/* * Copyright (C) 2011 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_LIBARTBASE_BASE_LEB128_H_ #define ART_LIBARTBASE_BASE_LEB128_H_ #include #include #include #include "bit_utils.h" #include "globals.h" #include "macros.h" namespace art { template static inline bool DecodeLeb128Helper(const uint8_t** data, const std::optional& end, T* out) { static_assert(sizeof(T) == 8 || sizeof(T) == 4); const uint8_t* ptr = *data; T result = 0; const size_t num_bits = (sizeof(T) * 8); // We can encode 7-bits per byte in leb128. So max_bytes is ceil(number_of_bits / 7) const size_t max_bytes = (num_bits + 6u) / 7u; for (size_t index = 0; index < max_bytes; ++index) { if (end.has_value() && ptr >= end.value()) { return false; } std::make_unsigned_t curr = *(ptr++); result |= ((curr & 0x7f) << (index * 7)); if (LIKELY(curr <= 0x7f)) { if (std::is_signed_v) { // For signed values we need to sign extend the result. If we are using all the bits then // the result is already sign extended and we don't need to do anything. if (index < max_bytes - 1) { int shift = num_bits - (index + 1) * 7; result = (result << shift) >> shift; } } // End of encoding. break; } } *out = result; *data = ptr; return true; } template static inline T DecodeUnsignedLeb128(const uint8_t** data) { static_assert(!std::is_signed_v); T value = 0; DecodeLeb128Helper(data, std::nullopt, &value); return value; } template static inline bool DecodeUnsignedLeb128Checked(const uint8_t** data, const void* end, T* out) { static_assert(!std::is_signed_v); return DecodeLeb128Helper(data, end, out); } static inline uint32_t DecodeUnsignedLeb128WithoutMovingCursor(const uint8_t* data) { return DecodeUnsignedLeb128(&data); } // Reads an unsigned LEB128 + 1 value. updating the given pointer to point // just past the end of the read value. This function tolerates // non-zero high-order bits in the fifth encoded byte. // It is possible for this function to return -1. static inline int32_t DecodeUnsignedLeb128P1(const uint8_t** data) { return DecodeUnsignedLeb128(data) - 1; } template static inline T DecodeSignedLeb128(const uint8_t** data) { static_assert(std::is_signed_v); T value = 0; DecodeLeb128Helper(data, std::nullopt, &value); return value; } template static inline bool DecodeSignedLeb128Checked(const uint8_t** data, const void* end, T* out) { static_assert(std::is_signed_v); return DecodeLeb128Helper(data, end, out); } // Returns the number of bytes needed to encode the value in unsigned LEB128. static inline uint32_t UnsignedLeb128Size(uint64_t data) { // bits_to_encode = (data != 0) ? 64 - CLZ(x) : 1 // 64 - CLZ(data | 1) // bytes = ceil(bits_to_encode / 7.0); // (6 + bits_to_encode) / 7 uint32_t x = 6 + 64 - CLZ(data | 1U); // Division by 7 is done by (x * 37) >> 8 where 37 = ceil(256 / 7). // This works for 0 <= x < 256 / (7 * 37 - 256), i.e. 0 <= x <= 85. return (x * 37) >> 8; } static inline bool IsLeb128Terminator(const uint8_t* ptr) { return *ptr <= 0x7f; } // Returns the first byte of a Leb128 value assuming that: // (1) `end_ptr` points to the first byte after the Leb128 value, and // (2) there is another Leb128 value before this one. template static inline T* ReverseSearchUnsignedLeb128(T* end_ptr) { static_assert(std::is_same_v, uint8_t>, "T must be a uint8_t"); T* ptr = end_ptr; // Move one byte back, check that this is the terminating byte. ptr--; DCHECK(IsLeb128Terminator(ptr)); // Keep moving back while the previous byte is not a terminating byte. // Fail after reading five bytes in case there isn't another Leb128 value // before this one. while (!IsLeb128Terminator(ptr - 1)) { ptr--; DCHECK_LE(static_cast(end_ptr - ptr), 5); } return ptr; } // Returns the number of bytes needed to encode the value in unsigned LEB128. static inline uint32_t SignedLeb128Size(int64_t data) { // Like UnsignedLeb128Size(), but we need one bit beyond the highest bit that differs from sign. uint64_t bits_to_encode = static_cast(data ^ (data >> 63)); uint32_t num_bits = 1 /* we need to encode the sign bit */ + 6 + 64 - CLZ(bits_to_encode | 1U); // See UnsignedLeb128Size for explanation. This is basically num_bits / 7. return (num_bits * 37) >> 8; } static inline uint8_t* EncodeUnsignedLeb128(uint8_t* dest, uint64_t value) { uint8_t out = value & 0x7f; value >>= 7; while (value != 0) { *dest++ = out | 0x80; out = value & 0x7f; value >>= 7; } *dest++ = out; return dest; } template static inline void EncodeUnsignedLeb128(Vector* dest, uint64_t value) { static_assert(std::is_same_v, "Invalid value type"); uint8_t out = value & 0x7f; value >>= 7; while (value != 0) { dest->push_back(out | 0x80); out = value & 0x7f; value >>= 7; } dest->push_back(out); } // Overwrite encoded Leb128 with a new value. The new value must be less than // or equal to the old value to ensure that it fits the allocated space. static inline void UpdateUnsignedLeb128(uint8_t* dest, uint32_t value) { const uint8_t* old_end = dest; uint32_t old_value = DecodeUnsignedLeb128(&old_end); DCHECK_LE(UnsignedLeb128Size(value), UnsignedLeb128Size(old_value)); for (uint8_t* end = EncodeUnsignedLeb128(dest, value); end < old_end; end++) { // Use longer encoding than necessary to fill the allocated space. end[-1] |= 0x80; end[0] = 0; } } static inline uint8_t* EncodeSignedLeb128(uint8_t* dest, int64_t value) { uint64_t extra_bits = static_cast(value ^ (value >> 63)) >> 6; uint8_t out = value & 0x7f; while (extra_bits != 0u) { *dest++ = out | 0x80; value >>= 7; out = value & 0x7f; extra_bits >>= 7; } *dest++ = out; return dest; } static inline void EncodeSignedLeb128(std::vector* dest, int64_t value) { uint32_t extra_bits = static_cast(value ^ (value >> 31)) >> 6; uint8_t out = value & 0x7f; while (extra_bits != 0u) { dest->push_back(out | 0x80); value >>= 7; out = value & 0x7f; extra_bits >>= 7; } dest->push_back(out); } // An encoder that pushes int32_t/uint32_t data onto the given std::vector. template > class Leb128Encoder { static_assert(std::is_same_v, "Invalid value type"); public: explicit Leb128Encoder(Vector* data) : data_(data) { DCHECK(data != nullptr); } void Reserve(uint32_t size) { data_->reserve(size); } void PushBackUnsigned(uint32_t value) { EncodeUnsignedLeb128(data_, value); } template void InsertBackUnsigned(It cur, It end) { for (; cur != end; ++cur) { PushBackUnsigned(*cur); } } void PushBackSigned(int32_t value) { EncodeSignedLeb128(data_, value); } template void InsertBackSigned(It cur, It end) { for (; cur != end; ++cur) { PushBackSigned(*cur); } } const Vector& GetData() const { return *data_; } protected: Vector* const data_; private: DISALLOW_COPY_AND_ASSIGN(Leb128Encoder); }; // An encoder with an API similar to vector where the data is captured in ULEB128 format. template > class Leb128EncodingVector final : private Vector, public Leb128Encoder { static_assert(std::is_same_v, "Invalid value type"); public: Leb128EncodingVector() : Leb128Encoder(this) { } explicit Leb128EncodingVector(const typename Vector::allocator_type& alloc) : Vector(alloc), Leb128Encoder(this) { } private: DISALLOW_COPY_AND_ASSIGN(Leb128EncodingVector); }; } // namespace art #endif // ART_LIBARTBASE_BASE_LEB128_H_