120 lines
3.4 KiB
GLSL
120 lines
3.4 KiB
GLSL
#[compute]
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#version 450
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#VERSION_DEFINES
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layout(local_size_x = 8, local_size_y = 8, local_size_z = 1) in;
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layout(push_constant, std430) uniform Params {
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uint cluster_render_data_size; // how much data for a single cluster takes
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uint max_render_element_count_div_32; //divided by 32
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uvec2 cluster_screen_size;
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uint render_element_count_div_32; //divided by 32
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uint max_cluster_element_count_div_32; //divided by 32
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uint pad1;
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uint pad2;
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}
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params;
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layout(set = 0, binding = 1, std430) buffer restrict readonly ClusterRender {
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uint data[];
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}
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cluster_render;
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layout(set = 0, binding = 2, std430) buffer restrict ClusterStore {
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uint data[];
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}
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cluster_store;
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struct RenderElement {
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uint type; //0-4
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bool touches_near;
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bool touches_far;
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uint original_index;
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mat3x4 transform_inv;
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vec3 scale;
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uint pad;
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};
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layout(set = 0, binding = 3, std430) buffer restrict readonly RenderElements {
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RenderElement data[];
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}
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render_elements;
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void main() {
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uvec2 pos = gl_GlobalInvocationID.xy;
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if (any(greaterThanEqual(pos, params.cluster_screen_size))) {
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return;
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}
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//counter for each type of render_element
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//base offset for this cluster
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uint base_offset = (pos.x + params.cluster_screen_size.x * pos.y);
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uint src_offset = base_offset * params.cluster_render_data_size;
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uint render_element_offset = 0;
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//check all render_elements and see which one was written to
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while (render_element_offset < params.render_element_count_div_32) {
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uint bits = cluster_render.data[src_offset + render_element_offset];
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while (bits != 0) {
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//if bits exist, check the render_element
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uint index_bit = findLSB(bits);
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uint index = render_element_offset * 32 + index_bit;
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uint type = render_elements.data[index].type;
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uint z_range_offset = src_offset + params.max_render_element_count_div_32 + index;
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uint z_range = cluster_render.data[z_range_offset];
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//if object was written, z was written, but check just in case
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if (z_range != 0) { //should always be > 0
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uint from_z = findLSB(z_range);
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uint to_z = findMSB(z_range) + 1;
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if (render_elements.data[index].touches_near) {
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from_z = 0;
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}
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if (render_elements.data[index].touches_far) {
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to_z = 32;
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}
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// find cluster offset in the buffer used for indexing in the renderer
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uint dst_offset = (base_offset + type * (params.cluster_screen_size.x * params.cluster_screen_size.y)) * (params.max_cluster_element_count_div_32 + 32);
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uint orig_index = render_elements.data[index].original_index;
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//store this index in the Z slices by setting the relevant bit
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for (uint i = from_z; i < to_z; i++) {
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uint slice_ofs = dst_offset + params.max_cluster_element_count_div_32 + i;
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uint minmax = cluster_store.data[slice_ofs];
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if (minmax == 0) {
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minmax = 0xFFFF; //min 0, max 0xFFFF
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}
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uint elem_min = min(orig_index, minmax & 0xFFFF);
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uint elem_max = max(orig_index + 1, minmax >> 16); //always store plus one, so zero means range is empty when not written to
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minmax = elem_min | (elem_max << 16);
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cluster_store.data[slice_ofs] = minmax;
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}
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uint store_word = orig_index >> 5;
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uint store_bit = orig_index & 0x1F;
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//store the actual render_element index at the end, so the rendering code can reference it
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cluster_store.data[dst_offset + store_word] |= 1 << store_bit;
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}
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bits &= ~(1 << index_bit); //clear the bit to continue iterating
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}
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render_element_offset++;
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}
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}
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