R/Ryujinx.Graphics.Gpu/Shader/ShaderCache.cs
riperiperi 9ac66336a2
GPU: Use lazy checks for specialization state (#4004)
* GPU: Use lazy checks for specialization state

This PR adds a new class, the SpecializationStateUpdater, that allows elements of specialization state to be updated individually, and signal the state is checked when it changes between draws, instead of building and checking it on every draw. This also avoids building spec state when

Most state updates have been moved behind the shader state update, so that their specialization state updates make it in before shaders are fetched.

Downside: Fields in GpuChannelGraphicsState are no longer readonly. To counteract copies that might be caused this I pass it as `ref` when possible, though maybe `in` would be better? Not really sure about the quirks of `in` and the difference probably won't show on a benchmark.

The result is around 2 extra FPS on SMO in the usual spot. Not much right now, but it will remove costs when we're doing more expensive specialization checks, such as fragment output type specialization for macos. It may also help more on other games with more draws.

* Address Feedback

* Oops
2022-12-04 18:41:17 +01:00

736 lines
31 KiB
C#

using Ryujinx.Common.Configuration;
using Ryujinx.Common.Logging;
using Ryujinx.Graphics.GAL;
using Ryujinx.Graphics.Gpu.Engine.Threed;
using Ryujinx.Graphics.Gpu.Engine.Types;
using Ryujinx.Graphics.Gpu.Image;
using Ryujinx.Graphics.Gpu.Memory;
using Ryujinx.Graphics.Gpu.Shader.DiskCache;
using Ryujinx.Graphics.Shader;
using Ryujinx.Graphics.Shader.Translation;
using System;
using System.Collections.Generic;
using System.IO;
using System.Linq;
using System.Threading;
namespace Ryujinx.Graphics.Gpu.Shader
{
/// <summary>
/// Memory cache of shader code.
/// </summary>
class ShaderCache : IDisposable
{
/// <summary>
/// Default flags used on the shader translation process.
/// </summary>
public const TranslationFlags DefaultFlags = TranslationFlags.DebugMode;
private struct TranslatedShader
{
public readonly CachedShaderStage Shader;
public readonly ShaderProgram Program;
public TranslatedShader(CachedShaderStage shader, ShaderProgram program)
{
Shader = shader;
Program = program;
}
}
private struct TranslatedShaderVertexPair
{
public readonly CachedShaderStage VertexA;
public readonly CachedShaderStage VertexB;
public readonly ShaderProgram Program;
public TranslatedShaderVertexPair(CachedShaderStage vertexA, CachedShaderStage vertexB, ShaderProgram program)
{
VertexA = vertexA;
VertexB = vertexB;
Program = program;
}
}
private readonly GpuContext _context;
private readonly ShaderDumper _dumper;
private readonly Dictionary<ulong, CachedShaderProgram> _cpPrograms;
private readonly Dictionary<ShaderAddresses, CachedShaderProgram> _gpPrograms;
private struct ProgramToSave
{
public readonly CachedShaderProgram CachedProgram;
public readonly IProgram HostProgram;
public readonly byte[] BinaryCode;
public ProgramToSave(CachedShaderProgram cachedProgram, IProgram hostProgram, byte[] binaryCode)
{
CachedProgram = cachedProgram;
HostProgram = hostProgram;
BinaryCode = binaryCode;
}
}
private Queue<ProgramToSave> _programsToSaveQueue;
private readonly ComputeShaderCacheHashTable _computeShaderCache;
private readonly ShaderCacheHashTable _graphicsShaderCache;
private readonly DiskCacheHostStorage _diskCacheHostStorage;
private readonly BackgroundDiskCacheWriter _cacheWriter;
/// <summary>
/// Event for signalling shader cache loading progress.
/// </summary>
public event Action<ShaderCacheState, int, int> ShaderCacheStateChanged;
/// <summary>
/// Creates a new instance of the shader cache.
/// </summary>
/// <param name="context">GPU context that the shader cache belongs to</param>
public ShaderCache(GpuContext context)
{
_context = context;
_dumper = new ShaderDumper();
_cpPrograms = new Dictionary<ulong, CachedShaderProgram>();
_gpPrograms = new Dictionary<ShaderAddresses, CachedShaderProgram>();
_programsToSaveQueue = new Queue<ProgramToSave>();
string diskCacheTitleId = GetDiskCachePath();
_computeShaderCache = new ComputeShaderCacheHashTable();
_graphicsShaderCache = new ShaderCacheHashTable();
_diskCacheHostStorage = new DiskCacheHostStorage(diskCacheTitleId);
if (_diskCacheHostStorage.CacheEnabled)
{
_cacheWriter = new BackgroundDiskCacheWriter(context, _diskCacheHostStorage);
}
}
/// <summary>
/// Gets the path where the disk cache for the current application is stored.
/// </summary>
private static string GetDiskCachePath()
{
return GraphicsConfig.EnableShaderCache && GraphicsConfig.TitleId != null
? Path.Combine(AppDataManager.GamesDirPath, GraphicsConfig.TitleId, "cache", "shader")
: null;
}
/// <summary>
/// Processes the queue of shaders that must save their binaries to the disk cache.
/// </summary>
public void ProcessShaderCacheQueue()
{
// Check to see if the binaries for previously compiled shaders are ready, and save them out.
while (_programsToSaveQueue.TryPeek(out ProgramToSave programToSave))
{
ProgramLinkStatus result = programToSave.HostProgram.CheckProgramLink(false);
if (result != ProgramLinkStatus.Incomplete)
{
if (result == ProgramLinkStatus.Success)
{
_cacheWriter.AddShader(programToSave.CachedProgram, programToSave.BinaryCode ?? programToSave.HostProgram.GetBinary());
}
_programsToSaveQueue.Dequeue();
}
else
{
break;
}
}
}
/// <summary>
/// Initialize the cache.
/// </summary>
/// <param name="cancellationToken">Cancellation token to cancel the shader cache initialization process</param>
internal void Initialize(CancellationToken cancellationToken)
{
if (_diskCacheHostStorage.CacheEnabled)
{
ParallelDiskCacheLoader loader = new ParallelDiskCacheLoader(
_context,
_graphicsShaderCache,
_computeShaderCache,
_diskCacheHostStorage,
cancellationToken,
ShaderCacheStateUpdate);
loader.LoadShaders();
int errorCount = loader.ErrorCount;
if (errorCount != 0)
{
Logger.Warning?.Print(LogClass.Gpu, $"Failed to load {errorCount} shaders from the disk cache.");
}
}
}
/// <summary>
/// Shader cache state update handler.
/// </summary>
/// <param name="state">Current state of the shader cache load process</param>
/// <param name="current">Number of the current shader being processed</param>
/// <param name="total">Total number of shaders to process</param>
private void ShaderCacheStateUpdate(ShaderCacheState state, int current, int total)
{
ShaderCacheStateChanged?.Invoke(state, current, total);
}
/// <summary>
/// Gets a compute shader from the cache.
/// </summary>
/// <remarks>
/// This automatically translates, compiles and adds the code to the cache if not present.
/// </remarks>
/// <param name="channel">GPU channel</param>
/// <param name="poolState">Texture pool state</param>
/// <param name="computeState">Compute engine state</param>
/// <param name="gpuVa">GPU virtual address of the binary shader code</param>
/// <returns>Compiled compute shader code</returns>
public CachedShaderProgram GetComputeShader(
GpuChannel channel,
GpuChannelPoolState poolState,
GpuChannelComputeState computeState,
ulong gpuVa)
{
if (_cpPrograms.TryGetValue(gpuVa, out var cpShader) && IsShaderEqual(channel, poolState, computeState, cpShader, gpuVa))
{
return cpShader;
}
if (_computeShaderCache.TryFind(channel, poolState, computeState, gpuVa, out cpShader, out byte[] cachedGuestCode))
{
_cpPrograms[gpuVa] = cpShader;
return cpShader;
}
ShaderSpecializationState specState = new ShaderSpecializationState(ref computeState);
GpuAccessorState gpuAccessorState = new GpuAccessorState(poolState, computeState, default, specState);
GpuAccessor gpuAccessor = new GpuAccessor(_context, channel, gpuAccessorState);
TranslatorContext translatorContext = DecodeComputeShader(gpuAccessor, _context.Capabilities.Api, gpuVa);
TranslatedShader translatedShader = TranslateShader(_dumper, channel, translatorContext, cachedGuestCode);
ShaderSource[] shaderSourcesArray = new ShaderSource[] { CreateShaderSource(translatedShader.Program) };
IProgram hostProgram = _context.Renderer.CreateProgram(shaderSourcesArray, new ShaderInfo(-1));
cpShader = new CachedShaderProgram(hostProgram, specState, translatedShader.Shader);
_computeShaderCache.Add(cpShader);
EnqueueProgramToSave(cpShader, hostProgram, shaderSourcesArray);
_cpPrograms[gpuVa] = cpShader;
return cpShader;
}
/// <summary>
/// Updates the shader pipeline state based on the current GPU state.
/// </summary>
/// <param name="state">Current GPU 3D engine state</param>
/// <param name="pipeline">Shader pipeline state to be updated</param>
/// <param name="graphicsState">Current graphics state</param>
/// <param name="channel">Current GPU channel</param>
private void UpdatePipelineInfo(
ref ThreedClassState state,
ref ProgramPipelineState pipeline,
GpuChannelGraphicsState graphicsState,
GpuChannel channel)
{
channel.TextureManager.UpdateRenderTargets();
var rtControl = state.RtControl;
var msaaMode = state.RtMsaaMode;
pipeline.SamplesCount = msaaMode.SamplesInX() * msaaMode.SamplesInY();
int count = rtControl.UnpackCount();
for (int index = 0; index < Constants.TotalRenderTargets; index++)
{
int rtIndex = rtControl.UnpackPermutationIndex(index);
var colorState = state.RtColorState[rtIndex];
if (index >= count || colorState.Format == 0 || colorState.WidthOrStride == 0)
{
pipeline.AttachmentEnable[index] = false;
pipeline.AttachmentFormats[index] = Format.R8G8B8A8Unorm;
}
else
{
pipeline.AttachmentEnable[index] = true;
pipeline.AttachmentFormats[index] = colorState.Format.Convert().Format;
}
}
pipeline.DepthStencilEnable = state.RtDepthStencilEnable;
pipeline.DepthStencilFormat = pipeline.DepthStencilEnable ? state.RtDepthStencilState.Format.Convert().Format : Format.D24UnormS8Uint;
pipeline.VertexBufferCount = Constants.TotalVertexBuffers;
pipeline.Topology = graphicsState.Topology;
}
/// <summary>
/// Gets a graphics shader program from the shader cache.
/// This includes all the specified shader stages.
/// </summary>
/// <remarks>
/// This automatically translates, compiles and adds the code to the cache if not present.
/// </remarks>
/// <param name="state">GPU state</param>
/// <param name="pipeline">Pipeline state</param>
/// <param name="channel">GPU channel</param>
/// <param name="poolState">Texture pool state</param>
/// <param name="graphicsState">3D engine state</param>
/// <param name="addresses">Addresses of the shaders for each stage</param>
/// <returns>Compiled graphics shader code</returns>
public CachedShaderProgram GetGraphicsShader(
ref ThreedClassState state,
ref ProgramPipelineState pipeline,
GpuChannel channel,
ref GpuChannelPoolState poolState,
ref GpuChannelGraphicsState graphicsState,
ShaderAddresses addresses)
{
if (_gpPrograms.TryGetValue(addresses, out var gpShaders) && IsShaderEqual(channel, ref poolState, ref graphicsState, gpShaders, addresses))
{
return gpShaders;
}
if (_graphicsShaderCache.TryFind(channel, ref poolState, ref graphicsState, addresses, out gpShaders, out var cachedGuestCode))
{
_gpPrograms[addresses] = gpShaders;
return gpShaders;
}
TransformFeedbackDescriptor[] transformFeedbackDescriptors = GetTransformFeedbackDescriptors(ref state);
UpdatePipelineInfo(ref state, ref pipeline, graphicsState, channel);
ShaderSpecializationState specState = new ShaderSpecializationState(ref graphicsState, ref pipeline, transformFeedbackDescriptors);
GpuAccessorState gpuAccessorState = new GpuAccessorState(poolState, default, graphicsState, specState, transformFeedbackDescriptors);
ReadOnlySpan<ulong> addressesSpan = addresses.AsSpan();
TranslatorContext[] translatorContexts = new TranslatorContext[Constants.ShaderStages + 1];
TranslatorContext nextStage = null;
TargetApi api = _context.Capabilities.Api;
for (int stageIndex = Constants.ShaderStages - 1; stageIndex >= 0; stageIndex--)
{
ulong gpuVa = addressesSpan[stageIndex + 1];
if (gpuVa != 0)
{
GpuAccessor gpuAccessor = new GpuAccessor(_context, channel, gpuAccessorState, stageIndex);
TranslatorContext currentStage = DecodeGraphicsShader(gpuAccessor, api, DefaultFlags, gpuVa);
if (nextStage != null)
{
currentStage.SetNextStage(nextStage);
}
if (stageIndex == 0 && addresses.VertexA != 0)
{
translatorContexts[0] = DecodeGraphicsShader(gpuAccessor, api, DefaultFlags | TranslationFlags.VertexA, addresses.VertexA);
}
translatorContexts[stageIndex + 1] = currentStage;
nextStage = currentStage;
}
}
CachedShaderStage[] shaders = new CachedShaderStage[Constants.ShaderStages + 1];
List<ShaderSource> shaderSources = new List<ShaderSource>();
TranslatorContext previousStage = null;
for (int stageIndex = 0; stageIndex < Constants.ShaderStages; stageIndex++)
{
TranslatorContext currentStage = translatorContexts[stageIndex + 1];
if (currentStage != null)
{
ShaderProgram program;
if (stageIndex == 0 && translatorContexts[0] != null)
{
TranslatedShaderVertexPair translatedShader = TranslateShader(
_dumper,
channel,
currentStage,
translatorContexts[0],
cachedGuestCode.VertexACode,
cachedGuestCode.VertexBCode);
shaders[0] = translatedShader.VertexA;
shaders[1] = translatedShader.VertexB;
program = translatedShader.Program;
}
else
{
byte[] code = cachedGuestCode.GetByIndex(stageIndex);
TranslatedShader translatedShader = TranslateShader(_dumper, channel, currentStage, code);
shaders[stageIndex + 1] = translatedShader.Shader;
program = translatedShader.Program;
}
if (program != null)
{
shaderSources.Add(CreateShaderSource(program));
}
previousStage = currentStage;
}
else if (
previousStage != null &&
previousStage.LayerOutputWritten &&
stageIndex == 3 &&
!_context.Capabilities.SupportsLayerVertexTessellation)
{
shaderSources.Add(CreateShaderSource(previousStage.GenerateGeometryPassthrough()));
}
}
ShaderSource[] shaderSourcesArray = shaderSources.ToArray();
int fragmentOutputMap = shaders[5]?.Info.FragmentOutputMap ?? -1;
IProgram hostProgram = _context.Renderer.CreateProgram(shaderSourcesArray, new ShaderInfo(fragmentOutputMap, pipeline));
gpShaders = new CachedShaderProgram(hostProgram, specState, shaders);
_graphicsShaderCache.Add(gpShaders);
EnqueueProgramToSave(gpShaders, hostProgram, shaderSourcesArray);
_gpPrograms[addresses] = gpShaders;
return gpShaders;
}
/// <summary>
/// Creates a shader source for use with the backend from a translated shader program.
/// </summary>
/// <param name="program">Translated shader program</param>
/// <returns>Shader source</returns>
public static ShaderSource CreateShaderSource(ShaderProgram program)
{
return new ShaderSource(program.Code, program.BinaryCode, GetBindings(program.Info), program.Info.Stage, program.Language);
}
/// <summary>
/// Puts a program on the queue of programs to be saved on the disk cache.
/// </summary>
/// <remarks>
/// This will not do anything if disk shader cache is disabled.
/// </remarks>
/// <param name="program">Cached shader program</param>
/// <param name="hostProgram">Host program</param>
/// <param name="sources">Source for each shader stage</param>
private void EnqueueProgramToSave(CachedShaderProgram program, IProgram hostProgram, ShaderSource[] sources)
{
if (_diskCacheHostStorage.CacheEnabled)
{
byte[] binaryCode = _context.Capabilities.Api == TargetApi.Vulkan ? ShaderBinarySerializer.Pack(sources) : null;
ProgramToSave programToSave = new ProgramToSave(program, hostProgram, binaryCode);
_programsToSaveQueue.Enqueue(programToSave);
}
}
/// <summary>
/// Gets transform feedback state from the current GPU state.
/// </summary>
/// <param name="state">Current GPU state</param>
/// <returns>Four transform feedback descriptors for the enabled TFBs, or null if TFB is disabled</returns>
private static TransformFeedbackDescriptor[] GetTransformFeedbackDescriptors(ref ThreedClassState state)
{
bool tfEnable = state.TfEnable;
if (!tfEnable)
{
return null;
}
TransformFeedbackDescriptor[] descs = new TransformFeedbackDescriptor[Constants.TotalTransformFeedbackBuffers];
for (int i = 0; i < Constants.TotalTransformFeedbackBuffers; i++)
{
var tf = state.TfState[i];
descs[i] = new TransformFeedbackDescriptor(
tf.BufferIndex,
tf.Stride,
tf.VaryingsCount,
ref state.TfVaryingLocations[i]);
}
return descs;
}
/// <summary>
/// Checks if compute shader code in memory is equal to the cached shader.
/// </summary>
/// <param name="channel">GPU channel using the shader</param>
/// <param name="poolState">GPU channel state to verify shader compatibility</param>
/// <param name="computeState">GPU channel compute state to verify shader compatibility</param>
/// <param name="cpShader">Cached compute shader</param>
/// <param name="gpuVa">GPU virtual address of the shader code in memory</param>
/// <returns>True if the code is different, false otherwise</returns>
private static bool IsShaderEqual(
GpuChannel channel,
GpuChannelPoolState poolState,
GpuChannelComputeState computeState,
CachedShaderProgram cpShader,
ulong gpuVa)
{
if (IsShaderEqual(channel.MemoryManager, cpShader.Shaders[0], gpuVa))
{
return cpShader.SpecializationState.MatchesCompute(channel, ref poolState, computeState, true);
}
return false;
}
/// <summary>
/// Checks if graphics shader code from all stages in memory are equal to the cached shaders.
/// </summary>
/// <param name="channel">GPU channel using the shader</param>
/// <param name="poolState">GPU channel state to verify shader compatibility</param>
/// <param name="graphicsState">GPU channel graphics state to verify shader compatibility</param>
/// <param name="gpShaders">Cached graphics shaders</param>
/// <param name="addresses">GPU virtual addresses of all enabled shader stages</param>
/// <returns>True if the code is different, false otherwise</returns>
private static bool IsShaderEqual(
GpuChannel channel,
ref GpuChannelPoolState poolState,
ref GpuChannelGraphicsState graphicsState,
CachedShaderProgram gpShaders,
ShaderAddresses addresses)
{
ReadOnlySpan<ulong> addressesSpan = addresses.AsSpan();
for (int stageIndex = 0; stageIndex < gpShaders.Shaders.Length; stageIndex++)
{
CachedShaderStage shader = gpShaders.Shaders[stageIndex];
ulong gpuVa = addressesSpan[stageIndex];
if (!IsShaderEqual(channel.MemoryManager, shader, gpuVa))
{
return false;
}
}
bool usesDrawParameters = gpShaders.Shaders[1]?.Info.UsesDrawParameters ?? false;
return gpShaders.SpecializationState.MatchesGraphics(channel, ref poolState, ref graphicsState, usesDrawParameters, true);
}
/// <summary>
/// Checks if the code of the specified cached shader is different from the code in memory.
/// </summary>
/// <param name="memoryManager">Memory manager used to access the GPU memory where the shader is located</param>
/// <param name="shader">Cached shader to compare with</param>
/// <param name="gpuVa">GPU virtual address of the binary shader code</param>
/// <returns>True if the code is different, false otherwise</returns>
private static bool IsShaderEqual(MemoryManager memoryManager, CachedShaderStage shader, ulong gpuVa)
{
if (shader == null)
{
return true;
}
ReadOnlySpan<byte> memoryCode = memoryManager.GetSpan(gpuVa, shader.Code.Length);
return memoryCode.SequenceEqual(shader.Code);
}
/// <summary>
/// Decode the binary Maxwell shader code to a translator context.
/// </summary>
/// <param name="gpuAccessor">GPU state accessor</param>
/// <param name="api">Graphics API that will be used with the shader</param>
/// <param name="gpuVa">GPU virtual address of the binary shader code</param>
/// <returns>The generated translator context</returns>
public static TranslatorContext DecodeComputeShader(IGpuAccessor gpuAccessor, TargetApi api, ulong gpuVa)
{
var options = CreateTranslationOptions(api, DefaultFlags | TranslationFlags.Compute);
return Translator.CreateContext(gpuVa, gpuAccessor, options);
}
/// <summary>
/// Decode the binary Maxwell shader code to a translator context.
/// </summary>
/// <remarks>
/// This will combine the "Vertex A" and "Vertex B" shader stages, if specified, into one shader.
/// </remarks>
/// <param name="gpuAccessor">GPU state accessor</param>
/// <param name="api">Graphics API that will be used with the shader</param>
/// <param name="flags">Flags that controls shader translation</param>
/// <param name="gpuVa">GPU virtual address of the shader code</param>
/// <returns>The generated translator context</returns>
public static TranslatorContext DecodeGraphicsShader(IGpuAccessor gpuAccessor, TargetApi api, TranslationFlags flags, ulong gpuVa)
{
var options = CreateTranslationOptions(api, flags);
return Translator.CreateContext(gpuVa, gpuAccessor, options);
}
/// <summary>
/// Translates a previously generated translator context to something that the host API accepts.
/// </summary>
/// <param name="dumper">Optional shader code dumper</param>
/// <param name="channel">GPU channel using the shader</param>
/// <param name="currentStage">Translator context of the stage to be translated</param>
/// <param name="vertexA">Optional translator context of the shader that should be combined</param>
/// <param name="codeA">Optional Maxwell binary code of the Vertex A shader, if present</param>
/// <param name="codeB">Optional Maxwell binary code of the Vertex B or current stage shader, if present on cache</param>
/// <returns>Compiled graphics shader code</returns>
private static TranslatedShaderVertexPair TranslateShader(
ShaderDumper dumper,
GpuChannel channel,
TranslatorContext currentStage,
TranslatorContext vertexA,
byte[] codeA,
byte[] codeB)
{
ulong cb1DataAddress = channel.BufferManager.GetGraphicsUniformBufferAddress(0, 1);
var memoryManager = channel.MemoryManager;
codeA ??= memoryManager.GetSpan(vertexA.Address, vertexA.Size).ToArray();
codeB ??= memoryManager.GetSpan(currentStage.Address, currentStage.Size).ToArray();
byte[] cb1DataA = memoryManager.Physical.GetSpan(cb1DataAddress, vertexA.Cb1DataSize).ToArray();
byte[] cb1DataB = memoryManager.Physical.GetSpan(cb1DataAddress, currentStage.Cb1DataSize).ToArray();
ShaderDumpPaths pathsA = default;
ShaderDumpPaths pathsB = default;
if (dumper != null)
{
pathsA = dumper.Dump(codeA, compute: false);
pathsB = dumper.Dump(codeB, compute: false);
}
ShaderProgram program = currentStage.Translate(vertexA);
pathsB.Prepend(program);
pathsA.Prepend(program);
CachedShaderStage vertexAStage = new CachedShaderStage(null, codeA, cb1DataA);
CachedShaderStage vertexBStage = new CachedShaderStage(program.Info, codeB, cb1DataB);
return new TranslatedShaderVertexPair(vertexAStage, vertexBStage, program);
}
/// <summary>
/// Translates a previously generated translator context to something that the host API accepts.
/// </summary>
/// <param name="dumper">Optional shader code dumper</param>
/// <param name="channel">GPU channel using the shader</param>
/// <param name="context">Translator context of the stage to be translated</param>
/// <param name="code">Optional Maxwell binary code of the current stage shader, if present on cache</param>
/// <returns>Compiled graphics shader code</returns>
private static TranslatedShader TranslateShader(ShaderDumper dumper, GpuChannel channel, TranslatorContext context, byte[] code)
{
var memoryManager = channel.MemoryManager;
ulong cb1DataAddress = context.Stage == ShaderStage.Compute
? channel.BufferManager.GetComputeUniformBufferAddress(1)
: channel.BufferManager.GetGraphicsUniformBufferAddress(StageToStageIndex(context.Stage), 1);
byte[] cb1Data = memoryManager.Physical.GetSpan(cb1DataAddress, context.Cb1DataSize).ToArray();
code ??= memoryManager.GetSpan(context.Address, context.Size).ToArray();
ShaderDumpPaths paths = dumper?.Dump(code, context.Stage == ShaderStage.Compute) ?? default;
ShaderProgram program = context.Translate();
paths.Prepend(program);
return new TranslatedShader(new CachedShaderStage(program.Info, code, cb1Data), program);
}
/// <summary>
/// Gets the index of a stage from a <see cref="ShaderStage"/>.
/// </summary>
/// <param name="stage">Stage to get the index from</param>
/// <returns>Stage index</returns>
private static int StageToStageIndex(ShaderStage stage)
{
return stage switch
{
ShaderStage.TessellationControl => 1,
ShaderStage.TessellationEvaluation => 2,
ShaderStage.Geometry => 3,
ShaderStage.Fragment => 4,
_ => 0
};
}
/// <summary>
/// Gets information about the bindings used by a shader program.
/// </summary>
/// <param name="info">Shader program information to get the information from</param>
/// <returns>Shader bindings</returns>
public static ShaderBindings GetBindings(ShaderProgramInfo info)
{
var uniformBufferBindings = info.CBuffers.Select(x => x.Binding).ToArray();
var storageBufferBindings = info.SBuffers.Select(x => x.Binding).ToArray();
var textureBindings = info.Textures.Select(x => x.Binding).ToArray();
var imageBindings = info.Images.Select(x => x.Binding).ToArray();
return new ShaderBindings(
uniformBufferBindings,
storageBufferBindings,
textureBindings,
imageBindings);
}
/// <summary>
/// Creates shader translation options with the requested graphics API and flags.
/// The shader language is choosen based on the current configuration and graphics API.
/// </summary>
/// <param name="api">Target graphics API</param>
/// <param name="flags">Translation flags</param>
/// <returns>Translation options</returns>
private static TranslationOptions CreateTranslationOptions(TargetApi api, TranslationFlags flags)
{
TargetLanguage lang = GraphicsConfig.EnableSpirvCompilationOnVulkan && api == TargetApi.Vulkan
? TargetLanguage.Spirv
: TargetLanguage.Glsl;
return new TranslationOptions(lang, api, flags);
}
/// <summary>
/// Disposes the shader cache, deleting all the cached shaders.
/// It's an error to use the shader cache after disposal.
/// </summary>
public void Dispose()
{
foreach (CachedShaderProgram program in _graphicsShaderCache.GetPrograms())
{
program.Dispose();
}
foreach (CachedShaderProgram program in _computeShaderCache.GetPrograms())
{
program.Dispose();
}
_cacheWriter?.Dispose();
}
}
}