From cbca17825614d18a96994c94ec0c38e9d8e812cf Mon Sep 17 00:00:00 2001
From: Rye Mutt <rye@alchemyviewer.org>
Date: Sat, 24 Aug 2024 00:55:32 -0400
Subject: Add Contrast Adaptive Sharpening post process effect(#2399)

---
 .../app_settings/shaders/class1/deferred/CASF.glsl | 2558 ++++++++++++++++++++
 1 file changed, 2558 insertions(+)
 create mode 100644 indra/newview/app_settings/shaders/class1/deferred/CASF.glsl

(limited to 'indra/newview/app_settings/shaders/class1/deferred/CASF.glsl')

diff --git a/indra/newview/app_settings/shaders/class1/deferred/CASF.glsl b/indra/newview/app_settings/shaders/class1/deferred/CASF.glsl
new file mode 100644
index 0000000000..96d08058cf
--- /dev/null
+++ b/indra/newview/app_settings/shaders/class1/deferred/CASF.glsl
@@ -0,0 +1,2558 @@
+/**
+ * @file CASF.glsl
+ *
+ * $LicenseInfo:firstyear=2024&license=viewerlgpl$
+ * Second Life Viewer Source Code
+ * Copyright (C) 2024, Linden Research, Inc.
+ *
+ * This library is free software; you can redistribute it and/or
+ * modify it under the terms of the GNU Lesser General Public
+ * License as published by the Free Software Foundation;
+ * version 2.1 of the License only.
+ *
+ * This library is distributed in the hope that it will be useful,
+ * but WITHOUT ANY WARRANTY; without even the implied warranty of
+ * MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE.  See the GNU
+ * Lesser General Public License for more details.
+ *
+ * You should have received a copy of the GNU Lesser General Public
+ * License along with this library; if not, write to the Free Software
+ * Foundation, Inc., 51 Franklin Street, Fifth Floor, Boston, MA  02110-1301  USA
+ *
+ * Linden Research, Inc., 945 Battery Street, San Francisco, CA  94111  USA
+ * $/LicenseInfo$
+ */
+
+/*[EXTRA_CODE_HERE]*/
+
+#ifndef A_CPU
+#define A_GPU
+#define A_GLSL
+#define CAS_BETTER_DIAGONALS
+#define CAS_SLOW
+
+out vec4 frag_color;
+in vec2 vary_fragcoord;
+
+uniform sampler2D diffuseRect;
+uniform vec2 out_screen_res;
+uniform uvec4 cas_param_0;
+uniform uvec4 cas_param_1;
+
+vec3 srgb_to_linear(vec3 cs);
+vec3 linear_to_srgb(vec3 cl);
+#endif
+
+#ifndef SHADER_PORTABILITY
+//==============================================================================================================================
+//
+//                                               [A] SHADER PORTABILITY 1.20210629
+//
+//==============================================================================================================================
+// FidelityFX Super Resolution Sample
+//
+// Copyright (c) 2021 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.
+//------------------------------------------------------------------------------------------------------------------------------
+// MIT LICENSE
+// ===========
+// Copyright (c) 2014 Michal Drobot (for concepts used in "FLOAT APPROXIMATIONS").
+// -----------
+// 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.
+//------------------------------------------------------------------------------------------------------------------------------
+#define A_2PI 6.28318530718
+#ifdef A_CPU
+ // Supporting user defined overrides.
+ #ifndef A_RESTRICT
+  #define A_RESTRICT __restrict
+ #endif
+//------------------------------------------------------------------------------------------------------------------------------
+ #ifndef A_STATIC
+  #define A_STATIC static
+ #endif
+//------------------------------------------------------------------------------------------------------------------------------
+ // Same types across CPU and GPU.
+ // Predicate uses 32-bit integer (C friendly bool).
+ typedef uint32_t AP1;
+ typedef float AF1;
+ typedef double AD1;
+ typedef uint8_t AB1;
+ typedef uint16_t AW1;
+ typedef uint32_t AU1;
+ typedef uint64_t AL1;
+ typedef int8_t ASB1;
+ typedef int16_t ASW1;
+ typedef int32_t ASU1;
+ typedef int64_t ASL1;
+//------------------------------------------------------------------------------------------------------------------------------
+ #define AD1_(a) ((AD1)(a))
+ #define AF1_(a) ((AF1)(a))
+ #define AL1_(a) ((AL1)(a))
+ #define AU1_(a) ((AU1)(a))
+//------------------------------------------------------------------------------------------------------------------------------
+ #define ASL1_(a) ((ASL1)(a))
+ #define ASU1_(a) ((ASU1)(a))
+//------------------------------------------------------------------------------------------------------------------------------
+ A_STATIC AU1 AU1_AF1(AF1 a){union{AF1 f;AU1 u;}bits;bits.f=a;return bits.u;}
+//------------------------------------------------------------------------------------------------------------------------------
+ #define A_TRUE 1
+ #define A_FALSE 0
+////////////////////////////////////////////////////////////////////////////////////////////////////////////////////////////////
+////////////////////////////////////////////////////////////////////////////////////////////////////////////////////////////////
+////////////////////////////////////////////////////////////////////////////////////////////////////////////////////////////////
+////////////////////////////////////////////////////////////////////////////////////////////////////////////////////////////////
+//_____________________________________________________________/\_______________________________________________________________
+//==============================================================================================================================
+//
+//                                                       CPU/GPU PORTING
+//
+//------------------------------------------------------------------------------------------------------------------------------
+// Get CPU and GPU to share all setup code, without duplicate code paths.
+// This uses a lower-case prefix for special vector constructs.
+//  - In C restrict pointers are used.
+//  - In the shading language, in/inout/out arguments are used.
+// This depends on the ability to access a vector value in both languages via array syntax (aka color[2]).
+//==============================================================================================================================
+////////////////////////////////////////////////////////////////////////////////////////////////////////////////////////////////
+////////////////////////////////////////////////////////////////////////////////////////////////////////////////////////////////
+//_____________________________________________________________/\_______________________________________________________________
+//==============================================================================================================================
+//                                     VECTOR ARGUMENT/RETURN/INITIALIZATION PORTABILITY
+//==============================================================================================================================
+ #define retAD2 AD1 *A_RESTRICT
+ #define retAD3 AD1 *A_RESTRICT
+ #define retAD4 AD1 *A_RESTRICT
+ #define retAF2 AF1 *A_RESTRICT
+ #define retAF3 AF1 *A_RESTRICT
+ #define retAF4 AF1 *A_RESTRICT
+ #define retAL2 AL1 *A_RESTRICT
+ #define retAL3 AL1 *A_RESTRICT
+ #define retAL4 AL1 *A_RESTRICT
+ #define retAU2 AU1 *A_RESTRICT
+ #define retAU3 AU1 *A_RESTRICT
+ #define retAU4 AU1 *A_RESTRICT
+//------------------------------------------------------------------------------------------------------------------------------
+ #define inAD2 AD1 *A_RESTRICT
+ #define inAD3 AD1 *A_RESTRICT
+ #define inAD4 AD1 *A_RESTRICT
+ #define inAF2 AF1 *A_RESTRICT
+ #define inAF3 AF1 *A_RESTRICT
+ #define inAF4 AF1 *A_RESTRICT
+ #define inAL2 AL1 *A_RESTRICT
+ #define inAL3 AL1 *A_RESTRICT
+ #define inAL4 AL1 *A_RESTRICT
+ #define inAU2 AU1 *A_RESTRICT
+ #define inAU3 AU1 *A_RESTRICT
+ #define inAU4 AU1 *A_RESTRICT
+//------------------------------------------------------------------------------------------------------------------------------
+ #define inoutAD2 AD1 *A_RESTRICT
+ #define inoutAD3 AD1 *A_RESTRICT
+ #define inoutAD4 AD1 *A_RESTRICT
+ #define inoutAF2 AF1 *A_RESTRICT
+ #define inoutAF3 AF1 *A_RESTRICT
+ #define inoutAF4 AF1 *A_RESTRICT
+ #define inoutAL2 AL1 *A_RESTRICT
+ #define inoutAL3 AL1 *A_RESTRICT
+ #define inoutAL4 AL1 *A_RESTRICT
+ #define inoutAU2 AU1 *A_RESTRICT
+ #define inoutAU3 AU1 *A_RESTRICT
+ #define inoutAU4 AU1 *A_RESTRICT
+//------------------------------------------------------------------------------------------------------------------------------
+ #define outAD2 AD1 *A_RESTRICT
+ #define outAD3 AD1 *A_RESTRICT
+ #define outAD4 AD1 *A_RESTRICT
+ #define outAF2 AF1 *A_RESTRICT
+ #define outAF3 AF1 *A_RESTRICT
+ #define outAF4 AF1 *A_RESTRICT
+ #define outAL2 AL1 *A_RESTRICT
+ #define outAL3 AL1 *A_RESTRICT
+ #define outAL4 AL1 *A_RESTRICT
+ #define outAU2 AU1 *A_RESTRICT
+ #define outAU3 AU1 *A_RESTRICT
+ #define outAU4 AU1 *A_RESTRICT
+//------------------------------------------------------------------------------------------------------------------------------
+ #define varAD2(x) AD1 x[2]
+ #define varAD3(x) AD1 x[3]
+ #define varAD4(x) AD1 x[4]
+ #define varAF2(x) AF1 x[2]
+ #define varAF3(x) AF1 x[3]
+ #define varAF4(x) AF1 x[4]
+ #define varAL2(x) AL1 x[2]
+ #define varAL3(x) AL1 x[3]
+ #define varAL4(x) AL1 x[4]
+ #define varAU2(x) AU1 x[2]
+ #define varAU3(x) AU1 x[3]
+ #define varAU4(x) AU1 x[4]
+//------------------------------------------------------------------------------------------------------------------------------
+ #define initAD2(x,y) {x,y}
+ #define initAD3(x,y,z) {x,y,z}
+ #define initAD4(x,y,z,w) {x,y,z,w}
+ #define initAF2(x,y) {x,y}
+ #define initAF3(x,y,z) {x,y,z}
+ #define initAF4(x,y,z,w) {x,y,z,w}
+ #define initAL2(x,y) {x,y}
+ #define initAL3(x,y,z) {x,y,z}
+ #define initAL4(x,y,z,w) {x,y,z,w}
+ #define initAU2(x,y) {x,y}
+ #define initAU3(x,y,z) {x,y,z}
+ #define initAU4(x,y,z,w) {x,y,z,w}
+////////////////////////////////////////////////////////////////////////////////////////////////////////////////////////////////
+////////////////////////////////////////////////////////////////////////////////////////////////////////////////////////////////
+//_____________________________________________________________/\_______________________________________________________________
+//==============================================================================================================================
+//                                                     SCALAR RETURN OPS
+//------------------------------------------------------------------------------------------------------------------------------
+// TODO
+// ====
+//  - Replace transcendentals with manual versions.
+//==============================================================================================================================
+ #ifdef A_GCC
+  A_STATIC AD1 AAbsD1(AD1 a){return __builtin_fabs(a);}
+  A_STATIC AF1 AAbsF1(AF1 a){return __builtin_fabsf(a);}
+  A_STATIC AU1 AAbsSU1(AU1 a){return AU1_(__builtin_abs(ASU1_(a)));}
+  A_STATIC AL1 AAbsSL1(AL1 a){return AL1_(__builtin_llabs(ASL1_(a)));}
+ #else
+  A_STATIC AD1 AAbsD1(AD1 a){return fabs(a);}
+  A_STATIC AF1 AAbsF1(AF1 a){return fabsf(a);}
+  A_STATIC AU1 AAbsSU1(AU1 a){return AU1_(abs(ASU1_(a)));}
+  A_STATIC AL1 AAbsSL1(AL1 a){return AL1_(labs((long)ASL1_(a)));}
+ #endif
+//------------------------------------------------------------------------------------------------------------------------------
+ #ifdef A_GCC
+  A_STATIC AD1 ACosD1(AD1 a){return __builtin_cos(a);}
+  A_STATIC AF1 ACosF1(AF1 a){return __builtin_cosf(a);}
+ #else
+  A_STATIC AD1 ACosD1(AD1 a){return cos(a);}
+  A_STATIC AF1 ACosF1(AF1 a){return cosf(a);}
+ #endif
+//------------------------------------------------------------------------------------------------------------------------------
+ A_STATIC AD1 ADotD2(inAD2 a,inAD2 b){return a[0]*b[0]+a[1]*b[1];}
+ A_STATIC AD1 ADotD3(inAD3 a,inAD3 b){return a[0]*b[0]+a[1]*b[1]+a[2]*b[2];}
+ A_STATIC AD1 ADotD4(inAD4 a,inAD4 b){return a[0]*b[0]+a[1]*b[1]+a[2]*b[2]+a[3]*b[3];}
+ A_STATIC AF1 ADotF2(inAF2 a,inAF2 b){return a[0]*b[0]+a[1]*b[1];}
+ A_STATIC AF1 ADotF3(inAF3 a,inAF3 b){return a[0]*b[0]+a[1]*b[1]+a[2]*b[2];}
+ A_STATIC AF1 ADotF4(inAF4 a,inAF4 b){return a[0]*b[0]+a[1]*b[1]+a[2]*b[2]+a[3]*b[3];}
+//------------------------------------------------------------------------------------------------------------------------------
+ #ifdef A_GCC
+  A_STATIC AD1 AExp2D1(AD1 a){return __builtin_exp2(a);}
+  A_STATIC AF1 AExp2F1(AF1 a){return __builtin_exp2f(a);}
+ #else
+  A_STATIC AD1 AExp2D1(AD1 a){return exp2(a);}
+  A_STATIC AF1 AExp2F1(AF1 a){return exp2f(a);}
+ #endif
+//------------------------------------------------------------------------------------------------------------------------------
+ #ifdef A_GCC
+  A_STATIC AD1 AFloorD1(AD1 a){return __builtin_floor(a);}
+  A_STATIC AF1 AFloorF1(AF1 a){return __builtin_floorf(a);}
+ #else
+  A_STATIC AD1 AFloorD1(AD1 a){return floor(a);}
+  A_STATIC AF1 AFloorF1(AF1 a){return floorf(a);}
+ #endif
+//------------------------------------------------------------------------------------------------------------------------------
+ A_STATIC AD1 ALerpD1(AD1 a,AD1 b,AD1 c){return b*c+(-a*c+a);}
+ A_STATIC AF1 ALerpF1(AF1 a,AF1 b,AF1 c){return b*c+(-a*c+a);}
+//------------------------------------------------------------------------------------------------------------------------------
+ #ifdef A_GCC
+  A_STATIC AD1 ALog2D1(AD1 a){return __builtin_log2(a);}
+  A_STATIC AF1 ALog2F1(AF1 a){return __builtin_log2f(a);}
+ #else
+  A_STATIC AD1 ALog2D1(AD1 a){return log2(a);}
+  A_STATIC AF1 ALog2F1(AF1 a){return log2f(a);}
+ #endif
+//------------------------------------------------------------------------------------------------------------------------------
+ A_STATIC AD1 AMaxD1(AD1 a,AD1 b){return a>b?a:b;}
+ A_STATIC AF1 AMaxF1(AF1 a,AF1 b){return a>b?a:b;}
+ A_STATIC AL1 AMaxL1(AL1 a,AL1 b){return a>b?a:b;}
+ A_STATIC AU1 AMaxU1(AU1 a,AU1 b){return a>b?a:b;}
+//------------------------------------------------------------------------------------------------------------------------------
+ // These follow the convention that A integer types don't have signage, until they are operated on.
+ A_STATIC AL1 AMaxSL1(AL1 a,AL1 b){return (ASL1_(a)>ASL1_(b))?a:b;}
+ A_STATIC AU1 AMaxSU1(AU1 a,AU1 b){return (ASU1_(a)>ASU1_(b))?a:b;}
+//------------------------------------------------------------------------------------------------------------------------------
+ A_STATIC AD1 AMinD1(AD1 a,AD1 b){return a<b?a:b;}
+ A_STATIC AF1 AMinF1(AF1 a,AF1 b){return a<b?a:b;}
+ A_STATIC AL1 AMinL1(AL1 a,AL1 b){return a<b?a:b;}
+ A_STATIC AU1 AMinU1(AU1 a,AU1 b){return a<b?a:b;}
+//------------------------------------------------------------------------------------------------------------------------------
+ A_STATIC AL1 AMinSL1(AL1 a,AL1 b){return (ASL1_(a)<ASL1_(b))?a:b;}
+ A_STATIC AU1 AMinSU1(AU1 a,AU1 b){return (ASU1_(a)<ASU1_(b))?a:b;}
+//------------------------------------------------------------------------------------------------------------------------------
+ A_STATIC AD1 ARcpD1(AD1 a){return 1.0/a;}
+ A_STATIC AF1 ARcpF1(AF1 a){return 1.0f/a;}
+//------------------------------------------------------------------------------------------------------------------------------
+ A_STATIC AL1 AShrSL1(AL1 a,AL1 b){return AL1_(ASL1_(a)>>ASL1_(b));}
+ A_STATIC AU1 AShrSU1(AU1 a,AU1 b){return AU1_(ASU1_(a)>>ASU1_(b));}
+//------------------------------------------------------------------------------------------------------------------------------
+ #ifdef A_GCC
+  A_STATIC AD1 ASinD1(AD1 a){return __builtin_sin(a);}
+  A_STATIC AF1 ASinF1(AF1 a){return __builtin_sinf(a);}
+ #else
+  A_STATIC AD1 ASinD1(AD1 a){return sin(a);}
+  A_STATIC AF1 ASinF1(AF1 a){return sinf(a);}
+ #endif
+//------------------------------------------------------------------------------------------------------------------------------
+ #ifdef A_GCC
+  A_STATIC AD1 ASqrtD1(AD1 a){return __builtin_sqrt(a);}
+  A_STATIC AF1 ASqrtF1(AF1 a){return __builtin_sqrtf(a);}
+ #else
+  A_STATIC AD1 ASqrtD1(AD1 a){return sqrt(a);}
+  A_STATIC AF1 ASqrtF1(AF1 a){return sqrtf(a);}
+ #endif
+////////////////////////////////////////////////////////////////////////////////////////////////////////////////////////////////
+////////////////////////////////////////////////////////////////////////////////////////////////////////////////////////////////
+//_____________________________________________________________/\_______________________________________________________________
+//==============================================================================================================================
+//                                               SCALAR RETURN OPS - DEPENDENT
+//==============================================================================================================================
+ A_STATIC AD1 AClampD1(AD1 x,AD1 n,AD1 m){return AMaxD1(n,AMinD1(x,m));}
+ A_STATIC AF1 AClampF1(AF1 x,AF1 n,AF1 m){return AMaxF1(n,AMinF1(x,m));}
+//------------------------------------------------------------------------------------------------------------------------------
+ A_STATIC AD1 AFractD1(AD1 a){return a-AFloorD1(a);}
+ A_STATIC AF1 AFractF1(AF1 a){return a-AFloorF1(a);}
+//------------------------------------------------------------------------------------------------------------------------------
+ A_STATIC AD1 APowD1(AD1 a,AD1 b){return AExp2D1(b*ALog2D1(a));}
+ A_STATIC AF1 APowF1(AF1 a,AF1 b){return AExp2F1(b*ALog2F1(a));}
+//------------------------------------------------------------------------------------------------------------------------------
+ A_STATIC AD1 ARsqD1(AD1 a){return ARcpD1(ASqrtD1(a));}
+ A_STATIC AF1 ARsqF1(AF1 a){return ARcpF1(ASqrtF1(a));}
+//------------------------------------------------------------------------------------------------------------------------------
+ A_STATIC AD1 ASatD1(AD1 a){return AMinD1(1.0,AMaxD1(0.0,a));}
+ A_STATIC AF1 ASatF1(AF1 a){return AMinF1(1.0f,AMaxF1(0.0f,a));}
+////////////////////////////////////////////////////////////////////////////////////////////////////////////////////////////////
+////////////////////////////////////////////////////////////////////////////////////////////////////////////////////////////////
+//_____________________________________________________________/\_______________________________________________________________
+//==============================================================================================================================
+//                                                         VECTOR OPS
+//------------------------------------------------------------------------------------------------------------------------------
+// These are added as needed for production or prototyping, so not necessarily a complete set.
+// They follow a convention of taking in a destination and also returning the destination value to increase utility.
+//==============================================================================================================================
+ A_STATIC retAD2 opAAbsD2(outAD2 d,inAD2 a){d[0]=AAbsD1(a[0]);d[1]=AAbsD1(a[1]);return d;}
+ A_STATIC retAD3 opAAbsD3(outAD3 d,inAD3 a){d[0]=AAbsD1(a[0]);d[1]=AAbsD1(a[1]);d[2]=AAbsD1(a[2]);return d;}
+ A_STATIC retAD4 opAAbsD4(outAD4 d,inAD4 a){d[0]=AAbsD1(a[0]);d[1]=AAbsD1(a[1]);d[2]=AAbsD1(a[2]);d[3]=AAbsD1(a[3]);return d;}
+//------------------------------------------------------------------------------------------------------------------------------
+ A_STATIC retAF2 opAAbsF2(outAF2 d,inAF2 a){d[0]=AAbsF1(a[0]);d[1]=AAbsF1(a[1]);return d;}
+ A_STATIC retAF3 opAAbsF3(outAF3 d,inAF3 a){d[0]=AAbsF1(a[0]);d[1]=AAbsF1(a[1]);d[2]=AAbsF1(a[2]);return d;}
+ A_STATIC retAF4 opAAbsF4(outAF4 d,inAF4 a){d[0]=AAbsF1(a[0]);d[1]=AAbsF1(a[1]);d[2]=AAbsF1(a[2]);d[3]=AAbsF1(a[3]);return d;}
+//==============================================================================================================================
+ A_STATIC retAD2 opAAddD2(outAD2 d,inAD2 a,inAD2 b){d[0]=a[0]+b[0];d[1]=a[1]+b[1];return d;}
+ A_STATIC retAD3 opAAddD3(outAD3 d,inAD3 a,inAD3 b){d[0]=a[0]+b[0];d[1]=a[1]+b[1];d[2]=a[2]+b[2];return d;}
+ A_STATIC retAD4 opAAddD4(outAD4 d,inAD4 a,inAD4 b){d[0]=a[0]+b[0];d[1]=a[1]+b[1];d[2]=a[2]+b[2];d[3]=a[3]+b[3];return d;}
+//------------------------------------------------------------------------------------------------------------------------------
+ A_STATIC retAF2 opAAddF2(outAF2 d,inAF2 a,inAF2 b){d[0]=a[0]+b[0];d[1]=a[1]+b[1];return d;}
+ A_STATIC retAF3 opAAddF3(outAF3 d,inAF3 a,inAF3 b){d[0]=a[0]+b[0];d[1]=a[1]+b[1];d[2]=a[2]+b[2];return d;}
+ A_STATIC retAF4 opAAddF4(outAF4 d,inAF4 a,inAF4 b){d[0]=a[0]+b[0];d[1]=a[1]+b[1];d[2]=a[2]+b[2];d[3]=a[3]+b[3];return d;}
+//==============================================================================================================================
+ A_STATIC retAD2 opAAddOneD2(outAD2 d,inAD2 a,AD1 b){d[0]=a[0]+b;d[1]=a[1]+b;return d;}
+ A_STATIC retAD3 opAAddOneD3(outAD3 d,inAD3 a,AD1 b){d[0]=a[0]+b;d[1]=a[1]+b;d[2]=a[2]+b;return d;}
+ A_STATIC retAD4 opAAddOneD4(outAD4 d,inAD4 a,AD1 b){d[0]=a[0]+b;d[1]=a[1]+b;d[2]=a[2]+b;d[3]=a[3]+b;return d;}
+//------------------------------------------------------------------------------------------------------------------------------
+ A_STATIC retAF2 opAAddOneF2(outAF2 d,inAF2 a,AF1 b){d[0]=a[0]+b;d[1]=a[1]+b;return d;}
+ A_STATIC retAF3 opAAddOneF3(outAF3 d,inAF3 a,AF1 b){d[0]=a[0]+b;d[1]=a[1]+b;d[2]=a[2]+b;return d;}
+ A_STATIC retAF4 opAAddOneF4(outAF4 d,inAF4 a,AF1 b){d[0]=a[0]+b;d[1]=a[1]+b;d[2]=a[2]+b;d[3]=a[3]+b;return d;}
+//==============================================================================================================================
+ A_STATIC retAD2 opACpyD2(outAD2 d,inAD2 a){d[0]=a[0];d[1]=a[1];return d;}
+ A_STATIC retAD3 opACpyD3(outAD3 d,inAD3 a){d[0]=a[0];d[1]=a[1];d[2]=a[2];return d;}
+ A_STATIC retAD4 opACpyD4(outAD4 d,inAD4 a){d[0]=a[0];d[1]=a[1];d[2]=a[2];d[3]=a[3];return d;}
+//------------------------------------------------------------------------------------------------------------------------------
+ A_STATIC retAF2 opACpyF2(outAF2 d,inAF2 a){d[0]=a[0];d[1]=a[1];return d;}
+ A_STATIC retAF3 opACpyF3(outAF3 d,inAF3 a){d[0]=a[0];d[1]=a[1];d[2]=a[2];return d;}
+ A_STATIC retAF4 opACpyF4(outAF4 d,inAF4 a){d[0]=a[0];d[1]=a[1];d[2]=a[2];d[3]=a[3];return d;}
+//==============================================================================================================================
+ A_STATIC retAD2 opALerpD2(outAD2 d,inAD2 a,inAD2 b,inAD2 c){d[0]=ALerpD1(a[0],b[0],c[0]);d[1]=ALerpD1(a[1],b[1],c[1]);return d;}
+ A_STATIC retAD3 opALerpD3(outAD3 d,inAD3 a,inAD3 b,inAD3 c){d[0]=ALerpD1(a[0],b[0],c[0]);d[1]=ALerpD1(a[1],b[1],c[1]);d[2]=ALerpD1(a[2],b[2],c[2]);return d;}
+ A_STATIC retAD4 opALerpD4(outAD4 d,inAD4 a,inAD4 b,inAD4 c){d[0]=ALerpD1(a[0],b[0],c[0]);d[1]=ALerpD1(a[1],b[1],c[1]);d[2]=ALerpD1(a[2],b[2],c[2]);d[3]=ALerpD1(a[3],b[3],c[3]);return d;}
+//------------------------------------------------------------------------------------------------------------------------------
+ A_STATIC retAF2 opALerpF2(outAF2 d,inAF2 a,inAF2 b,inAF2 c){d[0]=ALerpF1(a[0],b[0],c[0]);d[1]=ALerpF1(a[1],b[1],c[1]);return d;}
+ A_STATIC retAF3 opALerpF3(outAF3 d,inAF3 a,inAF3 b,inAF3 c){d[0]=ALerpF1(a[0],b[0],c[0]);d[1]=ALerpF1(a[1],b[1],c[1]);d[2]=ALerpF1(a[2],b[2],c[2]);return d;}
+ A_STATIC retAF4 opALerpF4(outAF4 d,inAF4 a,inAF4 b,inAF4 c){d[0]=ALerpF1(a[0],b[0],c[0]);d[1]=ALerpF1(a[1],b[1],c[1]);d[2]=ALerpF1(a[2],b[2],c[2]);d[3]=ALerpF1(a[3],b[3],c[3]);return d;}
+//==============================================================================================================================
+ A_STATIC retAD2 opALerpOneD2(outAD2 d,inAD2 a,inAD2 b,AD1 c){d[0]=ALerpD1(a[0],b[0],c);d[1]=ALerpD1(a[1],b[1],c);return d;}
+ A_STATIC retAD3 opALerpOneD3(outAD3 d,inAD3 a,inAD3 b,AD1 c){d[0]=ALerpD1(a[0],b[0],c);d[1]=ALerpD1(a[1],b[1],c);d[2]=ALerpD1(a[2],b[2],c);return d;}
+ A_STATIC retAD4 opALerpOneD4(outAD4 d,inAD4 a,inAD4 b,AD1 c){d[0]=ALerpD1(a[0],b[0],c);d[1]=ALerpD1(a[1],b[1],c);d[2]=ALerpD1(a[2],b[2],c);d[3]=ALerpD1(a[3],b[3],c);return d;}
+//------------------------------------------------------------------------------------------------------------------------------
+ A_STATIC retAF2 opALerpOneF2(outAF2 d,inAF2 a,inAF2 b,AF1 c){d[0]=ALerpF1(a[0],b[0],c);d[1]=ALerpF1(a[1],b[1],c);return d;}
+ A_STATIC retAF3 opALerpOneF3(outAF3 d,inAF3 a,inAF3 b,AF1 c){d[0]=ALerpF1(a[0],b[0],c);d[1]=ALerpF1(a[1],b[1],c);d[2]=ALerpF1(a[2],b[2],c);return d;}
+ A_STATIC retAF4 opALerpOneF4(outAF4 d,inAF4 a,inAF4 b,AF1 c){d[0]=ALerpF1(a[0],b[0],c);d[1]=ALerpF1(a[1],b[1],c);d[2]=ALerpF1(a[2],b[2],c);d[3]=ALerpF1(a[3],b[3],c);return d;}
+//==============================================================================================================================
+ A_STATIC retAD2 opAMaxD2(outAD2 d,inAD2 a,inAD2 b){d[0]=AMaxD1(a[0],b[0]);d[1]=AMaxD1(a[1],b[1]);return d;}
+ A_STATIC retAD3 opAMaxD3(outAD3 d,inAD3 a,inAD3 b){d[0]=AMaxD1(a[0],b[0]);d[1]=AMaxD1(a[1],b[1]);d[2]=AMaxD1(a[2],b[2]);return d;}
+ A_STATIC retAD4 opAMaxD4(outAD4 d,inAD4 a,inAD4 b){d[0]=AMaxD1(a[0],b[0]);d[1]=AMaxD1(a[1],b[1]);d[2]=AMaxD1(a[2],b[2]);d[3]=AMaxD1(a[3],b[3]);return d;}
+//------------------------------------------------------------------------------------------------------------------------------
+ A_STATIC retAF2 opAMaxF2(outAF2 d,inAF2 a,inAF2 b){d[0]=AMaxF1(a[0],b[0]);d[1]=AMaxF1(a[1],b[1]);return d;}
+ A_STATIC retAF3 opAMaxF3(outAF3 d,inAF3 a,inAF3 b){d[0]=AMaxF1(a[0],b[0]);d[1]=AMaxF1(a[1],b[1]);d[2]=AMaxF1(a[2],b[2]);return d;}
+ A_STATIC retAF4 opAMaxF4(outAF4 d,inAF4 a,inAF4 b){d[0]=AMaxF1(a[0],b[0]);d[1]=AMaxF1(a[1],b[1]);d[2]=AMaxF1(a[2],b[2]);d[3]=AMaxF1(a[3],b[3]);return d;}
+//==============================================================================================================================
+ A_STATIC retAD2 opAMinD2(outAD2 d,inAD2 a,inAD2 b){d[0]=AMinD1(a[0],b[0]);d[1]=AMinD1(a[1],b[1]);return d;}
+ A_STATIC retAD3 opAMinD3(outAD3 d,inAD3 a,inAD3 b){d[0]=AMinD1(a[0],b[0]);d[1]=AMinD1(a[1],b[1]);d[2]=AMinD1(a[2],b[2]);return d;}
+ A_STATIC retAD4 opAMinD4(outAD4 d,inAD4 a,inAD4 b){d[0]=AMinD1(a[0],b[0]);d[1]=AMinD1(a[1],b[1]);d[2]=AMinD1(a[2],b[2]);d[3]=AMinD1(a[3],b[3]);return d;}
+//------------------------------------------------------------------------------------------------------------------------------
+ A_STATIC retAF2 opAMinF2(outAF2 d,inAF2 a,inAF2 b){d[0]=AMinF1(a[0],b[0]);d[1]=AMinF1(a[1],b[1]);return d;}
+ A_STATIC retAF3 opAMinF3(outAF3 d,inAF3 a,inAF3 b){d[0]=AMinF1(a[0],b[0]);d[1]=AMinF1(a[1],b[1]);d[2]=AMinF1(a[2],b[2]);return d;}
+ A_STATIC retAF4 opAMinF4(outAF4 d,inAF4 a,inAF4 b){d[0]=AMinF1(a[0],b[0]);d[1]=AMinF1(a[1],b[1]);d[2]=AMinF1(a[2],b[2]);d[3]=AMinF1(a[3],b[3]);return d;}
+//==============================================================================================================================
+ A_STATIC retAD2 opAMulD2(outAD2 d,inAD2 a,inAD2 b){d[0]=a[0]*b[0];d[1]=a[1]*b[1];return d;}
+ A_STATIC retAD3 opAMulD3(outAD3 d,inAD3 a,inAD3 b){d[0]=a[0]*b[0];d[1]=a[1]*b[1];d[2]=a[2]*b[2];return d;}
+ A_STATIC retAD4 opAMulD4(outAD4 d,inAD4 a,inAD4 b){d[0]=a[0]*b[0];d[1]=a[1]*b[1];d[2]=a[2]*b[2];d[3]=a[3]*b[3];return d;}
+//------------------------------------------------------------------------------------------------------------------------------
+ A_STATIC retAF2 opAMulF2(outAF2 d,inAF2 a,inAF2 b){d[0]=a[0]*b[0];d[1]=a[1]*b[1];return d;}
+ A_STATIC retAF3 opAMulF3(outAF3 d,inAF3 a,inAF3 b){d[0]=a[0]*b[0];d[1]=a[1]*b[1];d[2]=a[2]*b[2];return d;}
+ A_STATIC retAF4 opAMulF4(outAF4 d,inAF4 a,inAF4 b){d[0]=a[0]*b[0];d[1]=a[1]*b[1];d[2]=a[2]*b[2];d[3]=a[3]*b[3];return d;}
+//==============================================================================================================================
+ A_STATIC retAD2 opAMulOneD2(outAD2 d,inAD2 a,AD1 b){d[0]=a[0]*b;d[1]=a[1]*b;return d;}
+ A_STATIC retAD3 opAMulOneD3(outAD3 d,inAD3 a,AD1 b){d[0]=a[0]*b;d[1]=a[1]*b;d[2]=a[2]*b;return d;}
+ A_STATIC retAD4 opAMulOneD4(outAD4 d,inAD4 a,AD1 b){d[0]=a[0]*b;d[1]=a[1]*b;d[2]=a[2]*b;d[3]=a[3]*b;return d;}
+//------------------------------------------------------------------------------------------------------------------------------
+ A_STATIC retAF2 opAMulOneF2(outAF2 d,inAF2 a,AF1 b){d[0]=a[0]*b;d[1]=a[1]*b;return d;}
+ A_STATIC retAF3 opAMulOneF3(outAF3 d,inAF3 a,AF1 b){d[0]=a[0]*b;d[1]=a[1]*b;d[2]=a[2]*b;return d;}
+ A_STATIC retAF4 opAMulOneF4(outAF4 d,inAF4 a,AF1 b){d[0]=a[0]*b;d[1]=a[1]*b;d[2]=a[2]*b;d[3]=a[3]*b;return d;}
+//==============================================================================================================================
+ A_STATIC retAD2 opANegD2(outAD2 d,inAD2 a){d[0]=-a[0];d[1]=-a[1];return d;}
+ A_STATIC retAD3 opANegD3(outAD3 d,inAD3 a){d[0]=-a[0];d[1]=-a[1];d[2]=-a[2];return d;}
+ A_STATIC retAD4 opANegD4(outAD4 d,inAD4 a){d[0]=-a[0];d[1]=-a[1];d[2]=-a[2];d[3]=-a[3];return d;}
+//------------------------------------------------------------------------------------------------------------------------------
+ A_STATIC retAF2 opANegF2(outAF2 d,inAF2 a){d[0]=-a[0];d[1]=-a[1];return d;}
+ A_STATIC retAF3 opANegF3(outAF3 d,inAF3 a){d[0]=-a[0];d[1]=-a[1];d[2]=-a[2];return d;}
+ A_STATIC retAF4 opANegF4(outAF4 d,inAF4 a){d[0]=-a[0];d[1]=-a[1];d[2]=-a[2];d[3]=-a[3];return d;}
+//==============================================================================================================================
+ A_STATIC retAD2 opARcpD2(outAD2 d,inAD2 a){d[0]=ARcpD1(a[0]);d[1]=ARcpD1(a[1]);return d;}
+ A_STATIC retAD3 opARcpD3(outAD3 d,inAD3 a){d[0]=ARcpD1(a[0]);d[1]=ARcpD1(a[1]);d[2]=ARcpD1(a[2]);return d;}
+ A_STATIC retAD4 opARcpD4(outAD4 d,inAD4 a){d[0]=ARcpD1(a[0]);d[1]=ARcpD1(a[1]);d[2]=ARcpD1(a[2]);d[3]=ARcpD1(a[3]);return d;}
+//------------------------------------------------------------------------------------------------------------------------------
+ A_STATIC retAF2 opARcpF2(outAF2 d,inAF2 a){d[0]=ARcpF1(a[0]);d[1]=ARcpF1(a[1]);return d;}
+ A_STATIC retAF3 opARcpF3(outAF3 d,inAF3 a){d[0]=ARcpF1(a[0]);d[1]=ARcpF1(a[1]);d[2]=ARcpF1(a[2]);return d;}
+ A_STATIC retAF4 opARcpF4(outAF4 d,inAF4 a){d[0]=ARcpF1(a[0]);d[1]=ARcpF1(a[1]);d[2]=ARcpF1(a[2]);d[3]=ARcpF1(a[3]);return d;}
+////////////////////////////////////////////////////////////////////////////////////////////////////////////////////////////////
+////////////////////////////////////////////////////////////////////////////////////////////////////////////////////////////////
+//_____________________________________________________________/\_______________________________________________________________
+//==============================================================================================================================
+//                                                     HALF FLOAT PACKING
+//==============================================================================================================================
+ // Convert float to half (in lower 16-bits of output).
+ // Same fast technique as documented here: ftp://ftp.fox-toolkit.org/pub/fasthalffloatconversion.pdf
+ // Supports denormals.
+ // Conversion rules are to make computations possibly "safer" on the GPU,
+ //  -INF & -NaN -> -65504
+ //  +INF & +NaN -> +65504
+ A_STATIC AU1 AU1_AH1_AF1(AF1 f){
+  static AW1 base[512]={
+   0x0000,0x0000,0x0000,0x0000,0x0000,0x0000,0x0000,0x0000,0x0000,0x0000,0x0000,0x0000,0x0000,0x0000,0x0000,0x0000,
+   0x0000,0x0000,0x0000,0x0000,0x0000,0x0000,0x0000,0x0000,0x0000,0x0000,0x0000,0x0000,0x0000,0x0000,0x0000,0x0000,
+   0x0000,0x0000,0x0000,0x0000,0x0000,0x0000,0x0000,0x0000,0x0000,0x0000,0x0000,0x0000,0x0000,0x0000,0x0000,0x0000,
+   0x0000,0x0000,0x0000,0x0000,0x0000,0x0000,0x0000,0x0000,0x0000,0x0000,0x0000,0x0000,0x0000,0x0000,0x0000,0x0000,
+   0x0000,0x0000,0x0000,0x0000,0x0000,0x0000,0x0000,0x0000,0x0000,0x0000,0x0000,0x0000,0x0000,0x0000,0x0000,0x0000,
+   0x0000,0x0000,0x0000,0x0000,0x0000,0x0000,0x0000,0x0000,0x0000,0x0000,0x0000,0x0000,0x0000,0x0000,0x0000,0x0000,
+   0x0000,0x0000,0x0000,0x0000,0x0000,0x0000,0x0000,0x0001,0x0002,0x0004,0x0008,0x0010,0x0020,0x0040,0x0080,0x0100,
+   0x0200,0x0400,0x0800,0x0c00,0x1000,0x1400,0x1800,0x1c00,0x2000,0x2400,0x2800,0x2c00,0x3000,0x3400,0x3800,0x3c00,
+   0x4000,0x4400,0x4800,0x4c00,0x5000,0x5400,0x5800,0x5c00,0x6000,0x6400,0x6800,0x6c00,0x7000,0x7400,0x7800,0x7bff,
+   0x7bff,0x7bff,0x7bff,0x7bff,0x7bff,0x7bff,0x7bff,0x7bff,0x7bff,0x7bff,0x7bff,0x7bff,0x7bff,0x7bff,0x7bff,0x7bff,
+   0x7bff,0x7bff,0x7bff,0x7bff,0x7bff,0x7bff,0x7bff,0x7bff,0x7bff,0x7bff,0x7bff,0x7bff,0x7bff,0x7bff,0x7bff,0x7bff,
+   0x7bff,0x7bff,0x7bff,0x7bff,0x7bff,0x7bff,0x7bff,0x7bff,0x7bff,0x7bff,0x7bff,0x7bff,0x7bff,0x7bff,0x7bff,0x7bff,
+   0x7bff,0x7bff,0x7bff,0x7bff,0x7bff,0x7bff,0x7bff,0x7bff,0x7bff,0x7bff,0x7bff,0x7bff,0x7bff,0x7bff,0x7bff,0x7bff,
+   0x7bff,0x7bff,0x7bff,0x7bff,0x7bff,0x7bff,0x7bff,0x7bff,0x7bff,0x7bff,0x7bff,0x7bff,0x7bff,0x7bff,0x7bff,0x7bff,
+   0x7bff,0x7bff,0x7bff,0x7bff,0x7bff,0x7bff,0x7bff,0x7bff,0x7bff,0x7bff,0x7bff,0x7bff,0x7bff,0x7bff,0x7bff,0x7bff,
+   0x7bff,0x7bff,0x7bff,0x7bff,0x7bff,0x7bff,0x7bff,0x7bff,0x7bff,0x7bff,0x7bff,0x7bff,0x7bff,0x7bff,0x7bff,0x7bff,
+   0x8000,0x8000,0x8000,0x8000,0x8000,0x8000,0x8000,0x8000,0x8000,0x8000,0x8000,0x8000,0x8000,0x8000,0x8000,0x8000,
+   0x8000,0x8000,0x8000,0x8000,0x8000,0x8000,0x8000,0x8000,0x8000,0x8000,0x8000,0x8000,0x8000,0x8000,0x8000,0x8000,
+   0x8000,0x8000,0x8000,0x8000,0x8000,0x8000,0x8000,0x8000,0x8000,0x8000,0x8000,0x8000,0x8000,0x8000,0x8000,0x8000,
+   0x8000,0x8000,0x8000,0x8000,0x8000,0x8000,0x8000,0x8000,0x8000,0x8000,0x8000,0x8000,0x8000,0x8000,0x8000,0x8000,
+   0x8000,0x8000,0x8000,0x8000,0x8000,0x8000,0x8000,0x8000,0x8000,0x8000,0x8000,0x8000,0x8000,0x8000,0x8000,0x8000,
+   0x8000,0x8000,0x8000,0x8000,0x8000,0x8000,0x8000,0x8000,0x8000,0x8000,0x8000,0x8000,0x8000,0x8000,0x8000,0x8000,
+   0x8000,0x8000,0x8000,0x8000,0x8000,0x8000,0x8000,0x8001,0x8002,0x8004,0x8008,0x8010,0x8020,0x8040,0x8080,0x8100,
+   0x8200,0x8400,0x8800,0x8c00,0x9000,0x9400,0x9800,0x9c00,0xa000,0xa400,0xa800,0xac00,0xb000,0xb400,0xb800,0xbc00,
+   0xc000,0xc400,0xc800,0xcc00,0xd000,0xd400,0xd800,0xdc00,0xe000,0xe400,0xe800,0xec00,0xf000,0xf400,0xf800,0xfbff,
+   0xfbff,0xfbff,0xfbff,0xfbff,0xfbff,0xfbff,0xfbff,0xfbff,0xfbff,0xfbff,0xfbff,0xfbff,0xfbff,0xfbff,0xfbff,0xfbff,
+   0xfbff,0xfbff,0xfbff,0xfbff,0xfbff,0xfbff,0xfbff,0xfbff,0xfbff,0xfbff,0xfbff,0xfbff,0xfbff,0xfbff,0xfbff,0xfbff,
+   0xfbff,0xfbff,0xfbff,0xfbff,0xfbff,0xfbff,0xfbff,0xfbff,0xfbff,0xfbff,0xfbff,0xfbff,0xfbff,0xfbff,0xfbff,0xfbff,
+   0xfbff,0xfbff,0xfbff,0xfbff,0xfbff,0xfbff,0xfbff,0xfbff,0xfbff,0xfbff,0xfbff,0xfbff,0xfbff,0xfbff,0xfbff,0xfbff,
+   0xfbff,0xfbff,0xfbff,0xfbff,0xfbff,0xfbff,0xfbff,0xfbff,0xfbff,0xfbff,0xfbff,0xfbff,0xfbff,0xfbff,0xfbff,0xfbff,
+   0xfbff,0xfbff,0xfbff,0xfbff,0xfbff,0xfbff,0xfbff,0xfbff,0xfbff,0xfbff,0xfbff,0xfbff,0xfbff,0xfbff,0xfbff,0xfbff,
+   0xfbff,0xfbff,0xfbff,0xfbff,0xfbff,0xfbff,0xfbff,0xfbff,0xfbff,0xfbff,0xfbff,0xfbff,0xfbff,0xfbff,0xfbff,0xfbff};
+  static AB1 shift[512]={
+   0x18,0x18,0x18,0x18,0x18,0x18,0x18,0x18,0x18,0x18,0x18,0x18,0x18,0x18,0x18,0x18,
+   0x18,0x18,0x18,0x18,0x18,0x18,0x18,0x18,0x18,0x18,0x18,0x18,0x18,0x18,0x18,0x18,
+   0x18,0x18,0x18,0x18,0x18,0x18,0x18,0x18,0x18,0x18,0x18,0x18,0x18,0x18,0x18,0x18,
+   0x18,0x18,0x18,0x18,0x18,0x18,0x18,0x18,0x18,0x18,0x18,0x18,0x18,0x18,0x18,0x18,
+   0x18,0x18,0x18,0x18,0x18,0x18,0x18,0x18,0x18,0x18,0x18,0x18,0x18,0x18,0x18,0x18,
+   0x18,0x18,0x18,0x18,0x18,0x18,0x18,0x18,0x18,0x18,0x18,0x18,0x18,0x18,0x18,0x18,
+   0x18,0x18,0x18,0x18,0x18,0x18,0x18,0x17,0x16,0x15,0x14,0x13,0x12,0x11,0x10,0x0f,
+   0x0e,0x0d,0x0d,0x0d,0x0d,0x0d,0x0d,0x0d,0x0d,0x0d,0x0d,0x0d,0x0d,0x0d,0x0d,0x0d,
+   0x0d,0x0d,0x0d,0x0d,0x0d,0x0d,0x0d,0x0d,0x0d,0x0d,0x0d,0x0d,0x0d,0x0d,0x0d,0x18,
+   0x18,0x18,0x18,0x18,0x18,0x18,0x18,0x18,0x18,0x18,0x18,0x18,0x18,0x18,0x18,0x18,
+   0x18,0x18,0x18,0x18,0x18,0x18,0x18,0x18,0x18,0x18,0x18,0x18,0x18,0x18,0x18,0x18,
+   0x18,0x18,0x18,0x18,0x18,0x18,0x18,0x18,0x18,0x18,0x18,0x18,0x18,0x18,0x18,0x18,
+   0x18,0x18,0x18,0x18,0x18,0x18,0x18,0x18,0x18,0x18,0x18,0x18,0x18,0x18,0x18,0x18,
+   0x18,0x18,0x18,0x18,0x18,0x18,0x18,0x18,0x18,0x18,0x18,0x18,0x18,0x18,0x18,0x18,
+   0x18,0x18,0x18,0x18,0x18,0x18,0x18,0x18,0x18,0x18,0x18,0x18,0x18,0x18,0x18,0x18,
+   0x18,0x18,0x18,0x18,0x18,0x18,0x18,0x18,0x18,0x18,0x18,0x18,0x18,0x18,0x18,0x18,
+   0x18,0x18,0x18,0x18,0x18,0x18,0x18,0x18,0x18,0x18,0x18,0x18,0x18,0x18,0x18,0x18,
+   0x18,0x18,0x18,0x18,0x18,0x18,0x18,0x18,0x18,0x18,0x18,0x18,0x18,0x18,0x18,0x18,
+   0x18,0x18,0x18,0x18,0x18,0x18,0x18,0x18,0x18,0x18,0x18,0x18,0x18,0x18,0x18,0x18,
+   0x18,0x18,0x18,0x18,0x18,0x18,0x18,0x18,0x18,0x18,0x18,0x18,0x18,0x18,0x18,0x18,
+   0x18,0x18,0x18,0x18,0x18,0x18,0x18,0x18,0x18,0x18,0x18,0x18,0x18,0x18,0x18,0x18,
+   0x18,0x18,0x18,0x18,0x18,0x18,0x18,0x18,0x18,0x18,0x18,0x18,0x18,0x18,0x18,0x18,
+   0x18,0x18,0x18,0x18,0x18,0x18,0x18,0x17,0x16,0x15,0x14,0x13,0x12,0x11,0x10,0x0f,
+   0x0e,0x0d,0x0d,0x0d,0x0d,0x0d,0x0d,0x0d,0x0d,0x0d,0x0d,0x0d,0x0d,0x0d,0x0d,0x0d,
+   0x0d,0x0d,0x0d,0x0d,0x0d,0x0d,0x0d,0x0d,0x0d,0x0d,0x0d,0x0d,0x0d,0x0d,0x0d,0x18,
+   0x18,0x18,0x18,0x18,0x18,0x18,0x18,0x18,0x18,0x18,0x18,0x18,0x18,0x18,0x18,0x18,
+   0x18,0x18,0x18,0x18,0x18,0x18,0x18,0x18,0x18,0x18,0x18,0x18,0x18,0x18,0x18,0x18,
+   0x18,0x18,0x18,0x18,0x18,0x18,0x18,0x18,0x18,0x18,0x18,0x18,0x18,0x18,0x18,0x18,
+   0x18,0x18,0x18,0x18,0x18,0x18,0x18,0x18,0x18,0x18,0x18,0x18,0x18,0x18,0x18,0x18,
+   0x18,0x18,0x18,0x18,0x18,0x18,0x18,0x18,0x18,0x18,0x18,0x18,0x18,0x18,0x18,0x18,
+   0x18,0x18,0x18,0x18,0x18,0x18,0x18,0x18,0x18,0x18,0x18,0x18,0x18,0x18,0x18,0x18,
+   0x18,0x18,0x18,0x18,0x18,0x18,0x18,0x18,0x18,0x18,0x18,0x18,0x18,0x18,0x18,0x18};
+  union{AF1 f;AU1 u;}bits;bits.f=f;AU1 u=bits.u;AU1 i=u>>23;return (AU1)(base[i])+((u&0x7fffff)>>shift[i]);}
+//------------------------------------------------------------------------------------------------------------------------------
+ // Used to output packed constant.
+ A_STATIC AU1 AU1_AH2_AF2(inAF2 a){return AU1_AH1_AF1(a[0])+(AU1_AH1_AF1(a[1])<<16);}
+#endif
+//_____________________________________________________________/\_______________________________________________________________
+//==============================================================================================================================
+//                                                            GLSL
+//==============================================================================================================================
+#if defined(A_GLSL) && defined(A_GPU)
+ #ifndef A_SKIP_EXT
+  #ifdef A_LONG
+   #extension GL_ARB_gpu_shader_int64:require
+   #extension GL_NV_shader_atomic_int64:require
+  #endif
+//------------------------------------------------------------------------------------------------------------------------------
+  #ifdef A_WAVE
+   #extension GL_KHR_shader_subgroup_arithmetic:require
+   #extension GL_KHR_shader_subgroup_ballot:require
+   #extension GL_KHR_shader_subgroup_quad:require
+   #extension GL_KHR_shader_subgroup_shuffle:require
+  #endif
+ #endif
+//==============================================================================================================================
+ #define AP1 bool
+ #define AP2 bvec2
+ #define AP3 bvec3
+ #define AP4 bvec4
+//------------------------------------------------------------------------------------------------------------------------------
+ #define AF1 float
+ #define AF2 vec2
+ #define AF3 vec3
+ #define AF4 vec4
+//------------------------------------------------------------------------------------------------------------------------------
+ #define AU1 uint
+ #define AU2 uvec2
+ #define AU3 uvec3
+ #define AU4 uvec4
+//------------------------------------------------------------------------------------------------------------------------------
+ #define ASU1 int
+ #define ASU2 ivec2
+ #define ASU3 ivec3
+ #define ASU4 ivec4
+//==============================================================================================================================
+ #define AF1_AU1(x) uintBitsToFloat(AU1(x))
+ #define AF2_AU2(x) uintBitsToFloat(AU2(x))
+ #define AF3_AU3(x) uintBitsToFloat(AU3(x))
+ #define AF4_AU4(x) uintBitsToFloat(AU4(x))
+//------------------------------------------------------------------------------------------------------------------------------
+ #define AU1_AF1(x) floatBitsToUint(AF1(x))
+ #define AU2_AF2(x) floatBitsToUint(AF2(x))
+ #define AU3_AF3(x) floatBitsToUint(AF3(x))
+ #define AU4_AF4(x) floatBitsToUint(AF4(x))
+//==============================================================================================================================
+ AF1 AF1_x(AF1 a){return AF1(a);}
+ AF2 AF2_x(AF1 a){return AF2(a,a);}
+ AF3 AF3_x(AF1 a){return AF3(a,a,a);}
+ AF4 AF4_x(AF1 a){return AF4(a,a,a,a);}
+ #define AF1_(a) AF1_x(AF1(a))
+ #define AF2_(a) AF2_x(AF1(a))
+ #define AF3_(a) AF3_x(AF1(a))
+ #define AF4_(a) AF4_x(AF1(a))
+//------------------------------------------------------------------------------------------------------------------------------
+ AU1 AU1_x(AU1 a){return AU1(a);}
+ AU2 AU2_x(AU1 a){return AU2(a,a);}
+ AU3 AU3_x(AU1 a){return AU3(a,a,a);}
+ AU4 AU4_x(AU1 a){return AU4(a,a,a,a);}
+ #define AU1_(a) AU1_x(AU1(a))
+ #define AU2_(a) AU2_x(AU1(a))
+ #define AU3_(a) AU3_x(AU1(a))
+ #define AU4_(a) AU4_x(AU1(a))
+//==============================================================================================================================
+ AU1 AAbsSU1(AU1 a){return AU1(abs(ASU1(a)));}
+ AU2 AAbsSU2(AU2 a){return AU2(abs(ASU2(a)));}
+ AU3 AAbsSU3(AU3 a){return AU3(abs(ASU3(a)));}
+ AU4 AAbsSU4(AU4 a){return AU4(abs(ASU4(a)));}
+//------------------------------------------------------------------------------------------------------------------------------
+ AU1 ABfe(AU1 src,AU1 off,AU1 bits){return bitfieldExtract(src,ASU1(off),ASU1(bits));}
+ AU1 ABfi(AU1 src,AU1 ins,AU1 mask){return (ins&mask)|(src&(~mask));}
+ // Proxy for V_BFI_B32 where the 'mask' is set as 'bits', 'mask=(1<<bits)-1', and 'bits' needs to be an immediate.
+ AU1 ABfiM(AU1 src,AU1 ins,AU1 bits){return bitfieldInsert(src,ins,0,ASU1(bits));}
+//------------------------------------------------------------------------------------------------------------------------------
+ // V_MED3_F32.
+ AF1 AClampF1(AF1 x,AF1 n,AF1 m){return clamp(x,n,m);}
+ AF2 AClampF2(AF2 x,AF2 n,AF2 m){return clamp(x,n,m);}
+ AF3 AClampF3(AF3 x,AF3 n,AF3 m){return clamp(x,n,m);}
+ AF4 AClampF4(AF4 x,AF4 n,AF4 m){return clamp(x,n,m);}
+//------------------------------------------------------------------------------------------------------------------------------
+ // V_FRACT_F32 (note DX frac() is different).
+ AF1 AFractF1(AF1 x){return fract(x);}
+ AF2 AFractF2(AF2 x){return fract(x);}
+ AF3 AFractF3(AF3 x){return fract(x);}
+ AF4 AFractF4(AF4 x){return fract(x);}
+//------------------------------------------------------------------------------------------------------------------------------
+ AF1 ALerpF1(AF1 x,AF1 y,AF1 a){return mix(x,y,a);}
+ AF2 ALerpF2(AF2 x,AF2 y,AF2 a){return mix(x,y,a);}
+ AF3 ALerpF3(AF3 x,AF3 y,AF3 a){return mix(x,y,a);}
+ AF4 ALerpF4(AF4 x,AF4 y,AF4 a){return mix(x,y,a);}
+//------------------------------------------------------------------------------------------------------------------------------
+ // V_MAX3_F32.
+ AF1 AMax3F1(AF1 x,AF1 y,AF1 z){return max(x,max(y,z));}
+ AF2 AMax3F2(AF2 x,AF2 y,AF2 z){return max(x,max(y,z));}
+ AF3 AMax3F3(AF3 x,AF3 y,AF3 z){return max(x,max(y,z));}
+ AF4 AMax3F4(AF4 x,AF4 y,AF4 z){return max(x,max(y,z));}
+//------------------------------------------------------------------------------------------------------------------------------
+ AU1 AMax3SU1(AU1 x,AU1 y,AU1 z){return AU1(max(ASU1(x),max(ASU1(y),ASU1(z))));}
+ AU2 AMax3SU2(AU2 x,AU2 y,AU2 z){return AU2(max(ASU2(x),max(ASU2(y),ASU2(z))));}
+ AU3 AMax3SU3(AU3 x,AU3 y,AU3 z){return AU3(max(ASU3(x),max(ASU3(y),ASU3(z))));}
+ AU4 AMax3SU4(AU4 x,AU4 y,AU4 z){return AU4(max(ASU4(x),max(ASU4(y),ASU4(z))));}
+//------------------------------------------------------------------------------------------------------------------------------
+ AU1 AMax3U1(AU1 x,AU1 y,AU1 z){return max(x,max(y,z));}
+ AU2 AMax3U2(AU2 x,AU2 y,AU2 z){return max(x,max(y,z));}
+ AU3 AMax3U3(AU3 x,AU3 y,AU3 z){return max(x,max(y,z));}
+ AU4 AMax3U4(AU4 x,AU4 y,AU4 z){return max(x,max(y,z));}
+//------------------------------------------------------------------------------------------------------------------------------
+ AU1 AMaxSU1(AU1 a,AU1 b){return AU1(max(ASU1(a),ASU1(b)));}
+ AU2 AMaxSU2(AU2 a,AU2 b){return AU2(max(ASU2(a),ASU2(b)));}
+ AU3 AMaxSU3(AU3 a,AU3 b){return AU3(max(ASU3(a),ASU3(b)));}
+ AU4 AMaxSU4(AU4 a,AU4 b){return AU4(max(ASU4(a),ASU4(b)));}
+//------------------------------------------------------------------------------------------------------------------------------
+ // Clamp has an easier pattern match for med3 when some ordering is known.
+ // V_MED3_F32.
+ AF1 AMed3F1(AF1 x,AF1 y,AF1 z){return max(min(x,y),min(max(x,y),z));}
+ AF2 AMed3F2(AF2 x,AF2 y,AF2 z){return max(min(x,y),min(max(x,y),z));}
+ AF3 AMed3F3(AF3 x,AF3 y,AF3 z){return max(min(x,y),min(max(x,y),z));}
+ AF4 AMed3F4(AF4 x,AF4 y,AF4 z){return max(min(x,y),min(max(x,y),z));}
+//------------------------------------------------------------------------------------------------------------------------------
+ // V_MIN3_F32.
+ AF1 AMin3F1(AF1 x,AF1 y,AF1 z){return min(x,min(y,z));}
+ AF2 AMin3F2(AF2 x,AF2 y,AF2 z){return min(x,min(y,z));}
+ AF3 AMin3F3(AF3 x,AF3 y,AF3 z){return min(x,min(y,z));}
+ AF4 AMin3F4(AF4 x,AF4 y,AF4 z){return min(x,min(y,z));}
+//------------------------------------------------------------------------------------------------------------------------------
+ AU1 AMin3SU1(AU1 x,AU1 y,AU1 z){return AU1(min(ASU1(x),min(ASU1(y),ASU1(z))));}
+ AU2 AMin3SU2(AU2 x,AU2 y,AU2 z){return AU2(min(ASU2(x),min(ASU2(y),ASU2(z))));}
+ AU3 AMin3SU3(AU3 x,AU3 y,AU3 z){return AU3(min(ASU3(x),min(ASU3(y),ASU3(z))));}
+ AU4 AMin3SU4(AU4 x,AU4 y,AU4 z){return AU4(min(ASU4(x),min(ASU4(y),ASU4(z))));}
+//------------------------------------------------------------------------------------------------------------------------------
+ AU1 AMin3U1(AU1 x,AU1 y,AU1 z){return min(x,min(y,z));}
+ AU2 AMin3U2(AU2 x,AU2 y,AU2 z){return min(x,min(y,z));}
+ AU3 AMin3U3(AU3 x,AU3 y,AU3 z){return min(x,min(y,z));}
+ AU4 AMin3U4(AU4 x,AU4 y,AU4 z){return min(x,min(y,z));}
+//------------------------------------------------------------------------------------------------------------------------------
+ AU1 AMinSU1(AU1 a,AU1 b){return AU1(min(ASU1(a),ASU1(b)));}
+ AU2 AMinSU2(AU2 a,AU2 b){return AU2(min(ASU2(a),ASU2(b)));}
+ AU3 AMinSU3(AU3 a,AU3 b){return AU3(min(ASU3(a),ASU3(b)));}
+ AU4 AMinSU4(AU4 a,AU4 b){return AU4(min(ASU4(a),ASU4(b)));}
+//------------------------------------------------------------------------------------------------------------------------------
+ // Normalized trig. Valid input domain is {-256 to +256}. No GLSL compiler intrinsic exists to map to this currently.
+ // V_COS_F32.
+ AF1 ANCosF1(AF1 x){return cos(x*AF1_(A_2PI));}
+ AF2 ANCosF2(AF2 x){return cos(x*AF2_(A_2PI));}
+ AF3 ANCosF3(AF3 x){return cos(x*AF3_(A_2PI));}
+ AF4 ANCosF4(AF4 x){return cos(x*AF4_(A_2PI));}
+//------------------------------------------------------------------------------------------------------------------------------
+ // Normalized trig. Valid input domain is {-256 to +256}. No GLSL compiler intrinsic exists to map to this currently.
+ // V_SIN_F32.
+ AF1 ANSinF1(AF1 x){return sin(x*AF1_(A_2PI));}
+ AF2 ANSinF2(AF2 x){return sin(x*AF2_(A_2PI));}
+ AF3 ANSinF3(AF3 x){return sin(x*AF3_(A_2PI));}
+ AF4 ANSinF4(AF4 x){return sin(x*AF4_(A_2PI));}
+//------------------------------------------------------------------------------------------------------------------------------
+ AF1 ARcpF1(AF1 x){return AF1_(1.0)/x;}
+ AF2 ARcpF2(AF2 x){return AF2_(1.0)/x;}
+ AF3 ARcpF3(AF3 x){return AF3_(1.0)/x;}
+ AF4 ARcpF4(AF4 x){return AF4_(1.0)/x;}
+//------------------------------------------------------------------------------------------------------------------------------
+ AF1 ARsqF1(AF1 x){return AF1_(1.0)/sqrt(x);}
+ AF2 ARsqF2(AF2 x){return AF2_(1.0)/sqrt(x);}
+ AF3 ARsqF3(AF3 x){return AF3_(1.0)/sqrt(x);}
+ AF4 ARsqF4(AF4 x){return AF4_(1.0)/sqrt(x);}
+//------------------------------------------------------------------------------------------------------------------------------
+ AF1 ASatF1(AF1 x){return clamp(x,AF1_(0.0),AF1_(1.0));}
+ AF2 ASatF2(AF2 x){return clamp(x,AF2_(0.0),AF2_(1.0));}
+ AF3 ASatF3(AF3 x){return clamp(x,AF3_(0.0),AF3_(1.0));}
+ AF4 ASatF4(AF4 x){return clamp(x,AF4_(0.0),AF4_(1.0));}
+//------------------------------------------------------------------------------------------------------------------------------
+ AU1 AShrSU1(AU1 a,AU1 b){return AU1(ASU1(a)>>ASU1(b));}
+ AU2 AShrSU2(AU2 a,AU2 b){return AU2(ASU2(a)>>ASU2(b));}
+ AU3 AShrSU3(AU3 a,AU3 b){return AU3(ASU3(a)>>ASU3(b));}
+ AU4 AShrSU4(AU4 a,AU4 b){return AU4(ASU4(a)>>ASU4(b));}
+////////////////////////////////////////////////////////////////////////////////////////////////////////////////////////////////
+////////////////////////////////////////////////////////////////////////////////////////////////////////////////////////////////
+//_____________________________________________________________/\_______________________________________________________________
+//==============================================================================================================================
+//                                                          GLSL BYTE
+//==============================================================================================================================
+ #ifdef A_BYTE
+  #define AB1 uint8_t
+  #define AB2 u8vec2
+  #define AB3 u8vec3
+  #define AB4 u8vec4
+//------------------------------------------------------------------------------------------------------------------------------
+  #define ASB1 int8_t
+  #define ASB2 i8vec2
+  #define ASB3 i8vec3
+  #define ASB4 i8vec4
+//------------------------------------------------------------------------------------------------------------------------------
+  AB1 AB1_x(AB1 a){return AB1(a);}
+  AB2 AB2_x(AB1 a){return AB2(a,a);}
+  AB3 AB3_x(AB1 a){return AB3(a,a,a);}
+  AB4 AB4_x(AB1 a){return AB4(a,a,a,a);}
+  #define AB1_(a) AB1_x(AB1(a))
+  #define AB2_(a) AB2_x(AB1(a))
+  #define AB3_(a) AB3_x(AB1(a))
+  #define AB4_(a) AB4_x(AB1(a))
+ #endif
+////////////////////////////////////////////////////////////////////////////////////////////////////////////////////////////////
+////////////////////////////////////////////////////////////////////////////////////////////////////////////////////////////////
+//_____________________________________________________________/\_______________________________________________________________
+//==============================================================================================================================
+//                                                         GLSL DOUBLE
+//==============================================================================================================================
+ #ifdef A_DUBL
+  #define AD1 double
+  #define AD2 dvec2
+  #define AD3 dvec3
+  #define AD4 dvec4
+//------------------------------------------------------------------------------------------------------------------------------
+  AD1 AD1_x(AD1 a){return AD1(a);}
+  AD2 AD2_x(AD1 a){return AD2(a,a);}
+  AD3 AD3_x(AD1 a){return AD3(a,a,a);}
+  AD4 AD4_x(AD1 a){return AD4(a,a,a,a);}
+  #define AD1_(a) AD1_x(AD1(a))
+  #define AD2_(a) AD2_x(AD1(a))
+  #define AD3_(a) AD3_x(AD1(a))
+  #define AD4_(a) AD4_x(AD1(a))
+//==============================================================================================================================
+  AD1 AFractD1(AD1 x){return fract(x);}
+  AD2 AFractD2(AD2 x){return fract(x);}
+  AD3 AFractD3(AD3 x){return fract(x);}
+  AD4 AFractD4(AD4 x){return fract(x);}
+//------------------------------------------------------------------------------------------------------------------------------
+  AD1 ALerpD1(AD1 x,AD1 y,AD1 a){return mix(x,y,a);}
+  AD2 ALerpD2(AD2 x,AD2 y,AD2 a){return mix(x,y,a);}
+  AD3 ALerpD3(AD3 x,AD3 y,AD3 a){return mix(x,y,a);}
+  AD4 ALerpD4(AD4 x,AD4 y,AD4 a){return mix(x,y,a);}
+//------------------------------------------------------------------------------------------------------------------------------
+  AD1 ARcpD1(AD1 x){return AD1_(1.0)/x;}
+  AD2 ARcpD2(AD2 x){return AD2_(1.0)/x;}
+  AD3 ARcpD3(AD3 x){return AD3_(1.0)/x;}
+  AD4 ARcpD4(AD4 x){return AD4_(1.0)/x;}
+//------------------------------------------------------------------------------------------------------------------------------
+  AD1 ARsqD1(AD1 x){return AD1_(1.0)/sqrt(x);}
+  AD2 ARsqD2(AD2 x){return AD2_(1.0)/sqrt(x);}
+  AD3 ARsqD3(AD3 x){return AD3_(1.0)/sqrt(x);}
+  AD4 ARsqD4(AD4 x){return AD4_(1.0)/sqrt(x);}
+//------------------------------------------------------------------------------------------------------------------------------
+  AD1 ASatD1(AD1 x){return clamp(x,AD1_(0.0),AD1_(1.0));}
+  AD2 ASatD2(AD2 x){return clamp(x,AD2_(0.0),AD2_(1.0));}
+  AD3 ASatD3(AD3 x){return clamp(x,AD3_(0.0),AD3_(1.0));}
+  AD4 ASatD4(AD4 x){return clamp(x,AD4_(0.0),AD4_(1.0));}
+ #endif
+////////////////////////////////////////////////////////////////////////////////////////////////////////////////////////////////
+////////////////////////////////////////////////////////////////////////////////////////////////////////////////////////////////
+//_____________________________________________________________/\_______________________________________________________________
+//==============================================================================================================================
+//                                                         GLSL LONG
+//==============================================================================================================================
+ #ifdef A_LONG
+  #define AL1 uint64_t
+  #define AL2 u64vec2
+  #define AL3 u64vec3
+  #define AL4 u64vec4
+//------------------------------------------------------------------------------------------------------------------------------
+  #define ASL1 int64_t
+  #define ASL2 i64vec2
+  #define ASL3 i64vec3
+  #define ASL4 i64vec4
+//------------------------------------------------------------------------------------------------------------------------------
+  #define AL1_AU2(x) packUint2x32(AU2(x))
+  #define AU2_AL1(x) unpackUint2x32(AL1(x))
+//------------------------------------------------------------------------------------------------------------------------------
+  AL1 AL1_x(AL1 a){return AL1(a);}
+  AL2 AL2_x(AL1 a){return AL2(a,a);}
+  AL3 AL3_x(AL1 a){return AL3(a,a,a);}
+  AL4 AL4_x(AL1 a){return AL4(a,a,a,a);}
+  #define AL1_(a) AL1_x(AL1(a))
+  #define AL2_(a) AL2_x(AL1(a))
+  #define AL3_(a) AL3_x(AL1(a))
+  #define AL4_(a) AL4_x(AL1(a))
+//==============================================================================================================================
+  AL1 AAbsSL1(AL1 a){return AL1(abs(ASL1(a)));}
+  AL2 AAbsSL2(AL2 a){return AL2(abs(ASL2(a)));}
+  AL3 AAbsSL3(AL3 a){return AL3(abs(ASL3(a)));}
+  AL4 AAbsSL4(AL4 a){return AL4(abs(ASL4(a)));}
+//------------------------------------------------------------------------------------------------------------------------------
+  AL1 AMaxSL1(AL1 a,AL1 b){return AL1(max(ASU1(a),ASU1(b)));}
+  AL2 AMaxSL2(AL2 a,AL2 b){return AL2(max(ASU2(a),ASU2(b)));}
+  AL3 AMaxSL3(AL3 a,AL3 b){return AL3(max(ASU3(a),ASU3(b)));}
+  AL4 AMaxSL4(AL4 a,AL4 b){return AL4(max(ASU4(a),ASU4(b)));}
+//------------------------------------------------------------------------------------------------------------------------------
+  AL1 AMinSL1(AL1 a,AL1 b){return AL1(min(ASU1(a),ASU1(b)));}
+  AL2 AMinSL2(AL2 a,AL2 b){return AL2(min(ASU2(a),ASU2(b)));}
+  AL3 AMinSL3(AL3 a,AL3 b){return AL3(min(ASU3(a),ASU3(b)));}
+  AL4 AMinSL4(AL4 a,AL4 b){return AL4(min(ASU4(a),ASU4(b)));}
+ #endif
+////////////////////////////////////////////////////////////////////////////////////////////////////////////////////////////////
+////////////////////////////////////////////////////////////////////////////////////////////////////////////////////////////////
+//_____________________________________________________________/\_______________________________________________________________
+//==============================================================================================================================
+//                                                      WAVE OPERATIONS
+//==============================================================================================================================
+ #ifdef A_WAVE
+  // Where 'x' must be a compile time literal.
+  AF1 AWaveXorF1(AF1 v,AU1 x){return subgroupShuffleXor(v,x);}
+  AF2 AWaveXorF2(AF2 v,AU1 x){return subgroupShuffleXor(v,x);}
+  AF3 AWaveXorF3(AF3 v,AU1 x){return subgroupShuffleXor(v,x);}
+  AF4 AWaveXorF4(AF4 v,AU1 x){return subgroupShuffleXor(v,x);}
+  AU1 AWaveXorU1(AU1 v,AU1 x){return subgroupShuffleXor(v,x);}
+  AU2 AWaveXorU2(AU2 v,AU1 x){return subgroupShuffleXor(v,x);}
+  AU3 AWaveXorU3(AU3 v,AU1 x){return subgroupShuffleXor(v,x);}
+  AU4 AWaveXorU4(AU4 v,AU1 x){return subgroupShuffleXor(v,x);}
+ #endif
+//==============================================================================================================================
+#endif
+////////////////////////////////////////////////////////////////////////////////////////////////////////////////////////////////
+////////////////////////////////////////////////////////////////////////////////////////////////////////////////////////////////
+////////////////////////////////////////////////////////////////////////////////////////////////////////////////////////////////
+////////////////////////////////////////////////////////////////////////////////////////////////////////////////////////////////
+////////////////////////////////////////////////////////////////////////////////////////////////////////////////////////////////
+////////////////////////////////////////////////////////////////////////////////////////////////////////////////////////////////
+//_____________________________________________________________/\_______________________________________________________________
+//==============================================================================================================================
+//
+//
+//                                                            HLSL
+//
+//
+//==============================================================================================================================
+#if defined(A_HLSL) && defined(A_GPU)
+ #ifdef A_HLSL_6_2
+  #define AP1 bool
+  #define AP2 bool2
+  #define AP3 bool3
+  #define AP4 bool4
+//------------------------------------------------------------------------------------------------------------------------------
+  #define AF1 float32_t
+  #define AF2 float32_t2
+  #define AF3 float32_t3
+  #define AF4 float32_t4
+//------------------------------------------------------------------------------------------------------------------------------
+  #define AU1 uint32_t
+  #define AU2 uint32_t2
+  #define AU3 uint32_t3
+  #define AU4 uint32_t4
+//------------------------------------------------------------------------------------------------------------------------------
+  #define ASU1 int32_t
+  #define ASU2 int32_t2
+  #define ASU3 int32_t3
+  #define ASU4 int32_t4
+ #else
+  #define AP1 bool
+  #define AP2 bool2
+  #define AP3 bool3
+  #define AP4 bool4
+//------------------------------------------------------------------------------------------------------------------------------
+  #define AF1 float
+  #define AF2 float2
+  #define AF3 float3
+  #define AF4 float4
+//------------------------------------------------------------------------------------------------------------------------------
+  #define AU1 uint
+  #define AU2 uint2
+  #define AU3 uint3
+  #define AU4 uint4
+//------------------------------------------------------------------------------------------------------------------------------
+  #define ASU1 int
+  #define ASU2 int2
+  #define ASU3 int3
+  #define ASU4 int4
+ #endif
+//==============================================================================================================================
+ #define AF1_AU1(x) asfloat(AU1(x))
+ #define AF2_AU2(x) asfloat(AU2(x))
+ #define AF3_AU3(x) asfloat(AU3(x))
+ #define AF4_AU4(x) asfloat(AU4(x))
+//------------------------------------------------------------------------------------------------------------------------------
+ #define AU1_AF1(x) asuint(AF1(x))
+ #define AU2_AF2(x) asuint(AF2(x))
+ #define AU3_AF3(x) asuint(AF3(x))
+ #define AU4_AF4(x) asuint(AF4(x))
+//------------------------------------------------------------------------------------------------------------------------------
+ AU1 AU1_AH1_AF1_x(AF1 a){return f32tof16(a);}
+ #define AU1_AH1_AF1(a) AU1_AH1_AF1_x(AF1(a))
+//------------------------------------------------------------------------------------------------------------------------------
+ AU1 AU1_AH2_AF2_x(AF2 a){return f32tof16(a.x)|(f32tof16(a.y)<<16);}
+ #define AU1_AH2_AF2(a) AU1_AH2_AF2_x(AF2(a))
+ #define AU1_AB4Unorm_AF4(x) D3DCOLORtoUBYTE4(AF4(x))
+//------------------------------------------------------------------------------------------------------------------------------
+ AF2 AF2_AH2_AU1_x(AU1 x){return AF2(f16tof32(x&0xFFFF),f16tof32(x>>16));}
+ #define AF2_AH2_AU1(x) AF2_AH2_AU1_x(AU1(x))
+//==============================================================================================================================
+ AF1 AF1_x(AF1 a){return AF1(a);}
+ AF2 AF2_x(AF1 a){return AF2(a,a);}
+ AF3 AF3_x(AF1 a){return AF3(a,a,a);}
+ AF4 AF4_x(AF1 a){return AF4(a,a,a,a);}
+ #define AF1_(a) AF1_x(AF1(a))
+ #define AF2_(a) AF2_x(AF1(a))
+ #define AF3_(a) AF3_x(AF1(a))
+ #define AF4_(a) AF4_x(AF1(a))
+//------------------------------------------------------------------------------------------------------------------------------
+ AU1 AU1_x(AU1 a){return AU1(a);}
+ AU2 AU2_x(AU1 a){return AU2(a,a);}
+ AU3 AU3_x(AU1 a){return AU3(a,a,a);}
+ AU4 AU4_x(AU1 a){return AU4(a,a,a,a);}
+ #define AU1_(a) AU1_x(AU1(a))
+ #define AU2_(a) AU2_x(AU1(a))
+ #define AU3_(a) AU3_x(AU1(a))
+ #define AU4_(a) AU4_x(AU1(a))
+//==============================================================================================================================
+ AU1 AAbsSU1(AU1 a){return AU1(abs(ASU1(a)));}
+ AU2 AAbsSU2(AU2 a){return AU2(abs(ASU2(a)));}
+ AU3 AAbsSU3(AU3 a){return AU3(abs(ASU3(a)));}
+ AU4 AAbsSU4(AU4 a){return AU4(abs(ASU4(a)));}
+//------------------------------------------------------------------------------------------------------------------------------
+ AU1 ABfe(AU1 src,AU1 off,AU1 bits){AU1 mask=(1u<<bits)-1;return (src>>off)&mask;}
+ AU1 ABfi(AU1 src,AU1 ins,AU1 mask){return (ins&mask)|(src&(~mask));}
+ AU1 ABfiM(AU1 src,AU1 ins,AU1 bits){AU1 mask=(1u<<bits)-1;return (ins&mask)|(src&(~mask));}
+//------------------------------------------------------------------------------------------------------------------------------
+ AF1 AClampF1(AF1 x,AF1 n,AF1 m){return max(n,min(x,m));}
+ AF2 AClampF2(AF2 x,AF2 n,AF2 m){return max(n,min(x,m));}
+ AF3 AClampF3(AF3 x,AF3 n,AF3 m){return max(n,min(x,m));}
+ AF4 AClampF4(AF4 x,AF4 n,AF4 m){return max(n,min(x,m));}
+//------------------------------------------------------------------------------------------------------------------------------
+ AF1 AFractF1(AF1 x){return x-floor(x);}
+ AF2 AFractF2(AF2 x){return x-floor(x);}
+ AF3 AFractF3(AF3 x){return x-floor(x);}
+ AF4 AFractF4(AF4 x){return x-floor(x);}
+//------------------------------------------------------------------------------------------------------------------------------
+ AF1 ALerpF1(AF1 x,AF1 y,AF1 a){return lerp(x,y,a);}
+ AF2 ALerpF2(AF2 x,AF2 y,AF2 a){return lerp(x,y,a);}
+ AF3 ALerpF3(AF3 x,AF3 y,AF3 a){return lerp(x,y,a);}
+ AF4 ALerpF4(AF4 x,AF4 y,AF4 a){return lerp(x,y,a);}
+//------------------------------------------------------------------------------------------------------------------------------
+ AF1 AMax3F1(AF1 x,AF1 y,AF1 z){return max(x,max(y,z));}
+ AF2 AMax3F2(AF2 x,AF2 y,AF2 z){return max(x,max(y,z));}
+ AF3 AMax3F3(AF3 x,AF3 y,AF3 z){return max(x,max(y,z));}
+ AF4 AMax3F4(AF4 x,AF4 y,AF4 z){return max(x,max(y,z));}
+//------------------------------------------------------------------------------------------------------------------------------
+ AU1 AMax3SU1(AU1 x,AU1 y,AU1 z){return AU1(max(ASU1(x),max(ASU1(y),ASU1(z))));}
+ AU2 AMax3SU2(AU2 x,AU2 y,AU2 z){return AU2(max(ASU2(x),max(ASU2(y),ASU2(z))));}
+ AU3 AMax3SU3(AU3 x,AU3 y,AU3 z){return AU3(max(ASU3(x),max(ASU3(y),ASU3(z))));}
+ AU4 AMax3SU4(AU4 x,AU4 y,AU4 z){return AU4(max(ASU4(x),max(ASU4(y),ASU4(z))));}
+//------------------------------------------------------------------------------------------------------------------------------
+ AU1 AMax3U1(AU1 x,AU1 y,AU1 z){return max(x,max(y,z));}
+ AU2 AMax3U2(AU2 x,AU2 y,AU2 z){return max(x,max(y,z));}
+ AU3 AMax3U3(AU3 x,AU3 y,AU3 z){return max(x,max(y,z));}
+ AU4 AMax3U4(AU4 x,AU4 y,AU4 z){return max(x,max(y,z));}
+//------------------------------------------------------------------------------------------------------------------------------
+ AU1 AMaxSU1(AU1 a,AU1 b){return AU1(max(ASU1(a),ASU1(b)));}
+ AU2 AMaxSU2(AU2 a,AU2 b){return AU2(max(ASU2(a),ASU2(b)));}
+ AU3 AMaxSU3(AU3 a,AU3 b){return AU3(max(ASU3(a),ASU3(b)));}
+ AU4 AMaxSU4(AU4 a,AU4 b){return AU4(max(ASU4(a),ASU4(b)));}
+//------------------------------------------------------------------------------------------------------------------------------
+ AF1 AMed3F1(AF1 x,AF1 y,AF1 z){return max(min(x,y),min(max(x,y),z));}
+ AF2 AMed3F2(AF2 x,AF2 y,AF2 z){return max(min(x,y),min(max(x,y),z));}
+ AF3 AMed3F3(AF3 x,AF3 y,AF3 z){return max(min(x,y),min(max(x,y),z));}
+ AF4 AMed3F4(AF4 x,AF4 y,AF4 z){return max(min(x,y),min(max(x,y),z));}
+//------------------------------------------------------------------------------------------------------------------------------
+ AF1 AMin3F1(AF1 x,AF1 y,AF1 z){return min(x,min(y,z));}
+ AF2 AMin3F2(AF2 x,AF2 y,AF2 z){return min(x,min(y,z));}
+ AF3 AMin3F3(AF3 x,AF3 y,AF3 z){return min(x,min(y,z));}
+ AF4 AMin3F4(AF4 x,AF4 y,AF4 z){return min(x,min(y,z));}
+//------------------------------------------------------------------------------------------------------------------------------
+ AU1 AMin3SU1(AU1 x,AU1 y,AU1 z){return AU1(min(ASU1(x),min(ASU1(y),ASU1(z))));}
+ AU2 AMin3SU2(AU2 x,AU2 y,AU2 z){return AU2(min(ASU2(x),min(ASU2(y),ASU2(z))));}
+ AU3 AMin3SU3(AU3 x,AU3 y,AU3 z){return AU3(min(ASU3(x),min(ASU3(y),ASU3(z))));}
+ AU4 AMin3SU4(AU4 x,AU4 y,AU4 z){return AU4(min(ASU4(x),min(ASU4(y),ASU4(z))));}
+//------------------------------------------------------------------------------------------------------------------------------
+ AU1 AMin3U1(AU1 x,AU1 y,AU1 z){return min(x,min(y,z));}
+ AU2 AMin3U2(AU2 x,AU2 y,AU2 z){return min(x,min(y,z));}
+ AU3 AMin3U3(AU3 x,AU3 y,AU3 z){return min(x,min(y,z));}
+ AU4 AMin3U4(AU4 x,AU4 y,AU4 z){return min(x,min(y,z));}
+//------------------------------------------------------------------------------------------------------------------------------
+ AU1 AMinSU1(AU1 a,AU1 b){return AU1(min(ASU1(a),ASU1(b)));}
+ AU2 AMinSU2(AU2 a,AU2 b){return AU2(min(ASU2(a),ASU2(b)));}
+ AU3 AMinSU3(AU3 a,AU3 b){return AU3(min(ASU3(a),ASU3(b)));}
+ AU4 AMinSU4(AU4 a,AU4 b){return AU4(min(ASU4(a),ASU4(b)));}
+//------------------------------------------------------------------------------------------------------------------------------
+ AF1 ANCosF1(AF1 x){return cos(x*AF1_(A_2PI));}
+ AF2 ANCosF2(AF2 x){return cos(x*AF2_(A_2PI));}
+ AF3 ANCosF3(AF3 x){return cos(x*AF3_(A_2PI));}
+ AF4 ANCosF4(AF4 x){return cos(x*AF4_(A_2PI));}
+//------------------------------------------------------------------------------------------------------------------------------
+ AF1 ANSinF1(AF1 x){return sin(x*AF1_(A_2PI));}
+ AF2 ANSinF2(AF2 x){return sin(x*AF2_(A_2PI));}
+ AF3 ANSinF3(AF3 x){return sin(x*AF3_(A_2PI));}
+ AF4 ANSinF4(AF4 x){return sin(x*AF4_(A_2PI));}
+//------------------------------------------------------------------------------------------------------------------------------
+ AF1 ARcpF1(AF1 x){return rcp(x);}
+ AF2 ARcpF2(AF2 x){return rcp(x);}
+ AF3 ARcpF3(AF3 x){return rcp(x);}
+ AF4 ARcpF4(AF4 x){return rcp(x);}
+//------------------------------------------------------------------------------------------------------------------------------
+ AF1 ARsqF1(AF1 x){return rsqrt(x);}
+ AF2 ARsqF2(AF2 x){return rsqrt(x);}
+ AF3 ARsqF3(AF3 x){return rsqrt(x);}
+ AF4 ARsqF4(AF4 x){return rsqrt(x);}
+//------------------------------------------------------------------------------------------------------------------------------
+ AF1 ASatF1(AF1 x){return saturate(x);}
+ AF2 ASatF2(AF2 x){return saturate(x);}
+ AF3 ASatF3(AF3 x){return saturate(x);}
+ AF4 ASatF4(AF4 x){return saturate(x);}
+//------------------------------------------------------------------------------------------------------------------------------
+ AU1 AShrSU1(AU1 a,AU1 b){return AU1(ASU1(a)>>ASU1(b));}
+ AU2 AShrSU2(AU2 a,AU2 b){return AU2(ASU2(a)>>ASU2(b));}
+ AU3 AShrSU3(AU3 a,AU3 b){return AU3(ASU3(a)>>ASU3(b));}
+ AU4 AShrSU4(AU4 a,AU4 b){return AU4(ASU4(a)>>ASU4(b));}
+////////////////////////////////////////////////////////////////////////////////////////////////////////////////////////////////
+////////////////////////////////////////////////////////////////////////////////////////////////////////////////////////////////
+//_____________________________________________________________/\_______________________________________________________________
+//==============================================================================================================================
+//                                                          HLSL BYTE
+//==============================================================================================================================
+ #ifdef A_BYTE
+ #endif
+////////////////////////////////////////////////////////////////////////////////////////////////////////////////////////////////
+////////////////////////////////////////////////////////////////////////////////////////////////////////////////////////////////
+//_____________________________________________________________/\_______________________________________________________________
+//==============================================================================================================================
+//                                                         HLSL DOUBLE
+//==============================================================================================================================
+ #ifdef A_DUBL
+  #ifdef A_HLSL_6_2
+   #define AD1 float64_t
+   #define AD2 float64_t2
+   #define AD3 float64_t3
+   #define AD4 float64_t4
+  #else
+   #define AD1 double
+   #define AD2 double2
+   #define AD3 double3
+   #define AD4 double4
+  #endif
+//------------------------------------------------------------------------------------------------------------------------------
+  AD1 AD1_x(AD1 a){return AD1(a);}
+  AD2 AD2_x(AD1 a){return AD2(a,a);}
+  AD3 AD3_x(AD1 a){return AD3(a,a,a);}
+  AD4 AD4_x(AD1 a){return AD4(a,a,a,a);}
+  #define AD1_(a) AD1_x(AD1(a))
+  #define AD2_(a) AD2_x(AD1(a))
+  #define AD3_(a) AD3_x(AD1(a))
+  #define AD4_(a) AD4_x(AD1(a))
+//==============================================================================================================================
+  AD1 AFractD1(AD1 a){return a-floor(a);}
+  AD2 AFractD2(AD2 a){return a-floor(a);}
+  AD3 AFractD3(AD3 a){return a-floor(a);}
+  AD4 AFractD4(AD4 a){return a-floor(a);}
+//------------------------------------------------------------------------------------------------------------------------------
+  AD1 ALerpD1(AD1 x,AD1 y,AD1 a){return lerp(x,y,a);}
+  AD2 ALerpD2(AD2 x,AD2 y,AD2 a){return lerp(x,y,a);}
+  AD3 ALerpD3(AD3 x,AD3 y,AD3 a){return lerp(x,y,a);}
+  AD4 ALerpD4(AD4 x,AD4 y,AD4 a){return lerp(x,y,a);}
+//------------------------------------------------------------------------------------------------------------------------------
+  AD1 ARcpD1(AD1 x){return rcp(x);}
+  AD2 ARcpD2(AD2 x){return rcp(x);}
+  AD3 ARcpD3(AD3 x){return rcp(x);}
+  AD4 ARcpD4(AD4 x){return rcp(x);}
+//------------------------------------------------------------------------------------------------------------------------------
+  AD1 ARsqD1(AD1 x){return rsqrt(x);}
+  AD2 ARsqD2(AD2 x){return rsqrt(x);}
+  AD3 ARsqD3(AD3 x){return rsqrt(x);}
+  AD4 ARsqD4(AD4 x){return rsqrt(x);}
+//------------------------------------------------------------------------------------------------------------------------------
+  AD1 ASatD1(AD1 x){return saturate(x);}
+  AD2 ASatD2(AD2 x){return saturate(x);}
+  AD3 ASatD3(AD3 x){return saturate(x);}
+  AD4 ASatD4(AD4 x){return saturate(x);}
+ #endif
+//==============================================================================================================================
+//                                                         HLSL WAVE
+//==============================================================================================================================
+ #ifdef A_WAVE
+  // Where 'x' must be a compile time literal.
+  AF1 AWaveXorF1(AF1 v,AU1 x){return WaveReadLaneAt(v,WaveGetLaneIndex()^x);}
+  AF2 AWaveXorF2(AF2 v,AU1 x){return WaveReadLaneAt(v,WaveGetLaneIndex()^x);}
+  AF3 AWaveXorF3(AF3 v,AU1 x){return WaveReadLaneAt(v,WaveGetLaneIndex()^x);}
+  AF4 AWaveXorF4(AF4 v,AU1 x){return WaveReadLaneAt(v,WaveGetLaneIndex()^x);}
+  AU1 AWaveXorU1(AU1 v,AU1 x){return WaveReadLaneAt(v,WaveGetLaneIndex()^x);}
+  AU2 AWaveXorU1(AU2 v,AU1 x){return WaveReadLaneAt(v,WaveGetLaneIndex()^x);}
+  AU3 AWaveXorU1(AU3 v,AU1 x){return WaveReadLaneAt(v,WaveGetLaneIndex()^x);}
+  AU4 AWaveXorU1(AU4 v,AU1 x){return WaveReadLaneAt(v,WaveGetLaneIndex()^x);}
+ #endif
+//==============================================================================================================================
+#endif
+////////////////////////////////////////////////////////////////////////////////////////////////////////////////////////////////
+////////////////////////////////////////////////////////////////////////////////////////////////////////////////////////////////
+////////////////////////////////////////////////////////////////////////////////////////////////////////////////////////////////
+////////////////////////////////////////////////////////////////////////////////////////////////////////////////////////////////
+////////////////////////////////////////////////////////////////////////////////////////////////////////////////////////////////
+////////////////////////////////////////////////////////////////////////////////////////////////////////////////////////////////
+//_____________________________________________________________/\_______________________________________________________________
+//==============================================================================================================================
+//
+//
+//                                                          GPU COMMON
+//
+//
+//==============================================================================================================================
+#ifdef A_GPU
+ // Negative and positive infinity.
+ #define A_INFP_F AF1_AU1(0x7f800000u)
+ #define A_INFN_F AF1_AU1(0xff800000u)
+//------------------------------------------------------------------------------------------------------------------------------
+ // Copy sign from 's' to positive 'd'.
+ AF1 ACpySgnF1(AF1 d,AF1 s){return AF1_AU1(AU1_AF1(d)|(AU1_AF1(s)&AU1_(0x80000000u)));}
+ AF2 ACpySgnF2(AF2 d,AF2 s){return AF2_AU2(AU2_AF2(d)|(AU2_AF2(s)&AU2_(0x80000000u)));}
+ AF3 ACpySgnF3(AF3 d,AF3 s){return AF3_AU3(AU3_AF3(d)|(AU3_AF3(s)&AU3_(0x80000000u)));}
+ AF4 ACpySgnF4(AF4 d,AF4 s){return AF4_AU4(AU4_AF4(d)|(AU4_AF4(s)&AU4_(0x80000000u)));}
+//------------------------------------------------------------------------------------------------------------------------------
+ // Single operation to return (useful to create a mask to use in lerp for branch free logic),
+ //  m=NaN := 0
+ //  m>=0  := 0
+ //  m<0   := 1
+ // Uses the following useful floating point logic,
+ //  saturate(+a*(-INF)==-INF) := 0
+ //  saturate( 0*(-INF)== NaN) := 0
+ //  saturate(-a*(-INF)==+INF) := 1
+ AF1 ASignedF1(AF1 m){return ASatF1(m*AF1_(A_INFN_F));}
+ AF2 ASignedF2(AF2 m){return ASatF2(m*AF2_(A_INFN_F));}
+ AF3 ASignedF3(AF3 m){return ASatF3(m*AF3_(A_INFN_F));}
+ AF4 ASignedF4(AF4 m){return ASatF4(m*AF4_(A_INFN_F));}
+//------------------------------------------------------------------------------------------------------------------------------
+ AF1 AGtZeroF1(AF1 m){return ASatF1(m*AF1_(A_INFP_F));}
+ AF2 AGtZeroF2(AF2 m){return ASatF2(m*AF2_(A_INFP_F));}
+ AF3 AGtZeroF3(AF3 m){return ASatF3(m*AF3_(A_INFP_F));}
+ AF4 AGtZeroF4(AF4 m){return ASatF4(m*AF4_(A_INFP_F));}
+////////////////////////////////////////////////////////////////////////////////////////////////////////////////////////////////
+////////////////////////////////////////////////////////////////////////////////////////////////////////////////////////////////
+//_____________________________________________________________/\_______________________________________________________________
+//==============================================================================================================================
+//                                                [FIS] FLOAT INTEGER SORTABLE
+//------------------------------------------------------------------------------------------------------------------------------
+// Float to integer sortable.
+//  - If sign bit=0, flip the sign bit (positives).
+//  - If sign bit=1, flip all bits     (negatives).
+// Integer sortable to float.
+//  - If sign bit=1, flip the sign bit (positives).
+//  - If sign bit=0, flip all bits     (negatives).
+// Has nice side effects.
+//  - Larger integers are more positive values.
+//  - Float zero is mapped to center of integers (so clear to integer zero is a nice default for atomic max usage).
+// Burns 3 ops for conversion {shift,or,xor}.
+//==============================================================================================================================
+ AU1 AFisToU1(AU1 x){return x^(( AShrSU1(x,AU1_(31)))|AU1_(0x80000000));}
+ AU1 AFisFromU1(AU1 x){return x^((~AShrSU1(x,AU1_(31)))|AU1_(0x80000000));}
+//------------------------------------------------------------------------------------------------------------------------------
+ // Just adjust high 16-bit value (useful when upper part of 32-bit word is a 16-bit float value).
+ AU1 AFisToHiU1(AU1 x){return x^(( AShrSU1(x,AU1_(15)))|AU1_(0x80000000));}
+ AU1 AFisFromHiU1(AU1 x){return x^((~AShrSU1(x,AU1_(15)))|AU1_(0x80000000));}
+////////////////////////////////////////////////////////////////////////////////////////////////////////////////////////////////
+////////////////////////////////////////////////////////////////////////////////////////////////////////////////////////////////
+//_____________________________________________________________/\_______________________________________________________________
+//==============================================================================================================================
+//                                               [BUC] BYTE UNSIGNED CONVERSION
+//------------------------------------------------------------------------------------------------------------------------------
+// Designed to use the optimal conversion, enables the scaling to possibly be factored into other computation.
+// Works on a range of {0 to A_BUC_<32,16>}, for <32-bit, and 16-bit> respectively.
+//------------------------------------------------------------------------------------------------------------------------------
+// OPCODE NOTES
+// ============
+// GCN does not do UNORM or SNORM for bytes in opcodes.
+//  - V_CVT_F32_UBYTE{0,1,2,3} - Unsigned byte to float.
+//  - V_CVT_PKACC_U8_F32 - Float to unsigned byte (does bit-field insert into 32-bit integer).
+// V_PERM_B32 does byte packing with ability to zero fill bytes as well.
+//  - Can pull out byte values from two sources, and zero fill upper 8-bits of packed hi and lo.
+//------------------------------------------------------------------------------------------------------------------------------
+// BYTE : FLOAT - ABuc{0,1,2,3}{To,From}U1() - Designed for V_CVT_F32_UBYTE* and V_CVT_PKACCUM_U8_F32 ops.
+// ====   =====
+//    0 : 0
+//    1 : 1
+//     ...
+//  255 : 255
+//      : 256 (just outside the encoding range)
+//------------------------------------------------------------------------------------------------------------------------------
+// BYTE : FLOAT - ABuc{0,1,2,3}{To,From}U2() - Designed for 16-bit denormal tricks and V_PERM_B32.
+// ====   =====
+//    0 : 0
+//    1 : 1/512
+//    2 : 1/256
+//     ...
+//   64 : 1/8
+//  128 : 1/4
+//  255 : 255/512
+//      : 1/2 (just outside the encoding range)
+//------------------------------------------------------------------------------------------------------------------------------
+// OPTIMAL IMPLEMENTATIONS ON AMD ARCHITECTURES
+// ============================================
+// r=ABuc0FromU1(i)
+//   V_CVT_F32_UBYTE0 r,i
+// --------------------------------------------
+// r=ABuc0ToU1(d,i)
+//   V_CVT_PKACCUM_U8_F32 r,i,0,d
+// --------------------------------------------
+// d=ABuc0FromU2(i)
+//   Where 'k0' is an SGPR with 0x0E0A
+//   Where 'k1' is an SGPR with {32768.0} packed into the lower 16-bits
+//   V_PERM_B32 d,i.x,i.y,k0
+//   V_PK_FMA_F16 d,d,k1.x,0
+// --------------------------------------------
+// r=ABuc0ToU2(d,i)
+//   Where 'k0' is an SGPR with {1.0/32768.0} packed into the lower 16-bits
+//   Where 'k1' is an SGPR with 0x????
+//   Where 'k2' is an SGPR with 0x????
+//   V_PK_FMA_F16 i,i,k0.x,0
+//   V_PERM_B32 r.x,i,i,k1
+//   V_PERM_B32 r.y,i,i,k2
+//==============================================================================================================================
+ // Peak range for 32-bit and 16-bit operations.
+ #define A_BUC_32 (255.0)
+ #define A_BUC_16 (255.0/512.0)
+//==============================================================================================================================
+ #if 1
+  // Designed to be one V_CVT_PKACCUM_U8_F32.
+  // The extra min is required to pattern match to V_CVT_PKACCUM_U8_F32.
+  AU1 ABuc0ToU1(AU1 d,AF1 i){return (d&0xffffff00u)|((min(AU1(i),255u)    )&(0x000000ffu));}
+  AU1 ABuc1ToU1(AU1 d,AF1 i){return (d&0xffff00ffu)|((min(AU1(i),255u)<< 8)&(0x0000ff00u));}
+  AU1 ABuc2ToU1(AU1 d,AF1 i){return (d&0xff00ffffu)|((min(AU1(i),255u)<<16)&(0x00ff0000u));}
+  AU1 ABuc3ToU1(AU1 d,AF1 i){return (d&0x00ffffffu)|((min(AU1(i),255u)<<24)&(0xff000000u));}
+//------------------------------------------------------------------------------------------------------------------------------
+  // Designed to be one V_CVT_F32_UBYTE*.
+  AF1 ABuc0FromU1(AU1 i){return AF1((i    )&255u);}
+  AF1 ABuc1FromU1(AU1 i){return AF1((i>> 8)&255u);}
+  AF1 ABuc2FromU1(AU1 i){return AF1((i>>16)&255u);}
+  AF1 ABuc3FromU1(AU1 i){return AF1((i>>24)&255u);}
+ #endif
+////////////////////////////////////////////////////////////////////////////////////////////////////////////////////////////////
+////////////////////////////////////////////////////////////////////////////////////////////////////////////////////////////////
+//_____________________________________________________________/\_______________________________________________________________
+//==============================================================================================================================
+//                                                 [BSC] BYTE SIGNED CONVERSION
+//------------------------------------------------------------------------------------------------------------------------------
+// Similar to [BUC].
+// Works on a range of {-/+ A_BSC_<32,16>}, for <32-bit, and 16-bit> respectively.
+//------------------------------------------------------------------------------------------------------------------------------
+// ENCODING (without zero-based encoding)
+// ========
+//   0 = unused (can be used to mean something else)
+//   1 = lowest value
+// 128 = exact zero center (zero based encoding
+// 255 = highest value
+//------------------------------------------------------------------------------------------------------------------------------
+// Zero-based [Zb] flips the MSB bit of the byte (making 128 "exact zero" actually zero).
+// This is useful if there is a desire for cleared values to decode as zero.
+//------------------------------------------------------------------------------------------------------------------------------
+// BYTE : FLOAT - ABsc{0,1,2,3}{To,From}U2() - Designed for 16-bit denormal tricks and V_PERM_B32.
+// ====   =====
+//    0 : -127/512 (unused)
+//    1 : -126/512
+//    2 : -125/512
+//     ...
+//  128 : 0
+//     ...
+//  255 : 127/512
+//      : 1/4 (just outside the encoding range)
+//==============================================================================================================================
+ // Peak range for 32-bit and 16-bit operations.
+ #define A_BSC_32 (127.0)
+ #define A_BSC_16 (127.0/512.0)
+//==============================================================================================================================
+ #if 1
+  AU1 ABsc0ToU1(AU1 d,AF1 i){return (d&0xffffff00u)|((min(AU1(i+128.0),255u)    )&(0x000000ffu));}
+  AU1 ABsc1ToU1(AU1 d,AF1 i){return (d&0xffff00ffu)|((min(AU1(i+128.0),255u)<< 8)&(0x0000ff00u));}
+  AU1 ABsc2ToU1(AU1 d,AF1 i){return (d&0xff00ffffu)|((min(AU1(i+128.0),255u)<<16)&(0x00ff0000u));}
+  AU1 ABsc3ToU1(AU1 d,AF1 i){return (d&0x00ffffffu)|((min(AU1(i+128.0),255u)<<24)&(0xff000000u));}
+//------------------------------------------------------------------------------------------------------------------------------
+  AU1 ABsc0ToZbU1(AU1 d,AF1 i){return ((d&0xffffff00u)|((min(AU1(trunc(i)+128.0),255u)    )&(0x000000ffu)))^0x00000080u;}
+  AU1 ABsc1ToZbU1(AU1 d,AF1 i){return ((d&0xffff00ffu)|((min(AU1(trunc(i)+128.0),255u)<< 8)&(0x0000ff00u)))^0x00008000u;}
+  AU1 ABsc2ToZbU1(AU1 d,AF1 i){return ((d&0xff00ffffu)|((min(AU1(trunc(i)+128.0),255u)<<16)&(0x00ff0000u)))^0x00800000u;}
+  AU1 ABsc3ToZbU1(AU1 d,AF1 i){return ((d&0x00ffffffu)|((min(AU1(trunc(i)+128.0),255u)<<24)&(0xff000000u)))^0x80000000u;}
+//------------------------------------------------------------------------------------------------------------------------------
+  AF1 ABsc0FromU1(AU1 i){return AF1((i    )&255u)-128.0;}
+  AF1 ABsc1FromU1(AU1 i){return AF1((i>> 8)&255u)-128.0;}
+  AF1 ABsc2FromU1(AU1 i){return AF1((i>>16)&255u)-128.0;}
+  AF1 ABsc3FromU1(AU1 i){return AF1((i>>24)&255u)-128.0;}
+//------------------------------------------------------------------------------------------------------------------------------
+  AF1 ABsc0FromZbU1(AU1 i){return AF1(((i    )&255u)^0x80u)-128.0;}
+  AF1 ABsc1FromZbU1(AU1 i){return AF1(((i>> 8)&255u)^0x80u)-128.0;}
+  AF1 ABsc2FromZbU1(AU1 i){return AF1(((i>>16)&255u)^0x80u)-128.0;}
+  AF1 ABsc3FromZbU1(AU1 i){return AF1(((i>>24)&255u)^0x80u)-128.0;}
+ #endif
+////////////////////////////////////////////////////////////////////////////////////////////////////////////////////////////////
+////////////////////////////////////////////////////////////////////////////////////////////////////////////////////////////////
+//_____________________________________________________________/\_______________________________________________________________
+//==============================================================================================================================
+//                                                    FLOAT APPROXIMATIONS
+//------------------------------------------------------------------------------------------------------------------------------
+// Michal Drobot has an excellent presentation on these: "Low Level Optimizations For GCN",
+//  - Idea dates back to SGI, then to Quake 3, etc.
+//  - https://michaldrobot.files.wordpress.com/2014/05/gcn_alu_opt_digitaldragons2014.pdf
+//     - sqrt(x)=rsqrt(x)*x
+//     - rcp(x)=rsqrt(x)*rsqrt(x) for positive x
+//  - https://github.com/michaldrobot/ShaderFastLibs/blob/master/ShaderFastMathLib.h
+//------------------------------------------------------------------------------------------------------------------------------
+// These below are from perhaps less complete searching for optimal.
+// Used FP16 normal range for testing with +4096 32-bit step size for sampling error.
+// So these match up well with the half approximations.
+//==============================================================================================================================
+ AF1 APrxLoSqrtF1(AF1 a){return AF1_AU1((AU1_AF1(a)>>AU1_(1))+AU1_(0x1fbc4639));}
+ AF1 APrxLoRcpF1(AF1 a){return AF1_AU1(AU1_(0x7ef07ebb)-AU1_AF1(a));}
+ AF1 APrxMedRcpF1(AF1 a){AF1 b=AF1_AU1(AU1_(0x7ef19fff)-AU1_AF1(a));return b*(-b*a+AF1_(2.0));}
+ AF1 APrxLoRsqF1(AF1 a){return AF1_AU1(AU1_(0x5f347d74)-(AU1_AF1(a)>>AU1_(1)));}
+//------------------------------------------------------------------------------------------------------------------------------
+ AF2 APrxLoSqrtF2(AF2 a){return AF2_AU2((AU2_AF2(a)>>AU2_(1))+AU2_(0x1fbc4639));}
+ AF2 APrxLoRcpF2(AF2 a){return AF2_AU2(AU2_(0x7ef07ebb)-AU2_AF2(a));}
+ AF2 APrxMedRcpF2(AF2 a){AF2 b=AF2_AU2(AU2_(0x7ef19fff)-AU2_AF2(a));return b*(-b*a+AF2_(2.0));}
+ AF2 APrxLoRsqF2(AF2 a){return AF2_AU2(AU2_(0x5f347d74)-(AU2_AF2(a)>>AU2_(1)));}
+//------------------------------------------------------------------------------------------------------------------------------
+ AF3 APrxLoSqrtF3(AF3 a){return AF3_AU3((AU3_AF3(a)>>AU3_(1))+AU3_(0x1fbc4639));}
+ AF3 APrxLoRcpF3(AF3 a){return AF3_AU3(AU3_(0x7ef07ebb)-AU3_AF3(a));}
+ AF3 APrxMedRcpF3(AF3 a){AF3 b=AF3_AU3(AU3_(0x7ef19fff)-AU3_AF3(a));return b*(-b*a+AF3_(2.0));}
+ AF3 APrxLoRsqF3(AF3 a){return AF3_AU3(AU3_(0x5f347d74)-(AU3_AF3(a)>>AU3_(1)));}
+//------------------------------------------------------------------------------------------------------------------------------
+ AF4 APrxLoSqrtF4(AF4 a){return AF4_AU4((AU4_AF4(a)>>AU4_(1))+AU4_(0x1fbc4639));}
+ AF4 APrxLoRcpF4(AF4 a){return AF4_AU4(AU4_(0x7ef07ebb)-AU4_AF4(a));}
+ AF4 APrxMedRcpF4(AF4 a){AF4 b=AF4_AU4(AU4_(0x7ef19fff)-AU4_AF4(a));return b*(-b*a+AF4_(2.0));}
+ AF4 APrxLoRsqF4(AF4 a){return AF4_AU4(AU4_(0x5f347d74)-(AU4_AF4(a)>>AU4_(1)));}
+////////////////////////////////////////////////////////////////////////////////////////////////////////////////////////////////
+////////////////////////////////////////////////////////////////////////////////////////////////////////////////////////////////
+//_____________________________________________________________/\_______________________________________________________________
+//==============================================================================================================================
+//                                                    PQ APPROXIMATIONS
+//------------------------------------------------------------------------------------------------------------------------------
+// PQ is very close to x^(1/8). The functions below Use the fast float approximation method to do
+// PQ<~>Gamma2 (4th power and fast 4th root) and PQ<~>Linear (8th power and fast 8th root). Maximum error is ~0.2%.
+//==============================================================================================================================
+// Helpers
+ AF1 Quart(AF1 a) { a = a * a; return a * a;}
+ AF1 Oct(AF1 a) { a = a * a; a = a * a; return a * a; }
+ AF2 Quart(AF2 a) { a = a * a; return a * a; }
+ AF2 Oct(AF2 a) { a = a * a; a = a * a; return a * a; }
+ AF3 Quart(AF3 a) { a = a * a; return a * a; }
+ AF3 Oct(AF3 a) { a = a * a; a = a * a; return a * a; }
+ AF4 Quart(AF4 a) { a = a * a; return a * a; }
+ AF4 Oct(AF4 a) { a = a * a; a = a * a; return a * a; }
+ //------------------------------------------------------------------------------------------------------------------------------
+ AF1 APrxPQToGamma2(AF1 a) { return Quart(a); }
+ AF1 APrxPQToLinear(AF1 a) { return Oct(a); }
+ AF1 APrxLoGamma2ToPQ(AF1 a) { return AF1_AU1((AU1_AF1(a) >> AU1_(2)) + AU1_(0x2F9A4E46)); }
+ AF1 APrxMedGamma2ToPQ(AF1 a) { AF1 b = AF1_AU1((AU1_AF1(a) >> AU1_(2)) + AU1_(0x2F9A4E46)); AF1 b4 = Quart(b); return b - b * (b4 - a) / (AF1_(4.0) * b4); }
+ AF1 APrxHighGamma2ToPQ(AF1 a) { return sqrt(sqrt(a)); }
+ AF1 APrxLoLinearToPQ(AF1 a) { return AF1_AU1((AU1_AF1(a) >> AU1_(3)) + AU1_(0x378D8723)); }
+ AF1 APrxMedLinearToPQ(AF1 a) { AF1 b = AF1_AU1((AU1_AF1(a) >> AU1_(3)) + AU1_(0x378D8723)); AF1 b8 = Oct(b); return b - b * (b8 - a) / (AF1_(8.0) * b8); }
+ AF1 APrxHighLinearToPQ(AF1 a) { return sqrt(sqrt(sqrt(a))); }
+ //------------------------------------------------------------------------------------------------------------------------------
+ AF2 APrxPQToGamma2(AF2 a) { return Quart(a); }
+ AF2 APrxPQToLinear(AF2 a) { return Oct(a); }
+ AF2 APrxLoGamma2ToPQ(AF2 a) { return AF2_AU2((AU2_AF2(a) >> AU2_(2)) + AU2_(0x2F9A4E46)); }
+ AF2 APrxMedGamma2ToPQ(AF2 a) { AF2 b = AF2_AU2((AU2_AF2(a) >> AU2_(2)) + AU2_(0x2F9A4E46)); AF2 b4 = Quart(b); return b - b * (b4 - a) / (AF1_(4.0) * b4); }
+ AF2 APrxHighGamma2ToPQ(AF2 a) { return sqrt(sqrt(a)); }
+ AF2 APrxLoLinearToPQ(AF2 a) { return AF2_AU2((AU2_AF2(a) >> AU2_(3)) + AU2_(0x378D8723)); }
+ AF2 APrxMedLinearToPQ(AF2 a) { AF2 b = AF2_AU2((AU2_AF2(a) >> AU2_(3)) + AU2_(0x378D8723)); AF2 b8 = Oct(b); return b - b * (b8 - a) / (AF1_(8.0) * b8); }
+ AF2 APrxHighLinearToPQ(AF2 a) { return sqrt(sqrt(sqrt(a))); }
+ //------------------------------------------------------------------------------------------------------------------------------
+ AF3 APrxPQToGamma2(AF3 a) { return Quart(a); }
+ AF3 APrxPQToLinear(AF3 a) { return Oct(a); }
+ AF3 APrxLoGamma2ToPQ(AF3 a) { return AF3_AU3((AU3_AF3(a) >> AU3_(2)) + AU3_(0x2F9A4E46)); }
+ AF3 APrxMedGamma2ToPQ(AF3 a) { AF3 b = AF3_AU3((AU3_AF3(a) >> AU3_(2)) + AU3_(0x2F9A4E46)); AF3 b4 = Quart(b); return b - b * (b4 - a) / (AF1_(4.0) * b4); }
+ AF3 APrxHighGamma2ToPQ(AF3 a) { return sqrt(sqrt(a)); }
+ AF3 APrxLoLinearToPQ(AF3 a) { return AF3_AU3((AU3_AF3(a) >> AU3_(3)) + AU3_(0x378D8723)); }
+ AF3 APrxMedLinearToPQ(AF3 a) { AF3 b = AF3_AU3((AU3_AF3(a) >> AU3_(3)) + AU3_(0x378D8723)); AF3 b8 = Oct(b); return b - b * (b8 - a) / (AF1_(8.0) * b8); }
+ AF3 APrxHighLinearToPQ(AF3 a) { return sqrt(sqrt(sqrt(a))); }
+ //------------------------------------------------------------------------------------------------------------------------------
+ AF4 APrxPQToGamma2(AF4 a) { return Quart(a); }
+ AF4 APrxPQToLinear(AF4 a) { return Oct(a); }
+ AF4 APrxLoGamma2ToPQ(AF4 a) { return AF4_AU4((AU4_AF4(a) >> AU4_(2)) + AU4_(0x2F9A4E46)); }
+ AF4 APrxMedGamma2ToPQ(AF4 a) { AF4 b = AF4_AU4((AU4_AF4(a) >> AU4_(2)) + AU4_(0x2F9A4E46)); AF4 b4 = Quart(b); return b - b * (b4 - a) / (AF1_(4.0) * b4); }
+ AF4 APrxHighGamma2ToPQ(AF4 a) { return sqrt(sqrt(a)); }
+ AF4 APrxLoLinearToPQ(AF4 a) { return AF4_AU4((AU4_AF4(a) >> AU4_(3)) + AU4_(0x378D8723)); }
+ AF4 APrxMedLinearToPQ(AF4 a) { AF4 b = AF4_AU4((AU4_AF4(a) >> AU4_(3)) + AU4_(0x378D8723)); AF4 b8 = Oct(b); return b - b * (b8 - a) / (AF1_(8.0) * b8); }
+ AF4 APrxHighLinearToPQ(AF4 a) { return sqrt(sqrt(sqrt(a))); }
+////////////////////////////////////////////////////////////////////////////////////////////////////////////////////////////////
+////////////////////////////////////////////////////////////////////////////////////////////////////////////////////////////////
+//_____________________________________________________________/\_______________________________________________________________
+//==============================================================================================================================
+//                                                    PARABOLIC SIN & COS
+//------------------------------------------------------------------------------------------------------------------------------
+// Approximate answers to transcendental questions.
+//------------------------------------------------------------------------------------------------------------------------------
+//==============================================================================================================================
+ #if 1
+  // Valid input range is {-1 to 1} representing {0 to 2 pi}.
+  // Output range is {-1/4 to 1/4} representing {-1 to 1}.
+  AF1 APSinF1(AF1 x){return x*abs(x)-x;} // MAD.
+  AF2 APSinF2(AF2 x){return x*abs(x)-x;}
+  AF1 APCosF1(AF1 x){x=AFractF1(x*AF1_(0.5)+AF1_(0.75));x=x*AF1_(2.0)-AF1_(1.0);return APSinF1(x);} // 3x MAD, FRACT
+  AF2 APCosF2(AF2 x){x=AFractF2(x*AF2_(0.5)+AF2_(0.75));x=x*AF2_(2.0)-AF2_(1.0);return APSinF2(x);}
+  AF2 APSinCosF1(AF1 x){AF1 y=AFractF1(x*AF1_(0.5)+AF1_(0.75));y=y*AF1_(2.0)-AF1_(1.0);return APSinF2(AF2(x,y));}
+ #endif
+////////////////////////////////////////////////////////////////////////////////////////////////////////////////////////////////
+////////////////////////////////////////////////////////////////////////////////////////////////////////////////////////////////
+//_____________________________________________________________/\_______________________________________________________________
+//==============================================================================================================================
+//                                                     [ZOL] ZERO ONE LOGIC
+//------------------------------------------------------------------------------------------------------------------------------
+// Conditional free logic designed for easy 16-bit packing, and backwards porting to 32-bit.
+//------------------------------------------------------------------------------------------------------------------------------
+// 0 := false
+// 1 := true
+//------------------------------------------------------------------------------------------------------------------------------
+// AndNot(x,y)   -> !(x&y) .... One op.
+// AndOr(x,y,z)  -> (x&y)|z ... One op.
+// GtZero(x)     -> x>0.0 ..... One op.
+// Sel(x,y,z)    -> x?y:z ..... Two ops, has no precision loss.
+// Signed(x)     -> x<0.0 ..... One op.
+// ZeroPass(x,y) -> x?0:y ..... Two ops, 'y' is a pass through safe for aliasing as integer.
+//------------------------------------------------------------------------------------------------------------------------------
+// OPTIMIZATION NOTES
+// ==================
+// - On Vega to use 2 constants in a packed op, pass in as one AW2 or one AH2 'k.xy' and use as 'k.xx' and 'k.yy'.
+//   For example 'a.xy*k.xx+k.yy'.
+//==============================================================================================================================
+ #if 1
+  AU1 AZolAndU1(AU1 x,AU1 y){return min(x,y);}
+  AU2 AZolAndU2(AU2 x,AU2 y){return min(x,y);}
+  AU3 AZolAndU3(AU3 x,AU3 y){return min(x,y);}
+  AU4 AZolAndU4(AU4 x,AU4 y){return min(x,y);}
+//------------------------------------------------------------------------------------------------------------------------------
+  AU1 AZolNotU1(AU1 x){return x^AU1_(1);}
+  AU2 AZolNotU2(AU2 x){return x^AU2_(1);}
+  AU3 AZolNotU3(AU3 x){return x^AU3_(1);}
+  AU4 AZolNotU4(AU4 x){return x^AU4_(1);}
+//------------------------------------------------------------------------------------------------------------------------------
+  AU1 AZolOrU1(AU1 x,AU1 y){return max(x,y);}
+  AU2 AZolOrU2(AU2 x,AU2 y){return max(x,y);}
+  AU3 AZolOrU3(AU3 x,AU3 y){return max(x,y);}
+  AU4 AZolOrU4(AU4 x,AU4 y){return max(x,y);}
+//==============================================================================================================================
+  AU1 AZolF1ToU1(AF1 x){return AU1(x);}
+  AU2 AZolF2ToU2(AF2 x){return AU2(x);}
+  AU3 AZolF3ToU3(AF3 x){return AU3(x);}
+  AU4 AZolF4ToU4(AF4 x){return AU4(x);}
+//------------------------------------------------------------------------------------------------------------------------------
+  // 2 ops, denormals don't work in 32-bit on PC (and if they are enabled, OMOD is disabled).
+  AU1 AZolNotF1ToU1(AF1 x){return AU1(AF1_(1.0)-x);}
+  AU2 AZolNotF2ToU2(AF2 x){return AU2(AF2_(1.0)-x);}
+  AU3 AZolNotF3ToU3(AF3 x){return AU3(AF3_(1.0)-x);}
+  AU4 AZolNotF4ToU4(AF4 x){return AU4(AF4_(1.0)-x);}
+//------------------------------------------------------------------------------------------------------------------------------
+  AF1 AZolU1ToF1(AU1 x){return AF1(x);}
+  AF2 AZolU2ToF2(AU2 x){return AF2(x);}
+  AF3 AZolU3ToF3(AU3 x){return AF3(x);}
+  AF4 AZolU4ToF4(AU4 x){return AF4(x);}
+//==============================================================================================================================
+  AF1 AZolAndF1(AF1 x,AF1 y){return min(x,y);}
+  AF2 AZolAndF2(AF2 x,AF2 y){return min(x,y);}
+  AF3 AZolAndF3(AF3 x,AF3 y){return min(x,y);}
+  AF4 AZolAndF4(AF4 x,AF4 y){return min(x,y);}
+//------------------------------------------------------------------------------------------------------------------------------
+  AF1 ASolAndNotF1(AF1 x,AF1 y){return (-x)*y+AF1_(1.0);}
+  AF2 ASolAndNotF2(AF2 x,AF2 y){return (-x)*y+AF2_(1.0);}
+  AF3 ASolAndNotF3(AF3 x,AF3 y){return (-x)*y+AF3_(1.0);}
+  AF4 ASolAndNotF4(AF4 x,AF4 y){return (-x)*y+AF4_(1.0);}
+//------------------------------------------------------------------------------------------------------------------------------
+  AF1 AZolAndOrF1(AF1 x,AF1 y,AF1 z){return ASatF1(x*y+z);}
+  AF2 AZolAndOrF2(AF2 x,AF2 y,AF2 z){return ASatF2(x*y+z);}
+  AF3 AZolAndOrF3(AF3 x,AF3 y,AF3 z){return ASatF3(x*y+z);}
+  AF4 AZolAndOrF4(AF4 x,AF4 y,AF4 z){return ASatF4(x*y+z);}
+//------------------------------------------------------------------------------------------------------------------------------
+  AF1 AZolGtZeroF1(AF1 x){return ASatF1(x*AF1_(A_INFP_F));}
+  AF2 AZolGtZeroF2(AF2 x){return ASatF2(x*AF2_(A_INFP_F));}
+  AF3 AZolGtZeroF3(AF3 x){return ASatF3(x*AF3_(A_INFP_F));}
+  AF4 AZolGtZeroF4(AF4 x){return ASatF4(x*AF4_(A_INFP_F));}
+//------------------------------------------------------------------------------------------------------------------------------
+  AF1 AZolNotF1(AF1 x){return AF1_(1.0)-x;}
+  AF2 AZolNotF2(AF2 x){return AF2_(1.0)-x;}
+  AF3 AZolNotF3(AF3 x){return AF3_(1.0)-x;}
+  AF4 AZolNotF4(AF4 x){return AF4_(1.0)-x;}
+//------------------------------------------------------------------------------------------------------------------------------
+  AF1 AZolOrF1(AF1 x,AF1 y){return max(x,y);}
+  AF2 AZolOrF2(AF2 x,AF2 y){return max(x,y);}
+  AF3 AZolOrF3(AF3 x,AF3 y){return max(x,y);}
+  AF4 AZolOrF4(AF4 x,AF4 y){return max(x,y);}
+//------------------------------------------------------------------------------------------------------------------------------
+  AF1 AZolSelF1(AF1 x,AF1 y,AF1 z){AF1 r=(-x)*z+z;return x*y+r;}
+  AF2 AZolSelF2(AF2 x,AF2 y,AF2 z){AF2 r=(-x)*z+z;return x*y+r;}
+  AF3 AZolSelF3(AF3 x,AF3 y,AF3 z){AF3 r=(-x)*z+z;return x*y+r;}
+  AF4 AZolSelF4(AF4 x,AF4 y,AF4 z){AF4 r=(-x)*z+z;return x*y+r;}
+//------------------------------------------------------------------------------------------------------------------------------
+  AF1 AZolSignedF1(AF1 x){return ASatF1(x*AF1_(A_INFN_F));}
+  AF2 AZolSignedF2(AF2 x){return ASatF2(x*AF2_(A_INFN_F));}
+  AF3 AZolSignedF3(AF3 x){return ASatF3(x*AF3_(A_INFN_F));}
+  AF4 AZolSignedF4(AF4 x){return ASatF4(x*AF4_(A_INFN_F));}
+//------------------------------------------------------------------------------------------------------------------------------
+  AF1 AZolZeroPassF1(AF1 x,AF1 y){return AF1_AU1((AU1_AF1(x)!=AU1_(0))?AU1_(0):AU1_AF1(y));}
+  AF2 AZolZeroPassF2(AF2 x,AF2 y){return AF2_AU2((AU2_AF2(x)!=AU2_(0))?AU2_(0):AU2_AF2(y));}
+  AF3 AZolZeroPassF3(AF3 x,AF3 y){return AF3_AU3((AU3_AF3(x)!=AU3_(0))?AU3_(0):AU3_AF3(y));}
+  AF4 AZolZeroPassF4(AF4 x,AF4 y){return AF4_AU4((AU4_AF4(x)!=AU4_(0))?AU4_(0):AU4_AF4(y));}
+ #endif
+////////////////////////////////////////////////////////////////////////////////////////////////////////////////////////////////
+////////////////////////////////////////////////////////////////////////////////////////////////////////////////////////////////
+//_____________________________________________________________/\_______________________________________________________________
+//==============================================================================================================================
+//                                                      COLOR CONVERSIONS
+//------------------------------------------------------------------------------------------------------------------------------
+// These are all linear to/from some other space (where 'linear' has been shortened out of the function name).
+// So 'ToGamma' is 'LinearToGamma', and 'FromGamma' is 'LinearFromGamma'.
+// These are branch free implementations.
+// The AToSrgbF1() function is useful for stores for compute shaders for GPUs without hardware linear->sRGB store conversion.
+//------------------------------------------------------------------------------------------------------------------------------
+// TRANSFER FUNCTIONS
+// ==================
+// 709 ..... Rec709 used for some HDTVs
+// Gamma ... Typically 2.2 for some PC displays, or 2.4-2.5 for CRTs, or 2.2 FreeSync2 native
+// Pq ...... PQ native for HDR10
+// Srgb .... The sRGB output, typical of PC displays, useful for 10-bit output, or storing to 8-bit UNORM without SRGB type
+// Two ..... Gamma 2.0, fastest conversion (useful for intermediate pass approximations)
+// Three ... Gamma 3.0, less fast, but good for HDR.
+//------------------------------------------------------------------------------------------------------------------------------
+// KEEPING TO SPEC
+// ===============
+// Both Rec.709 and sRGB have a linear segment which as spec'ed would intersect the curved segment 2 times.
+//  (a.) For 8-bit sRGB, steps {0 to 10.3} are in the linear region (4% of the encoding range).
+//  (b.) For 8-bit  709, steps {0 to 20.7} are in the linear region (8% of the encoding range).
+// Also there is a slight step in the transition regions.
+// Precision of the coefficients in the spec being the likely cause.
+// Main usage case of the sRGB code is to do the linear->sRGB converstion in a compute shader before store.
+// This is to work around lack of hardware (typically only ROP does the conversion for free).
+// To "correct" the linear segment, would be to introduce error, because hardware decode of sRGB->linear is fixed (and free).
+// So this header keeps with the spec.
+// For linear->sRGB transforms, the linear segment in some respects reduces error, because rounding in that region is linear.
+// Rounding in the curved region in hardware (and fast software code) introduces error due to rounding in non-linear.
+//------------------------------------------------------------------------------------------------------------------------------
+// FOR PQ
+// ======
+// Both input and output is {0.0-1.0}, and where output 1.0 represents 10000.0 cd/m^2.
+// All constants are only specified to FP32 precision.
+// External PQ source reference,
+//  - https://github.com/ampas/aces-dev/blob/master/transforms/ctl/utilities/ACESlib.Utilities_Color.a1.0.1.ctl
+//------------------------------------------------------------------------------------------------------------------------------
+// PACKED VERSIONS
+// ===============
+// These are the A*H2() functions.
+// There is no PQ functions as FP16 seemed to not have enough precision for the conversion.
+// The remaining functions are "good enough" for 8-bit, and maybe 10-bit if not concerned about a few 1-bit errors.
+// Precision is lowest in the 709 conversion, higher in sRGB, higher still in Two and Gamma (when using 2.2 at least).
+//------------------------------------------------------------------------------------------------------------------------------
+// NOTES
+// =====
+// Could be faster for PQ conversions to be in ALU or a texture lookup depending on usage case.
+//==============================================================================================================================
+ #if 1
+  AF1 ATo709F1(AF1 c){AF3 j=AF3(0.018*4.5,4.5,0.45);AF2 k=AF2(1.099,-0.099);
+   return clamp(j.x  ,c*j.y  ,pow(c,j.z  )*k.x  +k.y  );}
+  AF2 ATo709F2(AF2 c){AF3 j=AF3(0.018*4.5,4.5,0.45);AF2 k=AF2(1.099,-0.099);
+   return clamp(j.xx ,c*j.yy ,pow(c,j.zz )*k.xx +k.yy );}
+  AF3 ATo709F3(AF3 c){AF3 j=AF3(0.018*4.5,4.5,0.45);AF2 k=AF2(1.099,-0.099);
+   return clamp(j.xxx,c*j.yyy,pow(c,j.zzz)*k.xxx+k.yyy);}
+//------------------------------------------------------------------------------------------------------------------------------
+  // Note 'rcpX' is '1/x', where the 'x' is what would be used in AFromGamma().
+  AF1 AToGammaF1(AF1 c,AF1 rcpX){return pow(c,AF1_(rcpX));}
+  AF2 AToGammaF2(AF2 c,AF1 rcpX){return pow(c,AF2_(rcpX));}
+  AF3 AToGammaF3(AF3 c,AF1 rcpX){return pow(c,AF3_(rcpX));}
+//------------------------------------------------------------------------------------------------------------------------------
+  AF1 AToPqF1(AF1 x){AF1 p=pow(x,AF1_(0.159302));
+   return pow((AF1_(0.835938)+AF1_(18.8516)*p)/(AF1_(1.0)+AF1_(18.6875)*p),AF1_(78.8438));}
+  AF2 AToPqF1(AF2 x){AF2 p=pow(x,AF2_(0.159302));
+   return pow((AF2_(0.835938)+AF2_(18.8516)*p)/(AF2_(1.0)+AF2_(18.6875)*p),AF2_(78.8438));}
+  AF3 AToPqF1(AF3 x){AF3 p=pow(x,AF3_(0.159302));
+   return pow((AF3_(0.835938)+AF3_(18.8516)*p)/(AF3_(1.0)+AF3_(18.6875)*p),AF3_(78.8438));}
+//------------------------------------------------------------------------------------------------------------------------------
+  AF1 AToSrgbF1(AF1 c){AF3 j=AF3(0.0031308*12.92,12.92,1.0/2.4);AF2 k=AF2(1.055,-0.055);
+   return clamp(j.x  ,c*j.y  ,pow(c,j.z  )*k.x  +k.y  );}
+  AF2 AToSrgbF2(AF2 c){AF3 j=AF3(0.0031308*12.92,12.92,1.0/2.4);AF2 k=AF2(1.055,-0.055);
+   return clamp(j.xx ,c*j.yy ,pow(c,j.zz )*k.xx +k.yy );}
+  AF3 AToSrgbF3(AF3 c){AF3 j=AF3(0.0031308*12.92,12.92,1.0/2.4);AF2 k=AF2(1.055,-0.055);
+   return clamp(j.xxx,c*j.yyy,pow(c,j.zzz)*k.xxx+k.yyy);}
+//------------------------------------------------------------------------------------------------------------------------------
+  AF1 AToTwoF1(AF1 c){return sqrt(c);}
+  AF2 AToTwoF2(AF2 c){return sqrt(c);}
+  AF3 AToTwoF3(AF3 c){return sqrt(c);}
+//------------------------------------------------------------------------------------------------------------------------------
+  AF1 AToThreeF1(AF1 c){return pow(c,AF1_(1.0/3.0));}
+  AF2 AToThreeF2(AF2 c){return pow(c,AF2_(1.0/3.0));}
+  AF3 AToThreeF3(AF3 c){return pow(c,AF3_(1.0/3.0));}
+ #endif
+//==============================================================================================================================
+ #if 1
+  // Unfortunately median won't work here.
+  AF1 AFrom709F1(AF1 c){AF3 j=AF3(0.081/4.5,1.0/4.5,1.0/0.45);AF2 k=AF2(1.0/1.099,0.099/1.099);
+   return AZolSelF1(AZolSignedF1(c-j.x  ),c*j.y  ,pow(c*k.x  +k.y  ,j.z  ));}
+  AF2 AFrom709F2(AF2 c){AF3 j=AF3(0.081/4.5,1.0/4.5,1.0/0.45);AF2 k=AF2(1.0/1.099,0.099/1.099);
+   return AZolSelF2(AZolSignedF2(c-j.xx ),c*j.yy ,pow(c*k.xx +k.yy ,j.zz ));}
+  AF3 AFrom709F3(AF3 c){AF3 j=AF3(0.081/4.5,1.0/4.5,1.0/0.45);AF2 k=AF2(1.0/1.099,0.099/1.099);
+   return AZolSelF3(AZolSignedF3(c-j.xxx),c*j.yyy,pow(c*k.xxx+k.yyy,j.zzz));}
+//------------------------------------------------------------------------------------------------------------------------------
+  AF1 AFromGammaF1(AF1 c,AF1 x){return pow(c,AF1_(x));}
+  AF2 AFromGammaF2(AF2 c,AF1 x){return pow(c,AF2_(x));}
+  AF3 AFromGammaF3(AF3 c,AF1 x){return pow(c,AF3_(x));}
+//------------------------------------------------------------------------------------------------------------------------------
+  AF1 AFromPqF1(AF1 x){AF1 p=pow(x,AF1_(0.0126833));
+   return pow(ASatF1(p-AF1_(0.835938))/(AF1_(18.8516)-AF1_(18.6875)*p),AF1_(6.27739));}
+  AF2 AFromPqF1(AF2 x){AF2 p=pow(x,AF2_(0.0126833));
+   return pow(ASatF2(p-AF2_(0.835938))/(AF2_(18.8516)-AF2_(18.6875)*p),AF2_(6.27739));}
+  AF3 AFromPqF1(AF3 x){AF3 p=pow(x,AF3_(0.0126833));
+   return pow(ASatF3(p-AF3_(0.835938))/(AF3_(18.8516)-AF3_(18.6875)*p),AF3_(6.27739));}
+//------------------------------------------------------------------------------------------------------------------------------
+  // Unfortunately median won't work here.
+  AF1 AFromSrgbF1(AF1 c){AF3 j=AF3(0.04045/12.92,1.0/12.92,2.4);AF2 k=AF2(1.0/1.055,0.055/1.055);
+   return AZolSelF1(AZolSignedF1(c-j.x  ),c*j.y  ,pow(c*k.x  +k.y  ,j.z  ));}
+  AF2 AFromSrgbF2(AF2 c){AF3 j=AF3(0.04045/12.92,1.0/12.92,2.4);AF2 k=AF2(1.0/1.055,0.055/1.055);
+   return AZolSelF2(AZolSignedF2(c-j.xx ),c*j.yy ,pow(c*k.xx +k.yy ,j.zz ));}
+  AF3 AFromSrgbF3(AF3 c){AF3 j=AF3(0.04045/12.92,1.0/12.92,2.4);AF2 k=AF2(1.0/1.055,0.055/1.055);
+   return AZolSelF3(AZolSignedF3(c-j.xxx),c*j.yyy,pow(c*k.xxx+k.yyy,j.zzz));}
+//------------------------------------------------------------------------------------------------------------------------------
+  AF1 AFromTwoF1(AF1 c){return c*c;}
+  AF2 AFromTwoF2(AF2 c){return c*c;}
+  AF3 AFromTwoF3(AF3 c){return c*c;}
+//------------------------------------------------------------------------------------------------------------------------------
+  AF1 AFromThreeF1(AF1 c){return c*c*c;}
+  AF2 AFromThreeF2(AF2 c){return c*c*c;}
+  AF3 AFromThreeF3(AF3 c){return c*c*c;}
+ #endif
+//==============================================================================================================================
+////////////////////////////////////////////////////////////////////////////////////////////////////////////////////////////////
+////////////////////////////////////////////////////////////////////////////////////////////////////////////////////////////////
+//_____________________________________________________________/\_______________________________________________________________
+//==============================================================================================================================
+//                                                          CS REMAP
+//==============================================================================================================================
+ // Simple remap 64x1 to 8x8 with rotated 2x2 pixel quads in quad linear.
+ //  543210
+ //  ======
+ //  ..xxx.
+ //  yy...y
+ AU2 ARmp8x8(AU1 a){return AU2(ABfe(a,1u,3u),ABfiM(ABfe(a,3u,3u),a,1u));}
+//==============================================================================================================================
+ // More complex remap 64x1 to 8x8 which is necessary for 2D wave reductions.
+ //  543210
+ //  ======
+ //  .xx..x
+ //  y..yy.
+ // Details,
+ //  LANE TO 8x8 MAPPING
+ //  ===================
+ //  00 01 08 09 10 11 18 19
+ //  02 03 0a 0b 12 13 1a 1b
+ //  04 05 0c 0d 14 15 1c 1d
+ //  06 07 0e 0f 16 17 1e 1f
+ //  20 21 28 29 30 31 38 39
+ //  22 23 2a 2b 32 33 3a 3b
+ //  24 25 2c 2d 34 35 3c 3d
+ //  26 27 2e 2f 36 37 3e 3f
+ AU2 ARmpRed8x8(AU1 a){return AU2(ABfiM(ABfe(a,2u,3u),a,1u),ABfiM(ABfe(a,3u,3u),ABfe(a,1u,2u),2u));}
+//==============================================================================================================================
+#endif
+////////////////////////////////////////////////////////////////////////////////////////////////////////////////////////////////
+////////////////////////////////////////////////////////////////////////////////////////////////////////////////////////////////
+////////////////////////////////////////////////////////////////////////////////////////////////////////////////////////////////
+////////////////////////////////////////////////////////////////////////////////////////////////////////////////////////////////
+//_____________________________________________________________/\_______________________________________________________________
+//==============================================================================================================================
+//
+//                                                          REFERENCE
+//
+//------------------------------------------------------------------------------------------------------------------------------
+// IEEE FLOAT RULES
+// ================
+//  - saturate(NaN)=0, saturate(-INF)=0, saturate(+INF)=1
+//  - {+/-}0 * {+/-}INF = NaN
+//  - -INF + (+INF) = NaN
+//  - {+/-}0 / {+/-}0 = NaN
+//  - {+/-}INF / {+/-}INF = NaN
+//  - a<(-0) := sqrt(a) = NaN (a=-0.0 won't NaN)
+//  - 0 == -0
+//  - 4/0 = +INF
+//  - 4/-0 = -INF
+//  - 4+INF = +INF
+//  - 4-INF = -INF
+//  - 4*(+INF) = +INF
+//  - 4*(-INF) = -INF
+//  - -4*(+INF) = -INF
+//  - sqrt(+INF) = +INF
+//------------------------------------------------------------------------------------------------------------------------------
+// FP16 ENCODING
+// =============
+// fedcba9876543210
+// ----------------
+// ......mmmmmmmmmm  10-bit mantissa (encodes 11-bit 0.5 to 1.0 except for denormals)
+// .eeeee..........  5-bit exponent
+// .00000..........  denormals
+// .00001..........  -14 exponent
+// .11110..........   15 exponent
+// .111110000000000  infinity
+// .11111nnnnnnnnnn  NaN with n!=0
+// s...............  sign
+//------------------------------------------------------------------------------------------------------------------------------
+// FP16/INT16 ALIASING DENORMAL
+// ============================
+// 11-bit unsigned integers alias with half float denormal/normal values,
+//     1 = 2^(-24) = 1/16777216 ....................... first denormal value
+//     2 = 2^(-23)
+//   ...
+//  1023 = 2^(-14)*(1-2^(-10)) = 2^(-14)*(1-1/1024) ... last denormal value
+//  1024 = 2^(-14) = 1/16384 .......................... first normal value that still maps to integers
+//  2047 .............................................. last normal value that still maps to integers
+// Scaling limits,
+//  2^15 = 32768 ...................................... largest power of 2 scaling
+// Largest pow2 conversion mapping is at *32768,
+//     1 : 2^(-9) = 1/512
+//     2 : 1/256
+//     4 : 1/128
+//     8 : 1/64
+//    16 : 1/32
+//    32 : 1/16
+//    64 : 1/8
+//   128 : 1/4
+//   256 : 1/2
+//   512 : 1
+//  1024 : 2
+//  2047 : a little less than 4
+//==============================================================================================================================
+////////////////////////////////////////////////////////////////////////////////////////////////////////////////////////////////
+////////////////////////////////////////////////////////////////////////////////////////////////////////////////////////////////
+////////////////////////////////////////////////////////////////////////////////////////////////////////////////////////////////
+////////////////////////////////////////////////////////////////////////////////////////////////////////////////////////////////
+////////////////////////////////////////////////////////////////////////////////////////////////////////////////////////////////
+////////////////////////////////////////////////////////////////////////////////////////////////////////////////////////////////
+//_____________________________________________________________/\_______________________________________________________________
+//==============================================================================================================================
+//
+//
+//                                                     GPU/CPU PORTABILITY
+//
+//
+//------------------------------------------------------------------------------------------------------------------------------
+// This is the GPU implementation.
+// See the CPU implementation for docs.
+//==============================================================================================================================
+#ifdef A_GPU
+ #define A_TRUE true
+ #define A_FALSE false
+ #define A_STATIC
+////////////////////////////////////////////////////////////////////////////////////////////////////////////////////////////////
+////////////////////////////////////////////////////////////////////////////////////////////////////////////////////////////////
+//_____________________________________________________________/\_______________________________________________________________
+//==============================================================================================================================
+//                                     VECTOR ARGUMENT/RETURN/INITIALIZATION PORTABILITY
+//==============================================================================================================================
+ #define retAD2 AD2
+ #define retAD3 AD3
+ #define retAD4 AD4
+ #define retAF2 AF2
+ #define retAF3 AF3
+ #define retAF4 AF4
+ #define retAL2 AL2
+ #define retAL3 AL3
+ #define retAL4 AL4
+ #define retAU2 AU2
+ #define retAU3 AU3
+ #define retAU4 AU4
+//------------------------------------------------------------------------------------------------------------------------------
+ #define inAD2 in AD2
+ #define inAD3 in AD3
+ #define inAD4 in AD4
+ #define inAF2 in AF2
+ #define inAF3 in AF3
+ #define inAF4 in AF4
+ #define inAL2 in AL2
+ #define inAL3 in AL3
+ #define inAL4 in AL4
+ #define inAU2 in AU2
+ #define inAU3 in AU3
+ #define inAU4 in AU4
+//------------------------------------------------------------------------------------------------------------------------------
+ #define inoutAD2 inout AD2
+ #define inoutAD3 inout AD3
+ #define inoutAD4 inout AD4
+ #define inoutAF2 inout AF2
+ #define inoutAF3 inout AF3
+ #define inoutAF4 inout AF4
+ #define inoutAL2 inout AL2
+ #define inoutAL3 inout AL3
+ #define inoutAL4 inout AL4
+ #define inoutAU2 inout AU2
+ #define inoutAU3 inout AU3
+ #define inoutAU4 inout AU4
+//------------------------------------------------------------------------------------------------------------------------------
+ #define outAD2 out AD2
+ #define outAD3 out AD3
+ #define outAD4 out AD4
+ #define outAF2 out AF2
+ #define outAF3 out AF3
+ #define outAF4 out AF4
+ #define outAL2 out AL2
+ #define outAL3 out AL3
+ #define outAL4 out AL4
+ #define outAU2 out AU2
+ #define outAU3 out AU3
+ #define outAU4 out AU4
+//------------------------------------------------------------------------------------------------------------------------------
+ #define varAD2(x) AD2 x
+ #define varAD3(x) AD3 x
+ #define varAD4(x) AD4 x
+ #define varAF2(x) AF2 x
+ #define varAF3(x) AF3 x
+ #define varAF4(x) AF4 x
+ #define varAL2(x) AL2 x
+ #define varAL3(x) AL3 x
+ #define varAL4(x) AL4 x
+ #define varAU2(x) AU2 x
+ #define varAU3(x) AU3 x
+ #define varAU4(x) AU4 x
+//------------------------------------------------------------------------------------------------------------------------------
+ #define initAD2(x,y) AD2(x,y)
+ #define initAD3(x,y,z) AD3(x,y,z)
+ #define initAD4(x,y,z,w) AD4(x,y,z,w)
+ #define initAF2(x,y) AF2(x,y)
+ #define initAF3(x,y,z) AF3(x,y,z)
+ #define initAF4(x,y,z,w) AF4(x,y,z,w)
+ #define initAL2(x,y) AL2(x,y)
+ #define initAL3(x,y,z) AL3(x,y,z)
+ #define initAL4(x,y,z,w) AL4(x,y,z,w)
+ #define initAU2(x,y) AU2(x,y)
+ #define initAU3(x,y,z) AU3(x,y,z)
+ #define initAU4(x,y,z,w) AU4(x,y,z,w)
+////////////////////////////////////////////////////////////////////////////////////////////////////////////////////////////////
+////////////////////////////////////////////////////////////////////////////////////////////////////////////////////////////////
+//_____________________________________________________________/\_______________________________________________________________
+//==============================================================================================================================
+//                                                     SCALAR RETURN OPS
+//==============================================================================================================================
+ #define AAbsD1(a) abs(AD1(a))
+ #define AAbsF1(a) abs(AF1(a))
+//------------------------------------------------------------------------------------------------------------------------------
+ #define ACosD1(a) cos(AD1(a))
+ #define ACosF1(a) cos(AF1(a))
+//------------------------------------------------------------------------------------------------------------------------------
+ #define ADotD2(a,b) dot(AD2(a),AD2(b))
+ #define ADotD3(a,b) dot(AD3(a),AD3(b))
+ #define ADotD4(a,b) dot(AD4(a),AD4(b))
+ #define ADotF2(a,b) dot(AF2(a),AF2(b))
+ #define ADotF3(a,b) dot(AF3(a),AF3(b))
+ #define ADotF4(a,b) dot(AF4(a),AF4(b))
+//------------------------------------------------------------------------------------------------------------------------------
+ #define AExp2D1(a) exp2(AD1(a))
+ #define AExp2F1(a) exp2(AF1(a))
+//------------------------------------------------------------------------------------------------------------------------------
+ #define AFloorD1(a) floor(AD1(a))
+ #define AFloorF1(a) floor(AF1(a))
+//------------------------------------------------------------------------------------------------------------------------------
+ #define ALog2D1(a) log2(AD1(a))
+ #define ALog2F1(a) log2(AF1(a))
+//------------------------------------------------------------------------------------------------------------------------------
+ #define AMaxD1(a,b) max(a,b)
+ #define AMaxF1(a,b) max(a,b)
+ #define AMaxL1(a,b) max(a,b)
+ #define AMaxU1(a,b) max(a,b)
+//------------------------------------------------------------------------------------------------------------------------------
+ #define AMinD1(a,b) min(a,b)
+ #define AMinF1(a,b) min(a,b)
+ #define AMinL1(a,b) min(a,b)
+ #define AMinU1(a,b) min(a,b)
+//------------------------------------------------------------------------------------------------------------------------------
+ #define ASinD1(a) sin(AD1(a))
+ #define ASinF1(a) sin(AF1(a))
+//------------------------------------------------------------------------------------------------------------------------------
+ #define ASqrtD1(a) sqrt(AD1(a))
+ #define ASqrtF1(a) sqrt(AF1(a))
+////////////////////////////////////////////////////////////////////////////////////////////////////////////////////////////////
+////////////////////////////////////////////////////////////////////////////////////////////////////////////////////////////////
+//_____________________________________________________________/\_______________________________________________________________
+//==============================================================================================================================
+//                                               SCALAR RETURN OPS - DEPENDENT
+//==============================================================================================================================
+ #define APowD1(a,b) pow(AD1(a),AF1(b))
+ #define APowF1(a,b) pow(AF1(a),AF1(b))
+////////////////////////////////////////////////////////////////////////////////////////////////////////////////////////////////
+////////////////////////////////////////////////////////////////////////////////////////////////////////////////////////////////
+//_____________________________________________________________/\_______________________________________________________________
+//==============================================================================================================================
+//                                                         VECTOR OPS
+//------------------------------------------------------------------------------------------------------------------------------
+// These are added as needed for production or prototyping, so not necessarily a complete set.
+// They follow a convention of taking in a destination and also returning the destination value to increase utility.
+//==============================================================================================================================
+ #ifdef A_DUBL
+  AD2 opAAbsD2(outAD2 d,inAD2 a){d=abs(a);return d;}
+  AD3 opAAbsD3(outAD3 d,inAD3 a){d=abs(a);return d;}
+  AD4 opAAbsD4(outAD4 d,inAD4 a){d=abs(a);return d;}
+//------------------------------------------------------------------------------------------------------------------------------
+  AD2 opAAddD2(outAD2 d,inAD2 a,inAD2 b){d=a+b;return d;}
+  AD3 opAAddD3(outAD3 d,inAD3 a,inAD3 b){d=a+b;return d;}
+  AD4 opAAddD4(outAD4 d,inAD4 a,inAD4 b){d=a+b;return d;}
+//------------------------------------------------------------------------------------------------------------------------------
+  AD2 opAAddOneD2(outAD2 d,inAD2 a,AD1 b){d=a+AD2_(b);return d;}
+  AD3 opAAddOneD3(outAD3 d,inAD3 a,AD1 b){d=a+AD3_(b);return d;}
+  AD4 opAAddOneD4(outAD4 d,inAD4 a,AD1 b){d=a+AD4_(b);return d;}
+//------------------------------------------------------------------------------------------------------------------------------
+  AD2 opACpyD2(outAD2 d,inAD2 a){d=a;return d;}
+  AD3 opACpyD3(outAD3 d,inAD3 a){d=a;return d;}
+  AD4 opACpyD4(outAD4 d,inAD4 a){d=a;return d;}
+//------------------------------------------------------------------------------------------------------------------------------
+  AD2 opALerpD2(outAD2 d,inAD2 a,inAD2 b,inAD2 c){d=ALerpD2(a,b,c);return d;}
+  AD3 opALerpD3(outAD3 d,inAD3 a,inAD3 b,inAD3 c){d=ALerpD3(a,b,c);return d;}
+  AD4 opALerpD4(outAD4 d,inAD4 a,inAD4 b,inAD4 c){d=ALerpD4(a,b,c);return d;}
+//------------------------------------------------------------------------------------------------------------------------------
+  AD2 opALerpOneD2(outAD2 d,inAD2 a,inAD2 b,AD1 c){d=ALerpD2(a,b,AD2_(c));return d;}
+  AD3 opALerpOneD3(outAD3 d,inAD3 a,inAD3 b,AD1 c){d=ALerpD3(a,b,AD3_(c));return d;}
+  AD4 opALerpOneD4(outAD4 d,inAD4 a,inAD4 b,AD1 c){d=ALerpD4(a,b,AD4_(c));return d;}
+//------------------------------------------------------------------------------------------------------------------------------
+  AD2 opAMaxD2(outAD2 d,inAD2 a,inAD2 b){d=max(a,b);return d;}
+  AD3 opAMaxD3(outAD3 d,inAD3 a,inAD3 b){d=max(a,b);return d;}
+  AD4 opAMaxD4(outAD4 d,inAD4 a,inAD4 b){d=max(a,b);return d;}
+//------------------------------------------------------------------------------------------------------------------------------
+  AD2 opAMinD2(outAD2 d,inAD2 a,inAD2 b){d=min(a,b);return d;}
+  AD3 opAMinD3(outAD3 d,inAD3 a,inAD3 b){d=min(a,b);return d;}
+  AD4 opAMinD4(outAD4 d,inAD4 a,inAD4 b){d=min(a,b);return d;}
+//------------------------------------------------------------------------------------------------------------------------------
+  AD2 opAMulD2(outAD2 d,inAD2 a,inAD2 b){d=a*b;return d;}
+  AD3 opAMulD3(outAD3 d,inAD3 a,inAD3 b){d=a*b;return d;}
+  AD4 opAMulD4(outAD4 d,inAD4 a,inAD4 b){d=a*b;return d;}
+//------------------------------------------------------------------------------------------------------------------------------
+  AD2 opAMulOneD2(outAD2 d,inAD2 a,AD1 b){d=a*AD2_(b);return d;}
+  AD3 opAMulOneD3(outAD3 d,inAD3 a,AD1 b){d=a*AD3_(b);return d;}
+  AD4 opAMulOneD4(outAD4 d,inAD4 a,AD1 b){d=a*AD4_(b);return d;}
+//------------------------------------------------------------------------------------------------------------------------------
+  AD2 opANegD2(outAD2 d,inAD2 a){d=-a;return d;}
+  AD3 opANegD3(outAD3 d,inAD3 a){d=-a;return d;}
+  AD4 opANegD4(outAD4 d,inAD4 a){d=-a;return d;}
+//------------------------------------------------------------------------------------------------------------------------------
+  AD2 opARcpD2(outAD2 d,inAD2 a){d=ARcpD2(a);return d;}
+  AD3 opARcpD3(outAD3 d,inAD3 a){d=ARcpD3(a);return d;}
+  AD4 opARcpD4(outAD4 d,inAD4 a){d=ARcpD4(a);return d;}
+ #endif
+//==============================================================================================================================
+ AF2 opAAbsF2(outAF2 d,inAF2 a){d=abs(a);return d;}
+ AF3 opAAbsF3(outAF3 d,inAF3 a){d=abs(a);return d;}
+ AF4 opAAbsF4(outAF4 d,inAF4 a){d=abs(a);return d;}
+//------------------------------------------------------------------------------------------------------------------------------
+ AF2 opAAddF2(outAF2 d,inAF2 a,inAF2 b){d=a+b;return d;}
+ AF3 opAAddF3(outAF3 d,inAF3 a,inAF3 b){d=a+b;return d;}
+ AF4 opAAddF4(outAF4 d,inAF4 a,inAF4 b){d=a+b;return d;}
+//------------------------------------------------------------------------------------------------------------------------------
+ AF2 opAAddOneF2(outAF2 d,inAF2 a,AF1 b){d=a+AF2_(b);return d;}
+ AF3 opAAddOneF3(outAF3 d,inAF3 a,AF1 b){d=a+AF3_(b);return d;}
+ AF4 opAAddOneF4(outAF4 d,inAF4 a,AF1 b){d=a+AF4_(b);return d;}
+//------------------------------------------------------------------------------------------------------------------------------
+ AF2 opACpyF2(outAF2 d,inAF2 a){d=a;return d;}
+ AF3 opACpyF3(outAF3 d,inAF3 a){d=a;return d;}
+ AF4 opACpyF4(outAF4 d,inAF4 a){d=a;return d;}
+//------------------------------------------------------------------------------------------------------------------------------
+ AF2 opALerpF2(outAF2 d,inAF2 a,inAF2 b,inAF2 c){d=ALerpF2(a,b,c);return d;}
+ AF3 opALerpF3(outAF3 d,inAF3 a,inAF3 b,inAF3 c){d=ALerpF3(a,b,c);return d;}
+ AF4 opALerpF4(outAF4 d,inAF4 a,inAF4 b,inAF4 c){d=ALerpF4(a,b,c);return d;}
+//------------------------------------------------------------------------------------------------------------------------------
+ AF2 opALerpOneF2(outAF2 d,inAF2 a,inAF2 b,AF1 c){d=ALerpF2(a,b,AF2_(c));return d;}
+ AF3 opALerpOneF3(outAF3 d,inAF3 a,inAF3 b,AF1 c){d=ALerpF3(a,b,AF3_(c));return d;}
+ AF4 opALerpOneF4(outAF4 d,inAF4 a,inAF4 b,AF1 c){d=ALerpF4(a,b,AF4_(c));return d;}
+//------------------------------------------------------------------------------------------------------------------------------
+ AF2 opAMaxF2(outAF2 d,inAF2 a,inAF2 b){d=max(a,b);return d;}
+ AF3 opAMaxF3(outAF3 d,inAF3 a,inAF3 b){d=max(a,b);return d;}
+ AF4 opAMaxF4(outAF4 d,inAF4 a,inAF4 b){d=max(a,b);return d;}
+//------------------------------------------------------------------------------------------------------------------------------
+ AF2 opAMinF2(outAF2 d,inAF2 a,inAF2 b){d=min(a,b);return d;}
+ AF3 opAMinF3(outAF3 d,inAF3 a,inAF3 b){d=min(a,b);return d;}
+ AF4 opAMinF4(outAF4 d,inAF4 a,inAF4 b){d=min(a,b);return d;}
+//------------------------------------------------------------------------------------------------------------------------------
+ AF2 opAMulF2(outAF2 d,inAF2 a,inAF2 b){d=a*b;return d;}
+ AF3 opAMulF3(outAF3 d,inAF3 a,inAF3 b){d=a*b;return d;}
+ AF4 opAMulF4(outAF4 d,inAF4 a,inAF4 b){d=a*b;return d;}
+//------------------------------------------------------------------------------------------------------------------------------
+ AF2 opAMulOneF2(outAF2 d,inAF2 a,AF1 b){d=a*AF2_(b);return d;}
+ AF3 opAMulOneF3(outAF3 d,inAF3 a,AF1 b){d=a*AF3_(b);return d;}
+ AF4 opAMulOneF4(outAF4 d,inAF4 a,AF1 b){d=a*AF4_(b);return d;}
+//------------------------------------------------------------------------------------------------------------------------------
+ AF2 opANegF2(outAF2 d,inAF2 a){d=-a;return d;}
+ AF3 opANegF3(outAF3 d,inAF3 a){d=-a;return d;}
+ AF4 opANegF4(outAF4 d,inAF4 a){d=-a;return d;}
+//------------------------------------------------------------------------------------------------------------------------------
+ AF2 opARcpF2(outAF2 d,inAF2 a){d=ARcpF2(a);return d;}
+ AF3 opARcpF3(outAF3 d,inAF3 a){d=ARcpF3(a);return d;}
+ AF4 opARcpF4(outAF4 d,inAF4 a){d=ARcpF4(a);return d;}
+#endif
+
+#endif
+
+//_____________________________________________________________/\_______________________________________________________________
+//==============================================================================================================================
+//
+//                                 [CAS] FIDELITY FX - CONSTRAST ADAPTIVE SHARPENING 1.20190610
+//
+//==============================================================================================================================
+// LICENSE
+// =======
+// Copyright (c) 2017-2019 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.
+//------------------------------------------------------------------------------------------------------------------------------
+#define CAS_AREA_LIMIT 4.0
+//------------------------------------------------------------------------------------------------------------------------------
+// Pass in output and input resolution in pixels.
+// This returns true if CAS supports scaling in the given configuration.
+AP1 CasSupportScaling(AF1 outX,AF1 outY,AF1 inX,AF1 inY){return ((outX*outY)*ARcpF1(inX*inY))<=CAS_AREA_LIMIT;}
+//==============================================================================================================================
+// Call to setup required constant values (works on CPU or GPU).
+#ifndef A_GPU
+A_STATIC void CasSetup(
+ outAU4 const0,
+ outAU4 const1,
+ AF1 sharpness, // 0 := default (lower ringing), 1 := maximum (higest ringing)
+ AF1 inputSizeInPixelsX,
+ AF1 inputSizeInPixelsY,
+ AF1 outputSizeInPixelsX,
+ AF1 outputSizeInPixelsY){
+  // Scaling terms.
+  const0[0]=AU1_AF1(inputSizeInPixelsX*ARcpF1(outputSizeInPixelsX));
+  const0[1]=AU1_AF1(inputSizeInPixelsY*ARcpF1(outputSizeInPixelsY));
+  const0[2]=AU1_AF1(AF1_(0.5)*inputSizeInPixelsX*ARcpF1(outputSizeInPixelsX)-AF1_(0.5));
+  const0[3]=AU1_AF1(AF1_(0.5)*inputSizeInPixelsY*ARcpF1(outputSizeInPixelsY)-AF1_(0.5));
+  // Sharpness value.
+  AF1 sharp=-ARcpF1(ALerpF1(8.0,5.0,ASatF1(sharpness)));
+  varAF2(hSharp)=initAF2(sharp,0.0);
+  const1[0]=AU1_AF1(sharp);
+  const1[1]=AU1_AH2_AF2(hSharp);
+  const1[2]=AU1_AF1(AF1_(8.0)*inputSizeInPixelsX*ARcpF1(outputSizeInPixelsX));
+  const1[3]=0;}
+#endif
+
+////////////////////////////////////////////////////////////////////////////////////////////////////////////////////////////////
+////////////////////////////////////////////////////////////////////////////////////////////////////////////////////////////////
+//_____________________________________________________________/\_______________________________________________________________
+//==============================================================================================================================
+//                                                     NON-PACKED VERSION
+//==============================================================================================================================
+#ifdef A_GPU
+ AF3 CasLoad(ASU2 p) { return texelFetch(diffuseRect, p, 0).rgb; }
+ void CasInput(inout AF1 r,inout AF1 g,inout AF1 b)
+ {
+    r = AFromSrgbF1(r);
+    g = AFromSrgbF1(g);
+    b = AFromSrgbF1(b);
+ }
+
+//------------------------------------------------------------------------------------------------------------------------------
+ void CasFilter(
+ out AF1 pixR, // Output values, non-vector so port between CasFilter() and CasFilterH() is easy.
+ out AF1 pixG,
+ out AF1 pixB,
+ AU2 ip, // Integer pixel position in output.
+ AU4 const0, // Constants generated by CasSetup().
+ AU4 const1,
+ AP1 noScaling){ // Must be a compile-time literal value, true = sharpen only (no resize).
+//------------------------------------------------------------------------------------------------------------------------------
+  // Debug a checker pattern of on/off tiles for visual inspection.
+  #ifdef CAS_DEBUG_CHECKER
+   if((((ip.x^ip.y)>>8u)&1u)==0u){AF3 pix0=CasLoad(ASU2(ip));
+    pixR=pix0.r;pixG=pix0.g;pixB=pix0.b;CasInput(pixR,pixG,pixB);return;}
+  #endif
+//------------------------------------------------------------------------------------------------------------------------------
+  // No scaling algorithm uses minimal 3x3 pixel neighborhood.
+  if(noScaling){
+   // a b c
+   // d e f
+   // g h i
+   ASU2 sp=ASU2(ip);
+   AF3 a=CasLoad(sp+ASU2(-1,-1));
+   AF3 b=CasLoad(sp+ASU2( 0,-1));
+   AF3 c=CasLoad(sp+ASU2( 1,-1));
+   AF3 d=CasLoad(sp+ASU2(-1, 0));
+   AF3 e=CasLoad(sp);
+   AF3 f=CasLoad(sp+ASU2( 1, 0));
+   AF3 g=CasLoad(sp+ASU2(-1, 1));
+   AF3 h=CasLoad(sp+ASU2( 0, 1));
+   AF3 i=CasLoad(sp+ASU2( 1, 1));
+   // Run optional input transform.
+   CasInput(a.r,a.g,a.b);
+   CasInput(b.r,b.g,b.b);
+   CasInput(c.r,c.g,c.b);
+   CasInput(d.r,d.g,d.b);
+   CasInput(e.r,e.g,e.b);
+   CasInput(f.r,f.g,f.b);
+   CasInput(g.r,g.g,g.b);
+   CasInput(h.r,h.g,h.b);
+   CasInput(i.r,i.g,i.b);
+   // Soft min and max.
+   //  a b c             b
+   //  d e f * 0.5  +  d e f * 0.5
+   //  g h i             h
+   // These are 2.0x bigger (factored out the extra multiply).
+   AF1 mnR=AMin3F1(AMin3F1(d.r,e.r,f.r),b.r,h.r);
+   AF1 mnG=AMin3F1(AMin3F1(d.g,e.g,f.g),b.g,h.g);
+   AF1 mnB=AMin3F1(AMin3F1(d.b,e.b,f.b),b.b,h.b);
+   #ifdef CAS_BETTER_DIAGONALS
+    AF1 mnR2=AMin3F1(AMin3F1(mnR,a.r,c.r),g.r,i.r);
+    AF1 mnG2=AMin3F1(AMin3F1(mnG,a.g,c.g),g.g,i.g);
+    AF1 mnB2=AMin3F1(AMin3F1(mnB,a.b,c.b),g.b,i.b);
+    mnR=mnR+mnR2;
+    mnG=mnG+mnG2;
+    mnB=mnB+mnB2;
+   #endif
+   AF1 mxR=AMax3F1(AMax3F1(d.r,e.r,f.r),b.r,h.r);
+   AF1 mxG=AMax3F1(AMax3F1(d.g,e.g,f.g),b.g,h.g);
+   AF1 mxB=AMax3F1(AMax3F1(d.b,e.b,f.b),b.b,h.b);
+   #ifdef CAS_BETTER_DIAGONALS
+    AF1 mxR2=AMax3F1(AMax3F1(mxR,a.r,c.r),g.r,i.r);
+    AF1 mxG2=AMax3F1(AMax3F1(mxG,a.g,c.g),g.g,i.g);
+    AF1 mxB2=AMax3F1(AMax3F1(mxB,a.b,c.b),g.b,i.b);
+    mxR=mxR+mxR2;
+    mxG=mxG+mxG2;
+    mxB=mxB+mxB2;
+   #endif
+   // Smooth minimum distance to signal limit divided by smooth max.
+   #ifdef CAS_GO_SLOWER
+    AF1 rcpMR=ARcpF1(mxR);
+    AF1 rcpMG=ARcpF1(mxG);
+    AF1 rcpMB=ARcpF1(mxB);
+   #else
+    AF1 rcpMR=APrxLoRcpF1(mxR);
+    AF1 rcpMG=APrxLoRcpF1(mxG);
+    AF1 rcpMB=APrxLoRcpF1(mxB);
+   #endif
+   #ifdef CAS_BETTER_DIAGONALS
+    AF1 ampR=ASatF1(min(mnR,AF1_(2.0)-mxR)*rcpMR);
+    AF1 ampG=ASatF1(min(mnG,AF1_(2.0)-mxG)*rcpMG);
+    AF1 ampB=ASatF1(min(mnB,AF1_(2.0)-mxB)*rcpMB);
+   #else
+    AF1 ampR=ASatF1(min(mnR,AF1_(1.0)-mxR)*rcpMR);
+    AF1 ampG=ASatF1(min(mnG,AF1_(1.0)-mxG)*rcpMG);
+    AF1 ampB=ASatF1(min(mnB,AF1_(1.0)-mxB)*rcpMB);
+   #endif
+   // Shaping amount of sharpening.
+   #ifdef CAS_GO_SLOWER
+    ampR=sqrt(ampR);
+    ampG=sqrt(ampG);
+    ampB=sqrt(ampB);
+   #else
+    ampR=APrxLoSqrtF1(ampR);
+    ampG=APrxLoSqrtF1(ampG);
+    ampB=APrxLoSqrtF1(ampB);
+   #endif
+   // Filter shape.
+   //  0 w 0
+   //  w 1 w
+   //  0 w 0
+   AF1 peak=AF1_AU1(const1.x);
+   AF1 wR=ampR*peak;
+   AF1 wG=ampG*peak;
+   AF1 wB=ampB*peak;
+   // Filter.
+   #ifndef CAS_SLOW
+    // Using green coef only, depending on dead code removal to strip out the extra overhead.
+    #ifdef CAS_GO_SLOWER
+     AF1 rcpWeight=ARcpF1(AF1_(1.0)+AF1_(4.0)*wG);
+    #else
+     AF1 rcpWeight=APrxMedRcpF1(AF1_(1.0)+AF1_(4.0)*wG);
+    #endif
+    pixR=ASatF1((b.r*wG+d.r*wG+f.r*wG+h.r*wG+e.r)*rcpWeight);
+    pixG=ASatF1((b.g*wG+d.g*wG+f.g*wG+h.g*wG+e.g)*rcpWeight);
+    pixB=ASatF1((b.b*wG+d.b*wG+f.b*wG+h.b*wG+e.b)*rcpWeight);
+   #else
+    #ifdef CAS_GO_SLOWER
+     AF1 rcpWeightR=ARcpF1(AF1_(1.0)+AF1_(4.0)*wR);
+     AF1 rcpWeightG=ARcpF1(AF1_(1.0)+AF1_(4.0)*wG);
+     AF1 rcpWeightB=ARcpF1(AF1_(1.0)+AF1_(4.0)*wB);
+    #else
+     AF1 rcpWeightR=APrxMedRcpF1(AF1_(1.0)+AF1_(4.0)*wR);
+     AF1 rcpWeightG=APrxMedRcpF1(AF1_(1.0)+AF1_(4.0)*wG);
+     AF1 rcpWeightB=APrxMedRcpF1(AF1_(1.0)+AF1_(4.0)*wB);
+    #endif
+    pixR=ASatF1((b.r*wR+d.r*wR+f.r*wR+h.r*wR+e.r)*rcpWeightR);
+    pixG=ASatF1((b.g*wG+d.g*wG+f.g*wG+h.g*wG+e.g)*rcpWeightG);
+    pixB=ASatF1((b.b*wB+d.b*wB+f.b*wB+h.b*wB+e.b)*rcpWeightB);
+   #endif
+   return;}
+//------------------------------------------------------------------------------------------------------------------------------
+  // Scaling algorithm adaptively interpolates between nearest 4 results of the non-scaling algorithm.
+  //  a b c d
+  //  e f g h
+  //  i j k l
+  //  m n o p
+  // Working these 4 results.
+  //  +-----+-----+
+  //  |     |     |
+  //  |  f..|..g  |
+  //  |  .  |  .  |
+  //  +-----+-----+
+  //  |  .  |  .  |
+  //  |  j..|..k  |
+  //  |     |     |
+  //  +-----+-----+
+  AF2 pp=AF2(ip)*AF2_AU2(const0.xy)+AF2_AU2(const0.zw);
+  AF2 fp=floor(pp);
+  pp-=fp;
+  ASU2 sp=ASU2(fp);
+  AF3 a=CasLoad(sp+ASU2(-1,-1));
+  AF3 b=CasLoad(sp+ASU2( 0,-1));
+  AF3 e=CasLoad(sp+ASU2(-1, 0));
+  AF3 f=CasLoad(sp);
+  AF3 c=CasLoad(sp+ASU2( 1,-1));
+  AF3 d=CasLoad(sp+ASU2( 2,-1));
+  AF3 g=CasLoad(sp+ASU2( 1, 0));
+  AF3 h=CasLoad(sp+ASU2( 2, 0));
+  AF3 i=CasLoad(sp+ASU2(-1, 1));
+  AF3 j=CasLoad(sp+ASU2( 0, 1));
+  AF3 m=CasLoad(sp+ASU2(-1, 2));
+  AF3 n=CasLoad(sp+ASU2( 0, 2));
+  AF3 k=CasLoad(sp+ASU2( 1, 1));
+  AF3 l=CasLoad(sp+ASU2( 2, 1));
+  AF3 o=CasLoad(sp+ASU2( 1, 2));
+  AF3 p=CasLoad(sp+ASU2( 2, 2));
+  // Run optional input transform.
+  CasInput(a.r,a.g,a.b);
+  CasInput(b.r,b.g,b.b);
+  CasInput(c.r,c.g,c.b);
+  CasInput(d.r,d.g,d.b);
+  CasInput(e.r,e.g,e.b);
+  CasInput(f.r,f.g,f.b);
+  CasInput(g.r,g.g,g.b);
+  CasInput(h.r,h.g,h.b);
+  CasInput(i.r,i.g,i.b);
+  CasInput(j.r,j.g,j.b);
+  CasInput(k.r,k.g,k.b);
+  CasInput(l.r,l.g,l.b);
+  CasInput(m.r,m.g,m.b);
+  CasInput(n.r,n.g,n.b);
+  CasInput(o.r,o.g,o.b);
+  CasInput(p.r,p.g,p.b);
+  // Soft min and max.
+  // These are 2.0x bigger (factored out the extra multiply).
+  //  a b c             b
+  //  e f g * 0.5  +  e f g * 0.5  [F]
+  //  i j k             j
+  AF1 mnfR=AMin3F1(AMin3F1(b.r,e.r,f.r),g.r,j.r);
+  AF1 mnfG=AMin3F1(AMin3F1(b.g,e.g,f.g),g.g,j.g);
+  AF1 mnfB=AMin3F1(AMin3F1(b.b,e.b,f.b),g.b,j.b);
+  #ifdef CAS_BETTER_DIAGONALS
+   AF1 mnfR2=AMin3F1(AMin3F1(mnfR,a.r,c.r),i.r,k.r);
+   AF1 mnfG2=AMin3F1(AMin3F1(mnfG,a.g,c.g),i.g,k.g);
+   AF1 mnfB2=AMin3F1(AMin3F1(mnfB,a.b,c.b),i.b,k.b);
+   mnfR=mnfR+mnfR2;
+   mnfG=mnfG+mnfG2;
+   mnfB=mnfB+mnfB2;
+  #endif
+  AF1 mxfR=AMax3F1(AMax3F1(b.r,e.r,f.r),g.r,j.r);
+  AF1 mxfG=AMax3F1(AMax3F1(b.g,e.g,f.g),g.g,j.g);
+  AF1 mxfB=AMax3F1(AMax3F1(b.b,e.b,f.b),g.b,j.b);
+  #ifdef CAS_BETTER_DIAGONALS
+   AF1 mxfR2=AMax3F1(AMax3F1(mxfR,a.r,c.r),i.r,k.r);
+   AF1 mxfG2=AMax3F1(AMax3F1(mxfG,a.g,c.g),i.g,k.g);
+   AF1 mxfB2=AMax3F1(AMax3F1(mxfB,a.b,c.b),i.b,k.b);
+   mxfR=mxfR+mxfR2;
+   mxfG=mxfG+mxfG2;
+   mxfB=mxfB+mxfB2;
+  #endif
+  //  b c d             c
+  //  f g h * 0.5  +  f g h * 0.5  [G]
+  //  j k l             k
+  AF1 mngR=AMin3F1(AMin3F1(c.r,f.r,g.r),h.r,k.r);
+  AF1 mngG=AMin3F1(AMin3F1(c.g,f.g,g.g),h.g,k.g);
+  AF1 mngB=AMin3F1(AMin3F1(c.b,f.b,g.b),h.b,k.b);
+  #ifdef CAS_BETTER_DIAGONALS
+   AF1 mngR2=AMin3F1(AMin3F1(mngR,b.r,d.r),j.r,l.r);
+   AF1 mngG2=AMin3F1(AMin3F1(mngG,b.g,d.g),j.g,l.g);
+   AF1 mngB2=AMin3F1(AMin3F1(mngB,b.b,d.b),j.b,l.b);
+   mngR=mngR+mngR2;
+   mngG=mngG+mngG2;
+   mngB=mngB+mngB2;
+  #endif
+  AF1 mxgR=AMax3F1(AMax3F1(c.r,f.r,g.r),h.r,k.r);
+  AF1 mxgG=AMax3F1(AMax3F1(c.g,f.g,g.g),h.g,k.g);
+  AF1 mxgB=AMax3F1(AMax3F1(c.b,f.b,g.b),h.b,k.b);
+  #ifdef CAS_BETTER_DIAGONALS
+   AF1 mxgR2=AMax3F1(AMax3F1(mxgR,b.r,d.r),j.r,l.r);
+   AF1 mxgG2=AMax3F1(AMax3F1(mxgG,b.g,d.g),j.g,l.g);
+   AF1 mxgB2=AMax3F1(AMax3F1(mxgB,b.b,d.b),j.b,l.b);
+   mxgR=mxgR+mxgR2;
+   mxgG=mxgG+mxgG2;
+   mxgB=mxgB+mxgB2;
+  #endif
+  //  e f g             f
+  //  i j k * 0.5  +  i j k * 0.5  [J]
+  //  m n o             n
+  AF1 mnjR=AMin3F1(AMin3F1(f.r,i.r,j.r),k.r,n.r);
+  AF1 mnjG=AMin3F1(AMin3F1(f.g,i.g,j.g),k.g,n.g);
+  AF1 mnjB=AMin3F1(AMin3F1(f.b,i.b,j.b),k.b,n.b);
+  #ifdef CAS_BETTER_DIAGONALS
+   AF1 mnjR2=AMin3F1(AMin3F1(mnjR,e.r,g.r),m.r,o.r);
+   AF1 mnjG2=AMin3F1(AMin3F1(mnjG,e.g,g.g),m.g,o.g);
+   AF1 mnjB2=AMin3F1(AMin3F1(mnjB,e.b,g.b),m.b,o.b);
+   mnjR=mnjR+mnjR2;
+   mnjG=mnjG+mnjG2;
+   mnjB=mnjB+mnjB2;
+  #endif
+  AF1 mxjR=AMax3F1(AMax3F1(f.r,i.r,j.r),k.r,n.r);
+  AF1 mxjG=AMax3F1(AMax3F1(f.g,i.g,j.g),k.g,n.g);
+  AF1 mxjB=AMax3F1(AMax3F1(f.b,i.b,j.b),k.b,n.b);
+  #ifdef CAS_BETTER_DIAGONALS
+   AF1 mxjR2=AMax3F1(AMax3F1(mxjR,e.r,g.r),m.r,o.r);
+   AF1 mxjG2=AMax3F1(AMax3F1(mxjG,e.g,g.g),m.g,o.g);
+   AF1 mxjB2=AMax3F1(AMax3F1(mxjB,e.b,g.b),m.b,o.b);
+   mxjR=mxjR+mxjR2;
+   mxjG=mxjG+mxjG2;
+   mxjB=mxjB+mxjB2;
+  #endif
+  //  f g h             g
+  //  j k l * 0.5  +  j k l * 0.5  [K]
+  //  n o p             o
+  AF1 mnkR=AMin3F1(AMin3F1(g.r,j.r,k.r),l.r,o.r);
+  AF1 mnkG=AMin3F1(AMin3F1(g.g,j.g,k.g),l.g,o.g);
+  AF1 mnkB=AMin3F1(AMin3F1(g.b,j.b,k.b),l.b,o.b);
+  #ifdef CAS_BETTER_DIAGONALS
+   AF1 mnkR2=AMin3F1(AMin3F1(mnkR,f.r,h.r),n.r,p.r);
+   AF1 mnkG2=AMin3F1(AMin3F1(mnkG,f.g,h.g),n.g,p.g);
+   AF1 mnkB2=AMin3F1(AMin3F1(mnkB,f.b,h.b),n.b,p.b);
+   mnkR=mnkR+mnkR2;
+   mnkG=mnkG+mnkG2;
+   mnkB=mnkB+mnkB2;
+  #endif
+  AF1 mxkR=AMax3F1(AMax3F1(g.r,j.r,k.r),l.r,o.r);
+  AF1 mxkG=AMax3F1(AMax3F1(g.g,j.g,k.g),l.g,o.g);
+  AF1 mxkB=AMax3F1(AMax3F1(g.b,j.b,k.b),l.b,o.b);
+  #ifdef CAS_BETTER_DIAGONALS
+   AF1 mxkR2=AMax3F1(AMax3F1(mxkR,f.r,h.r),n.r,p.r);
+   AF1 mxkG2=AMax3F1(AMax3F1(mxkG,f.g,h.g),n.g,p.g);
+   AF1 mxkB2=AMax3F1(AMax3F1(mxkB,f.b,h.b),n.b,p.b);
+   mxkR=mxkR+mxkR2;
+   mxkG=mxkG+mxkG2;
+   mxkB=mxkB+mxkB2;
+  #endif
+  // Smooth minimum distance to signal limit divided by smooth max.
+  #ifdef CAS_GO_SLOWER
+   AF1 rcpMfR=ARcpF1(mxfR);
+   AF1 rcpMfG=ARcpF1(mxfG);
+   AF1 rcpMfB=ARcpF1(mxfB);
+   AF1 rcpMgR=ARcpF1(mxgR);
+   AF1 rcpMgG=ARcpF1(mxgG);
+   AF1 rcpMgB=ARcpF1(mxgB);
+   AF1 rcpMjR=ARcpF1(mxjR);
+   AF1 rcpMjG=ARcpF1(mxjG);
+   AF1 rcpMjB=ARcpF1(mxjB);
+   AF1 rcpMkR=ARcpF1(mxkR);
+   AF1 rcpMkG=ARcpF1(mxkG);
+   AF1 rcpMkB=ARcpF1(mxkB);
+  #else
+   AF1 rcpMfR=APrxLoRcpF1(mxfR);
+   AF1 rcpMfG=APrxLoRcpF1(mxfG);
+   AF1 rcpMfB=APrxLoRcpF1(mxfB);
+   AF1 rcpMgR=APrxLoRcpF1(mxgR);
+   AF1 rcpMgG=APrxLoRcpF1(mxgG);
+   AF1 rcpMgB=APrxLoRcpF1(mxgB);
+   AF1 rcpMjR=APrxLoRcpF1(mxjR);
+   AF1 rcpMjG=APrxLoRcpF1(mxjG);
+   AF1 rcpMjB=APrxLoRcpF1(mxjB);
+   AF1 rcpMkR=APrxLoRcpF1(mxkR);
+   AF1 rcpMkG=APrxLoRcpF1(mxkG);
+   AF1 rcpMkB=APrxLoRcpF1(mxkB);
+  #endif
+  #ifdef CAS_BETTER_DIAGONALS
+   AF1 ampfR=ASatF1(min(mnfR,AF1_(2.0)-mxfR)*rcpMfR);
+   AF1 ampfG=ASatF1(min(mnfG,AF1_(2.0)-mxfG)*rcpMfG);
+   AF1 ampfB=ASatF1(min(mnfB,AF1_(2.0)-mxfB)*rcpMfB);
+   AF1 ampgR=ASatF1(min(mngR,AF1_(2.0)-mxgR)*rcpMgR);
+   AF1 ampgG=ASatF1(min(mngG,AF1_(2.0)-mxgG)*rcpMgG);
+   AF1 ampgB=ASatF1(min(mngB,AF1_(2.0)-mxgB)*rcpMgB);
+   AF1 ampjR=ASatF1(min(mnjR,AF1_(2.0)-mxjR)*rcpMjR);
+   AF1 ampjG=ASatF1(min(mnjG,AF1_(2.0)-mxjG)*rcpMjG);
+   AF1 ampjB=ASatF1(min(mnjB,AF1_(2.0)-mxjB)*rcpMjB);
+   AF1 ampkR=ASatF1(min(mnkR,AF1_(2.0)-mxkR)*rcpMkR);
+   AF1 ampkG=ASatF1(min(mnkG,AF1_(2.0)-mxkG)*rcpMkG);
+   AF1 ampkB=ASatF1(min(mnkB,AF1_(2.0)-mxkB)*rcpMkB);
+  #else
+   AF1 ampfR=ASatF1(min(mnfR,AF1_(1.0)-mxfR)*rcpMfR);
+   AF1 ampfG=ASatF1(min(mnfG,AF1_(1.0)-mxfG)*rcpMfG);
+   AF1 ampfB=ASatF1(min(mnfB,AF1_(1.0)-mxfB)*rcpMfB);
+   AF1 ampgR=ASatF1(min(mngR,AF1_(1.0)-mxgR)*rcpMgR);
+   AF1 ampgG=ASatF1(min(mngG,AF1_(1.0)-mxgG)*rcpMgG);
+   AF1 ampgB=ASatF1(min(mngB,AF1_(1.0)-mxgB)*rcpMgB);
+   AF1 ampjR=ASatF1(min(mnjR,AF1_(1.0)-mxjR)*rcpMjR);
+   AF1 ampjG=ASatF1(min(mnjG,AF1_(1.0)-mxjG)*rcpMjG);
+   AF1 ampjB=ASatF1(min(mnjB,AF1_(1.0)-mxjB)*rcpMjB);
+   AF1 ampkR=ASatF1(min(mnkR,AF1_(1.0)-mxkR)*rcpMkR);
+   AF1 ampkG=ASatF1(min(mnkG,AF1_(1.0)-mxkG)*rcpMkG);
+   AF1 ampkB=ASatF1(min(mnkB,AF1_(1.0)-mxkB)*rcpMkB);
+  #endif
+  // Shaping amount of sharpening.
+  #ifdef CAS_GO_SLOWER
+   ampfR=sqrt(ampfR);
+   ampfG=sqrt(ampfG);
+   ampfB=sqrt(ampfB);
+   ampgR=sqrt(ampgR);
+   ampgG=sqrt(ampgG);
+   ampgB=sqrt(ampgB);
+   ampjR=sqrt(ampjR);
+   ampjG=sqrt(ampjG);
+   ampjB=sqrt(ampjB);
+   ampkR=sqrt(ampkR);
+   ampkG=sqrt(ampkG);
+   ampkB=sqrt(ampkB);
+  #else
+   ampfR=APrxLoSqrtF1(ampfR);
+   ampfG=APrxLoSqrtF1(ampfG);
+   ampfB=APrxLoSqrtF1(ampfB);
+   ampgR=APrxLoSqrtF1(ampgR);
+   ampgG=APrxLoSqrtF1(ampgG);
+   ampgB=APrxLoSqrtF1(ampgB);
+   ampjR=APrxLoSqrtF1(ampjR);
+   ampjG=APrxLoSqrtF1(ampjG);
+   ampjB=APrxLoSqrtF1(ampjB);
+   ampkR=APrxLoSqrtF1(ampkR);
+   ampkG=APrxLoSqrtF1(ampkG);
+   ampkB=APrxLoSqrtF1(ampkB);
+  #endif
+  // Filter shape.
+  //  0 w 0
+  //  w 1 w
+  //  0 w 0
+  AF1 peak=AF1_AU1(const1.x);
+  AF1 wfR=ampfR*peak;
+  AF1 wfG=ampfG*peak;
+  AF1 wfB=ampfB*peak;
+  AF1 wgR=ampgR*peak;
+  AF1 wgG=ampgG*peak;
+  AF1 wgB=ampgB*peak;
+  AF1 wjR=ampjR*peak;
+  AF1 wjG=ampjG*peak;
+  AF1 wjB=ampjB*peak;
+  AF1 wkR=ampkR*peak;
+  AF1 wkG=ampkG*peak;
+  AF1 wkB=ampkB*peak;
+  // Blend between 4 results.
+  //  s t
+  //  u v
+  AF1 s=(AF1_(1.0)-pp.x)*(AF1_(1.0)-pp.y);
+  AF1 t=           pp.x *(AF1_(1.0)-pp.y);
+  AF1 u=(AF1_(1.0)-pp.x)*           pp.y ;
+  AF1 v=           pp.x *           pp.y ;
+  // Thin edges to hide bilinear interpolation (helps diagonals).
+  AF1 thinB=1.0/32.0;
+  #ifdef CAS_GO_SLOWER
+   s*=ARcpF1(thinB+(mxfG-mnfG));
+   t*=ARcpF1(thinB+(mxgG-mngG));
+   u*=ARcpF1(thinB+(mxjG-mnjG));
+   v*=ARcpF1(thinB+(mxkG-mnkG));
+  #else
+   s*=APrxLoRcpF1(thinB+(mxfG-mnfG));
+   t*=APrxLoRcpF1(thinB+(mxgG-mngG));
+   u*=APrxLoRcpF1(thinB+(mxjG-mnjG));
+   v*=APrxLoRcpF1(thinB+(mxkG-mnkG));
+  #endif
+  // Final weighting.
+  //    b c
+  //  e f g h
+  //  i j k l
+  //    n o
+  //  _____  _____  _____  _____
+  //         fs        gt
+  //
+  //  _____  _____  _____  _____
+  //  fs      s gt  fs  t     gt
+  //         ju        kv
+  //  _____  _____  _____  _____
+  //         fs        gt
+  //  ju      u kv  ju  v     kv
+  //  _____  _____  _____  _____
+  //
+  //         ju        kv
+  AF1 qbeR=wfR*s;
+  AF1 qbeG=wfG*s;
+  AF1 qbeB=wfB*s;
+  AF1 qchR=wgR*t;
+  AF1 qchG=wgG*t;
+  AF1 qchB=wgB*t;
+  AF1 qfR=wgR*t+wjR*u+s;
+  AF1 qfG=wgG*t+wjG*u+s;
+  AF1 qfB=wgB*t+wjB*u+s;
+  AF1 qgR=wfR*s+wkR*v+t;
+  AF1 qgG=wfG*s+wkG*v+t;
+  AF1 qgB=wfB*s+wkB*v+t;
+  AF1 qjR=wfR*s+wkR*v+u;
+  AF1 qjG=wfG*s+wkG*v+u;
+  AF1 qjB=wfB*s+wkB*v+u;
+  AF1 qkR=wgR*t+wjR*u+v;
+  AF1 qkG=wgG*t+wjG*u+v;
+  AF1 qkB=wgB*t+wjB*u+v;
+  AF1 qinR=wjR*u;
+  AF1 qinG=wjG*u;
+  AF1 qinB=wjB*u;
+  AF1 qloR=wkR*v;
+  AF1 qloG=wkG*v;
+  AF1 qloB=wkB*v;
+  // Filter.
+  #ifndef CAS_SLOW
+   // Using green coef only, depending on dead code removal to strip out the extra overhead.
+   #ifdef CAS_GO_SLOWER
+    AF1 rcpWG=ARcpF1(AF1_(2.0)*qbeG+AF1_(2.0)*qchG+AF1_(2.0)*qinG+AF1_(2.0)*qloG+qfG+qgG+qjG+qkG);
+   #else
+    AF1 rcpWG=APrxMedRcpF1(AF1_(2.0)*qbeG+AF1_(2.0)*qchG+AF1_(2.0)*qinG+AF1_(2.0)*qloG+qfG+qgG+qjG+qkG);
+   #endif
+   pixR=ASatF1((b.r*qbeG+e.r*qbeG+c.r*qchG+h.r*qchG+i.r*qinG+n.r*qinG+l.r*qloG+o.r*qloG+f.r*qfG+g.r*qgG+j.r*qjG+k.r*qkG)*rcpWG);
+   pixG=ASatF1((b.g*qbeG+e.g*qbeG+c.g*qchG+h.g*qchG+i.g*qinG+n.g*qinG+l.g*qloG+o.g*qloG+f.g*qfG+g.g*qgG+j.g*qjG+k.g*qkG)*rcpWG);
+   pixB=ASatF1((b.b*qbeG+e.b*qbeG+c.b*qchG+h.b*qchG+i.b*qinG+n.b*qinG+l.b*qloG+o.b*qloG+f.b*qfG+g.b*qgG+j.b*qjG+k.b*qkG)*rcpWG);
+  #else
+   #ifdef CAS_GO_SLOWER
+    AF1 rcpWR=ARcpF1(AF1_(2.0)*qbeR+AF1_(2.0)*qchR+AF1_(2.0)*qinR+AF1_(2.0)*qloR+qfR+qgR+qjR+qkR);
+    AF1 rcpWG=ARcpF1(AF1_(2.0)*qbeG+AF1_(2.0)*qchG+AF1_(2.0)*qinG+AF1_(2.0)*qloG+qfG+qgG+qjG+qkG);
+    AF1 rcpWB=ARcpF1(AF1_(2.0)*qbeB+AF1_(2.0)*qchB+AF1_(2.0)*qinB+AF1_(2.0)*qloB+qfB+qgB+qjB+qkB);
+   #else
+    AF1 rcpWR=APrxMedRcpF1(AF1_(2.0)*qbeR+AF1_(2.0)*qchR+AF1_(2.0)*qinR+AF1_(2.0)*qloR+qfR+qgR+qjR+qkR);
+    AF1 rcpWG=APrxMedRcpF1(AF1_(2.0)*qbeG+AF1_(2.0)*qchG+AF1_(2.0)*qinG+AF1_(2.0)*qloG+qfG+qgG+qjG+qkG);
+    AF1 rcpWB=APrxMedRcpF1(AF1_(2.0)*qbeB+AF1_(2.0)*qchB+AF1_(2.0)*qinB+AF1_(2.0)*qloB+qfB+qgB+qjB+qkB);
+   #endif
+   pixR=ASatF1((b.r*qbeR+e.r*qbeR+c.r*qchR+h.r*qchR+i.r*qinR+n.r*qinR+l.r*qloR+o.r*qloR+f.r*qfR+g.r*qgR+j.r*qjR+k.r*qkR)*rcpWR);
+   pixG=ASatF1((b.g*qbeG+e.g*qbeG+c.g*qchG+h.g*qchG+i.g*qinG+n.g*qinG+l.g*qloG+o.g*qloG+f.g*qfG+g.g*qgG+j.g*qjG+k.g*qkG)*rcpWG);
+   pixB=ASatF1((b.b*qbeB+e.b*qbeB+c.b*qchB+h.b*qchB+i.b*qinB+n.b*qinB+l.b*qloB+o.b*qloB+f.b*qfB+g.b*qgB+j.b*qjB+k.b*qkB)*rcpWB);
+  #endif
+ }
+#endif
+
+#ifdef A_GPU
+void main()
+{
+    vec4 diff = vec4(0.f);
+    uvec2 point = uvec2(vary_fragcoord * out_screen_res.xy);
+    CasFilter(diff.r, diff.g, diff.b, point, cas_param_0, cas_param_1, true);
+    frag_color = vec4(linear_to_srgb(diff.rgb), 1.0);
+}
+#endif
-- 
cgit v1.2.3


From 958afaa7a7bfb1217bbffee3fe562f21901277ac Mon Sep 17 00:00:00 2001
From: Rye Mutt <rye@alchemyviewer.org>
Date: Tue, 27 Aug 2024 22:47:32 -0400
Subject: Integrate SMAA and rework post process chain for better visual
 quality Add SMAA buffer generation passes Add quality levels for both FXAA
 and SMAA Separate gamma correction and tonemapping for effects that require
 linear-but-tonemapped inputs Move application of noise to final render pass
 to screen to avoid damaging other post process effects

---
 indra/newview/app_settings/shaders/class1/deferred/CASF.glsl | 6 ++----
 1 file changed, 2 insertions(+), 4 deletions(-)

(limited to 'indra/newview/app_settings/shaders/class1/deferred/CASF.glsl')

diff --git a/indra/newview/app_settings/shaders/class1/deferred/CASF.glsl b/indra/newview/app_settings/shaders/class1/deferred/CASF.glsl
index 96d08058cf..e80c59b39f 100644
--- a/indra/newview/app_settings/shaders/class1/deferred/CASF.glsl
+++ b/indra/newview/app_settings/shaders/class1/deferred/CASF.glsl
@@ -2067,9 +2067,6 @@ A_STATIC void CasSetup(
  AF3 CasLoad(ASU2 p) { return texelFetch(diffuseRect, p, 0).rgb; }
  void CasInput(inout AF1 r,inout AF1 g,inout AF1 b)
  {
-    r = AFromSrgbF1(r);
-    g = AFromSrgbF1(g);
-    b = AFromSrgbF1(b);
  }
 
 //------------------------------------------------------------------------------------------------------------------------------
@@ -2553,6 +2550,7 @@ void main()
     vec4 diff = vec4(0.f);
     uvec2 point = uvec2(vary_fragcoord * out_screen_res.xy);
     CasFilter(diff.r, diff.g, diff.b, point, cas_param_0, cas_param_1, true);
-    frag_color = vec4(linear_to_srgb(diff.rgb), 1.0);
+    diff.a = texture(diffuseRect, vary_fragcoord).a;
+    frag_color = diff;
 }
 #endif
-- 
cgit v1.2.3