prosperon/source/shaders/grid3d.sglsl

@vs vsg3
// Shared set between most vertex shaders
uniform ViewUniforms {
  uniform mat4 view;
  uniform mat4 proj;
};

out vec3 nearPoint;
out vec3 farPoint;
out mat4 fragView;
out mat4 fragProj;

// Grid position are in xy clipped space
vec3 gridPlane[6] = vec3[](
    vec3(1, 1, 0), vec3(-1, -1, 0), vec3(-1, 1, 0),
    vec3(-1, -1, 0), vec3(1, 1, 0), vec3(1, -1, 0)
);

// normal vertice projection
vec3 UnprojectPoint(float x, float y, float z, mat4 view, mat4 projection) {
    mat4 viewInv = inverse(view);
    mat4 projInv = inverse(projection);
    vec4 unprojectedPoint =  viewInv * projInv * vec4(x, y, z, 1.0);
    return unprojectedPoint.xyz / unprojectedPoint.w;
}

void main() {
    vec3 p = gridPlane[gl_VertexIndex].xyz;
    nearPoint = UnprojectPoint(p.x, p.y, 0.0, view, proj).xyz; // unprojecting on the near plane
    farPoint = UnprojectPoint(p.x, p.y, 1.0, view, proj).xyz; // unprojecting on the far plane
    fragView = view;
    fragProj = proj;
    gl_Position = vec4(p, 1.0); // using directly the clipped coordinates
}
@end

@fs fsg3
float near = 0.01;
float far = 100;
in vec3 nearPoint;
in vec3 farPoint;
in mat4 fragView;
in mat4 fragProj;
out vec4 outColor;

vec4 grid(vec3 fragPos3D, float scale, bool drawAxis) {
    vec2 coord = fragPos3D.xz * scale;
    vec2 derivative = fwidth(coord);
    vec2 grid = abs(fract(coord - 0.5) - 0.5) / derivative;
    float line = min(grid.x, grid.y);
    float minimumz = min(derivative.y, 1);
    float minimumx = min(derivative.x, 1);
    vec4 color = vec4(0.2, 0.2, 0.2, 1.0 - min(line, 1.0));
    // z axis
    if(fragPos3D.x > -0.1 * minimumx && fragPos3D.x < 0.1 * minimumx)
        color.z = 1.0;
    // x axis
    if(fragPos3D.z > -0.1 * minimumz && fragPos3D.z < 0.1 * minimumz)
        color.x = 1.0;
    return color;
}
float computeDepth(vec3 pos) {
    vec4 clip_space_pos = fragProj * fragView * vec4(pos.xyz, 1.0);
    return (clip_space_pos.z / clip_space_pos.w);
}
float computeLinearDepth(vec3 pos) {
    vec4 clip_space_pos = fragProj * fragView * vec4(pos.xyz, 1.0);
    float clip_space_depth = (clip_space_pos.z / clip_space_pos.w) * 2.0 - 1.0; // put back between -1 and 1
    float linearDepth = (2.0 * near * far) / (far + near - clip_space_depth * (far - near)); // get linear value between 0.01 and 100
    return linearDepth / far; // normalize
}
void main() {
    float t = -nearPoint.y / (farPoint.y - nearPoint.y);
    vec3 fragPos3D = nearPoint + t * (farPoint - nearPoint);

    gl_FragDepth = computeDepth(fragPos3D);

    float linearDepth = computeLinearDepth(fragPos3D);
    float fading = max(0, (0.5 - linearDepth));

    outColor = (grid(fragPos3D, 10, true) + grid(fragPos3D, 1, true))* float(t > 0); // adding multiple resolution for the grid
    outColor.a *= fading;
}
@end

@program grid3d vsg3 fsg3
Basic 3d 2024-04-20 12:55:20 -05:00			`@vs vsg3`
			`// Shared set between most vertex shaders`
			`uniform ViewUniforms {`
			`uniform mat4 view;`
			`uniform mat4 proj;`
			`};`

			`out vec3 nearPoint;`
			`out vec3 farPoint;`
			`out mat4 fragView;`
			`out mat4 fragProj;`

			`// Grid position are in xy clipped space`
			`vec3 gridPlane[6] = vec3[](`
			`vec3(1, 1, 0), vec3(-1, -1, 0), vec3(-1, 1, 0),`
			`vec3(-1, -1, 0), vec3(1, 1, 0), vec3(1, -1, 0)`
			`);`

			`// normal vertice projection`
			`vec3 UnprojectPoint(float x, float y, float z, mat4 view, mat4 projection) {`
			`mat4 viewInv = inverse(view);`
			`mat4 projInv = inverse(projection);`
			`vec4 unprojectedPoint = viewInv * projInv * vec4(x, y, z, 1.0);`
			`return unprojectedPoint.xyz / unprojectedPoint.w;`
			`}`

			`void main() {`
			`vec3 p = gridPlane[gl_VertexIndex].xyz;`
			`nearPoint = UnprojectPoint(p.x, p.y, 0.0, view, proj).xyz; // unprojecting on the near plane`
			`farPoint = UnprojectPoint(p.x, p.y, 1.0, view, proj).xyz; // unprojecting on the far plane`
			`fragView = view;`
			`fragProj = proj;`
			`gl_Position = vec4(p, 1.0); // using directly the clipped coordinates`
			`}`
			`@end`

			`@fs fsg3`
			`float near = 0.01;`
			`float far = 100;`
			`in vec3 nearPoint;`
			`in vec3 farPoint;`
			`in mat4 fragView;`
			`in mat4 fragProj;`
			`out vec4 outColor;`

			`vec4 grid(vec3 fragPos3D, float scale, bool drawAxis) {`
			`vec2 coord = fragPos3D.xz * scale;`
			`vec2 derivative = fwidth(coord);`
			`vec2 grid = abs(fract(coord - 0.5) - 0.5) / derivative;`
			`float line = min(grid.x, grid.y);`
			`float minimumz = min(derivative.y, 1);`
			`float minimumx = min(derivative.x, 1);`
			`vec4 color = vec4(0.2, 0.2, 0.2, 1.0 - min(line, 1.0));`
			`// z axis`
			`if(fragPos3D.x > -0.1 * minimumx && fragPos3D.x < 0.1 * minimumx)`
			`color.z = 1.0;`
			`// x axis`
			`if(fragPos3D.z > -0.1 * minimumz && fragPos3D.z < 0.1 * minimumz)`
			`color.x = 1.0;`
			`return color;`
			`}`
			`float computeDepth(vec3 pos) {`
			`vec4 clip_space_pos = fragProj * fragView * vec4(pos.xyz, 1.0);`
			`return (clip_space_pos.z / clip_space_pos.w);`
			`}`
			`float computeLinearDepth(vec3 pos) {`
			`vec4 clip_space_pos = fragProj * fragView * vec4(pos.xyz, 1.0);`
			`float clip_space_depth = (clip_space_pos.z / clip_space_pos.w) * 2.0 - 1.0; // put back between -1 and 1`
			`float linearDepth = (2.0 * near * far) / (far + near - clip_space_depth * (far - near)); // get linear value between 0.01 and 100`
			`return linearDepth / far; // normalize`
			`}`
			`void main() {`
			`float t = -nearPoint.y / (farPoint.y - nearPoint.y);`
			`vec3 fragPos3D = nearPoint + t * (farPoint - nearPoint);`

			`gl_FragDepth = computeDepth(fragPos3D);`

			`float linearDepth = computeLinearDepth(fragPos3D);`
			`float fading = max(0, (0.5 - linearDepth));`

			`outColor = (grid(fragPos3D, 10, true) + grid(fragPos3D, 1, true))* float(t > 0); // adding multiple resolution for the grid`
			`outColor.a *= fading;`
			`}`
			`@end`

			`@program grid3d vsg3 fsg3`