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stream.ts
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stream.ts
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/**
* The stream module includes construction and combinator functions for a push
* stream datatype. Streams in fun are very close to the Streams of mostjs as
* well as the Observables of rxjs. There are few differences that come from
* a nuanced selection of invariants. Those invariants are:
*
* 1. Streams are lazy by default, and will not start collecting or emitting
* events until they are run.
* 2. A stream must be connected to a sink for events to be consumed. A sink is
* an object with a notion of accepting an event message and an end message.
* 3. When a stream is run by linking it with a sink it will return a
* Disposable, which can be used to cancel the operation of the stream early.
* 4. Once a stream is started it must call end when it completes. If the stream
* is disposed it will not call end.
*
* @module Stream
* @experimental
* @since 2.2.0
*/
import type { In, Kind, Out } from "./kind.ts";
import type { Wrappable } from "./wrappable.ts";
import type { BindTo, Mappable } from "./mappable.ts";
import type { Applicable } from "./applicable.ts";
import type { Bind, Flatmappable, Tap } from "./flatmappable.ts";
import type { Predicate } from "./predicate.ts";
import type { Refinement } from "./refinement.ts";
import type { Option } from "./option.ts";
import type { Either } from "./either.ts";
import type { Pair } from "./pair.ts";
import * as O from "./option.ts";
import * as E from "./either.ts";
import * as A from "./array.ts";
import { createBind, createTap } from "./flatmappable.ts";
import { createBindTo } from "./mappable.ts";
import { pair } from "./pair.ts";
import { flow, pipe } from "./fn.ts";
/**
* Represents a sink for receiving values emitted by a stream.
*
* @since 2.2.0
*/
export type Sink<A> = {
readonly event: (value: A) => void;
readonly end: (reason?: unknown) => void;
};
/**
* Represents a stream that emits values of type `A`.
*
* @since 2.2.0
*/
export type Stream<A, R = unknown> = (sink: Sink<A>, env: R) => Disposable;
/**
* Specifies Stream as a Higher Kinded Type, with covariant
* parameter A corresponding to the 0th index of any substitutions.
*
* @since 2.2.0
*/
export interface KindStream extends Kind {
readonly kind: Stream<Out<this, 0>, In<this, 0>>;
}
/**
* Represents a stream with unknown value type and any environment.
*
* @since 2.2.0
*/
// deno-lint-ignore no-explicit-any
export type AnyStream = Stream<any, any>;
/**
* Extracts the value type from a stream type.
*
* @since 2.2.0
*/
export type TypeOf<U> = U extends Stream<infer A, infer _> ? A : never;
/**
* Extracts the environment type from a stream type.
*
* @since 2.2.0
*/
export type EnvOf<U> = U extends Stream<infer _, infer R> ? R : never;
/**
* Represents a timeout object with `setTimeout` and `clearTimeout` methods.
*
* @since 2.2.0
*/
export type Timeout = {
readonly setTimeout: typeof setTimeout;
readonly clearTimeout: typeof clearTimeout;
};
/**
* Represents an interval object with `setInterval` and `clearInterval` methods.
*/
export type Interval = {
readonly setInterval: typeof setInterval;
readonly clearInterval: typeof clearInterval;
};
/**
* @since 2.2.0
*/
export type DefaultEnv = Timeout & Interval;
/**
* Creates a disposable resource with a dispose function. The resource can be disposed of
* by calling the `dispose` method. If `dispose` is called more than once, an error will be thrown.
*
* @param dispose A function that disposes of the resource.
* @returns A Disposable object with a dispose method.
*
* @since 2.2.0
*/
export function disposable(dispose: () => void): Disposable {
return { [Symbol.dispose]: dispose };
}
/**
* Disposes of a disposable resource by calling its dispose method.
*
* @since 2.2.0
*/
export function dispose(disposable: Disposable): void {
return disposable[Symbol.dispose]();
}
/**
* Creates a `Disposable` that does nothing when disposed.
*
* @since 2.0.0
*/
export function disposeNone(): Disposable {
return disposable(() => {});
}
/**
* @since 2.2.0
*/
export function sink<A>(
event: (value: A) => void,
end: (reason?: unknown) => void,
): Sink<A> {
return { event, end };
}
/**
* Creates a sink that does nothing when receiving events or ends
*
* @since 2.2.0
*/
export function emptySink(): Sink<unknown> {
return sink(NOOP, NOOP);
}
/**
* Creates a stream with a run function. The run function is responsible for
* managing the interaction with the provided sink and environment. It returns
* a Disposable object that can be used to clean up any resources associated
* with the stream.
*
* @since 2.2.0
*/
export function stream<A, R = unknown>(
run: (sink: Sink<A>, env: R) => Disposable,
): Stream<A, R> {
return run;
}
/**
* Runs a stream until completion, returning a disposable to stop the stream
* early.
*
* @param stream The stream to run.
* @param sink The sink to send event and end messages to.
* @param env The environment to run the stream in.
* @returns A disposable that can cancel the stream.
*
* @since 2.2.0
*/
export function run(): <A>(stream: Stream<A, typeof DefaultEnv>) => Disposable;
export function run<R>(env: R): <A>(stream: Stream<A, R>) => Disposable;
export function run<A, R>(
env: R,
sink: Sink<A>,
): (stream: Stream<A, R>) => Disposable;
export function run<A, R>(
env: R = DefaultEnv as R,
sink: Sink<A> = emptySink(),
): (stream: Stream<A, R>) => Disposable {
return (stream) => stream(sink, env);
}
/**
* Runs a stream until completion, returning a promise that resolves when the stream ends.
*
* @param stream The stream to run.
* @param env The environment to run the stream in.
* @returns A promise that resolves when the stream ends.
*
* @since 2.2.0
*/
export function runPromise(): <A>(
stream: Stream<A, typeof DefaultEnv>,
) => Promise<unknown>;
export function runPromise<R>(
env: R,
): <A>(stream: Stream<A, R>) => Promise<unknown>;
export function runPromise<R>(
env: R = DefaultEnv as R,
): <A>(stream: Stream<A, R>) => Promise<unknown> {
return (stream) =>
new Promise<unknown>((resolve) =>
pipe(stream, run(env, sink(NOOP, resolve)))
);
}
/**
* Runs a stream until completion, calling the onEvent when events arrive and
* onEnd when the stream ends.
*
* @param onEvent The function to run on each stream event.
* @param onEnd The function to run on stream end.
* @returns A function that takes a stream and returns a disposable
*
* @since 2.2.0
*/
export function forEach<A>(
onEvent: (value: A) => void,
onEnd?: (reason?: unknown) => void,
): (ua: Stream<A, typeof DefaultEnv>) => Disposable;
export function forEach<A, R>(
onEvent: (value: A) => void,
onEnd: (reason?: unknown) => void,
env: R,
): (ua: Stream<A, R>) => Disposable;
export function forEach<A, R = unknown>(
onEvent: (value: A) => void = NOOP,
onEnd: (reason?: unknown) => void = NOOP,
env: R = DefaultEnv as R,
): (ua: Stream<A, R>) => Disposable {
return run(env, sink(onEvent, onEnd));
}
/**
* Runs a stream, collecting eny events into an array, then returning the array
* once the stream ends.
*
* @since 2.2.0
*/
export function collect(): <A>(
stream: Stream<A, typeof DefaultEnv>,
) => Promise<ReadonlyArray<A>>;
export function collect<R>(
env: R,
): <A>(stream: Stream<A, R>) => Promise<ReadonlyArray<A>>;
export function collect<R>(
env: R = DefaultEnv as R,
): <A>(stream: Stream<A, R>) => Promise<ReadonlyArray<A>> {
return <A = never>(stream: Stream<A, R>): Promise<ReadonlyArray<A>> =>
new Promise((resolve) => {
const result: A[] = [];
pipe(
stream,
run(
env,
sink((value) => result.push(value), () => resolve(result)),
),
);
});
}
const NOOP: () => void = () => {};
/**
* A Stream instance that emits no values and immediately ends.
*/
const EMPTY: Stream<never, unknown> = stream(
(snk) => {
let open = true;
const close = () => open = false;
queueMicrotask(() => open && snk.end());
return disposable(close);
},
);
/**
* Creates an empty `Stream`, which emits no events and ends immediately.
*
* @since 2.2.0
*/
export function empty<A = never, R = unknown>(): Stream<A, R> {
return EMPTY;
}
/**
* Creates a `Stream` that never emits any events and never ends.
*
* @since 2.2.0
*/
export function never<A = never, R = unknown>(): Stream<A, R> {
return stream(() => disposable(NOOP));
}
/**
* Creates a `Stream` that emits a single event when the provided promise resolves, and then ends.
*
* @param ua The promise to convert into a stream.
* @returns A `Stream` that emits the resolved value of the provided promise and then ends.
*
* @since 2.0.0
*/
export function fromPromise<A>(ua: Promise<A>): Stream<A> {
return stream((snk) => {
let open = true;
const close = () => open = false;
ua.then((value) => {
if (open) {
close();
snk.event(value);
snk.end();
}
});
return disposable(close);
});
}
/**
* Creates a `Stream` that emits events from the provided iterable and then ends.
*
* @param values The iterable whose values will be emitted by the stream.
* @returns A `Stream` that emits each value from the provided iterable and then ends.
*
* @since 2.0.0
*/
export function fromIterable<A>(values: Iterable<A>): Stream<A> {
return stream((snk) => {
let open = true;
const close = () => open = false;
queueMicrotask(() => {
if (open) {
for (const value of values) {
snk.event(value);
}
snk.end();
}
});
return disposable(close);
});
}
/**
* Creates a stream that emits a single value after a specified delay.
*
* @param time The time in milliseconds after which the value should be emitted.
* @returns A stream that emits a single value after the specified delay.
*
* @since 2.2.0
*/
export function at(time: number): Stream<number, Timeout> {
return stream(
(snk: Sink<number>, { setTimeout, clearTimeout }: Timeout) => {
const handle = setTimeout(
() => {
snk.event(time);
snk.end();
},
time,
);
return disposable(() => {
clearTimeout(handle);
});
},
);
}
/**
* Creates a stream that emits incremental values at regular intervals.
*
* @param period The time interval in milliseconds between each emitted value.
* @returns A stream that emits incremental values at regular intervals.
*
* @since 2.2.0
*/
export function periodic(period: number): Stream<number, Interval> {
return stream((snk: Sink<number>, env: Interval) => {
let start = 0;
const { setInterval, clearInterval } = env;
const handle = setInterval(
() => {
snk.event(start += period);
},
period,
);
return disposable(() => {
clearInterval(handle);
});
});
}
/**
* Combines two streams, emitting events from the first stream until it
* ends, and then continuing with events from the second stream.
*
* @param second A function that returns the second stream to be concatenated.
* @returns A function that takes the first stream and returns a new stream concatenating events from both streams.
*
* @since 2.0.0
*/
export function combine<A2, R2>(
second: Stream<A2, R2>,
): <A1, R1>(first: Stream<A1, R1>) => Stream<A1 | A2, R1 & R2> {
return <A1, R1>(first: Stream<A1, R1>): Stream<A1 | A2, R1 & R2> =>
pipe(
fromIterable<Stream<A1 | A2, R1 & R2>>([first, second]),
join(1),
);
}
/**
* Maps the values of a stream from one type to another using a provided function.
*
* @param fai A function that maps values from type `A` to type `I`.
* @returns A higher-order function that takes a stream of type `A` and returns a new stream of type `I`.
*
* @since 2.2.0
*/
export function map<A, I>(
fai: (a: A) => I,
): <R>(ua: Stream<A, R>) => Stream<I, R> {
return (ua) =>
stream((snk, env) => ua(sink((a) => snk.event(fai(a)), snk.end), env));
}
/**
* Wraps a single value into a stream.
*
* @param value The value to be wrapped into the stream.
* @returns A stream containing the provided value.
*
* @since 2.2.0
*/
export function wrap<A, R = unknown>(value: A): Stream<A, R> {
return stream((snk) => {
let open = true;
const close = () => open = false;
queueMicrotask(() => {
if (open) {
snk.event(value);
snk.end();
}
});
return disposable(close);
});
}
/**
* Creates a new stream that only emits values from the original stream that satisfy the provided predicate function.
*
* @param predicate A function that determines whether a value should be emitted (`true`) or filtered out (`false`).
* @returns A higher-order function that takes a stream and returns a new stream containing only the values that satisfy the predicate.
*
* @since 2.2.0
*/
export function filter<A, B extends A>(
refinement: (a: A) => a is B,
): <R>(s: Stream<A, R>) => Stream<B, R>;
export function filter<A>(
predicate: (a: A) => boolean,
): <R>(s: Stream<A, R>) => Stream<A, R>;
export function filter<A>(
predicate: (a: A) => boolean,
): <R>(ua: Stream<A, R>) => Stream<A, R> {
return (ua) =>
stream((snk, env) =>
ua(
sink((value) => {
if (predicate(value)) {
snk.event(value);
}
}, snk.end),
env,
)
);
}
/**
* Apply a filter and mapping operation at the same time against a Stream.
*
* @since 2.2.0
*/
export function filterMap<A, I>(
fai: (a: A) => Option<I>,
): <R = unknown>(ua: Stream<A, R>) => Stream<I, R> {
return (ua) =>
stream((snk, env) =>
pipe(
ua,
run(
env,
sink((value) => {
const oi = fai(value);
if (O.isSome(oi)) {
snk.event(oi.value);
}
}, snk.end),
),
)
);
}
/**
* Given a refinement or predicate, return a function that splits an Stream into
* a Pair<Stream<A>, Stream<B>>.
*
* @since 2.2.0
*/
export function partition<A, B extends A>(
refinement: Refinement<A, B>,
): <R = unknown>(ua: Stream<A, R>) => Pair<Stream<B, R>, Stream<A, R>>;
export function partition<A>(
predicate: Predicate<A>,
): <R = unknown>(ua: Stream<A, R>) => Pair<Stream<A, R>, Stream<A, R>>;
export function partition<A>(
predicate: Predicate<A>,
): <R = unknown>(ua: Stream<A, R>) => Pair<Stream<A, R>, Stream<A, R>> {
return (ua) =>
pair(pipe(ua, filter(predicate)), pipe(ua, filter((a) => !predicate(a))));
}
/**
* Map and partition over the inner value of an Stream<A> at the same time.
*
* @since 2.0.0
*/
export function partitionMap<A, I, J>(
fai: (a: A) => Either<J, I>,
): <R = unknown>(ua: Stream<A, R>) => Pair<Stream<I, R>, Stream<J, R>> {
return (ua) =>
pair(
pipe(ua, filterMap(flow(fai, E.getRight))),
pipe(ua, filterMap(flow(fai, E.getLeft))),
);
}
/**
* Creates a new stream by continuously applying a function to a seed value and the values of the original stream.
*
* @param stepper A function that takes the current state and a value from the original stream, and returns an array containing the new state and the value to be emitted by the new stream.
* @param seed The initial state value.
* @returns A higher-order function that takes a stream and returns a new stream resulting from applying the stepper function to each value of the original stream.
*
* @since 2.2.0
*/
export function loop<A, B, S>(
stepper: (state: S, value: A) => [S, B],
seed: S,
): <R = unknown>(ua: Stream<A, R>) => Stream<B, R> {
return (ua) =>
stream((snk, env) => {
let hold: S = seed;
return pipe(
ua,
run(
env,
sink((a) => {
const [seed, value] = stepper(hold, a);
hold = seed;
snk.event(value);
}, snk.end),
),
);
});
}
/**
* Creates a new stream by accumulating values from the original stream using a provided scanning function.
*
* @param scanner A function that takes the current accumulator value and a value from the original stream, and returns the new accumulator value.
* @param seed The initial accumulator value.
* @returns A higher-order function that takes a stream and returns a new stream with accumulated values.
*
* @since 2.2.0
*/
export function scan<A, O>(
scanner: (accumulator: O, value: A) => O,
seed: O,
): <R>(ua: Stream<A, R>) => Stream<O, R> {
return (ua) =>
stream((snk, env) => {
let state = seed;
return ua(
sink(
(value) => {
state = scanner(state, value);
snk.event(state);
},
snk.end,
),
env,
);
});
}
/**
* Creates a new stream by concurrently merging multiple streams into one stream.
* The concurrency of the join can be set and defaults to positive infinity,
* indicating unbounded join. A strategy can also be supplied, which controls
* how inner streams are handled when maximum concurrency is met.
*
* *Hold Strategy*: This strategy keeps an ordered queue of streams to pull from
* when running inner streams end. This strategy has no loss of data.
*
* *Swap Strategy*: This strategy will dispose the oldest running inner stream
* when a new stream arrives to make space for the newest stream. In this
* strategy the oldest streams are where we lose data.
*
* *Drop Strategy": This strategy will ignore any new streams once concurrency
* is maxed. In this strategy newest streams are where we lose data.
*
* There is room for a combination of strategies in the future, but the vast
* majority of behaviors are representable with these three.
*
* @param concurrency The maximum number of inner streams to be running concurrently.
* @param strategy The strategy to use once concurrency is saturated.
* @returns A higher-order function that takes a stream of streams and returns a new stream containing values from all inner streams.
*
* @since 2.2.0
*/
export function join(
concurrency = Number.POSITIVE_INFINITY,
strategy: "hold" | "swap" | "drop" = "hold",
): <A, R1, R2>(
ua: Stream<Stream<A, R1>, R2>,
) => Stream<A, R1 & R2> {
return <A, R1, R2>(
ua: Stream<Stream<A, R1>, R2>,
): Stream<A, R1 & R2> =>
stream((outerSnk, env) => {
let outerClosed = false;
const queue: Stream<A, R1>[] = [];
const running = new Map<Sink<A>, Disposable>(); // WeakMap?
/**
* Start inner should only be called when there is enough concurrency to
* support starting a new stream.
*/
function startInner(strm: Stream<A, R1>) {
const innerSnk = sink<A>(outerSnk.event, () => {
/**
* We know that this inner stream has ended so we no longer need to
* dispose of it. Thus we start by removing the sink/disposable pair
* from our running map.
*/
if (running.has(innerSnk)) {
running.delete(innerSnk);
}
/**
* Next we decide if we should start a new stream by checking the
* concurrency and the queue. There might be a bug here but I haven't
* desk checked it yet. If the call to startInner here leads to a
* sync stream and that stream calls end it might lead to a double
* end call.
*
* I don't think it will because the inner stream started here should
* see running.size === 1, but I'm not entirely sure.
*/
if (running.size < concurrency && queue.length > 0) {
startInner(queue.shift() as Stream<A, R1>);
}
/**
* Lastly, we check to see if we are the last end call by looking at
* whether the outer stream is closed and whether we are running any
* inner streams still.
*/
if (outerClosed && running.size === 0) {
outerSnk.end();
}
});
/**
* Lastly, we start the innerStream and store it's disposable in
* running, indexed by the innerSnk created above.
*/
running.set(innerSnk, run(env, innerSnk)(strm));
}
const dsp = ua(
sink((strm) => {
/**
* If there is enough concurrency to start an inner stream then we
* start it. Otherwise we move on to queueing using the provided
* strategy.
*/
if (running.size < concurrency) {
return startInner(strm);
}
/**
* For the hold strategy we queue up any inner streams above
* concurrency. As running inner streams end they will be pulled from
* the queue.
*/
if (strategy === "hold") {
return queue.push(strm);
}
/**
* For the swap strategy we use the unique property of Map that when
* converted to an array it will be put into insertion order. This may
* have some performance impacts, in which case switching to another
* data structure may benefit. For now, the simplicity of this
* implementation wins.
*
* We start by finding the oldest running inner stream, disposing it,
* and starting the new stream. In other libraries this behavior is
* called left switch.
*/
if (strategy === "swap") {
pipe(
Array.from(running),
A.lookup(0),
O.match(
// If there is no running stream then something is likely wrong?
NOOP,
([oldestSink, oldestDsp]) => {
running.delete(oldestSink);
dispose(oldestDsp);
startInner(strm);
},
),
);
}
/**
* The drop strategy would go here, however its behavior is
* to ignore new streams so it is a noop.
*/
}, () => {
/**
* There are two cases for end coming from the outer stream. There are
* either inner streams left to process or not. When there are inner
* streams then the startInner function will handle end. If there
* aren't then end must be called here.
*/
outerClosed = true;
if (running.size === 0 && queue.length == 0) {
outerSnk.end();
}
}),
env,
);
/**
* In join both the outer and inner streams must be disposed. By design,
* disposed streams call end after their cleanup is complete. For join
* the process of dispose is to first dispose of the outer stream if it
* isn't closed, then to clear the queue, and last dispose of the inner
* streams. The last inner stream to be disposed is expected to call end,
* so the machinery of streams should lead to a single call to end.
*/
return disposable(() => {
queue.length = 0;
running.forEach(dispose);
if (!outerClosed) {
dispose(dsp);
}
});
});
}
/**
* Maps each value of the input stream to a new stream using a provided function,
* then flattens the resulting streams into a single stream.
*
* @param faui A function that maps each value of the input stream to a new stream.
* @param count The maximum number of inner streams to be running concurrently.
* @returns A higher-order function that takes a stream and returns a new stream
* containing values from all mapped streams
*
* @since 2.2.0
*/
export function flatmap<A, I, R2 = unknown>(
faui: (a: A) => Stream<I, R2>,
concurrency = Number.POSITIVE_INFINITY,
): <R1>(ua: Stream<A, R1>) => Stream<I, R1 & R2> {
return (ua) => pipe(ua, map(faui), join(concurrency));
}
export function switchmap<A, I, R2>(
faui: (a: A) => Stream<I, R2>,
concurrency = 1,
): <R1>(ua: Stream<A, R1>) => Stream<I, R1 & R2> {
return <R1>(ua: Stream<A, R1>): Stream<I, R1 & R2> =>
pipe(ua, map(faui), join(concurrency, "swap"));
}
export function exhaustmap<A, I, R2>(
faui: (a: A) => Stream<I, R2>,
concurrency = 1,
): <R1>(ua: Stream<A, R1>) => Stream<I, R1 & R2> {
return <R1>(ua: Stream<A, R1>): Stream<I, R1 & R2> =>
pipe(ua, map(faui), join(concurrency, "drop"));
}
/**
* Applies each value of the input stream to a stream of functions,
* producing a stream of results. Apply may lose data if the underlying streams
* push events in a tight loop. This is because in a tight loop the runtime does
* not allow pausing between events from one of the two streams.
*
* @param ua The input stream.
* @returns A higher-order function that takes a stream of functions and returns
* a new stream containing the results of applying each value of the input stream
* to the corresponding function.
*
* @since 2.2.0
*/
export function apply<A, R2 = never>(
ua: Stream<A, R2>,
): <I, R1>(ufai: Stream<(a: A) => I, R1>) => Stream<I, R2 & R1> {
return <I, R1>(ufai: Stream<(a: A) => I, R1>): Stream<I, R1 & R2> =>
stream((snk, env) => {
let valueDone = false;
let fnDone = false;
let fai: Option<(a: A) => I> = O.none;
let a: Option<A> = O.none;
function send() {
pipe(fai, O.apply(a), O.tap((i) => snk.event(i)));
}
const dsp_ufai = ufai(
sink((fn) => {
fai = O.some(fn);
send();
}, () => {
fnDone = true;
if (valueDone) {
snk.end();
}
}),
env,
);
const dsp_ua = ua(
sink((value) => {
a = O.some(value);
send();
}, () => {
valueDone = true;
if (fnDone) {
snk.end();
}
}),
env,
);
return disposable(() => {
if (!valueDone) {
dispose(dsp_ua);
}
if (!fnDone) {
dispose(dsp_ufai);
}
});
});
}
/**
* Creates a new stream by combining each value of the input stream with an index value generated by a provided indexing function.
*
* @param indexer A function that takes the current state and returns an array containing the index value and the new state.
* @param seed The initial state value.
* @returns A higher-order function that takes a stream and returns a new stream containing tuples of index-value pairs.
*
* @since 2.2.0
*/
export function indexed<S, I>(
indexer: (seed: S) => [I, S],
seed: S,
): <A, R = unknown>(ua: Stream<A, R>) => Stream<[I, A], R> {
return loop((previous, value) => {
const [index, next] = indexer(previous);
return [next, [index, value]];
}, seed);
}
/**
* Creates a new stream by combining each value of the input stream with an index value.
*
* @param start The starting index value.
* @param step The increment step for generating index values.
* @returns A higher-order function that takes a stream and returns a new stream containing tuples of index-value pairs.
*
* @since 2.2.0
*/
export function withIndex(
start: number = 0,
step: number = 1,
): <A, R = unknown>(ua: Stream<A, R>) => Stream<[number, A], R> {
return indexed((i) => [i, i + step], start);
}
/**
* Creates a new stream by combining each value of the input stream with a count index starting from 1.
*
* @param ua The input stream.
* @returns A stream containing tuples of count-value pairs.
*
* @since 2.2.0
*/
export function withCount<A, R = unknown>(
ua: Stream<A, R>,
): Stream<[number, A], R> {
return withIndex(1)(ua);
}
/**
* Creates a new stream by counting the number of values emitted by the input stream.
*
* @param ua The input stream.
* @returns A stream containing the count of values emitted by the input stream.
*
* @since 2.2.0
*/
export function count<A, R = unknown>(ua: Stream<A, R>): Stream<number, R> {
return pipe(ua, withCount, map(([i]) => i));
}
/**
* Creates a new stream that emits values from the input stream until a condition specified by the predicate function is met.
*
* @param predicate A function that determines whether to continue emitting values (`true`) or stop emitting values (`false`).
* @returns A higher-order function that takes a stream and returns a new stream containing values until the condition specified by the predicate function is met.
*
* @since 2.2.0
*/
export function takeUntil<A>(
predicate: (a: A) => boolean,
): <R = unknown>(ua: Stream<A, R>) => Stream<A, R> {
return (ua) =>
stream((snk, env) => {
const dsp = ua(
sink((a) => {
if (predicate(a)) {
snk.event(a);
dispose(dsp);
} else {
snk.event(a);
}
}, snk.end),
env,
);
return dsp;
});
}
/**
* Creates a new stream that emits a specified number of values from the input stream.
*
* @param count The number of values to emit.
* @returns A higher-order function that takes a stream and returns a new stream containing the specified number of values.
*
* @since 2.2.0
*/
export function take(count: number): <A, R>(ua: Stream<A, R>) => Stream<A, R> {
return (ua) => {
if (count <= 0) {
return empty();
}
return stream((snk, env) => {
let index = Math.max(0, count);
const dsp = ua(
sink(
(value) => {
snk.event(value);
if (--index <= 0) {
dispose(dsp);
snk.end();
}
},
snk.end,
),
env,
);
return dsp;
});
};
}