TypeScript/JavaScript utilities for those who don't like utilities.
yarn add antiutils
or
npm install antiutils --save
Based on the "only one way to do it" principle, this library provides a utility only when something can't be easily and readably done with vanilla JavaScript. For example, we do not provide a function to get an object's property value, so instead of get('a')
you would just write value => value.a
. This is because we see the mental overhead of choosing among multiple ways to write a piece of code as higher cost compared to doing more typing.
That said, we do sometimes provide a shortcut for what would otherwise be a one-liner, such as lastInIterable
for reduceIterable((...[, value]) => value)
- not for conciseness or performance, but to improve readability.
Pipeline operator ponyfill
The library includes a function applyPipe
which takes between 1 and 12 arguments: applyPipe(x, a, b)
is equivalent to b(a(x))
, or using the pipeline operator, x |> a |> b
. Type inference works well with this function, and if any one of the proposed flavors of the pipeline operator eventually reaches stage 3 and starts to be supported in TypeScript, it would be straightforward to build a codemod to convert the function to the operator.
The library intentionally doesn't include a pipe
function that would compose functions without applying the resulting function to an argument, mainly because this would go against "only one way to do it".
The library includes non-mutating functions for working with objects, arrays, maps, and sets.
💡 TIP
If you use TypeScript 4.1+, make sure you enable strictly checked indexed access using
--noUncheckedIndexedAccess
compiler flag.
Functions for working with iterables have signatures that try to stay close to corresponding native array methods and RxJS operators.
How-to:
-
Filter an iterable in a way that the type system understands:
applyPipe( [1, undefined], // Equivalent to `filterIterable((value) => value !== undefined)`. flatMapIterable((value) => (value !== undefined ? [value] : [])), );
(type will be inferred as
Iterable<number>
, notIterable<number | undefined>
as would be the case if you usedfilterIterable
; the same trick works when filtering arrays and observables). -
Index elements:
zipIterables(rangeIterable(), yourIterable)
(returns an iterable of[<element index>, <element>]
). -
Get a flag indicating if the element is the first element:
zipIterables(firstIterable, yourIterable)
(returns an iterable of[boolean, <element>]
). -
Count elements in an iterable::
applyPipe(yourIterable, reduceIterable(countReducer, 0))
. -
Check if every element in an iterable is true:
applyPipe(yourIterableOfBooleans, reduceIterable(andReducer, true))
(iteration will not continue unnecessarily because of howreduceIterable
andandReducer
are defined). -
Check if some elements in an iterable are true:
applyPipe(yourIterableOfBooleans, reduceIterable(orReducer, false))
. -
Find the first element matching a predicate:
applyPipe(yourIterable, filter(yourPredicate), firstInIterable)
. -
Yield values while a condition holds:
applyPipe( [1, 2, 3, 2], scanIterable((...[, value]) => (value <= 2 ? value : undefined)), );
(yields
1
,2
, seescanIterable
). -
Also yield the value that broke the condition:
applyPipe( [1, 2, 3, 2], scanIterable((accumulator, value) => accumulator <= 2 ? value : undefined, ), );
(yields
1
,2
,3
).
The library exports types
type CompareFunction<T> = (to: T, from: T) => number;
type EqualFunction<T> = (from: T, to: T) => boolean;
It provides implementations of CompareFunction
for primitive types and a function lexicographicCompare
to compose CompareFunction
s.
It also provides implementations of EqualFunction
for objects, iterables, maps, and sets, and a function deepEqual
that recursively delegates to those functions depending on the object type.
The library exports a type
type Reducer<Accumulator, Element> = (
accumulator: Accumulator,
element: Element,
) => Accumulator | undefined;
which is like a regular reducer, but can return undefined
to stop the iteration short, and which is used by functions reduceIterable
and scanIterable
.
The library includes basic implementations of this type, all of which except the boolean ones (andReducer
and orReducer
) can also be used with arrays and observables.
We start by defining a View
as a combination of a getter and a setter:
type View<S, A> = { get: () => A; set: (value: A) => S };
and define a Lens
as a function that transforms a view into another view:
type Lens<S, A, B> = (source: View<S, A>) => View<S, B>;
The library provides the following functions:
-
objectProp
: a lens to zoom in on an object's property. -
mapProp
: a lens to zoom in on a value stored in aMap
. -
setProp
: a lens to zoom in on presence of an element in aSet
. -
rootView
: a function that converts avalue
into a view{ get: () => value, set: <identity function> }
.
Example usage:
type State = { a: { b: string; c: string } };
/**
* A reducer that sets the value of `b` in the state to the payload.
**/
const sampleReducer = (state: State, action: { payload: string }) =>
applyPipe(
// Returns `View<State, State>`.
rootView(state),
// Transforms values into `View<State, { b: string; c: string }>`.
objectProp('a'),
// Transforms values into `View<State, string>`.
objectProp('b'),
)
// `set` takes a value for `b` and returns a new `State`.
.set(action.payload);
expect(sampleReducer({ a: { b: '', c: '' } }, { payload: 'x' })).toEqual({
a: { b: 'x', c: '' },
});
Example of usage with optional properties:
// Note the optional `a`.
type State = { a?: { b: string; c: string } };
const sampleReducer = (state: State, action: { payload: string }) =>
applyPipe(
rootView(state),
// Transforms values into `View<State, { b: string; c: string } |
// undefined>`.
objectProp('a'),
// Transforms values into `View<State, { b: string; c: string }>`.
({ get, set }) => ({
get: () => get() ?? { b: '', c: '' },
set,
}),
objectProp('b'),
).set(action.payload);
expect(sampleReducer({}, { payload: 'x' })).toEqual({
a: { b: 'x', c: '' },
});
The library also defines
type StateView<A> = View<void, A>; // = { get: () => A; set: (value: A) => void };
where the setter does not return any value, but instead produces a side effect. To learn about how this type is used, please see the docs for antiutils-react
, a package that provides glue between Antiutils and React.
The library provides utilities memoizeWeak
and memoizeStrong
to memoize functions that take a single argument. Internally they cache results in respectively a WeakMap and a Map, with arguments as keys and results as values. memoizeWeak
has an advantage that retaining a reference to the memoized function will not prevent cached arguments and results from being garbage-collected, but it can only memoize functions that take objects (not primitive values) as arguments, because only objects can be used as keys in a WeakMap.
💡 TIP
You can combine
memoizeWeak
andmemoizeStrong
to memoize a function that takes multiple arguments, some of them primitive values, e.g.const original = (x: { a: number }, y: number) => x.a + y; const memoized = memoizeWeak((x: { a: number }) => memoizeStrong((y: number) => original(x, y)), ); const withRestoredSignature = (x: { a: number }, y: number) => memoized(x)(y);
The library also provides a function teach
for cases when you need to teach a memoized function to return a result already known from an external source such as persisted storage, and a function knows
to check if there is a cached result for a given argument.
The library provides the following identity functions that cast the argument to a subtype, but unlike the TypeScript's as
, never make assertions:
-
asNever
: an identity function with signature(value: never) => never
used to typecheck that a symbol has typenever
. Throws if called. Example: ifa
has type0 | 1
, you could writea === 0 ? 'zero' : a === 1 ? 'one' : asNever(a)
to make sure that typecheck will fail if the type ofa
changes to say0 | 1 | 2
. -
as
: an identity function with signature<T>(value: T) => T
that can be used to downcast a value to a non-generic type:as<YourType>(yourValue)
. -
asContext
: an identity function with signature<A, B extends A>(value: B) => A
that can be used to infer the type of a value from the context instead of the other way around. For example, the functionfirstInIterable
can be implemented asreduceIterable(() => undefined)
, but writingapplyPipe([0, 1], reduceIterable(() => undefined))
will not typecheck. The reason is that TypeScript will look at the reducer() => undefined
and infer the type of the accumulator asundefined
, and then expect the array[0, 1]
to beundefined[]
. Enclosing the reducer inasContext
(asContext(() => undefined)
) will cause TypeScript to correctly infer the type of the accumulator asnumber
. -
asCompareFunction
,asEqualFunction
,asLens
,asReducer
,asStateView
,asView
: identity functions that can be used to downcast values to any of the generic types defined by the library.