// RUN: %clang_cc1 -std=c++2a %s -emit-llvm -o - -triple x86_64-linux-gnu | FileCheck %s // RUN: %clang_cc1 -std=c++2a %s -emit-llvm -o - -triple x86_64-linux-gnu -O2 -disable-llvm-passes | FileCheck %s --check-prefix=CHECK-OPT struct A { ~A(); int n; char c[3]; }; struct B { [[no_unique_address]] A a; char k; }; // CHECK-DAG: @b = global { i32, [3 x i8], i8 } { i32 1, [3 x i8] c"\02\03\04", i8 5 } B b = {1, 2, 3, 4, 5}; struct C : A {}; struct D : C {}; struct E { int e; [[no_unique_address]] D d; char k; }; // CHECK-DAG: @e = global { i32, i32, [3 x i8], i8 } { i32 1, i32 2, [3 x i8] c"\03\04\05", i8 6 } E e = {1, 2, 3, 4, 5, 6}; struct Empty1 {}; struct Empty2 {}; struct Empty3 {}; struct HasEmpty { [[no_unique_address]] Empty1 e1; int a; [[no_unique_address]] Empty2 e2; int b; [[no_unique_address]] Empty3 e3; }; // CHECK-DAG: @he = global %{{[^ ]*}} { i32 1, i32 2 } HasEmpty he = {{}, 1, {}, 2, {}}; struct HasEmptyDuplicates { [[no_unique_address]] Empty1 e1; // +0 int a; [[no_unique_address]] Empty1 e2; // +4 int b; [[no_unique_address]] Empty1 e3; // +8 }; // CHECK-DAG: @off1 = global i64 0 Empty1 HasEmptyDuplicates::*off1 = &HasEmptyDuplicates::e1; // CHECK-DAG: @off2 = global i64 4 Empty1 HasEmptyDuplicates::*off2 = &HasEmptyDuplicates::e2; // CHECK-DAG: @off3 = global i64 8 Empty1 HasEmptyDuplicates::*off3 = &HasEmptyDuplicates::e3; // CHECK-DAG: @hed = global %{{[^ ]*}} { i32 1, i32 2, [4 x i8] undef } HasEmptyDuplicates hed = {{}, 1, {}, 2, {}}; struct __attribute__((packed, aligned(2))) PackedAndPadded { ~PackedAndPadded(); char c; int n; }; struct WithPackedAndPadded { [[no_unique_address]] PackedAndPadded pap; char d; }; // CHECK-DAG: @wpap = global <{ i8, i32, i8 }> <{ i8 1, i32 2, i8 3 }> WithPackedAndPadded wpap = {1, 2, 3}; struct FieldOverlap { [[no_unique_address]] Empty1 e1, e2, e3, e4; int n; }; static_assert(sizeof(FieldOverlap) == 4); // CHECK-DAG: @fo = global %{{[^ ]*}} { i32 1234 } FieldOverlap fo = {{}, {}, {}, {}, 1234}; // CHECK-DAG: @e1 = constant %[[E1:[^ ]*]]* bitcast (%[[FO:[^ ]*]]* @fo to %[[E1]]*) Empty1 &e1 = fo.e1; // CHECK-DAG: @e2 = constant %[[E1]]* bitcast (i8* getelementptr (i8, i8* bitcast (%[[FO]]* @fo to i8*), i64 1) to %[[E1]]*) Empty1 &e2 = fo.e2; // CHECK-LABEL: accessE1 // CHECK: %[[RET:.*]] = bitcast %[[FO]]* %{{.*}} to %[[E1]]* // CHECK: ret %[[E1]]* %[[RET]] Empty1 &accessE1(FieldOverlap &fo) { return fo.e1; } // CHECK-LABEL: accessE2 // CHECK: %[[AS_I8:.*]] = bitcast %[[FO]]* %{{.*}} to i8* // CHECK: %[[ADJUSTED:.*]] = getelementptr inbounds i8, i8* %[[AS_I8]], i64 1 // CHECK: %[[RET:.*]] = bitcast i8* %[[ADJUSTED]] to %[[E1]]* // CHECK: ret %[[E1]]* %[[RET]] Empty1 &accessE2(FieldOverlap &fo) { return fo.e2; } struct LaterDeclaredFieldHasLowerOffset { int a; int b; [[no_unique_address]] Empty1 e; }; // CHECK-OPT-LABEL: @_Z41loadWhereLaterDeclaredFieldHasLowerOffset int loadWhereLaterDeclaredFieldHasLowerOffset(LaterDeclaredFieldHasLowerOffset &a) { // CHECK-OPT: getelementptr // CHECK-OPT: load {{.*}}, !tbaa ![[TBAA_AB:[0-9]*]] return a.b; } // Note, never emit TBAA for zero-size fields. // CHECK-OPT: ![[TBAA_AB]] = !{![[TBAA_A:[0-9]*]], ![[TBAA_INT:[0-9]*]], i64 4} // CHECK-OPT: ![[TBAA_A]] = !{!"_ZTS32LaterDeclaredFieldHasLowerOffset", ![[TBAA_INT]], i64 0, ![[TBAA_INT]], i64 4}