# The Widget system This document explains how to define, place and manage widgets. ## The default configuration This is what the widgets present in the default configuration are named: @DOC_awful_popup_defaultconfig_EXAMPLE@ ## The default widgets ### Widgets Awesome provides 2 collections of widgets: * `wibox.widget`: Generic widgets, containers and layouts * `awful.widget`: The Awesome specific widgets @DOC_widget_WIDGET_LIST@ ### Containers A container is a widget that wraps another widget. It can be used to add decorations or to modify the content of the child widget. @DOC_container_WIDGET_LIST@ ### Layouts Layouts are collections of children widgets. They are placed according to configurable rules. @DOC_layout_WIDGET_LIST@ ### Awful widgets This modules contains the higher level window manager widgets. Since most of them are used by the default config, here is how it maps: @DOC_awful_wibar_defaultwibar_EXAMPLE@ @DOC_awidget_WIDGET_LIST@ ### Titlebar widgets The titlebar comes with some convinient default widgets. It simplify the most basic "Windows/macOS" like titlebars. @DOC_awful_titlebar_defaulttitlebar_EXAMPLE@ Note that titlebars can also be added on each side. This is how "active" titlebars (click to resize) can be implemented. The default `rc.lua` does not add active borders: ![](../images/client_geo.svg)
WidgetDescription
`awful.titlebar.widget.iconwidget`The client icon (see `client.icon`)
`awful.titlebar.widget.titlewidget`The client title (see `client.name`)
`awful.titlebar.widget.floatingbutton` Toggle the floating (toggled) vs. tiling mode (untoggled).
`awful.titlebar.widget.maximizedbutton`Toggle the maximized mode (toggled). Note that this is the
"full" maximized mode, not vertical or horizontal maximization.
See `client.maximized`.
`awful.titlebar.widget.stickybutton`When toggled, a client will be displayed in all (screen) tags. See `client.sticky`)
`awful.titlebar.widget.ontopbutton`When toggled, the client will be part of the `ontop` layer (see `client.ontop`).
`awful.titlebar.widget.closebutton`
`titlebar.widget.minimizebutton`
### Notification widgets Notifications also have their own widgets. More information about the notification widgets can be found on the `naughty.notification` documentation page. ### The different type of widget boxes (Wibox) The Awesome API uses the word "wibox" (widget box) to describe an area of the screen filled with widgets. There are many subvariants of wiboxes with specialized roles such as widget bars or tooltips. All variants mostly share the same characteristics, but add some extra features to make those specialized widget boxes easier to work with. @DOC_awful_popup_wiboxtypes_EXAMPLE@ The normal `wibox` is the base class for each of these types. It is extremely flexible and allows to place just about anything on the screen. However it requires a lot of repetitive boilerplate code to use directly. For example, the user needs to compute the optimal size by hand or use `awful.placement`. The `awful.wibar` specialization allows to attach a `wibox` to a screen edge and prevents clients from using this area when tiled. The `awful.popup` allows to easily place widgets on the screen. It automatically resizes itself to fit the optimal widget size. It also has helper properties and methods to make it easy to place it on the screen. It supports absolute positioning, relative positioning, and manual positioning. The `awful.tooltip` is a very simple `wibox` that allows to display text next to an object such as the mouse. The `naughty.layout.box` allows to provide custom widgets to use within the notifications. Finally, the `awful.titlebar`, while not technically a real `wibox`, acts exactly the same way and allows to attach widgets on each side of clients. ## The different syntaxes to initiate widgets Awesome provides 2 totally different API access styles to manage widgets. Both suit different use cases. Under the hood, both produce the exact same code. Consider the declarative API to be compiled into the imperative syntax when loaded. Also note that in contrast to technologies such as QML, it is interpreted only once and isn't automatically updated when values change. The **imperative** widget initialization is similar to QtWidgets, GTK and Win32. You create the object, then set the property and add the widget as a child to another already declared widget. It is quite simple to use but very verbose and full of boilerplate code. The imperative API also offers properties both with accessors or directly. It is useful when creating highly dynamic layouts where widgets are added and removed over the course of their lifecycle. The **declarative** syntax resembles HTML style code written in JSON or YAML. The widget instances are created automatically and the hierarchy is related to the table nesting (indentation). It is preferred when creating static layouts that won't change over the course of their lifecycle. Here is the same code written in both the imperative and declarative style **Imperative with accessors** Code: local bg = wibox.container.background() bg:set_bg("#ff0000") local tb1 = wibox.widget.textbox() local tb2 = wibox.widget.textbox("bar") tb1:set_text("foo") tb2:set_text("bar") local l = wibox.layout.fixed.vertical() l:add(tb1) l:add(tb2) bg:set_widget(l) **Imperative with properties** Code: local bg = wibox.container.background() bg.bg = "#ff0000" local tb1 = wibox.widget.textbox("foo") local tb2 = wibox.widget.textbox("bar") tb1.text = "foo" tb2.text = "bar" local l = wibox.layout.fixed.vertical() l:add(tb1) l:add(tb2) bg.widget = l **Declarative** Code: local bg = wibox.widget { { { text = "foo", widget = wibox.widget.textbox }, { text = "bar", widget = wibox.widget.textbox }, layout = wibox.layout.fixed.vertical }, bg = "#ff0000", widget = wibox.container.background } The Awesome documentation mostly uses the declarative style for consistency, but both are **always** available. Note that each style can be mixed with other styles, but this creates very confusing code and should be avoided. ## Creating and placing widgets using the declarative style The examples below explain in detail how to use the declarative layout system. The imperative system is quite self explanatory and the respective widget API documentation should be enough for most. ### A simple layout * Display `my_first_widget` only on primary screen * Display `my_second_widget` only on screen two * Add a background color to `my_fourth_widget` * Dispose in a `wibox.layout.fixed.horizontal` layout Code: s.mywibox : setup { { layout = awful.widget.only_on_screen, screen = "primary", -- Only display on primary screen my_first_widget, }, { layout = awful.widget.only_on_screen, screen = 2, -- Only display on screen 2 my_second_widget, }, my_third_widget, -- Displayed on all screens { -- Add a background color/pattern for my_fourth_widget my_fourth_widget, bg = beautiful.bg_focus, widget = wibox.container.background, }, layout = wibox.layout.fixed.horizontal, } This examples uses the `awful.widget.only_on_screen` container to display widgets only on some screens. ### Composite widgets @DOC_wibox_widget_progressbar_encapsulation_EXAMPLE@ ### Define widgets inline and place them * Create a `wibox.widget.textbox` with various properties * Force the textbox size using `wibox.layout.constraint` * Add a margin around another textbox * Add a `wibox.container.background` (for visualization) Code: s.mywibox : setup { { -- Force the textbox to always be 300 pixel long { { markup = "Hello World!", align = "center", widget = wibox.widget.textbox }, bg = "#ff0000", widget = wibox.container.background, }, width = 300, strategy = "min", layout = wibox.layout.constraint }, { -- Add a border around the background { { markup = "Foobar", widget = wibox.widget.textbox }, bg = "#0000ff", widget = wibox.container.background }, left = 10, right = 10, top = 1, bottom = 2, layout = wibox.container.margin }, layout = wibox.layout.fixed.horizontal, } Result: ![Example2 screenshot](../images/widgetlayout1.png) ### Use a `wibox.layout.align` layout The `wibox.layout.align` is a little different. While most layouts will ignore any `nil` lines, the `align` layout relies on them so `left`, `middle` and `right` can be defined. Code: s.mywibox : setup { my_textbox1, -- Left nil, -- Nothing in the middle my_textbox2, -- Right layout = wibox.layout.align.horizontal, } ### Define new widgets New trivial widgets can be created directly in the layout declaration. Here is a simple circle widget: Code: s.mywibox : setup { fit = function(self, context, width, height) return height, height -- A square taking the full height end, draw = function(self, context, cr, width, height) cr:set_source_rgb(1, 0, 0) -- Red cr:arc(height/2, height/2, height/2, 0, math.pi*2) cr:fill() end, layout = wibox.widget.base.make_widget, } Result: ![Example4 screenshot](../images/widgetlayout2.png) For more information about how to draw widgets, refer to the `Cairo` API: * [Path](http://cairographics.org/manual/cairo-Paths.html) * [Context](http://cairographics.org/manual/cairo-cairo-t.html) * [Pattern](http://cairographics.org/manual/cairo-cairo-pattern-t.html) * [transformation](http://cairographics.org/manual/cairo-Transformations.html) * [Operator](http://cairographics.org/operators/) * [Pango text](https://developer.gnome.org/pango/stable/) ### Externally defined widgets and layouts This is useful when the widget is provided by an external module or when it requires complex manipulations which would make the declaration unreadable. Code: local tb = wibox.widget.textbox() tb:set_markup("Hello world! ") -- Repeat "tb" 3 times s.mywibox : setup { tb, tb, tb, layout = wibox.layout.fixed.horizontal, } ### Accessing widgets For each widget or container, it is possible to add an `identifier` attribute so that it can be accessed later. Widgets defined using `setup` can be accessed using these methods: * Avoiding the issue by using externally created widgets * Using `my_wibox.my_first_widget.my_second_widget` style access * Using JavaScript like `my_wibox:get_children_by_id("my_second_widget")[1]` The first method mixes the imperative and declarative syntax, and makes the code less readable. The second is a little verbose and only works if every node in the chain has a valid identifier. The last one doesn't require long paths, but it is not easy to get a specific instance if multiple widgets have the same identifier. WARNING: The widget identifier must not use a reserved name. This includes all method names, existing widget attributes, `layout` and `widget`. Names should also respect the Lua variable conventions (case-sensitive, alphanumeric, underscore characters and non-numeric first character). Code: s.mywibox : setup { { id = "second", widget = wibox.widget.textbox }, { id = "third", widget = wibox.widget.textbox }, id = "first", layout = wibox.layout.fixed.horizontal, } s.mywibox.first.second:set_markup("changed!") s.mywibox:get_children_by_id("third")[1]:set_markup("Also changed!") ### Extending the system This system is very flexible. Each section attribute (the entries with string keys) is directly linked to the layout or widget API. When setting the imaginary `myproperty`, it will first check if `set_myproperty` exists. If it doesn't, it will check if there is a `myproperty` method. Finally, it will just set the `mywidget.myproperty` directly in case it is used later or caught by a Lua `metatable` (operator overload). Code: -- "Monkeypatch" a new function to 3 widget classes to add vicious -- extension support for _, wdg in ipairs { wibox.widget.textbox , wibox.widget.progressbar, wibox.widget.graph } do function wdg:vicious(args) local f = unpack or table.unpack -- Lua 5.1 compat vicious.register(self, f(args)) end end s.mywibox : setup { { vicious = {vicious.widgets.cpu, "CPU: $1%", 3}, widget = wibox.widget.textbox }, layout = wibox.layout.fixed.horizontal, } In this example, the system is extended so that the popular [Vicious](https://github.com/vicious-widgets/vicious) extension module can be used directly in the layout declaration. This example will update the textbox every 3 seconds to show the CPU usage. ### Handling sections The system allows sections to be defined externally, then composed into the final layout declaration. Here is an example re-using one of the above example: Code: local circle = { fit = function(self, context, width, height) return height, height -- A square taking the full height end, draw = function(self, context, cr, width, height) cr:set_source_rgb(1, 0, 0) -- Red cr:arc(height/2, height/2, height/2, 0, math.pi*2) cr:fill() end, layout = wibox.widget.base.make_widget, } -- Define a layout with the imperative syntax local l = wibox.widget.align() -- 3 circle s.mywibox : setup { circle, circle, circle, l, layout = wibox.layout.align.horizontal } -- This can be done instead local three_circle = {layout = wibox.layout.align.horizontal} for i=1, 3 do table.insert(three_circle, circle) end s.mywibox : setup (three_circle) ### Instantiation rules Whenever it can, Awesome tries to be asynchronous. This can take various form depending on the situation. For example, the `connect_signal` method allows to execute code when an event arrives. `awful.screen.connect_for_each_screen` also allows to instantiate various elements when a new screen is added. In the later case, it is why some widgets are added as properties to other objects instead of being global variables like in previous versions of Awesome. However, there is a case where this isn't enough and another abstract widget has to be used. This concept is called the `widget_template` and is an optional property of many widgets such as the `awful.widget.taglist`, `awful.widget.tasklist` and `naughty.layout.box`. These templates are a **table** using the exact same syntax as the declarative widgets, but without the `wibox.widget` prefix in front of the curly braces. These templates represents future widgets that will be created by their parent widget. This is necessary for three reasons: * The widget must create many instances of the template at different points in time. * The widget data is only partially available and other fields must be set at a later time (by the parent widget). * The code is highly redundant and some of the logic is delegated to the parent widget to simplify everything.