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

 /// The expansion from a test function to the appropriate test struct for libtest
 /// Ideally, this code would be in libtest but for efficiency and error messages it lives here.
 use crate::util::check_builtin_macro_attribute;

 use rustc_ast::ast;
 use rustc_ast::attr;
 use rustc_ast_pretty::pprust;
 use rustc_expand::base::*;
 use rustc_span::source_map::respan;
 use rustc_span::symbol::{sym, Ident, Symbol};
 use rustc_span::Span;

 use std::iter;

 // #[test_case] is used by custom test authors to mark tests
 // When building for test, it needs to make the item public and gensym the name
 // Otherwise, we'll omit the item. This behavior means that any item annotated
 // with #[test_case] is never addressable.
 //
 // We mark item with an inert attribute "rustc_test_marker" which the test generation
 // logic will pick up on.
 pub fn expand_test_case(
     ecx: &mut ExtCtxt<'_>,
     attr_sp: Span,
     meta_item: &ast::MetaItem,
     anno_item: Annotatable,
 ) -> Vec<Annotatable> {
     check_builtin_macro_attribute(ecx, meta_item, sym::test_case);

     if !ecx.ecfg.should_test {
         return vec![];
     }

     let sp = ecx.with_def_site_ctxt(attr_sp);
     let mut item = anno_item.expect_item();
     item = item.map(|mut item| {
         item.vis = respan(item.vis.span, ast::VisibilityKind::Public);
         item.ident.span = item.ident.span.with_ctxt(sp.ctxt());
         item.attrs.push(ecx.attribute(ecx.meta_word(sp, sym::rustc_test_marker)));
         item
     });

     return vec![Annotatable::Item(item)];
 }

 pub fn expand_test(
     cx: &mut ExtCtxt<'_>,
     attr_sp: Span,
     meta_item: &ast::MetaItem,
     item: Annotatable,
 ) -> Vec<Annotatable> {
     check_builtin_macro_attribute(cx, meta_item, sym::test);
     expand_test_or_bench(cx, attr_sp, item, false)
 }

 pub fn expand_bench(
     cx: &mut ExtCtxt<'_>,
     attr_sp: Span,
     meta_item: &ast::MetaItem,
     item: Annotatable,
 ) -> Vec<Annotatable> {
     check_builtin_macro_attribute(cx, meta_item, sym::bench);
     expand_test_or_bench(cx, attr_sp, item, true)
 }

 pub fn expand_test_or_bench(
     cx: &mut ExtCtxt<'_>,
     attr_sp: Span,
     item: Annotatable,
     is_bench: bool,
 ) -> Vec<Annotatable> {
     // If we're not in test configuration, remove the annotated item
     if !cx.ecfg.should_test {
         return vec![];
     }

     let item = match item {
         Annotatable::Item(i) => i,
         other => {
             cx.struct_span_err(
                 other.span(),
                 "`#[test]` attribute is only allowed on non associated functions",
             )
             .emit();
             return vec![other];
         }
     };

     if let ast::ItemKind::MacCall(_) = item.kind {
         cx.parse_sess.span_diagnostic.span_warn(
             item.span,
             "`#[test]` attribute should not be used on macros. Use `#[cfg(test)]` instead.",
         );
         return vec![Annotatable::Item(item)];
     }

     // has_*_signature will report any errors in the type so compilation
     // will fail. We shouldn't try to expand in this case because the errors
     // would be spurious.
     if (!is_bench && !has_test_signature(cx, &item))
         || (is_bench && !has_bench_signature(cx, &item))
     {
         return vec![Annotatable::Item(item)];
     }

     let (sp, attr_sp) = (cx.with_def_site_ctxt(item.span), cx.with_def_site_ctxt(attr_sp));

     let test_id = Ident::new(sym::test, attr_sp);

     // creates test::$name
     let test_path = |name| cx.path(sp, vec![test_id, cx.ident_of(name, sp)]);

     // creates test::ShouldPanic::$name
     let should_panic_path =
         |name| cx.path(sp, vec![test_id, cx.ident_of("ShouldPanic", sp), cx.ident_of(name, sp)]);

     // creates test::TestType::$name
     let test_type_path =
         |name| cx.path(sp, vec![test_id, cx.ident_of("TestType", sp), cx.ident_of(name, sp)]);

     // creates $name: $expr
     let field = |name, expr| cx.field_imm(sp, cx.ident_of(name, sp), expr);

     let test_fn = if is_bench {
         // A simple ident for a lambda
         let b = cx.ident_of("b", attr_sp);

         cx.expr_call(
             sp,
             cx.expr_path(test_path("StaticBenchFn")),
             vec![
                 // |b| self::test::assert_test_result(
                 cx.lambda1(
                     sp,
                     cx.expr_call(
                         sp,
                         cx.expr_path(test_path("assert_test_result")),
                         vec![
                             // super::$test_fn(b)
                             cx.expr_call(
                                 sp,
                                 cx.expr_path(cx.path(sp, vec![item.ident])),
                                 vec![cx.expr_ident(sp, b)],
                             ),
                         ],
                     ),
                     b,
                 ), // )
             ],
         )
     } else {
         cx.expr_call(
             sp,
             cx.expr_path(test_path("StaticTestFn")),
             vec![
                 // || {
                 cx.lambda0(
                     sp,
                     // test::assert_test_result(
                     cx.expr_call(
                         sp,
                         cx.expr_path(test_path("assert_test_result")),
                         vec![
                             // $test_fn()
                             cx.expr_call(sp, cx.expr_path(cx.path(sp, vec![item.ident])), vec![]), // )
                         ],
                     ), // }
                 ), // )
             ],
         )
     };

     let mut test_const = cx.item(
         sp,
         Ident::new(item.ident.name, sp),
         vec![
             // #[cfg(test)]
             cx.attribute(attr::mk_list_item(
                 Ident::new(sym::cfg, attr_sp),
                 vec![attr::mk_nested_word_item(Ident::new(sym::test, attr_sp))],
             )),
             // #[rustc_test_marker]
             cx.attribute(cx.meta_word(attr_sp, sym::rustc_test_marker)),
         ],
         // const $ident: test::TestDescAndFn =
         ast::ItemKind::Const(
             ast::Defaultness::Final,
             cx.ty(sp, ast::TyKind::Path(None, test_path("TestDescAndFn"))),
             // test::TestDescAndFn {
             Some(
                 cx.expr_struct(
                     sp,
                     test_path("TestDescAndFn"),
                     vec![
                         // desc: test::TestDesc {
                         field(
                             "desc",
                             cx.expr_struct(
                                 sp,
                                 test_path("TestDesc"),
                                 vec![
                                     // name: "path::to::test"
                                     field(
                                         "name",
                                         cx.expr_call(
                                             sp,
                                             cx.expr_path(test_path("StaticTestName")),
                                             vec![cx.expr_str(
                                                 sp,
                                                 Symbol::intern(&item_path(
                                                     // skip the name of the root module
                                                     &cx.current_expansion.module.mod_path[1..],
                                                     &item.ident,
                                                 )),
                                             )],
                                         ),
                                     ),
                                     // ignore: true | false
                                     field("ignore", cx.expr_bool(sp, should_ignore(&item))),
                                     // allow_fail: true | false
                                     field("allow_fail", cx.expr_bool(sp, should_fail(&item))),
                                     // should_panic: ...
                                     field(
                                         "should_panic",
                                         match should_panic(cx, &item) {
                                             // test::ShouldPanic::No
                                             ShouldPanic::No => {
                                                 cx.expr_path(should_panic_path("No"))
                                             }
                                             // test::ShouldPanic::Yes
                                             ShouldPanic::Yes(None) => {
                                                 cx.expr_path(should_panic_path("Yes"))
                                             }
                                             // test::ShouldPanic::YesWithMessage("...")
                                             ShouldPanic::Yes(Some(sym)) => cx.expr_call(
                                                 sp,
                                                 cx.expr_path(should_panic_path("YesWithMessage")),
                                                 vec![cx.expr_str(sp, sym)],
                                             ),
                                         },
                                     ),
                                     // test_type: ...
                                     field(
                                         "test_type",
                                         match test_type(cx) {
                                             // test::TestType::UnitTest
                                             TestType::UnitTest => {
                                                 cx.expr_path(test_type_path("UnitTest"))
                                             }
                                             // test::TestType::IntegrationTest
                                             TestType::IntegrationTest => {
                                                 cx.expr_path(test_type_path("IntegrationTest"))
                                             }
                                             // test::TestPath::Unknown
                                             TestType::Unknown => {
                                                 cx.expr_path(test_type_path("Unknown"))
                                             }
                                         },
                                     ),
                                     // },
                                 ],
                             ),
                         ),
                         // testfn: test::StaticTestFn(...) | test::StaticBenchFn(...)
                         field("testfn", test_fn), // }
                     ],
                 ), // }
             ),
         ),
     );
     test_const = test_const.map(|mut tc| {
         tc.vis.node = ast::VisibilityKind::Public;
         tc
     });

     // extern crate test
     let test_extern = cx.item(sp, test_id, vec![], ast::ItemKind::ExternCrate(None));

     log::debug!("synthetic test item:\n{}\n", pprust::item_to_string(&test_const));

     vec![
         // Access to libtest under a hygienic name
         Annotatable::Item(test_extern),
         // The generated test case
         Annotatable::Item(test_const),
         // The original item
         Annotatable::Item(item),
     ]
 }

 fn item_path(mod_path: &[Ident], item_ident: &Ident) -> String {
     mod_path
         .iter()
         .chain(iter::once(item_ident))
         .map(|x| x.to_string())
         .collect::<Vec<String>>()
         .join("::")
 }

 enum ShouldPanic {
     No,
     Yes(Option<Symbol>),
 }

 fn should_ignore(i: &ast::Item) -> bool {
     attr::contains_name(&i.attrs, sym::ignore)
 }

 fn should_fail(i: &ast::Item) -> bool {
     attr::contains_name(&i.attrs, sym::allow_fail)
 }

 fn should_panic(cx: &ExtCtxt<'_>, i: &ast::Item) -> ShouldPanic {
     match attr::find_by_name(&i.attrs, sym::should_panic) {
         Some(attr) => {
             let sd = &cx.parse_sess.span_diagnostic;

             match attr.meta_item_list() {
                 // Handle #[should_panic(expected = "foo")]
                 Some(list) => {
                     let msg = list
                         .iter()
                         .find(|mi| mi.check_name(sym::expected))
                         .and_then(|mi| mi.meta_item())
                         .and_then(|mi| mi.value_str());
                     if list.len() != 1 || msg.is_none() {
                         sd.struct_span_warn(
                             attr.span,
                             "argument must be of the form: \
                              `expected = \"error message\"`",
                         )
                         .note(
                             "errors in this attribute were erroneously \
                                 allowed and will become a hard error in a \
                                 future release.",
                         )
                         .emit();
                         ShouldPanic::Yes(None)
                     } else {
                         ShouldPanic::Yes(msg)
                     }
                 }
                 // Handle #[should_panic] and #[should_panic = "expected"]
                 None => ShouldPanic::Yes(attr.value_str()),
             }
         }
         None => ShouldPanic::No,
     }
 }

 enum TestType {
     UnitTest,
     IntegrationTest,
     Unknown,
 }

 /// Attempts to determine the type of test.
 /// Since doctests are created without macro expanding, only possible variants here
 /// are `UnitTest`, `IntegrationTest` or `Unknown`.
 fn test_type(cx: &ExtCtxt<'_>) -> TestType {
     // Root path from context contains the topmost sources directory of the crate.
     // I.e., for `project` with sources in `src` and tests in `tests` folders
     // (no matter how many nested folders lie inside),
     // there will be two different root paths: `/project/src` and `/project/tests`.
     let crate_path = cx.root_path.as_path();

     if crate_path.ends_with("src") {
         // `/src` folder contains unit-tests.
         TestType::UnitTest
     } else if crate_path.ends_with("tests") {
         // `/tests` folder contains integration tests.
         TestType::IntegrationTest
     } else {
         // Crate layout doesn't match expected one, test type is unknown.
         TestType::Unknown
     }
 }

 fn has_test_signature(cx: &ExtCtxt<'_>, i: &ast::Item) -> bool {
     let has_should_panic_attr = attr::contains_name(&i.attrs, sym::should_panic);
     let sd = &cx.parse_sess.span_diagnostic;
     if let ast::ItemKind::Fn(_, ref sig, ref generics, _) = i.kind {
         if let ast::Unsafe::Yes(span) = sig.header.unsafety {
             sd.struct_span_err(i.span, "unsafe functions cannot be used for tests")
                 .span_label(span, "`unsafe` because of this")
                 .emit();
             return false;
         }
         if let ast::Async::Yes { span, .. } = sig.header.asyncness {
             sd.struct_span_err(i.span, "async functions cannot be used for tests")
                 .span_label(span, "`async` because of this")
                 .emit();
             return false;
         }

         // If the termination trait is active, the compiler will check that the output
         // type implements the `Termination` trait as `libtest` enforces that.
         let has_output = match sig.decl.output {
             ast::FnRetTy::Default(..) => false,
             ast::FnRetTy::Ty(ref t) if t.kind.is_unit() => false,
             _ => true,
         };

         if !sig.decl.inputs.is_empty() {
             sd.span_err(i.span, "functions used as tests can not have any arguments");
             return false;
         }

         match (has_output, has_should_panic_attr) {
             (true, true) => {
                 sd.span_err(i.span, "functions using `#[should_panic]` must return `()`");
                 false
             }
             (true, false) => {
                 if !generics.params.is_empty() {
                     sd.span_err(i.span, "functions used as tests must have signature fn() -> ()");
                     false
                 } else {
                     true
                 }
             }
             (false, _) => true,
         }
     } else {
         sd.span_err(i.span, "only functions may be used as tests");
         false
     }
 }

 fn has_bench_signature(cx: &ExtCtxt<'_>, i: &ast::Item) -> bool {
     let has_sig = if let ast::ItemKind::Fn(_, ref sig, _, _) = i.kind {
         // N.B., inadequate check, but we're running
         // well before resolve, can't get too deep.
         sig.decl.inputs.len() == 1
     } else {
         false
     };

     if !has_sig {
         cx.parse_sess.span_diagnostic.span_err(
             i.span,
             "functions used as benches must have \
             signature `fn(&mut Bencher) -> impl Termination`",
         );
     }

     has_sig
 }
	/// The expansion from a test function to the appropriate test struct for libtest
	/// Ideally, this code would be in libtest but for efficiency and error messages it lives here.
	use crate::util::check_builtin_macro_attribute;

	use rustc_ast::ast;
	use rustc_ast::attr;
	use rustc_ast_pretty::pprust;
	use rustc_expand::base::*;
	use rustc_span::source_map::respan;
	use rustc_span::symbol::{sym, Ident, Symbol};
	use rustc_span::Span;

	use std::iter;

	// #[test_case] is used by custom test authors to mark tests
	// When building for test, it needs to make the item public and gensym the name
	// Otherwise, we'll omit the item. This behavior means that any item annotated
	// with #[test_case] is never addressable.
	//
	// We mark item with an inert attribute "rustc_test_marker" which the test generation
	// logic will pick up on.
	pub fn expand_test_case(
	ecx: &mut ExtCtxt<'_>,
	attr_sp: Span,
	meta_item: &ast::MetaItem,
	anno_item: Annotatable,
	) -> Vec<Annotatable> {
	check_builtin_macro_attribute(ecx, meta_item, sym::test_case);

	if !ecx.ecfg.should_test {
	return vec![];
	}

	let sp = ecx.with_def_site_ctxt(attr_sp);
	let mut item = anno_item.expect_item();
	item = item.map(\|mut item\| {
	item.vis = respan(item.vis.span, ast::VisibilityKind::Public);
	item.ident.span = item.ident.span.with_ctxt(sp.ctxt());
	item.attrs.push(ecx.attribute(ecx.meta_word(sp, sym::rustc_test_marker)));
	item
	});

	return vec![Annotatable::Item(item)];
	}

	pub fn expand_test(
	cx: &mut ExtCtxt<'_>,
	attr_sp: Span,
	meta_item: &ast::MetaItem,
	item: Annotatable,
	) -> Vec<Annotatable> {
	check_builtin_macro_attribute(cx, meta_item, sym::test);
	expand_test_or_bench(cx, attr_sp, item, false)
	}

	pub fn expand_bench(
	cx: &mut ExtCtxt<'_>,
	attr_sp: Span,
	meta_item: &ast::MetaItem,
	item: Annotatable,
	) -> Vec<Annotatable> {
	check_builtin_macro_attribute(cx, meta_item, sym::bench);
	expand_test_or_bench(cx, attr_sp, item, true)
	}

	pub fn expand_test_or_bench(
	cx: &mut ExtCtxt<'_>,
	attr_sp: Span,
	item: Annotatable,
	is_bench: bool,
	) -> Vec<Annotatable> {
	// If we're not in test configuration, remove the annotated item
	if !cx.ecfg.should_test {
	return vec![];
	}

	let item = match item {
	Annotatable::Item(i) => i,
	other => {
	cx.struct_span_err(
	other.span(),
	"`#[test]` attribute is only allowed on non associated functions",
	)
	.emit();
	return vec![other];
	}
	};

	if let ast::ItemKind::MacCall(_) = item.kind {
	cx.parse_sess.span_diagnostic.span_warn(
	item.span,
	"`#[test]` attribute should not be used on macros. Use `#[cfg(test)]` instead.",
	);
	return vec![Annotatable::Item(item)];
	}

	// has_*_signature will report any errors in the type so compilation
	// will fail. We shouldn't try to expand in this case because the errors
	// would be spurious.
	if (!is_bench && !has_test_signature(cx, &item))
	\|\| (is_bench && !has_bench_signature(cx, &item))
	{
	return vec![Annotatable::Item(item)];
	}

	let (sp, attr_sp) = (cx.with_def_site_ctxt(item.span), cx.with_def_site_ctxt(attr_sp));

	let test_id = Ident::new(sym::test, attr_sp);

	// creates test::$name
	let test_path = \|name\| cx.path(sp, vec![test_id, cx.ident_of(name, sp)]);

	// creates test::ShouldPanic::$name
	let should_panic_path =
	\|name\| cx.path(sp, vec![test_id, cx.ident_of("ShouldPanic", sp), cx.ident_of(name, sp)]);

	// creates test::TestType::$name
	let test_type_path =
	\|name\| cx.path(sp, vec![test_id, cx.ident_of("TestType", sp), cx.ident_of(name, sp)]);

	// creates $name: $expr
	let field = \|name, expr\| cx.field_imm(sp, cx.ident_of(name, sp), expr);

	let test_fn = if is_bench {
	// A simple ident for a lambda
	let b = cx.ident_of("b", attr_sp);

	cx.expr_call(
	sp,
	cx.expr_path(test_path("StaticBenchFn")),
	vec![
	// \|b\| self::test::assert_test_result(
	cx.lambda1(
	sp,
	cx.expr_call(
	sp,
	cx.expr_path(test_path("assert_test_result")),
	vec![
	// super::$test_fn(b)
	cx.expr_call(
	sp,
	cx.expr_path(cx.path(sp, vec![item.ident])),
	vec![cx.expr_ident(sp, b)],
	),
	],
	),
	b,
	), // )
	],
	)
	} else {
	cx.expr_call(
	sp,
	cx.expr_path(test_path("StaticTestFn")),
	vec![
	// \|\| {
	cx.lambda0(
	sp,
	// test::assert_test_result(
	cx.expr_call(
	sp,
	cx.expr_path(test_path("assert_test_result")),
	vec![
	// $test_fn()
	cx.expr_call(sp, cx.expr_path(cx.path(sp, vec![item.ident])), vec![]), // )
	],
	), // }
	), // )
	],
	)
	};

	let mut test_const = cx.item(
	sp,
	Ident::new(item.ident.name, sp),
	vec![
	// #[cfg(test)]
	cx.attribute(attr::mk_list_item(
	Ident::new(sym::cfg, attr_sp),
	vec![attr::mk_nested_word_item(Ident::new(sym::test, attr_sp))],
	)),
	// #[rustc_test_marker]
	cx.attribute(cx.meta_word(attr_sp, sym::rustc_test_marker)),
	],
	// const $ident: test::TestDescAndFn =
	ast::ItemKind::Const(
	ast::Defaultness::Final,
	cx.ty(sp, ast::TyKind::Path(None, test_path("TestDescAndFn"))),
	// test::TestDescAndFn {
	Some(
	cx.expr_struct(
	sp,
	test_path("TestDescAndFn"),
	vec![
	// desc: test::TestDesc {
	field(
	"desc",
	cx.expr_struct(
	sp,
	test_path("TestDesc"),
	vec![
	// name: "path::to::test"
	field(
	"name",
	cx.expr_call(
	sp,
	cx.expr_path(test_path("StaticTestName")),
	vec![cx.expr_str(
	sp,
	Symbol::intern(&item_path(
	// skip the name of the root module
	&cx.current_expansion.module.mod_path[1..],
	&item.ident,
	)),
	)],
	),
	),
	// ignore: true \| false
	field("ignore", cx.expr_bool(sp, should_ignore(&item))),
	// allow_fail: true \| false
	field("allow_fail", cx.expr_bool(sp, should_fail(&item))),
	// should_panic: ...
	field(
	"should_panic",
	match should_panic(cx, &item) {
	// test::ShouldPanic::No
	ShouldPanic::No => {
	cx.expr_path(should_panic_path("No"))
	}
	// test::ShouldPanic::Yes
	ShouldPanic::Yes(None) => {
	cx.expr_path(should_panic_path("Yes"))
	}
	// test::ShouldPanic::YesWithMessage("...")
	ShouldPanic::Yes(Some(sym)) => cx.expr_call(
	sp,
	cx.expr_path(should_panic_path("YesWithMessage")),
	vec![cx.expr_str(sp, sym)],
	),
	},
	),
	// test_type: ...
	field(
	"test_type",
	match test_type(cx) {
	// test::TestType::UnitTest
	TestType::UnitTest => {
	cx.expr_path(test_type_path("UnitTest"))
	}
	// test::TestType::IntegrationTest
	TestType::IntegrationTest => {
	cx.expr_path(test_type_path("IntegrationTest"))
	}
	// test::TestPath::Unknown
	TestType::Unknown => {
	cx.expr_path(test_type_path("Unknown"))
	}
	},
	),
	// },
	],
	),
	),
	// testfn: test::StaticTestFn(...) \| test::StaticBenchFn(...)
	field("testfn", test_fn), // }
	],
	), // }
	),
	),
	);
	test_const = test_const.map(\|mut tc\| {
	tc.vis.node = ast::VisibilityKind::Public;
	tc
	});

	// extern crate test
	let test_extern = cx.item(sp, test_id, vec![], ast::ItemKind::ExternCrate(None));

	log::debug!("synthetic test item:\n{}\n", pprust::item_to_string(&test_const));

	vec![
	// Access to libtest under a hygienic name
	Annotatable::Item(test_extern),
	// The generated test case
	Annotatable::Item(test_const),
	// The original item
	Annotatable::Item(item),
	]
	}

	fn item_path(mod_path: &[Ident], item_ident: &Ident) -> String {
	mod_path
	.iter()
	.chain(iter::once(item_ident))
	.map(\|x\| x.to_string())
	.collect::<Vec<String>>()
	.join("::")
	}

	enum ShouldPanic {
	No,
	Yes(Option<Symbol>),
	}

	fn should_ignore(i: &ast::Item) -> bool {
	attr::contains_name(&i.attrs, sym::ignore)
	}

	fn should_fail(i: &ast::Item) -> bool {
	attr::contains_name(&i.attrs, sym::allow_fail)
	}

	fn should_panic(cx: &ExtCtxt<'_>, i: &ast::Item) -> ShouldPanic {
	match attr::find_by_name(&i.attrs, sym::should_panic) {
	Some(attr) => {
	let sd = &cx.parse_sess.span_diagnostic;

	match attr.meta_item_list() {
	// Handle #[should_panic(expected = "foo")]
	Some(list) => {
	let msg = list
	.iter()
	.find(\|mi\| mi.check_name(sym::expected))
	.and_then(\|mi\| mi.meta_item())
	.and_then(\|mi\| mi.value_str());
	if list.len() != 1 \|\| msg.is_none() {
	sd.struct_span_warn(
	attr.span,
	"argument must be of the form: \
	`expected = \"error message\"`",
	)
	.note(
	"errors in this attribute were erroneously \
	allowed and will become a hard error in a \
	future release.",
	)
	.emit();
	ShouldPanic::Yes(None)
	} else {
	ShouldPanic::Yes(msg)
	}
	}
	// Handle #[should_panic] and #[should_panic = "expected"]
	None => ShouldPanic::Yes(attr.value_str()),
	}
	}
	None => ShouldPanic::No,
	}
	}

	enum TestType {
	UnitTest,
	IntegrationTest,
	Unknown,
	}

	/// Attempts to determine the type of test.
	/// Since doctests are created without macro expanding, only possible variants here
	/// are `UnitTest`, `IntegrationTest` or `Unknown`.
	fn test_type(cx: &ExtCtxt<'_>) -> TestType {
	// Root path from context contains the topmost sources directory of the crate.
	// I.e., for `project` with sources in `src` and tests in `tests` folders
	// (no matter how many nested folders lie inside),
	// there will be two different root paths: `/project/src` and `/project/tests`.
	let crate_path = cx.root_path.as_path();

	if crate_path.ends_with("src") {
	// `/src` folder contains unit-tests.
	TestType::UnitTest
	} else if crate_path.ends_with("tests") {
	// `/tests` folder contains integration tests.
	TestType::IntegrationTest
	} else {
	// Crate layout doesn't match expected one, test type is unknown.
	TestType::Unknown
	}
	}

	fn has_test_signature(cx: &ExtCtxt<'_>, i: &ast::Item) -> bool {
	let has_should_panic_attr = attr::contains_name(&i.attrs, sym::should_panic);
	let sd = &cx.parse_sess.span_diagnostic;
	if let ast::ItemKind::Fn(_, ref sig, ref generics, _) = i.kind {
	if let ast::Unsafe::Yes(span) = sig.header.unsafety {
	sd.struct_span_err(i.span, "unsafe functions cannot be used for tests")
	.span_label(span, "`unsafe` because of this")
	.emit();
	return false;
	}
	if let ast::Async::Yes { span, .. } = sig.header.asyncness {
	sd.struct_span_err(i.span, "async functions cannot be used for tests")
	.span_label(span, "`async` because of this")
	.emit();
	return false;
	}

	// If the termination trait is active, the compiler will check that the output
	// type implements the `Termination` trait as `libtest` enforces that.
	let has_output = match sig.decl.output {
	ast::FnRetTy::Default(..) => false,
	ast::FnRetTy::Ty(ref t) if t.kind.is_unit() => false,
	_ => true,
	};

	if !sig.decl.inputs.is_empty() {
	sd.span_err(i.span, "functions used as tests can not have any arguments");
	return false;
	}

	match (has_output, has_should_panic_attr) {
	(true, true) => {
	sd.span_err(i.span, "functions using `#[should_panic]` must return `()`");
	false
	}
	(true, false) => {
	if !generics.params.is_empty() {
	sd.span_err(i.span, "functions used as tests must have signature fn() -> ()");
	false
	} else {
	true
	}
	}
	(false, _) => true,
	}
	} else {
	sd.span_err(i.span, "only functions may be used as tests");
	false
	}
	}

	fn has_bench_signature(cx: &ExtCtxt<'_>, i: &ast::Item) -> bool {
	let has_sig = if let ast::ItemKind::Fn(_, ref sig, _, _) = i.kind {
	// N.B., inadequate check, but we're running
	// well before resolve, can't get too deep.
	sig.decl.inputs.len() == 1
	} else {
	false
	};

	if !has_sig {
	cx.parse_sess.span_diagnostic.span_err(
	i.span,
	"functions used as benches must have \
	signature `fn(&mut Bencher) -> impl Termination`",
	);
	}

	has_sig
	}