src/test/run-make-fulldeps/reproducible-build/reproducible-build.rs - third_party/rust - Git at Google

 // This test case makes sure that two identical invocations of the compiler
 // (i.e., same code base, same compile-flags, same compiler-versions, etc.)
 // produce the same output. In the past, symbol names of monomorphized functions
 // were not deterministic (which we want to avoid).
 //
 // The test tries to exercise as many different paths into symbol name
 // generation as possible:
 //
 // - regular functions
 // - generic functions
 // - methods
 // - statics
 // - closures
 // - enum variant constructors
 // - tuple struct constructors
 // - drop glue
 // - FnOnce adapters
 // - Trait object shims
 // - Fn Pointer shims

 #![allow(dead_code, warnings)]

 extern crate reproducible_build_aux;

 static STATIC: i32 = 1234;

 pub struct Struct<T1, T2> {
     x: T1,
     y: T2,
 }

 fn regular_fn(_: i32) {}

 fn generic_fn<T1, T2>() {}

 impl<T1, T2> Drop for Struct<T1, T2> {
     fn drop(&mut self) {}
 }

 pub enum Enum {
     Variant1,
     Variant2(u32),
     Variant3 { x: u32 }
 }

 struct TupleStruct(i8, i16, i32, i64);

 impl TupleStruct {
     pub fn bar(&self) {}
 }

 trait Trait<T1, T2> {
     fn foo(&self);
 }

 impl Trait<i32, u64> for u64 {
     fn foo(&self) {}
 }

 impl reproducible_build_aux::Trait<char, String> for TupleStruct {
     fn foo(&self) {}
 }

 fn main() {
     regular_fn(STATIC);
     generic_fn::<u32, char>();
     generic_fn::<char, Struct<u32, u64>>();
     generic_fn::<Struct<u64, u32>, reproducible_build_aux::Struct<u32, u64>>();

     let dropped = Struct {
         x: "",
         y: 'a',
     };

     let _ = Enum::Variant1;
     let _ = Enum::Variant2(0);
     let _ = Enum::Variant3 { x: 0 };
     let _ = TupleStruct(1, 2, 3, 4);

     let closure  = |x| {
         x + 1i32
     };

     fn inner<F: Fn(i32) -> i32>(f: F) -> i32 {
         f(STATIC)
     }

     println!("{}", inner(closure));

     let object_shim: &Trait<i32, u64> = &0u64;
     object_shim.foo();

     fn with_fn_once_adapter<F: FnOnce(i32)>(f: F) {
         f(0);
     }

     with_fn_once_adapter(|_:i32| { });

     reproducible_build_aux::regular_fn(STATIC);
     reproducible_build_aux::generic_fn::<u32, char>();
     reproducible_build_aux::generic_fn::<char, Struct<u32, u64>>();
     reproducible_build_aux::generic_fn::<Struct<u64, u32>,
                                          reproducible_build_aux::Struct<u32, u64>>();

     let _ = reproducible_build_aux::Enum::Variant1;
     let _ = reproducible_build_aux::Enum::Variant2(0);
     let _ = reproducible_build_aux::Enum::Variant3 { x: 0 };
     let _ = reproducible_build_aux::TupleStruct(1, 2, 3, 4);

     let object_shim: &reproducible_build_aux::Trait<char, String> = &TupleStruct(0, 1, 2, 3);
     object_shim.foo();

     let pointer_shim: &Fn(i32) = &regular_fn;

     TupleStruct(1, 2, 3, 4).bar();
 }
	// This test case makes sure that two identical invocations of the compiler
	// (i.e., same code base, same compile-flags, same compiler-versions, etc.)
	// produce the same output. In the past, symbol names of monomorphized functions
	// were not deterministic (which we want to avoid).
	//
	// The test tries to exercise as many different paths into symbol name
	// generation as possible:
	//
	// - regular functions
	// - generic functions
	// - methods
	// - statics
	// - closures
	// - enum variant constructors
	// - tuple struct constructors
	// - drop glue
	// - FnOnce adapters
	// - Trait object shims
	// - Fn Pointer shims

	#![allow(dead_code, warnings)]

	extern crate reproducible_build_aux;

	static STATIC: i32 = 1234;

	pub struct Struct<T1, T2> {
	x: T1,
	y: T2,
	}

	fn regular_fn(_: i32) {}

	fn generic_fn<T1, T2>() {}

	impl<T1, T2> Drop for Struct<T1, T2> {
	fn drop(&mut self) {}
	}

	pub enum Enum {
	Variant1,
	Variant2(u32),
	Variant3 { x: u32 }
	}

	struct TupleStruct(i8, i16, i32, i64);

	impl TupleStruct {
	pub fn bar(&self) {}
	}

	trait Trait<T1, T2> {
	fn foo(&self);
	}

	impl Trait<i32, u64> for u64 {
	fn foo(&self) {}
	}

	impl reproducible_build_aux::Trait<char, String> for TupleStruct {
	fn foo(&self) {}
	}

	fn main() {
	regular_fn(STATIC);
	generic_fn::<u32, char>();
	generic_fn::<char, Struct<u32, u64>>();
	generic_fn::<Struct<u64, u32>, reproducible_build_aux::Struct<u32, u64>>();

	let dropped = Struct {
	x: "",
	y: 'a',
	};

	let _ = Enum::Variant1;
	let _ = Enum::Variant2(0);
	let _ = Enum::Variant3 { x: 0 };
	let _ = TupleStruct(1, 2, 3, 4);

	let closure = \|x\| {
	x + 1i32
	};

	fn inner<F: Fn(i32) -> i32>(f: F) -> i32 {
	f(STATIC)
	}

	println!("{}", inner(closure));

	let object_shim: &Trait<i32, u64> = &0u64;
	object_shim.foo();

	fn with_fn_once_adapter<F: FnOnce(i32)>(f: F) {
	f(0);
	}

	with_fn_once_adapter(\|_:i32\| { });

	reproducible_build_aux::regular_fn(STATIC);
	reproducible_build_aux::generic_fn::<u32, char>();
	reproducible_build_aux::generic_fn::<char, Struct<u32, u64>>();
	reproducible_build_aux::generic_fn::<Struct<u64, u32>,
	reproducible_build_aux::Struct<u32, u64>>();

	let _ = reproducible_build_aux::Enum::Variant1;
	let _ = reproducible_build_aux::Enum::Variant2(0);
	let _ = reproducible_build_aux::Enum::Variant3 { x: 0 };
	let _ = reproducible_build_aux::TupleStruct(1, 2, 3, 4);

	let object_shim: &reproducible_build_aux::Trait<char, String> = &TupleStruct(0, 1, 2, 3);
	object_shim.foo();

	let pointer_shim: &Fn(i32) = &regular_fn;

	TupleStruct(1, 2, 3, 4).bar();
	}