251 lines
10 KiB
C++
251 lines
10 KiB
C++
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// This file is part of the FidelityFX SDK.
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//
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// Copyright (c) 2022-2023 Advanced Micro Devices, Inc. All rights reserved.
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//
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// Permission is hereby granted, free of charge, to any person obtaining a copy
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// of this software and associated documentation files (the "Software"), to deal
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// in the Software without restriction, including without limitation the rights
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// to use, copy, modify, merge, publish, distribute, sublicense, and/or sell
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// copies of the Software, and to permit persons to whom the Software is
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// furnished to do so, subject to the following conditions:
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// The above copyright notice and this permission notice shall be included in
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// all copies or substantial portions of the Software.
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//
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// THE SOFTWARE IS PROVIDED "AS IS", WITHOUT WARRANTY OF ANY KIND, EXPRESS OR
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// IMPLIED, INCLUDING BUT NOT LIMITED TO THE WARRANTIES OF MERCHANTABILITY,
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// FITNESS FOR A PARTICULAR PURPOSE AND NONINFRINGEMENT. IN NO EVENT SHALL THE
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// AUTHORS OR COPYRIGHT HOLDERS BE LIABLE FOR ANY CLAIM, DAMAGES OR OTHER
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// LIABILITY, WHETHER IN AN ACTION OF CONTRACT, TORT OR OTHERWISE, ARISING FROM,
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// OUT OF OR IN CONNECTION WITH THE SOFTWARE OR THE USE OR OTHER DEALINGS IN
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// THE SOFTWARE.
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#define USE_YCOCG 1
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#define fAutogenEpsilon 0.01f
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// EXPERIMENTAL
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FFX_MIN16_F ComputeAutoTC_01(FFX_MIN16_I2 uDispatchThreadId, FFX_MIN16_I2 iPrevIdx)
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{
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FfxFloat32x3 colorPreAlpha = LoadOpaqueOnly(uDispatchThreadId);
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FfxFloat32x3 colorPostAlpha = LoadInputColor(uDispatchThreadId);
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FfxFloat32x3 colorPrevPreAlpha = LoadPrevPreAlpha(iPrevIdx);
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FfxFloat32x3 colorPrevPostAlpha = LoadPrevPostAlpha(iPrevIdx);
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#if USE_YCOCG
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colorPreAlpha = RGBToYCoCg(colorPreAlpha);
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colorPostAlpha = RGBToYCoCg(colorPostAlpha);
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colorPrevPreAlpha = RGBToYCoCg(colorPrevPreAlpha);
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colorPrevPostAlpha = RGBToYCoCg(colorPrevPostAlpha);
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#endif
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FfxFloat32x3 colorDeltaCurr = colorPostAlpha - colorPreAlpha;
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FfxFloat32x3 colorDeltaPrev = colorPrevPostAlpha - colorPrevPreAlpha;
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bool hasAlpha = any(FFX_GREATER_THAN(abs(colorDeltaCurr), FfxFloat32x3(fAutogenEpsilon, fAutogenEpsilon, fAutogenEpsilon)));
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bool hadAlpha = any(FFX_GREATER_THAN(abs(colorDeltaPrev), FfxFloat32x3(fAutogenEpsilon, fAutogenEpsilon, fAutogenEpsilon)));
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FfxFloat32x3 X = colorPreAlpha;
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FfxFloat32x3 Y = colorPostAlpha;
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FfxFloat32x3 Z = colorPrevPreAlpha;
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FfxFloat32x3 W = colorPrevPostAlpha;
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FFX_MIN16_F retVal = FFX_MIN16_F(ffxSaturate(dot(abs(abs(Y - X) - abs(W - Z)), FfxFloat32x3(1, 1, 1))));
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// cleanup very small values
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retVal = (retVal < getTcThreshold()) ? FFX_MIN16_F(0.0f) : FFX_MIN16_F(1.f);
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return retVal;
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}
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// works ok: thin edges
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FFX_MIN16_F ComputeAutoTC_02(FFX_MIN16_I2 uDispatchThreadId, FFX_MIN16_I2 iPrevIdx)
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{
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FfxFloat32x3 colorPreAlpha = LoadOpaqueOnly(uDispatchThreadId);
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FfxFloat32x3 colorPostAlpha = LoadInputColor(uDispatchThreadId);
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FfxFloat32x3 colorPrevPreAlpha = LoadPrevPreAlpha(iPrevIdx);
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FfxFloat32x3 colorPrevPostAlpha = LoadPrevPostAlpha(iPrevIdx);
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#if USE_YCOCG
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colorPreAlpha = RGBToYCoCg(colorPreAlpha);
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colorPostAlpha = RGBToYCoCg(colorPostAlpha);
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colorPrevPreAlpha = RGBToYCoCg(colorPrevPreAlpha);
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colorPrevPostAlpha = RGBToYCoCg(colorPrevPostAlpha);
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#endif
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FfxFloat32x3 colorDelta = colorPostAlpha - colorPreAlpha;
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FfxFloat32x3 colorPrevDelta = colorPrevPostAlpha - colorPrevPreAlpha;
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bool hasAlpha = any(FFX_GREATER_THAN(abs(colorDelta), FfxFloat32x3(fAutogenEpsilon, fAutogenEpsilon, fAutogenEpsilon)));
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bool hadAlpha = any(FFX_GREATER_THAN(abs(colorPrevDelta), FfxFloat32x3(fAutogenEpsilon, fAutogenEpsilon, fAutogenEpsilon)));
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FfxFloat32x3 delta = colorPostAlpha - colorPreAlpha; //prev+1*d = post => d = color, alpha =
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FfxFloat32x3 deltaPrev = colorPrevPostAlpha - colorPrevPreAlpha;
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FfxFloat32x3 X = colorPrevPreAlpha;
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FfxFloat32x3 N = colorPreAlpha - colorPrevPreAlpha;
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FfxFloat32x3 YAminusXA = colorPrevPostAlpha - colorPrevPreAlpha;
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FfxFloat32x3 NminusNA = colorPostAlpha - colorPrevPostAlpha;
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FfxFloat32x3 A = (hasAlpha || hadAlpha) ? NminusNA / max(FfxFloat32x3(fAutogenEpsilon, fAutogenEpsilon, fAutogenEpsilon), N) : FfxFloat32x3(0, 0, 0);
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FFX_MIN16_F retVal = FFX_MIN16_F( max(max(A.x, A.y), A.z) );
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// only pixels that have significantly changed in color shuold be considered
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retVal = ffxSaturate(retVal * FFX_MIN16_F(length(colorPostAlpha - colorPrevPostAlpha)) );
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return retVal;
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}
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// This function computes the TransparencyAndComposition mask:
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// This mask indicates pixels that should discard locks and apply color clamping.
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//
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// Typically this is the case for translucent pixels (that don't write depth values) or pixels where the correctness of
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// the MVs can not be guaranteed (e.g. procedutal movement or vegetation that does not have MVs to reduce the cost during rasterization)
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// Also, large changes in color due to changed lighting should be marked to remove locks on pixels with "old" lighting.
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//
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// This function takes a opaque only and a final texture and uses internal copies of those textures from the last frame.
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// The function tries to determine where the color changes between opaque only and final image to determine the pixels that use transparency.
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// Also it uses the previous frames and detects where the use of transparency changed to mark those pixels.
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// Additionally it marks pixels where the color changed significantly in the opaque only image, e.g. due to lighting or texture animation.
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//
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// In the final step it stores the current textures in internal textures for the next frame
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FFX_MIN16_F ComputeTransparencyAndComposition(FFX_MIN16_I2 uDispatchThreadId, FFX_MIN16_I2 iPrevIdx)
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{
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FFX_MIN16_F retVal = ComputeAutoTC_02(uDispatchThreadId, iPrevIdx);
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// [branch]
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if (retVal > FFX_MIN16_F(0.01f))
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{
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retVal = ComputeAutoTC_01(uDispatchThreadId, iPrevIdx);
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}
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return retVal;
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}
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float computeSolidEdge(FFX_MIN16_I2 curPos, FFX_MIN16_I2 prevPos)
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{
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float lum[9];
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int i = 0;
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for (int y = -1; y < 2; ++y)
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{
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for (int x = -1; x < 2; ++x)
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{
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FfxFloat32x3 curCol = LoadOpaqueOnly(curPos + FFX_MIN16_I2(x, y)).rgb;
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FfxFloat32x3 prevCol = LoadPrevPreAlpha(prevPos + FFX_MIN16_I2(x, y)).rgb;
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lum[i++] = length(curCol - prevCol);
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}
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}
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//float gradX = abs(lum[3] - lum[4]) + abs(lum[5] - lum[4]);
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//float gradY = abs(lum[1] - lum[4]) + abs(lum[7] - lum[4]);
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//return sqrt(gradX * gradX + gradY * gradY);
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float gradX = abs(lum[3] - lum[4]) * abs(lum[5] - lum[4]);
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float gradY = abs(lum[1] - lum[4]) * abs(lum[7] - lum[4]);
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return sqrt(sqrt(gradX * gradY));
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}
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float computeAlphaEdge(FFX_MIN16_I2 curPos, FFX_MIN16_I2 prevPos)
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{
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float lum[9];
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int i = 0;
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for (int y = -1; y < 2; ++y)
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{
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for (int x = -1; x < 2; ++x)
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{
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FfxFloat32x3 curCol = abs(LoadInputColor(curPos + FFX_MIN16_I2(x, y)).rgb - LoadOpaqueOnly(curPos + FFX_MIN16_I2(x, y)).rgb);
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FfxFloat32x3 prevCol = abs(LoadPrevPostAlpha(prevPos + FFX_MIN16_I2(x, y)).rgb - LoadPrevPreAlpha(prevPos + FFX_MIN16_I2(x, y)).rgb);
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lum[i++] = length(curCol - prevCol);
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}
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}
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//float gradX = abs(lum[3] - lum[4]) + abs(lum[5] - lum[4]);
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//float gradY = abs(lum[1] - lum[4]) + abs(lum[7] - lum[4]);
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//return sqrt(gradX * gradX + gradY * gradY);
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float gradX = abs(lum[3] - lum[4]) * abs(lum[5] - lum[4]);
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float gradY = abs(lum[1] - lum[4]) * abs(lum[7] - lum[4]);
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return sqrt(sqrt(gradX * gradY));
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}
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FFX_MIN16_F ComputeAabbOverlap(FFX_MIN16_I2 uDispatchThreadId, FFX_MIN16_I2 iPrevIdx)
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{
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FFX_MIN16_F retVal = FFX_MIN16_F(0.f);
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FfxFloat32x2 fMotionVector = LoadInputMotionVector(uDispatchThreadId);
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FfxFloat32x3 colorPreAlpha = LoadOpaqueOnly(uDispatchThreadId);
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FfxFloat32x3 colorPostAlpha = LoadInputColor(uDispatchThreadId);
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FfxFloat32x3 colorPrevPreAlpha = LoadPrevPreAlpha(iPrevIdx);
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FfxFloat32x3 colorPrevPostAlpha = LoadPrevPostAlpha(iPrevIdx);
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#if USE_YCOCG
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colorPreAlpha = RGBToYCoCg(colorPreAlpha);
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colorPostAlpha = RGBToYCoCg(colorPostAlpha);
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colorPrevPreAlpha = RGBToYCoCg(colorPrevPreAlpha);
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colorPrevPostAlpha = RGBToYCoCg(colorPrevPostAlpha);
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#endif
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FfxFloat32x3 minPrev = FFX_MIN16_F3(+1000.f, +1000.f, +1000.f);
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FfxFloat32x3 maxPrev = FFX_MIN16_F3(-1000.f, -1000.f, -1000.f);
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for (int y = -1; y < 2; ++y)
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{
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for (int x = -1; x < 2; ++x)
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{
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FfxFloat32x3 W = LoadPrevPostAlpha(iPrevIdx + FFX_MIN16_I2(x, y));
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#if USE_YCOCG
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W = RGBToYCoCg(W);
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#endif
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minPrev = min(minPrev, W);
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maxPrev = max(maxPrev, W);
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}
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}
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// instead of computing the overlap: simply count how many samples are outside
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// set reactive based on that
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FFX_MIN16_F count = FFX_MIN16_F(0.f);
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for (int y = -1; y < 2; ++y)
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{
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for (int x = -1; x < 2; ++x)
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{
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FfxFloat32x3 Y = LoadInputColor(uDispatchThreadId + FFX_MIN16_I2(x, y));
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#if USE_YCOCG
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Y = RGBToYCoCg(Y);
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#endif
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count += ((Y.x < minPrev.x) || (Y.x > maxPrev.x)) ? FFX_MIN16_F(1.f) : FFX_MIN16_F(0.f);
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count += ((Y.y < minPrev.y) || (Y.y > maxPrev.y)) ? FFX_MIN16_F(1.f) : FFX_MIN16_F(0.f);
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count += ((Y.z < minPrev.z) || (Y.z > maxPrev.z)) ? FFX_MIN16_F(1.f) : FFX_MIN16_F(0.f);
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}
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}
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retVal = count / FFX_MIN16_F(27.f);
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return retVal;
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}
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// This function computes the Reactive mask:
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// We want pixels marked where the alpha portion of the frame changes a lot between neighbours
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// Those pixels are expected to change quickly between frames, too. (e.g. small particles, reflections on curved surfaces...)
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// As a result history would not be trustworthy.
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// On the other hand we don't want pixels marked where pre-alpha has a large differnce, since those would profit from accumulation
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// For mirrors we may assume the pre-alpha is pretty uniform color.
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//
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// This works well generally, but also marks edge pixels
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FFX_MIN16_F ComputeReactive(FFX_MIN16_I2 uDispatchThreadId, FFX_MIN16_I2 iPrevIdx)
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{
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// we only get here if alpha has a significant contribution and has changed since last frame.
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FFX_MIN16_F retVal = FFX_MIN16_F(0.f);
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// mark pixels with huge variance in alpha as reactive
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FFX_MIN16_F alphaEdge = FFX_MIN16_F(computeAlphaEdge(uDispatchThreadId, iPrevIdx));
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FFX_MIN16_F opaqueEdge = FFX_MIN16_F(computeSolidEdge(uDispatchThreadId, iPrevIdx));
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retVal = ffxSaturate(alphaEdge - opaqueEdge);
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// the above also marks edge pixels due to jitter, so we need to cancel those out
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return retVal;
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}
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