//! Implements syntax highlighting. mod tags; mod html; #[cfg(test)] mod tests; use hir::{Name, Semantics}; use ra_ide_db::{ defs::{classify_name, classify_name_ref, Definition, NameClass, NameRefClass}, RootDatabase, }; use ra_prof::profile; use ra_syntax::{ ast::{self, HasFormatSpecifier, HasQuotes, HasStringValue}, AstNode, AstToken, Direction, NodeOrToken, SyntaxElement, SyntaxKind::*, SyntaxToken, TextRange, WalkEvent, T, }; use rustc_hash::FxHashMap; use crate::{call_info::ActiveParameter, Analysis, FileId}; use ast::FormatSpecifier; pub(crate) use html::highlight_as_html; pub use tags::{Highlight, HighlightModifier, HighlightModifiers, HighlightTag}; #[derive(Debug, Clone)] pub struct HighlightedRange { pub range: TextRange, pub highlight: Highlight, pub binding_hash: Option, } #[derive(Debug)] struct HighlightedRangeStack { stack: Vec>, } /// We use a stack to implement the flattening logic for the highlighted /// syntax ranges. impl HighlightedRangeStack { fn new() -> Self { Self { stack: vec![Vec::new()] } } fn push(&mut self) { self.stack.push(Vec::new()); } /// Flattens the highlighted ranges. /// /// For example `#[cfg(feature = "foo")]` contains the nested ranges: /// 1) parent-range: Attribute [0, 23) /// 2) child-range: String [16, 21) /// /// The following code implements the flattening, for our example this results to: /// `[Attribute [0, 16), String [16, 21), Attribute [21, 23)]` fn pop(&mut self) { let children = self.stack.pop().unwrap(); let prev = self.stack.last_mut().unwrap(); let needs_flattening = !children.is_empty() && !prev.is_empty() && prev.last().unwrap().range.contains_range(children.first().unwrap().range); if !needs_flattening { prev.extend(children); } else { let mut parent = prev.pop().unwrap(); for ele in children { assert!(parent.range.contains_range(ele.range)); let mut cloned = parent.clone(); parent.range = TextRange::new(parent.range.start(), ele.range.start()); cloned.range = TextRange::new(ele.range.end(), cloned.range.end()); if !parent.range.is_empty() { prev.push(parent); } prev.push(ele); parent = cloned; } if !parent.range.is_empty() { prev.push(parent); } } } fn add(&mut self, range: HighlightedRange) { self.stack .last_mut() .expect("during DFS traversal, the stack must not be empty") .push(range) } fn flattened(mut self) -> Vec { assert_eq!( self.stack.len(), 1, "after DFS traversal, the stack should only contain a single element" ); let mut res = self.stack.pop().unwrap(); res.sort_by_key(|range| range.range.start()); // Check that ranges are sorted and disjoint assert!(res .iter() .zip(res.iter().skip(1)) .all(|(left, right)| left.range.end() <= right.range.start())); res } } pub(crate) fn highlight( db: &RootDatabase, file_id: FileId, range_to_highlight: Option, ) -> Vec { let _p = profile("highlight"); let sema = Semantics::new(db); // Determine the root based on the given range. let (root, range_to_highlight) = { let source_file = sema.parse(file_id); match range_to_highlight { Some(range) => { let node = match source_file.syntax().covering_element(range) { NodeOrToken::Node(it) => it, NodeOrToken::Token(it) => it.parent(), }; (node, range) } None => (source_file.syntax().clone(), source_file.syntax().text_range()), } }; let mut bindings_shadow_count: FxHashMap = FxHashMap::default(); // We use a stack for the DFS traversal below. // When we leave a node, the we use it to flatten the highlighted ranges. let mut stack = HighlightedRangeStack::new(); let mut current_macro_call: Option = None; let mut format_string: Option = None; // Walk all nodes, keeping track of whether we are inside a macro or not. // If in macro, expand it first and highlight the expanded code. for event in root.preorder_with_tokens() { match &event { WalkEvent::Enter(_) => stack.push(), WalkEvent::Leave(_) => stack.pop(), }; let event_range = match &event { WalkEvent::Enter(it) => it.text_range(), WalkEvent::Leave(it) => it.text_range(), }; // Element outside of the viewport, no need to highlight if range_to_highlight.intersect(event_range).is_none() { continue; } // Track "inside macro" state match event.clone().map(|it| it.into_node().and_then(ast::MacroCall::cast)) { WalkEvent::Enter(Some(mc)) => { current_macro_call = Some(mc.clone()); if let Some(range) = macro_call_range(&mc) { stack.add(HighlightedRange { range, highlight: HighlightTag::Macro.into(), binding_hash: None, }); } continue; } WalkEvent::Leave(Some(mc)) => { assert!(current_macro_call == Some(mc)); current_macro_call = None; format_string = None; continue; } _ => (), } let element = match event { WalkEvent::Enter(it) => it, WalkEvent::Leave(_) => continue, }; let range = element.text_range(); let element_to_highlight = if current_macro_call.is_some() { // Inside a macro -- expand it first let token = match element.clone().into_token() { Some(it) if it.parent().kind() == TOKEN_TREE => it, _ => continue, }; let token = sema.descend_into_macros(token.clone()); let parent = token.parent(); // Check if macro takes a format string and remember it for highlighting later. // The macros that accept a format string expand to a compiler builtin macros // `format_args` and `format_args_nl`. if let Some(fmt_macro_call) = parent.parent().and_then(ast::MacroCall::cast) { if let Some(name) = fmt_macro_call.path().and_then(|p| p.segment()).and_then(|s| s.name_ref()) { match name.text().as_str() { "format_args" | "format_args_nl" => { format_string = parent .children_with_tokens() .filter(|t| t.kind() != WHITESPACE) .nth(1) .filter(|e| { ast::String::can_cast(e.kind()) || ast::RawString::can_cast(e.kind()) }) } _ => {} } } } // We only care Name and Name_ref match (token.kind(), parent.kind()) { (IDENT, NAME) | (IDENT, NAME_REF) => parent.into(), _ => token.into(), } } else { element.clone() }; if let Some(token) = element.as_token().cloned().and_then(ast::RawString::cast) { let expanded = element_to_highlight.as_token().unwrap().clone(); if highlight_injection(&mut stack, &sema, token, expanded).is_some() { continue; } } let is_format_string = format_string.as_ref() == Some(&element_to_highlight); if let Some((highlight, binding_hash)) = highlight_element(&sema, &mut bindings_shadow_count, element_to_highlight.clone()) { stack.add(HighlightedRange { range, highlight, binding_hash }); if let Some(string) = element_to_highlight.as_token().cloned().and_then(ast::String::cast) { stack.push(); if is_format_string { string.lex_format_specifier(|piece_range, kind| { if let Some(highlight) = highlight_format_specifier(kind) { stack.add(HighlightedRange { range: piece_range + range.start(), highlight: highlight.into(), binding_hash: None, }); } }); } stack.pop(); } else if let Some(string) = element_to_highlight.as_token().cloned().and_then(ast::RawString::cast) { stack.push(); if is_format_string { string.lex_format_specifier(|piece_range, kind| { if let Some(highlight) = highlight_format_specifier(kind) { stack.add(HighlightedRange { range: piece_range + range.start(), highlight: highlight.into(), binding_hash: None, }); } }); } stack.pop(); } } } stack.flattened() } fn highlight_format_specifier(kind: FormatSpecifier) -> Option { Some(match kind { FormatSpecifier::Open | FormatSpecifier::Close | FormatSpecifier::Colon | FormatSpecifier::Fill | FormatSpecifier::Align | FormatSpecifier::Sign | FormatSpecifier::NumberSign | FormatSpecifier::DollarSign | FormatSpecifier::Dot | FormatSpecifier::Asterisk | FormatSpecifier::QuestionMark => HighlightTag::FormatSpecifier, FormatSpecifier::Integer | FormatSpecifier::Zero => HighlightTag::NumericLiteral, FormatSpecifier::Identifier => HighlightTag::Local, }) } fn macro_call_range(macro_call: &ast::MacroCall) -> Option { let path = macro_call.path()?; let name_ref = path.segment()?.name_ref()?; let range_start = name_ref.syntax().text_range().start(); let mut range_end = name_ref.syntax().text_range().end(); for sibling in path.syntax().siblings_with_tokens(Direction::Next) { match sibling.kind() { T![!] | IDENT => range_end = sibling.text_range().end(), _ => (), } } Some(TextRange::new(range_start, range_end)) } fn highlight_element( sema: &Semantics, bindings_shadow_count: &mut FxHashMap, element: SyntaxElement, ) -> Option<(Highlight, Option)> { let db = sema.db; let mut binding_hash = None; let highlight: Highlight = match element.kind() { FN_DEF => { bindings_shadow_count.clear(); return None; } // Highlight definitions depending on the "type" of the definition. NAME => { let name = element.into_node().and_then(ast::Name::cast).unwrap(); let name_kind = classify_name(sema, &name); if let Some(NameClass::Definition(Definition::Local(local))) = &name_kind { if let Some(name) = local.name(db) { let shadow_count = bindings_shadow_count.entry(name.clone()).or_default(); *shadow_count += 1; binding_hash = Some(calc_binding_hash(&name, *shadow_count)) } }; match name_kind { Some(NameClass::Definition(def)) => { highlight_name(db, def) | HighlightModifier::Definition } Some(NameClass::ConstReference(def)) => highlight_name(db, def), None => highlight_name_by_syntax(name) | HighlightModifier::Definition, } } // Highlight references like the definitions they resolve to NAME_REF if element.ancestors().any(|it| it.kind() == ATTR) => return None, NAME_REF => { let name_ref = element.into_node().and_then(ast::NameRef::cast).unwrap(); match classify_name_ref(sema, &name_ref) { Some(name_kind) => match name_kind { NameRefClass::Definition(def) => { if let Definition::Local(local) = &def { if let Some(name) = local.name(db) { let shadow_count = bindings_shadow_count.entry(name.clone()).or_default(); binding_hash = Some(calc_binding_hash(&name, *shadow_count)) } }; highlight_name(db, def) } NameRefClass::FieldShorthand { .. } => HighlightTag::Field.into(), }, None => HighlightTag::UnresolvedReference.into(), } } // Simple token-based highlighting COMMENT => HighlightTag::Comment.into(), STRING | RAW_STRING | RAW_BYTE_STRING | BYTE_STRING => HighlightTag::StringLiteral.into(), ATTR => HighlightTag::Attribute.into(), INT_NUMBER | FLOAT_NUMBER => HighlightTag::NumericLiteral.into(), BYTE => HighlightTag::ByteLiteral.into(), CHAR => HighlightTag::CharLiteral.into(), LIFETIME => { let h = Highlight::new(HighlightTag::Lifetime); match element.parent().map(|it| it.kind()) { Some(LIFETIME_PARAM) | Some(LABEL) => h | HighlightModifier::Definition, _ => h, } } k if k.is_keyword() => { let h = Highlight::new(HighlightTag::Keyword); match k { T![break] | T![continue] | T![else] | T![for] | T![if] | T![loop] | T![match] | T![return] | T![while] => h | HighlightModifier::ControlFlow, T![unsafe] => h | HighlightModifier::Unsafe, _ => h, } } _ => return None, }; return Some((highlight, binding_hash)); fn calc_binding_hash(name: &Name, shadow_count: u32) -> u64 { fn hash(x: T) -> u64 { use std::{collections::hash_map::DefaultHasher, hash::Hasher}; let mut hasher = DefaultHasher::new(); x.hash(&mut hasher); hasher.finish() } hash((name, shadow_count)) } } fn highlight_name(db: &RootDatabase, def: Definition) -> Highlight { match def { Definition::Macro(_) => HighlightTag::Macro, Definition::Field(_) => HighlightTag::Field, Definition::ModuleDef(def) => match def { hir::ModuleDef::Module(_) => HighlightTag::Module, hir::ModuleDef::Function(_) => HighlightTag::Function, hir::ModuleDef::Adt(hir::Adt::Struct(_)) => HighlightTag::Struct, hir::ModuleDef::Adt(hir::Adt::Enum(_)) => HighlightTag::Enum, hir::ModuleDef::Adt(hir::Adt::Union(_)) => HighlightTag::Union, hir::ModuleDef::EnumVariant(_) => HighlightTag::EnumVariant, hir::ModuleDef::Const(_) => HighlightTag::Constant, hir::ModuleDef::Trait(_) => HighlightTag::Trait, hir::ModuleDef::TypeAlias(_) => HighlightTag::TypeAlias, hir::ModuleDef::BuiltinType(_) => HighlightTag::BuiltinType, hir::ModuleDef::Static(s) => { let mut h = Highlight::new(HighlightTag::Static); if s.is_mut(db) { h |= HighlightModifier::Mutable; } return h; } }, Definition::SelfType(_) => HighlightTag::SelfType, Definition::TypeParam(_) => HighlightTag::TypeParam, // FIXME: distinguish between locals and parameters Definition::Local(local) => { let mut h = Highlight::new(HighlightTag::Local); if local.is_mut(db) || local.ty(db).is_mutable_reference() { h |= HighlightModifier::Mutable; } return h; } } .into() } fn highlight_name_by_syntax(name: ast::Name) -> Highlight { let default = HighlightTag::Function.into(); let parent = match name.syntax().parent() { Some(it) => it, _ => return default, }; match parent.kind() { STRUCT_DEF => HighlightTag::Struct.into(), ENUM_DEF => HighlightTag::Enum.into(), UNION_DEF => HighlightTag::Union.into(), TRAIT_DEF => HighlightTag::Trait.into(), TYPE_ALIAS_DEF => HighlightTag::TypeAlias.into(), TYPE_PARAM => HighlightTag::TypeParam.into(), RECORD_FIELD_DEF => HighlightTag::Field.into(), _ => default, } } fn highlight_injection( acc: &mut HighlightedRangeStack, sema: &Semantics, literal: ast::RawString, expanded: SyntaxToken, ) -> Option<()> { let active_parameter = ActiveParameter::at_token(&sema, expanded)?; if !active_parameter.name.starts_with("ra_fixture") { return None; } let value = literal.value()?; let (analysis, tmp_file_id) = Analysis::from_single_file(value); if let Some(range) = literal.open_quote_text_range() { acc.add(HighlightedRange { range, highlight: HighlightTag::StringLiteral.into(), binding_hash: None, }) } for mut h in analysis.highlight(tmp_file_id).unwrap() { if let Some(r) = literal.map_range_up(h.range) { h.range = r; acc.add(h) } } if let Some(range) = literal.close_quote_text_range() { acc.add(HighlightedRange { range, highlight: HighlightTag::StringLiteral.into(), binding_hash: None, }) } Some(()) }