internal void OnEnable()
{
RuntimeUtilities.CreateIfNull(ref lightMeter);
RuntimeUtilities.CreateIfNull(ref histogram);
RuntimeUtilities.CreateIfNull(ref waveform);
RuntimeUtilities.CreateIfNull(ref vectorscope);
RuntimeUtilities.CreateIfNull(ref overlaySettings);
m_Monitors = new Dictionary <MonitorType, Monitor>
{
{ MonitorType.LightMeter, lightMeter },
{ MonitorType.Histogram, histogram },
{ MonitorType.Waveform, waveform },
{ MonitorType.Vectorscope, vectorscope }
};
foreach (var kvp in m_Monitors)
{
kvp.Value.OnEnable();
}
}
public Matrix4x4 GetJitteredProjectionMatrix(Camera camera)
{
Matrix4x4 cameraProj;
jitter = GenerateRandomOffset();
jitter *= jitterSpread;
if (jitteredMatrixFunc != null)
{
cameraProj = jitteredMatrixFunc(camera, jitter);
}
else
{
cameraProj = camera.orthographic
? RuntimeUtilities.GetJitteredOrthographicProjectionMatrix(camera, jitter)
: RuntimeUtilities.GetJitteredPerspectiveProjectionMatrix(camera, jitter);
}
jitter = new Vector2(jitter.x / camera.pixelWidth, jitter.y / camera.pixelHeight);
return(cameraProj);
}
void CheckInternalStripLut()
{
// Check internal lut state, (re)create it if needed
if (m_InternalLdrLut == null || !m_InternalLdrLut.IsCreated())
{
RuntimeUtilities.Destroy(m_InternalLdrLut);
var format = GetLutFormat();
m_InternalLdrLut = new RenderTexture(k_Lut2DSize * k_Lut2DSize, k_Lut2DSize, 0, format, RenderTextureReadWrite.Linear)
{
name = "Color Grading Strip Lut",
hideFlags = HideFlags.DontSave,
filterMode = FilterMode.Bilinear,
wrapMode = TextureWrapMode.Clamp,
anisoLevel = 0,
autoGenerateMips = false,
useMipMap = false
};
m_InternalLdrLut.Create();
}
}
// This will be called only once at runtime and everytime script reload kicks-in in the
// editor as we need to keep track of any compatible post-processing effects in the project
void ReloadBaseTypes()
{
CleanBaseTypes();
// Rebuild the base type map
var types = RuntimeUtilities.GetAllTypesDerivedFrom <PostProcessEffectSettings>()
.Where(
t => t.IsDefined(typeof(PostProcessAttribute), false) &&
!t.IsAbstract
);
foreach (var type in types)
{
settingsTypes.Add(type, type.GetAttribute <PostProcessAttribute>());
// Create an instance for each effect type, these will be used for the lowest
// priority global volume as we need a default state when exiting volume ranges
var inst = (PostProcessEffectSettings)ScriptableObject.CreateInstance(type);
inst.SetAllOverridesTo(true, false);
m_BaseSettings.Add(inst);
}
}
public void InitBundles()
{
if (haveBundlesBeenInited)
{
return;
}
// Create these lists only once, the serialization system will take over after that
RuntimeUtilities.CreateIfNull(ref m_BeforeTransparentBundles);
RuntimeUtilities.CreateIfNull(ref m_BeforeStackBundles);
RuntimeUtilities.CreateIfNull(ref m_AfterStackBundles);
// Create a bundle for each effect type
m_Bundles = new Dictionary <Type, PostProcessBundle>();
foreach (var type in PostProcessManager.instance.settingsTypes.Keys)
{
var settings = (PostProcessEffectSettings)ScriptableObject.CreateInstance(type);
var bundle = new PostProcessBundle(settings);
m_Bundles.Add(type, bundle);
}
// Update sorted lists with newly added or removed effects in the assemblies
UpdateBundleSortList(m_BeforeTransparentBundles, PostProcessEvent.BeforeTransparent);
UpdateBundleSortList(m_BeforeStackBundles, PostProcessEvent.BeforeStack);
UpdateBundleSortList(m_AfterStackBundles, PostProcessEvent.AfterStack);
// Push all sorted lists in a dictionary for easier access
sortedBundles = new Dictionary <PostProcessEvent, List <SerializedBundleRef> >(new PostProcessEventComparer())
{
{ PostProcessEvent.BeforeTransparent, m_BeforeTransparentBundles },
{ PostProcessEvent.BeforeStack, m_BeforeStackBundles },
{ PostProcessEvent.AfterStack, m_AfterStackBundles }
};
// Done
haveBundlesBeenInited = true;
}
void CheckAOTexture(PostProcessRenderContext context)
{
bool AOUpdateNeeded = m_AmbientOnlyAO == null || !m_AmbientOnlyAO.IsCreated() || m_AmbientOnlyAO.width != context.width || m_AmbientOnlyAO.height != context.height;
#if UNITY_2017_3_OR_NEWER
AOUpdateNeeded = AOUpdateNeeded || m_AmbientOnlyAO.useDynamicScale != context.camera.allowDynamicResolution;
#endif
if (AOUpdateNeeded)
{
RuntimeUtilities.Destroy(m_AmbientOnlyAO);
m_AmbientOnlyAO = new RenderTexture(context.width, context.height, 0, RenderTextureFormat.R8, RenderTextureReadWrite.Linear)
{
hideFlags = HideFlags.DontSave,
filterMode = FilterMode.Point,
enableRandomWrite = true,
#if UNITY_2017_3_OR_NEWER
useDynamicScale = context.camera.allowDynamicResolution
#endif
};
m_AmbientOnlyAO.Create();
}
}
void CheckInternalLogLut()
{
// Check internal lut state, (re)create it if needed
if (m_InternalLogLut == null || !m_InternalLogLut.IsCreated())
{
RuntimeUtilities.Destroy(m_InternalLogLut);
var format = GetLutFormat();
m_InternalLogLut = new RenderTexture(k_Lut3DSize, k_Lut3DSize, 0, format, RenderTextureReadWrite.Linear)
{
name = "Color Grading Log Lut",
hideFlags = HideFlags.DontSave,
filterMode = FilterMode.Bilinear,
wrapMode = TextureWrapMode.Clamp,
anisoLevel = 0,
enableRandomWrite = true,
volumeDepth = k_Lut3DSize,
dimension = TextureDimension.Tex3D,
autoGenerateMips = false,
useMipMap = false
};
m_InternalLogLut.Create();
}
}
internal override void Render(PostProcessRenderContext context)
{
CheckOutput(width, height);
LogHistogram logHistogram = context.logHistogram;
PropertySheet propertySheet = context.propertySheets.Get(context.resources.shaders.lightMeter);
propertySheet.ClearKeywords();
propertySheet.properties.SetBuffer(ShaderIDs.HistogramBuffer, logHistogram.data);
Vector4 histogramScaleOffsetRes = logHistogram.GetHistogramScaleOffsetRes(context);
histogramScaleOffsetRes.z = 1f / (float)width;
histogramScaleOffsetRes.w = 1f / (float)height;
propertySheet.properties.SetVector(ShaderIDs.ScaleOffsetRes, histogramScaleOffsetRes);
if (context.logLut != null && showCurves)
{
propertySheet.EnableKeyword("COLOR_GRADING_HDR");
propertySheet.properties.SetTexture(ShaderIDs.Lut3D, context.logLut);
}
AutoExposure autoExposure = context.autoExposure;
if (autoExposure != null)
{
float x = autoExposure.filtering.value.x;
float y = autoExposure.filtering.value.y;
y = Mathf.Clamp(y, 1.01f, 99f);
x = Mathf.Clamp(x, 1f, y - 0.01f);
Vector4 value = new Vector4(x * 0.01f, y * 0.01f, RuntimeUtilities.Exp2(autoExposure.minLuminance.value), RuntimeUtilities.Exp2(autoExposure.maxLuminance.value));
propertySheet.EnableKeyword("AUTO_EXPOSURE");
propertySheet.properties.SetVector(ShaderIDs.Params, value);
}
CommandBuffer command = context.command;
command.BeginSample("LightMeter");
command.BlitFullscreenTriangle(BuiltinRenderTextureType.None, base.output, propertySheet, 0);
command.EndSample("LightMeter");
}
public override void Render(PostProcessRenderContext context)
{
var cmd = context.command;
cmd.BeginSample("BloomPyramid");
var sheet = context.propertySheets.Get(context.resources.shaders.bloom);
// Apply auto exposure adjustment in the prefiltering pass
sheet.properties.SetTexture(ShaderIDs.AutoExposureTex, context.autoExposureTexture);
// Negative anamorphic ratio values distort vertically - positive is horizontal
float ratio = Mathf.Clamp(settings.anamorphicRatio, -1, 1);
float rw = ratio < 0 ? -ratio : 0f;
float rh = ratio > 0 ? ratio : 0f;
// Do bloom on a half-res buffer, full-res doesn't bring much and kills performances on
// fillrate limited platforms
int tw = Mathf.FloorToInt(context.screenWidth / (3f - rw));
int th = Mathf.FloorToInt(context.screenHeight / (1f - rh));
// Determine the iteration count
int s = Mathf.Max(tw, th);
float logs = Mathf.Log(s, 2f) + Mathf.Min(settings.diffusion.value, 10f) - 10f;
int logs_i = Mathf.FloorToInt(logs);
int iterations = Mathf.Clamp(logs_i, 1, k_MaxPyramidSize);
float sampleScale = 0.5f + logs - logs_i;
sheet.properties.SetFloat(ShaderIDs.SampleScale, sampleScale);
// Prefiltering parameters
float lthresh = Mathf.GammaToLinearSpace(settings.threshold.value);
float knee = lthresh * settings.softKnee.value + 1e-5f;
var threshold = new Vector4(lthresh, lthresh - knee, knee * 2f, 0.25f / knee);
sheet.properties.SetVector(ShaderIDs.Threshold, threshold);
int qualityOffset = settings.fastMode ? 1 : 0;
// Downsample
var lastDown = context.source;
for (int i = 0; i < iterations; i++)
{
int mipDown = m_Pyramid[i].down;
int mipUp = m_Pyramid[i].up;
int pass = i == 0
? (int)Pass.Prefilter13 + qualityOffset
: (int)Pass.Downsample13 + qualityOffset;
context.GetScreenSpaceTemporaryRT(cmd, mipDown, 0, context.sourceFormat, RenderTextureReadWrite.Default, FilterMode.Bilinear, tw, th);
context.GetScreenSpaceTemporaryRT(cmd, mipUp, 0, context.sourceFormat, RenderTextureReadWrite.Default, FilterMode.Bilinear, tw, th);
cmd.BlitFullscreenTriangle(lastDown, mipDown, sheet, pass);
lastDown = mipDown;
tw = Mathf.Max(tw / 2, 1);
th = Mathf.Max(th / 2, 1);
}
// Upsample
int lastUp = m_Pyramid[iterations - 1].down;
for (int i = iterations - 2; i >= 0; i--)
{
int mipDown = m_Pyramid[i].down;
int mipUp = m_Pyramid[i].up;
cmd.SetGlobalTexture(ShaderIDs.BloomTex, mipDown);
cmd.BlitFullscreenTriangle(lastUp, mipUp, sheet, (int)Pass.UpsampleTent + qualityOffset);
lastUp = mipUp;
}
var linearColor = settings.color.value.linear;
float intensity = RuntimeUtilities.Exp2(settings.intensity.value / 10f) - 1f;
var shaderSettings = new Vector4(sampleScale, intensity, settings.dirtIntensity.value, iterations);
// Debug overlays
if (context.IsDebugOverlayEnabled(DebugOverlay.BloomThreshold))
{
context.PushDebugOverlay(cmd, context.source, sheet, (int)Pass.DebugOverlayThreshold);
}
else if (context.IsDebugOverlayEnabled(DebugOverlay.BloomBuffer))
{
sheet.properties.SetVector(ShaderIDs.ColorIntensity, new Vector4(linearColor.r, linearColor.g, linearColor.b, intensity));
context.PushDebugOverlay(cmd, m_Pyramid[0].up, sheet, (int)Pass.DebugOverlayTent + qualityOffset);
}
// Lens dirtiness
// Keep the aspect ratio correct & center the dirt texture, we don't want it to be
// stretched or squashed
var dirtTexture = settings.dirtTexture.value == null
? RuntimeUtilities.blackTexture
: settings.dirtTexture.value;
var dirtRatio = (float)dirtTexture.width / (float)dirtTexture.height;
var screenRatio = (float)context.screenWidth / (float)context.screenHeight;
var dirtTileOffset = new Vector4(1f, 1f, 0f, 0f);
if (dirtRatio > screenRatio)
{
dirtTileOffset.x = screenRatio / dirtRatio;
dirtTileOffset.z = (1f - dirtTileOffset.x) * 0.5f;
}
else if (screenRatio > dirtRatio)
{
dirtTileOffset.y = dirtRatio / screenRatio;
dirtTileOffset.w = (1f - dirtTileOffset.y) * 0.5f;
}
// Shader properties
var uberSheet = context.uberSheet;
uberSheet.EnableKeyword("BLOOM");
uberSheet.properties.SetVector(ShaderIDs.Bloom_DirtTileOffset, dirtTileOffset);
uberSheet.properties.SetVector(ShaderIDs.Bloom_Settings, shaderSettings);
uberSheet.properties.SetColor(ShaderIDs.Bloom_Color, linearColor);
uberSheet.properties.SetTexture(ShaderIDs.Bloom_DirtTex, dirtTexture);
cmd.SetGlobalTexture(ShaderIDs.BloomTex, lastUp);
// Cleanup
for (int i = 0; i < iterations; i++)
{
if (m_Pyramid[i].down != lastUp)
{
cmd.ReleaseTemporaryRT(m_Pyramid[i].down);
}
if (m_Pyramid[i].up != lastUp)
{
cmd.ReleaseTemporaryRT(m_Pyramid[i].up);
}
}
cmd.EndSample("BloomPyramid");
context.bloomBufferNameID = lastUp;
}
public override void Render(PostProcessRenderContext context)
{
var cmd = context.command;
cmd.BeginSample("AutoExposureLookup");
// Prepare autoExpo texture pool
CheckTexture(context.xrActiveEye, 0);
CheckTexture(context.xrActiveEye, 1);
// Make sure filtering values are correct to avoid apocalyptic consequences
float lowPercent = settings.filtering.value.x;
float highPercent = settings.filtering.value.y;
const float kMinDelta = 1e-2f;
highPercent = Mathf.Clamp(highPercent, 1f + kMinDelta, 99f);
lowPercent = Mathf.Clamp(lowPercent, 1f, highPercent - kMinDelta);
// Clamp min/max adaptation values as well
float minLum = settings.minLuminance.value;
float maxLum = settings.maxLuminance.value;
settings.minLuminance.value = Mathf.Min(minLum, maxLum);
settings.maxLuminance.value = Mathf.Max(minLum, maxLum);
// Compute average luminance & auto exposure
bool firstFrame = m_ResetHistory || !Application.isPlaying;
string adaptation = null;
if (firstFrame || settings.eyeAdaptation.value == EyeAdaptation.Fixed)
{
adaptation = "KAutoExposureAvgLuminance_fixed";
}
else
{
adaptation = "KAutoExposureAvgLuminance_progressive";
}
var compute = context.resources.computeShaders.autoExposure;
int kernel = compute.FindKernel(adaptation);
cmd.SetComputeBufferParam(compute, kernel, "_HistogramBuffer", context.logHistogram.data);
cmd.SetComputeVectorParam(compute, "_Params1", new Vector4(lowPercent * 0.01f, highPercent * 0.01f, RuntimeUtilities.Exp2(settings.minLuminance.value), RuntimeUtilities.Exp2(settings.maxLuminance.value)));
cmd.SetComputeVectorParam(compute, "_Params2", new Vector4(settings.speedDown.value, settings.speedUp.value, settings.keyValue.value, Time.deltaTime));
cmd.SetComputeVectorParam(compute, "_ScaleOffsetRes", context.logHistogram.GetHistogramScaleOffsetRes(context));
if (firstFrame)
{
// We don't want eye adaptation when not in play mode because the GameView isn't
// animated, thus making it harder to tweak. Just use the final audo exposure value.
m_CurrentAutoExposure = m_AutoExposurePool[context.xrActiveEye][0];
cmd.SetComputeTextureParam(compute, kernel, "_Destination", m_CurrentAutoExposure);
cmd.DispatchCompute(compute, kernel, 1, 1, 1);
// Copy current exposure to the other pingpong target to avoid adapting from black
RuntimeUtilities.CopyTexture(cmd, m_AutoExposurePool[context.xrActiveEye][0], m_AutoExposurePool[context.xrActiveEye][1]);
m_ResetHistory = false;
}
else
{
int pp = m_AutoExposurePingPong[context.xrActiveEye];
var src = m_AutoExposurePool[context.xrActiveEye][++pp % 2];
var dst = m_AutoExposurePool[context.xrActiveEye][++pp % 2];
cmd.SetComputeTextureParam(compute, kernel, "_Source", src);
cmd.SetComputeTextureParam(compute, kernel, "_Destination", dst);
cmd.DispatchCompute(compute, kernel, 1, 1, 1);
m_AutoExposurePingPong[context.xrActiveEye] = ++pp % 2;
m_CurrentAutoExposure = dst;
}
cmd.EndSample("AutoExposureLookup");
context.autoExposureTexture = m_CurrentAutoExposure;
context.autoExposure = settings;
}
public Matrix4x4 GetJitteredProjectionMatrix(Camera camera)
{
this.jitter = GenerateRandomOffset();
this.jitter *= jitterSpread;
Matrix4x4 result = (jitteredMatrixFunc == null) ? ((!camera.orthographic) ? RuntimeUtilities.GetJitteredPerspectiveProjectionMatrix(camera, this.jitter) : RuntimeUtilities.GetJitteredOrthographicProjectionMatrix(camera, this.jitter)) : jitteredMatrixFunc(camera, this.jitter);
Vector2 jitter = this.jitter;
float x = jitter.x / (float)camera.pixelWidth;
Vector2 jitter2 = this.jitter;
this.jitter = new Vector2(x, jitter2.y / (float)camera.pixelHeight);
return(result);
}
public override void Release()
{
RuntimeUtilities.Destroy(m_GrainLookupRT);
m_GrainLookupRT = null;
m_SampleIndex = 0;
}
public override void Interp(Texture from, Texture to, float t)
{
// Both are null, do nothing
if (from == null && to == null)
{
value = null;
return;
}
// Both aren't null we're ready to blend
if (from != null && to != null)
{
value = TextureLerper.instance.Lerp(from, to, t);
return;
}
// One of them is null, blend to/from a default value is applicable
{
Texture defaultTexture;
switch (defaultState)
{
case TextureParameterDefault.Black:
defaultTexture = RuntimeUtilities.blackTexture;
break;
case TextureParameterDefault.White:
defaultTexture = RuntimeUtilities.whiteTexture;
break;
case TextureParameterDefault.Transparent:
defaultTexture = RuntimeUtilities.transparentTexture;
break;
case TextureParameterDefault.Lut2D:
// Find the current lut size
int size = from != null ? from.height : to.height;
defaultTexture = RuntimeUtilities.GetLutStrip(size);
break;
default:
defaultTexture = null;
break;
}
if (from == null)
{
from = defaultTexture;
}
if (to == null)
{
to = defaultTexture;
}
// defaultState could have been explicitly set to None
if (from == null || to == null)
{
base.Interp(from, to, t);
return;
}
value = TextureLerper.instance.Lerp(from, to, t);
}
}
void BuildCommandBuffers()
{
var context = m_CurrentContext;
var sourceFormat = m_Camera.allowHDR ? RuntimeUtilities.defaultHDRRenderTextureFormat : RenderTextureFormat.Default;
if (!RuntimeUtilities.isFloatingPointFormat(sourceFormat))
{
m_NaNKilled = true;
}
context.Reset();
context.camera = m_Camera;
context.sourceFormat = sourceFormat;
// TODO: Investigate retaining command buffers on XR multi-pass right eye
m_LegacyCmdBufferBeforeReflections.Clear();
m_LegacyCmdBufferBeforeLighting.Clear();
m_LegacyCmdBufferOpaque.Clear();
m_LegacyCmdBuffer.Clear();
SetupContext(context);
context.command = m_LegacyCmdBufferOpaque;
UpdateSettingsIfNeeded(context);
// Lighting & opaque-only effects
var aoBundle = GetBundle <AmbientOcclusion>();
var aoSettings = aoBundle.CastSettings <AmbientOcclusion>();
var aoRenderer = aoBundle.CastRenderer <AmbientOcclusionRenderer>();
bool aoSupported = aoSettings.IsEnabledAndSupported(context);
bool aoAmbientOnly = aoRenderer.IsAmbientOnly(context);
bool isAmbientOcclusionDeferred = aoSupported && aoAmbientOnly;
bool isAmbientOcclusionOpaque = aoSupported && !aoAmbientOnly;
var ssrBundle = GetBundle <ScreenSpaceReflections>();
var ssrSettings = ssrBundle.settings;
var ssrRenderer = ssrBundle.renderer;
bool isScreenSpaceReflectionsActive = ssrSettings.IsEnabledAndSupported(context);
// Ambient-only AO is a special case and has to be done in separate command buffers
if (isAmbientOcclusionDeferred)
{
var ao = aoRenderer.Get();
// Render as soon as possible - should be done async in SRPs when available
context.command = m_LegacyCmdBufferBeforeReflections;
ao.RenderAmbientOnly(context);
// Composite with GBuffer right before the lighting pass
context.command = m_LegacyCmdBufferBeforeLighting;
ao.CompositeAmbientOnly(context);
}
else if (isAmbientOcclusionOpaque)
{
context.command = m_LegacyCmdBufferOpaque;
aoRenderer.Get().RenderAfterOpaque(context);
}
bool isFogActive = fog.IsEnabledAndSupported(context);
bool hasCustomOpaqueOnlyEffects = HasOpaqueOnlyEffects(context);
int opaqueOnlyEffects = 0;
opaqueOnlyEffects += isScreenSpaceReflectionsActive ? 1 : 0;
opaqueOnlyEffects += isFogActive ? 1 : 0;
opaqueOnlyEffects += hasCustomOpaqueOnlyEffects ? 1 : 0;
// This works on right eye because it is resolved/populated at runtime
var cameraTarget = new RenderTargetIdentifier(BuiltinRenderTextureType.CameraTarget);
if (opaqueOnlyEffects > 0)
{
var cmd = m_LegacyCmdBufferOpaque;
context.command = cmd;
// We need to use the internal Blit method to copy the camera target or it'll fail
// on tiled GPU as it won't be able to resolve
int tempTarget0 = m_TargetPool.Get();
context.GetScreenSpaceTemporaryRT(cmd, tempTarget0, 0, sourceFormat);
cmd.Blit(cameraTarget, tempTarget0);
context.source = tempTarget0;
int tempTarget1 = -1;
if (opaqueOnlyEffects > 1)
{
tempTarget1 = m_TargetPool.Get();
context.GetScreenSpaceTemporaryRT(cmd, tempTarget1, 0, sourceFormat);
context.destination = tempTarget1;
}
else
{
context.destination = cameraTarget;
}
if (isScreenSpaceReflectionsActive)
{
ssrRenderer.Render(context);
opaqueOnlyEffects--;
var prevSource = context.source;
context.source = context.destination;
context.destination = opaqueOnlyEffects == 1 ? cameraTarget : prevSource;
}
if (isFogActive)
{
fog.Render(context);
opaqueOnlyEffects--;
var prevSource = context.source;
context.source = context.destination;
context.destination = opaqueOnlyEffects == 1 ? cameraTarget : prevSource;
}
if (hasCustomOpaqueOnlyEffects)
{
RenderOpaqueOnly(context);
}
if (opaqueOnlyEffects > 1)
{
cmd.ReleaseTemporaryRT(tempTarget1);
}
cmd.ReleaseTemporaryRT(tempTarget0);
}
// Post-transparency stack
// Same as before, first blit needs to use the builtin Blit command to properly handle
// tiled GPUs
int tempRt = m_TargetPool.Get();
context.GetScreenSpaceTemporaryRT(m_LegacyCmdBuffer, tempRt, 0, sourceFormat, RenderTextureReadWrite.sRGB);
m_LegacyCmdBuffer.Blit(cameraTarget, tempRt, RuntimeUtilities.copyStdMaterial, stopNaNPropagation ? 1 : 0);
if (!m_NaNKilled)
{
m_NaNKilled = stopNaNPropagation;
}
context.command = m_LegacyCmdBuffer;
context.source = tempRt;
context.destination = cameraTarget;
Render(context);
m_LegacyCmdBuffer.ReleaseTemporaryRT(tempRt);
}
void DestroyDebugOverlayTarget()
{
RuntimeUtilities.Destroy(debugOverlayTarget);
debugOverlayTarget = null;
}
public void Release()
{
RuntimeUtilities.Destroy(m_AmbientOnlyAO);
m_AmbientOnlyAO = null;
}
// HDR color pipeline is rendered to a 2D strip lut (works on HDR platforms without compute
// and 3D texture support). Precision is sliiiiiiightly lower than when using a 3D texture
// LUT (33^3 -> 32^3) but most of the time it's imperceptible.
void RenderHDRPipeline2D(PostProcessRenderContext context)
{
// For the same reasons as in RenderHDRPipeline3D, regen LUT on evey frame
{
CheckInternalStripLut();
// Lut setup
var lutSheet = context.propertySheets.Get(context.resources.shaders.lut2DBaker);
lutSheet.ClearKeywords();
lutSheet.properties.SetVector(ShaderIDs.Lut2D_Params, new Vector4(k_Lut2DSize, 0.5f / (k_Lut2DSize * k_Lut2DSize), 0.5f / k_Lut2DSize, k_Lut2DSize / (k_Lut2DSize - 1f)));
var colorBalance = ColorUtilities.ComputeColorBalance(settings.temperature.value, settings.tint.value);
lutSheet.properties.SetVector(ShaderIDs.ColorBalance, colorBalance);
lutSheet.properties.SetVector(ShaderIDs.ColorFilter, settings.colorFilter.value);
float hue = settings.hueShift.value / 360f; // Remap to [-0.5;0.5]
float sat = settings.saturation.value / 100f + 1f; // Remap to [0;2]
float con = settings.contrast.value / 100f + 1f; // Remap to [0;2]
lutSheet.properties.SetVector(ShaderIDs.HueSatCon, new Vector3(hue, sat, con));
var channelMixerR = new Vector3(settings.mixerRedOutRedIn, settings.mixerRedOutGreenIn, settings.mixerRedOutBlueIn);
var channelMixerG = new Vector3(settings.mixerGreenOutRedIn, settings.mixerGreenOutGreenIn, settings.mixerGreenOutBlueIn);
var channelMixerB = new Vector3(settings.mixerBlueOutRedIn, settings.mixerBlueOutGreenIn, settings.mixerBlueOutBlueIn);
lutSheet.properties.SetVector(ShaderIDs.ChannelMixerRed, channelMixerR / 100f); // Remap to [-2;2]
lutSheet.properties.SetVector(ShaderIDs.ChannelMixerGreen, channelMixerG / 100f);
lutSheet.properties.SetVector(ShaderIDs.ChannelMixerBlue, channelMixerB / 100f);
var lift = ColorUtilities.ColorToLift(settings.lift.value * 0.2f);
var gain = ColorUtilities.ColorToGain(settings.gain.value * 0.8f);
var invgamma = ColorUtilities.ColorToInverseGamma(settings.gamma.value * 0.8f);
lutSheet.properties.SetVector(ShaderIDs.Lift, lift);
lutSheet.properties.SetVector(ShaderIDs.InvGamma, invgamma);
lutSheet.properties.SetVector(ShaderIDs.Gain, gain);
lutSheet.properties.SetTexture(ShaderIDs.Curves, GetCurveTexture(false));
var tonemapper = settings.tonemapper.value;
if (tonemapper == Tonemapper.Custom)
{
lutSheet.EnableKeyword("TONEMAPPING_CUSTOM");
m_HableCurve.Init(
settings.toneCurveToeStrength.value,
settings.toneCurveToeLength.value,
settings.toneCurveShoulderStrength.value,
settings.toneCurveShoulderLength.value,
settings.toneCurveShoulderAngle.value,
settings.toneCurveGamma.value
);
lutSheet.properties.SetVector(ShaderIDs.CustomToneCurve, m_HableCurve.uniforms.curve);
lutSheet.properties.SetVector(ShaderIDs.ToeSegmentA, m_HableCurve.uniforms.toeSegmentA);
lutSheet.properties.SetVector(ShaderIDs.ToeSegmentB, m_HableCurve.uniforms.toeSegmentB);
lutSheet.properties.SetVector(ShaderIDs.MidSegmentA, m_HableCurve.uniforms.midSegmentA);
lutSheet.properties.SetVector(ShaderIDs.MidSegmentB, m_HableCurve.uniforms.midSegmentB);
lutSheet.properties.SetVector(ShaderIDs.ShoSegmentA, m_HableCurve.uniforms.shoSegmentA);
lutSheet.properties.SetVector(ShaderIDs.ShoSegmentB, m_HableCurve.uniforms.shoSegmentB);
}
else if (tonemapper == Tonemapper.ACES)
{
lutSheet.EnableKeyword("TONEMAPPING_ACES");
}
else if (tonemapper == Tonemapper.Neutral)
{
lutSheet.EnableKeyword("TONEMAPPING_NEUTRAL");
}
// Generate the lut
context.command.BeginSample("HdrColorGradingLut2D");
context.command.BlitFullscreenTriangle(BuiltinRenderTextureType.None, m_InternalLdrLut, lutSheet, (int)Pass.LutGenHDR2D);
context.command.EndSample("HdrColorGradingLut2D");
}
var lut = m_InternalLdrLut;
var uberSheet = context.uberSheet;
uberSheet.EnableKeyword("COLOR_GRADING_HDR_2D");
uberSheet.properties.SetVector(ShaderIDs.Lut2D_Params, new Vector3(1f / lut.width, 1f / lut.height, lut.height - 1f));
uberSheet.properties.SetTexture(ShaderIDs.Lut2D, lut);
uberSheet.properties.SetFloat(ShaderIDs.PostExposure, RuntimeUtilities.Exp2(settings.postExposure.value));
}
public override void Render(PostProcessRenderContext context)
{
var cmd = context.command;
cmd.BeginSample("AutoExposureLookup");
var sheet = context.propertySheets.Get(context.resources.shaders.autoExposure);
sheet.ClearKeywords();
// Prepare autoExpo texture pool
CheckTexture(context.xrActiveEye, 0);
CheckTexture(context.xrActiveEye, 1);
// Make sure filtering values are correct to avoid apocalyptic consequences
float lowPercent = settings.filtering.value.x;
float highPercent = settings.filtering.value.y;
const float kMinDelta = 1e-2f;
highPercent = Mathf.Clamp(highPercent, 1f + kMinDelta, 99f);
lowPercent = Mathf.Clamp(lowPercent, 1f, highPercent - kMinDelta);
// Clamp min/max adaptation values as well
float minLum = settings.minLuminance.value;
float maxLum = settings.maxLuminance.value;
settings.minLuminance.value = Mathf.Min(minLum, maxLum);
settings.maxLuminance.value = Mathf.Max(minLum, maxLum);
// Compute auto exposure
sheet.properties.SetBuffer(ShaderIDs.HistogramBuffer, context.logHistogram.data);
sheet.properties.SetVector(ShaderIDs.Params, new Vector4(lowPercent * 0.01f, highPercent * 0.01f, RuntimeUtilities.Exp2(settings.minLuminance.value), RuntimeUtilities.Exp2(settings.maxLuminance.value)));
sheet.properties.SetVector(ShaderIDs.Speed, new Vector2(settings.speedDown.value, settings.speedUp.value));
sheet.properties.SetVector(ShaderIDs.ScaleOffsetRes, context.logHistogram.GetHistogramScaleOffsetRes(context));
sheet.properties.SetFloat(ShaderIDs.ExposureCompensation, settings.keyValue.value);
if (m_ResetHistory || !Application.isPlaying)
{
// We don't want eye adaptation when not in play mode because the GameView isn't
// animated, thus making it harder to tweak. Just use the final audo exposure value.
m_CurrentAutoExposure = m_AutoExposurePool[context.xrActiveEye][0];
cmd.BlitFullscreenTriangle(BuiltinRenderTextureType.None, m_CurrentAutoExposure, sheet, (int)EyeAdaptation.Fixed);
// Copy current exposure to the other pingpong target to avoid adapting from black
RuntimeUtilities.CopyTexture(cmd, m_AutoExposurePool[context.xrActiveEye][0], m_AutoExposurePool[context.xrActiveEye][1]);
m_ResetHistory = false;
}
else
{
int pp = m_AutoExposurePingPong[context.xrActiveEye];
var src = m_AutoExposurePool[context.xrActiveEye][++pp % 2];
var dst = m_AutoExposurePool[context.xrActiveEye][++pp % 2];
cmd.BlitFullscreenTriangle(src, dst, sheet, (int)settings.eyeAdaptation.value);
m_AutoExposurePingPong[context.xrActiveEye] = ++pp % 2;
m_CurrentAutoExposure = dst;
}
cmd.EndSample("AutoExposureLookup");
context.autoExposureTexture = m_CurrentAutoExposure;
context.autoExposure = settings;
}
public override void Interp(Texture from, Texture to, float t)
{
// Both are null, do nothing
if (from == null && to == null)
{
value = null;
return;
}
// Both aren't null we're ready to blend
if (from != null && to != null)
{
value = TextureLerper.instance.Lerp(from, to, t);
return;
}
// One of them is null, blend to/from a default value is applicable
{
if (defaultState == TextureParameterDefault.Lut2D)
{
int size = from != null ? from.height : to.height;
Texture defaultTexture = RuntimeUtilities.GetLutStrip(size);
if (from == null)
{
from = defaultTexture;
}
if (to == null)
{
to = defaultTexture;
}
}
Color tgtColor;
switch (defaultState)
{
case TextureParameterDefault.Black:
tgtColor = Color.black;
break;
case TextureParameterDefault.White:
tgtColor = Color.white;
break;
case TextureParameterDefault.Transparent:
tgtColor = Color.clear;
break;
case TextureParameterDefault.Lut2D:
{
// Find the current lut size
int size = from != null ? from.height : to.height;
Texture defaultTexture = RuntimeUtilities.GetLutStrip(size);
if (from == null)
{
from = defaultTexture;
}
if (to == null)
{
to = defaultTexture;
}
value = TextureLerper.instance.Lerp(from, to, t);
// All done, return
return;
}
default:
// defaultState is none, so just interpolate the base and return
base.Interp(from, to, t);
return;
}
// If we made it this far, tgtColor contains the color we'll be lerping into (or out of)
if (from == null)
{
// color -> texture lerp, invert ratio
value = TextureLerper.instance.Lerp(to, tgtColor, 1f - t);
}
else
{
value = TextureLerper.instance.Lerp(from, tgtColor, t);
}
}
}
void PushDownsampleCommands(PostProcessRenderContext context, CommandBuffer cmd)
{
// Make a copy of the depth texture, or reuse the resolved depth
// buffer (it's only available in some specific situations).
var useDepthCopy = !RuntimeUtilities.IsResolvedDepthAvailable(context.camera);
if (useDepthCopy)
{
m_DepthCopy.PushAllocationCommand(cmd);
cmd.BlitFullscreenTriangle(BuiltinRenderTextureType.None, m_DepthCopy.id, m_PropertySheet, (int)Pass.DepthCopy);
}
// Temporary buffer allocations.
m_LinearDepth.PushAllocationCommand(cmd);
m_LowDepth1.PushAllocationCommand(cmd);
m_LowDepth2.PushAllocationCommand(cmd);
m_LowDepth3.PushAllocationCommand(cmd);
m_LowDepth4.PushAllocationCommand(cmd);
#if UNITY_2017_1_OR_NEWER
m_TiledDepth1.PushAllocationCommand(cmd);
m_TiledDepth2.PushAllocationCommand(cmd);
m_TiledDepth3.PushAllocationCommand(cmd);
m_TiledDepth4.PushAllocationCommand(cmd);
#endif
// 1st downsampling pass.
var cs = context.resources.computeShaders.multiScaleAODownsample1;
int kernel = cs.FindKernel("main");
cmd.SetComputeTextureParam(cs, kernel, "LinearZ", m_LinearDepth.id);
cmd.SetComputeTextureParam(cs, kernel, "DS2x", m_LowDepth1.id);
cmd.SetComputeTextureParam(cs, kernel, "DS4x", m_LowDepth2.id);
cmd.SetComputeTextureParam(cs, kernel, "DS2xAtlas", m_TiledDepth1.id);
cmd.SetComputeTextureParam(cs, kernel, "DS4xAtlas", m_TiledDepth2.id);
cmd.SetComputeVectorParam(cs, "ZBufferParams", CalculateZBufferParams(context.camera));
cmd.SetComputeTextureParam(cs, kernel, "Depth", useDepthCopy
? m_DepthCopy.id
: BuiltinRenderTextureType.ResolvedDepth
);
cmd.DispatchCompute(cs, kernel, m_TiledDepth2.width, m_TiledDepth2.height, 1);
if (useDepthCopy)
{
cmd.ReleaseTemporaryRT(m_DepthCopy.nameID);
}
// 2nd downsampling pass.
cs = context.resources.computeShaders.multiScaleAODownsample2;
kernel = cs.FindKernel("main");
cmd.SetComputeTextureParam(cs, kernel, "DS4x", m_LowDepth2.id);
cmd.SetComputeTextureParam(cs, kernel, "DS8x", m_LowDepth3.id);
cmd.SetComputeTextureParam(cs, kernel, "DS16x", m_LowDepth4.id);
cmd.SetComputeTextureParam(cs, kernel, "DS8xAtlas", m_TiledDepth3.id);
cmd.SetComputeTextureParam(cs, kernel, "DS16xAtlas", m_TiledDepth4.id);
cmd.DispatchCompute(cs, kernel, m_TiledDepth4.width, m_TiledDepth4.height, 1);
}
public void Destroy()
{
RuntimeUtilities.Destroy(m_RT);
m_RT = null;
}
// HDR color pipeline is rendered to a 3D lut; it requires Texture3D & compute shaders
// support - Desktop / Consoles / Some high-end mobiles
void RenderHDRPipeline3D(PostProcessRenderContext context)
{
// Unfortunately because AnimationCurve doesn't implement GetHashCode and we don't have
// any reliable way to figure out if a curve data is different from another one we can't
// skip regenerating the Lut if nothing has changed. So it has to be done on every
// frame...
// It's not a very expensive operation anyway (we're talking about filling a 33x33x33
// Lut on the GPU) but every little thing helps, especially on mobile.
{
CheckInternalLogLut();
// Lut setup
var compute = context.resources.computeShaders.lut3DBaker;
int kernel = 0;
switch (settings.tonemapper.value)
{
case Tonemapper.None: kernel = compute.FindKernel("KGenLut3D_NoTonemap");
break;
case Tonemapper.Neutral: kernel = compute.FindKernel("KGenLut3D_NeutralTonemap");
break;
case Tonemapper.ACES: kernel = compute.FindKernel("KGenLut3D_AcesTonemap");
break;
case Tonemapper.Custom: kernel = compute.FindKernel("KGenLut3D_CustomTonemap");
break;
}
int groupSizeXY = Mathf.CeilToInt(k_Lut3DSize / 8f);
int groupSizeZ = Mathf.CeilToInt(k_Lut3DSize / (RuntimeUtilities.isAndroidOpenGL ? 2f : 8f));
var cmd = context.command;
cmd.SetComputeTextureParam(compute, kernel, "_Output", m_InternalLogLut);
cmd.SetComputeVectorParam(compute, "_Size", new Vector4(k_Lut3DSize, 1f / (k_Lut3DSize - 1f), 0f, 0f));
var colorBalance = ColorUtilities.ComputeColorBalance(settings.temperature.value, settings.tint.value);
cmd.SetComputeVectorParam(compute, "_ColorBalance", colorBalance);
cmd.SetComputeVectorParam(compute, "_ColorFilter", settings.colorFilter.value);
float hue = settings.hueShift.value / 360f; // Remap to [-0.5;0.5]
float sat = settings.saturation.value / 100f + 1f; // Remap to [0;2]
float con = settings.contrast.value / 100f + 1f; // Remap to [0;2]
cmd.SetComputeVectorParam(compute, "_HueSatCon", new Vector4(hue, sat, con, 0f));
var channelMixerR = new Vector4(settings.mixerRedOutRedIn, settings.mixerRedOutGreenIn, settings.mixerRedOutBlueIn, 0f);
var channelMixerG = new Vector4(settings.mixerGreenOutRedIn, settings.mixerGreenOutGreenIn, settings.mixerGreenOutBlueIn, 0f);
var channelMixerB = new Vector4(settings.mixerBlueOutRedIn, settings.mixerBlueOutGreenIn, settings.mixerBlueOutBlueIn, 0f);
cmd.SetComputeVectorParam(compute, "_ChannelMixerRed", channelMixerR / 100f); // Remap to [-2;2]
cmd.SetComputeVectorParam(compute, "_ChannelMixerGreen", channelMixerG / 100f);
cmd.SetComputeVectorParam(compute, "_ChannelMixerBlue", channelMixerB / 100f);
var lift = ColorUtilities.ColorToLift(settings.lift.value * 0.2f);
var gain = ColorUtilities.ColorToGain(settings.gain.value * 0.8f);
var invgamma = ColorUtilities.ColorToInverseGamma(settings.gamma.value * 0.8f);
cmd.SetComputeVectorParam(compute, "_Lift", new Vector4(lift.x, lift.y, lift.z, 0f));
cmd.SetComputeVectorParam(compute, "_InvGamma", new Vector4(invgamma.x, invgamma.y, invgamma.z, 0f));
cmd.SetComputeVectorParam(compute, "_Gain", new Vector4(gain.x, gain.y, gain.z, 0f));
cmd.SetComputeTextureParam(compute, kernel, "_Curves", GetCurveTexture(true));
if (settings.tonemapper.value == Tonemapper.Custom)
{
m_HableCurve.Init(
settings.toneCurveToeStrength.value,
settings.toneCurveToeLength.value,
settings.toneCurveShoulderStrength.value,
settings.toneCurveShoulderLength.value,
settings.toneCurveShoulderAngle.value,
settings.toneCurveGamma.value
);
cmd.SetComputeVectorParam(compute, "_CustomToneCurve", m_HableCurve.uniforms.curve);
cmd.SetComputeVectorParam(compute, "_ToeSegmentA", m_HableCurve.uniforms.toeSegmentA);
cmd.SetComputeVectorParam(compute, "_ToeSegmentB", m_HableCurve.uniforms.toeSegmentB);
cmd.SetComputeVectorParam(compute, "_MidSegmentA", m_HableCurve.uniforms.midSegmentA);
cmd.SetComputeVectorParam(compute, "_MidSegmentB", m_HableCurve.uniforms.midSegmentB);
cmd.SetComputeVectorParam(compute, "_ShoSegmentA", m_HableCurve.uniforms.shoSegmentA);
cmd.SetComputeVectorParam(compute, "_ShoSegmentB", m_HableCurve.uniforms.shoSegmentB);
}
// Generate the lut
context.command.BeginSample("HdrColorGradingLut3D");
cmd.DispatchCompute(compute, kernel, groupSizeXY, groupSizeXY, groupSizeZ);
context.command.EndSample("HdrColorGradingLut3D");
}
var lut = m_InternalLogLut;
var uberSheet = context.uberSheet;
uberSheet.EnableKeyword("COLOR_GRADING_HDR_3D");
uberSheet.properties.SetTexture(ShaderIDs.Lut3D, lut);
uberSheet.properties.SetVector(ShaderIDs.Lut3D_Params, new Vector2(1f / lut.width, lut.width - 1f));
uberSheet.properties.SetFloat(ShaderIDs.PostExposure, RuntimeUtilities.Exp2(settings.postExposure.value));
context.logLut = lut;
}
public override void Render(PostProcessRenderContext context)
{
var cmd = context.command;
cmd.BeginSample("BloomPyramid");
var sheet = context.propertySheets.Get(context.resources.shaders.bloom);
// Apply auto exposure adjustment in the prefiltering pass
sheet.properties.SetTexture(ShaderIDs.AutoExposureTex, context.autoExposureTexture);
// Do bloom on a half-res buffer, full-res doesn't bring much and kills performances on
// fillrate limited platforms
int tw = context.width / 2;
int th = context.height / 2;
// Determine the iteration count
int s = Mathf.Max(tw, th);
float logs = Mathf.Log(s, 2f) + Mathf.Min(settings.diffusion.value, 10f) - 10f;
int logs_i = Mathf.FloorToInt(logs);
int iterations = Mathf.Clamp(logs_i, 1, k_MaxPyramidSize);
float sampleScale = 0.5f + logs - logs_i;
sheet.properties.SetFloat(ShaderIDs.SampleScale, sampleScale);
// Prefiltering parameters
float lthresh = Mathf.GammaToLinearSpace(settings.threshold.value);
float knee = lthresh * settings.softKnee.value + 1e-5f;
var threshold = new Vector4(lthresh, lthresh - knee, knee * 2f, 0.25f / knee);
sheet.properties.SetVector(ShaderIDs.Threshold, threshold);
int qualityOffset = settings.mobileOptimized ? 1 : 0;
// Downsample
var last = context.source;
for (int i = 0; i < iterations; i++)
{
int mipDown = m_Pyramid[i].down;
int mipUp = m_Pyramid[i].up;
int pass = i == 0
? (int)Pass.Prefilter13 + qualityOffset
: (int)Pass.Downsample13 + qualityOffset;
cmd.GetTemporaryRT(mipDown, tw, th, 0, FilterMode.Bilinear, context.sourceFormat);
cmd.GetTemporaryRT(mipUp, tw, th, 0, FilterMode.Bilinear, context.sourceFormat);
cmd.BlitFullscreenTriangle(last, mipDown, sheet, pass);
last = mipDown;
tw = Mathf.Max(tw / 2, 1);
th = Mathf.Max(th / 2, 1);
}
// Upsample
last = m_Pyramid[iterations - 1].down;
for (int i = iterations - 2; i >= 0; i--)
{
int mipDown = m_Pyramid[i].down;
int mipUp = m_Pyramid[i].up;
cmd.SetGlobalTexture(ShaderIDs.BloomTex, mipDown);
cmd.BlitFullscreenTriangle(last, mipUp, sheet, (int)Pass.UpsampleTent + qualityOffset);
last = mipUp;
}
var shaderSettings = new Vector4(
sampleScale,
RuntimeUtilities.Exp2(settings.intensity.value / 10f) - 1f,
settings.lensIntensity.value,
iterations
);
var dirtTexture = settings.lensTexture.value == null
? RuntimeUtilities.blackTexture
: settings.lensTexture.value;
var uberSheet = context.uberSheet;
uberSheet.EnableKeyword("BLOOM");
uberSheet.properties.SetVector(ShaderIDs.Bloom_Settings, shaderSettings);
uberSheet.properties.SetColor(ShaderIDs.Bloom_Color, settings.color.value.linear);
uberSheet.properties.SetTexture(ShaderIDs.Bloom_DirtTex, dirtTexture);
cmd.SetGlobalTexture(ShaderIDs.BloomTex, m_Pyramid[0].up);
// Cleanup
for (int i = 0; i < iterations; i++)
{
cmd.ReleaseTemporaryRT(m_Pyramid[i].down);
cmd.ReleaseTemporaryRT(m_Pyramid[i].up);
}
cmd.EndSample("BloomPyramid");
}
public override void Release()
{
RuntimeUtilities.Destroy(m_InternalSpectralLut);
m_InternalSpectralLut = null;
}
private void BuildCommandBuffers()
{
PostProcessRenderContext currentContext = m_CurrentContext;
RenderTextureFormat renderTextureFormat = (!m_Camera.allowHDR) ? RenderTextureFormat.Default : RuntimeUtilities.defaultHDRRenderTextureFormat;
if (!RuntimeUtilities.isFloatingPointFormat(renderTextureFormat))
{
m_NaNKilled = true;
}
currentContext.Reset();
currentContext.camera = m_Camera;
currentContext.sourceFormat = renderTextureFormat;
m_LegacyCmdBufferBeforeReflections.Clear();
m_LegacyCmdBufferBeforeLighting.Clear();
m_LegacyCmdBufferOpaque.Clear();
m_LegacyCmdBuffer.Clear();
SetupContext(currentContext);
currentContext.command = m_LegacyCmdBufferOpaque;
TextureLerper.instance.BeginFrame(currentContext);
UpdateSettingsIfNeeded(currentContext);
PostProcessBundle bundle = GetBundle <AmbientOcclusion>();
AmbientOcclusion ambientOcclusion = bundle.CastSettings <AmbientOcclusion>();
AmbientOcclusionRenderer ambientOcclusionRenderer = bundle.CastRenderer <AmbientOcclusionRenderer>();
bool flag = ambientOcclusion.IsEnabledAndSupported(currentContext);
bool flag2 = ambientOcclusionRenderer.IsAmbientOnly(currentContext);
bool flag3 = flag && flag2;
bool flag4 = flag && !flag2;
PostProcessBundle bundle2 = GetBundle <ScreenSpaceReflections>();
PostProcessEffectSettings settings = bundle2.settings;
PostProcessEffectRenderer renderer = bundle2.renderer;
bool flag5 = settings.IsEnabledAndSupported(currentContext);
if (flag3)
{
IAmbientOcclusionMethod ambientOcclusionMethod = ambientOcclusionRenderer.Get();
currentContext.command = m_LegacyCmdBufferBeforeReflections;
ambientOcclusionMethod.RenderAmbientOnly(currentContext);
currentContext.command = m_LegacyCmdBufferBeforeLighting;
ambientOcclusionMethod.CompositeAmbientOnly(currentContext);
}
else if (flag4)
{
currentContext.command = m_LegacyCmdBufferOpaque;
ambientOcclusionRenderer.Get().RenderAfterOpaque(currentContext);
}
bool flag6 = fog.IsEnabledAndSupported(currentContext);
bool flag7 = HasOpaqueOnlyEffects(currentContext);
int num = 0;
num += (flag5 ? 1 : 0);
num += (flag6 ? 1 : 0);
num += (flag7 ? 1 : 0);
RenderTargetIdentifier renderTargetIdentifier = new RenderTargetIdentifier(BuiltinRenderTextureType.CameraTarget);
if (num > 0)
{
CommandBuffer commandBuffer = currentContext.command = m_LegacyCmdBufferOpaque;
int nameID = m_TargetPool.Get();
currentContext.GetScreenSpaceTemporaryRT(commandBuffer, nameID, 0, renderTextureFormat);
commandBuffer.BuiltinBlit(renderTargetIdentifier, nameID, RuntimeUtilities.copyStdMaterial, stopNaNPropagation ? 1 : 0);
currentContext.source = nameID;
int nameID2 = -1;
if (num > 1)
{
nameID2 = m_TargetPool.Get();
currentContext.GetScreenSpaceTemporaryRT(commandBuffer, nameID2, 0, renderTextureFormat);
currentContext.destination = nameID2;
}
else
{
currentContext.destination = renderTargetIdentifier;
}
if (flag5)
{
renderer.Render(currentContext);
num--;
RenderTargetIdentifier source = currentContext.source;
currentContext.source = currentContext.destination;
currentContext.destination = ((num != 1) ? source : renderTargetIdentifier);
}
if (flag6)
{
fog.Render(currentContext);
num--;
RenderTargetIdentifier source2 = currentContext.source;
currentContext.source = currentContext.destination;
currentContext.destination = ((num != 1) ? source2 : renderTargetIdentifier);
}
if (flag7)
{
RenderOpaqueOnly(currentContext);
}
if (num > 1)
{
commandBuffer.ReleaseTemporaryRT(nameID2);
}
commandBuffer.ReleaseTemporaryRT(nameID);
}
int nameID3 = m_TargetPool.Get();
currentContext.GetScreenSpaceTemporaryRT(m_LegacyCmdBuffer, nameID3, 0, renderTextureFormat, RenderTextureReadWrite.sRGB);
m_LegacyCmdBuffer.BuiltinBlit(renderTargetIdentifier, nameID3, RuntimeUtilities.copyStdMaterial, stopNaNPropagation ? 1 : 0);
if (!m_NaNKilled)
{
m_NaNKilled = stopNaNPropagation;
}
currentContext.command = m_LegacyCmdBuffer;
currentContext.source = nameID3;
currentContext.destination = renderTargetIdentifier;
Render(currentContext);
m_LegacyCmdBuffer.ReleaseTemporaryRT(nameID3);
}
public void Release()
{
RuntimeUtilities.Destroy(m_Result);
m_Result = null;
}
public override void Interp(Texture from, Texture to, float t)
{
if (from == null && to == null)
{
value = null;
return;
}
if (from != null && to != null)
{
value = TextureLerper.instance.Lerp(from, to, t);
return;
}
if (defaultState == TextureParameterDefault.Lut2D)
{
int size = (!(from != null)) ? to.height : from.height;
Texture lutStrip = RuntimeUtilities.GetLutStrip(size);
if (from == null)
{
from = lutStrip;
}
if (to == null)
{
to = lutStrip;
}
}
Color to2;
switch (defaultState)
{
case TextureParameterDefault.Black:
to2 = Color.black;
break;
case TextureParameterDefault.White:
to2 = Color.white;
break;
case TextureParameterDefault.Transparent:
to2 = Color.clear;
break;
case TextureParameterDefault.Lut2D:
{
int size2 = (!(from != null)) ? to.height : from.height;
Texture lutStrip2 = RuntimeUtilities.GetLutStrip(size2);
if (from == null)
{
from = lutStrip2;
}
if (to == null)
{
to = lutStrip2;
}
value = TextureLerper.instance.Lerp(from, to, t);
return;
}
default:
base.Interp(from, to, t);
return;
}
if (from == null)
{
value = TextureLerper.instance.Lerp(to, to2, 1f - t);
}
else
{
value = TextureLerper.instance.Lerp(from, to2, t);
}
}
