src/librustc_builtin_macros/proc_macro_harness.rs - third_party/rust - Git at Google

 use std::mem;

 use rustc_ast::ast::{self, NodeId};
 use rustc_ast::attr;
 use rustc_ast::expand::is_proc_macro_attr;
 use rustc_ast::ptr::P;
 use rustc_ast::visit::{self, Visitor};
 use rustc_ast_pretty::pprust;
 use rustc_expand::base::{ExtCtxt, ResolverExpand};
 use rustc_expand::expand::{AstFragment, ExpansionConfig};
 use rustc_session::parse::ParseSess;
 use rustc_span::hygiene::AstPass;
 use rustc_span::source_map::SourceMap;
 use rustc_span::symbol::{kw, sym, Ident, Symbol};
 use rustc_span::{Span, DUMMY_SP};
 use smallvec::smallvec;
 use std::cell::RefCell;

 struct ProcMacroDerive {
     id: NodeId,
     trait_name: Symbol,
     function_name: Ident,
     span: Span,
     attrs: Vec<Symbol>,
 }

 enum ProcMacroDefType {
     Attr,
     Bang,
 }

 struct ProcMacroDef {
     id: NodeId,
     function_name: Ident,
     span: Span,
     def_type: ProcMacroDefType,
 }

 enum ProcMacro {
     Derive(ProcMacroDerive),
     Def(ProcMacroDef),
 }

 struct CollectProcMacros<'a> {
     macros: Vec<ProcMacro>,
     in_root: bool,
     handler: &'a rustc_errors::Handler,
     source_map: &'a SourceMap,
     is_proc_macro_crate: bool,
     is_test_crate: bool,
 }

 pub fn inject(
     sess: &ParseSess,
     resolver: &mut dyn ResolverExpand,
     mut krate: ast::Crate,
     is_proc_macro_crate: bool,
     has_proc_macro_decls: bool,
     is_test_crate: bool,
     num_crate_types: usize,
     handler: &rustc_errors::Handler,
 ) -> ast::Crate {
     let ecfg = ExpansionConfig::default("proc_macro".to_string());
     let mut cx = ExtCtxt::new(sess, ecfg, resolver, None);

     let mut collect = CollectProcMacros {
         macros: Vec::new(),
         in_root: true,
         handler,
         source_map: sess.source_map(),
         is_proc_macro_crate,
         is_test_crate,
     };

     if has_proc_macro_decls || is_proc_macro_crate {
         visit::walk_crate(&mut collect, &krate);
     }
     let macros = collect.macros;

     if !is_proc_macro_crate {
         return krate;
     }

     if num_crate_types > 1 {
         handler.err("cannot mix `proc-macro` crate type with others");
     }

     if is_test_crate {
         return krate;
     }

     let decls = mk_decls(&mut krate, &mut cx, &macros);
     krate.module.items.push(decls);

     krate
 }

 impl<'a> CollectProcMacros<'a> {
     fn check_not_pub_in_root(&self, vis: &ast::Visibility, sp: Span) {
         if self.is_proc_macro_crate && self.in_root && vis.node.is_pub() {
             self.handler.span_err(
                 sp,
                 "`proc-macro` crate types currently cannot export any items other \
                     than functions tagged with `#[proc_macro]`, `#[proc_macro_derive]`, \
                     or `#[proc_macro_attribute]`",
             );
         }
     }

     fn collect_custom_derive(&mut self, item: &'a ast::Item, attr: &'a ast::Attribute) {
         // Once we've located the `#[proc_macro_derive]` attribute, verify
         // that it's of the form `#[proc_macro_derive(Foo)]` or
         // `#[proc_macro_derive(Foo, attributes(A, ..))]`
         let list = match attr.meta_item_list() {
             Some(list) => list,
             None => return,
         };
         if list.len() != 1 && list.len() != 2 {
             self.handler.span_err(attr.span, "attribute must have either one or two arguments");
             return;
         }
         let trait_attr = match list[0].meta_item() {
             Some(meta_item) => meta_item,
             _ => {
                 self.handler.span_err(list[0].span(), "not a meta item");
                 return;
             }
         };
         let trait_ident = match trait_attr.ident() {
             Some(trait_ident) if trait_attr.is_word() => trait_ident,
             _ => {
                 self.handler.span_err(trait_attr.span, "must only be one word");
                 return;
             }
         };

         if !trait_ident.name.can_be_raw() {
             self.handler.span_err(
                 trait_attr.span,
                 &format!("`{}` cannot be a name of derive macro", trait_ident),
             );
         }

         let attributes_attr = list.get(1);
         let proc_attrs: Vec<_> = if let Some(attr) = attributes_attr {
             if !attr.check_name(sym::attributes) {
                 self.handler.span_err(attr.span(), "second argument must be `attributes`")
             }
             attr.meta_item_list()
                 .unwrap_or_else(|| {
                     self.handler
                         .span_err(attr.span(), "attribute must be of form: `attributes(foo, bar)`");
                     &[]
                 })
                 .iter()
                 .filter_map(|attr| {
                     let attr = match attr.meta_item() {
                         Some(meta_item) => meta_item,
                         _ => {
                             self.handler.span_err(attr.span(), "not a meta item");
                             return None;
                         }
                     };

                     let ident = match attr.ident() {
                         Some(ident) if attr.is_word() => ident,
                         _ => {
                             self.handler.span_err(attr.span, "must only be one word");
                             return None;
                         }
                     };
                     if !ident.name.can_be_raw() {
                         self.handler.span_err(
                             attr.span,
                             &format!("`{}` cannot be a name of derive helper attribute", ident),
                         );
                     }

                     Some(ident.name)
                 })
                 .collect()
         } else {
             Vec::new()
         };

         if self.in_root && item.vis.node.is_pub() {
             self.macros.push(ProcMacro::Derive(ProcMacroDerive {
                 id: item.id,
                 span: item.span,
                 trait_name: trait_ident.name,
                 function_name: item.ident,
                 attrs: proc_attrs,
             }));
         } else {
             let msg = if !self.in_root {
                 "functions tagged with `#[proc_macro_derive]` must \
                  currently reside in the root of the crate"
             } else {
                 "functions tagged with `#[proc_macro_derive]` must be `pub`"
             };
             self.handler.span_err(self.source_map.guess_head_span(item.span), msg);
         }
     }

     fn collect_attr_proc_macro(&mut self, item: &'a ast::Item) {
         if self.in_root && item.vis.node.is_pub() {
             self.macros.push(ProcMacro::Def(ProcMacroDef {
                 id: item.id,
                 span: item.span,
                 function_name: item.ident,
                 def_type: ProcMacroDefType::Attr,
             }));
         } else {
             let msg = if !self.in_root {
                 "functions tagged with `#[proc_macro_attribute]` must \
                  currently reside in the root of the crate"
             } else {
                 "functions tagged with `#[proc_macro_attribute]` must be `pub`"
             };
             self.handler.span_err(self.source_map.guess_head_span(item.span), msg);
         }
     }

     fn collect_bang_proc_macro(&mut self, item: &'a ast::Item) {
         if self.in_root && item.vis.node.is_pub() {
             self.macros.push(ProcMacro::Def(ProcMacroDef {
                 id: item.id,
                 span: item.span,
                 function_name: item.ident,
                 def_type: ProcMacroDefType::Bang,
             }));
         } else {
             let msg = if !self.in_root {
                 "functions tagged with `#[proc_macro]` must \
                  currently reside in the root of the crate"
             } else {
                 "functions tagged with `#[proc_macro]` must be `pub`"
             };
             self.handler.span_err(self.source_map.guess_head_span(item.span), msg);
         }
     }
 }

 impl<'a> Visitor<'a> for CollectProcMacros<'a> {
     fn visit_item(&mut self, item: &'a ast::Item) {
         if let ast::ItemKind::MacroDef(..) = item.kind {
             if self.is_proc_macro_crate && attr::contains_name(&item.attrs, sym::macro_export) {
                 let msg =
                     "cannot export macro_rules! macros from a `proc-macro` crate type currently";
                 self.handler.span_err(self.source_map.guess_head_span(item.span), msg);
             }
         }

         // First up, make sure we're checking a bare function. If we're not then
         // we're just not interested in this item.
         //
         // If we find one, try to locate a `#[proc_macro_derive]` attribute on it.
         let is_fn = match item.kind {
             ast::ItemKind::Fn(..) => true,
             _ => false,
         };

         let mut found_attr: Option<&'a ast::Attribute> = None;

         for attr in &item.attrs {
             if is_proc_macro_attr(&attr) {
                 if let Some(prev_attr) = found_attr {
                     let prev_item = prev_attr.get_normal_item();
                     let item = attr.get_normal_item();
                     let path_str = pprust::path_to_string(&item.path);
                     let msg = if item.path.segments[0].ident.name
                         == prev_item.path.segments[0].ident.name
                     {
                         format!(
                             "only one `#[{}]` attribute is allowed on any given function",
                             path_str,
                         )
                     } else {
                         format!(
                             "`#[{}]` and `#[{}]` attributes cannot both be applied
                             to the same function",
                             path_str,
                             pprust::path_to_string(&prev_item.path),
                         )
                     };

                     self.handler
                         .struct_span_err(attr.span, &msg)
                         .span_label(prev_attr.span, "previous attribute here")
                         .emit();

                     return;
                 }

                 found_attr = Some(attr);
             }
         }

         let attr = match found_attr {
             None => {
                 self.check_not_pub_in_root(&item.vis, self.source_map.guess_head_span(item.span));
                 let prev_in_root = mem::replace(&mut self.in_root, false);
                 visit::walk_item(self, item);
                 self.in_root = prev_in_root;
                 return;
             }
             Some(attr) => attr,
         };

         if !is_fn {
             let msg = format!(
                 "the `#[{}]` attribute may only be used on bare functions",
                 pprust::path_to_string(&attr.get_normal_item().path),
             );

             self.handler.span_err(attr.span, &msg);
             return;
         }

         if self.is_test_crate {
             return;
         }

         if !self.is_proc_macro_crate {
             let msg = format!(
                 "the `#[{}]` attribute is only usable with crates of the `proc-macro` crate type",
                 pprust::path_to_string(&attr.get_normal_item().path),
             );

             self.handler.span_err(attr.span, &msg);
             return;
         }

         if attr.check_name(sym::proc_macro_derive) {
             self.collect_custom_derive(item, attr);
         } else if attr.check_name(sym::proc_macro_attribute) {
             self.collect_attr_proc_macro(item);
         } else if attr.check_name(sym::proc_macro) {
             self.collect_bang_proc_macro(item);
         };

         let prev_in_root = mem::replace(&mut self.in_root, false);
         visit::walk_item(self, item);
         self.in_root = prev_in_root;
     }

     fn visit_mac(&mut self, mac: &'a ast::MacCall) {
         visit::walk_mac(self, mac)
     }
 }

 // Creates a new module which looks like:
 //
 //      const _: () = {
 //          extern crate proc_macro;
 //
 //          use proc_macro::bridge::client::ProcMacro;
 //
 //          #[rustc_proc_macro_decls]
 //          #[allow(deprecated)]
 //          static DECLS: &[ProcMacro] = &[
 //              ProcMacro::custom_derive($name_trait1, &[], ::$name1);
 //              ProcMacro::custom_derive($name_trait2, &["attribute_name"], ::$name2);
 //              // ...
 //          ];
 //      }
 fn mk_decls(
     ast_krate: &mut ast::Crate,
     cx: &mut ExtCtxt<'_>,
     macros: &[ProcMacro],
 ) -> P<ast::Item> {
     // We're the ones filling in this Vec,
     // so it should be empty to start with
     assert!(ast_krate.proc_macros.is_empty());

     let expn_id = cx.resolver.expansion_for_ast_pass(
         DUMMY_SP,
         AstPass::ProcMacroHarness,
         &[sym::rustc_attrs, sym::proc_macro_internals],
         None,
     );
     let span = DUMMY_SP.with_def_site_ctxt(expn_id);

     let proc_macro = Ident::new(sym::proc_macro, span);
     let krate = cx.item(span, proc_macro, Vec::new(), ast::ItemKind::ExternCrate(None));

     let bridge = cx.ident_of("bridge", span);
     let client = cx.ident_of("client", span);
     let proc_macro_ty = cx.ident_of("ProcMacro", span);
     let custom_derive = cx.ident_of("custom_derive", span);
     let attr = cx.ident_of("attr", span);
     let bang = cx.ident_of("bang", span);

     let krate_ref = RefCell::new(ast_krate);

     // We add NodeIds to 'krate.proc_macros' in the order
     // that we generate expressions. The position of each NodeId
     // in the 'proc_macros' Vec corresponds to its position
     // in the static array that will be generated
     let decls = {
         let local_path =
             |sp: Span, name| cx.expr_path(cx.path(sp.with_ctxt(span.ctxt()), vec![name]));
         let proc_macro_ty_method_path = |method| {
             cx.expr_path(cx.path(span, vec![proc_macro, bridge, client, proc_macro_ty, method]))
         };
         macros
             .iter()
             .map(|m| match m {
                 ProcMacro::Derive(cd) => {
                     krate_ref.borrow_mut().proc_macros.push(cd.id);
                     cx.expr_call(
                         span,
                         proc_macro_ty_method_path(custom_derive),
                         vec![
                             cx.expr_str(cd.span, cd.trait_name),
                             cx.expr_vec_slice(
                                 span,
                                 cd.attrs
                                     .iter()
                                     .map(|&s| cx.expr_str(cd.span, s))
                                     .collect::<Vec<_>>(),
                             ),
                             local_path(cd.span, cd.function_name),
                         ],
                     )
                 }
                 ProcMacro::Def(ca) => {
                     krate_ref.borrow_mut().proc_macros.push(ca.id);
                     let ident = match ca.def_type {
                         ProcMacroDefType::Attr => attr,
                         ProcMacroDefType::Bang => bang,
                     };

                     cx.expr_call(
                         span,
                         proc_macro_ty_method_path(ident),
                         vec![
                             cx.expr_str(ca.span, ca.function_name.name),
                             local_path(ca.span, ca.function_name),
                         ],
                     )
                 }
             })
             .collect()
     };

     let decls_static = cx
         .item_static(
             span,
             cx.ident_of("_DECLS", span),
             cx.ty_rptr(
                 span,
                 cx.ty(
                     span,
                     ast::TyKind::Slice(
                         cx.ty_path(cx.path(span, vec![proc_macro, bridge, client, proc_macro_ty])),
                     ),
                 ),
                 None,
                 ast::Mutability::Not,
             ),
             ast::Mutability::Not,
             cx.expr_vec_slice(span, decls),
         )
         .map(|mut i| {
             let attr = cx.meta_word(span, sym::rustc_proc_macro_decls);
             i.attrs.push(cx.attribute(attr));

             let deprecated_attr = attr::mk_nested_word_item(Ident::new(sym::deprecated, span));
             let allow_deprecated_attr =
                 attr::mk_list_item(Ident::new(sym::allow, span), vec![deprecated_attr]);
             i.attrs.push(cx.attribute(allow_deprecated_attr));

             i
         });

     let block = cx.expr_block(
         cx.block(span, vec![cx.stmt_item(span, krate), cx.stmt_item(span, decls_static)]),
     );

     let anon_constant = cx.item_const(
         span,
         Ident::new(kw::Underscore, span),
         cx.ty(span, ast::TyKind::Tup(Vec::new())),
         block,
     );

     // Integrate the new item into existing module structures.
     let items = AstFragment::Items(smallvec![anon_constant]);
     cx.monotonic_expander().fully_expand_fragment(items).make_items().pop().unwrap()
 }
	use std::mem;

	use rustc_ast::ast::{self, NodeId};
	use rustc_ast::attr;
	use rustc_ast::expand::is_proc_macro_attr;
	use rustc_ast::ptr::P;
	use rustc_ast::visit::{self, Visitor};
	use rustc_ast_pretty::pprust;
	use rustc_expand::base::{ExtCtxt, ResolverExpand};
	use rustc_expand::expand::{AstFragment, ExpansionConfig};
	use rustc_session::parse::ParseSess;
	use rustc_span::hygiene::AstPass;
	use rustc_span::source_map::SourceMap;
	use rustc_span::symbol::{kw, sym, Ident, Symbol};
	use rustc_span::{Span, DUMMY_SP};
	use smallvec::smallvec;
	use std::cell::RefCell;

	struct ProcMacroDerive {
	id: NodeId,
	trait_name: Symbol,
	function_name: Ident,
	span: Span,
	attrs: Vec<Symbol>,
	}

	enum ProcMacroDefType {
	Attr,
	Bang,
	}

	struct ProcMacroDef {
	id: NodeId,
	function_name: Ident,
	span: Span,
	def_type: ProcMacroDefType,
	}

	enum ProcMacro {
	Derive(ProcMacroDerive),
	Def(ProcMacroDef),
	}

	struct CollectProcMacros<'a> {
	macros: Vec<ProcMacro>,
	in_root: bool,
	handler: &'a rustc_errors::Handler,
	source_map: &'a SourceMap,
	is_proc_macro_crate: bool,
	is_test_crate: bool,
	}

	pub fn inject(
	sess: &ParseSess,
	resolver: &mut dyn ResolverExpand,
	mut krate: ast::Crate,
	is_proc_macro_crate: bool,
	has_proc_macro_decls: bool,
	is_test_crate: bool,
	num_crate_types: usize,
	handler: &rustc_errors::Handler,
	) -> ast::Crate {
	let ecfg = ExpansionConfig::default("proc_macro".to_string());
	let mut cx = ExtCtxt::new(sess, ecfg, resolver, None);

	let mut collect = CollectProcMacros {
	macros: Vec::new(),
	in_root: true,
	handler,
	source_map: sess.source_map(),
	is_proc_macro_crate,
	is_test_crate,
	};

	if has_proc_macro_decls \|\| is_proc_macro_crate {
	visit::walk_crate(&mut collect, &krate);
	}
	let macros = collect.macros;

	if !is_proc_macro_crate {
	return krate;
	}

	if num_crate_types > 1 {
	handler.err("cannot mix `proc-macro` crate type with others");
	}

	if is_test_crate {
	return krate;
	}

	let decls = mk_decls(&mut krate, &mut cx, &macros);
	krate.module.items.push(decls);

	krate
	}

	impl<'a> CollectProcMacros<'a> {
	fn check_not_pub_in_root(&self, vis: &ast::Visibility, sp: Span) {
	if self.is_proc_macro_crate && self.in_root && vis.node.is_pub() {
	self.handler.span_err(
	sp,
	"`proc-macro` crate types currently cannot export any items other \
	than functions tagged with `#[proc_macro]`, `#[proc_macro_derive]`, \
	or `#[proc_macro_attribute]`",
	);
	}
	}

	fn collect_custom_derive(&mut self, item: &'a ast::Item, attr: &'a ast::Attribute) {
	// Once we've located the `#[proc_macro_derive]` attribute, verify
	// that it's of the form `#[proc_macro_derive(Foo)]` or
	// `#[proc_macro_derive(Foo, attributes(A, ..))]`
	let list = match attr.meta_item_list() {
	Some(list) => list,
	None => return,
	};
	if list.len() != 1 && list.len() != 2 {
	self.handler.span_err(attr.span, "attribute must have either one or two arguments");
	return;
	}
	let trait_attr = match list[0].meta_item() {
	Some(meta_item) => meta_item,
	_ => {
	self.handler.span_err(list[0].span(), "not a meta item");
	return;
	}
	};
	let trait_ident = match trait_attr.ident() {
	Some(trait_ident) if trait_attr.is_word() => trait_ident,
	_ => {
	self.handler.span_err(trait_attr.span, "must only be one word");
	return;
	}
	};

	if !trait_ident.name.can_be_raw() {
	self.handler.span_err(
	trait_attr.span,
	&format!("`{}` cannot be a name of derive macro", trait_ident),
	);
	}

	let attributes_attr = list.get(1);
	let proc_attrs: Vec<_> = if let Some(attr) = attributes_attr {
	if !attr.check_name(sym::attributes) {
	self.handler.span_err(attr.span(), "second argument must be `attributes`")
	}
	attr.meta_item_list()
	.unwrap_or_else(\|\| {
	self.handler
	.span_err(attr.span(), "attribute must be of form: `attributes(foo, bar)`");
	&[]
	})
	.iter()
	.filter_map(\|attr\| {
	let attr = match attr.meta_item() {
	Some(meta_item) => meta_item,
	_ => {
	self.handler.span_err(attr.span(), "not a meta item");
	return None;
	}
	};

	let ident = match attr.ident() {
	Some(ident) if attr.is_word() => ident,
	_ => {
	self.handler.span_err(attr.span, "must only be one word");
	return None;
	}
	};
	if !ident.name.can_be_raw() {
	self.handler.span_err(
	attr.span,
	&format!("`{}` cannot be a name of derive helper attribute", ident),
	);
	}

	Some(ident.name)
	})
	.collect()
	} else {
	Vec::new()
	};

	if self.in_root && item.vis.node.is_pub() {
	self.macros.push(ProcMacro::Derive(ProcMacroDerive {
	id: item.id,
	span: item.span,
	trait_name: trait_ident.name,
	function_name: item.ident,
	attrs: proc_attrs,
	}));
	} else {
	let msg = if !self.in_root {
	"functions tagged with `#[proc_macro_derive]` must \
	currently reside in the root of the crate"
	} else {
	"functions tagged with `#[proc_macro_derive]` must be `pub`"
	};
	self.handler.span_err(self.source_map.guess_head_span(item.span), msg);
	}
	}

	fn collect_attr_proc_macro(&mut self, item: &'a ast::Item) {
	if self.in_root && item.vis.node.is_pub() {
	self.macros.push(ProcMacro::Def(ProcMacroDef {
	id: item.id,
	span: item.span,
	function_name: item.ident,
	def_type: ProcMacroDefType::Attr,
	}));
	} else {
	let msg = if !self.in_root {
	"functions tagged with `#[proc_macro_attribute]` must \
	currently reside in the root of the crate"
	} else {
	"functions tagged with `#[proc_macro_attribute]` must be `pub`"
	};
	self.handler.span_err(self.source_map.guess_head_span(item.span), msg);
	}
	}

	fn collect_bang_proc_macro(&mut self, item: &'a ast::Item) {
	if self.in_root && item.vis.node.is_pub() {
	self.macros.push(ProcMacro::Def(ProcMacroDef {
	id: item.id,
	span: item.span,
	function_name: item.ident,
	def_type: ProcMacroDefType::Bang,
	}));
	} else {
	let msg = if !self.in_root {
	"functions tagged with `#[proc_macro]` must \
	currently reside in the root of the crate"
	} else {
	"functions tagged with `#[proc_macro]` must be `pub`"
	};
	self.handler.span_err(self.source_map.guess_head_span(item.span), msg);
	}
	}
	}

	impl<'a> Visitor<'a> for CollectProcMacros<'a> {
	fn visit_item(&mut self, item: &'a ast::Item) {
	if let ast::ItemKind::MacroDef(..) = item.kind {
	if self.is_proc_macro_crate && attr::contains_name(&item.attrs, sym::macro_export) {
	let msg =
	"cannot export macro_rules! macros from a `proc-macro` crate type currently";
	self.handler.span_err(self.source_map.guess_head_span(item.span), msg);
	}
	}

	// First up, make sure we're checking a bare function. If we're not then
	// we're just not interested in this item.
	//
	// If we find one, try to locate a `#[proc_macro_derive]` attribute on it.
	let is_fn = match item.kind {
	ast::ItemKind::Fn(..) => true,
	_ => false,
	};

	let mut found_attr: Option<&'a ast::Attribute> = None;

	for attr in &item.attrs {
	if is_proc_macro_attr(&attr) {
	if let Some(prev_attr) = found_attr {
	let prev_item = prev_attr.get_normal_item();
	let item = attr.get_normal_item();
	let path_str = pprust::path_to_string(&item.path);
	let msg = if item.path.segments[0].ident.name
	== prev_item.path.segments[0].ident.name
	{
	format!(
	"only one `#[{}]` attribute is allowed on any given function",
	path_str,
	)
	} else {
	format!(
	"`#[{}]` and `#[{}]` attributes cannot both be applied
	to the same function",
	path_str,
	pprust::path_to_string(&prev_item.path),
	)
	};

	self.handler
	.struct_span_err(attr.span, &msg)
	.span_label(prev_attr.span, "previous attribute here")
	.emit();

	return;
	}

	found_attr = Some(attr);
	}
	}

	let attr = match found_attr {
	None => {
	self.check_not_pub_in_root(&item.vis, self.source_map.guess_head_span(item.span));
	let prev_in_root = mem::replace(&mut self.in_root, false);
	visit::walk_item(self, item);
	self.in_root = prev_in_root;
	return;
	}
	Some(attr) => attr,
	};

	if !is_fn {
	let msg = format!(
	"the `#[{}]` attribute may only be used on bare functions",
	pprust::path_to_string(&attr.get_normal_item().path),
	);

	self.handler.span_err(attr.span, &msg);
	return;
	}

	if self.is_test_crate {
	return;
	}

	if !self.is_proc_macro_crate {
	let msg = format!(
	"the `#[{}]` attribute is only usable with crates of the `proc-macro` crate type",
	pprust::path_to_string(&attr.get_normal_item().path),
	);

	self.handler.span_err(attr.span, &msg);
	return;
	}

	if attr.check_name(sym::proc_macro_derive) {
	self.collect_custom_derive(item, attr);
	} else if attr.check_name(sym::proc_macro_attribute) {
	self.collect_attr_proc_macro(item);
	} else if attr.check_name(sym::proc_macro) {
	self.collect_bang_proc_macro(item);
	};

	let prev_in_root = mem::replace(&mut self.in_root, false);
	visit::walk_item(self, item);
	self.in_root = prev_in_root;
	}

	fn visit_mac(&mut self, mac: &'a ast::MacCall) {
	visit::walk_mac(self, mac)
	}
	}

	// Creates a new module which looks like:
	//
	// const _: () = {
	// extern crate proc_macro;
	//
	// use proc_macro::bridge::client::ProcMacro;
	//
	// #[rustc_proc_macro_decls]
	// #[allow(deprecated)]
	// static DECLS: &[ProcMacro] = &[
	// ProcMacro::custom_derive($name_trait1, &[], ::$name1);
	// ProcMacro::custom_derive($name_trait2, &["attribute_name"], ::$name2);
	// // ...
	// ];
	// }
	fn mk_decls(
	ast_krate: &mut ast::Crate,
	cx: &mut ExtCtxt<'_>,
	macros: &[ProcMacro],
	) -> P<ast::Item> {
	// We're the ones filling in this Vec,
	// so it should be empty to start with
	assert!(ast_krate.proc_macros.is_empty());

	let expn_id = cx.resolver.expansion_for_ast_pass(
	DUMMY_SP,
	AstPass::ProcMacroHarness,
	&[sym::rustc_attrs, sym::proc_macro_internals],
	None,
	);
	let span = DUMMY_SP.with_def_site_ctxt(expn_id);

	let proc_macro = Ident::new(sym::proc_macro, span);
	let krate = cx.item(span, proc_macro, Vec::new(), ast::ItemKind::ExternCrate(None));

	let bridge = cx.ident_of("bridge", span);
	let client = cx.ident_of("client", span);
	let proc_macro_ty = cx.ident_of("ProcMacro", span);
	let custom_derive = cx.ident_of("custom_derive", span);
	let attr = cx.ident_of("attr", span);
	let bang = cx.ident_of("bang", span);

	let krate_ref = RefCell::new(ast_krate);

	// We add NodeIds to 'krate.proc_macros' in the order
	// that we generate expressions. The position of each NodeId
	// in the 'proc_macros' Vec corresponds to its position
	// in the static array that will be generated
	let decls = {
	let local_path =
	\|sp: Span, name\| cx.expr_path(cx.path(sp.with_ctxt(span.ctxt()), vec![name]));
	let proc_macro_ty_method_path = \|method\| {
	cx.expr_path(cx.path(span, vec![proc_macro, bridge, client, proc_macro_ty, method]))
	};
	macros
	.iter()
	.map(\|m\| match m {
	ProcMacro::Derive(cd) => {
	krate_ref.borrow_mut().proc_macros.push(cd.id);
	cx.expr_call(
	span,
	proc_macro_ty_method_path(custom_derive),
	vec![
	cx.expr_str(cd.span, cd.trait_name),
	cx.expr_vec_slice(
	span,
	cd.attrs
	.iter()
	.map(\|&s\| cx.expr_str(cd.span, s))
	.collect::<Vec<_>>(),
	),
	local_path(cd.span, cd.function_name),
	],
	)
	}
	ProcMacro::Def(ca) => {
	krate_ref.borrow_mut().proc_macros.push(ca.id);
	let ident = match ca.def_type {
	ProcMacroDefType::Attr => attr,
	ProcMacroDefType::Bang => bang,
	};

	cx.expr_call(
	span,
	proc_macro_ty_method_path(ident),
	vec![
	cx.expr_str(ca.span, ca.function_name.name),
	local_path(ca.span, ca.function_name),
	],
	)
	}
	})
	.collect()
	};

	let decls_static = cx
	.item_static(
	span,
	cx.ident_of("_DECLS", span),
	cx.ty_rptr(
	span,
	cx.ty(
	span,
	ast::TyKind::Slice(
	cx.ty_path(cx.path(span, vec![proc_macro, bridge, client, proc_macro_ty])),
	),
	),
	None,
	ast::Mutability::Not,
	),
	ast::Mutability::Not,
	cx.expr_vec_slice(span, decls),
	)
	.map(\|mut i\| {
	let attr = cx.meta_word(span, sym::rustc_proc_macro_decls);
	i.attrs.push(cx.attribute(attr));

	let deprecated_attr = attr::mk_nested_word_item(Ident::new(sym::deprecated, span));
	let allow_deprecated_attr =
	attr::mk_list_item(Ident::new(sym::allow, span), vec![deprecated_attr]);
	i.attrs.push(cx.attribute(allow_deprecated_attr));

	i
	});

	let block = cx.expr_block(
	cx.block(span, vec![cx.stmt_item(span, krate), cx.stmt_item(span, decls_static)]),
	);

	let anon_constant = cx.item_const(
	span,
	Ident::new(kw::Underscore, span),
	cx.ty(span, ast::TyKind::Tup(Vec::new())),
	block,
	);

	// Integrate the new item into existing module structures.
	let items = AstFragment::Items(smallvec![anon_constant]);
	cx.monotonic_expander().fully_expand_fragment(items).make_items().pop().unwrap()
	}