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- //
- // SpookyHash: a 128-bit noncryptographic hash function
- // By Bob Jenkins, public domain
- // Oct 31 2010: alpha, framework + SpookyHash::Mix appears right
- // Oct 31 2011: alpha again, Mix only good to 2^^69 but rest appears right
- // Dec 31 2011: beta, improved Mix, tested it for 2-bit deltas
- // Feb 2 2012: production, same bits as beta
- // Feb 5 2012: adjusted definitions of uint* to be more portable
- //
- // Up to 4 bytes/cycle for long messages. Reasonably fast for short messages.
- // All 1 or 2 bit deltas achieve avalanche within 1% bias per output bit.
- //
- // This was developed for and tested on 64-bit x86-compatible processors.
- // It assumes the processor is little-endian. There is a macro
- // controlling whether unaligned reads are allowed (by default they are).
- // This should be an equally good hash on big-endian machines, but it will
- // compute different results on them than on little-endian machines.
- //
- // Google's CityHash has similar specs to SpookyHash, and CityHash is faster
- // on some platforms. MD4 and MD5 also have similar specs, but they are orders
- // of magnitude slower. CRCs are two or more times slower, but unlike
- // SpookyHash, they have nice math for combining the CRCs of pieces to form
- // the CRCs of wholes. There are also cryptographic hashes, but those are even
- // slower than MD5.
- //
- #include "Platform.h"
- #include <stddef.h>
- #ifdef _MSC_VER
- # define INLINE __forceinline
- typedef unsigned __int64 uint64;
- typedef unsigned __int32 uint32;
- typedef unsigned __int16 uint16;
- typedef unsigned __int8 uint8;
- #else
- # include <stdint.h>
- # define INLINE inline
- typedef uint64_t uint64;
- typedef uint32_t uint32;
- typedef uint16_t uint16;
- typedef uint8_t uint8;
- #endif
- class SpookyHash
- {
- public:
- //
- // SpookyHash: hash a single message in one call, produce 128-bit output
- //
- static void Hash128(
- const void *message, // message to hash
- size_t length, // length of message in bytes
- uint64 *hash1, // in/out: in seed 1, out hash value 1
- uint64 *hash2); // in/out: in seed 2, out hash value 2
- //
- // Hash64: hash a single message in one call, return 64-bit output
- //
- static uint64 Hash64(
- const void *message, // message to hash
- size_t length, // length of message in bytes
- uint64 seed) // seed
- {
- uint64 hash1 = seed;
- Hash128(message, length, &hash1, &seed);
- return hash1;
- }
- //
- // Hash32: hash a single message in one call, produce 32-bit output
- //
- static uint32 Hash32(
- const void *message, // message to hash
- size_t length, // length of message in bytes
- uint32 seed) // seed
- {
- uint64 hash1 = seed, hash2 = seed;
- Hash128(message, length, &hash1, &hash2);
- return (uint32)hash1;
- }
- //
- // Init: initialize the context of a SpookyHash
- //
- void Init(
- uint64 seed1, // any 64-bit value will do, including 0
- uint64 seed2); // different seeds produce independent hashes
-
- //
- // Update: add a piece of a message to a SpookyHash state
- //
- void Update(
- const void *message, // message fragment
- size_t length); // length of message fragment in bytes
- //
- // Final: compute the hash for the current SpookyHash state
- //
- // This does not modify the state; you can keep updating it afterward
- //
- // The result is the same as if SpookyHash() had been called with
- // all the pieces concatenated into one message.
- //
- void Final(
- uint64 *hash1, // out only: first 64 bits of hash value.
- uint64 *hash2); // out only: second 64 bits of hash value.
- //
- // left rotate a 64-bit value by k bytes
- //
- static INLINE uint64 Rot64(uint64 x, int k)
- {
- return (x << k) | (x >> (64 - k));
- }
- //
- // This is used if the input is 96 bytes long or longer.
- //
- // The internal state is fully overwritten every 96 bytes.
- // Every input bit appears to cause at least 128 bits of entropy
- // before 96 other bytes are combined, when run forward or backward
- // For every input bit,
- // Two inputs differing in just that input bit
- // Where "differ" means xor or subtraction
- // And the base value is random
- // When run forward or backwards one Mix
- // I tried 3 pairs of each; they all differed by at least 212 bits.
- //
- static INLINE void Mix(
- const uint64 *data,
- uint64 &s0, uint64 &s1, uint64 &s2, uint64 &s3,
- uint64 &s4, uint64 &s5, uint64 &s6, uint64 &s7,
- uint64 &s8, uint64 &s9, uint64 &s10,uint64 &s11)
- {
- s0 += data[0]; s2 ^= s10; s11 ^= s0; s0 = Rot64(s0,11); s11 += s1;
- s1 += data[1]; s3 ^= s11; s0 ^= s1; s1 = Rot64(s1,32); s0 += s2;
- s2 += data[2]; s4 ^= s0; s1 ^= s2; s2 = Rot64(s2,43); s1 += s3;
- s3 += data[3]; s5 ^= s1; s2 ^= s3; s3 = Rot64(s3,31); s2 += s4;
- s4 += data[4]; s6 ^= s2; s3 ^= s4; s4 = Rot64(s4,17); s3 += s5;
- s5 += data[5]; s7 ^= s3; s4 ^= s5; s5 = Rot64(s5,28); s4 += s6;
- s6 += data[6]; s8 ^= s4; s5 ^= s6; s6 = Rot64(s6,39); s5 += s7;
- s7 += data[7]; s9 ^= s5; s6 ^= s7; s7 = Rot64(s7,57); s6 += s8;
- s8 += data[8]; s10 ^= s6; s7 ^= s8; s8 = Rot64(s8,55); s7 += s9;
- s9 += data[9]; s11 ^= s7; s8 ^= s9; s9 = Rot64(s9,54); s8 += s10;
- s10 += data[10]; s0 ^= s8; s9 ^= s10; s10 = Rot64(s10,22); s9 += s11;
- s11 += data[11]; s1 ^= s9; s10 ^= s11; s11 = Rot64(s11,46); s10 += s0;
- }
- //
- // Mix all 12 inputs together so that h0, h1 are a hash of them all.
- //
- // For two inputs differing in just the input bits
- // Where "differ" means xor or subtraction
- // And the base value is random, or a counting value starting at that bit
- // The final result will have each bit of h0, h1 flip
- // For every input bit,
- // with probability 50 +- .3%
- // For every pair of input bits,
- // with probability 50 +- 3%
- //
- // This does not rely on the last Mix() call having already mixed some.
- // Two iterations was almost good enough for a 64-bit result, but a
- // 128-bit result is reported, so End() does three iterations.
- //
- static INLINE void EndPartial(
- uint64 &h0, uint64 &h1, uint64 &h2, uint64 &h3,
- uint64 &h4, uint64 &h5, uint64 &h6, uint64 &h7,
- uint64 &h8, uint64 &h9, uint64 &h10,uint64 &h11)
- {
- h11+= h1; h2 ^= h11; h1 = Rot64(h1,44);
- h0 += h2; h3 ^= h0; h2 = Rot64(h2,15);
- h1 += h3; h4 ^= h1; h3 = Rot64(h3,34);
- h2 += h4; h5 ^= h2; h4 = Rot64(h4,21);
- h3 += h5; h6 ^= h3; h5 = Rot64(h5,38);
- h4 += h6; h7 ^= h4; h6 = Rot64(h6,33);
- h5 += h7; h8 ^= h5; h7 = Rot64(h7,10);
- h6 += h8; h9 ^= h6; h8 = Rot64(h8,13);
- h7 += h9; h10^= h7; h9 = Rot64(h9,38);
- h8 += h10; h11^= h8; h10= Rot64(h10,53);
- h9 += h11; h0 ^= h9; h11= Rot64(h11,42);
- h10+= h0; h1 ^= h10; h0 = Rot64(h0,54);
- }
- static INLINE void End(
- uint64 &h0, uint64 &h1, uint64 &h2, uint64 &h3,
- uint64 &h4, uint64 &h5, uint64 &h6, uint64 &h7,
- uint64 &h8, uint64 &h9, uint64 &h10,uint64 &h11)
- {
- EndPartial(h0,h1,h2,h3,h4,h5,h6,h7,h8,h9,h10,h11);
- EndPartial(h0,h1,h2,h3,h4,h5,h6,h7,h8,h9,h10,h11);
- EndPartial(h0,h1,h2,h3,h4,h5,h6,h7,h8,h9,h10,h11);
- }
- //
- // The goal is for each bit of the input to expand into 128 bits of
- // apparent entropy before it is fully overwritten.
- // n trials both set and cleared at least m bits of h0 h1 h2 h3
- // n: 2 m: 29
- // n: 3 m: 46
- // n: 4 m: 57
- // n: 5 m: 107
- // n: 6 m: 146
- // n: 7 m: 152
- // when run forwards or backwards
- // for all 1-bit and 2-bit diffs
- // with diffs defined by either xor or subtraction
- // with a base of all zeros plus a counter, or plus another bit, or random
- //
- static INLINE void ShortMix(uint64 &h0, uint64 &h1, uint64 &h2, uint64 &h3)
- {
- h2 = Rot64(h2,50); h2 += h3; h0 ^= h2;
- h3 = Rot64(h3,52); h3 += h0; h1 ^= h3;
- h0 = Rot64(h0,30); h0 += h1; h2 ^= h0;
- h1 = Rot64(h1,41); h1 += h2; h3 ^= h1;
- h2 = Rot64(h2,54); h2 += h3; h0 ^= h2;
- h3 = Rot64(h3,48); h3 += h0; h1 ^= h3;
- h0 = Rot64(h0,38); h0 += h1; h2 ^= h0;
- h1 = Rot64(h1,37); h1 += h2; h3 ^= h1;
- h2 = Rot64(h2,62); h2 += h3; h0 ^= h2;
- h3 = Rot64(h3,34); h3 += h0; h1 ^= h3;
- h0 = Rot64(h0,5); h0 += h1; h2 ^= h0;
- h1 = Rot64(h1,36); h1 += h2; h3 ^= h1;
- }
- //
- // Mix all 4 inputs together so that h0, h1 are a hash of them all.
- //
- // For two inputs differing in just the input bits
- // Where "differ" means xor or subtraction
- // And the base value is random, or a counting value starting at that bit
- // The final result will have each bit of h0, h1 flip
- // For every input bit,
- // with probability 50 +- .3% (it is probably better than that)
- // For every pair of input bits,
- // with probability 50 +- .75% (the worst case is approximately that)
- //
- static INLINE void ShortEnd(uint64 &h0, uint64 &h1, uint64 &h2, uint64 &h3)
- {
- h3 ^= h2; h2 = Rot64(h2,15); h3 += h2;
- h0 ^= h3; h3 = Rot64(h3,52); h0 += h3;
- h1 ^= h0; h0 = Rot64(h0,26); h1 += h0;
- h2 ^= h1; h1 = Rot64(h1,51); h2 += h1;
- h3 ^= h2; h2 = Rot64(h2,28); h3 += h2;
- h0 ^= h3; h3 = Rot64(h3,9); h0 += h3;
- h1 ^= h0; h0 = Rot64(h0,47); h1 += h0;
- h2 ^= h1; h1 = Rot64(h1,54); h2 += h1;
- h3 ^= h2; h2 = Rot64(h2,32); h3 += h2;
- h0 ^= h3; h3 = Rot64(h3,25); h0 += h3;
- h1 ^= h0; h0 = Rot64(h0,63); h1 += h0;
- }
-
- private:
- //
- // Short is used for messages under 192 bytes in length
- // Short has a low startup cost, the normal mode is good for long
- // keys, the cost crossover is at about 192 bytes. The two modes were
- // held to the same quality bar.
- //
- static void Short(
- const void *message,
- size_t length,
- uint64 *hash1,
- uint64 *hash2);
- // number of uint64's in internal state
- static const size_t sc_numVars = 12;
- // size of the internal state
- static const size_t sc_blockSize = sc_numVars*8;
- // size of buffer of unhashed data, in bytes
- static const size_t sc_bufSize = 2*sc_blockSize;
- //
- // sc_const: a constant which:
- // * is not zero
- // * is odd
- // * is a not-very-regular mix of 1's and 0's
- // * does not need any other special mathematical properties
- //
- static const uint64 sc_const = 0xdeadbeefdeadbeefULL;
- uint64 m_data[2*sc_numVars]; // unhashed data, for partial messages
- uint64 m_state[sc_numVars]; // internal state of the hash
- size_t m_length; // total length of the input so far
- uint8 m_remainder; // length of unhashed data stashed in m_data
- };
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