rustc_ast/
ast.rs

1//! The Rust abstract syntax tree module.
2//!
3//! This module contains common structures forming the language AST.
4//! Two main entities in the module are [`Item`] (which represents an AST element with
5//! additional metadata), and [`ItemKind`] (which represents a concrete type and contains
6//! information specific to the type of the item).
7//!
8//! Other module items worth mentioning:
9//! - [`Ty`] and [`TyKind`]: A parsed Rust type.
10//! - [`Expr`] and [`ExprKind`]: A parsed Rust expression.
11//! - [`Pat`] and [`PatKind`]: A parsed Rust pattern. Patterns are often dual to expressions.
12//! - [`Stmt`] and [`StmtKind`]: An executable action that does not return a value.
13//! - [`FnDecl`], [`FnHeader`] and [`Param`]: Metadata associated with a function declaration.
14//! - [`Generics`], [`GenericParam`], [`WhereClause`]: Metadata associated with generic parameters.
15//! - [`EnumDef`] and [`Variant`]: Enum declaration.
16//! - [`MetaItemLit`] and [`LitKind`]: Literal expressions.
17//! - [`MacroDef`], [`MacStmtStyle`], [`MacCall`]: Macro definition and invocation.
18//! - [`Attribute`]: Metadata associated with item.
19//! - [`UnOp`], [`BinOp`], and [`BinOpKind`]: Unary and binary operators.
20
21use std::borrow::Cow;
22use std::sync::Arc;
23use std::{cmp, fmt};
24
25pub use GenericArgs::*;
26pub use UnsafeSource::*;
27pub use rustc_ast_ir::{Movability, Mutability, Pinnedness};
28use rustc_data_structures::packed::Pu128;
29use rustc_data_structures::stable_hasher::{HashStable, StableHasher};
30use rustc_data_structures::stack::ensure_sufficient_stack;
31use rustc_data_structures::tagged_ptr::Tag;
32use rustc_macros::{Decodable, Encodable, HashStable_Generic};
33pub use rustc_span::AttrId;
34use rustc_span::source_map::{Spanned, respan};
35use rustc_span::{DUMMY_SP, ErrorGuaranteed, Ident, Span, Symbol, kw, sym};
36use thin_vec::{ThinVec, thin_vec};
37
38pub use crate::format::*;
39use crate::ptr::P;
40use crate::token::{self, CommentKind, Delimiter};
41use crate::tokenstream::{DelimSpan, LazyAttrTokenStream, TokenStream};
42use crate::util::parser::{ExprPrecedence, Fixity};
43
44/// A "Label" is an identifier of some point in sources,
45/// e.g. in the following code:
46///
47/// ```rust
48/// 'outer: loop {
49///     break 'outer;
50/// }
51/// ```
52///
53/// `'outer` is a label.
54#[derive(Clone, Encodable, Decodable, Copy, HashStable_Generic, Eq, PartialEq)]
55pub struct Label {
56    pub ident: Ident,
57}
58
59impl fmt::Debug for Label {
60    fn fmt(&self, f: &mut fmt::Formatter<'_>) -> fmt::Result {
61        write!(f, "label({:?})", self.ident)
62    }
63}
64
65/// A "Lifetime" is an annotation of the scope in which variable
66/// can be used, e.g. `'a` in `&'a i32`.
67#[derive(Clone, Encodable, Decodable, Copy, PartialEq, Eq, Hash)]
68pub struct Lifetime {
69    pub id: NodeId,
70    pub ident: Ident,
71}
72
73impl fmt::Debug for Lifetime {
74    fn fmt(&self, f: &mut fmt::Formatter<'_>) -> fmt::Result {
75        write!(f, "lifetime({}: {})", self.id, self)
76    }
77}
78
79impl fmt::Display for Lifetime {
80    fn fmt(&self, f: &mut fmt::Formatter<'_>) -> fmt::Result {
81        write!(f, "{}", self.ident.name)
82    }
83}
84
85/// A "Path" is essentially Rust's notion of a name.
86///
87/// It's represented as a sequence of identifiers,
88/// along with a bunch of supporting information.
89///
90/// E.g., `std::cmp::PartialEq`.
91#[derive(Clone, Encodable, Decodable, Debug)]
92pub struct Path {
93    pub span: Span,
94    /// The segments in the path: the things separated by `::`.
95    /// Global paths begin with `kw::PathRoot`.
96    pub segments: ThinVec<PathSegment>,
97    pub tokens: Option<LazyAttrTokenStream>,
98}
99
100// Succeeds if the path has a single segment that is arg-free and matches the given symbol.
101impl PartialEq<Symbol> for Path {
102    #[inline]
103    fn eq(&self, name: &Symbol) -> bool {
104        if let [segment] = self.segments.as_ref()
105            && segment == name
106        {
107            true
108        } else {
109            false
110        }
111    }
112}
113
114// Succeeds if the path has segments that are arg-free and match the given symbols.
115impl PartialEq<&[Symbol]> for Path {
116    #[inline]
117    fn eq(&self, names: &&[Symbol]) -> bool {
118        self.segments.len() == names.len()
119            && self.segments.iter().zip(names.iter()).all(|(s1, s2)| s1 == s2)
120    }
121}
122
123impl<CTX: rustc_span::HashStableContext> HashStable<CTX> for Path {
124    fn hash_stable(&self, hcx: &mut CTX, hasher: &mut StableHasher) {
125        self.segments.len().hash_stable(hcx, hasher);
126        for segment in &self.segments {
127            segment.ident.hash_stable(hcx, hasher);
128        }
129    }
130}
131
132impl Path {
133    /// Convert a span and an identifier to the corresponding
134    /// one-segment path.
135    pub fn from_ident(ident: Ident) -> Path {
136        Path { segments: thin_vec![PathSegment::from_ident(ident)], span: ident.span, tokens: None }
137    }
138
139    pub fn is_global(&self) -> bool {
140        self.segments.first().is_some_and(|segment| segment.ident.name == kw::PathRoot)
141    }
142
143    /// Check if this path is potentially a trivial const arg, i.e., one that can _potentially_
144    /// be represented without an anon const in the HIR.
145    ///
146    /// If `allow_mgca_arg` is true (as should be the case in most situations when
147    /// `#![feature(min_generic_const_args)]` is enabled), then this always returns true
148    /// because all paths are valid.
149    ///
150    /// Otherwise, it returns true iff the path has exactly one segment, and it has no generic args
151    /// (i.e., it is _potentially_ a const parameter).
152    #[tracing::instrument(level = "debug", ret)]
153    pub fn is_potential_trivial_const_arg(&self, allow_mgca_arg: bool) -> bool {
154        allow_mgca_arg
155            || self.segments.len() == 1 && self.segments.iter().all(|seg| seg.args.is_none())
156    }
157}
158
159/// A segment of a path: an identifier, an optional lifetime, and a set of types.
160///
161/// E.g., `std`, `String` or `Box<T>`.
162#[derive(Clone, Encodable, Decodable, Debug)]
163pub struct PathSegment {
164    /// The identifier portion of this path segment.
165    pub ident: Ident,
166
167    pub id: NodeId,
168
169    /// Type/lifetime parameters attached to this path. They come in
170    /// two flavors: `Path<A,B,C>` and `Path(A,B) -> C`.
171    /// `None` means that no parameter list is supplied (`Path`),
172    /// `Some` means that parameter list is supplied (`Path<X, Y>`)
173    /// but it can be empty (`Path<>`).
174    /// `P` is used as a size optimization for the common case with no parameters.
175    pub args: Option<P<GenericArgs>>,
176}
177
178// Succeeds if the path segment is arg-free and matches the given symbol.
179impl PartialEq<Symbol> for PathSegment {
180    #[inline]
181    fn eq(&self, name: &Symbol) -> bool {
182        self.args.is_none() && self.ident.name == *name
183    }
184}
185
186impl PathSegment {
187    pub fn from_ident(ident: Ident) -> Self {
188        PathSegment { ident, id: DUMMY_NODE_ID, args: None }
189    }
190
191    pub fn path_root(span: Span) -> Self {
192        PathSegment::from_ident(Ident::new(kw::PathRoot, span))
193    }
194
195    pub fn span(&self) -> Span {
196        match &self.args {
197            Some(args) => self.ident.span.to(args.span()),
198            None => self.ident.span,
199        }
200    }
201}
202
203/// The generic arguments and associated item constraints of a path segment.
204///
205/// E.g., `<A, B>` as in `Foo<A, B>` or `(A, B)` as in `Foo(A, B)`.
206#[derive(Clone, Encodable, Decodable, Debug)]
207pub enum GenericArgs {
208    /// The `<'a, A, B, C>` in `foo::bar::baz::<'a, A, B, C>`.
209    AngleBracketed(AngleBracketedArgs),
210    /// The `(A, B)` and `C` in `Foo(A, B) -> C`.
211    Parenthesized(ParenthesizedArgs),
212    /// `(..)` in return type notation.
213    ParenthesizedElided(Span),
214}
215
216impl GenericArgs {
217    pub fn is_angle_bracketed(&self) -> bool {
218        matches!(self, AngleBracketed(..))
219    }
220
221    pub fn span(&self) -> Span {
222        match self {
223            AngleBracketed(data) => data.span,
224            Parenthesized(data) => data.span,
225            ParenthesizedElided(span) => *span,
226        }
227    }
228}
229
230/// Concrete argument in the sequence of generic args.
231#[derive(Clone, Encodable, Decodable, Debug)]
232pub enum GenericArg {
233    /// `'a` in `Foo<'a>`.
234    Lifetime(Lifetime),
235    /// `Bar` in `Foo<Bar>`.
236    Type(P<Ty>),
237    /// `1` in `Foo<1>`.
238    Const(AnonConst),
239}
240
241impl GenericArg {
242    pub fn span(&self) -> Span {
243        match self {
244            GenericArg::Lifetime(lt) => lt.ident.span,
245            GenericArg::Type(ty) => ty.span,
246            GenericArg::Const(ct) => ct.value.span,
247        }
248    }
249}
250
251/// A path like `Foo<'a, T>`.
252#[derive(Clone, Encodable, Decodable, Debug, Default)]
253pub struct AngleBracketedArgs {
254    /// The overall span.
255    pub span: Span,
256    /// The comma separated parts in the `<...>`.
257    pub args: ThinVec<AngleBracketedArg>,
258}
259
260/// Either an argument for a generic parameter or a constraint on an associated item.
261#[derive(Clone, Encodable, Decodable, Debug)]
262pub enum AngleBracketedArg {
263    /// A generic argument for a generic parameter.
264    Arg(GenericArg),
265    /// A constraint on an associated item.
266    Constraint(AssocItemConstraint),
267}
268
269impl AngleBracketedArg {
270    pub fn span(&self) -> Span {
271        match self {
272            AngleBracketedArg::Arg(arg) => arg.span(),
273            AngleBracketedArg::Constraint(constraint) => constraint.span,
274        }
275    }
276}
277
278impl From<AngleBracketedArgs> for P<GenericArgs> {
279    fn from(val: AngleBracketedArgs) -> Self {
280        P(GenericArgs::AngleBracketed(val))
281    }
282}
283
284impl From<ParenthesizedArgs> for P<GenericArgs> {
285    fn from(val: ParenthesizedArgs) -> Self {
286        P(GenericArgs::Parenthesized(val))
287    }
288}
289
290/// A path like `Foo(A, B) -> C`.
291#[derive(Clone, Encodable, Decodable, Debug)]
292pub struct ParenthesizedArgs {
293    /// ```text
294    /// Foo(A, B) -> C
295    /// ^^^^^^^^^^^^^^
296    /// ```
297    pub span: Span,
298
299    /// `(A, B)`
300    pub inputs: ThinVec<P<Ty>>,
301
302    /// ```text
303    /// Foo(A, B) -> C
304    ///    ^^^^^^
305    /// ```
306    pub inputs_span: Span,
307
308    /// `C`
309    pub output: FnRetTy,
310}
311
312impl ParenthesizedArgs {
313    pub fn as_angle_bracketed_args(&self) -> AngleBracketedArgs {
314        let args = self
315            .inputs
316            .iter()
317            .cloned()
318            .map(|input| AngleBracketedArg::Arg(GenericArg::Type(input)))
319            .collect();
320        AngleBracketedArgs { span: self.inputs_span, args }
321    }
322}
323
324pub use crate::node_id::{CRATE_NODE_ID, DUMMY_NODE_ID, NodeId};
325
326/// Modifiers on a trait bound like `~const`, `?` and `!`.
327#[derive(Copy, Clone, PartialEq, Eq, Encodable, Decodable, Debug)]
328pub struct TraitBoundModifiers {
329    pub constness: BoundConstness,
330    pub asyncness: BoundAsyncness,
331    pub polarity: BoundPolarity,
332}
333
334impl TraitBoundModifiers {
335    pub const NONE: Self = Self {
336        constness: BoundConstness::Never,
337        asyncness: BoundAsyncness::Normal,
338        polarity: BoundPolarity::Positive,
339    };
340}
341
342#[derive(Clone, Encodable, Decodable, Debug)]
343pub enum GenericBound {
344    Trait(PolyTraitRef),
345    Outlives(Lifetime),
346    /// Precise capturing syntax: `impl Sized + use<'a>`
347    Use(ThinVec<PreciseCapturingArg>, Span),
348}
349
350impl GenericBound {
351    pub fn span(&self) -> Span {
352        match self {
353            GenericBound::Trait(t, ..) => t.span,
354            GenericBound::Outlives(l) => l.ident.span,
355            GenericBound::Use(_, span) => *span,
356        }
357    }
358}
359
360pub type GenericBounds = Vec<GenericBound>;
361
362/// Specifies the enforced ordering for generic parameters. In the future,
363/// if we wanted to relax this order, we could override `PartialEq` and
364/// `PartialOrd`, to allow the kinds to be unordered.
365#[derive(Hash, Clone, Copy, PartialEq, Eq, PartialOrd, Ord)]
366pub enum ParamKindOrd {
367    Lifetime,
368    TypeOrConst,
369}
370
371impl fmt::Display for ParamKindOrd {
372    fn fmt(&self, f: &mut fmt::Formatter<'_>) -> fmt::Result {
373        match self {
374            ParamKindOrd::Lifetime => "lifetime".fmt(f),
375            ParamKindOrd::TypeOrConst => "type and const".fmt(f),
376        }
377    }
378}
379
380#[derive(Clone, Encodable, Decodable, Debug)]
381pub enum GenericParamKind {
382    /// A lifetime definition (e.g., `'a: 'b + 'c + 'd`).
383    Lifetime,
384    Type {
385        default: Option<P<Ty>>,
386    },
387    Const {
388        ty: P<Ty>,
389        /// Span of the `const` keyword.
390        kw_span: Span,
391        /// Optional default value for the const generic param.
392        default: Option<AnonConst>,
393    },
394}
395
396#[derive(Clone, Encodable, Decodable, Debug)]
397pub struct GenericParam {
398    pub id: NodeId,
399    pub ident: Ident,
400    pub attrs: AttrVec,
401    pub bounds: GenericBounds,
402    pub is_placeholder: bool,
403    pub kind: GenericParamKind,
404    pub colon_span: Option<Span>,
405}
406
407impl GenericParam {
408    pub fn span(&self) -> Span {
409        match &self.kind {
410            GenericParamKind::Lifetime | GenericParamKind::Type { default: None } => {
411                self.ident.span
412            }
413            GenericParamKind::Type { default: Some(ty) } => self.ident.span.to(ty.span),
414            GenericParamKind::Const { kw_span, default: Some(default), .. } => {
415                kw_span.to(default.value.span)
416            }
417            GenericParamKind::Const { kw_span, default: None, ty } => kw_span.to(ty.span),
418        }
419    }
420}
421
422/// Represents lifetime, type and const parameters attached to a declaration of
423/// a function, enum, trait, etc.
424#[derive(Clone, Encodable, Decodable, Debug, Default)]
425pub struct Generics {
426    pub params: ThinVec<GenericParam>,
427    pub where_clause: WhereClause,
428    pub span: Span,
429}
430
431/// A where-clause in a definition.
432#[derive(Clone, Encodable, Decodable, Debug, Default)]
433pub struct WhereClause {
434    /// `true` if we ate a `where` token.
435    ///
436    /// This can happen if we parsed no predicates, e.g., `struct Foo where {}`.
437    /// This allows us to pretty-print accurately and provide correct suggestion diagnostics.
438    pub has_where_token: bool,
439    pub predicates: ThinVec<WherePredicate>,
440    pub span: Span,
441}
442
443impl WhereClause {
444    pub fn is_empty(&self) -> bool {
445        !self.has_where_token && self.predicates.is_empty()
446    }
447}
448
449/// A single predicate in a where-clause.
450#[derive(Clone, Encodable, Decodable, Debug)]
451pub struct WherePredicate {
452    pub attrs: AttrVec,
453    pub kind: WherePredicateKind,
454    pub id: NodeId,
455    pub span: Span,
456    pub is_placeholder: bool,
457}
458
459/// Predicate kind in where-clause.
460#[derive(Clone, Encodable, Decodable, Debug)]
461pub enum WherePredicateKind {
462    /// A type bound (e.g., `for<'c> Foo: Send + Clone + 'c`).
463    BoundPredicate(WhereBoundPredicate),
464    /// A lifetime predicate (e.g., `'a: 'b + 'c`).
465    RegionPredicate(WhereRegionPredicate),
466    /// An equality predicate (unsupported).
467    EqPredicate(WhereEqPredicate),
468}
469
470/// A type bound.
471///
472/// E.g., `for<'c> Foo: Send + Clone + 'c`.
473#[derive(Clone, Encodable, Decodable, Debug)]
474pub struct WhereBoundPredicate {
475    /// Any generics from a `for` binding.
476    pub bound_generic_params: ThinVec<GenericParam>,
477    /// The type being bounded.
478    pub bounded_ty: P<Ty>,
479    /// Trait and lifetime bounds (`Clone + Send + 'static`).
480    pub bounds: GenericBounds,
481}
482
483/// A lifetime predicate.
484///
485/// E.g., `'a: 'b + 'c`.
486#[derive(Clone, Encodable, Decodable, Debug)]
487pub struct WhereRegionPredicate {
488    pub lifetime: Lifetime,
489    pub bounds: GenericBounds,
490}
491
492/// An equality predicate (unsupported).
493///
494/// E.g., `T = int`.
495#[derive(Clone, Encodable, Decodable, Debug)]
496pub struct WhereEqPredicate {
497    pub lhs_ty: P<Ty>,
498    pub rhs_ty: P<Ty>,
499}
500
501#[derive(Clone, Encodable, Decodable, Debug)]
502pub struct Crate {
503    pub attrs: AttrVec,
504    pub items: ThinVec<P<Item>>,
505    pub spans: ModSpans,
506    /// Must be equal to `CRATE_NODE_ID` after the crate root is expanded, but may hold
507    /// expansion placeholders or an unassigned value (`DUMMY_NODE_ID`) before that.
508    pub id: NodeId,
509    pub is_placeholder: bool,
510}
511
512/// A semantic representation of a meta item. A meta item is a slightly
513/// restricted form of an attribute -- it can only contain expressions in
514/// certain leaf positions, rather than arbitrary token streams -- that is used
515/// for most built-in attributes.
516///
517/// E.g., `#[test]`, `#[derive(..)]`, `#[rustfmt::skip]` or `#[feature = "foo"]`.
518#[derive(Clone, Encodable, Decodable, Debug, HashStable_Generic)]
519pub struct MetaItem {
520    pub unsafety: Safety,
521    pub path: Path,
522    pub kind: MetaItemKind,
523    pub span: Span,
524}
525
526/// The meta item kind, containing the data after the initial path.
527#[derive(Clone, Encodable, Decodable, Debug, HashStable_Generic)]
528pub enum MetaItemKind {
529    /// Word meta item.
530    ///
531    /// E.g., `#[test]`, which lacks any arguments after `test`.
532    Word,
533
534    /// List meta item.
535    ///
536    /// E.g., `#[derive(..)]`, where the field represents the `..`.
537    List(ThinVec<MetaItemInner>),
538
539    /// Name value meta item.
540    ///
541    /// E.g., `#[feature = "foo"]`, where the field represents the `"foo"`.
542    NameValue(MetaItemLit),
543}
544
545/// Values inside meta item lists.
546///
547/// E.g., each of `Clone`, `Copy` in `#[derive(Clone, Copy)]`.
548#[derive(Clone, Encodable, Decodable, Debug, HashStable_Generic)]
549pub enum MetaItemInner {
550    /// A full MetaItem, for recursive meta items.
551    MetaItem(MetaItem),
552
553    /// A literal.
554    ///
555    /// E.g., `"foo"`, `64`, `true`.
556    Lit(MetaItemLit),
557}
558
559/// A block (`{ .. }`).
560///
561/// E.g., `{ .. }` as in `fn foo() { .. }`.
562#[derive(Clone, Encodable, Decodable, Debug)]
563pub struct Block {
564    /// The statements in the block.
565    pub stmts: ThinVec<Stmt>,
566    pub id: NodeId,
567    /// Distinguishes between `unsafe { ... }` and `{ ... }`.
568    pub rules: BlockCheckMode,
569    pub span: Span,
570    pub tokens: Option<LazyAttrTokenStream>,
571}
572
573/// A match pattern.
574///
575/// Patterns appear in match statements and some other contexts, such as `let` and `if let`.
576#[derive(Clone, Encodable, Decodable, Debug)]
577pub struct Pat {
578    pub id: NodeId,
579    pub kind: PatKind,
580    pub span: Span,
581    pub tokens: Option<LazyAttrTokenStream>,
582}
583
584impl Pat {
585    /// Attempt reparsing the pattern as a type.
586    /// This is intended for use by diagnostics.
587    pub fn to_ty(&self) -> Option<P<Ty>> {
588        let kind = match &self.kind {
589            PatKind::Missing => unreachable!(),
590            // In a type expression `_` is an inference variable.
591            PatKind::Wild => TyKind::Infer,
592            // An IDENT pattern with no binding mode would be valid as path to a type. E.g. `u32`.
593            PatKind::Ident(BindingMode::NONE, ident, None) => {
594                TyKind::Path(None, Path::from_ident(*ident))
595            }
596            PatKind::Path(qself, path) => TyKind::Path(qself.clone(), path.clone()),
597            PatKind::MacCall(mac) => TyKind::MacCall(mac.clone()),
598            // `&mut? P` can be reinterpreted as `&mut? T` where `T` is `P` reparsed as a type.
599            PatKind::Ref(pat, mutbl) => {
600                pat.to_ty().map(|ty| TyKind::Ref(None, MutTy { ty, mutbl: *mutbl }))?
601            }
602            // A slice/array pattern `[P]` can be reparsed as `[T]`, an unsized array,
603            // when `P` can be reparsed as a type `T`.
604            PatKind::Slice(pats) if let [pat] = pats.as_slice() => {
605                pat.to_ty().map(TyKind::Slice)?
606            }
607            // A tuple pattern `(P0, .., Pn)` can be reparsed as `(T0, .., Tn)`
608            // assuming `T0` to `Tn` are all syntactically valid as types.
609            PatKind::Tuple(pats) => {
610                let mut tys = ThinVec::with_capacity(pats.len());
611                // FIXME(#48994) - could just be collected into an Option<Vec>
612                for pat in pats {
613                    tys.push(pat.to_ty()?);
614                }
615                TyKind::Tup(tys)
616            }
617            _ => return None,
618        };
619
620        Some(P(Ty { kind, id: self.id, span: self.span, tokens: None }))
621    }
622
623    /// Walk top-down and call `it` in each place where a pattern occurs
624    /// starting with the root pattern `walk` is called on. If `it` returns
625    /// false then we will descend no further but siblings will be processed.
626    pub fn walk<'ast>(&'ast self, it: &mut impl FnMut(&'ast Pat) -> bool) {
627        if !it(self) {
628            return;
629        }
630
631        match &self.kind {
632            // Walk into the pattern associated with `Ident` (if any).
633            PatKind::Ident(_, _, Some(p)) => p.walk(it),
634
635            // Walk into each field of struct.
636            PatKind::Struct(_, _, fields, _) => fields.iter().for_each(|field| field.pat.walk(it)),
637
638            // Sequence of patterns.
639            PatKind::TupleStruct(_, _, s)
640            | PatKind::Tuple(s)
641            | PatKind::Slice(s)
642            | PatKind::Or(s) => s.iter().for_each(|p| p.walk(it)),
643
644            // Trivial wrappers over inner patterns.
645            PatKind::Box(s)
646            | PatKind::Deref(s)
647            | PatKind::Ref(s, _)
648            | PatKind::Paren(s)
649            | PatKind::Guard(s, _) => s.walk(it),
650
651            // These patterns do not contain subpatterns, skip.
652            PatKind::Missing
653            | PatKind::Wild
654            | PatKind::Rest
655            | PatKind::Never
656            | PatKind::Expr(_)
657            | PatKind::Range(..)
658            | PatKind::Ident(..)
659            | PatKind::Path(..)
660            | PatKind::MacCall(_)
661            | PatKind::Err(_) => {}
662        }
663    }
664
665    /// Is this a `..` pattern?
666    pub fn is_rest(&self) -> bool {
667        matches!(self.kind, PatKind::Rest)
668    }
669
670    /// Whether this could be a never pattern, taking into account that a macro invocation can
671    /// return a never pattern. Used to inform errors during parsing.
672    pub fn could_be_never_pattern(&self) -> bool {
673        let mut could_be_never_pattern = false;
674        self.walk(&mut |pat| match &pat.kind {
675            PatKind::Never | PatKind::MacCall(_) => {
676                could_be_never_pattern = true;
677                false
678            }
679            PatKind::Or(s) => {
680                could_be_never_pattern = s.iter().all(|p| p.could_be_never_pattern());
681                false
682            }
683            _ => true,
684        });
685        could_be_never_pattern
686    }
687
688    /// Whether this contains a `!` pattern. This in particular means that a feature gate error will
689    /// be raised if the feature is off. Used to avoid gating the feature twice.
690    pub fn contains_never_pattern(&self) -> bool {
691        let mut contains_never_pattern = false;
692        self.walk(&mut |pat| {
693            if matches!(pat.kind, PatKind::Never) {
694                contains_never_pattern = true;
695            }
696            true
697        });
698        contains_never_pattern
699    }
700
701    /// Return a name suitable for diagnostics.
702    pub fn descr(&self) -> Option<String> {
703        match &self.kind {
704            PatKind::Missing => unreachable!(),
705            PatKind::Wild => Some("_".to_string()),
706            PatKind::Ident(BindingMode::NONE, ident, None) => Some(format!("{ident}")),
707            PatKind::Ref(pat, mutbl) => pat.descr().map(|d| format!("&{}{d}", mutbl.prefix_str())),
708            _ => None,
709        }
710    }
711}
712
713impl From<P<Pat>> for Pat {
714    fn from(value: P<Pat>) -> Self {
715        *value
716    }
717}
718
719/// A single field in a struct pattern.
720///
721/// Patterns like the fields of `Foo { x, ref y, ref mut z }`
722/// are treated the same as `x: x, y: ref y, z: ref mut z`,
723/// except when `is_shorthand` is true.
724#[derive(Clone, Encodable, Decodable, Debug)]
725pub struct PatField {
726    /// The identifier for the field.
727    pub ident: Ident,
728    /// The pattern the field is destructured to.
729    pub pat: P<Pat>,
730    pub is_shorthand: bool,
731    pub attrs: AttrVec,
732    pub id: NodeId,
733    pub span: Span,
734    pub is_placeholder: bool,
735}
736
737#[derive(Clone, Copy, Debug, Eq, PartialEq)]
738#[derive(Encodable, Decodable, HashStable_Generic)]
739pub enum ByRef {
740    Yes(Mutability),
741    No,
742}
743
744impl ByRef {
745    #[must_use]
746    pub fn cap_ref_mutability(mut self, mutbl: Mutability) -> Self {
747        if let ByRef::Yes(old_mutbl) = &mut self {
748            *old_mutbl = cmp::min(*old_mutbl, mutbl);
749        }
750        self
751    }
752}
753
754/// The mode of a binding (`mut`, `ref mut`, etc).
755/// Used for both the explicit binding annotations given in the HIR for a binding
756/// and the final binding mode that we infer after type inference/match ergonomics.
757/// `.0` is the by-reference mode (`ref`, `ref mut`, or by value),
758/// `.1` is the mutability of the binding.
759#[derive(Clone, Copy, Debug, Eq, PartialEq)]
760#[derive(Encodable, Decodable, HashStable_Generic)]
761pub struct BindingMode(pub ByRef, pub Mutability);
762
763impl BindingMode {
764    pub const NONE: Self = Self(ByRef::No, Mutability::Not);
765    pub const REF: Self = Self(ByRef::Yes(Mutability::Not), Mutability::Not);
766    pub const MUT: Self = Self(ByRef::No, Mutability::Mut);
767    pub const REF_MUT: Self = Self(ByRef::Yes(Mutability::Mut), Mutability::Not);
768    pub const MUT_REF: Self = Self(ByRef::Yes(Mutability::Not), Mutability::Mut);
769    pub const MUT_REF_MUT: Self = Self(ByRef::Yes(Mutability::Mut), Mutability::Mut);
770
771    pub fn prefix_str(self) -> &'static str {
772        match self {
773            Self::NONE => "",
774            Self::REF => "ref ",
775            Self::MUT => "mut ",
776            Self::REF_MUT => "ref mut ",
777            Self::MUT_REF => "mut ref ",
778            Self::MUT_REF_MUT => "mut ref mut ",
779        }
780    }
781}
782
783#[derive(Clone, Encodable, Decodable, Debug)]
784pub enum RangeEnd {
785    /// `..=` or `...`
786    Included(RangeSyntax),
787    /// `..`
788    Excluded,
789}
790
791#[derive(Clone, Encodable, Decodable, Debug)]
792pub enum RangeSyntax {
793    /// `...`
794    DotDotDot,
795    /// `..=`
796    DotDotEq,
797}
798
799/// All the different flavors of pattern that Rust recognizes.
800//
801// Adding a new variant? Please update `test_pat` in `tests/ui/macros/stringify.rs`.
802#[derive(Clone, Encodable, Decodable, Debug)]
803pub enum PatKind {
804    /// A missing pattern, e.g. for an anonymous param in a bare fn like `fn f(u32)`.
805    Missing,
806
807    /// Represents a wildcard pattern (`_`).
808    Wild,
809
810    /// A `PatKind::Ident` may either be a new bound variable (`ref mut binding @ OPT_SUBPATTERN`),
811    /// or a unit struct/variant pattern, or a const pattern (in the last two cases the third
812    /// field must be `None`). Disambiguation cannot be done with parser alone, so it happens
813    /// during name resolution.
814    Ident(BindingMode, Ident, Option<P<Pat>>),
815
816    /// A struct or struct variant pattern (e.g., `Variant {x, y, ..}`).
817    Struct(Option<P<QSelf>>, Path, ThinVec<PatField>, PatFieldsRest),
818
819    /// A tuple struct/variant pattern (`Variant(x, y, .., z)`).
820    TupleStruct(Option<P<QSelf>>, Path, ThinVec<P<Pat>>),
821
822    /// An or-pattern `A | B | C`.
823    /// Invariant: `pats.len() >= 2`.
824    Or(ThinVec<P<Pat>>),
825
826    /// A possibly qualified path pattern.
827    /// Unqualified path patterns `A::B::C` can legally refer to variants, structs, constants
828    /// or associated constants. Qualified path patterns `<A>::B::C`/`<A as Trait>::B::C` can
829    /// only legally refer to associated constants.
830    Path(Option<P<QSelf>>, Path),
831
832    /// A tuple pattern (`(a, b)`).
833    Tuple(ThinVec<P<Pat>>),
834
835    /// A `box` pattern.
836    Box(P<Pat>),
837
838    /// A `deref` pattern (currently `deref!()` macro-based syntax).
839    Deref(P<Pat>),
840
841    /// A reference pattern (e.g., `&mut (a, b)`).
842    Ref(P<Pat>, Mutability),
843
844    /// A literal, const block or path.
845    Expr(P<Expr>),
846
847    /// A range pattern (e.g., `1...2`, `1..2`, `1..`, `..2`, `1..=2`, `..=2`).
848    Range(Option<P<Expr>>, Option<P<Expr>>, Spanned<RangeEnd>),
849
850    /// A slice pattern `[a, b, c]`.
851    Slice(ThinVec<P<Pat>>),
852
853    /// A rest pattern `..`.
854    ///
855    /// Syntactically it is valid anywhere.
856    ///
857    /// Semantically however, it only has meaning immediately inside:
858    /// - a slice pattern: `[a, .., b]`,
859    /// - a binding pattern immediately inside a slice pattern: `[a, r @ ..]`,
860    /// - a tuple pattern: `(a, .., b)`,
861    /// - a tuple struct/variant pattern: `$path(a, .., b)`.
862    ///
863    /// In all of these cases, an additional restriction applies,
864    /// only one rest pattern may occur in the pattern sequences.
865    Rest,
866
867    // A never pattern `!`.
868    Never,
869
870    /// A guard pattern (e.g., `x if guard(x)`).
871    Guard(P<Pat>, P<Expr>),
872
873    /// Parentheses in patterns used for grouping (i.e., `(PAT)`).
874    Paren(P<Pat>),
875
876    /// A macro pattern; pre-expansion.
877    MacCall(P<MacCall>),
878
879    /// Placeholder for a pattern that wasn't syntactically well formed in some way.
880    Err(ErrorGuaranteed),
881}
882
883/// Whether the `..` is present in a struct fields pattern.
884#[derive(Clone, Copy, Encodable, Decodable, Debug, PartialEq)]
885pub enum PatFieldsRest {
886    /// `module::StructName { field, ..}`
887    Rest,
888    /// `module::StructName { field, syntax error }`
889    Recovered(ErrorGuaranteed),
890    /// `module::StructName { field }`
891    None,
892}
893
894/// The kind of borrow in an `AddrOf` expression,
895/// e.g., `&place` or `&raw const place`.
896#[derive(Clone, Copy, PartialEq, Eq, Debug)]
897#[derive(Encodable, Decodable, HashStable_Generic)]
898pub enum BorrowKind {
899    /// A normal borrow, `&$expr` or `&mut $expr`.
900    /// The resulting type is either `&'a T` or `&'a mut T`
901    /// where `T = typeof($expr)` and `'a` is some lifetime.
902    Ref,
903    /// A raw borrow, `&raw const $expr` or `&raw mut $expr`.
904    /// The resulting type is either `*const T` or `*mut T`
905    /// where `T = typeof($expr)`.
906    Raw,
907}
908
909#[derive(Clone, Copy, Debug, PartialEq, Encodable, Decodable, HashStable_Generic)]
910pub enum BinOpKind {
911    /// The `+` operator (addition)
912    Add,
913    /// The `-` operator (subtraction)
914    Sub,
915    /// The `*` operator (multiplication)
916    Mul,
917    /// The `/` operator (division)
918    Div,
919    /// The `%` operator (modulus)
920    Rem,
921    /// The `&&` operator (logical and)
922    And,
923    /// The `||` operator (logical or)
924    Or,
925    /// The `^` operator (bitwise xor)
926    BitXor,
927    /// The `&` operator (bitwise and)
928    BitAnd,
929    /// The `|` operator (bitwise or)
930    BitOr,
931    /// The `<<` operator (shift left)
932    Shl,
933    /// The `>>` operator (shift right)
934    Shr,
935    /// The `==` operator (equality)
936    Eq,
937    /// The `<` operator (less than)
938    Lt,
939    /// The `<=` operator (less than or equal to)
940    Le,
941    /// The `!=` operator (not equal to)
942    Ne,
943    /// The `>=` operator (greater than or equal to)
944    Ge,
945    /// The `>` operator (greater than)
946    Gt,
947}
948
949impl BinOpKind {
950    pub fn as_str(&self) -> &'static str {
951        use BinOpKind::*;
952        match self {
953            Add => "+",
954            Sub => "-",
955            Mul => "*",
956            Div => "/",
957            Rem => "%",
958            And => "&&",
959            Or => "||",
960            BitXor => "^",
961            BitAnd => "&",
962            BitOr => "|",
963            Shl => "<<",
964            Shr => ">>",
965            Eq => "==",
966            Lt => "<",
967            Le => "<=",
968            Ne => "!=",
969            Ge => ">=",
970            Gt => ">",
971        }
972    }
973
974    pub fn is_lazy(&self) -> bool {
975        matches!(self, BinOpKind::And | BinOpKind::Or)
976    }
977
978    pub fn precedence(&self) -> ExprPrecedence {
979        use BinOpKind::*;
980        match *self {
981            Mul | Div | Rem => ExprPrecedence::Product,
982            Add | Sub => ExprPrecedence::Sum,
983            Shl | Shr => ExprPrecedence::Shift,
984            BitAnd => ExprPrecedence::BitAnd,
985            BitXor => ExprPrecedence::BitXor,
986            BitOr => ExprPrecedence::BitOr,
987            Lt | Gt | Le | Ge | Eq | Ne => ExprPrecedence::Compare,
988            And => ExprPrecedence::LAnd,
989            Or => ExprPrecedence::LOr,
990        }
991    }
992
993    pub fn fixity(&self) -> Fixity {
994        use BinOpKind::*;
995        match self {
996            Eq | Ne | Lt | Le | Gt | Ge => Fixity::None,
997            Add | Sub | Mul | Div | Rem | And | Or | BitXor | BitAnd | BitOr | Shl | Shr => {
998                Fixity::Left
999            }
1000        }
1001    }
1002
1003    pub fn is_comparison(self) -> bool {
1004        use BinOpKind::*;
1005        match self {
1006            Eq | Ne | Lt | Le | Gt | Ge => true,
1007            Add | Sub | Mul | Div | Rem | And | Or | BitXor | BitAnd | BitOr | Shl | Shr => false,
1008        }
1009    }
1010
1011    /// Returns `true` if the binary operator takes its arguments by value.
1012    pub fn is_by_value(self) -> bool {
1013        !self.is_comparison()
1014    }
1015}
1016
1017pub type BinOp = Spanned<BinOpKind>;
1018
1019// Sometimes `BinOpKind` and `AssignOpKind` need the same treatment. The
1020// operations covered by `AssignOpKind` are a subset of those covered by
1021// `BinOpKind`, so it makes sense to convert `AssignOpKind` to `BinOpKind`.
1022impl From<AssignOpKind> for BinOpKind {
1023    fn from(op: AssignOpKind) -> BinOpKind {
1024        match op {
1025            AssignOpKind::AddAssign => BinOpKind::Add,
1026            AssignOpKind::SubAssign => BinOpKind::Sub,
1027            AssignOpKind::MulAssign => BinOpKind::Mul,
1028            AssignOpKind::DivAssign => BinOpKind::Div,
1029            AssignOpKind::RemAssign => BinOpKind::Rem,
1030            AssignOpKind::BitXorAssign => BinOpKind::BitXor,
1031            AssignOpKind::BitAndAssign => BinOpKind::BitAnd,
1032            AssignOpKind::BitOrAssign => BinOpKind::BitOr,
1033            AssignOpKind::ShlAssign => BinOpKind::Shl,
1034            AssignOpKind::ShrAssign => BinOpKind::Shr,
1035        }
1036    }
1037}
1038
1039#[derive(Clone, Copy, Debug, PartialEq, Encodable, Decodable, HashStable_Generic)]
1040pub enum AssignOpKind {
1041    /// The `+=` operator (addition)
1042    AddAssign,
1043    /// The `-=` operator (subtraction)
1044    SubAssign,
1045    /// The `*=` operator (multiplication)
1046    MulAssign,
1047    /// The `/=` operator (division)
1048    DivAssign,
1049    /// The `%=` operator (modulus)
1050    RemAssign,
1051    /// The `^=` operator (bitwise xor)
1052    BitXorAssign,
1053    /// The `&=` operator (bitwise and)
1054    BitAndAssign,
1055    /// The `|=` operator (bitwise or)
1056    BitOrAssign,
1057    /// The `<<=` operator (shift left)
1058    ShlAssign,
1059    /// The `>>=` operator (shift right)
1060    ShrAssign,
1061}
1062
1063impl AssignOpKind {
1064    pub fn as_str(&self) -> &'static str {
1065        use AssignOpKind::*;
1066        match self {
1067            AddAssign => "+=",
1068            SubAssign => "-=",
1069            MulAssign => "*=",
1070            DivAssign => "/=",
1071            RemAssign => "%=",
1072            BitXorAssign => "^=",
1073            BitAndAssign => "&=",
1074            BitOrAssign => "|=",
1075            ShlAssign => "<<=",
1076            ShrAssign => ">>=",
1077        }
1078    }
1079
1080    /// AssignOps are always by value.
1081    pub fn is_by_value(self) -> bool {
1082        true
1083    }
1084}
1085
1086pub type AssignOp = Spanned<AssignOpKind>;
1087
1088/// Unary operator.
1089///
1090/// Note that `&data` is not an operator, it's an `AddrOf` expression.
1091#[derive(Clone, Copy, Debug, PartialEq, Encodable, Decodable, HashStable_Generic)]
1092pub enum UnOp {
1093    /// The `*` operator for dereferencing
1094    Deref,
1095    /// The `!` operator for logical inversion
1096    Not,
1097    /// The `-` operator for negation
1098    Neg,
1099}
1100
1101impl UnOp {
1102    pub fn as_str(&self) -> &'static str {
1103        match self {
1104            UnOp::Deref => "*",
1105            UnOp::Not => "!",
1106            UnOp::Neg => "-",
1107        }
1108    }
1109
1110    /// Returns `true` if the unary operator takes its argument by value.
1111    pub fn is_by_value(self) -> bool {
1112        matches!(self, Self::Neg | Self::Not)
1113    }
1114}
1115
1116/// A statement. No `attrs` or `tokens` fields because each `StmtKind` variant
1117/// contains an AST node with those fields. (Except for `StmtKind::Empty`,
1118/// which never has attrs or tokens)
1119#[derive(Clone, Encodable, Decodable, Debug)]
1120pub struct Stmt {
1121    pub id: NodeId,
1122    pub kind: StmtKind,
1123    pub span: Span,
1124}
1125
1126impl Stmt {
1127    pub fn has_trailing_semicolon(&self) -> bool {
1128        match &self.kind {
1129            StmtKind::Semi(_) => true,
1130            StmtKind::MacCall(mac) => matches!(mac.style, MacStmtStyle::Semicolon),
1131            _ => false,
1132        }
1133    }
1134
1135    /// Converts a parsed `Stmt` to a `Stmt` with
1136    /// a trailing semicolon.
1137    ///
1138    /// This only modifies the parsed AST struct, not the attached
1139    /// `LazyAttrTokenStream`. The parser is responsible for calling
1140    /// `ToAttrTokenStream::add_trailing_semi` when there is actually
1141    /// a semicolon in the tokenstream.
1142    pub fn add_trailing_semicolon(mut self) -> Self {
1143        self.kind = match self.kind {
1144            StmtKind::Expr(expr) => StmtKind::Semi(expr),
1145            StmtKind::MacCall(mut mac) => {
1146                mac.style = MacStmtStyle::Semicolon;
1147                StmtKind::MacCall(mac)
1148            }
1149            kind => kind,
1150        };
1151
1152        self
1153    }
1154
1155    pub fn is_item(&self) -> bool {
1156        matches!(self.kind, StmtKind::Item(_))
1157    }
1158
1159    pub fn is_expr(&self) -> bool {
1160        matches!(self.kind, StmtKind::Expr(_))
1161    }
1162}
1163
1164// Adding a new variant? Please update `test_stmt` in `tests/ui/macros/stringify.rs`.
1165#[derive(Clone, Encodable, Decodable, Debug)]
1166pub enum StmtKind {
1167    /// A local (let) binding.
1168    Let(P<Local>),
1169    /// An item definition.
1170    Item(P<Item>),
1171    /// Expr without trailing semi-colon.
1172    Expr(P<Expr>),
1173    /// Expr with a trailing semi-colon.
1174    Semi(P<Expr>),
1175    /// Just a trailing semi-colon.
1176    Empty,
1177    /// Macro.
1178    MacCall(P<MacCallStmt>),
1179}
1180
1181#[derive(Clone, Encodable, Decodable, Debug)]
1182pub struct MacCallStmt {
1183    pub mac: P<MacCall>,
1184    pub style: MacStmtStyle,
1185    pub attrs: AttrVec,
1186    pub tokens: Option<LazyAttrTokenStream>,
1187}
1188
1189#[derive(Clone, Copy, PartialEq, Encodable, Decodable, Debug)]
1190pub enum MacStmtStyle {
1191    /// The macro statement had a trailing semicolon (e.g., `foo! { ... };`
1192    /// `foo!(...);`, `foo![...];`).
1193    Semicolon,
1194    /// The macro statement had braces (e.g., `foo! { ... }`).
1195    Braces,
1196    /// The macro statement had parentheses or brackets and no semicolon (e.g.,
1197    /// `foo!(...)`). All of these will end up being converted into macro
1198    /// expressions.
1199    NoBraces,
1200}
1201
1202/// Local represents a `let` statement, e.g., `let <pat>:<ty> = <expr>;`.
1203#[derive(Clone, Encodable, Decodable, Debug)]
1204pub struct Local {
1205    pub id: NodeId,
1206    pub super_: Option<Span>,
1207    pub pat: P<Pat>,
1208    pub ty: Option<P<Ty>>,
1209    pub kind: LocalKind,
1210    pub span: Span,
1211    pub colon_sp: Option<Span>,
1212    pub attrs: AttrVec,
1213    pub tokens: Option<LazyAttrTokenStream>,
1214}
1215
1216#[derive(Clone, Encodable, Decodable, Debug)]
1217pub enum LocalKind {
1218    /// Local declaration.
1219    /// Example: `let x;`
1220    Decl,
1221    /// Local declaration with an initializer.
1222    /// Example: `let x = y;`
1223    Init(P<Expr>),
1224    /// Local declaration with an initializer and an `else` clause.
1225    /// Example: `let Some(x) = y else { return };`
1226    InitElse(P<Expr>, P<Block>),
1227}
1228
1229impl LocalKind {
1230    pub fn init(&self) -> Option<&Expr> {
1231        match self {
1232            Self::Decl => None,
1233            Self::Init(i) | Self::InitElse(i, _) => Some(i),
1234        }
1235    }
1236
1237    pub fn init_else_opt(&self) -> Option<(&Expr, Option<&Block>)> {
1238        match self {
1239            Self::Decl => None,
1240            Self::Init(init) => Some((init, None)),
1241            Self::InitElse(init, els) => Some((init, Some(els))),
1242        }
1243    }
1244}
1245
1246/// An arm of a 'match'.
1247///
1248/// E.g., `0..=10 => { println!("match!") }` as in
1249///
1250/// ```
1251/// match 123 {
1252///     0..=10 => { println!("match!") },
1253///     _ => { println!("no match!") },
1254/// }
1255/// ```
1256#[derive(Clone, Encodable, Decodable, Debug)]
1257pub struct Arm {
1258    pub attrs: AttrVec,
1259    /// Match arm pattern, e.g. `10` in `match foo { 10 => {}, _ => {} }`.
1260    pub pat: P<Pat>,
1261    /// Match arm guard, e.g. `n > 10` in `match foo { n if n > 10 => {}, _ => {} }`.
1262    pub guard: Option<P<Expr>>,
1263    /// Match arm body. Omitted if the pattern is a never pattern.
1264    pub body: Option<P<Expr>>,
1265    pub span: Span,
1266    pub id: NodeId,
1267    pub is_placeholder: bool,
1268}
1269
1270/// A single field in a struct expression, e.g. `x: value` and `y` in `Foo { x: value, y }`.
1271#[derive(Clone, Encodable, Decodable, Debug)]
1272pub struct ExprField {
1273    pub attrs: AttrVec,
1274    pub id: NodeId,
1275    pub span: Span,
1276    pub ident: Ident,
1277    pub expr: P<Expr>,
1278    pub is_shorthand: bool,
1279    pub is_placeholder: bool,
1280}
1281
1282#[derive(Clone, PartialEq, Encodable, Decodable, Debug, Copy)]
1283pub enum BlockCheckMode {
1284    Default,
1285    Unsafe(UnsafeSource),
1286}
1287
1288#[derive(Clone, PartialEq, Encodable, Decodable, Debug, Copy)]
1289pub enum UnsafeSource {
1290    CompilerGenerated,
1291    UserProvided,
1292}
1293
1294/// A constant (expression) that's not an item or associated item,
1295/// but needs its own `DefId` for type-checking, const-eval, etc.
1296/// These are usually found nested inside types (e.g., array lengths)
1297/// or expressions (e.g., repeat counts), and also used to define
1298/// explicit discriminant values for enum variants.
1299#[derive(Clone, Encodable, Decodable, Debug)]
1300pub struct AnonConst {
1301    pub id: NodeId,
1302    pub value: P<Expr>,
1303}
1304
1305/// An expression.
1306#[derive(Clone, Encodable, Decodable, Debug)]
1307pub struct Expr {
1308    pub id: NodeId,
1309    pub kind: ExprKind,
1310    pub span: Span,
1311    pub attrs: AttrVec,
1312    pub tokens: Option<LazyAttrTokenStream>,
1313}
1314
1315impl Expr {
1316    /// Check if this expression is potentially a trivial const arg, i.e., one that can _potentially_
1317    /// be represented without an anon const in the HIR.
1318    ///
1319    /// This will unwrap at most one block level (curly braces). After that, if the expression
1320    /// is a path, it mostly dispatches to [`Path::is_potential_trivial_const_arg`].
1321    /// See there for more info about `allow_mgca_arg`.
1322    ///
1323    /// The only additional thing to note is that when `allow_mgca_arg` is false, this function
1324    /// will only allow paths with no qself, before dispatching to the `Path` function of
1325    /// the same name.
1326    ///
1327    /// Does not ensure that the path resolves to a const param/item, the caller should check this.
1328    /// This also does not consider macros, so it's only correct after macro-expansion.
1329    pub fn is_potential_trivial_const_arg(&self, allow_mgca_arg: bool) -> bool {
1330        let this = self.maybe_unwrap_block();
1331        if allow_mgca_arg {
1332            matches!(this.kind, ExprKind::Path(..))
1333        } else {
1334            if let ExprKind::Path(None, path) = &this.kind
1335                && path.is_potential_trivial_const_arg(allow_mgca_arg)
1336            {
1337                true
1338            } else {
1339                false
1340            }
1341        }
1342    }
1343
1344    /// Returns an expression with (when possible) *one* outter brace removed
1345    pub fn maybe_unwrap_block(&self) -> &Expr {
1346        if let ExprKind::Block(block, None) = &self.kind
1347            && let [stmt] = block.stmts.as_slice()
1348            && let StmtKind::Expr(expr) = &stmt.kind
1349        {
1350            expr
1351        } else {
1352            self
1353        }
1354    }
1355
1356    /// Determines whether this expression is a macro call optionally wrapped in braces . If
1357    /// `already_stripped_block` is set then we do not attempt to peel off a layer of braces.
1358    ///
1359    /// Returns the [`NodeId`] of the macro call and whether a layer of braces has been peeled
1360    /// either before, or part of, this function.
1361    pub fn optionally_braced_mac_call(
1362        &self,
1363        already_stripped_block: bool,
1364    ) -> Option<(bool, NodeId)> {
1365        match &self.kind {
1366            ExprKind::Block(block, None)
1367                if let [stmt] = &*block.stmts
1368                    && !already_stripped_block =>
1369            {
1370                match &stmt.kind {
1371                    StmtKind::MacCall(_) => Some((true, stmt.id)),
1372                    StmtKind::Expr(expr) if let ExprKind::MacCall(_) = &expr.kind => {
1373                        Some((true, expr.id))
1374                    }
1375                    _ => None,
1376                }
1377            }
1378            ExprKind::MacCall(_) => Some((already_stripped_block, self.id)),
1379            _ => None,
1380        }
1381    }
1382
1383    pub fn to_bound(&self) -> Option<GenericBound> {
1384        match &self.kind {
1385            ExprKind::Path(None, path) => Some(GenericBound::Trait(PolyTraitRef::new(
1386                ThinVec::new(),
1387                path.clone(),
1388                TraitBoundModifiers::NONE,
1389                self.span,
1390            ))),
1391            _ => None,
1392        }
1393    }
1394
1395    pub fn peel_parens(&self) -> &Expr {
1396        let mut expr = self;
1397        while let ExprKind::Paren(inner) = &expr.kind {
1398            expr = inner;
1399        }
1400        expr
1401    }
1402
1403    pub fn peel_parens_and_refs(&self) -> &Expr {
1404        let mut expr = self;
1405        while let ExprKind::Paren(inner) | ExprKind::AddrOf(BorrowKind::Ref, _, inner) = &expr.kind
1406        {
1407            expr = inner;
1408        }
1409        expr
1410    }
1411
1412    /// Attempts to reparse as `Ty` (for diagnostic purposes).
1413    pub fn to_ty(&self) -> Option<P<Ty>> {
1414        let kind = match &self.kind {
1415            // Trivial conversions.
1416            ExprKind::Path(qself, path) => TyKind::Path(qself.clone(), path.clone()),
1417            ExprKind::MacCall(mac) => TyKind::MacCall(mac.clone()),
1418
1419            ExprKind::Paren(expr) => expr.to_ty().map(TyKind::Paren)?,
1420
1421            ExprKind::AddrOf(BorrowKind::Ref, mutbl, expr) => {
1422                expr.to_ty().map(|ty| TyKind::Ref(None, MutTy { ty, mutbl: *mutbl }))?
1423            }
1424
1425            ExprKind::Repeat(expr, expr_len) => {
1426                expr.to_ty().map(|ty| TyKind::Array(ty, expr_len.clone()))?
1427            }
1428
1429            ExprKind::Array(exprs) if let [expr] = exprs.as_slice() => {
1430                expr.to_ty().map(TyKind::Slice)?
1431            }
1432
1433            ExprKind::Tup(exprs) => {
1434                let tys = exprs.iter().map(|expr| expr.to_ty()).collect::<Option<ThinVec<_>>>()?;
1435                TyKind::Tup(tys)
1436            }
1437
1438            // If binary operator is `Add` and both `lhs` and `rhs` are trait bounds,
1439            // then type of result is trait object.
1440            // Otherwise we don't assume the result type.
1441            ExprKind::Binary(binop, lhs, rhs) if binop.node == BinOpKind::Add => {
1442                if let (Some(lhs), Some(rhs)) = (lhs.to_bound(), rhs.to_bound()) {
1443                    TyKind::TraitObject(vec![lhs, rhs], TraitObjectSyntax::None)
1444                } else {
1445                    return None;
1446                }
1447            }
1448
1449            ExprKind::Underscore => TyKind::Infer,
1450
1451            // This expression doesn't look like a type syntactically.
1452            _ => return None,
1453        };
1454
1455        Some(P(Ty { kind, id: self.id, span: self.span, tokens: None }))
1456    }
1457
1458    pub fn precedence(&self) -> ExprPrecedence {
1459        fn prefix_attrs_precedence(attrs: &AttrVec) -> ExprPrecedence {
1460            for attr in attrs {
1461                if let AttrStyle::Outer = attr.style {
1462                    return ExprPrecedence::Prefix;
1463                }
1464            }
1465            ExprPrecedence::Unambiguous
1466        }
1467
1468        match &self.kind {
1469            ExprKind::Closure(closure) => {
1470                match closure.fn_decl.output {
1471                    FnRetTy::Default(_) => ExprPrecedence::Jump,
1472                    FnRetTy::Ty(_) => prefix_attrs_precedence(&self.attrs),
1473                }
1474            }
1475
1476            ExprKind::Break(_ /*label*/, value)
1477            | ExprKind::Ret(value)
1478            | ExprKind::Yield(YieldKind::Prefix(value))
1479            | ExprKind::Yeet(value) => match value {
1480                Some(_) => ExprPrecedence::Jump,
1481                None => prefix_attrs_precedence(&self.attrs),
1482            },
1483
1484            ExprKind::Become(_) => ExprPrecedence::Jump,
1485
1486            // `Range` claims to have higher precedence than `Assign`, but `x .. x = x` fails to
1487            // parse, instead of parsing as `(x .. x) = x`. Giving `Range` a lower precedence
1488            // ensures that `pprust` will add parentheses in the right places to get the desired
1489            // parse.
1490            ExprKind::Range(..) => ExprPrecedence::Range,
1491
1492            // Binop-like expr kinds, handled by `AssocOp`.
1493            ExprKind::Binary(op, ..) => op.node.precedence(),
1494            ExprKind::Cast(..) => ExprPrecedence::Cast,
1495
1496            ExprKind::Assign(..) |
1497            ExprKind::AssignOp(..) => ExprPrecedence::Assign,
1498
1499            // Unary, prefix
1500            ExprKind::AddrOf(..)
1501            // Here `let pats = expr` has `let pats =` as a "unary" prefix of `expr`.
1502            // However, this is not exactly right. When `let _ = a` is the LHS of a binop we
1503            // need parens sometimes. E.g. we can print `(let _ = a) && b` as `let _ = a && b`
1504            // but we need to print `(let _ = a) < b` as-is with parens.
1505            | ExprKind::Let(..)
1506            | ExprKind::Unary(..) => ExprPrecedence::Prefix,
1507
1508            // Need parens if and only if there are prefix attributes.
1509            ExprKind::Array(_)
1510            | ExprKind::Await(..)
1511            | ExprKind::Use(..)
1512            | ExprKind::Block(..)
1513            | ExprKind::Call(..)
1514            | ExprKind::ConstBlock(_)
1515            | ExprKind::Continue(..)
1516            | ExprKind::Field(..)
1517            | ExprKind::ForLoop { .. }
1518            | ExprKind::FormatArgs(..)
1519            | ExprKind::Gen(..)
1520            | ExprKind::If(..)
1521            | ExprKind::IncludedBytes(..)
1522            | ExprKind::Index(..)
1523            | ExprKind::InlineAsm(..)
1524            | ExprKind::Lit(_)
1525            | ExprKind::Loop(..)
1526            | ExprKind::MacCall(..)
1527            | ExprKind::Match(..)
1528            | ExprKind::MethodCall(..)
1529            | ExprKind::OffsetOf(..)
1530            | ExprKind::Paren(..)
1531            | ExprKind::Path(..)
1532            | ExprKind::Repeat(..)
1533            | ExprKind::Struct(..)
1534            | ExprKind::Try(..)
1535            | ExprKind::TryBlock(..)
1536            | ExprKind::Tup(_)
1537            | ExprKind::Type(..)
1538            | ExprKind::Underscore
1539            | ExprKind::UnsafeBinderCast(..)
1540            | ExprKind::While(..)
1541            | ExprKind::Yield(YieldKind::Postfix(..))
1542            | ExprKind::Err(_)
1543            | ExprKind::Dummy => prefix_attrs_precedence(&self.attrs),
1544        }
1545    }
1546
1547    /// To a first-order approximation, is this a pattern?
1548    pub fn is_approximately_pattern(&self) -> bool {
1549        matches!(
1550            &self.peel_parens().kind,
1551            ExprKind::Array(_)
1552                | ExprKind::Call(_, _)
1553                | ExprKind::Tup(_)
1554                | ExprKind::Lit(_)
1555                | ExprKind::Range(_, _, _)
1556                | ExprKind::Underscore
1557                | ExprKind::Path(_, _)
1558                | ExprKind::Struct(_)
1559        )
1560    }
1561
1562    /// Creates a dummy `Expr`.
1563    ///
1564    /// Should only be used when it will be replaced afterwards or as a return value when an error was encountered.
1565    pub fn dummy() -> Expr {
1566        Expr {
1567            id: DUMMY_NODE_ID,
1568            kind: ExprKind::Dummy,
1569            span: DUMMY_SP,
1570            attrs: ThinVec::new(),
1571            tokens: None,
1572        }
1573    }
1574}
1575
1576impl From<P<Expr>> for Expr {
1577    fn from(value: P<Expr>) -> Self {
1578        *value
1579    }
1580}
1581
1582#[derive(Clone, Encodable, Decodable, Debug)]
1583pub struct Closure {
1584    pub binder: ClosureBinder,
1585    pub capture_clause: CaptureBy,
1586    pub constness: Const,
1587    pub coroutine_kind: Option<CoroutineKind>,
1588    pub movability: Movability,
1589    pub fn_decl: P<FnDecl>,
1590    pub body: P<Expr>,
1591    /// The span of the declaration block: 'move |...| -> ...'
1592    pub fn_decl_span: Span,
1593    /// The span of the argument block `|...|`
1594    pub fn_arg_span: Span,
1595}
1596
1597/// Limit types of a range (inclusive or exclusive).
1598#[derive(Copy, Clone, PartialEq, Encodable, Decodable, Debug)]
1599pub enum RangeLimits {
1600    /// Inclusive at the beginning, exclusive at the end.
1601    HalfOpen,
1602    /// Inclusive at the beginning and end.
1603    Closed,
1604}
1605
1606impl RangeLimits {
1607    pub fn as_str(&self) -> &'static str {
1608        match self {
1609            RangeLimits::HalfOpen => "..",
1610            RangeLimits::Closed => "..=",
1611        }
1612    }
1613}
1614
1615/// A method call (e.g. `x.foo::<Bar, Baz>(a, b, c)`).
1616#[derive(Clone, Encodable, Decodable, Debug)]
1617pub struct MethodCall {
1618    /// The method name and its generic arguments, e.g. `foo::<Bar, Baz>`.
1619    pub seg: PathSegment,
1620    /// The receiver, e.g. `x`.
1621    pub receiver: P<Expr>,
1622    /// The arguments, e.g. `a, b, c`.
1623    pub args: ThinVec<P<Expr>>,
1624    /// The span of the function, without the dot and receiver e.g. `foo::<Bar,
1625    /// Baz>(a, b, c)`.
1626    pub span: Span,
1627}
1628
1629#[derive(Clone, Encodable, Decodable, Debug)]
1630pub enum StructRest {
1631    /// `..x`.
1632    Base(P<Expr>),
1633    /// `..`.
1634    Rest(Span),
1635    /// No trailing `..` or expression.
1636    None,
1637}
1638
1639#[derive(Clone, Encodable, Decodable, Debug)]
1640pub struct StructExpr {
1641    pub qself: Option<P<QSelf>>,
1642    pub path: Path,
1643    pub fields: ThinVec<ExprField>,
1644    pub rest: StructRest,
1645}
1646
1647// Adding a new variant? Please update `test_expr` in `tests/ui/macros/stringify.rs`.
1648#[derive(Clone, Encodable, Decodable, Debug)]
1649pub enum ExprKind {
1650    /// An array (e.g, `[a, b, c, d]`).
1651    Array(ThinVec<P<Expr>>),
1652    /// Allow anonymous constants from an inline `const` block.
1653    ConstBlock(AnonConst),
1654    /// A function call.
1655    ///
1656    /// The first field resolves to the function itself,
1657    /// and the second field is the list of arguments.
1658    /// This also represents calling the constructor of
1659    /// tuple-like ADTs such as tuple structs and enum variants.
1660    Call(P<Expr>, ThinVec<P<Expr>>),
1661    /// A method call (e.g., `x.foo::<Bar, Baz>(a, b, c)`).
1662    MethodCall(Box<MethodCall>),
1663    /// A tuple (e.g., `(a, b, c, d)`).
1664    Tup(ThinVec<P<Expr>>),
1665    /// A binary operation (e.g., `a + b`, `a * b`).
1666    Binary(BinOp, P<Expr>, P<Expr>),
1667    /// A unary operation (e.g., `!x`, `*x`).
1668    Unary(UnOp, P<Expr>),
1669    /// A literal (e.g., `1`, `"foo"`).
1670    Lit(token::Lit),
1671    /// A cast (e.g., `foo as f64`).
1672    Cast(P<Expr>, P<Ty>),
1673    /// A type ascription (e.g., `builtin # type_ascribe(42, usize)`).
1674    ///
1675    /// Usually not written directly in user code but
1676    /// indirectly via the macro `type_ascribe!(...)`.
1677    Type(P<Expr>, P<Ty>),
1678    /// A `let pat = expr` expression that is only semantically allowed in the condition
1679    /// of `if` / `while` expressions. (e.g., `if let 0 = x { .. }`).
1680    ///
1681    /// `Span` represents the whole `let pat = expr` statement.
1682    Let(P<Pat>, P<Expr>, Span, Recovered),
1683    /// An `if` block, with an optional `else` block.
1684    ///
1685    /// `if expr { block } else { expr }`
1686    ///
1687    /// If present, the "else" expr is always `ExprKind::Block` (for `else`) or
1688    /// `ExprKind::If` (for `else if`).
1689    If(P<Expr>, P<Block>, Option<P<Expr>>),
1690    /// A while loop, with an optional label.
1691    ///
1692    /// `'label: while expr { block }`
1693    While(P<Expr>, P<Block>, Option<Label>),
1694    /// A `for` loop, with an optional label.
1695    ///
1696    /// `'label: for await? pat in iter { block }`
1697    ///
1698    /// This is desugared to a combination of `loop` and `match` expressions.
1699    ForLoop {
1700        pat: P<Pat>,
1701        iter: P<Expr>,
1702        body: P<Block>,
1703        label: Option<Label>,
1704        kind: ForLoopKind,
1705    },
1706    /// Conditionless loop (can be exited with `break`, `continue`, or `return`).
1707    ///
1708    /// `'label: loop { block }`
1709    Loop(P<Block>, Option<Label>, Span),
1710    /// A `match` block.
1711    Match(P<Expr>, ThinVec<Arm>, MatchKind),
1712    /// A closure (e.g., `move |a, b, c| a + b + c`).
1713    Closure(Box<Closure>),
1714    /// A block (`'label: { ... }`).
1715    Block(P<Block>, Option<Label>),
1716    /// An `async` block (`async move { ... }`),
1717    /// or a `gen` block (`gen move { ... }`).
1718    ///
1719    /// The span is the "decl", which is the header before the body `{ }`
1720    /// including the `asyng`/`gen` keywords and possibly `move`.
1721    Gen(CaptureBy, P<Block>, GenBlockKind, Span),
1722    /// An await expression (`my_future.await`). Span is of await keyword.
1723    Await(P<Expr>, Span),
1724    /// A use expression (`x.use`). Span is of use keyword.
1725    Use(P<Expr>, Span),
1726
1727    /// A try block (`try { ... }`).
1728    TryBlock(P<Block>),
1729
1730    /// An assignment (`a = foo()`).
1731    /// The `Span` argument is the span of the `=` token.
1732    Assign(P<Expr>, P<Expr>, Span),
1733    /// An assignment with an operator.
1734    ///
1735    /// E.g., `a += 1`.
1736    AssignOp(AssignOp, P<Expr>, P<Expr>),
1737    /// Access of a named (e.g., `obj.foo`) or unnamed (e.g., `obj.0`) struct field.
1738    Field(P<Expr>, Ident),
1739    /// An indexing operation (e.g., `foo[2]`).
1740    /// The span represents the span of the `[2]`, including brackets.
1741    Index(P<Expr>, P<Expr>, Span),
1742    /// A range (e.g., `1..2`, `1..`, `..2`, `1..=2`, `..=2`; and `..` in destructuring assignment).
1743    Range(Option<P<Expr>>, Option<P<Expr>>, RangeLimits),
1744    /// An underscore, used in destructuring assignment to ignore a value.
1745    Underscore,
1746
1747    /// Variable reference, possibly containing `::` and/or type
1748    /// parameters (e.g., `foo::bar::<baz>`).
1749    ///
1750    /// Optionally "qualified" (e.g., `<Vec<T> as SomeTrait>::SomeType`).
1751    Path(Option<P<QSelf>>, Path),
1752
1753    /// A referencing operation (`&a`, `&mut a`, `&raw const a` or `&raw mut a`).
1754    AddrOf(BorrowKind, Mutability, P<Expr>),
1755    /// A `break`, with an optional label to break, and an optional expression.
1756    Break(Option<Label>, Option<P<Expr>>),
1757    /// A `continue`, with an optional label.
1758    Continue(Option<Label>),
1759    /// A `return`, with an optional value to be returned.
1760    Ret(Option<P<Expr>>),
1761
1762    /// Output of the `asm!()` macro.
1763    InlineAsm(P<InlineAsm>),
1764
1765    /// An `offset_of` expression (e.g., `builtin # offset_of(Struct, field)`).
1766    ///
1767    /// Usually not written directly in user code but
1768    /// indirectly via the macro `core::mem::offset_of!(...)`.
1769    OffsetOf(P<Ty>, Vec<Ident>),
1770
1771    /// A macro invocation; pre-expansion.
1772    MacCall(P<MacCall>),
1773
1774    /// A struct literal expression.
1775    ///
1776    /// E.g., `Foo {x: 1, y: 2}`, or `Foo {x: 1, .. rest}`.
1777    Struct(P<StructExpr>),
1778
1779    /// An array literal constructed from one repeated element.
1780    ///
1781    /// E.g., `[1; 5]`. The expression is the element to be
1782    /// repeated; the constant is the number of times to repeat it.
1783    Repeat(P<Expr>, AnonConst),
1784
1785    /// No-op: used solely so we can pretty-print faithfully.
1786    Paren(P<Expr>),
1787
1788    /// A try expression (`expr?`).
1789    Try(P<Expr>),
1790
1791    /// A `yield`, with an optional value to be yielded.
1792    Yield(YieldKind),
1793
1794    /// A `do yeet` (aka `throw`/`fail`/`bail`/`raise`/whatever),
1795    /// with an optional value to be returned.
1796    Yeet(Option<P<Expr>>),
1797
1798    /// A tail call return, with the value to be returned.
1799    ///
1800    /// While `.0` must be a function call, we check this later, after parsing.
1801    Become(P<Expr>),
1802
1803    /// Bytes included via `include_bytes!`
1804    /// Added for optimization purposes to avoid the need to escape
1805    /// large binary blobs - should always behave like [`ExprKind::Lit`]
1806    /// with a `ByteStr` literal.
1807    IncludedBytes(Arc<[u8]>),
1808
1809    /// A `format_args!()` expression.
1810    FormatArgs(P<FormatArgs>),
1811
1812    UnsafeBinderCast(UnsafeBinderCastKind, P<Expr>, Option<P<Ty>>),
1813
1814    /// Placeholder for an expression that wasn't syntactically well formed in some way.
1815    Err(ErrorGuaranteed),
1816
1817    /// Acts as a null expression. Lowering it will always emit a bug.
1818    Dummy,
1819}
1820
1821/// Used to differentiate between `for` loops and `for await` loops.
1822#[derive(Clone, Copy, Encodable, Decodable, Debug, PartialEq, Eq)]
1823pub enum ForLoopKind {
1824    For,
1825    ForAwait,
1826}
1827
1828/// Used to differentiate between `async {}` blocks and `gen {}` blocks.
1829#[derive(Clone, Encodable, Decodable, Debug, PartialEq, Eq)]
1830pub enum GenBlockKind {
1831    Async,
1832    Gen,
1833    AsyncGen,
1834}
1835
1836impl fmt::Display for GenBlockKind {
1837    fn fmt(&self, f: &mut fmt::Formatter<'_>) -> fmt::Result {
1838        self.modifier().fmt(f)
1839    }
1840}
1841
1842impl GenBlockKind {
1843    pub fn modifier(&self) -> &'static str {
1844        match self {
1845            GenBlockKind::Async => "async",
1846            GenBlockKind::Gen => "gen",
1847            GenBlockKind::AsyncGen => "async gen",
1848        }
1849    }
1850}
1851
1852/// Whether we're unwrapping or wrapping an unsafe binder
1853#[derive(Copy, Clone, Debug, PartialEq, Eq, Hash)]
1854#[derive(Encodable, Decodable, HashStable_Generic)]
1855pub enum UnsafeBinderCastKind {
1856    // e.g. `&i32` -> `unsafe<'a> &'a i32`
1857    Wrap,
1858    // e.g. `unsafe<'a> &'a i32` -> `&i32`
1859    Unwrap,
1860}
1861
1862/// The explicit `Self` type in a "qualified path". The actual
1863/// path, including the trait and the associated item, is stored
1864/// separately. `position` represents the index of the associated
1865/// item qualified with this `Self` type.
1866///
1867/// ```ignore (only-for-syntax-highlight)
1868/// <Vec<T> as a::b::Trait>::AssociatedItem
1869///  ^~~~~     ~~~~~~~~~~~~~~^
1870///  ty        position = 3
1871///
1872/// <Vec<T>>::AssociatedItem
1873///  ^~~~~    ^
1874///  ty       position = 0
1875/// ```
1876#[derive(Clone, Encodable, Decodable, Debug)]
1877pub struct QSelf {
1878    pub ty: P<Ty>,
1879
1880    /// The span of `a::b::Trait` in a path like `<Vec<T> as
1881    /// a::b::Trait>::AssociatedItem`; in the case where `position ==
1882    /// 0`, this is an empty span.
1883    pub path_span: Span,
1884    pub position: usize,
1885}
1886
1887/// A capture clause used in closures and `async` blocks.
1888#[derive(Clone, Copy, PartialEq, Encodable, Decodable, Debug, HashStable_Generic)]
1889pub enum CaptureBy {
1890    /// `move |x| y + x`.
1891    Value {
1892        /// The span of the `move` keyword.
1893        move_kw: Span,
1894    },
1895    /// `move` or `use` keywords were not specified.
1896    Ref,
1897    /// `use |x| y + x`.
1898    ///
1899    /// Note that if you have a regular closure like `|| x.use`, this will *not* result
1900    /// in a `Use` capture. Instead, the `ExprUseVisitor` will look at the type
1901    /// of `x` and treat `x.use` as either a copy/clone/move as appropriate.
1902    Use {
1903        /// The span of the `use` keyword.
1904        use_kw: Span,
1905    },
1906}
1907
1908/// Closure lifetime binder, `for<'a, 'b>` in `for<'a, 'b> |_: &'a (), _: &'b ()|`.
1909#[derive(Clone, Encodable, Decodable, Debug)]
1910pub enum ClosureBinder {
1911    /// The binder is not present, all closure lifetimes are inferred.
1912    NotPresent,
1913    /// The binder is present.
1914    For {
1915        /// Span of the whole `for<>` clause
1916        ///
1917        /// ```text
1918        /// for<'a, 'b> |_: &'a (), _: &'b ()| { ... }
1919        /// ^^^^^^^^^^^ -- this
1920        /// ```
1921        span: Span,
1922
1923        /// Lifetimes in the `for<>` closure
1924        ///
1925        /// ```text
1926        /// for<'a, 'b> |_: &'a (), _: &'b ()| { ... }
1927        ///     ^^^^^^ -- this
1928        /// ```
1929        generic_params: ThinVec<GenericParam>,
1930    },
1931}
1932
1933/// Represents a macro invocation. The `path` indicates which macro
1934/// is being invoked, and the `args` are arguments passed to it.
1935#[derive(Clone, Encodable, Decodable, Debug)]
1936pub struct MacCall {
1937    pub path: Path,
1938    pub args: P<DelimArgs>,
1939}
1940
1941impl MacCall {
1942    pub fn span(&self) -> Span {
1943        self.path.span.to(self.args.dspan.entire())
1944    }
1945}
1946
1947/// Arguments passed to an attribute macro.
1948#[derive(Clone, Encodable, Decodable, Debug)]
1949pub enum AttrArgs {
1950    /// No arguments: `#[attr]`.
1951    Empty,
1952    /// Delimited arguments: `#[attr()/[]/{}]`.
1953    Delimited(DelimArgs),
1954    /// Arguments of a key-value attribute: `#[attr = "value"]`.
1955    Eq {
1956        /// Span of the `=` token.
1957        eq_span: Span,
1958        expr: P<Expr>,
1959    },
1960}
1961
1962impl AttrArgs {
1963    pub fn span(&self) -> Option<Span> {
1964        match self {
1965            AttrArgs::Empty => None,
1966            AttrArgs::Delimited(args) => Some(args.dspan.entire()),
1967            AttrArgs::Eq { eq_span, expr } => Some(eq_span.to(expr.span)),
1968        }
1969    }
1970
1971    /// Tokens inside the delimiters or after `=`.
1972    /// Proc macros see these tokens, for example.
1973    pub fn inner_tokens(&self) -> TokenStream {
1974        match self {
1975            AttrArgs::Empty => TokenStream::default(),
1976            AttrArgs::Delimited(args) => args.tokens.clone(),
1977            AttrArgs::Eq { expr, .. } => TokenStream::from_ast(expr),
1978        }
1979    }
1980}
1981
1982/// Delimited arguments, as used in `#[attr()/[]/{}]` or `mac!()/[]/{}`.
1983#[derive(Clone, Encodable, Decodable, Debug, HashStable_Generic)]
1984pub struct DelimArgs {
1985    pub dspan: DelimSpan,
1986    pub delim: Delimiter, // Note: `Delimiter::Invisible` never occurs
1987    pub tokens: TokenStream,
1988}
1989
1990impl DelimArgs {
1991    /// Whether a macro with these arguments needs a semicolon
1992    /// when used as a standalone item or statement.
1993    pub fn need_semicolon(&self) -> bool {
1994        !matches!(self, DelimArgs { delim: Delimiter::Brace, .. })
1995    }
1996}
1997
1998/// Represents a macro definition.
1999#[derive(Clone, Encodable, Decodable, Debug, HashStable_Generic)]
2000pub struct MacroDef {
2001    pub body: P<DelimArgs>,
2002    /// `true` if macro was defined with `macro_rules`.
2003    pub macro_rules: bool,
2004}
2005
2006#[derive(Clone, Encodable, Decodable, Debug, Copy, Hash, Eq, PartialEq)]
2007#[derive(HashStable_Generic)]
2008pub enum StrStyle {
2009    /// A regular string, like `"foo"`.
2010    Cooked,
2011    /// A raw string, like `r##"foo"##`.
2012    ///
2013    /// The value is the number of `#` symbols used.
2014    Raw(u8),
2015}
2016
2017/// The kind of match expression
2018#[derive(Clone, Copy, Encodable, Decodable, Debug, PartialEq)]
2019pub enum MatchKind {
2020    /// match expr { ... }
2021    Prefix,
2022    /// expr.match { ... }
2023    Postfix,
2024}
2025
2026/// The kind of yield expression
2027#[derive(Clone, Encodable, Decodable, Debug)]
2028pub enum YieldKind {
2029    /// yield expr { ... }
2030    Prefix(Option<P<Expr>>),
2031    /// expr.yield { ... }
2032    Postfix(P<Expr>),
2033}
2034
2035impl YieldKind {
2036    /// Returns the expression inside the yield expression, if any.
2037    ///
2038    /// For postfix yields, this is guaranteed to be `Some`.
2039    pub const fn expr(&self) -> Option<&P<Expr>> {
2040        match self {
2041            YieldKind::Prefix(expr) => expr.as_ref(),
2042            YieldKind::Postfix(expr) => Some(expr),
2043        }
2044    }
2045
2046    /// Returns a mutable reference to the expression being yielded, if any.
2047    pub const fn expr_mut(&mut self) -> Option<&mut P<Expr>> {
2048        match self {
2049            YieldKind::Prefix(expr) => expr.as_mut(),
2050            YieldKind::Postfix(expr) => Some(expr),
2051        }
2052    }
2053
2054    /// Returns true if both yields are prefix or both are postfix.
2055    pub const fn same_kind(&self, other: &Self) -> bool {
2056        match (self, other) {
2057            (YieldKind::Prefix(_), YieldKind::Prefix(_)) => true,
2058            (YieldKind::Postfix(_), YieldKind::Postfix(_)) => true,
2059            _ => false,
2060        }
2061    }
2062}
2063
2064/// A literal in a meta item.
2065#[derive(Clone, Encodable, Decodable, Debug, HashStable_Generic)]
2066pub struct MetaItemLit {
2067    /// The original literal as written in the source code.
2068    pub symbol: Symbol,
2069    /// The original suffix as written in the source code.
2070    pub suffix: Option<Symbol>,
2071    /// The "semantic" representation of the literal lowered from the original tokens.
2072    /// Strings are unescaped, hexadecimal forms are eliminated, etc.
2073    pub kind: LitKind,
2074    pub span: Span,
2075}
2076
2077/// Similar to `MetaItemLit`, but restricted to string literals.
2078#[derive(Clone, Copy, Encodable, Decodable, Debug)]
2079pub struct StrLit {
2080    /// The original literal as written in source code.
2081    pub symbol: Symbol,
2082    /// The original suffix as written in source code.
2083    pub suffix: Option<Symbol>,
2084    /// The semantic (unescaped) representation of the literal.
2085    pub symbol_unescaped: Symbol,
2086    pub style: StrStyle,
2087    pub span: Span,
2088}
2089
2090impl StrLit {
2091    pub fn as_token_lit(&self) -> token::Lit {
2092        let token_kind = match self.style {
2093            StrStyle::Cooked => token::Str,
2094            StrStyle::Raw(n) => token::StrRaw(n),
2095        };
2096        token::Lit::new(token_kind, self.symbol, self.suffix)
2097    }
2098}
2099
2100/// Type of the integer literal based on provided suffix.
2101#[derive(Clone, Copy, Encodable, Decodable, Debug, Hash, Eq, PartialEq)]
2102#[derive(HashStable_Generic)]
2103pub enum LitIntType {
2104    /// e.g. `42_i32`.
2105    Signed(IntTy),
2106    /// e.g. `42_u32`.
2107    Unsigned(UintTy),
2108    /// e.g. `42`.
2109    Unsuffixed,
2110}
2111
2112/// Type of the float literal based on provided suffix.
2113#[derive(Clone, Copy, Encodable, Decodable, Debug, Hash, Eq, PartialEq)]
2114#[derive(HashStable_Generic)]
2115pub enum LitFloatType {
2116    /// A float literal with a suffix (`1f32` or `1E10f32`).
2117    Suffixed(FloatTy),
2118    /// A float literal without a suffix (`1.0 or 1.0E10`).
2119    Unsuffixed,
2120}
2121
2122/// This type is used within both `ast::MetaItemLit` and `hir::Lit`.
2123///
2124/// Note that the entire literal (including the suffix) is considered when
2125/// deciding the `LitKind`. This means that float literals like `1f32` are
2126/// classified by this type as `Float`. This is different to `token::LitKind`
2127/// which does *not* consider the suffix.
2128#[derive(Clone, Encodable, Decodable, Debug, Hash, Eq, PartialEq, HashStable_Generic)]
2129pub enum LitKind {
2130    /// A string literal (`"foo"`). The symbol is unescaped, and so may differ
2131    /// from the original token's symbol.
2132    Str(Symbol, StrStyle),
2133    /// A byte string (`b"foo"`). Not stored as a symbol because it might be
2134    /// non-utf8, and symbols only allow utf8 strings.
2135    ByteStr(Arc<[u8]>, StrStyle),
2136    /// A C String (`c"foo"`). Guaranteed to only have `\0` at the end.
2137    CStr(Arc<[u8]>, StrStyle),
2138    /// A byte char (`b'f'`).
2139    Byte(u8),
2140    /// A character literal (`'a'`).
2141    Char(char),
2142    /// An integer literal (`1`).
2143    Int(Pu128, LitIntType),
2144    /// A float literal (`1.0`, `1f64` or `1E10f64`). The pre-suffix part is
2145    /// stored as a symbol rather than `f64` so that `LitKind` can impl `Eq`
2146    /// and `Hash`.
2147    Float(Symbol, LitFloatType),
2148    /// A boolean literal (`true`, `false`).
2149    Bool(bool),
2150    /// Placeholder for a literal that wasn't well-formed in some way.
2151    Err(ErrorGuaranteed),
2152}
2153
2154impl LitKind {
2155    pub fn str(&self) -> Option<Symbol> {
2156        match *self {
2157            LitKind::Str(s, _) => Some(s),
2158            _ => None,
2159        }
2160    }
2161
2162    /// Returns `true` if this literal is a string.
2163    pub fn is_str(&self) -> bool {
2164        matches!(self, LitKind::Str(..))
2165    }
2166
2167    /// Returns `true` if this literal is byte literal string.
2168    pub fn is_bytestr(&self) -> bool {
2169        matches!(self, LitKind::ByteStr(..))
2170    }
2171
2172    /// Returns `true` if this is a numeric literal.
2173    pub fn is_numeric(&self) -> bool {
2174        matches!(self, LitKind::Int(..) | LitKind::Float(..))
2175    }
2176
2177    /// Returns `true` if this literal has no suffix.
2178    /// Note: this will return true for literals with prefixes such as raw strings and byte strings.
2179    pub fn is_unsuffixed(&self) -> bool {
2180        !self.is_suffixed()
2181    }
2182
2183    /// Returns `true` if this literal has a suffix.
2184    pub fn is_suffixed(&self) -> bool {
2185        match *self {
2186            // suffixed variants
2187            LitKind::Int(_, LitIntType::Signed(..) | LitIntType::Unsigned(..))
2188            | LitKind::Float(_, LitFloatType::Suffixed(..)) => true,
2189            // unsuffixed variants
2190            LitKind::Str(..)
2191            | LitKind::ByteStr(..)
2192            | LitKind::CStr(..)
2193            | LitKind::Byte(..)
2194            | LitKind::Char(..)
2195            | LitKind::Int(_, LitIntType::Unsuffixed)
2196            | LitKind::Float(_, LitFloatType::Unsuffixed)
2197            | LitKind::Bool(..)
2198            | LitKind::Err(_) => false,
2199        }
2200    }
2201}
2202
2203// N.B., If you change this, you'll probably want to change the corresponding
2204// type structure in `middle/ty.rs` as well.
2205#[derive(Clone, Encodable, Decodable, Debug)]
2206pub struct MutTy {
2207    pub ty: P<Ty>,
2208    pub mutbl: Mutability,
2209}
2210
2211/// Represents a function's signature in a trait declaration,
2212/// trait implementation, or free function.
2213#[derive(Clone, Encodable, Decodable, Debug)]
2214pub struct FnSig {
2215    pub header: FnHeader,
2216    pub decl: P<FnDecl>,
2217    pub span: Span,
2218}
2219
2220#[derive(Clone, Copy, PartialEq, Eq, PartialOrd, Ord, Hash, Debug)]
2221#[derive(Encodable, Decodable, HashStable_Generic)]
2222pub enum FloatTy {
2223    F16,
2224    F32,
2225    F64,
2226    F128,
2227}
2228
2229impl FloatTy {
2230    pub fn name_str(self) -> &'static str {
2231        match self {
2232            FloatTy::F16 => "f16",
2233            FloatTy::F32 => "f32",
2234            FloatTy::F64 => "f64",
2235            FloatTy::F128 => "f128",
2236        }
2237    }
2238
2239    pub fn name(self) -> Symbol {
2240        match self {
2241            FloatTy::F16 => sym::f16,
2242            FloatTy::F32 => sym::f32,
2243            FloatTy::F64 => sym::f64,
2244            FloatTy::F128 => sym::f128,
2245        }
2246    }
2247}
2248
2249#[derive(Clone, Copy, PartialEq, Eq, PartialOrd, Ord, Hash, Debug)]
2250#[derive(Encodable, Decodable, HashStable_Generic)]
2251pub enum IntTy {
2252    Isize,
2253    I8,
2254    I16,
2255    I32,
2256    I64,
2257    I128,
2258}
2259
2260impl IntTy {
2261    pub fn name_str(&self) -> &'static str {
2262        match *self {
2263            IntTy::Isize => "isize",
2264            IntTy::I8 => "i8",
2265            IntTy::I16 => "i16",
2266            IntTy::I32 => "i32",
2267            IntTy::I64 => "i64",
2268            IntTy::I128 => "i128",
2269        }
2270    }
2271
2272    pub fn name(&self) -> Symbol {
2273        match *self {
2274            IntTy::Isize => sym::isize,
2275            IntTy::I8 => sym::i8,
2276            IntTy::I16 => sym::i16,
2277            IntTy::I32 => sym::i32,
2278            IntTy::I64 => sym::i64,
2279            IntTy::I128 => sym::i128,
2280        }
2281    }
2282}
2283
2284#[derive(Clone, PartialEq, Eq, PartialOrd, Ord, Hash, Copy, Debug)]
2285#[derive(Encodable, Decodable, HashStable_Generic)]
2286pub enum UintTy {
2287    Usize,
2288    U8,
2289    U16,
2290    U32,
2291    U64,
2292    U128,
2293}
2294
2295impl UintTy {
2296    pub fn name_str(&self) -> &'static str {
2297        match *self {
2298            UintTy::Usize => "usize",
2299            UintTy::U8 => "u8",
2300            UintTy::U16 => "u16",
2301            UintTy::U32 => "u32",
2302            UintTy::U64 => "u64",
2303            UintTy::U128 => "u128",
2304        }
2305    }
2306
2307    pub fn name(&self) -> Symbol {
2308        match *self {
2309            UintTy::Usize => sym::usize,
2310            UintTy::U8 => sym::u8,
2311            UintTy::U16 => sym::u16,
2312            UintTy::U32 => sym::u32,
2313            UintTy::U64 => sym::u64,
2314            UintTy::U128 => sym::u128,
2315        }
2316    }
2317}
2318
2319/// A constraint on an associated item.
2320///
2321/// ### Examples
2322///
2323/// * the `A = Ty` and `B = Ty` in `Trait<A = Ty, B = Ty>`
2324/// * the `G<Ty> = Ty` in `Trait<G<Ty> = Ty>`
2325/// * the `A: Bound` in `Trait<A: Bound>`
2326/// * the `RetTy` in `Trait(ArgTy, ArgTy) -> RetTy`
2327/// * the `C = { Ct }` in `Trait<C = { Ct }>` (feature `associated_const_equality`)
2328/// * the `f(..): Bound` in `Trait<f(..): Bound>` (feature `return_type_notation`)
2329#[derive(Clone, Encodable, Decodable, Debug)]
2330pub struct AssocItemConstraint {
2331    pub id: NodeId,
2332    pub ident: Ident,
2333    pub gen_args: Option<GenericArgs>,
2334    pub kind: AssocItemConstraintKind,
2335    pub span: Span,
2336}
2337
2338#[derive(Clone, Encodable, Decodable, Debug)]
2339pub enum Term {
2340    Ty(P<Ty>),
2341    Const(AnonConst),
2342}
2343
2344impl From<P<Ty>> for Term {
2345    fn from(v: P<Ty>) -> Self {
2346        Term::Ty(v)
2347    }
2348}
2349
2350impl From<AnonConst> for Term {
2351    fn from(v: AnonConst) -> Self {
2352        Term::Const(v)
2353    }
2354}
2355
2356/// The kind of [associated item constraint][AssocItemConstraint].
2357#[derive(Clone, Encodable, Decodable, Debug)]
2358pub enum AssocItemConstraintKind {
2359    /// An equality constraint for an associated item (e.g., `AssocTy = Ty` in `Trait<AssocTy = Ty>`).
2360    ///
2361    /// Also known as an *associated item binding* (we *bind* an associated item to a term).
2362    ///
2363    /// Furthermore, associated type equality constraints can also be referred to as *associated type
2364    /// bindings*. Similarly with associated const equality constraints and *associated const bindings*.
2365    Equality { term: Term },
2366    /// A bound on an associated type (e.g., `AssocTy: Bound` in `Trait<AssocTy: Bound>`).
2367    Bound { bounds: GenericBounds },
2368}
2369
2370#[derive(Encodable, Decodable, Debug)]
2371pub struct Ty {
2372    pub id: NodeId,
2373    pub kind: TyKind,
2374    pub span: Span,
2375    pub tokens: Option<LazyAttrTokenStream>,
2376}
2377
2378impl Clone for Ty {
2379    fn clone(&self) -> Self {
2380        ensure_sufficient_stack(|| Self {
2381            id: self.id,
2382            kind: self.kind.clone(),
2383            span: self.span,
2384            tokens: self.tokens.clone(),
2385        })
2386    }
2387}
2388
2389impl From<P<Ty>> for Ty {
2390    fn from(value: P<Ty>) -> Self {
2391        *value
2392    }
2393}
2394
2395impl Ty {
2396    pub fn peel_refs(&self) -> &Self {
2397        let mut final_ty = self;
2398        while let TyKind::Ref(_, MutTy { ty, .. }) | TyKind::Ptr(MutTy { ty, .. }) = &final_ty.kind
2399        {
2400            final_ty = ty;
2401        }
2402        final_ty
2403    }
2404
2405    pub fn is_maybe_parenthesised_infer(&self) -> bool {
2406        match &self.kind {
2407            TyKind::Infer => true,
2408            TyKind::Paren(inner) => inner.is_maybe_parenthesised_infer(),
2409            _ => false,
2410        }
2411    }
2412}
2413
2414#[derive(Clone, Encodable, Decodable, Debug)]
2415pub struct BareFnTy {
2416    pub safety: Safety,
2417    pub ext: Extern,
2418    pub generic_params: ThinVec<GenericParam>,
2419    pub decl: P<FnDecl>,
2420    /// Span of the `[unsafe] [extern] fn(...) -> ...` part, i.e. everything
2421    /// after the generic params (if there are any, e.g. `for<'a>`).
2422    pub decl_span: Span,
2423}
2424
2425#[derive(Clone, Encodable, Decodable, Debug)]
2426pub struct UnsafeBinderTy {
2427    pub generic_params: ThinVec<GenericParam>,
2428    pub inner_ty: P<Ty>,
2429}
2430
2431/// The various kinds of type recognized by the compiler.
2432//
2433// Adding a new variant? Please update `test_ty` in `tests/ui/macros/stringify.rs`.
2434#[derive(Clone, Encodable, Decodable, Debug)]
2435pub enum TyKind {
2436    /// A variable-length slice (`[T]`).
2437    Slice(P<Ty>),
2438    /// A fixed length array (`[T; n]`).
2439    Array(P<Ty>, AnonConst),
2440    /// A raw pointer (`*const T` or `*mut T`).
2441    Ptr(MutTy),
2442    /// A reference (`&'a T` or `&'a mut T`).
2443    Ref(Option<Lifetime>, MutTy),
2444    /// A pinned reference (`&'a pin const T` or `&'a pin mut T`).
2445    ///
2446    /// Desugars into `Pin<&'a T>` or `Pin<&'a mut T>`.
2447    PinnedRef(Option<Lifetime>, MutTy),
2448    /// A bare function (e.g., `fn(usize) -> bool`).
2449    BareFn(P<BareFnTy>),
2450    /// An unsafe existential lifetime binder (e.g., `unsafe<'a> &'a ()`).
2451    UnsafeBinder(P<UnsafeBinderTy>),
2452    /// The never type (`!`).
2453    Never,
2454    /// A tuple (`(A, B, C, D,...)`).
2455    Tup(ThinVec<P<Ty>>),
2456    /// A path (`module::module::...::Type`), optionally
2457    /// "qualified", e.g., `<Vec<T> as SomeTrait>::SomeType`.
2458    ///
2459    /// Type parameters are stored in the `Path` itself.
2460    Path(Option<P<QSelf>>, Path),
2461    /// A trait object type `Bound1 + Bound2 + Bound3`
2462    /// where `Bound` is a trait or a lifetime.
2463    TraitObject(GenericBounds, TraitObjectSyntax),
2464    /// An `impl Bound1 + Bound2 + Bound3` type
2465    /// where `Bound` is a trait or a lifetime.
2466    ///
2467    /// The `NodeId` exists to prevent lowering from having to
2468    /// generate `NodeId`s on the fly, which would complicate
2469    /// the generation of opaque `type Foo = impl Trait` items significantly.
2470    ImplTrait(NodeId, GenericBounds),
2471    /// No-op; kept solely so that we can pretty-print faithfully.
2472    Paren(P<Ty>),
2473    /// Unused for now.
2474    Typeof(AnonConst),
2475    /// This means the type should be inferred instead of it having been
2476    /// specified. This can appear anywhere in a type.
2477    Infer,
2478    /// Inferred type of a `self` or `&self` argument in a method.
2479    ImplicitSelf,
2480    /// A macro in the type position.
2481    MacCall(P<MacCall>),
2482    /// Placeholder for a `va_list`.
2483    CVarArgs,
2484    /// Pattern types like `pattern_type!(u32 is 1..=)`, which is the same as `NonZero<u32>`,
2485    /// just as part of the type system.
2486    Pat(P<Ty>, P<TyPat>),
2487    /// Sometimes we need a dummy value when no error has occurred.
2488    Dummy,
2489    /// Placeholder for a kind that has failed to be defined.
2490    Err(ErrorGuaranteed),
2491}
2492
2493impl TyKind {
2494    pub fn is_implicit_self(&self) -> bool {
2495        matches!(self, TyKind::ImplicitSelf)
2496    }
2497
2498    pub fn is_unit(&self) -> bool {
2499        matches!(self, TyKind::Tup(tys) if tys.is_empty())
2500    }
2501
2502    pub fn is_simple_path(&self) -> Option<Symbol> {
2503        if let TyKind::Path(None, Path { segments, .. }) = &self
2504            && let [segment] = &segments[..]
2505            && segment.args.is_none()
2506        {
2507            Some(segment.ident.name)
2508        } else {
2509            None
2510        }
2511    }
2512
2513    /// Returns `true` if this type is considered a scalar primitive (e.g.,
2514    /// `i32`, `u8`, `bool`, etc).
2515    ///
2516    /// This check is based on **symbol equality** and does **not** remove any
2517    /// path prefixes or references. If a type alias or shadowing is present
2518    /// (e.g., `type i32 = CustomType;`), this method will still return `true`
2519    /// for `i32`, even though it may not refer to the primitive type.
2520    pub fn maybe_scalar(&self) -> bool {
2521        let Some(ty_sym) = self.is_simple_path() else {
2522            // unit type
2523            return self.is_unit();
2524        };
2525        matches!(
2526            ty_sym,
2527            sym::i8
2528                | sym::i16
2529                | sym::i32
2530                | sym::i64
2531                | sym::i128
2532                | sym::u8
2533                | sym::u16
2534                | sym::u32
2535                | sym::u64
2536                | sym::u128
2537                | sym::f16
2538                | sym::f32
2539                | sym::f64
2540                | sym::f128
2541                | sym::char
2542                | sym::bool
2543        )
2544    }
2545}
2546
2547/// A pattern type pattern.
2548#[derive(Clone, Encodable, Decodable, Debug)]
2549pub struct TyPat {
2550    pub id: NodeId,
2551    pub kind: TyPatKind,
2552    pub span: Span,
2553    pub tokens: Option<LazyAttrTokenStream>,
2554}
2555
2556/// All the different flavors of pattern that Rust recognizes.
2557//
2558// Adding a new variant? Please update `test_pat` in `tests/ui/macros/stringify.rs`.
2559#[derive(Clone, Encodable, Decodable, Debug)]
2560pub enum TyPatKind {
2561    /// A range pattern (e.g., `1...2`, `1..2`, `1..`, `..2`, `1..=2`, `..=2`).
2562    Range(Option<P<AnonConst>>, Option<P<AnonConst>>, Spanned<RangeEnd>),
2563
2564    Or(ThinVec<P<TyPat>>),
2565
2566    /// Placeholder for a pattern that wasn't syntactically well formed in some way.
2567    Err(ErrorGuaranteed),
2568}
2569
2570/// Syntax used to declare a trait object.
2571#[derive(Clone, Copy, PartialEq, Encodable, Decodable, Debug, HashStable_Generic)]
2572#[repr(u8)]
2573pub enum TraitObjectSyntax {
2574    // SAFETY: When adding new variants make sure to update the `Tag` impl.
2575    Dyn = 0,
2576    DynStar = 1,
2577    None = 2,
2578}
2579
2580/// SAFETY: `TraitObjectSyntax` only has 3 data-less variants which means
2581/// it can be represented with a `u2`. We use `repr(u8)` to guarantee the
2582/// discriminants of the variants are no greater than `3`.
2583unsafe impl Tag for TraitObjectSyntax {
2584    const BITS: u32 = 2;
2585
2586    fn into_usize(self) -> usize {
2587        self as u8 as usize
2588    }
2589
2590    unsafe fn from_usize(tag: usize) -> Self {
2591        match tag {
2592            0 => TraitObjectSyntax::Dyn,
2593            1 => TraitObjectSyntax::DynStar,
2594            2 => TraitObjectSyntax::None,
2595            _ => unreachable!(),
2596        }
2597    }
2598}
2599
2600#[derive(Clone, Encodable, Decodable, Debug)]
2601pub enum PreciseCapturingArg {
2602    /// Lifetime parameter.
2603    Lifetime(Lifetime),
2604    /// Type or const parameter.
2605    Arg(Path, NodeId),
2606}
2607
2608/// Inline assembly operand explicit register or register class.
2609///
2610/// E.g., `"eax"` as in `asm!("mov eax, 2", out("eax") result)`.
2611#[derive(Clone, Copy, Encodable, Decodable, Debug)]
2612pub enum InlineAsmRegOrRegClass {
2613    Reg(Symbol),
2614    RegClass(Symbol),
2615}
2616
2617#[derive(Clone, Copy, PartialEq, Eq, Hash, Encodable, Decodable, HashStable_Generic)]
2618pub struct InlineAsmOptions(u16);
2619bitflags::bitflags! {
2620    impl InlineAsmOptions: u16 {
2621        const PURE            = 1 << 0;
2622        const NOMEM           = 1 << 1;
2623        const READONLY        = 1 << 2;
2624        const PRESERVES_FLAGS = 1 << 3;
2625        const NORETURN        = 1 << 4;
2626        const NOSTACK         = 1 << 5;
2627        const ATT_SYNTAX      = 1 << 6;
2628        const RAW             = 1 << 7;
2629        const MAY_UNWIND      = 1 << 8;
2630    }
2631}
2632
2633impl InlineAsmOptions {
2634    pub const COUNT: usize = Self::all().bits().count_ones() as usize;
2635
2636    pub const GLOBAL_OPTIONS: Self = Self::ATT_SYNTAX.union(Self::RAW);
2637    pub const NAKED_OPTIONS: Self = Self::ATT_SYNTAX.union(Self::RAW);
2638
2639    pub fn human_readable_names(&self) -> Vec<&'static str> {
2640        let mut options = vec![];
2641
2642        if self.contains(InlineAsmOptions::PURE) {
2643            options.push("pure");
2644        }
2645        if self.contains(InlineAsmOptions::NOMEM) {
2646            options.push("nomem");
2647        }
2648        if self.contains(InlineAsmOptions::READONLY) {
2649            options.push("readonly");
2650        }
2651        if self.contains(InlineAsmOptions::PRESERVES_FLAGS) {
2652            options.push("preserves_flags");
2653        }
2654        if self.contains(InlineAsmOptions::NORETURN) {
2655            options.push("noreturn");
2656        }
2657        if self.contains(InlineAsmOptions::NOSTACK) {
2658            options.push("nostack");
2659        }
2660        if self.contains(InlineAsmOptions::ATT_SYNTAX) {
2661            options.push("att_syntax");
2662        }
2663        if self.contains(InlineAsmOptions::RAW) {
2664            options.push("raw");
2665        }
2666        if self.contains(InlineAsmOptions::MAY_UNWIND) {
2667            options.push("may_unwind");
2668        }
2669
2670        options
2671    }
2672}
2673
2674impl std::fmt::Debug for InlineAsmOptions {
2675    fn fmt(&self, f: &mut std::fmt::Formatter<'_>) -> std::fmt::Result {
2676        bitflags::parser::to_writer(self, f)
2677    }
2678}
2679
2680#[derive(Clone, PartialEq, Encodable, Decodable, Debug, Hash, HashStable_Generic)]
2681pub enum InlineAsmTemplatePiece {
2682    String(Cow<'static, str>),
2683    Placeholder { operand_idx: usize, modifier: Option<char>, span: Span },
2684}
2685
2686impl fmt::Display for InlineAsmTemplatePiece {
2687    fn fmt(&self, f: &mut fmt::Formatter<'_>) -> fmt::Result {
2688        match self {
2689            Self::String(s) => {
2690                for c in s.chars() {
2691                    match c {
2692                        '{' => f.write_str("{{")?,
2693                        '}' => f.write_str("}}")?,
2694                        _ => c.fmt(f)?,
2695                    }
2696                }
2697                Ok(())
2698            }
2699            Self::Placeholder { operand_idx, modifier: Some(modifier), .. } => {
2700                write!(f, "{{{operand_idx}:{modifier}}}")
2701            }
2702            Self::Placeholder { operand_idx, modifier: None, .. } => {
2703                write!(f, "{{{operand_idx}}}")
2704            }
2705        }
2706    }
2707}
2708
2709impl InlineAsmTemplatePiece {
2710    /// Rebuilds the asm template string from its pieces.
2711    pub fn to_string(s: &[Self]) -> String {
2712        use fmt::Write;
2713        let mut out = String::new();
2714        for p in s.iter() {
2715            let _ = write!(out, "{p}");
2716        }
2717        out
2718    }
2719}
2720
2721/// Inline assembly symbol operands get their own AST node that is somewhat
2722/// similar to `AnonConst`.
2723///
2724/// The main difference is that we specifically don't assign it `DefId` in
2725/// `DefCollector`. Instead this is deferred until AST lowering where we
2726/// lower it to an `AnonConst` (for functions) or a `Path` (for statics)
2727/// depending on what the path resolves to.
2728#[derive(Clone, Encodable, Decodable, Debug)]
2729pub struct InlineAsmSym {
2730    pub id: NodeId,
2731    pub qself: Option<P<QSelf>>,
2732    pub path: Path,
2733}
2734
2735/// Inline assembly operand.
2736///
2737/// E.g., `out("eax") result` as in `asm!("mov eax, 2", out("eax") result)`.
2738#[derive(Clone, Encodable, Decodable, Debug)]
2739pub enum InlineAsmOperand {
2740    In {
2741        reg: InlineAsmRegOrRegClass,
2742        expr: P<Expr>,
2743    },
2744    Out {
2745        reg: InlineAsmRegOrRegClass,
2746        late: bool,
2747        expr: Option<P<Expr>>,
2748    },
2749    InOut {
2750        reg: InlineAsmRegOrRegClass,
2751        late: bool,
2752        expr: P<Expr>,
2753    },
2754    SplitInOut {
2755        reg: InlineAsmRegOrRegClass,
2756        late: bool,
2757        in_expr: P<Expr>,
2758        out_expr: Option<P<Expr>>,
2759    },
2760    Const {
2761        anon_const: AnonConst,
2762    },
2763    Sym {
2764        sym: InlineAsmSym,
2765    },
2766    Label {
2767        block: P<Block>,
2768    },
2769}
2770
2771impl InlineAsmOperand {
2772    pub fn reg(&self) -> Option<&InlineAsmRegOrRegClass> {
2773        match self {
2774            Self::In { reg, .. }
2775            | Self::Out { reg, .. }
2776            | Self::InOut { reg, .. }
2777            | Self::SplitInOut { reg, .. } => Some(reg),
2778            Self::Const { .. } | Self::Sym { .. } | Self::Label { .. } => None,
2779        }
2780    }
2781}
2782
2783#[derive(Clone, Copy, Encodable, Decodable, Debug, HashStable_Generic)]
2784pub enum AsmMacro {
2785    /// The `asm!` macro
2786    Asm,
2787    /// The `global_asm!` macro
2788    GlobalAsm,
2789    /// The `naked_asm!` macro
2790    NakedAsm,
2791}
2792
2793impl AsmMacro {
2794    pub const fn macro_name(self) -> &'static str {
2795        match self {
2796            AsmMacro::Asm => "asm",
2797            AsmMacro::GlobalAsm => "global_asm",
2798            AsmMacro::NakedAsm => "naked_asm",
2799        }
2800    }
2801
2802    pub const fn is_supported_option(self, option: InlineAsmOptions) -> bool {
2803        match self {
2804            AsmMacro::Asm => true,
2805            AsmMacro::GlobalAsm => InlineAsmOptions::GLOBAL_OPTIONS.contains(option),
2806            AsmMacro::NakedAsm => InlineAsmOptions::NAKED_OPTIONS.contains(option),
2807        }
2808    }
2809
2810    pub const fn diverges(self, options: InlineAsmOptions) -> bool {
2811        match self {
2812            AsmMacro::Asm => options.contains(InlineAsmOptions::NORETURN),
2813            AsmMacro::GlobalAsm => true,
2814            AsmMacro::NakedAsm => true,
2815        }
2816    }
2817}
2818
2819/// Inline assembly.
2820///
2821/// E.g., `asm!("NOP");`.
2822#[derive(Clone, Encodable, Decodable, Debug)]
2823pub struct InlineAsm {
2824    pub asm_macro: AsmMacro,
2825    pub template: Vec<InlineAsmTemplatePiece>,
2826    pub template_strs: Box<[(Symbol, Option<Symbol>, Span)]>,
2827    pub operands: Vec<(InlineAsmOperand, Span)>,
2828    pub clobber_abis: Vec<(Symbol, Span)>,
2829    pub options: InlineAsmOptions,
2830    pub line_spans: Vec<Span>,
2831}
2832
2833/// A parameter in a function header.
2834///
2835/// E.g., `bar: usize` as in `fn foo(bar: usize)`.
2836#[derive(Clone, Encodable, Decodable, Debug)]
2837pub struct Param {
2838    pub attrs: AttrVec,
2839    pub ty: P<Ty>,
2840    pub pat: P<Pat>,
2841    pub id: NodeId,
2842    pub span: Span,
2843    pub is_placeholder: bool,
2844}
2845
2846/// Alternative representation for `Arg`s describing `self` parameter of methods.
2847///
2848/// E.g., `&mut self` as in `fn foo(&mut self)`.
2849#[derive(Clone, Encodable, Decodable, Debug)]
2850pub enum SelfKind {
2851    /// `self`, `mut self`
2852    Value(Mutability),
2853    /// `&'lt self`, `&'lt mut self`
2854    Region(Option<Lifetime>, Mutability),
2855    /// `&'lt pin const self`, `&'lt pin mut self`
2856    Pinned(Option<Lifetime>, Mutability),
2857    /// `self: TYPE`, `mut self: TYPE`
2858    Explicit(P<Ty>, Mutability),
2859}
2860
2861impl SelfKind {
2862    pub fn to_ref_suggestion(&self) -> String {
2863        match self {
2864            SelfKind::Region(None, mutbl) => mutbl.ref_prefix_str().to_string(),
2865            SelfKind::Region(Some(lt), mutbl) => format!("&{lt} {}", mutbl.prefix_str()),
2866            SelfKind::Pinned(None, mutbl) => format!("&pin {}", mutbl.ptr_str()),
2867            SelfKind::Pinned(Some(lt), mutbl) => format!("&{lt} pin {}", mutbl.ptr_str()),
2868            SelfKind::Value(_) | SelfKind::Explicit(_, _) => {
2869                unreachable!("if we had an explicit self, we wouldn't be here")
2870            }
2871        }
2872    }
2873}
2874
2875pub type ExplicitSelf = Spanned<SelfKind>;
2876
2877impl Param {
2878    /// Attempts to cast parameter to `ExplicitSelf`.
2879    pub fn to_self(&self) -> Option<ExplicitSelf> {
2880        if let PatKind::Ident(BindingMode(ByRef::No, mutbl), ident, _) = self.pat.kind {
2881            if ident.name == kw::SelfLower {
2882                return match self.ty.kind {
2883                    TyKind::ImplicitSelf => Some(respan(self.pat.span, SelfKind::Value(mutbl))),
2884                    TyKind::Ref(lt, MutTy { ref ty, mutbl }) if ty.kind.is_implicit_self() => {
2885                        Some(respan(self.pat.span, SelfKind::Region(lt, mutbl)))
2886                    }
2887                    TyKind::PinnedRef(lt, MutTy { ref ty, mutbl })
2888                        if ty.kind.is_implicit_self() =>
2889                    {
2890                        Some(respan(self.pat.span, SelfKind::Pinned(lt, mutbl)))
2891                    }
2892                    _ => Some(respan(
2893                        self.pat.span.to(self.ty.span),
2894                        SelfKind::Explicit(self.ty.clone(), mutbl),
2895                    )),
2896                };
2897            }
2898        }
2899        None
2900    }
2901
2902    /// Returns `true` if parameter is `self`.
2903    pub fn is_self(&self) -> bool {
2904        if let PatKind::Ident(_, ident, _) = self.pat.kind {
2905            ident.name == kw::SelfLower
2906        } else {
2907            false
2908        }
2909    }
2910
2911    /// Builds a `Param` object from `ExplicitSelf`.
2912    pub fn from_self(attrs: AttrVec, eself: ExplicitSelf, eself_ident: Ident) -> Param {
2913        let span = eself.span.to(eself_ident.span);
2914        let infer_ty = P(Ty {
2915            id: DUMMY_NODE_ID,
2916            kind: TyKind::ImplicitSelf,
2917            span: eself_ident.span,
2918            tokens: None,
2919        });
2920        let (mutbl, ty) = match eself.node {
2921            SelfKind::Explicit(ty, mutbl) => (mutbl, ty),
2922            SelfKind::Value(mutbl) => (mutbl, infer_ty),
2923            SelfKind::Region(lt, mutbl) => (
2924                Mutability::Not,
2925                P(Ty {
2926                    id: DUMMY_NODE_ID,
2927                    kind: TyKind::Ref(lt, MutTy { ty: infer_ty, mutbl }),
2928                    span,
2929                    tokens: None,
2930                }),
2931            ),
2932            SelfKind::Pinned(lt, mutbl) => (
2933                mutbl,
2934                P(Ty {
2935                    id: DUMMY_NODE_ID,
2936                    kind: TyKind::PinnedRef(lt, MutTy { ty: infer_ty, mutbl }),
2937                    span,
2938                    tokens: None,
2939                }),
2940            ),
2941        };
2942        Param {
2943            attrs,
2944            pat: P(Pat {
2945                id: DUMMY_NODE_ID,
2946                kind: PatKind::Ident(BindingMode(ByRef::No, mutbl), eself_ident, None),
2947                span,
2948                tokens: None,
2949            }),
2950            span,
2951            ty,
2952            id: DUMMY_NODE_ID,
2953            is_placeholder: false,
2954        }
2955    }
2956}
2957
2958/// A signature (not the body) of a function declaration.
2959///
2960/// E.g., `fn foo(bar: baz)`.
2961///
2962/// Please note that it's different from `FnHeader` structure
2963/// which contains metadata about function safety, asyncness, constness and ABI.
2964#[derive(Clone, Encodable, Decodable, Debug)]
2965pub struct FnDecl {
2966    pub inputs: ThinVec<Param>,
2967    pub output: FnRetTy,
2968}
2969
2970impl FnDecl {
2971    pub fn has_self(&self) -> bool {
2972        self.inputs.get(0).is_some_and(Param::is_self)
2973    }
2974    pub fn c_variadic(&self) -> bool {
2975        self.inputs.last().is_some_and(|arg| matches!(arg.ty.kind, TyKind::CVarArgs))
2976    }
2977}
2978
2979/// Is the trait definition an auto trait?
2980#[derive(Copy, Clone, PartialEq, Encodable, Decodable, Debug, HashStable_Generic)]
2981pub enum IsAuto {
2982    Yes,
2983    No,
2984}
2985
2986/// Safety of items.
2987#[derive(Copy, Clone, PartialEq, Eq, Hash, Encodable, Decodable, Debug)]
2988#[derive(HashStable_Generic)]
2989pub enum Safety {
2990    /// `unsafe` an item is explicitly marked as `unsafe`.
2991    Unsafe(Span),
2992    /// `safe` an item is explicitly marked as `safe`.
2993    Safe(Span),
2994    /// Default means no value was provided, it will take a default value given the context in
2995    /// which is used.
2996    Default,
2997}
2998
2999/// Describes what kind of coroutine markers, if any, a function has.
3000///
3001/// Coroutine markers are things that cause the function to generate a coroutine, such as `async`,
3002/// which makes the function return `impl Future`, or `gen`, which makes the function return `impl
3003/// Iterator`.
3004#[derive(Copy, Clone, Encodable, Decodable, Debug)]
3005pub enum CoroutineKind {
3006    /// `async`, which returns an `impl Future`.
3007    Async { span: Span, closure_id: NodeId, return_impl_trait_id: NodeId },
3008    /// `gen`, which returns an `impl Iterator`.
3009    Gen { span: Span, closure_id: NodeId, return_impl_trait_id: NodeId },
3010    /// `async gen`, which returns an `impl AsyncIterator`.
3011    AsyncGen { span: Span, closure_id: NodeId, return_impl_trait_id: NodeId },
3012}
3013
3014impl CoroutineKind {
3015    pub fn span(self) -> Span {
3016        match self {
3017            CoroutineKind::Async { span, .. } => span,
3018            CoroutineKind::Gen { span, .. } => span,
3019            CoroutineKind::AsyncGen { span, .. } => span,
3020        }
3021    }
3022
3023    pub fn as_str(self) -> &'static str {
3024        match self {
3025            CoroutineKind::Async { .. } => "async",
3026            CoroutineKind::Gen { .. } => "gen",
3027            CoroutineKind::AsyncGen { .. } => "async gen",
3028        }
3029    }
3030
3031    pub fn closure_id(self) -> NodeId {
3032        match self {
3033            CoroutineKind::Async { closure_id, .. }
3034            | CoroutineKind::Gen { closure_id, .. }
3035            | CoroutineKind::AsyncGen { closure_id, .. } => closure_id,
3036        }
3037    }
3038
3039    /// In this case this is an `async` or `gen` return, the `NodeId` for the generated `impl Trait`
3040    /// item.
3041    pub fn return_id(self) -> (NodeId, Span) {
3042        match self {
3043            CoroutineKind::Async { return_impl_trait_id, span, .. }
3044            | CoroutineKind::Gen { return_impl_trait_id, span, .. }
3045            | CoroutineKind::AsyncGen { return_impl_trait_id, span, .. } => {
3046                (return_impl_trait_id, span)
3047            }
3048        }
3049    }
3050}
3051
3052#[derive(Copy, Clone, PartialEq, Eq, Hash, Encodable, Decodable, Debug)]
3053#[derive(HashStable_Generic)]
3054pub enum Const {
3055    Yes(Span),
3056    No,
3057}
3058
3059/// Item defaultness.
3060/// For details see the [RFC #2532](https://github.com/rust-lang/rfcs/pull/2532).
3061#[derive(Copy, Clone, PartialEq, Encodable, Decodable, Debug, HashStable_Generic)]
3062pub enum Defaultness {
3063    Default(Span),
3064    Final,
3065}
3066
3067#[derive(Copy, Clone, PartialEq, Encodable, Decodable, HashStable_Generic)]
3068pub enum ImplPolarity {
3069    /// `impl Trait for Type`
3070    Positive,
3071    /// `impl !Trait for Type`
3072    Negative(Span),
3073}
3074
3075impl fmt::Debug for ImplPolarity {
3076    fn fmt(&self, f: &mut fmt::Formatter<'_>) -> fmt::Result {
3077        match *self {
3078            ImplPolarity::Positive => "positive".fmt(f),
3079            ImplPolarity::Negative(_) => "negative".fmt(f),
3080        }
3081    }
3082}
3083
3084/// The polarity of a trait bound.
3085#[derive(Copy, Clone, PartialEq, Eq, Encodable, Decodable, Debug, Hash)]
3086#[derive(HashStable_Generic)]
3087pub enum BoundPolarity {
3088    /// `Type: Trait`
3089    Positive,
3090    /// `Type: !Trait`
3091    Negative(Span),
3092    /// `Type: ?Trait`
3093    Maybe(Span),
3094}
3095
3096impl BoundPolarity {
3097    pub fn as_str(self) -> &'static str {
3098        match self {
3099            Self::Positive => "",
3100            Self::Negative(_) => "!",
3101            Self::Maybe(_) => "?",
3102        }
3103    }
3104}
3105
3106/// The constness of a trait bound.
3107#[derive(Copy, Clone, PartialEq, Eq, Encodable, Decodable, Debug, Hash)]
3108#[derive(HashStable_Generic)]
3109pub enum BoundConstness {
3110    /// `Type: Trait`
3111    Never,
3112    /// `Type: const Trait`
3113    Always(Span),
3114    /// `Type: ~const Trait`
3115    Maybe(Span),
3116}
3117
3118impl BoundConstness {
3119    pub fn as_str(self) -> &'static str {
3120        match self {
3121            Self::Never => "",
3122            Self::Always(_) => "const",
3123            Self::Maybe(_) => "~const",
3124        }
3125    }
3126}
3127
3128/// The asyncness of a trait bound.
3129#[derive(Copy, Clone, PartialEq, Eq, Encodable, Decodable, Debug)]
3130#[derive(HashStable_Generic)]
3131pub enum BoundAsyncness {
3132    /// `Type: Trait`
3133    Normal,
3134    /// `Type: async Trait`
3135    Async(Span),
3136}
3137
3138impl BoundAsyncness {
3139    pub fn as_str(self) -> &'static str {
3140        match self {
3141            Self::Normal => "",
3142            Self::Async(_) => "async",
3143        }
3144    }
3145}
3146
3147#[derive(Clone, Encodable, Decodable, Debug)]
3148pub enum FnRetTy {
3149    /// Returns type is not specified.
3150    ///
3151    /// Functions default to `()` and closures default to inference.
3152    /// Span points to where return type would be inserted.
3153    Default(Span),
3154    /// Everything else.
3155    Ty(P<Ty>),
3156}
3157
3158impl FnRetTy {
3159    pub fn span(&self) -> Span {
3160        match self {
3161            &FnRetTy::Default(span) => span,
3162            FnRetTy::Ty(ty) => ty.span,
3163        }
3164    }
3165}
3166
3167#[derive(Clone, Copy, PartialEq, Encodable, Decodable, Debug)]
3168pub enum Inline {
3169    Yes,
3170    No,
3171}
3172
3173/// Module item kind.
3174#[derive(Clone, Encodable, Decodable, Debug)]
3175pub enum ModKind {
3176    /// Module with inlined definition `mod foo { ... }`,
3177    /// or with definition outlined to a separate file `mod foo;` and already loaded from it.
3178    /// The inner span is from the first token past `{` to the last token until `}`,
3179    /// or from the first to the last token in the loaded file.
3180    Loaded(ThinVec<P<Item>>, Inline, ModSpans, Result<(), ErrorGuaranteed>),
3181    /// Module with definition outlined to a separate file `mod foo;` but not yet loaded from it.
3182    Unloaded,
3183}
3184
3185#[derive(Copy, Clone, Encodable, Decodable, Debug, Default)]
3186pub struct ModSpans {
3187    /// `inner_span` covers the body of the module; for a file module, its the whole file.
3188    /// For an inline module, its the span inside the `{ ... }`, not including the curly braces.
3189    pub inner_span: Span,
3190    pub inject_use_span: Span,
3191}
3192
3193/// Foreign module declaration.
3194///
3195/// E.g., `extern { .. }` or `extern "C" { .. }`.
3196#[derive(Clone, Encodable, Decodable, Debug)]
3197pub struct ForeignMod {
3198    /// Span of the `extern` keyword.
3199    pub extern_span: Span,
3200    /// `unsafe` keyword accepted syntactically for macro DSLs, but not
3201    /// semantically by Rust.
3202    pub safety: Safety,
3203    pub abi: Option<StrLit>,
3204    pub items: ThinVec<P<ForeignItem>>,
3205}
3206
3207#[derive(Clone, Encodable, Decodable, Debug)]
3208pub struct EnumDef {
3209    pub variants: ThinVec<Variant>,
3210}
3211/// Enum variant.
3212#[derive(Clone, Encodable, Decodable, Debug)]
3213pub struct Variant {
3214    /// Attributes of the variant.
3215    pub attrs: AttrVec,
3216    /// Id of the variant (not the constructor, see `VariantData::ctor_id()`).
3217    pub id: NodeId,
3218    /// Span
3219    pub span: Span,
3220    /// The visibility of the variant. Syntactically accepted but not semantically.
3221    pub vis: Visibility,
3222    /// Name of the variant.
3223    pub ident: Ident,
3224
3225    /// Fields and constructor id of the variant.
3226    pub data: VariantData,
3227    /// Explicit discriminant, e.g., `Foo = 1`.
3228    pub disr_expr: Option<AnonConst>,
3229    /// Is a macro placeholder.
3230    pub is_placeholder: bool,
3231}
3232
3233/// Part of `use` item to the right of its prefix.
3234#[derive(Clone, Encodable, Decodable, Debug)]
3235pub enum UseTreeKind {
3236    /// `use prefix` or `use prefix as rename`
3237    Simple(Option<Ident>),
3238    /// `use prefix::{...}`
3239    ///
3240    /// The span represents the braces of the nested group and all elements within:
3241    ///
3242    /// ```text
3243    /// use foo::{bar, baz};
3244    ///          ^^^^^^^^^^
3245    /// ```
3246    Nested { items: ThinVec<(UseTree, NodeId)>, span: Span },
3247    /// `use prefix::*`
3248    Glob,
3249}
3250
3251/// A tree of paths sharing common prefixes.
3252/// Used in `use` items both at top-level and inside of braces in import groups.
3253#[derive(Clone, Encodable, Decodable, Debug)]
3254pub struct UseTree {
3255    pub prefix: Path,
3256    pub kind: UseTreeKind,
3257    pub span: Span,
3258}
3259
3260impl UseTree {
3261    pub fn ident(&self) -> Ident {
3262        match self.kind {
3263            UseTreeKind::Simple(Some(rename)) => rename,
3264            UseTreeKind::Simple(None) => {
3265                self.prefix.segments.last().expect("empty prefix in a simple import").ident
3266            }
3267            _ => panic!("`UseTree::ident` can only be used on a simple import"),
3268        }
3269    }
3270}
3271
3272/// Distinguishes between `Attribute`s that decorate items and Attributes that
3273/// are contained as statements within items. These two cases need to be
3274/// distinguished for pretty-printing.
3275#[derive(Clone, PartialEq, Encodable, Decodable, Debug, Copy, HashStable_Generic)]
3276pub enum AttrStyle {
3277    Outer,
3278    Inner,
3279}
3280
3281/// A list of attributes.
3282pub type AttrVec = ThinVec<Attribute>;
3283
3284/// A syntax-level representation of an attribute.
3285#[derive(Clone, Encodable, Decodable, Debug)]
3286pub struct Attribute {
3287    pub kind: AttrKind,
3288    pub id: AttrId,
3289    /// Denotes if the attribute decorates the following construct (outer)
3290    /// or the construct this attribute is contained within (inner).
3291    pub style: AttrStyle,
3292    pub span: Span,
3293}
3294
3295#[derive(Clone, Encodable, Decodable, Debug)]
3296pub enum AttrKind {
3297    /// A normal attribute.
3298    Normal(P<NormalAttr>),
3299
3300    /// A doc comment (e.g. `/// ...`, `//! ...`, `/** ... */`, `/*! ... */`).
3301    /// Doc attributes (e.g. `#[doc="..."]`) are represented with the `Normal`
3302    /// variant (which is much less compact and thus more expensive).
3303    DocComment(CommentKind, Symbol),
3304}
3305
3306#[derive(Clone, Encodable, Decodable, Debug)]
3307pub struct NormalAttr {
3308    pub item: AttrItem,
3309    // Tokens for the full attribute, e.g. `#[foo]`, `#![bar]`.
3310    pub tokens: Option<LazyAttrTokenStream>,
3311}
3312
3313impl NormalAttr {
3314    pub fn from_ident(ident: Ident) -> Self {
3315        Self {
3316            item: AttrItem {
3317                unsafety: Safety::Default,
3318                path: Path::from_ident(ident),
3319                args: AttrArgs::Empty,
3320                tokens: None,
3321            },
3322            tokens: None,
3323        }
3324    }
3325}
3326
3327#[derive(Clone, Encodable, Decodable, Debug)]
3328pub struct AttrItem {
3329    pub unsafety: Safety,
3330    pub path: Path,
3331    pub args: AttrArgs,
3332    // Tokens for the meta item, e.g. just the `foo` within `#[foo]` or `#![foo]`.
3333    pub tokens: Option<LazyAttrTokenStream>,
3334}
3335
3336impl AttrItem {
3337    pub fn is_valid_for_outer_style(&self) -> bool {
3338        self.path == sym::cfg_attr
3339            || self.path == sym::cfg
3340            || self.path == sym::forbid
3341            || self.path == sym::warn
3342            || self.path == sym::allow
3343            || self.path == sym::deny
3344    }
3345}
3346
3347/// `TraitRef`s appear in impls.
3348///
3349/// Resolution maps each `TraitRef`'s `ref_id` to its defining trait; that's all
3350/// that the `ref_id` is for. The `impl_id` maps to the "self type" of this impl.
3351/// If this impl is an `ItemKind::Impl`, the `impl_id` is redundant (it could be the
3352/// same as the impl's `NodeId`).
3353#[derive(Clone, Encodable, Decodable, Debug)]
3354pub struct TraitRef {
3355    pub path: Path,
3356    pub ref_id: NodeId,
3357}
3358
3359#[derive(Clone, Encodable, Decodable, Debug)]
3360pub struct PolyTraitRef {
3361    /// The `'a` in `for<'a> Foo<&'a T>`.
3362    pub bound_generic_params: ThinVec<GenericParam>,
3363
3364    // Optional constness, asyncness, or polarity.
3365    pub modifiers: TraitBoundModifiers,
3366
3367    /// The `Foo<&'a T>` in `<'a> Foo<&'a T>`.
3368    pub trait_ref: TraitRef,
3369
3370    pub span: Span,
3371}
3372
3373impl PolyTraitRef {
3374    pub fn new(
3375        generic_params: ThinVec<GenericParam>,
3376        path: Path,
3377        modifiers: TraitBoundModifiers,
3378        span: Span,
3379    ) -> Self {
3380        PolyTraitRef {
3381            bound_generic_params: generic_params,
3382            modifiers,
3383            trait_ref: TraitRef { path, ref_id: DUMMY_NODE_ID },
3384            span,
3385        }
3386    }
3387}
3388
3389#[derive(Clone, Encodable, Decodable, Debug)]
3390pub struct Visibility {
3391    pub kind: VisibilityKind,
3392    pub span: Span,
3393    pub tokens: Option<LazyAttrTokenStream>,
3394}
3395
3396#[derive(Clone, Encodable, Decodable, Debug)]
3397pub enum VisibilityKind {
3398    Public,
3399    Restricted { path: P<Path>, id: NodeId, shorthand: bool },
3400    Inherited,
3401}
3402
3403impl VisibilityKind {
3404    pub fn is_pub(&self) -> bool {
3405        matches!(self, VisibilityKind::Public)
3406    }
3407}
3408
3409/// Field definition in a struct, variant or union.
3410///
3411/// E.g., `bar: usize` as in `struct Foo { bar: usize }`.
3412#[derive(Clone, Encodable, Decodable, Debug)]
3413pub struct FieldDef {
3414    pub attrs: AttrVec,
3415    pub id: NodeId,
3416    pub span: Span,
3417    pub vis: Visibility,
3418    pub safety: Safety,
3419    pub ident: Option<Ident>,
3420
3421    pub ty: P<Ty>,
3422    pub default: Option<AnonConst>,
3423    pub is_placeholder: bool,
3424}
3425
3426/// Was parsing recovery performed?
3427#[derive(Copy, Clone, Debug, Encodable, Decodable, HashStable_Generic)]
3428pub enum Recovered {
3429    No,
3430    Yes(ErrorGuaranteed),
3431}
3432
3433/// Fields and constructor ids of enum variants and structs.
3434#[derive(Clone, Encodable, Decodable, Debug)]
3435pub enum VariantData {
3436    /// Struct variant.
3437    ///
3438    /// E.g., `Bar { .. }` as in `enum Foo { Bar { .. } }`.
3439    Struct { fields: ThinVec<FieldDef>, recovered: Recovered },
3440    /// Tuple variant.
3441    ///
3442    /// E.g., `Bar(..)` as in `enum Foo { Bar(..) }`.
3443    Tuple(ThinVec<FieldDef>, NodeId),
3444    /// Unit variant.
3445    ///
3446    /// E.g., `Bar = ..` as in `enum Foo { Bar = .. }`.
3447    Unit(NodeId),
3448}
3449
3450impl VariantData {
3451    /// Return the fields of this variant.
3452    pub fn fields(&self) -> &[FieldDef] {
3453        match self {
3454            VariantData::Struct { fields, .. } | VariantData::Tuple(fields, _) => fields,
3455            _ => &[],
3456        }
3457    }
3458
3459    /// Return the `NodeId` of this variant's constructor, if it has one.
3460    pub fn ctor_node_id(&self) -> Option<NodeId> {
3461        match *self {
3462            VariantData::Struct { .. } => None,
3463            VariantData::Tuple(_, id) | VariantData::Unit(id) => Some(id),
3464        }
3465    }
3466}
3467
3468/// An item definition.
3469#[derive(Clone, Encodable, Decodable, Debug)]
3470pub struct Item<K = ItemKind> {
3471    pub attrs: AttrVec,
3472    pub id: NodeId,
3473    pub span: Span,
3474    pub vis: Visibility,
3475
3476    pub kind: K,
3477
3478    /// Original tokens this item was parsed from. This isn't necessarily
3479    /// available for all items, although over time more and more items should
3480    /// have this be `Some`. Right now this is primarily used for procedural
3481    /// macros, notably custom attributes.
3482    ///
3483    /// Note that the tokens here do not include the outer attributes, but will
3484    /// include inner attributes.
3485    pub tokens: Option<LazyAttrTokenStream>,
3486}
3487
3488impl Item {
3489    /// Return the span that encompasses the attributes.
3490    pub fn span_with_attributes(&self) -> Span {
3491        self.attrs.iter().fold(self.span, |acc, attr| acc.to(attr.span))
3492    }
3493
3494    pub fn opt_generics(&self) -> Option<&Generics> {
3495        match &self.kind {
3496            ItemKind::ExternCrate(..)
3497            | ItemKind::Use(_)
3498            | ItemKind::Mod(..)
3499            | ItemKind::ForeignMod(_)
3500            | ItemKind::GlobalAsm(_)
3501            | ItemKind::MacCall(_)
3502            | ItemKind::Delegation(_)
3503            | ItemKind::DelegationMac(_)
3504            | ItemKind::MacroDef(..) => None,
3505            ItemKind::Static(_) => None,
3506            ItemKind::Const(i) => Some(&i.generics),
3507            ItemKind::Fn(i) => Some(&i.generics),
3508            ItemKind::TyAlias(i) => Some(&i.generics),
3509            ItemKind::TraitAlias(_, generics, _)
3510            | ItemKind::Enum(_, generics, _)
3511            | ItemKind::Struct(_, generics, _)
3512            | ItemKind::Union(_, generics, _) => Some(&generics),
3513            ItemKind::Trait(i) => Some(&i.generics),
3514            ItemKind::Impl(i) => Some(&i.generics),
3515        }
3516    }
3517}
3518
3519/// `extern` qualifier on a function item or function type.
3520#[derive(Clone, Copy, Encodable, Decodable, Debug)]
3521pub enum Extern {
3522    /// No explicit extern keyword was used.
3523    ///
3524    /// E.g. `fn foo() {}`.
3525    None,
3526    /// An explicit extern keyword was used, but with implicit ABI.
3527    ///
3528    /// E.g. `extern fn foo() {}`.
3529    ///
3530    /// This is just `extern "C"` (see `rustc_abi::ExternAbi::FALLBACK`).
3531    Implicit(Span),
3532    /// An explicit extern keyword was used with an explicit ABI.
3533    ///
3534    /// E.g. `extern "C" fn foo() {}`.
3535    Explicit(StrLit, Span),
3536}
3537
3538impl Extern {
3539    pub fn from_abi(abi: Option<StrLit>, span: Span) -> Extern {
3540        match abi {
3541            Some(name) => Extern::Explicit(name, span),
3542            None => Extern::Implicit(span),
3543        }
3544    }
3545}
3546
3547/// A function header.
3548///
3549/// All the information between the visibility and the name of the function is
3550/// included in this struct (e.g., `async unsafe fn` or `const extern "C" fn`).
3551#[derive(Clone, Copy, Encodable, Decodable, Debug)]
3552pub struct FnHeader {
3553    /// Whether this is `unsafe`, or has a default safety.
3554    pub safety: Safety,
3555    /// Whether this is `async`, `gen`, or nothing.
3556    pub coroutine_kind: Option<CoroutineKind>,
3557    /// The `const` keyword, if any
3558    pub constness: Const,
3559    /// The `extern` keyword and corresponding ABI string, if any.
3560    pub ext: Extern,
3561}
3562
3563impl FnHeader {
3564    /// Does this function header have any qualifiers or is it empty?
3565    pub fn has_qualifiers(&self) -> bool {
3566        let Self { safety, coroutine_kind, constness, ext } = self;
3567        matches!(safety, Safety::Unsafe(_))
3568            || coroutine_kind.is_some()
3569            || matches!(constness, Const::Yes(_))
3570            || !matches!(ext, Extern::None)
3571    }
3572
3573    /// Return a span encompassing the header, or none if all options are default.
3574    pub fn span(&self) -> Option<Span> {
3575        fn append(a: &mut Option<Span>, b: Span) {
3576            *a = match a {
3577                None => Some(b),
3578                Some(x) => Some(x.to(b)),
3579            }
3580        }
3581
3582        let mut full_span = None;
3583
3584        match self.safety {
3585            Safety::Unsafe(span) | Safety::Safe(span) => append(&mut full_span, span),
3586            Safety::Default => {}
3587        };
3588
3589        if let Some(coroutine_kind) = self.coroutine_kind {
3590            append(&mut full_span, coroutine_kind.span());
3591        }
3592
3593        if let Const::Yes(span) = self.constness {
3594            append(&mut full_span, span);
3595        }
3596
3597        match self.ext {
3598            Extern::Implicit(span) | Extern::Explicit(_, span) => append(&mut full_span, span),
3599            Extern::None => {}
3600        }
3601
3602        full_span
3603    }
3604}
3605
3606impl Default for FnHeader {
3607    fn default() -> FnHeader {
3608        FnHeader {
3609            safety: Safety::Default,
3610            coroutine_kind: None,
3611            constness: Const::No,
3612            ext: Extern::None,
3613        }
3614    }
3615}
3616
3617#[derive(Clone, Encodable, Decodable, Debug)]
3618pub struct Trait {
3619    pub safety: Safety,
3620    pub is_auto: IsAuto,
3621    pub ident: Ident,
3622    pub generics: Generics,
3623    pub bounds: GenericBounds,
3624    pub items: ThinVec<P<AssocItem>>,
3625}
3626
3627/// The location of a where clause on a `TyAlias` (`Span`) and whether there was
3628/// a `where` keyword (`bool`). This is split out from `WhereClause`, since there
3629/// are two locations for where clause on type aliases, but their predicates
3630/// are concatenated together.
3631///
3632/// Take this example:
3633/// ```ignore (only-for-syntax-highlight)
3634/// trait Foo {
3635///   type Assoc<'a, 'b> where Self: 'a, Self: 'b;
3636/// }
3637/// impl Foo for () {
3638///   type Assoc<'a, 'b> where Self: 'a = () where Self: 'b;
3639///   //                 ^^^^^^^^^^^^^^ first where clause
3640///   //                                     ^^^^^^^^^^^^^^ second where clause
3641/// }
3642/// ```
3643///
3644/// If there is no where clause, then this is `false` with `DUMMY_SP`.
3645#[derive(Copy, Clone, Encodable, Decodable, Debug, Default)]
3646pub struct TyAliasWhereClause {
3647    pub has_where_token: bool,
3648    pub span: Span,
3649}
3650
3651/// The span information for the two where clauses on a `TyAlias`.
3652#[derive(Copy, Clone, Encodable, Decodable, Debug, Default)]
3653pub struct TyAliasWhereClauses {
3654    /// Before the equals sign.
3655    pub before: TyAliasWhereClause,
3656    /// After the equals sign.
3657    pub after: TyAliasWhereClause,
3658    /// The index in `TyAlias.generics.where_clause.predicates` that would split
3659    /// into predicates from the where clause before the equals sign and the ones
3660    /// from the where clause after the equals sign.
3661    pub split: usize,
3662}
3663
3664#[derive(Clone, Encodable, Decodable, Debug)]
3665pub struct TyAlias {
3666    pub defaultness: Defaultness,
3667    pub ident: Ident,
3668    pub generics: Generics,
3669    pub where_clauses: TyAliasWhereClauses,
3670    pub bounds: GenericBounds,
3671    pub ty: Option<P<Ty>>,
3672}
3673
3674#[derive(Clone, Encodable, Decodable, Debug)]
3675pub struct Impl {
3676    pub defaultness: Defaultness,
3677    pub safety: Safety,
3678    pub generics: Generics,
3679    pub constness: Const,
3680    pub polarity: ImplPolarity,
3681    /// The trait being implemented, if any.
3682    pub of_trait: Option<TraitRef>,
3683    pub self_ty: P<Ty>,
3684    pub items: ThinVec<P<AssocItem>>,
3685}
3686
3687#[derive(Clone, Encodable, Decodable, Debug, Default)]
3688pub struct FnContract {
3689    pub requires: Option<P<Expr>>,
3690    pub ensures: Option<P<Expr>>,
3691}
3692
3693#[derive(Clone, Encodable, Decodable, Debug)]
3694pub struct Fn {
3695    pub defaultness: Defaultness,
3696    pub ident: Ident,
3697    pub generics: Generics,
3698    pub sig: FnSig,
3699    pub contract: Option<P<FnContract>>,
3700    pub define_opaque: Option<ThinVec<(NodeId, Path)>>,
3701    pub body: Option<P<Block>>,
3702}
3703
3704#[derive(Clone, Encodable, Decodable, Debug)]
3705pub struct Delegation {
3706    /// Path resolution id.
3707    pub id: NodeId,
3708    pub qself: Option<P<QSelf>>,
3709    pub path: Path,
3710    pub ident: Ident,
3711    pub rename: Option<Ident>,
3712    pub body: Option<P<Block>>,
3713    /// The item was expanded from a glob delegation item.
3714    pub from_glob: bool,
3715}
3716
3717#[derive(Clone, Encodable, Decodable, Debug)]
3718pub struct DelegationMac {
3719    pub qself: Option<P<QSelf>>,
3720    pub prefix: Path,
3721    // Some for list delegation, and None for glob delegation.
3722    pub suffixes: Option<ThinVec<(Ident, Option<Ident>)>>,
3723    pub body: Option<P<Block>>,
3724}
3725
3726#[derive(Clone, Encodable, Decodable, Debug)]
3727pub struct StaticItem {
3728    pub ident: Ident,
3729    pub ty: P<Ty>,
3730    pub safety: Safety,
3731    pub mutability: Mutability,
3732    pub expr: Option<P<Expr>>,
3733    pub define_opaque: Option<ThinVec<(NodeId, Path)>>,
3734}
3735
3736#[derive(Clone, Encodable, Decodable, Debug)]
3737pub struct ConstItem {
3738    pub defaultness: Defaultness,
3739    pub ident: Ident,
3740    pub generics: Generics,
3741    pub ty: P<Ty>,
3742    pub expr: Option<P<Expr>>,
3743    pub define_opaque: Option<ThinVec<(NodeId, Path)>>,
3744}
3745
3746// Adding a new variant? Please update `test_item` in `tests/ui/macros/stringify.rs`.
3747#[derive(Clone, Encodable, Decodable, Debug)]
3748pub enum ItemKind {
3749    /// An `extern crate` item, with the optional *original* crate name if the crate was renamed.
3750    ///
3751    /// E.g., `extern crate foo` or `extern crate foo_bar as foo`.
3752    ExternCrate(Option<Symbol>, Ident),
3753    /// A use declaration item (`use`).
3754    ///
3755    /// E.g., `use foo;`, `use foo::bar;` or `use foo::bar as FooBar;`.
3756    Use(UseTree),
3757    /// A static item (`static`).
3758    ///
3759    /// E.g., `static FOO: i32 = 42;` or `static FOO: &'static str = "bar";`.
3760    Static(Box<StaticItem>),
3761    /// A constant item (`const`).
3762    ///
3763    /// E.g., `const FOO: i32 = 42;`.
3764    Const(Box<ConstItem>),
3765    /// A function declaration (`fn`).
3766    ///
3767    /// E.g., `fn foo(bar: usize) -> usize { .. }`.
3768    Fn(Box<Fn>),
3769    /// A module declaration (`mod`).
3770    ///
3771    /// E.g., `mod foo;` or `mod foo { .. }`.
3772    /// `unsafe` keyword on modules is accepted syntactically for macro DSLs, but not
3773    /// semantically by Rust.
3774    Mod(Safety, Ident, ModKind),
3775    /// An external module (`extern`).
3776    ///
3777    /// E.g., `extern {}` or `extern "C" {}`.
3778    ForeignMod(ForeignMod),
3779    /// Module-level inline assembly (from `global_asm!()`).
3780    GlobalAsm(Box<InlineAsm>),
3781    /// A type alias (`type`).
3782    ///
3783    /// E.g., `type Foo = Bar<u8>;`.
3784    TyAlias(Box<TyAlias>),
3785    /// An enum definition (`enum`).
3786    ///
3787    /// E.g., `enum Foo<A, B> { C<A>, D<B> }`.
3788    Enum(Ident, Generics, EnumDef),
3789    /// A struct definition (`struct`).
3790    ///
3791    /// E.g., `struct Foo<A> { x: A }`.
3792    Struct(Ident, Generics, VariantData),
3793    /// A union definition (`union`).
3794    ///
3795    /// E.g., `union Foo<A, B> { x: A, y: B }`.
3796    Union(Ident, Generics, VariantData),
3797    /// A trait declaration (`trait`).
3798    ///
3799    /// E.g., `trait Foo { .. }`, `trait Foo<T> { .. }` or `auto trait Foo {}`.
3800    Trait(Box<Trait>),
3801    /// Trait alias.
3802    ///
3803    /// E.g., `trait Foo = Bar + Quux;`.
3804    TraitAlias(Ident, Generics, GenericBounds),
3805    /// An implementation.
3806    ///
3807    /// E.g., `impl<A> Foo<A> { .. }` or `impl<A> Trait for Foo<A> { .. }`.
3808    Impl(Box<Impl>),
3809    /// A macro invocation.
3810    ///
3811    /// E.g., `foo!(..)`.
3812    MacCall(P<MacCall>),
3813    /// A macro definition.
3814    MacroDef(Ident, MacroDef),
3815    /// A single delegation item (`reuse`).
3816    ///
3817    /// E.g. `reuse <Type as Trait>::name { target_expr_template }`.
3818    Delegation(Box<Delegation>),
3819    /// A list or glob delegation item (`reuse prefix::{a, b, c}`, `reuse prefix::*`).
3820    /// Treated similarly to a macro call and expanded early.
3821    DelegationMac(Box<DelegationMac>),
3822}
3823
3824impl ItemKind {
3825    pub fn ident(&self) -> Option<Ident> {
3826        match *self {
3827            ItemKind::ExternCrate(_, ident)
3828            | ItemKind::Static(box StaticItem { ident, .. })
3829            | ItemKind::Const(box ConstItem { ident, .. })
3830            | ItemKind::Fn(box Fn { ident, .. })
3831            | ItemKind::Mod(_, ident, _)
3832            | ItemKind::TyAlias(box TyAlias { ident, .. })
3833            | ItemKind::Enum(ident, ..)
3834            | ItemKind::Struct(ident, ..)
3835            | ItemKind::Union(ident, ..)
3836            | ItemKind::Trait(box Trait { ident, .. })
3837            | ItemKind::TraitAlias(ident, ..)
3838            | ItemKind::MacroDef(ident, _)
3839            | ItemKind::Delegation(box Delegation { ident, .. }) => Some(ident),
3840
3841            ItemKind::Use(_)
3842            | ItemKind::ForeignMod(_)
3843            | ItemKind::GlobalAsm(_)
3844            | ItemKind::Impl(_)
3845            | ItemKind::MacCall(_)
3846            | ItemKind::DelegationMac(_) => None,
3847        }
3848    }
3849
3850    /// "a" or "an"
3851    pub fn article(&self) -> &'static str {
3852        use ItemKind::*;
3853        match self {
3854            Use(..) | Static(..) | Const(..) | Fn(..) | Mod(..) | GlobalAsm(..) | TyAlias(..)
3855            | Struct(..) | Union(..) | Trait(..) | TraitAlias(..) | MacroDef(..)
3856            | Delegation(..) | DelegationMac(..) => "a",
3857            ExternCrate(..) | ForeignMod(..) | MacCall(..) | Enum(..) | Impl { .. } => "an",
3858        }
3859    }
3860
3861    pub fn descr(&self) -> &'static str {
3862        match self {
3863            ItemKind::ExternCrate(..) => "extern crate",
3864            ItemKind::Use(..) => "`use` import",
3865            ItemKind::Static(..) => "static item",
3866            ItemKind::Const(..) => "constant item",
3867            ItemKind::Fn(..) => "function",
3868            ItemKind::Mod(..) => "module",
3869            ItemKind::ForeignMod(..) => "extern block",
3870            ItemKind::GlobalAsm(..) => "global asm item",
3871            ItemKind::TyAlias(..) => "type alias",
3872            ItemKind::Enum(..) => "enum",
3873            ItemKind::Struct(..) => "struct",
3874            ItemKind::Union(..) => "union",
3875            ItemKind::Trait(..) => "trait",
3876            ItemKind::TraitAlias(..) => "trait alias",
3877            ItemKind::MacCall(..) => "item macro invocation",
3878            ItemKind::MacroDef(..) => "macro definition",
3879            ItemKind::Impl { .. } => "implementation",
3880            ItemKind::Delegation(..) => "delegated function",
3881            ItemKind::DelegationMac(..) => "delegation",
3882        }
3883    }
3884
3885    pub fn generics(&self) -> Option<&Generics> {
3886        match self {
3887            Self::Fn(box Fn { generics, .. })
3888            | Self::TyAlias(box TyAlias { generics, .. })
3889            | Self::Const(box ConstItem { generics, .. })
3890            | Self::Enum(_, generics, _)
3891            | Self::Struct(_, generics, _)
3892            | Self::Union(_, generics, _)
3893            | Self::Trait(box Trait { generics, .. })
3894            | Self::TraitAlias(_, generics, _)
3895            | Self::Impl(box Impl { generics, .. }) => Some(generics),
3896            _ => None,
3897        }
3898    }
3899}
3900
3901/// Represents associated items.
3902/// These include items in `impl` and `trait` definitions.
3903pub type AssocItem = Item<AssocItemKind>;
3904
3905/// Represents associated item kinds.
3906///
3907/// The term "provided" in the variants below refers to the item having a default
3908/// definition / body. Meanwhile, a "required" item lacks a definition / body.
3909/// In an implementation, all items must be provided.
3910/// The `Option`s below denote the bodies, where `Some(_)`
3911/// means "provided" and conversely `None` means "required".
3912#[derive(Clone, Encodable, Decodable, Debug)]
3913pub enum AssocItemKind {
3914    /// An associated constant, `const $ident: $ty $def?;` where `def ::= "=" $expr? ;`.
3915    /// If `def` is parsed, then the constant is provided, and otherwise required.
3916    Const(Box<ConstItem>),
3917    /// An associated function.
3918    Fn(Box<Fn>),
3919    /// An associated type.
3920    Type(Box<TyAlias>),
3921    /// A macro expanding to associated items.
3922    MacCall(P<MacCall>),
3923    /// An associated delegation item.
3924    Delegation(Box<Delegation>),
3925    /// An associated list or glob delegation item.
3926    DelegationMac(Box<DelegationMac>),
3927}
3928
3929impl AssocItemKind {
3930    pub fn ident(&self) -> Option<Ident> {
3931        match *self {
3932            AssocItemKind::Const(box ConstItem { ident, .. })
3933            | AssocItemKind::Fn(box Fn { ident, .. })
3934            | AssocItemKind::Type(box TyAlias { ident, .. })
3935            | AssocItemKind::Delegation(box Delegation { ident, .. }) => Some(ident),
3936
3937            AssocItemKind::MacCall(_) | AssocItemKind::DelegationMac(_) => None,
3938        }
3939    }
3940
3941    pub fn defaultness(&self) -> Defaultness {
3942        match *self {
3943            Self::Const(box ConstItem { defaultness, .. })
3944            | Self::Fn(box Fn { defaultness, .. })
3945            | Self::Type(box TyAlias { defaultness, .. }) => defaultness,
3946            Self::MacCall(..) | Self::Delegation(..) | Self::DelegationMac(..) => {
3947                Defaultness::Final
3948            }
3949        }
3950    }
3951}
3952
3953impl From<AssocItemKind> for ItemKind {
3954    fn from(assoc_item_kind: AssocItemKind) -> ItemKind {
3955        match assoc_item_kind {
3956            AssocItemKind::Const(item) => ItemKind::Const(item),
3957            AssocItemKind::Fn(fn_kind) => ItemKind::Fn(fn_kind),
3958            AssocItemKind::Type(ty_alias_kind) => ItemKind::TyAlias(ty_alias_kind),
3959            AssocItemKind::MacCall(a) => ItemKind::MacCall(a),
3960            AssocItemKind::Delegation(delegation) => ItemKind::Delegation(delegation),
3961            AssocItemKind::DelegationMac(delegation) => ItemKind::DelegationMac(delegation),
3962        }
3963    }
3964}
3965
3966impl TryFrom<ItemKind> for AssocItemKind {
3967    type Error = ItemKind;
3968
3969    fn try_from(item_kind: ItemKind) -> Result<AssocItemKind, ItemKind> {
3970        Ok(match item_kind {
3971            ItemKind::Const(item) => AssocItemKind::Const(item),
3972            ItemKind::Fn(fn_kind) => AssocItemKind::Fn(fn_kind),
3973            ItemKind::TyAlias(ty_kind) => AssocItemKind::Type(ty_kind),
3974            ItemKind::MacCall(a) => AssocItemKind::MacCall(a),
3975            ItemKind::Delegation(d) => AssocItemKind::Delegation(d),
3976            ItemKind::DelegationMac(d) => AssocItemKind::DelegationMac(d),
3977            _ => return Err(item_kind),
3978        })
3979    }
3980}
3981
3982/// An item in `extern` block.
3983#[derive(Clone, Encodable, Decodable, Debug)]
3984pub enum ForeignItemKind {
3985    /// A foreign static item (`static FOO: u8`).
3986    Static(Box<StaticItem>),
3987    /// A foreign function.
3988    Fn(Box<Fn>),
3989    /// A foreign type.
3990    TyAlias(Box<TyAlias>),
3991    /// A macro expanding to foreign items.
3992    MacCall(P<MacCall>),
3993}
3994
3995impl ForeignItemKind {
3996    pub fn ident(&self) -> Option<Ident> {
3997        match *self {
3998            ForeignItemKind::Static(box StaticItem { ident, .. })
3999            | ForeignItemKind::Fn(box Fn { ident, .. })
4000            | ForeignItemKind::TyAlias(box TyAlias { ident, .. }) => Some(ident),
4001
4002            ForeignItemKind::MacCall(_) => None,
4003        }
4004    }
4005}
4006
4007impl From<ForeignItemKind> for ItemKind {
4008    fn from(foreign_item_kind: ForeignItemKind) -> ItemKind {
4009        match foreign_item_kind {
4010            ForeignItemKind::Static(box static_foreign_item) => {
4011                ItemKind::Static(Box::new(static_foreign_item))
4012            }
4013            ForeignItemKind::Fn(fn_kind) => ItemKind::Fn(fn_kind),
4014            ForeignItemKind::TyAlias(ty_alias_kind) => ItemKind::TyAlias(ty_alias_kind),
4015            ForeignItemKind::MacCall(a) => ItemKind::MacCall(a),
4016        }
4017    }
4018}
4019
4020impl TryFrom<ItemKind> for ForeignItemKind {
4021    type Error = ItemKind;
4022
4023    fn try_from(item_kind: ItemKind) -> Result<ForeignItemKind, ItemKind> {
4024        Ok(match item_kind {
4025            ItemKind::Static(box static_item) => ForeignItemKind::Static(Box::new(static_item)),
4026            ItemKind::Fn(fn_kind) => ForeignItemKind::Fn(fn_kind),
4027            ItemKind::TyAlias(ty_alias_kind) => ForeignItemKind::TyAlias(ty_alias_kind),
4028            ItemKind::MacCall(a) => ForeignItemKind::MacCall(a),
4029            _ => return Err(item_kind),
4030        })
4031    }
4032}
4033
4034pub type ForeignItem = Item<ForeignItemKind>;
4035
4036// Some nodes are used a lot. Make sure they don't unintentionally get bigger.
4037#[cfg(target_pointer_width = "64")]
4038mod size_asserts {
4039    use rustc_data_structures::static_assert_size;
4040
4041    use super::*;
4042    // tidy-alphabetical-start
4043    static_assert_size!(AssocItem, 80);
4044    static_assert_size!(AssocItemKind, 16);
4045    static_assert_size!(Attribute, 32);
4046    static_assert_size!(Block, 32);
4047    static_assert_size!(Expr, 72);
4048    static_assert_size!(ExprKind, 40);
4049    static_assert_size!(Fn, 184);
4050    static_assert_size!(ForeignItem, 80);
4051    static_assert_size!(ForeignItemKind, 16);
4052    static_assert_size!(GenericArg, 24);
4053    static_assert_size!(GenericBound, 88);
4054    static_assert_size!(Generics, 40);
4055    static_assert_size!(Impl, 136);
4056    static_assert_size!(Item, 144);
4057    static_assert_size!(ItemKind, 80);
4058    static_assert_size!(LitKind, 24);
4059    static_assert_size!(Local, 96);
4060    static_assert_size!(MetaItemLit, 40);
4061    static_assert_size!(Param, 40);
4062    static_assert_size!(Pat, 72);
4063    static_assert_size!(Path, 24);
4064    static_assert_size!(PathSegment, 24);
4065    static_assert_size!(PatKind, 48);
4066    static_assert_size!(Stmt, 32);
4067    static_assert_size!(StmtKind, 16);
4068    static_assert_size!(Ty, 64);
4069    static_assert_size!(TyKind, 40);
4070    // tidy-alphabetical-end
4071}