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/**CFile****************************************************************
FileName [AbcGlucose.cpp]
SystemName [ABC: Logic synthesis and verification system.]
PackageName [SAT solver Glucose 3.0.]
Synopsis [Interface to Glucose.]
Author [Alan Mishchenko]
Affiliation [UC Berkeley]
Date [Ver. 1.0. Started - September 6, 2017.]
Revision [$Id: AbcGlucose.cpp,v 1.00 2005/06/20 00:00:00 alanmi Exp $]
***********************************************************************/
#include "sat/glucose/System.h"
#include "sat/glucose/ParseUtils.h"
#include "sat/glucose/Options.h"
#include "sat/glucose/Dimacs.h"
#include "sat/glucose/SimpSolver.h"
#include "sat/glucose/AbcGlucose.h"
#include "aig/gia/gia.h"
#include "sat/cnf/cnf.h"
using namespace Gluco;
ABC_NAMESPACE_IMPL_START
extern "C" {
////////////////////////////////////////////////////////////////////////
/// DECLARATIONS ///
////////////////////////////////////////////////////////////////////////
////////////////////////////////////////////////////////////////////////
/// FUNCTION DEFINITIONS ///
////////////////////////////////////////////////////////////////////////
/**Function*************************************************************
Synopsis []
Description []
SideEffects []
SeeAlso []
***********************************************************************/
Gluco::Solver * glucose_solver_start()
{
Solver * S = new Solver;
S->setIncrementalMode();
return S;
}
void glucose_solver_stop(Gluco::Solver* S)
{
delete S;
}
int glucose_solver_addclause(Gluco::Solver* S, int * plits, int nlits)
{
vec<Lit> lits;
for ( int i = 0; i < nlits; i++,plits++)
{
// note: Glucose uses the same var->lit conventiaon as ABC
while ((*plits)/2 >= S->nVars()) S->newVar();
assert((*plits)/2 < S->nVars()); // NOTE: since we explicitely use new function bmc_add_var
Lit p;
p.x = *plits;
lits.push(p);
}
return S->addClause(lits); // returns 0 if the problem is UNSAT
}
void glucose_solver_setcallback(Gluco::Solver* S, void * pman, int(*pfunc)(void*, int, int*))
{
S->pCnfMan = pman;
S->pCnfFunc = pfunc;
S->nCallConfl = 1000;
}
int glucose_solver_solve(Gluco::Solver* S, int * plits, int nlits)
{
vec<Lit> lits;
for (int i=0;i<nlits;i++,plits++)
{
Lit p;
p.x = *plits;
lits.push(p);
}
Gluco::lbool res = S->solveLimited(lits);
return (res == l_True ? 1 : res == l_False ? -1 : 0);
}
int glucose_solver_addvar(Gluco::Solver* S)
{
S->newVar();
return S->nVars() - 1;
}
int glucose_solver_read_cex_varvalue(Gluco::Solver* S, int ivar)
{
return S->model[ivar] == l_True;
}
void glucose_solver_setstop(Gluco::Solver* S, int * pstop)
{
S->pstop = pstop;
}
void glucose_print_stats(Solver& s, abctime clk)
{
double cpu_time = (double)(unsigned)clk / CLOCKS_PER_SEC;
double mem_used = memUsed();
printf("c restarts : %d (%d conflicts on average)\n", (int)s.starts, s.starts > 0 ? s.conflicts/s.starts : 0);
printf("c blocked restarts : %d (multiple: %d) \n", (int)s.nbstopsrestarts,s.nbstopsrestartssame);
printf("c last block at restart : %d\n", (int)s.lastblockatrestart);
printf("c nb ReduceDB : %-12d\n", (int)s.nbReduceDB);
printf("c nb removed Clauses : %-12d\n", (int)s.nbRemovedClauses);
printf("c nb learnts DL2 : %-12d\n", (int)s.nbDL2);
printf("c nb learnts size 2 : %-12d\n", (int)s.nbBin);
printf("c nb learnts size 1 : %-12d\n", (int)s.nbUn);
printf("c conflicts : %-12d (%.0f /sec)\n", (int)s.conflicts, s.conflicts /cpu_time);
printf("c decisions : %-12d (%4.2f %% random) (%.0f /sec)\n", (int)s.decisions, (float)s.rnd_decisions*100 / (float)s.decisions, s.decisions /cpu_time);
printf("c propagations : %-12d (%.0f /sec)\n", (int)s.propagations, s.propagations/cpu_time);
printf("c conflict literals : %-12d (%4.2f %% deleted)\n", (int)s.tot_literals, (s.max_literals - s.tot_literals)*100 / (double)s.max_literals);
printf("c nb reduced Clauses : %-12d\n", (int)s.nbReducedClauses);
if (mem_used != 0) printf("Memory used : %.2f MB\n", mem_used);
//printf("c CPU time : %.2f sec\n", cpu_time);
}
/**Function*************************************************************
Synopsis [Wrapper APIs to calling from ABC.]
Description []
SideEffects []
SeeAlso []
***********************************************************************/
bmcg_sat_solver * bmcg_sat_solver_start()
{
return (bmcg_sat_solver *)glucose_solver_start();
}
void bmcg_sat_solver_stop(bmcg_sat_solver* s)
{
glucose_solver_stop((Gluco::Solver*)s);
}
int bmcg_sat_solver_addclause(bmcg_sat_solver* s, int * plits, int nlits)
{
return glucose_solver_addclause((Gluco::Solver*)s,plits,nlits);
}
void bmcg_sat_solver_setcallback(bmcg_sat_solver* s, void * pman, int(*pfunc)(void*, int, int*))
{
glucose_solver_setcallback((Gluco::Solver*)s,pman,pfunc);
}
int bmcg_sat_solver_solve(bmcg_sat_solver* s, int * plits, int nlits)
{
return glucose_solver_solve((Gluco::Solver*)s,plits,nlits);
}
int bmcg_sat_solver_final(bmcg_sat_solver* s, int ** ppArray)
{
*ppArray = (int *)(Lit *)((Gluco::Solver*)s)->conflict;
return ((Gluco::Solver*)s)->conflict.size();
}
int bmcg_sat_solver_addvar(bmcg_sat_solver* s)
{
return glucose_solver_addvar((Gluco::Solver*)s);
}
void bmcg_sat_solver_set_nvars( bmcg_sat_solver* s, int nvars )
{
int i;
for ( i = bmcg_sat_solver_varnum(s); i < nvars; i++ )
bmcg_sat_solver_addvar(s);
}
int bmcg_sat_solver_eliminate( bmcg_sat_solver* s, int turn_off_elim )
{
return 1;
return ((Gluco::SimpSolver*)s)->eliminate(turn_off_elim != 0);
}
int bmcg_sat_solver_var_is_elim( bmcg_sat_solver* s, int v )
{
return 0;
return ((Gluco::SimpSolver*)s)->isEliminated(v);
}
int bmcg_sat_solver_read_cex_varvalue(bmcg_sat_solver* s, int ivar)
{
return glucose_solver_read_cex_varvalue((Gluco::Solver*)s, ivar);
}
void bmcg_sat_solver_set_stop(bmcg_sat_solver* s, int * pstop)
{
glucose_solver_setstop((Gluco::Solver*)s, pstop);
}
abctime bmcg_sat_solver_set_runtime_limit(bmcg_sat_solver* s, abctime Limit)
{
abctime nRuntimeLimit = ((Gluco::Solver*)s)->nRuntimeLimit;
((Gluco::Solver*)s)->nRuntimeLimit = Limit;
return nRuntimeLimit;
}
void bmcg_sat_solver_set_conflict_budget(bmcg_sat_solver* s, int Limit)
{
if ( Limit > 0 )
((Gluco::Solver*)s)->setConfBudget( (int64_t)Limit );
else
((Gluco::Solver*)s)->budgetOff();
}
int bmcg_sat_solver_varnum(bmcg_sat_solver* s)
{
return ((Gluco::Solver*)s)->nVars();
}
int bmcg_sat_solver_clausenum(bmcg_sat_solver* s)
{
return ((Gluco::Solver*)s)->nClauses();
}
int bmcg_sat_solver_learntnum(bmcg_sat_solver* s)
{
return ((Gluco::Solver*)s)->nLearnts();
}
int bmcg_sat_solver_conflictnum(bmcg_sat_solver* s)
{
return ((Gluco::Solver*)s)->conflicts;
}
/**Function*************************************************************
Synopsis []
Description []
SideEffects []
SeeAlso []
***********************************************************************/
void Glucose_SolveCnf( char * pFilename, Glucose_Pars * pPars )
{
abctime clk = Abc_Clock();
SimpSolver S;
S.verbosity = pPars->verb;
S.setConfBudget( pPars->nConfls > 0 ? (int64_t)pPars->nConfls : -1 );
gzFile in = gzopen(pFilename, "rb");
parse_DIMACS(in, S);
gzclose(in);
if ( pPars->verb )
{
printf("c ============================[ Problem Statistics ]=============================\n");
printf("c | |\n");
printf("c | Number of variables: %12d |\n", S.nVars());
printf("c | Number of clauses: %12d |\n", S.nClauses());
}
if ( pPars->pre ) S.eliminate(true);
vec<Lit> dummy;
lbool ret = S.solveLimited(dummy);
if ( pPars->verb ) glucose_print_stats(S, Abc_Clock() - clk);
printf(ret == l_True ? "SATISFIABLE" : ret == l_False ? "UNSATISFIABLE" : "INDETERMINATE");
Abc_PrintTime( 1, " Time", Abc_Clock() - clk );
}
/**Function*************************************************************
Synopsis []
Description []
SideEffects []
SeeAlso []
***********************************************************************/
Vec_Int_t * Glucose_SolverFromAig( Gia_Man_t * p, SimpSolver& S )
{
//abctime clk = Abc_Clock();
int * pLit, * pStop, i;
Cnf_Dat_t * pCnf = (Cnf_Dat_t *)Mf_ManGenerateCnf( p, 8 /*nLutSize*/, 0 /*fCnfObjIds*/, 1/*fAddOrCla*/, 0, 0/*verbose*/ );
for ( i = 0; i < pCnf->nClauses; i++ )
{
vec<Lit> lits;
for ( pLit = pCnf->pClauses[i], pStop = pCnf->pClauses[i+1]; pLit < pStop; pLit++ )
{
int Lit = *pLit;
int parsed_lit = (Lit & 1)? -(Lit >> 1)-1 : (Lit >> 1)+1;
int var = abs(parsed_lit)-1;
while (var >= S.nVars()) S.newVar();
lits.push( (parsed_lit > 0) ? mkLit(var) : ~mkLit(var) );
}
S.addClause(lits);
}
Vec_Int_t * vCnfIds = Vec_IntAllocArrayCopy(pCnf->pVarNums,pCnf->nVars);
//printf( "CNF stats: Vars = %6d. Clauses = %7d. Literals = %8d. ", pCnf->nVars, pCnf->nClauses, pCnf->nLiterals );
//Abc_PrintTime( 1, "Time", Abc_Clock() - clk );
Cnf_DataFree(pCnf);
return vCnfIds;
}
int Glucose_SolveAig(Gia_Man_t * p, Glucose_Pars * pPars)
{
abctime clk = Abc_Clock();
SimpSolver S;
S.verbosity = pPars->verb;
S.verbEveryConflicts = 50000;
S.showModel = false;
S.setConfBudget( pPars->nConfls > 0 ? (int64_t)pPars->nConfls : -1 );
S.parsing = 1;
Vec_Int_t * vCnfIds = Glucose_SolverFromAig(p,S);
S.parsing = 0;
if (pPars->verb)
{
printf("c ============================[ Problem Statistics ]=============================\n");
printf("c | |\n");
printf("c | Number of variables: %12d |\n", S.nVars());
printf("c | Number of clauses: %12d |\n", S.nClauses());
}
if (pPars->pre)
S.eliminate(true);
vec<Lit> dummy;
lbool ret = S.solveLimited(dummy);
if ( pPars->verb ) glucose_print_stats(S, Abc_Clock() - clk);
printf(ret == l_True ? "SATISFIABLE" : ret == l_False ? "UNSATISFIABLE" : "INDETERMINATE");
Abc_PrintTime( 1, " Time", Abc_Clock() - clk );
// port counterexample
if (ret == l_True)
{
Gia_Obj_t * pObj; int i;
p->pCexComb = Abc_CexAlloc(0,Gia_ManCiNum(p),1);
Gia_ManForEachCi( p, pObj, i )
{
assert(Vec_IntEntry(vCnfIds,Gia_ObjId(p, pObj))!=-1);
if (S.model[Vec_IntEntry(vCnfIds,Gia_ObjId(p, pObj))] == l_True)
Abc_InfoSetBit( p->pCexComb->pData, i);
}
}
Vec_IntFree(vCnfIds);
return (ret == l_True ? 10 : ret == l_False ? 20 : 0);
}
////////////////////////////////////////////////////////////////////////
/// END OF FILE ///
////////////////////////////////////////////////////////////////////////
}
ABC_NAMESPACE_IMPL_END
|