@comment %**start of header (This is for running Texinfo on a region.) @setfilename rltech.info @synindex fn vr @comment %**end of header (This is for running Texinfo on a region.) @setchapternewpage odd @ifinfo This document describes the GNU Readline Library, a utility for aiding in the consitency of user interface across discrete programs that need to provide a command line interface. Copyright (C) 1988 Free Software Foundation, Inc. Permission is granted to make and distribute verbatim copies of this manual provided the copyright notice and this permission notice pare preserved on all copies. @ignore Permission is granted to process this file through TeX and print the results, provided the printed document carries copying permission notice identical to this one except for the removal of this paragraph (this paragraph not being relevant to the printed manual). @end ignore Permission is granted to copy and distribute modified versions of this manual under the conditions for verbatim copying, provided that the entire resulting derived work is distributed under the terms of a permission notice identical to this one. Permission is granted to copy and distribute translations of this manual into another language, under the above conditions for modified versions, except that this permission notice may be stated in a translation approved by the Foundation. @end ifinfo @node Programming with GNU Readline @chapter Programming with GNU Readline This manual describes the interface between the GNU Readline Library and user programs. If you are a programmer, and you wish to include the features found in GNU Readline in your own programs, such as completion, line editing, and interactive history manipulation, this documentation is for you. @menu * Default Behaviour:: Using the default behaviour of Readline. * Custom Functions:: Adding your own functions to Readline. * Custom Completers:: Supplanting or supplementing Readline's completion functions. @end menu @node Default Behaviour @section Default Behaviour Many programs provide a command line interface, such as @code{mail}, @code{ftp}, and @code{sh}. For such programs, the default behaviour of Readline is sufficient. This section describes how to use Readline in the simplest way possible, perhaps to replace calls in your code to @code{gets ()}. @findex readline () @cindex readline, function The function @code{readline} prints a prompt and then reads and returns a single line of text from the user. The line which @code{readline ()} returns is allocated with @code{malloc ()}; you should @code{free ()} the line when you are done with it. The declaration for @code{readline} in ANSI C is @example @code{char *readline (char *@var{prompt});} @end example So, one might say @example @code{char *line = readline ("Enter a line: ");} @end example in order to read a line of text from the user. The line which is returned has the final newline removed, so only the text of the line remains. If readline encounters an @code{EOF} while reading the line, and the line is empty at that point, then @code{(char *)NULL} is returned. Otherwise, the line is ended just as if a newline was typed. If you want the user to be able to get at the line later, (with @key{C-p} for example), you must call @code{add_history ()} to save the line away in a @dfn{history} list of such lines. @example @code{add_history (line)}; @end example For full details on the GNU History Library, see the associated manual. It is polite to avoid saving empty lines on the history list, since it is rare than someone has a burning need to reuse a blank line. Here is a function which usefully replaces the standard @code{gets ()} library function: @example /* A static variable for holding the line. */ static char *line_read = (char *)NULL; /* Read a string, and return a pointer to it. Returns NULL on EOF. */ char * do_gets () @{ /* If the buffer has already been allocated, return the memory to the free pool. */ if (line_read != (char *)NULL) @{ free (line_read); line_read = (char *)NULL; @} /* Get a line from the user. */ line_read = readline (""); /* If the line has any text in it, save it on the history. */ if (line_read && *line_read) add_history (line_read); return (line_read); @} @end example The above code gives the user the default behaviour of @key{TAB} completion: completion on file names. If you do not want readline to complete on filenames, you can change the binding of the @key{TAB} key with @code{rl_bind_key ()}. @findex rl_bind_key () @example @code{int rl_bind_key (int @var{key}, (int (*)())@var{function});} @end example @code{rl_bind_key ()} takes 2 arguments; @var{key} is the character that you want to bind, and @var{function} is the address of the function to run when @var{key} is pressed. Binding @key{TAB} to @code{rl_insert ()} makes @key{TAB} just insert itself. @code{rl_bind_key ()} returns non-zero if @var{key} is not a valid ASCII character code (between 0 and 255). @example @code{rl_bind_key ('\t', rl_insert);} @end example This code should be executed once at the start of your program; you might write a function called @code{initialize_readline ()} which performs this and other desired initializations, such as installing custom completers, etc. @node Custom Functions @section Custom Functions Readline provides a great many functions for manipulating the text of the line. But it isn't possible to anticipate the needs of all programs. This section describes the various functions and variables defined in within the Readline library which allow a user program to add customized functionality to Readline. @menu * The Function Type:: C declarations to make code readable. * Function Naming:: How to give a function you write a name. * Keymaps:: Making keymaps. * Binding Keys:: Changing Keymaps. * Function Writing:: Variables and calling conventions. * Allowing Undoing:: How to make your functions undoable. @end menu @node The Function Type @subsection The Function Type For the sake of readabilty, we declare a new type of object, called @dfn{Function}. A @code{Function} is a C language function which returns an @code{int}. The type declaration for @code{Function} is: @noindent @code{typedef int Function ();} The reason for declaring this new type is to make it easier to write code describing pointers to C functions. Let us say we had a variable called @var{func} which was a pointer to a function. Instead of the classic C declaration @code{int (*)()func;} we have @code{Function *func;} @node Function Naming @subsection Naming a Function The user can dynamically change the bindings of keys while using Readline. This is done by representing the function with a descriptive name. The user is able to type the descriptive name when referring to the function. Thus, in an init file, one might find @example Meta-Rubout: backward-kill-word @end example This binds the keystroke @key{Meta-Rubout} to the function @emph{descriptively} named @code{backward-kill-word}. You, as the programmer, should bind the functions you write to descriptive names as well. Readline provides a function for doing that: @defun rl_add_defun (char *name, Function *function, int key) Add @var{name} to the list of named functions. Make @var{function} be the function that gets called. If @var{key} is not -1, then bind it to @var{function} using @code{rl_bind_key ()}. @end defun Using this function alone is sufficient for most applications. It is the recommended way to add a few functions to the default functions that Readline has built in already. If you need to do more or different things than adding a function to Readline, you may need to use the underlying functions described below. @node Keymaps @subsection Selecting a Keymap Key bindings take place on a @dfn{keymap}. The keymap is the association between the keys that the user types and the functions that get run. You can make your own keymaps, copy existing keymaps, and tell Readline which keymap to use. @defun {Keymap rl_make_bare_keymap} () Returns a new, empty keymap. The space for the keymap is allocated with @code{malloc ()}; you should @code{free ()} it when you are done. @end defun @defun {Keymap rl_copy_keymap} (Keymap map) Return a new keymap which is a copy of @var{map}. @end defun @defun {Keymap rl_make_keymap} () Return a new keymap with the printing characters bound to rl_insert, the lowercase Meta characters bound to run their equivalents, and the Meta digits bound to produce numeric arguments. @end defun @node Binding Keys @subsection Binding Keys You associate keys with functions through the keymap. Here are functions for doing that. @defun {int rl_bind_key} (int key, Function *function) Binds @var{key} to @var{function} in the currently selected keymap. Returns non-zero in the case of an invalid @var{key}. @end defun @defun {int rl_bind_key_in_map} (int key, Function *function, Keymap map) Bind @var{key} to @var{function} in @var{map}. Returns non-zero in the case of an invalid @var{key}. @end defun @defun {int rl_unbind_key} (int key) Make @var{key} do nothing in the currently selected keymap. Returns non-zero in case of error. @end defun @defun {int rl_unbind_key_in_map} (int key, Keymap map) Make @var{key} be bound to the null function in @var{map}. Returns non-zero in case of error. @end defun @defun rl_generic_bind (int type, char *keyseq, char *data, Keymap map) Bind the key sequence represented by the string @var{keyseq} to the arbitrary pointer @var{data}. @var{type} says what kind of data is pointed to by @var{data}; right now this can be a function (@code{ISFUNC}), a macro (@code{ISMACR}), or a keymap (@code{ISKMAP}). This makes new keymaps as necessary. The initial place to do bindings is in @var{map}. @end defun @node Function Writing @subsection Writing a New Function In order to write new functions for Readline, you need to know the calling conventions for keyboard invoked functions, and the names of the variables that describe the current state of the line gathered so far. @defvar {char *rl_line_buffer} This is the line gathered so far. You are welcome to modify the contents of this, but see Undoing, below. @end defvar @defvar {int rl_point} The offset of the current cursor position in @var{rl_line_buffer}. @end defvar @defvar {int rl_end} The number of characters present in @code{rl_line_buffer}. When @code{rl_point} is at the end of the line, then @code{rl_point} and @code{rl_end} are equal. @end defvar The calling sequence for a command @code{foo} looks like @example @code{foo (int count, int key)} @end example where @var{count} is the numeric argument (or 1 if defaulted) and @var{key} is the key that invoked this function. It is completely up to the function as to what should be done with the numeric argument; some functions use it as a repeat count, other functions as a flag, and some choose to ignore it. In general, if a function uses the numeric argument as a repeat count, it should be able to do something useful with a negative argument as well as a positive argument. At the very least, it should be aware that it can be passed a negative argument. @node Allowing Undoing @subsection Allowing Undoing Supporting the undo command is a painless thing to do, and makes your functions much more useful to the end user. It is certainly easy to try something if you know you can undo it. I could use an undo function for the stock market. If your function simply inserts text once, or deletes text once, and it calls @code{rl_insert_text ()} or @code{rl_delete_text ()} to do it, then undoing is already done for you automatically, and you can safely skip this section. If you do multiple insertions or multiple deletions, or any combination of these operations, you should group them together into one operation. This can be done with @code{rl_begin_undo_group ()} and @code{rl_end_undo_group ()}. @defun rl_begin_undo_group () Begins saving undo information in a group construct. The undo information usually comes from calls to @code{rl_insert_text ()} and @code{rl_delete_text ()}, but they could be direct calls to @code{rl_add_undo ()}. @end defun @defun rl_end_undo_group () Closes the current undo group started with @code{rl_begin_undo_group ()}. There should be exactly one call to @code{rl_end_undo_group ()} for every call to @code{rl_begin_undo_group ()}. @end defun Finally, if you neither insert nor delete text, but directly modify the existing text (e.g. change its case), you call @code{rl_modifying ()} once, just before you modify the text. You must supply the indices of the text range that you are going to modify. @defun rl_modifying (int start, int end) Tell Readline to save the text between @var{start} and @var{end} as a single undo unit. It is assumed that subsequent to this call you will modify that range of text in some way. @end defun @subsection An Example Here is a function which changes lowercase characters to the uppercase equivalents, and uppercase characters to the lowercase equivalents. If this function was bound to @samp{M-c}, then typing @samp{M-c} would change the case of the character under point. Typing @samp{10 M-c} would change the case of the following 10 characters, leaving the cursor on the last character changed. @example /* Invert the case of the COUNT following characters. */ invert_case_line (count, key) int count, key; @{ register int start, end; start = rl_point; if (count < 0) @{ direction = -1; count = -count; @} else direction = 1; /* Find the end of the range to modify. */ end = start + (count * direction); /* Force it to be within range. */ if (end > rl_end) end = rl_end; else if (end < 0) end = -1; if (start > end) @{ int temp = start; start = end; end = temp; @} if (start == end) return; /* Tell readline that we are modifying the line, so save the undo information. */ rl_modifying (start, end); for (; start != end; start += direction) @{ if (uppercase_p (rl_line_buffer[start])) rl_line_buffer[start] = to_lower (rl_line_buffer[start]); else if (lowercase_p (rl_line_buffer[start])) rl_line_buffer[start] = to_upper (rl_line_buffer[start]); @} /* Move point to on top of the last character changed. */ rl_point = end - direction; @} @end example @node Custom Completers @section Custom Completers Typically, a program that reads commands from the user has a way of disambiguating between commands and data. If your program is one of these, then it can provide completion for either commands, or data, or both commands and data. The following sections describe how your program and Readline cooperate to provide this service to end users. @menu * How Completing Works:: The logic used to do completion. * Completion Functions:: Functions provided by Readline. * Completion Variables:: Variables which control completion. * A Short Completion Example:: An example of writing completer subroutines. @end menu @node How Completing Works @subsection How Completing Works In order to complete some text, the full list of possible completions must be available. That is to say, it is not possible to accurately expand a partial word without knowing what all of the possible words that make sense in that context are. The GNU Readline library provides the user interface to completion, and additionally, two of the most common completion functions; filename and username. For completing other types of text, you must write your own completion function. This section describes exactly what those functions must do, and provides an example function. There are three major functions used to perform completion: @enumerate @item The user-interface function @code{rl_complete ()}. This function is called interactively with the same calling conventions as other functions in readline intended for interactive use; i.e. @var{count}, and @code{invoking-key}. It isolates the word to be completed and calls @code{completion_matches ()} to generate a list of possible completions. It then either lists the possible completions or actually performs the completion, depending on which behaviour is desired. @item The internal function @code{completion_matches ()} uses your @dfn{generator} function to generate the list of possible matches, and then returns the array of these matches. You should place the address of your generator function in @code{rl_completion_entry_function}. @item The generator function is called repeatedly from @code{completion_matches ()}, returning a string each time. The arguments to the generator function are @var{text} and @var{state}. @var{text} is the partial word to be completed. @var{state} is zero the first time the function is called, and a positive non-zero integer for each subsequent call. When the generator function returns @code{(char *)NULL} this signals @code{completion_matches ()} that there are no more possibilities left. @end enumerate @defun rl_complete (int ignore, int invoking_key) Complete the word at or before point. You have supplied the function that does the initial simple matching selection algorithm (see @code{completion_matches ()}). The default is to do filename completion. @end defun Note that @code{rl_complete ()} has the identical calling conventions as any other key-invokable function; this is because by default it is bound to the @samp{TAB} key. @defvar {Function *rl_completion_entry_function} This is a pointer to the generator function for @code{completion_matches ()}. If the value of @code{rl_completion_entry_function} is @code{(Function *)NULL} then the default filename generator function is used, namely @code{filename_entry_function ()}. @end defvar @node Completion Functions @subsection Completion Functions Here is the complete list of callable completion functions present in Readline. @defun rl_complete_internal (int what_to_do) Complete the word at or before point. @var{what_to_do} says what to do with the completion. A value of @samp{?} means list the possible completions. @samp{TAB} means do standard completion. @samp{*} means insert all of the possible completions. @end defun @defun rl_complete (int ignore, int invoking_key) Complete the word at or before point. You have supplied the function that does the initial simple matching selection algorithm (see @code{completion_matches ()}). The default is to do filename completion. This just calls @code{rl_complete_internal ()} with an argument of @samp{TAB}. @end defun @defun rl_possible_completions () List the possible completions. See description of @code{rl_complete ()}. This just calls @code{rl_complete_internal ()} with an argument of @samp{?}. @end defun @defun {char **completion_matches} (char *text, char *(*entry_function) ()) Returns an array of @code{(char *)} which is a list of completions for @var{text}. If there are no completions, returns @code{(char **)NULL}. The first entry in the returned array is the substitution for @var{text}. The remaining entries are the possible completions. The array is terminated with a @code{NULL} pointer. @var{entry_function} is a function of two args, and returns a @code{(char *)}. The first argument is @var{text}. The second is a state argument; it is zero on the first call, and non-zero on subsequent calls. It returns a @code{NULL} pointer to the caller when there are no more matches. @end defun @defun {char *filename_completion_function} (char *text, int state) A generator function for filename completion in the general case. Note that completion in the Bash shell is a little different because of all the pathnames that must be followed when looking up the completion for a command. @end defun @defun {char *username_completion_function} (char *text, int state) A completion generator for usernames. @var{text} contains a partial username preceded by a random character (usually @samp{~}). @end defun @node Completion Variables @subsection Completion Variables @defvar {Function *rl_completion_entry_function} A pointer to the generator function for @code{completion_matches ()}. @code{NULL} means to use @code{filename_entry_function ()}, the default filename completer. @end defvar @defvar {Function *rl_attempted_completion_function} A pointer to an alternative function to create matches. The function is called with @var{text}, @var{start}, and @var{end}. @var{start} and @var{end} are indices in @code{rl_line_buffer} saying what the boundaries of @var{text} are. If this function exists and returns @code{NULL} then @code{rl_complete ()} will call the value of @code{rl_completion_entry_function} to generate matches, otherwise the array of strings returned will be used. @end defvar @defvar {int rl_completion_query_items} Up to this many items will be displayed in response to a possible-completions call. After that, we ask the user if she is sure she wants to see them all. The default value is 100. @end defvar @defvar {char *rl_basic_word_break_characters} The basic list of characters that signal a break between words for the completer routine. The contents of this variable is what breaks words in the Bash shell, i.e. " \t\n\"\\'`@@$><=". @end defvar @defvar {char *rl_completer_word_break_characters} The list of characters that signal a break between words for @code{rl_complete_internal ()}. The default list is the contents of @code{rl_basic_word_break_characters}. @end defvar @defvar {char *rl_special_prefixes} The list of characters that are word break characters, but should be left in @var{text} when it is passed to the completion function. Programs can use this to help determine what kind of completing to do. @end defvar @defvar {int rl_ignore_completion_duplicates} If non-zero, then disallow duplicates in the matches. Default is 1. @end defvar @defvar {int rl_filename_completion_desired} Non-zero means that the results of the matches are to be treated as filenames. This is @emph{always} zero on entry, and can only be changed within a completion entry generator function. @end defvar @defvar {Function *rl_ignore_some_completions_function} This function, if defined, is called by the completer when real filename completion is done, after all the matching names have been generated. It is passed a @code{NULL} terminated array of pointers to @code{(char *)} known as @var{matches} in the code. The 1st element (@code{matches[0]}) is the maximal substring that is common to all matches. This function can re-arrange the list of matches as required, but each deleted element of the array must be @code{free()}'d. @end defvar @node A Short Completion Example @subsection A Short Completion Example Here is a small application demonstrating the use of the GNU Readline library. It is called @code{fileman}, and the source code resides in @file{readline/examples/fileman.c}. This sample application provides completion of command names, line editing features, and access to the history list. @page @smallexample /* fileman.c -- A tiny application which demonstrates how to use the GNU Readline library. This application interactively allows users to manipulate files and their modes. */ #include #include #include #include #include #include #include /* The names of functions that actually do the manipulation. */ int com_list (), com_view (), com_rename (), com_stat (), com_pwd (); int com_delete (), com_help (), com_cd (), com_quit (); /* A structure which contains information on the commands this program can understand. */ typedef struct @{ char *name; /* User printable name of the function. */ Function *func; /* Function to call to do the job. */ char *doc; /* Documentation for this function. */ @} COMMAND; COMMAND commands[] = @{ @{ "cd", com_cd, "Change to directory DIR" @}, @{ "delete", com_delete, "Delete FILE" @}, @{ "help", com_help, "Display this text" @}, @{ "?", com_help, "Synonym for `help'" @}, @{ "list", com_list, "List files in DIR" @}, @{ "ls", com_list, "Synonym for `list'" @}, @{ "pwd", com_pwd, "Print the current working directory" @}, @{ "quit", com_quit, "Quit using Fileman" @}, @{ "rename", com_rename, "Rename FILE to NEWNAME" @}, @{ "stat", com_stat, "Print out statistics on FILE" @}, @{ "view", com_view, "View the contents of FILE" @}, @{ (char *)NULL, (Function *)NULL, (char *)NULL @} @}; /* The name of this program, as taken from argv[0]. */ char *progname; /* When non-zero, this global means the user is done using this program. */ int done = 0; @page main (argc, argv) int argc; char **argv; @{ progname = argv[0]; initialize_readline (); /* Bind our completer. */ /* Loop reading and executing lines until the user quits. */ while (!done) @{ char *line; line = readline ("FileMan: "); if (!line) @{ done = 1; /* Encountered EOF at top level. */ @} else @{ /* Remove leading and trailing whitespace from the line. Then, if there is anything left, add it to the history list and execute it. */ stripwhite (line); if (*line) @{ add_history (line); execute_line (line); @} @} if (line) free (line); @} exit (0); @} /* Execute a command line. */ execute_line (line) char *line; @{ register int i; COMMAND *find_command (), *command; char *word; /* Isolate the command word. */ i = 0; while (line[i] && !whitespace (line[i])) i++; word = line; if (line[i]) line[i++] = '\0'; command = find_command (word); if (!command) @{ fprintf (stderr, "%s: No such command for FileMan.\n", word); return; @} /* Get argument to command, if any. */ while (whitespace (line[i])) i++; word = line + i; /* Call the function. */ (*(command->func)) (word); @} /* Look up NAME as the name of a command, and return a pointer to that command. Return a NULL pointer if NAME isn't a command name. */ COMMAND * find_command (name) char *name; @{ register int i; for (i = 0; commands[i].name; i++) if (strcmp (name, commands[i].name) == 0) return (&commands[i]); return ((COMMAND *)NULL); @} /* Strip whitespace from the start and end of STRING. */ stripwhite (string) char *string; @{ register int i = 0; while (whitespace (string[i])) i++; if (i) strcpy (string, string + i); i = strlen (string) - 1; while (i > 0 && whitespace (string[i])) i--; string[++i] = '\0'; @} @page /* **************************************************************** */ /* */ /* Interface to Readline Completion */ /* */ /* **************************************************************** */ /* Tell the GNU Readline library how to complete. We want to try to complete on command names if this is the first word in the line, or on filenames if not. */ initialize_readline () @{ char **fileman_completion (); /* Allow conditional parsing of the ~/.inputrc file. */ rl_readline_name = "FileMan"; /* Tell the completer that we want a crack first. */ rl_attempted_completion_function = (Function *)fileman_completion; @} /* Attempt to complete on the contents of TEXT. START and END show the region of TEXT that contains the word to complete. We can use the entire line in case we want to do some simple parsing. Return the array of matches, or NULL if there aren't any. */ char ** fileman_completion (text, start, end) char *text; int start, end; @{ char **matches; char *command_generator (); matches = (char **)NULL; /* If this word is at the start of the line, then it is a command to complete. Otherwise it is the name of a file in the current directory. */ if (start == 0) matches = completion_matches (text, command_generator); return (matches); @} /* Generator function for command completion. STATE lets us know whether to start from scratch; without any state (i.e. STATE == 0), then we start at the top of the list. */ char * command_generator (text, state) char *text; int state; @{ static int list_index, len; char *name; /* If this is a new word to complete, initialize now. This includes saving the length of TEXT for efficiency, and initializing the index variable to 0. */ if (!state) @{ list_index = 0; len = strlen (text); @} /* Return the next name which partially matches from the command list. */ while (name = commands[list_index].name) @{ list_index++; if (strncmp (name, text, len) == 0) return (name); @} /* If no names matched, then return NULL. */ return ((char *)NULL); @} @page /* **************************************************************** */ /* */ /* FileMan Commands */ /* */ /* **************************************************************** */ /* String to pass to system (). This is for the LIST, VIEW and RENAME commands. */ static char syscom[1024]; /* List the file(s) named in arg. */ com_list (arg) char *arg; @{ sprintf (syscom, "ls -FClg %s", arg); system (syscom); @} com_view (arg) char *arg; @{ if (!valid_argument ("view", arg)) return; sprintf (syscom, "cat %s | more", arg); system (syscom); @} com_rename (arg) char *arg; @{ too_dangerous ("rename"); @} com_stat (arg) char *arg; @{ struct stat finfo; if (!valid_argument ("stat", arg)) return; if (stat (arg, &finfo) == -1) @{ perror (arg); return; @} printf ("Statistics for `%s':\n", arg); printf ("%s has %d link%s, and is %d bytes in length.\n", arg, finfo.st_nlink, (finfo.st_nlink == 1) ? "" : "s", finfo.st_size); printf (" Created on: %s", ctime (&finfo.st_ctime)); printf (" Last access at: %s", ctime (&finfo.st_atime)); printf ("Last modified at: %s", ctime (&finfo.st_mtime)); @} com_delete (arg) char *arg; @{ too_dangerous ("delete"); @} /* Print out help for ARG, or for all of the commands if ARG is not present. */ com_help (arg) char *arg; @{ register int i; int printed = 0; for (i = 0; commands[i].name; i++) @{ if (!*arg || (strcmp (arg, commands[i].name) == 0)) @{ printf ("%s\t\t%s.\n", commands[i].name, commands[i].doc); printed++; @} @} if (!printed) @{ printf ("No commands match `%s'. Possibilties are:\n", arg); for (i = 0; commands[i].name; i++) @{ /* Print in six columns. */ if (printed == 6) @{ printed = 0; printf ("\n"); @} printf ("%s\t", commands[i].name); printed++; @} if (printed) printf ("\n"); @} @} /* Change to the directory ARG. */ com_cd (arg) char *arg; @{ if (chdir (arg) == -1) perror (arg); com_pwd (""); @} /* Print out the current working directory. */ com_pwd (ignore) char *ignore; @{ char dir[1024]; (void) getwd (dir); printf ("Current directory is %s\n", dir); @} /* The user wishes to quit using this program. Just set DONE non-zero. */ com_quit (arg) char *arg; @{ done = 1; @} /* Function which tells you that you can't do this. */ too_dangerous (caller) char *caller; @{ fprintf (stderr, "%s: Too dangerous for me to distribute. Write it yourself.\n", caller); @} /* Return non-zero if ARG is a valid argument for CALLER, else print an error message and return zero. */ int valid_argument (caller, arg) char *caller, *arg; @{ if (!arg || !*arg) @{ fprintf (stderr, "%s: Argument required.\n", caller); return (0); @} return (1); @} @end smallexample