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(These docs cover all versions between v3 to v8 and are equivalent to the old BuckleScript docs before the rebrand)
MutableSet
A mutable sorted set module which allows customize compare behavior. The implementation uses balanced binary trees, and therefore searching and insertion take time logarithmic in the size of the map.
It also has three specialized inner modules Belt.MutableSet.Int and Belt.MutableSet.String - This module separates data from function which is more verbose but slightly more efficient
REmodule PairComparator =
Belt.Id.MakeComparable({
type t = (int, int);
let cmp = ((a0, a1), (b0, b1)) =>
switch (Pervasives.compare(a0, b0)) {
| 0 => Pervasives.compare(a1, b1)
| c => c
};
});
let mySet = Belt.MutableSet.make(~id=(module PairComparator));
mySet->Belt.MutableSet.add((1, 2));
t
REtype t('value, 'id);
'value
is the element type
'id
the identity of the collection
id
REtype id('value, 'id) = Belt_Id.comparable('value, 'id);
The identity needed for making a set from scratch
make
RElet make: (~id: id('value, 'id)) => t('value, 'id);
Creates a new set by taking in the comparator
fromArray
RElet fromArray: (array('value), ~id: id('value, 'id)) => t('value, 'id);
Creates new set from array of elements.
REmodule IntCmp =
Belt.Id.MakeComparable({
type t = int;
let cmp = Pervasives.compare;
});
let s0 = Belt.MutableSet.fromArray([|1, 3, 2, 4|], ~id=(module IntCmp))
s0->Belt.MutableSet.toArray; /* [|1, 2, 3, 4|] */
fromSortedArrayUnsafe
RElet fromSortedArrayUnsafe: (array('value), ~id: id('value, 'id)) => t('value, 'id);
The same as [fromArray][#fromarray] except it is after assuming the input array is already sorted.
copy
RElet copy: t('value, 'id) => t('value, 'id);
Returns copy of a set.
REmodule IntCmp =
Belt.Id.MakeComparable({
type t = int;
let cmp = Pervasives.compare;
});
let s0 = Belt.MutableSet.fromArray([|1, 3, 2, 4|], ~id=(module IntCmp))
let copied = s0->Belt.MutableSet.copy;
copied->Belt.MutableSet.toArray /* [|1, 2, 3, 4|] */
isEmpty
RElet isEmpty: t('a, 'b) => bool;
Checks if set is empty.
REmodule IntCmp =
Belt.Id.MakeComparable({
type t = int;
let cmp = Pervasives.compare;
});
let empty = Belt.MutableSet.fromArray([||], ~id=(module IntCmp));
let notEmpty = Belt.MutableSet.fromArray([|1|],~id=(module IntCmp));
Belt.MutableSet.isEmpty(empty); /* true */
Belt.MutableSet.isEmpty(notEmpty); /* false */
has
RElet has: (t('value, 'a), 'value) => bool;
Checks if element exists in set.
REmodule IntCmp =
Belt.Id.MakeComparable({
type t = int;
let cmp = Pervasives.compare;
});
let set = Belt.MutableSet.fromArray([|1, 4, 2, 5|], ~id=(module IntCmp));
set->Belt.MutableSet.has(3) /* false */
set->Belt.MutableSet.has(1) /* true */
add
RElet add: (t('value, 'id), 'value) => unit;
Adds element to set. If element existed in set, value is unchanged.
REmodule IntCmp =
Belt.Id.MakeComparable({
type t = int;
let cmp = Pervasives.compare;
});
let s0 = Belt.MutableSet.make(~id=(module IntCmp));
s0->Belt.MutableSet.add(1);
s0->Belt.MutableSet.add(2);
s0->Belt.MutableSet.add(2);
s0->Belt.MutableSet.toArray; /* [|1, 2|] */
addCheck
RElet addCheck: (t('value, 'id), 'value) => bool;
mergeMany
RElet mergeMany: (t('value, 'id), array('value)) => unit;
Adds each element of array to set.
REmodule IntCmp =
Belt.Id.MakeComparable({
type t = int;
let cmp = Pervasives.compare;
});
let set = Belt.MutableSet.make(~id=(module IntCmp));
set->Belt.MutableSet.mergeMany([|5, 4, 3, 2, 1|]);
set->Belt.MutableSet.toArray; /* [|1, 2, 3, 4, 5|] */
remove
RElet remove: (t('value, 'id), 'value) => unit;
Removes element from set. If element wasn't existed in set, value is unchanged.
REmodule IntCmp =
Belt.Id.MakeComparable({
type t = int;
let cmp = Pervasives.compare;
});
let s0 = Belt.MutableSet.fromArray([|2,3,1,4,5|], ~id=(module IntCmp));
s0->Belt.MutableSet.remove(1);
s0->Belt.MutableSet.remove(3);
s0->Belt.MutableSet.remove(3);
s0->Belt.MutableSet.toArray; /* [|2,4,5|] */
removeCheck
RElet removeCheck: (t('value, 'id), 'value) => bool;
removeMany
RElet removeMany: (t('value, 'id), array('value)) => unit;
Removes each element of array from set.
REmodule IntCmp =
Belt.Id.MakeComparable({
type t = int;
let cmp = Pervasives.compare;
});
let set = Belt.MutableSet.fromArray([|1, 2, 3, 4|],~id=(module IntCmp));
set->Belt.MutableSet.removeMany([|5, 4, 3, 2, 1|]);
set->Belt.MutableSet.toArray; /* [||] */
union
RElet union: (t('value, 'id), t('value, 'id)) => t('value, 'id);
Returns union of two sets.
REmodule IntCmp =
Belt.Id.MakeComparable({
type t = int;
let cmp = Pervasives.compare;
});
let s0 = Belt.MutableSet.fromArray([|5,2,3,5,6|], ~id=(module IntCmp));
let s1 = Belt.MutableSet.fromArray([|5,2,3,1,5,4|], ~id=(module IntCmp));
let union = Belt.MutableSet.union(s0, s1);
union->Belt.MutableSet.toArray; /* [|1,2,3,4,5,6|] */
intersect
RElet intersect: (t('value, 'id), t('value, 'id)) => t('value, 'id);
Returns intersection of two sets.
REmodule IntCmp =
Belt.Id.MakeComparable({
type t = int;
let cmp = Pervasives.compare;
});
let s0 = Belt.MutableSet.fromArray([|5,2,3,5,6|], ~id=(module IntCmp));
let s1 = Belt.MutableSet.fromArray([|5,2,3,1,5,4|], ~id=(module IntCmp));
let intersect = Belt.MutableSet.intersect(s0, s1);
intersect->Belt.MutableSet.toArray; /* [|2,3,5|] */
diff
RElet diff: (t('value, 'id), t('value, 'id)) => t('value, 'id);
Returns elements from first set, not existing in second set.
REmodule IntCmp =
Belt.Id.MakeComparable({
type t = int;
let cmp = Pervasives.compare;
});
let s0 = Belt.MutableSet.fromArray([|5,2,3,5,6|], ~id=(module IntCmp));
let s1 = Belt.MutableSet.fromArray([|5,2,3,1,5,4|], ~id=(module IntCmp));
Belt.MutableSet.toArray(Belt.MutableSet.diff(s0, s1)); /* [|6|] */
Belt.MutableSet.toArray(Belt.MutableSet.diff(s1,s0)); /* [|1,4|] */
subset
RElet subset: (t('value, 'id), t('value, 'id)) => bool;
Checks if second set is subset of first set.
REmodule IntCmp =
Belt.Id.MakeComparable({
type t = int;
let cmp = Pervasives.compare;
});
let s0 = Belt.MutableSet.fromArray([|5,2,3,5,6|], ~id=(module IntCmp));
let s1 = Belt.MutableSet.fromArray([|5,2,3,1,5,4|], ~id=(module IntCmp));
let s2 = Belt.MutableSet.intersect(s0, s1);
Belt.MutableSet.subset(s2, s0); /* true */
Belt.MutableSet.subset(s2, s1); /* true */
Belt.MutableSet.subset(s1, s0); /* false */
cmp
RElet cmp: (t('value, 'id), t('value, 'id)) => 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
RElet eq: (t('value, 'id), t('value, 'id)) => bool;
Checks if two sets are equal.
REmodule IntCmp =
Belt.Id.MakeComparable({
type t = int;
let cmp = Pervasives.compare;
});
let s0 = Belt.MutableSet.fromArray([|5,2,3|], ~id=(module IntCmp));
let s1 = Belt.MutableSet.fromArray([|3,2,5|], ~id=(module IntCmp));
Belt.MutableSet.eq(s0, s1); /* true */
forEachU
RElet forEachU: (t('value, 'id), [@bs] ('value => unit)) => unit;
Same as forEach but takes uncurried functon.
forEach
RElet forEach: (t('value, 'id), 'value => unit) => unit;
Applies function f
in turn to all elements of set in increasing order.
REmodule IntCmp =
Belt.Id.MakeComparable({
type t = int;
let cmp = Pervasives.compare;
});
let s0 = Belt.MutableSet.fromArray([|5,2,3,5,6|], ~id=(module IntCmp));
let acc = ref([]);
s0->Belt.MutableSet.forEach(x => {
acc := Belt.List.add(acc^, x)
});
acc; /* [6,5,3,2] */
reduceU
RElet reduceU: (t('value, 'id), 'a, [@bs] (('a, 'value) => 'a)) => 'a;
reduce
RElet reduce: (t('value, 'id), '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.
REmodule IntCmp =
Belt.Id.MakeComparable({
type t = int;
let cmp = Pervasives.compare;
});
let s0 = Belt.MutableSet.fromArray([|5,2,3,5,6|], ~id=(module IntCmp));
s0->Belt.MutableSet.reduce([], (acc, element) =>
acc->Belt.List.add(element)
); /* [6,5,3,2] */
everyU
RElet everyU: (t('value, 'id), [@bs] ('value => bool)) => bool;
every
RElet every: (t('value, 'id), 'value => bool) => bool;
Checks if all elements of the set satisfy the predicate. Order unspecified.
REmodule IntCmp =
Belt.Id.MakeComparable({
type t = int;
let cmp = Pervasives.compare;
});
let isEven = x => x mod 2 == 0;
let s0 = Belt.MutableSet.fromArray([|2,4,6,8|], ~id=(module IntCmp));
s0->Belt.MutableSet.every(isEven); /* true */
someU
RElet someU: (t('value, 'id), [@bs] ('value => bool)) => bool;
some
RElet some: (t('value, 'id), 'value => bool) => bool;
Checks if at least one element of the set satisfies the predicate.
REmodule IntCmp =
Belt.Id.MakeComparable({
type t = int;
let cmp = Pervasives.compare;
});
let isOdd = x => x mod 2 != 0;
let s0 = Belt.MutableSet.fromArray([|1,2,4,6,8|], ~id=(module IntCmp));
s0->Belt.MutableSet.some(isOdd); /* true */
keepU
RElet keepU: (t('value, 'id), [@bs] ('value => bool)) => t('value, 'id);
keep
RElet keep: (t('value, 'id), 'value => bool) => t('value, 'id);
Returns the set of all elements that satisfy the predicate.
REmodule IntCmp =
Belt.Id.MakeComparable({
type t = int;
let cmp = Pervasives.compare;
});
let isEven = x => x mod 2 == 0;
let s0 = Belt.MutableSet.fromArray([|1,2,3,4,5|], ~id=(module IntCmp));
let s1 = s0->Belt.MutableSet.keep(isEven);
s1->Belt.MutableSet.toArray; /* [|2, 4|] */
partitionU
RElet partitionU: (t('value, 'id), [@bs] ('value => bool)) => (t('value, 'id), t('value, 'id));
partition
RElet partition: (t('value, 'id), 'value => bool) => (t('value, 'id), t('value, 'id));
REmodule IntCmp =
Belt.Id.MakeComparable({
type t = int;
let cmp = Pervasives.compare;
});
let isOdd = x => x mod 2 != 0;
let s0 = Belt.MutableSet.fromArray([|1,2,3,4,5|], ~id=(module IntCmp));
let (s1, s2) = s0->Belt.MutableSet.partition(isOdd);
s1->Belt.MutableSet.toArray; /* [|1,3,5|] */
s2->Belt.MutableSet.toArray; /* [|2,4|] */
size
RElet size: t('value, 'id) => int;
Returns size of the set.
REmodule IntCmp =
Belt.Id.MakeComparable({
type t = int;
let cmp = Pervasives.compare;
});
let s0 = Belt.MutableSet.fromArray([|1,2,3,4|], ~id=(module IntCmp));
s0->Belt.MutableSet.size; /* 4 */
toList
RElet toList: t('value, 'id) => list('value);
Returns list of ordered set elements.
REmodule IntCmp =
Belt.Id.MakeComparable({
type t = int;
let cmp = Pervasives.compare;
});
let s0 = Belt.MutableSet.fromArray([|3,2,1,5|], ~id=(module IntCmp));
s0->Belt.MutableSet.toList; /* [1,2,3,5] */
toArray
RElet toArray: t('value, 'id) => array('value);
Returns array of ordered set elements.
REmodule IntCmp =
Belt.Id.MakeComparable({
type t = int;
let cmp = Pervasives.compare;
});
let s0 = Belt.MutableSet.fromArray([|3,2,1,5|], ~id=(module IntCmp));
s0->Belt.MutableSet.toArray; /* [|1,2,3,5|] */
minimum
RElet minimum: t('value, 'id) => option('value);
Returns minimum value of the collection. None
if collection is empty.
REmodule IntCmp =
Belt.Id.MakeComparable({
type t = int;
let cmp = Pervasives.compare;
});
let s0 = Belt.MutableSet.make(~id=(module IntCmp));
let s1 = Belt.MutableSet.fromArray([|3,2,1,5|], ~id=(module IntCmp));
s0->Belt.MutableSet.minimum; /* None */
s1->Belt.MutableSet.minimum; /* Some(1) */
minUndefined
RElet minUndefined: t('value, 'id) => Js.undefined('value);
Returns minimum value of the collection. undefined
if collection is empty.
REmodule IntCmp =
Belt.Id.MakeComparable({
type t = int;
let cmp = Pervasives.compare;
});
let s0 = Belt.MutableSet.make(~id=(module IntCmp));
let s1 = Belt.MutableSet.fromArray([|3,2,1,5|], ~id=(module IntCmp));
s0->Belt.MutableSet.minUndefined; /* undefined */
s1->Belt.MutableSet.minUndefined; /* 1 */
maximum
RElet maximum: t('value, 'id) => option('value);
Returns maximum value of the collection. None
if collection is empty.
REmodule IntCmp =
Belt.Id.MakeComparable({
type t = int;
let cmp = Pervasives.compare;
});
let s0 = Belt.MutableSet.make(~id=(module IntCmp));
let s1 = Belt.MutableSet.fromArray([|3,2,1,5|], ~id=(module IntCmp));
s0->Belt.MutableSet.maximum; /* None */
s1->Belt.MutableSet.maximum; /* Some(5) */
maxUndefined
RElet maxUndefined: t('value, 'id) => Js.undefined('value);
Returns maximum value of the collection. undefined
if collection is empty.
REmodule IntCmp =
Belt.Id.MakeComparable({
type t = int;
let cmp = Pervasives.compare;
});
let s0 = Belt.MutableSet.make(~id=(module IntCmp));
let s1 = Belt.MutableSet.fromArray([|3,2,1,5|], ~id=(module IntCmp));
s0->Belt.MutableSet.maxUndefined; /* undefined */
s1->Belt.MutableSet.maxUndefined; /* 5 */
get
RElet get: (t('value, 'id), '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.
REmodule IntCmp =
Belt.Id.MakeComparable({
type t = int;
let cmp = Pervasives.compare;
});
let s0 = Belt.MutableSet.fromArray([|1,2,3,4,5|], ~id=(module IntCmp));
s0->Belt.MutableSet.get(3); /* Some(3) */
s0->Belt.MutableSet.get(20); /* None */
getUndefined
RElet getUndefined: (t('value, 'id), 'value) => Js.undefined('value);
Same as get but returns undefined
when element does not exist.
getExn
RElet getExn: (t('value, 'id), 'value) => 'value;
Same as get but raise when element does not exist.
split
RElet split: (t('value, 'id), 'value) => ((t('value, 'id), t('value, 'id)), bool);
Returns a tuple ((smaller, larger), present)
, present
is true when element exist in set.
REmodule IntCmp =
Belt.Id.MakeComparable({
type t = int;
let cmp = Pervasives.compare;
});
let s0 = Belt.MutableSet.fromArray([|1,2,3,4,5|], ~id=(module IntCmp));
let ((smaller, larger), present) = s0->Belt.MutableSet.split(3);
present; /* true */
smaller->Belt.MutableSet.toArray; /* [|1,2|] */
larger->Belt.MutableSet.toArray; /* [|4,5|] */
checkInvariantInternal
RElet checkInvariantInternal: t('a, 'b) => unit;
raise when invariant is not held