src/test/codegen/repr-transparent.rs - third_party/rust - Git at Google

 // compile-flags: -C no-prepopulate-passes

 #![crate_type="lib"]
 #![feature(repr_simd, transparent_enums, transparent_unions)]

 use std::marker::PhantomData;

 #[derive(Copy, Clone)]
 pub struct Zst1;
 #[derive(Copy, Clone)]
 pub struct Zst2(());

 #[derive(Copy, Clone)]
 #[repr(transparent)]
 pub struct F32(f32);

 // CHECK: define float @test_F32(float %_1)
 #[no_mangle]
 pub extern fn test_F32(_: F32) -> F32 { loop {} }

 #[repr(transparent)]
 pub struct Ptr(*mut u8);

 // CHECK: define i8* @test_Ptr(i8* %_1)
 #[no_mangle]
 pub extern fn test_Ptr(_: Ptr) -> Ptr { loop {} }

 #[repr(transparent)]
 pub struct WithZst(u64, Zst1);

 // CHECK: define i64 @test_WithZst(i64 %_1)
 #[no_mangle]
 pub extern fn test_WithZst(_: WithZst) -> WithZst { loop {} }

 #[repr(transparent)]
 pub struct WithZeroSizedArray(*const f32, [i8; 0]);

 // Apparently we use i32* when newtype-unwrapping f32 pointers. Whatever.
 // CHECK: define i32* @test_WithZeroSizedArray(i32* %_1)
 #[no_mangle]
 pub extern fn test_WithZeroSizedArray(_: WithZeroSizedArray) -> WithZeroSizedArray { loop {} }

 #[repr(transparent)]
 pub struct Generic<T>(T);

 // CHECK: define double @test_Generic(double %_1)
 #[no_mangle]
 pub extern fn test_Generic(_: Generic<f64>) -> Generic<f64> { loop {} }

 #[repr(transparent)]
 pub struct GenericPlusZst<T>(T, Zst2);

 #[repr(u8)]
 pub enum Bool { True, False, FileNotFound }

 // CHECK: define{{( zeroext)?}} i8 @test_Gpz(i8{{( zeroext)?}} %_1)
 #[no_mangle]
 pub extern fn test_Gpz(_: GenericPlusZst<Bool>) -> GenericPlusZst<Bool> { loop {} }

 #[repr(transparent)]
 pub struct LifetimePhantom<'a, T: 'a>(*const T, PhantomData<&'a T>);

 // CHECK: define i16* @test_LifetimePhantom(i16* %_1)
 #[no_mangle]
 pub extern fn test_LifetimePhantom(_: LifetimePhantom<i16>) -> LifetimePhantom<i16> { loop {} }

 // This works despite current alignment resrictions because PhantomData is always align(1)
 #[repr(transparent)]
 pub struct UnitPhantom<T, U> { val: T, unit: PhantomData<U> }

 pub struct Px;

 // CHECK: define float @test_UnitPhantom(float %_1)
 #[no_mangle]
 pub extern fn test_UnitPhantom(_: UnitPhantom<f32, Px>) -> UnitPhantom<f32, Px> { loop {} }

 #[repr(transparent)]
 pub struct TwoZsts(Zst1, i8, Zst2);

 // CHECK: define{{( signext)?}} i8 @test_TwoZsts(i8{{( signext)?}} %_1)
 #[no_mangle]
 pub extern fn test_TwoZsts(_: TwoZsts) -> TwoZsts { loop {} }

 #[repr(transparent)]
 pub struct Nested1(Zst2, Generic<f64>);

 // CHECK: define double @test_Nested1(double %_1)
 #[no_mangle]
 pub extern fn test_Nested1(_: Nested1) -> Nested1 { loop {} }

 #[repr(transparent)]
 pub struct Nested2(Nested1, Zst1);

 // CHECK: define double @test_Nested2(double %_1)
 #[no_mangle]
 pub extern fn test_Nested2(_: Nested2) -> Nested2 { loop {} }

 #[repr(simd)]
 struct f32x4(f32, f32, f32, f32);

 #[repr(transparent)]
 pub struct Vector(f32x4);

 // CHECK: define <4 x float> @test_Vector(<4 x float> %_1)
 #[no_mangle]
 pub extern fn test_Vector(_: Vector) -> Vector { loop {} }

 trait Mirror { type It: ?Sized; }
 impl<T: ?Sized> Mirror for T { type It = Self; }

 #[repr(transparent)]
 pub struct StructWithProjection(<f32 as Mirror>::It);

 // CHECK: define float @test_Projection(float %_1)
 #[no_mangle]
 pub extern fn test_Projection(_: StructWithProjection) -> StructWithProjection { loop {} }

 #[repr(transparent)]
 pub enum EnumF32 {
     Variant(F32)
 }

 // CHECK: define float @test_EnumF32(float %_1)
 #[no_mangle]
 pub extern fn test_EnumF32(_: EnumF32) -> EnumF32 { loop {} }

 #[repr(transparent)]
 pub enum EnumF32WithZsts {
     Variant(Zst1, F32, Zst2)
 }

 // CHECK: define float @test_EnumF32WithZsts(float %_1)
 #[no_mangle]
 pub extern fn test_EnumF32WithZsts(_: EnumF32WithZsts) -> EnumF32WithZsts { loop {} }

 #[repr(transparent)]
 pub union UnionF32 {
     field: F32,
 }

 // CHECK: define float @test_UnionF32(float %_1)
 #[no_mangle]
 pub extern fn test_UnionF32(_: UnionF32) -> UnionF32 { loop {} }

 #[repr(transparent)]
 pub union UnionF32WithZsts {
     zst1: Zst1,
     field: F32,
     zst2: Zst2,
 }

 // CHECK: define float @test_UnionF32WithZsts(float %_1)
 #[no_mangle]
 pub extern fn test_UnionF32WithZsts(_: UnionF32WithZsts) -> UnionF32WithZsts { loop {} }


 // All that remains to be tested are aggregates. They are tested in separate files called repr-
 // transparent-*.rs  with `only-*` or `ignore-*` directives, because the expected LLVM IR
 // function signatures vary so much that it's not reasonably possible to cover all of them with a
 // single CHECK line.
 //
 // You may be wondering why we don't just compare the return types and argument types for equality
 // with FileCheck regex captures. Well, rustc doesn't perform newtype unwrapping on newtypes
 // containing aggregates. This is OK on all ABIs we support, but because LLVM has not gotten rid of
 // pointee types yet, the IR function signature will be syntactically different (%Foo* vs
 // %FooWrapper*).
	// compile-flags: -C no-prepopulate-passes

	#![crate_type="lib"]
	#![feature(repr_simd, transparent_enums, transparent_unions)]

	use std::marker::PhantomData;

	#[derive(Copy, Clone)]
	pub struct Zst1;
	#[derive(Copy, Clone)]
	pub struct Zst2(());

	#[derive(Copy, Clone)]
	#[repr(transparent)]
	pub struct F32(f32);

	// CHECK: define float @test_F32(float %_1)
	#[no_mangle]
	pub extern fn test_F32(_: F32) -> F32 { loop {} }

	#[repr(transparent)]
	pub struct Ptr(*mut u8);

	// CHECK: define i8* @test_Ptr(i8* %_1)
	#[no_mangle]
	pub extern fn test_Ptr(_: Ptr) -> Ptr { loop {} }

	#[repr(transparent)]
	pub struct WithZst(u64, Zst1);

	// CHECK: define i64 @test_WithZst(i64 %_1)
	#[no_mangle]
	pub extern fn test_WithZst(_: WithZst) -> WithZst { loop {} }

	#[repr(transparent)]
	pub struct WithZeroSizedArray(*const f32, [i8; 0]);

	// Apparently we use i32* when newtype-unwrapping f32 pointers. Whatever.
	// CHECK: define i32* @test_WithZeroSizedArray(i32* %_1)
	#[no_mangle]
	pub extern fn test_WithZeroSizedArray(_: WithZeroSizedArray) -> WithZeroSizedArray { loop {} }

	#[repr(transparent)]
	pub struct Generic<T>(T);

	// CHECK: define double @test_Generic(double %_1)
	#[no_mangle]
	pub extern fn test_Generic(_: Generic<f64>) -> Generic<f64> { loop {} }

	#[repr(transparent)]
	pub struct GenericPlusZst<T>(T, Zst2);

	#[repr(u8)]
	pub enum Bool { True, False, FileNotFound }

	// CHECK: define{{( zeroext)?}} i8 @test_Gpz(i8{{( zeroext)?}} %_1)
	#[no_mangle]
	pub extern fn test_Gpz(_: GenericPlusZst<Bool>) -> GenericPlusZst<Bool> { loop {} }

	#[repr(transparent)]
	pub struct LifetimePhantom<'a, T: 'a>(*const T, PhantomData<&'a T>);

	// CHECK: define i16* @test_LifetimePhantom(i16* %_1)
	#[no_mangle]
	pub extern fn test_LifetimePhantom(_: LifetimePhantom<i16>) -> LifetimePhantom<i16> { loop {} }

	// This works despite current alignment resrictions because PhantomData is always align(1)
	#[repr(transparent)]
	pub struct UnitPhantom<T, U> { val: T, unit: PhantomData<U> }

	pub struct Px;

	// CHECK: define float @test_UnitPhantom(float %_1)
	#[no_mangle]
	pub extern fn test_UnitPhantom(_: UnitPhantom<f32, Px>) -> UnitPhantom<f32, Px> { loop {} }

	#[repr(transparent)]
	pub struct TwoZsts(Zst1, i8, Zst2);

	// CHECK: define{{( signext)?}} i8 @test_TwoZsts(i8{{( signext)?}} %_1)
	#[no_mangle]
	pub extern fn test_TwoZsts(_: TwoZsts) -> TwoZsts { loop {} }

	#[repr(transparent)]
	pub struct Nested1(Zst2, Generic<f64>);

	// CHECK: define double @test_Nested1(double %_1)
	#[no_mangle]
	pub extern fn test_Nested1(_: Nested1) -> Nested1 { loop {} }

	#[repr(transparent)]
	pub struct Nested2(Nested1, Zst1);

	// CHECK: define double @test_Nested2(double %_1)
	#[no_mangle]
	pub extern fn test_Nested2(_: Nested2) -> Nested2 { loop {} }

	#[repr(simd)]
	struct f32x4(f32, f32, f32, f32);

	#[repr(transparent)]
	pub struct Vector(f32x4);

	// CHECK: define <4 x float> @test_Vector(<4 x float> %_1)
	#[no_mangle]
	pub extern fn test_Vector(_: Vector) -> Vector { loop {} }

	trait Mirror { type It: ?Sized; }
	impl<T: ?Sized> Mirror for T { type It = Self; }

	#[repr(transparent)]
	pub struct StructWithProjection(<f32 as Mirror>::It);

	// CHECK: define float @test_Projection(float %_1)
	#[no_mangle]
	pub extern fn test_Projection(_: StructWithProjection) -> StructWithProjection { loop {} }

	#[repr(transparent)]
	pub enum EnumF32 {
	Variant(F32)
	}

	// CHECK: define float @test_EnumF32(float %_1)
	#[no_mangle]
	pub extern fn test_EnumF32(_: EnumF32) -> EnumF32 { loop {} }

	#[repr(transparent)]
	pub enum EnumF32WithZsts {
	Variant(Zst1, F32, Zst2)
	}

	// CHECK: define float @test_EnumF32WithZsts(float %_1)
	#[no_mangle]
	pub extern fn test_EnumF32WithZsts(_: EnumF32WithZsts) -> EnumF32WithZsts { loop {} }

	#[repr(transparent)]
	pub union UnionF32 {
	field: F32,
	}

	// CHECK: define float @test_UnionF32(float %_1)
	#[no_mangle]
	pub extern fn test_UnionF32(_: UnionF32) -> UnionF32 { loop {} }

	#[repr(transparent)]
	pub union UnionF32WithZsts {
	zst1: Zst1,
	field: F32,
	zst2: Zst2,
	}

	// CHECK: define float @test_UnionF32WithZsts(float %_1)
	#[no_mangle]
	pub extern fn test_UnionF32WithZsts(_: UnionF32WithZsts) -> UnionF32WithZsts { loop {} }


	// All that remains to be tested are aggregates. They are tested in separate files called repr-
	// transparent-.rs with `only-` or `ignore-*` directives, because the expected LLVM IR
	// function signatures vary so much that it's not reasonably possible to cover all of them with a
	// single CHECK line.
	//
	// You may be wondering why we don't just compare the return types and argument types for equality
	// with FileCheck regex captures. Well, rustc doesn't perform newtype unwrapping on newtypes
	// containing aggregates. This is OK on all ABIs we support, but because LLVM has not gotten rid of
	// pointee types yet, the IR function signature will be syntactically different (%Foo* vs
	// %FooWrapper*).