use crate::{Assoc, ChangeSet, Range, Rope, Selection, Transaction}; use once_cell::sync::Lazy; use regex::Regex; use std::num::NonZeroUsize; use std::time::{Duration, Instant}; #[derive(Debug, Clone)] pub struct State { pub doc: Rope, pub selection: Selection, } /// Stores the history of changes to a buffer. /// /// Currently the history is represented as a vector of revisions. The vector /// always has at least one element: the empty root revision. Each revision /// with the exception of the root has a parent revision, a [Transaction] /// that can be applied to its parent to transition from the parent to itself, /// and an inversion of that transaction to transition from the parent to its /// latest child. /// /// When using `u` to undo a change, an inverse of the stored transaction will /// be applied which will transition the buffer to the parent state. /// /// Each revision with the exception of the last in the vector also has a /// last child revision. When using `U` to redo a change, the last child transaction /// will be applied to the current state of the buffer. /// /// The current revision is the one currently displayed in the buffer. /// /// Committing a new revision to the history will update the last child of the /// current revision, and push a new revision to the end of the vector. /// /// Revisions are committed with a timestamp. :earlier and :later can be used /// to jump to the closest revision to a moment in time relative to the timestamp /// of the current revision plus (:later) or minus (:earlier) the duration /// given to the command. If a single integer is given, the editor will instead /// jump the given number of revisions in the vector. /// /// Limitations: /// * Changes in selections currently don't commit history changes. The selection /// will only be updated to the state after a committed buffer change. /// * The vector of history revisions is currently unbounded. This might /// cause the memory consumption to grow significantly large during long /// editing sessions. /// * Because delete transactions currently don't store the text that they /// delete, we also store an inversion of the transaction. /// /// Using time to navigate the history: #[derive(Debug)] pub struct History { revisions: Vec, current: usize, } /// A single point in history. See [History] for more information. #[derive(Debug, Clone)] struct Revision { parent: usize, last_child: Option, transaction: Transaction, // We need an inversion for undos because delete transactions don't store // the deleted text. inversion: Transaction, timestamp: Instant, } impl Default for History { fn default() -> Self { // Add a dummy root revision with empty transaction Self { revisions: vec![Revision { parent: 0, last_child: None, transaction: Transaction::from(ChangeSet::new(&Rope::new())), inversion: Transaction::from(ChangeSet::new(&Rope::new())), timestamp: Instant::now(), }], current: 0, } } } impl History { pub fn commit_revision(&mut self, transaction: &Transaction, original: &State) { self.commit_revision_at_timestamp(transaction, original, Instant::now()); } pub fn commit_revision_at_timestamp( &mut self, transaction: &Transaction, original: &State, timestamp: Instant, ) { let inversion = transaction .invert(&original.doc) // Store the current cursor position .with_selection(original.selection.clone()); let new_current = self.revisions.len(); self.revisions[self.current].last_child = NonZeroUsize::new(new_current); self.revisions.push(Revision { parent: self.current, last_child: None, transaction: transaction.clone(), inversion, timestamp, }); self.current = new_current; } #[inline] pub fn current_revision(&self) -> usize { self.current } #[inline] pub const fn at_root(&self) -> bool { self.current == 0 } /// Returns the changes since the given revision composed into a transaction. /// Returns None if there are no changes between the current and given revisions. pub fn changes_since(&self, revision: usize) -> Option { use std::cmp::Ordering::*; match revision.cmp(&self.current) { Equal => None, Less => { let mut child = self.revisions[revision].last_child?.get(); let mut transaction = self.revisions[child].transaction.clone(); while child != self.current { child = self.revisions[child].last_child?.get(); transaction = transaction.compose(self.revisions[child].transaction.clone()); } Some(transaction) } Greater => { let mut inversion = self.revisions[revision].inversion.clone(); let mut parent = self.revisions[revision].parent; while parent != self.current { parent = self.revisions[parent].parent; if parent == 0 { return None; } inversion = inversion.compose(self.revisions[parent].inversion.clone()); } Some(inversion) } } } /// Undo the last edit. pub fn undo(&mut self) -> Option<&Transaction> { if self.at_root() { return None; } let current_revision = &self.revisions[self.current]; self.current = current_revision.parent; Some(¤t_revision.inversion) } /// Redo the last edit. pub fn redo(&mut self) -> Option<&Transaction> { let current_revision = &self.revisions[self.current]; let last_child = current_revision.last_child?; self.current = last_child.get(); Some(&self.revisions[last_child.get()].transaction) } // Get the position of last change pub fn last_edit_pos(&self) -> Option { if self.current == 0 { return None; } let current_revision = &self.revisions[self.current]; let primary_selection = current_revision .inversion .selection() .expect("inversion always contains a selection") .primary(); let (_from, to, _fragment) = current_revision .transaction .changes_iter() // find a change that matches the primary selection .find(|(from, to, _fragment)| Range::new(*from, *to).overlaps(&primary_selection)) // or use the first change .or_else(|| current_revision.transaction.changes_iter().next()) .unwrap(); let pos = current_revision .transaction .changes() .map_pos(to, Assoc::After); Some(pos) } fn lowest_common_ancestor(&self, mut a: usize, mut b: usize) -> usize { use std::collections::HashSet; let mut a_path_set = HashSet::new(); let mut b_path_set = HashSet::new(); loop { a_path_set.insert(a); b_path_set.insert(b); if a_path_set.contains(&b) { return b; } if b_path_set.contains(&a) { return a; } a = self.revisions[a].parent; // Relies on the parent of 0 being 0. b = self.revisions[b].parent; // Same as above. } } /// List of nodes on the way from `n` to 'a`. Doesn't include `a`. /// Includes `n` unless `a == n`. `a` must be an ancestor of `n`. fn path_up(&self, mut n: usize, a: usize) -> Vec { let mut path = Vec::new(); while n != a { path.push(n); n = self.revisions[n].parent; } path } /// Create a [`Transaction`] that will jump to a specific revision in the history. fn jump_to(&mut self, to: usize) -> Vec { let lca = self.lowest_common_ancestor(self.current, to); let up = self.path_up(self.current, lca); let down = self.path_up(to, lca); self.current = to; let up_txns = up.iter().map(|&n| self.revisions[n].inversion.clone()); let down_txns = down .iter() .rev() .map(|&n| self.revisions[n].transaction.clone()); up_txns.chain(down_txns).collect() } /// Creates a [`Transaction`] that will undo `delta` revisions. fn jump_backward(&mut self, delta: usize) -> Vec { self.jump_to(self.current.saturating_sub(delta)) } /// Creates a [`Transaction`] that will redo `delta` revisions. fn jump_forward(&mut self, delta: usize) -> Vec { self.jump_to( self.current .saturating_add(delta) .min(self.revisions.len() - 1), ) } /// Helper for a binary search case below. fn revision_closer_to_instant(&self, i: usize, instant: Instant) -> usize { let dur_im1 = instant.duration_since(self.revisions[i - 1].timestamp); let dur_i = self.revisions[i].timestamp.duration_since(instant); use std::cmp::Ordering::*; match dur_im1.cmp(&dur_i) { Less => i - 1, Equal | Greater => i, } } /// Creates a [`Transaction`] that will match a revision created at around /// `instant`. fn jump_instant(&mut self, instant: Instant) -> Vec { let search_result = self .revisions .binary_search_by(|rev| rev.timestamp.cmp(&instant)); let revision = match search_result { Ok(revision) => revision, Err(insert_point) => match insert_point { 0 => 0, n if n == self.revisions.len() => n - 1, i => self.revision_closer_to_instant(i, instant), }, }; self.jump_to(revision) } /// Creates a [`Transaction`] that will match a revision created `duration` ago /// from the timestamp of current revision. fn jump_duration_backward(&mut self, duration: Duration) -> Vec { match self.revisions[self.current].timestamp.checked_sub(duration) { Some(instant) => self.jump_instant(instant), None => self.jump_to(0), } } /// Creates a [`Transaction`] that will match a revision created `duration` in /// the future from the timestamp of the current revision. fn jump_duration_forward(&mut self, duration: Duration) -> Vec { match self.revisions[self.current].timestamp.checked_add(duration) { Some(instant) => self.jump_instant(instant), None => self.jump_to(self.revisions.len() - 1), } } /// Creates an undo [`Transaction`]. pub fn earlier(&mut self, uk: UndoKind) -> Vec { use UndoKind::*; match uk { Steps(n) => self.jump_backward(n), TimePeriod(d) => self.jump_duration_backward(d), } } /// Creates a redo [`Transaction`]. pub fn later(&mut self, uk: UndoKind) -> Vec { use UndoKind::*; match uk { Steps(n) => self.jump_forward(n), TimePeriod(d) => self.jump_duration_forward(d), } } } /// Whether to undo by a number of edits or a duration of time. #[derive(Debug, PartialEq, Eq, Clone, Copy)] pub enum UndoKind { Steps(usize), TimePeriod(std::time::Duration), } /// A subset of systemd.time time span syntax units. const TIME_UNITS: &[(&[&str], &str, u64)] = &[ (&["seconds", "second", "sec", "s"], "seconds", 1), (&["minutes", "minute", "min", "m"], "minutes", 60), (&["hours", "hour", "hr", "h"], "hours", 60 * 60), (&["days", "day", "d"], "days", 24 * 60 * 60), ]; /// Checks if the duration input can be turned into a valid duration. It must be a /// positive integer and denote the [unit of time.](`TIME_UNITS`) /// Examples of valid durations: /// * `5 sec` /// * `5 min` /// * `5 hr` /// * `5 days` static DURATION_VALIDATION_REGEX: Lazy = Lazy::new(|| Regex::new(r"^(?:\d+\s*[a-z]+\s*)+$").unwrap()); /// Captures both the number and unit as separate capture groups. static NUMBER_UNIT_REGEX: Lazy = Lazy::new(|| Regex::new(r"(\d+)\s*([a-z]+)").unwrap()); /// Parse a string (e.g. "5 sec") and try to convert it into a [`Duration`]. fn parse_human_duration(s: &str) -> Result { if !DURATION_VALIDATION_REGEX.is_match(s) { return Err("duration should be composed \ of positive integers followed by time units" .to_string()); } let mut specified = [false; TIME_UNITS.len()]; let mut seconds = 0u64; for cap in NUMBER_UNIT_REGEX.captures_iter(s) { let (n, unit_str) = (&cap[1], &cap[2]); let n: u64 = n.parse().map_err(|_| format!("integer too large: {}", n))?; let time_unit = TIME_UNITS .iter() .enumerate() .find(|(_, (forms, _, _))| forms.iter().any(|f| f == &unit_str)); if let Some((i, (_, unit, mul))) = time_unit { if specified[i] { return Err(format!("{} specified more than once", unit)); } specified[i] = true; let new_seconds = n.checked_mul(*mul).and_then(|s| seconds.checked_add(s)); match new_seconds { Some(ns) => seconds = ns, None => return Err("duration too large".to_string()), } } else { return Err(format!("incorrect time unit: {}", unit_str)); } } Ok(Duration::from_secs(seconds)) } impl std::str::FromStr for UndoKind { type Err = String; fn from_str(s: &str) -> Result { let s = s.trim(); if s.is_empty() { Ok(Self::Steps(1usize)) } else if let Ok(n) = s.parse::() { Ok(UndoKind::Steps(n)) } else { Ok(Self::TimePeriod(parse_human_duration(s)?)) } } } #[cfg(test)] mod test { use super::*; use crate::Selection; #[test] fn test_undo_redo() { let mut history = History::default(); let doc = Rope::from("hello"); let mut state = State { doc, selection: Selection::point(0), }; let transaction1 = Transaction::change(&state.doc, vec![(5, 5, Some(" world!".into()))].into_iter()); // Need to commit before applying! history.commit_revision(&transaction1, &state); transaction1.apply(&mut state.doc); assert_eq!("hello world!", state.doc); // --- let transaction2 = Transaction::change(&state.doc, vec![(6, 11, Some("世界".into()))].into_iter()); // Need to commit before applying! history.commit_revision(&transaction2, &state); transaction2.apply(&mut state.doc); assert_eq!("hello 世界!", state.doc); // --- fn undo(history: &mut History, state: &mut State) { if let Some(transaction) = history.undo() { transaction.apply(&mut state.doc); } } fn redo(history: &mut History, state: &mut State) { if let Some(transaction) = history.redo() { transaction.apply(&mut state.doc); } } undo(&mut history, &mut state); assert_eq!("hello world!", state.doc); redo(&mut history, &mut state); assert_eq!("hello 世界!", state.doc); undo(&mut history, &mut state); undo(&mut history, &mut state); assert_eq!("hello", state.doc); // undo at root is a no-op undo(&mut history, &mut state); assert_eq!("hello", state.doc); } #[test] fn test_earlier_later() { let mut history = History::default(); let doc = Rope::from("a\n"); let mut state = State { doc, selection: Selection::point(0), }; fn undo(history: &mut History, state: &mut State) { if let Some(transaction) = history.undo() { transaction.apply(&mut state.doc); } } fn earlier(history: &mut History, state: &mut State, uk: UndoKind) { let txns = history.earlier(uk); for txn in txns { txn.apply(&mut state.doc); } } fn later(history: &mut History, state: &mut State, uk: UndoKind) { let txns = history.later(uk); for txn in txns { txn.apply(&mut state.doc); } } fn commit_change( history: &mut History, state: &mut State, change: crate::transaction::Change, instant: Instant, ) { let txn = Transaction::change(&state.doc, vec![change].into_iter()); history.commit_revision_at_timestamp(&txn, state, instant); txn.apply(&mut state.doc); } let t0 = Instant::now(); let t = |n| t0.checked_add(Duration::from_secs(n)).unwrap(); commit_change(&mut history, &mut state, (1, 1, Some(" b".into())), t(0)); assert_eq!("a b\n", state.doc); commit_change(&mut history, &mut state, (3, 3, Some(" c".into())), t(10)); assert_eq!("a b c\n", state.doc); commit_change(&mut history, &mut state, (5, 5, Some(" d".into())), t(20)); assert_eq!("a b c d\n", state.doc); undo(&mut history, &mut state); assert_eq!("a b c\n", state.doc); commit_change(&mut history, &mut state, (5, 5, Some(" e".into())), t(30)); assert_eq!("a b c e\n", state.doc); undo(&mut history, &mut state); undo(&mut history, &mut state); assert_eq!("a b\n", state.doc); commit_change(&mut history, &mut state, (1, 3, None), t(40)); assert_eq!("a\n", state.doc); commit_change(&mut history, &mut state, (1, 1, Some(" f".into())), t(50)); assert_eq!("a f\n", state.doc); use UndoKind::*; earlier(&mut history, &mut state, Steps(3)); assert_eq!("a b c d\n", state.doc); later(&mut history, &mut state, TimePeriod(Duration::new(20, 0))); assert_eq!("a\n", state.doc); earlier(&mut history, &mut state, TimePeriod(Duration::new(19, 0))); assert_eq!("a b c d\n", state.doc); earlier( &mut history, &mut state, TimePeriod(Duration::new(10000, 0)), ); assert_eq!("a\n", state.doc); later(&mut history, &mut state, Steps(50)); assert_eq!("a f\n", state.doc); earlier(&mut history, &mut state, Steps(4)); assert_eq!("a b c\n", state.doc); later(&mut history, &mut state, TimePeriod(Duration::new(1, 0))); assert_eq!("a b c\n", state.doc); later(&mut history, &mut state, TimePeriod(Duration::new(5, 0))); assert_eq!("a b c d\n", state.doc); later(&mut history, &mut state, TimePeriod(Duration::new(6, 0))); assert_eq!("a b c e\n", state.doc); later(&mut history, &mut state, Steps(1)); assert_eq!("a\n", state.doc); } #[test] fn test_parse_undo_kind() { use UndoKind::*; // Default is one step. assert_eq!("".parse(), Ok(Steps(1))); // An integer means the number of steps. assert_eq!("1".parse(), Ok(Steps(1))); assert_eq!(" 16 ".parse(), Ok(Steps(16))); // Duration has a strict format. let validation_err = Err("duration should be composed \ of positive integers followed by time units" .to_string()); assert_eq!(" 16 33".parse::(), validation_err); assert_eq!(" seconds 22 ".parse::(), validation_err); assert_eq!(" -4 m".parse::(), validation_err); assert_eq!("5s 3".parse::(), validation_err); // Units are u64. assert_eq!( "18446744073709551616minutes".parse::(), Err("integer too large: 18446744073709551616".to_string()) ); // Units are validated. assert_eq!( "1 millennium".parse::(), Err("incorrect time unit: millennium".to_string()) ); // Units can't be specified twice. assert_eq!( "2 seconds 6s".parse::(), Err("seconds specified more than once".to_string()) ); // Various formats are correctly handled. assert_eq!( "4s".parse::(), Ok(TimePeriod(Duration::from_secs(4))) ); assert_eq!( "2m".parse::(), Ok(TimePeriod(Duration::from_secs(120))) ); assert_eq!( "5h".parse::(), Ok(TimePeriod(Duration::from_secs(5 * 60 * 60))) ); assert_eq!( "3d".parse::(), Ok(TimePeriod(Duration::from_secs(3 * 24 * 60 * 60))) ); assert_eq!( "1m30s".parse::(), Ok(TimePeriod(Duration::from_secs(90))) ); assert_eq!( "1m 20 seconds".parse::(), Ok(TimePeriod(Duration::from_secs(80))) ); assert_eq!( " 2 minute 1day".parse::(), Ok(TimePeriod(Duration::from_secs(24 * 60 * 60 + 2 * 60))) ); assert_eq!( "3 d 2hour 5 minutes 30sec".parse::(), Ok(TimePeriod(Duration::from_secs( 3 * 24 * 60 * 60 + 2 * 60 * 60 + 5 * 60 + 30 ))) ); // Sum overflow is handled. assert_eq!( "18446744073709551615minutes".parse::(), Err("duration too large".to_string()) ); assert_eq!( "1 minute 18446744073709551615 seconds".parse::(), Err("duration too large".to_string()) ); } }