//========= Copyright © 1996-2005, Valve Corporation, All rights reserved. ============// // // Purpose: // //=============================================================================// #ifndef RESOURCEMANAGER_H #define RESOURCEMANAGER_H #ifdef _WIN32 #pragma once #endif #include "tier0/threadtools.h" #include "utlmultilist.h" #include "utlvector.h" FORWARD_DECLARE_HANDLE( memhandle_t ); #define INVALID_MEMHANDLE ((memhandle_t)0xffffffff) class CDataManagerBase { public: // public API // ----------------------------------------------------------------------------- // memhandle_t CreateResource( params ) // implemented by derived class void DestroyResource( memhandle_t handle ); // type-safe implementation in derived class //void *LockResource( memhandle_t handle ); int UnlockResource( memhandle_t handle ); void TouchResource( memhandle_t handle ); void MarkAsStale( memhandle_t handle ); // move to head of LRU int LockCount( memhandle_t handle ); int BreakLock( memhandle_t handle ); int BreakAllLocks(); // HACKHACK: For convenience - offers no lock protection // type-safe implementation in derived class //void *GetResource_NoLock( memhandle_t handle ); unsigned int TargetSize(); unsigned int AvailableSize(); unsigned int UsedSize(); void NotifySizeChanged( memhandle_t handle, unsigned int oldSize, unsigned int newSize ); void SetTargetSize( unsigned int targetSize ); // NOTE: flush is equivalent to Destroy unsigned int FlushAllUnlocked(); unsigned int FlushToTargetSize(); unsigned int FlushAll(); unsigned int Purge( unsigned int nBytesToPurge ); unsigned int EnsureCapacity( unsigned int size ); // Thread lock virtual void Lock() {} virtual bool TryLock() { return true; } virtual void Unlock() {} // Iteration // ----------------------------------------------------------------------------- void SetFreeOnDestruct( bool value ) { m_freeOnDestruct = value; } // Debugging only!!!! void GetLRUHandleList( CUtlVector< memhandle_t >& list ); void GetLockHandleList( CUtlVector< memhandle_t >& list ); protected: // derived class must call these to implement public API unsigned short CreateHandle( bool bCreateLocked ); memhandle_t StoreResourceInHandle( unsigned short memoryIndex, void *pStore, unsigned int realSize ); void *GetResource_NoLock( memhandle_t handle ); void *GetResource_NoLockNoLRUTouch( memhandle_t handle ); void *LockResource( memhandle_t handle ); void *LockResourceReturnCount( int *pCount, memhandle_t handle ); // NOTE: you must call this from the destructor of the derived class! (will assert otherwise) void FreeAllLists() { FlushAll(); m_listsAreFreed = true; } CDataManagerBase( unsigned int maxSize ); virtual ~CDataManagerBase(); inline unsigned int MemTotal_Inline() const { return m_targetMemorySize; } inline unsigned int MemAvailable_Inline() const { return m_targetMemorySize - m_memUsed; } inline unsigned int MemUsed_Inline() const { return m_memUsed; } // Implemented by derived class: virtual void DestroyResourceStorage( void * ) = 0; virtual unsigned int GetRealSize( void * ) = 0; memhandle_t ToHandle( unsigned short index ); unsigned short FromHandle( memhandle_t handle ); void TouchByIndex( unsigned short memoryIndex ); void * GetForFreeByIndex( unsigned short memoryIndex ); // One of these is stored per active allocation struct resource_lru_element_t { resource_lru_element_t() { lockCount = 0; serial = 1; pStore = 0; } unsigned short lockCount; unsigned short serial; void *pStore; }; unsigned int m_targetMemorySize; unsigned int m_memUsed; CUtlMultiList< resource_lru_element_t, unsigned short > m_memoryLists; unsigned short m_lruList; unsigned short m_lockList; unsigned short m_freeList; unsigned short m_listsAreFreed : 1; unsigned short m_freeOnDestruct : 1; unsigned short m_unused : 14; }; template< class STORAGE_TYPE, class CREATE_PARAMS, class LOCK_TYPE = STORAGE_TYPE *, class MUTEX_TYPE = CThreadNullMutex> class CDataManager : public CDataManagerBase { typedef CDataManagerBase BaseClass; public: CDataManager( unsigned int size = (unsigned)-1 ) : BaseClass(size) {} ~CDataManager() { // NOTE: This must be called in all implementations of CDataManager if ( m_freeOnDestruct ) { FreeAllLists(); } } // Use GetData() to translate pointer to LOCK_TYPE LOCK_TYPE LockResource( memhandle_t hMem ) { void *pLock = BaseClass::LockResource( hMem ); if ( pLock ) { return StoragePointer(pLock)->GetData(); } return NULL; } LOCK_TYPE LockResourceReturnCount( int *pCount, memhandle_t hMem ) { void *pLock = BaseClass::LockResourceReturnCount( pCount, hMem ); if ( pLock ) { return StoragePointer(pLock)->GetData(); } return NULL; } // Use GetData() to translate pointer to LOCK_TYPE LOCK_TYPE GetResource_NoLock( memhandle_t hMem ) { void *pLock = const_cast(BaseClass::GetResource_NoLock( hMem )); if ( pLock ) { return StoragePointer(pLock)->GetData(); } return NULL; } // Use GetData() to translate pointer to LOCK_TYPE // Doesn't touch the memory LRU LOCK_TYPE GetResource_NoLockNoLRUTouch( memhandle_t hMem ) { void *pLock = const_cast(BaseClass::GetResource_NoLockNoLRUTouch( hMem )); if ( pLock ) { return StoragePointer(pLock)->GetData(); } return NULL; } // Wrapper to match implementation of allocation with typed storage & alloc params. memhandle_t CreateResource( const CREATE_PARAMS &createParams, bool bCreateLocked = false ) { BaseClass::EnsureCapacity(STORAGE_TYPE::EstimatedSize(createParams)); STORAGE_TYPE *pStore = STORAGE_TYPE::CreateResource( createParams ); AUTO_LOCK_( CDataManagerBase, *this ); unsigned short memoryIndex = BaseClass::CreateHandle( bCreateLocked ); return BaseClass::StoreResourceInHandle( memoryIndex, pStore, pStore->Size() ); } // Iteration. Must lock first memhandle_t GetFirstUnlocked() { unsigned node = m_memoryLists.Head(m_lruList); if ( node == m_memoryLists.InvalidIndex() ) { return INVALID_MEMHANDLE; } return ToHandle( node ); } memhandle_t GetFirstLocked() { unsigned node = m_memoryLists.Head(m_lockList); if ( node == m_memoryLists.InvalidIndex() ) { return INVALID_MEMHANDLE; } return ToHandle( node ); } memhandle_t GetNext( memhandle_t hPrev ) { if ( hPrev == INVALID_MEMHANDLE ) { return INVALID_MEMHANDLE; } unsigned short iNext = m_memoryLists.Next( FromHandle( hPrev ) ); if ( iNext == m_memoryLists.InvalidIndex() ) { return INVALID_MEMHANDLE; } return ToHandle( iNext ); } MUTEX_TYPE &AccessMutex() { return m_mutex; } virtual void Lock() { m_mutex.Lock(); } virtual bool TryLock() { return m_mutex.TryLock(); } virtual void Unlock() { m_mutex.Unlock(); } private: STORAGE_TYPE *StoragePointer( void *pMem ) { return static_cast(pMem); } virtual void DestroyResourceStorage( void *pStore ) { StoragePointer(pStore)->DestroyResource(); } virtual unsigned int GetRealSize( void *pStore ) { return StoragePointer(pStore)->Size(); } MUTEX_TYPE m_mutex; }; //----------------------------------------------------------------------------- inline unsigned short CDataManagerBase::FromHandle( memhandle_t handle ) { unsigned int fullWord = (unsigned int)reinterpret_cast( handle ); unsigned short serial = fullWord>>16; unsigned short index = fullWord & 0xFFFF; index--; if ( m_memoryLists.IsValidIndex(index) && m_memoryLists[index].serial == serial ) return index; return m_memoryLists.InvalidIndex(); } inline int CDataManagerBase::LockCount( memhandle_t handle ) { Lock(); int result = 0; unsigned short memoryIndex = FromHandle(handle); if ( memoryIndex != m_memoryLists.InvalidIndex() ) { result = m_memoryLists[memoryIndex].lockCount; } Unlock(); return result; } #endif // RESOURCEMANAGER_H