compile

MODULE

compile

MODULE SUMMARY

Erlang Compiler

DESCRIPTION

This module provides an interface to the standard Erlang compiler. It can generate either a new file, which contains the object code, or return a binary, which can be loaded directly.

EXPORTS

env_compiler_options()

Return compiler options given via the environment variable ERL_COMPILER_OPTIONS. If the value is a list, it is returned as is. If it is not a list, it is put into a list.

file(File)

Is the same as file(File, [verbose,report_errors,report_warnings]).

file(File, Options) -> CompRet

Types:

CompRet = ModRet | BinRet | ErrRet
ModRet = {ok,ModuleName} | {ok,ModuleName,Warnings}
BinRet = {ok,ModuleName,Binary} | {ok,ModuleName,Binary,Warnings}
ErrRet = error | {error,Errors,Warnings}

Compiles the code in the file File, which is an Erlang source code file without the .erl extension. Options determine the behavior of the compiler.

Returns {ok,ModuleName} if successful, or error if there are errors. An object code file is created if the compilation succeeds without errors. It is considered to be an error if the module name in the source code is not the same as the basename of the output file.

Available options:

basic_validation

This option is a fast way to test whether a module will compile successfully. This is useful for code generators that want to verify the code that they emit. No code is generated. If warnings are enabled, warnings generated by the erl_lint module (such as warnings for unused variables and functions) are also returned.

Use option strong_validation to generate all warnings that the compiler would generate.

strong_validation

Similar to option basic_validation. No code is generated, but more compiler passes are run to ensure that warnings generated by the optimization passes are generated (such as clauses that will not match, or expressions that are guaranteed to fail with an exception at runtime).

binary

The compiler returns the object code in a binary instead of creating an object file. If successful, the compiler returns {ok,ModuleName,Binary}.

bin_opt_info

The compiler will emit informational warnings about binary matching optimizations (both successful and unsuccessful). For more information, see the section about bin_opt_info in the Efficiency Guide.

compressed

The compiler will compress the generated object code, which can be useful for embedded systems.

debug_info

Includes debug information in the form of abstract code (see The Abstract Format in ERTS User's Guide) in the compiled beam module. Tools such as Debugger, Xref, and Cover require the debug information to be included.

Warning: Source code can be reconstructed from the debug information. Use encrypted debug information (encrypt_debug_info) to prevent this.

For details, see beam_lib(3).

{debug_info_key,KeyString}
{debug_info_key,{Mode,KeyString}}

Includes debug information, but encrypts it so that it cannot be accessed without supplying the key. (To give option debug_info as well is allowed, but not necessary.) Using this option is a good way to always have the debug information available during testing, yet protecting the source code.

Mode is the type of crypto algorithm to be used for encrypting the debug information. The default (and currently the only) type is des3_cbc.

For details, see beam_lib(3).

encrypt_debug_info

Similar to the debug_info_key option, but the key is read from an .erlang.crypt file.

For details, see beam_lib(3).

makedep

Produces a Makefile rule to track headers dependencies. No object file is produced.

By default, this rule is written to <File>.Pbeam. However, if option binary is set, nothing is written and the rule is returned in Binary.

For example, if you have the following module:

-module(module).

-include_lib("eunit/include/eunit.hrl").
-include("header.hrl").

The Makefile rule generated by this option looks as follows:

module.beam: module.erl \
  /usr/local/lib/erlang/lib/eunit/include/eunit.hrl \
  header.hrl
{makedep_output, Output}

Writes generated rules to Output instead of the default <File>.Pbeam. Output can be a filename or an io_device(). To write to stdout, use standard_io. However, if binary is set, nothing is written to Output and the result is returned to the caller with {ok, ModuleName, Binary}.

{makedep_target, Target}

Changes the name of the rule emitted to Target.

makedep_quote_target

Characters in Target special to make(1) are quoted.

makedep_add_missing

Considers missing headers as generated files and adds them to the dependencies.

makedep_phony

Adds a phony target for each dependency.

'P'

Produces a listing of the parsed code, after preprocessing and parse transforms, in the file <File>.P. No object file is produced.

'E'

Produces a listing of the code, after all source code transformations have been performed, in the file <File>.E. No object file is produced.

'S'

Produces a listing of the assembler code in the file <File>.S. No object file is produced.

report_errors/report_warnings

Causes errors/warnings to be printed as they occur.

report

A short form for both report_errors and report_warnings.

return_errors

If this flag is set, {error,ErrorList,WarningList} is returned when there are errors.

return_warnings

If this flag is set, an extra field, containing WarningList, is added to the tuples returned on success.

warnings_as_errors

Causes warnings to be treated as errors. This option is supported since R13B04.

return

A short form for both return_errors and return_warnings.

verbose

Causes more verbose information from the compiler, describing what it is doing.

{source,FileName}

Sets the value of the source, as returned by module_info(compile).

{outdir,Dir}

Sets a new directory for the object code. The current directory is used for output, except when a directory has been specified with this option.

export_all

Causes all functions in the module to be exported.

{i,Dir}

Adds Dir to the list of directories to be searched when including a file. When encountering an -include or -include_lib directive, the compiler searches for header files in the following directories:

  • ".", the current working directory of the file server

  • The base name of the compiled file

  • The directories specified using option i; the directory specified last is searched first

{d,Macro}
{d,Macro,Value}

Defines a macro Macro to have the value Value. Macro is of type atom, and Value can be any term. The default Value is true.

{parse_transform,Module}

Causes the parse transformation function Module:parse_transform/2 to be applied to the parsed code before the code is checked for errors.

from_asm

The input file is expected to be assembler code (default file suffix ".S"). Notice that the format of assembler files is not documented, and can change between releases.

from_core

The input file is expected to be core code (default file suffix ".core"). Notice that the format of core files is not documented, and can change between releases.

no_strict_record_tests

This option is not recommended.

By default, the generated code for operation Record#record_tag.field verifies that the tuple Record has the correct size for the record, and that the first element is the tag record_tag. Use this option to omit the verification code.

no_error_module_mismatch

Normally the compiler verifies that the module name given in the source code is the same as the base name of the output file and refuses to generate an output file if there is a mismatch. If you have a good reason (or other reason) for having a module name unrelated to the name of the output file, this option disables that verification (there will not even be a warning if there is a mismatch).

{no_auto_import,[{F,A}, ...]}

Makes the function F/A no longer being auto-imported from the erlang module, which resolves BIF name clashes. This option must be used to resolve name clashes with BIFs auto-imported before R14A, if it is needed to call the local function with the same name as an auto-imported BIF without module prefix.

Note

As from R14A and forward, the compiler resolves calls without module prefix to local or imported functions before trying with auto-imported BIFs. If the BIF is to be called, use the erlang module prefix in the call, not { no_auto_import,[{F,A}, ...]}.

If this option is written in the source code, as a -compile directive, the syntax F/A can be used instead of {F,A}, for example:

-compile({no_auto_import,[error/1]}).
no_auto_import

Do not auto-import any functions from erlang module.

no_line_info

Omits line number information to produce a slightly smaller output file.

If warnings are turned on (option report_warnings described earlier), the following options control what type of warnings that are generated. Except from {warn_format,Verbosity}, the following options have two forms:

  • A warn_xxx form, to turn on the warning.
  • A nowarn_xxx form, to turn off the warning.

In the descriptions that follow, the form that is used to change the default value are listed.

{warn_format, Verbosity}

Causes warnings to be emitted for malformed format strings as arguments to io:format and similar functions.

Verbosity selects the number of warnings:

  • 0 = No warnings
  • 1 = Warnings for invalid format strings and incorrect number of arguments
  • 2 = Warnings also when the validity cannot be checked, for example, when the format string argument is a variable.

The default verbosity is 1. Verbosity 0 can also be selected by option nowarn_format.

nowarn_bif_clash

This option is removed, it generates a fatal error if used.

Warning

As from beginning with R14A, the compiler no longer calls the auto-imported BIF if the name clashes with a local or explicitly imported function, and a call without explicit module name is issued. Instead, the local or imported function is called. Still accepting nowarn_bif_clash would make a module calling functions clashing with auto-imported BIFs compile with both the old and new compilers, but with completely different semantics. This is why the option is removed.

The use of this option has always been discouraged. As from R14A, it is an error to use it.

To resolve BIF clashes, use explicit module names or the {no_auto_import,[F/A]} compiler directive.

{nowarn_bif_clash, FAs}

This option is removed, it generates a fatal error if used.

Warning

The use of this option has always been discouraged. As from R14A, it is an error to use it.

To resolve BIF clashes, use explicit module names or the {no_auto_import,[F/A]} compiler directive.

warn_export_all

Emits a warning if option export_all is also given.

warn_export_vars

Emits warnings for all implicitly exported variables referred to after the primitives where they were first defined. By default, the compiler only emits warnings for exported variables referred to in a pattern.

nowarn_shadow_vars

Turns off warnings for "fresh" variables in functional objects or list comprehensions with the same name as some already defined variable. Default is to emit warnings for such variables.

nowarn_unused_function

Turns off warnings for unused local functions. Default is to emit warnings for all local functions that are not called directly or indirectly by an exported function. The compiler does not include unused local functions in the generated beam file, but the warning is still useful to keep the source code cleaner.

{nowarn_unused_function, FAs}

Turns off warnings for unused local functions like nowarn_unused_function does, but only for the mentioned local functions. FAs is a tuple {Name,Arity} or a list of such tuples.

nowarn_deprecated_function

Turns off warnings for calls to deprecated functions. Default is to emit warnings for every call to a function known by the compiler to be deprecated. Notice that the compiler does not know about attribute -deprecated(), but uses an assembled list of deprecated functions in Erlang/OTP. To do a more general check, the Xref tool can be used. See also xref(3) and the function xref:m/1, also accessible through the function c:xm/1.

{nowarn_deprecated_function, MFAs}

Turns off warnings for calls to deprecated functions like nowarn_deprecated_function does, but only for the mentioned functions. MFAs is a tuple {Module,Name,Arity} or a list of such tuples.

nowarn_deprecated_type

Turns off warnings for use of deprecated types. Default is to emit warnings for every use of a type known by the compiler to be deprecated.

warn_obsolete_guard

Emits warnings for calls to old type testing BIFs, such as pid/1 and list/1. See the Erlang Reference Manual for a complete list of type testing BIFs and their old equivalents. Default is to emit no warnings for calls to old type testing BIFs.

warn_unused_import

Emits warnings for unused imported functions. Default is to emit no warnings for unused imported functions.

nowarn_unused_vars

By default, warnings are emitted for unused variables, except for variables beginning with an underscore ("Prolog style warnings"). Use this option to turn off this kind of warnings.

nowarn_unused_record

Turns off warnings for unused record types. Default is to emit warnings for unused locally defined record types.

Another class of warnings is generated by the compiler during optimization and code generation. They warn about patterns that will never match (such as a=b), guards that always evaluate to false, and expressions that always fail (such as atom+42).

Those warnings cannot be disabled (except by disabling all warnings).

Note

The compiler does not warn for expressions that it does not attempt to optimize. For example, the compiler tries to evaluate 1/0, detects that it will cause an exception, and emits a warning. However, the compiler is silent about the similar expression, X/0, because of the variable in it. Thus, the compiler does not even try to evaluate and therefore it emits no warnings.

Warning

The absence of warnings does not mean that there are no remaining errors in the code.

Note

All options, except the include path ({i,Dir}), can also be given in the file with attribute -compile([Option,...]). Attribute -compile() is allowed after the function definitions.

Note

The options {nowarn_unused_function, FAs}, {nowarn_bif_clash, FAs}, and {nowarn_deprecated_function, MFAs} are only recognized when given in files. They are not affected by options warn_unused_function, warn_bif_clash, or warn_deprecated_function.

For debugging of the compiler, or for pure curiosity, the intermediate code generated by each compiler pass can be inspected. To print a complete list of the options to produce list files, type compile:options() at the Erlang shell prompt. The options are printed in the order that the passes are executed. If more than one listing option is used, the one representing the earliest pass takes effect.

Unrecognized options are ignored.

Both WarningList and ErrorList have the following format:

[{FileName,[ErrorInfo]}].

ErrorInfo is described later in this section. The filename is included here, as the compiler uses the Erlang pre-processor epp, which allows the code to be included in other files. It is therefore important to know to which file the line number of an error or a warning refers.

forms(Forms)

Is the same as forms(Forms, [verbose,report_errors,report_warnings]).

forms(Forms, Options) -> CompRet

Types:

Forms = [Form]
CompRet = BinRet | ErrRet
BinRet = {ok,ModuleName,BinaryOrCode} | {ok,ModuleName,BinaryOrCode,Warnings}
BinaryOrCode = binary() | term()
ErrRet = error | {error,Errors,Warnings}

Analogous to file/1, but takes a list of forms (in the Erlang abstract format representation) as first argument. Option binary is implicit, that is, no object code file is produced. For options that normally produce a listing file, such as 'E', the internal format for that compiler pass (an Erlang term, usually not a binary) is returned instead of a binary.

format_error(ErrorDescriptor) -> chars()

Types:

ErrorDescriptor = errordesc()

Uses an ErrorDescriptor and returns a deep list of characters that describes the error. This function is usually called implicitly when an ErrorInfo structure (described in section Error Information) is processed.

output_generated(Options) -> true | false

Types:

Options = [term()]

Determines whether the compiler generates a beam file with the given options. true means that a beam file is generated. false means that the compiler generates some listing file, returns a binary, or merely checks the syntax of the source code.

noenv_file(File, Options) -> CompRet

Works like file/2, except that the environment variable ERL_COMPILER_OPTIONS is not consulted.

noenv_forms(Forms, Options) -> CompRet

Works like forms/2, except that the environment variable ERL_COMPILER_OPTIONS is not consulted.

noenv_output_generated(Options) -> true | false

Types:

Options = [term()]

Works like output_generated/1, except that the environment variable ERL_COMPILER_OPTIONS is not consulted.

Default Compiler Options

The (host operating system) environment variable ERL_COMPILER_OPTIONS can be used to give default compiler options. Its value must be a valid Erlang term. If the value is a list, it is used as is. If it is not a list, it is put into a list.

The list is appended to any options given to file/2, forms/2, and output_generated/2. Use the alternative functions noenv_file/2, noenv_forms/2, or noenv_output_generated/2 if you do not want the environment variable to be consulted, for example, if you are calling the compiler recursively from inside a parse transform.

The list can be retrieved with env_compiler_options/0.

Inlining

The compiler can do function inlining within an Erlang module. Inlining means that a call to a function is replaced with the function body with the arguments replaced with the actual values. The semantics are preserved, except if exceptions are generated in the inlined code. Exceptions are reported as occurring in the function the body was inlined into. Also, function_clause exceptions are converted to similar case_clause exceptions.

When a function is inlined, the original function is kept if it is exported (either by an explicit export or if the option export_all was given) or if not all calls to the function are inlined.

Inlining does not necessarily improve running time. For example, inlining can increase Beam stack use, which probably is detrimental to performance for recursive functions.

Inlining is never default. It must be explicitly enabled with a compiler option or a -compile() attribute in the source module.

To enable inlining, either use the option inline to let the compiler decide which functions to inline, or {inline,[{Name,Arity},...]} to have the compiler inline all calls to the given functions. If the option is given inside a compile directive in an Erlang module, {Name,Arity} can be written as Name/Arity.

Example of explicit inlining:

-compile({inline,[pi/0]}).

pi() -> 3.1416.
    

Example of implicit inlining:

-compile(inline).

The option {inline_size,Size} controls how large functions that are allowed to be inlined. Default is 24, which keeps the size of the inlined code roughly the same as the un-inlined version (only relatively small functions are inlined).

Example:

%% Aggressive inlining - will increase code size.
-compile(inline).
-compile({inline_size,100}).

Inlining of List Functions

The compiler can also inline various list manipulation functions from the module list in STDLIB.

This feature must be explicitly enabled with a compiler option or a -compile() attribute in the source module.

To enable inlining of list functions, use option inline_list_funcs.

The following functions are inlined:

Parse Transformations

Parse transformations are used when a programmer wants to use Erlang syntax but with different semantics. The original Erlang code is then transformed into other Erlang code.

Error Information

The ErrorInfo mentioned earlier is the standard ErrorInfo structure, which is returned from all I/O modules. It has the following format:

{ErrorLine, Module, ErrorDescriptor}

ErrorLine is the atom none if the error does not correspond to a specific line, for example, if the source file does not exist.

A string describing the error is obtained with the following call:

Module:format_error(ErrorDescriptor)

See Also