godot/thirdparty/amd-fsr2/shaders/ffx_fsr2_accumulate.h

296 lines
13 KiB
C++

// This file is part of the FidelityFX SDK.
//
// Copyright (c) 2022-2023 Advanced Micro Devices, Inc. All rights reserved.
//
// Permission is hereby granted, free of charge, to any person obtaining a copy
// of this software and associated documentation files (the "Software"), to deal
// in the Software without restriction, including without limitation the rights
// to use, copy, modify, merge, publish, distribute, sublicense, and/or sell
// copies of the Software, and to permit persons to whom the Software is
// furnished to do so, subject to the following conditions:
// The above copyright notice and this permission notice shall be included in
// all copies or substantial portions of the Software.
//
// THE SOFTWARE IS PROVIDED "AS IS", WITHOUT WARRANTY OF ANY KIND, EXPRESS OR
// IMPLIED, INCLUDING BUT NOT LIMITED TO THE WARRANTIES OF MERCHANTABILITY,
// FITNESS FOR A PARTICULAR PURPOSE AND NONINFRINGEMENT. IN NO EVENT SHALL THE
// AUTHORS OR COPYRIGHT HOLDERS BE LIABLE FOR ANY CLAIM, DAMAGES OR OTHER
// LIABILITY, WHETHER IN AN ACTION OF CONTRACT, TORT OR OTHERWISE, ARISING FROM,
// OUT OF OR IN CONNECTION WITH THE SOFTWARE OR THE USE OR OTHER DEALINGS IN
// THE SOFTWARE.
#ifndef FFX_FSR2_ACCUMULATE_H
#define FFX_FSR2_ACCUMULATE_H
FfxFloat32 GetPxHrVelocity(FfxFloat32x2 fMotionVector)
{
return length(fMotionVector * DisplaySize());
}
#if FFX_HALF
FFX_MIN16_F GetPxHrVelocity(FFX_MIN16_F2 fMotionVector)
{
return length(fMotionVector * FFX_MIN16_F2(DisplaySize()));
}
#endif
void Accumulate(const AccumulationPassCommonParams params, FFX_PARAMETER_INOUT FfxFloat32x3 fHistoryColor, FfxFloat32x3 fAccumulation, FFX_PARAMETER_IN FfxFloat32x4 fUpsampledColorAndWeight)
{
// Aviod invalid values when accumulation and upsampled weight is 0
fAccumulation = ffxMax(FSR2_EPSILON.xxx, fAccumulation + fUpsampledColorAndWeight.www);
#if FFX_FSR2_OPTION_HDR_COLOR_INPUT
//YCoCg -> RGB -> Tonemap -> YCoCg (Use RGB tonemapper to avoid color desaturation)
fUpsampledColorAndWeight.xyz = RGBToYCoCg(Tonemap(YCoCgToRGB(fUpsampledColorAndWeight.xyz)));
fHistoryColor = RGBToYCoCg(Tonemap(YCoCgToRGB(fHistoryColor)));
#endif
const FfxFloat32x3 fAlpha = fUpsampledColorAndWeight.www / fAccumulation;
fHistoryColor = ffxLerp(fHistoryColor, fUpsampledColorAndWeight.xyz, fAlpha);
fHistoryColor = YCoCgToRGB(fHistoryColor);
#if FFX_FSR2_OPTION_HDR_COLOR_INPUT
fHistoryColor = InverseTonemap(fHistoryColor);
#endif
}
void RectifyHistory(
const AccumulationPassCommonParams params,
RectificationBox clippingBox,
FFX_PARAMETER_INOUT FfxFloat32x3 fHistoryColor,
FFX_PARAMETER_INOUT FfxFloat32x3 fAccumulation,
FfxFloat32 fLockContributionThisFrame,
FfxFloat32 fTemporalReactiveFactor,
FfxFloat32 fLumaInstabilityFactor)
{
FfxFloat32 fScaleFactorInfluence = ffxMin(20.0f, ffxPow(FfxFloat32(1.0f / length(DownscaleFactor().x * DownscaleFactor().y)), 3.0f));
const FfxFloat32 fVecolityFactor = ffxSaturate(params.fHrVelocity / 20.0f);
const FfxFloat32 fBoxScaleT = ffxMax(params.fDepthClipFactor, ffxMax(params.fAccumulationMask, fVecolityFactor));
FfxFloat32 fBoxScale = ffxLerp(fScaleFactorInfluence, 1.0f, fBoxScaleT);
FfxFloat32x3 fScaledBoxVec = clippingBox.boxVec * fBoxScale;
FfxFloat32x3 boxMin = clippingBox.boxCenter - fScaledBoxVec;
FfxFloat32x3 boxMax = clippingBox.boxCenter + fScaledBoxVec;
FfxFloat32x3 boxCenter = clippingBox.boxCenter;
FfxFloat32 boxVecSize = length(clippingBox.boxVec);
boxMin = ffxMax(clippingBox.aabbMin, boxMin);
boxMax = ffxMin(clippingBox.aabbMax, boxMax);
if (any(FFX_GREATER_THAN(boxMin, fHistoryColor)) || any(FFX_GREATER_THAN(fHistoryColor, boxMax))) {
const FfxFloat32x3 fClampedHistoryColor = clamp(fHistoryColor, boxMin, boxMax);
FfxFloat32x3 fHistoryContribution = ffxMax(fLumaInstabilityFactor, fLockContributionThisFrame).xxx;
const FfxFloat32 fReactiveFactor = params.fDilatedReactiveFactor;
const FfxFloat32 fReactiveContribution = 1.0f - ffxPow(fReactiveFactor, 1.0f / 2.0f);
fHistoryContribution *= fReactiveContribution;
// Scale history color using rectification info, also using accumulation mask to avoid potential invalid color protection
fHistoryColor = ffxLerp(fClampedHistoryColor, fHistoryColor, ffxSaturate(fHistoryContribution));
// Scale accumulation using rectification info
const FfxFloat32x3 fAccumulationMin = ffxMin(fAccumulation, FFX_BROADCAST_FLOAT32X3(0.1f));
fAccumulation = ffxLerp(fAccumulationMin, fAccumulation, ffxSaturate(fHistoryContribution));
}
}
void WriteUpscaledOutput(FfxInt32x2 iPxHrPos, FfxFloat32x3 fUpscaledColor)
{
StoreUpscaledOutput(iPxHrPos, fUpscaledColor);
}
void FinalizeLockStatus(const AccumulationPassCommonParams params, FfxFloat32x2 fLockStatus, FfxFloat32 fUpsampledWeight)
{
// we expect similar motion for next frame
// kill lock if that location is outside screen, avoid locks to be clamped to screen borders
FfxFloat32x2 fEstimatedUvNextFrame = params.fHrUv - params.fMotionVector;
if (IsUvInside(fEstimatedUvNextFrame) == false) {
KillLock(fLockStatus);
}
else {
// Decrease lock lifetime
const FfxFloat32 fLifetimeDecreaseLanczosMax = FfxFloat32(JitterSequenceLength()) * FfxFloat32(fAverageLanczosWeightPerFrame);
const FfxFloat32 fLifetimeDecrease = FfxFloat32(fUpsampledWeight / fLifetimeDecreaseLanczosMax);
fLockStatus[LOCK_LIFETIME_REMAINING] = ffxMax(FfxFloat32(0), fLockStatus[LOCK_LIFETIME_REMAINING] - fLifetimeDecrease);
}
StoreLockStatus(params.iPxHrPos, fLockStatus);
}
FfxFloat32x3 ComputeBaseAccumulationWeight(const AccumulationPassCommonParams params, FfxFloat32 fThisFrameReactiveFactor, FfxBoolean bInMotionLastFrame, FfxFloat32 fUpsampledWeight, LockState lockState)
{
// Always assume max accumulation was reached
FfxFloat32 fBaseAccumulation = fMaxAccumulationLanczosWeight * FfxFloat32(params.bIsExistingSample) * (1.0f - fThisFrameReactiveFactor) * (1.0f - params.fDepthClipFactor);
fBaseAccumulation = ffxMin(fBaseAccumulation, ffxLerp(fBaseAccumulation, fUpsampledWeight * 10.0f, ffxMax(FfxFloat32(bInMotionLastFrame), ffxSaturate(params.fHrVelocity * FfxFloat32(10)))));
fBaseAccumulation = ffxMin(fBaseAccumulation, ffxLerp(fBaseAccumulation, fUpsampledWeight, ffxSaturate(params.fHrVelocity / FfxFloat32(20))));
return fBaseAccumulation.xxx;
}
FfxFloat32 ComputeLumaInstabilityFactor(const AccumulationPassCommonParams params, RectificationBox clippingBox, FfxFloat32 fThisFrameReactiveFactor, FfxFloat32 fLuminanceDiff)
{
const FfxFloat32 fUnormThreshold = 1.0f / 255.0f;
const FfxInt32 N_MINUS_1 = 0;
const FfxInt32 N_MINUS_2 = 1;
const FfxInt32 N_MINUS_3 = 2;
const FfxInt32 N_MINUS_4 = 3;
FfxFloat32 fCurrentFrameLuma = clippingBox.boxCenter.x;
#if FFX_FSR2_OPTION_HDR_COLOR_INPUT
fCurrentFrameLuma = fCurrentFrameLuma / (1.0f + ffxMax(0.0f, fCurrentFrameLuma));
#endif
fCurrentFrameLuma = round(fCurrentFrameLuma * 255.0f) / 255.0f;
const FfxBoolean bSampleLumaHistory = (ffxMax(ffxMax(params.fDepthClipFactor, params.fAccumulationMask), fLuminanceDiff) < 0.1f) && (params.bIsNewSample == false);
FfxFloat32x4 fCurrentFrameLumaHistory = bSampleLumaHistory ? SampleLumaHistory(params.fReprojectedHrUv) : FFX_BROADCAST_FLOAT32X4(0.0f);
FfxFloat32 fLumaInstability = 0.0f;
FfxFloat32 fDiffs0 = (fCurrentFrameLuma - fCurrentFrameLumaHistory[N_MINUS_1]);
FfxFloat32 fMin = abs(fDiffs0);
if (fMin >= fUnormThreshold)
{
for (int i = N_MINUS_2; i <= N_MINUS_4; i++) {
FfxFloat32 fDiffs1 = (fCurrentFrameLuma - fCurrentFrameLumaHistory[i]);
if (sign(fDiffs0) == sign(fDiffs1)) {
// Scale difference to protect historically similar values
const FfxFloat32 fMinBias = 1.0f;
fMin = ffxMin(fMin, abs(fDiffs1) * fMinBias);
}
}
const FfxFloat32 fBoxSize = clippingBox.boxVec.x;
const FfxFloat32 fBoxSizeFactor = ffxPow(ffxSaturate(fBoxSize / 0.1f), 6.0f);
fLumaInstability = FfxFloat32(fMin != abs(fDiffs0)) * fBoxSizeFactor;
fLumaInstability = FfxFloat32(fLumaInstability > fUnormThreshold);
fLumaInstability *= 1.0f - ffxMax(params.fAccumulationMask, ffxPow(fThisFrameReactiveFactor, 1.0f / 6.0f));
}
//shift history
fCurrentFrameLumaHistory[N_MINUS_4] = fCurrentFrameLumaHistory[N_MINUS_3];
fCurrentFrameLumaHistory[N_MINUS_3] = fCurrentFrameLumaHistory[N_MINUS_2];
fCurrentFrameLumaHistory[N_MINUS_2] = fCurrentFrameLumaHistory[N_MINUS_1];
fCurrentFrameLumaHistory[N_MINUS_1] = fCurrentFrameLuma;
StoreLumaHistory(params.iPxHrPos, fCurrentFrameLumaHistory);
return fLumaInstability * FfxFloat32(fCurrentFrameLumaHistory[N_MINUS_4] != 0);
}
FfxFloat32 ComputeTemporalReactiveFactor(const AccumulationPassCommonParams params, FfxFloat32 fTemporalReactiveFactor)
{
FfxFloat32 fNewFactor = ffxMin(0.99f, fTemporalReactiveFactor);
fNewFactor = ffxMax(fNewFactor, ffxLerp(fNewFactor, 0.4f, ffxSaturate(params.fHrVelocity)));
fNewFactor = ffxMax(fNewFactor * fNewFactor, ffxMax(params.fDepthClipFactor * 0.1f, params.fDilatedReactiveFactor));
// Force reactive factor for new samples
fNewFactor = params.bIsNewSample ? 1.0f : fNewFactor;
if (ffxSaturate(params.fHrVelocity * 10.0f) >= 1.0f) {
fNewFactor = ffxMax(FSR2_EPSILON, fNewFactor) * -1.0f;
}
return fNewFactor;
}
AccumulationPassCommonParams InitParams(FfxInt32x2 iPxHrPos)
{
AccumulationPassCommonParams params;
params.iPxHrPos = iPxHrPos;
const FfxFloat32x2 fHrUv = (iPxHrPos + 0.5f) / DisplaySize();
params.fHrUv = fHrUv;
const FfxFloat32x2 fLrUvJittered = fHrUv + Jitter() / RenderSize();
params.fLrUv_HwSampler = ClampUv(fLrUvJittered, RenderSize(), MaxRenderSize());
params.fMotionVector = GetMotionVector(iPxHrPos, fHrUv);
params.fHrVelocity = GetPxHrVelocity(params.fMotionVector);
ComputeReprojectedUVs(params, params.fReprojectedHrUv, params.bIsExistingSample);
params.fDepthClipFactor = ffxSaturate(SampleDepthClip(params.fLrUv_HwSampler));
const FfxFloat32x2 fDilatedReactiveMasks = SampleDilatedReactiveMasks(params.fLrUv_HwSampler);
params.fDilatedReactiveFactor = fDilatedReactiveMasks.x;
params.fAccumulationMask = fDilatedReactiveMasks.y;
params.bIsResetFrame = (0 == FrameIndex());
params.bIsNewSample = (params.bIsExistingSample == false || params.bIsResetFrame);
return params;
}
void Accumulate(FfxInt32x2 iPxHrPos)
{
const AccumulationPassCommonParams params = InitParams(iPxHrPos);
FfxFloat32x3 fHistoryColor = FfxFloat32x3(0, 0, 0);
FfxFloat32x2 fLockStatus;
InitializeNewLockSample(fLockStatus);
FfxFloat32 fTemporalReactiveFactor = 0.0f;
FfxBoolean bInMotionLastFrame = FFX_FALSE;
LockState lockState = { FFX_FALSE , FFX_FALSE };
if (params.bIsExistingSample && !params.bIsResetFrame) {
ReprojectHistoryColor(params, fHistoryColor, fTemporalReactiveFactor, bInMotionLastFrame);
lockState = ReprojectHistoryLockStatus(params, fLockStatus);
}
FfxFloat32 fThisFrameReactiveFactor = ffxMax(params.fDilatedReactiveFactor, fTemporalReactiveFactor);
FfxFloat32 fLuminanceDiff = 0.0f;
FfxFloat32 fLockContributionThisFrame = 0.0f;
UpdateLockStatus(params, fThisFrameReactiveFactor, lockState, fLockStatus, fLockContributionThisFrame, fLuminanceDiff);
// Load upsampled input color
RectificationBox clippingBox;
FfxFloat32x4 fUpsampledColorAndWeight = ComputeUpsampledColorAndWeight(params, clippingBox, fThisFrameReactiveFactor);
const FfxFloat32 fLumaInstabilityFactor = ComputeLumaInstabilityFactor(params, clippingBox, fThisFrameReactiveFactor, fLuminanceDiff);
FfxFloat32x3 fAccumulation = ComputeBaseAccumulationWeight(params, fThisFrameReactiveFactor, bInMotionLastFrame, fUpsampledColorAndWeight.w, lockState);
if (params.bIsNewSample) {
fHistoryColor = YCoCgToRGB(fUpsampledColorAndWeight.xyz);
}
else {
RectifyHistory(params, clippingBox, fHistoryColor, fAccumulation, fLockContributionThisFrame, fThisFrameReactiveFactor, fLumaInstabilityFactor);
Accumulate(params, fHistoryColor, fAccumulation, fUpsampledColorAndWeight);
}
fHistoryColor = UnprepareRgb(fHistoryColor, Exposure());
FinalizeLockStatus(params, fLockStatus, fUpsampledColorAndWeight.w);
// Get new temporal reactive factor
fTemporalReactiveFactor = ComputeTemporalReactiveFactor(params, fThisFrameReactiveFactor);
StoreInternalColorAndWeight(iPxHrPos, FfxFloat32x4(fHistoryColor, fTemporalReactiveFactor));
// Output final color when RCAS is disabled
#if FFX_FSR2_OPTION_APPLY_SHARPENING == 0
WriteUpscaledOutput(iPxHrPos, fHistoryColor);
#endif
StoreNewLocks(iPxHrPos, 0);
}
#endif // FFX_FSR2_ACCUMULATE_H