//===-- chunk.h -------------------------------------------------*- C++ -*-===// // // 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 // //===----------------------------------------------------------------------===// #ifndef SCUDO_CHUNK_H_ #define SCUDO_CHUNK_H_ #include "platform.h" #include "atomic_helpers.h" #include "checksum.h" #include "common.h" #include "report.h" namespace scudo { extern Checksum HashAlgorithm; inline u16 computeChecksum(u32 Seed, uptr Value, uptr *Array, uptr ArraySize) { // If the hardware CRC32 feature is defined here, it was enabled everywhere, // as opposed to only for crc32_hw.cpp. This means that other hardware // specific instructions were likely emitted at other places, and as a result // there is no reason to not use it here. #if defined(__CRC32__) || defined(__SSE4_2__) || defined(__ARM_FEATURE_CRC32) u32 Crc = static_cast(CRC32_INTRINSIC(Seed, Value)); for (uptr I = 0; I < ArraySize; I++) Crc = static_cast(CRC32_INTRINSIC(Crc, Array[I])); return static_cast(Crc ^ (Crc >> 16)); #else if (HashAlgorithm == Checksum::HardwareCRC32) { u32 Crc = computeHardwareCRC32(Seed, Value); for (uptr I = 0; I < ArraySize; I++) Crc = computeHardwareCRC32(Crc, Array[I]); return static_cast(Crc ^ (Crc >> 16)); } else { u16 Checksum = computeBSDChecksum(static_cast(Seed), Value); for (uptr I = 0; I < ArraySize; I++) Checksum = computeBSDChecksum(Checksum, Array[I]); return Checksum; } #endif // defined(__CRC32__) || defined(__SSE4_2__) || // defined(__ARM_FEATURE_CRC32) } namespace Chunk { // Note that in an ideal world, `State` and `Origin` should be `enum class`, and // the associated `UnpackedHeader` fields of their respective enum class type // but https://gcc.gnu.org/bugzilla/show_bug.cgi?id=61414 prevents it from // happening, as it will error, complaining the number of bits is not enough. enum Origin : u8 { Malloc = 0, New = 1, NewArray = 2, Memalign = 3, }; enum State : u8 { Available = 0, Allocated = 1, Quarantined = 2 }; typedef u64 PackedHeader; // Update the 'Mask' constants to reflect changes in this structure. struct UnpackedHeader { uptr ClassId : 8; u8 State : 2; // Origin if State == Allocated, or WasZeroed otherwise. u8 OriginOrWasZeroed : 2; uptr SizeOrUnusedBytes : 20; uptr Offset : 16; uptr Checksum : 16; }; typedef atomic_u64 AtomicPackedHeader; static_assert(sizeof(UnpackedHeader) == sizeof(PackedHeader), ""); // Those constants are required to silence some -Werror=conversion errors when // assigning values to the related bitfield variables. constexpr uptr ClassIdMask = (1UL << 8) - 1; constexpr u8 StateMask = (1U << 2) - 1; constexpr u8 OriginMask = (1U << 2) - 1; constexpr uptr SizeOrUnusedBytesMask = (1UL << 20) - 1; constexpr uptr OffsetMask = (1UL << 16) - 1; constexpr uptr ChecksumMask = (1UL << 16) - 1; constexpr uptr getHeaderSize() { return roundUpTo(sizeof(PackedHeader), 1U << SCUDO_MIN_ALIGNMENT_LOG); } inline AtomicPackedHeader *getAtomicHeader(void *Ptr) { return reinterpret_cast(reinterpret_cast(Ptr) - getHeaderSize()); } inline const AtomicPackedHeader *getConstAtomicHeader(const void *Ptr) { return reinterpret_cast( reinterpret_cast(Ptr) - getHeaderSize()); } // We do not need a cryptographically strong hash for the checksum, but a CRC // type function that can alert us in the event a header is invalid or // corrupted. Ideally slightly better than a simple xor of all fields. static inline u16 computeHeaderChecksum(u32 Cookie, const void *Ptr, UnpackedHeader *Header) { UnpackedHeader ZeroChecksumHeader = *Header; ZeroChecksumHeader.Checksum = 0; uptr HeaderHolder[sizeof(UnpackedHeader) / sizeof(uptr)]; memcpy(&HeaderHolder, &ZeroChecksumHeader, sizeof(HeaderHolder)); return computeChecksum(Cookie, reinterpret_cast(Ptr), HeaderHolder, ARRAY_SIZE(HeaderHolder)); } inline void storeHeader(u32 Cookie, void *Ptr, UnpackedHeader *NewUnpackedHeader) { NewUnpackedHeader->Checksum = computeHeaderChecksum(Cookie, Ptr, NewUnpackedHeader); PackedHeader NewPackedHeader = bit_cast(*NewUnpackedHeader); atomic_store_relaxed(getAtomicHeader(Ptr), NewPackedHeader); } inline void loadHeader(u32 Cookie, const void *Ptr, UnpackedHeader *NewUnpackedHeader) { PackedHeader NewPackedHeader = atomic_load_relaxed(getConstAtomicHeader(Ptr)); *NewUnpackedHeader = bit_cast(NewPackedHeader); if (UNLIKELY(NewUnpackedHeader->Checksum != computeHeaderChecksum(Cookie, Ptr, NewUnpackedHeader))) reportHeaderCorruption(const_cast(Ptr)); } inline void compareExchangeHeader(u32 Cookie, void *Ptr, UnpackedHeader *NewUnpackedHeader, UnpackedHeader *OldUnpackedHeader) { NewUnpackedHeader->Checksum = computeHeaderChecksum(Cookie, Ptr, NewUnpackedHeader); PackedHeader NewPackedHeader = bit_cast(*NewUnpackedHeader); PackedHeader OldPackedHeader = bit_cast(*OldUnpackedHeader); if (UNLIKELY(!atomic_compare_exchange_strong( getAtomicHeader(Ptr), &OldPackedHeader, NewPackedHeader, memory_order_relaxed))) reportHeaderRace(Ptr); } inline bool isValid(u32 Cookie, const void *Ptr, UnpackedHeader *NewUnpackedHeader) { PackedHeader NewPackedHeader = atomic_load_relaxed(getConstAtomicHeader(Ptr)); *NewUnpackedHeader = bit_cast(NewPackedHeader); return NewUnpackedHeader->Checksum == computeHeaderChecksum(Cookie, Ptr, NewUnpackedHeader); } } // namespace Chunk } // namespace scudo #endif // SCUDO_CHUNK_H_