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Ryujinx/ARMeilleure/Memory/MemoryManager.cs
Ficture Seven e4ee61d6c3
Improve V128 (#1097) 
* Improve V128

* Use LayoutKind.Sequential instead

* Add As<T>, Get<T> & Set<T>

* Fix CpuTest

* Rename Get<T> & Set<T> to Extract<T> & Insert<T>

* Add XML documentation

* Nit
2020-04-17 08:19:20 +10:00

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using ARMeilleure.State;
using System;
using System.Collections.Generic;
using System.Runtime.CompilerServices;
using System.Runtime.InteropServices;
using System.Threading;
using static ARMeilleure.Memory.MemoryManagement;
namespace ARMeilleure.Memory
{
public unsafe class MemoryManager
{
public const int PageBits = 12;
public const int PageSize = 1 << PageBits;
public const int PageMask = PageSize - 1;
internal const long PteFlagsMask = 7;
public IntPtr Ram { get; private set; }
private byte* _ramPtr;
private IntPtr _pageTable;
internal IntPtr PageTable => _pageTable;
internal int PtLevelBits { get; }
internal int PtLevelSize { get; }
internal int PtLevelMask { get; }
public int AddressSpaceBits { get; }
public long AddressSpaceSize { get; }
public MemoryManager(
IntPtr ram,
int addressSpaceBits = 48,
bool useFlatPageTable = false)
{
Ram = ram;
_ramPtr = (byte*)ram;
AddressSpaceBits = addressSpaceBits;
AddressSpaceSize = 1L << addressSpaceBits;
// When flat page table is requested, we use a single
// array for the mappings of the entire address space.
// This has better performance, but also high memory usage.
// The multi level page table uses 9 bits per level, so
// the memory usage is lower, but the performance is also
// lower, since each address translation requires multiple reads.
if (useFlatPageTable)
{
PtLevelBits = addressSpaceBits - PageBits;
}
else
{
PtLevelBits = 9;
}
PtLevelSize = 1 << PtLevelBits;
PtLevelMask = PtLevelSize - 1;
_pageTable = Allocate((ulong)(PtLevelSize * IntPtr.Size));
}
public void Map(long va, long pa, long size)
{
SetPtEntries(va, _ramPtr + pa, size);
}
public void Unmap(long position, long size)
{
SetPtEntries(position, null, size);
}
public bool IsMapped(long position)
{
return Translate(position) != IntPtr.Zero;
}
public long GetPhysicalAddress(long virtualAddress)
{
byte* ptr = (byte*)Translate(virtualAddress);
return (long)(ptr - _ramPtr);
}
private IntPtr Translate(long position)
{
if (!IsValidPosition(position))
{
return IntPtr.Zero;
}
byte* ptr = GetPtEntry(position);
ulong ptrUlong = (ulong)ptr;
if ((ptrUlong & PteFlagsMask) != 0)
{
ptrUlong &= ~(ulong)PteFlagsMask;
ptr = (byte*)ptrUlong;
}
if (ptr == null)
{
return IntPtr.Zero;
}
return new IntPtr(ptr + (position & PageMask));
}
private IntPtr TranslateWrite(long position)
{
if (!IsValidPosition(position))
{
return IntPtr.Zero;
}
byte* ptr = GetPtEntry(position);
ulong ptrUlong = (ulong)ptr;
if ((ptrUlong & PteFlagsMask) != 0)
{
ClearPtEntryFlag(position, PteFlagsMask);
ptrUlong &= ~(ulong)PteFlagsMask;
ptr = (byte*)ptrUlong;
}
return new IntPtr(ptr + (position & PageMask));
}
private byte* GetPtEntry(long position)
{
return *(byte**)GetPtPtr(position);
}
private void SetPtEntries(long va, byte* ptr, long size)
{
long endPosition = (va + size + PageMask) & ~PageMask;
while ((ulong)va < (ulong)endPosition)
{
SetPtEntry(va, ptr);
va += PageSize;
if (ptr != null)
{
ptr += PageSize;
}
}
}
private void SetPtEntry(long position, byte* ptr)
{
*(byte**)GetPtPtr(position) = ptr;
}
private void SetPtEntryFlag(long position, long flag)
{
ModifyPtEntryFlag(position, flag, setFlag: true);
}
private void ClearPtEntryFlag(long position, long flag)
{
ModifyPtEntryFlag(position, flag, setFlag: false);
}
private void ModifyPtEntryFlag(long position, long flag, bool setFlag)
{
IntPtr* pt = (IntPtr*)_pageTable;
while (true)
{
IntPtr* ptPtr = GetPtPtr(position);
IntPtr old = *ptPtr;
long modified = old.ToInt64();
if (setFlag)
{
modified |= flag;
}
else
{
modified &= ~flag;
}
IntPtr origValue = Interlocked.CompareExchange(ref *ptPtr, new IntPtr(modified), old);
if (origValue == old)
{
break;
}
}
}
private IntPtr* GetPtPtr(long position)
{
if (!IsValidPosition(position))
{
throw new ArgumentOutOfRangeException(nameof(position));
}
IntPtr nextPtr = _pageTable;
IntPtr* ptePtr = null;
int bit = PageBits;
while (true)
{
long index = (position >> bit) & PtLevelMask;
ptePtr = &((IntPtr*)nextPtr)[index];
bit += PtLevelBits;
if (bit >= AddressSpaceBits)
{
break;
}
nextPtr = *ptePtr;
if (nextPtr == IntPtr.Zero)
{
// Entry does not yet exist, allocate a new one.
IntPtr newPtr = Allocate((ulong)(PtLevelSize * IntPtr.Size));
// Try to swap the current pointer (should be zero), with the allocated one.
nextPtr = Interlocked.CompareExchange(ref *ptePtr, newPtr, IntPtr.Zero);
// If the old pointer is not null, then another thread already has set it.
if (nextPtr != IntPtr.Zero)
{
Free(newPtr);
}
else
{
nextPtr = newPtr;
}
}
}
return ptePtr;
}
public unsafe (ulong, ulong)[] GetModifiedRanges(ulong address, ulong size, int id)
{
ulong idMask = 1UL << id;
List<(ulong, ulong)> ranges = new List<(ulong, ulong)>();
ulong endAddress = (address + size + PageMask) & ~(ulong)PageMask;
address &= ~(ulong)PageMask;
ulong currAddr = address;
ulong currSize = 0;
while (address < endAddress)
{
// If the address is invalid, we stop and consider all the remaining memory
// as not modified (since the address is invalid, we can't check, and technically
// the memory doesn't exist).
if (!IsValidPosition((long)address))
{
break;
}
byte* ptr = ((byte**)_pageTable)[address >> PageBits];
ulong ptrUlong = (ulong)ptr;
if ((ptrUlong & idMask) == 0)
{
// Modified.
currSize += PageSize;
SetPtEntryFlag((long)address, (long)idMask);
}
else
{
if (currSize != 0)
{
ranges.Add((currAddr, currSize));
}
currAddr = address + PageSize;
currSize = 0;
}
address += PageSize;
}
if (currSize != 0)
{
ranges.Add((currAddr, currSize));
}
return ranges.ToArray();
}
private bool IsContiguous(long position, long size)
{
long endPos = position + size;
position &= ~PageMask;
long expectedPa = GetPhysicalAddress(position);
while ((ulong)position < (ulong)endPos)
{
long pa = GetPhysicalAddress(position);
if (pa != expectedPa)
{
return false;
}
position += PageSize;
expectedPa += PageSize;
}
return true;
}
public bool IsValidPosition(long position)
{
return (ulong)position < (ulong)AddressSpaceSize;
}
internal V128 AtomicLoadInt128(long position)
{
if ((position & 0xf) != 0)
{
AbortWithAlignmentFault(position);
}
IntPtr ptr = TranslateWrite(position);
return MemoryManagerPal.AtomicLoad128(ptr);
}
internal bool AtomicCompareExchangeByte(long position, byte expected, byte desired)
{
int* ptr = (int*)Translate(position);
int currentValue = *ptr;
int expected32 = (currentValue & ~byte.MaxValue) | expected;
int desired32 = (currentValue & ~byte.MaxValue) | desired;
return Interlocked.CompareExchange(ref *ptr, desired32, expected32) == expected32;
}
internal bool AtomicCompareExchangeInt16(long position, short expected, short desired)
{
if ((position & 1) != 0)
{
AbortWithAlignmentFault(position);
}
int* ptr = (int*)Translate(position);
int currentValue = *ptr;
int expected32 = (currentValue & ~ushort.MaxValue) | (ushort)expected;
int desired32 = (currentValue & ~ushort.MaxValue) | (ushort)desired;
return Interlocked.CompareExchange(ref *ptr, desired32, expected32) == expected32;
}
public bool AtomicCompareExchangeInt32(long position, int expected, int desired)
{
if ((position & 3) != 0)
{
AbortWithAlignmentFault(position);
}
int* ptr = (int*)TranslateWrite(position);
return Interlocked.CompareExchange(ref *ptr, desired, expected) == expected;
}
internal bool AtomicCompareExchangeInt64(long position, long expected, long desired)
{
if ((position & 7) != 0)
{
AbortWithAlignmentFault(position);
}
long* ptr = (long*)TranslateWrite(position);
return Interlocked.CompareExchange(ref *ptr, desired, expected) == expected;
}
internal bool AtomicCompareExchangeInt128(long position, V128 expected, V128 desired)
{
if ((position & 0xf) != 0)
{
AbortWithAlignmentFault(position);
}
IntPtr ptr = TranslateWrite(position);
return MemoryManagerPal.CompareAndSwap128(ptr, expected, desired) == expected;
}
public int AtomicIncrementInt32(long position)
{
if ((position & 3) != 0)
{
AbortWithAlignmentFault(position);
}
int* ptr = (int*)TranslateWrite(position);
return Interlocked.Increment(ref *ptr);
}
public int AtomicDecrementInt32(long position)
{
if ((position & 3) != 0)
{
AbortWithAlignmentFault(position);
}
int* ptr = (int*)TranslateWrite(position);
return Interlocked.Decrement(ref *ptr);
}
private void AbortWithAlignmentFault(long position)
{
// TODO: Abort mode and exception support on the CPU.
throw new InvalidOperationException($"Tried to compare exchange a misaligned address 0x{position:X16}.");
}
public sbyte ReadSByte(long position)
{
return (sbyte)ReadByte(position);
}
public short ReadInt16(long position)
{
return (short)ReadUInt16(position);
}
public int ReadInt32(long position)
{
return (int)ReadUInt32(position);
}
public long ReadInt64(long position)
{
return (long)ReadUInt64(position);
}
public byte ReadByte(long position)
{
return *((byte*)Translate(position));
}
public ushort ReadUInt16(long position)
{
if ((position & 1) == 0)
{
return *((ushort*)Translate(position));
}
else
{
return (ushort)(ReadByte(position + 0) << 0 |
ReadByte(position + 1) << 8);
}
}
public uint ReadUInt32(long position)
{
if ((position & 3) == 0)
{
return *((uint*)Translate(position));
}
else
{
return (uint)(ReadUInt16(position + 0) << 0 |
ReadUInt16(position + 2) << 16);
}
}
public ulong ReadUInt64(long position)
{
if ((position & 7) == 0)
{
return *((ulong*)Translate(position));
}
else
{
return (ulong)ReadUInt32(position + 0) << 0 |
(ulong)ReadUInt32(position + 4) << 32;
}
}
public V128 ReadVector128(long position)
{
return new V128(ReadUInt64(position), ReadUInt64(position + 8));
}
public byte[] ReadBytes(long position, long size)
{
long endAddr = position + size;
if ((ulong)size > int.MaxValue)
{
throw new ArgumentOutOfRangeException(nameof(size));
}
if ((ulong)endAddr < (ulong)position)
{
throw new ArgumentOutOfRangeException(nameof(position));
}
byte[] data = new byte[size];
int offset = 0;
while ((ulong)position < (ulong)endAddr)
{
long pageLimit = (position + PageSize) & ~(long)PageMask;
if ((ulong)pageLimit > (ulong)endAddr)
{
pageLimit = endAddr;
}
int copySize = (int)(pageLimit - position);
Marshal.Copy(Translate(position), data, offset, copySize);
position += copySize;
offset += copySize;
}
return data;
}
public ReadOnlySpan<byte> GetSpan(ulong address, ulong size)
{
if (IsContiguous(address, size))
{
return new ReadOnlySpan<byte>((void*)Translate((long)address), (int)size);
}
else
{
return ReadBytes((long)address, (long)size);
}
}
[MethodImpl(MethodImplOptions.AggressiveInlining)]
private bool IsContiguous(ulong address, ulong size)
{
if (!IsValidPosition((long)address))
{
return false;
}
ulong endVa = (address + size + PageMask) & ~(ulong)PageMask;
address &= ~(ulong)PageMask;
int pages = (int)((endVa - address) / PageSize);
for (int page = 0; page < pages - 1; page++)
{
if (!IsValidPosition((long)address + PageSize))
{
return false;
}
if (GetPtEntry((long)address) + PageSize != GetPtEntry((long)address + PageSize))
{
return false;
}
address += PageSize;
}
return true;
}
public void WriteSByte(long position, sbyte value)
{
WriteByte(position, (byte)value);
}
public void WriteInt16(long position, short value)
{
WriteUInt16(position, (ushort)value);
}
public void WriteInt32(long position, int value)
{
WriteUInt32(position, (uint)value);
}
public void WriteInt64(long position, long value)
{
WriteUInt64(position, (ulong)value);
}
public void WriteByte(long position, byte value)
{
*((byte*)TranslateWrite(position)) = value;
}
public void WriteUInt16(long position, ushort value)
{
if ((position & 1) == 0)
{
*((ushort*)TranslateWrite(position)) = value;
}
else
{
WriteByte(position + 0, (byte)(value >> 0));
WriteByte(position + 1, (byte)(value >> 8));
}
}
public void WriteUInt32(long position, uint value)
{
if ((position & 3) == 0)
{
*((uint*)TranslateWrite(position)) = value;
}
else
{
WriteUInt16(position + 0, (ushort)(value >> 0));
WriteUInt16(position + 2, (ushort)(value >> 16));
}
}
public void WriteUInt64(long position, ulong value)
{
if ((position & 7) == 0)
{
*((ulong*)TranslateWrite(position)) = value;
}
else
{
WriteUInt32(position + 0, (uint)(value >> 0));
WriteUInt32(position + 4, (uint)(value >> 32));
}
}
public void WriteVector128(long position, V128 value)
{
WriteUInt64(position + 0, value.Extract<ulong>(0));
WriteUInt64(position + 8, value.Extract<ulong>(1));
}
public void WriteBytes(long position, byte[] data)
{
long endAddr = position + data.Length;
if ((ulong)endAddr < (ulong)position)
{
throw new ArgumentOutOfRangeException(nameof(position));
}
int offset = 0;
while ((ulong)position < (ulong)endAddr)
{
long pageLimit = (position + PageSize) & ~(long)PageMask;
if ((ulong)pageLimit > (ulong)endAddr)
{
pageLimit = endAddr;
}
int copySize = (int)(pageLimit - position);
Marshal.Copy(data, offset, TranslateWrite(position), copySize);
position += copySize;
offset += copySize;
}
}
public void Dispose()
{
Dispose(true);
}
protected virtual void Dispose(bool disposing)
{
IntPtr ptr = Interlocked.Exchange(ref _pageTable, IntPtr.Zero);
if (ptr != IntPtr.Zero)
{
FreePageTableEntry(ptr, PageBits);
}
}
private void FreePageTableEntry(IntPtr ptr, int levelBitEnd)
{
levelBitEnd += PtLevelBits;
if (levelBitEnd >= AddressSpaceBits)
{
Free(ptr);
return;
}
for (int index = 0; index < PtLevelSize; index++)
{
IntPtr ptePtr = ((IntPtr*)ptr)[index];
if (ptePtr != IntPtr.Zero)
{
FreePageTableEntry(ptePtr, levelBitEnd);
}
}
Free(ptr);
}
}
}
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