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jinx/Ryujinx.HLE/HOS/Kernel/Memory/KMemoryRegionManager.cs
Berkan Diler 98c838b24c
Use BitOperations methods and delete now unused BitUtils methods (#3134)
Replaces BitUtils.CountTrailingZeros/CountLeadingZeros/IsPowerOfTwo with BitOperations methods
2022-02-18 02:35:23 +01:00

560 lines
No EOL
18 KiB
C#

using Ryujinx.Common;
using Ryujinx.HLE.HOS.Kernel.Common;
using System.Diagnostics;
using System.Numerics;
namespace Ryujinx.HLE.HOS.Kernel.Memory
{
class KMemoryRegionManager
{
private static readonly int[] BlockOrders = new int[] { 12, 16, 21, 22, 25, 29, 30 };
public ulong Address { get; private set; }
public ulong EndAddr { get; private set; }
public ulong Size { get; private set; }
private int _blockOrdersCount;
private readonly KMemoryRegionBlock[] _blocks;
private readonly ushort[] _pageReferenceCounts;
public KMemoryRegionManager(ulong address, ulong size, ulong endAddr)
{
_blocks = new KMemoryRegionBlock[BlockOrders.Length];
Address = address;
Size = size;
EndAddr = endAddr;
_blockOrdersCount = BlockOrders.Length;
for (int blockIndex = 0; blockIndex < _blockOrdersCount; blockIndex++)
{
_blocks[blockIndex] = new KMemoryRegionBlock();
_blocks[blockIndex].Order = BlockOrders[blockIndex];
int nextOrder = blockIndex == _blockOrdersCount - 1 ? 0 : BlockOrders[blockIndex + 1];
_blocks[blockIndex].NextOrder = nextOrder;
int currBlockSize = 1 << BlockOrders[blockIndex];
int nextBlockSize = currBlockSize;
if (nextOrder != 0)
{
nextBlockSize = 1 << nextOrder;
}
ulong startAligned = BitUtils.AlignDown(address, nextBlockSize);
ulong endAddrAligned = BitUtils.AlignDown(endAddr, currBlockSize);
ulong sizeInBlocksTruncated = (endAddrAligned - startAligned) >> BlockOrders[blockIndex];
ulong endAddrRounded = BitUtils.AlignUp(address + size, nextBlockSize);
ulong sizeInBlocksRounded = (endAddrRounded - startAligned) >> BlockOrders[blockIndex];
_blocks[blockIndex].StartAligned = startAligned;
_blocks[blockIndex].SizeInBlocksTruncated = sizeInBlocksTruncated;
_blocks[blockIndex].SizeInBlocksRounded = sizeInBlocksRounded;
ulong currSizeInBlocks = sizeInBlocksRounded;
int maxLevel = 0;
do
{
maxLevel++;
}
while ((currSizeInBlocks /= 64) != 0);
_blocks[blockIndex].MaxLevel = maxLevel;
_blocks[blockIndex].Masks = new long[maxLevel][];
currSizeInBlocks = sizeInBlocksRounded;
for (int level = maxLevel - 1; level >= 0; level--)
{
currSizeInBlocks = (currSizeInBlocks + 63) / 64;
_blocks[blockIndex].Masks[level] = new long[currSizeInBlocks];
}
}
_pageReferenceCounts = new ushort[size / KPageTableBase.PageSize];
if (size != 0)
{
FreePages(address, size / KPageTableBase.PageSize);
}
}
public KernelResult AllocatePages(ulong pagesCount, bool backwards, out KPageList pageList)
{
lock (_blocks)
{
KernelResult result = AllocatePagesImpl(pagesCount, backwards, out pageList);
if (result == KernelResult.Success)
{
foreach (var node in pageList)
{
IncrementPagesReferenceCount(node.Address, node.PagesCount);
}
}
return result;
}
}
public ulong AllocatePagesContiguous(KernelContext context, ulong pagesCount, bool backwards)
{
lock (_blocks)
{
ulong address = AllocatePagesContiguousImpl(pagesCount, backwards);
if (address != 0)
{
IncrementPagesReferenceCount(address, pagesCount);
context.Memory.Commit(address - DramMemoryMap.DramBase, pagesCount * KPageTableBase.PageSize);
}
return address;
}
}
private KernelResult AllocatePagesImpl(ulong pagesCount, bool backwards, out KPageList pageList)
{
pageList = new KPageList();
if (_blockOrdersCount > 0)
{
if (GetFreePagesImpl() < pagesCount)
{
return KernelResult.OutOfMemory;
}
}
else if (pagesCount != 0)
{
return KernelResult.OutOfMemory;
}
for (int blockIndex = _blockOrdersCount - 1; blockIndex >= 0; blockIndex--)
{
KMemoryRegionBlock block = _blocks[blockIndex];
ulong bestFitBlockSize = 1UL << block.Order;
ulong blockPagesCount = bestFitBlockSize / KPageTableBase.PageSize;
// Check if this is the best fit for this page size.
// If so, try allocating as much requested pages as possible.
while (blockPagesCount <= pagesCount)
{
ulong address = AllocatePagesForOrder(blockIndex, backwards, bestFitBlockSize);
// The address being zero means that no free space was found on that order,
// just give up and try with the next one.
if (address == 0)
{
break;
}
// Add new allocated page(s) to the pages list.
// If an error occurs, then free all allocated pages and fail.
KernelResult result = pageList.AddRange(address, blockPagesCount);
if (result != KernelResult.Success)
{
FreePages(address, blockPagesCount);
foreach (KPageNode pageNode in pageList)
{
FreePages(pageNode.Address, pageNode.PagesCount);
}
return result;
}
pagesCount -= blockPagesCount;
}
}
// Success case, all requested pages were allocated successfully.
if (pagesCount == 0)
{
return KernelResult.Success;
}
// Error case, free allocated pages and return out of memory.
foreach (KPageNode pageNode in pageList)
{
FreePages(pageNode.Address, pageNode.PagesCount);
}
pageList = null;
return KernelResult.OutOfMemory;
}
private ulong AllocatePagesContiguousImpl(ulong pagesCount, bool backwards)
{
if (pagesCount == 0 || _blocks.Length < 1)
{
return 0;
}
int blockIndex = 0;
while ((1UL << _blocks[blockIndex].Order) / KPageTableBase.PageSize < pagesCount)
{
if (++blockIndex >= _blocks.Length)
{
return 0;
}
}
ulong tightestFitBlockSize = 1UL << _blocks[blockIndex].Order;
ulong address = AllocatePagesForOrder(blockIndex, backwards, tightestFitBlockSize);
ulong requiredSize = pagesCount * KPageTableBase.PageSize;
if (address != 0 && tightestFitBlockSize > requiredSize)
{
FreePages(address + requiredSize, (tightestFitBlockSize - requiredSize) / KPageTableBase.PageSize);
}
return address;
}
private ulong AllocatePagesForOrder(int blockIndex, bool backwards, ulong bestFitBlockSize)
{
ulong address = 0;
KMemoryRegionBlock block = null;
for (int currBlockIndex = blockIndex;
currBlockIndex < _blockOrdersCount && address == 0;
currBlockIndex++)
{
block = _blocks[currBlockIndex];
int index = 0;
bool zeroMask = false;
for (int level = 0; level < block.MaxLevel; level++)
{
long mask = block.Masks[level][index];
if (mask == 0)
{
zeroMask = true;
break;
}
if (backwards)
{
index = (index * 64 + 63) - BitOperations.LeadingZeroCount((ulong)mask);
}
else
{
index = index * 64 + BitOperations.LeadingZeroCount((ulong)BitUtils.ReverseBits64(mask));
}
}
if (block.SizeInBlocksTruncated <= (ulong)index || zeroMask)
{
continue;
}
block.FreeCount--;
int tempIdx = index;
for (int level = block.MaxLevel - 1; level >= 0; level--, tempIdx /= 64)
{
block.Masks[level][tempIdx / 64] &= ~(1L << (tempIdx & 63));
if (block.Masks[level][tempIdx / 64] != 0)
{
break;
}
}
address = block.StartAligned + ((ulong)index << block.Order);
}
for (int currBlockIndex = blockIndex;
currBlockIndex < _blockOrdersCount && address == 0;
currBlockIndex++)
{
block = _blocks[currBlockIndex];
int index = 0;
bool zeroMask = false;
for (int level = 0; level < block.MaxLevel; level++)
{
long mask = block.Masks[level][index];
if (mask == 0)
{
zeroMask = true;
break;
}
if (backwards)
{
index = index * 64 + BitOperations.LeadingZeroCount((ulong)BitUtils.ReverseBits64(mask));
}
else
{
index = (index * 64 + 63) - BitOperations.LeadingZeroCount((ulong)mask);
}
}
if (block.SizeInBlocksTruncated <= (ulong)index || zeroMask)
{
continue;
}
block.FreeCount--;
int tempIdx = index;
for (int level = block.MaxLevel - 1; level >= 0; level--, tempIdx /= 64)
{
block.Masks[level][tempIdx / 64] &= ~(1L << (tempIdx & 63));
if (block.Masks[level][tempIdx / 64] != 0)
{
break;
}
}
address = block.StartAligned + ((ulong)index << block.Order);
}
if (address != 0)
{
// If we are using a larger order than best fit, then we should
// split it into smaller blocks.
ulong firstFreeBlockSize = 1UL << block.Order;
if (firstFreeBlockSize > bestFitBlockSize)
{
FreePages(address + bestFitBlockSize, (firstFreeBlockSize - bestFitBlockSize) / KPageTableBase.PageSize);
}
}
return address;
}
private void FreePages(ulong address, ulong pagesCount)
{
lock (_blocks)
{
ulong endAddr = address + pagesCount * KPageTableBase.PageSize;
int blockIndex = _blockOrdersCount - 1;
ulong addressRounded = 0;
ulong endAddrTruncated = 0;
for (; blockIndex >= 0; blockIndex--)
{
KMemoryRegionBlock allocInfo = _blocks[blockIndex];
int blockSize = 1 << allocInfo.Order;
addressRounded = BitUtils.AlignUp (address, blockSize);
endAddrTruncated = BitUtils.AlignDown(endAddr, blockSize);
if (addressRounded < endAddrTruncated)
{
break;
}
}
void FreeRegion(ulong currAddress)
{
for (int currBlockIndex = blockIndex;
currBlockIndex < _blockOrdersCount && currAddress != 0;
currBlockIndex++)
{
KMemoryRegionBlock block = _blocks[currBlockIndex];
block.FreeCount++;
ulong freedBlocks = (currAddress - block.StartAligned) >> block.Order;
int index = (int)freedBlocks;
for (int level = block.MaxLevel - 1; level >= 0; level--, index /= 64)
{
long mask = block.Masks[level][index / 64];
block.Masks[level][index / 64] = mask | (1L << (index & 63));
if (mask != 0)
{
break;
}
}
int blockSizeDelta = 1 << (block.NextOrder - block.Order);
int freedBlocksTruncated = BitUtils.AlignDown((int)freedBlocks, blockSizeDelta);
if (!block.TryCoalesce(freedBlocksTruncated, blockSizeDelta))
{
break;
}
currAddress = block.StartAligned + ((ulong)freedBlocksTruncated << block.Order);
}
}
// Free inside aligned region.
ulong baseAddress = addressRounded;
while (baseAddress < endAddrTruncated)
{
ulong blockSize = 1UL << _blocks[blockIndex].Order;
FreeRegion(baseAddress);
baseAddress += blockSize;
}
int nextBlockIndex = blockIndex - 1;
// Free region between Address and aligned region start.
baseAddress = addressRounded;
for (blockIndex = nextBlockIndex; blockIndex >= 0; blockIndex--)
{
ulong blockSize = 1UL << _blocks[blockIndex].Order;
while (baseAddress - blockSize >= address)
{
baseAddress -= blockSize;
FreeRegion(baseAddress);
}
}
// Free region between aligned region end and End Address.
baseAddress = endAddrTruncated;
for (blockIndex = nextBlockIndex; blockIndex >= 0; blockIndex--)
{
ulong blockSize = 1UL << _blocks[blockIndex].Order;
while (baseAddress + blockSize <= endAddr)
{
FreeRegion(baseAddress);
baseAddress += blockSize;
}
}
}
}
public ulong GetFreePages()
{
lock (_blocks)
{
return GetFreePagesImpl();
}
}
private ulong GetFreePagesImpl()
{
ulong availablePages = 0;
for (int blockIndex = 0; blockIndex < _blockOrdersCount; blockIndex++)
{
KMemoryRegionBlock block = _blocks[blockIndex];
ulong blockPagesCount = (1UL << block.Order) / KPageTableBase.PageSize;
availablePages += blockPagesCount * block.FreeCount;
}
return availablePages;
}
public void IncrementPagesReferenceCount(ulong address, ulong pagesCount)
{
ulong index = GetPageOffset(address);
ulong endIndex = index + pagesCount;
while (index < endIndex)
{
ushort referenceCount = ++_pageReferenceCounts[index];
Debug.Assert(referenceCount >= 1);
index++;
}
}
public void DecrementPagesReferenceCount(ulong address, ulong pagesCount)
{
ulong index = GetPageOffset(address);
ulong endIndex = index + pagesCount;
ulong freeBaseIndex = 0;
ulong freePagesCount = 0;
while (index < endIndex)
{
Debug.Assert(_pageReferenceCounts[index] > 0);
ushort referenceCount = --_pageReferenceCounts[index];
if (referenceCount == 0)
{
if (freePagesCount != 0)
{
freePagesCount++;
}
else
{
freeBaseIndex = index;
freePagesCount = 1;
}
}
else if (freePagesCount != 0)
{
FreePages(Address + freeBaseIndex * KPageTableBase.PageSize, freePagesCount);
freePagesCount = 0;
}
index++;
}
if (freePagesCount != 0)
{
FreePages(Address + freeBaseIndex * KPageTableBase.PageSize, freePagesCount);
}
}
public ulong GetPageOffset(ulong address)
{
return (address - Address) / KPageTableBase.PageSize;
}
public ulong GetPageOffsetFromEnd(ulong address)
{
return (EndAddr - address) / KPageTableBase.PageSize;
}
}
}