//! Compute forward single sided amplitude spectra use crate::config::*; use realfft::{RealFftPlanner, RealToComplex}; use std::sync::Arc; #[derive(Clone)] pub struct FFT { // The fft engine fft: Arc>, // Copy over time data, as it is used as scratch data in the fft engine timescratch: Vec, // rounded down nfft/2 half_nfft_rounded: usize, // nfft stored as float, this is how it is required most often nfftF: Flt, } impl Debug for FFT { fn fmt(&self, f: &mut std::fmt::Formatter<'_>) -> std::fmt::Result { f.debug_struct("Forward FFT engine, lenfth: {self.nfftF}").finish() } } impl FFT { /// Create new FFT from given nfft #[allow(dead_code)] pub fn newFromNFFT(nfft: usize) -> FFT { let mut planner = RealFftPlanner::::new(); let fft = planner.plan_fft_forward(nfft); Self::new(fft) } /// Create new fft engine from given fft engine pub fn new(fft: Arc>) -> FFT { let nfft = fft.len(); let timescratch = vec![0.; nfft]; FFT { fft, timescratch, half_nfft_rounded: nfft / 2, nfftF: nfft as Flt, } } pub fn process<'a, T, U>(&mut self, time: T, freq: U) where T: Into>, U: Into>, { let mut freq = freq.into(); let time = time.into(); self.timescratch.copy_from_slice(time.as_slice().unwrap()); let _ = self .fft .process(&mut self.timescratch, freq.as_slice_mut().unwrap()); freq[0] /= self.nfftF; freq[self.half_nfft_rounded] /= self.nfftF; freq.slice_mut(s![1..self.half_nfft_rounded]) .par_mapv_inplace(|x| 2. * x / self.nfftF); } }