1
0
Fork 0
mirror of https://github.com/Ryujinx/Ryujinx.git synced 2024-11-15 14:56:56 +00:00
Ryujinx/Ryujinx.Graphics.Gpu/Image/TexturePool.cs
riperiperi 1fc90e57d2
Update range for remapped sparse textures instead of recreating them (#4442)
* Update sparsely mapped texture ranges without recreating

Important TODO in TexturePool. Smaller TODO: should I look into making textures with views also do this? It needs to be able to detect if the views can be instantly deleted without issue if they're now remapped.

* Actually do partial updates

* Signal group dirty after mappings changed

* Fix various issues (should work now)

* Further optimisation

Should load a lot less data (16x) when partial updating 3d textures.

* Improve stability

* Allow granular uploads on large textures, improve rules

* Actually avoid updating slices that aren't modified.

* Address some feedback, minor optimisation

* Small tweak

* Refactor DereferenceRequest

More specific initialization methods.

* Improve code for resetting handles

* Explain data loading a bit more

* Add some safety for setting null from different threads.

All texture sets come from the one thread, but null sets can come from multiple. Only decrement ref count if we succeeded the null set first.

* Address feedback 1

* Make a bit safer
2023-03-14 17:08:44 -03:00

599 lines
No EOL
23 KiB
C#

using Ryujinx.Common.Logging;
using Ryujinx.Graphics.GAL;
using Ryujinx.Graphics.Gpu.Memory;
using Ryujinx.Graphics.Texture;
using Ryujinx.Memory.Range;
using System;
using System.Collections.Concurrent;
using System.Collections.Generic;
using System.Threading;
namespace Ryujinx.Graphics.Gpu.Image
{
/// <summary>
/// Texture pool.
/// </summary>
class TexturePool : Pool<Texture, TextureDescriptor>, IPool<TexturePool>
{
/// <summary>
/// A request to dereference a texture from a pool.
/// </summary>
private struct DereferenceRequest
{
/// <summary>
/// Whether the dereference is due to a mapping change or not.
/// </summary>
public readonly bool IsRemapped;
/// <summary>
/// The texture being dereferenced.
/// </summary>
public readonly Texture Texture;
/// <summary>
/// The ID of the pool entry this reference belonged to.
/// </summary>
public readonly int ID;
/// <summary>
/// Create a dereference request for a texture with a specific pool ID, and remapped flag.
/// </summary>
/// <param name="isRemapped">Whether the dereference is due to a mapping change or not</param>
/// <param name="texture">The texture being dereferenced</param>
/// <param name="id">The ID of the pool entry, used to restore remapped textures</param>
private DereferenceRequest(bool isRemapped, Texture texture, int id)
{
IsRemapped = isRemapped;
Texture = texture;
ID = id;
}
/// <summary>
/// Create a dereference request for a texture removal.
/// </summary>
/// <param name="texture">The texture being removed</param>
/// <returns>A texture removal dereference request</returns>
public static DereferenceRequest Remove(Texture texture)
{
return new DereferenceRequest(false, texture, 0);
}
/// <summary>
/// Create a dereference request for a texture remapping with a specific pool ID.
/// </summary>
/// <param name="texture">The texture being remapped</param>
/// <param name="id">The ID of the pool entry, used to restore remapped textures</param>
/// <returns>A remap dereference request</returns>
public static DereferenceRequest Remap(Texture texture, int id)
{
return new DereferenceRequest(true, texture, id);
}
}
private readonly GpuChannel _channel;
private readonly ConcurrentQueue<DereferenceRequest> _dereferenceQueue = new ConcurrentQueue<DereferenceRequest>();
private TextureDescriptor _defaultDescriptor;
/// <summary>
/// Linked list node used on the texture pool cache.
/// </summary>
public LinkedListNode<TexturePool> CacheNode { get; set; }
/// <summary>
/// Timestamp used by the texture pool cache, updated on every use of this texture pool.
/// </summary>
public ulong CacheTimestamp { get; set; }
/// <summary>
/// Creates a new instance of the texture pool.
/// </summary>
/// <param name="context">GPU context that the texture pool belongs to</param>
/// <param name="channel">GPU channel that the texture pool belongs to</param>
/// <param name="address">Address of the texture pool in guest memory</param>
/// <param name="maximumId">Maximum texture ID of the texture pool (equal to maximum textures minus one)</param>
public TexturePool(GpuContext context, GpuChannel channel, ulong address, int maximumId) : base(context, channel.MemoryManager.Physical, address, maximumId)
{
_channel = channel;
}
/// <summary>
/// Gets the texture descripor and texture with the given ID with no bounds check or synchronization.
/// </summary>
/// <param name="id">ID of the texture. This is effectively a zero-based index</param>
/// <param name="texture">The texture with the given ID</param>
/// <returns>The texture descriptor with the given ID</returns>
private ref readonly TextureDescriptor GetInternal(int id, out Texture texture)
{
texture = Items[id];
ref readonly TextureDescriptor descriptor = ref GetDescriptorRef(id);
if (texture == null)
{
texture = PhysicalMemory.TextureCache.FindShortCache(descriptor);
if (texture == null)
{
TextureInfo info = GetInfo(descriptor, out int layerSize);
// The dereference queue can put our texture back on the cache.
if ((texture = ProcessDereferenceQueue(id)) != null)
{
return ref descriptor;
}
texture = PhysicalMemory.TextureCache.FindOrCreateTexture(_channel.MemoryManager, TextureSearchFlags.ForSampler, info, layerSize);
// If this happens, then the texture address is invalid, we can't add it to the cache.
if (texture == null)
{
return ref descriptor;
}
}
Items[id] = texture;
texture.IncrementReferenceCount(this, id, descriptor.UnpackAddress());
DescriptorCache[id] = descriptor;
}
else
{
// On the path above (texture not yet in the pool), memory is automatically synchronized on texture creation.
texture.SynchronizeMemory();
}
return ref descriptor;
}
/// <summary>
/// Gets the texture with the given ID.
/// </summary>
/// <param name="id">ID of the texture. This is effectively a zero-based index</param>
/// <returns>The texture with the given ID</returns>
public override Texture Get(int id)
{
if ((uint)id >= Items.Length)
{
return null;
}
if (SequenceNumber != Context.SequenceNumber)
{
SequenceNumber = Context.SequenceNumber;
SynchronizeMemory();
}
GetInternal(id, out Texture texture);
return texture;
}
/// <summary>
/// Gets the texture descriptor and texture with the given ID.
/// </summary>
/// <remarks>
/// This method assumes that the pool has been manually synchronized before doing binding.
/// </remarks>
/// <param name="id">ID of the texture. This is effectively a zero-based index</param>
/// <param name="texture">The texture with the given ID</param>
/// <returns>The texture descriptor with the given ID</returns>
public ref readonly TextureDescriptor GetForBinding(int id, out Texture texture)
{
if ((uint)id >= Items.Length)
{
texture = null;
return ref _defaultDescriptor;
}
// When getting for binding, assume the pool has already been synchronized.
return ref GetInternal(id, out texture);
}
/// <summary>
/// Checks if the pool was modified, and returns the last sequence number where a modification was detected.
/// </summary>
/// <returns>A number that increments each time a modification is detected</returns>
public int CheckModified()
{
if (SequenceNumber != Context.SequenceNumber)
{
SequenceNumber = Context.SequenceNumber;
SynchronizeMemory();
}
return ModifiedSequenceNumber;
}
/// <summary>
/// Forcibly remove a texture from this pool's items.
/// If deferred, the dereference will be queued to occur on the render thread.
/// </summary>
/// <param name="texture">The texture being removed</param>
/// <param name="id">The ID of the texture in this pool</param>
/// <param name="deferred">If true, queue the dereference to happen on the render thread, otherwise dereference immediately</param>
public void ForceRemove(Texture texture, int id, bool deferred)
{
var previous = Interlocked.Exchange(ref Items[id], null);
if (deferred)
{
if (previous != null)
{
_dereferenceQueue.Enqueue(DereferenceRequest.Remove(texture));
}
}
else
{
texture.DecrementReferenceCount();
}
}
/// <summary>
/// Queues a request to update a texture's mapping.
/// Mapping is updated later to avoid deleting the texture if it is still sparsely mapped.
/// </summary>
/// <param name="texture">Texture with potential mapping change</param>
/// <param name="id">ID in cache of texture with potential mapping change</param>
public void QueueUpdateMapping(Texture texture, int id)
{
if (Interlocked.Exchange(ref Items[id], null) == texture)
{
_dereferenceQueue.Enqueue(DereferenceRequest.Remap(texture, id));
}
}
/// <summary>
/// Process the dereference queue, decrementing the reference count for each texture in it.
/// This is used to ensure that texture disposal happens on the render thread.
/// </summary>
/// <param name="id">The ID of the entry that triggered this method</param>
/// <returns>Texture that matches the entry ID if it has been readded to the cache.</returns>
private Texture ProcessDereferenceQueue(int id = -1)
{
while (_dereferenceQueue.TryDequeue(out DereferenceRequest request))
{
Texture texture = request.Texture;
// Unmapped storage textures can swap their ranges. The texture must be storage with no views or dependencies.
// TODO: Would need to update ranges on views, or guarantee that ones where the range changes can be instantly deleted.
if (request.IsRemapped && texture.Group.Storage == texture && !texture.HasViews && !texture.Group.HasCopyDependencies)
{
// Has the mapping for this texture changed?
ref readonly TextureDescriptor descriptor = ref GetDescriptorRef(request.ID);
ulong address = descriptor.UnpackAddress();
MultiRange range = _channel.MemoryManager.GetPhysicalRegions(address, texture.Size);
// If the texture is not mapped at all, delete its reference.
if (range.Count == 1 && range.GetSubRange(0).Address == MemoryManager.PteUnmapped)
{
texture.DecrementReferenceCount();
continue;
}
Items[request.ID] = texture;
// Create a new pool reference, as the last one was removed on unmap.
texture.IncrementReferenceCount(this, request.ID, address);
texture.DecrementReferenceCount();
// Refetch the range. Changes since the last check could have been lost
// as the cache entry was not restored (required to queue mapping change).
range = _channel.MemoryManager.GetPhysicalRegions(address, texture.Size);
if (!range.Equals(texture.Range))
{
// Part of the texture was mapped or unmapped. Replace the range and regenerate tracking handles.
if (!_channel.MemoryManager.Physical.TextureCache.UpdateMapping(texture, range))
{
// Texture could not be remapped due to a collision, just delete it.
if (Interlocked.Exchange(ref Items[request.ID], null) != null)
{
// If this is null, a request was already queued to decrement reference.
texture.DecrementReferenceCount(this, request.ID);
}
continue;
}
}
if (request.ID == id)
{
return texture;
}
}
else
{
texture.DecrementReferenceCount();
}
}
return null;
}
/// <summary>
/// Implementation of the texture pool range invalidation.
/// </summary>
/// <param name="address">Start address of the range of the texture pool</param>
/// <param name="size">Size of the range being invalidated</param>
protected override void InvalidateRangeImpl(ulong address, ulong size)
{
ProcessDereferenceQueue();
ulong endAddress = address + size;
for (; address < endAddress; address += DescriptorSize)
{
int id = (int)((address - Address) / DescriptorSize);
Texture texture = Items[id];
if (texture != null)
{
ref TextureDescriptor cachedDescriptor = ref DescriptorCache[id];
ref readonly TextureDescriptor descriptor = ref GetDescriptorRefAddress(address);
// If the descriptors are the same, the texture is the same,
// we don't need to remove as it was not modified. Just continue.
if (descriptor.Equals(ref cachedDescriptor))
{
continue;
}
if (texture.HasOneReference())
{
_channel.MemoryManager.Physical.TextureCache.AddShortCache(texture, ref cachedDescriptor);
}
if (Interlocked.Exchange(ref Items[id], null) != null)
{
texture.DecrementReferenceCount(this, id);
}
}
}
}
/// <summary>
/// Gets texture information from a texture descriptor.
/// </summary>
/// <param name="descriptor">The texture descriptor</param>
/// <param name="layerSize">Layer size for textures using a sub-range of mipmap levels, otherwise 0</param>
/// <returns>The texture information</returns>
private TextureInfo GetInfo(in TextureDescriptor descriptor, out int layerSize)
{
int depthOrLayers = descriptor.UnpackDepth();
int levels = descriptor.UnpackLevels();
TextureMsaaMode msaaMode = descriptor.UnpackTextureMsaaMode();
int samplesInX = msaaMode.SamplesInX();
int samplesInY = msaaMode.SamplesInY();
int stride = descriptor.UnpackStride();
TextureDescriptorType descriptorType = descriptor.UnpackTextureDescriptorType();
bool isLinear = descriptorType == TextureDescriptorType.Linear;
Target target = descriptor.UnpackTextureTarget().Convert((samplesInX | samplesInY) != 1);
int width = target == Target.TextureBuffer ? descriptor.UnpackBufferTextureWidth() : descriptor.UnpackWidth();
int height = descriptor.UnpackHeight();
if (target == Target.Texture2DMultisample || target == Target.Texture2DMultisampleArray)
{
// This is divided back before the backend texture is created.
width *= samplesInX;
height *= samplesInY;
}
// We use 2D targets for 1D textures as that makes texture cache
// management easier. We don't know the target for render target
// and copies, so those would normally use 2D targets, which are
// not compatible with 1D targets. By doing that we also allow those
// to match when looking for compatible textures on the cache.
if (target == Target.Texture1D)
{
target = Target.Texture2D;
height = 1;
}
else if (target == Target.Texture1DArray)
{
target = Target.Texture2DArray;
height = 1;
}
uint format = descriptor.UnpackFormat();
bool srgb = descriptor.UnpackSrgb();
ulong gpuVa = descriptor.UnpackAddress();
if (!FormatTable.TryGetTextureFormat(format, srgb, out FormatInfo formatInfo))
{
if (gpuVa != 0 && (int)format > 0)
{
Logger.Error?.Print(LogClass.Gpu, $"Invalid texture format 0x{format:X} (sRGB: {srgb}).");
}
formatInfo = FormatInfo.Default;
}
int gobBlocksInY = descriptor.UnpackGobBlocksInY();
int gobBlocksInZ = descriptor.UnpackGobBlocksInZ();
int gobBlocksInTileX = descriptor.UnpackGobBlocksInTileX();
layerSize = 0;
int minLod = descriptor.UnpackBaseLevel();
int maxLod = descriptor.UnpackMaxLevelInclusive();
// Linear textures don't support mipmaps, so we don't handle this case here.
if ((minLod != 0 || maxLod + 1 != levels) && target != Target.TextureBuffer && !isLinear)
{
int depth = TextureInfo.GetDepth(target, depthOrLayers);
int layers = TextureInfo.GetLayers(target, depthOrLayers);
SizeInfo sizeInfo = SizeCalculator.GetBlockLinearTextureSize(
width,
height,
depth,
levels,
layers,
formatInfo.BlockWidth,
formatInfo.BlockHeight,
formatInfo.BytesPerPixel,
gobBlocksInY,
gobBlocksInZ,
gobBlocksInTileX);
layerSize = sizeInfo.LayerSize;
if (minLod != 0 && minLod < levels)
{
// If the base level is not zero, we additionally add the mip level offset
// to the address, this allows the texture manager to find the base level from the
// address if there is a overlapping texture on the cache that can contain the new texture.
gpuVa += (ulong)sizeInfo.GetMipOffset(minLod);
width = Math.Max(1, width >> minLod);
height = Math.Max(1, height >> minLod);
if (target == Target.Texture3D)
{
depthOrLayers = Math.Max(1, depthOrLayers >> minLod);
}
(gobBlocksInY, gobBlocksInZ) = SizeCalculator.GetMipGobBlockSizes(height, depth, formatInfo.BlockHeight, gobBlocksInY, gobBlocksInZ);
}
levels = (maxLod - minLod) + 1;
}
SwizzleComponent swizzleR = descriptor.UnpackSwizzleR().Convert();
SwizzleComponent swizzleG = descriptor.UnpackSwizzleG().Convert();
SwizzleComponent swizzleB = descriptor.UnpackSwizzleB().Convert();
SwizzleComponent swizzleA = descriptor.UnpackSwizzleA().Convert();
DepthStencilMode depthStencilMode = GetDepthStencilMode(
formatInfo.Format,
swizzleR,
swizzleG,
swizzleB,
swizzleA);
if (formatInfo.Format.IsDepthOrStencil())
{
swizzleR = SwizzleComponent.Red;
swizzleG = SwizzleComponent.Red;
swizzleB = SwizzleComponent.Red;
if (depthStencilMode == DepthStencilMode.Depth)
{
swizzleA = SwizzleComponent.One;
}
else
{
swizzleA = SwizzleComponent.Red;
}
}
return new TextureInfo(
gpuVa,
width,
height,
depthOrLayers,
levels,
samplesInX,
samplesInY,
stride,
isLinear,
gobBlocksInY,
gobBlocksInZ,
gobBlocksInTileX,
target,
formatInfo,
depthStencilMode,
swizzleR,
swizzleG,
swizzleB,
swizzleA);
}
/// <summary>
/// Gets the texture depth-stencil mode, based on the swizzle components of each color channel.
/// The depth-stencil mode is determined based on how the driver sets those parameters.
/// </summary>
/// <param name="format">The format of the texture</param>
/// <param name="components">The texture swizzle components</param>
/// <returns>The depth-stencil mode</returns>
private static DepthStencilMode GetDepthStencilMode(Format format, params SwizzleComponent[] components)
{
// R = Depth, G = Stencil.
// On 24-bits depth formats, this is inverted (Stencil is R etc).
// NVN setup:
// For depth, A is set to 1.0f, the other components are set to Depth.
// For stencil, all components are set to Stencil.
SwizzleComponent component = components[0];
for (int index = 1; index < 4 && !IsRG(component); index++)
{
component = components[index];
}
if (!IsRG(component))
{
return DepthStencilMode.Depth;
}
if (format == Format.D24UnormS8Uint)
{
return component == SwizzleComponent.Red
? DepthStencilMode.Stencil
: DepthStencilMode.Depth;
}
else
{
return component == SwizzleComponent.Red
? DepthStencilMode.Depth
: DepthStencilMode.Stencil;
}
}
/// <summary>
/// Checks if the swizzle component is equal to the red or green channels.
/// </summary>
/// <param name="component">The swizzle component to check</param>
/// <returns>True if the swizzle component is equal to the red or green, false otherwise</returns>
private static bool IsRG(SwizzleComponent component)
{
return component == SwizzleComponent.Red ||
component == SwizzleComponent.Green;
}
/// <summary>
/// Decrements the reference count of the texture.
/// This indicates that the texture pool is not using it anymore.
/// </summary>
/// <param name="item">The texture to be deleted</param>
protected override void Delete(Texture item)
{
item?.DecrementReferenceCount(this);
}
public override void Dispose()
{
ProcessDereferenceQueue();
base.Dispose();
}
}
}