RetroShare/libretroshare/src/util/smallobject.cc

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#include <iostream>
#include "smallobject.h"
#include "util/rsthreads.h"
using namespace RsMemoryManagement ;
RsMutex SmallObject::_mtx("SmallObject") ;
SmallObjectAllocator SmallObject::_allocator(RsMemoryManagement::MAX_SMALL_OBJECT_SIZE) ;
void Chunk::init(size_t blockSize,unsigned char blocks)
{
_data = new unsigned char[blockSize*blocks] ;
_firstAvailableBlock = 0 ;
_blocksAvailable = blocks ;
// Inits the first byte of each block to point to the next available block
//
unsigned char *p = _data ;
for(unsigned char i=0;i<blocks;p += blockSize)
*p = ++i ;
}
void Chunk::free()
{
delete[] _data ;
_data = NULL ;
}
void *Chunk::allocate(size_t blockSize)
{
if(!_blocksAvailable)
return NULL ;
assert(blockSize >= 2) ;
unsigned char *result = _data + _firstAvailableBlock*blockSize ;
// Grab id of next available block from the block being allocated.
// Always the case because the first available block is the first, so the next
// available block is given by *result.
//
_firstAvailableBlock = *result ;
--_blocksAvailable ;
return result ;
}
void Chunk::deallocate(void *p,size_t blockSize)
{
assert(p >= _data) ;
unsigned char *toRelease = static_cast<unsigned char *>(p) ;
// alignment check
assert( (toRelease - _data) % blockSize == 0 ) ;
*toRelease = _firstAvailableBlock ;
_firstAvailableBlock = static_cast<unsigned char>( (toRelease - _data)/blockSize) ;
// truncation check
assert(_firstAvailableBlock == (toRelease - _data)/blockSize);
++_blocksAvailable ;
}
void Chunk::printStatistics(int blockSize) const
{
std::cerr << " blocksAvailable : " << (int)_blocksAvailable << std::endl;
std::cerr << " firstBlockAvailable: " << (int)_firstAvailableBlock << std::endl;
std::cerr << " blocks : " << (void*)_data << " to " << (void*)(_data+BLOCKS_PER_CHUNK*blockSize) << std::endl;
}
FixedAllocator::FixedAllocator(size_t bytes)
{
_blockSize = bytes ;
_numBlocks = BLOCKS_PER_CHUNK ;
_allocChunk = -1 ;
_deallocChunk = -1 ;
}
FixedAllocator::~FixedAllocator()
{
for(uint32_t i=0;i<_chunks.size();++i)
{
_chunks[i]->free() ;
delete _chunks[i] ;
}
}
void *FixedAllocator::allocate()
{
if(_allocChunk < 0 || _chunks[_allocChunk]->_blocksAvailable == 0)
{
// find availabel memory in this chunk
//
uint32_t i ;
_allocChunk = -1 ;
for(i=0;i<_chunks.size();++i)
if(_chunks[i]->_blocksAvailable > 0) // found a chunk
{
_allocChunk = i ;
break ;
}
if( _allocChunk < 0 )
{
_chunks.reserve(_chunks.size()+1) ;
Chunk *newChunk = new Chunk;
if(newChunk == NULL)
{
std::cerr << "RsMemoryManagement: ran out of memory !" << std::endl;
exit(-1) ;
}
newChunk->init(_blockSize,_numBlocks) ;
_chunks.push_back(newChunk) ;
_allocChunk = _chunks.size()-1 ;
_deallocChunk = _chunks.size()-1 ;
}
}
assert(_chunks[_allocChunk] != NULL) ;
assert(_chunks[_allocChunk]->_blocksAvailable > 0) ;
return _chunks[_allocChunk]->allocate(_blockSize) ;
}
void FixedAllocator::deallocate(void *p)
{
if(_deallocChunk < 0 || !chunkOwnsPointer(*_chunks[_deallocChunk],p))
{
// find the chunk that contains this pointer. Perform a linear search.
_deallocChunk = -1 ;
for(uint32_t i=0;i<_chunks.size();++i)
if(chunkOwnsPointer(*_chunks[i],p))
{
_deallocChunk = i ;
break ;
}
}
assert(_chunks[_deallocChunk] != NULL) ;
_chunks[_deallocChunk]->deallocate(p,_blockSize) ;
if(_chunks[_deallocChunk]->_blocksAvailable == BLOCKS_PER_CHUNK)
{
_chunks[_deallocChunk]->free() ;
delete _chunks[_deallocChunk] ;
_chunks[_deallocChunk] = _chunks.back() ;
if(_allocChunk == _deallocChunk) _allocChunk = -1 ;
if(_allocChunk == ((int)_chunks.size())-1) _allocChunk = _deallocChunk ;
_deallocChunk = -1 ;
_chunks.pop_back();
}
}
void FixedAllocator::printStatistics() const
{
std::cerr << " numBLocks=" << (int)_numBlocks << std::endl;
std::cerr << " blockSize=" << (int)_blockSize << std::endl;
std::cerr << " Number of chunks: " << _chunks.size() << std::endl;
for(uint32_t i=0;i<_chunks.size();++i)
_chunks[i]->printStatistics(_blockSize) ;
}
SmallObjectAllocator::SmallObjectAllocator(size_t maxObjectSize)
: _maxObjectSize(maxObjectSize)
{
RsStackMutex m(SmallObject::_mtx) ;
_lastAlloc = NULL ;
_lastDealloc = NULL ;
_active = true ;
}
SmallObjectAllocator::~SmallObjectAllocator()
{
RsStackMutex m(SmallObject::_mtx) ;
for(std::map<int,FixedAllocator*>::const_iterator it(_pool.begin());it!=_pool.end();++it)
delete it->second ;
_active = false ;
}
void *SmallObjectAllocator::allocate(size_t bytes)
{
if(bytes > _maxObjectSize)
return malloc(bytes) ;
else if(_lastAlloc != NULL && _lastAlloc->blockSize() == bytes)
return _lastAlloc->allocate() ;
else
{
std::map<int,FixedAllocator*>::iterator it(_pool.find(bytes)) ;
if(it == _pool.end())
{
_pool[bytes] = new FixedAllocator(bytes) ;
it = _pool.find(bytes) ;
}
_lastAlloc = it->second ;
return it->second->allocate() ;
}
}
void SmallObjectAllocator::deallocate(void *p,size_t bytes)
{
if(bytes > _maxObjectSize)
free(p) ;
else if(_lastDealloc != NULL && _lastDealloc->blockSize() == bytes)
_lastDealloc->deallocate(p) ;
else
{
std::map<int,FixedAllocator*>::iterator it(_pool.find(bytes)) ;
if(it == _pool.end())
{
_pool[bytes] = new FixedAllocator(bytes) ;
it = _pool.find(bytes) ;
}
it->second->deallocate(p) ;
_lastDealloc = it->second ;
}
}
void SmallObjectAllocator::printStatistics() const
{
std::cerr << "RsMemoryManagement Statistics:" << std::endl;
std::cerr << " Total Fixed-size allocators: " << _pool.size() << std::endl;
std::cerr << "Pool" << std::endl;
for(std::map<int,FixedAllocator*>::const_iterator it(_pool.begin());it!=_pool.end();++it)
{
std::cerr << " Allocator for size " << it->first << " : " << std::endl;
std::cerr << " Last Alloc: " << _lastAlloc << std::endl;
std::cerr << " Last Dealloc: " << _lastDealloc << std::endl;
it->second->printStatistics() ;
}
}
void *SmallObject::operator new(size_t size)
{
#ifdef DEBUG_MEMORY
bool print=false ;
{
RsStackMutex m(_mtx) ;
static time_t last_time = 0 ;
time_t now = time(NULL) ;
if(now > last_time + 20)
{
last_time = now ;
print=true ;
}
}
if(print)
printStatistics() ;
#endif
RsStackMutex m(_mtx) ;
if(!_allocator._active)
return (void*)NULL;
void *p = _allocator.allocate(size) ;
#ifdef DEBUG_MEMORY
std::cerr << "new RsItem: " << p << ", size=" << size << std::endl;
#endif
return p ;
}
void SmallObject::operator delete(void *p,size_t size)
{
RsStackMutex m(_mtx) ;
if(!_allocator._active)
return ;
_allocator.deallocate(p,size) ;
#ifdef DEBUG_MEMORY
std::cerr << "del RsItem: " << p << ", size=" << size << std::endl;
#endif
}
void SmallObject::printStatistics()
{
RsStackMutex m(_mtx) ;
if(!_allocator._active)
return ;
_allocator.printStatistics() ;
}
void RsMemoryManagement::printStatistics()
{
SmallObject::printStatistics();
}