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macro_parser.rs
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macro_parser.rs
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//! This is an NFA-based parser, which calls out to the main Rust parser for named non-terminals
//! (which it commits to fully when it hits one in a grammar). There's a set of current NFA threads
//! and a set of next ones. Instead of NTs, we have a special case for Kleene star. The big-O, in
//! pathological cases, is worse than traditional use of NFA or Earley parsing, but it's an easier
//! fit for Macro-by-Example-style rules.
//!
//! (In order to prevent the pathological case, we'd need to lazily construct the resulting
//! `NamedMatch`es at the very end. It'd be a pain, and require more memory to keep around old
//! items, but it would also save overhead)
//!
//! We don't say this parser uses the Earley algorithm, because it's unnecessarily inaccurate.
//! The macro parser restricts itself to the features of finite state automata. Earley parsers
//! can be described as an extension of NFAs with completion rules, prediction rules, and recursion.
//!
//! Quick intro to how the parser works:
//!
//! A 'position' is a dot in the middle of a matcher, usually represented as a
//! dot. For example `· a $( a )* a b` is a position, as is `a $( · a )* a b`.
//!
//! The parser walks through the input a character at a time, maintaining a list
//! of threads consistent with the current position in the input string: `cur_items`.
//!
//! As it processes them, it fills up `eof_items` with threads that would be valid if
//! the macro invocation is now over, `bb_items` with threads that are waiting on
//! a Rust non-terminal like `$e:expr`, and `next_items` with threads that are waiting
//! on a particular token. Most of the logic concerns moving the · through the
//! repetitions indicated by Kleene stars. The rules for moving the · without
//! consuming any input are called epsilon transitions. It only advances or calls
//! out to the real Rust parser when no `cur_items` threads remain.
//!
//! Example:
//!
//! ```text, ignore
//! Start parsing a a a a b against [· a $( a )* a b].
//!
//! Remaining input: a a a a b
//! next: [· a $( a )* a b]
//!
//! - - - Advance over an a. - - -
//!
//! Remaining input: a a a b
//! cur: [a · $( a )* a b]
//! Descend/Skip (first item).
//! next: [a $( · a )* a b] [a $( a )* · a b].
//!
//! - - - Advance over an a. - - -
//!
//! Remaining input: a a b
//! cur: [a $( a · )* a b] [a $( a )* a · b]
//! Follow epsilon transition: Finish/Repeat (first item)
//! next: [a $( a )* · a b] [a $( · a )* a b] [a $( a )* a · b]
//!
//! - - - Advance over an a. - - - (this looks exactly like the last step)
//!
//! Remaining input: a b
//! cur: [a $( a · )* a b] [a $( a )* a · b]
//! Follow epsilon transition: Finish/Repeat (first item)
//! next: [a $( a )* · a b] [a $( · a )* a b] [a $( a )* a · b]
//!
//! - - - Advance over an a. - - - (this looks exactly like the last step)
//!
//! Remaining input: b
//! cur: [a $( a · )* a b] [a $( a )* a · b]
//! Follow epsilon transition: Finish/Repeat (first item)
//! next: [a $( a )* · a b] [a $( · a )* a b] [a $( a )* a · b]
//!
//! - - - Advance over a b. - - -
//!
//! Remaining input: ''
//! eof: [a $( a )* a b ·]
//! ```
crate use NamedMatch::*;
crate use ParseResult::*;
use TokenTreeOrTokenTreeSlice::*;
use crate::mbe::{self, TokenTree};
use rustc_ast::token::{self, DocComment, Nonterminal, Token};
use rustc_parse::parser::Parser;
use rustc_session::parse::ParseSess;
use rustc_span::symbol::MacroRulesNormalizedIdent;
use smallvec::{smallvec, SmallVec};
use rustc_data_structures::fx::FxHashMap;
use rustc_data_structures::sync::Lrc;
use rustc_span::symbol::Ident;
use std::borrow::Cow;
use std::collections::hash_map::Entry::{Occupied, Vacant};
use std::mem;
use std::ops::{Deref, DerefMut};
// To avoid costly uniqueness checks, we require that `MatchSeq` always has a nonempty body.
/// Either a sequence of token trees or a single one. This is used as the representation of the
/// sequence of tokens that make up a matcher.
#[derive(Clone)]
enum TokenTreeOrTokenTreeSlice<'tt> {
Tt(TokenTree),
TtSeq(&'tt [TokenTree]),
}
impl<'tt> TokenTreeOrTokenTreeSlice<'tt> {
/// Returns the number of constituent top-level token trees of `self` (top-level in that it
/// will not recursively descend into subtrees).
fn len(&self) -> usize {
match *self {
TtSeq(ref v) => v.len(),
Tt(ref tt) => tt.len(),
}
}
/// The `index`-th token tree of `self`.
fn get_tt(&self, index: usize) -> TokenTree {
match *self {
TtSeq(ref v) => v[index].clone(),
Tt(ref tt) => tt.get_tt(index),
}
}
}
/// An unzipping of `TokenTree`s... see the `stack` field of `MatcherPos`.
///
/// This is used by `inner_parse_loop` to keep track of delimited submatchers that we have
/// descended into.
#[derive(Clone)]
struct MatcherTtFrame<'tt> {
/// The "parent" matcher that we are descending into.
elts: TokenTreeOrTokenTreeSlice<'tt>,
/// The position of the "dot" in `elts` at the time we descended.
idx: usize,
}
type NamedMatchVec = SmallVec<[NamedMatch; 4]>;
/// Represents a single "position" (aka "matcher position", aka "item"), as
/// described in the module documentation.
///
/// Here:
///
/// - `'root` represents the lifetime of the stack slot that holds the root
/// `MatcherPos`. As described in `MatcherPosHandle`, the root `MatcherPos`
/// structure is stored on the stack, but subsequent instances are put into
/// the heap.
/// - `'tt` represents the lifetime of the token trees that this matcher
/// position refers to.
///
/// It is important to distinguish these two lifetimes because we have a
/// `SmallVec<TokenTreeOrTokenTreeSlice<'tt>>` below, and the destructor of
/// that is considered to possibly access the data from its elements (it lacks
/// a `#[may_dangle]` attribute). As a result, the compiler needs to know that
/// all the elements in that `SmallVec` strictly outlive the root stack slot
/// lifetime. By separating `'tt` from `'root`, we can show that.
#[derive(Clone)]
struct MatcherPos<'root, 'tt> {
/// The token or sequence of tokens that make up the matcher
top_elts: TokenTreeOrTokenTreeSlice<'tt>,
/// The position of the "dot" in this matcher
idx: usize,
/// For each named metavar in the matcher, we keep track of token trees matched against the
/// metavar by the black box parser. In particular, there may be more than one match per
/// metavar if we are in a repetition (each repetition matches each of the variables).
/// Moreover, matchers and repetitions can be nested; the `matches` field is shared (hence the
/// `Rc`) among all "nested" matchers. `match_lo`, `match_cur`, and `match_hi` keep track of
/// the current position of the `self` matcher position in the shared `matches` list.
///
/// Also, note that while we are descending into a sequence, matchers are given their own
/// `matches` vector. Only once we reach the end of a full repetition of the sequence do we add
/// all bound matches from the submatcher into the shared top-level `matches` vector. If `sep`
/// and `up` are `Some`, then `matches` is _not_ the shared top-level list. Instead, if one
/// wants the shared `matches`, one should use `up.matches`.
matches: Box<[Lrc<NamedMatchVec>]>,
/// The position in `matches` corresponding to the first metavar in this matcher's sequence of
/// token trees. In other words, the first metavar in the first token of `top_elts` corresponds
/// to `matches[match_lo]`.
match_lo: usize,
/// The position in `matches` corresponding to the metavar we are currently trying to match
/// against the source token stream. `match_lo <= match_cur <= match_hi`.
match_cur: usize,
/// Similar to `match_lo` except `match_hi` is the position in `matches` of the _last_ metavar
/// in this matcher.
match_hi: usize,
// The following fields are used if we are matching a repetition. If we aren't, they should be
// `None`.
/// The KleeneOp of this sequence if we are in a repetition.
seq_op: Option<mbe::KleeneOp>,
/// The separator if we are in a repetition.
sep: Option<Token>,
/// The "parent" matcher position if we are in a repetition. That is, the matcher position just
/// before we enter the sequence.
up: Option<MatcherPosHandle<'root, 'tt>>,
/// Specifically used to "unzip" token trees. By "unzip", we mean to unwrap the delimiters from
/// a delimited token tree (e.g., something wrapped in `(` `)`) or to get the contents of a doc
/// comment...
///
/// When matching against matchers with nested delimited submatchers (e.g., `pat ( pat ( .. )
/// pat ) pat`), we need to keep track of the matchers we are descending into. This stack does
/// that where the bottom of the stack is the outermost matcher.
/// Also, throughout the comments, this "descent" is often referred to as "unzipping"...
stack: SmallVec<[MatcherTtFrame<'tt>; 1]>,
}
impl<'root, 'tt> MatcherPos<'root, 'tt> {
/// Adds `m` as a named match for the `idx`-th metavar.
fn push_match(&mut self, idx: usize, m: NamedMatch) {
let matches = Lrc::make_mut(&mut self.matches[idx]);
matches.push(m);
}
}
// Lots of MatcherPos instances are created at runtime. Allocating them on the
// heap is slow. Furthermore, using SmallVec<MatcherPos> to allocate them all
// on the stack is also slow, because MatcherPos is quite a large type and
// instances get moved around a lot between vectors, which requires lots of
// slow memcpy calls.
//
// Therefore, the initial MatcherPos is always allocated on the stack,
// subsequent ones (of which there aren't that many) are allocated on the heap,
// and this type is used to encapsulate both cases.
enum MatcherPosHandle<'root, 'tt> {
Ref(&'root mut MatcherPos<'root, 'tt>),
Box(Box<MatcherPos<'root, 'tt>>),
}
impl<'root, 'tt> Clone for MatcherPosHandle<'root, 'tt> {
// This always produces a new Box.
fn clone(&self) -> Self {
MatcherPosHandle::Box(match *self {
MatcherPosHandle::Ref(ref r) => Box::new((**r).clone()),
MatcherPosHandle::Box(ref b) => b.clone(),
})
}
}
impl<'root, 'tt> Deref for MatcherPosHandle<'root, 'tt> {
type Target = MatcherPos<'root, 'tt>;
fn deref(&self) -> &Self::Target {
match *self {
MatcherPosHandle::Ref(ref r) => r,
MatcherPosHandle::Box(ref b) => b,
}
}
}
impl<'root, 'tt> DerefMut for MatcherPosHandle<'root, 'tt> {
fn deref_mut(&mut self) -> &mut MatcherPos<'root, 'tt> {
match *self {
MatcherPosHandle::Ref(ref mut r) => r,
MatcherPosHandle::Box(ref mut b) => b,
}
}
}
/// Represents the possible results of an attempted parse.
crate enum ParseResult<T> {
/// Parsed successfully.
Success(T),
/// Arm failed to match. If the second parameter is `token::Eof`, it indicates an unexpected
/// end of macro invocation. Otherwise, it indicates that no rules expected the given token.
Failure(Token, &'static str),
/// Fatal error (malformed macro?). Abort compilation.
Error(rustc_span::Span, String),
ErrorReported,
}
/// A `ParseResult` where the `Success` variant contains a mapping of
/// `MacroRulesNormalizedIdent`s to `NamedMatch`es. This represents the mapping
/// of metavars to the token trees they bind to.
crate type NamedParseResult = ParseResult<FxHashMap<MacroRulesNormalizedIdent, NamedMatch>>;
/// Count how many metavars are named in the given matcher `ms`.
pub(super) fn count_names(ms: &[TokenTree]) -> usize {
ms.iter().fold(0, |count, elt| {
count
+ match *elt {
TokenTree::Sequence(_, ref seq) => seq.num_captures,
TokenTree::Delimited(_, ref delim) => count_names(&delim.tts),
TokenTree::MetaVar(..) => 0,
TokenTree::MetaVarDecl(..) => 1,
TokenTree::Token(..) => 0,
}
})
}
/// `len` `Vec`s (initially shared and empty) that will store matches of metavars.
fn create_matches(len: usize) -> Box<[Lrc<NamedMatchVec>]> {
if len == 0 {
vec![]
} else {
let empty_matches = Lrc::new(SmallVec::new());
vec![empty_matches; len]
}
.into_boxed_slice()
}
/// Generates the top-level matcher position in which the "dot" is before the first token of the
/// matcher `ms`.
fn initial_matcher_pos<'root, 'tt>(ms: &'tt [TokenTree]) -> MatcherPos<'root, 'tt> {
let match_idx_hi = count_names(ms);
let matches = create_matches(match_idx_hi);
MatcherPos {
// Start with the top level matcher given to us
top_elts: TtSeq(ms), // "elts" is an abbr. for "elements"
// The "dot" is before the first token of the matcher
idx: 0,
// Initialize `matches` to a bunch of empty `Vec`s -- one for each metavar in `top_elts`.
// `match_lo` for `top_elts` is 0 and `match_hi` is `matches.len()`. `match_cur` is 0 since
// we haven't actually matched anything yet.
matches,
match_lo: 0,
match_cur: 0,
match_hi: match_idx_hi,
// Haven't descended into any delimiters, so empty stack
stack: smallvec![],
// Haven't descended into any sequences, so both of these are `None`.
seq_op: None,
sep: None,
up: None,
}
}
/// `NamedMatch` is a pattern-match result for a single `token::MATCH_NONTERMINAL`:
/// so it is associated with a single ident in a parse, and all
/// `MatchedNonterminal`s in the `NamedMatch` have the same non-terminal type
/// (expr, item, etc). Each leaf in a single `NamedMatch` corresponds to a
/// single `token::MATCH_NONTERMINAL` in the `TokenTree` that produced it.
///
/// The in-memory structure of a particular `NamedMatch` represents the match
/// that occurred when a particular subset of a matcher was applied to a
/// particular token tree.
///
/// The width of each `MatchedSeq` in the `NamedMatch`, and the identity of
/// the `MatchedNonterminal`s, will depend on the token tree it was applied
/// to: each `MatchedSeq` corresponds to a single `TTSeq` in the originating
/// token tree. The depth of the `NamedMatch` structure will therefore depend
/// only on the nesting depth of `ast::TTSeq`s in the originating
/// token tree it was derived from.
#[derive(Debug, Clone)]
crate enum NamedMatch {
MatchedSeq(Lrc<NamedMatchVec>),
MatchedNonterminal(Lrc<Nonterminal>),
}
/// Takes a sequence of token trees `ms` representing a matcher which successfully matched input
/// and an iterator of items that matched input and produces a `NamedParseResult`.
fn nameize<I: Iterator<Item = NamedMatch>>(
sess: &ParseSess,
ms: &[TokenTree],
mut res: I,
) -> NamedParseResult {
// Recursively descend into each type of matcher (e.g., sequences, delimited, metavars) and make
// sure that each metavar has _exactly one_ binding. If a metavar does not have exactly one
// binding, then there is an error. If it does, then we insert the binding into the
// `NamedParseResult`.
fn n_rec<I: Iterator<Item = NamedMatch>>(
sess: &ParseSess,
m: &TokenTree,
res: &mut I,
ret_val: &mut FxHashMap<MacroRulesNormalizedIdent, NamedMatch>,
) -> Result<(), (rustc_span::Span, String)> {
match *m {
TokenTree::Sequence(_, ref seq) => {
for next_m in &seq.tts {
n_rec(sess, next_m, res.by_ref(), ret_val)?
}
}
TokenTree::Delimited(_, ref delim) => {
for next_m in &delim.tts {
n_rec(sess, next_m, res.by_ref(), ret_val)?;
}
}
TokenTree::MetaVarDecl(span, _, None) => {
if sess.missing_fragment_specifiers.borrow_mut().remove(&span).is_some() {
return Err((span, "missing fragment specifier".to_string()));
}
}
TokenTree::MetaVarDecl(sp, bind_name, _) => match ret_val
.entry(MacroRulesNormalizedIdent::new(bind_name))
{
Vacant(spot) => {
spot.insert(res.next().unwrap());
}
Occupied(..) => return Err((sp, format!("duplicated bind name: {}", bind_name))),
},
TokenTree::MetaVar(..) | TokenTree::Token(..) => (),
}
Ok(())
}
let mut ret_val = FxHashMap::default();
for m in ms {
match n_rec(sess, m, res.by_ref(), &mut ret_val) {
Ok(_) => {}
Err((sp, msg)) => return Error(sp, msg),
}
}
Success(ret_val)
}
/// Performs a token equality check, ignoring syntax context (that is, an unhygienic comparison)
fn token_name_eq(t1: &Token, t2: &Token) -> bool {
if let (Some((ident1, is_raw1)), Some((ident2, is_raw2))) = (t1.ident(), t2.ident()) {
ident1.name == ident2.name && is_raw1 == is_raw2
} else if let (Some(ident1), Some(ident2)) = (t1.lifetime(), t2.lifetime()) {
ident1.name == ident2.name
} else {
t1.kind == t2.kind
}
}
/// Process the matcher positions of `cur_items` until it is empty. In the process, this will
/// produce more items in `next_items`, `eof_items`, and `bb_items`.
///
/// For more info about the how this happens, see the module-level doc comments and the inline
/// comments of this function.
///
/// # Parameters
///
/// - `cur_items`: the set of current items to be processed. This should be empty by the end of a
/// successful execution of this function.
/// - `next_items`: the set of newly generated items. These are used to replenish `cur_items` in
/// the function `parse`.
/// - `eof_items`: the set of items that would be valid if this was the EOF.
/// - `bb_items`: the set of items that are waiting for the black-box parser.
/// - `token`: the current token of the parser.
///
/// # Returns
///
/// A `ParseResult`. Note that matches are kept track of through the items generated.
fn inner_parse_loop<'root, 'tt>(
sess: &ParseSess,
cur_items: &mut SmallVec<[MatcherPosHandle<'root, 'tt>; 1]>,
next_items: &mut Vec<MatcherPosHandle<'root, 'tt>>,
eof_items: &mut SmallVec<[MatcherPosHandle<'root, 'tt>; 1]>,
bb_items: &mut SmallVec<[MatcherPosHandle<'root, 'tt>; 1]>,
token: &Token,
) -> ParseResult<()> {
// Pop items from `cur_items` until it is empty.
while let Some(mut item) = cur_items.pop() {
// When unzipped trees end, remove them. This corresponds to backtracking out of a
// delimited submatcher into which we already descended. In backtracking out again, we need
// to advance the "dot" past the delimiters in the outer matcher.
while item.idx >= item.top_elts.len() {
match item.stack.pop() {
Some(MatcherTtFrame { elts, idx }) => {
item.top_elts = elts;
item.idx = idx + 1;
}
None => break,
}
}
// Get the current position of the "dot" (`idx`) in `item` and the number of token trees in
// the matcher (`len`).
let idx = item.idx;
let len = item.top_elts.len();
// If `idx >= len`, then we are at or past the end of the matcher of `item`.
if idx >= len {
// We are repeating iff there is a parent. If the matcher is inside of a repetition,
// then we could be at the end of a sequence or at the beginning of the next
// repetition.
if item.up.is_some() {
// At this point, regardless of whether there is a separator, we should add all
// matches from the complete repetition of the sequence to the shared, top-level
// `matches` list (actually, `up.matches`, which could itself not be the top-level,
// but anyway...). Moreover, we add another item to `cur_items` in which the "dot"
// is at the end of the `up` matcher. This ensures that the "dot" in the `up`
// matcher is also advanced sufficiently.
//
// NOTE: removing the condition `idx == len` allows trailing separators.
if idx == len {
// Get the `up` matcher
let mut new_pos = item.up.clone().unwrap();
// Add matches from this repetition to the `matches` of `up`
for idx in item.match_lo..item.match_hi {
let sub = item.matches[idx].clone();
new_pos.push_match(idx, MatchedSeq(sub));
}
// Move the "dot" past the repetition in `up`
new_pos.match_cur = item.match_hi;
new_pos.idx += 1;
cur_items.push(new_pos);
}
// Check if we need a separator.
if idx == len && item.sep.is_some() {
// We have a separator, and it is the current token. We can advance past the
// separator token.
if item.sep.as_ref().map_or(false, |sep| token_name_eq(token, sep)) {
item.idx += 1;
next_items.push(item);
}
}
// We don't need a separator. Move the "dot" back to the beginning of the matcher
// and try to match again UNLESS we are only allowed to have _one_ repetition.
else if item.seq_op != Some(mbe::KleeneOp::ZeroOrOne) {
item.match_cur = item.match_lo;
item.idx = 0;
cur_items.push(item);
}
}
// If we are not in a repetition, then being at the end of a matcher means that we have
// reached the potential end of the input.
else {
eof_items.push(item);
}
}
// We are in the middle of a matcher.
else {
// Look at what token in the matcher we are trying to match the current token (`token`)
// against. Depending on that, we may generate new items.
match item.top_elts.get_tt(idx) {
// Need to descend into a sequence
TokenTree::Sequence(sp, seq) => {
// Examine the case where there are 0 matches of this sequence. We are
// implicitly disallowing OneOrMore from having 0 matches here. Thus, that will
// result in a "no rules expected token" error by virtue of this matcher not
// working.
if seq.kleene.op == mbe::KleeneOp::ZeroOrMore
|| seq.kleene.op == mbe::KleeneOp::ZeroOrOne
{
let mut new_item = item.clone();
new_item.match_cur += seq.num_captures;
new_item.idx += 1;
for idx in item.match_cur..item.match_cur + seq.num_captures {
new_item.push_match(idx, MatchedSeq(Lrc::new(smallvec![])));
}
cur_items.push(new_item);
}
let matches = create_matches(item.matches.len());
cur_items.push(MatcherPosHandle::Box(Box::new(MatcherPos {
stack: smallvec![],
sep: seq.separator.clone(),
seq_op: Some(seq.kleene.op),
idx: 0,
matches,
match_lo: item.match_cur,
match_cur: item.match_cur,
match_hi: item.match_cur + seq.num_captures,
up: Some(item),
top_elts: Tt(TokenTree::Sequence(sp, seq)),
})));
}
// We need to match a metavar (but the identifier is invalid)... this is an error
TokenTree::MetaVarDecl(span, _, None) => {
if sess.missing_fragment_specifiers.borrow_mut().remove(&span).is_some() {
return Error(span, "missing fragment specifier".to_string());
}
}
// We need to match a metavar with a valid ident... call out to the black-box
// parser by adding an item to `bb_items`.
TokenTree::MetaVarDecl(_, _, Some(kind)) => {
// Built-in nonterminals never start with these tokens, so we can eliminate
// them from consideration.
//
// We use the span of the metavariable declaration to determine any
// edition-specific matching behavior for non-terminals.
if Parser::nonterminal_may_begin_with(kind, token) {
bb_items.push(item);
}
}
// We need to descend into a delimited submatcher or a doc comment. To do this, we
// push the current matcher onto a stack and push a new item containing the
// submatcher onto `cur_items`.
//
// At the beginning of the loop, if we reach the end of the delimited submatcher,
// we pop the stack to backtrack out of the descent.
seq @ (TokenTree::Delimited(..)
| TokenTree::Token(Token { kind: DocComment(..), .. })) => {
let lower_elts = mem::replace(&mut item.top_elts, Tt(seq));
let idx = item.idx;
item.stack.push(MatcherTtFrame { elts: lower_elts, idx });
item.idx = 0;
cur_items.push(item);
}
// We just matched a normal token. We can just advance the parser.
TokenTree::Token(t) if token_name_eq(&t, token) => {
item.idx += 1;
next_items.push(item);
}
// There was another token that was not `token`... This means we can't add any
// rules. NOTE that this is not necessarily an error unless _all_ items in
// `cur_items` end up doing this. There may still be some other matchers that do
// end up working out.
TokenTree::Token(..) | TokenTree::MetaVar(..) => {}
}
}
}
// Yay a successful parse (so far)!
Success(())
}
/// Use the given sequence of token trees (`ms`) as a matcher. Match the token
/// stream from the given `parser` against it and return the match.
pub(super) fn parse_tt(
parser: &mut Cow<'_, Parser<'_>>,
ms: &[TokenTree],
macro_name: Ident,
) -> NamedParseResult {
// A queue of possible matcher positions. We initialize it with the matcher position in which
// the "dot" is before the first token of the first token tree in `ms`. `inner_parse_loop` then
// processes all of these possible matcher positions and produces possible next positions into
// `next_items`. After some post-processing, the contents of `next_items` replenish `cur_items`
// and we start over again.
//
// This MatcherPos instance is allocated on the stack. All others -- and
// there are frequently *no* others! -- are allocated on the heap.
let mut initial = initial_matcher_pos(ms);
let mut cur_items = smallvec![MatcherPosHandle::Ref(&mut initial)];
let mut next_items = Vec::new();
loop {
// Matcher positions black-box parsed by parser.rs (`parser`)
let mut bb_items = SmallVec::new();
// Matcher positions that would be valid if the macro invocation was over now
let mut eof_items = SmallVec::new();
assert!(next_items.is_empty());
// Process `cur_items` until either we have finished the input or we need to get some
// parsing from the black-box parser done. The result is that `next_items` will contain a
// bunch of possible next matcher positions in `next_items`.
match inner_parse_loop(
parser.sess,
&mut cur_items,
&mut next_items,
&mut eof_items,
&mut bb_items,
&parser.token,
) {
Success(_) => {}
Failure(token, msg) => return Failure(token, msg),
Error(sp, msg) => return Error(sp, msg),
ErrorReported => return ErrorReported,
}
// inner parse loop handled all cur_items, so it's empty
assert!(cur_items.is_empty());
// We need to do some post processing after the `inner_parser_loop`.
//
// Error messages here could be improved with links to original rules.
// If we reached the EOF, check that there is EXACTLY ONE possible matcher. Otherwise,
// either the parse is ambiguous (which should never happen) or there is a syntax error.
if parser.token == token::Eof {
if eof_items.len() == 1 {
let matches =
eof_items[0].matches.iter_mut().map(|dv| Lrc::make_mut(dv).pop().unwrap());
return nameize(parser.sess, ms, matches);
} else if eof_items.len() > 1 {
return Error(
parser.token.span,
"ambiguity: multiple successful parses".to_string(),
);
} else {
return Failure(
Token::new(
token::Eof,
if parser.token.span.is_dummy() {
parser.token.span
} else {
parser.token.span.shrink_to_hi()
},
),
"missing tokens in macro arguments",
);
}
}
// Performance hack: eof_items may share matchers via Rc with other things that we want
// to modify. Dropping eof_items now may drop these refcounts to 1, preventing an
// unnecessary implicit clone later in Rc::make_mut.
drop(eof_items);
// If there are no possible next positions AND we aren't waiting for the black-box parser,
// then there is a syntax error.
if bb_items.is_empty() && next_items.is_empty() {
return Failure(parser.token.clone(), "no rules expected this token in macro call");
}
// Another possibility is that we need to call out to parse some rust nonterminal
// (black-box) parser. However, if there is not EXACTLY ONE of these, something is wrong.
else if (!bb_items.is_empty() && !next_items.is_empty()) || bb_items.len() > 1 {
let nts = bb_items
.iter()
.map(|item| match item.top_elts.get_tt(item.idx) {
TokenTree::MetaVarDecl(_, bind, Some(kind)) => format!("{} ('{}')", kind, bind),
_ => panic!(),
})
.collect::<Vec<String>>()
.join(" or ");
return Error(
parser.token.span,
format!(
"local ambiguity when calling macro `{macro_name}`: multiple parsing options: {}",
match next_items.len() {
0 => format!("built-in NTs {}.", nts),
1 => format!("built-in NTs {} or 1 other option.", nts),
n => format!("built-in NTs {} or {} other options.", nts, n),
}
),
);
}
// Dump all possible `next_items` into `cur_items` for the next iteration.
else if !next_items.is_empty() {
// Now process the next token
cur_items.extend(next_items.drain(..));
parser.to_mut().bump();
}
// Finally, we have the case where we need to call the black-box parser to get some
// nonterminal.
else {
assert_eq!(bb_items.len(), 1);
let mut item = bb_items.pop().unwrap();
if let TokenTree::MetaVarDecl(span, _, Some(kind)) = item.top_elts.get_tt(item.idx) {
let match_cur = item.match_cur;
// We use the span of the metavariable declaration to determine any
// edition-specific matching behavior for non-terminals.
let nt = match parser.to_mut().parse_nonterminal(kind) {
Err(mut err) => {
err.span_label(
span,
format!("while parsing argument for this `{}` macro fragment", kind),
)
.emit();
return ErrorReported;
}
Ok(nt) => nt,
};
item.push_match(match_cur, MatchedNonterminal(Lrc::new(nt)));
item.idx += 1;
item.match_cur += 1;
} else {
unreachable!()
}
cur_items.push(item);
}
assert!(!cur_items.is_empty());
}
}