godot/servers/visual/rasterizer_rd/shaders/giprobe_sdf.glsl

[compute]

#version 450

VERSION_DEFINES

layout(local_size_x = 4, local_size_y = 4, local_size_z = 4) in;

#define MAX_DISTANCE 100000

#define NO_CHILDREN 0xFFFFFFFF
#define GREY_VEC vec3(0.33333,0.33333,0.33333)

struct CellChildren {
	uint children[8];
};

layout(set=0,binding=1,std430) buffer CellChildrenBuffer {
    CellChildren data[];
} cell_children;


struct CellData {
	uint position; // xyz 10 bits
	uint albedo; //rgb albedo
	uint emission; //rgb normalized with e as multiplier
	uint normal; //RGB normal encoded
};

layout(set=0,binding=2,std430) buffer CellDataBuffer {
    CellData data[];
} cell_data;

layout (r8ui,set=0,binding=3) uniform restrict writeonly uimage3D sdf_tex;


layout(push_constant, binding = 0, std430) uniform Params {

	uint offset;
	uint end;
	uint pad0;
	uint pad1;
} params;

void main() {

	vec3 pos = vec3(gl_GlobalInvocationID);
	float closest_dist = 100000.0;

	for(uint i=params.offset;i<params.end;i++) {
		vec3 posu = vec3(uvec3(cell_data.data[i].position&0x7FF,(cell_data.data[i].position>>11)&0x3FF,cell_data.data[i].position>>21));
		float dist = length(pos-posu);
		if (dist < closest_dist) {
			closest_dist = dist;
		}
	}

	uint dist_8;

	if (closest_dist<0.0001) { // same cell
		dist_8=0; //equals to -1
	} else {
		dist_8 = clamp(uint(closest_dist),0,254) + 1; //conservative, 0 is 1, so <1 is considered solid
	}

	imageStore(sdf_tex,ivec3(gl_GlobalInvocationID),uvec4(dist_8));
	//imageStore(sdf_tex,pos,uvec4(pos*2,0));
}


#if 0
layout(push_constant, binding = 0, std430) uniform Params {

	ivec3 limits;
	uint stack_size;
} params;


float distance_to_aabb(ivec3 pos, ivec3 aabb_pos, ivec3 aabb_size) {

	vec3 delta = vec3(max(ivec3(0),max(aabb_pos - pos, pos - (aabb_pos + aabb_size - ivec3(1)))));
	return length(delta);
}

void main() {

	ivec3 pos = ivec3(gl_GlobalInvocationID);

	uint stack[10]=uint[](0,0,0,0,0,0,0,0,0,0);
	uint stack_indices[10]=uint[](0,0,0,0,0,0,0,0,0,0);
	ivec3 stack_positions[10]=ivec3[](ivec3(0),ivec3(0),ivec3(0),ivec3(0),ivec3(0),ivec3(0),ivec3(0),ivec3(0),ivec3(0),ivec3(0));

	const uint cell_orders[8]=uint[](
		0x11f58d1,
		0xe2e70a,
		0xd47463,
		0xbb829c,
		0x8d11f5,
		0x70ae2e,
		0x463d47,
		0x29cbb8
	);

	bool cell_found = false;
	bool cell_found_exact = false;
	ivec3 closest_cell_pos;
	float closest_distance = MAX_DISTANCE;
	int stack_pos = 0;

	while(true) {

		uint index = stack_indices[stack_pos]>>24;

		if (index == 8) {
			//go up
			if (stack_pos==0) {
				break; //done going through octree
			}
			stack_pos--;
			continue;
		}

		stack_indices[stack_pos] = (stack_indices[stack_pos]&((1<<24)-1))|((index + 1)<<24);


		uint cell_index = (stack_indices[stack_pos]>>(index*3))&0x7;
		uint child_cell = cell_children.data[stack[stack_pos]].children[cell_index];

		if (child_cell == NO_CHILDREN) {
			continue;
		}

		ivec3 child_cell_size = params.limits >> (stack_pos+1);
		ivec3 child_cell_pos = stack_positions[stack_pos];

		child_cell_pos+=mix(ivec3(0),child_cell_size,bvec3(uvec3(index&1,index&2,index&4)!=uvec3(0)));

		bool is_leaf = stack_pos == (params.stack_size-2);

		if (child_cell_pos==pos && is_leaf) {
			//we may actually end up in the exact cell.
			//if this happens, just abort
			cell_found_exact=true;
			break;
		}

		if (cell_found) {
			//discard by distance
			float distance = distance_to_aabb(pos,child_cell_pos,child_cell_size);
			if (distance >= closest_distance) {
				continue; //pointless, just test next child
			} else if (is_leaf) {
				//closer than what we have AND end of stack, save and continue
				closest_cell_pos = child_cell_pos;
				closest_distance = distance;
				continue;
			}
		} else if (is_leaf) {
			//first solid cell we find, save and continue
			closest_distance = distance_to_aabb(pos,child_cell_pos,child_cell_size);
			closest_cell_pos = child_cell_pos;
			cell_found=true;
			continue;
		}


		bvec3 direction = greaterThan(( pos - ( child_cell_pos + (child_cell_size >>1) ) ) , ivec3(0) );
		uint cell_order = 0;
		cell_order|=mix(0,1,direction.x);
		cell_order|=mix(0,2,direction.y);
		cell_order|=mix(0,4,direction.z);

		stack[stack_pos+1]=child_cell;
		stack_indices[stack_pos+1]=cell_orders[cell_order]; //start counting
		stack_positions[stack_pos+1]=child_cell_pos;
		stack_pos++; //go up stack

	}

	uint dist_8;

	if (cell_found_exact) {
		dist_8=0; //equals to -1
	} else {
		float closest_distance = length(vec3(pos-closest_cell_pos));
		dist_8 = clamp(uint(closest_distance),0,254) + 1; //conservative, 0 is 1, so <1 is considered solid
	}

	imageStore(sdf_tex,pos,uvec4(dist_8));

}
#endif
Dynamic object support for GI Probes (a bit buggy still) 2019-10-11 04:14:56 +02:00			`[compute]`

			`#version 450`

			`VERSION_DEFINES`

			`layout(local_size_x = 4, local_size_y = 4, local_size_z = 4) in;`

			`#define MAX_DISTANCE 100000`

			`#define NO_CHILDREN 0xFFFFFFFF`
			`#define GREY_VEC vec3(0.33333,0.33333,0.33333)`

			`struct CellChildren {`
			`uint children[8];`
			`};`

			`layout(set=0,binding=1,std430) buffer CellChildrenBuffer {`
			`CellChildren data[];`
			`} cell_children;`


			`struct CellData {`
			`uint position; // xyz 10 bits`
			`uint albedo; //rgb albedo`
			`uint emission; //rgb normalized with e as multiplier`
			`uint normal; //RGB normal encoded`
			`};`

			`layout(set=0,binding=2,std430) buffer CellDataBuffer {`
			`CellData data[];`
			`} cell_data;`

			`layout (r8ui,set=0,binding=3) uniform restrict writeonly uimage3D sdf_tex;`


			`layout(push_constant, binding = 0, std430) uniform Params {`

			`uint offset;`
			`uint end;`
			`uint pad0;`
			`uint pad1;`
			`} params;`

			`void main() {`

			`vec3 pos = vec3(gl_GlobalInvocationID);`
			`float closest_dist = 100000.0;`

			`for(uint i=params.offset;i<params.end;i++) {`
			`vec3 posu = vec3(uvec3(cell_data.data[i].position&0x7FF,(cell_data.data[i].position>>11)&0x3FF,cell_data.data[i].position>>21));`
			`float dist = length(pos-posu);`
			`if (dist < closest_dist) {`
			`closest_dist = dist;`
			`}`
			`}`

			`uint dist_8;`

			`if (closest_dist<0.0001) { // same cell`
			`dist_8=0; //equals to -1`
			`} else {`
			`dist_8 = clamp(uint(closest_dist),0,254) + 1; //conservative, 0 is 1, so <1 is considered solid`
			`}`

			`imageStore(sdf_tex,ivec3(gl_GlobalInvocationID),uvec4(dist_8));`
			`//imageStore(sdf_tex,pos,uvec4(pos*2,0));`
			`}`


			`#if 0`
			`layout(push_constant, binding = 0, std430) uniform Params {`

			`ivec3 limits;`
			`uint stack_size;`
			`} params;`


			`float distance_to_aabb(ivec3 pos, ivec3 aabb_pos, ivec3 aabb_size) {`

			`vec3 delta = vec3(max(ivec3(0),max(aabb_pos - pos, pos - (aabb_pos + aabb_size - ivec3(1)))));`
			`return length(delta);`
			`}`

			`void main() {`

			`ivec3 pos = ivec3(gl_GlobalInvocationID);`

			`uint stack[10]=uint[](0,0,0,0,0,0,0,0,0,0);`
			`uint stack_indices[10]=uint[](0,0,0,0,0,0,0,0,0,0);`
			`ivec3 stack_positions[10]=ivec3[](ivec3(0),ivec3(0),ivec3(0),ivec3(0),ivec3(0),ivec3(0),ivec3(0),ivec3(0),ivec3(0),ivec3(0));`

			`const uint cell_orders[8]=uint[](`
			`0x11f58d1,`
			`0xe2e70a,`
			`0xd47463,`
			`0xbb829c,`
			`0x8d11f5,`
			`0x70ae2e,`
			`0x463d47,`
			`0x29cbb8`
			`);`

			`bool cell_found = false;`
			`bool cell_found_exact = false;`
			`ivec3 closest_cell_pos;`
			`float closest_distance = MAX_DISTANCE;`
			`int stack_pos = 0;`

			`while(true) {`

			`uint index = stack_indices[stack_pos]>>24;`

			`if (index == 8) {`
			`//go up`
			`if (stack_pos==0) {`
			`break; //done going through octree`
			`}`
			`stack_pos--;`
			`continue;`
			`}`

			`stack_indices[stack_pos] = (stack_indices[stack_pos]&((1<<24)-1))\|((index + 1)<<24);`


			`uint cell_index = (stack_indices[stack_pos]>>(index*3))&0x7;`
			`uint child_cell = cell_children.data[stack[stack_pos]].children[cell_index];`

			`if (child_cell == NO_CHILDREN) {`
			`continue;`
			`}`

			`ivec3 child_cell_size = params.limits >> (stack_pos+1);`
			`ivec3 child_cell_pos = stack_positions[stack_pos];`

			`child_cell_pos+=mix(ivec3(0),child_cell_size,bvec3(uvec3(index&1,index&2,index&4)!=uvec3(0)));`

			`bool is_leaf = stack_pos == (params.stack_size-2);`

			`if (child_cell_pos==pos && is_leaf) {`
			`//we may actually end up in the exact cell.`
			`//if this happens, just abort`
			`cell_found_exact=true;`
			`break;`
			`}`

			`if (cell_found) {`
			`//discard by distance`
			`float distance = distance_to_aabb(pos,child_cell_pos,child_cell_size);`
			`if (distance >= closest_distance) {`
			`continue; //pointless, just test next child`
			`} else if (is_leaf) {`
			`//closer than what we have AND end of stack, save and continue`
			`closest_cell_pos = child_cell_pos;`
			`closest_distance = distance;`
			`continue;`
			`}`
			`} else if (is_leaf) {`
			`//first solid cell we find, save and continue`
			`closest_distance = distance_to_aabb(pos,child_cell_pos,child_cell_size);`
			`closest_cell_pos = child_cell_pos;`
			`cell_found=true;`
			`continue;`
			`}`




			`bvec3 direction = greaterThan(( pos - ( child_cell_pos + (child_cell_size >>1) ) ) , ivec3(0) );`
			`uint cell_order = 0;`
			`cell_order\|=mix(0,1,direction.x);`
			`cell_order\|=mix(0,2,direction.y);`
			`cell_order\|=mix(0,4,direction.z);`

			`stack[stack_pos+1]=child_cell;`
			`stack_indices[stack_pos+1]=cell_orders[cell_order]; //start counting`
			`stack_positions[stack_pos+1]=child_cell_pos;`
			`stack_pos++; //go up stack`

			`}`

			`uint dist_8;`

			`if (cell_found_exact) {`
			`dist_8=0; //equals to -1`
			`} else {`
			`float closest_distance = length(vec3(pos-closest_cell_pos));`
			`dist_8 = clamp(uint(closest_distance),0,254) + 1; //conservative, 0 is 1, so <1 is considered solid`
			`}`

			`imageStore(sdf_tex,pos,uvec4(dist_8));`

			`}`
			`#endif`