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/**CFile****************************************************************
FileName [intM114p.c]
SystemName [ABC: Logic synthesis and verification system.]
PackageName [Interpolation engine.]
Synopsis [Intepolation using interfaced to MiniSat-1.14p.]
Author [Alan Mishchenko]
Affiliation [UC Berkeley]
Date [Ver. 1.0. Started - June 24, 2008.]
Revision [$Id: intM114p.c,v 1.00 2005/06/20 00:00:00 alanmi Exp $]
***********************************************************************/
#include "intInt.h"
#include "m114p.h"
#ifdef ABC_USE_LIBRARIES
ABC_NAMESPACE_IMPL_START
////////////////////////////////////////////////////////////////////////
/// DECLARATIONS ///
////////////////////////////////////////////////////////////////////////
////////////////////////////////////////////////////////////////////////
/// FUNCTION DEFINITIONS ///
////////////////////////////////////////////////////////////////////////
/**Function*************************************************************
Synopsis [Returns the SAT solver for one interpolation run.]
Description [pInter is the previous interpolant. pAig is one time frame.
pFrames is the unrolled time frames.]
SideEffects []
SeeAlso []
***********************************************************************/
M114p_Solver_t Inter_ManDeriveSatSolverM114p(
Aig_Man_t * pInter, Cnf_Dat_t * pCnfInter,
Aig_Man_t * pAig, Cnf_Dat_t * pCnfAig,
Aig_Man_t * pFrames, Cnf_Dat_t * pCnfFrames,
Vec_Int_t ** pvMapRoots, Vec_Int_t ** pvMapVars )
{
M114p_Solver_t pSat;
Aig_Obj_t * pObj, * pObj2;
int i, Lits[2];
// sanity checks
assert( Aig_ManRegNum(pInter) == 0 );
assert( Aig_ManRegNum(pAig) > 0 );
assert( Aig_ManRegNum(pFrames) == 0 );
assert( Aig_ManPoNum(pInter) == 1 );
assert( Aig_ManPoNum(pFrames) == 1 );
assert( Aig_ManPiNum(pInter) == Aig_ManRegNum(pAig) );
// assert( (Aig_ManPiNum(pFrames) - Aig_ManRegNum(pAig)) % Saig_ManPiNum(pAig) == 0 );
// prepare CNFs
Cnf_DataLift( pCnfAig, pCnfFrames->nVars );
Cnf_DataLift( pCnfInter, pCnfFrames->nVars + pCnfAig->nVars );
*pvMapRoots = Vec_IntAlloc( 10000 );
*pvMapVars = Vec_IntAlloc( 0 );
Vec_IntFill( *pvMapVars, pCnfInter->nVars + pCnfAig->nVars + pCnfFrames->nVars, -1 );
for ( i = 0; i < pCnfFrames->nVars; i++ )
Vec_IntWriteEntry( *pvMapVars, i, -2 );
// start the solver
pSat = M114p_SolverNew( 1 );
M114p_SolverSetVarNum( pSat, pCnfInter->nVars + pCnfAig->nVars + pCnfFrames->nVars );
// add clauses of A
// interpolant
for ( i = 0; i < pCnfInter->nClauses; i++ )
{
Vec_IntPush( *pvMapRoots, 0 );
if ( !M114p_SolverAddClause( pSat, pCnfInter->pClauses[i], pCnfInter->pClauses[i+1] ) )
assert( 0 );
}
// connector clauses
Aig_ManForEachPi( pInter, pObj, i )
{
pObj2 = Saig_ManLo( pAig, i );
Lits[0] = toLitCond( pCnfInter->pVarNums[pObj->Id], 0 );
Lits[1] = toLitCond( pCnfAig->pVarNums[pObj2->Id], 1 );
Vec_IntPush( *pvMapRoots, 0 );
if ( !M114p_SolverAddClause( pSat, Lits, Lits+2 ) )
assert( 0 );
Lits[0] = toLitCond( pCnfInter->pVarNums[pObj->Id], 1 );
Lits[1] = toLitCond( pCnfAig->pVarNums[pObj2->Id], 0 );
Vec_IntPush( *pvMapRoots, 0 );
if ( !M114p_SolverAddClause( pSat, Lits, Lits+2 ) )
assert( 0 );
}
// one timeframe
for ( i = 0; i < pCnfAig->nClauses; i++ )
{
Vec_IntPush( *pvMapRoots, 0 );
if ( !M114p_SolverAddClause( pSat, pCnfAig->pClauses[i], pCnfAig->pClauses[i+1] ) )
assert( 0 );
}
// connector clauses
Aig_ManForEachPi( pFrames, pObj, i )
{
if ( i == Aig_ManRegNum(pAig) )
break;
// Vec_IntPush( vVarsAB, pCnfFrames->pVarNums[pObj->Id] );
Vec_IntWriteEntry( *pvMapVars, pCnfFrames->pVarNums[pObj->Id], i );
pObj2 = Saig_ManLi( pAig, i );
Lits[0] = toLitCond( pCnfFrames->pVarNums[pObj->Id], 0 );
Lits[1] = toLitCond( pCnfAig->pVarNums[pObj2->Id], 1 );
Vec_IntPush( *pvMapRoots, 0 );
if ( !M114p_SolverAddClause( pSat, Lits, Lits+2 ) )
assert( 0 );
Lits[0] = toLitCond( pCnfFrames->pVarNums[pObj->Id], 1 );
Lits[1] = toLitCond( pCnfAig->pVarNums[pObj2->Id], 0 );
Vec_IntPush( *pvMapRoots, 0 );
if ( !M114p_SolverAddClause( pSat, Lits, Lits+2 ) )
assert( 0 );
}
// add clauses of B
for ( i = 0; i < pCnfFrames->nClauses; i++ )
{
Vec_IntPush( *pvMapRoots, 1 );
if ( !M114p_SolverAddClause( pSat, pCnfFrames->pClauses[i], pCnfFrames->pClauses[i+1] ) )
{
// assert( 0 );
break;
}
}
// return clauses to the original state
Cnf_DataLift( pCnfAig, -pCnfFrames->nVars );
Cnf_DataLift( pCnfInter, -pCnfFrames->nVars -pCnfAig->nVars );
return pSat;
}
/**Function*************************************************************
Synopsis [Performs one resolution step.]
Description []
SideEffects []
SeeAlso []
***********************************************************************/
int Inter_ManResolveM114p( Vec_Int_t * vResolvent, int * pLits, int nLits, int iVar )
{
int i, k, iLit = -1, fFound = 0;
// find the variable in the clause
for ( i = 0; i < vResolvent->nSize; i++ )
if ( lit_var(vResolvent->pArray[i]) == iVar )
{
iLit = vResolvent->pArray[i];
vResolvent->pArray[i] = vResolvent->pArray[--vResolvent->nSize];
break;
}
assert( iLit != -1 );
// add other variables
for ( i = 0; i < nLits; i++ )
{
if ( lit_var(pLits[i]) == iVar )
{
assert( iLit == lit_neg(pLits[i]) );
fFound = 1;
continue;
}
// check if this literal appears
for ( k = 0; k < vResolvent->nSize; k++ )
if ( vResolvent->pArray[k] == pLits[i] )
break;
if ( k < vResolvent->nSize )
continue;
// add this literal
Vec_IntPush( vResolvent, pLits[i] );
}
assert( fFound );
return 1;
}
/**Function*************************************************************
Synopsis [Computes interpolant using MiniSat-1.14p.]
Description [Assumes that the solver returned UNSAT and proof
logging was enabled. Array vMapRoots maps number of each root clause
into 0 (clause of A) or 1 (clause of B). Array vMapVars maps each SAT
solver variable into -1 (var of A), -2 (var of B), and <num> (var of C),
where <num> is the var's 0-based number in the ordering of C variables.]
SideEffects []
SeeAlso []
***********************************************************************/
Aig_Man_t * Inter_ManInterpolateM114pPudlak( M114p_Solver_t s, Vec_Int_t * vMapRoots, Vec_Int_t * vMapVars )
{
Aig_Man_t * p;
Aig_Obj_t * pInter, * pInter2, * pVar;
Vec_Ptr_t * vInters;
Vec_Int_t * vLiterals, * vClauses, * vResolvent;
int * pLitsNext, nLitsNext, nOffset, iLit;
int * pLits, * pClauses, * pVars;
int nLits, nVars, i, k, v, iVar;
assert( M114p_SolverProofIsReady(s) );
vInters = Vec_PtrAlloc( 1000 );
vLiterals = Vec_IntAlloc( 10000 );
vClauses = Vec_IntAlloc( 1000 );
vResolvent = Vec_IntAlloc( 100 );
// create elementary variables
p = Aig_ManStart( 10000 );
Vec_IntForEachEntry( vMapVars, iVar, i )
if ( iVar >= 0 )
Aig_IthVar(p, iVar);
// process root clauses
M114p_SolverForEachRoot( s, &pLits, nLits, i )
{
if ( Vec_IntEntry(vMapRoots, i) == 1 ) // clause of B
pInter = Aig_ManConst1(p);
else // clause of A
pInter = Aig_ManConst0(p);
Vec_PtrPush( vInters, pInter );
// save the root clause
Vec_IntPush( vClauses, Vec_IntSize(vLiterals) );
Vec_IntPush( vLiterals, nLits );
for ( v = 0; v < nLits; v++ )
Vec_IntPush( vLiterals, pLits[v] );
}
assert( Vec_PtrSize(vInters) == Vec_IntSize(vMapRoots) );
// process learned clauses
M114p_SolverForEachChain( s, &pClauses, &pVars, nVars, i )
{
pInter = Vec_PtrEntry( vInters, pClauses[0] );
// initialize the resolvent
nOffset = Vec_IntEntry( vClauses, pClauses[0] );
nLitsNext = Vec_IntEntry( vLiterals, nOffset );
pLitsNext = Vec_IntArray(vLiterals) + nOffset + 1;
Vec_IntClear( vResolvent );
for ( v = 0; v < nLitsNext; v++ )
Vec_IntPush( vResolvent, pLitsNext[v] );
for ( k = 0; k < nVars; k++ )
{
iVar = Vec_IntEntry( vMapVars, pVars[k] );
pInter2 = Vec_PtrEntry( vInters, pClauses[k+1] );
// resolve it with the next clause
nOffset = Vec_IntEntry( vClauses, pClauses[k+1] );
nLitsNext = Vec_IntEntry( vLiterals, nOffset );
pLitsNext = Vec_IntArray(vLiterals) + nOffset + 1;
Inter_ManResolveM114p( vResolvent, pLitsNext, nLitsNext, pVars[k] );
if ( iVar == -1 ) // var of A
pInter = Aig_Or( p, pInter, pInter2 );
else if ( iVar == -2 ) // var of B
pInter = Aig_And( p, pInter, pInter2 );
else // var of C
{
// check polarity of the pivot variable in the clause
for ( v = 0; v < nLitsNext; v++ )
if ( lit_var(pLitsNext[v]) == pVars[k] )
break;
assert( v < nLitsNext );
pVar = Aig_NotCond( Aig_IthVar(p, iVar), lit_sign(pLitsNext[v]) );
pInter = Aig_Mux( p, pVar, pInter, pInter2 );
}
}
Vec_PtrPush( vInters, pInter );
// store the resulting clause
Vec_IntPush( vClauses, Vec_IntSize(vLiterals) );
Vec_IntPush( vLiterals, Vec_IntSize(vResolvent) );
Vec_IntForEachEntry( vResolvent, iLit, v )
Vec_IntPush( vLiterals, iLit );
}
assert( Vec_PtrSize(vInters) == M114p_SolverProofClauseNum(s) );
assert( Vec_IntSize(vResolvent) == 0 ); // the empty clause
Vec_PtrFree( vInters );
Vec_IntFree( vLiterals );
Vec_IntFree( vClauses );
Vec_IntFree( vResolvent );
Aig_ObjCreatePo( p, pInter );
Aig_ManCleanup( p );
return p;
}
/**Function*************************************************************
Synopsis [Computes interpolant using MiniSat-1.14p.]
Description [Assumes that the solver returned UNSAT and proof
logging was enabled. Array vMapRoots maps number of each root clause
into 0 (clause of A) or 1 (clause of B). Array vMapVars maps each SAT
solver variable into -1 (var of A), -2 (var of B), and <num> (var of C),
where <num> is the var's 0-based number in the ordering of C variables.]
SideEffects []
SeeAlso []
***********************************************************************/
Aig_Man_t * Inter_ManpInterpolateM114( M114p_Solver_t s, Vec_Int_t * vMapRoots, Vec_Int_t * vMapVars )
{
Aig_Man_t * p;
Aig_Obj_t * pInter, * pInter2, * pVar;
Vec_Ptr_t * vInters;
int * pLits, * pClauses, * pVars;
int nLits, nVars, i, k, iVar;
int nClauses;
nClauses = M114p_SolverProofClauseNum(s);
assert( M114p_SolverProofIsReady(s) );
vInters = Vec_PtrAlloc( 1000 );
// process root clauses
p = Aig_ManStart( 10000 );
M114p_SolverForEachRoot( s, &pLits, nLits, i )
{
if ( Vec_IntEntry(vMapRoots, i) == 1 ) // clause of B
pInter = Aig_ManConst1(p);
else // clause of A
{
pInter = Aig_ManConst0(p);
for ( k = 0; k < nLits; k++ )
{
iVar = Vec_IntEntry( vMapVars, lit_var(pLits[k]) );
if ( iVar < 0 ) // var of A or B
continue;
// this is a variable of C
pVar = Aig_NotCond( Aig_IthVar(p, iVar), lit_sign(pLits[k]) );
pInter = Aig_Or( p, pInter, pVar );
}
}
Vec_PtrPush( vInters, pInter );
}
// assert( Vec_PtrSize(vInters) == Vec_IntSize(vMapRoots) );
// process learned clauses
M114p_SolverForEachChain( s, &pClauses, &pVars, nVars, i )
{
pInter = Vec_PtrEntry( vInters, pClauses[0] );
for ( k = 0; k < nVars; k++ )
{
iVar = Vec_IntEntry( vMapVars, pVars[k] );
pInter2 = Vec_PtrEntry( vInters, pClauses[k+1] );
if ( iVar == -1 ) // var of A
pInter = Aig_Or( p, pInter, pInter2 );
else // var of B or C
pInter = Aig_And( p, pInter, pInter2 );
}
Vec_PtrPush( vInters, pInter );
}
assert( Vec_PtrSize(vInters) == M114p_SolverProofClauseNum(s) );
Vec_PtrFree( vInters );
Aig_ObjCreatePo( p, pInter );
Aig_ManCleanup( p );
assert( Aig_ManCheck(p) );
return p;
}
/**Function*************************************************************
Synopsis [Performs one SAT run with interpolation.]
Description [Returns 1 if proven. 0 if failed. -1 if undecided.]
SideEffects []
SeeAlso []
***********************************************************************/
int Inter_ManPerformOneStepM114p( Inter_Man_t * p, int fUsePudlak, int fUseOther )
{
M114p_Solver_t pSat;
Vec_Int_t * vMapRoots, * vMapVars;
int clk, status, RetValue;
assert( p->pInterNew == NULL );
// derive the SAT solver
pSat = Inter_ManDeriveSatSolverM114p( p->pInter, p->pCnfInter,
p->pAigTrans, p->pCnfAig, p->pFrames, p->pCnfFrames,
&vMapRoots, &vMapVars );
// solve the problem
clk = clock();
status = M114p_SolverSolve( pSat, NULL, NULL, 0 );
p->nConfCur = M114p_SolverGetConflictNum( pSat );
p->timeSat += clock() - clk;
if ( status == 0 )
{
RetValue = 1;
// Inter_ManpInterpolateM114Report( pSat, vMapRoots, vMapVars );
clk = clock();
if ( fUsePudlak )
p->pInterNew = Inter_ManInterpolateM114pPudlak( pSat, vMapRoots, vMapVars );
else
p->pInterNew = Inter_ManpInterpolateM114( pSat, vMapRoots, vMapVars );
p->timeInt += clock() - clk;
}
else if ( status == 1 )
{
RetValue = 0;
}
else
{
RetValue = -1;
}
M114p_SolverDelete( pSat );
Vec_IntFree( vMapRoots );
Vec_IntFree( vMapVars );
return RetValue;
}
////////////////////////////////////////////////////////////////////////
/// END OF FILE ///
////////////////////////////////////////////////////////////////////////
ABC_NAMESPACE_IMPL_END
#endif
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