// Copyright 2015 The Rust Project Developers. See the COPYRIGHT // file at the top-level directory of this distribution and at // http://rust-lang.org/COPYRIGHT. // // Licensed under the Apache License, Version 2.0 or the MIT license // , at your // option. This file may not be copied, modified, or distributed // except according to those terms. use ast::{self, TokenTree}; use codemap::{Span, DUMMY_SP}; use ext::base::{DummyResult, ExtCtxt, MacResult, SyntaxExtension}; use ext::base::{NormalTT, TTMacroExpander}; use ext::tt::macro_parser::{Success, Error, Failure}; use ext::tt::macro_parser::{MatchedSeq, MatchedNonterminal}; use ext::tt::macro_parser::parse; use parse::lexer::new_tt_reader; use parse::parser::{Parser, Restrictions}; use parse::token::{self, gensym_ident, NtTT, Token}; use parse::token::Token::*; use print; use ptr::P; use util::small_vector::SmallVector; use std::cell::RefCell; use std::collections::{HashMap}; use std::collections::hash_map::{Entry}; use std::rc::Rc; struct ParserAnyMacro<'a> { parser: RefCell>, /// 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: ast::Ident } impl<'a> ParserAnyMacro<'a> { /// Make sure we don't have any tokens left to parse, so we don't /// silently drop anything. `allow_semi` is so that "optional" /// semicolons at the end of normal expressions aren't complained /// about e.g. the semicolon in `macro_rules! kapow { () => { /// panic!(); } }` doesn't get picked up by .parse_expr(), but it's /// allowed to be there. fn ensure_complete_parse(&self, allow_semi: bool, context: &str) { let mut parser = self.parser.borrow_mut(); if allow_semi && parser.token == token::Semi { parser.bump(); } if parser.token != token::Eof { let token_str = parser.this_token_to_string(); let msg = format!("macro expansion ignores token `{}` and any \ following", token_str); let span = parser.span; let mut err = parser.diagnostic().struct_span_err(span, &msg[..]); let msg = format!("caused by the macro expansion here; the usage \ of `{}!` is likely invalid in {} context", self.macro_ident, context); err.span_note(self.site_span, &msg[..]) .emit(); } } } impl<'a> MacResult for ParserAnyMacro<'a> { fn make_expr(self: Box>) -> Option> { let ret = panictry!(self.parser.borrow_mut().parse_expr()); self.ensure_complete_parse(true, "expression"); Some(ret) } fn make_pat(self: Box>) -> Option> { let ret = panictry!(self.parser.borrow_mut().parse_pat()); self.ensure_complete_parse(false, "pattern"); Some(ret) } fn make_items(self: Box>) -> Option>> { let mut ret = SmallVector::zero(); while let Some(item) = panictry!(self.parser.borrow_mut().parse_item()) { ret.push(item); } self.ensure_complete_parse(false, "item"); Some(ret) } fn make_impl_items(self: Box>) -> Option> { let mut ret = SmallVector::zero(); loop { let mut parser = self.parser.borrow_mut(); match parser.token { token::Eof => break, _ => ret.push(panictry!(parser.parse_impl_item())) } } self.ensure_complete_parse(false, "item"); Some(ret) } fn make_stmts(self: Box>) -> Option> { let mut ret = SmallVector::zero(); loop { let mut parser = self.parser.borrow_mut(); match parser.token { token::Eof => break, _ => match parser.parse_stmt() { Ok(maybe_stmt) => match maybe_stmt { Some(stmt) => ret.push(stmt), None => (), }, Err(mut e) => { e.emit(); break; } } } } self.ensure_complete_parse(false, "statement"); Some(ret) } fn make_ty(self: Box>) -> Option> { let ret = panictry!(self.parser.borrow_mut().parse_ty()); self.ensure_complete_parse(false, "type"); Some(ret) } } struct MacroRulesMacroExpander { name: ast::Ident, imported_from: Option, lhses: Vec, rhses: Vec, valid: bool, } impl TTMacroExpander for MacroRulesMacroExpander { fn expand<'cx>(&self, cx: &'cx mut ExtCtxt, sp: Span, arg: &[TokenTree]) -> Box { if !self.valid { return DummyResult::any(sp); } generic_extension(cx, sp, self.name, self.imported_from, arg, &self.lhses, &self.rhses) } } /// Given `lhses` and `rhses`, this is the new macro we create fn generic_extension<'cx>(cx: &'cx ExtCtxt, sp: Span, name: ast::Ident, imported_from: Option, arg: &[TokenTree], lhses: &[TokenTree], rhses: &[TokenTree]) -> Box { if cx.trace_macros() { println!("{}! {{ {} }}", name, print::pprust::tts_to_string(arg)); } // Which arm's failure should we report? (the one furthest along) let mut best_fail_spot = DUMMY_SP; let mut best_fail_msg = "internal error: ran no matchers".to_string(); for (i, lhs) in lhses.iter().enumerate() { // try each arm's matchers let lhs_tt = match *lhs { TokenTree::Delimited(_, ref delim) => &delim.tts[..], _ => cx.span_bug(sp, "malformed macro lhs") }; match TokenTree::parse(cx, lhs_tt, arg) { Success(named_matches) => { let rhs = match rhses[i] { // ignore delimiters TokenTree::Delimited(_, ref delimed) => delimed.tts.clone(), _ => cx.span_bug(sp, "malformed macro rhs"), }; // rhs has holes ( `$id` and `$(...)` that need filled) let trncbr = new_tt_reader(&cx.parse_sess().span_diagnostic, Some(named_matches), imported_from, rhs); let mut p = Parser::new(cx.parse_sess(), cx.cfg(), Box::new(trncbr)); p.filename = cx.filename.clone(); p.mod_path_stack = cx.mod_path_stack.clone(); p.restrictions = match cx.in_block { true => Restrictions::NO_NONINLINE_MOD, false => Restrictions::empty(), }; p.check_unknown_macro_variable(); // Let the context choose how to interpret the result. // Weird, but useful for X-macros. return Box::new(ParserAnyMacro { parser: RefCell::new(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 }) } Failure(sp, ref msg) => if sp.lo >= best_fail_spot.lo { best_fail_spot = sp; best_fail_msg = (*msg).clone(); }, Error(err_sp, ref msg) => { cx.span_fatal(err_sp.substitute_dummy(sp), &msg[..]) } } } cx.span_fatal(best_fail_spot.substitute_dummy(sp), &best_fail_msg[..]); } // Note that macro-by-example's input is also matched against a token tree: // $( $lhs:tt => $rhs:tt );+ // // Holy self-referential! /// Converts a `macro_rules!` invocation into a syntax extension. pub fn compile<'cx>(cx: &'cx mut ExtCtxt, def: &ast::MacroDef) -> SyntaxExtension { let lhs_nm = gensym_ident("lhs"); let rhs_nm = gensym_ident("rhs"); // 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 match_lhs_tok = MatchNt(lhs_nm, token::str_to_ident("tt")); let match_rhs_tok = MatchNt(rhs_nm, token::str_to_ident("tt")); let argument_gram = vec!( TokenTree::Sequence(DUMMY_SP, Rc::new(ast::SequenceRepetition { tts: vec![ TokenTree::Token(DUMMY_SP, match_lhs_tok), TokenTree::Token(DUMMY_SP, token::FatArrow), TokenTree::Token(DUMMY_SP, match_rhs_tok)], separator: Some(token::Semi), op: ast::KleeneOp::OneOrMore, num_captures: 2 })), //to phase into semicolon-termination instead of //semicolon-separation TokenTree::Sequence(DUMMY_SP, Rc::new(ast::SequenceRepetition { tts: vec![TokenTree::Token(DUMMY_SP, token::Semi)], separator: None, op: ast::KleeneOp::ZeroOrMore, num_captures: 0 }))); // Parse the macro_rules! invocation (`none` is for no interpolations): let arg_reader = new_tt_reader(&cx.parse_sess().span_diagnostic, None, None, def.body.clone()); let argument_map = match parse(cx.parse_sess(), cx.cfg(), arg_reader, &argument_gram) { Success(m) => m, Failure(sp, str) | Error(sp, str) => { panic!(cx.parse_sess().span_diagnostic .span_fatal(sp.substitute_dummy(def.span), &str[..])); } }; let mut valid = true; // Extract the arguments: let lhses = match **argument_map.get(&lhs_nm.name).unwrap() { MatchedSeq(ref s, _) => { s.iter().map(|m| match **m { MatchedNonterminal(NtTT(ref tt)) => { valid &= check_lhs_nt_follows(cx, tt); (**tt).clone() } _ => cx.span_bug(def.span, "wrong-structured lhs") }).collect() } _ => cx.span_bug(def.span, "wrong-structured lhs") }; let rhses = match **argument_map.get(&rhs_nm.name).unwrap() { MatchedSeq(ref s, _) => { s.iter().map(|m| match **m { MatchedNonterminal(NtTT(ref tt)) => (**tt).clone(), _ => cx.span_bug(def.span, "wrong-structured rhs") }).collect() } _ => cx.span_bug(def.span, "wrong-structured rhs") }; for rhs in &rhses { valid &= check_rhs(cx, rhs); } let exp: Box<_> = Box::new(MacroRulesMacroExpander { name: def.ident, imported_from: def.imported_from, lhses: lhses, rhses: rhses, valid: valid, }); NormalTT(exp, Some(def.span), def.allow_internal_unstable) } fn check_lhs_nt_follows(cx: &mut ExtCtxt, lhs: &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. match lhs { &TokenTree::Delimited(_, ref tts) => check_matcher(cx, &tts.tts), _ => { cx.span_err(lhs.get_span(), "invalid macro matcher; matchers must \ be contained in balanced delimiters"); 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. } fn check_rhs(cx: &mut ExtCtxt, rhs: &TokenTree) -> bool { match *rhs { TokenTree::Delimited(..) => return true, _ => cx.span_err(rhs.get_span(), "macro rhs must be delimited") } false } fn check_matcher(cx: &mut ExtCtxt, matcher: &[TokenTree]) -> bool { let first_sets = FirstSets::new(matcher); let empty_suffix = TokenSet::empty(); let err = cx.parse_sess.span_diagnostic.err_count(); check_matcher_core(cx, &first_sets, matcher, &empty_suffix); err == cx.parse_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: HashMap>, } impl FirstSets { fn new(tts: &[TokenTree]) -> FirstSets { let mut sets = FirstSets { first: HashMap::new() }; 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(sp, ref tok) => { first.replace_with((sp, tok.clone())); } TokenTree::Delimited(_, ref delimited) => { build_recur(sets, &delimited.tts[..]); first.replace_with((delimited.open_span, Token::OpenDelim(delimited.delim))); } TokenTree::Sequence(sp, ref seq_rep) => { let subfirst = build_recur(sets, &seq_rep.tts[..]); match sets.first.entry(sp) { 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(ref sep), true) = (seq_rep.separator.clone(), subfirst.maybe_empty) { first.add_one_maybe((sp, sep.clone())); } // Reverse scan: Sequence comes before `first`. if subfirst.maybe_empty || seq_rep.op == ast::KleeneOp::ZeroOrMore { // 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; } } } } return first; } } // walks forward over `tts` until all potential FIRST tokens are // identified. fn first(&self, tts: &[TokenTree]) -> TokenSet { let mut first = TokenSet::empty(); for tt in tts.iter() { assert!(first.maybe_empty); match *tt { TokenTree::Token(sp, ref tok) => { first.add_one((sp, tok.clone())); return first; } TokenTree::Delimited(_, ref delimited) => { first.add_one((delimited.open_span, Token::OpenDelim(delimited.delim))); return first; } TokenTree::Sequence(sp, ref seq_rep) => { match self.first.get(&sp) { Some(&Some(ref subfirst)) => { // If the sequence contents can be empty, then the first // token could be the separator token itself. if let (Some(ref sep), true) = (seq_rep.separator.clone(), subfirst.maybe_empty) { first.add_one_maybe((sp, sep.clone())); } assert!(first.maybe_empty); first.add_all(subfirst); if subfirst.maybe_empty || seq_rep.op == ast::KleeneOp::ZeroOrMore { // continue scanning for more first // tokens, but also make sure we // restore empty-tracking state first.maybe_empty = true; continue; } else { return first; } } Some(&None) => { panic!("assume all sequences have (unique) spans for now"); } None => { panic!("We missed a sequence during FirstSets construction"); } } } } } // we only exit the loop if `tts` was empty or if every // element of `tts` matches the empty sequence. assert!(first.maybe_empty); return first; } } // A set of Tokens, which may include MatchNt tokens (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<(Span, Token)>, 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: (Span, Token)) -> 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: (Span, Token)) { 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: (Span, Token)) { 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: (Span, Token)) { 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 by 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(cx: &mut ExtCtxt, first_sets: &FirstSets, matcher: &[TokenTree], follow: &TokenSet) -> TokenSet { use print::pprust::token_to_string; 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); } return 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(sp, ref tok) => { let can_be_followed_by_any; if let Err(bad_frag) = has_legal_fragment_specifier(tok) { cx.struct_span_err(sp, &format!("invalid fragment specifier `{}`", bad_frag)) .help("valid fragment specifiers are `ident`, `block`, \ `stmt`, `expr`, `pat`, `ty`, `path`, `meta`, `tt` \ and `item`") .emit(); // (This eliminates false positives and duplicates // from error messages.) can_be_followed_by_any = true; } else { can_be_followed_by_any = token_can_be_followed_by_any(tok); } if can_be_followed_by_any { // 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((sp, tok.clone())); suffix_first = build_suffix_first(); } } TokenTree::Delimited(_, ref d) => { let my_suffix = TokenSet::singleton((d.close_span, Token::CloseDelim(d.delim))); check_matcher_core(cx, 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(sp, 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(ref u) = seq_rep.separator { new = suffix_first.clone(); new.add_one_maybe((sp, u.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(cx, 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`. 'each_last: for &(_sp, ref t) in &last.tokens { if let MatchNt(ref name, ref frag_spec) = *t { for &(sp, ref next_token) in &suffix_first.tokens { match is_in_follow(cx, next_token, &frag_spec.name.as_str()) { Err((msg, help)) => { cx.struct_span_err(sp, &msg).help(help).emit(); // don't bother reporting every source of // conflict for a particular element of `last`. continue 'each_last; } Ok(true) => {} Ok(false) => { let may_be = if last.tokens.len() == 1 && suffix_first.tokens.len() == 1 { "is" } else { "may be" }; cx.span_err( sp, &format!("`${name}:{frag}` {may_be} followed by `{next}`, which \ is not allowed for `{frag}` fragments", name=name, frag=frag_spec, next=token_to_string(next_token), may_be=may_be) ); } } } } } } last } fn token_can_be_followed_by_any(tok: &Token) -> bool { if let &MatchNt(_, ref frag_spec) = tok { frag_can_be_followed_by_any(&frag_spec.name.as_str()) } else { // (Non NT's can always be followed by anthing in matchers.) true } } /// True if a fragment of type `frag` can be followed by any sort of /// token. We use this (among other things) as a useful approximation /// for when `frag` can be followed by a repetition like `$(...)*` or /// `$(...)+`. In general, these can be a bit tricky to reason about, /// so we adopt a conservative position that says that any fragment /// specifier which consumes at most one token tree can be followed by /// a fragment specifier (indeed, these fragments can be followed by /// ANYTHING without fear of future compatibility hazards). fn frag_can_be_followed_by_any(frag: &str) -> bool { match frag { "item" | // always terminated by `}` or `;` "block" | // exactly one token tree "ident" | // exactly one token tree "meta" | // exactly one token tree "tt" => // exactly one token tree true, _ => false, } } /// True if `frag` can legally be followed by the token `tok`. For /// fragments that can consume an unbounded number of tokens, `tok` /// must be within a well-defined follow set. This is intended to /// guarantee future compatibility: for example, without this rule, if /// we expanded `expr` to include a new binary operator, we might /// break macros that were relying on that binary operator as a /// separator. // when changing this do not forget to update doc/book/macros.md! fn is_in_follow(_: &ExtCtxt, tok: &Token, frag: &str) -> Result { if let &CloseDelim(_) = tok { // closing a token tree can never be matched by any fragment; // iow, we always require that `(` and `)` match, etc. Ok(true) } else { match frag { "item" => { // since items *must* be followed by either a `;` or a `}`, we can // accept anything after them Ok(true) }, "block" => { // anything can follow block, the braces provide an easy boundary to // maintain Ok(true) }, "stmt" | "expr" => { match *tok { FatArrow | Comma | Semi => Ok(true), _ => Ok(false) } }, "pat" => { match *tok { FatArrow | Comma | Eq | BinOp(token::Or) => Ok(true), Ident(i) if (i.name.as_str() == "if" || i.name.as_str() == "in") => Ok(true), _ => Ok(false) } }, "path" | "ty" => { match *tok { OpenDelim(token::DelimToken::Brace) | OpenDelim(token::DelimToken::Bracket) | Comma | FatArrow | Colon | Eq | Gt | Semi | BinOp(token::Or) => Ok(true), MatchNt(_, ref frag) if frag.name.as_str() == "block" => Ok(true), Ident(i) if i.name.as_str() == "as" || i.name.as_str() == "where" => Ok(true), _ => Ok(false) } }, "ident" => { // being a single token, idents are harmless Ok(true) }, "meta" | "tt" => { // being either a single token or a delimited sequence, tt is // harmless Ok(true) }, _ => Err((format!("invalid fragment specifier `{}`", frag), "valid fragment specifiers are `ident`, `block`, \ `stmt`, `expr`, `pat`, `ty`, `path`, `meta`, `tt` \ and `item`")) } } } fn has_legal_fragment_specifier(tok: &Token) -> Result<(), String> { debug!("has_legal_fragment_specifier({:?})", tok); if let &MatchNt(_, ref frag_spec) = tok { let s = &frag_spec.name.as_str(); if !is_legal_fragment_specifier(s) { return Err(s.to_string()); } } Ok(()) } fn is_legal_fragment_specifier(frag: &str) -> bool { match frag { "item" | "block" | "stmt" | "expr" | "pat" | "path" | "ty" | "ident" | "meta" | "tt" => true, _ => false, } }