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NAME ^

Getopt::Complete - programmable shell completion for Perl apps

VERSION ^

This document describes Getopt::Complete 0.26.

SYNOPSIS ^

In the Perl program "myprogram":

  use Getopt::Complete (
      'frog'        => ['ribbit','urp','ugh'],
      'fraggle'     => sub { return ['rock','roll'] },
      'quiet!'      => undef,
      'name'        => undef,
      'age=n'       => undef,
      'outfile=s@'  => 'files', 
      'outdir'      => 'directories'
      'runthis'     => 'commands',
      'username'    => 'users',
      '<>'          => 'directories', 
  );

  print "the frog says " . $ARGS{frog} . "\n";

In ~/.bashrc or ~/.bash_profile, or directly in bash:

  function _getopt_complete () {
    COMPREPLY=($( COMP_CWORD=$COMP_CWORD perl `which ${COMP_WORDS[0]}` ${COMP_WORDS[@]:0} ));
  }
  complete -F _getopt_complete myprogram

Thereafter in the terminal (after next login, or sourcing the updated .bashrc):

  $ myprogram --f<TAB>
  $ myprogram --fr

  $ myprogram --fr<TAB><TAB>
  frog fraggle

  $ myprogram --fro<TAB>
  $ myprogram --frog 

  $ myprogram --frog <TAB>
  ribbit urp ugh

  $ myprogram --frog r<TAB>
  $ myprogram --frog ribbit

DESCRIPTION ^

This module makes it easy to add custom command-line completion to Perl applications. It also does additional validation of arguments, when the program is actually executed, based on completion lists.

Support is also present for apps which are an entry point for a hierarchy of sub-commands (in the style of cvs and git).

Getopt::Complete also wraps the standard options processing and exports it as a %ARGS hash at compile time, making using the arguments hassle-free.

The completion features currently work with the bash shell, which is the default on most Linux and Mac systems. Patches for other shells are welcome.

OPTIONS PROCESSING ^

Getopt::Complete processes the command-line options at compile time.

The results are avaialble in the %ARGS hash, which is intended as a companion to the @ARGV array generated natively by Perl.

  use Getopt::Complete (
    'mydir'     => 'd',
    'myfile'    => 'f',
    '<>'        =  ['monkey', 'taco', 'banana']
  );

  for $opt (keys %ARGS) {
    $val = $ARGS{$opt};
    print "$opt has value $val\n";
  }

Errors in shell argumentes result in messages to STDERR via warn(), and cause the program to exit during "use" call. Getopt::Complete verifies that the option values specified match their own completion list, and will otherwise add additional errors explaining the problem.

The %ARGS hash is an alias for %Getopt::Complete::ARGS. The alias is not created in the caller's namespaces if a hash named %ARGS already exists with data, but the results are always available from %Getopt::Complete::ARGS.

They keys of the hash are the option names, minus any specifiers like "=s" or "!". The key is only present if the option was specified on the command-line.

The values of the hash are the values from the command-line. For multi-value options the hash value is an arrayref.

OBJECT API ^

An object $ARGS is also created in the caller's namespace (class Getopt::Complete::Args) with a more detailed API for argument interrogation. See the documentation for that module, and also for the underlying Getopt::Complete::Options module.

It is possible to override any part of the default process, including doing custom parsing, doing processing at run-time, and and preventing exit when there are errors.

See OVERRIDING COMPILE-TIME OPTION PARSING for more information.

PROGRAMMABLE COMPLETION BACKGROUND ^

The bash shell supports smart completion of words when the <TAB> key is pressed. By default, after the program name is specified, bash will presume the word the user is typing a is a file name, and will attempt to complete the word accordingly. Where completion is ambiguous, the shell will go as far as it can and beep. Subsequent completion attempts at that position result in a list being shown of possible completions.

Bash can be configured to run a specific program to handle the completion task, allowing custom completions to be done for different appliations. The "complete" built-in bash command instructs the shell as-to how to handle tab-completion for a given command.

This module allows a program to be its own word-completer. It detects that the COMP_LINE and COMP_POINT environment variables are set, indicating that it is being used as a completion program, and responds by returning completion values suitable for the shell _instead_ of really running the application.

See the manual page for "bash", the heading "Programmable Completion" for full details on the general topic.

HOW TO CONFIGURE PROGRAMMABLE COMPLETION ^

  1. Put a "use Getopt::Complete" statement into your app as shown in the synopsis. The key-value pairs describe the command-line options available, and their completions.

    This should be at the TOP of the app, before any real processing is done. The only modules used before it should be those needed for custom callbacks, if there are any. No code should print to standard output during compile time, or it will confuse bash.

    Subsequent code can use %ARGS or the $ARGS object to check on command-line option values.

    Existing apps using Getopt::Long should use their option spec in the use declaration instead. If they bind variables directly the code should to be updated to get values from the %ARGS hash instead.

  2. Put the following in your .bashrc or .bash_profile:
      function _getopt_complete () {
        COMPREPLY=($( COMP_CWORD=$COMP_CWORD perl `which ${COMP_WORDS[0]}` ${COMP_WORDS[@]:0} ));
      }
      complete -F _getopt_complete myprogram
  3. New logins will automatically run the above and become aware that your program has programmable completion. For shells you already have open, run this to alert bash to your that your program has custom tab-completion.
      source ~/.bashrc 

Type the name of your app ("myprogram" in the example), and experiment with using the <TAB> key to get various completions to test it. Every time you hit <TAB>, bash sets certain environment variables, and then runs your program. The Getopt::Complete module detects these variables, responds to the completion request, and then forces the program to exit before really running your regular application code.

IMPORTANT: Do not do steps #2 and #3 w/o doing step #1, or your application will actually run "normally" every time you press <TAB> with it on the command-line! The module will not be present to detect that this is not a "real" execution of the program, and you may find your program is running when it should not.

KEYS IN THE OPTIONS SPECIFICATION ^

Each key in the list decribes an option which can be completed. Any key usable in a Getopt:::Long GetOptions specification works here, (except as noted in BUGS below):

an option name

A normal word is interpreted as an option name. The '=s' specifier is presumed if no specifier is present.

  'p1' => [...]
a complete option specifier

Any specification usable by Getopt::Long is valid as the key. For example:

  'p1=s' => [...]       # the same as just 'p1'
  'p2=s@' => [...]      # expect multiple values
the '<>' symbol for "bare arguments"

This special key specifies how to complete non-option (bare) arguments. It presumes multiple values are possible (like '=s@'):

Have an explicit list: '<>' = ['value1','value2','value3']

Do normal file completion: '<>' = 'files'

Take arbitrary values with no expectations: '<>' = undef

If there is no '<>' key specified, bare arguments will be treated as an error.

a sub-command specifier, starting with '>'

When a key in the options specification starts with '>', it indicates a that word maps to a distinct sub-command with its own options. The array to the right is itself a full options specification, following the same format as the one above it, including possible further sub-commands.

See SUB-COMMAND TREES for more details.

VALUES IN THE OPTIONS SPECIFICATION ^

Each value describes how the option in question should be completed.

array reference

An array reference expliciitly lists the valid values for the option.

  In the app:

    use Getopt::Complete (
        'color'    => ['red','green','blue'],
    );

  In the shell:

    $ myprogram --color <TAB>
    red green blue

    $ myprogram --color blue
    (runs with no errors)

The list of value is also used to validate the user's choice after options are processed:

    myprogram --color purple
    ERROR: color has invalid value purple: select from red green blue

See below for details on how to permit values which aren't shown in completions to be used and not generate errors.

undef

An undefined value indicates that the option is not completable. No completions will be offered by the application, though any value provided by the user will be considered valid.

Note that this is distinct from returning an empty arrayref from a callback, which implies that there ARE known completions but the user has failed to match any of them.

Also note: this is the only valid completion for boolean parameters, since there is no value to specify on the command-line.

  use Getopt::Complete (
    'name'      => undef,   # take --name "anyting" 
    'perky!'    => undef,   # take --perky or --no-perky
  );
subroutine callback

When the list of valid values must be determined dynamically, a subroutine reference or name can be specified. If a name is specified, it should be fully qualified. (If it is not, it will be presumed to refer to one of the bash builtin completions types. See BUILTIN COMPLETION TYPES below.)

The subroutine will be called, and is expected to return an arrayref of possiible matches. The arrayref will be treated as though it were specified directly in the specification.

As with explicit values, an empty arrayref indicated that there are no valid matches for this option, given the other params on the command-line, and the text already typed. An undef value indicates that any value is valid for this parameter.

Parameters to the callback are described below.

WRITING SUBROUTINE CALLBACKS ^

A subroutine callback is useful when the list of options to match must be dynamically generated.

It is also useful when knowing what the user has already typed helps narrow the search for valid completions, or when iterative completion needs to occur (see PARTIAL COMPLETIONS below).

The callback is expected to return an arrayref of valid completions. If it is empty, no completions are considered valid. If an undefined value is returned, no completions are specified, but ANY arbitrary value entered is considered valid as far as error checking is concerned.

The callback registerd in the completion specification will receive the following parameters:

command name

Contains the name of the command for which options are being parsed. This is $0 in most cases, though hierarchical commands may have a name "svn commit" or "foo bar baz" etc.

current word

This is the word the user is trying to complete. It may be an empty string, if the user hits <Tab> without typing anything first.

option name

This is the name of the option for which we are resolving a value. It is typically ignored unless you use the same subroutine to service multiple options.

A value of '<>' indicates an unnamed argument (a.k.a "bare argument" or "non-option" argument).

other opts

It is the hashref resulting from Getopt::Long processing of all of the OTHER arguments. This is useful when one option limits the valid values for another option.

In some cases, the options which should be available change depending on what other options are present, or the values available change depending on other options or their values.

The environment variables COMP_LINE and COMP_POINT have the exact text of the command-line and also the exact character position, if more detail is needed in raw form than the parameters provide.

The return value is a list of possible matches. The callback is free to narrow its results by examining the current word, but is not required to do so. The module will always return only the appropriate matches.

EXAMPLE

This app takes 2 parameters, one of which is dependent on the other:

  use Getopt::Complete (
    type => ['names','places','things'],
    instance => sub {
            my ($command, $value, $option, $other_opts) = @_;
            if ($other_opts{type} eq 'names') {
                return [qw/larry moe curly/],
            }
            elsif ($other_opts{type} eq 'places') {
                return [qw/here there everywhere/],
            }
            elsif ($other_opts{type} eq 'things') {
                return [ query_database_matching("${value}%") ]
            }
            elsif ($otper_opts{type} eq 'surprsing') {
                # no defined list: take anything typed
                return undef;
            }
            else {
                # invalid type: no matches
                return []
            }
        }
   );

   $ myprogram --type people --instance <TAB>
   larry moe curly

   $ myprogram --type places --instance <TAB>
   here there everywhere

   $ myprogram --type surprising --instance <TAB>
   (no completions appear)   

BUILTIN COMPLETIONS ^

Bash has a list of built-in value types which it knows how to complete. Any of the default shell completions supported by bash's "compgen" are supported by this module.

The list of builtin types supported as-of this writing are:

    files
    directories
    commands
    users
    groups
    environment
    services
    aliases
    builtins

To indicate that an argument's valid values are one of the above, use the exact string after Getopt::Complete:: as the completion callback. For example:

  use Getopt::Complete (
    infile  => 'Getopt::Complete::files',       
    outdir  => 'Getopt::Complete::directories', 
    myuser  => 'Getopt::Complete::users',
  );

The full name is alissed as the single-character compgen parameter name for convenience. Further, because Getopt::Complete is the default namespace during processing, it can be ommitted from callback function names.

The following are all equivalent. They effectively produce the same list as 'compgen -f':

   file1 => \&Getopt::Complete::files
   file1 => \&Getopt::Complete::f
   file1 => 'Getopt::Complete::files'
   file1 => 'Getopt::Complete::f'
   file1 => 'files'
   file1 => 'f'

See Getopt::Complete::Compgen for specifics on using builtin completions.

See "man bash", in the Programmable Complete secion, and the "compgen" builtin command for more details.

UNLISTED VALID VALUES ^

If there are options which should not be part of completion lists, but still count as valid if passed-into the app, they can be in a final sub-array at the end. This list doesn't affect the completion system at all, just prevents errors in the ERRORS array described above.

    use Getopt::Complete (
        'color'    => ['red','green','blue', ['yellow','orange']],
    );

    myprogram --color <TAB>
    red green blue

    myprogram --color orange
    # no errors

    myprogram --color purple
    # error

PARTIAL COMPLETIONS ^

BASICS

Any returned value ending in a <TAB> character ("\t") will be considered a "partial" completion. This means that the shell will be instructed to leave the cursor at the end of that word even if there is no ambiguity in the rest of the returned list.

Partial completions are only usable from callbacks. From a hard-coded array of values, it would be impossible to ever fuly complete the partial completion.

BACKGROUND

Sometimes, the entire list of completions is too big to reasonable resolve and return. The most obvious example is filename completion at the root of a large filesystem. In these cases, the completion of is handled in pieces, allowing the user to gradually "drill down" to the complete value directory by directory. It is even possible to hit <TAB> to get one completion, then hit it again and get more completion, in the case of single-sub-directory directories.

The Getopt::Complete module supports iterative drill-down completions from any parameter configured with a callback. It is completely valid to complete "a" with "aa" "ab" and "ac", but then to complete "ab" with yet more text.

Unless the shell knows, however that your "aa", "ab", and "ac" completions are in fact only partial completions, an inconvenient space will be added after the word on the terminal line, as the shell happily moves on to helping the user enter the next argument.

DETAILS

Because partial completions are indicated in Getopt::Complete by adding a "\t" tab character to the end of the returned string, an application can return a mix of partial and full completions, and it will respect each correctly.

Note: The "\t" is actually stripped-off before going to the shell and internal hackery is used to force the shell to not put a space where it isn't needed. This is not part of the bash programmable completion specification, but is used to simulate features typically only available with bash for builtin completions like files/directories.

SUB-COMMAND TREES ^

It is common for a given appliction to actually be an entry point for several different tools. Popular exmples are the big version control suites (cvs,svn,svk,git), which use the form:

 cvs SUBCOMMAND [ARGS]

Each sub-command has its own options specification. Those may in turn have further sub-commands.

Sub-commands are identified by an initial '>' in the options specification key. The value is interpreted as a complete, isolated options spec, using the same general syntax. This applies recursively.

EXAMPLE COMMAND TREE SPEC

    use Getopt::Complete (
        '>animal' => [
            '>dog' => [
                '>bark' => [
                    'ferocity'  => ['yip','wail','ruf','grrrr'], 
                    'count'  => ['1','2','one too many'], 
                ],
                '>drool' => [
                    'buckets=n' => undef, 
                    'lick'      => 'users', 
                ],
                'list!' => undef,
            ],
            '>cat' => [
                '>purr' => [],
                '>meow' => [ 
                    'volume=n' => undef,
                    'bass' => ['low','medium','high'],
                ]
            ],
        ],
        '>plant' => [
            '>taters' => [
                '>fry' => [
                    'greasiness'    => ['crispy','drippy'],
                    'width'         => ['fat','thin','frite'],
                ],
                '>bake' => [
                    'hard!'     => undef,
                    'temp=n'    => undef,
                ],
            ],
            '>dasies' => [
                '>pick' => [
                    '<>'            => ['mine','yours','theirs'],
                ],
                '>plant' => [
                    'season'        => ['winter','spring','summer','fall'],
                    'seeds=n'       => undef,
                    'deep!'         => undef,
                ]
            ]
        ]
    );

    my ($word1,$word2,$word3) = $ARGS->parent_sub_commands; 
    # (the above is also in $ARGS{'>'} for non-OO access)

    # your program probably has something smarter to decide where to go 
    # for a given command
    if ($word1 eq 'animal') {
        if ($word2 eq 'dog') {
            if ($word3 eq 'bark') {
                # work with %ARGS for barking dogs...
                # ....
            }
        }
    }
    elsif ($path[0] eq 'plant') {
        ...
    }

The above example specifies two sub-commands "animal" and "plant, each of which has its own two sub-commands, dog/cat and taters/dasies. Each of those, in turn, have two sub-commands, for a total of 8 complete commands possible, each with different arguments. Each of the 8 has thier own options specification.

When the program executes, the %ARGS hash contains option/value pairs for the specific command chosen. The the series of sub-command choices in $ARGS{'>'}, separate from the regular bare arguments in '<>'. (The method name on an $ARGS object for this is "parent_sub_commands", a companion to the "bare_args" method.

The method to determine the next available sub-commands is just "sub_commands".)

Note that, since the user can hit <ENTER> at any time, it is possible that the parent_sub_commands will be a partial drill-down. It isn't uncommon to have something like this in place:

 if (my @next = $ARGS->sub_commands) {
    print STDERR "Please select a sub-command:\n";
    print STDERR join("\n", @sub_commands),"\n";
    exit 1;
 }

The above checking is not done automatically, since a sub-command may have further sub-commands, but still also be used directly, possibly with other option and bare arguments.

THE LONE DASH ^

A lone dash is often used to represent using STDIN instead of a file for applications which otherwise take filenames.

This is supported by all options which complete with the "files" builtin, though it does not appear in completion hint displays.

To disable this, set $Getopt::Complete::LONE_DASH = 0.

OVERRIDING COMPILE-TIME OPTION PARSING ^

Getopt::Complete makes a lot of assumptions in order to be easy to use in the default case. Here is how to override that behavior if it's not what you want.

OPTION 1: DOING CUSTOM ERROR HANDLING

To prevent Getopt::Complete from exiting at compile time if there are errors, the EXIT_ON_ERRORS flag should be set to 0 first, at compile time, before using the Getopt::Complete module as follows:

 BEGIN { $Getopt:Complete::EXIT_ON_ERRORS = 0; }

This should not affect completions in any way (it will still exit if it realizes it is talking to bash, to prevent accidentally running your program).

Errors are retained in:

 $Getopt::Complete::ARGS->errors;

It is then up to the application to not run with invalid parameters.

OPTION 2: RE-PROCESS @ARGV

This module restores @ARGV to its original state after processing, so independent option processing can be done if necessary. The full spec imported by Getopt::Complete is stored as:

 $Getopt::Complete::ARGS->option_specs;

This is an easy option when upgrading old applications.

Combined with disabling the EXIT_ON_ERROS flag above, set, you can completely ignore, or partially ignore, the options processing which happens automatically.

OPTION 3: CHANGING COMPILE-TIME PROCESSING

You can also adjust how option processing happens inside of Getopt::Complete. Getopt::Complete wraps Getopt::Long to do the underlying option parsing. It uses GetOptions(\%h, @specification) to produce the %ARGS hash. Customization of Getopt::Long should occur in a BEGIN block before using Getopt::Complete.

OPTION 4: USE THE OBJECTS AND WRITE YOUR OWN LOGIC

The logic in import() is very short, and is simple to modify. It is best to do it in a BEGIN {} block so that bash can use 'perl -c myprogram' to get completions at compile time.

    BEGIN {

        my $options = Getopt::Complete::Options->new(
            'myfile' => 'f',
            'mychoice' => ['small','medium','huge']
        );

        $options->handle_shell_completion();

        my $args = Getopt::Complete::Args->new(
            options => $options,
            argv => [@ARGV]
        );
        
        if (my @errors = $ARGS->errors) {
            for my $error ($ARGS->errors) {
                chomp $error;
                warn __PACKAGE__ . ' ERROR:' . $error . "\n";
            }
            exit 1;
        }
    
        # make the %ARGS available to all of the app
        $args->__install_as_default__;

        # if you also want %ARGS and $ARGS here when you're finished...
        Getopt:Complete->export_aliases(__PACKAGE__);
    };

EXTENSIVE USAGE EXAMPLE ^

Cut-and-paste this into a script called "myprogram" in your path, make it executable, and then run this in the shell:

  function _getopt_complete () {
    COMPREPLY=($( COMP_CWORD=$COMP_CWORD perl `which ${COMP_WORDS[0]}` ${COMP_WORDS[@]:0} ));
  }
  complete -F _getopt_complete myprogram

Then try it out. It does one of everything, besides command trees.

    #!/usr/bin/env perl
    use strict;
    use warnings;

    use Getopt::Complete (
        # list the explicit values which are valid for this option
        'frog'    => ['ribbit','urp','ugh'],

        # you can add any valid Getopt::Long specification to the key on the left
        # ...if you put nothing: "=s" is assumed
        'names=s@' => ['eenie','meanie','miney'],

        # support for Bash "compgen" builtins is present with some pre-made callbacks
        'myfile'    => 'Getopt::Complete::Compgen::files',
        'mydir'     => 'Getopt::Complete::Compgen::directories',
        
        # the plain name or first letter of the compgen builtins also work
        'myfile2'   => 'files',
        'myfile3'   => 'f',

        # handle unnamed arguments from the command-line ("non-option" arguments) with a special key:
        '<>'      => ['some','raw','words'],

        # CODE callbacks allow a the completion list to be dynamically resolved 
        'fraggle' => sub { return ['rock','roll','fried fish','fried taters','fries and squid'] },

        # callbacks get extra info to help them, including the part of the
        # word already typed, and the remainder of the options already processed for context
        'type'    => ['people','places'],
        'instance'=> sub {
                            my ($command, $partial_word, $option_name, $other_opts_hashref) = @_;
                            # be lazy and ignore the partial word: bash will compensate
                            if (my $type = $other_opts_hashref->{type}) {
                                if ($type eq 'people') {
                                    return [qw/larry moe curly/]
                                }
                                elsif ($type eq 'places') {
                                    return [qw/here there everywhere/],
                                }
                            }
                            return [];
                        },
        
        # undef means we don't know how to complete the value: any value specified will do
        # this will result in no shell ompletions, but will still expect a value to be entered
        'name=s'  => undef,

        # boolean values never have a completion list, and will yell if you are that foolish
        # this will give you --no-fast for free as well
        'fast!'     => undef,

    );

    use Data::Dumper;
    print "The arguments are: " . Dumper(\%ARGS);

DEVELOPMENT ^

Patches are welcome.

 http://github.com/sakoht/Getopt--Complete-for-Perl/

 git clone git://github.com/sakoht/Getopt--Complete-for-Perl.git

As are complaints. Help us find bugs by sending an email to the address below, or using CPAN's bug tracking system:

 https://rt.cpan.org/

The latest version of this module is always availabe on CPAN:

 http://search.cpan.org/search?query=Getopt%3A%3AComplete&mode=all

And is readily installable with the CPAN shell on Mac, Linux, and other Unix-like systems:

 sudo cpan Getopt::Complete

BUGS ^

Completions with whitespace work, but they do so by escaping whitespace characters instead of quoting. Support should be present for completing quoted text. It should also be the default, since it is more attractive.

The logic to "shorten" the completion options shown in some cases is still in development. This means that filename completion shows full paths as options instead of just the last word in the file path.

Some uses of Getopt::Long will not work currently: multi-name options (though standard shortening works), +, :, %.

Currently this module only supports bash, though other shells could be added easily.

There is logic in development to have the tool possibly auto-update the user's .bashrc / .bash_profile, but this is incomplete.

SEE ALSO ^

Getopt::Complete::Args

the object API for the option/value argument set

Getopt::Complete::Options

the object API for the options specification

Getopt::Complete::Compgen

supplies builtin completions like file lists

Getopt::Long

the definitive options parser, wrapped by this module

bash

the manual page for bash has lots of info on how tab-completion works

COPYRIGHT ^

Copyright 2010, 2011 Washington University School of Medicine

AUTHORS ^

Scott Smith (sakoht at cpan .org) Nathan Nutter Andrei Benea

LICENSE ^

This program is free software; you can redistribute it and/or modify it under the same terms as Perl itself.

The full text of the license can be found in the LICENSE file included with this module.

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