mirror of
https://github.com/libretro/scummvm.git
synced 2024-12-11 11:45:21 +00:00
471 lines
12 KiB
C++
471 lines
12 KiB
C++
/* ScummVM - Graphic Adventure Engine
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*
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* ScummVM is the legal property of its developers, whose names
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* are too numerous to list here. Please refer to the COPYRIGHT
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* file distributed with this source distribution.
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*
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* This program is free software; you can redistribute it and/or
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* modify it under the terms of the GNU General Public License
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* as published by the Free Software Foundation; either version 2
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* of the License, or (at your option) any later version.
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* This program is distributed in the hope that it will be useful,
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* but WITHOUT ANY WARRANTY; without even the implied warranty of
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* MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the
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* GNU General Public License for more details.
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* You should have received a copy of the GNU General Public License
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* along with this program; if not, write to the Free Software
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* Foundation, Inc., 51 Franklin Street, Fifth Floor, Boston, MA 02110-1301, USA.
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*
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* This file contains the handle based Memory Manager code.
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*/
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#include "tinsel/heapmem.h"
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#include "tinsel/timers.h" // For DwGetCurrentTime
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#include "tinsel/tinsel.h"
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namespace Tinsel {
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#define NUM_MNODES 192 // the number of memory management nodes (was 128, then 192)
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// internal allocation flags
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#define DWM_USED 0x0001 ///< the objects memory block is in use
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#define DWM_DISCARDED 0x0002 ///< the objects memory block has been discarded
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#define DWM_LOCKED 0x0004 ///< the objects memory block is locked
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#define DWM_SENTINEL 0x0008 ///< the objects memory block is a sentinel
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struct MEM_NODE {
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MEM_NODE *pNext; // link to the next node in the list
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MEM_NODE *pPrev; // link to the previous node in the list
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uint8 *pBaseAddr; // base address of the memory object
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long size; // size of the memory object
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uint32 lruTime; // time when memory object was last accessed
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int flags; // allocation attributes
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};
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// Specifies the total amount of memory required for DW1 demo, DW1, or DW2 respectively.
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// Currently this is set at 5MB for the DW1 demo and DW1 and 10MB for DW2
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// This could probably be reduced somewhat
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// If the memory is not enough, the engine throws an "Out of memory" error in handle.cpp inside LockMem()
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static const uint32 MemoryPoolSize[3] = {5 * 1024 * 1024, 5 * 1024 * 1024, 10 * 1024 * 1024};
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// FIXME: Avoid non-const global vars
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// list of all memory nodes
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MEM_NODE mnodeList[NUM_MNODES];
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// pointer to the linked list of free mnodes
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static MEM_NODE *pFreeMemNodes;
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// list of all fixed memory nodes
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MEM_NODE s_fixedMnodesList[5];
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// the mnode heap sentinel
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static MEM_NODE heapSentinel;
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//
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static MEM_NODE *AllocMemNode();
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#ifdef DEBUG
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static void MemoryStats() {
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int usedNodes = 0;
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int allocedNodes = 0;
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int lockedNodes = 0;
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int lockedSize = 0;
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int totalSize = 0;
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const MEM_NODE *pHeap = &heapSentinel;
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MEM_NODE *pCur;
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for (pCur = pHeap->pNext; pCur != pHeap; pCur = pCur->pNext) {
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usedNodes++;
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totalSize += pCur->size;
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if (pCur->flags)
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allocedNodes++;
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if (pCur->flags & DWM_LOCKED) {
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lockedNodes++;
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lockedSize += pCur->size;
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}
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}
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debug("%d nodes used, %d alloced, %d locked; %d bytes locked, %d used",
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usedNodes, allocedNodes, lockedNodes, lockedSize, totalSize);
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}
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#endif
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/**
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* Initializes the memory manager.
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*/
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void MemoryInit() {
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// place first node on free list
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pFreeMemNodes = mnodeList;
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// link all other objects after first
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memset(mnodeList, 0, sizeof(mnodeList));
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for (int i = 1; i < NUM_MNODES; i++) {
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mnodeList[i - 1].pNext = mnodeList + i;
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}
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// null the last mnode
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mnodeList[NUM_MNODES - 1].pNext = NULL;
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// clear list of fixed memory nodes
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memset(s_fixedMnodesList, 0, sizeof(s_fixedMnodesList));
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// set cyclic links to the sentinel
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heapSentinel.pPrev = &heapSentinel;
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heapSentinel.pNext = &heapSentinel;
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// flag sentinel as locked
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heapSentinel.flags = DWM_LOCKED | DWM_SENTINEL;
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// store the current heap size in the sentinel
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uint32 size = MemoryPoolSize[0];
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if (TinselVersion == TINSEL_V1) size = MemoryPoolSize[1];
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else if (TinselVersion == TINSEL_V2) size = MemoryPoolSize[2];
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heapSentinel.size = size;
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}
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/**
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* Deinitializes the memory manager.
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*/
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void MemoryDeinit() {
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const MEM_NODE *pHeap = &heapSentinel;
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MEM_NODE *pCur;
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pCur = s_fixedMnodesList;
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for (int i = 0; i < ARRAYSIZE(s_fixedMnodesList); ++i, ++pCur) {
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free(pCur->pBaseAddr);
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pCur->pBaseAddr = 0;
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}
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for (pCur = pHeap->pNext; pCur != pHeap; pCur = pCur->pNext) {
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free(pCur->pBaseAddr);
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pCur->pBaseAddr = 0;
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}
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}
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/**
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* Allocate a mnode from the free list.
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*/
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static MEM_NODE *AllocMemNode() {
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// get the first free mnode
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MEM_NODE *pMemNode = pFreeMemNodes;
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// make sure a mnode is available
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assert(pMemNode); // Out of memory nodes
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// the next free mnode
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pFreeMemNodes = pMemNode->pNext;
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// wipe out the mnode
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memset(pMemNode, 0, sizeof(MEM_NODE));
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// return new mnode
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return pMemNode;
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}
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/**
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* Return a mnode back to the free list.
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* @param pMemNode Node of the memory object
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*/
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void FreeMemNode(MEM_NODE *pMemNode) {
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// validate mnode pointer
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assert(pMemNode >= mnodeList && pMemNode <= mnodeList + NUM_MNODES - 1);
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// place free list in mnode next
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pMemNode->pNext = pFreeMemNodes;
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// add mnode to top of free list
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pFreeMemNodes = pMemNode;
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}
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/**
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* Tries to make space for the specified number of bytes on the specified heap.
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* @param size Number of bytes to free up
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* @return true if any blocks were discarded, false otherwise
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*/
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static bool HeapCompact(long size) {
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const MEM_NODE *pHeap = &heapSentinel;
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MEM_NODE *pCur, *pOldest;
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uint32 oldest; // time of the oldest discardable block
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while (heapSentinel.size < size) {
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// find the oldest discardable block
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oldest = DwGetCurrentTime();
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pOldest = NULL;
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for (pCur = pHeap->pNext; pCur != pHeap; pCur = pCur->pNext) {
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if (pCur->flags == DWM_USED) {
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// found a non-discarded discardable block
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if (pCur->lruTime < oldest) {
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oldest = pCur->lruTime;
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pOldest = pCur;
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}
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}
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}
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if (pOldest)
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// discard the oldest block
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MemoryDiscard(pOldest);
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else
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// cannot discard any blocks
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return false;
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}
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// we have freed enough memory
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return true;
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}
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/**
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* Allocates the specified number of bytes from the heap.
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* @param flags Allocation attributes
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* @param size Number of bytes to allocate
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*/
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static MEM_NODE *MemoryAlloc(long size) {
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MEM_NODE *pHeap = &heapSentinel;
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#ifdef SCUMM_NEED_ALIGNMENT
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const int alignPadding = sizeof(void*) - 1;
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size = (size + alignPadding) & ~alignPadding; //round up to nearest multiple of sizeof(void*), this ensures the addresses that are returned are alignment-safe.
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#endif
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// compact the heap to make up room for 'size' bytes, if necessary
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if (!HeapCompact(size))
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return 0;
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// success! we may allocate a new node of the right size
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// Allocate a node.
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MEM_NODE *pNode = AllocMemNode();
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// Allocate memory for the node.
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pNode->pBaseAddr = (byte *)malloc(size);
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// Verify that we got the memory.
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// TODO: If this fails, we should first try to compact the heap some further.
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assert(pNode->pBaseAddr);
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// Subtract size of new block from total
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heapSentinel.size -= size;
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#ifdef DEBUG
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MemoryStats();
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#endif
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// Set flags, LRU time and size
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pNode->flags = DWM_USED;
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pNode->lruTime = DwGetCurrentTime() + 1;
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pNode->size = size;
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// set mnode at the end of the list
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pNode->pPrev = pHeap->pPrev;
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pNode->pNext = pHeap;
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// fix links to this mnode
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pHeap->pPrev->pNext = pNode;
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pHeap->pPrev = pNode;
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return pNode;
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}
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/**
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* Allocate a discarded MEM_NODE. Actual memory can be assigned to it
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* by using MemoryReAlloc().
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*/
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MEM_NODE *MemoryNoAlloc() {
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MEM_NODE *pHeap = &heapSentinel;
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// chain a discarded node onto the end of the heap
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MEM_NODE *pNode = AllocMemNode();
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pNode->flags = DWM_USED | DWM_DISCARDED;
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pNode->lruTime = DwGetCurrentTime();
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pNode->size = 0;
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// set mnode at the end of the list
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pNode->pPrev = pHeap->pPrev;
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pNode->pNext = pHeap;
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// fix links to this mnode
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pHeap->pPrev->pNext = pNode;
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pHeap->pPrev = pNode;
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// return the discarded node
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return pNode;
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}
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/**
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* Allocate a fixed block of data.
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* @todo We really should keep track of the allocated pointers,
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* so that we can discard them later on, when the engine quits.
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*/
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MEM_NODE *MemoryAllocFixed(long size) {
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#ifdef SCUMM_NEED_ALIGNMENT
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const int alignPadding = sizeof(void*) - 1;
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size = (size + alignPadding) & ~alignPadding; //round up to nearest multiple of sizeof(void*), this ensures the addresses that are returned are alignment-safe.
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#endif
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// Search for a free entry in s_fixedMnodesList
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MEM_NODE *pNode = s_fixedMnodesList;
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for (int i = 0; i < ARRAYSIZE(s_fixedMnodesList); ++i, ++pNode) {
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if (!pNode->pBaseAddr) {
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pNode->pNext = 0;
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pNode->pPrev = 0;
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pNode->pBaseAddr = (byte *)malloc(size);
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pNode->size = size;
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pNode->lruTime = DwGetCurrentTime() + 1;
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pNode->flags = DWM_USED;
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// Subtract size of new block from total
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heapSentinel.size -= size;
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return pNode;
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}
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}
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return 0;
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}
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/**
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* Discards the specified memory object.
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* @param pMemNode Node of the memory object
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*/
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void MemoryDiscard(MEM_NODE *pMemNode) {
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// validate mnode pointer
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assert(pMemNode >= mnodeList && pMemNode <= mnodeList + NUM_MNODES - 1);
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// object must be in use and locked
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assert((pMemNode->flags & (DWM_USED | DWM_LOCKED)) == DWM_USED);
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// discard it if it isn't already
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if ((pMemNode->flags & DWM_DISCARDED) == 0) {
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// free memory
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free(pMemNode->pBaseAddr);
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heapSentinel.size += pMemNode->size;
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#ifdef DEBUG
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MemoryStats();
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#endif
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// mark the node as discarded
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pMemNode->flags |= DWM_DISCARDED;
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pMemNode->pBaseAddr = NULL;
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pMemNode->size = 0;
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}
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}
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/**
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* Locks a memory object and returns a pointer to the first byte
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* of the objects memory block.
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* @param pMemNode Node of the memory object
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*/
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void *MemoryLock(MEM_NODE *pMemNode) {
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// make sure memory object is not already locked
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assert((pMemNode->flags & DWM_LOCKED) == 0);
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// check for a discarded or null memory object
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if ((pMemNode->flags & DWM_DISCARDED) || pMemNode->size == 0)
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return NULL;
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// set the lock flag
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pMemNode->flags |= DWM_LOCKED;
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#ifdef DEBUG
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MemoryStats();
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#endif
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// return memory objects base address
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return pMemNode->pBaseAddr;
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}
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/**
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* Unlocks a memory object.
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* @param pMemNode Node of the memory object
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*/
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void MemoryUnlock(MEM_NODE *pMemNode) {
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// make sure memory object is already locked
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assert(pMemNode->flags & DWM_LOCKED);
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// clear the lock flag
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pMemNode->flags &= ~DWM_LOCKED;
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#ifdef DEBUG
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MemoryStats();
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#endif
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// update the LRU time
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pMemNode->lruTime = DwGetCurrentTime();
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}
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/**
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* Changes the size of a specified memory object and re-allocate it if necessary.
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* @param pMemNode Node of the memory object
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* @param size New size of block
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*/
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void MemoryReAlloc(MEM_NODE *pMemNode, long size) {
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MEM_NODE *pNew;
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// validate mnode pointer
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assert(pMemNode >= mnodeList && pMemNode <= mnodeList + NUM_MNODES - 1);
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// align the size to machine boundary requirements
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size = (size + sizeof(void *) - 1) & ~(sizeof(void *) - 1);
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// validate the size
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assert(size);
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if (size != pMemNode->size) {
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// make sure memory object is discarded and not locked
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assert(pMemNode->flags == (DWM_USED | DWM_DISCARDED));
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assert(pMemNode->size == 0);
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// unlink the mnode from the current heap
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pMemNode->pNext->pPrev = pMemNode->pPrev;
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pMemNode->pPrev->pNext = pMemNode->pNext;
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// allocate a new node
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pNew = MemoryAlloc(size);
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// make sure memory allocated
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assert(pNew != NULL);
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// copy the node to the current node
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memcpy(pMemNode, pNew, sizeof(MEM_NODE));
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// relink the mnode into the list
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pMemNode->pPrev->pNext = pMemNode;
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pMemNode->pNext->pPrev = pMemNode;
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// free the new node
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FreeMemNode(pNew);
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}
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assert(pMemNode->pBaseAddr);
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}
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/**
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* Touch a memory object by updating its LRU time.
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* @param pMemNode Node of the memory object
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*/
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void MemoryTouch(MEM_NODE *pMemNode) {
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// update the LRU time
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pMemNode->lruTime = DwGetCurrentTime();
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}
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uint8 *MemoryDeref(MEM_NODE *pMemNode) {
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return pMemNode->pBaseAddr;
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}
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} // End of namespace Tinsel
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