/**CFile**************************************************************** FileName [simSymSat.c] SystemName [ABC: Logic synthesis and verification system.] PackageName [Network and node package.] Synopsis [Satisfiability to determine two variable symmetries.] Author [Alan Mishchenko] Affiliation [UC Berkeley] Date [Ver. 1.0. Started - June 20, 2005.] Revision [$Id: simSymSat.c,v 1.00 2005/06/20 00:00:00 alanmi Exp $] ***********************************************************************/ #include "base/abc/abc.h" #include "proof/fraig/fraig.h" #include "sim.h" ABC_NAMESPACE_IMPL_START //////////////////////////////////////////////////////////////////////// /// DECLARATIONS /// //////////////////////////////////////////////////////////////////////// static int Sim_SymmsSatProveOne( Sym_Man_t * p, int Out, int Var1, int Var2, unsigned * pPattern ); //////////////////////////////////////////////////////////////////////// /// FUNCTION DEFINITIONS /// //////////////////////////////////////////////////////////////////////// /**Function************************************************************* Synopsis [Tries to prove the remaining pairs using SAT.] Description [Continues to prove as long as it encounters symmetric pairs. Returns 1 if a non-symmetric pair is found (which gives a counter-example). Returns 0 if it finishes considering all pairs for all outputs.] SideEffects [] SeeAlso [] ***********************************************************************/ int Sim_SymmsGetPatternUsingSat( Sym_Man_t * p, unsigned * pPattern ) { Vec_Int_t * vSupport; Extra_BitMat_t * pMatSym, * pMatNonSym; int Index1, Index2, Index3, IndexU, IndexV; int v, u, i, k, b, out; // iterate through outputs for ( out = p->iOutput; out < p->nOutputs; out++ ) { pMatSym = (Extra_BitMat_t *)Vec_PtrEntry( p->vMatrSymms, out ); pMatNonSym = (Extra_BitMat_t *)Vec_PtrEntry( p->vMatrNonSymms, out ); // go through the remaining variable pairs vSupport = Vec_VecEntryInt( p->vSupports, out ); Vec_IntForEachEntry( vSupport, v, Index1 ) Vec_IntForEachEntryStart( vSupport, u, Index2, Index1+1 ) { if ( Extra_BitMatrixLookup1( pMatSym, v, u ) || Extra_BitMatrixLookup1( pMatNonSym, v, u ) ) continue; p->nSatRuns++; // collect the support variables that are symmetric with u and v Vec_IntClear( p->vVarsU ); Vec_IntClear( p->vVarsV ); Vec_IntForEachEntry( vSupport, b, Index3 ) { if ( Extra_BitMatrixLookup1( pMatSym, u, b ) ) Vec_IntPush( p->vVarsU, b ); if ( Extra_BitMatrixLookup1( pMatSym, v, b ) ) Vec_IntPush( p->vVarsV, b ); } if ( Sim_SymmsSatProveOne( p, out, v, u, pPattern ) ) { // update the symmetric variable info p->nSatRunsUnsat++; Vec_IntForEachEntry( p->vVarsU, i, IndexU ) Vec_IntForEachEntry( p->vVarsV, k, IndexV ) { Extra_BitMatrixInsert1( pMatSym, i, k ); // Theorem 1 Extra_BitMatrixInsert2( pMatSym, i, k ); // Theorem 1 Extra_BitMatrixOrTwo( pMatNonSym, i, k ); // Theorem 2 } } else { // update the assymmetric variable info p->nSatRunsSat++; Vec_IntForEachEntry( p->vVarsU, i, IndexU ) Vec_IntForEachEntry( p->vVarsV, k, IndexV ) { Extra_BitMatrixInsert1( pMatNonSym, i, k ); // Theorem 3 Extra_BitMatrixInsert2( pMatNonSym, i, k ); // Theorem 3 } // remember the out p->iOutput = out; p->iVar1Old = p->iVar1; p->iVar2Old = p->iVar2; p->iVar1 = v; p->iVar2 = u; return 1; } } // make sure that the symmetry matrix contains only cliques assert( Extra_BitMatrixIsClique( pMatSym ) ); } // mark that we finished all outputs p->iOutput = p->nOutputs; return 0; } /**Function************************************************************* Synopsis [Returns 1 if the variables are symmetric; 0 otherwise.] Description [] SideEffects [] SeeAlso [] ***********************************************************************/ int Sim_SymmsSatProveOne( Sym_Man_t * p, int Out, int Var1, int Var2, unsigned * pPattern ) { Fraig_Params_t Params; Fraig_Man_t * pMan; Abc_Ntk_t * pMiter; int RetValue, i; abctime clk; int * pModel; // get the miter for this problem pMiter = Abc_NtkMiterForCofactors( p->pNtk, Out, Var1, Var2 ); // transform the miter into a fraig Fraig_ParamsSetDefault( &Params ); Params.fInternal = 1; Params.nPatsRand = 512; Params.nPatsDyna = 512; Params.nSeconds = ABC_INFINITY; clk = Abc_Clock(); pMan = (Fraig_Man_t *)Abc_NtkToFraig( pMiter, &Params, 0, 0 ); p->timeFraig += Abc_Clock() - clk; clk = Abc_Clock(); Fraig_ManProveMiter( pMan ); p->timeSat += Abc_Clock() - clk; // analyze the result RetValue = Fraig_ManCheckMiter( pMan ); // assert( RetValue >= 0 ); // save the pattern if ( RetValue == 0 ) { // get the pattern pModel = Fraig_ManReadModel( pMan ); assert( pModel != NULL ); //printf( "Disproved by SAT: out = %d pair = (%d, %d)\n", Out, Var1, Var2 ); // transfer the model into the pattern for ( i = 0; i < p->nSimWords; i++ ) pPattern[i] = 0; for ( i = 0; i < p->nInputs; i++ ) if ( pModel[i] ) Sim_SetBit( pPattern, i ); // make sure these variables have the same value (1) Sim_SetBit( pPattern, Var1 ); Sim_SetBit( pPattern, Var2 ); } else if ( RetValue == -1 ) { // this should never happen; if it happens, such is life // we are conservative and assume that there is no symmetry //printf( "STRANGE THING: out = %d %s pair = (%d %s, %d %s)\n", // Out, Abc_ObjName(Abc_NtkCo(p->pNtk,Out)), // Var1, Abc_ObjName(Abc_NtkCi(p->pNtk,Var1)), // Var2, Abc_ObjName(Abc_NtkCi(p->pNtk,Var2)) ); memset( pPattern, 0, sizeof(unsigned) * p->nSimWords ); RetValue = 0; } // delete the fraig manager Fraig_ManFree( pMan ); // delete the miter Abc_NtkDelete( pMiter ); return RetValue; } //////////////////////////////////////////////////////////////////////// /// END OF FILE /// //////////////////////////////////////////////////////////////////////// ABC_NAMESPACE_IMPL_END