llvm-project/compiler-rt/lib/ubsan/ubsan_handlers.cpp
Vedant Kumar 8c4a65b9b2 [ubsan] Check implicit casts in ObjC for-in statements
Check that the implicit cast from `id` used to construct the element
variable in an ObjC for-in statement is valid.

This check is included as part of a new `objc-cast` sanitizer, outside
of the main 'undefined' group, as (IIUC) the behavior it's checking for
is not technically UB.

The check can be extended to cover other kinds of invalid casts in ObjC.

Partially addresses: rdar://12903059, rdar://9542496

Differential Revision: https://reviews.llvm.org/D71491
2020-07-13 15:11:18 -07:00

919 lines
32 KiB
C++

//===-- ubsan_handlers.cpp ------------------------------------------------===//
//
// Part of the LLVM Project, under the Apache License v2.0 with LLVM Exceptions.
// See https://llvm.org/LICENSE.txt for license information.
// SPDX-License-Identifier: Apache-2.0 WITH LLVM-exception
//
//===----------------------------------------------------------------------===//
//
// Error logging entry points for the UBSan runtime.
//
//===----------------------------------------------------------------------===//
#include "ubsan_platform.h"
#if CAN_SANITIZE_UB
#include "ubsan_handlers.h"
#include "ubsan_diag.h"
#include "ubsan_flags.h"
#include "ubsan_monitor.h"
#include "ubsan_value.h"
#include "sanitizer_common/sanitizer_common.h"
using namespace __sanitizer;
using namespace __ubsan;
namespace __ubsan {
bool ignoreReport(SourceLocation SLoc, ReportOptions Opts, ErrorType ET) {
// We are not allowed to skip error report: if we are in unrecoverable
// handler, we have to terminate the program right now, and therefore
// have to print some diagnostic.
//
// Even if source location is disabled, it doesn't mean that we have
// already report an error to the user: some concurrently running
// thread could have acquired it, but not yet printed the report.
if (Opts.FromUnrecoverableHandler)
return false;
return SLoc.isDisabled() || IsPCSuppressed(ET, Opts.pc, SLoc.getFilename());
}
/// Situations in which we might emit a check for the suitability of a
/// pointer or glvalue. Needs to be kept in sync with CodeGenFunction.h in
/// clang.
enum TypeCheckKind {
/// Checking the operand of a load. Must be suitably sized and aligned.
TCK_Load,
/// Checking the destination of a store. Must be suitably sized and aligned.
TCK_Store,
/// Checking the bound value in a reference binding. Must be suitably sized
/// and aligned, but is not required to refer to an object (until the
/// reference is used), per core issue 453.
TCK_ReferenceBinding,
/// Checking the object expression in a non-static data member access. Must
/// be an object within its lifetime.
TCK_MemberAccess,
/// Checking the 'this' pointer for a call to a non-static member function.
/// Must be an object within its lifetime.
TCK_MemberCall,
/// Checking the 'this' pointer for a constructor call.
TCK_ConstructorCall,
/// Checking the operand of a static_cast to a derived pointer type. Must be
/// null or an object within its lifetime.
TCK_DowncastPointer,
/// Checking the operand of a static_cast to a derived reference type. Must
/// be an object within its lifetime.
TCK_DowncastReference,
/// Checking the operand of a cast to a base object. Must be suitably sized
/// and aligned.
TCK_Upcast,
/// Checking the operand of a cast to a virtual base object. Must be an
/// object within its lifetime.
TCK_UpcastToVirtualBase,
/// Checking the value assigned to a _Nonnull pointer. Must not be null.
TCK_NonnullAssign,
/// Checking the operand of a dynamic_cast or a typeid expression. Must be
/// null or an object within its lifetime.
TCK_DynamicOperation
};
const char *TypeCheckKinds[] = {
"load of", "store to", "reference binding to", "member access within",
"member call on", "constructor call on", "downcast of", "downcast of",
"upcast of", "cast to virtual base of", "_Nonnull binding to",
"dynamic operation on"};
}
static void handleTypeMismatchImpl(TypeMismatchData *Data, ValueHandle Pointer,
ReportOptions Opts) {
Location Loc = Data->Loc.acquire();
uptr Alignment = (uptr)1 << Data->LogAlignment;
ErrorType ET;
if (!Pointer)
ET = (Data->TypeCheckKind == TCK_NonnullAssign)
? ErrorType::NullPointerUseWithNullability
: ErrorType::NullPointerUse;
else if (Pointer & (Alignment - 1))
ET = ErrorType::MisalignedPointerUse;
else
ET = ErrorType::InsufficientObjectSize;
// Use the SourceLocation from Data to track deduplication, even if it's
// invalid.
if (ignoreReport(Loc.getSourceLocation(), Opts, ET))
return;
SymbolizedStackHolder FallbackLoc;
if (Data->Loc.isInvalid()) {
FallbackLoc.reset(getCallerLocation(Opts.pc));
Loc = FallbackLoc;
}
ScopedReport R(Opts, Loc, ET);
switch (ET) {
case ErrorType::NullPointerUse:
case ErrorType::NullPointerUseWithNullability:
Diag(Loc, DL_Error, ET, "%0 null pointer of type %1")
<< TypeCheckKinds[Data->TypeCheckKind] << Data->Type;
break;
case ErrorType::MisalignedPointerUse:
Diag(Loc, DL_Error, ET, "%0 misaligned address %1 for type %3, "
"which requires %2 byte alignment")
<< TypeCheckKinds[Data->TypeCheckKind] << (void *)Pointer << Alignment
<< Data->Type;
break;
case ErrorType::InsufficientObjectSize:
Diag(Loc, DL_Error, ET, "%0 address %1 with insufficient space "
"for an object of type %2")
<< TypeCheckKinds[Data->TypeCheckKind] << (void *)Pointer << Data->Type;
break;
default:
UNREACHABLE("unexpected error type!");
}
if (Pointer)
Diag(Pointer, DL_Note, ET, "pointer points here");
}
void __ubsan::__ubsan_handle_type_mismatch_v1(TypeMismatchData *Data,
ValueHandle Pointer) {
GET_REPORT_OPTIONS(false);
handleTypeMismatchImpl(Data, Pointer, Opts);
}
void __ubsan::__ubsan_handle_type_mismatch_v1_abort(TypeMismatchData *Data,
ValueHandle Pointer) {
GET_REPORT_OPTIONS(true);
handleTypeMismatchImpl(Data, Pointer, Opts);
Die();
}
static void handleAlignmentAssumptionImpl(AlignmentAssumptionData *Data,
ValueHandle Pointer,
ValueHandle Alignment,
ValueHandle Offset,
ReportOptions Opts) {
Location Loc = Data->Loc.acquire();
SourceLocation AssumptionLoc = Data->AssumptionLoc.acquire();
ErrorType ET = ErrorType::AlignmentAssumption;
if (ignoreReport(Loc.getSourceLocation(), Opts, ET))
return;
ScopedReport R(Opts, Loc, ET);
uptr RealPointer = Pointer - Offset;
uptr LSB = LeastSignificantSetBitIndex(RealPointer);
uptr ActualAlignment = uptr(1) << LSB;
uptr Mask = Alignment - 1;
uptr MisAlignmentOffset = RealPointer & Mask;
if (!Offset) {
Diag(Loc, DL_Error, ET,
"assumption of %0 byte alignment for pointer of type %1 failed")
<< Alignment << Data->Type;
} else {
Diag(Loc, DL_Error, ET,
"assumption of %0 byte alignment (with offset of %1 byte) for pointer "
"of type %2 failed")
<< Alignment << Offset << Data->Type;
}
if (!AssumptionLoc.isInvalid())
Diag(AssumptionLoc, DL_Note, ET, "alignment assumption was specified here");
Diag(RealPointer, DL_Note, ET,
"%0address is %1 aligned, misalignment offset is %2 bytes")
<< (Offset ? "offset " : "") << ActualAlignment << MisAlignmentOffset;
}
void __ubsan::__ubsan_handle_alignment_assumption(AlignmentAssumptionData *Data,
ValueHandle Pointer,
ValueHandle Alignment,
ValueHandle Offset) {
GET_REPORT_OPTIONS(false);
handleAlignmentAssumptionImpl(Data, Pointer, Alignment, Offset, Opts);
}
void __ubsan::__ubsan_handle_alignment_assumption_abort(
AlignmentAssumptionData *Data, ValueHandle Pointer, ValueHandle Alignment,
ValueHandle Offset) {
GET_REPORT_OPTIONS(true);
handleAlignmentAssumptionImpl(Data, Pointer, Alignment, Offset, Opts);
Die();
}
/// \brief Common diagnostic emission for various forms of integer overflow.
template <typename T>
static void handleIntegerOverflowImpl(OverflowData *Data, ValueHandle LHS,
const char *Operator, T RHS,
ReportOptions Opts) {
SourceLocation Loc = Data->Loc.acquire();
bool IsSigned = Data->Type.isSignedIntegerTy();
ErrorType ET = IsSigned ? ErrorType::SignedIntegerOverflow
: ErrorType::UnsignedIntegerOverflow;
if (ignoreReport(Loc, Opts, ET))
return;
// If this is an unsigned overflow in non-fatal mode, potentially ignore it.
if (!IsSigned && !Opts.FromUnrecoverableHandler &&
flags()->silence_unsigned_overflow)
return;
ScopedReport R(Opts, Loc, ET);
Diag(Loc, DL_Error, ET, "%0 integer overflow: "
"%1 %2 %3 cannot be represented in type %4")
<< (IsSigned ? "signed" : "unsigned") << Value(Data->Type, LHS)
<< Operator << RHS << Data->Type;
}
#define UBSAN_OVERFLOW_HANDLER(handler_name, op, unrecoverable) \
void __ubsan::handler_name(OverflowData *Data, ValueHandle LHS, \
ValueHandle RHS) { \
GET_REPORT_OPTIONS(unrecoverable); \
handleIntegerOverflowImpl(Data, LHS, op, Value(Data->Type, RHS), Opts); \
if (unrecoverable) \
Die(); \
}
UBSAN_OVERFLOW_HANDLER(__ubsan_handle_add_overflow, "+", false)
UBSAN_OVERFLOW_HANDLER(__ubsan_handle_add_overflow_abort, "+", true)
UBSAN_OVERFLOW_HANDLER(__ubsan_handle_sub_overflow, "-", false)
UBSAN_OVERFLOW_HANDLER(__ubsan_handle_sub_overflow_abort, "-", true)
UBSAN_OVERFLOW_HANDLER(__ubsan_handle_mul_overflow, "*", false)
UBSAN_OVERFLOW_HANDLER(__ubsan_handle_mul_overflow_abort, "*", true)
static void handleNegateOverflowImpl(OverflowData *Data, ValueHandle OldVal,
ReportOptions Opts) {
SourceLocation Loc = Data->Loc.acquire();
bool IsSigned = Data->Type.isSignedIntegerTy();
ErrorType ET = IsSigned ? ErrorType::SignedIntegerOverflow
: ErrorType::UnsignedIntegerOverflow;
if (ignoreReport(Loc, Opts, ET))
return;
if (!IsSigned && flags()->silence_unsigned_overflow)
return;
ScopedReport R(Opts, Loc, ET);
if (IsSigned)
Diag(Loc, DL_Error, ET,
"negation of %0 cannot be represented in type %1; "
"cast to an unsigned type to negate this value to itself")
<< Value(Data->Type, OldVal) << Data->Type;
else
Diag(Loc, DL_Error, ET, "negation of %0 cannot be represented in type %1")
<< Value(Data->Type, OldVal) << Data->Type;
}
void __ubsan::__ubsan_handle_negate_overflow(OverflowData *Data,
ValueHandle OldVal) {
GET_REPORT_OPTIONS(false);
handleNegateOverflowImpl(Data, OldVal, Opts);
}
void __ubsan::__ubsan_handle_negate_overflow_abort(OverflowData *Data,
ValueHandle OldVal) {
GET_REPORT_OPTIONS(true);
handleNegateOverflowImpl(Data, OldVal, Opts);
Die();
}
static void handleDivremOverflowImpl(OverflowData *Data, ValueHandle LHS,
ValueHandle RHS, ReportOptions Opts) {
SourceLocation Loc = Data->Loc.acquire();
Value LHSVal(Data->Type, LHS);
Value RHSVal(Data->Type, RHS);
ErrorType ET;
if (RHSVal.isMinusOne())
ET = ErrorType::SignedIntegerOverflow;
else if (Data->Type.isIntegerTy())
ET = ErrorType::IntegerDivideByZero;
else
ET = ErrorType::FloatDivideByZero;
if (ignoreReport(Loc, Opts, ET))
return;
ScopedReport R(Opts, Loc, ET);
switch (ET) {
case ErrorType::SignedIntegerOverflow:
Diag(Loc, DL_Error, ET,
"division of %0 by -1 cannot be represented in type %1")
<< LHSVal << Data->Type;
break;
default:
Diag(Loc, DL_Error, ET, "division by zero");
break;
}
}
void __ubsan::__ubsan_handle_divrem_overflow(OverflowData *Data,
ValueHandle LHS, ValueHandle RHS) {
GET_REPORT_OPTIONS(false);
handleDivremOverflowImpl(Data, LHS, RHS, Opts);
}
void __ubsan::__ubsan_handle_divrem_overflow_abort(OverflowData *Data,
ValueHandle LHS,
ValueHandle RHS) {
GET_REPORT_OPTIONS(true);
handleDivremOverflowImpl(Data, LHS, RHS, Opts);
Die();
}
static void handleShiftOutOfBoundsImpl(ShiftOutOfBoundsData *Data,
ValueHandle LHS, ValueHandle RHS,
ReportOptions Opts) {
SourceLocation Loc = Data->Loc.acquire();
Value LHSVal(Data->LHSType, LHS);
Value RHSVal(Data->RHSType, RHS);
ErrorType ET;
if (RHSVal.isNegative() ||
RHSVal.getPositiveIntValue() >= Data->LHSType.getIntegerBitWidth())
ET = ErrorType::InvalidShiftExponent;
else
ET = ErrorType::InvalidShiftBase;
if (ignoreReport(Loc, Opts, ET))
return;
ScopedReport R(Opts, Loc, ET);
if (ET == ErrorType::InvalidShiftExponent) {
if (RHSVal.isNegative())
Diag(Loc, DL_Error, ET, "shift exponent %0 is negative") << RHSVal;
else
Diag(Loc, DL_Error, ET,
"shift exponent %0 is too large for %1-bit type %2")
<< RHSVal << Data->LHSType.getIntegerBitWidth() << Data->LHSType;
} else {
if (LHSVal.isNegative())
Diag(Loc, DL_Error, ET, "left shift of negative value %0") << LHSVal;
else
Diag(Loc, DL_Error, ET,
"left shift of %0 by %1 places cannot be represented in type %2")
<< LHSVal << RHSVal << Data->LHSType;
}
}
void __ubsan::__ubsan_handle_shift_out_of_bounds(ShiftOutOfBoundsData *Data,
ValueHandle LHS,
ValueHandle RHS) {
GET_REPORT_OPTIONS(false);
handleShiftOutOfBoundsImpl(Data, LHS, RHS, Opts);
}
void __ubsan::__ubsan_handle_shift_out_of_bounds_abort(
ShiftOutOfBoundsData *Data,
ValueHandle LHS,
ValueHandle RHS) {
GET_REPORT_OPTIONS(true);
handleShiftOutOfBoundsImpl(Data, LHS, RHS, Opts);
Die();
}
static void handleOutOfBoundsImpl(OutOfBoundsData *Data, ValueHandle Index,
ReportOptions Opts) {
SourceLocation Loc = Data->Loc.acquire();
ErrorType ET = ErrorType::OutOfBoundsIndex;
if (ignoreReport(Loc, Opts, ET))
return;
ScopedReport R(Opts, Loc, ET);
Value IndexVal(Data->IndexType, Index);
Diag(Loc, DL_Error, ET, "index %0 out of bounds for type %1")
<< IndexVal << Data->ArrayType;
}
void __ubsan::__ubsan_handle_out_of_bounds(OutOfBoundsData *Data,
ValueHandle Index) {
GET_REPORT_OPTIONS(false);
handleOutOfBoundsImpl(Data, Index, Opts);
}
void __ubsan::__ubsan_handle_out_of_bounds_abort(OutOfBoundsData *Data,
ValueHandle Index) {
GET_REPORT_OPTIONS(true);
handleOutOfBoundsImpl(Data, Index, Opts);
Die();
}
static void handleBuiltinUnreachableImpl(UnreachableData *Data,
ReportOptions Opts) {
ErrorType ET = ErrorType::UnreachableCall;
ScopedReport R(Opts, Data->Loc, ET);
Diag(Data->Loc, DL_Error, ET,
"execution reached an unreachable program point");
}
void __ubsan::__ubsan_handle_builtin_unreachable(UnreachableData *Data) {
GET_REPORT_OPTIONS(true);
handleBuiltinUnreachableImpl(Data, Opts);
Die();
}
static void handleMissingReturnImpl(UnreachableData *Data, ReportOptions Opts) {
ErrorType ET = ErrorType::MissingReturn;
ScopedReport R(Opts, Data->Loc, ET);
Diag(Data->Loc, DL_Error, ET,
"execution reached the end of a value-returning function "
"without returning a value");
}
void __ubsan::__ubsan_handle_missing_return(UnreachableData *Data) {
GET_REPORT_OPTIONS(true);
handleMissingReturnImpl(Data, Opts);
Die();
}
static void handleVLABoundNotPositive(VLABoundData *Data, ValueHandle Bound,
ReportOptions Opts) {
SourceLocation Loc = Data->Loc.acquire();
ErrorType ET = ErrorType::NonPositiveVLAIndex;
if (ignoreReport(Loc, Opts, ET))
return;
ScopedReport R(Opts, Loc, ET);
Diag(Loc, DL_Error, ET, "variable length array bound evaluates to "
"non-positive value %0")
<< Value(Data->Type, Bound);
}
void __ubsan::__ubsan_handle_vla_bound_not_positive(VLABoundData *Data,
ValueHandle Bound) {
GET_REPORT_OPTIONS(false);
handleVLABoundNotPositive(Data, Bound, Opts);
}
void __ubsan::__ubsan_handle_vla_bound_not_positive_abort(VLABoundData *Data,
ValueHandle Bound) {
GET_REPORT_OPTIONS(true);
handleVLABoundNotPositive(Data, Bound, Opts);
Die();
}
static bool looksLikeFloatCastOverflowDataV1(void *Data) {
// First field is either a pointer to filename or a pointer to a
// TypeDescriptor.
u8 *FilenameOrTypeDescriptor;
internal_memcpy(&FilenameOrTypeDescriptor, Data,
sizeof(FilenameOrTypeDescriptor));
// Heuristic: For float_cast_overflow, the TypeKind will be either TK_Integer
// (0x0), TK_Float (0x1) or TK_Unknown (0xff). If both types are known,
// adding both bytes will be 0 or 1 (for BE or LE). If it were a filename,
// adding two printable characters will not yield such a value. Otherwise,
// if one of them is 0xff, this is most likely TK_Unknown type descriptor.
u16 MaybeFromTypeKind =
FilenameOrTypeDescriptor[0] + FilenameOrTypeDescriptor[1];
return MaybeFromTypeKind < 2 || FilenameOrTypeDescriptor[0] == 0xff ||
FilenameOrTypeDescriptor[1] == 0xff;
}
static void handleFloatCastOverflow(void *DataPtr, ValueHandle From,
ReportOptions Opts) {
SymbolizedStackHolder CallerLoc;
Location Loc;
const TypeDescriptor *FromType, *ToType;
ErrorType ET = ErrorType::FloatCastOverflow;
if (looksLikeFloatCastOverflowDataV1(DataPtr)) {
auto Data = reinterpret_cast<FloatCastOverflowData *>(DataPtr);
CallerLoc.reset(getCallerLocation(Opts.pc));
Loc = CallerLoc;
FromType = &Data->FromType;
ToType = &Data->ToType;
} else {
auto Data = reinterpret_cast<FloatCastOverflowDataV2 *>(DataPtr);
SourceLocation SLoc = Data->Loc.acquire();
if (ignoreReport(SLoc, Opts, ET))
return;
Loc = SLoc;
FromType = &Data->FromType;
ToType = &Data->ToType;
}
ScopedReport R(Opts, Loc, ET);
Diag(Loc, DL_Error, ET,
"%0 is outside the range of representable values of type %2")
<< Value(*FromType, From) << *FromType << *ToType;
}
void __ubsan::__ubsan_handle_float_cast_overflow(void *Data, ValueHandle From) {
GET_REPORT_OPTIONS(false);
handleFloatCastOverflow(Data, From, Opts);
}
void __ubsan::__ubsan_handle_float_cast_overflow_abort(void *Data,
ValueHandle From) {
GET_REPORT_OPTIONS(true);
handleFloatCastOverflow(Data, From, Opts);
Die();
}
static void handleLoadInvalidValue(InvalidValueData *Data, ValueHandle Val,
ReportOptions Opts) {
SourceLocation Loc = Data->Loc.acquire();
// This check could be more precise if we used different handlers for
// -fsanitize=bool and -fsanitize=enum.
bool IsBool = (0 == internal_strcmp(Data->Type.getTypeName(), "'bool'")) ||
(0 == internal_strncmp(Data->Type.getTypeName(), "'BOOL'", 6));
ErrorType ET =
IsBool ? ErrorType::InvalidBoolLoad : ErrorType::InvalidEnumLoad;
if (ignoreReport(Loc, Opts, ET))
return;
ScopedReport R(Opts, Loc, ET);
Diag(Loc, DL_Error, ET,
"load of value %0, which is not a valid value for type %1")
<< Value(Data->Type, Val) << Data->Type;
}
void __ubsan::__ubsan_handle_load_invalid_value(InvalidValueData *Data,
ValueHandle Val) {
GET_REPORT_OPTIONS(false);
handleLoadInvalidValue(Data, Val, Opts);
}
void __ubsan::__ubsan_handle_load_invalid_value_abort(InvalidValueData *Data,
ValueHandle Val) {
GET_REPORT_OPTIONS(true);
handleLoadInvalidValue(Data, Val, Opts);
Die();
}
static void handleImplicitConversion(ImplicitConversionData *Data,
ReportOptions Opts, ValueHandle Src,
ValueHandle Dst) {
SourceLocation Loc = Data->Loc.acquire();
ErrorType ET = ErrorType::GenericUB;
const TypeDescriptor &SrcTy = Data->FromType;
const TypeDescriptor &DstTy = Data->ToType;
bool SrcSigned = SrcTy.isSignedIntegerTy();
bool DstSigned = DstTy.isSignedIntegerTy();
switch (Data->Kind) {
case ICCK_IntegerTruncation: { // Legacy, no longer used.
// Let's figure out what it should be as per the new types, and upgrade.
// If both types are unsigned, then it's an unsigned truncation.
// Else, it is a signed truncation.
if (!SrcSigned && !DstSigned) {
ET = ErrorType::ImplicitUnsignedIntegerTruncation;
} else {
ET = ErrorType::ImplicitSignedIntegerTruncation;
}
break;
}
case ICCK_UnsignedIntegerTruncation:
ET = ErrorType::ImplicitUnsignedIntegerTruncation;
break;
case ICCK_SignedIntegerTruncation:
ET = ErrorType::ImplicitSignedIntegerTruncation;
break;
case ICCK_IntegerSignChange:
ET = ErrorType::ImplicitIntegerSignChange;
break;
case ICCK_SignedIntegerTruncationOrSignChange:
ET = ErrorType::ImplicitSignedIntegerTruncationOrSignChange;
break;
}
if (ignoreReport(Loc, Opts, ET))
return;
ScopedReport R(Opts, Loc, ET);
// FIXME: is it possible to dump the values as hex with fixed width?
Diag(Loc, DL_Error, ET,
"implicit conversion from type %0 of value %1 (%2-bit, %3signed) to "
"type %4 changed the value to %5 (%6-bit, %7signed)")
<< SrcTy << Value(SrcTy, Src) << SrcTy.getIntegerBitWidth()
<< (SrcSigned ? "" : "un") << DstTy << Value(DstTy, Dst)
<< DstTy.getIntegerBitWidth() << (DstSigned ? "" : "un");
}
void __ubsan::__ubsan_handle_implicit_conversion(ImplicitConversionData *Data,
ValueHandle Src,
ValueHandle Dst) {
GET_REPORT_OPTIONS(false);
handleImplicitConversion(Data, Opts, Src, Dst);
}
void __ubsan::__ubsan_handle_implicit_conversion_abort(
ImplicitConversionData *Data, ValueHandle Src, ValueHandle Dst) {
GET_REPORT_OPTIONS(true);
handleImplicitConversion(Data, Opts, Src, Dst);
Die();
}
static void handleInvalidBuiltin(InvalidBuiltinData *Data, ReportOptions Opts) {
SourceLocation Loc = Data->Loc.acquire();
ErrorType ET = ErrorType::InvalidBuiltin;
if (ignoreReport(Loc, Opts, ET))
return;
ScopedReport R(Opts, Loc, ET);
Diag(Loc, DL_Error, ET,
"passing zero to %0, which is not a valid argument")
<< ((Data->Kind == BCK_CTZPassedZero) ? "ctz()" : "clz()");
}
void __ubsan::__ubsan_handle_invalid_builtin(InvalidBuiltinData *Data) {
GET_REPORT_OPTIONS(true);
handleInvalidBuiltin(Data, Opts);
}
void __ubsan::__ubsan_handle_invalid_builtin_abort(InvalidBuiltinData *Data) {
GET_REPORT_OPTIONS(true);
handleInvalidBuiltin(Data, Opts);
Die();
}
static void handleInvalidObjCCast(InvalidObjCCast *Data, ValueHandle Pointer,
ReportOptions Opts) {
SourceLocation Loc = Data->Loc.acquire();
ErrorType ET = ErrorType::InvalidObjCCast;
if (ignoreReport(Loc, Opts, ET))
return;
ScopedReport R(Opts, Loc, ET);
const char *GivenClass = getObjCClassName(Pointer);
const char *GivenClassStr = GivenClass ? GivenClass : "<unknown type>";
Diag(Loc, DL_Error, ET,
"invalid ObjC cast, object is a '%0', but expected a %1")
<< GivenClassStr << Data->ExpectedType;
}
void __ubsan::__ubsan_handle_invalid_objc_cast(InvalidObjCCast *Data,
ValueHandle Pointer) {
GET_REPORT_OPTIONS(false);
handleInvalidObjCCast(Data, Pointer, Opts);
}
void __ubsan::__ubsan_handle_invalid_objc_cast_abort(InvalidObjCCast *Data,
ValueHandle Pointer) {
GET_REPORT_OPTIONS(true);
handleInvalidObjCCast(Data, Pointer, Opts);
Die();
}
static void handleNonNullReturn(NonNullReturnData *Data, SourceLocation *LocPtr,
ReportOptions Opts, bool IsAttr) {
if (!LocPtr)
UNREACHABLE("source location pointer is null!");
SourceLocation Loc = LocPtr->acquire();
ErrorType ET = IsAttr ? ErrorType::InvalidNullReturn
: ErrorType::InvalidNullReturnWithNullability;
if (ignoreReport(Loc, Opts, ET))
return;
ScopedReport R(Opts, Loc, ET);
Diag(Loc, DL_Error, ET,
"null pointer returned from function declared to never return null");
if (!Data->AttrLoc.isInvalid())
Diag(Data->AttrLoc, DL_Note, ET, "%0 specified here")
<< (IsAttr ? "returns_nonnull attribute"
: "_Nonnull return type annotation");
}
void __ubsan::__ubsan_handle_nonnull_return_v1(NonNullReturnData *Data,
SourceLocation *LocPtr) {
GET_REPORT_OPTIONS(false);
handleNonNullReturn(Data, LocPtr, Opts, true);
}
void __ubsan::__ubsan_handle_nonnull_return_v1_abort(NonNullReturnData *Data,
SourceLocation *LocPtr) {
GET_REPORT_OPTIONS(true);
handleNonNullReturn(Data, LocPtr, Opts, true);
Die();
}
void __ubsan::__ubsan_handle_nullability_return_v1(NonNullReturnData *Data,
SourceLocation *LocPtr) {
GET_REPORT_OPTIONS(false);
handleNonNullReturn(Data, LocPtr, Opts, false);
}
void __ubsan::__ubsan_handle_nullability_return_v1_abort(
NonNullReturnData *Data, SourceLocation *LocPtr) {
GET_REPORT_OPTIONS(true);
handleNonNullReturn(Data, LocPtr, Opts, false);
Die();
}
static void handleNonNullArg(NonNullArgData *Data, ReportOptions Opts,
bool IsAttr) {
SourceLocation Loc = Data->Loc.acquire();
ErrorType ET = IsAttr ? ErrorType::InvalidNullArgument
: ErrorType::InvalidNullArgumentWithNullability;
if (ignoreReport(Loc, Opts, ET))
return;
ScopedReport R(Opts, Loc, ET);
Diag(Loc, DL_Error, ET,
"null pointer passed as argument %0, which is declared to "
"never be null")
<< Data->ArgIndex;
if (!Data->AttrLoc.isInvalid())
Diag(Data->AttrLoc, DL_Note, ET, "%0 specified here")
<< (IsAttr ? "nonnull attribute" : "_Nonnull type annotation");
}
void __ubsan::__ubsan_handle_nonnull_arg(NonNullArgData *Data) {
GET_REPORT_OPTIONS(false);
handleNonNullArg(Data, Opts, true);
}
void __ubsan::__ubsan_handle_nonnull_arg_abort(NonNullArgData *Data) {
GET_REPORT_OPTIONS(true);
handleNonNullArg(Data, Opts, true);
Die();
}
void __ubsan::__ubsan_handle_nullability_arg(NonNullArgData *Data) {
GET_REPORT_OPTIONS(false);
handleNonNullArg(Data, Opts, false);
}
void __ubsan::__ubsan_handle_nullability_arg_abort(NonNullArgData *Data) {
GET_REPORT_OPTIONS(true);
handleNonNullArg(Data, Opts, false);
Die();
}
static void handlePointerOverflowImpl(PointerOverflowData *Data,
ValueHandle Base,
ValueHandle Result,
ReportOptions Opts) {
SourceLocation Loc = Data->Loc.acquire();
ErrorType ET;
if (Base == 0 && Result == 0)
ET = ErrorType::NullptrWithOffset;
else if (Base == 0 && Result != 0)
ET = ErrorType::NullptrWithNonZeroOffset;
else if (Base != 0 && Result == 0)
ET = ErrorType::NullptrAfterNonZeroOffset;
else
ET = ErrorType::PointerOverflow;
if (ignoreReport(Loc, Opts, ET))
return;
ScopedReport R(Opts, Loc, ET);
if (ET == ErrorType::NullptrWithOffset) {
Diag(Loc, DL_Error, ET, "applying zero offset to null pointer");
} else if (ET == ErrorType::NullptrWithNonZeroOffset) {
Diag(Loc, DL_Error, ET, "applying non-zero offset %0 to null pointer")
<< Result;
} else if (ET == ErrorType::NullptrAfterNonZeroOffset) {
Diag(
Loc, DL_Error, ET,
"applying non-zero offset to non-null pointer %0 produced null pointer")
<< (void *)Base;
} else if ((sptr(Base) >= 0) == (sptr(Result) >= 0)) {
if (Base > Result)
Diag(Loc, DL_Error, ET,
"addition of unsigned offset to %0 overflowed to %1")
<< (void *)Base << (void *)Result;
else
Diag(Loc, DL_Error, ET,
"subtraction of unsigned offset from %0 overflowed to %1")
<< (void *)Base << (void *)Result;
} else {
Diag(Loc, DL_Error, ET,
"pointer index expression with base %0 overflowed to %1")
<< (void *)Base << (void *)Result;
}
}
void __ubsan::__ubsan_handle_pointer_overflow(PointerOverflowData *Data,
ValueHandle Base,
ValueHandle Result) {
GET_REPORT_OPTIONS(false);
handlePointerOverflowImpl(Data, Base, Result, Opts);
}
void __ubsan::__ubsan_handle_pointer_overflow_abort(PointerOverflowData *Data,
ValueHandle Base,
ValueHandle Result) {
GET_REPORT_OPTIONS(true);
handlePointerOverflowImpl(Data, Base, Result, Opts);
Die();
}
static void handleCFIBadIcall(CFICheckFailData *Data, ValueHandle Function,
ReportOptions Opts) {
if (Data->CheckKind != CFITCK_ICall && Data->CheckKind != CFITCK_NVMFCall)
Die();
SourceLocation Loc = Data->Loc.acquire();
ErrorType ET = ErrorType::CFIBadType;
if (ignoreReport(Loc, Opts, ET))
return;
ScopedReport R(Opts, Loc, ET);
const char *CheckKindStr = Data->CheckKind == CFITCK_NVMFCall
? "non-virtual pointer to member function call"
: "indirect function call";
Diag(Loc, DL_Error, ET,
"control flow integrity check for type %0 failed during %1")
<< Data->Type << CheckKindStr;
SymbolizedStackHolder FLoc(getSymbolizedLocation(Function));
const char *FName = FLoc.get()->info.function;
if (!FName)
FName = "(unknown)";
Diag(FLoc, DL_Note, ET, "%0 defined here") << FName;
// If the failure involved different DSOs for the check location and icall
// target, report the DSO names.
const char *DstModule = FLoc.get()->info.module;
if (!DstModule)
DstModule = "(unknown)";
const char *SrcModule = Symbolizer::GetOrInit()->GetModuleNameForPc(Opts.pc);
if (!SrcModule)
SrcModule = "(unknown)";
if (internal_strcmp(SrcModule, DstModule))
Diag(Loc, DL_Note, ET,
"check failed in %0, destination function located in %1")
<< SrcModule << DstModule;
}
namespace __ubsan {
#ifdef UBSAN_CAN_USE_CXXABI
#ifdef _WIN32
extern "C" void __ubsan_handle_cfi_bad_type_default(CFICheckFailData *Data,
ValueHandle Vtable,
bool ValidVtable,
ReportOptions Opts) {
Die();
}
WIN_WEAK_ALIAS(__ubsan_handle_cfi_bad_type, __ubsan_handle_cfi_bad_type_default)
#else
SANITIZER_WEAK_ATTRIBUTE
#endif
void __ubsan_handle_cfi_bad_type(CFICheckFailData *Data, ValueHandle Vtable,
bool ValidVtable, ReportOptions Opts);
#else
void __ubsan_handle_cfi_bad_type(CFICheckFailData *Data, ValueHandle Vtable,
bool ValidVtable, ReportOptions Opts) {
Die();
}
#endif
} // namespace __ubsan
void __ubsan::__ubsan_handle_cfi_check_fail(CFICheckFailData *Data,
ValueHandle Value,
uptr ValidVtable) {
GET_REPORT_OPTIONS(false);
if (Data->CheckKind == CFITCK_ICall || Data->CheckKind == CFITCK_NVMFCall)
handleCFIBadIcall(Data, Value, Opts);
else
__ubsan_handle_cfi_bad_type(Data, Value, ValidVtable, Opts);
}
void __ubsan::__ubsan_handle_cfi_check_fail_abort(CFICheckFailData *Data,
ValueHandle Value,
uptr ValidVtable) {
GET_REPORT_OPTIONS(true);
if (Data->CheckKind == CFITCK_ICall || Data->CheckKind == CFITCK_NVMFCall)
handleCFIBadIcall(Data, Value, Opts);
else
__ubsan_handle_cfi_bad_type(Data, Value, ValidVtable, Opts);
Die();
}
#endif // CAN_SANITIZE_UB