Int
This module is Belt.Set
specialized with value type to be a primitive type.
It is more efficient in general, the API is the same with Belt_Set
except its value type is fixed,
and identity is not needed(using the built-in one)
See Belt.Set
value
type value = int
The type of the set elements.
t
type t
The type of sets.
empty
let empty: t
fromArray
let fromArray: array<value> => t
fromSortedArrayUnsafe
let fromSortedArrayUnsafe: array<value> => t
isEmpty
let isEmpty: t => bool
has
let has: (t, value) => bool
add
let add: (t, value) => t
add(s, x)
If x
was already in s
, s
is returned unchanged.
mergeMany
let mergeMany: (t, array<value>) => t
remove
let remove: (t, value) => t
remove(m, x)
If x
was not in m
, m
is returned reference unchanged.
removeMany
let removeMany: (t, array<value>) => t
union
let union: (t, t) => t
intersect
let intersect: (t, t) => t
diff
let diff: (t, t) => t
subset
let subset: (t, t) => bool
subset(s1, s2)
tests whether the set s1
is a subset of the set s2
.
cmp
let cmp: (t, t) => int
Total ordering between sets. Can be used as the ordering function for doing sets of sets.
eq
let eq: (t, t) => bool
eq(s1, s2)
tests whether the sets s1
and s2
are equal, that is, contain
equal elements.
forEachU
let forEachU: (t, value => unit) => unit
forEach
let forEach: (t, value => unit) => unit
forEach(s, f)
applies f
in turn to all elements of s
. In increasing order
reduceU
let reduceU: (t, 'a, ('a, value) => 'a) => 'a
reduce
let reduce: (t, 'a, ('a, value) => 'a) => 'a
Iterate in increasing order.
everyU
let everyU: (t, value => bool) => bool
every
let every: (t, value => bool) => bool
every(p, s)
checks if all elements of the set satisfy the predicate p
. Order
unspecified.
someU
let someU: (t, value => bool) => bool
some
let some: (t, value => bool) => bool
some(p, s)
checks if at least one element of the set satisfies the predicate
p
. Oder unspecified.
keepU
let keepU: (t, value => bool) => t
keep
let keep: (t, value => bool) => t
keep(p, s)
returns the set of all elements in s
that satisfy predicate p
.
partitionU
let partitionU: (t, value => bool) => (t, t)
partition
let partition: (t, value => bool) => (t, t)
partition(p, s)
returns a pair of sets (s1, s2)
, where s1
is the set of
all the elements of s
that satisfy the predicate p
, and s2
is the set of
all the elements of s
that do not satisfy p
.
size
let size: t => int
toList
let toList: t => list<value>
In increasing order
toArray
let toArray: t => array<value>
minimum
let minimum: t => option<value>
minUndefined
let minUndefined: t => Js.undefined<value>
maximum
let maximum: t => option<value>
maxUndefined
let maxUndefined: t => Js.undefined<value>
get
let get: (t, value) => option<value>
getUndefined
let getUndefined: (t, value) => Js.undefined<value>
getExn
let getExn: (t, value) => value
split
let split: (t, value) => ((t, t), bool)
split(x, s)
returns a triple (l, present, r)
, where l
is the set of
elements of s
that are strictly less than x
;r
is the set of elements of
s
that are strictly greater than x
; present
is false
if s
contains no
element equal to x
, or true
if s
contains an element equal to x
.
checkInvariantInternal
let checkInvariantInternal: t => unit
raise when invariant is not held