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|
/**CFile****************************************************************
FileName [lpkAbcDsd.c]
SystemName [ABC: Logic synthesis and verification system.]
PackageName [Fast Boolean matching for LUT structures.]
Synopsis [LUT-decomposition based on recursive DSD.]
Author [Alan Mishchenko]
Affiliation [UC Berkeley]
Date [Ver. 1.0. Started - April 28, 2007.]
Revision [$Id: lpkAbcDsd.c,v 1.00 2007/04/28 00:00:00 alanmi Exp $]
***********************************************************************/
#include "lpkInt.h"
ABC_NAMESPACE_IMPL_START
////////////////////////////////////////////////////////////////////////
/// DECLARATIONS ///
////////////////////////////////////////////////////////////////////////
////////////////////////////////////////////////////////////////////////
/// FUNCTION DEFINITIONS ///
////////////////////////////////////////////////////////////////////////
/**Function*************************************************************
Synopsis [Cofactors TTs w.r.t. all vars and finds the best var.]
Description [The best variable is the variable with the minimum
sum total of the support sizes of all truth tables. This procedure
computes and returns cofactors w.r.t. the best variable.]
SideEffects []
SeeAlso []
***********************************************************************/
int Lpk_FunComputeMinSuppSizeVar( Lpk_Fun_t * p, unsigned ** ppTruths, int nTruths, unsigned ** ppCofs, unsigned uNonDecSupp )
{
int i, Var, VarBest, nSuppSize0, nSuppSize1;
int nSuppTotalMin = -1; // Suppress "might be used uninitialized"
int nSuppTotalCur;
int nSuppMaxMin = -1; // Suppress "might be used uninitialized"
int nSuppMaxCur;
assert( nTruths > 0 );
VarBest = -1;
Lpk_SuppForEachVar( p->uSupp, Var )
{
if ( (uNonDecSupp & (1 << Var)) == 0 )
continue;
nSuppMaxCur = 0;
nSuppTotalCur = 0;
for ( i = 0; i < nTruths; i++ )
{
if ( nTruths == 1 )
{
nSuppSize0 = Kit_WordCountOnes( p->puSupps[2*Var+0] );
nSuppSize1 = Kit_WordCountOnes( p->puSupps[2*Var+1] );
}
else
{
Kit_TruthCofactor0New( ppCofs[2*i+0], ppTruths[i], p->nVars, Var );
Kit_TruthCofactor1New( ppCofs[2*i+1], ppTruths[i], p->nVars, Var );
nSuppSize0 = Kit_TruthSupportSize( ppCofs[2*i+0], p->nVars );
nSuppSize1 = Kit_TruthSupportSize( ppCofs[2*i+1], p->nVars );
}
nSuppMaxCur = Abc_MaxInt( nSuppMaxCur, nSuppSize0 );
nSuppMaxCur = Abc_MaxInt( nSuppMaxCur, nSuppSize1 );
nSuppTotalCur += nSuppSize0 + nSuppSize1;
}
if ( VarBest == -1 || nSuppMaxMin > nSuppMaxCur ||
(nSuppMaxMin == nSuppMaxCur && nSuppTotalMin > nSuppTotalCur) )
{
VarBest = Var;
nSuppMaxMin = nSuppMaxCur;
nSuppTotalMin = nSuppTotalCur;
}
}
// recompute cofactors for the best var
for ( i = 0; i < nTruths; i++ )
{
Kit_TruthCofactor0New( ppCofs[2*i+0], ppTruths[i], p->nVars, VarBest );
Kit_TruthCofactor1New( ppCofs[2*i+1], ppTruths[i], p->nVars, VarBest );
}
return VarBest;
}
/**Function*************************************************************
Synopsis [Recursively computes decomposable subsets.]
Description []
SideEffects []
SeeAlso []
***********************************************************************/
unsigned Lpk_ComputeBoundSets_rec( Kit_DsdNtk_t * p, int iLit, Vec_Int_t * vSets, int nSizeMax )
{
unsigned i, iLitFanin, uSupport, uSuppCur;
Kit_DsdObj_t * pObj;
// consider the case of simple gate
pObj = Kit_DsdNtkObj( p, Abc_Lit2Var(iLit) );
if ( pObj == NULL )
return (1 << Abc_Lit2Var(iLit));
if ( pObj->Type == KIT_DSD_AND || pObj->Type == KIT_DSD_XOR )
{
unsigned uSupps[16], Limit, s;
uSupport = 0;
Kit_DsdObjForEachFanin( p, pObj, iLitFanin, i )
{
uSupps[i] = Lpk_ComputeBoundSets_rec( p, iLitFanin, vSets, nSizeMax );
uSupport |= uSupps[i];
}
// create all subsets, except empty and full
Limit = (1 << pObj->nFans) - 1;
for ( s = 1; s < Limit; s++ )
{
uSuppCur = 0;
for ( i = 0; i < pObj->nFans; i++ )
if ( s & (1 << i) )
uSuppCur |= uSupps[i];
if ( Kit_WordCountOnes(uSuppCur) <= nSizeMax )
Vec_IntPush( vSets, uSuppCur );
}
return uSupport;
}
assert( pObj->Type == KIT_DSD_PRIME );
// get the cumulative support of all fanins
uSupport = 0;
Kit_DsdObjForEachFanin( p, pObj, iLitFanin, i )
{
uSuppCur = Lpk_ComputeBoundSets_rec( p, iLitFanin, vSets, nSizeMax );
uSupport |= uSuppCur;
if ( Kit_WordCountOnes(uSuppCur) <= nSizeMax )
Vec_IntPush( vSets, uSuppCur );
}
return uSupport;
}
/**Function*************************************************************
Synopsis [Computes the set of subsets of decomposable variables.]
Description []
SideEffects []
SeeAlso []
***********************************************************************/
Vec_Int_t * Lpk_ComputeBoundSets( Kit_DsdNtk_t * p, int nSizeMax )
{
Vec_Int_t * vSets;
unsigned uSupport, Entry;
int Number, i;
assert( p->nVars <= 16 );
vSets = Vec_IntAlloc( 100 );
Vec_IntPush( vSets, 0 );
if ( Kit_DsdNtkRoot(p)->Type == KIT_DSD_CONST1 )
return vSets;
if ( Kit_DsdNtkRoot(p)->Type == KIT_DSD_VAR )
{
uSupport = ( 1 << Abc_Lit2Var(Kit_DsdNtkRoot(p)->pFans[0]) );
if ( Kit_WordCountOnes(uSupport) <= nSizeMax )
Vec_IntPush( vSets, uSupport );
return vSets;
}
uSupport = Lpk_ComputeBoundSets_rec( p, p->Root, vSets, nSizeMax );
assert( (uSupport & 0xFFFF0000) == 0 );
// add the total support of the network
if ( Kit_WordCountOnes(uSupport) <= nSizeMax )
Vec_IntPush( vSets, uSupport );
// set the remaining variables
Vec_IntForEachEntry( vSets, Number, i )
{
Entry = Number;
Vec_IntWriteEntry( vSets, i, Entry | ((uSupport & ~Entry) << 16) );
}
return vSets;
}
/**Function*************************************************************
Synopsis [Prints the sets of subsets.]
Description []
SideEffects []
SeeAlso []
***********************************************************************/
static void Lpk_PrintSetOne( int uSupport )
{
unsigned k;
for ( k = 0; k < 16; k++ )
if ( uSupport & (1<<k) )
printf( "%c", 'a'+k );
printf( " " );
}
/**Function*************************************************************
Synopsis [Prints the sets of subsets.]
Description []
SideEffects []
SeeAlso []
***********************************************************************/
static void Lpk_PrintSets( Vec_Int_t * vSets )
{
unsigned uSupport;
int Number, i;
printf( "Subsets(%d): ", Vec_IntSize(vSets) );
Vec_IntForEachEntry( vSets, Number, i )
{
uSupport = Number;
Lpk_PrintSetOne( uSupport );
}
printf( "\n" );
}
/**Function*************************************************************
Synopsis [Merges two bound sets.]
Description []
SideEffects []
SeeAlso []
***********************************************************************/
Vec_Int_t * Lpk_MergeBoundSets( Vec_Int_t * vSets0, Vec_Int_t * vSets1, int nSizeMax )
{
Vec_Int_t * vSets;
int Entry0, Entry1, Entry;
int i, k;
vSets = Vec_IntAlloc( 100 );
Vec_IntForEachEntry( vSets0, Entry0, i )
Vec_IntForEachEntry( vSets1, Entry1, k )
{
Entry = Entry0 | Entry1;
if ( (Entry & (Entry >> 16)) )
continue;
if ( Kit_WordCountOnes(Entry & 0xffff) <= nSizeMax )
Vec_IntPush( vSets, Entry );
}
return vSets;
}
/**Function*************************************************************
Synopsis [Performs DSD-based decomposition of the function.]
Description []
SideEffects []
SeeAlso []
***********************************************************************/
void Lpk_FunCompareBoundSets( Lpk_Fun_t * p, Vec_Int_t * vBSets, int nCofDepth, unsigned uNonDecSupp, unsigned uLateArrSupp, Lpk_Res_t * pRes )
{
int fVerbose = 0;
unsigned uBoundSet;
int i, nVarsBS, nVarsRem, Delay, Area;
// compare the resulting boundsets
memset( pRes, 0, sizeof(Lpk_Res_t) );
Vec_IntForEachEntry( vBSets, uBoundSet, i )
{
if ( (uBoundSet & 0xFFFF) == 0 ) // skip empty boundset
continue;
if ( (uBoundSet & uNonDecSupp) == 0 ) // skip those boundsets that are not in the domain of interest
continue;
if ( (uBoundSet & uLateArrSupp) ) // skip those boundsets that are late arriving
continue;
if ( fVerbose )
{
Lpk_PrintSetOne( uBoundSet & 0xFFFF );
//printf( "\n" );
//Lpk_PrintSetOne( uBoundSet >> 16 );
//printf( "\n" );
}
assert( (uBoundSet & (uBoundSet >> 16)) == 0 );
nVarsBS = Kit_WordCountOnes( uBoundSet & 0xFFFF );
if ( nVarsBS == 1 )
continue;
assert( nVarsBS <= (int)p->nLutK - nCofDepth );
nVarsRem = p->nVars - nVarsBS + 1;
Area = 1 + Lpk_LutNumLuts( nVarsRem, p->nLutK );
Delay = 1 + Lpk_SuppDelay( uBoundSet & 0xFFFF, p->pDelays );
if ( fVerbose )
printf( "area = %d limit = %d delay = %d limit = %d\n", Area, (int)p->nAreaLim, Delay, (int)p->nDelayLim );
if ( Area > (int)p->nAreaLim || Delay > (int)p->nDelayLim )
continue;
if ( pRes->BSVars == 0 || pRes->nSuppSizeL > nVarsRem || (pRes->nSuppSizeL == nVarsRem && pRes->DelayEst > Delay) )
{
pRes->nBSVars = nVarsBS;
pRes->BSVars = (uBoundSet & 0xFFFF);
pRes->nSuppSizeS = nVarsBS + nCofDepth;
pRes->nSuppSizeL = nVarsRem;
pRes->DelayEst = Delay;
pRes->AreaEst = Area;
}
}
if ( fVerbose )
{
if ( pRes->BSVars )
{
printf( "Found bound set " );
Lpk_PrintSetOne( pRes->BSVars );
printf( "\n" );
}
else
printf( "Did not find boundsets.\n" );
printf( "\n" );
}
if ( pRes->BSVars )
{
assert( pRes->DelayEst <= (int)p->nDelayLim );
assert( pRes->AreaEst <= (int)p->nAreaLim );
}
}
/**Function*************************************************************
Synopsis [Finds late arriving inputs, which cannot be in the bound set.]
Description []
SideEffects []
SeeAlso []
***********************************************************************/
unsigned Lpk_DsdLateArriving( Lpk_Fun_t * p )
{
unsigned i, uLateArrSupp = 0;
Lpk_SuppForEachVar( p->uSupp, i )
if ( p->pDelays[i] > (int)p->nDelayLim - 2 )
uLateArrSupp |= (1 << i);
return uLateArrSupp;
}
/**Function*************************************************************
Synopsis [Performs DSD-based decomposition of the function.]
Description []
SideEffects []
SeeAlso []
***********************************************************************/
int Lpk_DsdAnalizeOne( Lpk_Fun_t * p, unsigned * ppTruths[5][16], Kit_DsdNtk_t * pNtks[], char pCofVars[], int nCofDepth, Lpk_Res_t * pRes )
{
int fVerbose = 0;
Vec_Int_t * pvBSets[4][8];
unsigned uNonDecSupp, uLateArrSupp;
int i, k, nNonDecSize, nNonDecSizeMax;
assert( nCofDepth >= 1 && nCofDepth <= 3 );
assert( nCofDepth < (int)p->nLutK - 1 );
assert( p->fSupports );
// find the support of the largest non-DSD block
nNonDecSizeMax = 0;
uNonDecSupp = p->uSupp;
for ( i = 0; i < (1<<(nCofDepth-1)); i++ )
{
nNonDecSize = Kit_DsdNonDsdSizeMax( pNtks[i] );
if ( nNonDecSizeMax < nNonDecSize )
{
nNonDecSizeMax = nNonDecSize;
uNonDecSupp = Kit_DsdNonDsdSupports( pNtks[i] );
}
else if ( nNonDecSizeMax == nNonDecSize )
uNonDecSupp |= Kit_DsdNonDsdSupports( pNtks[i] );
}
// remove those variables that cannot be used because of delay constraints
// if variables arrival time is more than p->DelayLim - 2, it cannot be used
uLateArrSupp = Lpk_DsdLateArriving( p );
if ( (uNonDecSupp & ~uLateArrSupp) == 0 )
{
memset( pRes, 0, sizeof(Lpk_Res_t) );
return 0;
}
// find the next cofactoring variable
pCofVars[nCofDepth-1] = Lpk_FunComputeMinSuppSizeVar( p, ppTruths[nCofDepth-1], 1<<(nCofDepth-1), ppTruths[nCofDepth], uNonDecSupp & ~uLateArrSupp );
// derive decomposed networks
for ( i = 0; i < (1<<nCofDepth); i++ )
{
if ( pNtks[i] )
Kit_DsdNtkFree( pNtks[i] );
pNtks[i] = Kit_DsdDecomposeExpand( ppTruths[nCofDepth][i], p->nVars );
if ( fVerbose )
Kit_DsdPrint( stdout, pNtks[i] );
pvBSets[nCofDepth][i] = Lpk_ComputeBoundSets( pNtks[i], p->nLutK - nCofDepth ); // try restricting to those in uNonDecSupp!!!
}
// derive the set of feasible boundsets
for ( i = nCofDepth - 1; i >= 0; i-- )
for ( k = 0; k < (1<<i); k++ )
pvBSets[i][k] = Lpk_MergeBoundSets( pvBSets[i+1][2*k+0], pvBSets[i+1][2*k+1], p->nLutK - nCofDepth );
// compare bound-sets
Lpk_FunCompareBoundSets( p, pvBSets[0][0], nCofDepth, uNonDecSupp, uLateArrSupp, pRes );
// free the bound sets
for ( i = nCofDepth; i >= 0; i-- )
for ( k = 0; k < (1<<i); k++ )
Vec_IntFree( pvBSets[i][k] );
// copy the cofactoring variables
if ( pRes->BSVars )
{
pRes->nCofVars = nCofDepth;
for ( i = 0; i < nCofDepth; i++ )
pRes->pCofVars[i] = pCofVars[i];
}
return 1;
}
/**Function*************************************************************
Synopsis [Performs DSD-based decomposition of the function.]
Description []
SideEffects []
SeeAlso []
***********************************************************************/
Lpk_Res_t * Lpk_DsdAnalize( Lpk_Man_t * pMan, Lpk_Fun_t * p, int nShared )
{
static Lpk_Res_t Res0, * pRes0 = &Res0;
static Lpk_Res_t Res1, * pRes1 = &Res1;
static Lpk_Res_t Res2, * pRes2 = &Res2;
static Lpk_Res_t Res3, * pRes3 = &Res3;
int fUseBackLooking = 1;
Lpk_Res_t * pRes = NULL;
Vec_Int_t * vBSets;
Kit_DsdNtk_t * pNtks[8] = {NULL};
char pCofVars[5];
int i;
assert( p->nLutK >= 3 );
assert( nShared >= 0 && nShared <= 3 );
assert( p->uSupp == Kit_BitMask(p->nVars) );
// try decomposition without cofactoring
pNtks[0] = Kit_DsdDecomposeExpand( Lpk_FunTruth( p, 0 ), p->nVars );
if ( pMan->pPars->fVerbose )
pMan->nBlocks[ Kit_DsdNonDsdSizeMax(pNtks[0]) ]++;
vBSets = Lpk_ComputeBoundSets( pNtks[0], p->nLutK );
Lpk_FunCompareBoundSets( p, vBSets, 0, 0xFFFF, Lpk_DsdLateArriving(p), pRes0 );
Vec_IntFree( vBSets );
// check the result
if ( pRes0->nBSVars == (int)p->nLutK )
{ pRes = pRes0; goto finish; }
if ( pRes0->nBSVars == (int)p->nLutK - 1 )
{ pRes = pRes0; goto finish; }
if ( nShared == 0 )
goto finish;
// prepare storage
Kit_TruthCopy( pMan->ppTruths[0][0], Lpk_FunTruth( p, 0 ), p->nVars );
// cofactor 1 time
if ( !Lpk_DsdAnalizeOne( p, pMan->ppTruths, pNtks, pCofVars, 1, pRes1 ) )
goto finish;
assert( pRes1->nBSVars <= (int)p->nLutK - 1 );
if ( pRes1->nBSVars == (int)p->nLutK - 1 )
{ pRes = pRes1; goto finish; }
if ( pRes0->nBSVars == (int)p->nLutK - 2 )
{ pRes = pRes0; goto finish; }
if ( pRes1->nBSVars == (int)p->nLutK - 2 )
{ pRes = pRes1; goto finish; }
if ( nShared == 1 )
goto finish;
// cofactor 2 times
if ( p->nLutK >= 4 )
{
if ( !Lpk_DsdAnalizeOne( p, pMan->ppTruths, pNtks, pCofVars, 2, pRes2 ) )
goto finish;
assert( pRes2->nBSVars <= (int)p->nLutK - 2 );
if ( pRes2->nBSVars == (int)p->nLutK - 2 )
{ pRes = pRes2; goto finish; }
if ( fUseBackLooking )
{
if ( pRes0->nBSVars == (int)p->nLutK - 3 )
{ pRes = pRes0; goto finish; }
if ( pRes1->nBSVars == (int)p->nLutK - 3 )
{ pRes = pRes1; goto finish; }
}
if ( pRes2->nBSVars == (int)p->nLutK - 3 )
{ pRes = pRes2; goto finish; }
if ( nShared == 2 )
goto finish;
assert( nShared == 3 );
}
// cofactor 3 times
if ( p->nLutK >= 5 )
{
if ( !Lpk_DsdAnalizeOne( p, pMan->ppTruths, pNtks, pCofVars, 3, pRes3 ) )
goto finish;
assert( pRes3->nBSVars <= (int)p->nLutK - 3 );
if ( pRes3->nBSVars == (int)p->nLutK - 3 )
{ pRes = pRes3; goto finish; }
if ( fUseBackLooking )
{
if ( pRes0->nBSVars == (int)p->nLutK - 4 )
{ pRes = pRes0; goto finish; }
if ( pRes1->nBSVars == (int)p->nLutK - 4 )
{ pRes = pRes1; goto finish; }
if ( pRes2->nBSVars == (int)p->nLutK - 4 )
{ pRes = pRes2; goto finish; }
}
if ( pRes3->nBSVars == (int)p->nLutK - 4 )
{ pRes = pRes3; goto finish; }
}
finish:
// free the networks
for ( i = 0; i < (1<<nShared); i++ )
if ( pNtks[i] )
Kit_DsdNtkFree( pNtks[i] );
// choose the best under these conditions
return pRes;
}
/**Function*************************************************************
Synopsis [Splits the function into two subfunctions using DSD.]
Description []
SideEffects []
SeeAlso []
***********************************************************************/
Lpk_Fun_t * Lpk_DsdSplit( Lpk_Man_t * pMan, Lpk_Fun_t * p, char * pCofVars, int nCofVars, unsigned uBoundSet )
{
Lpk_Fun_t * pNew;
Kit_DsdNtk_t * pNtkDec;
int i, k, iVacVar, nCofs;
// prepare storage
Kit_TruthCopy( pMan->ppTruths[0][0], Lpk_FunTruth(p, 0), p->nVars );
// get the vacuous variable
iVacVar = Kit_WordFindFirstBit( uBoundSet );
// compute the cofactors
for ( i = 0; i < nCofVars; i++ )
for ( k = 0; k < (1<<i); k++ )
{
Kit_TruthCofactor0New( pMan->ppTruths[i+1][2*k+0], pMan->ppTruths[i][k], p->nVars, pCofVars[i] );
Kit_TruthCofactor1New( pMan->ppTruths[i+1][2*k+1], pMan->ppTruths[i][k], p->nVars, pCofVars[i] );
}
// decompose each cofactor w.r.t. the bound set
nCofs = (1<<nCofVars);
for ( k = 0; k < nCofs; k++ )
{
pNtkDec = Kit_DsdDecomposeExpand( pMan->ppTruths[nCofVars][k], p->nVars );
Kit_DsdTruthPartialTwo( pMan->pDsdMan, pNtkDec, uBoundSet, iVacVar, pMan->ppTruths[nCofVars+1][k], pMan->ppTruths[nCofVars+1][nCofs+k] );
Kit_DsdNtkFree( pNtkDec );
}
// compute the composition/decomposition functions (they will be in pMan->ppTruths[1][0]/pMan->ppTruths[1][1])
for ( i = nCofVars; i >= 1; i-- )
for ( k = 0; k < (1<<i); k++ )
Kit_TruthMuxVar( pMan->ppTruths[i][k], pMan->ppTruths[i+1][2*k+0], pMan->ppTruths[i+1][2*k+1], p->nVars, pCofVars[i-1] );
// derive the new component (decomposition function)
pNew = Lpk_FunDup( p, pMan->ppTruths[1][1] );
// update the old component (composition function)
Kit_TruthCopy( Lpk_FunTruth(p, 0), pMan->ppTruths[1][0], p->nVars );
p->uSupp = Kit_TruthSupport( Lpk_FunTruth(p, 0), p->nVars );
p->pFanins[iVacVar] = pNew->Id;
p->pDelays[iVacVar] = Lpk_SuppDelay( pNew->uSupp, pNew->pDelays );
// support minimize both
p->fSupports = 0;
Lpk_FunSuppMinimize( p );
Lpk_FunSuppMinimize( pNew );
// update delay and area requirements
pNew->nDelayLim = p->pDelays[iVacVar];
pNew->nAreaLim = 1;
p->nAreaLim = p->nAreaLim - 1;
return pNew;
}
////////////////////////////////////////////////////////////////////////
/// END OF FILE ///
////////////////////////////////////////////////////////////////////////
ABC_NAMESPACE_IMPL_END
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