ryujinx/Ryujinx.Graphics.Vulkan/PipelineBase.cs
riperiperi c3c41fa4bb
Periodically Flush Commands for Vulkan (#3689)
* Periodically Flush Commands for Vulkan

NVIDIA's OpenGL driver has a built-in mechanism to automatically flush commands to GPU when a lot have been queued. It's also pretty inconsistent, but we'll ignore that for now.

Our Vulkan implementation only submits a command buffer (flush equivalent) when it needs to. This is typically when another command buffer needs to be sequenced after it, presenting a frame, or an edge case where we flush around GPU queries to get results sooner.

This difference in flush behaviour causes a notable difference between Vulkan and OpenGL when we have to wait for commands. In the worst case, we will wait for a sync point that has just been created. In Vulkan, this sync point is created by flushing the command buffer, and storing a waitable fence that signals its completion. Our command buffer contains _every command that we queued since the last submit_, which could be an entire frame's worth of draws.

This has a huge effect on CPU <-> GPU latency. The more commands in a command buffer, the longer we have to wait for it to complete, which results in wasted time. Because we don't know when the guest will force us to wait, we always want the smallest possible latency.

By periodically flushing, we ensure that each command buffer takes a more consistent, smaller amount of time to execute, and that the back of the GPU queue isn't as far away when we need to wait for something to happen. This also might reduce time that the GPU is left inactive while commands are being built.

The main affected game is Pokemon Sword, which got significantly faster in overworld areas due to reduced waiting time when it flushes a shadow map from the main GPU thread.

Another affected game is BOTW, which gets faster depending on the area. This game flushes textures/buffers from its game thread, which is the bottleneck.

Flush latency and throughput may be improved on other games that are inexplicably slower than OpenGL. It's possible that certain games could have their performance _decreased_ slightly due to flushes not being free, but it is unlikely.

Also, flushing to get query results sooner has been tweaked to improve the number of full draw skips that can be done. (tested in SMO)

* Remove unused variable

* Fix possible issue with early query flush
2022-09-14 13:48:31 -03:00

1299 lines
46 KiB
C#

using Ryujinx.Graphics.GAL;
using Ryujinx.Graphics.Shader;
using Silk.NET.Vulkan;
using System;
using System.Numerics;
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;
protected readonly AutoFlushCounter AutoFlush;
private 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 _renderPassActive;
private readonly DescriptorSetUpdater _descriptorSetUpdater;
private BufferState _indexBuffer;
private readonly BufferState[] _transformFeedbackBuffers;
private readonly VertexBufferState[] _vertexBuffers;
private ulong _vertexBuffersDirty;
protected Rectangle<int> ClearScissor;
public SupportBufferUpdater SupportBufferUpdater;
private bool _needsIndexBufferRebind;
private bool _needsTransformFeedbackBuffersRebind;
private bool _tfEnabled;
private bool _tfActive;
public ulong DrawCount { 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, 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);
_newState.Initialize();
_newState.LineWidth = 1f;
_newState.SamplesCount = 1;
}
public void Initialize()
{
SupportBufferUpdater = new SupportBufferUpdater(Gd);
SupportBufferUpdater.UpdateRenderScale(_renderScale, 0, SupportBuffer.RenderScaleMaxCount);
}
public unsafe void Barrier()
{
MemoryBarrier memoryBarrier = new MemoryBarrier()
{
SType = StructureType.MemoryBarrier,
SrcAccessMask = AccessFlags.AccessMemoryReadBit | AccessFlags.AccessMemoryWriteBit,
DstAccessMask = AccessFlags.AccessMemoryReadBit | AccessFlags.AccessMemoryWriteBit
};
Gd.Api.CmdPipelineBarrier(
CommandBuffer,
PipelineStageFlags.PipelineStageFragmentShaderBit,
PipelineStageFlags.PipelineStageFragmentShaderBit,
0,
1,
memoryBarrier,
0,
null,
0,
null);
}
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, true).Get(Cbs, offset, size).Value;
BufferHolder.InsertBufferBarrier(
Gd,
Cbs.CommandBuffer,
dst,
BufferHolder.DefaultAccessFlags,
AccessFlags.AccessTransferWriteBit,
PipelineStageFlags.PipelineStageAllCommandsBit,
PipelineStageFlags.PipelineStageTransferBit,
offset,
size);
Gd.Api.CmdFillBuffer(CommandBuffer, dst, (ulong)offset, (ulong)size, value);
BufferHolder.InsertBufferBarrier(
Gd,
Cbs.CommandBuffer,
dst,
AccessFlags.AccessTransferWriteBit,
BufferHolder.DefaultAccessFlags,
PipelineStageFlags.PipelineStageTransferBit,
PipelineStageFlags.PipelineStageAllCommandsBit,
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.ImageAspectColorBit, (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.ImageAspectDepthBit : 0;
if (stencilMask != 0)
{
flags |= ImageAspectFlags.ImageAspectStencilBit;
}
var attachment = new ClearAttachment(flags, 0, clearValue);
var clearRect = FramebufferParams.GetClearRect(ClearScissor, layer, layerCount);
Gd.Api.CmdClearAttachments(CommandBuffer, 1, &attachment, 1, &clearRect);
}
public void CommandBufferBarrier()
{
// TODO: More specific barrier?
Barrier();
}
public void CopyBuffer(BufferHandle source, BufferHandle destination, int srcOffset, int dstOffset, int size)
{
EndRenderPass();
var src = Gd.BufferManager.GetBuffer(CommandBuffer, source, false);
var dst = Gd.BufferManager.GetBuffer(CommandBuffer, destination, 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 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 Draw(int vertexCount, int instanceCount, int firstVertex, int firstInstance)
{
if (!_program.IsLinked)
{
return;
}
RecreatePipelineIfNeeded(PipelineBindPoint.Graphics);
BeginRenderPass();
ResumeTransformFeedbackInternal();
DrawCount++;
if (_topology == GAL.PrimitiveTopology.Quads)
{
int quadsCount = vertexCount / 4;
for (int i = 0; i < quadsCount; i++)
{
Gd.Api.CmdDraw(CommandBuffer, 4, (uint)instanceCount, (uint)(firstVertex + i * 4), (uint)firstInstance);
}
}
else
{
Gd.Api.CmdDraw(CommandBuffer, (uint)vertexCount, (uint)instanceCount, (uint)firstVertex, (uint)firstInstance);
}
}
public void DrawIndexed(int indexCount, int instanceCount, int firstIndex, int firstVertex, int firstInstance)
{
if (!_program.IsLinked)
{
return;
}
RecreatePipelineIfNeeded(PipelineBindPoint.Graphics);
BeginRenderPass();
ResumeTransformFeedbackInternal();
DrawCount++;
if (_topology == GAL.PrimitiveTopology.Quads)
{
int quadsCount = indexCount / 4;
for (int i = 0; i < quadsCount; i++)
{
Gd.Api.CmdDrawIndexed(CommandBuffer, 4, (uint)instanceCount, (uint)(firstIndex + i * 4), firstVertex, (uint)firstInstance);
}
}
else
{
Gd.Api.CmdDrawIndexed(CommandBuffer, (uint)indexCount, (uint)instanceCount, (uint)firstIndex, firstVertex, (uint)firstInstance);
}
}
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.CullModeNone;
_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.Viewports = oldViewports;
_dynamicState.ViewportsCount = (int)oldViewportsCount;
_dynamicState.SetViewportsDirty();
_newState.ViewportsCount = oldViewportsCount;
SignalStateChange();
}
}
public void EndTransformFeedback()
{
PauseTransformFeedbackInternal();
_tfEnabled = false;
}
public bool IsCommandBufferActive(CommandBuffer cb)
{
return CommandBuffer.Handle == cb.Handle;
}
public void MultiDrawIndirectCount(BufferRange indirectBuffer, BufferRange parameterBuffer, int maxDrawCount, int stride)
{
if (!Gd.Capabilities.SupportsIndirectParameters)
{
throw new NotSupportedException();
}
if (_program.LinkStatus != ProgramLinkStatus.Success)
{
return;
}
RecreatePipelineIfNeeded(PipelineBindPoint.Graphics);
BeginRenderPass();
ResumeTransformFeedbackInternal();
DrawCount++;
var buffer = Gd.BufferManager.GetBuffer(CommandBuffer, indirectBuffer.Handle, true).Get(Cbs, indirectBuffer.Offset, indirectBuffer.Size).Value;
var countBuffer = Gd.BufferManager.GetBuffer(CommandBuffer, parameterBuffer.Handle, true).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 MultiDrawIndexedIndirectCount(BufferRange indirectBuffer, BufferRange parameterBuffer, int maxDrawCount, int stride)
{
if (!Gd.Capabilities.SupportsIndirectParameters)
{
throw new NotSupportedException();
}
if (_program.LinkStatus != ProgramLinkStatus.Success)
{
return;
}
RecreatePipelineIfNeeded(PipelineBindPoint.Graphics);
BeginRenderPass();
ResumeTransformFeedbackInternal();
DrawCount++;
var buffer = Gd.BufferManager.GetBuffer(CommandBuffer, indirectBuffer.Handle, true).Get(Cbs, indirectBuffer.Offset, indirectBuffer.Size).Value;
var countBuffer = Gd.BufferManager.GetBuffer(CommandBuffer, parameterBuffer.Handle, true).Get(Cbs, parameterBuffer.Offset, parameterBuffer.Size).Value;
Gd.DrawIndirectCountApi.CmdDrawIndexedIndirectCount(
CommandBuffer,
buffer,
(ulong)indirectBuffer.Offset,
countBuffer,
(ulong)parameterBuffer.Offset,
(uint)maxDrawCount,
(uint)stride);
}
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(int index, BlendDescriptor blend)
{
ref var vkBlend = ref _newState.Internal.ColorBlendAttachmentState[index];
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();
_newState.BlendConstantR = blend.BlendConstant.Red;
_newState.BlendConstantG = blend.BlendConstant.Green;
_newState.BlendConstantB = blend.BlendConstant.Blue;
_newState.BlendConstantA = blend.BlendConstant.Alpha;
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.CullModeNone;
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 SetIndexBuffer(BufferRange buffer, GAL.IndexType type)
{
_indexBuffer.Dispose();
if (buffer.Handle != BufferHandle.Null)
{
Auto<DisposableBuffer> ib = null;
int offset = buffer.Offset;
int size = buffer.Size;
if (type == GAL.IndexType.UByte && !Gd.Capabilities.SupportsIndexTypeUint8)
{
ib = Gd.BufferManager.GetBufferI8ToI16(Cbs, buffer.Handle, offset, size);
offset = 0;
size *= 2;
type = GAL.IndexType.UShort;
}
else
{
ib = Gd.BufferManager.GetBuffer(CommandBuffer, buffer.Handle, false);
}
_indexBuffer = new BufferState(ib, offset, size, type.Convert());
}
else
{
_indexBuffer = BufferState.Null;
}
_indexBuffer.BindIndexBuffer(Gd.Api, Cbs);
}
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 = 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();
}
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];
vkBlend.ColorWriteMask = (ColorComponentFlags)componentMask[i];
if (componentMask[i] != 0)
{
writtenAttachments++;
}
}
SignalStateChange();
if (writtenAttachments != _writtenAttachmentCount)
{
SignalAttachmentChange();
_writtenAttachmentCount = writtenAttachments;
}
}
public void SetRenderTargets(ITexture[] colors, ITexture depthStencil)
{
FramebufferParams?.UpdateModifications();
CreateFramebuffer(colors, depthStencil);
CreateRenderPass();
SignalStateChange();
SignalAttachmentChange();
}
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(int first, ReadOnlySpan<BufferRange> buffers)
{
_descriptorSetUpdater.SetStorageBuffers(CommandBuffer, first, 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, true), range.Offset, range.Size);
_transformFeedbackBuffers[i].BindTransformFeedbackBuffer(Gd, Cbs, (uint)i);
}
else
{
_transformFeedbackBuffers[i] = BufferState.Null;
}
}
}
public void SetUniformBuffers(int first, ReadOnlySpan<BufferRange> buffers)
{
_descriptorSetUpdater.SetUniformBuffers(CommandBuffer, first, 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 && 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 ((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);
}
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)));
}
_dynamicState.ViewportsCount = count;
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 unsafe void TextureBarrier()
{
MemoryBarrier memoryBarrier = new MemoryBarrier()
{
SType = StructureType.MemoryBarrier,
SrcAccessMask = AccessFlags.AccessMemoryReadBit | AccessFlags.AccessMemoryWriteBit,
DstAccessMask = AccessFlags.AccessMemoryReadBit | AccessFlags.AccessMemoryWriteBit
};
Gd.Api.CmdPipelineBarrier(
CommandBuffer,
PipelineStageFlags.PipelineStageFragmentShaderBit,
PipelineStageFlags.PipelineStageFragmentShaderBit,
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)
{
FramebufferParams = new FramebufferParams(Device, colors, depthStencil);
UpdatePipelineAttachmentFormats();
_newState.SamplesCount = FramebufferParams.AttachmentSamples.Length != 0 ? FramebufferParams.AttachmentSamples[0] : 1;
}
protected void UpdatePipelineAttachmentFormats()
{
var dstAttachmentFormats = _newState.Internal.AttachmentFormats.AsSpan();
FramebufferParams.AttachmentFormats.CopyTo(dstAttachmentFormats);
int maxAttachmentIndex = FramebufferParams.MaxColorAttachmentIndex + (FramebufferParams.HasDepthStencil ? 1 : 0);
for (int i = FramebufferParams.AttachmentFormats.Length; i <= maxAttachmentIndex; i++)
{
dstAttachmentFormats[i] = 0;
}
_newState.ColorBlendAttachmentStateCount = (uint)(FramebufferParams.MaxColorAttachmentIndex + 1);
_newState.HasDepthStencil = FramebufferParams.HasDepthStencil;
}
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++)
{
int bindIndex = FramebufferParams.AttachmentIndices[i];
attachmentDescs[i] = new AttachmentDescription(
0,
FramebufferParams.AttachmentFormats[i],
TextureStorage.ConvertToSampleCountFlags(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 = new SubpassDependency(
0,
0,
PipelineStageFlags.PipelineStageAllGraphicsBit,
PipelineStageFlags.PipelineStageAllGraphicsBit,
AccessFlags.AccessMemoryReadBit | AccessFlags.AccessMemoryWriteBit | AccessFlags.AccessColorAttachmentWriteBit,
AccessFlags.AccessMemoryReadBit | AccessFlags.AccessMemoryWriteBit | AccessFlags.AccessShaderReadBit,
0);
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)
{
_indexBuffer.BindIndexBuffer(Gd.Api, 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 &= ~(1u << 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();
_indexBuffer.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);
}
}
}