/* * Copyright (C) 2017 The Android Open Source Project * * Licensed under the Apache License, Version 2.0 (the "License"); * you may not use this file except in compliance with the License. * You may obtain a copy of the License at * * http://www.apache.org/licenses/LICENSE-2.0 * * Unless required by applicable law or agreed to in writing, software * distributed under the License is distributed on an "AS IS" BASIS, * WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied. * See the License for the specific language governing permissions and * limitations under the License. */ #ifndef ART_LIBDEXFILE_DEX_COMPACT_DEX_FILE_H_ #define ART_LIBDEXFILE_DEX_COMPACT_DEX_FILE_H_ #include "base/casts.h" #include "dex_file.h" #include "dex/compact_offset_table.h" namespace art { // CompactDex is a currently ART internal dex file format that aims to reduce storage/RAM usage. class CompactDexFile : public DexFile { public: static constexpr uint8_t kDexMagic[kDexMagicSize] = { 'c', 'd', 'e', 'x' }; static constexpr uint8_t kDexMagicVersion[] = {'0', '0', '1', '\0'}; enum class FeatureFlags : uint32_t { kDefaultMethods = 0x1, }; class Header : public DexFile::Header { public: static const Header* At(const void* at) { return reinterpret_cast<const Header*>(at); } uint32_t GetFeatureFlags() const { return feature_flags_; } uint32_t GetDataOffset() const { return data_off_; } uint32_t GetDataSize() const { return data_size_; } // Range of the shared data section owned by the dex file. Owned in this context refers to data // for this DEX that was not deduplicated to another DEX. uint32_t OwnedDataBegin() const { return owned_data_begin_; } uint32_t OwnedDataEnd() const { return owned_data_end_; } private: uint32_t feature_flags_ = 0u; // Position in the compact dex file for the debug info table data starts. uint32_t debug_info_offsets_pos_ = 0u; // Offset into the debug info table data where the lookup table is. uint32_t debug_info_offsets_table_offset_ = 0u; // Base offset of where debug info starts in the dex file. uint32_t debug_info_base_ = 0u; // Range of the shared data section owned by the dex file. uint32_t owned_data_begin_ = 0u; uint32_t owned_data_end_ = 0u; friend class CompactDexFile; friend class CompactDexWriter; }; // Like the standard code item except without a debug info offset. Each code item may have a // preheader to encode large methods. In 99% of cases, the preheader is not used. This enables // smaller size with a good fast path case in the accessors. struct CodeItem : public DexFile::CodeItem { static constexpr size_t kAlignment = sizeof(uint16_t); // Max preheader size in uint16_ts. static constexpr size_t kMaxPreHeaderSize = 6; private: CodeItem() = default; static constexpr size_t kRegistersSizeShift = 12; static constexpr size_t kInsSizeShift = 8; static constexpr size_t kOutsSizeShift = 4; static constexpr size_t kTriesSizeSizeShift = 0; static constexpr uint16_t kFlagPreHeaderRegisterSize = 0x1 << 0; static constexpr uint16_t kFlagPreHeaderInsSize = 0x1 << 1; static constexpr uint16_t kFlagPreHeaderOutsSize = 0x1 << 2; static constexpr uint16_t kFlagPreHeaderTriesSize = 0x1 << 3; static constexpr uint16_t kFlagPreHeaderInsnsSize = 0x1 << 4; static constexpr size_t kInsnsSizeShift = 5; static constexpr size_t kInsnsSizeBits = sizeof(uint16_t) * kBitsPerByte - kInsnsSizeShift; // Combined preheader flags for fast testing if we need to go slow path. static constexpr uint16_t kFlagPreHeaderCombined = kFlagPreHeaderRegisterSize | kFlagPreHeaderInsSize | kFlagPreHeaderOutsSize | kFlagPreHeaderTriesSize | kFlagPreHeaderInsnsSize; // Create a code item and associated preheader if required based on field values. // Returns the start of the preheader. The preheader buffer must be at least as large as // kMaxPreHeaderSize; uint16_t* Create(uint16_t registers_size, uint16_t ins_size, uint16_t outs_size, uint16_t tries_size, uint32_t insns_size_in_code_units, uint16_t* out_preheader) { // Dex verification ensures that registers size > ins_size, so we can subtract the registers // size accordingly to reduce how often we need to use the preheader. DCHECK_GE(registers_size, ins_size); registers_size -= ins_size; fields_ = (registers_size & 0xF) << kRegistersSizeShift; fields_ |= (ins_size & 0xF) << kInsSizeShift; fields_ |= (outs_size & 0xF) << kOutsSizeShift; fields_ |= (tries_size & 0xF) << kTriesSizeSizeShift; registers_size &= ~0xF; ins_size &= ~0xF; outs_size &= ~0xF; tries_size &= ~0xF; insns_count_and_flags_ = 0; const size_t masked_count = insns_size_in_code_units & ((1 << kInsnsSizeBits) - 1); insns_count_and_flags_ |= masked_count << kInsnsSizeShift; insns_size_in_code_units -= masked_count; // Since the preheader case is rare (1% of code items), use a suboptimally large but fast // decoding format. if (insns_size_in_code_units != 0) { insns_count_and_flags_ |= kFlagPreHeaderInsnsSize; --out_preheader; *out_preheader = static_cast<uint16_t>(insns_size_in_code_units); --out_preheader; *out_preheader = static_cast<uint16_t>(insns_size_in_code_units >> 16); } auto preheader_encode = [&](uint16_t size, uint16_t flag) { if (size != 0) { insns_count_and_flags_ |= flag; --out_preheader; *out_preheader = size; } }; preheader_encode(registers_size, kFlagPreHeaderRegisterSize); preheader_encode(ins_size, kFlagPreHeaderInsSize); preheader_encode(outs_size, kFlagPreHeaderOutsSize); preheader_encode(tries_size, kFlagPreHeaderTriesSize); return out_preheader; } ALWAYS_INLINE bool HasPreHeader(uint16_t flag) const { return (insns_count_and_flags_ & flag) != 0; } // Return true if the code item has any preheaders. ALWAYS_INLINE static bool HasAnyPreHeader(uint16_t insns_count_and_flags) { return (insns_count_and_flags & kFlagPreHeaderCombined) != 0; } ALWAYS_INLINE uint16_t* GetPreHeader() { return reinterpret_cast<uint16_t*>(this); } ALWAYS_INLINE const uint16_t* GetPreHeader() const { return reinterpret_cast<const uint16_t*>(this); } // Decode fields and read the preheader if necessary. If kDecodeOnlyInstructionCount is // specified then only the instruction count is decoded. template <bool kDecodeOnlyInstructionCount> ALWAYS_INLINE void DecodeFields(uint32_t* insns_count, uint16_t* registers_size, uint16_t* ins_size, uint16_t* outs_size, uint16_t* tries_size) const { *insns_count = insns_count_and_flags_ >> kInsnsSizeShift; if (!kDecodeOnlyInstructionCount) { const uint16_t fields = fields_; *registers_size = (fields >> kRegistersSizeShift) & 0xF; *ins_size = (fields >> kInsSizeShift) & 0xF; *outs_size = (fields >> kOutsSizeShift) & 0xF; *tries_size = (fields >> kTriesSizeSizeShift) & 0xF; } if (UNLIKELY(HasAnyPreHeader(insns_count_and_flags_))) { const uint16_t* preheader = GetPreHeader(); if (HasPreHeader(kFlagPreHeaderInsnsSize)) { --preheader; *insns_count += static_cast<uint32_t>(*preheader); --preheader; *insns_count += static_cast<uint32_t>(*preheader) << 16; } if (!kDecodeOnlyInstructionCount) { if (HasPreHeader(kFlagPreHeaderRegisterSize)) { --preheader; *registers_size += preheader[0]; } if (HasPreHeader(kFlagPreHeaderInsSize)) { --preheader; *ins_size += preheader[0]; } if (HasPreHeader(kFlagPreHeaderOutsSize)) { --preheader; *outs_size += preheader[0]; } if (HasPreHeader(kFlagPreHeaderTriesSize)) { --preheader; *tries_size += preheader[0]; } } } if (!kDecodeOnlyInstructionCount) { *registers_size += *ins_size; } } // Packed code item data, 4 bits each: [registers_size, ins_size, outs_size, tries_size] uint16_t fields_; // 5 bits for if either of the fields required preheader extension, 11 bits for the number of // instruction code units. uint16_t insns_count_and_flags_; uint16_t insns_[1]; // actual array of bytecode. ART_FRIEND_TEST(CodeItemAccessorsTest, TestDexInstructionsAccessor); ART_FRIEND_TEST(CompactDexFileTest, CodeItemFields); friend class CodeItemDataAccessor; friend class CodeItemDebugInfoAccessor; friend class CodeItemInstructionAccessor; friend class CompactDexFile; friend class CompactDexWriter; DISALLOW_COPY_AND_ASSIGN(CodeItem); }; // Write the compact dex specific magic. static void WriteMagic(uint8_t* magic); // Write the current version, note that the input is the address of the magic. static void WriteCurrentVersion(uint8_t* magic); // Returns true if the byte string points to the magic value. static bool IsMagicValid(const uint8_t* magic); virtual bool IsMagicValid() const OVERRIDE; // Returns true if the byte string after the magic is the correct value. static bool IsVersionValid(const uint8_t* magic); virtual bool IsVersionValid() const OVERRIDE; // TODO This is completely a guess. We really need to do better. b/72402467 // We ask for 64 megabytes which should be big enough for any realistic dex file. virtual size_t GetDequickenedSize() const OVERRIDE { return 64 * MB; } const Header& GetHeader() const { return down_cast<const Header&>(DexFile::GetHeader()); } virtual bool SupportsDefaultMethods() const OVERRIDE; uint32_t GetCodeItemSize(const DexFile::CodeItem& item) const OVERRIDE; uint32_t GetDebugInfoOffset(uint32_t dex_method_index) const { return debug_info_offsets_.GetOffset(dex_method_index); } static uint32_t CalculateChecksum(const uint8_t* base_begin, size_t base_size, const uint8_t* data_begin, size_t data_size); virtual uint32_t CalculateChecksum() const OVERRIDE; private: CompactDexFile(const uint8_t* base, size_t size, const uint8_t* data_begin, size_t data_size, const std::string& location, uint32_t location_checksum, const OatDexFile* oat_dex_file, std::unique_ptr<DexFileContainer> container); CompactOffsetTable::Accessor debug_info_offsets_; friend class DexFile; friend class DexFileLoader; DISALLOW_COPY_AND_ASSIGN(CompactDexFile); }; } // namespace art #endif // ART_LIBDEXFILE_DEX_COMPACT_DEX_FILE_H_