Rhythmical Arrays
May 27, 2020
show source
<Player
events={renderRhythmObject({
duration: 16,
value: [
['e5', ['b4', 'c5'], 'd5', ['c5', 'b4']],
['a4', ['a4', 'c5'], 'e5', ['d5', 'c5']],
['b4', ['r', 'c5'], 'd5', 'e5'],
['c5', 'a4', 'a4', 'r'],
[['r', 'd5'], ['r', 'f5'], 'a5', ['g5', 'f5']],
['e5', ['r', 'c5'], 'e5', ['d5', 'c5']],
['b4', ['b4', 'c5'], 'd5', 'e5'],
['c5', 'a4', 'a4', 'r'],
],
})}
/>
In this post, I want to describe how and why rhythmical is implemented.
Nested vs Flat Arrays
The goal of rhythmical is to convert rhythms from nested arrays to a flat arrays.
Nested Array
A simple nested array looks like this:
['C4', ['E4', 'G4'], 'B4', 'D5'];
We can visualize it with a tree:
- Pro: Easy to read and write for humans
- Pro: Good for hierarchical visualizations
- Contra: Hard to parse for machines
Flat Array
A flat representation of the nested array above could look like this:
[
{ value: 'C4', time: 0, duration: 1 },
{ value: 'E4', time: 1, duration: 0.5 },
{ value: 'G4', time: 1.5, duration: 0.5 },
{ value: 'B4', time: 2, duration: 1 },
{ value: 'D5', time: 3, duration: 1 },
];
- Pro: Easy to parse for machines
- Pro: Good for playback / visualization
- Contra: Hard to read and write for humans
We can render this as a piano roll:
... or as a score:
... or play it back
Now we want to find out how this transformation can be done.
Flattening arrays
Of course, we could just use Array.flat:
Array.flat(['C4', ['E4', 'G4'], 'B4', 'D5']);
// ['C4', 'E4', 'G4', 'B4', 'D5']
But with this, we loose the nesting information.
Keeping track of indices
To keep the nesting info when flattening, we need some way of representation for the position of elements inside the tree. We could use an array of indices:
[
{ value: 'C4', path: [0] },
{ value: 'E4', path: [1, 0] },
{ value: 'G4', path: [1, 1] },
{ value: 'B4', path: [2] },
{ value: 'D5', path: [3] },
];
So now we keep the nesting information. This is enough information to recreate the original nested tree.
Keeping track of array lengths
While the above flat array with indices might be lossless, it is really expensive to work with it, as we do not know how many elements are on each level. We could iterate over all elements and count them, but this is rather expensive. To avoid this, we can just keep track of the array lengths:
[
{ value: 'C4', path: [[0, 4]] },
{
value: 'E4',
path: [
[1, 4],
[0, 2],
],
},
{
value: 'G4',
path: [
[1, 4],
[1, 2],
],
},
{ value: 'B4', path: [[2, 4]] },
{ value: 'D5', path: [[3, 4]] },
];
Basic Implementation
This is a simple recursive implementation:
export function flatArray<T>(array: NestedArray<T>, path: Path[] = [], flat: FlatItem<T>[] = []): FlatItem<T>[] {
for (let i = 0; i < array.length; i++) {
if (typeof array[i] !== 'object') {
flat.push({ value: array[i] as T, path: path.concat([[i, array.length]]) })
} else if (Array.isArray(array[i])) {
flatArray(array[i] as NestedArray<T>, path.concat([[i, array.length]]), flat)
} else {
throw new Error('Non-Array Objects not supported!')
}
}
return flat;
}
export interface NestedArray<T> extends Array<T | NestedArray<T>> { }
export type Path = [number, number];
export type FlatItem<T> = { value: T, path: Path[] };
show example tests
test('flatArray', () => {
expect(flatArray([])).toEqual([]);
expect(flatArray(['C'])).toEqual([{ value: 'C', path: [[0, 1]] }]);
expect(flatArray(['C', 'D'])).toEqual([
{ value: 'C', path: [[0, 2]] },
{ value: 'D', path: [[1, 2]] },
]);
expect(flatArray(['C', 'D', ['E', 'F']])).toEqual([
{ value: 'C', path: [[0, 3]] },
{ value: 'D', path: [[1, 3]] },
{
value: 'E',
path: [
[2, 3],
[0, 2],
],
},
{
value: 'F',
path: [
[2, 3],
[1, 2],
],
},
]);
});
Calculating absolute time + duration from paths
We can calculate absolute time and duration of a path array like this:
export function getTimeDuration(path: [number, number][], whole = 1) {
let time = 0;
let subdivision = whole;
for (let i = 0; i < path.length; i++) {
subdivision *= 1 / path[i][1];
time += path[i][0] * subdivision;
}
return [time, subdivision];
}
show example tests
test('getTimeDuration', () => {
expect(getTimeDuration([[0, 2]])).toEqual([0, 0.5]);
expect(getTimeDuration([[1, 2]])).toEqual([0.5, 0.5]);
expect(
getTimeDuration([
[0, 2],
[0, 2],
])
).toEqual([0, 0.25]);
expect(
getTimeDuration([
[0, 2],
[1, 2],
])
).toEqual([0.25, 0.25]);
expect(
getTimeDuration([
[1, 2],
[0, 2],
])
).toEqual([0.5, 0.5]);
});
Why not calculate directly?
Of course we could directly calculate the time and duration in the process of flattening, but the path representation has some advantages:
- no information is lost => we could recreate the nested tree from the flat output
- we can transform nested trees by treating the paths like fractions
Throwing it together
We can now combine flatArray with getTimeDuration:
export function flatRhythmArray<T>(array: NestedArray<T>, whole = 1) {
return flatArray(array).map(({ value, path }) => {
let [time, duration] = getTimeDuration(path);
return { value, time, duration };
});
}
show example tests
test('flatRhythmArray', () => {
expect(flatRhythmArray(['C', 'D'])).toEqual([
{ value: 'C', time: 0, duration: 0.5 },
{ value: 'D', time: 0.5, duration: 0.5 },
]);
expect(flatRhythmArray(['C', ['D', 'E']])).toEqual([
{ value: 'C', time: 0, duration: 0.5 },
{ value: 'D', time: 0.5, duration: 0.25 },
{ value: 'E', time: 0.75, duration: 0.25 },
]);
});
Array nesting / unflattening
By remembering the tree position with the path array, we can return to the nested state again:
export function nestArray<T>(items: FlatItem<T>[]): NestedArray<T> {
return items.reduce((nested, item) => {
let [index, subdivision] = item.path[0];
if (!nested.length && subdivision) {
nested = Array(subdivision).fill(0); // populate array
}
if (item.path.length === 1) {
nested[index] = item.value;
} else {
nested[index] = nestArray(
items
.filter((i) => i.path.length > 1 && i.path[0][0] === index) // remove siblings
.map((i) => ({ ...i, path: i.path.slice(1) })) // remove first path
);
}
return nested;
}, []);
}
show example tests
test('nestArray', () => {
expect(nestArray([])).toEqual([]);
expect(nestArray([{ value: 'C', path: [[0, 1]] }])).toEqual(['C']);
expect(
nestArray([
{ value: 'C', path: [[0, 2]] },
{ value: 'D', path: [[1, 2]] },
])
).toEqual(['C', 'D']);
expect(
nestArray([
{ value: 'C', path: [[0, 3]] },
{ value: 'D', path: [[1, 3]] },
{
value: 'E',
path: [
[2, 3],
[0, 2],
],
},
{
value: 'F',
path: [
[2, 3],
[1, 2],
],
},
])
).toEqual(['C', 'D', ['E', 'F']]);
});
Durations
There is one thing we missed so far: We need a way to adjust the duration of elements. For example, without durations, we cannot represent this:
So we need some way to specify durations. We could use objects with duration and value:
[{ value: 'C4', duration: 3 }, 'D4'];
or some form of custom string syntax:
['C4*3', 'D4'];
If not specified, the default value for duration is 1.
With durations, calculating absolute time gets more complicated, because the time depends on the durations of the preceeding elements. The most obvious way to do this is by including the duration with the path, so we have 3 numbers:
[
{ value: 'C4', path: [[0, 3, 4]] },
{ value: 'D4', path: [[3, 1, 4]] },
];
Now, the format for the paths is [index, duration, subdivision]. Note that the index and subdivision are now scaled to the total duration. This representation can be seen as fractions:
Next Steps
We will implement durations in another post, as it requires allowing non-Array objects, which i call the extended rhythmical format. It opens up even more possibilities, like polyphony.