/* Part of SWI-Prolog Author: Jan Wielemaker E-mail: J.Wielemaker@vu.nl WWW: http://www.swi-prolog.org Copyright (c) 2002-2023, University of Amsterdam VU University Amsterdam SWI-Prolog Solutions b.v. All rights reserved. Redistribution and use in source and binary forms, with or without modification, are permitted provided that the following conditions are met: 1. Redistributions of source code must retain the above copyright notice, this list of conditions and the following disclaimer. 2. Redistributions in binary form must reproduce the above copyright notice, this list of conditions and the following disclaimer in the documentation and/or other materials provided with the distribution. THIS SOFTWARE IS PROVIDED BY THE COPYRIGHT HOLDERS AND CONTRIBUTORS "AS IS" AND ANY EXPRESS OR IMPLIED WARRANTIES, INCLUDING, BUT NOT LIMITED TO, THE IMPLIED WARRANTIES OF MERCHANTABILITY AND FITNESS FOR A PARTICULAR PURPOSE ARE DISCLAIMED. IN NO EVENT SHALL THE COPYRIGHT OWNER OR CONTRIBUTORS BE LIABLE FOR ANY DIRECT, INDIRECT, INCIDENTAL, SPECIAL, EXEMPLARY, OR CONSEQUENTIAL DAMAGES (INCLUDING, BUT NOT LIMITED TO, PROCUREMENT OF SUBSTITUTE GOODS OR SERVICES; LOSS OF USE, DATA, OR PROFITS; OR BUSINESS INTERRUPTION) HOWEVER CAUSED AND ON ANY THEORY OF LIABILITY, WHETHER IN CONTRACT, STRICT LIABILITY, OR TORT (INCLUDING NEGLIGENCE OR OTHERWISE) ARISING IN ANY WAY OUT OF THE USE OF THIS SOFTWARE, EVEN IF ADVISED OF THE POSSIBILITY OF SUCH DAMAGE. */ :- module(prolog_main, [ main/0, argv_options/3, % +Argv, -RestArgv, -Options argv_options/4, % +Argv, -RestArgv, -Options, +ParseOpts argv_usage/1, % +Level cli_parse_debug_options/2, % +OptionsIn, -Options cli_debug_opt_type/3, % -Flag, -Option, -Type cli_debug_opt_help/2, % -Option, -Message cli_debug_opt_meta/2, % -Option, -Arg cli_enable_development_system/0 ]). :- use_module(library(debug), [debug/1]). :- autoload(library(apply), [maplist/2, maplist/3, partition/4]). :- autoload(library(lists), [append/3]). :- autoload(library(pairs), [pairs_keys/2, pairs_values/2]). :- autoload(library(prolog_code), [pi_head/2]). :- autoload(library(prolog_debug), [spy/1]). :- autoload(library(dcg/high_order), [sequence//3, sequence//2]). :- autoload(library(option), [option/2]). :- if(exists_source(library(doc_markdown))). :- autoload(library(doc_markdown), [print_markdown/2]). :- endif. :- meta_predicate argv_options(:, -, -), argv_options(:, -, -, +), argv_usage(:). :- dynamic interactive/0. /** Provide entry point for scripts This library is intended for supporting PrologScript on Unix using the ``#!`` magic sequence for scripts using commandline options. The entry point main/0 calls the user-supplied predicate main/1 passing a list of commandline options. Below is a simle `echo` implementation in Prolog. ``` #!/usr/bin/env swipl :- initialization(main, main). main(Argv) :- echo(Argv). echo([]) :- nl. echo([Last]) :- !, write(Last), nl. echo([H|T]) :- write(H), write(' '), echo(T). ``` @see library(prolog_stack) to force backtraces in case of an uncaught exception. @see XPCE users should have a look at library(pce_main), which starts the GUI and processes events until all windows have gone. */ :- module_transparent main/0. %! main % % Call main/1 using the passed command-line arguments. Before calling % main/1 this predicate installs a signal handler for =SIGINT= % (Control-C) that terminates the process with status 1. % % When main/0 is called interactively it simply calls main/1 with the % arguments. This allows for debugging scripts as follows: % % ``` % $ swipl -l script.pl -- arg ... % ?- gspy(suspect/1). % setup debugging % ?- main. % run program % ``` main :- current_prolog_flag(break_level, _), !, current_prolog_flag(argv, Av), context_module(M), M:main(Av). main :- context_module(M), set_signals, current_prolog_flag(argv, Av), catch_with_backtrace(M:main(Av), Error, throw(Error)), ( interactive -> cli_enable_development_system ; true ). set_signals :- on_signal(int, _, interrupt). %! interrupt(+Signal) % % We received an interrupt. This handler is installed using % on_signal/3. interrupt(_Sig) :- halt(1). /******************************* * OPTIONS * *******************************/ %! argv_options(:Argv, -Positional, -Options) is det. % % Parse command line arguments. This predicate acts in one of two % modes. % % - If the calling module defines opt_type/3, full featured parsing % with long and short options, type conversion and help is % provided. % - If opt_type/3 is not defined, only unguided transformation % using long options is supported. See argv_untyped_options/3 % for details. % % When __guided__, three predicates are called in the calling module. % opt_type/3 __must__ be defined, the others need not. Note that these % three predicates _may_ be defined as _multifile_ to allow multiple % modules contributing to the provided commandline options. Defining % them as _discontiguous_ allows for creating blocks that describe a % group of related options. % % - opt_type(Opt, Name, Type) % Defines Opt to add an option Name(Value), where Value statisfies % Type. Opt does not include the leading `-`. A single character % implies a short option, multiple a long option. Long options % use ``_`` as _word separator_, user options may use either ``_`` % or ``-``. Type is one of: % % - A|B % Disjunctive type. Disjunction can be used create long % options with optional values. For example, using the type % ``nonneg|boolean``, for an option `http` handles ``--http`` % as http(true), ``--no-http`` as http(false) and ``--http=3000`` % as http(3000). Note that with an optional boolean a option is % considered boolean unless it has a value written as % ``--longopt=value``. % - boolean(Default) % - boolean % Boolean options are special. They do not take a value except % for when using the long ``--opt=value`` notation. This % explicit value specification converts ``true``, ``True``, % ``TRUE``, ``on``, ``On``, ``ON``, ``1`` and the obvious % false equivalents to Prolog `true` or `false`. If the % option is specified, Default is used. If ``--no-opt`` or % ``--noopt`` is used, the inverse of Default is used. % - integer % Argument is converted to an integer % - float % Argument is converted to a float. User may specify an integer % - nonneg % As `integer`. Requires value >= 0. % - natural % As `integer`. Requires value >= 1. % - number % Any number (integer, float, rational). % - between(Low, High) % If both one of Low and High is a float, convert as `float`, % else convert as `integer`. Then check the range. % - atom % No conversion % - oneof(List) % As `atom`, but requires the value to be a member of List % (_enum_ type). % - string % Convert to a SWI-Prolog string % - file % Convert to a file name in Prolog canonical notation % using prolog_to_os_filename/2. % - directory % Convert to a file name in Prolog canonical notation % using prolog_to_os_filename/2. No checking is done and % thus this type is the same as `file` % - file(Access) % As `file`, and check access using access_file/2. A value `-` % is not checked for access, assuming the application handles % this as standard input or output. % - directory(Access) % As `directory`, and check access. Access is one of `read` % `write` or `create`. In the latter case the parent directory % must exist and have write access. % - term % Parse option value to a Prolog term. % - term(+Options) % As `term`, but passes Options to term_string/3. If the option % variable_names(Bindings) is given the option value is set to % the _pair_ `Term-Bindings`. % % - opt_help(Name, HelpString) % Help string used by argv_usage/1. % % - opt_meta(Name, Meta) % If a typed argument is required this defines the placeholder % in the help message. The default is the uppercase version of % the type _functor name_. This produces the ``FILE`` in e.g. ``-f % FILE``. % % By default, ``-h``, ``-?`` and ``--help`` are bound to help. If % opt_type(Opt, help, boolean) is true for some `Opt`, the default % help binding and help message are disabled and the normal user % rules apply. In particular, the user should also provide a rule for % opt_help(help, String). argv_options(M:Argv, Positional, Options) :- in(M:opt_type(_,_,_)), !, argv_options(M:Argv, Positional, Options, [on_error(halt(1))]). argv_options(_:Argv, Positional, Options) :- argv_untyped_options(Argv, Positional, Options). %! argv_options(:Argv, -Positional, -Options, +ParseOptions) is det. % % As argv_options/3 in __guided__ mode, Currently this version allows % parsing argument options throwing an exception rather than calling % halt/1 by passing an empty list to ParseOptions. ParseOptions: % % - on_error(+Goal) % If Goal is halt(Code), exit with Code. Other goals are % currently not supported. % - options_after_arguments(+Boolean) % If `false` (default `true`), stop parsing after the first % positional argument, returning options that follow this % argument as positional arguments. E.g, ``-x file -y`` % results in positional arguments `[file, '-y']` argv_options(Argv, Positional, Options, POptions) :- option(on_error(halt(Code)), POptions), !, E = error(_,_), catch(opt_parse(Argv, Positional, Options, POptions), E, ( print_message(error, E), halt(Code) )). argv_options(Argv, Positional, Options, POptions) :- opt_parse(Argv, Positional, Options, POptions). %! argv_untyped_options(+Argv, -RestArgv, -Options) is det. % % Generic transformation of long commandline arguments to options. % Each ``--Name=Value`` is mapped to Name(Value). Each plain name is % mapped to Name(true), unless Name starts with ``no-``, in which case % the option is mapped to Name(false). Numeric option values are % mapped to Prolog numbers. argv_untyped_options([], Pos, Opts) => Pos = [], Opts = []. argv_untyped_options([--|R], Pos, Ops) => Pos = R, Ops = []. argv_untyped_options([H0|T0], R, Ops), sub_atom(H0, 0, _, _, --) => Ops = [H|T], ( sub_atom(H0, B, _, A, =) -> B2 is B-2, sub_atom(H0, 2, B2, _, Name), sub_string(H0, _, A, 0, Value0), convert_option(Name, Value0, Value) ; sub_atom(H0, 2, _, 0, Name0), ( sub_atom(Name0, 0, _, _, 'no-') -> sub_atom(Name0, 3, _, 0, Name), Value = false ; Name = Name0, Value = true ) ), canonical_name(Name, PlName), H =.. [PlName,Value], argv_untyped_options(T0, R, T). argv_untyped_options([H|T0], Ops, T) => Ops = [H|R], argv_untyped_options(T0, R, T). convert_option(password, String, String) :- !. convert_option(_, String, Number) :- number_string(Number, String), !. convert_option(_, String, Atom) :- atom_string(Atom, String). canonical_name(Name, PlName) :- split_string(Name, "-_", "", Parts), atomic_list_concat(Parts, '_', PlName). %! opt_parse(:Argv, -Positional, -Options, +POptions) is det. % % Rules follow those of Python optparse: % % - Short options must be boolean, except for the last. % - The value of a short option can be connected or the next % argument % - Long options can have "=value" or have the value in the % next argument. opt_parse(M:Argv, _Positional, _Options, _POptions) :- opt_needs_help(M:Argv), !, argv_usage(M:debug), halt(0). opt_parse(M:Argv, Positional, Options, POptions) :- opt_parse(Argv, Positional, Options, M, POptions). opt_needs_help(M:[Arg]) :- in(M:opt_type(_, help, boolean)), !, in(M:opt_type(Opt, help, boolean)), ( short_opt(Opt) -> atom_concat(-, Opt, Arg) ; atom_concat(--, Opt, Arg) ), !. opt_needs_help(_:['-h']). opt_needs_help(_:['-?']). opt_needs_help(_:['--help']). opt_parse([], Positional, Options, _, _) => Positional = [], Options = []. opt_parse([--|T], Positional, Options, _, _) => Positional = T, Options = []. opt_parse([H|T], Positional, Options, M, POptions), atom_concat(--, Long, H) => take_long(Long, T, Positional, Options, M, POptions). opt_parse([H|T], Positional, Options, M, POptions), H \== '-', string_concat(-, Opts, H) => string_chars(Opts, Shorts), take_shorts(Shorts, T, Positional, Options, M, POptions). opt_parse(Argv, Positional, Options, _M, POptions), option(options_after_arguments(false), POptions) => Positional = Argv, Options = []. opt_parse([H|T], Positional, Options, M, POptions) => Positional = [H|PT], opt_parse(T, PT, Options, M, POptions). take_long(Long, T, Positional, Options, M, POptions) :- % --long=Value sub_atom(Long, B, _, A, =), !, sub_atom(Long, 0, B, _, LName0), sub_atom(Long, _, A, 0, VAtom), canonical_name(LName0, LName), ( in(M:opt_type(LName, Name, Type)) -> opt_value(Type, Long, VAtom, Value), Opt =.. [Name,Value], Options = [Opt|OptionsT], opt_parse(T, Positional, OptionsT, M, POptions) ; opt_error(unknown_option(M:LName0)) ). take_long(LName0, T, Positional, Options, M, POptions) :- % --long canonical_name(LName0, LName), take_long_(LName, T, Positional, Options, M, POptions). take_long_(Long, T, Positional, Options, M, POptions) :- % --long opt_bool_type(Long, Name, Value, M), % only boolean !, Opt =.. [Name,Value], Options = [Opt|OptionsT], opt_parse(T, Positional, OptionsT, M, POptions). take_long_(Long, T, Positional, Options, M, POptions) :- % --no-long, --nolong ( atom_concat('no_', LName, Long) ; atom_concat('no', LName, Long) ), in(M:opt_type(LName, Name, Type)), type_optional_bool(Type, Value0), !, negate(Value0, Value), Opt =.. [Name,Value], Options = [Opt|OptionsT], opt_parse(T, Positional, OptionsT, M, POptions). take_long_(Long, T, Positional, Options, M, POptions) :- % --long [value] in(M:opt_type(Long, Name, Type)), type_optional_bool(Type, Value), !, Opt =.. [Name,Value], Options = [Opt|OptionsT], opt_parse(T, Positional, OptionsT, M, POptions). take_long_(Long, T, Positional, Options, M, POptions) :- % --long in(M:opt_type(Long, Name, Type)), !, ( T = [VAtom|T1] -> opt_value(Type, Long, VAtom, Value), Opt =.. [Name,Value], Options = [Opt|OptionsT], opt_parse(T1, Positional, OptionsT, M, POptions) ; opt_error(missing_value(Long, Type)) ). take_long_(Long, _, _, _, M, _) :- opt_error(unknown_option(M:Long)). take_shorts([], T, Positional, Options, M, POptions) :- opt_parse(T, Positional, Options, M, POptions). take_shorts([H|T], Argv, Positional, Options, M, POptions) :- opt_bool_type(H, Name, Value, M), !, Opt =.. [Name,Value], Options = [Opt|OptionsT], take_shorts(T, Argv, Positional, OptionsT, M, POptions). take_shorts([H|T], Argv, Positional, Options, M, POptions) :- in(M:opt_type(H, Name, Type)), !, ( T == [] -> ( Argv = [VAtom|ArgvT] -> opt_value(Type, H, VAtom, Value), Opt =.. [Name,Value], Options = [Opt|OptionsT], take_shorts(T, ArgvT, Positional, OptionsT, M, POptions) ; opt_error(missing_value(H, Type)) ) ; atom_chars(VAtom, T), opt_value(Type, H, VAtom, Value), Opt =.. [Name,Value], Options = [Opt|OptionsT], take_shorts([], Argv, Positional, OptionsT, M, POptions) ). take_shorts([H|_], _, _, _, M, _) :- opt_error(unknown_option(M:H)). opt_bool_type(Opt, Name, Value, M) :- in(M:opt_type(Opt, Name, Type)), type_bool(Type, Value). type_bool(Type, Value) :- ( Type == boolean -> Value = true ; Type = boolean(Value) ). type_optional_bool((A|B), Value) => ( type_optional_bool(A, Value) -> true ; type_optional_bool(B, Value) ). type_optional_bool(Type, Value) => type_bool(Type, Value). negate(true, false). negate(false, true). %! opt_value(+Type, +Opt, +VAtom, -Value) is det. % % @error opt_error(Error) opt_value(Type, _Opt, VAtom, Value) :- opt_convert(Type, VAtom, Value), !. opt_value(Type, Opt, VAtom, _) :- opt_error(value_type(Opt, Type, VAtom)). %! opt_convert(+Type, +VAtom, -Value) is semidet. opt_convert(A|B, Spec, Value) :- ( opt_convert(A, Spec, Value) -> true ; opt_convert(B, Spec, Value) ). opt_convert(boolean, Spec, Value) :- to_bool(Spec, Value). opt_convert(boolean(_), Spec, Value) :- to_bool(Spec, Value). opt_convert(number, Spec, Value) :- atom_number(Spec, Value). opt_convert(integer, Spec, Value) :- atom_number(Spec, Value), integer(Value). opt_convert(float, Spec, Value) :- atom_number(Spec, Value0), Value is float(Value0). opt_convert(nonneg, Spec, Value) :- atom_number(Spec, Value), integer(Value), Value >= 0. opt_convert(natural, Spec, Value) :- atom_number(Spec, Value), integer(Value), Value >= 1. opt_convert(between(Low, High), Spec, Value) :- atom_number(Spec, Value0), ( ( float(Low) ; float(High) ) -> Value is float(Value0) ; integer(Value0), Value = Value0 ), Value >= Low, Value =< High. opt_convert(atom, Value, Value). opt_convert(oneof(List), Value, Value) :- memberchk(Value, List). opt_convert(string, Value0, Value) :- atom_string(Value0, Value). opt_convert(file, Spec, Value) :- prolog_to_os_filename(Value, Spec). opt_convert(file(Access), Spec, Value) :- ( Spec == '-' -> Value = '-' ; prolog_to_os_filename(Value, Spec), ( access_file(Value, Access) -> true ; opt_error(access_file(Spec, Access)) ) ). opt_convert(directory, Spec, Value) :- prolog_to_os_filename(Value, Spec). opt_convert(directory(Access), Spec, Value) :- prolog_to_os_filename(Value, Spec), access_directory(Value, Access). opt_convert(term, Spec, Value) :- term_string(Value, Spec, []). opt_convert(term(Options), Spec, Value) :- term_string(Term, Spec, Options), ( option(variable_names(Bindings), Options) -> Value = Term-Bindings ; Value = Term ). access_directory(Dir, read) => exists_directory(Dir), access_file(Dir, read). access_directory(Dir, write) => exists_directory(Dir), access_file(Dir, write). access_directory(Dir, create) => ( exists_directory(Dir) -> access_file(Dir, write) ; \+ exists_file(Dir), file_directory_name(Dir, Parent), exists_directory(Parent), access_file(Parent, write) ). to_bool(true, true). to_bool('True', true). to_bool('TRUE', true). to_bool(on, true). to_bool('On', true). to_bool(yes, true). to_bool('Yes', true). to_bool('1', true). to_bool(false, false). to_bool('False', false). to_bool('FALSE', false). to_bool(off, false). to_bool('Off', false). to_bool(no, false). to_bool('No', false). to_bool('0', false). %! argv_usage(:Level) is det. % % Use print_message/2 to print a usage message at Level. To print the % message as plain text indefault color, use `debug`. Other meaningful % options are `informational` or `warning`. The help page consists of % four sections, two of which are optional: % % 1. The __header__ is created from opt_help(help(header), String). % It is optional. % 2. The __usage__ is added by default. The part behind % ``Usage: `` is by default ``[options]`` and can be % overruled using opt_help(help(usage), String). % 3. The actual option descriptions. The options are presented % in the order they are defined in opt_type/3. Subsequent % options for the same _destination_ (option name) are joined % with the first. % 4. The _footer__ is created from opt_help(help(footer), String). % It is optional. % % The help provided by help(header), help(usage) and help(footer) are % either a simple string or a list of elements as defined by % print_message_lines/3. In the latter case, the construct `\Callable` % can be used to call a DCG rule in the module from which the user % calls argv_options/3. For example, we can add a bold title using % % opt_help(help(header), [ansi(bold, '~w', ['My title'])]). argv_usage(M:Level) :- print_message(Level, opt_usage(M)). :- multifile prolog:message//1. prolog:message(opt_usage(M)) --> usage(M). usage(M) --> usage_text(M:header), usage_line(M), usage_text(M:description), usage_options(M), usage_text(M:footer). %! usage_text(:Which)// is det. % % Emit a user element. This may use elements as defined by % print_message_lines/3 or can be a simple string. usage_text(M:Which) --> { in(M:opt_help(help(Which), Help)) }, !, ( {Which == header ; Which == description} -> user_text(M:Help), [nl, nl] ; [nl, nl], user_text(M:Help) ). usage_text(_) --> []. user_text(M:Entries) --> { is_list(Entries) }, !, sequence(help_elem(M), Entries). :- if(current_predicate(print_markdown/2)). user_text(_:md(Help)) --> !, { with_output_to(string(String), ( current_output(S), set_stream(S, tty(true)), print_markdown(Help, []))) }, [ '~s'-[String] ]. :- else. user_text(_:md(Help)) --> !, [ '~w'-[Help] ]. :- endif. user_text(_:Help) --> [ '~w'-[Help] ]. help_elem(M, \Callable) --> { callable(Callable) }, call(M:Callable), !. help_elem(_M, Elem) --> [ Elem ]. usage_line(M) --> { findall(Help, in(M:opt_help(help(usage), Help)), HelpLines) }, [ ansi(comment, 'Usage: ', []) ], ( {HelpLines == []} -> cmdline(M), [ ' [options]'-[] ] ; sequence(usage_line(M), [nl], HelpLines) ), [ nl, nl ]. usage_line(M, Help) --> [ '~t~8|'-[] ], cmdline(M), user_text(M:Help). cmdline(_M) --> { current_prolog_flag(app_name, App), !, current_prolog_flag(os_argv, [Argv0|_]) }, cmdarg(Argv0), [' '-[], ansi(bold, '~w', [App])]. cmdline(_M) --> { current_prolog_flag(associated_file, AbsFile), file_base_name(AbsFile, Base), current_prolog_flag(os_argv, Argv), append(Pre, [File|_], Argv), file_base_name(File, Base), append(Pre, [File], Cmd), ! }, sequence(cmdarg, [' '-[]], Cmd). cmdline(_M) --> { current_prolog_flag(saved_program, true), current_prolog_flag(os_argv, OsArgv), append(_, ['-x', State|_], OsArgv), ! }, cmdarg(State). cmdline(_M) --> { current_prolog_flag(os_argv, [Argv0|_]) }, cmdarg(Argv0). cmdarg(A) --> [ '~w'-[A] ]. %! usage_options(+Module)// % % Find the defined options and display help on them. Uses opt_type/3 % to find the options and their type, opt_help/2 to find the option % help comment and opt_meta/2 for _meta types_. usage_options(M) --> { findall(Opt, get_option(M, Opt), Opts), maplist(options_width, Opts, OptWidths), max_list(OptWidths, MaxOptWidth), tty_width(Width), OptColW is min(MaxOptWidth, 30), HelpColW is Width-4-OptColW }, [ ansi(comment, 'Options:', []), nl ], sequence(opt_usage(OptColW, HelpColW), [nl], Opts). % Just catch/3 is enough, but dependency tracking in e.g., % list_undefined/0 still considers this a missing dependency. :- if(current_predicate(tty_size/2)). tty_width(Width) :- catch(tty_size(_, Width), _, Width = 80). :- else. tty_width(80). :- endif. opt_usage(OptColW, HelpColW, opt(_Name, Type, Short, Long, Help, Meta)) --> options(Type, Short, Long, Meta), [ '~t~*:| '-[OptColW] ], help_text(Help, OptColW, HelpColW). help_text([First|Lines], Indent, _Width) --> !, [ '~w'-[First], nl ], sequence(rest_line(Indent), [nl], Lines). help_text(Text, _Indent, Width) --> { string_length(Text, Len), Len =< Width }, !, [ '~w'-[Text] ]. help_text(Text, Indent, Width) --> { wrap_text(Width, Text, [First|Lines]) }, [ '~w'-[First], nl ], sequence(rest_line(Indent), [nl], Lines). rest_line(Indent, Line) --> [ '~t~*| ~w'-[Indent, Line] ]. %! wrap_text(+Width, +Text, -Wrapped) % % Simple text wrapper. Breaks Text into words and creates lines with % minimally one word and as many additional words as fit in Width. % Wrapped is a list of strings. wrap_text(Width, Text, Wrapped) :- split_string(Text, " \t\n", " \t\n", Words), wrap_lines(Words, Width, Wrapped). wrap_lines([], _, []). wrap_lines([H|T0], Width, [Line|Lines]) :- !, string_length(H, Len), take_line(T0, T1, Width, Len, LineWords), atomics_to_string([H|LineWords], " ", Line), wrap_lines(T1, Width, Lines). take_line([H|T0], T, Width, Here, [H|Line]) :- string_length(H, Len), NewHere is Here+Len+1, NewHere =< Width, !, take_line(T0, T, Width, NewHere, Line). take_line(T, T, _, _, []). %! options(+Type, +ShortOpt, +LongOpts, +Meta)// % % Emit a line with options. options(Type, ShortOpt, LongOpts, Meta) --> { append(ShortOpt, LongOpts, Opts) }, sequence(option(Type, Meta), [', '-[]], Opts). option(boolean, _, Opt) --> opt(Opt). option(_Type, [Meta], Opt) --> \+ { short_opt(Opt) }, !, opt(Opt), [ '[='-[], ansi(var, '~w', [Meta]), ']'-[] ]. option(_Type, Meta, Opt) --> opt(Opt), ( { short_opt(Opt) } -> [ ' '-[] ] ; [ '='-[] ] ), [ ansi(var, '~w', [Meta]) ]. %! options_width(+Opt, -Width) is det. % % Compute the width of the column we need for the options. options_width(opt(_Name, boolean, Short, Long, _Help, _Meta), W) => length(Short, SCount), length(Long, LCount), maplist(atom_length, Long, LLens), sum_list(LLens, LLen), W is ((SCount+LCount)-1)*2 + % ', ' seps SCount*2 + LCount*2 + LLen. options_width(opt(_Name, _Type, Short, Long, _Help, Meta), W) => length(Short, SCount), length(Long, LCount), ( Meta = [MName] -> atom_length(MName, MLen0), MLen is MLen0+2 ; atom_length(Meta, MLen) ), maplist(atom_length, Long, LLens), sum_list(LLens, LLen), W is ((SCount+LCount)-1)*2 + % ', ' seps SCount*3 + SCount*MLen + LCount*3 + LLen + LCount*MLen. %! get_option(+Module, -Opt) is multi. % % Get a description for a single option. Opt is a term % % opt(Name, Type, ShortFlags, Longflags, Help, Meta). get_option(M, opt(help, boolean, [h,?], [help], Help, -)) :- \+ in(M:opt_type(_, help, boolean)), % user defined help ( in(M:opt_help(help, Help)) -> true ; Help = "Show this help message and exit" ). get_option(M, opt(Name, TypeName, Short, Long, Help, Meta)) :- findall(Name, in(M:opt_type(_, Name, _)), Names), list_to_set(Names, UNames), member(Name, UNames), findall(Opt-Type, in(M:opt_type(Opt, Name, Type)), Pairs), option_type(Name, Pairs, TypeT), functor(TypeT, TypeName, _), pairs_keys(Pairs, Opts), partition(short_opt, Opts, Short, Long), ( in(M:opt_help(Name, Help)) -> true ; Help = '' ), ( in(M:opt_meta(Name, Meta0)) -> true ; type_name(TypeT, Meta0) -> true ; upcase_atom(TypeName, Meta0) ), ( \+ type_bool(TypeT, _), type_optional_bool(TypeT, _) -> Meta = [Meta0] ; Meta = Meta0 ). type_name(oneof(Values), Name) :- atomics_to_string(Values, ",", S0), format(atom(Name), '{~w}', [S0]). option_type(Name, Pairs, Type) :- pairs_values(Pairs, Types), sort(Types, [Type|UTypes]), ( UTypes = [] -> true ; print_message(warning, error(opt_error(multiple_types(Name, [Type|UTypes])),_)) ). %! in(:Goal) % % As call/1, but fails silently if there is no predicate that % implements Goal. in(Goal) :- pi_head(PI, Goal), current_predicate(PI), call(Goal). short_opt(Opt) :- atom_length(Opt, 1). /******************************* * OPT ERROR HANDLING * *******************************/ %! opt_error(+Error) % % @error opt_error(Term) opt_error(Error) :- throw(error(opt_error(Error), _)). :- multifile prolog:error_message//1. prolog:error_message(opt_error(Error)) --> opt_error(Error). opt_error(unknown_option(M:Opt)) --> [ 'Unknown option: '-[] ], opt(Opt), hint_help(M). opt_error(missing_value(Opt, Type)) --> [ 'Option '-[] ], opt(Opt), [ ' requires an argument (of type ~p)'-[Type] ]. opt_error(value_type(Opt, Type, Found)) --> [ 'Option '-[] ], opt(Opt), [' requires'], type(Type), [ ' (found '-[], ansi(code, '~w', [Found]), ')'-[] ]. opt_error(access_file(File, exist)) --> [ 'File '-[], ansi(code, '~w', [File]), ' does not exist'-[] ]. opt_error(access_file(File, Access)) --> { access_verb(Access, Verb) }, [ 'Cannot access file '-[], ansi(code, '~w', [File]), ' for '-[], ansi(code, '~w', [Verb]) ]. access_verb(read, reading). access_verb(write, writing). access_verb(append, writing). access_verb(execute, executing). hint_help(M) --> { in(M:opt_type(Opt, help, boolean)) }, !, [ ' (' ], opt(Opt), [' for help)']. hint_help(_) --> [ ' (-h for help)'-[] ]. opt(Opt) --> { short_opt(Opt) }, !, [ ansi(bold, '-~w', [Opt]) ]. opt(Opt) --> [ ansi(bold, '--~w', [Opt]) ]. type(A|B) --> type(A), [' or'], type(B). type(oneof([One])) --> !, [ ' ' ], atom(One). type(oneof(List)) --> !, [ ' one of '-[] ], sequence(atom, [', '], List). type(between(Low, High)) --> !, [ ' a number '-[], ansi(code, '~w', [Low]), '..', ansi(code, '~w', [High]) ]. type(nonneg) --> [ ' a non-negative integer'-[] ]. type(natural) --> [ ' a positive integer (>= 1)'-[] ]. type(file(Access)) --> [ ' a file with ~w access'-[Access] ]. type(Type) --> [ ' an argument of type '-[], ansi(code, '~w', [Type]) ]. atom(A) --> [ ansi(code, '~w', [A]) ]. /******************************* * DEBUG SUPPORT * *******************************/ %! cli_parse_debug_options(+OptionsIn, -Options) is det. % % Parse certain commandline options for debugging and development % purposes. Options processed are below. Note that the option % argument is an atom such that these options may be activated as % e.g., ``--debug='http(_)'``. % % - debug(Topic) % Call debug(Topic). See debug/1 and debug/3. % - spy(Predicate) % Place a spy-point on Predicate. % - gspy(Predicate) % As spy using the graphical debugger. See tspy/1. % - interactive(true) % Start the Prolog toplevel after main/1 completes. cli_parse_debug_options([], []). cli_parse_debug_options([H|T0], Opts) :- debug_option(H), !, cli_parse_debug_options(T0, Opts). cli_parse_debug_options([H|T0], [H|T]) :- cli_parse_debug_options(T0, T). %! cli_debug_opt_type(-Flag, -Option, -Type). %! cli_debug_opt_help(-Option, -Message). %! cli_debug_opt_meta(-Option, -Arg). % % Implements opt_type/3, opt_help/2 and opt_meta/2 for debug % arguments. Applications that wish to use these features can call % these predicates from their own hook. Fot example: % % ``` % opt_type(..., ..., ...). % application types % opt_type(Flag, Opt, Type) :- % cli_debug_opt_type(Flag, Opt, Type). % % similar for opt_help/2 and opt_meta/2 % % main(Argv) :- % argv_options(Argv, Positional, Options0), % cli_parse_debug_options(Options0, Options), % ... % ``` cli_debug_opt_type(debug, debug, string). cli_debug_opt_type(spy, spy, string). cli_debug_opt_type(gspy, gspy, string). cli_debug_opt_type(interactive, interactive, boolean). cli_debug_opt_help(debug, "Call debug(Topic). See debug/1 and debug/3. \c Multiple topics may be separated by : or ;"). cli_debug_opt_help(spy, "Place a spy-point on Predicate. \c Multiple topics may be separated by : or ;"). cli_debug_opt_help(gspy, "As --spy using the graphical debugger. See tspy/1 \c Multiple topics may be separated by `;`"). cli_debug_opt_help(interactive, "Start the Prolog toplevel after main/1 completes."). cli_debug_opt_meta(debug, 'TOPICS'). cli_debug_opt_meta(spy, 'PREDICATES'). cli_debug_opt_meta(gspy, 'PREDICATES'). :- meta_predicate spy_from_string(1, +). debug_option(interactive(true)) :- asserta(interactive). debug_option(debug(Spec)) :- split_string(Spec, ";", "", Specs), maplist(debug_from_string, Specs). debug_option(spy(Spec)) :- split_string(Spec, ";", "", Specs), maplist(spy_from_string(spy), Specs). debug_option(gspy(Spec)) :- split_string(Spec, ";", "", Specs), maplist(spy_from_string(cli_gspy), Specs). debug_from_string(TopicS) :- term_string(Topic, TopicS), debug(Topic). spy_from_string(Pred, Spec) :- atom_pi(Spec, PI), call(Pred, PI). cli_gspy(PI) :- ( exists_source(library(threadutil)) -> use_module(library(threadutil), [tspy/1]), Goal = tspy(PI) ; exists_source(library(gui_tracer)) -> use_module(library(gui_tracer), [gspy/1]), Goal = gspy(PI) ; Goal = spy(PI) ), call(Goal). atom_pi(Atom, Module:PI) :- split(Atom, :, Module, PiAtom), !, atom_pi(PiAtom, PI). atom_pi(Atom, Name//Arity) :- split(Atom, //, Name, Arity), !. atom_pi(Atom, Name/Arity) :- split(Atom, /, Name, Arity), !. atom_pi(Atom, _) :- format(user_error, 'Invalid predicate indicator: "~w"~n', [Atom]), halt(1). split(Atom, Sep, Before, After) :- sub_atom(Atom, BL, _, AL, Sep), !, sub_atom(Atom, 0, BL, _, Before), sub_atom(Atom, _, AL, 0, AfterAtom), ( atom_number(AfterAtom, After) -> true ; After = AfterAtom ). %! cli_enable_development_system % % Re-enable the development environment. Currently re-enables xpce if % this was loaded, but not initialised and causes the interactive % toplevel to be re-enabled. % % This predicate may be called from main/1 to enter the Prolog % toplevel rather than terminating the application after main/1 % completes. cli_enable_development_system :- on_signal(int, _, debug), set_prolog_flag(xpce_threaded, true), set_prolog_flag(message_ide, true), ( current_prolog_flag(xpce_version, _) -> use_module(library(pce_dispatch)), memberchk(Goal, [pce_dispatch([])]), call(Goal) ; true ), set_prolog_flag(toplevel_goal, prolog). /******************************* * IDE SUPPORT * *******************************/ :- multifile prolog:called_by/2. prolog:called_by(main, [main(_)]). prolog:called_by(argv_options(_,_,_), [ opt_type(_,_,_), opt_help(_,_), opt_meta(_,_) ]).