ryujinx-mirror/Ryujinx.Graphics.Vulkan/HelperShader.cs
riperiperi 8fa248ceb4
Vulkan: Add workarounds for MoltenVK (#4202)
* Add MVK basics.

* Use appropriate output attribute types

* 4kb vertex alignment, bunch of fixes

* Add reduced shader precision mode for mvk.

* Disable ASTC on MVK for now

* Only request robustnes2 when it is available.

* It's just the one feature actually

* Add triangle fan conversion

* Allow NullDescriptor on MVK for some reason.

* Force safe blit on MoltenVK

* Use ASTC only when formats are all available.

* Disable multilevel 3d texture views

* Filter duplicate render targets (on backend)

* Add Automatic MoltenVK Configuration

* Do not create color attachment views with formats that are not RT compatible

* Make sure that the host format matches the vertex shader input types for invalid/unknown guest formats

* FIx rebase for Vertex Attrib State

* Fix 4b alignment for vertex

* Use asynchronous queue submits for MVK

* Ensure color clear shader has correct output type

* Update MoltenVK config

* Always use MoltenVK workarounds on MacOS

* Make MVK supersede all vendors

* Fix rebase

* Various fixes on rebase

* Get portability flags from extension

* Fix some minor rebasing issues

* Style change

* Use LibraryImport for MVKConfiguration

* Rename MoltenVK vendor to Apple

Intel and AMD GPUs on moltenvk report with the those vendors - only apple silicon reports with vendor 0x106B.

* Fix features2 rebase conflict

* Rename fragment output type

* Add missing check for fragment output types

Might have caused the crash in MK8

* Only do fragment output specialization on MoltenVK

* Avoid copy when passing capabilities

* Self feedback

* Address feedback

Co-authored-by: gdk <gab.dark.100@gmail.com>
Co-authored-by: nastys <nastys@users.noreply.github.com>
2023-01-13 01:31:21 +01:00

1007 lines
38 KiB
C#

using Ryujinx.Graphics.GAL;
using Ryujinx.Graphics.Shader;
using Ryujinx.Graphics.Shader.Translation;
using Ryujinx.Graphics.Vulkan.Shaders;
using Silk.NET.Vulkan;
using System;
using System.Collections.Generic;
using VkFormat = Silk.NET.Vulkan.Format;
namespace Ryujinx.Graphics.Vulkan
{
enum ComponentType
{
Float,
SignedInteger,
UnsignedInteger
}
class HelperShader : IDisposable
{
private const int UniformBufferAlignment = 256;
private readonly PipelineHelperShader _pipeline;
private readonly ISampler _samplerLinear;
private readonly ISampler _samplerNearest;
private readonly IProgram _programColorBlit;
private readonly IProgram _programColorBlitClearAlpha;
private readonly IProgram _programColorClearF;
private readonly IProgram _programColorClearSI;
private readonly IProgram _programColorClearUI;
private readonly IProgram _programStrideChange;
private readonly IProgram _programConvertIndexBuffer;
private readonly IProgram _programConvertIndirectData;
private readonly IProgram _programColorCopyToNonMs;
private readonly IProgram _programColorDrawToMs;
public HelperShader(VulkanRenderer gd, Device device)
{
_pipeline = new PipelineHelperShader(gd, device);
_pipeline.Initialize();
_samplerLinear = gd.CreateSampler(GAL.SamplerCreateInfo.Create(MinFilter.Linear, MagFilter.Linear));
_samplerNearest = gd.CreateSampler(GAL.SamplerCreateInfo.Create(MinFilter.Nearest, MagFilter.Nearest));
var colorBlitVertexBindings = new ShaderBindings(
new[] { 1 },
Array.Empty<int>(),
Array.Empty<int>(),
Array.Empty<int>());
var colorBlitFragmentBindings = new ShaderBindings(
Array.Empty<int>(),
Array.Empty<int>(),
new[] { 0 },
Array.Empty<int>());
_programColorBlit = gd.CreateProgramWithMinimalLayout(new[]
{
new ShaderSource(ShaderBinaries.ColorBlitVertexShaderSource, colorBlitVertexBindings, ShaderStage.Vertex, TargetLanguage.Spirv),
new ShaderSource(ShaderBinaries.ColorBlitFragmentShaderSource, colorBlitFragmentBindings, ShaderStage.Fragment, TargetLanguage.Spirv),
});
_programColorBlitClearAlpha = gd.CreateProgramWithMinimalLayout(new[]
{
new ShaderSource(ShaderBinaries.ColorBlitVertexShaderSource, colorBlitVertexBindings, ShaderStage.Vertex, TargetLanguage.Spirv),
new ShaderSource(ShaderBinaries.ColorBlitClearAlphaFragmentShaderSource, colorBlitFragmentBindings, ShaderStage.Fragment, TargetLanguage.Spirv),
});
var colorClearFragmentBindings = new ShaderBindings(
Array.Empty<int>(),
Array.Empty<int>(),
Array.Empty<int>(),
Array.Empty<int>());
_programColorClearF = gd.CreateProgramWithMinimalLayout(new[]
{
new ShaderSource(ShaderBinaries.ColorClearVertexShaderSource, colorBlitVertexBindings, ShaderStage.Vertex, TargetLanguage.Spirv),
new ShaderSource(ShaderBinaries.ColorClearFFragmentShaderSource, colorClearFragmentBindings, ShaderStage.Fragment, TargetLanguage.Spirv),
});
_programColorClearSI = gd.CreateProgramWithMinimalLayout(new[]
{
new ShaderSource(ShaderBinaries.ColorClearVertexShaderSource, colorBlitVertexBindings, ShaderStage.Vertex, TargetLanguage.Spirv),
new ShaderSource(ShaderBinaries.ColorClearSIFragmentShaderSource, colorClearFragmentBindings, ShaderStage.Fragment, TargetLanguage.Spirv),
});
_programColorClearUI = gd.CreateProgramWithMinimalLayout(new[]
{
new ShaderSource(ShaderBinaries.ColorClearVertexShaderSource, colorBlitVertexBindings, ShaderStage.Vertex, TargetLanguage.Spirv),
new ShaderSource(ShaderBinaries.ColorClearUIFragmentShaderSource, colorClearFragmentBindings, ShaderStage.Fragment, TargetLanguage.Spirv),
});
var strideChangeBindings = new ShaderBindings(
new[] { 0 },
new[] { 1, 2 },
Array.Empty<int>(),
Array.Empty<int>());
_programStrideChange = gd.CreateProgramWithMinimalLayout(new[]
{
new ShaderSource(ShaderBinaries.ChangeBufferStrideShaderSource, strideChangeBindings, ShaderStage.Compute, TargetLanguage.Spirv),
});
var colorCopyToNonMsBindings = new ShaderBindings(
new[] { 0 },
Array.Empty<int>(),
new[] { 0 },
new[] { 0 });
_programColorCopyToNonMs = gd.CreateProgramWithMinimalLayout(new[]
{
new ShaderSource(ShaderBinaries.ColorCopyToNonMsComputeShaderSource, colorCopyToNonMsBindings, ShaderStage.Compute, TargetLanguage.Spirv),
});
var colorDrawToMsVertexBindings = new ShaderBindings(
Array.Empty<int>(),
Array.Empty<int>(),
Array.Empty<int>(),
Array.Empty<int>());
var colorDrawToMsFragmentBindings = new ShaderBindings(
new[] { 0 },
Array.Empty<int>(),
new[] { 0 },
Array.Empty<int>());
_programColorDrawToMs = gd.CreateProgramWithMinimalLayout(new[]
{
new ShaderSource(ShaderBinaries.ColorDrawToMsVertexShaderSource, colorDrawToMsVertexBindings, ShaderStage.Vertex, TargetLanguage.Spirv),
new ShaderSource(ShaderBinaries.ColorDrawToMsFragmentShaderSource, colorDrawToMsFragmentBindings, ShaderStage.Fragment, TargetLanguage.Spirv),
});
var convertIndexBufferBindings = new ShaderBindings(
new[] { 0 },
new[] { 1, 2 },
Array.Empty<int>(),
Array.Empty<int>());
_programConvertIndexBuffer = gd.CreateProgramWithMinimalLayout(new[]
{
new ShaderSource(ShaderBinaries.ConvertIndexBufferShaderSource, convertIndexBufferBindings, ShaderStage.Compute, TargetLanguage.Spirv),
});
var convertIndirectDataBindings = new ShaderBindings(
new[] { 0 },
new[] { 1, 2, 3 },
Array.Empty<int>(),
Array.Empty<int>());
_programConvertIndirectData = gd.CreateProgramWithMinimalLayout(new[]
{
new ShaderSource(ShaderBinaries.ConvertIndirectDataShaderSource, convertIndirectDataBindings, ShaderStage.Compute, TargetLanguage.Spirv),
});
}
public void Blit(
VulkanRenderer gd,
TextureView src,
Auto<DisposableImageView> dst,
int dstWidth,
int dstHeight,
VkFormat dstFormat,
Extents2D srcRegion,
Extents2D dstRegion,
bool linearFilter,
bool clearAlpha = false)
{
gd.FlushAllCommands();
using var cbs = gd.CommandBufferPool.Rent();
Blit(gd, cbs, src, dst, dstWidth, dstHeight, dstFormat, srcRegion, dstRegion, linearFilter, clearAlpha);
}
public void Blit(
VulkanRenderer gd,
CommandBufferScoped cbs,
TextureView src,
Auto<DisposableImageView> dst,
int dstWidth,
int dstHeight,
VkFormat dstFormat,
Extents2D srcRegion,
Extents2D dstRegion,
bool linearFilter,
bool clearAlpha = false)
{
_pipeline.SetCommandBuffer(cbs);
const int RegionBufferSize = 16;
var sampler = linearFilter ? _samplerLinear : _samplerNearest;
_pipeline.SetTextureAndSampler(ShaderStage.Fragment, 0, src, sampler);
Span<float> region = stackalloc float[RegionBufferSize / sizeof(float)];
region[0] = (float)srcRegion.X1 / src.Width;
region[1] = (float)srcRegion.X2 / src.Width;
region[2] = (float)srcRegion.Y1 / src.Height;
region[3] = (float)srcRegion.Y2 / src.Height;
if (dstRegion.X1 > dstRegion.X2)
{
(region[0], region[1]) = (region[1], region[0]);
}
if (dstRegion.Y1 > dstRegion.Y2)
{
(region[2], region[3]) = (region[3], region[2]);
}
var bufferHandle = gd.BufferManager.CreateWithHandle(gd, RegionBufferSize, false);
gd.BufferManager.SetData<float>(bufferHandle, 0, region);
_pipeline.SetUniformBuffers(stackalloc[] { new BufferAssignment(1, new BufferRange(bufferHandle, 0, RegionBufferSize)) });
Span<GAL.Viewport> viewports = stackalloc GAL.Viewport[1];
var rect = new Rectangle<float>(
MathF.Min(dstRegion.X1, dstRegion.X2),
MathF.Min(dstRegion.Y1, dstRegion.Y2),
MathF.Abs(dstRegion.X2 - dstRegion.X1),
MathF.Abs(dstRegion.Y2 - dstRegion.Y1));
viewports[0] = new GAL.Viewport(
rect,
ViewportSwizzle.PositiveX,
ViewportSwizzle.PositiveY,
ViewportSwizzle.PositiveZ,
ViewportSwizzle.PositiveW,
0f,
1f);
Span<Rectangle<int>> scissors = stackalloc Rectangle<int>[1];
scissors[0] = new Rectangle<int>(0, 0, dstWidth, dstHeight);
_pipeline.SetProgram(clearAlpha ? _programColorBlitClearAlpha : _programColorBlit);
_pipeline.SetRenderTarget(dst, (uint)dstWidth, (uint)dstHeight, false, dstFormat);
_pipeline.SetRenderTargetColorMasks(new uint[] { 0xf });
_pipeline.SetScissors(scissors);
if (clearAlpha)
{
_pipeline.ClearRenderTargetColor(0, 0, 1, new ColorF(0f, 0f, 0f, 1f));
}
_pipeline.SetViewports(viewports, false);
_pipeline.SetPrimitiveTopology(GAL.PrimitiveTopology.TriangleStrip);
_pipeline.Draw(4, 1, 0, 0);
_pipeline.Finish(gd, cbs);
gd.BufferManager.Delete(bufferHandle);
}
public void Clear(
VulkanRenderer gd,
Auto<DisposableImageView> dst,
ReadOnlySpan<float> clearColor,
uint componentMask,
int dstWidth,
int dstHeight,
VkFormat dstFormat,
ComponentType type,
Rectangle<int> scissor)
{
const int ClearColorBufferSize = 16;
gd.FlushAllCommands();
using var cbs = gd.CommandBufferPool.Rent();
_pipeline.SetCommandBuffer(cbs);
var bufferHandle = gd.BufferManager.CreateWithHandle(gd, ClearColorBufferSize, false);
gd.BufferManager.SetData<float>(bufferHandle, 0, clearColor);
_pipeline.SetUniformBuffers(stackalloc[] { new BufferAssignment(1, new BufferRange(bufferHandle, 0, ClearColorBufferSize)) });
Span<GAL.Viewport> viewports = stackalloc GAL.Viewport[1];
viewports[0] = new GAL.Viewport(
new Rectangle<float>(0, 0, dstWidth, dstHeight),
ViewportSwizzle.PositiveX,
ViewportSwizzle.PositiveY,
ViewportSwizzle.PositiveZ,
ViewportSwizzle.PositiveW,
0f,
1f);
Span<Rectangle<int>> scissors = stackalloc Rectangle<int>[1];
scissors[0] = scissor;
IProgram program;
if (type == ComponentType.SignedInteger)
{
program = _programColorClearSI;
}
else if (type == ComponentType.UnsignedInteger)
{
program = _programColorClearUI;
}
else
{
program = _programColorClearF;
}
_pipeline.SetProgram(program);
_pipeline.SetRenderTarget(dst, (uint)dstWidth, (uint)dstHeight, false, dstFormat);
_pipeline.SetRenderTargetColorMasks(new uint[] { componentMask });
_pipeline.SetViewports(viewports, false);
_pipeline.SetScissors(scissors);
_pipeline.SetPrimitiveTopology(GAL.PrimitiveTopology.TriangleStrip);
_pipeline.Draw(4, 1, 0, 0);
_pipeline.Finish();
gd.BufferManager.Delete(bufferHandle);
}
public void DrawTexture(
VulkanRenderer gd,
PipelineBase pipeline,
TextureView src,
ISampler srcSampler,
Extents2DF srcRegion,
Extents2DF dstRegion)
{
const int RegionBufferSize = 16;
pipeline.SetTextureAndSampler(ShaderStage.Fragment, 0, src, srcSampler);
Span<float> region = stackalloc float[RegionBufferSize / sizeof(float)];
region[0] = srcRegion.X1 / src.Width;
region[1] = srcRegion.X2 / src.Width;
region[2] = srcRegion.Y1 / src.Height;
region[3] = srcRegion.Y2 / src.Height;
if (dstRegion.X1 > dstRegion.X2)
{
(region[0], region[1]) = (region[1], region[0]);
}
if (dstRegion.Y1 > dstRegion.Y2)
{
(region[2], region[3]) = (region[3], region[2]);
}
var bufferHandle = gd.BufferManager.CreateWithHandle(gd, RegionBufferSize, false);
gd.BufferManager.SetData<float>(bufferHandle, 0, region);
pipeline.SetUniformBuffers(stackalloc[] { new BufferAssignment(1, new BufferRange(bufferHandle, 0, RegionBufferSize)) });
Span<GAL.Viewport> viewports = stackalloc GAL.Viewport[1];
var rect = new Rectangle<float>(
MathF.Min(dstRegion.X1, dstRegion.X2),
MathF.Min(dstRegion.Y1, dstRegion.Y2),
MathF.Abs(dstRegion.X2 - dstRegion.X1),
MathF.Abs(dstRegion.Y2 - dstRegion.Y1));
viewports[0] = new GAL.Viewport(
rect,
ViewportSwizzle.PositiveX,
ViewportSwizzle.PositiveY,
ViewportSwizzle.PositiveZ,
ViewportSwizzle.PositiveW,
0f,
1f);
Span<Rectangle<int>> scissors = stackalloc Rectangle<int>[1];
pipeline.SetProgram(_programColorBlit);
pipeline.SetViewports(viewports, false);
pipeline.SetPrimitiveTopology(GAL.PrimitiveTopology.TriangleStrip);
pipeline.Draw(4, 1, 0, 0);
gd.BufferManager.Delete(bufferHandle);
}
public unsafe void ConvertI8ToI16(VulkanRenderer gd, CommandBufferScoped cbs, BufferHolder src, BufferHolder dst, int srcOffset, int size)
{
ChangeStride(gd, cbs, src, dst, srcOffset, size, 1, 2);
}
public unsafe void ChangeStride(VulkanRenderer gd, CommandBufferScoped cbs, BufferHolder src, BufferHolder dst, int srcOffset, int size, int stride, int newStride)
{
bool supportsUint8 = gd.Capabilities.SupportsShaderInt8;
int elems = size / stride;
int newSize = elems * newStride;
var srcBufferAuto = src.GetBuffer();
var dstBufferAuto = dst.GetBuffer();
var srcBuffer = srcBufferAuto.Get(cbs, srcOffset, size).Value;
var dstBuffer = dstBufferAuto.Get(cbs, 0, newSize).Value;
var access = supportsUint8 ? AccessFlags.ShaderWriteBit : AccessFlags.TransferWriteBit;
var stage = supportsUint8 ? PipelineStageFlags.ComputeShaderBit : PipelineStageFlags.TransferBit;
BufferHolder.InsertBufferBarrier(
gd,
cbs.CommandBuffer,
dstBuffer,
BufferHolder.DefaultAccessFlags,
access,
PipelineStageFlags.AllCommandsBit,
stage,
0,
newSize);
if (supportsUint8)
{
const int ParamsBufferSize = 16;
Span<int> shaderParams = stackalloc int[ParamsBufferSize / sizeof(int)];
shaderParams[0] = stride;
shaderParams[1] = newStride;
shaderParams[2] = size;
shaderParams[3] = srcOffset;
var bufferHandle = gd.BufferManager.CreateWithHandle(gd, ParamsBufferSize, false);
gd.BufferManager.SetData<int>(bufferHandle, 0, shaderParams);
_pipeline.SetCommandBuffer(cbs);
_pipeline.SetUniformBuffers(stackalloc[] { new BufferAssignment(0, new BufferRange(bufferHandle, 0, ParamsBufferSize)) });
Span<Auto<DisposableBuffer>> sbRanges = new Auto<DisposableBuffer>[2];
sbRanges[0] = srcBufferAuto;
sbRanges[1] = dstBufferAuto;
_pipeline.SetStorageBuffers(1, sbRanges);
_pipeline.SetProgram(_programStrideChange);
_pipeline.DispatchCompute(1, 1, 1);
gd.BufferManager.Delete(bufferHandle);
_pipeline.Finish(gd, cbs);
}
else
{
gd.Api.CmdFillBuffer(cbs.CommandBuffer, dstBuffer, 0, Vk.WholeSize, 0);
var bufferCopy = new BufferCopy[elems];
for (ulong i = 0; i < (ulong)elems; i++)
{
bufferCopy[i] = new BufferCopy((ulong)srcOffset + i * (ulong)stride, i * (ulong)newStride, (ulong)stride);
}
fixed (BufferCopy* pBufferCopy = bufferCopy)
{
gd.Api.CmdCopyBuffer(cbs.CommandBuffer, srcBuffer, dstBuffer, (uint)elems, pBufferCopy);
}
}
BufferHolder.InsertBufferBarrier(
gd,
cbs.CommandBuffer,
dstBuffer,
access,
BufferHolder.DefaultAccessFlags,
stage,
PipelineStageFlags.AllCommandsBit,
0,
newSize);
}
public unsafe void ConvertIndexBuffer(VulkanRenderer gd,
CommandBufferScoped cbs,
BufferHolder src,
BufferHolder dst,
IndexBufferPattern pattern,
int indexSize,
int srcOffset,
int indexCount)
{
// TODO: Support conversion with primitive restart enabled.
// TODO: Convert with a compute shader?
int convertedCount = pattern.GetConvertedCount(indexCount);
int outputIndexSize = 4;
var srcBuffer = src.GetBuffer().Get(cbs, srcOffset, indexCount * indexSize).Value;
var dstBuffer = dst.GetBuffer().Get(cbs, 0, convertedCount * outputIndexSize).Value;
gd.Api.CmdFillBuffer(cbs.CommandBuffer, dstBuffer, 0, Vk.WholeSize, 0);
var bufferCopy = new List<BufferCopy>();
int outputOffset = 0;
// Try to merge copies of adjacent indices to reduce copy count.
int sequenceStart = 0;
int sequenceLength = 0;
foreach (var index in pattern.GetIndexMapping(indexCount))
{
if (sequenceLength > 0)
{
if (index == sequenceStart + sequenceLength && indexSize == outputIndexSize)
{
sequenceLength++;
continue;
}
// Commit the copy so far.
bufferCopy.Add(new BufferCopy((ulong)(srcOffset + sequenceStart * indexSize), (ulong)outputOffset, (ulong)(indexSize * sequenceLength)));
outputOffset += outputIndexSize * sequenceLength;
}
sequenceStart = index;
sequenceLength = 1;
}
if (sequenceLength > 0)
{
// Commit final pending copy.
bufferCopy.Add(new BufferCopy((ulong)(srcOffset + sequenceStart * indexSize), (ulong)outputOffset, (ulong)(indexSize * sequenceLength)));
}
var bufferCopyArray = bufferCopy.ToArray();
BufferHolder.InsertBufferBarrier(
gd,
cbs.CommandBuffer,
dstBuffer,
BufferHolder.DefaultAccessFlags,
AccessFlags.TransferWriteBit,
PipelineStageFlags.AllCommandsBit,
PipelineStageFlags.TransferBit,
0,
convertedCount * outputIndexSize);
fixed (BufferCopy* pBufferCopy = bufferCopyArray)
{
gd.Api.CmdCopyBuffer(cbs.CommandBuffer, srcBuffer, dstBuffer, (uint)bufferCopyArray.Length, pBufferCopy);
}
BufferHolder.InsertBufferBarrier(
gd,
cbs.CommandBuffer,
dstBuffer,
AccessFlags.TransferWriteBit,
BufferHolder.DefaultAccessFlags,
PipelineStageFlags.TransferBit,
PipelineStageFlags.AllCommandsBit,
0,
convertedCount * outputIndexSize);
}
public void CopyMSToNonMS(VulkanRenderer gd, CommandBufferScoped cbs, TextureView src, TextureView dst, int srcLayer, int dstLayer, int depth)
{
const int ParamsBufferSize = 16;
Span<int> shaderParams = stackalloc int[ParamsBufferSize / sizeof(int)];
int samples = src.Info.Samples;
// X and Y are the expected texture samples.
// Z and W are the actual texture samples used.
// They may differ if the GPU does not support the samples count requested and we had to use a lower amount.
(shaderParams[0], shaderParams[1]) = GetSampleCountXYLog2(samples);
(shaderParams[2], shaderParams[3]) = GetSampleCountXYLog2((int)TextureStorage.ConvertToSampleCountFlags(gd.Capabilities.SupportedSampleCounts, (uint)samples));
var bufferHandle = gd.BufferManager.CreateWithHandle(gd, ParamsBufferSize, false);
gd.BufferManager.SetData<int>(bufferHandle, 0, shaderParams);
TextureView.InsertImageBarrier(
gd.Api,
cbs.CommandBuffer,
src.GetImage().Get(cbs).Value,
TextureStorage.DefaultAccessMask,
AccessFlags.ShaderReadBit,
PipelineStageFlags.AllCommandsBit,
PipelineStageFlags.ComputeShaderBit,
ImageAspectFlags.ColorBit,
src.FirstLayer + srcLayer,
src.FirstLevel,
depth,
1);
_pipeline.SetCommandBuffer(cbs);
_pipeline.SetProgram(_programColorCopyToNonMs);
var format = GetFormat(src.Info.BytesPerPixel);
int dispatchX = (dst.Info.Width + 31) / 32;
int dispatchY = (dst.Info.Height + 31) / 32;
_pipeline.SetUniformBuffers(stackalloc[] { new BufferAssignment(0, new BufferRange(bufferHandle, 0, ParamsBufferSize)) });
if (src.Info.Target == Target.Texture2DMultisampleArray ||
dst.Info.Target == Target.Texture2DMultisampleArray)
{
for (int z = 0; z < depth; z++)
{
var srcView = Create2DLayerView(src, srcLayer + z, format);
var dstView = Create2DLayerView(dst, dstLayer + z);
_pipeline.SetTextureAndSampler(ShaderStage.Compute, 0, srcView, null);
_pipeline.SetImage(0, dstView, format);
_pipeline.DispatchCompute(dispatchX, dispatchY, 1);
srcView.Release();
dstView.Release();
}
}
else
{
var srcView = Create2DLayerView(src, srcLayer, format);
_pipeline.SetTextureAndSampler(ShaderStage.Compute, 0, srcView, null);
_pipeline.SetImage(0, dst, format);
_pipeline.DispatchCompute(dispatchX, dispatchY, 1);
srcView.Release();
}
gd.BufferManager.Delete(bufferHandle);
_pipeline.Finish(gd, cbs);
TextureView.InsertImageBarrier(
gd.Api,
cbs.CommandBuffer,
dst.GetImage().Get(cbs).Value,
AccessFlags.ShaderWriteBit,
TextureStorage.DefaultAccessMask,
PipelineStageFlags.ComputeShaderBit,
PipelineStageFlags.AllCommandsBit,
ImageAspectFlags.ColorBit,
dst.FirstLayer + dstLayer,
dst.FirstLevel,
depth,
1);
}
public void CopyNonMSToMS(VulkanRenderer gd, CommandBufferScoped cbs, TextureView src, TextureView dst, int srcLayer, int dstLayer, int depth)
{
const int ParamsBufferSize = 16;
Span<int> shaderParams = stackalloc int[ParamsBufferSize / sizeof(int)];
int samples = dst.Info.Samples;
// X and Y are the expected texture samples.
// Z and W are the actual texture samples used.
// They may differ if the GPU does not support the samples count requested and we had to use a lower amount.
(shaderParams[0], shaderParams[1]) = GetSampleCountXYLog2(samples);
(shaderParams[2], shaderParams[3]) = GetSampleCountXYLog2((int)TextureStorage.ConvertToSampleCountFlags(gd.Capabilities.SupportedSampleCounts, (uint)samples));
var bufferHandle = gd.BufferManager.CreateWithHandle(gd, ParamsBufferSize, false);
gd.BufferManager.SetData<int>(bufferHandle, 0, shaderParams);
TextureView.InsertImageBarrier(
gd.Api,
cbs.CommandBuffer,
src.GetImage().Get(cbs).Value,
TextureStorage.DefaultAccessMask,
AccessFlags.ShaderReadBit,
PipelineStageFlags.AllCommandsBit,
PipelineStageFlags.FragmentShaderBit,
ImageAspectFlags.ColorBit,
src.FirstLayer + srcLayer,
src.FirstLevel,
depth,
1);
_pipeline.SetCommandBuffer(cbs);
_pipeline.SetProgram(_programColorDrawToMs);
Span<GAL.Viewport> viewports = stackalloc GAL.Viewport[1];
var rect = new Rectangle<float>(0, 0, dst.Width, dst.Height);
viewports[0] = new GAL.Viewport(
rect,
ViewportSwizzle.PositiveX,
ViewportSwizzle.PositiveY,
ViewportSwizzle.PositiveZ,
ViewportSwizzle.PositiveW,
0f,
1f);
Span<Rectangle<int>> scissors = stackalloc Rectangle<int>[1];
scissors[0] = new Rectangle<int>(0, 0, dst.Width, dst.Height);
_pipeline.SetRenderTargetColorMasks(new uint[] { 0xf });
_pipeline.SetScissors(scissors);
_pipeline.SetViewports(viewports, false);
_pipeline.SetPrimitiveTopology(GAL.PrimitiveTopology.TriangleStrip);
_pipeline.SetUniformBuffers(stackalloc[] { new BufferAssignment(0, new BufferRange(bufferHandle, 0, ParamsBufferSize)) });
var format = GetFormat(src.Info.BytesPerPixel);
var vkFormat = FormatTable.GetFormat(format);
if (src.Info.Target == Target.Texture2DMultisampleArray ||
dst.Info.Target == Target.Texture2DMultisampleArray)
{
for (int z = 0; z < depth; z++)
{
var srcView = Create2DLayerView(src, srcLayer + z, format);
var dstView = Create2DLayerView(dst, dstLayer + z);
_pipeline.SetTextureAndSampler(ShaderStage.Fragment, 0, srcView, null);
_pipeline.SetRenderTarget(
((TextureView)dstView).GetView(format).GetImageViewForAttachment(),
(uint)dst.Width,
(uint)dst.Height,
(uint)samples,
false,
vkFormat);
_pipeline.Draw(4, 1, 0, 0);
srcView.Release();
dstView.Release();
}
}
else
{
var srcView = Create2DLayerView(src, srcLayer, format);
_pipeline.SetTextureAndSampler(ShaderStage.Fragment, 0, srcView, null);
_pipeline.SetRenderTarget(
dst.GetView(format).GetImageViewForAttachment(),
(uint)dst.Width,
(uint)dst.Height,
(uint)samples,
false,
vkFormat);
_pipeline.Draw(4, 1, 0, 0);
srcView.Release();
}
gd.BufferManager.Delete(bufferHandle);
_pipeline.Finish(gd, cbs);
TextureView.InsertImageBarrier(
gd.Api,
cbs.CommandBuffer,
dst.GetImage().Get(cbs).Value,
AccessFlags.ColorAttachmentWriteBit,
TextureStorage.DefaultAccessMask,
PipelineStageFlags.FragmentShaderBit,
PipelineStageFlags.AllCommandsBit,
ImageAspectFlags.ColorBit,
dst.FirstLayer + dstLayer,
dst.FirstLevel,
depth,
1);
}
private static (int, int) GetSampleCountXYLog2(int samples)
{
int samplesInXLog2 = 0;
int samplesInYLog2 = 0;
switch (samples)
{
case 2: // 2x1
samplesInXLog2 = 1;
break;
case 4: // 2x2
samplesInXLog2 = 1;
samplesInYLog2 = 1;
break;
case 8: // 4x2
samplesInXLog2 = 2;
samplesInYLog2 = 1;
break;
case 16: // 4x4
samplesInXLog2 = 2;
samplesInYLog2 = 2;
break;
case 32: // 8x4
samplesInXLog2 = 3;
samplesInYLog2 = 2;
break;
case 64: // 8x8
samplesInXLog2 = 3;
samplesInYLog2 = 3;
break;
}
return (samplesInXLog2, samplesInYLog2);
}
private static ITexture Create2DLayerView(TextureView from, int layer, GAL.Format? format = null)
{
var target = from.Info.Target switch
{
Target.Texture1DArray => Target.Texture1D,
Target.Texture2DArray => Target.Texture2D,
Target.Texture2DMultisampleArray => Target.Texture2DMultisample,
_ => from.Info.Target
};
var info = new TextureCreateInfo(
from.Info.Width,
from.Info.Height,
from.Info.Depth,
1,
from.Info.Samples,
from.Info.BlockWidth,
from.Info.BlockHeight,
from.Info.BytesPerPixel,
format ?? from.Info.Format,
from.Info.DepthStencilMode,
target,
from.Info.SwizzleR,
from.Info.SwizzleG,
from.Info.SwizzleB,
from.Info.SwizzleA);
return from.CreateView(info, layer, 0);
}
private static GAL.Format GetFormat(int bytesPerPixel)
{
return bytesPerPixel switch
{
1 => GAL.Format.R8Uint,
2 => GAL.Format.R16Uint,
4 => GAL.Format.R32Uint,
8 => GAL.Format.R32G32Uint,
16 => GAL.Format.R32G32B32A32Uint,
_ => throw new ArgumentException($"Invalid bytes per pixel {bytesPerPixel}.")
};
}
public void ConvertIndexBufferIndirect(
VulkanRenderer gd,
CommandBufferScoped cbs,
BufferHolder srcIndirectBuffer,
BufferHolder dstIndirectBuffer,
BufferRange drawCountBuffer,
BufferHolder srcIndexBuffer,
BufferHolder dstIndexBuffer,
IndexBufferPattern pattern,
int indexSize,
int srcIndexBufferOffset,
int srcIndexBufferSize,
int srcIndirectBufferOffset,
bool hasDrawCount,
int maxDrawCount,
int indirectDataStride)
{
// TODO: Support conversion with primitive restart enabled.
BufferRange drawCountBufferAligned = new BufferRange(
drawCountBuffer.Handle,
drawCountBuffer.Offset & ~(UniformBufferAlignment - 1),
UniformBufferAlignment);
int indirectDataSize = maxDrawCount * indirectDataStride;
int indexCount = srcIndexBufferSize / indexSize;
int primitivesCount = pattern.GetPrimitiveCount(indexCount);
int convertedCount = pattern.GetConvertedCount(indexCount);
int outputIndexSize = 4;
var srcBuffer = srcIndexBuffer.GetBuffer().Get(cbs, srcIndexBufferOffset, indexCount * indexSize).Value;
var dstBuffer = dstIndexBuffer.GetBuffer().Get(cbs, 0, convertedCount * outputIndexSize).Value;
const int ParamsBufferSize = 24 * sizeof(int);
const int ParamsIndirectDispatchOffset = 16 * sizeof(int);
const int ParamsIndirectDispatchSize = 3 * sizeof(int);
Span<int> shaderParams = stackalloc int[ParamsBufferSize / sizeof(int)];
shaderParams[8] = pattern.PrimitiveVertices;
shaderParams[9] = pattern.PrimitiveVerticesOut;
shaderParams[10] = indexSize;
shaderParams[11] = outputIndexSize;
shaderParams[12] = pattern.BaseIndex;
shaderParams[13] = pattern.IndexStride;
shaderParams[14] = srcIndexBufferOffset;
shaderParams[15] = primitivesCount;
shaderParams[16] = 1;
shaderParams[17] = 1;
shaderParams[18] = 1;
shaderParams[19] = hasDrawCount ? 1 : 0;
shaderParams[20] = maxDrawCount;
shaderParams[21] = (drawCountBuffer.Offset & (UniformBufferAlignment - 1)) / 4;
shaderParams[22] = indirectDataStride / 4;
shaderParams[23] = srcIndirectBufferOffset / 4;
pattern.OffsetIndex.CopyTo(shaderParams.Slice(0, pattern.OffsetIndex.Length));
var patternBufferHandle = gd.BufferManager.CreateWithHandle(gd, ParamsBufferSize, false, out var patternBuffer);
var patternBufferAuto = patternBuffer.GetBuffer();
gd.BufferManager.SetData<int>(patternBufferHandle, 0, shaderParams);
_pipeline.SetCommandBuffer(cbs);
BufferHolder.InsertBufferBarrier(
gd,
cbs.CommandBuffer,
srcIndirectBuffer.GetBuffer().Get(cbs, srcIndirectBufferOffset, indirectDataSize).Value,
BufferHolder.DefaultAccessFlags,
AccessFlags.ShaderReadBit,
PipelineStageFlags.AllCommandsBit,
PipelineStageFlags.ComputeShaderBit,
srcIndirectBufferOffset,
indirectDataSize);
_pipeline.SetUniformBuffers(stackalloc[] { new BufferAssignment(0, drawCountBufferAligned) });
_pipeline.SetStorageBuffers(1, new[] { srcIndirectBuffer.GetBuffer(), dstIndirectBuffer.GetBuffer(), patternBuffer.GetBuffer() });
_pipeline.SetProgram(_programConvertIndirectData);
_pipeline.DispatchCompute(1, 1, 1);
BufferHolder.InsertBufferBarrier(
gd,
cbs.CommandBuffer,
patternBufferAuto.Get(cbs, ParamsIndirectDispatchOffset, ParamsIndirectDispatchSize).Value,
AccessFlags.ShaderWriteBit,
AccessFlags.IndirectCommandReadBit,
PipelineStageFlags.ComputeShaderBit,
PipelineStageFlags.DrawIndirectBit,
ParamsIndirectDispatchOffset,
ParamsIndirectDispatchSize);
BufferHolder.InsertBufferBarrier(
gd,
cbs.CommandBuffer,
dstBuffer,
BufferHolder.DefaultAccessFlags,
AccessFlags.TransferWriteBit,
PipelineStageFlags.AllCommandsBit,
PipelineStageFlags.TransferBit,
0,
convertedCount * outputIndexSize);
_pipeline.SetUniformBuffers(stackalloc[] { new BufferAssignment(0, new BufferRange(patternBufferHandle, 0, ParamsBufferSize)) });
_pipeline.SetStorageBuffers(1, new[] { srcIndexBuffer.GetBuffer(), dstIndexBuffer.GetBuffer() });
_pipeline.SetProgram(_programConvertIndexBuffer);
_pipeline.DispatchComputeIndirect(patternBufferAuto, ParamsIndirectDispatchOffset);
BufferHolder.InsertBufferBarrier(
gd,
cbs.CommandBuffer,
dstBuffer,
AccessFlags.TransferWriteBit,
BufferHolder.DefaultAccessFlags,
PipelineStageFlags.TransferBit,
PipelineStageFlags.AllCommandsBit,
0,
convertedCount * outputIndexSize);
gd.BufferManager.Delete(patternBufferHandle);
_pipeline.Finish(gd, cbs);
}
protected virtual void Dispose(bool disposing)
{
if (disposing)
{
_programColorBlitClearAlpha.Dispose();
_programColorBlit.Dispose();
_programColorClearF.Dispose();
_programColorClearSI.Dispose();
_programColorClearUI.Dispose();
_programStrideChange.Dispose();
_programConvertIndexBuffer.Dispose();
_programConvertIndirectData.Dispose();
_programColorCopyToNonMs.Dispose();
_programColorDrawToMs.Dispose();
_samplerNearest.Dispose();
_samplerLinear.Dispose();
_pipeline.Dispose();
}
}
public void Dispose()
{
Dispose(true);
}
}
}