// Copyright 2015 The Servo Project Developers. See the // COPYRIGHT file at the top-level directory of this distribution. // // Licensed under the Apache License, Version 2.0 or the MIT license // , at your // option. This file may not be copied, modified, or distributed // except according to those terms. //! This crate implements the [Unicode Bidirectional Algorithm][tr9] for display of mixed //! right-to-left and left-to-right text. It is written in safe Rust, compatible with the //! current stable release. //! //! ## Example //! //! ```rust //! # #[cfg(feature = "hardcoded-data")] { //! use unicode_bidi::BidiInfo; //! //! // This example text is defined using `concat!` because some browsers //! // and text editors have trouble displaying bidi strings. //! let text = concat![ //! "א", //! "ב", //! "ג", //! "a", //! "b", //! "c", //! ]; //! //! // Resolve embedding levels within the text. Pass `None` to detect the //! // paragraph level automatically. //! let bidi_info = BidiInfo::new(&text, None); //! //! // This paragraph has embedding level 1 because its first strong character is RTL. //! assert_eq!(bidi_info.paragraphs.len(), 1); //! let para = &bidi_info.paragraphs[0]; //! assert_eq!(para.level.number(), 1); //! assert_eq!(para.level.is_rtl(), true); //! //! // Re-ordering is done after wrapping each paragraph into a sequence of //! // lines. For this example, I'll just use a single line that spans the //! // entire paragraph. //! let line = para.range.clone(); //! //! let display = bidi_info.reorder_line(para, line); //! assert_eq!(display, concat![ //! "a", //! "b", //! "c", //! "ג", //! "ב", //! "א", //! ]); //! # } // feature = "hardcoded-data" //! ``` //! //! # Features //! //! - `std`: Enabled by default, but can be disabled to make `unicode_bidi` //! `#![no_std]` + `alloc` compatible. //! - `hardcoded-data`: Enabled by default. Includes hardcoded Unicode bidi data and more convenient APIs. //! - `serde`: Adds [`serde::Serialize`] and [`serde::Deserialize`] //! implementations to relevant types. //! //! [tr9]: #![no_std] // We need to link to std to make doc tests work on older Rust versions #[cfg(feature = "std")] extern crate std; #[macro_use] extern crate alloc; pub mod data_source; pub mod deprecated; pub mod format_chars; pub mod level; mod char_data; mod explicit; mod implicit; mod prepare; pub use crate::char_data::{BidiClass, UNICODE_VERSION}; pub use crate::data_source::BidiDataSource; pub use crate::level::{Level, LTR_LEVEL, RTL_LEVEL}; pub use crate::prepare::LevelRun; #[cfg(feature = "hardcoded-data")] pub use crate::char_data::{bidi_class, HardcodedBidiData}; use alloc::borrow::Cow; use alloc::string::String; use alloc::vec::Vec; use core::cmp; use core::iter::repeat; use core::ops::Range; use crate::format_chars as chars; use crate::BidiClass::*; #[derive(PartialEq, Debug)] pub enum Direction { Ltr, Rtl, Mixed, } /// Bidi information about a single paragraph #[derive(Debug, PartialEq)] pub struct ParagraphInfo { /// The paragraphs boundaries within the text, as byte indices. /// /// TODO: Shrink this to only include the starting index? pub range: Range, /// The paragraph embedding level. /// /// pub level: Level, } impl ParagraphInfo { /// Gets the length of the paragraph in the source text. pub fn len(&self) -> usize { self.range.end - self.range.start } } /// Initial bidi information of the text. /// /// Contains the text paragraphs and `BidiClass` of its characters. #[derive(PartialEq, Debug)] pub struct InitialInfo<'text> { /// The text pub text: &'text str, /// The BidiClass of the character at each byte in the text. /// If a character is multiple bytes, its class will appear multiple times in the vector. pub original_classes: Vec, /// The boundaries and level of each paragraph within the text. pub paragraphs: Vec, } impl<'text> InitialInfo<'text> { /// Find the paragraphs and BidiClasses in a string of text. /// /// /// /// Also sets the class for each First Strong Isolate initiator (FSI) to LRI or RLI if a strong /// character is found before the matching PDI. If no strong character is found, the class will /// remain FSI, and it's up to later stages to treat these as LRI when needed. /// /// The `hardcoded-data` Cargo feature (enabled by default) must be enabled to use this. #[cfg_attr(feature = "flame_it", flamer::flame)] #[cfg(feature = "hardcoded-data")] pub fn new(text: &str, default_para_level: Option) -> InitialInfo<'_> { Self::new_with_data_source(&HardcodedBidiData, text, default_para_level) } /// Find the paragraphs and BidiClasses in a string of text, with a custom [`BidiDataSource`] /// for Bidi data. If you just wish to use the hardcoded Bidi data, please use [`InitialInfo::new()`] /// instead (enabled with tbe default `hardcoded-data` Cargo feature) /// /// /// /// Also sets the class for each First Strong Isolate initiator (FSI) to LRI or RLI if a strong /// character is found before the matching PDI. If no strong character is found, the class will /// remain FSI, and it's up to later stages to treat these as LRI when needed. #[cfg_attr(feature = "flame_it", flamer::flame)] pub fn new_with_data_source<'a, D: BidiDataSource>( data_source: &D, text: &'a str, default_para_level: Option, ) -> InitialInfo<'a> { let mut original_classes = Vec::with_capacity(text.len()); // The stack contains the starting byte index for each nested isolate we're inside. let mut isolate_stack = Vec::new(); let mut paragraphs = Vec::new(); let mut para_start = 0; let mut para_level = default_para_level; #[cfg(feature = "flame_it")] flame::start("InitialInfo::new(): iter text.char_indices()"); for (i, c) in text.char_indices() { let class = data_source.bidi_class(c); #[cfg(feature = "flame_it")] flame::start("original_classes.extend()"); original_classes.extend(repeat(class).take(c.len_utf8())); #[cfg(feature = "flame_it")] flame::end("original_classes.extend()"); match class { B => { // P1. Split the text into separate paragraphs. The paragraph separator is kept // with the previous paragraph. let para_end = i + c.len_utf8(); paragraphs.push(ParagraphInfo { range: para_start..para_end, // P3. If no character is found in p2, set the paragraph level to zero. level: para_level.unwrap_or(LTR_LEVEL), }); // Reset state for the start of the next paragraph. para_start = para_end; // TODO: Support defaulting to direction of previous paragraph // // para_level = default_para_level; isolate_stack.clear(); } L | R | AL => { match isolate_stack.last() { Some(&start) => { if original_classes[start] == FSI { // X5c. If the first strong character between FSI and its matching // PDI is R or AL, treat it as RLI. Otherwise, treat it as LRI. for j in 0..chars::FSI.len_utf8() { original_classes[start + j] = if class == L { LRI } else { RLI }; } } } None => { if para_level.is_none() { // P2. Find the first character of type L, AL, or R, while skipping // any characters between an isolate initiator and its matching // PDI. para_level = Some(if class != L { RTL_LEVEL } else { LTR_LEVEL }); } } } } RLI | LRI | FSI => { isolate_stack.push(i); } PDI => { isolate_stack.pop(); } _ => {} } } if para_start < text.len() { paragraphs.push(ParagraphInfo { range: para_start..text.len(), level: para_level.unwrap_or(LTR_LEVEL), }); } assert_eq!(original_classes.len(), text.len()); #[cfg(feature = "flame_it")] flame::end("InitialInfo::new(): iter text.char_indices()"); InitialInfo { text, original_classes, paragraphs, } } } /// Bidi information of the text. /// /// The `original_classes` and `levels` vectors are indexed by byte offsets into the text. If a /// character is multiple bytes wide, then its class and level will appear multiple times in these /// vectors. // TODO: Impl `struct StringProperty { values: Vec }` and use instead of Vec #[derive(Debug, PartialEq)] pub struct BidiInfo<'text> { /// The text pub text: &'text str, /// The BidiClass of the character at each byte in the text. pub original_classes: Vec, /// The directional embedding level of each byte in the text. pub levels: Vec, /// The boundaries and paragraph embedding level of each paragraph within the text. /// /// TODO: Use SmallVec or similar to avoid overhead when there are only one or two paragraphs? /// Or just don't include the first paragraph, which always starts at 0? pub paragraphs: Vec, } impl<'text> BidiInfo<'text> { /// Split the text into paragraphs and determine the bidi embedding levels for each paragraph. /// /// /// The `hardcoded-data` Cargo feature (enabled by default) must be enabled to use this. /// /// TODO: In early steps, check for special cases that allow later steps to be skipped. like /// text that is entirely LTR. See the `nsBidi` class from Gecko for comparison. /// /// TODO: Support auto-RTL base direction #[cfg_attr(feature = "flame_it", flamer::flame)] #[cfg(feature = "hardcoded-data")] pub fn new(text: &str, default_para_level: Option) -> BidiInfo<'_> { Self::new_with_data_source(&HardcodedBidiData, text, default_para_level) } /// Split the text into paragraphs and determine the bidi embedding levels for each paragraph, with a custom [`BidiDataSource`] /// for Bidi data. If you just wish to use the hardcoded Bidi data, please use [`BidiInfo::new()`] /// instead (enabled with tbe default `hardcoded-data` Cargo feature). /// /// TODO: In early steps, check for special cases that allow later steps to be skipped. like /// text that is entirely LTR. See the `nsBidi` class from Gecko for comparison. /// /// TODO: Support auto-RTL base direction #[cfg_attr(feature = "flame_it", flamer::flame)] pub fn new_with_data_source<'a, D: BidiDataSource>( data_source: &D, text: &'a str, default_para_level: Option, ) -> BidiInfo<'a> { let InitialInfo { original_classes, paragraphs, .. } = InitialInfo::new_with_data_source(data_source, text, default_para_level); let mut levels = Vec::::with_capacity(text.len()); let mut processing_classes = original_classes.clone(); for para in ¶graphs { let text = &text[para.range.clone()]; let original_classes = &original_classes[para.range.clone()]; let processing_classes = &mut processing_classes[para.range.clone()]; let new_len = levels.len() + para.range.len(); levels.resize(new_len, para.level); let levels = &mut levels[para.range.clone()]; explicit::compute( text, para.level, original_classes, levels, processing_classes, ); let sequences = prepare::isolating_run_sequences(para.level, original_classes, levels); for sequence in &sequences { implicit::resolve_weak(text, sequence, processing_classes); implicit::resolve_neutral( text, data_source, sequence, levels, original_classes, processing_classes, ); } implicit::resolve_levels(processing_classes, levels); assign_levels_to_removed_chars(para.level, original_classes, levels); } BidiInfo { text, original_classes, paragraphs, levels, } } /// Re-order a line based on resolved levels and return only the embedding levels, one `Level` /// per *byte*. #[cfg_attr(feature = "flame_it", flamer::flame)] pub fn reordered_levels(&self, para: &ParagraphInfo, line: Range) -> Vec { let (levels, _) = self.visual_runs(para, line); levels } /// Re-order a line based on resolved levels and return only the embedding levels, one `Level` /// per *character*. #[cfg_attr(feature = "flame_it", flamer::flame)] pub fn reordered_levels_per_char( &self, para: &ParagraphInfo, line: Range, ) -> Vec { let levels = self.reordered_levels(para, line); self.text.char_indices().map(|(i, _)| levels[i]).collect() } /// Re-order a line based on resolved levels and return the line in display order. #[cfg_attr(feature = "flame_it", flamer::flame)] pub fn reorder_line(&self, para: &ParagraphInfo, line: Range) -> Cow<'text, str> { let (levels, runs) = self.visual_runs(para, line.clone()); // If all isolating run sequences are LTR, no reordering is needed if runs.iter().all(|run| levels[run.start].is_ltr()) { return self.text[line].into(); } let mut result = String::with_capacity(line.len()); for run in runs { if levels[run.start].is_rtl() { result.extend(self.text[run].chars().rev()); } else { result.push_str(&self.text[run]); } } result.into() } /// Reorders pre-calculated levels of a sequence of characters. /// /// NOTE: This is a convenience method that does not use a `Paragraph` object. It is /// intended to be used when an application has determined the levels of the objects (character sequences) /// and just needs to have them reordered. /// /// the index map will result in `indexMap[visualIndex]==logicalIndex`. /// /// This only runs [Rule L2](http://www.unicode.org/reports/tr9/#L2) as it does not have /// information about the actual text. /// /// Furthermore, if `levels` is an array that is aligned with code units, bytes within a codepoint may be /// reversed. You may need to fix up the map to deal with this. Alternatively, only pass in arrays where each `Level` /// is for a single code point. /// /// /// # # Example /// ``` /// use unicode_bidi::BidiInfo; /// use unicode_bidi::Level; /// /// let l0 = Level::from(0); /// let l1 = Level::from(1); /// let l2 = Level::from(2); /// /// let levels = vec![l0, l0, l0, l0]; /// let index_map = BidiInfo::reorder_visual(&levels); /// assert_eq!(levels.len(), index_map.len()); /// assert_eq!(index_map, [0, 1, 2, 3]); /// /// let levels: Vec = vec![l0, l0, l0, l1, l1, l1, l2, l2]; /// let index_map = BidiInfo::reorder_visual(&levels); /// assert_eq!(levels.len(), index_map.len()); /// assert_eq!(index_map, [0, 1, 2, 6, 7, 5, 4, 3]); /// ``` pub fn reorder_visual(levels: &[Level]) -> Vec { // Gets the next range of characters after start_index with a level greater // than or equal to `max` fn next_range(levels: &[level::Level], mut start_index: usize, max: Level) -> Range { if levels.is_empty() || start_index >= levels.len() { return start_index..start_index; } while let Some(l) = levels.get(start_index) { if *l >= max { break; } start_index += 1; } if levels.get(start_index).is_none() { // If at the end of the array, adding one will // produce an out-of-range end element return start_index..start_index; } let mut end_index = start_index + 1; while let Some(l) = levels.get(end_index) { if *l < max { return start_index..end_index; } end_index += 1; } start_index..end_index } // This implementation is similar to the L2 implementation in `visual_runs()` // but it cannot benefit from a precalculated LevelRun vector so needs to be different. if levels.is_empty() { return vec![]; } // Get the min and max levels let (mut min, mut max) = levels .iter() .fold((levels[0], levels[0]), |(min, max), &l| { (cmp::min(min, l), cmp::max(max, l)) }); // Initialize an index map let mut result: Vec = (0..levels.len()).collect(); if min == max && min.is_ltr() { // Everything is LTR and at the same level, do nothing return result; } // Stop at the lowest *odd* level, since everything below that // is LTR and does not need further reordering min = min.new_lowest_ge_rtl().expect("Level error"); // For each max level, take all contiguous chunks of // levels ≥ max and reverse them // // We can do this check with the original levels instead of checking reorderings because all // prior reorderings will have been for contiguous chunks of levels >> max, which will // be a subset of these chunks anyway. while min <= max { let mut range = 0..0; loop { range = next_range(levels, range.end, max); result[range.clone()].reverse(); if range.end >= levels.len() { break; } } max.lower(1).expect("Level error"); } result } /// Find the level runs within a line and return them in visual order. /// /// `line` is a range of bytes indices within `levels`. /// /// #[cfg_attr(feature = "flame_it", flamer::flame)] pub fn visual_runs( &self, para: &ParagraphInfo, line: Range, ) -> (Vec, Vec) { assert!(line.start <= self.levels.len()); assert!(line.end <= self.levels.len()); let mut levels = self.levels.clone(); let line_classes = &self.original_classes[line.clone()]; let line_levels = &mut levels[line.clone()]; // Reset some whitespace chars to paragraph level. // let line_str: &str = &self.text[line.clone()]; let mut reset_from: Option = Some(0); let mut reset_to: Option = None; let mut prev_level = para.level; for (i, c) in line_str.char_indices() { match line_classes[i] { // Segment separator, Paragraph separator B | S => { assert_eq!(reset_to, None); reset_to = Some(i + c.len_utf8()); if reset_from == None { reset_from = Some(i); } } // Whitespace, isolate formatting WS | FSI | LRI | RLI | PDI => { if reset_from == None { reset_from = Some(i); } } // // same as above + set the level RLE | LRE | RLO | LRO | PDF | BN => { if reset_from == None { reset_from = Some(i); } // also set the level to previous line_levels[i] = prev_level; } _ => { reset_from = None; } } if let (Some(from), Some(to)) = (reset_from, reset_to) { for level in &mut line_levels[from..to] { *level = para.level; } reset_from = None; reset_to = None; } prev_level = line_levels[i]; } if let Some(from) = reset_from { for level in &mut line_levels[from..] { *level = para.level; } } // Find consecutive level runs. let mut runs = Vec::new(); let mut start = line.start; let mut run_level = levels[start]; let mut min_level = run_level; let mut max_level = run_level; for (i, &new_level) in levels.iter().enumerate().take(line.end).skip(start + 1) { if new_level != run_level { // End of the previous run, start of a new one. runs.push(start..i); start = i; run_level = new_level; min_level = cmp::min(run_level, min_level); max_level = cmp::max(run_level, max_level); } } runs.push(start..line.end); let run_count = runs.len(); // Re-order the odd runs. // // Stop at the lowest *odd* level. min_level = min_level.new_lowest_ge_rtl().expect("Level error"); // This loop goes through contiguous chunks of level runs that have a level // ≥ max_level and reverses their contents, reducing max_level by 1 each time. // // It can do this check with the original levels instead of checking reorderings because all // prior reorderings will have been for contiguous chunks of levels >> max, which will // be a subset of these chunks anyway. while max_level >= min_level { // Look for the start of a sequence of consecutive runs of max_level or higher. let mut seq_start = 0; while seq_start < run_count { if self.levels[runs[seq_start].start] < max_level { seq_start += 1; continue; } // Found the start of a sequence. Now find the end. let mut seq_end = seq_start + 1; while seq_end < run_count { if self.levels[runs[seq_end].start] < max_level { break; } seq_end += 1; } // Reverse the runs within this sequence. runs[seq_start..seq_end].reverse(); seq_start = seq_end; } max_level .lower(1) .expect("Lowering embedding level below zero"); } (levels, runs) } /// If processed text has any computed RTL levels /// /// This information is usually used to skip re-ordering of text when no RTL level is present #[inline] pub fn has_rtl(&self) -> bool { level::has_rtl(&self.levels) } } /// Contains a reference of `BidiInfo` and one of its `paragraphs`. /// And it supports all operation in the `Paragraph` that needs also its /// `BidiInfo` such as `direction`. #[derive(Debug)] pub struct Paragraph<'a, 'text> { pub info: &'a BidiInfo<'text>, pub para: &'a ParagraphInfo, } impl<'a, 'text> Paragraph<'a, 'text> { pub fn new(info: &'a BidiInfo<'text>, para: &'a ParagraphInfo) -> Paragraph<'a, 'text> { Paragraph { info, para } } /// Returns if the paragraph is Left direction, right direction or mixed. pub fn direction(&self) -> Direction { let mut ltr = false; let mut rtl = false; for i in self.para.range.clone() { if self.info.levels[i].is_ltr() { ltr = true; } if self.info.levels[i].is_rtl() { rtl = true; } } if ltr && rtl { return Direction::Mixed; } if ltr { return Direction::Ltr; } Direction::Rtl } /// Returns the `Level` of a certain character in the paragraph. pub fn level_at(&self, pos: usize) -> Level { let actual_position = self.para.range.start + pos; self.info.levels[actual_position] } } /// Assign levels to characters removed by rule X9. /// /// The levels assigned to these characters are not specified by the algorithm. This function /// assigns each one the level of the previous character, to avoid breaking level runs. #[cfg_attr(feature = "flame_it", flamer::flame)] fn assign_levels_to_removed_chars(para_level: Level, classes: &[BidiClass], levels: &mut [Level]) { for i in 0..levels.len() { if prepare::removed_by_x9(classes[i]) { levels[i] = if i > 0 { levels[i - 1] } else { para_level }; } } } #[cfg(test)] #[cfg(feature = "hardcoded-data")] mod tests { use super::*; #[test] fn test_initial_text_info() { let text = "a1"; assert_eq!( InitialInfo::new(text, None), InitialInfo { text, original_classes: vec![L, EN], paragraphs: vec![ParagraphInfo { range: 0..2, level: LTR_LEVEL, },], } ); let text = "غ א"; assert_eq!( InitialInfo::new(text, None), InitialInfo { text, original_classes: vec![AL, AL, WS, R, R], paragraphs: vec![ParagraphInfo { range: 0..5, level: RTL_LEVEL, },], } ); let text = "a\u{2029}b"; assert_eq!( InitialInfo::new(text, None), InitialInfo { text, original_classes: vec![L, B, B, B, L], paragraphs: vec![ ParagraphInfo { range: 0..4, level: LTR_LEVEL, }, ParagraphInfo { range: 4..5, level: LTR_LEVEL, }, ], } ); let text = format!("{}א{}a", chars::FSI, chars::PDI); assert_eq!( InitialInfo::new(&text, None), InitialInfo { text: &text, original_classes: vec![RLI, RLI, RLI, R, R, PDI, PDI, PDI, L], paragraphs: vec![ParagraphInfo { range: 0..9, level: LTR_LEVEL, },], } ); } #[test] #[cfg(feature = "hardcoded-data")] fn test_process_text() { let text = "abc123"; assert_eq!( BidiInfo::new(text, Some(LTR_LEVEL)), BidiInfo { text, levels: Level::vec(&[0, 0, 0, 0, 0, 0]), original_classes: vec![L, L, L, EN, EN, EN], paragraphs: vec![ParagraphInfo { range: 0..6, level: LTR_LEVEL, },], } ); let text = "abc אבג"; assert_eq!( BidiInfo::new(text, Some(LTR_LEVEL)), BidiInfo { text, levels: Level::vec(&[0, 0, 0, 0, 1, 1, 1, 1, 1, 1]), original_classes: vec![L, L, L, WS, R, R, R, R, R, R], paragraphs: vec![ParagraphInfo { range: 0..10, level: LTR_LEVEL, },], } ); assert_eq!( BidiInfo::new(text, Some(RTL_LEVEL)), BidiInfo { text, levels: Level::vec(&[2, 2, 2, 1, 1, 1, 1, 1, 1, 1]), original_classes: vec![L, L, L, WS, R, R, R, R, R, R], paragraphs: vec![ParagraphInfo { range: 0..10, level: RTL_LEVEL, },], } ); let text = "אבג abc"; assert_eq!( BidiInfo::new(text, Some(LTR_LEVEL)), BidiInfo { text, levels: Level::vec(&[1, 1, 1, 1, 1, 1, 0, 0, 0, 0]), original_classes: vec![R, R, R, R, R, R, WS, L, L, L], paragraphs: vec![ParagraphInfo { range: 0..10, level: LTR_LEVEL, },], } ); assert_eq!( BidiInfo::new(text, None), BidiInfo { text, levels: Level::vec(&[1, 1, 1, 1, 1, 1, 1, 2, 2, 2]), original_classes: vec![R, R, R, R, R, R, WS, L, L, L], paragraphs: vec![ParagraphInfo { range: 0..10, level: RTL_LEVEL, },], } ); let text = "غ2ظ א2ג"; assert_eq!( BidiInfo::new(text, Some(LTR_LEVEL)), BidiInfo { text, levels: Level::vec(&[1, 1, 2, 1, 1, 1, 1, 1, 2, 1, 1]), original_classes: vec![AL, AL, EN, AL, AL, WS, R, R, EN, R, R], paragraphs: vec![ParagraphInfo { range: 0..11, level: LTR_LEVEL, },], } ); let text = "a א.\nג"; assert_eq!( BidiInfo::new(text, None), BidiInfo { text, original_classes: vec![L, WS, R, R, CS, B, R, R], levels: Level::vec(&[0, 0, 1, 1, 0, 0, 1, 1]), paragraphs: vec![ ParagraphInfo { range: 0..6, level: LTR_LEVEL, }, ParagraphInfo { range: 6..8, level: RTL_LEVEL, }, ], } ); // BidiTest:69635 (AL ET EN) let bidi_info = BidiInfo::new("\u{060B}\u{20CF}\u{06F9}", None); assert_eq!(bidi_info.original_classes, vec![AL, AL, ET, ET, ET, EN, EN]); } #[test] #[cfg(feature = "hardcoded-data")] fn test_bidi_info_has_rtl() { // ASCII only assert_eq!(BidiInfo::new("123", None).has_rtl(), false); assert_eq!(BidiInfo::new("123", Some(LTR_LEVEL)).has_rtl(), false); assert_eq!(BidiInfo::new("123", Some(RTL_LEVEL)).has_rtl(), false); assert_eq!(BidiInfo::new("abc", None).has_rtl(), false); assert_eq!(BidiInfo::new("abc", Some(LTR_LEVEL)).has_rtl(), false); assert_eq!(BidiInfo::new("abc", Some(RTL_LEVEL)).has_rtl(), false); assert_eq!(BidiInfo::new("abc 123", None).has_rtl(), false); assert_eq!(BidiInfo::new("abc\n123", None).has_rtl(), false); // With Hebrew assert_eq!(BidiInfo::new("אבּג", None).has_rtl(), true); assert_eq!(BidiInfo::new("אבּג", Some(LTR_LEVEL)).has_rtl(), true); assert_eq!(BidiInfo::new("אבּג", Some(RTL_LEVEL)).has_rtl(), true); assert_eq!(BidiInfo::new("abc אבּג", None).has_rtl(), true); assert_eq!(BidiInfo::new("abc\nאבּג", None).has_rtl(), true); assert_eq!(BidiInfo::new("אבּג abc", None).has_rtl(), true); assert_eq!(BidiInfo::new("אבּג\nabc", None).has_rtl(), true); assert_eq!(BidiInfo::new("אבּג 123", None).has_rtl(), true); assert_eq!(BidiInfo::new("אבּג\n123", None).has_rtl(), true); } #[cfg(feature = "hardcoded-data")] fn reorder_paras(text: &str) -> Vec> { let bidi_info = BidiInfo::new(text, None); bidi_info .paragraphs .iter() .map(|para| bidi_info.reorder_line(para, para.range.clone())) .collect() } #[test] #[cfg(feature = "hardcoded-data")] fn test_reorder_line() { // Bidi_Class: L L L B L L L B L L L assert_eq!( reorder_paras("abc\ndef\nghi"), vec!["abc\n", "def\n", "ghi"] ); // Bidi_Class: L L EN B L L EN B L L EN assert_eq!( reorder_paras("ab1\nde2\ngh3"), vec!["ab1\n", "de2\n", "gh3"] ); // Bidi_Class: L L L B AL AL AL assert_eq!(reorder_paras("abc\nابج"), vec!["abc\n", "جبا"]); // Bidi_Class: AL AL AL B L L L assert_eq!(reorder_paras("ابج\nabc"), vec!["\nجبا", "abc"]); assert_eq!(reorder_paras("1.-2"), vec!["1.-2"]); assert_eq!(reorder_paras("1-.2"), vec!["1-.2"]); assert_eq!(reorder_paras("abc אבג"), vec!["abc גבא"]); // Numbers being weak LTR characters, cannot reorder strong RTL assert_eq!(reorder_paras("123 אבג"), vec!["גבא 123"]); assert_eq!(reorder_paras("abc\u{202A}def"), vec!["abc\u{202A}def"]); assert_eq!( reorder_paras("abc\u{202A}def\u{202C}ghi"), vec!["abc\u{202A}def\u{202C}ghi"] ); assert_eq!( reorder_paras("abc\u{2066}def\u{2069}ghi"), vec!["abc\u{2066}def\u{2069}ghi"] ); // Testing for RLE Character assert_eq!( reorder_paras("\u{202B}abc אבג\u{202C}"), vec!["\u{202B}\u{202C}גבא abc"] ); // Testing neutral characters assert_eq!(reorder_paras("אבג? אבג"), vec!["גבא ?גבא"]); // Testing neutral characters with special case assert_eq!(reorder_paras("A אבג?"), vec!["A גבא?"]); // Testing neutral characters with Implicit RTL Marker assert_eq!(reorder_paras("A אבג?\u{200F}"), vec!["A \u{200F}?גבא"]); assert_eq!(reorder_paras("אבג abc"), vec!["abc גבא"]); assert_eq!( reorder_paras("abc\u{2067}.-\u{2069}ghi"), vec!["abc\u{2067}-.\u{2069}ghi"] ); assert_eq!( reorder_paras("Hello, \u{2068}\u{202E}world\u{202C}\u{2069}!"), vec!["Hello, \u{2068}\u{202E}\u{202C}dlrow\u{2069}!"] ); // With mirrorable characters in RTL run assert_eq!(reorder_paras("א(ב)ג."), vec![".ג)ב(א"]); // With mirrorable characters on level boundry assert_eq!(reorder_paras("אב(גד[&ef].)gh"), vec!["gh).]ef&[דג(בא"]); } fn reordered_levels_for_paras(text: &str) -> Vec> { let bidi_info = BidiInfo::new(text, None); bidi_info .paragraphs .iter() .map(|para| bidi_info.reordered_levels(para, para.range.clone())) .collect() } fn reordered_levels_per_char_for_paras(text: &str) -> Vec> { let bidi_info = BidiInfo::new(text, None); bidi_info .paragraphs .iter() .map(|para| bidi_info.reordered_levels_per_char(para, para.range.clone())) .collect() } #[test] #[cfg(feature = "hardcoded-data")] fn test_reordered_levels() { // BidiTest:946 (LRI PDI) let text = "\u{2067}\u{2069}"; assert_eq!( reordered_levels_for_paras(text), vec![Level::vec(&[0, 0, 0, 0, 0, 0])] ); assert_eq!( reordered_levels_per_char_for_paras(text), vec![Level::vec(&[0, 0])] ); let text = "aa טֶ"; let bidi_info = BidiInfo::new(text, None); assert_eq!( bidi_info.reordered_levels(&bidi_info.paragraphs[0], 3..7), Level::vec(&[0, 0, 0, 1, 1, 1, 1]), ) /* TODO /// BidiTest:69635 (AL ET EN) let text = "\u{060B}\u{20CF}\u{06F9}"; assert_eq!( reordered_levels_for_paras(text), vec![Level::vec(&[1, 1, 1, 1, 1, 2, 2])] ); assert_eq!( reordered_levels_per_char_for_paras(text), vec![Level::vec(&[1, 1, 2])] ); */ /* TODO // BidiTest:291284 (AN RLI PDF R) assert_eq!( reordered_levels_per_char_for_paras("\u{0605}\u{2067}\u{202C}\u{0590}"), vec![&["2", "0", "x", "1"]] ); */ } #[test] fn test_paragraph_info_len() { let text = "hello world"; let bidi_info = BidiInfo::new(text, None); assert_eq!(bidi_info.paragraphs.len(), 1); assert_eq!(bidi_info.paragraphs[0].len(), text.len()); let text2 = "How are you"; let whole_text = format!("{}\n{}", text, text2); let bidi_info = BidiInfo::new(&whole_text, None); assert_eq!(bidi_info.paragraphs.len(), 2); // The first paragraph include the paragraph separator. // TODO: investigate if the paragraph separator character // should not be part of any paragraph. assert_eq!(bidi_info.paragraphs[0].len(), text.len() + 1); assert_eq!(bidi_info.paragraphs[1].len(), text2.len()); } #[test] fn test_direction() { let ltr_text = "hello world"; let rtl_text = "أهلا بكم"; let all_paragraphs = format!("{}\n{}\n{}{}", ltr_text, rtl_text, ltr_text, rtl_text); let bidi_info = BidiInfo::new(&all_paragraphs, None); assert_eq!(bidi_info.paragraphs.len(), 3); let p_ltr = Paragraph::new(&bidi_info, &bidi_info.paragraphs[0]); let p_rtl = Paragraph::new(&bidi_info, &bidi_info.paragraphs[1]); let p_mixed = Paragraph::new(&bidi_info, &bidi_info.paragraphs[2]); assert_eq!(p_ltr.direction(), Direction::Ltr); assert_eq!(p_rtl.direction(), Direction::Rtl); assert_eq!(p_mixed.direction(), Direction::Mixed); } #[test] fn test_edge_cases_direction() { // No paragraphs for empty text. let empty = ""; let bidi_info = BidiInfo::new(empty, Option::from(RTL_LEVEL)); assert_eq!(bidi_info.paragraphs.len(), 0); // The paragraph separator will take the value of the default direction // which is left to right. let empty = "\n"; let bidi_info = BidiInfo::new(empty, None); assert_eq!(bidi_info.paragraphs.len(), 1); let p = Paragraph::new(&bidi_info, &bidi_info.paragraphs[0]); assert_eq!(p.direction(), Direction::Ltr); // The paragraph separator will take the value of the given initial direction // which is left to right. let empty = "\n"; let bidi_info = BidiInfo::new(empty, Option::from(LTR_LEVEL)); assert_eq!(bidi_info.paragraphs.len(), 1); let p = Paragraph::new(&bidi_info, &bidi_info.paragraphs[0]); assert_eq!(p.direction(), Direction::Ltr); // The paragraph separator will take the value of the given initial direction // which is right to left. let empty = "\n"; let bidi_info = BidiInfo::new(empty, Option::from(RTL_LEVEL)); assert_eq!(bidi_info.paragraphs.len(), 1); let p = Paragraph::new(&bidi_info, &bidi_info.paragraphs[0]); assert_eq!(p.direction(), Direction::Rtl); } #[test] fn test_level_at() { let ltr_text = "hello world"; let rtl_text = "أهلا بكم"; let all_paragraphs = format!("{}\n{}\n{}{}", ltr_text, rtl_text, ltr_text, rtl_text); let bidi_info = BidiInfo::new(&all_paragraphs, None); assert_eq!(bidi_info.paragraphs.len(), 3); let p_ltr = Paragraph::new(&bidi_info, &bidi_info.paragraphs[0]); let p_rtl = Paragraph::new(&bidi_info, &bidi_info.paragraphs[1]); let p_mixed = Paragraph::new(&bidi_info, &bidi_info.paragraphs[2]); assert_eq!(p_ltr.level_at(0), LTR_LEVEL); assert_eq!(p_rtl.level_at(0), RTL_LEVEL); assert_eq!(p_mixed.level_at(0), LTR_LEVEL); assert_eq!(p_mixed.info.levels.len(), 54); assert_eq!(p_mixed.para.range.start, 28); assert_eq!(p_mixed.level_at(ltr_text.len()), RTL_LEVEL); } } #[cfg(all(feature = "serde", feature = "hardcoded-data", test))] mod serde_tests { use super::*; use serde_test::{assert_tokens, Token}; #[test] fn test_levels() { let text = "abc אבג"; let bidi_info = BidiInfo::new(text, None); let levels = bidi_info.levels; assert_eq!(text.as_bytes().len(), 10); assert_eq!(levels.len(), 10); assert_tokens( &levels, &[ Token::Seq { len: Some(10) }, Token::NewtypeStruct { name: "Level" }, Token::U8(0), Token::NewtypeStruct { name: "Level" }, Token::U8(0), Token::NewtypeStruct { name: "Level" }, Token::U8(0), Token::NewtypeStruct { name: "Level" }, Token::U8(0), Token::NewtypeStruct { name: "Level" }, Token::U8(1), Token::NewtypeStruct { name: "Level" }, Token::U8(1), Token::NewtypeStruct { name: "Level" }, Token::U8(1), Token::NewtypeStruct { name: "Level" }, Token::U8(1), Token::NewtypeStruct { name: "Level" }, Token::U8(1), Token::NewtypeStruct { name: "Level" }, Token::U8(1), Token::SeqEnd, ], ); } }