HexoDSP/src/matrix.rs

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// Copyright (c) 2021 Weird Constructor <weirdconstructor@gmail.com>
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// This file is a part of HexoDSP. Released under GPL-3.0-or-later.
// See README.md and COPYING for details.
use crate::dsp::tracker::PatternData;
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use crate::dsp::{NodeId, NodeInfo, ParamId, SAtom};
use crate::matrix_repr::*;
pub use crate::monitor::MON_SIG_CNT;
pub use crate::nodes::MinMaxMonitorSamples;
use crate::nodes::{NodeConfigurator, NodeGraphOrdering, NodeProg, MAX_ALLOCATED_NODES};
pub use crate::CellDir;
use std::collections::{HashMap, HashSet};
/// This is a cell/tile of the hexagonal [Matrix].
///
/// The [Matrix] stores it to keep track of the graphical representation
/// of the hexagonal tilemap. Using [Matrix::place] you can place new cells.
///
///```
/// use hexodsp::*;
///
/// let (node_conf, mut node_exec) = new_node_engine();
/// let mut matrix = Matrix::new(node_conf, 3, 3);
///
/// matrix.place(
/// 2, 2,
/// Cell::empty(NodeId::Sin(0))
/// .input(Some(0), None, None)
/// .out(None, None, Some(0)));
///
/// matrix.sync().unwrap();
///```
#[derive(Debug, Clone, Copy, Eq, PartialEq, Ord, PartialOrd)]
pub struct Cell {
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node_id: NodeId,
x: u8,
y: u8,
/// Top-Right output
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out1: Option<u8>,
/// Bottom-Right output
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out2: Option<u8>,
/// Bottom output
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out3: Option<u8>,
/// Top input
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in1: Option<u8>,
/// Top-Left input
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in2: Option<u8>,
/// Bottom-Left input
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in3: Option<u8>,
}
impl Cell {
/// This is the main contructor of a [Cell].
/// Empty means that there is no associated position of this cell
/// and no inputs/outputs have been assigned. Use the methods [Cell::input] and [Cell::out]
/// to assign inputs / outputs.
///
///```
/// use hexodsp::*;
///
/// let some_cell =
/// Cell::empty(NodeId::Sin(0))
/// .input(None, Some(0), Some(0))
/// .out(None, Some(0), Some(0));
///```
pub fn empty(node_id: NodeId) -> Self {
Self::empty_at(node_id, 0, 0)
}
/// This is an alternative constructor, in case you know the position of the
/// cell before you got it from the Matrix.
pub fn empty_at(node_id: NodeId, x: u8, y: u8) -> Self {
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Self { node_id, x, y, out1: None, out2: None, out3: None, in1: None, in2: None, in3: None }
}
/// Returns a serializable representation of this [Matrix] [Cell].
///
/// See also [CellRepr].
///
///```
/// use hexodsp::*;
///
/// let some_cell =
/// Cell::empty(NodeId::Sin(0))
/// .input(None, Some(0), Some(0))
/// .out(None, Some(0), Some(0));
///
/// let repr = some_cell.to_repr();
/// assert_eq!(
/// repr.serialize().to_string(),
/// "[\"sin\",0,0,0,[-1,\"freq\",\"freq\"],[-1,\"sig\",\"sig\"]]");
///```
pub fn to_repr(&self) -> CellRepr {
CellRepr {
node_id: self.node_id,
x: self.x as usize,
y: self.y as usize,
out: [
self.out1.map(|v| v as i16).unwrap_or(-1),
self.out2.map(|v| v as i16).unwrap_or(-1),
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self.out3.map(|v| v as i16).unwrap_or(-1),
],
inp: [
self.in1.map(|v| v as i16).unwrap_or(-1),
self.in2.map(|v| v as i16).unwrap_or(-1),
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self.in3.map(|v| v as i16).unwrap_or(-1),
],
}
}
pub fn from_repr(repr: &CellRepr) -> Self {
Self {
node_id: repr.node_id,
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x: repr.x as u8,
y: repr.y as u8,
out1: if repr.out[0] < 0 { None } else { Some(repr.out[0] as u8) },
out2: if repr.out[1] < 0 { None } else { Some(repr.out[1] as u8) },
out3: if repr.out[2] < 0 { None } else { Some(repr.out[2] as u8) },
in1: if repr.inp[0] < 0 { None } else { Some(repr.inp[0] as u8) },
in2: if repr.inp[1] < 0 { None } else { Some(repr.inp[1] as u8) },
in3: if repr.inp[2] < 0 { None } else { Some(repr.inp[2] as u8) },
}
}
pub fn with_pos_of(&self, other: Cell) -> Self {
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let mut new = *self;
new.x = other.x;
new.y = other.y;
new
}
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pub fn is_empty(&self) -> bool {
self.node_id == NodeId::Nop
}
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pub fn node_id(&self) -> NodeId {
self.node_id
}
pub fn set_node_id(&mut self, new_id: NodeId) {
self.node_id = new_id;
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// With a new node id, we also need new I/Os:
self.in1 = None;
self.in2 = None;
self.in3 = None;
self.out1 = None;
self.out2 = None;
self.out3 = None;
}
pub fn label<'a>(&self, buf: &'a mut [u8]) -> Option<&'a str> {
use std::io::Write;
let mut cur = std::io::Cursor::new(buf);
if self.node_id == NodeId::Nop {
return None;
}
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// let node_info = infoh.from_node_id(self.node_id);
match write!(cur, "{}", self.node_id) {
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Ok(_) => {
let len = cur.position() as usize;
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Some(std::str::from_utf8(&(cur.into_inner())[0..len]).unwrap())
}
Err(_) => None,
}
}
pub fn pos(&self) -> (usize, usize) {
(self.x as usize, self.y as usize)
}
pub fn offs_dir(&mut self, dir: CellDir) -> bool {
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if let Some(new_pos) = dir.offs_pos((self.x as usize, self.y as usize)) {
self.x = new_pos.0 as u8;
self.y = new_pos.1 as u8;
true
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} else {
false
}
}
pub fn has_dir_set(&self, dir: CellDir) -> bool {
match dir {
CellDir::TR => self.out1.is_some(),
CellDir::BR => self.out2.is_some(),
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CellDir::B => self.out3.is_some(),
CellDir::BL => self.in3.is_some(),
CellDir::TL => self.in2.is_some(),
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CellDir::T => self.in1.is_some(),
CellDir::C => false,
}
}
pub fn local_port_idx(&self, dir: CellDir) -> Option<u8> {
match dir {
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CellDir::TR => self.out1,
CellDir::BR => self.out2,
CellDir::B => self.out3,
CellDir::BL => self.in3,
CellDir::TL => self.in2,
CellDir::T => self.in1,
CellDir::C => None,
}
}
pub fn clear_io_dir(&mut self, dir: CellDir) {
match dir {
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CellDir::TR => {
self.out1 = None;
}
CellDir::BR => {
self.out2 = None;
}
CellDir::B => {
self.out3 = None;
}
CellDir::BL => {
self.in3 = None;
}
CellDir::TL => {
self.in2 = None;
}
CellDir::T => {
self.in1 = None;
}
CellDir::C => {
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self.out1 = None;
self.out2 = None;
self.out3 = None;
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self.in1 = None;
self.in2 = None;
self.in3 = None;
}
}
}
pub fn set_io_dir(&mut self, dir: CellDir, idx: usize) {
match dir {
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CellDir::TR => {
self.out1 = Some(idx as u8);
}
CellDir::BR => {
self.out2 = Some(idx as u8);
}
CellDir::B => {
self.out3 = Some(idx as u8);
}
CellDir::BL => {
self.in3 = Some(idx as u8);
}
CellDir::TL => {
self.in2 = Some(idx as u8);
}
CellDir::T => {
self.in1 = Some(idx as u8);
}
CellDir::C => {}
}
}
pub fn input(mut self, i1: Option<u8>, i2: Option<u8>, i3: Option<u8>) -> Self {
self.in1 = i1;
self.in2 = i2;
self.in3 = i3;
self
}
pub fn out(mut self, o1: Option<u8>, o2: Option<u8>, o3: Option<u8>) -> Self {
self.out1 = o1;
self.out2 = o2;
self.out3 = o3;
self
}
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/// Finds the first free input (one without an adjacent cell). If any free input
/// has an assigned input, that edge is returned.
/// With `dir` you can specify input with `CellDir::T`, output with `CellDir::B`
/// and any with `CellDir::C`.
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pub fn find_first_adjacent_free(
&self,
m: &mut Matrix,
dir: CellDir,
) -> Option<(CellDir, Option<u8>)> {
let mut free_ports = vec![];
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let options: &[CellDir] = if dir == CellDir::C {
&[CellDir::T, CellDir::TL, CellDir::BL, CellDir::TR, CellDir::BR, CellDir::B]
} else if dir.is_input() {
&[CellDir::T, CellDir::TL, CellDir::BL]
} else {
&[CellDir::TR, CellDir::BR, CellDir::B]
};
for dir in options {
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if let Some(pos) = dir.offs_pos((self.x as usize, self.y as usize)) {
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if m.get(pos.0, pos.1).map(|c| c.is_empty()).unwrap_or(false) {
free_ports.push(dir);
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}
}
}
for in_dir in &free_ports {
if self.has_dir_set(**in_dir) {
return Some((**in_dir, self.local_port_idx(**in_dir)));
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}
}
if free_ports.len() > 0 {
Some((*free_ports[0], None))
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} else {
None
}
}
/// Finds the all adjacent free places around the current cell.
/// With `dir` you can specify input with `CellDir::T`, output with `CellDir::B`
/// and any with `CellDir::C`.
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pub fn find_all_adjacent_free(
&self,
m: &mut Matrix,
dir: CellDir,
) -> Vec<(CellDir, (usize, usize))> {
let mut free_ports = vec![];
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let options: &[CellDir] = if dir == CellDir::C {
&[CellDir::T, CellDir::TL, CellDir::BL, CellDir::TR, CellDir::BR, CellDir::B]
} else if dir.is_input() {
&[CellDir::T, CellDir::TL, CellDir::BL]
} else {
&[CellDir::TR, CellDir::BR, CellDir::B]
};
for dir in options {
if let Some(pos) = dir.offs_pos((self.x as usize, self.y as usize)) {
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if m.get(pos.0, pos.1).map(|c| c.is_empty()).unwrap_or(false) {
free_ports.push((*dir, pos));
}
}
}
free_ports.to_vec()
}
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/// If the port is connected, it will return the position of the other cell.
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pub fn is_port_dir_connected(&self, m: &mut Matrix, dir: CellDir) -> Option<(usize, usize)> {
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if self.has_dir_set(dir) {
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if let Some(new_pos) = dir.offs_pos((self.x as usize, self.y as usize)) {
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if let Some(dst_cell) = m.get(new_pos.0, new_pos.1) {
if dst_cell.has_dir_set(dir.flip()) {
return Some(new_pos);
}
}
}
}
None
}
}
use std::sync::{Arc, Mutex};
/// To report back cycle errors from [Matrix::check] and [Matrix::sync].
#[derive(Debug, Clone, Copy, PartialEq, Eq, PartialOrd, Ord)]
pub enum MatrixError {
CycleDetected,
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DuplicatedInput { output1: (NodeId, u8), output2: (NodeId, u8) },
NonEmptyCell { cell: Cell },
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PosOutOfRange,
}
/// An intermediate data structure to store a single edge in the [Matrix].
#[derive(Debug, Clone, Copy, PartialEq, Eq, PartialOrd, Ord)]
struct Edge {
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from: NodeId,
from_out: u8,
to: NodeId,
to_input: u8,
}
/// This trait can be passed into [Matrix] as trait object
/// to get feedback when things change.
pub trait MatrixObserver {
/// Called when a property is changing eg. via [Matrix::set_prop]
/// or some other yet unknown method.
/// Not called, when [MatrixObserver::update_all] tells you that
/// everything has changed.
fn update_prop(&self, key: &str);
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/// Called when a new cell is monitored via [Matrix::monitor_cell].
/// Not called, when [MatrixObserver::update_all] tells you that
/// everything has changed.
fn update_monitor(&self, cell: &Cell);
/// Called when a parameter or it's modulation amount is changing.
/// Not called, when [MatrixObserver::update_all] tells you that
/// everything has changed.
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fn update_param(&self, param_id: &ParamId);
/// Called when the matrix graph was changed, usually called
/// when [Matrix::sync] is called.
/// Usually also called when [MatrixObserver::update_all] was called.
fn update_matrix(&self);
/// Called when the complete matrix has been changing.
/// The called then needs up update all it's internal state it knows
/// about [Matrix].
fn update_all(&self);
}
pub struct Matrix {
/// The node configurator to control the backend.
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config: NodeConfigurator,
/// Holds the actual 2 dimensional matrix cells in one big vector.
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matrix: Vec<Cell>,
/// Width of the matrix.
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w: usize,
/// Height of the matrix.
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h: usize,
/// The retained data structure of the graph topology.
/// This is used by `sync()` and `check()` to determine the
/// order and cycle freeness of the graph.
/// We store it in this field, so we don't have to reallocate it
/// all the time.
graph_ordering: NodeGraphOrdering,
/// Holds a saved version of the `matrix` field
/// to roll back changes that might introduce cycles or
/// other invalid topology.
saved_matrix: Option<Vec<Cell>>,
/// Stores the edges which are extracted from the `matrix` field
/// by [Matrix::update_graph_ordering_and_edges], which is used
/// by [Matrix::sync] and [Matrix::check].
edges: Vec<Edge>,
/// Holds custom user defined properties. They are saved with
/// the [MatrixRepr] and you can set and retrieve these properties
/// using [Matrix::set_prop] and [Matrix::get_prop].
properties: HashMap<String, SAtom>,
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/// Stores the [crate::dsp::ParamId] of the inputs that have an output
/// assigned to them. It's updates when [Matrix::edges] is updated and used
/// by [Matrix::param_input_is_used] to return whether a parameter is
/// controlled by some output port.
assigned_inputs: HashSet<ParamId>,
/// Holds the currently monitored cell.
monitored_cell: Cell,
/// A counter that increases for each sync(), it can be used
/// by other components of the application to detect changes in
/// the matrix to resync their own data.
gen_counter: usize,
/// A trait object that tracks changed on the [Matrix].
observer: Option<Arc<dyn MatrixObserver>>,
}
unsafe impl Send for Matrix {}
impl Matrix {
pub fn new(config: NodeConfigurator, w: usize, h: usize) -> Self {
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let mut matrix: Vec<Cell> = Vec::new();
matrix.resize(w * h, Cell::empty(NodeId::Nop));
Self {
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monitored_cell: Cell::empty(NodeId::Nop),
gen_counter: 0,
saved_matrix: None,
graph_ordering: NodeGraphOrdering::new(),
edges: Vec::with_capacity(MAX_ALLOCATED_NODES * 2),
assigned_inputs: HashSet::new(),
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properties: HashMap::new(),
observer: None,
config,
w,
h,
matrix,
}
}
/// Assigns the [MatrixObserver] to observe changes on the [Matrix].
pub fn set_observer(&mut self, obs: Arc<dyn MatrixObserver>) {
self.observer = Some(obs);
}
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pub fn size(&self) -> (usize, usize) {
(self.w, self.h)
}
pub fn unique_index_for(&self, node_id: &NodeId) -> Option<usize> {
self.config.unique_index_for(node_id)
}
pub fn info_for(&self, node_id: &NodeId) -> Option<NodeInfo> {
Some(self.config.node_by_id(&node_id)?.0.clone())
}
pub fn phase_value_for(&self, node_id: &NodeId) -> f32 {
self.config.phase_value_for(node_id)
}
pub fn led_value_for(&self, node_id: &NodeId) -> f32 {
self.config.led_value_for(node_id)
}
pub fn update_filters(&mut self) {
self.config.update_filters();
}
pub fn filtered_led_for(&mut self, ni: &NodeId) -> (f32, f32) {
self.config.filtered_led_for(ni)
}
pub fn filtered_out_fb_for(&mut self, ni: &NodeId, out: u8) -> (f32, f32) {
self.config.filtered_out_fb_for(ni, out)
}
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pub fn get_pattern_data(&self, tracker_id: usize) -> Option<Arc<Mutex<PatternData>>> {
self.config.get_pattern_data(tracker_id)
}
/// Checks if pattern data updates need to be sent to the
/// DSP thread.
pub fn check_pattern_data(&mut self, tracker_id: usize) {
self.config.check_pattern_data(tracker_id)
}
/// Saves the state of the hexagonal grid layout.
/// This is usually used together with [Matrix::check]
/// and [Matrix::restore_matrix] to try if changes on
/// the matrix using [Matrix::place] (or other grid changing
/// functions).
///
/// It is advised to use convenience functions such as [Matrix::change_matrix].
///
/// See also [Matrix::change_matrix], [Matrix::check] and [Matrix::sync].
pub fn save_matrix(&mut self) {
let matrix = self.matrix.clone();
self.saved_matrix = Some(matrix);
}
/// Restores the previously via [Matrix::save_matrix] saved matrix.
///
/// It is advised to use convenience functions such as [Matrix::change_matrix].
///
/// See also [Matrix::change_matrix], [Matrix::check].
pub fn restore_matrix(&mut self) {
if let Some(matrix) = self.saved_matrix.take() {
self.matrix = matrix;
}
}
/// Helps encapsulating changes of the matrix and wraps them into
/// a [Matrix::save_matrix], [Matrix::check] and [Matrix::restore_matrix].
///
///```
/// use hexodsp::*;
///
/// let (node_conf, mut node_exec) = new_node_engine();
/// let mut matrix = Matrix::new(node_conf, 3, 3);
///
/// let res = matrix.change_matrix(|matrix| {
/// matrix.place(0, 1,
/// Cell::empty(NodeId::Sin(1))
/// .input(Some(0), None, None));
/// matrix.place(0, 0,
/// Cell::empty(NodeId::Sin(1))
/// .out(None, None, Some(0)));
/// });
///
/// // In this examples case there is an error, as we created
/// // a cycle:
/// assert!(res.is_err());
///```
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pub fn change_matrix<F>(&mut self, mut f: F) -> Result<(), MatrixError>
where
F: FnMut(&mut Self),
{
self.save_matrix();
f(self);
if let Err(e) = self.check() {
self.restore_matrix();
Err(e)
} else {
Ok(())
}
}
/// Like [Matrix::change_matrix] but the function passed to this
/// needs to return a `Result<(), MatrixError>`.
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pub fn change_matrix_err<F>(&mut self, mut f: F) -> Result<(), MatrixError>
where
F: FnMut(&mut Self) -> Result<(), MatrixError>,
{
self.save_matrix();
if let Err(e) = f(self) {
self.restore_matrix();
return Err(e);
}
if let Err(e) = self.check() {
self.restore_matrix();
Err(e)
} else {
Ok(())
}
}
/// Tries to place all `cells` at once, if they are placed in empty
/// cells only! Returns an error of the destination cell is not empty
/// or out of range, or if the placement of the cluster results in any
/// other inconsistencies.
///
/// This action must be wrapped with [Matrix::change_matrix_err]!
///
/// Restores the matrix to the previous state if placing fails.
pub fn place_multiple(&mut self, cells: &[Cell]) -> Result<(), MatrixError> {
for cell in cells {
let x = cell.pos().0;
let y = cell.pos().1;
if let Some(existing) = self.get(x, y) {
if !existing.is_empty() {
return Err(MatrixError::NonEmptyCell { cell: *existing });
}
self.place(x, y, *cell);
} else {
return Err(MatrixError::PosOutOfRange);
}
}
if let Err(e) = self.check() {
Err(e)
} else {
Ok(())
}
}
/// Inserts a cell into the hexagonal grid of the matrix.
/// You have to make sure that the resulting DSP graph topology
/// does not have cycles, otherwise an upload to the DSP thread via
/// [Matrix::sync] will fail.
///
/// If you try to place a cell outside the grid, it will not be placed
/// and just silently ignored.
///
/// You can safely check the DSP topology of changes using
/// the convenience function [Matrix::change_matrix]
/// or alternatively: [Matrix::save_matrix], [Matrix::restore_matrix]
/// and [Matrix::check].
///
/// See also the example in [Matrix::change_matrix] and [Matrix::check].
pub fn place(&mut self, x: usize, y: usize, mut cell: Cell) {
cell.x = x as u8;
cell.y = y as u8;
if x >= self.w || y >= self.h {
return;
}
self.matrix[x * self.h + y] = cell;
}
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/// Set the cell at it's assigned position. This is basically a shorthand
/// for [Matrix::place]. As if you would call:
/// `m.place(cell.pos().0, cell.pos().1, cell)`.
pub fn place_cell(&mut self, cell: Cell) {
self.place(cell.pos().0, cell.pos().1, cell);
}
/// Clears the contents of the matrix. It's completely empty after this.
pub fn clear(&mut self) {
for cell in self.matrix.iter_mut() {
*cell = Cell::empty(NodeId::Nop);
}
self.graph_ordering.clear();
self.edges.clear();
self.assigned_inputs.clear();
self.saved_matrix = None;
self.properties.clear();
self.config.delete_nodes();
self.monitor_cell(Cell::empty(NodeId::Nop));
let _ = self.sync();
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if let Some(obs) = &self.observer {
obs.update_all();
}
}
/// Iterates through all atoms. This is useful for reading
/// all the atoms after a [MatrixRepr] has been loaded with [Matrix::from_repr].
pub fn for_each_atom<F: FnMut(usize, ParamId, &SAtom, Option<f32>)>(&self, f: F) {
self.config.for_each_param(f);
}
/// Returns the DSP graph generation, which is increased
/// after each call to [Matrix::sync].
///
/// This can be used by external components to track if they
/// should update their knowledge of the nodes in the DSP
/// graph. Such as parameter values.
///
/// HexoSynth for instance updates the UI by tracking this value.
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pub fn get_generation(&self) -> usize {
self.gen_counter
}
/// Returns a serializable representation of the matrix.
/// This representation contains all parameters,
/// created nodes, connections and the tracker's pattern data.
///
///```
/// use hexodsp::*;
///
/// let (node_conf, mut _node_exec) = new_node_engine();
/// let mut matrix = Matrix::new(node_conf, 3, 3);
///
/// let sin = NodeId::Sin(2);
///
/// matrix.place(0, 0,
/// Cell::empty(sin)
/// .out(None, Some(0), None));
///
/// let freq_param = sin.inp_param("freq").unwrap();
/// matrix.set_param(freq_param, SAtom::param(-0.1));
///
/// let mut serialized = matrix.to_repr().serialize().to_string();
///
/// assert!(serialized.find("\"sin\",2,0,0,[-1,-1,-1],[-1,\"sig\",-1]").is_some());
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/// assert!(serialized.find("\"freq\",220.0").is_some());
///```
///
/// See also [MatrixRepr::serialize].
pub fn to_repr(&self) -> MatrixRepr {
let (params, atoms) = self.config.dump_param_values();
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let mut cells: Vec<CellRepr> = vec![];
self.for_each(|_x, _y, cell| {
if cell.node_id() != NodeId::Nop {
cells.push(cell.to_repr())
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}
});
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let mut patterns: Vec<Option<PatternRepr>> = vec![];
let mut tracker_id = 0;
while let Some(pdata) = self.get_pattern_data(tracker_id) {
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patterns.push(if pdata.lock().unwrap().is_unset() {
None
} else {
Some(pdata.lock().unwrap().to_repr())
});
tracker_id += 1;
}
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let properties = self.properties.iter().map(|(k, v)| (k.to_string(), v.clone())).collect();
MatrixRepr { cells, params, atoms, patterns, properties, version: 2 }
}
/// Loads the matrix from a previously my [Matrix::to_repr]
/// generated matrix representation.
///
/// This function will call [Matrix::sync] after loading and
/// overwriting the current matrix contents.
pub fn from_repr(&mut self, repr: &MatrixRepr) -> Result<(), MatrixError> {
self.clear();
let normalize_params = repr.version > 1;
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self.config.load_dumped_param_values(&repr.params[..], &repr.atoms[..], normalize_params);
for (key, val) in repr.properties.iter() {
self.properties.insert(key.to_string(), val.clone());
}
for cell_repr in repr.cells.iter() {
let cell = Cell::from_repr(cell_repr);
self.place(cell.x as usize, cell.y as usize, cell);
}
for (tracker_id, pat) in repr.patterns.iter().enumerate() {
if let Some(pat) = pat {
if let Some(pd) = self.get_pattern_data(tracker_id) {
pd.lock().unwrap().from_repr(pat);
}
}
}
let ret = self.sync();
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if let Some(obs) = &self.observer {
obs.update_all();
}
ret
}
/// Saves a property in the matrix, these can be retrieved
/// using [Matrix::get_prop] and are saved/loaded along with
/// the [MatrixRepr]. See also [Matrix::to_repr] and [Matrix::from_repr].
///
///```
/// use hexodsp::*;
///
/// let repr = {
/// let (node_conf, mut _node_exec) = new_node_engine();
/// let mut matrix = Matrix::new(node_conf, 3, 3);
///
/// matrix.set_prop("test", SAtom::setting(31337));
///
/// matrix.to_repr()
/// };
///
/// let (node_conf, mut _node_exec) = new_node_engine();
/// let mut matrix2 = Matrix::new(node_conf, 3, 3);
///
/// matrix2.from_repr(&repr).unwrap();
/// assert_eq!(matrix2.get_prop("test").unwrap().i(), 31337);
///```
pub fn set_prop(&mut self, key: &str, val: SAtom) {
self.gen_counter += 1;
self.properties.insert(key.to_string(), val);
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if let Some(obs) = &self.observer {
obs.update_prop(key);
}
}
/// Retrieves a matrix property. See also [Matrix::set_prop] for an
/// example and more information.
pub fn get_prop(&mut self, key: &str) -> Option<&SAtom> {
self.properties.get(key)
}
/// Receives the most recent data for the monitored signal at index `idx`.
/// Might introduce a short wait, because internally a mutex is still locked.
/// If this leads to stuttering in the UI, we need to change the internal
/// handling to a triple buffer.
pub fn get_minmax_monitor_samples(&mut self, idx: usize) -> &MinMaxMonitorSamples {
self.config.get_minmax_monitor_samples(idx)
}
/// Returns the currently monitored cell.
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pub fn monitored_cell(&self) -> &Cell {
&self.monitored_cell
}
/// Sets the cell to monitor next. Please bear in mind, that you need to
/// call `sync` before retrieving the cell from the matrix, otherwise
/// the node instance might not have been created in the backend yet and
/// we can not start monitoring the cell.
pub fn monitor_cell(&mut self, cell: Cell) {
self.monitored_cell = cell;
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let inputs = [cell.in1, cell.in2, cell.in3];
let outputs = [cell.out1, cell.out2, cell.out3];
self.config.monitor(&cell.node_id, &inputs, &outputs);
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if let Some(obs) = &self.observer {
obs.update_monitor(&self.monitored_cell);
}
}
/// Is called by [Matrix::sync] to refresh the monitored cell.
/// In case the matrix has changed (inputs/outputs of a cell)
/// we show the current state.
///
/// Note, that if the UI actually moved a cell, it needs to
/// monitor the newly moved cell anyways.
fn remonitor_cell(&mut self) {
let m = self.monitored_cell();
if let Some(cell) = self.get(m.x as usize, m.y as usize).copied() {
self.monitor_cell(cell);
}
}
pub fn pop_error(&mut self) -> Option<String> {
self.config.pop_error()
}
/// Retrieve [SAtom] values for input parameters and atoms.
pub fn get_param(&self, param: &ParamId) -> Option<SAtom> {
self.config.get_param(param)
}
/// Assign [SAtom] values to input parameters and atoms.
pub fn set_param(&mut self, param: ParamId, at: SAtom) {
self.config.set_param(param.clone(), at);
self.gen_counter += 1;
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if let Some(obs) = &self.observer {
obs.update_param(&param);
}
}
/// Retrieve the modulation amount of the input parameter.
pub fn get_param_modamt(&self, param: &ParamId) -> Option<f32> {
self.config.get_param_modamt(param)
}
/// Assign or remove modulation of an input parameter.
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pub fn set_param_modamt(
&mut self,
param: ParamId,
modamt: Option<f32>,
) -> Result<(), MatrixError> {
if self.config.set_param_modamt(param.clone(), modamt) {
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if let Some(obs) = &self.observer {
obs.update_param(&param);
}
// XXX: Remove the observer from the matrix, so the sync() does not
// generate a matrix graph update! There is no structural change!
let obs = self.observer.take();
// XXX: sync implicitly increases gen_counter!
let ret = self.sync();
self.observer = obs;
ret
} else {
self.gen_counter += 1;
Ok(())
}
}
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pub fn get_adjacent_output(&self, x: usize, y: usize, dir: CellDir) -> Option<(NodeId, u8)> {
if dir.is_output() {
return None;
}
let cell = self.get_adjacent(x, y, dir)?;
if cell.node_id == NodeId::Nop {
return None;
}
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let cell_out = match dir {
CellDir::T => cell.out3?,
CellDir::TL => cell.out2?,
CellDir::BL => cell.out1?,
_ => {
return None;
}
};
Some((cell.node_id, cell_out))
}
pub fn get_adjacent(&self, x: usize, y: usize, dir: CellDir) -> Option<&Cell> {
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let offs: (i32, i32) = dir.as_offs(x);
let x = x as i32 + offs.0;
let y = y as i32 + offs.1;
if x < 0 || y < 0 || (x as usize) >= self.w || (y as usize) >= self.h {
return None;
}
Some(&self.matrix[(x as usize) * self.h + (y as usize)])
}
pub fn adjacent_edge_has_input(&self, x: usize, y: usize, edge: CellDir) -> bool {
if let Some(cell) = self.get_adjacent(x, y, edge) {
//d// println!(" ADJ CELL: {},{} ({})", cell.x, cell.y, cell.node_id());
match edge {
CellDir::TR => cell.in3.is_some(),
CellDir::BR => cell.in2.is_some(),
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CellDir::B => cell.in1.is_some(),
_ => false,
}
} else {
false
}
}
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/// Retrieves the immediate connections to adjacent cells and returns a list.
///
/// Returns a vector with pairs of this content:
///
/// (
/// (this_cell_connection_dir, this_cell_node_io_index),
/// (other_cell_connection_dir, other_cell_node_io_index, (other_cell_x, other_cell_y))
/// )
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pub fn get_connections(
&self,
x: usize,
y: usize,
) -> Option<Vec<((CellDir, u8), (CellDir, u8, (usize, usize)))>> {
let this_cell = self.get(x, y)?;
let mut ret = vec![];
for edge in 0..6 {
let dir = CellDir::from(edge);
if let Some(node_io_idx) = this_cell.local_port_idx(dir) {
if let Some((nx, ny)) = dir.offs_pos((x, y)) {
if !(nx < self.w && ny < self.h) {
continue;
}
if let Some(other_cell) = self.get(nx, ny) {
if let Some(other_node_io_idx) = other_cell.local_port_idx(dir.flip()) {
ret.push((
(dir, node_io_idx),
(dir.flip(), other_node_io_idx, (nx, ny)),
));
}
}
}
}
}
Some(ret)
}
pub fn for_each<F: FnMut(usize, usize, &Cell)>(&self, mut f: F) {
for x in 0..self.w {
for y in 0..self.h {
let cell = &self.matrix[x * self.h + y];
f(x, y, cell);
}
}
}
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pub fn edge_label<'a>(
&self,
cell: &Cell,
edge: CellDir,
buf: &'a mut [u8],
) -> Option<(&'a str, bool)> {
use std::io::Write;
let mut cur = std::io::Cursor::new(buf);
if cell.node_id == NodeId::Nop {
return None;
}
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let out_idx = match edge {
CellDir::TR => Some(cell.out1),
CellDir::BR => Some(cell.out2),
CellDir::B => Some(cell.out3),
_ => None,
};
let in_idx = match edge {
CellDir::BL => Some(cell.in3),
CellDir::TL => Some(cell.in2),
CellDir::T => Some(cell.in1),
_ => None,
};
let info = self.info_for(&cell.node_id)?;
let mut is_connected_edge = false;
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let edge_str = if let Some(out_idx) = out_idx {
//d// println!(" CHECK ADJ EDGE {},{} @ {:?}", cell.x, cell.y, edge);
is_connected_edge =
self.adjacent_edge_has_input(cell.x as usize, cell.y as usize, edge);
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info.out_name(out_idx? as usize)
} else if let Some(in_idx) = in_idx {
info.in_name(in_idx? as usize)
} else {
None
};
let edge_str = edge_str?;
match write!(cur, "{}", edge_str) {
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Ok(_) => {
let len = cur.position() as usize;
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Some((std::str::from_utf8(&(cur.into_inner())[0..len]).unwrap(), is_connected_edge))
}
Err(_) => None,
}
}
pub fn get_copy(&self, x: usize, y: usize) -> Option<Cell> {
if x >= self.w || y >= self.h {
return None;
}
let mut cell = self.matrix[x * self.h + y];
cell.x = x as u8;
cell.y = y as u8;
Some(cell)
}
pub fn get(&self, x: usize, y: usize) -> Option<&Cell> {
if x >= self.w || y >= self.h {
return None;
}
Some(&self.matrix[x * self.h + y])
}
pub fn param_input_is_used(&self, p: ParamId) -> bool {
self.assigned_inputs.contains(&p)
}
pub fn get_unused_instance_node_id(&self, id: NodeId) -> NodeId {
self.config.unused_instance_node_id(id)
}
fn create_intermediate_nodes(&mut self) {
// Scan through the matrix and check if (backend) nodes need to be created
// for new unknown nodes:
for x in 0..self.w {
for y in 0..self.h {
let cell = &mut self.matrix[x * self.h + y];
if cell.node_id == NodeId::Nop {
continue;
}
// - check if each NodeId has a corresponding entry in NodeConfigurator
// - if not, create a new one on the fly
if self.config.unique_index_for(&cell.node_id).is_none() {
// - check if the previous node exist, if not,
// create them on the fly now:
for inst in 0..cell.node_id.instance() {
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let new_hole_filler_node_id = cell.node_id.to_instance(inst);
if self.config.unique_index_for(&new_hole_filler_node_id).is_none() {
self.config
.create_node(new_hole_filler_node_id)
.expect("NodeInfo existent in Matrix");
}
}
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self.config.create_node(cell.node_id).expect("NodeInfo existent in Matrix");
}
}
}
}
fn update_graph_ordering_and_edges(&mut self) {
self.graph_ordering.clear();
self.edges.clear();
self.assigned_inputs.clear();
for x in 0..self.w {
for y in 0..self.h {
let cell = self.matrix[x * self.h + y];
if cell.node_id == NodeId::Nop {
continue;
}
self.graph_ordering.add_node(cell.node_id);
let in1_output = self.get_adjacent_output(x, y, CellDir::T);
let in2_output = self.get_adjacent_output(x, y, CellDir::TL);
let in3_output = self.get_adjacent_output(x, y, CellDir::BL);
match (cell.in1, in1_output) {
(Some(in1_idx), Some(in1_output)) => {
self.edges.push(Edge {
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to: cell.node_id,
to_input: in1_idx,
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from: in1_output.0,
from_out: in1_output.1,
});
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self.graph_ordering.add_edge(in1_output.0, cell.node_id);
}
_ => {}
}
match (cell.in2, in2_output) {
(Some(in2_idx), Some(in2_output)) => {
self.edges.push(Edge {
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to: cell.node_id,
to_input: in2_idx,
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from: in2_output.0,
from_out: in2_output.1,
});
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self.graph_ordering.add_edge(in2_output.0, cell.node_id);
}
_ => {}
}
match (cell.in3, in3_output) {
(Some(in3_idx), Some(in3_output)) => {
self.edges.push(Edge {
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to: cell.node_id,
to_input: in3_idx,
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from: in3_output.0,
from_out: in3_output.1,
});
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self.graph_ordering.add_edge(in3_output.0, cell.node_id);
}
_ => {}
}
}
}
for edge in self.edges.iter() {
if let Some(pid) = edge.to.param_by_idx(edge.to_input as usize) {
self.assigned_inputs.insert(pid);
}
}
}
/// Compiles a [NodeProg] from the data collected by the previous
/// call to [Matrix::update_graph_ordering_and_edges].
///
/// May return an error if the graph topology is invalid (cycles)
/// or something else happened.
fn build_prog(&mut self) -> Result<NodeProg, MatrixError> {
let mut ordered_nodes = vec![];
if !self.graph_ordering.calculate_order(&mut ordered_nodes) {
return Err(MatrixError::CycleDetected);
}
let mut prog = self.config.rebuild_node_ports();
for node_id in ordered_nodes.iter() {
self.config.add_prog_node(&mut prog, node_id);
}
for edge in self.edges.iter() {
self.config.set_prog_node_exec_connection(
&mut prog,
(edge.to, edge.to_input),
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(edge.from, edge.from_out),
);
}
Ok(prog)
}
/// Checks the topology of the DSP graph represented by the
/// hexagonal matrix.
///
/// Use [Matrix::save_matrix] and [Matrix::restore_matrix]
/// for trying out changes before committing them to the
/// DSP thread using [Matrix::sync].
///
/// Note that there is a convenience function with [Matrix::change_matrix]
/// to make it easier to test and rollback changes if they are faulty.
///
///```
/// use hexodsp::*;
///
/// let (node_conf, mut node_exec) = new_node_engine();
/// let mut matrix = Matrix::new(node_conf, 3, 3);
///
/// matrix.save_matrix();
///
/// // ...
/// matrix.place(0, 1,
/// Cell::empty(NodeId::Sin(1))
/// .input(Some(0), None, None));
/// matrix.place(0, 0,
/// Cell::empty(NodeId::Sin(1))
/// .out(None, None, Some(0)));
/// // ...
///
/// let error =
/// if let Err(_) = matrix.check() {
/// matrix.restore_matrix();
/// true
/// } else {
/// matrix.sync().unwrap();
/// false
/// };
///
/// // In this examples case there is an error, as we created
/// // a cycle:
/// assert!(error);
///```
pub fn check(&mut self) -> Result<(), MatrixError> {
self.update_graph_ordering_and_edges();
let mut edge_map = std::collections::HashMap::new();
for edge in self.edges.iter() {
if let Some((out1_node_id, out1_idx)) = edge_map.get(&(edge.to, edge.to_input)) {
return Err(MatrixError::DuplicatedInput {
output1: (*out1_node_id, *out1_idx),
output2: (edge.from, edge.from_out),
});
} else {
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edge_map.insert((edge.to, edge.to_input), (edge.from, edge.from_out));
}
}
let mut ordered_nodes = vec![];
if !self.graph_ordering.calculate_order(&mut ordered_nodes) {
return Err(MatrixError::CycleDetected);
}
Ok(())
}
/// Synchronizes the matrix with the DSP thread.
/// Call this everytime you changed any of the matrix [Cell]s
/// eg. with [Matrix::place] and want to publish the
/// changes to the DSP thread.
///
/// This method might return an error, for instance if the
/// DSP graph topology contains cycles or has other errors.
///
/// You can check any changes and roll them back
/// using the method [Matrix::change_matrix].
pub fn sync(&mut self) -> Result<(), MatrixError> {
self.create_intermediate_nodes();
self.update_graph_ordering_and_edges();
let prog = self.build_prog()?;
self.config.upload_prog(prog, true); // true => copy_old_out
// Update the generation counter which is used
// by external data structures to sync their state with
// the Matrix.
self.gen_counter += 1;
// Refresh the input/outputs of the monitored cell,
// just in case something has changed with that monitored cell.
self.remonitor_cell();
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if let Some(obs) = &self.observer {
obs.update_matrix();
}
Ok(())
}
/// Retrieves the output port feedback for a specific output
/// of the given [NodeId].
///
/// See also [NodeConfigurator::out_fb_for].
pub fn out_fb_for(&self, node_id: &NodeId, out: u8) -> Option<f32> {
self.config.out_fb_for(node_id, out)
}
/// Updates the output port feedback. Call this every UI frame
/// or whenever you want to get the most recent values from
/// [Matrix::out_fb_for].
///
/// See also [NodeConfigurator::update_output_feedback].
pub fn update_output_feedback(&mut self) {
self.config.update_output_feedback();
}
}
#[cfg(test)]
mod tests {
use super::*;
#[test]
fn check_matrix_3_sine() {
use crate::nodes::new_node_engine;
let (node_conf, mut node_exec) = new_node_engine();
let mut matrix = Matrix::new(node_conf, 3, 3);
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matrix.place(0, 0, Cell::empty(NodeId::Sin(0)).out(None, Some(0), None));
matrix.place(
1,
0,
Cell::empty(NodeId::Sin(1)).input(None, Some(0), None).out(None, None, Some(0)),
);
matrix.place(1, 1, Cell::empty(NodeId::Sin(2)).input(Some(0), None, None));
matrix.sync().unwrap();
node_exec.process_graph_updates();
let nodes = node_exec.get_nodes();
assert!(nodes[0].to_id(0) == NodeId::Sin(0));
assert!(nodes[1].to_id(1) == NodeId::Sin(1));
assert!(nodes[2].to_id(2) == NodeId::Sin(2));
let prog = node_exec.get_prog();
assert_eq!(prog.prog[0].to_string(), "Op(i=0 out=(0-1|1) in=(0-2|0) at=(0-0) mod=(0-0))");
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assert_eq!(
prog.prog[1].to_string(),
"Op(i=1 out=(1-2|1) in=(2-4|1) at=(0-0) mod=(0-0) cpy=(o0 => i2))"
);
assert_eq!(
prog.prog[2].to_string(),
"Op(i=2 out=(2-3|0) in=(4-6|1) at=(0-0) mod=(0-0) cpy=(o1 => i4))"
);
}
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#[test]
fn check_matrix_get_connections() {
use crate::nodes::new_node_engine;
let (node_conf, _node_exec) = new_node_engine();
let mut matrix = Matrix::new(node_conf, 3, 3);
matrix.place(0, 0, Cell::empty(NodeId::Sin(0)).out(None, Some(0), None));
matrix.place(
1,
0,
Cell::empty(NodeId::Sin(1)).input(None, Some(0), None).out(None, None, Some(0)),
);
matrix.place(1, 1, Cell::empty(NodeId::Sin(2)).input(Some(0), None, None));
matrix.sync().unwrap();
let res = matrix.get_connections(1, 0);
let res = res.expect("Found connected cells");
let (src_dir, src_io_idx) = res[0].0;
let (dst_dir, dst_io_idx, (nx, ny)) = res[0].1;
assert_eq!(src_dir, CellDir::B, "Found first connection at bottom");
assert_eq!(src_io_idx, 0, "Correct output port");
assert_eq!(dst_dir, CellDir::T, "Found first connection at bottom");
assert_eq!(dst_io_idx, 0, "Correct output port");
assert_eq!((nx, ny), (1, 1), "Correct other position");
let (src_dir, src_io_idx) = res[1].0;
let (dst_dir, dst_io_idx, (nx, ny)) = res[1].1;
assert_eq!(src_dir, CellDir::TL, "Found first connection at bottom");
assert_eq!(src_io_idx, 0, "Correct output port");
assert_eq!(dst_dir, CellDir::BR, "Found first connection at bottom");
assert_eq!(dst_io_idx, 0, "Correct output port");
assert_eq!((nx, ny), (0, 0), "Correct other position");
}
#[test]
fn check_matrix_param_is_used() {
use crate::nodes::new_node_engine;
let (node_conf, _node_exec) = new_node_engine();
let mut matrix = Matrix::new(node_conf, 3, 3);
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matrix.place(0, 0, Cell::empty(NodeId::Sin(0)).out(None, Some(0), None));
matrix.place(
1,
0,
Cell::empty(NodeId::Sin(1)).input(None, Some(0), None).out(None, None, Some(0)),
);
matrix.place(1, 1, Cell::empty(NodeId::Sin(2)).input(Some(0), None, None));
matrix.sync().unwrap();
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assert!(matrix.param_input_is_used(NodeId::Sin(1).inp_param("freq").unwrap()));
assert!(!matrix.param_input_is_used(NodeId::Sin(0).inp_param("freq").unwrap()));
matrix.place(1, 0, Cell::empty(NodeId::Nop));
matrix.sync().unwrap();
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assert!(!matrix.param_input_is_used(NodeId::Sin(1).inp_param("freq").unwrap()));
assert!(!matrix.param_input_is_used(NodeId::Sin(2).inp_param("freq").unwrap()));
}
#[test]
fn check_matrix_filled() {
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use crate::dsp::{Node, NodeId};
use crate::nodes::new_node_engine;
let (node_conf, mut node_exec) = new_node_engine();
let mut matrix = Matrix::new(node_conf, 9, 9);
let mut i = 1;
for x in 0..9 {
for y in 0..9 {
matrix.place(x, y, Cell::empty(NodeId::Sin(i)));
i += 1;
}
}
matrix.sync().unwrap();
node_exec.process_graph_updates();
let nodes = node_exec.get_nodes();
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let ex_nodes: Vec<&Node> = nodes.iter().filter(|n| n.to_id(0) != NodeId::Nop).collect();
assert_eq!(ex_nodes.len(), 9 * 9 + 1);
}
#[test]
fn check_matrix_into_output() {
use crate::nodes::new_node_engine;
let (node_conf, mut node_exec) = new_node_engine();
let mut matrix = Matrix::new(node_conf, 3, 3);
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matrix.place(0, 0, Cell::empty(NodeId::Sin(0)).out(None, Some(0), None));
matrix.place(
1,
0,
Cell::empty(NodeId::Out(0)).input(None, Some(0), None).out(None, None, Some(0)),
);
matrix.sync().unwrap();
node_exec.set_sample_rate(44100.0);
node_exec.process_graph_updates();
let nodes = node_exec.get_nodes();
assert!(nodes[0].to_id(0) == NodeId::Sin(0));
assert!(nodes[1].to_id(0) == NodeId::Out(0));
let prog = node_exec.get_prog();
assert_eq!(prog.prog.len(), 2);
assert_eq!(prog.prog[0].to_string(), "Op(i=0 out=(0-1|1) in=(0-2|0) at=(0-0) mod=(0-0))");
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assert_eq!(
prog.prog[1].to_string(),
"Op(i=1 out=(1-1|0) in=(2-5|1) at=(0-1) mod=(0-0) cpy=(o0 => i2))"
);
}
#[test]
fn check_matrix_skip_instance() {
use crate::nodes::new_node_engine;
let (node_conf, mut node_exec) = new_node_engine();
let mut matrix = Matrix::new(node_conf, 3, 3);
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matrix.place(0, 0, Cell::empty(NodeId::Sin(2)).out(None, Some(0), None));
matrix.place(
1,
0,
Cell::empty(NodeId::Out(0)).input(None, Some(0), None).out(None, None, Some(0)),
);
matrix.sync().unwrap();
node_exec.set_sample_rate(44100.0);
node_exec.process_graph_updates();
let nodes = node_exec.get_nodes();
assert!(nodes[0].to_id(0) == NodeId::Sin(0));
assert!(nodes[1].to_id(0) == NodeId::Sin(0));
assert!(nodes[2].to_id(0) == NodeId::Sin(0));
assert!(nodes[3].to_id(0) == NodeId::Out(0));
let prog = node_exec.get_prog();
assert_eq!(prog.prog.len(), 2);
assert_eq!(prog.prog[0].to_string(), "Op(i=2 out=(2-3|1) in=(4-6|0) at=(0-0) mod=(0-0))");
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assert_eq!(
prog.prog[1].to_string(),
"Op(i=3 out=(3-3|0) in=(6-9|1) at=(0-1) mod=(0-0) cpy=(o2 => i6))"
);
}
#[test]
fn check_matrix_check_cycle() {
use crate::nodes::new_node_engine;
let (node_conf, _node_exec) = new_node_engine();
let mut matrix = Matrix::new(node_conf, 3, 3);
matrix.save_matrix();
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matrix.place(0, 1, Cell::empty(NodeId::Sin(1)).input(Some(0), None, None));
matrix.place(0, 0, Cell::empty(NodeId::Sin(1)).out(None, None, Some(0)));
let error = if let Err(_) = matrix.check() {
matrix.restore_matrix();
true
} else {
matrix.sync().unwrap();
false
};
// In this examples case there is an error, as we created
// a cycle:
assert!(error);
}
#[test]
fn check_matrix_check_duplicate_input() {
use crate::nodes::new_node_engine;
let (node_conf, _node_exec) = new_node_engine();
let mut matrix = Matrix::new(node_conf, 5, 5);
matrix.save_matrix();
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matrix.place(0, 1, Cell::empty(NodeId::Sin(0)).input(Some(0), None, None));
matrix.place(0, 0, Cell::empty(NodeId::Sin(1)).out(None, None, Some(0)));
matrix.place(0, 3, Cell::empty(NodeId::Sin(0)).input(Some(0), None, None));
matrix.place(0, 2, Cell::empty(NodeId::Sin(2)).out(None, None, Some(0)));
assert_eq!(
matrix.check(),
Err(MatrixError::DuplicatedInput {
output1: (NodeId::Sin(1), 0),
output2: (NodeId::Sin(2), 0),
})
);
}
#[test]
fn check_matrix_mod_amt_pre_sync() {
use crate::nodes::new_node_engine;
let (node_conf, mut node_exec) = new_node_engine();
let mut matrix = Matrix::new(node_conf, 3, 3);
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matrix.place(0, 0, Cell::empty(NodeId::Sin(0)).out(None, Some(0), None));
matrix.place(
1,
0,
Cell::empty(NodeId::Sin(1)).input(None, Some(0), None).out(None, None, Some(0)),
);
matrix.place(
0,
1,
Cell::empty(NodeId::Sin(3)).input(None, None, None).out(None, Some(0), None),
);
matrix.place(1, 1, Cell::empty(NodeId::Sin(2)).input(Some(0), Some(1), None));
matrix.set_param_modamt(NodeId::Sin(1).param_by_idx(0).unwrap(), Some(0.5)).unwrap();
matrix.set_param_modamt(NodeId::Sin(1).param_by_idx(1).unwrap(), Some(0.33)).unwrap();
matrix.set_param_modamt(NodeId::Sin(0).param_by_idx(0).unwrap(), Some(0.25)).unwrap();
matrix.set_param_modamt(NodeId::Sin(2).param_by_idx(0).unwrap(), Some(0.75)).unwrap();
matrix.set_param_modamt(NodeId::Sin(2).param_by_idx(1).unwrap(), Some(-0.75)).unwrap();
matrix.sync().unwrap();
node_exec.process_graph_updates();
let prog = node_exec.get_prog();
assert_eq!(prog.prog[0].to_string(), "Op(i=0 out=(0-1|1) in=(0-2|0) at=(0-0) mod=(0-1))");
assert_eq!(prog.prog[1].to_string(), "Op(i=3 out=(3-4|1) in=(6-8|0) at=(0-0) mod=(5-5))");
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assert_eq!(
prog.prog[2].to_string(),
"Op(i=1 out=(1-2|1) in=(2-4|1) at=(0-0) mod=(1-3) cpy=(o0 => i2) mod=1)"
);
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assert_eq!(
prog.prog[3].to_string(),
"Op(i=2 out=(2-3|0) in=(4-6|3) at=(0-0) mod=(3-5) cpy=(o1 => i4) cpy=(o3 => i5) mod=3 mod=4)");
}
#[test]
fn check_matrix_mod_amt_post_sync() {
use crate::nodes::new_node_engine;
let (node_conf, mut node_exec) = new_node_engine();
let mut matrix = Matrix::new(node_conf, 3, 3);
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matrix.place(0, 0, Cell::empty(NodeId::Sin(0)).out(None, Some(0), None));
matrix.place(
1,
0,
Cell::empty(NodeId::Sin(1)).input(None, Some(0), None).out(None, None, Some(0)),
);
matrix.place(1, 1, Cell::empty(NodeId::Sin(2)).input(Some(0), None, None));
matrix.sync().unwrap();
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matrix.set_param_modamt(NodeId::Sin(1).param_by_idx(0).unwrap(), Some(0.5)).unwrap();
matrix.set_param_modamt(NodeId::Sin(1).param_by_idx(1).unwrap(), Some(0.33)).unwrap();
matrix.set_param_modamt(NodeId::Sin(0).param_by_idx(0).unwrap(), Some(0.25)).unwrap();
node_exec.process_graph_updates();
let prog = node_exec.get_prog();
assert_eq!(prog.prog[0].to_string(), "Op(i=0 out=(0-1|1) in=(0-2|0) at=(0-0) mod=(0-1))");
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assert_eq!(
prog.prog[1].to_string(),
"Op(i=1 out=(1-2|1) in=(2-4|1) at=(0-0) mod=(1-3) cpy=(o0 => i2) mod=1)"
);
assert_eq!(
prog.prog[2].to_string(),
"Op(i=2 out=(2-3|0) in=(4-6|1) at=(0-0) mod=(3-3) cpy=(o1 => i4))"
);
}
#[test]
fn check_matrix_set_get() {
use crate::nodes::new_node_engine;
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let (node_conf, _node_exec) = new_node_engine();
let mut matrix = Matrix::new(node_conf, 3, 3);
let pa1 = NodeId::Sin(1).param_by_idx(0).unwrap();
let pa2 = NodeId::Sin(1).param_by_idx(1).unwrap();
let pb1 = NodeId::Sin(2).param_by_idx(0).unwrap();
let pb2 = NodeId::Sin(2).param_by_idx(1).unwrap();
let px1 = NodeId::BOsc(1).param_by_idx(0).unwrap();
let px2 = NodeId::BOsc(1).param_by_idx(1).unwrap();
let gen1 = matrix.get_generation();
matrix.set_param(pa1, (0.75).into());
matrix.set_param(pa2, (0.50).into());
matrix.set_param(pb1, (0.25).into());
matrix.set_param(pb2, (0.20).into());
matrix.set_param(px1, (0.10).into());
matrix.set_param(px2, (0.13).into());
assert_eq!(matrix.get_generation(), gen1 + 6);
assert_eq!(matrix.get_param(&pa1), Some((0.75).into()));
let _ = matrix.set_param_modamt(pa2, Some(0.4));
let _ = matrix.set_param_modamt(pa1, Some(0.4));
let _ = matrix.set_param_modamt(pa1, None);
assert_eq!(matrix.get_generation(), gen1 + 9);
assert_eq!(matrix.get_param_modamt(&pa2), Some(0.4));
assert_eq!(matrix.get_param_modamt(&pa1), None);
}
}