ryujinx-mirror/Ryujinx.Memory/Tracking/SmartMultiRegionHandle.cs
riperiperi a1f77a5b6a
Implement lazy flush-on-read for Buffers (SSBO/Copy) (#1790)
* Initial implementation of buffer flush (VERY WIP)

* Host shaders need to be rebuilt for the SSBO write flag.

* New approach with reserved regions and gl sync

* Fix a ton of buffer issues.

* Remove unused buffer unmapped behaviour

* Revert "Remove unused buffer unmapped behaviour"

This reverts commit f1700e52fb8760180ac5e0987a07d409d1e70ece.

* Delete modified ranges on unmap

Fixes potential crashes in Super Smash Bros, where a previously modified range could lie on either side of an unmap.

* Cache some more delegates.

* Dispose Sync on Close

* Also create host sync for GPFifo syncpoint increment.

* Copy buffer optimization, add docs

* Fix race condition with OpenGL Sync

* Enable read tracking on CommandBuffer, insert syncpoint on WaitForIdle

* Performance: Only flush individual pages of SSBO at a time

This avoids flushing large amounts of data when only a small amount is actually used.

* Signal Modified rather than flushing after clear

* Fix some docs and code style.

* Introduce a new test for tracking memory protection.

Sucessfully demonstrates that the bug causing write protection to be cleared by a read action has been fixed. (these tests fail on master)

* Address Comments

* Add host sync for SetReference

This ensures that any indirect draws will correctly flush any related buffer data written before them. Fixes some flashing and misplaced world geometry in MH rise.

* Make PageAlign static

* Re-enable read tracking, for reads.
2021-01-17 17:08:06 -03:00

256 lines
8.6 KiB
C#

using System;
using System.Runtime.CompilerServices;
namespace Ryujinx.Memory.Tracking
{
/// <summary>
/// A MultiRegionHandle that attempts to segment a region's handles into the regions requested
/// to avoid iterating over granular chunks for canonically large regions.
/// If minimum granularity is to be expected, use MultiRegionHandle.
/// </summary>
public class SmartMultiRegionHandle : IMultiRegionHandle
{
/// <summary>
/// A list of region handles starting at each granularity size increment.
/// </summary>
private readonly RegionHandle[] _handles;
private readonly ulong _address;
private readonly ulong _granularity;
private readonly ulong _size;
private MemoryTracking _tracking;
public bool Dirty { get; private set; } = true;
internal SmartMultiRegionHandle(MemoryTracking tracking, ulong address, ulong size, ulong granularity)
{
// For this multi-region handle, the handle list starts empty.
// As regions are queried, they are added to the _handles array at their start index.
// When a region being added overlaps another, the existing region is split.
// A query can therefore scan multiple regions, though with no overlaps they can cover a large area.
_tracking = tracking;
_handles = new RegionHandle[size / granularity];
_granularity = granularity;
_address = address;
_size = size;
}
public void SignalWrite()
{
Dirty = true;
}
public void RegisterAction(RegionSignal action)
{
foreach (var handle in _handles)
{
if (handle != null)
{
handle?.RegisterAction((address, size) => action(handle.Address, handle.Size));
}
}
}
public void QueryModified(Action<ulong, ulong> modifiedAction)
{
if (!Dirty)
{
return;
}
Dirty = false;
QueryModified(_address, _size, modifiedAction);
}
[MethodImpl(MethodImplOptions.AggressiveInlining)]
private ulong HandlesToBytes(int handles)
{
return (ulong)handles * _granularity;
}
private void SplitHandle(int handleIndex, int splitIndex)
{
RegionHandle handle = _handles[handleIndex];
ulong address = _address + HandlesToBytes(handleIndex);
ulong size = HandlesToBytes(splitIndex - handleIndex);
// First, the target handle must be removed. Its data can still be used to determine the new handles.
RegionSignal signal = handle.PreAction;
handle.Dispose();
RegionHandle splitLow = _tracking.BeginTracking(address, size);
splitLow.Parent = this;
if (signal != null)
{
splitLow.RegisterAction(signal);
}
_handles[handleIndex] = splitLow;
RegionHandle splitHigh = _tracking.BeginTracking(address + size, handle.Size - size);
splitHigh.Parent = this;
if (signal != null)
{
splitHigh.RegisterAction(signal);
}
_handles[splitIndex] = splitHigh;
}
private void CreateHandle(int startHandle, int lastHandle)
{
ulong startAddress = _address + HandlesToBytes(startHandle);
// Scan for the first handle before us. If it's overlapping us, it must be split.
for (int i = startHandle - 1; i >= 0; i--)
{
RegionHandle handle = _handles[i];
if (handle != null)
{
if (handle.EndAddress > startAddress)
{
SplitHandle(i, startHandle);
return; // The remainer of this handle should be filled in later on.
}
break;
}
}
// Scan for handles after us. We should create a handle that goes up to this handle's start point, if present.
for (int i = startHandle + 1; i <= lastHandle; i++)
{
RegionHandle handle = _handles[i];
if (handle != null)
{
// Fill up to the found handle.
handle = _tracking.BeginTracking(startAddress, HandlesToBytes(i - startHandle));
handle.Parent = this;
_handles[startHandle] = handle;
return;
}
}
// Can fill the whole range.
_handles[startHandle] = _tracking.BeginTracking(startAddress, HandlesToBytes(1 + lastHandle - startHandle));
_handles[startHandle].Parent = this;
}
public void QueryModified(ulong address, ulong size, Action<ulong, ulong> modifiedAction)
{
int startHandle = (int)((address - _address) / _granularity);
int lastHandle = (int)((address + (size - 1) - _address) / _granularity);
ulong rgStart = _address + (ulong)startHandle * _granularity;
ulong rgSize = 0;
ulong endAddress = _address + ((ulong)lastHandle + 1) * _granularity;
int i = startHandle;
while (i <= lastHandle)
{
RegionHandle handle = _handles[i];
if (handle == null)
{
// Missing handle. A new handle must be created.
CreateHandle(i, lastHandle);
handle = _handles[i];
}
if (handle.EndAddress > endAddress)
{
// End address of handle is beyond the end of the search. Force a split.
SplitHandle(i, lastHandle + 1);
handle = _handles[i];
}
if (handle.Dirty)
{
rgSize += handle.Size;
handle.Reprotect();
}
else
{
// Submit the region scanned so far as dirty
if (rgSize != 0)
{
modifiedAction(rgStart, rgSize);
rgSize = 0;
}
rgStart = handle.EndAddress;
}
i += (int)(handle.Size / _granularity);
}
if (rgSize != 0)
{
modifiedAction(rgStart, rgSize);
}
}
public void QueryModified(ulong address, ulong size, Action<ulong, ulong> modifiedAction, int sequenceNumber)
{
int startHandle = (int)((address - _address) / _granularity);
int lastHandle = (int)((address + (size - 1) - _address) / _granularity);
ulong rgStart = _address + (ulong)startHandle * _granularity;
ulong rgSize = 0;
ulong endAddress = _address + ((ulong)lastHandle + 1) * _granularity;
int i = startHandle;
while (i <= lastHandle)
{
RegionHandle handle = _handles[i];
if (handle == null)
{
// Missing handle. A new handle must be created.
CreateHandle(i, lastHandle);
handle = _handles[i];
}
if (handle.EndAddress > endAddress)
{
// End address of handle is beyond the end of the search. Force a split.
SplitHandle(i, lastHandle + 1);
handle = _handles[i];
}
if (handle.Dirty && sequenceNumber != handle.SequenceNumber)
{
rgSize += handle.Size;
handle.Reprotect();
}
else
{
// Submit the region scanned so far as dirty
if (rgSize != 0)
{
modifiedAction(rgStart, rgSize);
rgSize = 0;
}
rgStart = handle.EndAddress;
}
handle.SequenceNumber = sequenceNumber;
i += (int)(handle.Size / _granularity);
}
if (rgSize != 0)
{
modifiedAction(rgStart, rgSize);
}
}
public void Dispose()
{
foreach (var handle in _handles)
{
handle?.Dispose();
}
}
}
}