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nih-plug/plugins/puberty_simulator/src/lib.rs

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// Puberty Simulator: the next generation in voice change simulation technology
// Copyright (C) 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 <https://www.gnu.org/licenses/>.
use fftw::array::AlignedVec;
use fftw::plan::{C2RPlan, C2RPlan32, R2CPlan, R2CPlan32};
use fftw::types::{c32, Flag};
use nih_plug::prelude::*;
use std::f32;
use std::pin::Pin;
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use std::sync::Arc;
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const MIN_WINDOW_SIZE: usize = 64;
const DEFAULT_WINDOW_SIZE: usize = 1024;
const MAX_WINDOW_SIZE: usize = 32768;
const MIN_OVERLAP_TIMES: usize = 2;
const DEFAULT_OVERLAP_TIMES: usize = 4;
const MAX_OVERLAP_TIMES: usize = 32;
struct PubertySimulator {
params: Pin<Box<PubertySimulatorParams>>,
/// An adapter that performs most of the overlap-add algorithm for us.
stft: util::StftHelper,
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/// Contains a Hann window function of the current window length, passed to the overlap-add
/// helper. Allocated with a `MAX_WINDOW_SIZE` initial capacity.
window_function: Vec<f32>,
/// The algorithms for the FFT and IFFT operations.
plan: Plan,
/// Scratch buffers for computing our FFT. The [`StftHelper`] already contains a buffer for the
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/// real values. This type cannot be resized, so we'll simply take a slice of it with the
/// correct length instead.
complex_fft_scratch_buffer: AlignedVec<c32>,
}
/// FFTW uses raw pointers which aren't Send+Sync, so we'll wrap this in a separate struct.
struct Plan {
r2c_plan: R2CPlan32,
c2r_plan: C2RPlan32,
}
unsafe impl Send for Plan {}
unsafe impl Sync for Plan {}
#[derive(Params)]
struct PubertySimulatorParams {
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/// The pitch change in octaves.
#[id = "pitch"]
pitch_octaves: FloatParam,
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/// The size of the FFT window as a power of two (to prevent invalid inputs).
#[id = "wndsz"]
window_size_order: IntParam,
/// The amount of overlap to use in the overlap-add algorithm as a power of two (again to
/// prevent invalid inputs).
#[id = "ovrlap"]
overlap_times_order: IntParam,
}
impl Default for PubertySimulator {
fn default() -> Self {
Self {
params: Box::pin(PubertySimulatorParams::default()),
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stft: util::StftHelper::new(2, MAX_WINDOW_SIZE),
window_function: Vec::with_capacity(MAX_WINDOW_SIZE),
plan: Plan {
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// These will be initialized with proper values during the initialization
r2c_plan: R2CPlan32::aligned(&[1], Flag::MEASURE).unwrap(),
c2r_plan: C2RPlan32::aligned(&[1], Flag::MEASURE).unwrap(),
},
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complex_fft_scratch_buffer: AlignedVec::new(MAX_WINDOW_SIZE / 2 + 1),
}
}
}
impl Default for PubertySimulatorParams {
fn default() -> Self {
let power_of_two_val2str = Arc::new(|value| format!("{}", 1 << value));
let power_of_two_str2val =
Arc::new(|string: &str| string.parse().ok().map(|n: i32| (n as f32).log2() as i32));
Self {
pitch_octaves: FloatParam::new(
"Pitch",
-1.0,
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FloatRange::SymmetricalSkewed {
min: -5.0,
max: 5.0,
factor: FloatRange::skew_factor(-2.0),
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center: 0.0,
},
)
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// This doesn't need smoothing to prevent zippers because we're already going
// overlap-add, but sounds kind of slick
.with_smoother(SmoothingStyle::Linear(100.0))
.with_unit(" Octaves")
.with_value_to_string(formatters::f32_rounded(2)),
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window_size_order: IntParam::new(
"Window Size",
(DEFAULT_WINDOW_SIZE as f32).log2() as i32,
IntRange::Linear {
min: (MIN_WINDOW_SIZE as f32).log2() as i32,
max: (MAX_WINDOW_SIZE as f32).log2() as i32,
},
)
.with_value_to_string(power_of_two_val2str.clone())
.with_string_to_value(power_of_two_str2val.clone()),
overlap_times_order: IntParam::new(
"Window Overlap",
(DEFAULT_OVERLAP_TIMES as f32).log2() as i32,
IntRange::Linear {
min: (MIN_OVERLAP_TIMES as f32).log2() as i32,
max: (MAX_OVERLAP_TIMES as f32).log2() as i32,
},
)
.with_value_to_string(power_of_two_val2str)
.with_string_to_value(power_of_two_str2val),
}
}
}
impl Plugin for PubertySimulator {
const NAME: &'static str = "Puberty Simulator";
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 = "0.1.0";
const DEFAULT_NUM_INPUTS: u32 = 2;
const DEFAULT_NUM_OUTPUTS: u32 = 2;
const ACCEPTS_MIDI: bool = false;
fn params(&self) -> Pin<&dyn Params> {
self.params.as_ref()
}
fn accepts_bus_config(&self, config: &BusConfig) -> bool {
// We'll only do stereo for simplicity's sake
config.num_input_channels == config.num_output_channels && config.num_input_channels == 2
}
fn initialize(
&mut self,
_bus_config: &BusConfig,
_buffer_config: &BufferConfig,
context: &mut impl ProcessContext,
) -> bool {
// Normally we'd also initialize the STFT helper for the correct channel count here, but we
// only do stereo so that's not necessary
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let window_size = self.window_size();
if self.window_function.len() != window_size {
self.resize_for_window(window_size);
context.set_latency_samples(self.stft.latency_samples());
}
true
}
fn reset(&mut self) {
// This zeroes out the buffers
self.stft.set_block_size(self.window_size());
}
fn process(&mut self, buffer: &mut Buffer, context: &mut impl ProcessContext) -> ProcessStatus {
// Compensate for the window function, the overlap, and the extra gain introduced by the
// IDFT operation
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let window_size = self.window_size();
let overlap_times = self.overlap_times();
let sample_rate = context.transport().sample_rate;
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let gain_compensation: f32 = 1.0 / (overlap_times as f32).log2() / window_size as f32;
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// If the window size has changed since the last process call, reset the buffers and chance
// our latency. All of these buffers already have enough capacity
if self.window_function.len() != window_size {
self.resize_for_window(window_size);
context.set_latency_samples(self.stft.latency_samples());
}
// Since this type cannot be resized, we'll simply slice the full buffer instead
let complex_fft_scratch_buffer =
&mut self.complex_fft_scratch_buffer.as_slice_mut()[..window_size / 2 + 1];
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let mut smoothed_pitch_value = 0.0;
self.stft.process_overlap_add(
buffer,
&self.window_function,
overlap_times,
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|channel_idx, real_fft_scratch_buffer| {
// This loop runs whenever there's a block ready, so we can't easily do any post- or
// pre-processing without muddying up the interface. But if this is channel 0, then
// we're dealing with a new block. We'll use this for our parameter smoothing.
if channel_idx == 0 {
smoothed_pitch_value = self
.params
.pitch_octaves
.smoothed
.next_step((window_size / overlap_times) as u32);
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}
// Negated because pitching down should cause us to take values from higher frequency bins
let frequency_multiplier = 2.0f32.powf(-smoothed_pitch_value);
// Forward FFT, the helper has already applied window function
self.plan
.r2c_plan
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.r2c(real_fft_scratch_buffer, complex_fft_scratch_buffer)
.unwrap();
// This simply interpolates between the complex sinusoids from the frequency bins
// for this bin's frequency scaled by the octave pitch multiplies. The iteration
// order dependson the pitch shifting direction since we're doing it in place.
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let num_bins = complex_fft_scratch_buffer.len();
let mut process_bin = |bin_idx| {
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let frequency = bin_idx as f32 / window_size as f32 * sample_rate;
let target_frequency = frequency * frequency_multiplier;
// Simple linear interpolation
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let target_bin = target_frequency / sample_rate * window_size as f32;
let target_bin_low = target_bin.floor() as usize;
let target_bin_high = target_bin.ceil() as usize;
let target_low_t = target_bin % 1.0;
let target_high_t = 1.0 - target_low_t;
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let target_low = complex_fft_scratch_buffer
.get(target_bin_low)
.copied()
.unwrap_or_default();
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let target_high = complex_fft_scratch_buffer
.get(target_bin_high)
.copied()
.unwrap_or_default();
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complex_fft_scratch_buffer[bin_idx] = (target_low * target_low_t
+ target_high * target_high_t)
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* 3.0 // Random extra gain, not sure
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* gain_compensation;
};
if frequency_multiplier >= 1.0 {
for bin_idx in 0..num_bins {
process_bin(bin_idx);
}
} else {
for bin_idx in (0..num_bins).rev() {
process_bin(bin_idx);
}
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}
// Inverse FFT back into the scratch buffer. This will be added to a ring buffer
// which gets written back to the host at a one block delay.
self.plan
.c2r_plan
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.c2r(complex_fft_scratch_buffer, real_fft_scratch_buffer)
.unwrap();
},
);
ProcessStatus::Normal
}
}
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impl PubertySimulator {
fn window_size(&self) -> usize {
1 << self.params.window_size_order.value as usize
}
fn overlap_times(&self) -> usize {
1 << self.params.overlap_times_order.value as usize
}
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/// `window_size` should not exceed `MAX_WINDOW_SIZE` or this will allocate.
fn resize_for_window(&mut self, window_size: usize) {
self.stft.set_block_size(window_size);
self.window_function.resize(window_size, 0.0);
util::window::hann_in_place(&mut self.window_function);
self.plan.r2c_plan = R2CPlan32::aligned(&[window_size], Flag::MEASURE).unwrap();
self.plan.c2r_plan = C2RPlan32::aligned(&[window_size], Flag::MEASURE).unwrap();
}
}
impl ClapPlugin for PubertySimulator {
const CLAP_ID: &'static str = "nl.robbertvanderhelm.puberty-simulator";
const CLAP_DESCRIPTION: &'static str = "Simulates a pitched down cracking voice";
const CLAP_FEATURES: &'static [&'static str] =
&["audio_effect", "stereo", "glitch", "pitch_shifter"];
const CLAP_MANUAL_URL: &'static str = Self::URL;
const CLAP_SUPPORT_URL: &'static str = Self::URL;
}
impl Vst3Plugin for PubertySimulator {
const VST3_CLASS_ID: [u8; 16] = *b"PubertySim..RvdH";
const VST3_CATEGORIES: &'static str = "Fx|Pitch Shift";
}
nih_export_clap!(PubertySimulator);
nih_export_vst3!(PubertySimulator);