// Diopser: a phase rotation plugin
// Copyright (C) 2021-2022 Robbert van der Helm
//
// This program is free software: you can redistribute it and/or modify
// it under the terms of the GNU General Public License as published by
// the Free Software Foundation, either version 3 of the License, or
// (at your option) any later version.
//
// This program is distributed in the hope that it will be useful,
// but WITHOUT ANY WARRANTY; without even the implied warranty of
// MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the
// GNU General Public License for more details.
//
// You should have received a copy of the GNU General Public License
// along with this program. If not, see .
#[macro_use]
extern crate nih_plug;
use nih_plug::{formatters, BoolParam, FloatParam, IntParam, Params, Range, SmoothingStyle};
use nih_plug::{
Buffer, BufferConfig, BusConfig, Plugin, ProcessContext, ProcessStatus, Vst3Plugin,
};
use std::pin::Pin;
use std::sync::atomic::{AtomicBool, Ordering};
use std::sync::Arc;
mod filter;
/// How many all-pass filters we can have in series at most. The filter stages parameter determines
/// how many filters are actually active.
const MAX_NUM_FILTERS: usize = 512;
/// The minimum step size for smoothing the filter parmaeters.
const MIN_AUTOMATION_STEP_SIZE: u32 = 1;
/// The maximum step size for smoothing the filter parameters. Updating these parameters can be
/// expensive, so updating them in larger steps can be useful.
const MAX_AUTOMATION_STEP_SIZE: u32 = 512;
// An incomplete list of unported features includes:
// - Actually add the parameters
// - Filter spread
//
// And after that I'll need to add a GUI
struct Diopser {
params: Pin>,
/// Needed for computing the filter coefficients.
sample_rate: f32,
/// All of the all-pass filters, with one array of serial filters per channelq.
/// [DiopserParams::num_stages] controls how many filters are actually active.
filters: Vec<[filter::Biquad; MAX_NUM_FILTERS]>,
/// If this is set at the start of the processing cycle, then the filter coefficients should be
/// updated. For the regular filter parameters we can look at the smoothers, but this is needed
/// when changing the number of active filters.
should_update_filters: Arc,
/// If this is 1 and any of the filter parameters are still smoothing, thenn the filter
/// coefficients should be recalculated on the next sample. After that, this gets reset to
/// `unnormalize_automation_precision(self.params.automation_precision.value)`. This is to
/// reduce the DSP load of automation parameters. It can also cause some fun sounding glitchy
/// effects when the precision is low.
next_filter_smoothing_in: i32,
}
// TODO: Some combinations of parameters can cause really loud resonance. We should limit the
// resonance and filter stages parameter ranges in the GUI until the user unlocks.
#[derive(Params)]
struct DiopserParams {
/// The number of all-pass filters applied in series.
#[id = "stages"]
filter_stages: IntParam,
/// The filter's cutoff frequqency. When this is applied, the filters are spread around this
/// frequency.
#[id = "cutoff"]
filter_frequency: FloatParam,
/// The Q parameter for the filters.
#[id = "res"]
filter_resonance: FloatParam,
/// The precision of the automation, determines the step size. This is presented to the userq as
/// a percentage, and it's stored here as `[0, 1]` float because smaller step sizes are more
/// precise so having this be an integer would result in odd situations.
#[id = "autopr"]
automation_precision: FloatParam,
/// Very important.
#[id = "ignore"]
very_important: BoolParam,
}
impl Default for Diopser {
fn default() -> Self {
let should_update_filters = Arc::new(AtomicBool::new(false));
Self {
params: Box::pin(DiopserParams::new(should_update_filters.clone())),
sample_rate: 1.0,
filters: Vec::new(),
should_update_filters,
next_filter_smoothing_in: 1,
}
}
}
impl DiopserParams {
pub fn new(should_update_filters: Arc) -> Self {
let trigger_filter_update =
Arc::new(move |_| should_update_filters.store(true, Ordering::Release));
Self {
filter_stages: IntParam::new(
"Filter Stages",
0,
Range::Linear {
min: 0,
max: MAX_NUM_FILTERS as i32,
},
)
.with_callback(trigger_filter_update),
// Smoothed parameters don't need the callback as we can just look at whether the
// smoother is still smoothing
filter_frequency: FloatParam::new(
"Filter Frequency",
200.0,
Range::Skewed {
min: 5.0, // This must never reach 0
max: 20_000.0,
factor: Range::skew_factor(-2.5),
},
)
// This needs quite a bit of smoothing to avoid artifacts
.with_smoother(SmoothingStyle::Logarithmic(100.0))
.with_unit(" Hz")
.with_value_to_string(formatters::f32_rounded(0)),
filter_resonance: FloatParam::new(
"Filter Resonance",
// The actual default neutral Q-value would be `sqrt(2) / 2`, but this value
// produces slightly less ringing.
0.5,
Range::Skewed {
min: 0.01, // This must also never reach 0
max: 30.0,
factor: Range::skew_factor(-2.5),
},
)
.with_smoother(SmoothingStyle::Logarithmic(100.0))
.with_value_to_string(formatters::f32_rounded(2)),
automation_precision: FloatParam::new(
"Automation precision",
normalize_automation_precision(128),
Range::Linear { min: 0.0, max: 1.0 },
)
.with_unit("%")
.with_value_to_string(Arc::new(|value| format!("{:.0}", value * 100.0))),
very_important: BoolParam::new("Don't touch this", true).with_value_to_string(
Arc::new(|value| String::from(if value { "please don't" } else { "stop it" })),
),
}
}
}
impl Plugin for Diopser {
const NAME: &'static str = "Diopser (WIP port)";
const VENDOR: &'static str = "Robbert van der Helm";
const URL: &'static str = "https://github.com/robbert-vdh/nih-plug";
const EMAIL: &'static str = "mail@robbertvanderhelm.nl";
const VERSION: &'static str = "0.2.0";
const DEFAULT_NUM_INPUTS: u32 = 2;
const DEFAULT_NUM_OUTPUTS: u32 = 2;
fn params(&self) -> Pin<&dyn Params> {
self.params.as_ref()
}
fn accepts_bus_config(&self, config: &BusConfig) -> bool {
// This works with any symmetrical IO layout
config.num_input_channels == config.num_output_channels && config.num_input_channels > 0
}
fn initialize(
&mut self,
bus_config: &BusConfig,
buffer_config: &BufferConfig,
_context: &mut impl ProcessContext,
) -> bool {
self.filters =
vec![[Default::default(); MAX_NUM_FILTERS]; bus_config.num_input_channels as usize];
// Initialize the filters on the first process call
self.sample_rate = buffer_config.sample_rate;
self.should_update_filters.store(true, Ordering::Release);
true
}
fn process(
&mut self,
buffer: &mut Buffer,
_context: &mut impl ProcessContext,
) -> ProcessStatus {
// Since this is an expensive operation, only update the filters when it's actually
// necessary, and allow smoothing only every n samples using the automation precision
// parameter
let smoothing_interval =
unnormalize_automation_precision(self.params.automation_precision.value);
for mut channel_samples in buffer.iter_mut() {
self.maybe_update_filters(smoothing_interval);
// We get better cache locality by iterating over the filters and then over the channels
for filter_idx in 0..self.params.filter_stages.value as usize {
// Because of this filter_idx outer loop we can't directly iterate over
// `channel_samples` as the iterator would be empty after the first loop
for (sample, filters) in channel_samples.iter_mut().zip(self.filters.iter_mut()) {
*sample = filters[filter_idx].process(*sample);
}
}
}
ProcessStatus::Normal
}
}
impl Diopser {
/// Check if the filters need to be updated beased on [Self::should_update_filters] and the
/// smoothing interval, and update them as needed.
fn maybe_update_filters(&mut self, smoothing_interval: u32) {
let should_update_filters = self
.should_update_filters
.compare_exchange(true, false, Ordering::Acquire, Ordering::Relaxed)
.is_ok()
|| ((self.params.filter_frequency.smoothed.is_smoothing()
|| self.params.filter_resonance.smoothed.is_smoothing())
&& self.next_filter_smoothing_in <= 1);
if should_update_filters {
self.update_filters(smoothing_interval);
self.next_filter_smoothing_in = smoothing_interval as i32;
} else {
self.next_filter_smoothing_in -= 1;
}
}
/// Recompute the filter coefficients based on the smoothed paraetersm. We can skip forwardq in
/// larger steps to reduce the DSP load.
fn update_filters(&mut self, smoothing_interval: u32) {
let coefficients = filter::BiquadCoefficients::allpass(
self.sample_rate,
self.params
.filter_frequency
.smoothed
.next_step(smoothing_interval),
self.params
.filter_resonance
.smoothed
.next_step(smoothing_interval),
);
for channel in self.filters.iter_mut() {
for filter in channel
.iter_mut()
.take(self.params.filter_stages.value as usize)
{
filter.coefficients = coefficients;
}
}
}
}
fn normalize_automation_precision(step_size: u32) -> f32 {
(MAX_AUTOMATION_STEP_SIZE - step_size) as f32
/ (MAX_AUTOMATION_STEP_SIZE - MIN_AUTOMATION_STEP_SIZE) as f32
}
fn unnormalize_automation_precision(normalized: f32) -> u32 {
MAX_AUTOMATION_STEP_SIZE
- (normalized * (MAX_AUTOMATION_STEP_SIZE - MIN_AUTOMATION_STEP_SIZE) as f32).round() as u32
}
impl Vst3Plugin for Diopser {
const VST3_CLASS_ID: [u8; 16] = *b"DiopserPlugRvdH.";
const VST3_CATEGORIES: &'static str = "Fx|Filter";
}
nih_export_vst3!(Diopser);