//! evtclib tracker definitions. //! //! The idea behind a "tracker" is to have one object taking care of one //! specific thing. This makes it easier to organize the whole "statistic //! gathering loop", and it keeps each tracker somewhat small. //! //! It's also easy to define your own trackers if there are any statistics that //! you want to track. Just implement [`Tracker`](trait.Tracker.html). It //! doesn't matter what you track, it doesn't matter how many trackers you //! define. //! //! You can use [`run_trackers`](../fn.run_trackers.html) to run multiple //! trackers on the same log. use std::collections::HashMap; use std::error::Error; use super::super::{Event, EventKind, Log}; use super::boon::{BoonQueue, BoonType}; use super::DamageStats; // A support macro to introduce a new block. // // Doesn't really require a macro, but it's nicer to look at // with! { foo = bar } // rather than // { let foo = bar; ... } macro_rules! with { ($name:ident = $expr:expr => $bl:block) => {{ let $name = $expr; $bl }}; } /// A tracker. /// /// A tracker should be responsible for tracking a single statistic. Each /// tracker is fed each event. If an error is returned while feeding, the whole /// calculation will be aborted. pub trait Tracker { /// The resulting statistic that this tracker will return. type Stat; /// The error that this tracker might return. type Error: Error; /// Feed a single event into this tracker. /// /// The tracker will update its internal state. fn feed(&mut self, event: &Event) -> Result<(), Self::Error>; /// Finalize this tracker and get the statistics out. fn finalize(self) -> Result; } /// A helper trait that erases the types from a tracker. /// /// This makes it able to use references like `&mut RunnableTracker` without /// having to specify the generic types, allowing you to e.g. store a bunch of /// them in a vector, regardless of their output type. Unless you want to do /// that, you probably don't want to use this trait directly. /// /// Note that you do not need to implement this yourself. It is automatically /// implemented for all types that implement `Tracker`. /// /// RunnableTrackers provide no way to extract their resources, and they wrap /// all errors in `Box<_>`, so you should always keep a "real" reference around /// if you plan on getting any data. pub trait RunnableTracker { /// See `Tracker.feed()`. Renamed to avoid conflicts. fn run_feed(&mut self, event: &Event) -> Result<(), Box>; } impl> RunnableTracker for T { fn run_feed(&mut self, event: &Event) -> Result<(), Box> { self.feed(event).map_err(|e| Box::new(e) as Box) } } /// A tracker that tracks per-target damage of all agents. pub struct DamageTracker<'l> { log: &'l Log, // Source -> Target -> Damage damages: HashMap>, } impl<'t> DamageTracker<'t> { /// Create a new damage tracker for the given log. pub fn new(log: &Log) -> DamageTracker { DamageTracker { log, damages: HashMap::new(), } } fn get_stats(&mut self, source: u64, target: u64) -> &mut DamageStats { self.damages .entry(source) .or_insert_with(Default::default) .entry(target) .or_insert_with(Default::default) } } impl<'t> Tracker for DamageTracker<'t> { type Stat = HashMap>; type Error = !; fn feed(&mut self, event: &Event) -> Result<(), Self::Error> { match event.kind { EventKind::Physical { source_agent_addr, destination_agent_addr, damage, .. } => { with! { stats = self.get_stats(source_agent_addr, destination_agent_addr) => { stats.total_damage += damage as u64; stats.power_damage += damage as u64; }} if let Some(master) = self.log.master_agent(source_agent_addr) { let master_stats = self.get_stats(master.addr, destination_agent_addr); master_stats.total_damage += damage as u64; master_stats.add_damage += damage as u64; } } EventKind::ConditionTick { source_agent_addr, destination_agent_addr, damage, .. } => { with! { stats = self.get_stats(source_agent_addr, destination_agent_addr) => { stats.total_damage += damage as u64; stats.condition_damage += damage as u64; }} if let Some(master) = self.log.master_agent(source_agent_addr) { let master_stats = self.get_stats(master.addr, destination_agent_addr); master_stats.total_damage += damage as u64; master_stats.add_damage += damage as u64; } } _ => (), } Ok(()) } fn finalize(self) -> Result { Ok(self.damages) } } /// Tracks when the log has been started. #[derive(Default)] pub struct LogStartTracker { event_time: u64, } impl LogStartTracker { /// Create a new log start tracker. pub fn new() -> LogStartTracker { LogStartTracker { event_time: 0 } } } impl Tracker for LogStartTracker { type Stat = u64; type Error = !; fn feed(&mut self, event: &Event) -> Result<(), Self::Error> { if let EventKind::LogStart { .. } = event.kind { self.event_time = event.time; } Ok(()) } fn finalize(self) -> Result { Ok(self.event_time) } } /// A tracker that tracks the combat entry and exit times for each agent. #[derive(Default)] pub struct CombatTimeTracker { times: HashMap, } impl CombatTimeTracker { /// Create a new combat time tracker. pub fn new() -> CombatTimeTracker { Default::default() } } impl Tracker for CombatTimeTracker { // Maps from agent addr to (entry time, exit time) type Stat = HashMap; type Error = !; fn feed(&mut self, event: &Event) -> Result<(), Self::Error> { match event.kind { EventKind::EnterCombat { agent_addr, .. } => { self.times.entry(agent_addr).or_insert((0, 0)).0 = event.time; } EventKind::ExitCombat { agent_addr } => { self.times.entry(agent_addr).or_insert((0, 0)).1 = event.time; } _ => (), } Ok(()) } fn finalize(self) -> Result { Ok(self.times) } } /// A tracker that tracks the total "boon area" per agent. /// /// The boon area is defined as the amount of stacks multiplied by the time. So /// 1 stack of Might for 1000 milliseconds equals 1000 "stackmilliseconds" of /// Might. You can use this boon area to calculate the average amount of stacks /// by taking the boon area and dividing it by the combat time. /// /// Note that this also tracks conditions, because internally, they're handled /// the same way. #[derive(Default)] pub struct BoonTracker { boon_areas: HashMap>, boon_queues: HashMap>, last_time: u64, } impl BoonTracker { const MAX_STACKS: u32 = 25; /// Creates a new boon tracker. pub fn new() -> BoonTracker { Default::default() } /// Updates the internal boon queues by the given amount of milliseconds. /// /// * `delta_t` - Amount of milliseconds to update. fn update_queues(&mut self, delta_t: u64) { self.boon_queues .values_mut() .flat_map(HashMap::values_mut) .for_each(|queue| queue.simulate(delta_t)); // Throw away empty boon queues or agents without any boon queue to // improve performance self.boon_queues .values_mut() .for_each(|q| q.retain(|_, v| !v.is_empty())); self.boon_queues.retain(|_, q| !q.is_empty()); } /// Update the internal tracking areas. /// /// Does not update the boon queues. /// /// * `delta_t` - Amount of milliseconds that passed. fn update_areas(&mut self, delta_t: u64) { for (agent, queues) in &self.boon_queues { for (buff_id, queue) in queues { let current_stacks = queue.current_stacks(); let area = self.boon_areas .entry(*agent) .or_insert_with(Default::default) .entry(*buff_id) .or_insert(0); *area += current_stacks as u64 * delta_t; } } } /// Get the boon queue for the given agent and buff_id. /// /// If the queue does not yet exist, create it. /// /// * `agent` - The agent. /// * `buff_id` - The buff (or condition) id. fn get_queue(&mut self, agent: u64, buff_id: u16) -> &mut BoonQueue { // XXX: Properly differentiate between intensity and duration based // boons, otherwise the results will be off. self.boon_queues .entry(agent) .or_insert_with(Default::default) .entry(buff_id) .or_insert_with(|| BoonQueue::new(Self::MAX_STACKS, BoonType::Intensity)) } } impl Tracker for BoonTracker { type Stat = HashMap>; type Error = !; fn feed(&mut self, event: &Event) -> Result<(), Self::Error> { let delta_t = event.time - self.last_time; self.update_queues(delta_t); self.update_areas(delta_t); self.last_time = event.time; match event.kind { EventKind::BuffApplication { destination_agent_addr, buff_id, duration, .. } => { self.get_queue(destination_agent_addr, buff_id) .add_stack(duration as u64); } _ => (), } Ok(()) } fn finalize(self) -> Result { println!("Number of agents: {}", self.boon_queues.len()); println!( "Number of boon queues: {}", self.boon_queues.values().flat_map(|qs| qs.values()).count() ); Ok(self.boon_areas) } }