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b7629531e5d774b6356c3eba39d4338fa7ecf074
UnrealEngineUWP/Engine/Source/Runtime/Renderer/Private/PostProcess/PostProcessing.cpp
Andrew Grant b7629531e5 Copying //UE4/Orion-Staging to //UE4/Main (originated from //Orion/Dev-General @ 2831630) 
#lockdown Nick.Penwarden

==========================
MAJOR FEATURES + CHANGES
==========================

Change 2831624 on 2016/01/17 by Marcus.Wassmer

	Merge disable of FCachedReadPlatformData on PS4.  Reduces memory spikes. 2830986
	#rb none
	#test none
	#codereview Michael.Noland,James.Golding

Change 2831402 on 2016/01/17 by Marcus.Wassmer

	HLOD priority and streamout changes.
	Give texture pool an extra 200MB which we can afford thanks to James/Michael
	#rb Chris.Gagnon
	#test run agora, notice nice textures.
	#lockdown Andrew.Grant

Change 2831398 on 2016/01/17 by Marcus.Wassmer

	Fix 3 logic bugs with Relocate
	#rb chris.gagnon
	#test run game, look for corruption.
	#lockdown Andrew.Grant

Change 2831372 on 2016/01/16 by Marcus.Wassmer

	Update param.sfo's and lockdown version in prep for good PS4 playtest build.
	#rb none
	#test build from last night...
	#lockdown Andrew.Grant

Change 2831274 on 2016/01/16 by Graeme.Thornton

	Disable platform file cache wrapper on PS4

	#codereview James.Golding
	#rb none
	#tests ran cooked ps4 build, timed loading (no real change), measured memory used for file handles (small)

Change 2831237 on 2016/01/16 by Sammy.James

	Fix PS4 compile error

	#codereview Andrew.Grant
	#rb none
	#tests none

Change 2831219 on 2016/01/16 by Matt.Kuhlenschmidt

	Fix possible invalid access to shared  movie player resource across threads causing startup crash.

	#codereview marcus.wassmer
	#rb none, #tests initial load

Change 2831218 on 2016/01/16 by Marcus.Wassmer

	Fix bad warning case.
	#codereview Martin.Mittring
	#rb none
	#test none

Change 2831201 on 2016/01/16 by Andrew.Grant

	Added extra info about referencer to missing asset reference message
	#rb none
	#tests cooked, ran editor

Change 2831183 on 2016/01/16 by David.Nikdel

	#OSS #PS4 #Purchasing #StoreV2
	- Force failure if we have no receipts after a "successful" checkout.
	- Report consumed entitlements as well as unconsumed but leave ValidationInfo empty so we can tell the difference at the application level
	- Convert productIds to skuIds at checkout time
	- Added PS4 Implementation of IOnlineStoreV2
	- Bugfix: set bSuccessfullyStartedUp=false when InitNPGameSettings() fails
	- Adjusted FOnlineStoreOffer to use FText::AsCurrencyBase
	#RB: Paul.Moore
	#TESTS: login, purchase redemption, store MTX purchasing on PS4 & PC

Change 2831129 on 2016/01/16 by David.Nikdel

	#MCP
	- Added a ctor to make converting from FOnlineError to FMcpQueryResult easier (for stuff that was already using FMcpQueryResult).
	#RB: none
	#TESTS: frontend

Change 2830986 on 2016/01/15 by Michael.Noland

	PS4: Disabling FCachedReadPlatformFile on PS4 to significantly reduce high watermark memory consumption during blocking loads
	#rb marcus.wassmer
	#tests Ran Paragon PS4 down a bad path that currently does a blocking map and hero load
	#lockdown andrew.grant

Change 2830943 on 2016/01/15 by Max.Chen

	Sequencer: Fix bug introduced with preroll. It was also causing a crash in particle track instance.

	#tests Master sequence trailer plays without crashing
	#rb none

Change 2830912 on 2016/01/15 by Michael.Noland

	Rendering: Exposed GRHIDeviceId (only filled in on D3D11 and D3D12 RHI's under the same circumstances as GRHIAdapterName, etc..., 0 otherwise)
	#rb mieszko.zielinski
	#tests Tested printing the value out
	#codereview martin.mittring

Change 2830910 on 2016/01/15 by Michael.Noland

	Rendering: Improved GPU driver detection logic to handle more cases
	#codereview martin.mittring
	#rb mieszko.zielinski
	#tests Tested on my machine which was previous reporting Unknown for the values as some entries contained the key in the Settings subfolder

Change 2830776 on 2016/01/15 by Martin.Mittring

	from Dev-Rendering
	added ensure to track down multiple issues like
	OR-11771 CRASH: User Crashed when pressing the Play button
	OR-12430 CRASH: OT2 user crashed with FRHIResource::AddRef()
	#rb:Gil.Gribb
	#code_review:Gil.Gribb,Mark.Satterthwaite,Marcus.Wassmer
2016-01-20 11:32:08 -05:00

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// Copyright 1998-2016 Epic Games, Inc. All Rights Reserved.
/*=============================================================================
PostProcessing.cpp: The center for all post processing activities.
=============================================================================*/
#include "RendererPrivate.h"
#include "ScenePrivate.h"
#include "PostProcessing.h"
#include "PostProcessAA.h"
#include "PostProcessMaterial.h"
#include "PostProcessInput.h"
#include "PostProcessWeightedSampleSum.h"
#include "PostProcessBloomSetup.h"
#include "PostProcessMobile.h"
#include "PostProcessDownsample.h"
#include "PostProcessHistogram.h"
#include "PostProcessHistogramReduce.h"
#include "PostProcessVisualizeHDR.h"
#include "VisualizeShadingModels.h"
#include "PostProcessSelectionOutline.h"
#include "PostProcessGBufferHints.h"
#include "PostProcessVisualizeBuffer.h"
#include "PostProcessEyeAdaptation.h"
#include "PostProcessTonemap.h"
#include "PostProcessLensFlares.h"
#include "PostProcessLensBlur.h"
#include "PostProcessBokehDOF.h"
#include "PostProcessBokehDOFRecombine.h"
#include "PostProcessCombineLUTs.h"
#include "BatchedElements.h"
#include "ScreenRendering.h"
#include "PostProcessTemporalAA.h"
#include "PostProcessMotionBlur.h"
#include "PostProcessDOF.h"
#include "PostProcessCircleDOF.h"
#include "PostProcessUpscale.h"
#include "PostProcessHMD.h"
#include "PostProcessVisualizeComplexity.h"
#include "PostProcessCompositeEditorPrimitives.h"
#include "PostProcessPassThrough.h"
#include "PostProcessAmbientOcclusion.h"
#include "ScreenSpaceReflections.h"
#include "PostProcessTestImage.h"
#include "HighResScreenshot.h"
#include "PostProcessSubsurface.h"
#include "PostProcessMorpheus.h"
#include "IHeadMountedDisplay.h"
#include "BufferVisualizationData.h"
#include "PostProcessLpvIndirect.h"
/** The global center for all post processing activities. */
FPostProcessing GPostProcessing;
int32 GShaderModelDebug = 0;
static FAutoConsoleVariableRef CVarShaderModelDebug(
TEXT("r.ShaderModelDebug"),
GShaderModelDebug,
TEXT("Added logging to each frame that should allow to track down issues with View.ShadingModelMaskInView\n")
TEXT(" 0: off (default)\n")
TEXT(" 1: logging is enabled\n")
TEXT("-1: logging is enabled for one frame only"),
ECVF_Scalability | ECVF_RenderThreadSafe);
static TAutoConsoleVariable<int32> CVarUseMobileBloom(
TEXT("r.UseMobileBloom"),
0,
TEXT("HACK: Set to 1 to use mobile bloom."),
ECVF_Scalability | ECVF_RenderThreadSafe);
static TAutoConsoleVariable<float> CVarDepthOfFieldNearBlurSizeThreshold(
TEXT("r.DepthOfField.NearBlurSizeThreshold"),
0.01f,
TEXT("Sets the minimum near blur size before the effect is forcably disabled. Currently only affects Gaussian DOF.\n")
TEXT(" (default: 0.01)"),
ECVF_RenderThreadSafe);
static TAutoConsoleVariable<float> CVarDepthOfFieldMaxSize(
TEXT("r.DepthOfField.MaxSize"),
100.0f,
TEXT("Allows to clamp the gaussian depth of field radius (for better performance), default: 100"),
ECVF_Scalability | ECVF_RenderThreadSafe);
static TAutoConsoleVariable<int32> CVarRenderTargetSwitchWorkaround(
TEXT("r.RenderTargetSwitchWorkaround"),
0,
TEXT("Workaround needed on some mobile platforms to avoid a performance drop related to switching render targets.\n")
TEXT("Only enabled on some hardware. This affects the bloom quality a bit. It runs slower than the normal code path but\n")
TEXT("still faster as it avoids the many render target switches. (Default: 0)\n")
TEXT("We want this enabled (1) on all 32 bit iOS devices (implemented through DeviceProfiles)."),
ECVF_RenderThreadSafe);
static TAutoConsoleVariable<int32> CVarUpscaleQuality(
TEXT("r.Upscale.Quality"),
3,
TEXT("Defines the quality in which ScreenPercentage and WindowedFullscreen scales the 3d rendering.\n")
TEXT(" 0: Nearest filtering\n")
TEXT(" 1: Simple Bilinear\n")
TEXT(" 2: 4 tap bilinear\n")
TEXT(" 3: Directional blur with unsharp mask upsample. (default)"),
ECVF_Scalability | ECVF_RenderThreadSafe);
static TAutoConsoleVariable<int32> CDownsampleQuality(
TEXT("r.Downsample.Quality"),
3,
TEXT("Defines the quality in which the Downsample passes. we might add more quality levels later.\n")
TEXT(" 0: low quality\n")
TEXT(">0: high quality (default: 3)\n"),
ECVF_Scalability | ECVF_RenderThreadSafe);
static TAutoConsoleVariable<float> CVarMotionBlurSoftEdgeSize(
TEXT("r.MotionBlurSoftEdgeSize"),
1.0f,
TEXT("Defines how wide the object motion blur is blurred (percent of screen width) to allow soft edge motion blur.\n")
TEXT("This scales linearly with the size (up to a maximum of 32 samples, 2.5 is about 18 samples) and with screen resolution\n")
TEXT("Smaller values are better for performance and provide more accurate motion vectors but the blurring outside the object is reduced.\n")
TEXT("If needed this can be exposed like the other motionblur settings.\n")
TEXT(" 0:off (not free and does never completely disable), >0, 1.0 (default)"),
ECVF_RenderThreadSafe);
static TAutoConsoleVariable<float> CVarBloomCross(
TEXT("r.Bloom.Cross"),
0.0f,
TEXT("Experimental feature to give bloom kernel a more bright center sample (values between 1 and 3 work without causing aliasing)\n")
TEXT("Existing bloom get lowered to match the same brightness\n")
TEXT("<0 for a anisomorphic lens flare look (X only)\n")
TEXT(" 0 off (default)\n")
TEXT(">0 for a cross look (X and Y)"),
ECVF_RenderThreadSafe);
static TAutoConsoleVariable<int32> CVarTonemapperScreenPercentage(
TEXT("r.Tonemapper.ScreenPercentage"),
0,
TEXT("Experimental ScreenPercentage upscale integrated into tonemapper pass (if certain conditions apply e.g. no FXAA)\n")
TEXT(" if enabled both features are done in one pass (faster, affects post process passes after the tonemapper including material post process e.g. sharpen)\n")
TEXT(" 0: off, the features run in separate passes (default)\n")
TEXT(" 1: enabled if nothing prevents it which is safe but it might do the two pass method"),
ECVF_Scalability | ECVF_RenderThreadSafe);
static TAutoConsoleVariable<int32> CVarMotionBlurNew(
TEXT("r.MotionBlurNew"),
1,
TEXT(""),
ECVF_RenderThreadSafe
);
static TAutoConsoleVariable<int32> CVarMotionBlurScatter(
TEXT("r.MotionBlurScatter"),
0,
TEXT(""),
ECVF_RenderThreadSafe
);
static TAutoConsoleVariable<int32> CVarMotionBlurSeparable(
TEXT("r.MotionBlurSeparable"),
0,
TEXT(""),
ECVF_RenderThreadSafe
);
IMPLEMENT_SHADER_TYPE(,FPostProcessVS,TEXT("PostProcessBloom"),TEXT("MainPostprocessCommonVS"),SF_Vertex);
static bool HasPostProcessMaterial(FPostprocessContext& Context, EBlendableLocation InLocation);
// -------------------------------------------------------
FPostprocessContext::FPostprocessContext(FRHICommandListImmediate& InRHICmdList, FRenderingCompositionGraph& InGraph, const FViewInfo& InView)
: RHICmdList(InRHICmdList)
, Graph(InGraph)
, View(InView)
, SceneColor(0)
, SceneDepth(0)
{
FSceneRenderTargets& SceneContext = FSceneRenderTargets::Get_Todo_PassContext();
if(SceneContext.IsSceneColorAllocated())
{
SceneColor = Graph.RegisterPass(new(FMemStack::Get()) FRCPassPostProcessInput(SceneContext.GetSceneColor()));
}
SceneDepth = Graph.RegisterPass(new(FMemStack::Get()) FRCPassPostProcessInput(SceneContext.SceneDepthZ));
FinalOutput = FRenderingCompositeOutputRef(SceneColor);
}
// Array of downsampled color with optional log2 luminance stored in alpha
template <int32 DownSampleStages>
class TBloomDownSampleArray
{
public:
// Convenience typedefs
typedef FRenderingCompositeOutputRef FRenderingRefArray[DownSampleStages];
typedef TSharedPtr<TBloomDownSampleArray> Ptr;
// Constructor: Generates and registers the downsamples with the Context Graph.
TBloomDownSampleArray(FPostprocessContext& InContext, FRenderingCompositeOutputRef SourceDownsample, bool bGenerateLog2Alpha) :
bHasLog2Alpha(bGenerateLog2Alpha), Context(InContext)
{
// Optionally encode log2 data in the alpha channel. Used for EyeAdaptation.
if (bHasLog2Alpha) {
FRenderingCompositePass* BasicEyeSetupPass = Context.Graph.RegisterPass(new(FMemStack::Get()) FRCPassPostProcessBasicEyeAdaptationSetUp());
BasicEyeSetupPass->SetInput(ePId_Input0, SourceDownsample);
PostProcessDownsamples[0] = FRenderingCompositeOutputRef(BasicEyeSetupPass);
}
else
{
// The source becomes the 0th down sample.
PostProcessDownsamples[0] = SourceDownsample;
}
// Queue the additional down samples. T
for (int i = 1; i < DownSampleStages; i++)
{
static const TCHAR* PassLabels[] =
{ NULL, TEXT("BloomDownsample1"), TEXT("BloomDownsample2"), TEXT("BloomDownsample3"), TEXT("BloomDownsample4"), TEXT("BloomDownsample5") };
static_assert(ARRAY_COUNT(PassLabels) == DownSampleStages, "PassLabel count must be equal to DownSampleStages.");
FRenderingCompositePass* Pass = Context.Graph.RegisterPass(new(FMemStack::Get()) FRCPassPostProcessDownsample(PF_Unknown, 1, PassLabels[i]));
Pass->SetInput(ePId_Input0, PostProcessDownsamples[i - 1]);
PostProcessDownsamples[i] = FRenderingCompositeOutputRef(Pass);
}
}
// The number of elements in the array.
inline static int32 Num() { return DownSampleStages; }
// Member data kept public for simplicity
bool bHasLog2Alpha;
FPostprocessContext& Context;
FRenderingRefArray PostProcessDownsamples;
private:
// no default constructor.
TBloomDownSampleArray() {};
};
// Standard DownsampleArray shared by Bloom, Tint, and Eye-Adaptation.
typedef TBloomDownSampleArray<6/*DownSampleStages*/> FBloomDownSampleArray;
FBloomDownSampleArray::Ptr CreateDownSampleArray(FPostprocessContext& Context, FRenderingCompositeOutputRef SourceToDownSample, bool bAddLog2)
{
return FBloomDownSampleArray::Ptr(new FBloomDownSampleArray(Context, SourceToDownSample, bAddLog2));
}
static FRenderingCompositeOutputRef RenderHalfResBloomThreshold(FPostprocessContext& Context, FRenderingCompositeOutputRef SceneColorHalfRes, FRenderingCompositeOutputRef EyeAdaptation)
{
// with multiple view ports the Setup pass also isolates the view from the others which allows for simpler simpler/faster blur passes.
if(Context.View.FinalPostProcessSettings.BloomThreshold <= -1 && Context.View.Family->Views.Num() == 1)
{
// no need for threshold, we don't need this pass
return SceneColorHalfRes;
}
else
{
// todo: optimize later, the missing node causes some wrong behavior
// if(Context.View.FinalPostProcessSettings.BloomIntensity <= 0.0f)
// {
// // this pass is not required
// return FRenderingCompositeOutputRef();
// }
// bloom threshold
FRenderingCompositePass* PostProcessBloomSetup = Context.Graph.RegisterPass(new(FMemStack::Get()) FRCPassPostProcessBloomSetup());
PostProcessBloomSetup->SetInput(ePId_Input0, SceneColorHalfRes);
PostProcessBloomSetup->SetInput(ePId_Input1, EyeAdaptation);
return FRenderingCompositeOutputRef(PostProcessBloomSetup);
}
}
// 2 pass Gaussian blur using uni-linear filtering
// @param CrossCenterWeight see r.Bloom.Cross (positive for X and Y, otherwise for X only)
static FRenderingCompositeOutputRef RenderGaussianBlur(
FPostprocessContext& Context,
const TCHAR* DebugNameX,
const TCHAR* DebugNameY,
const FRenderingCompositeOutputRef& Input,
float SizeScale,
FLinearColor Tint = FLinearColor::White,
const FRenderingCompositeOutputRef Additive = FRenderingCompositeOutputRef(),
float CrossCenterWeight = 0.0f)
{
// Gaussian blur in x
FRCPassPostProcessWeightedSampleSum* PostProcessBlurX = Context.Graph.RegisterPass(new(FMemStack::Get()) FRCPassPostProcessWeightedSampleSum(EFS_Horiz, EFCM_Weighted, SizeScale, DebugNameX));
PostProcessBlurX->SetInput(ePId_Input0, Input);
if(CrossCenterWeight > 0)
{
PostProcessBlurX->SetCrossCenterWeight(CrossCenterWeight);
}
// Gaussian blur in y
FRCPassPostProcessWeightedSampleSum* PostProcessBlurY = Context.Graph.RegisterPass(new(FMemStack::Get()) FRCPassPostProcessWeightedSampleSum(EFS_Vert, EFCM_Weighted, SizeScale, DebugNameY, Tint));
PostProcessBlurY->SetInput(ePId_Input0, FRenderingCompositeOutputRef(PostProcessBlurX));
PostProcessBlurY->SetInput(ePId_Input1, Additive);
PostProcessBlurY->SetCrossCenterWeight(FMath::Abs(CrossCenterWeight));
return FRenderingCompositeOutputRef(PostProcessBlurY);
}
// render one bloom pass and add another optional texture to it
static FRenderingCompositeOutputRef RenderBloom(
FPostprocessContext& Context,
const FRenderingCompositeOutputRef& PreviousBloom,
float Size,
FLinearColor Tint = FLinearColor::White,
const FRenderingCompositeOutputRef Additive = FRenderingCompositeOutputRef())
{
const float CrossBloom = CVarBloomCross.GetValueOnRenderThread();
return RenderGaussianBlur(Context, TEXT("BloomBlurX"), TEXT("BloomBlurY"), PreviousBloom, Size, Tint, Additive,CrossBloom);
}
static FRCPassPostProcessTonemap* AddTonemapper(
FPostprocessContext& Context,
const FRenderingCompositeOutputRef& BloomOutputCombined,
const FRenderingCompositeOutputRef& EyeAdaptation,
const EAutoExposureMethod& EyeAdapationMethodId)
{
const FEngineShowFlags& EngineShowFlags = Context.View.Family->EngineShowFlags;
FRenderingCompositePass* CombinedLUT = Context.Graph.RegisterPass(new(FMemStack::Get()) FRCPassPostProcessCombineLUTs(Context.View.GetShaderPlatform()));
const bool bDoEyeAdaptation = IsAutoExposureMethodSupported(Context.View.GetFeatureLevel(), EyeAdapationMethodId);
FRCPassPostProcessTonemap* PostProcessTonemap = Context.Graph.RegisterPass(new(FMemStack::Get()) FRCPassPostProcessTonemap(Context.View, false, bDoEyeAdaptation));
PostProcessTonemap->SetInput(ePId_Input0, Context.FinalOutput);
PostProcessTonemap->SetInput(ePId_Input1, BloomOutputCombined);
PostProcessTonemap->SetInput(ePId_Input2, EyeAdaptation);
PostProcessTonemap->SetInput(ePId_Input3, CombinedLUT);
Context.FinalOutput = FRenderingCompositeOutputRef(PostProcessTonemap);
return PostProcessTonemap;
}
#if WITH_EDITOR
static void AddSelectionOutline(FPostprocessContext& Context)
{
FRenderingCompositePass* SelectionColorPass = Context.Graph.RegisterPass(new(FMemStack::Get()) FRCPassPostProcessSelectionOutlineColor());
SelectionColorPass->SetInput(ePId_Input0, FRenderingCompositeOutputRef(Context.FinalOutput));
FRenderingCompositePass* Node = Context.Graph.RegisterPass(new(FMemStack::Get()) FRCPassPostProcessSelectionOutline());
Node->SetInput(ePId_Input0, FRenderingCompositeOutputRef(Context.FinalOutput));
Node->SetInput(ePId_Input1, FRenderingCompositeOutputRef(FRenderingCompositeOutputRef(SelectionColorPass)));
Context.FinalOutput = FRenderingCompositeOutputRef(Node);
}
#endif
static void AddGammaOnlyTonemapper(FPostprocessContext& Context)
{
FRenderingCompositePass* PostProcessTonemap = Context.Graph.RegisterPass(new(FMemStack::Get()) FRCPassPostProcessTonemap(Context.View, true, false/*eye*/));
PostProcessTonemap->SetInput(ePId_Input0, Context.FinalOutput);
Context.FinalOutput = FRenderingCompositeOutputRef(PostProcessTonemap);
}
static void AddPostProcessAA(FPostprocessContext& Context)
{
// console variable override
static const auto CVar = IConsoleManager::Get().FindTConsoleVariableDataInt(TEXT("r.PostProcessAAQuality"));
uint32 Quality = FMath::Clamp(CVar->GetValueOnRenderThread(), 1, 6);
FRenderingCompositePass* Node = Context.Graph.RegisterPass(new(FMemStack::Get()) FRCPassPostProcessAA(Quality));
Node->SetInput(ePId_Input0, FRenderingCompositeOutputRef(Context.FinalOutput));
Context.FinalOutput = FRenderingCompositeOutputRef(Node);
}
static FRenderingCompositeOutputRef AddPostProcessBasicEyeAdaptation(FViewInfo& View, FBloomDownSampleArray& BloomAndEyeDownSamples)
{
// Extract the context
FPostprocessContext& Context = BloomAndEyeDownSamples.Context;
// Extract the last (i.e. smallest) down sample
static const int32 FinalDSIdx = FBloomDownSampleArray::Num() - 1;
FRenderingCompositeOutputRef PostProcessPriorReduction = BloomAndEyeDownSamples.PostProcessDownsamples[FinalDSIdx];
// Compute the eye adaptation value based on average luminance from log2 luminance buffer, history, and specific shader parameters.
FRenderingCompositePass* Node = Context.Graph.RegisterPass(new(FMemStack::Get()) FRCPassPostProcessBasicEyeAdaptation());
Node->SetInput(ePId_Input0, PostProcessPriorReduction);
return FRenderingCompositeOutputRef(Node);
}
static FRenderingCompositeOutputRef AddPostProcessHistogramEyeAdaptation(FPostprocessContext& Context, FRenderingCompositeOutputRef& Histogram)
{
FRenderingCompositePass* Node = Context.Graph.RegisterPass(new(FMemStack::Get()) FRCPassPostProcessEyeAdaptation());
Node->SetInput(ePId_Input0, Histogram);
return FRenderingCompositeOutputRef(Node);
}
static void AddVisualizeBloomSetup(FPostprocessContext& Context)
{
auto Node = Context.Graph.RegisterPass(new(FMemStack::Get()) FRCPassPostProcessVisualizeBloomSetup());
Node->SetInput(ePId_Input0, Context.FinalOutput);
Context.FinalOutput = FRenderingCompositeOutputRef(Node);
}
static void AddVisualizeBloomOverlay(FPostprocessContext& Context, FRenderingCompositeOutputRef& HDRColor, FRenderingCompositeOutputRef& BloomOutputCombined)
{
auto Node = Context.Graph.RegisterPass(new(FMemStack::Get()) FRCPassPostProcessVisualizeBloomOverlay());
Node->SetInput(ePId_Input0, Context.FinalOutput);
Node->SetInput(ePId_Input1, HDRColor);
Node->SetInput(ePId_Input2, BloomOutputCombined);
Context.FinalOutput = FRenderingCompositeOutputRef(Node);
}
static void AddPostProcessDepthOfFieldBokeh(FPostprocessContext& Context, FRenderingCompositeOutputRef& SeparateTranslucency, FRenderingCompositeOutputRef& VelocityInput)
{
// downsample, mask out the in focus part, depth in alpha
FRenderingCompositePass* DOFSetup = Context.Graph.RegisterPass(new(FMemStack::Get()) FRCPassPostProcessBokehDOFSetup());
DOFSetup->SetInput(ePId_Input0, FRenderingCompositeOutputRef(Context.FinalOutput));
DOFSetup->SetInput(ePId_Input1, FRenderingCompositeOutputRef(Context.SceneDepth));
FSceneViewState* ViewState = (FSceneViewState*)Context.View.State;
FRenderingCompositePass* DOFInputPass = DOFSetup;
if( Context.View.FinalPostProcessSettings.AntiAliasingMethod == AAM_TemporalAA && ViewState )
{
FRenderingCompositePass* HistoryInput;
if( ViewState->DOFHistoryRT && ViewState->bDOFHistory && !Context.View.bCameraCut )
{
HistoryInput = Context.Graph.RegisterPass( new(FMemStack::Get()) FRCPassPostProcessInput( ViewState->DOFHistoryRT ) );
}
else
{
// No history so use current as history
HistoryInput = DOFSetup;
}
FRenderingCompositePass* NodeTemporalAA = Context.Graph.RegisterPass( new(FMemStack::Get()) FRCPassPostProcessDOFTemporalAA );
NodeTemporalAA->SetInput( ePId_Input0, DOFSetup );
NodeTemporalAA->SetInput( ePId_Input1, FRenderingCompositeOutputRef( HistoryInput ) );
NodeTemporalAA->SetInput( ePId_Input2, FRenderingCompositeOutputRef( HistoryInput ) );
NodeTemporalAA->SetInput( ePId_Input3, VelocityInput );
DOFInputPass = NodeTemporalAA;
ViewState->bDOFHistory = true;
}
FRenderingCompositePass* NodeBlurred = Context.Graph.RegisterPass(new(FMemStack::Get()) FRCPassPostProcessBokehDOF());
NodeBlurred->SetInput(ePId_Input0, DOFInputPass);
NodeBlurred->SetInput(ePId_Input1, Context.SceneColor);
NodeBlurred->SetInput(ePId_Input2, Context.SceneDepth);
FRenderingCompositePass* NodeRecombined = Context.Graph.RegisterPass(new(FMemStack::Get()) FRCPassPostProcessBokehDOFRecombine());
NodeRecombined->SetInput(ePId_Input0, Context.FinalOutput);
NodeRecombined->SetInput(ePId_Input1, NodeBlurred);
NodeRecombined->SetInput(ePId_Input2, SeparateTranslucency);
Context.FinalOutput = FRenderingCompositeOutputRef(NodeRecombined);
}
static bool AddPostProcessDepthOfFieldGaussian(FPostprocessContext& Context, FDepthOfFieldStats& Out, FRenderingCompositeOutputRef& VelocityInput, FRenderingCompositeOutputRef& SeparateTranslucency)
{
bool bSepTransWasApplied = false;
float FarSize = Context.View.FinalPostProcessSettings.DepthOfFieldFarBlurSize;
float NearSize = Context.View.FinalPostProcessSettings.DepthOfFieldNearBlurSize;
float MaxSize = CVarDepthOfFieldMaxSize.GetValueOnRenderThread();
FarSize = FMath::Min(FarSize, MaxSize);
NearSize = FMath::Min(NearSize, MaxSize);
Out.bFar = FarSize >= 0.01f;
{
const float CVarThreshold = CVarDepthOfFieldNearBlurSizeThreshold.GetValueOnRenderThread();
Out.bNear = (NearSize >= CVarThreshold);
}
if(Context.View.Family->EngineShowFlags.VisualizeDOF)
{
// no need for this pass
Out.bFar = false;
Out.bNear = false;
}
FSceneViewState* ViewState = (FSceneViewState*)Context.View.State;
if(Out.bFar)
{
FRenderingCompositePass* DOFSetupFar = Context.Graph.RegisterPass(new(FMemStack::Get()) FRCPassPostProcessDOFSetup(Out.bFar, false));
DOFSetupFar->SetInput(ePId_Input0, FRenderingCompositeOutputRef(Context.FinalOutput));
DOFSetupFar->SetInput(ePId_Input1, FRenderingCompositeOutputRef(Context.SceneDepth));
FRenderingCompositePass* DOFInputPassFar = DOFSetupFar;
if(Context.View.FinalPostProcessSettings.AntiAliasingMethod == AAM_TemporalAA && ViewState)
{
// If no history use current as history
FRenderingCompositePass* HistoryInput = DOFSetupFar;
if(ViewState->DOFHistoryRT && !ViewState->bDOFHistory && !Context.View.bCameraCut)
{
HistoryInput = Context.Graph.RegisterPass( new(FMemStack::Get()) FRCPassPostProcessInput(ViewState->DOFHistoryRT));
}
FRenderingCompositePass* NodeTemporalAA = Context.Graph.RegisterPass( new(FMemStack::Get()) FRCPassPostProcessDOFTemporalAA );
NodeTemporalAA->SetInput( ePId_Input0, DOFSetupFar );
NodeTemporalAA->SetInput( ePId_Input1, FRenderingCompositeOutputRef( HistoryInput ) );
NodeTemporalAA->SetInput( ePId_Input2, FRenderingCompositeOutputRef( HistoryInput ) );
NodeTemporalAA->SetInput( ePId_Input3, VelocityInput );
DOFInputPassFar = NodeTemporalAA;
ViewState->bDOFHistory = false;
}
FRenderingCompositeOutputRef Far = RenderGaussianBlur(Context, TEXT("FarDOFBlurX"), TEXT("FarDOFBlurY"), FRenderingCompositeOutputRef(DOFInputPassFar, ePId_Output0), FarSize);
FRenderingCompositePass* NodeAllButNear = Context.Graph.RegisterPass(new(FMemStack::Get()) FRCPassPostProcessDOFRecombine());
NodeAllButNear->SetInput(ePId_Input0, Context.FinalOutput);
NodeAllButNear->SetInput(ePId_Input1, Far);
NodeAllButNear->SetInput(ePId_Input3, SeparateTranslucency);
bSepTransWasApplied = true;
Context.FinalOutput = FRenderingCompositeOutputRef(NodeAllButNear);
}
// near
if(Out.bNear)
{
FRenderingCompositePass* DOFSetupNear = Context.Graph.RegisterPass(new(FMemStack::Get()) FRCPassPostProcessDOFSetup(false, Out.bNear));
DOFSetupNear->SetInput(ePId_Input0, Context.FinalOutput);
DOFSetupNear->SetInput(ePId_Input1, Context.SceneDepth);
FRenderingCompositePass* DOFInputPassNear = DOFSetupNear;
if(Context.View.FinalPostProcessSettings.AntiAliasingMethod == AAM_TemporalAA && ViewState)
{
// If no history use current as history
FRenderingCompositePass* HistoryInput = DOFSetupNear;
if(ViewState->DOFHistoryRT2 && !ViewState->bDOFHistory2 && !Context.View.bCameraCut)
{
HistoryInput = Context.Graph.RegisterPass(new(FMemStack::Get()) FRCPassPostProcessInput(ViewState->DOFHistoryRT2));
}
FRenderingCompositePass* NodeTemporalAA = Context.Graph.RegisterPass(new(FMemStack::Get()) FRCPassPostProcessDOFTemporalAANear);
NodeTemporalAA->SetInput( ePId_Input0, DOFSetupNear );
NodeTemporalAA->SetInput( ePId_Input1, HistoryInput);
NodeTemporalAA->SetInput( ePId_Input2, HistoryInput);
NodeTemporalAA->SetInput( ePId_Input3, VelocityInput );
DOFInputPassNear = NodeTemporalAA;
ViewState->bDOFHistory2 = false;
}
FRenderingCompositeOutputRef Near = RenderGaussianBlur(Context, TEXT("NearDOFBlurX"), TEXT("NearDOFBlurY"), FRenderingCompositeOutputRef(DOFInputPassNear, ePId_Output0), NearSize);
FRenderingCompositePass* NodeRecombined = Context.Graph.RegisterPass(new(FMemStack::Get()) FRCPassPostProcessDOFRecombine());
NodeRecombined->SetInput(ePId_Input0, Context.FinalOutput);
NodeRecombined->SetInput(ePId_Input2, Near);
if(!bSepTransWasApplied)
{
NodeRecombined->SetInput(ePId_Input3, SeparateTranslucency);
bSepTransWasApplied = true;
}
Context.FinalOutput = FRenderingCompositeOutputRef(NodeRecombined);
}
return bSepTransWasApplied;
}
static void AddPostProcessDepthOfFieldCircle(FPostprocessContext& Context, FDepthOfFieldStats& Out, FRenderingCompositeOutputRef& VelocityInput)
{
if(Context.View.Family->EngineShowFlags.VisualizeDOF)
{
// no need for this pass
return;
}
FRenderingCompositePass* DOFSetup = Context.Graph.RegisterPass(new(FMemStack::Get()) FRCPassPostProcessCircleDOFSetup(false));
DOFSetup->SetInput(ePId_Input0, FRenderingCompositeOutputRef(Context.FinalOutput));
DOFSetup->SetInput(ePId_Input1, FRenderingCompositeOutputRef(Context.SceneDepth));
FSceneViewState* ViewState = (FSceneViewState*)Context.View.State;
FRenderingCompositePass* DOFInputPass = DOFSetup;
if( Context.View.FinalPostProcessSettings.AntiAliasingMethod == AAM_TemporalAA && ViewState )
{
FRenderingCompositePass* HistoryInput;
if( ViewState->DOFHistoryRT && !ViewState->bDOFHistory && !Context.View.bCameraCut )
{
HistoryInput = Context.Graph.RegisterPass( new(FMemStack::Get()) FRCPassPostProcessInput( ViewState->DOFHistoryRT ) );
}
else
{
// No history so use current as history
HistoryInput = DOFSetup;
}
FRenderingCompositePass* NodeTemporalAA = Context.Graph.RegisterPass( new(FMemStack::Get()) FRCPassPostProcessDOFTemporalAA );
NodeTemporalAA->SetInput( ePId_Input0, DOFSetup );
NodeTemporalAA->SetInput( ePId_Input1, FRenderingCompositeOutputRef( HistoryInput ) );
NodeTemporalAA->SetInput( ePId_Input2, FRenderingCompositeOutputRef( HistoryInput ) );
NodeTemporalAA->SetInput( ePId_Input3, VelocityInput );
DOFInputPass = NodeTemporalAA;
ViewState->bDOFHistory = false;
}
FRenderingCompositeOutputRef Far;
FRenderingCompositeOutputRef Near;
FRenderingCompositePass* DOFNear = Context.Graph.RegisterPass(new(FMemStack::Get()) FRCPassPostProcessCircleDOFDilate());
DOFNear->SetInput(ePId_Input0, FRenderingCompositeOutputRef(DOFInputPass, ePId_Output0));
Near = FRenderingCompositeOutputRef(DOFNear, ePId_Output0);
FRenderingCompositePass* DOFApply = Context.Graph.RegisterPass(new(FMemStack::Get()) FRCPassPostProcessCircleDOF(false));
DOFApply->SetInput(ePId_Input0, FRenderingCompositeOutputRef(DOFInputPass, ePId_Output0));
DOFApply->SetInput(ePId_Input1, Near);
Far = FRenderingCompositeOutputRef(DOFApply, ePId_Output0);
FRenderingCompositePass* NodeRecombined = Context.Graph.RegisterPass(new(FMemStack::Get()) FRCPassPostProcessCircleDOFRecombine(false));
NodeRecombined->SetInput(ePId_Input0, Context.FinalOutput);
NodeRecombined->SetInput(ePId_Input1, Far);
Context.FinalOutput = FRenderingCompositeOutputRef(NodeRecombined);
}
static FRenderingCompositeOutputRef AddBloom(FBloomDownSampleArray& BloomDownSampleArray, bool bVisualizeBloom)
{
// Quality level to bloom stages table. Note: 0 is omitted, ensure element count tallys with the range documented with 'r.BloomQuality' definition.
const static uint32 BloomQualityStages[] =
{
3,// Q1
3,// Q2
4,// Q3
5,// Q4
6,// Q5
};
int32 BloomQuality;
{
// console variable override
static const auto CVar = IConsoleManager::Get().FindTConsoleVariableDataInt(TEXT("r.BloomQuality"));
BloomQuality = FMath::Clamp(CVar->GetValueOnRenderThread(), 0, (int32)ARRAY_COUNT(BloomQualityStages));
}
// Extract the Context
FPostprocessContext& Context = BloomDownSampleArray.Context;
// Extract the downsample array.
FBloomDownSampleArray::FRenderingRefArray& PostProcessDownsamples = BloomDownSampleArray.PostProcessDownsamples;
FRenderingCompositeOutputRef BloomOutput;
if (BloomQuality == 0)
{
// No bloom, provide substitute source for lens flare.
BloomOutput = PostProcessDownsamples[0];
}
else
{
// Perform bloom blur + accumulate.
struct FBloomStage
{
float BloomSize;
const FLinearColor* Tint;
};
const FFinalPostProcessSettings& Settings = Context.View.FinalPostProcessSettings;
FBloomStage BloomStages[] =
{
{ Settings.Bloom6Size, &Settings.Bloom6Tint },
{ Settings.Bloom5Size, &Settings.Bloom5Tint },
{ Settings.Bloom4Size, &Settings.Bloom4Tint },
{ Settings.Bloom3Size, &Settings.Bloom3Tint },
{ Settings.Bloom2Size, &Settings.Bloom2Tint },
{ Settings.Bloom1Size, &Settings.Bloom1Tint },
};
static const uint32 NumBloomStages = ARRAY_COUNT(BloomStages);
const uint32 BloomStageCount = BloomQualityStages[BloomQuality - 1];
check(BloomStageCount <= NumBloomStages);
float TintScale = 1.0f / NumBloomStages;
for (uint32 i = 0, SourceIndex = NumBloomStages - 1; i < BloomStageCount; i++, SourceIndex--)
{
FBloomStage& Op = BloomStages[i];
FLinearColor Tint = (*Op.Tint) * TintScale;
if (bVisualizeBloom)
{
float LumScale = Tint.ComputeLuminance();
// R is used to pass down the reference, G is the emulated bloom
Tint.R = 0;
Tint.G = LumScale;
Tint.B = 0;
}
BloomOutput = RenderBloom(Context, PostProcessDownsamples[SourceIndex], Op.BloomSize * Settings.BloomSizeScale, Tint, BloomOutput);
}
}
// Lens Flares
FLinearColor LensFlareHDRColor = Context.View.FinalPostProcessSettings.LensFlareTint * Context.View.FinalPostProcessSettings.LensFlareIntensity;
static const int32 MaxLensFlareQuality = 3;
int32 LensFlareQuality;
{
// console variable override
static const auto CVar = IConsoleManager::Get().FindTConsoleVariableDataInt(TEXT("r.LensFlareQuality"));
LensFlareQuality = FMath::Clamp(CVar->GetValueOnRenderThread(), 0, MaxLensFlareQuality);
}
if (!LensFlareHDRColor.IsAlmostBlack() && LensFlareQuality > 0 && !bVisualizeBloom)
{
float PercentKernelSize = Context.View.FinalPostProcessSettings.LensFlareBokehSize;
bool bLensBlur = PercentKernelSize > 0.3f;
FRenderingCompositePass* PostProcessFlares = Context.Graph.RegisterPass(new(FMemStack::Get()) FRCPassPostProcessLensFlares(bLensBlur ? 2.0f : 1.0f));
PostProcessFlares->SetInput(ePId_Input0, BloomOutput);
FRenderingCompositeOutputRef LensFlareInput = PostProcessDownsamples[MaxLensFlareQuality - LensFlareQuality];
if (bLensBlur)
{
float Threshold = Context.View.FinalPostProcessSettings.LensFlareThreshold;
FRenderingCompositePass* PostProcessLensBlur = Context.Graph.RegisterPass(new(FMemStack::Get()) FRCPassPostProcessLensBlur(PercentKernelSize, Threshold));
PostProcessLensBlur->SetInput(ePId_Input0, LensFlareInput);
PostProcessFlares->SetInput(ePId_Input1, FRenderingCompositeOutputRef(PostProcessLensBlur));
}
else
{
// fast: no blurring or blurring shared from bloom
PostProcessFlares->SetInput(ePId_Input1, LensFlareInput);
}
BloomOutput = FRenderingCompositeOutputRef(PostProcessFlares);
}
return BloomOutput;
}
static void AddTemporalAA( FPostprocessContext& Context, FRenderingCompositeOutputRef& VelocityInput )
{
check(VelocityInput.IsValid());
FSceneViewState* ViewState = (FSceneViewState*)Context.View.State;
FRenderingCompositePass* HistoryInput;
if( ViewState && ViewState->TemporalAAHistoryRT && !Context.View.bCameraCut )
{
HistoryInput = Context.Graph.RegisterPass( new(FMemStack::Get()) FRCPassPostProcessInput( ViewState->TemporalAAHistoryRT ) );
}
else
{
// No history so use current as history
HistoryInput = Context.Graph.RegisterPass( new(FMemStack::Get()) FRCPassPostProcessInput( FSceneRenderTargets::Get_Todo_PassContext().GetSceneColor() ) );
}
FRenderingCompositePass* TemporalAAPass = Context.Graph.RegisterPass( new(FMemStack::Get()) FRCPassPostProcessTemporalAA );
TemporalAAPass->SetInput( ePId_Input0, Context.FinalOutput );
TemporalAAPass->SetInput( ePId_Input1, FRenderingCompositeOutputRef( HistoryInput ) );
TemporalAAPass->SetInput( ePId_Input2, FRenderingCompositeOutputRef( HistoryInput ) );
TemporalAAPass->SetInput( ePId_Input3, VelocityInput );
Context.FinalOutput = FRenderingCompositeOutputRef( TemporalAAPass );
}
FPostProcessMaterialNode* IteratePostProcessMaterialNodes(const FFinalPostProcessSettings& Dest, EBlendableLocation InLocation, FBlendableEntry*& Iterator)
{
for(;;)
{
FPostProcessMaterialNode* DataPtr = Dest.BlendableManager.IterateBlendables<FPostProcessMaterialNode>(Iterator);
if(!DataPtr || DataPtr->GetLocation() == InLocation)
{
return DataPtr;
}
}
}
static FRenderingCompositePass* AddSinglePostProcessMaterial(FPostprocessContext& Context, EBlendableLocation InLocation)
{
if(!Context.View.Family->EngineShowFlags.PostProcessing || !Context.View.Family->EngineShowFlags.PostProcessMaterial)
{
return 0;
}
FBlendableEntry* Iterator = 0;
FPostProcessMaterialNode PPNode;
while(FPostProcessMaterialNode* Data = IteratePostProcessMaterialNodes(Context.View.FinalPostProcessSettings, InLocation, Iterator))
{
check(Data->GetMaterialInterface());
if(PPNode.IsValid())
{
FPostProcessMaterialNode::FCompare Dummy;
// take the one with the highest priority
if(!Dummy.operator()(PPNode, *Data))
{
continue;
}
}
PPNode = *Data;
}
if(UMaterialInterface* MaterialInterface = PPNode.GetMaterialInterface())
{
FMaterialRenderProxy* Proxy = MaterialInterface->GetRenderProxy(false);
check(Proxy);
const FMaterial* Material = Proxy->GetMaterial(Context.View.GetFeatureLevel());
check(Material);
if(Material->NeedsGBuffer())
{
// AdjustGBufferRefCount(-1) call is done when the pass gets executed
FSceneRenderTargets::Get_Todo_PassContext().AdjustGBufferRefCount(Context.RHICmdList, 1);
}
FRenderingCompositePass* Node = Context.Graph.RegisterPass(new(FMemStack::Get()) FRCPassPostProcessMaterial(MaterialInterface, Context.View.GetFeatureLevel()));
return Node;
}
return 0;
}
// simplied version of AddPostProcessMaterial(), side effect free
static bool HasPostProcessMaterial(FPostprocessContext& Context, EBlendableLocation InLocation)
{
if(!Context.View.Family->EngineShowFlags.PostProcessing || !Context.View.Family->EngineShowFlags.PostProcessMaterial)
{
return false;
}
if(Context.View.Family->EngineShowFlags.VisualizeBuffer)
{
// Apply requested material to the full screen
UMaterial* Material = GetBufferVisualizationData().GetMaterial(Context.View.CurrentBufferVisualizationMode);
if(Material && Material->BlendableLocation == InLocation)
{
return true;
}
}
FBlendableEntry* Iterator = 0;
FPostProcessMaterialNode* Data = IteratePostProcessMaterialNodes(Context.View.FinalPostProcessSettings, InLocation, Iterator);
if(Data)
{
return true;
}
return false;
}
static void AddPostProcessMaterial(FPostprocessContext& Context, EBlendableLocation InLocation, FRenderingCompositeOutputRef SeparateTranslucency, FRenderingCompositeOutputRef HDRColor = FRenderingCompositeOutputRef())
{
if( !Context.View.Family->EngineShowFlags.PostProcessing ||
!Context.View.Family->EngineShowFlags.PostProcessMaterial ||
Context.View.Family->EngineShowFlags.VisualizeShadingModels) // we should add more
{
return;
}
// hard coded - this should be a reasonable limit
const uint32 MAX_PPMATERIALNODES = 10;
FBlendableEntry* Iterator = 0;
FPostProcessMaterialNode PPNodes[MAX_PPMATERIALNODES];
uint32 PPNodeCount = 0;
bool bVisualizingBuffer = false;
if(Context.View.Family->EngineShowFlags.VisualizeBuffer)
{
// Apply requested material to the full screen
UMaterial* Material = GetBufferVisualizationData().GetMaterial(Context.View.CurrentBufferVisualizationMode);
if(Material && Material->BlendableLocation == InLocation)
{
PPNodes[0] = FPostProcessMaterialNode(Material, InLocation, Material->BlendablePriority);
++PPNodeCount;
bVisualizingBuffer = true;
}
}
for(;PPNodeCount < MAX_PPMATERIALNODES; ++PPNodeCount)
{
FPostProcessMaterialNode* Data = IteratePostProcessMaterialNodes(Context.View.FinalPostProcessSettings, InLocation, Iterator);
if(!Data)
{
break;
}
check(Data->GetMaterialInterface());
PPNodes[PPNodeCount] = *Data;
}
::Sort(PPNodes, PPNodeCount, FPostProcessMaterialNode::FCompare());
ERHIFeatureLevel::Type FeatureLevel = Context.View.GetFeatureLevel();
for(uint32 i = 0; i < PPNodeCount; ++i)
{
UMaterialInterface* MaterialInterface = PPNodes[i].GetMaterialInterface();
FMaterialRenderProxy* Proxy = MaterialInterface->GetRenderProxy(false);
check(Proxy);
const FMaterial* Material = Proxy->GetMaterial(Context.View.GetFeatureLevel());
check(Material);
if(Material->NeedsGBuffer())
{
// AdjustGBufferRefCount(-1) call is done when the pass gets executed
FSceneRenderTargets::Get_Todo_PassContext().AdjustGBufferRefCount(Context.RHICmdList, 1);
}
FRenderingCompositePass* Node = Context.Graph.RegisterPass(new(FMemStack::Get()) FRCPassPostProcessMaterial(MaterialInterface,FeatureLevel));
Node->SetInput(ePId_Input0, FRenderingCompositeOutputRef(Context.FinalOutput));
// We are binding separate translucency here because the post process SceneTexture node can reference
// the separate translucency buffers through ePId_Input1.
// TODO: Check if material actually uses this texture and only bind if needed.
Node->SetInput(ePId_Input1, SeparateTranslucency);
// This input is only needed for visualization and frame dumping
if (bVisualizingBuffer)
{
Node->SetInput(ePId_Input2, HDRColor);
}
Context.FinalOutput = FRenderingCompositeOutputRef(Node);
}
}
static void AddHighResScreenshotMask(FPostprocessContext& Context, FRenderingCompositeOutputRef& SeparateTranslucencyInput)
{
if (Context.View.Family->EngineShowFlags.HighResScreenshotMask != 0)
{
check(Context.View.FinalPostProcessSettings.HighResScreenshotMaterial);
FRenderingCompositeOutputRef Input = Context.FinalOutput;
FRenderingCompositePass* CompositePass = Context.Graph.RegisterPass(new(FMemStack::Get()) FRCPassPostProcessMaterial(Context.View.FinalPostProcessSettings.HighResScreenshotMaterial, Context.View.GetFeatureLevel()));
CompositePass->SetInput(ePId_Input0, FRenderingCompositeOutputRef(Input));
Context.FinalOutput = FRenderingCompositeOutputRef(CompositePass);
if (GIsHighResScreenshot)
{
check(Context.View.FinalPostProcessSettings.HighResScreenshotMaskMaterial);
FRenderingCompositePass* MaskPass = Context.Graph.RegisterPass(new(FMemStack::Get()) FRCPassPostProcessMaterial(Context.View.FinalPostProcessSettings.HighResScreenshotMaskMaterial, Context.View.GetFeatureLevel()));
MaskPass->SetInput(ePId_Input0, FRenderingCompositeOutputRef(Input));
CompositePass->AddDependency(MaskPass);
FString BaseFilename = FString(Context.View.FinalPostProcessSettings.BufferVisualizationDumpBaseFilename);
MaskPass->SetOutputColorArray(ePId_Output0, FScreenshotRequest::GetHighresScreenshotMaskColorArray());
}
}
// Draw the capture region if a material was supplied
if (Context.View.FinalPostProcessSettings.HighResScreenshotCaptureRegionMaterial)
{
auto Material = Context.View.FinalPostProcessSettings.HighResScreenshotCaptureRegionMaterial;
FRenderingCompositePass* CaptureRegionVisualizationPass = Context.Graph.RegisterPass(new(FMemStack::Get()) FRCPassPostProcessMaterial(Material, Context.View.GetFeatureLevel()));
CaptureRegionVisualizationPass->SetInput(ePId_Input0, FRenderingCompositeOutputRef(Context.FinalOutput));
Context.FinalOutput = FRenderingCompositeOutputRef(CaptureRegionVisualizationPass);
auto Proxy = Material->GetRenderProxy(false);
const FMaterial* RendererMaterial = Proxy->GetMaterial(Context.View.GetFeatureLevel());
if (RendererMaterial->NeedsGBuffer())
{
// AdjustGBufferRefCount(-1) call is done when the pass gets executed
FSceneRenderTargets::Get_Todo_PassContext().AdjustGBufferRefCount(Context.RHICmdList, 1);
}
}
}
static void AddGBufferVisualizationOverview(FPostprocessContext& Context, FRenderingCompositeOutputRef& SeparateTranslucencyInput, FRenderingCompositeOutputRef& HDRColorInput)
{
static const auto CVarDumpFrames = IConsoleManager::Get().FindTConsoleVariableDataInt(TEXT("r.BufferVisualizationDumpFrames"));
static const auto CVarDumpFramesAsHDR = IConsoleManager::Get().FindTConsoleVariableDataInt(TEXT("r.BufferVisualizationDumpFramesAsHDR"));
bool bVisualizationEnabled = Context.View.Family->EngineShowFlags.VisualizeBuffer;
bool bOverviewModeEnabled = bVisualizationEnabled && (Context.View.CurrentBufferVisualizationMode == NAME_None);
bool bHighResBufferVisualizationDumpRequried = GIsHighResScreenshot && GetHighResScreenshotConfig().bDumpBufferVisualizationTargets;
bool bDumpFrames = Context.View.FinalPostProcessSettings.bBufferVisualizationDumpRequired && (CVarDumpFrames->GetValueOnRenderThread() || bHighResBufferVisualizationDumpRequried);
bool bCaptureAsHDR = CVarDumpFramesAsHDR->GetValueOnRenderThread() || GetHighResScreenshotConfig().bCaptureHDR;
FString BaseFilename;
if (bDumpFrames)
{
BaseFilename = FString(Context.View.FinalPostProcessSettings.BufferVisualizationDumpBaseFilename);
}
if (bDumpFrames || bVisualizationEnabled)
{
FRenderingCompositeOutputRef IncomingStage = Context.FinalOutput;
if (bDumpFrames || bOverviewModeEnabled)
{
FRenderingCompositePass* CompositePass = Context.Graph.RegisterPass(new(FMemStack::Get()) FRCPassPostProcessVisualizeBuffer());
CompositePass->SetInput(ePId_Input0, FRenderingCompositeOutputRef(IncomingStage));
Context.FinalOutput = FRenderingCompositeOutputRef(CompositePass);
EPixelFormat OutputFormat = bCaptureAsHDR ? PF_FloatRGBA : PF_Unknown;
// Loop over materials, creating stages for generation and downsampling of the tiles.
for (TArray<UMaterialInterface*>::TConstIterator It = Context.View.FinalPostProcessSettings.BufferVisualizationOverviewMaterials.CreateConstIterator(); It; ++It)
{
auto MaterialInterface = *It;
if (MaterialInterface)
{
// Apply requested material
FRenderingCompositePass* MaterialPass = Context.Graph.RegisterPass(new(FMemStack::Get()) FRCPassPostProcessMaterial(*It, Context.View.GetFeatureLevel(), OutputFormat));
MaterialPass->SetInput(ePId_Input0, FRenderingCompositeOutputRef(IncomingStage));
MaterialPass->SetInput(ePId_Input1, FRenderingCompositeOutputRef(SeparateTranslucencyInput));
MaterialPass->SetInput(ePId_Input2, FRenderingCompositeOutputRef(HDRColorInput));
auto Proxy = MaterialInterface->GetRenderProxy(false);
const FMaterial* Material = Proxy->GetMaterial(Context.View.GetFeatureLevel());
if (Material->NeedsGBuffer())
{
// AdjustGBufferRefCount(-1) call is done when the pass gets executed
FSceneRenderTargets::Get_Todo_PassContext().AdjustGBufferRefCount(Context.RHICmdList, 1);
}
if (BaseFilename.Len())
{
FString MaterialFilename = BaseFilename + TEXT("_") + (*It)->GetName() + TEXT(".png");
MaterialPass->SetOutputDumpFilename(ePId_Output0, *MaterialFilename);
}
// If the overview mode is activated, downsample the material pass to quarter size
if (bOverviewModeEnabled)
{
// Down-sample to 1/2 size
FRenderingCompositePass* HalfSize = Context.Graph.RegisterPass(new(FMemStack::Get()) FRCPassPostProcessDownsample(PF_Unknown, 0, TEXT("MaterialHalfSize")));
HalfSize->SetInput(ePId_Input0, FRenderingCompositeOutputRef(MaterialPass));
// Down-sample to 1/4 size
FRenderingCompositePass* QuarterSize = Context.Graph.RegisterPass(new(FMemStack::Get()) FRCPassPostProcessDownsample(PF_Unknown, 0, TEXT("MaterialQuarterSize")));
QuarterSize->SetInput(ePId_Input0, FRenderingCompositeOutputRef(HalfSize));
// Mark the quarter size target as the dependency for the composite pass
((FRCPassPostProcessVisualizeBuffer*)CompositePass)->AddVisualizationBuffer(FRenderingCompositeOutputRef(QuarterSize), (*It)->GetName());
}
else
{
// We are just dumping the frames, so the material pass is the dependency of the composite
CompositePass->AddDependency(MaterialPass);
}
}
else
{
if (bOverviewModeEnabled)
{
((FRCPassPostProcessVisualizeBuffer*)CompositePass)->AddVisualizationBuffer(FRenderingCompositeOutputRef(), FString());
}
}
}
}
}
}
// could be moved into the graph
// allows for Framebuffer blending optimization with the composition graph
void OverrideRenderTarget(FRenderingCompositeOutputRef It, TRefCountPtr<IPooledRenderTarget>& RT, FPooledRenderTargetDesc& Desc)
{
for(;;)
{
It.GetOutput()->PooledRenderTarget = RT;
It.GetOutput()->RenderTargetDesc = Desc;
if(!It.GetPass()->FrameBufferBlendingWithInput0())
{
break;
}
It = *It.GetPass()->GetInput(ePId_Input0);
}
}
bool FPostProcessing::AllowFullPostProcessing(const FViewInfo& View, ERHIFeatureLevel::Type FeatureLevel)
{
return View.Family->EngineShowFlags.PostProcessing
&& FeatureLevel >= ERHIFeatureLevel::SM4
&& !View.Family->EngineShowFlags.VisualizeDistanceFieldAO
&& !View.Family->EngineShowFlags.VisualizeDistanceFieldGI
&& !View.Family->EngineShowFlags.VisualizeShadingModels
&& !View.Family->EngineShowFlags.VisualizeMeshDistanceFields;
}
void FPostProcessing::Process(FRHICommandListImmediate& RHICmdList, FViewInfo& View, TRefCountPtr<IPooledRenderTarget>& VelocityRT)
{
QUICK_SCOPE_CYCLE_COUNTER( STAT_PostProcessing_Process );
check(IsInRenderingThread());
const auto FeatureLevel = View.GetFeatureLevel();
GRenderTargetPool.AddPhaseEvent(TEXT("PostProcessing"));
// This page: https://udn.epicgames.com/Three/RenderingOverview#Rendering%20state%20defaults
// describes what state a pass can expect and to what state it need to be set back.
// All post processing is happening on the render thread side. All passes can access FinalPostProcessSettings and all
// view settings. Those are copies for the RT then never get access by the main thread again.
// Pointers to other structures might be unsafe to touch.
// so that the passes can register themselves to the graph
{
FMemMark Mark(FMemStack::Get());
FRenderingCompositePassContext CompositeContext(RHICmdList, View);
FPostprocessContext Context(RHICmdList, CompositeContext.Graph, View);
// not always valid
FRenderingCompositeOutputRef HDRColor;
// not always valid
FRenderingCompositeOutputRef HistogramOverScreen;
// not always valid
FRenderingCompositeOutputRef Histogram;
class FAutoExposure
{
public:
FAutoExposure(const FViewInfo& InView) :
MethodId(GetAutoExposureMethod(InView))
{}
// distinguish between Basic and Histogram-based
EAutoExposureMethod MethodId;
// not always valid
FRenderingCompositeOutputRef EyeAdaptation;
} AutoExposure(View);
// not always valid
FRenderingCompositeOutputRef SeparateTranslucency;
// optional
FRenderingCompositeOutputRef BloomOutputCombined;
// not always valid
FRenderingCompositePass* VelocityFlattenPass = 0;
// in the following code some feature might set this to false
bool bAllowTonemapper = FeatureLevel >= ERHIFeatureLevel::SM4;
//
bool bStereoRenderingAndHMD = View.Family->EngineShowFlags.StereoRendering && View.Family->EngineShowFlags.HMDDistortion;
//
FRCPassPostProcessUpscale::PaniniParams PaniniConfig(View);
//
EStereoscopicPass StereoPass = View.StereoPass;
//
FSceneViewState* ViewState = (FSceneViewState*)Context.View.State;
//
bool bDoScreenPercentage;
{
//
bool bHMDWantsUpscale = bStereoRenderingAndHMD && GEngine->HMDDevice->NeedsUpscalePostProcessPass();
// Do not use upscale if SeparateRenderTarget is in use! (stereo rendering wants to control this)
bool bAllowScreenPercentage = bHMDWantsUpscale || !View.Family->EngineShowFlags.StereoRendering || (!View.Family->EngineShowFlags.HMDDistortion && !View.Family->bUseSeparateRenderTarget);
// is Upscale from a lower resolution needed and allowed
bDoScreenPercentage = bAllowScreenPercentage && (View.UnscaledViewRect != View.ViewRect);
}
{
if (FSceneRenderTargets::Get(RHICmdList).SeparateTranslucencyRT)
{
FRenderingCompositePass* NodeSeparateTranslucency = Context.Graph.RegisterPass(new(FMemStack::Get()) FRCPassPostProcessInput(FSceneRenderTargets::Get(RHICmdList).SeparateTranslucencyRT));
SeparateTranslucency = FRenderingCompositeOutputRef(NodeSeparateTranslucency);
// make sure we only release if this is the last view we're rendering
int32 LastView = View.Family->Views.Num() - 1;
if (View.Family->Views[LastView] == &View)
{
// the node keeps another reference so the RT will not be release too early
FSceneRenderTargets::Get(RHICmdList).FreeSeparateTranslucency();
check(!FSceneRenderTargets::Get(RHICmdList).SeparateTranslucencyRT);
}
}
}
bool bVisualizeHDR = View.Family->EngineShowFlags.VisualizeHDR && FeatureLevel >= ERHIFeatureLevel::SM5;
bool bVisualizeBloom = View.Family->EngineShowFlags.VisualizeBloom && FeatureLevel >= ERHIFeatureLevel::SM4;
if(bVisualizeHDR || bVisualizeBloom)
{
bAllowTonemapper = false;
}
FRCPassPostProcessTonemap* Tonemapper = 0;
// add the passes we want to add to the graph (commenting a line means the pass is not inserted into the graph) ---------
if (AllowFullPostProcessing(View, FeatureLevel))
{
FRenderingCompositeOutputRef VelocityInput;
if(VelocityRT)
{
VelocityInput = Context.Graph.RegisterPass(new(FMemStack::Get()) FRCPassPostProcessInput(VelocityRT));
}
if( Context.View.FinalPostProcessSettings.AntiAliasingMethod != AAM_TemporalAA && ViewState )
{
if(ViewState->DOFHistoryRT)
{
ViewState->DOFHistoryRT.SafeRelease();
}
if(ViewState->TemporalAAHistoryRT)
{
ViewState->TemporalAAHistoryRT.SafeRelease();
}
}
AddPostProcessMaterial(Context, BL_BeforeTranslucency, SeparateTranslucency);
static const auto CVar = IConsoleManager::Get().FindTConsoleVariableDataInt(TEXT("r.DepthOfFieldQuality"));
check(CVar)
bool bDepthOfField = View.Family->EngineShowFlags.DepthOfField && CVar->GetValueOnRenderThread() > 0;
FDepthOfFieldStats DepthOfFieldStat;
bool bSepTransWasApplied = false;
if(bDepthOfField && View.FinalPostProcessSettings.DepthOfFieldMethod != DOFM_BokehDOF)
{
bool bCircleDOF = View.FinalPostProcessSettings.DepthOfFieldMethod == DOFM_CircleDOF;
if(!bCircleDOF)
{
if(VelocityInput.IsValid())
{
bSepTransWasApplied = AddPostProcessDepthOfFieldGaussian(Context, DepthOfFieldStat, VelocityInput, SeparateTranslucency);
}
else
{
// todo: black/white default is a compositing graph feature, no need to hook up a node
// black is how we clear the velocity buffer so this means no velocity
FRenderingCompositePass* NoVelocity = Context.Graph.RegisterPass(new(FMemStack::Get()) FRCPassPostProcessInput(GSystemTextures.BlackDummy));
FRenderingCompositeOutputRef NoVelocityRef(NoVelocity);
bSepTransWasApplied = AddPostProcessDepthOfFieldGaussian(Context, DepthOfFieldStat, NoVelocityRef, SeparateTranslucency);
}
}
else
{
if(VelocityInput.IsValid())
{
AddPostProcessDepthOfFieldCircle(Context, DepthOfFieldStat, VelocityInput);
}
else
{
// todo: black/white default is a compositing graph feature, no need to hook up a node
// black is how we clear the velocity buffer so this means no velocity
FRenderingCompositePass* NoVelocity = Context.Graph.RegisterPass(new(FMemStack::Get()) FRCPassPostProcessInput(GSystemTextures.BlackDummy));
FRenderingCompositeOutputRef NoVelocityRef(NoVelocity);
AddPostProcessDepthOfFieldCircle(Context, DepthOfFieldStat, NoVelocityRef);
}
}
}
bool bBokehDOF = bDepthOfField
&& View.FinalPostProcessSettings.DepthOfFieldScale > 0
&& View.FinalPostProcessSettings.DepthOfFieldMethod == DOFM_BokehDOF
&& !Context.View.Family->EngineShowFlags.VisualizeDOF;
if(bBokehDOF)
{
if(VelocityInput.IsValid())
{
AddPostProcessDepthOfFieldBokeh(Context, SeparateTranslucency, VelocityInput);
}
else
{
// todo: black/white default is a compositing graph feature, no need to hook up a node
// black is how we clear the velocity buffer so this means no velocity
FRenderingCompositePass* NoVelocity = Context.Graph.RegisterPass(new(FMemStack::Get()) FRCPassPostProcessInput(GSystemTextures.BlackDummy));
FRenderingCompositeOutputRef NoVelocityRef(NoVelocity);
AddPostProcessDepthOfFieldBokeh(Context, SeparateTranslucency, NoVelocityRef);
}
bSepTransWasApplied = true;
}
if(SeparateTranslucency.IsValid() && !bSepTransWasApplied)
{
// separate translucency is done here or in AddPostProcessDepthOfFieldBokeh()
FRenderingCompositePass* NodeRecombined = Context.Graph.RegisterPass(new(FMemStack::Get()) FRCPassPostProcessBokehDOFRecombine());
NodeRecombined->SetInput(ePId_Input0, Context.FinalOutput);
NodeRecombined->SetInput(ePId_Input2, SeparateTranslucency);
Context.FinalOutput = FRenderingCompositeOutputRef(NodeRecombined);
}
AddPostProcessMaterial(Context, BL_BeforeTonemapping, SeparateTranslucency);
EAntiAliasingMethod AntiAliasingMethod = Context.View.FinalPostProcessSettings.AntiAliasingMethod;
if( AntiAliasingMethod == AAM_TemporalAA && ViewState)
{
if(VelocityInput.IsValid())
{
AddTemporalAA( Context, VelocityInput );
}
else
{
// black is how we clear the velocity buffer so this means no velocity
FRenderingCompositePass* NoVelocity = Context.Graph.RegisterPass(new(FMemStack::Get()) FRCPassPostProcessInput(GSystemTextures.BlackDummy));
FRenderingCompositeOutputRef NoVelocityRef(NoVelocity);
AddTemporalAA( Context, NoVelocityRef );
}
}
if(IsMotionBlurEnabled(View) && VelocityInput.IsValid())
{
// Motion blur
if( CVarMotionBlurNew.GetValueOnRenderThread() && FeatureLevel >= ERHIFeatureLevel::SM5 )
{
FRenderingCompositeOutputRef MaxTileVelocity;
FRenderingCompositeOutputRef SceneDepth( Context.SceneDepth );
{
check(!VelocityFlattenPass);
VelocityFlattenPass = Context.Graph.RegisterPass( new(FMemStack::Get()) FRCPassPostProcessVelocityFlatten() );
VelocityFlattenPass->SetInput( ePId_Input0, VelocityInput );
VelocityFlattenPass->SetInput( ePId_Input1, SceneDepth );
VelocityInput = FRenderingCompositeOutputRef( VelocityFlattenPass, ePId_Output0 );
MaxTileVelocity = FRenderingCompositeOutputRef( VelocityFlattenPass, ePId_Output1 );
}
const float SizeX = View.ViewRect.Width();
// 0:no 1:full screen width, percent conversion
float MaxVelocity = View.FinalPostProcessSettings.MotionBlurMax / 100.0f;
float MaxVelocityTiles = MaxVelocity * SizeX * (0.5f / 16.0f);
float MaxTileDistGathered = 3.0f;
if( MaxVelocityTiles > MaxTileDistGathered || CVarMotionBlurScatter.GetValueOnRenderThread() )
{
FRenderingCompositePass* VelocityScatterPass = Context.Graph.RegisterPass( new(FMemStack::Get()) FRCPassPostProcessVelocityScatter() );
VelocityScatterPass->SetInput( ePId_Input0, MaxTileVelocity );
MaxTileVelocity = FRenderingCompositeOutputRef( VelocityScatterPass );
}
else
{
FRenderingCompositePass* VelocityGatherPass = Context.Graph.RegisterPass( new(FMemStack::Get()) FRCPassPostProcessVelocityGather() );
VelocityGatherPass->SetInput( ePId_Input0, MaxTileVelocity );
MaxTileVelocity = FRenderingCompositeOutputRef( VelocityGatherPass );
}
bool bTwoPass = CVarMotionBlurSeparable.GetValueOnRenderThread() != 0;
{
FRenderingCompositePass* MotionBlurPass = Context.Graph.RegisterPass( new(FMemStack::Get()) FRCPassPostProcessMotionBlurNew( GetMotionBlurQualityFromCVar(), bTwoPass ? 0 : -1 ) );
MotionBlurPass->SetInput( ePId_Input0, Context.FinalOutput );
MotionBlurPass->SetInput( ePId_Input1, SceneDepth );
MotionBlurPass->SetInput( ePId_Input2, VelocityInput );
MotionBlurPass->SetInput( ePId_Input3, MaxTileVelocity );
Context.FinalOutput = FRenderingCompositeOutputRef( MotionBlurPass );
}
if( bTwoPass )
{
FRenderingCompositePass* MotionBlurPass = Context.Graph.RegisterPass( new(FMemStack::Get()) FRCPassPostProcessMotionBlurNew( GetMotionBlurQualityFromCVar(), 1 ) );
MotionBlurPass->SetInput( ePId_Input0, Context.FinalOutput );
MotionBlurPass->SetInput( ePId_Input1, SceneDepth );
MotionBlurPass->SetInput( ePId_Input2, VelocityInput );
MotionBlurPass->SetInput( ePId_Input3, MaxTileVelocity );
Context.FinalOutput = FRenderingCompositeOutputRef( MotionBlurPass );
}
}
else
{
FRenderingCompositeOutputRef SoftEdgeVelocity;
FRenderingCompositeOutputRef MotionBlurHalfVelocity;
FRenderingCompositeOutputRef MotionBlurColorDepth;
// down sample screen space velocity and extend outside of borders to allows soft edge motion blur
{
// Down sample and prepare for soft masked blurring
FRenderingCompositePass* HalfResVelocity = Context.Graph.RegisterPass(new(FMemStack::Get()) FRCPassPostProcessMotionBlurSetup());
HalfResVelocity->SetInput(ePId_Input0, VelocityInput);
HalfResVelocity->SetInput(ePId_Input1, FRenderingCompositeOutputRef(Context.FinalOutput));
// only for Depth of Field we need the depth in the alpha channel
HalfResVelocity->SetInput(ePId_Input2, FRenderingCompositeOutputRef(Context.SceneDepth));
MotionBlurHalfVelocity = FRenderingCompositeOutputRef(HalfResVelocity, ePId_Output0);
MotionBlurColorDepth = FRenderingCompositeOutputRef(HalfResVelocity, ePId_Output1);
FRenderingCompositePass* QuarterResVelocity = Context.Graph.RegisterPass(new(FMemStack::Get()) FRCPassPostProcessDownsample(PF_Unknown, 0, TEXT("QuarterResVelocity")));
QuarterResVelocity->SetInput(ePId_Input0, HalfResVelocity);
SoftEdgeVelocity = FRenderingCompositeOutputRef(QuarterResVelocity);
float MotionBlurSoftEdgeSize = CVarMotionBlurSoftEdgeSize.GetValueOnRenderThread();
if(MotionBlurSoftEdgeSize > 0.01f)
{
SoftEdgeVelocity = RenderGaussianBlur(Context, TEXT("VelocityBlurX"), TEXT("VelocityBlurY"), QuarterResVelocity, MotionBlurSoftEdgeSize);
}
}
// doing the actual motion blur sampling, alpha to mask out the blurred areas
FRenderingCompositePass* MotionBlurPass;
if(View.Family->EngineShowFlags.VisualizeMotionBlur)
{
MotionBlurPass = Context.Graph.RegisterPass(new(FMemStack::Get()) FRCPassPostProcessVisualizeMotionBlur());
bAllowTonemapper = false;
}
else
{
int32 MotionBlurQuality = GetMotionBlurQualityFromCVar();
MotionBlurPass = Context.Graph.RegisterPass(new(FMemStack::Get()) FRCPassPostProcessMotionBlur(MotionBlurQuality));
}
MotionBlurPass->SetInput(ePId_Input0, MotionBlurColorDepth);
if(VelocityInput.IsValid())
{
// blurred screen space velocity for soft masked motion blur
MotionBlurPass->SetInput(ePId_Input1, SoftEdgeVelocity);
// screen space velocity input from per object velocity rendering
MotionBlurPass->SetInput(ePId_Input2, MotionBlurHalfVelocity);
}
FRenderingCompositePass* MotionBlurRecombinePass = Context.Graph.RegisterPass(new(FMemStack::Get()) FRCPassPostProcessMotionBlurRecombine());
MotionBlurRecombinePass->SetInput(ePId_Input0, Context.FinalOutput);
MotionBlurRecombinePass->SetInput(ePId_Input1, FRenderingCompositeOutputRef(MotionBlurPass));
Context.FinalOutput = FRenderingCompositeOutputRef(MotionBlurRecombinePass);
}
}
if(bVisualizeBloom)
{
AddVisualizeBloomSetup(Context);
}
// down sample Scene color from full to half res
FRenderingCompositeOutputRef SceneColorHalfRes;
{
int32 DownsampleQuality = FMath::Clamp(CDownsampleQuality.GetValueOnRenderThread(), 0, 1);
// doesn't have to be as high quality as the Scene color
FRenderingCompositePass* HalfResPass = Context.Graph.RegisterPass(new(FMemStack::Get()) FRCPassPostProcessDownsample(PF_FloatRGB, DownsampleQuality, TEXT("SceneColorHalfRes")));
HalfResPass->SetInput(ePId_Input0, FRenderingCompositeOutputRef(Context.FinalOutput));
SceneColorHalfRes = FRenderingCompositeOutputRef(HalfResPass);
}
{
bool bHistogramNeeded = false;
if (View.Family->EngineShowFlags.EyeAdaptation && (AutoExposure.MethodId == EAutoExposureMethod::AEM_Histogram)
&& View.FinalPostProcessSettings.AutoExposureMinBrightness < View.FinalPostProcessSettings.AutoExposureMaxBrightness
&& !View.bIsSceneCapture // Eye adaption is not available for scene captures.
&& !bVisualizeBloom)
{
bHistogramNeeded = true;
}
if(!bAllowTonemapper)
{
bHistogramNeeded = false;
}
if(View.Family->EngineShowFlags.VisualizeHDR)
{
bHistogramNeeded = true;
}
if (!GIsHighResScreenshot && bHistogramNeeded && FeatureLevel >= ERHIFeatureLevel::SM5 && StereoPass != eSSP_RIGHT_EYE)
{
FRenderingCompositePass* NodeHistogram = Context.Graph.RegisterPass(new(FMemStack::Get()) FRCPassPostProcessHistogram());
NodeHistogram->SetInput(ePId_Input0, SceneColorHalfRes);
HistogramOverScreen = FRenderingCompositeOutputRef(NodeHistogram);
FRenderingCompositePass* NodeHistogramReduce = Context.Graph.RegisterPass(new(FMemStack::Get()) FRCPassPostProcessHistogramReduce());
NodeHistogramReduce->SetInput(ePId_Input0, NodeHistogram);
Histogram = FRenderingCompositeOutputRef(NodeHistogramReduce);
}
}
// Compute DownSamples passes used by bloom, tint and eye-adaptation if possible.
FBloomDownSampleArray::Ptr BloomAndEyeDownSamplesPtr;
if (View.FinalPostProcessSettings.BloomIntensity > 0.f) // do bloom
{
// No Threshold: We can share with Eye-Adaptation.
if (Context.View.FinalPostProcessSettings.BloomThreshold <= -1 && Context.View.Family->Views.Num() == 1)
{
if (!GIsHighResScreenshot && View.State &&
(StereoPass != eSSP_RIGHT_EYE) &&
(AutoExposure.MethodId == EAutoExposureMethod::AEM_Basic))
{
BloomAndEyeDownSamplesPtr = CreateDownSampleArray(Context, SceneColorHalfRes, true /*bGenerateLog2Alpha*/);
}
}
}
// some views don't have a state (thumbnail rendering)
if(!GIsHighResScreenshot && View.State && (StereoPass != eSSP_RIGHT_EYE))
{
const bool bUseBasicEyeAdaptation = (AutoExposure.MethodId == EAutoExposureMethod::AEM_Basic);
if (bUseBasicEyeAdaptation) // log average ps reduction ( non histogram )
{
if (!BloomAndEyeDownSamplesPtr.IsValid())
{
// need downsamples for eye-adaptation.
FBloomDownSampleArray::Ptr EyeDownSamplesPtr = CreateDownSampleArray(Context, SceneColorHalfRes, true /*bGenerateLog2Alpha*/);
AutoExposure.EyeAdaptation = AddPostProcessBasicEyeAdaptation(View, *EyeDownSamplesPtr);
}
else
{
// Use the alpha channel in the last downsample (smallest) to compute eye adaptations values.
AutoExposure.EyeAdaptation = AddPostProcessBasicEyeAdaptation(View, *BloomAndEyeDownSamplesPtr);
}
}
else // Use histogram version version
{
// we always add eye adaptation, if the engine show flag is disabled we set the ExposureScale in the texture to a fixed value
AutoExposure.EyeAdaptation = AddPostProcessHistogramEyeAdaptation(Context, Histogram);
}
}
if(View.FinalPostProcessSettings.BloomIntensity > 0.0f)
{
if (CVarUseMobileBloom.GetValueOnRenderThread() == 0)
{
if (!BloomAndEyeDownSamplesPtr.IsValid())
{
FRenderingCompositeOutputRef HalfResBloomThreshold = RenderHalfResBloomThreshold(Context, SceneColorHalfRes, AutoExposure.EyeAdaptation);
BloomAndEyeDownSamplesPtr = CreateDownSampleArray(Context, HalfResBloomThreshold, false /*bGenerateLog2Alpha*/);
}
BloomOutputCombined = AddBloom(*BloomAndEyeDownSamplesPtr, bVisualizeBloom);
}
else
{
FIntPoint PrePostSourceViewportSize = View.ViewRect.Size();
// Bloom.
FRenderingCompositeOutputRef PostProcessDownsample2;
FRenderingCompositeOutputRef PostProcessDownsample3;
FRenderingCompositeOutputRef PostProcessDownsample4;
FRenderingCompositeOutputRef PostProcessDownsample5;
FRenderingCompositeOutputRef PostProcessUpsample4;
FRenderingCompositeOutputRef PostProcessUpsample3;
FRenderingCompositeOutputRef PostProcessUpsample2;
FRenderingCompositeOutputRef PostProcessSunMerge;
float DownScale = 0.66f * 4.0f;
// Downsample by 2
{
FRenderingCompositePass* Pass = Context.Graph.RegisterPass(new(FMemStack::Get()) FRCPassPostProcessBloomDownES2(PrePostSourceViewportSize/4, DownScale));
Pass->SetInput(ePId_Input0, SceneColorHalfRes);
PostProcessDownsample2 = FRenderingCompositeOutputRef(Pass);
}
// Downsample by 2
{
FRenderingCompositePass* Pass = Context.Graph.RegisterPass(new(FMemStack::Get()) FRCPassPostProcessBloomDownES2(PrePostSourceViewportSize/8, DownScale));
Pass->SetInput(ePId_Input0, PostProcessDownsample2);
PostProcessDownsample3 = FRenderingCompositeOutputRef(Pass);
}
// Downsample by 2
{
FRenderingCompositePass* Pass = Context.Graph.RegisterPass(new(FMemStack::Get()) FRCPassPostProcessBloomDownES2(PrePostSourceViewportSize/16, DownScale));
Pass->SetInput(ePId_Input0, PostProcessDownsample3);
PostProcessDownsample4 = FRenderingCompositeOutputRef(Pass);
}
// Downsample by 2
{
FRenderingCompositePass* Pass = Context.Graph.RegisterPass(new(FMemStack::Get()) FRCPassPostProcessBloomDownES2(PrePostSourceViewportSize/32, DownScale));
Pass->SetInput(ePId_Input0, PostProcessDownsample4);
PostProcessDownsample5 = FRenderingCompositeOutputRef(Pass);
}
const FFinalPostProcessSettings& Settings = Context.View.FinalPostProcessSettings;
float UpScale = 0.66f * 2.0f;
// Upsample by 2
{
FVector4 TintA = FVector4(Settings.Bloom4Tint.R, Settings.Bloom4Tint.G, Settings.Bloom4Tint.B, 0.0f);
FVector4 TintB = FVector4(Settings.Bloom5Tint.R, Settings.Bloom5Tint.G, Settings.Bloom5Tint.B, 0.0f);
TintA *= View.FinalPostProcessSettings.BloomIntensity;
TintB *= View.FinalPostProcessSettings.BloomIntensity;
FRenderingCompositePass* Pass = Context.Graph.RegisterPass(new(FMemStack::Get()) FRCPassPostProcessBloomUpES2(PrePostSourceViewportSize/32, FVector2D(UpScale, UpScale), TintA, TintB));
Pass->SetInput(ePId_Input0, PostProcessDownsample4);
Pass->SetInput(ePId_Input1, PostProcessDownsample5);
PostProcessUpsample4 = FRenderingCompositeOutputRef(Pass);
}
// Upsample by 2
{
FVector4 TintA = FVector4(Settings.Bloom3Tint.R, Settings.Bloom3Tint.G, Settings.Bloom3Tint.B, 0.0f);
TintA *= View.FinalPostProcessSettings.BloomIntensity;
FVector4 TintB = FVector4(1.0f, 1.0f, 1.0f, 0.0f);
FRenderingCompositePass* Pass = Context.Graph.RegisterPass(new(FMemStack::Get()) FRCPassPostProcessBloomUpES2(PrePostSourceViewportSize/16, FVector2D(UpScale, UpScale), TintA, TintB));
Pass->SetInput(ePId_Input0, PostProcessDownsample3);
Pass->SetInput(ePId_Input1, PostProcessUpsample4);
PostProcessUpsample3 = FRenderingCompositeOutputRef(Pass);
}
// Upsample by 2
{
FVector4 TintA = FVector4(Settings.Bloom2Tint.R, Settings.Bloom2Tint.G, Settings.Bloom2Tint.B, 0.0f);
TintA *= View.FinalPostProcessSettings.BloomIntensity;
// Scaling Bloom2 by extra factor to match filter area difference between PC default and mobile.
TintA *= 0.5;
FVector4 TintB = FVector4(1.0f, 1.0f, 1.0f, 0.0f);
FRenderingCompositePass* Pass = Context.Graph.RegisterPass(new(FMemStack::Get()) FRCPassPostProcessBloomUpES2(PrePostSourceViewportSize/8, FVector2D(UpScale, UpScale), TintA, TintB));
Pass->SetInput(ePId_Input0, PostProcessDownsample2);
Pass->SetInput(ePId_Input1, PostProcessUpsample3);
PostProcessUpsample2 = FRenderingCompositeOutputRef(Pass);
}
{
FRenderingCompositePass* Pass = Context.Graph.RegisterPass(new(FMemStack::Get()) FRCPassPostProcessSunMergeES2(PrePostSourceViewportSize));
Pass->SetInput(ePId_Input1, SceneColorHalfRes);
Pass->SetInput(ePId_Input2, PostProcessUpsample2);
PostProcessSunMerge = FRenderingCompositeOutputRef(Pass);
BloomOutputCombined = PostProcessSunMerge;
}
}
}
HDRColor = Context.FinalOutput;
if(bAllowTonemapper)
{
auto Node = AddSinglePostProcessMaterial(Context, BL_ReplacingTonemapper);
if(Node)
{
// a custom tonemapper is provided
Node->SetInput(ePId_Input0, Context.FinalOutput);
// We are binding separate translucency here because the post process SceneTexture node can reference
// the separate translucency buffers through ePId_Input1.
// TODO: Check if material actually uses this texture and only bind if needed.
Node->SetInput(ePId_Input1, SeparateTranslucency);
Node->SetInput(ePId_Input2, BloomOutputCombined);
Context.FinalOutput = Node;
}
else
{
Tonemapper = AddTonemapper(Context, BloomOutputCombined, AutoExposure.EyeAdaptation, AutoExposure.MethodId);
}
}
if(AntiAliasingMethod == AAM_FXAA)
{
AddPostProcessAA(Context);
}
if(bDepthOfField && Context.View.Family->EngineShowFlags.VisualizeDOF)
{
FRenderingCompositePass* VisualizeNode = Context.Graph.RegisterPass(new(FMemStack::Get()) FRCPassPostProcessVisualizeDOF(DepthOfFieldStat));
VisualizeNode->SetInput(ePId_Input0, FRenderingCompositeOutputRef(Context.FinalOutput));
Context.FinalOutput = FRenderingCompositeOutputRef(VisualizeNode);
bAllowTonemapper = false;
}
}
else
{
check(!FSceneRenderTargets::Get(RHICmdList).SeparateTranslucencyRT);
AddGammaOnlyTonemapper(Context);
}
if(View.Family->EngineShowFlags.StationaryLightOverlap)
{
FRenderingCompositePass* Node = Context.Graph.RegisterPass(new(FMemStack::Get()) FRCPassPostProcessVisualizeComplexity(GEngine->StationaryLightOverlapColors, FVisualizeComplexityApplyPS::CS_RAMP, 1.f, false));
Node->SetInput(ePId_Input0, FRenderingCompositeOutputRef(Context.SceneColor));
Context.FinalOutput = FRenderingCompositeOutputRef(Node);
}
const EDebugViewShaderMode DebugViewShaderMode = View.Family->GetDebugViewShaderMode();
if(DebugViewShaderMode == DVSM_QuadComplexity)
{
float ComplexityScale = 1.f / (float)(GEngine->QuadComplexityColors.Num() - 1) / NormalizedQuadComplexityValue; // .1f comes from the values used in LightAccumulator_GetResult
FRenderingCompositePass* Node = Context.Graph.RegisterPass(new(FMemStack::Get()) FRCPassPostProcessVisualizeComplexity(GEngine->QuadComplexityColors, FVisualizeComplexityApplyPS::CS_STAIR, ComplexityScale, true));
Node->SetInput(ePId_Input0, FRenderingCompositeOutputRef(Context.SceneColor));
Context.FinalOutput = FRenderingCompositeOutputRef(Node);
}
if(DebugViewShaderMode == DVSM_ShaderComplexity || DebugViewShaderMode == DVSM_ShaderComplexityContainedQuadOverhead || DebugViewShaderMode == DVSM_ShaderComplexityBleedingQuadOverhead)
{
FRenderingCompositePass* Node = Context.Graph.RegisterPass(new(FMemStack::Get()) FRCPassPostProcessVisualizeComplexity(GEngine->ShaderComplexityColors, FVisualizeComplexityApplyPS::CS_RAMP, 1.f, true));
Node->SetInput(ePId_Input0, FRenderingCompositeOutputRef(Context.SceneColor));
Context.FinalOutput = FRenderingCompositeOutputRef(Node);
}
if(View.Family->EngineShowFlags.VisualizeLightCulling)
{
float ComplexityScale = 1.f / (float)(GEngine->LightComplexityColors.Num() - 1) / .1f; // .1f comes from the values used in LightAccumulator_GetResult
FRenderingCompositePass* Node = Context.Graph.RegisterPass(new(FMemStack::Get()) FRCPassPostProcessVisualizeComplexity(GEngine->LightComplexityColors, FVisualizeComplexityApplyPS::CS_LINEAR, ComplexityScale, false));
Node->SetInput(ePId_Input0, FRenderingCompositeOutputRef(Context.SceneColor));
Context.FinalOutput = FRenderingCompositeOutputRef(Node);
}
if(View.Family->EngineShowFlags.VisualizeLPV && !View.Family->EngineShowFlags.VisualizeHDR)
{
FRenderingCompositePass* Node = Context.Graph.RegisterPass(new(FMemStack::Get()) FRCPassPostProcessVisualizeLPV());
Node->SetInput(ePId_Input0, Context.FinalOutput);
Context.FinalOutput = FRenderingCompositeOutputRef(Node);
}
#if WITH_EDITOR
// Show the selection outline if it is in the editor and we aren't in wireframe
// If the engine is in demo mode and game view is on we also do not show the selection outline
if ( GIsEditor
&& View.Family->EngineShowFlags.SelectionOutline
&& !(View.Family->EngineShowFlags.Wireframe)
&& ( !GIsDemoMode || ( GIsDemoMode && !View.Family->EngineShowFlags.Game ) )
&& !bVisualizeBloom
&& !View.Family->EngineShowFlags.VisualizeHDR)
{
// Selection outline is after bloom, but before AA
AddSelectionOutline(Context);
}
// Composite editor primitives if we had any to draw and compositing is enabled
if (FSceneRenderer::ShouldCompositeEditorPrimitives(View) && !bVisualizeBloom)
{
FRenderingCompositePass* Node = Context.Graph.RegisterPass(new(FMemStack::Get()) FRCPassPostProcessCompositeEditorPrimitives(true));
Node->SetInput(ePId_Input0, FRenderingCompositeOutputRef(Context.FinalOutput));
Context.FinalOutput = FRenderingCompositeOutputRef(Node);
}
#endif
if(View.Family->EngineShowFlags.VisualizeShadingModels && FeatureLevel >= ERHIFeatureLevel::SM4)
{
FRenderingCompositePass* Node = Context.Graph.RegisterPass(new(FMemStack::Get()) FRCPassPostProcessVisualizeShadingModels(RHICmdList));
Node->SetInput(ePId_Input0, FRenderingCompositeOutputRef(Context.FinalOutput));
Context.FinalOutput = FRenderingCompositeOutputRef(Node);
}
if (View.Family->EngineShowFlags.GBufferHints && FeatureLevel >= ERHIFeatureLevel::SM4)
{
FRenderingCompositePass* Node = Context.Graph.RegisterPass(new(FMemStack::Get()) FRCPassPostProcessGBufferHints(RHICmdList));
Node->SetInput(ePId_Input0, FRenderingCompositeOutputRef(Context.FinalOutput));
// Ideally without lighting as we want the emissive, we should do that later.
Node->SetInput(ePId_Input1, FRenderingCompositeOutputRef(Context.SceneColor));
Context.FinalOutput = FRenderingCompositeOutputRef(Node);
}
AddPostProcessMaterial(Context, BL_AfterTonemapping, SeparateTranslucency, HDRColor);
if(bVisualizeBloom)
{
AddVisualizeBloomOverlay(Context, HDRColor, BloomOutputCombined);
}
if (View.Family->EngineShowFlags.VisualizeSSS)
{
// the setup pass also does visualization, based on EngineShowFlags.VisualizeSSS
FRenderingCompositePass* PassVisualize = Context.Graph.RegisterPass(new(FMemStack::Get()) FRCPassPostProcessSubsurfaceVisualize(RHICmdList));
PassVisualize->SetInput(ePId_Input0, Context.FinalOutput);
Context.FinalOutput = FRenderingCompositeOutputRef(PassVisualize);
}
AddGBufferVisualizationOverview(Context, SeparateTranslucency, HDRColor);
if (bStereoRenderingAndHMD)
{
FRenderingCompositePass* Node = NULL;
const EHMDDeviceType::Type DeviceType = GEngine->HMDDevice->GetHMDDeviceType();
if(DeviceType == EHMDDeviceType::DT_OculusRift)
{
Node = Context.Graph.RegisterPass(new FRCPassPostProcessHMD());
}
else if(DeviceType == EHMDDeviceType::DT_Morpheus)
{
#if MORPHEUS_ENGINE_DISTORTION
FRCPassPostProcessMorpheus* MorpheusPass = new FRCPassPostProcessMorpheus();
MorpheusPass->SetInput(ePId_Input0, FRenderingCompositeOutputRef(Context.FinalOutput));
Node = Context.Graph.RegisterPass(MorpheusPass);
#endif
}
if(Node)
{
Node->SetInput(ePId_Input0, FRenderingCompositeOutputRef(Context.FinalOutput));
Context.FinalOutput = FRenderingCompositeOutputRef(Node);
}
}
if(bVisualizeHDR)
{
FRenderingCompositePass* Node = Context.Graph.RegisterPass(new(FMemStack::Get()) FRCPassPostProcessVisualizeHDR());
Node->SetInput(ePId_Input0, FRenderingCompositeOutputRef(Context.FinalOutput));
Node->SetInput(ePId_Input1, Histogram);
Node->SetInput(ePId_Input2, HDRColor);
Node->SetInput(ePId_Input3, HistogramOverScreen);
Node->AddDependency(AutoExposure.EyeAdaptation);
Context.FinalOutput = FRenderingCompositeOutputRef(Node);
}
if(View.Family->EngineShowFlags.TestImage && FeatureLevel >= ERHIFeatureLevel::SM5)
{
FRenderingCompositePass* Node = Context.Graph.RegisterPass(new(FMemStack::Get()) FRCPassPostProcessTestImage());
Node->SetInput(ePId_Input0, FRenderingCompositeOutputRef(Context.FinalOutput));
Context.FinalOutput = FRenderingCompositeOutputRef(Node);
}
AddHighResScreenshotMask(Context, SeparateTranslucency);
if(bDoScreenPercentage)
{
// Check if we can save the Upscale pass and do it in the Tonemapper to save performance
if(Tonemapper && !PaniniConfig.IsEnabled() && !Tonemapper->bDoGammaOnly)
{
int32 TonemapperScreenPercentage = CVarTonemapperScreenPercentage.GetValueOnRenderThread();
if(TonemapperScreenPercentage != 0)
{
if(Context.FinalOutput.GetPass() == Tonemapper)
{
Tonemapper->bDoScreenPercentageInTonemapper = true;
// the following pass is no longer needed
bDoScreenPercentage = false;
}
}
}
if (PaniniConfig.IsEnabled() || bDoScreenPercentage)
{
int32 UpscaleQuality = CVarUpscaleQuality.GetValueOnRenderThread();
UpscaleQuality = FMath::Clamp(UpscaleQuality, 0, 3);
FRenderingCompositePass* Node = Context.Graph.RegisterPass(new(FMemStack::Get()) FRCPassPostProcessUpscale(UpscaleQuality, PaniniConfig));
Node->SetInput(ePId_Input0, FRenderingCompositeOutputRef(Context.FinalOutput)); // Bilinear sampling.
Node->SetInput(ePId_Input1, FRenderingCompositeOutputRef(Context.FinalOutput)); // Point sampling.
Context.FinalOutput = FRenderingCompositeOutputRef(Node);
}
}
// After the graph is built but before the graph is processed.
// If a postprocess material is using a GBuffer it adds the refcount int FRCPassPostProcessMaterial::Process()
// and when it gets processed it removes the refcount
// We only release the GBuffers after the last view was processed (SplitScreen)
if(View.Family->Views[View.Family->Views.Num() - 1] == &View)
{
// Generally we no longer need the GBuffers, anyone that wants to keep the GBuffers for longer should have called AdjustGBufferRefCount(1) to keep it for longer
// and call AdjustGBufferRefCount(-1) once it's consumed. This needs to happen each frame. PostProcessMaterial do that automatically
FSceneRenderTargets::Get_Todo_PassContext().AdjustGBufferRefCount(RHICmdList, -1);
}
// The graph setup should be finished before this line ----------------------------------------
{
// currently created on the heap each frame but View.Family->RenderTarget could keep this object and all would be cleaner
TRefCountPtr<IPooledRenderTarget> Temp;
FSceneRenderTargetItem Item;
Item.TargetableTexture = (FTextureRHIRef&)View.Family->RenderTarget->GetRenderTargetTexture();
Item.ShaderResourceTexture = (FTextureRHIRef&)View.Family->RenderTarget->GetRenderTargetTexture();
FPooledRenderTargetDesc Desc;
// Texture could be bigger than viewport
if (View.Family->RenderTarget->GetRenderTargetTexture())
{
Desc.Extent.X = View.Family->RenderTarget->GetRenderTargetTexture()->GetSizeX();
Desc.Extent.Y = View.Family->RenderTarget->GetRenderTargetTexture()->GetSizeY();
}
else
{
Desc.Extent = View.Family->RenderTarget->GetSizeXY();
}
// todo: this should come from View.Family->RenderTarget
Desc.Format = PF_B8G8R8A8;
Desc.NumMips = 1;
Desc.DebugName = TEXT("FinalPostProcessColor");
GRenderTargetPool.CreateUntrackedElement(Desc, Temp, Item);
OverrideRenderTarget(Context.FinalOutput, Temp, Desc);
// execute the graph/DAG
CompositeContext.Process(Context.FinalOutput.GetPass(), TEXT("PostProcessing"));
}
}
GRenderTargetPool.AddPhaseEvent(TEXT("AfterPostprocessing"));
}
void FPostProcessing::ProcessES2(FRHICommandListImmediate& RHICmdList, FViewInfo& View, bool bUsedFramebufferFetch)
{
check(IsInRenderingThread());
// This page: https://udn.epicgames.com/Three/RenderingOverview#Rendering%20state%20defaults
// describes what state a pass can expect and to what state it need to be set back.
// All post processing is happening on the render thread side. All passes can access FinalPostProcessSettings and all
// view settings. Those are copies for the RT then never get access by the main thread again.
// Pointers to other structures might be unsafe to touch.
// so that the passes can register themselves to the graph
{
FMemMark Mark(FMemStack::Get());
FRenderingCompositePassContext CompositeContext(RHICmdList, View);
FPostprocessContext Context(RHICmdList, CompositeContext.Graph, View);
FRenderingCompositeOutputRef BloomOutput;
FRenderingCompositeOutputRef DofOutput;
bool bUseAa = View.FinalPostProcessSettings.AntiAliasingMethod == AAM_TemporalAA;
// AA with Mobile32bpp mode requires this outside of bUsePost.
if(bUseAa)
{
// Handle pointer swap for double buffering.
FSceneViewState* ViewState = (FSceneViewState*)View.State;
if(ViewState)
{
// Note that this drops references to the render targets from two frames ago. This
// causes them to be added back to the pool where we can grab them again.
ViewState->MobileAaBloomSunVignette1 = ViewState->MobileAaBloomSunVignette0;
ViewState->MobileAaColor1 = ViewState->MobileAaColor0;
}
}
const FIntPoint FinalTargetSize = View.Family->RenderTarget->GetSizeXY();
FIntRect FinalOutputViewRect = View.ViewRect;
FIntPoint PrePostSourceViewportSize = View.ViewRect.Size();
// ES2 preview uses a subsection of the scene RT, bUsedFramebufferFetch == true deals with this case.
bool bViewRectSource = bUsedFramebufferFetch || FSceneRenderTargets::Get(RHICmdList).GetBufferSizeXY() != PrePostSourceViewportSize;
// add the passes we want to add to the graph (commenting a line means the pass is not inserted into the graph) ---------
if( View.Family->EngineShowFlags.PostProcessing )
{
bool bUseMosaic = IsMobileHDRMosaic();
bool bUseEncodedHDR = IsMobileHDR32bpp() && !bUseMosaic;
bool bUseSun = !bUseEncodedHDR && View.bLightShaftUse;
bool bUseDof = !bUseEncodedHDR && View.FinalPostProcessSettings.DepthOfFieldScale > 0.0f;
bool bUseBloom = View.FinalPostProcessSettings.BloomIntensity > 0.0f;
bool bUseVignette = View.FinalPostProcessSettings.VignetteIntensity > 0.0f;
bool bWorkaround = CVarRenderTargetSwitchWorkaround.GetValueOnRenderThread() != 0;
// This is a workaround to avoid a performance cliff when using many render targets.
bool bUseBloomSmall = bUseBloom && !bUseSun && !bUseDof && bWorkaround;
bool bUsePost = bUseSun | bUseDof | bUseBloom | bUseVignette;
// Post is not supported on ES2 devices using mosaic.
bUsePost &= !bUseMosaic;
bUsePost &= IsMobileHDR();
if(bUsePost)
{
// Skip this pass if the pass was done prior before resolve.
if((!bUsedFramebufferFetch) && (bUseSun || bUseDof))
{
// Convert depth to {circle of confusion, sun shaft intensity} before resolve.
FRenderingCompositePass* PostProcessSunMask = Context.Graph.RegisterPass(new(FMemStack::Get()) FRCPassPostProcessSunMaskES2(PrePostSourceViewportSize, false));
PostProcessSunMask->SetInput(ePId_Input0, Context.FinalOutput);
Context.FinalOutput = FRenderingCompositeOutputRef(PostProcessSunMask);
// Context.FinalOutput now contains entire image.
// (potentially clipped to content of View.ViewRect.)
FinalOutputViewRect = FIntRect(FIntPoint(0, 0), PrePostSourceViewportSize);
}
FRenderingCompositeOutputRef PostProcessBloomSetup;
if(bUseSun || bUseDof || bUseBloom)
{
if(bUseBloomSmall)
{
FRenderingCompositePass* Pass = Context.Graph.RegisterPass(new(FMemStack::Get()) FRCPassPostProcessBloomSetupSmallES2(PrePostSourceViewportSize, bViewRectSource));
Pass->SetInput(ePId_Input0, Context.FinalOutput);
PostProcessBloomSetup = FRenderingCompositeOutputRef(Pass);
}
else
{
FRenderingCompositePass* Pass = Context.Graph.RegisterPass(new(FMemStack::Get()) FRCPassPostProcessBloomSetupES2(FinalOutputViewRect, bViewRectSource));
Pass->SetInput(ePId_Input0, Context.FinalOutput);
PostProcessBloomSetup = FRenderingCompositeOutputRef(Pass);
}
}
if(bUseDof)
{
// Near dilation circle of confusion size.
// Samples at 1/16 area, writes to 1/16 area.
FRenderingCompositeOutputRef PostProcessNear;
{
FRenderingCompositePass* Pass = Context.Graph.RegisterPass(new(FMemStack::Get()) FRCPassPostProcessDofNearES2(FinalOutputViewRect.Size()));
Pass->SetInput(ePId_Input0, PostProcessBloomSetup);
PostProcessNear = FRenderingCompositeOutputRef(Pass);
}
// DOF downsample pass.
// Samples at full resolution, writes to 1/4 area.
FRenderingCompositeOutputRef PostProcessDofDown;
{
FRenderingCompositePass* Pass = Context.Graph.RegisterPass(new(FMemStack::Get()) FRCPassPostProcessDofDownES2(FinalOutputViewRect, bViewRectSource));
Pass->SetInput(ePId_Input0, Context.FinalOutput);
Pass->SetInput(ePId_Input1, PostProcessNear);
PostProcessDofDown = FRenderingCompositeOutputRef(Pass);
}
// DOF blur pass.
// Samples at 1/4 area, writes to 1/4 area.
FRenderingCompositeOutputRef PostProcessDofBlur;
{
FRenderingCompositePass* Pass = Context.Graph.RegisterPass(new(FMemStack::Get()) FRCPassPostProcessDofBlurES2(FinalOutputViewRect.Size()));
Pass->SetInput(ePId_Input0, PostProcessDofDown);
Pass->SetInput(ePId_Input1, PostProcessNear);
PostProcessDofBlur = FRenderingCompositeOutputRef(Pass);
DofOutput = PostProcessDofBlur;
}
}
// Bloom.
FRenderingCompositeOutputRef PostProcessDownsample2;
FRenderingCompositeOutputRef PostProcessDownsample3;
FRenderingCompositeOutputRef PostProcessDownsample4;
FRenderingCompositeOutputRef PostProcessDownsample5;
FRenderingCompositeOutputRef PostProcessUpsample4;
FRenderingCompositeOutputRef PostProcessUpsample3;
FRenderingCompositeOutputRef PostProcessUpsample2;
if(bUseBloomSmall)
{
float DownScale = 0.66f * 4.0f;
// Downsample by 2
{
FRenderingCompositePass* Pass = Context.Graph.RegisterPass(new(FMemStack::Get()) FRCPassPostProcessBloomDownES2(PrePostSourceViewportSize/4, DownScale * 2.0f));
Pass->SetInput(ePId_Input0, PostProcessBloomSetup);
PostProcessDownsample2 = FRenderingCompositeOutputRef(Pass);
}
}
if(bUseBloom && (!bUseBloomSmall))
{
float DownScale = 0.66f * 4.0f;
// Downsample by 2
{
FRenderingCompositePass* Pass = Context.Graph.RegisterPass(new(FMemStack::Get()) FRCPassPostProcessBloomDownES2(PrePostSourceViewportSize/4, DownScale));
Pass->SetInput(ePId_Input0, PostProcessBloomSetup);
PostProcessDownsample2 = FRenderingCompositeOutputRef(Pass);
}
// Downsample by 2
{
FRenderingCompositePass* Pass = Context.Graph.RegisterPass(new(FMemStack::Get()) FRCPassPostProcessBloomDownES2(PrePostSourceViewportSize/8, DownScale));
Pass->SetInput(ePId_Input0, PostProcessDownsample2);
PostProcessDownsample3 = FRenderingCompositeOutputRef(Pass);
}
// Downsample by 2
{
FRenderingCompositePass* Pass = Context.Graph.RegisterPass(new(FMemStack::Get()) FRCPassPostProcessBloomDownES2(PrePostSourceViewportSize/16, DownScale));
Pass->SetInput(ePId_Input0, PostProcessDownsample3);
PostProcessDownsample4 = FRenderingCompositeOutputRef(Pass);
}
// Downsample by 2
{
FRenderingCompositePass* Pass = Context.Graph.RegisterPass(new(FMemStack::Get()) FRCPassPostProcessBloomDownES2(PrePostSourceViewportSize/32, DownScale));
Pass->SetInput(ePId_Input0, PostProcessDownsample4);
PostProcessDownsample5 = FRenderingCompositeOutputRef(Pass);
}
const FFinalPostProcessSettings& Settings = Context.View.FinalPostProcessSettings;
float UpScale = 0.66f * 2.0f;
// Upsample by 2
{
FVector4 TintA = FVector4(Settings.Bloom4Tint.R, Settings.Bloom4Tint.G, Settings.Bloom4Tint.B, 0.0f);
FVector4 TintB = FVector4(Settings.Bloom5Tint.R, Settings.Bloom5Tint.G, Settings.Bloom5Tint.B, 0.0f);
TintA *= View.FinalPostProcessSettings.BloomIntensity;
TintB *= View.FinalPostProcessSettings.BloomIntensity;
FRenderingCompositePass* Pass = Context.Graph.RegisterPass(new(FMemStack::Get()) FRCPassPostProcessBloomUpES2(PrePostSourceViewportSize/32, FVector2D(UpScale, UpScale), TintA, TintB));
Pass->SetInput(ePId_Input0, PostProcessDownsample4);
Pass->SetInput(ePId_Input1, PostProcessDownsample5);
PostProcessUpsample4 = FRenderingCompositeOutputRef(Pass);
}
// Upsample by 2
{
FVector4 TintA = FVector4(Settings.Bloom3Tint.R, Settings.Bloom3Tint.G, Settings.Bloom3Tint.B, 0.0f);
TintA *= View.FinalPostProcessSettings.BloomIntensity;
FVector4 TintB = FVector4(1.0f, 1.0f, 1.0f, 0.0f);
FRenderingCompositePass* Pass = Context.Graph.RegisterPass(new(FMemStack::Get()) FRCPassPostProcessBloomUpES2(PrePostSourceViewportSize/16, FVector2D(UpScale, UpScale), TintA, TintB));
Pass->SetInput(ePId_Input0, PostProcessDownsample3);
Pass->SetInput(ePId_Input1, PostProcessUpsample4);
PostProcessUpsample3 = FRenderingCompositeOutputRef(Pass);
}
// Upsample by 2
{
FVector4 TintA = FVector4(Settings.Bloom2Tint.R, Settings.Bloom2Tint.G, Settings.Bloom2Tint.B, 0.0f);
TintA *= View.FinalPostProcessSettings.BloomIntensity;
// Scaling Bloom2 by extra factor to match filter area difference between PC default and mobile.
TintA *= 0.5;
FVector4 TintB = FVector4(1.0f, 1.0f, 1.0f, 0.0f);
FRenderingCompositePass* Pass = Context.Graph.RegisterPass(new(FMemStack::Get()) FRCPassPostProcessBloomUpES2(PrePostSourceViewportSize/8, FVector2D(UpScale, UpScale), TintA, TintB));
Pass->SetInput(ePId_Input0, PostProcessDownsample2);
Pass->SetInput(ePId_Input1, PostProcessUpsample3);
PostProcessUpsample2 = FRenderingCompositeOutputRef(Pass);
}
}
FRenderingCompositeOutputRef PostProcessSunBlur;
if(bUseSun)
{
// Sunshaft depth blur using downsampled alpha.
FRenderingCompositeOutputRef PostProcessSunAlpha;
{
FRenderingCompositePass* Pass = Context.Graph.RegisterPass(new(FMemStack::Get()) FRCPassPostProcessSunAlphaES2(PrePostSourceViewportSize));
Pass->SetInput(ePId_Input0, PostProcessBloomSetup);
PostProcessSunAlpha = FRenderingCompositeOutputRef(Pass);
}
// Sunshaft blur number two.
{
FRenderingCompositePass* Pass = Context.Graph.RegisterPass(new(FMemStack::Get()) FRCPassPostProcessSunBlurES2(PrePostSourceViewportSize));
Pass->SetInput(ePId_Input0, PostProcessSunAlpha);
PostProcessSunBlur = FRenderingCompositeOutputRef(Pass);
}
}
if(bUseSun | bUseVignette | bUseBloom)
{
FRenderingCompositeOutputRef PostProcessSunMerge;
if(bUseBloomSmall)
{
FRenderingCompositePass* Pass = Context.Graph.RegisterPass(new(FMemStack::Get()) FRCPassPostProcessSunMergeSmallES2(PrePostSourceViewportSize));
Pass->SetInput(ePId_Input0, PostProcessBloomSetup);
Pass->SetInput(ePId_Input1, PostProcessDownsample2);
PostProcessSunMerge = FRenderingCompositeOutputRef(Pass);
BloomOutput = PostProcessSunMerge;
}
else
{
FRenderingCompositePass* Pass = Context.Graph.RegisterPass(new(FMemStack::Get()) FRCPassPostProcessSunMergeES2(PrePostSourceViewportSize));
if(bUseSun)
{
Pass->SetInput(ePId_Input0, PostProcessSunBlur);
}
if(bUseBloom)
{
Pass->SetInput(ePId_Input1, PostProcessBloomSetup);
Pass->SetInput(ePId_Input2, PostProcessUpsample2);
}
PostProcessSunMerge = FRenderingCompositeOutputRef(Pass);
BloomOutput = PostProcessSunMerge;
}
// Mobile temporal AA requires a composite of two of these frames.
if(bUseAa && (bUseBloom || bUseSun))
{
FSceneViewState* ViewState = (FSceneViewState*)View.State;
FRenderingCompositeOutputRef PostProcessSunMerge2;
if(ViewState && ViewState->MobileAaBloomSunVignette1)
{
FRenderingCompositePass* History;
History = Context.Graph.RegisterPass(new(FMemStack::Get()) FRCPassPostProcessInput(ViewState->MobileAaBloomSunVignette1));
PostProcessSunMerge2 = FRenderingCompositeOutputRef(History);
}
else
{
PostProcessSunMerge2 = PostProcessSunMerge;
}
FRenderingCompositeOutputRef PostProcessSunAvg;
{
FRenderingCompositePass* Pass = Context.Graph.RegisterPass(new(FMemStack::Get()) FRCPassPostProcessSunAvgES2(PrePostSourceViewportSize));
Pass->SetInput(ePId_Input0, PostProcessSunMerge);
Pass->SetInput(ePId_Input1, PostProcessSunMerge2);
PostProcessSunAvg = FRenderingCompositeOutputRef(Pass);
}
BloomOutput = PostProcessSunAvg;
}
}
}
}
// Must run to blit to back buffer even if post processing is off.
FRenderingCompositePass* PostProcessTonemap = Context.Graph.RegisterPass(new(FMemStack::Get()) FRCPassPostProcessTonemapES2(Context.View, FinalOutputViewRect, FinalTargetSize, bViewRectSource));
PostProcessTonemap->SetInput(ePId_Input0, Context.FinalOutput);
PostProcessTonemap->SetInput(ePId_Input1, BloomOutput);
PostProcessTonemap->SetInput(ePId_Input2, DofOutput);
Context.FinalOutput = FRenderingCompositeOutputRef(PostProcessTonemap);
// if Context.FinalOutput was the clipped result of sunmask stage then this stage also restores Context.FinalOutput back original target size.
FinalOutputViewRect = View.UnscaledViewRect;
if(bUseAa && View.Family->EngineShowFlags.PostProcessing)
{
// Double buffer post output.
FSceneViewState* ViewState = (FSceneViewState*)View.State;
FRenderingCompositeOutputRef PostProcessPrior = Context.FinalOutput;
if(ViewState && ViewState->MobileAaColor1)
{
FRenderingCompositePass* History;
History = Context.Graph.RegisterPass(new(FMemStack::Get()) FRCPassPostProcessInput(ViewState->MobileAaColor1));
PostProcessPrior = FRenderingCompositeOutputRef(History);
}
// Mobile temporal AA is done after tonemapping.
FRenderingCompositePass* PostProcessAa = Context.Graph.RegisterPass(new(FMemStack::Get()) FRCPassPostProcessAaES2());
PostProcessAa->SetInput(ePId_Input0, Context.FinalOutput);
PostProcessAa->SetInput(ePId_Input1, PostProcessPrior);
Context.FinalOutput = FRenderingCompositeOutputRef(PostProcessAa);
}
#if WITH_EDITOR
if (FSceneRenderer::ShouldCompositeEditorPrimitives(View) )
{
FRenderingCompositePass* EditorCompNode = Context.Graph.RegisterPass(new(FMemStack::Get()) FRCPassPostProcessCompositeEditorPrimitives(false));
EditorCompNode->SetInput(ePId_Input0, FRenderingCompositeOutputRef(Context.FinalOutput));
Context.FinalOutput = FRenderingCompositeOutputRef(EditorCompNode);
}
#endif
const EDebugViewShaderMode DebugViewShaderMode = View.Family->GetDebugViewShaderMode();
if(DebugViewShaderMode == DVSM_QuadComplexity)
{
// Legend is costly so we don't do it for ES2, ideally we make a shader permutation
FRenderingCompositePass* Node = Context.Graph.RegisterPass(new(FMemStack::Get()) FRCPassPostProcessVisualizeComplexity(GEngine->QuadComplexityColors, FVisualizeComplexityApplyPS::CS_STAIR, 1.f, false));
Node->SetInput(ePId_Input0, FRenderingCompositeOutputRef(Context.FinalOutput));
Context.FinalOutput = FRenderingCompositeOutputRef(Node);
}
if(DebugViewShaderMode == DVSM_ShaderComplexity || DebugViewShaderMode == DVSM_ShaderComplexityContainedQuadOverhead || DebugViewShaderMode == DVSM_ShaderComplexityBleedingQuadOverhead)
{
// Legend is costly so we don't do it for ES2, ideally we make a shader permutation
FRenderingCompositePass* Node = Context.Graph.RegisterPass(new(FMemStack::Get()) FRCPassPostProcessVisualizeComplexity(GEngine->ShaderComplexityColors, FVisualizeComplexityApplyPS::CS_RAMP, 1.f, false));
Node->SetInput(ePId_Input0, FRenderingCompositeOutputRef(Context.FinalOutput));
Context.FinalOutput = FRenderingCompositeOutputRef(Node);
}
bool bStereoRenderingAndHMD = View.Family->EngineShowFlags.StereoRendering && View.Family->EngineShowFlags.HMDDistortion;
if (bStereoRenderingAndHMD)
{
FRenderingCompositePass* Node = NULL;
const EHMDDeviceType::Type DeviceType = GEngine->HMDDevice->GetHMDDeviceType();
if (DeviceType == EHMDDeviceType::DT_ES2GenericStereoMesh)
{
Node = Context.Graph.RegisterPass(new FRCPassPostProcessHMD());
}
if (Node)
{
Node->SetInput(ePId_Input0, FRenderingCompositeOutputRef(Context.FinalOutput));
Context.FinalOutput = FRenderingCompositeOutputRef(Node);
}
}
// The graph setup should be finished before this line ----------------------------------------
{
// currently created on the heap each frame but View.Family->RenderTarget could keep this object and all would be cleaner
TRefCountPtr<IPooledRenderTarget> Temp;
FSceneRenderTargetItem Item;
Item.TargetableTexture = (FTextureRHIRef&)View.Family->RenderTarget->GetRenderTargetTexture();
Item.ShaderResourceTexture = (FTextureRHIRef&)View.Family->RenderTarget->GetRenderTargetTexture();
FPooledRenderTargetDesc Desc;
if (View.Family->RenderTarget->GetRenderTargetTexture())
{
Desc.Extent.X = View.Family->RenderTarget->GetRenderTargetTexture()->GetSizeX();
Desc.Extent.Y = View.Family->RenderTarget->GetRenderTargetTexture()->GetSizeY();
}
else
{
Desc.Extent = View.Family->RenderTarget->GetSizeXY();
}
// todo: this should come from View.Family->RenderTarget
Desc.Format = PF_B8G8R8A8;
Desc.NumMips = 1;
GRenderTargetPool.CreateUntrackedElement(Desc, Temp, Item);
OverrideRenderTarget(Context.FinalOutput, Temp, Desc);
CompositeContext.Process(Context.FinalOutput.GetPass(), TEXT("PostProcessingES2"));
}
}
}
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