892 lines
24 KiB
C++
892 lines
24 KiB
C++
//------------------------------------------------------------------------------
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// File: WXList.cpp
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//
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// Desc: DirectShow base classes - implements a non-MFC based generic list
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// template class.
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// Copyright (c) 1992-2001 Microsoft Corporation. All rights reserved.
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//------------------------------------------------------------------------------
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/* A generic list of pointers to objects.
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Objectives: avoid using MFC libraries in ndm kernel mode and
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provide a really useful list type.
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The class is thread safe in that separate threads may add and
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delete items in the list concurrently although the application
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must ensure that constructor and destructor access is suitably
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synchronised.
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The list name must not conflict with MFC classes as an
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application may use both
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The nodes form a doubly linked, NULL terminated chain with an anchor
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block (the list object per se) holding pointers to the first and last
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nodes and a count of the nodes.
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There is a node cache to reduce the allocation and freeing overhead.
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It optionally (determined at construction time) has an Event which is
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set whenever the list becomes non-empty and reset whenever it becomes
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empty.
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It optionally (determined at construction time) has a Critical Section
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which is entered during the important part of each operation. (About
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all you can do outside it is some parameter checking).
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The node cache is a repository of nodes that are NOT in the list to speed
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up storage allocation. Each list has its own cache to reduce locking and
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serialising. The list accesses are serialised anyway for a given list - a
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common cache would mean that we would have to separately serialise access
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of all lists within the cache. Because the cache only stores nodes that are
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not in the list, releasing the cache does not release any list nodes. This
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means that list nodes can be copied or rechained from one list to another
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without danger of creating a dangling reference if the original cache goes
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away.
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Questionable design decisions:
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1. Retaining the warts for compatibility
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2. Keeping an element count -i.e. counting whenever we do anything
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instead of only when we want the count.
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3. Making the chain pointers NULL terminated. If the list object
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itself looks just like a node and the list is kept as a ring then
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it reduces the number of special cases. All inserts look the same.
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*/
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#include <streams.h>
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/* set cursor to the position of each element of list in turn */
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#define INTERNALTRAVERSELIST(list, cursor) \
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for ( cursor = (list).GetHeadPositionI() \
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; cursor!=NULL \
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; cursor = (list).Next(cursor) \
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)
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/* set cursor to the position of each element of list in turn
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in reverse order
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*/
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#define INTERNALREVERSETRAVERSELIST(list, cursor) \
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for ( cursor = (list).GetTailPositionI() \
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; cursor!=NULL \
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; cursor = (list).Prev(cursor) \
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)
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/* Constructor calls a separate initialisation function that
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creates a node cache, optionally creates a lock object
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and optionally creates a signaling object.
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By default we create a locking object, a DEFAULTCACHE sized
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cache but no event object so the list cannot be used in calls
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to WaitForSingleObject
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*/
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CBaseList::CBaseList(__in_opt LPCTSTR pName, // Descriptive list name
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INT iItems) : // Node cache size
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#ifdef DEBUG
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CBaseObject(pName),
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#endif
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m_pFirst(NULL),
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m_pLast(NULL),
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m_Count(0),
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m_Cache(iItems)
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{
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} // constructor
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CBaseList::CBaseList(__in_opt LPCTSTR pName) : // Descriptive list name
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#ifdef DEBUG
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CBaseObject(pName),
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#endif
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m_pFirst(NULL),
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m_pLast(NULL),
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m_Count(0),
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m_Cache(DEFAULTCACHE)
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{
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} // constructor
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#ifdef UNICODE
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CBaseList::CBaseList(__in_opt LPCSTR pName, // Descriptive list name
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INT iItems) : // Node cache size
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#ifdef DEBUG
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CBaseObject(pName),
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#endif
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m_pFirst(NULL),
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m_pLast(NULL),
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m_Count(0),
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m_Cache(iItems)
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{
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} // constructor
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CBaseList::CBaseList(__in_opt LPCSTR pName) : // Descriptive list name
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#ifdef DEBUG
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CBaseObject(pName),
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#endif
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m_pFirst(NULL),
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m_pLast(NULL),
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m_Count(0),
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m_Cache(DEFAULTCACHE)
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{
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} // constructor
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#endif
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/* The destructor enumerates all the node objects in the list and
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in the cache deleting each in turn. We do not do any processing
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on the objects that the list holds (i.e. points to) so if they
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represent interfaces for example the creator of the list should
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ensure that each of them is released before deleting us
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*/
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CBaseList::~CBaseList()
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{
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/* Delete all our list nodes */
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RemoveAll();
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} // destructor
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/* Remove all the nodes from the list but don't do anything
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with the objects that each node looks after (this is the
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responsibility of the creator).
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Aa a last act we reset the signalling event
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(if available) to indicate to clients that the list
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does not have any entries in it.
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*/
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void CBaseList::RemoveAll()
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{
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/* Free up all the CNode objects NOTE we don't bother putting the
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deleted nodes into the cache as this method is only really called
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in serious times of change such as when we are being deleted at
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which point the cache will be deleted anway */
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CNode *pn = m_pFirst;
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while (pn) {
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CNode *op = pn;
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pn = pn->Next();
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delete op;
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}
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/* Reset the object count and the list pointers */
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m_Count = 0;
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m_pFirst = m_pLast = NULL;
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} // RemoveAll
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/* Return a position enumerator for the entire list.
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A position enumerator is a pointer to a node object cast to a
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transparent type so all we do is return the _head/_tail node
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pointer in the list.
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WARNING because the position is a pointer to a node there is
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an implicit assumption for users a the list class that after
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deleting an object from the list that any other position
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enumerators that you have may be invalid (since the node
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may be gone).
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*/
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__out_opt POSITION CBaseList::GetHeadPositionI() const
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{
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return (POSITION) m_pFirst;
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} // GetHeadPosition
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__out_opt POSITION CBaseList::GetTailPositionI() const
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{
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return (POSITION) m_pLast;
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} // GetTailPosition
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/* Get the number of objects in the list,
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Get the lock before accessing the count.
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Locking may not be entirely necessary but it has the side effect
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of making sure that all operations are complete before we get it.
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So for example if a list is being added to this list then that
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will have completed in full before we continue rather than seeing
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an intermediate albeit valid state
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*/
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int CBaseList::GetCountI() const
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{
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return m_Count;
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} // GetCount
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/* Return the object at rp, update rp to the next object from
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the list or NULL if you have moved over the last object.
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You may still call this function once we return NULL but
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we will continue to return a NULL position value
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*/
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__out void *CBaseList::GetNextI(__inout POSITION& rp) const
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{
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/* have we reached the end of the list */
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if (rp == NULL) {
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return NULL;
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}
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/* Lock the object before continuing */
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void *pObject;
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/* Copy the original position then step on */
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CNode *pn = (CNode *) rp;
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ASSERT(pn != NULL);
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rp = (POSITION) pn->Next();
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/* Get the object at the original position from the list */
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pObject = pn->GetData();
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// ASSERT(pObject != NULL); // NULL pointers in the list are allowed.
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return pObject;
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} //GetNext
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/* Return the object at p.
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Asking for the object at NULL ASSERTs then returns NULL
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The object is NOT locked. The list is not being changed
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in any way. If another thread is busy deleting the object
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then locking would only result in a change from one bad
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behaviour to another.
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*/
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__out_opt void *CBaseList::GetI(__in_opt POSITION p) const
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{
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if (p == NULL) {
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return NULL;
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}
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CNode * pn = (CNode *) p;
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void *pObject = pn->GetData();
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// ASSERT(pObject != NULL); // NULL pointers in the list are allowed.
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return pObject;
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} //Get
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__out void *CBaseList::GetValidI(__in POSITION p) const
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{
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CNode * pn = (CNode *) p;
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void *pObject = pn->GetData();
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// ASSERT(pObject != NULL); // NULL pointers in the list are allowed.
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return pObject;
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} //Get
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/* Return the first position in the list which holds the given pointer.
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Return NULL if it's not found.
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*/
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__out_opt POSITION CBaseList::FindI( __in void * pObj) const
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{
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POSITION pn;
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INTERNALTRAVERSELIST(*this, pn){
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if (GetI(pn)==pObj) {
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return pn;
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}
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}
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return NULL;
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} // Find
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/* Remove the first node in the list (deletes the pointer to its object
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from the list, does not free the object itself).
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Return the pointer to its object or NULL if empty
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*/
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__out_opt void *CBaseList::RemoveHeadI()
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{
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/* All we do is get the _head position and ask for that to be deleted.
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We could special case this since some of the code path checking
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in Remove() is redundant as we know there is no previous
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node for example but it seems to gain little over the
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added complexity
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*/
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return RemoveI((POSITION)m_pFirst);
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} // RemoveHead
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/* Remove the last node in the list (deletes the pointer to its object
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from the list, does not free the object itself).
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Return the pointer to its object or NULL if empty
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*/
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__out_opt void *CBaseList::RemoveTailI()
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{
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/* All we do is get the _tail position and ask for that to be deleted.
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We could special case this since some of the code path checking
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in Remove() is redundant as we know there is no previous
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node for example but it seems to gain little over the
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added complexity
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*/
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return RemoveI((POSITION)m_pLast);
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} // RemoveTail
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/* Remove the pointer to the object in this position from the list.
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Deal with all the chain pointers
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Return a pointer to the object removed from the list.
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The node object that is freed as a result
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of this operation is added to the node cache where
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it can be used again.
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Remove(NULL) is a harmless no-op - but probably is a wart.
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*/
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__out_opt void *CBaseList::RemoveI(__in_opt POSITION pos)
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{
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/* Lock the critical section before continuing */
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// ASSERT (pos!=NULL); // Removing NULL is to be harmless!
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if (pos==NULL) return NULL;
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CNode *pCurrent = (CNode *) pos;
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ASSERT(pCurrent != NULL);
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/* Update the previous node */
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CNode *pNode = pCurrent->Prev();
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if (pNode == NULL) {
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m_pFirst = pCurrent->Next();
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} else {
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pNode->SetNext(pCurrent->Next());
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}
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/* Update the following node */
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pNode = pCurrent->Next();
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if (pNode == NULL) {
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m_pLast = pCurrent->Prev();
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} else {
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pNode->SetPrev(pCurrent->Prev());
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}
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/* Get the object this node was looking after */
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void *pObject = pCurrent->GetData();
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// ASSERT(pObject != NULL); // NULL pointers in the list are allowed.
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/* Try and add the node object to the cache -
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a NULL return code from the cache means we ran out of room.
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The cache size is fixed by a constructor argument when the
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list is created and defaults to DEFAULTCACHE.
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This means that the cache will have room for this many
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node objects. So if you have a list of media samples
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and you know there will never be more than five active at
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any given time of them for example then override the default
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constructor
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*/
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m_Cache.AddToCache(pCurrent);
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/* If the list is empty then reset the list event */
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--m_Count;
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ASSERT(m_Count >= 0);
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return pObject;
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} // Remove
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/* Add this object to the _tail end of our list
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Return the new _tail position.
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*/
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__out_opt POSITION CBaseList::AddTailI(__in void *pObject)
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{
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/* Lock the critical section before continuing */
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CNode *pNode;
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// ASSERT(pObject); // NULL pointers in the list are allowed.
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/* If there is a node objects in the cache then use
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that otherwise we will have to create a new one */
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pNode = (CNode *) m_Cache.RemoveFromCache();
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if (pNode == NULL) {
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pNode = new CNode;
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}
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/* Check we have a valid object */
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if (pNode == NULL) {
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return NULL;
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}
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/* Initialise all the CNode object
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just in case it came from the cache
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*/
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pNode->SetData(pObject);
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pNode->SetNext(NULL);
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pNode->SetPrev(m_pLast);
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if (m_pLast == NULL) {
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m_pFirst = pNode;
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} else {
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m_pLast->SetNext(pNode);
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}
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/* Set the new last node pointer and also increment the number
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of list entries, the critical section is unlocked when we
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exit the function
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*/
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m_pLast = pNode;
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++m_Count;
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return (POSITION) pNode;
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} // AddTail(object)
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/* Add this object to the _head end of our list
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Return the new _head position.
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*/
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__out_opt POSITION CBaseList::AddHeadI(__in void *pObject)
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{
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CNode *pNode;
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// ASSERT(pObject); // NULL pointers in the list are allowed.
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/* If there is a node objects in the cache then use
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that otherwise we will have to create a new one */
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pNode = (CNode *) m_Cache.RemoveFromCache();
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if (pNode == NULL) {
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pNode = new CNode;
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}
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/* Check we have a valid object */
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if (pNode == NULL) {
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return NULL;
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}
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/* Initialise all the CNode object
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just in case it came from the cache
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*/
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pNode->SetData(pObject);
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/* chain it in (set four pointers) */
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pNode->SetPrev(NULL);
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pNode->SetNext(m_pFirst);
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if (m_pFirst == NULL) {
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m_pLast = pNode;
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} else {
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m_pFirst->SetPrev(pNode);
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}
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m_pFirst = pNode;
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++m_Count;
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return (POSITION) pNode;
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} // AddHead(object)
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/* Add all the elements in *pList to the _tail of this list.
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Return TRUE if it all worked, FALSE if it didn't.
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If it fails some elements may have been added.
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*/
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BOOL CBaseList::AddTail(__in CBaseList *pList)
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{
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/* lock the object before starting then enumerate
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each entry in the source list and add them one by one to
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our list (while still holding the object lock)
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Lock the other list too.
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*/
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POSITION pos = pList->GetHeadPositionI();
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while (pos) {
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if (NULL == AddTailI(pList->GetNextI(pos))) {
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return FALSE;
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}
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}
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return TRUE;
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} // AddTail(list)
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/* Add all the elements in *pList to the _head of this list.
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Return TRUE if it all worked, FALSE if it didn't.
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If it fails some elements may have been added.
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*/
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BOOL CBaseList::AddHead(__in CBaseList *pList)
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{
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/* lock the object before starting then enumerate
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each entry in the source list and add them one by one to
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our list (while still holding the object lock)
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Lock the other list too.
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To avoid reversing the list, traverse it backwards.
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*/
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POSITION pos;
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INTERNALREVERSETRAVERSELIST(*pList, pos) {
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if (NULL== AddHeadI(pList->GetValidI(pos))){
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return FALSE;
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}
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}
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return TRUE;
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} // AddHead(list)
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/* Add the object after position p
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p is still valid after the operation.
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AddAfter(NULL,x) adds x to the start - same as AddHead
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Return the position of the new object, NULL if it failed
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*/
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__out_opt POSITION CBaseList::AddAfterI(__in_opt POSITION pos, __in void * pObj)
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{
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if (pos==NULL)
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return AddHeadI(pObj);
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/* As someone else might be furkling with the list -
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Lock the critical section before continuing
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*/
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CNode *pAfter = (CNode *) pos;
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ASSERT(pAfter != NULL);
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if (pAfter==m_pLast)
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return AddTailI(pObj);
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/* set pnode to point to a new node, preferably from the cache */
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CNode *pNode = (CNode *) m_Cache.RemoveFromCache();
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if (pNode == NULL) {
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pNode = new CNode;
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}
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/* Check we have a valid object */
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if (pNode == NULL) {
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return NULL;
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}
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/* Initialise all the CNode object
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just in case it came from the cache
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*/
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pNode->SetData(pObj);
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/* It is to be added to the middle of the list - there is a before
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and after node. Chain it after pAfter, before pBefore.
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*/
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CNode * pBefore = pAfter->Next();
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ASSERT(pBefore != NULL);
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/* chain it in (set four pointers) */
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|
pNode->SetPrev(pAfter);
|
|
pNode->SetNext(pBefore);
|
|
pBefore->SetPrev(pNode);
|
|
pAfter->SetNext(pNode);
|
|
|
|
++m_Count;
|
|
|
|
return (POSITION) pNode;
|
|
|
|
} // AddAfter(object)
|
|
|
|
|
|
|
|
BOOL CBaseList::AddAfter(__in_opt POSITION p, __in CBaseList *pList)
|
|
{
|
|
POSITION pos;
|
|
INTERNALTRAVERSELIST(*pList, pos) {
|
|
/* p follows along the elements being added */
|
|
p = AddAfterI(p, pList->GetValidI(pos));
|
|
if (p==NULL) return FALSE;
|
|
}
|
|
return TRUE;
|
|
} // AddAfter(list)
|
|
|
|
|
|
|
|
/* Mirror images:
|
|
Add the element or list after position p.
|
|
p is still valid after the operation.
|
|
AddBefore(NULL,x) adds x to the end - same as AddTail
|
|
*/
|
|
__out_opt POSITION CBaseList::AddBeforeI(__in_opt POSITION pos, __in void * pObj)
|
|
{
|
|
if (pos==NULL)
|
|
return AddTailI(pObj);
|
|
|
|
/* set pnode to point to a new node, preferably from the cache */
|
|
|
|
CNode *pBefore = (CNode *) pos;
|
|
ASSERT(pBefore != NULL);
|
|
if (pBefore==m_pFirst)
|
|
return AddHeadI(pObj);
|
|
|
|
CNode * pNode = (CNode *) m_Cache.RemoveFromCache();
|
|
if (pNode == NULL) {
|
|
pNode = new CNode;
|
|
}
|
|
|
|
/* Check we have a valid object */
|
|
|
|
if (pNode == NULL) {
|
|
return NULL;
|
|
}
|
|
|
|
/* Initialise all the CNode object
|
|
just in case it came from the cache
|
|
*/
|
|
|
|
pNode->SetData(pObj);
|
|
|
|
/* It is to be added to the middle of the list - there is a before
|
|
and after node. Chain it after pAfter, before pBefore.
|
|
*/
|
|
|
|
CNode * pAfter = pBefore->Prev();
|
|
ASSERT(pAfter != NULL);
|
|
|
|
/* chain it in (set four pointers) */
|
|
pNode->SetPrev(pAfter);
|
|
pNode->SetNext(pBefore);
|
|
pBefore->SetPrev(pNode);
|
|
pAfter->SetNext(pNode);
|
|
|
|
++m_Count;
|
|
|
|
return (POSITION) pNode;
|
|
|
|
} // Addbefore(object)
|
|
|
|
|
|
|
|
BOOL CBaseList::AddBefore(__in_opt POSITION p, __in CBaseList *pList)
|
|
{
|
|
POSITION pos;
|
|
INTERNALREVERSETRAVERSELIST(*pList, pos) {
|
|
/* p follows along the elements being added */
|
|
p = AddBeforeI(p, pList->GetValidI(pos));
|
|
if (p==NULL) return FALSE;
|
|
}
|
|
return TRUE;
|
|
} // AddBefore(list)
|
|
|
|
|
|
|
|
/* 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
|
|
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 CBaseList::MoveToTail
|
|
(__in_opt POSITION pos, __in CBaseList *pList)
|
|
{
|
|
/* Algorithm:
|
|
Note that the elements (including their order) in the concatenation
|
|
of *pList to the _head of *this is invariant.
|
|
1. Count elements to be moved
|
|
2. Join *pList onto the _head of this to make one long chain
|
|
3. Set first/Last pointers in *this and *pList
|
|
4. Break the chain at the new place
|
|
5. Adjust counts
|
|
6. Set/Reset any events
|
|
*/
|
|
|
|
if (pos==NULL) return TRUE; // no-op. Eliminates special cases later.
|
|
|
|
|
|
/* Make cMove the number of nodes to move */
|
|
CNode * p = (CNode *)pos;
|
|
int cMove = 0; // number of nodes to move
|
|
while(p!=NULL) {
|
|
p = p->Prev();
|
|
++cMove;
|
|
}
|
|
|
|
|
|
/* Join the two chains together */
|
|
if (pList->m_pLast!=NULL)
|
|
pList->m_pLast->SetNext(m_pFirst);
|
|
if (m_pFirst!=NULL)
|
|
m_pFirst->SetPrev(pList->m_pLast);
|
|
|
|
|
|
/* set first and last pointers */
|
|
p = (CNode *)pos;
|
|
|
|
if (pList->m_pFirst==NULL)
|
|
pList->m_pFirst = m_pFirst;
|
|
m_pFirst = p->Next();
|
|
if (m_pFirst==NULL)
|
|
m_pLast = NULL;
|
|
pList->m_pLast = p;
|
|
|
|
|
|
/* Break the chain after p to create the new pieces */
|
|
if (m_pFirst!=NULL)
|
|
m_pFirst->SetPrev(NULL);
|
|
p->SetNext(NULL);
|
|
|
|
|
|
/* Adjust the counts */
|
|
m_Count -= cMove;
|
|
pList->m_Count += cMove;
|
|
|
|
return TRUE;
|
|
|
|
} // MoveToTail
|
|
|
|
|
|
|
|
/* Mirror image of MoveToTail:
|
|
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
|
|
Return TRUE if it all worked, FALSE if it didn't.
|
|
|
|
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
|
|
foo->MoveToHead(foo->GetHeadPosition, bar);
|
|
concatenates foo onto the start of bar and empties foo.
|
|
*/
|
|
BOOL CBaseList::MoveToHead
|
|
(__in_opt POSITION pos, __in CBaseList *pList)
|
|
{
|
|
|
|
/* See the comments on the algorithm in MoveToTail */
|
|
|
|
if (pos==NULL) return TRUE; // no-op. Eliminates special cases later.
|
|
|
|
/* Make cMove the number of nodes to move */
|
|
CNode * p = (CNode *)pos;
|
|
int cMove = 0; // number of nodes to move
|
|
while(p!=NULL) {
|
|
p = p->Next();
|
|
++cMove;
|
|
}
|
|
|
|
|
|
/* Join the two chains together */
|
|
if (pList->m_pFirst!=NULL)
|
|
pList->m_pFirst->SetPrev(m_pLast);
|
|
if (m_pLast!=NULL)
|
|
m_pLast->SetNext(pList->m_pFirst);
|
|
|
|
|
|
/* set first and last pointers */
|
|
p = (CNode *)pos;
|
|
|
|
|
|
if (pList->m_pLast==NULL)
|
|
pList->m_pLast = m_pLast;
|
|
|
|
m_pLast = p->Prev();
|
|
if (m_pLast==NULL)
|
|
m_pFirst = NULL;
|
|
pList->m_pFirst = p;
|
|
|
|
|
|
/* Break the chain after p to create the new pieces */
|
|
if (m_pLast!=NULL)
|
|
m_pLast->SetNext(NULL);
|
|
p->SetPrev(NULL);
|
|
|
|
|
|
/* Adjust the counts */
|
|
m_Count -= cMove;
|
|
pList->m_Count += cMove;
|
|
|
|
return TRUE;
|
|
|
|
} // MoveToHead
|
|
|
|
|
|
|
|
/* Reverse the order of the [pointers to] objects in *this
|
|
*/
|
|
void CBaseList::Reverse()
|
|
{
|
|
/* algorithm:
|
|
The obvious booby trap is that you flip pointers around and lose
|
|
addressability to the node that you are going to process next.
|
|
The easy way to avoid this is do do one chain at a time.
|
|
|
|
Run along the forward chain,
|
|
For each node, set the reverse pointer to the one ahead of us.
|
|
The reverse chain is now a copy of the old forward chain, including
|
|
the NULL termination.
|
|
|
|
Run along the reverse chain (i.e. old forward chain again)
|
|
For each node set the forward pointer of the node ahead to point back
|
|
to the one we're standing on.
|
|
The first node needs special treatment,
|
|
it's new forward pointer is NULL.
|
|
Finally set the First/Last pointers
|
|
|
|
*/
|
|
CNode * p;
|
|
|
|
// Yes we COULD use a traverse, but it would look funny!
|
|
p = m_pFirst;
|
|
while (p!=NULL) {
|
|
CNode * q;
|
|
q = p->Next();
|
|
p->SetNext(p->Prev());
|
|
p->SetPrev(q);
|
|
p = q;
|
|
}
|
|
|
|
p = m_pFirst;
|
|
m_pFirst = m_pLast;
|
|
m_pLast = p;
|
|
|
|
|
|
#if 0 // old version
|
|
|
|
if (m_pFirst==NULL) return; // empty list
|
|
if (m_pFirst->Next()==NULL) return; // single node list
|
|
|
|
|
|
/* run along forward chain */
|
|
for ( p = m_pFirst
|
|
; p!=NULL
|
|
; p = p->Next()
|
|
){
|
|
p->SetPrev(p->Next());
|
|
}
|
|
|
|
|
|
/* special case first element */
|
|
m_pFirst->SetNext(NULL); // fix the old first element
|
|
|
|
|
|
/* run along new reverse chain i.e. old forward chain again */
|
|
for ( p = m_pFirst // start at the old first element
|
|
; p->Prev()!=NULL // while there's a node still to be set
|
|
; p = p->Prev() // work in the same direction as before
|
|
){
|
|
p->Prev()->SetNext(p);
|
|
}
|
|
|
|
|
|
/* fix forward and reverse pointers
|
|
- the triple XOR swap would work but all the casts look hideous */
|
|
p = m_pFirst;
|
|
m_pFirst = m_pLast;
|
|
m_pLast = p;
|
|
#endif
|
|
|
|
} // Reverse
|