ladybird/Kernel/UBSanitizer.cpp

212 lines
9.1 KiB
C++

/*
* Copyright (c) 2021, Andreas Kling <kling@serenityos.org>
*
* SPDX-License-Identifier: BSD-2-Clause
*/
#include <AK/Format.h>
#include <AK/UBSanitizer.h>
#include <Kernel/Arch/Processor.h>
#include <Kernel/KSyms.h>
using namespace Kernel;
using namespace AK::UBSanitizer;
Atomic<bool> AK::UBSanitizer::g_ubsan_is_deadly { true };
extern "C" {
static void print_location(const SourceLocation& location)
{
if (!location.filename())
critical_dmesgln("KUBSAN: in unknown file");
else
critical_dmesgln("KUBSAN: at {}, line {}, column: {}", location.filename(), location.line(), location.column());
dump_backtrace(g_ubsan_is_deadly ? PrintToScreen::Yes : PrintToScreen::No);
if (g_ubsan_is_deadly) {
critical_dmesgln("UB is configured to be deadly, halting the system.");
Processor::halt();
}
}
void __ubsan_handle_load_invalid_value(const InvalidValueData&, ValueHandle) __attribute__((used));
void __ubsan_handle_load_invalid_value(const InvalidValueData& data, ValueHandle)
{
critical_dmesgln("KUBSAN: load-invalid-value: {} ({}-bit)", data.type.name(), data.type.bit_width());
print_location(data.location);
}
void __ubsan_handle_nonnull_arg(const NonnullArgData&) __attribute__((used));
void __ubsan_handle_nonnull_arg(const NonnullArgData& data)
{
critical_dmesgln("KUBSAN: null pointer passed as argument {}, which is declared to never be null", data.argument_index);
print_location(data.location);
}
void __ubsan_handle_nullability_arg(const NonnullArgData&) __attribute__((used));
void __ubsan_handle_nullability_arg(const NonnullArgData& data)
{
critical_dmesgln("KUBSAN: null pointer passed as argument {}, which is declared to never be null", data.argument_index);
print_location(data.location);
}
void __ubsan_handle_nonnull_return_v1(const NonnullReturnData&, const SourceLocation&) __attribute__((used));
void __ubsan_handle_nonnull_return_v1(const NonnullReturnData&, const SourceLocation& location)
{
critical_dmesgln("KUBSAN: null pointer return from function declared to never return null");
print_location(location);
}
void __ubsan_handle_nullability_return_v1(const NonnullReturnData& data, const SourceLocation& location) __attribute__((used));
void __ubsan_handle_nullability_return_v1(const NonnullReturnData&, const SourceLocation& location)
{
critical_dmesgln("KUBSAN: null pointer return from function declared to never return null");
print_location(location);
}
void __ubsan_handle_vla_bound_not_positive(const VLABoundData&, ValueHandle) __attribute__((used));
void __ubsan_handle_vla_bound_not_positive(const VLABoundData& data, ValueHandle)
{
critical_dmesgln("KUBSAN: VLA bound not positive {} ({}-bit)", data.type.name(), data.type.bit_width());
print_location(data.location);
}
void __ubsan_handle_add_overflow(const OverflowData&, ValueHandle lhs, ValueHandle rhs) __attribute__((used));
void __ubsan_handle_add_overflow(const OverflowData& data, ValueHandle, ValueHandle)
{
critical_dmesgln("KUBSAN: addition overflow, {} ({}-bit)", data.type.name(), data.type.bit_width());
print_location(data.location);
}
void __ubsan_handle_sub_overflow(const OverflowData&, ValueHandle lhs, ValueHandle rhs) __attribute__((used));
void __ubsan_handle_sub_overflow(const OverflowData& data, ValueHandle, ValueHandle)
{
critical_dmesgln("KUBSAN: subtraction overflow, {} ({}-bit)", data.type.name(), data.type.bit_width());
print_location(data.location);
}
void __ubsan_handle_negate_overflow(const OverflowData&, ValueHandle) __attribute__((used));
void __ubsan_handle_negate_overflow(const OverflowData& data, ValueHandle)
{
critical_dmesgln("KUBSAN: negation overflow, {} ({}-bit)", data.type.name(), data.type.bit_width());
print_location(data.location);
}
void __ubsan_handle_mul_overflow(const OverflowData&, ValueHandle lhs, ValueHandle rhs) __attribute__((used));
void __ubsan_handle_mul_overflow(const OverflowData& data, ValueHandle, ValueHandle)
{
critical_dmesgln("KUBSAN: multiplication overflow, {} ({}-bit)", data.type.name(), data.type.bit_width());
print_location(data.location);
}
void __ubsan_handle_shift_out_of_bounds(const ShiftOutOfBoundsData&, ValueHandle lhs, ValueHandle rhs) __attribute__((used));
void __ubsan_handle_shift_out_of_bounds(const ShiftOutOfBoundsData& data, ValueHandle, ValueHandle)
{
critical_dmesgln("KUBSAN: shift out of bounds, {} ({}-bit) shifted by {} ({}-bit)", data.lhs_type.name(), data.lhs_type.bit_width(), data.rhs_type.name(), data.rhs_type.bit_width());
print_location(data.location);
}
void __ubsan_handle_divrem_overflow(const OverflowData&, ValueHandle lhs, ValueHandle rhs) __attribute__((used));
void __ubsan_handle_divrem_overflow(const OverflowData& data, ValueHandle, ValueHandle)
{
critical_dmesgln("KUBSAN: divrem overflow, {} ({}-bit)", data.type.name(), data.type.bit_width());
print_location(data.location);
}
void __ubsan_handle_out_of_bounds(const OutOfBoundsData&, ValueHandle) __attribute__((used));
void __ubsan_handle_out_of_bounds(const OutOfBoundsData& data, ValueHandle)
{
critical_dmesgln("KUBSAN: out of bounds access into array of {} ({}-bit), index type {} ({}-bit)", data.array_type.name(), data.array_type.bit_width(), data.index_type.name(), data.index_type.bit_width());
print_location(data.location);
}
void __ubsan_handle_type_mismatch_v1(const TypeMismatchData&, ValueHandle) __attribute__((used));
void __ubsan_handle_type_mismatch_v1(const TypeMismatchData& data, ValueHandle ptr)
{
constexpr StringView kinds[] = {
"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"
};
FlatPtr alignment = (FlatPtr)1 << data.log_alignment;
auto kind = kinds[data.type_check_kind];
if (!ptr)
critical_dmesgln("KUBSAN: {} null pointer of type {}", kind, data.type.name());
else if ((FlatPtr)ptr & (alignment - 1))
critical_dmesgln("KUBSAN: {} misaligned address {:p} of type {}", kind, ptr, data.type.name());
else
critical_dmesgln("KUBSAN: {} address {:p} with insufficient space for type {}", kind, ptr, data.type.name());
print_location(data.location);
}
void __ubsan_handle_alignment_assumption(const AlignmentAssumptionData&, ValueHandle, ValueHandle, ValueHandle) __attribute__((used));
void __ubsan_handle_alignment_assumption(const AlignmentAssumptionData& data, ValueHandle pointer, ValueHandle alignment, ValueHandle offset)
{
if (offset)
critical_dmesgln("KUBSAN: assumption of {:p} byte alignment (with offset of {:p} byte) for pointer {:p} of type {} failed", alignment, offset, pointer, data.type.name());
else
critical_dmesgln("KUBSAN: assumption of {:p} byte alignment for pointer {:p} of type {} failed", alignment, pointer, data.type.name());
print_location(data.location);
}
void __ubsan_handle_builtin_unreachable(const UnreachableData&) __attribute__((used));
void __ubsan_handle_builtin_unreachable(const UnreachableData& data)
{
critical_dmesgln("KUBSAN: execution reached an unreachable program point");
print_location(data.location);
}
void __ubsan_handle_missing_return(const UnreachableData&) __attribute__((used));
void __ubsan_handle_missing_return(const UnreachableData& data)
{
critical_dmesgln("KUBSAN: execution reached the end of a value-returning function without returning a value");
print_location(data.location);
}
void __ubsan_handle_implicit_conversion(const ImplicitConversionData&, ValueHandle, ValueHandle) __attribute__((used));
void __ubsan_handle_implicit_conversion(const ImplicitConversionData& data, ValueHandle, ValueHandle)
{
const char* src_signed = data.from_type.is_signed() ? "" : "un";
const char* dst_signed = data.to_type.is_signed() ? "" : "un";
critical_dmesgln("KUBSAN: implicit conversion from type {} ({}-bit, {}signed) to type {} ({}-bit, {}signed)", data.from_type.name(), data.from_type.bit_width(), src_signed, data.to_type.name(), data.to_type.bit_width(), dst_signed);
print_location(data.location);
}
void __ubsan_handle_invalid_builtin(const InvalidBuiltinData) __attribute__((used));
void __ubsan_handle_invalid_builtin(const InvalidBuiltinData data)
{
critical_dmesgln("KUBSAN: passing invalid argument");
print_location(data.location);
}
void __ubsan_handle_pointer_overflow(const PointerOverflowData&, ValueHandle, ValueHandle) __attribute__((used));
void __ubsan_handle_pointer_overflow(const PointerOverflowData& data, ValueHandle base, ValueHandle result)
{
if (base == 0 && result == 0)
critical_dmesgln("KUBSAN: applied zero offset to nullptr");
else if (base == 0 && result != 0)
critical_dmesgln("KUBSAN: applied non-zero offset {:p} to nullptr", result);
else if (base != 0 && result == 0)
critical_dmesgln("KUBSAN: applying non-zero offset to non-null pointer {:p} produced null pointer", base);
else
critical_dmesgln("KUBSAN: addition of unsigned offset to {:p} overflowed to {:p}", base, result);
print_location(data.location);
}
}