diff --git a/plugins/crossover/src/crossover/fir.rs b/plugins/crossover/src/crossover/fir.rs index 9cdca110..a7c492bd 100644 --- a/plugins/crossover/src/crossover/fir.rs +++ b/plugins/crossover/src/crossover/fir.rs @@ -39,16 +39,16 @@ pub struct FirCrossover { /// These filters will be fed the FFT from the main input to produce output samples for the enxt /// period. Everything could be a bit nicer to read if the filter did the entire STFT process, /// but that would mean duplicating the input ring buffer and forward DFT up to five times. - band_filters: [FftFirFilter; NUM_BANDS], + band_filters: Box<[FftFirFilter; NUM_BANDS]>, /// A ring buffer that is used to store inputs for the next FFT. Until it is time to take the /// next FFT, samples are copied from the inputs to this buffer, while simultaneously copying /// the already processed output samples from the output buffers to the output. Once /// `io_buffer_next_indices` wrap back around to 0, the next buffer should be produced. - input_buffers: [[f32; FFT_INPUT_SIZE]; NUM_CHANNELS as usize], + input_buffers: Box<[[f32; FFT_INPUT_SIZE]; NUM_CHANNELS as usize]>, /// A ring that contains the next period's outputs for each of the five bands. This is written /// to and read from in lockstep with `input_buffers`. - band_output_buffers: [[[f32; FFT_INPUT_SIZE]; NUM_CHANNELS as usize]; NUM_BANDS], + band_output_buffers: Box<[[[f32; FFT_INPUT_SIZE]; NUM_CHANNELS as usize]; NUM_BANDS]>, /// The index in the inner `io_buffer` the next sample should be read from. After a sample is /// written to the band's output then this is incremented by one. Once /// `self.io_buffer_next_indices[channel_idx] == self.io_buffer.len()` then the next block @@ -64,10 +64,10 @@ pub struct FirCrossover { c2r_plan: Arc>, /// A real buffer that may be written to in place during the FFT and IFFT operations. - real_scratch_buffer: [f32; FFT_SIZE], + real_scratch_buffer: Box<[f32; FFT_SIZE]>, /// A complex buffer corresponding to `real_scratch_buffer` that may be written to in place /// during the FFT and IFFT operations. - complex_scratch_buffer: [Complex32; FFT_SIZE / 2 + 1], + complex_scratch_buffer: Box<[Complex32; FFT_SIZE / 2 + 1]>, } /// The type of FIR crossover to use. @@ -93,13 +93,15 @@ impl FirCrossover { mode, band_filters: Default::default(), - input_buffers: [[0.0; FFT_INPUT_SIZE]; NUM_CHANNELS as usize], - band_output_buffers: [[[0.0; FFT_INPUT_SIZE]; NUM_CHANNELS as usize]; NUM_BANDS], + input_buffers: Box::new([[0.0; FFT_INPUT_SIZE]; NUM_CHANNELS as usize]), + band_output_buffers: Box::new( + [[[0.0; FFT_INPUT_SIZE]; NUM_CHANNELS as usize]; NUM_BANDS], + ), io_buffers_next_indices: [0; NUM_CHANNELS as usize], r2c_plan: fft_planner.plan_fft_forward(FFT_SIZE), c2r_plan: fft_planner.plan_fft_inverse(FFT_SIZE), - real_scratch_buffer: [0.0; FFT_SIZE], - complex_scratch_buffer: [Complex32::default(); FFT_SIZE / 2 + 1], + real_scratch_buffer: Box::new([0.0; FFT_SIZE]), + complex_scratch_buffer: Box::new([Complex32::default(); FFT_SIZE / 2 + 1]), } } @@ -173,15 +175,15 @@ impl FirCrossover { self.r2c_plan .process_with_scratch( - &mut self.real_scratch_buffer, - &mut self.complex_scratch_buffer, + &mut *self.real_scratch_buffer, + &mut *self.complex_scratch_buffer, &mut [], ) .unwrap(); // The input can then be used to produce each band's output. Since realfft expects // to be able to modify the input, we need to make a copy of this first: - let input_fft = self.complex_scratch_buffer; + let input_fft = *self.complex_scratch_buffer; for (band_output_buffers, band_filter) in self .band_output_buffers @@ -313,12 +315,12 @@ impl FirCrossover { /// Reset the internal filter state for all crossovers. pub fn reset(&mut self) { - for filter in &mut self.band_filters { + for filter in self.band_filters.iter_mut() { filter.reset(); } // The inputs don't need to be reset as they'll be overwritten immediately - for band_buffers in &mut self.band_output_buffers { + for band_buffers in self.band_output_buffers.iter_mut() { for buffer in band_buffers { buffer.fill(0.0); }