Froebel - a strictly typed TypeScript utility library.
This is my (WIP) personal collection of TypeScript helper functions and utilities that I use across different projects. Think an opinionated version of lodash, but with first-class types.
If you have an idea for a utility that might make a good addition to this collection, please open an issue and suggest its inclusion.
Runs in Deno, Node.js, and the Browser. Get it from deno.land or npm.
Installation
Using npm
npm install froebel
and — assuming a module-compatible system like webpack — import as:
import { someUtility } from 'froebel';
// you can also import the utility you need directly:
import memoize from 'froebel/memoize';
Using Deno
import { someUtility } from "https://deno.land/x/[email protected]/mod.ts";
// or import just the utility you need:
import memoize from "https://deno.land/x/[email protected]/memoize.ts"
Available Utilities
Each category also has a file exporting only the utilities in that category, so if you want to only import utilities from one category, you could import them as
import { throttle, debounce } from "froebel/function";
A few utils are exported from multiple categories but will only be listed here
once. For example isPromise
is exported from both the promise
and the
predicate
category.
Table of Contents
function
list
iterable
object
path
equality
promise
predicate
string
math
data structures
Function
ident
(value: T) => T
Identity function.
Import
/* Node: */ import ident from "froebel/ident";
/* Deno: */ import ident from "https://deno.land/x/[email protected]/ident.ts";
noop
() => void
Import
/* Node: */ import noop from "froebel/noop";
/* Deno: */ import noop from "https://deno.land/x/[email protected]/noop.ts";
partial
(fun: T, ...argsLeft: PL) => (...argsRight: PR) => ReturnType<T>
Partially apply a function.
Import
/* Node: */ import partial from "froebel/partial";
/* Deno: */ import partial from "https://deno.land/x/[email protected]/partial.ts";
Example
const divide = (dividend: number, divisor: number) => dividend / divisor
// (divisor: number) => number
const oneOver = partial(divide, 1)
// prints: 0.25
console.log(oneOver(4))
forward
(fun: T, ...argsRight: PR) => (...argsLeft: PL) => ReturnType<T>
Given a function and its nth..last arguments, return a function accepting arguments 0..n-1.
Import
/* Node: */ import forward from "froebel/forward";
/* Deno: */ import forward from "https://deno.land/x/[email protected]/forward.ts";
Examples
const divide = (dividend: number, divisor: number) => dividend / divisor
// (dividend: number) => number
const divideBy2 = forward(divide, 2)
// prints: 0.5
console.log(divideBy2(1))
const fetchUrl = async (protocol: string, domain: string, path: string) =>
await fetch(`${protocol}://${domain}/${path}`)
const fetchRepo = forward(fetchUrl, 'github.com', 'MathisBullinger/froebel')
const viaHTTPS = await fetchRepo('https')
unary
(fun: T) => Unary<T>
Turns
fun
into a unary function (a function that only accepts one argument).Note:
fun
must accept at least one argument and must not require more than one argument.
Import
/* Node: */ import unary from "froebel/unary";
/* Deno: */ import unary from "https://deno.land/x/[email protected]/unary.ts";
Example
['1', '2', '3'].map(unary(parseInt)) // -> [1, 2, 3]
callAll
(funs: F[], ...args: P) => ReturnTypes<F>
Take a list of functions that accept the same parameters and call them all with the provided arguments.
Import
/* Node: */ import callAll from "froebel/callAll";
/* Deno: */ import callAll from "https://deno.land/x/[email protected]/callAll.ts";
Example
const mult = (a: number, b: number) => a * b
const div = (a: number, b: number) => a / b
// prints: [8, 2]
console.log( callAll([mult, div], 4, 2) )
pipe
(...funs: T) => PipedFun<T>
Given a list of functions returns a function that will execute the given functions one after another, always passing the result of the previous function as an argument to the next function.
If one of the given functions returns a promise, the promise will be resolved before being passed to the next function.
Import
/* Node: */ import pipe from "froebel/pipe";
/* Deno: */ import pipe from "https://deno.land/x/[email protected]/pipe.ts";
Example
const join = (...chars: string[]) => chars.join('')
pipe(join, parseInt)('1', '2', '3') // -> 123
const square = (n: number) => n ** 2
// this is equivalent to: square(square(square(2)))
pipe(square, square, square)(2) // -> 256
// also works with promises:
fetchNumber :: async () => Promise<number>
pipe(fetchNumber, n => n.toString()) // async () => Promise<string>
applyPipe
(arg: Parameters<T[0]>[0], ...funs: T) => CheckPipe<T, CarryReturn<ReturnTypes<T>, Parameters<T[0]>>, false>
Like
pipe
but takes an argument as its first parameter and invokes the pipe with it.Note: unlike in
pipe
, the first function of the pipe must take exactly one argument.see pipe
Import
/* Node: */ import { applyPipe } from "froebel/pipe";
/* Deno: */ import { applyPipe } from "https://deno.land/x/[email protected]/pipe.ts";
Example
applyPipe(2, double, square, half) // -> 8
bundle
(...funs: λ<T>[]) => (...args: T) => Promise<void>
Given a list of functions that accept the same parameters, returns a function that takes these parameters and invokes all of the given functions.
The returned function returns a promise that resolves once all functions returned/resolved and rejects if any of the functions throws/rejects - but only after all returned promises have been settled.
Import
/* Node: */ import bundle from "froebel/bundle";
/* Deno: */ import bundle from "https://deno.land/x/[email protected]/bundle.ts";
bundleSync
(...funs: λ<T>[]) => (...args: T) => void
Same as bundle, but return synchronously.
If any of the functions throws an error synchronously, none of the functions after it will be invoked and the error will propagate.
Import
/* Node: */ import { bundleSync } from "froebel/bundle";
/* Deno: */ import { bundleSync } from "https://deno.land/x/[email protected]/bundle.ts";
nullishChain
(...funs: [] | [FF, ...FR[]]) => (...args: Parameters<FF>) => ReturnType<FF> | ReturnType<FR[number]>
Given a list of functions that accept the same parameters, returns a function that given these arguments returns the result of the first function whose result is not nullish.
This is equivalent to chaining together invocations of the passed in functions with the given arguments with nullish coalescing (
??
) operators.
Import
/* Node: */ import { nullishChain } from "froebel/nullishChain";
/* Deno: */ import { nullishChain } from "https://deno.land/x/[email protected]/nullishChain.ts";
Example
const isAdult = (age: number) => { if (n >= 18) return 'adult' }
const isToddler = (age: number) => { if (n <= 3) return 'toddler' }
const ageGroup = nullishChain(isAdult, isToddler, () => 'child')
// this is functionally equivalent to:
const ageGroup = age => isAdult(age) ?? isToddler(age) ?? 'child'
ageGroup(1) // prints: 'toddler'
ageGroup(10) // prints: 'child'
ageGroup(50) // prints: 'adult'
asyncNullishChain
(...funs: [] | [FF, ...FR[]]) => (...args: Parameters<FF>) => Promise<PromType<ReturnType<FF>> | PromType<ReturnType<FR[number]>>>
Same as nullishChain but accept asynchronous functions too.
Import
/* Node: */ import { asyncNullishChain } from "froebel/nullishChain";
/* Deno: */ import { asyncNullishChain } from "https://deno.land/x/[email protected]/nullishChain.ts";
Example
const readFromCache = (id: string): Resource => { if (id in cache) return cache[id] }
const readFromFile = (id: string): Resource => { if (fileExists(id)) return readFile(id) }
const fetchFromNet = async (id: string): Promise<Resource> => await fetch(`someURL/${id}`)
// async (id: string) => Promise<Resource>
const getResource = asyncNullishChain(readFromCache, readFromFile, fetchFromNet)
throttle
(fun: T, ms: number, opts?: {leading: boolean, trailing: boolean}) => λ<Parameters<T>, void> & {[cancel]: () => void}
Create a throttled function that invokes
fun
at most everyms
milliseconds.
fun
is invoked with the last arguments passed to the throttled function.Calling
[throttle.cancel]()
on the throttled function will cancel the currently scheduled invocation.
Import
/* Node: */ import throttle from "froebel/throttle";
/* Deno: */ import throttle from "https://deno.land/x/[email protected]/throttle.ts";
debounce
(fun: T, ms: number) => λ<Parameters<T>, void> & {[cancel]: () => void}
Creates a debounced function that delays invoking
fun
untilms
milliseconds have passed since the last invocation of the debounced function.
fun
is invoked with the last arguments passed to the debounced function.Calling
[debounce.cancel]()
on the debounced function will cancel the currently scheduled invocation.
Import
/* Node: */ import debounce from "froebel/debounce";
/* Deno: */ import debounce from "https://deno.land/x/[email protected]/debounce.ts";
memoize
(fun: T, opt: {limit: number, weak: W, key: (...args: Parameters<T>) => K}) => T & {cache: W extends false ? Map<K, ReturnType<T>> : Cache<K, ReturnType<T>>}
Returns a copy of
fun
that remembers its result for any given arguments and only invokesfun
for unknown arguments.The cache key is computed using the
key
function. The defaultkey
function simply stringifies the arguments.If
limit
is specified, only thelimit
-last entries are kept in cache.The function's cache is available at
memoized.cache
.If
opt.weak
istrue
, non-primitive cache keys are stored in a WeakMap. This behavior might for example be useful if you want to memoize some calculation including a DOM Node without holding on to a reference of that node. Using weak keys prohibits setting alimit
.
Import
/* Node: */ import memoize from "froebel/memoize";
/* Deno: */ import memoize from "https://deno.land/x/[email protected]/memoize.ts";
Examples
const expensiveCalculation = (a: number, b: number) => {
console.log(`calculate ${a} + ${b}`)
return a + b
}
const calc = memoize(expensiveCalculation)
console.log( calc(1, 2) )
// calculate 1 + 2
// 3
console.log( calc(20, 5) )
// calculate 20 + 5
// 25
console.log( calc(20, 5) )
// 25
console.log( calc(1, 2) )
// 3
calc.cache.clear()
console.log( calc(1, 2) )
// calculate 1 + 2
// 3
const logIfDifferent = memoize(
(msg: string) => console.log(msg),
{
limit: 1,
key: msg => msg
}
)
logIfDifferent('a')
logIfDifferent('a')
logIfDifferent('b')
logIfDifferent('a')
// a
// b
// a
limitInvocations
(fun: T, limit: number, ...funs: ExcS<T>) => T
Returns a version of the function
fun
that can only be invokedlimit
times. An optionalexcept
function will be called with the same parameters on any additional invocations.If
fun
returns anything butvoid
(orPromise<void>
), supplying anexcept
function is mandatory.The
except
function must have the same return type asfun
, or — iffun
returns a promise — it may return the type that the promise resolves to synchronously.The
except
function may also throw instead of returning a value.
Import
/* Node: */ import { limitInvocations } from "froebel/invoke";
/* Deno: */ import { limitInvocations } from "https://deno.land/x/[email protected]/invoke.ts";
once
(fun: T, ...funs: ExcS<T>) => T
Special case of limitInvocations.
fun
can only be invoked once.see limitInvocations
Import
/* Node: */ import { once } from "froebel/invoke";
/* Deno: */ import { once } from "https://deno.land/x/[email protected]/invoke.ts";
List
atWrap
(arr: T[], i: number) => T
Access list at
i % length
. Negative indexes start indexing the last element as[-1]
and wrap around to the back.
Import
/* Node: */ import atWrap from "froebel/atWrap";
/* Deno: */ import atWrap from "https://deno.land/x/[email protected]/atWrap.ts";
zip
(...lists: T) => Zip<T>
Takes multiple lists and returns a list of tuples containing the value in each list at the current index. If the lists are of different lengths, the returned list of tuples has the length of the shortest passed in list.
Import
/* Node: */ import zip from "froebel/zip";
/* Deno: */ import zip from "https://deno.land/x/[email protected]/zip.ts";
Example
const pairs = zip([1,2,3], ['a','b','c'])
console.log(pairs) // prints: [[1,'a'], [2,'b'], [3,'c']]
zipWith
(zipper: (...args: {[I in string | number | symbol]: U}) => U, ...lists: T) => U[]
Same as zip but also takes a
zipper
function, that is called for each index with the element at current index in each list as arguments. The result ofzipper
is the element at current index in the list returned fromzipWith
.
Import
/* Node: */ import { zipWith } from "froebel/zip";
/* Deno: */ import { zipWith } from "https://deno.land/x/[email protected]/zip.ts";
Example
const sums = zipWith((a,b) => a+b, [1,2,3], [4,5,6])
console.log(sums) // prints: [5,7,9]
unzip
(...zipped: T[][]) => Unzip<T>
Reverse of zip. Takes a list of tuples and deconstructs them into an array (of length of the tuples length) of lists each containing all the elements in all tuples at the lists index.
Import
/* Node: */ import unzip from "froebel/unzip";
/* Deno: */ import unzip from "https://deno.land/x/[email protected]/unzip.ts";
Example
const [nums, chars] = unzip([1,'a'], [2,'b'], [3,'c'])
console.log(nums) // prints: [1, 2, 3]
console.log(chars) // prints: ['a','b','c']
unzipWith
(zipped: T[][], ...unzippers: U) => {[I in string | number | symbol]: ReturnType<U[I]>}
Same as unzip but accepts an
unzipper
function for each tuple index. Theunzipper
's return value is used as the value in the list at that index returned fromunzipWith
.The
unzipper
takes the current element as its first argument, an accumulator as second argument (initiallyundefined
) and its return value is the accumulator passed into the next invocation.
Import
/* Node: */ import { unzipWith } from "froebel/unzip";
/* Deno: */ import { unzipWith } from "https://deno.land/x/[email protected]/unzip.ts";
Example
const [nums, str] = unzipWith(
[ [1,'a'], [2,'b'], [3,'c'] ],
(n, acc: number[] = []) => [...acc, n],
(c, str = '') => str + c
)
console.log(nums) // prints: [1, 2, 3]
console.log(str) // prints: 'abc'
batch
(list: T[], batchSize: number) => T[][]
Takes a
list
and returns it in multiple smaller lists of the sizebatchSize
. The last batch may be smaller thanbatchSize
depending on iflist
size is divisible bybatchSize
.
Import
/* Node: */ import batch from "froebel/batch";
/* Deno: */ import batch from "https://deno.land/x/[email protected]/batch.ts";
Example
batch([1,2,3,4,5], 2) // -> [ [1,2], [3,4], [5] ]
partition
(list: T[], predicate: (el: T) => el is S) => [S[], Exclude<T, S>[]]
Takes a
list
and returns a pair of lists containing: the elements that match thepredicate
and those that don't, respectively.Think of it as
filter
, but the elements that don't pass the filter aren't discarded but returned in a separate list instead.
Import
/* Node: */ import partition from "froebel/partition";
/* Deno: */ import partition from "https://deno.land/x/[email protected]/partition.ts";
Example
const [strings, numbers] = partition(
['a', 'b', 1, 'c', 2, 3],
(el): el is string => typeof el === 'string'
)
// strings: ["a", "b", "c"]
// numbers: [1, 2, 3]
shuffle
(list: T[]) => T[]
Shuffles
list
using the Fisher-Yates shuffle algorithm. The originallist
is not modified and the shuffled list is returned.
Import
/* Node: */ import shuffle from "froebel/shuffle";
/* Deno: */ import shuffle from "https://deno.land/x/[email protected]/shuffle.ts";
shuffleInPlace
(list: unknown[]) => void
Same as shuffle but shuffles
list
in place.
Import
/* Node: */ import { shuffleInPlace } from "froebel/shuffle";
/* Deno: */ import { shuffleInPlace } from "https://deno.land/x/[email protected]/shuffle.ts";
take
(n: number, list: Iterable<T>) => T[]
Takes
n
elements from the iterablelist
and returns them as an array.
Import
/* Node: */ import { take } from "froebel/list";
/* Deno: */ import { take } from "https://deno.land/x/[email protected]/list.ts";
Example
take(5, repeat(1, 2)) // -> [1, 2, 1, 2, 1]
take(3, [1, 2, 3, 4]) // -> [1, 2, 3]
take(3, [1, 2]) // -> [1, 2]
range
Creates a range between two values.
see numberRange and alphaRange
Import
/* Node: */ import range from "froebel/range";
/* Deno: */ import range from "https://deno.land/x/[email protected]/range.ts";
numberRange
(start: number, end: number, step: number) => number[]
Constructs a numeric between
start
andend
inclusively.
Import
/* Node: */ import { numberRange } from "froebel/range";
/* Deno: */ import { numberRange } from "https://deno.land/x/[email protected]/range.ts";
Example
range(2, 6) // -> [2, 3, 4, 5, 6]
range(8, 9, .3) // -> [8, 8.3, 8.6, 8.9]
range(3, -2) // -> [3, 2, 1, 0, -1, -2]
alphaRange
(start: string, end: string) => string[]
Constructs a range between characters.
Import
/* Node: */ import { alphaRange } from "froebel/range";
/* Deno: */ import { alphaRange } from "https://deno.land/x/[email protected]/range.ts";
Example
range('a', 'd') // -> ['a', 'b', 'c', 'd']
range('Z', 'W') // -> ['Z', 'Y', 'X', 'W']
Iterable
repeat
(...sequence: [T, ...T[]]) => Generator<T>
Returns a generator that repeats
sequence
.
Import
/* Node: */ import repeat from "froebel/repeat";
/* Deno: */ import repeat from "https://deno.land/x/[email protected]/repeat.ts";
Example
// prints: 1, 2, 3, 1, 2, 3, ...
for (const n of repeat(1, 2, 3))
console.log(n)
take
(n: number, list: Iterable<T>) => Generator<T>
Takes
n
elements from the iterablelist
and returns them as a generator.
Import
/* Node: */ import { take } from "froebel/iterable";
/* Deno: */ import { take } from "https://deno.land/x/[email protected]/iterable.ts";
Example
[...take(5, repeat(1, 2))] // -> [1, 2, 1, 2, 1]
[...take(3, [1, 2, 3, 4])] // -> [1, 2, 3]
[...take(3, [1, 2])] // -> [1, 2]
Object
pick
(obj: T, ...keys: K[]) => Pick<T, K>
From
obj
, create a new object that only includeskeys
.
Import
/* Node: */ import pick from "froebel/pick";
/* Deno: */ import pick from "https://deno.land/x/[email protected]/pick.ts";
Example
pick({ a: 1, b: 2, c: 3 }, 'a', 'c') // { a: 1, c: 3 }
omit
(obj: T, ...keys: K[]) => Omit<T, K>
From
obj
, create a new object that does not includekeys
.
Import
/* Node: */ import omit from "froebel/omit";
/* Deno: */ import omit from "https://deno.land/x/[email protected]/omit.ts";
Example
omit({ a: 1, b: 2, c: 3 }, 'a', 'c') // { b: 2 }
map
(data: Map<IK, IV>, callback: (key: IK, value: IV) => [OK, OV]) => Map<OK, OV>
Map over
data
.data
can be a regular object, aMap
, aSet
, or an array.
Import
/* Node: */ import map from "froebel/map";
/* Deno: */ import map from "https://deno.land/x/[email protected]/map.ts";
Examples
// -> { a: 1, b: 2 }
map({ a: '1', b: '2' }, (key, value) => [key, parseInt(value)])
// -> Map([ [2, 1], [4, 3] ])
map(new Map([ [1, 2], [3, 4] ]), (key, value) => [key + 1, value - 1])
Path
select
(obj: T, ...path: P) => PickPath<T, P>
Returns the value in
obj
atpath
. If the given path does not exist, the symbolnone
is returned.
Import
/* Node: */ import select from "froebel/select";
/* Deno: */ import select from "https://deno.land/x/[email protected]/select.ts";
Example
// -> 'something'
select(
{ a: { deeply: [{ nested: { object: 'something' } }] } },
'a', 'deeply', 0, 'nested', 'object'
)
Equality
oneOf
(value: T, ...cmps: TT) => value is TT[number]
Checks if
v
is one ofcmps
.
Import
/* Node: */ import oneOf from "froebel/oneOf";
/* Deno: */ import oneOf from "https://deno.land/x/[email protected]/oneOf.ts";
equal
(a: unknown, b: unknown) => boolean
Checks if
a
andb
are structurally equal using the following algorithm:
- primitives are compared by value
- functions are compared by reference
- objects (including arrays) are checked to have the same properties and their values are compared recursively using the same algorithm
Import
/* Node: */ import equal from "froebel/equal";
/* Deno: */ import equal from "https://deno.land/x/[email protected]/equal.ts";
clone
(value: T) => T
Returns a copied version of
value
.If
value
is primitive, returnsvalue
. Otherwise, properties ofvalue
are copied recursively. Onlyvalue
's own enumerable properties are cloned. Arrays are cloned by mapping over their elements.If a path in
value
references itself or a parent path, then in the resulting object that path will also reference the path it referenced in the original object (but now in the resuling object instead of the original).
Import
/* Node: */ import clone from "froebel/clone";
/* Deno: */ import clone from "https://deno.land/x/[email protected]/clone.ts";
merge
(a: A, b: B) => Merge<A, B>
Recursively merges
A
andB
. If a property inA
andB
is of a different type (i.e. it's not an array, Set, Map, or plain object in both, the value fromB
will be used in the result).If there are self-references in the cloned values, array / Set items, or Map keys or values, they will also be self-referencing in the result.
Import
/* Node: */ import merge from "froebel/merge";
/* Deno: */ import merge from "https://deno.land/x/[email protected]/merge.ts";
Promise
promisify
(withCallback: T, resultIndex?: N, errorIndex: null | number) => Promisified<T, N>
Turns a function accepting a callback into a function returning a promise. You can specify in which parameter (if any) the callback expects to receive a result and in which it expects an error. Pass
null
toresultIndex
orerrorIndex
if no result or errors are passed to the callback. By default the first argument passed to the callback is interpreted as result and none of the arguments as error (if the function accepting the callback throws or rejects, that will still result in the promisified function rejecting).The
callbackFirst
property allows passing additional parameters after the callback andcallbackLast
will pass additional parameters before the callback.
Import
/* Node: */ import promisify from "froebel/promisify";
/* Deno: */ import promisify from "https://deno.land/x/[email protected]/promisify.ts";
Examples
const notify = (cb: (msg: string) => void) => { msg('something') }
const waitForMessage = promisify(notify)
await waitForMessage() // -> 'something'
// here result is passed at index 1 and errors at index 0.
const callbackAPI = (cb: (error?: Error, data?: unknown) => void) => {}
const asyncAPI = promisify(callbackAPI, 1, 0)
const sleep = promisify(setTimeout).callbackFirst
await sleep(200)
const fs = require('node:fs');
const stat = promisify(fs.stat, 1, 0).callbackLast
try {
const stats = await stat('.');
console.log(`This directory is owned by ${stats.uid}`);
} catch (err) {
console.error(err)
}
createQueue
() => Queue
Creates a
queue
function that accepts a function as it's only parameter. Whenqueue
is invoked, the passed in function is executed after the last function passed toqueue
has finished executing. Thequeue
function returns the result of the passed in function asynchronously.Reading
queue.done
istrue
if no functions are currently executing / scheduled and otherwise a promise that resolves once the last function has stopped executing and no futher functions are queued.
Import
/* Node: */ import createQueue from "froebel/queue";
/* Deno: */ import createQueue from "https://deno.land/x/[email protected]/queue.ts";
Example
const queue = createQueue()
queue(async () => {
console.log('start a')
await delay()
return 'end a'
}).then(console.log)
queue(async () => {
console.log('start b')
await delay()
return 'end b'
}).then(console.log)
queue(async () => {
console.log('start c')
await delay()
return 'end c'
}).then(console.log)
await queue.done
// start a
// end a
// start b
// end b
// start c
// end c
isPromise
(value: unknown) => value is Promise<T>
Checks if
value
looks like a promise.
Import
/* Node: */ import isPromise from "froebel/isPromise";
/* Deno: */ import isPromise from "https://deno.land/x/[email protected]/isPromise.ts";
isNotPromise
(value: T) => value is Exclude<T, Promise<any>>
Checks if
value
is not a promise.
Import
/* Node: */ import { isNotPromise } from "froebel/isPromise";
/* Deno: */ import { isNotPromise } from "https://deno.land/x/[email protected]/isPromise.ts";
Example
(value: number | Promise<unknown>) => {
if (isNotPromise(value)) return value / 2
}
Predicate
truthy
(value: T) => value is PickTruthy<T>
Checks if
value
is truthy. Literal types are narrowed accordingly.
Import
/* Node: */ import { truthy } from "froebel/truthy";
/* Deno: */ import { truthy } from "https://deno.land/x/[email protected]/truthy.ts";
falsy
(value: T) => value is PickFalsy<T>
Checks if
value
is falsy. Literal types are narrowed accordingly.
Import
/* Node: */ import { falsy } from "froebel/truthy";
/* Deno: */ import { falsy } from "https://deno.land/x/[email protected]/truthy.ts";
nullish
(value: T) => value is Nullish<T>
Checks if
value
is nullish. Literal types are narrowed accordingly.
Import
/* Node: */ import { nullish } from "froebel/nullish";
/* Deno: */ import { nullish } from "https://deno.land/x/[email protected]/nullish.ts";
notNullish
(value: null | T) => value is T
Checks if
value
is not nullish. Literal types are narrowed accordingly.
Import
/* Node: */ import { notNullish } from "froebel/nullish";
/* Deno: */ import { notNullish } from "https://deno.land/x/[email protected]/nullish.ts";
Example
const nums = (...values: (number | undefined)[]): number[] => values.filter(notNullish)
isFulfilled
(result: PromiseSettledResult<T>) => result is PromiseFulfilledResult<T>
Checks if
result
(returned fromPromise.allSettled
) is fulfilled.
Import
/* Node: */ import { isFulfilled } from "froebel/settled";
/* Deno: */ import { isFulfilled } from "https://deno.land/x/[email protected]/settled.ts";
isRejected
(result: PromiseSettledResult<unknown>) => result is PromiseRejectedResult
Checks if
result
(returned fromPromise.allSettled
) is rejected.
Import
/* Node: */ import { isRejected } from "froebel/settled";
/* Deno: */ import { isRejected } from "https://deno.land/x/[email protected]/settled.ts";
String
prefix
(prefix: T0, str: T1, caseMod?: C) => `${string}`
Returns
str
prefixed withprefix
. Optionally, allows prefxing in camel case, i.e.prefix('foo', 'bar', 'camel') => 'fooBar'
, or snake case, i.e.prefix('foo', 'bar', 'snake') => 'foo_bar'
.The result is strictly typed, so
prefix('foo', 'bar')
will return the type'foobar'
, not just a genericstring
.
Import
/* Node: */ import prefix from "froebel/prefix";
/* Deno: */ import prefix from "https://deno.land/x/[email protected]/prefix.ts";
suffix
(str: T1, suffix: T0, caseMod?: C) => `${string}`
Returns
str
suffixed withsuffix
. Same case and type behavior as prefix.
Import
/* Node: */ import suffix from "froebel/suffix";
/* Deno: */ import suffix from "https://deno.land/x/[email protected]/suffix.ts";
surround
(str: A, surrounding: B) => B extends "" ? A : Surround<A, B>
Surrounds the
str
withsurrounding
.surrounding
must have an even length.
Import
/* Node: */ import { surround } from "froebel/surround";
/* Deno: */ import { surround } from "https://deno.land/x/[email protected]/surround.ts";
Example
surround("foo", "()") // "(foo)"
surround("foo", "({[]})") // "({[foo]})"
capitalize
(str: T) => Capitalize
Upper-case first letter of string.
Import
/* Node: */ import { capitalize } from "froebel/case";
/* Deno: */ import { capitalize } from "https://deno.land/x/[email protected]/case.ts";
uncapitalize
(str: T) => Uncapitalize
Lower-case first letter of string
Import
/* Node: */ import { uncapitalize } from "froebel/case";
/* Deno: */ import { uncapitalize } from "https://deno.land/x/[email protected]/case.ts";
upper
(str: T) => Uppercase
Strictly typed
String.toUpperCase()
.
Import
/* Node: */ import { upper } from "froebel/case";
/* Deno: */ import { upper } from "https://deno.land/x/[email protected]/case.ts";
lower
(str: T) => Lowercase
Strictly typed
String.toLowerCase()
.
Import
/* Node: */ import { lower } from "froebel/case";
/* Deno: */ import { lower } from "https://deno.land/x/[email protected]/case.ts";
snake
(str: T) => DelimitedCase<T, "_">
Transforms a variable name to snake case.
Note: The rules for transforming anything to snake case are somewhat vague. So use this only for very simple names where the resulting value is absolutely unambiguous. For more examples of how names are transformed, have a look at the test cases.
Import
/* Node: */ import { snake } from "froebel/case";
/* Deno: */ import { snake } from "https://deno.land/x/[email protected]/case.ts";
Example
snake('fooBar') // 'foo_bar'
kebab
(str: T) => DelimitedCase<T, "-">
Transforms a variable name to kebab case.
Note: The rules for transforming anything to kebab case are somewhat vague. So use this only for very simple names where the resulting value is absolutely unambiguous. For more examples of how names are transformed, have a look at the test cases.
Import
/* Node: */ import { kebab } from "froebel/case";
/* Deno: */ import { kebab } from "https://deno.land/x/[email protected]/case.ts";
Example
kebab('fooBar') // 'foo-bar'
camel
(str: T) => CamelCase<T>
Transforms a variable name to camel case.
Note: The rules for transforming anything to camel case are somewhat vague. So use this only for very simple names where the resulting value is absolutely unambiguous. For more examples of how names are transformed, have a look at the test cases.
Import
/* Node: */ import { camel } from "froebel/case";
/* Deno: */ import { camel } from "https://deno.land/x/[email protected]/case.ts";
Example
camel('foo_bar') // 'fooBar'
pascal
(str: T) => Capitalize
Transforms a variable name to pascal case.
Note: The rules for transforming anything to pascal case are somewhat vague. So use this only for very simple names where the resulting value is absolutely unambiguous. For more examples of how names are transformed, have a look at the test cases.
Import
/* Node: */ import { pascal } from "froebel/case";
/* Deno: */ import { pascal } from "https://deno.land/x/[email protected]/case.ts";
Example
pascal('foo_bar') // 'FooBar'
screamingSnake
(str: T) => Uppercase
Transforms a variable name to screaming snake case.
see snake
Import
/* Node: */ import { screamingSnake } from "froebel/case";
/* Deno: */ import { screamingSnake } from "https://deno.land/x/[email protected]/case.ts";
Example
screamingSnake('fooBar') // 'FOO_BAR'
transformCase
(str: T, targetCase: C) => DelimitedCase<T, "_">
Transform a variable name to
targetCase
see snake, kebab, camel, pascal, and screamingSnake
Import
/* Node: */ import { transformCase } from "froebel/case";
/* Deno: */ import { transformCase } from "https://deno.land/x/[email protected]/case.ts";
Math
clamp
(min: number, num: number, max: number) => number
Clamp
num
betweenmin
andmax
inclusively.
Import
/* Node: */ import clamp from "froebel/clamp";
/* Deno: */ import clamp from "https://deno.land/x/[email protected]/clamp.ts";
Data Structures
BiMap
class BiMap<L, R>(data?: Map<L, R> | [L, R][], aliasLeft?: AL, aliasRight?: AR)
Bidirectional map. Maps two sets of keys in a one-to-one relation.
Both sides are accessible (at .left & .right, or at their respective alias if one was provided in the constructor) with an interface similar to that of the built-in Map and the same iteration behavior.
Import
/* Node: */ import BiMap from "froebel/bimap";
/* Deno: */ import BiMap from "https://deno.land/x/[email protected]/bimap.ts";
Examples
const nums = BiMap.from({ one: 1, two: 2 })
// different ways of iterating over the entries
[...nums.left] // [['one',1], ['two',2]]
[...nums.right] // [[1,'one'], [2,'two']]
[...nums.left.keys()] // ['one', 'two']
[...nums.left.values()] // [1, 2]
[...nums.right.keys()] // [1, 2]
[...nums.right.values()] // ['one', 'two']
[...nums] // [['one',1], ['two',2]]
[...nums.right.entries()] // [[1,'one'], [2,'two']]
Object.fromEntries(nums.right) // { '1': 'one', '2': 'two' }
// setting a value
nums.left.three = 3
// when accessing a property using bracket notation (i.e. nums.right[4]),
// JavaScript coerces the key to a string, so keys that aren't strings or
// symbols must be accessed using the same access methods known from Map.
nums.right.set(4, 'four')
// remapping values
nums.left.tres = 3 // {one: 1, two: 2, tres: 3, four: 4}
nums.right.set(4, 'cuatro') // {one: 1, two: 2, tres: 3, cuatro: 4}
// deleting
delete nums.left.tres // {one: 1, two: 2, cuatro: 4}
nums.right.delete(4) // {one: 1, two: 2}
// reversing the map
const num2Name = nums.reverse()
console.log([...num2Name.left]) // [[1,'one'], [2,'two']]
console.log(Object.fromEntries(num2Name.right)) // {one: 1, two: 2}
// other methods known from built-in Map
nums.size // 2
nums.[left|right].size // 2
nums.clear() // equivalent to nums.[left|right].clear()
console.log(nums.size) // 0
// giving aliases to both sides
const dictionary = new BiMap(
[
['hello', 'hallo'],
['bye', 'tschüss'],
],
'en',
'de'
)
dictionary.de.get('hallo') // 'hello'
dictionary.en.get('bye') // 'tschüss'
delete dictionary.de.hallo
console.log(Object.fromEntries(dictionary.en)) // { bye: 'tschüss' }
// you can also use the BiMap.alias method:
BiMap.alias('en', 'de')<string, string>()
BiMap.alias('en', 'de')([['hello', 'hallo']])
BiMap.alias('en', 'de')(new Map<string, string>())
BiMap.alias('en', 'de')({ hello: 'hallo' })
BiMap.alias('en', 'de')(new Set(['hello']), new Set(['hallo']))
// the same arguments can be used with BiMap.from, e.g.:
BiMap.from(new Set<number>(), new Set<number>())
SortedArray
class SortedArray<T>(compare: Cmp<T>, ...value: T[])
Sorted array. Behaves much like a regular array but its elements remain sorted using the
compare
function supplied in the constructor.Contains most of the methods defined on regular JavaScript arrays as long as they don't modify the array's content in place.
New elements are added using the
add(...values)
method.Elements can still be accessed using bracket notation as in plain JavaScript arrays but can't be assigned to using bracket notation (as that could change the element's sort position).
Elements can be removed using the
delete(...indices)
method, which returns an array containing the deleted values. Deleting an element usingdelete sorted[index]
will also work, but results in a TypeScript error because element access is marked readonly.Array methods that pass a reference of the array to a callback (e.g.
map
,reduce
,find
) will pass a reference to the SortedArray instance instead.The
filter
andslice
methods will return SortedArray instances instead of plain arrays.
Import
/* Node: */ import SortedArray from "froebel/sortedArray";
/* Deno: */ import SortedArray from "https://deno.land/x/[email protected]/sortedArray.ts";
SortedMap
class SortedMap<K, V>(compare: Cmp<K, V>, entries?: null | [K, V][])
Behaves like a regular JavaScript
Map
, but its iteration order is dependant on thecompare
function supplied in the constructor.Note: The item's sort position is only computed automatically on insertion. If you update one of the values that the
compare
function depends on, you must call theupdate(key)
method afterwards to ensure the map stays sorted.
Import
/* Node: */ import SortedMap from "froebel/sortedMap";
/* Deno: */ import SortedMap from "https://deno.land/x/[email protected]/sortedMap.ts";