gtk2/gsk/resources/glsl/blend.glsl
Timm Bäder cc909b160f gl renderer: Rewrite shader builder
Use a unified approach to write both vertex and fragment shader in the
same file.
2020-01-07 17:27:15 +01:00

311 lines
6.4 KiB
GLSL

// VERTEX_SHADER:
void main() {
gl_Position = u_projection * u_modelview * vec4(aPosition, 0.0, 1.0);
vUv = vec2(aUv.x, aUv.y);
}
// FRAGMENT_SHADER:
uniform int u_mode;
uniform sampler2D u_source2;
float
combine (float source, float backdrop)
{
return source + backdrop * (1.0 - source);
}
vec4
composite (vec4 Cs, vec4 Cb, vec3 B)
{
float ao = Cs.a + Cb.a * (1.0 - Cs.a);
vec3 Co = (Cs.a*(1.0 - Cb.a)*Cs.rgb + Cs.a*Cb.a*B + (1.0 - Cs.a)*Cb.a*Cb.rgb) / ao;
return vec4(Co, ao);
}
vec4
normal (vec4 Cs, vec4 Cb)
{
return composite (Cs, Cb, Cs.rgb);
}
vec4
multiply (vec4 Cs, vec4 Cb)
{
return composite (Cs, Cb, Cs.rgb * Cb.rgb);
}
vec4
difference (vec4 Cs, vec4 Cb)
{
return composite (Cs, Cb, abs(Cs.rgb - Cb.rgb));
}
vec4
screen (vec4 Cs, vec4 Cb)
{
return composite (Cs, Cb, Cs.rgb + Cb.rgb - Cs.rgb * Cb.rgb);
}
float
hard_light (float source, float backdrop)
{
if (source <= 0.5)
return 2.0 * backdrop * source;
else
return 2.0 * (backdrop + source - backdrop * source) - 1.0;
}
vec4
hard_light (vec4 Cs, vec4 Cb)
{
vec3 B = vec3 (hard_light (Cs.r, Cb.r),
hard_light (Cs.g, Cb.g),
hard_light (Cs.b, Cb.b));
return composite (Cs, Cb, B);
}
float
soft_light (float source, float backdrop)
{
float db;
if (backdrop <= 0.25)
db = ((16.0 * backdrop - 12.0) * backdrop + 4.0) * backdrop;
else
db = sqrt (backdrop);
if (source <= 0.5)
return backdrop - (1.0 - 2.0 * source) * backdrop * (1.0 - backdrop);
else
return backdrop + (2.0 * source - 1.0) * (db - backdrop);
}
vec4
soft_light (vec4 Cs, vec4 Cb)
{
vec3 B = vec3 (soft_light (Cs.r, Cb.r),
soft_light (Cs.g, Cb.g),
soft_light (Cs.b, Cb.b));
return composite (Cs, Cb, B);
}
vec4
overlay (vec4 Cs, vec4 Cb)
{
vec3 B = vec3 (hard_light (Cb.r, Cs.r),
hard_light (Cb.g, Cs.g),
hard_light (Cb.b, Cs.b));
return composite (Cs, Cb, B);
}
vec4
darken (vec4 Cs, vec4 Cb)
{
vec3 B = min (Cs.rgb, Cb.rgb);
return composite (Cs, Cb, B);
}
vec4
lighten (vec4 Cs, vec4 Cb)
{
vec3 B = max (Cs.rgb, Cb.rgb);
return composite (Cs, Cb, B);
}
float
color_dodge (float source, float backdrop)
{
return (source == 1.0) ? source : min (backdrop / (1.0 - source), 1.0);
}
vec4
color_dodge (vec4 Cs, vec4 Cb)
{
vec3 B = vec3 (color_dodge (Cs.r, Cb.r),
color_dodge (Cs.g, Cb.g),
color_dodge (Cs.b, Cb.b));
return composite (Cs, Cb, B);
}
float
color_burn (float source, float backdrop)
{
return (source == 0.0) ? source : max ((1.0 - ((1.0 - backdrop) / source)), 0.0);
}
vec4
color_burn (vec4 Cs, vec4 Cb)
{
vec3 B = vec3 (color_burn (Cs.r, Cb.r),
color_burn (Cs.g, Cb.g),
color_burn (Cs.b, Cb.b));
return composite (Cs, Cb, B);
}
vec4
exclusion (vec4 Cs, vec4 Cb)
{
vec3 B = Cb.rgb + Cs.rgb - 2.0 * Cb.rgb * Cs.rgb;
return composite (Cs, Cb, B);
}
float
lum (vec3 c)
{
return 0.3 * c.r + 0.59 * c.g + 0.11 * c.b;
}
vec3
clip_color (vec3 c)
{
float l = lum (c);
float n = min (c.r, min (c.g, c.b));
float x = max (c.r, max (c.g, c.b));
if (n < 0.0) c = l + (((c - l) * l) / (l - n));
if (x > 1.0) c = l + (((c - l) * (1.0 - l)) / (x - l));
return c;
}
vec3
set_lum (vec3 c, float l)
{
float d = l - lum (c);
return clip_color (vec3 (c.r + d, c.g + d, c.b + d));
}
float
sat (vec3 c)
{
return max (c.r, max (c.g, c.b)) - min (c.r, min (c.g, c.b));
}
vec3
set_sat (vec3 c, float s)
{
float cmin = min (c.r, min (c.g, c.b));
float cmax = max (c.r, max (c.g, c.b));
vec3 res;
if (cmax == cmin)
res = vec3 (0, 0, 0);
else
{
if (c.r == cmax)
{
if (c.g == cmin)
{
res.b = ((c.b - cmin) * s) / (cmax - cmin);
res.g = 0.0;
}
else
{
res.g = ((c.g - cmin) * s) / (cmax - cmin);
res.b = 0.0;
}
res.r = s;
}
else if (c.g == cmax)
{
if (c.r == cmin)
{
res.b = ((c.b - cmin) * s) / (cmax - cmin);
res.r = 0.0;
}
else
{
res.r = ((c.r - cmin) * s) / (cmax - cmin);
res.b = 0.0;
}
res.g = s;
}
else
{
if (c.r == cmin)
{
res.g = ((c.g - cmin) * s) / (cmax - cmin);
res.r = 0.0;
}
else
{
res.r = ((c.r - cmin) * s) / (cmax - cmin);
res.g = 0.0;
}
res.b = s;
}
}
return res;
}
vec4
color (vec4 Cs, vec4 Cb)
{
vec3 B = set_lum (Cs.rgb, lum (Cb.rgb));
return composite (Cs, Cb, B);
}
vec4
hue (vec4 Cs, vec4 Cb)
{
vec3 B = set_lum (set_sat (Cs.rgb, sat (Cb.rgb)), lum (Cb.rgb));
return composite (Cs, Cb, B);
}
vec4
saturation (vec4 Cs, vec4 Cb)
{
vec3 B = set_lum (set_sat (Cb.rgb, sat (Cs.rgb)), lum (Cb.rgb));
return composite (Cs, Cb, B);
}
vec4
luminosity (vec4 Cs, vec4 Cb)
{
vec3 B = set_lum (Cb.rgb, lum (Cs.rgb));
return composite (Cs, Cb, B);
}
void main() {
vec4 bottom_color = Texture(u_source, vUv);
vec4 top_color = Texture(u_source2, vUv);
vec4 result;
if (u_mode == 0)
result = normal(top_color, bottom_color);
else if (u_mode == 1)
result = multiply(top_color, bottom_color);
else if (u_mode == 2)
result = screen(top_color, bottom_color);
else if (u_mode == 3)
result = overlay(top_color, bottom_color);
else if (u_mode == 4)
result = darken(top_color, bottom_color);
else if (u_mode == 5)
result = lighten(top_color, bottom_color);
else if (u_mode == 6)
result = color_dodge(top_color, bottom_color);
else if (u_mode == 7)
result = color_burn(top_color, bottom_color);
else if (u_mode == 8)
result = hard_light(top_color, bottom_color);
else if (u_mode == 9)
result = soft_light(top_color, bottom_color);
else if (u_mode == 10)
result = difference(top_color, bottom_color);
else if (u_mode == 11)
result = exclusion(top_color, bottom_color);
else if (u_mode == 12)
result = color(top_color, bottom_color);
else if (u_mode == 13)
result = hue(top_color, bottom_color);
else if (u_mode == 14)
result = saturation(top_color, bottom_color);
else if (u_mode == 15)
result = luminosity(top_color, bottom_color);
else
discard;
setOutputColor(result * u_alpha);
}