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diff --git a/abc70930/src/aig/fra/fraClass.c b/abc70930/src/aig/fra/fraClass.c
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+++ b/abc70930/src/aig/fra/fraClass.c
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+/**CFile****************************************************************
+
+ FileName [fraClass.c]
+
+ SystemName [ABC: Logic synthesis and verification system.]
+
+ PackageName [New FRAIG package.]
+
+ Synopsis []
+
+ Author [Alan Mishchenko]
+
+ Affiliation [UC Berkeley]
+
+ Date [Ver. 1.0. Started - June 30, 2007.]
+
+ Revision [$Id: fraClass.c,v 1.00 2007/06/30 00:00:00 alanmi Exp $]
+
+***********************************************************************/
+
+#include "fra.h"
+
+/*
+ The candidate equivalence classes are stored as a vector of pointers
+ to the array of pointers to the nodes in each class.
+ The first node of the class is its representative node.
+ The representative has the smallest topological order among the class nodes.
+ The nodes inside each class are ordered according to their topological order.
+ The classes are ordered according to the topological order of their representatives.
+ The array of pointers to the class nodes is terminated with a NULL pointer.
+ To enable dynamic addition of new classes (during class refinement),
+ each array has at least as many NULLs in the end, as there are nodes in the class.
+*/
+
+////////////////////////////////////////////////////////////////////////
+/// DECLARATIONS ///
+////////////////////////////////////////////////////////////////////////
+
+static inline Aig_Obj_t * Fra_ObjNext( Aig_Obj_t ** ppNexts, Aig_Obj_t * pObj ) { return ppNexts[pObj->Id]; }
+static inline void Fra_ObjSetNext( Aig_Obj_t ** ppNexts, Aig_Obj_t * pObj, Aig_Obj_t * pNext ) { ppNexts[pObj->Id] = pNext; }
+
+////////////////////////////////////////////////////////////////////////
+/// FUNCTION DEFINITIONS ///
+////////////////////////////////////////////////////////////////////////
+
+/**Function*************************************************************
+
+ Synopsis [Starts representation of equivalence classes.]
+
+ Description []
+
+ SideEffects []
+
+ SeeAlso []
+
+***********************************************************************/
+Fra_Cla_t * Fra_ClassesStart( Aig_Man_t * pAig )
+{
+ Fra_Cla_t * p;
+ p = ALLOC( Fra_Cla_t, 1 );
+ memset( p, 0, sizeof(Fra_Cla_t) );
+ p->pAig = pAig;
+ p->pMemRepr = ALLOC( Aig_Obj_t *, Aig_ManObjNumMax(pAig) );
+ memset( p->pMemRepr, 0, sizeof(Aig_Obj_t *) * Aig_ManObjNumMax(pAig) );
+ p->vClasses = Vec_PtrAlloc( 100 );
+ p->vClasses1 = Vec_PtrAlloc( 100 );
+ p->vClassesTemp = Vec_PtrAlloc( 100 );
+ p->vClassOld = Vec_PtrAlloc( 100 );
+ p->vClassNew = Vec_PtrAlloc( 100 );
+ p->pFuncNodeHash = Fra_SmlNodeHash;
+ p->pFuncNodeIsConst = Fra_SmlNodeIsConst;
+ p->pFuncNodesAreEqual = Fra_SmlNodesAreEqual;
+ return p;
+}
+
+/**Function*************************************************************
+
+ Synopsis [Stop representation of equivalence classes.]
+
+ Description []
+
+ SideEffects []
+
+ SeeAlso []
+
+***********************************************************************/
+void Fra_ClassesStop( Fra_Cla_t * p )
+{
+ FREE( p->pMemClasses );
+ FREE( p->pMemRepr );
+ if ( p->vClassesTemp ) Vec_PtrFree( p->vClassesTemp );
+ if ( p->vClassNew ) Vec_PtrFree( p->vClassNew );
+ if ( p->vClassOld ) Vec_PtrFree( p->vClassOld );
+ if ( p->vClasses1 ) Vec_PtrFree( p->vClasses1 );
+ if ( p->vClasses ) Vec_PtrFree( p->vClasses );
+ if ( p->vImps ) Vec_IntFree( p->vImps );
+ free( p );
+}
+
+/**Function*************************************************************
+
+ Synopsis [Starts representation of equivalence classes.]
+
+ Description []
+
+ SideEffects []
+
+ SeeAlso []
+
+***********************************************************************/
+void Fra_ClassesCopyReprs( Fra_Cla_t * p, Vec_Ptr_t * vFailed )
+{
+ Aig_Obj_t * pObj;
+ int i;
+ Aig_ManReprStart( p->pAig, Aig_ManObjNumMax(p->pAig) );
+ memmove( p->pAig->pReprs, p->pMemRepr, sizeof(Aig_Obj_t *) * Aig_ManObjNumMax(p->pAig) );
+ if ( Vec_PtrSize(p->vClasses1) == 0 && Vec_PtrSize(p->vClasses) == 0 )
+ {
+ Aig_ManForEachObj( p->pAig, pObj, i )
+ {
+ if ( p->pAig->pReprs[i] != NULL )
+ printf( "Classes are not cleared!\n" );
+ assert( p->pAig->pReprs[i] == NULL );
+ }
+ }
+ if ( vFailed )
+ Vec_PtrForEachEntry( vFailed, pObj, i )
+ p->pAig->pReprs[pObj->Id] = NULL;
+}
+
+/**Function*************************************************************
+
+ Synopsis [Prints simulation classes.]
+
+ Description []
+
+ SideEffects []
+
+ SeeAlso []
+
+***********************************************************************/
+int Fra_ClassCount( Aig_Obj_t ** pClass )
+{
+ Aig_Obj_t * pTemp;
+ int i;
+ for ( i = 0; pTemp = pClass[i]; i++ );
+ return i;
+}
+
+/**Function*************************************************************
+
+ Synopsis [Count the number of literals.]
+
+ Description []
+
+ SideEffects []
+
+ SeeAlso []
+
+***********************************************************************/
+int Fra_ClassesCountLits( Fra_Cla_t * p )
+{
+ Aig_Obj_t ** pClass;
+ int i, nNodes, nLits = 0;
+ nLits = Vec_PtrSize( p->vClasses1 );
+ Vec_PtrForEachEntry( p->vClasses, pClass, i )
+ {
+ nNodes = Fra_ClassCount( pClass );
+ assert( nNodes > 1 );
+ nLits += nNodes - 1;
+ }
+ return nLits;
+}
+
+/**Function*************************************************************
+
+ Synopsis [Count the number of pairs.]
+
+ Description []
+
+ SideEffects []
+
+ SeeAlso []
+
+***********************************************************************/
+int Fra_ClassesCountPairs( Fra_Cla_t * p )
+{
+ Aig_Obj_t ** pClass;
+ int i, nNodes, nPairs = 0;
+ Vec_PtrForEachEntry( p->vClasses, pClass, i )
+ {
+ nNodes = Fra_ClassCount( pClass );
+ assert( nNodes > 1 );
+ nPairs += nNodes * (nNodes - 1) / 2;
+ }
+ return nPairs;
+}
+
+/**Function*************************************************************
+
+ Synopsis [Prints simulation classes.]
+
+ Description []
+
+ SideEffects []
+
+ SeeAlso []
+
+***********************************************************************/
+void Fra_PrintClass( Aig_Obj_t ** pClass )
+{
+ Aig_Obj_t * pTemp;
+ int i;
+ for ( i = 1; pTemp = pClass[i]; i++ )
+ assert( Fra_ClassObjRepr(pTemp) == pClass[0] );
+ printf( "{ " );
+ for ( i = 0; pTemp = pClass[i]; i++ )
+ printf( "%d(%d) ", pTemp->Id, pTemp->Level );
+ printf( "}\n" );
+}
+
+/**Function*************************************************************
+
+ Synopsis [Prints simulation classes.]
+
+ Description []
+
+ SideEffects []
+
+ SeeAlso []
+
+***********************************************************************/
+void Fra_ClassesPrint( Fra_Cla_t * p, int fVeryVerbose )
+{
+ Aig_Obj_t ** pClass;
+ Aig_Obj_t * pObj;
+ int i;
+
+ printf( "Const = %5d. Class = %5d. Lit = %5d. ",
+ Vec_PtrSize(p->vClasses1), Vec_PtrSize(p->vClasses), Fra_ClassesCountLits(p) );
+ if ( p->vImps && Vec_IntSize(p->vImps) > 0 )
+ printf( "Imp = %5d. ", Vec_IntSize(p->vImps) );
+ printf( "\n" );
+
+ if ( fVeryVerbose )
+ {
+ Vec_PtrForEachEntry( p->vClasses1, pObj, i )
+ assert( Fra_ClassObjRepr(pObj) == Aig_ManConst1(p->pAig) );
+ printf( "Constants { " );
+ Vec_PtrForEachEntry( p->vClasses1, pObj, i )
+ printf( "%d ", pObj->Id );
+ printf( "}\n" );
+ Vec_PtrForEachEntry( p->vClasses, pClass, i )
+ {
+ printf( "%3d (%3d) : ", i, Fra_ClassCount(pClass) );
+ Fra_PrintClass( pClass );
+ }
+ printf( "\n" );
+ }
+}
+
+/**Function*************************************************************
+
+ Synopsis [Creates initial simulation classes.]
+
+ Description [Assumes that simulation info is assigned.]
+
+ SideEffects []
+
+ SeeAlso []
+
+***********************************************************************/
+void Fra_ClassesPrepare( Fra_Cla_t * p, int fLatchCorr )
+{
+ Aig_Obj_t ** ppTable, ** ppNexts;
+ Aig_Obj_t * pObj, * pTemp;
+ int i, k, nTableSize, nEntries, nNodes, iEntry;
+
+ // allocate the hash table hashing simulation info into nodes
+ nTableSize = Aig_PrimeCudd( Aig_ManObjNumMax(p->pAig) );
+ ppTable = ALLOC( Aig_Obj_t *, nTableSize );
+ ppNexts = ALLOC( Aig_Obj_t *, nTableSize );
+ memset( ppTable, 0, sizeof(Aig_Obj_t *) * nTableSize );
+
+ // add all the nodes to the hash table
+ Vec_PtrClear( p->vClasses1 );
+ Aig_ManForEachObj( p->pAig, pObj, i )
+ {
+ if ( fLatchCorr )
+ {
+ if ( !Aig_ObjIsPi(pObj) )
+ continue;
+ }
+ else
+ {
+ if ( !Aig_ObjIsNode(pObj) && !Aig_ObjIsPi(pObj) )
+ continue;
+ // skip the node with more that the given number of levels
+// if ( pObj->Level > 3 )
+// continue;
+ }
+ // hash the node by its simulation info
+ iEntry = p->pFuncNodeHash( pObj, nTableSize );
+ // check if the node belongs to the class of constant 1
+ if ( p->pFuncNodeIsConst( pObj ) )
+ {
+ Vec_PtrPush( p->vClasses1, pObj );
+ Fra_ClassObjSetRepr( pObj, Aig_ManConst1(p->pAig) );
+ continue;
+ }
+ // add the node to the class
+ if ( ppTable[iEntry] == NULL )
+ {
+ ppTable[iEntry] = pObj;
+ Fra_ObjSetNext( ppNexts, pObj, pObj );
+ }
+ else
+ {
+ Fra_ObjSetNext( ppNexts, pObj, Fra_ObjNext(ppNexts,ppTable[iEntry]) );
+ Fra_ObjSetNext( ppNexts, ppTable[iEntry], pObj );
+ }
+ }
+
+ // count the total number of nodes in the non-trivial classes
+ // mark the representative nodes of each equivalence class
+ nEntries = 0;
+ for ( i = 0; i < nTableSize; i++ )
+ if ( ppTable[i] && ppTable[i] != Fra_ObjNext(ppNexts, ppTable[i]) )
+ {
+ for ( pTemp = Fra_ObjNext(ppNexts, ppTable[i]), k = 1;
+ pTemp != ppTable[i];
+ pTemp = Fra_ObjNext(ppNexts, pTemp), k++ );
+ assert( k > 1 );
+ nEntries += k;
+ // mark the node
+ assert( ppTable[i]->fMarkA == 0 );
+ ppTable[i]->fMarkA = 1;
+ }
+
+ // allocate room for classes
+ p->pMemClasses = ALLOC( Aig_Obj_t *, 2*(nEntries + Vec_PtrSize(p->vClasses1)) );
+ p->pMemClassesFree = p->pMemClasses + 2*nEntries;
+
+ // copy the entries into storage in the topological order
+ Vec_PtrClear( p->vClasses );
+ nEntries = 0;
+ Aig_ManForEachObj( p->pAig, pObj, i )
+ {
+ if ( !Aig_ObjIsNode(pObj) && !Aig_ObjIsPi(pObj) )
+ continue;
+ // skip the nodes that are not representatives of non-trivial classes
+ if ( pObj->fMarkA == 0 )
+ continue;
+ pObj->fMarkA = 0;
+ // add the class of nodes
+ Vec_PtrPush( p->vClasses, p->pMemClasses + 2*nEntries );
+ // count the number of entries in this class
+ for ( pTemp = Fra_ObjNext(ppNexts, pObj), k = 1;
+ pTemp != pObj;
+ pTemp = Fra_ObjNext(ppNexts, pTemp), k++ );
+ nNodes = k;
+ assert( nNodes > 1 );
+ // add the nodes to the class in the topological order
+ p->pMemClasses[2*nEntries] = pObj;
+ for ( pTemp = Fra_ObjNext(ppNexts, pObj), k = 1;
+ pTemp != pObj;
+ pTemp = Fra_ObjNext(ppNexts, pTemp), k++ )
+ {
+ p->pMemClasses[2*nEntries+nNodes-k] = pTemp;
+ Fra_ClassObjSetRepr( pTemp, pObj );
+ }
+ // add as many empty entries
+ p->pMemClasses[2*nEntries + nNodes] = NULL;
+ // increment the number of entries
+ nEntries += k;
+ }
+ free( ppTable );
+ free( ppNexts );
+ // now it is time to refine the classes
+ Fra_ClassesRefine( p );
+}
+
+/**Function*************************************************************
+
+ Synopsis [Refines one class using simulation info.]
+
+ Description [Returns the new class if refinement happened.]
+
+ SideEffects []
+
+ SeeAlso []
+
+***********************************************************************/
+Aig_Obj_t ** Fra_RefineClassOne( Fra_Cla_t * p, Aig_Obj_t ** ppClass )
+{
+ Aig_Obj_t * pObj, ** ppThis;
+ int i;
+ assert( ppClass[0] != NULL && ppClass[1] != NULL );
+
+ // check if the class is going to be refined
+ for ( ppThis = ppClass + 1; pObj = *ppThis; ppThis++ )
+ if ( !p->pFuncNodesAreEqual(ppClass[0], pObj) )
+ break;
+ if ( pObj == NULL )
+ return NULL;
+ // split the class
+ Vec_PtrClear( p->vClassOld );
+ Vec_PtrClear( p->vClassNew );
+ Vec_PtrPush( p->vClassOld, ppClass[0] );
+ for ( ppThis = ppClass + 1; pObj = *ppThis; ppThis++ )
+ if ( p->pFuncNodesAreEqual(ppClass[0], pObj) )
+ Vec_PtrPush( p->vClassOld, pObj );
+ else
+ Vec_PtrPush( p->vClassNew, pObj );
+/*
+ printf( "Refining class (" );
+ Vec_PtrForEachEntry( p->vClassOld, pObj, i )
+ printf( "%d,", pObj->Id );
+ printf( ") + (" );
+ Vec_PtrForEachEntry( p->vClassNew, pObj, i )
+ printf( "%d,", pObj->Id );
+ printf( ")\n" );
+*/
+ // put the nodes back into the class memory
+ Vec_PtrForEachEntry( p->vClassOld, pObj, i )
+ {
+ ppClass[i] = pObj;
+ ppClass[Vec_PtrSize(p->vClassOld)+i] = NULL;
+ Fra_ClassObjSetRepr( pObj, i? ppClass[0] : NULL );
+ }
+ ppClass += 2*Vec_PtrSize(p->vClassOld);
+ // put the new nodes into the class memory
+ Vec_PtrForEachEntry( p->vClassNew, pObj, i )
+ {
+ ppClass[i] = pObj;
+ ppClass[Vec_PtrSize(p->vClassNew)+i] = NULL;
+ Fra_ClassObjSetRepr( pObj, i? ppClass[0] : NULL );
+ }
+ return ppClass;
+}
+
+/**Function*************************************************************
+
+ Synopsis [Iteratively refines the classes after simulation.]
+
+ Description [Returns the number of refinements performed.]
+
+ SideEffects []
+
+ SeeAlso []
+
+***********************************************************************/
+int Fra_RefineClassLastIter( Fra_Cla_t * p, Vec_Ptr_t * vClasses )
+{
+ Aig_Obj_t ** pClass, ** pClass2;
+ int nRefis;
+ pClass = Vec_PtrEntryLast( vClasses );
+ for ( nRefis = 0; pClass2 = Fra_RefineClassOne( p, pClass ); nRefis++ )
+ {
+ // if the original class is trivial, remove it
+ if ( pClass[1] == NULL )
+ Vec_PtrPop( vClasses );
+ // if the new class is trivial, stop
+ if ( pClass2[1] == NULL )
+ {
+ nRefis++;
+ break;
+ }
+ // othewise, add the class and continue
+ assert( pClass2[0] != NULL );
+ Vec_PtrPush( vClasses, pClass2 );
+ pClass = pClass2;
+ }
+ return nRefis;
+}
+
+/**Function*************************************************************
+
+ Synopsis [Refines the classes after simulation.]
+
+ Description [Assumes that simulation info is assigned. Returns the
+ number of classes refined.]
+
+ SideEffects []
+
+ SeeAlso []
+
+***********************************************************************/
+int Fra_ClassesRefine( Fra_Cla_t * p )
+{
+ Vec_Ptr_t * vTemp;
+ Aig_Obj_t ** pClass;
+ int i, nRefis;
+ // refine the classes
+ nRefis = 0;
+ Vec_PtrClear( p->vClassesTemp );
+ Vec_PtrForEachEntry( p->vClasses, pClass, i )
+ {
+ // add the class to the new array
+ assert( pClass[0] != NULL );
+ Vec_PtrPush( p->vClassesTemp, pClass );
+ // refine the class iteratively
+ nRefis += Fra_RefineClassLastIter( p, p->vClassesTemp );
+ }
+ // exchange the class representation
+ vTemp = p->vClassesTemp;
+ p->vClassesTemp = p->vClasses;
+ p->vClasses = vTemp;
+ return nRefis;
+}
+
+/**Function*************************************************************
+
+ Synopsis [Refines constant 1 equivalence class.]
+
+ Description []
+
+ SideEffects []
+
+ SeeAlso []
+
+***********************************************************************/
+int Fra_ClassesRefine1( Fra_Cla_t * p, int fRefineNewClass, int * pSkipped )
+{
+ Aig_Obj_t * pObj, ** ppClass;
+ int i, k, nRefis = 1;
+ // check if there is anything to refine
+ if ( Vec_PtrSize(p->vClasses1) == 0 )
+ return 0;
+ // make sure constant 1 class contains only non-constant nodes
+ assert( Vec_PtrEntry(p->vClasses1,0) != Aig_ManConst1(p->pAig) );
+ // collect all the nodes to be refined
+ k = 0;
+ Vec_PtrClear( p->vClassNew );
+ Vec_PtrForEachEntry( p->vClasses1, pObj, i )
+ {
+ if ( p->pFuncNodeIsConst( pObj ) )
+ Vec_PtrWriteEntry( p->vClasses1, k++, pObj );
+ else
+ Vec_PtrPush( p->vClassNew, pObj );
+ }
+ Vec_PtrShrink( p->vClasses1, k );
+ if ( Vec_PtrSize(p->vClassNew) == 0 )
+ return 0;
+/*
+ printf( "Refined const-1 class: {" );
+ Vec_PtrForEachEntry( p->vClassNew, pObj, i )
+ printf( " %d", pObj->Id );
+ printf( " }\n" );
+*/
+ if ( Vec_PtrSize(p->vClassNew) == 1 )
+ {
+ Fra_ClassObjSetRepr( Vec_PtrEntry(p->vClassNew,0), NULL );
+ return 1;
+ }
+ // create a new class composed of these nodes
+ ppClass = p->pMemClassesFree;
+ p->pMemClassesFree += 2 * Vec_PtrSize(p->vClassNew);
+ Vec_PtrForEachEntry( p->vClassNew, pObj, i )
+ {
+ ppClass[i] = pObj;
+ ppClass[Vec_PtrSize(p->vClassNew)+i] = NULL;
+ Fra_ClassObjSetRepr( pObj, i? ppClass[0] : NULL );
+ }
+ assert( ppClass[0] != NULL );
+ Vec_PtrPush( p->vClasses, ppClass );
+ // iteratively refine this class
+ if ( fRefineNewClass )
+ nRefis += Fra_RefineClassLastIter( p, p->vClasses );
+ else if ( pSkipped )
+ (*pSkipped)++;
+ return nRefis;
+}
+
+/**Function*************************************************************
+
+ Synopsis [Starts representation of equivalence classes with one class.]
+
+ Description []
+
+ SideEffects []
+
+ SeeAlso []
+
+***********************************************************************/
+void Fra_ClassesTest( Fra_Cla_t * p, int Id1, int Id2 )
+{
+ Aig_Obj_t ** pClass;
+ p->pMemClasses = ALLOC( Aig_Obj_t *, 4 );
+ pClass = p->pMemClasses;
+ assert( Id1 < Id2 );
+ pClass[0] = Aig_ManObj( p->pAig, Id1 );
+ pClass[1] = Aig_ManObj( p->pAig, Id2 );
+ pClass[2] = NULL;
+ pClass[3] = NULL;
+ Fra_ClassObjSetRepr( pClass[1], pClass[0] );
+ Vec_PtrPush( p->vClasses, pClass );
+}
+
+/**Function*************************************************************
+
+ Synopsis [Creates latch correspondence classes.]
+
+ Description []
+
+ SideEffects []
+
+ SeeAlso []
+
+***********************************************************************/
+void Fra_ClassesLatchCorr( Fra_Man_t * p )
+{
+ Aig_Obj_t * pObj;
+ int i, nEntries = 0;
+ Vec_PtrClear( p->pCla->vClasses1 );
+ Aig_ManForEachLoSeq( p->pManAig, pObj, i )
+ {
+ Vec_PtrPush( p->pCla->vClasses1, pObj );
+ Fra_ClassObjSetRepr( pObj, Aig_ManConst1(p->pManAig) );
+ }
+ // allocate room for classes
+ p->pCla->pMemClasses = ALLOC( Aig_Obj_t *, 2*(nEntries + Vec_PtrSize(p->pCla->vClasses1)) );
+ p->pCla->pMemClassesFree = p->pCla->pMemClasses + 2*nEntries;
+}
+
+/**Function*************************************************************
+
+ Synopsis [Postprocesses the classes by removing half of the less useful.]
+
+ Description []
+
+ SideEffects []
+
+ SeeAlso []
+
+***********************************************************************/
+void Fra_ClassesPostprocess( Fra_Cla_t * p )
+{
+ int Ratio = 2;
+ Fra_Sml_t * pComb;
+ Aig_Obj_t * pObj, * pRepr, ** ppClass;
+ int * pWeights, WeightMax = 0, i, k, c;
+ // perform combinational simulation
+ pComb = Fra_SmlSimulateComb( p->pAig, 32 );
+ // compute the weight of each node in the classes
+ pWeights = ALLOC( int, Aig_ManObjNumMax(p->pAig) );
+ memset( pWeights, 0, sizeof(int) * Aig_ManObjNumMax(p->pAig) );
+ Aig_ManForEachObj( p->pAig, pObj, i )
+ {
+ pRepr = Fra_ClassObjRepr( pObj );
+ if ( pRepr == NULL )
+ continue;
+ pWeights[i] = Fra_SmlNodeNotEquWeight( pComb, pRepr->Id, pObj->Id );
+ WeightMax = AIG_MAX( WeightMax, pWeights[i] );
+ }
+ Fra_SmlStop( pComb );
+ printf( "Before: Const = %6d. Class = %6d. ", Vec_PtrSize(p->vClasses1), Vec_PtrSize(p->vClasses) );
+ // remove nodes from classes whose weight is less than WeightMax/Ratio
+ k = 0;
+ Vec_PtrForEachEntry( p->vClasses1, pObj, i )
+ {
+ if ( pWeights[pObj->Id] >= WeightMax/Ratio )
+ Vec_PtrWriteEntry( p->vClasses1, k++, pObj );
+ else
+ Fra_ClassObjSetRepr( pObj, NULL );
+ }
+ Vec_PtrShrink( p->vClasses1, k );
+ // in each class, compact the nodes
+ Vec_PtrForEachEntry( p->vClasses, ppClass, i )
+ {
+ k = 1;
+ for ( c = 1; ppClass[c]; c++ )
+ {
+ if ( pWeights[ppClass[c]->Id] >= WeightMax/Ratio )
+ ppClass[k++] = ppClass[c];
+ else
+ Fra_ClassObjSetRepr( ppClass[c], NULL );
+ }
+ ppClass[k] = NULL;
+ }
+ // remove classes with only repr
+ k = 0;
+ Vec_PtrForEachEntry( p->vClasses, ppClass, i )
+ if ( ppClass[1] != NULL )
+ Vec_PtrWriteEntry( p->vClasses, k++, ppClass );
+ Vec_PtrShrink( p->vClasses, k );
+ printf( "After: Const = %6d. Class = %6d. \n", Vec_PtrSize(p->vClasses1), Vec_PtrSize(p->vClasses) );
+ free( pWeights );
+}
+
+/**Function*************************************************************
+
+ Synopsis [Postprocesses the classes by selecting representative lowest in top order.]
+
+ Description []
+
+ SideEffects []
+
+ SeeAlso []
+
+***********************************************************************/
+void Fra_ClassesSelectRepr( Fra_Cla_t * p )
+{
+ Aig_Obj_t ** pClass, * pNodeMin;
+ int i, c, cMinSupp, nSuppSizeMin, nSuppSizeCur;
+ // reassign representatives in each class
+ Vec_PtrForEachEntry( p->vClasses, pClass, i )
+ {
+ // collect support sizes and find the min-support node
+ pNodeMin = NULL;
+ nSuppSizeMin = AIG_INFINITY;
+ for ( c = 0; pClass[c]; c++ )
+ {
+ nSuppSizeCur = Aig_SupportSize( p->pAig, pClass[c] );
+// nSuppSizeCur = 1;
+ if ( nSuppSizeMin > nSuppSizeCur ||
+ (nSuppSizeMin == nSuppSizeCur && pNodeMin->Level > pClass[c]->Level) )
+ {
+ nSuppSizeMin = nSuppSizeCur;
+ pNodeMin = pClass[c];
+ cMinSupp = c;
+ }
+ }
+ // skip the case when the repr did not change
+ if ( cMinSupp == 0 )
+ continue;
+ // make the new node the representative of the class
+ pClass[cMinSupp] = pClass[0];
+ pClass[0] = pNodeMin;
+ // set the representative
+ for ( c = 0; pClass[c]; c++ )
+ Fra_ClassObjSetRepr( pClass[c], c? pClass[0] : NULL );
+ }
+}
+
+
+
+static inline Aig_Obj_t * Fra_ObjEqu( Aig_Obj_t ** ppEquivs, Aig_Obj_t * pObj ) { return ppEquivs[pObj->Id]; }
+static inline void Fra_ObjSetEqu( Aig_Obj_t ** ppEquivs, Aig_Obj_t * pObj, Aig_Obj_t * pNode ) { ppEquivs[pObj->Id] = pNode; }
+
+static inline Aig_Obj_t * Fra_ObjChild0Equ( Aig_Obj_t ** ppEquivs, Aig_Obj_t * pObj ) { return Aig_NotCond(Fra_ObjEqu(ppEquivs,Aig_ObjFanin0(pObj)), Aig_ObjFaninC0(pObj)); }
+static inline Aig_Obj_t * Fra_ObjChild1Equ( Aig_Obj_t ** ppEquivs, Aig_Obj_t * pObj ) { return Aig_NotCond(Fra_ObjEqu(ppEquivs,Aig_ObjFanin1(pObj)), Aig_ObjFaninC1(pObj)); }
+
+/**Function*************************************************************
+
+ Synopsis [Add the node and its constraints to the new AIG.]
+
+ Description []
+
+ SideEffects []
+
+ SeeAlso []
+
+***********************************************************************/
+static inline void Fra_ClassesDeriveNode( Aig_Man_t * pManFraig, Aig_Obj_t * pObj, Aig_Obj_t ** ppEquivs )
+{
+ Aig_Obj_t * pObjNew, * pObjRepr, * pObjReprNew, * pMiter;//, * pObjNew2;
+ // skip nodes without representative
+ if ( (pObjRepr = Fra_ClassObjRepr(pObj)) == NULL )
+ return;
+ assert( pObjRepr->Id < pObj->Id );
+ // get the new node
+ pObjNew = Fra_ObjEqu( ppEquivs, pObj );
+ // get the new node of the representative
+ pObjReprNew = Fra_ObjEqu( ppEquivs, pObjRepr );
+ // if this is the same node, no need to add constraints
+ if ( Aig_Regular(pObjNew) == Aig_Regular(pObjReprNew) )
+ return;
+ // these are different nodes - perform speculative reduction
+// pObjNew2 = Aig_NotCond( pObjReprNew, pObj->fPhase ^ pObjRepr->fPhase );
+ // set the new node
+// Fra_ObjSetEqu( ppEquivs, pObj, pObjNew2 );
+ // add the constraint
+ pMiter = Aig_Exor( pManFraig, Aig_Regular(pObjNew), Aig_Regular(pObjReprNew) );
+ pMiter = Aig_NotCond( pMiter, Aig_Regular(pMiter)->fPhase ^ Aig_IsComplement(pMiter) );
+ pMiter = Aig_Not( pMiter );
+ Aig_ObjCreatePo( pManFraig, pMiter );
+}
+
+/**Function*************************************************************
+
+ Synopsis [Derives AIG for the partitioned problem.]
+
+ Description []
+
+ SideEffects []
+
+ SeeAlso []
+
+***********************************************************************/
+Aig_Man_t * Fra_ClassesDeriveAig( Fra_Cla_t * p, int nFramesK )
+{
+ Aig_Man_t * pManFraig;
+ Aig_Obj_t * pObj, * pObjNew;
+ Aig_Obj_t ** pLatches, ** ppEquivs;
+ int i, k, f, nFramesAll = nFramesK + 1;
+ assert( Aig_ManRegNum(p->pAig) > 0 );
+ assert( Aig_ManRegNum(p->pAig) < Aig_ManPiNum(p->pAig) );
+ assert( nFramesK > 0 );
+ // start the fraig package
+ pManFraig = Aig_ManStart( Aig_ManObjNumMax(p->pAig) * nFramesAll );
+ pManFraig->pName = Aig_UtilStrsav( p->pAig->pName );
+ // allocate place for the node mapping
+ ppEquivs = ALLOC( Aig_Obj_t *, Aig_ManObjNumMax(p->pAig) );
+ Fra_ObjSetEqu( ppEquivs, Aig_ManConst1(p->pAig), Aig_ManConst1(pManFraig) );
+ // create latches for the first frame
+ Aig_ManForEachLoSeq( p->pAig, pObj, i )
+ Fra_ObjSetEqu( ppEquivs, pObj, Aig_ObjCreatePi(pManFraig) );
+ // add timeframes
+ pLatches = ALLOC( Aig_Obj_t *, Aig_ManRegNum(p->pAig) );
+ for ( f = 0; f < nFramesAll; f++ )
+ {
+ // create PIs for this frame
+ Aig_ManForEachPiSeq( p->pAig, pObj, i )
+ Fra_ObjSetEqu( ppEquivs, pObj, Aig_ObjCreatePi(pManFraig) );
+ // set the constraints on the latch outputs
+ Aig_ManForEachLoSeq( p->pAig, pObj, i )
+ Fra_ClassesDeriveNode( pManFraig, pObj, ppEquivs );
+ // add internal nodes of this frame
+ Aig_ManForEachNode( p->pAig, pObj, i )
+ {
+ pObjNew = Aig_And( pManFraig, Fra_ObjChild0Equ(ppEquivs, pObj), Fra_ObjChild1Equ(ppEquivs, pObj) );
+ Fra_ObjSetEqu( ppEquivs, pObj, pObjNew );
+ Fra_ClassesDeriveNode( pManFraig, pObj, ppEquivs );
+ }
+ if ( f == nFramesAll - 1 )
+ break;
+ if ( f == nFramesAll - 2 )
+ pManFraig->nAsserts = Aig_ManPoNum(pManFraig);
+ // save the latch input values
+ k = 0;
+ Aig_ManForEachLiSeq( p->pAig, pObj, i )
+ pLatches[k++] = Fra_ObjChild0Equ( ppEquivs, pObj );
+ // insert them to the latch output values
+ k = 0;
+ Aig_ManForEachLoSeq( p->pAig, pObj, i )
+ Fra_ObjSetEqu( ppEquivs, pObj, pLatches[k++] );
+ }
+ free( pLatches );
+ free( ppEquivs );
+ // mark the asserts
+ assert( Aig_ManPoNum(pManFraig) % nFramesAll == 0 );
+printf( "Assert miters = %6d. Output miters = %6d.\n",
+ pManFraig->nAsserts, Aig_ManPoNum(pManFraig) - pManFraig->nAsserts );
+ // remove dangling nodes
+ Aig_ManCleanup( pManFraig );
+ return pManFraig;
+}
+
+////////////////////////////////////////////////////////////////////////
+/// END OF FILE ///
+////////////////////////////////////////////////////////////////////////
+
+