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|
/**
* @file llmemory.h
* @brief Memory allocation/deallocation header-stuff goes here.
*
* $LicenseInfo:firstyear=2002&license=viewerlgpl$
* Second Life Viewer Source Code
* Copyright (C) 2010, Linden Research, Inc.
*
* This library is free software; you can redistribute it and/or
* modify it under the terms of the GNU Lesser General Public
* License as published by the Free Software Foundation;
* version 2.1 of the License only.
*
* This library 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
* Lesser General Public License for more details.
*
* You should have received a copy of the GNU Lesser General Public
* License along with this library; if not, write to the Free Software
* Foundation, Inc., 51 Franklin Street, Fifth Floor, Boston, MA 02110-1301 USA
*
* Linden Research, Inc., 945 Battery Street, San Francisco, CA 94111 USA
* $/LicenseInfo$
*/
#ifndef LLMEMORY_H
#define LLMEMORY_H
#include "linden_common.h"
#include "llunits.h"
#include "stdtypes.h"
#if !LL_WINDOWS
#include <stdint.h>
#endif
class LLMutex ;
#if LL_WINDOWS && LL_DEBUG
#define LL_CHECK_MEMORY llassert(_CrtCheckMemory());
#else
#define LL_CHECK_MEMORY
#endif
#if LL_WINDOWS
#define LL_ALIGN_OF __alignof
#else
#define LL_ALIGN_OF __align_of__
#endif
#if LL_WINDOWS
#define LL_DEFAULT_HEAP_ALIGN 8
#elif LL_DARWIN
#define LL_DEFAULT_HEAP_ALIGN 16
#elif LL_LINUX
#define LL_DEFAULT_HEAP_ALIGN 8
#endif
LL_COMMON_API void ll_assert_aligned_func(uintptr_t ptr,U32 alignment);
#ifdef SHOW_ASSERT
#define ll_assert_aligned(ptr,alignment) ll_assert_aligned_func(uintptr_t(ptr),((U32)alignment))
#else
#define ll_assert_aligned(ptr,alignment)
#endif
#include <xmmintrin.h>
template <typename T> T* LL_NEXT_ALIGNED_ADDRESS(T* address)
{
return reinterpret_cast<T*>(
(uintptr_t(address) + 0xF) & ~0xF);
}
template <typename T> T* LL_NEXT_ALIGNED_ADDRESS_64(T* address)
{
return reinterpret_cast<T*>(
(uintptr_t(address) + 0x3F) & ~0x3F);
}
#if LL_LINUX || LL_DARWIN
#define LL_ALIGN_PREFIX(x)
#define LL_ALIGN_POSTFIX(x) __attribute__((aligned(x)))
#elif LL_WINDOWS
#define LL_ALIGN_PREFIX(x) __declspec(align(x))
#define LL_ALIGN_POSTFIX(x)
#else
#error "LL_ALIGN_PREFIX and LL_ALIGN_POSTFIX undefined"
#endif
#define LL_ALIGN_16(var) LL_ALIGN_PREFIX(16) var LL_ALIGN_POSTFIX(16)
//------------------------------------------------------------------------------------------------
//------------------------------------------------------------------------------------------------
// for enable buffer overrun detection predefine LL_DEBUG_BUFFER_OVERRUN in current library
// change preprocessor code to: #if 1 && defined(LL_WINDOWS)
#if 0 && defined(LL_WINDOWS)
void* ll_aligned_malloc_fallback( size_t size, int align );
void ll_aligned_free_fallback( void* ptr );
//------------------------------------------------------------------------------------------------
#else
inline void* ll_aligned_malloc_fallback( size_t size, int align )
{
#if defined(LL_WINDOWS)
return _aligned_malloc(size, align);
#else
void* mem = malloc( size + (align - 1) + sizeof(void*) );
char* aligned = ((char*)mem) + sizeof(void*);
aligned += align - ((uintptr_t)aligned & (align - 1));
((void**)aligned)[-1] = mem;
return aligned;
#endif
}
inline void ll_aligned_free_fallback( void* ptr )
{
#if defined(LL_WINDOWS)
_aligned_free(ptr);
#else
if (ptr)
{
free( ((void**)ptr)[-1] );
}
#endif
}
#endif
//------------------------------------------------------------------------------------------------
//------------------------------------------------------------------------------------------------
inline void* ll_aligned_malloc_16(size_t size) // returned hunk MUST be freed with ll_aligned_free_16().
{
#if defined(LL_WINDOWS)
return _aligned_malloc(size, 16);
#elif defined(LL_DARWIN)
return malloc(size); // default osx malloc is 16 byte aligned.
#else
void *rtn;
if (LL_LIKELY(0 == posix_memalign(&rtn, 16, size)))
return rtn;
else // bad alignment requested, or out of memory
return NULL;
#endif
}
inline void ll_aligned_free_16(void *p)
{
#if defined(LL_WINDOWS)
_aligned_free(p);
#elif defined(LL_DARWIN)
return free(p);
#else
free(p); // posix_memalign() is compatible with heap deallocator
#endif
}
inline void* ll_aligned_realloc_16(void* ptr, size_t size, size_t old_size) // returned hunk MUST be freed with ll_aligned_free_16().
{
#if defined(LL_WINDOWS)
return _aligned_realloc(ptr, size, 16);
#elif defined(LL_DARWIN)
return realloc(ptr,size); // default osx malloc is 16 byte aligned.
#else
//FIXME: memcpy is SLOW
void* ret = ll_aligned_malloc_16(size);
if (ptr)
{
if (ret)
{
// Only copy the size of the smallest memory block to avoid memory corruption.
memcpy(ret, ptr, llmin(old_size, size));
}
ll_aligned_free_16(ptr);
}
return ret;
#endif
}
inline void* ll_aligned_malloc_32(size_t size) // returned hunk MUST be freed with ll_aligned_free_32().
{
#if defined(LL_WINDOWS)
return _aligned_malloc(size, 32);
#elif defined(LL_DARWIN)
return ll_aligned_malloc_fallback( size, 32 );
#else
void *rtn;
if (LL_LIKELY(0 == posix_memalign(&rtn, 32, size)))
return rtn;
else // bad alignment requested, or out of memory
return NULL;
#endif
}
inline void ll_aligned_free_32(void *p)
{
#if defined(LL_WINDOWS)
_aligned_free(p);
#elif defined(LL_DARWIN)
ll_aligned_free_fallback( p );
#else
free(p); // posix_memalign() is compatible with heap deallocator
#endif
}
// general purpose dispatch functions that are forced inline so they can compile down to a single call
template<size_t ALIGNMENT>
LL_FORCE_INLINE void* ll_aligned_malloc(size_t size)
{
if (LL_DEFAULT_HEAP_ALIGN % ALIGNMENT == 0)
{
return malloc(size);
}
else if (ALIGNMENT == 16)
{
return ll_aligned_malloc_16(size);
}
else if (ALIGNMENT == 32)
{
return ll_aligned_malloc_32(size);
}
else
{
return ll_aligned_malloc_fallback(size, ALIGNMENT);
}
}
template<size_t ALIGNMENT>
LL_FORCE_INLINE void ll_aligned_free(void* ptr)
{
if (ALIGNMENT == LL_DEFAULT_HEAP_ALIGN)
{
free(ptr);
}
else if (ALIGNMENT == 16)
{
ll_aligned_free_16(ptr);
}
else if (ALIGNMENT == 32)
{
return ll_aligned_free_32(ptr);
}
else
{
return ll_aligned_free_fallback(ptr);
}
}
// Copy words 16-byte blocks from src to dst. Source and destination MUST NOT OVERLAP.
// Source and dest must be 16-byte aligned and size must be multiple of 16.
//
inline void ll_memcpy_nonaliased_aligned_16(char* __restrict dst, const char* __restrict src, size_t bytes)
{
assert(src != NULL);
assert(dst != NULL);
assert(bytes > 0);
assert((bytes % sizeof(F32))== 0);
ll_assert_aligned(src,16);
ll_assert_aligned(dst,16);
assert((src < dst) ? ((src + bytes) <= dst) : ((dst + bytes) <= src));
assert(bytes%16==0);
char* end = dst + bytes;
if (bytes > 64)
{
// Find start of 64b aligned area within block
//
void* begin_64 = LL_NEXT_ALIGNED_ADDRESS_64(dst);
//at least 64 bytes before the end of the destination, switch to 16 byte copies
void* end_64 = end-64;
// Prefetch the head of the 64b area now
//
_mm_prefetch((char*)begin_64, _MM_HINT_NTA);
_mm_prefetch((char*)begin_64 + 64, _MM_HINT_NTA);
_mm_prefetch((char*)begin_64 + 128, _MM_HINT_NTA);
_mm_prefetch((char*)begin_64 + 192, _MM_HINT_NTA);
// Copy 16b chunks until we're 64b aligned
//
while (dst < begin_64)
{
_mm_store_ps((F32*)dst, _mm_load_ps((F32*)src));
dst += 16;
src += 16;
}
// Copy 64b chunks up to your tail
//
// might be good to shmoo the 512b prefetch offset
// (characterize performance for various values)
//
while (dst < end_64)
{
_mm_prefetch((char*)src + 512, _MM_HINT_NTA);
_mm_prefetch((char*)dst + 512, _MM_HINT_NTA);
_mm_store_ps((F32*)dst, _mm_load_ps((F32*)src));
_mm_store_ps((F32*)(dst + 16), _mm_load_ps((F32*)(src + 16)));
_mm_store_ps((F32*)(dst + 32), _mm_load_ps((F32*)(src + 32)));
_mm_store_ps((F32*)(dst + 48), _mm_load_ps((F32*)(src + 48)));
dst += 64;
src += 64;
}
}
// Copy remainder 16b tail chunks (or ALL 16b chunks for sub-64b copies)
//
while (dst < end)
{
_mm_store_ps((F32*)dst, _mm_load_ps((F32*)src));
dst += 16;
src += 16;
}
}
#ifndef __DEBUG_PRIVATE_MEM__
#define __DEBUG_PRIVATE_MEM__ 0
#endif
class LL_COMMON_API LLMemory
{
public:
static void initClass();
static void cleanupClass();
static void freeReserve();
// Return the resident set size of the current process, in bytes.
// Return value is zero if not known.
static U64 getCurrentRSS();
static U32 getWorkingSetSize();
static void* tryToAlloc(void* address, U32 size);
static void initMaxHeapSizeGB(F32Gigabytes max_heap_size, BOOL prevent_heap_failure);
static void updateMemoryInfo() ;
static void logMemoryInfo(BOOL update = FALSE);
static bool isMemoryPoolLow();
static U32Kilobytes getAvailableMemKB() ;
static U32Kilobytes getMaxMemKB() ;
static U32Kilobytes getAllocatedMemKB() ;
private:
static char* reserveMem;
static U32Kilobytes sAvailPhysicalMemInKB ;
static U32Kilobytes sMaxPhysicalMemInKB ;
static U32Kilobytes sAllocatedMemInKB;
static U32Kilobytes sAllocatedPageSizeInKB ;
static U32Kilobytes sMaxHeapSizeInKB;
static BOOL sEnableMemoryFailurePrevention;
};
//
//class LLPrivateMemoryPool defines a private memory pool for an application to use, so the application does not
//need to access the heap directly fro each memory allocation. Throught this, the allocation speed is faster,
//and reduces virtaul address space gragmentation problem.
//Note: this class is thread-safe by passing true to the constructor function. However, you do not need to do this unless
//you are sure the memory allocation and de-allocation will happen in different threads. To make the pool thread safe
//increases allocation and deallocation cost.
//
class LL_COMMON_API LLPrivateMemoryPool
{
friend class LLPrivateMemoryPoolManager ;
public:
class LL_COMMON_API LLMemoryBlock //each block is devided into slots uniformly
{
public:
LLMemoryBlock() ;
~LLMemoryBlock() ;
void init(char* buffer, U32 buffer_size, U32 slot_size) ;
void setBuffer(char* buffer, U32 buffer_size) ;
char* allocate() ;
void freeMem(void* addr) ;
bool empty() {return !mAllocatedSlots;}
bool isFull() {return mAllocatedSlots == mTotalSlots;}
bool isFree() {return !mTotalSlots;}
U32 getSlotSize()const {return mSlotSize;}
U32 getTotalSlots()const {return mTotalSlots;}
U32 getBufferSize()const {return mBufferSize;}
char* getBuffer() const {return mBuffer;}
//debug use
void resetBitMap() ;
private:
char* mBuffer;
U32 mSlotSize ; //when the block is not initialized, it is the buffer size.
U32 mBufferSize ;
U32 mUsageBits ;
U8 mTotalSlots ;
U8 mAllocatedSlots ;
U8 mDummySize ; //size of extra bytes reserved for mUsageBits.
public:
LLMemoryBlock* mPrev ;
LLMemoryBlock* mNext ;
LLMemoryBlock* mSelf ;
struct CompareAddress
{
bool operator()(const LLMemoryBlock* const& lhs, const LLMemoryBlock* const& rhs)
{
return (U32)lhs->getBuffer() < (U32)rhs->getBuffer();
}
};
};
class LL_COMMON_API LLMemoryChunk //is divided into memory blocks.
{
public:
LLMemoryChunk() ;
~LLMemoryChunk() ;
void init(char* buffer, U32 buffer_size, U32 min_slot_size, U32 max_slot_size, U32 min_block_size, U32 max_block_size) ;
void setBuffer(char* buffer, U32 buffer_size) ;
bool empty() ;
char* allocate(U32 size) ;
void freeMem(void* addr) ;
char* getBuffer() const {return mBuffer;}
U32 getBufferSize() const {return mBufferSize;}
U32 getAllocatedSize() const {return mAlloatedSize;}
bool containsAddress(const char* addr) const;
static U32 getMaxOverhead(U32 data_buffer_size, U32 min_slot_size,
U32 max_slot_size, U32 min_block_size, U32 max_block_size) ;
void dump() ;
private:
U32 getPageIndex(U32 addr) ;
U32 getBlockLevel(U32 size) ;
U16 getPageLevel(U32 size) ;
LLMemoryBlock* addBlock(U32 blk_idx) ;
void popAvailBlockList(U32 blk_idx) ;
void addToFreeSpace(LLMemoryBlock* blk) ;
void removeFromFreeSpace(LLMemoryBlock* blk) ;
void removeBlock(LLMemoryBlock* blk) ;
void addToAvailBlockList(LLMemoryBlock* blk) ;
U32 calcBlockSize(U32 slot_size);
LLMemoryBlock* createNewBlock(LLMemoryBlock* blk, U32 buffer_size, U32 slot_size, U32 blk_idx) ;
private:
LLMemoryBlock** mAvailBlockList ;//256 by mMinSlotSize
LLMemoryBlock** mFreeSpaceList;
LLMemoryBlock* mBlocks ; //index of blocks by address.
char* mBuffer ;
U32 mBufferSize ;
char* mDataBuffer ;
char* mMetaBuffer ;
U32 mMinBlockSize ;
U32 mMinSlotSize ;
U32 mMaxSlotSize ;
U32 mAlloatedSize ;
U16 mBlockLevels;
U16 mPartitionLevels;
public:
//form a linked list
LLMemoryChunk* mNext ;
LLMemoryChunk* mPrev ;
} ;
private:
LLPrivateMemoryPool(S32 type, U32 max_pool_size) ;
~LLPrivateMemoryPool() ;
char *allocate(U32 size) ;
void freeMem(void* addr) ;
void dump() ;
U32 getTotalAllocatedSize() ;
U32 getTotalReservedSize() {return mReservedPoolSize;}
S32 getType() const {return mType; }
bool isEmpty() const {return !mNumOfChunks; }
private:
void lock() ;
void unlock() ;
S32 getChunkIndex(U32 size) ;
LLMemoryChunk* addChunk(S32 chunk_index) ;
bool checkSize(U32 asked_size) ;
void removeChunk(LLMemoryChunk* chunk) ;
U16 findHashKey(const char* addr);
void addToHashTable(LLMemoryChunk* chunk) ;
void removeFromHashTable(LLMemoryChunk* chunk) ;
void rehash() ;
bool fillHashTable(U16 start, U16 end, LLMemoryChunk* chunk) ;
LLMemoryChunk* findChunk(const char* addr) ;
void destroyPool() ;
public:
enum
{
SMALL_ALLOCATION = 0, //from 8 bytes to 2KB(exclusive), page size 2KB, max chunk size is 4MB.
MEDIUM_ALLOCATION, //from 2KB to 512KB(exclusive), page size 32KB, max chunk size 4MB
LARGE_ALLOCATION, //from 512KB to 4MB(inclusive), page size 64KB, max chunk size 16MB
SUPER_ALLOCATION //allocation larger than 4MB.
};
enum
{
STATIC = 0 , //static pool(each alllocation stays for a long time) without threading support
VOLATILE, //Volatile pool(each allocation stays for a very short time) without threading support
STATIC_THREADED, //static pool with threading support
VOLATILE_THREADED, //volatile pool with threading support
MAX_TYPES
}; //pool types
private:
LLMutex* mMutexp ;
U32 mMaxPoolSize;
U32 mReservedPoolSize ;
LLMemoryChunk* mChunkList[SUPER_ALLOCATION] ; //all memory chunks reserved by this pool, sorted by address
U16 mNumOfChunks ;
U16 mHashFactor ;
S32 mType ;
class LLChunkHashElement
{
public:
LLChunkHashElement() {mFirst = NULL ; mSecond = NULL ;}
bool add(LLMemoryChunk* chunk) ;
void remove(LLMemoryChunk* chunk) ;
LLMemoryChunk* findChunk(const char* addr) ;
bool empty() {return !mFirst && !mSecond; }
bool full() {return mFirst && mSecond; }
bool hasElement(LLMemoryChunk* chunk) {return mFirst == chunk || mSecond == chunk;}
private:
LLMemoryChunk* mFirst ;
LLMemoryChunk* mSecond ;
};
std::vector<LLChunkHashElement> mChunkHashList ;
};
class LL_COMMON_API LLPrivateMemoryPoolManager
{
private:
LLPrivateMemoryPoolManager(BOOL enabled, U32 max_pool_size) ;
~LLPrivateMemoryPoolManager() ;
public:
static LLPrivateMemoryPoolManager* getInstance() ;
static void initClass(BOOL enabled, U32 pool_size) ;
static void destroyClass() ;
LLPrivateMemoryPool* newPool(S32 type) ;
void deletePool(LLPrivateMemoryPool* pool) ;
private:
std::vector<LLPrivateMemoryPool*> mPoolList ;
U32 mMaxPrivatePoolSize;
static LLPrivateMemoryPoolManager* sInstance ;
static BOOL sPrivatePoolEnabled;
static std::vector<LLPrivateMemoryPool*> sDanglingPoolList ;
public:
//debug and statistics info.
void updateStatistics() ;
U32 mTotalReservedSize ;
U32 mTotalAllocatedSize ;
public:
#if __DEBUG_PRIVATE_MEM__
static char* allocate(LLPrivateMemoryPool* poolp, U32 size, const char* function, const int line) ;
typedef std::map<char*, std::string> mem_allocation_info_t ;
static mem_allocation_info_t sMemAllocationTracker;
#else
static char* allocate(LLPrivateMemoryPool* poolp, U32 size) ;
#endif
static void freeMem(LLPrivateMemoryPool* poolp, void* addr) ;
};
//-------------------------------------------------------------------------------------
#if __DEBUG_PRIVATE_MEM__
#define ALLOCATE_MEM(poolp, size) LLPrivateMemoryPoolManager::allocate((poolp), (size), __FUNCTION__, __LINE__)
#else
#define ALLOCATE_MEM(poolp, size) LLPrivateMemoryPoolManager::allocate((poolp), (size))
#endif
#define FREE_MEM(poolp, addr) LLPrivateMemoryPoolManager::freeMem((poolp), (addr))
//-------------------------------------------------------------------------------------
//
//the below singleton is used to test the private memory pool.
//
#if 0
class LL_COMMON_API LLPrivateMemoryPoolTester
{
private:
LLPrivateMemoryPoolTester() ;
~LLPrivateMemoryPoolTester() ;
public:
static LLPrivateMemoryPoolTester* getInstance() ;
static void destroy() ;
void run(S32 type) ;
private:
void correctnessTest() ;
void performanceTest() ;
void fragmentationtest() ;
void test(U32 min_size, U32 max_size, U32 stride, U32 times, bool random_deletion, bool output_statistics) ;
void testAndTime(U32 size, U32 times) ;
#if 0
public:
void* operator new(size_t size)
{
return (void*)sPool->allocate(size) ;
}
void operator delete(void* addr)
{
sPool->freeMem(addr) ;
}
void* operator new[](size_t size)
{
return (void*)sPool->allocate(size) ;
}
void operator delete[](void* addr)
{
sPool->freeMem(addr) ;
}
#endif
private:
static LLPrivateMemoryPoolTester* sInstance;
static LLPrivateMemoryPool* sPool ;
static LLPrivateMemoryPool* sThreadedPool ;
};
#if 0
//static
void* LLPrivateMemoryPoolTester::operator new(size_t size)
{
return (void*)sPool->allocate(size) ;
}
//static
void LLPrivateMemoryPoolTester::operator delete(void* addr)
{
sPool->free(addr) ;
}
//static
void* LLPrivateMemoryPoolTester::operator new[](size_t size)
{
return (void*)sPool->allocate(size) ;
}
//static
void LLPrivateMemoryPoolTester::operator delete[](void* addr)
{
sPool->free(addr) ;
}
#endif
#endif
// LLRefCount moved to llrefcount.h
// LLPointer moved to llpointer.h
// LLSafeHandle moved to llsafehandle.h
// LLSingleton moved to llsingleton.h
#endif
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