#[cfg(feature = "yaml")] use std::collections::BTreeMap; use std::rc::Rc; use std::ffi::{OsStr, OsString}; #[cfg(any(target_os = "windows", target_arch = "wasm32"))] use osstringext::OsStrExt3; #[cfg(not(any(target_os = "windows", target_arch = "wasm32")))] use std::os::unix::ffi::OsStrExt; use std::env; #[cfg(feature = "yaml")] use yaml_rust::Yaml; use map::VecMap; use usage_parser::UsageParser; use args::settings::ArgSettings; use args::arg_builder::{Base, Switched, Valued}; /// The abstract representation of a command line argument. Used to set all the options and /// relationships that define a valid argument for the program. /// /// There are two methods for constructing [`Arg`]s, using the builder pattern and setting options /// manually, or using a usage string which is far less verbose but has fewer options. You can also /// use a combination of the two methods to achieve the best of both worlds. /// /// # Examples /// /// ```rust /// # use clap::Arg; /// // Using the traditional builder pattern and setting each option manually /// let cfg = Arg::with_name("config") /// .short("c") /// .long("config") /// .takes_value(true) /// .value_name("FILE") /// .help("Provides a config file to myprog"); /// // Using a usage string (setting a similar argument to the one above) /// let input = Arg::from_usage("-i, --input=[FILE] 'Provides an input file to the program'"); /// ``` /// [`Arg`]: ./struct.Arg.html #[allow(missing_debug_implementations)] #[derive(Default, Clone)] pub struct Arg<'a, 'b> where 'a: 'b, { #[doc(hidden)] pub b: Base<'a, 'b>, #[doc(hidden)] pub s: Switched<'b>, #[doc(hidden)] pub v: Valued<'a, 'b>, #[doc(hidden)] pub index: Option, #[doc(hidden)] pub r_ifs: Option>, } impl<'a, 'b> Arg<'a, 'b> { /// Creates a new instance of [`Arg`] using a unique string name. The name will be used to get /// information about whether or not the argument was used at runtime, get values, set /// relationships with other args, etc.. /// /// **NOTE:** In the case of arguments that take values (i.e. [`Arg::takes_value(true)`]) /// and positional arguments (i.e. those without a preceding `-` or `--`) the name will also /// be displayed when the user prints the usage/help information of the program. /// /// # Examples /// /// ```rust /// # use clap::{App, Arg}; /// Arg::with_name("config") /// # ; /// ``` /// [`Arg::takes_value(true)`]: ./struct.Arg.html#method.takes_value /// [`Arg`]: ./struct.Arg.html pub fn with_name(n: &'a str) -> Self { Arg { b: Base::new(n), ..Default::default() } } /// Creates a new instance of [`Arg`] from a .yml (YAML) file. /// /// # Examples /// /// ```ignore /// # #[macro_use] /// # extern crate clap; /// # use clap::Arg; /// # fn main() { /// let yml = load_yaml!("arg.yml"); /// let arg = Arg::from_yaml(yml); /// # } /// ``` /// [`Arg`]: ./struct.Arg.html #[cfg(feature = "yaml")] pub fn from_yaml(y: &BTreeMap) -> Arg { // We WANT this to panic on error...so expect() is good. let name_yml = y.keys().nth(0).unwrap(); let name_str = name_yml.as_str().unwrap(); let mut a = Arg::with_name(name_str); let arg_settings = y.get(name_yml).unwrap().as_hash().unwrap(); for (k, v) in arg_settings.iter() { a = match k.as_str().unwrap() { "short" => yaml_to_str!(a, v, short), "long" => yaml_to_str!(a, v, long), "aliases" => yaml_vec_or_str!(v, a, alias), "help" => yaml_to_str!(a, v, help), "long_help" => yaml_to_str!(a, v, long_help), "required" => yaml_to_bool!(a, v, required), "required_if" => yaml_tuple2!(a, v, required_if), "required_ifs" => yaml_tuple2!(a, v, required_if), "takes_value" => yaml_to_bool!(a, v, takes_value), "index" => yaml_to_u64!(a, v, index), "global" => yaml_to_bool!(a, v, global), "multiple" => yaml_to_bool!(a, v, multiple), "hidden" => yaml_to_bool!(a, v, hidden), "next_line_help" => yaml_to_bool!(a, v, next_line_help), "empty_values" => yaml_to_bool!(a, v, empty_values), "group" => yaml_to_str!(a, v, group), "number_of_values" => yaml_to_u64!(a, v, number_of_values), "max_values" => yaml_to_u64!(a, v, max_values), "min_values" => yaml_to_u64!(a, v, min_values), "value_name" => yaml_to_str!(a, v, value_name), "use_delimiter" => yaml_to_bool!(a, v, use_delimiter), "allow_hyphen_values" => yaml_to_bool!(a, v, allow_hyphen_values), "last" => yaml_to_bool!(a, v, last), "require_delimiter" => yaml_to_bool!(a, v, require_delimiter), "value_delimiter" => yaml_to_str!(a, v, value_delimiter), "required_unless" => yaml_to_str!(a, v, required_unless), "display_order" => yaml_to_usize!(a, v, display_order), "default_value" => yaml_to_str!(a, v, default_value), "default_value_if" => yaml_tuple3!(a, v, default_value_if), "default_value_ifs" => yaml_tuple3!(a, v, default_value_if), "env" => yaml_to_str!(a, v, env), "value_names" => yaml_vec_or_str!(v, a, value_name), "groups" => yaml_vec_or_str!(v, a, group), "requires" => yaml_vec_or_str!(v, a, requires), "requires_if" => yaml_tuple2!(a, v, requires_if), "requires_ifs" => yaml_tuple2!(a, v, requires_if), "conflicts_with" => yaml_vec_or_str!(v, a, conflicts_with), "overrides_with" => yaml_vec_or_str!(v, a, overrides_with), "possible_values" => yaml_vec_or_str!(v, a, possible_value), "case_insensitive" => yaml_to_bool!(a, v, case_insensitive), "required_unless_one" => yaml_vec_or_str!(v, a, required_unless), "required_unless_all" => { a = yaml_vec_or_str!(v, a, required_unless); a.setb(ArgSettings::RequiredUnlessAll); a } s => panic!( "Unknown Arg setting '{}' in YAML file for arg '{}'", s, name_str ), } } a } /// Creates a new instance of [`Arg`] from a usage string. Allows creation of basic settings /// for the [`Arg`]. The syntax is flexible, but there are some rules to follow. /// /// **NOTE**: Not all settings may be set using the usage string method. Some properties are /// only available via the builder pattern. /// /// **NOTE**: Only ASCII values are officially supported in [`Arg::from_usage`] strings. Some /// UTF-8 codepoints may work just fine, but this is not guaranteed. /// /// # Syntax /// /// Usage strings typically following the form: /// /// ```notrust /// [explicit name] [short] [long] [value names] [help string] /// ``` /// /// This is not a hard rule as the attributes can appear in other orders. There are also /// several additional sigils which denote additional settings. Below are the details of each /// portion of the string. /// /// ### Explicit Name /// /// This is an optional field, if it's omitted the argument will use one of the additional /// fields as the name using the following priority order: /// /// * Explicit Name (This always takes precedence when present) /// * Long /// * Short /// * Value Name /// /// `clap` determines explicit names as the first string of characters between either `[]` or /// `<>` where `[]` has the dual notation of meaning the argument is optional, and `<>` meaning /// the argument is required. /// /// Explicit names may be followed by: /// * The multiple denotation `...` /// /// Example explicit names as follows (`ename` for an optional argument, and `rname` for a /// required argument): /// /// ```notrust /// [ename] -s, --long 'some flag' /// -r, --longer 'some other flag' /// ``` /// /// ### Short /// /// This is set by placing a single character after a leading `-`. /// /// Shorts may be followed by /// * The multiple denotation `...` /// * An optional comma `,` which is cosmetic only /// * Value notation /// /// Example shorts are as follows (`-s`, and `-r`): /// /// ```notrust /// -s, --long 'some flag' /// -r [val], --longer 'some option' /// ``` /// /// ### Long /// /// This is set by placing a word (no spaces) after a leading `--`. /// /// Shorts may be followed by /// * The multiple denotation `...` /// * Value notation /// /// Example longs are as follows (`--some`, and `--rapid`): /// /// ```notrust /// -s, --some 'some flag' /// --rapid=[FILE] 'some option' /// ``` /// /// ### Values (Value Notation) /// /// This is set by placing a word(s) between `[]` or `<>` optionally after `=` (although this /// is cosmetic only and does not affect functionality). If an explicit name has **not** been /// set, using `<>` will denote a required argument, and `[]` will denote an optional argument /// /// Values may be followed by /// * The multiple denotation `...` /// * More Value notation /// /// More than one value will also implicitly set the arguments number of values, i.e. having /// two values, `--option [val1] [val2]` specifies that in order for option to be satisified it /// must receive exactly two values /// /// Example values are as follows (`FILE`, and `SPEED`): /// /// ```notrust /// -s, --some [FILE] 'some option' /// --rapid=... 'some required multiple option' /// ``` /// /// ### Help String /// /// The help string is denoted between a pair of single quotes `''` and may contain any /// characters. /// /// Example help strings are as follows: /// /// ```notrust /// -s, --some [FILE] 'some option' /// --rapid=... 'some required multiple option' /// ``` /// /// ### Additional Sigils /// /// Multiple notation `...` (three consecutive dots/periods) specifies that this argument may /// be used multiple times. Do not confuse multiple occurrences (`...`) with multiple values. /// `--option val1 val2` is a single occurrence with multiple values. `--flag --flag` is /// multiple occurrences (and then you can obviously have instances of both as well) /// /// # Examples /// /// ```rust /// # use clap::{App, Arg}; /// App::new("prog") /// .args(&[ /// Arg::from_usage("--config 'a required file for the configuration and no short'"), /// Arg::from_usage("-d, --debug... 'turns on debugging information and allows multiples'"), /// Arg::from_usage("[input] 'an optional input file to use'") /// ]) /// # ; /// ``` /// [`Arg`]: ./struct.Arg.html /// [`Arg::from_usage`]: ./struct.Arg.html#method.from_usage pub fn from_usage(u: &'a str) -> Self { let parser = UsageParser::from_usage(u); parser.parse() } /// Sets the short version of the argument without the preceding `-`. /// /// By default `clap` automatically assigns `V` and `h` to the auto-generated `version` and /// `help` arguments respectively. You may use the uppercase `V` or lowercase `h` for your own /// arguments, in which case `clap` simply will not assign those to the auto-generated /// `version` or `help` arguments. /// /// **NOTE:** Any leading `-` characters will be stripped, and only the first /// non `-` character will be used as the [`short`] version /// /// # Examples /// /// To set [`short`] use a single valid UTF-8 code point. If you supply a leading `-` such as /// `-c`, the `-` will be stripped. /// /// ```rust /// # use clap::{App, Arg}; /// Arg::with_name("config") /// .short("c") /// # ; /// ``` /// /// Setting [`short`] allows using the argument via a single hyphen (`-`) such as `-c` /// /// ```rust /// # use clap::{App, Arg}; /// let m = App::new("prog") /// .arg(Arg::with_name("config") /// .short("c")) /// .get_matches_from(vec![ /// "prog", "-c" /// ]); /// /// assert!(m.is_present("config")); /// ``` /// [`short`]: ./struct.Arg.html#method.short pub fn short>(mut self, s: S) -> Self { self.s.short = s.as_ref().trim_left_matches(|c| c == '-').chars().nth(0); self } /// Sets the long version of the argument without the preceding `--`. /// /// By default `clap` automatically assigns `version` and `help` to the auto-generated /// `version` and `help` arguments respectively. You may use the word `version` or `help` for /// the long form of your own arguments, in which case `clap` simply will not assign those to /// the auto-generated `version` or `help` arguments. /// /// **NOTE:** Any leading `-` characters will be stripped /// /// # Examples /// /// To set `long` use a word containing valid UTF-8 codepoints. If you supply a double leading /// `--` such as `--config` they will be stripped. Hyphens in the middle of the word, however, /// will *not* be stripped (i.e. `config-file` is allowed) /// /// ```rust /// # use clap::{App, Arg}; /// Arg::with_name("cfg") /// .long("config") /// # ; /// ``` /// /// Setting `long` allows using the argument via a double hyphen (`--`) such as `--config` /// /// ```rust /// # use clap::{App, Arg}; /// let m = App::new("prog") /// .arg(Arg::with_name("cfg") /// .long("config")) /// .get_matches_from(vec![ /// "prog", "--config" /// ]); /// /// assert!(m.is_present("cfg")); /// ``` pub fn long(mut self, l: &'b str) -> Self { self.s.long = Some(l.trim_left_matches(|c| c == '-')); self } /// Allows adding a [`Arg`] alias, which function as "hidden" arguments that /// automatically dispatch as if this argument was used. This is more efficient, and easier /// than creating multiple hidden arguments as one only needs to check for the existence of /// this command, and not all variants. /// /// # Examples /// /// ```rust /// # use clap::{App, Arg}; /// let m = App::new("prog") /// .arg(Arg::with_name("test") /// .long("test") /// .alias("alias") /// .takes_value(true)) /// .get_matches_from(vec![ /// "prog", "--alias", "cool" /// ]); /// assert!(m.is_present("test")); /// assert_eq!(m.value_of("test"), Some("cool")); /// ``` /// [`Arg`]: ./struct.Arg.html pub fn alias>(mut self, name: S) -> Self { if let Some(ref mut als) = self.s.aliases { als.push((name.into(), false)); } else { self.s.aliases = Some(vec![(name.into(), false)]); } self } /// Allows adding [`Arg`] aliases, which function as "hidden" arguments that /// automatically dispatch as if this argument was used. This is more efficient, and easier /// than creating multiple hidden subcommands as one only needs to check for the existence of /// this command, and not all variants. /// /// # Examples /// /// ```rust /// # use clap::{App, Arg}; /// let m = App::new("prog") /// .arg(Arg::with_name("test") /// .long("test") /// .aliases(&["do-stuff", "do-tests", "tests"]) /// .help("the file to add") /// .required(false)) /// .get_matches_from(vec![ /// "prog", "--do-tests" /// ]); /// assert!(m.is_present("test")); /// ``` /// [`Arg`]: ./struct.Arg.html pub fn aliases(mut self, names: &[&'b str]) -> Self { if let Some(ref mut als) = self.s.aliases { for n in names { als.push((n, false)); } } else { self.s.aliases = Some(names.iter().map(|n| (*n, false)).collect::>()); } self } /// Allows adding a [`Arg`] alias that functions exactly like those defined with /// [`Arg::alias`], except that they are visible inside the help message. /// /// # Examples /// /// ```rust /// # use clap::{App, Arg}; /// let m = App::new("prog") /// .arg(Arg::with_name("test") /// .visible_alias("something-awesome") /// .long("test") /// .takes_value(true)) /// .get_matches_from(vec![ /// "prog", "--something-awesome", "coffee" /// ]); /// assert!(m.is_present("test")); /// assert_eq!(m.value_of("test"), Some("coffee")); /// ``` /// [`Arg`]: ./struct.Arg.html /// [`App::alias`]: ./struct.Arg.html#method.alias pub fn visible_alias>(mut self, name: S) -> Self { if let Some(ref mut als) = self.s.aliases { als.push((name.into(), true)); } else { self.s.aliases = Some(vec![(name.into(), true)]); } self } /// Allows adding multiple [`Arg`] aliases that functions exactly like those defined /// with [`Arg::aliases`], except that they are visible inside the help message. /// /// # Examples /// /// ```rust /// # use clap::{App, Arg}; /// let m = App::new("prog") /// .arg(Arg::with_name("test") /// .long("test") /// .visible_aliases(&["something", "awesome", "cool"])) /// .get_matches_from(vec![ /// "prog", "--awesome" /// ]); /// assert!(m.is_present("test")); /// ``` /// [`Arg`]: ./struct.Arg.html /// [`App::aliases`]: ./struct.Arg.html#method.aliases pub fn visible_aliases(mut self, names: &[&'b str]) -> Self { if let Some(ref mut als) = self.s.aliases { for n in names { als.push((n, true)); } } else { self.s.aliases = Some(names.iter().map(|n| (*n, true)).collect::>()); } self } /// Sets the short help text of the argument that will be displayed to the user when they print /// the help information with `-h`. Typically, this is a short (one line) description of the /// arg. /// /// **NOTE:** If only `Arg::help` is provided, and not [`Arg::long_help`] but the user requests /// `--help` clap will still display the contents of `help` appropriately /// /// **NOTE:** Only `Arg::help` is used in completion script generation in order to be concise /// /// # Examples /// /// Any valid UTF-8 is allowed in the help text. The one exception is when one wishes to /// include a newline in the help text and have the following text be properly aligned with all /// the other help text. /// /// ```rust /// # use clap::{App, Arg}; /// Arg::with_name("config") /// .help("The config file used by the myprog") /// # ; /// ``` /// /// Setting `help` displays a short message to the side of the argument when the user passes /// `-h` or `--help` (by default). /// /// ```rust /// # use clap::{App, Arg}; /// let m = App::new("prog") /// .arg(Arg::with_name("cfg") /// .long("config") /// .help("Some help text describing the --config arg")) /// .get_matches_from(vec![ /// "prog", "--help" /// ]); /// ``` /// /// The above example displays /// /// ```notrust /// helptest /// /// USAGE: /// helptest [FLAGS] /// /// FLAGS: /// --config Some help text describing the --config arg /// -h, --help Prints help information /// -V, --version Prints version information /// ``` /// [`Arg::long_help`]: ./struct.Arg.html#method.long_help pub fn help(mut self, h: &'b str) -> Self { self.b.help = Some(h); self } /// Sets the long help text of the argument that will be displayed to the user when they print /// the help information with `--help`. Typically this a more detailed (multi-line) message /// that describes the arg. /// /// **NOTE:** If only `long_help` is provided, and not [`Arg::help`] but the user requests `-h` /// clap will still display the contents of `long_help` appropriately /// /// **NOTE:** Only [`Arg::help`] is used in completion script generation in order to be concise /// /// # Examples /// /// Any valid UTF-8 is allowed in the help text. The one exception is when one wishes to /// include a newline in the help text and have the following text be properly aligned with all /// the other help text. /// /// ```rust /// # use clap::{App, Arg}; /// Arg::with_name("config") /// .long_help( /// "The config file used by the myprog must be in JSON format /// with only valid keys and may not contain other nonsense /// that cannot be read by this program. Obviously I'm going on /// and on, so I'll stop now.") /// # ; /// ``` /// /// Setting `help` displays a short message to the side of the argument when the user passes /// `-h` or `--help` (by default). /// /// ```rust /// # use clap::{App, Arg}; /// let m = App::new("prog") /// .arg(Arg::with_name("cfg") /// .long("config") /// .long_help( /// "The config file used by the myprog must be in JSON format /// with only valid keys and may not contain other nonsense /// that cannot be read by this program. Obviously I'm going on /// and on, so I'll stop now.")) /// .get_matches_from(vec![ /// "prog", "--help" /// ]); /// ``` /// /// The above example displays /// /// ```notrust /// helptest /// /// USAGE: /// helptest [FLAGS] /// /// FLAGS: /// --config /// The config file used by the myprog must be in JSON format /// with only valid keys and may not contain other nonsense /// that cannot be read by this program. Obviously I'm going on /// and on, so I'll stop now. /// /// -h, --help /// Prints help information /// /// -V, --version /// Prints version information /// ``` /// [`Arg::help`]: ./struct.Arg.html#method.help pub fn long_help(mut self, h: &'b str) -> Self { self.b.long_help = Some(h); self } /// Specifies that this arg is the last, or final, positional argument (i.e. has the highest /// index) and is *only* able to be accessed via the `--` syntax (i.e. `$ prog args -- /// last_arg`). Even, if no other arguments are left to parse, if the user omits the `--` syntax /// they will receive an [`UnknownArgument`] error. Setting an argument to `.last(true)` also /// allows one to access this arg early using the `--` syntax. Accessing an arg early, even with /// the `--` syntax is otherwise not possible. /// /// **NOTE:** This will change the usage string to look like `$ prog [FLAGS] [-- ]` if /// `ARG` is marked as `.last(true)`. /// /// **NOTE:** This setting will imply [`AppSettings::DontCollapseArgsInUsage`] because failing /// to set this can make the usage string very confusing. /// /// **NOTE**: This setting only applies to positional arguments, and has no affect on FLAGS / /// OPTIONS /// /// **CAUTION:** Setting an argument to `.last(true)` *and* having child subcommands is not /// recommended with the exception of *also* using [`AppSettings::ArgsNegateSubcommands`] /// (or [`AppSettings::SubcommandsNegateReqs`] if the argument marked `.last(true)` is also /// marked [`.required(true)`]) /// /// # Examples /// /// ```rust /// # use clap::Arg; /// Arg::with_name("args") /// .last(true) /// # ; /// ``` /// /// Setting [`Arg::last(true)`] ensures the arg has the highest [index] of all positional args /// and requires that the `--` syntax be used to access it early. /// /// ```rust /// # use clap::{App, Arg}; /// let res = App::new("prog") /// .arg(Arg::with_name("first")) /// .arg(Arg::with_name("second")) /// .arg(Arg::with_name("third").last(true)) /// .get_matches_from_safe(vec![ /// "prog", "one", "--", "three" /// ]); /// /// assert!(res.is_ok()); /// let m = res.unwrap(); /// assert_eq!(m.value_of("third"), Some("three")); /// assert!(m.value_of("second").is_none()); /// ``` /// /// Even if the positional argument marked `.last(true)` is the only argument left to parse, /// failing to use the `--` syntax results in an error. /// /// ```rust /// # use clap::{App, Arg, ErrorKind}; /// let res = App::new("prog") /// .arg(Arg::with_name("first")) /// .arg(Arg::with_name("second")) /// .arg(Arg::with_name("third").last(true)) /// .get_matches_from_safe(vec![ /// "prog", "one", "two", "three" /// ]); /// /// assert!(res.is_err()); /// assert_eq!(res.unwrap_err().kind, ErrorKind::UnknownArgument); /// ``` /// [`Arg::last(true)`]: ./struct.Arg.html#method.last /// [index]: ./struct.Arg.html#method.index /// [`AppSettings::DontCollapseArgsInUsage`]: ./enum.AppSettings.html#variant.DontCollapseArgsInUsage /// [`AppSettings::ArgsNegateSubcommands`]: ./enum.AppSettings.html#variant.ArgsNegateSubcommands /// [`AppSettings::SubcommandsNegateReqs`]: ./enum.AppSettings.html#variant.SubcommandsNegateReqs /// [`.required(true)`]: ./struct.Arg.html#method.required /// [`UnknownArgument`]: ./enum.ErrorKind.html#variant.UnknownArgument pub fn last(self, l: bool) -> Self { if l { self.set(ArgSettings::Last) } else { self.unset(ArgSettings::Last) } } /// Sets whether or not the argument is required by default. Required by default means it is /// required, when no other conflicting rules have been evaluated. Conflicting rules take /// precedence over being required. **Default:** `false` /// /// **NOTE:** Flags (i.e. not positional, or arguments that take values) cannot be required by /// default. This is simply because if a flag should be required, it should simply be implied /// as no additional information is required from user. Flags by their very nature are simply /// yes/no, or true/false. /// /// # Examples /// /// ```rust /// # use clap::Arg; /// Arg::with_name("config") /// .required(true) /// # ; /// ``` /// /// Setting [`Arg::required(true)`] requires that the argument be used at runtime. /// /// ```rust /// # use clap::{App, Arg}; /// let res = App::new("prog") /// .arg(Arg::with_name("cfg") /// .required(true) /// .takes_value(true) /// .long("config")) /// .get_matches_from_safe(vec![ /// "prog", "--config", "file.conf" /// ]); /// /// assert!(res.is_ok()); /// ``` /// /// Setting [`Arg::required(true)`] and *not* supplying that argument is an error. /// /// ```rust /// # use clap::{App, Arg, ErrorKind}; /// let res = App::new("prog") /// .arg(Arg::with_name("cfg") /// .required(true) /// .takes_value(true) /// .long("config")) /// .get_matches_from_safe(vec![ /// "prog" /// ]); /// /// assert!(res.is_err()); /// assert_eq!(res.unwrap_err().kind, ErrorKind::MissingRequiredArgument); /// ``` /// [`Arg::required(true)`]: ./struct.Arg.html#method.required pub fn required(self, r: bool) -> Self { if r { self.set(ArgSettings::Required) } else { self.unset(ArgSettings::Required) } } /// Requires that options use the `--option=val` syntax (i.e. an equals between the option and /// associated value) **Default:** `false` /// /// **NOTE:** This setting also removes the default of allowing empty values and implies /// [`Arg::empty_values(false)`]. /// /// # Examples /// /// ```rust /// # use clap::Arg; /// Arg::with_name("config") /// .long("config") /// .takes_value(true) /// .require_equals(true) /// # ; /// ``` /// /// Setting [`Arg::require_equals(true)`] requires that the option have an equals sign between /// it and the associated value. /// /// ```rust /// # use clap::{App, Arg}; /// let res = App::new("prog") /// .arg(Arg::with_name("cfg") /// .require_equals(true) /// .takes_value(true) /// .long("config")) /// .get_matches_from_safe(vec![ /// "prog", "--config=file.conf" /// ]); /// /// assert!(res.is_ok()); /// ``` /// /// Setting [`Arg::require_equals(true)`] and *not* supplying the equals will cause an error /// unless [`Arg::empty_values(true)`] is set. /// /// ```rust /// # use clap::{App, Arg, ErrorKind}; /// let res = App::new("prog") /// .arg(Arg::with_name("cfg") /// .require_equals(true) /// .takes_value(true) /// .long("config")) /// .get_matches_from_safe(vec![ /// "prog", "--config", "file.conf" /// ]); /// /// assert!(res.is_err()); /// assert_eq!(res.unwrap_err().kind, ErrorKind::EmptyValue); /// ``` /// [`Arg::require_equals(true)`]: ./struct.Arg.html#method.require_equals /// [`Arg::empty_values(true)`]: ./struct.Arg.html#method.empty_values /// [`Arg::empty_values(false)`]: ./struct.Arg.html#method.empty_values pub fn require_equals(mut self, r: bool) -> Self { if r { self.unsetb(ArgSettings::EmptyValues); self.set(ArgSettings::RequireEquals) } else { self.unset(ArgSettings::RequireEquals) } } /// Allows values which start with a leading hyphen (`-`) /// /// **WARNING**: Take caution when using this setting combined with [`Arg::multiple(true)`], as /// this becomes ambiguous `$ prog --arg -- -- val`. All three `--, --, val` will be values /// when the user may have thought the second `--` would constitute the normal, "Only /// positional args follow" idiom. To fix this, consider using [`Arg::number_of_values(1)`] /// /// **WARNING**: When building your CLIs, consider the effects of allowing leading hyphens and /// the user passing in a value that matches a valid short. For example `prog -opt -F` where /// `-F` is supposed to be a value, yet `-F` is *also* a valid short for another arg. Care should /// should be taken when designing these args. This is compounded by the ability to "stack" /// short args. I.e. if `-val` is supposed to be a value, but `-v`, `-a`, and `-l` are all valid /// shorts. /// /// # Examples /// /// ```rust /// # use clap::Arg; /// Arg::with_name("pattern") /// .allow_hyphen_values(true) /// # ; /// ``` /// /// ```rust /// # use clap::{App, Arg}; /// let m = App::new("prog") /// .arg(Arg::with_name("pat") /// .allow_hyphen_values(true) /// .takes_value(true) /// .long("pattern")) /// .get_matches_from(vec![ /// "prog", "--pattern", "-file" /// ]); /// /// assert_eq!(m.value_of("pat"), Some("-file")); /// ``` /// /// Not setting [`Arg::allow_hyphen_values(true)`] and supplying a value which starts with a /// hyphen is an error. /// /// ```rust /// # use clap::{App, Arg, ErrorKind}; /// let res = App::new("prog") /// .arg(Arg::with_name("pat") /// .takes_value(true) /// .long("pattern")) /// .get_matches_from_safe(vec![ /// "prog", "--pattern", "-file" /// ]); /// /// assert!(res.is_err()); /// assert_eq!(res.unwrap_err().kind, ErrorKind::UnknownArgument); /// ``` /// [`Arg::allow_hyphen_values(true)`]: ./struct.Arg.html#method.allow_hyphen_values /// [`Arg::multiple(true)`]: ./struct.Arg.html#method.multiple /// [`Arg::number_of_values(1)`]: ./struct.Arg.html#method.number_of_values pub fn allow_hyphen_values(self, a: bool) -> Self { if a { self.set(ArgSettings::AllowLeadingHyphen) } else { self.unset(ArgSettings::AllowLeadingHyphen) } } /// Sets an arg that override this arg's required setting. (i.e. this arg will be required /// unless this other argument is present). /// /// **Pro Tip:** Using [`Arg::required_unless`] implies [`Arg::required`] and is therefore not /// mandatory to also set. /// /// # Examples /// /// ```rust /// # use clap::Arg; /// Arg::with_name("config") /// .required_unless("debug") /// # ; /// ``` /// /// Setting [`Arg::required_unless(name)`] requires that the argument be used at runtime /// *unless* `name` is present. In the following example, the required argument is *not* /// provided, but it's not an error because the `unless` arg has been supplied. /// /// ```rust /// # use clap::{App, Arg}; /// let res = App::new("prog") /// .arg(Arg::with_name("cfg") /// .required_unless("dbg") /// .takes_value(true) /// .long("config")) /// .arg(Arg::with_name("dbg") /// .long("debug")) /// .get_matches_from_safe(vec![ /// "prog", "--debug" /// ]); /// /// assert!(res.is_ok()); /// ``` /// /// Setting [`Arg::required_unless(name)`] and *not* supplying `name` or this arg is an error. /// /// ```rust /// # use clap::{App, Arg, ErrorKind}; /// let res = App::new("prog") /// .arg(Arg::with_name("cfg") /// .required_unless("dbg") /// .takes_value(true) /// .long("config")) /// .arg(Arg::with_name("dbg") /// .long("debug")) /// .get_matches_from_safe(vec![ /// "prog" /// ]); /// /// assert!(res.is_err()); /// assert_eq!(res.unwrap_err().kind, ErrorKind::MissingRequiredArgument); /// ``` /// [`Arg::required_unless`]: ./struct.Arg.html#method.required_unless /// [`Arg::required`]: ./struct.Arg.html#method.required /// [`Arg::required_unless(name)`]: ./struct.Arg.html#method.required_unless pub fn required_unless(mut self, name: &'a str) -> Self { if let Some(ref mut vec) = self.b.r_unless { vec.push(name); } else { self.b.r_unless = Some(vec![name]); } self.required(true) } /// Sets args that override this arg's required setting. (i.e. this arg will be required unless /// all these other arguments are present). /// /// **NOTE:** If you wish for this argument to only be required if *one of* these args are /// present see [`Arg::required_unless_one`] /// /// # Examples /// /// ```rust /// # use clap::Arg; /// Arg::with_name("config") /// .required_unless_all(&["cfg", "dbg"]) /// # ; /// ``` /// /// Setting [`Arg::required_unless_all(names)`] requires that the argument be used at runtime /// *unless* *all* the args in `names` are present. In the following example, the required /// argument is *not* provided, but it's not an error because all the `unless` args have been /// supplied. /// /// ```rust /// # use clap::{App, Arg}; /// let res = App::new("prog") /// .arg(Arg::with_name("cfg") /// .required_unless_all(&["dbg", "infile"]) /// .takes_value(true) /// .long("config")) /// .arg(Arg::with_name("dbg") /// .long("debug")) /// .arg(Arg::with_name("infile") /// .short("i") /// .takes_value(true)) /// .get_matches_from_safe(vec![ /// "prog", "--debug", "-i", "file" /// ]); /// /// assert!(res.is_ok()); /// ``` /// /// Setting [`Arg::required_unless_all(names)`] and *not* supplying *all* of `names` or this /// arg is an error. /// /// ```rust /// # use clap::{App, Arg, ErrorKind}; /// let res = App::new("prog") /// .arg(Arg::with_name("cfg") /// .required_unless_all(&["dbg", "infile"]) /// .takes_value(true) /// .long("config")) /// .arg(Arg::with_name("dbg") /// .long("debug")) /// .arg(Arg::with_name("infile") /// .short("i") /// .takes_value(true)) /// .get_matches_from_safe(vec![ /// "prog" /// ]); /// /// assert!(res.is_err()); /// assert_eq!(res.unwrap_err().kind, ErrorKind::MissingRequiredArgument); /// ``` /// [`Arg::required_unless_one`]: ./struct.Arg.html#method.required_unless_one /// [`Arg::required_unless_all(names)`]: ./struct.Arg.html#method.required_unless_all pub fn required_unless_all(mut self, names: &[&'a str]) -> Self { if let Some(ref mut vec) = self.b.r_unless { for s in names { vec.push(s); } } else { self.b.r_unless = Some(names.iter().map(|s| *s).collect::>()); } self.setb(ArgSettings::RequiredUnlessAll); self.required(true) } /// Sets args that override this arg's [required] setting. (i.e. this arg will be required /// unless *at least one of* these other arguments are present). /// /// **NOTE:** If you wish for this argument to only be required if *all of* these args are /// present see [`Arg::required_unless_all`] /// /// # Examples /// /// ```rust /// # use clap::Arg; /// Arg::with_name("config") /// .required_unless_all(&["cfg", "dbg"]) /// # ; /// ``` /// /// Setting [`Arg::required_unless_one(names)`] requires that the argument be used at runtime /// *unless* *at least one of* the args in `names` are present. In the following example, the /// required argument is *not* provided, but it's not an error because one the `unless` args /// have been supplied. /// /// ```rust /// # use clap::{App, Arg}; /// let res = App::new("prog") /// .arg(Arg::with_name("cfg") /// .required_unless_one(&["dbg", "infile"]) /// .takes_value(true) /// .long("config")) /// .arg(Arg::with_name("dbg") /// .long("debug")) /// .arg(Arg::with_name("infile") /// .short("i") /// .takes_value(true)) /// .get_matches_from_safe(vec![ /// "prog", "--debug" /// ]); /// /// assert!(res.is_ok()); /// ``` /// /// Setting [`Arg::required_unless_one(names)`] and *not* supplying *at least one of* `names` /// or this arg is an error. /// /// ```rust /// # use clap::{App, Arg, ErrorKind}; /// let res = App::new("prog") /// .arg(Arg::with_name("cfg") /// .required_unless_one(&["dbg", "infile"]) /// .takes_value(true) /// .long("config")) /// .arg(Arg::with_name("dbg") /// .long("debug")) /// .arg(Arg::with_name("infile") /// .short("i") /// .takes_value(true)) /// .get_matches_from_safe(vec![ /// "prog" /// ]); /// /// assert!(res.is_err()); /// assert_eq!(res.unwrap_err().kind, ErrorKind::MissingRequiredArgument); /// ``` /// [required]: ./struct.Arg.html#method.required /// [`Arg::required_unless_one(names)`]: ./struct.Arg.html#method.required_unless_one /// [`Arg::required_unless_all`]: ./struct.Arg.html#method.required_unless_all pub fn required_unless_one(mut self, names: &[&'a str]) -> Self { if let Some(ref mut vec) = self.b.r_unless { for s in names { vec.push(s); } } else { self.b.r_unless = Some(names.iter().map(|s| *s).collect::>()); } self.required(true) } /// Sets a conflicting argument by name. I.e. when using this argument, /// the following argument can't be present and vice versa. /// /// **NOTE:** Conflicting rules take precedence over being required by default. Conflict rules /// only need to be set for one of the two arguments, they do not need to be set for each. /// /// **NOTE:** Defining a conflict is two-way, but does *not* need to defined for both arguments /// (i.e. if A conflicts with B, defining A.conflicts_with(B) is sufficient. You do not need /// need to also do B.conflicts_with(A)) /// /// # Examples /// /// ```rust /// # use clap::Arg; /// Arg::with_name("config") /// .conflicts_with("debug") /// # ; /// ``` /// /// Setting conflicting argument, and having both arguments present at runtime is an error. /// /// ```rust /// # use clap::{App, Arg, ErrorKind}; /// let res = App::new("prog") /// .arg(Arg::with_name("cfg") /// .takes_value(true) /// .conflicts_with("debug") /// .long("config")) /// .arg(Arg::with_name("debug") /// .long("debug")) /// .get_matches_from_safe(vec![ /// "prog", "--debug", "--config", "file.conf" /// ]); /// /// assert!(res.is_err()); /// assert_eq!(res.unwrap_err().kind, ErrorKind::ArgumentConflict); /// ``` pub fn conflicts_with(mut self, name: &'a str) -> Self { if let Some(ref mut vec) = self.b.blacklist { vec.push(name); } else { self.b.blacklist = Some(vec![name]); } self } /// The same as [`Arg::conflicts_with`] but allows specifying multiple two-way conlicts per /// argument. /// /// **NOTE:** Conflicting rules take precedence over being required by default. Conflict rules /// only need to be set for one of the two arguments, they do not need to be set for each. /// /// **NOTE:** Defining a conflict is two-way, but does *not* need to defined for both arguments /// (i.e. if A conflicts with B, defining A.conflicts_with(B) is sufficient. You do not need /// need to also do B.conflicts_with(A)) /// /// # Examples /// /// ```rust /// # use clap::Arg; /// Arg::with_name("config") /// .conflicts_with_all(&["debug", "input"]) /// # ; /// ``` /// /// Setting conflicting argument, and having any of the arguments present at runtime with a /// conflicting argument is an error. /// /// ```rust /// # use clap::{App, Arg, ErrorKind}; /// let res = App::new("prog") /// .arg(Arg::with_name("cfg") /// .takes_value(true) /// .conflicts_with_all(&["debug", "input"]) /// .long("config")) /// .arg(Arg::with_name("debug") /// .long("debug")) /// .arg(Arg::with_name("input") /// .index(1)) /// .get_matches_from_safe(vec![ /// "prog", "--config", "file.conf", "file.txt" /// ]); /// /// assert!(res.is_err()); /// assert_eq!(res.unwrap_err().kind, ErrorKind::ArgumentConflict); /// ``` /// [`Arg::conflicts_with`]: ./struct.Arg.html#method.conflicts_with pub fn conflicts_with_all(mut self, names: &[&'a str]) -> Self { if let Some(ref mut vec) = self.b.blacklist { for s in names { vec.push(s); } } else { self.b.blacklist = Some(names.iter().map(|s| *s).collect::>()); } self } /// Sets a overridable argument by name. I.e. this argument and the following argument /// will override each other in POSIX style (whichever argument was specified at runtime /// **last** "wins") /// /// **NOTE:** When an argument is overridden it is essentially as if it never was used, any /// conflicts, requirements, etc. are evaluated **after** all "overrides" have been removed /// /// **WARNING:** Positional arguments cannot override themselves (or we would never be able /// to advance to the next positional). If a positional agument lists itself as an override, /// it is simply ignored. /// /// # Examples /// /// ```rust /// # use clap::{App, Arg}; /// let m = App::new("prog") /// .arg(Arg::from_usage("-f, --flag 'some flag'") /// .conflicts_with("debug")) /// .arg(Arg::from_usage("-d, --debug 'other flag'")) /// .arg(Arg::from_usage("-c, --color 'third flag'") /// .overrides_with("flag")) /// .get_matches_from(vec![ /// "prog", "-f", "-d", "-c"]); /// // ^~~~~~~~~~~~^~~~~ flag is overridden by color /// /// assert!(m.is_present("color")); /// assert!(m.is_present("debug")); // even though flag conflicts with debug, it's as if flag /// // was never used because it was overridden with color /// assert!(!m.is_present("flag")); /// ``` /// Care must be taken when using this setting, and having an arg override with itself. This /// is common practice when supporting things like shell aliases, config files, etc. /// However, when combined with multiple values, it can get dicy. /// Here is how clap handles such situations: /// /// When a flag overrides itself, it's as if the flag was only ever used once (essentially /// preventing a "Unexpected multiple usage" error): /// /// ```rust /// # use clap::{App, Arg}; /// let m = App::new("posix") /// .arg(Arg::from_usage("--flag 'some flag'").overrides_with("flag")) /// .get_matches_from(vec!["posix", "--flag", "--flag"]); /// assert!(m.is_present("flag")); /// assert_eq!(m.occurrences_of("flag"), 1); /// ``` /// Making a arg `multiple(true)` and override itself is essentially meaningless. Therefore /// clap ignores an override of self if it's a flag and it already accepts multiple occurrences. /// /// ``` /// # use clap::{App, Arg}; /// let m = App::new("posix") /// .arg(Arg::from_usage("--flag... 'some flag'").overrides_with("flag")) /// .get_matches_from(vec!["", "--flag", "--flag", "--flag", "--flag"]); /// assert!(m.is_present("flag")); /// assert_eq!(m.occurrences_of("flag"), 4); /// ``` /// Now notice with options (which *do not* set `multiple(true)`), it's as if only the last /// occurrence happened. /// /// ``` /// # use clap::{App, Arg}; /// let m = App::new("posix") /// .arg(Arg::from_usage("--opt [val] 'some option'").overrides_with("opt")) /// .get_matches_from(vec!["", "--opt=some", "--opt=other"]); /// assert!(m.is_present("opt")); /// assert_eq!(m.occurrences_of("opt"), 1); /// assert_eq!(m.value_of("opt"), Some("other")); /// ``` /// /// Just like flags, options with `multiple(true)` set, will ignore the "override self" setting. /// /// ``` /// # use clap::{App, Arg}; /// let m = App::new("posix") /// .arg(Arg::from_usage("--opt [val]... 'some option'") /// .overrides_with("opt")) /// .get_matches_from(vec!["", "--opt", "first", "over", "--opt", "other", "val"]); /// assert!(m.is_present("opt")); /// assert_eq!(m.occurrences_of("opt"), 2); /// assert_eq!(m.values_of("opt").unwrap().collect::>(), &["first", "over", "other", "val"]); /// ``` /// /// A safe thing to do if you'd like to support an option which supports multiple values, but /// also is "overridable" by itself, is to use `use_delimiter(false)` and *not* use /// `multiple(true)` while telling users to seperate values with a comma (i.e. `val1,val2`) /// /// ``` /// # use clap::{App, Arg}; /// let m = App::new("posix") /// .arg(Arg::from_usage("--opt [val] 'some option'") /// .overrides_with("opt") /// .use_delimiter(false)) /// .get_matches_from(vec!["", "--opt=some,other", "--opt=one,two"]); /// assert!(m.is_present("opt")); /// assert_eq!(m.occurrences_of("opt"), 1); /// assert_eq!(m.values_of("opt").unwrap().collect::>(), &["one,two"]); /// ``` pub fn overrides_with(mut self, name: &'a str) -> Self { if let Some(ref mut vec) = self.b.overrides { vec.push(name); } else { self.b.overrides = Some(vec![name]); } self } /// Sets multiple mutually overridable arguments by name. I.e. this argument and the following /// argument will override each other in POSIX style (whichever argument was specified at /// runtime **last** "wins") /// /// **NOTE:** When an argument is overridden it is essentially as if it never was used, any /// conflicts, requirements, etc. are evaluated **after** all "overrides" have been removed /// /// # Examples /// /// ```rust /// # use clap::{App, Arg}; /// let m = App::new("prog") /// .arg(Arg::from_usage("-f, --flag 'some flag'") /// .conflicts_with("color")) /// .arg(Arg::from_usage("-d, --debug 'other flag'")) /// .arg(Arg::from_usage("-c, --color 'third flag'") /// .overrides_with_all(&["flag", "debug"])) /// .get_matches_from(vec![ /// "prog", "-f", "-d", "-c"]); /// // ^~~~~~^~~~~~~~~ flag and debug are overridden by color /// /// assert!(m.is_present("color")); // even though flag conflicts with color, it's as if flag /// // and debug were never used because they were overridden /// // with color /// assert!(!m.is_present("debug")); /// assert!(!m.is_present("flag")); /// ``` pub fn overrides_with_all(mut self, names: &[&'a str]) -> Self { if let Some(ref mut vec) = self.b.overrides { for s in names { vec.push(s); } } else { self.b.overrides = Some(names.iter().map(|s| *s).collect::>()); } self } /// Sets an argument by name that is required when this one is present I.e. when /// using this argument, the following argument *must* be present. /// /// **NOTE:** [Conflicting] rules and [override] rules take precedence over being required /// /// # Examples /// /// ```rust /// # use clap::Arg; /// Arg::with_name("config") /// .requires("input") /// # ; /// ``` /// /// Setting [`Arg::requires(name)`] requires that the argument be used at runtime if the /// defining argument is used. If the defining argument isn't used, the other argument isn't /// required /// /// ```rust /// # use clap::{App, Arg}; /// let res = App::new("prog") /// .arg(Arg::with_name("cfg") /// .takes_value(true) /// .requires("input") /// .long("config")) /// .arg(Arg::with_name("input") /// .index(1)) /// .get_matches_from_safe(vec![ /// "prog" /// ]); /// /// assert!(res.is_ok()); // We didn't use cfg, so input wasn't required /// ``` /// /// Setting [`Arg::requires(name)`] and *not* supplying that argument is an error. /// /// ```rust /// # use clap::{App, Arg, ErrorKind}; /// let res = App::new("prog") /// .arg(Arg::with_name("cfg") /// .takes_value(true) /// .requires("input") /// .long("config")) /// .arg(Arg::with_name("input") /// .index(1)) /// .get_matches_from_safe(vec![ /// "prog", "--config", "file.conf" /// ]); /// /// assert!(res.is_err()); /// assert_eq!(res.unwrap_err().kind, ErrorKind::MissingRequiredArgument); /// ``` /// [`Arg::requires(name)`]: ./struct.Arg.html#method.requires /// [Conflicting]: ./struct.Arg.html#method.conflicts_with /// [override]: ./struct.Arg.html#method.overrides_with pub fn requires(mut self, name: &'a str) -> Self { if let Some(ref mut vec) = self.b.requires { vec.push((None, name)); } else { let mut vec = vec![]; vec.push((None, name)); self.b.requires = Some(vec); } self } /// Allows a conditional requirement. The requirement will only become valid if this arg's value /// equals `val`. /// /// **NOTE:** If using YAML the values should be laid out as follows /// /// ```yaml /// requires_if: /// - [val, arg] /// ``` /// /// # Examples /// /// ```rust /// # use clap::Arg; /// Arg::with_name("config") /// .requires_if("val", "arg") /// # ; /// ``` /// /// Setting [`Arg::requires_if(val, arg)`] requires that the `arg` be used at runtime if the /// defining argument's value is equal to `val`. If the defining argument is anything other than /// `val`, the other argument isn't required. /// /// ```rust /// # use clap::{App, Arg}; /// let res = App::new("prog") /// .arg(Arg::with_name("cfg") /// .takes_value(true) /// .requires_if("my.cfg", "other") /// .long("config")) /// .arg(Arg::with_name("other")) /// .get_matches_from_safe(vec![ /// "prog", "--config", "some.cfg" /// ]); /// /// assert!(res.is_ok()); // We didn't use --config=my.cfg, so other wasn't required /// ``` /// /// Setting [`Arg::requires_if(val, arg)`] and setting the value to `val` but *not* supplying /// `arg` is an error. /// /// ```rust /// # use clap::{App, Arg, ErrorKind}; /// let res = App::new("prog") /// .arg(Arg::with_name("cfg") /// .takes_value(true) /// .requires_if("my.cfg", "input") /// .long("config")) /// .arg(Arg::with_name("input")) /// .get_matches_from_safe(vec![ /// "prog", "--config", "my.cfg" /// ]); /// /// assert!(res.is_err()); /// assert_eq!(res.unwrap_err().kind, ErrorKind::MissingRequiredArgument); /// ``` /// [`Arg::requires(name)`]: ./struct.Arg.html#method.requires /// [Conflicting]: ./struct.Arg.html#method.conflicts_with /// [override]: ./struct.Arg.html#method.overrides_with pub fn requires_if(mut self, val: &'b str, arg: &'a str) -> Self { if let Some(ref mut vec) = self.b.requires { vec.push((Some(val), arg)); } else { self.b.requires = Some(vec![(Some(val), arg)]); } self } /// Allows multiple conditional requirements. The requirement will only become valid if this arg's value /// equals `val`. /// /// **NOTE:** If using YAML the values should be laid out as follows /// /// ```yaml /// requires_if: /// - [val, arg] /// - [val2, arg2] /// ``` /// /// # Examples /// /// ```rust /// # use clap::Arg; /// Arg::with_name("config") /// .requires_ifs(&[ /// ("val", "arg"), /// ("other_val", "arg2"), /// ]) /// # ; /// ``` /// /// Setting [`Arg::requires_ifs(&["val", "arg"])`] requires that the `arg` be used at runtime if the /// defining argument's value is equal to `val`. If the defining argument's value is anything other /// than `val`, `arg` isn't required. /// /// ```rust /// # use clap::{App, Arg, ErrorKind}; /// let res = App::new("prog") /// .arg(Arg::with_name("cfg") /// .takes_value(true) /// .requires_ifs(&[ /// ("special.conf", "opt"), /// ("other.conf", "other"), /// ]) /// .long("config")) /// .arg(Arg::with_name("opt") /// .long("option") /// .takes_value(true)) /// .arg(Arg::with_name("other")) /// .get_matches_from_safe(vec![ /// "prog", "--config", "special.conf" /// ]); /// /// assert!(res.is_err()); // We used --config=special.conf so --option is required /// assert_eq!(res.unwrap_err().kind, ErrorKind::MissingRequiredArgument); /// ``` /// [`Arg::requires(name)`]: ./struct.Arg.html#method.requires /// [Conflicting]: ./struct.Arg.html#method.conflicts_with /// [override]: ./struct.Arg.html#method.overrides_with pub fn requires_ifs(mut self, ifs: &[(&'b str, &'a str)]) -> Self { if let Some(ref mut vec) = self.b.requires { for &(val, arg) in ifs { vec.push((Some(val), arg)); } } else { let mut vec = vec![]; for &(val, arg) in ifs { vec.push((Some(val), arg)); } self.b.requires = Some(vec); } self } /// Allows specifying that an argument is [required] conditionally. The requirement will only /// become valid if the specified `arg`'s value equals `val`. /// /// **NOTE:** If using YAML the values should be laid out as follows /// /// ```yaml /// required_if: /// - [arg, val] /// ``` /// /// # Examples /// /// ```rust /// # use clap::Arg; /// Arg::with_name("config") /// .required_if("other_arg", "value") /// # ; /// ``` /// /// Setting [`Arg::required_if(arg, val)`] makes this arg required if the `arg` is used at /// runtime and it's value is equal to `val`. If the `arg`'s value is anything other than `val`, /// this argument isn't required. /// /// ```rust /// # use clap::{App, Arg}; /// let res = App::new("prog") /// .arg(Arg::with_name("cfg") /// .takes_value(true) /// .required_if("other", "special") /// .long("config")) /// .arg(Arg::with_name("other") /// .long("other") /// .takes_value(true)) /// .get_matches_from_safe(vec![ /// "prog", "--other", "not-special" /// ]); /// /// assert!(res.is_ok()); // We didn't use --other=special, so "cfg" wasn't required /// ``` /// /// Setting [`Arg::required_if(arg, val)`] and having `arg` used with a value of `val` but *not* /// using this arg is an error. /// /// ```rust /// # use clap::{App, Arg, ErrorKind}; /// let res = App::new("prog") /// .arg(Arg::with_name("cfg") /// .takes_value(true) /// .required_if("other", "special") /// .long("config")) /// .arg(Arg::with_name("other") /// .long("other") /// .takes_value(true)) /// .get_matches_from_safe(vec![ /// "prog", "--other", "special" /// ]); /// /// assert!(res.is_err()); /// assert_eq!(res.unwrap_err().kind, ErrorKind::MissingRequiredArgument); /// ``` /// [`Arg::requires(name)`]: ./struct.Arg.html#method.requires /// [Conflicting]: ./struct.Arg.html#method.conflicts_with /// [required]: ./struct.Arg.html#method.required pub fn required_if(mut self, arg: &'a str, val: &'b str) -> Self { if let Some(ref mut vec) = self.r_ifs { vec.push((arg, val)); } else { self.r_ifs = Some(vec![(arg, val)]); } self } /// Allows specifying that an argument is [required] based on multiple conditions. The /// conditions are set up in a `(arg, val)` style tuple. The requirement will only become valid /// if one of the specified `arg`'s value equals it's corresponding `val`. /// /// **NOTE:** If using YAML the values should be laid out as follows /// /// ```yaml /// required_if: /// - [arg, val] /// - [arg2, val2] /// ``` /// /// # Examples /// /// ```rust /// # use clap::Arg; /// Arg::with_name("config") /// .required_ifs(&[ /// ("extra", "val"), /// ("option", "spec") /// ]) /// # ; /// ``` /// /// Setting [`Arg::required_ifs(&[(arg, val)])`] makes this arg required if any of the `arg`s /// are used at runtime and it's corresponding value is equal to `val`. If the `arg`'s value is /// anything other than `val`, this argument isn't required. /// /// ```rust /// # use clap::{App, Arg}; /// let res = App::new("prog") /// .arg(Arg::with_name("cfg") /// .required_ifs(&[ /// ("extra", "val"), /// ("option", "spec") /// ]) /// .takes_value(true) /// .long("config")) /// .arg(Arg::with_name("extra") /// .takes_value(true) /// .long("extra")) /// .arg(Arg::with_name("option") /// .takes_value(true) /// .long("option")) /// .get_matches_from_safe(vec![ /// "prog", "--option", "other" /// ]); /// /// assert!(res.is_ok()); // We didn't use --option=spec, or --extra=val so "cfg" isn't required /// ``` /// /// Setting [`Arg::required_ifs(&[(arg, val)])`] and having any of the `arg`s used with it's /// value of `val` but *not* using this arg is an error. /// /// ```rust /// # use clap::{App, Arg, ErrorKind}; /// let res = App::new("prog") /// .arg(Arg::with_name("cfg") /// .required_ifs(&[ /// ("extra", "val"), /// ("option", "spec") /// ]) /// .takes_value(true) /// .long("config")) /// .arg(Arg::with_name("extra") /// .takes_value(true) /// .long("extra")) /// .arg(Arg::with_name("option") /// .takes_value(true) /// .long("option")) /// .get_matches_from_safe(vec![ /// "prog", "--option", "spec" /// ]); /// /// assert!(res.is_err()); /// assert_eq!(res.unwrap_err().kind, ErrorKind::MissingRequiredArgument); /// ``` /// [`Arg::requires(name)`]: ./struct.Arg.html#method.requires /// [Conflicting]: ./struct.Arg.html#method.conflicts_with /// [required]: ./struct.Arg.html#method.required pub fn required_ifs(mut self, ifs: &[(&'a str, &'b str)]) -> Self { if let Some(ref mut vec) = self.r_ifs { for r_if in ifs { vec.push((r_if.0, r_if.1)); } } else { let mut vec = vec![]; for r_if in ifs { vec.push((r_if.0, r_if.1)); } self.r_ifs = Some(vec); } self } /// Sets multiple arguments by names that are required when this one is present I.e. when /// using this argument, the following arguments *must* be present. /// /// **NOTE:** [Conflicting] rules and [override] rules take precedence over being required /// by default. /// /// # Examples /// /// ```rust /// # use clap::Arg; /// Arg::with_name("config") /// .requires_all(&["input", "output"]) /// # ; /// ``` /// /// Setting [`Arg::requires_all(&[arg, arg2])`] requires that all the arguments be used at /// runtime if the defining argument is used. If the defining argument isn't used, the other /// argument isn't required /// /// ```rust /// # use clap::{App, Arg}; /// let res = App::new("prog") /// .arg(Arg::with_name("cfg") /// .takes_value(true) /// .requires("input") /// .long("config")) /// .arg(Arg::with_name("input") /// .index(1)) /// .arg(Arg::with_name("output") /// .index(2)) /// .get_matches_from_safe(vec![ /// "prog" /// ]); /// /// assert!(res.is_ok()); // We didn't use cfg, so input and output weren't required /// ``` /// /// Setting [`Arg::requires_all(&[arg, arg2])`] and *not* supplying all the arguments is an /// error. /// /// ```rust /// # use clap::{App, Arg, ErrorKind}; /// let res = App::new("prog") /// .arg(Arg::with_name("cfg") /// .takes_value(true) /// .requires_all(&["input", "output"]) /// .long("config")) /// .arg(Arg::with_name("input") /// .index(1)) /// .arg(Arg::with_name("output") /// .index(2)) /// .get_matches_from_safe(vec![ /// "prog", "--config", "file.conf", "in.txt" /// ]); /// /// assert!(res.is_err()); /// // We didn't use output /// assert_eq!(res.unwrap_err().kind, ErrorKind::MissingRequiredArgument); /// ``` /// [Conflicting]: ./struct.Arg.html#method.conflicts_with /// [override]: ./struct.Arg.html#method.overrides_with /// [`Arg::requires_all(&[arg, arg2])`]: ./struct.Arg.html#method.requires_all pub fn requires_all(mut self, names: &[&'a str]) -> Self { if let Some(ref mut vec) = self.b.requires { for s in names { vec.push((None, s)); } } else { let mut vec = vec![]; for s in names { vec.push((None, *s)); } self.b.requires = Some(vec); } self } /// Specifies that the argument takes a value at run time. /// /// **NOTE:** values for arguments may be specified in any of the following methods /// /// * Using a space such as `-o value` or `--option value` /// * Using an equals and no space such as `-o=value` or `--option=value` /// * Use a short and no space such as `-ovalue` /// /// **NOTE:** By default, args which allow [multiple values] are delimited by commas, meaning /// `--option=val1,val2,val3` is three values for the `--option` argument. If you wish to /// change the delimiter to another character you can use [`Arg::value_delimiter(char)`], /// alternatively you can turn delimiting values **OFF** by using [`Arg::use_delimiter(false)`] /// /// # Examples /// /// ```rust /// # use clap::{App, Arg}; /// Arg::with_name("config") /// .takes_value(true) /// # ; /// ``` /// /// ```rust /// # use clap::{App, Arg}; /// let m = App::new("prog") /// .arg(Arg::with_name("mode") /// .long("mode") /// .takes_value(true)) /// .get_matches_from(vec![ /// "prog", "--mode", "fast" /// ]); /// /// assert!(m.is_present("mode")); /// assert_eq!(m.value_of("mode"), Some("fast")); /// ``` /// [`Arg::value_delimiter(char)`]: ./struct.Arg.html#method.value_delimiter /// [`Arg::use_delimiter(false)`]: ./struct.Arg.html#method.use_delimiter /// [multiple values]: ./struct.Arg.html#method.multiple pub fn takes_value(self, tv: bool) -> Self { if tv { self.set(ArgSettings::TakesValue) } else { self.unset(ArgSettings::TakesValue) } } /// Specifies if the possible values of an argument should be displayed in the help text or /// not. Defaults to `false` (i.e. show possible values) /// /// This is useful for args with many values, or ones which are explained elsewhere in the /// help text. /// /// # Examples /// /// ```rust /// # use clap::{App, Arg}; /// Arg::with_name("config") /// .hide_possible_values(true) /// # ; /// ``` /// /// ```rust /// # use clap::{App, Arg}; /// let m = App::new("prog") /// .arg(Arg::with_name("mode") /// .long("mode") /// .possible_values(&["fast", "slow"]) /// .takes_value(true) /// .hide_possible_values(true)); /// /// ``` /// /// If we were to run the above program with `--help` the `[values: fast, slow]` portion of /// the help text would be omitted. pub fn hide_possible_values(self, hide: bool) -> Self { if hide { self.set(ArgSettings::HidePossibleValues) } else { self.unset(ArgSettings::HidePossibleValues) } } /// Specifies if the default value of an argument should be displayed in the help text or /// not. Defaults to `false` (i.e. show default value) /// /// This is useful when default behavior of an arg is explained elsewhere in the help text. /// /// # Examples /// /// ```rust /// # use clap::{App, Arg}; /// Arg::with_name("config") /// .hide_default_value(true) /// # ; /// ``` /// /// ```rust /// # use clap::{App, Arg}; /// let m = App::new("connect") /// .arg(Arg::with_name("host") /// .long("host") /// .default_value("localhost") /// .hide_default_value(true)); /// /// ``` /// /// If we were to run the above program with `--help` the `[default: localhost]` portion of /// the help text would be omitted. pub fn hide_default_value(self, hide: bool) -> Self { if hide { self.set(ArgSettings::HideDefaultValue) } else { self.unset(ArgSettings::HideDefaultValue) } } /// Specifies the index of a positional argument **starting at** 1. /// /// **NOTE:** The index refers to position according to **other positional argument**. It does /// not define position in the argument list as a whole. /// /// **NOTE:** If no [`Arg::short`], or [`Arg::long`] have been defined, you can optionally /// leave off the `index` method, and the index will be assigned in order of evaluation. /// Utilizing the `index` method allows for setting indexes out of order /// /// **NOTE:** When utilized with [`Arg::multiple(true)`], only the **last** positional argument /// may be defined as multiple (i.e. with the highest index) /// /// # Panics /// /// Although not in this method directly, [`App`] will [`panic!`] if indexes are skipped (such /// as defining `index(1)` and `index(3)` but not `index(2)`, or a positional argument is /// defined as multiple and is not the highest index /// /// # Examples /// /// ```rust /// # use clap::{App, Arg}; /// Arg::with_name("config") /// .index(1) /// # ; /// ``` /// /// ```rust /// # use clap::{App, Arg}; /// let m = App::new("prog") /// .arg(Arg::with_name("mode") /// .index(1)) /// .arg(Arg::with_name("debug") /// .long("debug")) /// .get_matches_from(vec![ /// "prog", "--debug", "fast" /// ]); /// /// assert!(m.is_present("mode")); /// assert_eq!(m.value_of("mode"), Some("fast")); // notice index(1) means "first positional" /// // *not* first argument /// ``` /// [`Arg::short`]: ./struct.Arg.html#method.short /// [`Arg::long`]: ./struct.Arg.html#method.long /// [`Arg::multiple(true)`]: ./struct.Arg.html#method.multiple /// [`App`]: ./struct.App.html /// [`panic!`]: https://doc.rust-lang.org/std/macro.panic!.html pub fn index(mut self, idx: u64) -> Self { self.index = Some(idx); self } /// Specifies that the argument may appear more than once. For flags, this results /// in the number of occurrences of the flag being recorded. For example `-ddd` or `-d -d -d` /// would count as three occurrences. For options there is a distinct difference in multiple /// occurrences vs multiple values. /// /// For example, `--opt val1 val2` is one occurrence, but two values. Whereas /// `--opt val1 --opt val2` is two occurrences. /// /// **WARNING:** /// /// Setting `multiple(true)` for an [option] with no other details, allows multiple values /// **and** multiple occurrences because it isn't possible to have more occurrences than values /// for options. Because multiple values are allowed, `--option val1 val2 val3` is perfectly /// valid, be careful when designing a CLI where positional arguments are expected after a /// option which accepts multiple values, as `clap` will continue parsing *values* until it /// reaches the max or specific number of values defined, or another flag or option. /// /// **Pro Tip**: /// /// It's possible to define an option which allows multiple occurrences, but only one value per /// occurrence. To do this use [`Arg::number_of_values(1)`] in coordination with /// [`Arg::multiple(true)`]. /// /// **WARNING:** /// /// When using args with `multiple(true)` on [options] or [positionals] (i.e. those args that /// accept values) and [subcommands], one needs to consider the possibility of an argument value /// being the same as a valid subcommand. By default `clap` will parse the argument in question /// as a value *only if* a value is possible at that moment. Otherwise it will be parsed as a /// subcommand. In effect, this means using `multiple(true)` with no additional parameters and /// a possible value that coincides with a subcommand name, the subcommand cannot be called /// unless another argument is passed first. /// /// As an example, consider a CLI with an option `--ui-paths=...` and subcommand `signer` /// /// The following would be parsed as values to `--ui-paths`. /// /// ```notrust /// $ program --ui-paths path1 path2 signer /// ``` /// /// This is because `--ui-paths` accepts multiple values. `clap` will continue parsing values /// until another argument is reached and it knows `--ui-paths` is done. /// /// By adding additional parameters to `--ui-paths` we can solve this issue. Consider adding /// [`Arg::number_of_values(1)`] as discussed above. The following are all valid, and `signer` /// is parsed as both a subcommand and a value in the second case. /// /// ```notrust /// $ program --ui-paths path1 signer /// $ program --ui-paths path1 --ui-paths signer signer /// ``` /// /// # Examples /// /// ```rust /// # use clap::{App, Arg}; /// Arg::with_name("debug") /// .short("d") /// .multiple(true) /// # ; /// ``` /// An example with flags /// /// ```rust /// # use clap::{App, Arg}; /// let m = App::new("prog") /// .arg(Arg::with_name("verbose") /// .multiple(true) /// .short("v")) /// .get_matches_from(vec![ /// "prog", "-v", "-v", "-v" // note, -vvv would have same result /// ]); /// /// assert!(m.is_present("verbose")); /// assert_eq!(m.occurrences_of("verbose"), 3); /// ``` /// /// An example with options /// /// ```rust /// # use clap::{App, Arg}; /// let m = App::new("prog") /// .arg(Arg::with_name("file") /// .multiple(true) /// .takes_value(true) /// .short("F")) /// .get_matches_from(vec![ /// "prog", "-F", "file1", "file2", "file3" /// ]); /// /// assert!(m.is_present("file")); /// assert_eq!(m.occurrences_of("file"), 1); // notice only one occurrence /// let files: Vec<_> = m.values_of("file").unwrap().collect(); /// assert_eq!(files, ["file1", "file2", "file3"]); /// ``` /// This is functionally equivalent to the example above /// /// ```rust /// # use clap::{App, Arg}; /// let m = App::new("prog") /// .arg(Arg::with_name("file") /// .multiple(true) /// .takes_value(true) /// .short("F")) /// .get_matches_from(vec![ /// "prog", "-F", "file1", "-F", "file2", "-F", "file3" /// ]); /// let files: Vec<_> = m.values_of("file").unwrap().collect(); /// assert_eq!(files, ["file1", "file2", "file3"]); /// /// assert!(m.is_present("file")); /// assert_eq!(m.occurrences_of("file"), 3); // Notice 3 occurrences /// let files: Vec<_> = m.values_of("file").unwrap().collect(); /// assert_eq!(files, ["file1", "file2", "file3"]); /// ``` /// /// A common mistake is to define an option which allows multiples, and a positional argument /// /// ```rust /// # use clap::{App, Arg}; /// let m = App::new("prog") /// .arg(Arg::with_name("file") /// .multiple(true) /// .takes_value(true) /// .short("F")) /// .arg(Arg::with_name("word") /// .index(1)) /// .get_matches_from(vec![ /// "prog", "-F", "file1", "file2", "file3", "word" /// ]); /// /// assert!(m.is_present("file")); /// let files: Vec<_> = m.values_of("file").unwrap().collect(); /// assert_eq!(files, ["file1", "file2", "file3", "word"]); // wait...what?! /// assert!(!m.is_present("word")); // but we clearly used word! /// ``` /// The problem is clap doesn't know when to stop parsing values for "files". This is further /// compounded by if we'd said `word -F file1 file2` it would have worked fine, so it would /// appear to only fail sometimes...not good! /// /// A solution for the example above is to specify that `-F` only accepts one value, but is /// allowed to appear multiple times /// /// ```rust /// # use clap::{App, Arg}; /// let m = App::new("prog") /// .arg(Arg::with_name("file") /// .multiple(true) /// .takes_value(true) /// .number_of_values(1) /// .short("F")) /// .arg(Arg::with_name("word") /// .index(1)) /// .get_matches_from(vec![ /// "prog", "-F", "file1", "-F", "file2", "-F", "file3", "word" /// ]); /// /// assert!(m.is_present("file")); /// let files: Vec<_> = m.values_of("file").unwrap().collect(); /// assert_eq!(files, ["file1", "file2", "file3"]); /// assert!(m.is_present("word")); /// assert_eq!(m.value_of("word"), Some("word")); /// ``` /// As a final example, notice if we define [`Arg::number_of_values(1)`] and try to run the /// problem example above, it would have been a runtime error with a pretty message to the /// user :) /// /// ```rust /// # use clap::{App, Arg, ErrorKind}; /// let res = App::new("prog") /// .arg(Arg::with_name("file") /// .multiple(true) /// .takes_value(true) /// .number_of_values(1) /// .short("F")) /// .arg(Arg::with_name("word") /// .index(1)) /// .get_matches_from_safe(vec![ /// "prog", "-F", "file1", "file2", "file3", "word" /// ]); /// /// assert!(res.is_err()); /// assert_eq!(res.unwrap_err().kind, ErrorKind::UnknownArgument); /// ``` /// [option]: ./struct.Arg.html#method.takes_value /// [options]: ./struct.Arg.html#method.takes_value /// [subcommands]: ./struct.SubCommand.html /// [positionals]: ./struct.Arg.html#method.index /// [`Arg::number_of_values(1)`]: ./struct.Arg.html#method.number_of_values /// [`Arg::multiple(true)`]: ./struct.Arg.html#method.multiple pub fn multiple(self, multi: bool) -> Self { if multi { self.set(ArgSettings::Multiple) } else { self.unset(ArgSettings::Multiple) } } /// Specifies a value that *stops* parsing multiple values of a give argument. By default when /// one sets [`multiple(true)`] on an argument, clap will continue parsing values for that /// argument until it reaches another valid argument, or one of the other more specific settings /// for multiple values is used (such as [`min_values`], [`max_values`] or /// [`number_of_values`]). /// /// **NOTE:** This setting only applies to [options] and [positional arguments] /// /// **NOTE:** When the terminator is passed in on the command line, it is **not** stored as one /// of the values /// /// # Examples /// /// ```rust /// # use clap::{App, Arg}; /// Arg::with_name("vals") /// .takes_value(true) /// .multiple(true) /// .value_terminator(";") /// # ; /// ``` /// The following example uses two arguments, a sequence of commands, and the location in which /// to perform them /// /// ```rust /// # use clap::{App, Arg}; /// let m = App::new("prog") /// .arg(Arg::with_name("cmds") /// .multiple(true) /// .allow_hyphen_values(true) /// .value_terminator(";")) /// .arg(Arg::with_name("location")) /// .get_matches_from(vec![ /// "prog", "find", "-type", "f", "-name", "special", ";", "/home/clap" /// ]); /// let cmds: Vec<_> = m.values_of("cmds").unwrap().collect(); /// assert_eq!(&cmds, &["find", "-type", "f", "-name", "special"]); /// assert_eq!(m.value_of("location"), Some("/home/clap")); /// ``` /// [options]: ./struct.Arg.html#method.takes_value /// [positional arguments]: ./struct.Arg.html#method.index /// [`multiple(true)`]: ./struct.Arg.html#method.multiple /// [`min_values`]: ./struct.Arg.html#method.min_values /// [`number_of_values`]: ./struct.Arg.html#method.number_of_values /// [`max_values`]: ./struct.Arg.html#method.max_values pub fn value_terminator(mut self, term: &'b str) -> Self { self.setb(ArgSettings::TakesValue); self.v.terminator = Some(term); self } /// Specifies that an argument can be matched to all child [`SubCommand`]s. /// /// **NOTE:** Global arguments *only* propagate down, **not** up (to parent commands), however /// their values once a user uses them will be propagated back up to parents. In effect, this /// means one should *define* all global arguments at the top level, however it doesn't matter /// where the user *uses* the global argument. /// /// # Examples /// /// ```rust /// # use clap::{App, Arg}; /// Arg::with_name("debug") /// .short("d") /// .global(true) /// # ; /// ``` /// /// For example, assume an application with two subcommands, and you'd like to define a /// `--verbose` flag that can be called on any of the subcommands and parent, but you don't /// want to clutter the source with three duplicate [`Arg`] definitions. /// /// ```rust /// # use clap::{App, Arg, SubCommand}; /// let m = App::new("prog") /// .arg(Arg::with_name("verb") /// .long("verbose") /// .short("v") /// .global(true)) /// .subcommand(SubCommand::with_name("test")) /// .subcommand(SubCommand::with_name("do-stuff")) /// .get_matches_from(vec![ /// "prog", "do-stuff", "--verbose" /// ]); /// /// assert_eq!(m.subcommand_name(), Some("do-stuff")); /// let sub_m = m.subcommand_matches("do-stuff").unwrap(); /// assert!(sub_m.is_present("verb")); /// ``` /// [`SubCommand`]: ./struct.SubCommand.html /// [required]: ./struct.Arg.html#method.required /// [`ArgMatches`]: ./struct.ArgMatches.html /// [`ArgMatches::is_present("flag")`]: ./struct.ArgMatches.html#method.is_present /// [`Arg`]: ./struct.Arg.html pub fn global(self, g: bool) -> Self { if g { self.set(ArgSettings::Global) } else { self.unset(ArgSettings::Global) } } /// Allows an argument to accept explicitly empty values. An empty value must be specified at /// the command line with an explicit `""`, or `''` /// /// **NOTE:** Defaults to `true` (Explicitly empty values are allowed) /// /// **NOTE:** Implicitly sets [`Arg::takes_value(true)`] when set to `false` /// /// # Examples /// /// ```rust /// # use clap::{App, Arg}; /// Arg::with_name("file") /// .long("file") /// .empty_values(false) /// # ; /// ``` /// The default is to allow empty values, such as `--option ""` would be an empty value. But /// we can change to make empty values become an error. /// /// ```rust /// # use clap::{App, Arg, ErrorKind}; /// let res = App::new("prog") /// .arg(Arg::with_name("cfg") /// .long("config") /// .short("v") /// .empty_values(false)) /// .get_matches_from_safe(vec![ /// "prog", "--config=" /// ]); /// /// assert!(res.is_err()); /// assert_eq!(res.unwrap_err().kind, ErrorKind::EmptyValue); /// ``` /// [`Arg::takes_value(true)`]: ./struct.Arg.html#method.takes_value pub fn empty_values(mut self, ev: bool) -> Self { if ev { self.set(ArgSettings::EmptyValues) } else { self = self.set(ArgSettings::TakesValue); self.unset(ArgSettings::EmptyValues) } } /// Hides an argument from help message output. /// /// **NOTE:** Implicitly sets [`Arg::hidden_short_help(true)`] and [`Arg::hidden_long_help(true)`] /// when set to true /// /// **NOTE:** This does **not** hide the argument from usage strings on error /// /// # Examples /// /// ```rust /// # use clap::{App, Arg}; /// Arg::with_name("debug") /// .hidden(true) /// # ; /// ``` /// Setting `hidden(true)` will hide the argument when displaying help text /// /// ```rust /// # use clap::{App, Arg}; /// let m = App::new("prog") /// .arg(Arg::with_name("cfg") /// .long("config") /// .hidden(true) /// .help("Some help text describing the --config arg")) /// .get_matches_from(vec![ /// "prog", "--help" /// ]); /// ``` /// /// The above example displays /// /// ```notrust /// helptest /// /// USAGE: /// helptest [FLAGS] /// /// FLAGS: /// -h, --help Prints help information /// -V, --version Prints version information /// ``` /// [`Arg::hidden_short_help(true)`]: ./struct.Arg.html#method.hidden_short_help /// [`Arg::hidden_long_help(true)`]: ./struct.Arg.html#method.hidden_long_help pub fn hidden(self, h: bool) -> Self { if h { self.set(ArgSettings::Hidden) } else { self.unset(ArgSettings::Hidden) } } /// Specifies a list of possible values for this argument. At runtime, `clap` verifies that /// only one of the specified values was used, or fails with an error message. /// /// **NOTE:** This setting only applies to [options] and [positional arguments] /// /// # Examples /// /// ```rust /// # use clap::{App, Arg}; /// Arg::with_name("mode") /// .takes_value(true) /// .possible_values(&["fast", "slow", "medium"]) /// # ; /// ``` /// /// ```rust /// # use clap::{App, Arg}; /// let m = App::new("prog") /// .arg(Arg::with_name("mode") /// .long("mode") /// .takes_value(true) /// .possible_values(&["fast", "slow", "medium"])) /// .get_matches_from(vec![ /// "prog", "--mode", "fast" /// ]); /// assert!(m.is_present("mode")); /// assert_eq!(m.value_of("mode"), Some("fast")); /// ``` /// /// The next example shows a failed parse from using a value which wasn't defined as one of the /// possible values. /// /// ```rust /// # use clap::{App, Arg, ErrorKind}; /// let res = App::new("prog") /// .arg(Arg::with_name("mode") /// .long("mode") /// .takes_value(true) /// .possible_values(&["fast", "slow", "medium"])) /// .get_matches_from_safe(vec![ /// "prog", "--mode", "wrong" /// ]); /// assert!(res.is_err()); /// assert_eq!(res.unwrap_err().kind, ErrorKind::InvalidValue); /// ``` /// [options]: ./struct.Arg.html#method.takes_value /// [positional arguments]: ./struct.Arg.html#method.index pub fn possible_values(mut self, names: &[&'b str]) -> Self { if let Some(ref mut vec) = self.v.possible_vals { for s in names { vec.push(s); } } else { self.v.possible_vals = Some(names.iter().map(|s| *s).collect::>()); } self } /// Specifies a possible value for this argument, one at a time. At runtime, `clap` verifies /// that only one of the specified values was used, or fails with error message. /// /// **NOTE:** This setting only applies to [options] and [positional arguments] /// /// # Examples /// /// ```rust /// # use clap::{App, Arg}; /// Arg::with_name("mode") /// .takes_value(true) /// .possible_value("fast") /// .possible_value("slow") /// .possible_value("medium") /// # ; /// ``` /// /// ```rust /// # use clap::{App, Arg}; /// let m = App::new("prog") /// .arg(Arg::with_name("mode") /// .long("mode") /// .takes_value(true) /// .possible_value("fast") /// .possible_value("slow") /// .possible_value("medium")) /// .get_matches_from(vec![ /// "prog", "--mode", "fast" /// ]); /// assert!(m.is_present("mode")); /// assert_eq!(m.value_of("mode"), Some("fast")); /// ``` /// /// The next example shows a failed parse from using a value which wasn't defined as one of the /// possible values. /// /// ```rust /// # use clap::{App, Arg, ErrorKind}; /// let res = App::new("prog") /// .arg(Arg::with_name("mode") /// .long("mode") /// .takes_value(true) /// .possible_value("fast") /// .possible_value("slow") /// .possible_value("medium")) /// .get_matches_from_safe(vec![ /// "prog", "--mode", "wrong" /// ]); /// assert!(res.is_err()); /// assert_eq!(res.unwrap_err().kind, ErrorKind::InvalidValue); /// ``` /// [options]: ./struct.Arg.html#method.takes_value /// [positional arguments]: ./struct.Arg.html#method.index pub fn possible_value(mut self, name: &'b str) -> Self { if let Some(ref mut vec) = self.v.possible_vals { vec.push(name); } else { self.v.possible_vals = Some(vec![name]); } self } /// When used with [`Arg::possible_values`] it allows the argument value to pass validation even if /// the case differs from that of the specified `possible_value`. /// /// **Pro Tip:** Use this setting with [`arg_enum!`] /// /// # Examples /// /// ```rust /// # use clap::{App, Arg}; /// # use std::ascii::AsciiExt; /// let m = App::new("pv") /// .arg(Arg::with_name("option") /// .long("--option") /// .takes_value(true) /// .possible_value("test123") /// .case_insensitive(true)) /// .get_matches_from(vec![ /// "pv", "--option", "TeSt123", /// ]); /// /// assert!(m.value_of("option").unwrap().eq_ignore_ascii_case("test123")); /// ``` /// /// This setting also works when multiple values can be defined: /// /// ```rust /// # use clap::{App, Arg}; /// let m = App::new("pv") /// .arg(Arg::with_name("option") /// .short("-o") /// .long("--option") /// .takes_value(true) /// .possible_value("test123") /// .possible_value("test321") /// .multiple(true) /// .case_insensitive(true)) /// .get_matches_from(vec![ /// "pv", "--option", "TeSt123", "teST123", "tESt321" /// ]); /// /// let matched_vals = m.values_of("option").unwrap().collect::>(); /// assert_eq!(&*matched_vals, &["TeSt123", "teST123", "tESt321"]); /// ``` /// [`Arg::case_insensitive(true)`]: ./struct.Arg.html#method.possible_values /// [`arg_enum!`]: ./macro.arg_enum.html pub fn case_insensitive(self, ci: bool) -> Self { if ci { self.set(ArgSettings::CaseInsensitive) } else { self.unset(ArgSettings::CaseInsensitive) } } /// Specifies the name of the [`ArgGroup`] the argument belongs to. /// /// # Examples /// /// ```rust /// # use clap::{App, Arg}; /// Arg::with_name("debug") /// .long("debug") /// .group("mode") /// # ; /// ``` /// /// Multiple arguments can be a member of a single group and then the group checked as if it /// was one of said arguments. /// /// ```rust /// # use clap::{App, Arg}; /// let m = App::new("prog") /// .arg(Arg::with_name("debug") /// .long("debug") /// .group("mode")) /// .arg(Arg::with_name("verbose") /// .long("verbose") /// .group("mode")) /// .get_matches_from(vec![ /// "prog", "--debug" /// ]); /// assert!(m.is_present("mode")); /// ``` /// [`ArgGroup`]: ./struct.ArgGroup.html pub fn group(mut self, name: &'a str) -> Self { if let Some(ref mut vec) = self.b.groups { vec.push(name); } else { self.b.groups = Some(vec![name]); } self } /// Specifies the names of multiple [`ArgGroup`]'s the argument belongs to. /// /// # Examples /// /// ```rust /// # use clap::{App, Arg}; /// Arg::with_name("debug") /// .long("debug") /// .groups(&["mode", "verbosity"]) /// # ; /// ``` /// /// Arguments can be members of multiple groups and then the group checked as if it /// was one of said arguments. /// /// ```rust /// # use clap::{App, Arg}; /// let m = App::new("prog") /// .arg(Arg::with_name("debug") /// .long("debug") /// .groups(&["mode", "verbosity"])) /// .arg(Arg::with_name("verbose") /// .long("verbose") /// .groups(&["mode", "verbosity"])) /// .get_matches_from(vec![ /// "prog", "--debug" /// ]); /// assert!(m.is_present("mode")); /// assert!(m.is_present("verbosity")); /// ``` /// [`ArgGroup`]: ./struct.ArgGroup.html pub fn groups(mut self, names: &[&'a str]) -> Self { if let Some(ref mut vec) = self.b.groups { for s in names { vec.push(s); } } else { self.b.groups = Some(names.into_iter().map(|s| *s).collect::>()); } self } /// Specifies how many values are required to satisfy this argument. For example, if you had a /// `-f ` argument where you wanted exactly 3 'files' you would set /// `.number_of_values(3)`, and this argument wouldn't be satisfied unless the user provided /// 3 and only 3 values. /// /// **NOTE:** Does *not* require [`Arg::multiple(true)`] to be set. Setting /// [`Arg::multiple(true)`] would allow `-f -f ` where /// as *not* setting [`Arg::multiple(true)`] would only allow one occurrence of this argument. /// /// # Examples /// /// ```rust /// # use clap::{App, Arg}; /// Arg::with_name("file") /// .short("f") /// .number_of_values(3) /// # ; /// ``` /// /// Not supplying the correct number of values is an error /// /// ```rust /// # use clap::{App, Arg, ErrorKind}; /// let res = App::new("prog") /// .arg(Arg::with_name("file") /// .takes_value(true) /// .number_of_values(2) /// .short("F")) /// .get_matches_from_safe(vec![ /// "prog", "-F", "file1" /// ]); /// /// assert!(res.is_err()); /// assert_eq!(res.unwrap_err().kind, ErrorKind::WrongNumberOfValues); /// ``` /// [`Arg::multiple(true)`]: ./struct.Arg.html#method.multiple pub fn number_of_values(mut self, qty: u64) -> Self { self.setb(ArgSettings::TakesValue); self.v.num_vals = Some(qty); self } /// Allows one to perform a custom validation on the argument value. You provide a closure /// which accepts a [`String`] value, and return a [`Result`] where the [`Err(String)`] is a /// message displayed to the user. /// /// **NOTE:** The error message does *not* need to contain the `error:` portion, only the /// message as all errors will appear as /// `error: Invalid value for '': ` where `` is replaced by the actual /// arg, and `` is the `String` you return as the error. /// /// **NOTE:** There is a small performance hit for using validators, as they are implemented /// with [`Rc`] pointers. And the value to be checked will be allocated an extra time in order /// to to be passed to the closure. This performance hit is extremely minimal in the grand /// scheme of things. /// /// # Examples /// /// ```rust /// # use clap::{App, Arg}; /// fn has_at(v: String) -> Result<(), String> { /// if v.contains("@") { return Ok(()); } /// Err(String::from("The value did not contain the required @ sigil")) /// } /// let res = App::new("prog") /// .arg(Arg::with_name("file") /// .index(1) /// .validator(has_at)) /// .get_matches_from_safe(vec![ /// "prog", "some@file" /// ]); /// assert!(res.is_ok()); /// assert_eq!(res.unwrap().value_of("file"), Some("some@file")); /// ``` /// [`String`]: https://doc.rust-lang.org/std/string/struct.String.html /// [`Result`]: https://doc.rust-lang.org/std/result/enum.Result.html /// [`Err(String)`]: https://doc.rust-lang.org/std/result/enum.Result.html#variant.Err /// [`Rc`]: https://doc.rust-lang.org/std/rc/struct.Rc.html pub fn validator(mut self, f: F) -> Self where F: Fn(String) -> Result<(), String> + 'static, { self.v.validator = Some(Rc::new(f)); self } /// Works identically to Validator but is intended to be used with values that could /// contain non UTF-8 formatted strings. /// /// # Examples /// #[cfg_attr(not(unix), doc = " ```ignore")] #[cfg_attr(unix, doc = " ```rust")] /// # use clap::{App, Arg}; /// # use std::ffi::{OsStr, OsString}; /// # use std::os::unix::ffi::OsStrExt; /// fn has_ampersand(v: &OsStr) -> Result<(), OsString> { /// if v.as_bytes().iter().any(|b| *b == b'&') { return Ok(()); } /// Err(OsString::from("The value did not contain the required & sigil")) /// } /// let res = App::new("prog") /// .arg(Arg::with_name("file") /// .index(1) /// .validator_os(has_ampersand)) /// .get_matches_from_safe(vec![ /// "prog", "Fish & chips" /// ]); /// assert!(res.is_ok()); /// assert_eq!(res.unwrap().value_of("file"), Some("Fish & chips")); /// ``` /// [`String`]: https://doc.rust-lang.org/std/string/struct.String.html /// [`OsStr`]: https://doc.rust-lang.org/std/ffi/struct.OsStr.html /// [`OsString`]: https://doc.rust-lang.org/std/ffi/struct.OsString.html /// [`Result`]: https://doc.rust-lang.org/std/result/enum.Result.html /// [`Err(String)`]: https://doc.rust-lang.org/std/result/enum.Result.html#variant.Err /// [`Rc`]: https://doc.rust-lang.org/std/rc/struct.Rc.html pub fn validator_os(mut self, f: F) -> Self where F: Fn(&OsStr) -> Result<(), OsString> + 'static, { self.v.validator_os = Some(Rc::new(f)); self } /// Specifies the *maximum* number of values are for this argument. For example, if you had a /// `-f ` argument where you wanted up to 3 'files' you would set `.max_values(3)`, and /// this argument would be satisfied if the user provided, 1, 2, or 3 values. /// /// **NOTE:** This does *not* implicitly set [`Arg::multiple(true)`]. This is because /// `-o val -o val` is multiple occurrences but a single value and `-o val1 val2` is a single /// occurrence with multiple values. For positional arguments this **does** set /// [`Arg::multiple(true)`] because there is no way to determine the difference between multiple /// occurrences and multiple values. /// /// # Examples /// /// ```rust /// # use clap::{App, Arg}; /// Arg::with_name("file") /// .short("f") /// .max_values(3) /// # ; /// ``` /// /// Supplying less than the maximum number of values is allowed /// /// ```rust /// # use clap::{App, Arg}; /// let res = App::new("prog") /// .arg(Arg::with_name("file") /// .takes_value(true) /// .max_values(3) /// .short("F")) /// .get_matches_from_safe(vec![ /// "prog", "-F", "file1", "file2" /// ]); /// /// assert!(res.is_ok()); /// let m = res.unwrap(); /// let files: Vec<_> = m.values_of("file").unwrap().collect(); /// assert_eq!(files, ["file1", "file2"]); /// ``` /// /// Supplying more than the maximum number of values is an error /// /// ```rust /// # use clap::{App, Arg, ErrorKind}; /// let res = App::new("prog") /// .arg(Arg::with_name("file") /// .takes_value(true) /// .max_values(2) /// .short("F")) /// .get_matches_from_safe(vec![ /// "prog", "-F", "file1", "file2", "file3" /// ]); /// /// assert!(res.is_err()); /// assert_eq!(res.unwrap_err().kind, ErrorKind::TooManyValues); /// ``` /// [`Arg::multiple(true)`]: ./struct.Arg.html#method.multiple pub fn max_values(mut self, qty: u64) -> Self { self.setb(ArgSettings::TakesValue); self.v.max_vals = Some(qty); self } /// Specifies the *minimum* number of values for this argument. For example, if you had a /// `-f ` argument where you wanted at least 2 'files' you would set /// `.min_values(2)`, and this argument would be satisfied if the user provided, 2 or more /// values. /// /// **NOTE:** This does not implicitly set [`Arg::multiple(true)`]. This is because /// `-o val -o val` is multiple occurrences but a single value and `-o val1 val2` is a single /// occurrence with multiple values. For positional arguments this **does** set /// [`Arg::multiple(true)`] because there is no way to determine the difference between multiple /// occurrences and multiple values. /// /// # Examples /// /// ```rust /// # use clap::{App, Arg}; /// Arg::with_name("file") /// .short("f") /// .min_values(3) /// # ; /// ``` /// /// Supplying more than the minimum number of values is allowed /// /// ```rust /// # use clap::{App, Arg}; /// let res = App::new("prog") /// .arg(Arg::with_name("file") /// .takes_value(true) /// .min_values(2) /// .short("F")) /// .get_matches_from_safe(vec![ /// "prog", "-F", "file1", "file2", "file3" /// ]); /// /// assert!(res.is_ok()); /// let m = res.unwrap(); /// let files: Vec<_> = m.values_of("file").unwrap().collect(); /// assert_eq!(files, ["file1", "file2", "file3"]); /// ``` /// /// Supplying less than the minimum number of values is an error /// /// ```rust /// # use clap::{App, Arg, ErrorKind}; /// let res = App::new("prog") /// .arg(Arg::with_name("file") /// .takes_value(true) /// .min_values(2) /// .short("F")) /// .get_matches_from_safe(vec![ /// "prog", "-F", "file1" /// ]); /// /// assert!(res.is_err()); /// assert_eq!(res.unwrap_err().kind, ErrorKind::TooFewValues); /// ``` /// [`Arg::multiple(true)`]: ./struct.Arg.html#method.multiple pub fn min_values(mut self, qty: u64) -> Self { self.v.min_vals = Some(qty); self.set(ArgSettings::TakesValue) } /// Specifies whether or not an argument should allow grouping of multiple values via a /// delimiter. I.e. should `--option=val1,val2,val3` be parsed as three values (`val1`, `val2`, /// and `val3`) or as a single value (`val1,val2,val3`). Defaults to using `,` (comma) as the /// value delimiter for all arguments that accept values (options and positional arguments) /// /// **NOTE:** The default is `false`. When set to `true` the default [`Arg::value_delimiter`] /// is the comma `,`. /// /// # Examples /// /// The following example shows the default behavior. /// /// ```rust /// # use clap::{App, Arg}; /// let delims = App::new("prog") /// .arg(Arg::with_name("option") /// .long("option") /// .use_delimiter(true) /// .takes_value(true)) /// .get_matches_from(vec![ /// "prog", "--option=val1,val2,val3", /// ]); /// /// assert!(delims.is_present("option")); /// assert_eq!(delims.occurrences_of("option"), 1); /// assert_eq!(delims.values_of("option").unwrap().collect::>(), ["val1", "val2", "val3"]); /// ``` /// The next example shows the difference when turning delimiters off. This is the default /// behavior /// /// ```rust /// # use clap::{App, Arg}; /// let nodelims = App::new("prog") /// .arg(Arg::with_name("option") /// .long("option") /// .use_delimiter(false) /// .takes_value(true)) /// .get_matches_from(vec![ /// "prog", "--option=val1,val2,val3", /// ]); /// /// assert!(nodelims.is_present("option")); /// assert_eq!(nodelims.occurrences_of("option"), 1); /// assert_eq!(nodelims.value_of("option").unwrap(), "val1,val2,val3"); /// ``` /// [`Arg::value_delimiter`]: ./struct.Arg.html#method.value_delimiter pub fn use_delimiter(mut self, d: bool) -> Self { if d { if self.v.val_delim.is_none() { self.v.val_delim = Some(','); } self.setb(ArgSettings::TakesValue); self.setb(ArgSettings::UseValueDelimiter); self.unset(ArgSettings::ValueDelimiterNotSet) } else { self.v.val_delim = None; self.unsetb(ArgSettings::UseValueDelimiter); self.unset(ArgSettings::ValueDelimiterNotSet) } } /// Specifies that *multiple values* may only be set using the delimiter. This means if an /// if an option is encountered, and no delimiter is found, it automatically assumed that no /// additional values for that option follow. This is unlike the default, where it is generally /// assumed that more values will follow regardless of whether or not a delimiter is used. /// /// **NOTE:** The default is `false`. /// /// **NOTE:** Setting this to true implies [`Arg::use_delimiter(true)`] /// /// **NOTE:** It's a good idea to inform the user that use of a delimiter is required, either /// through help text or other means. /// /// # Examples /// /// These examples demonstrate what happens when `require_delimiter(true)` is used. Notice /// everything works in this first example, as we use a delimiter, as expected. /// /// ```rust /// # use clap::{App, Arg}; /// let delims = App::new("prog") /// .arg(Arg::with_name("opt") /// .short("o") /// .takes_value(true) /// .multiple(true) /// .require_delimiter(true)) /// .get_matches_from(vec![ /// "prog", "-o", "val1,val2,val3", /// ]); /// /// assert!(delims.is_present("opt")); /// assert_eq!(delims.values_of("opt").unwrap().collect::>(), ["val1", "val2", "val3"]); /// ``` /// In this next example, we will *not* use a delimiter. Notice it's now an error. /// /// ```rust /// # use clap::{App, Arg, ErrorKind}; /// let res = App::new("prog") /// .arg(Arg::with_name("opt") /// .short("o") /// .takes_value(true) /// .multiple(true) /// .require_delimiter(true)) /// .get_matches_from_safe(vec![ /// "prog", "-o", "val1", "val2", "val3", /// ]); /// /// assert!(res.is_err()); /// let err = res.unwrap_err(); /// assert_eq!(err.kind, ErrorKind::UnknownArgument); /// ``` /// What's happening is `-o` is getting `val1`, and because delimiters are required yet none /// were present, it stops parsing `-o`. At this point it reaches `val2` and because no /// positional arguments have been defined, it's an error of an unexpected argument. /// /// In this final example, we contrast the above with `clap`'s default behavior where the above /// is *not* an error. /// /// ```rust /// # use clap::{App, Arg}; /// let delims = App::new("prog") /// .arg(Arg::with_name("opt") /// .short("o") /// .takes_value(true) /// .multiple(true)) /// .get_matches_from(vec![ /// "prog", "-o", "val1", "val2", "val3", /// ]); /// /// assert!(delims.is_present("opt")); /// assert_eq!(delims.values_of("opt").unwrap().collect::>(), ["val1", "val2", "val3"]); /// ``` /// [`Arg::use_delimiter(true)`]: ./struct.Arg.html#method.use_delimiter pub fn require_delimiter(mut self, d: bool) -> Self { if d { self = self.use_delimiter(true); self.unsetb(ArgSettings::ValueDelimiterNotSet); self.setb(ArgSettings::UseValueDelimiter); self.set(ArgSettings::RequireDelimiter) } else { self = self.use_delimiter(false); self.unsetb(ArgSettings::UseValueDelimiter); self.unset(ArgSettings::RequireDelimiter) } } /// Specifies the separator to use when values are clumped together, defaults to `,` (comma). /// /// **NOTE:** implicitly sets [`Arg::use_delimiter(true)`] /// /// **NOTE:** implicitly sets [`Arg::takes_value(true)`] /// /// # Examples /// /// ```rust /// # use clap::{App, Arg}; /// let m = App::new("prog") /// .arg(Arg::with_name("config") /// .short("c") /// .long("config") /// .value_delimiter(";")) /// .get_matches_from(vec![ /// "prog", "--config=val1;val2;val3" /// ]); /// /// assert_eq!(m.values_of("config").unwrap().collect::>(), ["val1", "val2", "val3"]) /// ``` /// [`Arg::use_delimiter(true)`]: ./struct.Arg.html#method.use_delimiter /// [`Arg::takes_value(true)`]: ./struct.Arg.html#method.takes_value pub fn value_delimiter(mut self, d: &str) -> Self { self.unsetb(ArgSettings::ValueDelimiterNotSet); self.setb(ArgSettings::TakesValue); self.setb(ArgSettings::UseValueDelimiter); self.v.val_delim = Some( d.chars() .nth(0) .expect("Failed to get value_delimiter from arg"), ); self } /// Specify multiple names for values of option arguments. These names are cosmetic only, used /// for help and usage strings only. The names are **not** used to access arguments. The values /// of the arguments are accessed in numeric order (i.e. if you specify two names `one` and /// `two` `one` will be the first matched value, `two` will be the second). /// /// This setting can be very helpful when describing the type of input the user should be /// using, such as `FILE`, `INTERFACE`, etc. Although not required, it's somewhat convention to /// use all capital letters for the value name. /// /// **Pro Tip:** It may help to use [`Arg::next_line_help(true)`] if there are long, or /// multiple value names in order to not throw off the help text alignment of all options. /// /// **NOTE:** This implicitly sets [`Arg::number_of_values`] if the number of value names is /// greater than one. I.e. be aware that the number of "names" you set for the values, will be /// the *exact* number of values required to satisfy this argument /// /// **NOTE:** implicitly sets [`Arg::takes_value(true)`] /// /// **NOTE:** Does *not* require or imply [`Arg::multiple(true)`]. /// /// # Examples /// /// ```rust /// # use clap::{App, Arg}; /// Arg::with_name("speed") /// .short("s") /// .value_names(&["fast", "slow"]) /// # ; /// ``` /// /// ```rust /// # use clap::{App, Arg}; /// let m = App::new("prog") /// .arg(Arg::with_name("io") /// .long("io-files") /// .value_names(&["INFILE", "OUTFILE"])) /// .get_matches_from(vec![ /// "prog", "--help" /// ]); /// ``` /// Running the above program produces the following output /// /// ```notrust /// valnames /// /// USAGE: /// valnames [FLAGS] [OPTIONS] /// /// FLAGS: /// -h, --help Prints help information /// -V, --version Prints version information /// /// OPTIONS: /// --io-files Some help text /// ``` /// [`Arg::next_line_help(true)`]: ./struct.Arg.html#method.next_line_help /// [`Arg::number_of_values`]: ./struct.Arg.html#method.number_of_values /// [`Arg::takes_value(true)`]: ./struct.Arg.html#method.takes_value /// [`Arg::multiple(true)`]: ./struct.Arg.html#method.multiple pub fn value_names(mut self, names: &[&'b str]) -> Self { self.setb(ArgSettings::TakesValue); if self.is_set(ArgSettings::ValueDelimiterNotSet) { self.unsetb(ArgSettings::ValueDelimiterNotSet); self.setb(ArgSettings::UseValueDelimiter); } if let Some(ref mut vals) = self.v.val_names { let mut l = vals.len(); for s in names { vals.insert(l, s); l += 1; } } else { let mut vm = VecMap::new(); for (i, n) in names.iter().enumerate() { vm.insert(i, *n); } self.v.val_names = Some(vm); } self } /// Specifies the name for value of [option] or [positional] arguments inside of help /// documentation. This name is cosmetic only, the name is **not** used to access arguments. /// This setting can be very helpful when describing the type of input the user should be /// using, such as `FILE`, `INTERFACE`, etc. Although not required, it's somewhat convention to /// use all capital letters for the value name. /// /// **NOTE:** implicitly sets [`Arg::takes_value(true)`] /// /// # Examples /// /// ```rust /// # use clap::{App, Arg}; /// Arg::with_name("cfg") /// .long("config") /// .value_name("FILE") /// # ; /// ``` /// /// ```rust /// # use clap::{App, Arg}; /// let m = App::new("prog") /// .arg(Arg::with_name("config") /// .long("config") /// .value_name("FILE")) /// .get_matches_from(vec![ /// "prog", "--help" /// ]); /// ``` /// Running the above program produces the following output /// /// ```notrust /// valnames /// /// USAGE: /// valnames [FLAGS] [OPTIONS] /// /// FLAGS: /// -h, --help Prints help information /// -V, --version Prints version information /// /// OPTIONS: /// --config Some help text /// ``` /// [option]: ./struct.Arg.html#method.takes_value /// [positional]: ./struct.Arg.html#method.index /// [`Arg::takes_value(true)`]: ./struct.Arg.html#method.takes_value pub fn value_name(mut self, name: &'b str) -> Self { self.setb(ArgSettings::TakesValue); if let Some(ref mut vals) = self.v.val_names { let l = vals.len(); vals.insert(l, name); } else { let mut vm = VecMap::new(); vm.insert(0, name); self.v.val_names = Some(vm); } self } /// Specifies the value of the argument when *not* specified at runtime. /// /// **NOTE:** If the user *does not* use this argument at runtime, [`ArgMatches::occurrences_of`] /// will return `0` even though the [`ArgMatches::value_of`] will return the default specified. /// /// **NOTE:** If the user *does not* use this argument at runtime [`ArgMatches::is_present`] will /// still return `true`. If you wish to determine whether the argument was used at runtime or /// not, consider [`ArgMatches::occurrences_of`] which will return `0` if the argument was *not* /// used at runtime. /// /// **NOTE:** This setting is perfectly compatible with [`Arg::default_value_if`] but slightly /// different. `Arg::default_value` *only* takes affect when the user has not provided this arg /// at runtime. `Arg::default_value_if` however only takes affect when the user has not provided /// a value at runtime **and** these other conditions are met as well. If you have set /// `Arg::default_value` and `Arg::default_value_if`, and the user **did not** provide a this /// arg at runtime, nor did were the conditions met for `Arg::default_value_if`, the /// `Arg::default_value` will be applied. /// /// **NOTE:** This implicitly sets [`Arg::takes_value(true)`]. /// /// **NOTE:** This setting effectively disables `AppSettings::ArgRequiredElseHelp` if used in /// conjunction as it ensures that some argument will always be present. /// /// # Examples /// /// First we use the default value without providing any value at runtime. /// /// ```rust /// # use clap::{App, Arg}; /// let m = App::new("prog") /// .arg(Arg::with_name("opt") /// .long("myopt") /// .default_value("myval")) /// .get_matches_from(vec![ /// "prog" /// ]); /// /// assert_eq!(m.value_of("opt"), Some("myval")); /// assert!(m.is_present("opt")); /// assert_eq!(m.occurrences_of("opt"), 0); /// ``` /// /// Next we provide a value at runtime to override the default. /// /// ```rust /// # use clap::{App, Arg}; /// let m = App::new("prog") /// .arg(Arg::with_name("opt") /// .long("myopt") /// .default_value("myval")) /// .get_matches_from(vec![ /// "prog", "--myopt=non_default" /// ]); /// /// assert_eq!(m.value_of("opt"), Some("non_default")); /// assert!(m.is_present("opt")); /// assert_eq!(m.occurrences_of("opt"), 1); /// ``` /// [`ArgMatches::occurrences_of`]: ./struct.ArgMatches.html#method.occurrences_of /// [`ArgMatches::value_of`]: ./struct.ArgMatches.html#method.value_of /// [`Arg::takes_value(true)`]: ./struct.Arg.html#method.takes_value /// [`ArgMatches::is_present`]: ./struct.ArgMatches.html#method.is_present /// [`Arg::default_value_if`]: ./struct.Arg.html#method.default_value_if pub fn default_value(self, val: &'a str) -> Self { self.default_value_os(OsStr::from_bytes(val.as_bytes())) } /// Provides a default value in the exact same manner as [`Arg::default_value`] /// only using [`OsStr`]s instead. /// [`Arg::default_value`]: ./struct.Arg.html#method.default_value /// [`OsStr`]: https://doc.rust-lang.org/std/ffi/struct.OsStr.html pub fn default_value_os(mut self, val: &'a OsStr) -> Self { self.setb(ArgSettings::TakesValue); self.v.default_val = Some(val); self } /// Specifies the value of the argument if `arg` has been used at runtime. If `val` is set to /// `None`, `arg` only needs to be present. If `val` is set to `"some-val"` then `arg` must be /// present at runtime **and** have the value `val`. /// /// **NOTE:** This setting is perfectly compatible with [`Arg::default_value`] but slightly /// different. `Arg::default_value` *only* takes affect when the user has not provided this arg /// at runtime. This setting however only takes affect when the user has not provided a value at /// runtime **and** these other conditions are met as well. If you have set `Arg::default_value` /// and `Arg::default_value_if`, and the user **did not** provide a this arg at runtime, nor did /// were the conditions met for `Arg::default_value_if`, the `Arg::default_value` will be /// applied. /// /// **NOTE:** This implicitly sets [`Arg::takes_value(true)`]. /// /// **NOTE:** If using YAML the values should be laid out as follows (`None` can be represented /// as `null` in YAML) /// /// ```yaml /// default_value_if: /// - [arg, val, default] /// ``` /// /// # Examples /// /// First we use the default value only if another arg is present at runtime. /// /// ```rust /// # use clap::{App, Arg}; /// let m = App::new("prog") /// .arg(Arg::with_name("flag") /// .long("flag")) /// .arg(Arg::with_name("other") /// .long("other") /// .default_value_if("flag", None, "default")) /// .get_matches_from(vec![ /// "prog", "--flag" /// ]); /// /// assert_eq!(m.value_of("other"), Some("default")); /// ``` /// /// Next we run the same test, but without providing `--flag`. /// /// ```rust /// # use clap::{App, Arg}; /// let m = App::new("prog") /// .arg(Arg::with_name("flag") /// .long("flag")) /// .arg(Arg::with_name("other") /// .long("other") /// .default_value_if("flag", None, "default")) /// .get_matches_from(vec![ /// "prog" /// ]); /// /// assert_eq!(m.value_of("other"), None); /// ``` /// /// Now lets only use the default value if `--opt` contains the value `special`. /// /// ```rust /// # use clap::{App, Arg}; /// let m = App::new("prog") /// .arg(Arg::with_name("opt") /// .takes_value(true) /// .long("opt")) /// .arg(Arg::with_name("other") /// .long("other") /// .default_value_if("opt", Some("special"), "default")) /// .get_matches_from(vec![ /// "prog", "--opt", "special" /// ]); /// /// assert_eq!(m.value_of("other"), Some("default")); /// ``` /// /// We can run the same test and provide any value *other than* `special` and we won't get a /// default value. /// /// ```rust /// # use clap::{App, Arg}; /// let m = App::new("prog") /// .arg(Arg::with_name("opt") /// .takes_value(true) /// .long("opt")) /// .arg(Arg::with_name("other") /// .long("other") /// .default_value_if("opt", Some("special"), "default")) /// .get_matches_from(vec![ /// "prog", "--opt", "hahaha" /// ]); /// /// assert_eq!(m.value_of("other"), None); /// ``` /// [`Arg::takes_value(true)`]: ./struct.Arg.html#method.takes_value /// [`Arg::default_value`]: ./struct.Arg.html#method.default_value pub fn default_value_if(self, arg: &'a str, val: Option<&'b str>, default: &'b str) -> Self { self.default_value_if_os( arg, val.map(str::as_bytes).map(OsStr::from_bytes), OsStr::from_bytes(default.as_bytes()), ) } /// Provides a conditional default value in the exact same manner as [`Arg::default_value_if`] /// only using [`OsStr`]s instead. /// [`Arg::default_value_if`]: ./struct.Arg.html#method.default_value_if /// [`OsStr`]: https://doc.rust-lang.org/std/ffi/struct.OsStr.html pub fn default_value_if_os( mut self, arg: &'a str, val: Option<&'b OsStr>, default: &'b OsStr, ) -> Self { self.setb(ArgSettings::TakesValue); if let Some(ref mut vm) = self.v.default_vals_ifs { let l = vm.len(); vm.insert(l, (arg, val, default)); } else { let mut vm = VecMap::new(); vm.insert(0, (arg, val, default)); self.v.default_vals_ifs = Some(vm); } self } /// Specifies multiple values and conditions in the same manner as [`Arg::default_value_if`]. /// The method takes a slice of tuples in the `(arg, Option, default)` format. /// /// **NOTE**: The conditions are stored in order and evaluated in the same order. I.e. the first /// if multiple conditions are true, the first one found will be applied and the ultimate value. /// /// **NOTE:** If using YAML the values should be laid out as follows /// /// ```yaml /// default_value_if: /// - [arg, val, default] /// - [arg2, null, default2] /// ``` /// /// # Examples /// /// First we use the default value only if another arg is present at runtime. /// /// ```rust /// # use clap::{App, Arg}; /// let m = App::new("prog") /// .arg(Arg::with_name("flag") /// .long("flag")) /// .arg(Arg::with_name("opt") /// .long("opt") /// .takes_value(true)) /// .arg(Arg::with_name("other") /// .long("other") /// .default_value_ifs(&[ /// ("flag", None, "default"), /// ("opt", Some("channal"), "chan"), /// ])) /// .get_matches_from(vec![ /// "prog", "--opt", "channal" /// ]); /// /// assert_eq!(m.value_of("other"), Some("chan")); /// ``` /// /// Next we run the same test, but without providing `--flag`. /// /// ```rust /// # use clap::{App, Arg}; /// let m = App::new("prog") /// .arg(Arg::with_name("flag") /// .long("flag")) /// .arg(Arg::with_name("other") /// .long("other") /// .default_value_ifs(&[ /// ("flag", None, "default"), /// ("opt", Some("channal"), "chan"), /// ])) /// .get_matches_from(vec![ /// "prog" /// ]); /// /// assert_eq!(m.value_of("other"), None); /// ``` /// /// We can also see that these values are applied in order, and if more than one condition is /// true, only the first evaluated "wins" /// /// ```rust /// # use clap::{App, Arg}; /// let m = App::new("prog") /// .arg(Arg::with_name("flag") /// .long("flag")) /// .arg(Arg::with_name("opt") /// .long("opt") /// .takes_value(true)) /// .arg(Arg::with_name("other") /// .long("other") /// .default_value_ifs(&[ /// ("flag", None, "default"), /// ("opt", Some("channal"), "chan"), /// ])) /// .get_matches_from(vec![ /// "prog", "--opt", "channal", "--flag" /// ]); /// /// assert_eq!(m.value_of("other"), Some("default")); /// ``` /// [`Arg::takes_value(true)`]: ./struct.Arg.html#method.takes_value /// [`Arg::default_value`]: ./struct.Arg.html#method.default_value pub fn default_value_ifs(mut self, ifs: &[(&'a str, Option<&'b str>, &'b str)]) -> Self { for &(arg, val, default) in ifs { self = self.default_value_if_os( arg, val.map(str::as_bytes).map(OsStr::from_bytes), OsStr::from_bytes(default.as_bytes()), ); } self } /// Provides multiple conditional default values in the exact same manner as /// [`Arg::default_value_ifs`] only using [`OsStr`]s instead. /// [`Arg::default_value_ifs`]: ./struct.Arg.html#method.default_value_ifs /// [`OsStr`]: https://doc.rust-lang.org/std/ffi/struct.OsStr.html #[cfg_attr(feature = "lints", allow(explicit_counter_loop))] pub fn default_value_ifs_os(mut self, ifs: &[(&'a str, Option<&'b OsStr>, &'b OsStr)]) -> Self { for &(arg, val, default) in ifs { self = self.default_value_if_os(arg, val, default); } self } /// Specifies that if the value is not passed in as an argument, that it should be retrieved /// from the environment, if available. If it is not present in the environment, then default /// rules will apply. /// /// **NOTE:** If the user *does not* use this argument at runtime, [`ArgMatches::occurrences_of`] /// will return `0` even though the [`ArgMatches::value_of`] will return the default specified. /// /// **NOTE:** If the user *does not* use this argument at runtime [`ArgMatches::is_present`] will /// return `true` if the variable is present in the environment . If you wish to determine whether /// the argument was used at runtime or not, consider [`ArgMatches::occurrences_of`] which will /// return `0` if the argument was *not* used at runtime. /// /// **NOTE:** This implicitly sets [`Arg::takes_value(true)`]. /// /// **NOTE:** If [`Arg::multiple(true)`] is set then [`Arg::use_delimiter(true)`] should also be /// set. Otherwise, only a single argument will be returned from the environment variable. The /// default delimiter is `,` and follows all the other delimiter rules. /// /// # Examples /// /// In this example, we show the variable coming from the environment: /// /// ```rust /// # use std::env; /// # use clap::{App, Arg}; /// /// env::set_var("MY_FLAG", "env"); /// /// let m = App::new("prog") /// .arg(Arg::with_name("flag") /// .long("flag") /// .env("MY_FLAG")) /// .get_matches_from(vec![ /// "prog" /// ]); /// /// assert_eq!(m.value_of("flag"), Some("env")); /// ``` /// /// In this example, we show the variable coming from an option on the CLI: /// /// ```rust /// # use std::env; /// # use clap::{App, Arg}; /// /// env::set_var("MY_FLAG", "env"); /// /// let m = App::new("prog") /// .arg(Arg::with_name("flag") /// .long("flag") /// .env("MY_FLAG")) /// .get_matches_from(vec![ /// "prog", "--flag", "opt" /// ]); /// /// assert_eq!(m.value_of("flag"), Some("opt")); /// ``` /// /// In this example, we show the variable coming from the environment even with the /// presence of a default: /// /// ```rust /// # use std::env; /// # use clap::{App, Arg}; /// /// env::set_var("MY_FLAG", "env"); /// /// let m = App::new("prog") /// .arg(Arg::with_name("flag") /// .long("flag") /// .env("MY_FLAG") /// .default_value("default")) /// .get_matches_from(vec![ /// "prog" /// ]); /// /// assert_eq!(m.value_of("flag"), Some("env")); /// ``` /// /// In this example, we show the use of multiple values in a single environment variable: /// /// ```rust /// # use std::env; /// # use clap::{App, Arg}; /// /// env::set_var("MY_FLAG_MULTI", "env1,env2"); /// /// let m = App::new("prog") /// .arg(Arg::with_name("flag") /// .long("flag") /// .env("MY_FLAG_MULTI") /// .multiple(true) /// .use_delimiter(true)) /// .get_matches_from(vec![ /// "prog" /// ]); /// /// assert_eq!(m.values_of("flag").unwrap().collect::>(), vec!["env1", "env2"]); /// ``` /// [`ArgMatches::occurrences_of`]: ./struct.ArgMatches.html#method.occurrences_of /// [`ArgMatches::value_of`]: ./struct.ArgMatches.html#method.value_of /// [`ArgMatches::is_present`]: ./struct.ArgMatches.html#method.is_present /// [`Arg::takes_value(true)`]: ./struct.Arg.html#method.takes_value /// [`Arg::multiple(true)`]: ./struct.Arg.html#method.multiple /// [`Arg::use_delimiter(true)`]: ./struct.Arg.html#method.use_delimiter pub fn env(self, name: &'a str) -> Self { self.env_os(OsStr::new(name)) } /// Specifies that if the value is not passed in as an argument, that it should be retrieved /// from the environment if available in the exact same manner as [`Arg::env`] only using /// [`OsStr`]s instead. pub fn env_os(mut self, name: &'a OsStr) -> Self { self.setb(ArgSettings::TakesValue); self.v.env = Some((name, env::var_os(name))); self } /// @TODO @p2 @docs @release: write docs pub fn hide_env_values(self, hide: bool) -> Self { if hide { self.set(ArgSettings::HideEnvValues) } else { self.unset(ArgSettings::HideEnvValues) } } /// When set to `true` the help string will be displayed on the line after the argument and /// indented once. This can be helpful for arguments with very long or complex help messages. /// This can also be helpful for arguments with very long flag names, or many/long value names. /// /// **NOTE:** To apply this setting to all arguments consider using /// [`AppSettings::NextLineHelp`] /// /// # Examples /// /// ```rust /// # use clap::{App, Arg}; /// let m = App::new("prog") /// .arg(Arg::with_name("opt") /// .long("long-option-flag") /// .short("o") /// .takes_value(true) /// .value_names(&["value1", "value2"]) /// .help("Some really long help and complex\n\ /// help that makes more sense to be\n\ /// on a line after the option") /// .next_line_help(true)) /// .get_matches_from(vec![ /// "prog", "--help" /// ]); /// ``` /// /// The above example displays the following help message /// /// ```notrust /// nlh /// /// USAGE: /// nlh [FLAGS] [OPTIONS] /// /// FLAGS: /// -h, --help Prints help information /// -V, --version Prints version information /// /// OPTIONS: /// -o, --long-option-flag /// Some really long help and complex /// help that makes more sense to be /// on a line after the option /// ``` /// [`AppSettings::NextLineHelp`]: ./enum.AppSettings.html#variant.NextLineHelp pub fn next_line_help(mut self, nlh: bool) -> Self { if nlh { self.setb(ArgSettings::NextLineHelp); } else { self.unsetb(ArgSettings::NextLineHelp); } self } /// Allows custom ordering of args within the help message. Args with a lower value will be /// displayed first in the help message. This is helpful when one would like to emphasise /// frequently used args, or prioritize those towards the top of the list. Duplicate values /// **are** allowed. Args with duplicate display orders will be displayed in alphabetical /// order. /// /// **NOTE:** The default is 999 for all arguments. /// /// **NOTE:** This setting is ignored for [positional arguments] which are always displayed in /// [index] order. /// /// # Examples /// /// ```rust /// # use clap::{App, Arg}; /// let m = App::new("prog") /// .arg(Arg::with_name("a") // Typically args are grouped alphabetically by name. /// // Args without a display_order have a value of 999 and are /// // displayed alphabetically with all other 999 valued args. /// .long("long-option") /// .short("o") /// .takes_value(true) /// .help("Some help and text")) /// .arg(Arg::with_name("b") /// .long("other-option") /// .short("O") /// .takes_value(true) /// .display_order(1) // In order to force this arg to appear *first* /// // all we have to do is give it a value lower than 999. /// // Any other args with a value of 1 will be displayed /// // alphabetically with this one...then 2 values, then 3, etc. /// .help("I should be first!")) /// .get_matches_from(vec![ /// "prog", "--help" /// ]); /// ``` /// /// The above example displays the following help message /// /// ```notrust /// cust-ord /// /// USAGE: /// cust-ord [FLAGS] [OPTIONS] /// /// FLAGS: /// -h, --help Prints help information /// -V, --version Prints version information /// /// OPTIONS: /// -O, --other-option I should be first! /// -o, --long-option Some help and text /// ``` /// [positional arguments]: ./struct.Arg.html#method.index /// [index]: ./struct.Arg.html#method.index pub fn display_order(mut self, ord: usize) -> Self { self.s.disp_ord = ord; self } /// Indicates that all parameters passed after this should not be parsed /// individually, but rather passed in their entirety. It is worth noting /// that setting this requires all values to come after a `--` to indicate they /// should all be captured. For example: /// /// ```notrust /// --foo something -- -v -v -v -b -b -b --baz -q -u -x /// ``` /// Will result in everything after `--` to be considered one raw argument. This behavior /// may not be exactly what you are expecting and using [`AppSettings::TrailingVarArg`] /// may be more appropriate. /// /// **NOTE:** Implicitly sets [`Arg::multiple(true)`], [`Arg::allow_hyphen_values(true)`], and /// [`Arg::last(true)`] when set to `true` /// /// [`Arg::multiple(true)`]: ./struct.Arg.html#method.multiple /// [`Arg::allow_hyphen_values(true)`]: ./struct.Arg.html#method.allow_hyphen_values /// [`Arg::last(true)`]: ./struct.Arg.html#method.last /// [`AppSettings::TrailingVarArg`]: ./enum.AppSettings.html#variant.TrailingVarArg pub fn raw(self, raw: bool) -> Self { self.multiple(raw).allow_hyphen_values(raw).last(raw) } /// Hides an argument from short help message output. /// /// **NOTE:** This does **not** hide the argument from usage strings on error /// /// **NOTE:** Setting this option will cause next-line-help output style to be used /// when long help (`--help`) is called. /// /// # Examples /// /// ```rust /// # use clap::{App, Arg}; /// Arg::with_name("debug") /// .hidden_short_help(true) /// # ; /// ``` /// Setting `hidden_short_help(true)` will hide the argument when displaying short help text /// /// ```rust /// # use clap::{App, Arg}; /// let m = App::new("prog") /// .arg(Arg::with_name("cfg") /// .long("config") /// .hidden_short_help(true) /// .help("Some help text describing the --config arg")) /// .get_matches_from(vec![ /// "prog", "-h" /// ]); /// ``` /// /// The above example displays /// /// ```notrust /// helptest /// /// USAGE: /// helptest [FLAGS] /// /// FLAGS: /// -h, --help Prints help information /// -V, --version Prints version information /// ``` /// /// However, when --help is called /// /// ```rust /// # use clap::{App, Arg}; /// let m = App::new("prog") /// .arg(Arg::with_name("cfg") /// .long("config") /// .hidden_short_help(true) /// .help("Some help text describing the --config arg")) /// .get_matches_from(vec![ /// "prog", "--help" /// ]); /// ``` /// /// Then the following would be displayed /// /// ```notrust /// helptest /// /// USAGE: /// helptest [FLAGS] /// /// FLAGS: /// --config Some help text describing the --config arg /// -h, --help Prints help information /// -V, --version Prints version information /// ``` pub fn hidden_short_help(self, hide: bool) -> Self { if hide { self.set(ArgSettings::HiddenShortHelp) } else { self.unset(ArgSettings::HiddenShortHelp) } } /// Hides an argument from long help message output. /// /// **NOTE:** This does **not** hide the argument from usage strings on error /// /// **NOTE:** Setting this option will cause next-line-help output style to be used /// when long help (`--help`) is called. /// /// # Examples /// /// ```rust /// # use clap::{App, Arg}; /// Arg::with_name("debug") /// .hidden_long_help(true) /// # ; /// ``` /// Setting `hidden_long_help(true)` will hide the argument when displaying long help text /// /// ```rust /// # use clap::{App, Arg}; /// let m = App::new("prog") /// .arg(Arg::with_name("cfg") /// .long("config") /// .hidden_long_help(true) /// .help("Some help text describing the --config arg")) /// .get_matches_from(vec![ /// "prog", "--help" /// ]); /// ``` /// /// The above example displays /// /// ```notrust /// helptest /// /// USAGE: /// helptest [FLAGS] /// /// FLAGS: /// -h, --help Prints help information /// -V, --version Prints version information /// ``` /// /// However, when -h is called /// /// ```rust /// # use clap::{App, Arg}; /// let m = App::new("prog") /// .arg(Arg::with_name("cfg") /// .long("config") /// .hidden_long_help(true) /// .help("Some help text describing the --config arg")) /// .get_matches_from(vec![ /// "prog", "-h" /// ]); /// ``` /// /// Then the following would be displayed /// /// ```notrust /// helptest /// /// USAGE: /// helptest [FLAGS] /// /// FLAGS: /// --config Some help text describing the --config arg /// -h, --help Prints help information /// -V, --version Prints version information /// ``` pub fn hidden_long_help(self, hide: bool) -> Self { if hide { self.set(ArgSettings::HiddenLongHelp) } else { self.unset(ArgSettings::HiddenLongHelp) } } /// Checks if one of the [`ArgSettings`] settings is set for the argument. /// /// [`ArgSettings`]: ./enum.ArgSettings.html pub fn is_set(&self, s: ArgSettings) -> bool { self.b.is_set(s) } /// Sets one of the [`ArgSettings`] settings for the argument. /// /// [`ArgSettings`]: ./enum.ArgSettings.html pub fn set(mut self, s: ArgSettings) -> Self { self.setb(s); self } /// Unsets one of the [`ArgSettings`] settings for the argument. /// /// [`ArgSettings`]: ./enum.ArgSettings.html pub fn unset(mut self, s: ArgSettings) -> Self { self.unsetb(s); self } #[doc(hidden)] pub fn setb(&mut self, s: ArgSettings) { self.b.set(s); } #[doc(hidden)] pub fn unsetb(&mut self, s: ArgSettings) { self.b.unset(s); } } impl<'a, 'b, 'z> From<&'z Arg<'a, 'b>> for Arg<'a, 'b> { fn from(a: &'z Arg<'a, 'b>) -> Self { Arg { b: a.b.clone(), v: a.v.clone(), s: a.s.clone(), index: a.index, r_ifs: a.r_ifs.clone(), } } } impl<'n, 'e> PartialEq for Arg<'n, 'e> { fn eq(&self, other: &Arg<'n, 'e>) -> bool { self.b == other.b } }