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android / toolchain / rustc / 859223d571ac76195f46ef610ad1f7fe42a915c1 / . / vendor / rustc-ap-syntax / parse / parser.rs
blob: 4a457f5a43caa651dd34e0bab0ccf7ffc8dc4b38 [file] [log] [blame]
mod expr;
mod pat;
mod item;
pub use item::AliasKind;
mod module;
pub use module::{ModulePath, ModulePathSuccess};
mod ty;
mod path;
pub use path::PathStyle;
mod stmt;
mod generics;
use crate::ast::{
self, DUMMY_NODE_ID, AttrStyle, Attribute, BindingMode, CrateSugar, Ident,
IsAsync, MacDelimiter, Mutability, Param, StrStyle, SelfKind, TyKind, Visibility,
VisibilityKind, Unsafety,
};
use crate::parse::{ParseSess, PResult, Directory, DirectoryOwnership, SeqSep, literal, token};
use crate::parse::diagnostics::{Error, dummy_arg};
use crate::parse::lexer::UnmatchedBrace;
use crate::parse::lexer::comments::{doc_comment_style, strip_doc_comment_decoration};
use crate::parse::token::{Token, TokenKind, DelimToken};
use crate::print::pprust;
use crate::ptr::P;
use crate::source_map::{self, respan};
use crate::symbol::{kw, sym, Symbol};
use crate::tokenstream::{self, DelimSpan, TokenTree, TokenStream, TreeAndJoint};
use crate::ThinVec;
use errors::{Applicability, DiagnosticId, FatalError};
use rustc_target::spec::abi::{self, Abi};
use syntax_pos::{Span, BytePos, DUMMY_SP, FileName};
use log::debug;
use std::borrow::Cow;
use std::{cmp, mem, slice};
use std::path::PathBuf;
bitflags::bitflags! {
struct Restrictions: u8 {
const STMT_EXPR = 1 << 0;
const NO_STRUCT_LITERAL = 1 << 1;
}
}
#[derive(Clone, Copy, PartialEq, Debug)]
crate enum SemiColonMode {
Break,
Ignore,
Comma,
}
#[derive(Clone, Copy, PartialEq, Debug)]
crate enum BlockMode {
Break,
Ignore,
}
/// The parsing configuration used to parse a parameter list (see `parse_fn_params`).
struct ParamCfg {
/// Is `self` is allowed as the first parameter?
is_self_allowed: bool,
/// Is `...` allowed as the tail of the parameter list?
allow_c_variadic: bool,
/// `is_name_required` decides if, per-parameter,
/// the parameter must have a pattern or just a type.
is_name_required: fn(&token::Token) -> bool,
}
/// Like `maybe_whole_expr`, but for things other than expressions.
#[macro_export]
macro_rules! maybe_whole {
($p:expr, $constructor:ident, |$x:ident| $e:expr) => {
if let token::Interpolated(nt) = &$p.token.kind {
if let token::$constructor(x) = &**nt {
let $x = x.clone();
$p.bump();
return Ok($e);
}
}
};
}
/// If the next tokens are ill-formed `$ty::` recover them as `<$ty>::`.
#[macro_export]
macro_rules! maybe_recover_from_interpolated_ty_qpath {
($self: expr, $allow_qpath_recovery: expr) => {
if $allow_qpath_recovery && $self.look_ahead(1, |t| t == &token::ModSep) {
if let token::Interpolated(nt) = &$self.token.kind {
if let token::NtTy(ty) = &**nt {
let ty = ty.clone();
$self.bump();
return $self.maybe_recover_from_bad_qpath_stage_2($self.prev_span, ty);
}
}
}
}
}
fn maybe_append(mut lhs: Vec<Attribute>, mut rhs: Option<Vec<Attribute>>) -> Vec<Attribute> {
if let Some(ref mut rhs) = rhs {
lhs.append(rhs);
}
lhs
}
#[derive(Debug, Clone, Copy, PartialEq)]
enum PrevTokenKind {
DocComment,
Comma,
Plus,
Interpolated,
Eof,
Ident,
BitOr,
Other,
}
// NOTE: `Ident`s are handled by `common.rs`.
#[derive(Clone)]
pub struct Parser<'a> {
pub sess: &'a ParseSess,
/// The current normalized token.
/// "Normalized" means that some interpolated tokens
/// (`$i: ident` and `$l: lifetime` meta-variables) are replaced
/// with non-interpolated identifier and lifetime tokens they refer to.
/// Perhaps the normalized / non-normalized setup can be simplified somehow.
pub token: Token,
/// The span of the current non-normalized token.
meta_var_span: Option<Span>,
/// The span of the previous non-normalized token.
pub prev_span: Span,
/// The kind of the previous normalized token (in simplified form).
prev_token_kind: PrevTokenKind,
restrictions: Restrictions,
/// Used to determine the path to externally loaded source files.
crate directory: Directory<'a>,
/// `true` to parse sub-modules in other files.
pub recurse_into_file_modules: bool,
/// Name of the root module this parser originated from. If `None`, then the
/// name is not known. This does not change while the parser is descending
/// into modules, and sub-parsers have new values for this name.
pub root_module_name: Option<String>,
crate expected_tokens: Vec<TokenType>,
token_cursor: TokenCursor,
desugar_doc_comments: bool,
/// `true` we should configure out of line modules as we parse.
pub cfg_mods: bool,
/// This field is used to keep track of how many left angle brackets we have seen. This is
/// required in order to detect extra leading left angle brackets (`<` characters) and error
/// appropriately.
///
/// See the comments in the `parse_path_segment` function for more details.
crate unmatched_angle_bracket_count: u32,
crate max_angle_bracket_count: u32,
/// A list of all unclosed delimiters found by the lexer. If an entry is used for error recovery
/// it gets removed from here. Every entry left at the end gets emitted as an independent
/// error.
crate unclosed_delims: Vec<UnmatchedBrace>,
crate last_unexpected_token_span: Option<Span>,
crate last_type_ascription: Option<(Span, bool /* likely path typo */)>,
/// If present, this `Parser` is not parsing Rust code but rather a macro call.
crate subparser_name: Option<&'static str>,
}
impl<'a> Drop for Parser<'a> {
fn drop(&mut self) {
let diag = self.diagnostic();
emit_unclosed_delims(&mut self.unclosed_delims, diag);
}
}
#[derive(Clone)]
struct TokenCursor {
frame: TokenCursorFrame,
stack: Vec<TokenCursorFrame>,
}
#[derive(Clone)]
struct TokenCursorFrame {
delim: token::DelimToken,
span: DelimSpan,
open_delim: bool,
tree_cursor: tokenstream::Cursor,
close_delim: bool,
last_token: LastToken,
}
/// This is used in `TokenCursorFrame` above to track tokens that are consumed
/// by the parser, and then that's transitively used to record the tokens that
/// each parse AST item is created with.
///
/// Right now this has two states, either collecting tokens or not collecting
/// tokens. If we're collecting tokens we just save everything off into a local
/// `Vec`. This should eventually though likely save tokens from the original
/// token stream and just use slicing of token streams to avoid creation of a
/// whole new vector.
///
/// The second state is where we're passively not recording tokens, but the last
/// token is still tracked for when we want to start recording tokens. This
/// "last token" means that when we start recording tokens we'll want to ensure
/// that this, the first token, is included in the output.
///
/// You can find some more example usage of this in the `collect_tokens` method
/// on the parser.
#[derive(Clone)]
crate enum LastToken {
Collecting(Vec<TreeAndJoint>),
Was(Option<TreeAndJoint>),
}
impl TokenCursorFrame {
fn new(span: DelimSpan, delim: DelimToken, tts: &TokenStream) -> Self {
TokenCursorFrame {
delim,
span,
open_delim: delim == token::NoDelim,
tree_cursor: tts.clone().into_trees(),
close_delim: delim == token::NoDelim,
last_token: LastToken::Was(None),
}
}
}
impl TokenCursor {
fn next(&mut self) -> Token {
loop {
let tree = if !self.frame.open_delim {
self.frame.open_delim = true;
TokenTree::open_tt(self.frame.span.open, self.frame.delim)
} else if let Some(tree) = self.frame.tree_cursor.next() {
tree
} else if !self.frame.close_delim {
self.frame.close_delim = true;
TokenTree::close_tt(self.frame.span.close, self.frame.delim)
} else if let Some(frame) = self.stack.pop() {
self.frame = frame;
continue
} else {
return Token::new(token::Eof, DUMMY_SP);
};
match self.frame.last_token {
LastToken::Collecting(ref mut v) => v.push(tree.clone().into()),
LastToken::Was(ref mut t) => *t = Some(tree.clone().into()),
}
match tree {
TokenTree::Token(token) => return token,
TokenTree::Delimited(sp, delim, tts) => {
let frame = TokenCursorFrame::new(sp, delim, &tts);
self.stack.push(mem::replace(&mut self.frame, frame));
}
}
}
}
fn next_desugared(&mut self) -> Token {
let (name, sp) = match self.next() {
Token { kind: token::DocComment(name), span } => (name, span),
tok => return tok,
};
let stripped = strip_doc_comment_decoration(&name.as_str());
// Searches for the occurrences of `"#*` and returns the minimum number of `#`s
// required to wrap the text.
let mut num_of_hashes = 0;
let mut count = 0;
for ch in stripped.chars() {
count = match ch {
'"' => 1,
'#' if count > 0 => count + 1,
_ => 0,
};
num_of_hashes = cmp::max(num_of_hashes, count);
}
let delim_span = DelimSpan::from_single(sp);
let body = TokenTree::Delimited(
delim_span,
token::Bracket,
[
TokenTree::token(token::Ident(sym::doc, false), sp),
TokenTree::token(token::Eq, sp),
TokenTree::token(TokenKind::lit(
token::StrRaw(num_of_hashes), Symbol::intern(&stripped), None
), sp),
]
.iter().cloned().collect::<TokenStream>().into(),
);
self.stack.push(mem::replace(&mut self.frame, TokenCursorFrame::new(
delim_span,
token::NoDelim,
&if doc_comment_style(&name.as_str()) == AttrStyle::Inner {
[TokenTree::token(token::Pound, sp), TokenTree::token(token::Not, sp), body]
.iter().cloned().collect::<TokenStream>().into()
} else {
[TokenTree::token(token::Pound, sp), body]
.iter().cloned().collect::<TokenStream>().into()
},
)));
self.next()
}
}
#[derive(Clone, PartialEq)]
crate enum TokenType {
Token(TokenKind),
Keyword(Symbol),
Operator,
Lifetime,
Ident,
Path,
Type,
Const,
}
impl TokenType {
crate fn to_string(&self) -> String {
match *self {
TokenType::Token(ref t) => format!("`{}`", pprust::token_kind_to_string(t)),
TokenType::Keyword(kw) => format!("`{}`", kw),
TokenType::Operator => "an operator".to_string(),
TokenType::Lifetime => "lifetime".to_string(),
TokenType::Ident => "identifier".to_string(),
TokenType::Path => "path".to_string(),
TokenType::Type => "type".to_string(),
TokenType::Const => "const".to_string(),
}
}
}
#[derive(Copy, Clone, Debug)]
crate enum TokenExpectType {
Expect,
NoExpect,
}
impl<'a> Parser<'a> {
pub fn new(
sess: &'a ParseSess,
tokens: TokenStream,
directory: Option<Directory<'a>>,
recurse_into_file_modules: bool,
desugar_doc_comments: bool,
subparser_name: Option<&'static str>,
) -> Self {
let mut parser = Parser {
sess,
token: Token::dummy(),
prev_span: DUMMY_SP,
meta_var_span: None,
prev_token_kind: PrevTokenKind::Other,
restrictions: Restrictions::empty(),
recurse_into_file_modules,
directory: Directory {
path: Cow::from(PathBuf::new()),
ownership: DirectoryOwnership::Owned { relative: None }
},
root_module_name: None,
expected_tokens: Vec::new(),
token_cursor: TokenCursor {
frame: TokenCursorFrame::new(
DelimSpan::dummy(),
token::NoDelim,
&tokens.into(),
),
stack: Vec::new(),
},
desugar_doc_comments,
cfg_mods: true,
unmatched_angle_bracket_count: 0,
max_angle_bracket_count: 0,
unclosed_delims: Vec::new(),
last_unexpected_token_span: None,
last_type_ascription: None,
subparser_name,
};
parser.token = parser.next_tok();
if let Some(directory) = directory {
parser.directory = directory;
} else if !parser.token.span.is_dummy() {
if let Some(FileName::Real(path)) =
&sess.source_map().lookup_char_pos(parser.token.span.lo()).file.unmapped_path {
if let Some(directory_path) = path.parent() {
parser.directory.path = Cow::from(directory_path.to_path_buf());
}
}
}
parser.process_potential_macro_variable();
parser
}
fn next_tok(&mut self) -> Token {
let mut next = if self.desugar_doc_comments {
self.token_cursor.next_desugared()
} else {
self.token_cursor.next()
};
if next.span.is_dummy() {
// Tweak the location for better diagnostics, but keep syntactic context intact.
next.span = self.prev_span.with_ctxt(next.span.ctxt());
}
next
}
/// Converts the current token to a string using `self`'s reader.
pub fn this_token_to_string(&self) -> String {
pprust::token_to_string(&self.token)
}
crate fn token_descr(&self) -> Option<&'static str> {
Some(match &self.token.kind {
_ if self.token.is_special_ident() => "reserved identifier",
_ if self.token.is_used_keyword() => "keyword",
_ if self.token.is_unused_keyword() => "reserved keyword",
token::DocComment(..) => "doc comment",
_ => return None,
})
}
crate fn this_token_descr(&self) -> String {
if let Some(prefix) = self.token_descr() {
format!("{} `{}`", prefix, self.this_token_to_string())
} else {
format!("`{}`", self.this_token_to_string())
}
}
crate fn unexpected<T>(&mut self) -> PResult<'a, T> {
match self.expect_one_of(&[], &[]) {
Err(e) => Err(e),
Ok(_) => unreachable!(),
}
}
/// Expects and consumes the token `t`. Signals an error if the next token is not `t`.
pub fn expect(&mut self, t: &TokenKind) -> PResult<'a, bool /* recovered */> {
if self.expected_tokens.is_empty() {
if self.token == *t {
self.bump();
Ok(false)
} else {
self.unexpected_try_recover(t)
}
} else {
self.expect_one_of(slice::from_ref(t), &[])
}
}
/// Expect next token to be edible or inedible token. If edible,
/// then consume it; if inedible, then return without consuming
/// anything. Signal a fatal error if next token is unexpected.
pub fn expect_one_of(
&mut self,
edible: &[TokenKind],
inedible: &[TokenKind],
) -> PResult<'a, bool /* recovered */> {
if edible.contains(&self.token.kind) {
self.bump();
Ok(false)
} else if inedible.contains(&self.token.kind) {
// leave it in the input
Ok(false)
} else if self.last_unexpected_token_span == Some(self.token.span) {
FatalError.raise();
} else {
self.expected_one_of_not_found(edible, inedible)
}
}
pub fn parse_ident(&mut self) -> PResult<'a, ast::Ident> {
self.parse_ident_common(true)
}
fn parse_ident_common(&mut self, recover: bool) -> PResult<'a, ast::Ident> {
match self.token.kind {
token::Ident(name, _) => {
if self.token.is_reserved_ident() {
let mut err = self.expected_ident_found();
if recover {
err.emit();
} else {
return Err(err);
}
}
let span = self.token.span;
self.bump();
Ok(Ident::new(name, span))
}
_ => {
Err(if self.prev_token_kind == PrevTokenKind::DocComment {
self.span_fatal_err(self.prev_span, Error::UselessDocComment)
} else {
self.expected_ident_found()
})
}
}
}
/// Checks if the next token is `tok`, and returns `true` if so.
///
/// This method will automatically add `tok` to `expected_tokens` if `tok` is not
/// encountered.
crate fn check(&mut self, tok: &TokenKind) -> bool {
let is_present = self.token == *tok;
if !is_present { self.expected_tokens.push(TokenType::Token(tok.clone())); }
is_present
}
/// Consumes a token 'tok' if it exists. Returns whether the given token was present.
pub fn eat(&mut self, tok: &TokenKind) -> bool {
let is_present = self.check(tok);
if is_present { self.bump() }
is_present
}
/// If the next token is the given keyword, returns `true` without eating it.
/// An expectation is also added for diagnostics purposes.
fn check_keyword(&mut self, kw: Symbol) -> bool {
self.expected_tokens.push(TokenType::Keyword(kw));
self.token.is_keyword(kw)
}
/// If the next token is the given keyword, eats it and returns `true`.
/// Otherwise, returns `false`. An expectation is also added for diagnostics purposes.
pub fn eat_keyword(&mut self, kw: Symbol) -> bool {
if self.check_keyword(kw) {
self.bump();
true
} else {
false
}
}
fn eat_keyword_noexpect(&mut self, kw: Symbol) -> bool {
if self.token.is_keyword(kw) {
self.bump();
true
} else {
false
}
}
/// If the given word is not a keyword, signals an error.
/// If the next token is not the given word, signals an error.
/// Otherwise, eats it.
fn expect_keyword(&mut self, kw: Symbol) -> PResult<'a, ()> {
if !self.eat_keyword(kw) {
self.unexpected()
} else {
Ok(())
}
}
fn check_or_expected(&mut self, ok: bool, typ: TokenType) -> bool {
if ok {
true
} else {
self.expected_tokens.push(typ);
false
}
}
crate fn check_ident(&mut self) -> bool {
self.check_or_expected(self.token.is_ident(), TokenType::Ident)
}
fn check_path(&mut self) -> bool {
self.check_or_expected(self.token.is_path_start(), TokenType::Path)
}
fn check_type(&mut self) -> bool {
self.check_or_expected(self.token.can_begin_type(), TokenType::Type)
}
fn check_const_arg(&mut self) -> bool {
self.check_or_expected(self.token.can_begin_const_arg(), TokenType::Const)
}
/// Checks to see if the next token is either `+` or `+=`.
/// Otherwise returns `false`.
fn check_plus(&mut self) -> bool {
self.check_or_expected(
self.token.is_like_plus(),
TokenType::Token(token::BinOp(token::Plus)),
)
}
/// Expects and consumes a `+`. if `+=` is seen, replaces it with a `=`
/// and continues. If a `+` is not seen, returns `false`.
///
/// This is used when token-splitting `+=` into `+`.
/// See issue #47856 for an example of when this may occur.
fn eat_plus(&mut self) -> bool {
self.expected_tokens.push(TokenType::Token(token::BinOp(token::Plus)));
match self.token.kind {
token::BinOp(token::Plus) => {
self.bump();
true
}
token::BinOpEq(token::Plus) => {
let span = self.token.span.with_lo(self.token.span.lo() + BytePos(1));
self.bump_with(token::Eq, span);
true
}
_ => false,
}
}
/// Expects and consumes an `&`. If `&&` is seen, replaces it with a single
/// `&` and continues. If an `&` is not seen, signals an error.
fn expect_and(&mut self) -> PResult<'a, ()> {
self.expected_tokens.push(TokenType::Token(token::BinOp(token::And)));
match self.token.kind {
token::BinOp(token::And) => {
self.bump();
Ok(())
}
token::AndAnd => {
let span = self.token.span.with_lo(self.token.span.lo() + BytePos(1));
Ok(self.bump_with(token::BinOp(token::And), span))
}
_ => self.unexpected()
}
}
/// Expects and consumes an `|`. If `||` is seen, replaces it with a single
/// `|` and continues. If an `|` is not seen, signals an error.
fn expect_or(&mut self) -> PResult<'a, ()> {
self.expected_tokens.push(TokenType::Token(token::BinOp(token::Or)));
match self.token.kind {
token::BinOp(token::Or) => {
self.bump();
Ok(())
}
token::OrOr => {
let span = self.token.span.with_lo(self.token.span.lo() + BytePos(1));
Ok(self.bump_with(token::BinOp(token::Or), span))
}
_ => self.unexpected()
}
}
fn expect_no_suffix(&self, sp: Span, kind: &str, suffix: Option<ast::Name>) {
literal::expect_no_suffix(&self.sess.span_diagnostic, sp, kind, suffix)
}
/// Attempts to consume a `<`. If `<<` is seen, replaces it with a single
/// `<` and continue. If `<-` is seen, replaces it with a single `<`
/// and continue. If a `<` is not seen, returns false.
///
/// This is meant to be used when parsing generics on a path to get the
/// starting token.
fn eat_lt(&mut self) -> bool {
self.expected_tokens.push(TokenType::Token(token::Lt));
let ate = match self.token.kind {
token::Lt => {
self.bump();
true
}
token::BinOp(token::Shl) => {
let span = self.token.span.with_lo(self.token.span.lo() + BytePos(1));
self.bump_with(token::Lt, span);
true
}
token::LArrow => {
let span = self.token.span.with_lo(self.token.span.lo() + BytePos(1));
self.bump_with(token::BinOp(token::Minus), span);
true
}
_ => false,
};
if ate {
// See doc comment for `unmatched_angle_bracket_count`.
self.unmatched_angle_bracket_count += 1;
self.max_angle_bracket_count += 1;
debug!("eat_lt: (increment) count={:?}", self.unmatched_angle_bracket_count);
}
ate
}
fn expect_lt(&mut self) -> PResult<'a, ()> {
if !self.eat_lt() {
self.unexpected()
} else {
Ok(())
}
}
/// Expects and consumes a single `>` token. if a `>>` is seen, replaces it
/// with a single `>` and continues. If a `>` is not seen, signals an error.
fn expect_gt(&mut self) -> PResult<'a, ()> {
self.expected_tokens.push(TokenType::Token(token::Gt));
let ate = match self.token.kind {
token::Gt => {
self.bump();
Some(())
}
token::BinOp(token::Shr) => {
let span = self.token.span.with_lo(self.token.span.lo() + BytePos(1));
Some(self.bump_with(token::Gt, span))
}
token::BinOpEq(token::Shr) => {
let span = self.token.span.with_lo(self.token.span.lo() + BytePos(1));
Some(self.bump_with(token::Ge, span))
}
token::Ge => {
let span = self.token.span.with_lo(self.token.span.lo() + BytePos(1));
Some(self.bump_with(token::Eq, span))
}
_ => None,
};
match ate {
Some(_) => {
// See doc comment for `unmatched_angle_bracket_count`.
if self.unmatched_angle_bracket_count > 0 {
self.unmatched_angle_bracket_count -= 1;
debug!("expect_gt: (decrement) count={:?}", self.unmatched_angle_bracket_count);
}
Ok(())
},
None => self.unexpected(),
}
}
/// Parses a sequence, including the closing delimiter. The function
/// `f` must consume tokens until reaching the next separator or
/// closing bracket.
pub fn parse_seq_to_end<T>(
&mut self,
ket: &TokenKind,
sep: SeqSep,
f: impl FnMut(&mut Parser<'a>) -> PResult<'a, T>,
) -> PResult<'a, Vec<T>> {
let (val, _, recovered) = self.parse_seq_to_before_end(ket, sep, f)?;
if !recovered {
self.bump();
}
Ok(val)
}
/// Parses a sequence, not including the closing delimiter. The function
/// `f` must consume tokens until reaching the next separator or
/// closing bracket.
pub fn parse_seq_to_before_end<T>(
&mut self,
ket: &TokenKind,
sep: SeqSep,
f: impl FnMut(&mut Parser<'a>) -> PResult<'a, T>,
) -> PResult<'a, (Vec<T>, bool, bool)> {
self.parse_seq_to_before_tokens(&[ket], sep, TokenExpectType::Expect, f)
}
fn expect_any_with_type(&mut self, kets: &[&TokenKind], expect: TokenExpectType) -> bool {
kets.iter().any(|k| {
match expect {
TokenExpectType::Expect => self.check(k),
TokenExpectType::NoExpect => self.token == **k,
}
})
}
crate fn parse_seq_to_before_tokens<T>(
&mut self,
kets: &[&TokenKind],
sep: SeqSep,
expect: TokenExpectType,
mut f: impl FnMut(&mut Parser<'a>) -> PResult<'a, T>,
) -> PResult<'a, (Vec<T>, bool /* trailing */, bool /* recovered */)> {
let mut first = true;
let mut recovered = false;
let mut trailing = false;
let mut v = vec![];
while !self.expect_any_with_type(kets, expect) {
if let token::CloseDelim(..) | token::Eof = self.token.kind {
break
}
if let Some(ref t) = sep.sep {
if first {
first = false;
} else {
match self.expect(t) {
Ok(false) => {}
Ok(true) => {
recovered = true;
break;
}
Err(mut e) => {
// Attempt to keep parsing if it was a similar separator.
if let Some(ref tokens) = t.similar_tokens() {
if tokens.contains(&self.token.kind) {
self.bump();
}
}
e.emit();
// Attempt to keep parsing if it was an omitted separator.
match f(self) {
Ok(t) => {
v.push(t);
continue;
},
Err(mut e) => {
e.cancel();
break;
}
}
}
}
}
}
if sep.trailing_sep_allowed && self.expect_any_with_type(kets, expect) {
trailing = true;
break;
}
let t = f(self)?;
v.push(t);
}
Ok((v, trailing, recovered))
}
/// Parses a sequence, including the closing delimiter. The function
/// `f` must consume tokens until reaching the next separator or
/// closing bracket.
fn parse_unspanned_seq<T>(
&mut self,
bra: &TokenKind,
ket: &TokenKind,
sep: SeqSep,
f: impl FnMut(&mut Parser<'a>) -> PResult<'a, T>,
) -> PResult<'a, (Vec<T>, bool)> {
self.expect(bra)?;
let (result, trailing, recovered) = self.parse_seq_to_before_end(ket, sep, f)?;
if !recovered {
self.eat(ket);
}
Ok((result, trailing))
}
fn parse_delim_comma_seq<T>(
&mut self,
delim: DelimToken,
f: impl FnMut(&mut Parser<'a>) -> PResult<'a, T>,
) -> PResult<'a, (Vec<T>, bool)> {
self.parse_unspanned_seq(
&token::OpenDelim(delim),
&token::CloseDelim(delim),
SeqSep::trailing_allowed(token::Comma),
f,
)
}
fn parse_paren_comma_seq<T>(
&mut self,
f: impl FnMut(&mut Parser<'a>) -> PResult<'a, T>,
) -> PResult<'a, (Vec<T>, bool)> {
self.parse_delim_comma_seq(token::Paren, f)
}
/// Advance the parser by one token.
pub fn bump(&mut self) {
if self.prev_token_kind == PrevTokenKind::Eof {
// Bumping after EOF is a bad sign, usually an infinite loop.
self.bug("attempted to bump the parser past EOF (may be stuck in a loop)");
}
self.prev_span = self.meta_var_span.take().unwrap_or(self.token.span);
// Record last token kind for possible error recovery.
self.prev_token_kind = match self.token.kind {
token::DocComment(..) => PrevTokenKind::DocComment,
token::Comma => PrevTokenKind::Comma,
token::BinOp(token::Plus) => PrevTokenKind::Plus,
token::BinOp(token::Or) => PrevTokenKind::BitOr,
token::Interpolated(..) => PrevTokenKind::Interpolated,
token::Eof => PrevTokenKind::Eof,
token::Ident(..) => PrevTokenKind::Ident,
_ => PrevTokenKind::Other,
};
self.token = self.next_tok();
self.expected_tokens.clear();
// Check after each token.
self.process_potential_macro_variable();
}
/// Advances the parser using provided token as a next one. Use this when
/// consuming a part of a token. For example a single `<` from `<<`.
fn bump_with(&mut self, next: TokenKind, span: Span) {
self.prev_span = self.token.span.with_hi(span.lo());
// It would be incorrect to record the kind of the current token, but
// fortunately for tokens currently using `bump_with`, the
// `prev_token_kind` will be of no use anyway.
self.prev_token_kind = PrevTokenKind::Other;
self.token = Token::new(next, span);
self.expected_tokens.clear();
}
/// Look-ahead `dist` tokens of `self.token` and get access to that token there.
/// When `dist == 0` then the current token is looked at.
pub fn look_ahead<R>(&self, dist: usize, looker: impl FnOnce(&Token) -> R) -> R {
if dist == 0 {
return looker(&self.token);
}
let frame = &self.token_cursor.frame;
looker(&match frame.tree_cursor.look_ahead(dist - 1) {
Some(tree) => match tree {
TokenTree::Token(token) => token,
TokenTree::Delimited(dspan, delim, _) =>
Token::new(token::OpenDelim(delim), dspan.open),
}
None => Token::new(token::CloseDelim(frame.delim), frame.span.close)
})
}
/// Returns whether any of the given keywords are `dist` tokens ahead of the current one.
fn is_keyword_ahead(&self, dist: usize, kws: &[Symbol]) -> bool {
self.look_ahead(dist, |t| kws.iter().any(|&kw| t.is_keyword(kw)))
}
/// Parses asyncness: `async` or nothing.
fn parse_asyncness(&mut self) -> IsAsync {
if self.eat_keyword(kw::Async) {
IsAsync::Async {
closure_id: DUMMY_NODE_ID,
return_impl_trait_id: DUMMY_NODE_ID,
}
} else {
IsAsync::NotAsync
}
}
/// Parses unsafety: `unsafe` or nothing.
fn parse_unsafety(&mut self) -> Unsafety {
if self.eat_keyword(kw::Unsafe) {
Unsafety::Unsafe
} else {
Unsafety::Normal
}
}
/// Parses mutability (`mut` or nothing).
fn parse_mutability(&mut self) -> Mutability {
if self.eat_keyword(kw::Mut) {
Mutability::Mutable
} else {
Mutability::Immutable
}
}
/// Possibly parses mutability (`const` or `mut`).
fn parse_const_or_mut(&mut self) -> Option<Mutability> {
if self.eat_keyword(kw::Mut) {
Some(Mutability::Mutable)
} else if self.eat_keyword(kw::Const) {
Some(Mutability::Immutable)
} else {
None
}
}
fn parse_field_name(&mut self) -> PResult<'a, Ident> {
if let token::Literal(token::Lit { kind: token::Integer, symbol, suffix }) =
self.token.kind {
self.expect_no_suffix(self.token.span, "a tuple index", suffix);
self.bump();
Ok(Ident::new(symbol, self.prev_span))
} else {
self.parse_ident_common(false)
}
}
fn expect_delimited_token_tree(&mut self) -> PResult<'a, (MacDelimiter, TokenStream)> {
let delim = match self.token.kind {
token::OpenDelim(delim) => delim,
_ => {
let msg = "expected open delimiter";
let mut err = self.fatal(msg);
err.span_label(self.token.span, msg);
return Err(err)
}
};
let tts = match self.parse_token_tree() {
TokenTree::Delimited(_, _, tts) => tts,
_ => unreachable!(),
};
let delim = match delim {
token::Paren => MacDelimiter::Parenthesis,
token::Bracket => MacDelimiter::Bracket,
token::Brace => MacDelimiter::Brace,
token::NoDelim => self.bug("unexpected no delimiter"),
};
Ok((delim, tts.into()))
}
fn parse_or_use_outer_attributes(
&mut self,
already_parsed_attrs: Option<ThinVec<Attribute>>,
) -> PResult<'a, ThinVec<Attribute>> {
if let Some(attrs) = already_parsed_attrs {
Ok(attrs)
} else {
self.parse_outer_attributes().map(|a| a.into())
}
}
crate fn process_potential_macro_variable(&mut self) {
self.token = match self.token.kind {
token::Dollar if self.token.span.from_expansion() &&
self.look_ahead(1, |t| t.is_ident()) => {
self.bump();
let name = match self.token.kind {
token::Ident(name, _) => name,
_ => unreachable!()
};
let span = self.prev_span.to(self.token.span);
self.diagnostic()
.struct_span_fatal(span, &format!("unknown macro variable `{}`", name))
.span_label(span, "unknown macro variable")
.emit();
self.bump();
return
}
token::Interpolated(ref nt) => {
self.meta_var_span = Some(self.token.span);
// Interpolated identifier and lifetime tokens are replaced with usual identifier
// and lifetime tokens, so the former are never encountered during normal parsing.
match **nt {
token::NtIdent(ident, is_raw) =>
Token::new(token::Ident(ident.name, is_raw), ident.span),
token::NtLifetime(ident) =>
Token::new(token::Lifetime(ident.name), ident.span),
_ => return,
}
}
_ => return,
};
}
/// Parses a single token tree from the input.
crate fn parse_token_tree(&mut self) -> TokenTree {
match self.token.kind {
token::OpenDelim(..) => {
let frame = mem::replace(&mut self.token_cursor.frame,
self.token_cursor.stack.pop().unwrap());
self.token.span = frame.span.entire();
self.bump();
TokenTree::Delimited(
frame.span,
frame.delim,
frame.tree_cursor.stream.into(),
)
},
token::CloseDelim(_) | token::Eof => unreachable!(),
_ => {
let token = self.token.take();
self.bump();
TokenTree::Token(token)
}
}
}
/// Parses a stream of tokens into a list of `TokenTree`s, up to EOF.
pub fn parse_all_token_trees(&mut self) -> PResult<'a, Vec<TokenTree>> {
let mut tts = Vec::new();
while self.token != token::Eof {
tts.push(self.parse_token_tree());
}
Ok(tts)
}
pub fn parse_tokens(&mut self) -> TokenStream {
let mut result = Vec::new();
loop {
match self.token.kind {
token::Eof | token::CloseDelim(..) => break,
_ => result.push(self.parse_token_tree().into()),
}
}
TokenStream::new(result)
}
/// Evaluates the closure with restrictions in place.
///
/// Afters the closure is evaluated, restrictions are reset.
fn with_res<T>(&mut self, res: Restrictions, f: impl FnOnce(&mut Self) -> T) -> T {
let old = self.restrictions;
self.restrictions = res;
let res = f(self);
self.restrictions = old;
res
}
/// Parses the parameter list of a function, including the `(` and `)` delimiters.
fn parse_fn_params(&mut self, mut cfg: ParamCfg) -> PResult<'a, Vec<Param>> {
let sp = self.token.span;
let is_trait_item = cfg.is_self_allowed;
let mut c_variadic = false;
// Parse the arguments, starting out with `self` being possibly allowed...
let (params, _) = self.parse_paren_comma_seq(|p| {
let param = p.parse_param_general(&cfg, is_trait_item);
// ...now that we've parsed the first argument, `self` is no longer allowed.
cfg.is_self_allowed = false;
match param {
Ok(param) => Ok(
if let TyKind::CVarArgs = param.ty.kind {
c_variadic = true;
if p.token != token::CloseDelim(token::Paren) {
p.span_err(
p.token.span,
"`...` must be the last argument of a C-variadic function",
);
// FIXME(eddyb) this should probably still push `CVarArgs`.
// Maybe AST validation/HIR lowering should emit the above error?
None
} else {
Some(param)
}
} else {
Some(param)
}
),
Err(mut e) => {
e.emit();
let lo = p.prev_span;
// Skip every token until next possible arg or end.
p.eat_to_tokens(&[&token::Comma, &token::CloseDelim(token::Paren)]);
// Create a placeholder argument for proper arg count (issue #34264).
let span = lo.to(p.prev_span);
Ok(Some(dummy_arg(Ident::new(kw::Invalid, span))))
}
}
})?;
let mut params: Vec<_> = params.into_iter().filter_map(|x| x).collect();
// Replace duplicated recovered params with `_` pattern to avoid unecessary errors.
self.deduplicate_recovered_params_names(&mut params);
if c_variadic && params.len() <= 1 {
self.span_err(
sp,
"C-variadic function must be declared with at least one named argument",
);
}
Ok(params)
}
/// Skips unexpected attributes and doc comments in this position and emits an appropriate
/// error.
/// This version of parse param doesn't necessarily require identifier names.
fn parse_param_general(&mut self, cfg: &ParamCfg, is_trait_item: bool) -> PResult<'a, Param> {
let lo = self.token.span;
let attrs = self.parse_outer_attributes()?;
// Possibly parse `self`. Recover if we parsed it and it wasn't allowed here.
if let Some(mut param) = self.parse_self_param()? {
param.attrs = attrs.into();
return if cfg.is_self_allowed {
Ok(param)
} else {
self.recover_bad_self_param(param, is_trait_item)
};
}
let is_name_required = match self.token.kind {
token::DotDotDot => false,
_ => (cfg.is_name_required)(&self.token),
};
let (pat, ty) = if is_name_required || self.is_named_param() {
debug!("parse_param_general parse_pat (is_name_required:{})", is_name_required);
let pat = self.parse_fn_param_pat()?;
if let Err(mut err) = self.expect(&token::Colon) {
return if let Some(ident) = self.parameter_without_type(
&mut err,
pat,
is_name_required,
cfg.is_self_allowed,
is_trait_item,
) {
err.emit();
Ok(dummy_arg(ident))
} else {
Err(err)
};
}
self.eat_incorrect_doc_comment_for_param_type();
(pat, self.parse_ty_common(true, true, cfg.allow_c_variadic)?)
} else {
debug!("parse_param_general ident_to_pat");
let parser_snapshot_before_ty = self.clone();
self.eat_incorrect_doc_comment_for_param_type();
let mut ty = self.parse_ty_common(true, true, cfg.allow_c_variadic);
if ty.is_ok() && self.token != token::Comma &&
self.token != token::CloseDelim(token::Paren) {
// This wasn't actually a type, but a pattern looking like a type,
// so we are going to rollback and re-parse for recovery.
ty = self.unexpected();
}
match ty {
Ok(ty) => {
let ident = Ident::new(kw::Invalid, self.prev_span);
let bm = BindingMode::ByValue(Mutability::Immutable);
let pat = self.mk_pat_ident(ty.span, bm, ident);
(pat, ty)
}
// If this is a C-variadic argument and we hit an error, return the error.
Err(err) if self.token == token::DotDotDot => return Err(err),
// Recover from attempting to parse the argument as a type without pattern.
Err(mut err) => {
err.cancel();
mem::replace(self, parser_snapshot_before_ty);
self.recover_arg_parse()?
}
}
};
let span = lo.to(self.token.span);
Ok(Param {
attrs: attrs.into(),
id: ast::DUMMY_NODE_ID,
is_placeholder: false,
pat,
span,
ty,
})
}
/// Returns the parsed optional self parameter and whether a self shortcut was used.
///
/// See `parse_self_param_with_attrs` to collect attributes.
fn parse_self_param(&mut self) -> PResult<'a, Option<Param>> {
// Extract an identifier *after* having confirmed that the token is one.
let expect_self_ident = |this: &mut Self| {
match this.token.kind {
// Preserve hygienic context.
token::Ident(name, _) => {
let span = this.token.span;
this.bump();
Ident::new(name, span)
}
_ => unreachable!(),
}
};
// Is `self` `n` tokens ahead?
let is_isolated_self = |this: &Self, n| {
this.is_keyword_ahead(n, &[kw::SelfLower])
&& this.look_ahead(n + 1, |t| t != &token::ModSep)
};
// Is `mut self` `n` tokens ahead?
let is_isolated_mut_self = |this: &Self, n| {
this.is_keyword_ahead(n, &[kw::Mut])
&& is_isolated_self(this, n + 1)
};
// Parse `self` or `self: TYPE`. We already know the current token is `self`.
let parse_self_possibly_typed = |this: &mut Self, m| {
let eself_ident = expect_self_ident(this);
let eself_hi = this.prev_span;
let eself = if this.eat(&token::Colon) {
SelfKind::Explicit(this.parse_ty()?, m)
} else {
SelfKind::Value(m)
};
Ok((eself, eself_ident, eself_hi))
};
// Recover for the grammar `*self`, `*const self`, and `*mut self`.
let recover_self_ptr = |this: &mut Self| {
let msg = "cannot pass `self` by raw pointer";
let span = this.token.span;
this.struct_span_err(span, msg)
.span_label(span, msg)
.emit();
Ok((SelfKind::Value(Mutability::Immutable), expect_self_ident(this), this.prev_span))
};
// Parse optional `self` parameter of a method.
// Only a limited set of initial token sequences is considered `self` parameters; anything
// else is parsed as a normal function parameter list, so some lookahead is required.
let eself_lo = self.token.span;
let (eself, eself_ident, eself_hi) = match self.token.kind {
token::BinOp(token::And) => {
let eself = if is_isolated_self(self, 1) {
// `&self`
self.bump();
SelfKind::Region(None, Mutability::Immutable)
} else if is_isolated_mut_self(self, 1) {
// `&mut self`
self.bump();
self.bump();
SelfKind::Region(None, Mutability::Mutable)
} else if self.look_ahead(1, |t| t.is_lifetime()) && is_isolated_self(self, 2) {
// `&'lt self`
self.bump();
let lt = self.expect_lifetime();
SelfKind::Region(Some(lt), Mutability::Immutable)
} else if self.look_ahead(1, |t| t.is_lifetime()) && is_isolated_mut_self(self, 2) {
// `&'lt mut self`
self.bump();
let lt = self.expect_lifetime();
self.bump();
SelfKind::Region(Some(lt), Mutability::Mutable)
} else {
// `&not_self`
return Ok(None);
};
(eself, expect_self_ident(self), self.prev_span)
}
// `*self`
token::BinOp(token::Star) if is_isolated_self(self, 1) => {
self.bump();
recover_self_ptr(self)?
}
// `*mut self` and `*const self`
token::BinOp(token::Star) if
self.look_ahead(1, |t| t.is_mutability())
&& is_isolated_self(self, 2) =>
{
self.bump();
self.bump();
recover_self_ptr(self)?
}
// `self` and `self: TYPE`
token::Ident(..) if is_isolated_self(self, 0) => {
parse_self_possibly_typed(self, Mutability::Immutable)?
}
// `mut self` and `mut self: TYPE`
token::Ident(..) if is_isolated_mut_self(self, 0) => {
self.bump();
parse_self_possibly_typed(self, Mutability::Mutable)?
}
_ => return Ok(None),
};
let eself = source_map::respan(eself_lo.to(eself_hi), eself);
Ok(Some(Param::from_self(ThinVec::default(), eself, eself_ident)))
}
fn is_named_param(&self) -> bool {
let offset = match self.token.kind {
token::Interpolated(ref nt) => match **nt {
token::NtPat(..) => return self.look_ahead(1, |t| t == &token::Colon),
_ => 0,
}
token::BinOp(token::And) | token::AndAnd => 1,
_ if self.token.is_keyword(kw::Mut) => 1,
_ => 0,
};
self.look_ahead(offset, |t| t.is_ident()) &&
self.look_ahead(offset + 1, |t| t == &token::Colon)
}
fn is_crate_vis(&self) -> bool {
self.token.is_keyword(kw::Crate) && self.look_ahead(1, |t| t != &token::ModSep)
}
/// Parses `pub`, `pub(crate)` and `pub(in path)` plus shortcuts `crate` for `pub(crate)`,
/// `pub(self)` for `pub(in self)` and `pub(super)` for `pub(in super)`.
/// If the following element can't be a tuple (i.e., it's a function definition), then
/// it's not a tuple struct field), and the contents within the parentheses isn't valid,
/// so emit a proper diagnostic.
pub fn parse_visibility(&mut self, can_take_tuple: bool) -> PResult<'a, Visibility> {
maybe_whole!(self, NtVis, |x| x);
self.expected_tokens.push(TokenType::Keyword(kw::Crate));
if self.is_crate_vis() {
self.bump(); // `crate`
return Ok(respan(self.prev_span, VisibilityKind::Crate(CrateSugar::JustCrate)));
}
if !self.eat_keyword(kw::Pub) {
// We need a span for our `Spanned<VisibilityKind>`, but there's inherently no
// keyword to grab a span from for inherited visibility; an empty span at the
// beginning of the current token would seem to be the "Schelling span".
return Ok(respan(self.token.span.shrink_to_lo(), VisibilityKind::Inherited))
}
let lo = self.prev_span;
if self.check(&token::OpenDelim(token::Paren)) {
// We don't `self.bump()` the `(` yet because this might be a struct definition where
// `()` or a tuple might be allowed. For example, `struct Struct(pub (), pub (usize));`.
// Because of this, we only `bump` the `(` if we're assured it is appropriate to do so
// by the following tokens.
if self.is_keyword_ahead(1, &[kw::Crate])
&& self.look_ahead(2, |t| t != &token::ModSep) // account for `pub(crate::foo)`
{
// Parse `pub(crate)`.
self.bump(); // `(`
self.bump(); // `crate`
self.expect(&token::CloseDelim(token::Paren))?; // `)`
let vis = VisibilityKind::Crate(CrateSugar::PubCrate);
return Ok(respan(lo.to(self.prev_span), vis));
} else if self.is_keyword_ahead(1, &[kw::In]) {
// Parse `pub(in path)`.
self.bump(); // `(`
self.bump(); // `in`
let path = self.parse_path(PathStyle::Mod)?; // `path`
self.expect(&token::CloseDelim(token::Paren))?; // `)`
let vis = VisibilityKind::Restricted {
path: P(path),
id: ast::DUMMY_NODE_ID,
};
return Ok(respan(lo.to(self.prev_span), vis));
} else if self.look_ahead(2, |t| t == &token::CloseDelim(token::Paren))
&& self.is_keyword_ahead(1, &[kw::Super, kw::SelfLower])
{
// Parse `pub(self)` or `pub(super)`.
self.bump(); // `(`
let path = self.parse_path(PathStyle::Mod)?; // `super`/`self`
self.expect(&token::CloseDelim(token::Paren))?; // `)`
let vis = VisibilityKind::Restricted {
path: P(path),
id: ast::DUMMY_NODE_ID,
};
return Ok(respan(lo.to(self.prev_span), vis));
} else if !can_take_tuple { // Provide this diagnostic if this is not a tuple struct.
self.recover_incorrect_vis_restriction()?;
// Emit diagnostic, but continue with public visibility.
}
}
Ok(respan(lo, VisibilityKind::Public))
}
/// Recovery for e.g. `pub(something) fn ...` or `struct X { pub(something) y: Z }`
fn recover_incorrect_vis_restriction(&mut self) -> PResult<'a, ()> {
self.bump(); // `(`
let path = self.parse_path(PathStyle::Mod)?;
self.expect(&token::CloseDelim(token::Paren))?; // `)`
let msg = "incorrect visibility restriction";
let suggestion = r##"some possible visibility restrictions are:
`pub(crate)`: visible only on the current crate
`pub(super)`: visible only in the current module's parent
`pub(in path::to::module)`: visible only on the specified path"##;
struct_span_err!(self.sess.span_diagnostic, path.span, E0704, "{}", msg)
.help(suggestion)
.span_suggestion(
path.span,
&format!("make this visible only to module `{}` with `in`", path),
format!("in {}", path),
Applicability::MachineApplicable,
)
.emit();
Ok(())
}
/// Parses `extern` followed by an optional ABI string, or nothing.
fn parse_extern_abi(&mut self) -> PResult<'a, Abi> {
if self.eat_keyword(kw::Extern) {
Ok(self.parse_opt_abi()?.unwrap_or(Abi::C))
} else {
Ok(Abi::Rust)
}
}
/// Parses a string as an ABI spec on an extern type or module. Consumes
/// the `extern` keyword, if one is found.
fn parse_opt_abi(&mut self) -> PResult<'a, Option<Abi>> {
match self.token.kind {
token::Literal(token::Lit { kind: token::Str, symbol, suffix }) |
token::Literal(token::Lit { kind: token::StrRaw(..), symbol, suffix }) => {
self.expect_no_suffix(self.token.span, "an ABI spec", suffix);
self.bump();
match abi::lookup(&symbol.as_str()) {
Some(abi) => Ok(Some(abi)),
None => {
self.error_on_invalid_abi(symbol);
Ok(None)
}
}
}
_ => Ok(None),
}
}
/// Emit an error where `symbol` is an invalid ABI.
fn error_on_invalid_abi(&self, symbol: Symbol) {
let prev_span = self.prev_span;
struct_span_err!(
self.sess.span_diagnostic,
prev_span,
E0703,
"invalid ABI: found `{}`",
symbol
)
.span_label(prev_span, "invalid ABI")
.help(&format!("valid ABIs: {}", abi::all_names().join(", ")))
.emit();
}
/// We are parsing `async fn`. If we are on Rust 2015, emit an error.
fn ban_async_in_2015(&self, async_span: Span) {
if async_span.rust_2015() {
self.diagnostic()
.struct_span_err_with_code(
async_span,
"`async fn` is not permitted in the 2015 edition",
DiagnosticId::Error("E0670".into())
)
.emit();
}
}
fn collect_tokens<R>(
&mut self,
f: impl FnOnce(&mut Self) -> PResult<'a, R>,
) -> PResult<'a, (R, TokenStream)> {
// Record all tokens we parse when parsing this item.
let mut tokens = Vec::new();
let prev_collecting = match self.token_cursor.frame.last_token {
LastToken::Collecting(ref mut list) => {
Some(mem::take(list))
}
LastToken::Was(ref mut last) => {
tokens.extend(last.take());
None
}
};
self.token_cursor.frame.last_token = LastToken::Collecting(tokens);
let prev = self.token_cursor.stack.len();
let ret = f(self);
let last_token = if self.token_cursor.stack.len() == prev {
&mut self.token_cursor.frame.last_token
} else if self.token_cursor.stack.get(prev).is_none() {
// This can happen due to a bad interaction of two unrelated recovery mechanisms with
// mismatched delimiters *and* recovery lookahead on the likely typo `pub ident(`
// (#62881).
return Ok((ret?, TokenStream::new(vec![])));
} else {
&mut self.token_cursor.stack[prev].last_token
};
// Pull out the tokens that we've collected from the call to `f` above.
let mut collected_tokens = match *last_token {
LastToken::Collecting(ref mut v) => mem::take(v),
LastToken::Was(ref was) => {
let msg = format!("our vector went away? - found Was({:?})", was);
debug!("collect_tokens: {}", msg);
self.sess.span_diagnostic.delay_span_bug(self.token.span, &msg);
// This can happen due to a bad interaction of two unrelated recovery mechanisms
// with mismatched delimiters *and* recovery lookahead on the likely typo
// `pub ident(` (#62895, different but similar to the case above).
return Ok((ret?, TokenStream::new(vec![])));
}
};
// If we're not at EOF our current token wasn't actually consumed by
// `f`, but it'll still be in our list that we pulled out. In that case
// put it back.
let extra_token = if self.token != token::Eof {
collected_tokens.pop()
} else {
None
};
// If we were previously collecting tokens, then this was a recursive
// call. In that case we need to record all the tokens we collected in
// our parent list as well. To do that we push a clone of our stream
// onto the previous list.
match prev_collecting {
Some(mut list) => {
list.extend(collected_tokens.iter().cloned());
list.extend(extra_token);
*last_token = LastToken::Collecting(list);
}
None => {
*last_token = LastToken::Was(extra_token);
}
}
Ok((ret?, TokenStream::new(collected_tokens)))
}
/// `::{` or `::*`
fn is_import_coupler(&mut self) -> bool {
self.check(&token::ModSep) &&
self.look_ahead(1, |t| *t == token::OpenDelim(token::Brace) ||
*t == token::BinOp(token::Star))
}
pub fn parse_optional_str(&mut self) -> Option<(Symbol, ast::StrStyle, Option<ast::Name>)> {
let ret = match self.token.kind {
token::Literal(token::Lit { kind: token::Str, symbol, suffix }) =>
(symbol, ast::StrStyle::Cooked, suffix),
token::Literal(token::Lit { kind: token::StrRaw(n), symbol, suffix }) =>
(symbol, ast::StrStyle::Raw(n), suffix),
_ => return None
};
self.bump();
Some(ret)
}
pub fn parse_str(&mut self) -> PResult<'a, (Symbol, StrStyle)> {
match self.parse_optional_str() {
Some((s, style, suf)) => {
let sp = self.prev_span;
self.expect_no_suffix(sp, "a string literal", suf);
Ok((s, style))
}
_ => {
let msg = "expected string literal";
let mut err = self.fatal(msg);
err.span_label(self.token.span, msg);
Err(err)
}
}
}
fn report_invalid_macro_expansion_item(&self) {
self.struct_span_err(
self.prev_span,
"macros that expand to items must be delimited with braces or followed by a semicolon",
).multipart_suggestion(
"change the delimiters to curly braces",
vec![
(self.prev_span.with_hi(self.prev_span.lo() + BytePos(1)), String::from(" {")),
(self.prev_span.with_lo(self.prev_span.hi() - BytePos(1)), '}'.to_string()),
],
Applicability::MaybeIncorrect,
).span_suggestion(
self.sess.source_map.next_point(self.prev_span),
"add a semicolon",
';'.to_string(),
Applicability::MaybeIncorrect,
).emit();
}
}
pub fn emit_unclosed_delims(unclosed_delims: &mut Vec<UnmatchedBrace>, handler: &errors::Handler) {
for unmatched in unclosed_delims.iter() {
let mut err = handler.struct_span_err(unmatched.found_span, &format!(
"incorrect close delimiter: `{}`",
pprust::token_kind_to_string(&token::CloseDelim(unmatched.found_delim)),
));
err.span_label(unmatched.found_span, "incorrect close delimiter");
if let Some(sp) = unmatched.candidate_span {
err.span_label(sp, "close delimiter possibly meant for this");
}
if let Some(sp) = unmatched.unclosed_span {
err.span_label(sp, "un-closed delimiter");
}
err.emit();
}
unclosed_delims.clear();
}