View Source Kernel.SpecialForms (Elixir v1.17.0)

Special forms are the basic building blocks of Elixir, and therefore cannot be overridden by the developer.

The Kernel.SpecialForms module consists solely of macros that can be invoked anywhere in Elixir code without the use of the Kernel.SpecialForms. prefix. This is possible because they all have been automatically imported, in the same fashion as the functions and macros from the Kernel module.

These building blocks are defined in this module. Some of these special forms are lexical (such as alias/2 and case/2). The macros {}/1 and <<>>/1 are also special forms used to define tuple and binary data structures respectively.

This module also documents macros that return information about Elixir's compilation environment, such as (__ENV__/0, __MODULE__/0, __DIR__/0, __STACKTRACE__/0, and __CALLER__/0).

Additionally, it documents two special forms, __block__/1 and __aliases__/1, which are not intended to be called directly by the developer but they appear in quoted contents since they are essential in Elixir's constructs.

Summary

Functions

Matches on or builds a struct.

%{}

Creates a map.

Capture operator. Captures or creates an anonymous function.

Dot operator. Defines a remote call, a call to an anonymous function, or an alias.

Internal special form to hold aliases information.

Internal special form for block expressions.

Returns the current calling environment as a Macro.Env struct.

Internal special form for cursor position.

Returns the absolute path of the directory of the current file as a binary.

Returns the current environment information as a Macro.Env struct.

Returns the current module name as an atom or nil otherwise.

Returns the stacktrace for the currently handled exception.

Type operator. Used by types and bitstrings to specify types.

Defines a new bitstring.

Match operator. Matches the value on the right against the pattern on the left.

alias/2 is used to set up aliases, often useful with modules' names.

Matches the given expression against the given clauses.

Evaluates the expression corresponding to the first clause that evaluates to a truthy value.

Defines an anonymous function.

Comprehensions allow you to quickly build a data structure from an enumerable or a bitstring.

Imports functions and macros from other modules.

Gets the representation of any expression.

Checks if there is a message matching any of the given clauses in the current process mailbox.

Requires a module in order to use its macros.

Calls the overridden function when overriding it with Kernel.defoverridable/1.

Evaluates the given expressions and handles any error, exit, or throw that may have happened.

Unquotes the given expression inside a quoted expression.

Unquotes the given list expanding its arguments.

Combine matching clauses.

Pin operator. Accesses an already bound variable in match clauses.

Creates a tuple.

Functions

Matches on or builds a struct.

A struct is a tagged map that allows developers to provide default values for keys, tags to be used in polymorphic dispatches and compile time assertions.

Structs are usually defined with the Kernel.defstruct/1 macro:

defmodule User do
  defstruct name: "john", age: 27
end

Now a struct can be created as follows:

%User{}

Underneath a struct is just a map with a :__struct__ key pointing to the User module:

%User{} == %{__struct__: User, name: "john", age: 27}

The struct fields can be given when building the struct:

%User{age: 31}
#=> %{__struct__: User, name: "john", age: 31}

Or also on pattern matching to extract values out:

%User{age: age} = user

An update operation specific for structs is also available:

%User{user | age: 28}

The advantage of structs is that they validate that the given keys are part of the defined struct. The example below will fail because there is no key :full_name in the User struct:

%User{full_name: "john doe"}

The syntax above will guarantee the given keys are valid at compilation time and it will guarantee at runtime the given argument is a struct, failing with BadStructError otherwise.

Although structs are maps, by default structs do not implement any of the protocols implemented for maps. Check Kernel.defprotocol/2 for more information on how structs can be used with protocols for polymorphic dispatch. Also see Kernel.struct/2 and Kernel.struct!/2 for examples on how to create and update structs dynamically.

Pattern matching on struct names

Besides allowing pattern matching on struct fields, such as:

%User{age: age} = user

Structs also allow pattern matching on the struct name:

%struct_name{} = user
struct_name #=> User

You can also assign the struct name to _ when you want to check if something is a struct but you are not interested in its name:

%_{} = user

Creates a map.

See the Map module for more information about maps, their syntax, and ways to access and manipulate them.

AST representation

Regardless of whether => or the keyword syntax is used, key-value pairs in maps are always represented internally as a list of two-element tuples for simplicity:

iex> quote do
...>   %{"a" => :b, c: :d}
...> end
{:%{}, [], [{"a", :b}, {:c, :d}]}

Capture operator. Captures or creates an anonymous function.

Capture

The capture operator is most commonly used to capture a function with given name and arity from a module:

iex> fun = &Kernel.is_atom/1
iex> fun.(:atom)
true
iex> fun.("string")
false

In the example above, we captured Kernel.is_atom/1 as an anonymous function and then invoked it.

The capture operator can also be used to capture local functions, including private ones, and imported functions by omitting the module name:

&local_function/1

See also Function.capture/3.

Anonymous functions

The capture operator can also be used to partially apply functions, where &1, &2 and so on can be used as value placeholders. For example:

iex> double = &(&1 * 2)
iex> double.(2)
4

In other words, &(&1 * 2) is equivalent to fn x -> x * 2 end.

We can partially apply a remote function with placeholder:

iex> take_five = &Enum.take(&1, 5)
iex> take_five.(1..10)
[1, 2, 3, 4, 5]

Another example while using an imported or local function:

iex> first_elem = &elem(&1, 0)
iex> first_elem.({0, 1})
0

The & operator can be used with more complex expressions:

iex> fun = &(&1 + &2 + &3)
iex> fun.(1, 2, 3)
6

As well as with lists and tuples:

iex> fun = &{&1, &2}
iex> fun.(1, 2)
{1, 2}

iex> fun = &[&1 | &2]
iex> fun.(1, [2, 3])
[1, 2, 3]

The only restrictions when creating anonymous functions is that at least one placeholder must be present, i.e. it must contain at least &1, and that block expressions are not supported:

# No placeholder, fails to compile.
&(:foo)

# Block expression, fails to compile.
&(&1; &2)

Dot operator. Defines a remote call, a call to an anonymous function, or an alias.

The dot (.) in Elixir can be used for remote calls:

iex> String.downcase("FOO")
"foo"

In this example above, we have used . to invoke downcase in the String module, passing "FOO" as argument.

The dot may be used to invoke anonymous functions too:

iex> (fn n -> n end).(7)
7

in which case there is a function on the left hand side.

We can also use the dot for creating aliases:

iex> Hello.World
Hello.World

This time, we have joined two aliases, defining the final alias Hello.World.

Syntax

The right side of . may be a word starting with an uppercase letter, which represents an alias, a word starting with lowercase or underscore, any valid language operator or any name wrapped in single- or double-quotes. Those are all valid examples:

iex> Kernel.Sample
Kernel.Sample

iex> Kernel.length([1, 2, 3])
3

iex> Kernel.+(1, 2)
3

iex> Kernel."+"(1, 2)
3

Wrapping the function name in single- or double-quotes is always a remote call. Therefore Kernel."Foo" will attempt to call the function "Foo" and not return the alias Kernel.Foo. This is done by design as module names are more strict than function names.

When the dot is used to invoke an anonymous function there is only one operand, but it is still written using a postfix notation:

iex> negate = fn n -> -n end
iex> negate.(7)
-7

Quoted expression

When . is used, the quoted expression may take two distinct forms. When the right side starts with a lowercase letter (or underscore):

iex> quote do
...>   String.downcase("FOO")
...> end
{{:., [], [{:__aliases__, [alias: false], [:String]}, :downcase]}, [], ["FOO"]}

Note that we have an inner tuple, containing the atom :. representing the dot as first element:

{:., [], [{:__aliases__, [alias: false], [:String]}, :downcase]}

This tuple follows the general quoted expression structure in Elixir, with the name as first argument, some keyword list as metadata as second, and the list of arguments as third. In this case, the arguments are the alias String and the atom :downcase. The second argument in a remote call is always an atom.

In the case of calls to anonymous functions, the inner tuple with the dot special form has only one argument, reflecting the fact that the operator is unary:

iex> quote do
...>   negate.(0)
...> end
{{:., [], [{:negate, [], __MODULE__}]}, [], [0]}

When the right side is an alias (i.e. starts with uppercase), we get instead:

iex> quote do
...>   Hello.World
...> end
{:__aliases__, [alias: false], [:Hello, :World]}

We go into more details about aliases in the __aliases__/1 special form documentation.

Unquoting

We can also use unquote to generate a remote call in a quoted expression:

iex> x = :downcase
iex> quote do
...>   String.unquote(x)("FOO")
...> end
{{:., [], [{:__aliases__, [alias: false], [:String]}, :downcase]}, [], ["FOO"]}

Similar to Kernel."FUNCTION_NAME", unquote(x) will always generate a remote call, independent of the value of x. To generate an alias via the quoted expression, one needs to rely on Module.concat/2:

iex> x = Sample
iex> quote do
...>   Module.concat(String, unquote(x))
...> end
{{:., [], [{:__aliases__, [alias: false], [:Module]}, :concat]}, [],
 [{:__aliases__, [alias: false], [:String]}, Sample]}
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__aliases__(args)

View Source (macro)

Internal special form to hold aliases information.

It is usually compiled to an atom:

iex> quote do
...>   Foo.Bar
...> end
{:__aliases__, [alias: false], [:Foo, :Bar]}

Elixir represents Foo.Bar as __aliases__ so calls can be unambiguously identified by the operator :.. For example:

iex> quote do
...>   Foo.bar()
...> end
{{:., [], [{:__aliases__, [alias: false], [:Foo]}, :bar]}, [], []}

Whenever an expression iterator sees a :. as the tuple key, it can be sure that it represents a call and the second argument in the list is an atom.

On the other hand, aliases hold some properties:

  1. The head element of aliases can be any term that must expand to an atom at compilation time.

  2. The tail elements of aliases are guaranteed to always be atoms.

  3. When the head element of aliases is the atom :Elixir, no expansion happens.

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__block__(args)

View Source (macro)

Internal special form for block expressions.

This is the special form used whenever we have a block of expressions in Elixir. This special form is private and should not be invoked directly:

iex> quote do
...>   1
...>   2
...>   3
...> end
{:__block__, [], [1, 2, 3]}

Returns the current calling environment as a Macro.Env struct.

In the environment you can access the filename, line numbers, set up aliases, the function and others.

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__cursor__(args)

View Source (macro)

Internal special form for cursor position.

This is the special form used whenever we need to represent the cursor position in Elixir's AST. See Code.Fragment for more information.

Returns the absolute path of the directory of the current file as a binary.

Although the directory can be accessed as Path.dirname(__ENV__.file), this macro is a convenient shortcut.

Returns the current environment information as a Macro.Env struct.

In the environment you can access the current filename, line numbers, set up aliases, the current function and others.

Returns the current module name as an atom or nil otherwise.

Although the module can be accessed in the __ENV__/0, this macro is a convenient shortcut.

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__STACKTRACE__

View Source (since 1.7.0) (macro)

Returns the stacktrace for the currently handled exception.

It is available only in the catch and rescue clauses of try/1 expressions.

To retrieve the stacktrace of the current process, use Process.info(self(), :current_stacktrace) instead.

Type operator. Used by types and bitstrings to specify types.

This operator is used in two distinct occasions in Elixir. It is used in typespecs to specify the type of a variable, function or of a type itself:

@type number :: integer | float
@spec add(number, number) :: number

It may also be used in bit strings to specify the type of a given bit segment:

<<int::integer-little, rest::bits>> = bits

Read the documentation on the Typespecs page and <<>>/1 for more information on typespecs and bitstrings respectively.

Defines a new bitstring.

Examples

iex> <<1, 2, 3>>
<<1, 2, 3>>

Types

A bitstring is made of many segments and each segment has a type. There are 9 types used in bitstrings:

  • integer
  • float
  • bits (alias for bitstring)
  • bitstring
  • binary
  • bytes (alias for binary)
  • utf8
  • utf16
  • utf32

When no type is specified, the default is integer:

iex> <<1, 2, 3>>
<<1, 2, 3>>

Elixir also accepts by default the segment to be a literal string which expands to integers:

iex> <<0, "foo">>
<<0, 102, 111, 111>>

You can use one of utf8 (the default), utf16, and utf32 to control how the string is encoded:

iex> <<"foo"::utf16>>
<<0, 102, 0, 111, 0, 111>>

Which is equivalent to writing:

iex> <<?f::utf16, ?o::utf16, ?o::utf16>>
<<0, 102, 0, 111, 0, 111>>

At runtime, binaries need to be explicitly tagged as binary:

iex> rest = "oo"
iex> <<102, rest::binary>>
"foo"

Otherwise we get an ArgumentError when constructing the binary:

rest = "oo"
<<102, rest>>
** (ArgumentError) argument error

Options

Many options can be given by using - as separator. Order is arbitrary, so the following are all equivalent:

<<102::integer-native, rest::binary>>
<<102::native-integer, rest::binary>>
<<102::unsigned-big-integer, rest::binary>>
<<102::unsigned-big-integer-size(8), rest::binary>>
<<102::unsigned-big-integer-8, rest::binary>>
<<102::8-integer-big-unsigned, rest::binary>>
<<102, rest::binary>>

Unit and Size

The length of the match is equal to the unit (a number of bits) times the size (the number of repeated segments of length unit).

TypeDefault Unit
integer1 bit
float1 bit
binary8 bits

Sizes for types are a bit more nuanced. The default size for integers is 8.

For floats, it is 64. For floats, size * unit must result in 16, 32, or 64, corresponding to IEEE 754 binary16, binary32, and binary64, respectively.

For binaries, the default is the size of the binary. Only the last binary in a match can use the default size. All others must have their size specified explicitly, even if the match is unambiguous. For example:

iex> <<name::binary-size(5), " the ", species::binary>> = <<"Frank the Walrus">>
"Frank the Walrus"
iex> {name, species}
{"Frank", "Walrus"}

The size can be a variable or any valid guard expression:

iex> name_size = 5
iex> <<name::binary-size(^name_size), " the ", species::binary>> = <<"Frank the Walrus">>
iex> {name, species}
{"Frank", "Walrus"}

The size can access prior variables defined in the binary itself:

iex> <<name_size::size(8), name::binary-size(name_size), " the ", species::binary>> = <<5, "Frank the Walrus">>
iex> {name, species}
{"Frank", "Walrus"}

However, it cannot access variables defined in the match outside of the binary/bitstring:

{name_size, <<name::binary-size(name_size), _rest::binary>>} = {5, <<"Frank the Walrus">>}
** (CompileError): undefined variable "name_size" in bitstring segment

Failing to specify the size for the non-last causes compilation to fail:

<<name::binary, " the ", species::binary>> = <<"Frank the Walrus">>
** (CompileError): a binary field without size is only allowed at the end of a binary pattern

Shortcut Syntax

Size and unit can also be specified using a syntax shortcut when passing integer values:

iex> x = 1
iex> <<x::8>> == <<x::size(8)>>
true
iex> <<x::8*4>> == <<x::size(8)-unit(4)>>
true

This syntax reflects the fact the effective size is given by multiplying the size by the unit.

Modifiers

Some types have associated modifiers to clear up ambiguity in byte representation.

ModifierRelevant Type(s)
signedinteger
unsigned (default)integer
littleinteger, float, utf16, utf32
big (default)integer, float, utf16, utf32
nativeinteger, float, utf16, utf32

Sign

Integers can be signed or unsigned, defaulting to unsigned.

iex> <<int::integer>> = <<-100>>
<<156>>
iex> int
156
iex> <<int::integer-signed>> = <<-100>>
<<156>>
iex> int
-100

signed and unsigned are only used for matching binaries (see below) and are only used for integers.

iex> <<-100::signed, _rest::binary>> = <<-100, "foo">>
<<156, 102, 111, 111>>

Endianness

Elixir has three options for endianness: big, little, and native. The default is big:

iex> <<number::little-integer-size(16)>> = <<0, 1>>
<<0, 1>>
iex> number
256
iex> <<number::big-integer-size(16)>> = <<0, 1>>
<<0, 1>>
iex> number
1

native is determined by the VM at startup and will depend on the host operating system.

Binary/Bitstring Matching

Binary matching is a powerful feature in Elixir that is useful for extracting information from binaries as well as pattern matching.

Binary matching can be used by itself to extract information from binaries:

iex> <<"Hello, ", place::binary>> = "Hello, World"
"Hello, World"
iex> place
"World"

Or as a part of function definitions to pattern match:

defmodule ImageType do
  @png_signature <<137::size(8), 80::size(8), 78::size(8), 71::size(8),
                   13::size(8), 10::size(8), 26::size(8), 10::size(8)>>
  @jpg_signature <<255::size(8), 216::size(8)>>

  def type(<<@png_signature, _rest::binary>>), do: :png
  def type(<<@jpg_signature, _rest::binary>>), do: :jpg
  def type(_), do: :unknown
end

Performance & Optimizations

The Erlang compiler can provide a number of optimizations on binary creation and matching. To see optimization output, set the bin_opt_info compiler option:

ERL_COMPILER_OPTIONS=bin_opt_info mix compile

To learn more about specific optimizations and performance considerations, check out the "Constructing and matching binaries" chapter of the Erlang's Efficiency Guide.

Match operator. Matches the value on the right against the pattern on the left.

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alias(module, opts)

View Source (macro)

alias/2 is used to set up aliases, often useful with modules' names.

Examples

alias/2 can be used to set up an alias for any module:

defmodule Math do
  alias MyKeyword, as: Keyword
end

In the example above, we have set up MyKeyword to be aliased as Keyword. So now, any reference to Keyword will be automatically replaced by MyKeyword.

In case one wants to access the original Keyword, it can be done by accessing Elixir:

Keyword.values #=> uses MyKeyword.values
Elixir.Keyword.values #=> uses Keyword.values

Note that calling alias without the :as option automatically sets an alias based on the last part of the module. For example:

alias Foo.Bar.Baz

Is the same as:

alias Foo.Bar.Baz, as: Baz

We can also alias multiple modules in one line:

alias Foo.{Bar, Baz, Biz}

Is the same as:

alias Foo.Bar
alias Foo.Baz
alias Foo.Biz

Lexical scope

import/2, require/2 and alias/2 are called directives and all have lexical scope. This means you can set up aliases inside specific functions and it won't affect the overall scope.

Warnings

If you alias a module and you don't use the alias, Elixir is going to issue a warning implying the alias is not being used.

In case the alias is generated automatically by a macro, Elixir won't emit any warnings though, since the alias was not explicitly defined.

Both warning behaviors could be changed by explicitly setting the :warn option to true or false.

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case(condition, clauses)

View Source (macro)

Matches the given expression against the given clauses.

case/2 relies on pattern matching and guards to choose which clause to execute. If your logic cannot be expressed within patterns and guards, consider using if/2 or cond/1 instead.

Examples

case File.read(file) do
  {:ok, contents} when is_binary(contents) ->
    String.split(contents, "\n")

  {:error, _reason} ->
    Logger.warning "could not find #{file}, assuming empty..."
    []
end

In the example above, we match the result of File.read/1 against each clause "head" and execute the clause "body" corresponding to the first clause that matches.

If no clause matches, an error is raised. For this reason, it may be necessary to add a final catch-all clause (like _) which will always match.

x = 10

case x do
  0 ->
    "This clause won't match"

  _ ->
    "This clause would match any value (x = #{x})"
end
#=> "This clause would match any value (x = 10)"

If you find yourself nesting case expressions inside case expressions, consider using with/1.

Variable handling

Note that variables bound in a clause do not leak to the outer context:

case data do
  {:ok, value} -> value
  :error -> nil
end

value
#=> unbound variable value

Variables in the outer context cannot be overridden either:

value = 7

case lucky? do
  false -> value = 13
  true -> true
end

value
#=> 7

In the example above, value is going to be 7 regardless of the value of lucky?. The variable value bound in the clause and the variable value bound in the outer context are two entirely separate variables.

If you want to pattern match against an existing variable, you need to use the ^/1 operator:

x = 1

case 10 do
  ^x -> "Won't match"
  _ -> "Will match"
end
#=> "Will match"

Using guards to match against multiple values

While it is not possible to match against multiple patterns in a single clause, it's possible to match against multiple values by using guards:

case data do
  value when value in [:one, :two] ->
    "#{value} has been matched"

  :three ->
    "three has been matched"
end

Evaluates the expression corresponding to the first clause that evaluates to a truthy value.

Examples

The following example has a single clause that always evaluates to true:

cond do
  hd([1, 2, 3]) ->
    "1 is considered as true"
end
#=> "1 is considered as true"

If all clauses evaluate to nil or false, cond raises an error. For this reason, it may be necessary to add a final always-truthy condition (anything non-false and non-nil), which will always match:

cond do
  1 + 1 == 1 ->
    "This will never match"
  2 * 2 != 4 ->
    "Nor this"
  true ->
    "This will"
end
#=> "This will"

If your cond has two clauses, and the last one falls back to true, you may consider using if/2 instead.

Defines an anonymous function.

See Function for more information.

Examples

iex> add = fn a, b -> a + b end
iex> add.(1, 2)
3

Anonymous functions can also have multiple clauses. All clauses should expect the same number of arguments:

iex> negate = fn
...>   true -> false
...>   false -> true
...> end
iex> negate.(false)
true

Comprehensions allow you to quickly build a data structure from an enumerable or a bitstring.

Let's start with an example:

iex> for n <- [1, 2, 3, 4], do: n * 2
[2, 4, 6, 8]

A comprehension accepts many generators and filters. for uses the <- operator to extract values from the enumerable on its right side and match them against the pattern on the left. We call them generators:

# A list generator:
iex> for n <- [1, 2, 3, 4], do: n * 2
[2, 4, 6, 8]

# A comprehension with two generators
iex> for x <- [1, 2], y <- [2, 3], do: x * y
[2, 3, 4, 6]

Filters can also be given:

# A comprehension with a generator and a filter
iex> for n <- [1, 2, 3, 4, 5, 6], rem(n, 2) == 0, do: n
[2, 4, 6]

Filters must evaluate to truthy values (everything but nil and false). If a filter is falsy, then the current value is discarded.

Generators can also be used to filter as it removes any value that doesn't match the pattern on the left side of <-:

iex> users = [user: "john", admin: "meg", guest: "barbara"]
iex> for {type, name} when type != :guest <- users do
...>   String.upcase(name)
...> end
["JOHN", "MEG"]

Bitstring generators are also supported and are very useful when you need to organize bitstring streams:

iex> pixels = <<213, 45, 132, 64, 76, 32, 76, 0, 0, 234, 32, 15>>
iex> for <<r::8, g::8, b::8 <- pixels>>, do: {r, g, b}
[{213, 45, 132}, {64, 76, 32}, {76, 0, 0}, {234, 32, 15}]

Variable assignments inside the comprehension, be it in generators, filters or inside the block, are not reflected outside of the comprehension.

Variable assignments inside filters must still return a truthy value, otherwise values are discarded. Let's see an example. Imagine you have a keyword list where the key is a programming language and the value is its direct parent. Then let's try to compute the grandparent of each language. You could try this:

iex> languages = [elixir: :erlang, erlang: :prolog, prolog: nil]
iex> for {language, parent} <- languages, grandparent = languages[parent], do: {language, grandparent}
[elixir: :prolog]

Given the grandparents of Erlang and Prolog were nil, those values were filtered out. If you don't want this behavior, a simple option is to move the filter inside the do-block:

iex> languages = [elixir: :erlang, erlang: :prolog, prolog: nil]
iex> for {language, parent} <- languages do
...>   grandparent = languages[parent]
...>   {language, grandparent}
...> end
[elixir: :prolog, erlang: nil, prolog: nil]

However, such option is not always available, as you may have further filters. An alternative is to convert the filter into a generator by wrapping the right side of = in a list:

iex> languages = [elixir: :erlang, erlang: :prolog, prolog: nil]
iex> for {language, parent} <- languages, grandparent <- [languages[parent]], do: {language, grandparent}
[elixir: :prolog, erlang: nil, prolog: nil]

The :into and :uniq options

In the examples above, the result returned by the comprehension was always a list. The returned result can be configured by passing an :into option, that accepts any structure as long as it implements the Collectable protocol.

For example, we can use bitstring generators with the :into option to easily remove all spaces in a string:

iex> for <<c <- " hello world ">>, c != ?\s, into: "", do: <<c>>
"helloworld"

The IO module provides streams, that are both Enumerable and Collectable, here is an upcase echo server using comprehensions:

for line <- IO.stream(), into: IO.stream() do
  String.upcase(line)
end

Similarly, uniq: true can also be given to comprehensions to guarantee the results are only added to the collection if they were not returned before. For example:

iex> for x <- [1, 1, 2, 3], uniq: true, do: x * 2
[2, 4, 6]

iex> for <<x <- "abcabc">>, uniq: true, into: "", do: <<x - 32>>
"ABC"

The :reduce option

Available since Elixir v1.8.

While the :into option allows us to customize the comprehension behavior to a given data type, such as putting all of the values inside a map or inside a binary, it is not always enough.

For example, imagine that you have a binary with letters where you want to count how many times each lowercase letter happens, ignoring all uppercase ones. For instance, for the string "AbCabCABc", we want to return the map %{"a" => 1, "b" => 2, "c" => 1}.

If we were to use :into, we would need a data type that computes the frequency of each element it holds. While there is no such data type in Elixir, you could implement one yourself.

A simpler option would be to use comprehensions for the mapping and filtering of letters, and then we invoke Enum.reduce/3 to build a map, for example:

iex> letters = for <<x <- "AbCabCABc">>, x in ?a..?z, do: <<x>>
iex> Enum.reduce(letters, %{}, fn x, acc -> Map.update(acc, x, 1, & &1 + 1) end)
%{"a" => 1, "b" => 2, "c" => 1}

While the above is straight-forward, it has the downside of traversing the data at least twice. If you are expecting long strings as inputs, this can be quite expensive.

Luckily, comprehensions also support the :reduce option, which would allow us to fuse both steps above into a single step:

iex> for <<x <- "AbCabCABc">>, x in ?a..?z, reduce: %{} do
...>   acc -> Map.update(acc, <<x>>, 1, & &1 + 1)
...> end
%{"a" => 1, "b" => 2, "c" => 1}

When the :reduce key is given, its value is used as the initial accumulator and the do block must be changed to use -> clauses, where the left side of -> receives the accumulated value of the previous iteration and the expression on the right side must return the new accumulator value. Once there are no more elements, the final accumulated value is returned. If there are no elements at all, then the initial accumulator value is returned.

Link to this macro

import(module, opts)

View Source (macro)

Imports functions and macros from other modules.

import/2 allows one to easily access functions or macros from other modules without using the qualified name.

Examples

If you are using several functions from a given module, you can import those functions and reference them as local functions, for example:

iex> import List
iex> flatten([1, [2], 3])
[1, 2, 3]

Selector

By default, Elixir imports functions and macros from the given module, except the ones starting with an underscore (which are usually callbacks):

import List

A developer can filter to import only functions, macros, or sigils (which can be functions or macros) via the :only option:

import List, only: :functions
import List, only: :macros
import Kernel, only: :sigils

Alternatively, Elixir allows a developer to pass pairs of name/arities to :only or :except as a fine grained control on what to import (or not):

import List, only: [flatten: 1]
import String, except: [split: 2]

Importing the same module again will erase the previous imports, except when the except option is used, which is always exclusive on a previously declared import/2. If there is no previous import, then it applies to all functions and macros in the module. For example:

import List, only: [flatten: 1, keyfind: 4]
import List, except: [flatten: 1]

After the two import calls above, only List.keyfind/4 will be imported.

Underscore functions

By default functions starting with _ are not imported. If you really want to import a function starting with _ you must explicitly include it in the :only selector.

import File.Stream, only: [__build__: 3]

Lexical scope

It is important to note that import/2 is lexical. This means you can import specific macros inside specific functions:

defmodule Math do
  def some_function do
    # 1) Disable "if/2" from Kernel
    import Kernel, except: [if: 2]

    # 2) Require the new "if/2" macro from MyMacros
    import MyMacros

    # 3) Use the new macro
    if do_something, it_works
  end
end

In the example above, we imported macros from MyMacros, replacing the original if/2 implementation by our own within that specific function. All other functions in that module will still be able to use the original one.

Warnings

If you import a module and you don't use any of the imported functions or macros from this module, Elixir is going to issue a warning implying the import is not being used.

In case the import is generated automatically by a macro, Elixir won't emit any warnings though, since the import was not explicitly defined.

Both warning behaviors could be changed by explicitly setting the :warn option to true or false.

Ambiguous function/macro names

If two modules A and B are imported and they both contain a foo function with an arity of 1, an error is only emitted if an ambiguous call to foo/1 is actually made; that is, the errors are emitted lazily, not eagerly.

Link to this macro

quote(opts, block)

View Source (macro)

Gets the representation of any expression.

Examples

iex> quote do
...>   sum(1, 2, 3)
...> end
{:sum, [], [1, 2, 3]}

Elixir's AST (Abstract Syntax Tree)

Any Elixir code can be represented using Elixir data structures. The building block of Elixir macros is a tuple with three elements, for example:

{:sum, [], [1, 2, 3]}

The tuple above represents a function call to sum passing 1, 2 and 3 as arguments. The tuple elements are:

  • The first element of the tuple is always an atom or another tuple in the same representation.

  • The second element of the tuple represents metadata.

  • The third element of the tuple are the arguments for the function call. The third argument may be an atom, which is usually a variable (or a local call).

Besides the tuple described above, Elixir has a few literals that are also part of its AST. Those literals return themselves when quoted. They are:

:sum         #=> Atoms
1            #=> Integers
2.0          #=> Floats
[1, 2]       #=> Lists
"strings"    #=> Strings
{key, value} #=> Tuples with two elements

Any other value, such as a map or a four-element tuple, must be escaped (Macro.escape/1) before being introduced into an AST.

Options

  • :bind_quoted - passes a binding to the macro. Whenever a binding is given, unquote/1 is automatically disabled.

  • :context - sets the resolution context.

  • :generated - marks the given chunk as generated so it does not emit warnings. It is also useful to avoid dialyzer reporting errors when macros generate unused clauses.

  • :file - sets the quoted expressions to have the given file.

  • :line - sets the quoted expressions to have the given line.

  • :location - when set to :keep, keeps the current line and file from quote. Read the "Stacktrace information" section below for more information.

  • :unquote - when false, disables unquoting. This means any unquote call will be kept as is in the AST, instead of replaced by the unquote arguments. For example:

    iex> quote do
    ...>   unquote("hello")
    ...> end
    "hello"
    
    iex> quote unquote: false do
    ...>   unquote("hello")
    ...> end
    {:unquote, [], ["hello"]}

Quote and macros

quote/2 is commonly used with macros for code generation. As an exercise, let's define a macro that multiplies a number by itself (squared). In practice, there is no reason to define such a macro (and it would actually be seen as a bad practice), but it is simple enough that it allows us to focus on the important aspects of quotes and macros:

defmodule Math do
  defmacro squared(x) do
    quote do
      unquote(x) * unquote(x)
    end
  end
end

We can invoke it as:

import Math
IO.puts("Got #{squared(5)}")

At first, there is nothing in this example that actually reveals it is a macro. But what is happening is that, at compilation time, squared(5) becomes 5 * 5. The argument 5 is duplicated in the produced code, we can see this behavior in practice though because our macro actually has a bug:

import Math
my_number = fn ->
  IO.puts("Returning 5")
  5
end
IO.puts("Got #{squared(my_number.())}")

The example above will print:

Returning 5
Returning 5
Got 25

Notice how "Returning 5" was printed twice, instead of just once. This is because a macro receives an expression and not a value (which is what we would expect in a regular function). This means that:

squared(my_number.())

Actually expands to:

my_number.() * my_number.()

Which invokes the function twice, explaining why we get the printed value twice! In the majority of the cases, this is actually unexpected behavior, and that's why one of the first things you need to keep in mind when it comes to macros is to not unquote the same value more than once.

Let's fix our macro:

defmodule Math do
  defmacro squared(x) do
    quote do
      x = unquote(x)
      x * x
    end
  end
end

Now invoking squared(my_number.()) as before will print the value just once.

In fact, this pattern is so common that most of the times you will want to use the bind_quoted option with quote/2:

defmodule Math do
  defmacro squared(x) do
    quote bind_quoted: [x: x] do
      x * x
    end
  end
end

:bind_quoted will translate to the same code as the example above. :bind_quoted can be used in many cases and is seen as good practice, not only because it helps prevent us from running into common mistakes, but also because it allows us to leverage other tools exposed by macros, such as unquote fragments discussed in some sections below.

Before we finish this brief introduction, you will notice that, even though we defined a variable x inside our quote:

quote do
  x = unquote(x)
  x * x
end

When we call:

import Math
squared(5)
x
** (CompileError) undefined variable "x"

We can see that x did not leak to the user context. This happens because Elixir macros are hygienic, a topic we will discuss at length in the next sections as well.

Hygiene in variables

Consider the following example:

defmodule Hygiene do
  defmacro no_interference do
    quote do
      a = 1
    end
  end
end

require Hygiene

a = 10
Hygiene.no_interference()
a
#=> 10

In the example above, a returns 10 even if the macro is apparently setting it to 1 because variables defined in the macro do not affect the context the macro is executed in. If you want to set or get a variable in the caller's context, you can do it with the help of the var! macro:

defmodule NoHygiene do
  defmacro interference do
    quote do
      var!(a) = 1
    end
  end
end

require NoHygiene

a = 10
NoHygiene.interference()
a
#=> 1

You cannot even access variables defined in the same module unless you explicitly give it a context:

defmodule Hygiene do
  defmacro write do
    quote do
      a = 1
    end
  end

  defmacro read do
    quote do
      a
    end
  end
end

require Hygiene
Hygiene.write()
Hygiene.read()
** (CompileError) undefined variable "a" (context Hygiene)

For such, you can explicitly pass the current module scope as argument:

defmodule ContextHygiene do
  defmacro write do
    quote do
      var!(a, ContextHygiene) = 1
    end
  end

  defmacro read do
    quote do
      var!(a, ContextHygiene)
    end
  end
end

require Hygiene
ContextHygiene.write()
ContextHygiene.read()
#=> 1

The contexts of a variable is identified by the third element of the tuple. The default context is nil and quote assigns another context to all variables within:

quote(do: var)
#=> {:var, [], Elixir}

In case of variables returned by macros, there may also be a :counter key in the metadata, which is used to further refine its contexts and guarantee isolation between macro invocations as seen in the previous example.

Hygiene in aliases

Aliases inside quote are hygienic by default. Consider the following example:

defmodule Hygiene do
  alias Map, as: M

  defmacro no_interference do
    quote do
      M.new()
    end
  end
end

require Hygiene
Hygiene.no_interference()
#=> %{}

Note that, even though the alias M is not available in the context the macro is expanded, the code above works because M still expands to Map.

Similarly, even if we defined an alias with the same name before invoking a macro, it won't affect the macro's result:

defmodule Hygiene do
  alias Map, as: M

  defmacro no_interference do
    quote do
      M.new()
    end
  end
end

require Hygiene
alias SomethingElse, as: M
Hygiene.no_interference()
#=> %{}

In some cases, you want to access an alias or a module defined in the caller. For such, you can use the alias! macro:

defmodule Hygiene do
  # This will expand to Elixir.Nested.hello()
  defmacro no_interference do
    quote do
      Nested.hello()
    end
  end

  # This will expand to Nested.hello() for
  # whatever is Nested in the caller
  defmacro interference do
    quote do
      alias!(Nested).hello()
    end
  end
end

defmodule Parent do
  defmodule Nested do
    def hello, do: "world"
  end

  require Hygiene
  Hygiene.no_interference()
  ** (UndefinedFunctionError) ...

  Hygiene.interference()
  #=> "world"
end

Hygiene in imports

Similar to aliases, imports in Elixir are hygienic. Consider the following code:

defmodule Hygiene do
  defmacrop get_length do
    quote do
      length([1, 2, 3])
    end
  end

  def return_length do
    import Kernel, except: [length: 1]
    get_length
  end
end

Hygiene.return_length()
#=> 3

Notice how Hygiene.return_length/0 returns 3 even though the Kernel.length/1 function is not imported. In fact, even if return_length/0 imported a function with the same name and arity from another module, it wouldn't affect the function result:

def return_length do
  import String, only: [length: 1]
  get_length
end

Calling this new return_length/0 will still return 3 as result.

Elixir is smart enough to delay the resolution to the latest possible moment. So, if you call length([1, 2, 3]) inside quote, but no length/1 function is available, it is then expanded in the caller:

defmodule Lazy do
  defmacrop get_length do
    import Kernel, except: [length: 1]

    quote do
      length("hello")
    end
  end

  def return_length do
    import Kernel, except: [length: 1]
    import String, only: [length: 1]
    get_length
  end
end

Lazy.return_length()
#=> 5

Stacktrace information

When defining functions via macros, developers have the option of choosing if runtime errors will be reported from the caller or from inside the quote. Let's see an example:

# adder.ex
defmodule Adder do
  @doc "Defines a function that adds two numbers"
  defmacro defadd do
    quote location: :keep do
      def add(a, b), do: a + b
    end
  end
end

# sample.ex
defmodule Sample do
  import Adder
  defadd
end

require Sample
Sample.add(:one, :two)
** (ArithmeticError) bad argument in arithmetic expression
    adder.ex:5: Sample.add/2

When using location: :keep and invalid arguments are given to Sample.add/2, the stacktrace information will point to the file and line inside the quote. Without location: :keep, the error is reported to where defadd was invoked. location: :keep affects only definitions inside the quote.

location: :keep and unquote

Do not use location: :keep if the function definition also unquotes some of the macro arguments. If you do so, Elixir will store the file definition of the current location but the unquoted arguments may contain line information of the macro caller, leading to erroneous stacktraces.

Binding and unquote fragments

Elixir quote/unquote mechanisms provide a functionality called unquote fragments. Unquote fragments provide an easy way to generate functions on the fly. Consider this example:

kv = [foo: 1, bar: 2]
Enum.each(kv, fn {k, v} ->
  def unquote(k)(), do: unquote(v)
end)

In the example above, we have generated the functions foo/0 and bar/0 dynamically. Now, imagine that we want to convert this functionality into a macro:

defmacro defkv(kv) do
  Enum.map(kv, fn {k, v} ->
    quote do
      def unquote(k)(), do: unquote(v)
    end
  end)
end

We can invoke this macro as:

defkv [foo: 1, bar: 2]

However, we can't invoke it as follows:

kv = [foo: 1, bar: 2]
defkv kv

This is because the macro is expecting its arguments to be a keyword list at compilation time. Since in the example above we are passing the representation of the variable kv, our code fails.

This is actually a common pitfall when developing macros. We are assuming a particular shape in the macro. We can work around it by unquoting the variable inside the quoted expression:

defmacro defkv(kv) do
  quote do
    Enum.each(unquote(kv), fn {k, v} ->
      def unquote(k)(), do: unquote(v)
    end)
  end
end

If you try to run our new macro, you will notice it won't even compile, complaining that the variables k and v do not exist. This is because of the ambiguity: unquote(k) can either be an unquote fragment, as previously, or a regular unquote as in unquote(kv).

One solution to this problem is to disable unquoting in the macro, however, doing that would make it impossible to inject the kv representation into the tree. That's when the :bind_quoted option comes to the rescue (again!). By using :bind_quoted, we can automatically disable unquoting while still injecting the desired variables into the tree:

defmacro defkv(kv) do
  quote bind_quoted: [kv: kv] do
    Enum.each(kv, fn {k, v} ->
      def unquote(k)(), do: unquote(v)
    end)
  end
end

In fact, the :bind_quoted option is recommended every time one desires to inject a value into the quote.

Checks if there is a message matching any of the given clauses in the current process mailbox.

If there is no matching message, the current process waits until a matching message arrives or until after a given timeout value.

Any new and existing messages that do not match will remain in the mailbox.

Examples

receive do
  {:selector, number, name} when is_integer(number) ->
    name
  name when is_atom(name) ->
    name
  _ ->
    IO.puts(:stderr, "Unexpected message received")
end

An optional after clause can be given in case no matching message is received during the given timeout period, specified in milliseconds:

receive do
  {:selector, number, name} when is_integer(number) ->
    name
  name when is_atom(name) ->
    name
  _ ->
    IO.puts(:stderr, "Unexpected message received")
after
  5000 ->
    IO.puts(:stderr, "No message in 5 seconds")
end

The after clause can be specified even if there are no match clauses. The timeout value given to after can be any expression evaluating to one of the allowed values:

  • :infinity - the process should wait indefinitely for a matching message, this is the same as not using the after clause

  • 0 - if there is no matching message in the mailbox, the timeout will occur immediately

  • positive integer smaller than or equal to 4_294_967_295 (0xFFFFFFFF in hexadecimal notation) - it should be possible to represent the timeout value as an unsigned 32-bit integer.

Variable handling

The receive/1 special form handles variables exactly as the case/2 special macro. For more information, check the docs for case/2.

Link to this macro

require(module, opts)

View Source (macro)

Requires a module in order to use its macros.

Examples

Public functions in modules are globally available, but in order to use macros, you need to opt-in by requiring the module they are defined in.

Let's suppose you created your own if/2 implementation in the module MyMacros. If you want to invoke it, you need to first explicitly require the MyMacros:

defmodule Math do
  require MyMacros
  MyMacros.if do_something, it_works
end

An attempt to call a macro that was not loaded will raise an error.

Alias shortcut

require/2 also accepts :as as an option so it automatically sets up an alias. Please check alias/2 for more information.

Calls the overridden function when overriding it with Kernel.defoverridable/1.

See Kernel.defoverridable/1 for more information and documentation.

Evaluates the given expressions and handles any error, exit, or throw that may have happened.

Examples

try do
  do_something_that_may_fail(some_arg)
rescue
  ArgumentError ->
    IO.puts("Invalid argument given")
catch
  value ->
    IO.puts("Caught #{inspect(value)}")
else
  value ->
    IO.puts("Success! The result was #{inspect(value)}")
after
  IO.puts("This is printed regardless if it failed or succeeded")
end

The rescue clause is used to handle exceptions while the catch clause can be used to catch thrown values and exits. The else clause can be used to control flow based on the result of the expression. catch, rescue, and else clauses work based on pattern matching (similar to the case special form).

Calls inside try/1 are not tail recursive since the VM needs to keep the stacktrace in case an exception happens. To retrieve the stacktrace, access __STACKTRACE__/0 inside the rescue or catch clause.

rescue clauses

Besides relying on pattern matching, rescue clauses provide some conveniences around exceptions that allow one to rescue an exception by its name. All the following formats are valid patterns in rescue clauses:

# Rescue a single exception without binding the exception
# to a variable
try do
  UndefinedModule.undefined_function
rescue
  UndefinedFunctionError -> nil
end

# Rescue any of the given exception without binding
try do
  UndefinedModule.undefined_function
rescue
  [UndefinedFunctionError, ArgumentError] -> nil
end

# Rescue and bind the exception to the variable "x"
try do
  UndefinedModule.undefined_function
rescue
  x in [UndefinedFunctionError] -> nil
end

# Rescue all kinds of exceptions and bind the rescued exception
# to the variable "x"
try do
  UndefinedModule.undefined_function
rescue
  x -> nil
end

Erlang errors

Erlang errors are transformed into Elixir ones when rescuing:

try do
  :erlang.error(:badarg)
rescue
  ArgumentError -> :ok
end
#=> :ok

The most common Erlang errors will be transformed into their Elixir counterpart. Those which are not will be transformed into the more generic ErlangError:

try do
  :erlang.error(:unknown)
rescue
  ErlangError -> :ok
end
#=> :ok

In fact, ErlangError can be used to rescue any error that is not a proper Elixir error. For example, it can be used to rescue the earlier :badarg error too, prior to transformation:

try do
  :erlang.error(:badarg)
rescue
  ErlangError -> :ok
end
#=> :ok

catch clauses

The catch clause can be used to catch thrown values, exits, and errors.

Catching thrown values

catch can be used to catch values thrown by Kernel.throw/1:

try do
  throw(:some_value)
catch
  thrown_value ->
    IO.puts("A value was thrown: #{inspect(thrown_value)}")
end

Catching values of any kind

The catch clause also supports catching exits and errors. To do that, it allows matching on both the kind of the caught value as well as the value itself:

try do
  exit(:shutdown)
catch
  :exit, value ->
    IO.puts("Exited with value #{inspect(value)}")
end

try do
  exit(:shutdown)
catch
  kind, value when kind in [:exit, :throw] ->
    IO.puts("Caught exit or throw with value #{inspect(value)}")
end

The catch clause also supports :error alongside :exit and :throw as in Erlang, although this is commonly avoided in favor of raise/rescue control mechanisms. One reason for this is that when catching :error, the error is not automatically transformed into an Elixir error:

try do
  :erlang.error(:badarg)
catch
  :error, :badarg -> :ok
end
#=> :ok

after clauses

An after clause allows you to define cleanup logic that will be invoked both when the block of code passed to try/1 succeeds and also when an error is raised. Note that the process will exit as usual when receiving an exit signal that causes it to exit abruptly and so the after clause is not guaranteed to be executed. Luckily, most resources in Elixir (such as open files, ETS tables, ports, sockets, and so on) are linked to or monitor the owning process and will automatically clean themselves up if that process exits.

File.write!("tmp/story.txt", "Hello, World")
try do
  do_something_with("tmp/story.txt")
after
  File.rm("tmp/story.txt")
end

Although after clauses are invoked whether or not there was an error, they do not modify the return value. All of the following examples return :return_me:

try do
  :return_me
after
  IO.puts("I will be printed")
  :not_returned
end

try do
  raise "boom"
rescue
  _ -> :return_me
after
  IO.puts("I will be printed")
  :not_returned
end

else clauses

else clauses allow the result of the body passed to try/1 to be pattern matched on:

x = 2
try do
  1 / x
rescue
  ArithmeticError ->
    :infinity
else
  y when y < 1 and y > -1 ->
    :small
  _ ->
    :large
end

If an else clause is not present and no exceptions are raised, the result of the expression will be returned:

x = 1
^x =
  try do
    1 / x
  rescue
    ArithmeticError ->
      :infinity
  end

However, when an else clause is present but the result of the expression does not match any of the patterns then an exception will be raised. This exception will not be caught by a catch or rescue in the same try:

x = 1
try do
  try do
    1 / x
  rescue
    # The TryClauseError cannot be rescued here:
    TryClauseError ->
      :error_a
  else
    0 ->
      :small
  end
rescue
  # The TryClauseError is rescued here:
  TryClauseError ->
    :error_b
end

Similarly, an exception inside an else clause is not caught or rescued inside the same try:

try do
  try do
    nil
  catch
    # The exit(1) call below can not be caught here:
    :exit, _ ->
      :exit_a
  else
    _ ->
      exit(1)
  end
catch
  # The exit is caught here:
  :exit, _ ->
    :exit_b
end

This means the VM no longer needs to keep the stacktrace once inside an else clause and so tail recursion is possible when using a try with a tail call as the final call inside an else clause. The same is true for rescue and catch clauses.

Only the result of the tried expression falls down to the else clause. If the try ends up in the rescue or catch clauses, their result will not fall down to else:

try do
  throw(:catch_this)
catch
  :throw, :catch_this ->
    :it_was_caught
else
  # :it_was_caught will not fall down to this "else" clause.
  other ->
    {:else, other}
end

Variable handling

Since an expression inside try may not have been evaluated due to an exception, any variable created inside try cannot be accessed externally. For instance:

try do
  x = 1
  do_something_that_may_fail(same_arg)
  :ok
catch
  _, _ -> :failed
end

x
#=> unbound variable "x"

In the example above, x cannot be accessed since it was defined inside the try clause. A common practice to address this issue is to return the variables defined inside try:

x =
  try do
    x = 1
    do_something_that_may_fail(same_arg)
    x
  catch
    _, _ -> :failed
  end

Unquotes the given expression inside a quoted expression.

This function expects a valid Elixir AST, also known as quoted expression, as argument. If you would like to unquote any value, such as a map or a four-element tuple, you should call Macro.escape/1 before unquoting.

Examples

Imagine the situation you have a quoted expression and you want to inject it inside some quote. The first attempt would be:

value =
  quote do
    13
  end

quote do
  sum(1, value, 3)
end

Which the argument for the :sum function call is not the expected result:

{:sum, [], [1, {:value, [], Elixir}, 3]}

For this, we use unquote:

iex> value =
...>   quote do
...>     13
...>   end
iex> quote do
...>   sum(1, unquote(value), 3)
...> end
{:sum, [], [1, 13, 3]}

If you want to unquote a value that is not a quoted expression, such as a map, you need to call Macro.escape/1 before:

iex> value = %{foo: :bar}
iex> quote do
...>   process_map(unquote(Macro.escape(value)))
...> end
{:process_map, [], [{:%{}, [], [foo: :bar]}]}

If you forget to escape it, Elixir will raise an error when compiling the code.

Link to this macro

unquote_splicing(expr)

View Source (macro)

Unquotes the given list expanding its arguments.

Similar to unquote/1.

Examples

iex> values = [2, 3, 4]
iex> quote do
...>   sum(1, unquote_splicing(values), 5)
...> end
{:sum, [], [1, 2, 3, 4, 5]}

Combine matching clauses.

One of the ways to understand with is to show which code patterns it improves. Imagine you have a map where the fields width and height are optional and you want to compute its area, as {:ok, area} or return :error. We could implement this function as:

def area(opts) do
  case Map.fetch(opts, :width) do
    {:ok, width} ->
      case Map.fetch(opts, :height) do
        {:ok, height} -> {:ok, width * height}
        :error -> :error
      end

    :error ->
      :error
  end
end

when called as area(%{width: 10, height: 15}), it should return {:ok, 150}. If any of the fields are missing, it returns :error.

While the code above works, it is quite verbose. Using with, we could rewrite it as:

def area(opts) do
  with {:ok, width} <- Map.fetch(opts, :width),
       {:ok, height} <- Map.fetch(opts, :height) do
    {:ok, width * height}
  end
end

Instead of defining nested cases with clauses, we use with alongside the PATTERN <- EXPRESSION operator to match expressions on its right side against the pattern on the left. Consider <- as a sibling to =, except that, while = raises in case of not matches, <- will simply abort the with chain and return the non-matched value.

Let's give it a try on IEx:

iex> opts = %{width: 10, height: 15}
iex> with {:ok, width} <- Map.fetch(opts, :width),
...>      {:ok, height} <- Map.fetch(opts, :height) do
...>   {:ok, width * height}
...> end
{:ok, 150}

If all clauses match, the do block is executed, returning its result. Otherwise the chain is aborted and the non-matched value is returned:

iex> opts = %{width: 10}
iex> with {:ok, width} <- Map.fetch(opts, :width),
...>      {:ok, height} <- Map.fetch(opts, :height) do
...>   {:ok, width * height}
...> end
:error

Guards can be used in patterns as well:

iex> users = %{"melany" => "guest", "bob" => :admin}
iex> with {:ok, role} when not is_binary(role) <- Map.fetch(users, "bob") do
...>   {:ok, to_string(role)}
...> end
{:ok, "admin"}

As in for/1, variables bound inside with/1 won't be accessible outside of with/1.

Expressions without <- may also be used in clauses. For instance, you can perform regular matches with the = operator:

iex> width = nil
iex> opts = %{width: 10, height: 15}
iex> with {:ok, width} <- Map.fetch(opts, :width),
...>      double_width = width * 2,
...>      {:ok, height} <- Map.fetch(opts, :height) do
...>   {:ok, double_width * height}
...> end
{:ok, 300}
iex> width
nil

The behavior of any expression in a clause is the same as if it was written outside of with. For example, = will raise a MatchError instead of returning the non-matched value:

with :foo = :bar, do: :ok
** (MatchError) no match of right hand side value: :bar

As with any other function or macro call in Elixir, explicit parens can also be used around the arguments before the do-end block:

iex> opts = %{width: 10, height: 15}
iex> with(
...>   {:ok, width} <- Map.fetch(opts, :width),
...>   {:ok, height} <- Map.fetch(opts, :height)
...> ) do
...>   {:ok, width * height}
...> end
{:ok, 150}

The choice between parens and no parens is a matter of preference.

Else clauses

An else option can be given to modify what is being returned from with in the case of a failed match:

iex> opts = %{width: 10}
iex> with {:ok, width} <- Map.fetch(opts, :width),
...>      {:ok, height} <- Map.fetch(opts, :height) do
...>   {:ok, width * height}
...> else
...>   :error ->
...>     {:error, :wrong_data}
...>
...>   _other_error ->
...>     :unexpected_error
...> end
{:error, :wrong_data}

The else block works like a case clause: it can have multiple clauses, and the first match will be used. Variables bound inside with (such as width in this example) are not available in the else block.

If an else block is used and there are no matching clauses, a WithClauseError exception is raised.

Beware!

Keep in mind that, one of potential drawback of with is that all failure clauses are flattened into a single else block. For example, take this code that checks if a given path points to an Elixir file and that it exists before creating a backup copy:

with ".ex" <- Path.extname(path),
     true <- File.exists?(path) do
  backup_path = path <> ".backup"
  File.cp!(path, backup_path)
  {:ok, backup_path}
else
  binary when is_binary(binary) ->
    {:error, :invalid_extension}

  false ->
    {:error, :missing_file}
end

Note how we are having to reconstruct the result types of Path.extname/1 and File.exists?/1 to build error messages. In this case, it is better to refactor the code so each <- already return the desired format in case of errors, like this:

with :ok <- validate_extension(path),
     :ok <- validate_exists(path) do
  backup_path = path <> ".backup"
  File.cp!(path, backup_path)
  {:ok, backup_path}
end

defp validate_extension(path) do
  if Path.extname(path) == ".ex", do: :ok, else: {:error, :invalid_extension}
end

defp validate_exists(path) do
  if File.exists?(path), do: :ok, else: {:error, :missing_file}
end

Note how the code above is better organized and clearer once we make sure each <- in with returns a normalized format.

Pin operator. Accesses an already bound variable in match clauses.

Examples

Elixir allows variables to be rebound via static single assignment:

iex> x = 1
iex> x = x + 1
iex> x
2

However, in some situations, it is useful to match against an existing value, instead of rebinding. This can be done with the ^ special form, colloquially known as the pin operator:

iex> x = 1
iex> ^x = List.first([1])
iex> ^x = List.first([2])
** (MatchError) no match of right hand side value: 2

Note that ^x always refers to the value of x prior to the match. The following example will match:

iex> x = 0
iex> {x, ^x} = {1, 0}
iex> x
1

Creates a tuple.

More information about the tuple data type and about functions to manipulate tuples can be found in the Tuple module; some functions for working with tuples are also available in Kernel (such as Kernel.elem/2 or Kernel.tuple_size/1).

AST representation

Only two-element tuples are considered literals in Elixir and return themselves when quoted. Therefore, all other tuples are represented in the AST as calls to the :{} special form.

iex> quote do
...>   {1, 2}
...> end
{1, 2}

iex> quote do
...>   {1, 2, 3}
...> end
{:{}, [], [1, 2, 3]}