diff options
Diffstat (limited to 'src')
-rw-r--r-- | src/aig/gia/giaMan.c | 1 | ||||
-rw-r--r-- | src/aig/gia/giaNf.c | 633 | ||||
-rw-r--r-- | src/aig/gia/giaPf.c | 1353 | ||||
-rw-r--r-- | src/aig/gia/module.make | 1 | ||||
-rw-r--r-- | src/base/abci/abc.c | 12 |
5 files changed, 1476 insertions, 524 deletions
diff --git a/src/aig/gia/giaMan.c b/src/aig/gia/giaMan.c index 7439ba73..bd364456 100644 --- a/src/aig/gia/giaMan.c +++ b/src/aig/gia/giaMan.c @@ -160,6 +160,7 @@ double Gia_ManMemory( Gia_Man_t * p ) Memory += sizeof(int) * Gia_ManCiNum(p); Memory += sizeof(int) * Gia_ManCoNum(p); Memory += sizeof(int) * p->nHTable * (p->pHTable != NULL); + Memory += sizeof(int) * Gia_ManObjNum(p) * (p->pRefs != NULL); return Memory; } diff --git a/src/aig/gia/giaNf.c b/src/aig/gia/giaNf.c index f191dfd7..3dad6fb2 100644 --- a/src/aig/gia/giaNf.c +++ b/src/aig/gia/giaNf.c @@ -40,8 +40,6 @@ ABC_NAMESPACE_IMPL_START #define NF_NO_LEAF 31 #define NF_INFINITY FLT_MAX -enum { NF_ANDOR = 1, NF_XOR = 2, NF_PRIME = 3 }; - typedef struct Nf_Cut_t_ Nf_Cut_t; struct Nf_Cut_t_ { @@ -53,6 +51,13 @@ struct Nf_Cut_t_ unsigned nLeaves : 5; // leaf number (NF_NO_LEAF) int pLeaves[NF_LEAF_MAX+1]; // leaves }; +typedef struct Pf_Mat_t_ Pf_Mat_t; +struct Pf_Mat_t_ +{ + unsigned fCompl : 8; // complemented + unsigned Phase : 6; // match phase + unsigned Perm : 18; // match permutation +}; typedef struct Nf_Mat_t_ Nf_Mat_t; struct Nf_Mat_t_ { @@ -78,7 +83,6 @@ struct Nf_Man_t_ // matching Vec_Mem_t * vTtMem; // truth tables Vec_Wec_t * vTt2Match; // matches for truth tables - Vec_Str_t * vMemStore; // memory for matches Mio_Cell_t * pCells; // library gates int nCells; // library gate count // cut data @@ -104,6 +108,9 @@ struct Nf_Man_t_ int nCutUseAll; // objects with useful cuts }; +static inline int Pf_Mat2Int( Pf_Mat_t Mat ) { union { int x; Pf_Mat_t y; } v; v.y = Mat; return v.x; } +static inline Pf_Mat_t Pf_Int2Mat( int Int ) { union { int x; Pf_Mat_t y; } v; v.x = Int; return v.y; } + static inline Nf_Obj_t * Nf_ManObj( Nf_Man_t * p, int i ) { return p->pNfObjs + i; } static inline Mio_Cell_t* Nf_ManCell( Nf_Man_t * p, int i ) { return p->pCells + i; } static inline int * Nf_ManCutSet( Nf_Man_t * p, int i ) { return (int *)Vec_PtrEntry(&p->vPages, i >> 16) + (i & 0xFFFF); } @@ -154,22 +161,9 @@ static inline int Nf_CutConfVar( int Conf, int i ) static inline int Nf_CutConfC( int Conf, int i ) { return Abc_LitIsCompl( Nf_CutConfLit(Conf, i) ); } #define Nf_SetForEachCut( pList, pCut, i ) for ( i = 0, pCut = pList + 1; i < pList[0]; i++, pCut += Nf_CutSize(pCut) + 1 ) -#define Nf_ObjForEachCut( pCuts, i, nCuts ) for ( i = 0, i < nCuts; i++ ) #define Nf_CutForEachLit( pCut, Conf, iLit, i ) for ( i = 0; i < Nf_CutSize(pCut) && (iLit = Abc_Lit2LitV(Nf_CutLeaves(pCut), Nf_CutConfLit(Conf, i))); i++ ) #define Nf_CutForEachVar( pCut, Conf, iVar, c, i ) for ( i = 0; i < Nf_CutSize(pCut) && (iVar = Nf_CutLeaves(pCut)[Nf_CutConfVar(Conf, i)]) && ((c = Nf_CutConfC(Conf, i)), 1); i++ ) -/* -Three types of config: -<match> : <gate> <compl> <type> <offset> -<type> : AND/OR | XOR | prime -<offset> : <record> -<record> -- XOR : <array> -- prime : <array>, ... <array> -- AND/OR : <num_configs>, <config>, ... <config> -<config> : <num_entries>, <num_neg_entries>, <array> -<array> : <entry>, ...., <entry> (sorted by increasing order of arrivals) -*/ //////////////////////////////////////////////////////////////////////// /// FUNCTION DEFINITIONS /// @@ -186,248 +180,41 @@ Three types of config: SeeAlso [] ***********************************************************************/ -static inline void Nf_StoSelectSort( int * pArray, int nSize, Mio_Cell_t * pCell ) -{ - int i, j, best_i; - for ( i = 0; i < nSize-1; i++ ) - { - best_i = i; - for ( j = i+1; j < nSize; j++ ) - if ( pCell->Delays[Abc_Lit2Var(pArray[j])] < pCell->Delays[Abc_Lit2Var(pArray[best_i])] ) - best_i = j; - if ( i != best_i ) - ABC_SWAP( int, pArray[i], pArray[best_i] ); - } -} -static inline void Nf_StoSelectSortLit( int * pArray, int nSize, Mio_Cell_t * pCell ) -{ - int i, j, best_i; - for ( i = 0; i < nSize-1; i++ ) - { - best_i = i; - for ( j = i+1; j < nSize; j++ ) - if ( Abc_LitIsCompl(pArray[j]) > Abc_LitIsCompl(pArray[best_i]) || - (Abc_LitIsCompl(pArray[j]) == Abc_LitIsCompl(pArray[best_i]) && - pCell->Delays[Abc_Lit2Var(pArray[j])] < pCell->Delays[Abc_Lit2Var(pArray[best_i])]) ) - best_i = j; - if ( i != best_i ) - ABC_SWAP( int, pArray[i], pArray[best_i] ); - } -} -void Nf_StoCreateGateAdd( Nf_Man_t * pMan, word uTruth, int * pFans, int nFans, int CellId, int Type ) +void Nf_StoCreateGateAdd( Nf_Man_t * pMan, word uTruth, int * pFans, int nFans, int CellId ) { + int fUsePinPermutation = 0; // set to 1 to enable pin-permutation (which is good for delay when pin-delays differ) Vec_Int_t * vArray; - int i, fCompl = (int)(uTruth & 1); + Pf_Mat_t Mat = Pf_Int2Mat(0); + int i, GateId, Entry, fCompl = (int)(uTruth & 1); word uFunc = fCompl ? ~uTruth : uTruth; int iFunc = Vec_MemHashInsert( pMan->vTtMem, &uFunc ); if ( iFunc == Vec_WecSize(pMan->vTt2Match) ) Vec_WecPushLevel( pMan->vTt2Match ); vArray = Vec_WecEntry( pMan->vTt2Match, iFunc ); - Vec_IntPush( vArray, (CellId << 8) | (Type << 4) | fCompl ); - Vec_IntPush( vArray, Vec_StrSize(pMan->vMemStore) ); - if ( Type == NF_ANDOR ) - return; + Mat.fCompl = fCompl; + assert( nFans < 7 ); for ( i = 0; i < nFans; i++ ) - Vec_StrPush( pMan->vMemStore, (char)pFans[i] ); -} - -/**Function************************************************************* - - Synopsis [] - - Description [] - - SideEffects [] - - SeeAlso [] - -***********************************************************************/ -int Nf_StoBuildDsdAnd_rec( Nf_Man_t * pMan, Mio_Cell_t * pCell, char * pStr, char ** p, int * pMatches, - int pGroups[NF_LEAF_MAX][NF_LEAF_MAX], int * nGroupSizes, int * pnGroups ) -{ - int fCompl = 0; - if ( **p == '!' ) - (*p)++, fCompl = 1; - if ( **p >= 'a' && **p < 'a' + NF_LEAF_MAX ) // var -// return Abc_Var2Lit( **p - 'a', fCompl ); - return Abc_Var2Lit( **p - 'a', 0 ); - if ( **p == '(' ) // and/or - { - char * q = pStr + pMatches[ *p - pStr ]; - int pFans[NF_LEAF_MAX], nFans = 0; - assert( **p == '(' && *q == ')' ); - for ( (*p)++; *p < q; (*p)++ ) - { - int Value = Nf_StoBuildDsdAnd_rec( pMan, pCell, pStr, p, pMatches, pGroups, nGroupSizes, pnGroups ); - if ( Value == -1 ) - continue; - pFans[nFans++] = Value; - } - // collect - if ( nFans > 0 ) - { - memcpy( pGroups[*pnGroups], pFans, sizeof(int) * nFans ); - nGroupSizes[*pnGroups] = nFans; - (*pnGroups)++; - } - assert( *p == q ); - return -1; - } - assert( 0 ); - return 0; -} -int Nf_StoBuildDsdAnd( Nf_Man_t * pMan, Mio_Cell_t * pCell, char * p ) -{ - int pGroups[NF_LEAF_MAX][NF_LEAF_MAX], pGroups2[NF_LEAF_MAX][NF_LEAF_MAX]; - int nGroupSizes[NF_LEAF_MAX], nGroupInvs[NF_LEAF_MAX], Phases[NF_LEAF_MAX]; - int nGroups = 0, nVars = 0, nConfigs = 1; - int i, k, c, Res, fCompl = 0; - char ** pp = &p; - word uTruth; - assert( *(p+1) != 0 ); - if ( *p == '!' ) - (*pp)++, fCompl = 1; - assert( **pp != '!' ); - Res = Nf_StoBuildDsdAnd_rec( pMan, pCell, p, pp, Dau_DsdComputeMatches(p), pGroups, nGroupSizes, &nGroups ); - assert( Res == -1 ); - assert( *++p == 0 ); - // create groups - for ( i = 0; i < nGroups; i++ ) { - nVars += nGroupSizes[i]; - nConfigs *= (1 << nGroupSizes[i]); + Mat.Perm |= (unsigned)(Abc_Lit2Var(pFans[i]) << (3*i)); + Mat.Phase |= (unsigned)(Abc_LitIsCompl(pFans[i]) << i); } - assert( nVars == (int)pCell->nFanins ); - // iterate through phase assignments - for ( c = 0; c < nConfigs; c++ ) + if ( fUsePinPermutation ) { - int Start = c; - for ( i = nGroups - 1; i >= 0; i-- ) - { - Phases[i] = Start % (1 << nGroupSizes[i]); - Start /= (1 << nGroupSizes[i]); - memcpy( pGroups2[i], pGroups[i], sizeof(int) * nGroupSizes[i] ); -// printf( "%d ", Phases[i] ); - } -// printf( "\n" ); - - // create configuration - uTruth = pCell->uTruth; - for ( i = 0; i < nGroups; i++ ) - { - nGroupInvs[i] = 0; - for ( k = 0; k < nGroupSizes[i]; k++ ) - if ( (Phases[i] >> k) & 1 ) - { - pGroups2[i][k] = Abc_LitNot(pGroups2[i][k]); - uTruth = Abc_Tt6Flip( uTruth, Abc_Lit2Var(pGroups2[i][k]) ); - nGroupInvs[i]++; - } -/* - if ( pCell->nFanins == 4 && nGroups == 1 ) - { - printf( "Group before:\n" ); - for ( k = 0; k < nGroupSizes[i]; k++ ) - printf( "%d %.2f\n", pGroups2[i][k], pCell->Delays[Abc_Lit2Var(pGroups2[i][k])] ); - } -*/ -// Nf_StoSelectSortLit( pGroups2[i], nGroupSizes[i], pCell ); -/* - if ( pCell->nFanins == 4 && nGroups == 1 ) - { - printf( "Group after:\n" ); - for ( k = 0; k < nGroupSizes[i]; k++ ) - printf( "%d %.2f\n", pGroups2[i][k], pCell->Delays[Abc_Lit2Var(pGroups2[i][k])] ); - printf( "\n" ); - } -*/ - } - // save - Nf_StoCreateGateAdd( pMan, uTruth, NULL, -1, pCell->Id, NF_ANDOR ); - Vec_StrPush( pMan->vMemStore, (char)nGroups ); - for ( i = 0; i < nGroups; i++ ) - for ( k = 0; k < nGroupSizes[i]; k++ ) - { - Vec_StrPush( pMan->vMemStore, (char)nGroupSizes[i] ); - Vec_StrPush( pMan->vMemStore, (char)nGroupInvs[i] ); - for ( k = 0; k < nGroupSizes[i]; k++ ) - Vec_StrPush( pMan->vMemStore, (char)pGroups2[i][k] ); - } - } - return Res; -} - -int Nf_StoCheckDsdAnd_rec( char * pStr, char ** p, int * pMatches ) -{ - if ( **p == '!' ) - (*p)++; - if ( **p >= 'a' && **p < 'a' + NF_LEAF_MAX ) // var - return 1; - if ( **p == '(' ) // and/or - { - char * q = pStr + pMatches[ *p - pStr ]; - assert( **p == '(' && *q == ')' ); - for ( (*p)++; *p < q; (*p)++ ) - if ( Nf_StoCheckDsdAnd_rec(pStr, p, pMatches) != 1 ) - return 0; - assert( *p == q ); - return 1; + Vec_IntPush( vArray, CellId ); + Vec_IntPush( vArray, Pf_Mat2Int(Mat) ); + return; } - return 0; -} -int Nf_StoCheckDsdAnd( char * p ) -{ - int Res; - assert( *(p+1) != 0 ); - Res = Nf_StoCheckDsdAnd_rec( p, &p, Dau_DsdComputeMatches(p) ); -// assert( *++p == 0 ); - return Res; -} - -int Nf_StoCheckDsdXor_rec( char * pStr, char ** p, int * pMatches ) -{ - int Value, fCompl = 0; - if ( **p == '!' ) - (*p)++, fCompl ^= 1; - if ( **p >= 'a' && **p < 'a' + NF_LEAF_MAX ) // var - return fCompl; - if ( **p == '[' ) // xor + // check if the same one exists + Vec_IntForEachEntryDouble( vArray, GateId, Entry, i ) + if ( GateId == CellId && Pf_Int2Mat(Entry).Phase == Mat.Phase ) + break; + if ( i == Vec_IntSize(vArray) ) { - char * q = pStr + pMatches[ *p - pStr ]; - assert( **p == '[' && *q == ']' ); - for ( (*p)++; *p < q; (*p)++ ) - { - Value = Nf_StoCheckDsdXor_rec( pStr, p, pMatches ); - if ( Value == -1 ) - return -1; - fCompl ^= Value; - } - assert( *p == q ); - return fCompl; + Vec_IntPush( vArray, CellId ); + Vec_IntPush( vArray, Pf_Mat2Int(Mat) ); } - return -1; } -int Nf_StoCheckDsdXor( char * p ) -{ - int Res; - assert( *(p+1) != 0 ); - Res = Nf_StoCheckDsdXor_rec( p, &p, Dau_DsdComputeMatches(p) ); -// assert( *++p == 0 ); - return Res; -} - -/**Function************************************************************* - - Synopsis [] - - Description [] - - SideEffects [] - - SeeAlso [] - -***********************************************************************/ -void Nf_StoCreateGateNonDsd( Nf_Man_t * pMan, Mio_Cell_t * pCell, int ** pComp, int ** pPerm, int * pnPerms ) +void Nf_StoCreateGateMaches( Nf_Man_t * pMan, Mio_Cell_t * pCell, int ** pComp, int ** pPerm, int * pnPerms ) { int Perm[NF_LEAF_MAX], * Perm1, * Perm2; int nPerms = pnPerms[pCell->nFanins]; @@ -442,7 +229,7 @@ void Nf_StoCreateGateNonDsd( Nf_Man_t * pMan, Mio_Cell_t * pCell, int ** pComp, tTemp2 = tCur; for ( c = 0; c < nMints; c++ ) { - Nf_StoCreateGateAdd( pMan, tCur, Perm, pCell->nFanins, pCell->Id, NF_PRIME ); + Nf_StoCreateGateAdd( pMan, tCur, Perm, pCell->nFanins, pCell->Id ); // update tCur = Abc_Tt6Flip( tCur, pComp[pCell->nFanins][c] ); Perm1 = Perm + pComp[pCell->nFanins][c]; @@ -457,34 +244,6 @@ void Nf_StoCreateGateNonDsd( Nf_Man_t * pMan, Mio_Cell_t * pCell, int ** pComp, } assert( tTemp1 == tCur ); } -void Nf_StoCreateGateDsd( Nf_Man_t * pMan, Mio_Cell_t * pCell, int ** pComp, int ** pPerm, int * pnPerms ) -{ -/* - char pDsd[1000]; - int i, Value, Perm[NF_LEAF_MAX]; - word uTruth = pCell->uTruth; - int nSizeNonDec = Dau_DsdDecompose( &uTruth, pCell->nFanins, 0, 0, pDsd ); - assert( pCell->nFanins > 1 ); - if ( nSizeNonDec == 0 ) - { - if ( Nf_StoCheckDsdAnd(pDsd) ) - { - Nf_StoBuildDsdAnd( pMan, pCell, pDsd ); - return; - } - Value = Nf_StoCheckDsdXor(pDsd); - if ( Value >= 0 ) - { - for ( i = 0; i < (int)pCell->nFanins; i++ ) - Perm[i] = Abc_Var2Lit(i, 0); -// Nf_StoSelectSort( Perm, pCell->nFanins, pCell ); - Nf_StoCreateGateAdd( pMan, pCell->uTruth, Perm, pCell->nFanins, pCell->Id, NF_XOR ); - return; - } - } -*/ - Nf_StoCreateGateNonDsd( pMan, pCell, pComp, pPerm, pnPerms ); -} void Nf_StoDeriveMatches( Nf_Man_t * p, int fVerbose ) { // abctime clk = Abc_Clock(); @@ -499,105 +258,55 @@ void Nf_StoDeriveMatches( Nf_Man_t * p, int fVerbose ) nPerms[i] = Extra_Factorial( i ); p->pCells = Mio_CollectRootsNewDefault( 6, &p->nCells, fVerbose ); for ( i = 4; i < p->nCells; i++ ) - Nf_StoCreateGateDsd( p, p->pCells + i, pComp, pPerm, nPerms ); + Nf_StoCreateGateMaches( p, p->pCells + i, pComp, pPerm, nPerms ); for ( i = 2; i <= 6; i++ ) ABC_FREE( pComp[i] ); for ( i = 2; i <= 6; i++ ) ABC_FREE( pPerm[i] ); // Abc_PrintTime( 1, "Time", Abc_Clock() - clk ); } -void Nf_StoPrintOne( Nf_Man_t * p, int Count, int t, int i, Mio_Cell_t * pC, int Type, int fCompl, char * pInfo ) +void Nf_StoPrintOne( Nf_Man_t * p, int Count, int t, int i, int GateId, Pf_Mat_t Mat ) { + Mio_Cell_t * pC = p->pCells + GateId; word * pTruth = Vec_MemReadEntry(p->vTtMem, t); int k, nSuppSize = Abc_TtSupportSize(pTruth, 6); - printf( "%6d : ", Count++ ); + printf( "%6d : ", Count ); printf( "%6d : ", t ); - printf( "%6d : ", i/2 ); - printf( "Gate %16s ", pC->pName ); - printf( "Inputs = %d ", pC->nFanins ); - if ( Type == NF_PRIME ) - printf( "prime" ); - else if ( Type == NF_XOR ) - printf( "xor " ); - else if ( Type == NF_ANDOR ) - printf( "andor" ); - else assert( 0 ); - if ( fCompl ) + printf( "%6d : ", i ); + printf( "Gate %16s ", pC->pName ); + printf( "Area =%8.2f ", pC->Area ); + printf( "In = %d ", pC->nFanins ); + if ( Mat.fCompl ) printf( " compl " ); else printf( " " ); - if ( Type == NF_PRIME || Type == NF_XOR ) + for ( k = 0; k < (int)pC->nFanins; k++ ) { - for ( k = 0; k < (int)pC->nFanins; k++ ) - { - int fComplF = Abc_LitIsCompl((int)pInfo[k]); - int iFanin = Abc_Lit2Var((int)pInfo[k]); - printf( "%c", 'a' + iFanin - fComplF * ('a' - 'A') ); - } + int fComplF = (Mat.Phase >> k) & 1; + int iFanin = (Mat.Perm >> (3*k)) & 7; + printf( "%c", 'a' + iFanin - fComplF * ('a' - 'A') ); } - else if ( Type == NF_ANDOR ) - { - int g, nGroups = (int)*pInfo++; - for ( g = 0; g < nGroups; g++ ) - { - int nSizeAll = (int)*pInfo++; - int nSizeNeg = (int)*pInfo++; - printf( "{" ); - for ( k = 0; k < nSizeAll; k++ ) - { - int fComplF = Abc_LitIsCompl((int)pInfo[k]); - int iFanin = Abc_Lit2Var((int)pInfo[k]); - printf( "%c", 'a' + iFanin - fComplF * ('a' - 'A') ); - } - printf( "}" ); - pInfo += nSizeAll; nSizeNeg = 0; - } - } - else assert( 0 ); printf( " " ); Dau_DsdPrintFromTruth( pTruth, nSuppSize ); } void Nf_StoPrint( Nf_Man_t * p, int fVerbose ) { - int t, i, Info, Offset, Count = 0, CountMux = 0; + int t, i, GateId, Entry, Count = 0; for ( t = 2; t < Vec_WecSize(p->vTt2Match); t++ ) { Vec_Int_t * vArr = Vec_WecEntry( p->vTt2Match, t ); - Vec_IntForEachEntryDouble( vArr, Info, Offset, i ) + Vec_IntForEachEntryDouble( vArr, GateId, Entry, i ) { - Mio_Cell_t*pC = p->pCells + (Info >> 8); - int Type = (Info >> 4) & 15; - int fCompl = (Info & 1); - char * pInfo = Vec_StrEntryP( p->vMemStore, Offset ); - if ( Type == NF_PRIME && pC->nFanins != 3 ) - { - Count++; - CountMux++; - continue; - } + Count++; if ( !fVerbose ) - { - Count++; continue; - } - Nf_StoPrintOne( p, Count, t, i, pC, Type, fCompl, pInfo ); + //if ( t < 10 ) + // Nf_StoPrintOne( p, Count, t, i/2, GateId, Pf_Int2Mat(Entry) ); } } - printf( "Gates = %d. Truths = %d. Matches = %d. MatchesPrime = %d. Size = %d.\n", - p->nCells, Vec_MemEntryNum(p->vTtMem), Count, CountMux, Vec_StrSize(p->vMemStore) ); -} -/* -void Nf_ManPrepareLibraryTest() -{ - int fVerbose = 0; - abctime clk = Abc_Clock(); - Nf_Man_t * p; - p = Nf_StoCreate( NULL, NULL, fVerbose ); - Nf_StoPrint( p, fVerbose ); - Nf_StoDelete(p); - Abc_PrintTime( 1, "Time", Abc_Clock() - clk ); + printf( "Gates = %d. Truths = %d. Matches = %d.\n", + p->nCells, Vec_MemEntryNum(p->vTtMem), Count ); } -*/ @@ -635,7 +344,7 @@ Nf_Man_t * Nf_StoCreate( Gia_Man_t * pGia, Jf_Par_t * pPars ) Vec_PtrGrow( &p->vPages, 256 ); // cut memory Vec_IntFill( &p->vMapRefs, 2*Gia_ManObjNum(pGia), 0 ); // mapping refs (2x) Vec_FltFill( &p->vFlowRefs, 2*Gia_ManObjNum(pGia), 0 ); // flow refs (2x) - Vec_FltFill( &p->vRequired, 2*Gia_ManObjNum(pGia), NF_INFINITY ); // required times (2x) + Vec_FltFill( &p->vRequired, 2*Gia_ManObjNum(pGia), NF_INFINITY ); // required times (2x) Vec_IntFill( &p->vCutSets, Gia_ManObjNum(pGia), 0 ); // cut offsets Vec_FltFill( &p->vCutFlows, Gia_ManObjNum(pGia), 0 ); // cut area Vec_IntFill( &p->vCutDelays,Gia_ManObjNum(pGia), 0 ); // cut delay @@ -653,7 +362,6 @@ Nf_Man_t * Nf_StoCreate( Gia_Man_t * pGia, Jf_Par_t * pPars ) // matching p->vTtMem = Vec_MemAllocForTT( 6, 0 ); p->vTt2Match = Vec_WecAlloc( 1000 ); - p->vMemStore = Vec_StrAlloc( 10000 ); Vec_WecPushLevel( p->vTt2Match ); Vec_WecPushLevel( p->vTt2Match ); assert( Vec_WecSize(p->vTt2Match) == Vec_MemEntryNum(p->vTtMem) ); @@ -682,7 +390,6 @@ void Nf_StoDelete( Nf_Man_t * p ) Vec_WecFree( p->vTt2Match ); Vec_MemHashFree( p->vTtMem ); Vec_MemFree( p->vTtMem ); - Vec_StrFree( p->vMemStore ); ABC_FREE( p->pCells ); ABC_FREE( p ); } @@ -1262,7 +969,7 @@ void Nf_ManPrintInit( Nf_Man_t * p ) return; printf( "LutSize = %d ", p->pPars->nLutSize ); printf( "CutNum = %d ", p->pPars->nCutNum ); - printf( "Iter = %d ", p->pPars->nRounds + p->pPars->nRoundsEla ); + printf( "Iter = %d ", p->pPars->nRounds );//+ p->pPars->nRoundsEla ); printf( "Coarse = %d ", p->pPars->fCoarsen ); printf( "Cells = %d ", p->nCells ); printf( "Funcs = %d ", Vec_MemEntryNum(p->vTtMem) ); @@ -1386,7 +1093,7 @@ float Nf_MatchRef2Area( Nf_Man_t * p, int i, int c, Nf_Mat_t * pM ) SeeAlso [] ***********************************************************************/ -void Nf_ManCutMatchprintf( Nf_Man_t * p, int iObj, int fCompl, Nf_Mat_t * pM ) +void Nf_ManCutMatchPrint( Nf_Man_t * p, int iObj, int fCompl, Nf_Mat_t * pM ) { Mio_Cell_t * pCell; int i, * pCut; @@ -1475,188 +1182,72 @@ void Nf_ManCutMatchOne( Nf_Man_t * p, int iObj, int * pCut, int * pCutSet ) // consider matches of this function Vec_IntForEachEntryDouble( vArr, Info, Offset, i ) { - Mio_Cell_t* pC = Nf_ManCell( p, Info >> 8 ); - int Type = (Info >> 4) & 15; - int fCompl = (Info & 1) ^ fComplExt; - char * pInfo = Vec_StrEntryP( p->vMemStore, Offset ); + Pf_Mat_t Mat = Pf_Int2Mat(Offset); + Mio_Cell_t* pC = Nf_ManCell( p, Info ); + int fCompl = Mat.fCompl ^ fComplExt; float Required = Nf_ObjRequired( p, iObj, fCompl ); Nf_Mat_t * pD = &pBest->M[fCompl][0]; Nf_Mat_t * pA = &pBest->M[fCompl][1]; + float Area = pC->Area, Delay = 0; assert( nFans == (int)pC->nFanins ); -// if ( iObj == 9 && fCompl == 0 && i == 192 ) -// Nf_StoPrintOne( p, -1, Abc_Lit2Var(iFuncLit), i, pC, Type, fCompl, pInfo ); - if ( Type == NF_PRIME ) + //char * pInfo = Vec_StrEntryP( p->vMemStore, Offset ); +// for ( k = 0; k < nFans; k++ ) +// pInfo[k] = (char)Abc_Var2Lit( (Mat.Perm >> (3*k)) & 7, (Mat.Phase >> k) & 1 ); + for ( k = 0; k < nFans; k++ ) { - float Area = pC->Area, Delay = 0; - for ( k = 0; k < nFans; k++ ) - { - iFanin = Abc_Lit2Var((int)pInfo[k]); - fComplF = Abc_LitIsCompl((int)pInfo[k]); - ArrivalD = pBestF[k]->M[fComplF][0].D; - ArrivalA = pBestF[k]->M[fComplF][1].D; - if ( ArrivalA + pC->Delays[iFanin] < Required + Epsilon && Required != NF_INFINITY ) - { - Delay = Abc_MaxFloat( Delay, ArrivalA + pC->Delays[iFanin] ); - Area += pBestF[k]->M[fComplF][1].A; - } - else - { -// assert( ArrivalD + pC->Delays[iFanin] < Required + Epsilon ); - if ( pD->D < NF_INFINITY && pA->D < NF_INFINITY && ArrivalD + pC->Delays[iFanin] >= Required + Epsilon ) - break; - Delay = Abc_MaxFloat( Delay, ArrivalD + pC->Delays[iFanin] ); - Area += pBestF[k]->M[fComplF][0].A; - } - } - if ( k < nFans ) - continue; - if ( p->fUseEla ) +// iFanin = Abc_Lit2Var((int)pInfo[k]); +// fComplF = Abc_LitIsCompl((int)pInfo[k]); + iFanin = (Mat.Perm >> (3*k)) & 7; + fComplF = (Mat.Phase >> k) & 1; + ArrivalD = pBestF[k]->M[fComplF][0].D; + ArrivalA = pBestF[k]->M[fComplF][1].D; + if ( ArrivalA + pC->Delays[iFanin] < Required + Epsilon && Required != NF_INFINITY ) { - Nf_Mat_t Temp, * pTemp = &Temp; - memset( pTemp, 0, sizeof(Nf_Mat_t) ); - pTemp->D = Delay; - pTemp->A = Area; - pTemp->CutH = Nf_CutHandle(pCutSet, pCut); - pTemp->Gate = pC->Id; - pTemp->Conf = 0; - for ( k = 0; k < nFans; k++ ) -// pD->Conf |= ((int)pInfo[k] << (k << 2)); - pTemp->Conf |= (Abc_Var2Lit(k, Abc_LitIsCompl((int)pInfo[k])) << (Abc_Lit2Var((int)pInfo[k]) << 2)); - Area = Nf_MatchRef2Area(p, iObj, fCompl, pTemp ); - } - // select best match - if ( pD->D > Delay )//+ Epsilon ) - { - pD->D = Delay; - pD->A = Area; - pD->CutH = Nf_CutHandle(pCutSet, pCut); - pD->Gate = pC->Id; - pD->Conf = 0; - for ( k = 0; k < nFans; k++ ) -// pD->Conf |= ((int)pInfo[k] << (k << 2)); - pD->Conf |= (Abc_Var2Lit(k, Abc_LitIsCompl((int)pInfo[k])) << (Abc_Lit2Var((int)pInfo[k]) << 2)); + Delay = Abc_MaxFloat( Delay, ArrivalA + pC->Delays[iFanin] ); + Area += pBestF[k]->M[fComplF][1].A; } - if ( pA->A > Area )//+ Epsilon ) + else { - pA->D = Delay; - pA->A = Area; - pA->CutH = Nf_CutHandle(pCutSet, pCut); - pA->Gate = pC->Id; - pA->Conf = 0; - for ( k = 0; k < nFans; k++ ) -// pA->Conf |= ((int)pInfo[k] << (k << 2)); - pA->Conf |= (Abc_Var2Lit(k, Abc_LitIsCompl((int)pInfo[k])) << (Abc_Lit2Var((int)pInfo[k]) << 2)); +// assert( ArrivalD + pC->Delays[iFanin] < Required + Epsilon ); + if ( pD->D < NF_INFINITY && pA->D < NF_INFINITY && ArrivalD + pC->Delays[iFanin] >= Required + Epsilon ) + break; + Delay = Abc_MaxFloat( Delay, ArrivalD + pC->Delays[iFanin] ); + Area += pBestF[k]->M[fComplF][0].A; } } - else if ( Type == NF_XOR ) + if ( k < nFans ) + continue; + // select best match + if ( pD->D > Delay )//+ Epsilon ) { - int m, nMints = 1 << nFans; - for ( m = 0; m < nMints; m++ ) - { - int fComplAll = fCompl; - // collect best fanin delays - float Area = pC->Area, Delay = 0; - for ( k = 0; k < nFans; k++ ) - { - assert( !Abc_LitIsCompl((int)pInfo[k]) ); - iFanin = Abc_Lit2Var((int)pInfo[k]); - fComplF = ((m >> k) & 1); - ArrivalD = pBestF[k]->M[fComplF][0].D; - ArrivalA = pBestF[k]->M[fComplF][1].D; - if ( ArrivalA + pC->Delays[iFanin] <= Required && Required != NF_INFINITY ) - { - Delay = Abc_MaxFloat( Delay, ArrivalA + pC->Delays[iFanin] ); - Area += pBestF[k]->M[fComplF][1].A; - } - else - { - assert( ArrivalD + pC->Delays[iFanin] < Required + Epsilon ); - Delay = Abc_MaxFloat( Delay, ArrivalD + pC->Delays[iFanin] ); - Area += pBestF[k]->M[fComplF][0].A; - } - fComplAll ^= fComplF; - } - pD = &pBest->M[fComplAll][0]; - pA = &pBest->M[fComplAll][1]; - if ( pD->D > Delay ) - { - pD->D = Delay; - pD->A = Area; - pD->CutH = Nf_CutHandle(pCutSet, pCut); - pD->Gate = pC->Id; - pD->Conf = 0; - for ( k = 0; k < nFans; k++ ) -// pD->Conf |= Abc_LitNotCond((int)pInfo[k], (m >> k) & 1) << (k << 2); - pD->Conf |= (Abc_Var2Lit(k, (m >> k) & 1) << (Abc_Lit2Var((int)pInfo[k]) << 2)); - } - if ( pA->A > Area ) - { - pA->D = Delay; - pA->A = Area; - pA->CutH = Nf_CutHandle(pCutSet, pCut); - pA->Gate = pC->Id; - pA->Conf = 0; - for ( k = 0; k < nFans; k++ ) -// pA->Conf |= Abc_LitNotCond((int)pInfo[k], (m >> k) & 1) << (k << 2); - pA->Conf |= (Abc_Var2Lit(k, (m >> k) & 1) << (Abc_Lit2Var((int)pInfo[k]) << 2)); - } - } + pD->D = Delay; + pD->A = Area; + pD->CutH = Nf_CutHandle(pCutSet, pCut); + pD->Gate = pC->Id; + pD->Conf = 0; + for ( k = 0; k < nFans; k++ ) +// pD->Conf |= ((int)pInfo[k] << (k << 2)); +// pD->Conf |= (Abc_Var2Lit(k, Abc_LitIsCompl((int)pInfo[k])) << (Abc_Lit2Var((int)pInfo[k]) << 2)); + pD->Conf |= (Abc_Var2Lit(k, (Mat.Phase >> k) & 1) << (((Mat.Perm >> (3*k)) & 7) << 2)); } - else if ( Type == NF_ANDOR ) + if ( pA->A > Area )//+ Epsilon ) { - float Area = pC->Area, Delay = 0; - int g, Conf = 0, nGroups = (int)*pInfo++; - for ( g = 0; g < nGroups; g++ ) - { - int nSizeAll = (int)*pInfo++; - int nSizeNeg = (int)*pInfo++; - float ArrivalD, ArrivalA; - for ( k = 0; k < nSizeAll; k++ ) - { - fComplF = Abc_LitIsCompl((int)pInfo[k]); - iFanin = Abc_Lit2Var((int)pInfo[k]); - ArrivalD = pBestF[k]->M[fComplF][0].D; - ArrivalA = pBestF[k]->M[fComplF][1].D; - if ( ArrivalA + pC->Delays[iFanin] < Required + Epsilon && Required != NF_INFINITY ) - { - Delay = Abc_MaxFloat( Delay, ArrivalA + pC->Delays[iFanin] ); - Area += pBestF[k]->M[fComplF][1].A; - } - else - { - assert( ArrivalD + pC->Delays[iFanin] < Required + Epsilon ); - Delay = Abc_MaxFloat( Delay, ArrivalD + pC->Delays[iFanin] ); - Area += pBestF[k]->M[fComplF][0].A; - } -// Conf |= Abc_LitNotCond((int)pInfo[k], 0) << (iFanin << 2); - Conf |= Abc_Var2Lit(iFanin, Abc_LitIsCompl((int)pInfo[k])) << (Abc_Lit2Var((int)pInfo[k]) << 2); - } - pInfo += nSizeAll; nSizeNeg = 0; - } - assert( Conf > 0 ); - if ( pD->D > Delay ) - { - pD->D = Delay; - pD->A = Area; - pD->CutH = Nf_CutHandle(pCutSet, pCut); - pD->Gate = pC->Id; - pD->Conf = Conf; - } - if ( pA->A > Area ) - { - pA->D = Delay; - pA->A = Area; - pA->CutH = Nf_CutHandle(pCutSet, pCut); - pA->Gate = pC->Id; - pA->Conf = Conf; - } + pA->D = Delay; + pA->A = Area; + pA->CutH = Nf_CutHandle(pCutSet, pCut); + pA->Gate = pC->Id; + pA->Conf = 0; + for ( k = 0; k < nFans; k++ ) +// pA->Conf |= ((int)pInfo[k] << (k << 2)); +// pA->Conf |= (Abc_Var2Lit(k, Abc_LitIsCompl((int)pInfo[k])) << (Abc_Lit2Var((int)pInfo[k]) << 2)); + pA->Conf |= (Abc_Var2Lit(k, (Mat.Phase >> k) & 1) << (((Mat.Perm >> (3*k)) & 7) << 2)); } } /* - Nf_ManCutMatchprintf( p, iObj, 0, &pBest->M[0][0] ); - Nf_ManCutMatchprintf( p, iObj, 0, &pBest->M[0][1] ); - Nf_ManCutMatchprintf( p, iObj, 1, &pBest->M[1][0] ); - Nf_ManCutMatchprintf( p, iObj, 1, &pBest->M[1][1] ); + Nf_ManCutMatchPrint( p, iObj, 0, &pBest->M[0][0] ); + Nf_ManCutMatchPrint( p, iObj, 0, &pBest->M[0][1] ); + Nf_ManCutMatchPrint( p, iObj, 1, &pBest->M[1][0] ); + Nf_ManCutMatchPrint( p, iObj, 1, &pBest->M[1][1] ); */ } static inline void Nf_ObjPrepareCi( Nf_Man_t * p, int iObj ) @@ -1765,10 +1356,10 @@ void Nf_ManCutMatch( Nf_Man_t * p, int iObj ) if ( 18687 == iObj ) { printf( "Obj %6d (%f %f):\n", iObj, Required[0], Required[1] ); - Nf_ManCutMatchprintf( p, iObj, 0, &pBest->M[0][0] ); - Nf_ManCutMatchprintf( p, iObj, 0, &pBest->M[0][1] ); - Nf_ManCutMatchprintf( p, iObj, 1, &pBest->M[1][0] ); - Nf_ManCutMatchprintf( p, iObj, 1, &pBest->M[1][1] ); + Nf_ManCutMatchPrint( p, iObj, 0, &pBest->M[0][0] ); + Nf_ManCutMatchPrint( p, iObj, 0, &pBest->M[0][1] ); + Nf_ManCutMatchPrint( p, iObj, 1, &pBest->M[1][0] ); + Nf_ManCutMatchPrint( p, iObj, 1, &pBest->M[1][1] ); printf( "\n" ); } */ @@ -1941,7 +1532,7 @@ int Nf_ManSetMapRefs( Nf_Man_t * p ) Required = Nf_ObjMatchD( p, Gia_ObjFaninId0p(p->pGia, pObj), Gia_ObjFaninC0(pObj) )->D; if ( Required == NF_INFINITY ) { - Nf_ManCutMatchprintf( p, Gia_ObjFaninId0p(p->pGia, pObj), Gia_ObjFaninC0(pObj), Nf_ObjMatchD( p, Gia_ObjFaninId0p(p->pGia, pObj), Gia_ObjFaninC0(pObj) ) ); + Nf_ManCutMatchPrint( p, Gia_ObjFaninId0p(p->pGia, pObj), Gia_ObjFaninC0(pObj), Nf_ObjMatchD( p, Gia_ObjFaninId0p(p->pGia, pObj), Gia_ObjFaninC0(pObj) ) ); } p->pPars->MapDelay = Abc_MaxFloat( p->pPars->MapDelay, Required ); } @@ -2152,7 +1743,7 @@ Gia_Man_t * Nf_ManDeriveMapping( Nf_Man_t * p ) Vec_IntWriteEntry( vMapping, Abc_Var2Lit(i, c), -1 ); continue; } - // Nf_ManCutMatchprintf( p, i, c, pM ); + // Nf_ManCutMatchPrint( p, i, c, pM ); pCut = Nf_CutFromHandle( Nf_ObjCutSet(p, i), pM->CutH ); // create mapping Vec_IntWriteEntry( vMapping, Abc_Var2Lit(i, c), Vec_IntSize(vMapping) ); @@ -2481,7 +2072,7 @@ void Nf_ManSetDefaultPars( Jf_Par_t * pPars ) pPars->nCutNum = 16; pPars->nProcNum = 0; pPars->nRounds = 3; - pPars->nRoundsEla = 0; + pPars->nRoundsEla = 3; pPars->nRelaxRatio = 0; pPars->nCoarseLimit = 3; pPars->nAreaTuner = 1; @@ -2526,6 +2117,7 @@ Gia_Man_t * Nf_ManPerformMapping( Gia_Man_t * pGia, Jf_Par_t * pPars ) Nf_ManSetMapRefs( p ); Nf_ManPrintStats( p, p->Iter ? "Area " : "Delay" ); } +/* p->fUseEla = 1; for ( ; p->Iter < p->pPars->nRounds + pPars->nRoundsEla; p->Iter++ ) { @@ -2533,6 +2125,7 @@ Gia_Man_t * Nf_ManPerformMapping( Gia_Man_t * pGia, Jf_Par_t * pPars ) Nf_ManUpdateStats( p ); Nf_ManPrintStats( p, "Ela " ); } +*/ pNew = Nf_ManDeriveMapping( p ); // Gia_ManMappingVerify( pNew ); Nf_StoDelete( p ); diff --git a/src/aig/gia/giaPf.c b/src/aig/gia/giaPf.c new file mode 100644 index 00000000..21c94cd5 --- /dev/null +++ b/src/aig/gia/giaPf.c @@ -0,0 +1,1353 @@ +/**CFile**************************************************************** + + FileName [giaNf.c] + + SystemName [ABC: Logic synthesis and verification system.] + + PackageName [Scalable AIG package.] + + Synopsis [Standard-cell mapper.] + + Author [Alan Mishchenko] + + Affiliation [UC Berkeley] + + Date [Ver. 1.0. Started - June 20, 2005.] + + Revision [$Id: giaNf.c,v 1.00 2005/06/20 00:00:00 alanmi Exp $] + +***********************************************************************/ + +#include <float.h> +#include "gia.h" +#include "misc/st/st.h" +#include "map/mio/mio.h" +#include "misc/util/utilTruth.h" +#include "misc/extra/extra.h" +#include "base/main/main.h" +#include "misc/vec/vecMem.h" +#include "misc/vec/vecWec.h" +#include "opt/dau/dau.h" + +ABC_NAMESPACE_IMPL_START + +//////////////////////////////////////////////////////////////////////// +/// DECLARATIONS /// +//////////////////////////////////////////////////////////////////////// + +#define PF_LEAF_MAX 6 +#define PF_CUT_MAX 32 +#define PF_NO_LEAF 31 +#define PF_INFINITY FLT_MAX + +typedef struct Pf_Cut_t_ Pf_Cut_t; +struct Pf_Cut_t_ +{ + word Sign; // signature + int Delay; // delay + float Flow; // flow + unsigned iFunc : 26; // function + unsigned Useless : 1; // function + unsigned nLeaves : 5; // leaf number (PF_NO_LEAF) + int pLeaves[PF_LEAF_MAX+1]; // leaves +}; +typedef struct Pf_Mat_t_ Pf_Mat_t; +struct Pf_Mat_t_ +{ + unsigned fCompl : 8; // complemented + unsigned Phase : 6; // match phase + unsigned Perm : 18; // match permutation +}; +typedef struct Pf_Obj_t_ Pf_Obj_t; +struct Pf_Obj_t_ +{ + float Area; + unsigned Gate : 7; // gate + unsigned nLeaves : 3; // fanin count + unsigned nRefs : 22; // ref count + int pLeaves[6]; // leaf literals +}; +typedef struct Pf_Man_t_ Pf_Man_t; +struct Pf_Man_t_ +{ + // user data + Gia_Man_t * pGia; // derived manager + Jf_Par_t * pPars; // parameters + // matching + Vec_Mem_t * vTtMem; // truth tables + Vec_Wec_t * vTt2Match; // matches for truth tables + Mio_Cell_t * pCells; // library gates + int nCells; // library gate count + // cut data + Pf_Obj_t * pPfObjs; // best cuts + Vec_Ptr_t vPages; // cut memory + Vec_Int_t vCutSets; // cut offsets + Vec_Flt_t vCutFlows; // temporary cut area + Vec_Int_t vCutDelays; // temporary cut delay + int iCur; // current position + int Iter; // mapping iterations + int fUseEla; // use exact area + int nInvs; // the inverter count + float InvDelay; // inverter delay + float InvArea; // inverter area + // statistics + abctime clkStart; // starting time + double CutCount[6]; // cut counts + int nCutUseAll; // objects with useful cuts +}; + +static inline int Pf_Mat2Int( Pf_Mat_t Mat ) { union { int x; Pf_Mat_t y; } v; v.y = Mat; return v.x; } +static inline Pf_Mat_t Pf_Int2Mat( int Int ) { union { int x; Pf_Mat_t y; } v; v.x = Int; return v.y; } + +static inline Pf_Obj_t * Pf_ManObj( Pf_Man_t * p, int i ) { return p->pPfObjs + i; } +static inline Mio_Cell_t* Pf_ManCell( Pf_Man_t * p, int i ) { return p->pCells + i; } +static inline int * Pf_ManCutSet( Pf_Man_t * p, int i ) { return (int *)Vec_PtrEntry(&p->vPages, i >> 16) + (i & 0xFFFF); } +static inline int Pf_ObjCutSetId( Pf_Man_t * p, int i ) { return Vec_IntEntry( &p->vCutSets, i ); } +static inline int * Pf_ObjCutSet( Pf_Man_t * p, int i ) { return Pf_ManCutSet(p, Pf_ObjCutSetId(p, i)); } +static inline int Pf_ObjHasCuts( Pf_Man_t * p, int i ) { return (int)(Vec_IntEntry(&p->vCutSets, i) > 0); } +static inline int Pf_ObjCutUseless( Pf_Man_t * p, int TruthId ) { return (int)(TruthId >= Vec_WecSize(p->vTt2Match)); } + +static inline float Pf_ObjCutFlow( Pf_Man_t * p, int i ) { return Vec_FltEntry(&p->vCutFlows, i); } +static inline int Pf_ObjCutDelay( Pf_Man_t * p, int i ) { return Vec_IntEntry(&p->vCutDelays, i); } +static inline void Pf_ObjSetCutFlow( Pf_Man_t * p, int i, float a ) { Vec_FltWriteEntry(&p->vCutFlows, i, a); } +static inline void Pf_ObjSetCutDelay( Pf_Man_t * p, int i, int d ) { Vec_IntWriteEntry(&p->vCutDelays, i, d); } + +static inline int Pf_CutSize( int * pCut ) { return pCut[0] & PF_NO_LEAF; } +static inline int Pf_CutFunc( int * pCut ) { return ((unsigned)pCut[0] >> 5); } +static inline int * Pf_CutLeaves( int * pCut ) { return pCut + 1; } +static inline int Pf_CutSetBoth( int n, int f ) { return n | (f << 5); } +static inline int Pf_CutIsTriv( int * pCut, int i ) { return Pf_CutSize(pCut) == 1 && pCut[1] == i; } +static inline int Pf_CutHandle( int * pCutSet, int * pCut ) { assert( pCut > pCutSet ); return pCut - pCutSet; } +static inline int * Pf_CutFromHandle( int * pCutSet, int h ) { assert( h > 0 ); return pCutSet + h; } +static inline int Pf_CutConfLit( int Conf, int i ) { return 15 & (Conf >> (i << 2)); } +static inline int Pf_CutConfVar( int Conf, int i ) { return Abc_Lit2Var( Pf_CutConfLit(Conf, i) ); } +static inline int Pf_CutConfC( int Conf, int i ) { return Abc_LitIsCompl( Pf_CutConfLit(Conf, i) ); } + +#define Pf_SetForEachCut( pList, pCut, i ) for ( i = 0, pCut = pList + 1; i < pList[0]; i++, pCut += Pf_CutSize(pCut) + 1 ) +#define Pf_ObjForEachCut( pCuts, i, nCuts ) for ( i = 0, i < nCuts; i++ ) +#define Pf_CutForEachLit( pCut, Conf, iLit, i ) for ( i = 0; i < Pf_CutSize(pCut) && (iLit = Abc_Lit2LitV(Pf_CutLeaves(pCut), Pf_CutConfLit(Conf, i))); i++ ) +#define Pf_CutForEachVar( pCut, Conf, iVar, c, i ) for ( i = 0; i < Pf_CutSize(pCut) && (iVar = Pf_CutLeaves(pCut)[Pf_CutConfVar(Conf, i)]) && ((c = Pf_CutConfC(Conf, i)), 1); i++ ) + +//////////////////////////////////////////////////////////////////////// +/// FUNCTION DEFINITIONS /// +//////////////////////////////////////////////////////////////////////// + +/**Function************************************************************* + + Synopsis [] + + Description [] + + SideEffects [] + + SeeAlso [] + +***********************************************************************/ +void Pf_StoCreateGateAdd( Pf_Man_t * pMan, word uTruth, int * pFans, int nFans, int CellId ) +{ + Vec_Int_t * vArray; + Pf_Mat_t Mat = Pf_Int2Mat(0); + int i, GateId, Entry, fCompl = (int)(uTruth & 1); + word uFunc = fCompl ? ~uTruth : uTruth; + int iFunc = Vec_MemHashInsert( pMan->vTtMem, &uFunc ); + if ( iFunc == Vec_WecSize(pMan->vTt2Match) ) + Vec_WecPushLevel( pMan->vTt2Match ); + vArray = Vec_WecEntry( pMan->vTt2Match, iFunc ); + Mat.fCompl = fCompl; + assert( nFans < 7 ); + for ( i = 0; i < nFans; i++ ) + { + Mat.Perm |= (unsigned)(Abc_Lit2Var(pFans[i]) << (3*i)); + Mat.Phase |= (unsigned)(Abc_LitIsCompl(pFans[i]) << i); + } + // check if the same one exists + Vec_IntForEachEntryDouble( vArray, GateId, Entry, i ) + if ( GateId == CellId && Pf_Int2Mat(Entry).Phase == Mat.Phase ) + break; + if ( i == Vec_IntSize(vArray) ) + { + Vec_IntPush( vArray, CellId ); + Vec_IntPush( vArray, Pf_Mat2Int(Mat) ); + } +} +void Pf_StoCreateGate( Pf_Man_t * pMan, Mio_Cell_t * pCell, int ** pComp, int ** pPerm, int * pnPerms ) +{ + int Perm[PF_LEAF_MAX], * Perm1, * Perm2; + int nPerms = pnPerms[pCell->nFanins]; + int nMints = (1 << pCell->nFanins); + word tCur, tTemp1, tTemp2; + int i, p, c; + for ( i = 0; i < (int)pCell->nFanins; i++ ) + Perm[i] = Abc_Var2Lit( i, 0 ); + tCur = tTemp1 = pCell->uTruth; + for ( p = 0; p < nPerms; p++ ) + { + tTemp2 = tCur; + for ( c = 0; c < nMints; c++ ) + { + Pf_StoCreateGateAdd( pMan, tCur, Perm, pCell->nFanins, pCell->Id ); + // update + tCur = Abc_Tt6Flip( tCur, pComp[pCell->nFanins][c] ); + Perm1 = Perm + pComp[pCell->nFanins][c]; + *Perm1 = Abc_LitNot( *Perm1 ); + } + assert( tTemp2 == tCur ); + // update + tCur = Abc_Tt6SwapAdjacent( tCur, pPerm[pCell->nFanins][p] ); + Perm1 = Perm + pPerm[pCell->nFanins][p]; + Perm2 = Perm1 + 1; + ABC_SWAP( int, *Perm1, *Perm2 ); + } + assert( tTemp1 == tCur ); +} +void Pf_StoDeriveMatches( Pf_Man_t * p, int fVerbose ) +{ +// abctime clk = Abc_Clock(); + int * pComp[7]; + int * pPerm[7]; + int nPerms[7], i; + for ( i = 2; i <= 6; i++ ) + pComp[i] = Extra_GreyCodeSchedule( i ); + for ( i = 2; i <= 6; i++ ) + pPerm[i] = Extra_PermSchedule( i ); + for ( i = 2; i <= 6; i++ ) + nPerms[i] = Extra_Factorial( i ); + p->pCells = Mio_CollectRootsNewDefault( 6, &p->nCells, fVerbose ); + for ( i = 4; i < p->nCells; i++ ) + Pf_StoCreateGate( p, p->pCells + i, pComp, pPerm, nPerms ); + for ( i = 2; i <= 6; i++ ) + ABC_FREE( pComp[i] ); + for ( i = 2; i <= 6; i++ ) + ABC_FREE( pPerm[i] ); +// Abc_PrintTime( 1, "Time", Abc_Clock() - clk ); +} +void Pf_StoPrintOne( Pf_Man_t * p, int Count, int t, int i, int GateId, Pf_Mat_t Mat ) +{ + Mio_Cell_t * pC = p->pCells + GateId; + word * pTruth = Vec_MemReadEntry(p->vTtMem, t); + int k, nSuppSize = Abc_TtSupportSize(pTruth, 6); + printf( "%6d : ", Count ); + printf( "%6d : ", t ); + printf( "%6d : ", i ); + printf( "Gate %16s ", pC->pName ); + printf( "Area =%8.2f ", pC->Area ); + printf( "In = %d ", pC->nFanins ); + if ( Mat.fCompl ) + printf( " compl " ); + else + printf( " " ); + for ( k = 0; k < (int)pC->nFanins; k++ ) + { + int fComplF = (Mat.Phase >> k) & 1; + int iFanin = (Mat.Perm >> (3*k)) & 7; + printf( "%c", 'a' + iFanin - fComplF * ('a' - 'A') ); + } + printf( " " ); + Dau_DsdPrintFromTruth( pTruth, nSuppSize ); +} +void Pf_StoPrint( Pf_Man_t * p, int fVerbose ) +{ + int t, i, GateId, Entry, Count = 0; + for ( t = 2; t < Vec_WecSize(p->vTt2Match); t++ ) + { + Vec_Int_t * vArr = Vec_WecEntry( p->vTt2Match, t ); + Vec_IntForEachEntryDouble( vArr, GateId, Entry, i ) + { + Count++; + if ( !fVerbose ) + continue; + if ( t < 10 ) + Pf_StoPrintOne( p, Count, t, i/2, GateId, Pf_Int2Mat(Entry) ); + } + } + printf( "Gates = %d. Truths = %d. Matches = %d.\n", + p->nCells, Vec_MemEntryNum(p->vTtMem), Count ); +} +/* +void Pf_ManPrepareLibraryTest() +{ + int fVerbose = 0; + abctime clk = Abc_Clock(); + Pf_Man_t * p; + p = Pf_StoCreate( NULL, NULL, fVerbose ); + Pf_StoPrint( p, fVerbose ); + Pf_StoDelete(p); + Abc_PrintTime( 1, "Time", Abc_Clock() - clk ); +} +*/ + + + +/**Function************************************************************* + + Synopsis [] + + Description [] + + SideEffects [] + + SeeAlso [] + +***********************************************************************/ +Pf_Man_t * Pf_StoCreate( Gia_Man_t * pGia, Jf_Par_t * pPars ) +{ + extern void Mf_ManSetFlowRefs( Gia_Man_t * p, Vec_Int_t * vRefs ); + Pf_Man_t * p; + Vec_Int_t * vFlowRefs; + assert( pPars->nCutNum > 1 && pPars->nCutNum <= PF_CUT_MAX ); + assert( pPars->nLutSize > 1 && pPars->nLutSize <= PF_LEAF_MAX ); + ABC_FREE( pGia->pRefs ); + Vec_IntFreeP( &pGia->vCellMapping ); + if ( Gia_ManHasChoices(pGia) ) + Gia_ManSetPhase(pGia); + // create references + ABC_FREE( pGia->pRefs ); + vFlowRefs = Vec_IntAlloc(0); + Mf_ManSetFlowRefs( pGia, vFlowRefs ); + pGia->pRefs= Vec_IntReleaseArray(vFlowRefs); + Vec_IntFree(vFlowRefs); + // create + p = ABC_CALLOC( Pf_Man_t, 1 ); + p->clkStart = Abc_Clock(); + p->pGia = pGia; + p->pPars = pPars; + p->pPfObjs = ABC_CALLOC( Pf_Obj_t, Gia_ManObjNum(pGia) ); + p->iCur = 2; + // other + Vec_PtrGrow( &p->vPages, 256 ); // cut memory + Vec_IntFill( &p->vCutSets, Gia_ManObjNum(pGia), 0 ); // cut offsets + Vec_FltFill( &p->vCutFlows, Gia_ManObjNum(pGia), 0 ); // cut area + Vec_IntFill( &p->vCutDelays,Gia_ManObjNum(pGia), 0 ); // cut delay + // matching + p->vTtMem = Vec_MemAllocForTT( 6, 0 ); + p->vTt2Match = Vec_WecAlloc( 1000 ); + Vec_WecPushLevel( p->vTt2Match ); + Vec_WecPushLevel( p->vTt2Match ); + assert( Vec_WecSize(p->vTt2Match) == Vec_MemEntryNum(p->vTtMem) ); + Pf_StoDeriveMatches( p, 0 );//pPars->fVerbose ); + p->InvDelay = p->pCells[3].Delays[0]; + p->InvArea = p->pCells[3].Area; + //Pf_ObjMatchD(p, 0, 0)->Gate = 0; + //Pf_ObjMatchD(p, 0, 1)->Gate = 1; + // prepare cuts + return p; +} +void Pf_StoDelete( Pf_Man_t * p ) +{ + Vec_PtrFreeData( &p->vPages ); + ABC_FREE( p->vPages.pArray ); + ABC_FREE( p->vCutSets.pArray ); + ABC_FREE( p->vCutFlows.pArray ); + ABC_FREE( p->vCutDelays.pArray ); + ABC_FREE( p->pPfObjs ); + // matching + Vec_WecFree( p->vTt2Match ); + Vec_MemHashFree( p->vTtMem ); + Vec_MemFree( p->vTtMem ); + ABC_FREE( p->pCells ); + ABC_FREE( p ); +} + + + + +/**Function************************************************************* + + Synopsis [] + + Description [] + + SideEffects [] + + SeeAlso [] + +***********************************************************************/ +static inline int Pf_CutComputeTruth6( Pf_Man_t * p, Pf_Cut_t * pCut0, Pf_Cut_t * pCut1, int fCompl0, int fCompl1, Pf_Cut_t * pCutR, int fIsXor ) +{ +// extern int Pf_ManTruthCanonicize( word * t, int nVars ); + int nOldSupp = pCutR->nLeaves, truthId, fCompl; word t; + word t0 = *Vec_MemReadEntry(p->vTtMem, Abc_Lit2Var(pCut0->iFunc)); + word t1 = *Vec_MemReadEntry(p->vTtMem, Abc_Lit2Var(pCut1->iFunc)); + if ( Abc_LitIsCompl(pCut0->iFunc) ^ fCompl0 ) t0 = ~t0; + if ( Abc_LitIsCompl(pCut1->iFunc) ^ fCompl1 ) t1 = ~t1; + t0 = Abc_Tt6Expand( t0, pCut0->pLeaves, pCut0->nLeaves, pCutR->pLeaves, pCutR->nLeaves ); + t1 = Abc_Tt6Expand( t1, pCut1->pLeaves, pCut1->nLeaves, pCutR->pLeaves, pCutR->nLeaves ); + t = fIsXor ? t0 ^ t1 : t0 & t1; + if ( (fCompl = (int)(t & 1)) ) t = ~t; + pCutR->nLeaves = Abc_Tt6MinBase( &t, pCutR->pLeaves, pCutR->nLeaves ); + assert( (int)(t & 1) == 0 ); + truthId = Vec_MemHashInsert(p->vTtMem, &t); + pCutR->iFunc = Abc_Var2Lit( truthId, fCompl ); + pCutR->Useless = Pf_ObjCutUseless( p, truthId ); + assert( (int)pCutR->nLeaves <= nOldSupp ); + return (int)pCutR->nLeaves < nOldSupp; +} +static inline int Pf_CutComputeTruthMux6( Pf_Man_t * p, Pf_Cut_t * pCut0, Pf_Cut_t * pCut1, Pf_Cut_t * pCutC, int fCompl0, int fCompl1, int fComplC, Pf_Cut_t * pCutR ) +{ + int nOldSupp = pCutR->nLeaves, truthId, fCompl; word t; + word t0 = *Vec_MemReadEntry(p->vTtMem, Abc_Lit2Var(pCut0->iFunc)); + word t1 = *Vec_MemReadEntry(p->vTtMem, Abc_Lit2Var(pCut1->iFunc)); + word tC = *Vec_MemReadEntry(p->vTtMem, Abc_Lit2Var(pCutC->iFunc)); + if ( Abc_LitIsCompl(pCut0->iFunc) ^ fCompl0 ) t0 = ~t0; + if ( Abc_LitIsCompl(pCut1->iFunc) ^ fCompl1 ) t1 = ~t1; + if ( Abc_LitIsCompl(pCutC->iFunc) ^ fComplC ) tC = ~tC; + t0 = Abc_Tt6Expand( t0, pCut0->pLeaves, pCut0->nLeaves, pCutR->pLeaves, pCutR->nLeaves ); + t1 = Abc_Tt6Expand( t1, pCut1->pLeaves, pCut1->nLeaves, pCutR->pLeaves, pCutR->nLeaves ); + tC = Abc_Tt6Expand( tC, pCutC->pLeaves, pCutC->nLeaves, pCutR->pLeaves, pCutR->nLeaves ); + t = (tC & t1) | (~tC & t0); + if ( (fCompl = (int)(t & 1)) ) t = ~t; + pCutR->nLeaves = Abc_Tt6MinBase( &t, pCutR->pLeaves, pCutR->nLeaves ); + assert( (int)(t & 1) == 0 ); + truthId = Vec_MemHashInsert(p->vTtMem, &t); + pCutR->iFunc = Abc_Var2Lit( truthId, fCompl ); + pCutR->Useless = Pf_ObjCutUseless( p, truthId ); + assert( (int)pCutR->nLeaves <= nOldSupp ); + return (int)pCutR->nLeaves < nOldSupp; +} + + +/**Function************************************************************* + + Synopsis [] + + Description [] + + SideEffects [] + + SeeAlso [] + +***********************************************************************/ +static inline int Pf_CutCountBits( word i ) +{ + i = i - ((i >> 1) & 0x5555555555555555); + i = (i & 0x3333333333333333) + ((i >> 2) & 0x3333333333333333); + i = ((i + (i >> 4)) & 0x0F0F0F0F0F0F0F0F); + return (i*(0x0101010101010101))>>56; +} +static inline word Pf_CutGetSign( int * pLeaves, int nLeaves ) +{ + word Sign = 0; int i; + for ( i = 0; i < nLeaves; i++ ) + Sign |= ((word)1) << (pLeaves[i] & 0x3F); + return Sign; +} +static inline int Pf_CutCreateUnit( Pf_Cut_t * p, int i ) +{ + p->Delay = 0; + p->Flow = 0; + p->iFunc = 2; + p->nLeaves = 1; + p->pLeaves[0] = i; + p->Sign = ((word)1) << (i & 0x3F); + return 1; +} +static inline void Pf_Cutprintf( Pf_Man_t * p, Pf_Cut_t * pCut ) +{ + int i, nDigits = Abc_Base10Log(Gia_ManObjNum(p->pGia)); + printf( "%d {", pCut->nLeaves ); + for ( i = 0; i < (int)pCut->nLeaves; i++ ) + printf( " %*d", nDigits, pCut->pLeaves[i] ); + for ( ; i < (int)p->pPars->nLutSize; i++ ) + printf( " %*s", nDigits, " " ); + printf( " } Useless = %d. D = %4d A = %9.4f F = %6d ", + pCut->Useless, pCut->Delay, pCut->Flow, pCut->iFunc ); + if ( p->vTtMem ) + Dau_DsdPrintFromTruth( Vec_MemReadEntry(p->vTtMem, Abc_Lit2Var(pCut->iFunc)), pCut->nLeaves ); + else + printf( "\n" ); +} +static inline int Pf_ManPrepareCuts( Pf_Cut_t * pCuts, Pf_Man_t * p, int iObj, int fAddUnit ) +{ + if ( Pf_ObjHasCuts(p, iObj) ) + { + Pf_Cut_t * pMfCut = pCuts; + int i, * pCut, * pList = Pf_ObjCutSet(p, iObj); + Pf_SetForEachCut( pList, pCut, i ) + { + pMfCut->Delay = 0; + pMfCut->Flow = 0; + pMfCut->iFunc = Pf_CutFunc( pCut ); + pMfCut->nLeaves = Pf_CutSize( pCut ); + pMfCut->Sign = Pf_CutGetSign( pCut+1, Pf_CutSize(pCut) ); + pMfCut->Useless = Pf_ObjCutUseless( p, Abc_Lit2Var(pMfCut->iFunc) ); + memcpy( pMfCut->pLeaves, pCut+1, sizeof(int) * Pf_CutSize(pCut) ); + pMfCut++; + } + if ( fAddUnit && pCuts->nLeaves > 1 ) + return pList[0] + Pf_CutCreateUnit( pMfCut, iObj ); + return pList[0]; + } + return Pf_CutCreateUnit( pCuts, iObj ); +} +static inline int Pf_ManSaveCuts( Pf_Man_t * p, Pf_Cut_t ** pCuts, int nCuts, int fUseful ) +{ + int i, * pPlace, iCur, nInts = 1, nCutsNew = 0; + for ( i = 0; i < nCuts; i++ ) + if ( !fUseful || !pCuts[i]->Useless ) + nInts += pCuts[i]->nLeaves + 1, nCutsNew++; + if ( (p->iCur & 0xFFFF) + nInts > 0xFFFF ) + p->iCur = ((p->iCur >> 16) + 1) << 16; + if ( Vec_PtrSize(&p->vPages) == (p->iCur >> 16) ) + Vec_PtrPush( &p->vPages, ABC_ALLOC(int, (1<<16)) ); + iCur = p->iCur; p->iCur += nInts; + pPlace = Pf_ManCutSet( p, iCur ); + *pPlace++ = nCutsNew; + for ( i = 0; i < nCuts; i++ ) + if ( !fUseful || !pCuts[i]->Useless ) + { + *pPlace++ = Pf_CutSetBoth( pCuts[i]->nLeaves, pCuts[i]->iFunc ); + memcpy( pPlace, pCuts[i]->pLeaves, sizeof(int) * pCuts[i]->nLeaves ); + pPlace += pCuts[i]->nLeaves; + } + return iCur; +} +static inline int Pf_ManCountUseful( Pf_Cut_t ** pCuts, int nCuts ) +{ + int i, Count = 0; + for ( i = 0; i < nCuts; i++ ) + Count += !pCuts[i]->Useless; + return Count; +} +static inline int Pf_ManCountMatches( Pf_Man_t * p, Pf_Cut_t ** pCuts, int nCuts ) +{ + int i, Count = 0; + for ( i = 0; i < nCuts; i++ ) + if ( !pCuts[i]->Useless ) + Count += Vec_IntSize(Vec_WecEntry(p->vTt2Match, Abc_Lit2Var(pCuts[i]->iFunc))) / 2; + return Count; +} + +/**Function************************************************************* + + Synopsis [Check correctness of cuts.] + + Description [] + + SideEffects [] + + SeeAlso [] + +***********************************************************************/ +static inline int Pf_CutCheck( Pf_Cut_t * pBase, Pf_Cut_t * pCut ) // check if pCut is contained in pBase +{ + int nSizeB = pBase->nLeaves; + int nSizeC = pCut->nLeaves; + int i, * pB = pBase->pLeaves; + int k, * pC = pCut->pLeaves; + for ( i = 0; i < nSizeC; i++ ) + { + for ( k = 0; k < nSizeB; k++ ) + if ( pC[i] == pB[k] ) + break; + if ( k == nSizeB ) + return 0; + } + return 1; +} +static inline int Pf_SetCheckArray( Pf_Cut_t ** ppCuts, int nCuts ) +{ + Pf_Cut_t * pCut0, * pCut1; + int i, k, m, n, Value; + assert( nCuts > 0 ); + for ( i = 0; i < nCuts; i++ ) + { + pCut0 = ppCuts[i]; + assert( pCut0->nLeaves <= PF_LEAF_MAX ); + assert( pCut0->Sign == Pf_CutGetSign(pCut0->pLeaves, pCut0->nLeaves) ); + // check duplicates + for ( m = 0; m < (int)pCut0->nLeaves; m++ ) + for ( n = m + 1; n < (int)pCut0->nLeaves; n++ ) + assert( pCut0->pLeaves[m] < pCut0->pLeaves[n] ); + // check pairs + for ( k = 0; k < nCuts; k++ ) + { + pCut1 = ppCuts[k]; + if ( pCut0 == pCut1 ) + continue; + // check containments + Value = Pf_CutCheck( pCut0, pCut1 ); + assert( Value == 0 ); + } + } + return 1; +} + + +/**Function************************************************************* + + Synopsis [] + + Description [] + + SideEffects [] + + SeeAlso [] + +***********************************************************************/ +static inline int Pf_CutMergeOrder( Pf_Cut_t * pCut0, Pf_Cut_t * pCut1, Pf_Cut_t * pCut, int nLutSize ) +{ + int nSize0 = pCut0->nLeaves; + int nSize1 = pCut1->nLeaves; + int i, * pC0 = pCut0->pLeaves; + int k, * pC1 = pCut1->pLeaves; + int c, * pC = pCut->pLeaves; + // the case of the largest cut sizes + if ( nSize0 == nLutSize && nSize1 == nLutSize ) + { + for ( i = 0; i < nSize0; i++ ) + { + if ( pC0[i] != pC1[i] ) return 0; + pC[i] = pC0[i]; + } + pCut->nLeaves = nLutSize; + pCut->iFunc = -1; + pCut->Sign = pCut0->Sign | pCut1->Sign; + return 1; + } + // compare two cuts with different numbers + i = k = c = 0; + if ( nSize0 == 0 ) goto FlushCut1; + if ( nSize1 == 0 ) goto FlushCut0; + while ( 1 ) + { + if ( c == nLutSize ) return 0; + if ( pC0[i] < pC1[k] ) + { + pC[c++] = pC0[i++]; + if ( i >= nSize0 ) goto FlushCut1; + } + else if ( pC0[i] > pC1[k] ) + { + pC[c++] = pC1[k++]; + if ( k >= nSize1 ) goto FlushCut0; + } + else + { + pC[c++] = pC0[i++]; k++; + if ( i >= nSize0 ) goto FlushCut1; + if ( k >= nSize1 ) goto FlushCut0; + } + } + +FlushCut0: + if ( c + nSize0 > nLutSize + i ) return 0; + while ( i < nSize0 ) + pC[c++] = pC0[i++]; + pCut->nLeaves = c; + pCut->iFunc = -1; + pCut->Sign = pCut0->Sign | pCut1->Sign; + return 1; + +FlushCut1: + if ( c + nSize1 > nLutSize + k ) return 0; + while ( k < nSize1 ) + pC[c++] = pC1[k++]; + pCut->nLeaves = c; + pCut->iFunc = -1; + pCut->Sign = pCut0->Sign | pCut1->Sign; + return 1; +} +static inline int Pf_CutMergeOrderMux( Pf_Cut_t * pCut0, Pf_Cut_t * pCut1, Pf_Cut_t * pCut2, Pf_Cut_t * pCut, int nLutSize ) +{ + int x0, i0 = 0, nSize0 = pCut0->nLeaves, * pC0 = pCut0->pLeaves; + int x1, i1 = 0, nSize1 = pCut1->nLeaves, * pC1 = pCut1->pLeaves; + int x2, i2 = 0, nSize2 = pCut2->nLeaves, * pC2 = pCut2->pLeaves; + int xMin, c = 0, * pC = pCut->pLeaves; + while ( 1 ) + { + x0 = (i0 == nSize0) ? ABC_INFINITY : pC0[i0]; + x1 = (i1 == nSize1) ? ABC_INFINITY : pC1[i1]; + x2 = (i2 == nSize2) ? ABC_INFINITY : pC2[i2]; + xMin = Abc_MinInt( Abc_MinInt(x0, x1), x2 ); + if ( xMin == ABC_INFINITY ) break; + if ( c == nLutSize ) return 0; + pC[c++] = xMin; + if (x0 == xMin) i0++; + if (x1 == xMin) i1++; + if (x2 == xMin) i2++; + } + pCut->nLeaves = c; + pCut->iFunc = -1; + pCut->Sign = pCut0->Sign | pCut1->Sign | pCut2->Sign; + return 1; +} +static inline int Pf_SetCutIsContainedOrder( Pf_Cut_t * pBase, Pf_Cut_t * pCut ) // check if pCut is contained in pBase +{ + int i, nSizeB = pBase->nLeaves; + int k, nSizeC = pCut->nLeaves; + if ( nSizeB == nSizeC ) + { + for ( i = 0; i < nSizeB; i++ ) + if ( pBase->pLeaves[i] != pCut->pLeaves[i] ) + return 0; + return 1; + } + assert( nSizeB > nSizeC ); + if ( nSizeC == 0 ) + return 1; + for ( i = k = 0; i < nSizeB; i++ ) + { + if ( pBase->pLeaves[i] > pCut->pLeaves[k] ) + return 0; + if ( pBase->pLeaves[i] == pCut->pLeaves[k] ) + { + if ( ++k == nSizeC ) + return 1; + } + } + return 0; +} +static inline int Pf_SetLastCutIsContained( Pf_Cut_t ** pCuts, int nCuts ) +{ + int i; + for ( i = 0; i < nCuts; i++ ) + if ( pCuts[i]->nLeaves <= pCuts[nCuts]->nLeaves && (pCuts[i]->Sign & pCuts[nCuts]->Sign) == pCuts[i]->Sign && Pf_SetCutIsContainedOrder(pCuts[nCuts], pCuts[i]) ) + return 1; + return 0; +} +static inline int Pf_SetLastCutContainsArea( Pf_Cut_t ** pCuts, int nCuts ) +{ + int i, k, fChanges = 0; + for ( i = 0; i < nCuts; i++ ) + if ( pCuts[nCuts]->nLeaves < pCuts[i]->nLeaves && (pCuts[nCuts]->Sign & pCuts[i]->Sign) == pCuts[nCuts]->Sign && Pf_SetCutIsContainedOrder(pCuts[i], pCuts[nCuts]) ) + pCuts[i]->nLeaves = PF_NO_LEAF, fChanges = 1; + if ( !fChanges ) + return nCuts; + for ( i = k = 0; i <= nCuts; i++ ) + { + if ( pCuts[i]->nLeaves == PF_NO_LEAF ) + continue; + if ( k < i ) + ABC_SWAP( Pf_Cut_t *, pCuts[k], pCuts[i] ); + k++; + } + return k - 1; +} +static inline int Pf_CutCompareArea( Pf_Cut_t * pCut0, Pf_Cut_t * pCut1 ) +{ + if ( pCut0->Useless < pCut1->Useless ) return -1; + if ( pCut0->Useless > pCut1->Useless ) return 1; + if ( pCut0->Flow < pCut1->Flow ) return -1; + if ( pCut0->Flow > pCut1->Flow ) return 1; + if ( pCut0->Delay < pCut1->Delay ) return -1; + if ( pCut0->Delay > pCut1->Delay ) return 1; + if ( pCut0->nLeaves < pCut1->nLeaves ) return -1; + if ( pCut0->nLeaves > pCut1->nLeaves ) return 1; + return 0; +} +static inline void Pf_SetSortByArea( Pf_Cut_t ** pCuts, int nCuts ) +{ + int i; + for ( i = nCuts; i > 0; i-- ) + { + if ( Pf_CutCompareArea(pCuts[i - 1], pCuts[i]) < 0 )//!= 1 ) + return; + ABC_SWAP( Pf_Cut_t *, pCuts[i - 1], pCuts[i] ); + } +} +static inline int Pf_SetAddCut( Pf_Cut_t ** pCuts, int nCuts, int nCutNum ) +{ + if ( nCuts == 0 ) + return 1; + nCuts = Pf_SetLastCutContainsArea(pCuts, nCuts); + Pf_SetSortByArea( pCuts, nCuts ); + return Abc_MinInt( nCuts + 1, nCutNum - 1 ); +} +static inline int Pf_CutArea( Pf_Man_t * p, int nLeaves ) +{ + if ( nLeaves < 2 ) + return 0; + return nLeaves + p->pPars->nAreaTuner; +} +static inline void Pf_CutParams( Pf_Man_t * p, Pf_Cut_t * pCut, int nGiaRefs ) +{ + int i, nLeaves = pCut->nLeaves; + assert( nLeaves <= p->pPars->nLutSize ); + pCut->Delay = 0; + pCut->Flow = 0; + for ( i = 0; i < nLeaves; i++ ) + { + pCut->Delay = Abc_MaxInt( pCut->Delay, Pf_ObjCutDelay(p, pCut->pLeaves[i]) ); + pCut->Flow += Pf_ObjCutFlow(p, pCut->pLeaves[i]); + } + pCut->Delay += (int)(nLeaves > 1); + pCut->Flow = (pCut->Flow + Pf_CutArea(p, nLeaves)) / (nGiaRefs ? nGiaRefs : 1); +} +void Pf_ObjMergeOrder( Pf_Man_t * p, int iObj ) +{ + Pf_Cut_t pCuts0[PF_CUT_MAX], pCuts1[PF_CUT_MAX], pCuts[PF_CUT_MAX], * pCutsR[PF_CUT_MAX]; + Gia_Obj_t * pObj = Gia_ManObj(p->pGia, iObj); + int nGiaRefs = 2*Gia_ObjRefNumId(p->pGia, iObj); + int nLutSize = p->pPars->nLutSize; + int nCutNum = p->pPars->nCutNum; + int nCuts0 = Pf_ManPrepareCuts(pCuts0, p, Gia_ObjFaninId0(pObj, iObj), 1); + int nCuts1 = Pf_ManPrepareCuts(pCuts1, p, Gia_ObjFaninId1(pObj, iObj), 1); + int fComp0 = Gia_ObjFaninC0(pObj); + int fComp1 = Gia_ObjFaninC1(pObj); + int iSibl = Gia_ObjSibl(p->pGia, iObj); + Pf_Cut_t * pCut0, * pCut1, * pCut0Lim = pCuts0 + nCuts0, * pCut1Lim = pCuts1 + nCuts1; + int i, nCutsUse, nCutsR = 0; + assert( !Gia_ObjIsBuf(pObj) ); + for ( i = 0; i < nCutNum; i++ ) + pCutsR[i] = pCuts + i; + if ( iSibl ) + { + Pf_Cut_t pCuts2[PF_CUT_MAX]; + Gia_Obj_t * pObjE = Gia_ObjSiblObj(p->pGia, iObj); + int fCompE = Gia_ObjPhase(pObj) ^ Gia_ObjPhase(pObjE); + int nCuts2 = Pf_ManPrepareCuts(pCuts2, p, iSibl, 0); + Pf_Cut_t * pCut2, * pCut2Lim = pCuts2 + nCuts2; + for ( pCut2 = pCuts2; pCut2 < pCut2Lim; pCut2++ ) + { + *pCutsR[nCutsR] = *pCut2; + pCutsR[nCutsR]->iFunc = Abc_LitNotCond( pCutsR[nCutsR]->iFunc, fCompE ); + Pf_CutParams( p, pCutsR[nCutsR], nGiaRefs ); + nCutsR = Pf_SetAddCut( pCutsR, nCutsR, nCutNum ); + } + } + if ( Gia_ObjIsMuxId(p->pGia, iObj) ) + { + Pf_Cut_t pCuts2[PF_CUT_MAX]; + int nCuts2 = Pf_ManPrepareCuts(pCuts2, p, Gia_ObjFaninId2(p->pGia, iObj), 1); + int fComp2 = Gia_ObjFaninC2(p->pGia, pObj); + Pf_Cut_t * pCut2, * pCut2Lim = pCuts2 + nCuts2; + p->CutCount[0] += nCuts0 * nCuts1 * nCuts2; + for ( pCut0 = pCuts0; pCut0 < pCut0Lim; pCut0++ ) + for ( pCut1 = pCuts1; pCut1 < pCut1Lim; pCut1++ ) + for ( pCut2 = pCuts2; pCut2 < pCut2Lim; pCut2++ ) + { + if ( Pf_CutCountBits(pCut0->Sign | pCut1->Sign | pCut2->Sign) > nLutSize ) + continue; + p->CutCount[1]++; + if ( !Pf_CutMergeOrderMux(pCut0, pCut1, pCut2, pCutsR[nCutsR], nLutSize) ) + continue; + if ( Pf_SetLastCutIsContained(pCutsR, nCutsR) ) + continue; + p->CutCount[2]++; + if ( Pf_CutComputeTruthMux6(p, pCut0, pCut1, pCut2, fComp0, fComp1, fComp2, pCutsR[nCutsR]) ) + pCutsR[nCutsR]->Sign = Pf_CutGetSign(pCutsR[nCutsR]->pLeaves, pCutsR[nCutsR]->nLeaves); + Pf_CutParams( p, pCutsR[nCutsR], nGiaRefs ); + nCutsR = Pf_SetAddCut( pCutsR, nCutsR, nCutNum ); + } + } + else + { + int fIsXor = Gia_ObjIsXor(pObj); + p->CutCount[0] += nCuts0 * nCuts1; + for ( pCut0 = pCuts0; pCut0 < pCut0Lim; pCut0++ ) + for ( pCut1 = pCuts1; pCut1 < pCut1Lim; pCut1++ ) + { + if ( (int)(pCut0->nLeaves + pCut1->nLeaves) > nLutSize && Pf_CutCountBits(pCut0->Sign | pCut1->Sign) > nLutSize ) + continue; + p->CutCount[1]++; + if ( !Pf_CutMergeOrder(pCut0, pCut1, pCutsR[nCutsR], nLutSize) ) + continue; + if ( Pf_SetLastCutIsContained(pCutsR, nCutsR) ) + continue; + p->CutCount[2]++; + if ( Pf_CutComputeTruth6(p, pCut0, pCut1, fComp0, fComp1, pCutsR[nCutsR], fIsXor) ) + pCutsR[nCutsR]->Sign = Pf_CutGetSign(pCutsR[nCutsR]->pLeaves, pCutsR[nCutsR]->nLeaves); + Pf_CutParams( p, pCutsR[nCutsR], nGiaRefs ); + nCutsR = Pf_SetAddCut( pCutsR, nCutsR, nCutNum ); + } + } + // debug printout + if ( 0 ) +// if ( iObj % 10000 == 0 ) +// if ( iObj == 1090 ) + { + printf( "*** Obj = %d Useful = %d\n", iObj, Pf_ManCountUseful(pCutsR, nCutsR) ); + for ( i = 0; i < nCutsR; i++ ) + Pf_Cutprintf( p, pCutsR[i] ); + printf( "\n" ); + } + // verify + assert( nCutsR > 0 && nCutsR < nCutNum ); +// assert( Pf_SetCheckArray(pCutsR, nCutsR) ); + // store the cutset + Pf_ObjSetCutFlow( p, iObj, pCutsR[0]->Flow ); + Pf_ObjSetCutDelay( p, iObj, pCutsR[0]->Delay ); + *Vec_IntEntryP(&p->vCutSets, iObj) = Pf_ManSaveCuts(p, pCutsR, nCutsR, 0); + p->CutCount[3] += nCutsR; + nCutsUse = Pf_ManCountUseful(pCutsR, nCutsR); + p->CutCount[4] += nCutsUse; + p->nCutUseAll += nCutsUse == nCutsR; + p->CutCount[5] += Pf_ManCountMatches(p, pCutsR, nCutsR); +} +void Pf_ManComputeCuts( Pf_Man_t * p ) +{ + Gia_Obj_t * pObj; int i, iFanin; + Gia_ManForEachAnd( p->pGia, pObj, i ) + if ( Gia_ObjIsBuf(pObj) ) + { + iFanin = Gia_ObjFaninId0(pObj, i); + Pf_ObjSetCutFlow( p, i, Pf_ObjCutFlow(p, iFanin) ); + Pf_ObjSetCutDelay( p, i, Pf_ObjCutDelay(p, iFanin) ); + } + else + Pf_ObjMergeOrder( p, i ); +} + + + + +/**Function************************************************************* + + Synopsis [] + + Description [] + + SideEffects [] + + SeeAlso [] + +***********************************************************************/ +void Pf_ManPrintStats( Pf_Man_t * p, char * pTitle ) +{ + if ( !p->pPars->fVerbose ) + return; + printf( "%s : ", pTitle ); + printf( "Delay =%8.2f ", p->pPars->MapDelay ); + printf( "Area =%12.2f ", p->pPars->MapArea ); + printf( "Gate =%6d ", (int)p->pPars->Area ); + printf( "Inv =%6d ", (int)p->nInvs ); + printf( "Edge =%7d ", (int)p->pPars->Edge ); + Abc_PrintTime( 1, "Time", Abc_Clock() - p->clkStart ); + fflush( stdout ); +} +void Pf_ManPrintInit( Pf_Man_t * p ) +{ + int nChoices; + if ( !p->pPars->fVerbose ) + return; + printf( "LutSize = %d ", p->pPars->nLutSize ); + printf( "CutNum = %d ", p->pPars->nCutNum ); + printf( "Iter = %d ", p->pPars->nRounds + p->pPars->nRoundsEla ); + printf( "Coarse = %d ", p->pPars->fCoarsen ); + printf( "Cells = %d ", p->nCells ); + printf( "Funcs = %d ", Vec_MemEntryNum(p->vTtMem) ); + printf( "Matches = %d ", Vec_WecSizeSize(p->vTt2Match)/2 ); + nChoices = Gia_ManChoiceNum( p->pGia ); + if ( nChoices ) + printf( "Choices = %d ", nChoices ); + printf( "\n" ); + printf( "Computing cuts...\r" ); + fflush( stdout ); +} +void Pf_ManPrintQuit( Pf_Man_t * p ) +{ + float MemGia = Gia_ManMemory(p->pGia) / (1<<20); + float MemMan =(1.0 * sizeof(Pf_Obj_t) + 3.0 * sizeof(int)) * Gia_ManObjNum(p->pGia) / (1<<20); + float MemCuts = 1.0 * sizeof(int) * (1 << 16) * Vec_PtrSize(&p->vPages) / (1<<20); + float MemTt = p->vTtMem ? Vec_MemMemory(p->vTtMem) / (1<<20) : 0; + if ( p->CutCount[0] == 0 ) + p->CutCount[0] = 1; + if ( !p->pPars->fVerbose ) + return; + printf( "CutPair = %.0f ", p->CutCount[0] ); + printf( "Merge = %.0f (%.1f) ", p->CutCount[1], 1.0*p->CutCount[1]/Gia_ManAndNum(p->pGia) ); + printf( "Eval = %.0f (%.1f) ", p->CutCount[2], 1.0*p->CutCount[2]/Gia_ManAndNum(p->pGia) ); + printf( "Cut = %.0f (%.1f) ", p->CutCount[3], 1.0*p->CutCount[3]/Gia_ManAndNum(p->pGia) ); + printf( "Use = %.0f (%.1f) ", p->CutCount[4], 1.0*p->CutCount[4]/Gia_ManAndNum(p->pGia) ); + printf( "Mat = %.0f (%.1f) ", p->CutCount[5], 1.0*p->CutCount[5]/Gia_ManAndNum(p->pGia) ); +// printf( "Equ = %d (%.2f %%) ", p->nCutUseAll, 100.0*p->nCutUseAll /p->CutCount[0] ); + printf( "\n" ); + printf( "Gia = %.2f MB ", MemGia ); + printf( "Man = %.2f MB ", MemMan ); + printf( "Cut = %.2f MB ", MemCuts ); + printf( "TT = %.2f MB ", MemTt ); + printf( "Total = %.2f MB ", MemGia + MemMan + MemCuts + MemTt ); +// printf( "\n" ); + Abc_PrintTime( 1, "Time", Abc_Clock() - p->clkStart ); + fflush( stdout ); +} + + +/**Function************************************************************* + + Synopsis [] + + Description [] + + SideEffects [] + + SeeAlso [] + +***********************************************************************/ +/* +void Pf_ManSetMapRefsGate( Pf_Man_t * p, int iObj, float Required, Pf_Mat_t * pM ) +{ + int k, iVar, fCompl; + Mio_Cell_t * pCell = Pf_ManCell( p, pM->Gate ); + int * pCut = Pf_CutFromHandle( Pf_ObjCutSet(p, iObj), pM->CutH ); + Pf_CutForEachVar( pCut, pM->Conf, iVar, fCompl, k ) + { + Pf_ObjMapRefInc( p, iVar, fCompl ); + Pf_ObjUpdateRequired( p, iVar, fCompl, Required - pCell->Delays[k] ); + } + assert( Pf_CutSize(pCut) == (int)pCell->nFanins ); + // update global stats + p->pPars->MapArea += pCell->Area; + p->pPars->Edge += Pf_CutSize(pCut); + p->pPars->Area++; + // update status of the gate + assert( pM->fBest == 0 ); + pM->fBest = 1; +} +int Pf_ManSetMapRefs( Pf_Man_t * p ) +{ + float Coef = 1.0 / (1.0 + (p->Iter + 1) * (p->Iter + 1)); + float * pFlowRefs = Vec_FltArray( &p->vFlowRefs ); + int * pMapRefs = Vec_IntArray( &p->vMapRefs ); + float Epsilon = p->pPars->Epsilon; + int nLits = 2*Gia_ManObjNum(p->pGia); + int i, c, Id, nRefs[2]; + Pf_Mat_t * pD, * pA, * pM; + Pf_Mat_t * pDs[2], * pAs[2], * pMs[2]; + Gia_Obj_t * pObj; + float Required = 0, Requireds[2]; + // check references + assert( !p->fUseEla ); + memset( pMapRefs, 0, sizeof(int) * nLits ); + Vec_FltFill( &p->vRequired, nLits, PF_INFINITY ); +// for ( i = 0; i < Gia_ManObjNum(p->pGia); i++ ) +// assert( !Pf_ObjMapRefNum(p, i, 0) && !Pf_ObjMapRefNum(p, i, 1) ); + // compute delay + p->pPars->MapDelay = 0; + Gia_ManForEachCo( p->pGia, pObj, i ) + { + Required = Pf_ObjMatchD( p, Gia_ObjFaninId0p(p->pGia, pObj), Gia_ObjFaninC0(pObj) )->D; + if ( Required == PF_INFINITY ) + { + Pf_ManCutMatchprintf( p, Gia_ObjFaninId0p(p->pGia, pObj), Gia_ObjFaninC0(pObj), Pf_ObjMatchD( p, Gia_ObjFaninId0p(p->pGia, pObj), Gia_ObjFaninC0(pObj) ) ); + } + p->pPars->MapDelay = Abc_MaxFloat( p->pPars->MapDelay, Required ); + } + // check delay target + if ( p->pPars->MapDelayTarget == -1 && p->pPars->nRelaxRatio ) + p->pPars->MapDelayTarget = (int)((float)p->pPars->MapDelay * (100.0 + p->pPars->nRelaxRatio) / 100.0); + if ( p->pPars->MapDelayTarget != -1 ) + { + if ( p->pPars->MapDelay < p->pPars->MapDelayTarget + Epsilon ) + p->pPars->MapDelay = p->pPars->MapDelayTarget; + else if ( p->pPars->nRelaxRatio == 0 ) + Abc_Print( 0, "Relaxing user-specified delay target from %.2f to %.2f.\n", p->pPars->MapDelayTarget, p->pPars->MapDelay ); + } + // set required times + Gia_ManForEachCo( p->pGia, pObj, i ) + { + Required = Pf_ObjMatchD( p, Gia_ObjFaninId0p(p->pGia, pObj), Gia_ObjFaninC0(pObj) )->D; + Required = p->pPars->fDoAverage ? Required * (100.0 + p->pPars->nRelaxRatio) / 100.0 : p->pPars->MapDelay; + Pf_ObjUpdateRequired( p, Gia_ObjFaninId0p(p->pGia, pObj), Gia_ObjFaninC0(pObj), Required ); + Pf_ObjMapRefInc( p, Gia_ObjFaninId0p(p->pGia, pObj), Gia_ObjFaninC0(pObj)); + } + // compute area and edges + p->nInvs = 0; + p->pPars->MapArea = 0; + p->pPars->Area = p->pPars->Edge = 0; + Gia_ManForEachAndReverse( p->pGia, pObj, i ) + { + if ( Gia_ObjIsBuf(pObj) ) + { + if ( Pf_ObjMapRefNum(p, i, 1) ) + { + Pf_ObjMapRefInc( p, i, 0 ); + Pf_ObjUpdateRequired( p, i, 0, Pf_ObjRequired(p, i, 1) - p->InvDelay ); + p->pPars->MapArea += p->InvArea; + p->pPars->Edge++; + p->pPars->Area++; + p->nInvs++; + } + Pf_ObjUpdateRequired( p, Gia_ObjFaninId0(pObj, i), Gia_ObjFaninC0(pObj), Pf_ObjRequired(p, i, 0) ); + Pf_ObjMapRefInc( p, Gia_ObjFaninId0(pObj, i), Gia_ObjFaninC0(pObj)); + continue; + } + // skip if this node is not used + for ( c = 0; c < 2; c++ ) + { + nRefs[c] = Pf_ObjMapRefNum(p, i, c); + + //if ( Pf_ObjMatchD( p, i, c )->fCompl ) + // printf( "Match D of node %d has inv in phase %d.\n", i, c ); + //if ( Pf_ObjMatchA( p, i, c )->fCompl ) + // printf( "Match A of node %d has inv in phase %d.\n", i, c ); + } + if ( !nRefs[0] && !nRefs[1] ) + continue; + + // consider two cases + if ( nRefs[0] && nRefs[1] ) + { + // find best matches for both phases + for ( c = 0; c < 2; c++ ) + { + Requireds[c] = Pf_ObjRequired( p, i, c ); + //assert( Requireds[c] < PF_INFINITY ); + pDs[c] = Pf_ObjMatchD( p, i, c ); + pAs[c] = Pf_ObjMatchA( p, i, c ); + pMs[c] = (pAs[c]->D < Requireds[c] + Epsilon) ? pAs[c] : pDs[c]; + } + // swap complemented matches + if ( pMs[0]->fCompl && pMs[1]->fCompl ) + { + pMs[0]->fCompl = pMs[1]->fCompl = 0; + ABC_SWAP( Pf_Mat_t *, pMs[0], pMs[1] ); + } + // check if intervers are involved + if ( !pMs[0]->fCompl && !pMs[1]->fCompl ) + { + // no inverters + for ( c = 0; c < 2; c++ ) + Pf_ManSetMapRefsGate( p, i, Requireds[c], pMs[c] ); + } + else + { + // one interver + assert( !pMs[0]->fCompl || !pMs[1]->fCompl ); + c = pMs[1]->fCompl; + assert( pMs[c]->fCompl && !pMs[!c]->fCompl ); + //printf( "Using inverter at node %d in phase %d\n", i, c ); + + // update this phase phase + pM = pMs[c]; + pM->fBest = 1; + Required = Requireds[c]; + + // update opposite phase + Pf_ObjMapRefInc( p, i, !c ); + Pf_ObjUpdateRequired( p, i, !c, Required - p->InvDelay ); + + // select oppositve phase + Required = Pf_ObjRequired( p, i, !c ); + //assert( Required < PF_INFINITY ); + pD = Pf_ObjMatchD( p, i, !c ); + pA = Pf_ObjMatchA( p, i, !c ); + pM = (pA->D < Required + Epsilon) ? pA : pD; + assert( !pM->fCompl ); + + // account for the inverter + p->pPars->MapArea += p->InvArea; + p->pPars->Edge++; + p->pPars->Area++; + p->nInvs++; + + // create gate + Pf_ManSetMapRefsGate( p, i, Required, pM ); + } + } + else + { + c = (int)(nRefs[1] > 0); + assert( nRefs[c] && !nRefs[!c] ); + // consider this phase + Required = Pf_ObjRequired( p, i, c ); + //assert( Required < PF_INFINITY ); + pD = Pf_ObjMatchD( p, i, c ); + pA = Pf_ObjMatchA( p, i, c ); + pM = (pA->D < Required + Epsilon) ? pA : pD; + + if ( pM->fCompl ) // use inverter + { + p->nInvs++; + //printf( "Using inverter at node %d in phase %d\n", i, c ); + pM->fBest = 1; + // update opposite phase + Pf_ObjMapRefInc( p, i, !c ); + Pf_ObjUpdateRequired( p, i, !c, Required - p->InvDelay ); + // select oppositve phase + Required = Pf_ObjRequired( p, i, !c ); + //assert( Required < PF_INFINITY ); + pD = Pf_ObjMatchD( p, i, !c ); + pA = Pf_ObjMatchA( p, i, !c ); + pM = (pA->D < Required + Epsilon) ? pA : pD; + assert( !pM->fCompl ); + + // account for the inverter + p->pPars->MapArea += p->InvArea; + p->pPars->Edge++; + p->pPars->Area++; + } + + // create gate + Pf_ManSetMapRefsGate( p, i, Required, pM ); + } + + + // the result of this: + // - only one phase can be implemented as inverter of the other phase + // - required times are propagated correctly + // - references are set correctly + } + Gia_ManForEachCiId( p->pGia, Id, i ) + if ( Pf_ObjMapRefNum(p, Id, 1) ) + { + Pf_ObjMapRefInc( p, Id, 0 ); + Pf_ObjUpdateRequired( p, Id, 0, Required - p->InvDelay ); + p->pPars->MapArea += p->InvArea; + p->pPars->Edge++; + p->pPars->Area++; + p->nInvs++; + } + // blend references + for ( i = 0; i < nLits; i++ ) +// pFlowRefs[i] = Abc_MaxFloat(1.0, pMapRefs[i]); + pFlowRefs[i] = Abc_MaxFloat(1.0, Coef * pFlowRefs[i] + (1.0 - Coef) * Abc_MaxFloat(1, pMapRefs[i])); +// pFlowRefs[i] = 0.2 * pFlowRefs[i] + 0.8 * Abc_MaxFloat(1, pMapRefs[i]); +// memset( pMapRefs, 0, sizeof(int) * nLits ); + return p->pPars->Area; +} +Gia_Man_t * Pf_ManDeriveMapping( Pf_Man_t * p ) +{ + Vec_Int_t * vMapping; + Pf_Mat_t * pM; + int i, k, c, Id, iLit, * pCut; + assert( p->pGia->vCellMapping == NULL ); + vMapping = Vec_IntAlloc( 2*Gia_ManObjNum(p->pGia) + (int)p->pPars->Edge + (int)p->pPars->Area * 2 ); + Vec_IntFill( vMapping, 2*Gia_ManObjNum(p->pGia), 0 ); + // create CI inverters + Gia_ManForEachCiId( p->pGia, Id, i ) + if ( Pf_ObjMapRefNum(p, Id, 1) ) + Vec_IntWriteEntry( vMapping, Abc_Var2Lit(Id, 1), -1 ); + // create internal nodes + Gia_ManForEachAndId( p->pGia, i ) + { + Gia_Obj_t * pObj = Gia_ManObj(p->pGia, i); + if ( Gia_ObjIsBuf(pObj) ) + { + if ( Pf_ObjMapRefNum(p, i, 1) ) + Vec_IntWriteEntry( vMapping, Abc_Var2Lit(i, 1), -1 ); + Vec_IntWriteEntry( vMapping, Abc_Var2Lit(i, 0), -2 ); + continue; + } + for ( c = 0; c < 2; c++ ) + if ( Pf_ObjMapRefNum(p, i, c) ) + { + // printf( "Using %d %d\n", i, c ); + pM = Pf_ObjMatchBest( p, i, c ); + // remember inverter + if ( pM->fCompl ) + { + Vec_IntWriteEntry( vMapping, Abc_Var2Lit(i, c), -1 ); + continue; + } + // Pf_ManCutMatchprintf( p, i, c, pM ); + pCut = Pf_CutFromHandle( Pf_ObjCutSet(p, i), pM->CutH ); + // create mapping + Vec_IntWriteEntry( vMapping, Abc_Var2Lit(i, c), Vec_IntSize(vMapping) ); + Vec_IntPush( vMapping, Pf_CutSize(pCut) ); + Pf_CutForEachLit( pCut, pM->Conf, iLit, k ) + Vec_IntPush( vMapping, iLit ); + Vec_IntPush( vMapping, pM->Gate ); + } + } +// assert( Vec_IntCap(vMapping) == 16 || Vec_IntSize(vMapping) == Vec_IntCap(vMapping) ); + p->pGia->vCellMapping = vMapping; + return p->pGia; +} +*/ + + +/**Function************************************************************* + + Synopsis [Technology mappping.] + + Description [] + + SideEffects [] + + SeeAlso [] + +***********************************************************************/ +void Pf_ManComputeMapping( Pf_Man_t * p ) +{ +} + +/**Function************************************************************* + + Synopsis [Technology mappping.] + + Description [] + + SideEffects [] + + SeeAlso [] + +***********************************************************************/ +void Pf_ManSetDefaultPars( Jf_Par_t * pPars ) +{ + memset( pPars, 0, sizeof(Jf_Par_t) ); + pPars->nLutSize = 6; + pPars->nCutNum = 16; + pPars->nProcNum = 0; + pPars->nRounds = 3; + pPars->nRoundsEla = 0; + pPars->nRelaxRatio = 0; + pPars->nCoarseLimit = 3; + pPars->nAreaTuner = 1; + pPars->nVerbLimit = 5; + pPars->DelayTarget = -1; + pPars->fAreaOnly = 0; + pPars->fOptEdge = 1; + pPars->fCoarsen = 0; + pPars->fCutMin = 1; + pPars->fGenCnf = 0; + pPars->fPureAig = 0; + pPars->fVerbose = 0; + pPars->fVeryVerbose = 0; + pPars->nLutSizeMax = PF_LEAF_MAX; + pPars->nCutNumMax = PF_CUT_MAX; + pPars->MapDelayTarget = -1; + pPars->Epsilon = (float)0.01; +} +Gia_Man_t * Pf_ManPerformMapping( Gia_Man_t * pGia, Jf_Par_t * pPars ) +{ + Gia_Man_t * pNew = NULL, * pCls; + Pf_Man_t * p; + if ( Gia_ManHasChoices(pGia) ) + pPars->fCoarsen = 0; + pCls = pPars->fCoarsen ? Gia_ManDupMuxes(pGia, pPars->nCoarseLimit) : pGia; + p = Pf_StoCreate( pCls, pPars ); +// if ( pPars->fVeryVerbose ) + Pf_StoPrint( p, 1 ); + if ( pPars->fVerbose && pPars->fCoarsen ) + { + printf( "Initial " ); Gia_ManPrintMuxStats( pGia ); printf( "\n" ); + printf( "Derived " ); Gia_ManPrintMuxStats( pCls ); printf( "\n" ); + } + Pf_ManPrintInit( p ); + Pf_ManComputeCuts( p ); + Pf_ManPrintQuit( p ); +/* + Gia_ManForEachCiId( p->pGia, Id, i ) + Pf_ObjPrepareCi( p, Id ); + for ( p->Iter = 0; p->Iter < p->pPars->nRounds; p->Iter++ ) + { + Pf_ManComputeMapping( p ); + //Pf_ManSetMapRefs( p ); + Pf_ManPrintStats( p, p->Iter ? "Area " : "Delay" ); + } + p->fUseEla = 1; + for ( ; p->Iter < p->pPars->nRounds + pPars->nRoundsEla; p->Iter++ ) + { + Pf_ManComputeMapping( p ); + //Pf_ManUpdateStats( p ); + Pf_ManPrintStats( p, "Ela " ); + } +*/ + pNew = NULL; //Pf_ManDeriveMapping( p ); +// Gia_ManMappingVerify( pNew ); + Pf_StoDelete( p ); + if ( pCls != pGia ) + Gia_ManStop( pCls ); + if ( pNew == NULL ) + return Gia_ManDup( pGia ); + return pNew; +} + +//////////////////////////////////////////////////////////////////////// +/// END OF FILE /// +//////////////////////////////////////////////////////////////////////// + + +ABC_NAMESPACE_IMPL_END + diff --git a/src/aig/gia/module.make b/src/aig/gia/module.make index 0c456333..f8794bcf 100644 --- a/src/aig/gia/module.make +++ b/src/aig/gia/module.make @@ -47,6 +47,7 @@ SRC += src/aig/gia/giaAig.c \ src/aig/gia/giaMuxes.c \ src/aig/gia/giaNf.c \ src/aig/gia/giaPat.c \ + src/aig/gia/giaPf.c \ src/aig/gia/giaQbf.c \ src/aig/gia/giaResub.c \ src/aig/gia/giaRetime.c \ diff --git a/src/base/abci/abc.c b/src/base/abci/abc.c index fce7c6dd..194c0592 100644 --- a/src/base/abci/abc.c +++ b/src/base/abci/abc.c @@ -33227,6 +33227,7 @@ int Abc_CommandAbc9Nf( Abc_Frame_t * pAbc, int argc, char ** argv ) { extern void Nf_ManSetDefaultPars( Jf_Par_t * pPars ); extern Gia_Man_t * Nf_ManPerformMapping( Gia_Man_t * pGia, Jf_Par_t * pPars ); + extern Gia_Man_t * Pf_ManPerformMapping( Gia_Man_t * pGia, Jf_Par_t * pPars ); char Buffer[200]; Jf_Par_t Pars, * pPars = &Pars; Gia_Man_t * pNew; int c; @@ -33368,7 +33369,10 @@ int Abc_CommandAbc9Nf( Abc_Frame_t * pAbc, int argc, char ** argv ) Abc_Print( -1, "Current library is not available.\n" ); return 1; } - pNew = Nf_ManPerformMapping( pAbc->pGia, pPars ); +// if ( pPars->fAreaOnly ) +// pNew = Pf_ManPerformMapping( pAbc->pGia, pPars ); +// else + pNew = Nf_ManPerformMapping( pAbc->pGia, pPars ); if ( pNew == NULL ) { Abc_Print( -1, "Abc_CommandAbc9Nf(): Mapping into LUTs has failed.\n" ); @@ -33382,17 +33386,17 @@ usage: sprintf(Buffer, "best possible" ); else sprintf(Buffer, "%d", pPars->DelayTarget ); - Abc_Print( -2, "usage: &nf [-KCFRLED num] [-kvwh]\n" ); + Abc_Print( -2, "usage: &nf [-KCFARLED num] [-akvwh]\n" ); Abc_Print( -2, "\t performs technology mapping of the network\n" ); Abc_Print( -2, "\t-K num : LUT size for the mapping (2 <= K <= %d) [default = %d]\n", pPars->nLutSizeMax, pPars->nLutSize ); Abc_Print( -2, "\t-C num : the max number of priority cuts (1 <= C <= %d) [default = %d]\n", pPars->nCutNumMax, pPars->nCutNum ); Abc_Print( -2, "\t-F num : the number of area flow rounds [default = %d]\n", pPars->nRounds ); -// Abc_Print( -2, "\t-A num : the number of exact area rounds [default = %d]\n", pPars->nRoundsEla ); + Abc_Print( -2, "\t-A num : the number of exact area rounds (when \'-a\' is used) [default = %d]\n", pPars->nRoundsEla ); Abc_Print( -2, "\t-R num : the delay relaxation ratio (num >= 0) [default = %d]\n", pPars->nRelaxRatio ); Abc_Print( -2, "\t-L num : the fanout limit for coarsening XOR/MUX (num >= 2) [default = %d]\n", pPars->nCoarseLimit ); Abc_Print( -2, "\t-E num : the area/edge tradeoff parameter (0 <= num <= 100) [default = %d]\n", pPars->nAreaTuner ); Abc_Print( -2, "\t-D num : sets the delay constraint for the mapping [default = %s]\n", Buffer ); -// Abc_Print( -2, "\t-a : toggles area-oriented mapping [default = %s]\n", pPars->fAreaOnly? "yes": "no" ); + Abc_Print( -2, "\t-a : toggles area-oriented mapping [default = %s]\n", pPars->fAreaOnly? "yes": "no" ); Abc_Print( -2, "\t-k : toggles coarsening the subject graph [default = %s]\n", pPars->fCoarsen? "yes": "no" ); Abc_Print( -2, "\t-v : toggles verbose output [default = %s]\n", pPars->fVerbose? "yes": "no" ); Abc_Print( -2, "\t-w : toggles very verbose output [default = %s]\n", pPars->fVeryVerbose? "yes": "no" ); |