Elixir v1.6.1 Macro View Source
Conveniences for working with macros.
Custom Sigils
To create a custom sigil, define a function with the name
sigil_{identifier}
that takes two arguments. The first argument will be
the string, the second will be a charlist containing any modifiers. If the
sigil is lower case (such as sigil_x
) then the string argument will allow
interpolation. If the sigil is upper case (such as sigil_X
) then the string
will not be interpolated.
Valid modifiers include only lower and upper case letters. Other characters will cause a syntax error.
The module containing the custom sigil must be imported before the sigil syntax can be used.
Examples
defmodule MySigils do
defmacro sigil_x(term, [?r]) do
quote do
unquote(term) |> String.reverse()
end
end
defmacro sigil_x(term, _modifiers) do
term
end
defmacro sigil_X(term, [?r]) do
quote do
unquote(term) |> String.reverse()
end
end
defmacro sigil_X(term, _modifiers) do
term
end
end
import MySigils
~x(with #{"inter" <> "polation"})
#=>"with interpolation"
~x(with #{"inter" <> "polation"})r
#=>"noitalopretni htiw"
~X(without #{"interpolation"})
#=>"without \#{"interpolation"}"
~X(without #{"interpolation"})r
#=>"}\"noitalopretni\"{# tuohtiw"
Link to this section Summary
Functions
Converts the given string to CamelCase format
Decomposes a local or remote call into its remote part (when provided), function name and argument list
Recursively escapes a value so it can be inserted into a syntax tree
Receives an AST node and expands it until it can no longer be expanded
Receives an AST node and expands it once
Generates AST nodes for a given number of required argument variables using
Macro.var/2
Pipes expr
into the call_args
at the given position
Performs a depth-first, post-order traversal of quoted expressions
Performs a depth-first, post-order traversal of quoted expressions using an accumulator
Performs a depth-first, pre-order traversal of quoted expressions
Performs a depth-first, pre-order traversal of quoted expressions using an accumulator
Converts the given expression AST to a string
Performs a depth-first traversal of quoted expressions using an accumulator
Converts the given atom or binary to underscore format
Unescapes the given chars
Unescapes the given chars according to the map given
Breaks a pipeline expression into a list
Applies the given function to the node metadata if it contains one
Validates the given expressions are valid quoted expressions
Generates an AST node representing the variable given
by the atoms var
and context
Link to this section Types
Represents expressions in the AST
Represents literals in the AST
Abstract Syntax Tree (AST)
Link to this section Functions
Converts the given string to CamelCase format.
This function was designed to camelize language identifiers/tokens,
that’s why it belongs to the Macro
module. Do not use it as a general
mechanism for camelizing strings as it does not support Unicode or
characters that are not valid in Elixir identifiers.
Examples
iex> Macro.camelize "foo_bar"
"FooBar"
If uppercase characters are present, they are not modified in anyway as a mechanism to preserve acronyms:
iex> Macro.camelize "API.V1"
"API.V1"
iex> Macro.camelize "API_SPEC"
"API_SPEC"
Decomposes a local or remote call into its remote part (when provided), function name and argument list.
Returns :error
when an invalid call syntax is provided.
Examples
iex> Macro.decompose_call(quote(do: foo))
{:foo, []}
iex> Macro.decompose_call(quote(do: foo()))
{:foo, []}
iex> Macro.decompose_call(quote(do: foo(1, 2, 3)))
{:foo, [1, 2, 3]}
iex> Macro.decompose_call(quote(do: Elixir.M.foo(1, 2, 3)))
{{:__aliases__, [], [:Elixir, :M]}, :foo, [1, 2, 3]}
iex> Macro.decompose_call(quote(do: 42))
:error
Recursively escapes a value so it can be inserted into a syntax tree.
One may pass unquote: true
to escape/2
which leaves unquote/1
statements unescaped, effectively
unquoting the contents on escape.
Examples
iex> Macro.escape(:foo)
:foo
iex> Macro.escape({:a, :b, :c})
{:{}, [], [:a, :b, :c]}
iex> Macro.escape({:unquote, [], [1]}, unquote: true)
1
Receives an AST node and expands it until it can no longer be expanded.
This function uses expand_once/2
under the hood. Check
it out for more information and examples.
Receives an AST node and expands it once.
The following contents are expanded:
- Macros (local or remote)
- Aliases are expanded (if possible) and return atoms
- Compilation environment macros (
__ENV__/0
,__MODULE__/0
and__DIR__/0
) - Module attributes reader (
@foo
)
If the expression cannot be expanded, it returns the expression
itself. Notice that expand_once/2
performs the expansion just
once and it is not recursive. Check expand/2
for expansion
until the node can no longer be expanded.
Examples
In the example below, we have a macro that generates a module
with a function named name_length
that returns the length
of the module name. The value of this function will be calculated
at compilation time and not at runtime.
Consider the implementation below:
defmacro defmodule_with_length(name, do: block) do
length = length(Atom.to_charlist(name))
quote do
defmodule unquote(name) do
def name_length, do: unquote(length)
unquote(block)
end
end
end
When invoked like this:
defmodule_with_length My.Module do
def other_function, do: ...
end
The compilation will fail because My.Module
when quoted
is not an atom, but a syntax tree as follow:
{:__aliases__, [], [:My, :Module]}
That said, we need to expand the aliases node above to an atom, so we can retrieve its length. Expanding the node is not straightforward because we also need to expand the caller aliases. For example:
alias MyHelpers, as: My
defmodule_with_length My.Module do
def other_function, do: ...
end
The final module name will be MyHelpers.Module
and not
My.Module
. With Macro.expand/2
, such aliases are taken
into consideration. Local and remote macros are also
expanded. We could rewrite our macro above to use this
function as:
defmacro defmodule_with_length(name, do: block) do
expanded = Macro.expand(name, __CALLER__)
length = length(Atom.to_charlist(expanded))
quote do
defmodule unquote(name) do
def name_length, do: unquote(length)
unquote(block)
end
end
end
Generates AST nodes for a given number of required argument variables using
Macro.var/2
.
Examples
iex> Macro.generate_arguments(2, __MODULE__)
[{:var1, [], __MODULE__}, {:var2, [], __MODULE__}]
Pipes expr
into the call_args
at the given position
.
Performs a depth-first, post-order traversal of quoted expressions.
Performs a depth-first, post-order traversal of quoted expressions using an accumulator.
Performs a depth-first, pre-order traversal of quoted expressions.
Performs a depth-first, pre-order traversal of quoted expressions using an accumulator.
Converts the given expression AST to a string.
The given fun
is called for every node in the AST with two arguments: the
AST of the node being printed and the string representation of that same
node. The return value of this function is used as the final string
representation for that AST node.
This function discards all formatting of the original code.
Examples
iex> Macro.to_string(quote(do: foo.bar(1, 2, 3)))
"foo.bar(1, 2, 3)"
iex> Macro.to_string(quote(do: 1 + 2), fn
...> 1, _string -> "one"
...> 2, _string -> "two"
...> _ast, string -> string
...> end)
"one + two"
Performs a depth-first traversal of quoted expressions using an accumulator.
Converts the given atom or binary to underscore format.
If an atom is given, it is assumed to be an Elixir module, so it is converted to a binary and then processed.
This function was designed to underscore language identifiers/tokens,
that’s why it belongs to the Macro
module. Do not use it as a general
mechanism for underscoring strings as it does not support Unicode or
characters that are not valid in Elixir identifiers.
Examples
iex> Macro.underscore "FooBar"
"foo_bar"
iex> Macro.underscore "Foo.Bar"
"foo/bar"
iex> Macro.underscore Foo.Bar
"foo/bar"
In general, underscore
can be thought of as the reverse of
camelize
, however, in some cases formatting may be lost:
iex> Macro.underscore "SAPExample"
"sap_example"
iex> Macro.camelize "sap_example"
"SapExample"
iex> Macro.camelize "hello_10"
"Hello10"
Unescapes the given chars.
This is the unescaping behaviour used by default in Elixir
single- and double-quoted strings. Check unescape_string/2
for information on how to customize the escaping map.
In this setup, Elixir will escape the following: \0
, \a
, \b
,
\d
, \e
, \f
, \n
, \r
, \s
, \t
and \v
. Bytes can be
given as hexadecimals via \xNN
and Unicode Codepoints as
\uNNNN
escapes.
This function is commonly used on sigil implementations
(like ~r
, ~s
and others) which receive a raw, unescaped
string.
Examples
iex> Macro.unescape_string("example\\n")
"example\n"
In the example above, we pass a string with \n
escaped
and return a version with it unescaped.
unescape_string(String.t(), (non_neg_integer() -> non_neg_integer() | false)) :: String.t()
Unescapes the given chars according to the map given.
Check unescape_string/1
if you want to use the same map
as Elixir single- and double-quoted strings.
Map
The map must be a function. The function receives an integer representing the codepoint of the character it wants to unescape. Here is the default mapping function implemented by Elixir:
def unescape_map(unicode), do: true
def unescape_map(hex), do: true
def unescape_map(?0), do: ?0
def unescape_map(?a), do: ?\a
def unescape_map(?b), do: ?\b
def unescape_map(?d), do: ?\d
def unescape_map(?e), do: ?\e
def unescape_map(?f), do: ?\f
def unescape_map(?n), do: ?\n
def unescape_map(?r), do: ?\r
def unescape_map(?s), do: ?\s
def unescape_map(?t), do: ?\t
def unescape_map(?v), do: ?\v
def unescape_map(e), do: e
If the unescape_map/1
function returns false
, the char is
not escaped and the backslash is kept in the string.
Hexadecimals and Unicode codepoints will be escaped if the map
function returns true
for ?x
. Unicode codepoints if the map
function returns true
for ?u
.
Examples
Using the unescape_map/1
function defined above is easy:
Macro.unescape_string "example\\n", &unescape_map(&1)
Breaks a pipeline expression into a list.
The AST for a pipeline (a sequence of applications of |>
) is similar to the
AST of a sequence of binary operators or function applications: the top-level
expression is the right-most :|>
(which is the last one to be executed), and
its left-hand and right-hand sides are its arguments:
quote do: 100 |> div(5) |> div(2)
#=> {:|>, _, [arg1, arg2]}
In the example above, the |>
pipe is the right-most pipe; arg1
is the AST
for 100 |> div(5)
, and arg2
is the AST for div(2)
.
It’s often useful to have the AST for such a pipeline as a list of function applications. This function does exactly that:
Macro.unpipe(quote do: 100 |> div(5) |> div(2))
#=> [{100, 0}, {{:div, [], [5]}, 0}, {{:div, [], [2]}, 0}]
We get a list that follows the pipeline directly: first the 100
, then the
div(5)
(more precisely, its AST), then div(2)
. The 0
as the second
element of the tuples is the position of the previous element in the pipeline
inside the current function application: {{:div, [], [5]}, 0}
means that the
previous element (100
) will be inserted as the 0th (first) argument to the
div/2
function, so that the AST for that function will become {:div, [],
[100, 5]}
(div(100, 5)
).
Applies the given function to the node metadata if it contains one.
This is often useful when used with Macro.prewalk/2
to remove
information like lines and hygienic counters from the expression
for either storage or comparison.
Examples
iex> quoted = quote line: 10, do: sample()
{:sample, [line: 10], []}
iex> Macro.update_meta(quoted, &Keyword.delete(&1, :line))
{:sample, [], []}
Validates the given expressions are valid quoted expressions.
Checks the Macro.t/0
for the specification of a valid
quoted expression.
It returns :ok
if the expression is valid. Otherwise it returns a tuple in the form of
{:error, remainder}
where remainder
is the invalid part of the quoted expression.
Examples
iex> Macro.validate({:two_element, :tuple})
:ok
iex> Macro.validate({:three, :element, :tuple})
{:error, {:three, :element, :tuple}}
iex> Macro.validate([1, 2, 3])
:ok
iex> Macro.validate([1, 2, 3, {4}])
{:error, {4}}
Generates an AST node representing the variable given
by the atoms var
and context
.
Examples
In order to build a variable, a context is expected.
Most of the times, in order to preserve hygiene, the
context must be __MODULE__/0
:
iex> Macro.var(:foo, __MODULE__)
{:foo, [], __MODULE__}
However, if there is a need to access the user variable, nil can be given:
iex> Macro.var(:foo, nil)
{:foo, [], nil}