src/tools/rust-analyzer/crates/hir-def/src/body.rs - toolchain/rustc - Git at Google

 //! Defines `Body`: a lowered representation of bodies of functions, statics and
 //! consts.
 mod lower;
 #[cfg(test)]
 mod tests;
 pub mod scope;
 mod pretty;

 use std::ops::Index;

 use base_db::CrateId;
 use cfg::{CfgExpr, CfgOptions};
 use either::Either;
 use hir_expand::{name::Name, HirFileId, InFile};
 use la_arena::{Arena, ArenaMap};
 use profile::Count;
 use rustc_hash::FxHashMap;
 use syntax::{ast, AstPtr, SyntaxNodePtr};
 use triomphe::Arc;

 use crate::{
     db::DefDatabase,
     expander::Expander,
     hir::{
         dummy_expr_id, Binding, BindingId, Expr, ExprId, Label, LabelId, Pat, PatId, RecordFieldPat,
     },
     nameres::DefMap,
     path::{ModPath, Path},
     src::{HasChildSource, HasSource},
     BlockId, DefWithBodyId, HasModule, Lookup,
 };

 /// The body of an item (function, const etc.).
 #[derive(Debug, Eq, PartialEq)]
 pub struct Body {
     pub exprs: Arena<Expr>,
     pub pats: Arena<Pat>,
     pub bindings: Arena<Binding>,
     pub labels: Arena<Label>,
     /// Id of the closure/generator that owns the corresponding binding. If a binding is owned by the
     /// top level expression, it will not be listed in here.
     pub binding_owners: FxHashMap<BindingId, ExprId>,
     /// The patterns for the function's parameters. While the parameter types are
     /// part of the function signature, the patterns are not (they don't change
     /// the external type of the function).
     ///
     /// If this `Body` is for the body of a constant, this will just be
     /// empty.
     pub params: Vec<PatId>,
     /// The `ExprId` of the actual body expression.
     pub body_expr: ExprId,
     /// Block expressions in this body that may contain inner items.
     block_scopes: Vec<BlockId>,
     _c: Count<Self>,
 }

 pub type ExprPtr = AstPtr<ast::Expr>;
 pub type ExprSource = InFile<ExprPtr>;

 pub type PatPtr = Either<AstPtr<ast::Pat>, AstPtr<ast::SelfParam>>;
 pub type PatSource = InFile<PatPtr>;

 pub type LabelPtr = AstPtr<ast::Label>;
 pub type LabelSource = InFile<LabelPtr>;

 pub type FieldPtr = AstPtr<ast::RecordExprField>;
 pub type FieldSource = InFile<FieldPtr>;

 /// An item body together with the mapping from syntax nodes to HIR expression
 /// IDs. This is needed to go from e.g. a position in a file to the HIR
 /// expression containing it; but for type inference etc., we want to operate on
 /// a structure that is agnostic to the actual positions of expressions in the
 /// file, so that we don't recompute types whenever some whitespace is typed.
 ///
 /// One complication here is that, due to macro expansion, a single `Body` might
 /// be spread across several files. So, for each ExprId and PatId, we record
 /// both the HirFileId and the position inside the file. However, we only store
 /// AST -> ExprId mapping for non-macro files, as it is not clear how to handle
 /// this properly for macros.
 #[derive(Default, Debug, Eq, PartialEq)]
 pub struct BodySourceMap {
     expr_map: FxHashMap<ExprSource, ExprId>,
     expr_map_back: ArenaMap<ExprId, ExprSource>,

     pat_map: FxHashMap<PatSource, PatId>,
     pat_map_back: ArenaMap<PatId, PatSource>,

     label_map: FxHashMap<LabelSource, LabelId>,
     label_map_back: ArenaMap<LabelId, LabelSource>,

     /// We don't create explicit nodes for record fields (`S { record_field: 92 }`).
     /// Instead, we use id of expression (`92`) to identify the field.
     field_map: FxHashMap<FieldSource, ExprId>,
     field_map_back: FxHashMap<ExprId, FieldSource>,

     expansions: FxHashMap<InFile<AstPtr<ast::MacroCall>>, HirFileId>,

     /// Diagnostics accumulated during body lowering. These contain `AstPtr`s and so are stored in
     /// the source map (since they're just as volatile).
     diagnostics: Vec<BodyDiagnostic>,
 }

 #[derive(Default, Debug, Eq, PartialEq, Clone, Copy)]
 pub struct SyntheticSyntax;

 #[derive(Debug, Eq, PartialEq)]
 pub enum BodyDiagnostic {
     InactiveCode { node: InFile<SyntaxNodePtr>, cfg: CfgExpr, opts: CfgOptions },
     MacroError { node: InFile<AstPtr<ast::MacroCall>>, message: String },
     UnresolvedProcMacro { node: InFile<AstPtr<ast::MacroCall>>, krate: CrateId },
     UnresolvedMacroCall { node: InFile<AstPtr<ast::MacroCall>>, path: ModPath },
     UnreachableLabel { node: InFile<AstPtr<ast::Lifetime>>, name: Name },
     UndeclaredLabel { node: InFile<AstPtr<ast::Lifetime>>, name: Name },
 }

 impl Body {
     pub(crate) fn body_with_source_map_query(
         db: &dyn DefDatabase,
         def: DefWithBodyId,
     ) -> (Arc<Body>, Arc<BodySourceMap>) {
         let _p = profile::span("body_with_source_map_query");
         let mut params = None;

         let mut is_async_fn = false;
         let InFile { file_id, value: body } = {
             match def {
                 DefWithBodyId::FunctionId(f) => {
                     let data = db.function_data(f);
                     let f = f.lookup(db);
                     let src = f.source(db);
                     params = src.value.param_list().map(|param_list| {
                         let item_tree = f.id.item_tree(db);
                         let func = &item_tree[f.id.value];
                         let krate = f.container.module(db).krate;
                         let crate_graph = db.crate_graph();
                         (
                             param_list,
                             func.params.clone().map(move |param| {
                                 item_tree
                                     .attrs(db, krate, param.into())
                                     .is_cfg_enabled(&crate_graph[krate].cfg_options)
                             }),
                         )
                     });
                     is_async_fn = data.has_async_kw();
                     src.map(|it| it.body().map(ast::Expr::from))
                 }
                 DefWithBodyId::ConstId(c) => {
                     let c = c.lookup(db);
                     let src = c.source(db);
                     src.map(|it| it.body())
                 }
                 DefWithBodyId::StaticId(s) => {
                     let s = s.lookup(db);
                     let src = s.source(db);
                     src.map(|it| it.body())
                 }
                 DefWithBodyId::VariantId(v) => {
                     let src = v.parent.child_source(db);
                     src.map(|it| it[v.local_id].expr())
                 }
                 DefWithBodyId::InTypeConstId(c) => c.lookup(db).id.map(|_| c.source(db).expr()),
             }
         };
         let module = def.module(db);
         let expander = Expander::new(db, file_id, module);
         let (mut body, source_map) =
             Body::new(db, def, expander, params, body, module.krate, is_async_fn);
         body.shrink_to_fit();

         (Arc::new(body), Arc::new(source_map))
     }

     pub(crate) fn body_query(db: &dyn DefDatabase, def: DefWithBodyId) -> Arc<Body> {
         db.body_with_source_map(def).0
     }

     /// Returns an iterator over all block expressions in this body that define inner items.
     pub fn blocks<'a>(
         &'a self,
         db: &'a dyn DefDatabase,
     ) -> impl Iterator<Item = (BlockId, Arc<DefMap>)> + '_ {
         self.block_scopes.iter().map(move |&block| (block, db.block_def_map(block)))
     }

     pub fn pretty_print(&self, db: &dyn DefDatabase, owner: DefWithBodyId) -> String {
         pretty::print_body_hir(db, self, owner)
     }

     pub fn pretty_print_expr(
         &self,
         db: &dyn DefDatabase,
         owner: DefWithBodyId,
         expr: ExprId,
     ) -> String {
         pretty::print_expr_hir(db, self, owner, expr)
     }

     fn new(
         db: &dyn DefDatabase,
         owner: DefWithBodyId,
         expander: Expander,
         params: Option<(ast::ParamList, impl Iterator<Item = bool>)>,
         body: Option<ast::Expr>,
         krate: CrateId,
         is_async_fn: bool,
     ) -> (Body, BodySourceMap) {
         lower::lower(db, owner, expander, params, body, krate, is_async_fn)
     }

     fn shrink_to_fit(&mut self) {
         let Self {
             _c: _,
             body_expr: _,
             block_scopes,
             exprs,
             labels,
             params,
             pats,
             bindings,
             binding_owners,
         } = self;
         block_scopes.shrink_to_fit();
         exprs.shrink_to_fit();
         labels.shrink_to_fit();
         params.shrink_to_fit();
         pats.shrink_to_fit();
         bindings.shrink_to_fit();
         binding_owners.shrink_to_fit();
     }

     pub fn walk_bindings_in_pat(&self, pat_id: PatId, mut f: impl FnMut(BindingId)) {
         self.walk_pats(pat_id, &mut |pat| {
             if let Pat::Bind { id, .. } = &self[pat] {
                 f(*id);
             }
         });
     }

     pub fn walk_pats_shallow(&self, pat_id: PatId, mut f: impl FnMut(PatId)) {
         let pat = &self[pat_id];
         match pat {
             Pat::Range { .. }
             | Pat::Lit(..)
             | Pat::Path(..)
             | Pat::ConstBlock(..)
             | Pat::Wild
             | Pat::Missing => {}
             &Pat::Bind { subpat, .. } => {
                 if let Some(subpat) = subpat {
                     f(subpat);
                 }
             }
             Pat::Or(args) | Pat::Tuple { args, .. } | Pat::TupleStruct { args, .. } => {
                 args.iter().copied().for_each(|p| f(p));
             }
             Pat::Ref { pat, .. } => f(*pat),
             Pat::Slice { prefix, slice, suffix } => {
                 let total_iter = prefix.iter().chain(slice.iter()).chain(suffix.iter());
                 total_iter.copied().for_each(|p| f(p));
             }
             Pat::Record { args, .. } => {
                 args.iter().for_each(|RecordFieldPat { pat, .. }| f(*pat));
             }
             Pat::Box { inner } => f(*inner),
         }
     }

     pub fn walk_pats(&self, pat_id: PatId, f: &mut impl FnMut(PatId)) {
         f(pat_id);
         self.walk_pats_shallow(pat_id, |p| self.walk_pats(p, f));
     }

     pub fn is_binding_upvar(&self, binding: BindingId, relative_to: ExprId) -> bool {
         match self.binding_owners.get(&binding) {
             Some(it) => {
                 // We assign expression ids in a way that outer closures will receive
                 // a lower id
                 it.into_raw() < relative_to.into_raw()
             }
             None => true,
         }
     }
 }

 impl Default for Body {
     fn default() -> Self {
         Self {
             body_expr: dummy_expr_id(),
             exprs: Default::default(),
             pats: Default::default(),
             bindings: Default::default(),
             labels: Default::default(),
             params: Default::default(),
             block_scopes: Default::default(),
             binding_owners: Default::default(),
             _c: Default::default(),
         }
     }
 }

 impl Index<ExprId> for Body {
     type Output = Expr;

     fn index(&self, expr: ExprId) -> &Expr {
         &self.exprs[expr]
     }
 }

 impl Index<PatId> for Body {
     type Output = Pat;

     fn index(&self, pat: PatId) -> &Pat {
         &self.pats[pat]
     }
 }

 impl Index<LabelId> for Body {
     type Output = Label;

     fn index(&self, label: LabelId) -> &Label {
         &self.labels[label]
     }
 }

 impl Index<BindingId> for Body {
     type Output = Binding;

     fn index(&self, b: BindingId) -> &Binding {
         &self.bindings[b]
     }
 }

 // FIXME: Change `node_` prefix to something more reasonable.
 // Perhaps `expr_syntax` and `expr_id`?
 impl BodySourceMap {
     pub fn expr_syntax(&self, expr: ExprId) -> Result<ExprSource, SyntheticSyntax> {
         self.expr_map_back.get(expr).cloned().ok_or(SyntheticSyntax)
     }

     pub fn node_expr(&self, node: InFile<&ast::Expr>) -> Option<ExprId> {
         let src = node.map(AstPtr::new);
         self.expr_map.get(&src).cloned()
     }

     pub fn node_macro_file(&self, node: InFile<&ast::MacroCall>) -> Option<HirFileId> {
         let src = node.map(AstPtr::new);
         self.expansions.get(&src).cloned()
     }

     pub fn pat_syntax(&self, pat: PatId) -> Result<PatSource, SyntheticSyntax> {
         self.pat_map_back.get(pat).cloned().ok_or(SyntheticSyntax)
     }

     pub fn node_pat(&self, node: InFile<&ast::Pat>) -> Option<PatId> {
         let src = node.map(|it| Either::Left(AstPtr::new(it)));
         self.pat_map.get(&src).cloned()
     }

     pub fn node_self_param(&self, node: InFile<&ast::SelfParam>) -> Option<PatId> {
         let src = node.map(|it| Either::Right(AstPtr::new(it)));
         self.pat_map.get(&src).cloned()
     }

     pub fn label_syntax(&self, label: LabelId) -> LabelSource {
         self.label_map_back[label].clone()
     }

     pub fn node_label(&self, node: InFile<&ast::Label>) -> Option<LabelId> {
         let src = node.map(AstPtr::new);
         self.label_map.get(&src).cloned()
     }

     pub fn field_syntax(&self, expr: ExprId) -> FieldSource {
         self.field_map_back[&expr].clone()
     }

     pub fn node_field(&self, node: InFile<&ast::RecordExprField>) -> Option<ExprId> {
         let src = node.map(AstPtr::new);
         self.field_map.get(&src).cloned()
     }

     pub fn macro_expansion_expr(&self, node: InFile<&ast::MacroExpr>) -> Option<ExprId> {
         let src = node.map(AstPtr::new).map(AstPtr::upcast::<ast::MacroExpr>).map(AstPtr::upcast);
         self.expr_map.get(&src).copied()
     }

     /// Get a reference to the body source map's diagnostics.
     pub fn diagnostics(&self) -> &[BodyDiagnostic] {
         &self.diagnostics
     }
 }
	//! Defines `Body`: a lowered representation of bodies of functions, statics and
	//! consts.
	mod lower;
	#[cfg(test)]
	mod tests;
	pub mod scope;
	mod pretty;

	use std::ops::Index;

	use base_db::CrateId;
	use cfg::{CfgExpr, CfgOptions};
	use either::Either;
	use hir_expand::{name::Name, HirFileId, InFile};
	use la_arena::{Arena, ArenaMap};
	use profile::Count;
	use rustc_hash::FxHashMap;
	use syntax::{ast, AstPtr, SyntaxNodePtr};
	use triomphe::Arc;

	use crate::{
	db::DefDatabase,
	expander::Expander,
	hir::{
	dummy_expr_id, Binding, BindingId, Expr, ExprId, Label, LabelId, Pat, PatId, RecordFieldPat,
	},
	nameres::DefMap,
	path::{ModPath, Path},
	src::{HasChildSource, HasSource},
	BlockId, DefWithBodyId, HasModule, Lookup,
	};

	/// The body of an item (function, const etc.).
	#[derive(Debug, Eq, PartialEq)]
	pub struct Body {
	pub exprs: Arena<Expr>,
	pub pats: Arena<Pat>,
	pub bindings: Arena<Binding>,
	pub labels: Arena<Label>,
	/// Id of the closure/generator that owns the corresponding binding. If a binding is owned by the
	/// top level expression, it will not be listed in here.
	pub binding_owners: FxHashMap<BindingId, ExprId>,
	/// The patterns for the function's parameters. While the parameter types are
	/// part of the function signature, the patterns are not (they don't change
	/// the external type of the function).
	///
	/// If this `Body` is for the body of a constant, this will just be
	/// empty.
	pub params: Vec<PatId>,
	/// The `ExprId` of the actual body expression.
	pub body_expr: ExprId,
	/// Block expressions in this body that may contain inner items.
	block_scopes: Vec<BlockId>,
	_c: Count<Self>,
	}

	pub type ExprPtr = AstPtr<ast::Expr>;
	pub type ExprSource = InFile<ExprPtr>;

	pub type PatPtr = Either<AstPtr<ast::Pat>, AstPtr<ast::SelfParam>>;
	pub type PatSource = InFile<PatPtr>;

	pub type LabelPtr = AstPtr<ast::Label>;
	pub type LabelSource = InFile<LabelPtr>;

	pub type FieldPtr = AstPtr<ast::RecordExprField>;
	pub type FieldSource = InFile<FieldPtr>;

	/// An item body together with the mapping from syntax nodes to HIR expression
	/// IDs. This is needed to go from e.g. a position in a file to the HIR
	/// expression containing it; but for type inference etc., we want to operate on
	/// a structure that is agnostic to the actual positions of expressions in the
	/// file, so that we don't recompute types whenever some whitespace is typed.
	///
	/// One complication here is that, due to macro expansion, a single `Body` might
	/// be spread across several files. So, for each ExprId and PatId, we record
	/// both the HirFileId and the position inside the file. However, we only store
	/// AST -> ExprId mapping for non-macro files, as it is not clear how to handle
	/// this properly for macros.
	#[derive(Default, Debug, Eq, PartialEq)]
	pub struct BodySourceMap {
	expr_map: FxHashMap<ExprSource, ExprId>,
	expr_map_back: ArenaMap<ExprId, ExprSource>,

	pat_map: FxHashMap<PatSource, PatId>,
	pat_map_back: ArenaMap<PatId, PatSource>,

	label_map: FxHashMap<LabelSource, LabelId>,
	label_map_back: ArenaMap<LabelId, LabelSource>,

	/// We don't create explicit nodes for record fields (`S { record_field: 92 }`).
	/// Instead, we use id of expression (`92`) to identify the field.
	field_map: FxHashMap<FieldSource, ExprId>,
	field_map_back: FxHashMap<ExprId, FieldSource>,

	expansions: FxHashMap<InFile<AstPtr<ast::MacroCall>>, HirFileId>,

	/// Diagnostics accumulated during body lowering. These contain `AstPtr`s and so are stored in
	/// the source map (since they're just as volatile).
	diagnostics: Vec<BodyDiagnostic>,
	}

	#[derive(Default, Debug, Eq, PartialEq, Clone, Copy)]
	pub struct SyntheticSyntax;

	#[derive(Debug, Eq, PartialEq)]
	pub enum BodyDiagnostic {
	InactiveCode { node: InFile<SyntaxNodePtr>, cfg: CfgExpr, opts: CfgOptions },
	MacroError { node: InFile<AstPtr<ast::MacroCall>>, message: String },
	UnresolvedProcMacro { node: InFile<AstPtr<ast::MacroCall>>, krate: CrateId },
	UnresolvedMacroCall { node: InFile<AstPtr<ast::MacroCall>>, path: ModPath },
	UnreachableLabel { node: InFile<AstPtr<ast::Lifetime>>, name: Name },
	UndeclaredLabel { node: InFile<AstPtr<ast::Lifetime>>, name: Name },
	}

	impl Body {
	pub(crate) fn body_with_source_map_query(
	db: &dyn DefDatabase,
	def: DefWithBodyId,
	) -> (Arc<Body>, Arc<BodySourceMap>) {
	let _p = profile::span("body_with_source_map_query");
	let mut params = None;

	let mut is_async_fn = false;
	let InFile { file_id, value: body } = {
	match def {
	DefWithBodyId::FunctionId(f) => {
	let data = db.function_data(f);
	let f = f.lookup(db);
	let src = f.source(db);
	params = src.value.param_list().map(\|param_list\| {
	let item_tree = f.id.item_tree(db);
	let func = &item_tree[f.id.value];
	let krate = f.container.module(db).krate;
	let crate_graph = db.crate_graph();
	(
	param_list,
	func.params.clone().map(move \|param\| {
	item_tree
	.attrs(db, krate, param.into())
	.is_cfg_enabled(&crate_graph[krate].cfg_options)
	}),
	)
	});
	is_async_fn = data.has_async_kw();
	src.map(\|it\| it.body().map(ast::Expr::from))
	}
	DefWithBodyId::ConstId(c) => {
	let c = c.lookup(db);
	let src = c.source(db);
	src.map(\|it\| it.body())
	}
	DefWithBodyId::StaticId(s) => {
	let s = s.lookup(db);
	let src = s.source(db);
	src.map(\|it\| it.body())
	}
	DefWithBodyId::VariantId(v) => {
	let src = v.parent.child_source(db);
	src.map(\|it\| it[v.local_id].expr())
	}
	DefWithBodyId::InTypeConstId(c) => c.lookup(db).id.map(\|_\| c.source(db).expr()),
	}
	};
	let module = def.module(db);
	let expander = Expander::new(db, file_id, module);
	let (mut body, source_map) =
	Body::new(db, def, expander, params, body, module.krate, is_async_fn);
	body.shrink_to_fit();

	(Arc::new(body), Arc::new(source_map))
	}

	pub(crate) fn body_query(db: &dyn DefDatabase, def: DefWithBodyId) -> Arc<Body> {
	db.body_with_source_map(def).0
	}

	/// Returns an iterator over all block expressions in this body that define inner items.
	pub fn blocks<'a>(
	&'a self,
	db: &'a dyn DefDatabase,
	) -> impl Iterator<Item = (BlockId, Arc<DefMap>)> + '_ {
	self.block_scopes.iter().map(move \|&block\| (block, db.block_def_map(block)))
	}

	pub fn pretty_print(&self, db: &dyn DefDatabase, owner: DefWithBodyId) -> String {
	pretty::print_body_hir(db, self, owner)
	}

	pub fn pretty_print_expr(
	&self,
	db: &dyn DefDatabase,
	owner: DefWithBodyId,
	expr: ExprId,
	) -> String {
	pretty::print_expr_hir(db, self, owner, expr)
	}

	fn new(
	db: &dyn DefDatabase,
	owner: DefWithBodyId,
	expander: Expander,
	params: Option<(ast::ParamList, impl Iterator<Item = bool>)>,
	body: Option<ast::Expr>,
	krate: CrateId,
	is_async_fn: bool,
	) -> (Body, BodySourceMap) {
	lower::lower(db, owner, expander, params, body, krate, is_async_fn)
	}

	fn shrink_to_fit(&mut self) {
	let Self {
	_c: _,
	body_expr: _,
	block_scopes,
	exprs,
	labels,
	params,
	pats,
	bindings,
	binding_owners,
	} = self;
	block_scopes.shrink_to_fit();
	exprs.shrink_to_fit();
	labels.shrink_to_fit();
	params.shrink_to_fit();
	pats.shrink_to_fit();
	bindings.shrink_to_fit();
	binding_owners.shrink_to_fit();
	}

	pub fn walk_bindings_in_pat(&self, pat_id: PatId, mut f: impl FnMut(BindingId)) {
	self.walk_pats(pat_id, &mut \|pat\| {
	if let Pat::Bind { id, .. } = &self[pat] {
	f(*id);
	}
	});
	}

	pub fn walk_pats_shallow(&self, pat_id: PatId, mut f: impl FnMut(PatId)) {
	let pat = &self[pat_id];
	match pat {
	Pat::Range { .. }
	\| Pat::Lit(..)
	\| Pat::Path(..)
	\| Pat::ConstBlock(..)
	\| Pat::Wild
	\| Pat::Missing => {}
	&Pat::Bind { subpat, .. } => {
	if let Some(subpat) = subpat {
	f(subpat);
	}
	}
	Pat::Or(args) \| Pat::Tuple { args, .. } \| Pat::TupleStruct { args, .. } => {
	args.iter().copied().for_each(\|p\| f(p));
	}
	Pat::Ref { pat, .. } => f(*pat),
	Pat::Slice { prefix, slice, suffix } => {
	let total_iter = prefix.iter().chain(slice.iter()).chain(suffix.iter());
	total_iter.copied().for_each(\|p\| f(p));
	}
	Pat::Record { args, .. } => {
	args.iter().for_each(\|RecordFieldPat { pat, .. }\| f(*pat));
	}
	Pat::Box { inner } => f(*inner),
	}
	}

	pub fn walk_pats(&self, pat_id: PatId, f: &mut impl FnMut(PatId)) {
	f(pat_id);
	self.walk_pats_shallow(pat_id, \|p\| self.walk_pats(p, f));
	}

	pub fn is_binding_upvar(&self, binding: BindingId, relative_to: ExprId) -> bool {
	match self.binding_owners.get(&binding) {
	Some(it) => {
	// We assign expression ids in a way that outer closures will receive
	// a lower id
	it.into_raw() < relative_to.into_raw()
	}
	None => true,
	}
	}
	}

	impl Default for Body {
	fn default() -> Self {
	Self {
	body_expr: dummy_expr_id(),
	exprs: Default::default(),
	pats: Default::default(),
	bindings: Default::default(),
	labels: Default::default(),
	params: Default::default(),
	block_scopes: Default::default(),
	binding_owners: Default::default(),
	_c: Default::default(),
	}
	}
	}

	impl Index<ExprId> for Body {
	type Output = Expr;

	fn index(&self, expr: ExprId) -> &Expr {
	&self.exprs[expr]
	}
	}

	impl Index<PatId> for Body {
	type Output = Pat;

	fn index(&self, pat: PatId) -> &Pat {
	&self.pats[pat]
	}
	}

	impl Index<LabelId> for Body {
	type Output = Label;

	fn index(&self, label: LabelId) -> &Label {
	&self.labels[label]
	}
	}

	impl Index<BindingId> for Body {
	type Output = Binding;

	fn index(&self, b: BindingId) -> &Binding {
	&self.bindings[b]
	}
	}

	// FIXME: Change `node_` prefix to something more reasonable.
	// Perhaps `expr_syntax` and `expr_id`?
	impl BodySourceMap {
	pub fn expr_syntax(&self, expr: ExprId) -> Result<ExprSource, SyntheticSyntax> {
	self.expr_map_back.get(expr).cloned().ok_or(SyntheticSyntax)
	}

	pub fn node_expr(&self, node: InFile<&ast::Expr>) -> Option<ExprId> {
	let src = node.map(AstPtr::new);
	self.expr_map.get(&src).cloned()
	}

	pub fn node_macro_file(&self, node: InFile<&ast::MacroCall>) -> Option<HirFileId> {
	let src = node.map(AstPtr::new);
	self.expansions.get(&src).cloned()
	}

	pub fn pat_syntax(&self, pat: PatId) -> Result<PatSource, SyntheticSyntax> {
	self.pat_map_back.get(pat).cloned().ok_or(SyntheticSyntax)
	}

	pub fn node_pat(&self, node: InFile<&ast::Pat>) -> Option<PatId> {
	let src = node.map(\|it\| Either::Left(AstPtr::new(it)));
	self.pat_map.get(&src).cloned()
	}

	pub fn node_self_param(&self, node: InFile<&ast::SelfParam>) -> Option<PatId> {
	let src = node.map(\|it\| Either::Right(AstPtr::new(it)));
	self.pat_map.get(&src).cloned()
	}

	pub fn label_syntax(&self, label: LabelId) -> LabelSource {
	self.label_map_back[label].clone()
	}

	pub fn node_label(&self, node: InFile<&ast::Label>) -> Option<LabelId> {
	let src = node.map(AstPtr::new);
	self.label_map.get(&src).cloned()
	}

	pub fn field_syntax(&self, expr: ExprId) -> FieldSource {
	self.field_map_back[&expr].clone()
	}

	pub fn node_field(&self, node: InFile<&ast::RecordExprField>) -> Option<ExprId> {
	let src = node.map(AstPtr::new);
	self.field_map.get(&src).cloned()
	}

	pub fn macro_expansion_expr(&self, node: InFile<&ast::MacroExpr>) -> Option<ExprId> {
	let src = node.map(AstPtr::new).map(AstPtr::upcast::<ast::MacroExpr>).map(AstPtr::upcast);
	self.expr_map.get(&src).copied()
	}

	/// Get a reference to the body source map's diagnostics.
	pub fn diagnostics(&self) -> &[BodyDiagnostic] {
	&self.diagnostics
	}
	}