/**CFile**************************************************************** FileName [simSupp.c] SystemName [ABC: Logic synthesis and verification system.] PackageName [Network and node package.] Synopsis [Simulation to determine functional support.] Author [Alan Mishchenko] Affiliation [UC Berkeley] Date [Ver. 1.0. Started - June 20, 2005.] Revision [$Id: simSupp.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_ComputeSuppRound( Sim_Man_t * p, int fUseTargets ); static int Sim_ComputeSuppRoundNode( Sim_Man_t * p, int iNumCi, int fUseTargets ); static void Sim_ComputeSuppSetTargets( Sim_Man_t * p ); static void Sim_UtilAssignRandom( Sim_Man_t * p ); static void Sim_UtilAssignFromFifo( Sim_Man_t * p ); static void Sim_SolveTargetsUsingSat( Sim_Man_t * p, int nCounters ); static int Sim_SolveSuppModelVerify( Abc_Ntk_t * pNtk, int * pModel, int Input, int Output ); //////////////////////////////////////////////////////////////////////// /// FUNCTION DEFINITIONS /// //////////////////////////////////////////////////////////////////////// /**Function************************************************************* Synopsis [Computes structural supports.] Description [Supports are returned as an array of bit strings, one for each CO.] SideEffects [] SeeAlso [] ***********************************************************************/ Vec_Ptr_t * Sim_ComputeStrSupp( Abc_Ntk_t * pNtk ) { Vec_Ptr_t * vSuppStr; Abc_Obj_t * pNode; unsigned * pSimmNode, * pSimmNode1, * pSimmNode2; int nSuppWords, i, k; // allocate room for structural supports nSuppWords = SIM_NUM_WORDS( Abc_NtkCiNum(pNtk) ); vSuppStr = Sim_UtilInfoAlloc( Abc_NtkObjNumMax(pNtk), nSuppWords, 1 ); // assign the structural support to the PIs Abc_NtkForEachCi( pNtk, pNode, i ) Sim_SuppStrSetVar( vSuppStr, pNode, i ); // derive the structural supports of the internal nodes Abc_NtkForEachNode( pNtk, pNode, i ) { // if ( Abc_NodeIsConst(pNode) ) // continue; pSimmNode = (unsigned *)vSuppStr->pArray[ pNode->Id ]; pSimmNode1 = (unsigned *)vSuppStr->pArray[ Abc_ObjFaninId0(pNode) ]; pSimmNode2 = (unsigned *)vSuppStr->pArray[ Abc_ObjFaninId1(pNode) ]; for ( k = 0; k < nSuppWords; k++ ) pSimmNode[k] = pSimmNode1[k] | pSimmNode2[k]; } // set the structural supports of the PO nodes Abc_NtkForEachCo( pNtk, pNode, i ) { pSimmNode = (unsigned *)vSuppStr->pArray[ pNode->Id ]; pSimmNode1 = (unsigned *)vSuppStr->pArray[ Abc_ObjFaninId0(pNode) ]; for ( k = 0; k < nSuppWords; k++ ) pSimmNode[k] = pSimmNode1[k]; } return vSuppStr; } /**Function************************************************************* Synopsis [Compute functional supports.] Description [Supports are returned as an array of bit strings, one for each CO.] SideEffects [] SeeAlso [] ***********************************************************************/ Vec_Ptr_t * Sim_ComputeFunSupp( Abc_Ntk_t * pNtk, int fVerbose ) { Sim_Man_t * p; Vec_Ptr_t * vResult; int nSolved, i; abctime clk = Abc_Clock(); srand( 0xABC ); // start the simulation manager p = Sim_ManStart( pNtk, 0 ); // compute functional support using one round of random simulation Sim_UtilAssignRandom( p ); Sim_ComputeSuppRound( p, 0 ); // set the support targets Sim_ComputeSuppSetTargets( p ); if ( fVerbose ) printf( "Number of support targets after simulation = %5d.\n", Vec_VecSizeSize(p->vSuppTargs) ); if ( Vec_VecSizeSize(p->vSuppTargs) == 0 ) goto exit; for ( i = 0; i < 1; i++ ) { // compute patterns using one round of random simulation Sim_UtilAssignRandom( p ); nSolved = Sim_ComputeSuppRound( p, 1 ); if ( Vec_VecSizeSize(p->vSuppTargs) == 0 ) goto exit; if ( fVerbose ) printf( "Targets = %5d. Solved = %5d. Fifo = %5d.\n", Vec_VecSizeSize(p->vSuppTargs), nSolved, Vec_PtrSize(p->vFifo) ); } // try to solve the support targets while ( Vec_VecSizeSize(p->vSuppTargs) > 0 ) { // solve targets until the first disproved one (which gives counter-example) Sim_SolveTargetsUsingSat( p, p->nSimWords/p->nSuppWords ); // compute additional functional support Sim_UtilAssignFromFifo( p ); nSolved = Sim_ComputeSuppRound( p, 1 ); if ( fVerbose ) printf( "Targets = %5d. Solved = %5d. Fifo = %5d. SAT runs = %3d.\n", Vec_VecSizeSize(p->vSuppTargs), nSolved, Vec_PtrSize(p->vFifo), p->nSatRuns ); } exit: p->timeTotal = Abc_Clock() - clk; vResult = p->vSuppFun; // p->vSuppFun = NULL; Sim_ManStop( p ); return vResult; } /**Function************************************************************* Synopsis [Computes functional support using one round of simulation.] Description [] SideEffects [] SeeAlso [] ***********************************************************************/ int Sim_ComputeSuppRound( Sim_Man_t * p, int fUseTargets ) { Vec_Int_t * vTargets; int i, Counter = 0; abctime clk; // perform one round of random simulation clk = Abc_Clock(); Sim_UtilSimulate( p, 0 ); p->timeSim += Abc_Clock() - clk; // iterate through the CIs and detect COs that depend on them for ( i = p->iInput; i < p->nInputs; i++ ) { vTargets = (Vec_Int_t *)p->vSuppTargs->pArray[i]; if ( fUseTargets && vTargets->nSize == 0 ) continue; Counter += Sim_ComputeSuppRoundNode( p, i, fUseTargets ); } return Counter; } /**Function************************************************************* Synopsis [Computes functional support for one node.] Description [] SideEffects [] SeeAlso [] ***********************************************************************/ int Sim_ComputeSuppRoundNode( Sim_Man_t * p, int iNumCi, int fUseTargets ) { int fVerbose = 0; Sim_Pat_t * pPat; Vec_Int_t * vTargets; Vec_Vec_t * vNodesByLevel; Abc_Obj_t * pNodeCi, * pNode; int i, k, v, Output, LuckyPat, fType0, fType1; int Counter = 0; int fFirst = 1; abctime clk; // collect nodes by level in the TFO of the CI // this proceduredoes not collect the CIs and COs // but it increments TravId of the collected nodes and CIs/COs clk = Abc_Clock(); pNodeCi = Abc_NtkCi( p->pNtk, iNumCi ); vNodesByLevel = Abc_DfsLevelized( pNodeCi, 0 ); p->timeTrav += Abc_Clock() - clk; // complement the simulation info of the selected CI Sim_UtilInfoFlip( p, pNodeCi ); // simulate the levelized structure of nodes Vec_VecForEachEntry( Abc_Obj_t *, vNodesByLevel, pNode, i, k ) { fType0 = Abc_NodeIsTravIdCurrent( Abc_ObjFanin0(pNode) ); fType1 = Abc_NodeIsTravIdCurrent( Abc_ObjFanin1(pNode) ); clk = Abc_Clock(); Sim_UtilSimulateNode( p, pNode, 1, fType0, fType1 ); p->timeSim += Abc_Clock() - clk; } // set the simulation info of the affected COs if ( fUseTargets ) { vTargets = (Vec_Int_t *)p->vSuppTargs->pArray[iNumCi]; for ( i = vTargets->nSize - 1; i >= 0; i-- ) { // get the target output Output = vTargets->pArray[i]; // get the target node pNode = Abc_ObjFanin0( Abc_NtkCo(p->pNtk, Output) ); // the output should be in the cone assert( Abc_NodeIsTravIdCurrent(pNode) ); // skip if the simulation info is equal if ( Sim_UtilInfoCompare( p, pNode ) ) continue; // otherwise, we solved a new target Vec_IntRemove( vTargets, Output ); if ( fVerbose ) printf( "(%d,%d) ", iNumCi, Output ); Counter++; // make sure this variable is not yet detected assert( !Sim_SuppFunHasVar(p->vSuppFun, Output, iNumCi) ); // set this variable Sim_SuppFunSetVar( p->vSuppFun, Output, iNumCi ); // detect the differences in the simulation info Sim_UtilInfoDetectDiffs( (unsigned *)p->vSim0->pArray[pNode->Id], (unsigned *)p->vSim1->pArray[pNode->Id], p->nSimWords, p->vDiffs ); // create new patterns if ( !fFirst && p->vFifo->nSize > 1000 ) continue; Vec_IntForEachEntry( p->vDiffs, LuckyPat, k ) { // set the new pattern pPat = Sim_ManPatAlloc( p ); pPat->Input = iNumCi; pPat->Output = Output; Abc_NtkForEachCi( p->pNtk, pNodeCi, v ) if ( Sim_SimInfoHasVar( p->vSim0, pNodeCi, LuckyPat ) ) Sim_SetBit( pPat->pData, v ); Vec_PtrPush( p->vFifo, pPat ); fFirst = 0; break; } } if ( fVerbose && Counter ) printf( "\n" ); } else { Abc_NtkForEachCo( p->pNtk, pNode, Output ) { if ( !Abc_NodeIsTravIdCurrent( pNode ) ) continue; if ( !Sim_UtilInfoCompare( p, Abc_ObjFanin0(pNode) ) ) { if ( !Sim_SuppFunHasVar(p->vSuppFun, Output, iNumCi) ) { Counter++; Sim_SuppFunSetVar( p->vSuppFun, Output, iNumCi ); } } } } Vec_VecFree( vNodesByLevel ); return Counter; } /**Function************************************************************* Synopsis [Sets the simulation targets.] Description [] SideEffects [] SeeAlso [] ***********************************************************************/ void Sim_ComputeSuppSetTargets( Sim_Man_t * p ) { Abc_Obj_t * pNode; unsigned * pSuppStr, * pSuppFun; int i, k, Num; Abc_NtkForEachCo( p->pNtk, pNode, i ) { pSuppStr = (unsigned *)p->vSuppStr->pArray[pNode->Id]; pSuppFun = (unsigned *)p->vSuppFun->pArray[i]; // find vars in the structural support that are not in the functional support Sim_UtilInfoDetectNews( pSuppFun, pSuppStr, p->nSuppWords, p->vDiffs ); Vec_IntForEachEntry( p->vDiffs, Num, k ) Vec_VecPush( p->vSuppTargs, Num, (void *)(ABC_PTRUINT_T)i ); } } /**Function************************************************************* Synopsis [Assigns random simulation info to the PIs.] Description [] SideEffects [] SeeAlso [] ***********************************************************************/ void Sim_UtilAssignRandom( Sim_Man_t * p ) { Abc_Obj_t * pNode; unsigned * pSimInfo; int i, k; // assign the random/systematic simulation info to the PIs Abc_NtkForEachCi( p->pNtk, pNode, i ) { pSimInfo = (unsigned *)p->vSim0->pArray[pNode->Id]; for ( k = 0; k < p->nSimWords; k++ ) pSimInfo[k] = SIM_RANDOM_UNSIGNED; } } /**Function************************************************************* Synopsis [Sets the new patterns from fifo.] Description [] SideEffects [] SeeAlso [] ***********************************************************************/ void Sim_UtilAssignFromFifo( Sim_Man_t * p ) { int fUseOneWord = 0; Abc_Obj_t * pNode; Sim_Pat_t * pPat; unsigned * pSimInfo; int nWordsNew, iWord, iWordLim, i, w; int iBeg, iEnd; int Counter = 0; // go through the patterns and fill in the dist-1 minterms for each for ( iWord = 0; p->vFifo->nSize > 0; iWord = iWordLim ) { ++Counter; // get the pattern pPat = (Sim_Pat_t *)Vec_PtrPop( p->vFifo ); if ( fUseOneWord ) { // get the first word of the next series iWordLim = iWord + 1; // set the pattern for all PIs from iBit to iWord + p->nInputs iBeg = p->iInput; iEnd = Abc_MinInt( iBeg + 32, p->nInputs ); // for ( i = iBeg; i < iEnd; i++ ) Abc_NtkForEachCi( p->pNtk, pNode, i ) { pNode = Abc_NtkCi(p->pNtk,i); pSimInfo = (unsigned *)p->vSim0->pArray[pNode->Id]; if ( Sim_HasBit(pPat->pData, i) ) pSimInfo[iWord] = SIM_MASK_FULL; else pSimInfo[iWord] = 0; // flip one bit if ( i >= iBeg && i < iEnd ) Sim_XorBit( pSimInfo + iWord, i-iBeg ); } } else { // get the number of words for the remaining inputs nWordsNew = p->nSuppWords; // nWordsNew = SIM_NUM_WORDS( p->nInputs - p->iInput ); // get the first word of the next series iWordLim = (iWord + nWordsNew < p->nSimWords)? iWord + nWordsNew : p->nSimWords; // set the pattern for all CIs from iWord to iWord + nWordsNew Abc_NtkForEachCi( p->pNtk, pNode, i ) { pSimInfo = (unsigned *)p->vSim0->pArray[pNode->Id]; if ( Sim_HasBit(pPat->pData, i) ) { for ( w = iWord; w < iWordLim; w++ ) pSimInfo[w] = SIM_MASK_FULL; } else { for ( w = iWord; w < iWordLim; w++ ) pSimInfo[w] = 0; } Sim_XorBit( pSimInfo + iWord, i ); // flip one bit // if ( i >= p->iInput ) // Sim_XorBit( pSimInfo + iWord, i-p->iInput ); } } Sim_ManPatFree( p, pPat ); // stop if we ran out of room for patterns if ( iWordLim == p->nSimWords ) break; // if ( Counter == 1 ) // break; } } /**Function************************************************************* Synopsis [Get the given number of counter-examples using SAT.] Description [] SideEffects [] SeeAlso [] ***********************************************************************/ void Sim_SolveTargetsUsingSat( Sim_Man_t * p, int Limit ) { Fraig_Params_t Params; Fraig_Man_t * pMan; Abc_Obj_t * pNodeCi; Abc_Ntk_t * pMiter; Sim_Pat_t * pPat; void * pEntry; int * pModel; int RetValue, Output, Input, k, v; int Counter = 0; abctime clk; p->nSatRuns = 0; // put targets into one array Vec_VecForEachEntryReverse( void *, p->vSuppTargs, pEntry, Input, k ) { p->nSatRuns++; Output = (int)(ABC_PTRUINT_T)pEntry; // set up the miter for the two cofactors of this output w.r.t. this input pMiter = Abc_NtkMiterForCofactors( p->pNtk, Output, Input, -1 ); // transform the miter into a fraig Fraig_ParamsSetDefault( &Params ); Params.nSeconds = ABC_INFINITY; Params.fInternal = 1; 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 ); if ( RetValue == 1 ) // unsat { p->nSatRunsUnsat++; pModel = NULL; Vec_PtrRemove( (Vec_Ptr_t *)p->vSuppTargs->pArray[Input], pEntry ); } else // sat { p->nSatRunsSat++; pModel = Fraig_ManReadModel( pMan ); assert( pModel != NULL ); assert( Sim_SolveSuppModelVerify( p->pNtk, pModel, Input, Output ) ); //printf( "Solved by SAT (%d,%d).\n", Input, Output ); // set the new pattern pPat = Sim_ManPatAlloc( p ); pPat->Input = Input; pPat->Output = Output; Abc_NtkForEachCi( p->pNtk, pNodeCi, v ) if ( pModel[v] ) Sim_SetBit( pPat->pData, v ); Vec_PtrPush( p->vFifo, pPat ); /* // set the new pattern pPat = Sim_ManPatAlloc( p ); pPat->Input = Input; pPat->Output = Output; Abc_NtkForEachCi( p->pNtk, pNodeCi, v ) if ( pModel[v] ) Sim_SetBit( pPat->pData, v ); Sim_XorBit( pPat->pData, Input ); // add this bit in the opposite polarity Vec_PtrPush( p->vFifo, pPat ); */ Counter++; } // delete the fraig manager Fraig_ManFree( pMan ); // delete the miter Abc_NtkDelete( pMiter ); // makr the input, which we are processing p->iInput = Input; // stop when we found enough patterns // if ( Counter == Limit ) if ( Counter == 1 ) return; } } /**Function************************************************************* Synopsis [Saves the counter example.] Description [] SideEffects [] SeeAlso [] ***********************************************************************/ int Sim_NtkSimTwoPats_rec( Abc_Obj_t * pNode ) { int Value0, Value1; if ( Abc_NodeIsTravIdCurrent( pNode ) ) return (int)(ABC_PTRUINT_T)pNode->pCopy; Abc_NodeSetTravIdCurrent( pNode ); Value0 = Sim_NtkSimTwoPats_rec( Abc_ObjFanin0(pNode) ); Value1 = Sim_NtkSimTwoPats_rec( Abc_ObjFanin1(pNode) ); if ( Abc_ObjFaninC0(pNode) ) Value0 = ~Value0; if ( Abc_ObjFaninC1(pNode) ) Value1 = ~Value1; pNode->pCopy = (Abc_Obj_t *)(ABC_PTRUINT_T)(Value0 & Value1); return Value0 & Value1; } /**Function************************************************************* Synopsis [Verifies that pModel proves the presence of Input in the support of Output.] Description [] SideEffects [] SeeAlso [] ***********************************************************************/ int Sim_SolveSuppModelVerify( Abc_Ntk_t * pNtk, int * pModel, int Input, int Output ) { Abc_Obj_t * pNode; int RetValue, i; // set the PI values Abc_NtkIncrementTravId( pNtk ); Abc_NtkForEachCi( pNtk, pNode, i ) { Abc_NodeSetTravIdCurrent( pNode ); if ( pNode == Abc_NtkCi(pNtk,Input) ) pNode->pCopy = (Abc_Obj_t *)1; else if ( pModel[i] == 1 ) pNode->pCopy = (Abc_Obj_t *)3; else pNode->pCopy = NULL; } // perform the traversal RetValue = 3 & Sim_NtkSimTwoPats_rec( Abc_ObjFanin0( Abc_NtkCo(pNtk,Output) ) ); // assert( RetValue == 1 || RetValue == 2 ); return RetValue == 1 || RetValue == 2; } //////////////////////////////////////////////////////////////////////// /// END OF FILE /// //////////////////////////////////////////////////////////////////////// ABC_NAMESPACE_IMPL_END