Samples/multimedia/directshow/baseclasses/wxlist.h - deps/third_party/winsdk_samples_v71 - Git at Google

 //------------------------------------------------------------------------------
 // File: WXList.h
 //
 // Desc: DirectShow base classes - defines a non-MFC generic template list
 //       class.
 //
 // Copyright (c) 1992-2001 Microsoft Corporation.  All rights reserved.
 //------------------------------------------------------------------------------


 /* A generic list of pointers to objects.
    No storage management or copying is done on the objects pointed to.
    Objectives: avoid using MFC libraries in ndm kernel mode and
    provide a really useful list type.

    The class is thread safe in that separate threads may add and
    delete items in the list concurrently although the application
    must ensure that constructor and destructor access is suitably
    synchronised. An application can cause deadlock with operations
    which use two lists by simultaneously calling
    list1->Operation(list2) and list2->Operation(list1).  So don't!

    The names must not conflict with MFC classes as an application
    may use both.
    */

 #ifndef __WXLIST__
 #define __WXLIST__

    /* A POSITION represents (in some fashion that's opaque) a cursor
       on the list that can be set to identify any element.  NULL is
       a valid value and several operations regard NULL as the position
       "one step off the end of the list".  (In an n element list there
       are n+1 places to insert and NULL is that "n+1-th" value).
       The POSITION of an element in the list is only invalidated if
       that element is deleted.  Move operations may mean that what
       was a valid POSITION in one list is now a valid POSITION in
       a different list.

       Some operations which at first sight are illegal are allowed as
       harmless no-ops.  For instance RemoveHead is legal on an empty
       list and it returns NULL.  This allows an atomic way to test if
       there is an element there, and if so, get it.  The two operations
       AddTail and RemoveHead thus implement a MONITOR (See Hoare's paper).

       Single element operations return POSITIONs, non-NULL means it worked.
       whole list operations return a BOOL.  TRUE means it all worked.

       This definition is the same as the POSITION type for MFCs, so we must
       avoid defining it twice.
    */
 #ifndef __AFX_H__
 struct __POSITION { int unused; };
 typedef __POSITION* POSITION;
 #endif

 const int DEFAULTCACHE = 10;    /* Default node object cache size */

 /* A class representing one node in a list.
    Each node knows a pointer to it's adjacent nodes and also a pointer
    to the object that it looks after.
    All of these pointers can be retrieved or set through member functions.
 */
 class CBaseList
 #ifdef DEBUG
     : public CBaseObject
 #endif
 {
     /* Making these classes inherit from CBaseObject does nothing
        functionally but it allows us to check there are no memory
        leaks in debug builds.
     */

 public:

 #ifdef DEBUG
     class CNode : public CBaseObject {
 #else
     class CNode {
 #endif

         CNode *m_pPrev;         /* Previous node in the list */
         CNode *m_pNext;         /* Next node in the list */
         void *m_pObject;      /* Pointer to the object */

     public:

         /* Constructor - initialise the object's pointers */
         CNode()
 #ifdef DEBUG
             : CBaseObject(NAME("List node"))
 #endif
         {
         };


         /* Return the previous node before this one */
         __out CNode *Prev() const { return m_pPrev; };


         /* Return the next node after this one */
         __out CNode *Next() const { return m_pNext; };


         /* Set the previous node before this one */
         void SetPrev(__in_opt CNode *p) { m_pPrev = p; };


         /* Set the next node after this one */
         void SetNext(__in_opt CNode *p) { m_pNext = p; };


         /* Get the pointer to the object for this node */
         __out void *GetData() const { return m_pObject; };


         /* Set the pointer to the object for this node */
         void SetData(__in void *p) { m_pObject = p; };
     };

     class CNodeCache
     {
     public:
         CNodeCache(INT iCacheSize) : m_iCacheSize(iCacheSize),
                                      m_pHead(NULL),
                                      m_iUsed(0)
                                      {};
         ~CNodeCache() {
             CNode *pNode = m_pHead;
             while (pNode) {
                 CNode *pCurrent = pNode;
                 pNode = pNode->Next();
                 delete pCurrent;
             }
         };
         void AddToCache(__inout CNode *pNode)
         {
             if (m_iUsed < m_iCacheSize) {
                 pNode->SetNext(m_pHead);
                 m_pHead = pNode;
                 m_iUsed++;
             } else {
                 delete pNode;
             }
         };
         CNode *RemoveFromCache()
         {
             CNode *pNode = m_pHead;
             if (pNode != NULL) {
                 m_pHead = pNode->Next();
                 m_iUsed--;
                 ASSERT(m_iUsed >= 0);
             } else {
                 ASSERT(m_iUsed == 0);
             }
             return pNode;
         };
     private:
         INT m_iCacheSize;
         INT m_iUsed;
         CNode *m_pHead;
     };

 protected:

     CNode* m_pFirst;    /* Pointer to first node in the list */
     CNode* m_pLast;     /* Pointer to the last node in the list */
     LONG m_Count;       /* Number of nodes currently in the list */

 private:

     CNodeCache m_Cache; /* Cache of unused node pointers */

 private:

     /* These override the default copy constructor and assignment
        operator for all list classes. They are in the private class
        declaration section so that anybody trying to pass a list
        object by value will generate a compile time error of
        "cannot access the private member function". If these were
        not here then the compiler will create default constructors
        and assignment operators which when executed first take a
        copy of all member variables and then during destruction
        delete them all. This must not be done for any heap
        allocated data.
     */
     CBaseList(const CBaseList &refList);
     CBaseList &operator=(const CBaseList &refList);

 public:

     CBaseList(__in_opt LPCTSTR pName,
               INT iItems);

     CBaseList(__in_opt LPCTSTR pName);
 #ifdef UNICODE
     CBaseList(__in_opt LPCSTR pName,
               INT iItems);

     CBaseList(__in_opt LPCSTR pName);
 #endif
     ~CBaseList();

     /* Remove all the nodes from *this i.e. make the list empty */
     void RemoveAll();


     /* Return a cursor which identifies the first element of *this */
     __out_opt POSITION GetHeadPositionI() const;


     /* Return a cursor which identifies the last element of *this */
     __out_opt POSITION GetTailPositionI() const;


     /* Return the number of objects in *this */
     int GetCountI() const;

 protected:
     /* Return the pointer to the object at rp,
        Update rp to the next node in *this
        but make it NULL if it was at the end of *this.
        This is a wart retained for backwards compatibility.
        GetPrev is not implemented.
        Use Next, Prev and Get separately.
     */
     __out void *GetNextI(__inout POSITION& rp) const;


     /* Return a pointer to the object at p
        Asking for the object at NULL will return NULL harmlessly.
     */
     __out_opt void *GetI(__in_opt POSITION p) const;
     __out void *GetValidI(__in POSITION p) const;

 public:
     /* return the next / prev position in *this
        return NULL when going past the end/start.
        Next(NULL) is same as GetHeadPosition()
        Prev(NULL) is same as GetTailPosition()
        An n element list therefore behaves like a n+1 element
        cycle with NULL at the start/end.

        !!WARNING!! - This handling of NULL is DIFFERENT from GetNext.

        Some reasons are:
        1. For a list of n items there are n+1 positions to insert
           These are conveniently encoded as the n POSITIONs and NULL.
        2. If you are keeping a list sorted (fairly common) and you
           search forward for an element to insert before and don't
           find it you finish up with NULL as the element before which
           to insert.  You then want that NULL to be a valid POSITION
           so that you can insert before it and you want that insertion
           point to mean the (n+1)-th one that doesn't have a POSITION.
           (symmetrically if you are working backwards through the list).
        3. It simplifies the algebra which the methods generate.
           e.g. AddBefore(p,x) is identical to AddAfter(Prev(p),x)
           in ALL cases.  All the other arguments probably are reflections
           of the algebraic point.
     */
     __out_opt POSITION Next(__in_opt POSITION pos) const
     {
         if (pos == NULL) {
             return (POSITION) m_pFirst;
         }
         CNode *pn = (CNode *) pos;
         return (POSITION) pn->Next();
     } //Next

     // See Next
     __out_opt POSITION Prev(__in_opt POSITION pos) const
     {
         if (pos == NULL) {
             return (POSITION) m_pLast;
         }
         CNode *pn = (CNode *) pos;
         return (POSITION) pn->Prev();
     } //Prev


     /* Return the first position in *this which holds the given
        pointer.  Return NULL if the pointer was not not found.
     */
 protected:
     __out_opt POSITION FindI( __in void * pObj) const;

     // ??? Should there be (or even should there be only)
     // ??? POSITION FindNextAfter(void * pObj, POSITION p)
     // ??? And of course FindPrevBefore too.
     // ??? List.Find(&Obj) then becomes List.FindNextAfter(&Obj, NULL)


     /* Remove the first node in *this (deletes the pointer to its
        object from the list, does not free the object itself).
        Return the pointer to its object.
        If *this was already empty it will harmlessly return NULL.
     */
     __out_opt void *RemoveHeadI();


     /* Remove the last node in *this (deletes the pointer to its
        object from the list, does not free the object itself).
        Return the pointer to its object.
        If *this was already empty it will harmlessly return NULL.
     */
     __out_opt void *RemoveTailI();


     /* Remove the node identified by p from the list (deletes the pointer
        to its object from the list, does not free the object itself).
        Asking to Remove the object at NULL will harmlessly return NULL.
        Return the pointer to the object removed.
     */
     __out_opt void *RemoveI(__in_opt POSITION p);

     /* Add single object *pObj to become a new last element of the list.
        Return the new tail position, NULL if it fails.
        If you are adding a COM objects, you might want AddRef it first.
        Other existing POSITIONs in *this are still valid
     */
     __out_opt POSITION AddTailI(__in void * pObj);
 public:


     /* Add all the elements in *pList to the tail of *this.
        This duplicates all the nodes in *pList (i.e. duplicates
        all its pointers to objects).  It does not duplicate the objects.
        If you are adding a list of pointers to a COM object into the list
        it's a good idea to AddRef them all  it when you AddTail it.
        Return TRUE if it all worked, FALSE if it didn't.
        If it fails some elements may have been added.
        Existing POSITIONs in *this are still valid

        If you actually want to MOVE the elements, use MoveToTail instead.
     */
     BOOL AddTail(__in CBaseList *pList);


     /* Mirror images of AddHead: */

     /* Add single object to become a new first element of the list.
        Return the new head position, NULL if it fails.
        Existing POSITIONs in *this are still valid
     */
 protected:
     __out_opt POSITION AddHeadI(__in void * pObj);
 public:

     /* Add all the elements in *pList to the head of *this.
        Same warnings apply as for AddTail.
        Return TRUE if it all worked, FALSE if it didn't.
        If it fails some of the objects may have been added.

        If you actually want to MOVE the elements, use MoveToHead instead.
     */
     BOOL AddHead(__in CBaseList *pList);


     /* Add the object *pObj to *this after position p in *this.
        AddAfter(NULL,x) adds x to the start - equivalent to AddHead
        Return the position of the object added, NULL if it failed.
        Existing POSITIONs in *this are undisturbed, including p.
     */
 protected:
     __out_opt POSITION AddAfterI(__in_opt POSITION p, __in void * pObj);
 public:

     /* Add the list *pList to *this after position p in *this
        AddAfter(NULL,x) adds x to the start - equivalent to AddHead
        Return TRUE if it all worked, FALSE if it didn't.
        If it fails, some of the objects may be added
        Existing POSITIONs in *this are undisturbed, including p.
     */
     BOOL AddAfter(__in_opt POSITION p, __in CBaseList *pList);


     /* Mirror images:
        Add the object *pObj to this-List after position p in *this.
        AddBefore(NULL,x) adds x to the end - equivalent to AddTail
        Return the position of the new object, NULL if it fails
        Existing POSITIONs in *this are undisturbed, including p.
     */
     protected:
     __out_opt POSITION AddBeforeI(__in_opt POSITION p, __in void * pObj);
     public:

     /* Add the list *pList to *this before position p in *this
        AddAfter(NULL,x) adds x to the start - equivalent to AddHead
        Return TRUE if it all worked, FALSE if it didn't.
        If it fails, some of the objects may be added
        Existing POSITIONs in *this are undisturbed, including p.
     */
     BOOL AddBefore(__in_opt POSITION p, __in CBaseList *pList);


     /* Note that AddAfter(p,x) is equivalent to AddBefore(Next(p),x)
        even in cases where p is NULL or Next(p) is NULL.
        Similarly for mirror images etc.
        This may make it easier to argue about programs.
     */


     /* The following operations do not copy any elements.
        They move existing blocks of elements around by switching pointers.
        They are fairly efficient for long lists as for short lists.
        (Alas, the Count slows things down).

        They split the list into two parts.
        One part remains as the original list, the other part
        is appended to the second list.  There are eight possible
        variations:
        Split the list {after/before} a given element
        keep the {head/tail} portion in the original list
        append the rest to the {head/tail} of the new list.

        Since After is strictly equivalent to Before Next
        we are not in serious need of the Before/After variants.
        That leaves only four.

        If you are processing a list left to right and dumping
        the bits that you have processed into another list as
        you go, the Tail/Tail variant gives the most natural result.
        If you are processing in reverse order, Head/Head is best.

        By using NULL positions and empty lists judiciously either
        of the other two can be built up in two operations.

        The definition of NULL (see Next/Prev etc) means that
        degenerate cases include
           "move all elements to new list"
           "Split a list into two lists"
           "Concatenate two lists"
           (and quite a few no-ops)

        !!WARNING!! The type checking won't buy you much if you get list
        positions muddled up - e.g. use a POSITION that's in a different
        list and see what a mess you get!
     */

     /* Split *this after position p in *this
        Retain as *this the tail portion of the original *this
        Add the head portion to the tail end of *pList
        Return TRUE if it all worked, FALSE if it didn't.

        e.g.
           foo->MoveToTail(foo->GetHeadPosition(), bar);
               moves one element from the head of foo to the tail of bar
           foo->MoveToTail(NULL, bar);
               is a no-op, returns NULL
           foo->MoveToTail(foo->GetTailPosition, bar);
               concatenates foo onto the end of bar and empties foo.

        A better, except excessively long name might be
            MoveElementsFromHeadThroughPositionToOtherTail
     */
     BOOL MoveToTail(__in_opt POSITION pos, __in CBaseList *pList);


     /* Mirror image:
        Split *this before position p in *this.
        Retain in *this the head portion of the original *this
        Add the tail portion to the start (i.e. head) of *pList

        e.g.
           foo->MoveToHead(foo->GetTailPosition(), bar);
               moves one element from the tail of foo to the head of bar
           foo->MoveToHead(NULL, bar);
               is a no-op, returns NULL
           foo->MoveToHead(foo->GetHeadPosition, bar);
               concatenates foo onto the start of bar and empties foo.
     */
     BOOL MoveToHead(__in_opt POSITION pos, __in CBaseList *pList);


     /* Reverse the order of the [pointers to] objects in *this
     */
     void Reverse();


     /* set cursor to the position of each element of list in turn  */
     #define TRAVERSELIST(list, cursor)               \
     for ( cursor = (list).GetHeadPosition()           \
         ; cursor!=NULL                               \
         ; cursor = (list).Next(cursor)                \
         )


     /* set cursor to the position of each element of list in turn
        in reverse order
     */
     #define REVERSETRAVERSELIST(list, cursor)        \
     for ( cursor = (list).GetTailPosition()           \
         ; cursor!=NULL                               \
         ; cursor = (list).Prev(cursor)                \
         )

 }; // end of class declaration

 template<class OBJECT> class CGenericList : public CBaseList
 {
 public:
     CGenericList(__in_opt LPCTSTR pName,
                  INT iItems,
                  BOOL bLock = TRUE,
                  BOOL bAlert = FALSE) :
                      CBaseList(pName, iItems) {
         UNREFERENCED_PARAMETER(bAlert);
         UNREFERENCED_PARAMETER(bLock);
     };
     CGenericList(__in_opt LPCTSTR pName) :
                      CBaseList(pName) {
     };

     __out_opt POSITION GetHeadPosition() const { return (POSITION)m_pFirst; }
     __out_opt POSITION GetTailPosition() const { return (POSITION)m_pLast; }
     int GetCount() const { return m_Count; }

     __out OBJECT *GetNext(__inout POSITION& rp) const { return (OBJECT *) GetNextI(rp); }

     __out_opt OBJECT *Get(__in_opt POSITION p) const { return (OBJECT *) GetI(p); }
     __out OBJECT *GetValid(__in POSITION p) const { return (OBJECT *) GetValidI(p); }
     __out_opt OBJECT *GetHead() const  { return Get(GetHeadPosition()); }

     __out_opt OBJECT *RemoveHead() { return (OBJECT *) RemoveHeadI(); }

     __out_opt OBJECT *RemoveTail() { return (OBJECT *) RemoveTailI(); }

     __out_opt OBJECT *Remove(__in_opt POSITION p) { return (OBJECT *) RemoveI(p); }
     __out_opt POSITION AddBefore(__in_opt POSITION p, __in OBJECT * pObj) { return AddBeforeI(p, pObj); }
     __out_opt POSITION AddAfter(__in_opt POSITION p, __in OBJECT * pObj)  { return AddAfterI(p, pObj); }
     __out_opt POSITION AddHead(__in OBJECT * pObj) { return AddHeadI(pObj); }
     __out_opt POSITION AddTail(__in OBJECT * pObj)  { return AddTailI(pObj); }
     BOOL AddTail(__in CGenericList<OBJECT> *pList)
             { return CBaseList::AddTail((CBaseList *) pList); }
     BOOL AddHead(__in CGenericList<OBJECT> *pList)
             { return CBaseList::AddHead((CBaseList *) pList); }
     BOOL AddAfter(__in_opt POSITION p, __in CGenericList<OBJECT> *pList)
             { return CBaseList::AddAfter(p, (CBaseList *) pList); };
     BOOL AddBefore(__in_opt POSITION p, __in CGenericList<OBJECT> *pList)
             { return CBaseList::AddBefore(p, (CBaseList *) pList); };
     __out_opt POSITION Find( __in OBJECT * pObj) const { return FindI(pObj); }
 }; // end of class declaration


 /* These define the standard list types */

 typedef CGenericList<CBaseObject> CBaseObjectList;
 typedef CGenericList<IUnknown> CBaseInterfaceList;

 #endif /* __WXLIST__ */
	//------------------------------------------------------------------------------
	// File: WXList.h
	//
	// Desc: DirectShow base classes - defines a non-MFC generic template list
	// class.
	//
	// Copyright (c) 1992-2001 Microsoft Corporation. All rights reserved.
	//------------------------------------------------------------------------------


	/* A generic list of pointers to objects.
	No storage management or copying is done on the objects pointed to.
	Objectives: avoid using MFC libraries in ndm kernel mode and
	provide a really useful list type.

	The class is thread safe in that separate threads may add and
	delete items in the list concurrently although the application
	must ensure that constructor and destructor access is suitably
	synchronised. An application can cause deadlock with operations
	which use two lists by simultaneously calling
	list1->Operation(list2) and list2->Operation(list1). So don't!

	The names must not conflict with MFC classes as an application
	may use both.
	*/

	#ifndef __WXLIST__
	#define __WXLIST__

	/* A POSITION represents (in some fashion that's opaque) a cursor
	on the list that can be set to identify any element. NULL is
	a valid value and several operations regard NULL as the position
	"one step off the end of the list". (In an n element list there
	are n+1 places to insert and NULL is that "n+1-th" value).
	The POSITION of an element in the list is only invalidated if
	that element is deleted. Move operations may mean that what
	was a valid POSITION in one list is now a valid POSITION in
	a different list.

	Some operations which at first sight are illegal are allowed as
	harmless no-ops. For instance RemoveHead is legal on an empty
	list and it returns NULL. This allows an atomic way to test if
	there is an element there, and if so, get it. The two operations
	AddTail and RemoveHead thus implement a MONITOR (See Hoare's paper).

	Single element operations return POSITIONs, non-NULL means it worked.
	whole list operations return a BOOL. TRUE means it all worked.

	This definition is the same as the POSITION type for MFCs, so we must
	avoid defining it twice.
	*/
	#ifndef __AFX_H__
	struct __POSITION { int unused; };
	typedef __POSITION* POSITION;
	#endif

	const int DEFAULTCACHE = 10; /* Default node object cache size */

	/* A class representing one node in a list.
	Each node knows a pointer to it's adjacent nodes and also a pointer
	to the object that it looks after.
	All of these pointers can be retrieved or set through member functions.
	*/
	class CBaseList
	#ifdef DEBUG
	: public CBaseObject
	#endif
	{
	/* Making these classes inherit from CBaseObject does nothing
	functionally but it allows us to check there are no memory
	leaks in debug builds.
	*/

	public:

	#ifdef DEBUG
	class CNode : public CBaseObject {
	#else
	class CNode {
	#endif

	CNode m_pPrev; / Previous node in the list */
	CNode m_pNext; / Next node in the list */
	void m_pObject; / Pointer to the object */

	public:

	/* Constructor - initialise the object's pointers */
	CNode()
	#ifdef DEBUG
	: CBaseObject(NAME("List node"))
	#endif
	{
	};


	/* Return the previous node before this one */
	__out CNode *Prev() const { return m_pPrev; };


	/* Return the next node after this one */
	__out CNode *Next() const { return m_pNext; };


	/* Set the previous node before this one */
	void SetPrev(__in_opt CNode *p) { m_pPrev = p; };


	/* Set the next node after this one */
	void SetNext(__in_opt CNode *p) { m_pNext = p; };


	/* Get the pointer to the object for this node */
	__out void *GetData() const { return m_pObject; };


	/* Set the pointer to the object for this node */
	void SetData(__in void *p) { m_pObject = p; };
	};

	class CNodeCache
	{
	public:
	CNodeCache(INT iCacheSize) : m_iCacheSize(iCacheSize),
	m_pHead(NULL),
	m_iUsed(0)
	{};
	~CNodeCache() {
	CNode *pNode = m_pHead;
	while (pNode) {
	CNode *pCurrent = pNode;
	pNode = pNode->Next();
	delete pCurrent;
	}
	};
	void AddToCache(__inout CNode *pNode)
	{
	if (m_iUsed < m_iCacheSize) {
	pNode->SetNext(m_pHead);
	m_pHead = pNode;
	m_iUsed++;
	} else {
	delete pNode;
	}
	};
	CNode *RemoveFromCache()
	{
	CNode *pNode = m_pHead;
	if (pNode != NULL) {
	m_pHead = pNode->Next();
	m_iUsed--;
	ASSERT(m_iUsed >= 0);
	} else {
	ASSERT(m_iUsed == 0);
	}
	return pNode;
	};
	private:
	INT m_iCacheSize;
	INT m_iUsed;
	CNode *m_pHead;
	};

	protected:

	CNode* m_pFirst; /* Pointer to first node in the list */
	CNode* m_pLast; /* Pointer to the last node in the list */
	LONG m_Count; /* Number of nodes currently in the list */

	private:

	CNodeCache m_Cache; /* Cache of unused node pointers */

	private:

	/* These override the default copy constructor and assignment
	operator for all list classes. They are in the private class
	declaration section so that anybody trying to pass a list
	object by value will generate a compile time error of
	"cannot access the private member function". If these were
	not here then the compiler will create default constructors
	and assignment operators which when executed first take a
	copy of all member variables and then during destruction
	delete them all. This must not be done for any heap
	allocated data.
	*/
	CBaseList(const CBaseList &refList);
	CBaseList &operator=(const CBaseList &refList);

	public:

	CBaseList(__in_opt LPCTSTR pName,
	INT iItems);

	CBaseList(__in_opt LPCTSTR pName);
	#ifdef UNICODE
	CBaseList(__in_opt LPCSTR pName,
	INT iItems);

	CBaseList(__in_opt LPCSTR pName);
	#endif
	~CBaseList();

	/* Remove all the nodes from this i.e. make the list empty /
	void RemoveAll();


	/* Return a cursor which identifies the first element of this /
	__out_opt POSITION GetHeadPositionI() const;


	/* Return a cursor which identifies the last element of this /
	__out_opt POSITION GetTailPositionI() const;


	/* Return the number of objects in this /
	int GetCountI() const;

	protected:
	/* Return the pointer to the object at rp,
	Update rp to the next node in *this
	but make it NULL if it was at the end of *this.
	This is a wart retained for backwards compatibility.
	GetPrev is not implemented.
	Use Next, Prev and Get separately.
	*/
	__out void *GetNextI(__inout POSITION& rp) const;


	/* Return a pointer to the object at p
	Asking for the object at NULL will return NULL harmlessly.
	*/
	__out_opt void *GetI(__in_opt POSITION p) const;
	__out void *GetValidI(__in POSITION p) const;

	public:
	/* return the next / prev position in *this
	return NULL when going past the end/start.
	Next(NULL) is same as GetHeadPosition()
	Prev(NULL) is same as GetTailPosition()
	An n element list therefore behaves like a n+1 element
	cycle with NULL at the start/end.

	!!WARNING!! - This handling of NULL is DIFFERENT from GetNext.

	Some reasons are:
	1. For a list of n items there are n+1 positions to insert
	These are conveniently encoded as the n POSITIONs and NULL.
	2. If you are keeping a list sorted (fairly common) and you
	search forward for an element to insert before and don't
	find it you finish up with NULL as the element before which
	to insert. You then want that NULL to be a valid POSITION
	so that you can insert before it and you want that insertion
	point to mean the (n+1)-th one that doesn't have a POSITION.
	(symmetrically if you are working backwards through the list).
	3. It simplifies the algebra which the methods generate.
	e.g. AddBefore(p,x) is identical to AddAfter(Prev(p),x)
	in ALL cases. All the other arguments probably are reflections
	of the algebraic point.
	*/
	__out_opt POSITION Next(__in_opt POSITION pos) const
	{
	if (pos == NULL) {
	return (POSITION) m_pFirst;
	}
	CNode pn = (CNode ) pos;
	return (POSITION) pn->Next();
	} //Next

	// See Next
	__out_opt POSITION Prev(__in_opt POSITION pos) const
	{
	if (pos == NULL) {
	return (POSITION) m_pLast;
	}
	CNode pn = (CNode ) pos;
	return (POSITION) pn->Prev();
	} //Prev


	/* Return the first position in *this which holds the given
	pointer. Return NULL if the pointer was not not found.
	*/
	protected:
	__out_opt POSITION FindI( __in void * pObj) const;

	// ??? Should there be (or even should there be only)
	// ??? POSITION FindNextAfter(void * pObj, POSITION p)
	// ??? And of course FindPrevBefore too.
	// ??? List.Find(&Obj) then becomes List.FindNextAfter(&Obj, NULL)


	/* Remove the first node in *this (deletes the pointer to its
	object from the list, does not free the object itself).
	Return the pointer to its object.
	If *this was already empty it will harmlessly return NULL.
	*/
	__out_opt void *RemoveHeadI();


	/* Remove the last node in *this (deletes the pointer to its
	object from the list, does not free the object itself).
	Return the pointer to its object.
	If *this was already empty it will harmlessly return NULL.
	*/
	__out_opt void *RemoveTailI();


	/* Remove the node identified by p from the list (deletes the pointer
	to its object from the list, does not free the object itself).
	Asking to Remove the object at NULL will harmlessly return NULL.
	Return the pointer to the object removed.
	*/
	__out_opt void *RemoveI(__in_opt POSITION p);

	/* Add single object *pObj to become a new last element of the list.
	Return the new tail position, NULL if it fails.
	If you are adding a COM objects, you might want AddRef it first.
	Other existing POSITIONs in *this are still valid
	*/
	__out_opt POSITION AddTailI(__in void * pObj);
	public:


	/* Add all the elements in pList to the tail of this.
	This duplicates all the nodes in *pList (i.e. duplicates
	all its pointers to objects). It does not duplicate the objects.
	If you are adding a list of pointers to a COM object into the list
	it's a good idea to AddRef them all it when you AddTail it.
	Return TRUE if it all worked, FALSE if it didn't.
	If it fails some elements may have been added.
	Existing POSITIONs in *this are still valid

	If you actually want to MOVE the elements, use MoveToTail instead.
	*/
	BOOL AddTail(__in CBaseList *pList);


	/* Mirror images of AddHead: */

	/* Add single object to become a new first element of the list.
	Return the new head position, NULL if it fails.
	Existing POSITIONs in *this are still valid
	*/
	protected:
	__out_opt POSITION AddHeadI(__in void * pObj);
	public:

	/* Add all the elements in pList to the head of this.
	Same warnings apply as for AddTail.
	Return TRUE if it all worked, FALSE if it didn't.
	If it fails some of the objects may have been added.

	If you actually want to MOVE the elements, use MoveToHead instead.
	*/
	BOOL AddHead(__in CBaseList *pList);


	/* Add the object pObj to this after position p in *this.
	AddAfter(NULL,x) adds x to the start - equivalent to AddHead
	Return the position of the object added, NULL if it failed.
	Existing POSITIONs in *this are undisturbed, including p.
	*/
	protected:
	__out_opt POSITION AddAfterI(__in_opt POSITION p, __in void * pObj);
	public:

	/* Add the list pList to this after position p in *this
	AddAfter(NULL,x) adds x to the start - equivalent to AddHead
	Return TRUE if it all worked, FALSE if it didn't.
	If it fails, some of the objects may be added
	Existing POSITIONs in *this are undisturbed, including p.
	*/
	BOOL AddAfter(__in_opt POSITION p, __in CBaseList *pList);


	/* Mirror images:
	Add the object pObj to this-List after position p in this.
	AddBefore(NULL,x) adds x to the end - equivalent to AddTail
	Return the position of the new object, NULL if it fails
	Existing POSITIONs in *this are undisturbed, including p.
	*/
	protected:
	__out_opt POSITION AddBeforeI(__in_opt POSITION p, __in void * pObj);
	public:

	/* Add the list pList to this before position p in *this
	AddAfter(NULL,x) adds x to the start - equivalent to AddHead
	Return TRUE if it all worked, FALSE if it didn't.
	If it fails, some of the objects may be added
	Existing POSITIONs in *this are undisturbed, including p.
	*/
	BOOL AddBefore(__in_opt POSITION p, __in CBaseList *pList);


	/* Note that AddAfter(p,x) is equivalent to AddBefore(Next(p),x)
	even in cases where p is NULL or Next(p) is NULL.
	Similarly for mirror images etc.
	This may make it easier to argue about programs.
	*/



	/* The following operations do not copy any elements.
	They move existing blocks of elements around by switching pointers.
	They are fairly efficient for long lists as for short lists.
	(Alas, the Count slows things down).

	They split the list into two parts.
	One part remains as the original list, the other part
	is appended to the second list. There are eight possible
	variations:
	Split the list {after/before} a given element
	keep the {head/tail} portion in the original list
	append the rest to the {head/tail} of the new list.

	Since After is strictly equivalent to Before Next
	we are not in serious need of the Before/After variants.
	That leaves only four.

	If you are processing a list left to right and dumping
	the bits that you have processed into another list as
	you go, the Tail/Tail variant gives the most natural result.
	If you are processing in reverse order, Head/Head is best.

	By using NULL positions and empty lists judiciously either
	of the other two can be built up in two operations.

	The definition of NULL (see Next/Prev etc) means that
	degenerate cases include
	"move all elements to new list"
	"Split a list into two lists"
	"Concatenate two lists"
	(and quite a few no-ops)

	!!WARNING!! The type checking won't buy you much if you get list
	positions muddled up - e.g. use a POSITION that's in a different
	list and see what a mess you get!
	*/

	/* Split this after position p in this
	Retain as this the tail portion of the original this
	Add the head portion to the tail end of *pList
	Return TRUE if it all worked, FALSE if it didn't.

	e.g.
	foo->MoveToTail(foo->GetHeadPosition(), bar);
	moves one element from the head of foo to the tail of bar
	foo->MoveToTail(NULL, bar);
	is a no-op, returns NULL
	foo->MoveToTail(foo->GetTailPosition, bar);
	concatenates foo onto the end of bar and empties foo.

	A better, except excessively long name might be
	MoveElementsFromHeadThroughPositionToOtherTail
	*/
	BOOL MoveToTail(__in_opt POSITION pos, __in CBaseList *pList);


	/* Mirror image:
	Split this before position p in this.
	Retain in this the head portion of the original this
	Add the tail portion to the start (i.e. head) of *pList

	e.g.
	foo->MoveToHead(foo->GetTailPosition(), bar);
	moves one element from the tail of foo to the head of bar
	foo->MoveToHead(NULL, bar);
	is a no-op, returns NULL
	foo->MoveToHead(foo->GetHeadPosition, bar);
	concatenates foo onto the start of bar and empties foo.
	*/
	BOOL MoveToHead(__in_opt POSITION pos, __in CBaseList *pList);


	/* Reverse the order of the [pointers to] objects in *this
	*/
	void Reverse();


	/* set cursor to the position of each element of list in turn */
	#define TRAVERSELIST(list, cursor) \
	for ( cursor = (list).GetHeadPosition() \
	; cursor!=NULL \
	; cursor = (list).Next(cursor) \
	)


	/* set cursor to the position of each element of list in turn
	in reverse order
	*/
	#define REVERSETRAVERSELIST(list, cursor) \
	for ( cursor = (list).GetTailPosition() \
	; cursor!=NULL \
	; cursor = (list).Prev(cursor) \
	)

	}; // end of class declaration

	template<class OBJECT> class CGenericList : public CBaseList
	{
	public:
	CGenericList(__in_opt LPCTSTR pName,
	INT iItems,
	BOOL bLock = TRUE,
	BOOL bAlert = FALSE) :
	CBaseList(pName, iItems) {
	UNREFERENCED_PARAMETER(bAlert);
	UNREFERENCED_PARAMETER(bLock);
	};
	CGenericList(__in_opt LPCTSTR pName) :
	CBaseList(pName) {
	};

	__out_opt POSITION GetHeadPosition() const { return (POSITION)m_pFirst; }
	__out_opt POSITION GetTailPosition() const { return (POSITION)m_pLast; }
	int GetCount() const { return m_Count; }

	__out OBJECT GetNext(__inout POSITION& rp) const { return (OBJECT ) GetNextI(rp); }

	__out_opt OBJECT Get(__in_opt POSITION p) const { return (OBJECT ) GetI(p); }
	__out OBJECT GetValid(__in POSITION p) const { return (OBJECT ) GetValidI(p); }
	__out_opt OBJECT *GetHead() const { return Get(GetHeadPosition()); }

	__out_opt OBJECT RemoveHead() { return (OBJECT ) RemoveHeadI(); }

	__out_opt OBJECT RemoveTail() { return (OBJECT ) RemoveTailI(); }

	__out_opt OBJECT Remove(__in_opt POSITION p) { return (OBJECT ) RemoveI(p); }
	__out_opt POSITION AddBefore(__in_opt POSITION p, __in OBJECT * pObj) { return AddBeforeI(p, pObj); }
	__out_opt POSITION AddAfter(__in_opt POSITION p, __in OBJECT * pObj) { return AddAfterI(p, pObj); }
	__out_opt POSITION AddHead(__in OBJECT * pObj) { return AddHeadI(pObj); }
	__out_opt POSITION AddTail(__in OBJECT * pObj) { return AddTailI(pObj); }
	BOOL AddTail(__in CGenericList<OBJECT> *pList)
	{ return CBaseList::AddTail((CBaseList *) pList); }
	BOOL AddHead(__in CGenericList<OBJECT> *pList)
	{ return CBaseList::AddHead((CBaseList *) pList); }
	BOOL AddAfter(__in_opt POSITION p, __in CGenericList<OBJECT> *pList)
	{ return CBaseList::AddAfter(p, (CBaseList *) pList); };
	BOOL AddBefore(__in_opt POSITION p, __in CGenericList<OBJECT> *pList)
	{ return CBaseList::AddBefore(p, (CBaseList *) pList); };
	__out_opt POSITION Find( __in OBJECT * pObj) const { return FindI(pObj); }
	}; // end of class declaration



	/* These define the standard list types */

	typedef CGenericList<CBaseObject> CBaseObjectList;
	typedef CGenericList<IUnknown> CBaseInterfaceList;

	#endif /* __WXLIST__ */