quantwave_core/indicators/
math.rs1use crate::utils::RingBuffer as VecDeque;
2
3native_pointwise_1!(ACOS, f64::acos);
4native_pointwise_1!(ASIN, f64::asin);
5native_pointwise_1!(ATAN, f64::atan);
6native_pointwise_1!(CEIL, f64::ceil);
7native_pointwise_1!(COS, f64::cos);
8native_pointwise_1!(COSH, f64::cosh);
9native_pointwise_1!(EXP, f64::exp);
10native_pointwise_1!(FLOOR, f64::floor);
11native_pointwise_1!(LN, f64::ln);
12native_pointwise_1!(LOG10, f64::log10);
13native_pointwise_1!(SIN, f64::sin);
14native_pointwise_1!(SINH, f64::sinh);
15native_pointwise_1!(SQRT, f64::sqrt);
16native_pointwise_1!(TAN, f64::tan);
17native_pointwise_1!(TANH, f64::tanh);
18
19#[derive(Debug, Clone)]
21pub struct RMS {
22 period: usize,
23 history: VecDeque<f64>,
24 sum_sq: f64,
25}
26
27impl RMS {
28 pub fn new(period: usize) -> Self {
29 Self {
30 period,
31 history: VecDeque::with_capacity(period),
32 sum_sq: 0.0,
33 }
34 }
35}
36
37impl crate::traits::Next<f64> for RMS {
38 type Output = f64;
39
40 fn next(&mut self, input: f64) -> Self::Output {
41 let input_sq = input * input;
42 self.sum_sq += input_sq;
43 self.history.push_back(input_sq);
44
45 if self.history.len() > self.period
46 && let Some(old) = self.history.pop_front()
47 {
48 self.sum_sq -= old;
49 }
50
51 if self.history.is_empty() {
52 0.0
53 } else {
54 (self.sum_sq / self.history.len() as f64).sqrt()
55 }
56 }
57}
58
59#[derive(Debug, Clone)]
64pub struct AGC {
65 peak: f64,
66 decay: f64,
67}
68
69impl AGC {
70 pub fn new(decay: f64) -> Self {
71 Self {
72 peak: 0.0000001,
73 decay,
74 }
75 }
76}
77
78impl crate::traits::Next<f64> for AGC {
79 type Output = f64;
80
81 fn next(&mut self, input: f64) -> Self::Output {
82 self.peak *= self.decay;
83 let abs_input = input.abs();
84 if abs_input > self.peak {
85 self.peak = abs_input;
86 }
87
88 if self.peak != 0.0 {
89 input / self.peak
90 } else {
91 0.0
92 }
93 }
94}
95
96native_binary_2!(ADD, |a, b| a + b);
97native_binary_2!(SUB, |a, b| a - b);
98native_binary_2!(MULT, |a, b| a * b);
99native_binary_2!(DIV, |a, b| a / b);
100
101pub use crate::indicators::incremental::rolling::{MAX, MAXINDEX, MIN, MININDEX, SUM};
102impl From<usize> for MAX {
103 fn from(p: usize) -> Self {
104 Self::new(p)
105 }
106}
107impl From<usize> for MAXINDEX {
108 fn from(p: usize) -> Self {
109 Self::new(p)
110 }
111}
112impl From<usize> for MIN {
113 fn from(p: usize) -> Self {
114 Self::new(p)
115 }
116}
117impl From<usize> for MININDEX {
118 fn from(p: usize) -> Self {
119 Self::new(p)
120 }
121}
122impl From<usize> for SUM {
123 fn from(p: usize) -> Self {
124 Self::new(p)
125 }
126}
127
128#[cfg(test)]
129mod tests {
130 use super::*;
131 use crate::traits::Next;
132 use proptest::prelude::*;
133
134 proptest! {
135 #[test]
136 fn test_sqrt_parity(input in prop::collection::vec(0.1..100.0, 1..100)) {
137 let mut sqrt = SQRT::new();
138 let streaming_results: Vec<f64> = input.iter().map(|&x| sqrt.next(x)).collect();
139 let batch_results = talib_rs::math_transform::sqrt(&input);
140
141 for (s, b) in streaming_results.iter().zip(batch_results.iter()) {
142 if s.is_nan() {
143 assert!(b.is_nan());
144 } else {
145 approx::assert_relative_eq!(s, b, epsilon = 1e-6);
146 }
147 }
148 }
149
150 #[test]
151 fn test_add_parity(
152 in1 in prop::collection::vec(0.1..100.0, 1..100),
153 in2 in prop::collection::vec(0.1..100.0, 1..100)
154 ) {
155 let len = in1.len().min(in2.len());
156 if len == 0 { return Ok(()); }
157
158 let mut add = ADD::new();
159 let streaming_results: Vec<f64> = (0..len).map(|i| add.next((in1[i], in2[i]))).collect();
160 let batch_results = talib_rs::math_operator::add(&in1[..len], &in2[..len]).unwrap_or_else(|_| vec![f64::NAN; len]);
161
162 for (s, b) in streaming_results.iter().zip(batch_results.iter()) {
163 if s.is_nan() {
164 assert!(b.is_nan());
165 } else {
166 approx::assert_relative_eq!(s, b, epsilon = 1e-6);
167 }
168 }
169 }
170
171 #[test]
172 fn test_rms_parity(input in prop::collection::vec(0.1..100.0, 10..100)) {
173 let period = 10;
174 let mut rms = RMS::new(period);
175 let streaming_results: Vec<f64> = input.iter().map(|&x| rms.next(x)).collect();
176
177 let mut batch_results = Vec::with_capacity(input.len());
178 for i in 0..input.len() {
179 let start = if i + 1 > period { i + 1 - period } else { 0 };
180 let window = &input[start..i+1];
181 let sum_sq: f64 = window.iter().map(|&x| x*x).sum();
182 batch_results.push((sum_sq / window.len() as f64).sqrt());
183 }
184
185 for (s, b) in streaming_results.iter().zip(batch_results.iter()) {
186 approx::assert_relative_eq!(s, b, epsilon = 1e-10);
187 }
188 }
189 }
190}