R/Ryujinx.Graphics.Vulkan/PipelineBase.cs
riperiperi 9f1cf6458c
Vulkan: Migrate buffers between memory types to improve GPU performance (#4540)
* Initial implementation of migration between memory heaps

- Missing OOM handling
- Missing `_map` data safety when remapping
  - Copy may not have completed yet (needs some kind of fence)
  - Map may be unmapped before it is done being used. (needs scoped access)
- SSBO accesses are all "writes" - maybe pass info in another way.
- Missing keeping map type when resizing buffers (should this be done?)

* Ensure migrated data is in place before flushing.

* Fix issue where old waitable would be signalled.

- There is a real issue where existing Auto<> references need to be replaced.

* Swap bound Auto<> instances when swapping buffer backing

* Fix conversion buffers

* Don't try move buffers if the host has shared memory.

* Make GPU methods return PinnedSpan with scope

* Storage Hint

* Fix stupidity

* Fix rebase

* Tweak rules

Attempt to sidestep BOTW slowdown

* Remove line

* Migrate only when command buffers flush

* Change backing swap log to debug

* Address some feedback

* Disallow backing swap when the flush lock is held by the current thread

* Make PinnedSpan from ReadOnlySpan explicitly unsafe

* Fix some small issues

- Index buffer swap fixed
- Allocate DeviceLocal buffers using a separate block list to images.

* Remove alternative flags

* Address feedback
2023-03-19 17:56:48 -03:00

1733 lines
62 KiB
C#

using Ryujinx.Common;
using Ryujinx.Graphics.GAL;
using Ryujinx.Graphics.Shader;
using Silk.NET.Vulkan;
using System;
using System.Linq;
using System.Numerics;
using System.Runtime.CompilerServices;
using System.Runtime.InteropServices;
namespace Ryujinx.Graphics.Vulkan
{
class PipelineBase : IDisposable
{
public const int DescriptorSetLayouts = 4;
public const int UniformSetIndex = 0;
public const int StorageSetIndex = 1;
public const int TextureSetIndex = 2;
public const int ImageSetIndex = 3;
protected readonly VulkanRenderer Gd;
protected readonly Device Device;
public readonly PipelineCache PipelineCache;
public readonly AutoFlushCounter AutoFlush;
protected PipelineDynamicState DynamicState;
private PipelineState _newState;
private bool _stateDirty;
private GAL.PrimitiveTopology _topology;
private ulong _currentPipelineHandle;
protected Auto<DisposablePipeline> Pipeline;
protected PipelineBindPoint Pbp;
protected CommandBufferScoped Cbs;
protected CommandBufferScoped? PreloadCbs;
protected CommandBuffer CommandBuffer;
public CommandBufferScoped CurrentCommandBuffer => Cbs;
private ShaderCollection _program;
private Vector4<float>[] _renderScale = new Vector4<float>[73];
private int _fragmentScaleCount;
protected FramebufferParams FramebufferParams;
private Auto<DisposableFramebuffer> _framebuffer;
private Auto<DisposableRenderPass> _renderPass;
private int _writtenAttachmentCount;
private bool _framebufferUsingColorWriteMask;
private ITexture[] _preMaskColors;
private ITexture _preMaskDepthStencil;
private readonly DescriptorSetUpdater _descriptorSetUpdater;
private IndexBufferState _indexBuffer;
private IndexBufferPattern _indexBufferPattern;
private readonly BufferState[] _transformFeedbackBuffers;
private readonly VertexBufferState[] _vertexBuffers;
private ulong _vertexBuffersDirty;
protected Rectangle<int> ClearScissor;
public SupportBufferUpdater SupportBufferUpdater;
public IndexBufferPattern QuadsToTrisPattern;
public IndexBufferPattern TriFanToTrisPattern;
private bool _needsIndexBufferRebind;
private bool _needsTransformFeedbackBuffersRebind;
private bool _tfEnabled;
private bool _tfActive;
private PipelineColorBlendAttachmentState[] _storedBlend;
public ulong DrawCount { get; private set; }
public bool RenderPassActive { get; private set; }
public unsafe PipelineBase(VulkanRenderer gd, Device device)
{
Gd = gd;
Device = device;
AutoFlush = new AutoFlushCounter();
var pipelineCacheCreateInfo = new PipelineCacheCreateInfo()
{
SType = StructureType.PipelineCacheCreateInfo
};
gd.Api.CreatePipelineCache(device, pipelineCacheCreateInfo, null, out PipelineCache).ThrowOnError();
_descriptorSetUpdater = new DescriptorSetUpdater(gd, this);
_transformFeedbackBuffers = new BufferState[Constants.MaxTransformFeedbackBuffers];
_vertexBuffers = new VertexBufferState[Constants.MaxVertexBuffers + 1];
const int EmptyVbSize = 16;
using var emptyVb = gd.BufferManager.Create(gd, EmptyVbSize);
emptyVb.SetData(0, new byte[EmptyVbSize]);
_vertexBuffers[0] = new VertexBufferState(emptyVb.GetBuffer(), 0, 0, EmptyVbSize, 0);
_vertexBuffersDirty = ulong.MaxValue >> (64 - _vertexBuffers.Length);
ClearScissor = new Rectangle<int>(0, 0, 0xffff, 0xffff);
var defaultScale = new Vector4<float> { X = 1f, Y = 0f, Z = 0f, W = 0f };
new Span<Vector4<float>>(_renderScale).Fill(defaultScale);
_storedBlend = new PipelineColorBlendAttachmentState[Constants.MaxRenderTargets];
_newState.Initialize();
}
public void Initialize()
{
_descriptorSetUpdater.Initialize();
SupportBufferUpdater = new SupportBufferUpdater(Gd);
SupportBufferUpdater.UpdateRenderScale(_renderScale, 0, SupportBuffer.RenderScaleMaxCount);
QuadsToTrisPattern = new IndexBufferPattern(Gd, 4, 6, 0, new[] { 0, 1, 2, 0, 2, 3 }, 4, false);
TriFanToTrisPattern = new IndexBufferPattern(Gd, 3, 3, 2, new[] { int.MinValue, -1, 0 }, 1, true);
}
public unsafe void Barrier()
{
MemoryBarrier memoryBarrier = new MemoryBarrier()
{
SType = StructureType.MemoryBarrier,
SrcAccessMask = AccessFlags.MemoryReadBit | AccessFlags.MemoryWriteBit,
DstAccessMask = AccessFlags.MemoryReadBit | AccessFlags.MemoryWriteBit
};
Gd.Api.CmdPipelineBarrier(
CommandBuffer,
PipelineStageFlags.FragmentShaderBit,
PipelineStageFlags.FragmentShaderBit,
0,
1,
memoryBarrier,
0,
null,
0,
null);
}
public void ComputeBarrier()
{
MemoryBarrier memoryBarrier = new MemoryBarrier()
{
SType = StructureType.MemoryBarrier,
SrcAccessMask = AccessFlags.MemoryReadBit | AccessFlags.MemoryWriteBit,
DstAccessMask = AccessFlags.MemoryReadBit | AccessFlags.MemoryWriteBit
};
Gd.Api.CmdPipelineBarrier(
CommandBuffer,
PipelineStageFlags.ComputeShaderBit,
PipelineStageFlags.AllCommandsBit,
0,
1,
new ReadOnlySpan<MemoryBarrier>(memoryBarrier),
0,
ReadOnlySpan<BufferMemoryBarrier>.Empty,
0,
ReadOnlySpan<ImageMemoryBarrier>.Empty);
}
public void BeginTransformFeedback(GAL.PrimitiveTopology topology)
{
_tfEnabled = true;
}
public void ClearBuffer(BufferHandle destination, int offset, int size, uint value)
{
EndRenderPass();
var dst = Gd.BufferManager.GetBuffer(CommandBuffer, destination, offset, size, true).Get(Cbs, offset, size).Value;
BufferHolder.InsertBufferBarrier(
Gd,
Cbs.CommandBuffer,
dst,
BufferHolder.DefaultAccessFlags,
AccessFlags.TransferWriteBit,
PipelineStageFlags.AllCommandsBit,
PipelineStageFlags.TransferBit,
offset,
size);
Gd.Api.CmdFillBuffer(CommandBuffer, dst, (ulong)offset, (ulong)size, value);
BufferHolder.InsertBufferBarrier(
Gd,
Cbs.CommandBuffer,
dst,
AccessFlags.TransferWriteBit,
BufferHolder.DefaultAccessFlags,
PipelineStageFlags.TransferBit,
PipelineStageFlags.AllCommandsBit,
offset,
size);
}
public unsafe void ClearRenderTargetColor(int index, int layer, int layerCount, ColorF color)
{
if (FramebufferParams == null || !FramebufferParams.IsValidColorAttachment(index))
{
return;
}
if (_renderPass == null)
{
CreateRenderPass();
}
BeginRenderPass();
var clearValue = new ClearValue(new ClearColorValue(color.Red, color.Green, color.Blue, color.Alpha));
var attachment = new ClearAttachment(ImageAspectFlags.ColorBit, (uint)index, clearValue);
var clearRect = FramebufferParams.GetClearRect(ClearScissor, layer, layerCount);
Gd.Api.CmdClearAttachments(CommandBuffer, 1, &attachment, 1, &clearRect);
}
public unsafe void ClearRenderTargetDepthStencil(int layer, int layerCount, float depthValue, bool depthMask, int stencilValue, int stencilMask)
{
// TODO: Use stencilMask (fully)
if (FramebufferParams == null || !FramebufferParams.HasDepthStencil)
{
return;
}
if (_renderPass == null)
{
CreateRenderPass();
}
BeginRenderPass();
var clearValue = new ClearValue(null, new ClearDepthStencilValue(depthValue, (uint)stencilValue));
var flags = depthMask ? ImageAspectFlags.DepthBit : 0;
if (stencilMask != 0)
{
flags |= ImageAspectFlags.StencilBit;
}
var attachment = new ClearAttachment(flags, 0, clearValue);
var clearRect = FramebufferParams.GetClearRect(ClearScissor, layer, layerCount);
Gd.Api.CmdClearAttachments(CommandBuffer, 1, &attachment, 1, &clearRect);
}
public unsafe void CommandBufferBarrier()
{
MemoryBarrier memoryBarrier = new MemoryBarrier()
{
SType = StructureType.MemoryBarrier,
SrcAccessMask = BufferHolder.DefaultAccessFlags,
DstAccessMask = AccessFlags.IndirectCommandReadBit
};
Gd.Api.CmdPipelineBarrier(
CommandBuffer,
PipelineStageFlags.AllCommandsBit,
PipelineStageFlags.DrawIndirectBit,
0,
1,
memoryBarrier,
0,
null,
0,
null);
}
public void CopyBuffer(BufferHandle source, BufferHandle destination, int srcOffset, int dstOffset, int size)
{
EndRenderPass();
var src = Gd.BufferManager.GetBuffer(CommandBuffer, source, srcOffset, size, false);
var dst = Gd.BufferManager.GetBuffer(CommandBuffer, destination, dstOffset, size, true);
BufferHolder.Copy(Gd, Cbs, src, dst, srcOffset, dstOffset, size);
}
public void DirtyVertexBuffer(Auto<DisposableBuffer> buffer)
{
for (int i = 0; i < _vertexBuffers.Length; i++)
{
if (_vertexBuffers[i].BoundEquals(buffer))
{
_vertexBuffersDirty |= 1UL << i;
}
}
}
public void DirtyIndexBuffer(Auto<DisposableBuffer> buffer)
{
if (_indexBuffer.BoundEquals(buffer))
{
_needsIndexBufferRebind = true;
}
}
public void DispatchCompute(int groupsX, int groupsY, int groupsZ)
{
if (!_program.IsLinked)
{
return;
}
EndRenderPass();
RecreatePipelineIfNeeded(PipelineBindPoint.Compute);
Gd.Api.CmdDispatch(CommandBuffer, (uint)groupsX, (uint)groupsY, (uint)groupsZ);
}
public void DispatchComputeIndirect(Auto<DisposableBuffer> indirectBuffer, int indirectBufferOffset)
{
if (!_program.IsLinked)
{
return;
}
EndRenderPass();
RecreatePipelineIfNeeded(PipelineBindPoint.Compute);
Gd.Api.CmdDispatchIndirect(CommandBuffer, indirectBuffer.Get(Cbs, indirectBufferOffset, 12).Value, (ulong)indirectBufferOffset);
}
public void Draw(int vertexCount, int instanceCount, int firstVertex, int firstInstance)
{
if (!_program.IsLinked)
{
return;
}
RecreatePipelineIfNeeded(PipelineBindPoint.Graphics);
BeginRenderPass();
DrawCount++;
if (Gd.TopologyUnsupported(_topology))
{
// Temporarily bind a conversion pattern as an index buffer.
_needsIndexBufferRebind = true;
IndexBufferPattern pattern = _topology switch
{
GAL.PrimitiveTopology.Quads => QuadsToTrisPattern,
GAL.PrimitiveTopology.TriangleFan or
GAL.PrimitiveTopology.Polygon => TriFanToTrisPattern,
_ => throw new NotSupportedException($"Unsupported topology: {_topology}")
};
BufferHandle handle = pattern.GetRepeatingBuffer(vertexCount, out int indexCount);
var buffer = Gd.BufferManager.GetBuffer(CommandBuffer, handle, false);
Gd.Api.CmdBindIndexBuffer(CommandBuffer, buffer.Get(Cbs, 0, indexCount * sizeof(int)).Value, 0, Silk.NET.Vulkan.IndexType.Uint32);
BeginRenderPass(); // May have been interrupted to set buffer data.
ResumeTransformFeedbackInternal();
Gd.Api.CmdDrawIndexed(CommandBuffer, (uint)indexCount, (uint)instanceCount, 0, firstVertex, (uint)firstInstance);
}
else
{
ResumeTransformFeedbackInternal();
Gd.Api.CmdDraw(CommandBuffer, (uint)vertexCount, (uint)instanceCount, (uint)firstVertex, (uint)firstInstance);
}
}
private void UpdateIndexBufferPattern()
{
IndexBufferPattern pattern = null;
if (Gd.TopologyUnsupported(_topology))
{
pattern = _topology switch
{
GAL.PrimitiveTopology.Quads => QuadsToTrisPattern,
GAL.PrimitiveTopology.TriangleFan or
GAL.PrimitiveTopology.Polygon => TriFanToTrisPattern,
_ => throw new NotSupportedException($"Unsupported topology: {_topology}")
};
}
if (_indexBufferPattern != pattern)
{
_indexBufferPattern = pattern;
_needsIndexBufferRebind = true;
}
}
public void DrawIndexed(int indexCount, int instanceCount, int firstIndex, int firstVertex, int firstInstance)
{
if (!_program.IsLinked)
{
return;
}
UpdateIndexBufferPattern();
RecreatePipelineIfNeeded(PipelineBindPoint.Graphics);
BeginRenderPass();
DrawCount++;
if (_indexBufferPattern != null)
{
// Convert the index buffer into a supported topology.
IndexBufferPattern pattern = _indexBufferPattern;
int convertedCount = pattern.GetConvertedCount(indexCount);
if (_needsIndexBufferRebind)
{
_indexBuffer.BindConvertedIndexBuffer(Gd, Cbs, firstIndex, indexCount, convertedCount, pattern);
_needsIndexBufferRebind = false;
}
BeginRenderPass(); // May have been interrupted to set buffer data.
ResumeTransformFeedbackInternal();
Gd.Api.CmdDrawIndexed(CommandBuffer, (uint)convertedCount, (uint)instanceCount, 0, firstVertex, (uint)firstInstance);
}
else
{
ResumeTransformFeedbackInternal();
Gd.Api.CmdDrawIndexed(CommandBuffer, (uint)indexCount, (uint)instanceCount, (uint)firstIndex, firstVertex, (uint)firstInstance);
}
}
public void DrawIndexedIndirect(BufferRange indirectBuffer)
{
if (!_program.IsLinked)
{
return;
}
UpdateIndexBufferPattern();
RecreatePipelineIfNeeded(PipelineBindPoint.Graphics);
BeginRenderPass();
DrawCount++;
if (_indexBufferPattern != null)
{
// Convert the index buffer into a supported topology.
IndexBufferPattern pattern = _indexBufferPattern;
Auto<DisposableBuffer> indirectBufferAuto = _indexBuffer.BindConvertedIndexBufferIndirect(
Gd,
Cbs,
indirectBuffer,
BufferRange.Empty,
pattern,
false,
1,
indirectBuffer.Size);
_needsIndexBufferRebind = false;
BeginRenderPass(); // May have been interrupted to set buffer data.
ResumeTransformFeedbackInternal();
Gd.Api.CmdDrawIndexedIndirect(CommandBuffer, indirectBufferAuto.Get(Cbs, 0, indirectBuffer.Size).Value, 0, 1, (uint)indirectBuffer.Size);
}
else
{
var buffer = Gd.BufferManager
.GetBuffer(CommandBuffer, indirectBuffer.Handle, indirectBuffer.Offset, indirectBuffer.Size, false)
.Get(Cbs, indirectBuffer.Offset, indirectBuffer.Size).Value;
ResumeTransformFeedbackInternal();
Gd.Api.CmdDrawIndexedIndirect(CommandBuffer, buffer, (ulong)indirectBuffer.Offset, 1, (uint)indirectBuffer.Size);
}
}
public void DrawIndexedIndirectCount(BufferRange indirectBuffer, BufferRange parameterBuffer, int maxDrawCount, int stride)
{
if (!_program.IsLinked)
{
return;
}
UpdateIndexBufferPattern();
RecreatePipelineIfNeeded(PipelineBindPoint.Graphics);
BeginRenderPass();
DrawCount++;
var countBuffer = Gd.BufferManager
.GetBuffer(CommandBuffer, parameterBuffer.Handle, parameterBuffer.Offset, parameterBuffer.Size, false)
.Get(Cbs, parameterBuffer.Offset, parameterBuffer.Size).Value;
if (_indexBufferPattern != null)
{
// Convert the index buffer into a supported topology.
IndexBufferPattern pattern = _indexBufferPattern;
Auto<DisposableBuffer> indirectBufferAuto = _indexBuffer.BindConvertedIndexBufferIndirect(
Gd,
Cbs,
indirectBuffer,
parameterBuffer,
pattern,
true,
maxDrawCount,
stride);
_needsIndexBufferRebind = false;
BeginRenderPass(); // May have been interrupted to set buffer data.
ResumeTransformFeedbackInternal();
if (Gd.Capabilities.SupportsIndirectParameters)
{
Gd.DrawIndirectCountApi.CmdDrawIndexedIndirectCount(
CommandBuffer,
indirectBufferAuto.Get(Cbs, 0, indirectBuffer.Size).Value,
0,
countBuffer,
(ulong)parameterBuffer.Offset,
(uint)maxDrawCount,
(uint)stride);
}
else
{
// This is also fine because the indirect data conversion always zeros
// the entries that are past the current draw count.
Gd.Api.CmdDrawIndexedIndirect(
CommandBuffer,
indirectBufferAuto.Get(Cbs, 0, indirectBuffer.Size).Value,
0,
(uint)maxDrawCount,
(uint)stride);
}
}
else
{
var buffer = Gd.BufferManager
.GetBuffer(CommandBuffer, indirectBuffer.Handle, indirectBuffer.Offset, indirectBuffer.Size, false)
.Get(Cbs, indirectBuffer.Offset, indirectBuffer.Size).Value;
ResumeTransformFeedbackInternal();
if (Gd.Capabilities.SupportsIndirectParameters)
{
Gd.DrawIndirectCountApi.CmdDrawIndexedIndirectCount(
CommandBuffer,
buffer,
(ulong)indirectBuffer.Offset,
countBuffer,
(ulong)parameterBuffer.Offset,
(uint)maxDrawCount,
(uint)stride);
}
else
{
// Not fully correct, but we can't do much better if the host does not support indirect count.
Gd.Api.CmdDrawIndexedIndirect(
CommandBuffer,
buffer,
(ulong)indirectBuffer.Offset,
(uint)maxDrawCount,
(uint)stride);
}
}
}
public void DrawIndirect(BufferRange indirectBuffer)
{
if (!_program.IsLinked)
{
return;
}
// TODO: Support quads and other unsupported topologies.
RecreatePipelineIfNeeded(PipelineBindPoint.Graphics);
BeginRenderPass();
ResumeTransformFeedbackInternal();
DrawCount++;
var buffer = Gd.BufferManager
.GetBuffer(CommandBuffer, indirectBuffer.Handle, indirectBuffer.Offset, indirectBuffer.Size, false)
.Get(Cbs, indirectBuffer.Offset, indirectBuffer.Size).Value;
Gd.Api.CmdDrawIndirect(CommandBuffer, buffer, (ulong)indirectBuffer.Offset, 1, (uint)indirectBuffer.Size);
}
public void DrawIndirectCount(BufferRange indirectBuffer, BufferRange parameterBuffer, int maxDrawCount, int stride)
{
if (!Gd.Capabilities.SupportsIndirectParameters)
{
// TODO: Fallback for when this is not supported.
throw new NotSupportedException();
}
if (!_program.IsLinked)
{
return;
}
// TODO: Support quads and other unsupported topologies.
RecreatePipelineIfNeeded(PipelineBindPoint.Graphics);
BeginRenderPass();
ResumeTransformFeedbackInternal();
DrawCount++;
var buffer = Gd.BufferManager
.GetBuffer(CommandBuffer, indirectBuffer.Handle, indirectBuffer.Offset, indirectBuffer.Size, false)
.Get(Cbs, indirectBuffer.Offset, indirectBuffer.Size).Value;
var countBuffer = Gd.BufferManager
.GetBuffer(CommandBuffer, parameterBuffer.Handle, parameterBuffer.Offset, parameterBuffer.Size, false)
.Get(Cbs, parameterBuffer.Offset, parameterBuffer.Size).Value;
Gd.DrawIndirectCountApi.CmdDrawIndirectCount(
CommandBuffer,
buffer,
(ulong)indirectBuffer.Offset,
countBuffer,
(ulong)parameterBuffer.Offset,
(uint)maxDrawCount,
(uint)stride);
}
public void DrawTexture(ITexture texture, ISampler sampler, Extents2DF srcRegion, Extents2DF dstRegion)
{
if (texture is TextureView srcTexture)
{
SupportBufferUpdater.Commit();
var oldCullMode = _newState.CullMode;
var oldStencilTestEnable = _newState.StencilTestEnable;
var oldDepthTestEnable = _newState.DepthTestEnable;
var oldDepthWriteEnable = _newState.DepthWriteEnable;
var oldTopology = _newState.Topology;
var oldViewports = DynamicState.Viewports;
var oldViewportsCount = _newState.ViewportsCount;
_newState.CullMode = CullModeFlags.None;
_newState.StencilTestEnable = false;
_newState.DepthTestEnable = false;
_newState.DepthWriteEnable = false;
SignalStateChange();
Gd.HelperShader.DrawTexture(
Gd,
this,
srcTexture,
sampler,
srcRegion,
dstRegion);
_newState.CullMode = oldCullMode;
_newState.StencilTestEnable = oldStencilTestEnable;
_newState.DepthTestEnable = oldDepthTestEnable;
_newState.DepthWriteEnable = oldDepthWriteEnable;
_newState.Topology = oldTopology;
DynamicState.SetViewports(ref oldViewports, oldViewportsCount);
_newState.ViewportsCount = oldViewportsCount;
SignalStateChange();
}
}
public void EndTransformFeedback()
{
PauseTransformFeedbackInternal();
_tfEnabled = false;
}
public double GetCounterDivisor(CounterType type)
{
if (type == CounterType.SamplesPassed)
{
return _renderScale[0].X * _renderScale[0].X;
}
return 1;
}
public bool IsCommandBufferActive(CommandBuffer cb)
{
return CommandBuffer.Handle == cb.Handle;
}
public void SetAlphaTest(bool enable, float reference, GAL.CompareOp op)
{
// This is currently handled using shader specialization, as Vulkan does not support alpha test.
// In the future, we may want to use this to write the reference value into the support buffer,
// to avoid creating one version of the shader per reference value used.
}
public void SetBlendState(AdvancedBlendDescriptor blend)
{
for (int index = 0; index < Constants.MaxRenderTargets; index++)
{
ref var vkBlend = ref _newState.Internal.ColorBlendAttachmentState[index];
if (index == 0)
{
var blendOp = blend.Op.Convert();
vkBlend = new PipelineColorBlendAttachmentState(
blendEnable: true,
colorBlendOp: blendOp,
alphaBlendOp: blendOp,
colorWriteMask: vkBlend.ColorWriteMask);
if (Gd.Capabilities.SupportsBlendEquationAdvancedNonPreMultipliedSrcColor)
{
_newState.AdvancedBlendSrcPreMultiplied = blend.SrcPreMultiplied;
}
if (Gd.Capabilities.SupportsBlendEquationAdvancedCorrelatedOverlap)
{
_newState.AdvancedBlendOverlap = blend.Overlap.Convert();
}
}
else
{
vkBlend = new PipelineColorBlendAttachmentState(
colorWriteMask: vkBlend.ColorWriteMask);
}
if (vkBlend.ColorWriteMask == 0)
{
_storedBlend[index] = vkBlend;
vkBlend = new PipelineColorBlendAttachmentState();
}
}
SignalStateChange();
}
public void SetBlendState(int index, BlendDescriptor blend)
{
ref var vkBlend = ref _newState.Internal.ColorBlendAttachmentState[index];
if (blend.Enable)
{
vkBlend.BlendEnable = blend.Enable;
vkBlend.SrcColorBlendFactor = blend.ColorSrcFactor.Convert();
vkBlend.DstColorBlendFactor = blend.ColorDstFactor.Convert();
vkBlend.ColorBlendOp = blend.ColorOp.Convert();
vkBlend.SrcAlphaBlendFactor = blend.AlphaSrcFactor.Convert();
vkBlend.DstAlphaBlendFactor = blend.AlphaDstFactor.Convert();
vkBlend.AlphaBlendOp = blend.AlphaOp.Convert();
}
else
{
vkBlend = new PipelineColorBlendAttachmentState(
colorWriteMask: vkBlend.ColorWriteMask);
}
if (vkBlend.ColorWriteMask == 0)
{
_storedBlend[index] = vkBlend;
vkBlend = new PipelineColorBlendAttachmentState();
}
DynamicState.SetBlendConstants(
blend.BlendConstant.Red,
blend.BlendConstant.Green,
blend.BlendConstant.Blue,
blend.BlendConstant.Alpha);
// Reset advanced blend state back defaults to the cache to help the pipeline cache.
_newState.AdvancedBlendSrcPreMultiplied = true;
_newState.AdvancedBlendDstPreMultiplied = true;
_newState.AdvancedBlendOverlap = BlendOverlapEXT.UncorrelatedExt;
SignalStateChange();
}
public void SetDepthBias(PolygonModeMask enables, float factor, float units, float clamp)
{
DynamicState.SetDepthBias(factor, units, clamp);
_newState.DepthBiasEnable = enables != 0;
SignalStateChange();
}
public void SetDepthClamp(bool clamp)
{
_newState.DepthClampEnable = clamp;
SignalStateChange();
}
public void SetDepthMode(DepthMode mode)
{
// Currently this is emulated on the shader, because Vulkan had no support for changing the depth mode.
// In the future, we may want to use the VK_EXT_depth_clip_control extension to change it here.
}
public void SetDepthTest(DepthTestDescriptor depthTest)
{
_newState.DepthTestEnable = depthTest.TestEnable;
_newState.DepthWriteEnable = depthTest.WriteEnable;
_newState.DepthCompareOp = depthTest.Func.Convert();
SignalStateChange();
}
public void SetFaceCulling(bool enable, Face face)
{
_newState.CullMode = enable ? face.Convert() : CullModeFlags.None;
SignalStateChange();
}
public void SetFrontFace(GAL.FrontFace frontFace)
{
_newState.FrontFace = frontFace.Convert();
SignalStateChange();
}
public void SetImage(int binding, ITexture image, GAL.Format imageFormat)
{
_descriptorSetUpdater.SetImage(binding, image, imageFormat);
}
public void SetImage(int binding, Auto<DisposableImageView> image)
{
_descriptorSetUpdater.SetImage(binding, image);
}
public void SetIndexBuffer(BufferRange buffer, GAL.IndexType type)
{
if (buffer.Handle != BufferHandle.Null)
{
_indexBuffer = new IndexBufferState(buffer.Handle, buffer.Offset, buffer.Size, type.Convert());
}
else
{
_indexBuffer = IndexBufferState.Null;
}
_needsIndexBufferRebind = true;
}
public void SetLineParameters(float width, bool smooth)
{
_newState.LineWidth = width;
SignalStateChange();
}
public void SetLogicOpState(bool enable, LogicalOp op)
{
_newState.LogicOpEnable = enable;
_newState.LogicOp = op.Convert();
SignalStateChange();
}
public void SetMultisampleState(MultisampleDescriptor multisample)
{
_newState.AlphaToCoverageEnable = multisample.AlphaToCoverageEnable;
_newState.AlphaToOneEnable = multisample.AlphaToOneEnable;
SignalStateChange();
}
public void SetOrigin(Origin origin)
{
// TODO.
}
public unsafe void SetPatchParameters(int vertices, ReadOnlySpan<float> defaultOuterLevel, ReadOnlySpan<float> defaultInnerLevel)
{
_newState.PatchControlPoints = (uint)vertices;
SignalStateChange();
// TODO: Default levels (likely needs emulation on shaders?)
}
public void SetPointParameters(float size, bool isProgramPointSize, bool enablePointSprite, Origin origin)
{
// TODO.
}
public void SetPolygonMode(GAL.PolygonMode frontMode, GAL.PolygonMode backMode)
{
// TODO.
}
public void SetPrimitiveRestart(bool enable, int index)
{
_newState.PrimitiveRestartEnable = enable;
// TODO: What to do about the index?
SignalStateChange();
}
public void SetPrimitiveTopology(GAL.PrimitiveTopology topology)
{
_topology = topology;
var vkTopology = Gd.TopologyRemap(topology).Convert();
_newState.Topology = vkTopology;
SignalStateChange();
}
public void SetProgram(IProgram program)
{
var internalProgram = (ShaderCollection)program;
var stages = internalProgram.GetInfos();
_program = internalProgram;
_descriptorSetUpdater.SetProgram(internalProgram);
_newState.PipelineLayout = internalProgram.PipelineLayout;
_newState.StagesCount = (uint)stages.Length;
stages.CopyTo(_newState.Stages.AsSpan().Slice(0, stages.Length));
SignalStateChange();
if (_program.IsCompute)
{
EndRenderPass();
}
}
public void Specialize<T>(in T data) where T : unmanaged
{
var dataSpan = MemoryMarshal.AsBytes(MemoryMarshal.CreateReadOnlySpan(ref Unsafe.AsRef(in data), 1));
if (!dataSpan.SequenceEqual(_newState.SpecializationData.Span))
{
_newState.SpecializationData = new SpecData(dataSpan);
SignalStateChange();
}
}
protected virtual void SignalAttachmentChange()
{
}
public void SetRasterizerDiscard(bool discard)
{
_newState.RasterizerDiscardEnable = discard;
SignalStateChange();
}
public void SetRenderTargetColorMasks(ReadOnlySpan<uint> componentMask)
{
int count = Math.Min(Constants.MaxRenderTargets, componentMask.Length);
int writtenAttachments = 0;
for (int i = 0; i < count; i++)
{
ref var vkBlend = ref _newState.Internal.ColorBlendAttachmentState[i];
var newMask = (ColorComponentFlags)componentMask[i];
// When color write mask is 0, remove all blend state to help the pipeline cache.
// Restore it when the mask becomes non-zero.
if (vkBlend.ColorWriteMask != newMask)
{
if (newMask == 0)
{
_storedBlend[i] = vkBlend;
vkBlend = new PipelineColorBlendAttachmentState();
}
else if (vkBlend.ColorWriteMask == 0)
{
vkBlend = _storedBlend[i];
}
}
vkBlend.ColorWriteMask = newMask;
if (componentMask[i] != 0)
{
writtenAttachments++;
}
}
if (_framebufferUsingColorWriteMask)
{
SetRenderTargetsInternal(_preMaskColors, _preMaskDepthStencil, true);
}
else
{
SignalStateChange();
if (writtenAttachments != _writtenAttachmentCount)
{
SignalAttachmentChange();
_writtenAttachmentCount = writtenAttachments;
}
}
}
private void SetRenderTargetsInternal(ITexture[] colors, ITexture depthStencil, bool filterWriteMasked)
{
FramebufferParams?.UpdateModifications();
CreateFramebuffer(colors, depthStencil, filterWriteMasked);
CreateRenderPass();
SignalStateChange();
SignalAttachmentChange();
}
public void SetRenderTargets(ITexture[] colors, ITexture depthStencil)
{
_framebufferUsingColorWriteMask = false;
SetRenderTargetsInternal(colors, depthStencil, Gd.IsTBDR);
}
public void SetRenderTargetScale(float scale)
{
_renderScale[0].X = scale;
SupportBufferUpdater.UpdateRenderScale(_renderScale, 0, 1); // Just the first element.
}
public void SetScissors(ReadOnlySpan<Rectangle<int>> regions)
{
int maxScissors = Gd.Capabilities.SupportsMultiView ? Constants.MaxViewports : 1;
int count = Math.Min(maxScissors, regions.Length);
if (count > 0)
{
ClearScissor = regions[0];
}
for (int i = 0; i < count; i++)
{
var region = regions[i];
var offset = new Offset2D(region.X, region.Y);
var extent = new Extent2D((uint)region.Width, (uint)region.Height);
DynamicState.SetScissor(i, new Rect2D(offset, extent));
}
DynamicState.ScissorsCount = count;
_newState.ScissorsCount = (uint)count;
SignalStateChange();
}
public void SetStencilTest(StencilTestDescriptor stencilTest)
{
DynamicState.SetStencilMasks(
(uint)stencilTest.BackFuncMask,
(uint)stencilTest.BackMask,
(uint)stencilTest.BackFuncRef,
(uint)stencilTest.FrontFuncMask,
(uint)stencilTest.FrontMask,
(uint)stencilTest.FrontFuncRef);
_newState.StencilTestEnable = stencilTest.TestEnable;
_newState.StencilBackFailOp = stencilTest.BackSFail.Convert();
_newState.StencilBackPassOp = stencilTest.BackDpPass.Convert();
_newState.StencilBackDepthFailOp = stencilTest.BackDpFail.Convert();
_newState.StencilBackCompareOp = stencilTest.BackFunc.Convert();
_newState.StencilFrontFailOp = stencilTest.FrontSFail.Convert();
_newState.StencilFrontPassOp = stencilTest.FrontDpPass.Convert();
_newState.StencilFrontDepthFailOp = stencilTest.FrontDpFail.Convert();
_newState.StencilFrontCompareOp = stencilTest.FrontFunc.Convert();
SignalStateChange();
}
public void SetStorageBuffers(ReadOnlySpan<BufferAssignment> buffers)
{
_descriptorSetUpdater.SetStorageBuffers(CommandBuffer, buffers);
}
public void SetStorageBuffers(int first, ReadOnlySpan<Auto<DisposableBuffer>> buffers)
{
_descriptorSetUpdater.SetStorageBuffers(CommandBuffer, first, buffers);
}
public void SetTextureAndSampler(ShaderStage stage, int binding, ITexture texture, ISampler sampler)
{
_descriptorSetUpdater.SetTextureAndSampler(Cbs, stage, binding, texture, sampler);
}
public void SetTransformFeedbackBuffers(ReadOnlySpan<BufferRange> buffers)
{
PauseTransformFeedbackInternal();
int count = Math.Min(Constants.MaxTransformFeedbackBuffers, buffers.Length);
for (int i = 0; i < count; i++)
{
var range = buffers[i];
_transformFeedbackBuffers[i].Dispose();
if (range.Handle != BufferHandle.Null)
{
_transformFeedbackBuffers[i] =
new BufferState(Gd.BufferManager.GetBuffer(CommandBuffer, range.Handle, range.Offset, range.Size, true), range.Offset, range.Size);
_transformFeedbackBuffers[i].BindTransformFeedbackBuffer(Gd, Cbs, (uint)i);
}
else
{
_transformFeedbackBuffers[i] = BufferState.Null;
}
}
}
public void SetUniformBuffers(ReadOnlySpan<BufferAssignment> buffers)
{
_descriptorSetUpdater.SetUniformBuffers(CommandBuffer, buffers);
}
public void SetUserClipDistance(int index, bool enableClip)
{
// TODO.
}
public void SetVertexAttribs(ReadOnlySpan<VertexAttribDescriptor> vertexAttribs)
{
var formatCapabilities = Gd.FormatCapabilities;
Span<int> newVbScalarSizes = stackalloc int[Constants.MaxVertexBuffers];
int count = Math.Min(Constants.MaxVertexAttributes, vertexAttribs.Length);
uint dirtyVbSizes = 0;
for (int i = 0; i < count; i++)
{
var attribute = vertexAttribs[i];
var rawIndex = attribute.BufferIndex;
var bufferIndex = attribute.IsZero ? 0 : rawIndex + 1;
if (!attribute.IsZero)
{
newVbScalarSizes[rawIndex] = Math.Max(newVbScalarSizes[rawIndex], attribute.Format.GetScalarSize());
dirtyVbSizes |= 1u << rawIndex;
}
_newState.Internal.VertexAttributeDescriptions[i] = new VertexInputAttributeDescription(
(uint)i,
(uint)bufferIndex,
formatCapabilities.ConvertToVertexVkFormat(attribute.Format),
(uint)attribute.Offset);
}
while (dirtyVbSizes != 0)
{
int dirtyBit = BitOperations.TrailingZeroCount(dirtyVbSizes);
ref var buffer = ref _vertexBuffers[dirtyBit + 1];
if (buffer.AttributeScalarAlignment != newVbScalarSizes[dirtyBit])
{
_vertexBuffersDirty |= 1UL << (dirtyBit + 1);
buffer.AttributeScalarAlignment = newVbScalarSizes[dirtyBit];
}
dirtyVbSizes &= ~(1u << dirtyBit);
}
_newState.VertexAttributeDescriptionsCount = (uint)count;
SignalStateChange();
}
public void SetVertexBuffers(ReadOnlySpan<VertexBufferDescriptor> vertexBuffers)
{
int count = Math.Min(Constants.MaxVertexBuffers, vertexBuffers.Length);
_newState.Internal.VertexBindingDescriptions[0] = new VertexInputBindingDescription(0, 0, VertexInputRate.Vertex);
int validCount = 1;
for (int i = 0; i < count; i++)
{
var vertexBuffer = vertexBuffers[i];
// TODO: Support divisor > 1
var inputRate = vertexBuffer.Divisor != 0 ? VertexInputRate.Instance : VertexInputRate.Vertex;
if (vertexBuffer.Buffer.Handle != BufferHandle.Null)
{
var vb = Gd.BufferManager.GetBuffer(CommandBuffer, vertexBuffer.Buffer.Handle, false);
if (vb != null)
{
int binding = i + 1;
int descriptorIndex = validCount++;
_newState.Internal.VertexBindingDescriptions[descriptorIndex] = new VertexInputBindingDescription(
(uint)binding,
(uint)vertexBuffer.Stride,
inputRate);
int vbSize = vertexBuffer.Buffer.Size;
if (Gd.Vendor == Vendor.Amd && !Gd.IsMoltenVk && vertexBuffer.Stride > 0)
{
// AMD has a bug where if offset + stride * count is greater than
// the size, then the last attribute will have the wrong value.
// As a workaround, simply use the full buffer size.
int remainder = vbSize % vertexBuffer.Stride;
if (remainder != 0)
{
vbSize += vertexBuffer.Stride - remainder;
}
}
ref var buffer = ref _vertexBuffers[binding];
int oldScalarAlign = buffer.AttributeScalarAlignment;
buffer.Dispose();
if (Gd.Capabilities.VertexBufferAlignment < 2 &&
(vertexBuffer.Stride % FormatExtensions.MaxBufferFormatScalarSize) == 0)
{
buffer = new VertexBufferState(
vb,
descriptorIndex,
vertexBuffer.Buffer.Offset,
vbSize,
vertexBuffer.Stride);
buffer.BindVertexBuffer(Gd, Cbs, (uint)binding, ref _newState);
}
else
{
// May need to be rewritten. Bind this buffer before draw.
buffer = new VertexBufferState(
vertexBuffer.Buffer.Handle,
descriptorIndex,
vertexBuffer.Buffer.Offset,
vbSize,
vertexBuffer.Stride);
_vertexBuffersDirty |= 1UL << binding;
}
buffer.AttributeScalarAlignment = oldScalarAlign;
}
}
}
_newState.VertexBindingDescriptionsCount = (uint)validCount;
SignalStateChange();
}
public void SetViewports(ReadOnlySpan<GAL.Viewport> viewports, bool disableTransform)
{
int maxViewports = Gd.Capabilities.SupportsMultiView ? Constants.MaxViewports : 1;
int count = Math.Min(maxViewports, viewports.Length);
static float Clamp(float value)
{
return Math.Clamp(value, 0f, 1f);
}
DynamicState.ViewportsCount = (uint)count;
for (int i = 0; i < count; i++)
{
var viewport = viewports[i];
DynamicState.SetViewport(i, new Silk.NET.Vulkan.Viewport(
viewport.Region.X,
viewport.Region.Y,
viewport.Region.Width == 0f ? 1f : viewport.Region.Width,
viewport.Region.Height == 0f ? 1f : viewport.Region.Height,
Clamp(viewport.DepthNear),
Clamp(viewport.DepthFar)));
}
float disableTransformF = disableTransform ? 1.0f : 0.0f;
if (SupportBufferUpdater.Data.ViewportInverse.W != disableTransformF || disableTransform)
{
float scale = _renderScale[0].X;
SupportBufferUpdater.UpdateViewportInverse(new Vector4<float>
{
X = scale * 2f / viewports[0].Region.Width,
Y = scale * 2f / viewports[0].Region.Height,
Z = 1,
W = disableTransformF
});
}
_newState.ViewportsCount = (uint)count;
SignalStateChange();
}
public void SwapBuffer(Auto<DisposableBuffer> from, Auto<DisposableBuffer> to)
{
_indexBuffer.Swap(from, to);
for (int i = 0; i < _vertexBuffers.Length; i++)
{
_vertexBuffers[i].Swap(from, to);
}
for (int i = 0; i < _transformFeedbackBuffers.Length; i++)
{
_transformFeedbackBuffers[i].Swap(from, to);
}
_descriptorSetUpdater.SwapBuffer(from, to);
SignalCommandBufferChange();
}
public unsafe void TextureBarrier()
{
MemoryBarrier memoryBarrier = new MemoryBarrier()
{
SType = StructureType.MemoryBarrier,
SrcAccessMask = AccessFlags.MemoryReadBit | AccessFlags.MemoryWriteBit,
DstAccessMask = AccessFlags.MemoryReadBit | AccessFlags.MemoryWriteBit
};
Gd.Api.CmdPipelineBarrier(
CommandBuffer,
PipelineStageFlags.FragmentShaderBit,
PipelineStageFlags.FragmentShaderBit,
0,
1,
memoryBarrier,
0,
null,
0,
null);
}
public void TextureBarrierTiled()
{
TextureBarrier();
}
public void UpdateRenderScale(ReadOnlySpan<float> scales, int totalCount, int fragmentCount)
{
bool changed = false;
for (int index = 0; index < totalCount; index++)
{
if (_renderScale[1 + index].X != scales[index])
{
_renderScale[1 + index].X = scales[index];
changed = true;
}
}
// Only update fragment count if there are scales after it for the vertex stage.
if (fragmentCount != totalCount && fragmentCount != _fragmentScaleCount)
{
_fragmentScaleCount = fragmentCount;
SupportBufferUpdater.UpdateFragmentRenderScaleCount(_fragmentScaleCount);
}
if (changed)
{
SupportBufferUpdater.UpdateRenderScale(_renderScale, 0, 1 + totalCount);
}
}
protected void SignalCommandBufferChange()
{
_needsIndexBufferRebind = true;
_needsTransformFeedbackBuffersRebind = true;
_vertexBuffersDirty = ulong.MaxValue >> (64 - _vertexBuffers.Length);
_descriptorSetUpdater.SignalCommandBufferChange();
DynamicState.ForceAllDirty();
_currentPipelineHandle = 0;
}
private void CreateFramebuffer(ITexture[] colors, ITexture depthStencil, bool filterWriteMasked)
{
if (filterWriteMasked)
{
// TBDR GPUs don't work properly if the same attachment is bound to multiple targets,
// due to each attachment being a copy of the real attachment, rather than a direct write.
// Just try to remove duplicate attachments.
// Save a copy of the array to rebind when mask changes.
void maskOut()
{
if (!_framebufferUsingColorWriteMask)
{
_preMaskColors = colors.ToArray();
_preMaskDepthStencil = depthStencil;
}
// If true, then the framebuffer must be recreated when the mask changes.
_framebufferUsingColorWriteMask = true;
}
// Look for textures that are masked out.
for (int i = 0; i < colors.Length; i++)
{
if (colors[i] == null)
{
continue;
}
ref var vkBlend = ref _newState.Internal.ColorBlendAttachmentState[i];
for (int j = 0; j < i; j++)
{
// Check each binding for a duplicate binding before it.
if (colors[i] == colors[j])
{
// Prefer the binding with no write mask.
ref var vkBlend2 = ref _newState.Internal.ColorBlendAttachmentState[j];
if (vkBlend.ColorWriteMask == 0)
{
colors[i] = null;
maskOut();
}
else if (vkBlend2.ColorWriteMask == 0)
{
colors[j] = null;
maskOut();
}
}
}
}
}
FramebufferParams = new FramebufferParams(Device, colors, depthStencil);
UpdatePipelineAttachmentFormats();
}
protected void UpdatePipelineAttachmentFormats()
{
var dstAttachmentFormats = _newState.Internal.AttachmentFormats.AsSpan();
FramebufferParams.AttachmentFormats.CopyTo(dstAttachmentFormats);
for (int i = FramebufferParams.AttachmentFormats.Length; i < dstAttachmentFormats.Length; i++)
{
dstAttachmentFormats[i] = 0;
}
_newState.ColorBlendAttachmentStateCount = (uint)(FramebufferParams.MaxColorAttachmentIndex + 1);
_newState.HasDepthStencil = FramebufferParams.HasDepthStencil;
_newState.SamplesCount = FramebufferParams.AttachmentSamples.Length != 0 ? FramebufferParams.AttachmentSamples[0] : 1;
}
protected unsafe void CreateRenderPass()
{
const int MaxAttachments = Constants.MaxRenderTargets + 1;
AttachmentDescription[] attachmentDescs = null;
var subpass = new SubpassDescription()
{
PipelineBindPoint = PipelineBindPoint.Graphics
};
AttachmentReference* attachmentReferences = stackalloc AttachmentReference[MaxAttachments];
var hasFramebuffer = FramebufferParams != null;
if (hasFramebuffer && FramebufferParams.AttachmentsCount != 0)
{
attachmentDescs = new AttachmentDescription[FramebufferParams.AttachmentsCount];
for (int i = 0; i < FramebufferParams.AttachmentsCount; i++)
{
attachmentDescs[i] = new AttachmentDescription(
0,
FramebufferParams.AttachmentFormats[i],
TextureStorage.ConvertToSampleCountFlags(Gd.Capabilities.SupportedSampleCounts, FramebufferParams.AttachmentSamples[i]),
AttachmentLoadOp.Load,
AttachmentStoreOp.Store,
AttachmentLoadOp.Load,
AttachmentStoreOp.Store,
ImageLayout.General,
ImageLayout.General);
}
int colorAttachmentsCount = FramebufferParams.ColorAttachmentsCount;
if (colorAttachmentsCount > MaxAttachments - 1)
{
colorAttachmentsCount = MaxAttachments - 1;
}
if (colorAttachmentsCount != 0)
{
int maxAttachmentIndex = FramebufferParams.MaxColorAttachmentIndex;
subpass.ColorAttachmentCount = (uint)maxAttachmentIndex + 1;
subpass.PColorAttachments = &attachmentReferences[0];
// Fill with VK_ATTACHMENT_UNUSED to cover any gaps.
for (int i = 0; i <= maxAttachmentIndex; i++)
{
subpass.PColorAttachments[i] = new AttachmentReference(Vk.AttachmentUnused, ImageLayout.Undefined);
}
for (int i = 0; i < colorAttachmentsCount; i++)
{
int bindIndex = FramebufferParams.AttachmentIndices[i];
subpass.PColorAttachments[bindIndex] = new AttachmentReference((uint)i, ImageLayout.General);
}
}
if (FramebufferParams.HasDepthStencil)
{
uint dsIndex = (uint)FramebufferParams.AttachmentsCount - 1;
subpass.PDepthStencilAttachment = &attachmentReferences[MaxAttachments - 1];
*subpass.PDepthStencilAttachment = new AttachmentReference(dsIndex, ImageLayout.General);
}
}
var subpassDependency = PipelineConverter.CreateSubpassDependency();
fixed (AttachmentDescription* pAttachmentDescs = attachmentDescs)
{
var renderPassCreateInfo = new RenderPassCreateInfo()
{
SType = StructureType.RenderPassCreateInfo,
PAttachments = pAttachmentDescs,
AttachmentCount = attachmentDescs != null ? (uint)attachmentDescs.Length : 0,
PSubpasses = &subpass,
SubpassCount = 1,
PDependencies = &subpassDependency,
DependencyCount = 1
};
Gd.Api.CreateRenderPass(Device, renderPassCreateInfo, null, out var renderPass).ThrowOnError();
_renderPass?.Dispose();
_renderPass = new Auto<DisposableRenderPass>(new DisposableRenderPass(Gd.Api, Device, renderPass));
}
EndRenderPass();
_framebuffer?.Dispose();
_framebuffer = hasFramebuffer ? FramebufferParams.Create(Gd.Api, Cbs, _renderPass) : null;
}
protected void SignalStateChange()
{
_stateDirty = true;
}
private void RecreatePipelineIfNeeded(PipelineBindPoint pbp)
{
DynamicState.ReplayIfDirty(Gd.Api, CommandBuffer);
// Commit changes to the support buffer before drawing.
SupportBufferUpdater.Commit();
if (_needsIndexBufferRebind && _indexBufferPattern == null)
{
_indexBuffer.BindIndexBuffer(Gd, Cbs);
_needsIndexBufferRebind = false;
}
if (_needsTransformFeedbackBuffersRebind)
{
PauseTransformFeedbackInternal();
for (int i = 0; i < Constants.MaxTransformFeedbackBuffers; i++)
{
_transformFeedbackBuffers[i].BindTransformFeedbackBuffer(Gd, Cbs, (uint)i);
}
_needsTransformFeedbackBuffersRebind = false;
}
if (_vertexBuffersDirty != 0)
{
while (_vertexBuffersDirty != 0)
{
int i = BitOperations.TrailingZeroCount(_vertexBuffersDirty);
_vertexBuffers[i].BindVertexBuffer(Gd, Cbs, (uint)i, ref _newState);
_vertexBuffersDirty &= ~(1UL << i);
}
}
if (_stateDirty || Pbp != pbp)
{
CreatePipeline(pbp);
_stateDirty = false;
Pbp = pbp;
}
_descriptorSetUpdater.UpdateAndBindDescriptorSets(Cbs, pbp);
}
private void CreatePipeline(PipelineBindPoint pbp)
{
// We can only create a pipeline if the have the shader stages set.
if (_newState.Stages != null)
{
if (pbp == PipelineBindPoint.Graphics && _renderPass == null)
{
CreateRenderPass();
}
var pipeline = pbp == PipelineBindPoint.Compute
? _newState.CreateComputePipeline(Gd, Device, _program, PipelineCache)
: _newState.CreateGraphicsPipeline(Gd, Device, _program, PipelineCache, _renderPass.Get(Cbs).Value);
ulong pipelineHandle = pipeline.GetUnsafe().Value.Handle;
if (_currentPipelineHandle != pipelineHandle)
{
_currentPipelineHandle = pipelineHandle;
Pipeline = pipeline;
PauseTransformFeedbackInternal();
Gd.Api.CmdBindPipeline(CommandBuffer, pbp, Pipeline.Get(Cbs).Value);
}
}
}
private unsafe void BeginRenderPass()
{
if (!RenderPassActive)
{
var renderArea = new Rect2D(null, new Extent2D(FramebufferParams.Width, FramebufferParams.Height));
var clearValue = new ClearValue();
var renderPassBeginInfo = new RenderPassBeginInfo()
{
SType = StructureType.RenderPassBeginInfo,
RenderPass = _renderPass.Get(Cbs).Value,
Framebuffer = _framebuffer.Get(Cbs).Value,
RenderArea = renderArea,
PClearValues = &clearValue,
ClearValueCount = 1
};
Gd.Api.CmdBeginRenderPass(CommandBuffer, renderPassBeginInfo, SubpassContents.Inline);
RenderPassActive = true;
}
}
public void EndRenderPass()
{
if (RenderPassActive)
{
PauseTransformFeedbackInternal();
Gd.Api.CmdEndRenderPass(CommandBuffer);
SignalRenderPassEnd();
RenderPassActive = false;
}
}
protected virtual void SignalRenderPassEnd()
{
}
private void PauseTransformFeedbackInternal()
{
if (_tfEnabled && _tfActive)
{
EndTransformFeedbackInternal();
_tfActive = false;
}
}
private void ResumeTransformFeedbackInternal()
{
if (_tfEnabled && !_tfActive)
{
BeginTransformFeedbackInternal();
_tfActive = true;
}
}
private unsafe void BeginTransformFeedbackInternal()
{
Gd.TransformFeedbackApi.CmdBeginTransformFeedback(CommandBuffer, 0, 0, null, null);
}
private unsafe void EndTransformFeedbackInternal()
{
Gd.TransformFeedbackApi.CmdEndTransformFeedback(CommandBuffer, 0, 0, null, null);
}
protected virtual void Dispose(bool disposing)
{
if (disposing)
{
_renderPass?.Dispose();
_framebuffer?.Dispose();
_newState.Dispose();
_descriptorSetUpdater.Dispose();
for (int i = 0; i < _vertexBuffers.Length; i++)
{
_vertexBuffers[i].Dispose();
}
for (int i = 0; i < _transformFeedbackBuffers.Length; i++)
{
_transformFeedbackBuffers[i].Dispose();
}
Pipeline?.Dispose();
unsafe
{
Gd.Api.DestroyPipelineCache(Device, PipelineCache, null);
}
SupportBufferUpdater.Dispose();
}
}
public void Dispose()
{
Dispose(true);
}
}
}