#![allow(missing_docs)] use crate::style::{Color, Style}; use crate::write::AnyWrite; use std::fmt; impl Style { /// Write any bytes that go *before* a piece of text to the given writer. fn write_prefix(&self, f: &mut W) -> Result<(), W::Error> { // If there are actually no styles here, then don’t write *any* codes // as the prefix. An empty ANSI code may not affect the terminal // output at all, but a user may just want a code-free string. if self.is_plain() { return Ok(()); } // Write the codes’ prefix, then write numbers, separated by // semicolons, for each text style we want to apply. write!(f, "\x1B[")?; let mut written_anything = false; { let mut write_char = |c| { if written_anything { write!(f, ";")?; } written_anything = true; write!(f, "{}", c)?; Ok(()) }; if self.is_bold { write_char('1')? } if self.is_dimmed { write_char('2')? } if self.is_italic { write_char('3')? } if self.is_underline { write_char('4')? } if self.is_blink { write_char('5')? } if self.is_reverse { write_char('7')? } if self.is_hidden { write_char('8')? } if self.is_strikethrough { write_char('9')? } } // The foreground and background colors, if specified, need to be // handled specially because the number codes are more complicated. // (see `write_background_code` and `write_foreground_code`) if let Some(bg) = self.background { if written_anything { write!(f, ";")?; } written_anything = true; bg.write_background_code(f)?; } if let Some(fg) = self.foreground { if written_anything { write!(f, ";")?; } fg.write_foreground_code(f)?; } // All the codes end with an `m`, because reasons. write!(f, "m")?; Ok(()) } /// Write any bytes that go *after* a piece of text to the given writer. fn write_suffix(&self, f: &mut W) -> Result<(), W::Error> { if self.is_plain() { Ok(()) } else { write!(f, "{}", RESET) } } } /// The code to send to reset all styles and return to `Style::default()`. pub static RESET: &str = "\x1B[0m"; impl Color { fn write_foreground_code(&self, f: &mut W) -> Result<(), W::Error> { match self { Color::Black => write!(f, "30"), Color::Red => write!(f, "31"), Color::Green => write!(f, "32"), Color::Yellow => write!(f, "33"), Color::Blue => write!(f, "34"), Color::Purple => write!(f, "35"), Color::Magenta => write!(f, "35"), Color::Cyan => write!(f, "36"), Color::White => write!(f, "37"), Color::Fixed(num) => write!(f, "38;5;{}", num), Color::Rgb(r, g, b) => write!(f, "38;2;{};{};{}", r, g, b), Color::DarkGray => write!(f, "90"), Color::LightRed => write!(f, "91"), Color::LightGreen => write!(f, "92"), Color::LightYellow => write!(f, "93"), Color::LightBlue => write!(f, "94"), Color::LightPurple => write!(f, "95"), Color::LightMagenta => write!(f, "95"), Color::LightCyan => write!(f, "96"), Color::LightGray => write!(f, "97"), } } fn write_background_code(&self, f: &mut W) -> Result<(), W::Error> { match self { Color::Black => write!(f, "40"), Color::Red => write!(f, "41"), Color::Green => write!(f, "42"), Color::Yellow => write!(f, "43"), Color::Blue => write!(f, "44"), Color::Purple => write!(f, "45"), Color::Magenta => write!(f, "45"), Color::Cyan => write!(f, "46"), Color::White => write!(f, "47"), Color::Fixed(num) => write!(f, "48;5;{}", num), Color::Rgb(r, g, b) => write!(f, "48;2;{};{};{}", r, g, b), Color::DarkGray => write!(f, "100"), Color::LightRed => write!(f, "101"), Color::LightGreen => write!(f, "102"), Color::LightYellow => write!(f, "103"), Color::LightBlue => write!(f, "104"), Color::LightPurple => write!(f, "105"), Color::LightMagenta => write!(f, "105"), Color::LightCyan => write!(f, "106"), Color::LightGray => write!(f, "107"), } } } /// Like `ANSIString`, but only displays the style prefix. /// /// This type implements the `Display` trait, meaning it can be written to a /// `std::fmt` formatting without doing any extra allocation, and written to a /// string with the `.to_string()` method. For examples, see /// [`Style::prefix`](struct.Style.html#method.prefix). #[derive(Clone, Copy, Debug)] pub struct Prefix(Style); /// Like `ANSIString`, but only displays the difference between two /// styles. /// /// This type implements the `Display` trait, meaning it can be written to a /// `std::fmt` formatting without doing any extra allocation, and written to a /// string with the `.to_string()` method. For examples, see /// [`Style::infix`](struct.Style.html#method.infix). #[derive(Clone, Copy, Debug)] pub struct Infix(Style, Style); /// Like `ANSIString`, but only displays the style suffix. /// /// This type implements the `Display` trait, meaning it can be written to a /// `std::fmt` formatting without doing any extra allocation, and written to a /// string with the `.to_string()` method. For examples, see /// [`Style::suffix`](struct.Style.html#method.suffix). #[derive(Clone, Copy, Debug)] pub struct Suffix(Style); impl Style { /// The prefix bytes for this style. These are the bytes that tell the /// terminal to use a different color or font style. /// /// # Examples /// /// ``` /// use nu_ansi_term::{Style, Color::Blue}; /// /// let style = Style::default().bold(); /// assert_eq!("\x1b[1m", /// style.prefix().to_string()); /// /// let style = Blue.bold(); /// assert_eq!("\x1b[1;34m", /// style.prefix().to_string()); /// /// let style = Style::default(); /// assert_eq!("", /// style.prefix().to_string()); /// ``` pub fn prefix(self) -> Prefix { Prefix(self) } /// The infix bytes between this style and `next` style. These are the bytes /// that tell the terminal to change the style to `next`. These may include /// a reset followed by the next color and style, depending on the two styles. /// /// # Examples /// /// ``` /// use nu_ansi_term::{Style, Color::Green}; /// /// let style = Style::default().bold(); /// assert_eq!("\x1b[32m", /// style.infix(Green.bold()).to_string()); /// /// let style = Green.normal(); /// assert_eq!("\x1b[1m", /// style.infix(Green.bold()).to_string()); /// /// let style = Style::default(); /// assert_eq!("", /// style.infix(style).to_string()); /// ``` pub fn infix(self, next: Style) -> Infix { Infix(self, next) } /// The suffix for this style. These are the bytes that tell the terminal /// to reset back to its normal color and font style. /// /// # Examples /// /// ``` /// use nu_ansi_term::{Style, Color::Green}; /// /// let style = Style::default().bold(); /// assert_eq!("\x1b[0m", /// style.suffix().to_string()); /// /// let style = Green.normal().bold(); /// assert_eq!("\x1b[0m", /// style.suffix().to_string()); /// /// let style = Style::default(); /// assert_eq!("", /// style.suffix().to_string()); /// ``` pub fn suffix(self) -> Suffix { Suffix(self) } } impl Color { /// The prefix bytes for this color as a `Style`. These are the bytes /// that tell the terminal to use a different color or font style. /// /// See also [`Style::prefix`](struct.Style.html#method.prefix). /// /// # Examples /// /// ``` /// use nu_ansi_term::Color::Green; /// /// assert_eq!("\x1b[0m", /// Green.suffix().to_string()); /// ``` pub fn prefix(self) -> Prefix { Prefix(self.normal()) } /// The infix bytes between this color and `next` color. These are the bytes /// that tell the terminal to use the `next` color, or to do nothing if /// the two colors are equal. /// /// See also [`Style::infix`](struct.Style.html#method.infix). /// /// # Examples /// /// ``` /// use nu_ansi_term::Color::{Red, Yellow}; /// /// assert_eq!("\x1b[33m", /// Red.infix(Yellow).to_string()); /// ``` pub fn infix(self, next: Color) -> Infix { Infix(self.normal(), next.normal()) } /// The suffix for this color as a `Style`. These are the bytes that /// tell the terminal to reset back to its normal color and font style. /// /// See also [`Style::suffix`](struct.Style.html#method.suffix). /// /// # Examples /// /// ``` /// use nu_ansi_term::Color::Purple; /// /// assert_eq!("\x1b[0m", /// Purple.suffix().to_string()); /// ``` pub fn suffix(self) -> Suffix { Suffix(self.normal()) } } impl fmt::Display for Prefix { fn fmt(&self, f: &mut fmt::Formatter) -> fmt::Result { let f: &mut dyn fmt::Write = f; self.0.write_prefix(f) } } impl fmt::Display for Infix { fn fmt(&self, f: &mut fmt::Formatter) -> fmt::Result { use crate::difference::Difference; match Difference::between(&self.0, &self.1) { Difference::ExtraStyles(style) => { let f: &mut dyn fmt::Write = f; style.write_prefix(f) } Difference::Reset => { let f: &mut dyn fmt::Write = f; write!(f, "{}{}", RESET, self.1.prefix()) } Difference::Empty => { Ok(()) // nothing to write } } } } impl fmt::Display for Suffix { fn fmt(&self, f: &mut fmt::Formatter) -> fmt::Result { let f: &mut dyn fmt::Write = f; self.0.write_suffix(f) } } #[cfg(test)] mod test { use crate::style::Color::*; use crate::style::Style; macro_rules! test { ($name: ident: $style: expr; $input: expr => $result: expr) => { #[test] fn $name() { assert_eq!($style.paint($input).to_string(), $result.to_string()); let mut v = Vec::new(); $style.paint($input.as_bytes()).write_to(&mut v).unwrap(); assert_eq!(v.as_slice(), $result.as_bytes()); } }; } test!(plain: Style::default(); "text/plain" => "text/plain"); test!(red: Red; "hi" => "\x1B[31mhi\x1B[0m"); test!(black: Black.normal(); "hi" => "\x1B[30mhi\x1B[0m"); test!(yellow_bold: Yellow.bold(); "hi" => "\x1B[1;33mhi\x1B[0m"); test!(yellow_bold_2: Yellow.normal().bold(); "hi" => "\x1B[1;33mhi\x1B[0m"); test!(blue_underline: Blue.underline(); "hi" => "\x1B[4;34mhi\x1B[0m"); test!(green_bold_ul: Green.bold().underline(); "hi" => "\x1B[1;4;32mhi\x1B[0m"); test!(green_bold_ul_2: Green.underline().bold(); "hi" => "\x1B[1;4;32mhi\x1B[0m"); test!(purple_on_white: Purple.on(White); "hi" => "\x1B[47;35mhi\x1B[0m"); test!(purple_on_white_2: Purple.normal().on(White); "hi" => "\x1B[47;35mhi\x1B[0m"); test!(yellow_on_blue: Style::new().on(Blue).fg(Yellow); "hi" => "\x1B[44;33mhi\x1B[0m"); test!(magenta_on_white: Magenta.on(White); "hi" => "\x1B[47;35mhi\x1B[0m"); test!(magenta_on_white_2: Magenta.normal().on(White); "hi" => "\x1B[47;35mhi\x1B[0m"); test!(yellow_on_blue_2: Cyan.on(Blue).fg(Yellow); "hi" => "\x1B[44;33mhi\x1B[0m"); test!(cyan_bold_on_white: Cyan.bold().on(White); "hi" => "\x1B[1;47;36mhi\x1B[0m"); test!(cyan_ul_on_white: Cyan.underline().on(White); "hi" => "\x1B[4;47;36mhi\x1B[0m"); test!(cyan_bold_ul_on_white: Cyan.bold().underline().on(White); "hi" => "\x1B[1;4;47;36mhi\x1B[0m"); test!(cyan_ul_bold_on_white: Cyan.underline().bold().on(White); "hi" => "\x1B[1;4;47;36mhi\x1B[0m"); test!(fixed: Fixed(100); "hi" => "\x1B[38;5;100mhi\x1B[0m"); test!(fixed_on_purple: Fixed(100).on(Purple); "hi" => "\x1B[45;38;5;100mhi\x1B[0m"); test!(fixed_on_fixed: Fixed(100).on(Fixed(200)); "hi" => "\x1B[48;5;200;38;5;100mhi\x1B[0m"); test!(rgb: Rgb(70,130,180); "hi" => "\x1B[38;2;70;130;180mhi\x1B[0m"); test!(rgb_on_blue: Rgb(70,130,180).on(Blue); "hi" => "\x1B[44;38;2;70;130;180mhi\x1B[0m"); test!(blue_on_rgb: Blue.on(Rgb(70,130,180)); "hi" => "\x1B[48;2;70;130;180;34mhi\x1B[0m"); test!(rgb_on_rgb: Rgb(70,130,180).on(Rgb(5,10,15)); "hi" => "\x1B[48;2;5;10;15;38;2;70;130;180mhi\x1B[0m"); test!(bold: Style::new().bold(); "hi" => "\x1B[1mhi\x1B[0m"); test!(underline: Style::new().underline(); "hi" => "\x1B[4mhi\x1B[0m"); test!(bunderline: Style::new().bold().underline(); "hi" => "\x1B[1;4mhi\x1B[0m"); test!(dimmed: Style::new().dimmed(); "hi" => "\x1B[2mhi\x1B[0m"); test!(italic: Style::new().italic(); "hi" => "\x1B[3mhi\x1B[0m"); test!(blink: Style::new().blink(); "hi" => "\x1B[5mhi\x1B[0m"); test!(reverse: Style::new().reverse(); "hi" => "\x1B[7mhi\x1B[0m"); test!(hidden: Style::new().hidden(); "hi" => "\x1B[8mhi\x1B[0m"); test!(stricken: Style::new().strikethrough(); "hi" => "\x1B[9mhi\x1B[0m"); test!(lr_on_lr: LightRed.on(LightRed); "hi" => "\x1B[101;91mhi\x1B[0m"); #[test] fn test_infix() { assert_eq!( Style::new().dimmed().infix(Style::new()).to_string(), "\x1B[0m" ); assert_eq!( White.dimmed().infix(White.normal()).to_string(), "\x1B[0m\x1B[37m" ); assert_eq!(White.normal().infix(White.bold()).to_string(), "\x1B[1m"); assert_eq!(White.normal().infix(Blue.normal()).to_string(), "\x1B[34m"); assert_eq!(Blue.bold().infix(Blue.bold()).to_string(), ""); } }