/* * KdTree.cpp * RVO2-3D Library * * Copyright 2008 University of North Carolina at Chapel Hill * * Licensed under the Apache License, Version 2.0 (the "License"); * you may not use this file except in compliance with the License. * You may obtain a copy of the License at * * http://www.apache.org/licenses/LICENSE-2.0 * * Unless required by applicable law or agreed to in writing, software * distributed under the License is distributed on an "AS IS" BASIS, * WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied. * See the License for the specific language governing permissions and * limitations under the License. * * Please send all bug reports to . * * The authors may be contacted via: * * Jur van den Berg, Stephen J. Guy, Jamie Snape, Ming C. Lin, Dinesh Manocha * Dept. of Computer Science * 201 S. Columbia St. * Frederick P. Brooks, Jr. Computer Science Bldg. * Chapel Hill, N.C. 27599-3175 * United States of America * * */ #include "KdTree.h" #include #include "Agent.h" #include "Definitions.h" namespace RVO { const size_t RVO_MAX_LEAF_SIZE = 10; KdTree::KdTree() {} void KdTree::buildAgentTree(std::vector agents) { agents_.swap(agents); if (!agents_.empty()) { agentTree_.resize(2 * agents_.size() - 1); buildAgentTreeRecursive(0, agents_.size(), 0); } } void KdTree::buildAgentTreeRecursive(size_t begin, size_t end, size_t node) { agentTree_[node].begin = begin; agentTree_[node].end = end; agentTree_[node].minCoord = agents_[begin]->position_; agentTree_[node].maxCoord = agents_[begin]->position_; for (size_t i = begin + 1; i < end; ++i) { agentTree_[node].maxCoord[0] = std::max(agentTree_[node].maxCoord[0], agents_[i]->position_.x()); agentTree_[node].minCoord[0] = std::min(agentTree_[node].minCoord[0], agents_[i]->position_.x()); agentTree_[node].maxCoord[1] = std::max(agentTree_[node].maxCoord[1], agents_[i]->position_.y()); agentTree_[node].minCoord[1] = std::min(agentTree_[node].minCoord[1], agents_[i]->position_.y()); agentTree_[node].maxCoord[2] = std::max(agentTree_[node].maxCoord[2], agents_[i]->position_.z()); agentTree_[node].minCoord[2] = std::min(agentTree_[node].minCoord[2], agents_[i]->position_.z()); } if (end - begin > RVO_MAX_LEAF_SIZE) { /* No leaf node. */ size_t coord; if (agentTree_[node].maxCoord[0] - agentTree_[node].minCoord[0] > agentTree_[node].maxCoord[1] - agentTree_[node].minCoord[1] && agentTree_[node].maxCoord[0] - agentTree_[node].minCoord[0] > agentTree_[node].maxCoord[2] - agentTree_[node].minCoord[2]) { coord = 0; } else if (agentTree_[node].maxCoord[1] - agentTree_[node].minCoord[1] > agentTree_[node].maxCoord[2] - agentTree_[node].minCoord[2]) { coord = 1; } else { coord = 2; } const float splitValue = 0.5f * (agentTree_[node].maxCoord[coord] + agentTree_[node].minCoord[coord]); size_t left = begin; size_t right = end; while (left < right) { while (left < right && agents_[left]->position_[coord] < splitValue) { ++left; } while (right > left && agents_[right - 1]->position_[coord] >= splitValue) { --right; } if (left < right) { std::swap(agents_[left], agents_[right - 1]); ++left; --right; } } size_t leftSize = left - begin; if (leftSize == 0) { ++leftSize; ++left; ++right; } agentTree_[node].left = node + 1; agentTree_[node].right = node + 2 * leftSize; buildAgentTreeRecursive(begin, left, agentTree_[node].left); buildAgentTreeRecursive(left, end, agentTree_[node].right); } } void KdTree::computeAgentNeighbors(Agent *agent, float rangeSq) const { queryAgentTreeRecursive(agent, rangeSq, 0); } void KdTree::queryAgentTreeRecursive(Agent *agent, float &rangeSq, size_t node) const { if (agentTree_[node].end - agentTree_[node].begin <= RVO_MAX_LEAF_SIZE) { for (size_t i = agentTree_[node].begin; i < agentTree_[node].end; ++i) { agent->insertAgentNeighbor(agents_[i], rangeSq); } } else { const float distSqLeft = sqr(std::max(0.0f, agentTree_[agentTree_[node].left].minCoord[0] - agent->position_.x())) + sqr(std::max(0.0f, agent->position_.x() - agentTree_[agentTree_[node].left].maxCoord[0])) + sqr(std::max(0.0f, agentTree_[agentTree_[node].left].minCoord[1] - agent->position_.y())) + sqr(std::max(0.0f, agent->position_.y() - agentTree_[agentTree_[node].left].maxCoord[1])) + sqr(std::max(0.0f, agentTree_[agentTree_[node].left].minCoord[2] - agent->position_.z())) + sqr(std::max(0.0f, agent->position_.z() - agentTree_[agentTree_[node].left].maxCoord[2])); const float distSqRight = sqr(std::max(0.0f, agentTree_[agentTree_[node].right].minCoord[0] - agent->position_.x())) + sqr(std::max(0.0f, agent->position_.x() - agentTree_[agentTree_[node].right].maxCoord[0])) + sqr(std::max(0.0f, agentTree_[agentTree_[node].right].minCoord[1] - agent->position_.y())) + sqr(std::max(0.0f, agent->position_.y() - agentTree_[agentTree_[node].right].maxCoord[1])) + sqr(std::max(0.0f, agentTree_[agentTree_[node].right].minCoord[2] - agent->position_.z())) + sqr(std::max(0.0f, agent->position_.z() - agentTree_[agentTree_[node].right].maxCoord[2])); if (distSqLeft < distSqRight) { if (distSqLeft < rangeSq) { queryAgentTreeRecursive(agent, rangeSq, agentTree_[node].left); if (distSqRight < rangeSq) { queryAgentTreeRecursive(agent, rangeSq, agentTree_[node].right); } } } else { if (distSqRight < rangeSq) { queryAgentTreeRecursive(agent, rangeSq, agentTree_[node].right); if (distSqLeft < rangeSq) { queryAgentTreeRecursive(agent, rangeSq, agentTree_[node].left); } } } } } } // namespace RVO