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macro_rules.rs
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macro_rules.rs
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use crate::base::{DummyResult, ExtCtxt, MacResult, TTMacroExpander};
use crate::base::{SyntaxExtension, SyntaxExtensionKind};
use crate::expand::{ensure_complete_parse, parse_ast_fragment, AstFragment, AstFragmentKind};
use crate::mbe;
use crate::mbe::macro_check;
use crate::mbe::macro_parser::parse_tt;
use crate::mbe::macro_parser::{Error, ErrorReported, Failure, Success};
use crate::mbe::macro_parser::{MatchedNonterminal, MatchedSeq};
use crate::mbe::transcribe::transcribe;
use rustc_ast as ast;
use rustc_ast::token::{self, NonterminalKind, NtTT, Token, TokenKind::*};
use rustc_ast::tokenstream::{DelimSpan, TokenStream};
use rustc_ast_pretty::pprust;
use rustc_attr::{self as attr, TransparencyError};
use rustc_data_structures::fx::FxHashMap;
use rustc_data_structures::sync::Lrc;
use rustc_errors::{Applicability, DiagnosticBuilder};
use rustc_feature::Features;
use rustc_parse::parser::Parser;
use rustc_session::parse::ParseSess;
use rustc_session::Session;
use rustc_span::edition::Edition;
use rustc_span::hygiene::Transparency;
use rustc_span::symbol::{kw, sym, Ident, MacroRulesNormalizedIdent};
use rustc_span::Span;
use std::borrow::Cow;
use std::collections::hash_map::Entry;
use std::{mem, slice};
use tracing::debug;
crate struct ParserAnyMacro<'a> {
parser: Parser<'a>,
/// Span of the expansion site of the macro this parser is for
site_span: Span,
/// The ident of the macro we're parsing
macro_ident: Ident,
arm_span: Span,
}
crate fn annotate_err_with_kind(
err: &mut DiagnosticBuilder<'_>,
kind: AstFragmentKind,
span: Span,
) {
match kind {
AstFragmentKind::Ty => {
err.span_label(span, "this macro call doesn't expand to a type");
}
AstFragmentKind::Pat => {
err.span_label(span, "this macro call doesn't expand to a pattern");
}
_ => {}
};
}
/// Instead of e.g. `vec![a, b, c]` in a pattern context, suggest `[a, b, c]`.
fn suggest_slice_pat(e: &mut DiagnosticBuilder<'_>, site_span: Span, parser: &Parser<'_>) {
let mut suggestion = None;
if let Ok(code) = parser.sess.source_map().span_to_snippet(site_span) {
if let Some(bang) = code.find('!') {
suggestion = Some(code[bang + 1..].to_string());
}
}
if let Some(suggestion) = suggestion {
e.span_suggestion(
site_span,
"use a slice pattern here instead",
suggestion,
Applicability::MachineApplicable,
);
} else {
e.span_label(site_span, "use a slice pattern here instead");
}
e.help(
"for more information, see https://doc.rust-lang.org/edition-guide/\
rust-2018/slice-patterns.html",
);
}
fn emit_frag_parse_err(
mut e: DiagnosticBuilder<'_>,
parser: &Parser<'_>,
orig_parser: &mut Parser<'_>,
site_span: Span,
macro_ident: Ident,
arm_span: Span,
kind: AstFragmentKind,
) {
if parser.token == token::Eof && e.message().ends_with(", found `<eof>`") {
if !e.span.is_dummy() {
// early end of macro arm (#52866)
e.replace_span_with(parser.sess.source_map().next_point(parser.token.span));
}
let msg = &e.message[0];
e.message[0] = (
format!(
"macro expansion ends with an incomplete expression: {}",
msg.0.replace(", found `<eof>`", ""),
),
msg.1,
);
}
if e.span.is_dummy() {
// Get around lack of span in error (#30128)
e.replace_span_with(site_span);
if !parser.sess.source_map().is_imported(arm_span) {
e.span_label(arm_span, "in this macro arm");
}
} else if parser.sess.source_map().is_imported(parser.token.span) {
e.span_label(site_span, "in this macro invocation");
}
match kind {
AstFragmentKind::Pat if macro_ident.name == sym::vec => {
suggest_slice_pat(&mut e, site_span, parser);
}
// Try a statement if an expression is wanted but failed and suggest adding `;` to call.
AstFragmentKind::Expr => match parse_ast_fragment(orig_parser, AstFragmentKind::Stmts) {
Err(mut err) => err.cancel(),
Ok(_) => {
e.note(
"the macro call doesn't expand to an expression, but it can expand to a statement",
);
e.span_suggestion_verbose(
site_span.shrink_to_hi(),
"add `;` to interpret the expansion as a statement",
";".to_string(),
Applicability::MaybeIncorrect,
);
}
},
_ => annotate_err_with_kind(&mut e, kind, site_span),
};
e.emit();
}
impl<'a> ParserAnyMacro<'a> {
crate fn make(mut self: Box<ParserAnyMacro<'a>>, kind: AstFragmentKind) -> AstFragment {
let ParserAnyMacro { site_span, macro_ident, ref mut parser, arm_span } = *self;
let snapshot = &mut parser.clone();
let fragment = match parse_ast_fragment(parser, kind) {
Ok(f) => f,
Err(err) => {
emit_frag_parse_err(err, parser, snapshot, site_span, macro_ident, arm_span, kind);
return kind.dummy(site_span);
}
};
// We allow semicolons at the end of expressions -- e.g., the semicolon in
// `macro_rules! m { () => { panic!(); } }` isn't parsed by `.parse_expr()`,
// but `m!()` is allowed in expression positions (cf. issue #34706).
if kind == AstFragmentKind::Expr && parser.token == token::Semi {
parser.bump();
}
// Make sure we don't have any tokens left to parse so we don't silently drop anything.
let path = ast::Path::from_ident(macro_ident.with_span_pos(site_span));
ensure_complete_parse(parser, &path, kind.name(), site_span);
fragment
}
}
struct MacroRulesMacroExpander {
name: Ident,
span: Span,
transparency: Transparency,
lhses: Vec<mbe::TokenTree>,
rhses: Vec<mbe::TokenTree>,
valid: bool,
}
impl TTMacroExpander for MacroRulesMacroExpander {
fn expand<'cx>(
&self,
cx: &'cx mut ExtCtxt<'_>,
sp: Span,
input: TokenStream,
) -> Box<dyn MacResult + 'cx> {
if !self.valid {
return DummyResult::any(sp);
}
generic_extension(
cx,
sp,
self.span,
self.name,
self.transparency,
input,
&self.lhses,
&self.rhses,
)
}
}
fn macro_rules_dummy_expander<'cx>(
_: &'cx mut ExtCtxt<'_>,
span: Span,
_: TokenStream,
) -> Box<dyn MacResult + 'cx> {
DummyResult::any(span)
}
fn trace_macros_note(cx_expansions: &mut FxHashMap<Span, Vec<String>>, sp: Span, message: String) {
let sp = sp.macro_backtrace().last().map(|trace| trace.call_site).unwrap_or(sp);
cx_expansions.entry(sp).or_default().push(message);
}
/// Given `lhses` and `rhses`, this is the new macro we create
fn generic_extension<'cx>(
cx: &'cx mut ExtCtxt<'_>,
sp: Span,
def_span: Span,
name: Ident,
transparency: Transparency,
arg: TokenStream,
lhses: &[mbe::TokenTree],
rhses: &[mbe::TokenTree],
) -> Box<dyn MacResult + 'cx> {
let sess = &cx.sess.parse_sess;
if cx.trace_macros() {
let msg = format!("expanding `{}! {{ {} }}`", name, pprust::tts_to_string(&arg));
trace_macros_note(&mut cx.expansions, sp, msg);
}
// Which arm's failure should we report? (the one furthest along)
let mut best_failure: Option<(Token, &str)> = None;
// We create a base parser that can be used for the "black box" parts.
// Every iteration needs a fresh copy of that parser. However, the parser
// is not mutated on many of the iterations, particularly when dealing with
// macros like this:
//
// macro_rules! foo {
// ("a") => (A);
// ("b") => (B);
// ("c") => (C);
// // ... etc. (maybe hundreds more)
// }
//
// as seen in the `html5ever` benchmark. We use a `Cow` so that the base
// parser is only cloned when necessary (upon mutation). Furthermore, we
// reinitialize the `Cow` with the base parser at the start of every
// iteration, so that any mutated parsers are not reused. This is all quite
// hacky, but speeds up the `html5ever` benchmark significantly. (Issue
// 68836 suggests a more comprehensive but more complex change to deal with
// this situation.)
let parser = parser_from_cx(sess, arg.clone());
for (i, lhs) in lhses.iter().enumerate() {
// try each arm's matchers
let lhs_tt = match *lhs {
mbe::TokenTree::Delimited(_, ref delim) => &delim.tts[..],
_ => cx.span_bug(sp, "malformed macro lhs"),
};
// Take a snapshot of the state of pre-expansion gating at this point.
// This is used so that if a matcher is not `Success(..)`ful,
// then the spans which became gated when parsing the unsuccessful matcher
// are not recorded. On the first `Success(..)`ful matcher, the spans are merged.
let mut gated_spans_snapshot = mem::take(&mut *sess.gated_spans.spans.borrow_mut());
match parse_tt(&mut Cow::Borrowed(&parser), lhs_tt) {
Success(named_matches) => {
// The matcher was `Success(..)`ful.
// Merge the gated spans from parsing the matcher with the pre-existing ones.
sess.gated_spans.merge(gated_spans_snapshot);
let rhs = match rhses[i] {
// ignore delimiters
mbe::TokenTree::Delimited(_, ref delimed) => delimed.tts.clone(),
_ => cx.span_bug(sp, "malformed macro rhs"),
};
let arm_span = rhses[i].span();
let rhs_spans = rhs.iter().map(|t| t.span()).collect::<Vec<_>>();
// rhs has holes ( `$id` and `$(...)` that need filled)
let mut tts = match transcribe(cx, &named_matches, rhs, transparency) {
Ok(tts) => tts,
Err(mut err) => {
err.emit();
return DummyResult::any(arm_span);
}
};
// Replace all the tokens for the corresponding positions in the macro, to maintain
// proper positions in error reporting, while maintaining the macro_backtrace.
if rhs_spans.len() == tts.len() {
tts = tts.map_enumerated(|i, tt| {
let mut tt = tt.clone();
let mut sp = rhs_spans[i];
sp = sp.with_ctxt(tt.span().ctxt());
tt.set_span(sp);
tt
});
}
if cx.trace_macros() {
let msg = format!("to `{}`", pprust::tts_to_string(&tts));
trace_macros_note(&mut cx.expansions, sp, msg);
}
let mut p = Parser::new(sess, tts, false, None);
p.last_type_ascription = cx.current_expansion.prior_type_ascription;
// Let the context choose how to interpret the result.
// Weird, but useful for X-macros.
return Box::new(ParserAnyMacro {
parser: p,
// Pass along the original expansion site and the name of the macro
// so we can print a useful error message if the parse of the expanded
// macro leaves unparsed tokens.
site_span: sp,
macro_ident: name,
arm_span,
});
}
Failure(token, msg) => match best_failure {
Some((ref best_token, _)) if best_token.span.lo() >= token.span.lo() => {}
_ => best_failure = Some((token, msg)),
},
Error(err_sp, ref msg) => {
let span = err_sp.substitute_dummy(sp);
cx.struct_span_err(span, &msg).emit();
return DummyResult::any(span);
}
ErrorReported => return DummyResult::any(sp),
}
// The matcher was not `Success(..)`ful.
// Restore to the state before snapshotting and maybe try again.
mem::swap(&mut gated_spans_snapshot, &mut sess.gated_spans.spans.borrow_mut());
}
drop(parser);
let (token, label) = best_failure.expect("ran no matchers");
let span = token.span.substitute_dummy(sp);
let mut err = cx.struct_span_err(span, &parse_failure_msg(&token));
err.span_label(span, label);
if !def_span.is_dummy() && !cx.source_map().is_imported(def_span) {
err.span_label(cx.source_map().guess_head_span(def_span), "when calling this macro");
}
// Check whether there's a missing comma in this macro call, like `println!("{}" a);`
if let Some((arg, comma_span)) = arg.add_comma() {
for lhs in lhses {
// try each arm's matchers
let lhs_tt = match *lhs {
mbe::TokenTree::Delimited(_, ref delim) => &delim.tts[..],
_ => continue,
};
if let Success(_) =
parse_tt(&mut Cow::Borrowed(&parser_from_cx(sess, arg.clone())), lhs_tt)
{
if comma_span.is_dummy() {
err.note("you might be missing a comma");
} else {
err.span_suggestion_short(
comma_span,
"missing comma here",
", ".to_string(),
Applicability::MachineApplicable,
);
}
}
}
}
err.emit();
cx.trace_macros_diag();
DummyResult::any(sp)
}
// Note that macro-by-example's input is also matched against a token tree:
// $( $lhs:tt => $rhs:tt );+
//
// Holy self-referential!
/// Converts a macro item into a syntax extension.
pub fn compile_declarative_macro(
sess: &Session,
features: &Features,
def: &ast::Item,
edition: Edition,
) -> SyntaxExtension {
debug!("compile_declarative_macro: {:?}", def);
let mk_syn_ext = |expander| {
SyntaxExtension::new(
sess,
SyntaxExtensionKind::LegacyBang(expander),
def.span,
Vec::new(),
edition,
def.ident.name,
&def.attrs,
)
};
let diag = &sess.parse_sess.span_diagnostic;
let lhs_nm = Ident::new(sym::lhs, def.span);
let rhs_nm = Ident::new(sym::rhs, def.span);
let tt_spec = NonterminalKind::TT;
// Parse the macro_rules! invocation
let (macro_rules, body) = match &def.kind {
ast::ItemKind::MacroDef(def) => (def.macro_rules, def.body.inner_tokens()),
_ => unreachable!(),
};
// The pattern that macro_rules matches.
// The grammar for macro_rules! is:
// $( $lhs:tt => $rhs:tt );+
// ...quasiquoting this would be nice.
// These spans won't matter, anyways
let argument_gram = vec![
mbe::TokenTree::Sequence(
DelimSpan::dummy(),
Lrc::new(mbe::SequenceRepetition {
tts: vec![
mbe::TokenTree::MetaVarDecl(def.span, lhs_nm, tt_spec),
mbe::TokenTree::token(token::FatArrow, def.span),
mbe::TokenTree::MetaVarDecl(def.span, rhs_nm, tt_spec),
],
separator: Some(Token::new(
if macro_rules { token::Semi } else { token::Comma },
def.span,
)),
kleene: mbe::KleeneToken::new(mbe::KleeneOp::OneOrMore, def.span),
num_captures: 2,
}),
),
// to phase into semicolon-termination instead of semicolon-separation
mbe::TokenTree::Sequence(
DelimSpan::dummy(),
Lrc::new(mbe::SequenceRepetition {
tts: vec![mbe::TokenTree::token(
if macro_rules { token::Semi } else { token::Comma },
def.span,
)],
separator: None,
kleene: mbe::KleeneToken::new(mbe::KleeneOp::ZeroOrMore, def.span),
num_captures: 0,
}),
),
];
let parser = Parser::new(&sess.parse_sess, body, true, rustc_parse::MACRO_ARGUMENTS);
let argument_map = match parse_tt(&mut Cow::Borrowed(&parser), &argument_gram) {
Success(m) => m,
Failure(token, msg) => {
let s = parse_failure_msg(&token);
let sp = token.span.substitute_dummy(def.span);
sess.parse_sess.span_diagnostic.struct_span_err(sp, &s).span_label(sp, msg).emit();
return mk_syn_ext(Box::new(macro_rules_dummy_expander));
}
Error(sp, msg) => {
sess.parse_sess
.span_diagnostic
.struct_span_err(sp.substitute_dummy(def.span), &msg)
.emit();
return mk_syn_ext(Box::new(macro_rules_dummy_expander));
}
ErrorReported => {
return mk_syn_ext(Box::new(macro_rules_dummy_expander));
}
};
let mut valid = true;
// Extract the arguments:
let lhses = match argument_map[&MacroRulesNormalizedIdent::new(lhs_nm)] {
MatchedSeq(ref s) => s
.iter()
.map(|m| {
if let MatchedNonterminal(ref nt) = *m {
if let NtTT(ref tt) = **nt {
let tt =
mbe::quoted::parse(tt.clone().into(), true, &sess.parse_sess, def.id)
.pop()
.unwrap();
valid &= check_lhs_nt_follows(&sess.parse_sess, features, &def.attrs, &tt);
return tt;
}
}
sess.parse_sess.span_diagnostic.span_bug(def.span, "wrong-structured lhs")
})
.collect::<Vec<mbe::TokenTree>>(),
_ => sess.parse_sess.span_diagnostic.span_bug(def.span, "wrong-structured lhs"),
};
let rhses = match argument_map[&MacroRulesNormalizedIdent::new(rhs_nm)] {
MatchedSeq(ref s) => s
.iter()
.map(|m| {
if let MatchedNonterminal(ref nt) = *m {
if let NtTT(ref tt) = **nt {
return mbe::quoted::parse(
tt.clone().into(),
false,
&sess.parse_sess,
def.id,
)
.pop()
.unwrap();
}
}
sess.parse_sess.span_diagnostic.span_bug(def.span, "wrong-structured lhs")
})
.collect::<Vec<mbe::TokenTree>>(),
_ => sess.parse_sess.span_diagnostic.span_bug(def.span, "wrong-structured rhs"),
};
for rhs in &rhses {
valid &= check_rhs(&sess.parse_sess, rhs);
}
// don't abort iteration early, so that errors for multiple lhses can be reported
for lhs in &lhses {
valid &= check_lhs_no_empty_seq(&sess.parse_sess, slice::from_ref(lhs));
}
valid &= macro_check::check_meta_variables(&sess.parse_sess, def.id, def.span, &lhses, &rhses);
let (transparency, transparency_error) = attr::find_transparency(sess, &def.attrs, macro_rules);
match transparency_error {
Some(TransparencyError::UnknownTransparency(value, span)) => {
diag.span_err(span, &format!("unknown macro transparency: `{}`", value))
}
Some(TransparencyError::MultipleTransparencyAttrs(old_span, new_span)) => {
diag.span_err(vec![old_span, new_span], "multiple macro transparency attributes")
}
None => {}
}
mk_syn_ext(Box::new(MacroRulesMacroExpander {
name: def.ident,
span: def.span,
transparency,
lhses,
rhses,
valid,
}))
}
fn check_lhs_nt_follows(
sess: &ParseSess,
features: &Features,
attrs: &[ast::Attribute],
lhs: &mbe::TokenTree,
) -> bool {
// lhs is going to be like TokenTree::Delimited(...), where the
// entire lhs is those tts. Or, it can be a "bare sequence", not wrapped in parens.
if let mbe::TokenTree::Delimited(_, ref tts) = *lhs {
check_matcher(sess, features, attrs, &tts.tts)
} else {
let msg = "invalid macro matcher; matchers must be contained in balanced delimiters";
sess.span_diagnostic.span_err(lhs.span(), msg);
false
}
// we don't abort on errors on rejection, the driver will do that for us
// after parsing/expansion. we can report every error in every macro this way.
}
/// Checks that the lhs contains no repetition which could match an empty token
/// tree, because then the matcher would hang indefinitely.
fn check_lhs_no_empty_seq(sess: &ParseSess, tts: &[mbe::TokenTree]) -> bool {
use mbe::TokenTree;
for tt in tts {
match *tt {
TokenTree::Token(..) | TokenTree::MetaVar(..) | TokenTree::MetaVarDecl(..) => (),
TokenTree::Delimited(_, ref del) => {
if !check_lhs_no_empty_seq(sess, &del.tts) {
return false;
}
}
TokenTree::Sequence(span, ref seq) => {
if seq.separator.is_none()
&& seq.tts.iter().all(|seq_tt| match *seq_tt {
TokenTree::MetaVarDecl(_, _, NonterminalKind::Vis) => true,
TokenTree::Sequence(_, ref sub_seq) => {
sub_seq.kleene.op == mbe::KleeneOp::ZeroOrMore
|| sub_seq.kleene.op == mbe::KleeneOp::ZeroOrOne
}
_ => false,
})
{
let sp = span.entire();
sess.span_diagnostic.span_err(sp, "repetition matches empty token tree");
return false;
}
if !check_lhs_no_empty_seq(sess, &seq.tts) {
return false;
}
}
}
}
true
}
fn check_rhs(sess: &ParseSess, rhs: &mbe::TokenTree) -> bool {
match *rhs {
mbe::TokenTree::Delimited(..) => return true,
_ => sess.span_diagnostic.span_err(rhs.span(), "macro rhs must be delimited"),
}
false
}
fn check_matcher(
sess: &ParseSess,
features: &Features,
attrs: &[ast::Attribute],
matcher: &[mbe::TokenTree],
) -> bool {
let first_sets = FirstSets::new(matcher);
let empty_suffix = TokenSet::empty();
let err = sess.span_diagnostic.err_count();
check_matcher_core(sess, features, attrs, &first_sets, matcher, &empty_suffix);
err == sess.span_diagnostic.err_count()
}
// `The FirstSets` for a matcher is a mapping from subsequences in the
// matcher to the FIRST set for that subsequence.
//
// This mapping is partially precomputed via a backwards scan over the
// token trees of the matcher, which provides a mapping from each
// repetition sequence to its *first* set.
//
// (Hypothetically, sequences should be uniquely identifiable via their
// spans, though perhaps that is false, e.g., for macro-generated macros
// that do not try to inject artificial span information. My plan is
// to try to catch such cases ahead of time and not include them in
// the precomputed mapping.)
struct FirstSets {
// this maps each TokenTree::Sequence `$(tt ...) SEP OP` that is uniquely identified by its
// span in the original matcher to the First set for the inner sequence `tt ...`.
//
// If two sequences have the same span in a matcher, then map that
// span to None (invalidating the mapping here and forcing the code to
// use a slow path).
first: FxHashMap<Span, Option<TokenSet>>,
}
impl FirstSets {
fn new(tts: &[mbe::TokenTree]) -> FirstSets {
use mbe::TokenTree;
let mut sets = FirstSets { first: FxHashMap::default() };
build_recur(&mut sets, tts);
return sets;
// walks backward over `tts`, returning the FIRST for `tts`
// and updating `sets` at the same time for all sequence
// substructure we find within `tts`.
fn build_recur(sets: &mut FirstSets, tts: &[TokenTree]) -> TokenSet {
let mut first = TokenSet::empty();
for tt in tts.iter().rev() {
match *tt {
TokenTree::Token(..) | TokenTree::MetaVar(..) | TokenTree::MetaVarDecl(..) => {
first.replace_with(tt.clone());
}
TokenTree::Delimited(span, ref delimited) => {
build_recur(sets, &delimited.tts[..]);
first.replace_with(delimited.open_tt(span));
}
TokenTree::Sequence(sp, ref seq_rep) => {
let subfirst = build_recur(sets, &seq_rep.tts[..]);
match sets.first.entry(sp.entire()) {
Entry::Vacant(vac) => {
vac.insert(Some(subfirst.clone()));
}
Entry::Occupied(mut occ) => {
// if there is already an entry, then a span must have collided.
// This should not happen with typical macro_rules macros,
// but syntax extensions need not maintain distinct spans,
// so distinct syntax trees can be assigned the same span.
// In such a case, the map cannot be trusted; so mark this
// entry as unusable.
occ.insert(None);
}
}
// If the sequence contents can be empty, then the first
// token could be the separator token itself.
if let (Some(sep), true) = (&seq_rep.separator, subfirst.maybe_empty) {
first.add_one_maybe(TokenTree::Token(sep.clone()));
}
// Reverse scan: Sequence comes before `first`.
if subfirst.maybe_empty
|| seq_rep.kleene.op == mbe::KleeneOp::ZeroOrMore
|| seq_rep.kleene.op == mbe::KleeneOp::ZeroOrOne
{
// If sequence is potentially empty, then
// union them (preserving first emptiness).
first.add_all(&TokenSet { maybe_empty: true, ..subfirst });
} else {
// Otherwise, sequence guaranteed
// non-empty; replace first.
first = subfirst;
}
}
}
}
first
}
}
// walks forward over `tts` until all potential FIRST tokens are
// identified.
fn first(&self, tts: &[mbe::TokenTree]) -> TokenSet {
use mbe::TokenTree;
let mut first = TokenSet::empty();
for tt in tts.iter() {
assert!(first.maybe_empty);
match *tt {
TokenTree::Token(..) | TokenTree::MetaVar(..) | TokenTree::MetaVarDecl(..) => {
first.add_one(tt.clone());
return first;
}
TokenTree::Delimited(span, ref delimited) => {
first.add_one(delimited.open_tt(span));
return first;
}
TokenTree::Sequence(sp, ref seq_rep) => {
let subfirst_owned;
let subfirst = match self.first.get(&sp.entire()) {
Some(&Some(ref subfirst)) => subfirst,
Some(&None) => {
subfirst_owned = self.first(&seq_rep.tts[..]);
&subfirst_owned
}
None => {
panic!("We missed a sequence during FirstSets construction");
}
};
// If the sequence contents can be empty, then the first
// token could be the separator token itself.
if let (Some(sep), true) = (&seq_rep.separator, subfirst.maybe_empty) {
first.add_one_maybe(TokenTree::Token(sep.clone()));
}
assert!(first.maybe_empty);
first.add_all(subfirst);
if subfirst.maybe_empty
|| seq_rep.kleene.op == mbe::KleeneOp::ZeroOrMore
|| seq_rep.kleene.op == mbe::KleeneOp::ZeroOrOne
{
// Continue scanning for more first
// tokens, but also make sure we
// restore empty-tracking state.
first.maybe_empty = true;
continue;
} else {
return first;
}
}
}
}
// we only exit the loop if `tts` was empty or if every
// element of `tts` matches the empty sequence.
assert!(first.maybe_empty);
first
}
}
// A set of `mbe::TokenTree`s, which may include `TokenTree::Match`s
// (for macro-by-example syntactic variables). It also carries the
// `maybe_empty` flag; that is true if and only if the matcher can
// match an empty token sequence.
//
// The First set is computed on submatchers like `$($a:expr b),* $(c)* d`,
// which has corresponding FIRST = {$a:expr, c, d}.
// Likewise, `$($a:expr b),* $(c)+ d` has FIRST = {$a:expr, c}.
//
// (Notably, we must allow for *-op to occur zero times.)
#[derive(Clone, Debug)]
struct TokenSet {
tokens: Vec<mbe::TokenTree>,
maybe_empty: bool,
}
impl TokenSet {
// Returns a set for the empty sequence.
fn empty() -> Self {
TokenSet { tokens: Vec::new(), maybe_empty: true }
}
// Returns the set `{ tok }` for the single-token (and thus
// non-empty) sequence [tok].
fn singleton(tok: mbe::TokenTree) -> Self {
TokenSet { tokens: vec![tok], maybe_empty: false }
}
// Changes self to be the set `{ tok }`.
// Since `tok` is always present, marks self as non-empty.
fn replace_with(&mut self, tok: mbe::TokenTree) {
self.tokens.clear();
self.tokens.push(tok);
self.maybe_empty = false;
}
// Changes self to be the empty set `{}`; meant for use when
// the particular token does not matter, but we want to
// record that it occurs.
fn replace_with_irrelevant(&mut self) {
self.tokens.clear();
self.maybe_empty = false;
}
// Adds `tok` to the set for `self`, marking sequence as non-empy.
fn add_one(&mut self, tok: mbe::TokenTree) {
if !self.tokens.contains(&tok) {
self.tokens.push(tok);
}
self.maybe_empty = false;
}
// Adds `tok` to the set for `self`. (Leaves `maybe_empty` flag alone.)
fn add_one_maybe(&mut self, tok: mbe::TokenTree) {
if !self.tokens.contains(&tok) {
self.tokens.push(tok);
}
}
// Adds all elements of `other` to this.
//
// (Since this is a set, we filter out duplicates.)
//
// If `other` is potentially empty, then preserves the previous
// setting of the empty flag of `self`. If `other` is guaranteed
// non-empty, then `self` is marked non-empty.
fn add_all(&mut self, other: &Self) {
for tok in &other.tokens {
if !self.tokens.contains(tok) {
self.tokens.push(tok.clone());
}
}
if !other.maybe_empty {
self.maybe_empty = false;
}
}
}
// Checks that `matcher` is internally consistent and that it
// can legally be followed by a token `N`, for all `N` in `follow`.
// (If `follow` is empty, then it imposes no constraint on
// the `matcher`.)
//
// Returns the set of NT tokens that could possibly come last in
// `matcher`. (If `matcher` matches the empty sequence, then
// `maybe_empty` will be set to true.)
//
// Requires that `first_sets` is pre-computed for `matcher`;
// see `FirstSets::new`.
fn check_matcher_core(
sess: &ParseSess,
features: &Features,
attrs: &[ast::Attribute],
first_sets: &FirstSets,
matcher: &[mbe::TokenTree],
follow: &TokenSet,
) -> TokenSet {
use mbe::TokenTree;
let mut last = TokenSet::empty();
// 2. For each token and suffix [T, SUFFIX] in M:
// ensure that T can be followed by SUFFIX, and if SUFFIX may be empty,
// then ensure T can also be followed by any element of FOLLOW.
'each_token: for i in 0..matcher.len() {
let token = &matcher[i];
let suffix = &matcher[i + 1..];
let build_suffix_first = || {
let mut s = first_sets.first(suffix);
if s.maybe_empty {
s.add_all(follow);
}
s
};
// (we build `suffix_first` on demand below; you can tell
// which cases are supposed to fall through by looking for the
// initialization of this variable.)
let suffix_first;
// First, update `last` so that it corresponds to the set
// of NT tokens that might end the sequence `... token`.
match *token {
TokenTree::Token(..) | TokenTree::MetaVar(..) | TokenTree::MetaVarDecl(..) => {
if token_can_be_followed_by_any(token) {
// don't need to track tokens that work with any,
last.replace_with_irrelevant();
// ... and don't need to check tokens that can be
// followed by anything against SUFFIX.
continue 'each_token;
} else {
last.replace_with(token.clone());
suffix_first = build_suffix_first();
}
}
TokenTree::Delimited(span, ref d) => {
let my_suffix = TokenSet::singleton(d.close_tt(span));
check_matcher_core(sess, features, attrs, first_sets, &d.tts, &my_suffix);
// don't track non NT tokens
last.replace_with_irrelevant();
// also, we don't need to check delimited sequences
// against SUFFIX
continue 'each_token;
}
TokenTree::Sequence(_, ref seq_rep) => {
suffix_first = build_suffix_first();
// The trick here: when we check the interior, we want
// to include the separator (if any) as a potential
// (but not guaranteed) element of FOLLOW. So in that
// case, we make a temp copy of suffix and stuff
// delimiter in there.
//
// FIXME: Should I first scan suffix_first to see if
// delimiter is already in it before I go through the
// work of cloning it? But then again, this way I may
// get a "tighter" span?
let mut new;
let my_suffix = if let Some(sep) = &seq_rep.separator {
new = suffix_first.clone();
new.add_one_maybe(TokenTree::Token(sep.clone()));
&new
} else {
&suffix_first
};
// At this point, `suffix_first` is built, and
// `my_suffix` is some TokenSet that we can use
// for checking the interior of `seq_rep`.
let next =
check_matcher_core(sess, features, attrs, first_sets, &seq_rep.tts, my_suffix);
if next.maybe_empty {
last.add_all(&next);
} else {
last = next;
}
// the recursive call to check_matcher_core already ran the 'each_last
// check below, so we can just keep going forward here.
continue 'each_token;
}
}
// (`suffix_first` guaranteed initialized once reaching here.)
// Now `last` holds the complete set of NT tokens that could
// end the sequence before SUFFIX. Check that every one works with `suffix`.
for token in &last.tokens {
if let TokenTree::MetaVarDecl(_, name, kind) = *token {
for next_token in &suffix_first.tokens {
match is_in_follow(next_token, kind) {
IsInFollow::Yes => {}
IsInFollow::No(possible) => {
let may_be = if last.tokens.len() == 1 && suffix_first.tokens.len() == 1
{
"is"
} else {
"may be"
};
let sp = next_token.span();
let mut err = sess.span_diagnostic.struct_span_err(
sp,
&format!(
"`${name}:{frag}` {may_be} followed by `{next}`, which \
is not allowed for `{frag}` fragments",
name = name,
frag = kind,
next = quoted_tt_to_string(next_token),
may_be = may_be
),
);
err.span_label(sp, format!("not allowed after `{}` fragments", kind));
let msg = "allowed there are: ";
match possible {
&[] => {}
&[t] => {
err.note(&format!(
"only {} is allowed after `{}` fragments",
t, kind,
));
}
ts => {
err.note(&format!(
"{}{} or {}",