examples: Add colored and inverted luma burn varitions (#283)

Adds colored and inverted colored variations for Luma Burn, enabling some more fancy transitions with it. All variations with color support smooth fading, and allow choosing any possible color for the transition.
This commit is contained in:
Charles Fettinger 2020-09-07 13:06:30 -07:00 committed by Michael Fabian 'Xaymar' Dirks
parent bec062a7bd
commit 56d041e1b7

View file

@ -39,7 +39,7 @@ uniform float Sharpness<
uniform bool LumaIsExponential<
string name = "Is Luminosity exponential?";
>;
> = false;
uniform float LumaExponent<
string name = "Luminosity Exponent";
string field_type = "slider";
@ -47,7 +47,30 @@ uniform float LumaExponent<
float maximum = 500.;
float step = .01;
float scale = .01;
> = 150.;
> = 100.;
uniform float4 TransitionColor<
string name = "Color";
string field_type = "slider";
float4 minimum = {0.,0.,0.,0.};
float4 maximum = {100.,100.,100.,100.};
float4 scale = {.01,.01,.01,.01};
float4 step = {.01,.01,.01,.01};
> = { 80.0, 33.0, 33.0, 75.0 };
uniform bool ColorEase<
string name = "Ease Color?";
> = false;
uniform int ColorEaseStart<
string name = "Ease Color Start";
string field_type = "slider";
string suffix = " %";
int minimum = 0;
int maximum = 100;
int step = 1;
int scale = 1;
> = 75;
// ---------- Shader Code
sampler_state def_sampler {
@ -68,30 +91,37 @@ VertData VSDefault(VertData v_in) {
return vert_out;
}
float4 RGBtoYUV(float4 rgba, float3x3 yuv) {
return float4(
rgba.r * yuv._m00 + rgba.g * yuv._m01 + rgba.b * yuv._m02,
rgba.r * yuv._m10 + rgba.g * yuv._m11 + rgba.b * yuv._m12,
rgba.r * yuv._m20 + rgba.g * yuv._m21 + rgba.b * yuv._m22,
rgba.a
) + float4(0,0.5,0.5,0);
float TransitionAlphaEase(float transition)
{
// (sin(3.5*(x - 0.5))+1)* 0.5) * (cos(3.5(x - 0.5)) +.333 - custom formula to create fast alpha to 100% then quick fade out
// based on y= a sin( b(x+c)) + D wave function combined with cos wave deform
float alpha = ((sin(4.5 * (transition - 0.2)) + 1.0) * 0.5) * (cos(3.5 * (transition - 0.5))) + (ColorEaseStart * 0.01);
return alpha;
}
#define C_e 2,7182818284590452353602874713527
float4 RGBtoYUV(float4 rgba) {
float3x3 yuv = float3x3(float3(0.2126,0.7152,0.0722),float3(-0.1145721060573399,-0.3854278939426601,0.5),float3(0.5,-0.4541529083058166,-0.0458470916941834));
float4 result = float4(0,0.5,0.5,0);
result += float4(
rgba.r * yuv[0][0] + rgba.g * yuv[0][1] + rgba.b * yuv[0][2],
rgba.r * yuv[1][0] + rgba.g * yuv[1][1] + rgba.b * yuv[1][2],
rgba.r * yuv[2][0] + rgba.g * yuv[2][1] + rgba.b * yuv[2][2],
rgba.a
);
return result;
}
//#define C_e 2,7182818284590452353602874713527
#define C_log2_e 1.4426950408889634073599246810019 // Windows calculator: log(e(1)) / log(2)
float4 PSDefault(VertData v_in) : TARGET {
const float3x3 mYUV709n = { // Normalized
0.2126, 0.7152, 0.0722,
-0.1145721060573399, -0.3854278939426601, 0.5,
0.5, -0.4541529083058166, -0.0458470916941834
};
float4 PSDefault(VertData v_in) : TARGET
{
float4 sampleA = InputA.Sample(def_sampler, v_in.uv);
float4 sampleB = InputB.Sample(def_sampler, v_in.uv);
float4 sampleAYUV = RGBtoYUV(sampleA, mYUV709n);
float4 sampleBYUV = RGBtoYUV(sampleB, mYUV709n);
float4 sampleAYUV = RGBtoYUV(sampleA);
float4 sampleBYUV = RGBtoYUV(sampleB);
float sharpinv = 1.0 / Sharpness;
float luma = sampleAYUV.r;
@ -108,27 +138,14 @@ float4 PSDefault(VertData v_in) : TARGET {
//return transition;
}
technique Draw
float4 PSInverse(VertData v_in) : TARGET
{
pass
{
vertex_shader = VSDefault(v_in);
pixel_shader = PSDefault(v_in);
}
}
float4 PSInverse(VertData v_in) : TARGET {
const float3x3 mYUV709n = { // Normalized
0.2126, 0.7152, 0.0722,
-0.1145721060573399, -0.3854278939426601, 0.5,
0.5, -0.4541529083058166, -0.0458470916941834
};
float4 sampleA = InputA.Sample(def_sampler, v_in.uv);
float4 sampleB = InputB.Sample(def_sampler, v_in.uv);
float4 sampleAYUV = RGBtoYUV(sampleA, mYUV709n);
float4 sampleBYUV = RGBtoYUV(sampleB, mYUV709n);
float4 sampleAYUV = RGBtoYUV(sampleA);
float4 sampleBYUV = RGBtoYUV(sampleB);
float sharpinv = 1.0 / Sharpness;
float luma = (1.0 - sampleAYUV.r);
@ -145,6 +162,139 @@ float4 PSInverse(VertData v_in) : TARGET {
//return transition;
}
float4 PSDarkToLightColored(VertData v_in) : TARGET
{
float4 sampleA = InputA.Sample(def_sampler, v_in.uv);
float4 sampleB = InputB.Sample(def_sampler, v_in.uv);
float4 sampleAYUV = RGBtoYUV(sampleA);
float4 sampleBYUV = RGBtoYUV(sampleB);
float sharpinv = 1.0 / Sharpness;
float luma = sampleAYUV.r;
if (LumaIsExponential)
{
luma = exp2(luma * LumaExponent * LumaExponent * -C_log2_e);
}
float transition = sharpinv + luma * (1.0 - sharpinv);
transition -= TransitionTime;
transition *= Sharpness;
transition += 0.5;
transition = clamp(transition, 0., 1.);
float colorAlpha = TransitionColor.a;
if (ColorEase)
{
colorAlpha *= TransitionAlphaEase(TransitionTime);
}
sampleB.rgb = lerp(sampleB.rgb, sampleB.rgb * TransitionColor.rgb, colorAlpha); // implement transition coloration
return sampleB * (1.0 - transition) + sampleA * (transition);
//return transition;
}
float4 PSLightToDarkColored(VertData v_in) : TARGET
{
float4 sampleA = InputA.Sample(def_sampler, v_in.uv);
float4 sampleB = InputB.Sample(def_sampler, v_in.uv);
float4 sampleAYUV = RGBtoYUV(sampleA);
float4 sampleBYUV = RGBtoYUV(sampleB);
float sharpinv = 1.0 / Sharpness;
float luma = (1.0 - sampleAYUV.r);
if (LumaIsExponential)
{
luma = exp2(luma * LumaExponent * LumaExponent * -C_log2_e);
}
float transition = sharpinv + luma * (1.0 - sharpinv);
transition -= TransitionTime;
transition *= Sharpness;
transition += 0.5;
transition = clamp(transition, 0., 1.);
float colorAlpha = TransitionColor.a;
if (ColorEase)
{
colorAlpha *= TransitionAlphaEase(TransitionTime);
}
sampleB.rgb = lerp(sampleB.rgb, sampleB.rgb * TransitionColor.rgb, colorAlpha); // implement transition coloration
return sampleB * (1.0 - transition) + sampleA * (transition);
//return transition;
}
float4 PSDarkColoredToLight(VertData v_in) : TARGET
{
float4 sampleA = InputA.Sample(def_sampler, v_in.uv);
float4 sampleB = InputB.Sample(def_sampler, v_in.uv);
float4 sampleAYUV = RGBtoYUV(sampleA);
float4 sampleBYUV = RGBtoYUV(sampleB);
float sharpinv = 1.0 / Sharpness;
float luma = sampleAYUV.r;
if (LumaIsExponential)
{
luma = exp2(luma * LumaExponent * LumaExponent * -C_log2_e);
}
float transition = sharpinv + luma * (1.0 - sharpinv);
transition -= TransitionTime;
transition *= Sharpness;
transition += 0.5;
transition = clamp(transition, 0., 1.);
float colorAlpha = TransitionColor.a;
if (ColorEase)
{
colorAlpha *= TransitionAlphaEase(TransitionTime);
}
sampleA.rgb = lerp(sampleA.rgb, sampleA.rgb * TransitionColor.rgb, colorAlpha); // implement transition coloration
return sampleB * (1.0 - transition) + sampleA * (transition);
//return transition;
}
float4 PSLightColoredToDark(VertData v_in) : TARGET
{
float4 sampleA = InputA.Sample(def_sampler, v_in.uv);
float4 sampleB = InputB.Sample(def_sampler, v_in.uv);
float4 sampleAYUV = RGBtoYUV(sampleA);
float4 sampleBYUV = RGBtoYUV(sampleB);
float sharpinv = 1.0 / Sharpness;
float luma = (1.0 - sampleAYUV.r);
if (LumaIsExponential)
{
luma = exp2(luma * LumaExponent * LumaExponent * -C_log2_e);
}
float transition = sharpinv + luma * (1.0 - sharpinv);
transition -= TransitionTime;
transition *= Sharpness;
transition += 0.5;
transition = clamp(transition, 0., 1.);
float colorAlpha = TransitionColor.a;
if (ColorEase)
{
colorAlpha *= TransitionAlphaEase(TransitionTime);
}
sampleA.rgb = lerp(sampleA.rgb, sampleA.rgb * TransitionColor.rgb, colorAlpha); // implement transition coloration
return sampleB * (1.0 - transition) + sampleA * (transition);
//return transition;
}
technique Draw
{
pass
{
vertex_shader = VSDefault(v_in);
pixel_shader = PSDefault(v_in);
}
}
technique DrawInverse
{
pass
@ -153,3 +303,59 @@ technique DrawInverse
pixel_shader = PSInverse(v_in);
}
}
technique LightToDark
{
pass
{
vertex_shader = VSDefault(v_in);
pixel_shader = PSInverse(v_in);
}
}
technique DarkToLight
{
pass
{
vertex_shader = VSDefault(v_in);
pixel_shader = PSDefault(v_in);
}
}
technique LightToDarkColored
{
pass
{
vertex_shader = VSDefault(v_in);
pixel_shader = PSLightToDarkColored(v_in);
}
}
technique DarkToLightColored
{
pass
{
vertex_shader = VSDefault(v_in);
pixel_shader = PSDarkToLightColored(v_in);
}
}
technique DarkColoredToLight
{
pass
{
vertex_shader = VSDefault(v_in);
pixel_shader = PSDarkColoredToLight(v_in);
}
}
technique LightColoredToDark
{
pass
{
vertex_shader = VSDefault(v_in);
pixel_shader = PSLightColoredToDark(v_in);
}
}