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Diffstat (limited to 'src/aig/fra/fraClaus.c')
-rw-r--r-- | src/aig/fra/fraClaus.c | 912 |
1 files changed, 912 insertions, 0 deletions
diff --git a/src/aig/fra/fraClaus.c b/src/aig/fra/fraClaus.c new file mode 100644 index 00000000..8024431e --- /dev/null +++ b/src/aig/fra/fraClaus.c @@ -0,0 +1,912 @@ +/**CFile**************************************************************** + + FileName [fraClaus.c] + + SystemName [ABC: Logic synthesis and verification system.] + + PackageName [New FRAIG package.] + + Synopsis [Induction with clause strengthening.] + + Author [Alan Mishchenko] + + Affiliation [UC Berkeley] + + Date [Ver. 1.0. Started - June 30, 2007.] + + Revision [$Id: fraClau.c,v 1.00 2007/06/30 00:00:00 alanmi Exp $] + +***********************************************************************/ + +#include "fra.h" +#include "cnf.h" +#include "satSolver.h" + +//////////////////////////////////////////////////////////////////////// +/// DECLARATIONS /// +//////////////////////////////////////////////////////////////////////// + +typedef struct Clu_Man_t_ Clu_Man_t; +struct Clu_Man_t_ +{ + // parameters + int nFrames; + int nClausesMax; + int fVerbose; + int fVeryVerbose; + int nSimWords; + int nSimFrames; + // the network + Aig_Man_t * pAig; + // SAT solvers + sat_solver * pSatMain; + sat_solver * pSatBmc; + // CNF for the test solver + Cnf_Dat_t * pCnf; + // the counter example + Vec_Int_t * vValues; + // clauses + Vec_Int_t * vLits; + Vec_Int_t * vClauses; + Vec_Int_t * vCosts; + int nClauses; + // counter-examples + Vec_Ptr_t * vCexes; + int nCexes; + int nCexesAlloc; +}; + +//////////////////////////////////////////////////////////////////////// +/// FUNCTION DEFINITIONS /// +//////////////////////////////////////////////////////////////////////// + +/**Function************************************************************* + + Synopsis [Runs the SAT solver on the problem.] + + Description [] + + SideEffects [] + + SeeAlso [] + +***********************************************************************/ +int Fra_ClausRunBmc( Clu_Man_t * p ) +{ + Aig_Obj_t * pObj; + int * pLits; + int nBTLimit = 0; + int i, RetValue; + pLits = ALLOC( int, p->nFrames + 1 ); + // set the output literals + pObj = Aig_ManPo(p->pAig, 0); + for ( i = 0; i < p->nFrames; i++ ) + pLits[i] = i * 2 * p->pCnf->nVars + toLitCond( p->pCnf->pVarNums[pObj->Id], 0 ); + // try to solve the problem +// sat_solver_act_var_clear( p->pSatBmc ); +// RetValue = sat_solver_solve( p->pSatBmc, NULL, NULL, (sint64)nBTLimit, (sint64)0, (sint64)0, (sint64)0 ); + for ( i = 0; i < p->nFrames; i++ ) + { + RetValue = sat_solver_solve( p->pSatBmc, pLits + i, pLits + i + 1, (sint64)nBTLimit, (sint64)0, (sint64)0, (sint64)0 ); + if ( RetValue != l_False ) + { + free( pLits ); + return 0; + } + } + free( pLits ); + +/* + // get the counter-example + assert( RetValue == l_True ); + nVarsTot = p->nFrames * p->pCnf->nVars; + Aig_ManForEachObj( p->pAig, pObj, i ) + Vec_IntWriteEntry( p->vValues, i, sat_solver_var_value(p->pSatBmc, nVarsTot + p->pCnf->pVarNums[i]) ); +*/ + return 1; +} + +/**Function************************************************************* + + Synopsis [Runs the SAT solver on the problem.] + + Description [] + + SideEffects [] + + SeeAlso [] + +***********************************************************************/ +int Fra_ClausRunSat( Clu_Man_t * p ) +{ + int nBTLimit = 0; + Aig_Obj_t * pObj; + int * pLits; + int i, nVarsTot, RetValue; + pLits = ALLOC( int, p->nFrames + 1 ); + // set the output literals + pObj = Aig_ManPo(p->pAig, 0); + for ( i = 0; i <= p->nFrames; i++ ) + pLits[i] = i * 2 * p->pCnf->nVars + toLitCond( p->pCnf->pVarNums[pObj->Id], i != p->nFrames ); + // try to solve the problem +// sat_solver_act_var_clear( p->pSatMain ); +// RetValue = sat_solver_solve( p->pSatMain, NULL, NULL, (sint64)nBTLimit, (sint64)0, (sint64)0, (sint64)0 ); + RetValue = sat_solver_solve( p->pSatMain, pLits, pLits + p->nFrames + 1, (sint64)nBTLimit, (sint64)0, (sint64)0, (sint64)0 ); + free( pLits ); + if ( RetValue == l_False ) + return 1; + // get the counter-example + assert( RetValue == l_True ); + nVarsTot = p->nFrames * p->pCnf->nVars; + Aig_ManForEachObj( p->pAig, pObj, i ) + Vec_IntWriteEntry( p->vValues, i, sat_solver_var_value(p->pSatMain, nVarsTot + p->pCnf->pVarNums[i]) ); + return 0; +} + +/**Function************************************************************* + + Synopsis [Runs the SAT solver on the problem.] + + Description [] + + SideEffects [] + + SeeAlso [] + +***********************************************************************/ +int Fra_ClausRunSat0( Clu_Man_t * p ) +{ + int nBTLimit = 0; + Aig_Obj_t * pObj; + int Lits[2], RetValue; + pObj = Aig_ManPo(p->pAig, 0); + Lits[0] = toLitCond( p->pCnf->pVarNums[pObj->Id], 0 ); + RetValue = sat_solver_solve( p->pSatMain, Lits, Lits + 1, (sint64)nBTLimit, (sint64)0, (sint64)0, (sint64)0 ); + if ( RetValue == l_False ) + return 1; + return 0; +} + +/**Function************************************************************* + + Synopsis [Processes the clauses.] + + Description [] + + SideEffects [] + + SeeAlso [] + +***********************************************************************/ +/* +int Fra_ClausProcessClausesCut( Clu_Man_t * p, Dar_Cut_t * pCut ) +{ + unsigned * pSimsC[4], * pSimsS[4]; + int pLits[4]; + int i, b, k, iMint, uMask, RetValue, nLeaves, nWordsTotal, nCounter; + // compute parameters + nLeaves = pCut->nLeaves; + nWordsTotal = p->pComb->nWordsTotal; + assert( nLeaves > 1 && nLeaves < 5 ); + assert( nWordsTotal == p->pSeq->nWordsTotal ); + // get parameters + for ( i = 0; i < (int)pCut->nLeaves; i++ ) + { + pSimsC[i] = Fra_ObjSim( p->pComb, pCut->pLeaves[i] ); + pSimsS[i] = Fra_ObjSim( p->pSeq, pCut->pLeaves[i] ); + } + // add combinational patterns + uMask = 0; + for ( i = 0; i < nWordsTotal; i++ ) + for ( k = 0; k < 32; k++ ) + { + iMint = 0; + for ( b = 0; b < nLeaves; b++ ) + if ( pSimsC[b][i] & (1 << k) ) + iMint |= (1 << b); + uMask |= (1 << iMint); + } + // remove sequential patterns + for ( i = 0; i < nWordsTotal; i++ ) + for ( k = 0; k < 32; k++ ) + { + iMint = 0; + for ( b = 0; b < nLeaves; b++ ) + if ( pSimsS[b][i] & (1 << k) ) + iMint |= (1 << b); + uMask &= ~(1 << iMint); + } + if ( uMask == 0 ) + return 0; + // add clauses for the remaining patterns + nCounter = 0; + for ( i = 0; i < (1<<nLeaves); i++ ) + { + if ( (uMask & (1 << i)) == 0 ) + continue; + nCounter++; +// continue; + + // add every third clause +// if ( (nCounter % 2) == 0 ) +// continue; + + for ( b = 0; b < nLeaves; b++ ) + pLits[b] = toLitCond( p->pCnf->pVarNums[pCut->pLeaves[b]], (i&(1<<b)) ); + // add the clause + RetValue = sat_solver_addclause( p->pSatMain, pLits, pLits + nLeaves ); +// assert( RetValue == 1 ); + if ( RetValue == 0 ) + { + printf( "Already UNSAT after %d clauses.\n", nCounter ); + return -1; + } + } + return nCounter; +} +*/ + + +/**Function************************************************************* + + Synopsis [Return combinations appearing in the cut.] + + Description [This procedure is taken from "Hacker's Delight" by H.S.Warren.] + + SideEffects [] + + SeeAlso [] + +***********************************************************************/ +void transpose32a( unsigned a[32] ) +{ + int j, k; + unsigned long m, t; + for ( j = 16, m = 0x0000FFFF; j; j >>= 1, m ^= m << j ) + { + for ( k = 0; k < 32; k = ((k | j) + 1) & ~j ) + { + t = (a[k] ^ (a[k|j] >> j)) & m; + a[k] ^= t; + a[k|j] ^= (t << j); + } + } +} + +/**Function************************************************************* + + Synopsis [Return combinations appearing in the cut.] + + Description [] + + SideEffects [] + + SeeAlso [] + +***********************************************************************/ +int Fra_ClausProcessClausesCut( Clu_Man_t * p, Fra_Sml_t * pSimMan, Dar_Cut_t * pCut, int * pScores ) +{ + unsigned Matrix[32]; + unsigned * pSims[4], uWord; + int nSeries, i, k, j; + // compute parameters + assert( pCut->nLeaves > 1 && pCut->nLeaves < 5 ); + assert( pSimMan->nWordsTotal % 8 == 0 ); + // get parameters + for ( i = 0; i < (int)pCut->nLeaves; i++ ) + pSims[i] = Fra_ObjSim( pSimMan, pCut->pLeaves[i] ); + // add combinational patterns + memset( pScores, 0, sizeof(int) * 16 ); + nSeries = pSimMan->nWordsTotal / 8; + for ( i = 0; i < nSeries; i++ ) + { + memset( Matrix, 0, sizeof(unsigned) * 32 ); + for ( k = 0; k < 8; k++ ) + for ( j = 0; j < (int)pCut->nLeaves; j++ ) + Matrix[31-(k*4+j)] = pSims[j][i*8+k]; +/* + for ( k = 0; k < 32; k++ ) + { + Extra_PrintBinary( stdout, Matrix + k, 32 ); printf( "\n" ); + } + printf( "\n" ); +*/ + transpose32a( Matrix ); +/* + for ( k = 0; k < 32; k++ ) + { + Extra_PrintBinary( stdout, Matrix + k, 32 ); printf( "\n" ); + } + printf( "\n" ); +*/ + for ( k = 0; k < 32; k++ ) + for ( j = 0, uWord = Matrix[k]; j < 8; j++, uWord >>= 4 ) + pScores[uWord & 0xF]++; + } + // collect patterns + uWord = 0; + for ( i = 0; i < 16; i++ ) + if ( pScores[i] ) + uWord |= (1 << i); +// Extra_PrintBinary( stdout, &uWord, 16 ); printf( "\n" ); + return (int)uWord; +} + +/**Function************************************************************* + + Synopsis [Return combinations appearing in the cut.] + + Description [] + + SideEffects [] + + SeeAlso [] + +***********************************************************************/ +int Fra_ClausProcessClausesCut2( Clu_Man_t * p, Fra_Sml_t * pSimMan, Dar_Cut_t * pCut, int * pScores ) +{ + unsigned * pSims[4], uWord; + int iMint, i, k, b; + // compute parameters + assert( pCut->nLeaves > 1 && pCut->nLeaves < 5 ); + assert( pSimMan->nWordsTotal % 8 == 0 ); + // get parameters + for ( i = 0; i < (int)pCut->nLeaves; i++ ) + pSims[i] = Fra_ObjSim( pSimMan, pCut->pLeaves[i] ); + // add combinational patterns + memset( pScores, 0, sizeof(int) * 16 ); + for ( i = 0; i < pSimMan->nWordsTotal; i++ ) + for ( k = 0; k < 32; k++ ) + { + iMint = 0; + for ( b = 0; b < (int)pCut->nLeaves; b++ ) + if ( pSims[b][i] & (1 << k) ) + iMint |= (1 << b); + pScores[iMint]++; + } + // collect patterns + uWord = 0; + for ( i = 0; i < 16; i++ ) + if ( pScores[i] ) + uWord |= (1 << i); +// Extra_PrintBinary( stdout, &uWord, 16 ); printf( "\n" ); + return (int)uWord; +} + +/**Function************************************************************* + + Synopsis [Processes the clauses.] + + Description [] + + SideEffects [] + + SeeAlso [] + +***********************************************************************/ +void Fra_ClausRecordClause( Clu_Man_t * p, Dar_Cut_t * pCut, int iMint, int Cost ) +{ + int i; + for ( i = 0; i < (int)pCut->nLeaves; i++ ) + Vec_IntPush( p->vLits, toLitCond( p->pCnf->pVarNums[pCut->pLeaves[i]], (iMint&(1<<i)) ) ); + Vec_IntPush( p->vClauses, Vec_IntSize(p->vLits) ); + Vec_IntPush( p->vCosts, Cost ); +} + +/**Function************************************************************* + + Synopsis [Processes the clauses.] + + Description [] + + SideEffects [] + + SeeAlso [] + +***********************************************************************/ +int Fra_ClausProcessClauses( Clu_Man_t * p ) +{ + Aig_MmFixed_t * pMemCuts; + Fra_Sml_t * pComb, * pSeq; + Aig_Obj_t * pObj; + Dar_Cut_t * pCut; + int Scores[16], uScores, i, k, j, clk, nCuts = 0; + + // simulate the AIG +clk = clock(); + srand( 0xAABBAABB ); + pSeq = Fra_SmlSimulateSeq( p->pAig, 0, p->nSimFrames, p->nSimWords/p->nSimFrames ); + if ( pSeq->fNonConstOut ) + { + printf( "Property failed after sequential simulation!\n" ); + Fra_SmlStop( pSeq ); + return 0; + } +PRT( "Sim-seq", clock() - clk ); + + // generate cuts for all nodes, assign cost, and find best cuts +clk = clock(); + pMemCuts = Dar_ManComputeCuts( p->pAig, 10 ); +PRT( "Cuts ", clock() - clk ); + + // collect sequential info for each cut +clk = clock(); + Aig_ManForEachNode( p->pAig, pObj, i ) + Dar_ObjForEachCut( pObj, pCut, k ) + if ( pCut->nLeaves > 1 ) + { + pCut->uTruth = Fra_ClausProcessClausesCut( p, pSeq, pCut, Scores ); +// uScores = Fra_ClausProcessClausesCut2( p, pSeq, pCut, Scores ); +// if ( uScores != pCut->uTruth ) +// { +// int x = 0; +// } + } +PRT( "Infoseq", clock() - clk ); + Fra_SmlStop( pSeq ); + + // perform combinational simulation +clk = clock(); + srand( 0xAABBAABB ); + pComb = Fra_SmlSimulateComb( p->pAig, p->nSimWords ); +PRT( "Sim-cmb", clock() - clk ); + + // collect combinational info for each cut +clk = clock(); + Aig_ManForEachNode( p->pAig, pObj, i ) + Dar_ObjForEachCut( pObj, pCut, k ) + if ( pCut->nLeaves > 1 ) + { + nCuts++; + uScores = Fra_ClausProcessClausesCut( p, pComb, pCut, Scores ); + uScores &= ~pCut->uTruth; pCut->uTruth = 0; + if ( uScores == 0 ) + continue; + // write the clauses + for ( j = 0; j < (1<<pCut->nLeaves); j++ ) + if ( uScores & (1 << j) ) + Fra_ClausRecordClause( p, pCut, j, Scores[j] ); + + } + Fra_SmlStop( pComb ); + Aig_MmFixedStop( pMemCuts, 0 ); +PRT( "Infocmb", clock() - clk ); + + printf( "Node = %5d. Non-triv cuts = %7d. Clauses = %6d. Clause per cut = %6.2f.\n", + Aig_ManNodeNum(p->pAig), nCuts, Vec_IntSize(p->vClauses), 1.0*Vec_IntSize(p->vClauses)/nCuts ); + return 1; +} + +/**Function************************************************************* + + Synopsis [Converts AIG into the SAT solver.] + + Description [] + + SideEffects [] + + SeeAlso [] + +***********************************************************************/ +int Fra_ClausBmcClauses( Clu_Man_t * p ) +{ + int nBTLimit = 0; + int * pStart, nLitsTot, RetValue, Beg, End, Counter, i, k, f; +/* + for ( i = 0; i < Vec_IntSize(p->vLits); i++ ) + printf( "%d ", p->vLits->pArray[i] ); + printf( "\n" ); +*/ + // add the clauses + Counter = 0; + nLitsTot = 2 * p->pCnf->nVars; + for ( f = 0; f < p->nFrames; f++ ) + { + Beg = 0; + Vec_IntForEachEntry( p->vClauses, End, i ) + { + if ( Vec_IntEntry( p->vCosts, i ) == -1 ) + { + Beg = End; + continue; + } + assert( Vec_IntEntry( p->vCosts, i ) > 0 ); + assert( End - Beg < 5 ); + pStart = Vec_IntArray(p->vLits); + for ( k = Beg; k < End; k++ ) + pStart[k] = lit_neg( pStart[k] ); + RetValue = sat_solver_solve( p->pSatBmc, pStart + Beg, pStart + End, (sint64)nBTLimit, (sint64)0, (sint64)0, (sint64)0 ); + for ( k = Beg; k < End; k++ ) + pStart[k] = lit_neg( pStart[k] ); + if ( RetValue != l_False ) + { + Beg = End; + Vec_IntWriteEntry( p->vCosts, i, -1 ); + Counter++; + continue; + } +/* + // add the clause + RetValue = sat_solver_addclause( p->pSatBmc, pStart + Beg, pStart + End ); + // assert( RetValue == 1 ); + if ( RetValue == 0 ) + { + printf( "Error: Solver is UNSAT after adding BMC clauses.\n" ); + return -1; + } +*/ + Beg = End; + + // simplify the solver + if ( p->pSatBmc->qtail != p->pSatBmc->qhead ) + { + RetValue = sat_solver_simplify(p->pSatBmc); + assert( RetValue != 0 ); + assert( p->pSatBmc->qtail == p->pSatBmc->qhead ); + } + } + // increment literals + for ( i = 0; i < Vec_IntSize(p->vLits); i++ ) + p->vLits->pArray[i] += nLitsTot; + } + + // return clauses back to normal + nLitsTot = p->nFrames * nLitsTot; + for ( i = 0; i < Vec_IntSize(p->vLits); i++ ) + p->vLits->pArray[i] -= nLitsTot; +/* + for ( i = 0; i < Vec_IntSize(p->vLits); i++ ) + printf( "%d ", p->vLits->pArray[i] ); + printf( "\n" ); +*/ + return Counter; +} + +/**Function************************************************************* + + Synopsis [Converts AIG into the SAT solver.] + + Description [] + + SideEffects [] + + SeeAlso [] + +***********************************************************************/ +int Fra_ClausInductiveClauses( Clu_Man_t * p ) +{ + int nBTLimit = 0; + int * pStart, nLitsTot, RetValue, Beg, End, Counter, i, k, f; + + // reset the solver + if ( p->pSatMain ) sat_solver_delete( p->pSatMain ); + p->pSatMain = Cnf_DataWriteIntoSolver( p->pCnf, p->nFrames+1, 0 ); + if ( p->pSatMain == NULL ) + { + printf( "Error: Main solver is unsat.\n" ); + return -1; + } +/* + // check if the property holds + if ( Fra_ClausRunSat0( p ) ) + printf( "Property holds without strengthening.\n" ); + else + printf( "Property does not hold without strengthening.\n" ); +*/ + // add the clauses + nLitsTot = 2 * p->pCnf->nVars; + for ( f = 0; f < p->nFrames; f++ ) + { + Beg = 0; + Vec_IntForEachEntry( p->vClauses, End, i ) + { + if ( Vec_IntEntry( p->vCosts, i ) == -1 ) + { + Beg = End; + continue; + } + assert( Vec_IntEntry( p->vCosts, i ) > 0 ); + assert( End - Beg < 5 ); + pStart = Vec_IntArray(p->vLits); + // add the clause to all timeframes + RetValue = sat_solver_addclause( p->pSatMain, pStart + Beg, pStart + End ); + if ( RetValue == 0 ) + { + printf( "Error: Solver is UNSAT after adding assumption clauses.\n" ); + return -1; + } + Beg = End; + } + // increment literals + for ( i = 0; i < Vec_IntSize(p->vLits); i++ ) + p->vLits->pArray[i] += nLitsTot; + } + + // simplify the solver + if ( p->pSatMain->qtail != p->pSatMain->qhead ) + { + RetValue = sat_solver_simplify(p->pSatMain); + assert( RetValue != 0 ); + assert( p->pSatMain->qtail == p->pSatMain->qhead ); + } + + // check if the property holds + if ( Fra_ClausRunSat0( p ) ) + { +// printf( "Property holds with strengthening.\n" ); + printf( " Property holds. " ); + } + else + { + printf( " Property fails. " ); + return -2; + } + +/* + // add the property for the first K frames + for ( i = 0; i < p->nFrames; i++ ) + { + Aig_Obj_t * pObj; + int Lits[2]; + // set the output literals + pObj = Aig_ManPo(p->pAig, 0); + Lits[0] = i * nLitsTot + toLitCond( p->pCnf->pVarNums[pObj->Id], 1 ); + // add the clause + RetValue = sat_solver_addclause( p->pSatMain, Lits, Lits + 1 ); +// assert( RetValue == 1 ); + if ( RetValue == 0 ) + { + printf( "Error: Solver is UNSAT after adding property for the first K frames.\n" ); + return -1; + } + } +*/ + + // simplify the solver + if ( p->pSatMain->qtail != p->pSatMain->qhead ) + { + RetValue = sat_solver_simplify(p->pSatMain); + assert( RetValue != 0 ); + assert( p->pSatMain->qtail == p->pSatMain->qhead ); + } + + + // check the clause in the last timeframe + Beg = 0; + Counter = 0; + Vec_IntForEachEntry( p->vClauses, End, i ) + { + if ( Vec_IntEntry( p->vCosts, i ) == -1 ) + { + Beg = End; + continue; + } + assert( Vec_IntEntry( p->vCosts, i ) > 0 ); + assert( End - Beg < 5 ); + pStart = Vec_IntArray(p->vLits); + + for ( k = Beg; k < End; k++ ) + pStart[k] = lit_neg( pStart[k] ); + RetValue = sat_solver_solve( p->pSatMain, pStart + Beg, pStart + End, (sint64)nBTLimit, (sint64)0, (sint64)0, (sint64)0 ); + for ( k = Beg; k < End; k++ ) + pStart[k] = lit_neg( pStart[k] ); + + // the problem is not solved + if ( RetValue != l_False ) + { + Beg = End; + Vec_IntWriteEntry( p->vCosts, i, -1 ); + Counter++; + continue; + } + // add the clause + RetValue = sat_solver_addclause( p->pSatMain, pStart + Beg, pStart + End ); +// assert( RetValue == 1 ); + if ( RetValue == 0 ) + { + printf( "Error: Solver is UNSAT after adding BMC clauses.\n" ); + return -1; + } + Beg = End; + + // simplify the solver + if ( p->pSatMain->qtail != p->pSatMain->qhead ) + { + RetValue = sat_solver_simplify(p->pSatMain); + assert( RetValue != 0 ); + assert( p->pSatMain->qtail == p->pSatMain->qhead ); + } + } + + // return clauses back to normal + nLitsTot = p->nFrames * nLitsTot; + for ( i = 0; i < Vec_IntSize(p->vLits); i++ ) + p->vLits->pArray[i] -= nLitsTot; + + return Counter; +} + + +/**Function************************************************************* + + Synopsis [Converts AIG into the SAT solver.] + + Description [] + + SideEffects [] + + SeeAlso [] + +***********************************************************************/ +Clu_Man_t * Fra_ClausAlloc( Aig_Man_t * pAig, int nFrames, int nClausesMax, int fVerbose, int fVeryVerbose ) +{ + Clu_Man_t * p; + p = ALLOC( Clu_Man_t, 1 ); + memset( p, 0, sizeof(Clu_Man_t) ); + p->pAig = pAig; + p->nFrames = nFrames; + p->nClausesMax = nClausesMax; + p->fVerbose = fVerbose; + p->fVeryVerbose = fVeryVerbose; + p->nSimWords = 256;//1024;//64; + p->nSimFrames = 16;//8;//32; + p->vValues = Vec_IntStart( Aig_ManObjNumMax(p->pAig) ); + + p->vLits = Vec_IntAlloc( 1<<14 ); + p->vClauses = Vec_IntAlloc( 1<<12 ); + p->vCosts = Vec_IntAlloc( 1<<12 ); + + p->nCexesAlloc = 1024; + p->vCexes = Vec_PtrAllocSimInfo( Aig_ManObjNumMax(p->pAig), p->nCexesAlloc/32 ); + Vec_PtrCleanSimInfo( p->vCexes, 0, p->nCexesAlloc/32 ); + return p; +} + +/**Function************************************************************* + + Synopsis [Converts AIG into the SAT solver.] + + Description [] + + SideEffects [] + + SeeAlso [] + +***********************************************************************/ +void Fra_ClausFree( Clu_Man_t * p ) +{ + if ( p->vCexes ) Vec_PtrFree( p->vCexes ); + if ( p->vLits ) Vec_IntFree( p->vLits ); + if ( p->vClauses ) Vec_IntFree( p->vClauses ); + if ( p->vCosts ) Vec_IntFree( p->vCosts ); + if ( p->vValues ) Vec_IntFree( p->vValues ); + if ( p->pCnf ) Cnf_DataFree( p->pCnf ); + if ( p->pSatMain ) sat_solver_delete( p->pSatMain ); + if ( p->pSatBmc ) sat_solver_delete( p->pSatBmc ); + free( p ); +} + +/**Function************************************************************* + + Synopsis [Converts AIG into the SAT solver.] + + Description [] + + SideEffects [] + + SeeAlso [] + +***********************************************************************/ +int Fra_Claus( Aig_Man_t * pAig, int nFrames, int nClausesMax, int fBmc, int fVerbose, int fVeryVerbose ) +{ + Clu_Man_t * p; + int clk, clkTotal = clock(); + int Iter, Counter; + + assert( Aig_ManPoNum(pAig) - Aig_ManRegNum(pAig) == 1 ); + + // create the manager + p = Fra_ClausAlloc( pAig, nFrames, nClausesMax, fVerbose, fVeryVerbose ); + +clk = clock(); + // derive CNF + p->pAig->nRegs++; + p->pCnf = Cnf_DeriveSimple( p->pAig, Aig_ManPoNum(p->pAig) ); + p->pAig->nRegs--; +PRT( "CNF ", clock() - clk ); + + // check BMC +clk = clock(); + p->pSatBmc = Cnf_DataWriteIntoSolver( p->pCnf, p->nFrames, 1 ); + if ( p->pSatBmc == NULL ) + { + printf( "Error: BMC solver is unsat.\n" ); + Fra_ClausFree( p ); + return 1; + } + if ( !Fra_ClausRunBmc( p ) ) + { + printf( "Problem trivially fails the base case.\n" ); + Fra_ClausFree( p ); + return 1; + } +PRT( "SAT try", clock() - clk ); + + // start the SAT solver +clk = clock(); + p->pSatMain = Cnf_DataWriteIntoSolver( p->pCnf, p->nFrames+1, 0 ); + if ( p->pSatMain == NULL ) + { + printf( "Error: Main solver is unsat.\n" ); + Fra_ClausFree( p ); + return 1; + } + // try solving without additional clauses + if ( Fra_ClausRunSat( p ) ) + { + printf( "Problem is inductive without strengthening.\n" ); + Fra_ClausFree( p ); + return 1; + } +PRT( "SAT try", clock() - clk ); + + // collect the candidate inductive clauses using 4-cuts +clk = clock(); + Fra_ClausProcessClauses( p ); + p->nClauses = Vec_IntSize( p->vClauses ); +PRT( "Clauses", clock() - clk ); + + + // check clauses using BMC + if ( fBmc ) + { +clk = clock(); + Counter = Fra_ClausBmcClauses( p ); + p->nClauses -= Counter; + printf( "BMC disproved %d clauses.\n", Counter ); +PRT( "Cla-bmc", clock() - clk ); + } + + + // prove clauses inductively +clk = clock(); + Counter = 1; + for ( Iter = 0; Counter > 0; Iter++ ) + { + printf( "Iter %3d : Begin = %5d. ", Iter, p->nClauses ); + Counter = Fra_ClausInductiveClauses( p ); + if ( Counter > 0 ) + p->nClauses -= Counter; + printf( "End = %5d. ", p->nClauses ); +// printf( "\n" ); + PRT( "Time", clock() - clk ); + clk = clock(); + } + if ( Counter == -1 ) + printf( "Fra_Claus(): Internal error.\n" ); + else if ( Counter == -2 ) + printf( "Property FAILS after %d iterations of refinement.\n", Iter ); + else + printf( "Property HOLDS inductively after strengthening.\n" ); + +/* +clk = clock(); + if ( Fra_ClausRunSat( p ) ) + printf( "Problem is solved.\n" ); + else + printf( "Problem is unsolved.\n" ); +PRT( "SAT try", clock() - clk ); +*/ + +PRT( "TOTAL ", clock() - clkTotal ); +printf( "\n" ); + // clean the manager + Fra_ClausFree( p ); + return 1; +} + +//////////////////////////////////////////////////////////////////////// +/// END OF FILE /// +//////////////////////////////////////////////////////////////////////// + + |