llvm-project/clang/test/CodeGenCXX/catch-undef-behavior.cpp

376 lines
12 KiB
C++

// RUN: %clang_cc1 -std=c++11 -fsanitize=signed-integer-overflow,integer-divide-by-zero,float-divide-by-zero,shift,unreachable,return,vla-bound,alignment,null,vptr,object-size,float-cast-overflow,bool,enum,bounds -emit-llvm %s -o - -triple x86_64-linux-gnu | FileCheck %s
struct S {
double d;
int a, b;
virtual int f();
};
struct T : S {};
// CHECK: @_Z17reference_binding
void reference_binding(int *p, S *q) {
// C++ core issue 453: If an lvalue to which a reference is directly bound
// designates neither an existing object or function of an appropriate type,
// nor a region of storage of suitable size and alignment to contain an object
// of the reference's type, the behavior is undefined.
// CHECK: icmp ne {{.*}}, null
// CHECK: %[[SIZE:.*]] = call i64 @llvm.objectsize.i64
// CHECK-NEXT: icmp uge i64 %[[SIZE]], 4
// CHECK: %[[PTRINT:.*]] = ptrtoint
// CHECK-NEXT: %[[MISALIGN:.*]] = and i64 %[[PTRINT]], 3
// CHECK-NEXT: icmp eq i64 %[[MISALIGN]], 0
int &r = *p;
// A reference is not required to refer to an object within its lifetime.
// CHECK-NOT: __ubsan_handle_dynamic_type_cache_miss
S &r2 = *q;
}
// CHECK: @_Z13member_access
void member_access(S *p) {
// (1a) Check 'p' is appropriately sized and aligned for member access.
// CHECK: icmp ne {{.*}}, null
// CHECK: %[[SIZE:.*]] = call i64 @llvm.objectsize.i64
// CHECK-NEXT: icmp uge i64 %[[SIZE]], 24
// CHECK: %[[PTRINT:.*]] = ptrtoint
// CHECK-NEXT: %[[MISALIGN:.*]] = and i64 %[[PTRINT]], 7
// CHECK-NEXT: icmp eq i64 %[[MISALIGN]], 0
// (1b) Check that 'p' actually points to an 'S'.
// CHECK: %[[VPTRADDR:.*]] = bitcast {{.*}} to i64*
// CHECK-NEXT: %[[VPTR:.*]] = load i64* %[[VPTRADDR]]
//
// hash_16_bytes:
//
// If this number changes, it indicates that either the mangled name of ::S
// has changed, or that LLVM's hashing function has changed. The latter case
// is OK if the hashing function is still stable.
//
// The two hash values are for 64- and 32-bit Clang binaries, respectively.
// FIXME: We should produce a 64-bit value either way.
//
// CHECK-NEXT: xor i64 {{-4030275160588942838|2562089159}}, %[[VPTR]]
// CHECK-NEXT: mul i64 {{.*}}, -7070675565921424023
// CHECK-NEXT: lshr i64 {{.*}}, 47
// CHECK-NEXT: xor i64
// CHECK-NEXT: xor i64 %[[VPTR]]
// CHECK-NEXT: mul i64 {{.*}}, -7070675565921424023
// CHECK-NEXT: lshr i64 {{.*}}, 47
// CHECK-NEXT: xor i64
// CHECK-NEXT: %[[HASH:.*]] = mul i64 {{.*}}, -7070675565921424023
//
// Check the hash against the table:
//
// CHECK-NEXT: %[[IDX:.*]] = and i64 %{{.*}}, 127
// CHECK-NEXT: getelementptr inbounds [128 x i64]* @__ubsan_vptr_type_cache, i32 0, i64 %[[IDX]]
// CHECK-NEXT: %[[CACHEVAL:.*]] = load i64*
// CHECK-NEXT: icmp eq i64 %[[CACHEVAL]], %[[HASH]]
// CHECK-NEXT: br i1
// CHECK: call void @__ubsan_handle_dynamic_type_cache_miss({{.*}}, i64 %{{.*}}, i64 %[[HASH]])
// CHECK-NOT: unreachable
// CHECK: {{.*}}:
// (2) Check 'p->b' is appropriately sized and aligned for a load.
// FIXME: Suppress this in the trivial case of a member access, because we
// know we've just checked the member access expression itself.
// CHECK: %[[SIZE:.*]] = call i64 @llvm.objectsize.i64
// CHECK-NEXT: icmp uge i64 %[[SIZE]], 4
// CHECK: %[[PTRINT:.*]] = ptrtoint
// CHECK-NEXT: %[[MISALIGN:.*]] = and i64 %[[PTRINT]], 3
// CHECK-NEXT: icmp eq i64 %[[MISALIGN]], 0
int k = p->b;
// (3a) Check 'p' is appropriately sized and aligned for member function call.
// CHECK: icmp ne {{.*}}, null
// CHECK: %[[SIZE:.*]] = call i64 @llvm.objectsize.i64
// CHECK-NEXT: icmp uge i64 %[[SIZE]], 24
// CHECK: %[[PTRINT:.*]] = ptrtoint
// CHECK-NEXT: %[[MISALIGN:.*]] = and i64 %[[PTRINT]], 7
// CHECK-NEXT: icmp eq i64 %[[MISALIGN]], 0
// (3b) Check that 'p' actually points to an 'S'
// CHECK: load i64*
// CHECK-NEXT: xor i64 {{-4030275160588942838|2562089159}},
// [...]
// CHECK: getelementptr inbounds [128 x i64]* @__ubsan_vptr_type_cache, i32 0, i64 %
// CHECK: br i1
// CHECK: call void @__ubsan_handle_dynamic_type_cache_miss({{.*}}, i64 %{{.*}}, i64 %{{.*}})
// CHECK-NOT: unreachable
// CHECK: {{.*}}:
k = p->f();
}
// CHECK: @_Z12lsh_overflow
int lsh_overflow(int a, int b) {
// CHECK: %[[INBOUNDS:.*]] = icmp ule i32 %[[RHS:.*]], 31
// CHECK-NEXT: br i1 %[[INBOUNDS]]
// CHECK: %[[SHIFTED_OUT_WIDTH:.*]] = sub nuw nsw i32 31, %[[RHS]]
// CHECK-NEXT: %[[SHIFTED_OUT:.*]] = lshr i32 %[[LHS:.*]], %[[SHIFTED_OUT_WIDTH]]
// This is present for C++11 but not for C: C++ core issue 1457 allows a '1'
// to be shifted into the sign bit, but not out of it.
// CHECK-NEXT: %[[SHIFTED_OUT_NOT_SIGN:.*]] = lshr i32 %[[SHIFTED_OUT]], 1
// CHECK-NEXT: %[[NO_OVERFLOW:.*]] = icmp eq i32 %[[SHIFTED_OUT_NOT_SIGN]], 0
// CHECK: %[[VALID:.*]] = phi i1 [ %[[INBOUNDS]], {{.*}} ], [ %[[NO_OVERFLOW]], {{.*}} ]
// CHECK-NEXT: br i1 %[[VALID]]
// CHECK: call void @__ubsan_handle_shift_out_of_bounds
// CHECK-NOT: call void @__ubsan_handle_shift_out_of_bounds
// CHECK: %[[RET:.*]] = shl i32 %[[LHS]], %[[RHS]]
// CHECK-NEXT: ret i32 %[[RET]]
return a << b;
}
// CHECK: @_Z9no_return
int no_return() {
// CHECK: call void @__ubsan_handle_missing_return(i8* bitcast ({{.*}}* @{{.*}} to i8*)) [[NR_NUW:#[0-9]+]]
// CHECK-NEXT: unreachable
}
// CHECK: @_Z9sour_bool
bool sour_bool(bool *p) {
// CHECK: %[[OK:.*]] = icmp ule i8 {{.*}}, 1
// CHECK: br i1 %[[OK]]
// CHECK: call void @__ubsan_handle_load_invalid_value(i8* bitcast ({{.*}}), i64 {{.*}})
return *p;
}
enum E1 { e1a = 0, e1b = 127 } e1;
enum E2 { e2a = -1, e2b = 64 } e2;
enum E3 { e3a = (1u << 31) - 1 } e3;
// CHECK: @_Z14bad_enum_value
int bad_enum_value() {
// CHECK: %[[E1:.*]] = icmp ule i32 {{.*}}, 127
// CHECK: br i1 %[[E1]]
// CHECK: call void @__ubsan_handle_load_invalid_value(
int a = e1;
// CHECK: %[[E2HI:.*]] = icmp sle i32 {{.*}}, 127
// CHECK: %[[E2LO:.*]] = icmp sge i32 {{.*}}, -128
// CHECK: %[[E2:.*]] = and i1 %[[E2HI]], %[[E2LO]]
// CHECK: br i1 %[[E2]]
// CHECK: call void @__ubsan_handle_load_invalid_value(
int b = e2;
// CHECK: %[[E3:.*]] = icmp ule i32 {{.*}}, 2147483647
// CHECK: br i1 %[[E3]]
// CHECK: call void @__ubsan_handle_load_invalid_value(
int c = e3;
return a + b + c;
}
// CHECK: @_Z20bad_downcast_pointer
void bad_downcast_pointer(S *p) {
// CHECK: %[[NONNULL:.*]] = icmp ne {{.*}}, null
// CHECK: br i1 %[[NONNULL]],
// CHECK: %[[SIZE:.*]] = call i64 @llvm.objectsize.i64(
// CHECK: %[[E1:.*]] = icmp uge i64 %[[SIZE]], 24
// CHECK: %[[MISALIGN:.*]] = and i64 %{{.*}}, 7
// CHECK: %[[E2:.*]] = icmp eq i64 %[[MISALIGN]], 0
// CHECK: %[[E12:.*]] = and i1 %[[E1]], %[[E2]]
// CHECK: br i1 %[[E12]],
// CHECK: call void @__ubsan_handle_type_mismatch
// CHECK: br label
// CHECK: br i1 %{{.*}},
// CHECK: call void @__ubsan_handle_dynamic_type_cache_miss
// CHECK: br label
(void) static_cast<T*>(p);
}
// CHECK: @_Z22bad_downcast_reference
void bad_downcast_reference(S &p) {
// CHECK: %[[E1:.*]] = icmp ne {{.*}}, null
// CHECK-NOT: br i1
// CHECK: %[[SIZE:.*]] = call i64 @llvm.objectsize.i64(
// CHECK: %[[E2:.*]] = icmp uge i64 %[[SIZE]], 24
// CHECK: %[[E12:.*]] = and i1 %[[E1]], %[[E2]]
// CHECK: %[[MISALIGN:.*]] = and i64 %{{.*}}, 7
// CHECK: %[[E3:.*]] = icmp eq i64 %[[MISALIGN]], 0
// CHECK: %[[E123:.*]] = and i1 %[[E12]], %[[E3]]
// CHECK: br i1 %[[E123]],
// CHECK: call void @__ubsan_handle_type_mismatch
// CHECK: br label
// CHECK: br i1 %{{.*}},
// CHECK: call void @__ubsan_handle_dynamic_type_cache_miss
// CHECK: br label
(void) static_cast<T&>(p);
}
// CHECK: @_Z11array_index
int array_index(const int (&a)[4], int n) {
// CHECK: %[[K1_OK:.*]] = icmp ult i64 %{{.*}}, 4
// CHECK: br i1 %[[K1_OK]]
// CHECK: call void @__ubsan_handle_out_of_bounds(
int k1 = a[n];
// CHECK: %[[R1_OK:.*]] = icmp ule i64 %{{.*}}, 4
// CHECK: br i1 %[[R1_OK]]
// CHECK: call void @__ubsan_handle_out_of_bounds(
const int *r1 = &a[n];
// CHECK: %[[K2_OK:.*]] = icmp ult i64 %{{.*}}, 8
// CHECK: br i1 %[[K2_OK]]
// CHECK: call void @__ubsan_handle_out_of_bounds(
int k2 = ((const int(&)[8])a)[n];
// CHECK: %[[K3_OK:.*]] = icmp ult i64 %{{.*}}, 4
// CHECK: br i1 %[[K3_OK]]
// CHECK: call void @__ubsan_handle_out_of_bounds(
int k3 = n[a];
return k1 + *r1 + k2;
}
// CHECK: @_Z17multi_array_index
int multi_array_index(int n, int m) {
int arr[4][6];
// CHECK: %[[IDX2_OK:.*]] = icmp ult i64 %{{.*}}, 6
// CHECK: br i1 %[[IDX2_OK]]
// CHECK: call void @__ubsan_handle_out_of_bounds(
// CHECK: %[[IDX1_OK:.*]] = icmp ult i64 %{{.*}}, 4
// CHECK: br i1 %[[IDX1_OK]]
// CHECK: call void @__ubsan_handle_out_of_bounds(
return arr[n][m];
}
// CHECK: @_Z11array_arith
int array_arith(const int (&a)[4], int n) {
// CHECK: %[[K1_OK:.*]] = icmp ule i64 %{{.*}}, 4
// CHECK: br i1 %[[K1_OK]]
// CHECK: call void @__ubsan_handle_out_of_bounds(
const int *k1 = a + n;
// CHECK: %[[K2_OK:.*]] = icmp ule i64 %{{.*}}, 8
// CHECK: br i1 %[[K2_OK]]
// CHECK: call void @__ubsan_handle_out_of_bounds(
const int *k2 = (const int(&)[8])a + n;
return *k1 + *k2;
}
struct ArrayMembers {
int a1[5];
int a2[1];
};
// CHECK: @_Z18struct_array_index
int struct_array_index(ArrayMembers *p, int n) {
// CHECK: %[[IDX_OK:.*]] = icmp ult i64 %{{.*}}, 5
// CHECK: br i1 %[[IDX_OK]]
// CHECK: call void @__ubsan_handle_out_of_bounds(
return p->a1[n];
}
// CHECK: @_Z16flex_array_index
int flex_array_index(ArrayMembers *p, int n) {
// CHECK-NOT: call void @__ubsan_handle_out_of_bounds(
return p->a2[n];
}
extern int incomplete[];
// CHECK: @_Z22incomplete_array_index
int incomplete_array_index(int n) {
// CHECK-NOT: call void @__ubsan_handle_out_of_bounds(
return incomplete[n];
}
typedef __attribute__((ext_vector_type(4))) int V4I;
// CHECK: @_Z12vector_index
int vector_index(V4I v, int n) {
// CHECK: %[[IDX_OK:.*]] = icmp ult i64 %{{.*}}, 4
// CHECK: br i1 %[[IDX_OK]]
// CHECK: call void @__ubsan_handle_out_of_bounds(
return v[n];
}
// CHECK: @_Z12string_index
char string_index(int n) {
// CHECK: %[[IDX_OK:.*]] = icmp ult i64 %{{.*}}, 6
// CHECK: br i1 %[[IDX_OK]]
// CHECK: call void @__ubsan_handle_out_of_bounds(
return "Hello"[n];
}
class A // align=4
{
int a1, a2, a3;
};
class B // align=8
{
long b1, b2;
};
class C : public A, public B // align=16
{
alignas(16) int c1;
};
// Make sure we check the alignment of the pointer after subtracting any
// offset. The pointer before subtraction doesn't need to be aligned for
// the destination type.
// CHECK-LABEL-LABEL: define void @_Z16downcast_pointerP1B(%class.B* %b)
void downcast_pointer(B *b) {
(void) static_cast<C*>(b);
// Alignment check from EmitTypeCheck(TCK_DowncastPointer, ...)
// CHECK: [[SUB:%[.a-z0-9]*]] = getelementptr i8* {{.*}}, i64 -16
// CHECK-NEXT: [[C:%[0-9]*]] = bitcast i8* [[SUB]] to %class.C*
// null check goes here
// CHECK: [[FROM_PHI:%[0-9]*]] = phi %class.C* [ [[C]], {{.*}} ], {{.*}}
// Objectsize check goes here
// CHECK: [[C_INT:%[0-9]*]] = ptrtoint %class.C* [[FROM_PHI]] to i64
// CHECK-NEXT: [[MASKED:%[0-9]*]] = and i64 [[C_INT]], 15
// CHECK-NEXT: [[TEST:%[0-9]*]] = icmp eq i64 [[MASKED]], 0
// AND the alignment test with the objectsize test.
// CHECK-NEXT: [[AND:%[0-9]*]] = and i1 {{.*}}, [[TEST]]
// CHECK-NEXT: br i1 [[AND]]
}
// CHECK-LABEL-LABEL: define void @_Z18downcast_referenceR1B(%class.B* %b)
void downcast_reference(B &b) {
(void) static_cast<C&>(b);
// Alignment check from EmitTypeCheck(TCK_DowncastReference, ...)
// CHECK: [[SUB:%[.a-z0-9]*]] = getelementptr i8* {{.*}}, i64 -16
// CHECK-NEXT: [[C:%[0-9]*]] = bitcast i8* [[SUB]] to %class.C*
// Objectsize check goes here
// CHECK: [[C_INT:%[0-9]*]] = ptrtoint %class.C* [[C]] to i64
// CHECK-NEXT: [[MASKED:%[0-9]*]] = and i64 [[C_INT]], 15
// CHECK-NEXT: [[TEST:%[0-9]*]] = icmp eq i64 [[MASKED]], 0
// AND the alignment test with the objectsize test.
// CHECK-NEXT: [[AND:%[0-9]*]] = and i1 {{.*}}, [[TEST]]
// CHECK-NEXT: br i1 [[AND]]
}
// CHECK: attributes [[NR_NUW]] = { noreturn nounwind }