using Ryujinx.Common;
using Ryujinx.Common.Logging;
using Ryujinx.Cpu.Tracking;
using Ryujinx.Graphics.GAL;
using Ryujinx.Graphics.Texture;
using Ryujinx.Graphics.Texture.Astc;
using Ryujinx.Memory.Range;
using System;
using System.Collections.Generic;
using System.Diagnostics;
namespace Ryujinx.Graphics.Gpu.Image
{
///
/// Represents a cached GPU texture.
///
class Texture : IRange, IDisposable
{
// How many updates we need before switching to the byte-by-byte comparison
// modification check method.
// This method uses much more memory so we want to avoid it if possible.
private const int ByteComparisonSwitchThreshold = 4;
private GpuContext _context;
private SizeInfo _sizeInfo;
///
/// Texture format.
///
public Format Format => Info.FormatInfo.Format;
///
/// Texture information.
///
public TextureInfo Info { get; private set; }
///
/// Host scale factor.
///
public float ScaleFactor { get; private set; }
///
/// Upscaling mode. Informs if a texture is scaled, or is eligible for scaling.
///
public TextureScaleMode ScaleMode { get; private set; }
///
/// Set when a texture has been modified by the Host GPU since it was last flushed.
///
public bool IsModified { get; internal set; }
///
/// Set when a texture has been changed size. This indicates that it may need to be
/// changed again when obtained as a sampler.
///
public bool ChangedSize { get; internal set; }
private int _depth;
private int _layers;
private int _firstLayer;
private int _firstLevel;
private bool _hasData;
private int _updateCount;
private byte[] _currentData;
private ITexture _arrayViewTexture;
private Target _arrayViewTarget;
private ITexture _flushHostTexture;
private Texture _viewStorage;
private List _views;
///
/// Host texture.
///
public ITexture HostTexture { get; private set; }
///
/// Intrusive linked list node used on the auto deletion texture cache.
///
public LinkedListNode CacheNode { get; set; }
///
/// Event to fire when texture data is disposed.
///
public event Action Disposed;
///
/// Start address of the texture in guest memory.
///
public ulong Address => Info.Address;
///
/// End address of the texture in guest memory.
///
public ulong EndAddress => Info.Address + Size;
///
/// Texture size in bytes.
///
public ulong Size => (ulong)_sizeInfo.TotalSize;
private CpuRegionHandle _memoryTracking;
private int _referenceCount;
///
/// Constructs a new instance of the cached GPU texture.
///
/// GPU context that the texture belongs to
/// Texture information
/// Size information of the texture
/// The first layer of the texture, or 0 if the texture has no parent
/// The first mipmap level of the texture, or 0 if the texture has no parent
/// The floating point scale factor to initialize with
/// The scale mode to initialize with
private Texture(
GpuContext context,
TextureInfo info,
SizeInfo sizeInfo,
int firstLayer,
int firstLevel,
float scaleFactor,
TextureScaleMode scaleMode)
{
InitializeTexture(context, info, sizeInfo);
_firstLayer = firstLayer;
_firstLevel = firstLevel;
ScaleFactor = scaleFactor;
ScaleMode = scaleMode;
InitializeData(true);
}
///
/// Constructs a new instance of the cached GPU texture.
///
/// GPU context that the texture belongs to
/// Texture information
/// Size information of the texture
/// The scale mode to initialize with. If scaled, the texture's data is loaded immediately and scaled up
public Texture(GpuContext context, TextureInfo info, SizeInfo sizeInfo, TextureScaleMode scaleMode)
{
ScaleFactor = 1f; // Texture is first loaded at scale 1x.
ScaleMode = scaleMode;
InitializeTexture(context, info, sizeInfo);
}
///
/// Common texture initialization method.
/// This sets the context, info and sizeInfo fields.
/// Other fields are initialized with their default values.
///
/// GPU context that the texture belongs to
/// Texture information
/// Size information of the texture
private void InitializeTexture(GpuContext context, TextureInfo info, SizeInfo sizeInfo)
{
_context = context;
_sizeInfo = sizeInfo;
SetInfo(info);
_viewStorage = this;
_views = new List();
}
///
/// Initializes the data for a texture. Can optionally initialize the texture with or without data.
/// If the texture is a view, it will initialize memory tracking to be non-dirty.
///
/// True if the texture is a view, false otherwise
/// True if the texture is to be initialized with data
public void InitializeData(bool isView, bool withData = false)
{
_memoryTracking = _context.PhysicalMemory.BeginTracking(Address, Size);
if (withData)
{
Debug.Assert(!isView);
TextureCreateInfo createInfo = TextureManager.GetCreateInfo(Info, _context.Capabilities, ScaleFactor);
HostTexture = _context.Renderer.CreateTexture(createInfo, ScaleFactor);
SynchronizeMemory(); // Load the data.
if (ScaleMode == TextureScaleMode.Scaled)
{
SetScale(GraphicsConfig.ResScale); // Scale the data up.
}
}
else
{
// Don't update this texture the next time we synchronize.
ConsumeModified();
_hasData = true;
if (!isView)
{
if (ScaleMode == TextureScaleMode.Scaled)
{
// Don't need to start at 1x as there is no data to scale, just go straight to the target scale.
ScaleFactor = GraphicsConfig.ResScale;
}
TextureCreateInfo createInfo = TextureManager.GetCreateInfo(Info, _context.Capabilities, ScaleFactor);
HostTexture = _context.Renderer.CreateTexture(createInfo, ScaleFactor);
}
}
}
///
/// Create a texture view from this texture.
/// A texture view is defined as a child texture, from a sub-range of their parent texture.
/// For example, the initial layer and mipmap level of the view can be defined, so the texture
/// will start at the given layer/level of the parent texture.
///
/// Child texture information
/// Child texture size information
/// Start layer of the child texture on the parent texture
/// Start mipmap level of the child texture on the parent texture
/// The child texture
public Texture CreateView(TextureInfo info, SizeInfo sizeInfo, int firstLayer, int firstLevel)
{
Texture texture = new Texture(
_context,
info,
sizeInfo,
_firstLayer + firstLayer,
_firstLevel + firstLevel,
ScaleFactor,
ScaleMode);
TextureCreateInfo createInfo = TextureManager.GetCreateInfo(info, _context.Capabilities, ScaleFactor);
texture.HostTexture = HostTexture.CreateView(createInfo, firstLayer, firstLevel);
_viewStorage.AddView(texture);
return texture;
}
///
/// Adds a child texture to this texture.
///
/// The child texture
private void AddView(Texture texture)
{
DisableMemoryTracking();
_views.Add(texture);
texture._viewStorage = this;
}
///
/// Removes a child texture from this texture.
///
/// The child texture
private void RemoveView(Texture texture)
{
_views.Remove(texture);
texture._viewStorage = texture;
DeleteIfNotUsed();
}
///
/// Changes the texture size.
///
///
/// This operation may also change the size of all mipmap levels, including from the parent
/// and other possible child textures, to ensure that all sizes are consistent.
///
/// The new texture width
/// The new texture height
/// The new texture depth (for 3D textures) or layers (for layered textures)
public void ChangeSize(int width, int height, int depthOrLayers)
{
int blockWidth = Info.FormatInfo.BlockWidth;
int blockHeight = Info.FormatInfo.BlockHeight;
width <<= _firstLevel;
height <<= _firstLevel;
if (Info.Target == Target.Texture3D)
{
depthOrLayers <<= _firstLevel;
}
else
{
depthOrLayers = _viewStorage.Info.DepthOrLayers;
}
_viewStorage.RecreateStorageOrView(width, height, blockWidth, blockHeight, depthOrLayers);
foreach (Texture view in _viewStorage._views)
{
int viewWidth = Math.Max(1, width >> view._firstLevel);
int viewHeight = Math.Max(1, height >> view._firstLevel);
int viewDepthOrLayers;
if (view.Info.Target == Target.Texture3D)
{
viewDepthOrLayers = Math.Max(1, depthOrLayers >> view._firstLevel);
}
else
{
viewDepthOrLayers = view.Info.DepthOrLayers;
}
view.RecreateStorageOrView(viewWidth, viewHeight, blockWidth, blockHeight, viewDepthOrLayers);
}
}
///
/// Disables memory tracking on this texture. Currently used for view containers, as we assume their views are covering all memory regions.
/// Textures with disabled memory tracking also cannot flush in most circumstances.
///
public void DisableMemoryTracking()
{
_memoryTracking?.Dispose();
_memoryTracking = null;
}
///
/// Recreates the texture storage (or view, in the case of child textures) of this texture.
/// This allows recreating the texture with a new size.
/// A copy is automatically performed from the old to the new texture.
///
/// The new texture width
/// The new texture height
/// The block width related to the given width
/// The block height related to the given height
/// The new texture depth (for 3D textures) or layers (for layered textures)
private void RecreateStorageOrView(int width, int height, int blockWidth, int blockHeight, int depthOrLayers)
{
RecreateStorageOrView(
BitUtils.DivRoundUp(width * Info.FormatInfo.BlockWidth, blockWidth),
BitUtils.DivRoundUp(height * Info.FormatInfo.BlockHeight, blockHeight),
depthOrLayers);
}
///
/// Recreates the texture storage (or view, in the case of child textures) of this texture.
/// This allows recreating the texture with a new size.
/// A copy is automatically performed from the old to the new texture.
///
/// The new texture width
/// The new texture height
/// The new texture depth (for 3D textures) or layers (for layered textures)
private void RecreateStorageOrView(int width, int height, int depthOrLayers)
{
ChangedSize = true;
SetInfo(new TextureInfo(
Info.Address,
width,
height,
depthOrLayers,
Info.Levels,
Info.SamplesInX,
Info.SamplesInY,
Info.Stride,
Info.IsLinear,
Info.GobBlocksInY,
Info.GobBlocksInZ,
Info.GobBlocksInTileX,
Info.Target,
Info.FormatInfo,
Info.DepthStencilMode,
Info.SwizzleR,
Info.SwizzleG,
Info.SwizzleB,
Info.SwizzleA));
TextureCreateInfo createInfo = TextureManager.GetCreateInfo(Info, _context.Capabilities, ScaleFactor);
if (_viewStorage != this)
{
ReplaceStorage(_viewStorage.HostTexture.CreateView(createInfo, _firstLayer, _firstLevel));
}
else
{
ITexture newStorage = _context.Renderer.CreateTexture(createInfo, ScaleFactor);
HostTexture.CopyTo(newStorage, 0, 0);
ReplaceStorage(newStorage);
}
}
///
/// Blacklists this texture from being scaled. Resets its scale to 1 if needed.
///
public void BlacklistScale()
{
ScaleMode = TextureScaleMode.Blacklisted;
SetScale(1f);
}
///
/// Propagates the scale between this texture and another to ensure they have the same scale.
/// If one texture is blacklisted from scaling, the other will become blacklisted too.
///
/// The other texture
public void PropagateScale(Texture other)
{
if (other.ScaleMode == TextureScaleMode.Blacklisted || ScaleMode == TextureScaleMode.Blacklisted)
{
BlacklistScale();
other.BlacklistScale();
}
else
{
// Prefer the configured scale if present. If not, prefer the max.
float targetScale = GraphicsConfig.ResScale;
float sharedScale = (ScaleFactor == targetScale || other.ScaleFactor == targetScale) ? targetScale : Math.Max(ScaleFactor, other.ScaleFactor);
SetScale(sharedScale);
other.SetScale(sharedScale);
}
}
///
/// Helper method for copying our Texture2DArray texture to the given target, with scaling.
/// This creates temporary views for each array layer on both textures, copying each one at a time.
///
/// The texture array to copy to
private void CopyArrayScaled(ITexture target)
{
TextureInfo viewInfo = new TextureInfo(
Info.Address,
Info.Width,
Info.Height,
1,
Info.Levels,
Info.SamplesInX,
Info.SamplesInY,
Info.Stride,
Info.IsLinear,
Info.GobBlocksInY,
Info.GobBlocksInZ,
Info.GobBlocksInTileX,
Target.Texture2D,
Info.FormatInfo,
Info.DepthStencilMode,
Info.SwizzleR,
Info.SwizzleG,
Info.SwizzleB,
Info.SwizzleA);
TextureCreateInfo createInfo = TextureManager.GetCreateInfo(viewInfo, _context.Capabilities, ScaleFactor);
for (int i = 0; i < Info.DepthOrLayers; i++)
{
ITexture from = HostTexture.CreateView(createInfo, i, 0);
ITexture to = target.CreateView(createInfo, i, 0);
from.CopyTo(to, new Extents2D(0, 0, from.Width, from.Height), new Extents2D(0, 0, to.Width, to.Height), true);
from.Release();
to.Release();
}
}
///
/// Copy the host texture to a scaled one. If a texture is not provided, create it with the given scale.
///
/// Scale factor
/// Texture to use instead of creating one
/// A host texture containing a scaled version of this texture
private ITexture GetScaledHostTexture(float scale, ITexture storage = null)
{
if (storage == null)
{
TextureCreateInfo createInfo = TextureManager.GetCreateInfo(Info, _context.Capabilities, scale);
storage = _context.Renderer.CreateTexture(createInfo, scale);
}
if (Info.Target == Target.Texture2DArray)
{
CopyArrayScaled(storage);
}
else
{
HostTexture.CopyTo(storage, new Extents2D(0, 0, HostTexture.Width, HostTexture.Height), new Extents2D(0, 0, storage.Width, storage.Height), true);
}
return storage;
}
///
/// Sets the Scale Factor on this texture, and immediately recreates it at the correct size.
/// When a texture is resized, a scaled copy is performed from the old texture to the new one, to ensure no data is lost.
/// If scale is equivalent, this only propagates the blacklisted/scaled mode.
/// If called on a view, its storage is resized instead.
/// When resizing storage, all texture views are recreated.
///
/// The new scale factor for this texture
public void SetScale(float scale)
{
TextureScaleMode newScaleMode = ScaleMode == TextureScaleMode.Blacklisted ? ScaleMode : TextureScaleMode.Scaled;
if (_viewStorage != this)
{
_viewStorage.ScaleMode = newScaleMode;
_viewStorage.SetScale(scale);
return;
}
if (ScaleFactor != scale)
{
Logger.Debug?.Print(LogClass.Gpu, $"Rescaling {Info.Width}x{Info.Height} {Info.FormatInfo.Format.ToString()} to ({ScaleFactor} to {scale}). ");
ScaleFactor = scale;
ITexture newStorage = GetScaledHostTexture(ScaleFactor);
Logger.Debug?.Print(LogClass.Gpu, $" Copy performed: {HostTexture.Width}x{HostTexture.Height} to {newStorage.Width}x{newStorage.Height}");
ReplaceStorage(newStorage);
// All views must be recreated against the new storage.
foreach (var view in _views)
{
Logger.Debug?.Print(LogClass.Gpu, $" Recreating view {Info.Width}x{Info.Height} {Info.FormatInfo.Format.ToString()}.");
view.ScaleFactor = scale;
TextureCreateInfo viewCreateInfo = TextureManager.GetCreateInfo(view.Info, _context.Capabilities, scale);
ITexture newView = HostTexture.CreateView(viewCreateInfo, view._firstLayer - _firstLayer, view._firstLevel - _firstLevel);
view.ReplaceStorage(newView);
view.ScaleMode = newScaleMode;
}
}
if (ScaleMode != newScaleMode)
{
ScaleMode = newScaleMode;
foreach (var view in _views)
{
view.ScaleMode = newScaleMode;
}
}
}
///
/// Checks if the memory for this texture was modified, and returns true if it was.
/// The modified flags are consumed as a result.
///
///
/// If there is no memory tracking for this texture, it will always report as modified.
///
/// True if the texture was modified, false otherwise.
public bool ConsumeModified()
{
bool wasDirty = _memoryTracking?.Dirty ?? true;
_memoryTracking?.Reprotect();
return wasDirty;
}
///
/// Synchronizes guest and host memory.
/// This will overwrite the texture data with the texture data on the guest memory, if a CPU
/// modification is detected.
/// Be aware that this can cause texture data written by the GPU to be lost, this is just a
/// one way copy (from CPU owned to GPU owned memory).
///
public void SynchronizeMemory()
{
if (Info.Target == Target.TextureBuffer)
{
return;
}
if (_hasData)
{
if (_memoryTracking?.Dirty != true)
{
return;
}
BlacklistScale();
}
_memoryTracking?.Reprotect();
ReadOnlySpan data = _context.PhysicalMemory.GetSpan(Address, (int)Size);
IsModified = false;
// If the host does not support ASTC compression, we need to do the decompression.
// The decompression is slow, so we want to avoid it as much as possible.
// This does a byte-by-byte check and skips the update if the data is equal in this case.
// This improves the speed on applications that overwrites ASTC data without changing anything.
if (Info.FormatInfo.Format.IsAstc() && !_context.Capabilities.SupportsAstcCompression)
{
if (_updateCount < ByteComparisonSwitchThreshold)
{
_updateCount++;
}
else
{
bool dataMatches = _currentData != null && data.SequenceEqual(_currentData);
_currentData = data.ToArray();
if (dataMatches)
{
return;
}
}
}
data = ConvertToHostCompatibleFormat(data);
HostTexture.SetData(data);
_hasData = true;
}
public void SetData(ReadOnlySpan data)
{
BlacklistScale();
_memoryTracking?.Reprotect();
IsModified = false;
HostTexture.SetData(data);
_hasData = true;
}
///
/// Converts texture data to a format and layout that is supported by the host GPU.
///
/// Data to be converted
/// Converted data
private ReadOnlySpan ConvertToHostCompatibleFormat(ReadOnlySpan data)
{
if (Info.IsLinear)
{
data = LayoutConverter.ConvertLinearStridedToLinear(
Info.Width,
Info.Height,
Info.FormatInfo.BlockWidth,
Info.FormatInfo.BlockHeight,
Info.Stride,
Info.FormatInfo.BytesPerPixel,
data);
}
else
{
data = LayoutConverter.ConvertBlockLinearToLinear(
Info.Width,
Info.Height,
_depth,
Info.Levels,
_layers,
Info.FormatInfo.BlockWidth,
Info.FormatInfo.BlockHeight,
Info.FormatInfo.BytesPerPixel,
Info.GobBlocksInY,
Info.GobBlocksInZ,
Info.GobBlocksInTileX,
_sizeInfo,
data);
}
// Handle compressed cases not supported by the host:
// - ASTC is usually not supported on desktop cards.
// - BC4/BC5 is not supported on 3D textures.
if (!_context.Capabilities.SupportsAstcCompression && Info.FormatInfo.Format.IsAstc())
{
if (!AstcDecoder.TryDecodeToRgba8(
data.ToArray(),
Info.FormatInfo.BlockWidth,
Info.FormatInfo.BlockHeight,
Info.Width,
Info.Height,
_depth,
Info.Levels,
_layers,
out Span decoded))
{
string texInfo = $"{Info.Target} {Info.FormatInfo.Format} {Info.Width}x{Info.Height}x{Info.DepthOrLayers} levels {Info.Levels}";
Logger.Debug?.Print(LogClass.Gpu, $"Invalid ASTC texture at 0x{Info.Address:X} ({texInfo}).");
}
data = decoded;
}
else if (Info.Target == Target.Texture3D && Info.FormatInfo.Format.IsBc4())
{
data = BCnDecoder.DecodeBC4(data, Info.Width, Info.Height, _depth, Info.Levels, _layers, Info.FormatInfo.Format == Format.Bc4Snorm);
}
else if (Info.Target == Target.Texture3D && Info.FormatInfo.Format.IsBc5())
{
data = BCnDecoder.DecodeBC5(data, Info.Width, Info.Height, _depth, Info.Levels, _layers, Info.FormatInfo.Format == Format.Bc5Snorm);
}
return data;
}
///
/// Flushes the texture data.
/// This causes the texture data to be written back to guest memory.
/// If the texture was written by the GPU, this includes all modification made by the GPU
/// up to this point.
/// Be aware that this is an expensive operation, avoid calling it unless strictly needed.
/// This may cause data corruption if the memory is already being used for something else on the CPU side.
///
/// Whether or not the flush triggers write tracking. If it doesn't, the texture will not be blacklisted for scaling either.
public void Flush(bool tracked = true)
{
IsModified = false;
if (TextureCompatibility.IsFormatHostIncompatible(Info, _context.Capabilities))
{
return; // Flushing this format is not supported, as it may have been converted to another host format.
}
if (tracked)
{
_context.PhysicalMemory.Write(Address, GetTextureDataFromGpu(tracked));
}
else
{
_context.PhysicalMemory.WriteUntracked(Address, GetTextureDataFromGpu(tracked));
}
}
///
/// Flushes the texture data, to be called from an external thread.
/// The host backend must ensure that we have shared access to the resource from this thread.
/// This is used when flushing from memory access handlers.
///
public void ExternalFlush(ulong address, ulong size)
{
if (!IsModified || _memoryTracking == null)
{
return;
}
_context.Renderer.BackgroundContextAction(() =>
{
IsModified = false;
if (TextureCompatibility.IsFormatHostIncompatible(Info, _context.Capabilities))
{
return; // Flushing this format is not supported, as it may have been converted to another host format.
}
ITexture texture = HostTexture;
if (ScaleFactor != 1f)
{
// If needed, create a texture to flush back to host at 1x scale.
texture = _flushHostTexture = GetScaledHostTexture(1f, _flushHostTexture);
}
_context.PhysicalMemory.WriteUntracked(Address, GetTextureDataFromGpu(false, texture));
});
}
///
/// Gets data from the host GPU.
///
///
/// This method should be used to retrieve data that was modified by the host GPU.
/// This is not cheap, avoid doing that unless strictly needed.
///
/// Host texture data
private Span GetTextureDataFromGpu(bool blacklist, ITexture texture = null)
{
Span data;
if (texture != null)
{
data = texture.GetData();
}
else
{
if (blacklist)
{
BlacklistScale();
data = HostTexture.GetData();
}
else if (ScaleFactor != 1f)
{
float scale = ScaleFactor;
SetScale(1f);
data = HostTexture.GetData();
SetScale(scale);
}
else
{
data = HostTexture.GetData();
}
}
if (Info.IsLinear)
{
data = LayoutConverter.ConvertLinearToLinearStrided(
Info.Width,
Info.Height,
Info.FormatInfo.BlockWidth,
Info.FormatInfo.BlockHeight,
Info.Stride,
Info.FormatInfo.BytesPerPixel,
data);
}
else
{
data = LayoutConverter.ConvertLinearToBlockLinear(
Info.Width,
Info.Height,
_depth,
Info.Levels,
_layers,
Info.FormatInfo.BlockWidth,
Info.FormatInfo.BlockHeight,
Info.FormatInfo.BytesPerPixel,
Info.GobBlocksInY,
Info.GobBlocksInZ,
Info.GobBlocksInTileX,
_sizeInfo,
data);
}
return data;
}
///
/// This performs a strict comparison, used to check if this texture is equal to the one supplied.
///
/// Texture information to compare against
/// Comparison flags
/// True if the textures are strictly equal or similar, false otherwise
public bool IsPerfectMatch(TextureInfo info, TextureSearchFlags flags)
{
if (!TextureCompatibility.FormatMatches(Info, info, (flags & TextureSearchFlags.ForSampler) != 0, (flags & TextureSearchFlags.ForCopy) != 0))
{
return false;
}
if (!TextureCompatibility.LayoutMatches(Info, info))
{
return false;
}
if (!TextureCompatibility.SizeMatches(Info, info, (flags & TextureSearchFlags.Strict) == 0))
{
return false;
}
if ((flags & TextureSearchFlags.ForSampler) != 0 || (flags & TextureSearchFlags.Strict) != 0)
{
if (!TextureCompatibility.SamplerParamsMatches(Info, info))
{
return false;
}
}
if ((flags & TextureSearchFlags.ForCopy) != 0)
{
bool msTargetCompatible = Info.Target == Target.Texture2DMultisample && info.Target == Target.Texture2D;
if (!msTargetCompatible && !TextureCompatibility.TargetAndSamplesCompatible(Info, info))
{
return false;
}
}
else if (!TextureCompatibility.TargetAndSamplesCompatible(Info, info))
{
return false;
}
return Info.Address == info.Address && Info.Levels == info.Levels;
}
///
/// Check if it's possible to create a view, with the given parameters, from this texture.
///
/// Texture view information
/// Texture view size
/// Texture view initial layer on this texture
/// Texture view first mipmap level on this texture
/// The level of compatiblilty a view with the given parameters created from this texture has
public TextureViewCompatibility IsViewCompatible(
TextureInfo info,
ulong size,
out int firstLayer,
out int firstLevel)
{
// Out of range.
if (info.Address < Address || info.Address + size > EndAddress)
{
firstLayer = 0;
firstLevel = 0;
return TextureViewCompatibility.Incompatible;
}
int offset = (int)(info.Address - Address);
if (!_sizeInfo.FindView(offset, (int)size, out firstLayer, out firstLevel))
{
return TextureViewCompatibility.Incompatible;
}
if (!TextureCompatibility.ViewLayoutCompatible(Info, info, firstLevel))
{
return TextureViewCompatibility.Incompatible;
}
if (!TextureCompatibility.ViewFormatCompatible(Info, info))
{
return TextureViewCompatibility.Incompatible;
}
TextureViewCompatibility result = TextureViewCompatibility.Full;
result = TextureCompatibility.PropagateViewCompatibility(result, TextureCompatibility.ViewSizeMatches(Info, info, firstLevel));
result = TextureCompatibility.PropagateViewCompatibility(result, TextureCompatibility.ViewTargetCompatible(Info, info));
return (Info.SamplesInX == info.SamplesInX &&
Info.SamplesInY == info.SamplesInY) ? result : TextureViewCompatibility.Incompatible;
}
///
/// Gets a texture of the specified target type from this texture.
/// This can be used to get an array texture from a non-array texture and vice-versa.
/// If this texture and the requested targets are equal, then this texture Host texture is returned directly.
///
/// The desired target type
/// A view of this texture with the requested target, or null if the target is invalid for this texture
public ITexture GetTargetTexture(Target target)
{
if (target == Info.Target)
{
return HostTexture;
}
if (_arrayViewTexture == null && IsSameDimensionsTarget(target))
{
TextureCreateInfo createInfo = new TextureCreateInfo(
Info.Width,
Info.Height,
target == Target.CubemapArray ? 6 : 1,
Info.Levels,
Info.Samples,
Info.FormatInfo.BlockWidth,
Info.FormatInfo.BlockHeight,
Info.FormatInfo.BytesPerPixel,
Info.FormatInfo.Format,
Info.DepthStencilMode,
target,
Info.SwizzleR,
Info.SwizzleG,
Info.SwizzleB,
Info.SwizzleA);
ITexture viewTexture = HostTexture.CreateView(createInfo, 0, 0);
_arrayViewTexture = viewTexture;
_arrayViewTarget = target;
return viewTexture;
}
else if (_arrayViewTarget == target)
{
return _arrayViewTexture;
}
return null;
}
///
/// Check if this texture and the specified target have the same number of dimensions.
/// For the purposes of this comparison, 2D and 2D Multisample textures are not considered to have
/// the same number of dimensions. Same for Cubemap and 3D textures.
///
/// The target to compare with
/// True if both targets have the same number of dimensions, false otherwise
private bool IsSameDimensionsTarget(Target target)
{
switch (Info.Target)
{
case Target.Texture1D:
case Target.Texture1DArray:
return target == Target.Texture1D ||
target == Target.Texture1DArray;
case Target.Texture2D:
case Target.Texture2DArray:
return target == Target.Texture2D ||
target == Target.Texture2DArray;
case Target.Cubemap:
case Target.CubemapArray:
return target == Target.Cubemap ||
target == Target.CubemapArray;
case Target.Texture2DMultisample:
case Target.Texture2DMultisampleArray:
return target == Target.Texture2DMultisample ||
target == Target.Texture2DMultisampleArray;
case Target.Texture3D:
return target == Target.Texture3D;
}
return false;
}
///
/// Replaces view texture information.
/// This should only be used for child textures with a parent.
///
/// The parent texture
/// The new view texture information
/// The new host texture
/// The first layer of the view
/// The first level of the view
public void ReplaceView(Texture parent, TextureInfo info, ITexture hostTexture, int firstLayer, int firstLevel)
{
parent._viewStorage.SynchronizeMemory();
ReplaceStorage(hostTexture);
_firstLayer = parent._firstLayer + firstLayer;
_firstLevel = parent._firstLevel + firstLevel;
parent._viewStorage.AddView(this);
SetInfo(info);
}
///
/// Sets the internal texture information structure.
///
/// The new texture information
private void SetInfo(TextureInfo info)
{
Info = info;
_depth = info.GetDepth();
_layers = info.GetLayers();
}
///
/// Signals that the texture has been modified.
///
public void SignalModified()
{
IsModified = true;
if (_viewStorage != this)
{
_viewStorage.SignalModified();
}
_memoryTracking?.RegisterAction(ExternalFlush);
}
///
/// Replaces the host texture, while disposing of the old one if needed.
///
/// The new host texture
private void ReplaceStorage(ITexture hostTexture)
{
DisposeTextures();
HostTexture = hostTexture;
}
///
/// Checks if the texture overlaps with a memory range.
///
/// Start address of the range
/// Size of the range
/// True if the texture overlaps with the range, false otherwise
public bool OverlapsWith(ulong address, ulong size)
{
return Address < address + size && address < EndAddress;
}
///
/// Determine if any of our child textures are compaible as views of the given texture.
///
/// The texture to check against
/// True if any child is view compatible, false otherwise
public bool HasViewCompatibleChild(Texture texture)
{
if (_viewStorage != this || _views.Count == 0)
{
return false;
}
foreach (Texture view in _views)
{
if (texture.IsViewCompatible(view.Info, view.Size, out int _, out int _) != TextureViewCompatibility.Incompatible)
{
return true;
}
}
return false;
}
///
/// Increments the texture reference count.
///
public void IncrementReferenceCount()
{
_referenceCount++;
}
///
/// Decrements the texture reference count.
/// When the reference count hits zero, the texture may be deleted and can't be used anymore.
///
/// True if the texture is now referenceless, false otherwise
public bool DecrementReferenceCount()
{
int newRefCount = --_referenceCount;
if (newRefCount == 0)
{
if (_viewStorage != this)
{
_viewStorage.RemoveView(this);
}
_context.Methods.TextureManager.RemoveTextureFromCache(this);
}
Debug.Assert(newRefCount >= 0);
DeleteIfNotUsed();
return newRefCount <= 0;
}
///
/// Delete the texture if it is not used anymore.
/// The texture is considered unused when the reference count is zero,
/// and it has no child views.
///
private void DeleteIfNotUsed()
{
// We can delete the texture as long it is not being used
// in any cache (the reference count is 0 in this case), and
// also all views that may be created from this texture were
// already deleted (views count is 0).
if (_referenceCount == 0 && _views.Count == 0)
{
Dispose();
}
}
///
/// Performs texture disposal, deleting the texture.
///
private void DisposeTextures()
{
_currentData = null;
HostTexture.Release();
_arrayViewTexture?.Release();
_arrayViewTexture = null;
_flushHostTexture?.Release();
_flushHostTexture = null;
}
///
/// Called when the memory for this texture has been unmapped.
/// Calls are from non-gpu threads.
///
public void Unmapped()
{
IsModified = false; // We shouldn't flush this texture, as its memory is no longer mapped.
CpuRegionHandle tracking = _memoryTracking;
tracking?.Reprotect();
tracking?.RegisterAction(null);
}
///
/// Performs texture disposal, deleting the texture.
///
public void Dispose()
{
DisposeTextures();
Disposed?.Invoke(this);
_memoryTracking?.Dispose();
}
}
}