View Source Access behaviour (Elixir v1.17.0-rc.1)
Key-based access to data structures.
The Access
module defines a behaviour for dynamically accessing
keys of any type in a data structure via the data[key]
syntax.
Access
supports keyword lists (Keyword
) and maps (Map
) out
of the box. Keywords supports only atoms keys, keys for maps can
be of any type. Both return nil
if the key does not exist:
iex> keywords = [a: 1, b: 2]
iex> keywords[:a]
1
iex> keywords[:c]
nil
iex> map = %{a: 1, b: 2}
iex> map[:a]
1
iex> star_ratings = %{1.0 => "★", 1.5 => "★☆", 2.0 => "★★"}
iex> star_ratings[1.5]
"★☆"
This syntax is very convenient as it can be nested arbitrarily:
iex> keywords = [a: 1, b: 2]
iex> keywords[:c][:unknown]
nil
This works because accessing anything on a nil
value, returns
nil
itself:
iex> nil[:a]
nil
Maps and structs
While the access syntax is allowed in maps via map[key]
,
if your map is made of predefined atom keys, you should prefer
to access those atom keys with map.key
instead of map[key]
,
as map.key
will raise if the key is missing (which is not
supposed to happen if the keys are predefined) or if map
is
nil
.
Similarly, since structs are maps and structs have predefined
keys, they only allow the struct.key
syntax and they do not
allow the struct[key]
access syntax.
In other words, the map[key]
syntax is loose, returning nil
for missing keys, while the map.key
syntax is strict, raising
for both nil values and missing keys.
To bridge this gap, Elixir provides the get_in/1
and get_in/2
functions, which are capable of traversing nested data structures,
even in the presence of nil
s:
iex> users = %{"john" => %{age: 27}, "meg" => %{age: 23}}
iex> get_in(users["john"].age)
27
iex> get_in(users["unknown"].age)
nil
Notice how, even if no user was found, get_in/1
returned nil
.
Outside of get_in/1
, trying to access the field .age
on nil
would raise.
The get_in/2
function takes one step further by allowing
different accessors to be mixed in. For example, given a user
map with the :name
and :languages
keys, here is how to
access the name of all programming languages:
iex> languages = [
...> %{name: "elixir", type: :functional},
...> %{name: "c", type: :procedural}
...> ]
iex> user = %{name: "john", languages: languages}
iex> get_in(user, [:languages, Access.all(), :name])
["elixir", "c"]
This module provides convenience functions for traversing other structures, like tuples and lists. As we will see next, they can even be used to update nested data structures.
If you want to learn more about the dual nature of maps in Elixir,
as they can be either for structured data or as a key-value store,
see the Map
module.
Updating nested data structures
The access syntax can also be used with the Kernel.put_in/2
,
Kernel.update_in/2
, Kernel.get_and_update_in/2
, and Kernel.pop_in/1
macros to further manipulate values in nested data structures:
iex> users = %{"john" => %{age: 27}, "meg" => %{age: 23}}
iex> put_in(users["john"].age, 28)
%{"john" => %{age: 28}, "meg" => %{age: 23}}
As shown in the previous section, you can also use the
Kernel.put_in/3
, Kernel.update_in/3
, Kernel.pop_in/2
, and
Kernel.get_and_update_in/3
functions to provide nested
custom accessors. For instance, given a user map with the
:name
and :languages
keys, here is how to deeply traverse
the map and convert all language names to uppercase:
iex> languages = [
...> %{name: "elixir", type: :functional},
...> %{name: "c", type: :procedural}
...> ]
iex> user = %{name: "john", languages: languages}
iex> update_in(user, [:languages, Access.all(), :name], &String.upcase/1)
%{
name: "john",
languages: [
%{name: "ELIXIR", type: :functional},
%{name: "C", type: :procedural}
]
}
See the functions key/1
, key!/1
, elem/1
, and all/0
for
some of the available accessors.
Summary
Callbacks
Invoked in order to access the value stored under key
in the given term term
.
Invoked in order to access the value under key
and update it at the same time.
Invoked to "pop" the value under key
out of the given data structure.
Functions
Returns a function that accesses all the elements in a list.
Returns a function that accesses the element at index
(zero based) of a list.
Same as at/1
except that it raises Enum.OutOfBoundsError
if the given index is out of bounds.
Returns a function that accesses the element at the given index in a tuple.
Fetches the value for the given key in a container (a map, keyword
list, or struct that implements the Access
behaviour).
Returns a function that accesses all elements of a list that match the provided predicate.
Returns a function that accesses the first element of a list that matches the provided predicate.
Gets the value for the given key in a container (a map, keyword
list, or struct that implements the Access
behaviour).
Gets and updates the given key in a container
(a map, a keyword list,
a struct that implements the Access
behaviour).
Returns a function that accesses the given key in a map/struct.
Returns a function that accesses the given key in a map/struct.
Removes the entry with a given key from a container (a map, keyword
list, or struct that implements the Access
behaviour).
Returns a function that accesses all items of a list that are within the provided range.
Types
@type access_fun(data, current_value) :: get_fun(data) | get_and_update_fun(data, current_value)
@type key() :: any()
@type nil_container() :: nil
@type t() :: container() | nil_container() | any()
@type value() :: any()
Callbacks
Invoked in order to access the value stored under key
in the given term term
.
This function should return {:ok, value}
where value
is the value under
key
if the key exists in the term, or :error
if the key does not exist in
the term.
Many of the functions defined in the Access
module internally call this
function. This function is also used when the square-brackets access syntax
(structure[key]
) is used: the fetch/2
callback implemented by the module
that defines the structure
struct is invoked and if it returns {:ok, value}
then value
is returned, or if it returns :error
then nil
is
returned.
See the Map.fetch/2
and Keyword.fetch/2
implementations for examples of
how to implement this callback.
@callback get_and_update(data, key(), (value() | nil -> {current_value, new_value :: value()} | :pop)) :: {current_value, new_data :: data} when current_value: value(), data: container()
Invoked in order to access the value under key
and update it at the same time.
The implementation of this callback should invoke fun
with the value under
key
in the passed structure data
, or with nil
if key
is not present in it.
This function must return either {current_value, new_value}
or :pop
.
If the passed function returns {current_value, new_value}
,
the return value of this callback should be {current_value, new_data}
, where:
current_value
is the retrieved value (which can be operated on before being returned)new_value
is the new value to be stored underkey
new_data
isdata
after updating the value ofkey
withnew_value
.
If the passed function returns :pop
, the return value of this callback
must be {value, new_data}
where value
is the value under key
(or nil
if not present) and new_data
is data
without key
.
See the implementations of Map.get_and_update/3
or Keyword.get_and_update/3
for more examples.
Invoked to "pop" the value under key
out of the given data structure.
When key
exists in the given structure data
, the implementation should
return a {value, new_data}
tuple where value
is the value that was under
key
and new_data
is term
without key
.
When key
is not present in the given structure, a tuple {value, data}
should be returned, where value
is implementation-defined.
See the implementations for Map.pop/3
or Keyword.pop/3
for more examples.
Functions
@spec all() :: access_fun(data :: list(), current_value :: list())
Returns a function that accesses all the elements in a list.
The returned function is typically passed as an accessor to Kernel.get_in/2
,
Kernel.get_and_update_in/3
, and friends.
Examples
iex> list = [%{name: "john"}, %{name: "mary"}]
iex> get_in(list, [Access.all(), :name])
["john", "mary"]
iex> get_and_update_in(list, [Access.all(), :name], fn prev ->
...> {prev, String.upcase(prev)}
...> end)
{["john", "mary"], [%{name: "JOHN"}, %{name: "MARY"}]}
iex> pop_in(list, [Access.all(), :name])
{["john", "mary"], [%{}, %{}]}
Here is an example that traverses the list dropping even numbers and multiplying odd numbers by 2:
iex> require Integer
iex> get_and_update_in([1, 2, 3, 4, 5], [Access.all()], fn num ->
...> if Integer.is_even(num), do: :pop, else: {num, num * 2}
...> end)
{[1, 2, 3, 4, 5], [2, 6, 10]}
An error is raised if the accessed structure is not a list:
iex> get_in(%{}, [Access.all()])
** (RuntimeError) Access.all/0 expected a list, got: %{}
@spec at(integer()) :: access_fun(data :: list(), current_value :: term())
Returns a function that accesses the element at index
(zero based) of a list.
Keep in mind that index lookups in lists take linear time: the larger the list,
the longer it will take to access its index. Therefore index-based operations
are generally avoided in favor of other functions in the Enum
module.
The returned function is typically passed as an accessor to Kernel.get_in/2
,
Kernel.get_and_update_in/3
, and friends.
Examples
iex> list = [%{name: "john"}, %{name: "mary"}]
iex> get_in(list, [Access.at(1), :name])
"mary"
iex> get_in(list, [Access.at(-1), :name])
"mary"
iex> get_and_update_in(list, [Access.at(0), :name], fn prev ->
...> {prev, String.upcase(prev)}
...> end)
{"john", [%{name: "JOHN"}, %{name: "mary"}]}
iex> get_and_update_in(list, [Access.at(-1), :name], fn prev ->
...> {prev, String.upcase(prev)}
...> end)
{"mary", [%{name: "john"}, %{name: "MARY"}]}
at/1
can also be used to pop elements out of a list or
a key inside of a list:
iex> list = [%{name: "john"}, %{name: "mary"}]
iex> pop_in(list, [Access.at(0)])
{%{name: "john"}, [%{name: "mary"}]}
iex> pop_in(list, [Access.at(0), :name])
{"john", [%{}, %{name: "mary"}]}
When the index is out of bounds, nil
is returned and the update function is never called:
iex> list = [%{name: "john"}, %{name: "mary"}]
iex> get_in(list, [Access.at(10), :name])
nil
iex> get_and_update_in(list, [Access.at(10), :name], fn prev ->
...> {prev, String.upcase(prev)}
...> end)
{nil, [%{name: "john"}, %{name: "mary"}]}
An error is raised if the accessed structure is not a list:
iex> get_in(%{}, [Access.at(1)])
** (RuntimeError) Access.at/1 expected a list, got: %{}
@spec at!(integer()) :: access_fun(data :: list(), current_value :: term())
Same as at/1
except that it raises Enum.OutOfBoundsError
if the given index is out of bounds.
Examples
iex> get_in([:a, :b, :c], [Access.at!(2)])
:c
iex> get_in([:a, :b, :c], [Access.at!(3)])
** (Enum.OutOfBoundsError) out of bounds error
@spec elem(non_neg_integer()) :: access_fun(data :: tuple(), current_value :: term())
Returns a function that accesses the element at the given index in a tuple.
The returned function is typically passed as an accessor to Kernel.get_in/2
,
Kernel.get_and_update_in/3
, and friends.
The returned function raises if index
is out of bounds.
Note that popping elements out of tuples is not possible and raises an error.
Examples
iex> map = %{user: {"john", 27}}
iex> get_in(map, [:user, Access.elem(0)])
"john"
iex> get_and_update_in(map, [:user, Access.elem(0)], fn prev ->
...> {prev, String.upcase(prev)}
...> end)
{"john", %{user: {"JOHN", 27}}}
iex> pop_in(map, [:user, Access.elem(0)])
** (RuntimeError) cannot pop data from a tuple
An error is raised if the accessed structure is not a tuple:
iex> get_in(%{}, [Access.elem(0)])
** (RuntimeError) Access.elem/1 expected a tuple, got: %{}
@spec fetch(container(), term()) :: {:ok, term()} | :error
@spec fetch(nil_container(), any()) :: :error
Fetches the value for the given key in a container (a map, keyword
list, or struct that implements the Access
behaviour).
Returns {:ok, value}
where value
is the value under key
if there is such
a key, or :error
if key
is not found.
Examples
iex> Access.fetch(%{name: "meg", age: 26}, :name)
{:ok, "meg"}
iex> Access.fetch([ordered: true, on_timeout: :exit], :timeout)
:error
Same as fetch/2
but returns the value directly,
or raises a KeyError
exception if key
is not found.
Examples
iex> Access.fetch!(%{name: "meg", age: 26}, :name)
"meg"
@spec filter((term() -> boolean())) :: access_fun(data :: list(), current_value :: list())
Returns a function that accesses all elements of a list that match the provided predicate.
The returned function is typically passed as an accessor to Kernel.get_in/2
,
Kernel.get_and_update_in/3
, and friends.
Examples
iex> list = [%{name: "john", salary: 10}, %{name: "francine", salary: 30}]
iex> get_in(list, [Access.filter(&(&1.salary > 20)), :name])
["francine"]
iex> get_and_update_in(list, [Access.filter(&(&1.salary <= 20)), :name], fn prev ->
...> {prev, String.upcase(prev)}
...> end)
{["john"], [%{name: "JOHN", salary: 10}, %{name: "francine", salary: 30}]}
filter/1
can also be used to pop elements out of a list or
a key inside of a list:
iex> list = [%{name: "john", salary: 10}, %{name: "francine", salary: 30}]
iex> pop_in(list, [Access.filter(&(&1.salary >= 20))])
{[%{name: "francine", salary: 30}], [%{name: "john", salary: 10}]}
iex> pop_in(list, [Access.filter(&(&1.salary >= 20)), :name])
{["francine"], [%{name: "john", salary: 10}, %{salary: 30}]}
When no match is found, an empty list is returned and the update function is never called
iex> list = [%{name: "john", salary: 10}, %{name: "francine", salary: 30}]
iex> get_in(list, [Access.filter(&(&1.salary >= 50)), :name])
[]
iex> get_and_update_in(list, [Access.filter(&(&1.salary >= 50)), :name], fn prev ->
...> {prev, String.upcase(prev)}
...> end)
{[], [%{name: "john", salary: 10}, %{name: "francine", salary: 30}]}
An error is raised if the predicate is not a function or is of the incorrect arity:
iex> get_in([], [Access.filter(5)])
** (FunctionClauseError) no function clause matching in Access.filter/1
An error is raised if the accessed structure is not a list:
iex> get_in(%{}, [Access.filter(fn a -> a == 10 end)])
** (RuntimeError) Access.filter/1 expected a list, got: %{}
@spec find((term() -> as_boolean(term()))) :: access_fun(data :: list(), current_value :: term())
Returns a function that accesses the first element of a list that matches the provided predicate.
The returned function is typically passed as an accessor to Kernel.get_in/2
,
Kernel.get_and_update_in/3
, and friends.
Examples
iex> list = [%{name: "john", salary: 10}, %{name: "francine", salary: 30}]
iex> get_in(list, [Access.find(&(&1.salary > 20)), :name])
"francine"
iex> get_and_update_in(list, [Access.find(&(&1.salary <= 40)), :name], fn prev ->
...> {prev, String.upcase(prev)}
...> end)
{"john", [%{name: "JOHN", salary: 10}, %{name: "francine", salary: 30}]}
find/1
can also be used to pop the first found element out of a list or
a key inside of a list:
iex> list = [%{name: "john", salary: 10}, %{name: "francine", salary: 30}]
iex> pop_in(list, [Access.find(&(&1.salary <= 40))])
{%{name: "john", salary: 10}, [%{name: "francine", salary: 30}]}
When no match is found, nil is returned and the update function is never called
iex> list = [%{name: "john", salary: 10}, %{name: "francine", salary: 30}]
iex> get_in(list, [Access.find(&(&1.salary >= 50)), :name])
nil
iex> get_and_update_in(list, [Access.find(&(&1.salary >= 50)), :name], fn prev ->
...> {prev, String.upcase(prev)}
...> end)
{nil, [%{name: "john", salary: 10}, %{name: "francine", salary: 30}]}
An error is raised if the predicate is not a function or is of the incorrect arity:
iex> get_in([], [Access.find(5)])
** (FunctionClauseError) no function clause matching in Access.find/1
An error is raised if the accessed structure is not a list:
iex> get_in(%{}, [Access.find(fn a -> a == 10 end)])
** (RuntimeError) Access.find/1 expected a list, got: %{}
@spec get(container(), term(), term()) :: term()
@spec get(nil_container(), any(), default) :: default when default: var
Gets the value for the given key in a container (a map, keyword
list, or struct that implements the Access
behaviour).
Returns the value under key
if there is such a key, or default
if key
is
not found.
Examples
iex> Access.get(%{name: "john"}, :name, "default name")
"john"
iex> Access.get(%{name: "john"}, :age, 25)
25
iex> Access.get([ordered: true], :timeout)
nil
@spec get_and_update(data, key(), (value() | nil -> {current_value, new_value :: value()} | :pop)) :: {current_value, new_data :: data} when data: container(), current_value: var
Gets and updates the given key in a container
(a map, a keyword list,
a struct that implements the Access
behaviour).
The fun
argument receives the value of key
(or nil
if key
is not
present in container
) and must return a two-element tuple {current_value, new_value}
:
the "get" value current_value
(the retrieved value, which can be operated on before
being returned) and the new value to be stored under key
(new_value
).
fun
may also return :pop
, which means the current value
should be removed from the container and returned.
The returned value is a two-element tuple with the "get" value returned by
fun
and a new container with the updated value under key
.
Examples
iex> Access.get_and_update([a: 1], :a, fn current_value ->
...> {current_value, current_value + 1}
...> end)
{1, [a: 2]}
Returns a function that accesses the given key in a map/struct.
The returned function is typically passed as an accessor to Kernel.get_in/2
,
Kernel.get_and_update_in/3
, and friends.
The returned function uses the default value if the key does not exist. This can be used to specify defaults and safely traverse missing keys:
iex> get_in(%{}, [Access.key(:user, %{}), Access.key(:name, "meg")])
"meg"
Such is also useful when using update functions, allowing us to introduce values as we traverse the data structure for updates:
iex> put_in(%{}, [Access.key(:user, %{}), Access.key(:name)], "Mary")
%{user: %{name: "Mary"}}
Examples
iex> map = %{user: %{name: "john"}}
iex> get_in(map, [Access.key(:unknown, %{}), Access.key(:name, "john")])
"john"
iex> get_and_update_in(map, [Access.key(:user), Access.key(:name)], fn prev ->
...> {prev, String.upcase(prev)}
...> end)
{"john", %{user: %{name: "JOHN"}}}
iex> pop_in(map, [Access.key(:user), Access.key(:name)])
{"john", %{user: %{}}}
An error is raised if the accessed structure is not a map or a struct:
iex> get_in([], [Access.key(:foo)])
** (BadMapError) expected a map, got: []
@spec key!(key()) :: access_fun(data :: struct() | map(), current_value :: term())
Returns a function that accesses the given key in a map/struct.
The returned function is typically passed as an accessor to Kernel.get_in/2
,
Kernel.get_and_update_in/3
, and friends.
Similar to key/2
, but the returned function raises if the key does not exist.
Examples
iex> map = %{user: %{name: "john"}}
iex> get_in(map, [Access.key!(:user), Access.key!(:name)])
"john"
iex> get_and_update_in(map, [Access.key!(:user), Access.key!(:name)], fn prev ->
...> {prev, String.upcase(prev)}
...> end)
{"john", %{user: %{name: "JOHN"}}}
iex> pop_in(map, [Access.key!(:user), Access.key!(:name)])
{"john", %{user: %{}}}
iex> get_in(map, [Access.key!(:user), Access.key!(:unknown)])
** (KeyError) key :unknown not found in: %{name: "john"}
The examples above could be partially written as:
iex> map = %{user: %{name: "john"}}
iex> map.user.name
"john"
iex> get_and_update_in(map.user.name, fn prev ->
...> {prev, String.upcase(prev)}
...> end)
{"john", %{user: %{name: "JOHN"}}}
However, it is not possible to remove fields using the dot notation,
as it is implied those fields must also be present. In any case,
Access.key!/1
is useful when the key is not known in advance
and must be accessed dynamically.
An error is raised if the accessed structure is not a map/struct:
iex> get_in([], [Access.key!(:foo)])
** (RuntimeError) Access.key!/1 expected a map/struct, got: []
Removes the entry with a given key from a container (a map, keyword
list, or struct that implements the Access
behaviour).
Returns a tuple containing the value associated with the key and the
updated container. nil
is returned for the value if the key isn't
in the container.
Examples
With a map:
iex> Access.pop(%{name: "Elixir", creator: "Valim"}, :name)
{"Elixir", %{creator: "Valim"}}
A keyword list:
iex> Access.pop([name: "Elixir", creator: "Valim"], :name)
{"Elixir", [creator: "Valim"]}
An unknown key:
iex> Access.pop(%{name: "Elixir", creator: "Valim"}, :year)
{nil, %{creator: "Valim", name: "Elixir"}}
@spec slice(Range.t()) :: access_fun(data :: list(), current_value :: list())
Returns a function that accesses all items of a list that are within the provided range.
The range will be normalized following the same rules from Enum.slice/2
.
The returned function is typically passed as an accessor to Kernel.get_in/2
,
Kernel.get_and_update_in/3
, and friends.
Examples
iex> list = [%{name: "john", salary: 10}, %{name: "francine", salary: 30}, %{name: "vitor", salary: 25}]
iex> get_in(list, [Access.slice(1..2), :name])
["francine", "vitor"]
iex> get_and_update_in(list, [Access.slice(1..3//2), :name], fn prev ->
...> {prev, String.upcase(prev)}
...> end)
{["francine"], [%{name: "john", salary: 10}, %{name: "FRANCINE", salary: 30}, %{name: "vitor", salary: 25}]}
slice/1
can also be used to pop elements out of a list or
a key inside of a list:
iex> list = [%{name: "john", salary: 10}, %{name: "francine", salary: 30}, %{name: "vitor", salary: 25}]
iex> pop_in(list, [Access.slice(-2..-1)])
{[%{name: "francine", salary: 30}, %{name: "vitor", salary: 25}], [%{name: "john", salary: 10}]}
iex> pop_in(list, [Access.slice(-2..-1), :name])
{["francine", "vitor"], [%{name: "john", salary: 10}, %{salary: 30}, %{salary: 25}]}
When no match is found, an empty list is returned and the update function is never called
iex> list = [%{name: "john", salary: 10}, %{name: "francine", salary: 30}, %{name: "vitor", salary: 25}]
iex> get_in(list, [Access.slice(5..10//2), :name])
[]
iex> get_and_update_in(list, [Access.slice(5..10//2), :name], fn prev ->
...> {prev, String.upcase(prev)}
...> end)
{[], [%{name: "john", salary: 10}, %{name: "francine", salary: 30}, %{name: "vitor", salary: 25}]}
An error is raised if the accessed structure is not a list:
iex> get_in(%{}, [Access.slice(2..10//3)])
** (ArgumentError) Access.slice/1 expected a list, got: %{}
An error is raised if the step of the range is negative:
iex> get_in([], [Access.slice(2..10//-1)])
** (ArgumentError) Access.slice/1 does not accept ranges with negative steps, got: 2..10//-1