slang-shaders/handheld/shaders/simpletex_lcd/simpletex_lcd.slang

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2018-04-13 21:33:40 +10:00
#version 450
/*
simpletex_lcd - a simple, textured LCD shader intended for non-backlit systems
- Makes use of the 'line weighting' equation from zfast_lcd_standard
[original zfast_lcd_standard code copyright (C) 2017 Greg Hogan (SoltanGris42)]
Other code by jdgleaver
Usage notes:
- Background texture size is hard-coded (I can't find a way to get this
automatically...). User must ensure that 'BG_TEXTURE_SIZE' define is
set appropriately.
- Adjustable parameters:
> GRID_INTENSITY: Sets overall visibility of grid effect
- 1.0: Grid is shown
- 0.0: Grid is invisible (same colour as pixels)
> GRID_WIDTH: Sets effective with of grid lines
- 1.0: Normal full width
- 0.0: Minimum width
(Note - this does not mean zero width! Instead, this
is the minimum 'sane' width, below which the grid
becomes pointless...)
> GRID_BIAS: Dynamically adjusts the grid intensity based on pixel luminosity
- 0.0: Grid intensity is uniform
- 1.0: Grid intensity scales linearly with pixel luminosity
> i.e. the darker the pixel, the less the grid effect
is apparent - black pixels exhibit no grid effect at all
> DARKEN_GRID: Darkens grid (duh...)
- 0.0: Grid is white
- 1.0: Grid is black
> DARKEN_COLOUR: Simply darkens pixel colours (effectively lowers gamma level of pixels)
- 0.0: Colours are normal
- 2.0: Colours are too dark...
This program is free software; you can redistribute it and/or modify it
under the terms of the GNU General Public License as published by the Free
Software Foundation; either version 2 of the License, or (at your option)
any later version.
*/
// Background texture size
// > 2048 x 2048 textures are suitable for screen resolutions up to
// 1200p (or 1440p if running 'square' aspect ratio systems)
#define BG_TEXTURE_SIZE 2048.0
// > 4096 x 4096 textures are suitable for screen resolutions up to 4k
//#define BG_TEXTURE_SIZE 4096.0
#pragma parameter GRID_INTENSITY "Grid Intensity" 1.0 0.0 1.0 0.05
#pragma parameter GRID_WIDTH "Grid Width" 1.0 0.0 1.0 0.05
#pragma parameter GRID_BIAS "Grid Bias" 0.0 0.0 1.0 0.05
#pragma parameter DARKEN_GRID "Darken Grid" 0.0 0.0 1.0 0.05
#pragma parameter DARKEN_COLOUR "Darken Colours" 0.0 0.0 2.0 0.05
layout(push_constant) uniform Push
{
float GRID_INTENSITY;
float GRID_WIDTH;
float GRID_BIAS;
float DARKEN_GRID;
float DARKEN_COLOUR;
vec4 OutputSize;
vec4 OriginalSize;
vec4 SourceSize;
} registers;
layout(std140, set = 0, binding = 0) uniform UBO
{
mat4 MVP;
} global;
#pragma stage vertex
layout(location = 0) in vec4 Position;
layout(location = 1) in vec2 TexCoord;
layout(location = 0) out vec2 vTexCoord;
/*
VERTEX_SHADER
*/
void main()
{
gl_Position = global.MVP * Position;
vTexCoord = TexCoord;
}
#pragma stage fragment
layout(location = 0) in vec2 vTexCoord;
layout(location = 0) out vec4 FragColor;
layout(set = 0, binding = 2) uniform sampler2D Source;
layout(set = 0, binding = 3) uniform sampler2D BACKGROUND;
// ### Magic Numbers...
// Grid pattern
// > Line weighting equation:
// y = a * (x^4 - b * x^6)
const float LINE_WEIGHT_A = 48.0;
const float LINE_WEIGHT_B = 8.0 / 3.0;
// RGB -> Luminosity conversion
// > Photometric/digital ITU BT.709
#define LUMA_R 0.2126
#define LUMA_G 0.7152
#define LUMA_B 0.0722
// > Digital ITU BT.601
//#define LUMA_R 0.299
//#define LUMA_G 0.587
//#define LUMA_B 0.114
// Background texture size
const float INV_BG_TEXTURE_SIZE = 1.0 / BG_TEXTURE_SIZE;
/*
FRAGMENT SHADER
*/
void main()
{
// Get current texture coordinate
vec2 imgPixelCoord = vTexCoord.xy * registers.SourceSize.xy;
vec2 imgCenterCoord = floor(imgPixelCoord.xy) + vec2(0.5, 0.5);
// Get colour of current pixel
vec3 colour = texture(Source, registers.SourceSize.zw * imgCenterCoord.xy).rgb;
// Darken colours (if required...)
colour.rgb = pow(colour.rgb, vec3(1.0 + registers.DARKEN_COLOUR));
// Generate grid pattern...
vec2 distFromCenter = abs(imgCenterCoord.xy - imgPixelCoord.xy);
float xSquared = max(distFromCenter.x, distFromCenter.y);
xSquared = xSquared * xSquared;
float xQuarted = xSquared * xSquared;
// > Line weighting equation:
// y = 48 * (x^4 - (8/3) * x^6)
float lineWeight = LINE_WEIGHT_A * (xQuarted - (LINE_WEIGHT_B * xQuarted * xSquared));
// > Apply grid adjustments (phase 1)
// - GRID_WIDTH:
// 1.0: Use raw lineWeight value
// 0.0: Use lineWeight ^ 2 (makes lines thinner - realistically, this is
// the thinnest we can go before the grid effect
// becomes pointless, particularly with 'high resolution'
// systems like the GBA)
// - GRID_INTENSITY:
// 1.0: Grid lines are white
// 0.0: Grid lines are invisible
lineWeight = lineWeight * (lineWeight + ((1.0 - lineWeight) * registers.GRID_WIDTH)) * registers.GRID_INTENSITY;
// > Apply grid adjustments (phase 2)
// - GRID_BIAS:
// 0.0: Use 'unbiased' lineWeight value calculated above
// 1.0: Scale lineWeight by current pixel luminosity
// > i.e. the darker the pixel, the lower the intensity of the grid
float luma = (LUMA_R * colour.r) + (LUMA_G * colour.g) + (LUMA_B * colour.b);
lineWeight = lineWeight * (luma + ((1.0 - luma) * (1.0 - registers.GRID_BIAS)));
// Apply grid pattern
// (lineWeight == 1 -> set colour to value specified by DARKEN_GRID)
colour.rgb = mix(colour.rgb, vec3(1.0 - registers.DARKEN_GRID), lineWeight);
// Get background sample point
// > NB: external texture coordinates are referenced in a completely different fashion
// here than they are in GLSL shaders...
vec2 bgPixelCoord = floor(vTexCoord.xy * registers.OutputSize.xy) + vec2(0.5, 0.5);
// Sample background texture and 'colourise' according to current pixel colour
// (NB: the 'colourisation' here is lame, but the proper method is slow...)
vec3 bgTexture = texture(BACKGROUND, bgPixelCoord.xy * INV_BG_TEXTURE_SIZE).rgb * colour.rgb;
// Blend current pixel with background according to luminosity
// (lighter colour == more transparent, more visible background)
// Note: Have to calculate luminosity a second time... tiresome, but
// it's not a particulary expensive operation...
luma = (LUMA_R * colour.r) + (LUMA_G * colour.g) + (LUMA_B * colour.b);
colour.rgb = mix(colour.rgb, bgTexture.rgb, luma);
FragColor = vec4(colour.rgb, 1.0);
}