use crate::bar_indicators::average::moving_average::MovingAverageType;
use crate::bar_indicators::channels::keltner_channel::{KeltnerChannel, KeltnerMode};
use crate::bar_indicators::indicator_value::IndicatorValue;
#[derive(Debug, Clone)]
pub struct KeltnerDistance {
kc: KeltnerChannel,
value: f64,
}
impl KeltnerDistance {
pub fn new(period: usize, multiplier: f64) -> Self {
Self {
kc: KeltnerChannel::new(
period.max(2),
multiplier.max(0.1),
KeltnerMode::Classic,
MovingAverageType::SMA,
MovingAverageType::RMA,
),
value: 0.0,
}
}
#[inline]
pub fn reset(&mut self) {
self.kc.reset();
self.value = 0.0;
}
#[inline]
pub fn is_ready(&self) -> bool {
self.kc.is_ready()
}
#[inline]
pub fn value(&self) -> IndicatorValue {
IndicatorValue::Single(self.value)
}
pub fn update_bar(&mut self, o: f64, h: f64, l: f64, c: f64, v: f64) -> f64 {
let _ = self.kc.update_bar(o, h, l, c, v);
self.value = self.kc.distance_from_center_atr(c);
self.value
}
}
#[cfg(test)]
mod tests {
use super::*;
#[test]
fn test_keltner_distance_creation() {
let kd = KeltnerDistance::new(20, 2.0);
assert!(!kd.is_ready());
assert_eq!(kd.value().main(), 0.0);
}
#[test]
fn test_keltner_distance_warmup() {
let mut kd = KeltnerDistance::new(20, 2.0);
for i in 0..25 {
let price = 100.0 + (i as f64 * 0.1).sin() * 5.0;
kd.update_bar(price, price + 1.0, price - 1.0, price, 1000.0);
}
assert!(kd.is_ready());
}
#[test]
fn test_keltner_distance_finite() {
let mut kd = KeltnerDistance::new(20, 2.0);
for i in 0..30 {
let price = 100.0 + (i as f64 * 0.2).sin() * 10.0;
let value = kd.update_bar(price, price + 1.0, price - 1.0, price, 1000.0);
assert!(value.is_finite(), "Distance should be finite");
}
}
#[test]
fn test_keltner_distance_reset() {
let mut kd = KeltnerDistance::new(20, 2.0);
for i in 0..25 {
kd.update_bar(100.0 + i as f64, 101.0, 99.0, 100.0 + i as f64, 1000.0);
}
kd.reset();
assert!(!kd.is_ready());
assert_eq!(kd.value().main(), 0.0);
}
}