//! The Rust parser. //! //! The parser doesn't know about concrete representation of tokens and syntax //! trees. Abstract `TokenSource` and `TreeSink` traits are used instead. As a //! consequence, this crates does not contain a lexer. //! //! The `Parser` struct from the `parser` module is a cursor into the sequence //! of tokens. Parsing routines use `Parser` to inspect current state and //! advance the parsing. //! //! The actual parsing happens in the `grammar` module. //! //! Tests for this crate live in `ra_syntax` crate. #[macro_use] mod token_set; mod syntax_kind; mod event; mod parser; mod grammar; pub(crate) use token_set::TokenSet; pub use syntax_kind::SyntaxKind; #[derive(Debug, Clone, PartialEq, Eq, Hash)] pub struct ParseError(pub String); /// `TokenSource` abstracts the source of the tokens parser operates one. /// /// Hopefully this will allow us to treat text and token trees in the same way! pub trait TokenSource { /// What is the current token? fn token_kind(&self, pos: usize) -> SyntaxKind; /// Is the current token joined to the next one (`> >` vs `>>`). fn is_token_joint_to_next(&self, pos: usize) -> bool; /// Is the current token a specified keyword? fn is_keyword(&self, pos: usize, kw: &str) -> bool; } /// `TreeSink` abstracts details of a particular syntax tree implementation. pub trait TreeSink { /// Adds new token to the current branch. fn token(&mut self, kind: SyntaxKind, n_tokens: u8); /// Start new branch and make it current. fn start_node(&mut self, kind: SyntaxKind); /// Finish current branch and restore previous /// branch as current. fn finish_node(&mut self); fn error(&mut self, error: ParseError); } fn parse_from_tokens(token_source: &dyn TokenSource, tree_sink: &mut dyn TreeSink, f: F) where F: FnOnce(&mut parser::Parser), { let mut p = parser::Parser::new(token_source); f(&mut p); let events = p.finish(); event::process(tree_sink, events); } /// Parse given tokens into the given sink as a rust file. pub fn parse(token_source: &dyn TokenSource, tree_sink: &mut dyn TreeSink) { parse_from_tokens(token_source, tree_sink, grammar::root); } /// Parse given tokens into the given sink as a path pub fn parse_path(token_source: &dyn TokenSource, tree_sink: &mut dyn TreeSink) { parse_from_tokens(token_source, tree_sink, grammar::path); } /// Parse given tokens into the given sink as a expression pub fn parse_expr(token_source: &dyn TokenSource, tree_sink: &mut dyn TreeSink) { parse_from_tokens(token_source, tree_sink, grammar::expr); } /// Parse given tokens into the given sink as a ty pub fn parse_ty(token_source: &dyn TokenSource, tree_sink: &mut dyn TreeSink) { parse_from_tokens(token_source, tree_sink, grammar::type_); } /// Parse given tokens into the given sink as a pattern pub fn parse_pat(token_source: &dyn TokenSource, tree_sink: &mut dyn TreeSink) { parse_from_tokens(token_source, tree_sink, grammar::pattern); } /// Parse given tokens into the given sink as a statement pub fn parse_stmt(token_source: &dyn TokenSource, tree_sink: &mut dyn TreeSink, with_semi: bool) { parse_from_tokens(token_source, tree_sink, |p| grammar::stmt(p, with_semi)); } /// Parse given tokens into the given sink as an item pub fn parse_item(token_source: &dyn TokenSource, tree_sink: &mut dyn TreeSink) { parse_from_tokens(token_source, tree_sink, grammar::item); } /// A parsing function for a specific braced-block. pub struct Reparser(fn(&mut parser::Parser)); impl Reparser { /// If the node is a braced block, return the corresponding `Reparser`. pub fn for_node( node: SyntaxKind, first_child: Option, parent: Option, ) -> Option { grammar::reparser(node, first_child, parent).map(Reparser) } /// Re-parse given tokens using this `Reparser`. /// /// Tokens must start with `{`, end with `}` and form a valid brace /// sequence. pub fn parse(self, token_source: &dyn TokenSource, tree_sink: &mut dyn TreeSink) { let Reparser(r) = self; let mut p = parser::Parser::new(token_source); r(&mut p); let events = p.finish(); event::process(tree_sink, events); } }