virtualx-engine/core/math/bvh_logic.inc
PouleyKetchoupp d8f681029f Support for Dynamic BVH as 2D Physics broadphase
List of changes:
- Modified bvh class to handle 2D and 3D as a template
- Changes in Rect2, Vector2, Vector3 interface to uniformize template
calls
- New option in Project Settings to enable BVH for 2D Physics (enabled
by default like in 3D)
2021-04-30 15:53:15 -07:00

225 lines
6.2 KiB
C++

// for slow incremental optimization, we will periodically remove each
// item from the tree and reinsert, to give it a chance to find a better position
void _logic_item_remove_and_reinsert(uint32_t p_ref_id) {
// get the reference
ItemRef &ref = _refs[p_ref_id];
// no need to optimize inactive items
if (!ref.is_active())
return;
// special case of debug draw
if (ref.item_id == BVHCommon::INVALID)
return;
BVH_ASSERT(ref.tnode_id != BVHCommon::INVALID);
// some overlay elaborate way to find out which tree the node is in!
BVHHandle temp_handle;
temp_handle.set_id(p_ref_id);
_current_tree = _handle_get_tree_id(temp_handle);
// remove and reinsert
BVHABB_CLASS abb;
node_remove_item(p_ref_id, &abb);
// we must choose where to add to tree
ref.tnode_id = _logic_choose_item_add_node(_root_node_id[_current_tree], abb);
_node_add_item(ref.tnode_id, p_ref_id, abb);
refit_upward_and_balance(ref.tnode_id);
}
// from randy gaul balance function
BVHABB_CLASS _logic_abb_merge(const BVHABB_CLASS &a, const BVHABB_CLASS &b) {
BVHABB_CLASS c = a;
c.merge(b);
return c;
}
//--------------------------------------------------------------------------------------------------
/**
@file q3DynamicAABBTree.h
@author Randy Gaul
@date 10/10/2014
Copyright (c) 2014 Randy Gaul http://www.randygaul.net
This software is provided 'as-is', without any express or implied
warranty. In no event will the authors be held liable for any damages
arising from the use of this software.
Permission is granted to anyone to use this software for any purpose,
including commercial applications, and to alter it and redistribute it
freely, subject to the following restrictions:
1. The origin of this software must not be misrepresented; you must not
claim that you wrote the original software. If you use this software
in a product, an acknowledgment in the product documentation would be
appreciated but is not required.
2. Altered source versions must be plainly marked as such, and must not
be misrepresented as being the original software.
3. This notice may not be removed or altered from any source distribution.
*/
//--------------------------------------------------------------------------------------------------
// This function is based on the 'Balance' function from Randy Gaul's qu3e
// https://github.com/RandyGaul/qu3e
// It is MODIFIED from qu3e version.
// This is the only function used (and _logic_abb_merge helper function).
int32_t _logic_balance(int32_t iA) {
// return iA; // uncomment this to bypass balance
TNode *A = &_nodes[iA];
if (A->is_leaf() || A->height == 1)
return iA;
/* A
/ \
B C
/ \ / \
D E F G
*/
CRASH_COND(A->num_children != 2);
int32_t iB = A->children[0];
int32_t iC = A->children[1];
TNode *B = &_nodes[iB];
TNode *C = &_nodes[iC];
int32_t balance = C->height - B->height;
// C is higher, promote C
if (balance > 1) {
int32_t iF = C->children[0];
int32_t iG = C->children[1];
TNode *F = &_nodes[iF];
TNode *G = &_nodes[iG];
// grandParent point to C
if (A->parent_id != BVHCommon::INVALID) {
if (_nodes[A->parent_id].children[0] == iA)
_nodes[A->parent_id].children[0] = iC;
else
_nodes[A->parent_id].children[1] = iC;
} else {
// check this .. seems dodgy
change_root_node(iC);
}
// Swap A and C
C->children[0] = iA;
C->parent_id = A->parent_id;
A->parent_id = iC;
// Finish rotation
if (F->height > G->height) {
C->children[1] = iF;
A->children[1] = iG;
G->parent_id = iA;
A->aabb = _logic_abb_merge(B->aabb, G->aabb);
C->aabb = _logic_abb_merge(A->aabb, F->aabb);
A->height = 1 + MAX(B->height, G->height);
C->height = 1 + MAX(A->height, F->height);
}
else {
C->children[1] = iG;
A->children[1] = iF;
F->parent_id = iA;
A->aabb = _logic_abb_merge(B->aabb, F->aabb);
C->aabb = _logic_abb_merge(A->aabb, G->aabb);
A->height = 1 + MAX(B->height, F->height);
C->height = 1 + MAX(A->height, G->height);
}
return iC;
}
// B is higher, promote B
else if (balance < -1) {
int32_t iD = B->children[0];
int32_t iE = B->children[1];
TNode *D = &_nodes[iD];
TNode *E = &_nodes[iE];
// grandParent point to B
if (A->parent_id != BVHCommon::INVALID) {
if (_nodes[A->parent_id].children[0] == iA)
_nodes[A->parent_id].children[0] = iB;
else
_nodes[A->parent_id].children[1] = iB;
}
else {
// check this .. seems dodgy
change_root_node(iB);
}
// Swap A and B
B->children[1] = iA;
B->parent_id = A->parent_id;
A->parent_id = iB;
// Finish rotation
if (D->height > E->height) {
B->children[0] = iD;
A->children[0] = iE;
E->parent_id = iA;
A->aabb = _logic_abb_merge(C->aabb, E->aabb);
B->aabb = _logic_abb_merge(A->aabb, D->aabb);
A->height = 1 + MAX(C->height, E->height);
B->height = 1 + MAX(A->height, D->height);
}
else {
B->children[0] = iE;
A->children[0] = iD;
D->parent_id = iA;
A->aabb = _logic_abb_merge(C->aabb, D->aabb);
B->aabb = _logic_abb_merge(A->aabb, E->aabb);
A->height = 1 + MAX(C->height, D->height);
B->height = 1 + MAX(A->height, E->height);
}
return iB;
}
return iA;
}
// either choose an existing node to add item to, or create a new node and return this
uint32_t _logic_choose_item_add_node(uint32_t p_node_id, const BVHABB_CLASS &p_aabb) {
while (true) {
BVH_ASSERT(p_node_id != BVHCommon::INVALID);
TNode &tnode = _nodes[p_node_id];
if (tnode.is_leaf()) {
// if a leaf, and non full, use this to add to
if (!node_is_leaf_full(tnode))
return p_node_id;
// else split the leaf, and use one of the children to add to
return split_leaf(p_node_id, p_aabb);
}
// this should not happen???
// is still happening, need to debug and find circumstances. Is not that serious
// but would be nice to prevent. I think it only happens with the root node.
if (tnode.num_children == 1) {
WARN_PRINT_ONCE("BVH::recursive_choose_item_add_node, node with 1 child, recovering");
p_node_id = tnode.children[0];
} else {
BVH_ASSERT(tnode.num_children == 2);
TNode &childA = _nodes[tnode.children[0]];
TNode &childB = _nodes[tnode.children[1]];
int which = p_aabb.select_by_proximity(childA.aabb, childB.aabb);
p_node_id = tnode.children[which];
}
}
}