70cd25f3eb
In rare situations if a light is placed near colinear to a frustum edge, the extra culling plane derived can have an inaccurate normal due to floating point error. This PR detects colinear triangles, and prevents adding a culling plane in this situation.
281 lines
11 KiB
C++
281 lines
11 KiB
C++
/**************************************************************************/
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/* rendering_light_culler.h */
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/**************************************************************************/
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/* This file is part of: */
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/* GODOT ENGINE */
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/* https://godotengine.org */
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/**************************************************************************/
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/* Copyright (c) 2014-present Godot Engine contributors (see AUTHORS.md). */
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/* Copyright (c) 2007-2014 Juan Linietsky, Ariel Manzur. */
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/* */
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/* Permission is hereby granted, free of charge, to any person obtaining */
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/* a copy of this software and associated documentation files (the */
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/* "Software"), to deal in the Software without restriction, including */
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/* without limitation the rights to use, copy, modify, merge, publish, */
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/* distribute, sublicense, and/or sell copies of the Software, and to */
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/* permit persons to whom the Software is furnished to do so, subject to */
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/* the following conditions: */
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/* */
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/* The above copyright notice and this permission notice shall be */
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/* included in all copies or substantial portions of the Software. */
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/* */
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/* THE SOFTWARE IS PROVIDED "AS IS", WITHOUT WARRANTY OF ANY KIND, */
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/* EXPRESS OR IMPLIED, INCLUDING BUT NOT LIMITED TO THE WARRANTIES OF */
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/* MERCHANTABILITY, FITNESS FOR A PARTICULAR PURPOSE AND NONINFRINGEMENT. */
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/* IN NO EVENT SHALL THE AUTHORS OR COPYRIGHT HOLDERS BE LIABLE FOR ANY */
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/* CLAIM, DAMAGES OR OTHER LIABILITY, WHETHER IN AN ACTION OF CONTRACT, */
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/* TORT OR OTHERWISE, ARISING FROM, OUT OF OR IN CONNECTION WITH THE */
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/* SOFTWARE OR THE USE OR OTHER DEALINGS IN THE SOFTWARE. */
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/**************************************************************************/
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#ifndef RENDERING_LIGHT_CULLER_H
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#define RENDERING_LIGHT_CULLER_H
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#include "core/math/plane.h"
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#include "core/math/vector3.h"
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#include "renderer_scene_cull.h"
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struct Projection;
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struct Transform3D;
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// For testing performance improvements from the LightCuller:
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// Uncomment LIGHT_CULLER_DEBUG_FLASH and it will turn the culler
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// on and off every LIGHT_CULLER_DEBUG_FLASH_FREQUENCY camera prepares.
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// Uncomment LIGHT_CULLER_DEBUG_LOGGING to get periodic print of the number of casters culled before / after.
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// Uncomment LIGHT_CULLER_DEBUG_DIRECTIONAL_LIGHT to get periodic print of the number of casters culled for the directional light..
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// #define LIGHT_CULLER_DEBUG_LOGGING
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// #define LIGHT_CULLER_DEBUG_DIRECTIONAL_LIGHT
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// #define LIGHT_CULLER_DEBUG_REGULAR_LIGHT
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// #define LIGHT_CULLER_DEBUG_FLASH
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#define LIGHT_CULLER_DEBUG_FLASH_FREQUENCY 1024
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////////////////////////////////////////////////////////////////////////////////////////////////
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// The code to generate the lookup table is included but commented out.
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// This may be useful for debugging / regenerating the LUT in the future,
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// especially if the order of planes changes.
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// When this define is set, the generated lookup table will be printed to debug output.
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// The generated lookup table can be copy pasted
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// straight to LUT_entry_sizes and LUT_entries.
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// See the referenced article for explanation.
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// #define RENDERING_LIGHT_CULLER_CALCULATE_LUT
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////////////////////////////////////////////////////////////////////////////////////////////////
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// This define will be set automatically depending on earlier defines, you can leave this as is.
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#if defined(LIGHT_CULLER_DEBUG_LOGGING) || defined(RENDERING_LIGHT_CULLER_CALCULATE_LUT)
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#define RENDERING_LIGHT_CULLER_DEBUG_STRINGS
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#endif
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// Culls shadow casters that can't cast shadows into the camera frustum.
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class RenderingLightCuller {
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public:
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RenderingLightCuller();
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private:
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class LightSource {
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public:
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enum SourceType {
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ST_UNKNOWN,
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ST_DIRECTIONAL,
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ST_SPOTLIGHT,
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ST_OMNI,
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};
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LightSource() {
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type = ST_UNKNOWN;
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angle = 0.0f;
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range = FLT_MAX;
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}
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// All in world space, culling done in world space.
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Vector3 pos;
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Vector3 dir;
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SourceType type;
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float angle; // For spotlight.
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float range;
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};
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// Same order as godot.
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enum PlaneOrder {
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PLANE_NEAR,
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PLANE_FAR,
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PLANE_LEFT,
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PLANE_TOP,
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PLANE_RIGHT,
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PLANE_BOTTOM,
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PLANE_TOTAL,
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};
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// Same order as godot.
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enum PointOrder {
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PT_FAR_LEFT_TOP,
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PT_FAR_LEFT_BOTTOM,
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PT_FAR_RIGHT_TOP,
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PT_FAR_RIGHT_BOTTOM,
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PT_NEAR_LEFT_TOP,
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PT_NEAR_LEFT_BOTTOM,
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PT_NEAR_RIGHT_TOP,
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PT_NEAR_RIGHT_BOTTOM,
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};
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// 6 bits, 6 planes.
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enum {
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NUM_CAM_PLANES = 6,
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NUM_CAM_POINTS = 8,
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MAX_CULL_PLANES = 17,
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LUT_SIZE = 64,
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};
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public:
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// Before each pass with a different camera, you must call this so the culler can pre-create
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// the camera frustum planes and corner points in world space which are used for the culling.
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bool prepare_camera(const Transform3D &p_cam_transform, const Projection &p_cam_matrix);
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// REGULAR LIGHTS (SPOT, OMNI).
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// These are prepared then used for culling one by one, single threaded.
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// prepare_regular_light() returns false if the entire light is culled (i.e. there is no intersection between the light and the view frustum).
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bool prepare_regular_light(const RendererSceneCull::Instance &p_instance) { return _prepare_light(p_instance, -1); }
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// Cull according to the regular light planes that were setup in the previous call to prepare_regular_light.
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void cull_regular_light(PagedArray<RendererSceneCull::Instance *> &r_instance_shadow_cull_result);
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// Directional lights are prepared in advance, and can be culled multithreaded chopping and changing between
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// different directional_light_id.
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void prepare_directional_light(const RendererSceneCull::Instance *p_instance, int32_t p_directional_light_id);
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// Return false if the instance is to be culled.
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bool cull_directional_light(const RendererSceneCull::InstanceBounds &p_bound, int32_t p_directional_light_id);
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// Can turn on and off from the engine if desired.
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void set_caster_culling_active(bool p_active) { data.caster_culling_active = p_active; }
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void set_light_culling_active(bool p_active) { data.light_culling_active = p_active; }
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private:
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struct LightCullPlanes {
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void add_cull_plane(const Plane &p);
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Plane cull_planes[MAX_CULL_PLANES];
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int num_cull_planes = 0;
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#ifdef LIGHT_CULLER_DEBUG_DIRECTIONAL_LIGHT
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uint32_t rejected_count = 0;
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#endif
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};
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bool _prepare_light(const RendererSceneCull::Instance &p_instance, int32_t p_directional_light_id = -1);
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// Avoid adding extra culling planes derived from near colinear triangles.
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// The normals derived from these will be inaccurate, and can lead to false
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// culling of objects that should be within the light volume.
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bool _is_colinear_tri(const Vector3 &p_a, const Vector3 &p_b, const Vector3 &p_c) const {
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// Lengths of sides a, b and c.
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float la = (p_b - p_a).length();
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float lb = (p_c - p_b).length();
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float lc = (p_c - p_a).length();
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// Get longest side into lc.
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if (lb < la) {
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SWAP(la, lb);
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}
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if (lc < lb) {
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SWAP(lb, lc);
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}
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// Prevent divide by zero.
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if (lc > 0.00001f) {
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// If the summed length of the smaller two
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// sides is close to the length of the longest side,
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// the points are colinear, and the triangle is near degenerate.
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float ld = ((la + lb) - lc) / lc;
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// ld will be close to zero for colinear tris.
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return ld < 0.00001f;
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}
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// Don't create planes from tiny triangles,
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// they won't be accurate.
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return true;
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}
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// Internal version uses LightSource.
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bool _add_light_camera_planes(LightCullPlanes &r_cull_planes, const LightSource &p_light_source);
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// Directional light gives parallel culling planes (as opposed to point lights).
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bool add_light_camera_planes_directional(LightCullPlanes &r_cull_planes, const LightSource &p_light_source);
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// Is the light culler active? maybe not in the editor...
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bool is_caster_culling_active() const { return data.caster_culling_active; }
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bool is_light_culling_active() const { return data.light_culling_active; }
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// Do we want to log some debug output?
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bool is_logging() const { return data.debug_count == 0; }
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struct Data {
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// Camera frustum planes (world space) - order ePlane.
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Vector<Plane> frustum_planes;
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// Camera frustum corners (world space) - order ePoint.
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Vector3 frustum_points[NUM_CAM_POINTS];
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// Master can have multiple directional lights.
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// These need to store their own cull planes individually, as master
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// chops and changes between culling different lights
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// instead of doing one by one, and we don't want to prepare
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// lights multiple times per frame.
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LocalVector<LightCullPlanes> directional_cull_planes;
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// Single threaded cull planes for regular lights
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// (OMNI, SPOT). These lights reuse the same set of cull plane data.
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LightCullPlanes regular_cull_planes;
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#ifdef LIGHT_CULLER_DEBUG_REGULAR_LIGHT
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uint32_t regular_rejected_count = 0;
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#endif
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// The whole regular light can be out of range of the view frustum, in which case all casters should be culled.
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bool out_of_range = false;
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#ifdef RENDERING_LIGHT_CULLER_DEBUG_STRINGS
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static String plane_bitfield_to_string(unsigned int BF);
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// Names of the plane and point enums, useful for debugging.
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static const char *string_planes[];
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static const char *string_points[];
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#endif
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// Precalculated look up table.
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static uint8_t LUT_entry_sizes[LUT_SIZE];
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static uint8_t LUT_entries[LUT_SIZE][8];
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bool caster_culling_active = true;
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bool light_culling_active = true;
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// Light culling is a basic on / off switch.
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// Caster culling only works if light culling is also on.
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bool is_active() const { return light_culling_active; }
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// Ideally a frame counter, but for ease of implementation
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// this is just incremented on each prepare_camera.
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// used to turn on and off debugging features.
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int debug_count = -1;
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} data;
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// This functionality is not required in general use (and is compiled out),
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// as the lookup table can normally be hard coded
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// (provided order of planes etc does not change).
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// It is provided for debugging / future maintenance.
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#ifdef RENDERING_LIGHT_CULLER_CALCULATE_LUT
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void get_neighbouring_planes(PlaneOrder p_plane, PlaneOrder r_neigh_planes[4]) const;
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void get_corners_of_planes(PlaneOrder p_plane_a, PlaneOrder p_plane_b, PointOrder r_points[2]) const;
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void create_LUT();
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void compact_LUT_entry(uint32_t p_entry_id);
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void debug_print_LUT();
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void debug_print_LUT_as_table();
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void add_LUT(int p_plane_0, int p_plane_1, PointOrder p_pts[2]);
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void add_LUT_entry(uint32_t p_entry_id, PointOrder p_pts[2]);
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String debug_string_LUT_entry(const LocalVector<uint8_t> &p_entry, bool p_pair = false);
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String string_LUT_entry(const LocalVector<uint8_t> &p_entry);
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// Contains a list of points for each combination of plane facing directions.
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LocalVector<uint8_t> _calculated_LUT[LUT_SIZE];
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#endif
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};
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#endif // RENDERING_LIGHT_CULLER_H
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