API / Belt / SetInt

SetInt

Specialized when value type is int, more efficient than the generic type, its compare behavior is fixed using the built-in comparison.

value

RES
type value = int

The type of the set elements.

t

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type t

Type of the sets.

empty

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let empty: t

Empty set

RES
let s0 = Belt.Set.Int.empty

fromArray

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let fromArray: array<value> => t

Creates new set from array of elements.

RES
let s0 = Belt.Set.Int.fromArray([1, 3, 2, 4]) s0->Belt.Set.Int.toArray /* [1, 2, 3, 4] */

fromSortedArrayUnsafe

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let fromSortedArrayUnsafe: array<value> => t

The same as [fromArray][#fromarray] except it is after assuming the input array is already sorted.

isEmpty

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let isEmpty: t => bool

Checks if set is empty.

RES
let empty = Belt.Set.Int.fromArray([]) let notEmpty = Belt.Set.Int.fromArray([1]) Belt.Set.Int.isEmpty(empty) /* true */ Belt.Set.Int.isEmpty(notEmpty) /* false */

has

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let has: (t, value) => bool

Checks if element exists in set.

RES
let set = Belt.Set.Int.fromArray([1, 4, 2, 5]) set->Belt.Set.Int.has(3) /* false */ set->Belt.Set.Int.has(1) /* true */

add

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let add: (t, value) => t

Adds element to set. If element existed in set, value is unchanged.

RES
let s0 = Belt.Set.Int.empty let s1 = s0->Belt.Set.Int.add(1) let s2 = s1->Belt.Set.Int.add(2) let s3 = s2->Belt.Set.Int.add(2) s0->Belt.Set.Int.toArray /* [] */ s1->Belt.Set.Int.toArray /* [1] */ s2->Belt.Set.Int.toArray /* [1, 2] */ s3->Belt.Set.Int.toArray /* [1,2 ] */ s2 == s3 /* true */

mergeMany

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let mergeMany: (t, array<value>) => t

Adds each element of array to set. Unlike add, the reference of return value might be changed even if all values in array already exist in set

RES
let set = Belt.Set.Int.empty let newSet = set->Belt.Set.Int.mergeMany([5, 4, 3, 2, 1]) newSet->Belt.Set.Int.toArray /* [1, 2, 3, 4, 5] */

remove

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let remove: (t, value) => t

Removes element from set. If element wasn't existed in set, value is unchanged.

RES
let s0 = Belt.Set.Int.fromArray([2, 3, 1, 4, 5]) let s1 = s0->Belt.Set.Int.remove(1) let s2 = s1->Belt.Set.Int.remove(3) let s3 = s2->Belt.Set.Int.remove(3) s1->Belt.Set.Int.toArray /* [2,3,4,5] */ s2->Belt.Set.Int.toArray /* [2,4,5] */ s2 == s3 /* true */

removeMany

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let removeMany: (t, array<value>) => t

Removes each element of array from set. Unlike remove, the reference of return value might be changed even if any values in array not existed in set.

RES
let set = Belt.Set.Int.fromArray([1, 2, 3, 4]) let newSet = set->Belt.Set.Int.removeMany([5, 4, 3, 2, 1]) newSet->Belt.Set.Int.toArray /* [] */

union

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let union: (t, t) => t

Returns union of two sets.

RES
let s0 = Belt.Set.Int.fromArray([5, 2, 3, 5, 6]) let s1 = Belt.Set.Int.fromArray([5, 2, 3, 1, 5, 4]) let union = Belt.Set.Int.union(s0, s1) union->Belt.Set.Int.toArray /* [1,2,3,4,5,6] */

intersect

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let intersect: (t, t) => t

Returns intersection of two sets.

RES
let s0 = Belt.Set.Int.fromArray([5, 2, 3, 5, 6]) let s1 = Belt.Set.Int.fromArray([5, 2, 3, 1, 5, 4]) let intersect = Belt.Set.Int.intersect(s0, s1) intersect->Belt.Set.Int.toArray /* [2,3,5] */

diff

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let diff: (t, t) => t

Returns elements from first set, not existing in second set.

RES
let s0 = Belt.Set.Int.fromArray([5, 2, 3, 5, 6]) let s1 = Belt.Set.Int.fromArray([5, 2, 3, 1, 5, 4]) Belt.Set.Int.toArray(Belt.Set.Int.diff(s0, s1)) /* [6] */ Belt.Set.Int.toArray(Belt.Set.Int.diff(s1, s0)) /* [1,4] */

subset

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let subset: (t, t) => bool

Checks if second set is subset of first set.

RES
let s0 = Belt.Set.Int.fromArray([5, 2, 3, 5, 6]) let s1 = Belt.Set.Int.fromArray([5, 2, 3, 1, 5, 4]) let s2 = Belt.Set.Int.intersect(s0, s1) Belt.Set.Int.subset(s2, s0) /* true */ Belt.Set.Int.subset(s2, s1) /* true */ Belt.Set.Int.subset(s1, s0) /* false */

cmp

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let cmp: (t, t) => int

Total ordering between sets. Can be used as the ordering function for doing sets of sets. It compares size first and then iterates over each element following the order of elements.

eq

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let eq: (t, t) => bool

Checks if two sets are equal.

RES
let s0 = Belt.Set.Int.fromArray([5, 2, 3]) let s1 = Belt.Set.Int.fromArray([3, 2, 5]) Belt.Set.Int.eq(s0, s1) /* true */

forEachU

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let forEachU: (t, (. value) => unit) => unit

Same as forEach but takes uncurried functon.

forEach

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let forEach: (t, value => unit) => unit

Applies function f in turn to all elements of set in increasing order.

RES
let s0 = Belt.Set.Int.fromArray([5, 2, 3, 5, 6]) let acc = ref(list{}) s0->Belt.Set.Int.forEach(x => acc := Belt.List.add(acc.contents, x)) acc /* [6,5,3,2] */

reduceU

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let reduceU: (t, 'a, (. 'a, value) => 'a) => 'a

reduce

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let reduce: (t, 'a, ('a, value) => 'a) => 'a

Applies function f to each element of set in increasing order. Function f has two parameters: the item from the set and an “accumulator”, which starts with a value of initialValue. reduce returns the final value of the accumulator.

RES
let s0 = Belt.Set.Int.fromArray([5, 2, 3, 5, 6]) s0->Belt.Set.Int.reduce(list{}, (acc, element) => acc->Belt.List.add(element)) /* [6,5,3,2] */

everyU

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let everyU: (t, (. value) => bool) => bool

every

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let every: (t, value => bool) => bool

Checks if all elements of the set satisfy the predicate. Order unspecified.

RES
let isEven = x => mod(x, 2) == 0 let s0 = Belt.Set.Int.fromArray([2, 4, 6, 8]) s0->Belt.Set.Int.every(isEven) /* true */

someU

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let someU: (t, (. value) => bool) => bool

some

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let some: (t, value => bool) => bool

Checks if at least one element of the set satisfies the predicate.

RES
let isOdd = x => mod(x, 2) != 0 let s0 = Belt.Set.Int.fromArray([1, 2, 4, 6, 8]) s0->Belt.Set.Int.some(isOdd) /* true */

keepU

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let keepU: (t, (. value) => bool) => t

keep

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let keep: (t, value => bool) => t

Returns the set of all elements that satisfy the predicate.

RES
let isEven = x => mod(x, 2) == 0 let s0 = Belt.Set.Int.fromArray([1, 2, 3, 4, 5]) let s1 = s0->Belt.Set.Int.keep(isEven) s1->Belt.Set.Int.toArray /* [2,4] */

partitionU

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let partitionU: (t, (. value) => bool) => (t, t)

partition

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let partition: (t, value => bool) => (t, t)

Returns a pair of sets, where first is the set of all the elements of set that satisfy the predicate, and second is the set of all the elements of set that do not satisfy the predicate.

RES
let isOdd = x => mod(x, 2) != 0 let s0 = Belt.Set.Int.fromArray([1, 2, 3, 4, 5]) let (s1, s2) = s0->Belt.Set.Int.partition(isOdd) s1->Belt.Set.Int.toArray /* [1,3,5] */ s2->Belt.Set.Int.toArray /* [2,4] */

size

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let size: t => int

Returns size of the set.

RES
let s0 = Belt.Set.Int.fromArray([1, 2, 3, 4]) s0->Belt.Set.Int.size /* 4 */

toList

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let toList: t => list<value>

Returns list of ordered set elements.

RES
let s0 = Belt.Set.Int.fromArray([3, 2, 1, 5]) s0->Belt.Set.Int.toList /* [1,2,3,5] */

toArray

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let toArray: t => array<value>

Returns array of ordered set elements.

RES
let s0 = Belt.Set.Int.fromArray([3, 2, 1, 5]) s0->Belt.Set.Int.toArray /* [1,2,3,5] */

minimum

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let minimum: t => option<value>

Returns minimum value of the collection. None if collection is empty.

RES
let s0 = Belt.Set.Int.empty let s1 = Belt.Set.Int.fromArray([3, 2, 1, 5]) s0->Belt.Set.Int.minimum /* None */ s1->Belt.Set.Int.minimum /* Some(1) */

minUndefined

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let minUndefined: t => Js.undefined<value>

Returns minimum value of the collection. undefined if collection is empty.

RES
let s0 = Belt.Set.Int.empty let s1 = Belt.Set.Int.fromArray([3, 2, 1, 5]) s0->Belt.Set.Int.minUndefined /* undefined */ s1->Belt.Set.Int.minUndefined /* 1 */

maximum

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let maximum: t => option<value>

Returns maximum value of the collection. None if collection is empty.

RES
let s0 = Belt.Set.Int.empty let s1 = Belt.Set.Int.fromArray([3, 2, 1, 5]) s0->Belt.Set.Int.maximum /* None */ s1->Belt.Set.Int.maximum /* Some(5) */

maxUndefined

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let maxUndefined: t => Js.undefined<value>

Returns maximum value of the collection. undefined if collection is empty.

RES
let s0 = Belt.Set.Int.empty let s1 = Belt.Set.Int.fromArray([3, 2, 1, 5]) s0->Belt.Set.Int.maxUndefined /* undefined */ s1->Belt.Set.Int.maxUndefined /* 5 */

get

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let get: (t, value) => option<value>

Returns the reference of the value which is equivalent to value using the comparator specifiecd by this collection. Returns None if element does not exist.

RES
let s0 = Belt.Set.Int.fromArray([1, 2, 3, 4, 5]) s0->Belt.Set.Int.get(3) /* Some(3) */ s0->Belt.Set.Int.get(20) /* None */

getUndefined

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let getUndefined: (t, value) => Js.undefined<value>

Same as get but returns undefined when element does not exist.

getExn

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let getExn: (t, value) => value

Same as get but raise when element does not exist.

split

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let split: (t, value) => ((t, t), bool)

Returns a tuple ((l, r), present), where l is the set of elements of set that are strictly less than value, r is the set of elements of set that are strictly greater than value, present is false if set contains no element equal to value, or true if set contains an element equal to value.

RES
let s0 = Belt.Set.Int.fromArray([1, 2, 3, 4, 5]) let ((smaller, larger), present) = s0->Belt.Set.Int.split(3) present /* true */ smaller->Belt.Set.Int.toArray /* [1,2] */ larger->Belt.Set.Int.toArray /* [4,5] */

checkInvariantInternal

RES
let checkInvariantInternal: t => unit

raise when invariant is not held