src/tools/rust-analyzer/crates/hir-expand/src/ast_id_map.rs - toolchain/rustc - Git at Google

 //! `AstIdMap` allows to create stable IDs for "large" syntax nodes like items
 //! and macro calls.
 //!
 //! Specifically, it enumerates all items in a file and uses position of a an
 //! item as an ID. That way, id's don't change unless the set of items itself
 //! changes.

 use std::{
     any::type_name,
     fmt,
     hash::{BuildHasher, BuildHasherDefault, Hash, Hasher},
     marker::PhantomData,
 };

 use la_arena::{Arena, Idx};
 use profile::Count;
 use rustc_hash::FxHasher;
 use syntax::{ast, AstNode, AstPtr, SyntaxNode, SyntaxNodePtr};

 /// `AstId` points to an AST node in a specific file.
 pub struct FileAstId<N: AstIdNode> {
     raw: ErasedFileAstId,
     covariant: PhantomData<fn() -> N>,
 }

 impl<N: AstIdNode> Clone for FileAstId<N> {
     fn clone(&self) -> FileAstId<N> {
         *self
     }
 }
 impl<N: AstIdNode> Copy for FileAstId<N> {}

 impl<N: AstIdNode> PartialEq for FileAstId<N> {
     fn eq(&self, other: &Self) -> bool {
         self.raw == other.raw
     }
 }
 impl<N: AstIdNode> Eq for FileAstId<N> {}
 impl<N: AstIdNode> Hash for FileAstId<N> {
     fn hash<H: Hasher>(&self, hasher: &mut H) {
         self.raw.hash(hasher);
     }
 }

 impl<N: AstIdNode> fmt::Debug for FileAstId<N> {
     fn fmt(&self, f: &mut fmt::Formatter<'_>) -> fmt::Result {
         write!(f, "FileAstId::<{}>({})", type_name::<N>(), self.raw.into_raw())
     }
 }

 impl<N: AstIdNode> FileAstId<N> {
     // Can't make this a From implementation because of coherence
     pub fn upcast<M: AstIdNode>(self) -> FileAstId<M>
     where
         N: Into<M>,
     {
         FileAstId { raw: self.raw, covariant: PhantomData }
     }

     pub fn erase(self) -> ErasedFileAstId {
         self.raw
     }
 }

 pub type ErasedFileAstId = Idx<SyntaxNodePtr>;

 pub trait AstIdNode: AstNode {}
 macro_rules! register_ast_id_node {
     (impl AstIdNode for $($ident:ident),+ ) => {
         $(
             impl AstIdNode for ast::$ident {}
         )+
         fn should_alloc_id(kind: syntax::SyntaxKind) -> bool {
             $(
                 ast::$ident::can_cast(kind)
             )||+
         }
     };
 }
 register_ast_id_node! {
     impl AstIdNode for
     Item,
         Adt,
             Enum,
             Struct,
             Union,
         Const,
         ExternBlock,
         ExternCrate,
         Fn,
         Impl,
         Macro,
             MacroDef,
             MacroRules,
         MacroCall,
         Module,
         Static,
         Trait,
         TraitAlias,
         TypeAlias,
         Use,
     AssocItem, BlockExpr, Variant, RecordField, TupleField, ConstArg
 }

 /// Maps items' `SyntaxNode`s to `ErasedFileAstId`s and back.
 #[derive(Default)]
 pub struct AstIdMap {
     /// Maps stable id to unstable ptr.
     arena: Arena<SyntaxNodePtr>,
     /// Reverse: map ptr to id.
     map: hashbrown::HashMap<Idx<SyntaxNodePtr>, (), ()>,
     _c: Count<Self>,
 }

 impl fmt::Debug for AstIdMap {
     fn fmt(&self, f: &mut fmt::Formatter<'_>) -> fmt::Result {
         f.debug_struct("AstIdMap").field("arena", &self.arena).finish()
     }
 }

 impl PartialEq for AstIdMap {
     fn eq(&self, other: &Self) -> bool {
         self.arena == other.arena
     }
 }
 impl Eq for AstIdMap {}

 impl AstIdMap {
     pub(crate) fn from_source(node: &SyntaxNode) -> AstIdMap {
         assert!(node.parent().is_none());
         let mut res = AstIdMap::default();
         // By walking the tree in breadth-first order we make sure that parents
         // get lower ids then children. That is, adding a new child does not
         // change parent's id. This means that, say, adding a new function to a
         // trait does not change ids of top-level items, which helps caching.
         bdfs(node, |it| {
             if should_alloc_id(it.kind()) {
                 res.alloc(&it);
                 true
             } else {
                 false
             }
         });
         res.map = hashbrown::HashMap::with_capacity_and_hasher(res.arena.len(), ());
         for (idx, ptr) in res.arena.iter() {
             let hash = hash_ptr(ptr);
             match res.map.raw_entry_mut().from_hash(hash, |idx2| *idx2 == idx) {
                 hashbrown::hash_map::RawEntryMut::Occupied(_) => unreachable!(),
                 hashbrown::hash_map::RawEntryMut::Vacant(entry) => {
                     entry.insert_with_hasher(hash, idx, (), |&idx| hash_ptr(&res.arena[idx]));
                 }
             }
         }
         res.arena.shrink_to_fit();
         res
     }

     pub fn ast_id<N: AstIdNode>(&self, item: &N) -> FileAstId<N> {
         let raw = self.erased_ast_id(item.syntax());
         FileAstId { raw, covariant: PhantomData }
     }

     pub fn get<N: AstIdNode>(&self, id: FileAstId<N>) -> AstPtr<N> {
         AstPtr::try_from_raw(self.arena[id.raw].clone()).unwrap()
     }

     pub(crate) fn get_raw(&self, id: ErasedFileAstId) -> SyntaxNodePtr {
         self.arena[id].clone()
     }

     fn erased_ast_id(&self, item: &SyntaxNode) -> ErasedFileAstId {
         let ptr = SyntaxNodePtr::new(item);
         let hash = hash_ptr(&ptr);
         match self.map.raw_entry().from_hash(hash, |&idx| self.arena[idx] == ptr) {
             Some((&idx, &())) => idx,
             None => panic!(
                 "Can't find {:?} in AstIdMap:\n{:?}",
                 item,
                 self.arena.iter().map(|(_id, i)| i).collect::<Vec<_>>(),
             ),
         }
     }

     fn alloc(&mut self, item: &SyntaxNode) -> ErasedFileAstId {
         self.arena.alloc(SyntaxNodePtr::new(item))
     }
 }

 fn hash_ptr(ptr: &SyntaxNodePtr) -> u64 {
     let mut hasher = BuildHasherDefault::<FxHasher>::default().build_hasher();
     ptr.hash(&mut hasher);
     hasher.finish()
 }

 /// Walks the subtree in bdfs order, calling `f` for each node. What is bdfs
 /// order? It is a mix of breadth-first and depth first orders. Nodes for which
 /// `f` returns true are visited breadth-first, all the other nodes are explored
 /// depth-first.
 ///
 /// In other words, the size of the bfs queue is bound by the number of "true"
 /// nodes.
 fn bdfs(node: &SyntaxNode, mut f: impl FnMut(SyntaxNode) -> bool) {
     let mut curr_layer = vec![node.clone()];
     let mut next_layer = vec![];
     while !curr_layer.is_empty() {
         curr_layer.drain(..).for_each(|node| {
             let mut preorder = node.preorder();
             while let Some(event) = preorder.next() {
                 match event {
                     syntax::WalkEvent::Enter(node) => {
                         if f(node.clone()) {
                             next_layer.extend(node.children());
                             preorder.skip_subtree();
                         }
                     }
                     syntax::WalkEvent::Leave(_) => {}
                 }
             }
         });
         std::mem::swap(&mut curr_layer, &mut next_layer);
     }
 }
	//! `AstIdMap` allows to create stable IDs for "large" syntax nodes like items
	//! and macro calls.
	//!
	//! Specifically, it enumerates all items in a file and uses position of a an
	//! item as an ID. That way, id's don't change unless the set of items itself
	//! changes.

	use std::{
	any::type_name,
	fmt,
	hash::{BuildHasher, BuildHasherDefault, Hash, Hasher},
	marker::PhantomData,
	};

	use la_arena::{Arena, Idx};
	use profile::Count;
	use rustc_hash::FxHasher;
	use syntax::{ast, AstNode, AstPtr, SyntaxNode, SyntaxNodePtr};

	/// `AstId` points to an AST node in a specific file.
	pub struct FileAstId<N: AstIdNode> {
	raw: ErasedFileAstId,
	covariant: PhantomData<fn() -> N>,
	}

	impl<N: AstIdNode> Clone for FileAstId<N> {
	fn clone(&self) -> FileAstId<N> {
	*self
	}
	}
	impl<N: AstIdNode> Copy for FileAstId<N> {}

	impl<N: AstIdNode> PartialEq for FileAstId<N> {
	fn eq(&self, other: &Self) -> bool {
	self.raw == other.raw
	}
	}
	impl<N: AstIdNode> Eq for FileAstId<N> {}
	impl<N: AstIdNode> Hash for FileAstId<N> {
	fn hash<H: Hasher>(&self, hasher: &mut H) {
	self.raw.hash(hasher);
	}
	}

	impl<N: AstIdNode> fmt::Debug for FileAstId<N> {
	fn fmt(&self, f: &mut fmt::Formatter<'_>) -> fmt::Result {
	write!(f, "FileAstId::<{}>({})", type_name::<N>(), self.raw.into_raw())
	}
	}

	impl<N: AstIdNode> FileAstId<N> {
	// Can't make this a From implementation because of coherence
	pub fn upcast<M: AstIdNode>(self) -> FileAstId<M>
	where
	N: Into<M>,
	{
	FileAstId { raw: self.raw, covariant: PhantomData }
	}

	pub fn erase(self) -> ErasedFileAstId {
	self.raw
	}
	}

	pub type ErasedFileAstId = Idx<SyntaxNodePtr>;

	pub trait AstIdNode: AstNode {}
	macro_rules! register_ast_id_node {
	(impl AstIdNode for $($ident:ident),+ ) => {
	$(
	impl AstIdNode for ast::$ident {}
	)+
	fn should_alloc_id(kind: syntax::SyntaxKind) -> bool {
	$(
	ast::$ident::can_cast(kind)
	)\|\|+
	}
	};
	}
	register_ast_id_node! {
	impl AstIdNode for
	Item,
	Adt,
	Enum,
	Struct,
	Union,
	Const,
	ExternBlock,
	ExternCrate,
	Fn,
	Impl,
	Macro,
	MacroDef,
	MacroRules,
	MacroCall,
	Module,
	Static,
	Trait,
	TraitAlias,
	TypeAlias,
	Use,
	AssocItem, BlockExpr, Variant, RecordField, TupleField, ConstArg
	}

	/// Maps items' `SyntaxNode`s to `ErasedFileAstId`s and back.
	#[derive(Default)]
	pub struct AstIdMap {
	/// Maps stable id to unstable ptr.
	arena: Arena<SyntaxNodePtr>,
	/// Reverse: map ptr to id.
	map: hashbrown::HashMap<Idx<SyntaxNodePtr>, (), ()>,
	_c: Count<Self>,
	}

	impl fmt::Debug for AstIdMap {
	fn fmt(&self, f: &mut fmt::Formatter<'_>) -> fmt::Result {
	f.debug_struct("AstIdMap").field("arena", &self.arena).finish()
	}
	}

	impl PartialEq for AstIdMap {
	fn eq(&self, other: &Self) -> bool {
	self.arena == other.arena
	}
	}
	impl Eq for AstIdMap {}

	impl AstIdMap {
	pub(crate) fn from_source(node: &SyntaxNode) -> AstIdMap {
	assert!(node.parent().is_none());
	let mut res = AstIdMap::default();
	// By walking the tree in breadth-first order we make sure that parents
	// get lower ids then children. That is, adding a new child does not
	// change parent's id. This means that, say, adding a new function to a
	// trait does not change ids of top-level items, which helps caching.
	bdfs(node, \|it\| {
	if should_alloc_id(it.kind()) {
	res.alloc(&it);
	true
	} else {
	false
	}
	});
	res.map = hashbrown::HashMap::with_capacity_and_hasher(res.arena.len(), ());
	for (idx, ptr) in res.arena.iter() {
	let hash = hash_ptr(ptr);
	match res.map.raw_entry_mut().from_hash(hash, \|idx2\| *idx2 == idx) {
	hashbrown::hash_map::RawEntryMut::Occupied(_) => unreachable!(),
	hashbrown::hash_map::RawEntryMut::Vacant(entry) => {
	entry.insert_with_hasher(hash, idx, (), \|&idx\| hash_ptr(&res.arena[idx]));
	}
	}
	}
	res.arena.shrink_to_fit();
	res
	}

	pub fn ast_id<N: AstIdNode>(&self, item: &N) -> FileAstId<N> {
	let raw = self.erased_ast_id(item.syntax());
	FileAstId { raw, covariant: PhantomData }
	}

	pub fn get<N: AstIdNode>(&self, id: FileAstId<N>) -> AstPtr<N> {
	AstPtr::try_from_raw(self.arena[id.raw].clone()).unwrap()
	}

	pub(crate) fn get_raw(&self, id: ErasedFileAstId) -> SyntaxNodePtr {
	self.arena[id].clone()
	}

	fn erased_ast_id(&self, item: &SyntaxNode) -> ErasedFileAstId {
	let ptr = SyntaxNodePtr::new(item);
	let hash = hash_ptr(&ptr);
	match self.map.raw_entry().from_hash(hash, \|&idx\| self.arena[idx] == ptr) {
	Some((&idx, &())) => idx,
	None => panic!(
	"Can't find {:?} in AstIdMap:\n{:?}",
	item,
	self.arena.iter().map(\|(_id, i)\| i).collect::<Vec<_>>(),
	),
	}
	}

	fn alloc(&mut self, item: &SyntaxNode) -> ErasedFileAstId {
	self.arena.alloc(SyntaxNodePtr::new(item))
	}
	}

	fn hash_ptr(ptr: &SyntaxNodePtr) -> u64 {
	let mut hasher = BuildHasherDefault::<FxHasher>::default().build_hasher();
	ptr.hash(&mut hasher);
	hasher.finish()
	}

	/// Walks the subtree in bdfs order, calling `f` for each node. What is bdfs
	/// order? It is a mix of breadth-first and depth first orders. Nodes for which
	/// `f` returns true are visited breadth-first, all the other nodes are explored
	/// depth-first.
	///
	/// In other words, the size of the bfs queue is bound by the number of "true"
	/// nodes.
	fn bdfs(node: &SyntaxNode, mut f: impl FnMut(SyntaxNode) -> bool) {
	let mut curr_layer = vec![node.clone()];
	let mut next_layer = vec![];
	while !curr_layer.is_empty() {
	curr_layer.drain(..).for_each(\|node\| {
	let mut preorder = node.preorder();
	while let Some(event) = preorder.next() {
	match event {
	syntax::WalkEvent::Enter(node) => {
	if f(node.clone()) {
	next_layer.extend(node.children());
	preorder.skip_subtree();
	}
	}
	syntax::WalkEvent::Leave(_) => {}
	}
	}
	});
	std::mem::swap(&mut curr_layer, &mut next_layer);
	}
	}