindings exist
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* Manage all existing windows
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* Enter the event loop
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== Keybindings
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=== Grabbing the bindings
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Grabbing the bindings is quite straight-forward. You pass X your combination of modifiers and
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the keycode you want to grab and whether you want to grab them actively or passively. Most
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bindings (everything except for bindings using Mode_switch) are grabbed passively, that is,
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just the window manager gets the event and cannot replay it.
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We need to grab bindings that use Mode_switch actively because of a bug in X. When the window
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manager receives the keypress/keyrelease event for an actively grabbed keycode, it has to decide
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what to do with this event: It can either replay it so that other applications get it or it
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can prevent other applications from receiving it.
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So, why do we need to grab keycodes actively? Because X does not set the state-property of
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keypress/keyrelease events properly. The Mode_switch bit is not set and we need to get it
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using XkbGetState. This means we cannot pass X our combination of modifiers containing Mode_switch
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when grabbing the key and therefore need to grab the keycode itself without any modiffiers.
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This means, if you bind Mode_switch + keycode 38 ("a"), i3 will grab keycode 38 ("a") and
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check on each press of "a" if the Mode_switch bit is set using XKB. If yes, it will handle
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the event, if not, it will replay the event.
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=== Handling a keypress
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As mentioned in "Grabbing the bindings", upon a keypress event, i3 first gets the correct state.
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Then, it looks through all bindings and gets the one which matches the received event.
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The bound command is parsed directly in command mode.
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== Manage windows (src/mainx.c, manage_window() and reparent_window())
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manage_window() does some checks to decide whether the window should be managed at all:
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* Windows have to be mapped, that is, visible on screen
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* The override_redirect must not be set. Windows with override_redirect shall not be
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managed by a window manager
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Afterwards, i3 gets the intial geometry and reparents the window if it wasn’t already
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managed.
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Reparenting means that for each window which is reparented, a new window, slightly larger
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than the original one, is created. The original window is then reparented to the bigger one
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(called "frame").
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After reparenting, the window type (_NET_WM_WINDOW_TYPE) is checked to see whether this
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window is a dock (_NET_WM_WINDOW_TYPE_DOCK), like dzen2 for example. Docks are handled
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differently, they don’t have decorations and are not assigned to a specific container.
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Instead, they are positioned at the bottom of the screen. To get the height which needsd
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to be reserved for the window, the _NET_WM_STRUT_PARTIAL property is used.
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== What happens when an application is started?
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i3 does not care for applications. All it notices is when new windows are mapped (see
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src/handlers.c, handle_map_notify_event()). The window is then reparented (see section
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"Manage windows").
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After reparenting the window, render_layout() is called which renders the internal
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layout table. The window was placed in the currently focused container and
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therefore the new window and the old windows (if any) need te be moved/resized
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so that the currently active layout (default mode/stacking mode) is rendered
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correctly. To move/resize windows, a window is "configured" in X11-speak.
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Some applications, such as MPlayer obivously assume the window manager is stupid
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and therefore configure their windows by themselves. This generates an event called
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configurenotify. i3 handles these events and pushes the window back to its position/size.
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== _NET_WM_STATE
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Only the _NET_WM_STATE_FULLSCREEN atom is handled. It calls toggle_fullscreen() for the
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specific client which just configures the client to use the whole screen on which it
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currently is. Also, it is set as fullscreen_client for the i3Screen.
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== WM_NAME
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When the WM_NAME property of a window changes, its decoration (containing the title)
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is re-rendered.
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== Size hints
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== Rendering
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There are two entry points to rendering: render_layout() and render_container(). The
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former one renders all virtual screens, the currently active workspace of each virtual
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screen and all containers (inside the table cells) of these workspaces using
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render_container(). Therefore, if you need to render only a single container, for
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example because a window was removed, added or changed its title, you should directly
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call render_container().
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Rendering consists of two steps: In the first one, in render_layout(), each container
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gets its position (screen offset + offset in the table) and size (container's width
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times colspan/rowspan). Then, render_container() is called:
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render_container() then takes different approaches, depending on the mode the container
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is in.
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=== Common parts
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On the frame (the window which was created around the client’s window for the decorations),
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a black rectangle is drawn as a background for windows like MPlayer, which don’t completely
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fit into the frame.
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=== Default mode
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Each clients gets the container’s width and an equal amount of height.
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=== Stack mode
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In stack mode, a window containing the decorations of all windows inside the container
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is placed at the top. The currently focused window is then given the whole remaining
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space.
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=== Window decorations
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The window decorations consist of a rectangle in the appropriate color (depends on whether
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this window is the currently focused one or the last focused one in a not focused container
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or not focused at all) forming the background. Afterwards, two lighter lines are drawn
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and the last step is drawing the window’s title (see WM_NAME) onto it.
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=== Resizing containers
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By clicking and dragging the border of a container, you can resize it freely.
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TODO
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== User commands / commandmode (src/commands.c)
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Like in vim, you can control i3 using commands. They are intended to be a powerful
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alternative to lots of shortcuts, because they can be combined. There are a few special
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commands, which are the following:
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exec::
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Starts the given command by passing it to /bin/sh.
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restart::
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Restarts i3 by executing argv[0] (the path with which you started i3) without forking.
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w::
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"With". This is used to select a bunch of windows. Currently, only selecting the whole
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container in which the window is in, is supported by specifying "w".
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f, s, d::
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Toggle fullscreen, stacking, default mode for the current window/container.
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The other commands are to be combined with a direction. The directions are h, j, k and l,
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like in vim (h = left, j = down, k = up, l = right). When you just specify the direction
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keys, i3 will move the focus in that direction. You can provide "m" or "s" before the
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direction to move a window respectively or snap.
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