pub mod attack; pub mod consts; pub mod data; pub mod util; use crate::{ rtsim::{entity::PersonalityTrait, RtSim}, sys::agent::{ consts::{ AVG_FOLLOW_DIST, DAMAGE_MEMORY_DURATION, DEFAULT_ATTACK_RANGE, FLEE_DURATION, HEALING_ITEM_THRESHOLD, IDLE_HEALING_ITEM_THRESHOLD, MAX_FLEE_DIST, MAX_FOLLOW_DIST, NPC_PICKUP_RANGE, PARTIAL_PATH_DIST, RETARGETING_THRESHOLD_SECONDS, SEPARATION_BIAS, SEPARATION_DIST, }, data::{AgentData, AttackData, Path, ReadData, Tactic, TargetData}, util::{ aim_projectile, are_our_owners_hostile, entities_have_line_of_sight, get_attacker, get_entity_by_id, is_dead, is_dead_or_invulnerable, is_dressed_as_cultist, is_invulnerable, is_village_guard, is_villager, stop_pursuing, }, }, }; use common::{ combat::perception_dist_multiplier_from_stealth, comp::{ self, agent::{ AgentEvent, Sound, SoundKind, Target, TimerAction, DEFAULT_INTERACTION_TIME, TRADE_INTERACTION_TIME, }, buff::BuffKind, compass::{Direction, Distance}, dialogue::{MoodContext, MoodState, Subject}, inventory::slot::EquipSlot, invite::{InviteKind, InviteResponse}, item::{ tool::{AbilitySpec, ToolKind}, ConsumableKind, Item, ItemDesc, ItemKind, }, item_drop, projectile::ProjectileConstructor, Agent, Alignment, BehaviorState, Body, CharacterState, ControlAction, ControlEvent, Controller, Health, HealthChange, InputKind, InventoryAction, InventoryEvent, Pos, Scale, UnresolvedChatMsg, UtteranceKind, }, effect::{BuffEffect, Effect}, event::{Emitter, EventBus, ServerEvent}, path::TraversalConfig, rtsim::{Memory, MemoryItem, RtSimEvent}, states::basic_beam, terrain::{Block, TerrainGrid}, time::DayPeriod, trade::{TradeAction, TradePhase, TradeResult}, util::Dir, vol::ReadVol, }; use common_base::prof_span; use common_ecs::{Job, Origin, ParMode, Phase, System}; use rand::{thread_rng, Rng}; use rayon::iter::ParallelIterator; use specs::{ saveload::{Marker, MarkerAllocator}, Entity as EcsEntity, Join, ParJoin, Read, WriteExpect, WriteStorage, }; use vek::*; /// This system will allow NPCs to modify their controller #[derive(Default)] pub struct Sys; impl<'a> System<'a> for Sys { type SystemData = ( ReadData<'a>, Read<'a, EventBus>, WriteStorage<'a, Agent>, WriteStorage<'a, Controller>, WriteExpect<'a, RtSim>, ); const NAME: &'static str = "agent"; const ORIGIN: Origin = Origin::Server; const PHASE: Phase = Phase::Create; fn run( job: &mut Job, (read_data, event_bus, mut agents, mut controllers, mut rtsim): Self::SystemData, ) { let rtsim = &mut *rtsim; job.cpu_stats.measure(ParMode::Rayon); ( &read_data.entities, (&read_data.energies, read_data.healths.maybe()), ( &read_data.positions, &read_data.velocities, &read_data.orientations, ), read_data.bodies.maybe(), &read_data.inventories, ( &read_data.char_states, &read_data.skill_set, &read_data.active_abilities, ), &read_data.physics_states, &read_data.uids, &mut agents, &mut controllers, read_data.light_emitter.maybe(), read_data.groups.maybe(), !&read_data.is_mounts, ) .par_join() .for_each_init( || { prof_span!(guard, "agent rayon job"); guard }, |_guard, ( entity, (energy, health), (pos, vel, ori), body, inventory, (char_state, skill_set, active_abilities), physics_state, uid, agent, controller, light_emitter, group, _, )| { let mut event_emitter = event_bus.emitter(); let mut rng = thread_rng(); // Hack, replace with better system when groups are more sophisticated // Override alignment if in a group unless entity is owned already let alignment = if matches!( &read_data.alignments.get(entity), &Some(Alignment::Owned(_)) ) { read_data.alignments.get(entity).copied() } else { group .and_then(|g| read_data.group_manager.group_info(*g)) .and_then(|info| read_data.uids.get(info.leader)) .copied() .map_or_else( || read_data.alignments.get(entity).copied(), |uid| Some(Alignment::Owned(uid)), ) }; if !matches!(char_state, CharacterState::LeapMelee(_)) { // Default to looking in orientation direction // (can be overridden below) // // This definitely breaks LeapMelee and // probably not only that, do we really need this at all? controller.reset(); controller.inputs.look_dir = ori.look_dir(); } let scale = read_data.scales.get(entity).map_or(1.0, |Scale(s)| *s); let glider_equipped = inventory .equipped(EquipSlot::Glider) .as_ref() .map_or(false, |item| { matches!(&*item.kind(), comp::item::ItemKind::Glider) }); let is_gliding = matches!( read_data.char_states.get(entity), Some(CharacterState::GlideWield(_) | CharacterState::Glide(_)) ) && physics_state.on_ground.is_none(); if let Some(pid) = agent.position_pid_controller.as_mut() { pid.add_measurement(read_data.time.0, pos.0); } // This controls how picky NPCs are about their pathfinding. // Giants are larger and so can afford to be less precise // when trying to move around the world // (especially since they would otherwise get stuck on // obstacles that smaller entities would not). let node_tolerance = scale * 1.5; let slow_factor = body.map_or(0.0, |b| b.base_accel() / 250.0).min(1.0); let traversal_config = TraversalConfig { node_tolerance, slow_factor, on_ground: physics_state.on_ground.is_some(), in_liquid: physics_state.in_liquid().is_some(), min_tgt_dist: 1.0, can_climb: body.map_or(false, Body::can_climb), can_fly: body.map_or(false, |b| b.fly_thrust().is_some()), }; let health_fraction = health.map_or(1.0, Health::fraction); let rtsim_entity = read_data .rtsim_entities .get(entity) .and_then(|rtsim_ent| rtsim.get_entity(rtsim_ent.0)); if traversal_config.can_fly && matches!(body, Some(Body::Ship(_))) { // hack (kinda): Never turn off flight airships // since it results in stuttering and falling back to the ground. // // TODO: look into `controller.reset()` line above // and see if it fixes it controller.push_basic_input(InputKind::Fly); } // Package all this agent's data into a convenient struct let data = AgentData { entity: &entity, rtsim_entity, uid, pos, vel, ori, energy, body, inventory, skill_set, physics_state, alignment: alignment.as_ref(), traversal_config, scale, damage: health_fraction, light_emitter, glider_equipped, is_gliding, health: read_data.healths.get(entity), char_state, active_abilities, cached_spatial_grid: &read_data.cached_spatial_grid, msm: &read_data.msm, }; /////////////////////////////////////////////////////////// // Behavior tree /////////////////////////////////////////////////////////// // The behavior tree is meant to make decisions for agents // *but should not* mutate any data (only action nodes // should do that). Each path should lead to one (and only // one) action node. This makes bugfinding much easier and // debugging way easier. If you don't think so, try // debugging the agent code before this MR // (https://gitlab.com/veloren/veloren/-/merge_requests/1801). // Each tick should arrive at one (1) action node which // then determines what the agent does. If this makes you // uncomfortable, consider dt the response time of the // NPC. To make the tree easier to read, subtrees can be // created as methods on `AgentData`. Action nodes are // also methods on the `AgentData` struct. Action nodes // are the only parts of this tree that should provide // inputs. // Falling damage starts from 30.0 as of time of writing // But keep in mind our 25 m/s gravity let is_falling_dangerous = data.vel.0.z < -20.0; let is_on_fire = read_data .buffs .get(entity) .map_or(false, |b| b.kinds.contains_key(&BuffKind::Burning)); // If falling velocity is critical, throw everything // and save yourself! // // If can fly - fly. // If have glider - glide. // Else, rest in peace. if is_falling_dangerous && data.traversal_config.can_fly { data.fly_upward(controller) } else if is_falling_dangerous && data.glider_equipped { data.glider_fall(controller); // If on fire and able, stop, drop, and roll } else if is_on_fire && data.body.map_or(false, |b| b.is_humanoid()) && data.physics_state.on_ground.is_some() && rng.gen_bool((2.0 * read_data.dt.0).clamp(0.0, 1.0) as f64) { controller.inputs.move_dir = ori .look_vec() .xy() .try_normalized() .unwrap_or_else(Vec2::zero); controller.push_basic_input(InputKind::Roll); } else { // Target an entity that's attacking us if the attack was recent and we have // a health component match health { Some(health) if read_data.time.0 - health.last_change.time.0 < DAMAGE_MEMORY_DURATION => { if let Some(by) = health.last_change.damage_by() { if let Some(attacker) = read_data.uid_allocator.retrieve_entity_internal(by.uid().0) { // If target is dead or invulnerable (for now, this only // means safezone), untarget them and idle. if is_dead_or_invulnerable(attacker, &read_data) { agent.target = None; } else { if agent.target.is_none() { controller.push_event(ControlEvent::Utterance( UtteranceKind::Angry, )); } // Determine whether the new target should be a priority // over the old one (i.e: because it's either close or // because they attacked us). if agent.target.map_or(true, |target| { data.is_more_dangerous_than_target( attacker, target, &read_data, ) }) { agent.target = Some(Target { target: attacker, hostile: true, selected_at: read_data.time.0, aggro_on: true, }); } // Remember this attack if we're an RtSim entity if let Some(attacker_stats) = data.rtsim_entity.and(read_data.stats.get(attacker)) { agent.add_fight_to_memory( &attacker_stats.name, read_data.time.0, ); } } } } }, _ => {}, } if let Some(target_info) = agent.target { data.react_to_target( agent, controller, &read_data, &mut event_emitter, target_info, &mut rng, ); } else { data.idle_tree(agent, controller, &read_data, &mut rng); } if agent.allowed_to_speak() && data.recv_interaction( agent, controller, &read_data, &mut event_emitter, ) { agent.timer.start(read_data.time.0, TimerAction::Interact); } // Interact if incoming messages if !agent.inbox.is_empty() { if matches!( agent.inbox.front(), Some(AgentEvent::ServerSound(_)) | Some(AgentEvent::Hurt) ) { let sound = agent.inbox.pop_front(); match sound { Some(AgentEvent::ServerSound(sound)) => { agent.sounds_heard.push(sound); }, Some(AgentEvent::Hurt) => { // Hurt utterances at random upon receiving damage if rng.gen::() < 0.4 { controller.push_utterance(UtteranceKind::Hurt); } }, //Note: this should be unreachable Some(_) | None => return, } } else { agent.action_state.timer = 0.1; } } } debug_assert!(controller.inputs.move_dir.map(|e| !e.is_nan()).reduce_and()); debug_assert!(controller.inputs.look_dir.map(|e| !e.is_nan()).reduce_and()); }, ); for (agent, rtsim_entity) in (&mut agents, &read_data.rtsim_entities).join() { // Entity must be loaded in as it has an agent component :) // React to all events in the controller for event in core::mem::take(&mut agent.rtsim_controller.events) { match event { RtSimEvent::AddMemory(memory) => { rtsim.insert_entity_memory(rtsim_entity.0, memory.clone()); }, RtSimEvent::ForgetEnemy(name) => { rtsim.forget_entity_enemy(rtsim_entity.0, &name); }, RtSimEvent::SetMood(memory) => { rtsim.set_entity_mood(rtsim_entity.0, memory.clone()); }, RtSimEvent::PrintMemories => {}, } } } } } impl<'a> AgentData<'a> { //////////////////////////////////////// // Subtrees //////////////////////////////////////// fn react_to_target( &self, agent: &mut Agent, controller: &mut Controller, read_data: &ReadData, event_emitter: &mut Emitter<'_, ServerEvent>, target_info: Target, rng: &mut impl Rng, ) { let Target { target, hostile, .. } = target_info; if let Some(tgt_health) = read_data.healths.get(target) { // If target is dead, forget them if tgt_health.is_dead { if let Some(tgt_stats) = self.rtsim_entity.and(read_data.stats.get(target)) { agent.forget_enemy(&tgt_stats.name); } agent.target = None; // Else, if target is hostile, hostile tree } else if hostile { self.cancel_interaction(agent, controller, event_emitter); self.hostile_tree(agent, controller, read_data, event_emitter, rng); // Else, if owned, act as pet to them } else if let Some(Alignment::Owned(uid)) = self.alignment { if read_data.uids.get(target) == Some(uid) { self.react_as_pet(agent, controller, read_data, target, rng); } else { agent.target = None; self.idle_tree(agent, controller, read_data, rng); }; } else { self.idle_tree(agent, controller, read_data, rng); } } else if matches!(read_data.bodies.get(target), Some(Body::ItemDrop(_))) { if let Some(tgt_pos) = read_data.positions.get(target) { let dist_sqrd = self.pos.0.distance_squared(tgt_pos.0); if dist_sqrd < NPC_PICKUP_RANGE.powi(2) { if let Some(uid) = read_data.uids.get(target) { controller .push_event(ControlEvent::InventoryEvent(InventoryEvent::Pickup(*uid))); } } else if let Some((bearing, speed)) = agent.chaser.chase( &*read_data.terrain, self.pos.0, self.vel.0, tgt_pos.0, TraversalConfig { min_tgt_dist: NPC_PICKUP_RANGE - 1.0, ..self.traversal_config }, ) { controller.inputs.move_dir = bearing.xy().try_normalized().unwrap_or_else(Vec2::zero) * speed.min(0.2 + (dist_sqrd - (NPC_PICKUP_RANGE - 1.5).powi(2)) / 8.0); self.jump_if(bearing.z > 1.5, controller); controller.inputs.move_z = bearing.z; } } } else { agent.target = None; self.idle_tree(agent, controller, read_data, rng); } } fn react_as_pet( &self, agent: &mut Agent, controller: &mut Controller, read_data: &ReadData, target: EcsEntity, rng: &mut impl Rng, ) { if let Some(tgt_pos) = read_data.positions.get(target) { let dist_sqrd = self.pos.0.distance_squared(tgt_pos.0); let owner_recently_attacked = if let Some(target_health) = read_data.healths.get(target) { read_data.time.0 - target_health.last_change.time.0 < 5.0 && target_health.last_change.amount < 0.0 } else { false }; // If too far away, then follow if dist_sqrd > (MAX_FOLLOW_DIST).powi(2) { self.follow(agent, controller, &read_data.terrain, tgt_pos); // Else, attack target's attacker (if there is one) // Target is the owner in this case } else if owner_recently_attacked { self.attack_target_attacker(agent, read_data, controller, rng); // Otherwise, just idle } else { self.idle_tree(agent, controller, read_data, rng); } } } fn idle_tree( &self, agent: &mut Agent, controller: &mut Controller, read_data: &ReadData, rng: &mut impl Rng, ) { // TODO: Awareness currently doesn't influence anything. //agent.decrement_awareness(read_data.dt.0); let small_chance = rng.gen_bool(0.1); // Set owner if no target if agent.target.is_none() && small_chance { if let Some(Alignment::Owned(owner)) = self.alignment { if let Some(owner) = get_entity_by_id(owner.id(), read_data) { agent.target = Some(Target::new(owner, false, read_data.time.0, false)); } } } let timeout = if agent.behavior.is(BehaviorState::TRADING) { TRADE_INTERACTION_TIME } else { DEFAULT_INTERACTION_TIME }; match agent .timer .timeout_elapsed(read_data.time.0, TimerAction::Interact, timeout as f64) { None => { // Look toward the interacting entity for a while if let Some(Target { target, .. }) = &agent.target { self.look_toward(controller, read_data, *target); controller.push_action(ControlAction::Talk); } }, Some(just_ended) => { if just_ended { agent.target = None; controller.push_action(ControlAction::Stand); } if rng.gen::() < 0.1 { self.choose_target(agent, controller, read_data); } else { self.handle_sounds_heard(agent, controller, read_data, rng); } }, } } fn hostile_tree( &self, agent: &mut Agent, controller: &mut Controller, read_data: &ReadData, event_emitter: &mut Emitter<'_, ServerEvent>, rng: &mut impl Rng, ) { if self.damage < HEALING_ITEM_THRESHOLD && self.heal_self(agent, controller, false) { agent.action_state.timer = 0.01; return; } if matches!(agent.inbox.front(), Some(AgentEvent::Hurt)) { // Hurt utterances at random upon receiving damage if rng.gen::() < 0.4 { controller.push_utterance(UtteranceKind::Hurt); } agent.inbox.pop_front(); } if let Some(Target { target, selected_at, aggro_on, .. }) = &mut agent.target { let target = *target; let selected_at = *selected_at; if let Some(tgt_pos) = read_data.positions.get(target) { let dist_sqrd = self.pos.0.distance_squared(tgt_pos.0); let origin_dist_sqrd = match agent.patrol_origin { Some(pos) => pos.distance_squared(self.pos.0), None => 1.0, }; let own_health_fraction = match self.health { Some(val) => val.fraction(), None => 1.0, }; let target_health_fraction = match read_data.healths.get(target) { Some(val) => val.fraction(), None => 1.0, }; let in_aggro_range = agent .psyche .aggro_dist .map_or(true, |ad| dist_sqrd < ad.powi(2)); if in_aggro_range { *aggro_on = true; } let aggro_on = *aggro_on; if self.below_flee_health(agent) { let has_opportunity_to_flee = agent.action_state.timer < FLEE_DURATION; let within_flee_distance = dist_sqrd < MAX_FLEE_DIST.powi(2); // FIXME: Using action state timer to see if allowed to speak is a hack. if agent.action_state.timer == 0.0 { self.cry_out(agent, event_emitter, read_data); agent.action_state.timer = 0.01; } else if within_flee_distance && has_opportunity_to_flee { self.flee(agent, controller, tgt_pos, &read_data.terrain); agent.action_state.timer += read_data.dt.0; } else { agent.action_state.timer = 0.0; agent.target = None; self.idle(agent, controller, read_data, rng); } } else if is_dead(target, read_data) { self.exclaim_relief_about_enemy_dead(agent, event_emitter); agent.target = None; self.idle(agent, controller, read_data, rng); } else if is_invulnerable(target, read_data) || stop_pursuing( dist_sqrd, origin_dist_sqrd, own_health_fraction, target_health_fraction, read_data.time.0 - selected_at, &agent.psyche, ) { agent.target = None; self.idle(agent, controller, read_data, rng); } else { let is_time_to_retarget = read_data.time.0 - selected_at > RETARGETING_THRESHOLD_SECONDS; if !in_aggro_range && is_time_to_retarget { self.choose_target(agent, controller, read_data); } if aggro_on { let target_data = TargetData::new( tgt_pos, read_data.bodies.get(target), read_data.scales.get(target), ); let tgt_name = read_data.stats.get(target).map(|stats| stats.name.clone()); tgt_name .map(|tgt_name| agent.add_fight_to_memory(&tgt_name, read_data.time.0)); self.attack(agent, controller, &target_data, read_data, rng); } else { self.menacing(agent, controller, target, read_data, event_emitter, rng); } } } } } //////////////////////////////////////// // Action Nodes //////////////////////////////////////// fn glider_fall(&self, controller: &mut Controller) { controller.push_action(ControlAction::GlideWield); let flight_direction = Vec3::from(self.vel.0.xy().try_normalized().unwrap_or_else(Vec2::zero)); let flight_ori = Quaternion::from_scalar_and_vec3((1.0, flight_direction)); let ori = self.ori.look_vec(); let look_dir = if ori.z > 0.0 { flight_ori.rotated_x(-0.1) } else { flight_ori.rotated_x(0.1) }; let (_, look_dir) = look_dir.into_scalar_and_vec3(); controller.inputs.look_dir = Dir::from_unnormalized(look_dir).unwrap_or_else(Dir::forward); } fn fly_upward(&self, controller: &mut Controller) { controller.push_basic_input(InputKind::Fly); controller.inputs.move_z = 1.0; } fn idle( &self, agent: &mut Agent, controller: &mut Controller, read_data: &ReadData, rng: &mut impl Rng, ) { // Light lanterns at night // TODO Add a method to turn on NPC lanterns underground let lantern_equipped = self .inventory .equipped(EquipSlot::Lantern) .as_ref() .map_or(false, |item| { matches!(&*item.kind(), comp::item::ItemKind::Lantern(_)) }); let lantern_turned_on = self.light_emitter.is_some(); let day_period = DayPeriod::from(read_data.time_of_day.0); // Only emit event for agents that have a lantern equipped if lantern_equipped && rng.gen_bool(0.001) { if day_period.is_dark() && !lantern_turned_on { // Agents with turned off lanterns turn them on randomly once it's // nighttime and keep them on. // Only emit event for agents that sill need to // turn on their lantern. controller.push_event(ControlEvent::EnableLantern) } else if lantern_turned_on && day_period.is_light() { // agents with turned on lanterns turn them off randomly once it's // daytime and keep them off. controller.push_event(ControlEvent::DisableLantern) } }; if let Some(body) = self.body { let attempt_heal = if matches!(body, Body::Humanoid(_)) { self.damage < IDLE_HEALING_ITEM_THRESHOLD } else { true }; if attempt_heal && self.heal_self(agent, controller, true) { agent.action_state.timer = 0.01; return; } } else { agent.action_state.timer = 0.01; return; } agent.action_state.timer = 0.0; if let Some((travel_to, _destination)) = &agent.rtsim_controller.travel_to { // If it has an rtsim destination and can fly, then it should. // If it is flying and bumps something above it, then it should move down. if self.traversal_config.can_fly && !read_data .terrain .ray(self.pos.0, self.pos.0 + (Vec3::unit_z() * 3.0)) .until(Block::is_solid) .cast() .1 .map_or(true, |b| b.is_some()) { controller.push_basic_input(InputKind::Fly); } else { controller.push_cancel_input(InputKind::Fly) } if let Some((bearing, speed)) = agent.chaser.chase( &*read_data.terrain, self.pos.0, self.vel.0, *travel_to, TraversalConfig { min_tgt_dist: 1.25, ..self.traversal_config }, ) { controller.inputs.move_dir = bearing.xy().try_normalized().unwrap_or_else(Vec2::zero) * speed.min(agent.rtsim_controller.speed_factor); self.jump_if(bearing.z > 1.5 || self.traversal_config.can_fly, controller); controller.inputs.climb = Some(comp::Climb::Up); //.filter(|_| bearing.z > 0.1 || self.physics_state.in_liquid().is_some()); let height_offset = bearing.z + if self.traversal_config.can_fly { // NOTE: costs 4 us (imbris) let obstacle_ahead = read_data .terrain .ray( self.pos.0 + Vec3::unit_z(), self.pos.0 + bearing.try_normalized().unwrap_or_else(Vec3::unit_y) * 80.0 + Vec3::unit_z(), ) .until(Block::is_solid) .cast() .1 .map_or(true, |b| b.is_some()); let mut ground_too_close = self .body .map(|body| { #[cfg(feature = "worldgen")] let height_approx = self.pos.0.z - read_data .world .sim() .get_alt_approx(self.pos.0.xy().map(|x: f32| x as i32)) .unwrap_or(0.0); #[cfg(not(feature = "worldgen"))] let height_approx = self.pos.0.z; height_approx < body.flying_height() }) .unwrap_or(false); const NUM_RAYS: usize = 5; // NOTE: costs 15-20 us (imbris) for i in 0..=NUM_RAYS { let magnitude = self.body.map_or(20.0, |b| b.flying_height()); // Lerp between a line straight ahead and straight down to detect a // wedge of obstacles we might fly into (inclusive so that both vectors // are sampled) if let Some(dir) = Lerp::lerp( -Vec3::unit_z(), Vec3::new(bearing.x, bearing.y, 0.0), i as f32 / NUM_RAYS as f32, ) .try_normalized() { ground_too_close |= read_data .terrain .ray(self.pos.0, self.pos.0 + magnitude * dir) .until(|b: &Block| b.is_solid() || b.is_liquid()) .cast() .1 .map_or(false, |b| b.is_some()) } } if obstacle_ahead || ground_too_close { 5.0 //fly up when approaching obstacles } else { -2.0 } //flying things should slowly come down from the stratosphere } else { 0.05 //normal land traveller offset }; if let Some(pid) = agent.position_pid_controller.as_mut() { pid.sp = self.pos.0.z + height_offset * Vec3::unit_z(); controller.inputs.move_z = pid.calc_err(); } else { controller.inputs.move_z = height_offset; } // Put away weapon if rng.gen_bool(0.1) && matches!( read_data.char_states.get(*self.entity), Some(CharacterState::Wielding(_)) ) { controller.push_action(ControlAction::Unwield); } } } else { agent.bearing += Vec2::new(rng.gen::() - 0.5, rng.gen::() - 0.5) * 0.1 - agent.bearing * 0.003 - agent.patrol_origin.map_or(Vec2::zero(), |patrol_origin| { (self.pos.0 - patrol_origin).xy() * 0.0002 }); // Stop if we're too close to a wall // or about to walk off a cliff // NOTE: costs 1 us (imbris) <- before cliff raycast added agent.bearing *= 0.1 + if read_data .terrain .ray( self.pos.0 + Vec3::unit_z(), self.pos.0 + Vec3::from(agent.bearing) .try_normalized() .unwrap_or_else(Vec3::unit_y) * 5.0 + Vec3::unit_z(), ) .until(Block::is_solid) .cast() .1 .map_or(true, |b| b.is_none()) && read_data .terrain .ray( self.pos.0 + Vec3::from(agent.bearing) .try_normalized() .unwrap_or_else(Vec3::unit_y), self.pos.0 + Vec3::from(agent.bearing) .try_normalized() .unwrap_or_else(Vec3::unit_y) - Vec3::unit_z() * 4.0, ) .until(Block::is_solid) .cast() .0 < 3.0 { 0.9 } else { 0.0 }; if agent.bearing.magnitude_squared() > 0.5f32.powi(2) { controller.inputs.move_dir = agent.bearing * 0.65; } // Put away weapon if rng.gen_bool(0.1) && matches!( read_data.char_states.get(*self.entity), Some(CharacterState::Wielding(_)) ) { controller.push_action(ControlAction::Unwield); } if rng.gen::() < 0.0015 { controller.push_utterance(UtteranceKind::Calm); } // Sit if rng.gen::() < 0.0035 { controller.push_action(ControlAction::Sit); } } } pub fn follow( &self, agent: &mut Agent, controller: &mut Controller, terrain: &TerrainGrid, tgt_pos: &Pos, ) { if let Some((bearing, speed)) = agent.chaser.chase( &*terrain, self.pos.0, self.vel.0, tgt_pos.0, TraversalConfig { min_tgt_dist: AVG_FOLLOW_DIST, ..self.traversal_config }, ) { let dist_sqrd = self.pos.0.distance_squared(tgt_pos.0); controller.inputs.move_dir = bearing.xy().try_normalized().unwrap_or_else(Vec2::zero) * speed.min(0.2 + (dist_sqrd - AVG_FOLLOW_DIST.powi(2)) / 8.0); self.jump_if(bearing.z > 1.5, controller); controller.inputs.move_z = bearing.z; } } /// deny any interaction whenever possible fn cancel_interaction( &self, agent: &mut Agent, controller: &mut Controller, event_emitter: &mut Emitter<'_, ServerEvent>, ) -> bool { if let Some(msg) = agent.inbox.front() { let used = match msg { AgentEvent::Talk(..) | AgentEvent::TradeAccepted(_) => { self.chat_npc_if_allowed_to_speak( "npc-speech-villager_busy", agent, event_emitter, ); true }, AgentEvent::TradeInvite(_) => { controller.push_invite_response(InviteResponse::Decline); if agent.behavior.can_trade() { self.chat_npc_if_allowed_to_speak( "npc-speech-merchant_busy", agent, event_emitter, ); } else { self.chat_npc_if_allowed_to_speak( "npc-speech-villager_busy", agent, event_emitter, ); } true }, AgentEvent::FinishedTrade(result) => { // copy pasted from recv_interaction // because the trade is not cancellable in this state if agent.behavior.is(BehaviorState::TRADING) { match result { TradeResult::Completed => { self.chat_npc( "npc-speech-merchant_trade_successful", event_emitter, ); }, _ => { self.chat_npc("npc-speech-merchant_trade_declined", event_emitter); }, } agent.behavior.unset(BehaviorState::TRADING); } true }, AgentEvent::UpdatePendingTrade(boxval) => { // immediately cancel the trade let (tradeid, _pending, _prices, _inventories) = &**boxval; agent.behavior.unset(BehaviorState::TRADING); event_emitter.emit(ServerEvent::ProcessTradeAction( *self.entity, *tradeid, TradeAction::Decline, )); self.chat_npc("npc-speech-merchant_trade_cancelled_hostile", event_emitter); true }, AgentEvent::ServerSound(_) | AgentEvent::Hurt => false, }; if used { agent.inbox.pop_front(); } return used; } false } fn recv_interaction( &self, agent: &mut Agent, controller: &mut Controller, read_data: &ReadData, event_emitter: &mut Emitter<'_, ServerEvent>, ) -> bool { // TODO: Process group invites // TODO: Add Group AgentEvent // let accept = false; // set back to "matches!(alignment, Alignment::Npc)" // when we got better NPC recruitment mechanics if accept { // // Clear agent comp // //*agent = Agent::default(); // controller // .push_event(ControlEvent::InviteResponse(InviteResponse::Accept)); // } else { // controller // .push_event(ControlEvent::InviteResponse(InviteResponse::Decline)); // } agent.action_state.timer += read_data.dt.0; let msg = agent.inbox.front(); let used = match msg { Some(AgentEvent::Talk(by, subject)) => { if agent.allowed_to_speak() { if let Some(target) = get_entity_by_id(by.id(), read_data) { agent.target = Some(Target::new(target, false, read_data.time.0, false)); if self.look_toward(controller, read_data, target) { controller.push_action(ControlAction::Stand); controller.push_action(ControlAction::Talk); controller.push_utterance(UtteranceKind::Greeting); match subject { Subject::Regular => { if let ( Some((_travel_to, destination_name)), Some(rtsim_entity), ) = (&agent.rtsim_controller.travel_to, &self.rtsim_entity) { let personality = &rtsim_entity.brain.personality; let standard_response_msg = || -> String { if personality .personality_traits .contains(PersonalityTrait::Extroverted) { format!( "I'm heading to {}! Want to come along?", destination_name ) } else if personality .personality_traits .contains(PersonalityTrait::Disagreeable) { "Hrm.".to_string() } else { "Hello!".to_string() } }; let msg = if let Some(tgt_stats) = read_data.stats.get(target) { agent.rtsim_controller.events.push( RtSimEvent::AddMemory(Memory { item: MemoryItem::CharacterInteraction { name: tgt_stats.name.clone(), }, time_to_forget: read_data.time.0 + 600.0, }), ); if rtsim_entity .brain .remembers_character(&tgt_stats.name) { if personality .personality_traits .contains(PersonalityTrait::Extroverted) { format!( "Greetings fair {}! It has been far \ too long since last I saw you. I'm \ going to {} right now.", &tgt_stats.name, destination_name ) } else if personality .personality_traits .contains(PersonalityTrait::Disagreeable) { "Oh. It's you again.".to_string() } else { format!( "Hi again {}! Unfortunately I'm in a \ hurry right now. See you!", &tgt_stats.name ) } } else { standard_response_msg() } } else { standard_response_msg() }; self.chat_npc(msg, event_emitter); } else if agent.behavior.can_trade() { if !agent.behavior.is(BehaviorState::TRADING) { controller.push_initiate_invite(*by, InviteKind::Trade); self.chat_npc( "npc-speech-merchant_advertisement", event_emitter, ); } else { let default_msg = "npc-speech-merchant_busy"; let msg = self.rtsim_entity.map_or(default_msg, |e| { if e.brain .personality .personality_traits .contains(PersonalityTrait::Disagreeable) { "npc-speech-merchant_busy_rude" } else { default_msg } }); self.chat_npc(msg, event_emitter); } } else { let mut rng = thread_rng(); if let Some(extreme_trait) = self.rtsim_entity.and_then(|e| { e.brain.personality.random_chat_trait(&mut rng) }) { let msg = match extreme_trait { PersonalityTrait::Open => { "npc-speech-villager_open" }, PersonalityTrait::Adventurous => { "npc-speech-villager_adventurous" }, PersonalityTrait::Closed => { "npc-speech-villager_closed" }, PersonalityTrait::Conscientious => { "npc-speech-villager_conscientious" }, PersonalityTrait::Busybody => { "npc-speech-villager_busybody" }, PersonalityTrait::Unconscientious => { "npc-speech-villager_unconscientious" }, PersonalityTrait::Extroverted => { "npc-speech-villager_extroverted" }, PersonalityTrait::Introverted => { "npc-speech-villager_introverted" }, PersonalityTrait::Agreeable => { "npc-speech-villager_agreeable" }, PersonalityTrait::Sociable => { "npc-speech-villager_sociable" }, PersonalityTrait::Disagreeable => { "npc-speech-villager_disagreeable" }, PersonalityTrait::Neurotic => { "npc-speech-villager_neurotic" }, PersonalityTrait::Seeker => { "npc-speech-villager_seeker" }, PersonalityTrait::SadLoner => { "npc-speech-villager_sad_loner" }, PersonalityTrait::Worried => { "npc-speech-villager_worried" }, PersonalityTrait::Stable => { "npc-speech-villager_stable" }, }; self.chat_npc(msg, event_emitter); } else { self.chat_npc("npc-speech-villager", event_emitter); } } }, Subject::Trade => { if agent.behavior.can_trade() { if !agent.behavior.is(BehaviorState::TRADING) { controller.push_initiate_invite(*by, InviteKind::Trade); self.chat_npc( "npc-speech-merchant_advertisement", event_emitter, ); } else { self.chat_npc( "npc-speech-merchant_busy", event_emitter, ); } } else { // TODO: maybe make some travellers willing to trade with // simpler goods like potions self.chat_npc( "npc-speech-villager_decline_trade", event_emitter, ); } }, Subject::Mood => { if let Some(rtsim_entity) = self.rtsim_entity { if !rtsim_entity.brain.remembers_mood() { // TODO: the following code will need a rework to // implement more mood contexts // This require that town NPCs becomes rtsim_entities to // work fully. match rand::random::() % 3 { 0 => agent.rtsim_controller.events.push( RtSimEvent::SetMood(Memory { item: MemoryItem::Mood { state: MoodState::Good( MoodContext::GoodWeather, ), }, time_to_forget: read_data.time.0 + 21200.0, }), ), 1 => agent.rtsim_controller.events.push( RtSimEvent::SetMood(Memory { item: MemoryItem::Mood { state: MoodState::Neutral( MoodContext::EverydayLife, ), }, time_to_forget: read_data.time.0 + 21200.0, }), ), 2 => agent.rtsim_controller.events.push( RtSimEvent::SetMood(Memory { item: MemoryItem::Mood { state: MoodState::Bad( MoodContext::GoodWeather, ), }, time_to_forget: read_data.time.0 + 86400.0, }), ), _ => {}, // will never happen } } if let Some(memory) = rtsim_entity.brain.get_mood() { let msg = match &memory.item { MemoryItem::Mood { state } => state.describe(), _ => "".to_string(), }; self.chat_npc(msg, event_emitter); } } }, Subject::Location(location) => { if let Some(tgt_pos) = read_data.positions.get(target) { let raw_dir = location.origin.as_::() - tgt_pos.0.xy(); let dist = Distance::from_dir(raw_dir).name(); let dir = Direction::from_dir(raw_dir).name(); let msg = format!( "{} ? I think it's {} {} from here!", location.name, dist, dir ); self.chat_npc(msg, event_emitter); } }, Subject::Person(person) => { if let Some(src_pos) = read_data.positions.get(target) { let msg = if let Some(person_pos) = person.origin { let distance = Distance::from_dir( person_pos.xy() - src_pos.0.xy(), ); match distance { Distance::NextTo | Distance::Near => { format!( "{} ? I think he's {} {} from here!", person.name(), distance.name(), Direction::from_dir( person_pos.xy() - src_pos.0.xy(), ) .name() ) }, _ => { format!( "{} ? I think he's gone visiting another \ town. Come back later!", person.name() ) }, } } else { format!( "{} ? Sorry, I don't know where you can find him.", person.name() ) }; self.chat_npc(msg, event_emitter); } }, Subject::Work => {}, } } } } true }, Some(AgentEvent::TradeInvite(with)) => { if agent.behavior.can_trade() { if !agent.behavior.is(BehaviorState::TRADING) { // stand still and looking towards the trading player controller.push_action(ControlAction::Stand); controller.push_action(ControlAction::Talk); if let Some(target) = get_entity_by_id(with.id(), read_data) { agent.target = Some(Target::new(target, false, read_data.time.0, false)); } controller.push_invite_response(InviteResponse::Accept); agent.behavior.unset(BehaviorState::TRADING_ISSUER); agent.behavior.set(BehaviorState::TRADING); } else { controller.push_invite_response(InviteResponse::Decline); self.chat_npc_if_allowed_to_speak( "npc-speech-merchant_busy", agent, event_emitter, ); } } else { // TODO: Provide a hint where to find the closest merchant? controller.push_invite_response(InviteResponse::Decline); self.chat_npc_if_allowed_to_speak( "npc-speech-villager_decline_trade", agent, event_emitter, ); } true }, Some(AgentEvent::TradeAccepted(with)) => { if !agent.behavior.is(BehaviorState::TRADING) { if let Some(target) = get_entity_by_id(with.id(), read_data) { agent.target = Some(Target::new(target, false, read_data.time.0, false)); } agent.behavior.set(BehaviorState::TRADING); agent.behavior.set(BehaviorState::TRADING_ISSUER); } true }, Some(AgentEvent::FinishedTrade(result)) => { if agent.behavior.is(BehaviorState::TRADING) { match result { TradeResult::Completed => { self.chat_npc("npc-speech-merchant_trade_successful", event_emitter); }, _ => { self.chat_npc("npc-speech-merchant_trade_declined", event_emitter); }, } agent.behavior.unset(BehaviorState::TRADING); } true }, Some(AgentEvent::UpdatePendingTrade(boxval)) => { let (tradeid, pending, prices, inventories) = &**boxval; if agent.behavior.is(BehaviorState::TRADING) { let who: usize = if agent.behavior.is(BehaviorState::TRADING_ISSUER) { 0 } else { 1 }; let balance0: f32 = prices.balance(&pending.offers, inventories, 1 - who, true); let balance1: f32 = prices.balance(&pending.offers, inventories, who, false); if balance0 >= balance1 { // If the trade is favourable to us, only send an accept message if we're // not already accepting (since otherwise, spam-clicking the accept button // results in lagging and moving to the review phase of an unfavorable trade // (although since the phase is included in the message, this shouldn't // result in fully accepting an unfavourable trade)) if !pending.accept_flags[who] && !pending.is_empty_trade() { event_emitter.emit(ServerEvent::ProcessTradeAction( *self.entity, *tradeid, TradeAction::Accept(pending.phase), )); tracing::trace!(?tradeid, ?balance0, ?balance1, "Accept Pending Trade"); } } else { if balance1 > 0.0 { let msg = format!( "That only covers {:.0}% of my costs!", (balance0 / balance1 * 100.0).floor() ); if let Some(tgt_data) = &agent.target { // If talking with someone in particular, "tell" it only to them if let Some(with) = read_data.uids.get(tgt_data.target) { event_emitter.emit(ServerEvent::Chat( UnresolvedChatMsg::npc_tell(*self.uid, *with, msg), )); } else { event_emitter.emit(ServerEvent::Chat( UnresolvedChatMsg::npc_say(*self.uid, msg), )); } } else { event_emitter.emit(ServerEvent::Chat(UnresolvedChatMsg::npc_say( *self.uid, msg, ))); } } if pending.phase != TradePhase::Mutate { // we got into the review phase but without balanced goods, decline agent.behavior.unset(BehaviorState::TRADING); event_emitter.emit(ServerEvent::ProcessTradeAction( *self.entity, *tradeid, TradeAction::Decline, )); } } } true }, Some(AgentEvent::ServerSound(_)) => false, Some(AgentEvent::Hurt) => false, None => false, }; if used { agent.inbox.pop_front(); } used } fn look_toward( &self, controller: &mut Controller, read_data: &ReadData, target: EcsEntity, ) -> bool { if let Some(tgt_pos) = read_data.positions.get(target) { let eye_offset = self.body.map_or(0.0, |b| b.eye_height()); let tgt_eye_offset = read_data.bodies.get(target).map_or(0.0, |b| b.eye_height()); if let Some(dir) = Dir::from_unnormalized( Vec3::new(tgt_pos.0.x, tgt_pos.0.y, tgt_pos.0.z + tgt_eye_offset) - Vec3::new(self.pos.0.x, self.pos.0.y, self.pos.0.z + eye_offset), ) { controller.inputs.look_dir = dir; } true } else { false } } fn menacing( &self, agent: &mut Agent, controller: &mut Controller, target: EcsEntity, read_data: &ReadData, event_emitter: &mut Emitter, rng: &mut impl Rng, ) { let max_move = 0.5; let move_dir = controller.inputs.move_dir; let move_dir_mag = move_dir.magnitude(); let small_chance = rng.gen::() < read_data.dt.0 * 0.25; let mut chat = |msg: &str| { self.chat_npc_if_allowed_to_speak(msg.to_string(), agent, event_emitter); }; let mut chat_villager_remembers_fighting = || { let tgt_name = read_data.stats.get(target).map(|stats| stats.name.clone()); if let Some(tgt_name) = tgt_name { chat(format!("{}! How dare you cross me again!", &tgt_name).as_str()); } else { chat("You! How dare you cross me again!"); } }; self.look_toward(controller, read_data, target); controller.push_action(ControlAction::Wield); if move_dir_mag > max_move { controller.inputs.move_dir = max_move * move_dir / move_dir_mag; } if small_chance { controller.push_utterance(UtteranceKind::Angry); if is_villager(self.alignment) { if self.remembers_fight_with(target, read_data) { chat_villager_remembers_fighting(); } else if is_dressed_as_cultist(target, read_data) { chat("npc-speech-villager_cultist_alarm"); } else { chat("npc-speech-menacing"); } } else { chat("npc-speech-menacing"); } } // Remember target. self.rtsim_entity.is_some().then(|| { read_data .stats .get(target) .map(|stats| agent.add_fight_to_memory(&stats.name, read_data.time.0)) }); } fn flee( &self, agent: &mut Agent, controller: &mut Controller, tgt_pos: &Pos, terrain: &TerrainGrid, ) { if let Some(body) = self.body { if body.can_strafe() && !self.is_gliding { controller.push_action(ControlAction::Unwield); } } if let Some((bearing, speed)) = agent.chaser.chase( &*terrain, self.pos.0, self.vel.0, // Away from the target (ironically) self.pos.0 + (self.pos.0 - tgt_pos.0) .try_normalized() .unwrap_or_else(Vec3::unit_y) * 50.0, TraversalConfig { min_tgt_dist: 1.25, ..self.traversal_config }, ) { controller.inputs.move_dir = bearing.xy().try_normalized().unwrap_or_else(Vec2::zero) * speed; self.jump_if(bearing.z > 1.5, controller); controller.inputs.move_z = bearing.z; } } /// Attempt to consume a healing item, and return whether any healing items /// were queued. Callers should use this to implement a delay so that /// the healing isn't interrupted. If `relaxed` is `true`, we allow eating /// food and prioritise healing. fn heal_self(&self, _agent: &mut Agent, controller: &mut Controller, relaxed: bool) -> bool { let healing_value = |item: &Item| { let mut value = 0.0; if let ItemKind::Consumable { kind, effects, .. } = &*item.kind() { if matches!(kind, ConsumableKind::Drink) || (relaxed && matches!(kind, ConsumableKind::Food)) { for effect in effects.iter() { use BuffKind::*; match effect { Effect::Health(HealthChange { amount, .. }) => { value += *amount; }, Effect::Buff(BuffEffect { kind, data, .. }) if matches!(kind, Regeneration | Saturation | Potion) => { value += data.strength * data.duration.map_or(0.0, |d| d.as_secs() as f32); }, _ => {}, } } } } value as i32 }; let item = self .inventory .slots_with_id() .filter_map(|(id, slot)| match slot { Some(item) if healing_value(item) > 0 => Some((id, item)), _ => None, }) .max_by_key(|(_, item)| { if relaxed { -healing_value(item) } else { healing_value(item) } }); if let Some((id, _)) = item { use comp::inventory::slot::Slot; controller.push_action(ControlAction::InventoryAction(InventoryAction::Use( Slot::Inventory(id), ))); true } else { false } } fn choose_target(&self, agent: &mut Agent, controller: &mut Controller, read_data: &ReadData) { agent.action_state.timer = 0.0; let mut aggro_on = false; let get_pos = |entity| read_data.positions.get(entity); let get_enemy = |(entity, attack_target): (EcsEntity, bool)| { if attack_target { if self.is_enemy(entity, read_data) { Some((entity, true)) } else if self.should_defend(entity, read_data) { if let Some(attacker) = get_attacker(entity, read_data) { if !self.passive_towards(attacker, read_data) { // aggro_on: attack immediately, do not warn/menace. aggro_on = true; Some((attacker, true)) } else { None } } else { None } } else { None } } else { Some((entity, false)) } }; let is_valid_target = |entity: EcsEntity| match read_data.bodies.get(entity) { Some(Body::ItemDrop(item)) => { //If the agent is humanoid, it will pick up all kinds of item drops. If the // agent isn't humanoid, it will pick up only consumable item drops. let wants_pickup = matches!(self.body, Some(Body::Humanoid(_))) || matches!(item, item_drop::Body::Consumable); // The agent will attempt to pickup the item if it wants to pick it up and is // allowed to let attempt_pickup = wants_pickup && read_data .loot_owners .get(entity) .map_or(true, |loot_owner| { loot_owner.can_pickup( *self.uid, read_data.groups.get(entity), self.alignment, self.body, None, ) }); if attempt_pickup { Some((entity, false)) } else { None } }, _ => { if read_data.healths.get(entity).map_or(false, |health| { !health.is_dead && !is_invulnerable(entity, read_data) }) { Some((entity, true)) } else { None } }, }; let can_sense_directly_near = { |e_pos: &Pos| e_pos.0.distance_squared(self.pos.0) < 5_f32.powi(2) }; let is_detected = |entity: EcsEntity, e_pos: &Pos| { let chance = thread_rng().gen_bool(0.3); (can_sense_directly_near(e_pos) && chance) || self.can_see_entity(agent, controller, entity, e_pos, read_data) }; // Search the area. // TODO: choose target by more than just distance let common::CachedSpatialGrid(grid) = self.cached_spatial_grid; let target = grid .in_circle_aabr(self.pos.0.xy(), agent.psyche.search_dist()) .filter_map(is_valid_target) .filter_map(get_enemy) .filter_map(|(entity, attack_target)| { get_pos(entity).map(|pos| (entity, pos, attack_target)) }) .filter(|(entity, e_pos, _)| is_detected(*entity, e_pos)) .min_by_key(|(_, e_pos, attack_target)| { ( *attack_target, (e_pos.0.distance_squared(self.pos.0) * 100.0) as i32, ) }) .map(|(entity, _, attack_target)| (entity, attack_target)); if agent.target.is_none() && target.is_some() { if aggro_on { controller.push_utterance(UtteranceKind::Angry); } else { controller.push_utterance(UtteranceKind::Surprised); } } agent.target = target.map(|(entity, attack_target)| Target { target: entity, hostile: attack_target, selected_at: read_data.time.0, aggro_on, }) } fn attack( &self, agent: &mut Agent, controller: &mut Controller, tgt_data: &TargetData, read_data: &ReadData, rng: &mut impl Rng, ) { let tool_tactic = |tool_kind| match tool_kind { ToolKind::Bow => Tactic::Bow, ToolKind::Staff => Tactic::Staff, ToolKind::Sceptre => Tactic::Sceptre, ToolKind::Hammer => Tactic::Hammer, ToolKind::Sword | ToolKind::Blowgun => Tactic::Sword, ToolKind::Axe => Tactic::Axe, _ => Tactic::SimpleMelee, }; let tactic = self .inventory .equipped(EquipSlot::ActiveMainhand) .as_ref() .map(|item| { if let Some(ability_spec) = item.ability_spec() { match &*ability_spec { AbilitySpec::Custom(spec) => match spec.as_str() { "Oni" | "Sword Simple" => Tactic::Sword, "Staff Simple" => Tactic::Staff, "Bow Simple" => Tactic::Bow, "Stone Golem" => Tactic::StoneGolem, "Quad Med Quick" => Tactic::CircleCharge { radius: 3, circle_time: 2, }, "Quad Med Jump" => Tactic::QuadMedJump, "Quad Med Charge" => Tactic::CircleCharge { radius: 6, circle_time: 1, }, "Quad Med Basic" => Tactic::QuadMedBasic, "Asp" | "Maneater" => Tactic::QuadLowRanged, "Quad Low Breathe" | "Quad Low Beam" | "Basilisk" => { Tactic::QuadLowBeam }, "Quad Low Tail" | "Husk Brute" => Tactic::TailSlap, "Quad Low Quick" => Tactic::QuadLowQuick, "Quad Low Basic" => Tactic::QuadLowBasic, "Theropod Basic" | "Theropod Bird" => Tactic::Theropod, // Arthropods "Antlion" => Tactic::ArthropodMelee, "Tarantula" | "Horn Beetle" => Tactic::ArthropodAmbush, "Weevil" | "Black Widow" => Tactic::ArthropodRanged, "Theropod Charge" => Tactic::CircleCharge { radius: 6, circle_time: 1, }, "Turret" => Tactic::Turret, "Haniwa Sentry" => Tactic::RotatingTurret, "Bird Large Breathe" => Tactic::BirdLargeBreathe, "Bird Large Fire" => Tactic::BirdLargeFire, "Bird Large Basic" => Tactic::BirdLargeBasic, "Mindflayer" => Tactic::Mindflayer, "Minotaur" => Tactic::Minotaur, "Clay Golem" => Tactic::ClayGolem, "Tidal Warrior" => Tactic::TidalWarrior, "Tidal Totem" | "Tornado" | "Gnarling Totem Red" | "Gnarling Totem Green" | "Gnarling Totem White" => Tactic::RadialTurret, "Yeti" => Tactic::Yeti, "Harvester" => Tactic::Harvester, "Gnarling Dagger" => Tactic::SimpleBackstab, "Gnarling Blowgun" => Tactic::ElevatedRanged, "Deadwood" => Tactic::Deadwood, "Mandragora" => Tactic::Mandragora, "Wood Golem" => Tactic::WoodGolem, "Gnarling Chieftain" => Tactic::GnarlingChieftain, _ => Tactic::SimpleMelee, }, AbilitySpec::Tool(tool_kind) => tool_tactic(*tool_kind), } } else if let ItemKind::Tool(tool) = &*item.kind() { tool_tactic(tool.kind) } else { Tactic::SimpleMelee } }) .unwrap_or(Tactic::SimpleMelee); // Wield the weapon as running towards the target controller.push_action(ControlAction::Wield); let min_attack_dist = (self.body.map_or(0.5, |b| b.max_radius()) + DEFAULT_ATTACK_RANGE) * self.scale + tgt_data.body.map_or(0.5, |b| b.max_radius()) * tgt_data.scale.map_or(1.0, |s| s.0); let dist_sqrd = self.pos.0.distance_squared(tgt_data.pos.0); let angle = self .ori .look_vec() .angle_between(tgt_data.pos.0 - self.pos.0) .to_degrees(); let angle_xy = self .ori .look_vec() .xy() .angle_between((tgt_data.pos.0 - self.pos.0).xy()) .to_degrees(); let eye_offset = self.body.map_or(0.0, |b| b.eye_height()); let tgt_eye_height = tgt_data.body.map_or(0.0, |b| b.eye_height()); let tgt_eye_offset = tgt_eye_height + // Special case for jumping attacks to jump at the body // of the target and not the ground around the target // For the ranged it is to shoot at the feet and not // the head to get splash damage if tactic == Tactic::QuadMedJump { 1.0 } else if matches!(tactic, Tactic::QuadLowRanged) { -1.0 } else { 0.0 }; // FIXME: // 1) Retrieve actual projectile speed! // We have to assume projectiles are faster than base speed because there are // skills that increase it, and in most cases this will cause agents to // overshoot // // 2) We use eye_offset-s which isn't actually ideal. // Some attacks (beam for example) may use different offsets, // we should probably use offsets from corresponding states. // // 3) Should we even have this big switch? // Not all attacks may want their direction overwritten. // And this is quite hard to debug when you don't see it in actual // attack handler. if let Some(dir) = match self.char_state { CharacterState::ChargedRanged(c) if dist_sqrd > 0.0 => { let charge_factor = c.timer.as_secs_f32() / c.static_data.charge_duration.as_secs_f32(); let projectile_speed = c.static_data.initial_projectile_speed + charge_factor * c.static_data.scaled_projectile_speed; aim_projectile( projectile_speed, self.pos.0 + self.body.map_or(Vec3::zero(), |body| { body.projectile_offsets(self.ori.look_vec()) }), Vec3::new( tgt_data.pos.0.x, tgt_data.pos.0.y, tgt_data.pos.0.z + tgt_eye_offset, ), ) }, CharacterState::BasicRanged(c) => { let offset_z = match c.static_data.projectile { // Aim fireballs at feet instead of eyes for splash damage ProjectileConstructor::Fireball { damage: _, radius: _, energy_regen: _, min_falloff: _, } => 0.0, _ => tgt_eye_offset, }; let projectile_speed = c.static_data.projectile_speed; aim_projectile( projectile_speed, self.pos.0 + self.body.map_or(Vec3::zero(), |body| { body.projectile_offsets(self.ori.look_vec()) }), Vec3::new( tgt_data.pos.0.x, tgt_data.pos.0.y, tgt_data.pos.0.z + offset_z, ), ) }, CharacterState::RepeaterRanged(c) => { let projectile_speed = c.static_data.projectile_speed; aim_projectile( projectile_speed, self.pos.0 + self.body.map_or(Vec3::zero(), |body| { body.projectile_offsets(self.ori.look_vec()) }), Vec3::new( tgt_data.pos.0.x, tgt_data.pos.0.y, tgt_data.pos.0.z + tgt_eye_offset, ), ) }, CharacterState::LeapMelee(_) if matches!(tactic, Tactic::Hammer | Tactic::Axe) => { let direction_weight = match tactic { Tactic::Hammer => 0.1, Tactic::Axe => 0.3, _ => unreachable!("Direction weight called on incorrect tactic."), }; let tgt_pos = tgt_data.pos.0; let self_pos = self.pos.0; let delta_x = (tgt_pos.x - self_pos.x) * direction_weight; let delta_y = (tgt_pos.y - self_pos.y) * direction_weight; Dir::from_unnormalized(Vec3::new(delta_x, delta_y, -1.0)) }, CharacterState::BasicBeam(_) => { let aim_from = self.body.map_or(self.pos.0, |body| { self.pos.0 + basic_beam::beam_offsets( body, controller.inputs.look_dir, self.ori.look_vec(), // Try to match animation by getting some context self.vel.0 - self.physics_state.ground_vel, self.physics_state.on_ground, ) }); let aim_to = Vec3::new( tgt_data.pos.0.x, tgt_data.pos.0.y, tgt_data.pos.0.z + tgt_eye_offset, ); Dir::from_unnormalized(aim_to - aim_from) }, _ => { let aim_from = Vec3::new(self.pos.0.x, self.pos.0.y, self.pos.0.z + eye_offset); let aim_to = Vec3::new( tgt_data.pos.0.x, tgt_data.pos.0.y, tgt_data.pos.0.z + tgt_eye_offset, ); Dir::from_unnormalized(aim_to - aim_from) }, } { controller.inputs.look_dir = dir; } let attack_data = AttackData { min_attack_dist, dist_sqrd, angle, angle_xy, }; // Match on tactic. Each tactic has different controls depending on the distance // from the agent to the target. match tactic { Tactic::SimpleMelee => { self.handle_simple_melee(agent, controller, &attack_data, tgt_data, read_data, rng) }, Tactic::Axe => { self.handle_axe_attack(agent, controller, &attack_data, tgt_data, read_data, rng) }, Tactic::Hammer => { self.handle_hammer_attack(agent, controller, &attack_data, tgt_data, read_data, rng) }, Tactic::Sword => { self.handle_sword_attack(agent, controller, &attack_data, tgt_data, read_data, rng) }, Tactic::Bow => { self.handle_bow_attack(agent, controller, &attack_data, tgt_data, read_data, rng) }, Tactic::Staff => { self.handle_staff_attack(agent, controller, &attack_data, tgt_data, read_data, rng) }, Tactic::Sceptre => self.handle_sceptre_attack( agent, controller, &attack_data, tgt_data, read_data, rng, ), Tactic::StoneGolem => { self.handle_stone_golem_attack(agent, controller, &attack_data, tgt_data, read_data) }, Tactic::CircleCharge { radius, circle_time, } => self.handle_circle_charge_attack( agent, controller, &attack_data, tgt_data, read_data, radius, circle_time, rng, ), Tactic::QuadLowRanged => self.handle_quadlow_ranged_attack( agent, controller, &attack_data, tgt_data, read_data, ), Tactic::TailSlap => { self.handle_tail_slap_attack(agent, controller, &attack_data, tgt_data, read_data) }, Tactic::QuadLowQuick => self.handle_quadlow_quick_attack( agent, controller, &attack_data, tgt_data, read_data, ), Tactic::QuadLowBasic => self.handle_quadlow_basic_attack( agent, controller, &attack_data, tgt_data, read_data, ), Tactic::QuadMedJump => self.handle_quadmed_jump_attack( agent, controller, &attack_data, tgt_data, read_data, ), Tactic::QuadMedBasic => self.handle_quadmed_basic_attack( agent, controller, &attack_data, tgt_data, read_data, ), Tactic::QuadLowBeam => self.handle_quadlow_beam_attack( agent, controller, &attack_data, tgt_data, read_data, ), Tactic::Theropod => { self.handle_theropod_attack(agent, controller, &attack_data, tgt_data, read_data) }, Tactic::ArthropodMelee => self.handle_arthropod_melee_attack( agent, controller, &attack_data, tgt_data, read_data, ), Tactic::ArthropodAmbush => self.handle_arthropod_ambush_attack( agent, controller, &attack_data, tgt_data, read_data, rng, ), Tactic::ArthropodRanged => self.handle_arthropod_ranged_attack( agent, controller, &attack_data, tgt_data, read_data, ), Tactic::Turret => { self.handle_turret_attack(agent, controller, &attack_data, tgt_data, read_data) }, Tactic::FixedTurret => self.handle_fixed_turret_attack( agent, controller, &attack_data, tgt_data, read_data, ), Tactic::RotatingTurret => { self.handle_rotating_turret_attack(agent, controller, tgt_data, read_data) }, Tactic::Mindflayer => self.handle_mindflayer_attack( agent, controller, &attack_data, tgt_data, read_data, rng, ), Tactic::BirdLargeFire => self.handle_birdlarge_fire_attack( agent, controller, &attack_data, tgt_data, read_data, rng, ), // Mostly identical to BirdLargeFire but tweaked for flamethrower instead of shockwave Tactic::BirdLargeBreathe => self.handle_birdlarge_breathe_attack( agent, controller, &attack_data, tgt_data, read_data, rng, ), Tactic::BirdLargeBasic => self.handle_birdlarge_basic_attack( agent, controller, &attack_data, tgt_data, read_data, ), Tactic::Minotaur => { self.handle_minotaur_attack(agent, controller, &attack_data, tgt_data, read_data) }, Tactic::ClayGolem => { self.handle_clay_golem_attack(agent, controller, &attack_data, tgt_data, read_data) }, Tactic::TidalWarrior => self.handle_tidal_warrior_attack( agent, controller, &attack_data, tgt_data, read_data, ), Tactic::RadialTurret => self.handle_radial_turret_attack(controller), Tactic::Yeti => { self.handle_yeti_attack(agent, controller, &attack_data, tgt_data, read_data) }, Tactic::Harvester => { self.handle_harvester_attack(agent, controller, &attack_data, tgt_data, read_data) }, Tactic::SimpleBackstab => { self.handle_simple_backstab(agent, controller, &attack_data, tgt_data, read_data) }, Tactic::ElevatedRanged => { self.handle_elevated_ranged(agent, controller, &attack_data, tgt_data, read_data) }, Tactic::Deadwood => { self.handle_deadwood(agent, controller, &attack_data, tgt_data, read_data) }, Tactic::Mandragora => { self.handle_mandragora(agent, controller, &attack_data, tgt_data, read_data) }, Tactic::WoodGolem => { self.handle_wood_golem(agent, controller, &attack_data, tgt_data, read_data) }, Tactic::GnarlingChieftain => self.handle_gnarling_chieftain( agent, controller, &attack_data, tgt_data, read_data, rng, ), } } fn handle_sounds_heard( &self, agent: &mut Agent, controller: &mut Controller, read_data: &ReadData, rng: &mut impl Rng, ) { agent.forget_old_sounds(read_data.time.0); if is_invulnerable(*self.entity, read_data) { self.idle(agent, controller, read_data, rng); return; } if let Some(sound) = agent.sounds_heard.last() { let sound_pos = Pos(sound.pos); let dist_sqrd = self.pos.0.distance_squared(sound_pos.0); // NOTE: There is an implicit distance requirement given that sound volume // dissipates as it travels, but we will not want to flee if a sound is super // loud but heard from a great distance, regardless of how loud it was. // `is_close` is this limiter. let is_close = dist_sqrd < 35.0_f32.powi(2); let sound_was_loud = sound.vol >= 10.0; let sound_was_threatening = sound_was_loud || matches!(sound.kind, SoundKind::Utterance(UtteranceKind::Scream, _)); let has_enemy_alignment = matches!(self.alignment, Some(Alignment::Enemy)); // FIXME: We need to be able to change the name of a guard without breaking this // logic. The `Mark` enum from common::agent could be used to match with // `agent::Mark::Guard` let is_village_guard = read_data .stats .get(*self.entity) .map_or(false, |stats| stats.name == *"Guard".to_string()); let follows_threatening_sounds = has_enemy_alignment || is_village_guard; // TODO: Awareness currently doesn't influence anything. //agent.awareness += 0.5 * sound.vol; if sound_was_threatening && is_close { if !self.below_flee_health(agent) && follows_threatening_sounds { self.follow(agent, controller, &read_data.terrain, &sound_pos); } else if self.below_flee_health(agent) || !follows_threatening_sounds { self.flee(agent, controller, &sound_pos, &read_data.terrain); } else { self.idle(agent, controller, read_data, rng); } } else { self.idle(agent, controller, read_data, rng); } } else { self.idle(agent, controller, read_data, rng); } } fn attack_target_attacker( &self, agent: &mut Agent, read_data: &ReadData, controller: &mut Controller, rng: &mut impl Rng, ) { if let Some(Target { target, .. }) = agent.target { if let Some(tgt_health) = read_data.healths.get(target) { if let Some(by) = tgt_health.last_change.damage_by() { if let Some(attacker) = get_entity_by_id(by.uid().0, read_data) { if agent.target.is_none() { controller.push_utterance(UtteranceKind::Angry); } agent.target = Some(Target::new(attacker, true, read_data.time.0, true)); if let Some(tgt_pos) = read_data.positions.get(attacker) { if is_dead_or_invulnerable(attacker, read_data) { // FIXME?: Shouldn't target be set to `None`? // If is dead, then probably. If invulnerable, maybe not. agent.target = Some(Target::new(target, false, read_data.time.0, false)); self.idle(agent, controller, read_data, rng); } else { let target_data = TargetData::new( tgt_pos, read_data.bodies.get(target), read_data.scales.get(target), ); if let Some(tgt_name) = read_data.stats.get(target).map(|stats| stats.name.clone()) { agent.add_fight_to_memory(&tgt_name, read_data.time.0) } self.attack(agent, controller, &target_data, read_data, rng); } } } } } } } /// Directs the entity to path and move toward the target /// If path is not Full, the entity will path to a location 50 units along /// the vector between the entity and the target. The speed multiplier /// multiplies the movement speed by a value less than 1.0. /// A `None` value implies a multiplier of 1.0. /// Returns `false` if the pathfinding algorithm fails to return a path fn path_toward_target( &self, agent: &mut Agent, controller: &mut Controller, tgt_pos: Vec3, read_data: &ReadData, path: Path, speed_multiplier: Option, ) -> bool { let partial_path_tgt_pos = |pos_difference: Vec3| { self.pos.0 + PARTIAL_PATH_DIST * pos_difference.try_normalized().unwrap_or_else(Vec3::zero) }; let pos_difference = tgt_pos - self.pos.0; let pathing_pos = match path { Path::Separate => { let mut sep_vec: Vec3 = Vec3::::zero(); for entity in read_data .cached_spatial_grid .0 .in_circle_aabr(self.pos.0.xy(), SEPARATION_DIST) { if let (Some(alignment), Some(other_alignment)) = (self.alignment, read_data.alignments.get(entity)) { if Alignment::passive_towards(*alignment, *other_alignment) { if let (Some(pos), Some(body), Some(other_body)) = ( read_data.positions.get(entity), self.body, read_data.bodies.get(entity), ) { let dist_xy = self.pos.0.xy().distance(pos.0.xy()); let spacing = body.spacing_radius() + other_body.spacing_radius(); if dist_xy < spacing { let pos_diff = self.pos.0.xy() - pos.0.xy(); sep_vec += pos_diff.try_normalized().unwrap_or_else(Vec2::zero) * ((spacing - dist_xy) / spacing); } } } } } partial_path_tgt_pos( sep_vec * SEPARATION_BIAS + pos_difference * (1.0 - SEPARATION_BIAS), ) }, Path::Full => tgt_pos, Path::Partial => partial_path_tgt_pos(pos_difference), }; let speed_multiplier = speed_multiplier.unwrap_or(1.0).min(1.0); if let Some((bearing, speed)) = agent.chaser.chase( &*read_data.terrain, self.pos.0, self.vel.0, pathing_pos, TraversalConfig { min_tgt_dist: 1.25, ..self.traversal_config }, ) { controller.inputs.move_dir = bearing.xy().try_normalized().unwrap_or_else(Vec2::zero) * speed * speed_multiplier; self.jump_if(bearing.z > 1.5, controller); controller.inputs.move_z = bearing.z; true } else { false } } fn chat_npc_if_allowed_to_speak( &self, msg: impl ToString, agent: &Agent, event_emitter: &mut Emitter<'_, ServerEvent>, ) -> bool { if agent.allowed_to_speak() { self.chat_npc(msg, event_emitter); true } else { false } } fn jump_if(&self, condition: bool, controller: &mut Controller) { if condition { controller.push_basic_input(InputKind::Jump); } else { controller.push_cancel_input(InputKind::Jump) } } fn chat_npc(&self, msg: impl ToString, event_emitter: &mut Emitter<'_, ServerEvent>) { event_emitter.emit(ServerEvent::Chat(UnresolvedChatMsg::npc( *self.uid, msg.to_string(), ))); } fn emit_scream(&self, time: f64, event_emitter: &mut Emitter<'_, ServerEvent>) { if let Some(body) = self.body { event_emitter.emit(ServerEvent::Sound { sound: Sound::new( SoundKind::Utterance(UtteranceKind::Scream, *body), self.pos.0, 13.0, time, ), }); } } fn cry_out( &self, agent: &Agent, event_emitter: &mut Emitter<'_, ServerEvent>, read_data: &ReadData, ) { let has_enemy_alignment = matches!(self.alignment, Some(Alignment::Enemy)); if has_enemy_alignment { // FIXME: If going to use "cultist + low health + fleeing" string, make sure // they are each true. self.chat_npc_if_allowed_to_speak( "npc-speech-cultist_low_health_fleeing", agent, event_emitter, ); } else if is_villager(self.alignment) { self.chat_npc_if_allowed_to_speak( "npc-speech-villager_under_attack", agent, event_emitter, ); self.emit_scream(read_data.time.0, event_emitter); } } fn exclaim_relief_about_enemy_dead( &self, agent: &Agent, event_emitter: &mut Emitter<'_, ServerEvent>, ) { if is_villager(self.alignment) { self.chat_npc_if_allowed_to_speak( "npc-speech-villager_enemy_killed", agent, event_emitter, ); } } fn below_flee_health(&self, agent: &Agent) -> bool { self.damage.min(1.0) < agent.psyche.flee_health } fn is_more_dangerous_than_target( &self, entity: EcsEntity, target: Target, read_data: &ReadData, ) -> bool { let entity_pos = read_data.positions.get(entity); let target_pos = read_data.positions.get(target.target); entity_pos.map_or(false, |entity_pos| { target_pos.map_or(true, |target_pos| { // Fuzzy factor that makes it harder for players to cheese enemies by making // them quickly flip aggro between two players. // It does this by only switching aggro if the entity is closer to the enemy by // a specific proportional threshold. const FUZZY_DIST_COMPARISON: f32 = 0.8; let is_target_further = target_pos.0.distance(entity_pos.0) < target_pos.0.distance(entity_pos.0) * FUZZY_DIST_COMPARISON; let is_entity_hostile = read_data .alignments .get(entity) .zip(self.alignment) .map_or(false, |(entity, me)| me.hostile_towards(*entity)); // Consider entity more dangerous than target if entity is closer or if target // had not triggered aggro. !target.aggro_on || (is_target_further && is_entity_hostile) }) }) } fn remembers_fight_with(&self, other: EcsEntity, read_data: &ReadData) -> bool { let name = || read_data.stats.get(other).map(|stats| stats.name.clone()); self.rtsim_entity.map_or(false, |rtsim_entity| { name().map_or(false, |name| { rtsim_entity.brain.remembers_fight_with_character(&name) }) }) } fn is_enemy(&self, entity: EcsEntity, read_data: &ReadData) -> bool { let other_alignment = read_data.alignments.get(entity); (entity != *self.entity) && !self.passive_towards(entity, read_data) && (are_our_owners_hostile(self.alignment, other_alignment, read_data) || self.remembers_fight_with(entity, read_data) || (is_villager(self.alignment) && is_dressed_as_cultist(entity, read_data))) } fn should_defend(&self, entity: EcsEntity, read_data: &ReadData) -> bool { let entity_alignment = read_data.alignments.get(entity); let we_are_friendly = entity_alignment.map_or(false, |entity_alignment| { self.alignment.map_or(false, |alignment| { !alignment.hostile_towards(*entity_alignment) }) }); let we_share_species = read_data.bodies.get(entity).map_or(false, |entity_body| { self.body.map_or(false, |body| { entity_body.is_same_species_as(body) || (entity_body.is_humanoid() && body.is_humanoid()) }) }); let self_owns_entity = matches!(entity_alignment, Some(Alignment::Owned(ouid)) if *self.uid == *ouid); (we_are_friendly && we_share_species) || (is_village_guard(*self.entity, read_data) && is_villager(entity_alignment)) || self_owns_entity } fn passive_towards(&self, entity: EcsEntity, read_data: &ReadData) -> bool { if let (Some(self_alignment), Some(other_alignment)) = (self.alignment, read_data.alignments.get(entity)) { self_alignment.passive_towards(*other_alignment) } else { false } } fn can_see_entity( &self, agent: &Agent, controller: &Controller, other: EcsEntity, other_pos: &Pos, read_data: &ReadData, ) -> bool { let other_stealth_multiplier = { let other_inventory = read_data.inventories.get(other); let other_char_state = read_data.char_states.get(other); perception_dist_multiplier_from_stealth(other_inventory, other_char_state, self.msm) }; let within_sight_dist = { let sight_dist = agent.psyche.sight_dist * other_stealth_multiplier; let dist_sqrd = other_pos.0.distance_squared(self.pos.0); dist_sqrd < sight_dist.powi(2) }; let within_fov = (other_pos.0 - self.pos.0) .try_normalized() .map_or(false, |v| v.dot(*controller.inputs.look_dir) > 0.15); let other_body = read_data.bodies.get(other); (within_sight_dist) && within_fov && entities_have_line_of_sight(self.pos, self.body, other_pos, other_body, read_data) } }