jedi-academy/code/Ratl/handle_pool_vs.h
2013-04-23 21:59:37 +10:00

291 lines
9.3 KiB
C++

////////////////////////////////////////////////////////////////////////////////////////
// RAVEN STANDARD TEMPLATE LIBRARY
// (c) 2002 Activision
//
//
// Handle Pool
// -----------
// The memory pool class is a simple routine for constant time allocation and deallocation
// from a fixed size pool of objects. The class uses a simple array to hold the actual
// data, a queue for the free list, and a bit field to mark which spots in the array
// are allocated.
//
// In addition to the standard memory pool features, this Handle Pool provides a fast
// iterator, asserts on attempting to access unused data, and a unique ID "handle" for
// the external system to use.
//
//
//
// NOTES:
//
//
//
////////////////////////////////////////////////////////////////////////////////////////
#if !defined(RATL_HANDLE_POOL_VS_INC)
#define RATL_HANDLE_POOL_VS_INC
////////////////////////////////////////////////////////////////////////////////////////
// Includes
////////////////////////////////////////////////////////////////////////////////////////
#if !defined(RATL_COMMON_INC)
#include "ratl_common.h"
#endif
#if !defined(RATL_POOL_VS_INC)
#include "pool_vs.h"
#endif
namespace ratl
{
template <class T>
class handle_pool_base : public pool_root<T>
{
public:
typedef T TStorageTraits;
typedef typename T::TValue TTValue;
////////////////////////////////////////////////////////////////////////////////////
// Capacity Enum
////////////////////////////////////////////////////////////////////////////////////
enum
{
CAPACITY = T::CAPACITY
};
private:
int mHandles[CAPACITY];
int mMASK_HANDLE_TO_INDEX;
int mMASK_NUM_BITS;
void IncHandle(int index)
{
mHandles[index] += (1<<mMASK_NUM_BITS);
if (mHandles[index]<0)
{
// we rolled over
mHandles[index] = index; // Reset The ID Counter
mHandles[index] |= (1<<mMASK_NUM_BITS);
}
}
public:
////////////////////////////////////////////////////////////////////////////////////
// Constructor
//
// We need a routine to calculate the MASK used to convert a handle to an index and
// the number of bits needed to shift by.
//
////////////////////////////////////////////////////////////////////////////////////
handle_pool_base()
{
mMASK_HANDLE_TO_INDEX = 0;
mMASK_NUM_BITS = 0;
int value=CAPACITY-1;
while(value)
{
value>>= 1;
mMASK_HANDLE_TO_INDEX <<= 1;
mMASK_HANDLE_TO_INDEX |= 1;
mMASK_NUM_BITS++;
}
for (int i=0; i<CAPACITY; i++)
{
#ifdef _DEBUG
mHandles[i] = i; // Reset The ID Counter
mHandles[i] |= ((++HandleSaltValue)<<mMASK_NUM_BITS);
#else
mHandles[i] = i; // Reset The ID Counter
mHandles[i] |= (1<<mMASK_NUM_BITS);
#endif
}
}
////////////////////////////////////////////////////////////////////////////////////
// Clear - Removes all allocation information
////////////////////////////////////////////////////////////////////////////////////
void clear()
{
pool_root<T>::clear();
// note that we do not refill the handles cause we want old handles to still be stale
for (int i=0; i<CAPACITY; i++)
{
IncHandle(i);
}
}
////////////////////////////////////////////////////////////////////////////////////
// Constant Accessor
////////////////////////////////////////////////////////////////////////////////////
const TTValue& operator[](int handle) const
{
assert(is_used(handle)); //typically this is a stale handle (already been freed)
return this->value_at_index(handle&mMASK_HANDLE_TO_INDEX);
}
////////////////////////////////////////////////////////////////////////////////////
// Accessor
////////////////////////////////////////////////////////////////////////////////////
TTValue& operator[](int i)
{
assert(is_used(i)); //typically this is a stale handle (already been freed)
return this->value_at_index(i&mMASK_HANDLE_TO_INDEX);
}
bool is_used(int i) const
{
if (mHandles[i&mMASK_HANDLE_TO_INDEX]==i)
{
return this->is_used_index(i&mMASK_HANDLE_TO_INDEX);
}
return false;
}
////////////////////////////////////////////////////////////////////////////////////
// Swap two items based on handle
////////////////////////////////////////////////////////////////////////////////////
void swap(int i,int j)
{
assert(is_used(i)); //typically this is a stale handle (already been freed)
assert(is_used(j)); //typically this is a stale handle (already been freed)
swap_index(handle_to_index(i),handle_to_index(j));
}
////////////////////////////////////////////////////////////////////////////////////
// The Allocator returns a handle
////////////////////////////////////////////////////////////////////////////////////
int alloc()
{
int index=this->alloc_index();
return mHandles[index];
}
////////////////////////////////////////////////////////////////////////////////////
// The Allocator, with value, returns a handle
////////////////////////////////////////////////////////////////////////////////////
int alloc(const TTValue &v)
{
int index=alloc_index(v);
return mHandles[index];
}
////////////////////////////////////////////////////////////////////////////////////
// The Deallocator, by index, not something generally needed
////////////////////////////////////////////////////////////////////////////////////
void free_index(int index)
{
pool_root<T>::free_index(index);
IncHandle(index);
}
////////////////////////////////////////////////////////////////////////////////////
// The Deallocator, by handle
////////////////////////////////////////////////////////////////////////////////////
void free(int handle)
{
assert(is_used(handle));
free_index(handle&mMASK_HANDLE_TO_INDEX);
}
////////////////////////////////////////////////////////////////////////////////////
// The Deallocator, by pointer
////////////////////////////////////////////////////////////////////////////////////
void free(TTValue *me)
{
free_index(pointer_to_index(me));
}
////////////////////////////////////////////////////////////////////////////////////
// Convert a handle to a raw index, not generally something you should use
////////////////////////////////////////////////////////////////////////////////////
int handle_to_index(int handle) const
{
assert(is_used(handle));
return (handle&mMASK_HANDLE_TO_INDEX);
}
////////////////////////////////////////////////////////////////////////////////////
// FInd the handle for a given index, this cannot check for stale handles, so it is ill advised
////////////////////////////////////////////////////////////////////////////////////
int index_to_handle(int index) const
{
assert(index>=0 && index<CAPACITY && is_used_index(index)); //disallowing this on stale handles
return (mHandles[index]);
}
////////////////////////////////////////////////////////////////////////////////////
// converts a T pointer to a handle, generally not something you need, cannot check for stale handles
////////////////////////////////////////////////////////////////////////////////////
int pointer_to_handle(const TTValue *me) const
{
return index_to_handle(pointer_to_index(me));
}
////////////////////////////////////////////////////////////////////////////////////
// converts a T pointer to a handle, generally not something you need, cannot check for stale handles
////////////////////////////////////////////////////////////////////////////////////
int pointer_to_handle(const TRatlNew *me) const
{
return this->index_to_handle(this->pointer_to_index(me));
}
////////////////////////////////////////////////////////////////////////////////////
// Get An Iterator To The Object At handle
////////////////////////////////////////////////////////////////////////////////////
typename pool_root<T>::iterator at(int handle)
{
assert(is_used(handle));
return this->at_index(handle&mMASK_HANDLE_TO_INDEX);
}
////////////////////////////////////////////////////////////////////////////////////
// Get An Iterator To The Object At handle
////////////////////////////////////////////////////////////////////////////////////
typename pool_root<T>::const_iterator at(int handle) const
{
assert(is_used(handle));
return this->at_index(handle&mMASK_HANDLE_TO_INDEX);
}
};
template<class T, int ARG_CAPACITY>
class handle_pool_vs : public handle_pool_base<storage::value_semantics<T,ARG_CAPACITY> >
{
public:
typedef typename storage::value_semantics<T,ARG_CAPACITY> TStorageTraits;
typedef typename TStorageTraits::TValue TTValue;
enum
{
CAPACITY = ARG_CAPACITY
};
handle_pool_vs() {}
};
template<class T, int ARG_CAPACITY>
class handle_pool_os : public handle_pool_base<storage::object_semantics<T,ARG_CAPACITY> >
{
public:
typedef typename storage::object_semantics<T,ARG_CAPACITY> TStorageTraits;
typedef typename TStorageTraits::TValue TTValue;
enum
{
CAPACITY = ARG_CAPACITY
};
handle_pool_os() {}
};
template<class T, int ARG_CAPACITY, int ARG_MAX_CLASS_SIZE>
class handle_pool_is : public handle_pool_base<storage::virtual_semantics<T,ARG_CAPACITY,ARG_MAX_CLASS_SIZE> >
{
public:
typedef typename storage::virtual_semantics<T,ARG_CAPACITY,ARG_MAX_CLASS_SIZE> TStorageTraits;
typedef typename TStorageTraits::TValue TTValue;
enum
{
CAPACITY = ARG_CAPACITY,
MAX_CLASS_SIZE = ARG_MAX_CLASS_SIZE
};
handle_pool_is() {}
};
}
#endif