/************************************************************************************************** MiniSat -- Copyright (c) 2005, Niklas Sorensson http://www.cs.chalmers.se/Cs/Research/FormalMethods/MiniSat/ Permission is hereby granted, free of charge, to any person obtaining a copy of this software and associated documentation files (the "Software"), to deal in the Software without restriction, including without limitation the rights to use, copy, modify, merge, publish, distribute, sublicense, and/or sell copies of the Software, and to permit persons to whom the Software is furnished to do so, subject to the following conditions: The above copyright notice and this permission notice shall be included in all copies or substantial portions of the Software. THE SOFTWARE IS PROVIDED "AS IS", WITHOUT WARRANTY OF ANY KIND, EXPRESS OR IMPLIED, INCLUDING BUT NOT LIMITED TO THE WARRANTIES OF MERCHANTABILITY, FITNESS FOR A PARTICULAR PURPOSE AND NONINFRINGEMENT. IN NO EVENT SHALL THE AUTHORS OR COPYRIGHT HOLDERS BE LIABLE FOR ANY CLAIM, DAMAGES OR OTHER LIABILITY, WHETHER IN AN ACTION OF CONTRACT, TORT OR OTHERWISE, ARISING FROM, OUT OF OR IN CONNECTION WITH THE SOFTWARE OR THE USE OR OTHER DEALINGS IN THE SOFTWARE. **************************************************************************************************/ // Modified to compile with MS Visual Studio 6.0 by Alan Mishchenko #include #include #include #include #include "satSolver2.h" ABC_NAMESPACE_IMPL_START #define SAT_USE_ANALYZE_FINAL #define SAT_USE_PROOF_LOGGING //================================================================================================= // Debug: //#define VERBOSEDEBUG // For derivation output (verbosity level 2) #define L_IND "%-*d" #define L_ind solver2_dlevel(s)*3+3,solver2_dlevel(s) #define L_LIT "%sx%d" #define L_lit(p) lit_sign(p)?"~":"", (lit_var(p)) static void printlits(lit* begin, lit* end) { int i; for (i = 0; i < end - begin; i++) printf(L_LIT" ",L_lit(begin[i])); } //================================================================================================= // Random numbers: // Returns a random float 0 <= x < 1. Seed must never be 0. static inline double drand(double* seed) { int q; *seed *= 1389796; q = (int)(*seed / 2147483647); *seed -= (double)q * 2147483647; return *seed / 2147483647; } // Returns a random integer 0 <= x < size. Seed must never be 0. static inline int irand(double* seed, int size) { return (int)(drand(seed) * size); } static inline int sat_float2int( float Val ) { union { int x; float y; } v; v.y = Val; return v.x; } static inline float sat_int2float( int Num ) { union { int x; float y; } v; v.x = Num; return v.y; } //================================================================================================= // Predeclarations: static void solver2_sort(void** array, int size, int(*comp)(const void *, const void *)); //================================================================================================= // Variable datatype + minor functions: static const int var0 = 1; static const int var1 = 0; static const int varX = 3; struct varinfo_t { unsigned val : 2; // variable value unsigned pol : 1; // last polarity unsigned partA : 1; // partA variable unsigned tag : 4; // conflict analysis tags unsigned lev : 24; // variable level }; int var_is_partA (sat_solver2* s, int v) { return s->vi[v].partA; } void var_set_partA(sat_solver2* s, int v, int partA) { s->vi[v].partA = partA; } static inline int var_value (sat_solver2* s, int v) { return s->vi[v].val; } static inline int var_polar (sat_solver2* s, int v) { return s->vi[v].pol; } static inline int var_level (sat_solver2* s, int v) { return s->vi[v].lev; } static inline void var_set_value (sat_solver2* s, int v, int val) { s->vi[v].val = val; } static inline void var_set_polar (sat_solver2* s, int v, int pol) { s->vi[v].pol = pol; } static inline void var_set_level (sat_solver2* s, int v, int lev) { s->vi[v].lev = lev; } // variable tags static inline int var_tag (sat_solver2* s, int v) { return s->vi[v].tag; } static inline void var_set_tag (sat_solver2* s, int v, int tag) { assert( tag > 0 && tag < 16 ); if ( s->vi[v].tag == 0 ) veci_push( &s->tagged, v ); s->vi[v].tag = tag; } static inline void var_add_tag (sat_solver2* s, int v, int tag) { assert( tag > 0 && tag < 16 ); if ( s->vi[v].tag == 0 ) veci_push( &s->tagged, v ); s->vi[v].tag |= tag; } static inline void solver2_clear_tags(sat_solver2* s, int start) { int i, * tagged = veci_begin(&s->tagged); for (i = start; i < veci_size(&s->tagged); i++) s->vi[tagged[i]].tag = 0; veci_resize(&s->tagged,start); } // level marks static inline int var_lev_mark (sat_solver2* s, int v) { return (veci_begin(&s->trail_lim)[var_level(s,v)] & 0x80000000) > 0; } static inline void var_lev_set_mark (sat_solver2* s, int v) { int level = var_level(s,v); assert( level < veci_size(&s->trail_lim) ); veci_begin(&s->trail_lim)[level] |= 0x80000000; veci_push(&s->mark_levels, level); } static inline void solver2_clear_marks(sat_solver2* s) { int i, * mark_levels = veci_begin(&s->mark_levels); for (i = 0; i < veci_size(&s->mark_levels); i++) veci_begin(&s->trail_lim)[mark_levels[i]] &= 0x7FFFFFFF; veci_resize(&s->mark_levels,0); } //================================================================================================= // Clause datatype + minor functions: static inline satset* clause_read (sat_solver2* s, cla h) { return satset_read( &s->clauses, h ); } static inline cla clause_handle (sat_solver2* s, satset* c) { return satset_handle( &s->clauses, c ); } static inline int clause_check (sat_solver2* s, satset* c) { return satset_check( &s->clauses, c ); } static inline int clause_proofid(sat_solver2* s, satset* c, int partA) { return c->learnt ? (veci_begin(&s->claProofs)[c->Id]<<2) | (partA<<1) : (clause_handle(s,c)<<2) | 1; } //static inline int var_reason (sat_solver2* s, int v) { return (s->reasons[v]&1) ? 0 : s->reasons[v] >> 1; } //static inline int lit_reason (sat_solver2* s, int l) { return (s->reasons[lit_var(l)&1]) ? 0 : s->reasons[lit_var(l)] >> 1; } //static inline satset* var_unit_clause(sat_solver2* s, int v) { return (s->reasons[v]&1) ? clause_read(s, s->reasons[v] >> 1) : NULL; } //static inline void var_set_unit_clause(sat_solver2* s, int v, cla i){ assert(i && !s->reasons[v]); s->reasons[v] = (i << 1) | 1; } static inline int var_reason (sat_solver2* s, int v) { return s->reasons[v]; } static inline int lit_reason (sat_solver2* s, int l) { return s->reasons[lit_var(l)]; } static inline satset* var_unit_clause(sat_solver2* s, int v) { return clause_read(s, s->units[v]); } static inline void var_set_unit_clause(sat_solver2* s, int v, cla i){ assert(v >= 0 && v < s->size && !s->units[v]); s->units[v] = i; s->nUnits++; } // these two only work after creating a clause before the solver is called int clause_is_partA (sat_solver2* s, int h) { return clause_read(s, h)->partA; } void clause_set_partA(sat_solver2* s, int h, int partA) { clause_read(s, h)->partA = partA; } int clause_id(sat_solver2* s, int h) { return clause_read(s, h)->Id; } #define sat_solver_foreach_clause( s, c, h ) satset_foreach_entry( &s->clauses, c, h, 1 ) #define sat_solver_foreach_learnt( s, c, h ) satset_foreach_entry( &s->clauses, c, h, s->hLearntFirst ) //================================================================================================= // Simple helpers: static inline int solver2_dlevel(sat_solver2* s) { return veci_size(&s->trail_lim); } static inline veci* solver2_wlist(sat_solver2* s, lit l) { return &s->wlists[l]; } //================================================================================================= // Proof logging: static inline void proof_chain_start( sat_solver2* s, satset* c ) { if ( s->fProofLogging ) { s->iStartChain = veci_size(&s->proofs); veci_push(&s->proofs, 0); veci_push(&s->proofs, 0); veci_push(&s->proofs, clause_proofid(s, c, 0) ); } } static inline void proof_chain_resolve( sat_solver2* s, satset* cls, int Var ) { if ( s->fProofLogging ) { satset* c = cls ? cls : var_unit_clause( s, Var ); veci_push(&s->proofs, clause_proofid(s, c, var_is_partA(s,Var)) ); // printf( "%d %d ", clause_proofid(s, c), Var ); } } static inline int proof_chain_stop( sat_solver2* s ) { if ( s->fProofLogging ) { int RetValue = s->iStartChain; satset* c = (satset*)(veci_begin(&s->proofs) + s->iStartChain); assert( s->iStartChain > 0 && s->iStartChain < veci_size(&s->proofs) ); c->nEnts = veci_size(&s->proofs) - s->iStartChain - 2; s->iStartChain = 0; return RetValue; } return 0; } //================================================================================================= // Variable order functions: static inline void order_update(sat_solver2* s, int v) // updateorder { int* orderpos = s->orderpos; int* heap = veci_begin(&s->order); int i = orderpos[v]; int x = heap[i]; int parent = (i - 1) / 2; assert(s->orderpos[v] != -1); while (i != 0 && s->activity[x] > s->activity[heap[parent]]){ heap[i] = heap[parent]; orderpos[heap[i]] = i; i = parent; parent = (i - 1) / 2; } heap[i] = x; orderpos[x] = i; } static inline void order_assigned(sat_solver2* s, int v) { } static inline void order_unassigned(sat_solver2* s, int v) // undoorder { int* orderpos = s->orderpos; if (orderpos[v] == -1){ orderpos[v] = veci_size(&s->order); veci_push(&s->order,v); order_update(s,v); } } static inline int order_select(sat_solver2* s, float random_var_freq) // selectvar { int* heap = veci_begin(&s->order); int* orderpos = s->orderpos; // Random decision: if (drand(&s->random_seed) < random_var_freq){ int next = irand(&s->random_seed,s->size); assert(next >= 0 && next < s->size); if (var_value(s, next) == varX) return next; } // Activity based decision: while (veci_size(&s->order) > 0){ int next = heap[0]; int size = veci_size(&s->order)-1; int x = heap[size]; veci_resize(&s->order,size); orderpos[next] = -1; if (size > 0){ unsigned act = s->activity[x]; int i = 0; int child = 1; while (child < size){ if (child+1 < size && s->activity[heap[child]] < s->activity[heap[child+1]]) child++; assert(child < size); if (act >= s->activity[heap[child]]) break; heap[i] = heap[child]; orderpos[heap[i]] = i; i = child; child = 2 * child + 1; } heap[i] = x; orderpos[heap[i]] = i; } if (var_value(s, next) == varX) return next; } return var_Undef; } //================================================================================================= // Activity functions: #ifdef USE_FLOAT_ACTIVITY static inline void act_var_rescale(sat_solver2* s) { double* activity = s->activity; int i; for (i = 0; i < s->size; i++) activity[i] *= 1e-100; s->var_inc *= 1e-100; } static inline void act_clause_rescale(sat_solver2* s) { static int Total = 0; float * claActs = (float *)veci_begin(&s->claActs); int i, clk = clock(); for (i = 0; i < veci_size(&s->claActs); i++) claActs[i] *= (float)1e-20; s->cla_inc *= (float)1e-20; Total += clock() - clk; // printf( "Rescaling... Cla inc = %10.3f Conf = %10d ", s->cla_inc, s->stats.conflicts ); // Abc_PrintTime( 1, "Time", Total ); } static inline void act_var_bump(sat_solver2* s, int v) { s->activity[v] += s->var_inc; if (s->activity[v] > 1e100) act_var_rescale(s); if (s->orderpos[v] != -1) order_update(s,v); } static inline void act_clause_bump(sat_solver2* s, satset*c) { float * claActs = (float *)veci_begin(&s->claActs); assert( c->Id < veci_size(&s->claActs) ); claActs[c->Id] += s->cla_inc; if (claActs[c->Id] > (float)1e20) act_clause_rescale(s); } static inline void act_var_decay(sat_solver2* s) { s->var_inc *= s->var_decay; } static inline void act_clause_decay(sat_solver2* s) { s->cla_inc *= s->cla_decay; } #else static inline void act_var_rescale(sat_solver2* s) { unsigned* activity = s->activity; int i; for (i = 0; i < s->size; i++) activity[i] >>= 19; s->var_inc >>= 19; s->var_inc = Abc_MaxInt( s->var_inc, (1<<4) ); } static inline void act_clause_rescale(sat_solver2* s) { static int Total = 0; int i, clk = clock(); unsigned * claActs = (unsigned *)veci_begin(&s->claActs); for (i = 1; i < veci_size(&s->claActs); i++) claActs[i] >>= 14; s->cla_inc >>= 14; s->cla_inc = Abc_MaxInt( s->cla_inc, (1<<10) ); Total += clock() - clk; // printf( "Rescaling... Cla inc = %5d Conf = %10d ", s->cla_inc, s->stats.conflicts ); // Abc_PrintTime( 1, "Time", Total ); } static inline void act_var_bump(sat_solver2* s, int v) { s->activity[v] += s->var_inc; if (s->activity[v] & 0x80000000) act_var_rescale(s); if (s->orderpos[v] != -1) order_update(s,v); } static inline void act_clause_bump(sat_solver2* s, satset*c) { unsigned * claActs = (unsigned *)veci_begin(&s->claActs); assert( c->Id > 0 && c->Id < veci_size(&s->claActs) ); claActs[c->Id] += s->cla_inc; if (claActs[c->Id] & 0x80000000) act_clause_rescale(s); } static inline void act_var_decay(sat_solver2* s) { s->var_inc += (s->var_inc >> 4); } static inline void act_clause_decay(sat_solver2* s) { s->cla_inc += (s->cla_inc >> 10); } #endif //================================================================================================= // Clause functions: static int clause_new(sat_solver2* s, lit* begin, lit* end, int learnt, int proof_id) { satset* c; int i, Cid, nLits = end - begin; assert(nLits < 1 || begin[0] >= 0); assert(nLits < 2 || begin[1] >= 0); assert(nLits < 1 || lit_var(begin[0]) < s->size); assert(nLits < 2 || lit_var(begin[1]) < s->size); // add memory if needed if ( veci_size(&s->clauses) + satset_size(nLits) > s->clauses.cap ) { int nMemAlloc = s->clauses.cap ? 2 * s->clauses.cap : (1 << 20); s->clauses.ptr = ABC_REALLOC( int, veci_begin(&s->clauses), nMemAlloc ); // memset( veci_begin(&s->clauses) + s->clauses.cap, 0, sizeof(int) * (nMemAlloc - s->clauses.cap) ); // printf( "Reallocing from %d to %d...\n", s->clauses.cap, nMemAlloc ); s->clauses.cap = nMemAlloc; if ( veci_size(&s->clauses) == 0 ) veci_push( &s->clauses, -1 ); } // create clause c = (satset*)(veci_begin(&s->clauses) + veci_size(&s->clauses)); ((int*)c)[0] = 0; c->learnt = learnt; c->nEnts = nLits; for (i = 0; i < nLits; i++) c->pEnts[i] = begin[i]; // assign clause ID if ( learnt ) { s->stats.learnts++; s->stats.learnts_literals += nLits; c->Id = s->stats.learnts; assert( c->Id == veci_size(&s->claActs) ); veci_push(&s->claActs, 0); if ( proof_id ) veci_push(&s->claProofs, proof_id); if ( nLits > 2 ) act_clause_bump( s,c ); // printf( "Clause for proof %d: ", proof_id ); // satset_print( c ); } else { s->stats.clauses++; s->stats.clauses_literals += nLits; c->Id = s->stats.clauses; } // extend storage Cid = veci_size(&s->clauses); s->clauses.size += satset_size(nLits); assert( veci_size(&s->clauses) <= s->clauses.cap ); assert(((ABC_PTRUINT_T)c & 3) == 0); // remember the last one and first learnt s->hLearntLast = Cid; if ( learnt && s->hLearntFirst == -1 ) s->hLearntFirst = Cid; // watch the clause if ( nLits > 1 ){ veci_push(solver2_wlist(s,lit_neg(begin[0])),Cid); veci_push(solver2_wlist(s,lit_neg(begin[1])),Cid); } return Cid; } //================================================================================================= // Minor (solver) functions: static inline int solver2_enqueue(sat_solver2* s, lit l, int from) { int v = lit_var(l); #ifdef VERBOSEDEBUG printf(L_IND"solver2_enqueue("L_LIT")\n", L_ind, L_lit(l)); #endif if (var_value(s, v) != varX) return var_value(s, v) == lit_sign(l); else { // New fact -- store it. #ifdef VERBOSEDEBUG printf(L_IND"bind("L_LIT")\n", L_ind, L_lit(l)); #endif var_set_value( s, v, lit_sign(l) ); var_set_level( s, v, solver2_dlevel(s) ); /* if ( s->units && s->units[v] != 0 ) { assert( solver2_dlevel(s) == 0 ); // assert( from == 0 ); if ( from ) printf( "." ); } */ s->reasons[v] = from; // = from << 1; s->trail[s->qtail++] = l; order_assigned(s, v); return true; } } static inline int solver2_assume(sat_solver2* s, lit l) { assert(s->qtail == s->qhead); assert(var_value(s, lit_var(l)) == varX); #ifdef VERBOSEDEBUG printf(L_IND"solver2_assume("L_LIT")\n", L_ind, L_lit(l)); #endif veci_push(&s->trail_lim,s->qtail); return solver2_enqueue(s,l,0); } static void solver2_canceluntil(sat_solver2* s, int level) { lit* trail; int bound; int lastLev; int c, x; if (solver2_dlevel(s) <= level) return; trail = s->trail; bound = (veci_begin(&s->trail_lim))[level]; lastLev = (veci_begin(&s->trail_lim))[veci_size(&s->trail_lim)-1]; for (c = s->qtail-1; c >= bound; c--) { x = lit_var(trail[c]); var_set_value(s, x, varX); s->reasons[x] = 0; if ( c < lastLev ) var_set_polar(s, x, !lit_sign(trail[c])); } for (c = s->qhead-1; c >= bound; c--) order_unassigned(s,lit_var(trail[c])); s->qhead = s->qtail = bound; veci_resize(&s->trail_lim,level); } static void solver2_record(sat_solver2* s, veci* cls, int proof_id) { lit* begin = veci_begin(cls); lit* end = begin + veci_size(cls); int Cid = clause_new(s,begin,end,1, proof_id); assert(veci_size(cls) > 0); if ( veci_size(cls) == 1 ) { if ( s->fProofLogging ) var_set_unit_clause(s, lit_var(begin[0]), Cid); Cid = 0; } solver2_enqueue(s, begin[0], Cid); } static double solver2_progress(sat_solver2* s) { int i; double progress = 0.0, F = 1.0 / s->size; for (i = 0; i < s->size; i++) if (var_value(s, i) != varX) progress += pow(F, var_level(s, i)); return progress / s->size; } //================================================================================================= // Major methods: /*_________________________________________________________________________________________________ | | analyzeFinal : (p : Lit) -> [void] | | Description: | Specialized analysis procedure to express the final conflict in terms of assumptions. | Calculates the (possibly empty) set of assumptions that led to the assignment of 'p', and | stores the result in 'out_conflict'. |________________________________________________________________________________________________@*/ /* void Solver::analyzeFinal(satset* confl, bool skip_first) { // -- NOTE! This code is relatively untested. Please report bugs! conflict.clear(); if (root_level == 0) return; vec& seen = analyze_seen; for (int i = skip_first ? 1 : 0; i < confl->size(); i++){ Var x = var((*confl)[i]); if (level[x] > 0) seen[x] = 1; } int start = (root_level >= trail_lim.size()) ? trail.size()-1 : trail_lim[root_level]; for (int i = start; i >= trail_lim[0]; i--){ Var x = var(trail[i]); if (seen[x]){ GClause r = reason[x]; if (r == GClause_NULL){ assert(level[x] > 0); conflict.push(~trail[i]); }else{ if (r.isLit()){ Lit p = r.lit(); if (level[var(p)] > 0) seen[var(p)] = 1; }else{ Clause& c = *r.clause(); for (int j = 1; j < c.size(); j++) if (level[var(c[j])] > 0) seen[var(c[j])] = 1; } } seen[x] = 0; } } } */ #ifdef SAT_USE_ANALYZE_FINAL static int solver2_analyze_final(sat_solver2* s, satset* conf, int skip_first) { int i, j, x;//, start; veci_resize(&s->conf_final,0); if ( s->root_level == 0 ) return -1; proof_chain_start( s, conf ); assert( veci_size(&s->tagged) == 0 ); satset_foreach_var( conf, x, i, skip_first ){ if ( var_level(s,x) ) var_set_tag(s, x, 1); else proof_chain_resolve( s, NULL, x ); } assert( s->root_level >= veci_size(&s->trail_lim) ); // start = (s->root_level >= veci_size(&s->trail_lim))? s->qtail-1 : (veci_begin(&s->trail_lim))[s->root_level]; for (i = s->qtail-1; i >= (veci_begin(&s->trail_lim))[0]; i--){ x = lit_var(s->trail[i]); if (var_tag(s,x)){ satset* c = clause_read(s, var_reason(s,x)); if (c){ proof_chain_resolve( s, c, x ); satset_foreach_var( c, x, j, 1 ){ if ( var_level(s,x) ) var_set_tag(s, x, 1); else proof_chain_resolve( s, NULL, x ); } }else { assert( var_level(s,x) ); veci_push(&s->conf_final,lit_neg(s->trail[i])); } } } solver2_clear_tags(s,0); return proof_chain_stop( s ); } #endif static int solver2_lit_removable_rec(sat_solver2* s, int v) { // tag[0]: True if original conflict clause literal. // tag[1]: Processed by this procedure // tag[2]: 0=non-removable, 1=removable satset* c; int i, x; // skip visited if (var_tag(s,v) & 2) return (var_tag(s,v) & 4) > 0; // skip decisions on a wrong level c = clause_read(s, var_reason(s,v)); if ( c == NULL ){ var_add_tag(s,v,2); return 0; } satset_foreach_var( c, x, i, 1 ){ if (var_tag(s,x) & 1) solver2_lit_removable_rec(s, x); else{ if (var_level(s,x) == 0 || var_tag(s,x) == 6) continue; // -- 'x' checked before, found to be removable (or belongs to the toplevel) if (var_tag(s,x) == 2 || !var_lev_mark(s,x) || !solver2_lit_removable_rec(s, x)) { // -- 'x' checked before, found NOT to be removable, or it belongs to a wrong level, or cannot be removed var_add_tag(s,v,2); return 0; } } } // if (pfl && visit[p0] & 1){ // result.push(p0); } if ( s->fProofLogging && (var_tag(s,v) & 1) ) veci_push(&s->min_lit_order, v ); var_add_tag(s,v,6); return 1; } static int solver2_lit_removable(sat_solver2* s, int x) { satset* c; int i, top; if ( !var_reason(s,x) ) return 0; if ( var_tag(s,x) & 2 ) { assert( var_tag(s,x) & 1 ); return 1; } top = veci_size(&s->tagged); veci_resize(&s->stack,0); veci_push(&s->stack, x << 1); while (veci_size(&s->stack)) { x = veci_pop(&s->stack); if ( s->fProofLogging ){ if ( x & 1 ){ if ( var_tag(s,x >> 1) & 1 ) veci_push(&s->min_lit_order, x >> 1 ); continue; } veci_push(&s->stack, x ^ 1 ); } x >>= 1; c = clause_read(s, var_reason(s,x)); satset_foreach_var( c, x, i, 1 ){ if (var_tag(s,x) || !var_level(s,x)) continue; if (!var_reason(s,x) || !var_lev_mark(s,x)){ solver2_clear_tags(s, top); return 0; } veci_push(&s->stack, x << 1); var_set_tag(s, x, 2); } } return 1; } static void solver2_logging_order(sat_solver2* s, int x) { satset* c; int i; if ( (var_tag(s,x) & 4) ) return; var_add_tag(s, x, 4); veci_resize(&s->stack,0); veci_push(&s->stack,x << 1); while (veci_size(&s->stack)) { x = veci_pop(&s->stack); if ( x & 1 ){ veci_push(&s->min_step_order, x >> 1 ); continue; } veci_push(&s->stack, x ^ 1 ); x >>= 1; c = clause_read(s, var_reason(s,x)); // if ( !c ) // printf( "solver2_logging_order(): Error in conflict analysis!!!\n" ); satset_foreach_var( c, x, i, 1 ){ if ( !var_level(s,x) || (var_tag(s,x) & 1) ) continue; veci_push(&s->stack, x << 1); var_add_tag(s, x, 4); } } } static void solver2_logging_order_rec(sat_solver2* s, int x) { satset* c; int i, y; if ( (var_tag(s,x) & 8) ) return; c = clause_read(s, var_reason(s,x)); satset_foreach_var( c, y, i, 1 ) if ( var_level(s,y) && (var_tag(s,y) & 1) == 0 ) solver2_logging_order_rec(s, y); var_add_tag(s, x, 8); veci_push(&s->min_step_order, x); } static int solver2_analyze(sat_solver2* s, satset* c, veci* learnt) { int cnt = 0; lit p = 0; int x, ind = s->qtail-1; int proof_id = 0; lit* lits,* vars, i, j, k; assert( veci_size(&s->tagged) == 0 ); // tag[0] - visited by conflict analysis (afterwards: literals of the learned clause) // tag[1] - visited by solver2_lit_removable() with success // tag[2] - visited by solver2_logging_order() proof_chain_start( s, c ); veci_push(learnt,lit_Undef); while ( 1 ){ assert(c != 0); if (c->learnt) act_clause_bump(s,c); satset_foreach_var( c, x, j, (int)(p > 0) ){ assert(x >= 0 && x < s->size); if ( var_tag(s, x) ) continue; if ( var_level(s,x) == 0 ) { proof_chain_resolve( s, NULL, x ); continue; } var_set_tag(s, x, 1); act_var_bump(s,x); if (var_level(s,x) == solver2_dlevel(s)) cnt++; else veci_push(learnt,c->pEnts[j]); } while (!var_tag(s, lit_var(s->trail[ind--]))); p = s->trail[ind+1]; c = clause_read(s, lit_reason(s,p)); cnt--; if ( cnt == 0 ) break; proof_chain_resolve( s, c, lit_var(p) ); } *veci_begin(learnt) = lit_neg(p); // mark levels assert( veci_size(&s->mark_levels) == 0 ); lits = veci_begin(learnt); for (i = 1; i < veci_size(learnt); i++) var_lev_set_mark(s, lit_var(lits[i])); // simplify (full) veci_resize(&s->min_lit_order, 0); for (i = j = 1; i < veci_size(learnt); i++){ // if (!solver2_lit_removable( s,lit_var(lits[i]))) if (!solver2_lit_removable_rec(s,lit_var(lits[i]))) // changed to vars!!! lits[j++] = lits[i]; } // record the proof if ( s->fProofLogging ) { // collect additional clauses to resolve veci_resize(&s->min_step_order, 0); vars = veci_begin(&s->min_lit_order); for (i = 0; i < veci_size(&s->min_lit_order); i++) // solver2_logging_order(s, vars[i]); solver2_logging_order_rec(s, vars[i]); // add them in the reverse order vars = veci_begin(&s->min_step_order); for (i = veci_size(&s->min_step_order); i > 0; ) { i--; c = clause_read(s, var_reason(s,vars[i])); proof_chain_resolve( s, c, vars[i] ); satset_foreach_var(c, x, k, 1) if ( var_level(s,x) == 0 ) proof_chain_resolve( s, NULL, x ); } proof_id = proof_chain_stop( s ); } // unmark levels solver2_clear_marks( s ); // update size of learnt + statistics veci_resize(learnt,j); s->stats.tot_literals += j; // clear tags solver2_clear_tags(s,0); #ifdef DEBUG for (i = 0; i < s->size; i++) assert(!var_tag(s, i)); #endif #ifdef VERBOSEDEBUG printf(L_IND"Learnt {", L_ind); for (i = 0; i < veci_size(learnt); i++) printf(" "L_LIT, L_lit(lits[i])); #endif if (veci_size(learnt) > 1){ lit tmp; int max_i = 1; int max = var_level(s, lit_var(lits[1])); for (i = 2; i < veci_size(learnt); i++) if (max < var_level(s, lit_var(lits[i]))) { max = var_level(s, lit_var(lits[i])); max_i = i; } tmp = lits[1]; lits[1] = lits[max_i]; lits[max_i] = tmp; } #ifdef VERBOSEDEBUG { int lev = veci_size(learnt) > 1 ? var_level(s, lit_var(lits[1])) : 0; printf(" } at level %d\n", lev); } #endif return proof_id; } satset* solver2_propagate(sat_solver2* s) { satset* c, * confl = NULL; veci* ws; lit* lits, false_lit, p, * stop, * k; cla* begin,* end, *i, *j; while (confl == 0 && s->qtail - s->qhead > 0){ p = s->trail[s->qhead++]; ws = solver2_wlist(s,p); begin = (cla*)veci_begin(ws); end = begin + veci_size(ws); s->stats.propagations++; s->simpdb_props--; for (i = j = begin; i < end; ){ c = clause_read(s,*i); lits = c->pEnts; // Make sure the false literal is data[1]: false_lit = lit_neg(p); if (lits[0] == false_lit){ lits[0] = lits[1]; lits[1] = false_lit; } assert(lits[1] == false_lit); // If 0th watch is true, then clause is already satisfied. if (var_value(s, lit_var(lits[0])) == lit_sign(lits[0])) *j++ = *i; else{ // Look for new watch: stop = lits + c->nEnts; for (k = lits + 2; k < stop; k++){ if (var_value(s, lit_var(*k)) != !lit_sign(*k)){ lits[1] = *k; *k = false_lit; veci_push(solver2_wlist(s,lit_neg(lits[1])),*i); goto WatchFound; } } // Did not find watch -- clause is unit under assignment: if (s->fProofLogging && solver2_dlevel(s) == 0){ int k, x, proof_id, Cid, Var = lit_var(lits[0]); int fLitIsFalse = (var_value(s, Var) == !lit_sign(lits[0])); // Log production of top-level unit clause: proof_chain_start( s, c ); satset_foreach_var( c, x, k, 1 ){ assert( var_level(s, x) == 0 ); proof_chain_resolve( s, NULL, x ); } proof_id = proof_chain_stop( s ); // get a new clause Cid = clause_new( s, lits, lits + 1, 1, proof_id ); assert( (var_unit_clause(s, Var) == NULL) != fLitIsFalse ); // if variable already has unit clause, it must be with the other polarity // in this case, we should derive the empty clause here if ( var_unit_clause(s, Var) == NULL ) var_set_unit_clause(s, Var, Cid); else{ // Empty clause derived: proof_chain_start( s, clause_read(s,Cid) ); proof_chain_resolve( s, NULL, Var ); proof_id = proof_chain_stop( s ); clause_new( s, lits, lits, 1, proof_id ); } } *j++ = *i; // Clause is unit under assignment: if (!solver2_enqueue(s,lits[0], *i)){ confl = clause_read(s,*i++); // Copy the remaining watches: while (i < end) *j++ = *i++; } } WatchFound: i++; } s->stats.inspects += j - (int*)veci_begin(ws); veci_resize(ws,j - (int*)veci_begin(ws)); } return confl; } /* static void clause_remove(sat_solver2* s, satset* c) { assert(lit_neg(c->pEnts[0]) < s->size*2); assert(lit_neg(c->pEnts[1]) < s->size*2); veci_remove(solver2_wlist(s,lit_neg(c->pEnts[0])),clause_handle(s,c)); veci_remove(solver2_wlist(s,lit_neg(c->pEnts[1])),clause_handle(s,c)); if (c->learnt){ s->stats.learnts--; s->stats.learnts_literals -= c->nEnts; }else{ s->stats.clauses--; s->stats.clauses_literals -= c->nEnts; } } */ static lbool clause_simplify(sat_solver2* s, satset* c) { int i, x; assert(solver2_dlevel(s) == 0); satset_foreach_var( c, x, i, 0 ) if (var_value(s, x) == lit_sign(c->pEnts[i])) return l_True; return l_False; } int sat_solver2_simplify(sat_solver2* s) { // int type; int Counter = 0; assert(solver2_dlevel(s) == 0); if (solver2_propagate(s) != 0) return false; if (s->qhead == s->simpdb_assigns || s->simpdb_props > 0) return true; /* for (type = 0; type < 2; type++){ veci* cs = type ? &s->learnts : &s->clauses; int* cls = (int*)veci_begin(cs); int i, j; for (j = i = 0; i < veci_size(cs); i++){ satset* c = clause_read(s,cls[i]); if (lit_reason(s,c->pEnts[0]) != cls[i] && clause_simplify(s,c) == l_True) clause_remove(s,c), Counter++; else cls[j++] = cls[i]; } veci_resize(cs,j); } */ //printf( "Simplification removed %d clauses (out of %d)...\n", Counter, s->stats.clauses ); s->simpdb_assigns = s->qhead; // (shouldn't depend on 'stats' really, but it will do for now) s->simpdb_props = (int)(s->stats.clauses_literals + s->stats.learnts_literals); return true; } /* void solver2_reducedb(sat_solver2* s) { satset* c; cla Cid; int clk = clock(); // sort the clauses by activity int nLearnts = veci_size(&s->claActs) - 1; extern int * Abc_SortCost( int * pCosts, int nSize ); int * pPerm, * pCosts = veci_begin(&s->claActs); pPerm = Abc_SortCost( pCosts, veci_size(&s->claActs) ); assert( pCosts[pPerm[1]] <= pCosts[pPerm[veci_size(&s->claActs)-1]] ); // mark clauses to be removed { double extra_limD = (double)s->cla_inc / nLearnts; // Remove any clause below this activity unsigned extra_lim = (extra_limD < 1.0) ? 1 : (int)extra_limD; unsigned * pActs = (unsigned *)veci_begin(&s->claActs); int k = 1, Counter = 0; sat_solver_foreach_learnt( s, c, Cid ) { assert( c->Id == k ); c->mark = 0; if ( c->nEnts > 2 && lit_reason(s,c->pEnts[0]) != Cid && (k < nLearnts/2 || pActs[k] < extra_lim) ) { c->mark = 1; Counter++; } k++; } printf( "ReduceDB removed %10d clauses (out of %10d)... Cutoff = %8d ", Counter, nLearnts, extra_lim ); Abc_PrintTime( 1, "Time", clock() - clk ); } ABC_FREE( pPerm ); } */ static lbool solver2_search(sat_solver2* s, ABC_INT64_T nof_conflicts) { double random_var_freq = s->fNotUseRandom ? 0.0 : 0.02; ABC_INT64_T conflictC = 0; veci learnt_clause; int proof_id; assert(s->root_level == solver2_dlevel(s)); s->stats.starts++; veci_resize(&s->model,0); veci_new(&learnt_clause); for (;;){ satset* confl = solver2_propagate(s); if (confl != 0){ // CONFLICT int blevel; #ifdef VERBOSEDEBUG printf(L_IND"**CONFLICT**\n", L_ind); #endif s->stats.conflicts++; conflictC++; if (solver2_dlevel(s) <= s->root_level){ #ifdef SAT_USE_ANALYZE_FINAL proof_id = solver2_analyze_final(s, confl, 0); if ( proof_id > 0 ) solver2_record(s,&s->conf_final, proof_id); #endif veci_delete(&learnt_clause); return l_False; } veci_resize(&learnt_clause,0); proof_id = solver2_analyze(s, confl, &learnt_clause); blevel = veci_size(&learnt_clause) > 1 ? var_level(s, lit_var(veci_begin(&learnt_clause)[1])) : s->root_level; blevel = s->root_level > blevel ? s->root_level : blevel; solver2_canceluntil(s,blevel); solver2_record(s,&learnt_clause, proof_id); #ifdef SAT_USE_ANALYZE_FINAL // if (learnt_clause.size() == 1) level[var(learnt_clause[0])] = 0; // (this is ugly (but needed for 'analyzeFinal()') -- in future versions, we will backtrack past the 'root_level' and redo the assumptions) if ( learnt_clause.size == 1 ) var_set_level( s, lit_var(learnt_clause.ptr[0]), 0 ); #endif act_var_decay(s); act_clause_decay(s); }else{ // NO CONFLICT int next; if (nof_conflicts >= 0 && conflictC >= nof_conflicts){ // Reached bound on number of conflicts: s->progress_estimate = solver2_progress(s); solver2_canceluntil(s,s->root_level); veci_delete(&learnt_clause); return l_Undef; } if ( (s->nConfLimit && s->stats.conflicts > s->nConfLimit) || // (s->nInsLimit && s->stats.inspects > s->nInsLimit) ) (s->nInsLimit && s->stats.propagations > s->nInsLimit) ) { // Reached bound on number of conflicts: s->progress_estimate = solver2_progress(s); solver2_canceluntil(s,s->root_level); veci_delete(&learnt_clause); return l_Undef; } // if (solver2_dlevel(s) == 0 && !s->fSkipSimplify) // Simplify the set of problem clauses: // sat_solver2_simplify(s); // New variable decision: s->stats.decisions++; next = order_select(s,(float)random_var_freq); if (next == var_Undef){ // Model found: int i; veci_resize(&s->model, 0); for (i = 0; i < s->size; i++) veci_push( &s->model, var_value(s,i)==var1 ? l_True : l_False ); solver2_canceluntil(s,s->root_level); veci_delete(&learnt_clause); /* veci apa; veci_new(&apa); for (i = 0; i < s->size; i++) veci_push(&apa,(int)(s->model.ptr[i] == l_True ? toLit(i) : lit_neg(toLit(i)))); printf("model: "); printlits((lit*)apa.ptr, (lit*)apa.ptr + veci_size(&apa)); printf("\n"); veci_delete(&apa); */ return l_True; } if ( var_polar(s, next) ) // positive polarity solver2_assume(s,toLit(next)); else solver2_assume(s,lit_neg(toLit(next))); } } return l_Undef; // cannot happen } //================================================================================================= // External solver functions: sat_solver2* sat_solver2_new(void) { sat_solver2* s = (sat_solver2 *)ABC_CALLOC( char, sizeof(sat_solver2) ); // initialize vectors veci_new(&s->order); veci_new(&s->trail_lim); veci_new(&s->tagged); veci_new(&s->stack); veci_new(&s->model); veci_new(&s->temp_clause); veci_new(&s->conf_final); veci_new(&s->mark_levels); veci_new(&s->min_lit_order); veci_new(&s->min_step_order); veci_new(&s->learnt_live); veci_new(&s->proofs); veci_push(&s->proofs, -1); veci_new(&s->claActs); veci_push(&s->claActs, -1); veci_new(&s->claProofs); veci_push(&s->claProofs, -1); // initialize other s->hLearntFirst = -1; // the first learnt clause s->hLearntLast = -1; // the last learnt clause #ifdef USE_FLOAT_ACTIVITY s->var_inc = 1; s->cla_inc = 1; s->var_decay = (float)(1 / 0.95 ); s->cla_decay = (float)(1 / 0.999 ); #else s->var_inc = (1 << 5); s->cla_inc = (1 << 11); #endif s->random_seed = 91648253; #ifdef SAT_USE_PROOF_LOGGING s->fProofLogging = 1; #else s->fProofLogging = 0; #endif // prealloc some arrays if ( s->fProofLogging ) { s->proofs.cap = (1 << 20); s->proofs.ptr = ABC_REALLOC( int, s->proofs.ptr, s->proofs.cap ); } return s; } void sat_solver2_setnvars(sat_solver2* s,int n) { int var; if (s->cap < n){ while (s->cap < n) s->cap = s->cap*2+1; s->wlists = ABC_REALLOC(veci, s->wlists, s->cap*2); s->vi = ABC_REALLOC(varinfo, s->vi, s->cap); s->trail = ABC_REALLOC(lit, s->trail, s->cap); s->orderpos = ABC_REALLOC(int, s->orderpos, s->cap); s->reasons = ABC_REALLOC(cla, s->reasons, s->cap); if ( s->fProofLogging ) s->units = ABC_REALLOC(cla, s->units, s->cap); #ifdef USE_FLOAT_ACTIVITY s->activity = ABC_REALLOC(double, s->activity, s->cap); #else s->activity = ABC_REALLOC(unsigned, s->activity, s->cap); #endif } for (var = s->size; var < n; var++){ veci_new(&s->wlists[2*var]); veci_new(&s->wlists[2*var+1]); *((int*)s->vi + var) = 0; s->vi[var].val = varX; s->orderpos[var] = veci_size(&s->order); s->reasons [var] = 0; if ( s->fProofLogging ) s->units [var] = 0; s->activity[var] = (1<<10); // does not hold because variables enqueued at top level will not be reinserted in the heap // assert(veci_size(&s->order) == var); veci_push(&s->order,var); order_update(s, var); } s->size = n > s->size ? n : s->size; } void sat_solver2_delete(sat_solver2* s) { satset * c = clause_read(s, s->hLearntLast); // report statistics printf( "Used %6.2f Mb for proof-logging. Unit clauses = %d.\n", 2.0 * veci_size(&s->proofs) / (1<<20), s->nUnits ); Sat_ProofTest( &s->clauses, // clauses &s->proofs, // proof clauses NULL, // proof roots veci_begin(&s->claProofs)[c->Id] // one root ); // delete vectors veci_delete(&s->order); veci_delete(&s->trail_lim); veci_delete(&s->tagged); veci_delete(&s->stack); veci_delete(&s->model); veci_delete(&s->temp_clause); veci_delete(&s->conf_final); veci_delete(&s->mark_levels); veci_delete(&s->min_lit_order); veci_delete(&s->min_step_order); veci_delete(&s->learnt_live); veci_delete(&s->proofs); veci_delete(&s->claActs); veci_delete(&s->claProofs); veci_delete(&s->clauses); // delete arrays if (s->vi != 0){ int i; if ( s->wlists ) for (i = 0; i < s->size*2; i++) { // printf( "%d ", s->wlists[i].size ); veci_delete(&s->wlists[i]); } ABC_FREE(s->wlists ); ABC_FREE(s->vi ); ABC_FREE(s->trail ); ABC_FREE(s->orderpos ); ABC_FREE(s->reasons ); ABC_FREE(s->units ); ABC_FREE(s->activity ); } ABC_FREE(s); } int sat_solver2_addclause__(sat_solver2* s, lit* begin, lit* end) { lit *i,*j; int maxvar; lit last; if (begin == end) { assert( 0 ); return false; } // copy clause into storage veci_resize( &s->temp_clause, 0 ); for ( i = begin; i < end; i++ ) veci_push( &s->temp_clause, *i ); begin = veci_begin( &s->temp_clause ); end = begin + veci_size( &s->temp_clause ); //printlits(begin,end); printf("\n"); // insertion sort maxvar = lit_var(*begin); for (i = begin + 1; i < end; i++){ lit l = *i; maxvar = lit_var(l) > maxvar ? lit_var(l) : maxvar; for (j = i; j > begin && *(j-1) > l; j--) *j = *(j-1); *j = l; } sat_solver2_setnvars(s,maxvar+1); // delete duplicates last = lit_Undef; for (i = j = begin; i < end; i++){ //printf("lit: "L_LIT", value = %d\n", L_lit(*i), (lit_sign(*i) ? -values[lit_var(*i)] : values[lit_var(*i)])); if (*i == lit_neg(last) || var_value(s, lit_var(*i)) == lit_sign(*i)) return true; // tautology else if (*i != last && var_value(s, lit_var(*i)) == varX) last = *j++ = *i; } //printf("final: "); printlits(begin,j); printf("\n"); if (j == begin) // empty clause { assert( 0 ); return false; } if (j - begin == 1) // unit clause return solver2_enqueue(s,*begin,0); // create new clause return clause_new(s,begin,j,0,0); } int sat_solver2_addclause(sat_solver2* s, lit* begin, lit* end) { cla Cid; lit *i,*j; int maxvar; assert( begin < end ); // copy clause into storage veci_resize( &s->temp_clause, 0 ); for ( i = begin; i < end; i++ ) veci_push( &s->temp_clause, *i ); begin = veci_begin( &s->temp_clause ); end = begin + veci_size( &s->temp_clause ); // insertion sort maxvar = lit_var(*begin); for (i = begin + 1; i < end; i++){ lit l = *i; maxvar = lit_var(l) > maxvar ? lit_var(l) : maxvar; for (j = i; j > begin && *(j-1) > l; j--) *j = *(j-1); *j = l; } sat_solver2_setnvars(s,maxvar+1); // create a new clause Cid = clause_new( s, begin, end, 0, 0 ); // handle unit clause if ( begin + 1 == end ) { printf( "Adding unit clause %d\n", begin[0] ); // solver2_canceluntil(s, 0); if ( s->fProofLogging ) var_set_unit_clause( s, lit_var(begin[0]), Cid ); if ( !solver2_enqueue(s,begin[0],0) ) assert( 0 ); } // count literals s->stats.clauses++; s->stats.clauses_literals += end - begin; return Cid; } double luby2(double y, int x) { int size, seq; for (size = 1, seq = 0; size < x+1; seq++, size = 2*size + 1); while (size-1 != x){ size = (size-1) >> 1; seq--; x = x % size; } return pow(y, (double)seq); } void luby2_test() { int i; for ( i = 0; i < 20; i++ ) printf( "%d ", (int)luby2(2,i) ); printf( "\n" ); } // updates clauses, watches, units, and proof void solver2_reducedb(sat_solver2* s) { extern void Sat_ProofReduce( veci * pProof, veci * pRoots ); satset * c; cla h,* pArray,* pArray2; int Counter = 0, CounterStart = s->stats.learnts * 2 / 3; int i, j, k, hTemp, hHandle, clk = clock(); static int TimeTotal = 0; // remove 2/3 of learned clauses while skipping small clauses veci_resize( &s->learnt_live, 0 ); sat_solver_foreach_learnt( s, c, h ) if ( Counter++ > CounterStart || c->nEnts < 3 ) veci_push( &s->learnt_live, h ); else c->mark = 1; // report the results printf( "reduceDB: Keeping %7d out of %7d clauses (%5.2f %%) ", veci_size(&s->learnt_live), s->stats.learnts, 100.0 * veci_size(&s->learnt_live) / s->stats.learnts ); // remap clause proofs and clauses hHandle = s->hLearntFirst; pArray = veci_begin(&s->claProofs); pArray2 = veci_begin(&s->claActs); satset_foreach_entry_vec( &s->learnt_live, &s->clauses, c, i ) { pArray[i+1] = pArray[c->Id]; pArray2[i+1] = pArray2[c->Id]; c->Id = hHandle; hHandle += satset_size(c->nEnts); } veci_resize(&s->claProofs,veci_size(&s->learnt_live)+1); veci_resize(&s->claActs,veci_size(&s->learnt_live)+1); // compact watches for ( i = 0; i < s->size*2; i++ ) { pArray = veci_begin(&s->wlists[i]); for ( j = k = 0; k < veci_size(&s->wlists[i]); k++ ) if ( pArray[k] < s->hLearntFirst ) pArray[j++] = pArray[k]; else if ( !(c = clause_read(s, pArray[k]))->mark ) pArray[j++] = c->Id; veci_resize(&s->wlists[i],j); } // compact units for ( i = 0; i < s->size; i++ ) if ( s->units[i] >= s->hLearntFirst ) s->units[i] = clause_read(s, s->units[i])->Id; // compact clauses satset_foreach_entry_vec( &s->learnt_live, &s->clauses, c, i ) { hTemp = c->Id; c->Id = i + 1; memmove( veci_begin(&s->clauses) + hTemp, c, sizeof(int)*satset_size(c->nEnts) ); } assert( hHandle == hTemp + satset_size(c->nEnts) ); veci_resize(&s->clauses,hHandle); s->stats.learnts = veci_size(&s->learnt_live); // compact proof (compacts 'proofs' and update 'claProofs') Sat_ProofReduce( &s->proofs, &s->claProofs ); TimeTotal += clock() - clk; Abc_PrintTime( 1, "Time", TimeTotal ); } int sat_solver2_solve(sat_solver2* s, lit* begin, lit* end, ABC_INT64_T nConfLimit, ABC_INT64_T nInsLimit, ABC_INT64_T nConfLimitGlobal, ABC_INT64_T nInsLimitGlobal) { int restart_iter = 0; ABC_INT64_T nof_conflicts; ABC_INT64_T nof_learnts = sat_solver2_nclauses(s) / 3; lbool status = l_Undef; // lbool* values = s->assigns; lit* i; s->hLearntLast = -1; // set the external limits // s->nCalls++; // s->nRestarts = 0; s->nConfLimit = 0; s->nInsLimit = 0; if ( nConfLimit ) s->nConfLimit = s->stats.conflicts + nConfLimit; if ( nInsLimit ) // s->nInsLimit = s->stats.inspects + nInsLimit; s->nInsLimit = s->stats.propagations + nInsLimit; if ( nConfLimitGlobal && (s->nConfLimit == 0 || s->nConfLimit > nConfLimitGlobal) ) s->nConfLimit = nConfLimitGlobal; if ( nInsLimitGlobal && (s->nInsLimit == 0 || s->nInsLimit > nInsLimitGlobal) ) s->nInsLimit = nInsLimitGlobal; #ifndef SAT_USE_ANALYZE_FINAL //printf("solve: "); printlits(begin, end); printf("\n"); for (i = begin; i < end; i++){ // switch (lit_sign(*i) ? -values[lit_var(*i)] : values[lit_var(*i)]){ switch (var_value(s, *i)) { case var1: // l_True: break; case varX: // l_Undef solver2_assume(s, *i); if (solver2_propagate(s) == NULL) break; // fallthrough case var0: // l_False solver2_canceluntil(s, 0); return l_False; } } s->root_level = solver2_dlevel(s); #endif /* // Perform assumptions: root_level = assumps.size(); for (int i = 0; i < assumps.size(); i++){ Lit p = assumps[i]; assert(var(p) < nVars()); if (!solver2_assume(p)){ GClause r = reason[var(p)]; if (r != GClause_NULL){ satset* confl; if (r.isLit()){ confl = propagate_tmpbin; (*confl)[1] = ~p; (*confl)[0] = r.lit(); }else confl = r.clause(); analyzeFinal(confl, true); conflict.push(~p); }else conflict.clear(), conflict.push(~p); cancelUntil(0); return false; } satset* confl = propagate(); if (confl != NULL){ analyzeFinal(confl), assert(conflict.size() > 0); cancelUntil(0); return false; } } assert(root_level == decisionLevel()); */ #ifdef SAT_USE_ANALYZE_FINAL // Perform assumptions: s->root_level = end - begin; for ( i = begin; i < end; i++ ) { lit p = *i; assert(lit_var(p) < s->size); veci_push(&s->trail_lim,s->qtail); if (!solver2_enqueue(s,p,0)) { satset* r = clause_read(s, lit_reason(s,p)); if (r != NULL) { satset* confl = r; solver2_analyze_final(s, confl, 1); veci_push(&s->conf_final, lit_neg(p)); } else { veci_resize(&s->conf_final,0); veci_push(&s->conf_final, lit_neg(p)); // the two lines below are a bug fix by Siert Wieringa if (var_level(s, lit_var(p)) > 0) veci_push(&s->conf_final, p); } solver2_canceluntil(s, 0); return l_False; } else { satset* confl = solver2_propagate(s); if (confl != NULL){ solver2_analyze_final(s, confl, 0); assert(s->conf_final.size > 0); solver2_canceluntil(s, 0); return l_False; } } } assert(s->root_level == solver2_dlevel(s)); #endif if (s->verbosity >= 1){ printf("==================================[MINISAT]===================================\n"); printf("| Conflicts | ORIGINAL | LEARNT | Progress |\n"); printf("| | Clauses Literals | Limit Clauses Literals Lit/Cl | |\n"); printf("==============================================================================\n"); } while (status == l_Undef){ if (s->verbosity >= 1) { printf("| %9.0f | %7.0f %8.0f | %7.0f %7.0f %8.0f %7.1f | %6.3f %% |\n", (double)s->stats.conflicts, (double)s->stats.clauses, (double)s->stats.clauses_literals, (double)nof_learnts, (double)s->stats.learnts, (double)s->stats.learnts_literals, (s->stats.learnts == 0)? 0.0 : (double)s->stats.learnts_literals / s->stats.learnts, s->progress_estimate*100); fflush(stdout); } if ( s->nRuntimeLimit && time(NULL) > s->nRuntimeLimit ) break; // reduce the set of learnt clauses: if (nof_learnts > 0 && s->stats.learnts > nof_learnts) { solver2_reducedb(s); nof_learnts = nof_learnts * 11 / 10; } // perform next run nof_conflicts = (ABC_INT64_T)( 100 * luby2(2, restart_iter++) ); status = solver2_search(s, nof_conflicts); // quit the loop if reached an external limit if ( s->nConfLimit && s->stats.conflicts > s->nConfLimit ) break; if ( s->nInsLimit && s->stats.propagations > s->nInsLimit ) break; } if (s->verbosity >= 1) printf("==============================================================================\n"); solver2_canceluntil(s,0); return status; } ABC_NAMESPACE_IMPL_END