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/*
SuperCollider real time audio synthesis system
Copyright (c) 2002 James McCartney. All rights reserved.
http://www.audiosynth.com
This program is free software; you can redistribute it and/or modify
it under the terms of the GNU General Public License as published by
the Free Software Foundation; either version 2 of the License, or
(at your option) any later version.
This program is distributed in the hope that it will be useful,
but WITHOUT ANY WARRANTY; without even the implied warranty of
MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the
GNU General Public License for more details.
You should have received a copy of the GNU General Public License
along with this program; if not, write to the Free Software
Foundation, Inc., 59 Temple Place, Suite 330, Boston, MA 02111-1307 USA
*/
/*
This is based on Doug Lea's allocator but rewritten so I can read and understand it...
also features of free all-at-once pools are added.
Now uses 16 byte alignment, which does increase the minimum allocation size to 32 bytes
including the overhead.
Improved bit block scanning by using a count leading zeroes instruction.
*/
#ifndef _AllocPool_
#define _AllocPool_
#include "SC_List.h"
#include "clz.h"
#include <stdlib.h>
const int kNumAllocBins = 128;
const int kNumSmallBins = 64;
const int kMaxSmallBin = kNumSmallBins - 1;
const int kBinWidth = 8;
const int kMaxSmallBinSize = kNumSmallBins * kBinWidth;
const int kBinBlockWidth = 4;
const int kBinBlockMask = kBinBlockWidth - 1;
const size_t kAlign = 16;
const size_t kAlignMask = kAlign - 1;
const size_t kChunkFree = 0;
const size_t kChunkInUse = 1;
const size_t kSizeBits = ~kChunkInUse;
class AllocChunk;
class AllocPool;
typedef AllocChunk *AllocChunkPtr;
typedef Link<AllocChunk> AllocBin;
typedef AllocBin* AllocBinPtr;
class AllocChunk : public Link<AllocChunk>
{
friend class AllocPool;
size_t Size()
{ return mSize & kSizeBits; }
size_t PrevSize()
{ return mPrevSize & kSizeBits; }
AllocChunkPtr ChunkAtOffset(size_t inSize)
{ return AllocChunkPtr((char*)this + inSize); }
AllocChunkPtr NextChunk()
{ return ChunkAtOffset(Size()); }
AllocChunkPtr PrevChunk()
{ return ChunkAtOffset(-PrevSize()); }
bool InUse()
{ return (bool)(mSize & kChunkInUse); }
bool PrevInUse()
{ return (bool)(mPrevSize & kChunkInUse); }
void SetSizeFree(size_t inSize)
{ mSize = ChunkAtOffset(inSize)->mPrevSize = inSize; }
void SetSizeInUse(size_t inSize)
{ mSize = ChunkAtOffset(inSize)->mPrevSize = inSize | kChunkInUse; }
void SetNeighborsInUse(size_t inOffset)
{ mPrevSize = ChunkAtOffset(inOffset)->mSize = kChunkInUse; }
bool IsArea()
{ return mPrevSize == kChunkInUse && NextChunk()->mSize == kChunkInUse; }
void* ToPtr()
{ return (void*)((char*)this + sizeof(AllocChunk)); }
size_t mPrevSize;
size_t mSize;
};
class AllocArea;
typedef AllocArea* AllocAreaPtr;
class AllocAreaHdr /* for size calculations */
{
protected:
friend class AllocPool;
AllocAreaPtr mPrev, mNext;
size_t mSize;
void *mUnalignedPointerToThis;
};
class AllocArea : public AllocAreaHdr
{
public:
void SanityCheck();
private:
friend class AllocPool;
AllocChunk mChunk;
};
const size_t kMinAllocSize = 2 * kAlign;
// FIXME: add kAlign to overhead? <sk>
const size_t kAreaOverhead = sizeof(AllocAreaHdr) + 2 * sizeof(AllocChunk);
typedef void* (*NewAreaFunc)(size_t size);
typedef void (*FreeAreaFunc)(void *);
class AllocPool
{
public:
AllocPool(NewAreaFunc allocArea, FreeAreaFunc freeArea,
size_t areaInitSize, size_t areaMoreSize);
~AllocPool();
void Reinit();
void *Alloc(size_t inBytes);
void *Realloc(void* inPtr, size_t inBytes);
void Free(void* inPtr);
void FreeAll();
void FreeAllInternal();
// debugging
size_t TotalFree();
size_t LargestFreeChunk();
void DoCheckPool();
void DoCheckInUseChunk(AllocChunkPtr p);
static AllocChunkPtr MemToChunk(void *inPtr)
{ return (AllocChunkPtr)((char*)(inPtr) - sizeof(AllocChunk)); }
private:
void InitAlloc();
void InitBins();
AllocAreaPtr NewArea(size_t inAreaSize);
void FreeArea(AllocChunkPtr chunk);
// debugging
void DoCheckArea(AllocAreaPtr area);
void DoCheckBin(AllocChunkPtr bin, long idx);
void DoCheckChunk(AllocChunkPtr p);
void DoCheckFreeChunk(AllocChunkPtr p);
void DoCheckAllocedChunk(AllocChunkPtr p, size_t s);
void DoGarbageFill(AllocChunkPtr p);
void DoGarbageFill(AllocChunkPtr p, long size);
// inlines
static size_t RequestToSize(size_t inReqSize)
{
size_t sizePlusOverhead = inReqSize + sizeof(AllocChunk);
if (sizePlusOverhead <= kMinAllocSize) return kMinAllocSize;
else return (sizePlusOverhead + kAlignMask) & ~kAlignMask;
}
static int SmallBinIndex(size_t inSize)
{ return inSize >> 4; }
static int BinIndex2(size_t inSize)
{
return
((inSize < 1024) ? (inSize>>4):
(inSize < 2048) ? 56 + (inSize>>7):
(inSize < 4096) ? 64 + (inSize>>8):
(inSize < 8192) ? 72 + (inSize>>9):
(inSize < 16384) ? 80 + (inSize>>10):
(inSize < 32768) ? 88 + (inSize>>11):
(inSize < 65536) ? 96 + (inSize>>12):
(inSize < 131072) ? 104 + (inSize>>13):
(inSize < 262144) ? 112 + (inSize>>14):127);
}
static int BinIndex(size_t inSize)
{
if (inSize < 1024) return inSize >> 4;
if (inSize >= 262144) return 127;
int bits = 28 - CLZ(inSize);
return (bits << 3) + (inSize >> bits) ;
}
void MarkBinBlock(int inIndex)
{
unsigned long word = inIndex >> 5;
unsigned long bitPosition = inIndex & 31;
unsigned long bitValue = 1L << bitPosition;
mBinBlocks[word] |= bitValue;
}
void ClearBinBlock(int inIndex)
{
unsigned long word = inIndex >> 5;
unsigned long bitPosition = inIndex & 31;
unsigned long bitValue = 1L << bitPosition;
mBinBlocks[word] &= ~bitValue;
}
int NextFullBin(int inStartingBinIndex)
{
if (inStartingBinIndex >= 128) return -1;
int word = inStartingBinIndex >> 5;
int bitPosition = inStartingBinIndex & 31;
unsigned long bitValue = 1L << bitPosition;
unsigned long binBits = mBinBlocks[word];
if (binBits >= bitValue) {
binBits = (~(bitValue - 1) & binBits);
} else {
for (++word; word<4 && !mBinBlocks[word]; ++word) {}
if (word==4) return -1;
binBits = mBinBlocks[word];
}
bitPosition = CTZ((int32)binBits);
return (word << 5) + bitPosition;
}
void LinkFree(AllocChunkPtr inChunk);
/*
{
size_t size = inChunk->Size();
int index = BinIndex(size);
AllocChunkPtr bin = mBins + index;
if (index < kNumSmallBins || bin->IsEmpty()) {
inChunk->InsertAfter(bin);
MarkBinBlock(index);
} else {
AllocChunkPtr link = bin->Next();
while (link != bin && size < link->Size()) link = link->Next();
inChunk->InsertBefore(link);
}
}
*/
void UnlinkFree(AllocChunkPtr inChunk)
{
inChunk->RemoveLeaveDangling();
size_t size = inChunk->Size();
int index = BinIndex(size);
AllocChunkPtr bin = mBins + index;
if (bin->IsEmpty()) ClearBinBlock(index);
}
AllocChunk mBins[kNumAllocBins];
AllocAreaPtr mAreas;
NewAreaFunc mAllocArea;
FreeAreaFunc mFreeArea;
size_t mAreaInitSize, mAreaMoreSize;
unsigned long mBinBlocks[4];
};
#endif
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