llvm-project/clang/test/CodeGenCXX/microsoft-abi-member-pointe...

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// RUN: %clang_cc1 -std=c++11 -Wno-uninitialized -fno-rtti -emit-llvm %s -o - -triple=i386-pc-win32 -fms-extensions | FileCheck -allow-deprecated-dag-overlap %s
// RUN: %clang_cc1 -std=c++11 -Wno-uninitialized -fno-rtti -emit-llvm %s -o - -triple=x86_64-pc-win32 -fms-extensions | FileCheck %s -check-prefix=X64
// RUN: %clang_cc1 -std=c++11 -Wno-uninitialized -fno-rtti -emit-llvm %s -o - -triple=i386-pc-win32 -DINCOMPLETE_VIRTUAL -fms-extensions -verify
// RUN: %clang_cc1 -std=c++11 -Wno-uninitialized -fno-rtti -emit-llvm %s -o - -triple=i386-pc-win32 -DINCOMPLETE_VIRTUAL -DMEMFUN -fms-extensions -verify
namespace pr37399 {
template <typename T>
struct Functor {
void (T::*PtrToMemberFunction)();
};
// CHECK-DAG: %"struct.pr37399::Functor" = type { i8* }
template <typename SomeType>
class SimpleDerivedFunctor;
template <typename SomeType>
class SimpleDerivedFunctor : public Functor<SimpleDerivedFunctor<SomeType>> {};
// CHECK-DAG: %"class.pr37399::SimpleDerivedFunctor" = type { %"struct.pr37399::Functor" }
SimpleDerivedFunctor<void> SimpleFunctor;
// CHECK-DAG: @"?SimpleFunctor@pr37399@@3V?$SimpleDerivedFunctor@X@1@A" = dso_local global %"class.pr37399::SimpleDerivedFunctor" zeroinitializer, align 4
short Global = 0;
template <typename SomeType>
class DerivedFunctor;
template <typename SomeType>
class DerivedFunctor
: public Functor<DerivedFunctor<void>> {
public:
void Foo() {
Global = 42;
}
};
class MultipleBase {
public:
MultipleBase() : Value() {}
short Value;
};
// CHECK-DAG: %"class.pr37399::MultipleBase" = type { i16 }
template <typename SomeType>
class MultiplyDerivedFunctor;
template <typename SomeType>
class MultiplyDerivedFunctor
: public Functor<MultiplyDerivedFunctor<void>>,
public MultipleBase {
public:
void Foo() {
MultipleBase::Value = 42*2;
}
};
class VirtualBase {
public:
VirtualBase() : Value() {}
short Value;
};
// CHECK-DAG: %"class.pr37399::VirtualBase" = type { i16 }
template <typename SomeType>
class VirtBaseFunctor
: public Functor<SomeType>,
public virtual VirtualBase{};
template <typename SomeType>
class VirtuallyDerivedFunctor;
template <typename SomeType>
class VirtuallyDerivedFunctor
: public VirtBaseFunctor<VirtuallyDerivedFunctor<void>>,
public virtual VirtualBase {
public:
void Foo() {
VirtualBase::Value = 42*3;
}
};
} // namespace pr37399
pr37399::DerivedFunctor<int> BFunctor;
// CHECK-DAG: @"?BFunctor@@3V?$DerivedFunctor@H@pr37399@@A" = dso_local global %"[[BFUNCTOR:class.pr37399::DerivedFunctor(\.[0-9]+)?]]" zeroinitializer, align 8
// CHECK-DAG: %"[[BFUNCTOR]]" = type { %"[[BFUNCTORBASE:struct.pr37399::Functor(\.[0-9]+)?]]" }
// CHECK-DAG: %"[[BFUNCTORBASE]]" = type { { i8*, i32, i32, i32 } }
pr37399::DerivedFunctor<void> AFunctor;
// CHECK-DAG: @"?AFunctor@@3V?$DerivedFunctor@X@pr37399@@A" = dso_local global %"[[AFUNCTOR:class.pr37399::DerivedFunctor(\.[0-9]+)?]]" zeroinitializer, align 8
// CHECK-DAG: %"[[AFUNCTOR]]" = type { %"[[AFUNCTORBASE:struct.pr37399::Functor(\.[0-9]+)?]]" }
// CHECK-DAG: %"[[AFUNCTORBASE]]" = type { { i8*, i32, i32, i32 } }
pr37399::MultiplyDerivedFunctor<int> DFunctor;
// CHECK-DAG: @"?DFunctor@@3V?$MultiplyDerivedFunctor@H@pr37399@@A" = dso_local global %"[[DFUNCTOR:class.pr37399::MultiplyDerivedFunctor(\.[0-9]+)?]]" zeroinitializer, align 8
// CHECK-DAG: %"[[DFUNCTOR]]" = type { %"[[DFUNCTORBASE:struct.pr37399::Functor(\.[0-9]+)?]]", %"class.pr37399::MultipleBase", [6 x i8] }
// CHECK-DAG: %"[[DFUNCTORBASE]]" = type { { i8*, i32, i32, i32 } }
pr37399::MultiplyDerivedFunctor<void> CFunctor;
// CHECK-DAG: @"?CFunctor@@3V?$MultiplyDerivedFunctor@X@pr37399@@A" = dso_local global %"[[CFUNCTOR:class.pr37399::MultiplyDerivedFunctor(\.[0-9]+)?]]" zeroinitializer, align 8
// CHECK-DAG: %"[[CFUNCTOR]]" = type { %"[[CFUNCTORBASE:struct.pr37399::Functor(\.[0-9]+)?]]", %"class.pr37399::MultipleBase", [6 x i8] }
// CHECK-DAG: %"[[CFUNCTORBASE]]" = type { { i8*, i32, i32, i32 } }
pr37399::VirtuallyDerivedFunctor<int> FFunctor;
// CHECK-DAG: @"?FFunctor@@3V?$VirtuallyDerivedFunctor@H@pr37399@@A" = dso_local global %"[[FFUNCTOR:class.pr37399::VirtuallyDerivedFunctor(\.[0-9]+)?]]" zeroinitializer, align 8
// CHECK-DAG: %"[[FFUNCTOR]]" = type { %"class.pr37399::VirtBaseFunctor.base", %"class.pr37399::VirtualBase" }
pr37399::VirtuallyDerivedFunctor<void> EFunctor;
// CHECK-DAG: @"?EFunctor@@3V?$VirtuallyDerivedFunctor@X@pr37399@@A" = dso_local global %"[[EFUNCTOR:class.pr37399::VirtuallyDerivedFunctor(\.[0-9]+)?]]" zeroinitializer, align 8
// CHECK-DAG: %"[[EFUNCTOR]]" = type { %"class.pr37399::VirtBaseFunctor.base", %"class.pr37399::VirtualBase" }
// CHECK-DAG: %"class.pr37399::VirtBaseFunctor.base" = type <{ %"[[VFUNCTORBASE:struct.pr37399::Functor(\.[0-9]+)?]]", i32*, [4 x i8] }>
// CHECK-DAG: %"[[VFUNCTORBASE]]" = type { { i8*, i32, i32, i32 } }
namespace pr37399 {
void SingleInheritanceFnPtrCall() {
BFunctor.PtrToMemberFunction = &DerivedFunctor<void>::Foo;
(AFunctor.*(BFunctor.PtrToMemberFunction))();
}
void MultipleInheritanceFnPtrCall() {
DFunctor.PtrToMemberFunction = &MultiplyDerivedFunctor<void>::Foo;
Global = CFunctor.MultipleBase::Value;
(CFunctor.*(DFunctor.PtrToMemberFunction))();
Global = CFunctor.MultipleBase::Value;
}
void VirtualInheritanceFnPtrCall() {
FFunctor.PtrToMemberFunction = &VirtuallyDerivedFunctor<void>::Foo;
Global = EFunctor.VirtualBase::Value;
(EFunctor.*(FFunctor.PtrToMemberFunction))();
Global = EFunctor.VirtualBase::Value;
}
} // namespace pr37399
struct PR26313_Y;
typedef void (PR26313_Y::*PR26313_FUNC)();
struct PR26313_X {
PR26313_FUNC *ptr;
PR26313_X();
};
PR26313_X::PR26313_X() {}
void PR26313_f(PR26313_FUNC *p) { delete p; }
struct PR26313_Z;
int PR26313_Z::**a = nullptr;
int PR26313_Z::*b = *a;
// CHECK-DAG: @"?a@@3PAPQPR26313_Z@@HA" = dso_local global %0* null, align 4
// CHECK-DAG: @"?b@@3PQPR26313_Z@@HQ1@" = dso_local global { i32, i32, i32 } { i32 0, i32 0, i32 -1 }, align 4
namespace PR20947 {
struct A;
int A::**a = nullptr;
// CHECK-DAG: @"?a@PR20947@@3PAPQA@1@HA" = dso_local global %{{.*}}* null, align 4
struct B;
int B::*&b = b;
// CHECK-DAG: @"?b@PR20947@@3AAPQB@1@HA" = dso_local global %{{.*}}* null, align 4
}
namespace PR20017 {
template <typename T>
struct A {
int T::*m_fn1() { return nullptr; }
};
struct B;
auto a = &A<B>::m_fn1;
// CHECK-DAG: @"?a@PR20017@@3P8?$A@UB@PR20017@@@1@AEPQB@1@HXZQ21@" = dso_local global i8* bitcast ({ i32, i32, i32 } ({{.*}}*)* @"?m_fn1@?$A@UB@PR20017@@@PR20017@@QAEPQB@2@HXZ" to i8*), align 4
}
#ifndef INCOMPLETE_VIRTUAL
struct B1 {
void foo();
int b;
};
struct B2 {
int b2;
void foo();
};
struct Single : B1 {
void foo();
};
struct Multiple : B1, B2 {
int m;
void foo();
};
struct Virtual : virtual B1 {
int v;
void foo();
};
struct POD {
int a;
int b;
};
struct Polymorphic {
virtual void myVirtual();
int a;
int b;
};
// This class uses the virtual inheritance model, yet its vbptr offset is not 0.
// We still use zero for the null field offset, despite it being a valid field
// offset.
struct NonZeroVBPtr : POD, Virtual {
int n;
void foo();
};
struct Unspecified;
struct UnspecSingle;
// Check that we can lower the LLVM types and get the null initializers right.
int Single ::*s_d_memptr;
int Polymorphic::*p_d_memptr;
int Multiple ::*m_d_memptr;
int Virtual ::*v_d_memptr;
int NonZeroVBPtr::*n_d_memptr;
int Unspecified::*u_d_memptr;
int UnspecSingle::*us_d_memptr;
// CHECK: @"?s_d_memptr@@3PQSingle@@HQ1@" = dso_local global i32 -1, align 4
// CHECK: @"?p_d_memptr@@3PQPolymorphic@@HQ1@" = dso_local global i32 0, align 4
// CHECK: @"?m_d_memptr@@3PQMultiple@@HQ1@" = dso_local global i32 -1, align 4
// CHECK: @"?v_d_memptr@@3PQVirtual@@HQ1@" = dso_local global { i32, i32 }
// CHECK: { i32 0, i32 -1 }, align 4
// CHECK: @"?n_d_memptr@@3PQNonZeroVBPtr@@HQ1@" = dso_local global { i32, i32 }
// CHECK: { i32 0, i32 -1 }, align 4
// CHECK: @"?u_d_memptr@@3PQUnspecified@@HQ1@" = dso_local global { i32, i32, i32 }
// CHECK: { i32 0, i32 0, i32 -1 }, align 4
// CHECK: @"?us_d_memptr@@3PQUnspecSingle@@HQ1@" = dso_local global { i32, i32, i32 }
// CHECK: { i32 0, i32 0, i32 -1 }, align 4
void (Single ::*s_f_memptr)();
void (Multiple::*m_f_memptr)();
void (Virtual ::*v_f_memptr)();
// CHECK: @"?s_f_memptr@@3P8Single@@AEXXZQ1@" = dso_local global i8* null, align 4
// CHECK: @"?m_f_memptr@@3P8Multiple@@AEXXZQ1@" = dso_local global { i8*, i32 } zeroinitializer, align 4
// CHECK: @"?v_f_memptr@@3P8Virtual@@AEXXZQ1@" = dso_local global { i8*, i32, i32 } zeroinitializer, align 4
// We can define Unspecified after locking in the inheritance model.
struct Unspecified : Multiple, Virtual {
void foo();
int u;
};
struct UnspecSingle {
void foo();
};
// Test memptr emission in a constant expression.
namespace Const {
void (Single ::*s_f_mp)() = &Single::foo;
void (Multiple ::*m_f_mp)() = &B2::foo;
void (Virtual ::*v_f_mp)() = &Virtual::foo;
void (Unspecified::*u_f_mp)() = &Unspecified::foo;
void (UnspecSingle::*us_f_mp)() = &UnspecSingle::foo;
// CHECK: @"?s_f_mp@Const@@3P8Single@@AEXXZQ2@" =
// CHECK: global i8* bitcast ({{.*}} @"?foo@Single@@QAEXXZ" to i8*), align 4
// CHECK: @"?m_f_mp@Const@@3P8Multiple@@AEXXZQ2@" =
// CHECK: global { i8*, i32 } { i8* bitcast ({{.*}} @"?foo@B2@@QAEXXZ" to i8*), i32 4 }, align 4
// CHECK: @"?v_f_mp@Const@@3P8Virtual@@AEXXZQ2@" =
// CHECK: global { i8*, i32, i32 } { i8* bitcast ({{.*}} @"?foo@Virtual@@QAEXXZ" to i8*), i32 0, i32 0 }, align 4
// CHECK: @"?u_f_mp@Const@@3P8Unspecified@@AEXXZQ2@" =
// CHECK: global { i8*, i32, i32, i32 } { i8* bitcast ({{.*}} @"?foo@Unspecified@@QAEXXZ" to i8*), i32 0, i32 0, i32 0 }, align 4
// CHECK: @"?us_f_mp@Const@@3P8UnspecSingle@@AEXXZQ2@" =
// CHECK: global { i8*, i32, i32, i32 } { i8* bitcast ({{.*}} @"?foo@UnspecSingle@@QAEXXZ" to i8*), i32 0, i32 0, i32 0 }, align 4
}
namespace CastParam {
// This exercises ConstExprEmitter instead of ValueDecl::evaluateValue. The
// extra reinterpret_cast for the parameter type requires more careful folding.
// FIXME: Or does it? If reinterpret_casts are no-ops, we should be able to
// strip them in evaluateValue() and just proceed as normal with an APValue.
struct A {
int a;
void foo(A *p);
};
struct B { int b; };
struct C : B, A { int c; };
void (A::*ptr1)(void *) = (void (A::*)(void *)) &A::foo;
// CHECK: @"?ptr1@CastParam@@3P8A@1@AEXPAX@ZQ21@" =
// CHECK: global i8* bitcast (void ({{.*}})* @"?foo@A@CastParam@@QAEXPAU12@@Z" to i8*), align 4
// Try a reinterpret_cast followed by a memptr conversion.
void (C::*ptr2)(void *) = (void (C::*)(void *)) (void (A::*)(void *)) &A::foo;
// CHECK: @"?ptr2@CastParam@@3P8C@1@AEXPAX@ZQ21@" =
// CHECK: global { i8*, i32 } { i8* bitcast (void ({{.*}})* @"?foo@A@CastParam@@QAEXPAU12@@Z" to i8*), i32 4 }, align 4
void (C::*ptr3)(void *) = (void (C::*)(void *)) (void (A::*)(void *)) (void (A::*)(A *)) 0;
// CHECK: @"?ptr3@CastParam@@3P8C@1@AEXPAX@ZQ21@" =
// CHECK: global { i8*, i32 } zeroinitializer, align 4
struct D : C {
virtual void isPolymorphic();
int d;
};
// Try a cast that changes the inheritance model. Null for D is 0, but null for
// C is -1. We need the cast to long in order to hit the non-APValue path.
int C::*ptr4 = (int C::*) (int D::*) (long D::*) 0;
// CHECK: @"?ptr4@CastParam@@3PQC@1@HQ21@" = dso_local global i32 -1, align 4
// MSVC rejects this but we accept it.
int C::*ptr5 = (int C::*) (long D::*) 0;
// CHECK: @"?ptr5@CastParam@@3PQC@1@HQ21@" = dso_local global i32 -1, align 4
}
struct UnspecWithVBPtr;
int UnspecWithVBPtr::*forceUnspecWithVBPtr;
struct UnspecWithVBPtr : B1, virtual B2 {
int u;
void foo();
};
// Test emitting non-virtual member pointers in a non-constexpr setting.
void EmitNonVirtualMemberPointers() {
void (Single ::*s_f_memptr)() = &Single::foo;
void (Multiple ::*m_f_memptr)() = &Multiple::foo;
void (Virtual ::*v_f_memptr)() = &Virtual::foo;
void (Unspecified::*u_f_memptr)() = &Unspecified::foo;
void (UnspecWithVBPtr::*u2_f_memptr)() = &UnspecWithVBPtr::foo;
// CHECK: define dso_local void @"?EmitNonVirtualMemberPointers@@YAXXZ"() {{.*}} {
// CHECK: alloca i8*, align 4
// CHECK: alloca { i8*, i32 }, align 4
// CHECK: alloca { i8*, i32, i32 }, align 4
// CHECK: alloca { i8*, i32, i32, i32 }, align 4
// CHECK: store i8* bitcast (void (%{{.*}}*)* @"?foo@Single@@QAEXXZ" to i8*), i8** %{{.*}}, align 4
// CHECK: store { i8*, i32 }
// CHECK: { i8* bitcast (void (%{{.*}}*)* @"?foo@Multiple@@QAEXXZ" to i8*), i32 0 },
// CHECK: { i8*, i32 }* %{{.*}}, align 4
// CHECK: store { i8*, i32, i32 }
// CHECK: { i8* bitcast (void (%{{.*}}*)* @"?foo@Virtual@@QAEXXZ" to i8*), i32 0, i32 0 },
// CHECK: { i8*, i32, i32 }* %{{.*}}, align 4
// CHECK: store { i8*, i32, i32, i32 }
// CHECK: { i8* bitcast (void (%{{.*}}*)* @"?foo@Unspecified@@QAEXXZ" to i8*), i32 0, i32 0, i32 0 },
// CHECK: { i8*, i32, i32, i32 }* %{{.*}}, align 4
// CHECK: store { i8*, i32, i32, i32 }
// CHECK: { i8* bitcast (void (%{{.*}}*)* @"?foo@UnspecWithVBPtr@@QAEXXZ" to i8*),
// CHECK: i32 0, i32 0, i32 0 },
// CHECK: { i8*, i32, i32, i32 }* %{{.*}}, align 4
// CHECK: ret void
// CHECK: }
}
void podMemPtrs() {
int POD::*memptr;
memptr = &POD::a;
memptr = &POD::b;
if (memptr)
memptr = 0;
// Check that member pointers use the right offsets and that null is -1.
// CHECK: define dso_local void @"?podMemPtrs@@YAXXZ"() {{.*}} {
// CHECK: %[[memptr:.*]] = alloca i32, align 4
// CHECK-NEXT: store i32 0, i32* %[[memptr]], align 4
// CHECK-NEXT: store i32 4, i32* %[[memptr]], align 4
// CHECK-NEXT: %[[memptr_val:.*]] = load i32, i32* %[[memptr]], align 4
// CHECK-NEXT: %{{.*}} = icmp ne i32 %[[memptr_val]], -1
// CHECK-NEXT: br i1 %{{.*}}, label %{{.*}}, label %{{.*}}
// CHECK: store i32 -1, i32* %[[memptr]], align 4
// CHECK: ret void
// CHECK: }
}
void polymorphicMemPtrs() {
int Polymorphic::*memptr;
memptr = &Polymorphic::a;
memptr = &Polymorphic::b;
if (memptr)
memptr = 0;
// Member pointers for polymorphic classes include the vtable slot in their
// offset and use 0 to represent null.
// CHECK: define dso_local void @"?polymorphicMemPtrs@@YAXXZ"() {{.*}} {
// CHECK: %[[memptr:.*]] = alloca i32, align 4
// CHECK-NEXT: store i32 4, i32* %[[memptr]], align 4
// CHECK-NEXT: store i32 8, i32* %[[memptr]], align 4
// CHECK-NEXT: %[[memptr_val:.*]] = load i32, i32* %[[memptr]], align 4
// CHECK-NEXT: %{{.*}} = icmp ne i32 %[[memptr_val]], 0
// CHECK-NEXT: br i1 %{{.*}}, label %{{.*}}, label %{{.*}}
// CHECK: store i32 0, i32* %[[memptr]], align 4
// CHECK: ret void
// CHECK: }
}
bool nullTestDataUnspecified(int Unspecified::*mp) {
return mp;
// CHECK: define dso_local zeroext i1 @"?nullTestDataUnspecified@@YA_NPQUnspecified@@H@Z"{{.*}} {
// CHECK: %{{.*}} = load { i32, i32, i32 }, { i32, i32, i32 }* %{{.*}}, align 4
// CHECK: store { i32, i32, i32 } {{.*}} align 4
// CHECK: %[[mp:.*]] = load { i32, i32, i32 }, { i32, i32, i32 }* %{{.*}}, align 4
// CHECK: %[[mp0:.*]] = extractvalue { i32, i32, i32 } %[[mp]], 0
// CHECK: %[[cmp0:.*]] = icmp ne i32 %[[mp0]], 0
// CHECK: %[[mp1:.*]] = extractvalue { i32, i32, i32 } %[[mp]], 1
// CHECK: %[[cmp1:.*]] = icmp ne i32 %[[mp1]], 0
// CHECK: %[[and0:.*]] = or i1 %[[cmp0]], %[[cmp1]]
// CHECK: %[[mp2:.*]] = extractvalue { i32, i32, i32 } %[[mp]], 2
// CHECK: %[[cmp2:.*]] = icmp ne i32 %[[mp2]], -1
// CHECK: %[[and1:.*]] = or i1 %[[and0]], %[[cmp2]]
// CHECK: ret i1 %[[and1]]
// CHECK: }
// Pass this large type indirectly.
// X64-LABEL: define dso_local zeroext i1 @"?nullTestDataUnspecified@@
// X64: ({ i32, i32, i32 }*)
}
bool nullTestFunctionUnspecified(void (Unspecified::*mp)()) {
return mp;
// CHECK: define dso_local zeroext i1 @"?nullTestFunctionUnspecified@@YA_NP8Unspecified@@AEXXZ@Z"{{.*}} {
// CHECK: %{{.*}} = load { i8*, i32, i32, i32 }, { i8*, i32, i32, i32 }* %{{.*}}, align 4
// CHECK: store { i8*, i32, i32, i32 } {{.*}} align 4
// CHECK: %[[mp:.*]] = load { i8*, i32, i32, i32 }, { i8*, i32, i32, i32 }* %{{.*}}, align 4
// CHECK: %[[mp0:.*]] = extractvalue { i8*, i32, i32, i32 } %[[mp]], 0
// CHECK: %[[cmp0:.*]] = icmp ne i8* %[[mp0]], null
// CHECK: ret i1 %[[cmp0]]
// CHECK: }
}
int loadDataMemberPointerVirtual(Virtual *o, int Virtual::*memptr) {
return o->*memptr;
// Test that we can unpack this aggregate member pointer and load the member
// data pointer.
// CHECK: define dso_local i32 @"?loadDataMemberPointerVirtual@@YAHPAUVirtual@@PQ1@H@Z"{{.*}} {
// CHECK: %[[o:.*]] = load %{{.*}}*, %{{.*}}** %{{.*}}, align 4
// CHECK: %[[memptr:.*]] = load { i32, i32 }, { i32, i32 }* %{{.*}}, align 4
// CHECK: %[[memptr0:.*]] = extractvalue { i32, i32 } %[[memptr:.*]], 0
// CHECK: %[[memptr1:.*]] = extractvalue { i32, i32 } %[[memptr:.*]], 1
// CHECK: %[[v6:.*]] = bitcast %{{.*}}* %[[o]] to i8*
// CHECK: %[[vbptr:.*]] = getelementptr inbounds i8, i8* %[[v6]], i32 0
// CHECK: %[[vbptr_a:.*]] = bitcast i8* %[[vbptr]] to i32**
// CHECK: %[[vbtable:.*]] = load i32*, i32** %[[vbptr_a:.*]]
// CHECK: %[[memptr1_shr:.*]] = ashr exact i32 %[[memptr1]], 2
// CHECK: %[[v7:.*]] = getelementptr inbounds i32, i32* %[[vbtable]], i32 %[[memptr1_shr]]
// CHECK: %[[vbase_offs:.*]] = load i32, i32* %[[v7]]
// CHECK: %[[v10:.*]] = getelementptr inbounds i8, i8* %[[vbptr]], i32 %[[vbase_offs]]
// CHECK: %[[offset:.*]] = getelementptr inbounds i8, i8* %[[v10]], i32 %[[memptr0]]
// CHECK: %[[v11:.*]] = bitcast i8* %[[offset]] to i32*
// CHECK: %[[v12:.*]] = load i32, i32* %[[v11]]
// CHECK: ret i32 %[[v12]]
// CHECK: }
// A two-field data memptr on x64 gets coerced to i64 and is passed in a
// register or memory.
// X64-LABEL: define dso_local i32 @"?loadDataMemberPointerVirtual@@YAHPEAUVirtual@@PEQ1@H@Z"
// X64: (%struct.Virtual* %o, i64 %memptr.coerce)
}
int loadDataMemberPointerUnspecified(Unspecified *o, int Unspecified::*memptr) {
return o->*memptr;
// Test that we can unpack this aggregate member pointer and load the member
// data pointer.
// CHECK: define dso_local i32 @"?loadDataMemberPointerUnspecified@@YAHPAUUnspecified@@PQ1@H@Z"{{.*}} {
// CHECK: %[[o:.*]] = load %{{.*}}*, %{{.*}}** %{{.*}}, align 4
// CHECK: %[[memptr:.*]] = load { i32, i32, i32 }, { i32, i32, i32 }* %{{.*}}, align 4
// CHECK: %[[memptr0:.*]] = extractvalue { i32, i32, i32 } %[[memptr:.*]], 0
// CHECK: %[[memptr1:.*]] = extractvalue { i32, i32, i32 } %[[memptr:.*]], 1
// CHECK: %[[memptr2:.*]] = extractvalue { i32, i32, i32 } %[[memptr:.*]], 2
// CHECK: %[[base:.*]] = bitcast %{{.*}}* %[[o]] to i8*
// CHECK: %[[is_vbase:.*]] = icmp ne i32 %[[memptr2]], 0
// CHECK: br i1 %[[is_vbase]], label %[[vadjust:.*]], label %[[skip:.*]]
//
// CHECK: [[vadjust]]
// CHECK: %[[vbptr:.*]] = getelementptr inbounds i8, i8* %[[base]], i32 %[[memptr1]]
// CHECK: %[[vbptr_a:.*]] = bitcast i8* %[[vbptr]] to i32**
// CHECK: %[[vbtable:.*]] = load i32*, i32** %[[vbptr_a:.*]]
// CHECK: %[[memptr2_shr:.*]] = ashr exact i32 %[[memptr2]], 2
// CHECK: %[[v7:.*]] = getelementptr inbounds i32, i32* %[[vbtable]], i32 %[[memptr2_shr]]
// CHECK: %[[vbase_offs:.*]] = load i32, i32* %[[v7]]
// CHECK: %[[base_adj:.*]] = getelementptr inbounds i8, i8* %[[vbptr]], i32 %[[vbase_offs]]
//
// CHECK: [[skip]]
// CHECK: %[[new_base:.*]] = phi i8* [ %[[base]], %{{.*}} ], [ %[[base_adj]], %[[vadjust]] ]
// CHECK: %[[offset:.*]] = getelementptr inbounds i8, i8* %[[new_base]], i32 %[[memptr0]]
// CHECK: %[[v11:.*]] = bitcast i8* %[[offset]] to i32*
// CHECK: %[[v12:.*]] = load i32, i32* %[[v11]]
// CHECK: ret i32 %[[v12]]
// CHECK: }
}
void callMemberPointerSingle(Single *o, void (Single::*memptr)()) {
(o->*memptr)();
// Just look for an indirect thiscall.
// CHECK: define dso_local void @"?callMemberPointerSingle@@{{.*}} {{.*}} {
// CHECK: call x86_thiscallcc void %{{.*}}(%{{.*}} %{{.*}})
// CHECK: ret void
// CHECK: }
// X64-LABEL: define dso_local void @"?callMemberPointerSingle@@
// X64: (%struct.Single* %o, i8* %memptr)
// X64: bitcast i8* %{{[^ ]*}} to void (%struct.Single*)*
// X64: ret void
}
void callMemberPointerMultiple(Multiple *o, void (Multiple::*memptr)()) {
(o->*memptr)();
// CHECK: define dso_local void @"?callMemberPointerMultiple@@{{.*}} {
// CHECK: %[[memptr0:.*]] = extractvalue { i8*, i32 } %{{.*}}, 0
// CHECK: %[[memptr1:.*]] = extractvalue { i8*, i32 } %{{.*}}, 1
// CHECK: %[[this_adjusted:.*]] = getelementptr inbounds i8, i8* %{{.*}}, i32 %[[memptr1]]
// CHECK: %[[this:.*]] = bitcast i8* %[[this_adjusted]] to {{.*}}
// CHECK: %[[fptr:.*]] = bitcast i8* %[[memptr0]] to {{.*}}
// CHECK: call x86_thiscallcc void %[[fptr]](%{{.*}} %[[this]])
// CHECK: ret void
// CHECK: }
}
void callMemberPointerVirtualBase(Virtual *o, void (Virtual::*memptr)()) {
(o->*memptr)();
// This shares a lot with virtual data member pointers.
// CHECK: define dso_local void @"?callMemberPointerVirtualBase@@{{.*}} {
// CHECK: %[[memptr0:.*]] = extractvalue { i8*, i32, i32 } %{{.*}}, 0
// CHECK: %[[memptr1:.*]] = extractvalue { i8*, i32, i32 } %{{.*}}, 1
// CHECK: %[[memptr2:.*]] = extractvalue { i8*, i32, i32 } %{{.*}}, 2
// CHECK: %[[vbptr:.*]] = getelementptr inbounds i8, i8* %{{.*}}, i32 0
// CHECK: %[[vbptr_a:.*]] = bitcast i8* %[[vbptr]] to i32**
// CHECK: %[[vbtable:.*]] = load i32*, i32** %[[vbptr_a:.*]]
// CHECK: %[[memptr2_shr:.*]] = ashr exact i32 %[[memptr2]], 2
// CHECK: %[[v7:.*]] = getelementptr inbounds i32, i32* %[[vbtable]], i32 %[[memptr2_shr]]
// CHECK: %[[vbase_offs:.*]] = load i32, i32* %[[v7]]
// CHECK: %[[v10:.*]] = getelementptr inbounds i8, i8* %[[vbptr]], i32 %[[vbase_offs]]
// CHECK: %[[this_adjusted:.*]] = getelementptr inbounds i8, i8* %[[v10]], i32 %[[memptr1]]
// CHECK: %[[fptr:.*]] = bitcast i8* %[[memptr0]] to void ({{.*}})
// CHECK: %[[this:.*]] = bitcast i8* %[[this_adjusted]] to {{.*}}
// CHECK: call x86_thiscallcc void %[[fptr]](%{{.*}} %[[this]])
// CHECK: ret void
// CHECK: }
}
bool compareSingleFunctionMemptr(void (Single::*l)(), void (Single::*r)()) {
return l == r;
// Should only be one comparison here.
// CHECK: define dso_local zeroext i1 @"?compareSingleFunctionMemptr@@YA_NP8Single@@AEXXZ0@Z"{{.*}} {
// CHECK-NOT: icmp
// CHECK: %[[r:.*]] = icmp eq
// CHECK-NOT: icmp
// CHECK: ret i1 %[[r]]
// CHECK: }
// X64-LABEL: define dso_local zeroext i1 @"?compareSingleFunctionMemptr@@
// X64: (i8* %{{[^,]*}}, i8* %{{[^)]*}})
}
bool compareNeqSingleFunctionMemptr(void (Single::*l)(), void (Single::*r)()) {
return l != r;
// Should only be one comparison here.
// CHECK: define dso_local zeroext i1 @"?compareNeqSingleFunctionMemptr@@YA_NP8Single@@AEXXZ0@Z"{{.*}} {
// CHECK-NOT: icmp
// CHECK: %[[r:.*]] = icmp ne
// CHECK-NOT: icmp
// CHECK: ret i1 %[[r]]
// CHECK: }
}
bool unspecFuncMemptrEq(void (Unspecified::*l)(), void (Unspecified::*r)()) {
return l == r;
// CHECK: define dso_local zeroext i1 @"?unspecFuncMemptrEq@@YA_NP8Unspecified@@AEXXZ0@Z"{{.*}} {
// CHECK: %[[lhs0:.*]] = extractvalue { i8*, i32, i32, i32 } %[[l:.*]], 0
// CHECK: %{{.*}} = extractvalue { i8*, i32, i32, i32 } %[[r:.*]], 0
// CHECK: %[[cmp0:.*]] = icmp eq i8* %[[lhs0]], %{{.*}}
// CHECK: %{{.*}} = extractvalue { i8*, i32, i32, i32 } %[[l]], 1
// CHECK: %{{.*}} = extractvalue { i8*, i32, i32, i32 } %[[r]], 1
// CHECK: %[[cmp1:.*]] = icmp eq i32
// CHECK: %{{.*}} = extractvalue { i8*, i32, i32, i32 } %[[l]], 2
// CHECK: %{{.*}} = extractvalue { i8*, i32, i32, i32 } %[[r]], 2
// CHECK: %[[cmp2:.*]] = icmp eq i32
// CHECK: %[[res12:.*]] = and i1 %[[cmp1]], %[[cmp2]]
// CHECK: %{{.*}} = extractvalue { i8*, i32, i32, i32 } %[[l]], 3
// CHECK: %{{.*}} = extractvalue { i8*, i32, i32, i32 } %[[r]], 3
// CHECK: %[[cmp3:.*]] = icmp eq i32
// CHECK: %[[res123:.*]] = and i1 %[[res12]], %[[cmp3]]
// CHECK: %[[iszero:.*]] = icmp eq i8* %[[lhs0]], null
// CHECK: %[[bits_or_null:.*]] = or i1 %[[res123]], %[[iszero]]
// CHECK: %{{.*}} = and i1 %[[bits_or_null]], %[[cmp0]]
// CHECK: ret i1 %{{.*}}
// CHECK: }
// X64-LABEL: define dso_local zeroext i1 @"?unspecFuncMemptrEq@@
// X64: ({ i8*, i32, i32, i32 }*, { i8*, i32, i32, i32 }*)
}
bool unspecFuncMemptrNeq(void (Unspecified::*l)(), void (Unspecified::*r)()) {
return l != r;
// CHECK: define dso_local zeroext i1 @"?unspecFuncMemptrNeq@@YA_NP8Unspecified@@AEXXZ0@Z"{{.*}} {
// CHECK: %[[lhs0:.*]] = extractvalue { i8*, i32, i32, i32 } %[[l:.*]], 0
// CHECK: %{{.*}} = extractvalue { i8*, i32, i32, i32 } %[[r:.*]], 0
// CHECK: %[[cmp0:.*]] = icmp ne i8* %[[lhs0]], %{{.*}}
// CHECK: %{{.*}} = extractvalue { i8*, i32, i32, i32 } %[[l]], 1
// CHECK: %{{.*}} = extractvalue { i8*, i32, i32, i32 } %[[r]], 1
// CHECK: %[[cmp1:.*]] = icmp ne i32
// CHECK: %{{.*}} = extractvalue { i8*, i32, i32, i32 } %[[l]], 2
// CHECK: %{{.*}} = extractvalue { i8*, i32, i32, i32 } %[[r]], 2
// CHECK: %[[cmp2:.*]] = icmp ne i32
// CHECK: %[[res12:.*]] = or i1 %[[cmp1]], %[[cmp2]]
// CHECK: %{{.*}} = extractvalue { i8*, i32, i32, i32 } %[[l]], 3
// CHECK: %{{.*}} = extractvalue { i8*, i32, i32, i32 } %[[r]], 3
// CHECK: %[[cmp3:.*]] = icmp ne i32
// CHECK: %[[res123:.*]] = or i1 %[[res12]], %[[cmp3]]
// CHECK: %[[iszero:.*]] = icmp ne i8* %[[lhs0]], null
// CHECK: %[[bits_or_null:.*]] = and i1 %[[res123]], %[[iszero]]
// CHECK: %{{.*}} = or i1 %[[bits_or_null]], %[[cmp0]]
// CHECK: ret i1 %{{.*}}
// CHECK: }
}
bool unspecDataMemptrEq(int Unspecified::*l, int Unspecified::*r) {
return l == r;
// CHECK: define dso_local zeroext i1 @"?unspecDataMemptrEq@@YA_NPQUnspecified@@H0@Z"{{.*}} {
// CHECK: extractvalue { i32, i32, i32 } %{{.*}}, 0
// CHECK: extractvalue { i32, i32, i32 } %{{.*}}, 0
// CHECK: icmp eq i32
// CHECK: extractvalue { i32, i32, i32 } %{{.*}}, 1
// CHECK: extractvalue { i32, i32, i32 } %{{.*}}, 1
// CHECK: icmp eq i32
// CHECK: extractvalue { i32, i32, i32 } %{{.*}}, 2
// CHECK: extractvalue { i32, i32, i32 } %{{.*}}, 2
// CHECK: icmp eq i32
// CHECK: and i1
// CHECK: and i1
// CHECK: ret i1
// CHECK: }
// X64-LABEL: define dso_local zeroext i1 @"?unspecDataMemptrEq@@
// X64: ({ i32, i32, i32 }*, { i32, i32, i32 }*)
}
void (Multiple::*convertB2FuncToMultiple(void (B2::*mp)()))() {
return mp;
// CHECK: define dso_local i64 @"?convertB2FuncToMultiple@@YAP8Multiple@@AEXXZP8B2@@AEXXZ@Z"{{.*}} {
// CHECK: store
// CHECK: %[[mp:.*]] = load i8*, i8** %{{.*}}, align 4
// CHECK: icmp ne i8* %[[mp]], null
// CHECK: br i1 %{{.*}} label %{{.*}}, label %{{.*}}
//
// memptr.convert: ; preds = %entry
// CHECK: insertvalue { i8*, i32 } undef, i8* %[[mp]], 0
// CHECK: insertvalue { i8*, i32 } %{{.*}}, i32 4, 1
// CHECK: br label
//
// memptr.converted: ; preds = %memptr.convert, %entry
// CHECK: phi { i8*, i32 } [ zeroinitializer, %{{.*}} ], [ {{.*}} ]
// CHECK: }
}
void (B2::*convertMultipleFuncToB2(void (Multiple::*mp)()))() {
// FIXME: cl emits warning C4407 on this code because of the representation
// change. We might want to do the same.
return static_cast<void (B2::*)()>(mp);
// FIXME: We should return i8* instead of i32 here. The ptrtoint cast prevents
// LLVM from optimizing away the branch. This is likely a bug in
// lib/CodeGen/TargetInfo.cpp with how we classify memptr types for returns.
//
// CHECK: define dso_local i32 @"?convertMultipleFuncToB2@@YAP8B2@@AEXXZP8Multiple@@AEXXZ@Z"{{.*}} {
// CHECK: store
// CHECK: %[[src:.*]] = load { i8*, i32 }, { i8*, i32 }* %{{.*}}, align 4
// CHECK: extractvalue { i8*, i32 } %[[src]], 0
// CHECK: icmp ne i8* %{{.*}}, null
// CHECK: br i1 %{{.*}}, label %{{.*}}, label %{{.*}}
//
// memptr.convert: ; preds = %entry
// CHECK: %[[fp:.*]] = extractvalue { i8*, i32 } %[[src]], 0
// CHECK: br label
//
// memptr.converted: ; preds = %memptr.convert, %entry
// CHECK: phi i8* [ null, %{{.*}} ], [ %[[fp]], %{{.*}} ]
// CHECK: }
}
namespace Test1 {
struct A { int a; };
struct B { int b; };
struct C : virtual A { int c; };
struct D : B, C { int d; };
void (D::*convertCToD(void (C::*mp)()))() {
return mp;
// CHECK: define dso_local void @"?convertCToD@Test1@@YAP8D@1@AEXXZP8C@1@AEXXZ@Z"{{.*}} {
// CHECK: store
// CHECK: load { i8*, i32, i32 }, { i8*, i32, i32 }* %{{.*}}, align 4
// CHECK: extractvalue { i8*, i32, i32 } %{{.*}}, 0
// CHECK: icmp ne i8* %{{.*}}, null
// CHECK: br i1 %{{.*}}, label %{{.*}}, label %{{.*}}
//
// memptr.convert: ; preds = %entry
// CHECK: extractvalue { i8*, i32, i32 } %{{.*}}, 0
[MS ABI] Rework member pointer conversion Member pointers in the MS ABI are made complicated due to the following: - Virtual methods in the most derived class (MDC) might live in a vftable in a virtual base. - There are four different representations of member pointer: single inheritance, multiple inheritance, virtual inheritance and the "most general" representation. - Bases might have a *more* general representation than classes which derived from them, a most surprising result. We believed that we could treat all member pointers as-if they were a degenerate case of the multiple inheritance model. This fell apart once we realized that implementing standard member pointers using this ABI requires referencing members with a non-zero vbindex. On a bright note, all but the virtual inheritance model operate rather similarly. The virtual inheritance member pointer representation awkwardly requires a virtual base adjustment in order to refer to entities in the MDC. However, the first virtual base might be quite far from the start of the virtual base. This means that we must add a negative non-virtual displacement. However, things get even more complicated. The most general representation interprets vbindex zero differently from the virtual inheritance model: it doesn't reference the vbtable at all. It turns out that this complexity can increase for quite some time: consider a derived to base conversion from the most general model to the multiple inheritance model... To manage this complexity we introduce a concept of "normalized" member pointer which allows us to treat all three models as the most general model. Then we try to figure out how to map this generalized member pointer onto the destination member pointer model. I've done my best to furnish the code with comments explaining why each adjustment is performed. This fixes PR23878. llvm-svn: 240384
2015-06-23 15:31:11 +08:00
// CHECK: %[[nvoff:.*]] = extractvalue { i8*, i32, i32 } %{{.*}}, 1
// CHECK: %[[vbidx:.*]] = extractvalue { i8*, i32, i32 } %{{.*}}, 2
// CHECK: %[[is_nvbase:.*]] = icmp eq i32 %[[vbidx]], 0
// CHECK: %[[nv_disp:.*]] = add nsw i32 %[[nvoff]], 4
// CHECK: %[[nv_adj:.*]] = select i1 %[[is_nvbase]], i32 %[[nv_disp]], i32 0
// CHECK: %[[dst_adj:.*]] = select i1 %[[is_nvbase]], i32 4, i32 0
// CHECK: %[[adj:.*]] = sub nsw i32 %[[nv_adj]], %[[dst_adj]]
// CHECK: insertvalue { i8*, i32, i32 } undef, i8* {{.*}}, 0
// CHECK: insertvalue { i8*, i32, i32 } {{.*}}, i32 %[[adj]], 1
// CHECK: insertvalue { i8*, i32, i32 } {{.*}}, i32 {{.*}}, 2
// CHECK: br label
//
// memptr.converted: ; preds = %memptr.convert, %entry
// CHECK: phi { i8*, i32, i32 } [ { i8* null, i32 0, i32 -1 }, {{.*}} ], [ {{.*}} ]
// CHECK: }
}
}
namespace Test2 {
// Test that we dynamically convert between different null reps.
struct A { int a; };
struct B : A { int b; };
struct C : A {
int c;
virtual void hasVfPtr();
};
int A::*reinterpret(int B::*mp) {
return reinterpret_cast<int A::*>(mp);
// CHECK: define dso_local i32 @"?reinterpret@Test2@@YAPQA@1@HPQB@1@H@Z"{{.*}} {
// CHECK-NOT: select
// CHECK: ret i32
// CHECK: }
}
int A::*reinterpret(int C::*mp) {
return reinterpret_cast<int A::*>(mp);
// CHECK: define dso_local i32 @"?reinterpret@Test2@@YAPQA@1@HPQC@1@H@Z"{{.*}} {
// CHECK: %[[mp:.*]] = load i32, i32*
// CHECK: %[[cmp:.*]] = icmp ne i32 %[[mp]], 0
// CHECK: select i1 %[[cmp]], i32 %[[mp]], i32 -1
// CHECK: }
}
}
namespace Test3 {
// Make sure we cast 'this' to i8* before using GEP.
struct A {
int a;
int b;
};
int *load_data(A *a, int A::*mp) {
return &(a->*mp);
// CHECK-LABEL: define dso_local i32* @"?load_data@Test3@@YAPAHPAUA@1@PQ21@H@Z"{{.*}} {
// CHECK: %[[a:.*]] = load %"struct.Test3::A"*, %"struct.Test3::A"** %{{.*}}, align 4
// CHECK: %[[mp:.*]] = load i32, i32* %{{.*}}, align 4
// CHECK: %[[a_i8:.*]] = bitcast %"struct.Test3::A"* %[[a]] to i8*
// CHECK: getelementptr inbounds i8, i8* %[[a_i8]], i32 %[[mp]]
// CHECK: }
}
}
namespace Test4 {
struct A { virtual void f(); };
struct B { virtual void g(); };
struct C : A, B { virtual void g(); };
void (C::*getmp())() {
return &C::g;
}
// CHECK-LABEL: define dso_local i64 @"?getmp@Test4@@YAP8C@1@AEXXZXZ"()
// CHECK: store { i8*, i32 } { i8* bitcast (void (%"struct.Test4::C"*, ...)* @"??_9C@Test4@@$BA@AE" to i8*), i32 4 }, { i8*, i32 }* %{{.*}}
//
// CHECK-LABEL: define linkonce_odr x86_thiscallcc void @"??_9C@Test4@@$BA@AE"(%"struct.Test4::C"* %this, ...) {{.*}} comdat
// CHECK-NOT: getelementptr
// CHECK: load void (%"struct.Test4::C"*, ...)**, void (%"struct.Test4::C"*, ...)*** %{{.*}}
// CHECK: getelementptr inbounds void (%"struct.Test4::C"*, ...)*, void (%"struct.Test4::C"*, ...)** %{{.*}}, i64 0
// CHECK-NOT: getelementptr
// CHECK: musttail call x86_thiscallcc void (%"struct.Test4::C"*, ...) %
}
namespace pr20007 {
struct A {
void f();
void f(int);
};
struct B : public A {};
void test() { void (B::*a)() = &B::f; }
// CHECK-LABEL: define dso_local void @"?test@pr20007@@YAXXZ"
// CHECK: store i8* bitcast (void (%"struct.pr20007::A"*)* @"?f@A@pr20007@@QAEXXZ" to i8*)
}
namespace pr20007_kw {
struct A {
void f();
void f(int);
};
struct __single_inheritance B;
struct B : public A {};
void test() { void (B::*a)() = &B::f; }
// CHECK-LABEL: define dso_local void @"?test@pr20007_kw@@YAXXZ"
// CHECK: store i8* bitcast (void (%"struct.pr20007_kw::A"*)* @"?f@A@pr20007_kw@@QAEXXZ" to i8*)
}
namespace pr20007_pragma {
struct A {
void f();
void f(int);
};
struct B : public A {};
void test() { (void)(void (B::*)()) &B::f; }
#pragma pointers_to_members(full_generality, virtual_inheritance)
static_assert(sizeof(int B::*) == 4, "");
static_assert(sizeof(int A::*) == 4, "");
#pragma pointers_to_members(best_case)
// CHECK-LABEL: define dso_local void @"?test@pr20007_pragma@@YAXXZ"
}
namespace pr20007_pragma2 {
struct A {
};
struct B : public A {
void f();
};
void test() { (void)&B::f; }
#pragma pointers_to_members(full_generality, virtual_inheritance)
static_assert(sizeof(int B::*) == 4, "");
static_assert(sizeof(int A::*) == 12, "");
#pragma pointers_to_members(best_case)
// CHECK-LABEL: define dso_local void @"?test@pr20007_pragma2@@YAXXZ"
}
namespace pr23823 {
struct Base { void Method(); };
struct Child : Base {};
void use(void (Child::*const &)());
void f() { use(&Child::Method); }
#pragma pointers_to_members(full_generality, virtual_inheritance)
static_assert(sizeof(int Base::*) == 4, "");
static_assert(sizeof(int Child::*) == 4, "");
#pragma pointers_to_members(best_case)
}
namespace pr19987 {
template <typename T>
struct S {
int T::*x;
};
struct U : S<U> {};
static_assert(sizeof(S<U>::x) == 12, "");
}
#else
struct __virtual_inheritance A;
#ifdef MEMFUN
int foo(A *a, int (A::*mp)()) {
return (a->*mp)(); // expected-error{{requires a complete class type}}
}
#else
int foo(A *a, int A::*mp) {
return a->*mp; // expected-error{{requires a complete class type}}
}
#endif
#endif
[MS ABI] Rework member pointer conversion Member pointers in the MS ABI are made complicated due to the following: - Virtual methods in the most derived class (MDC) might live in a vftable in a virtual base. - There are four different representations of member pointer: single inheritance, multiple inheritance, virtual inheritance and the "most general" representation. - Bases might have a *more* general representation than classes which derived from them, a most surprising result. We believed that we could treat all member pointers as-if they were a degenerate case of the multiple inheritance model. This fell apart once we realized that implementing standard member pointers using this ABI requires referencing members with a non-zero vbindex. On a bright note, all but the virtual inheritance model operate rather similarly. The virtual inheritance member pointer representation awkwardly requires a virtual base adjustment in order to refer to entities in the MDC. However, the first virtual base might be quite far from the start of the virtual base. This means that we must add a negative non-virtual displacement. However, things get even more complicated. The most general representation interprets vbindex zero differently from the virtual inheritance model: it doesn't reference the vbtable at all. It turns out that this complexity can increase for quite some time: consider a derived to base conversion from the most general model to the multiple inheritance model... To manage this complexity we introduce a concept of "normalized" member pointer which allows us to treat all three models as the most general model. Then we try to figure out how to map this generalized member pointer onto the destination member pointer model. I've done my best to furnish the code with comments explaining why each adjustment is performed. This fixes PR23878. llvm-svn: 240384
2015-06-23 15:31:11 +08:00
namespace pr23878 {
struct A { virtual void g(); };
struct B { virtual void f(); };
struct C : virtual B { void f(); };
struct D : A, C {};
typedef void (D::*DMemPtrTy)();
// CHECK-LABEL: define dso_local void @"?get_memptr@pr23878@@YAP8D@1@AEXXZXZ"
// CHECK: @"??_9C@pr23878@@$BA@AE" to i8*), i32 0, i32 4
[MS ABI] Rework member pointer conversion Member pointers in the MS ABI are made complicated due to the following: - Virtual methods in the most derived class (MDC) might live in a vftable in a virtual base. - There are four different representations of member pointer: single inheritance, multiple inheritance, virtual inheritance and the "most general" representation. - Bases might have a *more* general representation than classes which derived from them, a most surprising result. We believed that we could treat all member pointers as-if they were a degenerate case of the multiple inheritance model. This fell apart once we realized that implementing standard member pointers using this ABI requires referencing members with a non-zero vbindex. On a bright note, all but the virtual inheritance model operate rather similarly. The virtual inheritance member pointer representation awkwardly requires a virtual base adjustment in order to refer to entities in the MDC. However, the first virtual base might be quite far from the start of the virtual base. This means that we must add a negative non-virtual displacement. However, things get even more complicated. The most general representation interprets vbindex zero differently from the virtual inheritance model: it doesn't reference the vbtable at all. It turns out that this complexity can increase for quite some time: consider a derived to base conversion from the most general model to the multiple inheritance model... To manage this complexity we introduce a concept of "normalized" member pointer which allows us to treat all three models as the most general model. Then we try to figure out how to map this generalized member pointer onto the destination member pointer model. I've done my best to furnish the code with comments explaining why each adjustment is performed. This fixes PR23878. llvm-svn: 240384
2015-06-23 15:31:11 +08:00
DMemPtrTy get_memptr() { return &D::f; }
}
class C {};
typedef void (C::*f)();
class CA : public C {
public:
void OnHelp(void);
int OnHelp(int);
};
// CHECK-LABEL: foo_fun
void foo_fun() {
// CHECK: store i8* bitcast (void (%class.CA*)* @"?OnHelp@CA@@QAEXXZ" to i8*), i8**
f func = (f)&CA::OnHelp;
}
namespace PR24703 {
struct S;
void f(int S::*&p) {}
// CHECK-LABEL: define dso_local void @"?f@PR24703@@YAXAAPQS@1@H@Z"(
}
namespace ReferenceToMPTWithIncompleteClass {
struct S;
struct J;
struct K;
extern K *k;
// CHECK-LABEL: @"?f@ReferenceToMPTWithIncompleteClass@@YAIAAPQS@1@H@Z"(
// CHECK: ret i32 12
unsigned f(int S::*&p) { return sizeof p; }
// CHECK-LABEL: @"?g@ReferenceToMPTWithIncompleteClass@@YA_NAAPQJ@1@H0@Z"(
bool g(int J::*&p, int J::*&q) { return p == q; }
// CHECK-LABEL: @"?h@ReferenceToMPTWithIncompleteClass@@YAHAAPQK@1@H@Z"(
int h(int K::*&p) { return k->*p; }
}
namespace PMFInTemplateArgument {
template <class C, int (C::*M)(int)>
void JSMethod();
class A {
int printd(int);
void printd();
};
void A::printd() { JSMethod<A, &A::printd>(); }
// CHECK-LABEL: @"??$JSMethod@VA@PMFInTemplateArgument@@$1?printd@12@AAEHH@Z@PMFInTemplateArgument@@YAXXZ"(
}