//! The `TextCell` type for the details and lines views. use std::iter::Sum; use std::ops::{Add, Deref, DerefMut}; use ansi_term::{Style, ANSIString, ANSIStrings}; use unicode_width::UnicodeWidthStr; /// An individual cell that holds text in a table, used in the details and /// lines views to store ANSI-terminal-formatted data before it is printed. /// /// A text cell is made up of zero or more strings coupled with the /// pre-computed length of all the strings combined. When constructing details /// or grid-details tables, the length will have to be queried multiple times, /// so it makes sense to cache it. /// /// (This used to be called `Cell`, but was renamed because there’s a Rust /// type by that name too.) #[derive(PartialEq, Debug, Clone, Default)] pub struct TextCell { /// The contents of this cell, as a vector of ANSI-styled strings. pub contents: TextCellContents, /// The Unicode “display width” of this cell. pub width: DisplayWidth, } impl Deref for TextCell { type Target = TextCellContents; fn deref(&self) -> &Self::Target { &self.contents } } impl TextCell { /// Creates a new text cell that holds the given text in the given style, /// computing the Unicode width of the text. pub fn paint(style: Style, text: String) -> Self { let width = DisplayWidth::from(&*text); Self { contents: vec![ style.paint(text) ].into(), width, } } /// Creates a new text cell that holds the given text in the given style, /// computing the Unicode width of the text. (This could be merged with /// `paint`, but.) pub fn paint_str(style: Style, text: &'static str) -> Self { let width = DisplayWidth::from(text); Self { contents: vec![ style.paint(text) ].into(), width, } } /// Creates a new “blank” text cell that contains a single hyphen in the /// given style, which should be the “punctuation” style from a `Colours` /// value. /// /// This is used in place of empty table cells, as it is easier to read /// tabular data when there is *something* in each cell. pub fn blank(style: Style) -> Self { Self { contents: vec![ style.paint("-") ].into(), width: DisplayWidth::from(1), } } /// Adds the given number of unstyled spaces after this cell. /// /// This method allocates a `String` to hold the spaces. pub fn add_spaces(&mut self, count: usize) { use std::iter::repeat; (*self.width) += count; let spaces: String = repeat(' ').take(count).collect(); self.contents.0.push(Style::default().paint(spaces)); } /// Adds the contents of another `ANSIString` to the end of this cell. pub fn push(&mut self, string: ANSIString<'static>, extra_width: usize) { self.contents.0.push(string); (*self.width) += extra_width; } /// Adds all the contents of another `TextCell` to the end of this cell. pub fn append(&mut self, other: Self) { (*self.width) += *other.width; self.contents.0.extend(other.contents.0); } } // I’d like to eventually abstract cells so that instead of *every* cell // storing a vector, only variable-length cells would, and individual cells // would just store an array of a fixed length (which would usually be just 1 // or 2), which wouldn’t require a heap allocation. // // For examples, look at the `render_*` methods in the `Table` object in the // details view: // // - `render_blocks`, `inode`, and `links` will always return a // one-string-long TextCell; // - `render_size` will return one or two strings in a TextCell, depending on // the size and whether one is present; // - `render_permissions` will return ten or eleven strings; // - `filename` and `symlink_filename` in the output module root return six or // five strings. // // In none of these cases are we dealing with a *truly variable* number of // strings: it is only when the strings are concatenated together do we need a // growable, heap-allocated buffer. // // So it would be nice to abstract the `TextCell` type so instead of a `Vec`, // it can use anything of type `T: IntoIterator>`. // This would allow us to still hold all the data, but allocate less. // // But exa still has bugs and I need to fix those first :( /// The contents of a text cell, as a vector of ANSI-styled strings. /// /// It’s possible to use this type directly in the case where you want a /// `TextCell` but aren’t concerned with tracking its width, because it occurs /// in the final cell of a table or grid and there’s no point padding it. This /// happens when dealing with file names. #[derive(PartialEq, Debug, Clone, Default)] pub struct TextCellContents(Vec>); impl From>> for TextCellContents { fn from(strings: Vec>) -> Self { Self(strings) } } impl Deref for TextCellContents { type Target = [ANSIString<'static>]; fn deref(&self) -> &Self::Target { &*self.0 } } // No DerefMut implementation here — it would be publicly accessible, and as // the contents only get changed in this module, the mutators in the struct // above can just access the value directly. impl TextCellContents { /// Produces an `ANSIStrings` value that can be used to print the styled /// values of this cell as an ANSI-terminal-formatted string. pub fn strings(&self) -> ANSIStrings { ANSIStrings(&self.0) } /// Calculates the width that a cell with these contents would take up, by /// counting the number of characters in each unformatted ANSI string. pub fn width(&self) -> DisplayWidth { self.0.iter() .map(|anstr| DisplayWidth::from(&**anstr)) .sum() } /// Promotes these contents to a full cell containing them alongside /// their calculated width. pub fn promote(self) -> TextCell { TextCell { width: self.width(), contents: self, } } } /// The Unicode “display width” of a string. /// /// This is related to the number of *graphemes* of a string, rather than the /// number of *characters*, or *bytes*: although most characters are one /// column wide, a few can be two columns wide, and this is important to note /// when calculating widths for displaying tables in a terminal. /// /// This type is used to ensure that the width, rather than the length, is /// used when constructing a `TextCell` — it’s too easy to write something /// like `file_name.len()` and assume it will work! /// /// It has `From` impls that convert an input string or fixed with to values /// of this type, and will `Deref` to the contained `usize` value. #[derive(PartialEq, Debug, Clone, Copy, Default)] pub struct DisplayWidth(usize); impl<'a> From<&'a str> for DisplayWidth { fn from(input: &'a str) -> Self { Self(UnicodeWidthStr::width(input)) } } impl From for DisplayWidth { fn from(width: usize) -> Self { Self(width) } } impl Deref for DisplayWidth { type Target = usize; fn deref(&self) -> &Self::Target { &self.0 } } impl DerefMut for DisplayWidth { fn deref_mut(&mut self) -> &mut Self::Target { &mut self.0 } } impl Add for DisplayWidth { type Output = Self; fn add(self, rhs: Self) -> Self::Output { Self(self.0 + rhs.0) } } impl Add for DisplayWidth { type Output = Self; fn add(self, rhs: usize) -> Self::Output { Self(self.0 + rhs) } } impl Sum for DisplayWidth { fn sum(iter: I) -> Self where I: Iterator { iter.fold(Self(0), Add::add) } } #[cfg(test)] mod width_unit_test { use super::DisplayWidth; #[test] fn empty_string() { let cell = DisplayWidth::from(""); assert_eq!(*cell, 0); } #[test] fn test_string() { let cell = DisplayWidth::from("Diss Playwidth"); assert_eq!(*cell, 14); } #[test] fn addition() { let cell_one = DisplayWidth::from("/usr/bin/"); let cell_two = DisplayWidth::from("drinking"); assert_eq!(*(cell_one + cell_two), 17); } #[test] fn addition_usize() { let cell = DisplayWidth::from("/usr/bin/"); assert_eq!(*(cell + 8), 17); } }