logaritmisk
e4ff46f45c
EP message cancellation can leave a Gaussian's precision (pi) a tiny negative value — round-off of exactly zero. mu()/sigma() only special-cased pi == 0, so sigma() computed 1/sqrt(pi) = NaN for pi < 0. That NaN flowed through the moment-space Sub in the game diff-chain and poisoned every skill in the slice once it grew past ~75 competitors, making converge() return all-NaN on real-scale histories (regression vs 0.1.0, which stored sigma directly). Guard pi <= 0.0 in both accessors (improper Gaussian: mu 0, sigma infinite), matching the existing pi == 0 handling. Co-Authored-By: Claude Opus 4.8 (1M context) <noreply@anthropic.com>
TrueSkill - Through Time
Rust port of TrueSkillThroughTime.py.
Other implementations
- ttt-scala
- ChessAnalysis #F
- TrueSkillThroughTime.jl
- TrueSkillThroughTime.R
- TrueSkill Through Time: Revisiting the History of Chess
- TrueSkill Through Time. The full scientific documentation
Drift
Skill drift models how a player's true skill can change between appearances. Each time a player reappears after a gap, their skill uncertainty is widened by the drift model before the new evidence is incorporated.
Drift is represented by the Drift trait:
pub trait Drift: Copy + Debug {
fn variance_delta(&self, elapsed: i64) -> f64;
}
variance_delta returns the amount to add to σ² given the elapsed time since the player last played. Internally, Gaussian::forget uses this to compute the new sigma: σ_new = sqrt(σ² + variance_delta).
ConstantDrift
The built-in ConstantDrift implements a linear random walk — skill uncertainty grows proportionally to time:
variance_delta = elapsed * γ²
This is the standard TrueSkill Through Time model. Use it by passing a ConstantDrift(gamma) when constructing a Player:
use trueskill_tt::{Player, Gaussian, drift::ConstantDrift};
// gamma = 0.1 means skill can shift ~0.1 per time unit
let player = Player::new(Gaussian::from_ms(0.0, 6.0), 1.0, ConstantDrift(0.1));
Custom drift
Implement Drift to express any other model. For example, a drift that saturates after a long absence (uncertainty grows with the square root of elapsed time instead of linearly):
use trueskill_tt::drift::Drift;
#[derive(Clone, Copy, Debug)]
struct SqrtDrift {
gamma: f64,
}
impl Drift for SqrtDrift {
fn variance_delta(&self, elapsed: i64) -> f64 {
(elapsed as f64).sqrt() * self.gamma * self.gamma
}
}
let player = Player::new(Gaussian::from_ms(0.0, 6.0), 1.0, SqrtDrift { gamma: 0.5 });
To use a custom drift type with History, use the .drift() builder method instead of .gamma():
let h = History::builder()
.drift(SqrtDrift { gamma: 0.5 })
.build();
Scored outcomes
Use Outcome::scores([...]) when you have continuous per-team scores rather
than just ranks. Adjacent score margins flow into a MarginFactor that adds
soft Gaussian evidence about the latent performance diff. Configure
HistoryBuilder::score_sigma(σ) to control how much you trust the margins
(smaller σ = more trust).
use trueskill_tt::{History, Outcome};
let mut h = History::builder().score_sigma(2.0).build();
h.event(1)
.team(["alice"])
.team(["bob"])
.scores([21.0, 9.0])
.commit()
.unwrap();
h.converge().unwrap();
Todo
- Implement approx for Gaussian
- Add more tests from
TrueSkillThroughTime.jl - Add tests for
quality()(Use sublee/trueskill as reference) - Benchmark Batch::iteration()
- Time needs to be an enum so we can have multiple states (see
batch::compute_elapsed()) - Add examples (use same TrueSkillThroughTime.(py|jl))
- Add Observer (see argmin for inspiration)