#pragma once #include #include #include #include #include #include #include "config.h" #ifdef __clang__ # pragma clang diagnostic push # pragma clang diagnostic ignored "-Wused-but-marked-unused" #endif #include #if USE_BLAKE3 # include #endif #include #include #include #include #if USE_SSL # include # include # include #endif #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include namespace DB { namespace ErrorCodes { extern const int ILLEGAL_TYPE_OF_ARGUMENT; extern const int BAD_ARGUMENTS; extern const int LOGICAL_ERROR; extern const int NUMBER_OF_ARGUMENTS_DOESNT_MATCH; extern const int NOT_IMPLEMENTED; extern const int ILLEGAL_COLUMN; extern const int SUPPORT_IS_DISABLED; } namespace impl { struct SipHashKey { UInt64 key0 = 0; UInt64 key1 = 0; }; static SipHashKey parseSipHashKey(const ColumnWithTypeAndName & key) { SipHashKey ret; const auto * tuple = checkAndGetColumn(key.column.get()); if (!tuple) throw Exception(ErrorCodes::NOT_IMPLEMENTED, "key must be a tuple"); if (tuple->tupleSize() != 2) throw Exception(ErrorCodes::NOT_IMPLEMENTED, "wrong tuple size: key must be a tuple of 2 UInt64"); if (const auto * key0col = checkAndGetColumn(&(tuple->getColumn(0)))) ret.key0 = key0col->get64(0); else throw Exception(ErrorCodes::NOT_IMPLEMENTED, "first element of the key tuple is not UInt64"); if (const auto * key1col = checkAndGetColumn(&(tuple->getColumn(1)))) ret.key1 = key1col->get64(0); else throw Exception(ErrorCodes::NOT_IMPLEMENTED, "second element of the key tuple is not UInt64"); return ret; } } /** Hashing functions. * * halfMD5: String -> UInt64 * * A faster cryptographic hash function: * sipHash64: String -> UInt64 * * Fast non-cryptographic hash function for strings: * cityHash64: String -> UInt64 * * A non-cryptographic hashes from a tuple of values of any types (uses respective function for strings and intHash64 for numbers): * cityHash64: any* -> UInt64 * sipHash64: any* -> UInt64 * halfMD5: any* -> UInt64 * * Fast non-cryptographic hash function from any integer: * intHash32: number -> UInt32 * intHash64: number -> UInt64 * */ struct IntHash32Impl { using ReturnType = UInt32; static UInt32 apply(UInt64 x) { /// seed is taken from /dev/urandom. It allows you to avoid undesirable dependencies with hashes in different data structures. return intHash32<0x75D9543DE018BF45ULL>(x); } }; struct IntHash64Impl { using ReturnType = UInt64; static UInt64 apply(UInt64 x) { return intHash64(x ^ 0x4CF2D2BAAE6DA887ULL); } }; template T combineHashesFunc(T t1, T t2) { #if __BYTE_ORDER__ == __ORDER_BIG_ENDIAN__ T tmp; reverseMemcpy(&tmp, &t1, sizeof(T)); t1 = tmp; reverseMemcpy(&tmp, &t2, sizeof(T)); t2 = tmp; #endif T hashes[] = {t1, t2}; return HashFunction::apply(reinterpret_cast(hashes), 2 * sizeof(T)); } #if USE_SSL struct HalfMD5Impl { static constexpr auto name = "halfMD5"; using ReturnType = UInt64; static UInt64 apply(const char * begin, size_t size) { union { unsigned char char_data[16]; uint64_t uint64_data; } buf; MD5_CTX ctx; MD5_Init(&ctx); MD5_Update(&ctx, reinterpret_cast(begin), size); MD5_Final(buf.char_data, &ctx); #if __BYTE_ORDER__ == __ORDER_BIG_ENDIAN__ return buf.uint64_data; /// No need to flip bytes on big endian machines #else return std::byteswap(buf.uint64_data); /// Compatibility with existing code. Cast need for old poco AND macos where UInt64 != uint64_t #endif } static UInt64 combineHashes(UInt64 h1, UInt64 h2) { #if __BYTE_ORDER__ == __ORDER_BIG_ENDIAN__ h1 = std::byteswap(h1); h2 = std::byteswap(h2); #endif UInt64 hashes[] = {h1, h2}; return apply(reinterpret_cast(hashes), 16); } /// If true, it will use intHash32 or intHash64 to hash POD types. This behaviour is intended for better performance of some functions. /// Otherwise it will hash bytes in memory as a string using corresponding hash function. static constexpr bool use_int_hash_for_pods = false; }; struct MD4Impl { static constexpr auto name = "MD4"; enum { length = MD4_DIGEST_LENGTH }; static void apply(const char * begin, const size_t size, unsigned char * out_char_data) { MD4_CTX ctx; MD4_Init(&ctx); MD4_Update(&ctx, reinterpret_cast(begin), size); MD4_Final(out_char_data, &ctx); } }; struct MD5Impl { static constexpr auto name = "MD5"; enum { length = MD5_DIGEST_LENGTH }; static void apply(const char * begin, const size_t size, unsigned char * out_char_data) { MD5_CTX ctx; MD5_Init(&ctx); MD5_Update(&ctx, reinterpret_cast(begin), size); MD5_Final(out_char_data, &ctx); } }; struct SHA1Impl { static constexpr auto name = "SHA1"; enum { length = SHA_DIGEST_LENGTH }; static void apply(const char * begin, const size_t size, unsigned char * out_char_data) { SHA_CTX ctx; SHA1_Init(&ctx); SHA1_Update(&ctx, reinterpret_cast(begin), size); SHA1_Final(out_char_data, &ctx); } }; struct SHA224Impl { static constexpr auto name = "SHA224"; enum { length = SHA224_DIGEST_LENGTH }; static void apply(const char * begin, const size_t size, unsigned char * out_char_data) { SHA256_CTX ctx; SHA224_Init(&ctx); SHA224_Update(&ctx, reinterpret_cast(begin), size); SHA224_Final(out_char_data, &ctx); } }; struct SHA256Impl { static constexpr auto name = "SHA256"; enum { length = SHA256_DIGEST_LENGTH }; static void apply(const char * begin, const size_t size, unsigned char * out_char_data) { SHA256_CTX ctx; SHA256_Init(&ctx); SHA256_Update(&ctx, reinterpret_cast(begin), size); SHA256_Final(out_char_data, &ctx); } }; struct SHA384Impl { static constexpr auto name = "SHA384"; enum { length = SHA384_DIGEST_LENGTH }; static void apply(const char * begin, const size_t size, unsigned char * out_char_data) { SHA512_CTX ctx; SHA384_Init(&ctx); SHA384_Update(&ctx, reinterpret_cast(begin), size); SHA384_Final(out_char_data, &ctx); } }; struct SHA512Impl { static constexpr auto name = "SHA512"; enum { length = 64 }; static void apply(const char * begin, const size_t size, unsigned char * out_char_data) { SHA512_CTX ctx; SHA512_Init(&ctx); SHA512_Update(&ctx, reinterpret_cast(begin), size); SHA512_Final(out_char_data, &ctx); } }; #endif struct SipHash64Impl { static constexpr auto name = "sipHash64"; using ReturnType = UInt64; static UInt64 apply(const char * begin, size_t size) { return sipHash64(begin, size); } static UInt64 combineHashes(UInt64 h1, UInt64 h2) { return combineHashesFunc(h1, h2); } static constexpr bool use_int_hash_for_pods = false; }; struct SipHash64KeyedImpl { static constexpr auto name = "sipHash64Keyed"; using ReturnType = UInt64; using Key = impl::SipHashKey; static Key parseKey(const ColumnWithTypeAndName & key) { return impl::parseSipHashKey(key); } static UInt64 applyKeyed(const Key & key, const char * begin, size_t size) { return sipHash64Keyed(key.key0, key.key1, begin, size); } static UInt64 combineHashesKeyed(const Key & key, UInt64 h1, UInt64 h2) { #if __BYTE_ORDER__ == __ORDER_BIG_ENDIAN__ h1 = std::byteswap(h1); h2 = std::byteswap(h2); #endif UInt64 hashes[] = {h1, h2}; return applyKeyed(key, reinterpret_cast(hashes), 2 * sizeof(UInt64)); } static constexpr bool use_int_hash_for_pods = false; }; struct SipHash128Impl { static constexpr auto name = "sipHash128"; using ReturnType = UInt128; static UInt128 combineHashes(UInt128 h1, UInt128 h2) { return combineHashesFunc(h1, h2); } static UInt128 apply(const char * data, const size_t size) { return sipHash128(data, size); } static constexpr bool use_int_hash_for_pods = false; }; struct SipHash128KeyedImpl { static constexpr auto name = "sipHash128Keyed"; using ReturnType = UInt128; using Key = impl::SipHashKey; static Key parseKey(const ColumnWithTypeAndName & key) { return impl::parseSipHashKey(key); } static UInt128 applyKeyed(const Key & key, const char * begin, size_t size) { return sipHash128Keyed(key.key0, key.key1, begin, size); } static UInt128 combineHashesKeyed(const Key & key, UInt128 h1, UInt128 h2) { #if __BYTE_ORDER__ == __ORDER_BIG_ENDIAN__ UInt128 tmp; reverseMemcpy(&tmp, &h1, sizeof(UInt128)); h1 = tmp; reverseMemcpy(&tmp, &h2, sizeof(UInt128)); h2 = tmp; #endif UInt128 hashes[] = {h1, h2}; return applyKeyed(key, reinterpret_cast(hashes), 2 * sizeof(UInt128)); } static constexpr bool use_int_hash_for_pods = false; }; struct SipHash128ReferenceImpl { static constexpr auto name = "sipHash128Reference"; using ReturnType = UInt128; static UInt128 combineHashes(UInt128 h1, UInt128 h2) { return combineHashesFunc(h1, h2); } static UInt128 apply(const char * data, const size_t size) { return sipHash128Reference(data, size); } static constexpr bool use_int_hash_for_pods = false; }; struct SipHash128ReferenceKeyedImpl { static constexpr auto name = "sipHash128ReferenceKeyed"; using ReturnType = UInt128; using Key = impl::SipHashKey; static Key parseKey(const ColumnWithTypeAndName & key) { return impl::parseSipHashKey(key); } static UInt128 applyKeyed(const Key & key, const char * begin, size_t size) { return sipHash128ReferenceKeyed(key.key0, key.key1, begin, size); } static UInt128 combineHashesKeyed(const Key & key, UInt128 h1, UInt128 h2) { #if __BYTE_ORDER__ == __ORDER_BIG_ENDIAN__ UInt128 tmp; reverseMemcpy(&tmp, &h1, sizeof(UInt128)); h1 = tmp; reverseMemcpy(&tmp, &h2, sizeof(UInt128)); h2 = tmp; #endif UInt128 hashes[] = {h1, h2}; return applyKeyed(key, reinterpret_cast(hashes), 2 * sizeof(UInt128)); } static constexpr bool use_int_hash_for_pods = false; }; /** Why we need MurmurHash2? * MurmurHash2 is an outdated hash function, superseded by MurmurHash3 and subsequently by CityHash, xxHash, HighwayHash. * Usually there is no reason to use MurmurHash. * It is needed for the cases when you already have MurmurHash in some applications and you want to reproduce it * in ClickHouse as is. For example, it is needed to reproduce the behaviour * for NGINX a/b testing module: https://nginx.ru/en/docs/http/ngx_http_split_clients_module.html */ struct MurmurHash2Impl32 { static constexpr auto name = "murmurHash2_32"; using ReturnType = UInt32; static UInt32 apply(const char * data, const size_t size) { return MurmurHash2(data, size, 0); } static UInt32 combineHashes(UInt32 h1, UInt32 h2) { return IntHash32Impl::apply(h1) ^ h2; } static constexpr bool use_int_hash_for_pods = false; }; struct MurmurHash2Impl64 { static constexpr auto name = "murmurHash2_64"; using ReturnType = UInt64; static UInt64 apply(const char * data, const size_t size) { return MurmurHash64A(data, size, 0); } static UInt64 combineHashes(UInt64 h1, UInt64 h2) { return IntHash64Impl::apply(h1) ^ h2; } static constexpr bool use_int_hash_for_pods = false; }; /// To be compatible with gcc: https://github.com/gcc-mirror/gcc/blob/41d6b10e96a1de98e90a7c0378437c3255814b16/libstdc%2B%2B-v3/include/bits/functional_hash.h#L191 struct GccMurmurHashImpl { static constexpr auto name = "gccMurmurHash"; using ReturnType = UInt64; static UInt64 apply(const char * data, const size_t size) { return MurmurHash64A(data, size, 0xc70f6907UL); } static UInt64 combineHashes(UInt64 h1, UInt64 h2) { return IntHash64Impl::apply(h1) ^ h2; } static constexpr bool use_int_hash_for_pods = false; }; struct MurmurHash3Impl32 { static constexpr auto name = "murmurHash3_32"; using ReturnType = UInt32; static UInt32 apply(const char * data, const size_t size) { union { UInt32 h; char bytes[sizeof(h)]; }; MurmurHash3_x86_32(data, size, 0, bytes); return h; } static UInt32 combineHashes(UInt32 h1, UInt32 h2) { return IntHash32Impl::apply(h1) ^ h2; } static constexpr bool use_int_hash_for_pods = false; }; struct MurmurHash3Impl64 { static constexpr auto name = "murmurHash3_64"; using ReturnType = UInt64; static UInt64 apply(const char * data, const size_t size) { union { UInt64 h[2]; char bytes[16]; }; MurmurHash3_x64_128(data, size, 0, bytes); return h[0] ^ h[1]; } static UInt64 combineHashes(UInt64 h1, UInt64 h2) { return IntHash64Impl::apply(h1) ^ h2; } static constexpr bool use_int_hash_for_pods = false; }; struct MurmurHash3Impl128 { static constexpr auto name = "murmurHash3_128"; using ReturnType = UInt128; static UInt128 apply(const char * data, const size_t size) { char bytes[16]; MurmurHash3_x64_128(data, size, 0, bytes); return *reinterpret_cast(bytes); } static UInt128 combineHashes(UInt128 h1, UInt128 h2) { return combineHashesFunc(h1, h2); } static constexpr bool use_int_hash_for_pods = false; }; /// Care should be taken to do all calculation in unsigned integers (to avoid undefined behaviour on overflow) /// but obtain the same result as it is done in signed integers with two's complement arithmetic. struct JavaHashImpl { static constexpr auto name = "javaHash"; using ReturnType = Int32; static ReturnType apply(int64_t x) { return static_cast( static_cast(x) ^ static_cast(static_cast(x) >> 32)); } template || std::is_same_v || std::is_same_v, T>::type * = nullptr> static ReturnType apply(T x) { return x; } template && !std::is_same_v && !std::is_same_v && !std::is_same_v, T>::type * = nullptr> static ReturnType apply(T x) { if (std::is_unsigned_v) throw Exception(ErrorCodes::NOT_IMPLEMENTED, "Unsigned types are not supported"); const size_t size = sizeof(T); const char * data = reinterpret_cast(&x); return apply(data, size); } static ReturnType apply(const char * data, const size_t size) { UInt32 h = 0; for (size_t i = 0; i < size; ++i) h = 31 * h + static_cast(static_cast(data[i])); return static_cast(h); } static ReturnType combineHashes(Int32, Int32) { throw Exception(ErrorCodes::NOT_IMPLEMENTED, "Java hash is not combineable for multiple arguments"); } static constexpr bool use_int_hash_for_pods = false; }; struct JavaHashUTF16LEImpl { static constexpr auto name = "javaHashUTF16LE"; using ReturnType = Int32; static Int32 apply(const char * raw_data, const size_t raw_size) { char * data = const_cast(raw_data); size_t size = raw_size; // Remove Byte-order-mark(0xFFFE) for UTF-16LE if (size >= 2 && data[0] == '\xFF' && data[1] == '\xFE') { data += 2; size -= 2; } if (size % 2 != 0) throw Exception(ErrorCodes::BAD_ARGUMENTS, "Arguments for javaHashUTF16LE must be in the form of UTF-16"); UInt32 h = 0; for (size_t i = 0; i < size; i += 2) h = 31 * h + static_cast(static_cast(data[i]) | static_cast(data[i + 1]) << 8); return static_cast(h); } static Int32 combineHashes(Int32, Int32) { throw Exception(ErrorCodes::NOT_IMPLEMENTED, "Java hash is not combineable for multiple arguments"); } static constexpr bool use_int_hash_for_pods = false; }; /// This is just JavaHash with zeroed out sign bit. /// This function is used in Hive for versions before 3.0, /// after 3.0, Hive uses murmur-hash3. struct HiveHashImpl { static constexpr auto name = "hiveHash"; using ReturnType = Int32; static Int32 apply(const char * data, const size_t size) { return static_cast(0x7FFFFFFF & static_cast(JavaHashImpl::apply(data, size))); } static Int32 combineHashes(Int32, Int32) { throw Exception(ErrorCodes::NOT_IMPLEMENTED, "Hive hash is not combineable for multiple arguments"); } static constexpr bool use_int_hash_for_pods = false; }; struct ImplCityHash64 { static constexpr auto name = "cityHash64"; using ReturnType = UInt64; using uint128_t = CityHash_v1_0_2::uint128; static auto combineHashes(UInt64 h1, UInt64 h2) { return CityHash_v1_0_2::Hash128to64(uint128_t(h1, h2)); } static auto apply(const char * s, const size_t len) { return CityHash_v1_0_2::CityHash64(s, len); } static constexpr bool use_int_hash_for_pods = true; }; // see farmhash.h for definition of NAMESPACE_FOR_HASH_FUNCTIONS struct ImplFarmFingerprint64 { static constexpr auto name = "farmFingerprint64"; using ReturnType = UInt64; using uint128_t = NAMESPACE_FOR_HASH_FUNCTIONS::uint128_t; static auto combineHashes(UInt64 h1, UInt64 h2) { return NAMESPACE_FOR_HASH_FUNCTIONS::Fingerprint(uint128_t(h1, h2)); } static auto apply(const char * s, const size_t len) { return NAMESPACE_FOR_HASH_FUNCTIONS::Fingerprint64(s, len); } static constexpr bool use_int_hash_for_pods = true; }; // see farmhash.h for definition of NAMESPACE_FOR_HASH_FUNCTIONS struct ImplFarmHash64 { static constexpr auto name = "farmHash64"; using ReturnType = UInt64; using uint128_t = NAMESPACE_FOR_HASH_FUNCTIONS::uint128_t; static auto combineHashes(UInt64 h1, UInt64 h2) { return NAMESPACE_FOR_HASH_FUNCTIONS::Hash128to64(uint128_t(h1, h2)); } static auto apply(const char * s, const size_t len) { return NAMESPACE_FOR_HASH_FUNCTIONS::Hash64(s, len); } static constexpr bool use_int_hash_for_pods = true; }; struct ImplMetroHash64 { static constexpr auto name = "metroHash64"; using ReturnType = UInt64; using uint128_t = CityHash_v1_0_2::uint128; static auto combineHashes(UInt64 h1, UInt64 h2) { return CityHash_v1_0_2::Hash128to64(uint128_t(h1, h2)); } static auto apply(const char * s, const size_t len) { union { UInt64 u64; uint8_t u8[sizeof(u64)]; }; metrohash64_1(reinterpret_cast(s), len, 0, u8); return u64; } static constexpr bool use_int_hash_for_pods = true; }; struct ImplXxHash32 { static constexpr auto name = "xxHash32"; using ReturnType = UInt32; static auto apply(const char * s, const size_t len) { return XXH_INLINE_XXH32(s, len, 0); } /** * With current implementation with more than 1 arguments it will give the results * non-reproducible from outside of CH. * * Proper way of combining several input is to use streaming mode of hash function * https://github.com/Cyan4973/xxHash/issues/114#issuecomment-334908566 * * In common case doable by init_state / update_state / finalize_state */ static auto combineHashes(UInt32 h1, UInt32 h2) { return IntHash32Impl::apply(h1) ^ h2; } static constexpr bool use_int_hash_for_pods = false; }; struct ImplXxHash64 { static constexpr auto name = "xxHash64"; using ReturnType = UInt64; using uint128_t = CityHash_v1_0_2::uint128; static auto apply(const char * s, const size_t len) { return XXH_INLINE_XXH64(s, len, 0); } /* With current implementation with more than 1 arguments it will give the results non-reproducible from outside of CH. (see comment on ImplXxHash32). */ static auto combineHashes(UInt64 h1, UInt64 h2) { return CityHash_v1_0_2::Hash128to64(uint128_t(h1, h2)); } static constexpr bool use_int_hash_for_pods = false; }; struct ImplXXH3 { static constexpr auto name = "xxh3"; using ReturnType = UInt64; using uint128_t = CityHash_v1_0_2::uint128; static auto apply(const char * s, const size_t len) { return XXH_INLINE_XXH3_64bits(s, len); } /* With current implementation with more than 1 arguments it will give the results non-reproducible from outside of CH. (see comment on ImplXxHash32). */ static auto combineHashes(UInt64 h1, UInt64 h2) { return CityHash_v1_0_2::Hash128to64(uint128_t(h1, h2)); } static constexpr bool use_int_hash_for_pods = false; }; struct ImplBLAKE3 { static constexpr auto name = "BLAKE3"; enum { length = 32 }; #if !USE_BLAKE3 [[noreturn]] static void apply(const char * begin, const size_t size, unsigned char* out_char_data) { UNUSED(begin); UNUSED(size); UNUSED(out_char_data); throw Exception(ErrorCodes::SUPPORT_IS_DISABLED, "BLAKE3 is not available. Rust code or BLAKE3 itself may be disabled."); } #else static void apply(const char * begin, const size_t size, unsigned char* out_char_data) { #if defined(MEMORY_SANITIZER) auto err_msg = blake3_apply_shim_msan_compat(begin, safe_cast(size), out_char_data); __msan_unpoison(out_char_data, length); #else auto err_msg = blake3_apply_shim(begin, safe_cast(size), out_char_data); #endif if (err_msg != nullptr) { auto err_st = std::string(err_msg); blake3_free_char_pointer(err_msg); throw Exception(ErrorCodes::ILLEGAL_TYPE_OF_ARGUMENT, "Function returned error message: {}", err_st); } } #endif }; template class FunctionStringHashFixedString : public IFunction { public: static constexpr auto name = Impl::name; static FunctionPtr create(ContextPtr) { return std::make_shared(); } String getName() const override { return name; } size_t getNumberOfArguments() const override { return 1; } DataTypePtr getReturnTypeImpl(const DataTypes & arguments) const override { if (!isStringOrFixedString(arguments[0]) && !isIPv6(arguments[0])) throw Exception(ErrorCodes::ILLEGAL_TYPE_OF_ARGUMENT, "Illegal type {} of argument of function {}", arguments[0]->getName(), getName()); return std::make_shared(Impl::length); } bool useDefaultImplementationForConstants() const override { return true; } bool isSuitableForShortCircuitArgumentsExecution(const DataTypesWithConstInfo & /*arguments*/) const override { return true; } ColumnPtr executeImpl(const ColumnsWithTypeAndName & arguments, const DataTypePtr &, size_t /*input_rows_count*/) const override { if (const ColumnString * col_from = checkAndGetColumn(arguments[0].column.get())) { auto col_to = ColumnFixedString::create(Impl::length); const typename ColumnString::Chars & data = col_from->getChars(); const typename ColumnString::Offsets & offsets = col_from->getOffsets(); auto & chars_to = col_to->getChars(); const auto size = offsets.size(); chars_to.resize(size * Impl::length); ColumnString::Offset current_offset = 0; for (size_t i = 0; i < size; ++i) { Impl::apply( reinterpret_cast(&data[current_offset]), offsets[i] - current_offset - 1, reinterpret_cast(&chars_to[i * Impl::length])); current_offset = offsets[i]; } return col_to; } else if ( const ColumnFixedString * col_from_fix = checkAndGetColumn(arguments[0].column.get())) { auto col_to = ColumnFixedString::create(Impl::length); const typename ColumnFixedString::Chars & data = col_from_fix->getChars(); const auto size = col_from_fix->size(); auto & chars_to = col_to->getChars(); const auto length = col_from_fix->getN(); chars_to.resize(size * Impl::length); for (size_t i = 0; i < size; ++i) { Impl::apply( reinterpret_cast(&data[i * length]), length, reinterpret_cast(&chars_to[i * Impl::length])); } return col_to; } else if ( const ColumnIPv6 * col_from_ip = checkAndGetColumn(arguments[0].column.get())) { auto col_to = ColumnFixedString::create(Impl::length); const typename ColumnIPv6::Container & data = col_from_ip->getData(); const auto size = col_from_ip->size(); auto & chars_to = col_to->getChars(); const auto length = IPV6_BINARY_LENGTH; chars_to.resize(size * Impl::length); for (size_t i = 0; i < size; ++i) { Impl::apply( reinterpret_cast(&data[i * length]), length, reinterpret_cast(&chars_to[i * Impl::length])); } return col_to; } else throw Exception(ErrorCodes::ILLEGAL_COLUMN, "Illegal column {} of first argument of function {}", arguments[0].column->getName(), getName()); } }; DECLARE_MULTITARGET_CODE( template class FunctionIntHash : public IFunction { public: static constexpr auto name = Name::name; private: using ToType = typename Impl::ReturnType; template ColumnPtr executeType(const ColumnsWithTypeAndName & arguments) const { using ColVecType = ColumnVectorOrDecimal; if (const ColVecType * col_from = checkAndGetColumn(arguments[0].column.get())) { auto col_to = ColumnVector::create(); const typename ColVecType::Container & vec_from = col_from->getData(); typename ColumnVector::Container & vec_to = col_to->getData(); size_t size = vec_from.size(); vec_to.resize(size); for (size_t i = 0; i < size; ++i) vec_to[i] = Impl::apply(vec_from[i]); return col_to; } else throw Exception(ErrorCodes::ILLEGAL_COLUMN, "Illegal column {} of first argument of function {}", arguments[0].column->getName(), Name::name); } public: String getName() const override { return name; } size_t getNumberOfArguments() const override { return 1; } DataTypePtr getReturnTypeImpl(const DataTypes & arguments) const override { if (!arguments[0]->isValueRepresentedByNumber()) throw Exception(ErrorCodes::ILLEGAL_TYPE_OF_ARGUMENT, "Illegal type {} of argument of function {}", arguments[0]->getName(), getName()); return std::make_shared>(); } bool useDefaultImplementationForConstants() const override { return true; } bool isSuitableForShortCircuitArgumentsExecution(const DataTypesWithConstInfo & /*arguments*/) const override { return false; } ColumnPtr executeImpl(const ColumnsWithTypeAndName & arguments, const DataTypePtr &, size_t /*input_rows_count*/) const override { const IDataType * from_type = arguments[0].type.get(); WhichDataType which(from_type); if (which.isUInt8()) return executeType(arguments); else if (which.isUInt16()) return executeType(arguments); else if (which.isUInt32()) return executeType(arguments); else if (which.isUInt64()) return executeType(arguments); else if (which.isInt8()) return executeType(arguments); else if (which.isInt16()) return executeType(arguments); else if (which.isInt32()) return executeType(arguments); else if (which.isInt64()) return executeType(arguments); else if (which.isDate()) return executeType(arguments); else if (which.isDate32()) return executeType(arguments); else if (which.isDateTime()) return executeType(arguments); else if (which.isDecimal32()) return executeType(arguments); else if (which.isDecimal64()) return executeType(arguments); else if (which.isIPv4()) return executeType(arguments); else throw Exception(ErrorCodes::ILLEGAL_TYPE_OF_ARGUMENT, "Illegal type {} of argument of function {}", arguments[0].type->getName(), getName()); } }; ) // DECLARE_MULTITARGET_CODE template class FunctionIntHash : public TargetSpecific::Default::FunctionIntHash { public: explicit FunctionIntHash(ContextPtr context) : selector(context) { selector.registerImplementation>(); #if USE_MULTITARGET_CODE selector.registerImplementation>(); selector.registerImplementation>(); #endif } ColumnPtr executeImpl(const ColumnsWithTypeAndName & arguments, const DataTypePtr & result_type, size_t input_rows_count) const override { return selector.selectAndExecute(arguments, result_type, input_rows_count); } static FunctionPtr create(ContextPtr context) { return std::make_shared(context); } private: ImplementationSelector selector; }; DECLARE_MULTITARGET_CODE( template class FunctionAnyHash : public IFunction { public: static constexpr auto name = Impl::name; private: using ToType = typename Impl::ReturnType; template void executeIntType(const KeyType & key, const IColumn * column, typename ColumnVector::Container & vec_to) const { using ColVecType = ColumnVectorOrDecimal; if (const ColVecType * col_from = checkAndGetColumn(column)) { const typename ColVecType::Container & vec_from = col_from->getData(); size_t size = vec_from.size(); for (size_t i = 0; i < size; ++i) { ToType h; if constexpr (Impl::use_int_hash_for_pods) { if constexpr (std::is_same_v) h = IntHash64Impl::apply(bit_cast(vec_from[i])); else h = IntHash32Impl::apply(bit_cast(vec_from[i])); } else { if constexpr (std::is_same_v) h = JavaHashImpl::apply(vec_from[i]); else { FromType v = vec_from[i]; if constexpr (std::endian::native == std::endian::big) { FromType tmp_v; reverseMemcpy(&tmp_v, &v, sizeof(v)); v = tmp_v; } h = apply(key, reinterpret_cast(&v), sizeof(v)); } } if constexpr (first) vec_to[i] = h; else vec_to[i] = combineHashes(key, vec_to[i], h); } } else if (auto col_from_const = checkAndGetColumnConst(column)) { auto value = col_from_const->template getValue(); ToType hash; if constexpr (std::is_same_v) hash = IntHash64Impl::apply(bit_cast(value)); else hash = IntHash32Impl::apply(bit_cast(value)); size_t size = vec_to.size(); if constexpr (first) vec_to.assign(size, hash); else { for (size_t i = 0; i < size; ++i) vec_to[i] = combineHashes(key, vec_to[i], hash); } } else throw Exception(ErrorCodes::ILLEGAL_COLUMN, "Illegal column {} of argument of function {}", column->getName(), getName()); } template void executeBigIntType(const KeyType & key, const IColumn * column, typename ColumnVector::Container & vec_to) const { using ColVecType = ColumnVectorOrDecimal; if (const ColVecType * col_from = checkAndGetColumn(column)) { const typename ColVecType::Container & vec_from = col_from->getData(); size_t size = vec_from.size(); for (size_t i = 0; i < size; ++i) { ToType h; if constexpr (std::endian::native == std::endian::little) { h = apply(key, reinterpret_cast(&vec_from[i]), sizeof(vec_from[i])); } else { char tmp_buffer[sizeof(vec_from[i])]; reverseMemcpy(tmp_buffer, &vec_from[i], sizeof(vec_from[i])); h = apply(key, reinterpret_cast(tmp_buffer), sizeof(vec_from[i])); } if constexpr (first) vec_to[i] = h; else vec_to[i] = combineHashes(key, vec_to[i], h); } } else if (auto col_from_const = checkAndGetColumnConst(column)) { auto value = col_from_const->template getValue(); ToType h; if constexpr (std::endian::native == std::endian::little) { h = apply(key, reinterpret_cast(&value), sizeof(value)); } else { char tmp_buffer[sizeof(value)]; reverseMemcpy(tmp_buffer, &value, sizeof(value)); h = apply(key, reinterpret_cast(tmp_buffer), sizeof(value)); } size_t size = vec_to.size(); if constexpr (first) vec_to.assign(size, h); else { for (size_t i = 0; i < size; ++i) vec_to[i] = combineHashes(key, vec_to[i], h); } } else throw Exception(ErrorCodes::ILLEGAL_COLUMN, "Illegal column {} of argument of function {}", column->getName(), getName()); } template void executeGeneric(const KeyType & key, const IColumn * column, typename ColumnVector::Container & vec_to) const { for (size_t i = 0, size = column->size(); i < size; ++i) { StringRef bytes = column->getDataAt(i); const ToType h = apply(key, bytes.data, bytes.size); if constexpr (first) vec_to[i] = h; else vec_to[i] = combineHashes(key, vec_to[i], h); } } template void executeString(const KeyType & key, const IColumn * column, typename ColumnVector::Container & vec_to) const { if (const ColumnString * col_from = checkAndGetColumn(column)) { const typename ColumnString::Chars & data = col_from->getChars(); const typename ColumnString::Offsets & offsets = col_from->getOffsets(); size_t size = offsets.size(); ColumnString::Offset current_offset = 0; for (size_t i = 0; i < size; ++i) { const ToType h = apply(key, reinterpret_cast(&data[current_offset]), offsets[i] - current_offset - 1); if constexpr (first) vec_to[i] = h; else vec_to[i] = combineHashes(key, vec_to[i], h); current_offset = offsets[i]; } } else if (const ColumnFixedString * col_from_fixed = checkAndGetColumn(column)) { const typename ColumnString::Chars & data = col_from_fixed->getChars(); size_t n = col_from_fixed->getN(); size_t size = data.size() / n; for (size_t i = 0; i < size; ++i) { const ToType h = apply(key, reinterpret_cast(&data[i * n]), n); if constexpr (first) vec_to[i] = h; else vec_to[i] = combineHashes(key, vec_to[i], h); } } else if (const ColumnConst * col_from_const = checkAndGetColumnConstStringOrFixedString(column)) { String value = col_from_const->getValue(); const ToType hash = apply(key, value.data(), value.size()); const size_t size = vec_to.size(); if constexpr (first) { vec_to.assign(size, hash); } else { for (size_t i = 0; i < size; ++i) { vec_to[i] = combineHashes(key, vec_to[i], hash); } } } else throw Exception(ErrorCodes::ILLEGAL_COLUMN, "Illegal column {} of first argument of function {}", column->getName(), getName()); } template void executeArray(const KeyType & key, const IDataType * type, const IColumn * column, typename ColumnVector::Container & vec_to) const { const IDataType * nested_type = typeid_cast(type)->getNestedType().get(); if (const ColumnArray * col_from = checkAndGetColumn(column)) { const IColumn * nested_column = &col_from->getData(); const ColumnArray::Offsets & offsets = col_from->getOffsets(); const size_t nested_size = nested_column->size(); typename ColumnVector::Container vec_temp(nested_size); bool nested_is_first = true; executeForArgument(key, nested_type, nested_column, vec_temp, nested_is_first); const size_t size = offsets.size(); ColumnArray::Offset current_offset = 0; for (size_t i = 0; i < size; ++i) { ColumnArray::Offset next_offset = offsets[i]; ToType h; if constexpr (std::is_same_v) h = IntHash64Impl::apply(next_offset - current_offset); else h = IntHash32Impl::apply(next_offset - current_offset); if constexpr (first) vec_to[i] = h; else vec_to[i] = combineHashes(key, vec_to[i], h); for (size_t j = current_offset; j < next_offset; ++j) vec_to[i] = combineHashes(key, vec_to[i], vec_temp[j]); current_offset = offsets[i]; } } else if (const ColumnConst * col_from_const = checkAndGetColumnConst(column)) { /// NOTE: here, of course, you can do without the materialization of the column. ColumnPtr full_column = col_from_const->convertToFullColumn(); executeArray(key, type, full_column.get(), vec_to); } else throw Exception(ErrorCodes::ILLEGAL_COLUMN, "Illegal column {} of first argument of function {}", column->getName(), getName()); } template void executeAny(const KeyType & key, const IDataType * from_type, const IColumn * icolumn, typename ColumnVector::Container & vec_to) const { WhichDataType which(from_type); if (icolumn->size() != vec_to.size()) throw Exception(ErrorCodes::LOGICAL_ERROR, "Argument column '{}' size {} doesn't match result column size {} of function {}", icolumn->getName(), icolumn->size(), vec_to.size(), getName()); if (which.isUInt8()) executeIntType(key, icolumn, vec_to); else if (which.isUInt16()) executeIntType(key, icolumn, vec_to); else if (which.isUInt32()) executeIntType(key, icolumn, vec_to); else if (which.isUInt64()) executeIntType(key, icolumn, vec_to); else if (which.isUInt128()) executeBigIntType(key, icolumn, vec_to); else if (which.isUInt256()) executeBigIntType(key, icolumn, vec_to); else if (which.isInt8()) executeIntType(key, icolumn, vec_to); else if (which.isInt16()) executeIntType(key, icolumn, vec_to); else if (which.isInt32()) executeIntType(key, icolumn, vec_to); else if (which.isInt64()) executeIntType(key, icolumn, vec_to); else if (which.isInt128()) executeBigIntType(key, icolumn, vec_to); else if (which.isInt256()) executeBigIntType(key, icolumn, vec_to); else if (which.isUUID()) executeBigIntType(key, icolumn, vec_to); else if (which.isIPv4()) executeIntType(key, icolumn, vec_to); else if (which.isIPv6()) executeBigIntType(key, icolumn, vec_to); else if (which.isEnum8()) executeIntType(key, icolumn, vec_to); else if (which.isEnum16()) executeIntType(key, icolumn, vec_to); else if (which.isDate()) executeIntType(key, icolumn, vec_to); else if (which.isDate32()) executeIntType(key, icolumn, vec_to); else if (which.isDateTime()) executeIntType(key, icolumn, vec_to); /// TODO: executeIntType() for Decimal32/64 leads to incompatible result else if (which.isDecimal32()) executeBigIntType(key, icolumn, vec_to); else if (which.isDecimal64()) executeBigIntType(key, icolumn, vec_to); else if (which.isDecimal128()) executeBigIntType(key, icolumn, vec_to); else if (which.isDecimal256()) executeBigIntType(key, icolumn, vec_to); else if (which.isFloat32()) executeIntType(key, icolumn, vec_to); else if (which.isFloat64()) executeIntType(key, icolumn, vec_to); else if (which.isString()) executeString(key, icolumn, vec_to); else if (which.isFixedString()) executeString(key, icolumn, vec_to); else if (which.isArray()) executeArray(key, from_type, icolumn, vec_to); else executeGeneric(key, icolumn, vec_to); } void executeForArgument(const KeyType & key, const IDataType * type, const IColumn * column, typename ColumnVector::Container & vec_to, bool & is_first) const { /// Flattening of tuples. if (const ColumnTuple * tuple = typeid_cast(column)) { const auto & tuple_columns = tuple->getColumns(); const DataTypes & tuple_types = typeid_cast(*type).getElements(); size_t tuple_size = tuple_columns.size(); for (size_t i = 0; i < tuple_size; ++i) executeForArgument(key, tuple_types[i].get(), tuple_columns[i].get(), vec_to, is_first); } else if (const ColumnTuple * tuple_const = checkAndGetColumnConstData(column)) { const auto & tuple_columns = tuple_const->getColumns(); const DataTypes & tuple_types = typeid_cast(*type).getElements(); size_t tuple_size = tuple_columns.size(); for (size_t i = 0; i < tuple_size; ++i) { auto tmp = ColumnConst::create(tuple_columns[i], column->size()); executeForArgument(key, tuple_types[i].get(), tmp.get(), vec_to, is_first); } } else if (const auto * map = checkAndGetColumn(column)) { const auto & type_map = assert_cast(*type); executeForArgument(key, type_map.getNestedType().get(), map->getNestedColumnPtr().get(), vec_to, is_first); } else if (const auto * const_map = checkAndGetColumnConst(column)) { executeForArgument(key, type, const_map->convertToFullColumnIfConst().get(), vec_to, is_first); } else { if (is_first) executeAny(key, type, column, vec_to); else executeAny(key, type, column, vec_to); } is_first = false; } public: String getName() const override { return name; } bool isVariadic() const override { return true; } size_t getNumberOfArguments() const override { return 0; } bool useDefaultImplementationForConstants() const override { return true; } bool isSuitableForShortCircuitArgumentsExecution(const DataTypesWithConstInfo & /*arguments*/) const override { return true; } DataTypePtr getReturnTypeImpl(const DataTypes & /*arguments*/) const override { if constexpr (std::is_same_v) /// backward-compatible { return std::make_shared(sizeof(UInt128)); } else return std::make_shared>(); } ColumnPtr executeImpl(const ColumnsWithTypeAndName & arguments, const DataTypePtr &, size_t input_rows_count) const override { auto col_to = ColumnVector::create(input_rows_count); typename ColumnVector::Container & vec_to = col_to->getData(); /// If using a "keyed" algorithm, the first argument is the key and /// the data starts from the second argument. /// Otherwise there is no key and all arguments are interpreted as data. constexpr size_t first_data_argument = Keyed; if (arguments.size() <= first_data_argument) { /// Return a fixed random-looking magic number when input is empty vec_to.assign(input_rows_count, static_cast(0xe28dbde7fe22e41c)); } KeyType key{}; if constexpr (Keyed) if (!arguments.empty()) key = Impl::parseKey(arguments[0]); /// The function supports arbitrary number of arguments of arbitrary types. bool is_first_argument = true; for (size_t i = first_data_argument; i < arguments.size(); ++i) { const auto & col = arguments[i]; executeForArgument(key, col.type.get(), col.column.get(), vec_to, is_first_argument); } if constexpr (std::is_same_v) /// backward-compatible { auto col_to_fixed_string = ColumnFixedString::create(sizeof(UInt128)); col_to_fixed_string->getChars() = std::move(*reinterpret_cast(&col_to->getData())); return col_to_fixed_string; } return col_to; } static ToType apply(const KeyType & key, const char * begin, size_t size) { if constexpr (Keyed) return Impl::applyKeyed(key, begin, size); else return Impl::apply(begin, size); } static ToType combineHashes(const KeyType & key, ToType h1, ToType h2) { if constexpr (Keyed) return Impl::combineHashesKeyed(key, h1, h2); else return Impl::combineHashes(h1, h2); } }; ) // DECLARE_MULTITARGET_CODE template class FunctionAnyHash : public TargetSpecific::Default::FunctionAnyHash { public: explicit FunctionAnyHash(ContextPtr context) : selector(context) { selector.registerImplementation>(); #if USE_MULTITARGET_CODE selector.registerImplementation>(); selector.registerImplementation>(); #endif } ColumnPtr executeImpl(const ColumnsWithTypeAndName & arguments, const DataTypePtr & result_type, size_t input_rows_count) const override { return selector.selectAndExecute(arguments, result_type, input_rows_count); } static FunctionPtr create(ContextPtr context) { return std::make_shared(context); } private: ImplementationSelector selector; }; struct URLHashImpl { static UInt64 apply(const char * data, const size_t size) { /// do not take last slash, '?' or '#' character into account if (size > 0 && (data[size - 1] == '/' || data[size - 1] == '?' || data[size - 1] == '#')) return CityHash_v1_0_2::CityHash64(data, size - 1); return CityHash_v1_0_2::CityHash64(data, size); } }; struct URLHierarchyHashImpl { static size_t findLevelLength(const UInt64 level, const char * begin, const char * end) { const auto * pos = begin; /// Let's parse everything that goes before the path /// Suppose that the protocol has already been changed to lowercase. while (pos < end && ((*pos > 'a' && *pos < 'z') || (*pos > '0' && *pos < '9'))) ++pos; /** We will calculate the hierarchy only for URLs in which there is a protocol, and after it there are two slashes. * (http, file - fit, mailto, magnet - do not fit), and after two slashes there is still something * For the rest, simply return the full URL as the only element of the hierarchy. */ if (pos == begin || pos == end || !(*pos++ == ':' && pos < end && *pos++ == '/' && pos < end && *pos++ == '/' && pos < end)) { pos = end; return 0 == level ? pos - begin : 0; } /// The domain for simplicity is everything that after the protocol and the two slashes, until the next slash or before `?` or `#` while (pos < end && !(*pos == '/' || *pos == '?' || *pos == '#')) ++pos; if (pos != end) ++pos; if (0 == level) return pos - begin; UInt64 current_level = 0; while (current_level != level && pos < end) { /// We go to the next `/` or `?` or `#`, skipping all at the beginning. while (pos < end && (*pos == '/' || *pos == '?' || *pos == '#')) ++pos; if (pos == end) break; while (pos < end && !(*pos == '/' || *pos == '?' || *pos == '#')) ++pos; if (pos != end) ++pos; ++current_level; } return current_level == level ? pos - begin : 0; } static UInt64 apply(const UInt64 level, const char * data, const size_t size) { return URLHashImpl::apply(data, findLevelLength(level, data, data + size)); } }; class FunctionURLHash : public IFunction { public: static constexpr auto name = "URLHash"; static FunctionPtr create(ContextPtr) { return std::make_shared(); } String getName() const override { return name; } bool isVariadic() const override { return true; } size_t getNumberOfArguments() const override { return 0; } bool isSuitableForShortCircuitArgumentsExecution(const DataTypesWithConstInfo & /*arguments*/) const override { return true; } DataTypePtr getReturnTypeImpl(const DataTypes & arguments) const override { const auto arg_count = arguments.size(); if (arg_count != 1 && arg_count != 2) throw Exception(ErrorCodes::NUMBER_OF_ARGUMENTS_DOESNT_MATCH, "Number of arguments for function {} doesn't match: " "passed {}, should be 1 or 2.", getName(), arg_count); const auto * first_arg = arguments.front().get(); if (!WhichDataType(first_arg).isString()) throw Exception(ErrorCodes::ILLEGAL_TYPE_OF_ARGUMENT, "Illegal type {} of argument of function {}", first_arg->getName(), getName()); if (arg_count == 2) { const auto & second_arg = arguments.back(); if (!isInteger(second_arg)) throw Exception(ErrorCodes::ILLEGAL_TYPE_OF_ARGUMENT, "Illegal type {} of argument of function {}", second_arg->getName(), getName()); } return std::make_shared(); } bool useDefaultImplementationForConstants() const override { return true; } ColumnNumbers getArgumentsThatAreAlwaysConstant() const override { return {1}; } ColumnPtr executeImpl(const ColumnsWithTypeAndName & arguments, const DataTypePtr &, size_t /*input_rows_count*/) const override { const auto arg_count = arguments.size(); if (arg_count == 1) return executeSingleArg(arguments); else if (arg_count == 2) return executeTwoArgs(arguments); else throw Exception(ErrorCodes::LOGICAL_ERROR, "got into IFunction::execute with unexpected number of arguments"); } private: ColumnPtr executeSingleArg(const ColumnsWithTypeAndName & arguments) const { const auto * col_untyped = arguments.front().column.get(); if (const auto * col_from = checkAndGetColumn(col_untyped)) { const auto size = col_from->size(); auto col_to = ColumnUInt64::create(size); const auto & chars = col_from->getChars(); const auto & offsets = col_from->getOffsets(); auto & out = col_to->getData(); ColumnString::Offset current_offset = 0; for (size_t i = 0; i < size; ++i) { out[i] = URLHashImpl::apply( reinterpret_cast(&chars[current_offset]), offsets[i] - current_offset - 1); current_offset = offsets[i]; } return col_to; } else throw Exception(ErrorCodes::ILLEGAL_COLUMN, "Illegal column {} of argument of function {}", arguments[0].column->getName(), getName()); } ColumnPtr executeTwoArgs(const ColumnsWithTypeAndName & arguments) const { const auto * level_col = arguments.back().column.get(); if (!isColumnConst(*level_col)) throw Exception(ErrorCodes::ILLEGAL_COLUMN, "Second argument of function {} must be an integral constant", getName()); const auto level = level_col->get64(0); const auto * col_untyped = arguments.front().column.get(); if (const auto * col_from = checkAndGetColumn(col_untyped)) { const auto size = col_from->size(); auto col_to = ColumnUInt64::create(size); const auto & chars = col_from->getChars(); const auto & offsets = col_from->getOffsets(); auto & out = col_to->getData(); ColumnString::Offset current_offset = 0; for (size_t i = 0; i < size; ++i) { out[i] = URLHierarchyHashImpl::apply( level, reinterpret_cast(&chars[current_offset]), offsets[i] - current_offset - 1); current_offset = offsets[i]; } return col_to; } else throw Exception(ErrorCodes::ILLEGAL_COLUMN, "Illegal column {} of argument of function {}", arguments[0].column->getName(), getName()); } }; struct ImplWyHash64 { static constexpr auto name = "wyHash64"; using ReturnType = UInt64; static UInt64 apply(const char * s, const size_t len) { return wyhash(s, len, 0, _wyp); } static UInt64 combineHashes(UInt64 h1, UInt64 h2) { union { UInt64 u64[2]; char chars[16]; }; u64[0] = h1; u64[1] = h2; return apply(chars, 16); } static constexpr bool use_int_hash_for_pods = false; }; struct NameIntHash32 { static constexpr auto name = "intHash32"; }; struct NameIntHash64 { static constexpr auto name = "intHash64"; }; using FunctionSipHash64 = FunctionAnyHash; using FunctionSipHash64Keyed = FunctionAnyHash; using FunctionIntHash32 = FunctionIntHash; using FunctionIntHash64 = FunctionIntHash; #if USE_SSL using FunctionMD4 = FunctionStringHashFixedString; using FunctionHalfMD5 = FunctionAnyHash; using FunctionMD5 = FunctionStringHashFixedString; using FunctionSHA1 = FunctionStringHashFixedString; using FunctionSHA224 = FunctionStringHashFixedString; using FunctionSHA256 = FunctionStringHashFixedString; using FunctionSHA384 = FunctionStringHashFixedString; using FunctionSHA512 = FunctionStringHashFixedString; #endif using FunctionSipHash128 = FunctionAnyHash; using FunctionSipHash128Keyed = FunctionAnyHash; using FunctionSipHash128Reference = FunctionAnyHash; using FunctionSipHash128ReferenceKeyed = FunctionAnyHash; using FunctionCityHash64 = FunctionAnyHash; using FunctionFarmFingerprint64 = FunctionAnyHash; using FunctionFarmHash64 = FunctionAnyHash; using FunctionMetroHash64 = FunctionAnyHash; using FunctionMurmurHash2_32 = FunctionAnyHash; using FunctionMurmurHash2_64 = FunctionAnyHash; using FunctionGccMurmurHash = FunctionAnyHash; using FunctionMurmurHash3_32 = FunctionAnyHash; using FunctionMurmurHash3_64 = FunctionAnyHash; using FunctionMurmurHash3_128 = FunctionAnyHash; using FunctionJavaHash = FunctionAnyHash; using FunctionJavaHashUTF16LE = FunctionAnyHash; using FunctionHiveHash = FunctionAnyHash; using FunctionXxHash32 = FunctionAnyHash; using FunctionXxHash64 = FunctionAnyHash; using FunctionXXH3 = FunctionAnyHash; using FunctionWyHash64 = FunctionAnyHash; using FunctionBLAKE3 = FunctionStringHashFixedString; } #ifdef __clang__ # pragma clang diagnostic pop #endif