Rasagar/Library/PackageCache/com.unity.collections/Unity.Collections/AutoFreeAllocator.cs
2024-08-26 23:07:20 +03:00

265 lines
9.7 KiB
C#

using System;
using System.Diagnostics;
using System.Threading;
using AOT;
using Unity.Burst;
using Unity.Collections.LowLevel.Unsafe;
using Unity.Mathematics;
namespace Unity.Collections
{
unsafe internal struct ArrayOfArrays<T> : IDisposable where T : unmanaged
{
AllocatorManager.AllocatorHandle m_backingAllocatorHandle;
int m_lengthInElements;
int m_capacityInElements;
int m_log2BlockSizeInElements;
int m_blocks;
IntPtr* m_block;
int BlockSizeInElements => 1 << m_log2BlockSizeInElements;
int BlockSizeInBytes => BlockSizeInElements * sizeof(T);
int BlockMask => BlockSizeInElements - 1;
public int Length => m_lengthInElements;
public int Capacity => m_capacityInElements;
public ArrayOfArrays(int capacityInElements, AllocatorManager.AllocatorHandle backingAllocatorHandle, int log2BlockSizeInElements = 12)
{
this = default;
m_backingAllocatorHandle = backingAllocatorHandle;
m_lengthInElements = 0;
m_capacityInElements = capacityInElements;
m_log2BlockSizeInElements = log2BlockSizeInElements;
m_blocks = (capacityInElements + BlockMask) >> m_log2BlockSizeInElements;
m_block = (IntPtr*)Memory.Unmanaged.Allocate(sizeof(IntPtr) * m_blocks, 16, m_backingAllocatorHandle);
UnsafeUtility.MemSet(m_block, 0, sizeof(IntPtr) * m_blocks);
}
public void LockfreeAdd(T t)
{
var elementIndex = Interlocked.Increment(ref m_lengthInElements) - 1;
var blockIndex = BlockIndexOfElement(elementIndex);
CheckBlockIndex(blockIndex);
if(m_block[blockIndex] == IntPtr.Zero)
{
void* pointer = Memory.Unmanaged.Allocate(BlockSizeInBytes, 16, m_backingAllocatorHandle); // $$$!
var lastBlock = math.min(m_blocks, blockIndex + 4); // don't overgrow too fast, simply to avoid a $$$ free
for(; blockIndex < lastBlock; ++blockIndex)
if(IntPtr.Zero == Interlocked.CompareExchange(ref m_block[blockIndex], (IntPtr)pointer, IntPtr.Zero))
break; // install the new block, into *any* empty slot available, to avoid wasting the time we spent on malloc
if(blockIndex == lastBlock)
Memory.Unmanaged.Free(pointer, m_backingAllocatorHandle); // $$$, only if absolutely necessary
}
this[elementIndex] = t;
}
public ref T this[int elementIndex]
{
get
{
CheckElementIndex(elementIndex);
var blockIndex = BlockIndexOfElement(elementIndex);
CheckBlockIndex(blockIndex);
CheckBlockIsNotNull(blockIndex);
IntPtr blockIntPtr = m_block[blockIndex];
var elementIndexInBlock = elementIndex & BlockMask;
T* blockPointer = (T*)blockIntPtr;
return ref blockPointer[elementIndexInBlock];
}
}
public void Rewind()
{
m_lengthInElements = 0;
}
public void Clear()
{
Rewind();
for(var i = 0; i < m_blocks; ++i)
if(m_block[i] != IntPtr.Zero)
{
Memory.Unmanaged.Free((void*)m_block[i], m_backingAllocatorHandle);
m_block[i] = IntPtr.Zero;
}
}
public void Dispose()
{
Clear();
Memory.Unmanaged.Free(m_block, m_backingAllocatorHandle);
}
[Conditional("ENABLE_UNITY_COLLECTIONS_CHECKS"), Conditional("UNITY_DOTS_DEBUG")]
void CheckElementIndex(int elementIndex)
{
if (elementIndex >= m_lengthInElements)
throw new ArgumentException($"Element index {elementIndex} must be less than length in elements {m_lengthInElements}.");
}
[Conditional("ENABLE_UNITY_COLLECTIONS_CHECKS"), Conditional("UNITY_DOTS_DEBUG")]
void CheckBlockIndex(int blockIndex)
{
if (blockIndex >= m_blocks)
throw new ArgumentException($"Block index {blockIndex} must be less than number of blocks {m_blocks}.");
}
[Conditional("ENABLE_UNITY_COLLECTIONS_CHECKS"), Conditional("UNITY_DOTS_DEBUG")]
void CheckBlockIsNotNull(int blockIndex)
{
if(m_block[blockIndex] == IntPtr.Zero)
throw new ArgumentException($"Block index {blockIndex} is a null pointer.");
}
public void RemoveAtSwapBack(int elementIndex)
{
this[elementIndex] = this[Length-1];
--m_lengthInElements;
}
int BlockIndexOfElement(int elementIndex)
{
return elementIndex >> m_log2BlockSizeInElements;
}
public void TrimExcess()
{
for(var blockIndex = BlockIndexOfElement(m_lengthInElements + BlockMask); blockIndex < m_blocks; ++blockIndex)
{
CheckBlockIndex(blockIndex);
if(m_block[blockIndex] != IntPtr.Zero)
{
var blockIntPtr = m_block[blockIndex];
void* blockPointer = (void*)blockIntPtr;
Memory.Unmanaged.Free(blockPointer, m_backingAllocatorHandle);
m_block[blockIndex] = IntPtr.Zero;
}
}
}
}
[BurstCompile]
internal struct AutoFreeAllocator : AllocatorManager.IAllocator
{
ArrayOfArrays<IntPtr> m_allocated;
ArrayOfArrays<IntPtr> m_tofree;
AllocatorManager.AllocatorHandle m_handle;
AllocatorManager.AllocatorHandle m_backingAllocatorHandle;
unsafe public void Update()
{
for(var i = m_tofree.Length; i --> 0;)
for(var j = m_allocated.Length; j --> 0;)
if(m_allocated[j] == m_tofree[i])
{
Memory.Unmanaged.Free((void*)m_tofree[i], m_backingAllocatorHandle);
m_allocated.RemoveAtSwapBack(j);
break;
}
m_tofree.Rewind();
m_allocated.TrimExcess();
}
unsafe public void Initialize(AllocatorManager.AllocatorHandle backingAllocatorHandle)
{
m_allocated = new ArrayOfArrays<IntPtr>(1024 * 1024, backingAllocatorHandle);
m_tofree = new ArrayOfArrays<IntPtr>(128 * 1024, backingAllocatorHandle);
m_backingAllocatorHandle = backingAllocatorHandle;
}
unsafe public void FreeAll()
{
Update();
m_handle.Rewind();
for(var i = 0; i < m_allocated.Length; ++i)
Memory.Unmanaged.Free((void*) m_allocated[i], m_backingAllocatorHandle);
m_allocated.Rewind();
}
/// <summary>
/// Dispose the allocator. This must be called to free the memory blocks that were allocated from the system.
/// </summary>
public void Dispose()
{
FreeAll();
m_tofree.Dispose();
m_allocated.Dispose();
}
/// <summary>
/// The allocator function. It can allocate, deallocate, or reallocate.
/// </summary>
public AllocatorManager.TryFunction Function => Try;
/// <summary>
/// Invoke the allocator function.
/// </summary>
/// <param name="block">The block to allocate, deallocate, or reallocate. See <see cref="AllocatorManager.Try"/></param>
/// <returns>0 if successful. Otherwise, returns the error code from the allocator function.</returns>
public int Try(ref AllocatorManager.Block block)
{
unsafe
{
if (block.Range.Pointer == IntPtr.Zero)
{
if (block.Bytes == 0)
{
return 0;
}
var ptr = (byte*)Memory.Unmanaged.Allocate(block.Bytes, block.Alignment, m_backingAllocatorHandle);
block.Range.Pointer = (IntPtr)ptr;
block.AllocatedItems = block.Range.Items;
m_allocated.LockfreeAdd(block.Range.Pointer);
return 0;
}
if (block.Range.Items == 0)
{
m_tofree.LockfreeAdd(block.Range.Pointer);
block.Range.Pointer = IntPtr.Zero;
block.AllocatedItems = 0;
return 0;
}
return -1;
}
}
[BurstCompile]
[MonoPInvokeCallback(typeof(AllocatorManager.TryFunction))]
internal static int Try(IntPtr state, ref AllocatorManager.Block block)
{
unsafe { return ((AutoFreeAllocator*)state)->Try(ref block); }
}
/// <summary>
/// This allocator.
/// </summary>
/// <value>This allocator.</value>
public AllocatorManager.AllocatorHandle Handle { get { return m_handle; } set { m_handle = value; } }
/// <summary>
/// Cast the Allocator index into Allocator
/// </summary>
public Allocator ToAllocator { get { return m_handle.ToAllocator; } }
/// <summary>
/// Check whether an allocator is a custom allocator
/// </summary>
public bool IsCustomAllocator { get { return m_handle.IsCustomAllocator; } }
/// <summary>
/// Check whether this allocator will automatically dispose allocations.
/// </summary>
/// <remarks>Allocations made by Auto free allocator are automatically disposed.</remarks>
/// <value>Always true</value>
public bool IsAutoDispose { get { return true; } }
}
}