From 4d30a1e4f1edecff86d5066ce4653a370e59e5e1 Mon Sep 17 00:00:00 2001 From: Alan Mishchenko Date: Wed, 30 Jan 2008 08:01:00 -0800 Subject: Version abc80130 --- src/aig/kit/kitDsd.c | 2621 -------------------------------------------------- 1 file changed, 2621 deletions(-) delete mode 100644 src/aig/kit/kitDsd.c (limited to 'src/aig/kit/kitDsd.c') diff --git a/src/aig/kit/kitDsd.c b/src/aig/kit/kitDsd.c deleted file mode 100644 index e24a9964..00000000 --- a/src/aig/kit/kitDsd.c +++ /dev/null @@ -1,2621 +0,0 @@ -/**CFile**************************************************************** - - FileName [kitDsd.c] - - SystemName [ABC: Logic synthesis and verification system.] - - PackageName [Computation kit.] - - Synopsis [Performs disjoint-support decomposition based on truth tables.] - - Author [Alan Mishchenko] - - Affiliation [UC Berkeley] - - Date [Ver. 1.0. Started - Dec 6, 2006.] - - Revision [$Id: kitDsd.c,v 1.00 2006/12/06 00:00:00 alanmi Exp $] - -***********************************************************************/ - -#include "kit.h" - -//////////////////////////////////////////////////////////////////////// -/// DECLARATIONS /// -//////////////////////////////////////////////////////////////////////// - -//////////////////////////////////////////////////////////////////////// -/// FUNCTION DEFINITIONS /// -//////////////////////////////////////////////////////////////////////// - -/**Function************************************************************* - - Synopsis [Allocates the DSD manager.] - - Description [] - - SideEffects [] - - SeeAlso [] - -***********************************************************************/ -Kit_DsdMan_t * Kit_DsdManAlloc( int nVars, int nNodes ) -{ - Kit_DsdMan_t * p; - p = ALLOC( Kit_DsdMan_t, 1 ); - memset( p, 0, sizeof(Kit_DsdMan_t) ); - p->nVars = nVars; - p->nWords = Kit_TruthWordNum( p->nVars ); - p->vTtElems = Vec_PtrAllocTruthTables( p->nVars ); - p->vTtNodes = Vec_PtrAllocSimInfo( nNodes, p->nWords ); - p->dd = Cloud_Init( 16, 14 ); - p->vTtBdds = Vec_PtrAllocSimInfo( (1<<12), p->nWords ); - p->vNodes = Vec_IntAlloc( 512 ); - return p; -} - -/**Function************************************************************* - - Synopsis [Deallocates the DSD manager.] - - Description [] - - SideEffects [] - - SeeAlso [] - -***********************************************************************/ -void Kit_DsdManFree( Kit_DsdMan_t * p ) -{ - Cloud_Quit( p->dd ); - Vec_IntFree( p->vNodes ); - Vec_PtrFree( p->vTtBdds ); - Vec_PtrFree( p->vTtElems ); - Vec_PtrFree( p->vTtNodes ); - free( p ); -} - -/**Function************************************************************* - - Synopsis [Allocates the DSD node.] - - Description [] - - SideEffects [] - - SeeAlso [] - -***********************************************************************/ -Kit_DsdObj_t * Kit_DsdObjAlloc( Kit_DsdNtk_t * pNtk, Kit_Dsd_t Type, int nFans ) -{ - Kit_DsdObj_t * pObj; - int nSize = sizeof(Kit_DsdObj_t) + sizeof(unsigned) * (Kit_DsdObjOffset(nFans) + (Type == KIT_DSD_PRIME) * Kit_TruthWordNum(nFans)); - pObj = (Kit_DsdObj_t *)ALLOC( char, nSize ); - memset( pObj, 0, nSize ); - pObj->Id = pNtk->nVars + pNtk->nNodes; - pObj->Type = Type; - pObj->nFans = nFans; - pObj->Offset = Kit_DsdObjOffset( nFans ); - // add the object - if ( pNtk->nNodes == pNtk->nNodesAlloc ) - { - pNtk->nNodesAlloc *= 2; - pNtk->pNodes = REALLOC( Kit_DsdObj_t *, pNtk->pNodes, pNtk->nNodesAlloc ); - } - assert( pNtk->nNodes < pNtk->nNodesAlloc ); - pNtk->pNodes[pNtk->nNodes++] = pObj; - return pObj; -} - -/**Function************************************************************* - - Synopsis [Deallocates the DSD node.] - - Description [] - - SideEffects [] - - SeeAlso [] - -***********************************************************************/ -void Kit_DsdObjFree( Kit_DsdNtk_t * p, Kit_DsdObj_t * pObj ) -{ - free( pObj ); -} - -/**Function************************************************************* - - Synopsis [Allocates the DSD network.] - - Description [] - - SideEffects [] - - SeeAlso [] - -***********************************************************************/ -Kit_DsdNtk_t * Kit_DsdNtkAlloc( int nVars ) -{ - Kit_DsdNtk_t * pNtk; - pNtk = ALLOC( Kit_DsdNtk_t, 1 ); - memset( pNtk, 0, sizeof(Kit_DsdNtk_t) ); - pNtk->pNodes = ALLOC( Kit_DsdObj_t *, nVars ); - pNtk->nVars = nVars; - pNtk->nNodesAlloc = nVars; - pNtk->pMem = ALLOC( unsigned, 6 * Kit_TruthWordNum(nVars) ); - return pNtk; -} - -/**Function************************************************************* - - Synopsis [Deallocate the DSD network.] - - Description [] - - SideEffects [] - - SeeAlso [] - -***********************************************************************/ -void Kit_DsdNtkFree( Kit_DsdNtk_t * pNtk ) -{ - Kit_DsdObj_t * pObj; - unsigned i; - Kit_DsdNtkForEachObj( pNtk, pObj, i ) - free( pObj ); - FREE( pNtk->pSupps ); - free( pNtk->pNodes ); - free( pNtk->pMem ); - free( pNtk ); -} - -/**Function************************************************************* - - Synopsis [Prints the hex unsigned into a file.] - - Description [] - - SideEffects [] - - SeeAlso [] - -***********************************************************************/ -void Kit_DsdPrintHex( FILE * pFile, unsigned * pTruth, int nFans ) -{ - int nDigits, Digit, k; - nDigits = (1 << nFans) / 4; - for ( k = nDigits - 1; k >= 0; k-- ) - { - Digit = ((pTruth[k/8] >> ((k%8) * 4)) & 15); - if ( Digit < 10 ) - fprintf( pFile, "%d", Digit ); - else - fprintf( pFile, "%c", 'A' + Digit-10 ); - } -} - -/**Function************************************************************* - - Synopsis [Recursively print the DSD formula.] - - Description [] - - SideEffects [] - - SeeAlso [] - -***********************************************************************/ -void Kit_DsdPrint_rec( FILE * pFile, Kit_DsdNtk_t * pNtk, int Id ) -{ - Kit_DsdObj_t * pObj; - unsigned iLit, i; - char Symbol; - - pObj = Kit_DsdNtkObj( pNtk, Id ); - if ( pObj == NULL ) - { - assert( Id < pNtk->nVars ); - fprintf( pFile, "%c", 'a' + Id ); - return; - } - - if ( pObj->Type == KIT_DSD_CONST1 ) - { - assert( pObj->nFans == 0 ); - fprintf( pFile, "Const1" ); - return; - } - - if ( pObj->Type == KIT_DSD_VAR ) - assert( pObj->nFans == 1 ); - - if ( pObj->Type == KIT_DSD_AND ) - Symbol = '*'; - else if ( pObj->Type == KIT_DSD_XOR ) - Symbol = '+'; - else - Symbol = ','; - - if ( pObj->Type == KIT_DSD_PRIME ) - Kit_DsdPrintHex( stdout, Kit_DsdObjTruth(pObj), pObj->nFans ); - - fprintf( pFile, "(" ); - Kit_DsdObjForEachFanin( pNtk, pObj, iLit, i ) - { - if ( Kit_DsdLitIsCompl(iLit) ) - fprintf( pFile, "!" ); - Kit_DsdPrint_rec( pFile, pNtk, Kit_DsdLit2Var(iLit) ); - if ( i < pObj->nFans - 1 ) - fprintf( pFile, "%c", Symbol ); - } - fprintf( pFile, ")" ); -} - -/**Function************************************************************* - - Synopsis [Print the DSD formula.] - - Description [] - - SideEffects [] - - SeeAlso [] - -***********************************************************************/ -void Kit_DsdPrint( FILE * pFile, Kit_DsdNtk_t * pNtk ) -{ - fprintf( pFile, "F = " ); - if ( Kit_DsdLitIsCompl(pNtk->Root) ) - fprintf( pFile, "!" ); - Kit_DsdPrint_rec( pFile, pNtk, Kit_DsdLit2Var(pNtk->Root) ); - fprintf( pFile, "\n" ); -} - -/**Function************************************************************* - - Synopsis [Print the DSD formula.] - - Description [] - - SideEffects [] - - SeeAlso [] - -***********************************************************************/ -void Kit_DsdPrintExpanded( Kit_DsdNtk_t * pNtk ) -{ - Kit_DsdNtk_t * pTemp; - pTemp = Kit_DsdExpand( pNtk ); - Kit_DsdPrint( stdout, pTemp ); - Kit_DsdNtkFree( pTemp ); -} - -/**Function************************************************************* - - Synopsis [Print the DSD formula.] - - Description [] - - SideEffects [] - - SeeAlso [] - -***********************************************************************/ -void Kit_DsdPrintFromTruth( unsigned * pTruth, int nVars ) -{ - Kit_DsdNtk_t * pTemp; - pTemp = Kit_DsdDecomposeMux( pTruth, nVars, 5 ); - Kit_DsdVerify( pTemp, pTruth, nVars ); - Kit_DsdPrintExpanded( pTemp ); - Kit_DsdNtkFree( pTemp ); -} - -/**Function************************************************************* - - Synopsis [Derives the truth table of the DSD node.] - - Description [] - - SideEffects [] - - SeeAlso [] - -***********************************************************************/ -unsigned * Kit_DsdTruthComputeNode_rec( Kit_DsdMan_t * p, Kit_DsdNtk_t * pNtk, int Id ) -{ - Kit_DsdObj_t * pObj; - unsigned * pTruthRes, * pTruthFans[16], * pTruthTemp; - unsigned i, iLit, fCompl; -// unsigned m, nMints, * pTruthPrime, * pTruthMint; - - // get the node with this ID - pObj = Kit_DsdNtkObj( pNtk, Id ); - pTruthRes = Vec_PtrEntry( p->vTtNodes, Id ); - - // special case: literal of an internal node - if ( pObj == NULL ) - { - assert( Id < pNtk->nVars ); - return pTruthRes; - } - - // constant node - if ( pObj->Type == KIT_DSD_CONST1 ) - { - assert( pObj->nFans == 0 ); - Kit_TruthFill( pTruthRes, pNtk->nVars ); - return pTruthRes; - } - - // elementary variable node - if ( pObj->Type == KIT_DSD_VAR ) - { - assert( pObj->nFans == 1 ); - iLit = pObj->pFans[0]; - pTruthFans[0] = Kit_DsdTruthComputeNode_rec( p, pNtk, Kit_DsdLit2Var(iLit) ); - if ( Kit_DsdLitIsCompl(iLit) ) - Kit_TruthNot( pTruthRes, pTruthFans[0], pNtk->nVars ); - else - Kit_TruthCopy( pTruthRes, pTruthFans[0], pNtk->nVars ); - return pTruthRes; - } - - // collect the truth tables of the fanins - Kit_DsdObjForEachFanin( pNtk, pObj, iLit, i ) - pTruthFans[i] = Kit_DsdTruthComputeNode_rec( p, pNtk, Kit_DsdLit2Var(iLit) ); - // create the truth table - - // simple gates - if ( pObj->Type == KIT_DSD_AND ) - { - Kit_TruthFill( pTruthRes, pNtk->nVars ); - Kit_DsdObjForEachFanin( pNtk, pObj, iLit, i ) - Kit_TruthAndPhase( pTruthRes, pTruthRes, pTruthFans[i], pNtk->nVars, 0, Kit_DsdLitIsCompl(iLit) ); - return pTruthRes; - } - if ( pObj->Type == KIT_DSD_XOR ) - { - Kit_TruthClear( pTruthRes, pNtk->nVars ); - fCompl = 0; - Kit_DsdObjForEachFanin( pNtk, pObj, iLit, i ) - { - Kit_TruthXor( pTruthRes, pTruthRes, pTruthFans[i], pNtk->nVars ); - fCompl ^= Kit_DsdLitIsCompl(iLit); - } - if ( fCompl ) - Kit_TruthNot( pTruthRes, pTruthRes, pNtk->nVars ); - return pTruthRes; - } - assert( pObj->Type == KIT_DSD_PRIME ); -/* - // get the truth table of the prime node - pTruthPrime = Kit_DsdObjTruth( pObj ); - // get storage for the temporary minterm - pTruthMint = Vec_PtrEntry(p->vTtNodes, pNtk->nVars + pNtk->nNodes); - - // go through the minterms - nMints = (1 << pObj->nFans); - Kit_TruthClear( pTruthRes, pNtk->nVars ); - for ( m = 0; m < nMints; m++ ) - { - if ( !Kit_TruthHasBit(pTruthPrime, m) ) - continue; - Kit_TruthFill( pTruthMint, pNtk->nVars ); - Kit_DsdObjForEachFanin( pNtk, pObj, iLit, i ) - Kit_TruthAndPhase( pTruthMint, pTruthMint, pTruthFans[i], pNtk->nVars, 0, ((m & (1<nVars ); - } -*/ - pTruthTemp = Kit_TruthCompose( p->dd, Kit_DsdObjTruth(pObj), pObj->nFans, pTruthFans, pNtk->nVars, p->vTtBdds, p->vNodes ); - Kit_TruthCopy( pTruthRes, pTruthTemp, pNtk->nVars ); - return pTruthRes; -} - -/**Function************************************************************* - - Synopsis [Derives the truth table of the DSD network.] - - Description [] - - SideEffects [] - - SeeAlso [] - -***********************************************************************/ -unsigned * Kit_DsdTruthCompute( Kit_DsdMan_t * p, Kit_DsdNtk_t * pNtk ) -{ - unsigned * pTruthRes; - int i; - // assign elementary truth ables - assert( pNtk->nVars <= p->nVars ); - for ( i = 0; i < (int)pNtk->nVars; i++ ) - Kit_TruthCopy( Vec_PtrEntry(p->vTtNodes, i), Vec_PtrEntry(p->vTtElems, i), p->nVars ); - // compute truth table for each node - pTruthRes = Kit_DsdTruthComputeNode_rec( p, pNtk, Kit_DsdLit2Var(pNtk->Root) ); - // complement the truth table if needed - if ( Kit_DsdLitIsCompl(pNtk->Root) ) - Kit_TruthNot( pTruthRes, pTruthRes, pNtk->nVars ); - return pTruthRes; -} - -/**Function************************************************************* - - Synopsis [Derives the truth table of the DSD node.] - - Description [] - - SideEffects [] - - SeeAlso [] - -***********************************************************************/ -unsigned * Kit_DsdTruthComputeNodeOne_rec( Kit_DsdMan_t * p, Kit_DsdNtk_t * pNtk, int Id, unsigned uSupp ) -{ - Kit_DsdObj_t * pObj; - unsigned * pTruthRes, * pTruthFans[16], * pTruthTemp; - unsigned i, iLit, fCompl, nPartial = 0; -// unsigned m, nMints, * pTruthPrime, * pTruthMint; - - // get the node with this ID - pObj = Kit_DsdNtkObj( pNtk, Id ); - pTruthRes = Vec_PtrEntry( p->vTtNodes, Id ); - - // special case: literal of an internal node - if ( pObj == NULL ) - { - assert( Id < pNtk->nVars ); - assert( !uSupp || uSupp != (uSupp & ~(1<Type == KIT_DSD_CONST1 ) - { - assert( pObj->nFans == 0 ); - Kit_TruthFill( pTruthRes, pNtk->nVars ); - return pTruthRes; - } - - // elementary variable node - if ( pObj->Type == KIT_DSD_VAR ) - { - assert( pObj->nFans == 1 ); - iLit = pObj->pFans[0]; - assert( Kit_DsdLitIsLeaf( pNtk, iLit ) ); - pTruthFans[0] = Kit_DsdTruthComputeNodeOne_rec( p, pNtk, Kit_DsdLit2Var(iLit), uSupp ); - if ( Kit_DsdLitIsCompl(iLit) ) - Kit_TruthNot( pTruthRes, pTruthFans[0], pNtk->nVars ); - else - Kit_TruthCopy( pTruthRes, pTruthFans[0], pNtk->nVars ); - return pTruthRes; - } - - // collect the truth tables of the fanins - if ( uSupp ) - { - Kit_DsdObjForEachFanin( pNtk, pObj, iLit, i ) - if ( uSupp != (uSupp & ~Kit_DsdLitSupport(pNtk, iLit)) ) - pTruthFans[i] = Kit_DsdTruthComputeNodeOne_rec( p, pNtk, Kit_DsdLit2Var(iLit), uSupp ); - else - { - pTruthFans[i] = NULL; - nPartial = 1; - } - } - else - { - Kit_DsdObjForEachFanin( pNtk, pObj, iLit, i ) - pTruthFans[i] = Kit_DsdTruthComputeNodeOne_rec( p, pNtk, Kit_DsdLit2Var(iLit), uSupp ); - } - // create the truth table - - // simple gates - if ( pObj->Type == KIT_DSD_AND ) - { - Kit_TruthFill( pTruthRes, pNtk->nVars ); - Kit_DsdObjForEachFanin( pNtk, pObj, iLit, i ) - if ( pTruthFans[i] ) - Kit_TruthAndPhase( pTruthRes, pTruthRes, pTruthFans[i], pNtk->nVars, 0, Kit_DsdLitIsCompl(iLit) ); - return pTruthRes; - } - if ( pObj->Type == KIT_DSD_XOR ) - { - Kit_TruthClear( pTruthRes, pNtk->nVars ); - fCompl = 0; - Kit_DsdObjForEachFanin( pNtk, pObj, iLit, i ) - { - if ( pTruthFans[i] ) - { - Kit_TruthXor( pTruthRes, pTruthRes, pTruthFans[i], pNtk->nVars ); - fCompl ^= Kit_DsdLitIsCompl(iLit); - } - } - if ( fCompl ) - Kit_TruthNot( pTruthRes, pTruthRes, pNtk->nVars ); - return pTruthRes; - } - assert( pObj->Type == KIT_DSD_PRIME ); - - if ( uSupp && nPartial ) - { - // find the only non-empty component - Kit_DsdObjForEachFanin( pNtk, pObj, iLit, i ) - if ( pTruthFans[i] ) - break; - assert( i < pObj->nFans ); - return pTruthFans[i]; - } -/* - // get the truth table of the prime node - pTruthPrime = Kit_DsdObjTruth( pObj ); - // get storage for the temporary minterm - pTruthMint = Vec_PtrEntry(p->vTtNodes, pNtk->nVars + pNtk->nNodes); - - // go through the minterms - nMints = (1 << pObj->nFans); - Kit_TruthClear( pTruthRes, pNtk->nVars ); - for ( m = 0; m < nMints; m++ ) - { - if ( !Kit_TruthHasBit(pTruthPrime, m) ) - continue; - Kit_TruthFill( pTruthMint, pNtk->nVars ); - Kit_DsdObjForEachFanin( pNtk, pObj, iLit, i ) - Kit_TruthAndPhase( pTruthMint, pTruthMint, pTruthFans[i], pNtk->nVars, 0, ((m & (1<nVars ); - } -*/ - pTruthTemp = Kit_TruthCompose( p->dd, Kit_DsdObjTruth(pObj), pObj->nFans, pTruthFans, pNtk->nVars, p->vTtBdds, p->vNodes ); - Kit_TruthCopy( pTruthRes, pTruthTemp, pNtk->nVars ); - return pTruthRes; -} - -/**Function************************************************************* - - Synopsis [Derives the truth table of the DSD network.] - - Description [] - - SideEffects [] - - SeeAlso [] - -***********************************************************************/ -unsigned * Kit_DsdTruthComputeOne( Kit_DsdMan_t * p, Kit_DsdNtk_t * pNtk, unsigned uSupp ) -{ - unsigned * pTruthRes; - int i; - // if support is specified, request that supports are available - if ( uSupp ) - Kit_DsdGetSupports( pNtk ); - // assign elementary truth tables - assert( pNtk->nVars <= p->nVars ); - for ( i = 0; i < (int)pNtk->nVars; i++ ) - Kit_TruthCopy( Vec_PtrEntry(p->vTtNodes, i), Vec_PtrEntry(p->vTtElems, i), p->nVars ); - // compute truth table for each node - pTruthRes = Kit_DsdTruthComputeNodeOne_rec( p, pNtk, Kit_DsdLit2Var(pNtk->Root), uSupp ); - // complement the truth table if needed - if ( Kit_DsdLitIsCompl(pNtk->Root) ) - Kit_TruthNot( pTruthRes, pTruthRes, pNtk->nVars ); - return pTruthRes; -} - -/**Function************************************************************* - - Synopsis [Derives the truth table of the DSD node.] - - Description [] - - SideEffects [] - - SeeAlso [] - -***********************************************************************/ -unsigned * Kit_DsdTruthComputeNodeTwo_rec( Kit_DsdMan_t * p, Kit_DsdNtk_t * pNtk, int Id, unsigned uSupp, int iVar, unsigned * pTruthDec ) -{ - Kit_DsdObj_t * pObj; - int pfBoundSet[16]; - unsigned * pTruthRes, * pTruthFans[16], * pTruthTemp; - unsigned i, iLit, fCompl, nPartial, uSuppFan, uSuppCur; -// unsigned m, nMints, * pTruthPrime, * pTruthMint; - assert( uSupp > 0 ); - - // get the node with this ID - pObj = Kit_DsdNtkObj( pNtk, Id ); - pTruthRes = Vec_PtrEntry( p->vTtNodes, Id ); - if ( pObj == NULL ) - { - assert( Id < pNtk->nVars ); - return pTruthRes; - } - assert( pObj->Type != KIT_DSD_CONST1 ); - assert( pObj->Type != KIT_DSD_VAR ); - - // count the number of intersecting fanins - // collect the total support of the intersecting fanins - nPartial = 0; - uSuppFan = 0; - Kit_DsdObjForEachFanin( pNtk, pObj, iLit, i ) - { - uSuppCur = Kit_DsdLitSupport(pNtk, iLit); - if ( uSupp & uSuppCur ) - { - nPartial++; - uSuppFan |= uSuppCur; - } - } - - // if there is no intersection, or full intersection, use simple procedure - if ( nPartial == 0 || nPartial == pObj->nFans ) - return Kit_DsdTruthComputeNodeOne_rec( p, pNtk, Id, 0 ); - - // if support of the component includes some other variables - // we need to continue constructing it as usual by the two-function procedure - if ( uSuppFan != (uSuppFan & uSupp) ) - { - assert( nPartial == 1 ); -// return Kit_DsdTruthComputeNodeTwo_rec( p, pNtk, Id, uSupp, iVar, pTruthDec ); - Kit_DsdObjForEachFanin( pNtk, pObj, iLit, i ) - { - if ( uSupp & Kit_DsdLitSupport(pNtk, iLit) ) - pTruthFans[i] = Kit_DsdTruthComputeNodeTwo_rec( p, pNtk, Kit_DsdLit2Var(iLit), uSupp, iVar, pTruthDec ); - else - pTruthFans[i] = Kit_DsdTruthComputeNodeOne_rec( p, pNtk, Kit_DsdLit2Var(iLit), 0 ); - } - - // create composition/decomposition functions - if ( pObj->Type == KIT_DSD_AND ) - { - Kit_TruthFill( pTruthRes, pNtk->nVars ); - Kit_DsdObjForEachFanin( pNtk, pObj, iLit, i ) - Kit_TruthAndPhase( pTruthRes, pTruthRes, pTruthFans[i], pNtk->nVars, 0, Kit_DsdLitIsCompl(iLit) ); - return pTruthRes; - } - if ( pObj->Type == KIT_DSD_XOR ) - { - Kit_TruthClear( pTruthRes, pNtk->nVars ); - fCompl = 0; - Kit_DsdObjForEachFanin( pNtk, pObj, iLit, i ) - { - fCompl ^= Kit_DsdLitIsCompl(iLit); - Kit_TruthXor( pTruthRes, pTruthRes, pTruthFans[i], pNtk->nVars ); - } - if ( fCompl ) - Kit_TruthNot( pTruthRes, pTruthRes, pNtk->nVars ); - return pTruthRes; - } - assert( pObj->Type == KIT_DSD_PRIME ); - } - else - { - assert( uSuppFan == (uSuppFan & uSupp) ); - assert( nPartial < pObj->nFans ); - // the support of the insecting component(s) is contained in the bound-set - // and yet there are components that are not contained in the bound set - - // solve the fanins and collect info, which components belong to the bound set - Kit_DsdObjForEachFanin( pNtk, pObj, iLit, i ) - { - pTruthFans[i] = Kit_DsdTruthComputeNodeOne_rec( p, pNtk, Kit_DsdLit2Var(iLit), 0 ); - pfBoundSet[i] = (int)((uSupp & Kit_DsdLitSupport(pNtk, iLit)) > 0); - } - - // create composition/decomposition functions - if ( pObj->Type == KIT_DSD_AND ) - { - Kit_TruthIthVar( pTruthRes, pNtk->nVars, iVar ); - Kit_TruthFill( pTruthDec, pNtk->nVars ); - Kit_DsdObjForEachFanin( pNtk, pObj, iLit, i ) - if ( pfBoundSet[i] ) - Kit_TruthAndPhase( pTruthDec, pTruthDec, pTruthFans[i], pNtk->nVars, 0, Kit_DsdLitIsCompl(iLit) ); - else - Kit_TruthAndPhase( pTruthRes, pTruthRes, pTruthFans[i], pNtk->nVars, 0, Kit_DsdLitIsCompl(iLit) ); - return pTruthRes; - } - if ( pObj->Type == KIT_DSD_XOR ) - { - Kit_TruthIthVar( pTruthRes, pNtk->nVars, iVar ); - Kit_TruthClear( pTruthDec, pNtk->nVars ); - fCompl = 0; - Kit_DsdObjForEachFanin( pNtk, pObj, iLit, i ) - { - fCompl ^= Kit_DsdLitIsCompl(iLit); - if ( pfBoundSet[i] ) - Kit_TruthXor( pTruthDec, pTruthDec, pTruthFans[i], pNtk->nVars ); - else - Kit_TruthXor( pTruthRes, pTruthRes, pTruthFans[i], pNtk->nVars ); - } - if ( fCompl ) - Kit_TruthNot( pTruthRes, pTruthRes, pNtk->nVars ); - return pTruthRes; - } - assert( pObj->Type == KIT_DSD_PRIME ); - assert( nPartial == 1 ); - - // find the only non-empty component - Kit_DsdObjForEachFanin( pNtk, pObj, iLit, i ) - if ( pfBoundSet[i] ) - break; - assert( i < pObj->nFans ); - - // save this component as the decomposed function - Kit_TruthCopy( pTruthDec, pTruthFans[i], pNtk->nVars ); - // set the corresponding component to be the new variable - Kit_TruthIthVar( pTruthFans[i], pNtk->nVars, iVar ); - } -/* - // get the truth table of the prime node - pTruthPrime = Kit_DsdObjTruth( pObj ); - // get storage for the temporary minterm - pTruthMint = Vec_PtrEntry(p->vTtNodes, pNtk->nVars + pNtk->nNodes); - - // go through the minterms - nMints = (1 << pObj->nFans); - Kit_TruthClear( pTruthRes, pNtk->nVars ); - for ( m = 0; m < nMints; m++ ) - { - if ( !Kit_TruthHasBit(pTruthPrime, m) ) - continue; - Kit_TruthFill( pTruthMint, pNtk->nVars ); - Kit_DsdObjForEachFanin( pNtk, pObj, iLit, i ) - Kit_TruthAndPhase( pTruthMint, pTruthMint, pTruthFans[i], pNtk->nVars, 0, ((m & (1<nVars ); - } -*/ - Kit_DsdObjForEachFanin( pNtk, pObj, iLit, i ) - assert( !Kit_DsdLitIsCompl(iLit) ); - pTruthTemp = Kit_TruthCompose( p->dd, Kit_DsdObjTruth(pObj), pObj->nFans, pTruthFans, pNtk->nVars, p->vTtBdds, p->vNodes ); - Kit_TruthCopy( pTruthRes, pTruthTemp, pNtk->nVars ); - return pTruthRes; -} - -/**Function************************************************************* - - Synopsis [Derives the truth table of the DSD network.] - - Description [] - - SideEffects [] - - SeeAlso [] - -***********************************************************************/ -unsigned * Kit_DsdTruthComputeTwo( Kit_DsdMan_t * p, Kit_DsdNtk_t * pNtk, unsigned uSupp, int iVar, unsigned * pTruthDec ) -{ - unsigned * pTruthRes, uSuppAll; - int i; - assert( uSupp > 0 ); - assert( pNtk->nVars <= p->nVars ); - // compute support of all nodes - uSuppAll = Kit_DsdGetSupports( pNtk ); - // consider special case - there is no overlap - if ( (uSupp & uSuppAll) == 0 ) - { - Kit_TruthClear( pTruthDec, pNtk->nVars ); - return Kit_DsdTruthCompute( p, pNtk ); - } - // consider special case - support is fully contained - if ( (uSupp & uSuppAll) == uSuppAll ) - { - pTruthRes = Kit_DsdTruthCompute( p, pNtk ); - Kit_TruthCopy( pTruthDec, pTruthRes, pNtk->nVars ); - Kit_TruthIthVar( pTruthRes, pNtk->nVars, iVar ); - return pTruthRes; - } - // assign elementary truth tables - for ( i = 0; i < (int)pNtk->nVars; i++ ) - Kit_TruthCopy( Vec_PtrEntry(p->vTtNodes, i), Vec_PtrEntry(p->vTtElems, i), p->nVars ); - // compute truth table for each node - pTruthRes = Kit_DsdTruthComputeNodeTwo_rec( p, pNtk, Kit_DsdLit2Var(pNtk->Root), uSupp, iVar, pTruthDec ); - // complement the truth table if needed - if ( Kit_DsdLitIsCompl(pNtk->Root) ) - Kit_TruthNot( pTruthRes, pTruthRes, pNtk->nVars ); - return pTruthRes; -} - -/**Function************************************************************* - - Synopsis [Derives the truth table of the DSD network.] - - Description [] - - SideEffects [] - - SeeAlso [] - -***********************************************************************/ -void Kit_DsdTruth( Kit_DsdNtk_t * pNtk, unsigned * pTruthRes ) -{ - Kit_DsdMan_t * p; - unsigned * pTruth; - p = Kit_DsdManAlloc( pNtk->nVars, Kit_DsdNtkObjNum(pNtk) ); - pTruth = Kit_DsdTruthCompute( p, pNtk ); - Kit_TruthCopy( pTruthRes, pTruth, pNtk->nVars ); - Kit_DsdManFree( p ); -} - -/**Function************************************************************* - - Synopsis [Derives the truth table of the DSD network.] - - Description [] - - SideEffects [] - - SeeAlso [] - -***********************************************************************/ -void Kit_DsdTruthPartialTwo( Kit_DsdMan_t * p, Kit_DsdNtk_t * pNtk, unsigned uSupp, int iVar, unsigned * pTruthCo, unsigned * pTruthDec ) -{ - unsigned * pTruth = Kit_DsdTruthComputeTwo( p, pNtk, uSupp, iVar, pTruthDec ); - if ( pTruthCo ) - Kit_TruthCopy( pTruthCo, pTruth, pNtk->nVars ); -} - -/**Function************************************************************* - - Synopsis [Derives the truth table of the DSD network.] - - Description [] - - SideEffects [] - - SeeAlso [] - -***********************************************************************/ -void Kit_DsdTruthPartial( Kit_DsdMan_t * p, Kit_DsdNtk_t * pNtk, unsigned * pTruthRes, unsigned uSupp ) -{ - unsigned * pTruth = Kit_DsdTruthComputeOne( p, pNtk, uSupp ); - Kit_TruthCopy( pTruthRes, pTruth, pNtk->nVars ); -/* - // verification - { - // compute the same function using different procedure - unsigned * pTruthTemp = Vec_PtrEntry(p->vTtNodes, pNtk->nVars + pNtk->nNodes + 1); - pNtk->pSupps = NULL; - Kit_DsdTruthComputeTwo( p, pNtk, uSupp, -1, pTruthTemp ); -// if ( !Kit_TruthIsEqual( pTruthTemp, pTruthRes, pNtk->nVars ) ) - if ( !Kit_TruthIsEqualWithPhase( pTruthTemp, pTruthRes, pNtk->nVars ) ) - { - printf( "Verification FAILED!\n" ); - Kit_DsdPrint( stdout, pNtk ); - Kit_DsdPrintFromTruth( pTruthRes, pNtk->nVars ); - Kit_DsdPrintFromTruth( pTruthTemp, pNtk->nVars ); - } -// else -// printf( "Verification successful.\n" ); - } -*/ -} - -/**Function************************************************************* - - Synopsis [Counts the number of blocks of the given number of inputs.] - - Description [] - - SideEffects [] - - SeeAlso [] - -***********************************************************************/ -int Kit_DsdCountLuts_rec( Kit_DsdNtk_t * pNtk, int nLutSize, int Id, int * pCounter ) -{ - Kit_DsdObj_t * pObj; - unsigned iLit, i, Res0, Res1; - pObj = Kit_DsdNtkObj( pNtk, Id ); - if ( pObj == NULL ) - return 0; - if ( pObj->Type == KIT_DSD_AND || pObj->Type == KIT_DSD_XOR ) - { - assert( pObj->nFans == 2 ); - Res0 = Kit_DsdCountLuts_rec( pNtk, nLutSize, Kit_DsdLit2Var(pObj->pFans[0]), pCounter ); - Res1 = Kit_DsdCountLuts_rec( pNtk, nLutSize, Kit_DsdLit2Var(pObj->pFans[1]), pCounter ); - if ( Res0 == 0 && Res1 > 0 ) - return Res1 - 1; - if ( Res0 > 0 && Res1 == 0 ) - return Res0 - 1; - (*pCounter)++; - return nLutSize - 2; - } - assert( pObj->Type == KIT_DSD_PRIME ); - if ( (int)pObj->nFans > nLutSize ) //+ 1 ) - { - *pCounter = 1000; - return 0; - } - Kit_DsdObjForEachFanin( pNtk, pObj, iLit, i ) - Kit_DsdCountLuts_rec( pNtk, nLutSize, Kit_DsdLit2Var(iLit), pCounter ); - (*pCounter)++; -// if ( (int)pObj->nFans == nLutSize + 1 ) -// (*pCounter)++; - return nLutSize - pObj->nFans; -} - -/**Function************************************************************* - - Synopsis [Counts the number of blocks of the given number of inputs.] - - Description [] - - SideEffects [] - - SeeAlso [] - -***********************************************************************/ -int Kit_DsdCountLuts( Kit_DsdNtk_t * pNtk, int nLutSize ) -{ - int Counter = 0; - if ( Kit_DsdNtkRoot(pNtk)->Type == KIT_DSD_CONST1 ) - return 0; - if ( Kit_DsdNtkRoot(pNtk)->Type == KIT_DSD_VAR ) - return 0; - Kit_DsdCountLuts_rec( pNtk, nLutSize, Kit_DsdLit2Var(pNtk->Root), &Counter ); - if ( Counter >= 1000 ) - return -1; - return Counter; -} - -/**Function************************************************************* - - Synopsis [Counts the number of blocks of the given number of inputs.] - - Description [] - - SideEffects [] - - SeeAlso [] - -***********************************************************************/ -int Kit_DsdNonDsdSizeMax( Kit_DsdNtk_t * pNtk ) -{ - Kit_DsdObj_t * pObj; - unsigned i, nSizeMax = 0; - Kit_DsdNtkForEachObj( pNtk, pObj, i ) - { - if ( pObj->Type != KIT_DSD_PRIME ) - continue; - if ( nSizeMax < pObj->nFans ) - nSizeMax = pObj->nFans; - } - return nSizeMax; -} - -/**Function************************************************************* - - Synopsis [Finds the union of supports of the non-DSD blocks.] - - Description [] - - SideEffects [] - - SeeAlso [] - -***********************************************************************/ -unsigned Kit_DsdNonDsdSupports( Kit_DsdNtk_t * pNtk ) -{ - Kit_DsdObj_t * pObj; - unsigned i, uSupport = 0; -// FREE( pNtk->pSupps ); - Kit_DsdGetSupports( pNtk ); - Kit_DsdNtkForEachObj( pNtk, pObj, i ) - { - if ( pObj->Type != KIT_DSD_PRIME ) - continue; - uSupport |= Kit_DsdLitSupport( pNtk, Kit_DsdVar2Lit(pObj->Id,0) ); - } - return uSupport; -} - - -/**Function************************************************************* - - Synopsis [Expands the node.] - - Description [Returns the new literal.] - - SideEffects [] - - SeeAlso [] - -***********************************************************************/ -void Kit_DsdExpandCollectAnd_rec( Kit_DsdNtk_t * p, int iLit, int * piLitsNew, int * nLitsNew ) -{ - Kit_DsdObj_t * pObj; - unsigned i, iLitFanin; - // check the end of the supergate - pObj = Kit_DsdNtkObj( p, Kit_DsdLit2Var(iLit) ); - if ( Kit_DsdLitIsCompl(iLit) || Kit_DsdLit2Var(iLit) < p->nVars || pObj->Type != KIT_DSD_AND ) - { - piLitsNew[(*nLitsNew)++] = iLit; - return; - } - // iterate through the fanins - Kit_DsdObjForEachFanin( p, pObj, iLitFanin, i ) - Kit_DsdExpandCollectAnd_rec( p, iLitFanin, piLitsNew, nLitsNew ); -} - -/**Function************************************************************* - - Synopsis [Expands the node.] - - Description [Returns the new literal.] - - SideEffects [] - - SeeAlso [] - -***********************************************************************/ -void Kit_DsdExpandCollectXor_rec( Kit_DsdNtk_t * p, int iLit, int * piLitsNew, int * nLitsNew ) -{ - Kit_DsdObj_t * pObj; - unsigned i, iLitFanin; - // check the end of the supergate - pObj = Kit_DsdNtkObj( p, Kit_DsdLit2Var(iLit) ); - if ( Kit_DsdLit2Var(iLit) < p->nVars || pObj->Type != KIT_DSD_XOR ) - { - piLitsNew[(*nLitsNew)++] = iLit; - return; - } - // iterate through the fanins - pObj = Kit_DsdNtkObj( p, Kit_DsdLit2Var(iLit) ); - Kit_DsdObjForEachFanin( p, pObj, iLitFanin, i ) - Kit_DsdExpandCollectXor_rec( p, iLitFanin, piLitsNew, nLitsNew ); - // if the literal was complemented, pass the complemented attribute somewhere - if ( Kit_DsdLitIsCompl(iLit) ) - piLitsNew[0] = Kit_DsdLitNot( piLitsNew[0] ); -} - -/**Function************************************************************* - - Synopsis [Expands the node.] - - Description [Returns the new literal.] - - SideEffects [] - - SeeAlso [] - -***********************************************************************/ -int Kit_DsdExpandNode_rec( Kit_DsdNtk_t * pNew, Kit_DsdNtk_t * p, int iLit ) -{ - unsigned * pTruth, * pTruthNew; - unsigned i, iLitFanin, piLitsNew[16], nLitsNew = 0; - Kit_DsdObj_t * pObj, * pObjNew; - - // consider the case of simple gate - pObj = Kit_DsdNtkObj( p, Kit_DsdLit2Var(iLit) ); - if ( pObj == NULL ) - return iLit; - if ( pObj->Type == KIT_DSD_AND ) - { - Kit_DsdExpandCollectAnd_rec( p, Kit_DsdLitRegular(iLit), piLitsNew, &nLitsNew ); - pObjNew = Kit_DsdObjAlloc( pNew, KIT_DSD_AND, nLitsNew ); - for ( i = 0; i < pObjNew->nFans; i++ ) - pObjNew->pFans[i] = Kit_DsdExpandNode_rec( pNew, p, piLitsNew[i] ); - return Kit_DsdVar2Lit( pObjNew->Id, Kit_DsdLitIsCompl(iLit) ); - } - if ( pObj->Type == KIT_DSD_XOR ) - { - int fCompl = Kit_DsdLitIsCompl(iLit); - Kit_DsdExpandCollectXor_rec( p, Kit_DsdLitRegular(iLit), piLitsNew, &nLitsNew ); - pObjNew = Kit_DsdObjAlloc( pNew, KIT_DSD_XOR, nLitsNew ); - for ( i = 0; i < pObjNew->nFans; i++ ) - { - pObjNew->pFans[i] = Kit_DsdExpandNode_rec( pNew, p, Kit_DsdLitRegular(piLitsNew[i]) ); - fCompl ^= Kit_DsdLitIsCompl(piLitsNew[i]); - } - return Kit_DsdVar2Lit( pObjNew->Id, fCompl ); - } - assert( pObj->Type == KIT_DSD_PRIME ); - - // create new PRIME node - pObjNew = Kit_DsdObjAlloc( pNew, KIT_DSD_PRIME, pObj->nFans ); - // copy the truth table - pTruth = Kit_DsdObjTruth( pObj ); - pTruthNew = Kit_DsdObjTruth( pObjNew ); - Kit_TruthCopy( pTruthNew, pTruth, pObj->nFans ); - // create fanins - Kit_DsdObjForEachFanin( pNtk, pObj, iLitFanin, i ) - { - pObjNew->pFans[i] = Kit_DsdExpandNode_rec( pNew, p, iLitFanin ); - // complement the corresponding inputs of the truth table - if ( Kit_DsdLitIsCompl(pObjNew->pFans[i]) ) - { - pObjNew->pFans[i] = Kit_DsdLitRegular(pObjNew->pFans[i]); - Kit_TruthChangePhase( pTruthNew, pObjNew->nFans, i ); - } - } - // if the incoming phase is complemented, absorb it into the prime node - if ( Kit_DsdLitIsCompl(iLit) ) - Kit_TruthNot( pTruthNew, pTruthNew, pObj->nFans ); - return Kit_DsdVar2Lit( pObjNew->Id, 0 ); -} - -/**Function************************************************************* - - Synopsis [Expands the network.] - - Description [] - - SideEffects [] - - SeeAlso [] - -***********************************************************************/ -Kit_DsdNtk_t * Kit_DsdExpand( Kit_DsdNtk_t * p ) -{ - Kit_DsdNtk_t * pNew; - Kit_DsdObj_t * pObjNew; - assert( p->nVars <= 16 ); - // create a new network - pNew = Kit_DsdNtkAlloc( p->nVars ); - // consider simple special cases - if ( Kit_DsdNtkRoot(p)->Type == KIT_DSD_CONST1 ) - { - pObjNew = Kit_DsdObjAlloc( pNew, KIT_DSD_CONST1, 0 ); - pNew->Root = Kit_DsdVar2Lit( pObjNew->Id, Kit_DsdLitIsCompl(p->Root) ); - return pNew; - } - if ( Kit_DsdNtkRoot(p)->Type == KIT_DSD_VAR ) - { - pObjNew = Kit_DsdObjAlloc( pNew, KIT_DSD_VAR, 1 ); - pObjNew->pFans[0] = Kit_DsdNtkRoot(p)->pFans[0]; - pNew->Root = Kit_DsdVar2Lit( pObjNew->Id, Kit_DsdLitIsCompl(p->Root) ); - return pNew; - } - // convert the root node - pNew->Root = Kit_DsdExpandNode_rec( pNew, p, p->Root ); - return pNew; -} - -/**Function************************************************************* - - Synopsis [Sorts the literals by their support.] - - Description [] - - SideEffects [] - - SeeAlso [] - -***********************************************************************/ -void Kit_DsdCompSort( int pPrios[], unsigned uSupps[], unsigned char * piLits, int nVars, int piLitsRes[] ) -{ - int nSuppSizes[16], Priority[16], pOrder[16]; - int i, k, iVarBest, SuppMax, PrioMax; - // compute support sizes and priorities of the components - for ( i = 0; i < nVars; i++ ) - { - assert( uSupps[i] ); - pOrder[i] = i; - Priority[i] = KIT_INFINITY; - for ( k = 0; k < 16; k++ ) - if ( uSupps[i] & (1 << k) ) - Priority[i] = KIT_MIN( Priority[i], pPrios[k] ); - assert( Priority[i] != 16 ); - nSuppSizes[i] = Kit_WordCountOnes(uSupps[i]); - } - // sort the components by pririty - Extra_BubbleSort( pOrder, Priority, nVars, 0 ); - // find the component by with largest size and lowest priority - iVarBest = -1; - SuppMax = 0; - PrioMax = 0; - for ( i = 0; i < nVars; i++ ) - { - if ( SuppMax < nSuppSizes[i] || (SuppMax == nSuppSizes[i] && PrioMax < Priority[i]) ) - { - SuppMax = nSuppSizes[i]; - PrioMax = Priority[i]; - iVarBest = i; - } - } - assert( iVarBest != -1 ); - // copy the resulting literals - k = 0; - piLitsRes[k++] = piLits[iVarBest]; - for ( i = 0; i < nVars; i++ ) - { - if ( pOrder[i] == iVarBest ) - continue; - piLitsRes[k++] = piLits[pOrder[i]]; - } - assert( k == nVars ); -} - -/**Function************************************************************* - - Synopsis [Shrinks multi-input nodes.] - - Description [Takes the array of variable priorities pPrios.] - - SideEffects [] - - SeeAlso [] - -***********************************************************************/ -int Kit_DsdShrink_rec( Kit_DsdNtk_t * pNew, Kit_DsdNtk_t * p, int iLit, int pPrios[] ) -{ - Kit_DsdObj_t * pObj, * pObjNew; - unsigned * pTruth, * pTruthNew; - unsigned i, piLitsNew[16], uSupps[16]; - int iLitFanin, iLitNew; - - // consider the case of simple gate - pObj = Kit_DsdNtkObj( p, Kit_DsdLit2Var(iLit) ); - if ( pObj == NULL ) - return iLit; - if ( pObj->Type == KIT_DSD_AND ) - { - // get the supports - Kit_DsdObjForEachFanin( p, pObj, iLitFanin, i ) - uSupps[i] = Kit_DsdLitSupport( p, iLitFanin ); - // put the largest component last - // sort other components in the decreasing order of priority of their vars - Kit_DsdCompSort( pPrios, uSupps, pObj->pFans, pObj->nFans, piLitsNew ); - // construct the two-input node network - iLitNew = Kit_DsdShrink_rec( pNew, p, piLitsNew[0], pPrios ); - for ( i = 1; i < pObj->nFans; i++ ) - { - pObjNew = Kit_DsdObjAlloc( pNew, KIT_DSD_AND, 2 ); - pObjNew->pFans[0] = Kit_DsdShrink_rec( pNew, p, piLitsNew[i], pPrios ); - pObjNew->pFans[1] = iLitNew; - iLitNew = Kit_DsdVar2Lit( pObjNew->Id, 0 ); - } - return Kit_DsdVar2Lit( pObjNew->Id, Kit_DsdLitIsCompl(iLit) ); - } - if ( pObj->Type == KIT_DSD_XOR ) - { - // get the supports - Kit_DsdObjForEachFanin( p, pObj, iLitFanin, i ) - { - assert( !Kit_DsdLitIsCompl(iLitFanin) ); - uSupps[i] = Kit_DsdLitSupport( p, iLitFanin ); - } - // put the largest component last - // sort other components in the decreasing order of priority of their vars - Kit_DsdCompSort( pPrios, uSupps, pObj->pFans, pObj->nFans, piLitsNew ); - // construct the two-input node network - iLitNew = Kit_DsdShrink_rec( pNew, p, piLitsNew[0], pPrios ); - for ( i = 1; i < pObj->nFans; i++ ) - { - pObjNew = Kit_DsdObjAlloc( pNew, KIT_DSD_XOR, 2 ); - pObjNew->pFans[0] = Kit_DsdShrink_rec( pNew, p, piLitsNew[i], pPrios ); - pObjNew->pFans[1] = iLitNew; - iLitNew = Kit_DsdVar2Lit( pObjNew->Id, 0 ); - } - return Kit_DsdVar2Lit( pObjNew->Id, Kit_DsdLitIsCompl(iLit) ); - } - assert( pObj->Type == KIT_DSD_PRIME ); - - // create new PRIME node - pObjNew = Kit_DsdObjAlloc( pNew, KIT_DSD_PRIME, pObj->nFans ); - // copy the truth table - pTruth = Kit_DsdObjTruth( pObj ); - pTruthNew = Kit_DsdObjTruth( pObjNew ); - Kit_TruthCopy( pTruthNew, pTruth, pObj->nFans ); - // create fanins - Kit_DsdObjForEachFanin( pNtk, pObj, iLitFanin, i ) - { - pObjNew->pFans[i] = Kit_DsdShrink_rec( pNew, p, iLitFanin, pPrios ); - // complement the corresponding inputs of the truth table - if ( Kit_DsdLitIsCompl(pObjNew->pFans[i]) ) - { - pObjNew->pFans[i] = Kit_DsdLitRegular(pObjNew->pFans[i]); - Kit_TruthChangePhase( pTruthNew, pObjNew->nFans, i ); - } - } - // if the incoming phase is complemented, absorb it into the prime node - if ( Kit_DsdLitIsCompl(iLit) ) - Kit_TruthNot( pTruthNew, pTruthNew, pObj->nFans ); - return Kit_DsdVar2Lit( pObjNew->Id, 0 ); -} - -/**Function************************************************************* - - Synopsis [Shrinks the network.] - - Description [Transforms the network to have two-input nodes so that the - higher-ordered nodes were decomposed out first.] - - SideEffects [] - - SeeAlso [] - -***********************************************************************/ -Kit_DsdNtk_t * Kit_DsdShrink( Kit_DsdNtk_t * p, int pPrios[] ) -{ - Kit_DsdNtk_t * pNew; - Kit_DsdObj_t * pObjNew; - assert( p->nVars <= 16 ); - // create a new network - pNew = Kit_DsdNtkAlloc( p->nVars ); - // consider simple special cases - if ( Kit_DsdNtkRoot(p)->Type == KIT_DSD_CONST1 ) - { - pObjNew = Kit_DsdObjAlloc( pNew, KIT_DSD_CONST1, 0 ); - pNew->Root = Kit_DsdVar2Lit( pObjNew->Id, Kit_DsdLitIsCompl(p->Root) ); - return pNew; - } - if ( Kit_DsdNtkRoot(p)->Type == KIT_DSD_VAR ) - { - pObjNew = Kit_DsdObjAlloc( pNew, KIT_DSD_VAR, 1 ); - pObjNew->pFans[0] = Kit_DsdNtkRoot(p)->pFans[0]; - pNew->Root = Kit_DsdVar2Lit( pObjNew->Id, Kit_DsdLitIsCompl(p->Root) ); - return pNew; - } - // convert the root node - pNew->Root = Kit_DsdShrink_rec( pNew, p, p->Root, pPrios ); - return pNew; -} - -/**Function************************************************************* - - Synopsis [Rotates the network.] - - Description [Transforms prime nodes to have the fanin with the - highest frequency of supports go first.] - - SideEffects [] - - SeeAlso [] - -***********************************************************************/ -void Kit_DsdRotate( Kit_DsdNtk_t * p, int pFreqs[] ) -{ - Kit_DsdObj_t * pObj; - unsigned * pIn, * pOut, * pTemp, k; - int i, v, Temp, uSuppFanin, iFaninLit, WeightMax, FaninMax, nSwaps; - int Weights[16]; - // go through the prime nodes - Kit_DsdNtkForEachObj( p, pObj, i ) - { - if ( pObj->Type != KIT_DSD_PRIME ) - continue; - // count the fanin frequencies - Kit_DsdObjForEachFanin( p, pObj, iFaninLit, k ) - { - uSuppFanin = Kit_DsdLitSupport( p, iFaninLit ); - Weights[k] = 0; - for ( v = 0; v < 16; v++ ) - if ( uSuppFanin & (1 << v) ) - Weights[k] += pFreqs[v] - 1; - } - // find the most frequent fanin - WeightMax = 0; - FaninMax = -1; - for ( k = 0; k < pObj->nFans; k++ ) - if ( WeightMax < Weights[k] ) - { - WeightMax = Weights[k]; - FaninMax = k; - } - // no need to reorder if there are no frequent fanins - if ( FaninMax == -1 ) - continue; - // move the fanins number k to the first place - nSwaps = 0; - pIn = Kit_DsdObjTruth(pObj); - pOut = p->pMem; -// for ( v = FaninMax; v < ((int)pObj->nFans)-1; v++ ) - for ( v = FaninMax-1; v >= 0; v-- ) - { - // swap the fanins - Temp = pObj->pFans[v]; - pObj->pFans[v] = pObj->pFans[v+1]; - pObj->pFans[v+1] = Temp; - // swap the truth table variables - Kit_TruthSwapAdjacentVars( pOut, pIn, pObj->nFans, v ); - pTemp = pIn; pIn = pOut; pOut = pTemp; - nSwaps++; - } - if ( nSwaps & 1 ) - Kit_TruthCopy( pOut, pIn, pObj->nFans ); - } -} - -/**Function************************************************************* - - Synopsis [Compute the support.] - - Description [] - - SideEffects [] - - SeeAlso [] - -***********************************************************************/ -unsigned Kit_DsdGetSupports_rec( Kit_DsdNtk_t * p, int iLit ) -{ - Kit_DsdObj_t * pObj; - unsigned uSupport, k; - int iFaninLit; - pObj = Kit_DsdNtkObj( p, Kit_DsdLit2Var(iLit) ); - if ( pObj == NULL ) - return Kit_DsdLitSupport( p, iLit ); - uSupport = 0; - Kit_DsdObjForEachFanin( p, pObj, iFaninLit, k ) - uSupport |= Kit_DsdGetSupports_rec( p, iFaninLit ); - p->pSupps[pObj->Id - p->nVars] = uSupport; - assert( uSupport <= 0xFFFF ); - return uSupport; -} - -/**Function************************************************************* - - Synopsis [Compute the support.] - - Description [] - - SideEffects [] - - SeeAlso [] - -***********************************************************************/ -unsigned Kit_DsdGetSupports( Kit_DsdNtk_t * p ) -{ - Kit_DsdObj_t * pRoot; - unsigned uSupport; - assert( p->pSupps == NULL ); - p->pSupps = ALLOC( unsigned, p->nNodes ); - // consider simple special cases - pRoot = Kit_DsdNtkRoot(p); - if ( pRoot->Type == KIT_DSD_CONST1 ) - { - assert( p->nNodes == 1 ); - uSupport = p->pSupps[0] = 0; - } - if ( pRoot->Type == KIT_DSD_VAR ) - { - assert( p->nNodes == 1 ); - uSupport = p->pSupps[0] = Kit_DsdLitSupport( p, pRoot->pFans[0] ); - } - else - uSupport = Kit_DsdGetSupports_rec( p, p->Root ); - assert( uSupport <= 0xFFFF ); - return uSupport; -} - -/**Function************************************************************* - - Synopsis [Returns 1 if there is a component with more than 3 inputs.] - - Description [] - - SideEffects [] - - SeeAlso [] - -***********************************************************************/ -int Kit_DsdFindLargeBox_rec( Kit_DsdNtk_t * pNtk, int Id, int Size ) -{ - Kit_DsdObj_t * pObj; - unsigned iLit, i, RetValue; - pObj = Kit_DsdNtkObj( pNtk, Id ); - if ( pObj == NULL ) - return 0; - if ( pObj->Type == KIT_DSD_PRIME && (int)pObj->nFans > Size ) - return 1; - RetValue = 0; - Kit_DsdObjForEachFanin( pNtk, pObj, iLit, i ) - RetValue |= Kit_DsdFindLargeBox_rec( pNtk, Kit_DsdLit2Var(iLit), Size ); - return RetValue; -} - -/**Function************************************************************* - - Synopsis [Returns 1 if there is a component with more than 3 inputs.] - - Description [] - - SideEffects [] - - SeeAlso [] - -***********************************************************************/ -int Kit_DsdFindLargeBox( Kit_DsdNtk_t * pNtk, int Size ) -{ - return Kit_DsdFindLargeBox_rec( pNtk, Kit_DsdLit2Var(pNtk->Root), Size ); -} - -/**Function************************************************************* - - Synopsis [Returns 1 if the non-DSD 4-var func is implementable with two 3-LUTs.] - - Description [] - - SideEffects [] - - SeeAlso [] - -***********************************************************************/ -int Kit_DsdRootNodeHasCommonVars( Kit_DsdObj_t * pObj0, Kit_DsdObj_t * pObj1 ) -{ - unsigned i, k; - for ( i = 0; i < pObj0->nFans; i++ ) - { - if ( Kit_DsdLit2Var(pObj0->pFans[i]) >= 4 ) - continue; - for ( k = 0; k < pObj1->nFans; k++ ) - if ( Kit_DsdLit2Var(pObj0->pFans[i]) == Kit_DsdLit2Var(pObj1->pFans[k]) ) - return 1; - } - return 0; -} - -/**Function************************************************************* - - Synopsis [Returns 1 if the non-DSD 4-var func is implementable with two 3-LUTs.] - - Description [] - - SideEffects [] - - SeeAlso [] - -***********************************************************************/ -int Kit_DsdCheckVar4Dec2( Kit_DsdNtk_t * pNtk0, Kit_DsdNtk_t * pNtk1 ) -{ - assert( pNtk0->nVars == 4 ); - assert( pNtk1->nVars == 4 ); - if ( Kit_DsdFindLargeBox(pNtk0, 2) ) - return 0; - if ( Kit_DsdFindLargeBox(pNtk1, 2) ) - return 0; - return Kit_DsdRootNodeHasCommonVars( Kit_DsdNtkRoot(pNtk0), Kit_DsdNtkRoot(pNtk1) ); -} - -/**Function************************************************************* - - Synopsis [Performs decomposition of the node.] - - Description [] - - SideEffects [] - - SeeAlso [] - -***********************************************************************/ -void Kit_DsdDecompose_rec( Kit_DsdNtk_t * pNtk, Kit_DsdObj_t * pObj, unsigned uSupp, unsigned char * pPar, int nDecMux ) -{ - Kit_DsdObj_t * pRes, * pRes0, * pRes1; - int nWords = Kit_TruthWordNum(pObj->nFans); - unsigned * pTruth = Kit_DsdObjTruth(pObj); - unsigned * pCofs2[2] = { pNtk->pMem, pNtk->pMem + nWords }; - unsigned * pCofs4[2][2] = { {pNtk->pMem + 2 * nWords, pNtk->pMem + 3 * nWords}, {pNtk->pMem + 4 * nWords, pNtk->pMem + 5 * nWords} }; - int i, iLit0, iLit1, nFans0, nFans1, nPairs; - int fEquals[2][2], fOppos, fPairs[4][4]; - unsigned j, k, nFansNew, uSupp0, uSupp1; - - assert( pObj->nFans > 0 ); - assert( pObj->Type == KIT_DSD_PRIME ); - assert( uSupp == (uSupp0 = (unsigned)Kit_TruthSupport(pTruth, pObj->nFans)) ); - - // compress the truth table - if ( uSupp != Kit_BitMask(pObj->nFans) ) - { - nFansNew = Kit_WordCountOnes(uSupp); - Kit_TruthShrink( pNtk->pMem, pTruth, nFansNew, pObj->nFans, uSupp, 1 ); - for ( j = k = 0; j < pObj->nFans; j++ ) - if ( uSupp & (1 << j) ) - pObj->pFans[k++] = pObj->pFans[j]; - assert( k == nFansNew ); - pObj->nFans = k; - uSupp = Kit_BitMask(pObj->nFans); - } - - // consider the single variable case - if ( pObj->nFans == 1 ) - { - pObj->Type = KIT_DSD_NONE; - if ( pTruth[0] == 0x55555555 ) - pObj->pFans[0] = Kit_DsdLitNot(pObj->pFans[0]); - else - assert( pTruth[0] == 0xAAAAAAAA ); - // update the parent pointer - *pPar = Kit_DsdLitNotCond( pObj->pFans[0], Kit_DsdLitIsCompl(*pPar) ); - return; - } - - // decompose the output - if ( !pObj->fMark ) - for ( i = pObj->nFans - 1; i >= 0; i-- ) - { - // get the two-variable cofactors - Kit_TruthCofactor0New( pCofs2[0], pTruth, pObj->nFans, i ); - Kit_TruthCofactor1New( pCofs2[1], pTruth, pObj->nFans, i ); -// assert( !Kit_TruthVarInSupport( pCofs2[0], pObj->nFans, i) ); -// assert( !Kit_TruthVarInSupport( pCofs2[1], pObj->nFans, i) ); - // get the constant cofs - fEquals[0][0] = Kit_TruthIsConst0( pCofs2[0], pObj->nFans ); - fEquals[0][1] = Kit_TruthIsConst0( pCofs2[1], pObj->nFans ); - fEquals[1][0] = Kit_TruthIsConst1( pCofs2[0], pObj->nFans ); - fEquals[1][1] = Kit_TruthIsConst1( pCofs2[1], pObj->nFans ); - fOppos = Kit_TruthIsOpposite( pCofs2[0], pCofs2[1], pObj->nFans ); - assert( !Kit_TruthIsEqual(pCofs2[0], pCofs2[1], pObj->nFans) ); - if ( fEquals[0][0] + fEquals[0][1] + fEquals[1][0] + fEquals[1][1] + fOppos == 0 ) - { - // check the MUX decomposition - uSupp0 = Kit_TruthSupport( pCofs2[0], pObj->nFans ); - uSupp1 = Kit_TruthSupport( pCofs2[1], pObj->nFans ); - assert( uSupp == (uSupp0 | uSupp1 | (1<nFans ); - pRes1 = Kit_DsdObjAlloc( pNtk, KIT_DSD_PRIME, pObj->nFans ); - for ( k = 0; k < pObj->nFans; k++ ) - { - pRes0->pFans[k] = (uSupp0 & (1 << k))? pObj->pFans[k] : 127; - pRes1->pFans[k] = (uSupp1 & (1 << k))? pObj->pFans[k] : 127; - } - Kit_TruthCopy( Kit_DsdObjTruth(pRes0), pCofs2[0], pObj->nFans ); - Kit_TruthCopy( Kit_DsdObjTruth(pRes1), pCofs2[1], pObj->nFans ); - // update the current one - assert( pObj->Type == KIT_DSD_PRIME ); - pTruth[0] = 0xCACACACA; - pObj->nFans = 3; - pObj->pFans[2] = pObj->pFans[i]; - pObj->pFans[0] = 2*pRes0->Id; pRes0->nRefs++; - pObj->pFans[1] = 2*pRes1->Id; pRes1->nRefs++; - // call recursively - Kit_DsdDecompose_rec( pNtk, pRes0, uSupp0, pObj->pFans + 0, nDecMux ); - Kit_DsdDecompose_rec( pNtk, pRes1, uSupp1, pObj->pFans + 1, nDecMux ); - return; - } - - // create the new node - pRes = Kit_DsdObjAlloc( pNtk, KIT_DSD_AND, 2 ); - pRes->nRefs++; - pRes->nFans = 2; - pRes->pFans[0] = pObj->pFans[i]; pObj->pFans[i] = 127; uSupp &= ~(1 << i); - pRes->pFans[1] = 2*pObj->Id; - // update the parent pointer - *pPar = Kit_DsdLitNotCond( 2 * pRes->Id, Kit_DsdLitIsCompl(*pPar) ); - // consider different decompositions - if ( fEquals[0][0] ) - { - Kit_TruthCopy( pTruth, pCofs2[1], pObj->nFans ); - } - else if ( fEquals[0][1] ) - { - pRes->pFans[0] = Kit_DsdLitNot(pRes->pFans[0]); - Kit_TruthCopy( pTruth, pCofs2[0], pObj->nFans ); - } - else if ( fEquals[1][0] ) - { - *pPar = Kit_DsdLitNot(*pPar); - pRes->pFans[1] = Kit_DsdLitNot(pRes->pFans[1]); - Kit_TruthCopy( pTruth, pCofs2[1], pObj->nFans ); - } - else if ( fEquals[1][1] ) - { - *pPar = Kit_DsdLitNot(*pPar); - pRes->pFans[0] = Kit_DsdLitNot(pRes->pFans[0]); - pRes->pFans[1] = Kit_DsdLitNot(pRes->pFans[1]); - Kit_TruthCopy( pTruth, pCofs2[0], pObj->nFans ); - } - else if ( fOppos ) - { - pRes->Type = KIT_DSD_XOR; - Kit_TruthCopy( pTruth, pCofs2[0], pObj->nFans ); - } - else - assert( 0 ); - // decompose the remainder - assert( Kit_DsdObjTruth(pObj) == pTruth ); - Kit_DsdDecompose_rec( pNtk, pObj, uSupp, pRes->pFans + 1, nDecMux ); - return; - } - pObj->fMark = 1; - - // decompose the input - for ( i = pObj->nFans - 1; i >= 0; i-- ) - { - assert( Kit_TruthVarInSupport( pTruth, pObj->nFans, i ) ); - // get the single variale cofactors - Kit_TruthCofactor0New( pCofs2[0], pTruth, pObj->nFans, i ); - Kit_TruthCofactor1New( pCofs2[1], pTruth, pObj->nFans, i ); - // check the existence of MUX decomposition - uSupp0 = Kit_TruthSupport( pCofs2[0], pObj->nFans ); - uSupp1 = Kit_TruthSupport( pCofs2[1], pObj->nFans ); - assert( uSupp == (uSupp0 | uSupp1 | (1<fMark = 0; - Kit_DsdDecompose_rec( pNtk, pObj, uSupp, pPar, nDecMux ); - return; - } - assert( uSupp0 && uSupp1 ); - // get the number of unique variables - nFans0 = Kit_WordCountOnes( uSupp0 & ~uSupp1 ); - nFans1 = Kit_WordCountOnes( uSupp1 & ~uSupp0 ); - if ( nFans0 == 1 && nFans1 == 1 ) - { - // get the cofactors w.r.t. the unique variables - iLit0 = Kit_WordFindFirstBit( uSupp0 & ~uSupp1 ); - iLit1 = Kit_WordFindFirstBit( uSupp1 & ~uSupp0 ); - // get four cofactors - Kit_TruthCofactor0New( pCofs4[0][0], pCofs2[0], pObj->nFans, iLit0 ); - Kit_TruthCofactor1New( pCofs4[0][1], pCofs2[0], pObj->nFans, iLit0 ); - Kit_TruthCofactor0New( pCofs4[1][0], pCofs2[1], pObj->nFans, iLit1 ); - Kit_TruthCofactor1New( pCofs4[1][1], pCofs2[1], pObj->nFans, iLit1 ); - // check existence conditions - fEquals[0][0] = Kit_TruthIsEqual( pCofs4[0][0], pCofs4[1][0], pObj->nFans ); - fEquals[0][1] = Kit_TruthIsEqual( pCofs4[0][1], pCofs4[1][1], pObj->nFans ); - fEquals[1][0] = Kit_TruthIsEqual( pCofs4[0][0], pCofs4[1][1], pObj->nFans ); - fEquals[1][1] = Kit_TruthIsEqual( pCofs4[0][1], pCofs4[1][0], pObj->nFans ); - if ( (fEquals[0][0] && fEquals[0][1]) || (fEquals[1][0] && fEquals[1][1]) ) - { - // construct the MUX - pRes = Kit_DsdObjAlloc( pNtk, KIT_DSD_PRIME, 3 ); - Kit_DsdObjTruth(pRes)[0] = 0xCACACACA; - pRes->nRefs++; - pRes->nFans = 3; - pRes->pFans[0] = pObj->pFans[iLit0]; pObj->pFans[iLit0] = 127; uSupp &= ~(1 << iLit0); - pRes->pFans[1] = pObj->pFans[iLit1]; pObj->pFans[iLit1] = 127; uSupp &= ~(1 << iLit1); - pRes->pFans[2] = pObj->pFans[i]; pObj->pFans[i] = 2 * pRes->Id; // remains in support - // update the node -// if ( fEquals[0][0] && fEquals[0][1] ) -// Kit_TruthMuxVar( pTruth, pCofs4[0][0], pCofs4[0][1], pObj->nFans, i ); -// else -// Kit_TruthMuxVar( pTruth, pCofs4[0][1], pCofs4[0][0], pObj->nFans, i ); - Kit_TruthMuxVar( pTruth, pCofs4[1][0], pCofs4[1][1], pObj->nFans, i ); - if ( fEquals[1][0] && fEquals[1][1] ) - pRes->pFans[0] = Kit_DsdLitNot(pRes->pFans[0]); - // decompose the remainder - Kit_DsdDecompose_rec( pNtk, pObj, uSupp, pPar, nDecMux ); - return; - } - } - - // try other inputs - for ( k = i+1; k < pObj->nFans; k++ ) - { - // get four cofactors ik - Kit_TruthCofactor0New( pCofs4[0][0], pCofs2[0], pObj->nFans, k ); // 00 - Kit_TruthCofactor1New( pCofs4[0][1], pCofs2[0], pObj->nFans, k ); // 01 - Kit_TruthCofactor0New( pCofs4[1][0], pCofs2[1], pObj->nFans, k ); // 10 - Kit_TruthCofactor1New( pCofs4[1][1], pCofs2[1], pObj->nFans, k ); // 11 - // compare equal pairs - fPairs[0][1] = fPairs[1][0] = Kit_TruthIsEqual( pCofs4[0][0], pCofs4[0][1], pObj->nFans ); - fPairs[0][2] = fPairs[2][0] = Kit_TruthIsEqual( pCofs4[0][0], pCofs4[1][0], pObj->nFans ); - fPairs[0][3] = fPairs[3][0] = Kit_TruthIsEqual( pCofs4[0][0], pCofs4[1][1], pObj->nFans ); - fPairs[1][2] = fPairs[2][1] = Kit_TruthIsEqual( pCofs4[0][1], pCofs4[1][0], pObj->nFans ); - fPairs[1][3] = fPairs[3][1] = Kit_TruthIsEqual( pCofs4[0][1], pCofs4[1][1], pObj->nFans ); - fPairs[2][3] = fPairs[3][2] = Kit_TruthIsEqual( pCofs4[1][0], pCofs4[1][1], pObj->nFans ); - nPairs = fPairs[0][1] + fPairs[0][2] + fPairs[0][3] + fPairs[1][2] + fPairs[1][3] + fPairs[2][3]; - if ( nPairs != 3 && nPairs != 2 ) - continue; - - // decomposition exists - pRes = Kit_DsdObjAlloc( pNtk, KIT_DSD_AND, 2 ); - pRes->nRefs++; - pRes->nFans = 2; - pRes->pFans[0] = pObj->pFans[k]; pObj->pFans[k] = 2 * pRes->Id; // remains in support - pRes->pFans[1] = pObj->pFans[i]; pObj->pFans[i] = 127; uSupp &= ~(1 << i); - if ( !fPairs[0][1] && !fPairs[0][2] && !fPairs[0][3] ) // 00 - { - pRes->pFans[0] = Kit_DsdLitNot(pRes->pFans[0]); - pRes->pFans[1] = Kit_DsdLitNot(pRes->pFans[1]); - Kit_TruthMuxVar( pTruth, pCofs4[1][1], pCofs4[0][0], pObj->nFans, k ); - } - else if ( !fPairs[1][0] && !fPairs[1][2] && !fPairs[1][3] ) // 01 - { - pRes->pFans[1] = Kit_DsdLitNot(pRes->pFans[1]); - Kit_TruthMuxVar( pTruth, pCofs4[0][0], pCofs4[0][1], pObj->nFans, k ); - } - else if ( !fPairs[2][0] && !fPairs[2][1] && !fPairs[2][3] ) // 10 - { - pRes->pFans[0] = Kit_DsdLitNot(pRes->pFans[0]); - Kit_TruthMuxVar( pTruth, pCofs4[0][0], pCofs4[1][0], pObj->nFans, k ); - } - else if ( !fPairs[3][0] && !fPairs[3][1] && !fPairs[3][2] ) // 11 - { -// unsigned uSupp0 = Kit_TruthSupport(pCofs4[0][0], pObj->nFans); -// unsigned uSupp1 = Kit_TruthSupport(pCofs4[1][1], pObj->nFans); -// unsigned uSupp; -// Extra_PrintBinary( stdout, &uSupp0, pObj->nFans ); printf( "\n" ); -// Extra_PrintBinary( stdout, &uSupp1, pObj->nFans ); printf( "\n" ); - Kit_TruthMuxVar( pTruth, pCofs4[0][0], pCofs4[1][1], pObj->nFans, k ); -// uSupp = Kit_TruthSupport(pTruth, pObj->nFans); -// Extra_PrintBinary( stdout, &uSupp, pObj->nFans ); printf( "\n" ); printf( "\n" ); - } - else - { - assert( fPairs[0][3] && fPairs[1][2] ); - pRes->Type = KIT_DSD_XOR;; - Kit_TruthMuxVar( pTruth, pCofs4[0][0], pCofs4[0][1], pObj->nFans, k ); - } - // decompose the remainder - Kit_DsdDecompose_rec( pNtk, pObj, uSupp, pPar, nDecMux ); - return; - } - } -/* - // if all decomposition methods failed and we are still above the limit, perform MUX-decomposition - if ( nDecMux > 0 && (int)pObj->nFans > nDecMux ) - { - int iBestVar = Kit_TruthBestCofVar( pTruth, pObj->nFans, pCofs2[0], pCofs2[1] ); - uSupp0 = Kit_TruthSupport( pCofs2[0], pObj->nFans ); - uSupp1 = Kit_TruthSupport( pCofs2[1], pObj->nFans ); - // perform MUX decomposition - pRes0 = Kit_DsdObjAlloc( pNtk, KIT_DSD_PRIME, pObj->nFans ); - pRes1 = Kit_DsdObjAlloc( pNtk, KIT_DSD_PRIME, pObj->nFans ); - for ( k = 0; k < pObj->nFans; k++ ) - pRes0->pFans[k] = pRes1->pFans[k] = pObj->pFans[k]; - Kit_TruthCopy( Kit_DsdObjTruth(pRes0), pCofs2[0], pObj->nFans ); - Kit_TruthCopy( Kit_DsdObjTruth(pRes1), pCofs2[1], pObj->nFans ); - // update the current one - assert( pObj->Type == KIT_DSD_PRIME ); - pTruth[0] = 0xCACACACA; - pObj->nFans = 3; - pObj->pFans[0] = 2*pRes0->Id; pRes0->nRefs++; - pObj->pFans[1] = 2*pRes1->Id; pRes1->nRefs++; - pObj->pFans[2] = pObj->pFans[iBestVar]; - // call recursively - Kit_DsdDecompose_rec( pNtk, pRes0, uSupp0, pObj->pFans + 0, nDecMux ); - Kit_DsdDecompose_rec( pNtk, pRes1, uSupp1, pObj->pFans + 1, nDecMux ); - } -*/ -} - -/**Function************************************************************* - - Synopsis [Performs decomposition of the truth table.] - - Description [] - - SideEffects [] - - SeeAlso [] - -***********************************************************************/ -Kit_DsdNtk_t * Kit_DsdDecomposeInt( unsigned * pTruth, int nVars, int nDecMux ) -{ - Kit_DsdNtk_t * pNtk; - Kit_DsdObj_t * pObj; - unsigned uSupp; - int i, nVarsReal; - assert( nVars <= 16 ); - pNtk = Kit_DsdNtkAlloc( nVars ); - pNtk->Root = Kit_DsdVar2Lit( pNtk->nVars, 0 ); - // create the first node - pObj = Kit_DsdObjAlloc( pNtk, KIT_DSD_PRIME, nVars ); - assert( pNtk->pNodes[0] == pObj ); - for ( i = 0; i < nVars; i++ ) - pObj->pFans[i] = Kit_DsdVar2Lit( i, 0 ); - Kit_TruthCopy( Kit_DsdObjTruth(pObj), pTruth, nVars ); - uSupp = Kit_TruthSupport( pTruth, nVars ); - // consider special cases - nVarsReal = Kit_WordCountOnes( uSupp ); - if ( nVarsReal == 0 ) - { - pObj->Type = KIT_DSD_CONST1; - pObj->nFans = 0; - if ( pTruth[0] == 0 ) - pNtk->Root = Kit_DsdLitNot(pNtk->Root); - return pNtk; - } - if ( nVarsReal == 1 ) - { - pObj->Type = KIT_DSD_VAR; - pObj->nFans = 1; - pObj->pFans[0] = Kit_DsdVar2Lit( Kit_WordFindFirstBit(uSupp), (pTruth[0] & 1) ); - return pNtk; - } - Kit_DsdDecompose_rec( pNtk, pNtk->pNodes[0], uSupp, &pNtk->Root, nDecMux ); - return pNtk; -} - -/**Function************************************************************* - - Synopsis [Performs decomposition of the truth table.] - - Description [] - - SideEffects [] - - SeeAlso [] - -***********************************************************************/ -Kit_DsdNtk_t * Kit_DsdDecompose( unsigned * pTruth, int nVars ) -{ - return Kit_DsdDecomposeInt( pTruth, nVars, 0 ); -} - -/**Function************************************************************* - - Synopsis [Performs decomposition of the truth table.] - - Description [] - - SideEffects [] - - SeeAlso [] - -***********************************************************************/ -Kit_DsdNtk_t * Kit_DsdDecomposeExpand( unsigned * pTruth, int nVars ) -{ - Kit_DsdNtk_t * pNtk, * pTemp; - pNtk = Kit_DsdDecomposeInt( pTruth, nVars, 0 ); - pNtk = Kit_DsdExpand( pTemp = pNtk ); - Kit_DsdNtkFree( pTemp ); - return pNtk; -} - -/**Function************************************************************* - - Synopsis [Performs decomposition of the truth table.] - - Description [Uses MUXes to break-down large prime nodes.] - - SideEffects [] - - SeeAlso [] - -***********************************************************************/ -Kit_DsdNtk_t * Kit_DsdDecomposeMux( unsigned * pTruth, int nVars, int nDecMux ) -{ - return Kit_DsdDecomposeInt( pTruth, nVars, nDecMux ); -} - -/**Function************************************************************* - - Synopsis [Performs decomposition of the truth table.] - - Description [] - - SideEffects [] - - SeeAlso [] - -***********************************************************************/ -int Kit_DsdTestCofs( Kit_DsdNtk_t * pNtk, unsigned * pTruthInit ) -{ - Kit_DsdNtk_t * pNtk0, * pNtk1, * pTemp; -// Kit_DsdObj_t * pRoot; - unsigned * pCofs2[2] = { pNtk->pMem, pNtk->pMem + Kit_TruthWordNum(pNtk->nVars) }; - unsigned i, * pTruth; - int fVerbose = 1; - int RetValue = 0; - - pTruth = pTruthInit; -// pRoot = Kit_DsdNtkRoot(pNtk); -// pTruth = Kit_DsdObjTruth(pRoot); -// assert( pRoot->nFans == pNtk->nVars ); - - if ( fVerbose ) - { - printf( "Function: " ); -// Extra_PrintBinary( stdout, pTruth, (1 << pNtk->nVars) ); - Extra_PrintHexadecimal( stdout, pTruth, pNtk->nVars ); - printf( "\n" ); - Kit_DsdPrint( stdout, pNtk ); - } - for ( i = 0; i < pNtk->nVars; i++ ) - { - Kit_TruthCofactor0New( pCofs2[0], pTruth, pNtk->nVars, i ); - pNtk0 = Kit_DsdDecompose( pCofs2[0], pNtk->nVars ); - pNtk0 = Kit_DsdExpand( pTemp = pNtk0 ); - Kit_DsdNtkFree( pTemp ); - - if ( fVerbose ) - { - printf( "Cof%d0: ", i ); - Kit_DsdPrint( stdout, pNtk0 ); - } - - Kit_TruthCofactor1New( pCofs2[1], pTruth, pNtk->nVars, i ); - pNtk1 = Kit_DsdDecompose( pCofs2[1], pNtk->nVars ); - pNtk1 = Kit_DsdExpand( pTemp = pNtk1 ); - Kit_DsdNtkFree( pTemp ); - - if ( fVerbose ) - { - printf( "Cof%d1: ", i ); - Kit_DsdPrint( stdout, pNtk1 ); - } - -// if ( Kit_DsdCheckVar4Dec2( pNtk0, pNtk1 ) ) -// RetValue = 1; - - Kit_DsdNtkFree( pNtk0 ); - Kit_DsdNtkFree( pNtk1 ); - } - if ( fVerbose ) - printf( "\n" ); - - return RetValue; -} - -/**Function************************************************************* - - Synopsis [Performs decomposition of the truth table.] - - Description [] - - SideEffects [] - - SeeAlso [] - -***********************************************************************/ -int Kit_DsdEval( unsigned * pTruth, int nVars, int nLutSize ) -{ - Kit_DsdMan_t * p; - Kit_DsdNtk_t * pNtk; - unsigned * pTruthC; - int Result; - - // decompose the function - pNtk = Kit_DsdDecompose( pTruth, nVars ); - Result = Kit_DsdCountLuts( pNtk, nLutSize ); -// printf( "\n" ); -// Kit_DsdPrint( stdout, pNtk ); -// printf( "Eval = %d.\n", Result ); - - // recompute the truth table - p = Kit_DsdManAlloc( nVars, Kit_DsdNtkObjNum(pNtk) ); - pTruthC = Kit_DsdTruthCompute( p, pNtk ); - if ( !Kit_TruthIsEqual( pTruth, pTruthC, nVars ) ) - printf( "Verification failed.\n" ); - Kit_DsdManFree( p ); - - Kit_DsdNtkFree( pNtk ); - return Result; -} - -/**Function************************************************************* - - Synopsis [Performs decomposition of the truth table.] - - Description [] - - SideEffects [] - - SeeAlso [] - -***********************************************************************/ -void Kit_DsdVerify( Kit_DsdNtk_t * pNtk, unsigned * pTruth, int nVars ) -{ - Kit_DsdMan_t * p; - unsigned * pTruthC; - p = Kit_DsdManAlloc( nVars, Kit_DsdNtkObjNum(pNtk)+2 ); - pTruthC = Kit_DsdTruthCompute( p, pNtk ); - if ( !Extra_TruthIsEqual( pTruth, pTruthC, nVars ) ) - printf( "Verification failed.\n" ); - Kit_DsdManFree( p ); -} - -/**Function************************************************************* - - Synopsis [Performs decomposition of the truth table.] - - Description [] - - SideEffects [] - - SeeAlso [] - -***********************************************************************/ -void Kit_DsdTest( unsigned * pTruth, int nVars ) -{ - Kit_DsdMan_t * p; - unsigned * pTruthC; - Kit_DsdNtk_t * pNtk, * pTemp; - pNtk = Kit_DsdDecompose( pTruth, nVars ); - -// if ( Kit_DsdFindLargeBox(pNtk, Kit_DsdLit2Var(pNtk->Root)) ) -// Kit_DsdPrint( stdout, pNtk ); - -// if ( Kit_DsdNtkRoot(pNtk)->nFans == (unsigned)nVars && nVars == 6 ) - - printf( "\n" ); - Kit_DsdPrint( stdout, pNtk ); - - pNtk = Kit_DsdExpand( pTemp = pNtk ); - Kit_DsdNtkFree( pTemp ); - - Kit_DsdPrint( stdout, pNtk ); - -// if ( Kit_DsdFindLargeBox(pNtk, Kit_DsdLit2Var(pNtk->Root)) ) -// Kit_DsdTestCofs( pNtk, pTruth ); - - // recompute the truth table - p = Kit_DsdManAlloc( nVars, Kit_DsdNtkObjNum(pNtk) ); - pTruthC = Kit_DsdTruthCompute( p, pNtk ); -// Extra_PrintBinary( stdout, pTruth, 1 << nVars ); printf( "\n" ); -// Extra_PrintBinary( stdout, pTruthC, 1 << nVars ); printf( "\n" ); - if ( Extra_TruthIsEqual( pTruth, pTruthC, nVars ) ) - { -// printf( "Verification is okay.\n" ); - } - else - printf( "Verification failed.\n" ); - Kit_DsdManFree( p ); - - - Kit_DsdNtkFree( pNtk ); -} - -/**Function************************************************************* - - Synopsis [Performs decomposition of the truth table.] - - Description [] - - SideEffects [] - - SeeAlso [] - -***********************************************************************/ -void Kit_DsdPrecompute4Vars() -{ - Kit_DsdMan_t * p; - Kit_DsdNtk_t * pNtk, * pTemp; - FILE * pFile; - unsigned uTruth; - unsigned * pTruthC; - char Buffer[256]; - int i, RetValue; - int Counter1 = 0, Counter2 = 0; - - pFile = fopen( "5npn/npn4.txt", "r" ); - for ( i = 0; fgets( Buffer, 100, pFile ); i++ ) - { - Buffer[6] = 0; - Extra_ReadHexadecimal( &uTruth, Buffer+2, 4 ); - uTruth = ((uTruth & 0xffff) << 16) | (uTruth & 0xffff); - pNtk = Kit_DsdDecompose( &uTruth, 4 ); - - pNtk = Kit_DsdExpand( pTemp = pNtk ); - Kit_DsdNtkFree( pTemp ); - - - if ( Kit_DsdFindLargeBox(pNtk, 3) ) - { -// RetValue = 0; - RetValue = Kit_DsdTestCofs( pNtk, &uTruth ); - printf( "\n" ); - printf( "%3d : Non-DSD function %s %s\n", i, Buffer + 2, RetValue? "implementable" : "" ); - Kit_DsdPrint( stdout, pNtk ); - - Counter1++; - Counter2 += RetValue; - } - -/* - printf( "%3d : Function %s ", i, Buffer + 2 ); - if ( !Kit_DsdFindLargeBox(pNtk, 3) ) - Kit_DsdPrint( stdout, pNtk ); - else - printf( "\n" ); -*/ - - p = Kit_DsdManAlloc( 4, Kit_DsdNtkObjNum(pNtk) ); - pTruthC = Kit_DsdTruthCompute( p, pNtk ); - if ( !Extra_TruthIsEqual( &uTruth, pTruthC, 4 ) ) - printf( "Verification failed.\n" ); - Kit_DsdManFree( p ); - - Kit_DsdNtkFree( pNtk ); - } - fclose( pFile ); - printf( "non-DSD = %d implementable = %d\n", Counter1, Counter2 ); -} - - -/**Function************************************************************* - - Synopsis [Returns the set of cofactoring variables.] - - Description [If there is no DSD components returns 0.] - - SideEffects [] - - SeeAlso [] - -***********************************************************************/ -int Kit_DsdCofactoringGetVars( Kit_DsdNtk_t ** ppNtk, int nSize, int * pVars ) -{ - Kit_DsdObj_t * pObj; - unsigned m; - int i, k, v, Var, nVars, iFaninLit; - // go through all the networks - nVars = 0; - for ( i = 0; i < nSize; i++ ) - { - // go through the prime objects of each networks - Kit_DsdNtkForEachObj( ppNtk[i], pObj, k ) - { - if ( pObj->Type != KIT_DSD_PRIME ) - continue; - if ( pObj->nFans == 3 ) - continue; - // collect direct fanin variables - Kit_DsdObjForEachFanin( ppNtk[i], pObj, iFaninLit, m ) - { - if ( !Kit_DsdLitIsLeaf(ppNtk[i], iFaninLit) ) - continue; - // add it to the array - Var = Kit_DsdLit2Var( iFaninLit ); - for ( v = 0; v < nVars; v++ ) - if ( pVars[v] == Var ) - break; - if ( v == nVars ) - pVars[nVars++] = Var; - } - } - } - return nVars; -} - -/**Function************************************************************* - - Synopsis [Canonical decomposition into completely DSD-structure.] - - Description [Returns the number of cofactoring steps. Also returns - the cofactoring variables in pVars.] - - SideEffects [] - - SeeAlso [] - -***********************************************************************/ -int Kit_DsdCofactoring( unsigned * pTruth, int nVars, int * pCofVars, int nLimit, int fVerbose ) -{ - Kit_DsdNtk_t * ppNtks[5][16] = {0}, * pTemp; - unsigned * ppCofs[5][16]; - int pTryVars[16], nTryVars; - int nPrimeSizeMin, nPrimeSizeMax, nPrimeSizeCur; - int nSuppSizeMin, nSuppSizeMax, iVarBest; - int i, k, v, nStep, nSize, nMemSize; - assert( nLimit < 5 ); - - // allocate storage for cofactors - nMemSize = Kit_TruthWordNum(nVars); - ppCofs[0][0] = ALLOC( unsigned, 80 * nMemSize ); - nSize = 0; - for ( i = 0; i < 5; i++ ) - for ( k = 0; k < 16; k++ ) - ppCofs[i][k] = ppCofs[0][0] + nMemSize * nSize++; - assert( nSize == 80 ); - - // copy the function - Kit_TruthCopy( ppCofs[0][0], pTruth, nVars ); - ppNtks[0][0] = Kit_DsdDecompose( ppCofs[0][0], nVars ); - - if ( fVerbose ) - printf( "\nProcessing prime function with %d support variables:\n", nVars ); - - // perform recursive cofactoring - for ( nStep = 0; nStep < nLimit; nStep++ ) - { - nSize = (1 << nStep); - // find the variables to use in the cofactoring step - nTryVars = Kit_DsdCofactoringGetVars( ppNtks[nStep], nSize, pTryVars ); - if ( nTryVars == 0 ) - break; - // cofactor w.r.t. the above variables - iVarBest = -1; - nPrimeSizeMin = 10000; - nSuppSizeMin = 10000; - for ( v = 0; v < nTryVars; v++ ) - { - nPrimeSizeMax = 0; - nSuppSizeMax = 0; - for ( i = 0; i < nSize; i++ ) - { - // cofactor and decompose cofactors - Kit_TruthCofactor0New( ppCofs[nStep+1][2*i+0], ppCofs[nStep][i], nVars, pTryVars[v] ); - Kit_TruthCofactor1New( ppCofs[nStep+1][2*i+1], ppCofs[nStep][i], nVars, pTryVars[v] ); - ppNtks[nStep+1][2*i+0] = Kit_DsdDecompose( ppCofs[nStep+1][2*i+0], nVars ); - ppNtks[nStep+1][2*i+1] = Kit_DsdDecompose( ppCofs[nStep+1][2*i+1], nVars ); - // compute the largest non-decomp block - nPrimeSizeCur = Kit_DsdNonDsdSizeMax(ppNtks[nStep+1][2*i+0]); - nPrimeSizeMax = KIT_MAX( nPrimeSizeMax, nPrimeSizeCur ); - nPrimeSizeCur = Kit_DsdNonDsdSizeMax(ppNtks[nStep+1][2*i+1]); - nPrimeSizeMax = KIT_MAX( nPrimeSizeMax, nPrimeSizeCur ); - // compute the sum total of supports - nSuppSizeMax += Kit_TruthSupportSize( ppCofs[nStep+1][2*i+0], nVars ); - nSuppSizeMax += Kit_TruthSupportSize( ppCofs[nStep+1][2*i+1], nVars ); - // free the networks - Kit_DsdNtkFree( ppNtks[nStep+1][2*i+0] ); - Kit_DsdNtkFree( ppNtks[nStep+1][2*i+1] ); - } - // find the min max support size of the prime component - if ( nPrimeSizeMin > nPrimeSizeMax || (nPrimeSizeMin == nPrimeSizeMax && nSuppSizeMin > nSuppSizeMax) ) - { - nPrimeSizeMin = nPrimeSizeMax; - nSuppSizeMin = nSuppSizeMax; - iVarBest = pTryVars[v]; - } - } - assert( iVarBest != -1 ); - // save the variable - if ( pCofVars ) - pCofVars[nStep] = iVarBest; - // cofactor w.r.t. the best - for ( i = 0; i < nSize; i++ ) - { - Kit_TruthCofactor0New( ppCofs[nStep+1][2*i+0], ppCofs[nStep][i], nVars, iVarBest ); - Kit_TruthCofactor1New( ppCofs[nStep+1][2*i+1], ppCofs[nStep][i], nVars, iVarBest ); - ppNtks[nStep+1][2*i+0] = Kit_DsdDecompose( ppCofs[nStep+1][2*i+0], nVars ); - ppNtks[nStep+1][2*i+1] = Kit_DsdDecompose( ppCofs[nStep+1][2*i+1], nVars ); - if ( fVerbose ) - { - ppNtks[nStep+1][2*i+0] = Kit_DsdExpand( pTemp = ppNtks[nStep+1][2*i+0] ); - Kit_DsdNtkFree( pTemp ); - ppNtks[nStep+1][2*i+1] = Kit_DsdExpand( pTemp = ppNtks[nStep+1][2*i+1] ); - Kit_DsdNtkFree( pTemp ); - - printf( "Cof%d%d: ", nStep+1, 2*i+0 ); - Kit_DsdPrint( stdout, ppNtks[nStep+1][2*i+0] ); - printf( "Cof%d%d: ", nStep+1, 2*i+1 ); - Kit_DsdPrint( stdout, ppNtks[nStep+1][2*i+1] ); - } - } - } - - // free the networks - for ( i = 0; i < 5; i++ ) - for ( k = 0; k < 16; k++ ) - if ( ppNtks[i][k] ) - Kit_DsdNtkFree( ppNtks[i][k] ); - free( ppCofs[0][0] ); - - assert( nStep <= nLimit ); - return nStep; -} - -/**Function************************************************************* - - Synopsis [Canonical decomposition into completely DSD-structure.] - - Description [Returns the number of cofactoring steps. Also returns - the cofactoring variables in pVars.] - - SideEffects [] - - SeeAlso [] - -***********************************************************************/ -void Kit_DsdPrintCofactors( unsigned * pTruth, int nVars, int nCofLevel, int fVerbose ) -{ - Kit_DsdNtk_t * ppNtks[32] = {0}, * pTemp; - unsigned * ppCofs[5][16]; - int piCofVar[5]; - int nPrimeSizeMax, nPrimeSizeCur, nSuppSizeMax; - int i, k, v1, v2, v3, v4, s, nSteps, nSize, nMemSize; - assert( nCofLevel < 5 ); - - // print the function - ppNtks[0] = Kit_DsdDecompose( pTruth, nVars ); - ppNtks[0] = Kit_DsdExpand( pTemp = ppNtks[0] ); - Kit_DsdNtkFree( pTemp ); - if ( fVerbose ) - Kit_DsdPrint( stdout, ppNtks[0] ); - Kit_DsdNtkFree( ppNtks[0] ); - - // allocate storage for cofactors - nMemSize = Kit_TruthWordNum(nVars); - ppCofs[0][0] = ALLOC( unsigned, 80 * nMemSize ); - nSize = 0; - for ( i = 0; i < 5; i++ ) - for ( k = 0; k < 16; k++ ) - ppCofs[i][k] = ppCofs[0][0] + nMemSize * nSize++; - assert( nSize == 80 ); - - // copy the function - Kit_TruthCopy( ppCofs[0][0], pTruth, nVars ); - - if ( nCofLevel == 1 ) - for ( v1 = 0; v1 < nVars; v1++ ) - { - nSteps = 0; - piCofVar[nSteps++] = v1; - - printf( " Variables { " ); - for ( i = 0; i < nSteps; i++ ) - printf( "%c ", 'a' + piCofVar[i] ); - printf( "}\n" ); - - // single cofactors - for ( s = 1; s <= nSteps; s++ ) - { - for ( k = 0; k < s; k++ ) - { - nSize = (1 << k); - for ( i = 0; i < nSize; i++ ) - { - Kit_TruthCofactor0New( ppCofs[k+1][2*i+0], ppCofs[k][i], nVars, piCofVar[k] ); - Kit_TruthCofactor1New( ppCofs[k+1][2*i+1], ppCofs[k][i], nVars, piCofVar[k] ); - } - } - } - // compute DSD networks - nSize = (1 << nSteps); - nPrimeSizeMax = 0; - nSuppSizeMax = 0; - for ( i = 0; i < nSize; i++ ) - { - ppNtks[i] = Kit_DsdDecompose( ppCofs[nSteps][i], nVars ); - ppNtks[i] = Kit_DsdExpand( pTemp = ppNtks[i] ); - Kit_DsdNtkFree( pTemp ); - if ( fVerbose ) - { - printf( "Cof%d%d: ", nSteps, i ); - Kit_DsdPrint( stdout, ppNtks[i] ); - } - // compute the largest non-decomp block - nPrimeSizeCur = Kit_DsdNonDsdSizeMax(ppNtks[i]); - nPrimeSizeMax = KIT_MAX( nPrimeSizeMax, nPrimeSizeCur ); - Kit_DsdNtkFree( ppNtks[i] ); - nSuppSizeMax += Kit_TruthSupportSize( ppCofs[nSteps][i], nVars ); - } - printf( "Max = %2d. Supps = %2d.\n", nPrimeSizeMax, nSuppSizeMax ); - } - - if ( nCofLevel == 2 ) - for ( v1 = 0; v1 < nVars; v1++ ) - for ( v2 = v1+1; v2 < nVars; v2++ ) - { - nSteps = 0; - piCofVar[nSteps++] = v1; - piCofVar[nSteps++] = v2; - - printf( " Variables { " ); - for ( i = 0; i < nSteps; i++ ) - printf( "%c ", 'a' + piCofVar[i] ); - printf( "}\n" ); - - // single cofactors - for ( s = 1; s <= nSteps; s++ ) - { - for ( k = 0; k < s; k++ ) - { - nSize = (1 << k); - for ( i = 0; i < nSize; i++ ) - { - Kit_TruthCofactor0New( ppCofs[k+1][2*i+0], ppCofs[k][i], nVars, piCofVar[k] ); - Kit_TruthCofactor1New( ppCofs[k+1][2*i+1], ppCofs[k][i], nVars, piCofVar[k] ); - } - } - } - // compute DSD networks - nSize = (1 << nSteps); - nPrimeSizeMax = 0; - nSuppSizeMax = 0; - for ( i = 0; i < nSize; i++ ) - { - ppNtks[i] = Kit_DsdDecompose( ppCofs[nSteps][i], nVars ); - ppNtks[i] = Kit_DsdExpand( pTemp = ppNtks[i] ); - Kit_DsdNtkFree( pTemp ); - if ( fVerbose ) - { - printf( "Cof%d%d: ", nSteps, i ); - Kit_DsdPrint( stdout, ppNtks[i] ); - } - // compute the largest non-decomp block - nPrimeSizeCur = Kit_DsdNonDsdSizeMax(ppNtks[i]); - nPrimeSizeMax = KIT_MAX( nPrimeSizeMax, nPrimeSizeCur ); - Kit_DsdNtkFree( ppNtks[i] ); - nSuppSizeMax += Kit_TruthSupportSize( ppCofs[nSteps][i], nVars ); - } - printf( "Max = %2d. Supps = %2d.\n", nPrimeSizeMax, nSuppSizeMax ); - } - - if ( nCofLevel == 3 ) - for ( v1 = 0; v1 < nVars; v1++ ) - for ( v2 = v1+1; v2 < nVars; v2++ ) - for ( v3 = v2+1; v3 < nVars; v3++ ) - { - nSteps = 0; - piCofVar[nSteps++] = v1; - piCofVar[nSteps++] = v2; - piCofVar[nSteps++] = v3; - - printf( " Variables { " ); - for ( i = 0; i < nSteps; i++ ) - printf( "%c ", 'a' + piCofVar[i] ); - printf( "}\n" ); - - // single cofactors - for ( s = 1; s <= nSteps; s++ ) - { - for ( k = 0; k < s; k++ ) - { - nSize = (1 << k); - for ( i = 0; i < nSize; i++ ) - { - Kit_TruthCofactor0New( ppCofs[k+1][2*i+0], ppCofs[k][i], nVars, piCofVar[k] ); - Kit_TruthCofactor1New( ppCofs[k+1][2*i+1], ppCofs[k][i], nVars, piCofVar[k] ); - } - } - } - // compute DSD networks - nSize = (1 << nSteps); - nPrimeSizeMax = 0; - nSuppSizeMax = 0; - for ( i = 0; i < nSize; i++ ) - { - ppNtks[i] = Kit_DsdDecompose( ppCofs[nSteps][i], nVars ); - ppNtks[i] = Kit_DsdExpand( pTemp = ppNtks[i] ); - Kit_DsdNtkFree( pTemp ); - if ( fVerbose ) - { - printf( "Cof%d%d: ", nSteps, i ); - Kit_DsdPrint( stdout, ppNtks[i] ); - } - // compute the largest non-decomp block - nPrimeSizeCur = Kit_DsdNonDsdSizeMax(ppNtks[i]); - nPrimeSizeMax = KIT_MAX( nPrimeSizeMax, nPrimeSizeCur ); - Kit_DsdNtkFree( ppNtks[i] ); - nSuppSizeMax += Kit_TruthSupportSize( ppCofs[nSteps][i], nVars ); - } - printf( "Max = %2d. Supps = %2d.\n", nPrimeSizeMax, nSuppSizeMax ); - } - - if ( nCofLevel == 4 ) - for ( v1 = 0; v1 < nVars; v1++ ) - for ( v2 = v1+1; v2 < nVars; v2++ ) - for ( v3 = v2+1; v3 < nVars; v3++ ) - for ( v4 = v3+1; v4 < nVars; v4++ ) - { - nSteps = 0; - piCofVar[nSteps++] = v1; - piCofVar[nSteps++] = v2; - piCofVar[nSteps++] = v3; - piCofVar[nSteps++] = v4; - - printf( " Variables { " ); - for ( i = 0; i < nSteps; i++ ) - printf( "%c ", 'a' + piCofVar[i] ); - printf( "}\n" ); - - // single cofactors - for ( s = 1; s <= nSteps; s++ ) - { - for ( k = 0; k < s; k++ ) - { - nSize = (1 << k); - for ( i = 0; i < nSize; i++ ) - { - Kit_TruthCofactor0New( ppCofs[k+1][2*i+0], ppCofs[k][i], nVars, piCofVar[k] ); - Kit_TruthCofactor1New( ppCofs[k+1][2*i+1], ppCofs[k][i], nVars, piCofVar[k] ); - } - } - } - // compute DSD networks - nSize = (1 << nSteps); - nPrimeSizeMax = 0; - nSuppSizeMax = 0; - for ( i = 0; i < nSize; i++ ) - { - ppNtks[i] = Kit_DsdDecompose( ppCofs[nSteps][i], nVars ); - ppNtks[i] = Kit_DsdExpand( pTemp = ppNtks[i] ); - Kit_DsdNtkFree( pTemp ); - if ( fVerbose ) - { - printf( "Cof%d%d: ", nSteps, i ); - Kit_DsdPrint( stdout, ppNtks[i] ); - } - // compute the largest non-decomp block - nPrimeSizeCur = Kit_DsdNonDsdSizeMax(ppNtks[i]); - nPrimeSizeMax = KIT_MAX( nPrimeSizeMax, nPrimeSizeCur ); - Kit_DsdNtkFree( ppNtks[i] ); - nSuppSizeMax += Kit_TruthSupportSize( ppCofs[nSteps][i], nVars ); - } - printf( "Max = %2d. Supps = %2d.\n", nPrimeSizeMax, nSuppSizeMax ); - } - - - free( ppCofs[0][0] ); -} - -//////////////////////////////////////////////////////////////////////// -/// END OF FILE /// -//////////////////////////////////////////////////////////////////////// - - -- cgit v1.2.3