//! # Token Streams //! //! `TokenStream`s represent syntactic objects before they are converted into ASTs. //! A `TokenStream` is, roughly speaking, a sequence of [`TokenTree`]s, //! which are themselves a single [`Token`] or a `Delimited` subsequence of tokens. //! //! ## Ownership //! //! `TokenStream`s are persistent data structures constructed as ropes with reference //! counted-children. In general, this means that calling an operation on a `TokenStream` //! (such as `slice`) produces an entirely new `TokenStream` from the borrowed reference to //! the original. This essentially coerces `TokenStream`s into "views" of their subparts, //! and a borrowed `TokenStream` is sufficient to build an owned `TokenStream` without taking //! ownership of the original. use std::borrow::Cow; use std::sync::Arc; use std::{cmp, fmt, iter}; use rustc_data_structures::stable_hasher::{HashStable, StableHasher}; use rustc_data_structures::sync; use rustc_macros::{Decodable, Encodable, HashStable_Generic}; use rustc_serialize::{Decodable, Encodable}; use rustc_span::{DUMMY_SP, Span, SpanDecoder, SpanEncoder, Symbol, sym}; use crate::ast::AttrStyle; use crate::ast_traits::{HasAttrs, HasTokens}; use crate::token::{self, Delimiter, InvisibleOrigin, Nonterminal, Token, TokenKind}; use crate::{AttrVec, Attribute}; /// Part of a `TokenStream`. #[derive(Debug, Clone, PartialEq, Encodable, Decodable, HashStable_Generic)] pub enum TokenTree { /// A single token. Should never be `OpenDelim` or `CloseDelim`, because /// delimiters are implicitly represented by `Delimited`. Token(Token, Spacing), /// A delimited sequence of token trees. Delimited(DelimSpan, DelimSpacing, Delimiter, TokenStream), } // Ensure all fields of `TokenTree` are `DynSend` and `DynSync`. fn _dummy() where Token: sync::DynSend + sync::DynSync, Spacing: sync::DynSend + sync::DynSync, DelimSpan: sync::DynSend + sync::DynSync, Delimiter: sync::DynSend + sync::DynSync, TokenStream: sync::DynSend + sync::DynSync, { } impl TokenTree { /// Checks if this `TokenTree` is equal to the other, regardless of span/spacing information. pub fn eq_unspanned(&self, other: &TokenTree) -> bool { match (self, other) { (TokenTree::Token(token, _), TokenTree::Token(token2, _)) => token.kind == token2.kind, (TokenTree::Delimited(.., delim, tts), TokenTree::Delimited(.., delim2, tts2)) => { delim == delim2 && tts.eq_unspanned(tts2) } _ => false, } } /// Retrieves the `TokenTree`'s span. pub fn span(&self) -> Span { match self { TokenTree::Token(token, _) => token.span, TokenTree::Delimited(sp, ..) => sp.entire(), } } /// Create a `TokenTree::Token` with alone spacing. pub fn token_alone(kind: TokenKind, span: Span) -> TokenTree { TokenTree::Token(Token::new(kind, span), Spacing::Alone) } /// Create a `TokenTree::Token` with joint spacing. pub fn token_joint(kind: TokenKind, span: Span) -> TokenTree { TokenTree::Token(Token::new(kind, span), Spacing::Joint) } /// Create a `TokenTree::Token` with joint-hidden spacing. pub fn token_joint_hidden(kind: TokenKind, span: Span) -> TokenTree { TokenTree::Token(Token::new(kind, span), Spacing::JointHidden) } pub fn uninterpolate(&self) -> Cow<'_, TokenTree> { match self { TokenTree::Token(token, spacing) => match token.uninterpolate() { Cow::Owned(token) => Cow::Owned(TokenTree::Token(token, *spacing)), Cow::Borrowed(_) => Cow::Borrowed(self), }, _ => Cow::Borrowed(self), } } } impl HashStable for TokenStream where CTX: crate::HashStableContext, { fn hash_stable(&self, hcx: &mut CTX, hasher: &mut StableHasher) { for sub_tt in self.iter() { sub_tt.hash_stable(hcx, hasher); } } } pub trait ToAttrTokenStream: sync::DynSend + sync::DynSync { fn to_attr_token_stream(&self) -> AttrTokenStream; } impl ToAttrTokenStream for AttrTokenStream { fn to_attr_token_stream(&self) -> AttrTokenStream { self.clone() } } /// A lazy version of [`TokenStream`], which defers creation /// of an actual `TokenStream` until it is needed. /// `Box` is here only to reduce the structure size. #[derive(Clone)] pub struct LazyAttrTokenStream(Arc>); impl LazyAttrTokenStream { pub fn new(inner: impl ToAttrTokenStream + 'static) -> LazyAttrTokenStream { LazyAttrTokenStream(Arc::new(Box::new(inner))) } pub fn to_attr_token_stream(&self) -> AttrTokenStream { self.0.to_attr_token_stream() } } impl fmt::Debug for LazyAttrTokenStream { fn fmt(&self, f: &mut fmt::Formatter<'_>) -> fmt::Result { write!(f, "LazyAttrTokenStream({:?})", self.to_attr_token_stream()) } } impl Encodable for LazyAttrTokenStream { fn encode(&self, _s: &mut S) { panic!("Attempted to encode LazyAttrTokenStream"); } } impl Decodable for LazyAttrTokenStream { fn decode(_d: &mut D) -> Self { panic!("Attempted to decode LazyAttrTokenStream"); } } impl HashStable for LazyAttrTokenStream { fn hash_stable(&self, _hcx: &mut CTX, _hasher: &mut StableHasher) { panic!("Attempted to compute stable hash for LazyAttrTokenStream"); } } /// An `AttrTokenStream` is similar to a `TokenStream`, but with extra /// information about the tokens for attribute targets. This is used /// during expansion to perform early cfg-expansion, and to process attributes /// during proc-macro invocations. #[derive(Clone, Debug, Default, Encodable, Decodable)] pub struct AttrTokenStream(pub Arc>); /// Like `TokenTree`, but for `AttrTokenStream`. #[derive(Clone, Debug, Encodable, Decodable)] pub enum AttrTokenTree { Token(Token, Spacing), Delimited(DelimSpan, DelimSpacing, Delimiter, AttrTokenStream), /// Stores the attributes for an attribute target, /// along with the tokens for that attribute target. /// See `AttrsTarget` for more information AttrsTarget(AttrsTarget), } impl AttrTokenStream { pub fn new(tokens: Vec) -> AttrTokenStream { AttrTokenStream(Arc::new(tokens)) } /// Converts this `AttrTokenStream` to a plain `Vec`. During /// conversion, any `AttrTokenTree::AttrsTarget` gets "flattened" back to a /// `TokenStream`, as described in the comment on /// `attrs_and_tokens_to_token_trees`. pub fn to_token_trees(&self) -> Vec { let mut res = Vec::with_capacity(self.0.len()); for tree in self.0.iter() { match tree { AttrTokenTree::Token(inner, spacing) => { res.push(TokenTree::Token(inner.clone(), *spacing)); } AttrTokenTree::Delimited(span, spacing, delim, stream) => { res.push(TokenTree::Delimited( *span, *spacing, *delim, TokenStream::new(stream.to_token_trees()), )) } AttrTokenTree::AttrsTarget(target) => { attrs_and_tokens_to_token_trees(&target.attrs, &target.tokens, &mut res); } } } res } } // Converts multiple attributes and the tokens for a target AST node into token trees, and appends // them to `res`. // // Example: if the AST node is "fn f() { blah(); }", then: // - Simple if no attributes are present, e.g. "fn f() { blah(); }" // - Simple if only outer attribute are present, e.g. "#[outer1] #[outer2] fn f() { blah(); }" // - Trickier if inner attributes are present, because they must be moved within the AST node's // tokens, e.g. "#[outer] fn f() { #![inner] blah() }" fn attrs_and_tokens_to_token_trees( attrs: &[Attribute], target_tokens: &LazyAttrTokenStream, res: &mut Vec, ) { let idx = attrs.partition_point(|attr| matches!(attr.style, crate::AttrStyle::Outer)); let (outer_attrs, inner_attrs) = attrs.split_at(idx); // Add outer attribute tokens. for attr in outer_attrs { res.extend(attr.token_trees()); } // Add target AST node tokens. res.extend(target_tokens.to_attr_token_stream().to_token_trees()); // Insert inner attribute tokens. if !inner_attrs.is_empty() { let found = insert_inner_attrs(inner_attrs, res); assert!(found, "Failed to find trailing delimited group in: {res:?}"); } // Inner attributes are only supported on blocks, functions, impls, and // modules. All of these have their inner attributes placed at the // beginning of the rightmost outermost braced group: // e.g. `fn foo() { #![my_attr] }`. (Note: the braces may be within // invisible delimiters.) // // Therefore, we can insert them back into the right location without // needing to do any extra position tracking. // // Note: Outline modules are an exception - they can have attributes like // `#![my_attr]` at the start of a file. Support for custom attributes in // this position is not properly implemented - we always synthesize fake // tokens, so we never reach this code. fn insert_inner_attrs(inner_attrs: &[Attribute], tts: &mut Vec) -> bool { for tree in tts.iter_mut().rev() { if let TokenTree::Delimited(span, spacing, Delimiter::Brace, stream) = tree { // Found it: the rightmost, outermost braced group. let mut tts = vec![]; for inner_attr in inner_attrs { tts.extend(inner_attr.token_trees()); } tts.extend(stream.0.iter().cloned()); let stream = TokenStream::new(tts); *tree = TokenTree::Delimited(*span, *spacing, Delimiter::Brace, stream); return true; } else if let TokenTree::Delimited(span, spacing, Delimiter::Invisible(src), stream) = tree { // Recurse inside invisible delimiters. let mut vec: Vec<_> = stream.iter().cloned().collect(); if insert_inner_attrs(inner_attrs, &mut vec) { *tree = TokenTree::Delimited( *span, *spacing, Delimiter::Invisible(*src), TokenStream::new(vec), ); return true; } } } false } } /// Stores the tokens for an attribute target, along /// with its attributes. /// /// This is constructed during parsing when we need to capture /// tokens, for `cfg` and `cfg_attr` attributes. /// /// For example, `#[cfg(FALSE)] struct Foo {}` would /// have an `attrs` field containing the `#[cfg(FALSE)]` attr, /// and a `tokens` field storing the (unparsed) tokens `struct Foo {}` /// /// The `cfg`/`cfg_attr` processing occurs in /// `StripUnconfigured::configure_tokens`. #[derive(Clone, Debug, Encodable, Decodable)] pub struct AttrsTarget { /// Attributes, both outer and inner. /// These are stored in the original order that they were parsed in. pub attrs: AttrVec, /// The underlying tokens for the attribute target that `attrs` /// are applied to pub tokens: LazyAttrTokenStream, } /// A `TokenStream` is an abstract sequence of tokens, organized into [`TokenTree`]s. /// /// The goal is for procedural macros to work with `TokenStream`s and `TokenTree`s /// instead of a representation of the abstract syntax tree. /// Today's `TokenTree`s can still contain AST via `token::Interpolated` for /// backwards compatibility. #[derive(Clone, Debug, Default, Encodable, Decodable)] pub struct TokenStream(pub(crate) Arc>); /// 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(Clone, Copy, Debug, PartialEq, Encodable, Decodable, HashStable_Generic)] 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, } impl TokenStream { /// Given a `TokenStream` with a `Stream` of only two arguments, return a new `TokenStream` /// separating the two arguments with a comma for diagnostic suggestions. pub fn add_comma(&self) -> Option<(TokenStream, Span)> { // Used to suggest if a user writes `foo!(a b);` let mut suggestion = None; let mut iter = self.0.iter().enumerate().peekable(); while let Some((pos, ts)) = iter.next() { if let Some((_, next)) = iter.peek() { let sp = match (&ts, &next) { (_, TokenTree::Token(Token { kind: token::Comma, .. }, _)) => continue, ( TokenTree::Token(token_left, Spacing::Alone), TokenTree::Token(token_right, _), ) if ((token_left.is_ident() && !token_left.is_reserved_ident()) || token_left.is_lit()) && ((token_right.is_ident() && !token_right.is_reserved_ident()) || token_right.is_lit()) => { token_left.span } (TokenTree::Delimited(sp, ..), _) => sp.entire(), _ => continue, }; let sp = sp.shrink_to_hi(); let comma = TokenTree::token_alone(token::Comma, sp); suggestion = Some((pos, comma, sp)); } } if let Some((pos, comma, sp)) = suggestion { let mut new_stream = Vec::with_capacity(self.0.len() + 1); let parts = self.0.split_at(pos + 1); new_stream.extend_from_slice(parts.0); new_stream.push(comma); new_stream.extend_from_slice(parts.1); return Some((TokenStream::new(new_stream), sp)); } None } } impl FromIterator for TokenStream { fn from_iter>(iter: I) -> Self { TokenStream::new(iter.into_iter().collect::>()) } } impl Eq for TokenStream {} impl PartialEq for TokenStream { fn eq(&self, other: &TokenStream) -> bool { self.iter().eq(other.iter()) } } impl TokenStream { pub fn new(tts: Vec) -> TokenStream { TokenStream(Arc::new(tts)) } pub fn is_empty(&self) -> bool { self.0.is_empty() } pub fn len(&self) -> usize { self.0.len() } pub fn get(&self, index: usize) -> Option<&TokenTree> { self.0.get(index) } pub fn iter(&self) -> TokenStreamIter<'_> { TokenStreamIter::new(self) } /// Compares two `TokenStream`s, checking equality without regarding span information. pub fn eq_unspanned(&self, other: &TokenStream) -> bool { let mut iter1 = self.iter(); let mut iter2 = other.iter(); for (tt1, tt2) in iter::zip(&mut iter1, &mut iter2) { if !tt1.eq_unspanned(tt2) { return false; } } iter1.next().is_none() && iter2.next().is_none() } /// Create a token stream containing a single token with alone spacing. The /// spacing used for the final token in a constructed stream doesn't matter /// because it's never used. In practice we arbitrarily use /// `Spacing::Alone`. pub fn token_alone(kind: TokenKind, span: Span) -> TokenStream { TokenStream::new(vec![TokenTree::token_alone(kind, span)]) } pub fn from_ast(node: &(impl HasAttrs + HasTokens + fmt::Debug)) -> TokenStream { let tokens = node.tokens().unwrap_or_else(|| panic!("missing tokens for node: {:?}", node)); let mut tts = vec![]; attrs_and_tokens_to_token_trees(node.attrs(), tokens, &mut tts); TokenStream::new(tts) } pub fn from_nonterminal_ast(nt: &Nonterminal) -> TokenStream { match nt { Nonterminal::NtBlock(block) => TokenStream::from_ast(block), } } fn flatten_token(token: &Token, spacing: Spacing) -> TokenTree { match token.kind { token::NtIdent(ident, is_raw) => { TokenTree::Token(Token::new(token::Ident(ident.name, is_raw), ident.span), spacing) } token::NtLifetime(ident, is_raw) => TokenTree::Delimited( DelimSpan::from_single(token.span), DelimSpacing::new(Spacing::JointHidden, spacing), Delimiter::Invisible(InvisibleOrigin::FlattenToken), TokenStream::token_alone(token::Lifetime(ident.name, is_raw), ident.span), ), token::Interpolated(ref nt) => TokenTree::Delimited( DelimSpan::from_single(token.span), DelimSpacing::new(Spacing::JointHidden, spacing), Delimiter::Invisible(InvisibleOrigin::FlattenToken), TokenStream::from_nonterminal_ast(&nt).flattened(), ), _ => TokenTree::Token(token.clone(), spacing), } } fn flatten_token_tree(tree: &TokenTree) -> TokenTree { match tree { TokenTree::Token(token, spacing) => TokenStream::flatten_token(token, *spacing), TokenTree::Delimited(span, spacing, delim, tts) => { TokenTree::Delimited(*span, *spacing, *delim, tts.flattened()) } } } #[must_use] pub fn flattened(&self) -> TokenStream { fn can_skip(stream: &TokenStream) -> bool { stream.iter().all(|tree| match tree { TokenTree::Token(token, _) => !matches!( token.kind, token::NtIdent(..) | token::NtLifetime(..) | token::Interpolated(..) ), TokenTree::Delimited(.., inner) => can_skip(inner), }) } if can_skip(self) { return self.clone(); } self.iter().map(|tree| TokenStream::flatten_token_tree(tree)).collect() } // If `vec` is not empty, try to glue `tt` onto its last token. The return // value indicates if gluing took place. fn try_glue_to_last(vec: &mut Vec, tt: &TokenTree) -> bool { if let Some(TokenTree::Token(last_tok, Spacing::Joint | Spacing::JointHidden)) = vec.last() && let TokenTree::Token(tok, spacing) = tt && let Some(glued_tok) = last_tok.glue(tok) { // ...then overwrite the last token tree in `vec` with the // glued token, and skip the first token tree from `stream`. *vec.last_mut().unwrap() = TokenTree::Token(glued_tok, *spacing); true } else { false } } /// Push `tt` onto the end of the stream, possibly gluing it to the last /// token. Uses `make_mut` to maximize efficiency. pub fn push_tree(&mut self, tt: TokenTree) { let vec_mut = Arc::make_mut(&mut self.0); if Self::try_glue_to_last(vec_mut, &tt) { // nothing else to do } else { vec_mut.push(tt); } } /// Push `stream` onto the end of the stream, possibly gluing the first /// token tree to the last token. (No other token trees will be glued.) /// Uses `make_mut` to maximize efficiency. pub fn push_stream(&mut self, stream: TokenStream) { let vec_mut = Arc::make_mut(&mut self.0); let stream_iter = stream.0.iter().cloned(); if let Some(first) = stream.0.first() && Self::try_glue_to_last(vec_mut, first) { // Now skip the first token tree from `stream`. vec_mut.extend(stream_iter.skip(1)); } else { // Append all of `stream`. vec_mut.extend(stream_iter); } } pub fn chunks(&self, chunk_size: usize) -> core::slice::Chunks<'_, TokenTree> { self.0.chunks(chunk_size) } /// Desugar doc comments like `/// foo` in the stream into `#[doc = /// r"foo"]`. Modifies the `TokenStream` via `Arc::make_mut`, but as little /// as possible. pub fn desugar_doc_comments(&mut self) { if let Some(desugared_stream) = desugar_inner(self.clone()) { *self = desugared_stream; } // The return value is `None` if nothing in `stream` changed. fn desugar_inner(mut stream: TokenStream) -> Option { let mut i = 0; let mut modified = false; while let Some(tt) = stream.0.get(i) { match tt { &TokenTree::Token( Token { kind: token::DocComment(_, attr_style, data), span }, _spacing, ) => { let desugared = desugared_tts(attr_style, data, span); let desugared_len = desugared.len(); Arc::make_mut(&mut stream.0).splice(i..i + 1, desugared); modified = true; i += desugared_len; } &TokenTree::Token(..) => i += 1, &TokenTree::Delimited(sp, spacing, delim, ref delim_stream) => { if let Some(desugared_delim_stream) = desugar_inner(delim_stream.clone()) { let new_tt = TokenTree::Delimited(sp, spacing, delim, desugared_delim_stream); Arc::make_mut(&mut stream.0)[i] = new_tt; modified = true; } i += 1; } } } if modified { Some(stream) } else { None } } fn desugared_tts(attr_style: AttrStyle, data: Symbol, span: Span) -> Vec { // Searches for the occurrences of `"#*` and returns the minimum number of `#`s // required to wrap the text. E.g. // - `abc d` is wrapped as `r"abc d"` (num_of_hashes = 0) // - `abc "d"` is wrapped as `r#"abc "d""#` (num_of_hashes = 1) // - `abc "##d##"` is wrapped as `r###"abc ##"d"##"###` (num_of_hashes = 3) let mut num_of_hashes = 0; let mut count = 0; for ch in data.as_str().chars() { count = match ch { '"' => 1, '#' if count > 0 => count + 1, _ => 0, }; num_of_hashes = cmp::max(num_of_hashes, count); } // `/// foo` becomes `[doc = r"foo"]`. let delim_span = DelimSpan::from_single(span); let body = TokenTree::Delimited( delim_span, DelimSpacing::new(Spacing::JointHidden, Spacing::Alone), Delimiter::Bracket, [ TokenTree::token_alone(token::Ident(sym::doc, token::IdentIsRaw::No), span), TokenTree::token_alone(token::Eq, span), TokenTree::token_alone( TokenKind::lit(token::StrRaw(num_of_hashes), data, None), span, ), ] .into_iter() .collect::(), ); if attr_style == AttrStyle::Inner { vec![ TokenTree::token_joint(token::Pound, span), TokenTree::token_joint_hidden(token::Bang, span), body, ] } else { vec![TokenTree::token_joint_hidden(token::Pound, span), body] } } } } #[derive(Clone)] pub struct TokenStreamIter<'t> { stream: &'t TokenStream, index: usize, } impl<'t> TokenStreamIter<'t> { fn new(stream: &'t TokenStream) -> Self { TokenStreamIter { stream, index: 0 } } // Peeking could be done via `Peekable`, but most iterators need peeking, // and this is simple and avoids the need to use `peekable` and `Peekable` // at all the use sites. pub fn peek(&self) -> Option<&'t TokenTree> { self.stream.0.get(self.index) } } impl<'t> Iterator for TokenStreamIter<'t> { type Item = &'t TokenTree; fn next(&mut self) -> Option<&'t TokenTree> { self.stream.0.get(self.index).map(|tree| { self.index += 1; tree }) } } #[derive(Debug, Copy, Clone, PartialEq, Encodable, Decodable, HashStable_Generic)] pub struct DelimSpan { pub open: Span, pub close: Span, } impl DelimSpan { pub fn from_single(sp: Span) -> Self { DelimSpan { open: sp, close: sp } } pub fn from_pair(open: Span, close: Span) -> Self { DelimSpan { open, close } } pub fn dummy() -> Self { Self::from_single(DUMMY_SP) } pub fn entire(self) -> Span { self.open.with_hi(self.close.hi()) } } #[derive(Copy, Clone, Debug, PartialEq, Encodable, Decodable, HashStable_Generic)] pub struct DelimSpacing { pub open: Spacing, pub close: Spacing, } impl DelimSpacing { pub fn new(open: Spacing, close: Spacing) -> DelimSpacing { DelimSpacing { open, close } } } // Some types are used a lot. Make sure they don't unintentionally get bigger. #[cfg(target_pointer_width = "64")] mod size_asserts { use rustc_data_structures::static_assert_size; use super::*; // tidy-alphabetical-start static_assert_size!(AttrTokenStream, 8); static_assert_size!(AttrTokenTree, 32); static_assert_size!(LazyAttrTokenStream, 8); static_assert_size!(Option, 8); // must be small, used in many AST nodes static_assert_size!(TokenStream, 8); static_assert_size!(TokenTree, 32); // tidy-alphabetical-end }