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diff --git a/abc70930/src/aig/kit/kitFactor.c b/abc70930/src/aig/kit/kitFactor.c
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+++ b/abc70930/src/aig/kit/kitFactor.c
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+/**CFile****************************************************************
+
+  FileName    [kitFactor.c]
+
+  SystemName  [ABC: Logic synthesis and verification system.]
+
+  PackageName [Computation kit.]
+
+  Synopsis    [Algebraic factoring.]
+
+  Author      [Alan Mishchenko]
+  
+  Affiliation [UC Berkeley]
+
+  Date        [Ver. 1.0. Started - Dec 6, 2006.]
+
+  Revision    [$Id: kitFactor.c,v 1.00 2006/12/06 00:00:00 alanmi Exp $]
+
+***********************************************************************/
+
+#include "kit.h"
+
+////////////////////////////////////////////////////////////////////////
+///                        DECLARATIONS                              ///
+////////////////////////////////////////////////////////////////////////
+
+// factoring fails if intermediate memory usage exceed this limit
+#define KIT_FACTOR_MEM_LIMIT  (1<<16)
+
+static Kit_Edge_t  Kit_SopFactor_rec( Kit_Graph_t * pFForm, Kit_Sop_t * cSop, int nLits, Vec_Int_t * vMemory );
+static Kit_Edge_t  Kit_SopFactorLF_rec( Kit_Graph_t * pFForm, Kit_Sop_t * cSop, Kit_Sop_t * cSimple, int nLits, Vec_Int_t * vMemory );
+static Kit_Edge_t  Kit_SopFactorTrivial( Kit_Graph_t * pFForm, Kit_Sop_t * cSop, int nLits );
+static Kit_Edge_t  Kit_SopFactorTrivialCube( Kit_Graph_t * pFForm, unsigned uCube, int nLits );
+
+extern int         Kit_SopFactorVerify( Vec_Int_t * cSop, Kit_Graph_t * pFForm, int nVars );
+
+////////////////////////////////////////////////////////////////////////
+///                     FUNCTION DEFINITIONS                         ///
+////////////////////////////////////////////////////////////////////////
+
+/**Function*************************************************************
+
+  Synopsis    [Factors the cover.]
+
+  Description []
+               
+  SideEffects []
+
+  SeeAlso     []
+
+***********************************************************************/
+Kit_Graph_t * Kit_SopFactor( Vec_Int_t * vCover, int fCompl, int nVars, Vec_Int_t * vMemory )
+{
+    Kit_Sop_t Sop, * cSop = &Sop;
+    Kit_Graph_t * pFForm;
+    Kit_Edge_t eRoot;
+//    int nCubes;
+
+    // works for up to 15 variables because divisin procedure
+    // used the last bit for marking the cubes going to the remainder
+    assert( nVars < 16 );
+
+    // check for trivial functions
+    if ( Vec_IntSize(vCover) == 0 )
+        return Kit_GraphCreateConst0();
+    if ( Vec_IntSize(vCover) == 1 && Vec_IntEntry(vCover, 0) == 0 )
+        return Kit_GraphCreateConst1();
+
+    // prepare memory manager
+//    Vec_IntClear( vMemory );
+    Vec_IntGrow( vMemory, KIT_FACTOR_MEM_LIMIT );
+
+    // perform CST
+    Kit_SopCreateInverse( cSop, vCover, 2 * nVars, vMemory ); // CST
+
+    // start the factored form
+    pFForm = Kit_GraphCreate( nVars );
+    // factor the cover
+    eRoot = Kit_SopFactor_rec( pFForm, cSop, 2 * nVars, vMemory );
+    // finalize the factored form
+    Kit_GraphSetRoot( pFForm, eRoot );
+    if ( fCompl )
+        Kit_GraphComplement( pFForm );
+
+    // verify the factored form
+//    nCubes = Vec_IntSize(vCover);
+//    Vec_IntShrink( vCover, nCubes );
+//    if ( !Kit_SopFactorVerify( vCover, pFForm, nVars ) )
+//        printf( "Verification has failed.\n" );
+    return pFForm;
+}
+
+/**Function*************************************************************
+
+  Synopsis    [Recursive factoring procedure.]
+
+  Description [For the pseudo-code, see Hachtel/Somenzi, 
+  Logic synthesis and verification algorithms, Kluwer, 1996, p. 432.]
+               
+  SideEffects []
+
+  SeeAlso     []
+
+***********************************************************************/
+Kit_Edge_t Kit_SopFactor_rec( Kit_Graph_t * pFForm, Kit_Sop_t * cSop, int nLits, Vec_Int_t * vMemory )
+{
+    Kit_Sop_t Div, Quo, Rem, Com;
+    Kit_Sop_t * cDiv = &Div, * cQuo = &Quo, * cRem = &Rem, * cCom = &Com;
+    Kit_Edge_t eNodeDiv, eNodeQuo, eNodeRem, eNodeAnd;
+
+    // make sure the cover contains some cubes
+    assert( Kit_SopCubeNum(cSop) > 0 );
+
+    // get the divisor
+    if ( !Kit_SopDivisor(cDiv, cSop, nLits, vMemory) )
+        return Kit_SopFactorTrivial( pFForm, cSop, nLits );
+
+    // divide the cover by the divisor
+    Kit_SopDivideInternal( cSop, cDiv, cQuo, cRem, vMemory );
+
+    // check the trivial case
+    assert( Kit_SopCubeNum(cQuo) > 0 );
+    if ( Kit_SopCubeNum(cQuo) == 1 )
+        return Kit_SopFactorLF_rec( pFForm, cSop, cQuo, nLits, vMemory );
+
+    // make the quotient cube free
+    Kit_SopMakeCubeFree( cQuo );
+
+    // divide the cover by the quotient
+    Kit_SopDivideInternal( cSop, cQuo, cDiv, cRem, vMemory );
+
+    // check the trivial case
+    if ( Kit_SopIsCubeFree( cDiv ) )
+    {
+        eNodeDiv = Kit_SopFactor_rec( pFForm, cDiv, nLits, vMemory );
+        eNodeQuo = Kit_SopFactor_rec( pFForm, cQuo, nLits, vMemory );
+        eNodeAnd = Kit_GraphAddNodeAnd( pFForm, eNodeDiv, eNodeQuo );
+        if ( Kit_SopCubeNum(cRem) == 0 )
+            return eNodeAnd;
+        eNodeRem = Kit_SopFactor_rec( pFForm, cRem, nLits, vMemory );
+        return Kit_GraphAddNodeOr( pFForm, eNodeAnd, eNodeRem );
+    }
+
+    // get the common cube
+    Kit_SopCommonCubeCover( cCom, cDiv, vMemory );
+
+    // solve the simple problem
+    return Kit_SopFactorLF_rec( pFForm, cSop, cCom, nLits, vMemory );
+}
+
+
+/**Function*************************************************************
+
+  Synopsis    [Internal recursive factoring procedure for the leaf case.]
+
+  Description []
+               
+  SideEffects []
+
+  SeeAlso     []
+
+***********************************************************************/
+Kit_Edge_t Kit_SopFactorLF_rec( Kit_Graph_t * pFForm, Kit_Sop_t * cSop, Kit_Sop_t * cSimple, int nLits, Vec_Int_t * vMemory )
+{
+    Kit_Sop_t Div, Quo, Rem;
+    Kit_Sop_t * cDiv = &Div, * cQuo = &Quo, * cRem = &Rem;
+    Kit_Edge_t eNodeDiv, eNodeQuo, eNodeRem, eNodeAnd;
+    assert( Kit_SopCubeNum(cSimple) == 1 );
+    // get the most often occurring literal
+    Kit_SopBestLiteralCover( cDiv, cSop, Kit_SopCube(cSimple, 0), nLits, vMemory );
+    // divide the cover by the literal
+    Kit_SopDivideByCube( cSop, cDiv, cQuo, cRem, vMemory );
+    // get the node pointer for the literal
+    eNodeDiv = Kit_SopFactorTrivialCube( pFForm, Kit_SopCube(cDiv, 0), nLits );
+    // factor the quotient and remainder
+    eNodeQuo = Kit_SopFactor_rec( pFForm, cQuo, nLits, vMemory );
+    eNodeAnd = Kit_GraphAddNodeAnd( pFForm, eNodeDiv, eNodeQuo );
+    if ( Kit_SopCubeNum(cRem) == 0 )
+        return eNodeAnd;
+    eNodeRem = Kit_SopFactor_rec( pFForm, cRem, nLits, vMemory );
+    return Kit_GraphAddNodeOr( pFForm, eNodeAnd, eNodeRem );
+}
+
+
+/**Function*************************************************************
+
+  Synopsis    [Factoring cube.]
+
+  Description []
+               
+  SideEffects []
+
+  SeeAlso     []
+
+***********************************************************************/
+Kit_Edge_t Kit_SopFactorTrivialCube_rec( Kit_Graph_t * pFForm, unsigned uCube, int nStart, int nFinish )
+{
+    Kit_Edge_t eNode1, eNode2;
+    int i, iLit = -1, nLits, nLits1, nLits2;
+    assert( uCube );
+    // count the number of literals in this interval
+    nLits = 0;
+    for ( i = nStart; i < nFinish; i++ )
+        if ( Kit_CubeHasLit(uCube, i) )
+        {
+            iLit = i;
+            nLits++;
+        }
+    assert( iLit != -1 );
+    // quit if there is only one literal        
+    if ( nLits == 1 )
+        return Kit_EdgeCreate( iLit/2, iLit%2 ); // CST
+    // split the literals into two parts
+    nLits1 = nLits/2;
+    nLits2 = nLits - nLits1;
+//    nLits2 = nLits/2;
+//    nLits1 = nLits - nLits2;
+    // find the splitting point
+    nLits = 0;
+    for ( i = nStart; i < nFinish; i++ )
+        if ( Kit_CubeHasLit(uCube, i) )
+        {
+            if ( nLits == nLits1 )
+                break;
+            nLits++;
+        }
+    // recursively construct the tree for the parts
+    eNode1 = Kit_SopFactorTrivialCube_rec( pFForm, uCube, nStart, i  );
+    eNode2 = Kit_SopFactorTrivialCube_rec( pFForm, uCube, i, nFinish );
+    return Kit_GraphAddNodeAnd( pFForm, eNode1, eNode2 );
+}
+
+/**Function*************************************************************
+
+  Synopsis    [Factoring cube.]
+
+  Description []
+               
+  SideEffects []
+
+  SeeAlso     []
+
+***********************************************************************/
+Kit_Edge_t Kit_SopFactorTrivialCube( Kit_Graph_t * pFForm, unsigned uCube, int nLits )
+{
+    return Kit_SopFactorTrivialCube_rec( pFForm, uCube, 0, nLits );
+}
+
+/**Function*************************************************************
+
+  Synopsis    [Factoring SOP.]
+
+  Description []
+               
+  SideEffects []
+
+  SeeAlso     []
+
+***********************************************************************/
+Kit_Edge_t Kit_SopFactorTrivial_rec( Kit_Graph_t * pFForm, unsigned * pCubes, int nCubes, int nLits )
+{
+    Kit_Edge_t eNode1, eNode2;
+    int nCubes1, nCubes2;
+    if ( nCubes == 1 )
+        return Kit_SopFactorTrivialCube_rec( pFForm, pCubes[0], 0, nLits );
+    // split the cubes into two parts
+    nCubes1 = nCubes/2;
+    nCubes2 = nCubes - nCubes1;
+//    nCubes2 = nCubes/2;
+//    nCubes1 = nCubes - nCubes2;
+    // recursively construct the tree for the parts
+    eNode1 = Kit_SopFactorTrivial_rec( pFForm, pCubes,           nCubes1, nLits );
+    eNode2 = Kit_SopFactorTrivial_rec( pFForm, pCubes + nCubes1, nCubes2, nLits );
+    return Kit_GraphAddNodeOr( pFForm, eNode1, eNode2 );
+}
+
+/**Function*************************************************************
+
+  Synopsis    [Factoring the cover, which has no algebraic divisors.]
+
+  Description []
+               
+  SideEffects []
+
+  SeeAlso     []
+
+***********************************************************************/
+Kit_Edge_t Kit_SopFactorTrivial( Kit_Graph_t * pFForm, Kit_Sop_t * cSop, int nLits )
+{
+    return Kit_SopFactorTrivial_rec( pFForm, cSop->pCubes, cSop->nCubes, nLits );
+}
+
+
+/**Function*************************************************************
+
+  Synopsis    [Testing procedure for the factoring code.]
+
+  Description []
+               
+  SideEffects []
+
+  SeeAlso     []
+
+***********************************************************************/
+void Kit_FactorTest( unsigned * pTruth, int nVars )
+{
+    Vec_Int_t * vCover, * vMemory;
+    Kit_Graph_t * pGraph;
+//    unsigned uTruthRes;
+    int RetValue;
+
+    // derive SOP
+    vCover = Vec_IntAlloc( 0 );
+    RetValue = Kit_TruthIsop( pTruth, nVars, vCover, 0 );
+    assert( RetValue == 0 );
+
+    // derive factored form
+    vMemory = Vec_IntAlloc( 0 );
+    pGraph = Kit_SopFactor( vCover, 0, nVars, vMemory );
+/*
+    // derive truth table
+    assert( nVars <= 5 );
+    uTruthRes = Kit_GraphToTruth( pGraph );
+    if ( uTruthRes != pTruth[0] )
+        printf( "Verification failed!" );
+*/
+    printf( "Vars = %2d. Cubes = %3d. FFNodes = %3d. FF_memory = %3d.\n",
+        nVars, Vec_IntSize(vCover), Kit_GraphNodeNum(pGraph), Vec_IntSize(vMemory) );
+
+    Vec_IntFree( vMemory );
+    Vec_IntFree( vCover );
+    Kit_GraphFree( pGraph );
+}
+
+////////////////////////////////////////////////////////////////////////
+///                       END OF FILE                                ///
+////////////////////////////////////////////////////////////////////////
+
+