Ryujinx/src/Ryujinx.Graphics.OpenGL/Pipeline.cs
gdkchan 53d096e392
Allow texture arrays to use separate descriptor sets on Vulkan (#6870)
* Report base and extra sets from the backend

* Pass texture set index everywhere

* Key textures using set and binding (rather than just binding)

* Start using extra sets for array textures

* Shader cache version bump

* Separate new commands, some PR feedback

* Introduce new manual descriptor set reservation method that prevents it from being used by something else while owned by an array

* Move bind extra sets logic to new method

* Should only use separate array is MaximumExtraSets is not zero

* Format whitespace
2024-05-26 13:30:19 -03:00

1706 lines
53 KiB
C#

using OpenTK.Graphics.OpenGL;
using Ryujinx.Common.Logging;
using Ryujinx.Graphics.GAL;
using Ryujinx.Graphics.OpenGL.Image;
using Ryujinx.Graphics.OpenGL.Queries;
using Ryujinx.Graphics.Shader;
using System;
namespace Ryujinx.Graphics.OpenGL
{
class Pipeline : IPipeline, IDisposable
{
private const int SavedImages = 2;
private readonly DrawTextureEmulation _drawTexture;
internal ulong DrawCount { get; private set; }
private Program _program;
private bool _rasterizerDiscard;
private VertexArray _vertexArray;
private Framebuffer _framebuffer;
private IntPtr _indexBaseOffset;
private DrawElementsType _elementsType;
private PrimitiveType _primitiveType;
private int _stencilFrontMask;
private bool _depthMask;
private bool _depthTestEnable;
private bool _stencilTestEnable;
private bool _cullEnable;
private float[] _viewportArray = Array.Empty<float>();
private double[] _depthRangeArray = Array.Empty<double>();
private int _boundDrawFramebuffer;
private int _boundReadFramebuffer;
private CounterQueueEvent _activeConditionalRender;
private readonly Vector4<int>[] _fpIsBgra = new Vector4<int>[SupportBuffer.FragmentIsBgraCount];
private readonly (TextureBase, Format)[] _images;
private TextureBase _unit0Texture;
private Sampler _unit0Sampler;
private FrontFaceDirection _frontFace;
private ClipOrigin _clipOrigin;
private ClipDepthMode _clipDepthMode;
private uint _fragmentOutputMap;
private uint _componentMasks;
private uint _currentComponentMasks;
private bool _advancedBlendEnable;
private uint _scissorEnables;
private bool _tfEnabled;
private TransformFeedbackPrimitiveType _tfTopology;
private readonly BufferHandle[] _tfbs;
private readonly BufferRange[] _tfbTargets;
private ColorF _blendConstant;
internal Pipeline()
{
_drawTexture = new DrawTextureEmulation();
_rasterizerDiscard = false;
_clipOrigin = ClipOrigin.LowerLeft;
_clipDepthMode = ClipDepthMode.NegativeOneToOne;
_fragmentOutputMap = uint.MaxValue;
_componentMasks = uint.MaxValue;
_images = new (TextureBase, Format)[SavedImages];
_tfbs = new BufferHandle[Constants.MaxTransformFeedbackBuffers];
_tfbTargets = new BufferRange[Constants.MaxTransformFeedbackBuffers];
}
public void Barrier()
{
GL.MemoryBarrier(MemoryBarrierFlags.AllBarrierBits);
}
public void BeginTransformFeedback(PrimitiveTopology topology)
{
GL.BeginTransformFeedback(_tfTopology = topology.ConvertToTfType());
_tfEnabled = true;
}
public void ClearBuffer(BufferHandle destination, int offset, int size, uint value)
{
Buffer.Clear(destination, offset, size, value);
}
public void ClearRenderTargetColor(int index, int layer, int layerCount, uint componentMask, ColorF color)
{
EnsureFramebuffer();
GL.ColorMask(
index,
(componentMask & 1) != 0,
(componentMask & 2) != 0,
(componentMask & 4) != 0,
(componentMask & 8) != 0);
float[] colors = new float[] { color.Red, color.Green, color.Blue, color.Alpha };
if (layer != 0 || layerCount != _framebuffer.GetColorLayerCount(index))
{
for (int l = layer; l < layer + layerCount; l++)
{
_framebuffer.AttachColorLayerForClear(index, l);
GL.ClearBuffer(OpenTK.Graphics.OpenGL.ClearBuffer.Color, index, colors);
}
_framebuffer.DetachColorLayerForClear(index);
}
else
{
GL.ClearBuffer(OpenTK.Graphics.OpenGL.ClearBuffer.Color, index, colors);
}
RestoreComponentMask(index);
}
public void ClearRenderTargetDepthStencil(int layer, int layerCount, float depthValue, bool depthMask, int stencilValue, int stencilMask)
{
EnsureFramebuffer();
bool stencilMaskChanged =
stencilMask != 0 &&
stencilMask != _stencilFrontMask;
bool depthMaskChanged = depthMask && depthMask != _depthMask;
if (stencilMaskChanged)
{
GL.StencilMaskSeparate(StencilFace.Front, stencilMask);
}
if (depthMaskChanged)
{
GL.DepthMask(depthMask);
}
if (layer != 0 || layerCount != _framebuffer.GetDepthStencilLayerCount())
{
for (int l = layer; l < layer + layerCount; l++)
{
_framebuffer.AttachDepthStencilLayerForClear(l);
ClearDepthStencil(depthValue, depthMask, stencilValue, stencilMask);
}
_framebuffer.DetachDepthStencilLayerForClear();
}
else
{
ClearDepthStencil(depthValue, depthMask, stencilValue, stencilMask);
}
if (stencilMaskChanged)
{
GL.StencilMaskSeparate(StencilFace.Front, _stencilFrontMask);
}
if (depthMaskChanged)
{
GL.DepthMask(_depthMask);
}
}
private static void ClearDepthStencil(float depthValue, bool depthMask, int stencilValue, int stencilMask)
{
if (depthMask && stencilMask != 0)
{
GL.ClearBuffer(ClearBufferCombined.DepthStencil, 0, depthValue, stencilValue);
}
else if (depthMask)
{
GL.ClearBuffer(OpenTK.Graphics.OpenGL.ClearBuffer.Depth, 0, ref depthValue);
}
else if (stencilMask != 0)
{
GL.ClearBuffer(OpenTK.Graphics.OpenGL.ClearBuffer.Stencil, 0, ref stencilValue);
}
}
public void CommandBufferBarrier()
{
GL.MemoryBarrier(MemoryBarrierFlags.CommandBarrierBit);
}
public void CopyBuffer(BufferHandle source, BufferHandle destination, int srcOffset, int dstOffset, int size)
{
Buffer.Copy(source, destination, srcOffset, dstOffset, size);
}
public void DispatchCompute(int groupsX, int groupsY, int groupsZ)
{
if (!_program.IsLinked)
{
Logger.Debug?.Print(LogClass.Gpu, "Dispatch error, shader not linked.");
return;
}
PrepareForDispatch();
GL.DispatchCompute(groupsX, groupsY, groupsZ);
}
public void Draw(int vertexCount, int instanceCount, int firstVertex, int firstInstance)
{
if (!_program.IsLinked)
{
Logger.Debug?.Print(LogClass.Gpu, "Draw error, shader not linked.");
return;
}
PreDraw(vertexCount);
if (_primitiveType == PrimitiveType.Quads && !HwCapabilities.SupportsQuads)
{
DrawQuadsImpl(vertexCount, instanceCount, firstVertex, firstInstance);
}
else if (_primitiveType == PrimitiveType.QuadStrip && !HwCapabilities.SupportsQuads)
{
DrawQuadStripImpl(vertexCount, instanceCount, firstVertex, firstInstance);
}
else
{
DrawImpl(vertexCount, instanceCount, firstVertex, firstInstance);
}
PostDraw();
}
private static void DrawQuadsImpl(
int vertexCount,
int instanceCount,
int firstVertex,
int firstInstance)
{
// TODO: Instanced rendering.
int quadsCount = vertexCount / 4;
int[] firsts = new int[quadsCount];
int[] counts = new int[quadsCount];
for (int quadIndex = 0; quadIndex < quadsCount; quadIndex++)
{
firsts[quadIndex] = firstVertex + quadIndex * 4;
counts[quadIndex] = 4;
}
GL.MultiDrawArrays(
PrimitiveType.TriangleFan,
firsts,
counts,
quadsCount);
}
private static void DrawQuadStripImpl(
int vertexCount,
int instanceCount,
int firstVertex,
int firstInstance)
{
int quadsCount = (vertexCount - 2) / 2;
if (firstInstance != 0 || instanceCount != 1)
{
for (int quadIndex = 0; quadIndex < quadsCount; quadIndex++)
{
GL.DrawArraysInstancedBaseInstance(PrimitiveType.TriangleFan, firstVertex + quadIndex * 2, 4, instanceCount, firstInstance);
}
}
else
{
int[] firsts = new int[quadsCount];
int[] counts = new int[quadsCount];
firsts[0] = firstVertex;
counts[0] = 4;
for (int quadIndex = 1; quadIndex < quadsCount; quadIndex++)
{
firsts[quadIndex] = firstVertex + quadIndex * 2;
counts[quadIndex] = 4;
}
GL.MultiDrawArrays(
PrimitiveType.TriangleFan,
firsts,
counts,
quadsCount);
}
}
private void DrawImpl(
int vertexCount,
int instanceCount,
int firstVertex,
int firstInstance)
{
if (firstInstance == 0 && instanceCount == 1)
{
GL.DrawArrays(_primitiveType, firstVertex, vertexCount);
}
else if (firstInstance == 0)
{
GL.DrawArraysInstanced(_primitiveType, firstVertex, vertexCount, instanceCount);
}
else
{
GL.DrawArraysInstancedBaseInstance(
_primitiveType,
firstVertex,
vertexCount,
instanceCount,
firstInstance);
}
}
public void DrawIndexed(
int indexCount,
int instanceCount,
int firstIndex,
int firstVertex,
int firstInstance)
{
if (!_program.IsLinked)
{
Logger.Debug?.Print(LogClass.Gpu, "Draw error, shader not linked.");
return;
}
PreDrawVbUnbounded();
int indexElemSize = 1;
switch (_elementsType)
{
case DrawElementsType.UnsignedShort:
indexElemSize = 2;
break;
case DrawElementsType.UnsignedInt:
indexElemSize = 4;
break;
}
IntPtr indexBaseOffset = _indexBaseOffset + firstIndex * indexElemSize;
if (_primitiveType == PrimitiveType.Quads && !HwCapabilities.SupportsQuads)
{
DrawQuadsIndexedImpl(
indexCount,
instanceCount,
indexBaseOffset,
indexElemSize,
firstVertex,
firstInstance);
}
else if (_primitiveType == PrimitiveType.QuadStrip && !HwCapabilities.SupportsQuads)
{
DrawQuadStripIndexedImpl(
indexCount,
instanceCount,
indexBaseOffset,
indexElemSize,
firstVertex,
firstInstance);
}
else
{
DrawIndexedImpl(
indexCount,
instanceCount,
indexBaseOffset,
firstVertex,
firstInstance);
}
PostDraw();
}
private void DrawQuadsIndexedImpl(
int indexCount,
int instanceCount,
IntPtr indexBaseOffset,
int indexElemSize,
int firstVertex,
int firstInstance)
{
int quadsCount = indexCount / 4;
if (firstInstance != 0 || instanceCount != 1)
{
if (firstVertex != 0 && firstInstance != 0)
{
for (int quadIndex = 0; quadIndex < quadsCount; quadIndex++)
{
GL.DrawElementsInstancedBaseVertexBaseInstance(
PrimitiveType.TriangleFan,
4,
_elementsType,
indexBaseOffset + quadIndex * 4 * indexElemSize,
instanceCount,
firstVertex,
firstInstance);
}
}
else if (firstInstance != 0)
{
for (int quadIndex = 0; quadIndex < quadsCount; quadIndex++)
{
GL.DrawElementsInstancedBaseInstance(
PrimitiveType.TriangleFan,
4,
_elementsType,
indexBaseOffset + quadIndex * 4 * indexElemSize,
instanceCount,
firstInstance);
}
}
else
{
for (int quadIndex = 0; quadIndex < quadsCount; quadIndex++)
{
GL.DrawElementsInstanced(
PrimitiveType.TriangleFan,
4,
_elementsType,
indexBaseOffset + quadIndex * 4 * indexElemSize,
instanceCount);
}
}
}
else
{
IntPtr[] indices = new IntPtr[quadsCount];
int[] counts = new int[quadsCount];
int[] baseVertices = new int[quadsCount];
for (int quadIndex = 0; quadIndex < quadsCount; quadIndex++)
{
indices[quadIndex] = indexBaseOffset + quadIndex * 4 * indexElemSize;
counts[quadIndex] = 4;
baseVertices[quadIndex] = firstVertex;
}
GL.MultiDrawElementsBaseVertex(
PrimitiveType.TriangleFan,
counts,
_elementsType,
indices,
quadsCount,
baseVertices);
}
}
private void DrawQuadStripIndexedImpl(
int indexCount,
int instanceCount,
IntPtr indexBaseOffset,
int indexElemSize,
int firstVertex,
int firstInstance)
{
// TODO: Instanced rendering.
int quadsCount = (indexCount - 2) / 2;
IntPtr[] indices = new IntPtr[quadsCount];
int[] counts = new int[quadsCount];
int[] baseVertices = new int[quadsCount];
indices[0] = indexBaseOffset;
counts[0] = 4;
baseVertices[0] = firstVertex;
for (int quadIndex = 1; quadIndex < quadsCount; quadIndex++)
{
indices[quadIndex] = indexBaseOffset + quadIndex * 2 * indexElemSize;
counts[quadIndex] = 4;
baseVertices[quadIndex] = firstVertex;
}
GL.MultiDrawElementsBaseVertex(
PrimitiveType.TriangleFan,
counts,
_elementsType,
indices,
quadsCount,
baseVertices);
}
private void DrawIndexedImpl(
int indexCount,
int instanceCount,
IntPtr indexBaseOffset,
int firstVertex,
int firstInstance)
{
if (firstInstance == 0 && firstVertex == 0 && instanceCount == 1)
{
GL.DrawElements(_primitiveType, indexCount, _elementsType, indexBaseOffset);
}
else if (firstInstance == 0 && instanceCount == 1)
{
GL.DrawElementsBaseVertex(
_primitiveType,
indexCount,
_elementsType,
indexBaseOffset,
firstVertex);
}
else if (firstInstance == 0 && firstVertex == 0)
{
GL.DrawElementsInstanced(
_primitiveType,
indexCount,
_elementsType,
indexBaseOffset,
instanceCount);
}
else if (firstInstance == 0)
{
GL.DrawElementsInstancedBaseVertex(
_primitiveType,
indexCount,
_elementsType,
indexBaseOffset,
instanceCount,
firstVertex);
}
else if (firstVertex == 0)
{
GL.DrawElementsInstancedBaseInstance(
_primitiveType,
indexCount,
_elementsType,
indexBaseOffset,
instanceCount,
firstInstance);
}
else
{
GL.DrawElementsInstancedBaseVertexBaseInstance(
_primitiveType,
indexCount,
_elementsType,
indexBaseOffset,
instanceCount,
firstVertex,
firstInstance);
}
}
public void DrawIndexedIndirect(BufferRange indirectBuffer)
{
if (!_program.IsLinked)
{
Logger.Debug?.Print(LogClass.Gpu, "Draw error, shader not linked.");
return;
}
PreDrawVbUnbounded();
_vertexArray.SetRangeOfIndexBuffer();
GL.BindBuffer((BufferTarget)All.DrawIndirectBuffer, indirectBuffer.Handle.ToInt32());
GL.DrawElementsIndirect(_primitiveType, _elementsType, (IntPtr)indirectBuffer.Offset);
_vertexArray.RestoreIndexBuffer();
PostDraw();
}
public void DrawIndexedIndirectCount(BufferRange indirectBuffer, BufferRange parameterBuffer, int maxDrawCount, int stride)
{
if (!_program.IsLinked)
{
Logger.Debug?.Print(LogClass.Gpu, "Draw error, shader not linked.");
return;
}
PreDrawVbUnbounded();
_vertexArray.SetRangeOfIndexBuffer();
GL.BindBuffer((BufferTarget)All.DrawIndirectBuffer, indirectBuffer.Handle.ToInt32());
GL.BindBuffer((BufferTarget)All.ParameterBuffer, parameterBuffer.Handle.ToInt32());
GL.MultiDrawElementsIndirectCount(
_primitiveType,
(All)_elementsType,
(IntPtr)indirectBuffer.Offset,
(IntPtr)parameterBuffer.Offset,
maxDrawCount,
stride);
_vertexArray.RestoreIndexBuffer();
PostDraw();
}
public void DrawIndirect(BufferRange indirectBuffer)
{
if (!_program.IsLinked)
{
Logger.Debug?.Print(LogClass.Gpu, "Draw error, shader not linked.");
return;
}
PreDrawVbUnbounded();
GL.BindBuffer((BufferTarget)All.DrawIndirectBuffer, indirectBuffer.Handle.ToInt32());
GL.DrawArraysIndirect(_primitiveType, (IntPtr)indirectBuffer.Offset);
PostDraw();
}
public void DrawIndirectCount(BufferRange indirectBuffer, BufferRange parameterBuffer, int maxDrawCount, int stride)
{
if (!_program.IsLinked)
{
Logger.Debug?.Print(LogClass.Gpu, "Draw error, shader not linked.");
return;
}
PreDrawVbUnbounded();
GL.BindBuffer((BufferTarget)All.DrawIndirectBuffer, indirectBuffer.Handle.ToInt32());
GL.BindBuffer((BufferTarget)All.ParameterBuffer, parameterBuffer.Handle.ToInt32());
GL.MultiDrawArraysIndirectCount(
_primitiveType,
(IntPtr)indirectBuffer.Offset,
(IntPtr)parameterBuffer.Offset,
maxDrawCount,
stride);
PostDraw();
}
public void DrawTexture(ITexture texture, ISampler sampler, Extents2DF srcRegion, Extents2DF dstRegion)
{
if (texture is TextureView view && sampler is Sampler samp)
{
if (HwCapabilities.SupportsDrawTexture)
{
GL.NV.DrawTexture(
view.Handle,
samp.Handle,
dstRegion.X1,
dstRegion.Y1,
dstRegion.X2,
dstRegion.Y2,
0,
srcRegion.X1 / view.Width,
srcRegion.Y1 / view.Height,
srcRegion.X2 / view.Width,
srcRegion.Y2 / view.Height);
}
else
{
static void Disable(EnableCap cap, bool enabled)
{
if (enabled)
{
GL.Disable(cap);
}
}
static void Enable(EnableCap cap, bool enabled)
{
if (enabled)
{
GL.Enable(cap);
}
}
Disable(EnableCap.CullFace, _cullEnable);
Disable(EnableCap.StencilTest, _stencilTestEnable);
Disable(EnableCap.DepthTest, _depthTestEnable);
if (_depthMask)
{
GL.DepthMask(false);
}
if (_tfEnabled)
{
GL.EndTransformFeedback();
}
GL.ClipControl(ClipOrigin.UpperLeft, ClipDepthMode.NegativeOneToOne);
_drawTexture.Draw(
view,
samp,
dstRegion.X1,
dstRegion.Y1,
dstRegion.X2,
dstRegion.Y2,
srcRegion.X1 / view.Width,
srcRegion.Y1 / view.Height,
srcRegion.X2 / view.Width,
srcRegion.Y2 / view.Height);
_program?.Bind();
_unit0Sampler?.Bind(0);
RestoreViewport0();
Enable(EnableCap.CullFace, _cullEnable);
Enable(EnableCap.StencilTest, _stencilTestEnable);
Enable(EnableCap.DepthTest, _depthTestEnable);
if (_depthMask)
{
GL.DepthMask(true);
}
if (_tfEnabled)
{
GL.BeginTransformFeedback(_tfTopology);
}
RestoreClipControl();
}
}
}
public void EndTransformFeedback()
{
GL.EndTransformFeedback();
_tfEnabled = false;
}
public void SetAlphaTest(bool enable, float reference, CompareOp op)
{
if (!enable)
{
GL.Disable(EnableCap.AlphaTest);
return;
}
GL.AlphaFunc((AlphaFunction)op.Convert(), reference);
GL.Enable(EnableCap.AlphaTest);
}
public void SetBlendState(AdvancedBlendDescriptor blend)
{
if (HwCapabilities.SupportsBlendEquationAdvanced)
{
GL.BlendEquation((BlendEquationMode)blend.Op.Convert());
GL.NV.BlendParameter(NvBlendEquationAdvanced.BlendOverlapNv, (int)blend.Overlap.Convert());
GL.NV.BlendParameter(NvBlendEquationAdvanced.BlendPremultipliedSrcNv, blend.SrcPreMultiplied ? 1 : 0);
GL.Enable(EnableCap.Blend);
_advancedBlendEnable = true;
}
}
public void SetBlendState(int index, BlendDescriptor blend)
{
if (_advancedBlendEnable)
{
GL.Disable(EnableCap.Blend);
_advancedBlendEnable = false;
}
if (!blend.Enable)
{
GL.Disable(IndexedEnableCap.Blend, index);
return;
}
GL.BlendEquationSeparate(
index,
blend.ColorOp.Convert(),
blend.AlphaOp.Convert());
GL.BlendFuncSeparate(
index,
(BlendingFactorSrc)blend.ColorSrcFactor.Convert(),
(BlendingFactorDest)blend.ColorDstFactor.Convert(),
(BlendingFactorSrc)blend.AlphaSrcFactor.Convert(),
(BlendingFactorDest)blend.AlphaDstFactor.Convert());
EnsureFramebuffer();
_framebuffer.SetDualSourceBlend(
blend.ColorSrcFactor.IsDualSource() ||
blend.ColorDstFactor.IsDualSource() ||
blend.AlphaSrcFactor.IsDualSource() ||
blend.AlphaDstFactor.IsDualSource());
if (_blendConstant != blend.BlendConstant)
{
_blendConstant = blend.BlendConstant;
GL.BlendColor(
blend.BlendConstant.Red,
blend.BlendConstant.Green,
blend.BlendConstant.Blue,
blend.BlendConstant.Alpha);
}
GL.Enable(IndexedEnableCap.Blend, index);
}
public void SetDepthBias(PolygonModeMask enables, float factor, float units, float clamp)
{
if ((enables & PolygonModeMask.Point) != 0)
{
GL.Enable(EnableCap.PolygonOffsetPoint);
}
else
{
GL.Disable(EnableCap.PolygonOffsetPoint);
}
if ((enables & PolygonModeMask.Line) != 0)
{
GL.Enable(EnableCap.PolygonOffsetLine);
}
else
{
GL.Disable(EnableCap.PolygonOffsetLine);
}
if ((enables & PolygonModeMask.Fill) != 0)
{
GL.Enable(EnableCap.PolygonOffsetFill);
}
else
{
GL.Disable(EnableCap.PolygonOffsetFill);
}
if (enables == 0)
{
return;
}
if (HwCapabilities.SupportsPolygonOffsetClamp)
{
GL.PolygonOffsetClamp(factor, units, clamp);
}
else
{
GL.PolygonOffset(factor, units);
}
}
public void SetDepthClamp(bool clamp)
{
if (!clamp)
{
GL.Disable(EnableCap.DepthClamp);
return;
}
GL.Enable(EnableCap.DepthClamp);
}
public void SetDepthMode(DepthMode mode)
{
ClipDepthMode depthMode = mode.Convert();
if (_clipDepthMode != depthMode)
{
_clipDepthMode = depthMode;
GL.ClipControl(_clipOrigin, depthMode);
}
}
public void SetDepthTest(DepthTestDescriptor depthTest)
{
if (depthTest.TestEnable)
{
GL.Enable(EnableCap.DepthTest);
GL.DepthFunc((DepthFunction)depthTest.Func.Convert());
}
else
{
GL.Disable(EnableCap.DepthTest);
}
GL.DepthMask(depthTest.WriteEnable);
_depthMask = depthTest.WriteEnable;
_depthTestEnable = depthTest.TestEnable;
}
public void SetFaceCulling(bool enable, Face face)
{
_cullEnable = enable;
if (!enable)
{
GL.Disable(EnableCap.CullFace);
return;
}
GL.CullFace(face.Convert());
GL.Enable(EnableCap.CullFace);
}
public void SetFrontFace(FrontFace frontFace)
{
SetFrontFace(_frontFace = frontFace.Convert());
}
public void SetImage(ShaderStage stage, int binding, ITexture texture, Format imageFormat)
{
if ((uint)binding < SavedImages)
{
_images[binding] = (texture as TextureBase, imageFormat);
}
if (texture == null)
{
GL.BindImageTexture(binding, 0, 0, true, 0, TextureAccess.ReadWrite, SizedInternalFormat.Rgba8);
return;
}
TextureBase texBase = (TextureBase)texture;
SizedInternalFormat format = FormatTable.GetImageFormat(imageFormat);
if (format != 0)
{
GL.BindImageTexture(binding, texBase.Handle, 0, true, 0, TextureAccess.ReadWrite, format);
}
}
public void SetImageArray(ShaderStage stage, int binding, IImageArray array)
{
(array as ImageArray).Bind(binding);
}
public void SetImageArraySeparate(ShaderStage stage, int setIndex, IImageArray array)
{
throw new NotSupportedException("OpenGL does not support descriptor sets.");
}
public void SetIndexBuffer(BufferRange buffer, IndexType type)
{
_elementsType = type.Convert();
_indexBaseOffset = (IntPtr)buffer.Offset;
EnsureVertexArray();
_vertexArray.SetIndexBuffer(buffer);
}
public void SetLogicOpState(bool enable, LogicalOp op)
{
if (enable)
{
GL.Enable(EnableCap.ColorLogicOp);
GL.LogicOp((LogicOp)op.Convert());
}
else
{
GL.Disable(EnableCap.ColorLogicOp);
}
}
public void SetMultisampleState(MultisampleDescriptor multisample)
{
if (multisample.AlphaToCoverageEnable)
{
GL.Enable(EnableCap.SampleAlphaToCoverage);
if (multisample.AlphaToOneEnable)
{
GL.Enable(EnableCap.SampleAlphaToOne);
}
else
{
GL.Disable(EnableCap.SampleAlphaToOne);
}
if (HwCapabilities.SupportsAlphaToCoverageDitherControl)
{
GL.NV.AlphaToCoverageDitherControl(multisample.AlphaToCoverageDitherEnable
? NvAlphaToCoverageDitherControl.AlphaToCoverageDitherEnableNv
: NvAlphaToCoverageDitherControl.AlphaToCoverageDitherDisableNv);
}
}
else
{
GL.Disable(EnableCap.SampleAlphaToCoverage);
}
}
public void SetLineParameters(float width, bool smooth)
{
if (smooth)
{
GL.Enable(EnableCap.LineSmooth);
}
else
{
GL.Disable(EnableCap.LineSmooth);
}
GL.LineWidth(width);
}
public unsafe void SetPatchParameters(int vertices, ReadOnlySpan<float> defaultOuterLevel, ReadOnlySpan<float> defaultInnerLevel)
{
GL.PatchParameter(PatchParameterInt.PatchVertices, vertices);
fixed (float* pOuterLevel = defaultOuterLevel)
{
GL.PatchParameter(PatchParameterFloat.PatchDefaultOuterLevel, pOuterLevel);
}
fixed (float* pInnerLevel = defaultInnerLevel)
{
GL.PatchParameter(PatchParameterFloat.PatchDefaultInnerLevel, pInnerLevel);
}
}
public void SetPointParameters(float size, bool isProgramPointSize, bool enablePointSprite, Origin origin)
{
// GL_POINT_SPRITE was deprecated in core profile 3.2+ and causes GL_INVALID_ENUM when set.
// As we don't know if the current context is core or compat, it's safer to keep this code.
if (enablePointSprite)
{
GL.Enable(EnableCap.PointSprite);
}
else
{
GL.Disable(EnableCap.PointSprite);
}
if (isProgramPointSize)
{
GL.Enable(EnableCap.ProgramPointSize);
}
else
{
GL.Disable(EnableCap.ProgramPointSize);
}
GL.PointParameter(origin == Origin.LowerLeft
? PointSpriteCoordOriginParameter.LowerLeft
: PointSpriteCoordOriginParameter.UpperLeft);
// Games seem to set point size to 0 which generates a GL_INVALID_VALUE
// From the spec, GL_INVALID_VALUE is generated if size is less than or equal to 0.
GL.PointSize(Math.Max(float.Epsilon, size));
}
public void SetPolygonMode(GAL.PolygonMode frontMode, GAL.PolygonMode backMode)
{
if (frontMode == backMode)
{
GL.PolygonMode(MaterialFace.FrontAndBack, frontMode.Convert());
}
else
{
GL.PolygonMode(MaterialFace.Front, frontMode.Convert());
GL.PolygonMode(MaterialFace.Back, backMode.Convert());
}
}
public void SetPrimitiveRestart(bool enable, int index)
{
if (!enable)
{
GL.Disable(EnableCap.PrimitiveRestart);
return;
}
GL.PrimitiveRestartIndex(index);
GL.Enable(EnableCap.PrimitiveRestart);
}
public void SetPrimitiveTopology(PrimitiveTopology topology)
{
_primitiveType = topology.Convert();
}
public void SetProgram(IProgram program)
{
Program prg = (Program)program;
if (_tfEnabled)
{
GL.EndTransformFeedback();
prg.Bind();
GL.BeginTransformFeedback(_tfTopology);
}
else
{
prg.Bind();
}
if (_fragmentOutputMap != (uint)prg.FragmentOutputMap)
{
_fragmentOutputMap = (uint)prg.FragmentOutputMap;
for (int index = 0; index < Constants.MaxRenderTargets; index++)
{
RestoreComponentMask(index, force: false);
}
}
_program = prg;
}
public void SetRasterizerDiscard(bool discard)
{
if (discard)
{
GL.Enable(EnableCap.RasterizerDiscard);
}
else
{
GL.Disable(EnableCap.RasterizerDiscard);
}
_rasterizerDiscard = discard;
}
public void SetRenderTargetColorMasks(ReadOnlySpan<uint> componentMasks)
{
_componentMasks = 0;
for (int index = 0; index < componentMasks.Length; index++)
{
_componentMasks |= componentMasks[index] << (index * 4);
RestoreComponentMask(index, force: false);
}
}
public void SetRenderTargets(ITexture[] colors, ITexture depthStencil)
{
EnsureFramebuffer();
for (int index = 0; index < colors.Length; index++)
{
TextureView color = (TextureView)colors[index];
_framebuffer.AttachColor(index, color);
if (color != null)
{
int isBgra = color.Format.IsBgr() ? 1 : 0;
if (_fpIsBgra[index].X != isBgra)
{
_fpIsBgra[index].X = isBgra;
RestoreComponentMask(index);
}
}
}
TextureView depthStencilView = (TextureView)depthStencil;
_framebuffer.AttachDepthStencil(depthStencilView);
_framebuffer.SetDrawBuffers(colors.Length);
}
public void SetScissors(ReadOnlySpan<Rectangle<int>> regions)
{
int count = Math.Min(regions.Length, Constants.MaxViewports);
Span<int> v = stackalloc int[count * 4];
for (int index = 0; index < count; index++)
{
int vIndex = index * 4;
var region = regions[index];
bool enabled = (region.X | region.Y) != 0 || region.Width != 0xffff || region.Height != 0xffff;
uint mask = 1u << index;
if (enabled)
{
v[vIndex] = region.X;
v[vIndex + 1] = region.Y;
v[vIndex + 2] = region.Width;
v[vIndex + 3] = region.Height;
if ((_scissorEnables & mask) == 0)
{
_scissorEnables |= mask;
GL.Enable(IndexedEnableCap.ScissorTest, index);
}
}
else
{
if ((_scissorEnables & mask) != 0)
{
_scissorEnables &= ~mask;
GL.Disable(IndexedEnableCap.ScissorTest, index);
}
}
}
GL.ScissorArray(0, count, ref v[0]);
}
public void SetStencilTest(StencilTestDescriptor stencilTest)
{
_stencilTestEnable = stencilTest.TestEnable;
if (!stencilTest.TestEnable)
{
GL.Disable(EnableCap.StencilTest);
return;
}
GL.StencilOpSeparate(
StencilFace.Front,
stencilTest.FrontSFail.Convert(),
stencilTest.FrontDpFail.Convert(),
stencilTest.FrontDpPass.Convert());
GL.StencilFuncSeparate(
StencilFace.Front,
(StencilFunction)stencilTest.FrontFunc.Convert(),
stencilTest.FrontFuncRef,
stencilTest.FrontFuncMask);
GL.StencilMaskSeparate(StencilFace.Front, stencilTest.FrontMask);
GL.StencilOpSeparate(
StencilFace.Back,
stencilTest.BackSFail.Convert(),
stencilTest.BackDpFail.Convert(),
stencilTest.BackDpPass.Convert());
GL.StencilFuncSeparate(
StencilFace.Back,
(StencilFunction)stencilTest.BackFunc.Convert(),
stencilTest.BackFuncRef,
stencilTest.BackFuncMask);
GL.StencilMaskSeparate(StencilFace.Back, stencilTest.BackMask);
GL.Enable(EnableCap.StencilTest);
_stencilFrontMask = stencilTest.FrontMask;
}
public void SetStorageBuffers(ReadOnlySpan<BufferAssignment> buffers)
{
SetBuffers(buffers, isStorage: true);
}
public void SetTextureAndSampler(ShaderStage stage, int binding, ITexture texture, ISampler sampler)
{
if (texture != null)
{
if (binding == 0)
{
_unit0Texture = (TextureBase)texture;
}
else
{
((TextureBase)texture).Bind(binding);
}
}
else
{
TextureBase.ClearBinding(binding);
}
Sampler glSampler = (Sampler)sampler;
glSampler?.Bind(binding);
if (binding == 0)
{
_unit0Sampler = glSampler;
}
}
public void SetTextureArray(ShaderStage stage, int binding, ITextureArray array)
{
(array as TextureArray).Bind(binding);
}
public void SetTextureArraySeparate(ShaderStage stage, int setIndex, ITextureArray array)
{
throw new NotSupportedException("OpenGL does not support descriptor sets.");
}
public void SetTransformFeedbackBuffers(ReadOnlySpan<BufferRange> buffers)
{
if (_tfEnabled)
{
GL.EndTransformFeedback();
}
int count = Math.Min(buffers.Length, Constants.MaxTransformFeedbackBuffers);
for (int i = 0; i < count; i++)
{
BufferRange buffer = buffers[i];
_tfbTargets[i] = buffer;
if (buffer.Handle == BufferHandle.Null)
{
GL.BindBufferBase(BufferRangeTarget.TransformFeedbackBuffer, i, 0);
continue;
}
if (_tfbs[i] == BufferHandle.Null)
{
_tfbs[i] = Buffer.Create();
}
Buffer.Resize(_tfbs[i], buffer.Size);
Buffer.Copy(buffer.Handle, _tfbs[i], buffer.Offset, 0, buffer.Size);
GL.BindBufferBase(BufferRangeTarget.TransformFeedbackBuffer, i, _tfbs[i].ToInt32());
}
if (_tfEnabled)
{
GL.BeginTransformFeedback(_tfTopology);
}
}
public void SetUniformBuffers(ReadOnlySpan<BufferAssignment> buffers)
{
SetBuffers(buffers, isStorage: false);
}
public void SetUserClipDistance(int index, bool enableClip)
{
if (!enableClip)
{
GL.Disable(EnableCap.ClipDistance0 + index);
return;
}
GL.Enable(EnableCap.ClipDistance0 + index);
}
public void SetVertexAttribs(ReadOnlySpan<VertexAttribDescriptor> vertexAttribs)
{
EnsureVertexArray();
_vertexArray.SetVertexAttributes(vertexAttribs);
}
public void SetVertexBuffers(ReadOnlySpan<VertexBufferDescriptor> vertexBuffers)
{
EnsureVertexArray();
_vertexArray.SetVertexBuffers(vertexBuffers);
}
public void SetViewports(ReadOnlySpan<Viewport> viewports)
{
Array.Resize(ref _viewportArray, viewports.Length * 4);
Array.Resize(ref _depthRangeArray, viewports.Length * 2);
float[] viewportArray = _viewportArray;
double[] depthRangeArray = _depthRangeArray;
for (int index = 0; index < viewports.Length; index++)
{
int viewportElemIndex = index * 4;
Viewport viewport = viewports[index];
viewportArray[viewportElemIndex + 0] = viewport.Region.X;
viewportArray[viewportElemIndex + 1] = viewport.Region.Y + (viewport.Region.Height < 0 ? viewport.Region.Height : 0);
viewportArray[viewportElemIndex + 2] = viewport.Region.Width;
viewportArray[viewportElemIndex + 3] = MathF.Abs(viewport.Region.Height);
if (HwCapabilities.SupportsViewportSwizzle)
{
GL.NV.ViewportSwizzle(
index,
viewport.SwizzleX.Convert(),
viewport.SwizzleY.Convert(),
viewport.SwizzleZ.Convert(),
viewport.SwizzleW.Convert());
}
depthRangeArray[index * 2 + 0] = viewport.DepthNear;
depthRangeArray[index * 2 + 1] = viewport.DepthFar;
}
bool flipY = viewports.Length != 0 && viewports[0].Region.Height < 0;
SetOrigin(flipY ? ClipOrigin.UpperLeft : ClipOrigin.LowerLeft);
GL.ViewportArray(0, viewports.Length, viewportArray);
GL.DepthRangeArray(0, viewports.Length, depthRangeArray);
}
public void TextureBarrier()
{
GL.MemoryBarrier(MemoryBarrierFlags.TextureFetchBarrierBit);
}
public void TextureBarrierTiled()
{
GL.MemoryBarrier(MemoryBarrierFlags.TextureFetchBarrierBit);
}
private static void SetBuffers(ReadOnlySpan<BufferAssignment> buffers, bool isStorage)
{
BufferRangeTarget target = isStorage ? BufferRangeTarget.ShaderStorageBuffer : BufferRangeTarget.UniformBuffer;
for (int index = 0; index < buffers.Length; index++)
{
BufferAssignment assignment = buffers[index];
BufferRange buffer = assignment.Range;
if (buffer.Handle == BufferHandle.Null)
{
GL.BindBufferRange(target, assignment.Binding, 0, IntPtr.Zero, 0);
continue;
}
GL.BindBufferRange(target, assignment.Binding, buffer.Handle.ToInt32(), (IntPtr)buffer.Offset, buffer.Size);
}
}
private void SetOrigin(ClipOrigin origin)
{
if (_clipOrigin != origin)
{
_clipOrigin = origin;
GL.ClipControl(origin, _clipDepthMode);
SetFrontFace(_frontFace);
}
}
private void SetFrontFace(FrontFaceDirection frontFace)
{
// Changing clip origin will also change the front face to compensate
// for the flipped viewport, we flip it again here to compensate as
// this effect is undesirable for us.
if (_clipOrigin == ClipOrigin.UpperLeft)
{
frontFace = frontFace == FrontFaceDirection.Ccw ? FrontFaceDirection.Cw : FrontFaceDirection.Ccw;
}
GL.FrontFace(frontFace);
}
private void EnsureVertexArray()
{
if (_vertexArray == null)
{
_vertexArray = new VertexArray();
_vertexArray.Bind();
}
}
private void EnsureFramebuffer()
{
if (_framebuffer == null)
{
_framebuffer = new Framebuffer();
int boundHandle = _framebuffer.Bind();
_boundDrawFramebuffer = _boundReadFramebuffer = boundHandle;
GL.Enable(EnableCap.FramebufferSrgb);
}
}
internal (int drawHandle, int readHandle) GetBoundFramebuffers()
{
if (BackgroundContextWorker.InBackground)
{
return (0, 0);
}
return (_boundDrawFramebuffer, _boundReadFramebuffer);
}
private void PrepareForDispatch()
{
_unit0Texture?.Bind(0);
}
private void PreDraw(int vertexCount)
{
_vertexArray.PreDraw(vertexCount);
PreDraw();
}
private void PreDrawVbUnbounded()
{
_vertexArray.PreDrawVbUnbounded();
PreDraw();
}
private void PreDraw()
{
DrawCount++;
_unit0Texture?.Bind(0);
}
private void PostDraw()
{
if (_tfEnabled)
{
for (int i = 0; i < Constants.MaxTransformFeedbackBuffers; i++)
{
if (_tfbTargets[i].Handle != BufferHandle.Null)
{
Buffer.Copy(_tfbs[i], _tfbTargets[i].Handle, 0, _tfbTargets[i].Offset, _tfbTargets[i].Size);
}
}
}
}
public void RestoreComponentMask(int index, bool force = true)
{
// If the bound render target is bgra, swap the red and blue masks.
uint redMask = _fpIsBgra[index].X == 0 ? 1u : 4u;
uint blueMask = _fpIsBgra[index].X == 0 ? 4u : 1u;
int shift = index * 4;
uint componentMask = _componentMasks & _fragmentOutputMap;
uint checkMask = 0xfu << shift;
uint componentMaskAtIndex = componentMask & checkMask;
if (!force && componentMaskAtIndex == (_currentComponentMasks & checkMask))
{
return;
}
componentMask >>= shift;
componentMask &= 0xfu;
GL.ColorMask(
index,
(componentMask & redMask) != 0,
(componentMask & 2u) != 0,
(componentMask & blueMask) != 0,
(componentMask & 8u) != 0);
_currentComponentMasks &= ~checkMask;
_currentComponentMasks |= componentMaskAtIndex;
}
public void RestoreClipControl()
{
GL.ClipControl(_clipOrigin, _clipDepthMode);
}
public void RestoreScissor0Enable()
{
if ((_scissorEnables & 1u) != 0)
{
GL.Enable(IndexedEnableCap.ScissorTest, 0);
}
}
public void RestoreRasterizerDiscard()
{
if (_rasterizerDiscard)
{
GL.Enable(EnableCap.RasterizerDiscard);
}
}
public void RestoreViewport0()
{
if (_viewportArray.Length > 0)
{
GL.ViewportArray(0, 1, _viewportArray);
}
}
public void RestoreProgram()
{
_program?.Bind();
}
public void RestoreImages1And2()
{
for (int i = 0; i < SavedImages; i++)
{
(TextureBase texBase, Format imageFormat) = _images[i];
if (texBase != null)
{
SizedInternalFormat format = FormatTable.GetImageFormat(imageFormat);
if (format != 0)
{
GL.BindImageTexture(i, texBase.Handle, 0, true, 0, TextureAccess.ReadWrite, format);
continue;
}
}
GL.BindImageTexture(i, 0, 0, true, 0, TextureAccess.ReadWrite, SizedInternalFormat.Rgba8);
}
}
public bool TryHostConditionalRendering(ICounterEvent value, ulong compare, bool isEqual)
{
// Compare an event and a constant value.
if (value is CounterQueueEvent evt)
{
// Easy host conditional rendering when the check matches what GL can do:
// - Event is of type samples passed.
// - Result is not a combination of multiple queries.
// - Comparing against 0.
// - Event has not already been flushed.
if (compare == 0 && evt.Type == QueryTarget.SamplesPassed && evt.ClearCounter)
{
if (!value.ReserveForHostAccess())
{
// If the event has been flushed, then just use the values on the CPU.
// The query object may already be repurposed for another draw (eg. begin + end).
return false;
}
GL.BeginConditionalRender(evt.Query, isEqual ? ConditionalRenderType.QueryNoWaitInverted : ConditionalRenderType.QueryNoWait);
_activeConditionalRender = evt;
return true;
}
}
// The GPU will flush the queries to CPU and evaluate the condition there instead.
GL.Flush(); // The thread will be stalled manually flushing the counter, so flush GL commands now.
return false;
}
public bool TryHostConditionalRendering(ICounterEvent value, ICounterEvent compare, bool isEqual)
{
GL.Flush(); // The GPU thread will be stalled manually flushing the counter, so flush GL commands now.
return false; // We don't currently have a way to compare two counters for conditional rendering.
}
public void EndHostConditionalRendering()
{
GL.EndConditionalRender();
_activeConditionalRender?.ReleaseHostAccess();
_activeConditionalRender = null;
}
public void Dispose()
{
for (int i = 0; i < Constants.MaxTransformFeedbackBuffers; i++)
{
if (_tfbs[i] != BufferHandle.Null)
{
Buffer.Delete(_tfbs[i]);
_tfbs[i] = BufferHandle.Null;
}
}
_activeConditionalRender?.ReleaseHostAccess();
_framebuffer?.Dispose();
_vertexArray?.Dispose();
_drawTexture.Dispose();
}
}
}