virtual void ReleaseRHI() override
{
DEC_DWORD_STAT_BY( STAT_TextureMemory, TextureSize );
DEC_DWORD_STAT_FNAME_BY( LODGroupStatName, TextureSize );
RHIUpdateTextureReference(Owner->TextureReference.TextureReferenceRHI,FTextureRHIParamRef());
TextureCubeRHI.SafeRelease();
FTextureResource::ReleaseRHI();
}
void FMediaTextureResource::ReleaseDynamicRHI()
{
// release the FTexture RHI resources here as well
ReleaseRHI();
RHIUpdateTextureReference(Owner->TextureReference.TextureReferenceRHI, FTextureRHIParamRef());
Texture2DRHI.SafeRelease();
RenderTargetTextureRHI.SafeRelease();
// remove from global list of deferred updates
RemoveFromDeferredUpdateList();
}
void FRCPassPostProcessDOFSetup::Process(FRenderingCompositePassContext& Context)
{
SCOPED_DRAW_EVENT(Context.RHICmdList, DOFSetup);
const FPooledRenderTargetDesc* InputDesc = GetInputDesc(ePId_Input0);
if(!InputDesc)
{
// input is not hooked up correctly
return;
}
uint32 NumRenderTargets = bNearBlurEnabled ? 2 : 1;
const FSceneView& View = Context.View;
const FSceneViewFamily& ViewFamily = *(View.Family);
const auto FeatureLevel = Context.GetFeatureLevel();
auto ShaderMap = Context.GetShaderMap();
FIntPoint SrcSize = InputDesc->Extent;
FIntPoint DestSize = PassOutputs[0].RenderTargetDesc.Extent;
// e.g. 4 means the input texture is 4x smaller than the buffer size
uint32 ScaleFactor = FSceneRenderTargets::Get(Context.RHICmdList).GetBufferSizeXY().X / SrcSize.X;
FIntRect SrcRect = View.ViewRect / ScaleFactor;
FIntRect DestRect = SrcRect / 2;
const FSceneRenderTargetItem& DestRenderTarget0 = PassOutputs[0].RequestSurface(Context);
const FSceneRenderTargetItem& DestRenderTarget1 = bNearBlurEnabled ? PassOutputs[1].RequestSurface(Context) : FSceneRenderTargetItem();
// Set the view family's render target/viewport.
FTextureRHIParamRef RenderTargets[2] =
{
DestRenderTarget0.TargetableTexture,
DestRenderTarget1.TargetableTexture
};
SetRenderTargets(Context.RHICmdList, NumRenderTargets, RenderTargets, FTextureRHIParamRef(), 0, NULL);
FLinearColor ClearColors[2] =
{
FLinearColor(0, 0, 0, 0),
FLinearColor(0, 0, 0, 0)
};
// is optimized away if possible (RT size=view size, )
Context.RHICmdList.ClearMRT(true, NumRenderTargets, ClearColors, false, 1.0f, false, 0, DestRect);
Context.SetViewportAndCallRHI(0, 0, 0.0f, DestSize.X, DestSize.Y, 1.0f );
// set the state
Context.RHICmdList.SetBlendState(TStaticBlendState<>::GetRHI());
Context.RHICmdList.SetRasterizerState(TStaticRasterizerState<>::GetRHI());
Context.RHICmdList.SetDepthStencilState(TStaticDepthStencilState<false, CF_Always>::GetRHI());
TShaderMapRef<FPostProcessVS> VertexShader(ShaderMap);
if (bNearBlurEnabled)
{
static FGlobalBoundShaderState BoundShaderState;
TShaderMapRef< FPostProcessDOFSetupPS<1> > PixelShader(ShaderMap);
SetGlobalBoundShaderState(Context.RHICmdList, FeatureLevel, BoundShaderState, GFilterVertexDeclaration.VertexDeclarationRHI, *VertexShader, *PixelShader);
PixelShader->SetParameters(Context);
}
else
{
static FGlobalBoundShaderState BoundShaderState;
TShaderMapRef< FPostProcessDOFSetupPS<0> > PixelShader(ShaderMap);
SetGlobalBoundShaderState(Context.RHICmdList, FeatureLevel, BoundShaderState, GFilterVertexDeclaration.VertexDeclarationRHI, *VertexShader, *PixelShader);
PixelShader->SetParameters(Context);
}
VertexShader->SetParameters(Context);
DrawPostProcessPass(
Context.RHICmdList,
DestRect.Min.X, DestRect.Min.Y,
DestRect.Width() + 1, DestRect.Height() + 1,
SrcRect.Min.X, SrcRect.Min.Y,
SrcRect.Width() + 1, SrcRect.Height() + 1,
DestSize,
SrcSize,
*VertexShader,
View.StereoPass,
Context.HasHmdMesh(),
EDRF_UseTriangleOptimization);
Context.RHICmdList.CopyToResolveTarget(DestRenderTarget0.TargetableTexture, DestRenderTarget0.ShaderResourceTexture, false, FResolveParams());
Context.RHICmdList.CopyToResolveTarget(DestRenderTarget1.TargetableTexture, DestRenderTarget1.ShaderResourceTexture, false, FResolveParams());
}
void UnbindBuffers(FRHICommandList& RHICmdList)
{
// TODO: Is this necessary here?
FPixelShaderRHIParamRef ShaderRHI = GetPixelShader();
#if LPV_VOLUME_TEXTURE
for ( int i=0; i<7; i++ )
{
if ( LpvBufferSRVParameters[i].IsBound() )
{
RHICmdList.SetShaderTexture(ShaderRHI, LpvBufferSRVParameters[i].GetBaseIndex(), FTextureRHIParamRef());
}
}
#else
if ( InLpvBuffer.IsBound() ) RHICmdList.SetShaderResourceViewParameter( ShaderRHI, InLpvBuffer.GetBaseIndex(), FShaderResourceViewRHIParamRef() );
#endif
#if LPV_GV_VOLUME_TEXTURE
for ( int i=0; i<3; i++ )
{
if ( GvBufferSRVParameters[i].IsBound() )
{
RHICmdList.SetShaderTexture(ShaderRHI, GvBufferSRVParameters[i].GetBaseIndex(), FTextureRHIParamRef());
}
}
#else
if ( InGvBuffer.IsBound() ) RHICmdList.SetShaderResourceViewParameter( ShaderRHI, InGvBuffer.GetBaseIndex(), FShaderResourceViewRHIParamRef() );
#endif
}
/** Called when the resource is released. This is only called by the rendering thread. */
void FTexture2DDynamicResource::ReleaseRHI()
{
RHIUpdateTextureReference(Owner->TextureReference.TextureReferenceRHI,FTextureRHIParamRef());
FTextureResource::ReleaseRHI();
Texture2DRHI.SafeRelease();
}
checkSlow( RenderTargetResource );
TArray< TSharedPtr<FSlateWindowElementList> >& WindowsToDraw = WindowDrawBuffer.GetWindowElementLists();
// Enqueue a command to unlock the draw buffer after all windows have been drawn
ENQUEUE_UNIQUE_RENDER_COMMAND_ONEPARAMETER(SlateBeginDrawingWindowsCommand,
FSlateRHIRenderingPolicy&, Policy, *RenderTargetPolicy,
{
Policy.BeginDrawingWindows();
});
// Set render target and clear.
FTexture2DRHIRef RTResource = RenderTargetResource->GetTextureRHI();
FRHIRenderTargetView ColorRTV(RTResource);
ColorRTV.LoadAction = ERenderTargetLoadAction::EClear;
FRHISetRenderTargetsInfo Info(1, &ColorRTV, FTextureRHIParamRef());
Info.bClearColor = bInClearTarget;
InRHICmdList.TransitionResource(EResourceTransitionAccess::EWritable, RTResource);
InRHICmdList.SetRenderTargetsAndClear(Info);
for ( int32 WindowIndex = 0; WindowIndex < WindowsToDraw.Num(); WindowIndex++ )
{
FSlateWindowElementList& WindowElementList = *WindowsToDraw[WindowIndex].Get();
FSlateBatchData& BatchData = WindowElementList.GetBatchData();
FElementBatchMap& RootBatchMap = WindowElementList.GetRootDrawLayer().GetElementBatchMap();
WindowElementList.PreDraw_ParallelThread();
BatchData.CreateRenderBatches(RootBatchMap);
void FRCPassPostProcessMotionBlurSetup::Process(FRenderingCompositePassContext& Context)
{
SCOPED_DRAW_EVENT(MotionBlurSetup, DEC_SCENE_ITEMS);
const FPooledRenderTargetDesc* InputDesc = GetInputDesc(ePId_Input0);
if(!InputDesc)
{
// input is not hooked up correctly
return;
}
const FSceneView& View = Context.View;
const FSceneViewFamily& ViewFamily = *(View.Family);
FIntPoint SrcSize = InputDesc->Extent;
FIntPoint DestSize = PassOutputs[0].RenderTargetDesc.Extent;
// e.g. 4 means the input texture is 4x smaller than the buffer size
uint32 ScaleFactor = GSceneRenderTargets.GetBufferSizeXY().X / SrcSize.X;
FIntRect SrcRect = View.ViewRect / ScaleFactor;
// Viewport size not even also causes issue
FIntRect DestRect = FIntRect::DivideAndRoundUp(SrcRect, 2);
const FSceneRenderTargetItem& DestRenderTarget0 = PassOutputs[0].RequestSurface(Context);
const FSceneRenderTargetItem& DestRenderTarget1 = PassOutputs[1].RequestSurface(Context);
// Set the view family's render target/viewport.
FTextureRHIParamRef RenderTargets[] =
{
DestRenderTarget0.TargetableTexture,
DestRenderTarget1.TargetableTexture
};
RHISetRenderTargets( ARRAY_COUNT(RenderTargets), RenderTargets, FTextureRHIParamRef(), 0, NULL );
// is optimized away if possible (RT size=view size, )
FLinearColor ClearColors[2] = {FLinearColor(0,0,0,0), FLinearColor(0,0,0,0)};
RHIClearMRT(true, 2, ClearColors, false, 1.0f, false, 0, DestRect);
Context.SetViewportAndCallRHI(0, 0, 0.0f, DestSize.X, DestSize.Y, 1.0f );
// set the state
RHISetBlendState(TStaticBlendState<>::GetRHI());
RHISetRasterizerState(TStaticRasterizerState<>::GetRHI());
RHISetDepthStencilState(TStaticDepthStencilState<false,CF_Always>::GetRHI());
{
TShaderMapRef<FPostProcessVS> VertexShader(GetGlobalShaderMap());
TShaderMapRef<FPostProcessMotionBlurSetupPS > PixelShader(GetGlobalShaderMap());
static FGlobalBoundShaderState BoundShaderState;
SetGlobalBoundShaderState(BoundShaderState, GFilterVertexDeclaration.VertexDeclarationRHI, *VertexShader, *PixelShader);
PixelShader->SetParameters(Context);
VertexShader->SetParameters(Context);
}
// Draw a quad mapping scene color to the view's render target
DrawRectangle(
DestRect.Min.X, DestRect.Min.Y,
DestRect.Width(), DestRect.Height(),
SrcRect.Min.X, SrcRect.Min.Y,
SrcRect.Width(), SrcRect.Height(),
DestSize,
SrcSize,
EDRF_UseTriangleOptimization);
RHICopyToResolveTarget(DestRenderTarget0.TargetableTexture, DestRenderTarget0.ShaderResourceTexture, false, FResolveParams());
RHICopyToResolveTarget(DestRenderTarget1.TargetableTexture, DestRenderTarget1.ShaderResourceTexture, false, FResolveParams());
}
void FRCPassPostProcessMaterial::Process(FRenderingCompositePassContext& Context)
{
FMaterialRenderProxy* Proxy = MaterialInterface->GetRenderProxy(false);
check(Proxy);
const FMaterial* Material = Proxy->GetMaterial(Context.View.GetFeatureLevel());
check(Material);
SCOPED_DRAW_EVENTF(Context.RHICmdList, PostProcessMaterial, TEXT("PostProcessMaterial Material=%s"), *Material->GetFriendlyName());
const FPooledRenderTargetDesc* InputDesc = GetInputDesc(ePId_Input0);
if(!InputDesc)
{
// input is not hooked up correctly
return;
}
const FSceneView& View = Context.View;
const FSceneViewFamily& ViewFamily = *(View.Family);
// hacky cast
FRenderingCompositePassContext RenderingCompositePassContext(Context.RHICmdList, (FViewInfo&)View);
RenderingCompositePassContext.Pass = this;
FIntRect SrcRect = View.ViewRect;
FIntRect DestRect = View.ViewRect;
FIntPoint SrcSize = InputDesc->Extent;
const FSceneRenderTargetItem& DestRenderTarget = PassOutputs[0].RequestSurface(Context);
// Set the view family's render target/viewport.
SetRenderTarget(Context.RHICmdList, DestRenderTarget.TargetableTexture, FTextureRHIParamRef());
if( ViewFamily.RenderTarget->GetRenderTargetTexture() != DestRenderTarget.TargetableTexture )
{
Context.RHICmdList.Clear(true, FLinearColor::Black, false, 1.0f, false, 0, View.ViewRect);
}
Context.SetViewportAndCallRHI(View.ViewRect);
// set the state
Context.RHICmdList.SetBlendState(TStaticBlendState<>::GetRHI());
Context.RHICmdList.SetRasterizerState(TStaticRasterizerState<>::GetRHI());
Context.RHICmdList.SetDepthStencilState(TStaticDepthStencilState<false, CF_Always>::GetRHI());
float ScaleX = 1.0f / InputDesc->Extent.X;
float ScaleY = 1.0f / InputDesc->Extent.Y;
const FMaterialShaderMap* MaterialShaderMap = Material->GetRenderingThreadShaderMap();
FPostProcessMaterialPS* PixelShader = MaterialShaderMap->GetShader<FPostProcessMaterialPS>();
FPostProcessMaterialVS* VertexShader = MaterialShaderMap->GetShader<FPostProcessMaterialVS>();
Context.RHICmdList.SetLocalBoundShaderState(Context.RHICmdList.BuildLocalBoundShaderState(GetVertexDeclarationFVector4(), VertexShader->GetVertexShader(), FHullShaderRHIRef(), FDomainShaderRHIRef(), PixelShader->GetPixelShader(), FGeometryShaderRHIRef()));
VertexShader->SetParameters(Context.RHICmdList, Context);
PixelShader->SetParameters(Context.RHICmdList, Context, MaterialInterface->GetRenderProxy(false));
DrawRectangle(
Context.RHICmdList,
0, 0,
DestRect.Width(), DestRect.Height(),
SrcRect.Min.X, SrcRect.Min.Y,
SrcRect.Width(), SrcRect.Height(),
DestRect.Size(),
SrcSize,
VertexShader,
EDRF_UseTriangleOptimization);
Context.RHICmdList.CopyToResolveTarget(DestRenderTarget.TargetableTexture, DestRenderTarget.ShaderResourceTexture, false, FResolveParams());
if(Material->NeedsGBuffer())
{
GSceneRenderTargets.AdjustGBufferRefCount(-1);
}
}
void FRCPassPostProcessSelectionOutlineColor::Process(FRenderingCompositePassContext& Context)
{
SCOPED_DRAW_EVENT(Context.RHICmdList, PostProcessSelectionOutlineBuffer);
const FPooledRenderTargetDesc* SceneColorInputDesc = GetInputDesc(ePId_Input0);
if(!SceneColorInputDesc)
{
// input is not hooked up correctly
return;
}
const FViewInfo& View = Context.View;
FIntRect ViewRect = View.ViewRect;
FIntPoint SrcSize = SceneColorInputDesc->Extent;
// Get the output render target
const FSceneRenderTargetItem& DestRenderTarget = PassOutputs[0].RequestSurface(Context);
// Set the render target/viewport.
SetRenderTarget(Context.RHICmdList, FTextureRHIParamRef(), DestRenderTarget.TargetableTexture);
// This is a reversed Z depth surface, so 0.0f is the far plane.
Context.RHICmdList.Clear(false, FLinearColor(0, 0, 0, 0), true, (float)ERHIZBuffer::FarPlane, true, 0, FIntRect());
Context.SetViewportAndCallRHI(ViewRect);
if (View.Family->EngineShowFlags.Selection)
{
FHitProxyDrawingPolicyFactory::ContextType FactoryContext;
//@todo - use memstack
TMap<FName, int32> ActorNameToStencilIndex;
TMap<const FPrimitiveSceneProxy*, int32> IndividuallySelectedProxies;
ActorNameToStencilIndex.Add(NAME_BSP, 1);
Context.RHICmdList.SetRasterizerState(TStaticRasterizerState<>::GetRHI());
Context.RHICmdList.SetBlendState(TStaticBlendStateWriteMask<CW_NONE, CW_NONE, CW_NONE, CW_NONE>::GetRHI());
for (int32 MeshBatchIndex = 0; MeshBatchIndex < View.DynamicMeshElements.Num(); MeshBatchIndex++)
{
const FMeshBatchAndRelevance& MeshBatchAndRelevance = View.DynamicMeshElements[MeshBatchIndex];
const FPrimitiveSceneProxy* PrimitiveSceneProxy = MeshBatchAndRelevance.PrimitiveSceneProxy;
#if WITH_EDITOR
// Selected actors should be subdued if any component is individually selected
bool bActorSelectionColorIsSubdued = View.bHasSelectedComponents;
#else
bool bActorSelectionColorIsSubdued = false;
#endif
if (PrimitiveSceneProxy->IsSelected() && MeshBatchAndRelevance.Mesh->bUseSelectionOutline)
{
const int32* AssignedStencilIndexPtr = PrimitiveSceneProxy->IsIndividuallySelected() ? IndividuallySelectedProxies.Find( PrimitiveSceneProxy ) : ActorNameToStencilIndex.Find(PrimitiveSceneProxy->GetOwnerName());
if (!AssignedStencilIndexPtr)
{
if( PrimitiveSceneProxy->IsIndividuallySelected() )
{
// Any component that is individually selected should have a stencil value of < 128 so that it can have a unique color. We offset the value by 2 because 0 means no selection and 1 is for bsp
int32 StencilValue = IndividuallySelectedProxies.Num() % 126 + 2;
AssignedStencilIndexPtr = &IndividuallySelectedProxies.Add(PrimitiveSceneProxy, StencilValue);
}
else
{
// If we are subduing actor color highlight then use the top level bits to indicate that to the shader.
int32 StencilValue = bActorSelectionColorIsSubdued ? ActorNameToStencilIndex.Num() % 128 + 128 : ActorNameToStencilIndex.Num() % 126 + 2;
AssignedStencilIndexPtr = &ActorNameToStencilIndex.Add(PrimitiveSceneProxy->GetOwnerName(), StencilValue);
}
}
// Note that the stencil value will overflow with enough selected objects
Context.RHICmdList.SetDepthStencilState(TStaticDepthStencilState<true, CF_DepthNearOrEqual, true, CF_Always, SO_Keep, SO_Keep, SO_Replace>::GetRHI(), *AssignedStencilIndexPtr);
const FMeshBatch& MeshBatch = *MeshBatchAndRelevance.Mesh;
FHitProxyDrawingPolicyFactory::DrawDynamicMesh(Context.RHICmdList, View, FactoryContext, MeshBatch, false, true, MeshBatchAndRelevance.PrimitiveSceneProxy, MeshBatch.BatchHitProxyId);
}
}
// to get an outline around the objects if it's partly outside of the screen
{
FIntRect InnerRect = ViewRect;
// 1 as we have an outline that is that thick
InnerRect.InflateRect(-1);
// We could use Clear with InnerRect but this is just an optimization - on some hardware it might do a full clear (and we cannot disable yet)
// RHICmdList.Clear(false, FLinearColor(0, 0, 0, 0), true, 0.0f, true, 0, InnerRect);
// so we to 4 clears - one for each border.
// top
Context.RHICmdList.SetScissorRect(true, ViewRect.Min.X, ViewRect.Min.Y, ViewRect.Max.X, InnerRect.Min.Y);
Context.RHICmdList.Clear(false, FLinearColor(0, 0, 0, 0), true, (float)ERHIZBuffer::FarPlane, true, 0, FIntRect());
// bottom
Context.RHICmdList.SetScissorRect(true, ViewRect.Min.X, InnerRect.Max.Y, ViewRect.Max.X, ViewRect.Max.Y);
Context.RHICmdList.Clear(false, FLinearColor(0, 0, 0, 0), true, (float)ERHIZBuffer::FarPlane, true, 0, FIntRect());
// left
Context.RHICmdList.SetScissorRect(true, ViewRect.Min.X, ViewRect.Min.Y, InnerRect.Min.X, ViewRect.Max.Y);
Context.RHICmdList.Clear(false, FLinearColor(0, 0, 0, 0), true, (float)ERHIZBuffer::FarPlane, true, 0, FIntRect());
// right
Context.RHICmdList.SetScissorRect(true, InnerRect.Max.X, ViewRect.Min.Y, ViewRect.Max.X, ViewRect.Max.Y);
Context.RHICmdList.Clear(false, FLinearColor(0, 0, 0, 0), true, (float)ERHIZBuffer::FarPlane, true, 0, FIntRect());
Context.RHICmdList.SetScissorRect(false, 0, 0, 0, 0);
}
}
// Resolve to the output
Context.RHICmdList.CopyToResolveTarget(DestRenderTarget.TargetableTexture, DestRenderTarget.ShaderResourceTexture, false, FResolveParams());
}
/**
* Transfers a list of curves to a texture on the GPU. All main memory allocated
* for curve samples is released.
* @param CurveTextureRHI - The
* @param CurveTextureTargetRHI - The render target for the curve texture.
* @param InPendingCurves - Curves to be stored on the GPU.
*/
static void InjectCurves(
FRHICommandListImmediate& RHICmdList,
FTexture2DRHIParamRef CurveTextureRHI,
FTexture2DRHIParamRef CurveTextureTargetRHI,
TArray<FCurveSamples>& InPendingCurves )
{
static bool bFirstCall = true;
check( IsInRenderingThread() );
SCOPED_DRAW_EVENT(RHICmdList, InjectParticleCurves);
FVertexBufferRHIParamRef ScratchVertexBufferRHI = GParticleScratchVertexBuffer.VertexBufferRHI;
SetRenderTarget(RHICmdList, CurveTextureTargetRHI, FTextureRHIParamRef());
RHICmdList.SetScissorRect(false, 0, 0, 0, 0);
RHICmdList.SetViewport(0, 0, 0.0f, GParticleCurveTextureSizeX, GParticleCurveTextureSizeY, 1.0f);
RHICmdList.SetDepthStencilState(TStaticDepthStencilState<false, CF_Always>::GetRHI());
RHICmdList.SetRasterizerState(TStaticRasterizerState<FM_Solid, CM_None>::GetRHI());
RHICmdList.SetBlendState(TStaticBlendState<>::GetRHI());
if (bFirstCall)
{
RHICmdList.Clear(true, FLinearColor::Blue, false, 0.0f, false, 0, FIntRect());
bFirstCall = false;
}
int32 PendingCurveCount = InPendingCurves.Num();
for ( int32 CurveIndex = 0; CurveIndex < PendingCurveCount; ++CurveIndex )
{
FCurveSamples& Curve = InPendingCurves[CurveIndex];
check( Curve.Samples );
// Copy curve samples in to the scratch vertex buffer.
const int32 SampleCount = Curve.TexelAllocation.Size;
const int32 SampleByteCount = SampleCount * sizeof(FColor);
FColor* RESTRICT DestSamples = (FColor*)RHILockVertexBuffer( ScratchVertexBufferRHI, 0, SampleByteCount, RLM_WriteOnly );
FMemory::Memcpy( DestSamples, Curve.Samples, SampleByteCount );
RHICmdList.UnlockVertexBuffer(ScratchVertexBufferRHI);
FMemory::Free( Curve.Samples );
Curve.Samples = NULL;
// Compute the offset in to the texture.
FVector2D CurveOffset(
(float)Curve.TexelAllocation.X / GParticleCurveTextureSizeX,
(float)Curve.TexelAllocation.Y / GParticleCurveTextureSizeY );
// Grab shaders.
TShaderMapRef<FParticleCurveInjectionVS> VertexShader(GetGlobalShaderMap(GMaxRHIFeatureLevel));
TShaderMapRef<FParticleCurveInjectionPS> PixelShader(GetGlobalShaderMap(GMaxRHIFeatureLevel));
// Bound shader state.
static FGlobalBoundShaderState BoundShaderState;
SetGlobalBoundShaderState(
RHICmdList,
GMaxRHIFeatureLevel,
BoundShaderState,
GParticleCurveInjectionVertexDeclaration.VertexDeclarationRHI,
*VertexShader,
*PixelShader,
0
);
VertexShader->SetParameters(RHICmdList, CurveOffset );
// Stream 0: New particles.
RHICmdList.SetStreamSource(
0,
ScratchVertexBufferRHI,
/*Stride=*/ sizeof(FColor),
/*Offset=*/ 0
);
// Stream 1: TexCoord.
RHICmdList.SetStreamSource(
1,
GParticleTexCoordVertexBuffer.VertexBufferRHI,
/*Stride=*/ sizeof(FVector2D),
/*Offset=*/ 0
);
// Inject particles.
RHICmdList.DrawIndexedPrimitive(
GParticleIndexBuffer.IndexBufferRHI,
PT_TriangleList,
/*BaseVertexIndex=*/ 0,
/*MinIndex=*/ 0,
/*NumVertices=*/ 4,
/*StartIndex=*/ 0,
/*NumPrimitives=*/ 2,
/*NumInstances=*/ SampleCount
);
}
RHICmdList.CopyToResolveTarget(CurveTextureTargetRHI, CurveTextureRHI, /*bKeepOriginalSurface=*/ false, FResolveParams());
}
void FRCPassPostProcessSelectionOutlineColor::Process(FRenderingCompositePassContext& Context)
{
#if WITH_EDITOR
SCOPED_DRAW_EVENT(Context.RHICmdList, PostProcessSelectionOutlineBuffer);
const FPooledRenderTargetDesc* SceneColorInputDesc = GetInputDesc(ePId_Input0);
if(!SceneColorInputDesc)
{
// input is not hooked up correctly
return;
}
const FViewInfo& View = Context.View;
FIntRect ViewRect = View.ViewRect;
FIntPoint SrcSize = SceneColorInputDesc->Extent;
// Get the output render target
const FSceneRenderTargetItem& DestRenderTarget = PassOutputs[0].RequestSurface(Context);
// Set the render target/viewport.
SetRenderTarget(Context.RHICmdList, FTextureRHIParamRef(), DestRenderTarget.TargetableTexture);
// This is a reversed Z depth surface, so 0.0f is the far plane.
Context.RHICmdList.Clear(false, FLinearColor(0, 0, 0, 0), true, (float)ERHIZBuffer::FarPlane, true, 0, FIntRect());
Context.SetViewportAndCallRHI(ViewRect);
if (View.Family->EngineShowFlags.Selection)
{
FHitProxyDrawingPolicyFactory::ContextType FactoryContext;
Context.RHICmdList.SetRasterizerState(TStaticRasterizerState<>::GetRHI());
Context.RHICmdList.SetBlendState(TStaticBlendStateWriteMask<CW_NONE, CW_NONE, CW_NONE, CW_NONE>::GetRHI());
// Note that the stencil value will overflow with enough selected objects
FEditorSelectionDrawingPolicy::ResetStencilValues();
// Run selection pass on static elements
FScene* Scene = View.Family->Scene->GetRenderScene();
if(Scene)
{
Scene->EditorSelectionDrawList.DrawVisible(Context.RHICmdList, View, View.StaticMeshEditorSelectionMap, View.StaticMeshBatchVisibility);
}
for (int32 MeshBatchIndex = 0; MeshBatchIndex < View.DynamicMeshElements.Num(); MeshBatchIndex++)
{
const FMeshBatchAndRelevance& MeshBatchAndRelevance = View.DynamicMeshElements[MeshBatchIndex];
const FPrimitiveSceneProxy* PrimitiveSceneProxy = MeshBatchAndRelevance.PrimitiveSceneProxy;
// Selected actors should be subdued if any component is individually selected
bool bActorSelectionColorIsSubdued = View.bHasSelectedComponents;
if (PrimitiveSceneProxy->IsSelected() && MeshBatchAndRelevance.Mesh->bUseSelectionOutline && PrimitiveSceneProxy->WantsSelectionOutline())
{
int32 StencilValue = 1;
if(PrimitiveSceneProxy->GetOwnerName() != NAME_BSP)
{
StencilValue = FEditorSelectionDrawingPolicy::GetStencilValue(View, PrimitiveSceneProxy);
}
// Note that the stencil value will overflow with enough selected objects
Context.RHICmdList.SetDepthStencilState(TStaticDepthStencilState<true, CF_DepthNearOrEqual, true, CF_Always, SO_Keep, SO_Keep, SO_Replace>::GetRHI(), StencilValue);
const FMeshBatch& MeshBatch = *MeshBatchAndRelevance.Mesh;
FHitProxyDrawingPolicyFactory::DrawDynamicMesh(Context.RHICmdList, View, FactoryContext, MeshBatch, false, true, MeshBatchAndRelevance.PrimitiveSceneProxy, MeshBatch.BatchHitProxyId);
}
}
// to get an outline around the objects if it's partly outside of the screen
{
FIntRect InnerRect = ViewRect;
// 1 as we have an outline that is that thick
InnerRect.InflateRect(-1);
// We could use Clear with InnerRect but this is just an optimization - on some hardware it might do a full clear (and we cannot disable yet)
// RHICmdList.Clear(false, FLinearColor(0, 0, 0, 0), true, 0.0f, true, 0, InnerRect);
// so we to 4 clears - one for each border.
// top
Context.RHICmdList.SetScissorRect(true, ViewRect.Min.X, ViewRect.Min.Y, ViewRect.Max.X, InnerRect.Min.Y);
Context.RHICmdList.Clear(false, FLinearColor(0, 0, 0, 0), true, (float)ERHIZBuffer::FarPlane, true, 0, FIntRect());
// bottom
Context.RHICmdList.SetScissorRect(true, ViewRect.Min.X, InnerRect.Max.Y, ViewRect.Max.X, ViewRect.Max.Y);
Context.RHICmdList.Clear(false, FLinearColor(0, 0, 0, 0), true, (float)ERHIZBuffer::FarPlane, true, 0, FIntRect());
// left
Context.RHICmdList.SetScissorRect(true, ViewRect.Min.X, ViewRect.Min.Y, InnerRect.Min.X, ViewRect.Max.Y);
Context.RHICmdList.Clear(false, FLinearColor(0, 0, 0, 0), true, (float)ERHIZBuffer::FarPlane, true, 0, FIntRect());
// right
Context.RHICmdList.SetScissorRect(true, InnerRect.Max.X, ViewRect.Min.Y, ViewRect.Max.X, ViewRect.Max.Y);
Context.RHICmdList.Clear(false, FLinearColor(0, 0, 0, 0), true, (float)ERHIZBuffer::FarPlane, true, 0, FIntRect());
Context.RHICmdList.SetScissorRect(false, 0, 0, 0, 0);
}
}
// Resolve to the output
Context.RHICmdList.CopyToResolveTarget(DestRenderTarget.TargetableTexture, DestRenderTarget.ShaderResourceTexture, false, FResolveParams());
#endif
}
void FRCPassPostProcessSelectionOutlineColor::Process(FRenderingCompositePassContext& Context)
{
SCOPED_DRAW_EVENT(Context.RHICmdList, PostProcessSelectionOutlineBuffer, DEC_SCENE_ITEMS);
const FPooledRenderTargetDesc* SceneColorInputDesc = GetInputDesc(ePId_Input0);
if(!SceneColorInputDesc)
{
// input is not hooked up correctly
return;
}
const FViewInfo& View = Context.View;
FIntRect ViewRect = View.ViewRect;
FIntPoint SrcSize = SceneColorInputDesc->Extent;
// Get the output render target
const FSceneRenderTargetItem& DestRenderTarget = PassOutputs[0].RequestSurface(Context);
// Set the render target/viewport.
SetRenderTarget(Context.RHICmdList, FTextureRHIParamRef(), DestRenderTarget.TargetableTexture);
// This is a reversed Z depth surface, so 0.0f is the far plane.
Context.RHICmdList.Clear(false, FLinearColor(0, 0, 0, 0), true, 0.0f, true, 0, FIntRect());
Context.SetViewportAndCallRHI(ViewRect);
if (View.Family->EngineShowFlags.Selection)
{
const bool bUseGetMeshElements = ShouldUseGetDynamicMeshElements();
if (bUseGetMeshElements)
{
FHitProxyDrawingPolicyFactory::ContextType FactoryContext;
//@todo - use memstack
TMap<FName, int32> ActorNameToStencilIndex;
ActorNameToStencilIndex.Add(NAME_BSP, 1);
Context.RHICmdList.SetRasterizerState(TStaticRasterizerState<>::GetRHI());
Context.RHICmdList.SetBlendState(TStaticBlendStateWriteMask<CW_NONE, CW_NONE, CW_NONE, CW_NONE>::GetRHI());
for (int32 MeshBatchIndex = 0; MeshBatchIndex < View.DynamicMeshElements.Num(); MeshBatchIndex++)
{
const FMeshBatchAndRelevance& MeshBatchAndRelevance = View.DynamicMeshElements[MeshBatchIndex];
const FPrimitiveSceneProxy* PrimitiveSceneProxy = MeshBatchAndRelevance.PrimitiveSceneProxy;
if (PrimitiveSceneProxy->IsSelected() && MeshBatchAndRelevance.Mesh->bUseSelectionOutline)
{
const int32* AssignedStencilIndexPtr = ActorNameToStencilIndex.Find(PrimitiveSceneProxy->GetOwnerName());
if (!AssignedStencilIndexPtr)
{
AssignedStencilIndexPtr = &ActorNameToStencilIndex.Add(PrimitiveSceneProxy->GetOwnerName(), ActorNameToStencilIndex.Num() + 1);
}
// This is a reversed Z depth surface, using CF_GreaterEqual.
// Note that the stencil value will overflow with enough selected objects
Context.RHICmdList.SetDepthStencilState(TStaticDepthStencilState<true, CF_GreaterEqual, true, CF_Always, SO_Keep, SO_Keep, SO_Replace>::GetRHI(), *AssignedStencilIndexPtr);
const FMeshBatch& MeshBatch = *MeshBatchAndRelevance.Mesh;
FHitProxyDrawingPolicyFactory::DrawDynamicMesh(Context.RHICmdList, View, FactoryContext, MeshBatch, false, true, MeshBatchAndRelevance.PrimitiveSceneProxy, MeshBatch.BatchHitProxyId);
}
}
}
else if (View.VisibleDynamicPrimitives.Num() > 0)
{
TDynamicPrimitiveDrawer<FHitProxyDrawingPolicyFactory> Drawer(Context.RHICmdList, &View, FHitProxyDrawingPolicyFactory::ContextType(), true, false, false, true);
TMultiMap<FName, const FPrimitiveSceneInfo*> PrimitivesByActor;
for (int32 PrimitiveIndex = 0; PrimitiveIndex < View.VisibleDynamicPrimitives.Num();PrimitiveIndex++)
{
const FPrimitiveSceneInfo* PrimitiveSceneInfo = View.VisibleDynamicPrimitives[PrimitiveIndex];
// Only draw the primitive if relevant
if(PrimitiveSceneInfo->Proxy->IsSelected())
{
PrimitivesByActor.Add(PrimitiveSceneInfo->Proxy->GetOwnerName(), PrimitiveSceneInfo);
}
}
if (PrimitivesByActor.Num())
{
// 0 means no object, 1 means BSP so we start with 2
uint32 StencilValue = 2;
Context.RHICmdList.SetRasterizerState(TStaticRasterizerState<>::GetRHI());
Context.RHICmdList.SetBlendState(TStaticBlendStateWriteMask<CW_NONE, CW_NONE, CW_NONE, CW_NONE>::GetRHI());
// Sort by actor
TArray<FName> Actors;
PrimitivesByActor.GetKeys(Actors);
for( TArray<FName>::TConstIterator ActorIt(Actors); ActorIt; ++ActorIt )
{
bool bBSP = *ActorIt == NAME_BSP;
if (bBSP)
{
// This is a reversed Z depth surface, using CF_GreaterEqual.
Context.RHICmdList.SetDepthStencilState(TStaticDepthStencilState<true, CF_GreaterEqual, true, CF_Always, SO_Keep, SO_Keep, SO_Replace>::GetRHI(), 1);
}
else
{
// This is a reversed Z depth surface, using CF_GreaterEqual.
Context.RHICmdList.SetDepthStencilState(TStaticDepthStencilState<true, CF_GreaterEqual, true, CF_Always, SO_Keep, SO_Keep, SO_Replace>::GetRHI(), StencilValue);
// we want to use 1..255 for all objects, not correct silhouettes after that is acceptable
StencilValue = (StencilValue == 255) ? 2 : (StencilValue + 1);
}
TArray<const FPrimitiveSceneInfo*> Primitives;
PrimitivesByActor.MultiFind(*ActorIt, Primitives);
for( TArray<const FPrimitiveSceneInfo*>::TConstIterator PrimIt(Primitives); PrimIt; ++PrimIt )
{
const FPrimitiveSceneInfo* PrimitiveSceneInfo = *PrimIt;
// Render the object to the stencil/depth buffer
Drawer.SetPrimitive(PrimitiveSceneInfo->Proxy);
PrimitiveSceneInfo->Proxy->DrawDynamicElements(&Drawer, &View);
}
}
}
}
// to get an outline around the objects if it's partly outside of the screen
{
FIntRect InnerRect = ViewRect;
// 1 as we have an outline that is that thick
InnerRect.InflateRect(-1);
// We could use Clear with InnerRect but this is just an optimization - on some hardware it might do a full clear (and we cannot disable yet)
// RHICmdList.Clear(false, FLinearColor(0, 0, 0, 0), true, 0.0f, true, 0, InnerRect);
// so we to 4 clears - one for each border.
// top
Context.RHICmdList.SetScissorRect(true, ViewRect.Min.X, ViewRect.Min.Y, ViewRect.Max.X, InnerRect.Min.Y);
Context.RHICmdList.Clear(false, FLinearColor(0, 0, 0, 0), true, 0.0f, true, 0, FIntRect());
// bottom
Context.RHICmdList.SetScissorRect(true, ViewRect.Min.X, InnerRect.Max.Y, ViewRect.Max.X, ViewRect.Max.Y);
Context.RHICmdList.Clear(false, FLinearColor(0, 0, 0, 0), true, 0.0f, true, 0, FIntRect());
// left
Context.RHICmdList.SetScissorRect(true, ViewRect.Min.X, ViewRect.Min.Y, InnerRect.Min.X, ViewRect.Max.Y);
Context.RHICmdList.Clear(false, FLinearColor(0, 0, 0, 0), true, 0.0f, true, 0, FIntRect());
// right
Context.RHICmdList.SetScissorRect(true, InnerRect.Max.X, ViewRect.Min.Y, ViewRect.Max.X, ViewRect.Max.Y);
Context.RHICmdList.Clear(false, FLinearColor(0, 0, 0, 0), true, 0.0f, true, 0, FIntRect());
Context.RHICmdList.SetScissorRect(false, 0, 0, 0, 0);
}
}
// Resolve to the output
Context.RHICmdList.CopyToResolveTarget(DestRenderTarget.TargetableTexture, DestRenderTarget.ShaderResourceTexture, false, FResolveParams());
}
void FRCPassPostProcessDeferredDecals::Process(FRenderingCompositePassContext& Context)
{
FRHICommandListImmediate& RHICmdList = Context.RHICmdList;
const bool bShaderComplexity = Context.View.Family->EngineShowFlags.ShaderComplexity;
const bool bDBuffer = IsDBufferEnabled();
const bool bStencilSizeThreshold = CVarStencilSizeThreshold.GetValueOnRenderThread() >= 0;
SCOPED_DRAW_EVENT(RHICmdList, PostProcessDeferredDecals);
if(RenderStage == 0)
{
// before BasePass, only if DBuffer is enabled
check(bDBuffer);
// DBuffer: Decal buffer
FPooledRenderTargetDesc Desc(FPooledRenderTargetDesc::Create2DDesc(GSceneRenderTargets.GBufferA->GetDesc().Extent,
PF_B8G8R8A8,
TexCreate_None,
TexCreate_ShaderResource | TexCreate_RenderTargetable,
false));
if(!GSceneRenderTargets.DBufferA)
{
GRenderTargetPool.FindFreeElement(Desc, GSceneRenderTargets.DBufferA, TEXT("DBufferA"));
}
if(!GSceneRenderTargets.DBufferB)
{
GRenderTargetPool.FindFreeElement(Desc, GSceneRenderTargets.DBufferB, TEXT("DBufferB"));
}
Desc.Format = PF_R8G8;
if(!GSceneRenderTargets.DBufferC)
{
GRenderTargetPool.FindFreeElement(Desc, GSceneRenderTargets.DBufferC, TEXT("DBufferC"));
}
// we assume views are non overlapping, then we need to clear only once in the beginning, otherwise we would need to set scissor rects
// and don't get FastClear any more.
bool bFirstView = Context.View.Family->Views[0] == &Context.View;
if(bFirstView)
{
SCOPED_DRAW_EVENT(RHICmdList, DBufferClear);
// could be optimized
SetRenderTarget(RHICmdList, GSceneRenderTargets.DBufferA->GetRenderTargetItem().TargetableTexture, FTextureRHIParamRef());
RHICmdList.Clear(true, FLinearColor(0, 0, 0, 1), false, (float)ERHIZBuffer::FarPlane, false, 0, FIntRect());
SetRenderTarget(RHICmdList, GSceneRenderTargets.DBufferB->GetRenderTargetItem().TargetableTexture, FTextureRHIParamRef());
// todo: some hardware would like to have 0 or 1 for faster clear, we chose 128/255 to represent 0 (8 bit cannot represent 0.5f)
RHICmdList.Clear(true, FLinearColor(128.0f / 255.0f, 128.0f / 255.0f, 128.0f / 255.0f, 1), false, (float)ERHIZBuffer::FarPlane, false, 0, FIntRect());
SetRenderTarget(RHICmdList, GSceneRenderTargets.DBufferC->GetRenderTargetItem().TargetableTexture, FTextureRHIParamRef());
// R:roughness, G:roughness opacity
RHICmdList.Clear(true, FLinearColor(0, 1, 0, 1), false, (float)ERHIZBuffer::FarPlane, false, 0, FIntRect());
}
}
// this cast is safe as only the dedicated server implements this differently and this pass should not be executed on the dedicated server
const FViewInfo& View = Context.View;
const FSceneViewFamily& ViewFamily = *(View.Family);
FScene& Scene = *(FScene*)ViewFamily.Scene;
if(!Scene.Decals.Num())
{
// to avoid the stats showing up
return;
}
TArray<FTransientDecalRenderData, SceneRenderingAllocator> SortedDecals;
SortedDecals.Empty(Scene.Decals.Num());
// Build a list of decals that need to be rendered for this view in SortedDecals
for (TSparseArray<FDeferredDecalProxy*>::TConstIterator It(Scene.Decals); It; ++It)
{
FDeferredDecalProxy* DecalProxy = *It;
bool bIsShown = true;
// Handle the decal actor having bHidden set when we are in the editor, in G mode
#if WITH_EDITOR
if (View.Family->EngineShowFlags.Editor)
#endif
{
if (!DecalProxy->DrawInGame)
{
bIsShown = false;
}
}
const FMatrix ComponentToWorldMatrix = DecalProxy->ComponentTrans.ToMatrixWithScale();
// can be optimized as we test against a sphere around the box instead of the box itself
const float ConservativeRadius = FMath::Sqrt(
ComponentToWorldMatrix.GetScaledAxis( EAxis::X ).SizeSquared() * FMath::Square(GDefaultDecalSize.X) +
ComponentToWorldMatrix.GetScaledAxis( EAxis::Y ).SizeSquared() * FMath::Square(GDefaultDecalSize.Y) +
ComponentToWorldMatrix.GetScaledAxis( EAxis::Z ).SizeSquared() * FMath::Square(GDefaultDecalSize.Z));
// can be optimized as the test is too conservative (sphere instead of OBB)
if(ConservativeRadius < SMALL_NUMBER || !View.ViewFrustum.IntersectSphere(ComponentToWorldMatrix.GetOrigin(), ConservativeRadius))
{
bIsShown = false;
}
if (bIsShown)
{
FTransientDecalRenderData Data(Scene, DecalProxy);
uint32 DecalRenderStage = ComputeRenderStage(Data.DecalBlendMode);
// we could do this test earlier to avoid the decal intersection but getting DecalBlendMode also costs
if (Context.View.Family->EngineShowFlags.ShaderComplexity || RenderStage == DecalRenderStage)
{
SortedDecals.Add(Data);
}
}
}
if(SortedDecals.Num() > 0)
{
FIntRect SrcRect = View.ViewRect;
FIntRect DestRect = View.ViewRect;
bool bStencilDecals = true;
#if DBUFFER_DONT_USE_STENCIL_YET
if(RenderStage == 0)
{
bStencilDecals = false;
}
#endif
// Setup a stencil mask to prevent certain pixels from receiving deferred decals
if(bStencilDecals)
{
StencilDecalMask(RHICmdList, View);
}
// Sort by sort order to allow control over composited result
// Then sort decals by state to reduce render target switches
// Also sort by component since Sort() is not stable
struct FCompareFTransientDecalRenderData
{
FORCEINLINE bool operator()( const FTransientDecalRenderData& A, const FTransientDecalRenderData& B ) const
{
if (B.DecalProxy->SortOrder != A.DecalProxy->SortOrder)
{
return A.DecalProxy->SortOrder < B.DecalProxy->SortOrder;
}
if (B.DecalBlendMode != A.DecalBlendMode)
{
return (int32)B.DecalBlendMode < (int32)A.DecalBlendMode;
}
if (B.bHasNormal != A.bHasNormal)
{
return B.bHasNormal < A.bHasNormal;
}
// Batch decals with the same material together
if (B.MaterialProxy != A.MaterialProxy )
{
return B.MaterialProxy < A.MaterialProxy;
}
return (PTRINT)B.DecalProxy->Component < (PTRINT)A.DecalProxy->Component;
}
};
// Sort decals by blend mode to reduce render target switches
SortedDecals.Sort( FCompareFTransientDecalRenderData() );
// optimization to have less state changes
int32 LastDecalBlendMode = -1;
int32 LastDecalHasNormal = -1; // Decal state can change based on its normal property.(SM5)
ERenderTargetMode LastRenderTargetMode = RTM_Unknown;
int32 WasInsideDecal = -1;
const ERHIFeatureLevel::Type SMFeatureLevel = Context.GetFeatureLevel();
SCOPED_DRAW_EVENT(RHICmdList, Decals);
INC_DWORD_STAT_BY(STAT_Decals, SortedDecals.Num());
enum EDecalResolveBufferIndex
{
SceneColorIndex,
GBufferAIndex,
GBufferBIndex,
GBufferCIndex,
DBufferAIndex,
DBufferBIndex,
DBufferCIndex,
ResolveBufferMax,
};
FTextureRHIParamRef TargetsToResolve[ResolveBufferMax] = { nullptr };
for (int32 DecalIndex = 0, DecalCount = SortedDecals.Num(); DecalIndex < DecalCount; DecalIndex++)
{
const FTransientDecalRenderData& DecalData = SortedDecals[DecalIndex];
const FDeferredDecalProxy& DecalProxy = *DecalData.DecalProxy;
const FMatrix ComponentToWorldMatrix = DecalProxy.ComponentTrans.ToMatrixWithScale();
// Set vertex shader params
const FMaterialShaderMap* MaterialShaderMap = DecalData.MaterialResource->GetRenderingThreadShaderMap();
FScaleMatrix DecalScaleTransform(GDefaultDecalSize);
FTranslationMatrix PreViewTranslation(View.ViewMatrices.PreViewTranslation);
FMatrix FrustumComponentToClip = DecalScaleTransform * ComponentToWorldMatrix * PreViewTranslation * View.ViewMatrices.TranslatedViewProjectionMatrix;
// can be optimized as we test against a sphere around the box instead of the box itself
const float ConservativeRadius = FMath::Sqrt(
ComponentToWorldMatrix.GetScaledAxis( EAxis::X ).SizeSquared() * FMath::Square(GDefaultDecalSize.X) +
ComponentToWorldMatrix.GetScaledAxis( EAxis::Y ).SizeSquared() * FMath::Square(GDefaultDecalSize.Y) +
ComponentToWorldMatrix.GetScaledAxis( EAxis::Z ).SizeSquared() * FMath::Square(GDefaultDecalSize.Z));
EDecalBlendMode DecalBlendMode = DecalData.DecalBlendMode;
bool bStencilThisDecal = bStencilDecals;
#if DBUFFER_DONT_USE_STENCIL_YET
if(ComputeRenderStage(DecalBlendMode) == 0)
{
bStencilThisDecal = false;
}
#endif
ERenderTargetMode CurrentRenderTargetMode = ComputeRenderTargetMode(DecalBlendMode);
if(bShaderComplexity)
{
CurrentRenderTargetMode = RTM_SceneColor;
// we want additive blending for the ShaderComplexity mode
DecalBlendMode = DBM_Emissive;
}
// fewer rendertarget switches if possible
if(CurrentRenderTargetMode != LastRenderTargetMode)
{
LastRenderTargetMode = CurrentRenderTargetMode;
switch(CurrentRenderTargetMode)
{
case RTM_SceneColorAndGBuffer:
{
TargetsToResolve[SceneColorIndex] = GSceneRenderTargets.GetSceneColor()->GetRenderTargetItem().TargetableTexture;
TargetsToResolve[GBufferAIndex] = GSceneRenderTargets.GBufferA->GetRenderTargetItem().TargetableTexture;
TargetsToResolve[GBufferBIndex] = GSceneRenderTargets.GBufferB->GetRenderTargetItem().TargetableTexture;
TargetsToResolve[GBufferCIndex] = GSceneRenderTargets.GBufferC->GetRenderTargetItem().TargetableTexture;
SetRenderTargets(RHICmdList, 4, TargetsToResolve, GSceneRenderTargets.GetSceneDepthSurface(), ESimpleRenderTargetMode::EExistingColorAndDepth, FExclusiveDepthStencil::DepthRead_StencilWrite);
}
break;
case RTM_GBufferNormal:
TargetsToResolve[GBufferAIndex] = GSceneRenderTargets.GBufferA->GetRenderTargetItem().TargetableTexture;
SetRenderTarget(RHICmdList, TargetsToResolve[GBufferAIndex], GSceneRenderTargets.GetSceneDepthSurface(), ESimpleRenderTargetMode::EExistingColorAndDepth, FExclusiveDepthStencil::DepthRead_StencilWrite);
break;
case RTM_SceneColor:
TargetsToResolve[SceneColorIndex] = GSceneRenderTargets.GetSceneColor()->GetRenderTargetItem().TargetableTexture;
SetRenderTarget(RHICmdList, TargetsToResolve[SceneColorIndex], GSceneRenderTargets.GetSceneDepthSurface(), ESimpleRenderTargetMode::EExistingColorAndDepth, FExclusiveDepthStencil::DepthRead_StencilWrite);
break;
case RTM_DBuffer:
{
TargetsToResolve[DBufferAIndex] = GSceneRenderTargets.DBufferA->GetRenderTargetItem().TargetableTexture;
TargetsToResolve[DBufferBIndex] = GSceneRenderTargets.DBufferB->GetRenderTargetItem().TargetableTexture;
TargetsToResolve[DBufferCIndex] = GSceneRenderTargets.DBufferC->GetRenderTargetItem().TargetableTexture;
SetRenderTargets(RHICmdList, 3, &TargetsToResolve[DBufferAIndex], GSceneRenderTargets.GetSceneDepthSurface(), ESimpleRenderTargetMode::EExistingColorAndDepth, FExclusiveDepthStencil::DepthRead_StencilWrite);
}
break;
default:
check(0);
break;
}
Context.SetViewportAndCallRHI(DestRect);
// we need to reset the stream source after any call to SetRenderTarget (at least for Metal, which doesn't queue up VB assignments)
RHICmdList.SetStreamSource(0, GUnitCubeVertexBuffer.VertexBufferRHI, sizeof(FVector4), 0);
}
bool bThisDecalUsesStencil = false;
if (bStencilThisDecal)
{
if (bStencilSizeThreshold)
{
// note this is after a SetStreamSource (in if CurrentRenderTargetMode != LastRenderTargetMode) call as it needs to get the VB input
bThisDecalUsesStencil = RenderPreStencil(Context, MaterialShaderMap, ComponentToWorldMatrix, FrustumComponentToClip);
WasInsideDecal = -1;
LastDecalBlendMode = -1;
}
}
const bool bBlendStateChange = DecalBlendMode != LastDecalBlendMode;// Has decal mode changed.
const bool bDecalNormalChanged = GSupportsSeparateRenderTargetBlendState && // has normal changed for SM5 stain/translucent decals?
(DecalBlendMode == DBM_Translucent || DecalBlendMode == DBM_Stain) &&
(int32)DecalData.bHasNormal != LastDecalHasNormal;
// fewer blend state changes if possible
if (bBlendStateChange || bDecalNormalChanged)
{
LastDecalBlendMode = DecalBlendMode;
LastDecalHasNormal = (int32)DecalData.bHasNormal;
SetDecalBlendState(RHICmdList, SMFeatureLevel, RenderStage, (EDecalBlendMode)LastDecalBlendMode, DecalData.bHasNormal);
}
{
TShaderMapRef<FDeferredDecalVS> VertexShader(Context.GetShaderMap());
SetShader(Context, bShaderComplexity, DecalData, *VertexShader);
VertexShader->SetParameters(RHICmdList, View, FrustumComponentToClip);
const int32 IsInsideDecal = ((FVector)View.ViewMatrices.ViewOrigin - ComponentToWorldMatrix.GetOrigin()).SizeSquared() < FMath::Square(ConservativeRadius * 1.05f + View.NearClippingDistance * 2.0f) + ( bThisDecalUsesStencil ) ? 2 : 0;
if ( WasInsideDecal != IsInsideDecal )
{
WasInsideDecal = IsInsideDecal;
if ( !(IsInsideDecal & 1) )
{
// Render backfaces with depth tests disabled since the camera is inside (or close to inside) the light function geometry
RHICmdList.SetRasterizerState(View.bReverseCulling ? TStaticRasterizerState<FM_Solid, CM_CCW>::GetRHI() : TStaticRasterizerState<FM_Solid, CM_CW>::GetRHI());
if(bStencilDecals)
{
// Enable stencil testing, only write to pixels with stencil of 0
if ( bThisDecalUsesStencil )
{
RHICmdList.SetDepthStencilState(TStaticDepthStencilState<
false,CF_Always,
true,CF_Equal,SO_Zero,SO_Zero,SO_Zero,
true,CF_Equal,SO_Zero,SO_Zero,SO_Zero,
0xff, 0x7f
>::GetRHI(), 1);
}
else
{
RHICmdList.SetDepthStencilState(TStaticDepthStencilState<
false,CF_Always,
true,CF_Equal,SO_Keep,SO_Keep,SO_Keep,
false,CF_Always,SO_Keep,SO_Keep,SO_Keep,
0x80,0x00>::GetRHI(), 0);
}
}
else
{
RHICmdList.SetDepthStencilState(TStaticDepthStencilState<false, CF_Always, true>::GetRHI(), 0);
}
}
else
{
// Render frontfaces with depth tests on to get the speedup from HiZ since the camera is outside the light function geometry
if(bStencilDecals)
{
// Render frontfaces with depth tests on to get the speedup from HiZ since the camera is outside the light function geometry
// Enable stencil testing, only write to pixels with stencil of 0
if ( bThisDecalUsesStencil )
{
RHICmdList.SetDepthStencilState(TStaticDepthStencilState<
false,CF_DepthNearOrEqual,
true,CF_Equal,SO_Zero,SO_Zero,SO_Zero,
true,CF_Equal,SO_Zero,SO_Zero,SO_Zero,
0xff, 0x7f
>::GetRHI(), 1);
}
else
{
RHICmdList.SetDepthStencilState(TStaticDepthStencilState<
false,CF_DepthNearOrEqual,
true,CF_Equal,SO_Keep,SO_Keep,SO_Keep,
false,CF_Always,SO_Keep,SO_Keep,SO_Keep,
0x80,0x00>::GetRHI(), 0);
}
RHICmdList.SetRasterizerState(View.bReverseCulling ? TStaticRasterizerState<FM_Solid, CM_CW>::GetRHI() : TStaticRasterizerState<FM_Solid, CM_CCW>::GetRHI());
}
else
{
RHICmdList.SetDepthStencilState(TStaticDepthStencilState<false, CF_DepthNearOrEqual>::GetRHI(), 0);
}
RHICmdList.SetRasterizerState(View.bReverseCulling ? TStaticRasterizerState<FM_Solid, CM_CW>::GetRHI() : TStaticRasterizerState<FM_Solid, CM_CCW>::GetRHI());
}
}
RHICmdList.DrawIndexedPrimitive(GUnitCubeIndexBuffer.IndexBufferRHI, PT_TriangleList, 0, 0, 8, 0, GUnitCubeIndexBuffer.GetIndexCount() / 3, 1);
}
}
// we don't modify stencil but if out input was having stencil for us (after base pass - we need to clear)
// Clear stencil to 0, which is the assumed default by other passes
RHICmdList.Clear(false, FLinearColor::White, false, (float)ERHIZBuffer::FarPlane, true, 0, FIntRect());
// resolve the targets we wrote to.
FResolveParams ResolveParams;
for (int32 i = 0; i < ResolveBufferMax; ++i)
{
if (TargetsToResolve[i])
{
RHICmdList.CopyToResolveTarget(TargetsToResolve[i], TargetsToResolve[i], true, ResolveParams);
}
}
}
if(RenderStage == 0)
{
// before BasePass
GRenderTargetPool.VisualizeTexture.SetCheckPoint(RHICmdList, GSceneRenderTargets.DBufferA);
GRenderTargetPool.VisualizeTexture.SetCheckPoint(RHICmdList, GSceneRenderTargets.DBufferB);
GRenderTargetPool.VisualizeTexture.SetCheckPoint(RHICmdList, GSceneRenderTargets.DBufferC);
}
}
