src/librustc_resolve/def_collector.rs - third_party/rust - Git at Google

 use log::debug;
 use rustc::hir::map::definitions::*;
 use rustc::hir::def_id::DefIndex;
 use syntax::ast::*;
 use syntax::visit;
 use syntax::symbol::{kw, sym};
 use syntax::token::{self, Token};
 use syntax_expand::expand::AstFragment;
 use syntax_pos::hygiene::ExpnId;
 use syntax_pos::Span;

 crate fn collect_definitions(
     definitions: &mut Definitions,
     fragment: &AstFragment,
     expansion: ExpnId,
 ) {
     let parent_def = definitions.invocation_parent(expansion);
     fragment.visit_with(&mut DefCollector { definitions, parent_def, expansion });
 }

 /// Creates `DefId`s for nodes in the AST.
 struct DefCollector<'a> {
     definitions: &'a mut Definitions,
     parent_def: DefIndex,
     expansion: ExpnId,
 }

 impl<'a> DefCollector<'a> {
     fn create_def(&mut self,
                   node_id: NodeId,
                   data: DefPathData,
                   span: Span)
                   -> DefIndex {
         let parent_def = self.parent_def;
         debug!("create_def(node_id={:?}, data={:?}, parent_def={:?})", node_id, data, parent_def);
         self.definitions.create_def_with_parent(parent_def, node_id, data, self.expansion, span)
     }

     fn with_parent<F: FnOnce(&mut Self)>(&mut self, parent_def: DefIndex, f: F) {
         let orig_parent_def = std::mem::replace(&mut self.parent_def, parent_def);
         f(self);
         self.parent_def = orig_parent_def;
     }

     fn visit_async_fn(
         &mut self,
         id: NodeId,
         name: Name,
         span: Span,
         header: &FnHeader,
         generics: &'a Generics,
         decl: &'a FnDecl,
         body: &'a Block,
     ) {
         let (closure_id, return_impl_trait_id) = match header.asyncness.node {
             IsAsync::Async {
                 closure_id,
                 return_impl_trait_id,
             } => (closure_id, return_impl_trait_id),
             _ => unreachable!(),
         };

         // For async functions, we need to create their inner defs inside of a
         // closure to match their desugared representation.
         let fn_def_data = DefPathData::ValueNs(name);
         let fn_def = self.create_def(id, fn_def_data, span);
         return self.with_parent(fn_def, |this| {
             this.create_def(return_impl_trait_id, DefPathData::ImplTrait, span);

             visit::walk_generics(this, generics);
             visit::walk_fn_decl(this, decl);

             let closure_def = this.create_def(
                 closure_id, DefPathData::ClosureExpr, span,
             );
             this.with_parent(closure_def, |this| {
                 visit::walk_block(this, body);
             })
         })
     }

     fn collect_field(&mut self, field: &'a StructField, index: Option<usize>) {
         let index = |this: &Self| index.unwrap_or_else(|| {
             let node_id = NodeId::placeholder_from_expn_id(this.expansion);
             this.definitions.placeholder_field_index(node_id)
         });

         if field.is_placeholder {
             self.definitions.set_placeholder_field_index(field.id, index(self));
             self.visit_macro_invoc(field.id);
         } else {
             let name = field.ident.map_or_else(|| sym::integer(index(self)), |ident| ident.name);
             let def = self.create_def(field.id, DefPathData::ValueNs(name), field.span);
             self.with_parent(def, |this| visit::walk_struct_field(this, field));
         }
     }

     fn visit_macro_invoc(&mut self, id: NodeId) {
         self.definitions.set_invocation_parent(id.placeholder_to_expn_id(), self.parent_def);
     }
 }

 impl<'a> visit::Visitor<'a> for DefCollector<'a> {
     fn visit_item(&mut self, i: &'a Item) {
         debug!("visit_item: {:?}", i);

         // Pick the def data. This need not be unique, but the more
         // information we encapsulate into, the better
         let def_data = match &i.kind {
             ItemKind::Impl(..) => DefPathData::Impl,
             ItemKind::Mod(..) if i.ident.name == kw::Invalid => {
                 return visit::walk_item(self, i);
             }
             ItemKind::Mod(..) | ItemKind::Trait(..) | ItemKind::TraitAlias(..) |
             ItemKind::Enum(..) | ItemKind::Struct(..) | ItemKind::Union(..) |
             ItemKind::ExternCrate(..) | ItemKind::ForeignMod(..) |
             ItemKind::TyAlias(..) => DefPathData::TypeNs(i.ident.name),
             ItemKind::Fn(sig, generics, body) if sig.header.asyncness.node.is_async() => {
                 return self.visit_async_fn(
                     i.id,
                     i.ident.name,
                     i.span,
                     &sig.header,
                     generics,
                     &sig.decl,
                     body,
                 )
             }
             ItemKind::Static(..) | ItemKind::Const(..) | ItemKind::Fn(..) =>
                 DefPathData::ValueNs(i.ident.name),
             ItemKind::MacroDef(..) => DefPathData::MacroNs(i.ident.name),
             ItemKind::Mac(..) => return self.visit_macro_invoc(i.id),
             ItemKind::GlobalAsm(..) => DefPathData::Misc,
             ItemKind::Use(..) => {
                 return visit::walk_item(self, i);
             }
         };
         let def = self.create_def(i.id, def_data, i.span);

         self.with_parent(def, |this| {
             match i.kind {
                 ItemKind::Struct(ref struct_def, _) | ItemKind::Union(ref struct_def, _) => {
                     // If this is a unit or tuple-like struct, register the constructor.
                     if let Some(ctor_hir_id) = struct_def.ctor_id() {
                         this.create_def(ctor_hir_id, DefPathData::Ctor, i.span);
                     }
                 }
                 _ => {}
             }
             visit::walk_item(this, i);
         });
     }

     fn visit_use_tree(&mut self, use_tree: &'a UseTree, id: NodeId, _nested: bool) {
         self.create_def(id, DefPathData::Misc, use_tree.span);
         visit::walk_use_tree(self, use_tree, id);
     }

     fn visit_foreign_item(&mut self, foreign_item: &'a ForeignItem) {
         if let ForeignItemKind::Macro(_) = foreign_item.kind {
             return self.visit_macro_invoc(foreign_item.id);
         }

         let def = self.create_def(foreign_item.id,
                                   DefPathData::ValueNs(foreign_item.ident.name),
                                   foreign_item.span);

         self.with_parent(def, |this| {
             visit::walk_foreign_item(this, foreign_item);
         });
     }

     fn visit_variant(&mut self, v: &'a Variant) {
         if v.is_placeholder {
             return self.visit_macro_invoc(v.id);
         }
         let def = self.create_def(v.id,
                                   DefPathData::TypeNs(v.ident.name),
                                   v.span);
         self.with_parent(def, |this| {
             if let Some(ctor_hir_id) = v.data.ctor_id() {
                 this.create_def(ctor_hir_id, DefPathData::Ctor, v.span);
             }
             visit::walk_variant(this, v)
         });
     }

     fn visit_variant_data(&mut self, data: &'a VariantData) {
         // The assumption here is that non-`cfg` macro expansion cannot change field indices.
         // It currently holds because only inert attributes are accepted on fields,
         // and every such attribute expands into a single field after it's resolved.
         for (index, field) in data.fields().iter().enumerate() {
             self.collect_field(field, Some(index));
         }
     }

     fn visit_generic_param(&mut self, param: &'a GenericParam) {
         if param.is_placeholder {
             self.visit_macro_invoc(param.id);
             return;
         }
         let name = param.ident.name;
         let def_path_data = match param.kind {
             GenericParamKind::Lifetime { .. } => DefPathData::LifetimeNs(name),
             GenericParamKind::Type { .. } => DefPathData::TypeNs(name),
             GenericParamKind::Const { .. } => DefPathData::ValueNs(name),
         };
         self.create_def(param.id, def_path_data, param.ident.span);

         visit::walk_generic_param(self, param);
     }

     fn visit_trait_item(&mut self, ti: &'a TraitItem) {
         let def_data = match ti.kind {
             TraitItemKind::Method(..) | TraitItemKind::Const(..) =>
                 DefPathData::ValueNs(ti.ident.name),
             TraitItemKind::Type(..) => {
                 DefPathData::TypeNs(ti.ident.name)
             },
             TraitItemKind::Macro(..) => return self.visit_macro_invoc(ti.id),
         };

         let def = self.create_def(ti.id, def_data, ti.span);
         self.with_parent(def, |this| visit::walk_trait_item(this, ti));
     }

     fn visit_impl_item(&mut self, ii: &'a ImplItem) {
         let def_data = match ii.kind {
             ImplItemKind::Method(FnSig {
                 ref header,
                 ref decl,
             }, ref body) if header.asyncness.node.is_async() => {
                 return self.visit_async_fn(
                     ii.id,
                     ii.ident.name,
                     ii.span,
                     header,
                     &ii.generics,
                     decl,
                     body,
                 )
             }
             ImplItemKind::Method(..) |
             ImplItemKind::Const(..) => DefPathData::ValueNs(ii.ident.name),
             ImplItemKind::TyAlias(..) => DefPathData::TypeNs(ii.ident.name),
             ImplItemKind::Macro(..) => return self.visit_macro_invoc(ii.id),
         };

         let def = self.create_def(ii.id, def_data, ii.span);
         self.with_parent(def, |this| visit::walk_impl_item(this, ii));
     }

     fn visit_pat(&mut self, pat: &'a Pat) {
         match pat.kind {
             PatKind::Mac(..) => return self.visit_macro_invoc(pat.id),
             _ => visit::walk_pat(self, pat),
         }
     }

     fn visit_anon_const(&mut self, constant: &'a AnonConst) {
         let def = self.create_def(constant.id,
                                   DefPathData::AnonConst,
                                   constant.value.span);
         self.with_parent(def, |this| visit::walk_anon_const(this, constant));
     }

     fn visit_expr(&mut self, expr: &'a Expr) {
         let parent_def = match expr.kind {
             ExprKind::Mac(..) => return self.visit_macro_invoc(expr.id),
             ExprKind::Closure(_, asyncness, ..) => {
                 // Async closures desugar to closures inside of closures, so
                 // we must create two defs.
                 let closure_def = self.create_def(expr.id, DefPathData::ClosureExpr, expr.span);
                 match asyncness {
                     IsAsync::Async { closure_id, .. } =>
                         self.create_def(closure_id, DefPathData::ClosureExpr, expr.span),
                     IsAsync::NotAsync => closure_def,
                 }
             }
             ExprKind::Async(_, async_id, _) =>
                 self.create_def(async_id, DefPathData::ClosureExpr, expr.span),
             _ => self.parent_def,
         };

         self.with_parent(parent_def, |this| visit::walk_expr(this, expr));
     }

     fn visit_ty(&mut self, ty: &'a Ty) {
         match ty.kind {
             TyKind::Mac(..) => return self.visit_macro_invoc(ty.id),
             TyKind::ImplTrait(node_id, _) => {
                 self.create_def(node_id, DefPathData::ImplTrait, ty.span);
             }
             _ => {}
         }
         visit::walk_ty(self, ty);
     }

     fn visit_stmt(&mut self, stmt: &'a Stmt) {
         match stmt.kind {
             StmtKind::Mac(..) => self.visit_macro_invoc(stmt.id),
             _ => visit::walk_stmt(self, stmt),
         }
     }

     fn visit_token(&mut self, t: Token) {
         if let token::Interpolated(nt) = t.kind {
             if let token::NtExpr(ref expr) = *nt {
                 if let ExprKind::Mac(..) = expr.kind {
                     self.visit_macro_invoc(expr.id);
                 }
             }
         }
     }

     fn visit_arm(&mut self, arm: &'a Arm) {
         if arm.is_placeholder {
             self.visit_macro_invoc(arm.id)
         } else {
             visit::walk_arm(self, arm)
         }
     }

     fn visit_field(&mut self, f: &'a Field) {
         if f.is_placeholder {
             self.visit_macro_invoc(f.id)
         } else {
             visit::walk_field(self, f)
         }
     }

     fn visit_field_pattern(&mut self, fp: &'a FieldPat) {
         if fp.is_placeholder {
             self.visit_macro_invoc(fp.id)
         } else {
             visit::walk_field_pattern(self, fp)
         }
     }

     fn visit_param(&mut self, p: &'a Param) {
         if p.is_placeholder {
             self.visit_macro_invoc(p.id)
         } else {
             visit::walk_param(self, p)
         }
     }

     // This method is called only when we are visiting an individual field
     // after expanding an attribute on it.
     fn visit_struct_field(&mut self, field: &'a StructField) {
         self.collect_field(field, None);
     }
 }
	use log::debug;
	use rustc::hir::map::definitions::*;
	use rustc::hir::def_id::DefIndex;
	use syntax::ast::*;
	use syntax::visit;
	use syntax::symbol::{kw, sym};
	use syntax::token::{self, Token};
	use syntax_expand::expand::AstFragment;
	use syntax_pos::hygiene::ExpnId;
	use syntax_pos::Span;

	crate fn collect_definitions(
	definitions: &mut Definitions,
	fragment: &AstFragment,
	expansion: ExpnId,
	) {
	let parent_def = definitions.invocation_parent(expansion);
	fragment.visit_with(&mut DefCollector { definitions, parent_def, expansion });
	}

	/// Creates `DefId`s for nodes in the AST.
	struct DefCollector<'a> {
	definitions: &'a mut Definitions,
	parent_def: DefIndex,
	expansion: ExpnId,
	}

	impl<'a> DefCollector<'a> {
	fn create_def(&mut self,
	node_id: NodeId,
	data: DefPathData,
	span: Span)
	-> DefIndex {
	let parent_def = self.parent_def;
	debug!("create_def(node_id={:?}, data={:?}, parent_def={:?})", node_id, data, parent_def);
	self.definitions.create_def_with_parent(parent_def, node_id, data, self.expansion, span)
	}

	fn with_parent<F: FnOnce(&mut Self)>(&mut self, parent_def: DefIndex, f: F) {
	let orig_parent_def = std::mem::replace(&mut self.parent_def, parent_def);
	f(self);
	self.parent_def = orig_parent_def;
	}

	fn visit_async_fn(
	&mut self,
	id: NodeId,
	name: Name,
	span: Span,
	header: &FnHeader,
	generics: &'a Generics,
	decl: &'a FnDecl,
	body: &'a Block,
	) {
	let (closure_id, return_impl_trait_id) = match header.asyncness.node {
	IsAsync::Async {
	closure_id,
	return_impl_trait_id,
	} => (closure_id, return_impl_trait_id),
	_ => unreachable!(),
	};

	// For async functions, we need to create their inner defs inside of a
	// closure to match their desugared representation.
	let fn_def_data = DefPathData::ValueNs(name);
	let fn_def = self.create_def(id, fn_def_data, span);
	return self.with_parent(fn_def, \|this\| {
	this.create_def(return_impl_trait_id, DefPathData::ImplTrait, span);

	visit::walk_generics(this, generics);
	visit::walk_fn_decl(this, decl);

	let closure_def = this.create_def(
	closure_id, DefPathData::ClosureExpr, span,
	);
	this.with_parent(closure_def, \|this\| {
	visit::walk_block(this, body);
	})
	})
	}

	fn collect_field(&mut self, field: &'a StructField, index: Option<usize>) {
	let index = \|this: &Self\| index.unwrap_or_else(\|\| {
	let node_id = NodeId::placeholder_from_expn_id(this.expansion);
	this.definitions.placeholder_field_index(node_id)
	});

	if field.is_placeholder {
	self.definitions.set_placeholder_field_index(field.id, index(self));
	self.visit_macro_invoc(field.id);
	} else {
	let name = field.ident.map_or_else(\|\| sym::integer(index(self)), \|ident\| ident.name);
	let def = self.create_def(field.id, DefPathData::ValueNs(name), field.span);
	self.with_parent(def, \|this\| visit::walk_struct_field(this, field));
	}
	}

	fn visit_macro_invoc(&mut self, id: NodeId) {
	self.definitions.set_invocation_parent(id.placeholder_to_expn_id(), self.parent_def);
	}
	}

	impl<'a> visit::Visitor<'a> for DefCollector<'a> {
	fn visit_item(&mut self, i: &'a Item) {
	debug!("visit_item: {:?}", i);

	// Pick the def data. This need not be unique, but the more
	// information we encapsulate into, the better
	let def_data = match &i.kind {
	ItemKind::Impl(..) => DefPathData::Impl,
	ItemKind::Mod(..) if i.ident.name == kw::Invalid => {
	return visit::walk_item(self, i);
	}
	ItemKind::Mod(..) \| ItemKind::Trait(..) \| ItemKind::TraitAlias(..) \|
	ItemKind::Enum(..) \| ItemKind::Struct(..) \| ItemKind::Union(..) \|
	ItemKind::ExternCrate(..) \| ItemKind::ForeignMod(..) \|
	ItemKind::TyAlias(..) => DefPathData::TypeNs(i.ident.name),
	ItemKind::Fn(sig, generics, body) if sig.header.asyncness.node.is_async() => {
	return self.visit_async_fn(
	i.id,
	i.ident.name,
	i.span,
	&sig.header,
	generics,
	&sig.decl,
	body,
	)
	}
	ItemKind::Static(..) \| ItemKind::Const(..) \| ItemKind::Fn(..) =>
	DefPathData::ValueNs(i.ident.name),
	ItemKind::MacroDef(..) => DefPathData::MacroNs(i.ident.name),
	ItemKind::Mac(..) => return self.visit_macro_invoc(i.id),
	ItemKind::GlobalAsm(..) => DefPathData::Misc,
	ItemKind::Use(..) => {
	return visit::walk_item(self, i);
	}
	};
	let def = self.create_def(i.id, def_data, i.span);

	self.with_parent(def, \|this\| {
	match i.kind {
	ItemKind::Struct(ref struct_def, _) \| ItemKind::Union(ref struct_def, _) => {
	// If this is a unit or tuple-like struct, register the constructor.
	if let Some(ctor_hir_id) = struct_def.ctor_id() {
	this.create_def(ctor_hir_id, DefPathData::Ctor, i.span);
	}
	}
	_ => {}
	}
	visit::walk_item(this, i);
	});
	}

	fn visit_use_tree(&mut self, use_tree: &'a UseTree, id: NodeId, _nested: bool) {
	self.create_def(id, DefPathData::Misc, use_tree.span);
	visit::walk_use_tree(self, use_tree, id);
	}

	fn visit_foreign_item(&mut self, foreign_item: &'a ForeignItem) {
	if let ForeignItemKind::Macro(_) = foreign_item.kind {
	return self.visit_macro_invoc(foreign_item.id);
	}

	let def = self.create_def(foreign_item.id,
	DefPathData::ValueNs(foreign_item.ident.name),
	foreign_item.span);

	self.with_parent(def, \|this\| {
	visit::walk_foreign_item(this, foreign_item);
	});
	}

	fn visit_variant(&mut self, v: &'a Variant) {
	if v.is_placeholder {
	return self.visit_macro_invoc(v.id);
	}
	let def = self.create_def(v.id,
	DefPathData::TypeNs(v.ident.name),
	v.span);
	self.with_parent(def, \|this\| {
	if let Some(ctor_hir_id) = v.data.ctor_id() {
	this.create_def(ctor_hir_id, DefPathData::Ctor, v.span);
	}
	visit::walk_variant(this, v)
	});
	}

	fn visit_variant_data(&mut self, data: &'a VariantData) {
	// The assumption here is that non-`cfg` macro expansion cannot change field indices.
	// It currently holds because only inert attributes are accepted on fields,
	// and every such attribute expands into a single field after it's resolved.
	for (index, field) in data.fields().iter().enumerate() {
	self.collect_field(field, Some(index));
	}
	}

	fn visit_generic_param(&mut self, param: &'a GenericParam) {
	if param.is_placeholder {
	self.visit_macro_invoc(param.id);
	return;
	}
	let name = param.ident.name;
	let def_path_data = match param.kind {
	GenericParamKind::Lifetime { .. } => DefPathData::LifetimeNs(name),
	GenericParamKind::Type { .. } => DefPathData::TypeNs(name),
	GenericParamKind::Const { .. } => DefPathData::ValueNs(name),
	};
	self.create_def(param.id, def_path_data, param.ident.span);

	visit::walk_generic_param(self, param);
	}

	fn visit_trait_item(&mut self, ti: &'a TraitItem) {
	let def_data = match ti.kind {
	TraitItemKind::Method(..) \| TraitItemKind::Const(..) =>
	DefPathData::ValueNs(ti.ident.name),
	TraitItemKind::Type(..) => {
	DefPathData::TypeNs(ti.ident.name)
	},
	TraitItemKind::Macro(..) => return self.visit_macro_invoc(ti.id),
	};

	let def = self.create_def(ti.id, def_data, ti.span);
	self.with_parent(def, \|this\| visit::walk_trait_item(this, ti));
	}

	fn visit_impl_item(&mut self, ii: &'a ImplItem) {
	let def_data = match ii.kind {
	ImplItemKind::Method(FnSig {
	ref header,
	ref decl,
	}, ref body) if header.asyncness.node.is_async() => {
	return self.visit_async_fn(
	ii.id,
	ii.ident.name,
	ii.span,
	header,
	&ii.generics,
	decl,
	body,
	)
	}
	ImplItemKind::Method(..) \|
	ImplItemKind::Const(..) => DefPathData::ValueNs(ii.ident.name),
	ImplItemKind::TyAlias(..) => DefPathData::TypeNs(ii.ident.name),
	ImplItemKind::Macro(..) => return self.visit_macro_invoc(ii.id),
	};

	let def = self.create_def(ii.id, def_data, ii.span);
	self.with_parent(def, \|this\| visit::walk_impl_item(this, ii));
	}

	fn visit_pat(&mut self, pat: &'a Pat) {
	match pat.kind {
	PatKind::Mac(..) => return self.visit_macro_invoc(pat.id),
	_ => visit::walk_pat(self, pat),
	}
	}

	fn visit_anon_const(&mut self, constant: &'a AnonConst) {
	let def = self.create_def(constant.id,
	DefPathData::AnonConst,
	constant.value.span);
	self.with_parent(def, \|this\| visit::walk_anon_const(this, constant));
	}

	fn visit_expr(&mut self, expr: &'a Expr) {
	let parent_def = match expr.kind {
	ExprKind::Mac(..) => return self.visit_macro_invoc(expr.id),
	ExprKind::Closure(_, asyncness, ..) => {
	// Async closures desugar to closures inside of closures, so
	// we must create two defs.
	let closure_def = self.create_def(expr.id, DefPathData::ClosureExpr, expr.span);
	match asyncness {
	IsAsync::Async { closure_id, .. } =>
	self.create_def(closure_id, DefPathData::ClosureExpr, expr.span),
	IsAsync::NotAsync => closure_def,
	}
	}
	ExprKind::Async(_, async_id, _) =>
	self.create_def(async_id, DefPathData::ClosureExpr, expr.span),
	_ => self.parent_def,
	};

	self.with_parent(parent_def, \|this\| visit::walk_expr(this, expr));
	}

	fn visit_ty(&mut self, ty: &'a Ty) {
	match ty.kind {
	TyKind::Mac(..) => return self.visit_macro_invoc(ty.id),
	TyKind::ImplTrait(node_id, _) => {
	self.create_def(node_id, DefPathData::ImplTrait, ty.span);
	}
	_ => {}
	}
	visit::walk_ty(self, ty);
	}

	fn visit_stmt(&mut self, stmt: &'a Stmt) {
	match stmt.kind {
	StmtKind::Mac(..) => self.visit_macro_invoc(stmt.id),
	_ => visit::walk_stmt(self, stmt),
	}
	}

	fn visit_token(&mut self, t: Token) {
	if let token::Interpolated(nt) = t.kind {
	if let token::NtExpr(ref expr) = *nt {
	if let ExprKind::Mac(..) = expr.kind {
	self.visit_macro_invoc(expr.id);
	}
	}
	}
	}

	fn visit_arm(&mut self, arm: &'a Arm) {
	if arm.is_placeholder {
	self.visit_macro_invoc(arm.id)
	} else {
	visit::walk_arm(self, arm)
	}
	}

	fn visit_field(&mut self, f: &'a Field) {
	if f.is_placeholder {
	self.visit_macro_invoc(f.id)
	} else {
	visit::walk_field(self, f)
	}
	}

	fn visit_field_pattern(&mut self, fp: &'a FieldPat) {
	if fp.is_placeholder {
	self.visit_macro_invoc(fp.id)
	} else {
	visit::walk_field_pattern(self, fp)
	}
	}

	fn visit_param(&mut self, p: &'a Param) {
	if p.is_placeholder {
	self.visit_macro_invoc(p.id)
	} else {
	visit::walk_param(self, p)
	}
	}

	// This method is called only when we are visiting an individual field
	// after expanding an attribute on it.
	fn visit_struct_field(&mut self, field: &'a StructField) {
	self.collect_field(field, None);
	}
	}