mirror of
https://github.com/Relintai/pandemonium_engine_minimal.git
synced 2024-11-17 22:17:19 +01:00
395 lines
14 KiB
C++
395 lines
14 KiB
C++
/**************************************************************************/
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/* nav_agent.cpp */
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/**************************************************************************/
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/* This file is part of: */
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/* GODOT ENGINE */
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/* https://godotengine.org */
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/**************************************************************************/
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/* Copyright (c) 2014-present Godot Engine contributors (see AUTHORS.md). */
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/* Copyright (c) 2007-2014 Juan Linietsky, Ariel Manzur. */
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/* */
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/* Permission is hereby granted, free of charge, to any person obtaining */
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/* a copy of this software and associated documentation files (the */
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/* "Software"), to deal in the Software without restriction, including */
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/* without limitation the rights to use, copy, modify, merge, publish, */
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/* distribute, sublicense, and/or sell copies of the Software, and to */
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/* permit persons to whom the Software is furnished to do so, subject to */
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/* the following conditions: */
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/* */
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/* The above copyright notice and this permission notice shall be */
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/* included in all copies or substantial portions of the Software. */
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/* */
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/* THE SOFTWARE IS PROVIDED "AS IS", WITHOUT WARRANTY OF ANY KIND, */
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/* EXPRESS OR IMPLIED, INCLUDING BUT NOT LIMITED TO THE WARRANTIES OF */
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/* MERCHANTABILITY, FITNESS FOR A PARTICULAR PURPOSE AND NONINFRINGEMENT. */
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/* IN NO EVENT SHALL THE AUTHORS OR COPYRIGHT HOLDERS BE LIABLE FOR ANY */
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/* CLAIM, DAMAGES OR OTHER LIABILITY, WHETHER IN AN ACTION OF CONTRACT, */
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/* TORT OR OTHERWISE, ARISING FROM, OUT OF OR IN CONNECTION WITH THE */
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/* SOFTWARE OR THE USE OR OTHER DEALINGS IN THE SOFTWARE. */
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/**************************************************************************/
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#include "nav_agent.h"
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#include "nav_map.h"
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NavAgent::NavAgent() {
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height = 1.0;
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radius = 1.0;
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max_speed = 1.0;
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time_horizon_agents = 1.0;
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time_horizon_obstacles = 0.0;
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max_neighbors = 5;
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neighbor_distance = 5.0;
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clamp_speed = true; // Experimental, clamps velocity to max_speed.
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map = nullptr;
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use_3d_avoidance = false;
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avoidance_enabled = false;
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avoidance_layers = 1;
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avoidance_mask = 1;
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avoidance_priority = 1.0;
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avoidance_callback.id = ObjectID(0);
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agent_dirty = true;
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map_update_id = 0;
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paused = false;
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}
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void NavAgent::set_avoidance_enabled(bool p_enabled) {
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avoidance_enabled = p_enabled;
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_update_rvo_agent_properties();
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}
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void NavAgent::set_use_3d_avoidance(bool p_enabled) {
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use_3d_avoidance = p_enabled;
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_update_rvo_agent_properties();
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}
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void NavAgent::_update_rvo_agent_properties() {
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if (use_3d_avoidance) {
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rvo_agent_3d.neighborDist_ = neighbor_distance;
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rvo_agent_3d.maxNeighbors_ = max_neighbors;
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rvo_agent_3d.timeHorizon_ = time_horizon_agents;
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rvo_agent_3d.timeHorizonObst_ = time_horizon_obstacles;
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rvo_agent_3d.radius_ = radius;
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rvo_agent_3d.maxSpeed_ = max_speed;
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rvo_agent_3d.position_ = RVO3D::Vector3(position.x, position.y, position.z);
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// Replacing the internal velocity directly causes major jitter / bugs due to unpredictable velocity jumps, left line here for testing.
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//rvo_agent_3d.velocity_ = RVO3D::Vector3(velocity.x, velocity.y ,velocity.z);
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rvo_agent_3d.prefVelocity_ = RVO3D::Vector3(velocity.x, velocity.y, velocity.z);
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rvo_agent_3d.height_ = height;
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rvo_agent_3d.avoidance_layers_ = avoidance_layers;
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rvo_agent_3d.avoidance_mask_ = avoidance_mask;
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rvo_agent_3d.avoidance_priority_ = avoidance_priority;
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} else {
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rvo_agent_2d.neighborDist_ = neighbor_distance;
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rvo_agent_2d.maxNeighbors_ = max_neighbors;
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rvo_agent_2d.timeHorizon_ = time_horizon_agents;
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rvo_agent_2d.timeHorizonObst_ = time_horizon_obstacles;
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rvo_agent_2d.radius_ = radius;
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rvo_agent_2d.maxSpeed_ = max_speed;
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rvo_agent_2d.position_ = RVO2D::Vector2(position.x, position.z);
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rvo_agent_2d.elevation_ = position.y;
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// Replacing the internal velocity directly causes major jitter / bugs due to unpredictable velocity jumps, left line here for testing.
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//rvo_agent_2d.velocity_ = RVO2D::Vector2(velocity.x, velocity.z);
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rvo_agent_2d.prefVelocity_ = RVO2D::Vector2(velocity.x, velocity.z);
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rvo_agent_2d.height_ = height;
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rvo_agent_2d.avoidance_layers_ = avoidance_layers;
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rvo_agent_2d.avoidance_mask_ = avoidance_mask;
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rvo_agent_2d.avoidance_priority_ = avoidance_priority;
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}
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if (map != nullptr) {
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if (avoidance_enabled) {
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map->set_agent_as_controlled(this);
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} else {
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map->remove_agent_as_controlled(this);
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}
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}
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agent_dirty = true;
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}
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void NavAgent::set_map(NavMap *p_map) {
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map = p_map;
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agent_dirty = true;
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}
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bool NavAgent::is_map_changed() {
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if (map) {
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bool is_changed = map->get_map_update_id() != map_update_id;
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map_update_id = map->get_map_update_id();
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return is_changed;
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} else {
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return false;
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}
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}
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void NavAgent::set_neighbor_distance(real_t p_neighbor_distance) {
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neighbor_distance = p_neighbor_distance;
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if (use_3d_avoidance) {
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rvo_agent_3d.neighborDist_ = neighbor_distance;
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} else {
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rvo_agent_2d.neighborDist_ = neighbor_distance;
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}
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agent_dirty = true;
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}
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void NavAgent::set_max_neighbors(int p_max_neighbors) {
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max_neighbors = p_max_neighbors;
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if (use_3d_avoidance) {
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rvo_agent_3d.maxNeighbors_ = max_neighbors;
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} else {
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rvo_agent_2d.maxNeighbors_ = max_neighbors;
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}
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agent_dirty = true;
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}
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void NavAgent::set_time_horizon_agents(real_t p_time_horizon) {
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time_horizon_agents = p_time_horizon;
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if (use_3d_avoidance) {
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rvo_agent_3d.timeHorizon_ = time_horizon_agents;
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} else {
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rvo_agent_2d.timeHorizon_ = time_horizon_agents;
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}
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agent_dirty = true;
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}
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void NavAgent::set_time_horizon_obstacles(real_t p_time_horizon) {
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time_horizon_obstacles = p_time_horizon;
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if (use_3d_avoidance) {
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rvo_agent_3d.timeHorizonObst_ = time_horizon_obstacles;
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} else {
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rvo_agent_2d.timeHorizonObst_ = time_horizon_obstacles;
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}
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agent_dirty = true;
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}
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void NavAgent::set_radius(real_t p_radius) {
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radius = p_radius;
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if (use_3d_avoidance) {
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rvo_agent_3d.radius_ = radius;
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} else {
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rvo_agent_2d.radius_ = radius;
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}
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agent_dirty = true;
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}
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void NavAgent::set_height(real_t p_height) {
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height = p_height;
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if (use_3d_avoidance) {
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rvo_agent_3d.height_ = height;
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} else {
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rvo_agent_2d.height_ = height;
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}
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agent_dirty = true;
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}
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void NavAgent::set_max_speed(real_t p_max_speed) {
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max_speed = p_max_speed;
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if (avoidance_enabled) {
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if (use_3d_avoidance) {
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rvo_agent_3d.maxSpeed_ = max_speed;
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} else {
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rvo_agent_2d.maxSpeed_ = max_speed;
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}
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}
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agent_dirty = true;
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}
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void NavAgent::set_position(const Vector3 p_position) {
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position = p_position;
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if (avoidance_enabled) {
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if (use_3d_avoidance) {
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rvo_agent_3d.position_ = RVO3D::Vector3(p_position.x, p_position.y, p_position.z);
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} else {
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rvo_agent_2d.elevation_ = p_position.y;
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rvo_agent_2d.position_ = RVO2D::Vector2(p_position.x, p_position.z);
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}
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}
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agent_dirty = true;
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}
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void NavAgent::set_target_position(const Vector3 p_target_position) {
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target_position = p_target_position;
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}
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void NavAgent::set_velocity(const Vector3 p_velocity) {
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// Sets the "wanted" velocity for an agent as a suggestion
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// This velocity is not guaranteed, RVO simulation will only try to fulfill it
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velocity = p_velocity;
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if (avoidance_enabled) {
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if (use_3d_avoidance) {
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rvo_agent_3d.prefVelocity_ = RVO3D::Vector3(velocity.x, velocity.y, velocity.z);
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} else {
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rvo_agent_2d.prefVelocity_ = RVO2D::Vector2(velocity.x, velocity.z);
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}
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}
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agent_dirty = true;
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}
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void NavAgent::set_velocity_forced(const Vector3 p_velocity) {
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// This function replaces the internal rvo simulation velocity
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// should only be used after the agent was teleported
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// as it destroys consistency in movement in cramped situations
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// use velocity instead to update with a safer "suggestion"
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velocity_forced = p_velocity;
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if (avoidance_enabled) {
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if (use_3d_avoidance) {
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rvo_agent_3d.velocity_ = RVO3D::Vector3(p_velocity.x, p_velocity.y, p_velocity.z);
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} else {
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rvo_agent_2d.velocity_ = RVO2D::Vector2(p_velocity.x, p_velocity.z);
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}
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}
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agent_dirty = true;
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}
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void NavAgent::update() {
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// Updates this agent with the calculated results from the rvo simulation
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if (avoidance_enabled) {
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if (use_3d_avoidance) {
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velocity = Vector3(rvo_agent_3d.velocity_.x(), rvo_agent_3d.velocity_.y(), rvo_agent_3d.velocity_.z());
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} else {
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velocity = Vector3(rvo_agent_2d.velocity_.x(), 0.0, rvo_agent_2d.velocity_.y());
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}
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}
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}
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void NavAgent::set_avoidance_mask(uint32_t p_mask) {
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avoidance_mask = p_mask;
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if (use_3d_avoidance) {
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rvo_agent_3d.avoidance_mask_ = avoidance_mask;
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} else {
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rvo_agent_2d.avoidance_mask_ = avoidance_mask;
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}
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agent_dirty = true;
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}
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void NavAgent::set_avoidance_layers(uint32_t p_layers) {
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avoidance_layers = p_layers;
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if (use_3d_avoidance) {
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rvo_agent_3d.avoidance_layers_ = avoidance_layers;
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} else {
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rvo_agent_2d.avoidance_layers_ = avoidance_layers;
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}
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agent_dirty = true;
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}
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void NavAgent::set_avoidance_priority(real_t p_priority) {
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ERR_FAIL_COND_MSG(p_priority < 0.0, "Avoidance priority must be between 0.0 and 1.0 inclusive.");
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ERR_FAIL_COND_MSG(p_priority > 1.0, "Avoidance priority must be between 0.0 and 1.0 inclusive.");
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avoidance_priority = p_priority;
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if (use_3d_avoidance) {
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rvo_agent_3d.avoidance_priority_ = avoidance_priority;
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} else {
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rvo_agent_2d.avoidance_priority_ = avoidance_priority;
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}
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agent_dirty = true;
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};
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bool NavAgent::check_dirty() {
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const bool was_dirty = agent_dirty;
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agent_dirty = false;
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return was_dirty;
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}
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const Dictionary NavAgent::get_avoidance_data() const {
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// Returns debug data from RVO simulation internals of this agent.
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Dictionary _avoidance_data;
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if (use_3d_avoidance) {
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_avoidance_data["max_neighbors"] = int(rvo_agent_3d.maxNeighbors_);
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_avoidance_data["max_speed"] = float(rvo_agent_3d.maxSpeed_);
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_avoidance_data["neighbor_distance"] = float(rvo_agent_3d.neighborDist_);
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_avoidance_data["new_velocity"] = Vector3(rvo_agent_3d.newVelocity_.x(), rvo_agent_3d.newVelocity_.y(), rvo_agent_3d.newVelocity_.z());
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_avoidance_data["velocity"] = Vector3(rvo_agent_3d.velocity_.x(), rvo_agent_3d.velocity_.y(), rvo_agent_3d.velocity_.z());
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_avoidance_data["position"] = Vector3(rvo_agent_3d.position_.x(), rvo_agent_3d.position_.y(), rvo_agent_3d.position_.z());
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_avoidance_data["prefered_velocity"] = Vector3(rvo_agent_3d.prefVelocity_.x(), rvo_agent_3d.prefVelocity_.y(), rvo_agent_3d.prefVelocity_.z());
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_avoidance_data["radius"] = float(rvo_agent_3d.radius_);
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_avoidance_data["time_horizon_agents"] = float(rvo_agent_3d.timeHorizon_);
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_avoidance_data["time_horizon_obstacles"] = 0.0;
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_avoidance_data["height"] = float(rvo_agent_3d.height_);
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_avoidance_data["avoidance_layers"] = int(rvo_agent_3d.avoidance_layers_);
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_avoidance_data["avoidance_mask"] = int(rvo_agent_3d.avoidance_mask_);
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_avoidance_data["avoidance_priority"] = float(rvo_agent_3d.avoidance_priority_);
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} else {
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_avoidance_data["max_neighbors"] = int(rvo_agent_2d.maxNeighbors_);
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_avoidance_data["max_speed"] = float(rvo_agent_2d.maxSpeed_);
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_avoidance_data["neighbor_distance"] = float(rvo_agent_2d.neighborDist_);
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_avoidance_data["new_velocity"] = Vector3(rvo_agent_2d.newVelocity_.x(), 0.0, rvo_agent_2d.newVelocity_.y());
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_avoidance_data["velocity"] = Vector3(rvo_agent_2d.velocity_.x(), 0.0, rvo_agent_2d.velocity_.y());
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_avoidance_data["position"] = Vector3(rvo_agent_2d.position_.x(), 0.0, rvo_agent_2d.position_.y());
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_avoidance_data["prefered_velocity"] = Vector3(rvo_agent_2d.prefVelocity_.x(), 0.0, rvo_agent_2d.prefVelocity_.y());
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_avoidance_data["radius"] = float(rvo_agent_2d.radius_);
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_avoidance_data["time_horizon_agents"] = float(rvo_agent_2d.timeHorizon_);
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_avoidance_data["time_horizon_obstacles"] = float(rvo_agent_2d.timeHorizonObst_);
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_avoidance_data["height"] = float(rvo_agent_2d.height_);
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_avoidance_data["avoidance_layers"] = int(rvo_agent_2d.avoidance_layers_);
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_avoidance_data["avoidance_mask"] = int(rvo_agent_2d.avoidance_mask_);
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_avoidance_data["avoidance_priority"] = float(rvo_agent_2d.avoidance_priority_);
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}
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return _avoidance_data;
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}
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void NavAgent::set_paused(bool p_paused) {
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if (paused == p_paused) {
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return;
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}
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paused = p_paused;
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if (map) {
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if (paused) {
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map->remove_agent_as_controlled(this);
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} else {
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map->set_agent_as_controlled(this);
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}
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}
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}
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bool NavAgent::get_paused() const {
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return paused;
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}
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void NavAgent::set_avoidance_callback(ObjectID p_id, const StringName p_method, const Variant p_udata) {
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avoidance_callback.id = p_id;
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avoidance_callback.method = p_method;
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avoidance_callback.udata = p_udata;
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}
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bool NavAgent::has_avoidance_callback() const {
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return avoidance_callback.id != 0;
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}
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void NavAgent::dispatch_avoidance_callback() {
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if (avoidance_callback.id == 0) {
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return;
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}
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Object *obj = ObjectDB::get_instance(avoidance_callback.id);
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if (!obj) {
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avoidance_callback.id = ObjectID(0);
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return;
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}
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Variant::CallError responseCallError;
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Vector3 new_velocity;
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if (use_3d_avoidance) {
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new_velocity = Vector3(rvo_agent_3d.velocity_.x(), rvo_agent_3d.velocity_.y(), rvo_agent_3d.velocity_.z());
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} else {
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new_velocity = Vector3(rvo_agent_2d.velocity_.x(), 0.0, rvo_agent_2d.velocity_.y());
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}
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if (clamp_speed) {
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new_velocity = new_velocity.limit_length(max_speed);
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}
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avoidance_callback.new_velocity = new_velocity;
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const Variant *vp[2] = { &avoidance_callback.new_velocity, &avoidance_callback.udata };
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int argc = (avoidance_callback.udata.get_type() == Variant::NIL) ? 1 : 2;
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obj->call(avoidance_callback.method, vp, argc, responseCallError);
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}
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