Text User Interface (Full screen applications)¶
quo can be used to create complex full screen terminal applications. Typically, an application consists of a layout (to describe the graphical part) and a set of key bindings.
The sections below describe the components required for full screen applications (or custom, non full screen applications), and how to assemble them together.
Note
Also remember that the examples
directory of the quo
repository contains plenty of examples. Each example is supposed to explain
one idea. So, this as well should help you get started.
Don’t hesitate to open a GitHub issue if you feel that a certain example is missing.
A simple application
¶
Almost every quo application is an instance of an Console
object. The simplest full screen example would look like this:
from quo import container
from quo.widget import Label
content = Label("Hello, world")
container(content)
This will only consume the least amount of space required.
Note
If we set the
full_screen
option, the application will run in an alternate screen buffer, in full screen mode.
Starting with v2022.4.5, ctrl-c will be the default key binder for to exit the app, you will still be able to define your own set of key bindings.
from quo import container
from quo.widget import TextField
content = TextField("Hello, world")
container(content, bind=True, full_screen=True)
An application consists of several components. The most important are:
I/O objects: the input and output device.
The layout: this defines the graphical structure of the application. For instance, a text box on the left side, and a button on the right side.
A style: this defines what colors and underline/bold/italic styles are used everywhere.
A set of key bindings.
We will discuss all of these in more detail below.
The layout
¶
Under the hood, class Layout
is the layout for function container()
.
"""simple example of a a text area displaying `Hello World!` """
from quo import container
from quo.widget import Box, Frame, TextArea
# Layout for displaying hello world.
# (The frame creates the border, the box takes care of the margin/padding.)
content = Box(
Frame(
TextField("Hello, world!!")
)
)
container(content, bind=True, full_screen=True)
In the example above, the Layout consists of Box
, Frame
and TextField
for displaying hello world.
The class Box
takes csre of the margin/padding, class Frame
creates the border, and class TextField
takes care of the text to be printed
A layered layout architecture¶
There are several ways to create a layout, depending on how customizable you want things to be. In fact, there are several layers of abstraction.
The most low-level way of creating a layout is by combining
Container
andUIControl
objects.Examples of
Container
objects areVSplit
(vertical split),HSplit
(horizontal split) andFloatContainer
. These containers arrange the layout and can split it in multiple regions. Each container can recursively contain multiple other containers. They can be combined in any way to define the “shape” of the layout.The
Window
object is a special kind of container that can contain aUIControl
object. TheUIControl
object is responsible for the generation of the actual content. TheWindow
object acts as an adaptor between theUIControl
and other containers, but it’s also responsible for the scrolling and line wrapping of the content.Examples of
UIControl
objects areBufferControl
for showing the content of an editable/scrollable buffer, andFormattedTextControl
for displaying (formatted) text.Normally, it is never needed to create new
UIControl
orContainer
classes, but instead you would create the layout by composing instances of the existing built-ins.A higher level abstraction of building a layout is by using “widgets”. A widget is a reusable layout component that can contain multiple containers and controls.
- Quo contains several widgets like:
Button
,Frame
,Label
,TextField
,VerticalLine
and so on.
The highest level abstractions can be found in the
dialog
module. There we don’t have to think about the layout, controls and containers at all. This is the simplest way to use quo, but is only meant for specific use cases, like a prompt or a simple dialog window.
Containers and controls¶
The biggest difference between containers and controls is that containers arrange the layout by splitting the screen in many regions, while controls are responsible for generating the actual content.
Note
Under the hood, the difference is:
containers use absolute coordinates, and paint on a
Screen
instance.user controls create a
UIContent
instance. This is a collection of lines that represent the actual content. AUIControl
is not aware of the screen.
Abstract base class |
Examples |
---|---|
|
|
|
|
The Window
class itself is
particular: it is a Container
that
can contain a UIControl
. Thus, it’s the adaptor
between the two. The Window
class also takes
care of scrolling the content and wrapping the lines if needed.
Finally, there is the Layout
class which wraps
the whole layout. This is responsible for keeping track of which window has the
focus.
Here is an example of a layout that displays the content of the default buffer
on the left, and displays "Hello world"
on the right. In between it shows a
vertical line:
from quo import container
from quo.buffer import Buffer
from quo.layout import BufferControl, FormattedTextControl, VSplit, Window
buffer1 = Buffer() # Editable buffer.
content = VSplit([
# One window that holds the BufferControl with the default buffer on the left.
Window(BufferControl(buffer=buffer1)),
# A vertical line in the middle. We explicitly specify the width, to
# make sure that the layout engine will not try to divide the whole
# width by three for all these windows. The window will simply fill its
# content by repeating this character.
Window(width=1, char='|'),
# Display the text 'Hello world' on the right.
Window(FormattedTextControl('Hello world')),
])
container(content, full_screen=True)
# You won't be able to Exit this app unless you add a key binder
Notice that if you execute this right now, there is no way to quit this application yet. This is something we explain in the next section below.
More complex layouts can be achieved by nesting multiple
VSplit
,
HSplit
and
FloatContainer
objects.
If you want to make some part of the layout only visible when a certain
condition is satisfied, use a
ConditionalContainer
.
Finally, there is ScrollablePane
, a container
class that can be used to create long forms or nested layouts that are
scrollable as a whole.
Key bindings
¶
In order to react to user actions, we need to create a
Bind
object using quo.keys.bind()
There are two kinds of key bindings:
Global key bindings, which are always active.
Key bindings that belong to a certain
UIControl
and are only active when this control is focused. BothBufferControl
FormattedTextControl
takes abind
argument.
Global key bindings¶
Key bindings can be passed to the application as follows:
from quo import container
from quo.keys import bind
container(bind=True)
Registering Key bindings¶
To register a new keyboard shortcut, we can use the
add()
method as a decorator of the key handler:
from quo import container
from quo.keys import bind
from quo.widget import TextField
content = TextField("Hello, world")
# A custom Key binder to exit the application
@bind.add("ctrl-q")
def exit_(event):
"""
Pressing "ctrl-q" will exot the user interface
"""
event.app.exit()
container(content, bind=True, full_screen=True)
The callback function is named exit_
for clarity, but it could have been named _
(underscore) as well, or anything you see fit
Read more about key bindings
HSplit¶
Several layouts, one stacked above/under the other. like so:
+--------------------+
| |
+--------------------+
| |
+--------------------+
By default, this doesn’t display a horizontal line between the children, but if this is something you need, then create a HSplit as follows:
HSplit(subset=[ ... ], padding_char='-', padding=1, padding_style='fg:red')
Parameters
subset
- List of childContainer
objects.
window_too_small
- AContainer
object that is displayed if there is not enough space for all the subsets. By default, this is a “Window too small” message.
align
- A VerticalAlign value. i.etop
,center
,bottom
orjustify
width
- When given, use this width instead of looking at the subsets.
height
- When given, use this height instead of looking at the subsets.
z_index
- (int or None) When specified, this can be used to bring element in front of floating elements. None means: inherit from parent.
style
- A style string.
modal
(bool) - Settingmodal=True
makes what is called a modal container. Normally, a subset container would inherit its parent key bindings. This does not apply to modal containers.
bind
-None
or aBind
object.
padding
- (Dimension or int), size to be used for the padding. -padding_char
- Character to be used for filling in the padding.
padding_style
- Style to applied to the padding.
from quo import container
from quo.layout import HSplit, Window
from quo.widget import Label
# 1. The layout
content = HSplit([
Label("\n\n(Top pane)"),
Window(height=1, char="-"), # Horizontal line in the middle.
Label("\n\n(Bottom pane)")
])
# 2. The `Application`
# Press `ctrl-c` to exit
container(content, bind=True)
VSplit¶
Several layouts, one stacked left/right of the other like so:
+---------+----------+
| | |
| | |
+---------+----------+
By default, this doesn’t display a vertical line between the children, but if this is something you need, then create a VSplit as follows:
VSplipt([ ... ], padding_char='|', padding=1, padding_style='fg:blue')
- Parameters
subset
- List of subsetsContainer
objects.window_too_small
- AContainer
object that is displayed if there is not enough space for all the children. By default, this is a “Window too small” message.align
- A HorizontalAlign value. i.eleft
,centre
,right
orjustify
width
- When given, use this width instead of looking at the subsets.height
- When given, use this height instead of looking at the subsets.z_index
- (int or None) When specified, this can be used to bring element in front of floating elements. None means: inherit from parent.style
- A style string.modal
(bool) - Settingmodal=True
makes what is called a modal container. Normally, a subset container would inherit its parent key bindings. This does not apply to modal containers.bind
-None
or aBind
object.padding
- (Dimension or int), size to be used for the padding.padding_char
- Character to be used for filling in the padding.padding_style
- Style to applied to the padding.
# Press `ctrl-c` to exit
from quo import container
from quo.layout import VSplit, Window
from quo.widget import Label
# 1. The layout
content = VSplit([
Label("(Left pane)"),
Window(width=1, char="|"), # Vertical line in the middle.
Label("(Right pane)")
])
container(content, bind=True, full_screen=True)
VSplit
and HSplit
take a modal
argument.
Setting modal=True
makes what is called a modal container. Normally, a child container would inherit its parent key bindings. This does not apply to modal containers.
Consider a modal container (e.g. VSplit
)
is child of another container, its parent. Any key bindings from the parent are not taken into account if the modal container (subset) has the focus.
This is useful in a complex layout, where many controls have their own key bindings, but you only want to enable the key bindings for a certain region of the layout.
The global key bindings are always active.
Window¶
Window
is a Container
that wraps a UIControl
, like a BufferControl
or FormattedTextControl
.
- Parameters
content
-UIControl
instance.width
-Dimension
instance or callable.height
-Dimension
instance or callable.z_index
- When specified, this can be used to bring element in front of floating elements.dont_extend_width
(bool) - When True, don’t take up more width then the preferred width reported by the control.dont_extend_height
(bool) - When True, don’t take up more width then the preferred height reported by the control.ignore_content_width
(bool) - A bool orFilter
instance. Ignore theUIContent
width when calculating the dimensions.ignore_content_height
(bool) - A bool orFilter
instance. Ignore theUIContent
height when calculating the dimensions.left_margins
- A list ofMargin
instance to be displayed on the left. For instance:NumberedMargin
can be one of them in order to show line numbers.right_margins
- Like left_margins, but on the other side.scroll_offsets
-ScrollOffsets
instance, representing the preferred amount of lines/columns to be always visible before/after the cursor. When both top and bottom are a very high number, the cursor will be centered vertically most of the time.allow_scroll_beyond_bottom
(bool) - A bool orFilter
instance. When True, allow scrolling so far, that the top part of the content is not visible anymore, while there is still empty space available at the bottom of the window. In the Vi editor for instance, this is possible. You will see tildes while the top part of the body is hidden.wrap_lines
(bool)* - A bool orFilter
instance. When True, don’t scroll horizontally, but wrap lines instead.get_vertical_scroll
- Callable that takes this window instance as input and returns a preferred vertical scroll. (When this is `None`, the scroll is only determined by the last and current cursor position.)get_horizontal_scroll
- Callable that takes this window instance as input and returns a preferred vertical scroll.always_hide_cursor
(bool) - A bool orFilter
instance. When True, never display the cursor, even when the user control specifies a cursor position.cursorline
(bool) - A bool orFilter
instance. When True, display a cursorline.cursorcolumn
(bool) - A bool orFilter
instance When True, display a cursorcolumn.colorcolumns
- A list ofColorColumn
instances that describe the columns to be highlighted, or a callable that returns such a list.align
-WindowAlign
value or callable that returns anWindowAlign
value. alignment of content. i.eleft
,centre
orright
style
- A style string. Style to be applied to all the cells in this window. (This can be a callable that returns a string.)char
(str) - Character to be used for filling the background. This can also be a callable that returns a character.get_line_prefix
- None or a callable that returns formatted text to atted text to be inserted before a line. It takes a line number (int) and a wrap_count and returns formatted text. This can be used for implementation of line continuations, things like Vim “breakindent”.
FloatContainer¶
Container which can contain another container for the background, as well as a list of floating containers on top of it.
Parameters
content
-AnyContainer
object
z_index
- (int or None) When specified, this can be used to bring element in front of floating elements. None means: inherit from parent. This is the z_index for the whole Float container as a whole.
floats
- List ofFloat
object.
modal
(bool) - Settingmodal=True
makes what is called a modal container. Normally, a subset container would inherit its parent key bindings. This does not apply to modal containers.
bind
-None
or aBind
object.
style
- A style string.
Example Usage: .. code:: python
- FloatContainer(
Window(…), floats=[
- Float(
xcursor=True, ycursor=True, content=CompletionsMenu(…)
) ])
More about buffers and BufferControl
¶
Input processors¶
A Processor
is used to postprocess
the content of a BufferControl
before it’s
displayed. It can for instance highlight matching brackets or change the
visualisation of tabs and so on.
A Processor
operates on individual
lines. Basically, it takes a (formatted) line and produces a new (formatted)
line.
Some build-in processors:
Processor |
Usage: |
---|---|
|
Highlight the current search results. |
|
Highlight the selection. |
|
Display input as asterisks. ( |
|
Highlight open/close mismatches for brackets. |
|
Insert some text before. |
|
Insert some text after. |
|
Append auto suggestion text. |
|
Visualise leading whitespace. |
|
Visualise trailing whitespace. |
|
Visualise tabs as n spaces, or some symbols. |
A BufferControl
takes only one processor as
input, but it is possible to “merge” multiple processors into one with the merge_processors()
function
» Check out more examples here