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-rw-r--r--indra/llcommon/llmemory.cpp1919
1 files changed, 1913 insertions, 6 deletions
diff --git a/indra/llcommon/llmemory.cpp b/indra/llcommon/llmemory.cpp
index 21d1c84d69..bb7998c0a8 100644
--- a/indra/llcommon/llmemory.cpp
+++ b/indra/llcommon/llmemory.cpp
@@ -26,14 +26,13 @@
#include "linden_common.h"
-#include "llmemory.h"
-#if MEM_TRACK_MEM
+//#if MEM_TRACK_MEM
#include "llthread.h"
-#endif
+//#endif
#if defined(LL_WINDOWS)
-# include <windows.h>
+//# include <windows.h>
# include <psapi.h>
#elif defined(LL_DARWIN)
# include <sys/types.h>
@@ -43,10 +42,24 @@
# include <unistd.h>
#endif
+#include "llmemory.h"
+
+#include "llsys.h"
+#include "llframetimer.h"
//----------------------------------------------------------------------------
//static
char* LLMemory::reserveMem = 0;
+U32 LLMemory::sAvailPhysicalMemInKB = U32_MAX ;
+U32 LLMemory::sMaxPhysicalMemInKB = 0;
+U32 LLMemory::sAllocatedMemInKB = 0;
+U32 LLMemory::sAllocatedPageSizeInKB = 0 ;
+U32 LLMemory::sMaxHeapSizeInKB = U32_MAX ;
+BOOL LLMemory::sEnableMemoryFailurePrevention = FALSE;
+
+#if __DEBUG_PRIVATE_MEM__
+LLPrivateMemoryPoolManager::mem_allocation_info_t LLPrivateMemoryPoolManager::sMemAllocationTracker;
+#endif
//static
void LLMemory::initClass()
@@ -71,6 +84,175 @@ void LLMemory::freeReserve()
reserveMem = NULL;
}
+//static
+void LLMemory::initMaxHeapSizeGB(F32 max_heap_size_gb, BOOL prevent_heap_failure)
+{
+ sMaxHeapSizeInKB = (U32)(max_heap_size_gb * 1024 * 1024) ;
+ sEnableMemoryFailurePrevention = prevent_heap_failure ;
+}
+
+//static
+void LLMemory::updateMemoryInfo()
+{
+#if LL_WINDOWS
+ HANDLE self = GetCurrentProcess();
+ PROCESS_MEMORY_COUNTERS counters;
+
+ if (!GetProcessMemoryInfo(self, &counters, sizeof(counters)))
+ {
+ llwarns << "GetProcessMemoryInfo failed" << llendl;
+ return ;
+ }
+
+ sAllocatedMemInKB = (U32)(counters.WorkingSetSize / 1024) ;
+ sAllocatedPageSizeInKB = (U32)(counters.PagefileUsage / 1024) ;
+
+ U32 avail_phys, avail_virtual;
+ LLMemoryInfo::getAvailableMemoryKB(avail_phys, avail_virtual) ;
+ sMaxPhysicalMemInKB = llmin(avail_phys + sAllocatedMemInKB, sMaxHeapSizeInKB);
+
+ if(sMaxPhysicalMemInKB > sAllocatedMemInKB)
+ {
+ sAvailPhysicalMemInKB = sMaxPhysicalMemInKB - sAllocatedMemInKB ;
+ }
+ else
+ {
+ sAvailPhysicalMemInKB = 0 ;
+ }
+#else
+ //not valid for other systems for now.
+ sAllocatedMemInKB = (U32)(LLMemory::getCurrentRSS() / 1024) ;
+ sMaxPhysicalMemInKB = U32_MAX ;
+ sAvailPhysicalMemInKB = U32_MAX ;
+#endif
+
+ return ;
+}
+
+//
+//this function is to test if there is enough space with the size in the virtual address space.
+//it does not do any real allocation
+//if success, it returns the address where the memory chunk can fit in;
+//otherwise it returns NULL.
+//
+//static
+void* LLMemory::tryToAlloc(void* address, U32 size)
+{
+#if LL_WINDOWS
+ address = VirtualAlloc(address, size, MEM_RESERVE | MEM_TOP_DOWN, PAGE_NOACCESS) ;
+ if(address)
+ {
+ if(!VirtualFree(address, 0, MEM_RELEASE))
+ {
+ llerrs << "error happens when free some memory reservation." << llendl ;
+ }
+ }
+ return address ;
+#else
+ return (void*)0x01 ; //skip checking
+#endif
+}
+
+//static
+void LLMemory::logMemoryInfo(BOOL update)
+{
+ if(update)
+ {
+ updateMemoryInfo() ;
+ }
+
+ llinfos << "Current allocated physical memory(KB): " << sAllocatedMemInKB << llendl ;
+ llinfos << "Current allocated page size (KB): " << sAllocatedPageSizeInKB << llendl ;
+ llinfos << "Current availabe physical memory(KB): " << sAvailPhysicalMemInKB << llendl ;
+ llinfos << "Current max usable memory(KB): " << sMaxPhysicalMemInKB << llendl ;
+
+ llinfos << "--- private pool information -- " << llendl ;
+ llinfos << "Total reserved (KB): " << LLPrivateMemoryPoolManager::getInstance()->mTotalReservedSize / 1024 << llendl ;
+ llinfos << "Total allocated (KB): " << LLPrivateMemoryPoolManager::getInstance()->mTotalAllocatedSize / 1024 << llendl ;
+}
+
+//return 0: everything is normal;
+//return 1: the memory pool is low, but not in danger;
+//return -1: the memory pool is in danger, is about to crash.
+//static
+bool LLMemory::isMemoryPoolLow()
+{
+ static const U32 LOW_MEMEOY_POOL_THRESHOLD_KB = 64 * 1024 ; //64 MB for emergency use
+ const static U32 MAX_SIZE_CHECKED_MEMORY_BLOCK = 64 * 1024 * 1024 ; //64 MB
+ static void* last_reserved_address = NULL ;
+
+ if(!sEnableMemoryFailurePrevention)
+ {
+ return false ; //no memory failure prevention.
+ }
+
+ if(sAvailPhysicalMemInKB < (LOW_MEMEOY_POOL_THRESHOLD_KB >> 2)) //out of physical memory
+ {
+ return true ;
+ }
+
+ if(sAllocatedPageSizeInKB + (LOW_MEMEOY_POOL_THRESHOLD_KB >> 2) > sMaxHeapSizeInKB) //out of virtual address space.
+ {
+ return true ;
+ }
+
+ bool is_low = (S32)(sAvailPhysicalMemInKB < LOW_MEMEOY_POOL_THRESHOLD_KB ||
+ sAllocatedPageSizeInKB + LOW_MEMEOY_POOL_THRESHOLD_KB > sMaxHeapSizeInKB) ;
+
+ //check the virtual address space fragmentation
+ if(!is_low)
+ {
+ if(!last_reserved_address)
+ {
+ last_reserved_address = LLMemory::tryToAlloc(last_reserved_address, MAX_SIZE_CHECKED_MEMORY_BLOCK) ;
+ }
+ else
+ {
+ last_reserved_address = LLMemory::tryToAlloc(last_reserved_address, MAX_SIZE_CHECKED_MEMORY_BLOCK) ;
+ if(!last_reserved_address) //failed, try once more
+ {
+ last_reserved_address = LLMemory::tryToAlloc(last_reserved_address, MAX_SIZE_CHECKED_MEMORY_BLOCK) ;
+ }
+ }
+
+ is_low = !last_reserved_address ; //allocation failed
+ }
+
+ return is_low ;
+}
+
+//static
+U32 LLMemory::getAvailableMemKB()
+{
+ return sAvailPhysicalMemInKB ;
+}
+
+//static
+U32 LLMemory::getMaxMemKB()
+{
+ return sMaxPhysicalMemInKB ;
+}
+
+//static
+U32 LLMemory::getAllocatedMemKB()
+{
+ return sAllocatedMemInKB ;
+}
+
+void* ll_allocate (size_t size)
+{
+ if (size == 0)
+ {
+ llwarns << "Null allocation" << llendl;
+ }
+ void *p = malloc(size);
+ if (p == NULL)
+ {
+ LLMemory::freeReserve();
+ llerrs << "Out of memory Error" << llendl;
+ }
+ return p;
+}
//----------------------------------------------------------------------------
@@ -237,7 +419,7 @@ U64 LLMemory::getCurrentRSS()
U32 LLMemory::getWorkingSetSize()
{
- return 0 ;
+ return 0;
}
#endif
@@ -258,7 +440,7 @@ LLMemTracker::LLMemTracker()
mDrawnIndex = 0 ;
mPaused = FALSE ;
- mMutexp = new LLMutex(NULL) ;
+ mMutexp = new LLMutex() ;
mStringBuffer = new char*[128] ;
mStringBuffer[0] = new char[mCapacity * 128] ;
for(S32 i = 1 ; i < mCapacity ; i++)
@@ -376,3 +558,1728 @@ const char* LLMemTracker::getNextLine()
#endif //MEM_TRACK_MEM
//--------------------------------------------------------------------------------------------------
+
+//--------------------------------------------------------------------------------------------------
+//--------------------------------------------------------------------------------------------------
+//minimum slot size and minimal slot size interval
+const U32 ATOMIC_MEM_SLOT = 16 ; //bytes
+
+//minimum block sizes (page size) for small allocation, medium allocation, large allocation
+const U32 MIN_BLOCK_SIZES[LLPrivateMemoryPool::SUPER_ALLOCATION] = {2 << 10, 4 << 10, 16 << 10} ; //
+
+//maximum block sizes for small allocation, medium allocation, large allocation
+const U32 MAX_BLOCK_SIZES[LLPrivateMemoryPool::SUPER_ALLOCATION] = {64 << 10, 1 << 20, 4 << 20} ;
+
+//minimum slot sizes for small allocation, medium allocation, large allocation
+const U32 MIN_SLOT_SIZES[LLPrivateMemoryPool::SUPER_ALLOCATION] = {ATOMIC_MEM_SLOT, 2 << 10, 512 << 10};
+
+//maximum slot sizes for small allocation, medium allocation, large allocation
+const U32 MAX_SLOT_SIZES[LLPrivateMemoryPool::SUPER_ALLOCATION] = {(2 << 10) - ATOMIC_MEM_SLOT, (512 - 2) << 10, 4 << 20};
+
+//size of a block with multiple slots can not exceed CUT_OFF_SIZE
+const U32 CUT_OFF_SIZE = (64 << 10) ; //64 KB
+
+//max number of slots in a block
+const U32 MAX_NUM_SLOTS_IN_A_BLOCK = llmin(MIN_BLOCK_SIZES[0] / ATOMIC_MEM_SLOT, ATOMIC_MEM_SLOT * 8) ;
+
+//-------------------------------------------------------------
+//align val to be integer times of ATOMIC_MEM_SLOT
+U32 align(U32 val)
+{
+ U32 aligned = (val / ATOMIC_MEM_SLOT) * ATOMIC_MEM_SLOT ;
+ if(aligned < val)
+ {
+ aligned += ATOMIC_MEM_SLOT ;
+ }
+
+ return aligned ;
+}
+
+//-------------------------------------------------------------
+//class LLPrivateMemoryPool::LLMemoryBlock
+//-------------------------------------------------------------
+//
+//each memory block could fit for two page sizes: 0.75 * mSlotSize, which starts from the beginning of the memory chunk and grow towards the end of the
+//the block; another is mSlotSize, which starts from the end of the block and grows towards the beginning of the block.
+//
+LLPrivateMemoryPool::LLMemoryBlock::LLMemoryBlock()
+{
+ //empty
+}
+
+LLPrivateMemoryPool::LLMemoryBlock::~LLMemoryBlock()
+{
+ //empty
+}
+
+//create and initialize a memory block
+void LLPrivateMemoryPool::LLMemoryBlock::init(char* buffer, U32 buffer_size, U32 slot_size)
+{
+ mBuffer = buffer ;
+ mBufferSize = buffer_size ;
+ mSlotSize = slot_size ;
+ mTotalSlots = buffer_size / mSlotSize ;
+
+ llassert_always(buffer_size / mSlotSize <= MAX_NUM_SLOTS_IN_A_BLOCK) ; //max number is 128
+
+ mAllocatedSlots = 0 ;
+ mDummySize = 0 ;
+
+ //init the bit map.
+ //mark free bits
+ if(mTotalSlots > 32) //reserve extra space from mBuffer to store bitmap if needed.
+ {
+ mDummySize = ATOMIC_MEM_SLOT ;
+ mTotalSlots -= (mDummySize + mSlotSize - 1) / mSlotSize ;
+ mUsageBits = 0 ;
+
+ S32 usage_bit_len = (mTotalSlots + 31) / 32 ;
+
+ for(S32 i = 0 ; i < usage_bit_len - 1 ; i++)
+ {
+ *((U32*)mBuffer + i) = 0 ;
+ }
+ for(S32 i = usage_bit_len - 1 ; i < mDummySize / sizeof(U32) ; i++)
+ {
+ *((U32*)mBuffer + i) = 0xffffffff ;
+ }
+
+ if(mTotalSlots & 31)
+ {
+ *((U32*)mBuffer + usage_bit_len - 2) = (0xffffffff << (mTotalSlots & 31)) ;
+ }
+ }
+ else//no extra bitmap space reserved
+ {
+ mUsageBits = 0 ;
+ if(mTotalSlots & 31)
+ {
+ mUsageBits = (0xffffffff << (mTotalSlots & 31)) ;
+ }
+ }
+
+ mSelf = this ;
+ mNext = NULL ;
+ mPrev = NULL ;
+
+ llassert_always(mTotalSlots > 0) ;
+}
+
+//mark this block to be free with the memory [mBuffer, mBuffer + mBufferSize).
+void LLPrivateMemoryPool::LLMemoryBlock::setBuffer(char* buffer, U32 buffer_size)
+{
+ mBuffer = buffer ;
+ mBufferSize = buffer_size ;
+ mSelf = NULL ;
+ mTotalSlots = 0 ; //set the block is free.
+}
+
+//reserve a slot
+char* LLPrivateMemoryPool::LLMemoryBlock::allocate()
+{
+ llassert_always(mAllocatedSlots < mTotalSlots) ;
+
+ //find a free slot
+ U32* bits = NULL ;
+ U32 k = 0 ;
+ if(mUsageBits != 0xffffffff)
+ {
+ bits = &mUsageBits ;
+ }
+ else if(mDummySize > 0)//go to extra space
+ {
+ for(S32 i = 0 ; i < mDummySize / sizeof(U32); i++)
+ {
+ if(*((U32*)mBuffer + i) != 0xffffffff)
+ {
+ bits = (U32*)mBuffer + i ;
+ k = i + 1 ;
+ break ;
+ }
+ }
+ }
+ S32 idx = 0 ;
+ U32 tmp = *bits ;
+ for(; tmp & 1 ; tmp >>= 1, idx++) ;
+
+ //set the slot reserved
+ if(!idx)
+ {
+ *bits |= 1 ;
+ }
+ else
+ {
+ *bits |= (1 << idx) ;
+ }
+
+ mAllocatedSlots++ ;
+
+ return mBuffer + mDummySize + (k * 32 + idx) * mSlotSize ;
+}
+
+//free a slot
+void LLPrivateMemoryPool::LLMemoryBlock::freeMem(void* addr)
+{
+ //bit index
+ U32 idx = ((U32)addr - (U32)mBuffer - mDummySize) / mSlotSize ;
+
+ U32* bits = &mUsageBits ;
+ if(idx >= 32)
+ {
+ bits = (U32*)mBuffer + (idx - 32) / 32 ;
+ }
+
+ //reset the bit
+ if(idx & 31)
+ {
+ *bits &= ~(1 << (idx & 31)) ;
+ }
+ else
+ {
+ *bits &= ~1 ;
+ }
+
+ mAllocatedSlots-- ;
+}
+
+//for debug use: reset the entire bitmap.
+void LLPrivateMemoryPool::LLMemoryBlock::resetBitMap()
+{
+ for(S32 i = 0 ; i < mDummySize / sizeof(U32) ; i++)
+ {
+ *((U32*)mBuffer + i) = 0 ;
+ }
+ mUsageBits = 0 ;
+}
+//-------------------------------------------------------------------
+//class LLMemoryChunk
+//--------------------------------------------------------------------
+LLPrivateMemoryPool::LLMemoryChunk::LLMemoryChunk()
+{
+ //empty
+}
+
+LLPrivateMemoryPool::LLMemoryChunk::~LLMemoryChunk()
+{
+ //empty
+}
+
+//create and init a memory chunk
+void LLPrivateMemoryPool::LLMemoryChunk::init(char* buffer, U32 buffer_size, U32 min_slot_size, U32 max_slot_size, U32 min_block_size, U32 max_block_size)
+{
+ mBuffer = buffer ;
+ mBufferSize = buffer_size ;
+ mAlloatedSize = 0 ;
+
+ mMetaBuffer = mBuffer + sizeof(LLMemoryChunk) ;
+
+ mMinBlockSize = min_block_size; //page size
+ mMinSlotSize = min_slot_size;
+ mMaxSlotSize = max_slot_size ;
+ mBlockLevels = mMaxSlotSize / mMinSlotSize ;
+ mPartitionLevels = max_block_size / mMinBlockSize + 1 ;
+
+ S32 max_num_blocks = (buffer_size - sizeof(LLMemoryChunk) - mBlockLevels * sizeof(LLMemoryBlock*) - mPartitionLevels * sizeof(LLMemoryBlock*)) /
+ (mMinBlockSize + sizeof(LLMemoryBlock)) ;
+ //meta data space
+ mBlocks = (LLMemoryBlock*)mMetaBuffer ; //space reserved for all memory blocks.
+ mAvailBlockList = (LLMemoryBlock**)((char*)mBlocks + sizeof(LLMemoryBlock) * max_num_blocks) ;
+ mFreeSpaceList = (LLMemoryBlock**)((char*)mAvailBlockList + sizeof(LLMemoryBlock*) * mBlockLevels) ;
+
+ //data buffer, which can be used for allocation
+ mDataBuffer = (char*)mFreeSpaceList + sizeof(LLMemoryBlock*) * mPartitionLevels ;
+
+ //alignmnet
+ mDataBuffer = mBuffer + align(mDataBuffer - mBuffer) ;
+
+ //init
+ for(U32 i = 0 ; i < mBlockLevels; i++)
+ {
+ mAvailBlockList[i] = NULL ;
+ }
+ for(U32 i = 0 ; i < mPartitionLevels ; i++)
+ {
+ mFreeSpaceList[i] = NULL ;
+ }
+
+ //assign the entire chunk to the first block
+ mBlocks[0].mPrev = NULL ;
+ mBlocks[0].mNext = NULL ;
+ mBlocks[0].setBuffer(mDataBuffer, buffer_size - (mDataBuffer - mBuffer)) ;
+ addToFreeSpace(&mBlocks[0]) ;
+
+ mNext = NULL ;
+ mPrev = NULL ;
+}
+
+//static
+U32 LLPrivateMemoryPool::LLMemoryChunk::getMaxOverhead(U32 data_buffer_size, U32 min_slot_size,
+ U32 max_slot_size, U32 min_block_size, U32 max_block_size)
+{
+ //for large allocations, reserve some extra memory for meta data to avoid wasting much
+ if(data_buffer_size / min_slot_size < 64) //large allocations
+ {
+ U32 overhead = sizeof(LLMemoryChunk) + (data_buffer_size / min_block_size) * sizeof(LLMemoryBlock) +
+ sizeof(LLMemoryBlock*) * (max_slot_size / min_slot_size) + sizeof(LLMemoryBlock*) * (max_block_size / min_block_size + 1) ;
+
+ //round to integer times of min_block_size
+ overhead = ((overhead + min_block_size - 1) / min_block_size) * min_block_size ;
+ return overhead ;
+ }
+ else
+ {
+ return 0 ; //do not reserve extra overhead if for small allocations
+ }
+}
+
+char* LLPrivateMemoryPool::LLMemoryChunk::allocate(U32 size)
+{
+ if(mMinSlotSize > size)
+ {
+ size = mMinSlotSize ;
+ }
+ if(mAlloatedSize + size > mBufferSize - (mDataBuffer - mBuffer))
+ {
+ return NULL ; //no enough space in this chunk.
+ }
+
+ char* p = NULL ;
+ U32 blk_idx = getBlockLevel(size);
+
+ LLMemoryBlock* blk = NULL ;
+
+ //check if there is free block available
+ if(mAvailBlockList[blk_idx])
+ {
+ blk = mAvailBlockList[blk_idx] ;
+ p = blk->allocate() ;
+
+ if(blk->isFull())
+ {
+ popAvailBlockList(blk_idx) ;
+ }
+ }
+
+ //ask for a new block
+ if(!p)
+ {
+ blk = addBlock(blk_idx) ;
+ if(blk)
+ {
+ p = blk->allocate() ;
+
+ if(blk->isFull())
+ {
+ popAvailBlockList(blk_idx) ;
+ }
+ }
+ }
+
+ //ask for space from larger blocks
+ if(!p)
+ {
+ for(S32 i = blk_idx + 1 ; i < mBlockLevels; i++)
+ {
+ if(mAvailBlockList[i])
+ {
+ blk = mAvailBlockList[i] ;
+ p = blk->allocate() ;
+
+ if(blk->isFull())
+ {
+ popAvailBlockList(i) ;
+ }
+ break ;
+ }
+ }
+ }
+
+ if(p && blk)
+ {
+ mAlloatedSize += blk->getSlotSize() ;
+ }
+ return p ;
+}
+
+void LLPrivateMemoryPool::LLMemoryChunk::freeMem(void* addr)
+{
+ U32 blk_idx = getPageIndex((U32)addr) ;
+ LLMemoryBlock* blk = (LLMemoryBlock*)(mMetaBuffer + blk_idx * sizeof(LLMemoryBlock)) ;
+ blk = blk->mSelf ;
+
+ bool was_full = blk->isFull() ;
+ blk->freeMem(addr) ;
+ mAlloatedSize -= blk->getSlotSize() ;
+
+ if(blk->empty())
+ {
+ removeBlock(blk) ;
+ }
+ else if(was_full)
+ {
+ addToAvailBlockList(blk) ;
+ }
+}
+
+bool LLPrivateMemoryPool::LLMemoryChunk::empty()
+{
+ return !mAlloatedSize ;
+}
+
+bool LLPrivateMemoryPool::LLMemoryChunk::containsAddress(const char* addr) const
+{
+ return (U32)mBuffer <= (U32)addr && (U32)mBuffer + mBufferSize > (U32)addr ;
+}
+
+//debug use
+void LLPrivateMemoryPool::LLMemoryChunk::dump()
+{
+#if 0
+ //sanity check
+ //for(S32 i = 0 ; i < mBlockLevels ; i++)
+ //{
+ // LLMemoryBlock* blk = mAvailBlockList[i] ;
+ // while(blk)
+ // {
+ // blk_list.push_back(blk) ;
+ // blk = blk->mNext ;
+ // }
+ //}
+ for(S32 i = 0 ; i < mPartitionLevels ; i++)
+ {
+ LLMemoryBlock* blk = mFreeSpaceList[i] ;
+ while(blk)
+ {
+ blk_list.push_back(blk) ;
+ blk = blk->mNext ;
+ }
+ }
+
+ std::sort(blk_list.begin(), blk_list.end(), LLMemoryBlock::CompareAddress());
+
+ U32 total_size = blk_list[0]->getBufferSize() ;
+ for(U32 i = 1 ; i < blk_list.size(); i++)
+ {
+ total_size += blk_list[i]->getBufferSize() ;
+ if((U32)blk_list[i]->getBuffer() < (U32)blk_list[i-1]->getBuffer() + blk_list[i-1]->getBufferSize())
+ {
+ llerrs << "buffer corrupted." << llendl ;
+ }
+ }
+
+ llassert_always(total_size + mMinBlockSize >= mBufferSize - ((U32)mDataBuffer - (U32)mBuffer)) ;
+
+ U32 blk_num = (mBufferSize - (mDataBuffer - mBuffer)) / mMinBlockSize ;
+ for(U32 i = 0 ; i < blk_num ; )
+ {
+ LLMemoryBlock* blk = &mBlocks[i] ;
+ if(blk->mSelf)
+ {
+ U32 end = blk->getBufferSize() / mMinBlockSize ;
+ for(U32 j = 0 ; j < end ; j++)
+ {
+ llassert_always(blk->mSelf == blk || !blk->mSelf) ;
+ }
+ i += end ;
+ }
+ else
+ {
+ llerrs << "gap happens" << llendl ;
+ }
+ }
+#endif
+#if 0
+ llinfos << "---------------------------" << llendl ;
+ llinfos << "Chunk buffer: " << (U32)getBuffer() << " size: " << getBufferSize() << llendl ;
+
+ llinfos << "available blocks ... " << llendl ;
+ for(S32 i = 0 ; i < mBlockLevels ; i++)
+ {
+ LLMemoryBlock* blk = mAvailBlockList[i] ;
+ while(blk)
+ {
+ llinfos << "blk buffer " << (U32)blk->getBuffer() << " size: " << blk->getBufferSize() << llendl ;
+ blk = blk->mNext ;
+ }
+ }
+
+ llinfos << "free blocks ... " << llendl ;
+ for(S32 i = 0 ; i < mPartitionLevels ; i++)
+ {
+ LLMemoryBlock* blk = mFreeSpaceList[i] ;
+ while(blk)
+ {
+ llinfos << "blk buffer " << (U32)blk->getBuffer() << " size: " << blk->getBufferSize() << llendl ;
+ blk = blk->mNext ;
+ }
+ }
+#endif
+}
+
+//compute the size for a block, the size is round to integer times of mMinBlockSize.
+U32 LLPrivateMemoryPool::LLMemoryChunk::calcBlockSize(U32 slot_size)
+{
+ //
+ //Note: we try to make a block to have 32 slots if the size is not over 32 pages
+ //32 is the number of bits of an integer in a 32-bit system
+ //
+
+ U32 block_size;
+ U32 cut_off_size = llmin(CUT_OFF_SIZE, (U32)(mMinBlockSize << 5)) ;
+
+ if((slot_size << 5) <= mMinBlockSize)//for small allocations, return one page
+ {
+ block_size = mMinBlockSize ;
+ }
+ else if(slot_size >= cut_off_size)//for large allocations, return one-slot block
+ {
+ block_size = (slot_size / mMinBlockSize) * mMinBlockSize ;
+ if(block_size < slot_size)
+ {
+ block_size += mMinBlockSize ;
+ }
+ }
+ else //medium allocations
+ {
+ if((slot_size << 5) >= cut_off_size)
+ {
+ block_size = cut_off_size ;
+ }
+ else
+ {
+ block_size = ((slot_size << 5) / mMinBlockSize) * mMinBlockSize ;
+ }
+ }
+
+ llassert_always(block_size >= slot_size) ;
+
+ return block_size ;
+}
+
+//create a new block in the chunk
+LLPrivateMemoryPool::LLMemoryBlock* LLPrivateMemoryPool::LLMemoryChunk::addBlock(U32 blk_idx)
+{
+ U32 slot_size = mMinSlotSize * (blk_idx + 1) ;
+ U32 preferred_block_size = calcBlockSize(slot_size) ;
+ U16 idx = getPageLevel(preferred_block_size);
+ LLMemoryBlock* blk = NULL ;
+
+ if(mFreeSpaceList[idx])//if there is free slot for blk_idx
+ {
+ blk = createNewBlock(mFreeSpaceList[idx], preferred_block_size, slot_size, blk_idx) ;
+ }
+ else if(mFreeSpaceList[mPartitionLevels - 1]) //search free pool
+ {
+ blk = createNewBlock(mFreeSpaceList[mPartitionLevels - 1], preferred_block_size, slot_size, blk_idx) ;
+ }
+ else //search for other non-preferred but enough space slot.
+ {
+ S32 min_idx = 0 ;
+ if(slot_size > mMinBlockSize)
+ {
+ min_idx = getPageLevel(slot_size) ;
+ }
+ for(S32 i = (S32)idx - 1 ; i >= min_idx ; i--) //search the small slots first
+ {
+ if(mFreeSpaceList[i])
+ {
+ U32 new_preferred_block_size = mFreeSpaceList[i]->getBufferSize();
+ new_preferred_block_size = (new_preferred_block_size / mMinBlockSize) * mMinBlockSize ; //round to integer times of mMinBlockSize.
+
+ //create a NEW BLOCK THERE.
+ if(new_preferred_block_size >= slot_size) //at least there is space for one slot.
+ {
+
+ blk = createNewBlock(mFreeSpaceList[i], new_preferred_block_size, slot_size, blk_idx) ;
+ }
+ break ;
+ }
+ }
+
+ if(!blk)
+ {
+ for(U16 i = idx + 1 ; i < mPartitionLevels - 1; i++) //search the large slots
+ {
+ if(mFreeSpaceList[i])
+ {
+ //create a NEW BLOCK THERE.
+ blk = createNewBlock(mFreeSpaceList[i], preferred_block_size, slot_size, blk_idx) ;
+ break ;
+ }
+ }
+ }
+ }
+
+ return blk ;
+}
+
+//create a new block at the designed location
+LLPrivateMemoryPool::LLMemoryBlock* LLPrivateMemoryPool::LLMemoryChunk::createNewBlock(LLMemoryBlock* blk, U32 buffer_size, U32 slot_size, U32 blk_idx)
+{
+ //unlink from the free space
+ removeFromFreeSpace(blk) ;
+
+ //check the rest space
+ U32 new_free_blk_size = blk->getBufferSize() - buffer_size ;
+ if(new_free_blk_size < mMinBlockSize) //can not partition the memory into size smaller than mMinBlockSize
+ {
+ new_free_blk_size = 0 ; //discard the last small extra space.
+ }
+
+ //add the rest space back to the free list
+ if(new_free_blk_size > 0) //blk still has free space
+ {
+ LLMemoryBlock* next_blk = blk + (buffer_size / mMinBlockSize) ;
+ next_blk->mPrev = NULL ;
+ next_blk->mNext = NULL ;
+ next_blk->setBuffer(blk->getBuffer() + buffer_size, new_free_blk_size) ;
+ addToFreeSpace(next_blk) ;
+ }
+
+ blk->init(blk->getBuffer(), buffer_size, slot_size) ;
+ //insert to the available block list...
+ mAvailBlockList[blk_idx] = blk ;
+
+ //mark the address map: all blocks covered by this block space pointing back to this block.
+ U32 end = (buffer_size / mMinBlockSize) ;
+ for(U32 i = 1 ; i < end ; i++)
+ {
+ (blk + i)->mSelf = blk ;
+ }
+
+ return blk ;
+}
+
+//delete a block, release the block to the free pool.
+void LLPrivateMemoryPool::LLMemoryChunk::removeBlock(LLMemoryBlock* blk)
+{
+ //remove from the available block list
+ if(blk->mPrev)
+ {
+ blk->mPrev->mNext = blk->mNext ;
+ }
+ if(blk->mNext)
+ {
+ blk->mNext->mPrev = blk->mPrev ;
+ }
+ U32 blk_idx = getBlockLevel(blk->getSlotSize());
+ if(mAvailBlockList[blk_idx] == blk)
+ {
+ mAvailBlockList[blk_idx] = blk->mNext ;
+ }
+
+ blk->mNext = NULL ;
+ blk->mPrev = NULL ;
+
+ //mark it free
+ blk->setBuffer(blk->getBuffer(), blk->getBufferSize()) ;
+
+#if 1
+ //merge blk with neighbors if possible
+ if(blk->getBuffer() > mDataBuffer) //has the left neighbor
+ {
+ if((blk - 1)->mSelf->isFree())
+ {
+ LLMemoryBlock* left_blk = (blk - 1)->mSelf ;
+ removeFromFreeSpace((blk - 1)->mSelf);
+ left_blk->setBuffer(left_blk->getBuffer(), left_blk->getBufferSize() + blk->getBufferSize()) ;
+ blk = left_blk ;
+ }
+ }
+ if(blk->getBuffer() + blk->getBufferSize() <= mBuffer + mBufferSize - mMinBlockSize) //has the right neighbor
+ {
+ U32 d = blk->getBufferSize() / mMinBlockSize ;
+ if((blk + d)->isFree())
+ {
+ LLMemoryBlock* right_blk = blk + d ;
+ removeFromFreeSpace(blk + d) ;
+ blk->setBuffer(blk->getBuffer(), blk->getBufferSize() + right_blk->getBufferSize()) ;
+ }
+ }
+#endif
+
+ addToFreeSpace(blk) ;
+
+ return ;
+}
+
+//the top block in the list is full, pop it out of the list
+void LLPrivateMemoryPool::LLMemoryChunk::popAvailBlockList(U32 blk_idx)
+{
+ if(mAvailBlockList[blk_idx])
+ {
+ LLMemoryBlock* next = mAvailBlockList[blk_idx]->mNext ;
+ if(next)
+ {
+ next->mPrev = NULL ;
+ }
+ mAvailBlockList[blk_idx]->mPrev = NULL ;
+ mAvailBlockList[blk_idx]->mNext = NULL ;
+ mAvailBlockList[blk_idx] = next ;
+ }
+}
+
+//add the block back to the free pool
+void LLPrivateMemoryPool::LLMemoryChunk::addToFreeSpace(LLMemoryBlock* blk)
+{
+ llassert_always(!blk->mPrev) ;
+ llassert_always(!blk->mNext) ;
+
+ U16 free_idx = blk->getBufferSize() / mMinBlockSize - 1;
+
+ (blk + free_idx)->mSelf = blk ; //mark the end pointing back to the head.
+ free_idx = llmin(free_idx, (U16)(mPartitionLevels - 1)) ;
+
+ blk->mNext = mFreeSpaceList[free_idx] ;
+ if(mFreeSpaceList[free_idx])
+ {
+ mFreeSpaceList[free_idx]->mPrev = blk ;
+ }
+ mFreeSpaceList[free_idx] = blk ;
+ blk->mPrev = NULL ;
+ blk->mSelf = blk ;
+
+ return ;
+}
+
+//remove the space from the free pool
+void LLPrivateMemoryPool::LLMemoryChunk::removeFromFreeSpace(LLMemoryBlock* blk)
+{
+ U16 free_idx = blk->getBufferSize() / mMinBlockSize - 1;
+ free_idx = llmin(free_idx, (U16)(mPartitionLevels - 1)) ;
+
+ if(mFreeSpaceList[free_idx] == blk)
+ {
+ mFreeSpaceList[free_idx] = blk->mNext ;
+ }
+ if(blk->mPrev)
+ {
+ blk->mPrev->mNext = blk->mNext ;
+ }
+ if(blk->mNext)
+ {
+ blk->mNext->mPrev = blk->mPrev ;
+ }
+ blk->mNext = NULL ;
+ blk->mPrev = NULL ;
+ blk->mSelf = NULL ;
+
+ return ;
+}
+
+void LLPrivateMemoryPool::LLMemoryChunk::addToAvailBlockList(LLMemoryBlock* blk)
+{
+ llassert_always(!blk->mPrev) ;
+ llassert_always(!blk->mNext) ;
+
+ U32 blk_idx = getBlockLevel(blk->getSlotSize());
+
+ blk->mNext = mAvailBlockList[blk_idx] ;
+ if(blk->mNext)
+ {
+ blk->mNext->mPrev = blk ;
+ }
+ blk->mPrev = NULL ;
+ mAvailBlockList[blk_idx] = blk ;
+
+ return ;
+}
+
+U32 LLPrivateMemoryPool::LLMemoryChunk::getPageIndex(U32 addr)
+{
+ return (addr - (U32)mDataBuffer) / mMinBlockSize ;
+}
+
+//for mAvailBlockList
+U32 LLPrivateMemoryPool::LLMemoryChunk::getBlockLevel(U32 size)
+{
+ llassert(size >= mMinSlotSize && size <= mMaxSlotSize) ;
+
+ //start from 0
+ return (size + mMinSlotSize - 1) / mMinSlotSize - 1 ;
+}
+
+//for mFreeSpaceList
+U16 LLPrivateMemoryPool::LLMemoryChunk::getPageLevel(U32 size)
+{
+ //start from 0
+ U16 level = size / mMinBlockSize - 1 ;
+ if(level >= mPartitionLevels)
+ {
+ level = mPartitionLevels - 1 ;
+ }
+ return level ;
+}
+
+//-------------------------------------------------------------------
+//class LLPrivateMemoryPool
+//--------------------------------------------------------------------
+const U32 CHUNK_SIZE = 4 << 20 ; //4 MB
+const U32 LARGE_CHUNK_SIZE = 4 * CHUNK_SIZE ; //16 MB
+LLPrivateMemoryPool::LLPrivateMemoryPool(S32 type, U32 max_pool_size) :
+ mMutexp(NULL),
+ mReservedPoolSize(0),
+ mHashFactor(1),
+ mType(type),
+ mMaxPoolSize(max_pool_size)
+{
+ if(type == STATIC_THREADED || type == VOLATILE_THREADED)
+ {
+ mMutexp = new LLMutex(NULL) ;
+ }
+
+ for(S32 i = 0 ; i < SUPER_ALLOCATION ; i++)
+ {
+ mChunkList[i] = NULL ;
+ }
+
+ mNumOfChunks = 0 ;
+}
+
+LLPrivateMemoryPool::~LLPrivateMemoryPool()
+{
+ destroyPool();
+ delete mMutexp ;
+}
+
+char* LLPrivateMemoryPool::allocate(U32 size)
+{
+ if(!size)
+ {
+ return NULL ;
+ }
+
+ //if the asked size larger than MAX_BLOCK_SIZE, fetch from heap directly, the pool does not manage it
+ if(size >= CHUNK_SIZE)
+ {
+ return (char*)malloc(size) ;
+ }
+
+ char* p = NULL ;
+
+ //find the appropriate chunk
+ S32 chunk_idx = getChunkIndex(size) ;
+
+ lock() ;
+
+ LLMemoryChunk* chunk = mChunkList[chunk_idx];
+ while(chunk)
+ {
+ if((p = chunk->allocate(size)))
+ {
+ break ;
+ }
+ chunk = chunk->mNext ;
+ }
+
+ //fetch new memory chunk
+ if(!p)
+ {
+ if(mReservedPoolSize + CHUNK_SIZE > mMaxPoolSize)
+ {
+ chunk = mChunkList[chunk_idx];
+ while(chunk)
+ {
+ if((p = chunk->allocate(size)))
+ {
+ break ;
+ }
+ chunk = chunk->mNext ;
+ }
+ }
+ else
+ {
+ chunk = addChunk(chunk_idx) ;
+ if(chunk)
+ {
+ p = chunk->allocate(size) ;
+ }
+ }
+ }
+
+ unlock() ;
+
+ if(!p) //to get memory from the private pool failed, try the heap directly
+ {
+ static bool to_log = true ;
+
+ if(to_log)
+ {
+ llwarns << "The memory pool overflows, now using heap directly!" << llendl ;
+ to_log = false ;
+ }
+
+ return (char*)malloc(size) ;
+ }
+
+ return p ;
+}
+
+void LLPrivateMemoryPool::freeMem(void* addr)
+{
+ if(!addr)
+ {
+ return ;
+ }
+
+ lock() ;
+
+ LLMemoryChunk* chunk = findChunk((char*)addr) ;
+
+ if(!chunk)
+ {
+ free(addr) ; //release from heap
+ }
+ else
+ {
+ chunk->freeMem(addr) ;
+
+ if(chunk->empty())
+ {
+ removeChunk(chunk) ;
+ }
+ }
+
+ unlock() ;
+}
+
+void LLPrivateMemoryPool::dump()
+{
+}
+
+U32 LLPrivateMemoryPool::getTotalAllocatedSize()
+{
+ U32 total_allocated = 0 ;
+
+ LLMemoryChunk* chunk ;
+ for(S32 i = 0 ; i < SUPER_ALLOCATION ; i++)
+ {
+ chunk = mChunkList[i];
+ while(chunk)
+ {
+ total_allocated += chunk->getAllocatedSize() ;
+ chunk = chunk->mNext ;
+ }
+ }
+
+ return total_allocated ;
+}
+
+void LLPrivateMemoryPool::lock()
+{
+ if(mMutexp)
+ {
+ mMutexp->lock() ;
+ }
+}
+
+void LLPrivateMemoryPool::unlock()
+{
+ if(mMutexp)
+ {
+ mMutexp->unlock() ;
+ }
+}
+
+S32 LLPrivateMemoryPool::getChunkIndex(U32 size)
+{
+ S32 i ;
+ for(i = 0 ; size > MAX_SLOT_SIZES[i]; i++);
+
+ llassert_always(i < SUPER_ALLOCATION);
+
+ return i ;
+}
+
+//destroy the entire pool
+void LLPrivateMemoryPool::destroyPool()
+{
+ lock() ;
+
+ if(mNumOfChunks > 0)
+ {
+ llwarns << "There is some memory not freed when destroy the memory pool!" << llendl ;
+ }
+
+ mNumOfChunks = 0 ;
+ mChunkHashList.clear() ;
+ mHashFactor = 1 ;
+ for(S32 i = 0 ; i < SUPER_ALLOCATION ; i++)
+ {
+ mChunkList[i] = NULL ;
+ }
+
+ unlock() ;
+}
+
+bool LLPrivateMemoryPool::checkSize(U32 asked_size)
+{
+ if(mReservedPoolSize + asked_size > mMaxPoolSize)
+ {
+ llinfos << "Max pool size: " << mMaxPoolSize << llendl ;
+ llinfos << "Total reserved size: " << mReservedPoolSize + asked_size << llendl ;
+ llinfos << "Total_allocated Size: " << getTotalAllocatedSize() << llendl ;
+
+ //llerrs << "The pool is overflowing..." << llendl ;
+
+ return false ;
+ }
+
+ return true ;
+}
+
+LLPrivateMemoryPool::LLMemoryChunk* LLPrivateMemoryPool::addChunk(S32 chunk_index)
+{
+ U32 preferred_size ;
+ U32 overhead ;
+ if(chunk_index < LARGE_ALLOCATION)
+ {
+ preferred_size = CHUNK_SIZE ; //4MB
+ overhead = LLMemoryChunk::getMaxOverhead(preferred_size, MIN_SLOT_SIZES[chunk_index],
+ MAX_SLOT_SIZES[chunk_index], MIN_BLOCK_SIZES[chunk_index], MAX_BLOCK_SIZES[chunk_index]) ;
+ }
+ else
+ {
+ preferred_size = LARGE_CHUNK_SIZE ; //16MB
+ overhead = LLMemoryChunk::getMaxOverhead(preferred_size, MIN_SLOT_SIZES[chunk_index],
+ MAX_SLOT_SIZES[chunk_index], MIN_BLOCK_SIZES[chunk_index], MAX_BLOCK_SIZES[chunk_index]) ;
+ }
+
+ if(!checkSize(preferred_size + overhead))
+ {
+ return NULL ;
+ }
+
+ mReservedPoolSize += preferred_size + overhead ;
+
+ char* buffer = (char*)malloc(preferred_size + overhead) ;
+ if(!buffer)
+ {
+ return NULL ;
+ }
+
+ LLMemoryChunk* chunk = new (buffer) LLMemoryChunk() ;
+ chunk->init(buffer, preferred_size + overhead, MIN_SLOT_SIZES[chunk_index],
+ MAX_SLOT_SIZES[chunk_index], MIN_BLOCK_SIZES[chunk_index], MAX_BLOCK_SIZES[chunk_index]) ;
+
+ //add to the tail of the linked list
+ {
+ if(!mChunkList[chunk_index])
+ {
+ mChunkList[chunk_index] = chunk ;
+ }
+ else
+ {
+ LLMemoryChunk* cur = mChunkList[chunk_index] ;
+ while(cur->mNext)
+ {
+ cur = cur->mNext ;
+ }
+ cur->mNext = chunk ;
+ chunk->mPrev = cur ;
+ }
+ }
+
+ //insert into the hash table
+ addToHashTable(chunk) ;
+
+ mNumOfChunks++;
+
+ return chunk ;
+}
+
+void LLPrivateMemoryPool::removeChunk(LLMemoryChunk* chunk)
+{
+ if(!chunk)
+ {
+ return ;
+ }
+
+ //remove from the linked list
+ for(S32 i = 0 ; i < SUPER_ALLOCATION ; i++)
+ {
+ if(mChunkList[i] == chunk)
+ {
+ mChunkList[i] = chunk->mNext ;
+ }
+ }
+
+ if(chunk->mPrev)
+ {
+ chunk->mPrev->mNext = chunk->mNext ;
+ }
+ if(chunk->mNext)
+ {
+ chunk->mNext->mPrev = chunk->mPrev ;
+ }
+
+ //remove from the hash table
+ removeFromHashTable(chunk) ;
+
+ mNumOfChunks--;
+ mReservedPoolSize -= chunk->getBufferSize() ;
+
+ //release memory
+ free(chunk->getBuffer()) ;
+}
+
+U16 LLPrivateMemoryPool::findHashKey(const char* addr)
+{
+ return (((U32)addr) / CHUNK_SIZE) % mHashFactor ;
+}
+
+LLPrivateMemoryPool::LLMemoryChunk* LLPrivateMemoryPool::findChunk(const char* addr)
+{
+ U16 key = findHashKey(addr) ;
+ if(mChunkHashList.size() <= key)
+ {
+ return NULL ;
+ }
+
+ return mChunkHashList[key].findChunk(addr) ;
+}
+
+void LLPrivateMemoryPool::addToHashTable(LLMemoryChunk* chunk)
+{
+ static const U16 HASH_FACTORS[] = {41, 83, 193, 317, 419, 523, 719, 997, 1523, 0xFFFF};
+
+ U16 i ;
+ if(mChunkHashList.empty())
+ {
+ mHashFactor = HASH_FACTORS[0] ;
+ rehash() ;
+ }
+
+ U16 start_key = findHashKey(chunk->getBuffer()) ;
+ U16 end_key = findHashKey(chunk->getBuffer() + chunk->getBufferSize() - 1) ;
+ bool need_rehash = false ;
+
+ if(mChunkHashList[start_key].hasElement(chunk))
+ {
+ return; //already inserted.
+ }
+ need_rehash = mChunkHashList[start_key].add(chunk) ;
+
+ if(start_key == end_key && !need_rehash)
+ {
+ return ; //done
+ }
+
+ if(!need_rehash)
+ {
+ need_rehash = mChunkHashList[end_key].add(chunk) ;
+ }
+
+ if(!need_rehash)
+ {
+ if(end_key < start_key)
+ {
+ need_rehash = fillHashTable(start_key + 1, mHashFactor, chunk) ;
+ if(!need_rehash)
+ {
+ need_rehash = fillHashTable(0, end_key, chunk) ;
+ }
+ }
+ else
+ {
+ need_rehash = fillHashTable(start_key + 1, end_key, chunk) ;
+ }
+ }
+
+ if(need_rehash)
+ {
+ i = 0 ;
+ while(HASH_FACTORS[i] <= mHashFactor) i++;
+
+ mHashFactor = HASH_FACTORS[i] ;
+ llassert_always(mHashFactor != 0xFFFF) ;//stop point to prevent endlessly recursive calls
+
+ rehash() ;
+ }
+}
+
+void LLPrivateMemoryPool::removeFromHashTable(LLMemoryChunk* chunk)
+{
+ U16 start_key = findHashKey(chunk->getBuffer()) ;
+ U16 end_key = findHashKey(chunk->getBuffer() + chunk->getBufferSize() - 1) ;
+
+ mChunkHashList[start_key].remove(chunk) ;
+ if(start_key == end_key)
+ {
+ return ; //done
+ }
+
+ mChunkHashList[end_key].remove(chunk) ;
+
+ if(end_key < start_key)
+ {
+ for(U16 i = start_key + 1 ; i < mHashFactor; i++)
+ {
+ mChunkHashList[i].remove(chunk) ;
+ }
+ for(U16 i = 0 ; i < end_key; i++)
+ {
+ mChunkHashList[i].remove(chunk) ;
+ }
+ }
+ else
+ {
+ for(U16 i = start_key + 1 ; i < end_key; i++)
+ {
+ mChunkHashList[i].remove(chunk) ;
+ }
+ }
+}
+
+void LLPrivateMemoryPool::rehash()
+{
+ llinfos << "new hash factor: " << mHashFactor << llendl ;
+
+ mChunkHashList.clear() ;
+ mChunkHashList.resize(mHashFactor) ;
+
+ LLMemoryChunk* chunk ;
+ for(U16 i = 0 ; i < SUPER_ALLOCATION ; i++)
+ {
+ chunk = mChunkList[i] ;
+ while(chunk)
+ {
+ addToHashTable(chunk) ;
+ chunk = chunk->mNext ;
+ }
+ }
+}
+
+bool LLPrivateMemoryPool::fillHashTable(U16 start, U16 end, LLMemoryChunk* chunk)
+{
+ for(U16 i = start; i < end; i++)
+ {
+ if(mChunkHashList[i].add(chunk))
+ {
+ return true ;
+ }
+ }
+
+ return false ;
+}
+
+//--------------------------------------------------------------------
+// class LLChunkHashElement
+//--------------------------------------------------------------------
+LLPrivateMemoryPool::LLMemoryChunk* LLPrivateMemoryPool::LLChunkHashElement::findChunk(const char* addr)
+{
+ if(mFirst && mFirst->containsAddress(addr))
+ {
+ return mFirst ;
+ }
+ else if(mSecond && mSecond->containsAddress(addr))
+ {
+ return mSecond ;
+ }
+
+ return NULL ;
+}
+
+//return false if successfully inserted to the hash slot.
+bool LLPrivateMemoryPool::LLChunkHashElement::add(LLPrivateMemoryPool::LLMemoryChunk* chunk)
+{
+ llassert_always(!hasElement(chunk)) ;
+
+ if(!mFirst)
+ {
+ mFirst = chunk ;
+ }
+ else if(!mSecond)
+ {
+ mSecond = chunk ;
+ }
+ else
+ {
+ return true ; //failed
+ }
+
+ return false ;
+}
+
+void LLPrivateMemoryPool::LLChunkHashElement::remove(LLPrivateMemoryPool::LLMemoryChunk* chunk)
+{
+ if(mFirst == chunk)
+ {
+ mFirst = NULL ;
+ }
+ else if(mSecond ==chunk)
+ {
+ mSecond = NULL ;
+ }
+ else
+ {
+ llerrs << "This slot does not contain this chunk!" << llendl ;
+ }
+}
+
+//--------------------------------------------------------------------
+//class LLPrivateMemoryPoolManager
+//--------------------------------------------------------------------
+LLPrivateMemoryPoolManager* LLPrivateMemoryPoolManager::sInstance = NULL ;
+BOOL LLPrivateMemoryPoolManager::sPrivatePoolEnabled = FALSE ;
+std::vector<LLPrivateMemoryPool*> LLPrivateMemoryPoolManager::sDanglingPoolList ;
+
+LLPrivateMemoryPoolManager::LLPrivateMemoryPoolManager(BOOL enabled, U32 max_pool_size)
+{
+ mPoolList.resize(LLPrivateMemoryPool::MAX_TYPES) ;
+
+ for(S32 i = 0 ; i < LLPrivateMemoryPool::MAX_TYPES; i++)
+ {
+ mPoolList[i] = NULL ;
+ }
+
+ sPrivatePoolEnabled = enabled ;
+
+ const U32 MAX_POOL_SIZE = 256 * 1024 * 1024 ; //256 MB
+ mMaxPrivatePoolSize = llmax(max_pool_size, MAX_POOL_SIZE) ;
+}
+
+LLPrivateMemoryPoolManager::~LLPrivateMemoryPoolManager()
+{
+
+#if __DEBUG_PRIVATE_MEM__
+ if(!sMemAllocationTracker.empty())
+ {
+ llwarns << "there is potential memory leaking here. The list of not freed memory blocks are from: " <<llendl ;
+
+ S32 k = 0 ;
+ for(mem_allocation_info_t::iterator iter = sMemAllocationTracker.begin() ; iter != sMemAllocationTracker.end() ; ++iter)
+ {
+ llinfos << k++ << ", " << (U32)iter->first << " : " << iter->second << llendl ;
+ }
+ sMemAllocationTracker.clear() ;
+ }
+#endif
+
+#if 0
+ //all private pools should be released by their owners before reaching here.
+ for(S32 i = 0 ; i < LLPrivateMemoryPool::MAX_TYPES; i++)
+ {
+ llassert_always(!mPoolList[i]) ;
+ }
+ mPoolList.clear() ;
+
+#else
+ //forcefully release all memory
+ for(S32 i = 0 ; i < LLPrivateMemoryPool::MAX_TYPES; i++)
+ {
+ if(mPoolList[i])
+ {
+ if(mPoolList[i]->isEmpty())
+ {
+ delete mPoolList[i] ;
+ }
+ else
+ {
+ //can not delete this pool because it has alloacted memory to be freed.
+ //move it to the dangling list.
+ sDanglingPoolList.push_back(mPoolList[i]) ;
+ }
+
+ mPoolList[i] = NULL ;
+ }
+ }
+ mPoolList.clear() ;
+#endif
+}
+
+//static
+void LLPrivateMemoryPoolManager::initClass(BOOL enabled, U32 max_pool_size)
+{
+ llassert_always(!sInstance) ;
+
+ sInstance = new LLPrivateMemoryPoolManager(enabled, max_pool_size) ;
+}
+
+//static
+LLPrivateMemoryPoolManager* LLPrivateMemoryPoolManager::getInstance()
+{
+ //if(!sInstance)
+ //{
+ // sInstance = new LLPrivateMemoryPoolManager(FALSE) ;
+ //}
+ return sInstance ;
+}
+
+//static
+void LLPrivateMemoryPoolManager::destroyClass()
+{
+ if(sInstance)
+ {
+ delete sInstance ;
+ sInstance = NULL ;
+ }
+}
+
+LLPrivateMemoryPool* LLPrivateMemoryPoolManager::newPool(S32 type)
+{
+ if(!sPrivatePoolEnabled)
+ {
+ return NULL ;
+ }
+
+ if(!mPoolList[type])
+ {
+ mPoolList[type] = new LLPrivateMemoryPool(type, mMaxPrivatePoolSize) ;
+ }
+
+ return mPoolList[type] ;
+}
+
+void LLPrivateMemoryPoolManager::deletePool(LLPrivateMemoryPool* pool)
+{
+ if(pool && pool->isEmpty())
+ {
+ mPoolList[pool->getType()] = NULL ;
+ delete pool;
+ }
+}
+
+//debug
+void LLPrivateMemoryPoolManager::updateStatistics()
+{
+ mTotalReservedSize = 0 ;
+ mTotalAllocatedSize = 0 ;
+
+ for(U32 i = 0; i < mPoolList.size(); i++)
+ {
+ if(mPoolList[i])
+ {
+ mTotalReservedSize += mPoolList[i]->getTotalReservedSize() ;
+ mTotalAllocatedSize += mPoolList[i]->getTotalAllocatedSize() ;
+ }
+ }
+}
+
+#if __DEBUG_PRIVATE_MEM__
+//static
+char* LLPrivateMemoryPoolManager::allocate(LLPrivateMemoryPool* poolp, U32 size, const char* function, const int line)
+{
+ char* p ;
+
+ if(!poolp)
+ {
+ p = (char*)malloc(size) ;
+ }
+ else
+ {
+ p = poolp->allocate(size) ;
+ }
+
+ if(p)
+ {
+ char num[16] ;
+ sprintf(num, " line: %d ", line) ;
+ std::string str(function) ;
+ str += num;
+
+ sMemAllocationTracker[p] = str ;
+ }
+
+ return p ;
+}
+#else
+//static
+char* LLPrivateMemoryPoolManager::allocate(LLPrivateMemoryPool* poolp, U32 size)
+{
+ if(poolp)
+ {
+ return poolp->allocate(size) ;
+ }
+ else
+ {
+ return (char*)malloc(size) ;
+ }
+}
+#endif
+
+//static
+void LLPrivateMemoryPoolManager::freeMem(LLPrivateMemoryPool* poolp, void* addr)
+{
+ if(!addr)
+ {
+ return ;
+ }
+
+#if __DEBUG_PRIVATE_MEM__
+ sMemAllocationTracker.erase((char*)addr) ;
+#endif
+
+ if(poolp)
+ {
+ poolp->freeMem(addr) ;
+ }
+ else
+ {
+ if(!sPrivatePoolEnabled)
+ {
+ free(addr) ; //private pool is disabled.
+ }
+ else if(!sInstance) //the private memory manager is destroyed, try the dangling list
+ {
+ for(S32 i = 0 ; i < sDanglingPoolList.size(); i++)
+ {
+ if(sDanglingPoolList[i]->findChunk((char*)addr))
+ {
+ sDanglingPoolList[i]->freeMem(addr) ;
+ if(sDanglingPoolList[i]->isEmpty())
+ {
+ delete sDanglingPoolList[i] ;
+
+ if(i < sDanglingPoolList.size() - 1)
+ {
+ sDanglingPoolList[i] = sDanglingPoolList[sDanglingPoolList.size() - 1] ;
+ }
+ sDanglingPoolList.pop_back() ;
+ }
+
+ addr = NULL ;
+ break ;
+ }
+ }
+ llassert_always(!addr) ; //addr should be release before hitting here!
+ }
+ else
+ {
+ llerrs << "private pool is used before initialized.!" << llendl ;
+ }
+ }
+}
+
+//--------------------------------------------------------------------
+//class LLPrivateMemoryPoolTester
+//--------------------------------------------------------------------
+#if 0
+LLPrivateMemoryPoolTester* LLPrivateMemoryPoolTester::sInstance = NULL ;
+LLPrivateMemoryPool* LLPrivateMemoryPoolTester::sPool = NULL ;
+LLPrivateMemoryPoolTester::LLPrivateMemoryPoolTester()
+{
+}
+
+LLPrivateMemoryPoolTester::~LLPrivateMemoryPoolTester()
+{
+}
+
+//static
+LLPrivateMemoryPoolTester* LLPrivateMemoryPoolTester::getInstance()
+{
+ if(!sInstance)
+ {
+ sInstance = ::new LLPrivateMemoryPoolTester() ;
+ }
+ return sInstance ;
+}
+
+//static
+void LLPrivateMemoryPoolTester::destroy()
+{
+ if(sInstance)
+ {
+ ::delete sInstance ;
+ sInstance = NULL ;
+ }
+
+ if(sPool)
+ {
+ LLPrivateMemoryPoolManager::getInstance()->deletePool(sPool) ;
+ sPool = NULL ;
+ }
+}
+
+void LLPrivateMemoryPoolTester::run(S32 type)
+{
+ if(sPool)
+ {
+ LLPrivateMemoryPoolManager::getInstance()->deletePool(sPool) ;
+ }
+ sPool = LLPrivateMemoryPoolManager::getInstance()->newPool(type) ;
+
+ //run the test
+ correctnessTest() ;
+ performanceTest() ;
+ //fragmentationtest() ;
+
+ //release pool.
+ LLPrivateMemoryPoolManager::getInstance()->deletePool(sPool) ;
+ sPool = NULL ;
+}
+
+void LLPrivateMemoryPoolTester::test(U32 min_size, U32 max_size, U32 stride, U32 times,
+ bool random_deletion, bool output_statistics)
+{
+ U32 levels = (max_size - min_size) / stride + 1 ;
+ char*** p ;
+ U32 i, j ;
+ U32 total_allocated_size = 0 ;
+
+ //allocate space for p ;
+ if(!(p = ::new char**[times]) || !(*p = ::new char*[times * levels]))
+ {
+ llerrs << "memory initialization for p failed" << llendl ;
+ }
+
+ //init
+ for(i = 0 ; i < times; i++)
+ {
+ p[i] = *p + i * levels ;
+ for(j = 0 ; j < levels; j++)
+ {
+ p[i][j] = NULL ;
+ }
+ }
+
+ //allocation
+ U32 size ;
+ for(i = 0 ; i < times ; i++)
+ {
+ for(j = 0 ; j < levels; j++)
+ {
+ size = min_size + j * stride ;
+ p[i][j] = ALLOCATE_MEM(sPool, size) ;
+
+ total_allocated_size+= size ;
+
+ *(U32*)p[i][j] = i ;
+ *((U32*)p[i][j] + 1) = j ;
+ //p[i][j][size - 1] = '\0' ; //access the last element to verify the success of the allocation.
+
+ //randomly release memory
+ if(random_deletion)
+ {
+ S32 k = rand() % levels ;
+
+ if(p[i][k])
+ {
+ llassert_always(*(U32*)p[i][k] == i && *((U32*)p[i][k] + 1) == k) ;
+ FREE_MEM(sPool, p[i][k]) ;
+ total_allocated_size -= min_size + k * stride ;
+ p[i][k] = NULL ;
+ }
+ }
+ }
+ }
+
+ //output pool allocation statistics
+ if(output_statistics)
+ {
+ }
+
+ //release all memory allocations
+ for(i = 0 ; i < times; i++)
+ {
+ for(j = 0 ; j < levels; j++)
+ {
+ if(p[i][j])
+ {
+ llassert_always(*(U32*)p[i][j] == i && *((U32*)p[i][j] + 1) == j) ;
+ FREE_MEM(sPool, p[i][j]) ;
+ total_allocated_size -= min_size + j * stride ;
+ p[i][j] = NULL ;
+ }
+ }
+ }
+
+ ::delete[] *p ;
+ ::delete[] p ;
+}
+
+void LLPrivateMemoryPoolTester::testAndTime(U32 size, U32 times)
+{
+ LLTimer timer ;
+
+ llinfos << " -**********************- " << llendl ;
+ llinfos << "test size: " << size << " test times: " << times << llendl ;
+
+ timer.reset() ;
+ char** p = new char*[times] ;
+
+ //using the customized memory pool
+ //allocation
+ for(U32 i = 0 ; i < times; i++)
+ {
+ p[i] = ALLOCATE_MEM(sPool, size) ;
+ if(!p[i])
+ {
+ llerrs << "allocation failed" << llendl ;
+ }
+ }
+ //de-allocation
+ for(U32 i = 0 ; i < times; i++)
+ {
+ FREE_MEM(sPool, p[i]) ;
+ p[i] = NULL ;
+ }
+ llinfos << "time spent using customized memory pool: " << timer.getElapsedTimeF32() << llendl ;
+
+ timer.reset() ;
+
+ //using the standard allocator/de-allocator:
+ //allocation
+ for(U32 i = 0 ; i < times; i++)
+ {
+ p[i] = ::new char[size] ;
+ if(!p[i])
+ {
+ llerrs << "allocation failed" << llendl ;
+ }
+ }
+ //de-allocation
+ for(U32 i = 0 ; i < times; i++)
+ {
+ ::delete[] p[i] ;
+ p[i] = NULL ;
+ }
+ llinfos << "time spent using standard allocator/de-allocator: " << timer.getElapsedTimeF32() << llendl ;
+
+ delete[] p;
+}
+
+void LLPrivateMemoryPoolTester::correctnessTest()
+{
+ //try many different sized allocation, and all kinds of edge cases, access the allocated memory
+ //to see if allocation is right.
+
+ //edge case
+ char* p = ALLOCATE_MEM(sPool, 0) ;
+ FREE_MEM(sPool, p) ;
+
+ //small sized
+ // [8 bytes, 2KB), each asks for 256 allocations and deallocations
+ test(8, 2040, 8, 256, true, true) ;
+
+ //medium sized
+ //[2KB, 512KB), each asks for 16 allocations and deallocations
+ test(2048, 512 * 1024 - 2048, 2048, 16, true, true) ;
+
+ //large sized
+ //[512KB, 4MB], each asks for 8 allocations and deallocations
+ test(512 * 1024, 4 * 1024 * 1024, 64 * 1024, 6, true, true) ;
+}
+
+void LLPrivateMemoryPoolTester::performanceTest()
+{
+ U32 test_size[3] = {768, 3* 1024, 3* 1024 * 1024};
+
+ //small sized
+ testAndTime(test_size[0], 8) ;
+
+ //medium sized
+ testAndTime(test_size[1], 8) ;
+
+ //large sized
+ testAndTime(test_size[2], 8) ;
+}
+
+void LLPrivateMemoryPoolTester::fragmentationtest()
+{
+ //for internal fragmentation statistics:
+ //every time when asking for a new chunk during correctness test, and performance test,
+ //print out the chunk usage statistices.
+}
+#endif
+//--------------------------------------------------------------------