// Thanks to https://github.com/ogham/rust-term-grid for making this available //! This library arranges textual data in a grid format suitable for //! fixed-width fonts, using an algorithm to minimise the amount of space //! needed. For example: //! //! ```rust //! use nu_term_grid::grid::{Grid, GridOptions, Direction, Filling, Cell}; //! //! let mut grid = Grid::new(GridOptions { //! filling: Filling::Spaces(1), //! direction: Direction::LeftToRight, //! }); //! //! for s in &["one", "two", "three", "four", "five", "six", "seven", //! "eight", "nine", "ten", "eleven", "twelve"] //! { //! grid.add(Cell::from(*s)); //! } //! //! println!("{}", grid.fit_into_width(24).unwrap()); //! ``` //! //! Produces the following tabular result: //! //! ```text //! one two three four //! five six seven eight //! nine ten eleven twelve //! ``` //! //! //! ## Creating a grid //! //! To add data to a grid, first create a new [`Grid`] value, and then add //! cells to them with the `add` function. //! //! There are two options that must be specified in the [`GridOptions`] value //! that dictate how the grid is formatted: //! //! - `filling`: what to put in between two columns — either a number of //! spaces, or a text string; //! - `direction`, which specifies whether the cells should go along //! rows, or columns: //! - `Direction::LeftToRight` starts them in the top left and //! moves *rightwards*, going to the start of a new row after reaching the //! final column; //! - `Direction::TopToBottom` starts them in the top left and moves //! *downwards*, going to the top of a new column after reaching the final //! row. //! //! //! ## Displaying a grid //! //! When display a grid, you can either specify the number of columns in advance, //! or try to find the maximum number of columns that can fit in an area of a //! given width. //! //! Splitting a series of cells into columns — or, in other words, starting a new //! row every n cells — is achieved with the [`fit_into_columns`] function //! on a `Grid` value. It takes as its argument the number of columns. //! //! Trying to fit as much data onto one screen as possible is the main use case //! for specifying a maximum width instead. This is achieved with the //! [`fit_into_width`] function. It takes the maximum allowed width, including //! separators, as its argument. However, it returns an *optional* [`Display`] //! value, depending on whether any of the cells actually had a width greater than //! the maximum width! If this is the case, your best bet is to just output the //! cells with one per line. //! //! //! ## Cells and data //! //! Grids to not take `String`s or `&str`s — they take [`Cell`] values. //! //! A **Cell** is a struct containing an individual cell’s contents, as a string, //! and its pre-computed length, which gets used when calculating a grid’s final //! dimensions. Usually, you want the *Unicode width* of the string to be used for //! this, so you can turn a `String` into a `Cell` with the `.into()` function. //! //! However, you may also want to supply your own width: when you already know the //! width in advance, or when you want to change the measurement, such as skipping //! over terminal control characters. For cases like these, the fields on the //! `Cell` values are public, meaning you can construct your own instances as //! necessary. //! //! [`Cell`]: ./struct.Cell.html //! [`Display`]: ./struct.Display.html //! [`Grid`]: ./struct.Grid.html //! [`fit_into_columns`]: ./struct.Grid.html#method.fit_into_columns //! [`fit_into_width`]: ./struct.Grid.html#method.fit_into_width //! [`GridOptions`]: ./struct.GridOptions.html use std::cmp::max; use std::fmt; use std::iter::repeat; use unicode_width::UnicodeWidthStr; fn unicode_width_strip_ansi(astring: &str) -> usize { nu_utils::strip_ansi_unlikely(astring).width() } /// Alignment indicate on which side the content should stick if some filling /// is required. #[derive(Debug, Clone, Copy, PartialEq, Eq)] pub enum Alignment { /// The content will stick to the left. Left, /// The content will stick to the right. Right, } /// A **Cell** is the combination of a string and its pre-computed length. /// /// The easiest way to create a Cell is just by using `string.into()`, which /// uses the **unicode width** of the string (see the `unicode_width` crate). /// However, the fields are public, if you wish to provide your own length. #[derive(PartialEq, Eq, Debug, Clone)] pub struct Cell { /// The string to display when this cell gets rendered. pub contents: String, /// The pre-computed length of the string. pub width: Width, /// The side (left/right) to align the content if some filling is required. pub alignment: Alignment, } impl From for Cell { fn from(string: String) -> Self { Self { width: unicode_width_strip_ansi(&*string), contents: string, alignment: Alignment::Left, } } } impl<'a> From<&'a str> for Cell { fn from(string: &'a str) -> Self { Self { width: unicode_width_strip_ansi(string), contents: string.into(), alignment: Alignment::Left, } } } /// Direction cells should be written in — either across, or downwards. #[derive(PartialEq, Eq, Debug, Copy, Clone)] pub enum Direction { /// Starts at the top left and moves rightwards, going back to the first /// column for a new row, like a typewriter. LeftToRight, /// Starts at the top left and moves downwards, going back to the first /// row for a new column, like how `ls` lists files by default. TopToBottom, } /// The width of a cell, in columns. pub type Width = usize; /// The text to put in between each pair of columns. /// This does not include any spaces used when aligning cells. #[derive(PartialEq, Eq, Debug)] pub enum Filling { /// A certain number of spaces should be used as the separator. Spaces(Width), /// An arbitrary string. /// `"|"` is a common choice. Text(String), } impl Filling { fn width(&self) -> Width { match *self { Filling::Spaces(w) => w, Filling::Text(ref t) => unicode_width_strip_ansi(&t[..]), } } } /// The user-assignable options for a grid view that should be passed to /// [`Grid::new()`](struct.Grid.html#method.new). #[derive(PartialEq, Eq, Debug)] pub struct GridOptions { /// The direction that the cells should be written in — either /// across, or downwards. pub direction: Direction, /// The number of spaces to put in between each column of cells. pub filling: Filling, } #[derive(PartialEq, Eq, Debug)] struct Dimensions { /// The number of lines in the grid. num_lines: Width, /// The width of each column in the grid. The length of this vector serves /// as the number of columns. widths: Vec, } impl Dimensions { fn total_width(&self, separator_width: Width) -> Width { if self.widths.is_empty() { 0 } else { let values = self.widths.iter().sum::(); let separators = separator_width * (self.widths.len() - 1); values + separators } } } /// Everything needed to format the cells with the grid options. /// /// For more information, see the [`grid` crate documentation](index.html). #[derive(Eq, PartialEq, Debug)] pub struct Grid { options: GridOptions, cells: Vec, widest_cell_length: Width, width_sum: Width, cell_count: usize, } impl Grid { /// Creates a new grid view with the given options. pub fn new(options: GridOptions) -> Self { let cells = Vec::new(); Self { options, cells, widest_cell_length: 0, width_sum: 0, cell_count: 0, } } /// Reserves space in the vector for the given number of additional cells /// to be added. (See the `Vec::reserve` function.) pub fn reserve(&mut self, additional: usize) { self.cells.reserve(additional) } /// Adds another cell onto the vector. pub fn add(&mut self, cell: Cell) { if cell.width > self.widest_cell_length { self.widest_cell_length = cell.width; } self.width_sum += cell.width; self.cell_count += 1; self.cells.push(cell) } /// Returns a displayable grid that’s been packed to fit into the given /// width in the fewest number of rows. /// /// Returns `None` if any of the cells has a width greater than the /// maximum width. pub fn fit_into_width(&self, maximum_width: Width) -> Option> { self.width_dimensions(maximum_width).map(|dims| Display { grid: self, dimensions: dims, }) } /// Returns a displayable grid with the given number of columns, and no /// maximum width. pub fn fit_into_columns(&self, num_columns: usize) -> Display<'_> { Display { grid: self, dimensions: self.columns_dimensions(num_columns), } } fn columns_dimensions(&self, num_columns: usize) -> Dimensions { let mut num_lines = self.cells.len() / num_columns; if self.cells.len() % num_columns != 0 { num_lines += 1; } self.column_widths(num_lines, num_columns) } fn column_widths(&self, num_lines: usize, num_columns: usize) -> Dimensions { let mut widths: Vec = repeat(0).take(num_columns).collect(); for (index, cell) in self.cells.iter().enumerate() { let index = match self.options.direction { Direction::LeftToRight => index % num_columns, Direction::TopToBottom => index / num_lines, }; widths[index] = max(widths[index], cell.width); } Dimensions { num_lines, widths } } fn theoretical_max_num_lines(&self, maximum_width: usize) -> usize { let mut theoretical_min_num_cols = 0; let mut col_total_width_so_far = 0; let mut cells = self.cells.clone(); cells.sort_unstable_by(|a, b| b.width.cmp(&a.width)); // Sort in reverse order for cell in &cells { if cell.width + col_total_width_so_far <= maximum_width { theoretical_min_num_cols += 1; col_total_width_so_far += cell.width; } else { let mut theoretical_max_num_lines = self.cell_count / theoretical_min_num_cols; if self.cell_count % theoretical_min_num_cols != 0 { theoretical_max_num_lines += 1; } return theoretical_max_num_lines; } col_total_width_so_far += self.options.filling.width() } // If we make it to this point, we have exhausted all cells before // reaching the maximum width; the theoretical max number of lines // needed to display all cells is 1. 1 } fn width_dimensions(&self, maximum_width: Width) -> Option { if self.widest_cell_length > maximum_width { // Largest cell is wider than maximum width; it is impossible to fit. return None; } if self.cell_count == 0 { return Some(Dimensions { num_lines: 0, widths: Vec::new(), }); } if self.cell_count == 1 { let the_cell = &self.cells[0]; return Some(Dimensions { num_lines: 1, widths: vec![the_cell.width], }); } let theoretical_max_num_lines = self.theoretical_max_num_lines(maximum_width); if theoretical_max_num_lines == 1 { // This if—statement is neccesary for the function to work correctly // for small inputs. return Some(Dimensions { num_lines: 1, // I clone self.cells twice. Once here, and once in // self.theoretical_max_num_lines. Perhaps not the best for // performance? widths: self .cells .clone() .into_iter() .map(|cell| cell.width) .collect(), }); } // Instead of numbers of columns, try to find the fewest number of *lines* // that the output will fit in. let mut smallest_dimensions_yet = None; for num_lines in (1..=theoretical_max_num_lines).rev() { // The number of columns is the number of cells divided by the number // of lines, *rounded up*. let mut num_columns = self.cell_count / num_lines; if self.cell_count % num_lines != 0 { num_columns += 1; } // Early abort: if there are so many columns that the width of the // *column separators* is bigger than the width of the screen, then // don’t even try to tabulate it. // This is actually a necessary check, because the width is stored as // a usize, and making it go negative makes it huge instead, but it // also serves as a speed-up. let total_separator_width = (num_columns - 1) * self.options.filling.width(); if maximum_width < total_separator_width { continue; } // Remove the separator width from the available space. let adjusted_width = maximum_width - total_separator_width; let potential_dimensions = self.column_widths(num_lines, num_columns); if potential_dimensions.widths.iter().sum::() < adjusted_width { smallest_dimensions_yet = Some(potential_dimensions); } else { return smallest_dimensions_yet; } } None } } /// A displayable representation of a [`Grid`](struct.Grid.html). /// /// This type implements `Display`, so you can get the textual version /// of the grid by calling `.to_string()`. #[derive(Eq, PartialEq, Debug)] pub struct Display<'grid> { /// The grid to display. grid: &'grid Grid, /// The pre-computed column widths for this grid. dimensions: Dimensions, } impl Display<'_> { /// Returns how many columns this display takes up, based on the separator /// width and the number and width of the columns. pub fn width(&self) -> Width { self.dimensions .total_width(self.grid.options.filling.width()) } /// Returns how many rows this display takes up. pub fn row_count(&self) -> usize { self.dimensions.num_lines } /// Returns whether this display takes up as many columns as were allotted /// to it. /// /// It’s possible to construct tables that don’t actually use up all the /// columns that they could, such as when there are more columns than /// cells! In this case, a column would have a width of zero. This just /// checks for that. pub fn is_complete(&self) -> bool { self.dimensions.widths.iter().all(|&x| x > 0) } } impl fmt::Display for Display<'_> { fn fmt(&self, f: &mut fmt::Formatter<'_>) -> Result<(), fmt::Error> { for y in 0..self.dimensions.num_lines { for x in 0..self.dimensions.widths.len() { let num = match self.grid.options.direction { Direction::LeftToRight => y * self.dimensions.widths.len() + x, Direction::TopToBottom => y + self.dimensions.num_lines * x, }; // Abandon a line mid-way through if that’s where the cells end if num >= self.grid.cells.len() { continue; } let cell = &self.grid.cells[num]; if x == self.dimensions.widths.len() - 1 { match cell.alignment { Alignment::Left => { // The final column doesn’t need to have trailing spaces, // as long as it’s left-aligned. write!(f, "{}", cell.contents)?; } Alignment::Right => { let extra_spaces = self.dimensions.widths[x] - cell.width; write!( f, "{}", pad_string(&cell.contents, extra_spaces, Alignment::Right) )?; } } } else { assert!(self.dimensions.widths[x] >= cell.width); match (&self.grid.options.filling, cell.alignment) { (Filling::Spaces(n), Alignment::Left) => { let extra_spaces = self.dimensions.widths[x] - cell.width + n; write!( f, "{}", pad_string(&cell.contents, extra_spaces, cell.alignment) )?; } (Filling::Spaces(n), Alignment::Right) => { let s = spaces(*n); let extra_spaces = self.dimensions.widths[x] - cell.width; write!( f, "{}{}", pad_string(&cell.contents, extra_spaces, cell.alignment), s )?; } (Filling::Text(ref t), _) => { let extra_spaces = self.dimensions.widths[x] - cell.width; write!( f, "{}{}", pad_string(&cell.contents, extra_spaces, cell.alignment), t )?; } } } } writeln!(f)?; } Ok(()) } } /// Pad a string with the given number of spaces. fn spaces(length: usize) -> String { " ".repeat(length) } /// Pad a string with the given alignment and number of spaces. /// /// This doesn’t take the width the string *should* be, rather the number /// of spaces to add. fn pad_string(string: &str, padding: usize, alignment: Alignment) -> String { if alignment == Alignment::Left { format!("{}{}", string, spaces(padding)) } else { format!("{}{}", spaces(padding), string) } } #[cfg(test)] mod test { use super::*; #[test] fn no_items() { let grid = Grid::new(GridOptions { direction: Direction::TopToBottom, filling: Filling::Spaces(2), }); let display = grid.fit_into_width(40).unwrap(); assert_eq!(display.dimensions.num_lines, 0); assert!(display.dimensions.widths.is_empty()); assert_eq!(display.width(), 0); } #[test] fn one_item() { let mut grid = Grid::new(GridOptions { direction: Direction::TopToBottom, filling: Filling::Spaces(2), }); grid.add(Cell::from("1")); let display = grid.fit_into_width(40).unwrap(); assert_eq!(display.dimensions.num_lines, 1); assert_eq!(display.dimensions.widths, vec![1]); assert_eq!(display.width(), 1); } #[test] fn one_item_exact_width() { let mut grid = Grid::new(GridOptions { direction: Direction::TopToBottom, filling: Filling::Spaces(2), }); grid.add(Cell::from("1234567890")); let display = grid.fit_into_width(10).unwrap(); assert_eq!(display.dimensions.num_lines, 1); assert_eq!(display.dimensions.widths, vec![10]); assert_eq!(display.width(), 10); } #[test] fn one_item_just_over() { let mut grid = Grid::new(GridOptions { direction: Direction::TopToBottom, filling: Filling::Spaces(2), }); grid.add(Cell::from("1234567890!")); assert_eq!(grid.fit_into_width(10), None); } #[test] fn two_small_items() { let mut grid = Grid::new(GridOptions { direction: Direction::TopToBottom, filling: Filling::Spaces(2), }); grid.add(Cell::from("1")); grid.add(Cell::from("2")); let display = grid.fit_into_width(40).unwrap(); assert_eq!(display.dimensions.num_lines, 1); assert_eq!(display.dimensions.widths, vec![1, 1]); assert_eq!(display.width(), 1 + 2 + 1); } #[test] fn two_medium_size_items() { let mut grid = Grid::new(GridOptions { direction: Direction::TopToBottom, filling: Filling::Spaces(2), }); grid.add(Cell::from("hello there")); grid.add(Cell::from("how are you today?")); let display = grid.fit_into_width(40).unwrap(); assert_eq!(display.dimensions.num_lines, 1); assert_eq!(display.dimensions.widths, vec![11, 18]); assert_eq!(display.width(), 11 + 2 + 18); } #[test] fn two_big_items() { let mut grid = Grid::new(GridOptions { direction: Direction::TopToBottom, filling: Filling::Spaces(2), }); grid.add(Cell::from( "nuihuneihsoenhisenouiuteinhdauisdonhuisudoiosadiuohnteihaosdinhteuieudi", )); grid.add(Cell::from( "oudisnuthasuouneohbueobaugceoduhbsauglcobeuhnaeouosbubaoecgueoubeohubeo", )); assert_eq!(grid.fit_into_width(40), None); } #[test] fn that_example_from_earlier() { let mut grid = Grid::new(GridOptions { filling: Filling::Spaces(1), direction: Direction::LeftToRight, }); for s in &[ "one", "two", "three", "four", "five", "six", "seven", "eight", "nine", "ten", "eleven", "twelve", ] { grid.add(Cell::from(*s)); } let bits = "one two three four\nfive six seven eight\nnine ten eleven twelve\n"; assert_eq!(grid.fit_into_width(24).unwrap().to_string(), bits); assert_eq!(grid.fit_into_width(24).unwrap().row_count(), 3); } #[test] fn number_grid_with_pipe() { let mut grid = Grid::new(GridOptions { filling: Filling::Text("|".into()), direction: Direction::LeftToRight, }); for s in &[ "one", "two", "three", "four", "five", "six", "seven", "eight", "nine", "ten", "eleven", "twelve", ] { grid.add(Cell::from(*s)); } let bits = "one |two|three |four\nfive|six|seven |eight\nnine|ten|eleven|twelve\n"; assert_eq!(grid.fit_into_width(24).unwrap().to_string(), bits); assert_eq!(grid.fit_into_width(24).unwrap().row_count(), 3); } #[test] fn numbers_right() { let mut grid = Grid::new(GridOptions { filling: Filling::Spaces(1), direction: Direction::LeftToRight, }); for s in &[ "one", "two", "three", "four", "five", "six", "seven", "eight", "nine", "ten", "eleven", "twelve", ] { let mut cell = Cell::from(*s); cell.alignment = Alignment::Right; grid.add(cell); } let bits = " one two three four\nfive six seven eight\nnine ten eleven twelve\n"; assert_eq!(grid.fit_into_width(24).unwrap().to_string(), bits); assert_eq!(grid.fit_into_width(24).unwrap().row_count(), 3); } #[test] fn numbers_right_pipe() { let mut grid = Grid::new(GridOptions { filling: Filling::Text("|".into()), direction: Direction::LeftToRight, }); for s in &[ "one", "two", "three", "four", "five", "six", "seven", "eight", "nine", "ten", "eleven", "twelve", ] { let mut cell = Cell::from(*s); cell.alignment = Alignment::Right; grid.add(cell); } let bits = " one|two| three| four\nfive|six| seven| eight\nnine|ten|eleven|twelve\n"; assert_eq!(grid.fit_into_width(24).unwrap().to_string(), bits); assert_eq!(grid.fit_into_width(24).unwrap().row_count(), 3); } #[test] fn huge_separator() { let mut grid = Grid::new(GridOptions { filling: Filling::Spaces(100), direction: Direction::LeftToRight, }); grid.add("a".into()); grid.add("b".into()); assert_eq!(grid.fit_into_width(99), None); } #[test] fn huge_yet_unused_separator() { let mut grid = Grid::new(GridOptions { filling: Filling::Spaces(100), direction: Direction::LeftToRight, }); grid.add("abcd".into()); let display = grid.fit_into_width(99).unwrap(); assert_eq!(display.dimensions.num_lines, 1); assert_eq!(display.dimensions.widths, vec![4]); assert_eq!(display.width(), 4); } }