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maps(3erl) Erlang Module Definition maps(3erl)

NAME

maps - Maps processing functions.

DESCRIPTION

This module contains functions for maps processing. The Efficiency Guide contains a chapter that describes how to use maps efficiently.

DATA TYPES

iterator(Key, Value)

An iterator representing the associations in a map with keys of type Key and values of type Value.

Created using maps:iterator/1 or maps:iterator/2.

Consumed by:

*
maps:next/1
*
maps:filter/2
*
maps:filtermap/2
*
maps:fold/3
*
maps:foreach/2
*
maps:map/2
*
maps:to_list/1

iterator() = iterator(term(), term())

iterator_order(Key) = 

undefined | ordered | reversed |
fun((A :: Key, B :: Key) -> boolean())

Key-based iterator order option that can be one of undefined (default for maps:iterator/1), ordered (sorted in map-key order), reversed, or a custom sorting function.

Used by maps:iterator/2.

The Expressions section contains descriptions of how terms are ordered.

iterator_order() = iterator_order(term())

EXPORTS


filter(Pred, MapOrIter) -> Map


Types:

Pred = fun((Key, Value) -> boolean())
MapOrIter = #{Key => Value} | iterator(Key, Value)
Map = #{Key => Value}

Returns a map Map for which predicate Pred holds true in MapOrIter.

The call fails with a {badmap,Map} exception if MapOrIter is not a map or valid iterator, or with badarg if Pred is not a function of arity 2.

Example:

> M = #{a => 2, b => 3, c=> 4, "a" => 1, "b" => 2, "c" => 4},

Pred = fun(K,V) -> is_atom(K) andalso (V rem 2) =:= 0 end,
maps:filter(Pred,M). #{a => 2,c => 4}


filtermap(Fun, MapOrIter) -> Map


Types:

Fun = fun((Key, Value1) -> boolean() | {true, Value2})
MapOrIter = #{Key => Value1} | iterator(Key, Value1)
Map = #{Key => Value1 | Value2}

Returns a map Map that is the result of calling Fun(Key, Value1) for every Key to value Value1 association in MapOrIter in any order.

If Fun(Key, Value1) returns true, the association is copied to the result map. If it returns false, the association is not copied. If it returns {true, NewValue}, the value for Key is replaced with NewValue in the result map.

The call fails with a {badmap,Map} exception if MapOrIter is not a map or valid iterator, or with badarg if Fun is not a function of arity 2.

Example:

> Fun = fun(K,V) when is_atom(K) -> {true, V*2}; (_,V) -> (V rem 2) =:= 0 end,

Map = #{k1 => 1, "k2" => 2, "k3" => 3},
maps:filtermap(Fun,Map). #{k1 => 2,"k2" => 2}


find(Key, Map) -> {ok, Value} | error


Types:

Map = #{Key => Value, term() => term()}

Returns a tuple {ok, Value}, where Value is the value associated with Key, or error if no value is associated with Key in Map.

The call fails with a {badmap,Map} exception if Map is not a map.

Example:

> Map = #{"hi" => 42},

Key = "hi",
maps:find(Key,Map). {ok,42}


fold(Fun, Init, MapOrIter) -> Acc


Types:

Fun = fun((Key, Value, AccIn) -> AccOut)
Init = term()
Acc = AccOut
AccIn = Init | AccOut
MapOrIter = #{Key => Value} | iterator(Key, Value)

Calls F(Key, Value, AccIn) for every Key to value Value association in MapOrIter in any order. Function fun F/3 must return a new accumulator, which is passed to the next successive call. This function returns the final value of the accumulator. The initial accumulator value Init is returned if the map is empty.

The call fails with a {badmap,Map} exception if MapOrIter is not a map or valid iterator, or with badarg if Fun is not a function of arity 3.

Example:

> Fun = fun(K,V,AccIn) when is_list(K) -> AccIn + V end,

Map = #{"k1" => 1, "k2" => 2, "k3" => 3},
maps:fold(Fun,0,Map). 6


foreach(Fun, MapOrIter) -> ok


Types:

Fun = fun((Key, Value) -> term())
MapOrIter = #{Key => Value} | iterator(Key, Value)

Calls fun F(Key, Value) for every Key to value Value association in MapOrIter in any order.

The call fails with a {badmap,Map} exception if MapOrIter is not a map or valid iterator, or with badarg if Fun is not a function of arity 2.


from_keys(Keys, Value) -> Map


Types:

Keys = list()
Value = term()
Map = map()

Takes a list of keys and a value and builds a map where all keys point to the same value. The key can be in any order, and keys and value can be of any term.

Example:

> Keys = ["a", "b", "c"], maps:from_keys(Keys, ok).
#{"a" => ok,"b" => ok,"c" => ok}


from_list(List) -> Map


Types:

List = [{Key, Value}]
Key = Value = term()
Map = map()

Takes a list of key-value tuples elements and builds a map. The associations can be in any order, and both keys and values in the association can be of any term. If the same key appears more than once, the latter (right-most) value is used and the previous values are ignored.

Example:

> List = [{"a",ignored},{1337,"value two"},{42,value_three},{"a",1}],

maps:from_list(List). #{42 => value_three,1337 => "value two","a" => 1}


get(Key, Map) -> Value


Types:

Key = term()
Map = map()
Value = term()

Returns value Value associated with Key if Map contains Key.

The call fails with a {badmap,Map} exception if Map is not a map, or with a {badkey,Key} exception if no value is associated with Key.

Example:

> Key = 1337,

Map = #{42 => value_two,1337 => "value one","a" => 1},
maps:get(Key,Map). "value one"


get(Key, Map, Default) -> Value | Default


Types:

Map = #{Key => Value, term() => term()}

Returns value Value associated with Key if Map contains Key. If no value is associated with Key, Default is returned.

The call fails with a {badmap,Map} exception if Map is not a map.

Example:

> Map = #{ key1 => val1, key2 => val2 }.
#{key1 => val1,key2 => val2}
> maps:get(key1, Map, "Default value").
val1
> maps:get(key3, Map, "Default value").
"Default value"


groups_from_list(KeyFun, List) -> GroupsMap


Types:

KeyFun = fun((Elem) -> Key)
GroupsMap = #{Key => Group}
Key = term()
List = Group = [Elem]
Elem = term()

Partitions the given List into a map of groups.

The result is a map where each key is given by KeyFun and each value is a list of elements from the given List for which KeyFun returned the same key.

The order of elements within each group list is preserved from the original list.

Examples:

> EvenOdd = fun(X) -> case X rem 2 of 0 -> even; 1 -> odd end end,
maps:groups_from_list(EvenOdd, [1, 2, 3]).
#{even => [2], odd => [1, 3]}
> maps:groups_from_list(fun erlang:length/1, ["ant", "buffalo", "cat", "dingo"]).
#{3 => ["ant", "cat"], 5 => ["dingo"], 7 => ["buffalo"]}


groups_from_list(KeyFun, ValueFun, List) -> GroupsMap


Types:

KeyFun = fun((Elem) -> Key)
ValueFun = fun((Elem) -> Value)
GroupsMap = #{Key := Group}
Key = Value = term()
List = [Elem]
Group = [Value]
Elem = term()

Partitions the given List into a map of groups.

The result is a map where each key is given by KeyFun and each value is a list of elements from the given List, mapped via ValueFun, for which KeyFun returned the same key.

The order of elements within each group list is preserved from the original list.

Examples:

> EvenOdd = fun(X) -> case X rem 2 of 0 -> even; 1 -> odd end end,
> Square = fun(X) -> X * X end,
> maps:groups_from_list(EvenOdd, Square, [1, 2, 3]).
#{even => [4], odd => [1, 9]}
> maps:groups_from_list(

fun erlang:length/1,
fun lists:reverse/1,
["ant", "buffalo", "cat", "dingo"]). #{3 => ["tna", "tac"],5 => ["ognid"],7 => ["olaffub"]}


intersect(Map1, Map2) -> Map3


Types:

Map1 = #{Key => term()}
Map2 = #{term() => Value2}
Map3 = #{Key => Value2}

Intersects two maps into a single map Map3. If a key exists in both maps, the value in Map1 is superseded by the value in Map2.

The call fails with a {badmap,Map} exception if Map1 or Map2 is not a map.

Example:

> Map1 = #{a => "value_one", b => "value_two"},

Map2 = #{a => 1, c => 2},
maps:intersect(Map1,Map2). #{a => 1}


intersect_with(Combiner, Map1, Map2) -> Map3


Types:

Map1 = #{Key => Value1}
Map2 = #{term() => Value2}
Combiner = fun((Key, Value1, Value2) -> CombineResult)
Map3 = #{Key => CombineResult}

Intersects two maps into a single map Map3. If a key exists in both maps, the value in Map1 is combined with the value in Map2 by the Combiner fun. When Combiner is applied the key that exists in both maps is the first parameter, the value from Map1 is the second parameter, and the value from Map2 is the third parameter.

The call fails with a {badmap,Map} exception if Map1 or Map2 is not a map. The call fails with a badarg exception if Combiner is not a fun that takes three arguments.

Example:

> Map1 = #{a => "value_one", b => "value_two"},

Map2 = #{a => 1, c => 2},
maps:intersect_with(fun(_Key, Value1, Value2) -> {Value1, Value2} end, Map1, Map2). #{a => {"value_one",1}}


is_key(Key, Map) -> boolean()


Types:

Key = term()
Map = map()

Returns true if map Map contains Key and returns false if it does not contain the Key.

The call fails with a {badmap,Map} exception if Map is not a map.

Example:

> Map = #{"42" => value}.
#{"42" => value}
> maps:is_key("42",Map).
true
> maps:is_key(value,Map).
false


iterator(Map) -> Iterator


Types:

Map = #{Key => Value}
Iterator = iterator(Key, Value)

Returns a map iterator Iterator that can be used by maps:next/1 to traverse the key-value associations in a map. When iterating over a map, the memory usage is guaranteed to be bounded no matter the size of the map.

The call fails with a {badmap,Map} exception if Map is not a map.

Example:

> M = #{ a => 1, b => 2 }.
#{a => 1,b => 2}
> I = maps:iterator(M), ok.
ok
> {K1, V1, I2} = maps:next(I), {K1, V1}.
{a,1}
> {K2, V2, I3} = maps:next(I2),{K2, V2}.
{b,2}
> maps:next(I3).
none


iterator(Map, Order) -> Iterator


Types:

Map = #{Key => Value}
Order = iterator_order(Key)
Iterator = iterator(Key, Value)

Returns a map iterator Iterator that can be used by maps:next/1 to traverse the key-value associations in a map sorted by key using the given Order.

The call fails with a {badmap,Map} exception if Map is not a map or if Order is invalid.

Example (when Order is ordered):

> M = #{ a => 1, b => 2 }.
#{a => 1,b => 2}
> OrdI = maps:iterator(M, ordered), ok.
ok
> {K1, V1, OrdI2} = maps:next(OrdI), {K1, V1}.
{a,1}
> {K2, V2, OrdI3} = maps:next(OrdI2),{K2, V2}.
{b,2}
> maps:next(OrdI3).
none

Example (when Order is reversed):

> M = #{ a => 1, b => 2 }.
#{a => 1,b => 2}
> RevI = maps:iterator(M, reversed), ok.
ok
> {K2, V2, RevI2} = maps:next(RevI), {K2, V2}.
{b,2}
> {K1, V1, RevI3} = maps:next(RevI2),{K1, V1}.
{a,1}
> maps:next(RevI3).
none

Example (when Order is an arithmetic sorting function):

> M = #{ -1 => a, -1.0 => b, 0 => c, 0.0 => d }.
#{-1 => a,0 => c,-1.0 => b,0.0 => d}
> ArithOrdI = maps:iterator(M, fun(A, B) -> A =< B end), ok.
ok
> maps:to_list(ArithOrdI).
[{-1,a},{-1.0,b},{0,c},{0.0,d}]
> ArithRevI = maps:iterator(M, fun(A, B) -> B < A end), ok.
ok
> maps:to_list(ArithRevI).
[{0.0,d},{0,c},{-1.0,b},{-1,a}]


keys(Map) -> Keys


Types:

Map = #{Key => term()}
Keys = [Key]

Returns a complete list of keys, in any order, which resides within Map.

The call fails with a {badmap,Map} exception if Map is not a map.

Example:

> Map = #{42 => value_three,1337 => "value two","a" => 1},

maps:keys(Map). [42,1337,"a"]


map(Fun, MapOrIter) -> Map


Types:

Fun = fun((Key, Value1) -> Value2)
MapOrIter = #{Key => Value1} | iterator(Key, Value1)
Map = #{Key => Value2}

Produces a new map Map by calling function fun F(Key, Value1) for every Key to value Value1 association in MapOrIter in any order. Function fun Fun/2 must return value Value2 to be associated with key Key for the new map Map.

The call fails with a {badmap,Map} exception if MapOrIter is not a map or valid iterator, or with badarg if Fun is not a function of arity 2.

Example:

> Fun = fun(K,V1) when is_list(K) -> V1*2 end,

Map = #{"k1" => 1, "k2" => 2, "k3" => 3},
maps:map(Fun,Map). #{"k1" => 2,"k2" => 4,"k3" => 6}


merge(Map1, Map2) -> Map3


Types:

Map1 = Map2 = Map3 = map()

Merges two maps into a single map Map3. If two keys exist in both maps, the value in Map1 is superseded by the value in Map2.

The call fails with a {badmap,Map} exception if Map1 or Map2 is not a map.

Example:

> Map1 = #{a => "value_one", b => "value_two"},

Map2 = #{a => 1, c => 2},
maps:merge(Map1,Map2). #{a => 1,b => "value_two",c => 2}


merge_with(Combiner, Map1, Map2) -> Map3


Types:

Map1 = #{Key1 => Value1}
Map2 = #{Key2 => Value2}
Combiner = fun((Key1, Value1, Value2) -> CombineResult)
Map3 = #{Key1 => CombineResult, Key1 => Value1, Key2 => Value2}

Merges two maps into a single map Map3. If a key exists in both maps, the value in Map1 is combined with the value in Map2 by the Combiner fun. When Combiner is applied the key that exists in both maps is the first parameter, the value from Map1 is the second parameter, and the value from Map2 is the third parameter.

The call fails with a {badmap,Map} exception if Map1 or Map2 is not a map. The call fails with a badarg exception if Combiner is not a fun that takes three arguments.

Example:

> Map1 = #{a => "value_one", b => "value_two"},

Map2 = #{a => 1, c => 2},
maps:merge_with(fun(_Key, Value1, Value2) -> {Value1, Value2} end, Map1, Map2). #{a => {"value_one",1},b => "value_two",c => 2}


new() -> Map


Types:

Map = #{}

Returns a new empty map.

Example:

> maps:new().
#{}


next(Iterator) -> {Key, Value, NextIterator} | none


Types:

Iterator = NextIterator = iterator(Key, Value)

Returns the next key-value association in Iterator and a new iterator for the remaining associations in the iterator.

If there are no more associations in the iterator, none is returned.

Example:

> Map = #{a => 1, b => 2, c => 3}.
#{a => 1,b => 2,c => 3}
> I = maps:iterator(Map), ok.
ok
> {K1, V1, I1} = maps:next(I), {K1, V1}.
{a,1}
> {K2, V2, I2} = maps:next(I1), {K2, V2}.
{b,2}
> {K3, V3, I3} = maps:next(I2), {K3, V3}.
{c,3}
> maps:next(I3).
none


put(Key, Value, Map1) -> Map2


Types:

Key = Value = term()
Map1 = Map2 = map()

Associates Key with value Value and inserts the association into map Map2. If key Key already exists in map Map1, the old associated value is replaced by value Value. The function returns a new map Map2 containing the new association and the old associations in Map1.

The call fails with a {badmap,Map} exception if Map1 is not a map.

Example:

> Map = #{"a" => 1}.
#{"a" => 1}
> maps:put("a", 42, Map).
#{"a" => 42}
> maps:put("b", 1337, Map).
#{"a" => 1,"b" => 1337}


remove(Key, Map1) -> Map2


Types:

Key = term()
Map1 = Map2 = map()

Removes the Key, if it exists, and its associated value from Map1 and returns a new map Map2 without key Key.

The call fails with a {badmap,Map} exception if Map1 is not a map.

Example:

> Map = #{"a" => 1}.
#{"a" => 1}
> maps:remove("a",Map).
#{}
> maps:remove("b",Map).
#{"a" => 1}


size(Map) -> integer() >= 0


Types:

Map = map()

Returns the number of key-value associations in Map. This operation occurs in constant time.

Example:

> Map = #{42 => value_two,1337 => "value one","a" => 1},

maps:size(Map). 3


take(Key, Map1) -> {Value, Map2} | error


Types:

Map1 = #{Key => Value, term() => term()}
Map2 = #{term() => term()}

The function removes the Key, if it exists, and its associated value from Map1 and returns a tuple with the removed Value and the new map Map2 without key Key. If the key does not exist error is returned.

The call will fail with a {badmap,Map} exception if Map1 is not a map.

Example:

> Map = #{"a" => "hello", "b" => "world"}.
#{"a" => "hello", "b" => "world"}
> maps:take("a",Map).
{"hello",#{"b" => "world"}}
> maps:take("does not exist",Map).
error


to_list(MapOrIterator) -> [{Key, Value}]


Types:

MapOrIterator = #{Key => Value} | iterator(Key, Value)

Returns a list of pairs representing the key-value associations of MapOrIterator, where the pairs [{K1,V1}, ..., {Kn,Vn}] are returned in arbitrary order.

The call fails with a {badmap,Map} exception if MapOrIterator is not a map or an iterator obtained by a call to iterator/1 or iterator/2.

Example:

> Map = #{42 => value_three,1337 => "value two","a" => 1},

maps:to_list(Map). [{42,value_three},{1337,"value two"},{"a",1}]

Example (using iterator/2):

> Map = #{ z => 1, y => 2, x => 3 }.
#{x => 3,y => 2,z => 1}
> maps:to_list(maps:iterator(Map, ordered)).
[{x,3},{y,2},{z,1}]


update(Key, Value, Map1) -> Map2


Types:

Map1 = #{Key := term(), term() => term()}
Map2 = #{Key := Value, term() => term()}

If Key exists in Map1, the old associated value is replaced by value Value. The function returns a new map Map2 containing the new associated value.

The call fails with a {badmap,Map} exception if Map1 is not a map, or with a {badkey,Key} exception if no value is associated with Key.

Example:

> Map = #{"a" => 1}.
#{"a" => 1}
> maps:update("a", 42, Map).
#{"a" => 42}


update_with(Key, Fun, Map1) -> Map2


Types:

Map1 = #{Key := Value1, term() => term()}
Map2 = #{Key := Value2, term() => term()}
Fun = fun((Value1) -> Value2)

Update a value in a Map1 associated with Key by calling Fun on the old value to get a new value. An exception {badkey,Key} is generated if Key is not present in the map.

Example:

> Map = #{"counter" => 1},

Fun = fun(V) -> V + 1 end,
maps:update_with("counter",Fun,Map). #{"counter" => 2}


update_with(Key, Fun, Init, Map1) -> Map2


Types:

Map1 = #{Key => Value1, term() => term()}
Map2 = #{Key := Value2 | Init, term() => term()}
Fun = fun((Value1) -> Value2)

Update a value in a Map1 associated with Key by calling Fun on the old value to get a new value. If Key is not present in Map1 then Init will be associated with Key.

Example:

> Map = #{"counter" => 1},

Fun = fun(V) -> V + 1 end,
maps:update_with("new counter",Fun,42,Map). #{"counter" => 1,"new counter" => 42}


values(Map) -> Values


Types:

Map = #{term() => Value}
Values = [Value]

Returns a complete list of values, in arbitrary order, contained in map Map.

The call fails with a {badmap,Map} exception if Map is not a map.

Example:

> Map = #{42 => value_three,1337 => "value two","a" => 1},

maps:values(Map). [value_three,"value two",1]


with(Ks, Map1) -> Map2


Types:

Ks = [K]
Map1 = #{K => V, term() => term()}
Map2 = #{K => V}

Returns a new map Map2 with the keys K1 through Kn and their associated values from map Map1. Any key in Ks that does not exist in Map1 is ignored.

Example:

> Map = #{42 => value_three,1337 => "value two","a" => 1},

Ks = ["a",42,"other key"],
maps:with(Ks,Map). #{42 => value_three,"a" => 1}


without(Ks, Map1) -> Map2


Types:

Ks = [K]
Map1 = Map2 = map()
K = term()

Returns a new map Map2 without keys K1 through Kn and their associated values from map Map1. Any key in Ks that does not exist in Map1 is ignored

Example:

> Map = #{42 => value_three,1337 => "value two","a" => 1},

Ks = ["a",42,"other key"],
maps:without(Ks,Map). #{1337 => "value two"}
stdlib 5.2 Ericsson AB