//@ only-x86_64 //@ compile-flags: -O -C no-prepopulate-passes --crate-type=lib // On LLVM 17 and earlier LLVM's own data layout specifies that i128 has 8 byte alignment, // while rustc wants it to have 16 byte alignment. This test checks that we handle this // correctly. // CHECK: %ScalarPair = type { i32, [3 x i32], i128 } #![feature(core_intrinsics)] #[repr(C)] #[derive(Clone, Copy)] pub struct ScalarPair { a: i32, b: i128, } #[no_mangle] pub fn load(x: &ScalarPair) -> ScalarPair { // CHECK-LABEL: @load( // CHECK-SAME: sret([32 x i8]) align 16 dereferenceable(32) %_0, // CHECK-SAME: align 16 dereferenceable(32) %x // CHECK: [[A:%.*]] = load i32, ptr %x, align 16 // CHECK-NEXT: [[GEP:%.*]] = getelementptr inbounds i8, ptr %x, i64 16 // CHECK-NEXT: [[B:%.*]] = load i128, ptr [[GEP]], align 16 // CHECK-NEXT: store i32 [[A]], ptr %_0, align 16 // CHECK-NEXT: [[GEP:%.*]] = getelementptr inbounds i8, ptr %_0, i64 16 // CHECK-NEXT: store i128 [[B]], ptr [[GEP]], align 16 // CHECK-NEXT: ret void *x } #[no_mangle] pub fn store(x: &mut ScalarPair) { // CHECK-LABEL: @store( // CHECK-SAME: align 16 dereferenceable(32) %x // CHECK: store i32 1, ptr %x, align 16 // CHECK-NEXT: [[GEP:%.*]] = getelementptr inbounds i8, ptr %x, i64 16 // CHECK-NEXT: store i128 2, ptr [[GEP]], align 16 *x = ScalarPair { a: 1, b: 2 }; } #[no_mangle] pub fn alloca() { // CHECK-LABEL: @alloca( // CHECK: [[X:%.*]] = alloca [32 x i8], align 16 // CHECK: store i32 1, ptr %x, align 16 // CHECK-NEXT: [[GEP:%.*]] = getelementptr inbounds i8, ptr %x, i64 16 // CHECK-NEXT: store i128 2, ptr [[GEP]], align 16 let mut x = ScalarPair { a: 1, b: 2 }; store(&mut x); } #[no_mangle] pub fn load_volatile(x: &ScalarPair) -> ScalarPair { // CHECK-LABEL: @load_volatile( // CHECK-SAME: sret([32 x i8]) align 16 dereferenceable(32) %_0, // CHECK-SAME: align 16 dereferenceable(32) %x // CHECK: [[LOAD:%.*]] = load volatile %ScalarPair, ptr %x, align 16 // CHECK-NEXT: store %ScalarPair [[LOAD]], ptr %_0, align 16 // CHECK-NEXT: ret void unsafe { std::intrinsics::volatile_load(x) } } #[no_mangle] pub fn transmute(x: ScalarPair) -> (std::mem::MaybeUninit, i128) { // CHECK-LABEL: @transmute( // CHECK-SAME: sret([32 x i8]) align 16 dereferenceable(32) %_0, // CHECK-SAME: i32 noundef %x.0, i128 noundef %x.1 // CHECK: store i32 %x.0, ptr %_0, align 16 // CHECK-NEXT: [[GEP:%.*]] = getelementptr inbounds i8, ptr %_0, i64 16 // CHECK-NEXT: store i128 %x.1, ptr [[GEP]], align 16 // CHECK-NEXT: ret void unsafe { std::mem::transmute(x) } } #[repr(C)] #[derive(Clone, Copy)] pub struct Struct { a: i32, b: i32, c: i128, } #[no_mangle] pub fn store_struct(x: &mut Struct) { // CHECK-LABEL: @store_struct( // CHECK-SAME: align 16 dereferenceable(32) %x // CHECK: [[TMP:%.*]] = alloca [32 x i8], align 16 // CHECK: store i32 1, ptr [[TMP]], align 16 // CHECK-NEXT: [[GEP1:%.*]] = getelementptr inbounds i8, ptr [[TMP]], i64 4 // CHECK-NEXT: store i32 2, ptr [[GEP1]], align 4 // CHECK-NEXT: [[GEP2:%.*]] = getelementptr inbounds i8, ptr [[TMP]], i64 16 // CHECK-NEXT: store i128 3, ptr [[GEP2]], align 16 // CHECK-NEXT: call void @llvm.memcpy.p0.p0.i64(ptr align 16 %x, ptr align 16 [[TMP]], i64 32, i1 false) *x = Struct { a: 1, b: 2, c: 3 }; }