# ![icon] RedACT Composer
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**A Rust library for building modular musical composers.**
Composers are built by creating a set of composition elements, and defining how each of these elements will generate
further sub-elements. In this library's domain, these correspond to the
[`Element`](crate::Element) and [`Renderer`](crate::Renderer) traits respectively.
> This project adheres to [Semantic Versioning](https://semver.org/spec/v2.0.0.html). Most importantly at this time
> would be [spec item #4](https://semver.org/spec/v2.0.0.html#spec-item-4).
Jump to: [
[Setup](#setup)
| [Example](#example)
| [Bigger Example](#much-bigger-example)
| [Inspector](#inspector)
| [Feature Flags](#feature-flags)
]
## Setup
```shell
cargo add redact-composer
```
If using the `serde` [feature](#feature-flags), `typetag` is also required:
```shell
cargo add typetag
```
## Example
The basic capabilities can be demonstrated by creating a simple I-IV-V-I chord composer. The full code example is
located at
[`redact-composer/examples/simple.rs`](https://github.com/dousto/redact-composer/blob/main/redact-composer/examples/simple.rs).
### Building Blocks
This example composer will use some library-provided elements ([`Chord`](crate::musical::elements::Chord),
[`Part`](crate::elements::Part), [`PlayNote`](crate::elements::PlayNote)) and two new elements:
```rust
#[derive(Element, Serialize, Deserialize, Debug)]
pub struct CompositionRoot;
#[derive(Element, Serialize, Deserialize, Debug)]
struct PlayChords;
```
Before moving ahead, some background: A composition is an n-ary tree structure and is "composed" by starting with a
root [`Element`](crate::Element), and calling its associated [`Renderer`](crate::Renderer) which
generates additional [`Element`](crate::Element)s as children. These children then have their
[`Renderer`](crate::Renderer)s called, and this process continues until tree leaves are reached (i.e. elements that do
not generate further children).
This composer will use the `CompositionRoot` element as a root. Defining a [`Renderer`](crate::Renderer) for this
then looks like:
```rust
struct CompositionRenderer;
impl Renderer for CompositionRenderer {
type Element = CompositionRoot;
fn render(
&self, composition: SegmentRef, context: CompositionContext,
) -> Result> {
let chords: [Chord; 4] = [
(C, maj).into(),
(F, maj).into(),
(G, maj).into(),
(C, maj).into(),
];
Ok(
// Repeat the four chords over the composition -- one every two beats
Rhythm::from([2 * context.beat_length()])
.iter_over(composition)
.zip(chords.into_iter().cycle())
.map(|(subdivision, chord)| chord.over(subdivision))
.chain([
// Also include the new component, spanning the whole composition
Part::instrument(PlayChords).over(composition),
])
.collect(),
)
}
}
```
> Note: [`Part::instrument(...)`](crate::elements::Part::instrument) is just a wrapper for another element, indicating
> that notes generated within the wrapped element are to be played by a single instrument at a time.
This [`Renderer`](crate::Renderer) takes a `CompositionRoot` element (via a [`SegmentRef`](crate::SegmentRef)) and generates several
children including [`Chord`](crate::musical::elements::Chord) elements (with a [`Rhythm`](crate::musical::rhythm::Rhythm) of one every two beats over the composition), and
newly defined `PlayChords` element. These children are returned as [`Segment`](crate::Segment)s, which defines where they
are located in the composition's timeline.
At this stage, the [`Chord`](crate::musical::elements::Chord) and `PlayChords` elements are just abstract concepts
however, and need to produce something concrete. This is done with another [`Renderer`](crate::Renderer) for
`PlayChords`:
```rust
struct PlayChordsRenderer;
impl Renderer for PlayChordsRenderer {
type Element = PlayChords;
fn render(
&self, play_chords: SegmentRef, context: CompositionContext,
) -> Result> {
// `CompositionContext` enables finding previously rendered elements
let chord_segments = context.find::()
.with_timing(Within, play_chords)
.require_all()?;
// As well as random number generation
let mut rng = context.rng();
// Map Chord notes to PlayNote elements, forming a triad
let notes = chord_segments
.iter()
.flat_map(|chord| {
chord.element
.iter_notes_in_range(Note::from((C, 4))..Note::from((C, 5)))
.map(|note|
// Add subtle nuance striking the notes with different velocities
note.play(rng.gen_range(80..110) /* velocity */)
.over(chord))
.collect::>()
})
.collect();
Ok(notes)
}
}
```
Here, [`CompositionContext`](crate::render::context::CompositionContext) is used to reference the previously created
[`Chord`](crate::musical::elements::Chord) segments. Then the [`Note`](crate::musical::elements::Note)s from each
[`Chord`](crate::musical::elements::Chord) within an octave range are [`play`](crate::musical::Note::play)ed over the
[`Chord`](crate::musical::elements::Chord) segment's timing.
### Creating the Composer
In essence, a [`Composer`](crate::Composer) is just a set of [`Renderer`](crate::Renderer)s, and can be constructed with
just a little bit of glue:
```rust
let composer = Composer::from(
RenderEngine::new() + CompositionRenderer + PlayChordsRenderer,
);
```
And finally the magic unfolds by passing a root [`Segment`](crate::Segment) to its
[`compose()`](crate::Composer::compose) method.
```rust
// Create a 16-beat length composition
let composition_length = composer.options.ticks_per_beat * 16;
let composition = composer.compose(CompositionRoot.over(0..composition_length));
// Convert it to a MIDI file and save it
MidiConverter::convert(&composition).save("./composition.mid").unwrap();
```
When plugged into your favorite midi player, the `composition.mid` file should sound somewhat like this:
Additionally, composition outputs support serialization/deserialization (with `serde` feature, enabled by default).
```rust
// Write the composition output in json format
fs::write("./composition.json", serde_json::to_string_pretty(&composition).unwrap()).unwrap();
```
## Much bigger example
Check out [this repo](https://github.com/dousto/redact-renderer-example) for a more in depth example which utilizes
additional features to create a full length composition.
## Inspector
Debugging composition outputs can quickly get unwieldy with larger compositions.
[redact-composer-inspector](https://dousto.github.io/redact-composer-inspector/) is a simple web tool that helps to
visualize and navigate the structure of [`Composition`](crate::Composition) outputs (currently only compatible with
json output).
For example, here is the [simple example loaded in the inspector](https://dousto.github.io/redact-composer-inspector/inspect?composition=examples/simple).
## Feature Flags
### `default`
`derive`, `musical`, `midi`, `serde`
### `derive` default
Enable derive macro for [`Element`](crate::Element).
### `musical` default
Include [`musical`](crate::musical) domain module. ([`Key`](crate::musical::Key), [`Chord`](crate::musical::Chord),
[`Rhythm`](crate::musical::rhythm::Rhythm), etc..).
### `midi` default
Include [`midi`](crate::midi) module containing MIDI-related [`Element`](crate::Element)s and MIDI converter for
[`Composition`](crate::Composition)s.
### `serde` default
Enables serialization and deserialization of [`Composition`](crate::Composition) outputs via (as you may have guessed)
[`serde`](https://docs.rs/serde/latest/serde/).
[icon]: https://dousto.github.io/redact-composer-inspector-dev/favicon-32.png ""
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