// RUN: %clang_cc1 -std=c++11 -triple x86_64-apple-darwin %s -emit-llvm -o - | FileCheck -check-prefixes=X64,CHECK %s
// RUN: %clang_cc1 -std=c++11 -triple amdgcn %s -emit-llvm -o - | FileCheck -check-prefixes=AMDGCN,CHECK %s
template<typename T>
struct S {
static int n;
};
template<typename T> int S<T>::n = 5;
int f() {
// Make sure that the reference here is enough to trigger the instantiation of
// the static data member.
// CHECK: @_ZN1SIiE1nE = linkonce_odr{{.*}} global i32 5
int a[S<int>::n];
return sizeof a;
}
void test0(void *array, int n) {
// CHECK-LABEL: define{{.*}} void @_Z5test0Pvi(
// AMDGCN: [[ARRAY0:%.*]] = alloca ptr, align 8, addrspace(5)
// AMDGCN-NEXT: [[N0:%.*]] = alloca i32, align 4, addrspace(5)
// AMDGCN-NEXT: [[REF0:%.*]] = alloca ptr, align 8, addrspace(5)
// AMDGCN-NEXT: [[S0:%.*]] = alloca i16, align 2, addrspace(5)
// AMDGCN-NEXT: [[ARRAY:%.*]] = addrspacecast ptr addrspace(5) [[ARRAY0]] to ptr
// AMDGCN-NEXT: [[N:%.*]] = addrspacecast ptr addrspace(5) [[N0]] to ptr
// AMDGCN-NEXT: [[REF:%.*]] = addrspacecast ptr addrspace(5) [[REF0]] to ptr
// AMDGCN-NEXT: [[S:%.*]] = addrspacecast ptr addrspace(5) [[S0]] to ptr
// X64: [[ARRAY:%.*]] = alloca ptr, align 8
// X64-NEXT: [[N:%.*]] = alloca i32, align 4
// X64-NEXT: [[REF:%.*]] = alloca ptr, align 8
// X64-NEXT: [[S:%.*]] = alloca i16, align 2
// CHECK-NEXT: store ptr
// CHECK-NEXT: store i32
// Capture the bounds.
// CHECK-NEXT: [[T0:%.*]] = load i32, ptr [[N]], align 4
// CHECK-NEXT: [[DIM0:%.*]] = zext i32 [[T0]] to i64
// CHECK-NEXT: [[T0:%.*]] = load i32, ptr [[N]], align 4
// CHECK-NEXT: [[T1:%.*]] = add nsw i32 [[T0]], 1
// CHECK-NEXT: [[DIM1:%.*]] = zext i32 [[T1]] to i64
typedef short array_t[n][n+1];
// CHECK-NEXT: [[T0:%.*]] = load ptr, ptr [[ARRAY]], align 8
// CHECK-NEXT: store ptr [[T0]], ptr [[REF]], align 8
array_t &ref = *(array_t*) array;
// CHECK-NEXT: [[T0:%.*]] = load ptr, ptr [[REF]]
// CHECK-NEXT: [[T1:%.*]] = mul nsw i64 1, [[DIM1]]
// CHECK-NEXT: [[T2:%.*]] = getelementptr inbounds i16, ptr [[T0]], i64 [[T1]]
// CHECK-NEXT: [[T3:%.*]] = getelementptr inbounds i16, ptr [[T2]], i64 2
// CHECK-NEXT: store i16 3, ptr [[T3]]
ref[1][2] = 3;
// CHECK-NEXT: [[T0:%.*]] = load ptr, ptr [[REF]]
// CHECK-NEXT: [[T1:%.*]] = mul nsw i64 4, [[DIM1]]
// CHECK-NEXT: [[T2:%.*]] = getelementptr inbounds i16, ptr [[T0]], i64 [[T1]]
// CHECK-NEXT: [[T3:%.*]] = getelementptr inbounds i16, ptr [[T2]], i64 5
// CHECK-NEXT: [[T4:%.*]] = load i16, ptr [[T3]]
// CHECK-NEXT: store i16 [[T4]], ptr [[S]], align 2
short s = ref[4][5];
// CHECK-NEXT: ret void
}
void test2(int b) {
// CHECK-LABEL: define{{.*}} void {{.*}}test2{{.*}}(i32 noundef %b)
int varr[b];
// AMDGCN: %__end1 = alloca ptr, align 8, addrspace(5)
// AMDGCN: [[END:%.*]] = addrspacecast ptr addrspace(5) %__end1 to ptr
// get the address of %b by checking the first store that stores it
//CHECK: store i32 %b, ptr [[PTR_B:%.*]]
// get the size of the VLA by getting the first load of the PTR_B
//CHECK: [[VLA_NUM_ELEMENTS_PREZEXT:%.*]] = load i32, ptr [[PTR_B]]
//CHECK-NEXT: [[VLA_NUM_ELEMENTS_PRE:%.*]] = zext i32 [[VLA_NUM_ELEMENTS_PREZEXT]]
b = 15;
//CHECK: store i32 15, ptr [[PTR_B]]
// Now get the sizeof, and then divide by the element size
//CHECK: [[VLA_SIZEOF:%.*]] = mul nuw i64 4, [[VLA_NUM_ELEMENTS_PRE]]
//CHECK-NEXT: [[VLA_NUM_ELEMENTS_POST:%.*]] = udiv i64 [[VLA_SIZEOF]], 4
//CHECK-NEXT: [[VLA_END_PTR:%.*]] = getelementptr inbounds nuw i32, ptr {{%.*}}, i64 [[VLA_NUM_ELEMENTS_POST]]
//X64-NEXT: store ptr [[VLA_END_PTR]], ptr %__end1
//AMDGCN-NEXT: store ptr [[VLA_END_PTR]], ptr [[END]]
for (int d : varr) 0;
}
void test3(int b, int c) {
// CHECK-LABEL: define{{.*}} void {{.*}}test3{{.*}}(i32 noundef %b, i32 noundef %c)
int varr[b][c];
// AMDGCN: %__end1 = alloca ptr, align 8, addrspace(5)
// AMDGCN: [[END:%.*]] = addrspacecast ptr addrspace(5) %__end1 to ptr
// get the address of %b by checking the first store that stores it
//CHECK: store i32 %b, ptr [[PTR_B:%.*]]
//CHECK-NEXT: store i32 %c, ptr [[PTR_C:%.*]]
// get the size of the VLA by getting the first load of the PTR_B
//CHECK: [[VLA_DIM1_PREZEXT:%.*]] = load i32, ptr [[PTR_B]]
//CHECK-NEXT: [[VLA_DIM1_PRE:%.*]] = zext i32 [[VLA_DIM1_PREZEXT]]
//CHECK: [[VLA_DIM2_PREZEXT:%.*]] = load i32, ptr [[PTR_C]]
//CHECK-NEXT: [[VLA_DIM2_PRE:%.*]] = zext i32 [[VLA_DIM2_PREZEXT]]
b = 15;
c = 15;
//CHECK: store i32 15, ptr [[PTR_B]]
//CHECK: store i32 15, ptr [[PTR_C]]
// Now get the sizeof, and then divide by the element size
// multiply the two dimensions, then by the element type and then divide by the sizeof dim2
//CHECK: [[VLA_DIM1_X_DIM2:%.*]] = mul nuw i64 [[VLA_DIM1_PRE]], [[VLA_DIM2_PRE]]
//CHECK-NEXT: [[VLA_SIZEOF:%.*]] = mul nuw i64 4, [[VLA_DIM1_X_DIM2]]
//CHECK-NEXT: [[VLA_SIZEOF_DIM2:%.*]] = mul nuw i64 4, [[VLA_DIM2_PRE]]
//CHECK-NEXT: [[VLA_NUM_ELEMENTS:%.*]] = udiv i64 [[VLA_SIZEOF]], [[VLA_SIZEOF_DIM2]]
//CHECK-NEXT: [[VLA_END_INDEX:%.*]] = mul nsw i64 [[VLA_NUM_ELEMENTS]], [[VLA_DIM2_PRE]]
//CHECK-NEXT: [[VLA_END_PTR:%.*]] = getelementptr inbounds nuw i32, ptr {{%.*}}, i64 [[VLA_END_INDEX]]
//X64-NEXT: store ptr [[VLA_END_PTR]], ptr %__end
//AMDGCN-NEXT: store ptr [[VLA_END_PTR]], ptr [[END]]
for (auto &d : varr) 0;
}
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