use std::borrow::Cow; use crate::{ graphics::Rect, gutter::{self, Gutter}, Document, DocumentId, ViewId, }; use helix_core::{ graphemes::{grapheme_width, RopeGraphemes}, line_ending::line_end_char_index, visual_coords_at_pos, Position, RopeSlice, Selection, }; type Jump = (DocumentId, Selection); #[derive(Debug, Clone)] pub struct JumpList { jumps: Vec, current: usize, } impl JumpList { pub fn new(initial: Jump) -> Self { Self { jumps: vec![initial], current: 0, } } pub fn push(&mut self, jump: Jump) { self.jumps.truncate(self.current); // don't push duplicates if self.jumps.last() != Some(&jump) { self.jumps.push(jump); self.current = self.jumps.len(); } } pub fn forward(&mut self, count: usize) -> Option<&Jump> { if self.current + count < self.jumps.len() { self.current += count; self.jumps.get(self.current) } else { None } } // Taking view and doc to prevent unnecessary cloning when jump is not required. pub fn backward(&mut self, view_id: ViewId, doc: &mut Document, count: usize) -> Option<&Jump> { if let Some(current) = self.current.checked_sub(count) { if self.current == self.jumps.len() { let jump = (doc.id(), doc.selection(view_id).clone()); self.push(jump); } self.current = current; self.jumps.get(self.current) } else { None } } pub fn remove(&mut self, doc_id: &DocumentId) { self.jumps.retain(|(other_id, _)| other_id != doc_id); } } const GUTTERS: &[(Gutter, usize)] = &[ (gutter::diagnostics_or_breakpoints, 1), (gutter::line_number, 5), ]; #[derive(Debug)] pub struct View { pub id: ViewId, pub doc: DocumentId, pub offset: Position, pub area: Rect, pub jumps: JumpList, /// the last accessed file before the current one pub last_accessed_doc: Option, } impl View { pub fn new(doc: DocumentId) -> Self { Self { id: ViewId::default(), doc, offset: Position::new(0, 0), area: Rect::default(), // will get calculated upon inserting into tree jumps: JumpList::new((doc, Selection::point(0))), // TODO: use actual sel last_accessed_doc: None, } } pub fn gutters(&self) -> &[(Gutter, usize)] { GUTTERS } pub fn inner_area(&self) -> Rect { // TODO: cache this let offset = self .gutters() .iter() .map(|(_, width)| *width as u16) .sum::() + 1; // +1 for some space between gutters and line self.area.clip_left(offset).clip_bottom(1) // -1 for statusline } // pub fn offset_coords_to_in_view( &self, doc: &Document, scrolloff: usize, ) -> Option<(usize, usize)> { let cursor = doc .selection(self.id) .primary() .cursor(doc.text().slice(..)); let Position { col, row: line } = visual_coords_at_pos(doc.text().slice(..), cursor, doc.tab_width()); let inner_area = self.inner_area(); let last_line = (self.offset.row + inner_area.height as usize).saturating_sub(1); // - 1 so we have at least one gap in the middle. // a height of 6 with padding of 3 on each side will keep shifting the view back and forth // as we type let scrolloff = scrolloff.min(inner_area.height.saturating_sub(1) as usize / 2); let last_col = self.offset.col + inner_area.width.saturating_sub(1) as usize; let row = if line > last_line.saturating_sub(scrolloff) { // scroll down self.offset.row + line - (last_line.saturating_sub(scrolloff)) } else if line < self.offset.row + scrolloff { // scroll up line.saturating_sub(scrolloff) } else { self.offset.row }; let col = if col > last_col.saturating_sub(scrolloff) { // scroll right self.offset.col + col - (last_col.saturating_sub(scrolloff)) } else if col < self.offset.col + scrolloff { // scroll left col.saturating_sub(scrolloff) } else { self.offset.col }; if row == self.offset.row && col == self.offset.col { None } else { Some((row, col)) } } pub fn ensure_cursor_in_view(&mut self, doc: &Document, scrolloff: usize) { if let Some((row, col)) = self.offset_coords_to_in_view(doc, scrolloff) { self.offset.row = row; self.offset.col = col; } } pub fn is_cursor_in_view(&mut self, doc: &Document, scrolloff: usize) -> bool { self.offset_coords_to_in_view(doc, scrolloff).is_none() } /// Calculates the last visible line on screen #[inline] pub fn last_line(&self, doc: &Document) -> usize { let height = self.inner_area().height; std::cmp::min( // Saturating subs to make it inclusive zero indexing. (self.offset.row + height as usize).saturating_sub(1), doc.text().len_lines().saturating_sub(1), ) } /// Translates a document position to an absolute position in the terminal. /// Returns a (line, col) position if the position is visible on screen. // TODO: Could return width as well for the character width at cursor. pub fn screen_coords_at_pos( &self, doc: &Document, text: RopeSlice, pos: usize, ) -> Option { let line = text.char_to_line(pos); if line < self.offset.row || line > self.last_line(doc) { // Line is not visible on screen return None; } let line_start = text.line_to_char(line); let line_slice = text.slice(line_start..pos); let mut col = 0; let tab_width = doc.tab_width(); for grapheme in RopeGraphemes::new(line_slice) { if grapheme == "\t" { col += tab_width; } else { let grapheme = Cow::from(grapheme); col += grapheme_width(&grapheme); } } // It is possible for underflow to occur if the buffer length is larger than the terminal width. let row = line.saturating_sub(self.offset.row); let col = col.saturating_sub(self.offset.col); Some(Position::new(row, col)) } pub fn text_pos_at_screen_coords( &self, text: &RopeSlice, row: u16, column: u16, tab_width: usize, ) -> Option { let inner = self.inner_area(); // 1 for status if row < inner.top() || row >= inner.bottom() { return None; } if column < inner.left() || column > inner.right() { return None; } let line_number = (row - inner.y) as usize + self.offset.row; if line_number > text.len_lines() - 1 { return Some(text.len_chars()); } let mut pos = text.line_to_char(line_number); let current_line = text.line(line_number); let target = (column - inner.x) as usize + self.offset.col; let mut selected = 0; for grapheme in RopeGraphemes::new(current_line) { if selected >= target { break; } if grapheme == "\t" { selected += tab_width; } else { let width = grapheme_width(&Cow::from(grapheme)); selected += width; } pos += grapheme.chars().count(); } Some(pos.min(line_end_char_index(&text.slice(..), line_number))) } /// Translates a screen position to position in the text document. /// Returns a usize typed position in bounds of the text if found in this view, None if out of view. pub fn pos_at_screen_coords(&self, doc: &Document, row: u16, column: u16) -> Option { self.text_pos_at_screen_coords(&doc.text().slice(..), row, column, doc.tab_width()) } /// Translates screen coordinates into coordinates on the gutter of the view. /// Returns a tuple of usize typed line and column numbers starting with 0. /// Returns None if coordinates are not on the gutter. pub fn gutter_coords_at_screen_coords(&self, row: u16, column: u16) -> Option { // 1 for status if row < self.area.top() || row >= self.area.bottom() { return None; } if column < self.area.left() || column > self.area.right() { return None; } Some(Position::new( (row - self.area.top()) as usize, (column - self.area.left()) as usize, )) } // pub fn traverse(&self, text: RopeSlice, start: usize, end: usize, fun: F) // where // F: Fn(usize, usize), // { // let start = self.screen_coords_at_pos(text, start); // let end = self.screen_coords_at_pos(text, end); // match (start, end) { // // fully on screen // (Some(start), Some(end)) => { // // we want to calculate ends of lines for each char.. // } // // from start to end of screen // (Some(start), None) => {} // // from start of screen to end // (None, Some(end)) => {} // // not on screen // (None, None) => return, // } // } } #[cfg(test)] mod tests { use super::*; use helix_core::Rope; const OFFSET: u16 = 7; // 1 diagnostic + 5 linenr + 1 gutter // const OFFSET: u16 = GUTTERS.iter().map(|(_, width)| *width as u16).sum(); #[test] fn test_text_pos_at_screen_coords() { let mut view = View::new(DocumentId::default()); view.area = Rect::new(40, 40, 40, 40); let rope = Rope::from_str("abc\n\tdef"); let text = rope.slice(..); assert_eq!(view.text_pos_at_screen_coords(&text, 40, 2, 4), None); assert_eq!(view.text_pos_at_screen_coords(&text, 40, 41, 4), None); assert_eq!(view.text_pos_at_screen_coords(&text, 0, 2, 4), None); assert_eq!(view.text_pos_at_screen_coords(&text, 0, 49, 4), None); assert_eq!(view.text_pos_at_screen_coords(&text, 0, 41, 4), None); assert_eq!(view.text_pos_at_screen_coords(&text, 40, 81, 4), None); assert_eq!(view.text_pos_at_screen_coords(&text, 78, 41, 4), None); assert_eq!( view.text_pos_at_screen_coords(&text, 40, 40 + OFFSET + 3, 4), Some(3) ); assert_eq!(view.text_pos_at_screen_coords(&text, 40, 80, 4), Some(3)); assert_eq!( view.text_pos_at_screen_coords(&text, 41, 40 + OFFSET + 1, 4), Some(5) ); assert_eq!( view.text_pos_at_screen_coords(&text, 41, 40 + OFFSET + 4, 4), Some(5) ); assert_eq!( view.text_pos_at_screen_coords(&text, 41, 40 + OFFSET + 7, 4), Some(8) ); assert_eq!(view.text_pos_at_screen_coords(&text, 41, 80, 4), Some(8)); } #[test] fn test_text_pos_at_screen_coords_cjk() { let mut view = View::new(DocumentId::default()); view.area = Rect::new(40, 40, 40, 40); let rope = Rope::from_str("Hi! こんにちは皆さん"); let text = rope.slice(..); assert_eq!( view.text_pos_at_screen_coords(&text, 40, 40 + OFFSET + 0, 4), Some(0) ); assert_eq!( view.text_pos_at_screen_coords(&text, 40, 40 + OFFSET + 5, 4), Some(5) ); assert_eq!( view.text_pos_at_screen_coords(&text, 40, 40 + OFFSET + 6, 4), Some(5) ); assert_eq!( view.text_pos_at_screen_coords(&text, 40, 40 + OFFSET + 7, 4), Some(6) ); assert_eq!( view.text_pos_at_screen_coords(&text, 40, 40 + OFFSET + 8, 4), Some(6) ); } #[test] fn test_text_pos_at_screen_coords_graphemes() { let mut view = View::new(DocumentId::default()); view.area = Rect::new(40, 40, 40, 40); let rope = Rope::from_str("Hèl̀l̀ò world!"); let text = rope.slice(..); assert_eq!( view.text_pos_at_screen_coords(&text, 40, 40 + OFFSET + 0, 4), Some(0) ); assert_eq!( view.text_pos_at_screen_coords(&text, 40, 40 + OFFSET + 1, 4), Some(1) ); assert_eq!( view.text_pos_at_screen_coords(&text, 40, 40 + OFFSET + 2, 4), Some(3) ); assert_eq!( view.text_pos_at_screen_coords(&text, 40, 40 + OFFSET + 3, 4), Some(5) ); assert_eq!( view.text_pos_at_screen_coords(&text, 40, 40 + OFFSET + 4, 4), Some(7) ); } }