tests/ui-fulldeps/rustc_public/check_attribute.rs - rust-lang/rust - Git at Google

 //@ run-pass
 //! Test information regarding type layout.

 //@ ignore-stage1
 //@ ignore-cross-compile
 //@ ignore-remote

 #![feature(rustc_private)]

 extern crate rustc_hir;
 extern crate rustc_middle;

 extern crate rustc_driver;
 extern crate rustc_interface;
 #[macro_use]
 extern crate rustc_public;

 use rustc_public::{CrateDef, CrateItems};
 use std::io::Write;
 use std::ops::ControlFlow;

 const CRATE_NAME: &str = "input";

 /// This function uses the Stable MIR APIs to get information about the test crate.
 fn test_stable_mir() -> ControlFlow<()> {
     // Find items in the local crate.
     let items = rustc_public::all_local_items();

     test_tool(&items);

     ControlFlow::Continue(())
 }

 // Test tool attributes.
 fn test_tool(items: &CrateItems) {
     let rustfmt_fn = *get_item(&items, "do_not_format").unwrap();
     let rustfmt_attrs = rustfmt_fn.tool_attrs(&["rustfmt".to_string(), "skip".to_string()]);
     assert_eq!(rustfmt_attrs[0].as_str(), "#[rustfmt::skip]\n");

     let clippy_fn = *get_item(&items, "complex_fn").unwrap();
     let clippy_attrs = clippy_fn.tool_attrs(&["clippy".to_string(),
                                                "cyclomatic_complexity".to_string()]);
     assert_eq!(clippy_attrs[0].as_str(), "#[clippy::cyclomatic_complexity = \"100\"]\n");
 }

 fn get_item<'a>(
     items: &'a CrateItems,
     name: &str,
 ) -> Option<&'a rustc_public::CrateItem> {
     items.iter().find(|crate_item| crate_item.name() == name)
 }

 /// This test will generate and analyze a dummy crate using the stable mir.
 /// For that, it will first write the dummy crate into a file.
 /// Then it will create a `RustcPublic` using custom arguments and then
 /// it will run the compiler.
 fn main() {
     let path = "attribute_input.rs";
     generate_input(&path).unwrap();
     let args = &[
         "rustc".to_string(),
         "--crate-type=lib".to_string(),
         "--crate-name".to_string(),
         CRATE_NAME.to_string(),
         path.to_string(),
     ];
     run!(args, test_stable_mir).unwrap();
 }

 fn generate_input(path: &str) -> std::io::Result<()> {
     let mut file = std::fs::File::create(path)?;
     write!(
         file,
         r#"
         // General metadata applied to the enclosing module or crate.
         #![crate_type = "lib"]

         // Mixed inner and outer attributes.
         #[inline]
         #[deprecated(since = "5.2.0")]
         fn builtins_fn() {{
             #![allow(unused_variables)]

             let x = ();
             let y = ();
             let z = ();
         }}

         // A derive attribute to automatically implement a trait.
         #[derive(Debug, Clone, Copy)]
         struct Foo(u32);

         // A rustfmt tool attribute.
         #[rustfmt::skip]
         fn do_not_format() {{}}

         // A clippy tool attribute.
         #[clippy::cyclomatic_complexity = "100"]
         pub fn complex_fn() {{}}

         // A function with many attributes.
         #[inline]
         #[allow(unused_variables)]
         #[allow(dead_code)]
         #[allow(unused_imports)]
         fn many_attrs() {{
             #![allow(clippy::filter_map)]
             todo!()
         }}
         "#
     )?;
     Ok(())
 }
	//@ run-pass
	//! Test information regarding type layout.

	//@ ignore-stage1
	//@ ignore-cross-compile
	//@ ignore-remote

	#![feature(rustc_private)]

	extern crate rustc_hir;
	extern crate rustc_middle;

	extern crate rustc_driver;
	extern crate rustc_interface;
	#[macro_use]
	extern crate rustc_public;

	use rustc_public::{CrateDef, CrateItems};
	use std::io::Write;
	use std::ops::ControlFlow;

	const CRATE_NAME: &str = "input";

	/// This function uses the Stable MIR APIs to get information about the test crate.
	fn test_stable_mir() -> ControlFlow<()> {
	// Find items in the local crate.
	let items = rustc_public::all_local_items();

	test_tool(&items);

	ControlFlow::Continue(())
	}

	// Test tool attributes.
	fn test_tool(items: &CrateItems) {
	let rustfmt_fn = *get_item(&items, "do_not_format").unwrap();
	let rustfmt_attrs = rustfmt_fn.tool_attrs(&["rustfmt".to_string(), "skip".to_string()]);
	assert_eq!(rustfmt_attrs[0].as_str(), "#[rustfmt::skip]\n");

	let clippy_fn = *get_item(&items, "complex_fn").unwrap();
	let clippy_attrs = clippy_fn.tool_attrs(&["clippy".to_string(),
	"cyclomatic_complexity".to_string()]);
	assert_eq!(clippy_attrs[0].as_str(), "#[clippy::cyclomatic_complexity = \"100\"]\n");
	}

	fn get_item<'a>(
	items: &'a CrateItems,
	name: &str,
	) -> Option<&'a rustc_public::CrateItem> {
	items.iter().find(\|crate_item\| crate_item.name() == name)
	}

	/// This test will generate and analyze a dummy crate using the stable mir.
	/// For that, it will first write the dummy crate into a file.
	/// Then it will create a `RustcPublic` using custom arguments and then
	/// it will run the compiler.
	fn main() {
	let path = "attribute_input.rs";
	generate_input(&path).unwrap();
	let args = &[
	"rustc".to_string(),
	"--crate-type=lib".to_string(),
	"--crate-name".to_string(),
	CRATE_NAME.to_string(),
	path.to_string(),
	];
	run!(args, test_stable_mir).unwrap();
	}

	fn generate_input(path: &str) -> std::io::Result<()> {
	let mut file = std::fs::File::create(path)?;
	write!(
	file,
	r#"
	// General metadata applied to the enclosing module or crate.
	#![crate_type = "lib"]

	// Mixed inner and outer attributes.
	#[inline]
	#[deprecated(since = "5.2.0")]
	fn builtins_fn() {{
	#![allow(unused_variables)]

	let x = ();
	let y = ();
	let z = ();
	}}

	// A derive attribute to automatically implement a trait.
	#[derive(Debug, Clone, Copy)]
	struct Foo(u32);

	// A rustfmt tool attribute.
	#[rustfmt::skip]
	fn do_not_format() {{}}

	// A clippy tool attribute.
	#[clippy::cyclomatic_complexity = "100"]
	pub fn complex_fn() {{}}

	// A function with many attributes.
	#[inline]
	#[allow(unused_variables)]
	#[allow(dead_code)]
	#[allow(unused_imports)]
	fn many_attrs() {{
	#![allow(clippy::filter_map)]
	todo!()
	}}
	"#
	)?;
	Ok(())
	}