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|
//! This module provides a way to construct a `File`.
//! It is intended to be completely decoupled from the
//! parser, so as to allow to evolve the tree representation
//! and the parser algorithm independently.
//!
//! The `Sink` trait is the bridge between the parser and the
//! tree builder: the parser produces a stream of events like
//! `start node`, `finish node`, and `FileBuilder` converts
//! this stream to a real tree.
use std::mem;
use crate::{
TextUnit, TextRange, SmolStr,
lexer::Token,
parser_impl::Sink,
SyntaxKind::{self, *},
};
/// `Parser` produces a flat list of `Event`s.
/// They are converted to a tree-structure in
/// a separate pass, via `TreeBuilder`.
#[derive(Debug)]
pub(crate) enum Event {
/// This event signifies the start of the node.
/// It should be either abandoned (in which case the
/// `kind` is `TOMBSTONE`, and the event is ignored),
/// or completed via a `Finish` event.
///
/// All tokens between a `Start` and a `Finish` would
/// become the children of the respective node.
///
/// For left-recursive syntactic constructs, the parser produces
/// a child node before it sees a parent. `forward_parent`
/// exists to allow to tweak parent-child relationships.
///
/// Consider this path
///
/// foo::bar
///
/// The events for it would look like this:
///
///
/// START(PATH) IDENT('foo') FINISH START(PATH) COLONCOLON IDENT('bar') FINISH
/// | /\
/// | |
/// +------forward-parent------+
///
/// And the tree would look like this
///
/// +--PATH---------+
/// | | |
/// | | |
/// | '::' 'bar'
/// |
/// PATH
/// |
/// 'foo'
///
/// See also `CompletedMarker::precede`.
Start {
kind: SyntaxKind,
forward_parent: Option<u32>,
},
/// Complete the previous `Start` event
Finish,
/// Produce a single leaf-element.
/// `n_raw_tokens` is used to glue complex contextual tokens.
/// For example, lexer tokenizes `>>` as `>`, `>`, and
/// `n_raw_tokens = 2` is used to produced a single `>>`.
Token {
kind: SyntaxKind,
n_raw_tokens: u8,
},
Error {
msg: String,
},
}
pub(super) struct EventProcessor<'a, S: Sink> {
sink: S,
text_pos: TextUnit,
text: &'a str,
token_pos: usize,
tokens: &'a [Token],
events: &'a mut [Event],
}
impl<'a, S: Sink> EventProcessor<'a, S> {
pub(super) fn new(sink: S, text: &'a str, tokens: &'a[Token], events: &'a mut [Event]) -> EventProcessor<'a, S> {
EventProcessor {
sink,
text_pos: 0.into(),
text,
token_pos: 0,
tokens,
events
}
}
pub(super) fn process(mut self) -> S {
fn tombstone() -> Event {
Event::Start { kind: TOMBSTONE, forward_parent: None }
}
let mut forward_parents = Vec::new();
for i in 0..self.events.len() {
match mem::replace(&mut self.events[i], tombstone()) {
Event::Start {
kind: TOMBSTONE, ..
} => (),
Event::Start { kind, forward_parent } => {
forward_parents.push(kind);
let mut idx = i;
let mut fp = forward_parent;
while let Some(fwd) = fp {
idx += fwd as usize;
fp = match mem::replace(&mut self.events[idx], tombstone()) {
Event::Start {
kind,
forward_parent,
} => {
forward_parents.push(kind);
forward_parent
},
_ => unreachable!(),
};
}
for kind in forward_parents.drain(..).rev() {
self.start(kind);
}
}
Event::Finish => {
let last = i == self.events.len() - 1;
self.finish(last);
},
Event::Token { kind, n_raw_tokens } => {
self.eat_ws();
let n_raw_tokens = n_raw_tokens as usize;
let len = self.tokens[self.token_pos..self.token_pos + n_raw_tokens]
.iter()
.map(|it| it.len)
.sum::<TextUnit>();
self.leaf(kind, len, n_raw_tokens);
}
Event::Error { msg } => self.sink.error(msg, self.text_pos),
}
}
self.sink
}
fn start(&mut self, kind: SyntaxKind) {
if kind == ROOT {
self.sink.start_internal(kind);
return;
}
let n_trivias = self.tokens[self.token_pos..]
.iter()
.take_while(|it| it.kind.is_trivia())
.count();
let leading_trivias = &self.tokens[self.token_pos..self.token_pos + n_trivias];
let mut trivia_end = self.text_pos + leading_trivias
.iter()
.map(|it| it.len)
.sum::<TextUnit>();
let n_attached_trivias = {
let leading_trivias = leading_trivias.iter().rev()
.map(|it| {
let next_end = trivia_end - it.len;
let range = TextRange::from_to(next_end, trivia_end);
trivia_end = next_end;
(it.kind, &self.text[range])
});
n_attached_trivias(kind, leading_trivias)
};
self.eat_n_trivias(n_trivias - n_attached_trivias);
self.sink.start_internal(kind);
self.eat_n_trivias(n_attached_trivias);
}
fn finish(&mut self, last: bool) {
if last {
self.eat_ws()
}
self.sink.finish_internal();
}
fn eat_ws(&mut self) {
while let Some(&token) = self.tokens.get(self.token_pos) {
if !token.kind.is_trivia() {
break;
}
self.leaf(token.kind, token.len, 1);
}
}
fn eat_n_trivias(&mut self, n: usize) {
for _ in 0..n {
let token = self.tokens[self.token_pos];
assert!(token.kind.is_trivia());
self.leaf(token.kind, token.len, 1);
}
}
fn leaf(&mut self, kind: SyntaxKind, len: TextUnit, n_tokens: usize) {
let range = TextRange::offset_len(self.text_pos, len);
let text: SmolStr = self.text[range].into();
self.text_pos += len;
self.token_pos += n_tokens;
self.sink.leaf(kind, text);
}
}
fn n_attached_trivias<'a>(kind: SyntaxKind, trivias: impl Iterator<Item=(SyntaxKind, &'a str)>) -> usize {
match kind {
STRUCT_DEF | ENUM_DEF | FN_DEF | TRAIT_DEF | MODULE => {
let mut res = 0;
for (i, (kind, text)) in trivias.enumerate() {
match kind {
WHITESPACE => {
if text.contains("\n\n") {
break;
}
}
COMMENT => {
res = i + 1;
}
_ => (),
}
}
res
}
_ => 0,
}
}
|
