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//! `tt` crate defines a `TokenTree` data structure: this is the interface (both
//! input and output) of macros. It closely mirrors `proc_macro` crate's
//! `TokenTree`.
#![cfg_attr(feature = "in-rust-tree", feature(rustc_private))]
#[cfg(not(feature = "in-rust-tree"))]
extern crate ra_ap_rustc_lexer as rustc_lexer;
#[cfg(feature = "in-rust-tree")]
extern crate rustc_lexer;
pub mod buffer;
pub mod iter;
use std::fmt;
use intern::Symbol;
use stdx::{impl_from, itertools::Itertools as _};
pub use text_size::{TextRange, TextSize};
#[derive(Clone, PartialEq, Debug)]
pub struct Lit {
pub kind: LitKind,
pub symbol: Symbol,
pub suffix: Option<Symbol>,
}
#[derive(Debug, Copy, Clone, PartialEq, Eq, Hash)]
pub enum IdentIsRaw {
No,
Yes,
}
impl IdentIsRaw {
pub fn yes(self) -> bool {
matches!(self, IdentIsRaw::Yes)
}
pub fn no(&self) -> bool {
matches!(self, IdentIsRaw::No)
}
pub fn as_str(self) -> &'static str {
match self {
IdentIsRaw::No => "",
IdentIsRaw::Yes => "r#",
}
}
pub fn split_from_symbol(sym: &str) -> (Self, &str) {
if let Some(sym) = sym.strip_prefix("r#") {
(IdentIsRaw::Yes, sym)
} else {
(IdentIsRaw::No, sym)
}
}
}
#[derive(Clone, Copy, PartialEq, Eq, Debug, Hash)]
pub enum LitKind {
Byte,
Char,
Integer, // e.g. `1`, `1u8`, `1f32`
Float, // e.g. `1.`, `1.0`, `1e3f32`
Str,
StrRaw(u8), // raw string delimited by `n` hash symbols
ByteStr,
ByteStrRaw(u8), // raw byte string delimited by `n` hash symbols
CStr,
CStrRaw(u8),
Err(()),
}
#[derive(Debug, Clone, PartialEq, Eq, Hash)]
pub enum TokenTree<S = u32> {
Leaf(Leaf<S>),
Subtree(Subtree<S>),
}
impl_from!(Leaf<S>, Subtree<S> for TokenTree);
impl<S: Copy> TokenTree<S> {
pub fn empty(span: S) -> Self {
Self::Subtree(Subtree {
delimiter: Delimiter::invisible_spanned(span),
token_trees: Box::new([]),
})
}
pub fn subtree_or_wrap(self, span: DelimSpan<S>) -> Subtree<S> {
match self {
TokenTree::Leaf(_) => Subtree {
delimiter: Delimiter::invisible_delim_spanned(span),
token_trees: Box::new([self]),
},
TokenTree::Subtree(s) => s,
}
}
pub fn first_span(&self) -> S {
match self {
TokenTree::Leaf(l) => *l.span(),
TokenTree::Subtree(s) => s.delimiter.open,
}
}
}
#[derive(Debug, Clone, PartialEq, Eq, Hash)]
pub enum Leaf<S> {
Literal(Literal<S>),
Punct(Punct<S>),
Ident(Ident<S>),
}
impl<S> Leaf<S> {
pub fn span(&self) -> &S {
match self {
Leaf::Literal(it) => &it.span,
Leaf::Punct(it) => &it.span,
Leaf::Ident(it) => &it.span,
}
}
}
impl_from!(Literal<S>, Punct<S>, Ident<S> for Leaf);
#[derive(Clone, PartialEq, Eq, Hash)]
pub struct Subtree<S> {
pub delimiter: Delimiter<S>,
pub token_trees: Box<[TokenTree<S>]>,
}
impl<S: Copy> Subtree<S> {
pub fn empty(span: DelimSpan<S>) -> Self {
Subtree { delimiter: Delimiter::invisible_delim_spanned(span), token_trees: Box::new([]) }
}
/// This is slow, and should be avoided, as it will always reallocate!
pub fn push(&mut self, subtree: TokenTree<S>) {
let mut mutable_trees = std::mem::take(&mut self.token_trees).into_vec();
// Reserve exactly space for one element, to avoid `into_boxed_slice` having to reallocate again.
mutable_trees.reserve_exact(1);
mutable_trees.push(subtree);
self.token_trees = mutable_trees.into_boxed_slice();
}
}
#[derive(Clone, PartialEq, Eq, Hash)]
pub struct SubtreeBuilder<S> {
pub delimiter: Delimiter<S>,
pub token_trees: Vec<TokenTree<S>>,
}
impl<S> SubtreeBuilder<S> {
pub fn build(self) -> Subtree<S> {
Subtree { delimiter: self.delimiter, token_trees: self.token_trees.into_boxed_slice() }
}
}
#[derive(Debug, Copy, Clone, PartialEq)]
pub struct DelimSpan<S> {
pub open: S,
pub close: S,
}
impl<Span: Copy> DelimSpan<Span> {
pub fn from_single(sp: Span) -> Self {
DelimSpan { open: sp, close: sp }
}
pub fn from_pair(open: Span, close: Span) -> Self {
DelimSpan { open, close }
}
}
#[derive(Clone, Copy, Debug, PartialEq, Eq, Hash)]
pub struct Delimiter<S> {
pub open: S,
pub close: S,
pub kind: DelimiterKind,
}
impl<S: Copy> Delimiter<S> {
pub const fn invisible_spanned(span: S) -> Self {
Delimiter { open: span, close: span, kind: DelimiterKind::Invisible }
}
pub const fn invisible_delim_spanned(span: DelimSpan<S>) -> Self {
Delimiter { open: span.open, close: span.close, kind: DelimiterKind::Invisible }
}
pub fn delim_span(&self) -> DelimSpan<S> {
DelimSpan { open: self.open, close: self.close }
}
}
#[derive(Clone, Copy, Debug, PartialEq, Eq, Hash)]
pub enum DelimiterKind {
Parenthesis,
Brace,
Bracket,
Invisible,
}
#[derive(Debug, Clone, PartialEq, Eq, Hash)]
pub struct Literal<S> {
// escaped
pub symbol: Symbol,
pub span: S,
pub kind: LitKind,
pub suffix: Option<Symbol>,
}
pub fn token_to_literal<S>(text: &str, span: S) -> Literal<S>
where
S: Copy,
{
use rustc_lexer::LiteralKind;
let token = rustc_lexer::tokenize(text).next_tuple();
let Some((rustc_lexer::Token {
kind: rustc_lexer::TokenKind::Literal { kind, suffix_start },
..
},)) = token
else {
return Literal {
span,
symbol: Symbol::intern(text),
kind: LitKind::Err(()),
suffix: None,
};
};
let (kind, start_offset, end_offset) = match kind {
LiteralKind::Int { .. } => (LitKind::Integer, 0, 0),
LiteralKind::Float { .. } => (LitKind::Float, 0, 0),
LiteralKind::Char { terminated } => (LitKind::Char, 1, terminated as usize),
LiteralKind::Byte { terminated } => (LitKind::Byte, 2, terminated as usize),
LiteralKind::Str { terminated } => (LitKind::Str, 1, terminated as usize),
LiteralKind::ByteStr { terminated } => (LitKind::ByteStr, 2, terminated as usize),
LiteralKind::CStr { terminated } => (LitKind::CStr, 2, terminated as usize),
LiteralKind::RawStr { n_hashes } => (
LitKind::StrRaw(n_hashes.unwrap_or_default()),
2 + n_hashes.unwrap_or_default() as usize,
1 + n_hashes.unwrap_or_default() as usize,
),
LiteralKind::RawByteStr { n_hashes } => (
LitKind::ByteStrRaw(n_hashes.unwrap_or_default()),
3 + n_hashes.unwrap_or_default() as usize,
1 + n_hashes.unwrap_or_default() as usize,
),
LiteralKind::RawCStr { n_hashes } => (
LitKind::CStrRaw(n_hashes.unwrap_or_default()),
3 + n_hashes.unwrap_or_default() as usize,
1 + n_hashes.unwrap_or_default() as usize,
),
};
let (lit, suffix) = text.split_at(suffix_start as usize);
let lit = &lit[start_offset..lit.len() - end_offset];
let suffix = match suffix {
"" | "_" => None,
suffix => Some(Symbol::intern(suffix)),
};
Literal { span, symbol: Symbol::intern(lit), kind, suffix }
}
#[derive(Debug, Clone, Copy, PartialEq, Eq, Hash)]
pub struct Punct<S> {
pub char: char,
pub spacing: Spacing,
pub span: S,
}
/// Indicates whether a token can join with the following token to form a
/// compound token. Used for conversions to `proc_macro::Spacing`. Also used to
/// guide pretty-printing, which is where the `JointHidden` value (which isn't
/// part of `proc_macro::Spacing`) comes in useful.
#[derive(Debug, Clone, Copy, PartialEq, Eq, Hash)]
pub enum Spacing {
/// The token cannot join with the following token to form a compound
/// token.
///
/// In token streams parsed from source code, the compiler will use `Alone`
/// for any token immediately followed by whitespace, a non-doc comment, or
/// EOF.
///
/// When constructing token streams within the compiler, use this for each
/// token that (a) should be pretty-printed with a space after it, or (b)
/// is the last token in the stream. (In the latter case the choice of
/// spacing doesn't matter because it is never used for the last token. We
/// arbitrarily use `Alone`.)
///
/// Converts to `proc_macro::Spacing::Alone`, and
/// `proc_macro::Spacing::Alone` converts back to this.
Alone,
/// The token can join with the following token to form a compound token.
///
/// In token streams parsed from source code, the compiler will use `Joint`
/// for any token immediately followed by punctuation (as determined by
/// `Token::is_punct`).
///
/// When constructing token streams within the compiler, use this for each
/// token that (a) should be pretty-printed without a space after it, and
/// (b) is followed by a punctuation token.
///
/// Converts to `proc_macro::Spacing::Joint`, and
/// `proc_macro::Spacing::Joint` converts back to this.
Joint,
/// The token can join with the following token to form a compound token,
/// but this will not be visible at the proc macro level. (This is what the
/// `Hidden` means; see below.)
///
/// In token streams parsed from source code, the compiler will use
/// `JointHidden` for any token immediately followed by anything not
/// covered by the `Alone` and `Joint` cases: an identifier, lifetime,
/// literal, delimiter, doc comment.
///
/// When constructing token streams, use this for each token that (a)
/// should be pretty-printed without a space after it, and (b) is followed
/// by a non-punctuation token.
///
/// Converts to `proc_macro::Spacing::Alone`, but
/// `proc_macro::Spacing::Alone` converts back to `token::Spacing::Alone`.
/// Because of that, pretty-printing of `TokenStream`s produced by proc
/// macros is unavoidably uglier (with more whitespace between tokens) than
/// pretty-printing of `TokenStream`'s produced by other means (i.e. parsed
/// source code, internally constructed token streams, and token streams
/// produced by declarative macros).
JointHidden,
}
/// Identifier or keyword.
#[derive(Debug, Clone, PartialEq, Eq, Hash)]
pub struct Ident<S> {
pub sym: Symbol,
pub span: S,
pub is_raw: IdentIsRaw,
}
impl<S> Ident<S> {
pub fn new(text: &str, span: S) -> Self {
// let raw_stripped = IdentIsRaw::split_from_symbol(text.as_ref());
let (is_raw, text) = IdentIsRaw::split_from_symbol(text);
Ident { sym: Symbol::intern(text), span, is_raw }
}
}
fn print_debug_subtree<S: fmt::Debug>(
f: &mut fmt::Formatter<'_>,
subtree: &Subtree<S>,
level: usize,
) -> fmt::Result {
let align = " ".repeat(level);
let Delimiter { kind, open, close } = &subtree.delimiter;
let delim = match kind {
DelimiterKind::Invisible => "$$",
DelimiterKind::Parenthesis => "()",
DelimiterKind::Brace => "{}",
DelimiterKind::Bracket => "[]",
};
write!(f, "{align}SUBTREE {delim} ",)?;
fmt::Debug::fmt(&open, f)?;
write!(f, " ")?;
fmt::Debug::fmt(&close, f)?;
if !subtree.token_trees.is_empty() {
writeln!(f)?;
for (idx, child) in subtree.token_trees.iter().enumerate() {
print_debug_token(f, child, level + 1)?;
if idx != subtree.token_trees.len() - 1 {
writeln!(f)?;
}
}
}
Ok(())
}
fn print_debug_token<S: fmt::Debug>(
f: &mut fmt::Formatter<'_>,
tkn: &TokenTree<S>,
level: usize,
) -> fmt::Result {
let align = " ".repeat(level);
match tkn {
TokenTree::Leaf(leaf) => match leaf {
Leaf::Literal(lit) => {
write!(
f,
"{}LITERAL {:?} {}{} {:#?}",
align,
lit.kind,
lit.symbol,
lit.suffix.as_ref().map(|it| it.as_str()).unwrap_or(""),
lit.span
)?;
}
Leaf::Punct(punct) => {
write!(
f,
"{}PUNCH {} [{}] {:#?}",
align,
punct.char,
if punct.spacing == Spacing::Alone { "alone" } else { "joint" },
punct.span
)?;
}
Leaf::Ident(ident) => {
write!(
f,
"{}IDENT {}{} {:#?}",
align,
ident.is_raw.as_str(),
ident.sym,
ident.span
)?;
}
},
TokenTree::Subtree(subtree) => {
print_debug_subtree(f, subtree, level)?;
}
}
Ok(())
}
impl<S: fmt::Debug> fmt::Debug for Subtree<S> {
fn fmt(&self, f: &mut fmt::Formatter<'_>) -> fmt::Result {
print_debug_subtree(f, self, 0)
}
}
impl<S> fmt::Display for TokenTree<S> {
fn fmt(&self, f: &mut fmt::Formatter<'_>) -> fmt::Result {
match self {
TokenTree::Leaf(it) => fmt::Display::fmt(it, f),
TokenTree::Subtree(it) => fmt::Display::fmt(it, f),
}
}
}
impl<S> fmt::Display for Subtree<S> {
fn fmt(&self, f: &mut fmt::Formatter<'_>) -> fmt::Result {
let (l, r) = match self.delimiter.kind {
DelimiterKind::Parenthesis => ("(", ")"),
DelimiterKind::Brace => ("{", "}"),
DelimiterKind::Bracket => ("[", "]"),
DelimiterKind::Invisible => ("", ""),
};
f.write_str(l)?;
let mut needs_space = false;
for tt in self.token_trees.iter() {
if needs_space {
f.write_str(" ")?;
}
needs_space = true;
match tt {
TokenTree::Leaf(Leaf::Punct(p)) => {
needs_space = p.spacing == Spacing::Alone;
fmt::Display::fmt(p, f)?;
}
tt => fmt::Display::fmt(tt, f)?,
}
}
f.write_str(r)?;
Ok(())
}
}
impl<S> fmt::Display for Leaf<S> {
fn fmt(&self, f: &mut fmt::Formatter<'_>) -> fmt::Result {
match self {
Leaf::Ident(it) => fmt::Display::fmt(it, f),
Leaf::Literal(it) => fmt::Display::fmt(it, f),
Leaf::Punct(it) => fmt::Display::fmt(it, f),
}
}
}
impl<S> fmt::Display for Ident<S> {
fn fmt(&self, f: &mut fmt::Formatter<'_>) -> fmt::Result {
fmt::Display::fmt(&self.is_raw.as_str(), f)?;
fmt::Display::fmt(&self.sym, f)
}
}
impl<S> fmt::Display for Literal<S> {
fn fmt(&self, f: &mut fmt::Formatter<'_>) -> fmt::Result {
match self.kind {
LitKind::Byte => write!(f, "b'{}'", self.symbol),
LitKind::Char => write!(f, "'{}'", self.symbol),
LitKind::Integer | LitKind::Float | LitKind::Err(_) => write!(f, "{}", self.symbol),
LitKind::Str => write!(f, "\"{}\"", self.symbol),
LitKind::ByteStr => write!(f, "b\"{}\"", self.symbol),
LitKind::CStr => write!(f, "c\"{}\"", self.symbol),
LitKind::StrRaw(num_of_hashes) => {
let num_of_hashes = num_of_hashes as usize;
write!(
f,
r#"r{0:#<num_of_hashes$}"{text}"{0:#<num_of_hashes$}"#,
"",
text = self.symbol
)
}
LitKind::ByteStrRaw(num_of_hashes) => {
let num_of_hashes = num_of_hashes as usize;
write!(
f,
r#"br{0:#<num_of_hashes$}"{text}"{0:#<num_of_hashes$}"#,
"",
text = self.symbol
)
}
LitKind::CStrRaw(num_of_hashes) => {
let num_of_hashes = num_of_hashes as usize;
write!(
f,
r#"cr{0:#<num_of_hashes$}"{text}"{0:#<num_of_hashes$}"#,
"",
text = self.symbol
)
}
}?;
if let Some(suffix) = &self.suffix {
write!(f, "{}", suffix)?;
}
Ok(())
}
}
impl<S> fmt::Display for Punct<S> {
fn fmt(&self, f: &mut fmt::Formatter<'_>) -> fmt::Result {
fmt::Display::fmt(&self.char, f)
}
}
impl<S> Subtree<S> {
/// Count the number of tokens recursively
pub fn count(&self) -> usize {
let children_count = self
.token_trees
.iter()
.map(|c| match c {
TokenTree::Subtree(c) => c.count(),
TokenTree::Leaf(_) => 0,
})
.sum::<usize>();
self.token_trees.len() + children_count
}
}
impl<S> Subtree<S> {
/// A simple line string used for debugging
pub fn as_debug_string(&self) -> String {
let delim = match self.delimiter.kind {
DelimiterKind::Brace => ("{", "}"),
DelimiterKind::Bracket => ("[", "]"),
DelimiterKind::Parenthesis => ("(", ")"),
DelimiterKind::Invisible => ("$", "$"),
};
let mut res = String::new();
res.push_str(delim.0);
let mut last = None;
for child in self.token_trees.iter() {
let s = match child {
TokenTree::Leaf(it) => {
let s = match it {
Leaf::Literal(it) => it.symbol.to_string(),
Leaf::Punct(it) => it.char.to_string(),
Leaf::Ident(it) => format!("{}{}", it.is_raw.as_str(), it.sym),
};
match (it, last) {
(Leaf::Ident(_), Some(&TokenTree::Leaf(Leaf::Ident(_)))) => {
" ".to_owned() + &s
}
(Leaf::Punct(_), Some(TokenTree::Leaf(Leaf::Punct(punct)))) => {
if punct.spacing == Spacing::Alone {
" ".to_owned() + &s
} else {
s
}
}
_ => s,
}
}
TokenTree::Subtree(it) => it.as_debug_string(),
};
res.push_str(&s);
last = Some(child);
}
res.push_str(delim.1);
res
}
}
pub fn pretty<S>(tkns: &[TokenTree<S>]) -> String {
fn tokentree_to_text<S>(tkn: &TokenTree<S>) -> String {
match tkn {
TokenTree::Leaf(Leaf::Ident(ident)) => {
format!("{}{}", ident.is_raw.as_str(), ident.sym)
}
TokenTree::Leaf(Leaf::Literal(literal)) => format!("{literal}"),
TokenTree::Leaf(Leaf::Punct(punct)) => format!("{}", punct.char),
TokenTree::Subtree(subtree) => {
let content = pretty(&subtree.token_trees);
let (open, close) = match subtree.delimiter.kind {
DelimiterKind::Brace => ("{", "}"),
DelimiterKind::Bracket => ("[", "]"),
DelimiterKind::Parenthesis => ("(", ")"),
DelimiterKind::Invisible => ("", ""),
};
format!("{open}{content}{close}")
}
}
}
tkns.iter()
.fold((String::new(), true), |(last, last_to_joint), tkn| {
let s = [last, tokentree_to_text(tkn)].join(if last_to_joint { "" } else { " " });
let mut is_joint = false;
if let TokenTree::Leaf(Leaf::Punct(punct)) = tkn {
if punct.spacing == Spacing::Joint {
is_joint = true;
}
}
(s, is_joint)
})
.0
}