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bdnugget
2026-05-05 23:15:08 +02:00
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zig-pkg/raylib-6.0.0-whq8uCSwLgWWeF3ec3dbG6Rr36SLFL-s2WJ1Q_2E22Bb/examples/shaders/resources/LICENSE.md Normal file
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| resource | author | licence | notes |
| :----------------- | :-----------: | :------ | :---- |
| models/barracks.obj,<br> models/barracks_diffuse.png | [Alberto Cano](https://www.artstation.com/albertocano) | [CC-BY-NC](https://creativecommons.org/licenses/by-nc/4.0/legalcode) | - |
| models/church.obj,<br> models/church_diffuse.png | [Alberto Cano](https://www.artstation.com/albertocano) | [CC-BY-NC](https://creativecommons.org/licenses/by-nc/4.0/legalcode) | - |
| models/watermill.obj,<br> models/watermill_diffuse.png | [Alberto Cano](https://www.artstation.com/albertocano) | [CC-BY-NC](https://creativecommons.org/licenses/by-nc/4.0/legalcode) | - |
| fudesumi.png | [Eiden Marsal](https://www.artstation.com/marshall_z) | [CC-BY-NC](https://creativecommons.org/licenses/by-nc/4.0/) | - |
| mask.png | [@raysan5](https://github.com/raysan5) | [CC0](https://creativecommons.org/publicdomain/zero/1.0/) | Made with [EffectTextureMaker](https://mebiusbox.github.io/contents/EffectTextureMaker/) |
| plasma.png | [@chriscamacho](https://github.com/chriscamacho) | [CC0](https://creativecommons.org/publicdomain/zero/1.0/) | - |
| raysan.png | [@raysan5](https://github.com/raysan5) | [CC0](https://creativecommons.org/publicdomain/zero/1.0/) | - |
| space.png | ❔ | ❔ | - |
| texel_checker.png | [@raysan5](https://github.com/raysan5) | [CC0](https://creativecommons.org/publicdomain/zero/1.0/) | Made with [UV Checker Map Maker](http://uvchecker.byvalle.com/) |
| cubicmap.png | [@raysan5](https://github.com/raysan5) | [CC0](https://creativecommons.org/publicdomain/zero/1.0/) | - |
| spark_flame.png | [@raysan5](https://github.com/raysan5) | [CC0](https://creativecommons.org/publicdomain/zero/1.0/) | Made with [EffectTextureMaker](https://mebiusbox.github.io/contents/EffectTextureMaker/) |
| parrots.png | [Kodak set](http://r0k.us/graphics/kodak/) | ❔ | Original name: `kodim23.png` |
| cat.png | ❔ | ❔ | - |
| mandrill.png | ❔ | [CC0](https://creativecommons.org/publicdomain/zero/1.0/) | Mandrill (a.k.a. Baboon) |

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zig-pkg/raylib-6.0.0-whq8uCSwLgWWeF3ec3dbG6Rr36SLFL-s2WJ1Q_2E22Bb/examples/shaders/resources/shaders/glsl100/ascii.fs Normal file
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#version 100
precision mediump float;
// Input from the vertex shader
varying vec2 fragTexCoord;
// Output color for the screen
varying vec4 finalColor;
uniform sampler2D texture0;
uniform vec2 resolution;
// Fontsize less then 9 may be not complete
uniform float fontSize;
float GreyScale(in vec3 col)
{
return dot(col, vec3(0.2126, 0.7152, 0.0722));
}
float GetCharacter(float n, vec2 p)
{
p = floor(p*vec2(-4.0, 4.0) + 2.5);
// Check if the calculated coordinate is inside the 5x5 grid (from 0.0 to 4.0)
if (clamp(p.x, 0.0, 4.0) == p.x && clamp(p.y, 0.0, 4.0) == p.y)
{
float a = floor(p.x + 0.5) + 5.0*floor(p.y + 0.5);
// This checked if the 'a'-th bit of 'n' was set
float shiftedN = floor(n/pow(2.0, a));
if (mod(shiftedN, 2.0) == 1.0)
{
return 1.0; // The bit is on
}
}
return 0.0; // The bit is off, or we are outside the grid
}
// -----------------------------------------------------------------------------
// Main shader logic
// -----------------------------------------------------------------------------
void main()
{
vec2 charPixelSize = vec2(fontSize, fontSize);
vec2 uvCellSize = charPixelSize/resolution;
// The cell size is based on the fontSize set by application
vec2 cellUV = floor(fragTexCoord/uvCellSize)*uvCellSize;
vec3 cellColor = texture2D(texture0, cellUV).rgb;
// Gray is used to define what character will be selected to draw
float gray = GreyScale(cellColor);
float n = 4096.0;
// Character set from https://www.shadertoy.com/view/lssGDj
// Create new bitmaps https://thrill-project.com/archiv/coding/bitmap/
if (gray > 0.2) n = 65600.0; // :
if (gray > 0.3) n = 18725316.0; // v
if (gray > 0.4) n = 15255086.0; // o
if (gray > 0.5) n = 13121101.0; // &
if (gray > 0.6) n = 15252014.0; // 8
if (gray > 0.7) n = 13195790.0; // @
if (gray > 0.8) n = 11512810.0; // #
vec2 localUV = (fragTexCoord - cellUV)/uvCellSize; // Range [0.0, 1.0]
vec2 p = localUV*2.0 - 1.0; // Range [-1.0, 1.0]
// cellColor and charShape will define the color of the char
vec3 color = cellColor*GetCharacter(n, p);
gl_FragColor = vec4(color, 1.0);
}

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zig-pkg/raylib-6.0.0-whq8uCSwLgWWeF3ec3dbG6Rr36SLFL-s2WJ1Q_2E22Bb/examples/shaders/resources/shaders/glsl100/base.fs Normal file
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#version 100
precision mediump float;
// Input vertex attributes (from vertex shader)
varying vec2 fragTexCoord;
varying vec4 fragColor;
// Input uniform values
uniform sampler2D texture0;
uniform vec4 colDiffuse;
// NOTE: Add your custom variables here
void main()
{
// Texel color fetching from texture sampler
vec4 texelColor = texture2D(texture0, fragTexCoord);
// NOTE: Implement here your fragment shader code
gl_FragColor = texelColor*colDiffuse;
}

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zig-pkg/raylib-6.0.0-whq8uCSwLgWWeF3ec3dbG6Rr36SLFL-s2WJ1Q_2E22Bb/examples/shaders/resources/shaders/glsl100/base.vs Normal file
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#version 100
// Input vertex attributes
attribute vec3 vertexPosition;
attribute vec2 vertexTexCoord;
attribute vec3 vertexNormal;
attribute vec4 vertexColor;
// Input uniform values
uniform mat4 mvp;
// Output vertex attributes (to fragment shader)
varying vec2 fragTexCoord;
varying vec4 fragColor;
// NOTE: Add your custom variables here
void main()
{
// Send vertex attributes to fragment shader
fragTexCoord = vertexTexCoord;
fragColor = vertexColor;
// Calculate final vertex position
gl_Position = mvp*vec4(vertexPosition, 1.0);
}

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zig-pkg/raylib-6.0.0-whq8uCSwLgWWeF3ec3dbG6Rr36SLFL-s2WJ1Q_2E22Bb/examples/shaders/resources/shaders/glsl100/bloom.fs Normal file
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#version 100
precision mediump float;
// Input vertex attributes (from vertex shader)
varying vec2 fragTexCoord;
varying vec4 fragColor;
// Input uniform values
uniform sampler2D texture0;
uniform vec4 colDiffuse;
// NOTE: Add your custom variables here
const vec2 size = vec2(800, 450); // Framebuffer size
const float samples = 5.0; // Pixels per axis; higher = bigger glow, worse performance
const float quality = 2.5; // Defines size factor: Lower = smaller glow, better quality
void main()
{
vec4 sum = vec4(0);
vec2 sizeFactor = vec2(1)/size*quality;
// Texel color fetching from texture sampler
vec4 source = texture2D(texture0, fragTexCoord);
const int range = 2; // should be = (samples - 1)/2;
for (int x = -range; x <= range; x++)
{
for (int y = -range; y <= range; y++)
{
sum += texture2D(texture0, fragTexCoord + vec2(x, y)*sizeFactor);
}
}
// Calculate final fragment color
gl_FragColor = ((sum/(samples*samples)) + source)*colDiffuse;
}

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#version 100
precision mediump float;
// Input vertex attributes (from vertex shader)
varying vec2 fragTexCoord;
varying vec4 fragColor;
// Input uniform values
uniform sampler2D texture0;
uniform vec4 colDiffuse;
// NOTE: Add your custom variables here
// NOTE: Render size values must be passed from code
const float renderWidth = 800.0;
const float renderHeight = 450.0;
vec3 offset = vec3(0.0, 1.3846153846, 3.2307692308);
vec3 weight = vec3(0.2270270270, 0.3162162162, 0.0702702703);
void main()
{
// Texel color fetching from texture sampler
vec3 tc = texture2D(texture0, fragTexCoord).rgb*weight.x;
tc += texture2D(texture0, fragTexCoord + vec2(offset.y)/renderWidth, 0.0).rgb*weight.y;
tc += texture2D(texture0, fragTexCoord - vec2(offset.y)/renderWidth, 0.0).rgb*weight.y;
tc += texture2D(texture0, fragTexCoord + vec2(offset.z)/renderWidth, 0.0).rgb*weight.z;
tc += texture2D(texture0, fragTexCoord - vec2(offset.z)/renderWidth, 0.0).rgb*weight.z;
gl_FragColor = vec4(tc, 1.0);
}

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zig-pkg/raylib-6.0.0-whq8uCSwLgWWeF3ec3dbG6Rr36SLFL-s2WJ1Q_2E22Bb/examples/shaders/resources/shaders/glsl100/cel.fs Normal file
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#version 100
precision mediump float;
varying vec3 fragPosition;
varying vec2 fragTexCoord;
varying vec4 fragColor;
varying vec3 fragNormal;
uniform sampler2D texture0;
uniform vec4 colDiffuse;
uniform vec3 viewPos;
uniform float numBands;
struct Light {
int enabled;
int type;
vec3 position;
vec3 target;
vec4 color;
};
uniform Light lights[4];
void main()
{
vec4 texColor = texture2D(texture0, fragTexCoord);
vec3 baseColor = texColor.rgb * fragColor.rgb * colDiffuse.rgb;
vec3 norm = normalize(fragNormal);
float lightAccum = 0.08; // ambient floor
for (int i = 0; i < 4; i++)
{
if (lights[i].enabled == 1) // no continue in GLSL ES 1.0
{
vec3 lightDir;
if (lights[i].type == 0)
{
// Directional: direction is from position toward target.
lightDir = normalize(lights[i].position - lights[i].target);
}
else
{
// Point: direction from surface to light.
lightDir = normalize(lights[i].position - fragPosition);
}
float NdotL = max(dot(norm, lightDir), 0.0);
// Quantize NdotL into numBands discrete steps.
float quantized = min(floor(NdotL * numBands), numBands - 1.0) / (numBands - 1.0);
lightAccum += quantized * lights[i].color.r;
}
}
lightAccum = clamp(lightAccum, 0.0, 1.0);
gl_FragColor = vec4(baseColor * lightAccum, texColor.a * colDiffuse.a);
}

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zig-pkg/raylib-6.0.0-whq8uCSwLgWWeF3ec3dbG6Rr36SLFL-s2WJ1Q_2E22Bb/examples/shaders/resources/shaders/glsl100/cel.vs Normal file
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#version 100
attribute vec3 vertexPosition;
attribute vec2 vertexTexCoord;
attribute vec3 vertexNormal;
attribute vec4 vertexColor;
uniform mat4 mvp;
uniform mat4 matModel;
varying vec3 fragPosition;
varying vec2 fragTexCoord;
varying vec4 fragColor;
varying vec3 fragNormal;
mat3 inverse(mat3 m)
{
float a00 = m[0][0], a01 = m[0][1], a02 = m[0][2];
float a10 = m[1][0], a11 = m[1][1], a12 = m[1][2];
float a20 = m[2][0], a21 = m[2][1], a22 = m[2][2];
float b01 = a22*a11 - a12*a21;
float b11 = -a22*a10 + a12*a20;
float b21 = a21*a10 - a11*a20;
float det = a00*b01 + a01*b11 + a02*b21;
return mat3(b01, (-a22*a01 + a02*a21), ( a12*a01 - a02*a11),
b11, ( a22*a00 - a02*a20), (-a12*a00 + a02*a10),
b21, (-a21*a00 + a01*a20), ( a11*a00 - a01*a10)) / det;
}
mat3 transpose(mat3 m)
{
return mat3(m[0][0], m[1][0], m[2][0],
m[0][1], m[1][1], m[2][1],
m[0][2], m[1][2], m[2][2]);
}
void main()
{
fragPosition = vec3(matModel * vec4(vertexPosition, 1.0));
fragTexCoord = vertexTexCoord;
fragColor = vertexColor;
mat3 normalMatrix = transpose(inverse(mat3(matModel)));
fragNormal = normalize(normalMatrix * vertexNormal);
gl_Position = mvp * vec4(vertexPosition, 1.0);
}

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zig-pkg/raylib-6.0.0-whq8uCSwLgWWeF3ec3dbG6Rr36SLFL-s2WJ1Q_2E22Bb/examples/shaders/resources/shaders/glsl100/color_correction.fs Normal file
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#version 100
precision mediump float;
// Input vertex attributes (from vertex shader)
varying vec2 fragTexCoord;
varying vec4 fragColor;
// Input uniform values
uniform sampler2D texture0;
uniform vec4 colDiffuse;
uniform float contrast;
uniform float saturation;
uniform float brightness;
void main()
{
// Get texel color
vec4 texel = texture2D(texture0, fragTexCoord);
// Apply contrast
texel.rgb = (texel.rgb - 0.5)*(contrast/100.0 + 1.0) + 0.5;
// Apply brightness
texel.rgb = texel.rgb + brightness/100.0;
// Apply saturation
float intensity = dot(texel.rgb, vec3(0.299, 0.587, 0.114));
texel.rgb = (texel.rgb - intensity)*saturation/100.0 + texel.rgb;
// Output resulting color
gl_FragColor = texel;
}

26
zig-pkg/raylib-6.0.0-whq8uCSwLgWWeF3ec3dbG6Rr36SLFL-s2WJ1Q_2E22Bb/examples/shaders/resources/shaders/glsl100/color_mix.fs Normal file
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#version 100
precision mediump float;
// Input vertex attributes (from vertex shader)
varying vec2 fragTexCoord;
varying vec4 fragColor;
// Input uniform values
uniform sampler2D texture0;
uniform sampler2D texture1;
uniform vec4 colDiffuse;
uniform float divider;
void main()
{
// Texel color fetching from texture sampler
vec4 texelColor0 = texture2D(texture0, fragTexCoord);
vec4 texelColor1 = texture2D(texture1, fragTexCoord);
float x = fract(fragTexCoord.s);
float final = smoothstep(divider - 0.1, divider + 0.1, x);
gl_FragColor = mix(texelColor0, texelColor1, final);
}

47
zig-pkg/raylib-6.0.0-whq8uCSwLgWWeF3ec3dbG6Rr36SLFL-s2WJ1Q_2E22Bb/examples/shaders/resources/shaders/glsl100/cross_hatching.fs Normal file
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# version 100
precision mediump float;
// Input vertex attributes (from vertex shader)
varying vec2 fragTexCoord;
varying vec4 fragColor;
// Input uniform values
uniform sampler2D texture0;
uniform vec4 colDiffuse;
// NOTE: Add your custom variables here
float hatchOffsetY = 5.0;
float lumThreshold01 = 0.9;
float lumThreshold02 = 0.7;
float lumThreshold03 = 0.5;
float lumThreshold04 = 0.3;
void main()
{
vec3 tc = vec3(1.0, 1.0, 1.0);
float lum = length(texture2D(texture0, fragTexCoord).rgb);
if (lum < lumThreshold01)
{
if (mod(gl_FragCoord.x + gl_FragCoord.y, 10.0) == 0.0) tc = vec3(0.0, 0.0, 0.0);
}
if (lum < lumThreshold02)
{
if (mod(gl_FragCoord .x - gl_FragCoord .y, 10.0) == 0.0) tc = vec3(0.0, 0.0, 0.0);
}
if (lum < lumThreshold03)
{
if (mod(gl_FragCoord .x + gl_FragCoord .y - hatchOffsetY, 10.0) == 0.0) tc = vec3(0.0, 0.0, 0.0);
}
if (lum < lumThreshold04)
{
if (mod(gl_FragCoord .x - gl_FragCoord .y - hatchOffsetY, 10.0) == 0.0) tc = vec3(0.0, 0.0, 0.0);
}
gl_FragColor = vec4(tc, 1.0);
}

57
zig-pkg/raylib-6.0.0-whq8uCSwLgWWeF3ec3dbG6Rr36SLFL-s2WJ1Q_2E22Bb/examples/shaders/resources/shaders/glsl100/cross_stitching.fs Normal file
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# version 100
precision mediump float;
// Input vertex attributes (from vertex shader)
varying vec2 fragTexCoord;
varying vec4 fragColor;
// Input uniform values
uniform sampler2D texture0;
uniform vec4 colDiffuse;
// NOTE: Add your custom variables here
// NOTE: Render size values must be passed from code
const float renderWidth = 800.0;
const float renderHeight = 450.0;
float stitchingSize = 6.0;
int invert = 0;
vec4 PostFX(sampler2D tex, vec2 uv)
{
vec4 c = vec4(0.0);
float size = stitchingSize;
vec2 cPos = uv*vec2(renderWidth, renderHeight);
vec2 tlPos = floor(cPos/vec2(size, size));
tlPos *= size;
int remX = int(mod(cPos.x, size));
int remY = int(mod(cPos.y, size));
if (remX == 0 && remY == 0) tlPos = cPos;
vec2 blPos = tlPos;
blPos.y += (size - 1.0);
if ((remX == remY) || (((int(cPos.x) - int(blPos.x)) == (int(blPos.y) - int(cPos.y)))))
{
if (invert == 1) c = vec4(0.2, 0.15, 0.05, 1.0);
else c = texture2D(tex, tlPos*vec2(1.0/renderWidth, 1.0/renderHeight))*1.4;
}
else
{
if (invert == 1) c = texture2D(tex, tlPos*vec2(1.0/renderWidth, 1.0/renderHeight))*1.4;
else c = vec4(0.0, 0.0, 0.0, 1.0);
}
return c;
}
void main()
{
vec3 tc = PostFX(texture0, fragTexCoord).rgb;
gl_FragColor = vec4(tc, 1.0);
}

60
zig-pkg/raylib-6.0.0-whq8uCSwLgWWeF3ec3dbG6Rr36SLFL-s2WJ1Q_2E22Bb/examples/shaders/resources/shaders/glsl100/cubes_panning.fs Normal file
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#version 100
precision mediump float;
// Input vertex attributes (from vertex shader)
varying vec2 fragTexCoord;
varying vec4 fragColor;
// Custom variables
const float PI = 3.14159265358979323846;
uniform float uTime;
float divisions = 5.0;
float angle = 0.0;
vec2 VectorRotateTime(vec2 v, float speed)
{
float time = uTime*speed;
float localTime = fract(time); // The time domain this works on is 1 sec
if ((localTime >= 0.0) && (localTime < 0.25)) angle = 0.0;
else if ((localTime >= 0.25) && (localTime < 0.50)) angle = PI/4.0*sin(2.0*PI*localTime - PI/2.0);
else if ((localTime >= 0.50) && (localTime < 0.75)) angle = PI*0.25;
else if ((localTime >= 0.75) && (localTime < 1.00)) angle = PI/4.0*sin(2.0*PI*localTime);
// Rotate vector by angle
v -= 0.5;
v = mat2(cos(angle), -sin(angle), sin(angle), cos(angle))*v;
v += 0.5;
return v;
}
float Rectangle(in vec2 st, in float size, in float fill)
{
float roundSize = 0.5 - size/2.0;
float left = step(roundSize, st.x);
float top = step(roundSize, st.y);
float bottom = step(roundSize, 1.0 - st.y);
float right = step(roundSize, 1.0 - st.x);
return (left*bottom*right*top)*fill;
}
void main()
{
vec2 fragPos = fragTexCoord;
fragPos.xy += uTime/9.0;
fragPos *= divisions;
vec2 ipos = floor(fragPos); // Get the integer coords
vec2 fpos = fract(fragPos); // Get the fractional coords
fpos = VectorRotateTime(fpos, 0.2);
float alpha = Rectangle(fpos, 0.216, 1.0);
vec3 color = vec3(0.3, 0.3, 0.3);
gl_FragColor = vec4(color, alpha);
}

59
zig-pkg/raylib-6.0.0-whq8uCSwLgWWeF3ec3dbG6Rr36SLFL-s2WJ1Q_2E22Bb/examples/shaders/resources/shaders/glsl100/deferred_shading.fs Normal file
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#version 100
precision mediump float;
// Input vertex attributes (from vertex shader)
varying vec2 fragTexCoord;
varying vec4 fragColor;
// Input uniform values
uniform sampler2D gPosition;
uniform sampler2D gNormal;
uniform sampler2D gAlbedoSpec;
struct Light {
int enabled;
int type; // Unused in this demo
vec3 position;
vec3 target; // Unused in this demo
vec4 color;
};
const int NR_LIGHTS = 4;
uniform Light lights[NR_LIGHTS];
uniform vec3 viewPosition;
const float QUADRATIC = 0.032;
const float LINEAR = 0.09;
void main()
{
vec3 fragPosition = texture2D(gPosition, fragTexCoord).rgb;
vec3 normal = texture2D(gNormal, fragTexCoord).rgb;
vec3 albedo = texture2D(gAlbedoSpec, fragTexCoord).rgb;
float specular = texture2D(gAlbedoSpec, fragTexCoord).a;
vec3 ambient = albedo*vec3(0.1);
vec3 viewDirection = normalize(viewPosition - fragPosition);
for (int i = 0; i < NR_LIGHTS; i++)
{
if (lights[i].enabled == 0) continue;
vec3 lightDirection = lights[i].position - fragPosition;
vec3 diffuse = max(dot(normal, lightDirection), 0.0)*albedo*lights[i].color.xyz;
vec3 halfwayDirection = normalize(lightDirection + viewDirection);
float spec = pow(max(dot(normal, halfwayDirection), 0.0), 32.0);
vec3 specular = specular*spec*lights[i].color.xyz;
// Attenuation
float distance = length(lights[i].position - fragPosition);
float attenuation = 1.0/(1.0 + LINEAR*distance + QUADRATIC*distance*distance);
diffuse *= attenuation;
specular *= attenuation;
ambient += diffuse + specular;
}
gl_FragColor = vec4(ambient, 1.0);
}

16
zig-pkg/raylib-6.0.0-whq8uCSwLgWWeF3ec3dbG6Rr36SLFL-s2WJ1Q_2E22Bb/examples/shaders/resources/shaders/glsl100/deferred_shading.vs Normal file
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#version 100
// Input vertex attributes
attribute vec3 vertexPosition;
attribute vec2 vertexTexCoord;
// Output vertex attributes (to fragment shader)
varying vec2 fragTexCoord;
void main()
{
fragTexCoord = vertexTexCoord;
// Calculate final vertex position
gl_Position = vec4(vertexPosition, 1.0);
}

29
zig-pkg/raylib-6.0.0-whq8uCSwLgWWeF3ec3dbG6Rr36SLFL-s2WJ1Q_2E22Bb/examples/shaders/resources/shaders/glsl100/depth_render.fs Normal file
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#version 100
precision mediump float;
// Input vertex attributes (from vertex shader)
varying vec2 fragTexCoord;
// Input uniform values
uniform sampler2D depthTexture;
uniform bool flipY;
float nearPlane = 0.1;
float farPlane = 100.0;
void main()
{
// Handle potential Y-flipping
vec2 texCoord = fragTexCoord;
if (flipY) texCoord.y = 1.0 - texCoord.y;
// Sample depth texture
float depth = texture2D(depthTexture, texCoord).r;
// Linearize depth
float linearDepth = (2.0*nearPlane)/(farPlane + nearPlane - depth*(farPlane - nearPlane));
// Output final color
gl_FragColor = vec4(vec3(linearDepth), 1.0);
}

20
zig-pkg/raylib-6.0.0-whq8uCSwLgWWeF3ec3dbG6Rr36SLFL-s2WJ1Q_2E22Bb/examples/shaders/resources/shaders/glsl100/depth_write.fs Normal file
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#version 100
#extension GL_EXT_frag_depth : enable
precision mediump float;
// Input vertex attributes (from vertex shader)
varying vec2 fragTexCoord;
varying vec4 fragColor;
// Input uniform values
uniform sampler2D texture0;
uniform vec4 colDiffuse;
void main()
{
vec4 texelColor = texture2D(texture0, fragTexCoord);
gl_FragColor = texelColor*colDiffuse*fragColor;
gl_FragDepthEXT = 1.0 - gl_FragCoord.z;
}

54
zig-pkg/raylib-6.0.0-whq8uCSwLgWWeF3ec3dbG6Rr36SLFL-s2WJ1Q_2E22Bb/examples/shaders/resources/shaders/glsl100/distortion.fs Normal file
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#version 100
precision mediump float;
// Input vertex attributes (from vertex shader)
varying vec2 fragTexCoord;
// Input uniform values
uniform sampler2D texture0;
// NOTE: Default parameters for Oculus Rift DK2 device
const vec2 LeftLensCenter = vec2(0.2863248, 0.5);
const vec2 RightLensCenter = vec2(0.7136753, 0.5);
const vec2 LeftScreenCenter = vec2(0.25, 0.5);
const vec2 RightScreenCenter = vec2(0.75, 0.5);
const vec2 Scale = vec2(0.25, 0.45);
const vec2 ScaleIn = vec2(4.0, 2.5);
const vec4 HmdWarpParam = vec4(1.0, 0.22, 0.24, 0.0);
const vec4 ChromaAbParam = vec4(0.996, -0.004, 1.014, 0.0);
void main()
{
// The following two variables need to be set per eye
vec2 LensCenter = fragTexCoord.x < 0.5 ? LeftLensCenter : RightLensCenter;
vec2 ScreenCenter = fragTexCoord.x < 0.5 ? LeftScreenCenter : RightScreenCenter;
// Scales input texture coordinates for distortion: vec2 HmdWarp(vec2 fragTexCoord, vec2 LensCenter)
vec2 theta = (fragTexCoord - LensCenter)*ScaleIn; // Scales to [-1, 1]
float rSq = theta.x*theta.x + theta.y*theta.y;
vec2 theta1 = theta*(HmdWarpParam.x + HmdWarpParam.y*rSq + HmdWarpParam.z*rSq*rSq + HmdWarpParam.w*rSq*rSq*rSq);
//vec2 tc = LensCenter + Scale*theta1;
// Detect whether blue texture coordinates are out of range since these will scaled out the furthest
vec2 thetaBlue = theta1*(ChromaAbParam.z + ChromaAbParam.w*rSq);
vec2 tcBlue = LensCenter + Scale*thetaBlue;
if (any(bvec2(clamp(tcBlue, ScreenCenter - vec2(0.25, 0.5), ScreenCenter + vec2(0.25, 0.5)) - tcBlue))) gl_FragColor = vec4(0.0, 0.0, 0.0, 1.0);
else
{
// Do blue texture lookup
float blue = texture2D(texture0, tcBlue).b;
// Do green lookup (no scaling)
vec2 tcGreen = LensCenter + Scale*theta1;
float green = texture2D(texture0, tcGreen).g;
// Do red scale and lookup
vec2 thetaRed = theta1*(ChromaAbParam.x + ChromaAbParam.y*rSq);
vec2 tcRed = LensCenter + Scale*thetaRed;
float red = texture2D(texture0, tcRed).r;
gl_FragColor = vec4(red, green, blue, 1.0);
}
}

37
zig-pkg/raylib-6.0.0-whq8uCSwLgWWeF3ec3dbG6Rr36SLFL-s2WJ1Q_2E22Bb/examples/shaders/resources/shaders/glsl100/dream_vision.fs Normal file
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#version 100
precision mediump float;
// Input vertex attributes (from vertex shader)
varying vec2 fragTexCoord;
varying vec4 fragColor;
// Input uniform values
uniform sampler2D texture0;
uniform vec4 colDiffuse;
// NOTE: Add your custom variables here
void main()
{
vec4 color = texture2D(texture0, fragTexCoord);
color += texture2D(texture0, fragTexCoord + 0.001);
color += texture2D(texture0, fragTexCoord + 0.003);
color += texture2D(texture0, fragTexCoord + 0.005);
color += texture2D(texture0, fragTexCoord + 0.007);
color += texture2D(texture0, fragTexCoord + 0.009);
color += texture2D(texture0, fragTexCoord + 0.011);
color += texture2D(texture0, fragTexCoord - 0.001);
color += texture2D(texture0, fragTexCoord - 0.003);
color += texture2D(texture0, fragTexCoord - 0.005);
color += texture2D(texture0, fragTexCoord - 0.007);
color += texture2D(texture0, fragTexCoord - 0.009);
color += texture2D(texture0, fragTexCoord - 0.011);
color.rgb = vec3((color.r + color.g + color.b)/3.0);
color = color/9.5;
gl_FragColor = color;
}

60
zig-pkg/raylib-6.0.0-whq8uCSwLgWWeF3ec3dbG6Rr36SLFL-s2WJ1Q_2E22Bb/examples/shaders/resources/shaders/glsl100/eratosthenes.fs Normal file
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#version 100
precision mediump float;
/*************************************************************************************
The Sieve of Eratosthenes -- a simple shader by ProfJski
An early prime number sieve: https://en.wikipedia.org/wiki/Sieve_of_Eratosthenes
The screen is divided into a square grid of boxes, each representing an integer value
Each integer is tested to see if it is a prime number. Primes are colored white
Non-primes are colored with a color that indicates the smallest factor which evenly divdes our integer
You can change the scale variable to make a larger or smaller grid
Total number of integers displayed = scale squared, so scale = 100 tests the first 10,000 integers
WARNING: If you make scale too large, your GPU may bog down!
***************************************************************************************/
// Input vertex attributes (from vertex shader)
varying vec2 fragTexCoord;
varying vec4 fragColor;
// Make a nice spectrum of colors based on counter and maxSize
vec4 Colorizer(float counter, float maxSize)
{
float red = 0.0, green = 0.0, blue = 0.0;
float normsize = counter/maxSize;
red = smoothstep(0.3, 0.7, normsize);
green = sin(3.14159*normsize);
blue = 1.0 - smoothstep(0.0, 0.4, normsize);
return vec4(0.8*red, 0.8*green, 0.8*blue, 1.0);
}
void main()
{
vec4 color = vec4(1.0);
float scale = 1000.0; // Makes 100x100 square grid. Change this variable to make a smaller or larger grid
float value = scale*floor(fragTexCoord.y*scale) + floor(fragTexCoord.x*scale); // Group pixels into boxes representing integer values
int valuei = int(value);
//if ((valuei == 0) || (valuei == 1) || (valuei == 2)) gl_FragColor = vec4(1.0);
//else
{
//for (int i = 2; (i < int(max(2.0, sqrt(value) + 1.0))); i++)
// NOTE: On GLSL 100 for loops are restricted and loop condition must be a constant
// Tested on RPI, it seems loops are limited around 60 iteractions
for (int i = 2; i < 48; i++)
{
if ((value - float(i)*floor(value/float(i))) <= 0.0)
{
gl_FragColor = Colorizer(float(i), scale);
//break; // Uncomment to color by the largest factor instead
}
}
}
}

43
zig-pkg/raylib-6.0.0-whq8uCSwLgWWeF3ec3dbG6Rr36SLFL-s2WJ1Q_2E22Bb/examples/shaders/resources/shaders/glsl100/fisheye.fs Normal file
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#version 100
precision mediump float;
// Input vertex attributes (from vertex shader)
varying vec2 fragTexCoord;
varying vec4 fragColor;
// Input uniform values
uniform sampler2D texture0;
uniform vec4 colDiffuse;
// NOTE: Add your custom variables here
const float PI = 3.1415926535;
void main()
{
float aperture = 178.0;
float apertureHalf = 0.5*aperture*(PI/180.0);
float maxFactor = sin(apertureHalf);
vec2 uv = vec2(0.0);
vec2 xy = 2.0*fragTexCoord.xy - 1.0;
float d = length(xy);
if (d < (2.0 - maxFactor))
{
d = length(xy*maxFactor);
float z = sqrt(1.0 - d*d);
float r = atan(d, z)/PI;
float phi = atan(xy.y, xy.x);
uv.x = r*cos(phi) + 0.5;
uv.y = r*sin(phi) + 0.5;
}
else
{
uv = fragTexCoord.xy;
}
gl_FragColor = texture2D(texture0, uv);
}

94
zig-pkg/raylib-6.0.0-whq8uCSwLgWWeF3ec3dbG6Rr36SLFL-s2WJ1Q_2E22Bb/examples/shaders/resources/shaders/glsl100/fog.fs Normal file
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#version 100
precision mediump float;
// Input vertex attributes (from vertex shader)
varying vec3 fragPosition;
varying vec2 fragTexCoord;
varying vec4 fragColor;
varying vec3 fragNormal;
// Input uniform values
uniform sampler2D texture0;
uniform vec4 colDiffuse;
// NOTE: Add your custom variables here
#define MAX_LIGHTS 4
#define LIGHT_DIRECTIONAL 0
#define LIGHT_POINT 1
struct MaterialProperty {
vec3 color;
int useSampler;
sampler2D sampler;
};
struct Light {
int enabled;
int type;
vec3 position;
vec3 target;
vec4 color;
};
// Input lighting values
uniform Light lights[MAX_LIGHTS];
uniform vec4 ambient;
uniform vec3 viewPos;
uniform float fogDensity;
void main()
{
// Texel color fetching from texture sampler
vec4 texelColor = texture2D(texture0, fragTexCoord);
vec3 lightDot = vec3(0.0);
vec3 normal = normalize(fragNormal);
vec3 viewD = normalize(viewPos - fragPosition);
vec3 specular = vec3(0.0);
// NOTE: Implement here your fragment shader code
for (int i = 0; i < MAX_LIGHTS; i++)
{
if (lights[i].enabled == 1)
{
vec3 light = vec3(0.0);
if (lights[i].type == LIGHT_DIRECTIONAL) light = -normalize(lights[i].target - lights[i].position);
if (lights[i].type == LIGHT_POINT) light = normalize(lights[i].position - fragPosition);
float NdotL = max(dot(normal, light), 0.0);
lightDot += lights[i].color.rgb*NdotL;
float specCo = 0.0;
if (NdotL > 0.0) specCo = pow(max(0.0, dot(viewD, reflect(-(light), normal))), 16.0); // Shine: 16.0
specular += specCo;
}
}
vec4 finalColor = (texelColor*((colDiffuse + vec4(specular,1))*vec4(lightDot, 1.0)));
finalColor += texelColor*(ambient/10.0);
// Gamma correction
finalColor = pow(finalColor, vec4(1.0/2.2));
// Fog calculation
float dist = length(viewPos - fragPosition);
// these could be parameters...
const vec4 fogColor = vec4(0.5, 0.5, 0.5, 1.0);
//const float fogDensity = 0.16;
// Exponential fog
float fogFactor = 1.0/exp((dist*fogDensity)*(dist*fogDensity));
// Linear fog (less nice)
//const float fogStart = 2.0;
//const float fogEnd = 10.0;
//float fogFactor = (fogEnd - dist)/(fogEnd - fogStart);
fogFactor = clamp(fogFactor, 0.0, 1.0);
gl_FragColor = mix(fogColor, finalColor, fogFactor);
}

44
zig-pkg/raylib-6.0.0-whq8uCSwLgWWeF3ec3dbG6Rr36SLFL-s2WJ1Q_2E22Bb/examples/shaders/resources/shaders/glsl100/game_of_life.fs Normal file
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#version 100
precision highp float;
// Input vertex attributes (from vertex shader)
varying vec2 fragTexCoord;
varying vec4 fragColor;
// Input uniform values
uniform sampler2D texture0;
uniform vec4 colDiffuse;
// Input size in pixels of the textures
uniform vec2 resolution;
void main()
{
// Size of one pixel in texture coordinates (from 0.0 to 1.0)
float x = 1.0/resolution.x;
float y = 1.0/resolution.y;
// Status of the current cell (1 = alive, 0 = dead)
int origValue = (texture2D(texture0, fragTexCoord).r < 0.1)? 1 : 0;
// Sum of alive neighbors
int sumValue = (texture2D(texture0, vec2(fragTexCoord.x - x, fragTexCoord.y - y)).r < 0.1)? 1 : 0; // Top-left
sumValue += (texture2D(texture0, vec2(fragTexCoord.x - x, fragTexCoord.y )).r < 0.1)? 1 : 0; // Top
sumValue += (texture2D(texture0, vec2(fragTexCoord.x - x, fragTexCoord.y + y)).r < 0.1)? 1 : 0; // Top-right
sumValue += (texture2D(texture0, vec2(fragTexCoord.x, fragTexCoord.y - y)).r < 0.1)? 1 : 0; // Left
sumValue += (texture2D(texture0, vec2(fragTexCoord.x, fragTexCoord.y + y)).r < 0.1)? 1 : 0; // Right
sumValue += (texture2D(texture0, vec2(fragTexCoord.x + x, fragTexCoord.y - y)).r < 0.1)? 1 : 0; // Bottom-left
sumValue += (texture2D(texture0, vec2(fragTexCoord.x + x, fragTexCoord.y )).r < 0.1)? 1 : 0; // Bottom
sumValue += (texture2D(texture0, vec2(fragTexCoord.x + x, fragTexCoord.y + y)).r < 0.1)? 1 : 0; // Bottom-right
// Game of life rules:
// Current cell remains alive when 2 or 3 neighbors are alive, dies otherwise
// Current cell goes from dead to alive when exactly 3 neighbors are alive
if ((origValue == 1 && sumValue == 2) || sumValue == 3)
gl_FragColor = vec4(0.0, 0.0, 0.0, 255.0); // Alive: draw the pixel black
else
gl_FragColor = fragColor; // Dead: draw the pixel with the background color, RAYWHITE
}

36
zig-pkg/raylib-6.0.0-whq8uCSwLgWWeF3ec3dbG6Rr36SLFL-s2WJ1Q_2E22Bb/examples/shaders/resources/shaders/glsl100/gbuffer.fs Normal file
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#version 100
precision mediump float;
// Input vertex attributes (from vertex shader)
varying vec3 fragPosition;
varying vec2 fragTexCoord;
varying vec3 fragNormal;
varying vec4 fragColor;
// TODO: Is there some alternative for GLSL100
//layout (location = 0) out vec3 gPosition;
//layout (location = 1) out vec3 gNormal;
//layout (location = 2) out vec4 gAlbedoSpec;
//uniform vec3 gPosition;
//uniform vec3 gNormal;
//uniform vec4 gAlbedoSpec;
// Input uniform values
uniform sampler2D texture0; // Diffuse texture
uniform sampler2D specularTexture;
void main()
{
// Store the fragment position vector in the first gbuffer texture
//gPosition = fragPosition;
// Store the per-fragment normals into the gbuffer
//gNormal = normalize(fragNormal);
// Store the diffuse per-fragment color
gl_FragColor.rgb = texture2D(texture0, fragTexCoord).rgb;
// Store specular intensity in gAlbedoSpec's alpha component
gl_FragColor.a = texture2D(specularTexture, fragTexCoord).r;
}

60
zig-pkg/raylib-6.0.0-whq8uCSwLgWWeF3ec3dbG6Rr36SLFL-s2WJ1Q_2E22Bb/examples/shaders/resources/shaders/glsl100/gbuffer.vs Normal file
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#version 100
// Input vertex attributes
attribute vec3 vertexPosition;
attribute vec2 vertexTexCoord;
attribute vec3 vertexNormal;
attribute vec4 vertexColor;
// Input uniform values
uniform mat4 matModel;
uniform mat4 matView;
uniform mat4 matProjection;
// Output vertex attributes (to fragment shader)
varying vec3 fragPosition;
varying vec2 fragTexCoord;
varying vec3 fragNormal;
varying vec4 fragColor;
// https://github.com/glslify/glsl-inverse
mat3 inverse(mat3 m)
{
float a00 = m[0][0], a01 = m[0][1], a02 = m[0][2];
float a10 = m[1][0], a11 = m[1][1], a12 = m[1][2];
float a20 = m[2][0], a21 = m[2][1], a22 = m[2][2];
float b01 = a22*a11 - a12*a21;
float b11 = -a22*a10 + a12*a20;
float b21 = a21*a10 - a11*a20;
float det = a00*b01 + a01*b11 + a02*b21;
return mat3(b01, (-a22*a01 + a02*a21), (a12*a01 - a02*a11),
b11, (a22*a00 - a02*a20), (-a12*a00 + a02*a10),
b21, (-a21*a00 + a01*a20), (a11*a00 - a01*a10))/det;
}
// https://github.com/glslify/glsl-transpose
mat3 transpose(mat3 m)
{
return mat3(m[0][0], m[1][0], m[2][0],
m[0][1], m[1][1], m[2][1],
m[0][2], m[1][2], m[2][2]);
}
void main()
{
// Calculate vertex attributes for fragment shader
vec4 worldPos = matModel*vec4(vertexPosition, 1.0);
fragPosition = worldPos.xyz;
fragTexCoord = vertexTexCoord;
fragColor = vertexColor;
mat3 normalMatrix = transpose(inverse(mat3(matModel)));
fragNormal = normalMatrix*vertexNormal;
// Calculate final vertex position
gl_Position = matProjection*matView*worldPos;
}

25
zig-pkg/raylib-6.0.0-whq8uCSwLgWWeF3ec3dbG6Rr36SLFL-s2WJ1Q_2E22Bb/examples/shaders/resources/shaders/glsl100/grayscale.fs Normal file
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#version 100
precision mediump float;
// Input vertex attributes (from vertex shader)
varying vec2 fragTexCoord;
varying vec4 fragColor;
// Input uniform values
uniform sampler2D texture0;
uniform vec4 colDiffuse;
// NOTE: Add your custom variables here
void main()
{
// Texel color fetching from texture sampler
vec4 texelColor = texture2D(texture0, fragTexCoord)*colDiffuse*fragColor;
// Convert texel color to grayscale using NTSC conversion weights
float gray = dot(texelColor.rgb, vec3(0.299, 0.587, 0.114));
// Calculate final fragment color
gl_FragColor = vec4(gray, gray, gray, texelColor.a);
}

19
zig-pkg/raylib-6.0.0-whq8uCSwLgWWeF3ec3dbG6Rr36SLFL-s2WJ1Q_2E22Bb/examples/shaders/resources/shaders/glsl100/hybrid_raster.fs Normal file
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#version 100
#extension GL_EXT_frag_depth : enable // Extension required for writing depth
precision mediump float; // Precision required for OpenGL ES2 (WebGL)
varying vec2 fragTexCoord;
varying vec4 fragColor;
uniform sampler2D texture0;
uniform vec4 colDiffuse;
void main()
{
vec4 texelColor = texture2D(texture0, fragTexCoord);
gl_FragColor = texelColor*colDiffuse*fragColor;
gl_FragDepthEXT = gl_FragCoord.z;
}

295
zig-pkg/raylib-6.0.0-whq8uCSwLgWWeF3ec3dbG6Rr36SLFL-s2WJ1Q_2E22Bb/examples/shaders/resources/shaders/glsl100/hybrid_raymarch.fs Normal file
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#version 100
#extension GL_EXT_frag_depth : enable //Extension required for writing depth
#extension GL_OES_standard_derivatives : enable //Extension used for fwidth()
#define ZERO 0
precision mediump float; // Precision required for OpenGL ES2 (WebGL)
// Input vertex attributes (from vertex shader)
varying vec2 fragTexCoord;
varying vec4 fragColor;
// Input uniform values
uniform sampler2D texture0;
uniform vec4 colDiffuse;
// Custom Input Uniform
uniform vec3 camPos;
uniform vec3 camDir;
uniform vec2 screenCenter;
// SRC: https://learnopengl.com/Advanced-OpenGL/Depth-testing
float CalcDepth(in vec3 rd, in float Idist)
{
float local_z = dot(normalize(camDir),rd)*Idist;
return (1.0/(local_z) - 1.0/0.01)/(1.0/1000.0 -1.0/0.01);
}
// SRC: https://iquilezles.org/articles/distfunctions/
float sdHorseshoe(in vec3 p, in vec2 c, in float r, in float le, vec2 w)
{
p.x = abs(p.x);
float l = length(p.xy);
p.xy = mat2(-c.x, c.y,
c.y, c.x)*p.xy;
p.xy = vec2((p.y>0.0 || p.x>0.0)?p.x:l*sign(-c.x),
(p.x>0.0)?p.y:l);
p.xy = vec2(p.x,abs(p.y-r))-vec2(le,0.0);
vec2 q = vec2(length(max(p.xy,0.0)) + min(0.0,max(p.x,p.y)),p.z);
vec2 d = abs(q) - w;
return min(max(d.x,d.y),0.0) + length(max(d,0.0));
}
// r = sphere's radius
// h = cutting's plane's position
// t = thickness
float sdSixWayCutHollowSphere(vec3 p, float r, float h, float t)
{
// Six way symetry Transformation
vec3 ap = abs(p);
if (ap.x < max(ap.y, ap.z)){
if (ap.y < ap.z) ap.xz = ap.zx;
else ap.xy = ap.yx;
}
vec2 q = vec2(length(ap.yz), ap.x);
float w = sqrt(r*r-h*h);
return ((h*q.x<w*q.y) ? length(q-vec2(w,h)) : abs(length(q)-r)) - t;
}
// SRC: https://iquilezles.org/articles/boxfunctions
vec2 iBox(in vec3 ro, in vec3 rd, in vec3 rad)
{
vec3 m = 1.0/rd;
vec3 n = m*ro;
vec3 k = abs(m)*rad;
vec3 t1 = -n - k;
vec3 t2 = -n + k;
return vec2(max(max(t1.x, t1.y), t1.z),
min(min(t2.x, t2.y), t2.z));
}
vec2 opU(vec2 d1, vec2 d2)
{
return (d1.x<d2.x) ? d1 : d2;
}
vec2 map(in vec3 pos)
{
vec2 res = vec2(sdHorseshoe(pos-vec3(-1.0,0.08, 1.0), vec2(cos(1.3),sin(1.3)), 0.2, 0.3, vec2(0.03,0.5)), 11.5) ;
res = opU(res, vec2(sdSixWayCutHollowSphere(pos-vec3(0.0, 1.0, 0.0), 4.0, 3.5, 0.5), 4.5)) ;
return res;
}
// SRC: https://www.shadertoy.com/view/Xds3zN
vec2 raycast(in vec3 ro, in vec3 rd)
{
vec2 res = vec2(-1.0,-1.0);
float tmin = 1.0;
float tmax = 20.0;
// Raytrace floor plane
float tp1 = (-ro.y)/rd.y;
if (tp1>0.0)
{
tmax = min(tmax, tp1);
res = vec2(tp1, 1.0);
}
float t = tmin;
for (int i=0; i<70 ; i++)
{
if (t>tmax) break;
vec2 h = map(ro+rd*t);
if (abs(h.x) < (0.0001*t))
{
res = vec2(t,h.y);
break;
}
t += h.x;
}
return res;
}
// https://iquilezles.org/articles/rmshadows
float calcSoftshadow(in vec3 ro, in vec3 rd, in float mint, in float tmax)
{
// bounding volume
float tp = (0.8-ro.y)/rd.y; if (tp>0.0) tmax = min(tmax, tp);
float res = 1.0;
float t = mint;
for (int i = ZERO; i < 24; i++)
{
float h = map(ro + rd*t).x;
float s = clamp(8.0*h/t,0.0,1.0);
res = min(res, s);
t += clamp(h, 0.01, 0.2);
if (res<0.004 || t>tmax) break;
}
res = clamp(res, 0.0, 1.0);
return res*res*(3.0-2.0*res);
}
// https://iquilezles.org/articles/normalsSDF
vec3 calcNormal(in vec3 pos)
{
vec2 e = vec2(1.0,-1.0)*0.5773*0.0005;
return normalize(e.xyy*map(pos + e.xyy).x +
e.yyx*map(pos + e.yyx).x +
e.yxy*map(pos + e.yxy).x +
e.xxx*map(pos + e.xxx).x);
}
// https://iquilezles.org/articles/nvscene2008/rwwtt.pdf
float calcAO(in vec3 pos, in vec3 nor)
{
float occ = 0.0;
float sca = 1.0;
for (int i = ZERO; i < 5; i++)
{
float h = 0.01 + 0.12*float(i)/4.0;
float d = map(pos + h*nor).x;
occ += (h-d)*sca;
sca *= 0.95;
if (occ>0.35) break;
}
return clamp(1.0 - 3.0*occ, 0.0, 1.0)*(0.5+0.5*nor.y);
}
// https://iquilezles.org/articles/checkerfiltering
float checkersGradBox(in vec2 p)
{
// filter kernel
vec2 w = fwidth(p) + 0.001;
// analytical integral (box filter)
vec2 i = 2.0*(abs(fract((p-0.5*w)*0.5)-0.5)-abs(fract((p+0.5*w)*0.5)-0.5))/w;
// xor pattern
return 0.5 - 0.5*i.x*i.y;
}
// https://www.shadertoy.com/view/tdS3DG
vec4 render(in vec3 ro, in vec3 rd)
{
// background
vec3 col = vec3(0.7, 0.7, 0.9) - max(rd.y,0.0)*0.3;
// raycast scene
vec2 res = raycast(ro,rd);
float t = res.x;
float m = res.y;
if (m>-0.5)
{
vec3 pos = ro + t*rd;
vec3 nor = (m<1.5) ? vec3(0.0,1.0,0.0) : calcNormal(pos);
vec3 ref = reflect(rd, nor);
// material
col = 0.2 + 0.2*sin(m*2.0 + vec3(0.0,1.0,2.0));
float ks = 1.0;
if (m<1.5)
{
float f = checkersGradBox(3.0*pos.xz);
col = 0.15 + f*vec3(0.05);
ks = 0.4;
}
// lighting
float occ = calcAO(pos, nor);
vec3 lin = vec3(0.0);
// sun
{
vec3 lig = normalize(vec3(-0.5, 0.4, -0.6));
vec3 hal = normalize(lig-rd);
float dif = clamp(dot(nor, lig), 0.0, 1.0);
//if (dif>0.0001)
dif *= calcSoftshadow(pos, lig, 0.02, 2.5);
float spe = pow(clamp(dot(nor, hal), 0.0, 1.0),16.0);
spe *= dif;
spe *= 0.04+0.96*pow(clamp(1.0-dot(hal,lig),0.0,1.0),5.0);
//spe *= 0.04+0.96*pow(clamp(1.0-sqrt(0.5*(1.0-dot(rd,lig))),0.0,1.0),5.0);
lin += col*2.20*dif*vec3(1.30,1.00,0.70);
lin += 5.00*spe*vec3(1.30,1.00,0.70)*ks;
}
// sky
{
float dif = sqrt(clamp(0.5+0.5*nor.y, 0.0, 1.0));
dif *= occ;
float spe = smoothstep(-0.2, 0.2, ref.y);
spe *= dif;
spe *= 0.04+0.96*pow(clamp(1.0+dot(nor,rd),0.0,1.0), 5.0);
//if (spe>0.001)
spe *= calcSoftshadow(pos, ref, 0.02, 2.5);
lin += col*0.60*dif*vec3(0.40,0.60,1.15);
lin += 2.00*spe*vec3(0.40,0.60,1.30)*ks;
}
// back
{
float dif = clamp(dot(nor, normalize(vec3(0.5,0.0,0.6))), 0.0, 1.0)*clamp(1.0-pos.y,0.0,1.0);
dif *= occ;
lin += col*0.55*dif*vec3(0.25,0.25,0.25);
}
// sss
{
float dif = pow(clamp(1.0+dot(nor,rd),0.0,1.0),2.0);
dif *= occ;
lin += col*0.25*dif*vec3(1.00,1.00,1.00);
}
col = lin;
col = mix(col, vec3(0.7,0.7,0.9), 1.0-exp(-0.0001*t*t*t));
}
return vec4(vec3(clamp(col,0.0,1.0)),t);
}
vec3 CalcRayDir(vec2 nCoord)
{
vec3 horizontal = normalize(cross(camDir,vec3(.0 , 1.0, .0)));
vec3 vertical = normalize(cross(horizontal,camDir));
return normalize(camDir + horizontal*nCoord.x + vertical*nCoord.y);
}
mat3 setCamera()
{
vec3 cw = normalize(camDir);
vec3 cp = vec3(0.0, 1.0 ,0.0);
vec3 cu = normalize(cross(cw,cp));
vec3 cv = (cross(cu,cw));
return mat3(cu, cv, cw);
}
void main()
{
vec2 nCoord = (gl_FragCoord.xy - screenCenter.xy)/screenCenter.y;
mat3 ca = setCamera();
// focal length
float fl = length(camDir);
vec3 rd = ca*normalize(vec3(nCoord,fl));
vec3 color = vec3(nCoord/2.0 + 0.5, 0.0);
float depth = gl_FragCoord.z;
{
vec4 res = render(camPos - vec3(0.0, 0.0, 0.0) , rd);
color = res.xyz;
depth = CalcDepth(rd,res.w);
}
gl_FragColor = vec4(color , 1.0);
gl_FragDepthEXT = depth;
}

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zig-pkg/raylib-6.0.0-whq8uCSwLgWWeF3ec3dbG6Rr36SLFL-s2WJ1Q_2E22Bb/examples/shaders/resources/shaders/glsl100/julia_set.fs Normal file
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#version 100
precision mediump float;
// Input vertex attributes (from vertex shader)
varying vec2 fragTexCoord;
varying vec4 fragColor;
uniform vec2 c; // c.x = real, c.y = imaginary component. Equation done is z^2 + c
uniform vec2 offset; // Offset of the scale
uniform float zoom; // Zoom of the scale
// NOTE: Maximum number of shader for-loop iterations depend on GPU,
// for example, on RasperryPi for this examply only supports up to 60
const int maxIterations = 255; // Max iterations to do.
const float colorCycles = 1.0; // Number of times the color palette repeats.
// Square a complex number
vec2 ComplexSquare(vec2 z)
{
return vec2(z.x*z.x - z.y*z.y, z.x*z.y*2.0);
}
// Convert Hue Saturation Value (HSV) color into RGB
vec3 Hsv2rgb(vec3 c)
{
vec4 K = vec4(1.0, 2.0/3.0, 1.0/3.0, 3.0);
vec3 p = abs(fract(c.xxx + K.xyz)*6.0 - K.www);
return c.z*mix(K.xxx, clamp(p - K.xxx, 0.0, 1.0), c.y);
}
void main()
{
/**********************************************************************************************
Julia sets use a function z^2 + c, where c is a constant
This function is iterated until the nature of the point is determined
If the magnitude of the number becomes greater than 2, then from that point onward
the number will get bigger and bigger, and will never get smaller (tends towards infinity)
2^2 = 4, 4^2 = 8 and so on
So at 2 we stop iterating
If the number is below 2, we keep iterating
But when do we stop iterating if the number is always below 2 (it converges)?
That is what maxIterations is for
Then we can divide the iterations by the maxIterations value to get a normalized value
that we can then map to a color
We use dot product (z.x*z.x + z.y*z.y) to determine the magnitude (length) squared
And once the magnitude squared is > 4, then magnitude > 2 is also true (saves computational power)
*************************************************************************************************/
// The pixel coordinates are scaled so they are on the mandelbrot scale
// NOTE: fragTexCoord already comes as normalized screen coordinates but offset must be normalized before scaling and zoom
vec2 z = vec2((fragTexCoord.x - 0.5)*2.5, (fragTexCoord.y - 0.5)*1.5)/zoom;
z.x += offset.x;
z.y += offset.y;
int iter = 0;
for (int iterations = 0; iterations < maxIterations; iterations++)
{
z = ComplexSquare(z) + c; // Iterate function
if (dot(z, z) > 4.0) break;
iter = iterations;
}
// Another few iterations decreases errors in the smoothing calculation
// See http://linas.org/art-gallery/escape/escape.html for more information
z = ComplexSquare(z) + c;
z = ComplexSquare(z) + c;
// This last part smooths the color (again see link above)
float smoothVal = float(iter) + 1.0 - (log(log(length(z)))/log(2.0));
// Normalize the value so it is between 0 and 1
float norm = smoothVal/float(maxIterations);
// If in set, color black. 0.999 allows for some float accuracy error
if (norm > 0.999) gl_FragColor = vec4(0.0, 0.0, 0.0, 1.0);
else gl_FragColor = vec4(Hsv2rgb(vec3(norm*colorCycles, 1.0, 1.0)), 1.0);
}

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zig-pkg/raylib-6.0.0-whq8uCSwLgWWeF3ec3dbG6Rr36SLFL-s2WJ1Q_2E22Bb/examples/shaders/resources/shaders/glsl100/lighting.fs Normal file
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#version 100
precision mediump float;
// Input vertex attributes (from vertex shader)
varying vec3 fragPosition;
varying vec2 fragTexCoord;
varying vec4 fragColor;
varying vec3 fragNormal;
// Input uniform values
uniform sampler2D texture0;
uniform vec4 colDiffuse;
// NOTE: Add your custom variables here
#define MAX_LIGHTS 4
#define LIGHT_DIRECTIONAL 0
#define LIGHT_POINT 1
struct Light {
int enabled;
int type;
vec3 position;
vec3 target;
vec4 color;
};
// Input lighting values
uniform Light lights[MAX_LIGHTS];
uniform vec4 ambient;
uniform vec3 viewPos;
void main()
{
// Texel color fetching from texture sampler
vec4 texelColor = texture2D(texture0, fragTexCoord);
vec3 lightDot = vec3(0.0);
vec3 normal = normalize(fragNormal);
vec3 viewD = normalize(viewPos - fragPosition);
vec3 specular = vec3(0.0);
vec4 tint = colDiffuse*fragColor;
// NOTE: Implement here your fragment shader code
for (int i = 0; i < MAX_LIGHTS; i++)
{
if (lights[i].enabled == 1)
{
vec3 light = vec3(0.0);
if (lights[i].type == LIGHT_DIRECTIONAL)
{
light = -normalize(lights[i].target - lights[i].position);
}
if (lights[i].type == LIGHT_POINT)
{
light = normalize(lights[i].position - fragPosition);
}
float NdotL = max(dot(normal, light), 0.0);
lightDot += lights[i].color.rgb*NdotL;
float specCo = 0.0;
if (NdotL > 0.0) specCo = pow(max(0.0, dot(viewD, reflect(-(light), normal))), 16.0); // 16 refers to shine
specular += specCo;
}
}
vec4 finalColor = (texelColor*((tint + vec4(specular, 1.0))*vec4(lightDot, 1.0)));
finalColor += texelColor*(ambient/10.0);
// Gamma correction
gl_FragColor = pow(finalColor, vec4(1.0/2.2));
}

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zig-pkg/raylib-6.0.0-whq8uCSwLgWWeF3ec3dbG6Rr36SLFL-s2WJ1Q_2E22Bb/examples/shaders/resources/shaders/glsl100/lighting.vs Normal file
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#version 100
// Input vertex attributes
attribute vec3 vertexPosition;
attribute vec2 vertexTexCoord;
attribute vec3 vertexNormal;
attribute vec4 vertexColor;
// Input uniform values
uniform mat4 mvp;
uniform mat4 matModel;
// Output vertex attributes (to fragment shader)
varying vec3 fragPosition;
varying vec2 fragTexCoord;
varying vec4 fragColor;
varying vec3 fragNormal;
// NOTE: Add your custom variables here
// https://github.com/glslify/glsl-inverse
mat3 inverse(mat3 m)
{
float a00 = m[0][0], a01 = m[0][1], a02 = m[0][2];
float a10 = m[1][0], a11 = m[1][1], a12 = m[1][2];
float a20 = m[2][0], a21 = m[2][1], a22 = m[2][2];
float b01 = a22*a11 - a12*a21;
float b11 = -a22*a10 + a12*a20;
float b21 = a21*a10 - a11*a20;
float det = a00*b01 + a01*b11 + a02*b21;
return mat3(b01, (-a22*a01 + a02*a21), (a12*a01 - a02*a11),
b11, (a22*a00 - a02*a20), (-a12*a00 + a02*a10),
b21, (-a21*a00 + a01*a20), (a11*a00 - a01*a10))/det;
}
// https://github.com/glslify/glsl-transpose
mat3 transpose(mat3 m)
{
return mat3(m[0][0], m[1][0], m[2][0],
m[0][1], m[1][1], m[2][1],
m[0][2], m[1][2], m[2][2]);
}
void main()
{
// Send vertex attributes to fragment shader
fragPosition = vec3(matModel*vec4(vertexPosition, 1.0));
fragTexCoord = vertexTexCoord;
fragColor = vertexColor;
mat3 normalMatrix = transpose(inverse(mat3(matModel)));
fragNormal = normalize(normalMatrix*vertexNormal);
// Calculate final vertex position
gl_Position = mvp*vec4(vertexPosition, 1.0);
}

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zig-pkg/raylib-6.0.0-whq8uCSwLgWWeF3ec3dbG6Rr36SLFL-s2WJ1Q_2E22Bb/examples/shaders/resources/shaders/glsl100/lighting_instancing.vs Normal file
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#version 100
// Input vertex attributes
attribute vec3 vertexPosition;
attribute vec2 vertexTexCoord;
attribute vec3 vertexNormal;
attribute vec4 vertexColor;
attribute mat4 instanceTransform;
// Input uniform values
uniform mat4 mvp;
uniform mat4 matNormal;
// Output vertex attributes (to fragment shader)
varying vec3 fragPosition;
varying vec2 fragTexCoord;
varying vec4 fragColor;
varying vec3 fragNormal;
// NOTE: Add your custom variables here
void main()
{
// Compute MVP for current instance
mat4 mvpi = mvp*instanceTransform;
// Send vertex attributes to fragment shader
fragPosition = vec3(mvpi*vec4(vertexPosition, 1.0));
fragTexCoord = vertexTexCoord;
fragColor = vertexColor;
fragNormal = normalize(vec3(matNormal*vec4(vertexNormal, 1.0)));
// Calculate final vertex position
gl_Position = mvpi*vec4(vertexPosition, 1.0);
}

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zig-pkg/raylib-6.0.0-whq8uCSwLgWWeF3ec3dbG6Rr36SLFL-s2WJ1Q_2E22Bb/examples/shaders/resources/shaders/glsl100/lightmap.fs Normal file
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#version 100
precision mediump float;
// Input vertex attributes (from vertex shader)
varying vec2 fragTexCoord;
varying vec2 fragTexCoord2;
varying vec3 fragPosition;
varying vec4 fragColor;
// Input uniform values
uniform sampler2D texture0;
uniform sampler2D texture1;
void main()
{
// Texel color fetching from texture sampler
vec4 texelColor = texture2D(texture0, fragTexCoord);
vec4 texelColor2 = texture2D(texture1, fragTexCoord2);
gl_FragColor = texelColor*texelColor2;
}

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zig-pkg/raylib-6.0.0-whq8uCSwLgWWeF3ec3dbG6Rr36SLFL-s2WJ1Q_2E22Bb/examples/shaders/resources/shaders/glsl100/lightmap.vs Normal file
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#version 100
// Input vertex attributes
attribute vec3 vertexPosition;
attribute vec2 vertexTexCoord;
attribute vec2 vertexTexCoord2;
attribute vec4 vertexColor;
// Input uniform values
uniform mat4 mvp;
uniform mat4 matModel;
// Output vertex attributes (to fragment shader)
varying vec3 fragPosition;
varying vec2 fragTexCoord;
varying vec2 fragTexCoord2;
varying vec4 fragColor;
// NOTE: Add your custom variables here
void main()
{
// Send vertex attributes to fragment shader
fragPosition = vec3(matModel*vec4(vertexPosition, 1.0));
fragTexCoord = vertexTexCoord;
fragTexCoord2 = vertexTexCoord2;
fragColor = vertexColor;
// Calculate final vertex position
gl_Position = mvp*vec4(vertexPosition, 1.0);
}

62
zig-pkg/raylib-6.0.0-whq8uCSwLgWWeF3ec3dbG6Rr36SLFL-s2WJ1Q_2E22Bb/examples/shaders/resources/shaders/glsl100/mandelbrot_set.fs Normal file
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#version 100
#define PI 3.1415926535897932384626433832795
precision highp float;
// Input vertex attributes (from vertex shader)
varying vec2 fragTexCoord;
varying vec4 fragColor;
uniform vec2 offset; // Offset of the scale
uniform float zoom; // Zoom of the scale
// NOTE: Maximum number of shader for-loop iterations depend on GPU,
// For example, on RasperryPi for this examply only supports up to 60
uniform int maxIterations; // Max iterations per pixel
const float max = 4.0; // We consider infinite as 4.0: if a point reaches a distance of 4.0 it will escape to infinity
const float max2 = max*max; // Square of max to avoid computing square root
// WebGL shaders for loop iteration limit only const
const int maxIterationsLimit = 20000;
void main()
{
// The pixel coordinates are scaled so they are on the mandelbrot scale
// NOTE: fragTexCoord already comes as normalized screen coordinates but offset must be normalized before scaling and zoom
vec2 c = vec2((fragTexCoord.x - 0.5)*2.5, (fragTexCoord.y - 0.5)*1.5)/zoom;
c.x += offset.x;
c.y += offset.y;
float a = 0.0;
float b = 0.0;
// The Mandelbrot set is a two-dimensional set defined in the complex plane on which the iteration of the function
// Fc(z) = z^2 + c on the complex numbers c from the plane does not diverge to infinity starting at z = 0
// Here: z = a + bi. Iterations: z -> z^2 + c = (a + bi)^2 + (c.x + c.yi) = (a^2 - b^2 + c.x) + (2ab + c.y)i
for (int iter = 0; iter < maxIterationsLimit; iter++)
{
float aa = a*a;
float bb = b*b;
if (iter >= maxIterations)
{
gl_FragColor = vec4(0.0, 0.0, 0.0, 1.0);
return;
}
if (aa + bb > max2)
{
float normR = float(iter - (iter/55)*55)/55.0;
float normG = float(iter - (iter/69)*69)/69.0;
float normB = float(iter - (iter/40)*40)/40.0;
gl_FragColor = vec4(sin(normR*PI), sin(normG*PI), sin(normB*PI), 1.0);
return;
}
float twoab = 2.0*a*b;
a = aa - bb + c.x;
b = twoab + c.y;
}
gl_FragColor = vec4(0.0, 0.0, 0.0, 1.0);
}

24
zig-pkg/raylib-6.0.0-whq8uCSwLgWWeF3ec3dbG6Rr36SLFL-s2WJ1Q_2E22Bb/examples/shaders/resources/shaders/glsl100/mask.fs Normal file
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#version 100
precision mediump float;
// Input vertex attributes (from vertex shader)
varying vec2 fragTexCoord;
varying vec4 fragColor;
// Input uniform values
uniform sampler2D texture0;
uniform sampler2D mask;
uniform vec4 colDiffuse;
uniform int frame;
// NOTE: Add your custom variables here
void main()
{
vec4 maskColour = texture2D(mask, fragTexCoord + vec2(sin(-float(frame)/150.0)/10.0, cos(-float(frame)/170.0)/10.0));
if (maskColour.r < 0.25) discard;
vec4 texelColor = texture2D(texture0, fragTexCoord + vec2(sin(float(frame)/90.0)/8.0, cos(float(frame)/60.0)/8.0));
gl_FragColor = texelColor*maskColour;
}

64
zig-pkg/raylib-6.0.0-whq8uCSwLgWWeF3ec3dbG6Rr36SLFL-s2WJ1Q_2E22Bb/examples/shaders/resources/shaders/glsl100/normalmap.fs Normal file
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#version 100
precision mediump float;
// Input vertex attributes (from vertex shader)
varying vec3 fragPosition;
varying vec2 fragTexCoord;
varying vec3 fragNormal; //used for when normal mapping is toggled off
varying vec4 fragColor;
varying mat3 TBN;
// Input uniform values
uniform sampler2D texture0;
uniform sampler2D normalMap;
uniform vec4 colDiffuse;
uniform vec3 viewPos;
// NOTE: Add your custom variables here
uniform vec3 lightPos;
uniform bool useNormalMap;
uniform float specularExponent;
void main()
{
vec4 texelColor = texture2D(texture0, vec2(fragTexCoord.x, fragTexCoord.y));
vec3 specular = vec3(0.0);
vec3 viewDir = normalize(viewPos - fragPosition);
vec3 lightDir = normalize(lightPos - fragPosition);
vec3 normal = vec3(0.0);
if (useNormalMap)
{
normal = texture2D(normalMap, vec2(fragTexCoord.x, fragTexCoord.y)).rgb;
// Transform normal values to the range -1.0 ... 1.0
normal = normalize(normal*2.0 - 1.0);
// Transform the normal from tangent-space to world-space for lighting calculation
normal = normalize(normal*TBN);
}
else
{
normal = normalize(fragNormal);
}
vec4 tint = colDiffuse*fragColor;
vec3 lightColor = vec3(1.0, 1.0, 1.0);
float NdotL = max(dot(normal, lightDir), 0.0);
vec3 lightDot = lightColor*NdotL;
float specCo = 0.0;
if (NdotL > 0.0) specCo = pow(max(0.0, dot(viewDir, reflect(-lightDir, normal))), specularExponent);
specular += specCo;
vec4 finalColor = (texelColor*((tint + vec4(specular, 1.0))*vec4(lightDot, 1.0)));
finalColor += texelColor*(vec4(1.0, 1.0, 1.0, 1.0)/40.0)*tint;
// Gamma correction
gl_FragColor = pow(finalColor, vec4(1.0/2.2));
}

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zig-pkg/raylib-6.0.0-whq8uCSwLgWWeF3ec3dbG6Rr36SLFL-s2WJ1Q_2E22Bb/examples/shaders/resources/shaders/glsl100/normalmap.vs Normal file
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#version 100
// Input vertex attributes
attribute vec3 vertexPosition;
attribute vec2 vertexTexCoord;
attribute vec3 vertexNormal;
attribute vec4 vertexTangent;
attribute vec4 vertexColor;
// Input uniform values
uniform mat4 mvp;
uniform mat4 matModel;
// Output vertex attributes (to fragment shader)
varying vec3 fragPosition;
varying vec2 fragTexCoord;
varying vec3 fragNormal; //used for when normal mapping is toggled off
varying vec4 fragColor;
varying mat3 TBN;
// NOTE: Add your custom variables here
// https://github.com/glslify/glsl-inverse
mat3 inverse(mat3 m)
{
float a00 = m[0][0], a01 = m[0][1], a02 = m[0][2];
float a10 = m[1][0], a11 = m[1][1], a12 = m[1][2];
float a20 = m[2][0], a21 = m[2][1], a22 = m[2][2];
float b01 = a22*a11 - a12*a21;
float b11 = -a22*a10 + a12*a20;
float b21 = a21*a10 - a11*a20;
float det = a00*b01 + a01*b11 + a02*b21;
return mat3(b01, (-a22*a01 + a02*a21), (a12*a01 - a02*a11),
b11, (a22*a00 - a02*a20), (-a12*a00 + a02*a10),
b21, (-a21*a00 + a01*a20), (a11*a00 - a01*a10))/det;
}
// https://github.com/glslify/glsl-transpose
mat3 transpose(mat3 m)
{
return mat3(m[0][0], m[1][0], m[2][0],
m[0][1], m[1][1], m[2][1],
m[0][2], m[1][2], m[2][2]);
}
void main()
{
// Compute binormal from vertex normal and tangent. W component is the tangent handedness
vec3 vertexBinormal = cross(vertexNormal, vertexTangent.xyz)*vertexTangent.w;
// Compute fragment normal based on normal transformations
mat3 normalMatrix = transpose(inverse(mat3(matModel)));
// Compute fragment position based on model transformations
fragPosition = vec3(matModel*vec4(vertexPosition, 1.0));
//Create TBN matrix for transforming the normal map values from tangent-space to world-space
fragNormal = normalize(normalMatrix*vertexNormal);
vec3 fragTangent = normalize(normalMatrix*vertexTangent.xyz);
fragTangent = normalize(fragTangent - dot(fragTangent, fragNormal)*fragNormal);
vec3 fragBinormal = normalize(normalMatrix*vertexBinormal);
fragBinormal = cross(fragNormal, fragTangent);
TBN = transpose(mat3(fragTangent, fragBinormal, fragNormal));
fragColor = vertexColor;
fragTexCoord = vertexTexCoord;
gl_Position = mvp*vec4(vertexPosition, 1.0);
}

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zig-pkg/raylib-6.0.0-whq8uCSwLgWWeF3ec3dbG6Rr36SLFL-s2WJ1Q_2E22Bb/examples/shaders/resources/shaders/glsl100/outline.fs Normal file
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#version 100
precision mediump float;
// Input vertex attributes (from vertex shader)
varying vec2 fragTexCoord;
varying vec4 fragColor;
// Input uniform values
uniform sampler2D texture0;
uniform vec4 colDiffuse;
uniform vec2 textureSize;
uniform float outlineSize;
uniform vec4 outlineColor;
void main()
{
vec4 texel = texture2D(texture0, fragTexCoord); // Get texel color
vec2 texelScale = vec2(0.0);
texelScale.x = outlineSize/textureSize.x;
texelScale.y = outlineSize/textureSize.y;
// We sample four corner texels, but only for the alpha channel (this is for the outline)
vec4 corners = vec4(0.0);
corners.x = texture2D(texture0, fragTexCoord + vec2(texelScale.x, texelScale.y)).a;
corners.y = texture2D(texture0, fragTexCoord + vec2(texelScale.x, -texelScale.y)).a;
corners.z = texture2D(texture0, fragTexCoord + vec2(-texelScale.x, texelScale.y)).a;
corners.w = texture2D(texture0, fragTexCoord + vec2(-texelScale.x, -texelScale.y)).a;
float outline = min(dot(corners, vec4(1.0)), 1.0);
vec4 color = mix(vec4(0.0), outlineColor, outline);
gl_FragColor = mix(color, texel, texel.a);
}

8
zig-pkg/raylib-6.0.0-whq8uCSwLgWWeF3ec3dbG6Rr36SLFL-s2WJ1Q_2E22Bb/examples/shaders/resources/shaders/glsl100/outline_hull.fs Normal file
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#version 100
precision mediump float;
void main()
{
gl_FragColor = vec4(0.05, 0.05, 0.05, 1.0);
}

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zig-pkg/raylib-6.0.0-whq8uCSwLgWWeF3ec3dbG6Rr36SLFL-s2WJ1Q_2E22Bb/examples/shaders/resources/shaders/glsl100/outline_hull.vs Normal file
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#version 100
attribute vec3 vertexPosition;
attribute vec3 vertexNormal;
attribute vec2 vertexTexCoord;
attribute vec4 vertexColor;
uniform mat4 mvp;
uniform float outlineThickness;
void main()
{
vec3 extruded = vertexPosition + vertexNormal * outlineThickness;
gl_Position = mvp * vec4(extruded, 1.0);
}

43
zig-pkg/raylib-6.0.0-whq8uCSwLgWWeF3ec3dbG6Rr36SLFL-s2WJ1Q_2E22Bb/examples/shaders/resources/shaders/glsl100/palette_switch.fs Normal file
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#version 100
precision mediump float;
const int MAX_INDEXED_COLORS = 8;
// Input vertex attributes (from vertex shader)
varying vec2 fragTexCoord;
varying vec4 fragColor;
// Input uniform values
uniform sampler2D texture0;
uniform ivec3 palette[MAX_INDEXED_COLORS];
//uniform sampler2D palette; // Alternative to ivec3, palette provided as a 256x1 texture
void main()
{
// Texel color fetching from texture sampler
vec4 texelColor = texture2D(texture0, fragTexCoord)*fragColor;
// Convert the (normalized) texel color RED component (GB would work, too)
// to the palette index by scaling up from [0..1] to [0..255]
int index = int(texelColor.r*255.0);
ivec3 color = ivec3(0);
// NOTE: On GLSL 100 we are not allowed to index a uniform array by a variable value,
// a constant must be used, so this logic...
if (index == 0) color = palette[0];
else if (index == 1) color = palette[1];
else if (index == 2) color = palette[2];
else if (index == 3) color = palette[3];
else if (index == 4) color = palette[4];
else if (index == 5) color = palette[5];
else if (index == 6) color = palette[6];
else if (index == 7) color = palette[7];
//gl_FragColor = texture2D(palette, texelColor.xy); // Alternative to ivec3
// Calculate final fragment color. Note that the palette color components
// are defined in the range [0..255] and need to be normalized to [0..1]
gl_FragColor = vec4(float(color.x)/255.0, float(color.y)/255.0, float(color.z)/255.0, texelColor.a);
}

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zig-pkg/raylib-6.0.0-whq8uCSwLgWWeF3ec3dbG6Rr36SLFL-s2WJ1Q_2E22Bb/examples/shaders/resources/shaders/glsl100/pbr.fs Normal file
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#version 100
precision highp float;
#define MAX_LIGHTS 4
#define LIGHT_DIRECTIONAL 0
#define LIGHT_POINT 1
#define PI 3.14159265358979323846
struct Light {
int enabled;
int type;
vec3 position;
vec3 target;
vec4 color;
float intensity;
};
// Input vertex attributes (from vertex shader)
varying vec3 fragPosition;
varying vec2 fragTexCoord;
varying vec4 fragColor;
varying vec3 fragNormal;
varying vec4 shadowPos;
varying mat3 TBN;
// Input uniform values
uniform int numOfLights;
uniform sampler2D albedoMap;
uniform sampler2D mraMap;
uniform sampler2D normalMap;
uniform sampler2D emissiveMap; // r: Hight g:emissive
uniform vec2 tiling;
uniform vec2 offset;
uniform int useTexAlbedo;
uniform int useTexNormal;
uniform int useTexMRA;
uniform int useTexEmissive;
uniform vec4 albedoColor;
uniform vec4 emissiveColor;
uniform float normalValue;
uniform float metallicValue;
uniform float roughnessValue;
uniform float aoValue;
uniform float emissivePower;
// Input lighting values
uniform Light lights[MAX_LIGHTS];
uniform vec3 viewPos;
uniform vec3 ambientColor;
uniform float ambient;
// Reflectivity in range 0.0 to 1.0
// NOTE: Reflectivity is increased when surface view at larger angle
vec3 SchlickFresnel(float hDotV,vec3 refl)
{
return refl + (1.0 - refl)*pow(1.0 - hDotV, 5.0);
}
float GgxDistribution(float nDotH,float roughness)
{
float a = roughness*roughness*roughness*roughness;
float d = nDotH*nDotH*(a - 1.0) + 1.0;
d = PI*d*d;
return (a/max(d,0.0000001));
}
float GeomSmith(float nDotV,float nDotL,float roughness)
{
float r = roughness + 1.0;
float k = r*r/8.0;
float ik = 1.0 - k;
float ggx1 = nDotV/(nDotV*ik + k);
float ggx2 = nDotL/(nDotL*ik + k);
return ggx1*ggx2;
}
vec3 ComputePBR()
{
vec3 albedo = texture2D(albedoMap, vec2(fragTexCoord.x*tiling.x + offset.x, fragTexCoord.y*tiling.y + offset.y)).rgb;
albedo = vec3(albedoColor.x*albedo.x, albedoColor.y*albedo.y, albedoColor.z*albedo.z);
float metallic = clamp(metallicValue, 0.0, 1.0);
float roughness = clamp(roughnessValue, 0.0, 1.0);
float ao = clamp(aoValue, 0.0, 1.0);
if (useTexMRA == 1)
{
vec4 mra = texture2D(mraMap, vec2(fragTexCoord.x*tiling.x + offset.x, fragTexCoord.y*tiling.y + offset.y));
metallic = clamp(mra.r + metallicValue, 0.04, 1.0);
roughness = clamp(mra.g + roughnessValue, 0.04, 1.0);
ao = (mra.b + aoValue)*0.5;
}
vec3 N = normalize(fragNormal);
if (useTexNormal == 1)
{
N = texture2D(normalMap, vec2(fragTexCoord.x*tiling.x + offset.y, fragTexCoord.y*tiling.y + offset.y)).rgb;
N = normalize(N*2.0 - 1.0);
N = normalize(N*TBN);
}
vec3 V = normalize(viewPos - fragPosition);
vec3 emissive = vec3(0);
emissive = (texture2D(emissiveMap, vec2(fragTexCoord.x*tiling.x + offset.x, fragTexCoord.y*tiling.y + offset.y)).rgb).g*emissiveColor.rgb*emissivePower*float(useTexEmissive);
// return N;//vec3(metallic,metallic,metallic);
// If dia-electric use base reflectivity of 0.04 otherwise ut is a metal use albedo as base reflectivity
vec3 baseRefl = mix(vec3(0.04), albedo.rgb, metallic);
vec3 lightAccum = vec3(0.0); // Acumulate lighting lum
for (int i = 0; i < 4; i++)
{
vec3 L = normalize(lights[i].position - fragPosition); // Compute light vector
vec3 H = normalize(V + L); // Compute halfway bisecting vector
float dist = length(lights[i].position - fragPosition); // Compute distance to light
float attenuation = 1.0/(dist*dist*0.23); // Compute attenuation
vec3 radiance = lights[i].color.rgb*lights[i].intensity*attenuation; // Compute input radiance, light energy comming in
// Cook-Torrance BRDF distribution function
float nDotV = max(dot(N,V), 0.0000001);
float nDotL = max(dot(N,L), 0.0000001);
float hDotV = max(dot(H,V), 0.0);
float nDotH = max(dot(N,H), 0.0);
float D = GgxDistribution(nDotH, roughness); // Larger the more micro-facets aligned to H
float G = GeomSmith(nDotV, nDotL, roughness); // Smaller the more micro-facets shadow
vec3 F = SchlickFresnel(hDotV, baseRefl); // Fresnel proportion of specular reflectance
vec3 spec = (D*G*F)/(4.0*nDotV*nDotL);
// Difuse and spec light can't be above 1.0
// kD = 1.0 - kS diffuse component is equal 1.0 - spec comonent
vec3 kD = vec3(1.0) - F;
// Mult kD by the inverse of metallnes, only non-metals should have diffuse light
kD *= 1.0 - metallic;
lightAccum += ((kD*albedo.rgb/PI + spec)*radiance*nDotL)*float(lights[i].enabled); // Angle of light has impact on result
}
vec3 ambientFinal = (ambientColor + albedo)*ambient*0.5;
return (ambientFinal + lightAccum*ao + emissive);
}
void main()
{
vec3 color = ComputePBR();
// HDR tonemapping
color = pow(color, color + vec3(1.0));
// Gamma correction
color = pow(color, vec3(1.0/2.2));
gl_FragColor = vec4(color,1.0);
}

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zig-pkg/raylib-6.0.0-whq8uCSwLgWWeF3ec3dbG6Rr36SLFL-s2WJ1Q_2E22Bb/examples/shaders/resources/shaders/glsl100/pbr.vs Normal file
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#version 100
// Input vertex attributes
attribute vec3 vertexPosition;
attribute vec2 vertexTexCoord;
attribute vec3 vertexNormal;
attribute vec4 vertexTangent;
attribute vec4 vertexColor;
// Input uniform values
uniform mat4 mvp;
uniform mat4 matModel;
uniform mat4 matNormal;
uniform vec3 lightPos;
uniform vec4 difColor;
// Output vertex attributes (to fragment shader)
varying vec3 fragPosition;
varying vec2 fragTexCoord;
varying vec4 fragColor;
varying vec3 fragNormal;
varying mat3 TBN;
const float normalOffset = 0.1;
// https://github.com/glslify/glsl-inverse
mat3 inverse(mat3 m)
{
float a00 = m[0][0], a01 = m[0][1], a02 = m[0][2];
float a10 = m[1][0], a11 = m[1][1], a12 = m[1][2];
float a20 = m[2][0], a21 = m[2][1], a22 = m[2][2];
float b01 = a22*a11 - a12*a21;
float b11 = -a22*a10 + a12*a20;
float b21 = a21*a10 - a11*a20;
float det = a00*b01 + a01*b11 + a02*b21;
return mat3(b01, (-a22*a01 + a02*a21), (a12*a01 - a02*a11),
b11, (a22*a00 - a02*a20), (-a12*a00 + a02*a10),
b21, (-a21*a00 + a01*a20), (a11*a00 - a01*a10))/det;
}
// https://github.com/glslify/glsl-transpose
mat3 transpose(mat3 m)
{
return mat3(m[0][0], m[1][0], m[2][0],
m[0][1], m[1][1], m[2][1],
m[0][2], m[1][2], m[2][2]);
}
void main()
{
// Compute binormal from vertex normal and tangent
vec3 vertexBinormal = cross(vertexNormal, vertexTangent.xyz)*vertexTangent.w;
// Compute fragment normal based on normal transformations
mat3 normalMatrix = transpose(inverse(mat3(matModel)));
// Compute fragment position based on model transformations
fragPosition = vec3(matModel*vec4(vertexPosition, 1.0));
fragTexCoord = vertexTexCoord*2.0;
fragNormal = normalize(normalMatrix*vertexNormal);
vec3 fragTangent = normalize(normalMatrix*vertexTangent.xyz);
fragTangent = normalize(fragTangent - dot(fragTangent, fragNormal)*fragNormal);
vec3 fragBinormal = normalize(normalMatrix*vertexBinormal);
fragBinormal = cross(fragNormal, fragTangent);
TBN = transpose(mat3(fragTangent, fragBinormal, fragNormal));
// Calculate final vertex position
gl_Position = mvp*vec4(vertexPosition, 1.0);
}

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zig-pkg/raylib-6.0.0-whq8uCSwLgWWeF3ec3dbG6Rr36SLFL-s2WJ1Q_2E22Bb/examples/shaders/resources/shaders/glsl100/pixelizer.fs Normal file
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#version 100
precision mediump float;
// Input vertex attributes (from vertex shader)
varying vec2 fragTexCoord;
varying vec4 fragColor;
// Input uniform values
uniform sampler2D texture0;
uniform vec4 colDiffuse;
// NOTE: Add your custom variables here
// NOTE: Render size values must be passed from code
const float renderWidth = 800.0;
const float renderHeight = 450.0;
float pixelWidth = 5.0;
float pixelHeight = 5.0;
void main()
{
float dx = pixelWidth*(1.0/renderWidth);
float dy = pixelHeight*(1.0/renderHeight);
vec2 coord = vec2(dx*floor(fragTexCoord.x/dx), dy*floor(fragTexCoord.y/dy));
vec3 tc = texture2D(texture0, coord).rgb;
gl_FragColor = vec4(tc, 1.0);
}

29
zig-pkg/raylib-6.0.0-whq8uCSwLgWWeF3ec3dbG6Rr36SLFL-s2WJ1Q_2E22Bb/examples/shaders/resources/shaders/glsl100/posterization.fs Normal file
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#version 100
precision mediump float;
// Input vertex attributes (from vertex shader)
varying vec2 fragTexCoord;
varying vec4 fragColor;
// Input uniform values
uniform sampler2D texture0;
uniform vec4 colDiffuse;
// NOTE: Add your custom variables here
float gamma = 0.6;
float numColors = 8.0;
void main()
{
vec3 color = texture2D(texture0, fragTexCoord.xy).rgb;
color = pow(color, vec3(gamma, gamma, gamma));
color = color*numColors;
color = floor(color);
color = color/numColors;
color = pow(color, vec3(1.0/gamma));
gl_FragColor = vec4(color, 1.0);
}

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zig-pkg/raylib-6.0.0-whq8uCSwLgWWeF3ec3dbG6Rr36SLFL-s2WJ1Q_2E22Bb/examples/shaders/resources/shaders/glsl100/predator.fs Normal file
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#version 100
precision mediump float;
// Input vertex attributes (from vertex shader)
varying vec2 fragTexCoord;
varying vec4 fragColor;
// Input uniform values
uniform sampler2D texture0;
uniform vec4 colDiffuse;
// NOTE: Add your custom variables here
void main()
{
vec3 color = texture2D(texture0, fragTexCoord).rgb;
vec3 colors[3];
colors[0] = vec3(0.0, 0.0, 1.0);
colors[1] = vec3(1.0, 1.0, 0.0);
colors[2] = vec3(1.0, 0.0, 0.0);
float lum = (color.r + color.g + color.b)/3.0;
vec3 tc = vec3(0.0, 0.0, 0.0);
if (lum < 0.5) tc = mix(colors[0], colors[1], lum/0.5);
else tc = mix(colors[1], colors[2], (lum - 0.5)/0.5);
gl_FragColor = vec4(tc, 1.0);
}

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zig-pkg/raylib-6.0.0-whq8uCSwLgWWeF3ec3dbG6Rr36SLFL-s2WJ1Q_2E22Bb/examples/shaders/resources/shaders/glsl100/raymarching.fs Normal file
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#version 100
#extension GL_OES_standard_derivatives : enable
precision mediump float;
// Input vertex attributes (from vertex shader)
varying vec2 fragTexCoord;
varying vec4 fragColor;
uniform vec3 viewEye;
uniform vec3 viewCenter;
uniform float runTime;
uniform vec2 resolution;
// The MIT License
// Copyright © 2013 Inigo Quilez
// 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.
// A list of useful distance function to simple primitives, and an example on how to
// do some interesting boolean operations, repetition and displacement
//
// More info here: http://www.iquilezles.org/www/articles/distfunctions/distfunctions.htm
#define AA 1 // make this 1 if your machine is too slow
//------------------------------------------------------------------
float sdPlane(vec3 p)
{
return p.y;
}
float sdSphere(vec3 p, float s)
{
return length(p)-s;
}
float sdBox(vec3 p, vec3 b)
{
vec3 d = abs(p) - b;
return min(max(d.x,max(d.y,d.z)),0.0) + length(max(d,0.0));
}
float sdEllipsoid(in vec3 p, in vec3 r)
{
return (length(p/r) - 1.0)*min(min(r.x,r.y),r.z);
}
float udRoundBox(vec3 p, vec3 b, float r)
{
return length(max(abs(p)-b,0.0))-r;
}
float sdTorus(vec3 p, vec2 t)
{
return length(vec2(length(p.xz)-t.x,p.y))-t.y;
}
float sdHexPrism(vec3 p, vec2 h)
{
vec3 q = abs(p);
#if 0
return max(q.z-h.y,max((q.x*0.866025+q.y*0.5),q.y)-h.x);
#else
float d1 = q.z-h.y;
float d2 = max((q.x*0.866025+q.y*0.5),q.y)-h.x;
return length(max(vec2(d1,d2),0.0)) + min(max(d1,d2), 0.);
#endif
}
float sdCapsule(vec3 p, vec3 a, vec3 b, float r)
{
vec3 pa = p-a, ba = b-a;
float h = clamp(dot(pa,ba)/dot(ba,ba), 0.0, 1.0);
return length(pa - ba*h) - r;
}
float sdEquilateralTriangle( in vec2 p)
{
const float k = sqrt(3.0);
p.x = abs(p.x) - 1.0;
p.y = p.y + 1.0/k;
if (p.x + k*p.y > 0.0) p = vec2(p.x - k*p.y, -k*p.x - p.y)/2.0;
p.x += 2.0 - 2.0*clamp((p.x+2.0)/2.0, 0.0, 1.0);
return -length(p)*sign(p.y);
}
float sdTriPrism(vec3 p, vec2 h)
{
vec3 q = abs(p);
float d1 = q.z-h.y;
#if 1
// distance bound
float d2 = max(q.x*0.866025+p.y*0.5,-p.y)-h.x*0.5;
#else
// correct distance
h.x *= 0.866025;
float d2 = sdEquilateralTriangle(p.xy/h.x)*h.x;
#endif
return length(max(vec2(d1,d2),0.0)) + min(max(d1,d2), 0.);
}
float sdCylinder(vec3 p, vec2 h)
{
vec2 d = abs(vec2(length(p.xz),p.y)) - h;
return min(max(d.x,d.y),0.0) + length(max(d,0.0));
}
float sdCone(in vec3 p, in vec3 c)
{
vec2 q = vec2(length(p.xz), p.y);
float d1 = -q.y-c.z;
float d2 = max(dot(q,c.xy), q.y);
return length(max(vec2(d1,d2),0.0)) + min(max(d1,d2), 0.);
}
float sdConeSection(in vec3 p, in float h, in float r1, in float r2)
{
float d1 = -p.y - h;
float q = p.y - h;
float si = 0.5*(r1-r2)/h;
float d2 = max(sqrt(dot(p.xz,p.xz)*(1.0-si*si)) + q*si - r2, q);
return length(max(vec2(d1,d2),0.0)) + min(max(d1,d2), 0.);
}
float sdPryamid4(vec3 p, vec3 h) // h = { cos a, sin a, height }
{
// Tetrahedron = Octahedron - Cube
float box = sdBox(p - vec3(0,-2.0*h.z,0), vec3(2.0*h.z));
float d = 0.0;
d = max(d, abs(dot(p, vec3(-h.x, h.y, 0))));
d = max(d, abs(dot(p, vec3( h.x, h.y, 0))));
d = max(d, abs(dot(p, vec3( 0, h.y, h.x))));
d = max(d, abs(dot(p, vec3( 0, h.y,-h.x))));
float octa = d - h.z;
return max(-box,octa); // Subtraction
}
float length2(vec2 p)
{
return sqrt(p.x*p.x + p.y*p.y);
}
float length6(vec2 p)
{
p = p*p*p; p = p*p;
return pow(p.x + p.y, 1.0/6.0);
}
float length8(vec2 p)
{
p = p*p; p = p*p; p = p*p;
return pow(p.x + p.y, 1.0/8.0);
}
float sdTorus82(vec3 p, vec2 t)
{
vec2 q = vec2(length2(p.xz)-t.x,p.y);
return length8(q)-t.y;
}
float sdTorus88(vec3 p, vec2 t)
{
vec2 q = vec2(length8(p.xz)-t.x,p.y);
return length8(q)-t.y;
}
float sdCylinder6(vec3 p, vec2 h)
{
return max(length6(p.xz)-h.x, abs(p.y)-h.y);
}
//------------------------------------------------------------------
float opS(float d1, float d2)
{
return max(-d2,d1);
}
vec2 opU(vec2 d1, vec2 d2)
{
return (d1.x<d2.x) ? d1 : d2;
}
vec3 opRep(vec3 p, vec3 c)
{
return mod(p,c)-0.5*c;
}
vec3 opTwist(vec3 p)
{
float c = cos(10.0*p.y+10.0);
float s = sin(10.0*p.y+10.0);
mat2 m = mat2(c,-s,s,c);
return vec3(m*p.xz,p.y);
}
//------------------------------------------------------------------
vec2 map(in vec3 pos)
{
vec2 res = opU(vec2(sdPlane( pos), 1.0),
vec2(sdSphere( pos-vec3(0.0,0.25, 0.0), 0.25), 46.9));
res = opU(res, vec2(sdBox( pos-vec3(1.0,0.25, 0.0), vec3(0.25)), 3.0));
res = opU(res, vec2(udRoundBox( pos-vec3(1.0,0.25, 1.0), vec3(0.15), 0.1), 41.0));
res = opU(res, vec2(sdTorus( pos-vec3(0.0,0.25, 1.0), vec2(0.20,0.05)), 25.0));
res = opU(res, vec2(sdCapsule( pos,vec3(-1.3,0.10,-0.1), vec3(-0.8,0.50,0.2), 0.1 ), 31.9));
res = opU(res, vec2(sdTriPrism( pos-vec3(-1.0,0.25,-1.0), vec2(0.25,0.05)),43.5));
res = opU(res, vec2(sdCylinder( pos-vec3(1.0,0.30,-1.0), vec2(0.1,0.2)), 8.0));
res = opU(res, vec2(sdCone( pos-vec3(0.0,0.50,-1.0), vec3(0.8,0.6,0.3)), 55.0));
res = opU(res, vec2(sdTorus82( pos-vec3(0.0,0.25, 2.0), vec2(0.20,0.05)),50.0));
res = opU(res, vec2(sdTorus88( pos-vec3(-1.0,0.25, 2.0), vec2(0.20,0.05)),43.0));
res = opU(res, vec2(sdCylinder6(pos-vec3(1.0,0.30, 2.0), vec2(0.1,0.2)), 12.0));
res = opU(res, vec2(sdHexPrism( pos-vec3(-1.0,0.20, 1.0), vec2(0.25,0.05)),17.0));
res = opU(res, vec2(sdPryamid4( pos-vec3(-1.0,0.15,-2.0), vec3(0.8,0.6,0.25)),37.0));
res = opU(res, vec2(opS(udRoundBox( pos-vec3(-2.0,0.2, 1.0), vec3(0.15),0.05),
sdSphere( pos-vec3(-2.0,0.2, 1.0), 0.25)), 13.0));
res = opU(res, vec2(opS(sdTorus82( pos-vec3(-2.0,0.2, 0.0), vec2(0.20,0.1)),
sdCylinder( opRep(vec3(atan(pos.x+2.0,pos.z)/6.2831, pos.y, 0.02+0.5*length(pos-vec3(-2.0,0.2, 0.0))), vec3(0.05,1.0,0.05)), vec2(0.02,0.6))), 51.0));
res = opU(res, vec2(0.5*sdSphere( pos-vec3(-2.0,0.25,-1.0), 0.2) + 0.03*sin(50.0*pos.x)*sin(50.0*pos.y)*sin(50.0*pos.z), 65.0));
res = opU(res, vec2(0.5*sdTorus(opTwist(pos-vec3(-2.0,0.25, 2.0)),vec2(0.20,0.05)), 46.7));
res = opU(res, vec2(sdConeSection(pos-vec3(0.0,0.35,-2.0), 0.15, 0.2, 0.1), 13.67));
res = opU(res, vec2(sdEllipsoid(pos-vec3(1.0,0.35,-2.0), vec3(0.15, 0.2, 0.05)), 43.17));
return res;
}
vec2 castRay(in vec3 ro, in vec3 rd)
{
float tmin = 0.2;
float tmax = 30.0;
#if 1
// bounding volume
float tp1 = (0.0-ro.y)/rd.y; if (tp1>0.0) tmax = min(tmax, tp1);
float tp2 = (1.6-ro.y)/rd.y; if (tp2>0.0) { if (ro.y>1.6) tmin = max(tmin, tp2);
else tmax = min(tmax, tp2); }
#endif
float t = tmin;
float m = -1.0;
for (int i=0; i<64; i++)
{
float precis = 0.0005*t;
vec2 res = map(ro+rd*t);
if (res.x<precis || t>tmax) break;
t += res.x;
m = res.y;
}
if (t>tmax) m=-1.0;
return vec2(t, m);
}
float calcSoftshadow(in vec3 ro, in vec3 rd, in float mint, in float tmax)
{
float res = 1.0;
float t = mint;
for (int i=0; i<16; i++)
{
float h = map(ro + rd*t).x;
res = min(res, 8.0*h/t);
t += clamp(h, 0.02, 0.10);
if (h<0.001 || t>tmax) break;
}
return clamp(res, 0.0, 1.0);
}
vec3 calcNormal(in vec3 pos)
{
vec2 e = vec2(1.0,-1.0)*0.5773*0.0005;
return normalize(e.xyy*map(pos + e.xyy).x +
e.yyx*map(pos + e.yyx).x +
e.yxy*map(pos + e.yxy).x +
e.xxx*map(pos + e.xxx).x);
/*
vec3 eps = vec3(0.0005, 0.0, 0.0);
vec3 nor = vec3(
map(pos+eps.xyy).x - map(pos-eps.xyy).x,
map(pos+eps.yxy).x - map(pos-eps.yxy).x,
map(pos+eps.yyx).x - map(pos-eps.yyx).x);
return normalize(nor);
*/
}
float calcAO(in vec3 pos, in vec3 nor)
{
float occ = 0.0;
float sca = 1.0;
for (int i=0; i<5; i++)
{
float hr = 0.01 + 0.12*float(i)/4.0;
vec3 aopos = nor*hr + pos;
float dd = map(aopos).x;
occ += -(dd-hr)*sca;
sca *= 0.95;
}
return clamp(1.0 - 3.0*occ, 0.0, 1.0);
}
// http://iquilezles.org/www/articles/checkerfiltering/checkerfiltering.htm
float checkersGradBox(in vec2 p)
{
// filter kernel
vec2 w = fwidth(p) + 0.001;
// analytical integral (box filter)
vec2 i = 2.0*(abs(fract((p-0.5*w)*0.5)-0.5)-abs(fract((p+0.5*w)*0.5)-0.5))/w;
// xor pattern
return 0.5 - 0.5*i.x*i.y;
}
vec3 render(in vec3 ro, in vec3 rd)
{
vec3 col = vec3(0.7, 0.9, 1.0) +rd.y*0.8;
vec2 res = castRay(ro,rd);
float t = res.x;
float m = res.y;
if (m>-0.5)
{
vec3 pos = ro + t*rd;
vec3 nor = calcNormal(pos);
vec3 ref = reflect(rd, nor);
// material
col = 0.45 + 0.35*sin(vec3(0.05,0.08,0.10)*(m-1.0));
if (m<1.5)
{
float f = checkersGradBox(5.0*pos.xz);
col = 0.3 + f*vec3(0.1);
}
// lighting
float occ = calcAO(pos, nor);
vec3 lig = normalize(vec3(cos(-0.4*runTime), sin(0.7*runTime), -0.6));
vec3 hal = normalize(lig-rd);
float amb = clamp(0.5+0.5*nor.y, 0.0, 1.0);
float dif = clamp(dot(nor, lig), 0.0, 1.0);
float bac = clamp(dot(nor, normalize(vec3(-lig.x,0.0,-lig.z))), 0.0, 1.0)*clamp(1.0-pos.y,0.0,1.0);
float dom = smoothstep(-0.1, 0.1, ref.y);
float fre = pow(clamp(1.0+dot(nor,rd),0.0,1.0), 2.0);
dif *= calcSoftshadow(pos, lig, 0.02, 2.5);
dom *= calcSoftshadow(pos, ref, 0.02, 2.5);
float spe = pow(clamp(dot(nor, hal), 0.0, 1.0),16.0)*
dif *
(0.04 + 0.96*pow(clamp(1.0+dot(hal,rd),0.0,1.0), 5.0));
vec3 lin = vec3(0.0);
lin += 1.30*dif*vec3(1.00,0.80,0.55);
lin += 0.40*amb*vec3(0.40,0.60,1.00)*occ;
lin += 0.50*dom*vec3(0.40,0.60,1.00)*occ;
lin += 0.50*bac*vec3(0.25,0.25,0.25)*occ;
lin += 0.25*fre*vec3(1.00,1.00,1.00)*occ;
col = col*lin;
col += 10.00*spe*vec3(1.00,0.90,0.70);
col = mix(col, vec3(0.8,0.9,1.0), 1.0-exp(-0.0002*t*t*t));
}
return vec3(clamp(col,0.0,1.0));
}
mat3 setCamera(in vec3 ro, in vec3 ta, float cr)
{
vec3 cw = normalize(ta-ro);
vec3 cp = vec3(sin(cr), cos(cr),0.0);
vec3 cu = normalize(cross(cw,cp));
vec3 cv = normalize(cross(cu,cw));
return mat3(cu, cv, cw);
}
void main()
{
vec3 tot = vec3(0.0);
#if AA>1
for (int m=0; m<AA; m++)
for (int n=0; n<AA; n++)
{
// pixel coordinates
vec2 o = vec2(float(m),float(n))/float(AA) - 0.5;
vec2 p = (-resolution.xy + 2.0*(gl_FragCoord.xy+o))/resolution.y;
#else
vec2 p = (-resolution.xy + 2.0*gl_FragCoord.xy)/resolution.y;
#endif
// RAY: Camera is provided from raylib
//vec3 ro = vec3(-0.5+3.5*cos(0.1*time + 6.0*mo.x), 1.0 + 2.0*mo.y, 0.5 + 4.0*sin(0.1*time + 6.0*mo.x));
vec3 ro = viewEye;
vec3 ta = viewCenter;
// camera-to-world transformation
mat3 ca = setCamera(ro, ta, 0.0);
// ray direction
vec3 rd = ca*normalize(vec3(p.xy,2.0));
// render
vec3 col = render(ro, rd);
// gamma
col = pow(col, vec3(0.4545));
tot += col;
#if AA>1
}
tot /= float(AA*AA);
#endif
gl_FragColor = vec4(tot, 1.0);
}

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zig-pkg/raylib-6.0.0-whq8uCSwLgWWeF3ec3dbG6Rr36SLFL-s2WJ1Q_2E22Bb/examples/shaders/resources/shaders/glsl100/reload.fs Normal file
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#version 100
precision mediump float;
// Input vertex attributes (from vertex shader)
varying vec2 fragTexCoord; // Texture coordinates (sampler2D)
varying vec4 fragColor; // Tint color
// Uniform inputs
uniform vec2 resolution; // Viewport resolution (in pixels)
uniform vec2 mouse; // Mouse pixel xy coordinates
uniform float time; // Total run time (in secods)
// Draw circle
vec4 DrawCircle(vec2 fragCoord, vec2 position, float radius, vec3 color)
{
float d = length(position - fragCoord) - radius;
float t = clamp(d, 0.0, 1.0);
return vec4(color, 1.0 - t);
}
void main()
{
vec2 fragCoord = gl_FragCoord.xy;
vec2 position = vec2(mouse.x, resolution.y - mouse.y);
float radius = 40.0;
// Draw background layer
vec4 colorA = vec4(0.2,0.2,0.8, 1.0);
vec4 colorB = vec4(1.0,0.7,0.2, 1.0);
vec4 layer1 = mix(colorA, colorB, abs(sin(time*0.1)));
// Draw circle layer
vec3 color = vec3(0.9, 0.16, 0.21);
vec4 layer2 = DrawCircle(fragCoord, position, radius, color);
// Blend the two layers
gl_FragColor = mix(layer1, layer2, layer2.a);
}

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zig-pkg/raylib-6.0.0-whq8uCSwLgWWeF3ec3dbG6Rr36SLFL-s2WJ1Q_2E22Bb/examples/shaders/resources/shaders/glsl100/rounded_rectangle.fs Normal file
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#version 100
precision mediump float;
// NOTE: SDF by Iñigo Quilez, licensed under MIT License
// Input vertex attributes (from vertex shader)
varying vec2 fragTexCoord;
varying vec4 fragColor;
// Input uniform values
uniform sampler2D texture0;
uniform vec4 colDiffuse;
uniform vec4 rectangle; // Rectangle dimensions (x, y, width, height)
uniform vec4 radius; // Corner radius (top-left, top-right, bottom-left, bottom-right)
uniform vec4 color;
// Shadow parameters
uniform float shadowRadius;
uniform vec2 shadowOffset;
uniform float shadowScale;
uniform vec4 shadowColor;
// Border parameters
uniform float borderThickness;
uniform vec4 borderColor;
// Create a rounded rectangle using signed distance field
// Thanks to Iñigo Quilez (https://www.iquilezles.org/www/articles/distfunctions/distfunctions.htm)
// And thanks to inobelar (https://www.shadertoy.com/view/fsdyzB) for shader
// MIT License
float RoundedRectangleSDF(vec2 fragCoord, vec2 center, vec2 halfSize, vec4 radius)
{
vec2 fragFromCenter = fragCoord - center;
// Determine which corner radius to use
radius.xy = (fragFromCenter.y > 0.0) ? radius.xy : radius.zw;
radius.x = (fragFromCenter.x < 0.0) ? radius.x : radius.y;
// Calculate signed distance field
vec2 dist = abs(fragFromCenter) - halfSize + radius.x;
return min(max(dist.x, dist.y), 0.0) + length(max(dist, 0.0)) - radius.x;
}
void main()
{
// Texel color fetching from texture sampler
vec4 texelColor = texture2D(texture0, fragTexCoord);
// Requires fragment coordinate varying pixels
vec2 fragCoord = gl_FragCoord.xy;
// Calculate signed distance field for rounded rectangle
vec2 halfSize = rectangle.zw*0.5;
vec2 center = rectangle.xy + halfSize;
float recSDF = RoundedRectangleSDF(fragCoord, center, halfSize, radius);
// Calculate signed distance field for rectangle shadow
vec2 shadowHalfSize = halfSize*shadowScale;
vec2 shadowCenter = center + shadowOffset;
float shadowSDF = RoundedRectangleSDF(fragCoord, shadowCenter, shadowHalfSize, radius);
// Caculate alpha factors
float recFactor = smoothstep(1.0, 0.0, recSDF);
float shadowFactor = smoothstep(shadowRadius, 0.0, shadowSDF);
float borderFactor = smoothstep(0.0, 1.0, recSDF + borderThickness)*recFactor;
// Multiply each color by its respective alpha factor
vec4 recColor = vec4(color.rgb, color.a*recFactor);
vec4 shadowCol = vec4(shadowColor.rgb, shadowColor.a*shadowFactor);
vec4 borderCol = vec4(borderColor.rgb, borderColor.a*borderFactor);
// Combine the colors varying the order (shadow, rectangle, border)
gl_FragColor = mix(mix(shadowCol, recColor, recColor.a), borderCol, borderCol.a);
}

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zig-pkg/raylib-6.0.0-whq8uCSwLgWWeF3ec3dbG6Rr36SLFL-s2WJ1Q_2E22Bb/examples/shaders/resources/shaders/glsl100/scanlines.fs Normal file
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#version 100
precision mediump float;
// Input vertex attributes (from vertex shader)
varying vec2 fragTexCoord;
varying vec4 fragColor;
// Input uniform values
uniform sampler2D texture0;
uniform vec4 colDiffuse;
// NOTE: Add your custom variables here
float offset = 0.0;
float frequency = 450.0/3.0;
uniform float time;
void main()
{
/*
// Scanlines method 1
float tval = 0; //time
vec2 uv = 0.5 + (fragTexCoord - 0.5)*(0.9 + 0.01*sin(0.5*tval));
vec4 color = texture2D(texture0, fragTexCoord);
color = clamp(color*0.5 + 0.5*color*color*1.2, 0.0, 1.0);
color *= 0.5 + 0.5*16.0*uv.x*uv.y*(1.0 - uv.x)*(1.0 - uv.y);
color *= vec4(0.8, 1.0, 0.7, 1);
color *= 0.9 + 0.1*sin(10.0*tval + uv.y*1000.0);
color *= 0.97 + 0.03*sin(110.0*tval);
fragColor = color;
*/
// Scanlines method 2
float globalPos = (fragTexCoord.y + offset)*frequency;
float wavePos = cos((fract(globalPos) - 0.5)*3.14);
vec4 color = texture2D(texture0, fragTexCoord);
gl_FragColor = mix(vec4(0.0, 0.3, 0.0, 0.0), color, wavePos);
}

86
zig-pkg/raylib-6.0.0-whq8uCSwLgWWeF3ec3dbG6Rr36SLFL-s2WJ1Q_2E22Bb/examples/shaders/resources/shaders/glsl100/shadowmap.fs Normal file
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#version 100
precision mediump float;
// This shader is based on the basic lighting shader
// This only supports one light, which is directional, and it (of course) supports shadows
// Input vertex attributes (from vertex shader)
varying vec3 fragPosition;
varying vec2 fragTexCoord;
//varying in vec4 fragColor;
varying vec3 fragNormal;
// Input uniform values
uniform sampler2D texture0;
uniform vec4 colDiffuse;
// Input lighting values
uniform vec3 lightDir;
uniform vec4 lightColor;
uniform vec4 ambient;
uniform vec3 viewPos;
// Input shadowmapping values
uniform mat4 lightVP; // Light source view-projection matrix
uniform sampler2D shadowMap;
uniform int shadowMapResolution;
void main()
{
// Texel color fetching from texture sampler
vec4 texelColor = texture2D(texture0, fragTexCoord);
vec3 lightDot = vec3(0.0);
vec3 normal = normalize(fragNormal);
vec3 viewD = normalize(viewPos - fragPosition);
vec3 specular = vec3(0.0);
vec3 l = -lightDir;
float NdotL = max(dot(normal, l), 0.0);
lightDot += lightColor.rgb*NdotL;
float specCo = 0.0;
if (NdotL > 0.0) specCo = pow(max(0.0, dot(viewD, reflect(-(l), normal))), 16.0); // 16 refers to shine
specular += specCo;
vec4 finalColor = (texelColor*((colDiffuse + vec4(specular, 1.0))*vec4(lightDot, 1.0)));
// Shadow calculations
vec4 fragPosLightSpace = lightVP*vec4(fragPosition, 1);
fragPosLightSpace.xyz /= fragPosLightSpace.w; // Perform the perspective division
fragPosLightSpace.xyz = (fragPosLightSpace.xyz + 1.0)/2.0; // Transform from [-1, 1] range to [0, 1] range
vec2 sampleCoords = fragPosLightSpace.xy;
float curDepth = fragPosLightSpace.z;
// Slope-scale depth bias: depth biasing reduces "shadow acne" artifacts, where dark stripes appear all over the scene
// The solution is adding a small bias to the depth
// In this case, the bias is proportional to the slope of the surface, relative to the light
float bias = max(0.0008*(1.0 - dot(normal, l)), 0.00008);
int shadowCounter = 0;
const int numSamples = 9;
// PCF (percentage-closer filtering) algorithm:
// Instead of testing if just one point is closer to the current point,
// we test the surrounding points as well
// This blurs shadow edges, hiding aliasing artifacts
vec2 texelSize = vec2(1.0/float(shadowMapResolution));
for (int x = -1; x <= 1; x++)
{
for (int y = -1; y <= 1; y++)
{
float sampleDepth = texture2D(shadowMap, sampleCoords + texelSize*vec2(x, y)).r;
if (curDepth - bias > sampleDepth) shadowCounter++;
}
}
finalColor = mix(finalColor, vec4(0, 0, 0, 1), float(shadowCounter)/float(numSamples));
// Add ambient lighting whether in shadow or not
finalColor += texelColor*(ambient/10.0)*colDiffuse;
// Gamma correction
finalColor = pow(finalColor, vec4(1.0/2.2));
gl_FragColor = finalColor;
}

32
zig-pkg/raylib-6.0.0-whq8uCSwLgWWeF3ec3dbG6Rr36SLFL-s2WJ1Q_2E22Bb/examples/shaders/resources/shaders/glsl100/shadowmap.vs Normal file
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#version 100
// Input vertex attributes
attribute vec3 vertexPosition;
attribute vec2 vertexTexCoord;
attribute vec3 vertexNormal;
attribute vec4 vertexColor;
// Input uniform values
uniform mat4 mvp;
uniform mat4 matModel;
uniform mat4 matNormal;
// Output vertex attributes (to fragment shader)
varying vec3 fragPosition;
varying vec2 fragTexCoord;
varying vec4 fragColor;
varying vec3 fragNormal;
// NOTE: Add your custom variables here
void main()
{
// Send vertex attributes to fragment shader
fragPosition = vec3(matModel*vec4(vertexPosition, 1.0));
fragTexCoord = vertexTexCoord;
fragColor = vertexColor;
fragNormal = normalize(vec3(matNormal*vec4(vertexNormal, 1.0)));
// Calculate final vertex position
gl_Position = mvp*vec4(vertexPosition, 1.0);
}

40
zig-pkg/raylib-6.0.0-whq8uCSwLgWWeF3ec3dbG6Rr36SLFL-s2WJ1Q_2E22Bb/examples/shaders/resources/shaders/glsl100/sobel.fs Normal file
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#version 100
precision mediump float;
// Input vertex attributes (from vertex shader)
varying vec2 fragTexCoord;
varying vec4 fragColor;
// Input uniform values
uniform sampler2D texture0;
uniform vec4 colDiffuse;
// NOTE: Add your custom variables here
vec2 resolution = vec2(800.0, 450.0);
void main()
{
float x = 1.0/resolution.x;
float y = 1.0/resolution.y;
vec4 horizEdge = vec4(0.0);
horizEdge -= texture2D(texture0, vec2(fragTexCoord.x - x, fragTexCoord.y - y))*1.0;
horizEdge -= texture2D(texture0, vec2(fragTexCoord.x - x, fragTexCoord.y ))*2.0;
horizEdge -= texture2D(texture0, vec2(fragTexCoord.x - x, fragTexCoord.y + y))*1.0;
horizEdge += texture2D(texture0, vec2(fragTexCoord.x + x, fragTexCoord.y - y))*1.0;
horizEdge += texture2D(texture0, vec2(fragTexCoord.x + x, fragTexCoord.y ))*2.0;
horizEdge += texture2D(texture0, vec2(fragTexCoord.x + x, fragTexCoord.y + y))*1.0;
vec4 vertEdge = vec4(0.0);
vertEdge -= texture2D(texture0, vec2(fragTexCoord.x - x, fragTexCoord.y - y))*1.0;
vertEdge -= texture2D(texture0, vec2(fragTexCoord.x , fragTexCoord.y - y))*2.0;
vertEdge -= texture2D(texture0, vec2(fragTexCoord.x + x, fragTexCoord.y - y))*1.0;
vertEdge += texture2D(texture0, vec2(fragTexCoord.x - x, fragTexCoord.y + y))*1.0;
vertEdge += texture2D(texture0, vec2(fragTexCoord.x , fragTexCoord.y + y))*2.0;
vertEdge += texture2D(texture0, vec2(fragTexCoord.x + x, fragTexCoord.y + y))*1.0;
vec3 edge = sqrt((horizEdge.rgb*horizEdge.rgb) + (vertEdge.rgb*vertEdge.rgb));
gl_FragColor = vec4(edge, texture2D(texture0, fragTexCoord).a);
}

77
zig-pkg/raylib-6.0.0-whq8uCSwLgWWeF3ec3dbG6Rr36SLFL-s2WJ1Q_2E22Bb/examples/shaders/resources/shaders/glsl100/spotlight.fs Normal file
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#version 100
precision mediump float;
#define MAX_SPOTS 3
struct Spot {
vec2 pos; // window coords of spot
float inner; // inner fully transparent centre radius
float radius; // alpha fades out to this radius
};
uniform Spot spots[MAX_SPOTS]; // Spotlight positions array
uniform float screenWidth; // Width of the screen
void main()
{
float alpha = 1.0;
// Get the position of the current fragment (screen coordinates!)
vec2 pos = vec2(gl_FragCoord.x, gl_FragCoord.y);
// Find out which spotlight is nearest
float d = 65000.0; // some high value
int fi = -1; // found index
for (int i = 0; i < MAX_SPOTS; i++)
{
for (int j = 0; j < MAX_SPOTS; j++)
{
float dj = distance(pos, spots[j].pos) - spots[j].radius + spots[i].radius;
if (d > dj)
{
d = dj;
fi = i;
}
}
}
// d now equals distance to nearest spot...
// allowing for the different radii of all spotlights
if (fi == 0)
{
if (d > spots[0].radius) alpha = 1.0;
else
{
if (d < spots[0].inner) alpha = 0.0;
else alpha = (d - spots[0].inner)/(spots[0].radius - spots[0].inner);
}
}
else if (fi == 1)
{
if (d > spots[1].radius) alpha = 1.0;
else
{
if (d < spots[1].inner) alpha = 0.0;
else alpha = (d - spots[1].inner)/(spots[1].radius - spots[1].inner);
}
}
else if (fi == 2)
{
if (d > spots[2].radius) alpha = 1.0;
else
{
if (d < spots[2].inner) alpha = 0.0;
else alpha = (d - spots[2].inner)/(spots[2].radius - spots[2].inner);
}
}
// Right hand side of screen is dimly lit,
// could make the threshold value user definable
if ((pos.x > screenWidth/2.0) && (alpha > 0.9)) alpha = 0.9;
// could make the black out colour user definable...
gl_FragColor = vec4(0, 0, 0, alpha);
}

46
zig-pkg/raylib-6.0.0-whq8uCSwLgWWeF3ec3dbG6Rr36SLFL-s2WJ1Q_2E22Bb/examples/shaders/resources/shaders/glsl100/swirl.fs Normal file
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#version 100
precision mediump float;
// Input vertex attributes (from vertex shader)
varying vec2 fragTexCoord;
varying vec4 fragColor;
// Input uniform values
uniform sampler2D texture0;
uniform vec4 colDiffuse;
// NOTE: Add your custom variables here
// NOTE: Render size values should be passed from code
const float renderWidth = 800.0;
const float renderHeight = 450.0;
float radius = 250.0;
float angle = 0.8;
uniform vec2 center;
void main()
{
vec2 texSize = vec2(renderWidth, renderHeight);
vec2 tc = fragTexCoord*texSize;
tc -= center;
float dist = length(tc);
if (dist < radius)
{
float percent = (radius - dist)/radius;
float theta = percent*percent*angle*8.0;
float s = sin(theta);
float c = cos(theta);
tc = vec2(dot(tc, vec2(c, -s)), dot(tc, vec2(s, c)));
}
tc += center;
vec4 color = texture2D(texture0, tc/texSize)*colDiffuse*fragColor;;
gl_FragColor = vec4(color.rgb, 1.0);
}

21
zig-pkg/raylib-6.0.0-whq8uCSwLgWWeF3ec3dbG6Rr36SLFL-s2WJ1Q_2E22Bb/examples/shaders/resources/shaders/glsl100/tiling.fs Normal file
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#version 100
precision mediump float;
// Input vertex attributes (from vertex shader)
varying vec2 fragTexCoord;
varying vec4 fragColor;
// Input uniform values
uniform sampler2D texture0;
uniform vec4 colDiffuse;
// NOTE: Add your custom variables here
uniform vec2 tiling;
void main()
{
vec2 texCoord = fragTexCoord*tiling;
gl_FragColor = texture2D(texture0, texCoord)*colDiffuse;
}

17
zig-pkg/raylib-6.0.0-whq8uCSwLgWWeF3ec3dbG6Rr36SLFL-s2WJ1Q_2E22Bb/examples/shaders/resources/shaders/glsl100/vertex_displacement.fs Normal file
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#version 100
precision mediump float;
// Input vertex attributes (from fragment shader)
varying vec2 fragTexCoord;
varying float height;
void main()
{
vec4 darkblue = vec4(0.0, 0.13, 0.18, 1.0);
vec4 lightblue = vec4(1.0, 1.0, 1.0, 1.0);
// Interpolate between two colors based on height
vec4 finalColor = mix(darkblue, lightblue, height);
gl_FragColor = finalColor;
}

45
zig-pkg/raylib-6.0.0-whq8uCSwLgWWeF3ec3dbG6Rr36SLFL-s2WJ1Q_2E22Bb/examples/shaders/resources/shaders/glsl100/vertex_displacement.vs Normal file
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#version 100
precision mediump float;
attribute vec3 vertexPosition;
attribute vec2 vertexTexCoord;
attribute vec3 vertexNormal;
attribute vec4 vertexColor;
uniform mat4 mvp;
uniform mat4 matModel;
uniform mat4 matNormal;
uniform float time;
uniform sampler2D perlinNoiseMap;
varying vec3 fragPosition;
varying vec2 fragTexCoord;
varying vec3 fragNormal;
varying float height;
void main()
{
// Calculate animated texture coordinates based on time and vertex position
vec2 animatedTexCoord = sin(vertexTexCoord + vec2(sin(time + vertexPosition.x*0.1), cos(time + vertexPosition.z*0.1))*0.3);
// Normalize animated texture coordinates to range [0, 1]
animatedTexCoord = animatedTexCoord*0.5 + 0.5;
// Fetch displacement from the perlin noise map
float displacement = texture2D(perlinNoiseMap, animatedTexCoord).r*7.0; // Amplified displacement
// Displace vertex position
vec3 displacedPosition = vertexPosition + vec3(0.0, displacement, 0.0);
// Send vertex attributes to fragment shader
fragPosition = vec3(matModel*vec4(displacedPosition, 1.0));
fragTexCoord = vertexTexCoord;
fragNormal = normalize(vec3(matNormal*vec4(vertexNormal, 1.0)));
height = displacedPosition.y*0.2; // send height to fragment shader for coloring
// Calculate final vertex position
gl_Position = mvp*vec4(displacedPosition, 1.0);
}

35
zig-pkg/raylib-6.0.0-whq8uCSwLgWWeF3ec3dbG6Rr36SLFL-s2WJ1Q_2E22Bb/examples/shaders/resources/shaders/glsl100/wave.fs Normal file
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#version 100
precision mediump float;
// Input vertex attributes (from vertex shader)
varying vec2 fragTexCoord;
varying vec4 fragColor;
// Input uniform values
uniform sampler2D texture0;
uniform vec4 colDiffuse;
uniform float seconds;
uniform vec2 size;
uniform float freqX;
uniform float freqY;
uniform float ampX;
uniform float ampY;
uniform float speedX;
uniform float speedY;
void main()
{
float pixelWidth = 1.0/size.x;
float pixelHeight = 1.0/size.y;
float aspect = pixelHeight/pixelWidth;
float boxLeft = 0.0;
float boxTop = 0.0;
vec2 p = fragTexCoord;
p.x += cos((fragTexCoord.y - boxTop)*freqX/(pixelWidth*750.0) + (seconds*speedX))*ampX*pixelWidth;
p.y += sin((fragTexCoord.x - boxLeft)*freqY*aspect/(pixelHeight*750.0) + (seconds*speedY))*ampY*pixelHeight;
gl_FragColor = texture2D(texture0, p)*colDiffuse*fragColor;
}

78
zig-pkg/raylib-6.0.0-whq8uCSwLgWWeF3ec3dbG6Rr36SLFL-s2WJ1Q_2E22Bb/examples/shaders/resources/shaders/glsl120/ascii.fs Normal file
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#version 120
// Input from the vertex shader
varying vec2 fragTexCoord;
// Output color for the screen
varying vec4 finalColor;
uniform sampler2D texture0;
uniform vec2 resolution;
// Fontsize less then 9 may be not complete
uniform float fontSize;
float GreyScale(in vec3 col)
{
return dot(col, vec3(0.2126, 0.7152, 0.0722));
}
float GetCharacter(float n, vec2 p)
{
p = floor(p*vec2(-4.0, 4.0) + 2.5);
// Check if the calculated coordinate is inside the 5x5 grid (from 0.0 to 4.0)
if (clamp(p.x, 0.0, 4.0) == p.x && clamp(p.y, 0.0, 4.0) == p.y)
{
float a = floor(p.x + 0.5) + 5.0*floor(p.y + 0.5);
// This checked if the 'a'-th bit of 'n' was set
float shiftedN = floor(n/pow(2.0, a));
if (mod(shiftedN, 2.0) == 1.0)
{
return 1.0; // The bit is on
}
}
return 0.0; // The bit is off, or we are outside the grid
}
// -----------------------------------------------------------------------------
// Main shader logic
// -----------------------------------------------------------------------------
void main()
{
vec2 charPixelSize = vec2(fontSize, fontSize);
vec2 uvCellSize = charPixelSize / resolution;
// The cell size is based on the fontSize set by application
vec2 cellUV = floor(fragTexCoord / uvCellSize)*uvCellSize;
vec3 cellColor = texture2D(texture0, cellUV).rgb;
// Gray is used to define what character will be selected to draw
float gray = GreyScale(cellColor);
float n = 4096.0;
// Character set from https://www.shadertoy.com/view/lssGDj
// Create new bitmaps https://thrill-project.com/archiv/coding/bitmap/
if (gray > 0.2) n = 65600.0; // :
if (gray > 0.3) n = 18725316.0; // v
if (gray > 0.4) n = 15255086.0; // o
if (gray > 0.5) n = 13121101.0; // &
if (gray > 0.6) n = 15252014.0; // 8
if (gray > 0.7) n = 13195790.0; // @
if (gray > 0.8) n = 11512810.0; // #
vec2 localUV = (fragTexCoord - cellUV)/uvCellSize; // Range [0.0, 1.0]
vec2 p = localUV*2.0 - 1.0; // Range [-1.0, 1.0]
// cellColor and charShape will define the color of the char
vec3 color = cellColor*GetCharacter(n, p);
gl_FragColor = vec4(color, 1.0);
}

22
zig-pkg/raylib-6.0.0-whq8uCSwLgWWeF3ec3dbG6Rr36SLFL-s2WJ1Q_2E22Bb/examples/shaders/resources/shaders/glsl120/base.fs Normal file
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#version 120
// Input vertex attributes (from vertex shader)
varying vec2 fragTexCoord;
varying vec4 fragColor;
// Input uniform values
uniform sampler2D texture0;
uniform vec4 colDiffuse;
// NOTE: Add your custom variables here
uniform vec2 resolution = vec2(800, 450);
void main()
{
// Texel color fetching from texture sampler
vec4 texelColor = texture2D(texture0, fragTexCoord);
// NOTE: Implement here your fragment shader code
gl_FragColor = texelColor*colDiffuse;
}

26
zig-pkg/raylib-6.0.0-whq8uCSwLgWWeF3ec3dbG6Rr36SLFL-s2WJ1Q_2E22Bb/examples/shaders/resources/shaders/glsl120/base.vs Normal file
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#version 120
// Input vertex attributes
attribute vec3 vertexPosition;
attribute vec2 vertexTexCoord;
attribute vec3 vertexNormal;
attribute vec4 vertexColor;
// Input uniform values
uniform mat4 mvp;
// Output vertex attributes (to fragment shader)
varying vec2 fragTexCoord;
varying vec4 fragColor;
// NOTE: Add your custom variables here
void main()
{
// Send vertex attributes to fragment shader
fragTexCoord = vertexTexCoord;
fragColor = vertexColor;
// Calculate final vertex position
gl_Position = mvp*vec4(vertexPosition, 1.0);
}

37
zig-pkg/raylib-6.0.0-whq8uCSwLgWWeF3ec3dbG6Rr36SLFL-s2WJ1Q_2E22Bb/examples/shaders/resources/shaders/glsl120/bloom.fs Normal file
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#version 120
// Input vertex attributes (from vertex shader)
varying vec2 fragTexCoord;
varying vec4 fragColor;
// Input uniform values
uniform sampler2D texture0;
uniform vec4 colDiffuse;
// NOTE: Add your custom variables here
const vec2 size = vec2(800, 450); // Framebuffer size
const float samples = 5.0; // Pixels per axis; higher = bigger glow, worse performance
const float quality = 2.5; // Defines size factor: Lower = smaller glow, better quality
void main()
{
vec4 sum = vec4(0);
vec2 sizeFactor = vec2(1)/size*quality;
// Texel color fetching from texture sampler
vec4 source = texture2D(texture0, fragTexCoord);
const int range = 2; // should be = (samples - 1)/2;
for (int x = -range; x <= range; x++)
{
for (int y = -range; y <= range; y++)
{
sum += texture2D(texture0, fragTexCoord + vec2(x, y)*sizeFactor);
}
}
// Calculate final fragment color
gl_FragColor = ((sum/(samples*samples)) + source)*colDiffuse;
}

32
zig-pkg/raylib-6.0.0-whq8uCSwLgWWeF3ec3dbG6Rr36SLFL-s2WJ1Q_2E22Bb/examples/shaders/resources/shaders/glsl120/blur.fs Normal file
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#version 120
// Input vertex attributes (from vertex shader)
varying vec2 fragTexCoord;
varying vec4 fragColor;
// Input uniform values
uniform sampler2D texture0;
uniform vec4 colDiffuse;
// NOTE: Add your custom variables here
// NOTE: Render size values must be passed from code
const float renderWidth = 800.0;
const float renderHeight = 450.0;
vec3 offset = vec3(0.0, 1.3846153846, 3.2307692308);
vec3 weight = vec3(0.2270270270, 0.3162162162, 0.0702702703);
void main()
{
// Texel color fetching from texture sampler
vec3 tc = texture2D(texture0, fragTexCoord).rgb*weight.x;
tc += texture2D(texture0, fragTexCoord + vec2(offset.y)/renderWidth, 0.0).rgb*weight.y;
tc += texture2D(texture0, fragTexCoord - vec2(offset.y)/renderWidth, 0.0).rgb*weight.y;
tc += texture2D(texture0, fragTexCoord + vec2(offset.z)/renderWidth, 0.0).rgb*weight.z;
tc += texture2D(texture0, fragTexCoord - vec2(offset.z)/renderWidth, 0.0).rgb*weight.z;
gl_FragColor = vec4(tc, 1.0);
}

56
zig-pkg/raylib-6.0.0-whq8uCSwLgWWeF3ec3dbG6Rr36SLFL-s2WJ1Q_2E22Bb/examples/shaders/resources/shaders/glsl120/cel.fs Normal file
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#version 120
varying vec3 fragPosition;
varying vec2 fragTexCoord;
varying vec4 fragColor;
varying vec3 fragNormal;
uniform sampler2D texture0;
uniform vec4 colDiffuse;
uniform vec3 viewPos;
uniform float numBands;
struct Light {
int enabled;
int type;
vec3 position;
vec3 target;
vec4 color;
};
uniform Light lights[4];
void main()
{
vec4 texColor = texture2D(texture0, fragTexCoord);
vec3 baseColor = texColor.rgb * fragColor.rgb * colDiffuse.rgb;
vec3 norm = normalize(fragNormal);
float lightAccum = 0.08; // ambient floor
for (int i = 0; i < 4; i++)
{
if (lights[i].enabled == 1)
{
vec3 lightDir;
if (lights[i].type == 0)
{
// Directional: direction is from position toward target.
lightDir = normalize(lights[i].position - lights[i].target);
}
else
{
// Point: direction from surface to light.
lightDir = normalize(lights[i].position - fragPosition);
}
float NdotL = max(dot(norm, lightDir), 0.0);
// Quantize NdotL into numBands discrete steps.
float quantized = min(floor(NdotL * numBands), numBands - 1.0) / (numBands - 1.0);
lightAccum += quantized * lights[i].color.r;
}
}
lightAccum = clamp(lightAccum, 0.0, 1.0);
gl_FragColor = vec4(baseColor * lightAccum, texColor.a * colDiffuse.a);
}

48
zig-pkg/raylib-6.0.0-whq8uCSwLgWWeF3ec3dbG6Rr36SLFL-s2WJ1Q_2E22Bb/examples/shaders/resources/shaders/glsl120/cel.vs Normal file
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#version 120
attribute vec3 vertexPosition;
attribute vec2 vertexTexCoord;
attribute vec3 vertexNormal;
attribute vec4 vertexColor;
uniform mat4 mvp;
uniform mat4 matModel;
varying vec3 fragPosition;
varying vec2 fragTexCoord;
varying vec4 fragColor;
varying vec3 fragNormal;
// inverse() and transpose() are not built-in until GLSL 1.40
mat3 inverse(mat3 m)
{
float a00 = m[0][0], a01 = m[0][1], a02 = m[0][2];
float a10 = m[1][0], a11 = m[1][1], a12 = m[1][2];
float a20 = m[2][0], a21 = m[2][1], a22 = m[2][2];
float b01 = a22*a11 - a12*a21;
float b11 = -a22*a10 + a12*a20;
float b21 = a21*a10 - a11*a20;
float det = a00*b01 + a01*b11 + a02*b21;
return mat3(b01, (-a22*a01 + a02*a21), ( a12*a01 - a02*a11),
b11, ( a22*a00 - a02*a20), (-a12*a00 + a02*a10),
b21, (-a21*a00 + a01*a20), ( a11*a00 - a01*a10)) / det;
}
mat3 transpose(mat3 m)
{
return mat3(m[0][0], m[1][0], m[2][0],
m[0][1], m[1][1], m[2][1],
m[0][2], m[1][2], m[2][2]);
}
void main()
{
fragPosition = vec3(matModel * vec4(vertexPosition, 1.0));
fragTexCoord = vertexTexCoord;
fragColor = vertexColor;
mat3 normalMatrix = transpose(inverse(mat3(matModel)));
fragNormal = normalize(normalMatrix * vertexNormal);
gl_Position = mvp * vec4(vertexPosition, 1.0);
}

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