// DO NOT ADD INCLUDE GUARDS OR PRAGMA ONCE. // This file will be included more than once. /*************************************************************************/ /* octree_definition.inc */ /*************************************************************************/ /* This file is part of: */ /* GODOT ENGINE */ /* https://godotengine.org */ /*************************************************************************/ /* Copyright (c) 2007-2020 Juan Linietsky, Ariel Manzur. */ /* Copyright (c) 2014-2020 Godot Engine contributors (cf. AUTHORS.md). */ /* */ /* Permission is hereby granted, free of charge, to any person obtaining */ /* a copy of this software and associated documentation files (the */ /* "Software"), to deal in the Software without restriction, including */ /* without limitation the rights to use, copy, modify, merge, publish, */ /* distribute, sublicense, and/or sell copies of the Software, and to */ /* permit persons to whom the Software is furnished to do so, subject to */ /* the following conditions: */ /* */ /* The above copyright notice and this permission notice shall be */ /* included in all copies or substantial portions of the Software. */ /* */ /* THE SOFTWARE IS PROVIDED "AS IS", WITHOUT WARRANTY OF ANY KIND, */ /* EXPRESS OR IMPLIED, INCLUDING BUT NOT LIMITED TO THE WARRANTIES OF */ /* MERCHANTABILITY, FITNESS FOR A PARTICULAR PURPOSE AND NONINFRINGEMENT.*/ /* IN NO EVENT SHALL THE AUTHORS OR COPYRIGHT HOLDERS BE LIABLE FOR ANY */ /* CLAIM, DAMAGES OR OTHER LIABILITY, WHETHER IN AN ACTION OF CONTRACT, */ /* TORT OR OTHERWISE, ARISING FROM, OUT OF OR IN CONNECTION WITH THE */ /* SOFTWARE OR THE USE OR OTHER DEALINGS IN THE SOFTWARE. */ /*************************************************************************/ #include "core/list.h" #include "core/local_vector.h" #include "core/map.h" #include "core/math/aabb.h" #include "core/math/geometry.h" #include "core/math/vector3.h" #include "core/print_string.h" #include "core/variant.h" typedef uint32_t OctreeElementID; // macro to reduce boiler plate code when providing function implementations #define OCTREE_FUNC(RET_VALUE) template \ RET_VALUE OCTREE_CLASS_NAME #define OCTREE_FUNC_CONSTRUCTOR template \ OCTREE_CLASS_NAME template class OCTREE_CLASS_NAME { public: typedef void *(*PairCallback)(void *, OctreeElementID, T *, int, OctreeElementID, T *, int); typedef void (*UnpairCallback)(void *, OctreeElementID, T *, int, OctreeElementID, T *, int, void *); private: enum { NEG = 0, POS = 1, }; enum { OCTANT_NX_NY_NZ, OCTANT_PX_NY_NZ, OCTANT_NX_PY_NZ, OCTANT_PX_PY_NZ, OCTANT_NX_NY_PZ, OCTANT_PX_NY_PZ, OCTANT_NX_PY_PZ, OCTANT_PX_PY_PZ }; struct PairKey { union { struct { OctreeElementID A; OctreeElementID B; }; uint64_t key; }; _FORCE_INLINE_ bool operator<(const PairKey &p_pair) const { return key < p_pair.key; } _FORCE_INLINE_ PairKey(OctreeElementID p_A, OctreeElementID p_B) { if (p_A < p_B) { A = p_A; B = p_B; } else { B = p_A; A = p_B; } } _FORCE_INLINE_ PairKey() {} }; struct Element; #ifdef OCTREE_USE_CACHED_LISTS // instead of iterating the linked list every time within octants, // we can cache a linear list of prepared elements containing essential data // for fast traversal, and rebuild it only when an octant changes. struct CachedList { LocalVector aabbs; LocalVector elements; void update(List &eles) { // make sure local vector doesn't delete the memory // no need to be thrashing allocations aabbs.clear(); elements.clear(); typename List::Element *E = eles.front(); while (E) { Element *e = E->get(); aabbs.push_back(e->aabb); elements.push_back(e); E = E->next(); } } }; #endif struct Octant { // cached for FAST plane check AABB aabb; uint64_t last_pass; Octant *parent; Octant *children[8]; int children_count; // cache for amount of childrens (fast check for removal) int parent_index; // cache for parent index (fast check for removal) List pairable_elements; List elements; #ifdef OCTREE_USE_CACHED_LISTS // cached lists are linear in memory so are faster than using linked list CachedList clist_pairable; CachedList clist; // use dirty flag to indicate when cached lists need updating // this avoids having to update the cached list on lots of octants // if nothing is moving in them. bool dirty; void update_cached_lists() { if (!dirty) { #ifdef TOOLS_ENABLED //#define OCTREE_CACHED_LIST_ERROR_CHECKS #endif #ifdef OCTREE_CACHED_LIST_ERROR_CHECKS // debug - this will slow down performance a lot, // only enable these error checks for testing that the cached // lists are up to date. int hash_before_P = clist_pairable.aabbs.size(); int hash_before_N = clist.aabbs.size(); clist_pairable.update(pairable_elements); clist.update(elements); int hash_after_P = clist_pairable.aabbs.size(); int hash_after_N = clist.aabbs.size(); ERR_FAIL_COND(hash_before_P != hash_after_P); ERR_FAIL_COND(hash_before_N != hash_after_N); #endif return; } clist_pairable.update(pairable_elements); clist.update(elements); dirty = false; } #endif Octant() { children_count = 0; parent_index = -1; last_pass = 0; parent = NULL; #ifdef OCTREE_USE_CACHED_LISTS dirty = true; #endif for (int i = 0; i < 8; i++) children[i] = NULL; } ~Octant() { /* for (int i=0;i<8;i++) memdelete_notnull(children[i]); */ } }; struct PairData; struct Element { OCTREE_CLASS_NAME *octree; T *userdata; int subindex; bool pairable; uint32_t pairable_mask; uint32_t pairable_type; uint64_t last_pass; OctreeElementID _id; Octant *common_parent; AABB aabb; AABB container_aabb; List pair_list; struct OctantOwner { Octant *octant; typename List::Element *E; }; // an element can be in max 8 octants List octant_owners; #ifdef OCTREE_USE_CACHED_LISTS // when moving we need make all owner octants dirty, because the AABB can change. void moving() { for (typename List::Element *F = octant_owners.front(); F;) { Octant *o = F->get().octant; o->dirty = true; F = F->next(); } } #endif Element() { last_pass = 0; _id = 0; pairable = false; subindex = 0; userdata = 0; octree = 0; pairable_mask = 0; pairable_type = 0; common_parent = NULL; } }; struct PairData { int refcount; bool intersect; Element *A, *B; void *ud; typename List::Element *eA, *eB; }; typedef Map, AL> ElementMap; typedef Map, AL> PairMap; ElementMap element_map; PairMap pair_map; PairCallback pair_callback; UnpairCallback unpair_callback; void *pair_callback_userdata; void *unpair_callback_userdata; OctreeElementID last_element_id; uint64_t pass; real_t unit_size; Octant *root; int octant_count; int pair_count; int octant_elements_limit; _FORCE_INLINE_ void _pair_check(PairData *p_pair) { bool intersect = p_pair->A->aabb.intersects_inclusive(p_pair->B->aabb); if (intersect != p_pair->intersect) { if (intersect) { if (pair_callback) { p_pair->ud = pair_callback(pair_callback_userdata, p_pair->A->_id, p_pair->A->userdata, p_pair->A->subindex, p_pair->B->_id, p_pair->B->userdata, p_pair->B->subindex); } pair_count++; } else { if (unpair_callback) { unpair_callback(pair_callback_userdata, p_pair->A->_id, p_pair->A->userdata, p_pair->A->subindex, p_pair->B->_id, p_pair->B->userdata, p_pair->B->subindex, p_pair->ud); } pair_count--; } p_pair->intersect = intersect; } } _FORCE_INLINE_ void _pair_reference(Element *p_A, Element *p_B) { if (p_A == p_B || (p_A->userdata == p_B->userdata && p_A->userdata)) return; if (!(p_A->pairable_type & p_B->pairable_mask) && !(p_B->pairable_type & p_A->pairable_mask)) return; // none can pair with none PairKey key(p_A->_id, p_B->_id); typename PairMap::Element *E = pair_map.find(key); if (!E) { PairData pdata; pdata.refcount = 1; pdata.A = p_A; pdata.B = p_B; pdata.intersect = false; E = pair_map.insert(key, pdata); E->get().eA = p_A->pair_list.push_back(&E->get()); E->get().eB = p_B->pair_list.push_back(&E->get()); /* if (pair_callback) pair_callback(pair_callback_userdata,p_A->userdata,p_B->userdata); */ } else { E->get().refcount++; } } _FORCE_INLINE_ void _pair_unreference(Element *p_A, Element *p_B) { if (p_A == p_B) return; PairKey key(p_A->_id, p_B->_id); typename PairMap::Element *E = pair_map.find(key); if (!E) { return; // no pair } E->get().refcount--; if (E->get().refcount == 0) { // bye pair if (E->get().intersect) { if (unpair_callback) { unpair_callback(pair_callback_userdata, p_A->_id, p_A->userdata, p_A->subindex, p_B->_id, p_B->userdata, p_B->subindex, E->get().ud); } pair_count--; } if (p_A == E->get().B) { //may be reaching inverted SWAP(p_A, p_B); } p_A->pair_list.erase(E->get().eA); p_B->pair_list.erase(E->get().eB); pair_map.erase(E); } } _FORCE_INLINE_ void _element_check_pairs(Element *p_element) { typename List::Element *E = p_element->pair_list.front(); while (E) { _pair_check(E->get()); E = E->next(); } } _FORCE_INLINE_ void _optimize() { while (root && root->children_count < 2 && !root->elements.size() && !(use_pairs && root->pairable_elements.size())) { Octant *new_root = NULL; if (root->children_count == 1) { for (int i = 0; i < 8; i++) { if (root->children[i]) { new_root = root->children[i]; root->children[i] = NULL; break; } } ERR_FAIL_COND(!new_root); new_root->parent = NULL; new_root->parent_index = -1; } memdelete_allocator(root); octant_count--; root = new_root; } } void _insert_element(Element *p_element, Octant *p_octant); void _ensure_valid_root(const AABB &p_aabb); bool _remove_element_pair_and_remove_empty_octants(Element *p_element, Octant *p_octant, Octant *p_limit = NULL); void _remove_element(Element *p_element); void _pair_element(Element *p_element, Octant *p_octant); void _unpair_element(Element *p_element, Octant *p_octant); struct _CullConvexData { const Plane *planes; int plane_count; const Vector3 *points; int point_count; T **result_array; int *result_idx; int result_max; uint32_t mask; }; void _cull_convex(Octant *p_octant, _CullConvexData *p_cull); void _cull_aabb(Octant *p_octant, const AABB &p_aabb, T **p_result_array, int *p_result_idx, int p_result_max, int *p_subindex_array, uint32_t p_mask); void _cull_segment(Octant *p_octant, const Vector3 &p_from, const Vector3 &p_to, T **p_result_array, int *p_result_idx, int p_result_max, int *p_subindex_array, uint32_t p_mask); void _cull_point(Octant *p_octant, const Vector3 &p_point, T **p_result_array, int *p_result_idx, int p_result_max, int *p_subindex_array, uint32_t p_mask); void _remove_tree(Octant *p_octant) { if (!p_octant) return; for (int i = 0; i < 8; i++) { if (p_octant->children[i]) _remove_tree(p_octant->children[i]); } memdelete_allocator(p_octant); } #ifdef TOOLS_ENABLED String debug_aabb_to_string(const AABB &aabb) const; void debug_octant(const Octant &oct, int depth = 0); #endif public: OctreeElementID create(T *p_userdata, const AABB &p_aabb = AABB(), int p_subindex = 0, bool p_pairable = false, uint32_t p_pairable_type = 0, uint32_t pairable_mask = 1); void move(OctreeElementID p_id, const AABB &p_aabb); void set_pairable(OctreeElementID p_id, bool p_pairable = false, uint32_t p_pairable_type = 0, uint32_t pairable_mask = 1); void erase(OctreeElementID p_id); bool is_pairable(OctreeElementID p_id) const; T *get(OctreeElementID p_id) const; int get_subindex(OctreeElementID p_id) const; int cull_convex(const Vector &p_convex, T **p_result_array, int p_result_max, uint32_t p_mask = 0xFFFFFFFF); int cull_aabb(const AABB &p_aabb, T **p_result_array, int p_result_max, int *p_subindex_array = NULL, uint32_t p_mask = 0xFFFFFFFF); int cull_segment(const Vector3 &p_from, const Vector3 &p_to, T **p_result_array, int p_result_max, int *p_subindex_array = NULL, uint32_t p_mask = 0xFFFFFFFF); int cull_point(const Vector3 &p_point, T **p_result_array, int p_result_max, int *p_subindex_array = NULL, uint32_t p_mask = 0xFFFFFFFF); void set_pair_callback(PairCallback p_callback, void *p_userdata); void set_unpair_callback(UnpairCallback p_callback, void *p_userdata); int get_octant_count() const { return octant_count; } int get_pair_count() const { return pair_count; } void set_octant_elements_limit(int p_limit) { octant_elements_limit = p_limit; } // just convenience for project settings, as users don't need to know exact numbers void set_balance(float p_bal) // 0.0 is optimized for multiple tests, 1.0 is for multiple edits (moves etc) { float v = CLAMP(p_bal, 0.0f, 1.0f); v *= v; v *= v; v *= 8096.0f; // these values have been found empirically int l = 0 + v; set_octant_elements_limit(l); } #ifdef TOOLS_ENABLED void debug_octants(); #endif OCTREE_CLASS_NAME(real_t p_unit_size = 1.0); ~OCTREE_CLASS_NAME() { _remove_tree(root); } }; /* PRIVATE FUNCTIONS */ OCTREE_FUNC(T *)::get(OctreeElementID p_id) const { const typename ElementMap::Element *E = element_map.find(p_id); ERR_FAIL_COND_V(!E, NULL); return E->get().userdata; } OCTREE_FUNC(bool)::is_pairable(OctreeElementID p_id) const { const typename ElementMap::Element *E = element_map.find(p_id); ERR_FAIL_COND_V(!E, false); return E->get().pairable; } OCTREE_FUNC(int)::get_subindex(OctreeElementID p_id) const { const typename ElementMap::Element *E = element_map.find(p_id); ERR_FAIL_COND_V(!E, -1); return E->get().subindex; } #define OCTREE_DIVISOR 4 OCTREE_FUNC(void)::_insert_element(Element *p_element, Octant *p_octant) { real_t element_size = p_element->aabb.get_longest_axis_size() * 1.01; // avoid precision issues // don't create new child octants unless there is more than a certain number in // this octant. This prevents runaway creation of too many octants, and is more efficient // because brute force is faster up to a certain point. bool can_split = true; if (p_element->pairable) { if (p_octant->pairable_elements.size() < octant_elements_limit) can_split = false; } else { if (p_octant->elements.size() < octant_elements_limit) can_split = false; } if (!can_split || (element_size > (p_octant->aabb.size.x / OCTREE_DIVISOR))) { /* at smallest possible size for the element */ typename Element::OctantOwner owner; owner.octant = p_octant; if (use_pairs && p_element->pairable) { p_octant->pairable_elements.push_back(p_element); owner.E = p_octant->pairable_elements.back(); } else { p_octant->elements.push_back(p_element); owner.E = p_octant->elements.back(); } #ifdef OCTREE_USE_CACHED_LISTS p_octant->dirty = true; #endif p_element->octant_owners.push_back(owner); if (p_element->common_parent == NULL) { p_element->common_parent = p_octant; p_element->container_aabb = p_octant->aabb; } else { p_element->container_aabb.merge_with(p_octant->aabb); } if (use_pairs && p_octant->children_count > 0) { pass++; //elements below this only get ONE reference added for (int i = 0; i < 8; i++) { if (p_octant->children[i]) { _pair_element(p_element, p_octant->children[i]); } } } } else { /* not big enough, send it to subitems */ int splits = 0; bool candidate = p_element->common_parent == NULL; for (int i = 0; i < 8; i++) { if (p_octant->children[i]) { /* element exists, go straight to it */ if (p_octant->children[i]->aabb.intersects_inclusive(p_element->aabb)) { _insert_element(p_element, p_octant->children[i]); splits++; } } else { /* check against AABB where child should be */ AABB aabb = p_octant->aabb; aabb.size *= 0.5; if (i & 1) aabb.position.x += aabb.size.x; if (i & 2) aabb.position.y += aabb.size.y; if (i & 4) aabb.position.z += aabb.size.z; if (aabb.intersects_inclusive(p_element->aabb)) { /* if actually intersects, create the child */ Octant *child = memnew_allocator(Octant, AL); p_octant->children[i] = child; child->parent = p_octant; child->parent_index = i; child->aabb = aabb; p_octant->children_count++; _insert_element(p_element, child); octant_count++; splits++; } } } if (candidate && splits > 1) { p_element->common_parent = p_octant; } } if (use_pairs) { typename List::Element *E = p_octant->pairable_elements.front(); while (E) { _pair_reference(p_element, E->get()); E = E->next(); } if (p_element->pairable) { // and always test non-pairable if element is pairable E = p_octant->elements.front(); while (E) { _pair_reference(p_element, E->get()); E = E->next(); } } } } OCTREE_FUNC(void)::_ensure_valid_root(const AABB &p_aabb) { if (!root) { // octre is empty AABB base(Vector3(), Vector3(1.0, 1.0, 1.0) * unit_size); while (!base.encloses(p_aabb)) { if (ABS(base.position.x + base.size.x) <= ABS(base.position.x)) { /* grow towards positive */ base.size *= 2.0; } else { base.position -= base.size; base.size *= 2.0; } } root = memnew_allocator(Octant, AL); root->parent = NULL; root->parent_index = -1; root->aabb = base; octant_count++; } else { AABB base = root->aabb; while (!base.encloses(p_aabb)) { ERR_FAIL_COND_MSG(base.size.x > OCTREE_SIZE_LIMIT, "Octree upper size limit reached, does the AABB supplied contain NAN?"); Octant *gp = memnew_allocator(Octant, AL); octant_count++; root->parent = gp; if (ABS(base.position.x + base.size.x) <= ABS(base.position.x)) { /* grow towards positive */ base.size *= 2.0; gp->aabb = base; gp->children[0] = root; root->parent_index = 0; } else { base.position -= base.size; base.size *= 2.0; gp->aabb = base; gp->children[(1 << 0) | (1 << 1) | (1 << 2)] = root; // add at all-positive root->parent_index = (1 << 0) | (1 << 1) | (1 << 2); } gp->children_count = 1; root = gp; } } } OCTREE_FUNC(bool)::_remove_element_pair_and_remove_empty_octants(Element *p_element, Octant *p_octant, Octant *p_limit) { bool octant_removed = false; while (true) { // check all exit conditions if (p_octant == p_limit) // reached limit, nothing to erase, exit return octant_removed; bool unpaired = false; if (use_pairs && p_octant->last_pass != pass) { // check whether we should unpair stuff // always test pairable typename List::Element *E = p_octant->pairable_elements.front(); while (E) { _pair_unreference(p_element, E->get()); E = E->next(); } if (p_element->pairable) { // and always test non-pairable if element is pairable E = p_octant->elements.front(); while (E) { _pair_unreference(p_element, E->get()); E = E->next(); } } p_octant->last_pass = pass; unpaired = true; } bool removed = false; Octant *parent = p_octant->parent; if (p_octant->children_count == 0 && p_octant->elements.empty() && p_octant->pairable_elements.empty()) { // erase octant if (p_octant == root) { // won't have a parent, just erase root = NULL; } else { ERR_FAIL_INDEX_V(p_octant->parent_index, 8, octant_removed); parent->children[p_octant->parent_index] = NULL; parent->children_count--; } memdelete_allocator(p_octant); octant_count--; removed = true; octant_removed = true; } if (!removed && !unpaired) return octant_removed; // no reason to keep going up anymore! was already visited and was not removed p_octant = parent; } return octant_removed; } OCTREE_FUNC(void)::_unpair_element(Element *p_element, Octant *p_octant) { // always test pairable typename List::Element *E = p_octant->pairable_elements.front(); while (E) { if (E->get()->last_pass != pass) { // only remove ONE reference _pair_unreference(p_element, E->get()); E->get()->last_pass = pass; } E = E->next(); } if (p_element->pairable) { // and always test non-pairable if element is pairable E = p_octant->elements.front(); while (E) { if (E->get()->last_pass != pass) { // only remove ONE reference _pair_unreference(p_element, E->get()); E->get()->last_pass = pass; } E = E->next(); } } p_octant->last_pass = pass; if (p_octant->children_count == 0) return; // small optimization for leafs for (int i = 0; i < 8; i++) { if (p_octant->children[i]) _unpair_element(p_element, p_octant->children[i]); } } OCTREE_FUNC(void)::_pair_element(Element *p_element, Octant *p_octant) { // always test pairable typename List::Element *E = p_octant->pairable_elements.front(); while (E) { if (E->get()->last_pass != pass) { // only get ONE reference _pair_reference(p_element, E->get()); E->get()->last_pass = pass; } E = E->next(); } if (p_element->pairable) { // and always test non-pairable if element is pairable E = p_octant->elements.front(); while (E) { if (E->get()->last_pass != pass) { // only get ONE reference _pair_reference(p_element, E->get()); E->get()->last_pass = pass; } E = E->next(); } } p_octant->last_pass = pass; if (p_octant->children_count == 0) return; // small optimization for leafs for (int i = 0; i < 8; i++) { if (p_octant->children[i]) _pair_element(p_element, p_octant->children[i]); } } OCTREE_FUNC(void)::_remove_element(Element *p_element) { pass++; // will do a new pass for this typename List::Element *I = p_element->octant_owners.front(); for (; I; I = I->next()) { Octant *o = I->get().octant; if (!use_pairs) { o->elements.erase(I->get().E); } else { // erase children pairs, they are erased ONCE even if repeated pass++; for (int i = 0; i < 8; i++) { if (o->children[i]) { _unpair_element(p_element, o->children[i]); } } if (p_element->pairable) { o->pairable_elements.erase(I->get().E); } else { o->elements.erase(I->get().E); } } #ifdef OCTREE_USE_CACHED_LISTS o->dirty = true; #endif _remove_element_pair_and_remove_empty_octants(p_element, o); } p_element->octant_owners.clear(); if (use_pairs) { int remaining = p_element->pair_list.size(); //p_element->pair_list.clear(); ERR_FAIL_COND(remaining); } } OCTREE_FUNC(OctreeElementID)::create(T *p_userdata, const AABB &p_aabb, int p_subindex, bool p_pairable, uint32_t p_pairable_type, uint32_t p_pairable_mask) { // check for AABB validity #ifdef DEBUG_ENABLED ERR_FAIL_COND_V(p_aabb.position.x > 1e15 || p_aabb.position.x < -1e15, 0); ERR_FAIL_COND_V(p_aabb.position.y > 1e15 || p_aabb.position.y < -1e15, 0); ERR_FAIL_COND_V(p_aabb.position.z > 1e15 || p_aabb.position.z < -1e15, 0); ERR_FAIL_COND_V(p_aabb.size.x > 1e15 || p_aabb.size.x < 0.0, 0); ERR_FAIL_COND_V(p_aabb.size.y > 1e15 || p_aabb.size.y < 0.0, 0); ERR_FAIL_COND_V(p_aabb.size.z > 1e15 || p_aabb.size.z < 0.0, 0); ERR_FAIL_COND_V(Math::is_nan(p_aabb.size.x), 0); ERR_FAIL_COND_V(Math::is_nan(p_aabb.size.y), 0); ERR_FAIL_COND_V(Math::is_nan(p_aabb.size.z), 0); #endif typename ElementMap::Element *E = element_map.insert(last_element_id++, Element()); Element &e = E->get(); e.aabb = p_aabb; e.userdata = p_userdata; e.subindex = p_subindex; e.last_pass = 0; e.octree = this; e.pairable = p_pairable; e.pairable_type = p_pairable_type; e.pairable_mask = p_pairable_mask; e._id = last_element_id - 1; if (!e.aabb.has_no_surface()) { _ensure_valid_root(p_aabb); _insert_element(&e, root); if (use_pairs) _element_check_pairs(&e); } return last_element_id - 1; } OCTREE_FUNC(void)::move(OctreeElementID p_id, const AABB &p_aabb) { #ifdef DEBUG_ENABLED // check for AABB validity ERR_FAIL_COND(p_aabb.position.x > 1e15 || p_aabb.position.x < -1e15); ERR_FAIL_COND(p_aabb.position.y > 1e15 || p_aabb.position.y < -1e15); ERR_FAIL_COND(p_aabb.position.z > 1e15 || p_aabb.position.z < -1e15); ERR_FAIL_COND(p_aabb.size.x > 1e15 || p_aabb.size.x < 0.0); ERR_FAIL_COND(p_aabb.size.y > 1e15 || p_aabb.size.y < 0.0); ERR_FAIL_COND(p_aabb.size.z > 1e15 || p_aabb.size.z < 0.0); ERR_FAIL_COND(Math::is_nan(p_aabb.size.x)); ERR_FAIL_COND(Math::is_nan(p_aabb.size.y)); ERR_FAIL_COND(Math::is_nan(p_aabb.size.z)); #endif typename ElementMap::Element *E = element_map.find(p_id); ERR_FAIL_COND(!E); Element &e = E->get(); bool old_has_surf = !e.aabb.has_no_surface(); bool new_has_surf = !p_aabb.has_no_surface(); if (old_has_surf != new_has_surf) { if (old_has_surf) { _remove_element(&e); // removing e.common_parent = NULL; e.aabb = AABB(); _optimize(); } else { _ensure_valid_root(p_aabb); // inserting e.common_parent = NULL; e.aabb = p_aabb; _insert_element(&e, root); if (use_pairs) _element_check_pairs(&e); } return; } if (!old_has_surf) // doing nothing return; // it still is enclosed in the same AABB it was assigned to if (e.container_aabb.encloses(p_aabb)) { e.aabb = p_aabb; if (use_pairs) _element_check_pairs(&e); // must check pairs anyway #ifdef OCTREE_USE_CACHED_LISTS e.moving(); #endif return; } AABB combined = e.aabb; combined.merge_with(p_aabb); _ensure_valid_root(combined); ERR_FAIL_COND(e.octant_owners.front() == NULL); /* FIND COMMON PARENT */ List owners = e.octant_owners; // save the octant owners Octant *common_parent = e.common_parent; ERR_FAIL_COND(!common_parent); //src is now the place towards where insertion is going to happen pass++; while (common_parent && !common_parent->aabb.encloses(p_aabb)) common_parent = common_parent->parent; ERR_FAIL_COND(!common_parent); //prepare for reinsert e.octant_owners.clear(); e.common_parent = NULL; e.aabb = p_aabb; _insert_element(&e, common_parent); // reinsert from this point pass++; for (typename List::Element *F = owners.front(); F;) { Octant *o = F->get().octant; typename List::Element *N = F->next(); /* if (!use_pairs) o->elements.erase( F->get().E ); */ if (use_pairs && e.pairable) o->pairable_elements.erase(F->get().E); else o->elements.erase(F->get().E); #ifdef OCTREE_USE_CACHED_LISTS o->dirty = true; #endif if (_remove_element_pair_and_remove_empty_octants(&e, o, common_parent->parent)) { owners.erase(F); } F = N; } if (use_pairs) { //unpair child elements in anything that survived for (typename List::Element *F = owners.front(); F; F = F->next()) { Octant *o = F->get().octant; // erase children pairs, unref ONCE pass++; for (int i = 0; i < 8; i++) { if (o->children[i]) _unpair_element(&e, o->children[i]); } } _element_check_pairs(&e); } _optimize(); } OCTREE_FUNC(void)::set_pairable(OctreeElementID p_id, bool p_pairable, uint32_t p_pairable_type, uint32_t p_pairable_mask) { typename ElementMap::Element *E = element_map.find(p_id); ERR_FAIL_COND(!E); Element &e = E->get(); if (p_pairable == e.pairable && e.pairable_type == p_pairable_type && e.pairable_mask == p_pairable_mask) return; // no changes, return if (!e.aabb.has_no_surface()) { _remove_element(&e); } e.pairable = p_pairable; e.pairable_type = p_pairable_type; e.pairable_mask = p_pairable_mask; e.common_parent = NULL; if (!e.aabb.has_no_surface()) { _ensure_valid_root(e.aabb); _insert_element(&e, root); if (use_pairs) _element_check_pairs(&e); } } OCTREE_FUNC(void)::erase(OctreeElementID p_id) { typename ElementMap::Element *E = element_map.find(p_id); ERR_FAIL_COND(!E); Element &e = E->get(); if (!e.aabb.has_no_surface()) { _remove_element(&e); } element_map.erase(p_id); _optimize(); } OCTREE_FUNC(void)::_cull_convex(Octant *p_octant, _CullConvexData *p_cull) { if (*p_cull->result_idx == p_cull->result_max) return; //pointless if (!p_octant->elements.empty()) { #ifdef OCTREE_USE_CACHED_LISTS // make sure cached list of element pointers and aabbs is up to date if this octant is dirty p_octant->update_cached_lists(); int num_elements = p_octant->clist.elements.size(); for (int n = 0; n < num_elements; n++) { const AABB &aabb = p_octant->clist.aabbs[n]; Element *e = p_octant->clist.elements[n]; // in most cases with the cached linear list tests we will do the AABB checks BEFORE last pass and cull mask. // The reason is that the later checks are more expensive because they are not in cache, and many of the AABB // tests will fail so we can avoid these cache misses. if (aabb.intersects_convex_shape(p_cull->planes, p_cull->plane_count, p_cull->points, p_cull->point_count)) { if (e->last_pass == pass || (use_pairs && !(e->pairable_type & p_cull->mask))) continue; e->last_pass = pass; if (*p_cull->result_idx < p_cull->result_max) { p_cull->result_array[*p_cull->result_idx] = e->userdata; (*p_cull->result_idx)++; } else { return; // pointless to continue } } } // for n #else typename List::Element *I; I = p_octant->elements.front(); for (; I; I = I->next()) { Element *e = I->get(); const AABB &aabb = e->aabb; if (e->last_pass == pass || (use_pairs && !(e->pairable_type & p_cull->mask))) continue; e->last_pass = pass; if (aabb.intersects_convex_shape(p_cull->planes, p_cull->plane_count, p_cull->points, p_cull->point_count)) { if (*p_cull->result_idx < p_cull->result_max) { p_cull->result_array[*p_cull->result_idx] = e->userdata; (*p_cull->result_idx)++; } else { return; // pointless to continue } } } #endif } // if elements not empty if (use_pairs && !p_octant->pairable_elements.empty()) { #ifdef OCTREE_USE_CACHED_LISTS // make sure cached list of element pointers and aabbs is up to date if this octant is dirty p_octant->update_cached_lists(); int num_elements = p_octant->clist_pairable.elements.size(); for (int n = 0; n < num_elements; n++) { const AABB &aabb = p_octant->clist_pairable.aabbs[n]; Element *e = p_octant->clist_pairable.elements[n]; if (aabb.intersects_convex_shape(p_cull->planes, p_cull->plane_count, p_cull->points, p_cull->point_count)) { if (e->last_pass == pass || (use_pairs && !(e->pairable_type & p_cull->mask))) continue; e->last_pass = pass; if (*p_cull->result_idx < p_cull->result_max) { p_cull->result_array[*p_cull->result_idx] = e->userdata; (*p_cull->result_idx)++; } else { return; // pointless to continue } } } #else typename List::Element *I; I = p_octant->pairable_elements.front(); for (; I; I = I->next()) { Element *e = I->get(); const AABB &aabb = e->aabb; if (e->last_pass == pass || (use_pairs && !(e->pairable_type & p_cull->mask))) continue; e->last_pass = pass; if (aabb.intersects_convex_shape(p_cull->planes, p_cull->plane_count, p_cull->points, p_cull->point_count)) { if (*p_cull->result_idx < p_cull->result_max) { p_cull->result_array[*p_cull->result_idx] = e->userdata; (*p_cull->result_idx)++; } else { return; // pointless to continue } } } #endif } for (int i = 0; i < 8; i++) { if (p_octant->children[i] && p_octant->children[i]->aabb.intersects_convex_shape(p_cull->planes, p_cull->plane_count, p_cull->points, p_cull->point_count)) { _cull_convex(p_octant->children[i], p_cull); } } } OCTREE_FUNC(void)::_cull_aabb(Octant *p_octant, const AABB &p_aabb, T **p_result_array, int *p_result_idx, int p_result_max, int *p_subindex_array, uint32_t p_mask) { if (*p_result_idx == p_result_max) return; //pointless if (!p_octant->elements.empty()) { #ifdef OCTREE_USE_CACHED_LISTS // make sure cached list of element pointers and aabbs is up to date if this octant is dirty p_octant->update_cached_lists(); int num_elements = p_octant->clist.elements.size(); for (int n = 0; n < num_elements; n++) { const AABB &aabb = p_octant->clist.aabbs[n]; Element *e = p_octant->clist.elements[n]; if (p_aabb.intersects_inclusive(aabb)) { if (e->last_pass == pass || (use_pairs && !(e->pairable_type & p_mask))) continue; e->last_pass = pass; if (*p_result_idx < p_result_max) { p_result_array[*p_result_idx] = e->userdata; if (p_subindex_array) p_subindex_array[*p_result_idx] = e->subindex; (*p_result_idx)++; } else { return; // pointless to continue } } } #else typename List::Element *I; I = p_octant->elements.front(); for (; I; I = I->next()) { Element *e = I->get(); const AABB &aabb = e->aabb; if (p_aabb.intersects_inclusive(aabb)) { if (e->last_pass == pass || (use_pairs && !(e->pairable_type & p_mask))) continue; e->last_pass = pass; if (*p_result_idx < p_result_max) { p_result_array[*p_result_idx] = e->userdata; if (p_subindex_array) p_subindex_array[*p_result_idx] = e->subindex; (*p_result_idx)++; } else { return; // pointless to continue } } } #endif } if (use_pairs && !p_octant->pairable_elements.empty()) { #ifdef OCTREE_USE_CACHED_LISTS // make sure cached list of element pointers and aabbs is up to date if this octant is dirty p_octant->update_cached_lists(); int num_elements = p_octant->clist_pairable.elements.size(); for (int n = 0; n < num_elements; n++) { const AABB &aabb = p_octant->clist_pairable.aabbs[n]; Element *e = p_octant->clist_pairable.elements[n]; if (p_aabb.intersects_inclusive(aabb)) { if (e->last_pass == pass || (use_pairs && !(e->pairable_type & p_mask))) continue; e->last_pass = pass; if (*p_result_idx < p_result_max) { p_result_array[*p_result_idx] = e->userdata; if (p_subindex_array) p_subindex_array[*p_result_idx] = e->subindex; (*p_result_idx)++; } else { return; // pointless to continue } } } #else typename List::Element *I; I = p_octant->pairable_elements.front(); for (; I; I = I->next()) { Element *e = I->get(); const AABB &aabb = e->aabb; if (e->last_pass == pass || (use_pairs && !(e->pairable_type & p_mask))) continue; e->last_pass = pass; if (p_aabb.intersects_inclusive(aabb)) { if (*p_result_idx < p_result_max) { p_result_array[*p_result_idx] = e->userdata; if (p_subindex_array) p_subindex_array[*p_result_idx] = e->subindex; (*p_result_idx)++; } else { return; // pointless to continue } } } #endif } for (int i = 0; i < 8; i++) { if (p_octant->children[i] && p_octant->children[i]->aabb.intersects_inclusive(p_aabb)) { _cull_aabb(p_octant->children[i], p_aabb, p_result_array, p_result_idx, p_result_max, p_subindex_array, p_mask); } } } OCTREE_FUNC(void)::_cull_segment(Octant *p_octant, const Vector3 &p_from, const Vector3 &p_to, T **p_result_array, int *p_result_idx, int p_result_max, int *p_subindex_array, uint32_t p_mask) { if (*p_result_idx == p_result_max) return; //pointless if (!p_octant->elements.empty()) { #ifdef OCTREE_USE_CACHED_LISTS // make sure cached list of element pointers and aabbs is up to date if this octant is dirty p_octant->update_cached_lists(); int num_elements = p_octant->clist.elements.size(); for (int n = 0; n < num_elements; n++) { const AABB &aabb = p_octant->clist.aabbs[n]; Element *e = p_octant->clist.elements[n]; if (e->last_pass == pass || (use_pairs && !(e->pairable_type & p_mask))) continue; e->last_pass = pass; if (aabb.intersects_segment(p_from, p_to)) { if (*p_result_idx < p_result_max) { p_result_array[*p_result_idx] = e->userdata; if (p_subindex_array) p_subindex_array[*p_result_idx] = e->subindex; (*p_result_idx)++; } else { return; // pointless to continue } } } #else typename List::Element *I; I = p_octant->elements.front(); for (; I; I = I->next()) { Element *e = I->get(); const AABB &aabb = e->aabb; if (e->last_pass == pass || (use_pairs && !(e->pairable_type & p_mask))) continue; e->last_pass = pass; if (aabb.intersects_segment(p_from, p_to)) { if (*p_result_idx < p_result_max) { p_result_array[*p_result_idx] = e->userdata; if (p_subindex_array) p_subindex_array[*p_result_idx] = e->subindex; (*p_result_idx)++; } else { return; // pointless to continue } } } #endif } if (use_pairs && !p_octant->pairable_elements.empty()) { #ifdef OCTREE_USE_CACHED_LISTS // make sure cached list of element pointers and aabbs is up to date if this octant is dirty p_octant->update_cached_lists(); int num_elements = p_octant->clist_pairable.elements.size(); for (int n = 0; n < num_elements; n++) { const AABB &aabb = p_octant->clist_pairable.aabbs[n]; Element *e = p_octant->clist_pairable.elements[n]; if (e->last_pass == pass || (use_pairs && !(e->pairable_type & p_mask))) continue; e->last_pass = pass; if (aabb.intersects_segment(p_from, p_to)) { if (*p_result_idx < p_result_max) { p_result_array[*p_result_idx] = e->userdata; if (p_subindex_array) p_subindex_array[*p_result_idx] = e->subindex; (*p_result_idx)++; } else { return; // pointless to continue } } } #else typename List::Element *I; I = p_octant->pairable_elements.front(); for (; I; I = I->next()) { Element *e = I->get(); const AABB &aabb = e->aabb; if (e->last_pass == pass || (use_pairs && !(e->pairable_type & p_mask))) continue; e->last_pass = pass; if (aabb.intersects_segment(p_from, p_to)) { if (*p_result_idx < p_result_max) { p_result_array[*p_result_idx] = e->userdata; if (p_subindex_array) p_subindex_array[*p_result_idx] = e->subindex; (*p_result_idx)++; } else { return; // pointless to continue } } } #endif } for (int i = 0; i < 8; i++) { if (p_octant->children[i] && p_octant->children[i]->aabb.intersects_segment(p_from, p_to)) { _cull_segment(p_octant->children[i], p_from, p_to, p_result_array, p_result_idx, p_result_max, p_subindex_array, p_mask); } } } OCTREE_FUNC(void)::_cull_point(Octant *p_octant, const Vector3 &p_point, T **p_result_array, int *p_result_idx, int p_result_max, int *p_subindex_array, uint32_t p_mask) { if (*p_result_idx == p_result_max) return; //pointless if (!p_octant->elements.empty()) { #ifdef OCTREE_USE_CACHED_LISTS // make sure cached list of element pointers and aabbs is up to date if this octant is dirty p_octant->update_cached_lists(); int num_elements = p_octant->clist.elements.size(); for (int n = 0; n < num_elements; n++) { const AABB &aabb = p_octant->clist.aabbs[n]; Element *e = p_octant->clist.elements[n]; if (aabb.has_point(p_point)) { if (e->last_pass == pass || (use_pairs && !(e->pairable_type & p_mask))) continue; e->last_pass = pass; if (*p_result_idx < p_result_max) { p_result_array[*p_result_idx] = e->userdata; if (p_subindex_array) p_subindex_array[*p_result_idx] = e->subindex; (*p_result_idx)++; } else { return; // pointless to continue } } } #else typename List::Element *I; I = p_octant->elements.front(); for (; I; I = I->next()) { Element *e = I->get(); const AABB &aabb = e->aabb; if (e->last_pass == pass || (use_pairs && !(e->pairable_type & p_mask))) continue; e->last_pass = pass; if (aabb.has_point(p_point)) { if (*p_result_idx < p_result_max) { p_result_array[*p_result_idx] = e->userdata; if (p_subindex_array) p_subindex_array[*p_result_idx] = e->subindex; (*p_result_idx)++; } else { return; // pointless to continue } } } #endif } if (use_pairs && !p_octant->pairable_elements.empty()) { #ifdef OCTREE_USE_CACHED_LISTS // make sure cached list of element pointers and aabbs is up to date if this octant is dirty p_octant->update_cached_lists(); int num_elements = p_octant->clist_pairable.elements.size(); for (int n = 0; n < num_elements; n++) { const AABB &aabb = p_octant->clist_pairable.aabbs[n]; Element *e = p_octant->clist_pairable.elements[n]; if (aabb.has_point(p_point)) { if (e->last_pass == pass || (use_pairs && !(e->pairable_type & p_mask))) continue; e->last_pass = pass; if (*p_result_idx < p_result_max) { p_result_array[*p_result_idx] = e->userdata; if (p_subindex_array) p_subindex_array[*p_result_idx] = e->subindex; (*p_result_idx)++; } else { return; // pointless to continue } } } #else typename List::Element *I; I = p_octant->pairable_elements.front(); for (; I; I = I->next()) { Element *e = I->get(); const AABB &aabb = e->aabb; if (e->last_pass == pass || (use_pairs && !(e->pairable_type & p_mask))) continue; e->last_pass = pass; if (aabb.has_point(p_point)) { if (*p_result_idx < p_result_max) { p_result_array[*p_result_idx] = e->userdata; if (p_subindex_array) p_subindex_array[*p_result_idx] = e->subindex; (*p_result_idx)++; } else { return; // pointless to continue } } } #endif } for (int i = 0; i < 8; i++) { //could be optimized.. if (p_octant->children[i] && p_octant->children[i]->aabb.has_point(p_point)) { _cull_point(p_octant->children[i], p_point, p_result_array, p_result_idx, p_result_max, p_subindex_array, p_mask); } } } OCTREE_FUNC(int)::cull_convex(const Vector &p_convex, T **p_result_array, int p_result_max, uint32_t p_mask) { if (!root || p_convex.size() == 0) return 0; Vector convex_points = Geometry::compute_convex_mesh_points(&p_convex[0], p_convex.size()); if (convex_points.size() == 0) return 0; int result_count = 0; pass++; _CullConvexData cdata; cdata.planes = &p_convex[0]; cdata.plane_count = p_convex.size(); cdata.points = &convex_points[0]; cdata.point_count = convex_points.size(); cdata.result_array = p_result_array; cdata.result_max = p_result_max; cdata.result_idx = &result_count; cdata.mask = p_mask; _cull_convex(root, &cdata); return result_count; } OCTREE_FUNC(int)::cull_aabb(const AABB &p_aabb, T **p_result_array, int p_result_max, int *p_subindex_array, uint32_t p_mask) { if (!root) return 0; int result_count = 0; pass++; _cull_aabb(root, p_aabb, p_result_array, &result_count, p_result_max, p_subindex_array, p_mask); return result_count; } OCTREE_FUNC(int)::cull_segment(const Vector3 &p_from, const Vector3 &p_to, T **p_result_array, int p_result_max, int *p_subindex_array, uint32_t p_mask) { if (!root) return 0; int result_count = 0; pass++; _cull_segment(root, p_from, p_to, p_result_array, &result_count, p_result_max, p_subindex_array, p_mask); return result_count; } OCTREE_FUNC(int)::cull_point(const Vector3 &p_point, T **p_result_array, int p_result_max, int *p_subindex_array, uint32_t p_mask) { if (!root) return 0; int result_count = 0; pass++; _cull_point(root, p_point, p_result_array, &result_count, p_result_max, p_subindex_array, p_mask); return result_count; } OCTREE_FUNC(void)::set_pair_callback(PairCallback p_callback, void *p_userdata) { pair_callback = p_callback; pair_callback_userdata = p_userdata; } OCTREE_FUNC(void)::set_unpair_callback(UnpairCallback p_callback, void *p_userdata) { unpair_callback = p_callback; unpair_callback_userdata = p_userdata; } OCTREE_FUNC_CONSTRUCTOR::OCTREE_CLASS_NAME(real_t p_unit_size) { last_element_id = 1; pass = 1; unit_size = p_unit_size; root = NULL; octant_count = 0; pair_count = 0; octant_elements_limit = OCTREE_DEFAULT_OCTANT_LIMIT; pair_callback = NULL; unpair_callback = NULL; pair_callback_userdata = NULL; unpair_callback_userdata = NULL; } #ifdef TOOLS_ENABLED OCTREE_FUNC(String)::debug_aabb_to_string(const AABB &aabb) const { String sz; sz = "( " + String(aabb.position); sz += " ) - ( "; Vector3 max = aabb.position + aabb.size; sz += String(max) + " )"; return sz; } OCTREE_FUNC(void)::debug_octants() { if (root) debug_octant(*root); } OCTREE_FUNC(void)::debug_octant(const Octant &oct, int depth) { String sz = ""; for (int d = 0; d < depth; d++) sz += "\t"; sz += "Octant " + debug_aabb_to_string(oct.aabb); sz += "\tnum_children " + itos(oct.children_count); sz += ", num_eles " + itos(oct.elements.size()); sz += ", num_paired_eles" + itos(oct.pairable_elements.size()); print_line(sz); for (int n = 0; n < 8; n++) { const Octant *pChild = oct.children[n]; if (pChild) { debug_octant(*pChild, depth + 1); } } } #endif // TOOLS_ENABLED #undef OCTREE_FUNC