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+/**CFile****************************************************************
+
+ FileName [fxuInt.h]
+
+ PackageName [MVSIS 2.0: Multi-valued logic synthesis system.]
+
+ Synopsis [Internal declarations of fast extract for unate covers.]
+
+ Author [MVSIS Group]
+
+ Affiliation [UC Berkeley]
+
+ Date [Ver. 1.0. Started - February 1, 2003.]
+
+ Revision [$Id: fxuInt.h,v 1.3 2003/04/10 05:42:44 donald Exp $]
+
+***********************************************************************/
+
+#ifndef __FXU_INT_H__
+#define __FXU_INT_H__
+
+////////////////////////////////////////////////////////////////////////
+/// INCLUDES ///
+////////////////////////////////////////////////////////////////////////
+
+#include "extra.h"
+#include "vec.h"
+
+////////////////////////////////////////////////////////////////////////
+/// PARAMETERS ///
+////////////////////////////////////////////////////////////////////////
+
+// uncomment this macro to switch to standard memory management
+//#define USE_SYSTEM_MEMORY_MANAGEMENT
+
+////////////////////////////////////////////////////////////////////////
+/// STRUCTURE DEFINITIONS ///
+////////////////////////////////////////////////////////////////////////
+
+/*
+ Here is an informal description of the FX data structure.
+ (1) The sparse matrix is filled with literals, associated with
+ cubes (row) and variables (columns). The matrix contains
+ all the cubes of all the nodes in the network.
+ (2) A cube is associated with
+ (a) its literals in the matrix,
+ (b) the output variable of the node, to which this cube belongs,
+ (3) A variable is associated with
+ (a) its literals in the matrix and
+ (b) the list of cube pairs in the cover, for which it is the output
+ (4) A cube pair is associated with two cubes and contains the counters
+ of literals in the base and in the cubes without the base
+ (5) A double-cube divisor is associated with list of all cube pairs
+ that produce it and its current weight (which is updated automatically
+ each time a new pair is added or an old pair is removed).
+ (6) A single-cube divisor is associated the pair of variables.
+*/
+
+// sparse matrix
+typedef struct FxuMatrix Fxu_Matrix; // the sparse matrix
+
+// sparse matrix contents: cubes (rows), vars (columns), literals (entries)
+typedef struct FxuCube Fxu_Cube; // one cube in the sparse matrix
+typedef struct FxuVar Fxu_Var; // one literal in the sparse matrix
+typedef struct FxuLit Fxu_Lit; // one entry in the sparse matrix
+
+// double cube divisors
+typedef struct FxuPair Fxu_Pair; // the pair of cubes
+typedef struct FxuDouble Fxu_Double; // the double-cube divisor
+typedef struct FxuSingle Fxu_Single; // the two-literal single-cube divisor
+
+// various lists
+typedef struct FxuListCube Fxu_ListCube; // the list of cubes
+typedef struct FxuListVar Fxu_ListVar; // the list of literals
+typedef struct FxuListLit Fxu_ListLit; // the list of entries
+typedef struct FxuListPair Fxu_ListPair; // the list of pairs
+typedef struct FxuListDouble Fxu_ListDouble; // the list of divisors
+typedef struct FxuListSingle Fxu_ListSingle; // the list of single-cube divisors
+
+// various heaps
+typedef struct FxuHeapDouble Fxu_HeapDouble; // the heap of divisors
+typedef struct FxuHeapSingle Fxu_HeapSingle; // the heap of variables
+
+
+// various lists
+
+// the list of cubes in the sparse matrix
+struct FxuListCube
+{
+ Fxu_Cube * pHead;
+ Fxu_Cube * pTail;
+ int nItems;
+};
+
+// the list of literals in the sparse matrix
+struct FxuListVar
+{
+ Fxu_Var * pHead;
+ Fxu_Var * pTail;
+ int nItems;
+};
+
+// the list of entries in the sparse matrix
+struct FxuListLit
+{
+ Fxu_Lit * pHead;
+ Fxu_Lit * pTail;
+ int nItems;
+};
+
+// the list of cube pair in the sparse matrix
+struct FxuListPair
+{
+ Fxu_Pair * pHead;
+ Fxu_Pair * pTail;
+ int nItems;
+};
+
+// the list of divisors in the sparse matrix
+struct FxuListDouble
+{
+ Fxu_Double * pHead;
+ Fxu_Double * pTail;
+ int nItems;
+};
+
+// the list of divisors in the sparse matrix
+struct FxuListSingle
+{
+ Fxu_Single * pHead;
+ Fxu_Single * pTail;
+ int nItems;
+};
+
+
+// various heaps
+
+// the heap of double cube divisors by weight
+struct FxuHeapDouble
+{
+ Fxu_Double ** pTree;
+ int nItems;
+ int nItemsAlloc;
+ int i;
+};
+
+// the heap of variable by their occurrence in the cubes
+struct FxuHeapSingle
+{
+ Fxu_Single ** pTree;
+ int nItems;
+ int nItemsAlloc;
+ int i;
+};
+
+
+
+// sparse matrix
+struct FxuMatrix // ~ 30 words
+{
+ // the cubes
+ Fxu_ListCube lCubes; // the double linked list of cubes
+ // the values (binary literals)
+ Fxu_ListVar lVars; // the double linked list of variables
+ Fxu_Var ** ppVars; // the array of variables
+ // the double cube divisors
+ Fxu_ListDouble * pTable; // the hash table of divisors
+ int nTableSize; // the hash table size
+ int nDivs; // the number of divisors in the table
+ int nDivsTotal; // the number of divisors in the table
+ Fxu_HeapDouble * pHeapDouble; // the heap of divisors by weight
+ // the single cube divisors
+ Fxu_ListSingle lSingles; // the linked list of single cube divisors
+ Fxu_HeapSingle * pHeapSingle; // the heap of variables by the number of literals in the matrix
+ int nWeightLimit;// the limit on weight of single cube divisors collected
+ int nSingleTotal;// the total number of single cube divisors
+ // storage for cube pairs
+ Fxu_Pair *** pppPairs;
+ Fxu_Pair ** ppPairs;
+ // temporary storage for cubes
+ Fxu_Cube * pOrderCubes;
+ Fxu_Cube ** ppTailCubes;
+ // temporary storage for variables
+ Fxu_Var * pOrderVars;
+ Fxu_Var ** ppTailVars;
+ // temporary storage for pairs
+ Vec_Ptr_t * vPairs;
+ // statistics
+ int nEntries; // the total number of entries in the sparse matrix
+ int nDivs1; // the single cube divisors taken
+ int nDivs2; // the double cube divisors taken
+ int nDivs3; // the double cube divisors with complement
+ // memory manager
+ Extra_MmFixed_t * pMemMan; // the memory manager for all small sized entries
+};
+
+// the cube in the sparse matrix
+struct FxuCube // 9 words
+{
+ int iCube; // the number of this cube in the cover
+ Fxu_Cube * pFirst; // the pointer to the first cube of this cover
+ Fxu_Var * pVar; // the variable representing the output of the cover
+ Fxu_ListLit lLits; // the row in the table
+ Fxu_Cube * pPrev; // the previous cube
+ Fxu_Cube * pNext; // the next cube
+ Fxu_Cube * pOrder; // the specialized linked list of cubes
+};
+
+// the variable in the sparse matrix
+struct FxuVar // 10 words
+{
+ int iVar; // the number of this variable
+ int nCubes; // the number of cubes assoc with this var
+ Fxu_Cube * pFirst; // the first cube assoc with this var
+ Fxu_Pair *** ppPairs; // the pairs of cubes assoc with this var
+ Fxu_ListLit lLits; // the column in the table
+ Fxu_Var * pPrev; // the previous variable
+ Fxu_Var * pNext; // the next variable
+ Fxu_Var * pOrder; // the specialized linked list of variables
+};
+
+// the literal entry in the sparse matrix
+struct FxuLit // 8 words
+{
+ int iVar; // the number of this variable
+ int iCube; // the number of this cube
+ Fxu_Cube * pCube; // the cube of this literal
+ Fxu_Var * pVar; // the variable of this literal
+ Fxu_Lit * pHPrev; // prev lit in the cube
+ Fxu_Lit * pHNext; // next lit in the cube
+ Fxu_Lit * pVPrev; // prev lit of the var
+ Fxu_Lit * pVNext; // next lit of the var
+};
+
+// the cube pair
+struct FxuPair // 10 words
+{
+ int nLits1; // the number of literals in the two cubes
+ int nLits2; // the number of literals in the two cubes
+ int nBase; // the number of literals in the base
+ Fxu_Double * pDiv; // the divisor of this pair
+ Fxu_Cube * pCube1; // the first cube of the pair
+ Fxu_Cube * pCube2; // the second cube of the pair
+ int iCube1; // the first cube of the pair
+ int iCube2; // the second cube of the pair
+ Fxu_Pair * pDPrev; // the previous pair in the divisor
+ Fxu_Pair * pDNext; // the next pair in the divisor
+};
+
+// the double cube divisor
+struct FxuDouble // 10 words
+{
+ int Num; // the unique number of this divisor
+ int HNum; // the heap number of this divisor
+ int Weight; // the weight of this divisor
+ unsigned Key; // the hash key of this divisor
+ Fxu_ListPair lPairs; // the pairs of cubes, which produce this divisor
+ Fxu_Double * pPrev; // the previous divisor in the table
+ Fxu_Double * pNext; // the next divisor in the table
+ Fxu_Double * pOrder; // the specialized linked list of divisors
+};
+
+// the single cube divisor
+struct FxuSingle // 7 words
+{
+ int Num; // the unique number of this divisor
+ int HNum; // the heap number of this divisor
+ int Weight; // the weight of this divisor
+ Fxu_Var * pVar1; // the first variable of the single-cube divisor
+ Fxu_Var * pVar2; // the second variable of the single-cube divisor
+ Fxu_Single * pPrev; // the previous divisor in the list
+ Fxu_Single * pNext; // the next divisor in the list
+};
+
+////////////////////////////////////////////////////////////////////////
+/// MACRO DEFINITIONS ///
+////////////////////////////////////////////////////////////////////////
+
+// minimum/maximum
+#define Fxu_Min( a, b ) ( ((a)<(b))? (a):(b) )
+#define Fxu_Max( a, b ) ( ((a)>(b))? (a):(b) )
+
+// selection of the minimum/maximum cube in the pair
+#define Fxu_PairMinCube( pPair ) (((pPair)->iCube1 < (pPair)->iCube2)? (pPair)->pCube1: (pPair)->pCube2)
+#define Fxu_PairMaxCube( pPair ) (((pPair)->iCube1 > (pPair)->iCube2)? (pPair)->pCube1: (pPair)->pCube2)
+#define Fxu_PairMinCubeInt( pPair ) (((pPair)->iCube1 < (pPair)->iCube2)? (pPair)->iCube1: (pPair)->iCube2)
+#define Fxu_PairMaxCubeInt( pPair ) (((pPair)->iCube1 > (pPair)->iCube2)? (pPair)->iCube1: (pPair)->iCube2)
+
+// iterators
+
+#define Fxu_MatrixForEachCube( Matrix, Cube )\
+ for ( Cube = (Matrix)->lCubes.pHead;\
+ Cube;\
+ Cube = Cube->pNext )
+#define Fxu_MatrixForEachCubeSafe( Matrix, Cube, Cube2 )\
+ for ( Cube = (Matrix)->lCubes.pHead, Cube2 = (Cube? Cube->pNext: NULL);\
+ Cube;\
+ Cube = Cube2, Cube2 = (Cube? Cube->pNext: NULL) )
+
+#define Fxu_MatrixForEachVariable( Matrix, Var )\
+ for ( Var = (Matrix)->lVars.pHead;\
+ Var;\
+ Var = Var->pNext )
+#define Fxu_MatrixForEachVariableSafe( Matrix, Var, Var2 )\
+ for ( Var = (Matrix)->lVars.pHead, Var2 = (Var? Var->pNext: NULL);\
+ Var;\
+ Var = Var2, Var2 = (Var? Var->pNext: NULL) )
+
+#define Fxu_MatrixForEachSingle( Matrix, Single )\
+ for ( Single = (Matrix)->lSingles.pHead;\
+ Single;\
+ Single = Single->pNext )
+#define Fxu_MatrixForEachSingleSafe( Matrix, Single, Single2 )\
+ for ( Single = (Matrix)->lSingles.pHead, Single2 = (Single? Single->pNext: NULL);\
+ Single;\
+ Single = Single2, Single2 = (Single? Single->pNext: NULL) )
+
+#define Fxu_TableForEachDouble( Matrix, Key, Div )\
+ for ( Div = (Matrix)->pTable[Key].pHead;\
+ Div;\
+ Div = Div->pNext )
+#define Fxu_TableForEachDoubleSafe( Matrix, Key, Div, Div2 )\
+ for ( Div = (Matrix)->pTable[Key].pHead, Div2 = (Div? Div->pNext: NULL);\
+ Div;\
+ Div = Div2, Div2 = (Div? Div->pNext: NULL) )
+
+#define Fxu_MatrixForEachDouble( Matrix, Div, Index )\
+ for ( Index = 0; Index < (Matrix)->nTableSize; Index++ )\
+ Fxu_TableForEachDouble( Matrix, Index, Div )
+#define Fxu_MatrixForEachDoubleSafe( Matrix, Div, Div2, Index )\
+ for ( Index = 0; Index < (Matrix)->nTableSize; Index++ )\
+ Fxu_TableForEachDoubleSafe( Matrix, Index, Div, Div2 )
+
+
+#define Fxu_CubeForEachLiteral( Cube, Lit )\
+ for ( Lit = (Cube)->lLits.pHead;\
+ Lit;\
+ Lit = Lit->pHNext )
+#define Fxu_CubeForEachLiteralSafe( Cube, Lit, Lit2 )\
+ for ( Lit = (Cube)->lLits.pHead, Lit2 = (Lit? Lit->pHNext: NULL);\
+ Lit;\
+ Lit = Lit2, Lit2 = (Lit? Lit->pHNext: NULL) )
+
+#define Fxu_VarForEachLiteral( Var, Lit )\
+ for ( Lit = (Var)->lLits.pHead;\
+ Lit;\
+ Lit = Lit->pVNext )
+
+#define Fxu_CubeForEachDivisor( Cube, Div )\
+ for ( Div = (Cube)->lDivs.pHead;\
+ Div;\
+ Div = Div->pCNext )
+
+#define Fxu_DoubleForEachPair( Div, Pair )\
+ for ( Pair = (Div)->lPairs.pHead;\
+ Pair;\
+ Pair = Pair->pDNext )
+#define Fxu_DoubleForEachPairSafe( Div, Pair, Pair2 )\
+ for ( Pair = (Div)->lPairs.pHead, Pair2 = (Pair? Pair->pDNext: NULL);\
+ Pair;\
+ Pair = Pair2, Pair2 = (Pair? Pair->pDNext: NULL) )
+
+
+// iterator through the cube pairs belonging to the given cube
+#define Fxu_CubeForEachPair( pCube, pPair, i )\
+ for ( i = 0;\
+ i < pCube->pVar->nCubes &&\
+ (((unsigned)(pPair = pCube->pVar->ppPairs[pCube->iCube][i])) >= 0);\
+ i++ )\
+ if ( pPair )
+
+// iterator through all the items in the heap
+#define Fxu_HeapDoubleForEachItem( Heap, Div )\
+ for ( Heap->i = 1;\
+ Heap->i <= Heap->nItems && (Div = Heap->pTree[Heap->i]);\
+ Heap->i++ )
+#define Fxu_HeapSingleForEachItem( Heap, Single )\
+ for ( Heap->i = 1;\
+ Heap->i <= Heap->nItems && (Single = Heap->pTree[Heap->i]);\
+ Heap->i++ )
+
+// starting the rings
+#define Fxu_MatrixRingCubesStart( Matrix ) (((Matrix)->ppTailCubes = &((Matrix)->pOrderCubes)), ((Matrix)->pOrderCubes = NULL))
+#define Fxu_MatrixRingVarsStart( Matrix ) (((Matrix)->ppTailVars = &((Matrix)->pOrderVars)), ((Matrix)->pOrderVars = NULL))
+// stopping the rings
+#define Fxu_MatrixRingCubesStop( Matrix )
+#define Fxu_MatrixRingVarsStop( Matrix )
+// resetting the rings
+#define Fxu_MatrixRingCubesReset( Matrix ) (((Matrix)->pOrderCubes = NULL), ((Matrix)->ppTailCubes = NULL))
+#define Fxu_MatrixRingVarsReset( Matrix ) (((Matrix)->pOrderVars = NULL), ((Matrix)->ppTailVars = NULL))
+// adding to the rings
+#define Fxu_MatrixRingCubesAdd( Matrix, Cube) ((*((Matrix)->ppTailCubes) = Cube), ((Matrix)->ppTailCubes = &(Cube)->pOrder), ((Cube)->pOrder = (Fxu_Cube *)1))
+#define Fxu_MatrixRingVarsAdd( Matrix, Var ) ((*((Matrix)->ppTailVars ) = Var ), ((Matrix)->ppTailVars = &(Var)->pOrder ), ((Var)->pOrder = (Fxu_Var *)1))
+// iterating through the rings
+#define Fxu_MatrixForEachCubeInRing( Matrix, Cube )\
+ if ( (Matrix)->pOrderCubes )\
+ for ( Cube = (Matrix)->pOrderCubes;\
+ Cube != (Fxu_Cube *)1;\
+ Cube = Cube->pOrder )
+#define Fxu_MatrixForEachCubeInRingSafe( Matrix, Cube, Cube2 )\
+ if ( (Matrix)->pOrderCubes )\
+ for ( Cube = (Matrix)->pOrderCubes, Cube2 = ((Cube != (Fxu_Cube *)1)? Cube->pOrder: (Fxu_Cube *)1);\
+ Cube != (Fxu_Cube *)1;\
+ Cube = Cube2, Cube2 = ((Cube != (Fxu_Cube *)1)? Cube->pOrder: (Fxu_Cube *)1) )
+#define Fxu_MatrixForEachVarInRing( Matrix, Var )\
+ if ( (Matrix)->pOrderVars )\
+ for ( Var = (Matrix)->pOrderVars;\
+ Var != (Fxu_Var *)1;\
+ Var = Var->pOrder )
+#define Fxu_MatrixForEachVarInRingSafe( Matrix, Var, Var2 )\
+ if ( (Matrix)->pOrderVars )\
+ for ( Var = (Matrix)->pOrderVars, Var2 = ((Var != (Fxu_Var *)1)? Var->pOrder: (Fxu_Var *)1);\
+ Var != (Fxu_Var *)1;\
+ Var = Var2, Var2 = ((Var != (Fxu_Var *)1)? Var->pOrder: (Fxu_Var *)1) )
+// the procedures are related to the above macros
+extern void Fxu_MatrixRingCubesUnmark( Fxu_Matrix * p );
+extern void Fxu_MatrixRingVarsUnmark( Fxu_Matrix * p );
+
+
+// macros working with memory
+// MEM_ALLOC: allocate the given number (Size) of items of type (Type)
+// MEM_FREE: deallocate the pointer (Pointer) to the given number (Size) of items of type (Type)
+#ifdef USE_SYSTEM_MEMORY_MANAGEMENT
+#define MEM_ALLOC_FXU( Manager, Type, Size ) ((Type *)malloc( (Size) * sizeof(Type) ))
+#define MEM_FREE_FXU( Manager, Type, Size, Pointer ) if ( Pointer ) { free(Pointer); Pointer = NULL; }
+#else
+#define MEM_ALLOC_FXU( Manager, Type, Size )\
+ ((Type *)Fxu_MemFetch( Manager, (Size) * sizeof(Type) ))
+#define MEM_FREE_FXU( Manager, Type, Size, Pointer )\
+ if ( Pointer ) { Fxu_MemRecycle( Manager, (char *)(Pointer), (Size) * sizeof(Type) ); Pointer = NULL; }
+#endif
+
+////////////////////////////////////////////////////////////////////////
+/// FUNCTION DEFINITIONS ///
+////////////////////////////////////////////////////////////////////////
+
+/*===== fxu.c ====================================================*/
+extern char * Fxu_MemFetch( Fxu_Matrix * p, int nBytes );
+extern void Fxu_MemRecycle( Fxu_Matrix * p, char * pItem, int nBytes );
+/*===== fxuCreate.c ====================================================*/
+/*===== fxuReduce.c ====================================================*/
+/*===== fxuPrint.c ====================================================*/
+extern void Fxu_MatrixPrint( FILE * pFile, Fxu_Matrix * p );
+extern void Fxu_MatrixPrintDivisorProfile( FILE * pFile, Fxu_Matrix * p );
+/*===== fxuSelect.c ====================================================*/
+extern int Fxu_Select( Fxu_Matrix * p, Fxu_Single ** ppSingle, Fxu_Double ** ppDouble );
+extern int Fxu_SelectSCD( Fxu_Matrix * p, int Weight, Fxu_Var ** ppVar1, Fxu_Var ** ppVar2 );
+/*===== fxuUpdate.c ====================================================*/
+extern void Fxu_Update( Fxu_Matrix * p, Fxu_Single * pSingle, Fxu_Double * pDouble );
+extern void Fxu_UpdateDouble( Fxu_Matrix * p );
+extern void Fxu_UpdateSingle( Fxu_Matrix * p );
+/*===== fxuPair.c ====================================================*/
+extern void Fxu_PairCanonicize( Fxu_Cube ** ppCube1, Fxu_Cube ** ppCube2 );
+extern unsigned Fxu_PairHashKeyArray( Fxu_Matrix * p, int piVarsC1[], int piVarsC2[], int nVarsC1, int nVarsC2 );
+extern unsigned Fxu_PairHashKey( Fxu_Matrix * p, Fxu_Cube * pCube1, Fxu_Cube * pCube2, int * pnBase, int * pnLits1, int * pnLits2 );
+extern unsigned Fxu_PairHashKeyMv( Fxu_Matrix * p, Fxu_Cube * pCube1, Fxu_Cube * pCube2, int * pnBase, int * pnLits1, int * pnLits2 );
+extern int Fxu_PairCompare( Fxu_Pair * pPair1, Fxu_Pair * pPair2 );
+extern void Fxu_PairAllocStorage( Fxu_Var * pVar, int nCubes );
+extern void Fxu_PairFreeStorage( Fxu_Var * pVar );
+extern void Fxu_PairClearStorage( Fxu_Cube * pCube );
+extern Fxu_Pair * Fxu_PairAlloc( Fxu_Matrix * p, Fxu_Cube * pCube1, Fxu_Cube * pCube2 );
+extern void Fxu_PairAdd( Fxu_Pair * pPair );
+/*===== fxuSingle.c ====================================================*/
+extern void Fxu_MatrixComputeSingles( Fxu_Matrix * p, int fUse0, int nSingleMax );
+extern void Fxu_MatrixComputeSinglesOne( Fxu_Matrix * p, Fxu_Var * pVar );
+extern int Fxu_SingleCountCoincidence( Fxu_Matrix * p, Fxu_Var * pVar1, Fxu_Var * pVar2 );
+/*===== fxuMatrix.c ====================================================*/
+// matrix
+extern Fxu_Matrix * Fxu_MatrixAllocate();
+extern void Fxu_MatrixDelete( Fxu_Matrix * p );
+// double-cube divisor
+extern void Fxu_MatrixAddDivisor( Fxu_Matrix * p, Fxu_Cube * pCube1, Fxu_Cube * pCube2 );
+extern void Fxu_MatrixDelDivisor( Fxu_Matrix * p, Fxu_Double * pDiv );
+// single-cube divisor
+extern void Fxu_MatrixAddSingle( Fxu_Matrix * p, Fxu_Var * pVar1, Fxu_Var * pVar2, int Weight );
+// variable
+extern Fxu_Var * Fxu_MatrixAddVar( Fxu_Matrix * p );
+// cube
+extern Fxu_Cube * Fxu_MatrixAddCube( Fxu_Matrix * p, Fxu_Var * pVar, int iCube );
+// literal
+extern void Fxu_MatrixAddLiteral( Fxu_Matrix * p, Fxu_Cube * pCube, Fxu_Var * pVar );
+extern void Fxu_MatrixDelLiteral( Fxu_Matrix * p, Fxu_Lit * pLit );
+/*===== fxuList.c ====================================================*/
+// matrix -> variable
+extern void Fxu_ListMatrixAddVariable( Fxu_Matrix * p, Fxu_Var * pVar );
+extern void Fxu_ListMatrixDelVariable( Fxu_Matrix * p, Fxu_Var * pVar );
+// matrix -> cube
+extern void Fxu_ListMatrixAddCube( Fxu_Matrix * p, Fxu_Cube * pCube );
+extern void Fxu_ListMatrixDelCube( Fxu_Matrix * p, Fxu_Cube * pCube );
+// matrix -> single
+extern void Fxu_ListMatrixAddSingle( Fxu_Matrix * p, Fxu_Single * pSingle );
+extern void Fxu_ListMatrixDelSingle( Fxu_Matrix * p, Fxu_Single * pSingle );
+// table -> divisor
+extern void Fxu_ListTableAddDivisor( Fxu_Matrix * p, Fxu_Double * pDiv );
+extern void Fxu_ListTableDelDivisor( Fxu_Matrix * p, Fxu_Double * pDiv );
+// cube -> literal
+extern void Fxu_ListCubeAddLiteral( Fxu_Cube * pCube, Fxu_Lit * pLit );
+extern void Fxu_ListCubeDelLiteral( Fxu_Cube * pCube, Fxu_Lit * pLit );
+// var -> literal
+extern void Fxu_ListVarAddLiteral( Fxu_Var * pVar, Fxu_Lit * pLit );
+extern void Fxu_ListVarDelLiteral( Fxu_Var * pVar, Fxu_Lit * pLit );
+// divisor -> pair
+extern void Fxu_ListDoubleAddPairLast( Fxu_Double * pDiv, Fxu_Pair * pLink );
+extern void Fxu_ListDoubleAddPairFirst( Fxu_Double * pDiv, Fxu_Pair * pLink );
+extern void Fxu_ListDoubleAddPairMiddle( Fxu_Double * pDiv, Fxu_Pair * pSpot, Fxu_Pair * pLink );
+extern void Fxu_ListDoubleDelPair( Fxu_Double * pDiv, Fxu_Pair * pPair );
+/*===== fxuHeapDouble.c ====================================================*/
+extern Fxu_HeapDouble * Fxu_HeapDoubleStart();
+extern void Fxu_HeapDoubleStop( Fxu_HeapDouble * p );
+extern void Fxu_HeapDoublePrint( FILE * pFile, Fxu_HeapDouble * p );
+extern void Fxu_HeapDoubleCheck( Fxu_HeapDouble * p );
+extern void Fxu_HeapDoubleCheckOne( Fxu_HeapDouble * p, Fxu_Double * pDiv );
+
+extern void Fxu_HeapDoubleInsert( Fxu_HeapDouble * p, Fxu_Double * pDiv );
+extern void Fxu_HeapDoubleUpdate( Fxu_HeapDouble * p, Fxu_Double * pDiv );
+extern void Fxu_HeapDoubleDelete( Fxu_HeapDouble * p, Fxu_Double * pDiv );
+extern int Fxu_HeapDoubleReadMaxWeight( Fxu_HeapDouble * p );
+extern Fxu_Double * Fxu_HeapDoubleReadMax( Fxu_HeapDouble * p );
+extern Fxu_Double * Fxu_HeapDoubleGetMax( Fxu_HeapDouble * p );
+/*===== fxuHeapSingle.c ====================================================*/
+extern Fxu_HeapSingle * Fxu_HeapSingleStart();
+extern void Fxu_HeapSingleStop( Fxu_HeapSingle * p );
+extern void Fxu_HeapSinglePrint( FILE * pFile, Fxu_HeapSingle * p );
+extern void Fxu_HeapSingleCheck( Fxu_HeapSingle * p );
+extern void Fxu_HeapSingleCheckOne( Fxu_HeapSingle * p, Fxu_Single * pSingle );
+
+extern void Fxu_HeapSingleInsert( Fxu_HeapSingle * p, Fxu_Single * pSingle );
+extern void Fxu_HeapSingleUpdate( Fxu_HeapSingle * p, Fxu_Single * pSingle );
+extern void Fxu_HeapSingleDelete( Fxu_HeapSingle * p, Fxu_Single * pSingle );
+extern int Fxu_HeapSingleReadMaxWeight( Fxu_HeapSingle * p );
+extern Fxu_Single * Fxu_HeapSingleReadMax( Fxu_HeapSingle * p );
+extern Fxu_Single * Fxu_HeapSingleGetMax( Fxu_HeapSingle * p );
+
+#endif
+
+////////////////////////////////////////////////////////////////////////
+/// END OF FILE ///
+////////////////////////////////////////////////////////////////////////
+