10  Preprocessor

10 Preprocessor

A file can be included as follows:

-include(File).
-include_lib(File).

File, a string, is to point out a file. The contents of this file are included as is, at the position of the directive.

Include files are typically used for record and macro definitions that are shared by several modules. It is recommended to use the file name extension .hrl for include files.

File can start with a path component $VAR, for some string VAR. If that is the case, the value of the environment variable VAR as returned by os:getenv(VAR) is substituted for $VAR. If os:getenv(VAR) returns false, $VAR is left as is.

If the filename File is absolute (possibly after variable substitution), the include file with that name is included. Otherwise, the specified file is searched for in the following directories, and in this order:

  1. The current working directory
  2. The directory where the module is being compiled
  3. The directories given by the include option

For details, see the erlc(1) manual page in ERTS and compile(3) manual page in Compiler.

Examples:

-include("my_records.hrl").
-include("incdir/my_records.hrl").
-include("/home/user/proj/my_records.hrl").
-include("$PROJ_ROOT/my_records.hrl").

include_lib is similar to include, but is not to point out an absolute file. Instead, the first path component (possibly after variable substitution) is assumed to be the name of an application.

Example:

-include_lib("kernel/include/file.hrl").

The code server uses code:lib_dir(kernel) to find the directory of the current (latest) version of Kernel, and then the subdirectory include is searched for the file file.hrl.

A macro is defined as follows:

-define(Const, Replacement).
-define(Func(Var1,...,VarN), Replacement).

A macro definition can be placed anywhere among the attributes and function declarations of a module, but the definition must come before any usage of the macro.

If a macro is used in several modules, it is recommended that the macro definition is placed in an include file.

A macro is used as follows:

?Const
?Func(Arg1,...,ArgN)

Macros are expanded during compilation. A simple macro ?Const is replaced with Replacement.

Example:

-define(TIMEOUT, 200).
...
call(Request) ->
    server:call(refserver, Request, ?TIMEOUT).

This is expanded to:

call(Request) ->
    server:call(refserver, Request, 200).

A macro ?Func(Arg1,...,ArgN) is replaced with Replacement, where all occurrences of a variable Var from the macro definition are replaced with the corresponding argument Arg.

Example:

-define(MACRO1(X, Y), {a, X, b, Y}).
...
bar(X) ->
    ?MACRO1(a, b),
    ?MACRO1(X, 123)

This is expanded to:

bar(X) ->
    {a,a,b,b},
    {a,X,b,123}.

It is good programming practice, but not mandatory, to ensure that a macro definition is a valid Erlang syntactic form.

To view the result of macro expansion, a module can be compiled with the 'P' option. compile:file(File, ['P']). This produces a listing of the parsed code after preprocessing and parse transforms, in the file File.P.

The following macros are predefined:

The name of the current module.
The name of the current module, as a string.
The file name of the current module.
The current line number.
The machine name, 'BEAM'.
The name of the current function.
The arity (number of arguments) for the current function.
The OTP release that the currently executing ERTS application is part of, as an integer. For details, see erlang:system_info(otp_release).
Change

The ?OTP_RELEASE macro was introduced in Erlang/OTP 21.

Expands to true if the feature Feature is available. The feature might or might not be enabled.
Change

The ?FEATURE_AVAILABLE() macro was introduced in Erlang/OTP 25.

Expands to true if the feature Feature is enabled.
Change

The ?FEATURE_ENABLED() macro was introduced in Erlang/OTP 25.

It is possible to overload macros, except for predefined macros. An overloaded macro has more than one definition, each with a different number of arguments.

Change

Support for overloading of macros was added in Erlang 5.7.5/OTP R13B04.

A macro ?Func(Arg1,...,ArgN) with a (possibly empty) list of arguments results in an error message if there is at least one definition of Func with arguments, but none with N arguments.

Assuming these definitions:

-define(F0(), c).
-define(F1(A), A).
-define(C, m:f).

the following does not work:

f0() ->
    ?F0. % No, an empty list of arguments expected.

f1(A) ->
    ?F1(A, A). % No, exactly one argument expected.

On the other hand,

f() ->
    ?C().

is expanded to

f() ->
    m:f().

The following macro directives are supplied:

Causes the macro to behave as if it had never been defined.
Evaluate the following lines only if Macro is defined.
Evaluate the following lines only if Macro is not defined.
Only allowed after an ifdef or ifndef directive. If that condition is false, the lines following else are evaluated instead.
Specifies the end of an ifdef, an ifndef directive, or the end of an if or elif directive.
Evaluates the following lines only if Condition evaluates to true.
Only allowed after an if or another elif directive. If the preceding if or elif directives do not evaluate to true, and the Condition evaluates to true, the lines following the elif are evaluated instead.
Note

The macro directives cannot be used inside functions.

Example:

-module(m).
...

-ifdef(debug).
-define(LOG(X), io:format("{~p,~p}: ~p~n", [?MODULE,?LINE,X])).
-else.
-define(LOG(X), true).
-endif.

...

When trace output is desired, debug is to be defined when the module m is compiled:

% erlc -Ddebug m.erl

or

1> c(m, {d, debug}).
{ok,m}

?LOG(Arg) is then expanded to a call to io:format/2 and provide the user with some simple trace output.

Example:

-module(m)
...
-ifdef(OTP_RELEASE).
  %% OTP 21 or higher
  -if(?OTP_RELEASE >= 22).
    %% Code that will work in OTP 22 or higher
  -elif(?OTP_RELEASE >= 21).
    %% Code that will work in OTP 21 or higher
  -endif.
-else.
  %% OTP 20 or lower.
-endif.
...

The code uses the OTP_RELEASE macro to conditionally select code depending on release.

The directive -feature(FeatureName, enable | disable) can be used to enable or disable the feature FeatureName. This is the preferred way of enabling (disabling) features, although it is possible to do it with options to the compiler as well.

Note that the -feature(..) directive may only appear before any syntax is used. In practice this means it should appear before any -export(..) or record definitions.

The directive -error(Term) causes a compilation error.

Example:

-module(t).
-export([version/0]).

-ifdef(VERSION).
version() -> ?VERSION.
-else.
-error("Macro VERSION must be defined.").
version() -> "".
-endif.

The error message will look like this:

% erlc t.erl
t.erl:7: -error("Macro VERSION must be defined.").

The directive -warning(Term) causes a compilation warning.

Example:

-module(t).
-export([version/0]).

-ifndef(VERSION).
-warning("Macro VERSION not defined -- using default version.").
-define(VERSION, "0").
-endif.
version() -> ?VERSION.

The warning message will look like this:

% erlc t.erl
t.erl:5: Warning: -warning("Macro VERSION not defined -- using default version.").
Change

The -error() and -warning() directives were added in Erlang/OTP 19.

The construction ??Arg, where Arg is a macro argument, is expanded to a string containing the tokens of the argument. This is similar to the #arg stringifying construction in C.

Example:

-define(TESTCALL(Call), io:format("Call ~s: ~w~n", [??Call, Call])).

?TESTCALL(myfunction(1,2)),
?TESTCALL(you:function(2,1)).

results in

io:format("Call ~s: ~w~n",["myfunction ( 1 , 2 )",myfunction(1,2)]),
io:format("Call ~s: ~w~n",["you : function ( 2 , 1 )",you:function(2,1)]).

That is, a trace output, with both the function called and the resulting value.