use crate::{Range, Rope, Selection, State, Tendril}; use std::borrow::Cow; use std::convert::TryFrom; /// (from, to, replacement) pub type Change = (usize, usize, Option); #[derive(Debug, Clone, PartialEq, Eq)] pub(crate) enum Operation { /// Move cursor by n characters. Retain(usize), /// Delete n characters. Delete(usize), /// Insert text at position. Insert(Tendril), } #[derive(Copy, Clone, PartialEq, Eq)] pub enum Assoc { Before, After, } // ChangeSpec = Change | ChangeSet | Vec #[derive(Debug, Clone, PartialEq, Eq)] pub struct ChangeSet { pub(crate) changes: Vec, /// The required document length. Will refuse to apply changes unless it matches. len: usize, } impl ChangeSet { #[must_use] pub fn new(doc: &Rope) -> Self { let len = doc.len_chars(); Self { changes: vec![Operation::Retain(len)], len, } } // TODO: from iter /// Combine two changesets together. /// In other words, If `this` goes `docA` → `docB` and `other` represents `docB` → `docC`, the /// returned value will represent the change `docA` → `docC`. pub fn compose(self, other: ChangeSet) -> Result { // TODO: len before b should match len after a let len = self.changes.len(); let mut changes_a = self.changes.into_iter(); let mut changes_b = other.changes.into_iter(); let mut head_a = changes_a.next(); let mut head_b = changes_b.next(); let mut changes: Vec = Vec::with_capacity(len); // TODO: max(a, b), shrink_to_fit() afterwards loop { use std::cmp::Ordering; use Operation::*; match (head_a, head_b) { // we are done (None, None) => { break; } // deletion in A (Some(change @ Delete(..)), b) => { changes.push(change); head_a = changes_a.next(); head_b = b; } // insertion in B (a, Some(change @ Insert(..))) => { changes.push(change); head_a = a; head_b = changes_b.next(); } (None, _) | (_, None) => return Err(()), (Some(Retain(i)), Some(Retain(j))) => match i.cmp(&j) { Ordering::Less => { changes.push(Retain(i)); head_a = changes_a.next(); head_b = Some(Retain(j - i)); } Ordering::Equal => { changes.push(Retain(i)); head_a = changes_a.next(); head_b = changes_b.next(); } Ordering::Greater => { changes.push(Retain(j)); head_a = Some(Retain(i - j)); head_b = changes_b.next(); } }, (Some(Insert(mut s)), Some(Delete(j))) => { let len = s.chars().count(); match len.cmp(&j) { Ordering::Less => { head_a = changes_a.next(); head_b = Some(Delete(j - len)); } Ordering::Equal => { head_a = changes_a.next(); head_b = changes_b.next(); } Ordering::Greater => { // figure out the byte index of the truncated string end let (pos, _) = s.char_indices().nth(len - j).unwrap(); // calculate the difference let to_drop = s.len() - pos; s.pop_back(u32::try_from(to_drop).unwrap()); head_a = Some(Insert(s)); head_b = changes_b.next(); } } } (Some(Insert(mut s)), Some(Retain(j))) => { let len = s.chars().count(); match len.cmp(&j) { Ordering::Less => { changes.push(Insert(s)); head_a = changes_a.next(); head_b = Some(Retain(j - len)); } Ordering::Equal => { changes.push(Insert(s)); head_a = changes_a.next(); head_b = changes_b.next(); } Ordering::Greater => { // figure out the byte index of the truncated string end let (pos, _) = s.char_indices().nth(j).unwrap(); // calculate the difference let to_drop = s.len() - pos; s.pop_back(u32::try_from(to_drop).unwrap()); head_a = Some(Insert(s)); head_b = changes_b.next(); } } } (Some(Retain(i)), Some(Delete(j))) => match i.cmp(&j) { Ordering::Less => { changes.push(Delete(i)); head_a = changes_a.next(); head_b = Some(Delete(j - i)); } Ordering::Equal => { changes.push(Delete(j)); head_a = changes_a.next(); head_b = changes_b.next(); } Ordering::Greater => { changes.push(Delete(j)); head_a = Some(Retain(i - j)); head_b = changes_b.next(); } }, }; } Ok(Self { len: self.len, changes, }) } /// Given another change set starting in the same document, maps this /// change set over the other, producing a new change set that can be /// applied to the document produced by applying `other`. When /// `before` is `true`, order changes as if `this` comes before /// `other`, otherwise (the default) treat `other` as coming first. /// /// Given two changes `A` and `B`, `A.compose(B.map(A))` and /// `B.compose(A.map(B, true))` will produce the same document. This /// provides a basic form of [operational /// transformation](https://en.wikipedia.org/wiki/Operational_transformation), /// and can be used for collaborative editing. pub fn map(self, _other: Self) -> Self { unimplemented!() } /// Returns a new changeset that reverts this one. Useful for `undo` implementation. /// The document parameter expects the original document before this change was applied. pub fn invert(&self, original_doc: &Rope) -> Self { if original_doc.len_chars() != self.len { panic!("Document length mismatch"); // return false; } let mut changes = Vec::with_capacity(self.changes.len()); let mut pos = 0; let mut len = 0; for change in &self.changes { use Operation::*; match change { Retain(n) => { changes.push(Retain(*n)); pos += n; len += n; } Delete(n) => { let text = Cow::from(original_doc.slice(pos..pos + *n)); changes.push(Insert(Tendril::from_slice(&text))); pos += n; } Insert(s) => { let chars = s.chars().count(); changes.push(Delete(chars)); len += chars; } } } Self { changes, len } } /// Returns true if applied successfully. pub fn apply(&self, text: &mut Rope) -> bool { if text.len_chars() != self.len { return false; } let mut pos = 0; for change in &self.changes { use Operation::*; match change { Retain(n) => { pos += n; } Delete(n) => { text.remove(pos..pos + *n); // pos += n; } Insert(s) => { text.insert(pos, s); pos += s.chars().count(); } } } true } /// `true` when the set is empty. #[inline] pub fn is_empty(&self) -> bool { let len = self.changes.len(); len == 0 || (len == 1 && self.changes[0] == Operation::Retain(self.len)) } /// Map a position through the changes. /// /// `assoc` indicates which size to associate the position with. `Before` will keep the /// position close to the character before, and will place it before insertions over that /// range, or at that point. `After` will move it forward, placing it at the end of such /// insertions. pub fn map_pos(&self, pos: usize, assoc: Assoc) -> usize { use Operation::*; let mut old_pos = 0; let mut new_pos = 0; let mut iter = self.changes.iter().peekable(); while let Some(change) = iter.next() { let len = match change { Delete(i) | Retain(i) => *i, Insert(_) => 0, }; let old_end = old_pos + len; match change { Retain(_) => { if old_end > pos { return new_pos + (pos - old_pos); } new_pos += len; } Delete(_) => { // a subsequent ins means a replace, consume it let ins = if let Some(Insert(s)) = iter.peek() { iter.next(); s.chars().count() } else { 0 }; // in range if old_end > pos { // at point or tracking before if pos == old_pos || assoc == Assoc::Before { return new_pos; } else { // place to end of delete return new_pos + ins; } } new_pos += ins; } Insert(s) => { let ins = s.chars().count(); // at insert point if old_pos == pos { // return position before inserted text if assoc == Assoc::Before { return new_pos; } else { // after text return new_pos + ins; } } new_pos += ins; } } old_pos = old_end; } if pos > old_pos { panic!( "Position {} is out of range for changeset len {}!", pos, old_pos ) } new_pos } } /// Transaction represents a single undoable unit of changes. Several changes can be grouped into /// a single transaction. #[derive(Debug, Clone)] pub struct Transaction { /// Changes made to the buffer. pub(crate) changes: ChangeSet, /// When set, explicitly updates the selection. selection: Option, // effects, annotations // scroll_into_view } impl Transaction { /// Create a new, empty transaction. pub fn new(state: &mut State) -> Self { Self { changes: ChangeSet::new(&state.doc), selection: None, } } /// Returns true if applied successfully. pub fn apply(&self, state: &mut State) -> bool { if !self.changes.is_empty() { // TODO: also avoid mapping the selection if not necessary let old_doc = state.doc().clone(); // apply changes to the document if !self.changes.apply(&mut state.doc) { return false; } // Compose this transaction with the previous one let old_changes = state.changes.take(); state.changes = Some(old_changes.map_or_else( || self.changes.clone(), |changes| changes.compose(self.changes.clone()).unwrap(), )); if let Some(syntax) = &mut state.syntax { // TODO: no unwrap syntax.update(&old_doc, &state.doc, &self.changes).unwrap(); } } // update the selection: either take the selection specified in the transaction, or map the // current selection through changes. state.selection = self .selection .clone() .unwrap_or_else(|| state.selection.clone().map(&self.changes)); true } /// Generate a transaction that reverts this one. pub fn invert(&self, original: &State) -> Self { let changes = self.changes.invert(original.doc()); // Store the current cursor position let selection = original.selection.clone(); Self { changes, selection: Some(selection), } } pub fn with_selection(mut self, selection: Selection) -> Self { self.selection = Some(selection); self } /// Generate a transaction from a set of changes. pub fn change(state: &State, changes: I) -> Self where I: IntoIterator + ExactSizeIterator, { let len = state.doc.len_chars(); let mut acc = Vec::with_capacity(2 * changes.len() + 1); // TODO: verify ranges are ordered and not overlapping. let mut last = 0; for (from, to, tendril) in changes { // Retain from last "to" to current "from" acc.push(Operation::Retain(from - last)); let span = to - from; match tendril { Some(text) => { if span > 0 { acc.push(Operation::Delete(span)); } acc.push(Operation::Insert(text)); } None => acc.push(Operation::Delete(span)), } last = to; } acc.push(Operation::Retain(len - last)); Self::from(ChangeSet { changes: acc, len }) } /// Generate a transaction with a change per selection range. pub fn change_by_selection(state: &State, f: F) -> Self where F: FnMut(&Range) -> Change, { Self::change(state, state.selection.ranges().iter().map(f)) } /// Insert text at each selection head. pub fn insert(state: &State, text: Tendril) -> Self { Self::change_by_selection(state, |range| (range.head, range.head, Some(text.clone()))) } } impl From for Transaction { fn from(changes: ChangeSet) -> Self { Self { changes, selection: None, } } } #[cfg(test)] mod test { use super::*; #[test] fn composition() { use Operation::*; let a = ChangeSet { changes: vec![ Retain(5), Insert("!".into()), Retain(1), Delete(2), Insert("abc".into()), ], len: 8, }; let b = ChangeSet { changes: vec![Delete(5), Insert("world".into()), Retain(5)], len: 9, }; let mut text = Rope::from("hello xz"); // should probably return cloned text let composed = a.compose(b).unwrap(); assert_eq!(composed.len, 8); assert!(composed.apply(&mut text)); assert_eq!(text, "world! abc"); } #[test] fn invert() { use Operation::*; let changes = ChangeSet { changes: vec![Retain(4), Delete(5), Insert("test".into()), Retain(3)], len: 12, }; let doc = Rope::from("世界3 hello xz"); let revert = changes.invert(&doc); let mut doc2 = doc.clone(); changes.apply(&mut doc2); // a revert is different assert_ne!(changes, revert); assert_ne!(doc, doc2); // but inverting a revert will give us the original assert_eq!(changes, revert.invert(&doc2)); // applying a revert gives us back the original revert.apply(&mut doc2); assert_eq!(doc, doc2); } #[test] fn map_pos() { use Operation::*; // maps inserts let cs = ChangeSet { changes: vec![Retain(4), Insert("!!".into()), Retain(4)], len: 8, }; assert_eq!(cs.map_pos(0, Assoc::Before), 0); // before insert region assert_eq!(cs.map_pos(4, Assoc::Before), 4); // at insert, track before assert_eq!(cs.map_pos(4, Assoc::After), 6); // at insert, track after assert_eq!(cs.map_pos(5, Assoc::Before), 7); // after insert region // maps deletes let cs = ChangeSet { changes: vec![Retain(4), Delete(4), Retain(4)], len: 12, }; assert_eq!(cs.map_pos(0, Assoc::Before), 0); // at start assert_eq!(cs.map_pos(4, Assoc::Before), 4); // before a delete assert_eq!(cs.map_pos(5, Assoc::Before), 4); // inside a delete assert_eq!(cs.map_pos(5, Assoc::After), 4); // inside a delete // TODO: delete tracking // stays inbetween replacements let cs = ChangeSet { changes: vec![ Delete(2), Insert("ab".into()), Delete(2), Insert("cd".into()), ], len: 4, }; assert_eq!(cs.map_pos(2, Assoc::Before), 2); assert_eq!(cs.map_pos(2, Assoc::After), 2); } #[test] fn transaction_change() { let mut state = State::new("hello world!\ntest 123".into()); let transaction = Transaction::change( &state, vec![(6, 11, Some("void".into())), (12, 17, None)].into_iter(), ); transaction.apply(&mut state); assert_eq!(state.doc, Rope::from_str("hello void! 123")); } }