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dev_miner.h
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dev_miner.h
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// Equihash solver
// Copyright (c) 2016 John Tromp
// This development version uses xenoncat's highly optimized
// 4-way parallel blake2b implementation
// Fix N, K, such that n = N/(k+1) is integer
// Fix M = 2^{n+1} hashes each of length N bits,
// H_0, ... , H_{M-1}, generated fom (n+1)-bit indices.
// Problem: find binary tree on 2^K distinct indices,
// for which the exclusive-or of leaf hashes is all 0s.
// Additionally, it should satisfy the Wagner conditions:
// for each height i subtree, the exclusive-or
// of its 2^i corresponding hashes starts with i*n 0 bits,
// and for i>0 the leftmost leaf of its left subtree
// is less than the leftmost leaf of its right subtree
// The algorithm below solves this by maintaining the tree
// in a graph of K layers, each split into buckets
// with buckets indexed by the first n-RESTBITS bits following
// the i*n 0s, each bucket having 4 * 2^RESTBITS slots,
// twice the number of subtrees expected to land there.
#include "equi.h"
#include <stdio.h>
#include <pthread.h>
#include <assert.h>
#ifdef __cplusplus
extern "C" {
#endif
void Blake2PrepareMidstate4(void *midstate, uchar *input);
#ifdef __cplusplus
}
#endif
//midstate: 256 bytes of buffer for output midstate, aligned by 32
//input: 140 bytes header, preferably aligned by 8
#ifdef __cplusplus
extern "C" {
#endif
void Blake2Run4(uchar *hashout, void *midstate, u32 indexctr);
#ifdef __cplusplus
}
#endif
//hashout: hash output buffer: 4*64 bytes
//midstate: 256 bytes from Blake2PrepareMidstate4
//indexctr: For n=200, k=9: {0, 4, 8, ..., 1048572}
#if defined __builtin_bswap32 && defined __LITTLE_ENDIAN
#undef htobe32
#define htobe32(x) __builtin_bswap32(x)
#elif defined __APPLE__
#undef htobe32
#define htobe32(x) OSSwapHostToBigInt32(x)
#endif
typedef uint16_t u16;
typedef uint64_t u64;
#ifdef ATOMIC
#include <atomic>
typedef std::atomic<u32> au32;
#else
typedef u32 au32;
#endif
#ifndef RESTBITS
#define RESTBITS 8
#endif
// 2_log of number of buckets
#define BUCKBITS (DIGITBITS-RESTBITS)
#ifndef SAVEMEM
#if RESTBITS == 4
// can't save memory in such small buckets
#define SAVEMEM 1
#elif RESTBITS >= 8
// take advantage of law of large numbers (sum of 2^8 random numbers)
// this reduces (200,9) memory to under 144MB, with negligible discarding
#define SAVEMEM 9/14
#endif
#endif
// number of buckets
static const u32 NBUCKETS = 1<<BUCKBITS;
// bucket mask
static const u32 BUCKMASK = NBUCKETS-1;
// 2_log of number of slots per bucket
static const u32 SLOTBITS = RESTBITS+1+1;
static const u32 SLOTRANGE = 1<<SLOTBITS;
static const u32 SLOTMSB = 1<<(SLOTBITS-1);
// number of slots per bucket
static const u32 NSLOTS = SLOTRANGE * SAVEMEM;
// SLOTBITS mask
static const u32 SLOTMASK = SLOTRANGE-1;
// number of possible values of xhash (rest of n) bits
static const u32 NRESTS = 1<<RESTBITS;
// nothing larger found in 100000 runs
static const u32 MAXSOLS = 8;
// tree node identifying its children as two different slots in
// a bucket on previous layer with the same rest bits (x-tra hash)
struct tree {
u32 bid_s0_s1; // manual bitfields
tree(const u32 idx) {
bid_s0_s1 = idx;
}
tree(const u32 bid, const u32 s0, const u32 s1) {
#ifdef SLOTDIFF
u32 ds10 = (s1 - s0) & SLOTMASK;
if (ds10 & SLOTMSB) {
bid_s0_s1 = (((bid << SLOTBITS) | s1) << (SLOTBITS-1)) | (SLOTMASK & ~ds10);
} else {
bid_s0_s1 = (((bid << SLOTBITS) | s0) << (SLOTBITS-1)) | (ds10 - 1);
}
#else
bid_s0_s1 = (((bid << SLOTBITS) | s0) << SLOTBITS) | s1;
#endif
}
u32 getindex() const {
return bid_s0_s1;
}
u32 bucketid() const {
#ifdef SLOTDIFF
return bid_s0_s1 >> (2 * SLOTBITS - 1);
#else
return bid_s0_s1 >> (2 * SLOTBITS);
#endif
}
u32 slotid0() const {
#ifdef SLOTDIFF
return (bid_s0_s1 >> (SLOTBITS-1)) & SLOTMASK;
#else
return (bid_s0_s1 >> SLOTBITS) & SLOTMASK;
#endif
}
u32 slotid1() const {
#ifdef SLOTDIFF
return (slotid0() + 1 + (bid_s0_s1 & (SLOTMASK>>1))) & SLOTMASK;
#else
return bid_s0_s1 & SLOTMASK;
#endif
}
};
union htunit {
tree tag;
u32 word;
uchar bytes[sizeof(u32)];
};
#define WORDS(bits) ((bits + 31) / 32)
#define HASHWORDS0 WORDS(WN - DIGITBITS + RESTBITS)
#define HASHWORDS1 WORDS(WN - 2*DIGITBITS + RESTBITS)
// A slot is up to HASHWORDS0 hash units followed by a tag
typedef htunit slot0[HASHWORDS0+1];
typedef htunit slot1[HASHWORDS1+1];
// a bucket is NSLOTS treenodes
typedef slot0 bucket0[NSLOTS];
typedef slot1 bucket1[NSLOTS];
// the N-bit hash consists of K+1 n-bit "digits"
// each of which corresponds to a layer of NBUCKETS buckets
typedef bucket0 digit0[NBUCKETS];
typedef bucket1 digit1[NBUCKETS];
typedef au32 bsizes[NBUCKETS];
u32 min(const u32 a, const u32 b) {
return a < b ? a : b;
}
// size (in bytes) of hash in round 0 <= r < WK
u32 hashsize(const u32 r) {
const u32 hashbits = WN - (r+1) * DIGITBITS + RESTBITS;
return (hashbits + 7) / 8;
}
u32 hashwords(u32 bytes) {
return (bytes + 3) / 4;
}
// manages hash and tree data
struct htalloc {
bucket0 *heap0;
bucket1 *heap1;
u32 alloced;
htalloc() {
alloced = 0;
}
void alloctrees() {
// optimize xenoncat's fixed memory layout, avoiding any waste
// digit hashes tree hashes tree
// 0 A A A A A A 0 . . . . . .
// 1 A A A A A A 0 B B B B B 1
// 2 C C C C C 2 0 B B B B B 1
// 3 C C C C C 2 0 D D D D 3 1
// 4 E E E E 4 2 0 D D D D 3 1
// 5 E E E E 4 2 0 F F F 5 3 1
// 6 G G 6 . 4 2 0 F F F 5 3 1
// 7 G G 6 . 4 2 0 H H 7 5 3 1
// 8 I 8 6 . 4 2 0 H H 7 5 3 1
static_assert(DIGITBITS >= 16, "needed to ensure hashes shorten by 1 unit every 2 digits");
heap0 = (bucket0 *)alloc(NBUCKETS, sizeof(bucket0));
heap1 = (bucket1 *)alloc(NBUCKETS, sizeof(bucket1));
}
void dealloctrees() {
free(heap0);
free(heap1);
}
void *alloc(const u32 n, const u32 sz) {
void *mem = calloc(n, sz);
assert(mem);
alloced += n * sz;
return mem;
}
};
struct equi {
alignas(32) uchar blake_ctx[256];
htalloc hta;
bsizes *nslots;
proof *sols;
au32 nsols;
u32 nthreads;
u32 bfull;
u32 hfull;
pthread_barrier_t barry;
equi(const u32 n_threads) {
static_assert(sizeof(htunit) == 4, "");
static_assert(WK&1, "K assumed odd in candidate() calling indices1()");
nthreads = n_threads;
const int err = pthread_barrier_init(&barry, NULL, nthreads);
assert(!err);
hta.alloctrees();
nslots = (bsizes *)hta.alloc(2 * NBUCKETS, sizeof(au32));
sols = (proof *)hta.alloc(MAXSOLS, sizeof(proof));
}
~equi() {
hta.dealloctrees();
free(nslots);
free(sols);
}
void setheadernonce(const char *headernonce, const u32 len) {
alignas(8) uchar alignheader[HEADERNONCELEN];
memcpy(alignheader, headernonce, len);
assert(len == HEADERNONCELEN);
alignas(32) uchar midstate[256];
Blake2PrepareMidstate4(midstate, alignheader);
memcpy(&blake_ctx, midstate, 256);
memset(nslots, 0, NBUCKETS * sizeof(au32)); // only nslots[0] needs zeroing
nsols = bfull = hfull = 0;
}
u32 getslot0(const u32 bucketi) {
#ifdef ATOMIC
return std::atomic_fetch_add_explicit(&nslots[0][bucketi], 1U, std::memory_order_relaxed);
#else
return nslots[0][bucketi]++;
#endif
}
u32 getslot1(const u32 bucketi) {
#ifdef ATOMIC
return std::atomic_fetch_add_explicit(&nslots[1][bucketi], 1U, std::memory_order_relaxed);
#else
return nslots[1][bucketi]++;
#endif
}
u32 getnslots0(const u32 bid) {
au32 &nslot = nslots[0][bid];
const u32 n = min(nslot, NSLOTS);
nslot = 0;
return n;
}
u32 getnslots1(const u32 bid) {
au32 &nslot = nslots[1][bid];
const u32 n = min(nslot, NSLOTS);
nslot = 0;
return n;
}
#ifdef MERGESORT
// if merged != 0, mergesort indices and return true if dupe found
// if merged == 0, order indices as in Wagner condition
bool orderindices(u32 *indices, u32 size, u32 *merged) {
if (merged) {
u32 i = 0, j = 0, k;
for (k = 0; i<size && j<size; k++) {
if (indices[i] == indices[size+j]) return true;
merged[k] = indices[i] < indices[size+j] ? indices[i++] : indices[size+j++];
}
memcpy(merged+k, indices+i, (size-i) * sizeof(u32));
memcpy(indices, merged, (size+j) * sizeof(u32));
return false;
} else {
if (indices[0] > indices[size]) {
for (u32 i=0; i < size; i++) {
const u32 tmp = indices[i];
indices[i] = indices[size+i];
indices[size+i] = tmp;
}
}
return false;
}
}
// return true if dupe found
bool listindices0(u32 r, const tree t, u32 *indices, u32 *merged) {
if (r == 0) {
*indices = t.getindex();
return false;
}
const slot1 *buck = hta.heap1[t.bucketid()];
const u32 size = 1 << --r;
u32 *indices1 = indices + size;
u32 tagi = hashwords(hashsize(r));
return listindices1(r, buck[t.slotid0()][tagi].tag, indices, merged)
|| listindices1(r, buck[t.slotid1()][tagi].tag, indices1, merged)
|| orderindices(indices, size, merged);
}
bool listindices1(u32 r, const tree t, u32 *indices, u32 *merged) {
const slot0 *buck = hta.heap0[t.bucketid()];
const u32 size = 1 << --r;
u32 *indices1 = indices + size;
u32 tagi = hashwords(hashsize(r));
return listindices0(r, buck[t.slotid0()][tagi].tag, indices, merged)
|| listindices0(r, buck[t.slotid1()][tagi].tag, indices1, merged)
|| orderindices(indices, size, merged);
}
void candidate(const tree t) {
proof prf, merged;
if (listindices1(WK, t, prf, merged)) return;
#ifdef ATOMIC
u32 soli = std::atomic_fetch_add_explicit(&nsols, 1U, std::memory_order_relaxed);
#else
u32 soli = nsols++;
#endif
if (soli < MAXSOLS) listindices1(WK, t, sols[soli], 0);
}
#else
bool orderindices(u32 *indices, u32 size) {
if (indices[0] > indices[size]) {
for (u32 i=0; i < size; i++) {
const u32 tmp = indices[i];
indices[i] = indices[size+i];
indices[size+i] = tmp;
}
}
return false;
}
// order indices as in Wagner condition,
// and return true if a left and right subtree have identical leftmost leaves
bool listindices0(u32 r, const tree t, u32 *indices) {
if (r == 0) {
*indices = t.getindex();
return false;
}
const slot1 *buck = hta.heap1[t.bucketid()];
const u32 size = 1 << --r;
u32 tagi = hashwords(hashsize(r));
return listindices1(r, buck[t.slotid0()][tagi].tag, indices)
|| listindices1(r, buck[t.slotid1()][tagi].tag, indices+size)
|| orderindices(indices, size) || indices[0] == indices[size];
}
bool listindices1(u32 r, const tree t, u32 *indices) {
const slot0 *buck = hta.heap0[t.bucketid()];
const u32 size = 1 << --r;
u32 tagi = hashwords(hashsize(r));
return listindices0(r, buck[t.slotid0()][tagi].tag, indices)
|| listindices0(r, buck[t.slotid1()][tagi].tag, indices+size)
|| orderindices(indices, size) || indices[0] == indices[size];
}
void candidate(const tree t) {
proof prf;
// listindices combines index tree reconstruction with probably dupe test
if (listindices1(WK, t, prf) || duped(prf)) return; // assume WK odd
// and now we have ourselves a genuine solution
#ifdef ATOMIC
u32 soli = std::atomic_fetch_add_explicit(&nsols, 1U, std::memory_order_relaxed);
#else
u32 soli = nsols++;
#endif
if (soli < MAXSOLS) memcpy(sols[soli], prf, sizeof(proof));
}
#endif
void showbsizes(u32 r) {
printf(" b%d h%d\n", bfull, hfull);
bfull = hfull = 0;
#if defined(HIST) || defined(SPARK) || defined(LOGSPARK)
u32 binsizes[65];
memset(binsizes, 0, 65 * sizeof(u32));
for (u32 bucketid = 0; bucketid < NBUCKETS; bucketid++) {
u32 bsize = min(nslots[r&1][bucketid], NSLOTS) >> (SLOTBITS-6);
binsizes[bsize]++;
}
for (u32 i=0; i < 65; i++) {
#ifdef HIST
printf(" %d:%d", i, binsizes[i]);
#else
#ifdef SPARK
u32 sparks = binsizes[i] / SPARKSCALE;
#else
u32 sparks = 0;
for (u32 bs = binsizes[i]; bs; bs >>= 1) sparks++;
sparks = sparks * 7 / SPARKSCALE;
#endif
printf("\342\226%c", '\201' + sparks);
#endif
}
printf("\n");
#endif
printf("Digit %d", r+1);
}
struct htlayout {
htalloc hta;
u32 prevhtunits;
u32 nexthtunits;
u32 dunits;
u32 prevbo;
htlayout(equi *eq, u32 r): hta(eq->hta), prevhtunits(0), dunits(0) {
u32 nexthashbytes = hashsize(r);
nexthtunits = hashwords(nexthashbytes);
prevbo = 0;
if (r) {
u32 prevhashbytes = hashsize(r-1);
prevhtunits = hashwords(prevhashbytes);
prevbo = prevhtunits * sizeof(htunit) - prevhashbytes; // 0-3
dunits = prevhtunits - nexthtunits;
}
}
u32 getxhash0(const htunit* slot) const {
#if WN == 200 && RESTBITS == 4
return slot->bytes[prevbo] >> 4;
#elif WN == 200 && RESTBITS == 8
return (slot->bytes[prevbo] & 0xf) << 4 | slot->bytes[prevbo+1] >> 4;
#elif WN == 144 && RESTBITS == 4
return slot->bytes[prevbo] & 0xf;
#else
#error non implemented
#endif
}
u32 getxhash1(const htunit* slot) const {
#if WN == 200 && RESTBITS == 4
return slot->bytes[prevbo] & 0xf;
#elif WN == 200 && RESTBITS == 8
return slot->bytes[prevbo];
#elif WN == 144 && RESTBITS == 4
return slot->bytes[prevbo] & 0xf;
#else
#error non implemented
#endif
}
bool equal(const htunit *hash0, const htunit *hash1) const {
return hash0[prevhtunits-1].word == hash1[prevhtunits-1].word;
}
};
struct collisiondata {
#ifdef XBITMAP
#if NSLOTS > 64
#error cant use XBITMAP with more than 64 slots
#endif
u64 xhashmap[NRESTS];
u64 xmap;
#else
#if RESTBITS <= 6
typedef uchar xslot;
#else
typedef u16 xslot;
#endif
static const xslot xnil = ~0;
xslot xhashslots[NRESTS];
xslot nextxhashslot[NSLOTS];
xslot nextslot;
#endif
u32 s0;
void clear() {
#ifdef XBITMAP
memset(xhashmap, 0, NRESTS * sizeof(u64));
#else
memset(xhashslots, xnil, NRESTS * sizeof(xslot));
memset(nextxhashslot, xnil, NSLOTS * sizeof(xslot));
#endif
}
void addslot(u32 s1, u32 xh) {
#ifdef XBITMAP
xmap = xhashmap[xh];
xhashmap[xh] |= (u64)1 << s1;
s0 = -1;
#else
nextslot = xhashslots[xh];
nextxhashslot[s1] = nextslot;
xhashslots[xh] = s1;
#endif
}
bool nextcollision() const {
#ifdef XBITMAP
return xmap != 0;
#else
return nextslot != xnil;
#endif
}
u32 slot() {
#ifdef XBITMAP
const u32 ffs = __builtin_ffsll(xmap);
s0 += ffs; xmap >>= ffs;
#else
nextslot = nextxhashslot[s0 = nextslot];
#endif
return s0;
}
};
static const u32 BLAKESINPARALLEL = 4;
// number of hashes extracted from BLAKESINPARALLEL blake2b outputs
static const u32 HASHESPERBLOCK = BLAKESINPARALLEL*HASHESPERBLAKE;
// number of blocks of parallel blake2b calls
static const u32 NBLOCKS = (NHASHES+HASHESPERBLOCK-1)/HASHESPERBLOCK;
void digit0(const u32 id) {
htlayout htl(this, 0);
#ifndef HASHONLY
const u32 hashbytes = hashsize(0);
#endif
alignas(32) uchar midstate[256], hashes[256];
//aligned256 midstate, hashes;
memcpy((void *)midstate, blake_ctx, 256);
for (u32 block = id; block < NBLOCKS; block += nthreads) {
Blake2Run4(hashes, (void *)midstate, block * BLAKESINPARALLEL);
#ifndef HASHONLY
for (u32 i = 0; i<BLAKESINPARALLEL; i++) {
for (u32 j = 0; j<HASHESPERBLAKE; j++) {
const uchar *ph = hashes+ i * 64 + j * WN/8;
const u32 bucketid = ((u32)ph[0] << 4) | ph[1] >> 4;
const u32 slot = getslot0(bucketid);
if (slot >= NSLOTS) {
bfull++;
continue;
}
htunit *s = hta.heap0[bucketid][slot] + htl.nexthtunits;
memcpy(s->bytes-hashbytes, ph+WN/8-hashbytes, hashbytes);
s->tag = tree((block * BLAKESINPARALLEL + i) * HASHESPERBLAKE + j);
}
}
#endif
}
}
void digitodd(const u32 r, const u32 id) {
htlayout htl(this, r);
collisiondata cd;
for (u32 bucketid=id; bucketid < NBUCKETS; bucketid += nthreads) {
cd.clear();
slot0 *buck = htl.hta.heap0[bucketid];
u32 bsize = getnslots0(bucketid);
for (u32 s1 = 0; s1 < bsize; s1++) {
const htunit *slot1 = buck[s1];
cd.addslot(s1, htl.getxhash0(slot1));
for (; cd.nextcollision(); ) {
const u32 s0 = cd.slot();
const htunit *slot0 = buck[s0];
if (htl.equal(slot0, slot1)) {
hfull++;
continue;
}
u32 xorbucketid;
const uchar *bytes0 = slot0->bytes, *bytes1 = slot1->bytes;
#if WN == 200 && BUCKBITS == 12 && RESTBITS == 8
xorbucketid = (((u32)(bytes0[htl.prevbo+1] ^ bytes1[htl.prevbo+1]) & 0xf) << 8)
| (bytes0[htl.prevbo+2] ^ bytes1[htl.prevbo+2]);
#elif WN == 144 && BUCKBITS == 20 && RESTBITS == 4
xorbucketid = ((((u32)(bytes0[htl.prevbo+1] ^ bytes1[htl.prevbo+1]) << 8)
| (bytes0[htl.prevbo+2] ^ bytes1[htl.prevbo+2])) << 4)
| (bytes0[htl.prevbo+3] ^ bytes1[htl.prevbo+3]) >> 4;
#elif WN == 96 && BUCKBITS == 12 && RESTBITS == 4
xorbucketid = ((u32)(bytes0[htl.prevbo+1] ^ bytes1[htl.prevbo+1]) << 4)
| (bytes0[htl.prevbo+2] ^ bytes1[htl.prevbo+2]) >> 4;
#else
#error not implemented
#endif
const u32 xorslot = getslot1(xorbucketid);
if (xorslot >= NSLOTS) {
bfull++;
continue;
}
htunit *xs = htl.hta.heap1[xorbucketid][xorslot];
for (u32 i=htl.dunits; i < htl.prevhtunits; i++)
xs++->word = slot0[i].word ^ slot1[i].word;
xs->tag = tree(bucketid, s0, s1);
}
}
}
}
void digiteven(const u32 r, const u32 id) {
htlayout htl(this, r);
collisiondata cd;
for (u32 bucketid=id; bucketid < NBUCKETS; bucketid += nthreads) {
cd.clear();
slot1 *buck = htl.hta.heap1[bucketid];
u32 bsize = getnslots1(bucketid);
for (u32 s1 = 0; s1 < bsize; s1++) {
const htunit *slot1 = buck[s1];
cd.addslot(s1, htl.getxhash1(slot1));
for (; cd.nextcollision(); ) {
const u32 s0 = cd.slot();
const htunit *slot0 = buck[s0];
if (htl.equal(slot0, slot1)) {
hfull++;
continue;
}
u32 xorbucketid;
const uchar *bytes0 = slot0->bytes, *bytes1 = slot1->bytes;
#if WN == 200 && BUCKBITS == 12 && RESTBITS == 8
xorbucketid = ((u32)(bytes0[htl.prevbo+1] ^ bytes1[htl.prevbo+1]) << 4)
| (bytes0[htl.prevbo+2] ^ bytes1[htl.prevbo+2]) >> 4;
#elif WN == 144 && BUCKBITS == 20 && RESTBITS == 4
xorbucketid = ((((u32)(bytes0[htl.prevbo+1] ^ bytes1[htl.prevbo+1]) << 8)
| (bytes0[htl.prevbo+2] ^ bytes1[htl.prevbo+2])) << 4)
| (bytes0[htl.prevbo+3] ^ bytes1[htl.prevbo+3]) >> 4;
#elif WN == 96 && BUCKBITS == 12 && RESTBITS == 4
xorbucketid = ((u32)(bytes0[htl.prevbo+1] ^ bytes1[htl.prevbo+1]) << 4)
| (bytes0[htl.prevbo+2] ^ bytes1[htl.prevbo+2]) >> 4;
#else
#error not implemented
#endif
const u32 xorslot = getslot0(xorbucketid);
if (xorslot >= NSLOTS) {
bfull++;
continue;
}
htunit *xs = htl.hta.heap0[xorbucketid][xorslot];
for (u32 i=htl.dunits; i < htl.prevhtunits; i++)
xs++->word = slot0[i].word ^ slot1[i].word;
xs->tag = tree(bucketid, s0, s1);
}
}
}
}
void digit1(const u32 id) {
htalloc heaps = hta;
collisiondata cd;
for (u32 bucketid=id; bucketid < NBUCKETS; bucketid += nthreads) {
cd.clear();
slot0 *buck = heaps.heap0[bucketid];
u32 bsize = getnslots0(bucketid);
for (u32 s1 = 0; s1 < bsize; s1++) {
const htunit *slot1 = buck[s1];
cd.addslot(s1, htobe32(slot1->word) >> 20 & 0xff);
for (; cd.nextcollision(); ) {
const u32 s0 = cd.slot();
const htunit *slot0 = buck[s0];
if (slot0[5].word == slot1[5].word) {
hfull++;
continue;
}
u32 xorbucketid = htobe32(slot0->word ^ slot1->word) >> 8 & BUCKMASK;
const u32 xorslot = getslot1(xorbucketid);
if (xorslot >= NSLOTS) {
bfull++;
continue;
}
u64 *x = (u64 *)heaps.heap1[xorbucketid][xorslot];
u64 *x0 = (u64 *)slot0, *x1 = (u64 *)slot1;
*x++ = x0[0] ^ x1[0];
*x++ = x0[1] ^ x1[1];
*x++ = x0[2] ^ x1[2];
((htunit *)x)->tag = tree(bucketid, s0, s1);
}
}
}
}
void digit2(const u32 id) {
htalloc heaps = hta;
collisiondata cd;
for (u32 bucketid=id; bucketid < NBUCKETS; bucketid += nthreads) {
cd.clear();
slot1 *buck = heaps.heap1[bucketid];
u32 bsize = getnslots1(bucketid);
for (u32 s1 = 0; s1 < bsize; s1++) {
const htunit *slot1 = buck[s1];
cd.addslot(s1, slot1->bytes[3]);
for (; cd.nextcollision(); ) {
const u32 s0 = cd.slot();
const htunit *slot0 = buck[s0];
if (slot0[5].word == slot1[5].word) {
hfull++;
continue;
}
u32 xorbucketid = htobe32(slot0[1].word ^ slot1[1].word) >> 20;
const u32 xorslot = getslot0(xorbucketid);
if (xorslot >= NSLOTS) {
bfull++;
continue;
}
htunit *xs = heaps.heap0[xorbucketid][xorslot];
xs++->word = slot0[1].word ^ slot1[1].word;
u64 *x = (u64 *)xs, *x0 = (u64 *)slot0, *x1 = (u64 *)slot1;
*x++ = x0[1] ^ x1[1];
*x++ = x0[2] ^ x1[2];
((htunit *)x)->tag = tree(bucketid, s0, s1);
}
}
}
}
void digit3(const u32 id) {
htalloc heaps = hta;
collisiondata cd;
for (u32 bucketid=id; bucketid < NBUCKETS; bucketid += nthreads) {
cd.clear();
slot0 *buck = heaps.heap0[bucketid];
u32 bsize = getnslots0(bucketid);
for (u32 s1 = 0; s1 < bsize; s1++) {
const htunit *slot1 = buck[s1];
cd.addslot(s1, htobe32(slot1->word) >> 12 & 0xff);
for (; cd.nextcollision(); ) {
const u32 s0 = cd.slot();
const htunit *slot0 = buck[s0];
if (slot0[4].word == slot1[4].word) {
hfull++;
continue;
}
u32 xorbucketid = htobe32(slot0[0].word ^ slot1[0].word) & BUCKMASK;
const u32 xorslot = getslot1(xorbucketid);
if (xorslot >= NSLOTS) {
bfull++;
continue;
}
u64 *x = (u64 *)heaps.heap1[xorbucketid][xorslot];
u64 *x0 = (u64 *)(slot0+1), *x1 = (u64 *)(slot1+1);
*x++ = x0[0] ^ x1[0];
*x++ = x0[1] ^ x1[1];
((htunit *)x)->tag = tree(bucketid, s0, s1);
}
}
}
}
void digit4(const u32 id) {
htalloc heaps = hta;
collisiondata cd;
for (u32 bucketid=id; bucketid < NBUCKETS; bucketid += nthreads) {
cd.clear();
slot1 *buck = heaps.heap1[bucketid];
u32 bsize = getnslots1(bucketid);
for (u32 s1 = 0; s1 < bsize; s1++) {
const htunit *slot1 = buck[s1];
cd.addslot(s1, slot1->bytes[0]);
for (; cd.nextcollision(); ) {
const u32 s0 = cd.slot();
const htunit *slot0 = buck[s0];
if (slot0[3].word == slot1[3].word) {
hfull++;
continue;
}
u32 xorbucketid = htobe32(slot0[0].word ^ slot1[0].word) >> 12 & BUCKMASK;
const u32 xorslot = getslot0(xorbucketid);
if (xorslot >= NSLOTS) {
bfull++;
continue;
}
u64 *x = (u64 *)heaps.heap0[xorbucketid][xorslot];
u64 *x0 = (u64 *)slot0, *x1 = (u64 *)slot1;
*x++ = x0[0] ^ x1[0];
*x++ = x0[1] ^ x1[1];
((htunit *)x)->tag = tree(bucketid, s0, s1);
}
}
}
}
void digit5(const u32 id) {
htalloc heaps = hta;
collisiondata cd;
for (u32 bucketid=id; bucketid < NBUCKETS; bucketid += nthreads) {
cd.clear();
slot0 *buck = heaps.heap0[bucketid];
u32 bsize = getnslots0(bucketid);
for (u32 s1 = 0; s1 < bsize; s1++) {
const htunit *slot1 = buck[s1];
cd.addslot(s1, htobe32(slot1->word) >> 4 & 0xff);
for (; cd.nextcollision(); ) {
const u32 s0 = cd.slot();
const htunit *slot0 = buck[s0];
if (slot0[3].word == slot1[3].word) {
hfull++;
continue;
}
u32 xor1 = slot0[1].word ^ slot1[1].word;
u32 xorbucketid = (((u32)(slot0->bytes[3] ^ slot1->bytes[3]) & 0xf)
<< 8) | (xor1 & 0xff);
const u32 xorslot = getslot1(xorbucketid);
if (xorslot >= NSLOTS) {
bfull++;
continue;
}
htunit *xs = heaps.heap1[xorbucketid][xorslot];
xs++->word = xor1;
u64 *x = (u64 *)xs, *x0 = (u64 *)slot0, *x1 = (u64 *)slot1;
*x++ = x0[1] ^ x1[1];
((htunit *)x)->tag = tree(bucketid, s0, s1);
}
}
}
}
void digit6(const u32 id) {
htalloc heaps = hta;
collisiondata cd;
for (u32 bucketid=id; bucketid < NBUCKETS; bucketid += nthreads) {
cd.clear();
slot1 *buck = heaps.heap1[bucketid];
u32 bsize = getnslots1(bucketid);
for (u32 s1 = 0; s1 < bsize; s1++) {
const htunit *slot1 = buck[s1];
cd.addslot(s1, slot1->bytes[1]);
for (; cd.nextcollision(); ) {
const u32 s0 = cd.slot();
const htunit *slot0 = buck[s0];
if (slot0[2].word == slot1[2].word) {
hfull++;
continue;
}
u32 xorbucketid = htobe32(slot0[0].word ^ slot1[0].word) >> 4 & BUCKMASK;
const u32 xorslot = getslot0(xorbucketid);
if (xorslot >= NSLOTS) {
bfull++;
continue;
}
htunit *xs = heaps.heap0[xorbucketid][xorslot];
xs++->word = slot0[0].word ^ slot1[0].word;
u64 *x = (u64 *)xs, *x0 = (u64 *)(slot0+1), *x1 = (u64 *)(slot1+1);
*x++ = x0[0] ^ x1[0];
((htunit *)x)->tag = tree(bucketid, s0, s1);
}
}
}
}
void digit7(const u32 id) {
htalloc heaps = hta;
collisiondata cd;
for (u32 bucketid=id; bucketid < NBUCKETS; bucketid += nthreads) {
cd.clear();
slot0 *buck = heaps.heap0[bucketid];
u32 bsize = getnslots0(bucketid);
for (u32 s1 = 0; s1 < bsize; s1++) {
const htunit *slot1 = buck[s1];
cd.addslot(s1, (slot1->bytes[3] & 0xf) << 4 | slot1->bytes[4] >> 4);
for (; cd.nextcollision(); ) {
const u32 s0 = cd.slot();
const htunit *slot0 = buck[s0];
if (slot0[2].word == slot1[2].word) {
hfull++;
continue;
}
u32 xorbucketid = htobe32(slot0[1].word ^ slot1[1].word) >> 16 & BUCKMASK;
const u32 xorslot = getslot1(xorbucketid);
if (xorslot >= NSLOTS) {
bfull++;
continue;
}
u64 *x = (u64 *)heaps.heap1[xorbucketid][xorslot];
u64 *x0 = (u64 *)(slot0+1), *x1 = (u64 *)(slot1+1);
*x++ = x0[0] ^ x1[0];
((htunit *)x)->tag = tree(bucketid, s0, s1);
}
}
}
}
void digit8(const u32 id) {
htalloc heaps = hta;
collisiondata cd;
for (u32 bucketid=id; bucketid < NBUCKETS; bucketid += nthreads) {
cd.clear();
slot1 *buck = heaps.heap1[bucketid];
u32 bsize = getnslots1(bucketid);
for (u32 s1 = 0; s1 < bsize; s1++) {
const htunit *slot1 = buck[s1];
cd.addslot(s1, slot1->bytes[2]);
for (; cd.nextcollision(); ) {
const u32 s0 = cd.slot();
const htunit *slot0 = buck[s0];
u32 xor1 = slot0[1].word ^ slot1[1].word;
if (!xor1) {
hfull++;
continue;
}
u32 xorbucketid = ((u32)(slot0->bytes[3] ^ slot1->bytes[3]) << 4)
| (xor1 >> 4 & 0xf);
const u32 xorslot = getslot0(xorbucketid);
if (xorslot >= NSLOTS) {
bfull++;
continue;
}
htunit *xs = heaps.heap0[xorbucketid][xorslot];
xs++->word = xor1;
xs->tag = tree(bucketid, s0, s1);
}
}
}
}
void digitK(const u32 id) {
collisiondata cd;
htlayout htl(this, WK);
u32 nc = 0;
for (u32 bucketid = id; bucketid < NBUCKETS; bucketid += nthreads) {
cd.clear();
slot0 *buck = htl.hta.heap0[bucketid];
u32 bsize = getnslots0(bucketid);
for (u32 s1 = 0; s1 < bsize; s1++) {
const htunit *slot1 = buck[s1];
cd.addslot(s1, htl.getxhash0(slot1)); // assume WK odd
for (; cd.nextcollision(); ) {
const u32 s0 = cd.slot();
if (htl.equal(buck[s0], slot1)) { // EASY OPTIMIZE
candidate(tree(bucketid, s0, s1));
nc++;
}
}
}
}
// printf(" %d candidates ", nc);
}
};
typedef struct {
u32 id;
pthread_t thread;
equi *eq;
} thread_ctx;
void barrier(pthread_barrier_t *barry) {
const int rc = pthread_barrier_wait(barry);
if (rc != 0 && rc != PTHREAD_BARRIER_SERIAL_THREAD) {
printf("Could not wait on barrier\n");
pthread_exit(NULL);
}
}
void *worker(void *vp) {
thread_ctx *tp = (thread_ctx *)vp;
equi *eq = tp->eq;
if (tp->id == 0) printf("Digit 0");
eq->digit0(tp->id);
#ifdef HASHONLY
pthread_exit(NULL);
#endif
barrier(&eq->barry);
if (tp->id == 0) eq->showbsizes(0);
barrier(&eq->barry);
#if WN == 200 && WK == 9 && RESTBITS == 8
eq->digit1(tp->id);
barrier(&eq->barry);
if (tp->id == 0) eq->showbsizes(1);
barrier(&eq->barry);
eq->digit2(tp->id);
barrier(&eq->barry);
if (tp->id == 0) eq->showbsizes(2);
barrier(&eq->barry);
eq->digit3(tp->id);
barrier(&eq->barry);
if (tp->id == 0) eq->showbsizes(3);
barrier(&eq->barry);
eq->digit4(tp->id);
barrier(&eq->barry);
if (tp->id == 0) eq->showbsizes(4);
barrier(&eq->barry);
eq->digit5(tp->id);
barrier(&eq->barry);
if (tp->id == 0) eq->showbsizes(5);
barrier(&eq->barry);
eq->digit6(tp->id);
barrier(&eq->barry);
if (tp->id == 0) eq->showbsizes(6);
barrier(&eq->barry);
eq->digit7(tp->id);
barrier(&eq->barry);
if (tp->id == 0) eq->showbsizes(7);
barrier(&eq->barry);
eq->digit8(tp->id);
barrier(&eq->barry);
if (tp->id == 0) eq->showbsizes(8);
barrier(&eq->barry);
#else
for (u32 r = 1; r < WK; r++) {
r&1 ? eq->digitodd(r, tp->id) : eq->digiteven(r, tp->id);
barrier(&eq->barry);
if (tp->id == 0) eq->showbsizes(r);
barrier(&eq->barry);
}
#endif
eq->digitK(tp->id);
pthread_exit(NULL);
return 0;
}