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Ryujinx/Ryujinx.Graphics.Vulkan/ShaderCollection.cs
gdkchan f82309fa2d
Vulkan: Implement multisample <-> non-multisample copies and depth-stencil resolve (#3723)
* Vulkan: Implement multisample <-> non-multisample copies and depth-stencil resolve

* FramebufferParams is no longer required there

* Implement Specialization Constants and merge CopyMS Shaders (#15)

* Vulkan: Initial Specialization Constants

* Replace with specialized helper shader

* Reimplement everything

Fix nonexistant interaction with Ryu pipeline caching
Decouple specialization info from data and relocate them
Generalize mapping and add type enum to better match spv types
Use local fixed scopes instead of global unmanaged allocs

* Fix misses in initial implementation

Use correct info variable in Create2DLayerView
Add ShaderStorageImageMultisample to required feature set

* Use texture for source image

* No point in using ReadOnlyMemory

* Apply formatting feedback

Co-authored-by: gdkchan <gab.dark.100@gmail.com>

* Apply formatting suggestions on shader source

Co-authored-by: gdkchan <gab.dark.100@gmail.com>

Co-authored-by: gdkchan <gab.dark.100@gmail.com>

* Support conversion with samples count that does not match the requested count, other minor changes

Co-authored-by: mageven <62494521+mageven@users.noreply.github.com>
2022-11-02 18:17:19 -03:00

427 lines
13 KiB
C#

using Ryujinx.Common.Logging;
using Ryujinx.Graphics.GAL;
using Silk.NET.Vulkan;
using System;
using System.Collections.Generic;
using System.Linq;
using System.Threading.Tasks;
namespace Ryujinx.Graphics.Vulkan
{
class ShaderCollection : IProgram
{
private readonly PipelineShaderStageCreateInfo[] _infos;
private readonly Shader[] _shaders;
private readonly PipelineLayoutCacheEntry _plce;
public PipelineLayout PipelineLayout => _plce.PipelineLayout;
public bool HasMinimalLayout { get; }
public bool UsePushDescriptors { get; }
public uint Stages { get; }
public int[][][] Bindings { get; }
public ProgramLinkStatus LinkStatus { get; private set; }
public readonly SpecDescription[] SpecDescriptions;
public bool IsLinked
{
get
{
if (LinkStatus == ProgramLinkStatus.Incomplete)
{
CheckProgramLink(true);
}
return LinkStatus == ProgramLinkStatus.Success;
}
}
private HashTableSlim<PipelineUid, Auto<DisposablePipeline>> _graphicsPipelineCache;
private HashTableSlim<SpecData, Auto<DisposablePipeline>> _computePipelineCache;
private VulkanRenderer _gd;
private Device _device;
private bool _initialized;
private bool _isCompute;
private ProgramPipelineState _state;
private DisposableRenderPass _dummyRenderPass;
private Task _compileTask;
private bool _firstBackgroundUse;
public ShaderCollection(VulkanRenderer gd, Device device, ShaderSource[] shaders, SpecDescription[] specDescription = null, bool isMinimal = false)
{
_gd = gd;
_device = device;
if (specDescription != null && specDescription.Length != shaders.Length)
{
throw new ArgumentException($"{nameof(specDescription)} array length must match {nameof(shaders)} array if provided");
}
gd.Shaders.Add(this);
var internalShaders = new Shader[shaders.Length];
_infos = new PipelineShaderStageCreateInfo[shaders.Length];
SpecDescriptions = specDescription;
LinkStatus = ProgramLinkStatus.Incomplete;
uint stages = 0;
for (int i = 0; i < shaders.Length; i++)
{
var shader = new Shader(gd.Api, device, shaders[i]);
stages |= 1u << shader.StageFlags switch
{
ShaderStageFlags.ShaderStageFragmentBit => 1,
ShaderStageFlags.ShaderStageGeometryBit => 2,
ShaderStageFlags.ShaderStageTessellationControlBit => 3,
ShaderStageFlags.ShaderStageTessellationEvaluationBit => 4,
_ => 0
};
if (shader.StageFlags == ShaderStageFlags.ShaderStageComputeBit)
{
_isCompute = true;
}
internalShaders[i] = shader;
}
_shaders = internalShaders;
bool usePd = !isMinimal && VulkanConfiguration.UsePushDescriptors && _gd.Capabilities.SupportsPushDescriptors;
_plce = isMinimal
? gd.PipelineLayoutCache.Create(gd, device, shaders)
: gd.PipelineLayoutCache.GetOrCreate(gd, device, stages, usePd);
HasMinimalLayout = isMinimal;
UsePushDescriptors = usePd;
Stages = stages;
int[][] GrabAll(Func<ShaderBindings, IReadOnlyCollection<int>> selector)
{
bool hasAny = false;
int[][] bindings = new int[internalShaders.Length][];
for (int i = 0; i < internalShaders.Length; i++)
{
var collection = selector(internalShaders[i].Bindings);
hasAny |= collection.Count != 0;
bindings[i] = collection.ToArray();
}
return hasAny ? bindings : Array.Empty<int[]>();
}
Bindings = new[]
{
GrabAll(x => x.UniformBufferBindings),
GrabAll(x => x.StorageBufferBindings),
GrabAll(x => x.TextureBindings),
GrabAll(x => x.ImageBindings)
};
_compileTask = Task.CompletedTask;
_firstBackgroundUse = false;
}
public ShaderCollection(
VulkanRenderer gd,
Device device,
ShaderSource[] sources,
ProgramPipelineState state,
bool fromCache) : this(gd, device, sources)
{
_state = state;
_compileTask = BackgroundCompilation();
_firstBackgroundUse = !fromCache;
}
private async Task BackgroundCompilation()
{
await Task.WhenAll(_shaders.Select(shader => shader.CompileTask));
if (_shaders.Any(shader => shader.CompileStatus == ProgramLinkStatus.Failure))
{
LinkStatus = ProgramLinkStatus.Failure;
return;
}
try
{
if (_isCompute)
{
CreateBackgroundComputePipeline();
}
else
{
CreateBackgroundGraphicsPipeline();
}
}
catch (VulkanException e)
{
Logger.Error?.PrintMsg(LogClass.Gpu, $"Background Compilation failed: {e.Message}");
LinkStatus = ProgramLinkStatus.Failure;
}
}
private void EnsureShadersReady()
{
if (!_initialized)
{
CheckProgramLink(true);
ProgramLinkStatus resultStatus = ProgramLinkStatus.Success;
for (int i = 0; i < _shaders.Length; i++)
{
var shader = _shaders[i];
if (shader.CompileStatus != ProgramLinkStatus.Success)
{
resultStatus = ProgramLinkStatus.Failure;
}
_infos[i] = shader.GetInfo();
}
// If the link status was already set as failure by background compilation, prefer that decision.
if (LinkStatus != ProgramLinkStatus.Failure)
{
LinkStatus = resultStatus;
}
_initialized = true;
}
}
public PipelineShaderStageCreateInfo[] GetInfos()
{
EnsureShadersReady();
return _infos;
}
protected unsafe DisposableRenderPass CreateDummyRenderPass()
{
if (_dummyRenderPass.Value.Handle != 0)
{
return _dummyRenderPass;
}
return _dummyRenderPass = _state.ToRenderPass(_gd, _device);
}
public void CreateBackgroundComputePipeline()
{
PipelineState pipeline = new PipelineState();
pipeline.Initialize();
pipeline.Stages[0] = _shaders[0].GetInfo();
pipeline.StagesCount = 1;
pipeline.PipelineLayout = PipelineLayout;
pipeline.CreateComputePipeline(_gd, _device, this, (_gd.Pipeline as PipelineBase).PipelineCache);
pipeline.Dispose();
}
public void CreateBackgroundGraphicsPipeline()
{
// To compile shaders in the background in Vulkan, we need to create valid pipelines using the shader modules.
// The GPU provides pipeline state via the GAL that can be converted into our internal Vulkan pipeline state.
// This should match the pipeline state at the time of the first draw. If it doesn't, then it'll likely be
// close enough that the GPU driver will reuse the compiled shader for the different state.
// First, we need to create a render pass object compatible with the one that will be used at runtime.
// The active attachment formats have been provided by the abstraction layer.
var renderPass = CreateDummyRenderPass();
PipelineState pipeline = _state.ToVulkanPipelineState(_gd);
// Copy the shader stage info to the pipeline.
var stages = pipeline.Stages.AsSpan();
for (int i = 0; i < _shaders.Length; i++)
{
stages[i] = _shaders[i].GetInfo();
}
pipeline.StagesCount = (uint)_shaders.Length;
pipeline.PipelineLayout = PipelineLayout;
pipeline.CreateGraphicsPipeline(_gd, _device, this, (_gd.Pipeline as PipelineBase).PipelineCache, renderPass.Value);
pipeline.Dispose();
}
public ProgramLinkStatus CheckProgramLink(bool blocking)
{
if (LinkStatus == ProgramLinkStatus.Incomplete)
{
ProgramLinkStatus resultStatus = ProgramLinkStatus.Success;
foreach (Shader shader in _shaders)
{
if (shader.CompileStatus == ProgramLinkStatus.Incomplete)
{
if (blocking)
{
// Wait for this shader to finish compiling.
shader.WaitForCompile();
if (shader.CompileStatus != ProgramLinkStatus.Success)
{
resultStatus = ProgramLinkStatus.Failure;
}
}
else
{
return ProgramLinkStatus.Incomplete;
}
}
}
if (!_compileTask.IsCompleted)
{
if (blocking)
{
_compileTask.Wait();
if (LinkStatus == ProgramLinkStatus.Failure)
{
return ProgramLinkStatus.Failure;
}
}
else
{
return ProgramLinkStatus.Incomplete;
}
}
return resultStatus;
}
return LinkStatus;
}
public byte[] GetBinary()
{
return null;
}
public void AddComputePipeline(ref SpecData key, Auto<DisposablePipeline> pipeline)
{
(_computePipelineCache ??= new()).Add(ref key, pipeline);
}
public void AddGraphicsPipeline(ref PipelineUid key, Auto<DisposablePipeline> pipeline)
{
(_graphicsPipelineCache ??= new()).Add(ref key, pipeline);
}
public bool TryGetComputePipeline(ref SpecData key, out Auto<DisposablePipeline> pipeline)
{
if (_computePipelineCache == null)
{
pipeline = default;
return false;
}
if (_computePipelineCache.TryGetValue(ref key, out pipeline))
{
return true;
}
return false;
}
public bool TryGetGraphicsPipeline(ref PipelineUid key, out Auto<DisposablePipeline> pipeline)
{
if (_graphicsPipelineCache == null)
{
pipeline = default;
return false;
}
if (!_graphicsPipelineCache.TryGetValue(ref key, out pipeline))
{
if (_firstBackgroundUse)
{
Logger.Warning?.Print(LogClass.Gpu, "Background pipeline compile missed on draw - incorrect pipeline state?");
_firstBackgroundUse = false;
}
return false;
}
_firstBackgroundUse = false;
return true;
}
public Auto<DescriptorSetCollection> GetNewDescriptorSetCollection(
VulkanRenderer gd,
int commandBufferIndex,
int setIndex,
out bool isNew)
{
return _plce.GetNewDescriptorSetCollection(gd, commandBufferIndex, setIndex, out isNew);
}
protected virtual unsafe void Dispose(bool disposing)
{
if (disposing)
{
if (!_gd.Shaders.Remove(this))
{
return;
}
for (int i = 0; i < _shaders.Length; i++)
{
_shaders[i].Dispose();
}
if (_graphicsPipelineCache != null)
{
foreach (Auto<DisposablePipeline> pipeline in _graphicsPipelineCache.Values)
{
pipeline.Dispose();
}
}
if (_computePipelineCache != null)
{
foreach (Auto<DisposablePipeline> pipeline in _computePipelineCache.Values)
{
pipeline.Dispose();
}
}
if (_dummyRenderPass.Value.Handle != 0)
{
_dummyRenderPass.Dispose();
}
}
}
public void Dispose()
{
Dispose(true);
}
}
}