| //! Code related to parsing literals. |
| |
| use crate::ast::{self, Lit, LitKind}; |
| use crate::parse::parser::Parser; |
| use crate::parse::PResult; |
| use crate::parse::token::{self, Token, TokenKind}; |
| use crate::print::pprust; |
| use crate::symbol::{kw, sym, Symbol}; |
| use crate::tokenstream::{TokenStream, TokenTree}; |
| |
| use errors::{Applicability, Handler}; |
| use log::debug; |
| use rustc_data_structures::sync::Lrc; |
| use syntax_pos::Span; |
| use rustc_lexer::unescape::{unescape_char, unescape_byte}; |
| use rustc_lexer::unescape::{unescape_str, unescape_byte_str}; |
| use rustc_lexer::unescape::{unescape_raw_str, unescape_raw_byte_str}; |
| |
| use std::ascii; |
| |
| crate enum LitError { |
| NotLiteral, |
| LexerError, |
| InvalidSuffix, |
| InvalidIntSuffix, |
| InvalidFloatSuffix, |
| NonDecimalFloat(u32), |
| IntTooLarge, |
| } |
| |
| impl LitError { |
| fn report(&self, diag: &Handler, lit: token::Lit, span: Span) { |
| let token::Lit { kind, suffix, .. } = lit; |
| match *self { |
| // `NotLiteral` is not an error by itself, so we don't report |
| // it and give the parser opportunity to try something else. |
| LitError::NotLiteral => {} |
| // `LexerError` *is* an error, but it was already reported |
| // by lexer, so here we don't report it the second time. |
| LitError::LexerError => {} |
| LitError::InvalidSuffix => { |
| expect_no_suffix( |
| diag, span, &format!("{} {} literal", kind.article(), kind.descr()), suffix |
| ); |
| } |
| LitError::InvalidIntSuffix => { |
| let suf = suffix.expect("suffix error with no suffix").as_str(); |
| if looks_like_width_suffix(&['i', 'u'], &suf) { |
| // If it looks like a width, try to be helpful. |
| let msg = format!("invalid width `{}` for integer literal", &suf[1..]); |
| diag.struct_span_err(span, &msg) |
| .help("valid widths are 8, 16, 32, 64 and 128") |
| .emit(); |
| } else { |
| let msg = format!("invalid suffix `{}` for integer literal", suf); |
| diag.struct_span_err(span, &msg) |
| .span_label(span, format!("invalid suffix `{}`", suf)) |
| .help("the suffix must be one of the integral types (`u32`, `isize`, etc)") |
| .emit(); |
| } |
| } |
| LitError::InvalidFloatSuffix => { |
| let suf = suffix.expect("suffix error with no suffix").as_str(); |
| if looks_like_width_suffix(&['f'], &suf) { |
| // If it looks like a width, try to be helpful. |
| let msg = format!("invalid width `{}` for float literal", &suf[1..]); |
| diag.struct_span_err(span, &msg) |
| .help("valid widths are 32 and 64") |
| .emit(); |
| } else { |
| let msg = format!("invalid suffix `{}` for float literal", suf); |
| diag.struct_span_err(span, &msg) |
| .span_label(span, format!("invalid suffix `{}`", suf)) |
| .help("valid suffixes are `f32` and `f64`") |
| .emit(); |
| } |
| } |
| LitError::NonDecimalFloat(base) => { |
| let descr = match base { |
| 16 => "hexadecimal", |
| 8 => "octal", |
| 2 => "binary", |
| _ => unreachable!(), |
| }; |
| diag.struct_span_err(span, &format!("{} float literal is not supported", descr)) |
| .span_label(span, "not supported") |
| .emit(); |
| } |
| LitError::IntTooLarge => { |
| diag.struct_span_err(span, "integer literal is too large") |
| .emit(); |
| } |
| } |
| } |
| } |
| |
| impl LitKind { |
| /// Converts literal token into a semantic literal. |
| fn from_lit_token(lit: token::Lit) -> Result<LitKind, LitError> { |
| let token::Lit { kind, symbol, suffix } = lit; |
| if suffix.is_some() && !kind.may_have_suffix() { |
| return Err(LitError::InvalidSuffix); |
| } |
| |
| Ok(match kind { |
| token::Bool => { |
| assert!(symbol == kw::True || symbol == kw::False); |
| LitKind::Bool(symbol == kw::True) |
| } |
| token::Byte => return unescape_byte(&symbol.as_str()) |
| .map(LitKind::Byte).map_err(|_| LitError::LexerError), |
| token::Char => return unescape_char(&symbol.as_str()) |
| .map(LitKind::Char).map_err(|_| LitError::LexerError), |
| |
| // There are some valid suffixes for integer and float literals, |
| // so all the handling is done internally. |
| token::Integer => return integer_lit(symbol, suffix), |
| token::Float => return float_lit(symbol, suffix), |
| |
| token::Str => { |
| // If there are no characters requiring special treatment we can |
| // reuse the symbol from the token. Otherwise, we must generate a |
| // new symbol because the string in the LitKind is different to the |
| // string in the token. |
| let s = symbol.as_str(); |
| let symbol = if s.contains(&['\\', '\r'][..]) { |
| let mut buf = String::with_capacity(s.len()); |
| let mut error = Ok(()); |
| unescape_str(&s, &mut |_, unescaped_char| { |
| match unescaped_char { |
| Ok(c) => buf.push(c), |
| Err(_) => error = Err(LitError::LexerError), |
| } |
| }); |
| error?; |
| Symbol::intern(&buf) |
| } else { |
| symbol |
| }; |
| LitKind::Str(symbol, ast::StrStyle::Cooked) |
| } |
| token::StrRaw(n) => { |
| // Ditto. |
| let s = symbol.as_str(); |
| let symbol = if s.contains('\r') { |
| let mut buf = String::with_capacity(s.len()); |
| let mut error = Ok(()); |
| unescape_raw_str(&s, &mut |_, unescaped_char| { |
| match unescaped_char { |
| Ok(c) => buf.push(c), |
| Err(_) => error = Err(LitError::LexerError), |
| } |
| }); |
| error?; |
| buf.shrink_to_fit(); |
| Symbol::intern(&buf) |
| } else { |
| symbol |
| }; |
| LitKind::Str(symbol, ast::StrStyle::Raw(n)) |
| } |
| token::ByteStr => { |
| let s = symbol.as_str(); |
| let mut buf = Vec::with_capacity(s.len()); |
| let mut error = Ok(()); |
| unescape_byte_str(&s, &mut |_, unescaped_byte| { |
| match unescaped_byte { |
| Ok(c) => buf.push(c), |
| Err(_) => error = Err(LitError::LexerError), |
| } |
| }); |
| error?; |
| buf.shrink_to_fit(); |
| LitKind::ByteStr(Lrc::new(buf)) |
| } |
| token::ByteStrRaw(_) => { |
| let s = symbol.as_str(); |
| let bytes = if s.contains('\r') { |
| let mut buf = Vec::with_capacity(s.len()); |
| let mut error = Ok(()); |
| unescape_raw_byte_str(&s, &mut |_, unescaped_byte| { |
| match unescaped_byte { |
| Ok(c) => buf.push(c), |
| Err(_) => error = Err(LitError::LexerError), |
| } |
| }); |
| error?; |
| buf.shrink_to_fit(); |
| buf |
| } else { |
| symbol.to_string().into_bytes() |
| }; |
| |
| LitKind::ByteStr(Lrc::new(bytes)) |
| }, |
| token::Err => LitKind::Err(symbol), |
| }) |
| } |
| |
| /// Attempts to recover a token from semantic literal. |
| /// This function is used when the original token doesn't exist (e.g. the literal is created |
| /// by an AST-based macro) or unavailable (e.g. from HIR pretty-printing). |
| pub fn to_lit_token(&self) -> token::Lit { |
| let (kind, symbol, suffix) = match *self { |
| LitKind::Str(symbol, ast::StrStyle::Cooked) => { |
| // Don't re-intern unless the escaped string is different. |
| let s = &symbol.as_str(); |
| let escaped = s.escape_default().to_string(); |
| let symbol = if escaped == *s { symbol } else { Symbol::intern(&escaped) }; |
| (token::Str, symbol, None) |
| } |
| LitKind::Str(symbol, ast::StrStyle::Raw(n)) => { |
| (token::StrRaw(n), symbol, None) |
| } |
| LitKind::ByteStr(ref bytes) => { |
| let string = bytes.iter().cloned().flat_map(ascii::escape_default) |
| .map(Into::<char>::into).collect::<String>(); |
| (token::ByteStr, Symbol::intern(&string), None) |
| } |
| LitKind::Byte(byte) => { |
| let string: String = ascii::escape_default(byte).map(Into::<char>::into).collect(); |
| (token::Byte, Symbol::intern(&string), None) |
| } |
| LitKind::Char(ch) => { |
| let string: String = ch.escape_default().map(Into::<char>::into).collect(); |
| (token::Char, Symbol::intern(&string), None) |
| } |
| LitKind::Int(n, ty) => { |
| let suffix = match ty { |
| ast::LitIntType::Unsigned(ty) => Some(ty.to_symbol()), |
| ast::LitIntType::Signed(ty) => Some(ty.to_symbol()), |
| ast::LitIntType::Unsuffixed => None, |
| }; |
| (token::Integer, sym::integer(n), suffix) |
| } |
| LitKind::Float(symbol, ty) => { |
| (token::Float, symbol, Some(ty.to_symbol())) |
| } |
| LitKind::FloatUnsuffixed(symbol) => { |
| (token::Float, symbol, None) |
| } |
| LitKind::Bool(value) => { |
| let symbol = if value { kw::True } else { kw::False }; |
| (token::Bool, symbol, None) |
| } |
| LitKind::Err(symbol) => { |
| (token::Err, symbol, None) |
| } |
| }; |
| |
| token::Lit::new(kind, symbol, suffix) |
| } |
| } |
| |
| impl Lit { |
| /// Converts literal token into an AST literal. |
| fn from_lit_token(token: token::Lit, span: Span) -> Result<Lit, LitError> { |
| Ok(Lit { token, node: LitKind::from_lit_token(token)?, span }) |
| } |
| |
| /// Converts arbitrary token into an AST literal. |
| crate fn from_token(token: &Token) -> Result<Lit, LitError> { |
| let lit = match token.kind { |
| token::Ident(name, false) if name == kw::True || name == kw::False => |
| token::Lit::new(token::Bool, name, None), |
| token::Literal(lit) => |
| lit, |
| token::Interpolated(ref nt) => { |
| if let token::NtExpr(expr) | token::NtLiteral(expr) = &**nt { |
| if let ast::ExprKind::Lit(lit) = &expr.node { |
| return Ok(lit.clone()); |
| } |
| } |
| return Err(LitError::NotLiteral); |
| } |
| _ => return Err(LitError::NotLiteral) |
| }; |
| |
| Lit::from_lit_token(lit, token.span) |
| } |
| |
| /// Attempts to recover an AST literal from semantic literal. |
| /// This function is used when the original token doesn't exist (e.g. the literal is created |
| /// by an AST-based macro) or unavailable (e.g. from HIR pretty-printing). |
| pub fn from_lit_kind(node: LitKind, span: Span) -> Lit { |
| Lit { token: node.to_lit_token(), node, span } |
| } |
| |
| /// Losslessly convert an AST literal into a token stream. |
| crate fn tokens(&self) -> TokenStream { |
| let token = match self.token.kind { |
| token::Bool => token::Ident(self.token.symbol, false), |
| _ => token::Literal(self.token), |
| }; |
| TokenTree::token(token, self.span).into() |
| } |
| } |
| |
| impl<'a> Parser<'a> { |
| /// Matches `lit = true | false | token_lit`. |
| crate fn parse_lit(&mut self) -> PResult<'a, Lit> { |
| let mut recovered = None; |
| if self.token == token::Dot { |
| // Attempt to recover `.4` as `0.4`. |
| recovered = self.look_ahead(1, |next_token| { |
| if let token::Literal(token::Lit { kind: token::Integer, symbol, suffix }) |
| = next_token.kind { |
| if self.token.span.hi() == next_token.span.lo() { |
| let s = String::from("0.") + &symbol.as_str(); |
| let kind = TokenKind::lit(token::Float, Symbol::intern(&s), suffix); |
| return Some(Token::new(kind, self.token.span.to(next_token.span))); |
| } |
| } |
| None |
| }); |
| if let Some(token) = &recovered { |
| self.bump(); |
| self.diagnostic() |
| .struct_span_err(token.span, "float literals must have an integer part") |
| .span_suggestion( |
| token.span, |
| "must have an integer part", |
| pprust::token_to_string(token), |
| Applicability::MachineApplicable, |
| ) |
| .emit(); |
| } |
| } |
| |
| let token = recovered.as_ref().unwrap_or(&self.token); |
| match Lit::from_token(token) { |
| Ok(lit) => { |
| self.bump(); |
| Ok(lit) |
| } |
| Err(LitError::NotLiteral) => { |
| let msg = format!("unexpected token: {}", self.this_token_descr()); |
| Err(self.span_fatal(token.span, &msg)) |
| } |
| Err(err) => { |
| let (lit, span) = (token.expect_lit(), token.span); |
| self.bump(); |
| err.report(&self.sess.span_diagnostic, lit, span); |
| // Pack possible quotes and prefixes from the original literal into |
| // the error literal's symbol so they can be pretty-printed faithfully. |
| let suffixless_lit = token::Lit::new(lit.kind, lit.symbol, None); |
| let symbol = Symbol::intern(&suffixless_lit.to_string()); |
| let lit = token::Lit::new(token::Err, symbol, lit.suffix); |
| Lit::from_lit_token(lit, span).map_err(|_| unreachable!()) |
| } |
| } |
| } |
| } |
| |
| crate fn expect_no_suffix(diag: &Handler, sp: Span, kind: &str, suffix: Option<Symbol>) { |
| if let Some(suf) = suffix { |
| let mut err = if kind == "a tuple index" && |
| [sym::i32, sym::u32, sym::isize, sym::usize].contains(&suf) { |
| // #59553: warn instead of reject out of hand to allow the fix to percolate |
| // through the ecosystem when people fix their macros |
| let mut err = diag.struct_span_warn( |
| sp, |
| &format!("suffixes on {} are invalid", kind), |
| ); |
| err.note(&format!( |
| "`{}` is *temporarily* accepted on tuple index fields as it was \ |
| incorrectly accepted on stable for a few releases", |
| suf, |
| )); |
| err.help( |
| "on proc macros, you'll want to use `syn::Index::from` or \ |
| `proc_macro::Literal::*_unsuffixed` for code that will desugar \ |
| to tuple field access", |
| ); |
| err.note( |
| "for more context, see https://github.com/rust-lang/rust/issues/60210", |
| ); |
| err |
| } else { |
| diag.struct_span_err(sp, &format!("suffixes on {} are invalid", kind)) |
| }; |
| err.span_label(sp, format!("invalid suffix `{}`", suf)); |
| err.emit(); |
| } |
| } |
| |
| // Checks if `s` looks like i32 or u1234 etc. |
| fn looks_like_width_suffix(first_chars: &[char], s: &str) -> bool { |
| s.len() > 1 && s.starts_with(first_chars) && s[1..].chars().all(|c| c.is_ascii_digit()) |
| } |
| |
| fn strip_underscores(symbol: Symbol) -> Symbol { |
| // Do not allocate a new string unless necessary. |
| let s = symbol.as_str(); |
| if s.contains('_') { |
| let mut s = s.to_string(); |
| s.retain(|c| c != '_'); |
| return Symbol::intern(&s); |
| } |
| symbol |
| } |
| |
| fn filtered_float_lit(symbol: Symbol, suffix: Option<Symbol>, base: u32) |
| -> Result<LitKind, LitError> { |
| debug!("filtered_float_lit: {:?}, {:?}, {:?}", symbol, suffix, base); |
| if base != 10 { |
| return Err(LitError::NonDecimalFloat(base)); |
| } |
| Ok(match suffix { |
| Some(suf) => match suf { |
| sym::f32 => LitKind::Float(symbol, ast::FloatTy::F32), |
| sym::f64 => LitKind::Float(symbol, ast::FloatTy::F64), |
| _ => return Err(LitError::InvalidFloatSuffix), |
| } |
| None => LitKind::FloatUnsuffixed(symbol) |
| }) |
| } |
| |
| fn float_lit(symbol: Symbol, suffix: Option<Symbol>) -> Result<LitKind, LitError> { |
| debug!("float_lit: {:?}, {:?}", symbol, suffix); |
| filtered_float_lit(strip_underscores(symbol), suffix, 10) |
| } |
| |
| fn integer_lit(symbol: Symbol, suffix: Option<Symbol>) -> Result<LitKind, LitError> { |
| debug!("integer_lit: {:?}, {:?}", symbol, suffix); |
| let symbol = strip_underscores(symbol); |
| let s = symbol.as_str(); |
| |
| let mut base = 10; |
| if s.len() > 1 && s.as_bytes()[0] == b'0' { |
| match s.as_bytes()[1] { |
| b'x' => base = 16, |
| b'o' => base = 8, |
| b'b' => base = 2, |
| _ => {} |
| } |
| } |
| |
| let ty = match suffix { |
| Some(suf) => match suf { |
| sym::isize => ast::LitIntType::Signed(ast::IntTy::Isize), |
| sym::i8 => ast::LitIntType::Signed(ast::IntTy::I8), |
| sym::i16 => ast::LitIntType::Signed(ast::IntTy::I16), |
| sym::i32 => ast::LitIntType::Signed(ast::IntTy::I32), |
| sym::i64 => ast::LitIntType::Signed(ast::IntTy::I64), |
| sym::i128 => ast::LitIntType::Signed(ast::IntTy::I128), |
| sym::usize => ast::LitIntType::Unsigned(ast::UintTy::Usize), |
| sym::u8 => ast::LitIntType::Unsigned(ast::UintTy::U8), |
| sym::u16 => ast::LitIntType::Unsigned(ast::UintTy::U16), |
| sym::u32 => ast::LitIntType::Unsigned(ast::UintTy::U32), |
| sym::u64 => ast::LitIntType::Unsigned(ast::UintTy::U64), |
| sym::u128 => ast::LitIntType::Unsigned(ast::UintTy::U128), |
| // `1f64` and `2f32` etc. are valid float literals, and |
| // `fxxx` looks more like an invalid float literal than invalid integer literal. |
| _ if suf.as_str().starts_with('f') => return filtered_float_lit(symbol, suffix, base), |
| _ => return Err(LitError::InvalidIntSuffix), |
| } |
| _ => ast::LitIntType::Unsuffixed |
| }; |
| |
| let s = &s[if base != 10 { 2 } else { 0 } ..]; |
| u128::from_str_radix(s, base).map(|i| LitKind::Int(i, ty)).map_err(|_| { |
| // Small bases are lexed as if they were base 10, e.g, the string |
| // might be `0b10201`. This will cause the conversion above to fail, |
| // but these kinds of errors are already reported by the lexer. |
| let from_lexer = |
| base < 10 && s.chars().any(|c| c.to_digit(10).map_or(false, |d| d >= base)); |
| if from_lexer { LitError::LexerError } else { LitError::IntTooLarge } |
| }) |
| } |