virtualx-engine/core/math/bvh_refit.inc
风青山 e705aa4550 Fix not refitting upward from leaf nodes.
Previously, the wrong node id (root node id) was used. Dirty leaf nodes
do not actually recalculate aabb.

Additionally, when requesting a new leaf, mark `dirty` as `false` in `clear()`.

Make sure to only mark the leaf as **dirty** when shrinking the border of
the leaf when removing items.

In other cases, the leaf node's aabb will get the correct result immediately.
1. When adding an item, the leaf nodes will be calculated immediately.
2. Removing the item within the border of the leaf node has no effect on the
original aabb.
2023-09-28 20:27:51 +08:00

141 lines
3.3 KiB
C++

void _debug_node_verify_bound(uint32_t p_node_id) {
TNode &node = _nodes[p_node_id];
BVHABB_CLASS abb_before = node.aabb;
node_update_aabb(node);
BVHABB_CLASS abb_after = node.aabb;
CRASH_COND(abb_before != abb_after);
}
void node_update_aabb(TNode &tnode) {
tnode.aabb.set_to_max_opposite_extents();
tnode.height = 0;
if (!tnode.is_leaf()) {
for (int n = 0; n < tnode.num_children; n++) {
uint32_t child_node_id = tnode.children[n];
// merge with child aabb
const TNode &tchild = _nodes[child_node_id];
tnode.aabb.merge(tchild.aabb);
// do heights at the same time
if (tchild.height > tnode.height) {
tnode.height = tchild.height;
}
}
// the height of a non leaf is always 1 bigger than the biggest child
tnode.height++;
#ifdef BVH_CHECKS
if (!tnode.num_children) {
// the 'blank' aabb will screw up parent aabbs
WARN_PRINT("BVH_Tree::TNode no children, AABB is undefined");
}
#endif
} else {
// leaf
const TLeaf &leaf = _node_get_leaf(tnode);
for (int n = 0; n < leaf.num_items; n++) {
tnode.aabb.merge(leaf.get_aabb(n));
}
// now the leaf items are unexpanded, we expand only in the node AABB
tnode.aabb.expand(_node_expansion);
#ifdef BVH_CHECKS
if (!leaf.num_items) {
// the 'blank' aabb will screw up parent aabbs
WARN_PRINT("BVH_Tree::TLeaf no items, AABB is undefined");
}
#endif
}
}
void refit_all(int p_tree_id) {
refit_downward(_root_node_id[p_tree_id]);
}
void refit_upward(uint32_t p_node_id) {
while (p_node_id != BVHCommon::INVALID) {
TNode &tnode = _nodes[p_node_id];
node_update_aabb(tnode);
p_node_id = tnode.parent_id;
}
}
void refit_upward_and_balance(uint32_t p_node_id, uint32_t p_tree_id) {
while (p_node_id != BVHCommon::INVALID) {
uint32_t before = p_node_id;
p_node_id = _logic_balance(p_node_id, p_tree_id);
if (before != p_node_id) {
VERBOSE_PRINT("REBALANCED!");
}
TNode &tnode = _nodes[p_node_id];
// update overall aabb from the children
node_update_aabb(tnode);
p_node_id = tnode.parent_id;
}
}
void refit_downward(uint32_t p_node_id) {
TNode &tnode = _nodes[p_node_id];
// do children first
if (!tnode.is_leaf()) {
for (int n = 0; n < tnode.num_children; n++) {
refit_downward(tnode.children[n]);
}
}
node_update_aabb(tnode);
}
// go down to the leaves, then refit upward
void refit_branch(uint32_t p_node_id) {
// our function parameters to keep on a stack
struct RefitParams {
uint32_t node_id;
};
// most of the iterative functionality is contained in this helper class
BVH_IterativeInfo<RefitParams> ii;
// alloca must allocate the stack from this function, it cannot be allocated in the
// helper class
ii.stack = (RefitParams *)alloca(ii.get_alloca_stacksize());
// seed the stack
ii.get_first()->node_id = p_node_id;
RefitParams rp;
// while there are still more nodes on the stack
while (ii.pop(rp)) {
TNode &tnode = _nodes[rp.node_id];
// do children first
if (!tnode.is_leaf()) {
for (int n = 0; n < tnode.num_children; n++) {
uint32_t child_id = tnode.children[n];
// add to the stack
RefitParams *child = ii.request();
child->node_id = child_id;
}
} else {
// leaf .. only refit upward if dirty
TLeaf &leaf = _node_get_leaf(tnode);
if (leaf.is_dirty()) {
leaf.set_dirty(false);
refit_upward(rp.node_id);
}
}
} // while more nodes to pop
}