axmol/thirdparty/box2d-optimized/include/box2d/b2_slab_allocator.h

245 lines
6.7 KiB
C
Raw Normal View History

/*
* Copyright (c) 2014 Google, Inc.
*
* This software is provided 'as-is', without any express or implied
* warranty. In no event will the authors be held liable for any damages
* arising from the use of this software.
* Permission is granted to anyone to use this software for any purpose,
* including commercial applications, and to alter it and redistribute it
* freely, subject to the following restrictions:
* 1. The origin of this software must not be misrepresented; you must not
* claim that you wrote the original software. If you use this software
* in a product, an acknowledgment in the product documentation would be
* appreciated but is not required.
* 2. Altered source versions must be plainly marked as such, and must not be
* misrepresented as being the original software.
* 3. This notice may not be removed or altered from any source distribution.
*/
#ifndef B2_SLAB_ALLOCATOR_H
#define B2_SLAB_ALLOCATOR_H
#include <stddef.h>
#include <stdint.h>
#include <new>
#include "b2_intrusive_list.h"
#include "b2_free_list.h"
#include "b2_settings.h"
#include "b2_tracked_block.h"
/// Freelist based allocator for fixed sized items from slabs (memory
/// preallocated from the heap).
/// T should be a class which has a default constructor and implements the
/// member function "b2IntrusiveList* GetListNode()".
/// All objects in a slab are constructed when a slab is created and destructed
/// when a slab is freed.
template<typename T>
class b2SlabAllocator
{
private:
// Information about a slab.
class Slab
{
public:
/// Initialize a slab with the number of items it contains.
Slab(uint32 numberOfItems) :
m_numberOfItems(numberOfItems)
{
B2_NOT_USED(m_padding);
// This assumes that this class is packed on at least a 4-byte
// boundary with no padding. Verify the assumption.
b2Assert(sizeof(*this) == b2_mallocAlignment);
}
/// Empty destructor.
~Slab() { }
/// Get the number of items in this slab.
uint32 GetNumberOfItems() const { return m_numberOfItems; }
/// Get a pointer to the first item in the slab.
T* GetFirstItem() const
{
return (T*)((uint8*)(this + 1));
}
/// Get a pointer to the end of the slab.
/// NOTE: This is a pointer after the last byte of the slab not the
/// last item in the slab.
T* GetItemEnd() const { return GetFirstItem() + GetNumberOfItems(); }
private:
/// Number of items in the slab.
uint32 m_numberOfItems;
/// Padding to align the first item in the slab to b2_mallocAlignment.
uint8 m_padding[b2_mallocAlignment - sizeof(uint32)];
};
public:
/// Initialize the allocator to allocate itemsPerSlab of type T for each
/// slab that is allocated.
b2SlabAllocator(const uint32 itemsPerSlab) :
m_itemsPerSlab(itemsPerSlab)
{
}
/// Free all allocated slabs.
~b2SlabAllocator()
{
FreeAllSlabs();
}
/// Set size of the next allocated slab using the number of items per
/// slab. Setting this value to zero disables further slab allocation.
void SetItemsPerSlab(uint32 itemsPerSlab)
{
m_itemsPerSlab = itemsPerSlab;
}
// Get the size of the next allocated slab.
uint32 GetItemsPerSlab() const
{
return m_itemsPerSlab;
}
/// Allocate a item from the slab.
T* Allocate()
{
// Allocate a slab if needed here.
if (m_freeList.GetFreeList()->GetFreeList().IsEmpty() &&
!AllocateSlab())
return NULL;
return m_freeList.Allocate();
}
/// Free an item from the slab.
void Free(T *object)
{
m_freeList.Free(object);
}
/// Allocate a slab, construct instances of T and add them to the free
/// pool.
bool AllocateSlab()
{
if (!m_itemsPerSlab) return false;
const uint32 slabSize = sizeof(Slab) + (sizeof(T) * m_itemsPerSlab);
void* const memory = m_slabs.Allocate(slabSize);
if (!memory) return false;
Slab* const slab = new (BlockGetSlab(memory)) Slab(m_itemsPerSlab);
T* item = slab->GetFirstItem();
for (uint32 i = 0; i < m_itemsPerSlab; ++i, ++item)
{
m_freeList.AddToFreeList(new (item) T);
}
return true;
}
/// Free all slabs.
void FreeAllSlabs()
{
const b2TypedIntrusiveListNode<b2TrackedBlock>& slabList =
m_slabs.GetList();
while (!slabList.IsEmpty())
{
FreeSlab(BlockGetSlab(slabList.GetNext()->GetMemory()));
}
}
/// Free all empty slabs.
/// This method is slow - O(M^N) - since this class doesn't track
/// the association between each item and slab.
void FreeEmptySlabs()
{
const b2IntrusiveListNode& freeItemList =
m_freeList.GetFreeList()->GetFreeList();
const b2IntrusiveListNode* freeItemListTerminator =
freeItemList.GetTerminator();
const b2TypedIntrusiveListNode<b2TrackedBlock>& slabList =
m_slabs.GetList();
const b2TypedIntrusiveListNode<b2TrackedBlock>* slabListTerminator =
slabList.GetTerminator();
b2TrackedBlock* block = slabList.GetNext();
while (block != slabListTerminator)
{
// Get the Slab from the memory associated with the block.
Slab* const slab = BlockGetSlab(block->GetMemory());
block = block->GetNext();
// Determine the range of memory the Slab owns.
const uint8* const slabItemStart = (uint8*)slab->GetFirstItem();
const uint8* const slabItemEnd = (uint8*)slab->GetItemEnd();
// Count all free items that are owned by the current slab.
uint8 freeItems = 0;
bool empty = false;
for (b2IntrusiveListNode* itemNode = freeItemList.GetNext();
itemNode != freeItemListTerminator;
itemNode = itemNode->GetNext())
{
const uint8* itemNodeAddress = (uint8*)itemNode;
if (itemNodeAddress >= slabItemStart &&
itemNodeAddress <= slabItemEnd)
{
++freeItems;
if (slab->GetNumberOfItems() == freeItems)
{
empty = true;
break;
}
}
}
// If a slab is empty, free it.
if (empty)
{
FreeSlab(slab);
}
}
}
/// Get the item allocator freelist.
const b2TypedFreeList<T>& GetFreeList() const
{
return m_freeList;
}
private:
/// Destroy all objects in a slab and free the slab.
void FreeSlab(Slab * const slab)
{
b2Assert(slab);
const uint32 numberOfItems = slab->GetNumberOfItems();
T* item = slab->GetFirstItem();
for (uint32 i = 0; i < numberOfItems; ++i, ++item)
{
item->~T();
}
slab->~Slab();
m_slabs.Free(slab);
}
/// Get a pointer to a Slab from a block of memory in m_slabs.
Slab* BlockGetSlab(void *memory)
{
return (Slab*)memory;
}
/// Get a pointer to the first item in the array of items referenced by a
/// Slab.
T* SlabGetFirstItem(Slab* slab)
{
return (T*)(slab + 1);
}
private:
/// Contains a list of b2TrackedBlock instances where each b2TrackedBlock's
/// associated user memory contains a Slab followed by instances of T.
b2TrackedBlockAllocator m_slabs;
/// Number of items to allocate in the next allocated slab.
uint32 m_itemsPerSlab;
/// Freelist which contains instances of T.
b2TypedFreeList<T> m_freeList;
};
#endif // B2_SLAB_ALLOCATOR_H