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/**CFile****************************************************************
FileName [sswCore.c]
SystemName [ABC: Logic synthesis and verification system.]
PackageName [Inductive prover with constraints.]
Synopsis [The core procedures.]
Author [Alan Mishchenko]
Affiliation [UC Berkeley]
Date [Ver. 1.0. Started - September 1, 2008.]
Revision [$Id: sswCore.c,v 1.00 2008/09/01 00:00:00 alanmi Exp $]
***********************************************************************/
#include "sswInt.h"
////////////////////////////////////////////////////////////////////////
/// DECLARATIONS ///
////////////////////////////////////////////////////////////////////////
////////////////////////////////////////////////////////////////////////
/// FUNCTION DEFINITIONS ///
////////////////////////////////////////////////////////////////////////
/**Function*************************************************************
Synopsis [This procedure sets default parameters.]
Description []
SideEffects []
SeeAlso []
***********************************************************************/
void Ssw_ManSetDefaultParams( Ssw_Pars_t * p )
{
memset( p, 0, sizeof(Ssw_Pars_t) );
p->nPartSize = 0; // size of the partition
p->nOverSize = 0; // size of the overlap between partitions
p->nFramesK = 1; // the induction depth
p->nFramesAddSim = 2; // additional frames to simulate
p->nConstrs = 0; // treat the last nConstrs POs as seq constraints
p->nBTLimit = 1000; // conflict limit at a node
p->nMinDomSize = 100; // min clock domain considered for optimization
p->fPolarFlip = 0; // uses polarity adjustment
p->fSkipCheck = 0; // do not run equivalence check for unaffected cones
p->fLatchCorr = 0; // performs register correspondence
p->fVerbose = 0; // verbose stats
// latch correspondence
p->fLatchCorrOpt = 0; // performs optimized register correspondence
p->nSatVarMax = 1000; // the max number of SAT variables
p->nRecycleCalls = 50; // calls to perform before recycling SAT solver
// return values
p->nIters = 0; // the number of iterations performed
}
/**Function*************************************************************
Synopsis [This procedure sets default parameters.]
Description []
SideEffects []
SeeAlso []
***********************************************************************/
void Ssw_ManSetDefaultParamsLcorr( Ssw_Pars_t * p )
{
Ssw_ManSetDefaultParams( p );
p->fLatchCorrOpt = 1;
p->nBTLimit = 10000;
}
/**Function*************************************************************
Synopsis [Performs computation of signal correspondence with constraints.]
Description []
SideEffects []
SeeAlso []
***********************************************************************/
Aig_Man_t * Ssw_SignalCorrespondenceRefine( Ssw_Man_t * p )
{
int nSatProof, nSatCallsSat, nRecycles, nSatFailsReal;
Aig_Man_t * pAigNew;
int RetValue, nIter;
int clk, clkTotal = clock();
// get the starting stats
p->nLitsBeg = Ssw_ClassesLitNum( p->ppClasses );
p->nNodesBeg = Aig_ManNodeNum(p->pAig);
p->nRegsBeg = Aig_ManRegNum(p->pAig);
// refine classes using BMC
if ( p->pPars->fVerbose )
{
printf( "Before BMC: " );
Ssw_ClassesPrint( p->ppClasses, 0 );
}
if ( !p->pPars->fLatchCorr )
{
Ssw_ManSweepBmc( p );
Ssw_ManCleanup( p );
}
if ( p->pPars->fVerbose )
{
printf( "After BMC: " );
Ssw_ClassesPrint( p->ppClasses, 0 );
}
// refine classes using induction
nSatProof = nSatCallsSat = nRecycles = nSatFailsReal = 0;
for ( nIter = 0; ; nIter++ )
{
clk = clock();
if ( p->pPars->fLatchCorrOpt )
{
RetValue = Ssw_ManSweepLatch( p );
if ( p->pPars->fVerbose )
{
printf( "%3d : Const = %6d. Cl = %6d. Pr = %5d. Cex = %5d. Rcl = %3d. F = %3d. ",
nIter, Ssw_ClassesCand1Num(p->ppClasses), Ssw_ClassesClassNum(p->ppClasses),
p->nSatProof-nSatProof, p->nSatCallsSat-nSatCallsSat,
p->nRecycles-nRecycles, p->nSatFailsReal-nSatFailsReal );
PRT( "T", clock() - clk );
nSatProof = p->nSatProof;
nSatCallsSat = p->nSatCallsSat;
nRecycles = p->nRecycles;
nSatFailsReal = p->nSatFailsReal;
}
}
else
{
RetValue = Ssw_ManSweep( p );
if ( p->pPars->fVerbose )
{
printf( "%3d : Const = %6d. Cl = %6d. LR = %6d. NR = %6d. F = %5d. ",
nIter, Ssw_ClassesCand1Num(p->ppClasses), Ssw_ClassesClassNum(p->ppClasses),
p->nConstrReduced, Aig_ManNodeNum(p->pFrames), p->nSatFailsReal );
if ( p->pPars->fSkipCheck )
printf( "Use = %5d. Skip = %5d. ",
p->nRefUse, p->nRefSkip );
PRT( "T", clock() - clk );
}
}
Ssw_ManCleanup( p );
if ( !RetValue )
break;
}
p->pPars->nIters = nIter + 1;
p->timeTotal = clock() - clkTotal;
pAigNew = Aig_ManDupRepr( p->pAig, 0 );
Aig_ManSeqCleanup( pAigNew );
// get the final stats
p->nLitsEnd = Ssw_ClassesLitNum( p->ppClasses );
p->nNodesEnd = Aig_ManNodeNum(pAigNew);
p->nRegsEnd = Aig_ManRegNum(pAigNew);
return pAigNew;
}
/**Function*************************************************************
Synopsis [Performs computation of signal correspondence with constraints.]
Description []
SideEffects []
SeeAlso []
***********************************************************************/
Aig_Man_t * Ssw_SignalCorrespondence( Aig_Man_t * pAig, Ssw_Pars_t * pPars )
{
Ssw_Pars_t Pars;
Aig_Man_t * pAigNew;
Ssw_Man_t * p;
assert( Aig_ManRegNum(pAig) > 0 );
// reset random numbers
Aig_ManRandom( 1 );
// if parameters are not given, create them
if ( pPars == NULL )
Ssw_ManSetDefaultParams( pPars = &Pars );
// consider the case of empty AIG
if ( Aig_ManNodeNum(pAig) == 0 )
{
pPars->nIters = 0;
// Ntl_ManFinalize() needs the following to satisfy an assertion
Aig_ManReprStart( pAig,Aig_ManObjNumMax(pAig) );
return Aig_ManDupOrdered(pAig);
}
// check and update parameters
if ( pPars->fLatchCorrOpt )
{
pPars->fLatchCorr = 1;
pPars->nFramesAddSim = 0;
}
else
{
assert( pPars->nFramesK > 0 );
if ( pPars->nFramesK > 1 )
pPars->fSkipCheck = 0;
// perform partitioning
if ( (pPars->nPartSize > 0 && pPars->nPartSize < Aig_ManRegNum(pAig))
|| (pAig->vClockDoms && Vec_VecSize(pAig->vClockDoms) > 0) )
return Ssw_SignalCorrespondencePart( pAig, pPars );
}
// start the induction manager
p = Ssw_ManCreate( pAig, pPars );
// compute candidate equivalence classes
// p->pPars->nConstrs = 1;
if ( p->pPars->nConstrs == 0 )
{
// perform one round of seq simulation and generate candidate equivalence classes
p->ppClasses = Ssw_ClassesPrepare( pAig, pPars->fLatchCorr, pPars->nMaxLevs, pPars->fVerbose );
p->pSml = Ssw_SmlStart( pAig, 0, p->nFrames + p->pPars->nFramesAddSim, 1 );
Ssw_ClassesSetData( p->ppClasses, p->pSml, Ssw_SmlObjHashWord, Ssw_SmlObjIsConstWord, Ssw_SmlObjsAreEqualWord );
}
else
{
// create trivial equivalence classes with all nodes being candidates for constant 1
p->ppClasses = Ssw_ClassesPrepareSimple( pAig, pPars->fLatchCorr, pPars->nMaxLevs );
Ssw_ClassesSetData( p->ppClasses, NULL, NULL, Ssw_SmlObjIsConstBit, Ssw_SmlObjsAreEqualBit );
}
// perform refinement of classes
pAigNew = Ssw_SignalCorrespondenceRefine( p );
// cleanup
Ssw_ManStop( p );
return pAigNew;
}
/**Function*************************************************************
Synopsis [Performs computation of latch correspondence.]
Description []
SideEffects []
SeeAlso []
***********************************************************************/
Aig_Man_t * Ssw_LatchCorrespondence( Aig_Man_t * pAig, Ssw_Pars_t * pPars )
{
Ssw_Pars_t Pars;
if ( pPars == NULL )
Ssw_ManSetDefaultParamsLcorr( pPars = &Pars );
return Ssw_SignalCorrespondence( pAig, pPars );
}
////////////////////////////////////////////////////////////////////////
/// END OF FILE ///
////////////////////////////////////////////////////////////////////////
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