Commit 3712dd30 by Alan Mishchenko

Changes for delay-oriented computation.

parent 0f64f3b7
...@@ -526,6 +526,10 @@ static inline void Abc_ObjSetMvVar( Abc_Obj_t * pObj, void * pV) { Vec_At ...@@ -526,6 +526,10 @@ static inline void Abc_ObjSetMvVar( Abc_Obj_t * pObj, void * pV) { Vec_At
for ( i = 0; (i < Abc_ObjFaninNum(pObj)) && (((pFanin) = Abc_ObjFanin(pObj, i)), 1); i++ ) for ( i = 0; (i < Abc_ObjFaninNum(pObj)) && (((pFanin) = Abc_ObjFanin(pObj, i)), 1); i++ )
#define Abc_ObjForEachFanout( pObj, pFanout, i ) \ #define Abc_ObjForEachFanout( pObj, pFanout, i ) \
for ( i = 0; (i < Abc_ObjFanoutNum(pObj)) && (((pFanout) = Abc_ObjFanout(pObj, i)), 1); i++ ) for ( i = 0; (i < Abc_ObjFanoutNum(pObj)) && (((pFanout) = Abc_ObjFanout(pObj, i)), 1); i++ )
#define Abc_ObjForEachFaninId( pObj, iFanin, i ) \
for ( i = 0; (i < Abc_ObjFaninNum(pObj)) && (((iFanin) = Abc_ObjFaninId(pObj, i)), 1); i++ )
#define Abc_ObjForEachFanoutId( pObj, iFanout, i ) \
for ( i = 0; (i < Abc_ObjFanoutNum(pObj)) && (((iFanout) = Abc_ObjFanoutId(pObj, i)), 1); i++ )
// cubes and literals // cubes and literals
#define Abc_CubeForEachVar( pCube, Value, i ) \ #define Abc_CubeForEachVar( pCube, Value, i ) \
for ( i = 0; (pCube[i] != ' ') && (Value = pCube[i]); i++ ) for ( i = 0; (pCube[i] != ' ') && (Value = pCube[i]); i++ )
......
...@@ -880,7 +880,7 @@ Abc_Ntk_t * Abc_NtkFromCellMappedGia( Gia_Man_t * p ) ...@@ -880,7 +880,7 @@ Abc_Ntk_t * Abc_NtkFromCellMappedGia( Gia_Man_t * p )
Abc_Obj_t * pObjNew, * pObjNewLi, * pObjNewLo; Abc_Obj_t * pObjNew, * pObjNewLi, * pObjNewLo;
Gia_Obj_t * pObj, * pObjLi, * pObjLo; Gia_Obj_t * pObj, * pObjLi, * pObjLo;
int i, k, iLit, iFanLit, nCells, fNeedConst[2] = {0}; int i, k, iLit, iFanLit, nCells, fNeedConst[2] = {0};
Mio_Cell_t * pCells = Mio_CollectRootsNewDefault( 6, &nCells, 0 ); Mio_Cell2_t * pCells = Mio_CollectRootsNewDefault2( 6, &nCells, 0 );
assert( Gia_ManHasCellMapping(p) ); assert( Gia_ManHasCellMapping(p) );
// start network // start network
pNtkNew = Abc_NtkAlloc( ABC_NTK_LOGIC, ABC_FUNC_MAP, 1 ); pNtkNew = Abc_NtkAlloc( ABC_NTK_LOGIC, ABC_FUNC_MAP, 1 );
......
...@@ -65,10 +65,11 @@ struct Mio_Cell2_t_ ...@@ -65,10 +65,11 @@ struct Mio_Cell2_t_
word uTruth; // truth table word uTruth; // truth table
word DelayAve; // average delay word DelayAve; // average delay
word Delays[6]; // delay word Delays[6]; // delay
void * pMioGate; // gate pointer
}; };
#define MIO_NUM 1000000 #define MIO_NUM 1000
#define MIO_NUMINV 0.000001 #define MIO_NUMINV 0.001
//////////////////////////////////////////////////////////////////////// ////////////////////////////////////////////////////////////////////////
/// GLOBAL VARIABLES /// /// GLOBAL VARIABLES ///
......
...@@ -635,6 +635,7 @@ static inline void Mio_CollectCopy2( Mio_Cell2_t * pCell, Mio_Gate_t * pGate ) ...@@ -635,6 +635,7 @@ static inline void Mio_CollectCopy2( Mio_Cell2_t * pCell, Mio_Gate_t * pGate )
pCell->uTruth = pGate->uTruth; pCell->uTruth = pGate->uTruth;
pCell->Area = (word)(MIO_NUM * pGate->dArea); pCell->Area = (word)(MIO_NUM * pGate->dArea);
pCell->nFanins = pGate->nInputs; pCell->nFanins = pGate->nInputs;
pCell->pMioGate = pGate;
pCell->DelayAve = 0; pCell->DelayAve = 0;
for ( k = 0, pPin = pGate->pPins; pPin; pPin = pPin->pNext, k++ ) for ( k = 0, pPin = pGate->pPins; pPin; pPin = pPin->pNext, k++ )
{ {
......
...@@ -39,6 +39,8 @@ struct Sfm_Dec_t_ ...@@ -39,6 +39,8 @@ struct Sfm_Dec_t_
// external // external
Sfm_Par_t * pPars; // parameters Sfm_Par_t * pPars; // parameters
Sfm_Lib_t * pLib; // library Sfm_Lib_t * pLib; // library
Sfm_Tim_t * pTim; // timing
Abc_Ntk_t * pNtk; // network
// library // library
Vec_Int_t vGateSizes; // fanin counts Vec_Int_t vGateSizes; // fanin counts
Vec_Wrd_t vGateFuncs; // gate truth tables Vec_Wrd_t vGateFuncs; // gate truth tables
...@@ -65,6 +67,8 @@ struct Sfm_Dec_t_ ...@@ -65,6 +67,8 @@ struct Sfm_Dec_t_
Vec_Int_t vObjInMffc; // inputs of MFFC nodes Vec_Int_t vObjInMffc; // inputs of MFFC nodes
Vec_Wrd_t vObjSims; // simulation patterns Vec_Wrd_t vObjSims; // simulation patterns
Vec_Wrd_t vObjSims2; // simulation patterns Vec_Wrd_t vObjSims2; // simulation patterns
Vec_Ptr_t vMatchGates; // matched gates
Vec_Ptr_t vMatchFans; // matched fanins
// solver // solver
sat_solver * pSat; // reusable solver sat_solver * pSat; // reusable solver
Vec_Wec_t vClauses; // CNF clauses for the node Vec_Wec_t vClauses; // CNF clauses for the node
...@@ -77,6 +81,7 @@ struct Sfm_Dec_t_ ...@@ -77,6 +81,7 @@ struct Sfm_Dec_t_
// temporary // temporary
Vec_Int_t vTemp; Vec_Int_t vTemp;
Vec_Int_t vTemp2; Vec_Int_t vTemp2;
Vec_Int_t vCands;
// statistics // statistics
abctime timeWin; abctime timeWin;
abctime timeCnf; abctime timeCnf;
...@@ -150,7 +155,7 @@ void Sfm_ParSetDefault3( Sfm_Par_t * pPars ) ...@@ -150,7 +155,7 @@ void Sfm_ParSetDefault3( Sfm_Par_t * pPars )
pPars->fUseAndOr = 0; // enable internal detection of AND/OR gates pPars->fUseAndOr = 0; // enable internal detection of AND/OR gates
pPars->fZeroCost = 0; // enable zero-cost replacement pPars->fZeroCost = 0; // enable zero-cost replacement
pPars->fUseSim = 0; // enable simulation pPars->fUseSim = 0; // enable simulation
pPars->fArea = 0; // performs optimization for area pPars->fArea = 1; // performs optimization for area
pPars->fVerbose = 0; // enable basic stats pPars->fVerbose = 0; // enable basic stats
pPars->fVeryVerbose = 0; // enable detailed stats pPars->fVeryVerbose = 0; // enable detailed stats
} }
...@@ -166,24 +171,49 @@ void Sfm_ParSetDefault3( Sfm_Par_t * pPars ) ...@@ -166,24 +171,49 @@ void Sfm_ParSetDefault3( Sfm_Par_t * pPars )
SeeAlso [] SeeAlso []
***********************************************************************/ ***********************************************************************/
Sfm_Dec_t * Sfm_DecStart( Sfm_Par_t * pPars ) Sfm_Dec_t * Sfm_DecStart( Sfm_Par_t * pPars, Mio_Library_t * pLib, Abc_Ntk_t * pNtk )
{ {
extern void Sfm_LibPreprocess( Mio_Library_t * pLib, Vec_Int_t * vGateSizes, Vec_Wrd_t * vGateFuncs, Vec_Wec_t * vGateCnfs, Vec_Ptr_t * vGateHands );
Sfm_Dec_t * p = ABC_CALLOC( Sfm_Dec_t, 1 ); int i; Sfm_Dec_t * p = ABC_CALLOC( Sfm_Dec_t, 1 ); int i;
p->pPars = pPars; p->pPars = pPars;
p->pNtk = pNtk;
p->pSat = sat_solver_new(); p->pSat = sat_solver_new();
p->timeStart = Abc_Clock(); p->timeStart = Abc_Clock();
for ( i = 0; i < SFM_SUPP_MAX; i++ ) for ( i = 0; i < SFM_SUPP_MAX; i++ )
p->pTtElems[i] = p->TtElems[i]; p->pTtElems[i] = p->TtElems[i];
Abc_TtElemInit( p->pTtElems, SFM_SUPP_MAX ); Abc_TtElemInit( p->pTtElems, SFM_SUPP_MAX );
p->pLib = Sfm_LibPrepare( pPars->nMffcMax + 1, 1, !pPars->fArea, pPars->fVerbose ); p->pLib = Sfm_LibPrepare( pPars->nMffcMax + 1, 1, !pPars->fArea, pPars->fVerbose );
if ( !pPars->fArea )
p->pTim = Sfm_TimStart( pLib, NULL, pNtk );
if ( pPars->fVeryVerbose ) if ( pPars->fVeryVerbose )
// if ( pPars->fVerbose ) // if ( pPars->fVerbose )
Sfm_LibPrint( p->pLib ); Sfm_LibPrint( p->pLib );
pNtk->pData = p;
// enter library
assert( Abc_NtkIsMappedLogic(pNtk) );
Sfm_LibPreprocess( pLib, &p->vGateSizes, &p->vGateFuncs, &p->vGateCnfs, &p->vGateHands );
p->GateConst0 = Mio_GateReadValue( Mio_LibraryReadConst0(pLib) );
p->GateConst1 = Mio_GateReadValue( Mio_LibraryReadConst1(pLib) );
p->GateBuffer = Mio_GateReadValue( Mio_LibraryReadBuf(pLib) );
p->GateInvert = Mio_GateReadValue( Mio_LibraryReadInv(pLib) );
if ( pPars->fRrOnly )
{
p->GateAnd[0] = Mio_GateReadValue( Mio_LibraryReadGateByName(pLib, "and00", NULL) );
p->GateAnd[1] = Mio_GateReadValue( Mio_LibraryReadGateByName(pLib, "and01", NULL) );
p->GateAnd[2] = Mio_GateReadValue( Mio_LibraryReadGateByName(pLib, "and10", NULL) );
p->GateAnd[3] = Mio_GateReadValue( Mio_LibraryReadGateByName(pLib, "and11", NULL) );
p->GateOr[0] = Mio_GateReadValue( Mio_LibraryReadGateByName(pLib, "or00", NULL) );
p->GateOr[1] = Mio_GateReadValue( Mio_LibraryReadGateByName(pLib, "or01", NULL) );
p->GateOr[2] = Mio_GateReadValue( Mio_LibraryReadGateByName(pLib, "or10", NULL) );
p->GateOr[3] = Mio_GateReadValue( Mio_LibraryReadGateByName(pLib, "or11", NULL) );
}
return p; return p;
} }
void Sfm_DecStop( Sfm_Dec_t * p ) void Sfm_DecStop( Sfm_Dec_t * p )
{ {
Abc_Ntk_t * pNtk = p->pNtk;
Sfm_LibStop( p->pLib ); Sfm_LibStop( p->pLib );
if ( p->pTim ) Sfm_TimStop( p->pTim );
// library // library
Vec_IntErase( &p->vGateSizes ); Vec_IntErase( &p->vGateSizes );
Vec_WrdErase( &p->vGateFuncs ); Vec_WrdErase( &p->vGateFuncs );
...@@ -199,6 +229,8 @@ void Sfm_DecStop( Sfm_Dec_t * p ) ...@@ -199,6 +229,8 @@ void Sfm_DecStop( Sfm_Dec_t * p )
Vec_IntErase( &p->vObjInMffc ); Vec_IntErase( &p->vObjInMffc );
Vec_WrdErase( &p->vObjSims ); Vec_WrdErase( &p->vObjSims );
Vec_WrdErase( &p->vObjSims2 ); Vec_WrdErase( &p->vObjSims2 );
Vec_PtrErase( &p->vMatchGates );
Vec_PtrErase( &p->vMatchFans );
// solver // solver
sat_solver_delete( p->pSat ); sat_solver_delete( p->pSat );
Vec_WecErase( &p->vClauses ); Vec_WecErase( &p->vClauses );
...@@ -209,7 +241,9 @@ void Sfm_DecStop( Sfm_Dec_t * p ) ...@@ -209,7 +241,9 @@ void Sfm_DecStop( Sfm_Dec_t * p )
// temporary // temporary
Vec_IntErase( &p->vTemp ); Vec_IntErase( &p->vTemp );
Vec_IntErase( &p->vTemp2 ); Vec_IntErase( &p->vTemp2 );
Vec_IntErase( &p->vCands );
ABC_FREE( p ); ABC_FREE( p );
pNtk->pData = NULL;
} }
/**Function************************************************************* /**Function*************************************************************
...@@ -1060,6 +1094,7 @@ int Sfm_DecPeformDec2( Sfm_Dec_t * p, Abc_Obj_t * pObj ) ...@@ -1060,6 +1094,7 @@ int Sfm_DecPeformDec2( Sfm_Dec_t * p, Abc_Obj_t * pObj )
int fVeryVerbose = p->pPars->fPrintDecs || p->pPars->fVeryVerbose; int fVeryVerbose = p->pPars->fPrintDecs || p->pPars->fVeryVerbose;
int nDecs = Abc_MaxInt(p->pPars->nDecMax, 1); int nDecs = Abc_MaxInt(p->pPars->nDecMax, 1);
int i, iBest = -1, RetValue, Prev = 0; int i, iBest = -1, RetValue, Prev = 0;
assert( p->pPars->fArea == 1 );
if ( p->pPars->fUseSim ) if ( p->pPars->fUseSim )
Sfm_ObjSetupSimInfo( pObj ); Sfm_ObjSetupSimInfo( pObj );
else else
...@@ -1119,6 +1154,97 @@ int Sfm_DecPeformDec2( Sfm_Dec_t * p, Abc_Obj_t * pObj ) ...@@ -1119,6 +1154,97 @@ int Sfm_DecPeformDec2( Sfm_Dec_t * p, Abc_Obj_t * pObj )
printf( "Area-reducing implementation %sfound.\n", RetValue < 0 ? "NOT " : "" ); printf( "Area-reducing implementation %sfound.\n", RetValue < 0 ? "NOT " : "" );
return RetValue; return RetValue;
} }
int Sfm_DecPeformDec3( Sfm_Dec_t * p, Abc_Obj_t * pObj )
{
word uTruth[SFM_DEC_MAX][SFM_WORD_MAX], Masks[2];
int pSupp[SFM_DEC_MAX][2*SFM_SUPP_MAX];
int nSupp[SFM_DEC_MAX], pAssump[SFM_WIN_MAX];
int fVeryVerbose = p->pPars->fPrintDecs || p->pPars->fVeryVerbose;
int nDecs = Abc_MaxInt(p->pPars->nDecMax, 1);
int i, k, DelayMin, nMatches, iBest = -1, RetValue, Prev = 0;
Mio_Gate_t * pGate1Best = NULL, * pGate2Best = NULL;
char * pFans1Best = NULL, * pFans2Best = NULL;
assert( p->pPars->fArea == 0 );
if ( p->pPars->fUseSim )
Sfm_ObjSetupSimInfo( pObj );
else
{
p->nPats[0] = p->nPats[1] = 0;
p->uMask[0] = p->uMask[1] = 0;
Vec_WrdFill( &p->vSets[0], p->nDivs, 0 );
Vec_WrdFill( &p->vSets[1], p->nDivs, 0 );
}
//Sfm_DecPrint( p, NULL );
if ( fVeryVerbose )
printf( "\nNode %4d : MFFC %2d\n", p->iTarget, p->nMffc );
assert( p->pPars->nDecMax <= SFM_DEC_MAX );
for ( i = 0; i < nDecs; i++ )
{
// reduce the variable array
if ( Vec_IntSize(&p->vObjDec) > Prev )
Vec_IntShrink( &p->vObjDec, Prev );
Prev = Vec_IntSize(&p->vObjDec) + 1;
// perform decomposition
Masks[0] = Masks[1] = ~(word)0;
nSupp[i] = Sfm_DecPeformDec_rec( p, uTruth[i], pSupp[i], pAssump, 0, Masks, 1 );
if ( nSupp[i] == -2 )
{
if ( fVeryVerbose )
printf( "Dec %d: Pat0 = %2d Pat1 = %2d NO DEC.\n", i, p->nPats[0], p->nPats[1] );
continue;
}
if ( fVeryVerbose )
printf( "Dec %d: Pat0 = %2d Pat1 = %2d Supp = %d ", i, p->nPats[0], p->nPats[1], nSupp[i] );
if ( fVeryVerbose )
Dau_DsdPrintFromTruth( uTruth[i], nSupp[i] );
if ( nSupp[iBest] < 2 )
{
RetValue = Sfm_LibImplement( p->pLib, uTruth[i][0], pSupp[i], nSupp[i], p->AreaMffc, &p->vObjGates, &p->vObjFanins, p->pPars->fZeroCost );
return RetValue;
}
// try the delay
nMatches = Sfm_LibFindMatches( p->pLib, uTruth[i][0], pSupp[i], nSupp[i], &p->vMatchGates, &p->vMatchFans );
DelayMin = Sfm_TimReadObjDelay( p->pTim, Abc_ObjId(pObj) );
for ( k = 0; k < nMatches; k++ )
{
Mio_Gate_t * pGate1 = (Mio_Gate_t *)Vec_PtrEntry( &p->vMatchGates, 2*k+0 );
Mio_Gate_t * pGate2 = (Mio_Gate_t *)Vec_PtrEntry( &p->vMatchGates, 2*k+1 );
char * pFans1 = (char *)Vec_PtrEntry( &p->vMatchFans, 2*k+0 );
char * pFans2 = (char *)Vec_PtrEntry( &p->vMatchFans, 2*k+1 );
Vec_Int_t vFanins = { nSupp[i], nSupp[i], pSupp[i] };
int Delay = Sfm_TimEvalRemapping( p->pTim, &vFanins, pGate1, pFans1, pGate2, pFans2 );
if ( Delay < DelayMin )
{
pGate1Best = pGate1;
pGate2Best = pGate2;
pFans1Best = pFans1;
pFans2Best = pFans2;
iBest = i;
}
}
}
if ( p->pPars->fUseSim )
Sfm_ObjSetdownSimInfo( pObj );
if ( iBest == -1 )
{
if ( fVeryVerbose )
printf( "Best : NO DEC.\n" );
p->nNoDecs++;
return -2;
}
else
{
if ( fVeryVerbose )
printf( "Best %d: %d ", iBest, nSupp[iBest] );
// if ( fVeryVerbose )
// Dau_DsdPrintFromTruth( uTruth[iBest], nSupp[iBest] );
Sfm_LibAddNewGates( p->pLib, pSupp[iBest], pGate1Best, pGate2Best, pFans1Best, pFans2Best, &p->vObjGates, &p->vObjFanins );
}
// return -1;
if ( fVeryVerbose )
printf( "Delay-reducing implementation found.\n" );
return 1;
}
/**Function************************************************************* /**Function*************************************************************
...@@ -1223,38 +1349,68 @@ static inline int Sfm_DecNodeIsMffc( Abc_Obj_t * p, int nLevelMin ) ...@@ -1223,38 +1349,68 @@ static inline int Sfm_DecNodeIsMffc( Abc_Obj_t * p, int nLevelMin )
{ {
return Abc_ObjIsNode(p) && Abc_ObjFanoutNum(p) == 1 && Abc_NodeIsTravIdCurrent(p) && (Abc_ObjLevel(p) >= nLevelMin || Abc_ObjFaninNum(p) == 0); return Abc_ObjIsNode(p) && Abc_ObjFanoutNum(p) == 1 && Abc_NodeIsTravIdCurrent(p) && (Abc_ObjLevel(p) >= nLevelMin || Abc_ObjFaninNum(p) == 0);
} }
void Sfm_DecMarkMffc( Abc_Obj_t * pPivot, int nLevelMin, int nMffcMax, int fVeryVerbose, Vec_Int_t * vMffc, Vec_Int_t * vInMffc ) static inline int Sfm_DecNodeIsMffcInput( Abc_Obj_t * p, int nLevelMin, Sfm_Tim_t * pTim, Abc_Obj_t * pPivot )
{
return Abc_NodeIsTravIdCurrent(p) && (Abc_ObjLevel(p) >= nLevelMin || Abc_ObjFaninNum(p) == 0) && Sfm_TimNodeIsNonCritical(pTim, pPivot, p);
}
void Sfm_DecMarkMffc( Abc_Obj_t * pPivot, int nLevelMin, int nMffcMax, int fVeryVerbose, Vec_Int_t * vMffc, Vec_Int_t * vInMffc, Sfm_Tim_t * pTim )
{ {
Abc_Obj_t * pFanin, * pFanin2, * pFanin3, * pObj; int i, k, n; Abc_Obj_t * pFanin, * pFanin2, * pFanin3, * pObj; int i, k, n;
assert( nMffcMax > 0 ); assert( nMffcMax > 0 );
// collect MFFC
Vec_IntFill( vMffc, 1, Abc_ObjId(pPivot) ); Vec_IntFill( vMffc, 1, Abc_ObjId(pPivot) );
Abc_ObjForEachFanin( pPivot, pFanin, i ) if ( pTim != NULL )
if ( Sfm_DecNodeIsMffc(pFanin, nLevelMin) && Vec_IntSize(vMffc) < nMffcMax ) {
Vec_IntPush( vMffc, Abc_ObjId(pFanin) ); pPivot->iTemp |= SFM_MASK_MFFC;
Abc_ObjForEachFanin( pPivot, pFanin, i ) pPivot->iTemp |= SFM_MASK_PIVOT;
if ( Sfm_DecNodeIsMffc(pFanin, nLevelMin) && Vec_IntSize(vMffc) < nMffcMax ) // collect MFFC inputs (these are low-delay nodes close to the pivot)
Abc_ObjForEachFanin( pFanin, pFanin2, k ) Vec_IntClear(vInMffc);
if ( Sfm_DecNodeIsMffc(pFanin2, nLevelMin) && Vec_IntSize(vMffc) < nMffcMax ) Abc_ObjForEachFanin( pPivot, pFanin, i )
Vec_IntPush( vMffc, Abc_ObjId(pFanin2) ); if ( Sfm_DecNodeIsMffcInput(pFanin, nLevelMin, pTim, pPivot) )
Abc_ObjForEachFanin( pPivot, pFanin, i ) Vec_IntPush( vInMffc, Abc_ObjId(pFanin) );
if ( Sfm_DecNodeIsMffc(pFanin, nLevelMin) && Vec_IntSize(vMffc) < nMffcMax ) Abc_ObjForEachFanin( pPivot, pFanin, i )
Abc_ObjForEachFanin( pFanin, pFanin2, k ) if ( Sfm_DecNodeIsMffcInput(pFanin, nLevelMin, pTim, pPivot) )
if ( Sfm_DecNodeIsMffc(pFanin2, nLevelMin) && Vec_IntSize(vMffc) < nMffcMax ) Abc_ObjForEachFanin( pFanin, pFanin2, k )
Abc_ObjForEachFanin( pFanin2, pFanin3, n ) if ( Sfm_DecNodeIsMffcInput(pFanin2, nLevelMin, pTim, pPivot) )
if ( Sfm_DecNodeIsMffc(pFanin3, nLevelMin) && Vec_IntSize(vMffc) < nMffcMax ) Vec_IntPush( vInMffc, Abc_ObjId(pFanin2) );
Vec_IntPush( vMffc, Abc_ObjId(pFanin3) ); Abc_ObjForEachFanin( pPivot, pFanin, i )
// mark MFFC if ( Sfm_DecNodeIsMffcInput(pFanin, nLevelMin, pTim, pPivot) )
assert( Vec_IntSize(vMffc) <= nMffcMax ); Abc_ObjForEachFanin( pFanin, pFanin2, k )
Abc_NtkForEachObjVec( vMffc, pPivot->pNtk, pObj, i ) if ( Sfm_DecNodeIsMffcInput(pFanin2, nLevelMin, pTim, pPivot) )
pObj->iTemp |= SFM_MASK_MFFC; Abc_ObjForEachFanin( pFanin2, pFanin3, n )
pPivot->iTemp |= SFM_MASK_PIVOT; if ( Sfm_DecNodeIsMffcInput(pFanin3, nLevelMin, pTim, pPivot) )
// collect MFFC inputs Vec_IntPush( vInMffc, Abc_ObjId(pFanin3) );
Vec_IntClear(vInMffc);
Abc_NtkForEachObjVec( vMffc, pPivot->pNtk, pObj, i ) }
Abc_ObjForEachFanin( pObj, pFanin, k ) else
if ( Abc_NodeIsTravIdCurrent(pFanin) && pFanin->iTemp == SFM_MASK_PI ) {
Vec_IntPushUnique( vInMffc, Abc_ObjId(pFanin) ); // collect MFFC
Abc_ObjForEachFanin( pPivot, pFanin, i )
if ( Sfm_DecNodeIsMffc(pFanin, nLevelMin) && Vec_IntSize(vMffc) < nMffcMax )
Vec_IntPush( vMffc, Abc_ObjId(pFanin) );
Abc_ObjForEachFanin( pPivot, pFanin, i )
if ( Sfm_DecNodeIsMffc(pFanin, nLevelMin) && Vec_IntSize(vMffc) < nMffcMax )
Abc_ObjForEachFanin( pFanin, pFanin2, k )
if ( Sfm_DecNodeIsMffc(pFanin2, nLevelMin) && Vec_IntSize(vMffc) < nMffcMax )
Vec_IntPush( vMffc, Abc_ObjId(pFanin2) );
Abc_ObjForEachFanin( pPivot, pFanin, i )
if ( Sfm_DecNodeIsMffc(pFanin, nLevelMin) && Vec_IntSize(vMffc) < nMffcMax )
Abc_ObjForEachFanin( pFanin, pFanin2, k )
if ( Sfm_DecNodeIsMffc(pFanin2, nLevelMin) && Vec_IntSize(vMffc) < nMffcMax )
Abc_ObjForEachFanin( pFanin2, pFanin3, n )
if ( Sfm_DecNodeIsMffc(pFanin3, nLevelMin) && Vec_IntSize(vMffc) < nMffcMax )
Vec_IntPush( vMffc, Abc_ObjId(pFanin3) );
// mark MFFC
assert( Vec_IntSize(vMffc) <= nMffcMax );
Abc_NtkForEachObjVec( vMffc, pPivot->pNtk, pObj, i )
pObj->iTemp |= SFM_MASK_MFFC;
pPivot->iTemp |= SFM_MASK_PIVOT;
// collect MFFC inputs
Vec_IntClear(vInMffc);
Abc_NtkForEachObjVec( vMffc, pPivot->pNtk, pObj, i )
Abc_ObjForEachFanin( pObj, pFanin, k )
if ( Abc_NodeIsTravIdCurrent(pFanin) && pFanin->iTemp == SFM_MASK_PI )
Vec_IntPushUnique( vInMffc, Abc_ObjId(pFanin) );
}
} }
/**Function************************************************************* /**Function*************************************************************
...@@ -1276,7 +1432,7 @@ int Sfm_DecMffcArea( Abc_Ntk_t * pNtk, Vec_Int_t * vMffc ) ...@@ -1276,7 +1432,7 @@ int Sfm_DecMffcArea( Abc_Ntk_t * pNtk, Vec_Int_t * vMffc )
nAreaMffc += (int)(MIO_NUM * Mio_GateReadArea((Mio_Gate_t *)pObj->pData)); nAreaMffc += (int)(MIO_NUM * Mio_GateReadArea((Mio_Gate_t *)pObj->pData));
return nAreaMffc; return nAreaMffc;
} }
int Sfm_DecExtract( Abc_Ntk_t * pNtk, Sfm_Par_t * pPars, Abc_Obj_t * pPivot, Vec_Int_t * vRoots, Vec_Int_t * vGates, Vec_Wec_t * vFanins, Vec_Int_t * vMap, Vec_Int_t * vTfi, Vec_Int_t * vTfo, Vec_Int_t * vMffc, Vec_Int_t * vInMffc ) int Sfm_DecExtract( Abc_Ntk_t * pNtk, Sfm_Par_t * pPars, Abc_Obj_t * pPivot, Vec_Int_t * vRoots, Vec_Int_t * vGates, Vec_Wec_t * vFanins, Vec_Int_t * vMap, Vec_Int_t * vTfi, Vec_Int_t * vTfo, Vec_Int_t * vMffc, Vec_Int_t * vInMffc, Sfm_Tim_t * pTim )
{ {
int fVeryVerbose = 0;//pPars->fVeryVerbose; int fVeryVerbose = 0;//pPars->fVeryVerbose;
Vec_Int_t * vLevel; Vec_Int_t * vLevel;
...@@ -1308,7 +1464,7 @@ printf( "\n\nTarget %d\n", Abc_ObjId(pPivot) ); ...@@ -1308,7 +1464,7 @@ printf( "\n\nTarget %d\n", Abc_ObjId(pPivot) );
nTfiSize = Vec_IntSize(vTfi); nTfiSize = Vec_IntSize(vTfi);
Sfm_ObjFlipNode( pPivot ); Sfm_ObjFlipNode( pPivot );
// additinally mark MFFC // additinally mark MFFC
Sfm_DecMarkMffc( pPivot, nLevelMin, pPars->nMffcMax, fVeryVerbose, vMffc, vInMffc ); Sfm_DecMarkMffc( pPivot, nLevelMin, pPars->nMffcMax, fVeryVerbose, vMffc, vInMffc, pTim );
assert( Vec_IntSize(vMffc) <= pPars->nMffcMax ); assert( Vec_IntSize(vMffc) <= pPars->nMffcMax );
if ( fVeryVerbose ) if ( fVeryVerbose )
printf( "Mffc size = %d. Mffc area = %.2f. InMffc size = %d.\n", Vec_IntSize(vMffc), Sfm_DecMffcArea(pNtk, vMffc)*MIO_NUMINV, Vec_IntSize(vInMffc) ); printf( "Mffc size = %d. Mffc area = %.2f. InMffc size = %d.\n", Vec_IntSize(vMffc), Sfm_DecMffcArea(pNtk, vMffc)*MIO_NUMINV, Vec_IntSize(vInMffc) );
...@@ -1336,6 +1492,22 @@ printf( "\nSides:\n" ); ...@@ -1336,6 +1492,22 @@ printf( "\nSides:\n" );
Abc_NtkForEachObjVec( vTfi, pNtk, pObj, i ) Abc_NtkForEachObjVec( vTfi, pNtk, pObj, i )
if ( pObj->iTemp == (SFM_MASK_PI | SFM_MASK_INPUT) || pObj->iTemp == SFM_MASK_FANIN ) if ( pObj->iTemp == (SFM_MASK_PI | SFM_MASK_INPUT) || pObj->iTemp == SFM_MASK_FANIN )
Sfm_DecAddNode( pObj, vMap, vGates, pObj->iTemp == SFM_MASK_FANIN, fVeryVerbose ); Sfm_DecAddNode( pObj, vMap, vGates, pObj->iTemp == SFM_MASK_FANIN, fVeryVerbose );
// reorder nodes acording to delay
if ( pTim )
{
int nDivsNew, nOldSize = Vec_IntSize(vMap);
Vec_IntClear( vTfo );
Vec_IntAppend( vTfo, vMap );
nDivsNew = Sfm_TimSortArrayByArrival( pTim, vTfo, Abc_ObjId(pPivot) );
// collect again
Vec_IntClear( vMap );
Vec_IntClear( vGates );
Abc_NtkForEachObjVec( vTfo, pNtk, pObj, i )
Sfm_DecAddNode( pObj, vMap, vGates, Abc_ObjIsCi(pObj) || (Abc_ObjLevel(pObj) < nLevelMin && Abc_ObjFaninNum(pObj) > 0) || pObj->iTemp == SFM_MASK_FANIN, 0 );
assert( nOldSize == Vec_IntSize(vMap) );
// update divisor count
nDivs = nDivsNew;
}
// add the TFO nodes // add the TFO nodes
if ( fVeryVerbose ) if ( fVeryVerbose )
printf( "\nTFO:\n" ); printf( "\nTFO:\n" );
...@@ -1380,11 +1552,13 @@ printf( "\n" ); ...@@ -1380,11 +1552,13 @@ printf( "\n" );
*/ */
return nDivs; return nDivs;
} }
void Sfm_DecInsert( Abc_Ntk_t * pNtk, Abc_Obj_t * pPivot, int Limit, Vec_Int_t * vGates, Vec_Wec_t * vFanins, Vec_Int_t * vMap, Vec_Ptr_t * vGateHandles, int GateBuf, int GateInv, Vec_Wrd_t * vFuncs ) void Sfm_DecInsert( Abc_Ntk_t * pNtk, Abc_Obj_t * pPivot, int Limit, Vec_Int_t * vGates, Vec_Wec_t * vFanins, Vec_Int_t * vMap, Vec_Ptr_t * vGateHandles, int GateBuf, int GateInv, Vec_Wrd_t * vFuncs, Vec_Int_t * vTimeNodes )
{ {
Abc_Obj_t * pObjNew = NULL; Abc_Obj_t * pObjNew = NULL;
Vec_Int_t * vLevel; Vec_Int_t * vLevel;
int i, k, iObj, Gate; int i, k, iObj, Gate;
if ( vTimeNodes )
Vec_IntClear( vTimeNodes );
// assuming that new gates are appended at the end // assuming that new gates are appended at the end
assert( Limit < Vec_IntSize(vGates) ); assert( Limit < Vec_IntSize(vGates) );
assert( Limit == Vec_IntSize(vMap) ); assert( Limit == Vec_IntSize(vMap) );
...@@ -1399,9 +1573,11 @@ void Sfm_DecInsert( Abc_Ntk_t * pNtk, Abc_Obj_t * pPivot, int Limit, Vec_Int_t * ...@@ -1399,9 +1573,11 @@ void Sfm_DecInsert( Abc_Ntk_t * pNtk, Abc_Obj_t * pPivot, int Limit, Vec_Int_t *
// update level // update level
pObjNew->Level = 0; pObjNew->Level = 0;
Abc_NtkUpdateIncLevel_rec( pObjNew ); Abc_NtkUpdateIncLevel_rec( pObjNew );
if ( vTimeNodes )
Vec_IntPush( vTimeNodes, Abc_ObjId(pObjNew) );
return; return;
} }
else if ( Gate == GateInv ) else if ( vTimeNodes == NULL && Gate == GateInv )
{ {
// check if fanouts can be updated // check if fanouts can be updated
Abc_Obj_t * pFanout; Abc_Obj_t * pFanout;
...@@ -1445,6 +1621,8 @@ void Sfm_DecInsert( Abc_Ntk_t * pNtk, Abc_Obj_t * pPivot, int Limit, Vec_Int_t * ...@@ -1445,6 +1621,8 @@ void Sfm_DecInsert( Abc_Ntk_t * pNtk, Abc_Obj_t * pPivot, int Limit, Vec_Int_t *
Abc_ObjAddFanin( pObjNew, Abc_NtkObj(pNtk, Vec_IntEntry(vMap, iObj)) ); Abc_ObjAddFanin( pObjNew, Abc_NtkObj(pNtk, Vec_IntEntry(vMap, iObj)) );
pObjNew->pData = Vec_PtrEntry( vGateHandles, Gate ); pObjNew->pData = Vec_PtrEntry( vGateHandles, Gate );
Vec_IntPush( vMap, Abc_ObjId(pObjNew) ); Vec_IntPush( vMap, Abc_ObjId(pObjNew) );
if ( vTimeNodes )
Vec_IntPush( vTimeNodes, Abc_ObjId(pObjNew) );
} }
Abc_ObjReplace( pPivot, pObjNew ); Abc_ObjReplace( pPivot, pObjNew );
// update level // update level
...@@ -1493,66 +1671,25 @@ void Abc_NtkCountStats( Sfm_Dec_t * p, int Limit ) ...@@ -1493,66 +1671,25 @@ void Abc_NtkCountStats( Sfm_Dec_t * p, int Limit )
else else
p->nNodesResyn++; p->nNodesResyn++;
} }
void Abc_NtkPerformMfs3( Abc_Ntk_t * pNtk, Sfm_Par_t * pPars )
/**Function*************************************************************
Synopsis []
Description []
SideEffects []
SeeAlso []
***********************************************************************/
void Abc_NtkAreaOpt( Sfm_Dec_t * p )
{ {
extern void Sfm_LibPreprocess( Mio_Library_t * pLib, Vec_Int_t * vGateSizes, Vec_Wrd_t * vGateFuncs, Vec_Wec_t * vGateCnfs, Vec_Ptr_t * vGateHands ); Abc_Ntk_t * pNtk = p->pNtk;
Mio_Library_t * pLib = (Mio_Library_t *)pNtk->pManFunc; Sfm_Par_t * pPars = p->pPars;
Sfm_Dec_t * p = Sfm_DecStart( pPars );
Abc_Obj_t * pObj; Abc_Obj_t * pObj;
abctime clk; abctime clk;
int i = 0, Limit, RetValue, nStop = Abc_NtkObjNumMax(pNtk); int i = 0, Limit, RetValue, nStop = Abc_NtkObjNumMax(pNtk);
if ( pPars->fVerbose )
{
printf( "Remapping parameters: " );
if ( pPars->nTfoLevMax )
printf( "TFO = %d. ", pPars->nTfoLevMax );
if ( pPars->nTfiLevMax )
printf( "TFI = %d. ", pPars->nTfiLevMax );
if ( pPars->nFanoutMax )
printf( "FanMax = %d. ", pPars->nFanoutMax );
if ( pPars->nWinSizeMax )
printf( "WinMax = %d. ", pPars->nWinSizeMax );
if ( pPars->nBTLimit )
printf( "Confl = %d. ", pPars->nBTLimit );
if ( pPars->nMffcMin )
printf( "MffcMin = %d. ", pPars->nMffcMin );
if ( pPars->nMffcMax )
printf( "MffcMax = %d. ", pPars->nMffcMax );
if ( pPars->nDecMax )
printf( "DecMax = %d. ", pPars->nDecMax );
if ( pPars->iNodeOne )
printf( "Pivot = %d. ", pPars->iNodeOne );
printf( "Sim = %s. ", pPars->fUseSim ? "yes" : "no" );
printf( "0-cost = %s. ", pPars->fZeroCost ? "yes" : "no" );
printf( "\n" );
}
// enter library
assert( Abc_NtkIsMappedLogic(pNtk) );
Sfm_LibPreprocess( pLib, &p->vGateSizes, &p->vGateFuncs, &p->vGateCnfs, &p->vGateHands );
p->GateConst0 = Mio_GateReadValue( Mio_LibraryReadConst0(pLib) );
p->GateConst1 = Mio_GateReadValue( Mio_LibraryReadConst1(pLib) );
p->GateBuffer = Mio_GateReadValue( Mio_LibraryReadBuf(pLib) );
p->GateInvert = Mio_GateReadValue( Mio_LibraryReadInv(pLib) );
if ( pPars->fRrOnly )
{
p->GateAnd[0] = Mio_GateReadValue( Mio_LibraryReadGateByName(pLib, "and00", NULL) );
p->GateAnd[1] = Mio_GateReadValue( Mio_LibraryReadGateByName(pLib, "and01", NULL) );
p->GateAnd[2] = Mio_GateReadValue( Mio_LibraryReadGateByName(pLib, "and10", NULL) );
p->GateAnd[3] = Mio_GateReadValue( Mio_LibraryReadGateByName(pLib, "and11", NULL) );
p->GateOr[0] = Mio_GateReadValue( Mio_LibraryReadGateByName(pLib, "or00", NULL) );
p->GateOr[1] = Mio_GateReadValue( Mio_LibraryReadGateByName(pLib, "or01", NULL) );
p->GateOr[2] = Mio_GateReadValue( Mio_LibraryReadGateByName(pLib, "or10", NULL) );
p->GateOr[3] = Mio_GateReadValue( Mio_LibraryReadGateByName(pLib, "or11", NULL) );
}
if ( pPars->fVerbose )
p->nTotalNodesBeg = Abc_NtkNodeNum(pNtk);
if ( pPars->fVerbose )
p->nTotalEdgesBeg = Abc_NtkGetTotalFanins(pNtk);
// iterate over nodes
pNtk->pData = p;
Abc_NtkLevel( pNtk );
if ( p->pPars->fUseSim )
Sfm_NtkSimulate( pNtk );
Abc_NtkForEachNode( pNtk, pObj, i ) Abc_NtkForEachNode( pNtk, pObj, i )
{ {
if ( i >= nStop || (pPars->nNodesMax && i > pPars->nNodesMax) ) if ( i >= nStop || (pPars->nNodesMax && i > pPars->nNodesMax) )
...@@ -1561,10 +1698,11 @@ void Abc_NtkPerformMfs3( Abc_Ntk_t * pNtk, Sfm_Par_t * pPars ) ...@@ -1561,10 +1698,11 @@ void Abc_NtkPerformMfs3( Abc_Ntk_t * pNtk, Sfm_Par_t * pPars )
continue; continue;
if ( pPars->iNodeOne && i != pPars->iNodeOne ) if ( pPars->iNodeOne && i != pPars->iNodeOne )
continue; continue;
pPars->fVeryVerbose = pPars->iNodeOne && i == pPars->iNodeOne; if ( pPars->iNodeOne )
pPars->fVeryVerbose = (int)(i == pPars->iNodeOne);
p->nNodesTried++; p->nNodesTried++;
clk = Abc_Clock(); clk = Abc_Clock();
p->nDivs = Sfm_DecExtract( pNtk, pPars, pObj, &p->vObjRoots, &p->vObjGates, &p->vObjFanins, &p->vObjMap, &p->vTemp, &p->vTemp2, &p->vObjMffc, &p->vObjInMffc ); p->nDivs = Sfm_DecExtract( pNtk, pPars, pObj, &p->vObjRoots, &p->vObjGates, &p->vObjFanins, &p->vObjMap, &p->vTemp, &p->vTemp2, &p->vObjMffc, &p->vObjInMffc, NULL );
p->timeWin += Abc_Clock() - clk; p->timeWin += Abc_Clock() - clk;
if ( pPars->nWinSizeMax && pPars->nWinSizeMax < Vec_IntSize(&p->vObjGates) ) if ( pPars->nWinSizeMax && pPars->nWinSizeMax < Vec_IntSize(&p->vObjGates) )
continue; continue;
...@@ -1593,16 +1731,122 @@ p->timeSat += Abc_Clock() - clk; ...@@ -1593,16 +1731,122 @@ p->timeSat += Abc_Clock() - clk;
continue; continue;
p->nNodesChanged++; p->nNodesChanged++;
Abc_NtkCountStats( p, Limit ); Abc_NtkCountStats( p, Limit );
Sfm_DecInsert( pNtk, pObj, Limit, &p->vObjGates, &p->vObjFanins, &p->vObjMap, &p->vGateHands, p->GateBuffer, p->GateInvert, &p->vGateFuncs ); Sfm_DecInsert( pNtk, pObj, Limit, &p->vObjGates, &p->vObjFanins, &p->vObjMap, &p->vGateHands, p->GateBuffer, p->GateInvert, &p->vGateFuncs, NULL );
} }
}
void Abc_NtkDelayOpt( Sfm_Dec_t * p )
{
Abc_Ntk_t * pNtk = p->pNtk;
Sfm_Par_t * pPars = p->pPars;
printf( "Initial delay = %8.2f.\n", MIO_NUMINV*Sfm_TimReadNtkDelay(p->pTim) );
while ( 1 )
{
Abc_Obj_t * pObj; abctime clk;
int i = 0, Limit, RetValue;
// try improving delay for the nodes according to the priority
if ( !Sfm_TimPriorityNodes(p->pTim, &p->vCands) )
break;
Abc_NtkForEachObjVec( &p->vCands, p->pNtk, pObj, i )
{
p->nNodesTried++;
clk = Abc_Clock();
p->nDivs = Sfm_DecExtract( pNtk, pPars, pObj, &p->vObjRoots, &p->vObjGates, &p->vObjFanins, &p->vObjMap, &p->vTemp, &p->vTemp2, &p->vObjMffc, &p->vObjInMffc, p->pTim );
p->timeWin += Abc_Clock() - clk;
if ( p->nDivs < 2 || (pPars->nWinSizeMax && pPars->nWinSizeMax < Vec_IntSize(&p->vObjGates)) )
{
assert( pObj->fMarkA == 0 );
pObj->fMarkA = 1;
continue;
}
p->nMffc = Vec_IntSize(&p->vObjMffc);
p->AreaMffc = Sfm_DecMffcArea(pNtk, &p->vObjMffc);
p->nMaxDivs = Abc_MaxInt( p->nMaxDivs, p->nDivs );
p->nAllDivs += p->nDivs;
p->iTarget = pObj->iTemp;
Limit = Vec_IntSize( &p->vObjGates );
p->nMaxWin = Abc_MaxInt( p->nMaxWin, Limit );
p->nAllWin += Limit;
clk = Abc_Clock();
RetValue = Sfm_DecPrepareSolver( p );
p->timeCnf += Abc_Clock() - clk;
if ( !RetValue )
{
assert( pObj->fMarkA == 0 );
pObj->fMarkA = 1;
continue;
}
clk = Abc_Clock();
RetValue = Sfm_DecPeformDec3( p, pObj );
if ( p->pPars->fVeryVerbose )
printf( "\n\n" );
p->timeSat += Abc_Clock() - clk;
if ( RetValue < 0 )
{
assert( pObj->fMarkA == 0 );
pObj->fMarkA = 1;
continue;
}
assert( Vec_IntSize(&p->vObjGates) - Limit > 0 );
assert( Vec_IntSize(&p->vObjGates) - Limit <= 2 );
p->nNodesChanged++;
Abc_NtkCountStats( p, Limit );
Sfm_DecInsert( pNtk, pObj, Limit, &p->vObjGates, &p->vObjFanins, &p->vObjMap, &p->vGateHands, p->GateBuffer, p->GateInvert, &p->vGateFuncs, &p->vCands );
Sfm_TimUpdateTiming( p->pTim, &p->vCands );
printf( "Node %5d delay = %8.2f.\n", Abc_ObjId(pObj), MIO_NUMINV*Sfm_TimReadNtkDelay(p->pTim) );
break;
}
}
}
void Abc_NtkPerformMfs3( Abc_Ntk_t * pNtk, Sfm_Par_t * pPars )
{
Sfm_Dec_t * p = Sfm_DecStart( pPars, (Mio_Library_t *)pNtk->pManFunc, pNtk );
if ( pPars->fVerbose ) if ( pPars->fVerbose )
p->nTotalNodesEnd = Abc_NtkNodeNum(pNtk); {
if ( pPars->fVerbose ) printf( "Remapping parameters: " );
p->nTotalEdgesEnd = Abc_NtkGetTotalFanins(pNtk); if ( pPars->nTfoLevMax )
printf( "TFO = %d. ", pPars->nTfoLevMax );
if ( pPars->nTfiLevMax )
printf( "TFI = %d. ", pPars->nTfiLevMax );
if ( pPars->nFanoutMax )
printf( "FanMax = %d. ", pPars->nFanoutMax );
if ( pPars->nWinSizeMax )
printf( "WinMax = %d. ", pPars->nWinSizeMax );
if ( pPars->nBTLimit )
printf( "Confl = %d. ", pPars->nBTLimit );
if ( pPars->nMffcMin )
printf( "MffcMin = %d. ", pPars->nMffcMin );
if ( pPars->nMffcMax )
printf( "MffcMax = %d. ", pPars->nMffcMax );
if ( pPars->nDecMax )
printf( "DecMax = %d. ", pPars->nDecMax );
if ( pPars->iNodeOne )
printf( "Pivot = %d. ", pPars->iNodeOne );
printf( "Sim = %s. ", pPars->fUseSim ? "yes" : "no" );
printf( "0-cost = %s. ", pPars->fZeroCost ? "yes" : "no" );
printf( "\n" );
}
// preparation steps
Abc_NtkLevel( pNtk );
Abc_NtkCleanMarkABC( pNtk );
if ( p->pPars->fUseSim )
Sfm_NtkSimulate( pNtk );
// record statistics
if ( pPars->fVerbose ) p->nTotalNodesBeg = Abc_NtkNodeNum(pNtk);
if ( pPars->fVerbose ) p->nTotalEdgesBeg = Abc_NtkGetTotalFanins(pNtk);
// perform optimization
if ( pPars->fArea )
Abc_NtkAreaOpt( p );
else
Abc_NtkDelayOpt( p );
// record statistics
if ( pPars->fVerbose ) p->nTotalNodesEnd = Abc_NtkNodeNum(pNtk);
if ( pPars->fVerbose ) p->nTotalEdgesEnd = Abc_NtkGetTotalFanins(pNtk);
// print stats and quit
if ( pPars->fVerbose ) if ( pPars->fVerbose )
Sfm_DecPrintStats( p ); Sfm_DecPrintStats( p );
Sfm_DecStop( p ); Sfm_DecStop( p );
pNtk->pData = NULL;
} }
//////////////////////////////////////////////////////////////////////// ////////////////////////////////////////////////////////////////////////
......
...@@ -33,6 +33,11 @@ ...@@ -33,6 +33,11 @@
#include "misc/vec/vec.h" #include "misc/vec/vec.h"
#include "sat/bsat/satSolver.h" #include "sat/bsat/satSolver.h"
#include "misc/util/utilNam.h"
#include "map/scl/sclCon.h"
#include "misc/st/st.h"
#include "map/mio/mio.h"
#include "base/abc/abc.h"
#include "sfm.h" #include "sfm.h"
//////////////////////////////////////////////////////////////////////// ////////////////////////////////////////////////////////////////////////
...@@ -56,6 +61,7 @@ ABC_NAMESPACE_HEADER_START ...@@ -56,6 +61,7 @@ ABC_NAMESPACE_HEADER_START
typedef struct Sfm_Fun_t_ Sfm_Fun_t; typedef struct Sfm_Fun_t_ Sfm_Fun_t;
typedef struct Sfm_Lib_t_ Sfm_Lib_t; typedef struct Sfm_Lib_t_ Sfm_Lib_t;
typedef struct Sfm_Tim_t_ Sfm_Tim_t;
struct Sfm_Ntk_t_ struct Sfm_Ntk_t_
{ {
...@@ -195,6 +201,8 @@ extern int Sfm_LibFindComplInputGate( Vec_Wrd_t * vFuncs, int iGate, in ...@@ -195,6 +201,8 @@ extern int Sfm_LibFindComplInputGate( Vec_Wrd_t * vFuncs, int iGate, in
extern Sfm_Lib_t * Sfm_LibPrepare( int nVars, int fTwo, int fDelay, int fVerbose ); extern Sfm_Lib_t * Sfm_LibPrepare( int nVars, int fTwo, int fDelay, int fVerbose );
extern void Sfm_LibPrint( Sfm_Lib_t * p ); extern void Sfm_LibPrint( Sfm_Lib_t * p );
extern void Sfm_LibStop( Sfm_Lib_t * p ); extern void Sfm_LibStop( Sfm_Lib_t * p );
extern int Sfm_LibFindMatches( Sfm_Lib_t * p, word uTruth, int * pFanins, int nFanins, Vec_Ptr_t * vGates, Vec_Ptr_t * vFans );
extern int Sfm_LibAddNewGates( Sfm_Lib_t * p, int * pFanins, Mio_Gate_t * pGateB, Mio_Gate_t * pGateT, char * pFansB, char * pFansT, Vec_Int_t * vGates, Vec_Wec_t * vFanins );
extern int Sfm_LibImplement( Sfm_Lib_t * p, word uTruth, int * pFanins, int nFanins, int AreaMffc, Vec_Int_t * vGates, Vec_Wec_t * vFanins, int fZeroCost ); extern int Sfm_LibImplement( Sfm_Lib_t * p, word uTruth, int * pFanins, int nFanins, int AreaMffc, Vec_Int_t * vGates, Vec_Wec_t * vFanins, int fZeroCost );
/*=== sfmNtk.c ==========================================================*/ /*=== sfmNtk.c ==========================================================*/
extern Sfm_Ntk_t * Sfm_ConstructNetwork( Vec_Wec_t * vFanins, int nPis, int nPos ); extern Sfm_Ntk_t * Sfm_ConstructNetwork( Vec_Wec_t * vFanins, int nPis, int nPos );
...@@ -203,6 +211,16 @@ extern void Sfm_NtkUpdate( Sfm_Ntk_t * p, int iNode, int f, int iFaninNe ...@@ -203,6 +211,16 @@ extern void Sfm_NtkUpdate( Sfm_Ntk_t * p, int iNode, int f, int iFaninNe
/*=== sfmSat.c ==========================================================*/ /*=== sfmSat.c ==========================================================*/
extern int Sfm_NtkWindowToSolver( Sfm_Ntk_t * p ); extern int Sfm_NtkWindowToSolver( Sfm_Ntk_t * p );
extern word Sfm_ComputeInterpolant( Sfm_Ntk_t * p ); extern word Sfm_ComputeInterpolant( Sfm_Ntk_t * p );
/*=== sfmTime.c ==========================================================*/
extern Sfm_Tim_t * Sfm_TimStart( Mio_Library_t * pLib, Scl_Con_t * pExt, Abc_Ntk_t * pNtk );
extern void Sfm_TimStop( Sfm_Tim_t * p );
extern int Sfm_TimReadNtkDelay( Sfm_Tim_t * p );
extern int Sfm_TimReadObjDelay( Sfm_Tim_t * p, int iObj );
extern void Sfm_TimUpdateTiming( Sfm_Tim_t * p, Vec_Int_t * vTimeNodes );
extern int Sfm_TimSortArrayByArrival( Sfm_Tim_t * p, Vec_Int_t * vNodes, int iPivot );
extern int Sfm_TimPriorityNodes( Sfm_Tim_t * p, Vec_Int_t * vCands );
extern int Sfm_TimNodeIsNonCritical( Sfm_Tim_t * p, Abc_Obj_t * pPivot, Abc_Obj_t * pNode );
extern int Sfm_TimEvalRemapping( Sfm_Tim_t * p, Vec_Int_t * vFanins, Mio_Gate_t * pGate1, char * pFans1, Mio_Gate_t * pGate2, char * pFans2 );
/*=== sfmWin.c ==========================================================*/ /*=== sfmWin.c ==========================================================*/
extern int Sfm_ObjMffcSize( Sfm_Ntk_t * p, int iObj ); extern int Sfm_ObjMffcSize( Sfm_Ntk_t * p, int iObj );
extern int Sfm_NtkCreateWindow( Sfm_Ntk_t * p, int iNode, int fVerbose ); extern int Sfm_NtkCreateWindow( Sfm_Ntk_t * p, int iNode, int fVerbose );
......
...@@ -548,6 +548,64 @@ void Sfm_LibTest() ...@@ -548,6 +548,64 @@ void Sfm_LibTest()
SeeAlso [] SeeAlso []
***********************************************************************/ ***********************************************************************/
int Sfm_LibFindMatches( Sfm_Lib_t * p, word uTruth, int * pFanins, int nFanins, Vec_Ptr_t * vGates, Vec_Ptr_t * vFans )
{
Mio_Cell2_t * pCellB, * pCellT;
Sfm_Fun_t * pObj;
int iFunc;
Vec_PtrClear( vGates );
Vec_PtrClear( vFans );
// look for gate
assert( uTruth != 0 && uTruth != ~(word)0 && uTruth != s_Truths6[0] && uTruth != ~s_Truths6[0] );
iFunc = *Vec_MemHashLookup( p->vTtMem, &uTruth );
if ( iFunc == -1 )
return 0;
// collect matches
Sfm_LibForEachSuper( p, pObj, iFunc )
{
pCellB = p->pCells + (int)pObj->pFansB[0];
pCellT = p->pCells + (int)pObj->pFansT[0];
Vec_PtrPush( vGates, pCellB );
Vec_PtrPush( vGates, pCellT == p->pCells ? NULL : pCellT );
Vec_PtrPush( vFans, pObj->pFansB + 1 );
Vec_PtrPush( vFans, pCellT == p->pCells ? NULL : pObj->pFansT + 1 );
}
return Vec_PtrSize(vGates) / 2;
}
/**Function*************************************************************
Synopsis []
Description []
SideEffects []
SeeAlso []
***********************************************************************/
int Sfm_LibAddNewGates( Sfm_Lib_t * p, int * pFanins, Mio_Gate_t * pGateB, Mio_Gate_t * pGateT, char * pFansB, char * pFansT, Vec_Int_t * vGates, Vec_Wec_t * vFanins )
{
Vec_Int_t * vLevel;
int i, nFanins;
// create bottom gate
Vec_IntPush( vGates, Mio_GateReadValue(pGateB) );
vLevel = Vec_WecPushLevel( vFanins );
nFanins = Mio_GateReadPinNum( pGateB );
for ( i = 0; i < nFanins; i++ )
Vec_IntPush( vLevel, pFanins[(int)pFansB[i]] );
if ( pGateT == NULL )
return 1;
// create top gate
Vec_IntPush( vGates, Mio_GateReadValue(pGateT) );
vLevel = Vec_WecPushLevel( vFanins );
for ( i = 0; i < nFanins; i++ )
if ( pFansT[i] == (char)16 )
Vec_IntPush( vLevel, Vec_WecSize(vFanins)-2 );
else
Vec_IntPush( vLevel, pFanins[(int)pFansT[i]] );
return 2;
}
int Sfm_LibImplement( Sfm_Lib_t * p, word uTruth, int * pFanins, int nFanins, int AreaMffc, Vec_Int_t * vGates, Vec_Wec_t * vFanins, int fZeroCost ) int Sfm_LibImplement( Sfm_Lib_t * p, word uTruth, int * pFanins, int nFanins, int AreaMffc, Vec_Int_t * vGates, Vec_Wec_t * vFanins, int fZeroCost )
{ {
Mio_Library_t * pLib = (Mio_Library_t *)Abc_FrameReadLibGen(); Mio_Library_t * pLib = (Mio_Library_t *)Abc_FrameReadLibGen();
...@@ -587,6 +645,7 @@ int Sfm_LibImplement( Sfm_Lib_t * p, word uTruth, int * pFanins, int nFanins, in ...@@ -587,6 +645,7 @@ int Sfm_LibImplement( Sfm_Lib_t * p, word uTruth, int * pFanins, int nFanins, in
pCellT = p->pCells + (int)pObjMin->pFansT[0]; pCellT = p->pCells + (int)pObjMin->pFansT[0];
// create bottom gate // create bottom gate
pGate = Mio_LibraryReadGateByName( pLib, pCellB->pName, NULL ); pGate = Mio_LibraryReadGateByName( pLib, pCellB->pName, NULL );
assert( pGate == pCellB->pMioGate );
Vec_IntPush( vGates, Mio_GateReadValue(pGate) ); Vec_IntPush( vGates, Mio_GateReadValue(pGate) );
vLevel = Vec_WecPushLevel( vFanins ); vLevel = Vec_WecPushLevel( vFanins );
for ( i = 0; i < (int)pCellB->nFanins; i++ ) for ( i = 0; i < (int)pCellB->nFanins; i++ )
...@@ -595,6 +654,7 @@ int Sfm_LibImplement( Sfm_Lib_t * p, word uTruth, int * pFanins, int nFanins, in ...@@ -595,6 +654,7 @@ int Sfm_LibImplement( Sfm_Lib_t * p, word uTruth, int * pFanins, int nFanins, in
return 1; return 1;
// create top gate // create top gate
pGate = Mio_LibraryReadGateByName( pLib, pCellT->pName, NULL ); pGate = Mio_LibraryReadGateByName( pLib, pCellT->pName, NULL );
assert( pGate == pCellT->pMioGate );
Vec_IntPush( vGates, Mio_GateReadValue(pGate) ); Vec_IntPush( vGates, Mio_GateReadValue(pGate) );
vLevel = Vec_WecPushLevel( vFanins ); vLevel = Vec_WecPushLevel( vFanins );
for ( i = 0; i < (int)pCellT->nFanins; i++ ) for ( i = 0; i < (int)pCellT->nFanins; i++ )
......
...@@ -19,11 +19,6 @@ ...@@ -19,11 +19,6 @@
***********************************************************************/ ***********************************************************************/
#include "sfmInt.h" #include "sfmInt.h"
#include "misc/st/st.h"
#include "map/mio/mio.h"
#include "base/abc/abc.h"
#include "misc/util/utilNam.h"
#include "map/scl/sclCon.h"
ABC_NAMESPACE_IMPL_START ABC_NAMESPACE_IMPL_START
...@@ -32,7 +27,6 @@ ABC_NAMESPACE_IMPL_START ...@@ -32,7 +27,6 @@ ABC_NAMESPACE_IMPL_START
/// DECLARATIONS /// /// DECLARATIONS ///
//////////////////////////////////////////////////////////////////////// ////////////////////////////////////////////////////////////////////////
typedef struct Sfm_Tim_t_ Sfm_Tim_t;
struct Sfm_Tim_t_ struct Sfm_Tim_t_
{ {
// external // external
...@@ -40,6 +34,7 @@ struct Sfm_Tim_t_ ...@@ -40,6 +34,7 @@ struct Sfm_Tim_t_
Scl_Con_t * pExt; // external timing Scl_Con_t * pExt; // external timing
Abc_Ntk_t * pNtk; // mapped network Abc_Ntk_t * pNtk; // mapped network
int Delay; // the largest delay int Delay; // the largest delay
int CritDelta; // critical delay delta
// timing info // timing info
Vec_Int_t vTimArrs; // arrivals (rise/fall) Vec_Int_t vTimArrs; // arrivals (rise/fall)
Vec_Int_t vTimReqs; // required (rise/fall) Vec_Int_t vTimReqs; // required (rise/fall)
...@@ -48,15 +43,25 @@ struct Sfm_Tim_t_ ...@@ -48,15 +43,25 @@ struct Sfm_Tim_t_
// timing edges // timing edges
Vec_Int_t vObjOffs; // object offsets Vec_Int_t vObjOffs; // object offsets
Vec_Int_t vTimEdges; // edge timings (rise/fall) Vec_Int_t vTimEdges; // edge timings (rise/fall)
// incremental timing
Vec_Wec_t vLevels; // levels
// critical path // critical path
Vec_Int_t vPath; // critical path Vec_Int_t vPath; // critical path
Vec_Wrd_t vSortData; // node priority order
}; };
static inline int * Sfm_TimArrId( Sfm_Tim_t * p, int Id ) { return Vec_IntEntryP( &p->vTimArrs, Abc_Var2Lit(Id, 0) ); }
static inline int * Sfm_TimReqId( Sfm_Tim_t * p, int Id ) { return Vec_IntEntryP( &p->vTimReqs, Abc_Var2Lit(Id, 0) ); }
static inline int * Sfm_TimSlewId( Sfm_Tim_t * p, int Id ) { return Vec_IntEntryP( &p->vTimSlews, Abc_Var2Lit(Id, 0) ); }
static inline int * Sfm_TimLoadId( Sfm_Tim_t * p, int Id ) { return Vec_IntEntryP( &p->vTimLoads, Abc_Var2Lit(Id, 0) ); }
static inline int * Sfm_TimArr( Sfm_Tim_t * p, Abc_Obj_t * pNode ) { return Vec_IntEntryP( &p->vTimArrs, Abc_Var2Lit(Abc_ObjId(pNode), 0) ); } static inline int * Sfm_TimArr( Sfm_Tim_t * p, Abc_Obj_t * pNode ) { return Vec_IntEntryP( &p->vTimArrs, Abc_Var2Lit(Abc_ObjId(pNode), 0) ); }
static inline int * Sfm_TimReq( Sfm_Tim_t * p, Abc_Obj_t * pNode ) { return Vec_IntEntryP( &p->vTimReqs, Abc_Var2Lit(Abc_ObjId(pNode), 0) ); } static inline int * Sfm_TimReq( Sfm_Tim_t * p, Abc_Obj_t * pNode ) { return Vec_IntEntryP( &p->vTimReqs, Abc_Var2Lit(Abc_ObjId(pNode), 0) ); }
static inline int * Sfm_TimSlew( Sfm_Tim_t * p, Abc_Obj_t * pNode ) { return Vec_IntEntryP( &p->vTimSlews, Abc_Var2Lit(Abc_ObjId(pNode), 0) ); } static inline int * Sfm_TimSlew( Sfm_Tim_t * p, Abc_Obj_t * pNode ) { return Vec_IntEntryP( &p->vTimSlews, Abc_Var2Lit(Abc_ObjId(pNode), 0) ); }
static inline int * Sfm_TimLoad( Sfm_Tim_t * p, Abc_Obj_t * pNode ) { return Vec_IntEntryP( &p->vTimLoads, Abc_Var2Lit(Abc_ObjId(pNode), 0) ); } static inline int * Sfm_TimLoad( Sfm_Tim_t * p, Abc_Obj_t * pNode ) { return Vec_IntEntryP( &p->vTimLoads, Abc_Var2Lit(Abc_ObjId(pNode), 0) ); }
static inline int Sfm_TimArrMaxId( Sfm_Tim_t * p, int Id ) { int * a = Sfm_TimArrId(p, Id); return Abc_MaxInt(a[0], a[1]); }
static inline int Sfm_TimArrMax( Sfm_Tim_t * p, Abc_Obj_t * pNode ) { int * a = Sfm_TimArr(p, pNode); return Abc_MaxInt(a[0], a[1]); } static inline int Sfm_TimArrMax( Sfm_Tim_t * p, Abc_Obj_t * pNode ) { int * a = Sfm_TimArr(p, pNode); return Abc_MaxInt(a[0], a[1]); }
static inline void Sfm_TimSetReq( Sfm_Tim_t * p, Abc_Obj_t * pNode, int t ) { int * r = Sfm_TimReq(p, pNode); r[0] = r[1] = t; } static inline void Sfm_TimSetReq( Sfm_Tim_t * p, Abc_Obj_t * pNode, int t ) { int * r = Sfm_TimReq(p, pNode); r[0] = r[1] = t; }
static inline int Sfm_TimSlack( Sfm_Tim_t * p, Abc_Obj_t * pNode ) { int * r = Sfm_TimReq(p, pNode), * a = Sfm_TimArr(p, pNode); return Abc_MinInt(r[0]-a[0], r[1]-a[1]); } static inline int Sfm_TimSlack( Sfm_Tim_t * p, Abc_Obj_t * pNode ) { int * r = Sfm_TimReq(p, pNode), * a = Sfm_TimArr(p, pNode); return Abc_MinInt(r[0]-a[0], r[1]-a[1]); }
...@@ -76,13 +81,11 @@ static inline int Sfm_TimSlack( Sfm_Tim_t * p, Abc_Obj_t * pNode ) { i ...@@ -76,13 +81,11 @@ static inline int Sfm_TimSlack( Sfm_Tim_t * p, Abc_Obj_t * pNode ) { i
SeeAlso [] SeeAlso []
***********************************************************************/ ***********************************************************************/
void Sfm_TimEdgeArrival( Sfm_Tim_t * p, Abc_Obj_t * pNode, int iEdge, Mio_Pin_t * pPin ) static inline void Sfm_TimEdgeArrival( Sfm_Tim_t * p, Mio_Pin_t * pPin, int * pTimeIn, int * pTimeOut )
{ {
Mio_PinPhase_t PinPhase = Mio_PinReadPhase(pPin); Mio_PinPhase_t PinPhase = Mio_PinReadPhase(pPin);
int tDelayBlockRise = (int)(MIO_NUM*Mio_PinReadDelayBlockRise(pPin)); int tDelayBlockRise = (int)(MIO_NUM*Mio_PinReadDelayBlockRise(pPin));
int tDelayBlockFall = (int)(MIO_NUM*Mio_PinReadDelayBlockFall(pPin)); int tDelayBlockFall = (int)(MIO_NUM*Mio_PinReadDelayBlockFall(pPin));
int * pTimeOut = Sfm_TimArr(p, pNode);
int * pTimeIn = Sfm_TimArr(p, Abc_ObjFanin(pNode, iEdge));
if ( PinPhase != MIO_PHASE_INV ) // NONINV phase is present if ( PinPhase != MIO_PHASE_INV ) // NONINV phase is present
{ {
pTimeOut[0] = Abc_MaxInt( pTimeOut[0], pTimeIn[0] + tDelayBlockRise ); pTimeOut[0] = Abc_MaxInt( pTimeOut[0], pTimeIn[0] + tDelayBlockRise );
...@@ -94,22 +97,29 @@ void Sfm_TimEdgeArrival( Sfm_Tim_t * p, Abc_Obj_t * pNode, int iEdge, Mio_Pin_t ...@@ -94,22 +97,29 @@ void Sfm_TimEdgeArrival( Sfm_Tim_t * p, Abc_Obj_t * pNode, int iEdge, Mio_Pin_t
pTimeOut[1] = Abc_MaxInt( pTimeOut[1], pTimeIn[0] + tDelayBlockFall ); pTimeOut[1] = Abc_MaxInt( pTimeOut[1], pTimeIn[0] + tDelayBlockFall );
} }
} }
void Sfm_TimGateArrival( Sfm_Tim_t * p, Abc_Obj_t * pNode ) static inline void Sfm_TimGateArrival( Sfm_Tim_t * p, Mio_Gate_t * pGate, int ** pTimesIn, int * pTimeOut )
{ {
Mio_Gate_t * pGate = (Mio_Gate_t *)pNode->pData;
Mio_Pin_t * pPin; int i = 0; Mio_Pin_t * pPin; int i = 0;
pTimeOut[0] = pTimeOut[1] = 0;
Mio_GateForEachPin( pGate, pPin ) Mio_GateForEachPin( pGate, pPin )
Sfm_TimEdgeArrival( p, pNode, i++, pPin ); Sfm_TimEdgeArrival( p, pPin, pTimesIn[i++], pTimeOut );
assert( i == Mio_GateReadPinNum(pGate) ); assert( i == Mio_GateReadPinNum(pGate) );
} }
static inline void Sfm_TimNodeArrival( Sfm_Tim_t * p, Abc_Obj_t * pNode )
{
int i, iFanin, * pTimesIn[6];
int * pTimeOut = Sfm_TimArr(p, pNode);
assert( Abc_ObjFaninNum(pNode) <= 6 );
Abc_ObjForEachFaninId( pNode, iFanin, i )
pTimesIn[i] = Sfm_TimArrId( p, iFanin );
Sfm_TimGateArrival( p, (Mio_Gate_t *)pNode->pData, pTimesIn, pTimeOut );
}
void Sfm_TimEdgeRequired( Sfm_Tim_t * p, Abc_Obj_t * pNode, int iEdge, Mio_Pin_t * pPin ) static inline void Sfm_TimEdgeRequired( Sfm_Tim_t * p, Mio_Pin_t * pPin, int * pTimeIn, int * pTimeOut )
{ {
Mio_PinPhase_t PinPhase = Mio_PinReadPhase(pPin); Mio_PinPhase_t PinPhase = Mio_PinReadPhase(pPin);
int tDelayBlockRise = (int)(MIO_NUM*Mio_PinReadDelayBlockRise(pPin)); int tDelayBlockRise = (int)(MIO_NUM*Mio_PinReadDelayBlockRise(pPin));
int tDelayBlockFall = (int)(MIO_NUM*Mio_PinReadDelayBlockFall(pPin)); int tDelayBlockFall = (int)(MIO_NUM*Mio_PinReadDelayBlockFall(pPin));
int * pTimeOut = Sfm_TimReq(p, pNode);
int * pTimeIn = Sfm_TimReq(p, Abc_ObjFanin(pNode, iEdge));
if ( PinPhase != MIO_PHASE_INV ) // NONINV phase is present if ( PinPhase != MIO_PHASE_INV ) // NONINV phase is present
{ {
pTimeIn[0] = Abc_MinInt( pTimeIn[0], pTimeOut[0] - tDelayBlockRise ); pTimeIn[0] = Abc_MinInt( pTimeIn[0], pTimeOut[0] - tDelayBlockRise );
...@@ -121,14 +131,22 @@ void Sfm_TimEdgeRequired( Sfm_Tim_t * p, Abc_Obj_t * pNode, int iEdge, Mio_Pin_t ...@@ -121,14 +131,22 @@ void Sfm_TimEdgeRequired( Sfm_Tim_t * p, Abc_Obj_t * pNode, int iEdge, Mio_Pin_t
pTimeIn[1] = Abc_MinInt( pTimeIn[1], pTimeOut[0] - tDelayBlockFall ); pTimeIn[1] = Abc_MinInt( pTimeIn[1], pTimeOut[0] - tDelayBlockFall );
} }
} }
void Sfm_TimGateRequired( Sfm_Tim_t * p, Abc_Obj_t * pNode ) static inline void Sfm_TimGateRequired( Sfm_Tim_t * p, Mio_Gate_t * pGate, int ** pTimesIn, int * pTimeOut )
{ {
Mio_Gate_t * pGate = (Mio_Gate_t *)pNode->pData;
Mio_Pin_t * pPin; int i = 0; Mio_Pin_t * pPin; int i = 0;
Mio_GateForEachPin( pGate, pPin ) Mio_GateForEachPin( pGate, pPin )
Sfm_TimEdgeRequired( p, pNode, i++, pPin ); Sfm_TimEdgeRequired( p, pPin, pTimesIn[i++], pTimeOut );
assert( i == Mio_GateReadPinNum(pGate) ); assert( i == Mio_GateReadPinNum(pGate) );
} }
void Sfm_TimNodeRequired( Sfm_Tim_t * p, Abc_Obj_t * pNode )
{
int i, iFanin, * pTimesIn[6];
int * pTimeOut = Sfm_TimReq(p, pNode);
assert( Abc_ObjFaninNum(pNode) <= 6 );
Abc_ObjForEachFaninId( pNode, iFanin, i )
pTimesIn[i] = Sfm_TimReqId( p, iFanin );
Sfm_TimGateRequired( p, (Mio_Gate_t *)pNode->pData, pTimesIn, pTimeOut );
}
/**Function************************************************************* /**Function*************************************************************
...@@ -194,13 +212,14 @@ int Sfm_TimTrace( Sfm_Tim_t * p ) ...@@ -194,13 +212,14 @@ int Sfm_TimTrace( Sfm_Tim_t * p )
Abc_Obj_t * pObj; int i, Delay = 0; Abc_Obj_t * pObj; int i, Delay = 0;
Vec_Ptr_t * vNodes = Abc_NtkDfs( p->pNtk, 1 ); Vec_Ptr_t * vNodes = Abc_NtkDfs( p->pNtk, 1 );
Vec_PtrForEachEntry( Abc_Obj_t *, vNodes, pObj, i ) Vec_PtrForEachEntry( Abc_Obj_t *, vNodes, pObj, i )
Sfm_TimGateArrival( p, pObj ); Sfm_TimNodeArrival( p, pObj );
Abc_NtkForEachCo( p->pNtk, pObj, i ) Abc_NtkForEachCo( p->pNtk, pObj, i )
Delay = Abc_MaxInt( Delay, Sfm_TimArrMax(p, Abc_ObjFanin0(pObj)) ); Delay = Abc_MaxInt( Delay, Sfm_TimArrMax(p, Abc_ObjFanin0(pObj)) );
Vec_IntFill( &p->vTimReqs, 2*Abc_NtkObjNumMax(p->pNtk), ABC_INFINITY );
Abc_NtkForEachCo( p->pNtk, pObj, i ) Abc_NtkForEachCo( p->pNtk, pObj, i )
Sfm_TimSetReq( p, Abc_ObjFanin0(pObj), Delay ); Sfm_TimSetReq( p, Abc_ObjFanin0(pObj), Delay );
Vec_PtrForEachEntryReverse( Abc_Obj_t *, vNodes, pObj, i ) Vec_PtrForEachEntryReverse( Abc_Obj_t *, vNodes, pObj, i )
Sfm_TimGateRequired( p, pObj ); Sfm_TimNodeRequired( p, pObj );
Vec_PtrFree( vNodes ); Vec_PtrFree( vNodes );
return Delay; return Delay;
} }
...@@ -233,6 +252,8 @@ Sfm_Tim_t * Sfm_TimStart( Mio_Library_t * pLib, Scl_Con_t * pExt, Abc_Ntk_t * pN ...@@ -233,6 +252,8 @@ Sfm_Tim_t * Sfm_TimStart( Mio_Library_t * pLib, Scl_Con_t * pExt, Abc_Ntk_t * pN
// Vec_IntWriteEntry( &p->vObjOffs, i, Vec_IntSize(Vec_IntSize(&p->vTimEdges)) ); // Vec_IntWriteEntry( &p->vObjOffs, i, Vec_IntSize(Vec_IntSize(&p->vTimEdges)) );
// Vec_IntFillExtra( &p->vTimEdges, Vec_IntSize(Vec_IntSize(&p->vTimEdges)) + Abc_ObjFaninNum(pObj), 0 ); // Vec_IntFillExtra( &p->vTimEdges, Vec_IntSize(Vec_IntSize(&p->vTimEdges)) + Abc_ObjFaninNum(pObj), 0 );
// } // }
p->Delay = Sfm_TimTrace( p );
p->CritDelta = 3 * (int)(MIO_NUM*Mio_LibraryReadDelayInvMax(pLib));
return p; return p;
} }
void Sfm_TimStop( Sfm_Tim_t * p ) void Sfm_TimStop( Sfm_Tim_t * p )
...@@ -246,6 +267,14 @@ void Sfm_TimStop( Sfm_Tim_t * p ) ...@@ -246,6 +267,14 @@ void Sfm_TimStop( Sfm_Tim_t * p )
Vec_IntErase( &p->vPath ); Vec_IntErase( &p->vPath );
ABC_FREE( p ); ABC_FREE( p );
} }
int Sfm_TimReadNtkDelay( Sfm_Tim_t * p )
{
return p->Delay;
}
int Sfm_TimReadObjDelay( Sfm_Tim_t * p, int iObj )
{
return Sfm_TimArrMaxId(p, iObj);
}
/**Function************************************************************* /**Function*************************************************************
...@@ -262,11 +291,174 @@ void Sfm_TimTest( Abc_Ntk_t * pNtk ) ...@@ -262,11 +291,174 @@ void Sfm_TimTest( Abc_Ntk_t * pNtk )
{ {
Mio_Library_t * pLib = (Mio_Library_t *)pNtk->pManFunc; Mio_Library_t * pLib = (Mio_Library_t *)pNtk->pManFunc;
Sfm_Tim_t * p = Sfm_TimStart( pLib, NULL, pNtk ); Sfm_Tim_t * p = Sfm_TimStart( pLib, NULL, pNtk );
p->Delay = Sfm_TimTrace( p );
printf( "Max delay = %.2f. Path = %d (%d).\n", MIO_NUMINV*p->Delay, Sfm_TimCriticalPath(p, 1), Abc_NtkNodeNum(p->pNtk) ); printf( "Max delay = %.2f. Path = %d (%d).\n", MIO_NUMINV*p->Delay, Sfm_TimCriticalPath(p, 1), Abc_NtkNodeNum(p->pNtk) );
Sfm_TimStop( p ); Sfm_TimStop( p );
} }
/**Function*************************************************************
Synopsis [Levelized structure.]
Description []
SideEffects []
SeeAlso []
***********************************************************************/
static inline void Sfm_TimUpdateClean( Sfm_Tim_t * p )
{
Vec_Int_t * vLevel;
Abc_Obj_t * pObj;
int i, k;
Vec_WecForEachLevel( &p->vLevels, vLevel, i )
{
Abc_NtkForEachObjVec( vLevel, p->pNtk, pObj, k )
{
assert( pObj->fMarkC == 1 );
pObj->fMarkC = 0;
}
Vec_IntClear( vLevel );
}
}
/**Function*************************************************************
Synopsis []
Description []
SideEffects []
SeeAlso []
***********************************************************************/
void Sfm_TimUpdateTiming( Sfm_Tim_t * p, Vec_Int_t * vTimeNodes )
{
assert( Vec_IntSize(vTimeNodes) > 0 && Vec_IntSize(vTimeNodes) <= 2 );
p->Delay = Sfm_TimTrace( p );
}
/**Function*************************************************************
Synopsis [Sort an array of nodes using their max arrival times.]
Description [Returns the number of new divisor nodes.]
SideEffects []
SeeAlso []
***********************************************************************/
int Sfm_TimSortArrayByArrival( Sfm_Tim_t * p, Vec_Int_t * vNodes, int iPivot )
{
word Entry;
int i, Id, nDivNew = -1;
int MaxDelay = Sfm_TimArrMaxId(p, iPivot);
assert( p->CritDelta > 0 );
// collect nodes
Vec_WrdClear( &p->vSortData );
Vec_IntForEachEntry( vNodes, Id, i )
Vec_WrdPush( &p->vSortData, ((word)Id << 32) | Sfm_TimArrMaxId(p, Id) );
// sort nodes by delay
Abc_QuickSort3( Vec_WrdArray(&p->vSortData), Vec_WrdSize(&p->vSortData), 0 );
// collect sorted nodes and find place where divisors end
Vec_IntClear( vNodes );
Vec_WrdForEachEntry( &p->vSortData, Entry, i )
{
Vec_IntPush( vNodes, (int)(Entry >> 32) );
if ( nDivNew == -1 && ((int)Entry) + p->CritDelta > MaxDelay )
nDivNew = i;
}
return nDivNew;
}
/**Function*************************************************************
Synopsis [Priority of nodes to try remapping for delay.]
Description []
SideEffects []
SeeAlso []
***********************************************************************/
int Sfm_TimPriorityNodes( Sfm_Tim_t * p, Vec_Int_t * vCands )
{
Vec_Int_t * vLevel;
Abc_Obj_t * pObj;
int i;
// collect critical path
Sfm_TimCriticalPath(p, 1);
// add nodes to the levelized structure
Sfm_TimUpdateClean( p );
Abc_NtkForEachObjVec( &p->vPath, p->pNtk, pObj, i )
{
assert( pObj->fMarkC == 0 );
pObj->fMarkC = 1;
Vec_WecPush( &p->vLevels, Abc_ObjLevel(pObj), Abc_ObjId(pObj) );
}
// prioritize nodes by expected gain
Vec_WecSort( &p->vLevels, 0 );
Vec_IntClear( vCands );
Vec_WecForEachLevel( &p->vLevels, vLevel, i )
Abc_NtkForEachObjVec( vLevel, p->pNtk, pObj, i )
if ( !pObj->fMarkA )
Vec_IntPush( vCands, Abc_ObjId(pObj) );
return Vec_IntSize(vCands) > 0;
}
/**Function*************************************************************
Synopsis [Returns 1 if node is relatively non-critical compared to the pivot.]
Description []
SideEffects []
SeeAlso []
***********************************************************************/
int Sfm_TimNodeIsNonCritical( Sfm_Tim_t * p, Abc_Obj_t * pPivot, Abc_Obj_t * pNode )
{
return Sfm_TimArrMax(p, pNode) + p->CritDelta <= Sfm_TimArrMax(p, pPivot);
}
/**Function*************************************************************
Synopsis []
Description []
SideEffects []
SeeAlso []
***********************************************************************/
int Sfm_TimEvalRemapping( Sfm_Tim_t * p, Vec_Int_t * vFanins, Mio_Gate_t * pGate1, char * pFans1, Mio_Gate_t * pGate2, char * pFans2 )
{
int TimeOut[2][2];
int * pTimesIn1[6], * pTimesIn2[6];
int i, nFanins1, nFanins2;
// process the first gate
nFanins1 = Mio_GateReadPinNum( pGate1 );
for ( i = 0; i < nFanins1; i++ )
pTimesIn1[i] = Sfm_TimArrId( p, Vec_IntEntry(vFanins, (int)pFans1[i]) );
Sfm_TimGateArrival( p, pGate1, pTimesIn1, TimeOut[0] );
if ( pGate2 == NULL )
return Abc_MaxInt(TimeOut[0][0], TimeOut[0][1]);
// process the second gate
nFanins2 = Mio_GateReadPinNum( pGate2 );
for ( i = 0; i < nFanins2; i++ )
if ( (int)pFans2[i] == 16 )
pTimesIn2[i] = TimeOut[0];
else
pTimesIn2[i] = Sfm_TimArrId( p, Vec_IntEntry(vFanins, (int)pFans2[i]) );
Sfm_TimGateArrival( p, pGate2, pTimesIn2, TimeOut[1] );
return Abc_MaxInt(TimeOut[1][0], TimeOut[1][1]);
}
//////////////////////////////////////////////////////////////////////// ////////////////////////////////////////////////////////////////////////
/// END OF FILE /// /// END OF FILE ///
......
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