View Source Code (Elixir v1.12.3)

Utilities for managing code compilation, code evaluation, and code loading.

This module complements Erlang's :code module to add behaviour which is specific to Elixir. Almost all of the functions in this module have global side effects on the behaviour of Elixir.

Working with files

This module contains three functions for compiling and evaluating files. Here is a summary of them and their behaviour:

  • require_file/2 - compiles a file and tracks its name. It does not compile the file again if it has been previously required.

  • compile_file/2 - compiles a file without tracking its name. Compiles the file multiple times when invoked multiple times.

  • eval_file/2 - evaluates the file contents without tracking its name. It returns the result of the last expression in the file, instead of the modules defined in it. Evaluated files do not trigger the compilation tracers described in the next section.

In a nutshell, the first must be used when you want to keep track of the files handled by the system, to avoid the same file from being compiled multiple times. This is common in scripts.

compile_file/2 must be used when you are interested in the modules defined in a file, without tracking. eval_file/2 should be used when you are interested in the result of evaluating the file rather than the modules it defines.

Code loading on the Erlang VM

Erlang has two modes to load code: interactive and embedded.

By default, the Erlang VM runs in interactive mode, where modules are loaded as needed. In embedded mode the opposite happens, as all modules need to be loaded upfront or explicitly.

You can use ensure_loaded/1 (as well as ensure_lodead?/1 and ensure_lodead!/1) to check if a module is loaded before using it and act.

ensure_compiled/1 and ensure_compiled!/1

Elixir also includes ensure_compiled/1 and ensure_compiled!/1 functions that are a superset of ensure_loaded/1.

Since Elixir's compilation happens in parallel, in some situations you may need to use a module that was not yet compiled, therefore it can't even be loaded.

When invoked, ensure_compiled/1 and ensure_compiled!/1 halt the compilation of the caller until the module becomes available. Note the distinction between ensure_compiled/1 and ensure_compiled!/1 is important: if you are using ensure_compiled!/1, you are indicating to the compiler that you can only continue if said module is available.

If you are using Code.ensure_compiled/1, you are implying you may continue without the module and therefore Elixir may return {:error, :unavailable} for cases where the module is not yet available (but may be available later on).

For those reasons, developers must typically use Code.ensure_compiled!/1. In particular, do not do this:

case Code.ensure_compiled(module) do
  {:module, _} -> module
  {:error, _} -> raise ...
end

Finally, note you only need ensure_compiled!/1 to check for modules being defined within the same project. It does not apply to modules from dependencies as dependencies are always compiled upfront.

In most cases, ensure_loaded/1 is enough. ensure_compiled!/1 must be used in rare cases, usually involving macros that need to invoke a module for callback information. The use of ensure_compiled/1 is even less likely.

Compilation tracers

Elixir supports compilation tracers, which allows modules to observe constructs handled by the Elixir compiler when compiling files. A tracer is a module that implements the trace/2 function. The function receives the event name as first argument and Macro.Env as second and it must return :ok. It is very important for a tracer to do as little work as possible synchronously and dispatch the bulk of the work to a separate process. Slow tracers will slow down compilation.

You can configure your list of tracers via put_compiler_option/2. The following events are available to tracers:

  • :start - (since v1.11.0) invoked whenever the compiler starts to trace a new lexical context, such as a new file. Keep in mind the compiler runs in parallel, so multiple files may invoke :start and run at the same time. The value of the lexical_tracker of the macro environment, albeit opaque, can be used to uniquely identify the environment.

  • :stop - (since v1.11.0) invoked whenever the compiler stops tracing a new lexical context, such as a new file.

  • {:import, meta, module, opts} - traced whenever module is imported. meta is the import AST metadata and opts are the import options.

  • {:imported_function, meta, module, name, arity} and {:imported_macro, meta, module, name, arity} - traced whenever an imported function or macro is invoked. meta is the call AST metadata, module is the module the import is from, followed by the name and arity of the imported function/macro.

  • {:alias, meta, alias, as, opts} - traced whenever alias is aliased to as. meta is the alias AST metadata and opts are the alias options.

  • {:alias_expansion, meta, as, alias} traced whenever there is an alias expansion for a previously defined alias, i.e. when the user writes as which is expanded to alias. meta is the alias expansion AST metadata.

  • {:alias_reference, meta, module} - traced whenever there is an alias in the code, i.e. whenever the user writes MyModule.Foo.Bar in the code, regardless if it was expanded or not.

  • {:require, meta, module, opts} - traced whenever module is required. meta is the require AST metadata and opts are the require options.

  • {:struct_expansion, meta, module, keys} - traced whenever module's struct is expanded. meta is the struct AST metadata and keys are the keys being used by expansion

  • {:remote_function, meta, module, name, arity} and {:remote_macro, meta, module, name, arity} - traced whenever a remote function or macro is referenced. meta is the call AST metadata, module is the invoked module, followed by the name and arity.

  • {:local_function, meta, name, arity} and {:local_macro, meta, name, arity} - traced whenever a local function or macro is referenced. meta is the call AST metadata, followed by the name and arity.

  • {:compile_env, app, path, return} - traced whenever Application.compile_env/3 or Application.compile_env!/2 are called. app is an atom, path is a list of keys to traverse in the application environment and return is either {:ok, value} or :error.

The :tracers compiler option can be combined with the :parser_options compiler option to enrich the metadata of the traced events above.

New events may be added at any time in the future, therefore it is advised for the trace/2 function to have a "catch-all" clause.

Below is an example tracer that prints all remote function invocations:

defmodule MyTracer do
  def trace({:remote_function, _meta, module, name, arity}, env) do
    IO.puts "#{env.file}:#{env.line} #{inspect(module)}.#{name}/#{arity}"
    :ok
  end

  def trace(_event, _env) do
    :ok
  end
end

Link to this section Summary

Types

A list with all variable bindings.

Functions

Appends a path to the end of the Erlang VM code path list.

Returns a list with all available compiler options.

Returns true if the current process can await for module compilation.

Compiles the given file.

Compiles the quoted expression.

Compiles the given string.

Gets all compilation options from the code server.

Stores all given compilation options.

Receives a string and returns the cursor context.

Deletes a path from the Erlang VM code path list. This is the list of directories the Erlang VM uses for finding module code.

Similar to ensure_compiled!/1 but indicates you can continue without said module.

Ensures the given module is compiled and loaded.

Ensures the given module is loaded.

Same as ensure_loaded/1 but raises if the module cannot be loaded.

Ensures the given module is loaded.

Evals the given file.

Evaluates the quoted contents.

Evaluates the contents given by string.

Returns the docs for the given module or path to .beam file.

Formats the given code string.

Returns the value of a given compiler option.

Deprecated function to retrieve old documentation format.

Prepends a path to the beginning of the Erlang VM code path list.

Purge compiler modules.

Stores a compilation option.

Requires the given file.

Lists all required files.

Converts the given string to its quoted form.

Converts the given string to its quoted form.

Removes files from the required files list.

Link to this section Types

@type binding() :: [{atom() | tuple(), any()}]

A list with all variable bindings.

The binding keys are usually atoms, but they may be a tuple for variables defined in a different context.

Link to this section Functions

@spec append_path(Path.t()) :: true | {:error, :bad_directory}

Appends a path to the end of the Erlang VM code path list.

This is the list of directories the Erlang VM uses for finding module code.

The path is expanded with Path.expand/1 before being appended. If this path does not exist, an error is returned.

Examples

Code.append_path(".")
#=> true

Code.append_path("/does_not_exist")
#=> {:error, :bad_directory}
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available_compiler_options()

View Source
@spec available_compiler_options() :: [atom()]

Returns a list with all available compiler options.

For a description of all options, see put_compiler_option/2.

Examples

Code.available_compiler_options()
#=> [:docs, :debug_info, ...]
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can_await_module_compilation?()

View Source (since 1.11.0)
@spec can_await_module_compilation?() :: boolean()

Returns true if the current process can await for module compilation.

When compiling Elixir code via Kernel.ParallelCompiler, which is used by Mix and elixirc, calling a module that has not yet been compiled will block the caller until the module becomes available. Executing Elixir scripts, such as passing a filename to elixir, does not await.

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compile_file(file, relative_to \\ nil)

View Source (since 1.7.0)
@spec compile_file(binary(), nil | binary()) :: [{module(), binary()}]

Compiles the given file.

Accepts relative_to as an argument to tell where the file is located.

Returns a list of tuples where the first element is the module name and the second one is its bytecode (as a binary). Opposite to require_file/2, it does not track the filename of the compiled file.

If you would like to get the result of evaluating file rather than the modules defined in it, see eval_file/2.

For compiling many files concurrently, see Kernel.ParallelCompiler.compile/2.

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compile_quoted(quoted, file \\ "nofile")

View Source
@spec compile_quoted(Macro.t(), binary()) :: [{module(), binary()}]

Compiles the quoted expression.

Returns a list of tuples where the first element is the module name and the second one is its bytecode (as a binary). A file can be given as second argument which will be used for reporting warnings and errors.

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compile_string(string, file \\ "nofile")

View Source
@spec compile_string(List.Chars.t(), binary()) :: [{module(), binary()}]

Compiles the given string.

Returns a list of tuples where the first element is the module name and the second one is its bytecode (as a binary). A file can be given as second argument which will be used for reporting warnings and errors.

Warning: string can be any Elixir code and code can be executed with the same privileges as the Erlang VM: this means that such code could compromise the machine (for example by executing system commands). Don't use compile_string/2 with untrusted input (such as strings coming from the network).

@spec compiler_options() :: map()

Gets all compilation options from the code server.

To get individual options, see get_compiler_option/1. For a description of all options, see put_compiler_option/2.

Examples

Code.compiler_options()
#=> %{debug_info: true, docs: true, ...}
@spec compiler_options(Enumerable.t()) :: %{optional(atom()) => boolean()}

Stores all given compilation options.

To store individual options, see put_compiler_option/2. For a description of all options, see put_compiler_option/2.

Examples

Code.compiler_options()
#=> %{debug_info: true, docs: true, ...}
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cursor_context(string, opts \\ [])

View Source (since 1.12.0)
@spec cursor_context(List.Chars.t(), keyword()) ::
  {:alias, charlist()}
  | {:dot, inside_dot, charlist()}
  | {:dot_arity, inside_dot, charlist()}
  | {:dot_call, inside_dot, charlist()}
  | :expr
  | {:local_or_var, charlist()}
  | {:local_arity, charlist()}
  | {:local_call, charlist()}
  | {:module_attribute, charlist()}
  | :none
  | {:unquoted_atom, charlist()}
when inside_dot:
       {:alias, charlist()}
       | {:dot, inside_dot, charlist()}
       | {:module_attribute, charlist()}
       | {:unquoted_atom, charlist()}
       | {:var, charlist()}

Receives a string and returns the cursor context.

This function receives a string with incomplete Elixir code, representing a cursor position, and based on the string, it provides contextual information about said position. The return of this function can then be used to provide tips, suggestions, and autocompletion functionality.

This function provides a best-effort detection and may not be accurate under certain circumstances. See the "Limitations" section below.

Consider adding a catch-all clause when handling the return type of this function as new cursor information may be added in future releases.

Examples

iex> Code.cursor_context("")
:expr

iex> Code.cursor_context("hello_wor")
{:local_or_var, 'hello_wor'}

Return values

  • {:alias, charlist} - the context is an alias, potentially a nested one, such as Hello.Wor or HelloWor

  • {:dot, inside_dot, charlist} - the context is a dot where inside_dot is either a {:var, charlist}, {:alias, charlist}, {:module_attribute, charlist}, {:unquoted_atom, charlist} or a dot itself. If a var is given, this may either be a remote call or a map field access. Examples are Hello.wor, :hello.wor, hello.wor, Hello.nested.wor, hello.nested.wor, and @hello.world

  • {:dot_arity, inside_dot, charlist} - the context is a dot arity where inside_dot is either a {:var, charlist}, {:alias, charlist}, {:module_attribute, charlist}, {:unquoted_atom, charlist} or a dot itself. If a var is given, it must be a remote arity. Examples are Hello.world/, :hello.world/, hello.world/2, and @hello.world/2

  • {:dot_call, inside_dot, charlist} - the context is a dot call. This means parentheses or space have been added after the expression. where inside_dot is either a {:var, charlist}, {:alias, charlist}, {:module_attribute, charlist}, {:unquoted_atom, charlist} or a dot itself. If a var is given, it must be a remote call. Examples are Hello.world(, :hello.world(, Hello.world, hello.world(, hello.world, and @hello.world(

  • :expr - may be any expression. Autocompletion may suggest an alias, local or var

  • {:local_or_var, charlist} - the context is a variable or a local (import or local) call, such as hello_wor

  • {:local_arity, charlist} - the context is a local (import or local) call, such as hello_world/

  • {:local_call, charlist} - the context is a local (import or local) call, such as hello_world( and hello_world

  • {:module_attribute, charlist} - the context is a module attribute, such as @hello_wor

  • :none - no context possible

  • :unquoted_atom - the context is an unquoted atom. This can be either previous atoms or all available :erlang modules

Limitations

  • There is no context for operators
  • The current algorithm only considers the last line of the input
  • Context does not yet track strings, sigils, etc.
  • Arguments of functions calls are not currently recognized
@spec delete_path(Path.t()) :: boolean()

Deletes a path from the Erlang VM code path list. This is the list of directories the Erlang VM uses for finding module code.

The path is expanded with Path.expand/1 before being deleted. If the path does not exist, this function returns false.

Examples

Code.prepend_path(".")
Code.delete_path(".")
#=> true

Code.delete_path("/does_not_exist")
#=> false
@spec ensure_compiled(module()) ::
  {:module, module()}
  | {:error, :embedded | :badfile | :nofile | :on_load_failure | :unavailable}

Similar to ensure_compiled!/1 but indicates you can continue without said module.

While ensure_compiled!/1 indicates to the Elixir compiler you can only continue when said module is available, this function indicates you may continue compilation without said module.

If it succeeds in loading the module, it returns {:module, module}. If not, returns {:error, reason} with the error reason. If the module being checked is currently in a compiler deadlock, this function returns {:error, :unavailable}. Unavailable doesn't necessarily mean the module doesn't exist, just that it is not currently available, but it (or may not) become available in the future.

Therefore, if you can only continue if the module is available, use ensure_compiled!/1 instead. In particular, do not do this:

case Code.ensure_compiled(module) do
  {:module, _} -> module
  {:error, _} -> raise ...
end

See the module documentation for more information on code loading.

Link to this function

ensure_compiled!(module)

View Source (since 1.12.0)
@spec ensure_compiled!(module()) :: module()

Ensures the given module is compiled and loaded.

If the module is already loaded, it works as no-op. If the module was not compiled yet, ensure_compiled!/1 halts the compilation of the caller until the module given to ensure_compiled!/1 becomes available or all files for the current project have been compiled. If compilation finishes and the module is not available or is in a deadlock, an error is raised.

Given this function halts compilation, use it carefully. In particular, avoid using it to guess which modules are in the system. Overuse of this function can also lead to deadlocks, where two modules check at the same time if the other is compiled. This returns a specific unavailable error code, where we cannot successfully verify a module is available or not.

See the module documentation for more information on code loading.

@spec ensure_loaded(module()) ::
  {:module, module()}
  | {:error, :embedded | :badfile | :nofile | :on_load_failure}

Ensures the given module is loaded.

If the module is already loaded, this works as no-op. If the module was not yet loaded, it tries to load it.

If it succeeds in loading the module, it returns {:module, module}. If not, returns {:error, reason} with the error reason.

See the module documentation for more information on code loading.

Examples

iex> Code.ensure_loaded(Atom)
{:module, Atom}

iex> Code.ensure_loaded(DoesNotExist)
{:error, :nofile}
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ensure_loaded!(module)

View Source (since 1.12.0)
@spec ensure_loaded!(module()) :: module()

Same as ensure_loaded/1 but raises if the module cannot be loaded.

@spec ensure_loaded?(module()) :: boolean()

Ensures the given module is loaded.

Similar to ensure_loaded/1, but returns true if the module is already loaded or was successfully loaded. Returns false otherwise.

Examples

iex> Code.ensure_loaded?(Atom)
true
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eval_file(file, relative_to \\ nil)

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@spec eval_file(binary(), nil | binary()) :: {term(), binding()}

Evals the given file.

Accepts relative_to as an argument to tell where the file is located.

While require_file/2 and compile_file/2 return the loaded modules and their bytecode, eval_file/2 simply evaluates the file contents and returns the evaluation result and its binding (exactly the same return value as eval_string/3).

Link to this function

eval_quoted(quoted, binding \\ [], opts \\ [])

View Source
@spec eval_quoted(Macro.t(), binding(), Macro.Env.t() | keyword()) ::
  {term(), binding()}

Evaluates the quoted contents.

Warning: Calling this function inside a macro is considered bad practice as it will attempt to evaluate runtime values at compile time. Macro arguments are typically transformed by unquoting them into the returned quoted expressions (instead of evaluated).

See eval_string/3 for a description of binding and options.

Examples

iex> contents = quote(do: var!(a) + var!(b))
iex> {result, binding} = Code.eval_quoted(contents, [a: 1, b: 2], file: __ENV__.file, line: __ENV__.line)
iex> result
3
iex> Enum.sort(binding)
[a: 1, b: 2]

For convenience, you can pass __ENV__/0 as the opts argument and all options will be automatically extracted from the current environment:

iex> contents = quote(do: var!(a) + var!(b))
iex> {result, binding} = Code.eval_quoted(contents, [a: 1, b: 2], __ENV__)
iex> result
3
iex> Enum.sort(binding)
[a: 1, b: 2]
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eval_string(string, binding \\ [], opts \\ [])

View Source
@spec eval_string(List.Chars.t(), binding(), Macro.Env.t() | keyword()) ::
  {term(), binding()}

Evaluates the contents given by string.

The binding argument is a list of variable bindings. The opts argument is a keyword list of environment options.

Warning: string can be any Elixir code and will be executed with the same privileges as the Erlang VM: this means that such code could compromise the machine (for example by executing system commands). Don't use eval_string/3 with untrusted input (such as strings coming from the network).

Options

Options can be:

  • :file - the file to be considered in the evaluation

  • :line - the line on which the script starts

Additionally, the following scope values can be configured:

  • :aliases - a list of tuples with the alias and its target

  • :requires - a list of modules required

  • :functions - a list of tuples where the first element is a module and the second a list of imported function names and arity; the list of function names and arity must be sorted

  • :macros - a list of tuples where the first element is a module and the second a list of imported macro names and arity; the list of function names and arity must be sorted

Note that setting any of the values above overrides Elixir's default values. For example, setting :requires to [] will no longer automatically require the Kernel module. In the same way setting :macros will no longer auto-import Kernel macros like Kernel.if/2, Kernel.SpecialForms.case/2, and so on.

Returns a tuple of the form {value, binding}, where value is the value returned from evaluating string. If an error occurs while evaluating string an exception will be raised.

binding is a list with all variable bindings after evaluating string. The binding keys are usually atoms, but they may be a tuple for variables defined in a different context.

Examples

iex> {result, binding} = Code.eval_string("a + b", [a: 1, b: 2], file: __ENV__.file, line: __ENV__.line)
iex> result
3
iex> Enum.sort(binding)
[a: 1, b: 2]

iex> {result, binding} = Code.eval_string("c = a + b", [a: 1, b: 2], __ENV__)
iex> result
3
iex> Enum.sort(binding)
[a: 1, b: 2, c: 3]

iex> {result, binding} = Code.eval_string("a = a + b", [a: 1, b: 2])
iex> result
3
iex> Enum.sort(binding)
[a: 3, b: 2]

For convenience, you can pass __ENV__/0 as the opts argument and all imports, requires and aliases defined in the current environment will be automatically carried over:

iex> {result, binding} = Code.eval_string("a + b", [a: 1, b: 2], __ENV__)
iex> result
3
iex> Enum.sort(binding)
[a: 1, b: 2]
Link to this function

fetch_docs(module_or_path)

View Source (since 1.7.0)
@spec fetch_docs(module() | String.t()) ::
  {:docs_v1, annotation, beam_language, format, module_doc :: doc_content,
   metadata, docs :: [doc_element]}
  | {:error, :module_not_found | :chunk_not_found | {:invalid_chunk, binary()}}
when annotation: :erl_anno.anno(),
     beam_language: :elixir | :erlang | atom(),
     doc_content: %{optional(binary()) => binary()} | :none | :hidden,
     doc_element:
       {{kind :: atom(), function_name :: atom(), arity()}, annotation,
        signature, doc_content, metadata},
     format: binary(),
     signature: [binary()],
     metadata: map()

Returns the docs for the given module or path to .beam file.

When given a module name, it finds its BEAM code and reads the docs from it.

When given a path to a .beam file, it will load the docs directly from that file.

It returns the term stored in the documentation chunk in the format defined by EEP 48 or {:error, reason} if the chunk is not available.

Examples

# Module documentation of an existing module
iex> {:docs_v1, _, :elixir, _, %{"en" => module_doc}, _, _} = Code.fetch_docs(Atom)
iex> module_doc |> String.split("\n") |> Enum.at(0)
"Atoms are constants whose values are their own name."

# A module that doesn't exist
iex> Code.fetch_docs(ModuleNotGood)
{:error, :module_not_found}
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format_file!(file, opts \\ [])

View Source (since 1.6.0)
@spec format_file!(binary(), keyword()) :: iodata()

Formats a file.

See format_string!/2 for more information on code formatting and available options.

Link to this function

format_string!(string, opts \\ [])

View Source (since 1.6.0)
@spec format_string!(binary(), keyword()) :: iodata()

Formats the given code string.

The formatter receives a string representing Elixir code and returns iodata representing the formatted code according to pre-defined rules.

Options

  • :file - the file which contains the string, used for error reporting

  • :line - the line the string starts, used for error reporting

  • :line_length - the line length to aim for when formatting the document. Defaults to 98. Note this value is used as guideline but there are situations where it is not enforced. See the "Line length" section below for more information

  • :locals_without_parens - a keyword list of name and arity pairs that should be kept without parens whenever possible. The arity may be the atom :*, which implies all arities of that name. The formatter already includes a list of functions and this option augments this list.

  • :force_do_end_blocks (since v1.9.0) - when true, converts all inline usages of do: ..., else: ... and friends into do/end blocks. Defaults to false. Note that this option is convergent: once you set it to true, all keywords will be converted. If you set it to false later on, do/end blocks won't be converted back to keywords.

Design principles

The formatter was designed under three principles.

First, the formatter never changes the semantics of the code by default. This means the input AST and the output AST are equivalent.

The second principle is to provide as little configuration as possible. This eases the formatter adoption by removing contention points while making sure a single style is followed consistently by the community as a whole.

The formatter does not hard code names. The formatter will not behave specially because a function is named defmodule, def, or the like. This principle mirrors Elixir's goal of being an extensible language where developers can extend the language with new constructs as if they were part of the language. When it is absolutely necessary to change behaviour based on the name, this behaviour should be configurable, such as the :locals_without_parens option.

Running the formatter

The formatter attempts to fit the most it can on a single line and introduces line breaks wherever possible when it cannot.

In some cases, this may lead to undesired formatting. Therefore, some code generated by the formatter may not be aesthetically pleasing and may require explicit intervention from the developer. That's why we do not recommend to run the formatter blindly in an existing codebase. Instead you should format and sanity check each formatted file.

For example, the formatter may break a long function definition over multiple clauses:

def my_function(
  %User{name: name, age: age, ...},
  arg1,
  arg2
) do
  ...
end

While the code above is completely valid, you may prefer to match on the struct variables inside the function body in order to keep the definition on a single line:

def my_function(%User{} = user, arg1, arg2) do
  %{name: name, age: age, ...} = user
  ...
end

In some situations, you can use the fact the formatter does not generate elegant code as a hint for refactoring. Take this code:

def board?(board_id, %User{} = user, available_permissions, required_permissions) do
  Tracker.OrganizationMembers.user_in_organization?(user.id, board.organization_id) and
    required_permissions == Enum.to_list(MapSet.intersection(MapSet.new(required_permissions), MapSet.new(available_permissions)))
end

The code above has very long lines and running the formatter is not going to address this issue. In fact, the formatter may make it more obvious that you have complex expressions:

def board?(board_id, %User{} = user, available_permissions, required_permissions) do
  Tracker.OrganizationMembers.user_in_organization?(user.id, board.organization_id) and
    required_permissions ==
      Enum.to_list(
        MapSet.intersection(
          MapSet.new(required_permissions),
          MapSet.new(available_permissions)
        )
      )
end

Take such cases as a suggestion that your code should be refactored:

def board?(board_id, %User{} = user, available_permissions, required_permissions) do
  Tracker.OrganizationMembers.user_in_organization?(user.id, board.organization_id) and
    matching_permissions?(required_permissions, available_permissions)
end

defp matching_permissions?(required_permissions, available_permissions) do
  intersection =
    required_permissions
    |> MapSet.new()
    |> MapSet.intersection(MapSet.new(available_permissions))
    |> Enum.to_list()

  required_permissions == intersection
end

To sum it up: since the formatter cannot change the semantics of your code, sometimes it is necessary to tweak or refactor the code to get optimal formatting. To help better understand how to control the formatter, we describe in the next sections the cases where the formatter keeps the user encoding and how to control multiline expressions.

Line length

Another point about the formatter is that the :line_length configuration is a guideline. In many cases, it is not possible for the formatter to break your code apart, which means it will go over the line length. For example, if you have a long string:

"this is a very long string that will go over the line length"

The formatter doesn't know how to break it apart without changing the code underlying syntax representation, so it is up to you to step in:

"this is a very long string " <>
   "that will go over the line length"

The string concatenation makes the code fit on a single line and also gives more options to the formatter.

This may also appear in do/end blocks, where the do keyword (or ->) may go over the line lenth because there is no opportunity for the formatter to introduce a line break in a readable way. For example, if you do:

case very_long_expression() do

And only the do keyword is above the line length, Elixir will not emit this:

case very_long_expression()
do

So it prefers to not touch the line at all and leave do above the line limit.

Keeping user's formatting

The formatter respects the input format in some cases. Those are listed below:

  • Insignificant digits in numbers are kept as is. The formatter however always inserts underscores for decimal numbers with more than 5 digits and converts hexadecimal digits to uppercase

  • Strings, charlists, atoms and sigils are kept as is. No character is automatically escaped or unescaped. The choice of delimiter is also respected from the input

  • Newlines inside blocks are kept as in the input except for:

    1. expressions that take multiple lines will always have an empty line before and after and 2) empty lines are always squeezed together into a single empty line
  • The choice between :do keyword and do/end blocks is left to the user

  • Lists, tuples, bitstrings, maps, structs and function calls will be broken into multiple lines if they are followed by a newline in the opening bracket and preceded by a new line in the closing bracket

  • Newlines before certain operators (such as the pipeline operators) and before other operators (such as comparison operators)

The behaviours above are not guaranteed. We may remove or add new rules in the future. The goal of documenting them is to provide better understanding on what to expect from the formatter.

Multi-line lists, maps, tuples, and the like

You can force lists, tuples, bitstrings, maps, structs and function calls to have one entry per line by adding a newline after the opening bracket and a new line before the closing bracket lines. For example:

[
  foo,
  bar
]

If there are no newlines around the brackets, then the formatter will try to fit everything on a single line, such that the snippet below

[foo,
 bar]

will be formatted as

[foo, bar]

You can also force function calls and keywords to be rendered on multiple lines by having each entry on its own line:

defstruct name: nil,
          age: 0

The code above will be kept with one keyword entry per line by the formatter. To avoid that, just squash everything into a single line.

Parens and no parens in function calls

Elixir has two syntaxes for function calls. With parens and no parens. By default, Elixir will add parens to all calls except for:

  1. calls that have do/end blocks
  2. local calls without parens where the name and arity of the local call is also listed under :locals_without_parens (except for calls with arity 0, where the compiler always require parens)

The choice of parens and no parens also affects indentation. When a function call with parens doesn't fit on the same line, the formatter introduces a newline around parens and indents the arguments with two spaces:

some_call(
  arg1,
  arg2,
  arg3
)

On the other hand, function calls without parens are always indented by the function call length itself, like this:

some_call arg1,
          arg2,
          arg3

If the last argument is a data structure, such as maps and lists, and the beginning of the data structure fits on the same line as the function call, then no indentation happens, this allows code like this:

Enum.reduce(some_collection, initial_value, fn element, acc ->
  # code
end)

some_function_without_parens %{
  foo: :bar,
  baz: :bat
}

Code comments

The formatter also handles code comments in a way to guarantee a space is always added between the beginning of the comment (#) and the next character.

The formatter also extracts all trailing comments to their previous line. For example, the code below

hello #world

will be rewritten to

# world
hello

Because code comments are handled apart from the code representation (AST), there are some situations where code comments are seen as ambiguous by the code formatter. For example, the comment in the anonymous function below

fn
  arg1 ->
    body1
    # comment

  arg2 ->
    body2
end

and in this one

fn
  arg1 ->
    body1

  # comment
  arg2 ->
    body2
end

are considered equivalent (the nesting is discarded alongside most of user formatting). In such cases, the code formatter will always format to the latter.

Newlines

The formatter converts all newlines in code from \r\n to \n.

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get_compiler_option(key)

View Source (since 1.10.0)
@spec get_compiler_option(atom()) :: term()

Returns the value of a given compiler option.

For a description of all options, see put_compiler_option/2.

Examples

Code.get_compiler_option(:debug_info)
#=> true
This function is deprecated. Code.get_docs/2 always returns nil as its outdated documentation is no longer stored on BEAM files. Use Code.fetch_docs/1 instead.
@spec get_docs(module(), :moduledoc | :docs | :callback_docs | :type_docs | :all) ::
  nil

Deprecated function to retrieve old documentation format.

Elixir v1.7 adopts EEP 48 which is a new documentation format meant to be shared across all BEAM languages. The old format, used by Code.get_docs/2, is no longer available, and therefore this function always returns nil. Use Code.fetch_docs/1 instead.

@spec prepend_path(Path.t()) :: true | {:error, :bad_directory}

Prepends a path to the beginning of the Erlang VM code path list.

This is the list of directories the Erlang VM uses for finding module code.

The path is expanded with Path.expand/1 before being prepended. If this path does not exist, an error is returned.

Examples

Code.prepend_path(".")
#=> true

Code.prepend_path("/does_not_exist")
#=> {:error, :bad_directory}
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purge_compiler_modules()

View Source (since 1.7.0)
@spec purge_compiler_modules() :: {:ok, non_neg_integer()}

Purge compiler modules.

The compiler utilizes temporary modules to compile code. For example, elixir_compiler_1, elixir_compiler_2, and so on. In case the compiled code stores references to anonymous functions or similar, the Elixir compiler may be unable to reclaim those modules, keeping an unnecessary amount of code in memory and eventually leading to modules such as elixir_compiler_12345.

This function purges all modules currently kept by the compiler, allowing old compiler module names to be reused. If there are any processes running any code from such modules, they will be terminated too.

It returns {:ok, number_of_modules_purged}.

Link to this function

put_compiler_option(key, value)

View Source (since 1.10.0)
@spec put_compiler_option(atom(), term()) :: :ok

Stores a compilation option.

These options are global since they are stored by Elixir's code server.

Available options are:

  • :docs - when true, retain documentation in the compiled module. Defaults to true.

  • :debug_info - when true, retain debug information in the compiled module. This allows a developer to reconstruct the original source code. Defaults to true.

  • :ignore_module_conflict - when true, override modules that were already defined without raising errors. Defaults to false.

  • :relative_paths - when true, use relative paths in quoted nodes, warnings and errors generated by the compiler. Note disabling this option won't affect runtime warnings and errors. Defaults to true.

  • :warnings_as_errors - causes compilation to fail when warnings are generated. Defaults to false.

  • :no_warn_undefined (since v1.10.0) - list of modules and {Mod, fun, arity} tuples that will not emit warnings that the module or function does not exist at compilation time. Pass atom :all to skip warning for all undefined functions. This can be useful when doing dynamic compilation. Defaults to [].

  • :tracers (since v1.10.0) - a list of tracers (modules) to be used during compilation. See the module docs for more information. Defaults to [].

  • :parser_options (since v1.10.0) - a keyword list of options to be given to the parser when compiling files. It accepts the same options as string_to_quoted/2 (except by the options that change the AST itself). This can be used in combination with the tracer to retrieve localized information about events happening during compilation. Defaults to [].

It always returns :ok. Raises an error for invalid options.

Examples

Code.put_compiler_option(:debug_info, true)
#=> :ok
Link to this function

require_file(file, relative_to \\ nil)

View Source
@spec require_file(binary(), nil | binary()) :: [{module(), binary()}] | nil

Requires the given file.

Accepts relative_to as an argument to tell where the file is located. If the file was already required, require_file/2 doesn't do anything and returns nil.

Note that if require_file/2 is invoked by different processes concurrently, the first process to invoke require_file/2 acquires a lock and the remaining ones will block until the file is available. This means that if require_file/2 is called more than once with a given file, that file will be compiled only once. The first process to call require_file/2 will get the list of loaded modules, others will get nil.

See compile_file/2 if you would like to compile a file without tracking its filenames. Finally, if you would like to get the result of evaluating a file rather than the modules defined in it, see eval_file/2.

Examples

If the file has not been required, it returns the list of modules:

modules = Code.require_file("eex_test.exs", "../eex/test")
List.first(modules)
#=> {EExTest.Compiled, <<70, 79, 82, 49, ...>>}

If the file has been required, it returns nil:

Code.require_file("eex_test.exs", "../eex/test")
#=> nil
Link to this function

required_files()

View Source (since 1.7.0)
@spec required_files() :: [binary()]

Lists all required files.

Examples

Code.require_file("../eex/test/eex_test.exs")
List.first(Code.required_files()) =~ "eex_test.exs"
#=> true
Link to this function

string_to_quoted(string, opts \\ [])

View Source
@spec string_to_quoted(List.Chars.t(), keyword()) ::
  {:ok, Macro.t()} | {:error, {location :: keyword(), term(), term()}}

Converts the given string to its quoted form.

Returns {:ok, quoted_form} if it succeeds, {:error, {line, error, token}} otherwise.

Options

  • :file - the filename to be reported in case of parsing errors. Defaults to "nofile".

  • :line - the starting line of the string being parsed. Defaults to 1.

  • :column - (since v1.11.0) the starting column of the string being parsed. Defaults to 1.

  • :columns - when true, attach a :column key to the quoted metadata. Defaults to false.

  • :existing_atoms_only - when true, raises an error when non-existing atoms are found by the tokenizer. Defaults to false.

  • :token_metadata (since v1.10.0) - when true, includes token-related metadata in the expression AST, such as metadata for do and end tokens, for closing tokens, end of expressions, as well as delimiters for sigils. See Macro.metadata/0. Defaults to false.

  • :literal_encoder (since v1.10.0) - how to encode literals in the AST. It must be a function that receives two arguments, the literal and its metadata, and it must return {:ok, ast :: Macro.t} or {:error, reason :: binary}. If you return anything than the literal itself as the term, then the AST is no longer valid. This option may still useful for textual analysis of the source code.

  • :static_atoms_encoder - the static atom encoder function, see "The :static_atoms_encoder function" section below. Note this option overrides the :existing_atoms_only behaviour for static atoms but :existing_atoms_only is still used for dynamic atoms, such as atoms with interpolations.

  • :warn_on_unnecessary_quotes - when false, does not warn when atoms, keywords or calls have unnecessary quotes on them. Defaults to true.

Macro.to_string/2

The opposite of converting a string to its quoted form is Macro.to_string/2, which converts a quoted form to a string/binary representation.

The :static_atoms_encoder function

When static_atoms_encoder: &my_encoder/2 is passed as an argument, my_encoder/2 is called every time the tokenizer needs to create a "static" atom. Static atoms are atoms in the AST that function as aliases, remote calls, local calls, variable names, regular atoms and keyword lists.

The encoder function will receive the atom name (as a binary) and a keyword list with the current file, line and column. It must return {:ok, token :: term} | {:error, reason :: binary}.

The encoder function is supposed to create an atom from the given string. To produce a valid AST, it is required to return {:ok, term}, where term is an atom. It is possible to return something other than an atom, however, in that case the AST is no longer "valid" in that it cannot be used to compile or evaluate Elixir code. A use case for this is if you want to use the Elixir parser in a user-facing situation, but you don't want to exhaust the atom table.

The atom encoder is not called for all atoms that are present in the AST. It won't be invoked for the following atoms:

  • operators (:+, :-, and so on)

  • syntax keywords (fn, do, else, and so on)

  • atoms containing interpolation (:"#{1 + 1} is two"), as these atoms are constructed at runtime.

Link to this function

string_to_quoted!(string, opts \\ [])

View Source
@spec string_to_quoted!(List.Chars.t(), keyword()) :: Macro.t()

Converts the given string to its quoted form.

It returns the ast if it succeeds, raises an exception otherwise. The exception is a TokenMissingError in case a token is missing (usually because the expression is incomplete), SyntaxError otherwise.

Check string_to_quoted/2 for options information.

Link to this function

unrequire_files(files)

View Source (since 1.7.0)
@spec unrequire_files([binary()]) :: :ok

Removes files from the required files list.

The modules defined in the file are not removed; calling this function only removes them from the list, allowing them to be required again.

Examples

# Require EEx test code
Code.require_file("../eex/test/eex_test.exs")

# Now unrequire all files
Code.unrequire_files(Code.required_files())

# Note that modules are still available
function_exported?(EExTest.Compiled, :before_compile, 0)
#=> true