shithub: femtolisp

ref: 076b3b75c0f116421c17e7c2afd52b3079521ef4
dir: /3rd/spooky.c/

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//
// SpookyHash - 128-bit noncryptographic hash function
//
// Written in 2012 by Bob Jenkins
//
// Converted to C in 2015 by Joergen Ibsen
//
// To the extent possible under law, the author(s) have dedicated all
// copyright and related and neighboring rights to this software to the
// public domain worldwide. This software is distributed without any
// warranty. <http://creativecommons.org/publicdomain/zero/1.0/>
//
// Original comment from SpookyV2.cpp by Bob Jenkins:
//
// Spooky Hash
// A 128-bit noncryptographic hash, for checksums and table lookup
// By Bob Jenkins.  Public domain.
//   Oct 31 2010: published framework, disclaimer ShortHash isn't right
//   Nov 7 2010: disabled ShortHash
//   Oct 31 2011: replace End, ShortMix, ShortEnd, enable ShortHash again
//   April 10 2012: buffer overflow on platforms without unaligned reads
//   July 12 2012: was passing out variables in final to in/out in short
//   July 30 2012: I reintroduced the buffer overflow
//   August 5 2012: SpookyV2: d = should be d += in short hash, and remove extra mix from long hash

#include "platform.h"
#include "spooky.h"

#define ALLOW_UNALIGNED_READS 0

//
// 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
//
#define SC_CONST 0xDEADBEEFDEADBEEFULL

#define ROTL64(x, k) (((x) << (k)) | ((x) >> (64 - (k))))

#ifdef _MSC_VER
# define restrict __restrict
# define inline __forceinline
#endif

static bool
spooky_is_aligned(const void *p, size_t size)
{
	return (uintptr_t) p % size == 0;
}

static bool
spooky_is_little_endian(void)
{
	const union {
		uint32_t i;
		uint8_t c[sizeof(uint32_t)];
	} x = { 1 };

	return x.c[0];
}

//
// Read uint64_t in little-endian order.
//
static inline uint64_t
spooky_read_le64(const uint64_t *s)
{
	if (spooky_is_little_endian()) {
		uint64_t v;
		memcpy(&v, s, sizeof(v));
		return v;
	}
	else {
		const uint8_t *p = (const uint8_t *) s;
		return (uint64_t) p[0]
		    | ((uint64_t) p[1] << 8)
		    | ((uint64_t) p[2] << 16)
		    | ((uint64_t) p[3] << 24)
		    | ((uint64_t) p[4] << 32)
		    | ((uint64_t) p[5] << 40)
		    | ((uint64_t) p[6] << 48)
		    | ((uint64_t) p[7] << 56);
	}
}

//
// 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
spooky_mix(const uint64_t *restrict data, uint64_t *restrict s)
{
	s[0] += spooky_read_le64(&data[0]);          s[2] ^= s[10];
	s[11] ^= s[0];   s[0] = ROTL64(s[0], 11);    s[11] += s[1];
	s[1] += spooky_read_le64(&data[1]);          s[3] ^= s[11];
	s[0] ^= s[1];    s[1] = ROTL64(s[1], 32);    s[0] += s[2];
	s[2] += spooky_read_le64(&data[2]);          s[4] ^= s[0];
	s[1] ^= s[2];    s[2] = ROTL64(s[2], 43);    s[1] += s[3];
	s[3] += spooky_read_le64(&data[3]);          s[5] ^= s[1];
	s[2] ^= s[3];    s[3] = ROTL64(s[3], 31);    s[2] += s[4];
	s[4] += spooky_read_le64(&data[4]);          s[6] ^= s[2];
	s[3] ^= s[4];    s[4] = ROTL64(s[4], 17);    s[3] += s[5];
	s[5] += spooky_read_le64(&data[5]);          s[7] ^= s[3];
	s[4] ^= s[5];    s[5] = ROTL64(s[5], 28);    s[4] += s[6];
	s[6] += spooky_read_le64(&data[6]);          s[8] ^= s[4];
	s[5] ^= s[6];    s[6] = ROTL64(s[6], 39);    s[5] += s[7];
	s[7] += spooky_read_le64(&data[7]);          s[9] ^= s[5];
	s[6] ^= s[7];    s[7] = ROTL64(s[7], 57);    s[6] += s[8];
	s[8] += spooky_read_le64(&data[8]);          s[10] ^= s[6];
	s[7] ^= s[8];    s[8] = ROTL64(s[8], 55);    s[7] += s[9];
	s[9] += spooky_read_le64(&data[9]);          s[11] ^= s[7];
	s[8] ^= s[9];    s[9] = ROTL64(s[9], 54);    s[8] += s[10];
	s[10] += spooky_read_le64(&data[10]);        s[0] ^= s[8];
	s[9] ^= s[10];   s[10] = ROTL64(s[10], 22);  s[9] += s[11];
	s[11] += spooky_read_le64(&data[11]);        s[1] ^= s[9];
	s[10] ^= s[11];  s[11] = ROTL64(s[11], 46);  s[10] += s[0];
}

//
// 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
spooky_end_partial(uint64_t *h)
{
	h[11] += h[1];  h[2] ^= h[11];  h[1] = ROTL64(h[1], 44);
	h[0] += h[2];   h[3] ^= h[0];   h[2] = ROTL64(h[2], 15);
	h[1] += h[3];   h[4] ^= h[1];   h[3] = ROTL64(h[3], 34);
	h[2] += h[4];   h[5] ^= h[2];   h[4] = ROTL64(h[4], 21);
	h[3] += h[5];   h[6] ^= h[3];   h[5] = ROTL64(h[5], 38);
	h[4] += h[6];   h[7] ^= h[4];   h[6] = ROTL64(h[6], 33);
	h[5] += h[7];   h[8] ^= h[5];   h[7] = ROTL64(h[7], 10);
	h[6] += h[8];   h[9] ^= h[6];   h[8] = ROTL64(h[8], 13);
	h[7] += h[9];   h[10] ^= h[7];  h[9] = ROTL64(h[9], 38);
	h[8] += h[10];  h[11] ^= h[8];  h[10] = ROTL64(h[10], 53);
	h[9] += h[11];  h[0] ^= h[9];   h[11] = ROTL64(h[11], 42);
	h[10] += h[0];  h[1] ^= h[10];  h[0] = ROTL64(h[0], 54);
}

static inline void
spooky_end(const uint64_t *restrict data, uint64_t *restrict h)
{
	h[0] += spooky_read_le64(&data[0]);
	h[1] += spooky_read_le64(&data[1]);
	h[2] += spooky_read_le64(&data[2]);
	h[3] += spooky_read_le64(&data[3]);
	h[4] += spooky_read_le64(&data[4]);
	h[5] += spooky_read_le64(&data[5]);
	h[6] += spooky_read_le64(&data[6]);
	h[7] += spooky_read_le64(&data[7]);
	h[8] += spooky_read_le64(&data[8]);
	h[9] += spooky_read_le64(&data[9]);
	h[10] += spooky_read_le64(&data[10]);
	h[11] += spooky_read_le64(&data[11]);
	spooky_end_partial(h);
	spooky_end_partial(h);
	spooky_end_partial(h);
}

//
// 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
spooky_short_mix(uint64_t *h)
{
	h[2] = ROTL64(h[2], 50);  h[2] += h[3];  h[0] ^= h[2];
	h[3] = ROTL64(h[3], 52);  h[3] += h[0];  h[1] ^= h[3];
	h[0] = ROTL64(h[0], 30);  h[0] += h[1];  h[2] ^= h[0];
	h[1] = ROTL64(h[1], 41);  h[1] += h[2];  h[3] ^= h[1];
	h[2] = ROTL64(h[2], 54);  h[2] += h[3];  h[0] ^= h[2];
	h[3] = ROTL64(h[3], 48);  h[3] += h[0];  h[1] ^= h[3];
	h[0] = ROTL64(h[0], 38);  h[0] += h[1];  h[2] ^= h[0];
	h[1] = ROTL64(h[1], 37);  h[1] += h[2];  h[3] ^= h[1];
	h[2] = ROTL64(h[2], 62);  h[2] += h[3];  h[0] ^= h[2];
	h[3] = ROTL64(h[3], 34);  h[3] += h[0];  h[1] ^= h[3];
	h[0] = ROTL64(h[0], 5);   h[0] += h[1];  h[2] ^= h[0];
	h[1] = ROTL64(h[1], 36);  h[1] += h[2];  h[3] ^= h[1];
}

//
// 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
spooky_short_end(uint64_t *h)
{
	h[3] ^= h[2];  h[2] = ROTL64(h[2], 15);  h[3] += h[2];
	h[0] ^= h[3];  h[3] = ROTL64(h[3], 52);  h[0] += h[3];
	h[1] ^= h[0];  h[0] = ROTL64(h[0], 26);  h[1] += h[0];
	h[2] ^= h[1];  h[1] = ROTL64(h[1], 51);  h[2] += h[1];
	h[3] ^= h[2];  h[2] = ROTL64(h[2], 28);  h[3] += h[2];
	h[0] ^= h[3];  h[3] = ROTL64(h[3], 9);   h[0] += h[3];
	h[1] ^= h[0];  h[0] = ROTL64(h[0], 47);  h[1] += h[0];
	h[2] ^= h[1];  h[1] = ROTL64(h[1], 54);  h[2] += h[1];
	h[3] ^= h[2];  h[2] = ROTL64(h[2], 32);  h[3] += h[2];
	h[0] ^= h[3];  h[3] = ROTL64(h[3], 25);  h[0] += h[3];
	h[1] ^= h[0];  h[0] = ROTL64(h[0], 63);  h[1] += h[0];
}

//
// short hash ... it could be used on any message,
// but it's used by Spooky just for short messages.
//
static void
spooky_short(const void *restrict message, size_t length,
             uint64_t *restrict hash1, uint64_t *restrict hash2)
{
	uint64_t buf[2 * SC_NUMVARS];
	union {
		const uint8_t *p8;
		uint64_t *p64;
	} u;

	u.p8 = (const uint8_t *) message;

	if (ALLOW_UNALIGNED_READS == 0 && !spooky_is_aligned(u.p8, 8)) {
		memcpy(buf, message, length);
		u.p64 = buf;
	}

	size_t left = length % 32;
	uint64_t h[4];
	h[0] = *hash1;
	h[1] = *hash2;
	h[2] = SC_CONST;
	h[3] = SC_CONST;

	if (length > 15) {
		const uint64_t *end = u.p64 + (length / 32) * 4;

		// handle all complete sets of 32 bytes
		for (; u.p64 < end; u.p64 += 4) {
			h[2] += spooky_read_le64(&u.p64[0]);
			h[3] += spooky_read_le64(&u.p64[1]);
			spooky_short_mix(h);
			h[0] += spooky_read_le64(&u.p64[2]);
			h[1] += spooky_read_le64(&u.p64[3]);
		}

		//Handle the case of 16+ remaining bytes.
		if (left >= 16) {
			h[2] += spooky_read_le64(&u.p64[0]);
			h[3] += spooky_read_le64(&u.p64[1]);
			spooky_short_mix(h);
			u.p64 += 2;
			left -= 16;
		}
	}

	// Handle the last 0..15 bytes, and its length
	h[3] += ((uint64_t) length) << 56;
	switch (left) {
	case 15:
		h[3] += ((uint64_t) u.p8[14]) << 48; // fallthrough
	case 14:
		h[3] += ((uint64_t) u.p8[13]) << 40; // fallthrough
	case 13:
		h[3] += ((uint64_t) u.p8[12]) << 32; // fallthrough
	case 12:
		h[3] += ((uint64_t) u.p8[11]) << 24; // fallthrough
	case 11:
		h[3] += ((uint64_t) u.p8[10]) << 16; // fallthrough
	case 10:
		h[3] += ((uint64_t) u.p8[9]) << 8; // fallthrough
	case 9:
		h[3] += (uint64_t) u.p8[8]; // fallthrough
	case 8:
		h[2] += spooky_read_le64(&u.p64[0]);
		break;
	case 7:
		h[2] += ((uint64_t) u.p8[6]) << 48; // fallthrough
	case 6:
		h[2] += ((uint64_t) u.p8[5]) << 40; // fallthrough
	case 5:
		h[2] += ((uint64_t) u.p8[4]) << 32; // fallthrough
	case 4:
		h[2] += ((uint64_t) u.p8[3]) << 24; // fallthrough
	case 3:
		h[2] += ((uint64_t) u.p8[2]) << 16; // fallthrough
	case 2:
		h[2] += ((uint64_t) u.p8[1]) << 8; // fallthrough
	case 1:
		h[2] += (uint64_t) u.p8[0];
		break;
	case 0:
		h[2] += SC_CONST;
		h[3] += SC_CONST;
	}
	spooky_short_end(h);
	*hash1 = h[0];
	*hash2 = h[1];
}

uint64_t
spooky_hash64(const void *message, size_t length, uint64_t seed)
{
	uint64_t hash1 = seed;
	spooky_hash128(message, length, &hash1, &seed);
	return hash1;
}

uint32_t
spooky_hash32(const void *message, size_t length, uint32_t seed)
{
	uint64_t hash1 = seed, hash2 = seed;
	spooky_hash128(message, length, &hash1, &hash2);
	return (uint32_t) hash1;
}

// do the whole hash in one call
void
spooky_hash128(const void *restrict message, size_t length,
               uint64_t *restrict hash1, uint64_t *restrict hash2)
{
	if (length < SC_BUFSIZE) {
		spooky_short(message, length, hash1, hash2);
		return;
	}

	uint64_t h[SC_NUMVARS];
	uint64_t buf[SC_NUMVARS];
	uint64_t *end;
	union {
		const uint8_t *p8;
		uint64_t *p64;
	} u;
	size_t left;

	h[0] = *hash1;
	h[1] = *hash2;
	h[2] = SC_CONST;
	h[3] = *hash1;
	h[4] = *hash2;
	h[5] = SC_CONST;
	h[6] = *hash1;
	h[7] = *hash2;
	h[8] = SC_CONST;
	h[9] = *hash1;
	h[10] = *hash2;
	h[11] = SC_CONST;

	u.p8 = (const uint8_t *) message;
	end = u.p64 + (length / SC_BLOCKSIZE) * SC_NUMVARS;

	// handle all whole SC_BLOCKSIZE blocks of bytes
	if (ALLOW_UNALIGNED_READS || spooky_is_aligned(u.p8, 8)) {
		do {
			spooky_mix(u.p64, h);
			u.p64 += SC_NUMVARS;
		} while (u.p64 < end);
	}
	else {
		do {
			memcpy(buf, u.p64, SC_BLOCKSIZE);
			spooky_mix(buf, h);
			u.p64 += SC_NUMVARS;
		} while (u.p64 < end);
	}

	// handle the last partial block of SC_BLOCKSIZE bytes
	left = length - ((const uint8_t *) end - (const uint8_t *) message);
	memcpy(buf, end, left);
	memset(((uint8_t *) buf) + left, 0, SC_BLOCKSIZE - left);
	((uint8_t *) buf)[SC_BLOCKSIZE - 1] = (uint8_t) left;

	// do some final mixing
	spooky_end(buf, h);
	*hash1 = h[0];
	*hash2 = h[1];
}

/*
// init spooky state
void
spooky_init(struct spooky_state *state, uint64_t seed1, uint64_t seed2)
{
	state->length = 0;
	state->left = 0;
	state->state[0] = seed1;
	state->state[1] = seed2;
}

// add a message fragment to the state
void
spooky_update(struct spooky_state *restrict state,
              const void *restrict message, size_t length)
{
	uint64_t h[SC_NUMVARS];
	size_t newLength = length + state->left;
	uint8_t left;
	union {
		const uint8_t *p8;
		uint64_t *p64;
	} u;
	const uint64_t *end;

	// Is this message fragment too short?  If it is, stuff it away.
	if (newLength < SC_BUFSIZE) {
		memcpy(&((uint8_t *) state->data)[state->left], message, length);
		state->length = length + state->length;
		state->left = (uint8_t) newLength;
		return;
	}

	// init the variables
	if (state->length < SC_BUFSIZE) {
		h[0] = h[3] = h[6] = h[9] = state->state[0];
		h[1] = h[4] = h[7] = h[10] = state->state[1];
		h[2] = h[5] = h[8] = h[11] = SC_CONST;
	}
	else {
		memcpy(h, state->state, sizeof(state->state));
	}
	state->length = length + state->length;

	// if we've got anything stuffed away, use it now
	if (state->left) {
		uint8_t prefix = SC_BUFSIZE - state->left;
		memcpy(&(((uint8_t *) state->data)[state->left]), message, prefix);
		u.p64 = state->data;
		spooky_mix(u.p64, h);
		spooky_mix(&u.p64[SC_NUMVARS], h);
		u.p8 = ((const uint8_t *) message) + prefix;
		length -= prefix;
	}
	else {
		u.p8 = (const uint8_t *) message;
	}

	// handle all whole blocks of SC_BLOCKSIZE bytes
	end = u.p64 + (length / SC_BLOCKSIZE) * SC_NUMVARS;
	left = (uint8_t) (length - ((const uint8_t *) end - u.p8));
	if (ALLOW_UNALIGNED_READS || spooky_is_aligned(u.p8, 8)) {
		while (u.p64 < end) {
			spooky_mix(u.p64, h);
			u.p64 += SC_NUMVARS;
		}
	}
	else {
		while (u.p64 < end) {
			memcpy(state->data, u.p8, SC_BLOCKSIZE);
			spooky_mix(state->data, h);
			u.p64 += SC_NUMVARS;
		}
	}

	// stuff away the last few bytes
	state->left = left;
	memcpy(state->data, end, left);

	// stuff away the variables
	memcpy(state->state, h, sizeof(state->state));
}

// report the hash for the concatenation of all message fragments so far
void
spooky_final(struct spooky_state *restrict state,
             uint64_t *restrict hash1, uint64_t *restrict hash2)
{
	// init the variables
	if (state->length < SC_BUFSIZE) {
		*hash1 = state->state[0];
		*hash2 = state->state[1];
		spooky_short(state->data, state->length, hash1, hash2);
		return;
	}

	const uint64_t *data = (const uint64_t *) state->data;
	uint8_t left = state->left;

	uint64_t h[SC_NUMVARS];
	memcpy(h, state->state, sizeof(state->state));

	if (left >= SC_BLOCKSIZE) {
		// m_data can contain two blocks; handle any whole first block
		spooky_mix(data, h);
		data += SC_NUMVARS;
		left -= SC_BLOCKSIZE;
	}

	// mix in the last partial block, and the length mod SC_BLOCKSIZE
	memset(&((uint8_t *) data)[left], 0, (SC_BLOCKSIZE - left));

	((uint8_t *) data)[SC_BLOCKSIZE - 1] = left;

	// do some final mixing
	spooky_end(data, h);

	*hash1 = h[0];
	*hash2 = h[1];
}
*/