This is a library for controlling colours and formatting, such as red bold text or blue underlined text, on ANSI terminals.
Disclaimer: This crate is still in development, and is not yet available on crates.io
We promise to keep the API stable, and not break anything that is already working in the original crate.
There are three main types in this crate that you need to be concerned with: ANSIString
, Style
, and Colour
.
A Style
holds stylistic information: foreground and background colours, whether the text should be bold, or blinking, or other properties.
The Colour
enum represents the available colours.
And an ANSIString
is a string paired with a Style
.
Color
is also available as an alias to Colour
.
To format a string, call the paint
method on a Style
or a Colour
, passing in the string you want to format as the argument.
For example, here’s how to get some red text:
use ansi_term::Colour::Red;
println!("This is in red: {}", Red.paint("a red string"));
It’s important to note that the paint
method does not actually return a string with the ANSI control characters surrounding it.
Instead, it returns an ANSIString
value that has a Display
implementation that, when formatted, returns the characters.
This allows strings to be printed with a minimum of String
allocations being performed behind the scenes.
If you do want to get at the escape codes, then you can convert the ANSIString
to a string as you would any other Display
value:
use ansi_term::Colour::Red;
let red_string = Red.paint("a red string").to_string();
Note for Windows 10 users: On Windows 10, the application must enable ANSI support first:
let enabled = ansi_term::enable_ansi_support();
For anything more complex than plain foreground colour changes, you need to construct Style
values themselves, rather than beginning with a Colour
.
You can do this by chaining methods based on a new Style
, created with Style::new()
.
Each method creates a new style that has that specific property set.
For example:
use ansi_term::Style;
println!("How about some {} and {}?",
Style::new().bold().paint("bold"),
Style::new().underline().paint("underline"));
For brevity, these methods have also been implemented for Colour
values, so you can give your styles a foreground colour without having to begin with an empty Style
value:
use ansi_term::Colour::{Blue, Yellow};
println!("Demonstrating {} and {}!",
Blue.bold().paint("blue bold"),
Yellow.underline().paint("yellow underline"));
println!("Yellow on blue: {}", Yellow.on(Blue).paint("wow!"));
The complete list of styles you can use are:
bold
, dimmed
, italic
, underline
, blink
, reverse
, hidden
, and on
for background colours.
In some cases, you may find it easier to change the foreground on an existing Style
rather than starting from the appropriate Colour
.
You can do this using the fg
method:
use ansi_term::Style;
use ansi_term::Colour::{Blue, Cyan, Yellow};
println!("Yellow on blue: {}", Style::new().on(Blue).fg(Yellow).paint("yow!"));
println!("Also yellow on blue: {}", Cyan.on(Blue).fg(Yellow).paint("zow!"));
You can turn a Colour
into a Style
with the normal
method.
This will produce the exact same ANSIString
as if you just used the paint
method on the Colour
directly, but it’s useful in certain cases: for example, you may have a method that returns Styles
, and need to represent both the “red bold” and “red, but not bold” styles with values of the same type. The Style
struct also has a Default
implementation if you want to have a style with nothing set.
use ansi_term::Style;
use ansi_term::Colour::Red;
Red.normal().paint("yet another red string");
Style::default().paint("a completely regular string");
You can access the extended range of 256 colours by using the Colour::Fixed
variant, which takes an argument of the colour number to use.
This can be included wherever you would use a Colour
:
use ansi_term::Colour::Fixed;
Fixed(134).paint("A sort of light purple");
Fixed(221).on(Fixed(124)).paint("Mustard in the ketchup");
The first sixteen of these values are the same as the normal and bold standard colour variants.
There’s nothing stopping you from using these as Fixed
colours instead, but there’s nothing to be gained by doing so either.
You can also access full 24-bit colour by using the Colour::RGB
variant, which takes separate u8
arguments for red, green, and blue:
use ansi_term::Colour::RGB;
RGB(70, 130, 180).paint("Steel blue");
The benefit of writing ANSI escape codes to the terminal is that they stack: you do not need to end every coloured string with a reset code if the text that follows it is of a similar style. For example, if you want to have some blue text followed by some blue bold text, it’s possible to send the ANSI code for blue, followed by the ANSI code for bold, and finishing with a reset code without having to have an extra one between the two strings.
This crate can optimise the ANSI codes that get printed in situations like this, making life easier for your terminal renderer.
The ANSIStrings
struct takes a slice of several ANSIString
values, and will iterate over each of them, printing only the codes for the styles that need to be updated as part of its formatting routine.
The following code snippet uses this to enclose a binary number displayed in red bold text inside some red, but not bold, brackets:
use ansi_term::Colour::Red;
use ansi_term::{ANSIString, ANSIStrings};
let some_value = format!("{:b}", 42);
let strings: &[ANSIString<'static>] = &[
Red.paint("["),
Red.bold().paint(some_value),
Red.paint("]"),
];
println!("Value: {}", ANSIStrings(strings));
There are several things to note here.
Firstly, the paint
method can take either an owned String
or a borrowed &str
.
Internally, an ANSIString
holds a copy-on-write (Cow
) string value to deal with both owned and borrowed strings at the same time.
This is used here to display a String
, the result of the format!
call, using the same mechanism as some statically-available &str
slices.
Secondly, that the ANSIStrings
value works in the same way as its singular counterpart, with a Display
implementation that only performs the formatting when required.
This library also supports formatting [u8]
byte strings; this supports applications working with text in an unknown encoding.
Style
and Colour
support painting [u8]
values, resulting in an ANSIByteString
.
This type does not implement Display
, as it may not contain UTF-8, but it does provide a method write_to
to write the result to any value that implements Write
:
use ansi_term::Colour::Green;
Green.paint("user data".as_bytes()).write_to(&mut std::io::stdout()).unwrap();
Similarly, the type ANSIByteStrings
supports writing a list of ANSIByteString
values with minimal escape sequences:
use ansi_term::Colour::Green;
use ansi_term::ANSIByteStrings;
ANSIByteStrings(&[
Green.paint("user data 1\n".as_bytes()),
Green.bold().paint("user data 2\n".as_bytes()),
]).write_to(&mut std::io::stdout()).unwrap();