ryujinx/Ryujinx.HLE/HOS/Kernel/Memory/KPageTableBase.cs
gdkchan 95017b8c66
Support memory aliasing (#2954)
* Back to the origins: Make memory manager take guest PA rather than host address once again

* Direct mapping with alias support on Windows

* Fixes and remove more of the emulated shared memory

* Linux support

* Make shared and transfer memory not depend on SharedMemoryStorage

* More efficient view mapping on Windows (no more restricted to 4KB pages at a time)

* Handle potential access violations caused by partial unmap

* Implement host mapping using shared memory on Linux

* Add new GetPhysicalAddressChecked method, used to ensure the virtual address is mapped before address translation

Also align GetRef behaviour with software memory manager

* We don't need a mirrorable memory block for software memory manager mode

* Disable memory aliasing tests while we don't have shared memory support on Mac

* Shared memory & SIGBUS handler for macOS

* Fix typo + nits + re-enable memory tests

* Set MAP_JIT_DARWIN on x86 Mac too

* Add back the address space mirror

* Only set MAP_JIT_DARWIN if we are mapping as executable

* Disable aliasing tests again (still fails on Mac)

* Fix UnmapView4KB (by not casting size to int)

* Use ref counting on memory blocks to delay closing the shared memory handle until all blocks using it are disposed

* Address PR feedback

* Make RO hold a reference to the guest process memory manager to avoid early disposal

Co-authored-by: nastys <nastys@users.noreply.github.com>
2022-05-02 20:30:02 -03:00

2850 lines
99 KiB
C#

using Ryujinx.Common;
using Ryujinx.HLE.HOS.Kernel.Common;
using Ryujinx.HLE.HOS.Kernel.Process;
using System;
using System.Collections.Generic;
using System.Diagnostics;
namespace Ryujinx.HLE.HOS.Kernel.Memory
{
abstract class KPageTableBase
{
private static readonly int[] MappingUnitSizes = new int[]
{
0x1000,
0x10000,
0x200000,
0x400000,
0x2000000,
0x40000000
};
public const int PageSize = 0x1000;
private const int KMemoryBlockSize = 0x40;
// We need 2 blocks for the case where a big block
// needs to be split in 2, plus one block that will be the new one inserted.
private const int MaxBlocksNeededForInsertion = 2;
protected readonly KernelContext Context;
public ulong AddrSpaceStart { get; private set; }
public ulong AddrSpaceEnd { get; private set; }
public ulong CodeRegionStart { get; private set; }
public ulong CodeRegionEnd { get; private set; }
public ulong HeapRegionStart { get; private set; }
public ulong HeapRegionEnd { get; private set; }
private ulong _currentHeapAddr;
public ulong AliasRegionStart { get; private set; }
public ulong AliasRegionEnd { get; private set; }
public ulong StackRegionStart { get; private set; }
public ulong StackRegionEnd { get; private set; }
public ulong TlsIoRegionStart { get; private set; }
public ulong TlsIoRegionEnd { get; private set; }
private ulong _heapCapacity;
public ulong PhysicalMemoryUsage { get; private set; }
private readonly KMemoryBlockManager _blockManager;
private MemoryRegion _memRegion;
private bool _aslrDisabled;
public int AddrSpaceWidth { get; private set; }
private bool _isKernel;
private bool _aslrEnabled;
private KMemoryBlockSlabManager _slabManager;
private int _contextId;
private MersenneTwister _randomNumberGenerator;
private MemoryFillValue _heapFillValue;
private MemoryFillValue _ipcFillValue;
public KPageTableBase(KernelContext context)
{
Context = context;
_blockManager = new KMemoryBlockManager();
_isKernel = false;
_heapFillValue = MemoryFillValue.Zero;
_ipcFillValue = MemoryFillValue.Zero;
}
private static readonly int[] AddrSpaceSizes = new int[] { 32, 36, 32, 39 };
public KernelResult InitializeForProcess(
AddressSpaceType addrSpaceType,
bool aslrEnabled,
bool aslrDisabled,
MemoryRegion memRegion,
ulong address,
ulong size,
KMemoryBlockSlabManager slabManager)
{
if ((uint)addrSpaceType > (uint)AddressSpaceType.Addr39Bits)
{
throw new ArgumentException(nameof(addrSpaceType));
}
_contextId = Context.ContextIdManager.GetId();
ulong addrSpaceBase = 0;
ulong addrSpaceSize = 1UL << AddrSpaceSizes[(int)addrSpaceType];
KernelResult result = CreateUserAddressSpace(
addrSpaceType,
aslrEnabled,
aslrDisabled,
addrSpaceBase,
addrSpaceSize,
memRegion,
address,
size,
slabManager);
if (result != KernelResult.Success)
{
Context.ContextIdManager.PutId(_contextId);
}
return result;
}
private class Region
{
public ulong Start;
public ulong End;
public ulong Size;
public ulong AslrOffset;
}
private KernelResult CreateUserAddressSpace(
AddressSpaceType addrSpaceType,
bool aslrEnabled,
bool aslrDisabled,
ulong addrSpaceStart,
ulong addrSpaceEnd,
MemoryRegion memRegion,
ulong address,
ulong size,
KMemoryBlockSlabManager slabManager)
{
ulong endAddr = address + size;
Region aliasRegion = new Region();
Region heapRegion = new Region();
Region stackRegion = new Region();
Region tlsIoRegion = new Region();
ulong codeRegionSize;
ulong stackAndTlsIoStart;
ulong stackAndTlsIoEnd;
ulong baseAddress;
switch (addrSpaceType)
{
case AddressSpaceType.Addr32Bits:
aliasRegion.Size = 0x40000000;
heapRegion.Size = 0x40000000;
stackRegion.Size = 0;
tlsIoRegion.Size = 0;
CodeRegionStart = 0x200000;
codeRegionSize = 0x3fe00000;
stackAndTlsIoStart = 0x200000;
stackAndTlsIoEnd = 0x40000000;
baseAddress = 0x200000;
AddrSpaceWidth = 32;
break;
case AddressSpaceType.Addr36Bits:
aliasRegion.Size = 0x180000000;
heapRegion.Size = 0x180000000;
stackRegion.Size = 0;
tlsIoRegion.Size = 0;
CodeRegionStart = 0x8000000;
codeRegionSize = 0x78000000;
stackAndTlsIoStart = 0x8000000;
stackAndTlsIoEnd = 0x80000000;
baseAddress = 0x8000000;
AddrSpaceWidth = 36;
break;
case AddressSpaceType.Addr32BitsNoMap:
aliasRegion.Size = 0;
heapRegion.Size = 0x80000000;
stackRegion.Size = 0;
tlsIoRegion.Size = 0;
CodeRegionStart = 0x200000;
codeRegionSize = 0x3fe00000;
stackAndTlsIoStart = 0x200000;
stackAndTlsIoEnd = 0x40000000;
baseAddress = 0x200000;
AddrSpaceWidth = 32;
break;
case AddressSpaceType.Addr39Bits:
aliasRegion.Size = 0x1000000000;
heapRegion.Size = 0x180000000;
stackRegion.Size = 0x80000000;
tlsIoRegion.Size = 0x1000000000;
CodeRegionStart = BitUtils.AlignDown(address, 0x200000);
codeRegionSize = BitUtils.AlignUp(endAddr, 0x200000) - CodeRegionStart;
stackAndTlsIoStart = 0;
stackAndTlsIoEnd = 0;
baseAddress = 0x8000000;
AddrSpaceWidth = 39;
break;
default: throw new ArgumentException(nameof(addrSpaceType));
}
CodeRegionEnd = CodeRegionStart + codeRegionSize;
ulong mapBaseAddress;
ulong mapAvailableSize;
if (CodeRegionStart - baseAddress >= addrSpaceEnd - CodeRegionEnd)
{
// Has more space before the start of the code region.
mapBaseAddress = baseAddress;
mapAvailableSize = CodeRegionStart - baseAddress;
}
else
{
// Has more space after the end of the code region.
mapBaseAddress = CodeRegionEnd;
mapAvailableSize = addrSpaceEnd - CodeRegionEnd;
}
ulong mapTotalSize = aliasRegion.Size + heapRegion.Size + stackRegion.Size + tlsIoRegion.Size;
ulong aslrMaxOffset = mapAvailableSize - mapTotalSize;
_aslrEnabled = aslrEnabled;
AddrSpaceStart = addrSpaceStart;
AddrSpaceEnd = addrSpaceEnd;
_slabManager = slabManager;
if (mapAvailableSize < mapTotalSize)
{
return KernelResult.OutOfMemory;
}
if (aslrEnabled)
{
aliasRegion.AslrOffset = GetRandomValue(0, aslrMaxOffset >> 21) << 21;
heapRegion.AslrOffset = GetRandomValue(0, aslrMaxOffset >> 21) << 21;
stackRegion.AslrOffset = GetRandomValue(0, aslrMaxOffset >> 21) << 21;
tlsIoRegion.AslrOffset = GetRandomValue(0, aslrMaxOffset >> 21) << 21;
}
// Regions are sorted based on ASLR offset.
// When ASLR is disabled, the order is Map, Heap, NewMap and TlsIo.
aliasRegion.Start = mapBaseAddress + aliasRegion.AslrOffset;
aliasRegion.End = aliasRegion.Start + aliasRegion.Size;
heapRegion.Start = mapBaseAddress + heapRegion.AslrOffset;
heapRegion.End = heapRegion.Start + heapRegion.Size;
stackRegion.Start = mapBaseAddress + stackRegion.AslrOffset;
stackRegion.End = stackRegion.Start + stackRegion.Size;
tlsIoRegion.Start = mapBaseAddress + tlsIoRegion.AslrOffset;
tlsIoRegion.End = tlsIoRegion.Start + tlsIoRegion.Size;
SortRegion(heapRegion, aliasRegion);
if (stackRegion.Size != 0)
{
SortRegion(stackRegion, aliasRegion);
SortRegion(stackRegion, heapRegion);
}
else
{
stackRegion.Start = stackAndTlsIoStart;
stackRegion.End = stackAndTlsIoEnd;
}
if (tlsIoRegion.Size != 0)
{
SortRegion(tlsIoRegion, aliasRegion);
SortRegion(tlsIoRegion, heapRegion);
SortRegion(tlsIoRegion, stackRegion);
}
else
{
tlsIoRegion.Start = stackAndTlsIoStart;
tlsIoRegion.End = stackAndTlsIoEnd;
}
AliasRegionStart = aliasRegion.Start;
AliasRegionEnd = aliasRegion.End;
HeapRegionStart = heapRegion.Start;
HeapRegionEnd = heapRegion.End;
StackRegionStart = stackRegion.Start;
StackRegionEnd = stackRegion.End;
TlsIoRegionStart = tlsIoRegion.Start;
TlsIoRegionEnd = tlsIoRegion.End;
// TODO: Check kernel configuration via secure monitor call when implemented to set memory fill values.
_currentHeapAddr = HeapRegionStart;
_heapCapacity = 0;
PhysicalMemoryUsage = 0;
_memRegion = memRegion;
_aslrDisabled = aslrDisabled;
return _blockManager.Initialize(addrSpaceStart, addrSpaceEnd, slabManager);
}
private ulong GetRandomValue(ulong min, ulong max)
{
return (ulong)GetRandomValue((long)min, (long)max);
}
private long GetRandomValue(long min, long max)
{
if (_randomNumberGenerator == null)
{
_randomNumberGenerator = new MersenneTwister(0);
}
return _randomNumberGenerator.GenRandomNumber(min, max);
}
private static void SortRegion(Region lhs, Region rhs)
{
if (lhs.AslrOffset < rhs.AslrOffset)
{
rhs.Start += lhs.Size;
rhs.End += lhs.Size;
}
else
{
lhs.Start += rhs.Size;
lhs.End += rhs.Size;
}
}
public KernelResult MapPages(ulong address, KPageList pageList, MemoryState state, KMemoryPermission permission)
{
ulong pagesCount = pageList.GetPagesCount();
ulong size = pagesCount * PageSize;
if (!CanContain(address, size, state))
{
return KernelResult.InvalidMemState;
}
lock (_blockManager)
{
if (!IsUnmapped(address, pagesCount * PageSize))
{
return KernelResult.InvalidMemState;
}
if (!_slabManager.CanAllocate(MaxBlocksNeededForInsertion))
{
return KernelResult.OutOfResource;
}
KernelResult result = MapPages(address, pageList, permission);
if (result == KernelResult.Success)
{
_blockManager.InsertBlock(address, pagesCount, state, permission);
}
return result;
}
}
public KernelResult UnmapPages(ulong address, KPageList pageList, MemoryState stateExpected)
{
ulong pagesCount = pageList.GetPagesCount();
ulong size = pagesCount * PageSize;
ulong endAddr = address + size;
ulong addrSpacePagesCount = (AddrSpaceEnd - AddrSpaceStart) / PageSize;
if (AddrSpaceStart > address)
{
return KernelResult.InvalidMemState;
}
if (addrSpacePagesCount < pagesCount)
{
return KernelResult.InvalidMemState;
}
if (endAddr - 1 > AddrSpaceEnd - 1)
{
return KernelResult.InvalidMemState;
}
lock (_blockManager)
{
KPageList currentPageList = new KPageList();
GetPhysicalRegions(address, size, currentPageList);
if (!currentPageList.IsEqual(pageList))
{
return KernelResult.InvalidMemRange;
}
if (CheckRange(
address,
size,
MemoryState.Mask,
stateExpected,
KMemoryPermission.None,
KMemoryPermission.None,
MemoryAttribute.Mask,
MemoryAttribute.None,
MemoryAttribute.IpcAndDeviceMapped,
out MemoryState state,
out _,
out _))
{
if (!_slabManager.CanAllocate(MaxBlocksNeededForInsertion))
{
return KernelResult.OutOfResource;
}
KernelResult result = Unmap(address, pagesCount);
if (result == KernelResult.Success)
{
_blockManager.InsertBlock(address, pagesCount, MemoryState.Unmapped);
}
return result;
}
else
{
return KernelResult.InvalidMemState;
}
}
}
public KernelResult MapNormalMemory(long address, long size, KMemoryPermission permission)
{
// TODO.
return KernelResult.Success;
}
public KernelResult MapIoMemory(long address, long size, KMemoryPermission permission)
{
// TODO.
return KernelResult.Success;
}
public KernelResult MapPages(
ulong pagesCount,
int alignment,
ulong srcPa,
bool paIsValid,
ulong regionStart,
ulong regionPagesCount,
MemoryState state,
KMemoryPermission permission,
out ulong address)
{
address = 0;
ulong regionSize = regionPagesCount * PageSize;
if (!CanContain(regionStart, regionSize, state))
{
return KernelResult.InvalidMemState;
}
if (regionPagesCount <= pagesCount)
{
return KernelResult.OutOfMemory;
}
lock (_blockManager)
{
address = AllocateVa(regionStart, regionPagesCount, pagesCount, alignment);
if (address == 0)
{
return KernelResult.OutOfMemory;
}
if (!_slabManager.CanAllocate(MaxBlocksNeededForInsertion))
{
return KernelResult.OutOfResource;
}
KernelResult result;
if (paIsValid)
{
result = MapPages(address, pagesCount, srcPa, permission);
}
else
{
result = AllocateAndMapPages(address, pagesCount, permission);
}
if (result != KernelResult.Success)
{
return result;
}
_blockManager.InsertBlock(address, pagesCount, state, permission);
}
return KernelResult.Success;
}
public KernelResult MapPages(ulong address, ulong pagesCount, MemoryState state, KMemoryPermission permission)
{
ulong size = pagesCount * PageSize;
if (!CanContain(address, size, state))
{
return KernelResult.InvalidMemState;
}
lock (_blockManager)
{
if (!IsUnmapped(address, size))
{
return KernelResult.InvalidMemState;
}
if (!_slabManager.CanAllocate(MaxBlocksNeededForInsertion))
{
return KernelResult.OutOfResource;
}
KernelResult result = AllocateAndMapPages(address, pagesCount, permission);
if (result == KernelResult.Success)
{
_blockManager.InsertBlock(address, pagesCount, state, permission);
}
return result;
}
}
private KernelResult AllocateAndMapPages(ulong address, ulong pagesCount, KMemoryPermission permission)
{
KMemoryRegionManager region = GetMemoryRegionManager();
KernelResult result = region.AllocatePages(pagesCount, _aslrDisabled, out KPageList pageList);
if (result != KernelResult.Success)
{
return result;
}
using var _ = new OnScopeExit(() => pageList.DecrementPagesReferenceCount(Context.MemoryManager));
return MapPages(address, pageList, permission);
}
public KernelResult MapProcessCodeMemory(ulong dst, ulong src, ulong size)
{
lock (_blockManager)
{
bool success = CheckRange(
src,
size,
MemoryState.Mask,
MemoryState.Heap,
KMemoryPermission.Mask,
KMemoryPermission.ReadAndWrite,
MemoryAttribute.Mask,
MemoryAttribute.None,
MemoryAttribute.IpcAndDeviceMapped,
out MemoryState state,
out KMemoryPermission permission,
out _);
success &= IsUnmapped(dst, size);
if (success)
{
if (!_slabManager.CanAllocate(MaxBlocksNeededForInsertion * 2))
{
return KernelResult.OutOfResource;
}
ulong pagesCount = size / PageSize;
KernelResult result = MapMemory(src, dst, pagesCount, permission, KMemoryPermission.None);
_blockManager.InsertBlock(src, pagesCount, state, KMemoryPermission.None, MemoryAttribute.Borrowed);
_blockManager.InsertBlock(dst, pagesCount, MemoryState.ModCodeStatic);
return KernelResult.Success;
}
else
{
return KernelResult.InvalidMemState;
}
}
}
public KernelResult UnmapProcessCodeMemory(ulong dst, ulong src, ulong size)
{
lock (_blockManager)
{
bool success = CheckRange(
src,
size,
MemoryState.Mask,
MemoryState.Heap,
KMemoryPermission.None,
KMemoryPermission.None,
MemoryAttribute.Mask,
MemoryAttribute.Borrowed,
MemoryAttribute.IpcAndDeviceMapped,
out _,
out _,
out _);
success &= CheckRange(
dst,
PageSize,
MemoryState.UnmapProcessCodeMemoryAllowed,
MemoryState.UnmapProcessCodeMemoryAllowed,
KMemoryPermission.None,
KMemoryPermission.None,
MemoryAttribute.Mask,
MemoryAttribute.None,
MemoryAttribute.IpcAndDeviceMapped,
out MemoryState state,
out _,
out _);
success &= CheckRange(
dst,
size,
MemoryState.Mask,
state,
KMemoryPermission.None,
KMemoryPermission.None,
MemoryAttribute.Mask,
MemoryAttribute.None);
if (success)
{
ulong pagesCount = size / PageSize;
KernelResult result = Unmap(dst, pagesCount);
if (result != KernelResult.Success)
{
return result;
}
// TODO: Missing some checks here.
if (!_slabManager.CanAllocate(MaxBlocksNeededForInsertion * 2))
{
return KernelResult.OutOfResource;
}
_blockManager.InsertBlock(dst, pagesCount, MemoryState.Unmapped);
_blockManager.InsertBlock(src, pagesCount, MemoryState.Heap, KMemoryPermission.ReadAndWrite);
return KernelResult.Success;
}
else
{
return KernelResult.InvalidMemState;
}
}
}
public KernelResult SetHeapSize(ulong size, out ulong address)
{
address = 0;
if (size > HeapRegionEnd - HeapRegionStart)
{
return KernelResult.OutOfMemory;
}
KProcess currentProcess = KernelStatic.GetCurrentProcess();
lock (_blockManager)
{
ulong currentHeapSize = GetHeapSize();
if (currentHeapSize <= size)
{
// Expand.
ulong sizeDelta = size - currentHeapSize;
if (currentProcess.ResourceLimit != null && sizeDelta != 0 &&
!currentProcess.ResourceLimit.Reserve(LimitableResource.Memory, sizeDelta))
{
return KernelResult.ResLimitExceeded;
}
ulong pagesCount = sizeDelta / PageSize;
KMemoryRegionManager region = GetMemoryRegionManager();
KernelResult result = region.AllocatePages(pagesCount, _aslrDisabled, out KPageList pageList);
using var _ = new OnScopeExit(() => pageList.DecrementPagesReferenceCount(Context.MemoryManager));
void CleanUpForError()
{
if (currentProcess.ResourceLimit != null && sizeDelta != 0)
{
currentProcess.ResourceLimit.Release(LimitableResource.Memory, sizeDelta);
}
}
if (result != KernelResult.Success)
{
CleanUpForError();
return result;
}
if (!_slabManager.CanAllocate(MaxBlocksNeededForInsertion))
{
CleanUpForError();
return KernelResult.OutOfResource;
}
if (!IsUnmapped(_currentHeapAddr, sizeDelta))
{
CleanUpForError();
return KernelResult.InvalidMemState;
}
result = MapPages(_currentHeapAddr, pageList, KMemoryPermission.ReadAndWrite, true, (byte)_heapFillValue);
if (result != KernelResult.Success)
{
CleanUpForError();
return result;
}
_blockManager.InsertBlock(_currentHeapAddr, pagesCount, MemoryState.Heap, KMemoryPermission.ReadAndWrite);
}
else
{
// Shrink.
ulong freeAddr = HeapRegionStart + size;
ulong sizeDelta = currentHeapSize - size;
if (!_slabManager.CanAllocate(MaxBlocksNeededForInsertion))
{
return KernelResult.OutOfResource;
}
if (!CheckRange(
freeAddr,
sizeDelta,
MemoryState.Mask,
MemoryState.Heap,
KMemoryPermission.Mask,
KMemoryPermission.ReadAndWrite,
MemoryAttribute.Mask,
MemoryAttribute.None,
MemoryAttribute.IpcAndDeviceMapped,
out _,
out _,
out _))
{
return KernelResult.InvalidMemState;
}
ulong pagesCount = sizeDelta / PageSize;
KernelResult result = Unmap(freeAddr, pagesCount);
if (result != KernelResult.Success)
{
return result;
}
currentProcess.ResourceLimit?.Release(LimitableResource.Memory, sizeDelta);
_blockManager.InsertBlock(freeAddr, pagesCount, MemoryState.Unmapped);
}
_currentHeapAddr = HeapRegionStart + size;
}
address = HeapRegionStart;
return KernelResult.Success;
}
public KernelResult SetMemoryPermission(ulong address, ulong size, KMemoryPermission permission)
{
lock (_blockManager)
{
if (CheckRange(
address,
size,
MemoryState.PermissionChangeAllowed,
MemoryState.PermissionChangeAllowed,
KMemoryPermission.None,
KMemoryPermission.None,
MemoryAttribute.Mask,
MemoryAttribute.None,
MemoryAttribute.IpcAndDeviceMapped,
out MemoryState oldState,
out KMemoryPermission oldPermission,
out _))
{
if (permission != oldPermission)
{
if (!_slabManager.CanAllocate(MaxBlocksNeededForInsertion))
{
return KernelResult.OutOfResource;
}
ulong pagesCount = size / PageSize;
KernelResult result = Reprotect(address, pagesCount, permission);
if (result != KernelResult.Success)
{
return result;
}
_blockManager.InsertBlock(address, pagesCount, oldState, permission);
}
return KernelResult.Success;
}
else
{
return KernelResult.InvalidMemState;
}
}
}
public ulong GetTotalHeapSize()
{
lock (_blockManager)
{
return GetHeapSize() + PhysicalMemoryUsage;
}
}
private ulong GetHeapSize()
{
return _currentHeapAddr - HeapRegionStart;
}
public KernelResult SetHeapCapacity(ulong capacity)
{
lock (_blockManager)
{
_heapCapacity = capacity;
}
return KernelResult.Success;
}
public KernelResult SetMemoryAttribute(
ulong address,
ulong size,
MemoryAttribute attributeMask,
MemoryAttribute attributeValue)
{
lock (_blockManager)
{
if (CheckRange(
address,
size,
MemoryState.AttributeChangeAllowed,
MemoryState.AttributeChangeAllowed,
KMemoryPermission.None,
KMemoryPermission.None,
MemoryAttribute.BorrowedAndIpcMapped,
MemoryAttribute.None,
MemoryAttribute.DeviceMappedAndUncached,
out MemoryState state,
out KMemoryPermission permission,
out MemoryAttribute attribute))
{
if (!_slabManager.CanAllocate(MaxBlocksNeededForInsertion))
{
return KernelResult.OutOfResource;
}
ulong pagesCount = size / PageSize;
attribute &= ~attributeMask;
attribute |= attributeMask & attributeValue;
_blockManager.InsertBlock(address, pagesCount, state, permission, attribute);
return KernelResult.Success;
}
else
{
return KernelResult.InvalidMemState;
}
}
}
public KMemoryInfo QueryMemory(ulong address)
{
if (address >= AddrSpaceStart &&
address < AddrSpaceEnd)
{
lock (_blockManager)
{
return _blockManager.FindBlock(address).GetInfo();
}
}
else
{
return new KMemoryInfo(
AddrSpaceEnd,
~AddrSpaceEnd + 1,
MemoryState.Reserved,
KMemoryPermission.None,
MemoryAttribute.None,
KMemoryPermission.None,
0,
0);
}
}
public KernelResult Map(ulong dst, ulong src, ulong size)
{
bool success;
lock (_blockManager)
{
success = CheckRange(
src,
size,
MemoryState.MapAllowed,
MemoryState.MapAllowed,
KMemoryPermission.Mask,
KMemoryPermission.ReadAndWrite,
MemoryAttribute.Mask,
MemoryAttribute.None,
MemoryAttribute.IpcAndDeviceMapped,
out MemoryState srcState,
out _,
out _);
success &= IsUnmapped(dst, size);
if (success)
{
if (!_slabManager.CanAllocate(MaxBlocksNeededForInsertion * 2))
{
return KernelResult.OutOfResource;
}
ulong pagesCount = size / PageSize;
KernelResult result = MapMemory(src, dst, pagesCount, KMemoryPermission.ReadAndWrite, KMemoryPermission.ReadAndWrite);
if (result != KernelResult.Success)
{
return result;
}
_blockManager.InsertBlock(src, pagesCount, srcState, KMemoryPermission.None, MemoryAttribute.Borrowed);
_blockManager.InsertBlock(dst, pagesCount, MemoryState.Stack, KMemoryPermission.ReadAndWrite);
return KernelResult.Success;
}
else
{
return KernelResult.InvalidMemState;
}
}
}
public KernelResult UnmapForKernel(ulong address, ulong pagesCount, MemoryState stateExpected)
{
ulong size = pagesCount * PageSize;
lock (_blockManager)
{
if (CheckRange(
address,
size,
MemoryState.Mask,
stateExpected,
KMemoryPermission.None,
KMemoryPermission.None,
MemoryAttribute.Mask,
MemoryAttribute.None,
MemoryAttribute.IpcAndDeviceMapped,
out _,
out _,
out _))
{
if (!_slabManager.CanAllocate(MaxBlocksNeededForInsertion))
{
return KernelResult.OutOfResource;
}
KernelResult result = Unmap(address, pagesCount);
if (result == KernelResult.Success)
{
_blockManager.InsertBlock(address, pagesCount, MemoryState.Unmapped);
}
return KernelResult.Success;
}
else
{
return KernelResult.InvalidMemState;
}
}
}
public KernelResult Unmap(ulong dst, ulong src, ulong size)
{
bool success;
lock (_blockManager)
{
success = CheckRange(
src,
size,
MemoryState.MapAllowed,
MemoryState.MapAllowed,
KMemoryPermission.Mask,
KMemoryPermission.None,
MemoryAttribute.Mask,
MemoryAttribute.Borrowed,
MemoryAttribute.IpcAndDeviceMapped,
out MemoryState srcState,
out _,
out _);
success &= CheckRange(
dst,
size,
MemoryState.Mask,
MemoryState.Stack,
KMemoryPermission.None,
KMemoryPermission.None,
MemoryAttribute.Mask,
MemoryAttribute.None,
MemoryAttribute.IpcAndDeviceMapped,
out _,
out KMemoryPermission dstPermission,
out _);
if (success)
{
if (!_slabManager.CanAllocate(MaxBlocksNeededForInsertion * 2))
{
return KernelResult.OutOfResource;
}
ulong pagesCount = size / PageSize;
KernelResult result = UnmapMemory(dst, src, pagesCount, dstPermission, KMemoryPermission.ReadAndWrite);
if (result != KernelResult.Success)
{
return result;
}
_blockManager.InsertBlock(src, pagesCount, srcState, KMemoryPermission.ReadAndWrite);
_blockManager.InsertBlock(dst, pagesCount, MemoryState.Unmapped);
return KernelResult.Success;
}
else
{
return KernelResult.InvalidMemState;
}
}
}
public KernelResult SetProcessMemoryPermission(ulong address, ulong size, KMemoryPermission permission)
{
lock (_blockManager)
{
if (CheckRange(
address,
size,
MemoryState.ProcessPermissionChangeAllowed,
MemoryState.ProcessPermissionChangeAllowed,
KMemoryPermission.None,
KMemoryPermission.None,
MemoryAttribute.Mask,
MemoryAttribute.None,
MemoryAttribute.IpcAndDeviceMapped,
out MemoryState oldState,
out KMemoryPermission oldPermission,
out _))
{
MemoryState newState = oldState;
// If writing into the code region is allowed, then we need
// to change it to mutable.
if ((permission & KMemoryPermission.Write) != 0)
{
if (oldState == MemoryState.CodeStatic)
{
newState = MemoryState.CodeMutable;
}
else if (oldState == MemoryState.ModCodeStatic)
{
newState = MemoryState.ModCodeMutable;
}
else
{
throw new InvalidOperationException($"Memory state \"{oldState}\" not valid for this operation.");
}
}
if (newState != oldState || permission != oldPermission)
{
if (!_slabManager.CanAllocate(MaxBlocksNeededForInsertion))
{
return KernelResult.OutOfResource;
}
ulong pagesCount = size / PageSize;
KernelResult result;
if ((oldPermission & KMemoryPermission.Execute) != 0)
{
result = ReprotectWithAttributes(address, pagesCount, permission);
}
else
{
result = Reprotect(address, pagesCount, permission);
}
if (result != KernelResult.Success)
{
return result;
}
_blockManager.InsertBlock(address, pagesCount, newState, permission);
}
return KernelResult.Success;
}
else
{
return KernelResult.InvalidMemState;
}
}
}
public KernelResult MapPhysicalMemory(ulong address, ulong size)
{
ulong endAddr = address + size;
lock (_blockManager)
{
ulong mappedSize = 0;
foreach (KMemoryInfo info in IterateOverRange(address, endAddr))
{
if (info.State != MemoryState.Unmapped)
{
mappedSize += GetSizeInRange(info, address, endAddr);
}
}
if (mappedSize == size)
{
return KernelResult.Success;
}
ulong remainingSize = size - mappedSize;
ulong remainingPages = remainingSize / PageSize;
KProcess currentProcess = KernelStatic.GetCurrentProcess();
if (currentProcess.ResourceLimit != null &&
!currentProcess.ResourceLimit.Reserve(LimitableResource.Memory, remainingSize))
{
return KernelResult.ResLimitExceeded;
}
KMemoryRegionManager region = GetMemoryRegionManager();
KernelResult result = region.AllocatePages(remainingPages, _aslrDisabled, out KPageList pageList);
using var _ = new OnScopeExit(() => pageList.DecrementPagesReferenceCount(Context.MemoryManager));
void CleanUpForError()
{
currentProcess.ResourceLimit?.Release(LimitableResource.Memory, remainingSize);
}
if (result != KernelResult.Success)
{
CleanUpForError();
return result;
}
if (!_slabManager.CanAllocate(MaxBlocksNeededForInsertion))
{
CleanUpForError();
return KernelResult.OutOfResource;
}
LinkedListNode<KPageNode> pageListNode = pageList.Nodes.First;
KPageNode pageNode = pageListNode.Value;
ulong srcPa = pageNode.Address;
ulong srcPaPages = pageNode.PagesCount;
foreach (KMemoryInfo info in IterateOverRange(address, endAddr))
{
if (info.State != MemoryState.Unmapped)
{
continue;
}
ulong blockSize = GetSizeInRange(info, address, endAddr);
ulong dstVaPages = blockSize / PageSize;
ulong dstVa = GetAddrInRange(info, address);
while (dstVaPages > 0)
{
if (srcPaPages == 0)
{
pageListNode = pageListNode.Next;
pageNode = pageListNode.Value;
srcPa = pageNode.Address;
srcPaPages = pageNode.PagesCount;
}
ulong currentPagesCount = Math.Min(srcPaPages, dstVaPages);
MapPages(dstVa, currentPagesCount, srcPa, KMemoryPermission.ReadAndWrite);
dstVa += currentPagesCount * PageSize;
srcPa += currentPagesCount * PageSize;
srcPaPages -= currentPagesCount;
dstVaPages -= currentPagesCount;
}
}
PhysicalMemoryUsage += remainingSize;
ulong pagesCount = size / PageSize;
_blockManager.InsertBlock(
address,
pagesCount,
MemoryState.Unmapped,
KMemoryPermission.None,
MemoryAttribute.None,
MemoryState.Heap,
KMemoryPermission.ReadAndWrite,
MemoryAttribute.None);
}
return KernelResult.Success;
}
public KernelResult UnmapPhysicalMemory(ulong address, ulong size)
{
ulong endAddr = address + size;
lock (_blockManager)
{
// Scan, ensure that the region can be unmapped (all blocks are heap or
// already unmapped), fill pages list for freeing memory.
ulong heapMappedSize = 0;
foreach (KMemoryInfo info in IterateOverRange(address, endAddr))
{
if (info.State == MemoryState.Heap)
{
if (info.Attribute != MemoryAttribute.None)
{
return KernelResult.InvalidMemState;
}
ulong blockSize = GetSizeInRange(info, address, endAddr);
heapMappedSize += blockSize;
}
else if (info.State != MemoryState.Unmapped)
{
return KernelResult.InvalidMemState;
}
}
if (heapMappedSize == 0)
{
return KernelResult.Success;
}
if (!_slabManager.CanAllocate(MaxBlocksNeededForInsertion))
{
return KernelResult.OutOfResource;
}
// Try to unmap all the heap mapped memory inside range.
KernelResult result = KernelResult.Success;
foreach (KMemoryInfo info in IterateOverRange(address, endAddr))
{
if (info.State == MemoryState.Heap)
{
ulong blockSize = GetSizeInRange(info, address, endAddr);
ulong blockAddress = GetAddrInRange(info, address);
ulong blockPagesCount = blockSize / PageSize;
result = Unmap(blockAddress, blockPagesCount);
// The kernel would attempt to remap if this fails, but we don't because:
// - The implementation may not support remapping if memory aliasing is not supported on the platform.
// - Unmap can't ever fail here anyway.
Debug.Assert(result == KernelResult.Success);
}
}
if (result == KernelResult.Success)
{
PhysicalMemoryUsage -= heapMappedSize;
KProcess currentProcess = KernelStatic.GetCurrentProcess();
currentProcess.ResourceLimit?.Release(LimitableResource.Memory, heapMappedSize);
ulong pagesCount = size / PageSize;
_blockManager.InsertBlock(address, pagesCount, MemoryState.Unmapped);
}
return result;
}
}
public KernelResult CopyDataToCurrentProcess(
ulong dst,
ulong size,
ulong src,
MemoryState stateMask,
MemoryState stateExpected,
KMemoryPermission permission,
MemoryAttribute attributeMask,
MemoryAttribute attributeExpected)
{
// Client -> server.
return CopyDataFromOrToCurrentProcess(
size,
src,
dst,
stateMask,
stateExpected,
permission,
attributeMask,
attributeExpected,
toServer: true);
}
public KernelResult CopyDataFromCurrentProcess(
ulong dst,
ulong size,
MemoryState stateMask,
MemoryState stateExpected,
KMemoryPermission permission,
MemoryAttribute attributeMask,
MemoryAttribute attributeExpected,
ulong src)
{
// Server -> client.
return CopyDataFromOrToCurrentProcess(
size,
dst,
src,
stateMask,
stateExpected,
permission,
attributeMask,
attributeExpected,
toServer: false);
}
private KernelResult CopyDataFromOrToCurrentProcess(
ulong size,
ulong clientAddress,
ulong serverAddress,
MemoryState stateMask,
MemoryState stateExpected,
KMemoryPermission permission,
MemoryAttribute attributeMask,
MemoryAttribute attributeExpected,
bool toServer)
{
if (AddrSpaceStart > clientAddress)
{
return KernelResult.InvalidMemState;
}
ulong srcEndAddr = clientAddress + size;
if (srcEndAddr <= clientAddress || srcEndAddr - 1 > AddrSpaceEnd - 1)
{
return KernelResult.InvalidMemState;
}
lock (_blockManager)
{
if (CheckRange(
clientAddress,
size,
stateMask,
stateExpected,
permission,
permission,
attributeMask | MemoryAttribute.Uncached,
attributeExpected))
{
KProcess currentProcess = KernelStatic.GetCurrentProcess();
while (size > 0)
{
ulong copySize = 0x100000; // Copy chunck size. Any value will do, moderate sizes are recommended.
if (copySize > size)
{
copySize = size;
}
if (toServer)
{
currentProcess.CpuMemory.Write(serverAddress, GetSpan(clientAddress, (int)copySize));
}
else
{
Write(clientAddress, currentProcess.CpuMemory.GetSpan(serverAddress, (int)copySize));
}
serverAddress += copySize;
clientAddress += copySize;
size -= copySize;
}
return KernelResult.Success;
}
else
{
return KernelResult.InvalidMemState;
}
}
}
public KernelResult MapBufferFromClientProcess(
ulong size,
ulong src,
KPageTableBase srcPageTable,
KMemoryPermission permission,
MemoryState state,
bool send,
out ulong dst)
{
dst = 0;
lock (srcPageTable._blockManager)
{
lock (_blockManager)
{
KernelResult result = srcPageTable.ReprotectClientProcess(
src,
size,
permission,
state,
out int blocksNeeded);
if (result != KernelResult.Success)
{
return result;
}
if (!srcPageTable._slabManager.CanAllocate(blocksNeeded))
{
return KernelResult.OutOfResource;
}
ulong srcMapAddress = BitUtils.AlignUp(src, PageSize);
ulong srcMapEndAddr = BitUtils.AlignDown(src + size, PageSize);
ulong srcMapSize = srcMapEndAddr - srcMapAddress;
result = MapPagesFromClientProcess(size, src, permission, state, srcPageTable, send, out ulong va);
if (result != KernelResult.Success)
{
if (srcMapEndAddr > srcMapAddress)
{
srcPageTable.UnmapIpcRestorePermission(src, size, state);
}
return result;
}
if (srcMapAddress < srcMapEndAddr)
{
KMemoryPermission permissionMask = permission == KMemoryPermission.ReadAndWrite
? KMemoryPermission.None
: KMemoryPermission.Read;
srcPageTable._blockManager.InsertBlock(srcMapAddress, srcMapSize / PageSize, SetIpcMappingPermissions, permissionMask);
}
dst = va;
}
}
return KernelResult.Success;
}
private KernelResult ReprotectClientProcess(
ulong address,
ulong size,
KMemoryPermission permission,
MemoryState state,
out int blocksNeeded)
{
blocksNeeded = 0;
if (AddrSpaceStart > address)
{
return KernelResult.InvalidMemState;
}
ulong endAddr = address + size;
if (endAddr <= address || endAddr - 1 > AddrSpaceEnd - 1)
{
return KernelResult.InvalidMemState;
}
MemoryState stateMask;
switch (state)
{
case MemoryState.IpcBuffer0: stateMask = MemoryState.IpcSendAllowedType0; break;
case MemoryState.IpcBuffer1: stateMask = MemoryState.IpcSendAllowedType1; break;
case MemoryState.IpcBuffer3: stateMask = MemoryState.IpcSendAllowedType3; break;
default: return KernelResult.InvalidCombination;
}
KMemoryPermission permissionMask = permission == KMemoryPermission.ReadAndWrite
? KMemoryPermission.None
: KMemoryPermission.Read;
MemoryAttribute attributeMask = MemoryAttribute.Borrowed | MemoryAttribute.Uncached;
if (state == MemoryState.IpcBuffer0)
{
attributeMask |= MemoryAttribute.DeviceMapped;
}
ulong addressRounded = BitUtils.AlignUp(address, PageSize);
ulong addressTruncated = BitUtils.AlignDown(address, PageSize);
ulong endAddrRounded = BitUtils.AlignUp(endAddr, PageSize);
ulong endAddrTruncated = BitUtils.AlignDown(endAddr, PageSize);
if (!_slabManager.CanAllocate(MaxBlocksNeededForInsertion))
{
return KernelResult.OutOfResource;
}
ulong visitedSize = 0;
void CleanUpForError()
{
if (visitedSize == 0)
{
return;
}
ulong endAddrVisited = address + visitedSize;
foreach (KMemoryInfo info in IterateOverRange(addressRounded, endAddrVisited))
{
if ((info.Permission & KMemoryPermission.ReadAndWrite) != permissionMask && info.IpcRefCount == 0)
{
ulong blockAddress = GetAddrInRange(info, addressRounded);
ulong blockSize = GetSizeInRange(info, addressRounded, endAddrVisited);
ulong blockPagesCount = blockSize / PageSize;
KernelResult reprotectResult = Reprotect(blockAddress, blockPagesCount, info.Permission);
Debug.Assert(reprotectResult == KernelResult.Success);
}
}
}
// Signal a read for any resources tracking reads in the region, as the other process is likely to use their data.
SignalMemoryTracking(addressTruncated, endAddrRounded - addressTruncated, false);
// Reprotect the aligned pages range on the client to make them inaccessible from the client process.
KernelResult result;
if (addressRounded < endAddrTruncated)
{
foreach (KMemoryInfo info in IterateOverRange(addressRounded, endAddrTruncated))
{
// Check if the block state matches what we expect.
if ((info.State & stateMask) != stateMask ||
(info.Permission & permission) != permission ||
(info.Attribute & attributeMask) != MemoryAttribute.None)
{
CleanUpForError();
return KernelResult.InvalidMemState;
}
ulong blockAddress = GetAddrInRange(info, addressRounded);
ulong blockSize = GetSizeInRange(info, addressRounded, endAddrTruncated);
ulong blockPagesCount = blockSize / PageSize;
// If the first block starts before the aligned range, it will need to be split.
if (info.Address < addressRounded)
{
blocksNeeded++;
}
// If the last block ends after the aligned range, it will need to be split.
if (endAddrTruncated - 1 < info.Address + info.Size - 1)
{
blocksNeeded++;
}
if ((info.Permission & KMemoryPermission.ReadAndWrite) != permissionMask && info.IpcRefCount == 0)
{
result = Reprotect(blockAddress, blockPagesCount, permissionMask);
if (result != KernelResult.Success)
{
CleanUpForError();
return result;
}
}
visitedSize += blockSize;
}
}
return KernelResult.Success;
}
private KernelResult MapPagesFromClientProcess(
ulong size,
ulong address,
KMemoryPermission permission,
MemoryState state,
KPageTableBase srcPageTable,
bool send,
out ulong dst)
{
dst = 0;
if (!_slabManager.CanAllocate(MaxBlocksNeededForInsertion))
{
return KernelResult.OutOfResource;
}
ulong endAddr = address + size;
ulong addressTruncated = BitUtils.AlignDown(address, PageSize);
ulong addressRounded = BitUtils.AlignUp(address, PageSize);
ulong endAddrTruncated = BitUtils.AlignDown(endAddr, PageSize);
ulong endAddrRounded = BitUtils.AlignUp(endAddr, PageSize);
ulong neededSize = endAddrRounded - addressTruncated;
ulong neededPagesCount = neededSize / PageSize;
ulong regionPagesCount = (AliasRegionEnd - AliasRegionStart) / PageSize;
ulong va = 0;
for (int unit = MappingUnitSizes.Length - 1; unit >= 0 && va == 0; unit--)
{
int alignment = MappingUnitSizes[unit];
va = AllocateVa(AliasRegionStart, regionPagesCount, neededPagesCount, alignment);
}
if (va == 0)
{
return KernelResult.OutOfVaSpace;
}
ulong dstFirstPagePa = 0;
ulong dstLastPagePa = 0;
ulong currentVa = va;
using var _ = new OnScopeExit(() =>
{
if (dstFirstPagePa != 0)
{
Context.MemoryManager.DecrementPagesReferenceCount(dstFirstPagePa, 1);
}
if (dstLastPagePa != 0)
{
Context.MemoryManager.DecrementPagesReferenceCount(dstLastPagePa, 1);
}
});
void CleanUpForError()
{
if (currentVa != va)
{
Unmap(va, (currentVa - va) / PageSize);
}
}
// Is the first page address aligned?
// If not, allocate a new page and copy the unaligned chunck.
if (addressTruncated < addressRounded)
{
dstFirstPagePa = GetMemoryRegionManager().AllocatePagesContiguous(Context, 1, _aslrDisabled);
if (dstFirstPagePa == 0)
{
CleanUpForError();
return KernelResult.OutOfMemory;
}
}
// Is the last page end address aligned?
// If not, allocate a new page and copy the unaligned chunck.
if (endAddrTruncated < endAddrRounded && (addressTruncated == addressRounded || addressTruncated < endAddrTruncated))
{
dstLastPagePa = GetMemoryRegionManager().AllocatePagesContiguous(Context, 1, _aslrDisabled);
if (dstLastPagePa == 0)
{
CleanUpForError();
return KernelResult.OutOfMemory;
}
}
if (dstFirstPagePa != 0)
{
ulong firstPageFillAddress = dstFirstPagePa;
ulong unusedSizeAfter;
if (send)
{
ulong unusedSizeBefore = address - addressTruncated;
Context.Memory.Fill(GetDramAddressFromPa(dstFirstPagePa), unusedSizeBefore, (byte)_ipcFillValue);
ulong copySize = addressRounded <= endAddr ? addressRounded - address : size;
var data = srcPageTable.GetSpan(addressTruncated + unusedSizeBefore, (int)copySize);
Context.Memory.Write(GetDramAddressFromPa(dstFirstPagePa + unusedSizeBefore), data);
firstPageFillAddress += unusedSizeBefore + copySize;
unusedSizeAfter = addressRounded > endAddr ? addressRounded - endAddr : 0;
}
else
{
unusedSizeAfter = PageSize;
}
if (unusedSizeAfter != 0)
{
Context.Memory.Fill(GetDramAddressFromPa(firstPageFillAddress), unusedSizeAfter, (byte)_ipcFillValue);
}
KernelResult result = MapPages(currentVa, 1, dstFirstPagePa, permission);
if (result != KernelResult.Success)
{
CleanUpForError();
return result;
}
currentVa += PageSize;
}
if (endAddrTruncated > addressRounded)
{
ulong alignedSize = endAddrTruncated - addressRounded;
KPageList pageList = new KPageList();
srcPageTable.GetPhysicalRegions(addressRounded, alignedSize, pageList);
KernelResult result = MapPages(currentVa, pageList, permission);
if (result != KernelResult.Success)
{
CleanUpForError();
return result;
}
currentVa += alignedSize;
}
if (dstLastPagePa != 0)
{
ulong lastPageFillAddr = dstLastPagePa;
ulong unusedSizeAfter;
if (send)
{
ulong copySize = endAddr - endAddrTruncated;
var data = srcPageTable.GetSpan(endAddrTruncated, (int)copySize);
Context.Memory.Write(GetDramAddressFromPa(dstLastPagePa), data);
lastPageFillAddr += copySize;
unusedSizeAfter = PageSize - copySize;
}
else
{
unusedSizeAfter = PageSize;
}
Context.Memory.Fill(GetDramAddressFromPa(lastPageFillAddr), unusedSizeAfter, (byte)_ipcFillValue);
KernelResult result = MapPages(currentVa, 1, dstLastPagePa, permission);
if (result != KernelResult.Success)
{
CleanUpForError();
return result;
}
}
_blockManager.InsertBlock(va, neededPagesCount, state, permission);
dst = va + (address - addressTruncated);
return KernelResult.Success;
}
public KernelResult UnmapNoAttributeIfStateEquals(ulong address, ulong size, MemoryState state)
{
if (AddrSpaceStart > address)
{
return KernelResult.InvalidMemState;
}
ulong endAddr = address + size;
if (endAddr <= address || endAddr - 1 > AddrSpaceEnd - 1)
{
return KernelResult.InvalidMemState;
}
lock (_blockManager)
{
if (CheckRange(
address,
size,
MemoryState.Mask,
state,
KMemoryPermission.Read,
KMemoryPermission.Read,
MemoryAttribute.Mask,
MemoryAttribute.None,
MemoryAttribute.IpcAndDeviceMapped,
out _,
out _,
out _))
{
if (!_slabManager.CanAllocate(MaxBlocksNeededForInsertion))
{
return KernelResult.OutOfResource;
}
ulong addressTruncated = BitUtils.AlignDown(address, PageSize);
ulong addressRounded = BitUtils.AlignUp(address, PageSize);
ulong endAddrTruncated = BitUtils.AlignDown(endAddr, PageSize);
ulong endAddrRounded = BitUtils.AlignUp(endAddr, PageSize);
ulong pagesCount = (endAddrRounded - addressTruncated) / PageSize;
KernelResult result = Unmap(addressTruncated, pagesCount);
if (result == KernelResult.Success)
{
_blockManager.InsertBlock(addressTruncated, pagesCount, MemoryState.Unmapped);
}
return result;
}
else
{
return KernelResult.InvalidMemState;
}
}
}
public KernelResult UnmapIpcRestorePermission(ulong address, ulong size, MemoryState state)
{
ulong endAddr = address + size;
ulong addressRounded = BitUtils.AlignUp(address, PageSize);
ulong addressTruncated = BitUtils.AlignDown(address, PageSize);
ulong endAddrRounded = BitUtils.AlignUp(endAddr, PageSize);
ulong endAddrTruncated = BitUtils.AlignDown(endAddr, PageSize);
ulong pagesCount = addressRounded < endAddrTruncated ? (endAddrTruncated - addressRounded) / PageSize : 0;
if (pagesCount == 0)
{
return KernelResult.Success;
}
MemoryState stateMask;
switch (state)
{
case MemoryState.IpcBuffer0: stateMask = MemoryState.IpcSendAllowedType0; break;
case MemoryState.IpcBuffer1: stateMask = MemoryState.IpcSendAllowedType1; break;
case MemoryState.IpcBuffer3: stateMask = MemoryState.IpcSendAllowedType3; break;
default: return KernelResult.InvalidCombination;
}
MemoryAttribute attributeMask =
MemoryAttribute.Borrowed |
MemoryAttribute.IpcMapped |
MemoryAttribute.Uncached;
if (state == MemoryState.IpcBuffer0)
{
attributeMask |= MemoryAttribute.DeviceMapped;
}
if (!_slabManager.CanAllocate(MaxBlocksNeededForInsertion))
{
return KernelResult.OutOfResource;
}
// Anything on the client side should see this memory as modified.
SignalMemoryTracking(addressTruncated, endAddrRounded - addressTruncated, true);
lock (_blockManager)
{
foreach (KMemoryInfo info in IterateOverRange(addressRounded, endAddrTruncated))
{
// Check if the block state matches what we expect.
if ((info.State & stateMask) != stateMask ||
(info.Attribute & attributeMask) != MemoryAttribute.IpcMapped)
{
return KernelResult.InvalidMemState;
}
if (info.Permission != info.SourcePermission && info.IpcRefCount == 1)
{
ulong blockAddress = GetAddrInRange(info, addressRounded);
ulong blockSize = GetSizeInRange(info, addressRounded, endAddrTruncated);
ulong blockPagesCount = blockSize / PageSize;
KernelResult result = Reprotect(blockAddress, blockPagesCount, info.SourcePermission);
if (result != KernelResult.Success)
{
return result;
}
}
}
_blockManager.InsertBlock(addressRounded, pagesCount, RestoreIpcMappingPermissions);
return KernelResult.Success;
}
}
private static void SetIpcMappingPermissions(KMemoryBlock block, KMemoryPermission permission)
{
block.SetIpcMappingPermission(permission);
}
private static void RestoreIpcMappingPermissions(KMemoryBlock block, KMemoryPermission permission)
{
block.RestoreIpcMappingPermission();
}
public KernelResult BorrowIpcBuffer(ulong address, ulong size)
{
return SetAttributesAndChangePermission(
address,
size,
MemoryState.IpcBufferAllowed,
MemoryState.IpcBufferAllowed,
KMemoryPermission.Mask,
KMemoryPermission.ReadAndWrite,
MemoryAttribute.Mask,
MemoryAttribute.None,
KMemoryPermission.None,
MemoryAttribute.Borrowed);
}
public KernelResult BorrowTransferMemory(KPageList pageList, ulong address, ulong size, KMemoryPermission permission)
{
return SetAttributesAndChangePermission(
address,
size,
MemoryState.TransferMemoryAllowed,
MemoryState.TransferMemoryAllowed,
KMemoryPermission.Mask,
KMemoryPermission.ReadAndWrite,
MemoryAttribute.Mask,
MemoryAttribute.None,
permission,
MemoryAttribute.Borrowed,
pageList);
}
private KernelResult SetAttributesAndChangePermission(
ulong address,
ulong size,
MemoryState stateMask,
MemoryState stateExpected,
KMemoryPermission permissionMask,
KMemoryPermission permissionExpected,
MemoryAttribute attributeMask,
MemoryAttribute attributeExpected,
KMemoryPermission newPermission,
MemoryAttribute attributeSetMask,
KPageList pageList = null)
{
if (address + size <= address || !InsideAddrSpace(address, size))
{
return KernelResult.InvalidMemState;
}
lock (_blockManager)
{
if (CheckRange(
address,
size,
stateMask | MemoryState.IsPoolAllocated,
stateExpected | MemoryState.IsPoolAllocated,
permissionMask,
permissionExpected,
attributeMask,
attributeExpected,
MemoryAttribute.IpcAndDeviceMapped,
out MemoryState oldState,
out KMemoryPermission oldPermission,
out MemoryAttribute oldAttribute))
{
ulong pagesCount = size / PageSize;
if (pageList != null)
{
GetPhysicalRegions(address, pagesCount * PageSize, pageList);
}
if (!_slabManager.CanAllocate(MaxBlocksNeededForInsertion))
{
return KernelResult.OutOfResource;
}
if (newPermission == KMemoryPermission.None)
{
newPermission = oldPermission;
}
if (newPermission != oldPermission)
{
KernelResult result = Reprotect(address, pagesCount, newPermission);
if (result != KernelResult.Success)
{
return result;
}
}
MemoryAttribute newAttribute = oldAttribute | attributeSetMask;
_blockManager.InsertBlock(address, pagesCount, oldState, newPermission, newAttribute);
return KernelResult.Success;
}
else
{
return KernelResult.InvalidMemState;
}
}
}
public KernelResult UnborrowIpcBuffer(ulong address, ulong size)
{
return ClearAttributesAndChangePermission(
address,
size,
MemoryState.IpcBufferAllowed,
MemoryState.IpcBufferAllowed,
KMemoryPermission.None,
KMemoryPermission.None,
MemoryAttribute.Mask,
MemoryAttribute.Borrowed,
KMemoryPermission.ReadAndWrite,
MemoryAttribute.Borrowed);
}
public KernelResult UnborrowTransferMemory(ulong address, ulong size, KPageList pageList)
{
return ClearAttributesAndChangePermission(
address,
size,
MemoryState.TransferMemoryAllowed,
MemoryState.TransferMemoryAllowed,
KMemoryPermission.None,
KMemoryPermission.None,
MemoryAttribute.Mask,
MemoryAttribute.Borrowed,
KMemoryPermission.ReadAndWrite,
MemoryAttribute.Borrowed,
pageList);
}
private KernelResult ClearAttributesAndChangePermission(
ulong address,
ulong size,
MemoryState stateMask,
MemoryState stateExpected,
KMemoryPermission permissionMask,
KMemoryPermission permissionExpected,
MemoryAttribute attributeMask,
MemoryAttribute attributeExpected,
KMemoryPermission newPermission,
MemoryAttribute attributeClearMask,
KPageList pageList = null)
{
if (address + size <= address || !InsideAddrSpace(address, size))
{
return KernelResult.InvalidMemState;
}
lock (_blockManager)
{
if (CheckRange(
address,
size,
stateMask | MemoryState.IsPoolAllocated,
stateExpected | MemoryState.IsPoolAllocated,
permissionMask,
permissionExpected,
attributeMask,
attributeExpected,
MemoryAttribute.IpcAndDeviceMapped,
out MemoryState oldState,
out KMemoryPermission oldPermission,
out MemoryAttribute oldAttribute))
{
ulong pagesCount = size / PageSize;
if (pageList != null)
{
KPageList currentPageList = new KPageList();
GetPhysicalRegions(address, pagesCount * PageSize, currentPageList);
if (!currentPageList.IsEqual(pageList))
{
return KernelResult.InvalidMemRange;
}
}
if (!_slabManager.CanAllocate(MaxBlocksNeededForInsertion))
{
return KernelResult.OutOfResource;
}
if (newPermission == KMemoryPermission.None)
{
newPermission = oldPermission;
}
if (newPermission != oldPermission)
{
KernelResult result = Reprotect(address, pagesCount, newPermission);
if (result != KernelResult.Success)
{
return result;
}
}
MemoryAttribute newAttribute = oldAttribute & ~attributeClearMask;
_blockManager.InsertBlock(address, pagesCount, oldState, newPermission, newAttribute);
return KernelResult.Success;
}
else
{
return KernelResult.InvalidMemState;
}
}
}
private static ulong GetAddrInRange(KMemoryInfo info, ulong start)
{
if (info.Address < start)
{
return start;
}
return info.Address;
}
private static ulong GetSizeInRange(KMemoryInfo info, ulong start, ulong end)
{
ulong endAddr = info.Size + info.Address;
ulong size = info.Size;
if (info.Address < start)
{
size -= start - info.Address;
}
if (endAddr > end)
{
size -= endAddr - end;
}
return size;
}
private bool IsUnmapped(ulong address, ulong size)
{
return CheckRange(
address,
size,
MemoryState.Mask,
MemoryState.Unmapped,
KMemoryPermission.Mask,
KMemoryPermission.None,
MemoryAttribute.Mask,
MemoryAttribute.None,
MemoryAttribute.IpcAndDeviceMapped,
out _,
out _,
out _);
}
private bool CheckRange(
ulong address,
ulong size,
MemoryState stateMask,
MemoryState stateExpected,
KMemoryPermission permissionMask,
KMemoryPermission permissionExpected,
MemoryAttribute attributeMask,
MemoryAttribute attributeExpected,
MemoryAttribute attributeIgnoreMask,
out MemoryState outState,
out KMemoryPermission outPermission,
out MemoryAttribute outAttribute)
{
ulong endAddr = address + size;
LinkedListNode<KMemoryBlock> node = _blockManager.FindBlockNode(address);
KMemoryInfo info = node.Value.GetInfo();
MemoryState firstState = info.State;
KMemoryPermission firstPermission = info.Permission;
MemoryAttribute firstAttribute = info.Attribute;
do
{
info = node.Value.GetInfo();
// Check if the block state matches what we expect.
if (firstState != info.State ||
firstPermission != info.Permission ||
(info.Attribute & attributeMask) != attributeExpected ||
(firstAttribute | attributeIgnoreMask) != (info.Attribute | attributeIgnoreMask) ||
(firstState & stateMask) != stateExpected ||
(firstPermission & permissionMask) != permissionExpected)
{
outState = MemoryState.Unmapped;
outPermission = KMemoryPermission.None;
outAttribute = MemoryAttribute.None;
return false;
}
}
while (info.Address + info.Size - 1 < endAddr - 1 && (node = node.Next) != null);
outState = firstState;
outPermission = firstPermission;
outAttribute = firstAttribute & ~attributeIgnoreMask;
return true;
}
private bool CheckRange(
ulong address,
ulong size,
MemoryState stateMask,
MemoryState stateExpected,
KMemoryPermission permissionMask,
KMemoryPermission permissionExpected,
MemoryAttribute attributeMask,
MemoryAttribute attributeExpected)
{
foreach (KMemoryInfo info in IterateOverRange(address, address + size))
{
// Check if the block state matches what we expect.
if ((info.State & stateMask) != stateExpected ||
(info.Permission & permissionMask) != permissionExpected ||
(info.Attribute & attributeMask) != attributeExpected)
{
return false;
}
}
return true;
}
private IEnumerable<KMemoryInfo> IterateOverRange(ulong start, ulong end)
{
LinkedListNode<KMemoryBlock> node = _blockManager.FindBlockNode(start);
KMemoryInfo info;
do
{
info = node.Value.GetInfo();
yield return info;
}
while (info.Address + info.Size - 1 < end - 1 && (node = node.Next) != null);
}
private ulong AllocateVa(ulong regionStart, ulong regionPagesCount, ulong neededPagesCount, int alignment)
{
ulong address = 0;
ulong regionEndAddr = regionStart + regionPagesCount * PageSize;
ulong reservedPagesCount = _isKernel ? 1UL : 4UL;
if (_aslrEnabled)
{
ulong totalNeededSize = (reservedPagesCount + neededPagesCount) * PageSize;
ulong remainingPages = regionPagesCount - neededPagesCount;
ulong aslrMaxOffset = ((remainingPages + reservedPagesCount) * PageSize) / (ulong)alignment;
for (int attempt = 0; attempt < 8; attempt++)
{
address = BitUtils.AlignDown(regionStart + GetRandomValue(0, aslrMaxOffset) * (ulong)alignment, alignment);
ulong endAddr = address + totalNeededSize;
KMemoryInfo info = _blockManager.FindBlock(address).GetInfo();
if (info.State != MemoryState.Unmapped)
{
continue;
}
ulong currBaseAddr = info.Address + reservedPagesCount * PageSize;
ulong currEndAddr = info.Address + info.Size;
if (address >= regionStart &&
address >= currBaseAddr &&
endAddr - 1 <= regionEndAddr - 1 &&
endAddr - 1 <= currEndAddr - 1)
{
break;
}
}
if (address == 0)
{
ulong aslrPage = GetRandomValue(0, aslrMaxOffset);
address = FindFirstFit(
regionStart + aslrPage * PageSize,
regionPagesCount - aslrPage,
neededPagesCount,
alignment,
0,
reservedPagesCount);
}
}
if (address == 0)
{
address = FindFirstFit(
regionStart,
regionPagesCount,
neededPagesCount,
alignment,
0,
reservedPagesCount);
}
return address;
}
private ulong FindFirstFit(
ulong regionStart,
ulong regionPagesCount,
ulong neededPagesCount,
int alignment,
ulong reservedStart,
ulong reservedPagesCount)
{
ulong reservedSize = reservedPagesCount * PageSize;
ulong totalNeededSize = reservedSize + neededPagesCount * PageSize;
ulong regionEndAddr = regionStart + regionPagesCount * PageSize;
LinkedListNode<KMemoryBlock> node = _blockManager.FindBlockNode(regionStart);
KMemoryInfo info = node.Value.GetInfo();
while (regionEndAddr >= info.Address)
{
if (info.State == MemoryState.Unmapped)
{
ulong currBaseAddr = info.Address <= regionStart ? regionStart : info.Address;
ulong currEndAddr = info.Address + info.Size - 1;
currBaseAddr += reservedSize;
ulong address = BitUtils.AlignDown(currBaseAddr, alignment) + reservedStart;
if (currBaseAddr > address)
{
address += (ulong)alignment;
}
ulong allocationEndAddr = address + totalNeededSize - 1;
if (info.Address <= address &&
address < allocationEndAddr &&
allocationEndAddr <= regionEndAddr &&
allocationEndAddr <= currEndAddr)
{
return address;
}
}
node = node.Next;
if (node == null)
{
break;
}
info = node.Value.GetInfo();
}
return 0;
}
public bool CanContain(ulong address, ulong size, MemoryState state)
{
ulong endAddr = address + size;
ulong regionBaseAddr = GetBaseAddress(state);
ulong regionEndAddr = regionBaseAddr + GetSize(state);
bool InsideRegion()
{
return regionBaseAddr <= address &&
endAddr > address &&
endAddr - 1 <= regionEndAddr - 1;
}
bool OutsideHeapRegion()
{
return endAddr <= HeapRegionStart || address >= HeapRegionEnd;
}
bool OutsideAliasRegion()
{
return endAddr <= AliasRegionStart || address >= AliasRegionEnd;
}
switch (state)
{
case MemoryState.Io:
case MemoryState.Normal:
case MemoryState.CodeStatic:
case MemoryState.CodeMutable:
case MemoryState.SharedMemory:
case MemoryState.ModCodeStatic:
case MemoryState.ModCodeMutable:
case MemoryState.Stack:
case MemoryState.ThreadLocal:
case MemoryState.TransferMemoryIsolated:
case MemoryState.TransferMemory:
case MemoryState.ProcessMemory:
case MemoryState.CodeReadOnly:
case MemoryState.CodeWritable:
return InsideRegion() && OutsideHeapRegion() && OutsideAliasRegion();
case MemoryState.Heap:
return InsideRegion() && OutsideAliasRegion();
case MemoryState.IpcBuffer0:
case MemoryState.IpcBuffer1:
case MemoryState.IpcBuffer3:
return InsideRegion() && OutsideHeapRegion();
case MemoryState.KernelStack:
return InsideRegion();
}
throw new ArgumentException($"Invalid state value \"{state}\".");
}
private ulong GetBaseAddress(MemoryState state)
{
switch (state)
{
case MemoryState.Io:
case MemoryState.Normal:
case MemoryState.ThreadLocal:
return TlsIoRegionStart;
case MemoryState.CodeStatic:
case MemoryState.CodeMutable:
case MemoryState.SharedMemory:
case MemoryState.ModCodeStatic:
case MemoryState.ModCodeMutable:
case MemoryState.TransferMemoryIsolated:
case MemoryState.TransferMemory:
case MemoryState.ProcessMemory:
case MemoryState.CodeReadOnly:
case MemoryState.CodeWritable:
return GetAddrSpaceBaseAddr();
case MemoryState.Heap:
return HeapRegionStart;
case MemoryState.IpcBuffer0:
case MemoryState.IpcBuffer1:
case MemoryState.IpcBuffer3:
return AliasRegionStart;
case MemoryState.Stack:
return StackRegionStart;
case MemoryState.KernelStack:
return AddrSpaceStart;
}
throw new ArgumentException($"Invalid state value \"{state}\".");
}
private ulong GetSize(MemoryState state)
{
switch (state)
{
case MemoryState.Io:
case MemoryState.Normal:
case MemoryState.ThreadLocal:
return TlsIoRegionEnd - TlsIoRegionStart;
case MemoryState.CodeStatic:
case MemoryState.CodeMutable:
case MemoryState.SharedMemory:
case MemoryState.ModCodeStatic:
case MemoryState.ModCodeMutable:
case MemoryState.TransferMemoryIsolated:
case MemoryState.TransferMemory:
case MemoryState.ProcessMemory:
case MemoryState.CodeReadOnly:
case MemoryState.CodeWritable:
return GetAddrSpaceSize();
case MemoryState.Heap:
return HeapRegionEnd - HeapRegionStart;
case MemoryState.IpcBuffer0:
case MemoryState.IpcBuffer1:
case MemoryState.IpcBuffer3:
return AliasRegionEnd - AliasRegionStart;
case MemoryState.Stack:
return StackRegionEnd - StackRegionStart;
case MemoryState.KernelStack:
return AddrSpaceEnd - AddrSpaceStart;
}
throw new ArgumentException($"Invalid state value \"{state}\".");
}
public ulong GetAddrSpaceBaseAddr()
{
if (AddrSpaceWidth == 36 || AddrSpaceWidth == 39)
{
return 0x8000000;
}
else if (AddrSpaceWidth == 32)
{
return 0x200000;
}
else
{
throw new InvalidOperationException("Invalid address space width!");
}
}
public ulong GetAddrSpaceSize()
{
if (AddrSpaceWidth == 36)
{
return 0xff8000000;
}
else if (AddrSpaceWidth == 39)
{
return 0x7ff8000000;
}
else if (AddrSpaceWidth == 32)
{
return 0xffe00000;
}
else
{
throw new InvalidOperationException("Invalid address space width!");
}
}
private static ulong GetDramAddressFromPa(ulong pa)
{
return pa - DramMemoryMap.DramBase;
}
protected KMemoryRegionManager GetMemoryRegionManager()
{
return Context.MemoryManager.MemoryRegions[(int)_memRegion];
}
public ulong GetMmUsedPages()
{
lock (_blockManager)
{
return BitUtils.DivRoundUp(GetMmUsedSize(), PageSize);
}
}
private ulong GetMmUsedSize()
{
return (ulong)(_blockManager.BlocksCount * KMemoryBlockSize);
}
public bool IsInvalidRegion(ulong address, ulong size)
{
return address + size - 1 > GetAddrSpaceBaseAddr() + GetAddrSpaceSize() - 1;
}
public bool InsideAddrSpace(ulong address, ulong size)
{
return AddrSpaceStart <= address && address + size - 1 <= AddrSpaceEnd - 1;
}
public bool InsideAliasRegion(ulong address, ulong size)
{
return address + size > AliasRegionStart && AliasRegionEnd > address;
}
public bool InsideHeapRegion(ulong address, ulong size)
{
return address + size > HeapRegionStart && HeapRegionEnd > address;
}
public bool InsideStackRegion(ulong address, ulong size)
{
return address + size > StackRegionStart && StackRegionEnd > address;
}
public bool OutsideAliasRegion(ulong address, ulong size)
{
return AliasRegionStart > address || address + size - 1 > AliasRegionEnd - 1;
}
public bool OutsideAddrSpace(ulong address, ulong size)
{
return AddrSpaceStart > address || address + size - 1 > AddrSpaceEnd - 1;
}
public bool OutsideStackRegion(ulong address, ulong size)
{
return StackRegionStart > address || address + size - 1 > StackRegionEnd - 1;
}
/// <summary>
/// Gets the physical regions that make up the given virtual address region.
/// If any part of the virtual region is unmapped, null is returned.
/// </summary>
/// <param name="va">Virtual address of the range</param>
/// <param name="size">Size of the range</param>
/// <param name="pageList">Page list where the ranges will be added</param>
protected abstract void GetPhysicalRegions(ulong va, ulong size, KPageList pageList);
/// <summary>
/// Gets a read-only span of data from CPU mapped memory.
/// </summary>
/// <remarks>
/// This may perform a allocation if the data is not contiguous in memory.
/// For this reason, the span is read-only, you can't modify the data.
/// </remarks>
/// <param name="va">Virtual address of the data</param>
/// <param name="size">Size of the data</param>
/// <param name="tracked">True if read tracking is triggered on the span</param>
/// <returns>A read-only span of the data</returns>
/// <exception cref="Ryujinx.Memory.InvalidMemoryRegionException">Throw for unhandled invalid or unmapped memory accesses</exception>
protected abstract ReadOnlySpan<byte> GetSpan(ulong va, int size);
/// <summary>
/// Maps a new memory region with the contents of a existing memory region.
/// </summary>
/// <param name="src">Source memory region where the data will be taken from</param>
/// <param name="dst">Destination memory region to map</param>
/// <param name="pagesCount">Number of pages to map</param>
/// <param name="oldSrcPermission">Current protection of the source memory region</param>
/// <param name="newDstPermission">Desired protection for the destination memory region</param>
/// <returns>Result of the mapping operation</returns>
protected abstract KernelResult MapMemory(ulong src, ulong dst, ulong pagesCount, KMemoryPermission oldSrcPermission, KMemoryPermission newDstPermission);
/// <summary>
/// Unmaps a region of memory that was previously mapped with <see cref="MapMemory"/>.
/// </summary>
/// <param name="dst">Destination memory region to be unmapped</param>
/// <param name="src">Source memory region that was originally remapped</param>
/// <param name="pagesCount">Number of pages to unmap</param>
/// <param name="oldDstPermission">Current protection of the destination memory region</param>
/// <param name="newSrcPermission">Desired protection of the source memory region</param>
/// <returns>Result of the unmapping operation</returns>
protected abstract KernelResult UnmapMemory(ulong dst, ulong src, ulong pagesCount, KMemoryPermission oldDstPermission, KMemoryPermission newSrcPermission);
/// <summary>
/// Maps a region of memory into the specified physical memory region.
/// </summary>
/// <param name="dstVa">Destination virtual address that should be mapped</param>
/// <param name="pagesCount">Number of pages to map</param>
/// <param name="srcPa">Physical address where the pages should be mapped. May be ignored if aliasing is not supported</param>
/// <param name="permission">Permission of the region to be mapped</param>
/// <param name="shouldFillPages">Indicate if the pages should be filled with the <paramref name="fillValue"/> value</param>
/// <param name="fillValue">The value used to fill pages when <paramref name="shouldFillPages"/> is set to true</param>
/// <returns>Result of the mapping operation</returns>
protected abstract KernelResult MapPages(ulong dstVa, ulong pagesCount, ulong srcPa, KMemoryPermission permission, bool shouldFillPages = false, byte fillValue = 0);
/// <summary>
/// Maps a region of memory into the specified physical memory region.
/// </summary>
/// <param name="address">Destination virtual address that should be mapped</param>
/// <param name="pageList">List of physical memory pages where the pages should be mapped. May be ignored if aliasing is not supported</param>
/// <param name="permission">Permission of the region to be mapped</param>
/// <param name="shouldFillPages">Indicate if the pages should be filled with the <paramref name="fillValue"/> value</param>
/// <param name="fillValue">The value used to fill pages when <paramref name="shouldFillPages"/> is set to true</param>
/// <returns>Result of the mapping operation</returns>
protected abstract KernelResult MapPages(ulong address, KPageList pageList, KMemoryPermission permission, bool shouldFillPages = false, byte fillValue = 0);
/// <summary>
/// Unmaps a region of memory that was previously mapped with one of the page mapping methods.
/// </summary>
/// <param name="address">Virtual address of the region to unmap</param>
/// <param name="pagesCount">Number of pages to unmap</param>
/// <returns>Result of the unmapping operation</returns>
protected abstract KernelResult Unmap(ulong address, ulong pagesCount);
/// <summary>
/// Changes the permissions of a given virtual memory region.
/// </summary>
/// <param name="address">Virtual address of the region to have the permission changes</param>
/// <param name="pagesCount">Number of pages to have their permissions changed</param>
/// <param name="permission">New permission</param>
/// <returns>Result of the permission change operation</returns>
protected abstract KernelResult Reprotect(ulong address, ulong pagesCount, KMemoryPermission permission);
/// <summary>
/// Changes the permissions of a given virtual memory region.
/// </summary>
/// <param name="address">Virtual address of the region to have the permission changes</param>
/// <param name="pagesCount">Number of pages to have their permissions changed</param>
/// <param name="permission">New permission</param>
/// <returns>Result of the permission change operation</returns>
protected abstract KernelResult ReprotectWithAttributes(ulong address, ulong pagesCount, KMemoryPermission permission);
/// <summary>
/// Alerts the memory tracking that a given region has been read from or written to.
/// This should be called before read/write is performed.
/// </summary>
/// <param name="va">Virtual address of the region</param>
/// <param name="size">Size of the region</param>
protected abstract void SignalMemoryTracking(ulong va, ulong size, bool write);
/// <summary>
/// Writes data to CPU mapped memory, with write tracking.
/// </summary>
/// <param name="va">Virtual address to write the data into</param>
/// <param name="data">Data to be written</param>
/// <exception cref="Ryujinx.Memory.InvalidMemoryRegionException">Throw for unhandled invalid or unmapped memory accesses</exception>
protected abstract void Write(ulong va, ReadOnlySpan<byte> data);
}
}