godot/modules/lightmapper_rd/lm_raster.glsl

#[vertex]

#version 450

#VERSION_DEFINES

#include "lm_common_inc.glsl"

layout(location = 0) out vec3 vertex_interp;
layout(location = 1) out vec3 normal_interp;
layout(location = 2) out vec2 uv_interp;
layout(location = 3) out vec3 barycentric;
layout(location = 4) flat out uvec3 vertex_indices;
layout(location = 5) flat out vec3 face_normal;
layout(location = 6) flat out uint fragment_action;

layout(push_constant, std430) uniform Params {
	vec2 atlas_size;
	vec2 uv_offset;
	vec3 to_cell_size;
	uint base_triangle;
	vec3 to_cell_offset;
	float bias;
	ivec3 grid_size;
	uint pad2;
}
params;

void main() {
	uint triangle_idx = params.base_triangle + gl_VertexIndex / 3;
	uint triangle_subidx = gl_VertexIndex % 3;

	vertex_indices = triangles.data[triangle_idx].indices;

	uint vertex_idx;
	if (triangle_subidx == 0) {
		vertex_idx = vertex_indices.x;
		barycentric = vec3(1, 0, 0);
	} else if (triangle_subidx == 1) {
		vertex_idx = vertex_indices.y;
		barycentric = vec3(0, 1, 0);
	} else {
		vertex_idx = vertex_indices.z;
		barycentric = vec3(0, 0, 1);
	}

	vertex_interp = vertices.data[vertex_idx].position;
	uv_interp = vertices.data[vertex_idx].uv;
	normal_interp = vec3(vertices.data[vertex_idx].normal_xy, vertices.data[vertex_idx].normal_z);

	face_normal = -normalize(cross((vertices.data[vertex_indices.x].position - vertices.data[vertex_indices.y].position), (vertices.data[vertex_indices.x].position - vertices.data[vertex_indices.z].position)));

	{
		const float FLAT_THRESHOLD = 0.99;
		const vec3 norm_a = vec3(vertices.data[vertex_indices.x].normal_xy, vertices.data[vertex_indices.x].normal_z);
		const vec3 norm_b = vec3(vertices.data[vertex_indices.y].normal_xy, vertices.data[vertex_indices.y].normal_z);
		const vec3 norm_c = vec3(vertices.data[vertex_indices.z].normal_xy, vertices.data[vertex_indices.z].normal_z);
		fragment_action = (dot(norm_a, norm_b) < FLAT_THRESHOLD || dot(norm_a, norm_c) < FLAT_THRESHOLD || dot(norm_b, norm_c) < FLAT_THRESHOLD) ? FA_SMOOTHEN_POSITION : FA_NONE;
	}

	gl_Position = vec4((uv_interp + params.uv_offset) * 2.0 - 1.0, 0.0001, 1.0);
}

#[fragment]

#version 450

#VERSION_DEFINES

#include "lm_common_inc.glsl"

layout(push_constant, std430) uniform Params {
	vec2 atlas_size;
	vec2 uv_offset;
	vec3 to_cell_size;
	uint base_triangle;
	vec3 to_cell_offset;
	float bias;
	ivec3 grid_size;
	uint pad2;
}
params;

layout(location = 0) in vec3 vertex_interp;
layout(location = 1) in vec3 normal_interp;
layout(location = 2) in vec2 uv_interp;
layout(location = 3) in vec3 barycentric;
layout(location = 4) in flat uvec3 vertex_indices;
layout(location = 5) in flat vec3 face_normal;
layout(location = 6) in flat uint fragment_action;

layout(location = 0) out vec4 position;
layout(location = 1) out vec4 normal;
layout(location = 2) out vec4 unocclude;

void main() {
	vec3 vertex_pos = vertex_interp;

	if (fragment_action == FA_SMOOTHEN_POSITION) {
		// smooth out vertex position by interpolating its projection in the 3 normal planes (normal plane is created by vertex pos and normal)
		// because we don't want to interpolate inwards, normals found pointing inwards are pushed out.
		vec3 pos_a = vertices.data[vertex_indices.x].position;
		vec3 pos_b = vertices.data[vertex_indices.y].position;
		vec3 pos_c = vertices.data[vertex_indices.z].position;
		vec3 center = (pos_a + pos_b + pos_c) * 0.3333333;
		vec3 norm_a = vec3(vertices.data[vertex_indices.x].normal_xy, vertices.data[vertex_indices.x].normal_z);
		vec3 norm_b = vec3(vertices.data[vertex_indices.y].normal_xy, vertices.data[vertex_indices.y].normal_z);
		vec3 norm_c = vec3(vertices.data[vertex_indices.z].normal_xy, vertices.data[vertex_indices.z].normal_z);

		{
			vec3 dir_a = normalize(pos_a - center);
			float d_a = dot(dir_a, norm_a);
			if (d_a < 0) {
				//pointing inwards
				norm_a = normalize(norm_a - dir_a * d_a);
			}
		}
		{
			vec3 dir_b = normalize(pos_b - center);
			float d_b = dot(dir_b, norm_b);
			if (d_b < 0) {
				//pointing inwards
				norm_b = normalize(norm_b - dir_b * d_b);
			}
		}
		{
			vec3 dir_c = normalize(pos_c - center);
			float d_c = dot(dir_c, norm_c);
			if (d_c < 0) {
				//pointing inwards
				norm_c = normalize(norm_c - dir_c * d_c);
			}
		}

		float d_a = dot(norm_a, pos_a);
		float d_b = dot(norm_b, pos_b);
		float d_c = dot(norm_c, pos_c);

		vec3 proj_a = vertex_pos - norm_a * (dot(norm_a, vertex_pos) - d_a);
		vec3 proj_b = vertex_pos - norm_b * (dot(norm_b, vertex_pos) - d_b);
		vec3 proj_c = vertex_pos - norm_c * (dot(norm_c, vertex_pos) - d_c);

		vec3 smooth_position = proj_a * barycentric.x + proj_b * barycentric.y + proj_c * barycentric.z;

		if (dot(face_normal, smooth_position) > dot(face_normal, vertex_pos)) { //only project outwards
			vertex_pos = smooth_position;
		}
	}

	{
		// unocclusion technique based on:
		// https://ndotl.wordpress.com/2018/08/29/baking-artifact-free-lightmaps/

		/* compute texel size */
		vec3 delta_uv = max(abs(dFdx(vertex_interp)), abs(dFdy(vertex_interp)));
		float texel_size = max(delta_uv.x, max(delta_uv.y, delta_uv.z));
		texel_size *= sqrt(2.0); //expand to unit box edge length (again, worst case)

		unocclude.xyz = face_normal;
		unocclude.w = texel_size;

		//continued on lm_compute.glsl
	}

	position = vec4(vertex_pos, 1.0);
	normal = vec4(normalize(normal_interp), 1.0);
}
GLSL: Change shader type specifier from [vertex] to #[vertex] The added `#` prevents clang-format from misinterpreting the meaning of this statement and thus messing up the formatting of the next lines up until the first `layout` statement. Similarly, a semicolon is now enforced on `versions` defines to prevent clang-format from messing up formatting and putting them all on a single line. Note: In its current state the code will ignore chained statements on a single line separated by a semicolon. Also removed some extraneous lines missed in previous style changes or added by mistake with said changes (e.g. after uniform definitions that clang-format messes up somewhat too, but we live with it). 2020-05-18 08:56:22 +00:00			`#[vertex]`
New lightmapper -Added LocalVector (needed it) -Added stb_rect_pack (It's pretty cool, we could probably use it for other stuff too) -Fixes and changes all around the place -Added library for 128 bits fixed point (required for Delaunay3D) 2020-05-01 12:34:23 +00:00
			`#version 450`

Refactor GLSL shader compilation -Used a more consistent set of keywords for the shader -Remove all harcoded entry points -Re-wrote the GLSL shader parser, new system is more flexible. Allows any entry point organization. -Entry point for sky shaders is now sky(). -Entry point for particle shaders is now process(). 2021-04-13 20:01:43 +00:00			`#VERSION_DEFINES`
New lightmapper -Added LocalVector (needed it) -Added stb_rect_pack (It's pretty cool, we could probably use it for other stuff too) -Fixes and changes all around the place -Added library for 128 bits fixed point (required for Delaunay3D) 2020-05-01 12:34:23 +00:00
			`#include "lm_common_inc.glsl"`

GLSL: Change shader type specifier from [vertex] to #[vertex] The added `#` prevents clang-format from misinterpreting the meaning of this statement and thus messing up the formatting of the next lines up until the first `layout` statement. Similarly, a semicolon is now enforced on `versions` defines to prevent clang-format from messing up formatting and putting them all on a single line. Note: In its current state the code will ignore chained statements on a single line separated by a semicolon. Also removed some extraneous lines missed in previous style changes or added by mistake with said changes (e.g. after uniform definitions that clang-format messes up somewhat too, but we live with it). 2020-05-18 08:56:22 +00:00			`layout(location = 0) out vec3 vertex_interp;`
New lightmapper -Added LocalVector (needed it) -Added stb_rect_pack (It's pretty cool, we could probably use it for other stuff too) -Fixes and changes all around the place -Added library for 128 bits fixed point (required for Delaunay3D) 2020-05-01 12:34:23 +00:00			`layout(location = 1) out vec3 normal_interp;`
			`layout(location = 2) out vec2 uv_interp;`
			`layout(location = 3) out vec3 barycentric;`
			`layout(location = 4) flat out uvec3 vertex_indices;`
			`layout(location = 5) flat out vec3 face_normal;`
GPULightmapper: skip smoothen positions for flat triangles Smoothening positions for flat, non-smoothened, triangles is unnecessary and caused positions to move outside their triangle which caused side-effects as rays from those positions intersected with triangles which could not be reached from the original triangle. This is solved by skipping smoothening of positions for flat triangles. A triangle is determined to be flas as its vertex normals are equal. 2021-10-01 21:20:20 +00:00			`layout(location = 6) flat out uint fragment_action;`
New lightmapper -Added LocalVector (needed it) -Added stb_rect_pack (It's pretty cool, we could probably use it for other stuff too) -Fixes and changes all around the place -Added library for 128 bits fixed point (required for Delaunay3D) 2020-05-01 12:34:23 +00:00
RendererRD: Remove binding specifier for push constants This is unsupported and glslang made it raise an error in 11.7.0: https://github.com/KhronosGroup/glslang/pull/2810 Co-authored-by: Clay John <claynjohn@gmail.com> 2022-02-11 17:40:24 +00:00			`layout(push_constant, std430) uniform Params {`
New lightmapper -Added LocalVector (needed it) -Added stb_rect_pack (It's pretty cool, we could probably use it for other stuff too) -Fixes and changes all around the place -Added library for 128 bits fixed point (required for Delaunay3D) 2020-05-01 12:34:23 +00:00			`vec2 atlas_size;`
			`vec2 uv_offset;`
			`vec3 to_cell_size;`
			`uint base_triangle;`
			`vec3 to_cell_offset;`
			`float bias;`
			`ivec3 grid_size;`
			`uint pad2;`
			`}`
			`params;`

			`void main() {`
			`uint triangle_idx = params.base_triangle + gl_VertexIndex / 3;`
			`uint triangle_subidx = gl_VertexIndex % 3;`

			`vertex_indices = triangles.data[triangle_idx].indices;`

			`uint vertex_idx;`
			`if (triangle_subidx == 0) {`
			`vertex_idx = vertex_indices.x;`
			`barycentric = vec3(1, 0, 0);`
			`} else if (triangle_subidx == 1) {`
			`vertex_idx = vertex_indices.y;`
			`barycentric = vec3(0, 1, 0);`
			`} else {`
			`vertex_idx = vertex_indices.z;`
			`barycentric = vec3(0, 0, 1);`
			`}`

			`vertex_interp = vertices.data[vertex_idx].position;`
			`uv_interp = vertices.data[vertex_idx].uv;`
			`normal_interp = vec3(vertices.data[vertex_idx].normal_xy, vertices.data[vertex_idx].normal_z);`

			`face_normal = -normalize(cross((vertices.data[vertex_indices.x].position - vertices.data[vertex_indices.y].position), (vertices.data[vertex_indices.x].position - vertices.data[vertex_indices.z].position)));`

GPULightmapper: skip smoothen positions for flat triangles Smoothening positions for flat, non-smoothened, triangles is unnecessary and caused positions to move outside their triangle which caused side-effects as rays from those positions intersected with triangles which could not be reached from the original triangle. This is solved by skipping smoothening of positions for flat triangles. A triangle is determined to be flas as its vertex normals are equal. 2021-10-01 21:20:20 +00:00			`{`
			`const float FLAT_THRESHOLD = 0.99;`
			`const vec3 norm_a = vec3(vertices.data[vertex_indices.x].normal_xy, vertices.data[vertex_indices.x].normal_z);`
			`const vec3 norm_b = vec3(vertices.data[vertex_indices.y].normal_xy, vertices.data[vertex_indices.y].normal_z);`
			`const vec3 norm_c = vec3(vertices.data[vertex_indices.z].normal_xy, vertices.data[vertex_indices.z].normal_z);`
			`fragment_action = (dot(norm_a, norm_b) < FLAT_THRESHOLD \|\| dot(norm_a, norm_c) < FLAT_THRESHOLD \|\| dot(norm_b, norm_c) < FLAT_THRESHOLD) ? FA_SMOOTHEN_POSITION : FA_NONE;`
			`}`

New lightmapper -Added LocalVector (needed it) -Added stb_rect_pack (It's pretty cool, we could probably use it for other stuff too) -Fixes and changes all around the place -Added library for 128 bits fixed point (required for Delaunay3D) 2020-05-01 12:34:23 +00:00			`gl_Position = vec4((uv_interp + params.uv_offset) * 2.0 - 1.0, 0.0001, 1.0);`
			`}`

GLSL: Change shader type specifier from [vertex] to #[vertex] The added `#` prevents clang-format from misinterpreting the meaning of this statement and thus messing up the formatting of the next lines up until the first `layout` statement. Similarly, a semicolon is now enforced on `versions` defines to prevent clang-format from messing up formatting and putting them all on a single line. Note: In its current state the code will ignore chained statements on a single line separated by a semicolon. Also removed some extraneous lines missed in previous style changes or added by mistake with said changes (e.g. after uniform definitions that clang-format messes up somewhat too, but we live with it). 2020-05-18 08:56:22 +00:00			`#[fragment]`
New lightmapper -Added LocalVector (needed it) -Added stb_rect_pack (It's pretty cool, we could probably use it for other stuff too) -Fixes and changes all around the place -Added library for 128 bits fixed point (required for Delaunay3D) 2020-05-01 12:34:23 +00:00
			`#version 450`

Refactor GLSL shader compilation -Used a more consistent set of keywords for the shader -Remove all harcoded entry points -Re-wrote the GLSL shader parser, new system is more flexible. Allows any entry point organization. -Entry point for sky shaders is now sky(). -Entry point for particle shaders is now process(). 2021-04-13 20:01:43 +00:00			`#VERSION_DEFINES`
New lightmapper -Added LocalVector (needed it) -Added stb_rect_pack (It's pretty cool, we could probably use it for other stuff too) -Fixes and changes all around the place -Added library for 128 bits fixed point (required for Delaunay3D) 2020-05-01 12:34:23 +00:00
			`#include "lm_common_inc.glsl"`

RendererRD: Remove binding specifier for push constants This is unsupported and glslang made it raise an error in 11.7.0: https://github.com/KhronosGroup/glslang/pull/2810 Co-authored-by: Clay John <claynjohn@gmail.com> 2022-02-11 17:40:24 +00:00			`layout(push_constant, std430) uniform Params {`
New lightmapper -Added LocalVector (needed it) -Added stb_rect_pack (It's pretty cool, we could probably use it for other stuff too) -Fixes and changes all around the place -Added library for 128 bits fixed point (required for Delaunay3D) 2020-05-01 12:34:23 +00:00			`vec2 atlas_size;`
			`vec2 uv_offset;`
			`vec3 to_cell_size;`
			`uint base_triangle;`
			`vec3 to_cell_offset;`
			`float bias;`
			`ivec3 grid_size;`
			`uint pad2;`
GLSL: Change shader type specifier from [vertex] to #[vertex] The added `#` prevents clang-format from misinterpreting the meaning of this statement and thus messing up the formatting of the next lines up until the first `layout` statement. Similarly, a semicolon is now enforced on `versions` defines to prevent clang-format from messing up formatting and putting them all on a single line. Note: In its current state the code will ignore chained statements on a single line separated by a semicolon. Also removed some extraneous lines missed in previous style changes or added by mistake with said changes (e.g. after uniform definitions that clang-format messes up somewhat too, but we live with it). 2020-05-18 08:56:22 +00:00			`}`
			`params;`
New lightmapper -Added LocalVector (needed it) -Added stb_rect_pack (It's pretty cool, we could probably use it for other stuff too) -Fixes and changes all around the place -Added library for 128 bits fixed point (required for Delaunay3D) 2020-05-01 12:34:23 +00:00
			`layout(location = 0) in vec3 vertex_interp;`
			`layout(location = 1) in vec3 normal_interp;`
			`layout(location = 2) in vec2 uv_interp;`
			`layout(location = 3) in vec3 barycentric;`
			`layout(location = 4) in flat uvec3 vertex_indices;`
			`layout(location = 5) in flat vec3 face_normal;`
GPULightmapper: skip smoothen positions for flat triangles Smoothening positions for flat, non-smoothened, triangles is unnecessary and caused positions to move outside their triangle which caused side-effects as rays from those positions intersected with triangles which could not be reached from the original triangle. This is solved by skipping smoothening of positions for flat triangles. A triangle is determined to be flas as its vertex normals are equal. 2021-10-01 21:20:20 +00:00			`layout(location = 6) in flat uint fragment_action;`
New lightmapper -Added LocalVector (needed it) -Added stb_rect_pack (It's pretty cool, we could probably use it for other stuff too) -Fixes and changes all around the place -Added library for 128 bits fixed point (required for Delaunay3D) 2020-05-01 12:34:23 +00:00
			`layout(location = 0) out vec4 position;`
			`layout(location = 1) out vec4 normal;`
			`layout(location = 2) out vec4 unocclude;`

			`void main() {`
			`vec3 vertex_pos = vertex_interp;`

GPULightmapper: skip smoothen positions for flat triangles Smoothening positions for flat, non-smoothened, triangles is unnecessary and caused positions to move outside their triangle which caused side-effects as rays from those positions intersected with triangles which could not be reached from the original triangle. This is solved by skipping smoothening of positions for flat triangles. A triangle is determined to be flas as its vertex normals are equal. 2021-10-01 21:20:20 +00:00			`if (fragment_action == FA_SMOOTHEN_POSITION) {`
New lightmapper -Added LocalVector (needed it) -Added stb_rect_pack (It's pretty cool, we could probably use it for other stuff too) -Fixes and changes all around the place -Added library for 128 bits fixed point (required for Delaunay3D) 2020-05-01 12:34:23 +00:00			`// smooth out vertex position by interpolating its projection in the 3 normal planes (normal plane is created by vertex pos and normal)`
			`// because we don't want to interpolate inwards, normals found pointing inwards are pushed out.`
			`vec3 pos_a = vertices.data[vertex_indices.x].position;`
			`vec3 pos_b = vertices.data[vertex_indices.y].position;`
			`vec3 pos_c = vertices.data[vertex_indices.z].position;`
			`vec3 center = (pos_a + pos_b + pos_c) * 0.3333333;`
			`vec3 norm_a = vec3(vertices.data[vertex_indices.x].normal_xy, vertices.data[vertex_indices.x].normal_z);`
			`vec3 norm_b = vec3(vertices.data[vertex_indices.y].normal_xy, vertices.data[vertex_indices.y].normal_z);`
			`vec3 norm_c = vec3(vertices.data[vertex_indices.z].normal_xy, vertices.data[vertex_indices.z].normal_z);`

			`{`
			`vec3 dir_a = normalize(pos_a - center);`
			`float d_a = dot(dir_a, norm_a);`
			`if (d_a < 0) {`
			`//pointing inwards`
			`norm_a = normalize(norm_a - dir_a * d_a);`
			`}`
			`}`
			`{`
			`vec3 dir_b = normalize(pos_b - center);`
			`float d_b = dot(dir_b, norm_b);`
			`if (d_b < 0) {`
			`//pointing inwards`
			`norm_b = normalize(norm_b - dir_b * d_b);`
			`}`
			`}`
			`{`
			`vec3 dir_c = normalize(pos_c - center);`
			`float d_c = dot(dir_c, norm_c);`
			`if (d_c < 0) {`
			`//pointing inwards`
			`norm_c = normalize(norm_c - dir_c * d_c);`
			`}`
			`}`

			`float d_a = dot(norm_a, pos_a);`
			`float d_b = dot(norm_b, pos_b);`
			`float d_c = dot(norm_c, pos_c);`

			`vec3 proj_a = vertex_pos - norm_a * (dot(norm_a, vertex_pos) - d_a);`
			`vec3 proj_b = vertex_pos - norm_b * (dot(norm_b, vertex_pos) - d_b);`
			`vec3 proj_c = vertex_pos - norm_c * (dot(norm_c, vertex_pos) - d_c);`

			`vec3 smooth_position = proj_a * barycentric.x + proj_b * barycentric.y + proj_c * barycentric.z;`

			`if (dot(face_normal, smooth_position) > dot(face_normal, vertex_pos)) { //only project outwards`
			`vertex_pos = smooth_position;`
			`}`
			`}`

			`{`
			`// unocclusion technique based on:`
			`// https://ndotl.wordpress.com/2018/08/29/baking-artifact-free-lightmaps/`

			`/* compute texel size */`
			`vec3 delta_uv = max(abs(dFdx(vertex_interp)), abs(dFdy(vertex_interp)));`
			`float texel_size = max(delta_uv.x, max(delta_uv.y, delta_uv.z));`
			`texel_size *= sqrt(2.0); //expand to unit box edge length (again, worst case)`

			`unocclude.xyz = face_normal;`
			`unocclude.w = texel_size;`

			`//continued on lm_compute.glsl`
			`}`

			`position = vec4(vertex_pos, 1.0);`
			`normal = vec4(normalize(normal_interp), 1.0);`
			`}`