// Copyright 2015 The Rust Project Developers. See the COPYRIGHT // file at the top-level directory of this distribution and at // http://rust-lang.org/COPYRIGHT. // // Licensed under the Apache License, Version 2.0 or the MIT license // , at your // option. This file may not be copied, modified, or distributed // except according to those terms. // The Rust HIR. pub use self::BinOp_::*; pub use self::BlockCheckMode::*; pub use self::CaptureClause::*; pub use self::Decl_::*; pub use self::Expr_::*; pub use self::FunctionRetTy::*; pub use self::ForeignItem_::*; pub use self::Item_::*; pub use self::Mutability::*; pub use self::PrimTy::*; pub use self::Stmt_::*; pub use self::Ty_::*; pub use self::TyParamBound::*; pub use self::UnOp::*; pub use self::UnsafeSource::*; pub use self::Visibility::{Public, Inherited}; use hir::def::Def; use hir::def_id::{DefId, DefIndex, LocalDefId, CRATE_DEF_INDEX}; use util::nodemap::{NodeMap, FxHashSet}; use mir::mono::Linkage; use syntax_pos::{Span, DUMMY_SP}; use syntax::codemap::{self, Spanned}; use syntax::abi::Abi; use syntax::ast::{self, Name, NodeId, DUMMY_NODE_ID, AsmDialect}; use syntax::ast::{Attribute, Lit, StrStyle, FloatTy, IntTy, UintTy, MetaItem}; use syntax::attr::InlineAttr; use syntax::ext::hygiene::SyntaxContext; use syntax::ptr::P; use syntax::symbol::{Symbol, keywords}; use syntax::tokenstream::TokenStream; use syntax::util::ThinVec; use syntax::util::parser::ExprPrecedence; use ty::AdtKind; use ty::maps::Providers; use rustc_data_structures::indexed_vec; use serialize::{self, Encoder, Encodable, Decoder, Decodable}; use std::collections::BTreeMap; use std::fmt; use std::iter; use std::slice; /// HIR doesn't commit to a concrete storage type and has its own alias for a vector. /// It can be `Vec`, `P<[T]>` or potentially `Box<[T]>`, or some other container with similar /// behavior. Unlike AST, HIR is mostly a static structure, so we can use an owned slice instead /// of `Vec` to avoid keeping extra capacity. pub type HirVec = P<[T]>; macro_rules! hir_vec { ($elem:expr; $n:expr) => ( $crate::hir::HirVec::from(vec![$elem; $n]) ); ($($x:expr),*) => ( $crate::hir::HirVec::from(vec![$($x),*]) ); ($($x:expr,)*) => (hir_vec![$($x),*]) } pub mod check_attr; pub mod def; pub mod def_id; pub mod intravisit; pub mod itemlikevisit; pub mod lowering; pub mod map; pub mod pat_util; pub mod print; pub mod svh; /// A HirId uniquely identifies a node in the HIR of the current crate. It is /// composed of the `owner`, which is the DefIndex of the directly enclosing /// hir::Item, hir::TraitItem, or hir::ImplItem (i.e. the closest "item-like"), /// and the `local_id` which is unique within the given owner. /// /// This two-level structure makes for more stable values: One can move an item /// around within the source code, or add or remove stuff before it, without /// the local_id part of the HirId changing, which is a very useful property in /// incremental compilation where we have to persist things through changes to /// the code base. #[derive(Copy, Clone, PartialEq, Eq, Hash, PartialOrd, Ord, Debug)] pub struct HirId { pub owner: DefIndex, pub local_id: ItemLocalId, } impl HirId { pub fn owner_def_id(self) -> DefId { DefId::local(self.owner) } pub fn owner_local_def_id(self) -> LocalDefId { LocalDefId::from_def_id(DefId::local(self.owner)) } } impl serialize::UseSpecializedEncodable for HirId { fn default_encode(&self, s: &mut S) -> Result<(), S::Error> { let HirId { owner, local_id, } = *self; owner.encode(s)?; local_id.encode(s) } } impl serialize::UseSpecializedDecodable for HirId { fn default_decode(d: &mut D) -> Result { let owner = DefIndex::decode(d)?; let local_id = ItemLocalId::decode(d)?; Ok(HirId { owner, local_id }) } } /// An `ItemLocalId` uniquely identifies something within a given "item-like", /// that is within a hir::Item, hir::TraitItem, or hir::ImplItem. There is no /// guarantee that the numerical value of a given `ItemLocalId` corresponds to /// the node's position within the owning item in any way, but there is a /// guarantee that the `LocalItemId`s within an owner occupy a dense range of /// integers starting at zero, so a mapping that maps all or most nodes within /// an "item-like" to something else can be implement by a `Vec` instead of a /// tree or hash map. #[derive(Copy, Clone, PartialEq, Eq, Hash, PartialOrd, Ord, Debug, RustcEncodable, RustcDecodable)] pub struct ItemLocalId(pub u32); impl ItemLocalId { pub fn as_usize(&self) -> usize { self.0 as usize } } impl indexed_vec::Idx for ItemLocalId { fn new(idx: usize) -> Self { debug_assert!((idx as u32) as usize == idx); ItemLocalId(idx as u32) } fn index(self) -> usize { self.0 as usize } } /// The `HirId` corresponding to CRATE_NODE_ID and CRATE_DEF_INDEX pub const CRATE_HIR_ID: HirId = HirId { owner: CRATE_DEF_INDEX, local_id: ItemLocalId(0) }; pub const DUMMY_HIR_ID: HirId = HirId { owner: CRATE_DEF_INDEX, local_id: DUMMY_ITEM_LOCAL_ID, }; pub const DUMMY_ITEM_LOCAL_ID: ItemLocalId = ItemLocalId(!0); #[derive(Clone, PartialEq, Eq, RustcEncodable, RustcDecodable, Hash, Copy)] pub struct Label { pub name: Name, pub span: Span, } impl fmt::Debug for Label { fn fmt(&self, f: &mut fmt::Formatter) -> fmt::Result { write!(f, "label({:?})", self.name) } } #[derive(Clone, PartialEq, Eq, RustcEncodable, RustcDecodable, Hash, Copy)] pub struct Lifetime { pub id: NodeId, pub span: Span, /// Either "'a", referring to a named lifetime definition, /// or "" (aka keywords::Invalid), for elision placeholders. /// /// HIR lowering inserts these placeholders in type paths that /// refer to type definitions needing lifetime parameters, /// `&T` and `&mut T`, and trait objects without `... + 'a`. pub name: LifetimeName, } #[derive(Debug, Clone, PartialEq, Eq, RustcEncodable, RustcDecodable, Hash, Copy)] pub enum LifetimeName { /// User typed nothing. e.g. the lifetime in `&u32`. Implicit, /// User typed `'_`. Underscore, /// Synthetic name generated when user elided a lifetime in an impl header, /// e.g. the lifetimes in cases like these: /// /// impl Foo for &u32 /// impl Foo<'_> for u32 /// /// in that case, we rewrite to /// /// impl<'f> Foo for &'f u32 /// impl<'f> Foo<'f> for u32 /// /// where `'f` is something like `Fresh(0)`. The indices are /// unique per impl, but not necessarily continuous. Fresh(usize), /// User wrote `'static` Static, /// Some user-given name like `'x` Name(Name), } impl LifetimeName { pub fn name(&self) -> Name { use self::LifetimeName::*; match *self { Implicit => keywords::Invalid.name(), Fresh(_) | Underscore => keywords::UnderscoreLifetime.name(), Static => keywords::StaticLifetime.name(), Name(name) => name, } } } impl fmt::Debug for Lifetime { fn fmt(&self, f: &mut fmt::Formatter) -> fmt::Result { write!(f, "lifetime({}: {})", self.id, print::to_string(print::NO_ANN, |s| s.print_lifetime(self))) } } impl Lifetime { pub fn is_elided(&self) -> bool { use self::LifetimeName::*; match self.name { Implicit | Underscore => true, // It might seem surprising that `Fresh(_)` counts as // *not* elided -- but this is because, as far as the code // in the compiler is concerned -- `Fresh(_)` variants act // equivalently to "some fresh name". They correspond to // early-bound regions on an impl, in other words. Fresh(_) | Static | Name(_) => false, } } pub fn is_static(&self) -> bool { self.name == LifetimeName::Static } } /// A lifetime definition, eg `'a: 'b+'c+'d` #[derive(Clone, PartialEq, Eq, RustcEncodable, RustcDecodable, Hash, Debug)] pub struct LifetimeDef { pub lifetime: Lifetime, pub bounds: HirVec, pub pure_wrt_drop: bool, // Indicates that the lifetime definition was synthetically added // as a result of an in-band lifetime usage like // `fn foo(x: &'a u8) -> &'a u8 { x }` pub in_band: bool, } /// A "Path" is essentially Rust's notion of a name; for instance: /// `std::cmp::PartialEq`. It's represented as a sequence of identifiers, /// along with a bunch of supporting information. #[derive(Clone, PartialEq, Eq, RustcEncodable, RustcDecodable, Hash)] pub struct Path { pub span: Span, /// The definition that the path resolved to. pub def: Def, /// The segments in the path: the things separated by `::`. pub segments: HirVec, } impl Path { pub fn is_global(&self) -> bool { !self.segments.is_empty() && self.segments[0].name == keywords::CrateRoot.name() } } impl fmt::Debug for Path { fn fmt(&self, f: &mut fmt::Formatter) -> fmt::Result { write!(f, "path({})", print::to_string(print::NO_ANN, |s| s.print_path(self, false))) } } impl fmt::Display for Path { fn fmt(&self, f: &mut fmt::Formatter) -> fmt::Result { write!(f, "{}", print::to_string(print::NO_ANN, |s| s.print_path(self, false))) } } /// A segment of a path: an identifier, an optional lifetime, and a set of /// types. #[derive(Clone, PartialEq, Eq, RustcEncodable, RustcDecodable, Hash, Debug)] pub struct PathSegment { /// The identifier portion of this path segment. pub name: Name, /// Type/lifetime parameters attached to this path. They come in /// two flavors: `Path` and `Path(A,B) -> C`. Note that /// this is more than just simple syntactic sugar; the use of /// parens affects the region binding rules, so we preserve the /// distinction. pub parameters: Option>, /// Whether to infer remaining type parameters, if any. /// This only applies to expression and pattern paths, and /// out of those only the segments with no type parameters /// to begin with, e.g. `Vec::new` is `>::new::<..>`. pub infer_types: bool, } impl PathSegment { /// Convert an identifier to the corresponding segment. pub fn from_name(name: Name) -> PathSegment { PathSegment { name, infer_types: true, parameters: None } } pub fn new(name: Name, parameters: PathParameters, infer_types: bool) -> Self { PathSegment { name, infer_types, parameters: if parameters.is_empty() { None } else { Some(P(parameters)) } } } // FIXME: hack required because you can't create a static // PathParameters, so you can't just return a &PathParameters. pub fn with_parameters(&self, f: F) -> R where F: FnOnce(&PathParameters) -> R { let dummy = PathParameters::none(); f(if let Some(ref params) = self.parameters { ¶ms } else { &dummy }) } } #[derive(Clone, PartialEq, Eq, RustcEncodable, RustcDecodable, Hash, Debug)] pub struct PathParameters { /// The lifetime parameters for this path segment. pub lifetimes: HirVec, /// The type parameters for this path segment, if present. pub types: HirVec>, /// Bindings (equality constraints) on associated types, if present. /// E.g., `Foo`. pub bindings: HirVec, /// Were parameters written in parenthesized form `Fn(T) -> U`? /// This is required mostly for pretty-printing and diagnostics, /// but also for changing lifetime elision rules to be "function-like". pub parenthesized: bool, } impl PathParameters { pub fn none() -> Self { Self { lifetimes: HirVec::new(), types: HirVec::new(), bindings: HirVec::new(), parenthesized: false, } } pub fn is_empty(&self) -> bool { self.lifetimes.is_empty() && self.types.is_empty() && self.bindings.is_empty() && !self.parenthesized } pub fn inputs(&self) -> &[P] { if self.parenthesized { if let Some(ref ty) = self.types.get(0) { if let TyTup(ref tys) = ty.node { return tys; } } } bug!("PathParameters::inputs: not a `Fn(T) -> U`"); } } /// The AST represents all type param bounds as types. /// typeck::collect::compute_bounds matches these against /// the "special" built-in traits (see middle::lang_items) and /// detects Copy, Send and Sync. #[derive(Clone, PartialEq, Eq, RustcEncodable, RustcDecodable, Hash, Debug)] pub enum TyParamBound { TraitTyParamBound(PolyTraitRef, TraitBoundModifier), RegionTyParamBound(Lifetime), } impl TyParamBound { pub fn span(&self) -> Span { match self { &TraitTyParamBound(ref t, ..) => t.span, &RegionTyParamBound(ref l) => l.span, } } } /// A modifier on a bound, currently this is only used for `?Sized`, where the /// modifier is `Maybe`. Negative bounds should also be handled here. #[derive(Copy, Clone, PartialEq, Eq, RustcEncodable, RustcDecodable, Hash, Debug)] pub enum TraitBoundModifier { None, Maybe, } pub type TyParamBounds = HirVec; #[derive(Clone, PartialEq, Eq, RustcEncodable, RustcDecodable, Hash, Debug)] pub struct TyParam { pub name: Name, pub id: NodeId, pub bounds: TyParamBounds, pub default: Option>, pub span: Span, pub pure_wrt_drop: bool, pub synthetic: Option, pub attrs: HirVec, } #[derive(Clone, PartialEq, Eq, RustcEncodable, RustcDecodable, Hash, Debug)] pub enum GenericParam { Lifetime(LifetimeDef), Type(TyParam), } impl GenericParam { pub fn is_lifetime_param(&self) -> bool { match *self { GenericParam::Lifetime(_) => true, _ => false, } } pub fn is_type_param(&self) -> bool { match *self { GenericParam::Type(_) => true, _ => false, } } } pub trait GenericParamsExt { fn lifetimes<'a>(&'a self) -> iter::FilterMap< slice::Iter, fn(&GenericParam) -> Option<&LifetimeDef>, >; fn ty_params<'a>(&'a self) -> iter::FilterMap< slice::Iter, fn(&GenericParam) -> Option<&TyParam>, >; } impl GenericParamsExt for [GenericParam] { fn lifetimes<'a>(&'a self) -> iter::FilterMap< slice::Iter, fn(&GenericParam) -> Option<&LifetimeDef>, > { self.iter().filter_map(|param| match *param { GenericParam::Lifetime(ref l) => Some(l), _ => None, }) } fn ty_params<'a>(&'a self) -> iter::FilterMap< slice::Iter, fn(&GenericParam) -> Option<&TyParam>, > { self.iter().filter_map(|param| match *param { GenericParam::Type(ref t) => Some(t), _ => None, }) } } /// Represents lifetimes and type parameters attached to a declaration /// of a function, enum, trait, etc. #[derive(Clone, PartialEq, Eq, RustcEncodable, RustcDecodable, Hash, Debug)] pub struct Generics { pub params: HirVec, pub where_clause: WhereClause, pub span: Span, } impl Generics { pub fn empty() -> Generics { Generics { params: HirVec::new(), where_clause: WhereClause { id: DUMMY_NODE_ID, predicates: HirVec::new(), }, span: DUMMY_SP, } } pub fn is_lt_parameterized(&self) -> bool { self.params.iter().any(|param| param.is_lifetime_param()) } pub fn is_type_parameterized(&self) -> bool { self.params.iter().any(|param| param.is_type_param()) } pub fn lifetimes<'a>(&'a self) -> impl Iterator { self.params.lifetimes() } pub fn ty_params<'a>(&'a self) -> impl Iterator { self.params.ty_params() } } pub enum UnsafeGeneric { Region(LifetimeDef, &'static str), Type(TyParam, &'static str), } impl UnsafeGeneric { pub fn attr_name(&self) -> &'static str { match *self { UnsafeGeneric::Region(_, s) => s, UnsafeGeneric::Type(_, s) => s, } } } impl Generics { pub fn carries_unsafe_attr(&self) -> Option { for param in &self.params { match *param { GenericParam::Lifetime(ref l) => { if l.pure_wrt_drop { return Some(UnsafeGeneric::Region(l.clone(), "may_dangle")); } } GenericParam::Type(ref t) => { if t.pure_wrt_drop { return Some(UnsafeGeneric::Type(t.clone(), "may_dangle")); } } } } None } } /// Synthetic Type Parameters are converted to an other form during lowering, this allows /// to track the original form they had. Useful for error messages. #[derive(Copy, Clone, PartialEq, Eq, RustcEncodable, RustcDecodable, Hash, Debug)] pub enum SyntheticTyParamKind { ImplTrait } /// A `where` clause in a definition #[derive(Clone, PartialEq, Eq, RustcEncodable, RustcDecodable, Hash, Debug)] pub struct WhereClause { pub id: NodeId, pub predicates: HirVec, } /// A single predicate in a `where` clause #[derive(Clone, PartialEq, Eq, RustcEncodable, RustcDecodable, Hash, Debug)] pub enum WherePredicate { /// A type binding, eg `for<'c> Foo: Send+Clone+'c` BoundPredicate(WhereBoundPredicate), /// A lifetime predicate, e.g. `'a: 'b+'c` RegionPredicate(WhereRegionPredicate), /// An equality predicate (unsupported) EqPredicate(WhereEqPredicate), } impl WherePredicate { pub fn span(&self) -> Span { match self { &WherePredicate::BoundPredicate(ref p) => p.span, &WherePredicate::RegionPredicate(ref p) => p.span, &WherePredicate::EqPredicate(ref p) => p.span, } } } /// A type bound, eg `for<'c> Foo: Send+Clone+'c` #[derive(Clone, PartialEq, Eq, RustcEncodable, RustcDecodable, Hash, Debug)] pub struct WhereBoundPredicate { pub span: Span, /// Any generics from a `for` binding pub bound_generic_params: HirVec, /// The type being bounded pub bounded_ty: P, /// Trait and lifetime bounds (`Clone+Send+'static`) pub bounds: TyParamBounds, } /// A lifetime predicate, e.g. `'a: 'b+'c` #[derive(Clone, PartialEq, Eq, RustcEncodable, RustcDecodable, Hash, Debug)] pub struct WhereRegionPredicate { pub span: Span, pub lifetime: Lifetime, pub bounds: HirVec, } /// An equality predicate (unsupported), e.g. `T=int` #[derive(Clone, PartialEq, Eq, RustcEncodable, RustcDecodable, Hash, Debug)] pub struct WhereEqPredicate { pub id: NodeId, pub span: Span, pub lhs_ty: P, pub rhs_ty: P, } pub type CrateConfig = HirVec>; /// The top-level data structure that stores the entire contents of /// the crate currently being compiled. /// /// For more details, see the [rustc guide]. /// /// [rustc guide]: https://rust-lang-nursery.github.io/rustc-guide/hir.html #[derive(Clone, PartialEq, Eq, RustcEncodable, RustcDecodable, Debug)] pub struct Crate { pub module: Mod, pub attrs: HirVec, pub span: Span, pub exported_macros: HirVec, // NB: We use a BTreeMap here so that `visit_all_items` iterates // over the ids in increasing order. In principle it should not // matter what order we visit things in, but in *practice* it // does, because it can affect the order in which errors are // detected, which in turn can make compile-fail tests yield // slightly different results. pub items: BTreeMap, pub trait_items: BTreeMap, pub impl_items: BTreeMap, pub bodies: BTreeMap, pub trait_impls: BTreeMap>, pub trait_auto_impl: BTreeMap, /// A list of the body ids written out in the order in which they /// appear in the crate. If you're going to process all the bodies /// in the crate, you should iterate over this list rather than the keys /// of bodies. pub body_ids: Vec, } impl Crate { pub fn item(&self, id: NodeId) -> &Item { &self.items[&id] } pub fn trait_item(&self, id: TraitItemId) -> &TraitItem { &self.trait_items[&id] } pub fn impl_item(&self, id: ImplItemId) -> &ImplItem { &self.impl_items[&id] } /// Visits all items in the crate in some deterministic (but /// unspecified) order. If you just need to process every item, /// but don't care about nesting, this method is the best choice. /// /// If you do care about nesting -- usually because your algorithm /// follows lexical scoping rules -- then you want a different /// approach. You should override `visit_nested_item` in your /// visitor and then call `intravisit::walk_crate` instead. pub fn visit_all_item_likes<'hir, V>(&'hir self, visitor: &mut V) where V: itemlikevisit::ItemLikeVisitor<'hir> { for (_, item) in &self.items { visitor.visit_item(item); } for (_, trait_item) in &self.trait_items { visitor.visit_trait_item(trait_item); } for (_, impl_item) in &self.impl_items { visitor.visit_impl_item(impl_item); } } pub fn body(&self, id: BodyId) -> &Body { &self.bodies[&id] } } /// A macro definition, in this crate or imported from another. /// /// Not parsed directly, but created on macro import or `macro_rules!` expansion. #[derive(Clone, PartialEq, Eq, RustcEncodable, RustcDecodable, Hash, Debug)] pub struct MacroDef { pub name: Name, pub vis: Visibility, pub attrs: HirVec, pub id: NodeId, pub span: Span, pub body: TokenStream, pub legacy: bool, } #[derive(Clone, PartialEq, Eq, RustcEncodable, RustcDecodable, Hash, Debug)] pub struct Block { /// Statements in a block pub stmts: HirVec, /// An expression at the end of the block /// without a semicolon, if any pub expr: Option>, pub id: NodeId, pub hir_id: HirId, /// Distinguishes between `unsafe { ... }` and `{ ... }` pub rules: BlockCheckMode, pub span: Span, /// If true, then there may exist `break 'a` values that aim to /// break out of this block early. As of this writing, this is not /// currently permitted in Rust itself, but it is generated as /// part of `catch` statements. pub targeted_by_break: bool, /// If true, don't emit return value type errors as the parser had /// to recover from a parse error so this block will not have an /// appropriate type. A parse error will have been emitted so the /// compilation will never succeed if this is true. pub recovered: bool, } #[derive(Clone, PartialEq, Eq, RustcEncodable, RustcDecodable, Hash)] pub struct Pat { pub id: NodeId, pub hir_id: HirId, pub node: PatKind, pub span: Span, } impl fmt::Debug for Pat { fn fmt(&self, f: &mut fmt::Formatter) -> fmt::Result { write!(f, "pat({}: {})", self.id, print::to_string(print::NO_ANN, |s| s.print_pat(self))) } } impl Pat { // FIXME(#19596) this is a workaround, but there should be a better way fn walk_(&self, it: &mut G) -> bool where G: FnMut(&Pat) -> bool { if !it(self) { return false; } match self.node { PatKind::Binding(.., Some(ref p)) => p.walk_(it), PatKind::Struct(_, ref fields, _) => { fields.iter().all(|field| field.node.pat.walk_(it)) } PatKind::TupleStruct(_, ref s, _) | PatKind::Tuple(ref s, _) => { s.iter().all(|p| p.walk_(it)) } PatKind::Box(ref s) | PatKind::Ref(ref s, _) => { s.walk_(it) } PatKind::Slice(ref before, ref slice, ref after) => { before.iter().all(|p| p.walk_(it)) && slice.iter().all(|p| p.walk_(it)) && after.iter().all(|p| p.walk_(it)) } PatKind::Wild | PatKind::Lit(_) | PatKind::Range(..) | PatKind::Binding(..) | PatKind::Path(_) => { true } } } pub fn walk(&self, mut it: F) -> bool where F: FnMut(&Pat) -> bool { self.walk_(&mut it) } } /// A single field in a struct pattern /// /// Patterns like the fields of Foo `{ x, ref y, ref mut z }` /// are treated the same as` x: x, y: ref y, z: ref mut z`, /// except is_shorthand is true #[derive(Clone, PartialEq, Eq, RustcEncodable, RustcDecodable, Hash, Debug)] pub struct FieldPat { /// The identifier for the field pub name: Name, /// The pattern the field is destructured to pub pat: P, pub is_shorthand: bool, } /// Explicit binding annotations given in the HIR for a binding. Note /// that this is not the final binding *mode* that we infer after type /// inference. #[derive(Clone, PartialEq, Eq, RustcEncodable, RustcDecodable, Hash, Debug, Copy)] pub enum BindingAnnotation { /// No binding annotation given: this means that the final binding mode /// will depend on whether we have skipped through a `&` reference /// when matching. For example, the `x` in `Some(x)` will have binding /// mode `None`; if you do `let Some(x) = &Some(22)`, it will /// ultimately be inferred to be by-reference. /// /// Note that implicit reference skipping is not implemented yet (#42640). Unannotated, /// Annotated with `mut x` -- could be either ref or not, similar to `None`. Mutable, /// Annotated as `ref`, like `ref x` Ref, /// Annotated as `ref mut x`. RefMut, } #[derive(Copy, Clone, PartialEq, Eq, RustcEncodable, RustcDecodable, Hash, Debug)] pub enum RangeEnd { Included, Excluded, } #[derive(Clone, PartialEq, Eq, RustcEncodable, RustcDecodable, Hash, Debug)] pub enum PatKind { /// Represents a wildcard pattern (`_`) Wild, /// A fresh binding `ref mut binding @ OPT_SUBPATTERN`. /// The `NodeId` is the canonical ID for the variable being bound, /// e.g. in `Ok(x) | Err(x)`, both `x` use the same canonical ID, /// which is the pattern ID of the first `x`. Binding(BindingAnnotation, NodeId, Spanned, Option>), /// A struct or struct variant pattern, e.g. `Variant {x, y, ..}`. /// The `bool` is `true` in the presence of a `..`. Struct(QPath, HirVec>, bool), /// A tuple struct/variant pattern `Variant(x, y, .., z)`. /// If the `..` pattern fragment is present, then `Option` denotes its position. /// 0 <= position <= subpats.len() TupleStruct(QPath, HirVec>, Option), /// A path pattern for an unit struct/variant or a (maybe-associated) constant. Path(QPath), /// A tuple pattern `(a, b)`. /// If the `..` pattern fragment is present, then `Option` denotes its position. /// 0 <= position <= subpats.len() Tuple(HirVec>, Option), /// A `box` pattern Box(P), /// A reference pattern, e.g. `&mut (a, b)` Ref(P, Mutability), /// A literal Lit(P), /// A range pattern, e.g. `1...2` or `1..2` Range(P, P, RangeEnd), /// `[a, b, ..i, y, z]` is represented as: /// `PatKind::Slice(box [a, b], Some(i), box [y, z])` Slice(HirVec>, Option>, HirVec>), } #[derive(Clone, PartialEq, Eq, RustcEncodable, RustcDecodable, Hash, Debug, Copy)] pub enum Mutability { MutMutable, MutImmutable, } impl Mutability { /// Return MutMutable only if both arguments are mutable. pub fn and(self, other: Self) -> Self { match self { MutMutable => other, MutImmutable => MutImmutable, } } } #[derive(Clone, PartialEq, Eq, RustcEncodable, RustcDecodable, Hash, Debug, Copy)] pub enum BinOp_ { /// The `+` operator (addition) BiAdd, /// The `-` operator (subtraction) BiSub, /// The `*` operator (multiplication) BiMul, /// The `/` operator (division) BiDiv, /// The `%` operator (modulus) BiRem, /// The `&&` operator (logical and) BiAnd, /// The `||` operator (logical or) BiOr, /// The `^` operator (bitwise xor) BiBitXor, /// The `&` operator (bitwise and) BiBitAnd, /// The `|` operator (bitwise or) BiBitOr, /// The `<<` operator (shift left) BiShl, /// The `>>` operator (shift right) BiShr, /// The `==` operator (equality) BiEq, /// The `<` operator (less than) BiLt, /// The `<=` operator (less than or equal to) BiLe, /// The `!=` operator (not equal to) BiNe, /// The `>=` operator (greater than or equal to) BiGe, /// The `>` operator (greater than) BiGt, } impl BinOp_ { pub fn as_str(self) -> &'static str { match self { BiAdd => "+", BiSub => "-", BiMul => "*", BiDiv => "/", BiRem => "%", BiAnd => "&&", BiOr => "||", BiBitXor => "^", BiBitAnd => "&", BiBitOr => "|", BiShl => "<<", BiShr => ">>", BiEq => "==", BiLt => "<", BiLe => "<=", BiNe => "!=", BiGe => ">=", BiGt => ">", } } pub fn is_lazy(self) -> bool { match self { BiAnd | BiOr => true, _ => false, } } pub fn is_shift(self) -> bool { match self { BiShl | BiShr => true, _ => false, } } pub fn is_comparison(self) -> bool { match self { BiEq | BiLt | BiLe | BiNe | BiGt | BiGe => true, BiAnd | BiOr | BiAdd | BiSub | BiMul | BiDiv | BiRem | BiBitXor | BiBitAnd | BiBitOr | BiShl | BiShr => false, } } /// Returns `true` if the binary operator takes its arguments by value pub fn is_by_value(self) -> bool { !self.is_comparison() } } impl Into for BinOp_ { fn into(self) -> ast::BinOpKind { match self { BiAdd => ast::BinOpKind::Add, BiSub => ast::BinOpKind::Sub, BiMul => ast::BinOpKind::Mul, BiDiv => ast::BinOpKind::Div, BiRem => ast::BinOpKind::Rem, BiAnd => ast::BinOpKind::And, BiOr => ast::BinOpKind::Or, BiBitXor => ast::BinOpKind::BitXor, BiBitAnd => ast::BinOpKind::BitAnd, BiBitOr => ast::BinOpKind::BitOr, BiShl => ast::BinOpKind::Shl, BiShr => ast::BinOpKind::Shr, BiEq => ast::BinOpKind::Eq, BiLt => ast::BinOpKind::Lt, BiLe => ast::BinOpKind::Le, BiNe => ast::BinOpKind::Ne, BiGe => ast::BinOpKind::Ge, BiGt => ast::BinOpKind::Gt, } } } pub type BinOp = Spanned; #[derive(Clone, PartialEq, Eq, RustcEncodable, RustcDecodable, Hash, Debug, Copy)] pub enum UnOp { /// The `*` operator for dereferencing UnDeref, /// The `!` operator for logical inversion UnNot, /// The `-` operator for negation UnNeg, } impl UnOp { pub fn as_str(self) -> &'static str { match self { UnDeref => "*", UnNot => "!", UnNeg => "-", } } /// Returns `true` if the unary operator takes its argument by value pub fn is_by_value(self) -> bool { match self { UnNeg | UnNot => true, _ => false, } } } /// A statement pub type Stmt = Spanned; impl fmt::Debug for Stmt_ { fn fmt(&self, f: &mut fmt::Formatter) -> fmt::Result { // Sadness. let spanned = codemap::dummy_spanned(self.clone()); write!(f, "stmt({}: {})", spanned.node.id(), print::to_string(print::NO_ANN, |s| s.print_stmt(&spanned))) } } #[derive(Clone, PartialEq, Eq, RustcEncodable, RustcDecodable, Hash)] pub enum Stmt_ { /// Could be an item or a local (let) binding: StmtDecl(P, NodeId), /// Expr without trailing semi-colon (must have unit type): StmtExpr(P, NodeId), /// Expr with trailing semi-colon (may have any type): StmtSemi(P, NodeId), } impl Stmt_ { pub fn attrs(&self) -> &[Attribute] { match *self { StmtDecl(ref d, _) => d.node.attrs(), StmtExpr(ref e, _) | StmtSemi(ref e, _) => &e.attrs, } } pub fn id(&self) -> NodeId { match *self { StmtDecl(_, id) => id, StmtExpr(_, id) => id, StmtSemi(_, id) => id, } } } /// Local represents a `let` statement, e.g., `let : = ;` #[derive(Clone, PartialEq, Eq, RustcEncodable, RustcDecodable, Hash, Debug)] pub struct Local { pub pat: P, pub ty: Option>, /// Initializer expression to set the value, if any pub init: Option>, pub id: NodeId, pub hir_id: HirId, pub span: Span, pub attrs: ThinVec, pub source: LocalSource, } pub type Decl = Spanned; #[derive(Clone, PartialEq, Eq, RustcEncodable, RustcDecodable, Hash, Debug)] pub enum Decl_ { /// A local (let) binding: DeclLocal(P), /// An item binding: DeclItem(ItemId), } impl Decl_ { pub fn attrs(&self) -> &[Attribute] { match *self { DeclLocal(ref l) => &l.attrs, DeclItem(_) => &[] } } pub fn is_local(&self) -> bool { match *self { Decl_::DeclLocal(_) => true, _ => false, } } } /// represents one arm of a 'match' #[derive(Clone, PartialEq, Eq, RustcEncodable, RustcDecodable, Hash, Debug)] pub struct Arm { pub attrs: HirVec, pub pats: HirVec>, pub guard: Option>, pub body: P, } #[derive(Clone, PartialEq, Eq, RustcEncodable, RustcDecodable, Hash, Debug)] pub struct Field { pub name: Spanned, pub expr: P, pub span: Span, pub is_shorthand: bool, } #[derive(Clone, PartialEq, Eq, RustcEncodable, RustcDecodable, Hash, Debug, Copy)] pub enum BlockCheckMode { DefaultBlock, UnsafeBlock(UnsafeSource), PushUnsafeBlock(UnsafeSource), PopUnsafeBlock(UnsafeSource), } #[derive(Clone, PartialEq, Eq, RustcEncodable, RustcDecodable, Hash, Debug, Copy)] pub enum UnsafeSource { CompilerGenerated, UserProvided, } #[derive(Copy, Clone, PartialEq, Eq, PartialOrd, Ord, RustcEncodable, RustcDecodable, Hash, Debug)] pub struct BodyId { pub node_id: NodeId, } /// The body of a function, closure, or constant value. In the case of /// a function, the body contains not only the function body itself /// (which is an expression), but also the argument patterns, since /// those are something that the caller doesn't really care about. /// /// # Examples /// /// ``` /// fn foo((x, y): (u32, u32)) -> u32 { /// x + y /// } /// ``` /// /// Here, the `Body` associated with `foo()` would contain: /// /// - an `arguments` array containing the `(x, y)` pattern /// - a `value` containing the `x + y` expression (maybe wrapped in a block) /// - `is_generator` would be false /// /// All bodies have an **owner**, which can be accessed via the HIR /// map using `body_owner_def_id()`. #[derive(Clone, PartialEq, Eq, RustcEncodable, RustcDecodable, Hash, Debug)] pub struct Body { pub arguments: HirVec, pub value: Expr, pub is_generator: bool, } impl Body { pub fn id(&self) -> BodyId { BodyId { node_id: self.value.id } } } #[derive(Copy, Clone, Debug)] pub enum BodyOwnerKind { /// Functions and methods. Fn, /// Constants and associated constants. Const, /// Initializer of a `static` item. Static(Mutability), } /// An expression #[derive(Clone, PartialEq, Eq, RustcEncodable, RustcDecodable, Hash)] pub struct Expr { pub id: NodeId, pub span: Span, pub node: Expr_, pub attrs: ThinVec, pub hir_id: HirId, } impl Expr { pub fn precedence(&self) -> ExprPrecedence { match self.node { ExprBox(_) => ExprPrecedence::Box, ExprArray(_) => ExprPrecedence::Array, ExprCall(..) => ExprPrecedence::Call, ExprMethodCall(..) => ExprPrecedence::MethodCall, ExprTup(_) => ExprPrecedence::Tup, ExprBinary(op, ..) => ExprPrecedence::Binary(op.node.into()), ExprUnary(..) => ExprPrecedence::Unary, ExprLit(_) => ExprPrecedence::Lit, ExprType(..) | ExprCast(..) => ExprPrecedence::Cast, ExprIf(..) => ExprPrecedence::If, ExprWhile(..) => ExprPrecedence::While, ExprLoop(..) => ExprPrecedence::Loop, ExprMatch(..) => ExprPrecedence::Match, ExprClosure(..) => ExprPrecedence::Closure, ExprBlock(..) => ExprPrecedence::Block, ExprAssign(..) => ExprPrecedence::Assign, ExprAssignOp(..) => ExprPrecedence::AssignOp, ExprField(..) => ExprPrecedence::Field, ExprTupField(..) => ExprPrecedence::TupField, ExprIndex(..) => ExprPrecedence::Index, ExprPath(..) => ExprPrecedence::Path, ExprAddrOf(..) => ExprPrecedence::AddrOf, ExprBreak(..) => ExprPrecedence::Break, ExprAgain(..) => ExprPrecedence::Continue, ExprRet(..) => ExprPrecedence::Ret, ExprInlineAsm(..) => ExprPrecedence::InlineAsm, ExprStruct(..) => ExprPrecedence::Struct, ExprRepeat(..) => ExprPrecedence::Repeat, ExprYield(..) => ExprPrecedence::Yield, } } } impl fmt::Debug for Expr { fn fmt(&self, f: &mut fmt::Formatter) -> fmt::Result { write!(f, "expr({}: {})", self.id, print::to_string(print::NO_ANN, |s| s.print_expr(self))) } } #[derive(Clone, PartialEq, Eq, RustcEncodable, RustcDecodable, Hash, Debug)] pub enum Expr_ { /// A `box x` expression. ExprBox(P), /// An array (`[a, b, c, d]`) ExprArray(HirVec), /// A function call /// /// The first field resolves to the function itself (usually an `ExprPath`), /// and the second field is the list of arguments. /// This also represents calling the constructor of /// tuple-like ADTs such as tuple structs and enum variants. ExprCall(P, HirVec), /// A method call (`x.foo::<'static, Bar, Baz>(a, b, c, d)`) /// /// The `PathSegment`/`Span` represent the method name and its generic arguments /// (within the angle brackets). /// The first element of the vector of `Expr`s is the expression that evaluates /// to the object on which the method is being called on (the receiver), /// and the remaining elements are the rest of the arguments. /// Thus, `x.foo::(a, b, c, d)` is represented as /// `ExprKind::MethodCall(PathSegment { foo, [Bar, Baz] }, [x, a, b, c, d])`. ExprMethodCall(PathSegment, Span, HirVec), /// A tuple (`(a, b, c ,d)`) ExprTup(HirVec), /// A binary operation (For example: `a + b`, `a * b`) ExprBinary(BinOp, P, P), /// A unary operation (For example: `!x`, `*x`) ExprUnary(UnOp, P), /// A literal (For example: `1`, `"foo"`) ExprLit(P), /// A cast (`foo as f64`) ExprCast(P, P), ExprType(P, P), /// An `if` block, with an optional else block /// /// `if expr { expr } else { expr }` ExprIf(P, P, Option>), /// A while loop, with an optional label /// /// `'label: while expr { block }` ExprWhile(P, P, Option