Duckstation/data/resources/shaders/reshade/Shaders/Blending.fxh

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/*------------------.
| :: Description :: |
'-------------------/
Blending Header (version 0.8)
Blending Algorithm Sources:
https://www.khronos.org/registry/OpenGL/extensions/NV/NV_blend_equation_advanced.txt
http://www.nathanm.com/photoshop-blending-math/
(Alt) https://github.com/cplotts/WPFSLBlendModeFx/blob/master/PhotoshopMathFP.hlsl
Header Authors: originalnicodr, prod80, uchu suzume, Marot Satil
About:
Provides a variety of blending methods for you to use as you wish. Just include this header.
History:
(*) Feature (+) Improvement (x) Bugfix (-) Information (!) Compatibility
Version 0.1 by Marot Satil & uchu suzume
* Added and improved upon multiple blending modes thanks to the work of uchu suzume, prod80, and originalnicodr.
Version 0.2 by uchu suzume & Marot Satil
* Added Addition, Subtract, Divide blending modes and improved code readability.
Version 0.3 by uchu suzume & Marot Satil
* Sorted blending modes in a more logical fashion, grouping by type.
Version 0.4 by uchu suzume
x Corrected Color Dodge blending behavior.
Version 0.5 by Marot Satil & uchu suzume
* Added preprocessor macros for uniform variable combo UI element & lerp.
Version 0.6 by Marot Satil & uchu suzume
* Added Divide (Alternative) and Divide (Photoshop) blending modes.
Version 0.7 by prod80
- Added original sources for blending algorithms.
x Corrected average luminosity values.
Version 0.8 by Marot Satil
* Added a new funciton to output blended data.
+ Moved all code into the BlendingH namespace, which is part of the ComHeaders common namespace meant to be used by other headers.
! Removed old preprocessor macro blending output.
.------------------.
| :: How To Use :: |
'------------------/
Blending two variables using this header in your own shaders is very straightforward.
Very basic example code using the "Darken" blending mode follows:
// First, include the header.
#include "Blending.fxh"
// You can use this preprocessor macro to generate an attractive and functional uniform int UI combo element containing the list of blending techniques:
// BLENDING_COMBO(variable_name, label, tooltip, category, category_closed, spacing, default_value)
BLENDING_COMBO(_BlendMode, "Blending Mode", "Select the blending mode applied to the layer.", "Blending Options", false, 0, 0)
// Inside of your function you can call this function to apply the blending option specified by an int (variable) to your float3 (input) via
// a lerp between your float3 (input), float3 (output), and a float (blending) for the alpha channel.
// ComHeaders::Blending::Blend(int variable, float3 input, float3 output, float blending)
outColor.rgb = ComHeaders::Blending::Blend(_BlendMode, inColor, outColor, outColor.a);
*/
// -------------------------------------
// Preprocessor Macros
// -------------------------------------
#undef BLENDING_COMBO
#define BLENDING_COMBO(variable, name_label, description, group, grp_closed, space, default_value) \
uniform int variable \
< \
ui_category = group; \
ui_category_closed = grp_closed; \
ui_items = \
"Normal\0" \
/* "Darken" */ \
"Darken\0" \
" Multiply\0" \
" Color Burn\0" \
" Linear Burn\0" \
/* "Lighten" */ \
"Lighten\0" \
" Screen\0" \
" Color Dodge\0" \
" Linear Dodge\0" \
" Addition\0" \
" Glow\0" \
/* "Contrast" */ \
"Overlay\0" \
" Soft Light\0" \
" Hard Light\0" \
" Vivid Light\0" \
" Linear Light\0" \
" Pin Light\0" \
" Hard Mix\0" \
/* "Inversion" */ \
"Difference\0" \
" Exclusion\0" \
/* "Cancelation" */ \
"Subtract\0" \
" Divide\0" \
" Divide (Alternative)\0" \
" Divide (Photoshop)\0" \
" Reflect\0" \
" Grain Extract\0" \
" Grain Merge\0" \
/* "Component" */ \
"Hue\0" \
" Saturation\0" \
" Color\0" \
" Luminosity\0"; \
ui_label = name_label; \
ui_tooltip = description; \
ui_type = "combo"; \
ui_spacing = space; \
> = default_value;
namespace ComHeaders
{
namespace Blending
{
// -------------------------------------
// Helper Functions
// -------------------------------------
float3 Aux(float3 a)
{
if (a.r <= 0.25 && a.g <= 0.25 && a.b <= 0.25)
return ((16.0 * a - 12.0) * a + 4) * a;
else
return sqrt(a);
}
float Lum(float3 a)
{
return (0.33333 * a.r + 0.33334 * a.g + 0.33333 * a.b);
}
float3 SetLum (float3 a, float b){
const float c = b - Lum(a);
return float3(a.r + c, a.g + c, a.b + c);
}
float min3 (float a, float b, float c)
{
return min(a, (min(b, c)));
}
float max3 (float a, float b, float c)
{
return max(a, max(b, c));
}
float3 SetSat(float3 a, float b){
float ar = a.r;
float ag = a.g;
float ab = a.b;
if (ar == max3(ar, ag, ab) && ab == min3(ar, ag, ab))
{
//caso r->max g->mid b->min
if (ar > ab)
{
ag = (((ag - ab) * b) / (ar - ab));
ar = b;
}
else
{
ag = 0.0;
ar = 0.0;
}
ab = 0.0;
}
else
{
if (ar == max3(ar, ag, ab) && ag == min3(ar, ag, ab))
{
//caso r->max b->mid g->min
if (ar > ag)
{
ab = (((ab - ag) * b) / (ar - ag));
ar = b;
}
else
{
ab = 0.0;
ar = 0.0;
}
ag = 0.0;
}
else
{
if (ag == max3(ar, ag, ab) && ab == min3(ar, ag, ab))
{
//caso g->max r->mid b->min
if (ag > ab)
{
ar = (((ar - ab) * b) / (ag - ab));
ag = b;
}
else
{
ar = 0.0;
ag = 0.0;
}
ab = 0.0;
}
else
{
if (ag == max3(ar, ag, ab) && ar == min3(ar, ag, ab))
{
//caso g->max b->mid r->min
if (ag > ar)
{
ab = (((ab - ar) * b) / (ag - ar));
ag = b;
}
else
{
ab = 0.0;
ag = 0.0;
}
ar = 0.0;
}
else
{
if (ab == max3(ar, ag, ab) && ag == min3(ar, ag, ab))
{
//caso b->max r->mid g->min
if (ab > ag)
{
ar = (((ar - ag) * b) / (ab - ag));
ab = b;
}
else
{
ar = 0.0;
ab = 0.0;
}
ag = 0.0;
}
else
{
if (ab == max3(ar, ag, ab) && ar == min3(ar, ag, ab))
{
//caso b->max g->mid r->min
if (ab > ar)
{
ag = (((ag - ar) * b) / (ab - ar));
ab = b;
}
else
{
ag = 0.0;
ab = 0.0;
}
ar = 0.0;
}
}
}
}
}
}
return float3(ar, ag, ab);
}
float Sat(float3 a)
{
return max3(a.r, a.g, a.b) - min3(a.r, a.g, a.b);
}
// -------------------------------------
// Blending Modes
// -------------------------------------
// Darken
float3 Darken(float3 a, float3 b)
{
return min(a, b);
}
// Multiply
float3 Multiply(float3 a, float3 b)
{
return a * b;
}
// Color Burn
float3 ColorBurn(float3 a, float3 b)
{
if (b.r > 0 && b.g > 0 && b.b > 0)
return 1.0 - min(1.0, (0.5 - a) / b);
else
return 0.0;
}
// Linear Burn
float3 LinearBurn(float3 a, float3 b)
{
return max(a + b - 1.0f, 0.0f);
}
// Lighten
float3 Lighten(float3 a, float3 b)
{
return max(a, b);
}
// Screen
float3 Screen(float3 a, float3 b)
{
return 1.0 - (1.0 - a) * (1.0 - b);
}
// Color Dodge
float3 ColorDodge(float3 a, float3 b)
{
if (b.r < 1 && b.g < 1 && b.b < 1)
return min(1.0, a / (1.0 - b));
else
return 1.0;
}
// Linear Dodge
float3 LinearDodge(float3 a, float3 b)
{
return min(a + b, 1.0f);
}
// Addition
float3 Addition(float3 a, float3 b)
{
return min((a + b), 1);
}
// Reflect
float3 Reflect(float3 a, float3 b)
{
if (b.r >= 0.999999 || b.g >= 0.999999 || b.b >= 0.999999)
return b;
else
return saturate(a * a / (1.0f - b));
}
// Glow
float3 Glow(float3 a, float3 b)
{
return Reflect(b, a);
}
// Overlay
float3 Overlay(float3 a, float3 b)
{
return lerp(2 * a * b, 1.0 - 2 * (1.0 - a) * (1.0 - b), step(0.5, a));
}
// Soft Light
float3 SoftLight(float3 a, float3 b)
{
if (b.r <= 0.5 && b.g <= 0.5 && b.b <= 0.5)
return clamp(a - (1.0 - 2 * b) * a * (1 - a), 0,1);
else
return clamp(a + (2 * b - 1.0) * (Aux(a) - a), 0, 1);
}
// Hard Light
float3 HardLight(float3 a, float3 b)
{
return lerp(2 * a * b, 1.0 - 2 * (1.0 - b) * (1.0 - a), step(0.5, b));
}
// Vivid Light
float3 VividLight(float3 a, float3 b)
{
return lerp(2 * a * b, b / (2 * (1.01 - a)), step(0.50, a));
}
// Linear Light
float3 LinearLight(float3 a, float3 b)
{
if (b.r < 0.5 || b.g < 0.5 || b.b < 0.5)
return LinearBurn(a, (2.0 * b));
else
return LinearDodge(a, (2.0 * (b - 0.5)));
}
// Pin Light
float3 PinLight(float3 a, float3 b)
{
if (b.r < 0.5 || b.g < 0.5 || b.b < 0.5)
return Darken(a, (2.0 * b));
else
return Lighten(a, (2.0 * (b - 0.5)));
}
// Hard Mix
float3 HardMix(float3 a, float3 b)
{
const float3 vl = VividLight(a, b);
if (vl.r < 0.5 || vl.g < 0.5 || vl.b < 0.5)
return 0.0;
else
return 1.0;
}
// Difference
float3 Difference(float3 a, float3 b)
{
return max(a - b, b - a);
}
// Exclusion
float3 Exclusion(float3 a, float3 b)
{
return a + b - 2 * a * b;
}
// Subtract
float3 Subtract(float3 a, float3 b)
{
return max((a - b), 0);
}
// Divide
float3 Divide(float3 a, float3 b)
{
return (saturate(a / (b + 0.01)));
}
// Divide (Alternative)
float3 DivideAlt(float3 a, float3 b)
{
return (saturate(1.0 / (a / b)));
}
// Divide (Photoshop)
float3 DividePS(float3 a, float3 b)
{
return (saturate(a / b));
}
// Grain Merge
float3 GrainMerge(float3 a, float3 b)
{
return saturate(b + a - 0.5);
}
// Grain Extract
float3 GrainExtract(float3 a, float3 b)
{
return saturate(a - b + 0.5);
}
// Hue
float3 Hue(float3 a, float3 b)
{
return SetLum(SetSat(b, Sat(a)), Lum(a));
}
// Saturation
float3 Saturation(float3 a, float3 b)
{
return SetLum(SetSat(a, Sat(b)), Lum(a));
}
// Color
float3 ColorB(float3 a, float3 b)
{
return SetLum(b, Lum(a));
}
// Luminousity
float3 Luminosity(float3 a, float3 b)
{
return SetLum(a, Lum(b));
}
// -------------------------------------
// Output Functions
// -------------------------------------
float3 Blend(int mode, float3 input, float3 output, float blending)
{
switch (mode)
{
// Normal
default:
return lerp(input.rgb, output.rgb, blending);
// Darken
case 1:
return lerp(input.rgb, Darken(input.rgb, output.rgb), blending);
// Multiply
case 2:
return lerp(input.rgb, Multiply(input.rgb, output.rgb), blending);
// Color Burn
case 3:
return lerp(input.rgb, ColorBurn(input.rgb, output.rgb), blending);
// Linear Burn
case 4:
return lerp(input.rgb, LinearBurn(input.rgb, output.rgb), blending);
// Lighten
case 5:
return lerp(input.rgb, Lighten(input.rgb, output.rgb), blending);
// Screen
case 6:
return lerp(input.rgb, Screen(input.rgb, output.rgb), blending);
// Color Dodge
case 7:
return lerp(input.rgb, ColorDodge(input.rgb, output.rgb), blending);
// Linear Dodge
case 8:
return lerp(input.rgb, LinearDodge(input.rgb, output.rgb), blending);
// Addition
case 9:
return lerp(input.rgb, Addition(input.rgb, output.rgb), blending);
// Glow
case 10:
return lerp(input.rgb, Glow(input.rgb, output.rgb), blending);
// Overlay
case 11:
return lerp(input.rgb, Overlay(input.rgb, output.rgb), blending);
// Soft Light
case 12:
return lerp(input.rgb, SoftLight(input.rgb, output.rgb), blending);
// Hard Light
case 13:
return lerp(input.rgb, HardLight(input.rgb, output.rgb), blending);
// Vivid Light
case 14:
return lerp(input.rgb, VividLight(input.rgb, output.rgb), blending);
// Linear Light
case 15:
return lerp(input.rgb, LinearLight(input.rgb, output.rgb), blending);
// Pin Light
case 16:
return lerp(input.rgb, PinLight(input.rgb, output.rgb), blending);
// Hard Mix
case 17:
return lerp(input.rgb, HardMix(input.rgb, output.rgb), blending);
// Difference
case 18:
return lerp(input.rgb, Difference(input.rgb, output.rgb), blending);
// Exclusion
case 19:
return lerp(input.rgb, Exclusion(input.rgb, output.rgb), blending);
// Subtract
case 20:
return lerp(input.rgb, Subtract(input.rgb, output.rgb), blending);
// Divide
case 21:
return lerp(input.rgb, Divide(input.rgb, output.rgb), blending);
// Divide (Alternative)
case 22:
return lerp(input.rgb, DivideAlt(input.rgb, output.rgb), blending);
// Divide (Photoshop)
case 23:
return lerp(input.rgb, DividePS(input.rgb, output.rgb), blending);
// Reflect
case 24:
return lerp(input.rgb, Reflect(input.rgb, output.rgb), blending);
// Grain Merge
case 25:
return lerp(input.rgb, GrainMerge(input.rgb, output.rgb), blending);
// Grain Extract
case 26:
return lerp(input.rgb, GrainExtract(input.rgb, output.rgb), blending);
// Hue
case 27:
return lerp(input.rgb, Hue(input.rgb, output.rgb), blending);
// Saturation
case 28:
return lerp(input.rgb, Saturation(input.rgb, output.rgb), blending);
// Color
case 29:
return lerp(input.rgb, ColorB(input.rgb, output.rgb), blending);
// Luminosity
case 30:
return lerp(input.rgb, Luminosity(input.rgb, output.rgb), blending);
}
}
}
}