/* ** Copyright (C) 2009-2014 Mischa Sandberg ** ** This program is free software; you can redistribute it and/or modify ** it under the terms of the GNU Lesser General Public License Version as ** published by the Free Software Foundation. You may not use, modify or ** distribute this program under any other version of the GNU Lesser General ** Public License. ** ** This program is distributed in the hope that it will be useful, ** but WITHOUT ANY WARRANTY; without even the implied warranty of ** MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the ** GNU Lesser General Public License for more details. ** ** You should have received a copy of the GNU Lesser General Public License ** along with this program; if not, write to the Free Software ** Foundation, Inc., 51 Franklin Street, Fifth Floor, Boston, MA 02110-1301, USA. */ #include "_acism.h" typedef struct tnode { struct tnode *child, *next, *back; union { unsigned nrefs; STATE state; } x; STRNO match; SYMBOL sym, is_suffix; } TNODE; //--------------|--------------------------------------------- // bitwid: 1+floor(log2(u)) static inline int bitwid(unsigned u) { int ret = !!u; if (u & 0xFFFF0000) u >>= 16, ret += 16; if (u & 0x0000FF00) u >>= 8, ret += 8; if (u & 0x000000F0) u >>= 4, ret += 4; if (u & 0x0000000C) u >>= 2, ret += 2; if (u & 0x00000002) ret++; return ret; } static void fill_symv(ac_trie_t*, ac_trie_pat_t const*, int ns); static int create_tree(TNODE*, SYMBOL const*symv, ac_trie_pat_t const*strv, int nstrs); static void add_backlinks(TNODE*, TNODE**, TNODE**); static int interleave(TNODE*, int nnodes, int nsyms, TNODE**, TNODE**); static void fill_tranv(ac_trie_t*, TNODE const*); static void fill_hashv(ac_trie_t*, TNODE const*, int nn); static TNODE* find_child(TNODE*, SYMBOL); // (ns) is either a STATE, or a (STRNO + tran_size) static inline void set_tran(ac_trie_t *psp, STATE s, SYMBOL sym, int match, int suffix, TRAN ns) { psp->tranv[s + sym] = sym | (match ? IS_MATCH : 0) | (suffix ? IS_SUFFIX : 0) | (ns << SYM_BITS); } // Track statistics for construction #ifdef ACISM_STATS typedef struct { long long val; const char *name; } PSSTAT; extern PSSTAT psstat[]; # define NOTE(n) (psstat[__LINE__] = (PSSTAT) {n, #n}) # define HIT(id) (psstat[__LINE__].val++, psstat[__LINE__].name = id) #else # define NOTE(n) (void)0 # define HIT(id) (void)0 #endif //ACISM_STATS //--------------|--------------------------------------------- ac_trie_t* acism_create(ac_trie_pat_t const* strv, int nstrs) { TNODE *tp, **v1 = NULL, **v2 = NULL; ac_trie_t *psp = g_malloc0(sizeof(*psp)); fill_symv(psp, strv, nstrs); TNODE *troot = g_new0(TNODE, psp->nchars + 1); int nnodes = create_tree(troot, psp->symv, strv, nstrs); NOTE(nnodes); // v1, v2: breadth-first work vectors for add_backlink and interleave. int nhash = 0, i = (nstrs + 1) * sizeof*tp; for (tp = troot + nnodes; --tp > troot;) { nhash += tp->match && tp->child; } v1 = g_malloc(i); v2 = g_malloc(i); add_backlinks(troot, v1, v2); // Calculate each node's offset in tranv[]: psp->tran_size = interleave(troot, nnodes, psp->nsyms, v1, v2); if (bitwid(psp->tran_size + nstrs - 1) + SYM_BITS > sizeof(TRAN)*8 - 2) goto FAIL; if (nhash) { // Hash table is for match info of non-leaf nodes (only). // Set hash_size for p_size(psp): psp->hash_mod = nhash * 5 / 4 + 1; // Initially oversize the table for overflows without wraparound. psp->hash_size = psp->hash_mod + nhash; } set_tranv(psp, g_malloc0(p_size(psp))); if (!psp->tranv) goto FAIL; fill_tranv(psp, troot); // The root state (0) must not look like a valid backref. // Any symbol value other than (0) in tranv[0] ensures that. psp->tranv[0] = 1; if (nhash) { fill_hashv(psp, troot, nnodes); // Adjust hash_size to include trailing overflows // but trim trailing empty slots. psp->hash_size = psp->hash_mod; while ( psp->hashv[psp->hash_size].state) ++psp->hash_size; while (!psp->hashv[psp->hash_size - 1].state) --psp->hash_size; set_tranv(psp, g_realloc(psp->tranv, p_size(psp))); } // Diagnostics/statistics only: psp->nstrs = nstrs; for (i = psp->maxlen = 0; i < nstrs; ++i) if (psp->maxlen < strv[i].len) psp->maxlen = strv[i].len; goto DONE; FAIL: acism_destroy(psp), psp = NULL; DONE: g_free(troot), g_free(v1), g_free(v2); return psp; } typedef struct { int freq, rank; } FRANK; static int frcmp(FRANK*a, FRANK*b) { return a->freq - b->freq; } static void fill_symv(ac_trie_t *psp, ac_trie_pat_t const *strv, int nstrs) { int i, j; FRANK frv[256]; for (i = 0; i < 256; ++i) frv[i] = (FRANK){0,i}; for (i = 0; i < nstrs; ++i) for (psp->nchars += j = strv[i].len; --j >= 0;) frv[(uint8_t)strv[i].ptr[j]].freq++; qsort(frv, 256, sizeof*frv, (qsort_cmp)frcmp); for (i = 256; --i >= 0 && frv[i].freq;) psp->symv[frv[i].rank] = ++psp->nsyms; ++psp->nsyms; #if ACISM_SIZE < 8 psp->sym_bits = bitwid(psp->nsyms); psp->sym_mask = ~(((TRAN)-1) << psp->sym_bits); #endif } static int create_tree(TNODE *Tree, SYMBOL const *symv, ac_trie_pat_t const *strv, int nstrs) { int i, j; TNODE *nextp = Tree + 1; for (i = 0; i < nstrs; ++i) { TNODE *tp = Tree; for (j = 0; tp->child && j < (int)strv[i].len; ++j) { SYMBOL sym = symv[(uint8_t)strv[i].ptr[j]]; if (sym < tp->child->sym) { // Prep to insert new node before tp->child nextp->next = tp->child; break; } tp = tp->child; while (tp->next && sym >= tp->next->sym) tp = tp->next; // Insert new sibling after tp if (sym > tp->sym) { nextp->next = tp->next; tp = tp->next = nextp++; tp->sym = sym; tp->back = Tree; } } for (; j < (int) strv[i].len; ++j) { tp = tp->child = nextp++; tp->sym = symv[(uint8_t)strv[i].ptr[j]]; tp->back = Tree; } tp->match = i + 1; // Encode strno as nonzero } return nextp - Tree; } static void add_backlinks(TNODE *troot, TNODE **v1, TNODE **v2) { TNODE *tp, **tmp; for (tp = troot->child, tmp = v1; tp; tp = tp->next) *tmp++ = tp; *tmp = NULL; while (*v1) { TNODE **spp = v1, **dpp = v2, *srcp, *dstp; while ((srcp = *spp++)) { for (dstp = srcp->child; dstp; dstp = dstp->next) { TNODE *bp = NULL; *dpp++ = dstp; for (tp = srcp->back; tp; tp = tp->back) if ((bp = find_child(tp, dstp->sym)) && bp->child) break; if (!bp) bp = troot; dstp->back = dstp->child ? bp : tp ? tp : troot; dstp->back->x.nrefs++; dstp->is_suffix = bp->match || bp->is_suffix; } } *dpp = 0; tmp = v1; v1 = v2; v2 = tmp; } } static int interleave(TNODE *troot, int nnodes, int nsyms, TNODE **v1, TNODE **v2) { unsigned usev_size = nnodes + nsyms; char *usev = g_new0(char, usev_size); STATE last_trans = 0, startv[nsyms][2]; TNODE *cp, **tmp; memset(startv, 0, nsyms * sizeof*startv); // Iterate through one level of the Tree at a time. // That srsly improves locality (L1-cache use). v1[0] = troot, v1[1] = NULL; for (; *v1; tmp = v1, v1 = v2, v2 = tmp) { TNODE **srcp = v1, **dstp = v2, *tp; while ((tp = *srcp++)) { if (!tp->child) continue; HIT("nonleaf"); if (tp->back == troot) tp->back = NULL; // simplify tests. cp = tp->child; STATE pos, *startp = &startv[cp->sym][!!tp->back]; while ((cp = cp->next)) { STATE *newp = &startv[cp->sym][!!tp->back]; if (*startp < *newp) startp = newp; } // If (tp) has a backref, we need a slot at offset 0 // that is free as a base AND to be used (filled in). char need = tp->back ? BASE|USED : BASE; for (pos = *startp;; ++pos) { if (usev[pos] & need) { HIT("inner loop"); continue; } for (cp = tp->child; cp; cp = cp->next) { HIT("child loop"); if (usev[pos + cp->sym] & USED) break; } // No child needs an in-use slot? We're done. if (!cp) break; } tp->x.state = pos; // Mark node's base and children as used: usev[pos] |= need; STATE last = 0; // Make compiler happy int nkids = 0; for (cp = tp->child; cp; *dstp++ = cp, cp = cp->next, ++nkids) usev[last = pos + cp->sym] |= USED; // This is a HEURISTIC for advancing search for other nodes *startp += (pos - *startp) / nkids; if (last_trans < last) { last_trans = last; if (last + nsyms >= usev_size) { char *tmp = g_realloc(usev, usev_size << 1); if (tmp != NULL) { usev = tmp; memset(usev + usev_size, 0, usev_size); usev_size <<= 1; } else { g_free(usev); /* And handle error */ } } } } *dstp = NULL; } g_free(usev); return last_trans + 1; } static void fill_hashv(ac_trie_t *psp, TNODE const treev[], int nnodes) { STRASH *sv = g_malloc(psp->hash_mod * sizeof*sv), *sp = sv; int i; // First pass: insert without resolving collisions. for (i = 0; i < nnodes; ++i) { STATE base = treev[i].x.state; TNODE const *tp; for (tp = treev[i].child; tp; tp = tp->next) { if (tp->match && tp->child) { STATE state = base + tp->sym; STRASH *hp = &psp->hashv[p_hash(psp, state)]; *(hp->state ? sp++ : hp) = (STRASH){state, tp->match - 1}; } } } while (--sp >= sv) { HIT("hash collisions"); for (i = p_hash(psp, sp->state); psp->hashv[i].state; ++i) HIT("hash displacements"); psp->hashv[i] = *sp; } g_free(sv); } static void fill_tranv(ac_trie_t *psp, TNODE const*tp) { TNODE const *cp = tp->child; if (cp && tp->back) set_tran(psp, tp->x.state, 0, 0, 0, tp->back->x.state); for (; cp; cp = cp->next) { //NOTE: cp->match is (strno+1) so that !cp->match means "no match". set_tran(psp, tp->x.state, cp->sym, cp->match, cp->is_suffix, cp->child ? cp->x.state : cp->match - 1 + psp->tran_size); if (cp->child) fill_tranv(psp, cp); } } static TNODE * find_child(TNODE *tp, SYMBOL sym) { for (tp = tp->child; tp && tp->sym < sym; tp = tp->next); return tp && tp->sym == sym ? tp : NULL; } #ifdef ACISM_STATS PSSTAT psstat[__LINE__] = {{__LINE__,0}}; #endif//ACISM_STATS //EOF