abc/src/opt/lpk/lpkMux.c - third_party/vtr-verilog-to-routing - Git at Google

 /**CFile****************************************************************

   FileName    [lpkMux.c]

   SystemName  [ABC: Logic synthesis and verification system.]

   PackageName [Fast Boolean matching for LUT structures.]

   Synopsis    []

   Author      [Alan Mishchenko]

   Affiliation [UC Berkeley]

   Date        [Ver. 1.0. Started - April 28, 2007.]

   Revision    [$Id: lpkMux.c,v 1.00 2007/04/28 00:00:00 alanmi Exp $]

 ***********************************************************************/

 #include "lpkInt.h"

 ABC_NAMESPACE_IMPL_START


 ////////////////////////////////////////////////////////////////////////
 ///                        DECLARATIONS                              ///
 ////////////////////////////////////////////////////////////////////////

 ////////////////////////////////////////////////////////////////////////
 ///                     FUNCTION DEFINITIONS                         ///
 ////////////////////////////////////////////////////////////////////////

 /**Function*************************************************************

   Synopsis    [Find the best cofactoring variable.]

   Description []

   SideEffects []

   SeeAlso     []

 ***********************************************************************/
 int Lpk_MapTreeBestCofVar( Lpk_Man_t * p, unsigned * pTruth, int nVars, unsigned * pCof0, unsigned * pCof1 )
 {
     int i, iBestVar, nSuppSizeCur0, nSuppSizeCur1, nSuppSizeCur, nSuppSizeMin;
     // iterate through variables
     iBestVar = -1;
     nSuppSizeMin = KIT_INFINITY;
     for ( i = 0; i < nVars; i++ )
     {
         // cofactor the functiona and get support sizes
         Kit_TruthCofactor0New( pCof0, pTruth, nVars, i );
         Kit_TruthCofactor1New( pCof1, pTruth, nVars, i );
         nSuppSizeCur0 = Kit_TruthSupportSize( pCof0, nVars );
         nSuppSizeCur1 = Kit_TruthSupportSize( pCof1, nVars );
         nSuppSizeCur  = nSuppSizeCur0 + nSuppSizeCur1;
         // skip cofactoring that goes above the limit
         if ( nSuppSizeCur0 > p->pPars->nLutSize || nSuppSizeCur1 > p->pPars->nLutSize )
             continue;
         // compare this variable with other variables
         if ( nSuppSizeMin > nSuppSizeCur )
         {
             nSuppSizeMin = nSuppSizeCur;
             iBestVar = i;
         }
     }
     // cofactor w.r.t. this variable
     if ( iBestVar != -1 )
     {
         Kit_TruthCofactor0New( pCof0, pTruth, nVars, iBestVar );
         Kit_TruthCofactor1New( pCof1, pTruth, nVars, iBestVar );
     }
     return iBestVar;
 }

 /**Function*************************************************************

   Synopsis    [Maps the function by the best cofactoring.]

   Description []

   SideEffects []

   SeeAlso     []

 ***********************************************************************/
 If_Obj_t * Lpk_MapTreeMux_rec( Lpk_Man_t * p, unsigned * pTruth, int nVars, If_Obj_t ** ppLeaves )
 {
     unsigned * pCof0 = (unsigned *)Vec_PtrEntry( p->vTtNodes, 0 );
     unsigned * pCof1 = (unsigned *)Vec_PtrEntry( p->vTtNodes, 1 );
     If_Obj_t * pObj0, * pObj1;
     Kit_DsdNtk_t * ppNtks[2];
     int iBestVar;
     assert( nVars > 3 );
     p->fCalledOnce = 1;
     // cofactor w.r.t. the best variable
     iBestVar = Lpk_MapTreeBestCofVar( p, pTruth, nVars, pCof0, pCof1 );
     if ( iBestVar == -1 )
         return NULL;
     // decompose the functions
     ppNtks[0] = Kit_DsdDecompose( pCof0, nVars );
     ppNtks[1] = Kit_DsdDecompose( pCof1, nVars );
     if ( p->pPars->fVeryVerbose )
     {
         printf( "Cofactoring w.r.t. var %c (%d -> %d+%d supp vars):\n",
             'a'+iBestVar, nVars, Kit_TruthSupportSize(pCof0, nVars), Kit_TruthSupportSize(pCof1, nVars) );
         Kit_DsdPrintExpanded( ppNtks[0] );
         Kit_DsdPrintExpanded( ppNtks[1] );
     }
     // map the DSD structures
     pObj0 = Lpk_MapTree_rec( p, ppNtks[0], ppLeaves, ppNtks[0]->Root, NULL );
     pObj1 = Lpk_MapTree_rec( p, ppNtks[1], ppLeaves, ppNtks[1]->Root, NULL );
     Kit_DsdNtkFree( ppNtks[0] );
     Kit_DsdNtkFree( ppNtks[1] );
     return If_ManCreateMux( p->pIfMan, pObj0, pObj1, ppLeaves[iBestVar] );
 }


 /**Function*************************************************************

   Synopsis    [Implements support-reducing decomposition.]

   Description []

   SideEffects []

   SeeAlso     []

 ***********************************************************************/
 If_Obj_t * Lpk_MapSuppRedDec_rec( Lpk_Man_t * p, unsigned * pTruth, int nVars, If_Obj_t ** ppLeaves )
 {
     Kit_DsdNtk_t * pNtkDec, * pNtkComp, * ppNtks[2], * pTemp;
     If_Obj_t * pObjNew;
     unsigned * pCof0 = (unsigned *)Vec_PtrEntry( p->vTtNodes,  0 );
     unsigned * pCof1 = (unsigned *)Vec_PtrEntry( p->vTtNodes,  1 );
     unsigned * pDec0 = (unsigned *)Vec_PtrEntry( p->vTtNodes,  2 );
     unsigned * pDec1 = (unsigned *)Vec_PtrEntry( p->vTtNodes,  3 );
     unsigned * pDec  = (unsigned *)Vec_PtrEntry( p->vTtNodes,  4 );
     unsigned * pCo00 = (unsigned *)Vec_PtrEntry( p->vTtNodes,  5 );
     unsigned * pCo01 = (unsigned *)Vec_PtrEntry( p->vTtNodes,  6 );
     unsigned * pCo10 = (unsigned *)Vec_PtrEntry( p->vTtNodes,  7 );
     unsigned * pCo11 = (unsigned *)Vec_PtrEntry( p->vTtNodes,  8 );
     unsigned * pCo0  = (unsigned *)Vec_PtrEntry( p->vTtNodes,  9 );
     unsigned * pCo1  = (unsigned *)Vec_PtrEntry( p->vTtNodes, 10 );
     unsigned * pCo   = (unsigned *)Vec_PtrEntry( p->vTtNodes, 11 );
     int TrueMint0, TrueMint1, FalseMint0, FalseMint1;
     int uSubsets, uSubset0, uSubset1, iVar, iVarReused, i;

     // determine if supp-red decomposition exists
     uSubsets = Lpk_MapSuppRedDecSelect( p, pTruth, nVars, &iVar, &iVarReused );
     if ( uSubsets == 0 )
         return NULL;
     p->nCalledSRed++;

     // get the cofactors
     Kit_TruthCofactor0New( pCof0, pTruth, nVars, iVar );
     Kit_TruthCofactor1New( pCof1, pTruth, nVars, iVar );

     // get the bound sets
     uSubset0 = uSubsets & 0xFFFF;
     uSubset1 = uSubsets >> 16;

     // compute the decomposed functions
     ppNtks[0] = Kit_DsdDecompose( pCof0, nVars );
     ppNtks[1] = Kit_DsdDecompose( pCof1, nVars );
     ppNtks[0] = Kit_DsdExpand( pTemp = ppNtks[0] );      Kit_DsdNtkFree( pTemp );
     ppNtks[1] = Kit_DsdExpand( pTemp = ppNtks[1] );      Kit_DsdNtkFree( pTemp );
     Kit_DsdTruthPartial( p->pDsdMan, ppNtks[0], pDec0, uSubset0 );
     Kit_DsdTruthPartial( p->pDsdMan, ppNtks[1], pDec1, uSubset1 );
 //    Kit_DsdTruthPartialTwo( p->pDsdMan, ppNtks[0], uSubset0, iVarReused, pCo0, pDec0 );
 //    Kit_DsdTruthPartialTwo( p->pDsdMan, ppNtks[1], uSubset1, iVarReused, pCo1, pDec1 );
     Kit_DsdNtkFree( ppNtks[0] );
     Kit_DsdNtkFree( ppNtks[1] );
 //Kit_DsdPrintFromTruth( pDec0, nVars );
 //Kit_DsdPrintFromTruth( pDec1, nVars );
     // get the decomposed function
     Kit_TruthMuxVar( pDec, pDec0, pDec1, nVars, iVar );

     // find any true assignments of the decomposed functions
     TrueMint0 = Kit_TruthFindFirstBit( pDec0, nVars );
     TrueMint1 = Kit_TruthFindFirstBit( pDec1, nVars );
     assert( TrueMint0 >= 0 && TrueMint1 >= 0 );
     // find any false assignments of the decomposed functions
     FalseMint0 = Kit_TruthFindFirstZero( pDec0, nVars );
     FalseMint1 = Kit_TruthFindFirstZero( pDec1, nVars );
     assert( FalseMint0 >= 0 && FalseMint1 >= 0 );

     // cofactor the cofactors according to these minterms
     Kit_TruthCopy( pCo00, pCof0, nVars );
     Kit_TruthCopy( pCo01, pCof0, nVars );
     for ( i = 0; i < nVars; i++ )
         if ( uSubset0 & (1 << i) )
         {
             if ( FalseMint0 & (1 << i) )
                 Kit_TruthCofactor1( pCo00, nVars, i );
             else
                 Kit_TruthCofactor0( pCo00, nVars, i );
             if ( TrueMint0 & (1 << i) )
                 Kit_TruthCofactor1( pCo01, nVars, i );
             else
                 Kit_TruthCofactor0( pCo01, nVars, i );
         }
     Kit_TruthCopy( pCo10, pCof1, nVars );
     Kit_TruthCopy( pCo11, pCof1, nVars );
     for ( i = 0; i < nVars; i++ )
         if ( uSubset1 & (1 << i) )
         {
             if ( FalseMint1 & (1 << i) )
                 Kit_TruthCofactor1( pCo10, nVars, i );
             else
                 Kit_TruthCofactor0( pCo10, nVars, i );
             if ( TrueMint1 & (1 << i) )
                 Kit_TruthCofactor1( pCo11, nVars, i );
             else
                 Kit_TruthCofactor0( pCo11, nVars, i );
         }

     // derive the functions by composing them with the new variable (iVarReused)
     Kit_TruthMuxVar( pCo0, pCo00, pCo01, nVars, iVarReused );
     Kit_TruthMuxVar( pCo1, pCo10, pCo11, nVars, iVarReused );
 //Kit_DsdPrintFromTruth( pCo0, nVars );
 //Kit_DsdPrintFromTruth( pCo1, nVars );

     // derive the composition function
     Kit_TruthMuxVar( pCo , pCo0 , pCo1 , nVars, iVar );

     // process the decomposed function
     pNtkDec = Kit_DsdDecompose( pDec, nVars );
     pNtkComp = Kit_DsdDecompose( pCo, nVars );
 //Kit_DsdPrint( stdout, pNtkDec );
 //Kit_DsdPrint( stdout, pNtkComp );
 //printf( "cofactored variable %c\n", 'a' + iVar );
 //printf( "reused variable %c\n", 'a' + iVarReused );

     ppLeaves[iVarReused] = Lpk_MapTree_rec( p, pNtkDec, ppLeaves, pNtkDec->Root, NULL );
     pObjNew = Lpk_MapTree_rec( p, pNtkComp, ppLeaves, pNtkComp->Root, NULL );

     Kit_DsdNtkFree( pNtkDec );
     Kit_DsdNtkFree( pNtkComp );
     return pObjNew;
 }

 ////////////////////////////////////////////////////////////////////////
 ///                       END OF FILE                                ///
 ////////////////////////////////////////////////////////////////////////


 ABC_NAMESPACE_IMPL_END
	/CFile**************************************************************

	FileName [lpkMux.c]

	SystemName [ABC: Logic synthesis and verification system.]

	PackageName [Fast Boolean matching for LUT structures.]

	Synopsis []

	Author [Alan Mishchenko]

	Affiliation [UC Berkeley]

	Date [Ver. 1.0. Started - April 28, 2007.]

	Revision [$Id: lpkMux.c,v 1.00 2007/04/28 00:00:00 alanmi Exp $]

	***********************************************************************/

	#include "lpkInt.h"

	ABC_NAMESPACE_IMPL_START


	////////////////////////////////////////////////////////////////////////
	/// DECLARATIONS ///
	////////////////////////////////////////////////////////////////////////

	////////////////////////////////////////////////////////////////////////
	/// FUNCTION DEFINITIONS ///
	////////////////////////////////////////////////////////////////////////

	/Function***********************************************************

	Synopsis [Find the best cofactoring variable.]

	Description []

	SideEffects []

	SeeAlso []

	***********************************************************************/
	int Lpk_MapTreeBestCofVar( Lpk_Man_t * p, unsigned * pTruth, int nVars, unsigned * pCof0, unsigned * pCof1 )
	{
	int i, iBestVar, nSuppSizeCur0, nSuppSizeCur1, nSuppSizeCur, nSuppSizeMin;
	// iterate through variables
	iBestVar = -1;
	nSuppSizeMin = KIT_INFINITY;
	for ( i = 0; i < nVars; i++ )
	{
	// cofactor the functiona and get support sizes
	Kit_TruthCofactor0New( pCof0, pTruth, nVars, i );
	Kit_TruthCofactor1New( pCof1, pTruth, nVars, i );
	nSuppSizeCur0 = Kit_TruthSupportSize( pCof0, nVars );
	nSuppSizeCur1 = Kit_TruthSupportSize( pCof1, nVars );
	nSuppSizeCur = nSuppSizeCur0 + nSuppSizeCur1;
	// skip cofactoring that goes above the limit
	if ( nSuppSizeCur0 > p->pPars->nLutSize \|\| nSuppSizeCur1 > p->pPars->nLutSize )
	continue;
	// compare this variable with other variables
	if ( nSuppSizeMin > nSuppSizeCur )
	{
	nSuppSizeMin = nSuppSizeCur;
	iBestVar = i;
	}
	}
	// cofactor w.r.t. this variable
	if ( iBestVar != -1 )
	{
	Kit_TruthCofactor0New( pCof0, pTruth, nVars, iBestVar );
	Kit_TruthCofactor1New( pCof1, pTruth, nVars, iBestVar );
	}
	return iBestVar;
	}

	/Function***********************************************************

	Synopsis [Maps the function by the best cofactoring.]

	Description []

	SideEffects []

	SeeAlso []

	***********************************************************************/
	If_Obj_t * Lpk_MapTreeMux_rec( Lpk_Man_t * p, unsigned * pTruth, int nVars, If_Obj_t ** ppLeaves )
	{
	unsigned * pCof0 = (unsigned *)Vec_PtrEntry( p->vTtNodes, 0 );
	unsigned * pCof1 = (unsigned *)Vec_PtrEntry( p->vTtNodes, 1 );
	If_Obj_t * pObj0, * pObj1;
	Kit_DsdNtk_t * ppNtks[2];
	int iBestVar;
	assert( nVars > 3 );
	p->fCalledOnce = 1;
	// cofactor w.r.t. the best variable
	iBestVar = Lpk_MapTreeBestCofVar( p, pTruth, nVars, pCof0, pCof1 );
	if ( iBestVar == -1 )
	return NULL;
	// decompose the functions
	ppNtks[0] = Kit_DsdDecompose( pCof0, nVars );
	ppNtks[1] = Kit_DsdDecompose( pCof1, nVars );
	if ( p->pPars->fVeryVerbose )
	{
	printf( "Cofactoring w.r.t. var %c (%d -> %d+%d supp vars):\n",
	'a'+iBestVar, nVars, Kit_TruthSupportSize(pCof0, nVars), Kit_TruthSupportSize(pCof1, nVars) );
	Kit_DsdPrintExpanded( ppNtks[0] );
	Kit_DsdPrintExpanded( ppNtks[1] );
	}
	// map the DSD structures
	pObj0 = Lpk_MapTree_rec( p, ppNtks[0], ppLeaves, ppNtks[0]->Root, NULL );
	pObj1 = Lpk_MapTree_rec( p, ppNtks[1], ppLeaves, ppNtks[1]->Root, NULL );
	Kit_DsdNtkFree( ppNtks[0] );
	Kit_DsdNtkFree( ppNtks[1] );
	return If_ManCreateMux( p->pIfMan, pObj0, pObj1, ppLeaves[iBestVar] );
	}



	/Function***********************************************************

	Synopsis [Implements support-reducing decomposition.]

	Description []

	SideEffects []

	SeeAlso []

	***********************************************************************/
	If_Obj_t * Lpk_MapSuppRedDec_rec( Lpk_Man_t * p, unsigned * pTruth, int nVars, If_Obj_t ** ppLeaves )
	{
	Kit_DsdNtk_t * pNtkDec, * pNtkComp, * ppNtks[2], * pTemp;
	If_Obj_t * pObjNew;
	unsigned * pCof0 = (unsigned *)Vec_PtrEntry( p->vTtNodes, 0 );
	unsigned * pCof1 = (unsigned *)Vec_PtrEntry( p->vTtNodes, 1 );
	unsigned * pDec0 = (unsigned *)Vec_PtrEntry( p->vTtNodes, 2 );
	unsigned * pDec1 = (unsigned *)Vec_PtrEntry( p->vTtNodes, 3 );
	unsigned * pDec = (unsigned *)Vec_PtrEntry( p->vTtNodes, 4 );
	unsigned * pCo00 = (unsigned *)Vec_PtrEntry( p->vTtNodes, 5 );
	unsigned * pCo01 = (unsigned *)Vec_PtrEntry( p->vTtNodes, 6 );
	unsigned * pCo10 = (unsigned *)Vec_PtrEntry( p->vTtNodes, 7 );
	unsigned * pCo11 = (unsigned *)Vec_PtrEntry( p->vTtNodes, 8 );
	unsigned * pCo0 = (unsigned *)Vec_PtrEntry( p->vTtNodes, 9 );
	unsigned * pCo1 = (unsigned *)Vec_PtrEntry( p->vTtNodes, 10 );
	unsigned * pCo = (unsigned *)Vec_PtrEntry( p->vTtNodes, 11 );
	int TrueMint0, TrueMint1, FalseMint0, FalseMint1;
	int uSubsets, uSubset0, uSubset1, iVar, iVarReused, i;

	// determine if supp-red decomposition exists
	uSubsets = Lpk_MapSuppRedDecSelect( p, pTruth, nVars, &iVar, &iVarReused );
	if ( uSubsets == 0 )
	return NULL;
	p->nCalledSRed++;

	// get the cofactors
	Kit_TruthCofactor0New( pCof0, pTruth, nVars, iVar );
	Kit_TruthCofactor1New( pCof1, pTruth, nVars, iVar );

	// get the bound sets
	uSubset0 = uSubsets & 0xFFFF;
	uSubset1 = uSubsets >> 16;

	// compute the decomposed functions
	ppNtks[0] = Kit_DsdDecompose( pCof0, nVars );
	ppNtks[1] = Kit_DsdDecompose( pCof1, nVars );
	ppNtks[0] = Kit_DsdExpand( pTemp = ppNtks[0] ); Kit_DsdNtkFree( pTemp );
	ppNtks[1] = Kit_DsdExpand( pTemp = ppNtks[1] ); Kit_DsdNtkFree( pTemp );
	Kit_DsdTruthPartial( p->pDsdMan, ppNtks[0], pDec0, uSubset0 );
	Kit_DsdTruthPartial( p->pDsdMan, ppNtks[1], pDec1, uSubset1 );
	// Kit_DsdTruthPartialTwo( p->pDsdMan, ppNtks[0], uSubset0, iVarReused, pCo0, pDec0 );
	// Kit_DsdTruthPartialTwo( p->pDsdMan, ppNtks[1], uSubset1, iVarReused, pCo1, pDec1 );
	Kit_DsdNtkFree( ppNtks[0] );
	Kit_DsdNtkFree( ppNtks[1] );
	//Kit_DsdPrintFromTruth( pDec0, nVars );
	//Kit_DsdPrintFromTruth( pDec1, nVars );
	// get the decomposed function
	Kit_TruthMuxVar( pDec, pDec0, pDec1, nVars, iVar );

	// find any true assignments of the decomposed functions
	TrueMint0 = Kit_TruthFindFirstBit( pDec0, nVars );
	TrueMint1 = Kit_TruthFindFirstBit( pDec1, nVars );
	assert( TrueMint0 >= 0 && TrueMint1 >= 0 );
	// find any false assignments of the decomposed functions
	FalseMint0 = Kit_TruthFindFirstZero( pDec0, nVars );
	FalseMint1 = Kit_TruthFindFirstZero( pDec1, nVars );
	assert( FalseMint0 >= 0 && FalseMint1 >= 0 );

	// cofactor the cofactors according to these minterms
	Kit_TruthCopy( pCo00, pCof0, nVars );
	Kit_TruthCopy( pCo01, pCof0, nVars );
	for ( i = 0; i < nVars; i++ )
	if ( uSubset0 & (1 << i) )
	{
	if ( FalseMint0 & (1 << i) )
	Kit_TruthCofactor1( pCo00, nVars, i );
	else
	Kit_TruthCofactor0( pCo00, nVars, i );
	if ( TrueMint0 & (1 << i) )
	Kit_TruthCofactor1( pCo01, nVars, i );
	else
	Kit_TruthCofactor0( pCo01, nVars, i );
	}
	Kit_TruthCopy( pCo10, pCof1, nVars );
	Kit_TruthCopy( pCo11, pCof1, nVars );
	for ( i = 0; i < nVars; i++ )
	if ( uSubset1 & (1 << i) )
	{
	if ( FalseMint1 & (1 << i) )
	Kit_TruthCofactor1( pCo10, nVars, i );
	else
	Kit_TruthCofactor0( pCo10, nVars, i );
	if ( TrueMint1 & (1 << i) )
	Kit_TruthCofactor1( pCo11, nVars, i );
	else
	Kit_TruthCofactor0( pCo11, nVars, i );
	}

	// derive the functions by composing them with the new variable (iVarReused)
	Kit_TruthMuxVar( pCo0, pCo00, pCo01, nVars, iVarReused );
	Kit_TruthMuxVar( pCo1, pCo10, pCo11, nVars, iVarReused );
	//Kit_DsdPrintFromTruth( pCo0, nVars );
	//Kit_DsdPrintFromTruth( pCo1, nVars );

	// derive the composition function
	Kit_TruthMuxVar( pCo , pCo0 , pCo1 , nVars, iVar );

	// process the decomposed function
	pNtkDec = Kit_DsdDecompose( pDec, nVars );
	pNtkComp = Kit_DsdDecompose( pCo, nVars );
	//Kit_DsdPrint( stdout, pNtkDec );
	//Kit_DsdPrint( stdout, pNtkComp );
	//printf( "cofactored variable %c\n", 'a' + iVar );
	//printf( "reused variable %c\n", 'a' + iVarReused );

	ppLeaves[iVarReused] = Lpk_MapTree_rec( p, pNtkDec, ppLeaves, pNtkDec->Root, NULL );
	pObjNew = Lpk_MapTree_rec( p, pNtkComp, ppLeaves, pNtkComp->Root, NULL );

	Kit_DsdNtkFree( pNtkDec );
	Kit_DsdNtkFree( pNtkComp );
	return pObjNew;
	}

	////////////////////////////////////////////////////////////////////////
	/// END OF FILE ///
	////////////////////////////////////////////////////////////////////////


	ABC_NAMESPACE_IMPL_END