public void query(TreeCallback callback, AABB aabb) { nodeStack.reset(); nodeStack.push(m_root); while (nodeStack.getCount() > 0) { DynamicTreeNode node = nodeStack.pop(); if (node == null) { continue; } if (AABB.testOverlap(node.aabb, aabb)) { if (node.child1 == null) { bool proceed = callback.treeCallback(node.id); if (!proceed) { return; } } else { nodeStack.push(node.child1); nodeStack.push(node.child2); } } } }
/// <summary> /// Query an AABB for overlapping proxies. The callback class is called for each proxy that /// overlaps the supplied AABB. /// </summary> /// <param name="callback"></param> /// <param name="araabbgAABB"></param> public void query(TreeCallback callback, AABB aabb) { intStack.reset(); intStack.push(m_root); while (intStack.Count > 0) { int nodeId = intStack.pop(); if (nodeId == TreeNode.NULL_NODE) { continue; } TreeNode node = m_nodes[nodeId]; if (AABB.testOverlap(node.aabb, aabb)) { if (node.Leaf) { bool proceed = callback.treeCallback(nodeId); if (!proceed) { return; } } else { intStack.push(node.child1); intStack.push(node.child2); } } } }
public void query(TreeCallback callback, AABB aabb) { m_tree.query(callback, aabb); }
/** * Query an AABB for overlapping proxies. The callback class is called for each proxy that * overlaps the supplied AABB. * * @param callback * @param aabb */ public void query(TreeCallback callback, AABB aabb) { m_tree.query(callback, aabb); }
public void query(TreeCallback callback, AABB aabb) { Debug.Assert(aabb.isValid()); nodeStackIndex = 0; nodeStack[nodeStackIndex++] = m_root; while (nodeStackIndex > 0) { DynamicTreeNode node = nodeStack[--nodeStackIndex]; if (node == null) { continue; } if (AABB.testOverlap(node.aabb, aabb)) { if (node.child1 == null) { bool proceed = callback.treeCallback(node.id); if (!proceed) { return; } } else { if (nodeStack.Length - nodeStackIndex - 2 <= 0) { DynamicTreeNode[] newBuffer = new DynamicTreeNode[nodeStack.Length*2]; Array.Copy(nodeStack, 0, newBuffer, 0, nodeStack.Length); nodeStack = newBuffer; } nodeStack[nodeStackIndex++] = node.child1; nodeStack[nodeStackIndex++] = node.child2; } } } }
public void query(TreeCallback callback, AABB aabb) { nodeStackIndex = 0; nodeStack[nodeStackIndex++] = m_root; while (nodeStackIndex > 0) { int node = nodeStack[--nodeStackIndex]; if (node == NULL_NODE) { continue; } if (AABB.testOverlap(m_aabb[node], aabb)) { int child1 = m_child1[node]; if (child1 == NULL_NODE) { bool proceed = callback.treeCallback(node); if (!proceed) { return; } } else { if (nodeStack.Length - nodeStackIndex - 2 <= 0) { nodeStack = BufferUtils.reallocateBuffer(nodeStack, nodeStack.Length, nodeStack.Length*2); } nodeStack[nodeStackIndex++] = child1; nodeStack[nodeStackIndex++] = m_child2[node]; } } } }