#include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #if MBEDTLS_VERSION_MAJOR <= 2 #define mbedtls_md5_starts mbedtls_md5_starts_ret #define mbedtls_md5_update mbedtls_md5_update_ret #define mbedtls_md5_finish mbedtls_md5_finish_ret #define mbedtls_sha1_starts mbedtls_sha1_starts_ret #define mbedtls_sha1_update mbedtls_sha1_update_ret #define mbedtls_sha1_finish mbedtls_sha1_finish_ret #define mbedtls_sha256_starts mbedtls_sha256_starts_ret #define mbedtls_sha256_update mbedtls_sha256_update_ret #define mbedtls_sha256_finish mbedtls_sha256_finish_ret #define mbedtls_sha512_starts mbedtls_sha512_starts_ret #define mbedtls_sha512_update mbedtls_sha512_update_ret #define mbedtls_sha512_finish mbedtls_sha512_finish_ret #endif namespace hex::crypt { using namespace std::placeholders; template Func> void processDataByChunks(prv::Provider *data, u64 offset, size_t size, Func func) { std::array buffer = { 0 }; for (size_t bufferOffset = 0; bufferOffset < size; bufferOffset += buffer.size()) { const auto readSize = std::min(buffer.size(), size - bufferOffset); data->read(offset + bufferOffset, buffer.data(), readSize); func(buffer.data(), readSize); } } template T reflect(T in, std::size_t bits) { T out {}; for (std::size_t i = 0; i < bits; i++) { out <<= 1; if (in & 0b1) out |= 1; in >>= 1; } return out; } template T reflect(T in) { if constexpr (sizeof(T) == 1) { T out { in }; out = ((out & 0xf0u) >> 4) | ((out & 0x0fu) << 4); out = ((out & 0xccu) >> 2) | ((out & 0x33u) << 2); out = ((out & 0xaau) >> 1) | ((out & 0x55u) << 1); return out; } else { return reflect(in, sizeof(T) * 8); } } template requires (std::has_single_bit(NumBits)) class Crc { // use reflected algorithm, so we reflect only if refin / refout is FALSE // mask values, 0b1 << 64 is UB, so use 0b10 << 63 public: constexpr Crc(u64 polynomial, u64 init, u64 xorOut, bool reflectInput, bool reflectOutput) : m_value(0x00), m_init(init & ((0b10ull << (NumBits - 1)) - 1)), m_xorOut(xorOut & ((0b10ull << (NumBits - 1)) - 1)), m_reflectInput(reflectInput), m_reflectOutput(reflectOutput), m_table([polynomial]() { auto reflectedPoly = reflect(polynomial & ((0b10ull << (NumBits - 1)) - 1), NumBits); std::array table = { 0 }; for (uint32_t i = 0; i < 256; i++) { uint64_t c = i; for (std::size_t j = 0; j < 8; j++) { if (c & 0b1) c = reflectedPoly ^ (c >> 1); else c >>= 1; } table[i] = c; } return table; }()) { reset(); }; constexpr void reset() { this->m_value = reflect(m_init, NumBits); } constexpr void processBytes(const unsigned char *data, std::size_t size) { for (std::size_t i = 0; i < size; i++) { u8 byte; if (this->m_reflectInput) byte = data[i]; else byte = reflect(data[i]); this->m_value = this->m_table[(this->m_value ^ byte) & 0xFFL] ^ (this->m_value >> 8); } } [[nodiscard]] constexpr u64 checksum() const { if (this->m_reflectOutput) return this->m_value ^ m_xorOut; else return reflect(this->m_value, NumBits) ^ m_xorOut; } private: u64 m_value; u64 m_init; u64 m_xorOut; bool m_reflectInput; bool m_reflectOutput; std::array m_table; }; template auto calcCrc(prv::Provider *data, u64 offset, std::size_t size, u32 polynomial, u32 init, u32 xorout, bool reflectIn, bool reflectOut) { using Crc = Crc; Crc crc(polynomial, init, xorout, reflectIn, reflectOut); processDataByChunks(data, offset, size, std::bind(&Crc::processBytes, &crc, _1, _2)); return crc.checksum(); } u8 crc8(prv::Provider *&data, u64 offset, size_t size, u32 polynomial, u32 init, u32 xorOut, bool reflectIn, bool reflectOut) { return calcCrc<8>(data, offset, size, polynomial, init, xorOut, reflectIn, reflectOut); } u16 crc16(prv::Provider *&data, u64 offset, size_t size, u32 polynomial, u32 init, u32 xorOut, bool reflectIn, bool reflectOut) { return calcCrc<16>(data, offset, size, polynomial, init, xorOut, reflectIn, reflectOut); } u32 crc32(prv::Provider *&data, u64 offset, size_t size, u32 polynomial, u32 init, u32 xorOut, bool reflectIn, bool reflectOut) { return calcCrc<32>(data, offset, size, polynomial, init, xorOut, reflectIn, reflectOut); } std::array md5(prv::Provider *&data, u64 offset, size_t size) { std::array result = { 0 }; mbedtls_md5_context ctx; mbedtls_md5_init(&ctx); mbedtls_md5_starts(&ctx); processDataByChunks(data, offset, size, std::bind(mbedtls_md5_update, &ctx, _1, _2)); mbedtls_md5_finish(&ctx, result.data()); mbedtls_md5_free(&ctx); return result; } std::array md5(const std::vector &data) { std::array result = { 0 }; mbedtls_md5_context ctx; mbedtls_md5_init(&ctx); mbedtls_md5_starts(&ctx); mbedtls_md5_update(&ctx, data.data(), data.size()); mbedtls_md5_finish(&ctx, result.data()); mbedtls_md5_free(&ctx); return result; } std::array sha1(prv::Provider *&data, u64 offset, size_t size) { std::array result = { 0 }; mbedtls_sha1_context ctx; mbedtls_sha1_init(&ctx); mbedtls_sha1_starts(&ctx); processDataByChunks(data, offset, size, std::bind(mbedtls_sha1_update, &ctx, _1, _2)); mbedtls_sha1_finish(&ctx, result.data()); mbedtls_sha1_free(&ctx); return result; } std::array sha1(const std::vector &data) { std::array result = { 0 }; mbedtls_sha1_context ctx; mbedtls_sha1_init(&ctx); mbedtls_sha1_starts(&ctx); mbedtls_sha1_update(&ctx, data.data(), data.size()); mbedtls_sha1_finish(&ctx, result.data()); mbedtls_sha1_free(&ctx); return result; } std::array sha224(prv::Provider *&data, u64 offset, size_t size) { std::array result = { 0 }; mbedtls_sha256_context ctx; mbedtls_sha256_init(&ctx); mbedtls_sha256_starts(&ctx, true); processDataByChunks(data, offset, size, std::bind(mbedtls_sha256_update, &ctx, _1, _2)); mbedtls_sha256_finish(&ctx, result.data()); mbedtls_sha256_free(&ctx); return result; } std::array sha224(const std::vector &data) { std::array result = { 0 }; mbedtls_sha256_context ctx; mbedtls_sha256_init(&ctx); mbedtls_sha256_starts(&ctx, true); mbedtls_sha256_update(&ctx, data.data(), data.size()); mbedtls_sha256_finish(&ctx, result.data()); mbedtls_sha256_free(&ctx); return result; } std::array sha256(prv::Provider *&data, u64 offset, size_t size) { std::array result = { 0 }; mbedtls_sha256_context ctx; mbedtls_sha256_init(&ctx); mbedtls_sha256_starts(&ctx, false); processDataByChunks(data, offset, size, std::bind(mbedtls_sha256_update, &ctx, _1, _2)); mbedtls_sha256_finish(&ctx, result.data()); mbedtls_sha256_free(&ctx); return result; } std::array sha256(const std::vector &data) { std::array result = { 0 }; mbedtls_sha256_context ctx; mbedtls_sha256_init(&ctx); mbedtls_sha256_starts(&ctx, false); mbedtls_sha256_update(&ctx, data.data(), data.size()); mbedtls_sha256_finish(&ctx, result.data()); mbedtls_sha256_free(&ctx); return result; } std::array sha384(prv::Provider *&data, u64 offset, size_t size) { std::array result = { 0 }; mbedtls_sha512_context ctx; mbedtls_sha512_init(&ctx); mbedtls_sha512_starts(&ctx, true); processDataByChunks(data, offset, size, std::bind(mbedtls_sha512_update, &ctx, _1, _2)); mbedtls_sha512_finish(&ctx, result.data()); mbedtls_sha512_free(&ctx); return result; } std::array sha384(const std::vector &data) { std::array result = { 0 }; mbedtls_sha512_context ctx; mbedtls_sha512_init(&ctx); mbedtls_sha512_starts(&ctx, true); mbedtls_sha512_update(&ctx, data.data(), data.size()); mbedtls_sha512_finish(&ctx, result.data()); mbedtls_sha512_free(&ctx); return result; } std::array sha512(prv::Provider *&data, u64 offset, size_t size) { std::array result = { 0 }; mbedtls_sha512_context ctx; mbedtls_sha512_init(&ctx); mbedtls_sha512_starts(&ctx, false); processDataByChunks(data, offset, size, std::bind(mbedtls_sha512_update, &ctx, _1, _2)); mbedtls_sha512_finish(&ctx, result.data()); mbedtls_sha512_free(&ctx); return result; } std::array sha512(const std::vector &data) { std::array result = { 0 }; mbedtls_sha512_context ctx; mbedtls_sha512_init(&ctx); mbedtls_sha512_starts(&ctx, false); mbedtls_sha512_update(&ctx, data.data(), data.size()); mbedtls_sha512_finish(&ctx, result.data()); mbedtls_sha512_free(&ctx); return result; } std::vector decode64(const std::vector &input) { size_t written = 0; mbedtls_base64_decode(nullptr, 0, &written, reinterpret_cast(input.data()), input.size()); std::vector output(written, 0x00); if (mbedtls_base64_decode(output.data(), output.size(), &written, reinterpret_cast(input.data()), input.size())) return {}; output.resize(written); return output; } std::vector encode64(const std::vector &input) { size_t written = 0; mbedtls_base64_encode(nullptr, 0, &written, reinterpret_cast(input.data()), input.size()); std::vector output(written, 0x00); if (mbedtls_base64_encode(output.data(), output.size(), &written, reinterpret_cast(input.data()), input.size())) return {}; output.resize(written); return output; } std::vector decode16(const std::string &input) { std::vector output(input.length() / 2, 0x00); mbedtls_mpi ctx; mbedtls_mpi_init(&ctx); ON_SCOPE_EXIT { mbedtls_mpi_free(&ctx); }; // read buffered constexpr static auto BufferSize = 0x100; for (size_t offset = 0; offset < input.size(); offset += BufferSize) { std::string inputPart = input.substr(offset, std::min(BufferSize, input.size() - offset)); if (mbedtls_mpi_read_string(&ctx, 16, inputPart.c_str())) return {}; if (mbedtls_mpi_write_binary(&ctx, output.data() + offset / 2, inputPart.size() / 2)) return {}; } return output; } std::string encode16(const std::vector &input) { if (input.empty()) return {}; std::string output(input.size() * 2, '\0'); for (size_t i = 0; i < input.size(); i++) { output[2 * i + 0] = "0123456789ABCDEF"[input[i] / 16]; output[2 * i + 1] = "0123456789ABCDEF"[input[i] % 16]; } return output; } template static T safeLeftShift(T t, u32 shift) { if (shift >= sizeof(t) * 8) { return 0; } else { return t << shift; } } template static T decodeLeb128(const std::vector &bytes) { T value = 0; u32 shift = 0; u8 b = 0; for (u8 byte : bytes) { b = byte; value |= safeLeftShift(static_cast(byte & 0x7F), shift); shift += 7; if ((byte & 0x80) == 0) { break; } } if constexpr(std::is_signed::value) { if ((b & 0x40) != 0) { value |= safeLeftShift(~static_cast(0), shift); } } return value; } u128 decodeUleb128(const std::vector &bytes) { return decodeLeb128(bytes); } i128 decodeSleb128(const std::vector &bytes) { return decodeLeb128(bytes); } template static std::vector encodeLeb128(T value) { std::vector bytes; u8 byte; while (true) { byte = value & 0x7F; value >>= 7; if constexpr(std::is_signed::value) { if (value == 0 && (byte & 0x40) == 0) { break; } if (value == -1 && (byte & 0x40) != 0) { break; } } else { if (value == 0) { break; } } bytes.push_back(byte | 0x80); } bytes.push_back(byte); return bytes; } std::vector encodeUleb128(u128 value) { return encodeLeb128(value); } std::vector encodeSleb128(i128 value) { return encodeLeb128(value); } static std::vector aes(mbedtls_cipher_type_t type, mbedtls_operation_t operation, const std::vector &key, std::array nonce, std::array iv, const std::vector &input) { std::vector output; if (input.empty()) return {}; if (key.size() > 256) return {}; mbedtls_cipher_context_t ctx; auto cipherInfo = mbedtls_cipher_info_from_type(type); mbedtls_cipher_setup(&ctx, cipherInfo); mbedtls_cipher_setkey(&ctx, key.data(), static_cast(key.size() * 8), operation); std::array nonceCounter = { 0 }; std::copy(nonce.begin(), nonce.end(), nonceCounter.begin()); std::copy(iv.begin(), iv.end(), nonceCounter.begin() + 8); size_t outputSize = input.size() + mbedtls_cipher_get_block_size(&ctx); output.resize(outputSize, 0x00); mbedtls_cipher_crypt(&ctx, nonceCounter.data(), nonceCounter.size(), input.data(), input.size(), output.data(), &outputSize); mbedtls_cipher_free(&ctx); output.resize(input.size()); return output; } std::vector aesDecrypt(AESMode mode, KeyLength keyLength, const std::vector &key, std::array nonce, std::array iv, const std::vector &input) { switch (keyLength) { case KeyLength::Key128Bits: if (key.size() != 128 / 8) return {}; break; case KeyLength::Key192Bits: if (key.size() != 192 / 8) return {}; break; case KeyLength::Key256Bits: if (key.size() != 256 / 8) return {}; break; default: return {}; } mbedtls_cipher_type_t type; switch (mode) { case AESMode::ECB: type = MBEDTLS_CIPHER_AES_128_ECB; break; case AESMode::CBC: type = MBEDTLS_CIPHER_AES_128_CBC; break; case AESMode::CFB128: type = MBEDTLS_CIPHER_AES_128_CFB128; break; case AESMode::CTR: type = MBEDTLS_CIPHER_AES_128_CTR; break; case AESMode::GCM: type = MBEDTLS_CIPHER_AES_128_GCM; break; case AESMode::CCM: type = MBEDTLS_CIPHER_AES_128_CCM; break; case AESMode::OFB: type = MBEDTLS_CIPHER_AES_128_OFB; break; case AESMode::XTS: type = MBEDTLS_CIPHER_AES_128_XTS; break; default: return {}; } type = mbedtls_cipher_type_t(type + u8(keyLength)); return aes(type, MBEDTLS_DECRYPT, key, nonce, iv, input); } }